diff --git a/.github/workflows/ci.yaml b/.github/workflows/ci.yaml
deleted file mode 100644
index 28912b611c396ee32678f3a6b2a79261aae5b593..0000000000000000000000000000000000000000
--- a/.github/workflows/ci.yaml
+++ /dev/null
@@ -1,38 +0,0 @@
-name: Continuous Integration
-
-on:
-  # Trigger the workflow on push or pull request, only on the main branch.
-  push:
-    branches:
-      - main
-  pull_request:
-    branches:
-      - main
-  workflow_dispatch:
-
-jobs:
-  build:
-    name: "build ${{ matrix.name-prefix }} (py ${{ matrix.python-version }} on ${{ matrix.os }})"
-    runs-on: ${{ matrix.os }}
-    strategy:
-      matrix:
-        include:
-          - name-prefix: "all tests"
-            python-version: '3.11'
-            os: ubuntu-latest
-    steps:
-    - uses: actions/checkout@v4
-    - name: Set up Python ${{ matrix.python-version }}
-      uses: actions/setup-python@v5
-      with:
-        python-version: ${{ matrix.python-version }}
-    - name: Install dependencies
-      run: |
-        sudo apt-get install -y hmmer
-        pip install --upgrade pip
-        pip install -r dev-requirements.txt
-        pip install --no-deps .
-        build_data
-    - name: Run CPU-only tests
-      run: |
-        python run_alphafold_data_test.py
diff --git a/.gitlab-ci.yml b/.gitlab-ci.yml
index dea82c35937e91ec3ae444e60fb73cf75f38df40..d50815f10f082a5094f63f05bc8da1a9884189e5 100644
--- a/.gitlab-ci.yml
+++ b/.gitlab-ci.yml
@@ -1,24 +1,64 @@
-default:
-  image: docker:latest
-
 stages:
+  - prep_tags
   - build
 
 variables:
-  PACKAGE_NAME: "alphafold3"
-  DOCKER_IMAGE: "$CI_REGISTRY_IMAGE/$PACKAGE_NAME"
+  GITHUB_URL: "github.com/google-deepmind/alphafold3.git"
+  REGISTRY_URL: "${CI_REGISTRY_IMAGE}"
+  IMAGE_NAME: "alphafold3"
+  REPO_URL: "https://gitlab.rc.uab.edu/api/v4/projects/${CI_PROJECT_ID}/registry/repositories/"
   DOCKER_TLS_CERTDIR: "/certs"
 
-before_script:
-  - unset DOCKER_HOST
-  - echo "${CI_REGISTRY_PASSWORD}" | docker login -u "${CI_REGISTRY_USER}" --password-stdin ${CI_REGISTRY}
+workflow:
+  rules:
+    - if: $CI_COMMIT_BRANCH == $CI_DEFAULT_BRANCH # Only run on main
+    - if: '$CI_PIPELINE_SOURCE == "web"'
+    - when: never
+
+prep_missing_tags:
+  image: ubuntu:latest
+  stage: prep_tags
+  script:
+    - apt-get update && apt-get install -y curl git jq
+    - git clone https://${CI_GITHUB_USER}:${CI_GITHUB_TOKEN}@${GITHUB_URL}
+    - cd alphafold3
+    - git fetch --tags
+    - 'REPO_ID=$(curl -s --header "PRIVATE-TOKEN: ${CI_PROJECT_ACCESS_TOKEN}" "${REPO_URL}" | jq ".[0].id")'
+    - 'export REGISTRY_TAGS=($(curl -s --header "PRIVATE-TOKEN: ${CI_PROJECT_ACCESS_TOKEN}" "${REPO_URL}/${REPO_ID}/tags" | jq ".[].name" | sed "s|\"||g"))'
+    - 'export REPO_TAGS=($(git tag | sed "s|v||g"))'
+    - 'export MISSING=($(comm -23 <(printf "%s\n" "${REPO_TAGS[@]}" | sort) <(printf "%s\n" "${REGISTRY_TAGS[@]}" | sort)))'
+    - 'export MISSING=$(echo "${MISSING[@]}" | sed "s|[[:space:]]|,|g")'
+    - 'echo "Missing tags: ${MISSING}"'
+    - cd ..
+    - sed -e "s/REPLACE_HERE/${MISSING}/g" template-build-tags.yml > build-tags.yml
+  artifacts:
+    paths:
+      - build-tags.yml
+    expire_in: 1 hour
 
-push_docker_image:
+trigger_tag_builds:
+  stage: build
+  needs: [prep_missing_tags]
+  trigger:
+    include:
+      - artifact: 'build-tags.yml'
+        job: prep_missing_tags
+    strategy: depend
+    
+build_latest:
+  image: docker:latest
   stage: build
   services:
     - docker:dind
+  before_script:
+    - unset DOCKER_HOST
+    - echo "${CI_REGISTRY_PASSWORD}" | docker login -u "${CI_REGISTRY_USER}" --password-stdin ${CI_REGISTRY}
   script:
-    - docker build -t $DOCKER_IMAGE:$CI_COMMIT_SHORT_SHA -f docker/Dockerfile .
-    - docker push $DOCKER_IMAGE:$CI_COMMIT_SHORT_SHA
-  only:
-    - main  # Only run on the main branch
+    - |
+      apk update && apk add git
+      git clone https://${CI_GITHUB_USER}:${CI_GITHUB_TOKEN}@${GITHUB_URL}
+      cd alphafold3
+      echo "Building main branch as latest"
+      git checkout main
+      docker build -t $REGISTRY_URL/$IMAGE_NAME:latest -f docker/Dockerfile .
+      docker push $REGISTRY_URL/$IMAGE_NAME:latest
\ No newline at end of file
diff --git a/.gitmodules b/.gitmodules
deleted file mode 100644
index 4873e7c7478abc9c1ab7411cff604164a1f55052..0000000000000000000000000000000000000000
--- a/.gitmodules
+++ /dev/null
@@ -1,3 +0,0 @@
-[submodule "Alphafold_github"]
-	path = Alphafold_github
-	url = https://github.com/google-deepmind/alphafold3.git
diff --git a/Alphafold_github b/Alphafold_github
deleted file mode 160000
index 23e3d46d4ca126e8731e8c0cbb5673e9a848ceb5..0000000000000000000000000000000000000000
--- a/Alphafold_github
+++ /dev/null
@@ -1 +0,0 @@
-Subproject commit 23e3d46d4ca126e8731e8c0cbb5673e9a848ceb5
diff --git a/CMakeLists.txt b/CMakeLists.txt
deleted file mode 100644
index 81162722e04a3d9a245c1d4bd5e558b65ed5110b..0000000000000000000000000000000000000000
--- a/CMakeLists.txt
+++ /dev/null
@@ -1,95 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-cmake_minimum_required(VERSION 3.28)
-project(
-  "${SKBUILD_PROJECT_NAME}"
-  LANGUAGES CXX
-  VERSION "${SKBUILD_PROJECT_VERSION}")
-
-include(FetchContent)
-set(CMAKE_CXX_STANDARD 20)
-set(CMAKE_CXX_STANDARD_REQUIRED ON)
-set(CMAKE_POSITION_INDEPENDENT_CODE TRUE)
-set(ABSL_PROPAGATE_CXX_STD ON)
-
-# Remove support for scan deps, which is only useful when using C++ modules.
-unset(CMAKE_CXX_SCANDEP_SOURCE)
-
-FetchContent_Declare(
-  abseil-cpp
-  GIT_REPOSITORY https://github.com/abseil/abseil-cpp
-  GIT_TAG d7aaad83b488fd62bd51c81ecf16cd938532cc0a # 20240116.2
-  EXCLUDE_FROM_ALL)
-
-FetchContent_Declare(
-  pybind11
-  GIT_REPOSITORY https://github.com/pybind/pybind11
-  GIT_TAG 2e0815278cb899b20870a67ca8205996ef47e70f # v2.12.0
-  EXCLUDE_FROM_ALL)
-
-FetchContent_Declare(
-  pybind11_abseil
-  GIT_REPOSITORY https://github.com/pybind/pybind11_abseil
-  GIT_TAG bddf30141f9fec8e577f515313caec45f559d319 # HEAD @ 2024-08-07
-  EXCLUDE_FROM_ALL)
-
-FetchContent_Declare(
-  cifpp
-  GIT_REPOSITORY https://github.com/pdb-redo/libcifpp
-  GIT_TAG ac98531a2fc8daf21131faa0c3d73766efa46180 # v7.0.3
-  # Don't `EXCLUDE_FROM_ALL` as necessary for build_data.
-)
-
-FetchContent_Declare(
-  dssp
-  GIT_REPOSITORY https://github.com/PDB-REDO/dssp
-  GIT_TAG 57560472b4260dc41f457706bc45fc6ef0bc0f10 # v4.4.7
-  EXCLUDE_FROM_ALL)
-
-FetchContent_MakeAvailable(pybind11 abseil-cpp pybind11_abseil cifpp dssp)
-
-find_package(
-  Python3
-  COMPONENTS Interpreter Development NumPy
-  REQUIRED)
-
-include_directories(${PYTHON_INCLUDE_DIRS})
-include_directories(src/)
-
-file(GLOB_RECURSE cpp_srcs src/alphafold3/*.cc)
-list(FILTER cpp_srcs EXCLUDE REGEX ".*\(_test\|_main\|_benchmark\).cc$")
-
-add_compile_definitions(NPY_NO_DEPRECATED_API=NPY_1_7_API_VERSION)
-
-pybind11_add_module(cpp ${cpp_srcs})
-
-target_link_libraries(
-  cpp
-  PRIVATE absl::check
-          absl::flat_hash_map
-          absl::node_hash_map
-          absl::strings
-          absl::status
-          absl::statusor
-          absl::log
-          pybind11_abseil::absl_casters
-          Python3::NumPy
-          dssp::dssp
-          cifpp::cifpp)
-
-target_compile_definitions(cpp PRIVATE VERSION_INFO=${PROJECT_VERSION})
-install(TARGETS cpp LIBRARY DESTINATION alphafold3)
-install(
-  FILES LICENSE
-        OUTPUT_TERMS_OF_USE.md
-        WEIGHTS_PROHIBITED_USE_POLICY.md
-        WEIGHTS_TERMS_OF_USE.md
-  DESTINATION alphafold3)
diff --git a/LICENSE b/LICENSE
deleted file mode 100644
index cbe5ad1670406e4402217edfb82d2c56af7e8631..0000000000000000000000000000000000000000
--- a/LICENSE
+++ /dev/null
@@ -1,437 +0,0 @@
-Attribution-NonCommercial-ShareAlike 4.0 International
-
-=======================================================================
-
-Creative Commons Corporation ("Creative Commons") is not a law firm and
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-  d. Sections 1, 5, 6, 7, and 8 survive termination of this Public
-     License.
-
-
-Section 7 -- Other Terms and Conditions.
-
-  a. The Licensor shall not be bound by any additional or different
-     terms or conditions communicated by You unless expressly agreed.
-
-  b. Any arrangements, understandings, or agreements regarding the
-     Licensed Material not stated herein are separate from and
-     independent of the terms and conditions of this Public License.
-
-
-Section 8 -- Interpretation.
-
-  a. For the avoidance of doubt, this Public License does not, and
-     shall not be interpreted to, reduce, limit, restrict, or impose
-     conditions on any use of the Licensed Material that could lawfully
-     be made without permission under this Public License.
-
-  b. To the extent possible, if any provision of this Public License is
-     deemed unenforceable, it shall be automatically reformed to the
-     minimum extent necessary to make it enforceable. If the provision
-     cannot be reformed, it shall be severed from this Public License
-     without affecting the enforceability of the remaining terms and
-     conditions.
-
-  c. No term or condition of this Public License will be waived and no
-     failure to comply consented to unless expressly agreed to by the
-     Licensor.
-
-  d. Nothing in this Public License constitutes or may be interpreted
-     as a limitation upon, or waiver of, any privileges and immunities
-     that apply to the Licensor or You, including from the legal
-     processes of any jurisdiction or authority.
-
-=======================================================================
-
-Creative Commons is not a party to its public
-licenses. Notwithstanding, Creative Commons may elect to apply one of
-its public licenses to material it publishes and in those instances
-will be considered the “Licensor.” The text of the Creative Commons
-public licenses is dedicated to the public domain under the CC0 Public
-Domain Dedication. Except for the limited purpose of indicating that
-material is shared under a Creative Commons public license or as
-otherwise permitted by the Creative Commons policies published at
-creativecommons.org/policies, Creative Commons does not authorize the
-use of the trademark "Creative Commons" or any other trademark or logo
-of Creative Commons without its prior written consent including,
-without limitation, in connection with any unauthorized modifications
-to any of its public licenses or any other arrangements,
-understandings, or agreements concerning use of licensed material. For
-the avoidance of doubt, this paragraph does not form part of the
-public licenses.
-
-Creative Commons may be contacted at creativecommons.org.
diff --git a/OUTPUT_TERMS_OF_USE.md b/OUTPUT_TERMS_OF_USE.md
deleted file mode 100644
index 01ea93044bb682c756142e4af4b261b43e2d147d..0000000000000000000000000000000000000000
--- a/OUTPUT_TERMS_OF_USE.md
+++ /dev/null
@@ -1,246 +0,0 @@
-# ALPHAFOLD 3 OUTPUT TERMS OF USE
-
-Last Modified: 2024-11-09
-
-By using AlphaFold 3 Output (as defined below), without having agreed to
-[AlphaFold 3 Model Parameters Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md),
-you agree to be bound by these AlphaFold 3 Output Terms of Use between you (or
-your organization, as applicable) and Google LLC (these "**Terms**").
-
-If you are using Output on behalf of an organization, you confirm you are
-authorized either explicitly or implicitly to agree to, and are agreeing to,
-these Terms as an employee on behalf of, or otherwise on behalf of, your
-organization.
-
-If you have agreed to
-[AlphaFold 3 Model Parameters Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md),
-your use of Output are governed by those terms. **If you have not agreed to
-[AlphaFold 3 Model Parameters Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md)
-and do not agree to these Terms, do not use Output or permit any third party to
-do so on your behalf.**
-
-When we say "**you**", we mean the individual or organization using Output. When
-we say "**we**", "**us**" or "**Google**", we mean the entities that belong to
-the Google group of companies, which means Google LLC and its affiliates.
-
-## Key Definitions
-
-As used in these Terms:
-
-"**AlphaFold 3**" means the AlphaFold 3 Code and Model Parameters.
-
-"**AlphaFold 3 Code**" means the AlphaFold 3 source code: (a) identified at
-[public GitHub repo](https://github.com/google-deepmind/alphafold3/), or such
-other location in which we may make it available from time to time, regardless
-of the source that it was obtained from; and (b) made available by Google to
-organizations for their use in accordance with the
-[AlphaFold 3 Model Parameters Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md)
-(not these Terms) together with (i) modifications to that code, (ii) works based
-on that code, or (iii) other code or machine learning model which incorporates,
-in full or in part, that code.
-
-"**Model Parameters**" means the trained model weights and parameters made
-available by Google to organizations (at its sole discretion) for their use in
-accordance with the
-[AlphaFold 3 Model Parameters Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md)
-(not these Terms), together with (a) modifications to those weights and
-parameters, (b) works based on those weights and parameters, or (c) other code
-or machine learning model which incorporates, in full or in part, those weights
-and parameters.
-
-"**Output**" means the structure predictions and all related information
-provided by AlphaFold 3, together with any visual representations, computational
-predictions, descriptions, modifications, copies, or adaptations that are
-substantially derived from Output.
-
-## Use restrictions
-
-[AlphaFold 3](https://blog.google/technology/ai/google-deepmind-isomorphic-alphafold-3-ai-model/)
-belongs to us. Output are made available free of charge, for non-commercial use
-only, in accordance with the following use restrictions. You must not use nor
-allow others to use Output:
-
-1.  **On behalf of a commercial organization or in connection with any
-    commercial activities, including research on behalf of commercial
-    organizations.**
-
-    1.  This means that only non-commercial organizations (*i.e.*, universities,
-        non-profit organizations and research institutes, educational,
-        journalism and government bodies) may use Output for their
-        non-commercial activities. Output are not available for use by any other
-        types of organization, even if conducting non-commercial work.
-
-    2.  If you are a researcher affiliated with a non-commercial organization,
-        provided **you are not a commercial organisation or acting on behalf of
-        a commercial organisation**, you can use Output for your non-commercial
-        affiliated research.
-
-    3.  You must not share Output with any commercial organization. The only
-        exception is making Output publicly available (including, indirectly, to
-        commercial organizations) via a scientific publication or open source
-        release or using these to support journalism, each of which are
-        permitted.
-
-2.  **To misinform, misrepresent or mislead**, including:
-
-    1.  providing false or inaccurate information in relation to your access to
-        or use of Output;
-
-    2.  misrepresenting your relationship with Google - including by using
-        Google’s trademarks, trade names, logos or suggesting endorsement by
-        Google without Google’s permission to do so - nothing in these Terms
-        grants such permission;
-
-    3.  misrepresenting the origin of Output;
-
-    4.  distributing misleading claims of expertise or capability, or engaging
-        in the unauthorized or unlicensed practice of any profession,
-        particularly in sensitive areas (*e.g.*, health); or
-
-    5.  making decisions in domains that affect material or individual rights or
-        well-being (*e.g.*, healthcare).
-
-3.  **To perform, promote or facilitate dangerous, illegal or malicious
-    activities**, including:
-
-    1.  promoting or facilitating the sale of, or providing instructions for
-        synthesizing or accessing, illegal substances, goods or services;
-
-    2.  abusing, harming, interfering, or disrupting any services, including
-        generating or distributing content for deceptive or fraudulent
-        activities or malware;
-
-    3.  generating or distributing any content that infringes, misappropriates,
-        or otherwise violates any individual’s or entity’s rights (including,
-        but not limited to rights in copyrighted content); or
-
-    4.  attempting to circumvent these Terms.
-
-4.  **To train or create machine learning models or related technology for
-    biomolecular structure prediction similar to AlphaFold 3 as made available
-    by Google ("Derived Models"),** including via distillation or other
-    methods**.** For the avoidance of doubt, the use restrictions set out in
-    these Terms would apply in full to any Derived Models created in breach of
-    these Terms.
-
-5.  **Without providing conspicuous notice that published or distributed Output
-    is provided under and subject to these Terms and of any modifications you
-    make to Output.**
-
-    1.  This means if you remove, or cause to be removed (for example by using
-        third-party software), these Terms, or any notice of these Terms, from
-        Output, you must ensure further distribution or publication is
-        accompanied by a copy of the
-        [AlphaFold 3 Output Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-        and a "*Legally Binding Terms of Use*" text file that contains the
-        following notice:
-
-        "*By using this information, you agree to AlphaFold 3 Output Terms of
-        Use found at
-        https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md.*
-
-        *To request access to the AlphaFold 3 model parameters, follow the
-        process set out at https://github.com/google-deepmind/alphafold3. You
-        may only use these if received directly from Google. Use is subject to
-        terms of use available at
-        https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md.*"
-
-    2.  You must not include any additional or different terms that conflict
-        with the
-        [AlphaFold 3 Output Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-6.  **Distribute Output, or disclose findings arising from using AlphaFold 3
-    without citing our paper:** [Abramson, J et al. Accurate structure
-    prediction of biomolecular interactions with AlphaFold 3. *Nature*
-    (2024)](https://www.nature.com/articles/s41586-024-07487-w). For the
-    avoidance of doubt, this is an additional requirement to the notice
-    requirements set out above.
-
-We grant you a non-exclusive, royalty-free, revocable, non-transferable and
-non-sublicensable (except as expressly permitted in these Terms) license to any
-intellectual property rights we have in Output to the extent necessary for these
-purposes. You agree that your right to use and share Output is subject to your
-compliance with these Terms. If you breach these Terms, Google reserves the
-right to request that you delete and cease use or sharing of Output in your
-possession or control and prohibit you from using the AlphaFold 3 Assets
-(including as made available via
-[AlphaFold Server](https://alphafoldserver.com/about)). You agree to immediately
-comply with any such request.
-
-## Disclaimers
-
-Nothing in these Terms restricts any rights that cannot be restricted under
-applicable law or limits Google’s responsibilities except as allowed by
-applicable law.
-
-**Output are provided on an "as is" basis, without warranties or conditions of
-any kind, either express or implied, including any warranties or conditions of
-title, non-infringement, merchantability, or fitness for a particular purpose.
-You are solely responsible for determining the appropriateness of using or
-distributing any of the Output and assume any and all risks associated with your
-use or distribution of any Output and your exercise of rights and obligations
-under these Terms. You and anyone you share Output with are solely responsible
-for these and their subsequent uses.**
-
-**Output are predictions with varying levels of confidence and should be
-interpreted carefully. Use discretion before relying on, publishing, downloading
-or otherwise using Output.**
-
-**Output are for theoretical modeling only. These are not intended, validated,
-or approved for clinical use. You should not use these for clinical purposes or
-rely on them for medical or other professional advice. Any content regarding
-those topics is provided for informational purposes only and is not a substitute
-for advice from a qualified professional.**
-
-## Liabilities
-
-To the extent allowed by applicable law, you will indemnify Google and its
-directors, officers, employees, and contractors for any third-party legal
-proceedings (including actions by government authorities) arising out of or
-relating to your unlawful use of Output or violation of these Terms. This
-indemnity covers any liability or expense arising from claims, losses, damages,
-judgments, fines, litigation costs, and legal fees, except to the extent a
-liability or expense is caused by Google's breach, negligence, or willful
-misconduct. If you are legally exempt from certain responsibilities, including
-indemnification, then those responsibilities don’t apply to you under these
-terms.
-
-In no circumstances will Google be responsible for any indirect, special,
-incidental, exemplary, consequential, or punitive damages, or lost profits of
-any kind, even if Google has been advised of the possibility of such damages.
-Google’s total, aggregate liability for all claims arising out of or in
-connection with these Terms or Output, including for its own negligence, is
-limited to $500.
-
-## Governing law and disputes
-
-These Terms will be governed by the laws of the State of California. The state
-or federal courts of Santa Clara County, California shall have exclusive
-jurisdiction of any dispute arising out of these Terms.
-
-Given the nature of scientific research, it may take some time for any breach of
-these Terms to become apparent. To the extent allowed by applicable law, any
-legal claims relating to these Terms or Output can be initiated until the later
-of (a) the cut-off date under applicable law for bringing the legal claim; or
-(b) two years from the date you or Google (as applicable) became aware, or
-should reasonably have become aware, of the facts giving rise to that claim. You
-will not argue limitation, time bar, delay, waiver or the like in an attempt to
-bar an action filed within that time period, and neither will we.
-
-All rights not specifically and expressly granted to you by these Terms are
-reserved to Google. No delay, act or omission by Google in exercising any right
-or remedy will be deemed a waiver of any breach of these Terms and Google
-expressly reserves any and all rights and remedies available under these Terms
-or at law or in equity or otherwise, including the remedy of injunctive relief
-against any threatened or actual breach of these Terms without the necessity of
-proving actual damages.
-
-## Miscellaneous
-
-Google may update these Terms (1) to reflect changes in how it does business,
-(2) for legal, regulatory or security reasons, or (3) to prevent abuse or harm.
-The version of these Terms that were effective on the date the relevant Output
-was generated will apply to your use of that Output.
-
-If it turns out that a particular provision of these Terms is not valid or
-enforceable, this will not affect any other provisions.
diff --git a/README.md b/README.md
deleted file mode 100644
index 7acc8c22c83b3c13546b550e9cc4d2c56fe2f70c..0000000000000000000000000000000000000000
--- a/README.md
+++ /dev/null
@@ -1,31 +0,0 @@
-# Using this container on Cheaha
-
-Please follow these instructions to set up for Alphafold3 on Cheaha.
-
-1. Pull this container using the command:
-
-    ``` bash
-    singularity pull alphafold3.sif docker://gitlab.rc.uab.edu:4567/rc-data-science/community-containers/alphafold3/alphafold3:<tag> 
-    
-    #get the tag by clicking on "Deploy" -> "Container Registry" -> Click on "alphafold3/alphafold3" and then use the "Copy image path" option to get the image path used above, complete with the appropriate tag (latest).
-    ```
-
-1. If you already cloned the Alphafold3 [github repo](https://github.com/google-deepmind/alphafold3), you do not need to clone this repo, otherwise clone this repo.
-
-1. Download the needed databases for Alphafold3 by running the below command. Make sure you are in the same folder as the `fetch_databases.sh` file before running the below command, or use an absolute path for the file to run it.
-
-    ``` bash
-    ./fetch_databases.sh <DB_DIR> #<DB_DIR> is your preferred location for storing the databases
-    ```
-You will also need to get the model parameters for alphafold3, you have to fill out a form, and submit a request to Google.
-
-1. When the above steps are completed, run the Alphafold3 container on Cheaha to test it out using the commands:
-
-    ``` bash
-    singularity exec --nv alphafold3.sif sh -c 'nvidia-smi'
-    ```
-    or
-
-    ``` bash
-    singularity exec --nv alphafold3.sif python3 /app/run_alphafold.py --help
-    ```
diff --git a/WEIGHTS_PROHIBITED_USE_POLICY.md b/WEIGHTS_PROHIBITED_USE_POLICY.md
deleted file mode 100644
index da977ff39ae21e810363ae029dc616cdc587a240..0000000000000000000000000000000000000000
--- a/WEIGHTS_PROHIBITED_USE_POLICY.md
+++ /dev/null
@@ -1,132 +0,0 @@
-# ALPHAFOLD 3 MODEL PARAMETERS PROHIBITED USE POLICY
-
-Last Modified: 2024-11-09
-
-AlphaFold 3 can help you accelerate scientific research by predicting the 3D
-structure of biological molecules. Google makes the AlphaFold Assets available
-free of charge for certain non-commercial uses in accordance with the
-restrictions set out below. This policy uses the same defined terms as the
-[AlphaFold 3 Model Parameters Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md).
-
-**You must not access or use nor allow others to access or use the AlphaFold 3
-Assets:**
-
-1.  **On behalf of a commercial organization or in connection with any
-    commercial activities, including research on behalf of commercial
-    organizations.**
-
-    1.  This means that only non-commercial organizations (*i.e.*, universities,
-        non-profit organizations and research institutes, educational,
-        journalism and government bodies) may use the AlphaFold 3 Assets for
-        their non-commercial activities. The AlphaFold 3 Assets are not
-        available for any other types of organization, even if conducting
-        non-commercial work.
-
-    2.  If you are a researcher affiliated with a non-commercial organization,
-        provided **you are not a commercial organisation or acting on behalf of
-        a commercial organisation,** you can use the AlphaFold 3 Assets for your
-        non-commercial affiliated research.
-
-    3.  You must not share the AlphaFold 3 Assets with any commercial
-        organization or use the AlphaFold 3 Assets in a manner that will grant a
-        commercial organization any rights in these. The only exception is
-        making Output publicly available (including indirectly to commercial
-        organizations) via a scientific publication or open source release or
-        using it to support journalism, each of which is permitted.
-
-2.  **To misinform, misrepresent or mislead**, including:
-
-    1.  providing false or inaccurate information in relation to your access to
-        or use of AlphaFold 3 or Output, including accessing or using the Model
-        Parameters on behalf of an organization without telling us or submitting
-        a request to access the Model Parameters where Google has prohibited
-        your use of AlphaFold 3 in full or in part (including as made available
-        via [AlphaFold Server](https://alphafoldserver.com/about));
-
-    2.  misrepresenting your relationship with us, including by using Google’s
-        trademarks, trade names, logos or suggesting endorsement by Google
-        without Google’s permission to do so - nothing in the Terms grants such
-        permission;
-
-    3.  misrepresenting the origin of AlphaFold 3 in full or in part;
-
-    4.  distributing misleading claims of expertise or capability, or engaging
-        in the unauthorized or unlicensed practice of any profession,
-        particularly in sensitive areas (*e.g.*, health); or
-
-    5.  to make decisions in domains that affect material or individual rights
-        or well-being (*e.g.*, healthcare).
-
-3.  **To perform, promote or facilitate dangerous, illegal or malicious
-    activities**, including:
-
-    1.  promoting or facilitating the sale of, or providing instructions for
-        synthesizing or accessing, illegal substances, goods or services;
-
-    2.  abusing, harming, interfering, or disrupting any services, including
-        generating or distributing content for deceptive or fraudulent
-        activities or malware;
-
-    3.  generating or distributing any content, including Output, that
-        infringes, misappropriates, or otherwise violates any individual's or
-        entity's rights (including, but not limited to rights in copyrighted
-        content); or
-
-    4.  attempting to circumvent, or intentionally causing (directly or
-        indirectly) AlphaFold 3 to act in a manner that contravenes the Terms.
-
-**You must not nor allow others to:**
-
-1.  **Use Output to train or create machine learning models or related
-    technology for biomolecular structure prediction similar to AlphaFold 3
-    ("Derived Models"),** including via distillation or other methods. For the
-    avoidance of doubt, the use restrictions set out in the Terms would apply in
-    full to any Derived Models created in breach of the Terms.
-
-2.  **Distribute Output without providing conspicuous notice that what you
-    Distribute is provided under and subject to the
-    [AlphaFold 3 Output Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-    and of any modifications you make.**
-
-    1.  This means if you remove, or cause to be removed (for example by using
-        third-party software), the notices and terms we provide when you
-        generate Output using AlphaFold 3, you must ensure any further
-        Distribution of Output is accompanied by a copy of the
-        [AlphaFold 3 Output Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-        and a "Legally Binding Terms of Use" text file that contains the
-        following notice:
-
-        "*By using this information, you agree to AlphaFold 3 Output Terms of
-        Use found at
-        https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md.*
-
-        *To request access to the AlphaFold 3 model parameters, follow the
-        process set out at https://github.com/google-deepmind/alphafold3. You
-        may only use these if received directly from Google. Use is subject to
-        terms of use available at
-        https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md.*"
-
-    2.  You must not include any additional or different terms that conflict
-        with the
-        [AlphaFold 3 Output Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-3.  **Distribute Output, or disclose findings arising from using AlphaFold 3
-    without citing our paper:** [Abramson, J et al. Accurate structure
-    prediction of biomolecular interactions with AlphaFold 3. *Nature*
-    (2024)](https://www.nature.com/articles/s41586-024-07487-w). For the
-    avoidance of doubt, this is an additional requirement to the notice
-    requirements set out above.
-
-4.  **Circumvent access restrictions relating to the Model Parameters, including
-    utilising, sharing or making available the Model Parameters when you have
-    not been expressly authorized to do so by Google.** Google will grant access
-    to the Model Parameters to either:
-
-    1.  you for your individual use on behalf of your organization, in which
-        case you cannot share your copy of Model Parameters with anyone else; or
-
-    2.  an authorized representative of your organization, with full legal
-        authority to bind that organization to these Terms in which case you may
-        share that organization’s copy of the Model Parameters with employees,
-        consultants, contractors and agents of the organization as authorized by
-        that representative.
diff --git a/WEIGHTS_TERMS_OF_USE.md b/WEIGHTS_TERMS_OF_USE.md
deleted file mode 100644
index cfcc596320f4cf090cd056bc53d6486aed1440d5..0000000000000000000000000000000000000000
--- a/WEIGHTS_TERMS_OF_USE.md
+++ /dev/null
@@ -1,288 +0,0 @@
-# ALPHAFOLD 3 MODEL PARAMETERS TERMS OF USE
-
-Last Modified: 2024-11-09
-
-[AlphaFold 3](https://blog.google/technology/ai/google-deepmind-isomorphic-alphafold-3-ai-model/)
-is an AI model developed by [Google DeepMind](https://deepmind.google/) and
-[Isomorphic Labs](https://www.isomorphiclabs.com/). It generates 3D structure
-predictions of biological molecules, providing model confidence for the
-structure predictions. We make the trained model parameters and output generated
-using those available free of charge for certain non-commercial uses, in
-accordance with these terms of use and the
-[AlphaFold 3 Model Parameters Prohibited Use Policy](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_PROHIBITED_USE_POLICY.md).
-
-**Key things to know when using the AlphaFold 3 model parameters and output**
-
-1.  The AlphaFold 3 model parameters and output are **only** available for
-    non-commercial use by, or on behalf of, non-commercial organizations
-    (*i.e.*, universities, non-profit organizations and research institutes,
-    educational, journalism and government bodies). If you are a researcher
-    affiliated with a non-commercial organization, provided **you are not a
-    commercial organisation or acting on behalf of a commercial organisation,**
-    this means you can use these for your non-commercial affiliated research.
-2.  You **must not** use nor allow others to use:
-    1.  AlphaFold 3 model parameters or output in connection with **any
-        commercial activities, including research** **on behalf of commercial
-        organizations;** or
-    2.  AlphaFold 3 output to **train machine learning models** or related
-        technology for **biomolecular structure prediction** similar to
-        AlphaFold 3.
-3.  You ***must not* publish or share AlphaFold 3 model parameters**, except
-    sharing these within your organization in accordance with these Terms.
-4.  You ***can* publish, share and adapt AlphaFold 3 *output*** in accordance
-    with these Terms, including the requirements to provide clear notice of any
-    modifications you make and that ongoing use of AlphaFold 3 output and
-    derivatives are subject to the
-    [AlphaFold 3 Output Terms of Use](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-By using, reproducing, modifying, performing, distributing or displaying any
-portion or element of the Model Parameters (as defined below) or otherwise
-accepting the terms of this agreement, you agree to be bound by (1) these terms
-of use, and (2) the
-[AlphaFold 3 Model Parameters Prohibited Use Policy](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_PROHIBITED_USE_POLICY.md)
-which is incorporated herein by reference (together, the "**Terms**"), in each
-case (a) as modified from time to time in accordance with the Terms, and (b)
-between you and (i) if you are from a country in the European Economic Area or
-Switzerland, Google Ireland Limited, or (ii) otherwise, Google LLC.
-
-You confirm you are authorized either explicitly or implicitly to enter, and are
-entering, into the Terms as an employee on behalf of, or otherwise on behalf of,
-your organization.
-
-Please read these Terms carefully. They establish what you can expect from us as
-you access and use the AlphaFold 3 Assets (as defined below), and what Google
-expects from you. When we say "**you**", we mean the individual or organization
-using the AlphaFold 3 Assets. When we say "**we**", "**us**" or "**Google**", we
-mean the entities that belong to the Google group of companies, which means
-Google LLC and its affiliates.
-
-## 1. Key Definitions
-
-As used in these Terms:
-
-"**AlphaFold 3**" means: (a) the AlphaFold 3 source code made available
-[here](https://github.com/google-deepmind/alphafold3/) and licensed under the
-terms of the Creative Commons Attribution-NonCommercial-Sharealike 4.0
-International (CC-BY-NC-SA 4.0) license and any derivative source code, and (b)
-Model Parameters.
-
-"**AlphaFold 3 Assets**" means the Model Parameters and Output.
-
-"**Distribution**" or "**Distribute**" means any transmission, publication, or
-other sharing of Output publicly or to any other person.
-
-"**Model Parameters**" means the trained model weights and parameters made
-available by Google to organizations (at its sole discretion) for their use in
-accordance with these Terms, together with (a) modifications to those weights
-and parameters, (b) works based on those weights and parameters, or (c) other
-code or machine learning models which incorporate, in full or in part, those
-weights and parameters.
-
-"**Output**" means the structure predictions and all ancillary and related
-information provided by AlphaFold 3 or using the Model Parameters, together with
-any visual representations, computational predictions, descriptions,
-modifications, copies, or adaptations that are substantially derived from
-Output.
-
-"**Including"** means "**including without limitation**".
-
-## 2. Accessing and using the AlphaFold 3 Assets
-
-Subject to your compliance with the Terms, including the
-[AlphaFold 3 Model Parameters Prohibited Use Policy](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_PROHIBITED_USE_POLICY.md),
-you may access, use and modify the AlphaFold 3 Assets and Distribute the Output
-as set out in these Terms. We grant you a non-exclusive, royalty-free,
-revocable, non-transferable and non-sublicensable (except as expressly permitted
-in these Terms) license to any intellectual property rights we have in the
-AlphaFold Assets to the extent necessary for these purposes. In order to verify
-your access and use of AlphaFold 3, we may from time-to-time ask for additional
-information from you, including verification of your name, organization, and
-other identifying information.
-
-By accessing, using, or modifying the AlphaFold 3 Assets, Distributing Output,
-or requesting to access the Model Parameters, you represent and warrant that (a)
-you have full power and authority to enter into these Terms (including being of
-sufficient age of consent), (b) Google has never previously terminated your
-access and right to use AlphaFold 3 (including as made available via
-[AlphaFold Server](https://alphafoldserver.com/about)) due to your breach of
-applicable terms of use, (c) entering into or performing your rights and
-obligations under these Terms will not violate any agreement you have with a
-third party or any third-party rights, (d) any information provided by you to
-Google in relation to AlphaFold 3, including (where applicable) in order to
-request access to the Model Parameters, is correct and current, and (e) you are
-not (i) resident of a embargoed country, (ii) ordinarily resident in a US
-embargoed country, or (iii) otherwise prohibited by applicable export controls
-and sanctions programs from accessing, using, or modifying the AlphaFold 3
-Assets.
-
-If you choose to give Google feedback, such as suggestions to improve AlphaFold
-3, you undertake any such information is non-confidential and non-proprietary,
-and Google may act on your feedback without obligation to you.
-
-## 3. Use Restrictions
-
-You must not use any of the AlphaFold 3 Assets:
-
-1.  for the restricted uses set forth in the
-    [AlphaFold 3 Model Parameters Prohibited Use Policy](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_PROHIBITED_USE_POLICY.md);
-    or
-2.  in violation of applicable laws and regulations.
-
-To the maximum extent permitted by law and without limiting any of our other
-rights, Google reserves the right to revoke your right to use, and (to the
-extent feasible) restrict usage of any of the AlphaFold 3 Assets that Google
-reasonably believes is in violation of these Terms.
-
-## 4. Generated Output
-
-Although you must comply with these Terms when using the AlphaFold 3 Assets, we
-will not claim ownership in original Output you generate using AlphaFold 3.
-However, you acknowledge that AlphaFold 3 may generate the same or similar
-Output for multiple users, including Google, and we reserve all our rights in
-this respect.
-
-## 5. Changes to the AlphaFold 3 Assets or these Terms
-
-Google may add or remove functionalities or features of the AlphaFold 3 Assets
-at any time and may stop offering access to the AlphaFold 3 Assets altogether.
-
-Google may update these Terms and the access mechanism for the Model Parameters
-at any time. We'll post any modifications to the Terms
-[in the AlphaFold 3 GitHub repository](https://github.com/google-deepmind/alphafold3).
-Changes will generally become effective 14 days after they are posted. However,
-changes addressing functionality or made for legal reasons will be effective
-immediately.
-
-You should review the Terms whenever we update them or you use the AlphaFold 3
-Assets. If you do not agree to any modifications to the Terms, you must stop
-using the AlphaFold 3 Assets immediately.
-
-## 6. Suspending or terminating your right to use the AlphaFold 3 Assets
-
-Google may at any time suspend or terminate your right to use and, as applicable
-access to, the AlphaFold 3 Assets because of, among other reasons, your failure
-to fully comply with the Terms. If Google suspends or terminates your right to
-access or use the AlphaFold 3 Assets, you must immediately delete and cease use
-and Distribution of all copies of the AlphaFold 3 Assets in your possession or
-control and are prohibited from using the AlphaFold 3 Assets, including by
-submitting an application to use the Model Parameters. Google will endeavour to
-give you reasonable notice prior to any such suspension or termination, but no
-notice or prior warning will be given if the suspension or termination is for
-your failure to fully comply with the Terms or other serious grounds.
-
-Of course, you are always free to stop using the AlphaFold 3 Assets. If you do
-stop using these, we would appreciate knowing why (via
-[alphafold@google.com](mailto:alphafold@google.com)) so that we can continue to
-improve our technologies.
-
-## 7. Confidentiality
-
-You agree not to disclose or make available Google Confidential Information to
-anyone without our prior written consent. "**Google Confidential Information**"
-means (a) the AlphaFold 3 Model Parameters and all software, technology and
-documentation relating to AlphaFold 3, except for the AlphaFold 3 source code,
-and (b) any other information made available by Google that is marked
-confidential or would normally be considered confidential under the
-circumstances in which it is presented. Google Confidential Information does not
-include (a) information that you already knew prior to your access to, or use
-of, the AlphaFold 3 Assets (including via
-[AlphaFold Server](https://alphafoldserver.com/about)), (b) that becomes public
-through no fault of yours (for example, your breach of the Terms), (c) that was
-independently developed by you without reference to Google Confidential
-Information, or (d) that was lawfully given to you by a third party (without
-your or their breach of the Terms).
-
-## 8. Disclaimers
-
-Nothing in the Terms restricts any rights that cannot be restricted under
-applicable law or limits Google's responsibilities except as allowed by
-applicable law.
-
-**AlphaFold 3 and Output are provided on an "as is" basis, without warranties or
-conditions of any kind, either express or implied, including any warranties or
-conditions of title, non-infringement, merchantability, or fitness for a
-particular purpose. You are solely responsible for determining the
-appropriateness of using AlphaFold 3, or using or distributing Output, and
-assume any and all risks associated with such use or distribution and your
-exercise of rights and obligations under these Terms. You and anyone you share
-Output with are solely responsible for these and their subsequent uses.**
-
-**Output are predictions with varying levels of confidence and should be
-interpreted carefully. Use discretion before relying on, publishing, downloading
-or otherwise using AlphaFold 3.**
-
-**AlphaFold 3 and Outputs are for theoretical modeling only. They are not
-intended, validated, or approved for clinical use. You should not use AlphaFold
-3 or Output for clinical purposes or rely on them for medical or other
-professional advice. Any content regarding those topics is provided for
-informational purposes only and is not a substitute for advice from a qualified
-professional.**
-
-## 9. Liabilities
-
-To the extent allowed by applicable law, you will indemnify Google and its
-directors, officers, employees, and contractors for any third-party legal
-proceedings (including actions by government authorities) arising out of or
-relating to your unlawful use of the AlphaFold 3 Assets or violation of the
-Terms. This indemnity covers any liability or expense arising from claims,
-losses, damages, judgments, fines, litigation costs, and legal fees, except to
-the extent a liability or expense is caused by Google's breach, negligence, or
-willful misconduct. If you are legally exempt from certain responsibilities,
-including indemnification, then those responsibilities do not apply to you under
-the Terms.
-
-In no circumstances will Google be responsible for any indirect, special,
-incidental, exemplary, consequential, or punitive damages, or lost profits of
-any kind in connection with the Terms or the AlphaFold 3 Assets, even if Google
-has been advised of the possibility of such damages. Google's total aggregate
-liability for all claims arising out of or in connection with the Terms or the
-AlphaFold 3 Assets, including for its own negligence, is limited to $500.
-
-## 10. Miscellaneous
-
-By law, you have certain rights that cannot be limited by a contract like the
-Terms. The Terms are in no way intended to restrict those rights.
-
-The Terms are our entire agreement relating to your use of the AlphaFold 3
-Assets and supersede any prior or contemporaneous agreements on that subject.
-
-If it turns out that a particular provision of the Terms is not enforceable, the
-balance of the Terms will remain in full force and effect.
-
-## 11. Disputes
-
-California law will govern all disputes arising out of or relating to the Terms
-or in connection to the AlphaFold 3 Assets. These disputes will be resolved
-exclusively in the federal or state courts of Santa Clara County, California,
-USA and you and Google consent to personal jurisdiction in those courts. To the
-extent that applicable local law prevents certain disputes from being resolved
-in a California court, you and Google can file those disputes in your local
-courts. If applicable local law prevents your local court from applying
-California law to resolve these disputes, then these disputes will be governed
-by the applicable local laws of your country, state, or other place of
-residence. If you are using the AlphaFold 3 Assets on behalf of a government
-organization other than US federal government organizations (where the foregoing
-provisions shall apply to the extent permitted by federal law), these Terms will
-be silent regarding governing law and courts.
-
-Given the nature of scientific research, it may take some time for any breach of
-the Terms to become apparent. To protect you, Google and the AlphaFold 3 Assets,
-to the extent allowed by applicable law you agree that:
-
-1.  any legal claims relating to the Terms or the AlphaFold 3 Assets can be
-    initiated until the later of:
-    1.  the cut-off date under applicable law for bringing the legal claim; or
-    2.  two years from the date you or Google (as applicable) became aware, or
-        should reasonably have become aware, of the facts giving rise to that
-        claim; and
-2.  you will not argue limitation, time bar, delay, waiver, or the like in an
-    attempt to bar an action filed within that time period, and neither will
-    Google.
-
-All rights not specifically and expressly granted to you by the Terms are
-reserved to Google. No delay, act or omission by Google in exercising any right
-or remedy will be deemed a waiver of any breach of the Terms and Google
-expressly reserves any and all rights and remedies available under the Terms or
-at law or in equity or otherwise, including the remedy of injunctive relief
-against any threatened or actual breach of the Terms without the necessity of
-proving actual damages.
diff --git a/dev-requirements.txt b/dev-requirements.txt
deleted file mode 100644
index aa24d4202735594f6eb8a202f6f9ca1d3674f848..0000000000000000000000000000000000000000
--- a/dev-requirements.txt
+++ /dev/null
@@ -1,553 +0,0 @@
-#
-# This file is autogenerated by pip-compile with Python 3.11
-# by the following command:
-#
-#    pip-compile --extra=dev --generate-hashes --output-file=dev-requirements.txt pyproject.toml
-#
-absl-py==2.1.0 \
-    --hash=sha256:526a04eadab8b4ee719ce68f204172ead1027549089702d99b9059f129ff1308 \
-    --hash=sha256:7820790efbb316739cde8b4e19357243fc3608a152024288513dd968d7d959ff
-    # via
-    #   alphafold3 (pyproject.toml)
-    #   chex
-    #   dm-haiku
-    #   jax-triton
-chex==0.1.87 \
-    --hash=sha256:0096d89cc8d898bb521ef4bfbf5c24549022b0e5b301f529ab57238896fe6c5d \
-    --hash=sha256:ce536475661fd96d21be0c1728ecdbedd03f8ff950c662dfc338c92ea782cb16
-    # via alphafold3 (pyproject.toml)
-dm-haiku==0.0.13 \
-    --hash=sha256:029bb91b5b1edb0d3fe23304d3bf12a545ea6e485041f7f5d8c8d85ebcf6e17d \
-    --hash=sha256:ee9562c68a059f146ad07f555ca591cb8c11ef751afecc38353863562bd23f43
-    # via alphafold3 (pyproject.toml)
-dm-tree==0.1.8 \
-    --hash=sha256:054b461f8176f4bce7a21f7b1870f873a1ced3bdbe1282c816c550bb43c71fa6 \
-    --hash=sha256:09964470f76a5201aff2e8f9b26842976de7889300676f927930f6285e256760 \
-    --hash=sha256:0d3172394079a86c3a759179c65f64c48d1a42b89495fcf38976d11cc3bb952c \
-    --hash=sha256:0e9620ccf06393eb6b613b5e366469304622d4ea96ae6540b28a33840e6c89cf \
-    --hash=sha256:0fcaabbb14e7980377439e7140bd05552739ca5e515ecb3119f234acee4b9430 \
-    --hash=sha256:1607ce49aa42f010d1e5e616d92ce899d66835d4d8bea49679582435285515de \
-    --hash=sha256:181c35521d480d0365f39300542cb6cd7fd2b77351bb43d7acfda15aef63b317 \
-    --hash=sha256:1d7c26e431fc93cc7e0cba867eb000db6a05f6f2b25af11ac4e9dada88fc5bca \
-    --hash=sha256:1fe962015b2fe1282892b28ebe962faed53c7f98d942da9a4625cbf27baef913 \
-    --hash=sha256:250b692fb75f45f02e2f58fbef9ab338904ef334b90557565621fa251df267cf \
-    --hash=sha256:2869228d9c619074de501a3c10dc7f07c75422f8fab36ecdcb859b6f1b1ec3ef \
-    --hash=sha256:28c52cbf4f8b3dbd0beaedf44f69fa85eec5e9dede612e08035e06ada6ec9426 \
-    --hash=sha256:2f7915660f59c09068e428613c480150180df1060561fd0d1470684ae7007bd1 \
-    --hash=sha256:343a4a4ebaa127451ff971254a4be4084eb4bdc0b2513c32b46f6f728fd03f9e \
-    --hash=sha256:35cc164a79336bfcfafb47e5f297898359123bbd3330c1967f0c4994f9cf9f60 \
-    --hash=sha256:378cc8ad93c5fe3590f405a309980721f021c790ca1bdf9b15bb1d59daec57f5 \
-    --hash=sha256:39070ba268c0491af9fe7a58644d99e8b4f2cde6e5884ba3380bddc84ed43d5f \
-    --hash=sha256:435227cf3c5dc63f4de054cf3d00183790bd9ead4c3623138c74dde7f67f521b \
-    --hash=sha256:5483dca4d7eb1a0d65fe86d3b6a53ae717face83c1f17e0887b1a4a64ae5c410 \
-    --hash=sha256:694c3654cfd2a81552c08ec66bb5c4a3d48fa292b9a181880fb081c36c5b9134 \
-    --hash=sha256:75c5d528bb992981c20793b6b453e91560784215dffb8a5440ba999753c14ceb \
-    --hash=sha256:803bfc53b4659f447ac694dbd04235f94a73ef7c1fd1e0df7c84ac41e0bc963b \
-    --hash=sha256:81fce77f22a302d7a5968aebdf4efafef4def7ce96528719a354e6990dcd49c7 \
-    --hash=sha256:83b7764de0d855338abefc6e3ee9fe40d301668310aa3baea3f778ff051f4393 \
-    --hash=sha256:8c60a7eadab64c2278861f56bca320b2720f163dca9d7558103c3b77f2416571 \
-    --hash=sha256:8ed3564abed97c806db122c2d3e1a2b64c74a63debe9903aad795167cc301368 \
-    --hash=sha256:94d3f0826311f45ee19b75f5b48c99466e4218a0489e81c0f0167bda50cacf22 \
-    --hash=sha256:96a548a406a6fb15fe58f6a30a57ff2f2aafbf25f05afab00c8f5e5977b6c715 \
-    --hash=sha256:a5d819c38c03f0bb5b3b3703c60e4b170355a0fc6b5819325bf3d4ceb3ae7e80 \
-    --hash=sha256:ad16ceba90a56ec47cf45b21856d14962ac314787975ef786efb5e6e9ca75ec7 \
-    --hash=sha256:af4b3d372f2477dcd89a6e717e4a575ca35ccc20cc4454a8a4b6f8838a00672d \
-    --hash=sha256:b095ba4f8ca1ba19350fd53cf1f8f3eb0bd406aa28af64a6dfc86707b32a810a \
-    --hash=sha256:b9bd9b9ccb59409d33d51d84b7668010c04c2af7d4a371632874c1ca356cff3d \
-    --hash=sha256:b9f89a454e98806b44fe9d40ec9eee61f848388f7e79ac2371a55679bd5a3ac6 \
-    --hash=sha256:bb2d109f42190225112da899b9f3d46d0d5f26aef501c61e43529fe9322530b5 \
-    --hash=sha256:c0a94aba18a35457a1b5cd716fd7b46c5dafdc4cf7869b4bae665b91c4682a8e \
-    --hash=sha256:c5c8c12e3fda754ef6af94161bacdaeda816d941995fac415d6855c6c386af68 \
-    --hash=sha256:d1612fcaecd79023dbc6a6ae48d51a80beb5c385d6f3f6d71688e57bc8d07de8 \
-    --hash=sha256:d16e1f2a073604cfcc09f7131ae8d534674f43c3aef4c25742eae295bc60d04f \
-    --hash=sha256:d20f2faa3672b52e5013f4077117bfb99c4cfc0b445d3bde1584c34032b57436 \
-    --hash=sha256:d40fa4106ca6edc66760246a08f500ec0c85ef55c762fb4a363f6ee739ba02ee \
-    --hash=sha256:de287fabc464b8734be251e46e06aa9aa1001f34198da2b6ce07bd197172b9cb \
-    --hash=sha256:e4d714371bb08839e4e5e29024fc95832d9affe129825ef38836b143028bd144 \
-    --hash=sha256:ea9e59e0451e7d29aece402d9f908f2e2a80922bcde2ebfd5dcb07750fcbfee8 \
-    --hash=sha256:f7ac31b9aecccb2c6e1ab29706f6ded3eba0c2c69c770322c9c685929c3d6afb \
-    --hash=sha256:fa42a605d099ee7d41ba2b5fb75e21423951fd26e5d50583a00471238fb3021d
-    # via alphafold3 (pyproject.toml)
-filelock==3.16.1 \
-    --hash=sha256:2082e5703d51fbf98ea75855d9d5527e33d8ff23099bec374a134febee6946b0 \
-    --hash=sha256:c249fbfcd5db47e5e2d6d62198e565475ee65e4831e2561c8e313fa7eb961435
-    # via triton
-jax[cuda12]==0.4.34 \
-    --hash=sha256:44196854f40c5f9cea3142824b9f1051f85afc3fcf7593ec5479fc8db01c58db \
-    --hash=sha256:b957ca1fc91f7343f91a186af9f19c7f342c946f95a8c11c7f1e5cdfe2e58d9e
-    # via
-    #   alphafold3 (pyproject.toml)
-    #   chex
-    #   jax-triton
-jax-cuda12-pjrt==0.4.34 \
-    --hash=sha256:0c7cc98f962cc7fc8e0a5ea6331b42a0cee516f202f1c3019f6aa5cd9530cca0 \
-    --hash=sha256:6247459827550e7d11480f5707d7d2843cbf57bcda5d833565493456075cd143
-    # via jax-cuda12-plugin
-jax-cuda12-plugin[with-cuda]==0.4.34 \
-    --hash=sha256:15fa8ff678fad34df424e01f1a9151abc966700670d3b22f52b87a2740028602 \
-    --hash=sha256:1b037a408b9d9de59367c9513a9445b705da526657a0c4d593e84234312261e7 \
-    --hash=sha256:b2099a4407225122ff76f6dcdc8dbdae47e6f29343bdfd21460ad337dc34a209 \
-    --hash=sha256:d035ea72bd9b8a65a6ea621bca1affdd33127fa3a52e7bded7692670d360adab \
-    --hash=sha256:dadb507949b70ba148567219bf0e7752eb63baec551f7ec860f8fcbb4ee48c48 \
-    --hash=sha256:db988b7ba5063483a936ddbf162f04d1b4412e0d64340f11788c7bbc877e8a43 \
-    --hash=sha256:e23721d1654b311b47cd6b35768520284bd036f8c7e6b11600143258b4a0409a \
-    --hash=sha256:fb72bda44ae9f8a1e5ee9c5f82e2d273abe019874b0110b5c2d8395f1fe966b4
-    # via jax
-jax-triton==0.2.0 \
-    --hash=sha256:6db5f6147327f2462c35becab612d415cf9ee70c96e43020c3c7ea873eb8576e \
-    --hash=sha256:ed564a5ffb9e404557dc8d296e7eb30e501da5a4d7b03408acd0837c1c618c21
-    # via alphafold3 (pyproject.toml)
-jaxlib==0.4.34 \
-    --hash=sha256:096f0ca309d41fa692a9d1f2f9baab1c5c8ca0749876ebb3f748e738a27c7ff4 \
-    --hash=sha256:133070d4fec5525ffea4dc72956398c1cf647a04dcb37f8a935ee82af78d9965 \
-    --hash=sha256:1a30771d85fa77f9ab8f18e63240f455ab3a3f87660ed7b8d5eea6ceecbe5c1e \
-    --hash=sha256:3bcfa639ca3cfaf86c8ceebd5fc0d47300fd98a078014a1d0cc03133e1523d5f \
-    --hash=sha256:3e60bc826933082e99b19b87c21818a8d26fcdb01f418d47cedff554746fd6cc \
-    --hash=sha256:45d719a2ce0ebf21255a277b71d756f3609b7b5be70cddc5d88fd58c35219de0 \
-    --hash=sha256:48272e9034ff868d4328cf0055a07882fd2be93f59dfb6283af7de491f9d1290 \
-    --hash=sha256:571ef03259835458111596a71a2f4a6fabf4ec34595df4cea555035362ac5bf0 \
-    --hash=sha256:6b43a974c5d91a19912d138f2658dd8dbb7d30dcdff5c961d896c673e872b611 \
-    --hash=sha256:72e22e99a5dc890a64443c3fc12f13f20091f578c405a76de077ba42b4c62cd7 \
-    --hash=sha256:7be673a876ebd1aef440fb7e3ebaf99a91abeb550c9728c644b7d7c7b5d7c108 \
-    --hash=sha256:87f25a477cd279840e53718403f97092eba0e8a945fcab47bcf435b6f9119dda \
-    --hash=sha256:8ee3f93836e53c86556ccd9449a4ea43516ee05184d031a71dd692e81259f7d9 \
-    --hash=sha256:901cb4040ed24eae40071d8114ea8d10dff436277fa74a1a5b9e7206f641151c \
-    --hash=sha256:b0001c8f0e2b1c7bc99e4f314b524a340d25653505c1a1484d4041a9d3617f6f \
-    --hash=sha256:b7a212a3cb5c6acc201c32ae4f4b5f5a9ac09457fbb77ba8db5ce7e7d4adc214 \
-    --hash=sha256:c303f5acaf6c56ce5ff133a923c9b6247bdebedde15bd2c893c24be4d8f71306 \
-    --hash=sha256:c7b3e724a30426a856070aba0192b5d199e95b4411070e7ad96ad8b196877b10 \
-    --hash=sha256:c9d3adcae43a33aad4332be9c2aedc5ef751d1e755f917a5afb30c7872eacaa8 \
-    --hash=sha256:d840e64b85f8865404d6d225b9bb340e158df1457152a361b05680e24792b232
-    # via
-    #   chex
-    #   jax
-jaxtyping==0.2.34 \
-    --hash=sha256:2f81fb6d1586e497a6ea2d28c06dcab37b108a096cbb36ea3fe4fa2e1c1f32e5 \
-    --hash=sha256:eed9a3458ec8726c84ea5457ebde53c964f65d2c22c0ec40d0555ae3fed5bbaf
-    # via alphafold3 (pyproject.toml)
-jmp==0.0.4 \
-    --hash=sha256:5dfeb0fd7c7a9f72a70fff0aab9d0cbfae32a809c02f4037ff3485ceb33e1730 \
-    --hash=sha256:6aa7adbddf2bd574b28c7faf6e81a735eb11f53386447896909c6968dc36807d
-    # via dm-haiku
-ml-dtypes==0.5.0 \
-    --hash=sha256:099e09edd54e676903b4538f3815b5ab96f5b119690514602d96bfdb67172cbe \
-    --hash=sha256:2e7534392682c3098bc7341648c650864207169c654aed83143d7a19c67ae06f \
-    --hash=sha256:3e7d3a380fe73a63c884f06136f8baa7a5249cc8e9fdec677997dd78549f8128 \
-    --hash=sha256:54415257f00eb44fbcc807454efac3356f75644f1cbfc2d4e5522a72ae1dacab \
-    --hash=sha256:5f2b59233a0dbb6a560b3137ed6125433289ccba2f8d9c3695a52423a369ed15 \
-    --hash=sha256:60275f2b51b56834e840c4809fca840565f9bf8e9a73f6d8c94f5b5935701215 \
-    --hash=sha256:76942f6aeb5c40766d5ea62386daa4148e6a54322aaf5b53eae9e7553240222f \
-    --hash=sha256:7ee9c320bb0f9ffdf9f6fa6a696ef2e005d1f66438d6f1c1457338e00a02e8cf \
-    --hash=sha256:8c32138975797e681eb175996d64356bcfa124bdbb6a70460b9768c2b35a6fa4 \
-    --hash=sha256:968fede07d1f9b926a63df97d25ac656cac1a57ebd33701734eaf704bc55d8d8 \
-    --hash=sha256:a03fc861b86cc586728e3d093ba37f0cc05e65330c3ebd7688e7bae8290f8859 \
-    --hash=sha256:a38df8df61194aeaae1ab7579075779b4ad32cd1cffd012c28be227fa7f2a70a \
-    --hash=sha256:a988bac6572630e1e9c2edd9b1277b4eefd1c86209e52b0d061b775ac33902ff \
-    --hash=sha256:ab046f2ff789b1f11b2491909682c5d089934835f9a760fafc180e47dcb676b8 \
-    --hash=sha256:afa08343069874a30812871d639f9c02b4158ace065601406a493a8511180c02 \
-    --hash=sha256:c7a9152f5876fef565516aa5dd1dccd6fc298a5891b2467973905103eb5c7856 \
-    --hash=sha256:cb5cc7b25acabd384f75bbd78892d0c724943f3e2e1986254665a1aa10982e07 \
-    --hash=sha256:d3b3db9990c3840986a0e70524e122cfa32b91139c3653df76121ba7776e015f \
-    --hash=sha256:d4b1a70a3e5219790d6b55b9507606fc4e02911d1497d16c18dd721eb7efe7d0 \
-    --hash=sha256:dc74fd9995513d33eac63d64e436240f5494ec74d522a9f0920194942fc3d2d7 \
-    --hash=sha256:e04fde367b2fe901b1d47234426fe8819909bd1dd862a5adb630f27789c20599
-    # via
-    #   jax
-    #   jaxlib
-numpy==2.1.3 \
-    --hash=sha256:016d0f6f5e77b0f0d45d77387ffa4bb89816b57c835580c3ce8e099ef830befe \
-    --hash=sha256:02135ade8b8a84011cbb67dc44e07c58f28575cf9ecf8ab304e51c05528c19f0 \
-    --hash=sha256:08788d27a5fd867a663f6fc753fd7c3ad7e92747efc73c53bca2f19f8bc06f48 \
-    --hash=sha256:0d30c543f02e84e92c4b1f415b7c6b5326cbe45ee7882b6b77db7195fb971e3a \
-    --hash=sha256:0fa14563cc46422e99daef53d725d0c326e99e468a9320a240affffe87852564 \
-    --hash=sha256:13138eadd4f4da03074851a698ffa7e405f41a0845a6b1ad135b81596e4e9958 \
-    --hash=sha256:14e253bd43fc6b37af4921b10f6add6925878a42a0c5fe83daee390bca80bc17 \
-    --hash=sha256:15cb89f39fa6d0bdfb600ea24b250e5f1a3df23f901f51c8debaa6a5d122b2f0 \
-    --hash=sha256:17ee83a1f4fef3c94d16dc1802b998668b5419362c8a4f4e8a491de1b41cc3ee \
-    --hash=sha256:2312b2aa89e1f43ecea6da6ea9a810d06aae08321609d8dc0d0eda6d946a541b \
-    --hash=sha256:2564fbdf2b99b3f815f2107c1bbc93e2de8ee655a69c261363a1172a79a257d4 \
-    --hash=sha256:3522b0dfe983a575e6a9ab3a4a4dfe156c3e428468ff08ce582b9bb6bd1d71d4 \
-    --hash=sha256:4394bc0dbd074b7f9b52024832d16e019decebf86caf909d94f6b3f77a8ee3b6 \
-    --hash=sha256:45966d859916ad02b779706bb43b954281db43e185015df6eb3323120188f9e4 \
-    --hash=sha256:4d1167c53b93f1f5d8a139a742b3c6f4d429b54e74e6b57d0eff40045187b15d \
-    --hash=sha256:4f2015dfe437dfebbfce7c85c7b53d81ba49e71ba7eadbf1df40c915af75979f \
-    --hash=sha256:50ca6aba6e163363f132b5c101ba078b8cbd3fa92c7865fd7d4d62d9779ac29f \
-    --hash=sha256:50d18c4358a0a8a53f12a8ba9d772ab2d460321e6a93d6064fc22443d189853f \
-    --hash=sha256:5641516794ca9e5f8a4d17bb45446998c6554704d888f86df9b200e66bdcce56 \
-    --hash=sha256:576a1c1d25e9e02ed7fa5477f30a127fe56debd53b8d2c89d5578f9857d03ca9 \
-    --hash=sha256:6a4825252fcc430a182ac4dee5a505053d262c807f8a924603d411f6718b88fd \
-    --hash=sha256:72dcc4a35a8515d83e76b58fdf8113a5c969ccd505c8a946759b24e3182d1f23 \
-    --hash=sha256:747641635d3d44bcb380d950679462fae44f54b131be347d5ec2bce47d3df9ed \
-    --hash=sha256:762479be47a4863e261a840e8e01608d124ee1361e48b96916f38b119cfda04a \
-    --hash=sha256:78574ac2d1a4a02421f25da9559850d59457bac82f2b8d7a44fe83a64f770098 \
-    --hash=sha256:825656d0743699c529c5943554d223c021ff0494ff1442152ce887ef4f7561a1 \
-    --hash=sha256:8637dcd2caa676e475503d1f8fdb327bc495554e10838019651b76d17b98e512 \
-    --hash=sha256:96fe52fcdb9345b7cd82ecd34547fca4321f7656d500eca497eb7ea5a926692f \
-    --hash=sha256:973faafebaae4c0aaa1a1ca1ce02434554d67e628b8d805e61f874b84e136b09 \
-    --hash=sha256:996bb9399059c5b82f76b53ff8bb686069c05acc94656bb259b1d63d04a9506f \
-    --hash=sha256:a38c19106902bb19351b83802531fea19dee18e5b37b36454f27f11ff956f7fc \
-    --hash=sha256:a6b46587b14b888e95e4a24d7b13ae91fa22386c199ee7b418f449032b2fa3b8 \
-    --hash=sha256:a9f7f672a3388133335589cfca93ed468509cb7b93ba3105fce780d04a6576a0 \
-    --hash=sha256:aa08e04e08aaf974d4458def539dece0d28146d866a39da5639596f4921fd761 \
-    --hash=sha256:b0df3635b9c8ef48bd3be5f862cf71b0a4716fa0e702155c45067c6b711ddcef \
-    --hash=sha256:b47fbb433d3260adcd51eb54f92a2ffbc90a4595f8970ee00e064c644ac788f5 \
-    --hash=sha256:baed7e8d7481bfe0874b566850cb0b85243e982388b7b23348c6db2ee2b2ae8e \
-    --hash=sha256:bc6f24b3d1ecc1eebfbf5d6051faa49af40b03be1aaa781ebdadcbc090b4539b \
-    --hash=sha256:c006b607a865b07cd981ccb218a04fc86b600411d83d6fc261357f1c0966755d \
-    --hash=sha256:c181ba05ce8299c7aa3125c27b9c2167bca4a4445b7ce73d5febc411ca692e43 \
-    --hash=sha256:c7662f0e3673fe4e832fe07b65c50342ea27d989f92c80355658c7f888fcc83c \
-    --hash=sha256:c80e4a09b3d95b4e1cac08643f1152fa71a0a821a2d4277334c88d54b2219a41 \
-    --hash=sha256:c894b4305373b9c5576d7a12b473702afdf48ce5369c074ba304cc5ad8730dff \
-    --hash=sha256:d7aac50327da5d208db2eec22eb11e491e3fe13d22653dce51b0f4109101b408 \
-    --hash=sha256:d89dd2b6da69c4fff5e39c28a382199ddedc3a5be5390115608345dec660b9e2 \
-    --hash=sha256:d9beb777a78c331580705326d2367488d5bc473b49a9bc3036c154832520aca9 \
-    --hash=sha256:dc258a761a16daa791081d026f0ed4399b582712e6fc887a95af09df10c5ca57 \
-    --hash=sha256:e14e26956e6f1696070788252dcdff11b4aca4c3e8bd166e0df1bb8f315a67cb \
-    --hash=sha256:e6988e90fcf617da2b5c78902fe8e668361b43b4fe26dbf2d7b0f8034d4cafb9 \
-    --hash=sha256:e711e02f49e176a01d0349d82cb5f05ba4db7d5e7e0defd026328e5cfb3226d3 \
-    --hash=sha256:ea4dedd6e394a9c180b33c2c872b92f7ce0f8e7ad93e9585312b0c5a04777a4a \
-    --hash=sha256:ecc76a9ba2911d8d37ac01de72834d8849e55473457558e12995f4cd53e778e0 \
-    --hash=sha256:f55ba01150f52b1027829b50d70ef1dafd9821ea82905b63936668403c3b471e \
-    --hash=sha256:f653490b33e9c3a4c1c01d41bc2aef08f9475af51146e4a7710c450cf9761598 \
-    --hash=sha256:fa2d1337dc61c8dc417fbccf20f6d1e139896a30721b7f1e832b2bb6ef4eb6c4
-    # via
-    #   alphafold3 (pyproject.toml)
-    #   chex
-    #   dm-haiku
-    #   jax
-    #   jaxlib
-    #   jmp
-    #   ml-dtypes
-    #   rdkit
-    #   scipy
-nvidia-cublas-cu12==12.6.3.3 \
-    --hash=sha256:e1f70bee38b964eac1907293b336bceb24498a4243e61eaf91a52977c59aebc4 \
-    --hash=sha256:e531199ca4f1f764fb45bc1dde49a006f6765033f9c89c737e4553b9502ca1f5 \
-    --hash=sha256:f33fb68e101d99470c82d17f92a0dd9f74de2a21685c217f4716cdd63b1316eb
-    # via
-    #   jax-cuda12-plugin
-    #   nvidia-cudnn-cu12
-    #   nvidia-cusolver-cu12
-nvidia-cuda-cupti-cu12==12.6.80 \
-    --hash=sha256:358b4a1d35370353d52e12f0a7d1769fc01ff74a191689d3870b2123156184c4 \
-    --hash=sha256:a3eff6cdfcc6a4c35db968a06fcadb061cbc7d6dde548609a941ff8701b98b73 \
-    --hash=sha256:bbe6ae76e83ce5251b56e8c8e61a964f757175682bbad058b170b136266ab00a
-    # via jax-cuda12-plugin
-nvidia-cuda-nvcc-cu12==12.6.77 \
-    --hash=sha256:26e118b4dae4ebd316ab6f5ee3f3c4cb929f8265f717a8e016ba57e254c0b4f1 \
-    --hash=sha256:9a2aad43b8f4e4be9c237ece04f64450df77871eeebffad5a5a872714a97ca77 \
-    --hash=sha256:b66bb5dd6b8ae62262586691977d3b4a425e91db61b4b9bc2f6b42bcd4154b96
-    # via jax-cuda12-plugin
-nvidia-cuda-runtime-cu12==12.6.77 \
-    --hash=sha256:86c58044c824bf3c173c49a2dbc7a6c8b53cb4e4dca50068be0bf64e9dab3f7f \
-    --hash=sha256:a84d15d5e1da416dd4774cb42edf5e954a3e60cc945698dc1d5be02321c44dc8 \
-    --hash=sha256:d461264ecb429c84c8879a7153499ddc7b19b5f8d84c204307491989a365588e
-    # via jax-cuda12-plugin
-nvidia-cudnn-cu12==9.5.1.17 \
-    --hash=sha256:30ac3869f6db17d170e0e556dd6cc5eee02647abc31ca856634d5a40f82c15b2 \
-    --hash=sha256:9fd4584468533c61873e5fda8ca41bac3a38bcb2d12350830c69b0a96a7e4def \
-    --hash=sha256:d7af0f8a4f3b4b9dbb3122f2ef553b45694ed9c384d5a75bab197b8eefb79ab8
-    # via jax-cuda12-plugin
-nvidia-cufft-cu12==11.3.0.4 \
-    --hash=sha256:6048ebddfb90d09d2707efb1fd78d4e3a77cb3ae4dc60e19aab6be0ece2ae464 \
-    --hash=sha256:768160ac89f6f7b459bee747e8d175dbf53619cfe74b2a5636264163138013ca \
-    --hash=sha256:8510990de9f96c803a051822618d42bf6cb8f069ff3f48d93a8486efdacb48fb
-    # via jax-cuda12-plugin
-nvidia-cusolver-cu12==11.7.1.2 \
-    --hash=sha256:0ce237ef60acde1efc457335a2ddadfd7610b892d94efee7b776c64bb1cac9e0 \
-    --hash=sha256:6813f9d8073f555444a8705f3ab0296d3e1cb37a16d694c5fc8b862a0d8706d7 \
-    --hash=sha256:6cf28f17f64107a0c4d7802be5ff5537b2130bfc112f25d5a30df227058ca0e6
-    # via jax-cuda12-plugin
-nvidia-cusparse-cu12==12.5.4.2 \
-    --hash=sha256:23749a6571191a215cb74d1cdbff4a86e7b19f1200c071b3fcf844a5bea23a2f \
-    --hash=sha256:4acb8c08855a26d737398cba8fb6f8f5045d93f82612b4cfd84645a2332ccf20 \
-    --hash=sha256:7aa32fa5470cf754f72d1116c7cbc300b4e638d3ae5304cfa4a638a5b87161b1
-    # via
-    #   jax-cuda12-plugin
-    #   nvidia-cusolver-cu12
-nvidia-nccl-cu12==2.23.4 \
-    --hash=sha256:aa946c8327e22ced28e7cef508a334673abc42064ec85f02d005ba1785ea4cec \
-    --hash=sha256:b097258d9aab2fa9f686e33c6fe40ae57b27df60cedbd15d139701bb5509e0c1
-    # via jax-cuda12-plugin
-nvidia-nvjitlink-cu12==12.6.77 \
-    --hash=sha256:3bf10d85bb1801e9c894c6e197e44dd137d2a0a9e43f8450e9ad13f2df0dd52d \
-    --hash=sha256:410718cd44962bed862a31dd0318620f6f9a8b28a6291967bcfcb446a6516771 \
-    --hash=sha256:9ae346d16203ae4ea513be416495167a0101d33d2d14935aa9c1829a3fb45142
-    # via
-    #   jax-cuda12-plugin
-    #   nvidia-cufft-cu12
-    #   nvidia-cusolver-cu12
-    #   nvidia-cusparse-cu12
-opt-einsum==3.4.0 \
-    --hash=sha256:69bb92469f86a1565195ece4ac0323943e83477171b91d24c35afe028a90d7cd \
-    --hash=sha256:96ca72f1b886d148241348783498194c577fa30a8faac108586b14f1ba4473ac
-    # via jax
-pillow==11.0.0 \
-    --hash=sha256:00177a63030d612148e659b55ba99527803288cea7c75fb05766ab7981a8c1b7 \
-    --hash=sha256:006bcdd307cc47ba43e924099a038cbf9591062e6c50e570819743f5607404f5 \
-    --hash=sha256:084a07ef0821cfe4858fe86652fffac8e187b6ae677e9906e192aafcc1b69903 \
-    --hash=sha256:0ae08bd8ffc41aebf578c2af2f9d8749d91f448b3bfd41d7d9ff573d74f2a6b2 \
-    --hash=sha256:0e038b0745997c7dcaae350d35859c9715c71e92ffb7e0f4a8e8a16732150f38 \
-    --hash=sha256:1187739620f2b365de756ce086fdb3604573337cc28a0d3ac4a01ab6b2d2a6d2 \
-    --hash=sha256:16095692a253047fe3ec028e951fa4221a1f3ed3d80c397e83541a3037ff67c9 \
-    --hash=sha256:1a61b54f87ab5786b8479f81c4b11f4d61702830354520837f8cc791ebba0f5f \
-    --hash=sha256:1c1d72714f429a521d8d2d018badc42414c3077eb187a59579f28e4270b4b0fc \
-    --hash=sha256:1e2688958a840c822279fda0086fec1fdab2f95bf2b717b66871c4ad9859d7e8 \
-    --hash=sha256:20ec184af98a121fb2da42642dea8a29ec80fc3efbaefb86d8fdd2606619045d \
-    --hash=sha256:21a0d3b115009ebb8ac3d2ebec5c2982cc693da935f4ab7bb5c8ebe2f47d36f2 \
-    --hash=sha256:224aaa38177597bb179f3ec87eeefcce8e4f85e608025e9cfac60de237ba6316 \
-    --hash=sha256:2679d2258b7f1192b378e2893a8a0a0ca472234d4c2c0e6bdd3380e8dfa21b6a \
-    --hash=sha256:27a7860107500d813fcd203b4ea19b04babe79448268403172782754870dac25 \
-    --hash=sha256:290f2cc809f9da7d6d622550bbf4c1e57518212da51b6a30fe8e0a270a5b78bd \
-    --hash=sha256:2e46773dc9f35a1dd28bd6981332fd7f27bec001a918a72a79b4133cf5291dba \
-    --hash=sha256:3107c66e43bda25359d5ef446f59c497de2b5ed4c7fdba0894f8d6cf3822dafc \
-    --hash=sha256:375b8dd15a1f5d2feafff536d47e22f69625c1aa92f12b339ec0b2ca40263273 \
-    --hash=sha256:45c566eb10b8967d71bf1ab8e4a525e5a93519e29ea071459ce517f6b903d7fa \
-    --hash=sha256:499c3a1b0d6fc8213519e193796eb1a86a1be4b1877d678b30f83fd979811d1a \
-    --hash=sha256:4ad70c4214f67d7466bea6a08061eba35c01b1b89eaa098040a35272a8efb22b \
-    --hash=sha256:4b60c9520f7207aaf2e1d94de026682fc227806c6e1f55bba7606d1c94dd623a \
-    --hash=sha256:5178952973e588b3f1360868847334e9e3bf49d19e169bbbdfaf8398002419ae \
-    --hash=sha256:52a2d8323a465f84faaba5236567d212c3668f2ab53e1c74c15583cf507a0291 \
-    --hash=sha256:598b4e238f13276e0008299bd2482003f48158e2b11826862b1eb2ad7c768b97 \
-    --hash=sha256:5bd2d3bdb846d757055910f0a59792d33b555800813c3b39ada1829c372ccb06 \
-    --hash=sha256:5c39ed17edea3bc69c743a8dd3e9853b7509625c2462532e62baa0732163a904 \
-    --hash=sha256:5d203af30149ae339ad1b4f710d9844ed8796e97fda23ffbc4cc472968a47d0b \
-    --hash=sha256:5ddbfd761ee00c12ee1be86c9c0683ecf5bb14c9772ddbd782085779a63dd55b \
-    --hash=sha256:607bbe123c74e272e381a8d1957083a9463401f7bd01287f50521ecb05a313f8 \
-    --hash=sha256:61b887f9ddba63ddf62fd02a3ba7add935d053b6dd7d58998c630e6dbade8527 \
-    --hash=sha256:6619654954dc4936fcff82db8eb6401d3159ec6be81e33c6000dfd76ae189947 \
-    --hash=sha256:674629ff60030d144b7bca2b8330225a9b11c482ed408813924619c6f302fdbb \
-    --hash=sha256:6ec0d5af64f2e3d64a165f490d96368bb5dea8b8f9ad04487f9ab60dc4bb6003 \
-    --hash=sha256:6f4dba50cfa56f910241eb7f883c20f1e7b1d8f7d91c750cd0b318bad443f4d5 \
-    --hash=sha256:70fbbdacd1d271b77b7721fe3cdd2d537bbbd75d29e6300c672ec6bb38d9672f \
-    --hash=sha256:72bacbaf24ac003fea9bff9837d1eedb6088758d41e100c1552930151f677739 \
-    --hash=sha256:7326a1787e3c7b0429659e0a944725e1b03eeaa10edd945a86dead1913383944 \
-    --hash=sha256:73853108f56df97baf2bb8b522f3578221e56f646ba345a372c78326710d3830 \
-    --hash=sha256:73e3a0200cdda995c7e43dd47436c1548f87a30bb27fb871f352a22ab8dcf45f \
-    --hash=sha256:75acbbeb05b86bc53cbe7b7e6fe00fbcf82ad7c684b3ad82e3d711da9ba287d3 \
-    --hash=sha256:8069c5179902dcdce0be9bfc8235347fdbac249d23bd90514b7a47a72d9fecf4 \
-    --hash=sha256:846e193e103b41e984ac921b335df59195356ce3f71dcfd155aa79c603873b84 \
-    --hash=sha256:8594f42df584e5b4bb9281799698403f7af489fba84c34d53d1c4bfb71b7c4e7 \
-    --hash=sha256:86510e3f5eca0ab87429dd77fafc04693195eec7fd6a137c389c3eeb4cfb77c6 \
-    --hash=sha256:8853a3bf12afddfdf15f57c4b02d7ded92c7a75a5d7331d19f4f9572a89c17e6 \
-    --hash=sha256:88a58d8ac0cc0e7f3a014509f0455248a76629ca9b604eca7dc5927cc593c5e9 \
-    --hash=sha256:8ba470552b48e5835f1d23ecb936bb7f71d206f9dfeee64245f30c3270b994de \
-    --hash=sha256:8c676b587da5673d3c75bd67dd2a8cdfeb282ca38a30f37950511766b26858c4 \
-    --hash=sha256:8ec4a89295cd6cd4d1058a5e6aec6bf51e0eaaf9714774e1bfac7cfc9051db47 \
-    --hash=sha256:94f3e1780abb45062287b4614a5bc0874519c86a777d4a7ad34978e86428b8dd \
-    --hash=sha256:9a0f748eaa434a41fccf8e1ee7a3eed68af1b690e75328fd7a60af123c193b50 \
-    --hash=sha256:a5629742881bcbc1f42e840af185fd4d83a5edeb96475a575f4da50d6ede337c \
-    --hash=sha256:a65149d8ada1055029fcb665452b2814fe7d7082fcb0c5bed6db851cb69b2086 \
-    --hash=sha256:b3c5ac4bed7519088103d9450a1107f76308ecf91d6dabc8a33a2fcfb18d0fba \
-    --hash=sha256:b4fd7bd29610a83a8c9b564d457cf5bd92b4e11e79a4ee4716a63c959699b306 \
-    --hash=sha256:bcd1fb5bb7b07f64c15618c89efcc2cfa3e95f0e3bcdbaf4642509de1942a699 \
-    --hash=sha256:c12b5ae868897c7338519c03049a806af85b9b8c237b7d675b8c5e089e4a618e \
-    --hash=sha256:c26845094b1af3c91852745ae78e3ea47abf3dbcd1cf962f16b9a5fbe3ee8488 \
-    --hash=sha256:c6a660307ca9d4867caa8d9ca2c2658ab685de83792d1876274991adec7b93fa \
-    --hash=sha256:c809a70e43c7977c4a42aefd62f0131823ebf7dd73556fa5d5950f5b354087e2 \
-    --hash=sha256:c8b2351c85d855293a299038e1f89db92a2f35e8d2f783489c6f0b2b5f3fe8a3 \
-    --hash=sha256:cb929ca942d0ec4fac404cbf520ee6cac37bf35be479b970c4ffadf2b6a1cad9 \
-    --hash=sha256:d2c0a187a92a1cb5ef2c8ed5412dd8d4334272617f532d4ad4de31e0495bd923 \
-    --hash=sha256:d69bfd8ec3219ae71bcde1f942b728903cad25fafe3100ba2258b973bd2bc1b2 \
-    --hash=sha256:daffdf51ee5db69a82dd127eabecce20729e21f7a3680cf7cbb23f0829189790 \
-    --hash=sha256:e58876c91f97b0952eb766123bfef372792ab3f4e3e1f1a2267834c2ab131734 \
-    --hash=sha256:eda2616eb2313cbb3eebbe51f19362eb434b18e3bb599466a1ffa76a033fb916 \
-    --hash=sha256:ee217c198f2e41f184f3869f3e485557296d505b5195c513b2bfe0062dc537f1 \
-    --hash=sha256:f02541ef64077f22bf4924f225c0fd1248c168f86e4b7abdedd87d6ebaceab0f \
-    --hash=sha256:f1b82c27e89fffc6da125d5eb0ca6e68017faf5efc078128cfaa42cf5cb38798 \
-    --hash=sha256:fba162b8872d30fea8c52b258a542c5dfd7b235fb5cb352240c8d63b414013eb \
-    --hash=sha256:fbbcb7b57dc9c794843e3d1258c0fbf0f48656d46ffe9e09b63bbd6e8cd5d0a2 \
-    --hash=sha256:fcb4621042ac4b7865c179bb972ed0da0218a076dc1820ffc48b1d74c1e37fe9
-    # via rdkit
-rdkit==2024.3.5 \
-    --hash=sha256:01fd323f5902a720925293c0ce08a33e630422374cf263d04ef173c106c63c36 \
-    --hash=sha256:04079aef5f91965bd2a48bf432b32c36ea1bf088e26efb2c9a43b625b6a75d15 \
-    --hash=sha256:1cb7cdb29956649d4c875790b94142868c08c0735dee4d90b2d70dfd378e9d2e \
-    --hash=sha256:292141f0ba2359be07d8566d9a39ce697c1d6e7eb406031a2bf0387026503a47 \
-    --hash=sha256:2affa1b4cf601d27b157bbc44255c640baac9bc04cfdf5fa88f43c34c3f360d5 \
-    --hash=sha256:316bb5273bff5be76d4e5b0def998455e9b1a20898df44548b0e299f90786cb2 \
-    --hash=sha256:455d510beff8806e62e48b977d7acbfbc351474fa132124738a07223440c1b9a \
-    --hash=sha256:53638d0d94f7c511273ff5765abc6a1fe60fe6c8633db13cad03bc527550a7a9 \
-    --hash=sha256:6af38c62d4af9d669f8996551d3ae809de9ab245570b861be3f7a2b1a536f79f \
-    --hash=sha256:73fa2fe3a9a2334edf8448a5a3093a6f949ee715de77d3baa685751e2cf9317b \
-    --hash=sha256:7c91c5ccbf8d51cd3dd894bf770ca99da5fe37714f6e2a66016e8af4f57d2b56 \
-    --hash=sha256:7d5576bad6672959d0c1939e8d7e2fcd8656f8daf9788ce58e5c313db719b5ec \
-    --hash=sha256:89f7a72466ffbd45320d845ee1bcde1bddb1a322352836835d26ebb712228a41 \
-    --hash=sha256:8d4ebafb7e845bdc55eb6e2e188123ec84fb2bf724d3a7eb2da9bcfade7acc65 \
-    --hash=sha256:90376467f4988ee44f3f47d1e558ffc27646254a99fe65d19a7d9a123e832ef2 \
-    --hash=sha256:913494a03fcf6121c103e5db43fa33bca0fcc65ebd5a6c46661baa6851f79d91 \
-    --hash=sha256:98dac94a5e414ed1880b215eacec63e5fd77b0ea351e0a18fc5229acb8e886f5 \
-    --hash=sha256:a51cc403792ba37d1ee8ad84ad829177a4453547a4e085e1115ae2b237084ddb \
-    --hash=sha256:a98099cef42c1eb52512b343beb68a8b7cc4da79924a67181f58692a6376d91b \
-    --hash=sha256:c971eba2a67f8ae301b9b8c66b3431cd62472f648cdec9694e5413d8ebc59720 \
-    --hash=sha256:cf2747e7c82d6c90a8a631fe063d24d77b31f535e0f8a17ac9dbfbe4ab456886 \
-    --hash=sha256:d8714c03558086d022649617197c0c45c75c301f6a9fb67205695493a7e5b826 \
-    --hash=sha256:e5b0dfb28aa0949152ff816fba0a2f6267154f5c25159a9ec84c27cf18f72322 \
-    --hash=sha256:e69cec14cbb42c5ca912346b594d3f6a7aac572463949c55c7749da257e68123 \
-    --hash=sha256:f662ed10e14c7874d0e011c1f8260a6cf4a5547100806f9f4540f8550a3f1d36
-    # via alphafold3 (pyproject.toml)
-scipy==1.14.1 \
-    --hash=sha256:0c2f95de3b04e26f5f3ad5bb05e74ba7f68b837133a4492414b3afd79dfe540e \
-    --hash=sha256:1729560c906963fc8389f6aac023739ff3983e727b1a4d87696b7bf108316a79 \
-    --hash=sha256:278266012eb69f4a720827bdd2dc54b2271c97d84255b2faaa8f161a158c3b37 \
-    --hash=sha256:2843f2d527d9eebec9a43e6b406fb7266f3af25a751aa91d62ff416f54170bc5 \
-    --hash=sha256:2da0469a4ef0ecd3693761acbdc20f2fdeafb69e6819cc081308cc978153c675 \
-    --hash=sha256:2ff0a7e01e422c15739ecd64432743cf7aae2b03f3084288f399affcefe5222d \
-    --hash=sha256:2ff38e22128e6c03ff73b6bb0f85f897d2362f8c052e3b8ad00532198fbdae3f \
-    --hash=sha256:30ac8812c1d2aab7131a79ba62933a2a76f582d5dbbc695192453dae67ad6310 \
-    --hash=sha256:3a1b111fac6baec1c1d92f27e76511c9e7218f1695d61b59e05e0fe04dc59617 \
-    --hash=sha256:4079b90df244709e675cdc8b93bfd8a395d59af40b72e339c2287c91860deb8e \
-    --hash=sha256:5149e3fd2d686e42144a093b206aef01932a0059c2a33ddfa67f5f035bdfe13e \
-    --hash=sha256:5a275584e726026a5699459aa72f828a610821006228e841b94275c4a7c08417 \
-    --hash=sha256:631f07b3734d34aced009aaf6fedfd0eb3498a97e581c3b1e5f14a04164a456d \
-    --hash=sha256:716e389b694c4bb564b4fc0c51bc84d381735e0d39d3f26ec1af2556ec6aad94 \
-    --hash=sha256:8426251ad1e4ad903a4514712d2fa8fdd5382c978010d1c6f5f37ef286a713ad \
-    --hash=sha256:8475230e55549ab3f207bff11ebfc91c805dc3463ef62eda3ccf593254524ce8 \
-    --hash=sha256:8bddf15838ba768bb5f5083c1ea012d64c9a444e16192762bd858f1e126196d0 \
-    --hash=sha256:8e32dced201274bf96899e6491d9ba3e9a5f6b336708656466ad0522d8528f69 \
-    --hash=sha256:8f9ea80f2e65bdaa0b7627fb00cbeb2daf163caa015e59b7516395fe3bd1e066 \
-    --hash=sha256:97c5dddd5932bd2a1a31c927ba5e1463a53b87ca96b5c9bdf5dfd6096e27efc3 \
-    --hash=sha256:a49f6ed96f83966f576b33a44257d869756df6cf1ef4934f59dd58b25e0327e5 \
-    --hash=sha256:af29a935803cc707ab2ed7791c44288a682f9c8107bc00f0eccc4f92c08d6e07 \
-    --hash=sha256:b05d43735bb2f07d689f56f7b474788a13ed8adc484a85aa65c0fd931cf9ccd2 \
-    --hash=sha256:b28d2ca4add7ac16ae8bb6632a3c86e4b9e4d52d3e34267f6e1b0c1f8d87e389 \
-    --hash=sha256:b99722ea48b7ea25e8e015e8341ae74624f72e5f21fc2abd45f3a93266de4c5d \
-    --hash=sha256:baff393942b550823bfce952bb62270ee17504d02a1801d7fd0719534dfb9c84 \
-    --hash=sha256:c0ee987efa6737242745f347835da2cc5bb9f1b42996a4d97d5c7ff7928cb6f2 \
-    --hash=sha256:d0d2821003174de06b69e58cef2316a6622b60ee613121199cb2852a873f8cf3 \
-    --hash=sha256:e0cf28db0f24a38b2a0ca33a85a54852586e43cf6fd876365c86e0657cfe7d73 \
-    --hash=sha256:e4f5a7c49323533f9103d4dacf4e4f07078f360743dec7f7596949149efeec06 \
-    --hash=sha256:eb58ca0abd96911932f688528977858681a59d61a7ce908ffd355957f7025cfc \
-    --hash=sha256:edaf02b82cd7639db00dbff629995ef185c8df4c3ffa71a5562a595765a06ce1 \
-    --hash=sha256:fef8c87f8abfb884dac04e97824b61299880c43f4ce675dd2cbeadd3c9b466d2
-    # via
-    #   jax
-    #   jaxlib
-tabulate==0.9.0 \
-    --hash=sha256:0095b12bf5966de529c0feb1fa08671671b3368eec77d7ef7ab114be2c068b3c \
-    --hash=sha256:024ca478df22e9340661486f85298cff5f6dcdba14f3813e8830015b9ed1948f
-    # via dm-haiku
-toolz==1.0.0 \
-    --hash=sha256:292c8f1c4e7516bf9086f8850935c799a874039c8bcf959d47b600e4c44a6236 \
-    --hash=sha256:2c86e3d9a04798ac556793bced838816296a2f085017664e4995cb40a1047a02
-    # via chex
-tqdm==4.67.0 \
-    --hash=sha256:0cd8af9d56911acab92182e88d763100d4788bdf421d251616040cc4d44863be \
-    --hash=sha256:fe5a6f95e6fe0b9755e9469b77b9c3cf850048224ecaa8293d7d2d31f97d869a
-    # via alphafold3 (pyproject.toml)
-triton==3.1.0 \
-    --hash=sha256:0f34f6e7885d1bf0eaaf7ba875a5f0ce6f3c13ba98f9503651c1e6dc6757ed5c \
-    --hash=sha256:6b0dd10a925263abbe9fa37dcde67a5e9b2383fc269fdf59f5657cac38c5d1d8 \
-    --hash=sha256:6dadaca7fc24de34e180271b5cf864c16755702e9f63a16f62df714a8099126a \
-    --hash=sha256:aafa9a20cd0d9fee523cd4504aa7131807a864cd77dcf6efe7e981f18b8c6c11 \
-    --hash=sha256:c8182f42fd8080a7d39d666814fa36c5e30cc00ea7eeeb1a2983dbb4c99a0fdc
-    # via
-    #   alphafold3 (pyproject.toml)
-    #   jax-triton
-typeguard==2.13.3 \
-    --hash=sha256:00edaa8da3a133674796cf5ea87d9f4b4c367d77476e185e80251cc13dfbb8c4 \
-    --hash=sha256:5e3e3be01e887e7eafae5af63d1f36c849aaa94e3a0112097312aabfa16284f1
-    # via jaxtyping
-typing-extensions==4.12.2 \
-    --hash=sha256:04e5ca0351e0f3f85c6853954072df659d0d13fac324d0072316b67d7794700d \
-    --hash=sha256:1a7ead55c7e559dd4dee8856e3a88b41225abfe1ce8df57b7c13915fe121ffb8
-    # via chex
-zstandard==0.23.0 \
-    --hash=sha256:034b88913ecc1b097f528e42b539453fa82c3557e414b3de9d5632c80439a473 \
-    --hash=sha256:0a7f0804bb3799414af278e9ad51be25edf67f78f916e08afdb983e74161b916 \
-    --hash=sha256:11e3bf3c924853a2d5835b24f03eeba7fc9b07d8ca499e247e06ff5676461a15 \
-    --hash=sha256:12a289832e520c6bd4dcaad68e944b86da3bad0d339ef7989fb7e88f92e96072 \
-    --hash=sha256:1516c8c37d3a053b01c1c15b182f3b5f5eef19ced9b930b684a73bad121addf4 \
-    --hash=sha256:157e89ceb4054029a289fb504c98c6a9fe8010f1680de0201b3eb5dc20aa6d9e \
-    --hash=sha256:1bfe8de1da6d104f15a60d4a8a768288f66aa953bbe00d027398b93fb9680b26 \
-    --hash=sha256:1e172f57cd78c20f13a3415cc8dfe24bf388614324d25539146594c16d78fcc8 \
-    --hash=sha256:1fd7e0f1cfb70eb2f95a19b472ee7ad6d9a0a992ec0ae53286870c104ca939e5 \
-    --hash=sha256:203d236f4c94cd8379d1ea61db2fce20730b4c38d7f1c34506a31b34edc87bdd \
-    --hash=sha256:27d3ef2252d2e62476389ca8f9b0cf2bbafb082a3b6bfe9d90cbcbb5529ecf7c \
-    --hash=sha256:29a2bc7c1b09b0af938b7a8343174b987ae021705acabcbae560166567f5a8db \
-    --hash=sha256:2ef230a8fd217a2015bc91b74f6b3b7d6522ba48be29ad4ea0ca3a3775bf7dd5 \
-    --hash=sha256:2ef3775758346d9ac6214123887d25c7061c92afe1f2b354f9388e9e4d48acfc \
-    --hash=sha256:2f146f50723defec2975fb7e388ae3a024eb7151542d1599527ec2aa9cacb152 \
-    --hash=sha256:2fb4535137de7e244c230e24f9d1ec194f61721c86ebea04e1581d9d06ea1269 \
-    --hash=sha256:32ba3b5ccde2d581b1e6aa952c836a6291e8435d788f656fe5976445865ae045 \
-    --hash=sha256:34895a41273ad33347b2fc70e1bff4240556de3c46c6ea430a7ed91f9042aa4e \
-    --hash=sha256:379b378ae694ba78cef921581ebd420c938936a153ded602c4fea612b7eaa90d \
-    --hash=sha256:38302b78a850ff82656beaddeb0bb989a0322a8bbb1bf1ab10c17506681d772a \
-    --hash=sha256:3aa014d55c3af933c1315eb4bb06dd0459661cc0b15cd61077afa6489bec63bb \
-    --hash=sha256:4051e406288b8cdbb993798b9a45c59a4896b6ecee2f875424ec10276a895740 \
-    --hash=sha256:40b33d93c6eddf02d2c19f5773196068d875c41ca25730e8288e9b672897c105 \
-    --hash=sha256:43da0f0092281bf501f9c5f6f3b4c975a8a0ea82de49ba3f7100e64d422a1274 \
-    --hash=sha256:445e4cb5048b04e90ce96a79b4b63140e3f4ab5f662321975679b5f6360b90e2 \
-    --hash=sha256:48ef6a43b1846f6025dde6ed9fee0c24e1149c1c25f7fb0a0585572b2f3adc58 \
-    --hash=sha256:50a80baba0285386f97ea36239855f6020ce452456605f262b2d33ac35c7770b \
-    --hash=sha256:519fbf169dfac1222a76ba8861ef4ac7f0530c35dd79ba5727014613f91613d4 \
-    --hash=sha256:53dd9d5e3d29f95acd5de6802e909ada8d8d8cfa37a3ac64836f3bc4bc5512db \
-    --hash=sha256:53ea7cdc96c6eb56e76bb06894bcfb5dfa93b7adcf59d61c6b92674e24e2dd5e \
-    --hash=sha256:576856e8594e6649aee06ddbfc738fec6a834f7c85bf7cadd1c53d4a58186ef9 \
-    --hash=sha256:59556bf80a7094d0cfb9f5e50bb2db27fefb75d5138bb16fb052b61b0e0eeeb0 \
-    --hash=sha256:5d41d5e025f1e0bccae4928981e71b2334c60f580bdc8345f824e7c0a4c2a813 \
-    --hash=sha256:61062387ad820c654b6a6b5f0b94484fa19515e0c5116faf29f41a6bc91ded6e \
-    --hash=sha256:61f89436cbfede4bc4e91b4397eaa3e2108ebe96d05e93d6ccc95ab5714be512 \
-    --hash=sha256:62136da96a973bd2557f06ddd4e8e807f9e13cbb0bfb9cc06cfe6d98ea90dfe0 \
-    --hash=sha256:64585e1dba664dc67c7cdabd56c1e5685233fbb1fc1966cfba2a340ec0dfff7b \
-    --hash=sha256:65308f4b4890aa12d9b6ad9f2844b7ee42c7f7a4fd3390425b242ffc57498f48 \
-    --hash=sha256:66b689c107857eceabf2cf3d3fc699c3c0fe8ccd18df2219d978c0283e4c508a \
-    --hash=sha256:6a41c120c3dbc0d81a8e8adc73312d668cd34acd7725f036992b1b72d22c1772 \
-    --hash=sha256:6f77fa49079891a4aab203d0b1744acc85577ed16d767b52fc089d83faf8d8ed \
-    --hash=sha256:72c68dda124a1a138340fb62fa21b9bf4848437d9ca60bd35db36f2d3345f373 \
-    --hash=sha256:752bf8a74412b9892f4e5b58f2f890a039f57037f52c89a740757ebd807f33ea \
-    --hash=sha256:76e79bc28a65f467e0409098fa2c4376931fd3207fbeb6b956c7c476d53746dd \
-    --hash=sha256:774d45b1fac1461f48698a9d4b5fa19a69d47ece02fa469825b442263f04021f \
-    --hash=sha256:77da4c6bfa20dd5ea25cbf12c76f181a8e8cd7ea231c673828d0386b1740b8dc \
-    --hash=sha256:77ea385f7dd5b5676d7fd943292ffa18fbf5c72ba98f7d09fc1fb9e819b34c23 \
-    --hash=sha256:80080816b4f52a9d886e67f1f96912891074903238fe54f2de8b786f86baded2 \
-    --hash=sha256:80a539906390591dd39ebb8d773771dc4db82ace6372c4d41e2d293f8e32b8db \
-    --hash=sha256:82d17e94d735c99621bf8ebf9995f870a6b3e6d14543b99e201ae046dfe7de70 \
-    --hash=sha256:837bb6764be6919963ef41235fd56a6486b132ea64afe5fafb4cb279ac44f259 \
-    --hash=sha256:84433dddea68571a6d6bd4fbf8ff398236031149116a7fff6f777ff95cad3df9 \
-    --hash=sha256:8c24f21fa2af4bb9f2c492a86fe0c34e6d2c63812a839590edaf177b7398f700 \
-    --hash=sha256:8ed7d27cb56b3e058d3cf684d7200703bcae623e1dcc06ed1e18ecda39fee003 \
-    --hash=sha256:9206649ec587e6b02bd124fb7799b86cddec350f6f6c14bc82a2b70183e708ba \
-    --hash=sha256:983b6efd649723474f29ed42e1467f90a35a74793437d0bc64a5bf482bedfa0a \
-    --hash=sha256:98da17ce9cbf3bfe4617e836d561e433f871129e3a7ac16d6ef4c680f13a839c \
-    --hash=sha256:9c236e635582742fee16603042553d276cca506e824fa2e6489db04039521e90 \
-    --hash=sha256:9da6bc32faac9a293ddfdcb9108d4b20416219461e4ec64dfea8383cac186690 \
-    --hash=sha256:a05e6d6218461eb1b4771d973728f0133b2a4613a6779995df557f70794fd60f \
-    --hash=sha256:a0817825b900fcd43ac5d05b8b3079937073d2b1ff9cf89427590718b70dd840 \
-    --hash=sha256:a4ae99c57668ca1e78597d8b06d5af837f377f340f4cce993b551b2d7731778d \
-    --hash=sha256:a8c86881813a78a6f4508ef9daf9d4995b8ac2d147dcb1a450448941398091c9 \
-    --hash=sha256:a8fffdbd9d1408006baaf02f1068d7dd1f016c6bcb7538682622c556e7b68e35 \
-    --hash=sha256:a9b07268d0c3ca5c170a385a0ab9fb7fdd9f5fd866be004c4ea39e44edce47dd \
-    --hash=sha256:ab19a2d91963ed9e42b4e8d77cd847ae8381576585bad79dbd0a8837a9f6620a \
-    --hash=sha256:ac184f87ff521f4840e6ea0b10c0ec90c6b1dcd0bad2f1e4a9a1b4fa177982ea \
-    --hash=sha256:b0e166f698c5a3e914947388c162be2583e0c638a4703fc6a543e23a88dea3c1 \
-    --hash=sha256:b2170c7e0367dde86a2647ed5b6f57394ea7f53545746104c6b09fc1f4223573 \
-    --hash=sha256:b2d8c62d08e7255f68f7a740bae85b3c9b8e5466baa9cbf7f57f1cde0ac6bc09 \
-    --hash=sha256:b4567955a6bc1b20e9c31612e615af6b53733491aeaa19a6b3b37f3b65477094 \
-    --hash=sha256:b69bb4f51daf461b15e7b3db033160937d3ff88303a7bc808c67bbc1eaf98c78 \
-    --hash=sha256:b8c0bd73aeac689beacd4e7667d48c299f61b959475cdbb91e7d3d88d27c56b9 \
-    --hash=sha256:be9b5b8659dff1f913039c2feee1aca499cfbc19e98fa12bc85e037c17ec6ca5 \
-    --hash=sha256:bf0a05b6059c0528477fba9054d09179beb63744355cab9f38059548fedd46a9 \
-    --hash=sha256:c16842b846a8d2a145223f520b7e18b57c8f476924bda92aeee3a88d11cfc391 \
-    --hash=sha256:c363b53e257246a954ebc7c488304b5592b9c53fbe74d03bc1c64dda153fb847 \
-    --hash=sha256:c7c517d74bea1a6afd39aa612fa025e6b8011982a0897768a2f7c8ab4ebb78a2 \
-    --hash=sha256:d20fd853fbb5807c8e84c136c278827b6167ded66c72ec6f9a14b863d809211c \
-    --hash=sha256:d2240ddc86b74966c34554c49d00eaafa8200a18d3a5b6ffbf7da63b11d74ee2 \
-    --hash=sha256:d477ed829077cd945b01fc3115edd132c47e6540ddcd96ca169facff28173057 \
-    --hash=sha256:d50d31bfedd53a928fed6707b15a8dbeef011bb6366297cc435accc888b27c20 \
-    --hash=sha256:dc1d33abb8a0d754ea4763bad944fd965d3d95b5baef6b121c0c9013eaf1907d \
-    --hash=sha256:dc5d1a49d3f8262be192589a4b72f0d03b72dcf46c51ad5852a4fdc67be7b9e4 \
-    --hash=sha256:e2d1a054f8f0a191004675755448d12be47fa9bebbcffa3cdf01db19f2d30a54 \
-    --hash=sha256:e7792606d606c8df5277c32ccb58f29b9b8603bf83b48639b7aedf6df4fe8171 \
-    --hash=sha256:ed1708dbf4d2e3a1c5c69110ba2b4eb6678262028afd6c6fbcc5a8dac9cda68e \
-    --hash=sha256:f2d4380bf5f62daabd7b751ea2339c1a21d1c9463f1feb7fc2bdcea2c29c3160 \
-    --hash=sha256:f3513916e8c645d0610815c257cbfd3242adfd5c4cfa78be514e5a3ebb42a41b \
-    --hash=sha256:f8346bfa098532bc1fb6c7ef06783e969d87a99dd1d2a5a18a892c1d7a643c58 \
-    --hash=sha256:f83fa6cae3fff8e98691248c9320356971b59678a17f20656a9e59cd32cee6d8 \
-    --hash=sha256:fa6ce8b52c5987b3e34d5674b0ab529a4602b632ebab0a93b07bfb4dfc8f8a33 \
-    --hash=sha256:fb2b1ecfef1e67897d336de3a0e3f52478182d6a47eda86cbd42504c5cbd009a \
-    --hash=sha256:fc9ca1c9718cb3b06634c7c8dec57d24e9438b2aa9a0f02b8bb36bf478538880 \
-    --hash=sha256:fd30d9c67d13d891f2360b2a120186729c111238ac63b43dbd37a5a40670b8ca \
-    --hash=sha256:fd7699e8fd9969f455ef2926221e0233f81a2542921471382e77a9e2f2b57f4b \
-    --hash=sha256:fe3b385d996ee0822fd46528d9f0443b880d4d05528fd26a9119a54ec3f91c69
-    # via alphafold3 (pyproject.toml)
diff --git a/docker/Dockerfile b/docker/Dockerfile
deleted file mode 100644
index 004c9d071f2c2ad66cf74d871b06fc4a5f5cafe6..0000000000000000000000000000000000000000
--- a/docker/Dockerfile
+++ /dev/null
@@ -1,68 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-FROM nvidia/cuda:12.6.0-base-ubuntu22.04
-
-# Some RUN statements are combined together to make Docker build run faster.
-# Get latest package listing, install software-properties-common, git, wget,
-# compilers and libraries.
-# git is required for pyproject.toml toolchain's use of CMakeLists.txt.
-# gcc, g++, make are required for compiling hmmer and AlphaFold 3 libaries.
-# zlib is a required dependency of AlphaFold 3.
-RUN apt update --quiet \
-    && apt install --yes --quiet software-properties-common \
-    && apt install --yes --quiet git wget gcc g++ make zlib1g-dev zstd
-
-# Get apt repository of specific Python versions. Then install Python. Tell APT
-# this isn't an interactive TTY to avoid timezone prompt when installing.
-RUN add-apt-repository ppa:deadsnakes/ppa \
-    && DEBIAN_FRONTEND=noninteractive apt install --yes --quiet python3.11 python3-pip python3.11-venv python3.11-dev
-RUN python3.11 -m venv /alphafold3_venv
-ENV PATH="/hmmer/bin:/alphafold3_venv/bin:$PATH"
-# Update pip to the latest version. Not necessary in Docker, but good to do when
-# this is used as a recipe for local installation since we rely on new pip
-# features for secure installs.
-RUN pip3 install --upgrade pip
-
-# Install HMMER. Do so before copying the source code, so that docker can cache
-# the image layer containing HMMER. Alternatively, you could also install it 
-# using `apt-get install hmmer` instead of bulding it from source.
-RUN mkdir /hmmer_build /hmmer ; \
-    wget http://eddylab.org/software/hmmer/hmmer-3.4.tar.gz --directory-prefix /hmmer_build ; \
-    (cd /hmmer_build && tar zxf hmmer-3.4.tar.gz && rm hmmer-3.4.tar.gz) ; \
-    (cd /hmmer_build/hmmer-3.4 && ./configure --prefix /hmmer) ; \
-    (cd /hmmer_build/hmmer-3.4 && make -j8) ; \
-    (cd /hmmer_build/hmmer-3.4 && make install) ; \
-    (cd /hmmer_build/hmmer-3.4/easel && make install) ; \
-    rm -R /hmmer_build
-
-# Copy the AlphaFold 3 source code from the local machine to the container and
-# set the working directory to there.
-COPY . /app/alphafold
-WORKDIR /app/alphafold
-
-# Install the Python dependencies AlphaFold 3 needs.
-RUN pip3 install -r dev-requirements.txt
-RUN pip3 install --no-deps .
-# Build chemical components database (this binary was installed by pip).
-RUN build_data
-
-# To work around a known XLA issue causing the compilation time to greatly
-# increase, the following environment variable setting XLA flags must be enabled
-# when running AlphaFold 3. Note that if using CUDA capability 7 GPUs, it is
-# necessary to set the following XLA_FLAGS value instead:
-# ENV XLA_FLAGS="--xla_disable_hlo_passes=custom-kernel-fusion-rewriter"
-# (no need to disable gemm in that case as it is not supported for such GPU).
-ENV XLA_FLAGS="--xla_gpu_enable_triton_gemm=false"
-# Memory settings used for folding up to 5,120 tokens on A100 80 GB.
-ENV XLA_PYTHON_CLIENT_PREALLOCATE=true
-ENV XLA_CLIENT_MEM_FRACTION=0.95
-
-CMD ["python3", "run_alphafold.py"]
\ No newline at end of file
diff --git a/docker/dockerignore b/docker/dockerignore
deleted file mode 100644
index b104deed47decf92709a2eec1e72e39d3fa8053e..0000000000000000000000000000000000000000
--- a/docker/dockerignore
+++ /dev/null
@@ -1,2 +0,0 @@
-dockerignore
-Dockerfile
\ No newline at end of file
diff --git a/docs/contributing.md b/docs/contributing.md
deleted file mode 100644
index c8e5b9ded8c3ce75a268ecffd8c2f1b8afd389e1..0000000000000000000000000000000000000000
--- a/docs/contributing.md
+++ /dev/null
@@ -1,31 +0,0 @@
-# How to Contribute
-
-We welcome small patches related to bug fixes and documentation, but we do not
-plan to make any major changes to this repository.
-
-## Before You Begin
-
-### Sign Our Contributor License Agreement
-
-Contributions to this project must be accompanied by a
-[Contributor License Agreement](https://cla.developers.google.com/about) (CLA).
-You (or your employer) retain the copyright to your contribution; this simply
-gives us permission to use and redistribute your contributions as part of the
-project.
-
-If you or your current employer have already signed the Google CLA (even if it
-was for a different project), you probably don't need to do it again.
-
-Visit <https://cla.developers.google.com/> to see your current agreements or to
-sign a new one.
-
-### Review Our Community Guidelines
-
-This project follows
-[Google's Open Source Community Guidelines](https://opensource.google/conduct/).
-
-## Contribution Process
-
-We won't accept pull requests directly, but if you send one, we will review it.
-If we send a fix based on your pull request, we will make sure to credit you in
-the release notes.
diff --git a/docs/header.jpg b/docs/header.jpg
deleted file mode 100644
index 079332b19526cdfcf46ce9b7811e2daf4acd3360..0000000000000000000000000000000000000000
Binary files a/docs/header.jpg and /dev/null differ
diff --git a/docs/input.md b/docs/input.md
deleted file mode 100644
index d9438573cbbc53c3e9f228f97eda904b9182ecf4..0000000000000000000000000000000000000000
--- a/docs/input.md
+++ /dev/null
@@ -1,970 +0,0 @@
-# AlphaFold 3 Input
-
-## Specifying Input Files
-
-You can provide inputs to `run_alphafold.py` in one of two ways:
-
--   Single input file: Use the `--json_path` flag followed by the path to a
-    single JSON file.
--   Multiple input files: Use the `--input_dir` flag followed by the path to a
-    directory of JSON files.
-
-## Input Format
-
-AlphaFold 3 uses a custom JSON input format differing from the
-[AlphaFold Server JSON input format](https://github.com/google-deepmind/alphafold/tree/main/server).
-See [below](#alphafold-server-json-compatibility) for more information.
-
-The custom AlphaFold 3 format allows:
-
-*   Specifying protein, RNA, and DNA chains, including modified residues.
-*   Specifying custom multiple sequence alignment (MSA) for protein and RNA
-    chains.
-*   Specifying custom structural templates for protein chains.
-*   Specifying ligands using
-    [Chemical Component Dictionary (CCD)](https://www.wwpdb.org/data/ccd) codes.
-*   Specifying ligands using SMILES.
-*   Specifying ligands by defining them using the CCD mmCIF format and supplying
-    them via the [user-provided CCD](#user-provided-ccd).
-*   Specifying covalent bonds between entities.
-*   Specifying multiple random seeds.
-
-## AlphaFold Server JSON Compatibility
-
-The [AlphaFold Server](https://alphafoldserver.com/) uses a separate
-[JSON format](https://github.com/google-deepmind/alphafold/tree/main/server)
-from the one used here in the AlphaFold 3 codebase. In particular, the JSON
-format used in the AlphaFold 3 codebase offers more flexibility and control in
-defining custom ligands, branched glycans, and covalent bonds between entities.
-
-We provide a converter in `run_alphafold.py` which automatically detects the
-input JSON format, denoted `dialect` in the converter code. The converter
-denotes the AlphaFoldServer JSON as `alphafoldserver`, and the JSON format
-defined here in the AlphaFold 3 codebase as `alphafold3`. If the detected input
-JSON format is `alphafoldserver`, then the converter will translate that into
-the JSON format `alphafold3`.
-
-### Multiple Inputs
-
-The top-level of the `alphafoldserver` JSON format is a list, allowing
-specification of multiple inputs in a single JSON. In contrast, the `alphafold3`
-JSON format requires exactly one input per JSON file. Specifying multiple inputs
-in a single `alphafoldserver` JSON is fully supported.
-
-Note that the converter distinguishes between `alphafoldserver` and `alphafold3`
-JSON formats by checking if the top-level of the JSON is a list or not. In
-particular, if you pass in a `alphafoldserver`-style JSON without a top-level
-list, then this is considered incorrect and `run_alphafold.py` will raise an
-error.
-
-### Glycans
-
-If the JSON in `alphafoldserver` format specifies glycans, the converter will
-raise an error. This is because translating glycans specified in the
-`alphafoldserver` format to the `alphafold3` format is not currently supported.
-
-### Random Seeds
-
-The `alphafoldserver` JSON format allows users to specify `"modelSeeds": []`, in
-which case a seed is chosen randomly for the user. On the other hand, the
-`alphafold3` format requires users to specify a seed.
-
-The converter will choose a seed randomly if `"modelSeeds": []` is set when
-translating from `alphafoldserver` JSON format to `alphafold3` JSON format. If
-seeds are specified in the `alphafoldserver` JSON format, then those will be
-preserved in the translation to the `alphafold3` JSON format.
-
-### Ions
-
-While AlphaFold Server treats ions and ligands as different entity types in the
-JSON format, AlphaFold 3 treats ions as ligands. Therefore, to specify e.g. a
-magnesium ion, one would specify it as an entity of type `ligand` with
-`ccdCodes: ["MG"]`.
-
-### Sequence IDs
-
-The `alphafold3` JSON format requires the user to specify a unique identifier
-(`id`) for each entity. On the other hand, the `alphafoldserver` does not allow
-specification of an `id` for each entity. Thus, the converter automatically
-assigns one.
-
-The converter iterates through the list provided in the `sequences` field of the
-`alphafoldserver` JSON format, assigning an `id` to each entity using the
-following order ("reverse spreadsheet style"):
-
-```
-A, B, ..., Z, AA, BA, CA, ..., ZA, AB, BB, CB, ..., ZB, ...
-```
-
-For any entity with `count > 1`, an `id` is assigned arbitrarily to each "copy"
-of the entity.
-
-## Top-level Structure
-
-The top-level structure of the input JSON is:
-
-```json
-{
-  "name": "Job name goes here",
-  "modelSeeds": [1, 2],  # At least one seed required.
-  "sequences": [
-    {"protein": {...}},
-    {"rna": {...}},
-    {"dna": {...}},
-    {"ligand": {...}}
-  ],
-  "bondedAtomPairs": [...],  # Optional.
-  "userCCD": "...",  # Optional, mutually exclusive with userCCDPath.
-  "userCCDPath": "...",  # Optional, mutually exclusive with userCCD.
-  "dialect": "alphafold3",  # Required.
-  "version": 3  # Required.
-}
-```
-
-The fields specify the following:
-
-*   `name: str`: The name of the job. A sanitised version of this name is used
-    for naming the output files.
-*   `modelSeeds: list[int]`: A list of integer random seeds. The pipeline and
-    the model will be invoked with each of the seeds in the list. I.e. if you
-    provide *n* random seeds, you will get *n* predicted structures, each with
-    the respective random seed. You must provide at least one random seed.
-*   `sequences: list[Protein | RNA | DNA | Ligand]`: A list of sequence
-    dictionaries, each defining a molecular entity, see below.
-*   `bondedAtomPairs: list[Bond]`: An optional list of covalently bonded atoms.
-    These can link atoms within an entity, or across two entities. See more
-    below.
-*   `userCCD: str`: An optional string with user-provided chemical components
-    dictionary. This is an expert mode for providing custom molecules when
-    SMILES is not sufficient. This should also be used when you have a custom
-    molecule that needs to be bonded with other entities - SMILES can't be used
-    in such cases since it doesn't give the possibility of uniquely naming all
-    atoms. It can also be used to provide a reference conformer for cases where
-    RDKit fails to generate a conformer. See more below.
-*   `userCCDPath: str`: An optional path to a file that contains the
-    user-provided chemical components dictionary instead of providing it inline
-    using the `userCCD` field. The path can be either absolute, or relative to
-    the input JSON path. The file must be in the
-    [CCD mmCIF format](https://www.wwpdb.org/data/ccd#mmcifFormat), and could be
-    either plain text, or compressed using gzip, xz, or zstd.
-*   `dialect: str`: The dialect of the input JSON. This must be set to
-    `alphafold3`. See
-    [AlphaFold Server JSON Compatibility](#alphafold-server-json-compatibility)
-    for more information.
-*   `version: int`: The version of the input JSON. This must be set to 1 or 2.
-    See
-    [AlphaFold Server JSON Compatibility](#alphafold-server-json-compatibility)
-    and [versions](#versions) below for more information.
-
-## Versions
-
-The top-level `version` field (for the `alphafold3` dialect) can be either `1`,
-`2`, or `3`. The following features have been added in respective versions:
-
-*   `1`: the initial AlphaFold 3 input format.
-*   `2`: added the option of specifying external MSA and templates using newly
-    added fields `unpairedMsaPath`, `pairedMsaPath`, and `mmcifPath`.
-*   `3`: added the option of specifying external user-provided CCD using newly
-    added field `userCCDPath`.
-
-## Sequences
-
-The `sequences` section specifies the protein chains, RNA chains, DNA chains,
-and ligands. Every entity in `sequences` must have a unique ID. IDs don't have
-to be sorted alphabetically.
-
-### Protein
-
-Specifies a single protein chain.
-
-```json
-{
-  "protein": {
-    "id": "A",
-    "sequence": "PVLSCGEWQL",
-    "modifications": [
-      {"ptmType": "HY3", "ptmPosition": 1},
-      {"ptmType": "P1L", "ptmPosition": 5}
-    ],
-    "unpairedMsa": ...,  # Mutually exclusive with unpairedMsaPath.
-    "unpairedMsaPath": ...,  # Mutually exclusive with unpairedMsa.
-    "pairedMsa": ...,  # Mutually exclusive with pairedMsaPath.
-    "pairedMsaPath": ...,  # Mutually exclusive with pairedMsa.
-    "templates": [...]
-  }
-}
-```
-
-The fields specify the following:
-
-*   `id: str | list[str]`: An uppercase letter or multiple letters specifying
-    the unique IDs for each copy of this protein chain. The IDs are then also
-    used in the output mmCIF file. Specifying a list of IDs (e.g. `["A", "B",
-    "C"]`) implies a homomeric chain with multiple copies.
-*   `sequence: str`: The amino-acid sequence, specified as a string that uses
-    the 1-letter standard amino acid codes.
-*   `modifications: list[ProteinModification]`: An optional list of
-    post-translational modifications. Each modification is specified using its
-    CCD code and 1-based residue position. In the example above, we see that the
-    first residue won't be a proline (`P`) but instead `HY3`.
-*   `unpairedMsa: str`: An optional multiple sequence alignment for this chain.
-    This is specified using the A3M format (equivalent to the FASTA format, but
-    also allows gaps denoted by the hyphen `-` character). See more details
-    below.
-*   `unpairedMsaPath: str`: An optional path to a file that contains the
-    multiple sequence alignment for this chain instead of providing it inline
-    using the `unpairedMsa` field. The path can be either absolute, or relative
-    to the input JSON path. The file must be in the A3M format, and could be
-    either plain text, or compressed using gzip, xz, or zstd.
-*   `pairedMsa: str`: We recommend *not* using this optional field and using the
-    `unpairedMsa` for the purposes of pairing. See more details below.
-*   `pairedMsaPath: str`: An optional path to a file that contains the multiple
-    sequence alignment for this chain instead of providing it inline using the
-    `pairedMsa` field. The path can be either absolute, or relative to the input
-    JSON path. The file must be in the A3M format, and could be either plain
-    text, or compressed using gzip, xz, or zstd.
-*   `templates: list[Template]`: An optional list of structural templates. See
-    more details below.
-
-### RNA
-
-Specifies a single RNA chain.
-
-```json
-{
-  "rna": {
-    "id": "A",
-    "sequence": "AGCU",
-    "modifications": [
-      {"modificationType": "2MG", "basePosition": 1},
-      {"modificationType": "5MC", "basePosition": 4}
-    ],
-    "unpairedMsa": ...,  # Mutually exclusive with unpairedMsaPath.
-    "unpairedMsaPath": ...  # Mutually exclusive with unpairedMsa.
-  }
-}
-```
-
-The fields specify the following:
-
-*   `id: str | list[str]`: An uppercase letter or multiple letters specifying
-    the unique IDs for each copy of this RNA chain. The IDs are then also used
-    in the output mmCIF file. Specifying a list of IDs (e.g. `["A", "B", "C"]`)
-    implies a homomeric chain with multiple copies.
-*   `sequence: str`: The RNA sequence, specified as a string using only the
-    letters `A`, `C`, `G`, `U`.
-*   `modifications: list[RnaModification]`: An optional list of modifications.
-    Each modification is specified using its CCD code and 1-based base position.
-*   `unpairedMsa: str`: An optional multiple sequence alignment for this chain.
-    This is specified using the A3M format. See more details below.
-*   `unpairedMsaPath: str`: An optional path to a file that contains the
-    multiple sequence alignment for this chain instead of providing it inline
-    using the `unpairedMsa` field. The path can be either absolute, or relative
-    to the input JSON path. The file must be in the A3M format, and could be
-    either plain text, or compressed using gzip, xz, or zstd.
-
-### DNA
-
-Specifies a single DNA chain.
-
-```json
-{
-  "dna": {
-    "id": "A",
-    "sequence": "GACCTCT",
-    "modifications": [
-      {"modificationType": "6OG", "basePosition": 1},
-      {"modificationType": "6MA", "basePosition": 2}
-    ]
-  }
-}
-```
-
-The fields specify the following:
-
-*   `id: str | list[str]`: An uppercase letter or multiple letters specifying
-    the unique IDs for each copy of this DNA chain. The IDs are then also used
-    in the output mmCIF file. Specifying a list of IDs (e.g. `["A", "B", "C"]`)
-    implies a homomeric chain with multiple copies.
-*   `sequence: str`: The DNA sequence, specified as a string using only the
-    letters `A`, `C`, `G`, `T`.
-*   `modifications: list[DnaModification]`: An optional list of modifications.
-    Each modification is specified using its CCD code and 1-based base position.
-
-### Ligands
-
-Specifies a single ligand. Ligands can be specified using 3 different formats:
-
-1.  [CCD code(s)](https://www.wwpdb.org/data/ccd). This is the easiest way to
-    specify ligands. Supports specifying covalent bonds to other entities. CCD
-    from 2022-09-28 is used. If multiple CCD codes are specified, you may want
-    to specify a bond between these and/or a bond to some other entity. See the
-    [bonds](#bonds) section below.
-2.  [SMILES string](https://en.wikipedia.org/wiki/Simplified_Molecular_Input_Line_Entry_System).
-    This enables specifying ligands that are not in CCD. If using SMILES, you
-    cannot specify covalent bonds to other entities as these rely on specific
-    atom names - see the next option for what to use for this case.
-3.  User-provided CCD + custom ligand codes. This enables specifying ligands not
-    in CCD, while also supporting specification of covalent bonds to other
-    entities and backup reference coordinates for when RDKit fails to generate a
-    conformer. This offers the most flexibility, but also requires careful
-    attention to get all of the details right.
-
-```json
-{
-  "ligand": {
-    "id": ["G", "H", "I"],
-    "ccdCodes": ["ATP"]
-  }
-},
-{
-  "ligand": {
-    "id": "J",
-    "ccdCodes": ["LIG-1337"]
-  }
-},
-{
-  "ligand": {
-    "id": "K",
-    "smiles": "CC(=O)OC1C[NH+]2CCC1CC2"
-  }
-}
-```
-
-The fields specify the following:
-
-*   `id: str | list[str]`: An uppercase letter (or multiple letters) specifying
-    the unique ID of this ligand. This ID is then also used in the output mmCIF
-    file. Specifying a list of IDs (e.g. `["A", "B", "C"]`) implies a ligand
-    that has multiple copies.
-*   `ccdCodes: list[str]`: An optional list of CCD codes. These could be either
-    standard CCD codes, or custom codes pointing to the
-    [user-provided CCD](#user-provided-ccd).
-*   `smiles: str`: An optional string defining the ligand using a SMILES string.
-    The SMILES string must be correctly JSON-escaped.
-
-Each ligand may be specified using CCD codes or SMILES but not both, i.e. for a
-given ligand, the `ccdCodes` and `smiles` fields are mutually exclusive.
-
-#### SMILES string JSON escaping
-
-The SMILES string must be correctly JSON-escaped, in particular the backslash
-character must be escaped as two backslashes, otherwise the JSON parser will
-fail with a `JSONDecodeError`. For instance, the following SMILES string
-`CCC[C@@H](O)CC\C=C\C=C\C#CC#C\C=C\CO` has to be specified as:
-
-```json
-{
-  "ligand": {
-    "id": "A",
-    "smiles": "CCC[C@@H](O)CC\\C=C\\C=C\\C#CC#C\\C=C\\CO"
-  }
-}
-```
-
-You can JSON-escape the SMILES string using the
-[`jq`](https://github.com/jqlang/jq) command-line tool which should be easily
-installable on most Linux systems:
-
-```bash
-jq -R . <<< 'CCC[C@@H](O)CC\C=C\C=C\C#CC#C\C=C\CO'  # Replace with your SMILES.
-```
-
-Alternatively, you can use this Python code:
-
-```python
-import json
-
-smiles = r'CCC[C@@H](O)CC\C=C\C=C\C#CC#C\C=C\CO'  # Replace with your SMILES.
-print(json.dumps(smiles))
-```
-
-#### Reference structure construction with SMILES
-
-For some ligands and some random seeds, RDKit might fail to generate a
-conformer, indicated by the `Failed to construct RDKit reference structure`
-error message. In this case, you can either provide a reference structure for
-the ligand using the [user-provided CCD Format](#user-provided-ccd-format), or
-try increasing the number of RDKit conformer iterations using the
-`--conformer_max_iterations=...` flag.
-
-### Ions
-
-Ions are treated as ligands, e.g. a magnesium ion would simply be a ligand with
-`ccdCodes: ["MG"]`.
-
-## Multiple Sequence Alignment
-
-Protein and RNA chains allow setting a custom Multiple Sequence Alignment (MSA).
-If not set, the data pipeline will automatically build MSAs for protein and RNA
-entities using Jackhmmer/Nhmmer search over genetic databases as described in
-the paper.
-
-### RNA Multiple Sequence Alignment
-
-RNA `unpairedMsa` can be either:
-
-1.  Unset (or set explicitly to `null`). AlphaFold 3 won't build MSA for this
-    RNA chain.
-2.  Set to an empty string (`""`). AlphaFold 3 won't build MSA and will run
-    MSA-free for this RNA chain.
-3.  Set to a non-empty A3M string. AlphaFold 3 will use the provided MSA for
-    this RNA chain.
-
-### Protein Multiple Sequence Alignment
-
-For protein chains, the situation is slightly more complicated due to paired and
-unpaired MSA (see [MSA Pairing](#msa-pairing) below for more details).
-
-The following combinations are valid for a given protein chain:
-
-1.  Both `unpairedMsa` and `pairedMsa` fields are unset (or explicitly set to
-    `null`), AlphaFold 3 will build both MSAs automatically. This is the
-    recommended option.
-2.  The `unpairedMsa` is set to to a non-empty A3M string, `pairedMsa` set to an
-    empty string (`""`). AlphaFold 3 won't build MSA, will use the `unpairedMsa`
-    as is and run `pairedMSA`-free.
-3.  The `pairedMsa` is set to to a non-empty A3M string, `unpairedMsa` set to an
-    empty string (`""`). AlphaFold 3 won't build MSA, will use the `pairedMsa`
-    and run `unpairedMSA`-free. **This option is not recommended**, see
-    [MSA Pairing](#msa-pairing) below.
-4.  Both `unpairedMsa` and `pairedMsa` fields are set to an empty string (`""`).
-    AlphaFold 3 will not build the MSA and the MSA input to the model will be
-    just the query sequence (equivalent to running completely MSA-free).
-5.  Both `unpairedMsa` and `pairedMsa` fields are set to a custom non-empty A3M
-    string, AlphaFold 3 will use the provided MSA instead of building one as
-    part of the data pipeline. This is considered an expert option.
-
-Note that both `unpairedMsa` and `pairedMsa` have to either be *both* set (i.e.
-non-`null`), or both unset (i.e. both `null`, explicitly or implicitly).
-Typically, when setting `unpairedMsa`, you will set the `pairedMsa` to an empty
-string (`""`). For example this will run the protein chain A with the given MSA,
-but without any templates (template-free):
-
-```json
-{
-  "protein": {
-    "id": "A",
-    "sequence": ...,
-    "unpairedMsa": "The A3M you want to run with",
-    "pairedMsa": "",
-    "templates": []
-  }
-}
-```
-
-When setting your own MSA, you have to make sure that:
-
-1.  The MSA is in the A3M format. This means adhering to the FASTA format while
-    also allowing lowercase characters denoting inserted residues and hyphens
-    (`-`) denoting gaps in sequences.
-2.  The first sequence is exactly equal to the query sequence.
-3.  If all insertions are removed from MSA hits (i.e. all lowercase letters are
-    removed), all sequences have exactly the same length as the query (they form
-    an exact rectangular matrix).
-
-### MSA Pairing
-
-MSA pairing matters only when folding multiple chains (multimers), since we need
-to find a way to concatenate MSAs for the individual chains along the sequence
-dimension. If done naively, by simply concatenating the individual MSA matrices
-along the sequence dimension and padding so that all MSAs have the same depth,
-one can end up with rows in the concatenated MSA that are formed by sequences
-from different organisms.
-
-It may be desirable to ensure that across multiple chains, sequences in the MSA
-that are from the same organism end up in the same MSA row. AlphaFold 3
-internally achieves this by looking for the UniProt organism ID in the
-`pairedMsa` and pairing sequences based on this information.
-
-We recommend users do the pairing manually or use the output of an appropriate
-software and then provide the MSA using only the `unpairedMsa` field. This
-method gives exact control over the placement of each sequence in the MSA, as
-opposed to relying on name-matching post-processing heuristics used for
-`pairedMsa`.
-
-When setting `unpairedMsa` manually, the `pairedMsa` must be explicitly set to
-an empty string (`""`).
-
-For instance, if there are two chains `DEEP` and `MIND` which we want to be
-paired on organism A and C, we can achieve it as follows:
-
-```txt
-> query
-DEEP
-> match 1 (organism A)
-D--P
-> match 2 (organism B)
-DD-P
-> match 3 (organism C)
-DD-P
-```
-
-```txt
-> query
-MIND
-> match 1 (organism A)
-M--D
-> Empty hit to make sure pairing is achieved
-----
-> match 2 (organism C)
-MIN-
-```
-
-The resulting MSA when chains are concatenated will then be:
-
-```txt
-> query
-DEEPMIND
-> match 1 + match 1
-D--PM--D
-> match 2 + padding
-DD-P----
-> match 3 + match 2
-DD-PMIN-
-```
-
-## Structural Templates
-
-Structural templates can be specified only for protein chains:
-
-```json
-"templates": [
-  {
-    "mmcif": ...,  # Mutually exclusive with mmcifPath.
-    "mmcifPath": ...,  # Mutually exclusive with mmcif.
-    "queryIndices": [0, 1, 2, 4, 5, 6],
-    "templateIndices": [0, 1, 2, 3, 4, 8]
-  }
-]
-```
-
-The fields specify the following:
-
-*   `mmcif: str`: A string containing the single chain protein structural
-    template in the mmCIF format.
-*   `mmcifPath: str`: An optional path to a file that contains the mmCIF with
-    the structural template instead of providing it inline using the `mmcifPath`
-    field. The path can be either absolute, or relative to the input JSON path.
-    The file must be in the mmCIF format, and could be either plain text, or
-    compressed using gzip, xz, or zstd.
-*   `queryIndices: list[int]`: O-based indices in the query sequence, defining
-    the mapping from query residues to template residues.
-*   `templateIndices: list[int]`: O-based indices in the template sequence,
-    defining the mapping from query residues to template residues.
-
-A template is specified as an mmCIF string containing a single chain with the
-structural template together with a 0-based mapping that maps query residue
-indices to the template residue indices. The mapping is specified using two
-lists of the same length. E.g. to express a mapping `{0: 0, 1: 2, 2: 5, 3: 6}`,
-you would specify the two indices lists as:
-
-```json
-"queryIndices":    [0, 1, 2, 3],
-"templateIndices": [0, 2, 5, 6]
-```
-
-You can provide multiple structural templates. Note that if an mmCIF containing
-more than one chain is provided, you will get an error since it is not possible
-to determine which of the chains should be used as the template.
-
-You can run template-free (but still run genetic search and build MSA) by
-setting templates to `[]` and either explicitly setting both `unpairedMsa` and
-`pairedMsa` to `null`:
-
-```json
-"protein": {
-  "id": "A",
-  "sequence": ...,
-  "pairedMsa": null,
-  "unpairedMsa": null,
-  "templates": []
-}
-```
-
-Or you can simply fully omit them:
-
-```json
-"protein": {
-  "id": "A",
-  "sequence": ...,
-  "templates": []
-}
-```
-
-You can also run with pre-computed MSA, but let AlphaFold 3 search for
-templates. This can be achieved by setting `unpairedMsa` and `pairedMsa`, but
-keeping templates unset (or set to `null`). The profile given as an input to
-Hmmsearch when searching for templates will be built from the provided
-`unpairedMsa`:
-
-```json
-"protein": {
-  "id": "A",
-  "sequence": ...,
-  "unpairedMsa": ...,
-  "pairedMsa": ...,
-  "templates": null
-}
-```
-
-Or you can simply fully omit the `templates` field thus setting it implicitly to
-`null`:
-
-```json
-"protein": {
-  "id": "A",
-  "sequence": ...,
-  "unpairedMsa": ...,
-  "pairedMsa": ...,
-}
-```
-
-## Bonds
-
-To manually specify covalent bonds, use the `bondedAtomPairs` field. This is
-intended for modelling covalent ligands, and for defining multi-CCD ligands
-(e.g. glycans). Defining covalent bonds between or within polymer entities is
-not currently supported.
-
-Bonds are specified as pairs of (source atom, destination atom), with each atom
-being uniquely addressed using 3 fields:
-
-*   **Entity ID** (`str`): this corresponds to the `id` field for that entity.
-*   **Residue ID** (`int`): this is 1-based residue index *within* the chain.
-    For single-residue ligands, this is simply set to 1.
-*   **Atom name** (`str`): this is the unique atom name *within* the given
-    residue. The atom name for protein/RNA/DNA residues or CCD ligands can be
-    looked up in the CCD for the given chemical component. This also explains
-    why SMILES ligands don't support bonds: there is no atom name that could be
-    used to define the bond. This shortcoming can be addressed by using the
-    user-provided CCD format (see below).
-
-The example below shows two bonds:
-
-```json
-"bondedAtomPairs": [
-  [["A", 145, "SG"], ["L", 1, "C04"]],
-  [["J", 1, "O6"], ["J", 2, "C1"]]
-]
-```
-
-The first bond is between chain A, residue 145, atom SG and chain L, residue 1,
-atom C04. This is a typical example for a covalent ligand. The second bond is
-between chain J, residue 1, atom O6 and chain J, residue 2, atom C1. This bond
-is within the same entity and is a typical example when defining a glycan.
-
-All bonds are implicitly assumed to be covalent bonds. Other bond types are not
-supported.
-
-### Defining Glycans
-
-Glycans are bound to a protein residue, and they are typically formed of
-multiple chemical components. To define a glycan, define a new ligand with all
-of the chemical components of the glycan. Then define a bond that links the
-glycan to the protein residue, and all bonds that are within the glycan between
-its individual chemical components.
-
-For example, to define the following glycan composed of 4 components (CMP1,
-CMP2, CMP3, CMP4) bound to an asparagine in a protein chain A:
-
-```
- â‹®
-ALA            CMP4
- |              |
-ASN ―― CMP1 ―― CMP2
- |              |
-ALA            CMP3
- â‹®
-```
-
-You will need to specify:
-
-1.  Protein chain A.
-2.  Ligand chain B with the 4 components.
-3.  Bonds ASN-CMP1, CMP1-CMP2, CMP2-CMP3, CMP2-CMP4.
-
-## User-provided CCD
-
-There are two approaches to model a custom ligand not defined in the CCD:
-
-1.  If the ligand is not bonded to other entities, it can be defined using a
-    [SMILES string](https://en.wikipedia.org/wiki/Simplified_Molecular_Input_Line_Entry_System).
-2.  If it is bonded to other entities, or to be able to customise relevant
-    features (such as bond orders, atom names and ideal coordinates used when
-    conformer generation fails), it is necessary to define that particular
-    ligand using the
-    [CCD mmCIF format](https://www.wwpdb.org/data/ccd#mmcifFormat).
-
-Note that if a full CCD mmCIF is provided, any SMILES string input as part of
-that mmCIF is ignored.
-
-Once defined, this ligand needs to be assigned a name that doesn't clash with
-existing CCD ligand names (e.g. `LIG-1`). Avoid underscores (`_`) in the name,
-as it could cause issues in the mmCIF format.
-
-The newly defined ligand can then be used as a standard CCD ligand using its
-custom name, and bonds can be linked to it using its named atom scheme.
-
-### Conformer Generation
-
-The data pipeline attempts to generate a conformer for ligands using RDKit. The
-`Mol` used to generate the conformer is constructed either from the information
-provided in the CCD mmCIF, or from the SMILES string if that is the only
-information provided.
-
-If conformer generation fails, the model will fall back to using the ideal
-coordinates in the CCD mmCIF if these are provided. If they are not provided,
-the model will use the reference coordinates if the last modification date given
-in the CCD mmCIF is prior to the training cutoff date. If no coordinates can be
-found in this way, all conformer coordinates are set to zero and the model will
-output `NaN` (`null` in the output JSON) confidences for the ligand.
-
-Note that sometimes conformer generation failures can be resolved by
-increasinging the number of RDKit conformer iterations using the
-`--conformer_max_iterations=...` flag.
-
-### User-provided CCD Format
-
-The user-provided CCD must be passed either:
-
-*   In the `userCCD` field (in the root of the input JSON) as a string. Note
-    that JSON doesn't allow newlines within strings, so newline characters
-    (`\n`) must be used to delimit lines. Single rather than double quotes
-    should also be used around strings like the chemical formula.
-*   In the `userCCDPath` field, as a path to a file that contains the
-    user-provided chemical components dictionary. The path can be either
-    absolute, or relative to the input JSON path. The file must be in the
-    [CCD mmCIF format](https://www.wwpdb.org/data/ccd#mmcifFormat), and could be
-    either plain text, or compressed using gzip, xz, or zstd.
-
-The main pieces of information used are the atom names and elements, bonds, and
-also the ideal coordinates (`pdbx_model_Cartn_{x,y,z}_ideal`) which essentially
-serve as a structural template for the ligand if RDKit fails to generate
-conformers for that ligand.
-
-The user-provided CCD can also be used to redefine standard chemical components
-in the CCD. This can be useful if you need to redefine the ideal coordinates.
-
-Below is an example user-provided CCD redefining component X7F, which serves to
-illustrate the required sections. For readability purposes, newlines have not
-been replaced by `\n`.
-
-```
-data_MY-X7F
-#
-_chem_comp.id MY-X7F
-_chem_comp.name '5,8-bis(oxidanyl)naphthalene-1,4-dione'
-_chem_comp.type non-polymer
-_chem_comp.formula 'C10 H6 O4'
-_chem_comp.mon_nstd_parent_comp_id ?
-_chem_comp.pdbx_synonyms ?
-_chem_comp.formula_weight 190.152
-#
-loop_
-_chem_comp_atom.comp_id
-_chem_comp_atom.atom_id
-_chem_comp_atom.type_symbol
-_chem_comp_atom.charge
-_chem_comp_atom.pdbx_leaving_atom_flag
-_chem_comp_atom.pdbx_model_Cartn_x_ideal
-_chem_comp_atom.pdbx_model_Cartn_y_ideal
-_chem_comp_atom.pdbx_model_Cartn_z_ideal
-MY-X7F C02 C 0 N -1.418 -1.260 0.018
-MY-X7F C03 C 0 N -0.665 -2.503 -0.247
-MY-X7F C04 C 0 N 0.677 -2.501 -0.235
-MY-X7F C05 C 0 N 1.421 -1.257 0.043
-MY-X7F C06 C 0 N 0.706 0.032 0.008
-MY-X7F C07 C 0 N -0.706 0.030 -0.004
-MY-X7F C08 C 0 N -1.397 1.240 -0.037
-MY-X7F C10 C 0 N -0.685 2.443 -0.057
-MY-X7F C11 C 0 N 0.679 2.445 -0.045
-MY-X7F C12 C 0 N 1.394 1.243 -0.013
-MY-X7F O01 O 0 N -2.611 -1.301 0.247
-MY-X7F O09 O 0 N -2.752 1.249 -0.049
-MY-X7F O13 O 0 N 2.750 1.257 -0.001
-MY-X7F O14 O 0 N 2.609 -1.294 0.298
-MY-X7F H1 H 0 N -1.199 -3.419 -0.452
-MY-X7F H2 H 0 N 1.216 -3.416 -0.429
-MY-X7F H3 H 0 N -1.221 3.381 -0.082
-MY-X7F H4 H 0 N 1.212 3.384 -0.062
-MY-X7F H5 H 0 N -3.154 1.271 0.830
-MY-X7F H6 H 0 N 3.151 1.241 -0.880
-#
-loop_
-_chem_comp_bond.atom_id_1
-_chem_comp_bond.atom_id_2
-_chem_comp_bond.value_order
-_chem_comp_bond.pdbx_aromatic_flag
-O01 C02 DOUB N
-O09 C08 SING N
-C02 C03 SING N
-C02 C07 SING N
-C03 C04 DOUB N
-C08 C07 DOUB Y
-C08 C10 SING Y
-C07 C06 SING Y
-C10 C11 DOUB Y
-C04 C05 SING N
-C06 C05 SING N
-C06 C12 DOUB Y
-C11 C12 SING Y
-C05 O14 DOUB N
-C12 O13 SING N
-C03 H1 SING N
-C04 H2 SING N
-C10 H3 SING N
-C11 H4 SING N
-O09 H5 SING N
-O13 H6 SING N
-#
-```
-
-### Mandatory fields
-
-Parsing the user-provided CCD needs only a subset of the fields that CCD uses.
-The mandatory fields are described below. Refer to
-[CCD documentation](https://www.wwpdb.org/data/ccd#mmcifFormat) for more
-detailed explanation of each field. Note that not all of these fields are input
-to the model, but they are necessary for the data pipeline to run – see the
-[Model input fields](#model-input-fields) section below.
-
-**Singular fields (containing just a single value)**
-
-*   `_chem_comp.id`: The ID of the component. Must match the `_data` record and
-    must not contain special CIF characters (like `_` or `#`).
-*   `_chem_comp.name`: Optional full name of the component. If unknown, set to
-    `?`.
-*   `_chem_comp.type`: Type of the component, typically `non-polymer`.
-*   `_chem_comp.formula`: Optional component formula. If unknown, set to `?`.
-*   `_chem_comp.mon_nstd_parent_comp_id`: Optional parent component ID. If
-    unknown, set to `?`.
-*   `_chem_comp.pdbx_synonyms`: Optional synonym IDs. If unknown, set to `?`.
-*   `_chem_comp.formula_weight`: Optional weight of the component. If unknown,
-    set to `?`.
-
-**Per-atom fields (containing one record per atom)**
-
-*   `_chem_comp_atom.comp_id`: Component ID.
-*   `_chem_comp_atom.atom_id`: Atom ID.
-*   `_chem_comp_atom.type_symbol`: Atom element type.
-*   `_chem_comp_atom.charge`: Atom charge.
-*   `_chem_comp_atom.pdbx_leaving_atom_flag`: Optional flag determining whether
-    this is a leaving atom. If unset, assumed to be no (`N`) for all atoms.
-*   `_chem_comp_atom.pdbx_model_Cartn_x_ideal`: Ideal x coordinate.
-*   `_chem_comp_atom.pdbx_model_Cartn_y_ideal`: Ideal y coordinate.
-*   `_chem_comp_atom.pdbx_model_Cartn_z_ideal`: Ideal z coordinate.
-
-**Per-bond fields (containing one record per bond)**
-
-*   `_chem_comp_bond.atom_id_1`: The ID of the first of the two atoms that
-    define the bond.
-*   `_chem_comp_bond.atom_id_2`: The ID of the second of the two atoms that
-    define the bond.
-*   `_chem_comp_bond.value_order`: The bond order of the chemical bond
-    associated with the specified atoms.
-*   `_chem_comp_bond.pdbx_aromatic_flag`: Whether the bond is aromatic.
-
-### Model input fields
-
-The following fields are used to generate input for the model:
-
-*   `_chem_comp_atom.atom_id`: Atom ID.
-*   `_chem_comp_atom.type_symbol`: Atom element type.
-*   `_chem_comp_atom.charge`: Atom charge.
-*   `_chem_comp_atom.pdbx_model_Cartn_x_ideal`: Ideal x coordinate. Only used if
-    conformer generation fails.
-*   `_chem_comp_atom.pdbx_model_Cartn_y_ideal`: Ideal y coordinate. Only used if
-    conformer generation fails.
-*   `_chem_comp_atom.pdbx_model_Cartn_z_ideal`: Ideal z coordinate. Only used if
-    conformer generation fails.
-*   `_chem_comp_bond.atom_id_1`: The ID of the first of the two atoms that
-    define the bond.
-*   `_chem_comp_bond.atom_id_2`: The ID of the second of the two atoms that
-    define the bond.
-
-## Full Example
-
-An example illustrating all the aspects of the input format is provided below.
-Note that AlphaFold 3 won't run this input out of the box as it abbreviates
-certain fields and the sequences are not biologically meaningful.
-
-```json
-{
-  "name": "Hello fold",
-  "modelSeeds": [10, 42],
-  "sequences": [
-    {
-      "protein": {
-        "id": "A",
-        "sequence": "PVLSCGEWQL",
-        "modifications": [
-          {"ptmType": "HY3", "ptmPosition": 1},
-          {"ptmType": "P1L", "ptmPosition": 5}
-        ],
-        "unpairedMsa": ...,
-      }
-    },
-    {
-      "protein": {
-        "id": "B",
-        "sequence": "RPACQLW",
-        "templates": [
-          {
-            "mmcif": ...,
-            "queryIndices": [0, 1, 2, 4, 5, 6],
-            "templateIndices": [0, 1, 2, 3, 4, 8]
-          }
-        ]
-      }
-    },
-    {
-      "dna": {
-        "id": "C",
-        "sequence": "GACCTCT",
-        "modifications": [
-          {"modificationType": "6OG", "basePosition": 1},
-          {"modificationType": "6MA", "basePosition": 2}
-        ]
-      }
-    },
-    {
-      "rna": {
-        "id": "E",
-        "sequence": "AGCU",
-        "modifications": [
-          {"modificationType": "2MG", "basePosition": 1},
-          {"modificationType": "5MC", "basePosition": 4}
-        ],
-        "unpairedMsa": ...
-      }
-    },
-    {
-      "ligand": {
-        "id": ["F", "G", "H"],
-        "ccdCodes": ["ATP"]
-      }
-    },
-    {
-      "ligand": {
-        "id": "I",
-        "ccdCodes": ["NAG", "FUC"]
-      }
-    },
-    {
-      "ligand": {
-        "id": "Z",
-        "smiles": "CC(=O)OC1C[NH+]2CCC1CC2"
-      }
-    }
-  ],
-  "bondedAtomPairs": [
-    [["A", 1, "CA"], ["G", 1, "CHA"]],
-    [["I", 1, "O6"], ["I", 2, "C1"]]
-  ],
-  "userCCD": ...,
-  "dialect": "alphafold3",
-  "version": 3
-}
-
-```
diff --git a/docs/installation.md b/docs/installation.md
deleted file mode 100644
index ac71ba3a38af31de10c66c077239a5ffcd7a415a..0000000000000000000000000000000000000000
--- a/docs/installation.md
+++ /dev/null
@@ -1,448 +0,0 @@
-# Installation and Running Your First Prediction
-
-You will need a machine running Linux; AlphaFold 3 does not support other
-operating systems. Full installation requires up to 1 TB of disk space to keep
-genetic databases (SSD storage is recommended) and an NVIDIA GPU with Compute
-Capability 8.0 or greater (GPUs with more memory can predict larger protein
-structures). We have verified that inputs with up to 5,120 tokens can fit on a
-single NVIDIA A100 80 GB, or a single NVIDIA H100 80 GB. We have verified
-numerical accuracy on both NVIDIA A100 and H100 GPUs.
-
-Especially for long targets, the genetic search stage can consume a lot of RAM –
-we recommend running with at least 64 GB of RAM.
-
-We provide installation instructions for a machine with an NVIDIA A100 80 GB GPU
-and a clean Ubuntu 22.04 LTS installation, and expect that these instructions
-should aid others with different setups. If you are installing locally outside
-of a Docker container, please ensure CUDA, cuDNN, and JAX are correctly
-installed; the
-[JAX installation documentation](https://jax.readthedocs.io/en/latest/installation.html#nvidia-gpu)
-is a useful reference for this case. Please note that the Docker container
-requires that the host machine has CUDA 12.6 installed.
-
-The instructions provided below describe how to:
-
-1.  Provision a machine on GCP.
-1.  Install Docker.
-1.  Install NVIDIA drivers for an A100.
-1.  Obtain genetic databases.
-1.  Obtain model parameters.
-1.  Build the AlphaFold 3 Docker container or Singularity image.
-
-## Provisioning a Machine
-
-Clean Ubuntu images are available on Google Cloud, AWS, Azure, and other major
-platforms.
-
-Using an existing Google Cloud project, we provisioned a new machine:
-
-*   We recommend using `--machine-type a2-ultragpu-1g` but feel free to use
-    `--machine-type a2-highgpu-1g` for smaller predictions.
-*   If desired, replace `--zone us-central1-a` with a zone that has quota for
-    the machine you have selected. See
-    [gpu-regions-zones](https://cloud.google.com/compute/docs/gpus/gpu-regions-zones).
-
-```sh
-gcloud compute instances create alphafold3 \
-    --machine-type a2-ultragpu-1g \
-    --zone us-central1-a \
-    --image-family ubuntu-2204-lts \
-    --image-project ubuntu-os-cloud \
-    --maintenance-policy TERMINATE \
-    --boot-disk-size 1000 \
-    --boot-disk-type pd-balanced
-```
-
-This provisions a bare Ubuntu 22.04 LTS image on an
-[A2 Ultra](https://cloud.google.com/compute/docs/accelerator-optimized-machines#a2-vms)
-machine with 12 CPUs, 170 GB RAM, 1 TB disk and NVIDIA A100 80 GB GPU attached.
-We verified the following installation steps from this point.
-
-## Installing Docker
-
-These instructions are for rootless Docker.
-
-### Installing Docker on Host
-
-Note these instructions only apply to Ubuntu 22.04 LTS images, see above.
-
-Add Docker's official GPG key. Official Docker instructions are
-[here](https://docs.docker.com/engine/install/ubuntu/#install-using-the-repository).
-The commands we ran are:
-
-```sh
-sudo apt-get update
-sudo apt-get install ca-certificates curl
-sudo install -m 0755 -d /etc/apt/keyrings
-sudo curl -fsSL https://download.docker.com/linux/ubuntu/gpg -o /etc/apt/keyrings/docker.asc
-sudo chmod a+r /etc/apt/keyrings/docker.asc
-```
-
-Add the repository to apt sources:
-
-```sh
-echo \
-  "deb [arch=$(dpkg --print-architecture) signed-by=/etc/apt/keyrings/docker.asc] https://download.docker.com/linux/ubuntu \
-  $(. /etc/os-release && echo "$VERSION_CODENAME") stable" | \
-  sudo tee /etc/apt/sources.list.d/docker.list > /dev/null
-sudo apt-get update
-sudo apt-get install -y docker-ce docker-ce-cli containerd.io docker-buildx-plugin docker-compose-plugin
-sudo docker run hello-world
-```
-
-### Enabling Rootless Docker
-
-Official Docker instructions are
-[here](https://docs.docker.com/engine/security/rootless/#distribution-specific-hint).
-The commands we ran are:
-
-```sh
-sudo apt-get install -y uidmap systemd-container
-
-sudo machinectl shell $(whoami)@ /bin/bash -c 'dockerd-rootless-setuptool.sh install && sudo loginctl enable-linger $(whoami) && DOCKER_HOST=unix:///run/user/1001/docker.sock docker context use rootless'
-```
-
-## Installing GPU Support
-
-### Installing NVIDIA Drivers
-
-Official Ubuntu instructions are
-[here](https://documentation.ubuntu.com/server/how-to/graphics/install-nvidia-drivers/).
-The commands we ran are:
-
-```sh
-sudo apt-get -y install alsa-utils ubuntu-drivers-common
-sudo ubuntu-drivers install
-
-sudo nvidia-smi --gpu-reset
-
-nvidia-smi  # Check that the drivers are installed.
-```
-
-Accept the "Pending kernel upgrade" dialog if it appears.
-
-You will need to reboot the instance with `sudo reboot now` to reset the GPU if
-you see the following warning:
-
-```text
-NVIDIA-SMI has failed because it couldn't communicate with the NVIDIA driver.
-Make sure that the latest NVIDIA driver is installed and running.
-```
-
-Proceed only if `nvidia-smi` has a sensible output.
-
-### Installing NVIDIA Support for Docker
-
-Official NVIDIA instructions are
-[here](https://docs.nvidia.com/datacenter/cloud-native/container-toolkit/install-guide.html).
-The commands we ran are:
-
-```sh
-curl -fsSL https://nvidia.github.io/libnvidia-container/gpgkey | sudo gpg --dearmor -o /usr/share/keyrings/nvidia-container-toolkit-keyring.gpg \
-  && curl -s -L https://nvidia.github.io/libnvidia-container/stable/deb/nvidia-container-toolkit.list | \
-    sed 's#deb https://#deb [signed-by=/usr/share/keyrings/nvidia-container-toolkit-keyring.gpg] https://#g' | \
-    sudo tee /etc/apt/sources.list.d/nvidia-container-toolkit.list
-sudo apt-get update
-sudo apt-get install -y nvidia-container-toolkit
-nvidia-ctk runtime configure --runtime=docker --config=$HOME/.config/docker/daemon.json
-systemctl --user restart docker
-sudo nvidia-ctk config --set nvidia-container-cli.no-cgroups --in-place
-```
-
-Check that your container can see the GPU:
-
-```sh
-docker run --rm --gpus all nvidia/cuda:12.6.0-base-ubuntu22.04 nvidia-smi
-```
-
-Example output:
-
-```text
-Mon Nov  11 12:00:00 2024
-+-----------------------------------------------------------------------------------------+
-| NVIDIA-SMI 550.120                Driver Version: 550.120        CUDA Version: 12.6     |
-|-----------------------------------------+------------------------+----------------------+
-| GPU  Name                 Persistence-M | Bus-Id          Disp.A | Volatile Uncorr. ECC |
-| Fan  Temp   Perf          Pwr:Usage/Cap |           Memory-Usage | GPU-Util  Compute M. |
-|                                         |                        |               MIG M. |
-|=========================================+========================+======================|
-|   0  NVIDIA A100-SXM4-80GB          Off |   00000000:00:05.0 Off |                    0 |
-| N/A   34C    P0             51W /  400W |       1MiB /  81920MiB |      0%      Default |
-|                                         |                        |             Disabled |
-+-----------------------------------------+------------------------+----------------------+
-
-+-----------------------------------------------------------------------------------------+
-| Processes:                                                                              |
-|  GPU   GI   CI        PID   Type   Process name                              GPU Memory |
-|        ID   ID                                                               Usage      |
-|=========================================================================================|
-|  No running processes found                                                             |
-+-----------------------------------------------------------------------------------------+
-```
-
-## Obtaining AlphaFold 3 Source Code
-
-Install `git` and download the AlphaFold 3 repository:
-
-```sh
-git clone https://github.com/google-deepmind/alphafold3.git
-```
-
-## Obtaining Genetic Databases
-
-This step requires `wget` and `zstd` to be installed on your machine. On
-Debian-based systems install them by running `sudo apt install wget zstd`.
-
-AlphaFold 3 needs multiple genetic (sequence) protein and RNA databases to run:
-
-*   [BFD small](https://bfd.mmseqs.com/)
-*   [MGnify](https://www.ebi.ac.uk/metagenomics/)
-*   [PDB](https://www.rcsb.org/) (structures in the mmCIF format)
-*   [PDB seqres](https://www.rcsb.org/)
-*   [UniProt](https://www.uniprot.org/uniprot/)
-*   [UniRef90](https://www.uniprot.org/help/uniref)
-*   [NT](https://www.ncbi.nlm.nih.gov/nucleotide/)
-*   [RFam](https://rfam.org/)
-*   [RNACentral](https://rnacentral.org/)
-
-We provide a bash script `fetch_databases.sh` that can be used to download and
-set up all of these databases. This process takes around 45 minutes when not
-installing on local SSD. We recommend running the following in a `screen` or
-`tmux` session as downloading and decompressing the databases takes some time.
-
-```sh
-cd alphafold3  # Navigate to the directory with cloned AlphaFold 3 repository.
-./fetch_databases.sh [<DB_DIR>]
-```
-
-This script downloads the databases from a mirror hosted on GCS, with all
-versions being the same as used in the AlphaFold 3 paper, to the directory
-`<DB_DIR>`. If not specified, the default `<DB_DIR>` is
-`$HOME/public_databases`.
-
-:ledger: **Note: The download directory `<DB_DIR>` should *not* be a
-subdirectory in the AlphaFold 3 repository directory.** If it is, the Docker
-build will be slow as the large databases will be copied during the image
-creation.
-
-:ledger: **Note: The total download size for the full databases is around 252 GB
-and the total size when unzipped is 630 GB. Please make sure you have sufficient
-hard drive space, bandwidth, and time to download. We recommend using an SSD for
-better genetic search performance.**
-
-:ledger: **Note: If the download directory and datasets don't have full read and
-write permissions, it can cause errors with the MSA tools, with opaque
-(external) error messages. Please ensure the required permissions are applied,
-e.g. with the `sudo chmod 755 --recursive <DB_DIR>` command.**
-
-Once the script has finished, you should have the following directory structure:
-
-```sh
-mmcif_files/  # Directory containing ~200k PDB mmCIF files.
-bfd-first_non_consensus_sequences.fasta
-mgy_clusters_2022_05.fa
-nt_rna_2023_02_23_clust_seq_id_90_cov_80_rep_seq.fasta
-pdb_seqres_2022_09_28.fasta
-rfam_14_9_clust_seq_id_90_cov_80_rep_seq.fasta
-rnacentral_active_seq_id_90_cov_80_linclust.fasta
-uniprot_all_2021_04.fa
-uniref90_2022_05.fa
-```
-
-Optionally, after the script finishes, you may want copy databases to an SSD.
-You can use theses two scripts:
-
-*   `src/scripts/gcp_mount_ssd.sh [<SSD_MOUNT_PATH>]` Mounts and formats an
-    unmounted GCP SSD drive to the specified path. It will skip the either step
-    if the disk is either already formatted or already mounted. The default
-    `<SSD_MOUNT_PATH>` is `/mnt/disks/ssd`.
-*   `src/scripts/copy_to_ssd.sh [<DB_DIR>] [<SSD_DB_DIR>]` this will copy as
-    many files that it can fit on to the SSD. The default `<DB_DIR>` is
-    `$HOME/public_databases`, and must match the path used in the
-    `fetch_databases.sh` command above, and the default `<SSD_DB_DIR>` is
-    `/mnt/disks/ssd/public_databases`.
-
-## Obtaining Model Parameters
-
-To request access to the AlphaFold 3 model parameters, please complete
-[this form](https://forms.gle/svvpY4u2jsHEwWYS6). Access will be granted at
-Google DeepMind’s sole discretion. We will aim to respond to requests within 2–3
-business days. You may only use AlphaFold 3 model parameters if received
-directly from Google. Use is subject to these
-[terms of use](https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md).
-
-Once access has been granted, download the model parameters to a directory of
-your choosing, referred to as `<MODEL_PARAMETERS_DIR>` in the following
-instructions. As with the databases, this should *not* be a subdirectory in the
-AlphaFold 3 repository directory.
-
-## Building the Docker Container That Will Run AlphaFold 3
-
-Then, build the Docker container. This builds a container with all the right
-python dependencies:
-
-```sh
-docker build -t alphafold3 -f docker/Dockerfile .
-```
-
-Create an input JSON file, using either the example in the
-[README](https://github.com/google-deepmind/alphafold3?tab=readme-ov-file#installation-and-running-your-first-prediction)
-or a
-[custom input](https://github.com/google-deepmind/alphafold3/blob/main/docs/input.md),
-and place it in a directory, e.g. `$HOME/af_input`. You can now run AlphaFold 3!
-
-```sh
-docker run -it \
-    --volume $HOME/af_input:/root/af_input \
-    --volume $HOME/af_output:/root/af_output \
-    --volume <MODEL_PARAMETERS_DIR>:/root/models \
-    --volume <DB_DIR>:/root/public_databases \
-    --gpus all \
-    alphafold3 \
-    python run_alphafold.py \
-    --json_path=/root/af_input/fold_input.json \
-    --model_dir=/root/models \
-    --output_dir=/root/af_output
-```
-
-where `$HOME/af_input` is the directory containing the input JSON file;
-`$HOME/af_output` is the directory where the output will be written to; and
-`<DB_DIR>` and `<MODEL_PARAMETERS_DIR>` are the directories containing the
-databases and model parameters. The values of these directories must match the
-directories used in previous steps for downloading databases and model weights,
-and for the input file.
-
-:ledger: Note: You may also need to create the output directory,
-`$HOME/af_output` directory before running the `docker` command and make it and
-the input directory writable from the docker container, e.g. by running `chmod
-755 $HOME/af_input $HOME/af_output`. In most cases `docker` and
-`run_alphafold.py` will create the output directory if it does not exist.
-
-:ledger: **Note: In the example above the databases have been placed on the
-persistent disk, which is slow.** If you want better genetic and template search
-performance, make sure all databases are placed on a local SSD.
-
-If you have some databases on an SSD in the `<SSD_DB_DIR>` directory and some
-databases on a slower disk in the `<DB_DIR>` directory, you can mount both
-directories and specify `db_dir` multiple times. This will enable the fast
-access to databases with a fallback to the larger, slower disk:
-
-```sh
-docker run -it \
-    --volume $HOME/af_input:/root/af_input \
-    --volume $HOME/af_output:/root/af_output \
-    --volume <MODEL_PARAMETERS_DIR>:/root/models \
-    --volume <SSD_DB_DIR>:/root/public_databases \
-    --volume <DB_DIR>:/root/public_databases_fallback \
-    --gpus all \
-    alphafold3 \
-    python run_alphafold.py \
-    --json_path=/root/af_input/fold_input.json \
-    --model_dir=/root/models \
-    --db_dir=/root/public_databases \
-    --db_dir=/root/public_databases_fallback \
-    --output_dir=/root/af_output
-```
-
-If you get an error like the following, make sure the models and data are in the
-paths (flags named `--volume` above) in the correct locations.
-
-```
-docker: Error response from daemon: error while creating mount source path '/srv/alphafold3_data/models': mkdir /srv/alphafold3_data/models: permission denied.
-```
-
-`run_alphafold.py` supports many flags for controlling performance, running on
-multiple input files, specifying external binary paths, and more. See
-
-```sh
-docker run alphafold3 python run_alphafold.py --help
-```
-
-for more information.
-
-## Running Using Singularity Instead of Docker
-
-You may prefer to run AlphaFold 3 within Singularity. You'll still need to
-*build* the Singularity image from the Docker container. Afterwards, you will
-not have to depend on Docker (at structure prediction time).
-
-### Install Singularity
-
-Official Singularity instructions are
-[here](https://docs.sylabs.io/guides/3.3/user-guide/installation.html). The
-commands we ran are:
-
-```sh
-wget https://github.com/sylabs/singularity/releases/download/v4.2.1/singularity-ce_4.2.1-jammy_amd64.deb
-sudo dpkg --install singularity-ce_4.2.1-jammy_amd64.deb
-sudo apt-get install -f
-```
-
-### Build the Singularity Container From the Docker Image
-
-After building the *Docker* container above with `docker build -t`, start a
-local Docker registry and upload your image `alphafold3` to it. Singularity's
-instructions are [here](https://github.com/apptainer/singularity/issues/1537).
-The commands we ran are:
-
-```sh
-docker run -d -p 5000:5000 --restart=always --name registry registry:2
-docker tag alphafold3 localhost:5000/alphafold3
-docker push localhost:5000/alphafold3
-```
-
-Then build the Singularity container:
-
-```sh
-SINGULARITY_NOHTTPS=1 singularity build alphafold3.sif docker://localhost:5000/alphafold3:latest
-```
-
-You can confirm your build by starting a shell and inspecting the environment.
-For example, you may want to ensure the Singularity image can access your GPU.
-You may want to restart your computer if you have issues with this.
-
-```sh
-singularity exec --nv alphafold3.sif sh -c 'nvidia-smi'
-```
-
-You can now run AlphaFold 3!
-
-```sh
-singularity exec --nv alphafold3.sif <<args>>
-```
-
-For example:
-
-```sh
-singularity exec \
-     --nv \
-     --bind $HOME/af_input:/root/af_input \
-     --bind $HOME/af_output:/root/af_output \
-     --bind <MODEL_PARAMETERS_DIR>:/root/models \
-     --bind <DB_DIR>:/root/public_databases \
-     alphafold3.sif \
-     python run_alphafold.py \
-     --json_path=/root/af_input/fold_input.json \
-     --model_dir=/root/models \
-     --db_dir=/root/public_databases \
-     --output_dir=/root/af_output
-```
-
-Or with some databases on SSD in location `<SSD_DB_DIR>`:
-
-```sh
-singularity exec \
-     --nv \
-     --bind $HOME/af_input:/root/af_input \
-     --bind $HOME/af_output:/root/af_output \
-     --bind <MODEL_PARAMETERS_DIR>:/root/models \
-     --bind <SSD_DB_DIR>:/root/public_databases \
-     --bind <DB_DIR>:/root/public_databases_fallback \
-     alphafold3.sif \
-     python run_alphafold.py \
-     --json_path=/root/af_input/fold_input.json \
-     --model_dir=/root/models \
-     --db_dir=/root/public_databases \
-     --db_dir=/root/public_databases_fallback \
-     --output_dir=/root/af_output
-```
diff --git a/docs/known_issues.md b/docs/known_issues.md
deleted file mode 100644
index 2f0be4f76b86d67e3171af98a2eb2533b1fb788b..0000000000000000000000000000000000000000
--- a/docs/known_issues.md
+++ /dev/null
@@ -1,15 +0,0 @@
-# Known Issues
-
-## Numerical performance for CUDA Capability 7.x GPUs
-
-All CUDA Capability 7.x GPUs (e.g. V100) produce obviously bad output, with lots
-of clashing residues (the clashes cause a ranking score of -99 or lower), unless
-the environment variable `XLA_FLAGS` is set to include
-`--xla_disable_hlo_passes=custom-kernel-fusion-rewriter`.
-
-## Incorrect handling of two-letter atoms in SMILES ligands
-
-Between commits https://github.com/google-deepmind/alphafold3/commit/f8df1c7 and
-https://github.com/google-deepmind/alphafold3/commit/4e4023c, AlphaFold 3
-handled incorrectly any two-letter atoms (e.g. Cl, Br) in ligands defined using
-SMILES strings.
diff --git a/docs/metadata_antibody_antigen.csv b/docs/metadata_antibody_antigen.csv
deleted file mode 100644
index 8c256123a9e3a5bf0726d5806216bb6c0da76adc..0000000000000000000000000000000000000000
--- a/docs/metadata_antibody_antigen.csv
+++ /dev/null
@@ -1,167 +0,0 @@
-pdb_id,chain_id_1,chain_id_2,cluster_key_chain_1,cluster_key_chain_2,interface_cluster_key
-7fci,A,B,5581,5964,5581|5964
-7fci,A,C,5581,17640,17640|5581
-7mnl,A,C,8677,17640,17640|8677
-7n0a,A,B,33602,5964,33602|5964
-7n0a,A,C,33602,17640,17640|33602
-7ox1,A,G,17640,41184,17640|41184
-7ox1,B,G,5964,41184,41184|5964
-7ox2,A,C,17640,41184,17640|41184
-7ox2,B,C,5964,41184,41184|5964
-7ox3,A,C,5964,41184,41184|5964
-7ox3,B,C,17640,41184,17640|41184
-7ox4,A,C,17640,41184,17640|41184
-7ox4,B,C,5964,41184,41184|5964
-7q6c,A,B,15496,17640,15496|17640
-7q6c,A,D,15496,5964,15496|5964
-7r58,A,B,30790,17640,17640|30790
-7r58,A,C,30790,5964,30790|5964
-7ru6,A,B,7068,17640,17640|7068
-7sbd,A,C,17640,20692,17640|20692
-7sbd,B,C,5964,20692,20692|5964
-7sbg,A,C,17640,20692,17640|20692
-7sbg,B,C,5964,20692,20692|5964
-7sjo,A,F,7390,17640,17640|7390
-7sjo,A,I,7390,5964,5964|7390
-7sjo,B,G,7390,17640,17640|7390
-7sjo,B,H,7390,5964,5964|7390
-7sjo,C,D,7390,17640,17640|7390
-7sjo,C,E,7390,5964,5964|7390
-7sk3,A,C,45640,5964,45640|5964
-7sk3,A,D,45640,17640,17640|45640
-7sk3,A,E,45640,5964,45640|5964
-7sk3,A,F,45640,17640,17640|45640
-7sk4,A,C,45640,5964,45640|5964
-7sk4,A,D,45640,17640,17640|45640
-7sk4,A,E,45640,5964,45640|5964
-7sk4,A,F,45640,17640,17640|45640
-7sk5,A,B,45640,17640,17640|45640
-7sk5,A,D,45640,5964,45640|5964
-7sk6,A,C,45640,5964,45640|5964
-7sk6,A,D,45640,17640,17640|45640
-7sk7,A,C,45640,5964,45640|5964
-7sk7,A,D,45640,17640,17640|45640
-7sk8,A,C,45640,5964,45640|5964
-7sk8,A,D,45640,17640,17640|45640
-7sk8,A,E,45640,5964,45640|5964
-7sk8,A,F,45640,17640,17640|45640
-7sk9,A,B,45640,17640,17640|45640
-7sk9,A,C,45640,5964,45640|5964
-7st8,A,C,17640,41188,17640|41188
-7st8,B,C,5964,41188,41188|5964
-7t6x,E,H,5964,24273,24273|5964
-7t82,A,C,9703,5964,5964|9703
-7t82,A,D,9703,17640,17640|9703
-7t9m,A,C,17640,13210,13210|17640
-7t9m,B,C,5964,13210,13210|5964
-7t9n,A,D,5964,13210,13210|5964
-7t9n,B,D,17640,13210,13210|17640
-7tuf,A,B,22549,17640,17640|22549
-7tuf,A,C,22549,5964,22549|5964
-7tuf,A,E,22549,17640,17640|22549
-7tuf,B,D,17640,22549,17640|22549
-7tuf,D,E,22549,17640,17640|22549
-7tuf,D,F,22549,5964,22549|5964
-7tug,A,B,22549,17640,17640|22549
-7tug,A,C,22549,5964,22549|5964
-7u8c,A,B,20081,17640,17640|20081
-7u8c,A,C,20081,5964,20081|5964
-7u8g,A,C,29632,17640,17640|29632
-7u8g,A,D,29632,5964,29632|5964
-7uih,A,B,11223,5964,11223|5964
-7uih,A,C,11223,17640,11223|17640
-7uih,A,D,11223,5964,11223|5964
-7uih,A,E,11223,17640,11223|17640
-7um3,A,E,17640,33649,17640|33649
-7um3,B,E,5964,33649,33649|5964
-7ura,A,B,44530,5964,44530|5964
-7ura,A,C,44530,17640,17640|44530
-7urc,A,B,44530,5964,44530|5964
-7urc,A,C,44530,17640,17640|44530
-7urd,A,C,44530,5964,44530|5964
-7urd,A,D,44530,17640,17640|44530
-7ure,A,B,44530,5964,44530|5964
-7ure,A,C,44530,17640,17640|44530
-7uvf,A,C,23558,17640,17640|23558
-7uvf,A,D,23558,5964,23558|5964
-7uvf,B,E,23558,5964,23558|5964
-7uvf,B,F,23558,17640,17640|23558
-7vad,A,B,5581,17640,17640|5581
-7vad,A,C,5581,5964,5581|5964
-7vae,A,B,5581,17640,17640|5581
-7vae,A,C,5581,5964,5581|5964
-7vaf,A,C,17640,5581,17640|5581
-7vaf,B,C,5964,5581,5581|5964
-7vag,A,B,5581,17640,17640|5581
-7vag,A,C,5581,5964,5581|5964
-7vgr,A,E,5964,33673,33673|5964
-7vgr,A,F,5964,33673,33673|5964
-7vgr,B,E,17640,33673,17640|33673
-7vgr,B,F,17640,33673,17640|33673
-7vgr,C,E,5964,33673,33673|5964
-7vgr,C,F,5964,33673,33673|5964
-7vgr,D,E,17640,33673,17640|33673
-7vgr,D,F,17640,33673,17640|33673
-7vgs,A,B,33673,5964,33673|5964
-7vgs,A,C,33673,17640,17640|33673
-7vgs,A,E,33673,5964,33673|5964
-7vgs,B,D,5964,33673,33673|5964
-7vgs,D,E,33673,5964,33673|5964
-7vgs,D,F,33673,17640,17640|33673
-7vn9,A,C,17640,20046,17640|20046
-7vn9,B,C,5964,20046,20046|5964
-7vng,A,B,20046,17640,17640|20046
-7vng,A,C,20046,5964,20046|5964
-7w71,A,E,24335,17640,17640|24335
-7w71,A,F,24335,5964,24335|5964
-7wsi,A,B,5581,17640,17640|5581
-7wsi,A,C,5581,5964,5581|5964
-7xq8,A,B,26372,5964,26372|5964
-7xq8,C,D,26372,5964,26372|5964
-7zlg,A,D,17640,29547,17640|29547
-7zlg,C,D,5964,29547,29547|5964
-7zlh,A,D,17640,29547,17640|29547
-7zlh,C,D,5964,29547,29547|5964
-7zli,A,D,17640,29547,17640|29547
-7zli,C,D,5964,29547,29547|5964
-7zlj,A,D,17640,29547,17640|29547
-7zlj,C,D,5964,29547,29547|5964
-7zwi,A,C,7003,5964,5964|7003
-7zxf,A,C,7003,5964,5964|7003
-7zxf,A,E,7003,5964,5964|7003
-7zxg,A,C,7003,5964,5964|7003
-7zxk,A,F,26707,5964,26707|5964
-7zxk,A,G,26707,17640,17640|26707
-7zyi,A,B,5581,17640,17640|5581
-7zyi,A,C,5581,5964,5581|5964
-8cz5,A,B,24059,17640,17640|24059
-8cz5,A,C,24059,5964,24059|5964
-8dcy,A,C,17640,23342,17640|23342
-8dcy,B,C,5964,23342,23342|5964
-8ddk,A,C,17640,23342,17640|23342
-8ddk,B,C,5964,23342,23342|5964
-8djk,A,E,15456,17640,15456|17640
-8djk,B,D,15455,5964,15455|5964
-8djk,B,E,15455,17640,15455|17640
-8djm,A,E,15456,17640,15456|17640
-8djm,B,D,15455,5964,15455|5964
-8djm,B,E,15455,17640,15455|17640
-8dke,A,B,13979,17640,13979|17640
-8dke,A,C,13979,5964,13979|5964
-8dki,A,B,13979,17640,13979|17640
-8dki,A,C,13979,5964,13979|5964
-8dkm,A,C,17640,13979,13979|17640
-8dkm,B,C,5964,13979,13979|5964
-8dkw,A,C,17640,13979,13979|17640
-8dkw,B,C,5964,13979,13979|5964
-8dkx,A,C,17640,13979,13979|17640
-8dkx,B,C,5964,13979,13979|5964
-8hii,A,B,21158,17640,17640|21158
-8hii,A,D,21158,5964,21158|5964
-8hij,A,B,21158,17640,17640|21158
-8hij,A,D,21158,5964,21158|5964
-8hik,A,B,21158,17640,17640|21158
-8hik,A,D,21158,5964,21158|5964
-7so7,A,F,3006,5964,3006|5964
-7xy8,A,C,2517,17640,17640|2517
-7xy8,A,E,2517,5964,2517|5964
\ No newline at end of file
diff --git a/docs/metadata_antibody_antigen.md b/docs/metadata_antibody_antigen.md
deleted file mode 100644
index dcaba93eccf3342de8832c8eb464a4c71db19643..0000000000000000000000000000000000000000
--- a/docs/metadata_antibody_antigen.md
+++ /dev/null
@@ -1,11 +0,0 @@
-# Metadata for Antibody-Antigen pairs used to create figure 5a
-
-Figure 5a in the AlphaFold 3 paper was created using 71 antibody–antigen
-complexes, containing 166 antibody–antigen interfaces spanning 65 interface
-clusters. Scores were averaged within each interface cluster then across
-clusters. Note that the first bioassembly is used in all cases.
-
-We provide metadata for these complexes and the associated clusters in this CSV
-file:
-
-https://github.com/google-deepmind/alphafold3/blob/main/docs/metadata_antibody_antigen.csv
diff --git a/docs/output.md b/docs/output.md
deleted file mode 100644
index 2850d54cb6bcd55c2a45e01818d7119fc1fa0b35..0000000000000000000000000000000000000000
--- a/docs/output.md
+++ /dev/null
@@ -1,229 +0,0 @@
-# AlphaFold 3 Output
-
-## Output Directory Structure
-
-For every input job, AlphaFold 3 writes all its outputs in a directory called by
-the sanitized version of the job name. E.g. for job name "My first fold (test)",
-AlphaFold 3 will write its outputs in a directory called `my_first_fold_test`.
-If such directory already exists, AlphaFold 3 will append a timestamp to the
-directory name to avoid overwriting existing data.
-
-The following structure is used within the output directory:
-
-*   Sub-directories with results for each sample and seed. There will be
-    *num\_seeds* \* *num\_samples* such sub-directories. The naming pattern is
-    `seed-<seed value>_sample-<sample number>`. Each of these directories
-    contains a confidence JSON, summary confidence JSON, and the mmCIF with the
-    predicted structure.
-*   Embeddings for each seed: `seed-<seed value>_embeddings/embeddings.npz`.
-    Only saved if AlphaFold 3 is run with `--save_embeddings=true`.
-*   Top-ranking prediction mmCIF: `<job_name>_model.cif`. This file contains the
-    predicted coordinates and should be compatible with most structural biology
-    tools. We do not provide the output in the PDB format, the CIF file can be
-    easily converted into one if needed.
-*   Top-ranking prediction confidence JSON: `<job_name>_confidences.json`.
-*   Top-ranking prediction summary confidence JSON:
-    `<job_name>_summary_confidences.json`.
-*   Job input JSON file with the MSA and template data added by the data
-    pipeline: `<job_name>_data.json`.
-*   Ranking scores for all predictions: `ranking_scores.csv`. The prediction
-    with highest ranking is the one included in the root directory.
-*   Output terms of use: `TERMS_OF_USE.md`.
-
-Below is an example AlphaFold 3 output directory listing for a job called "Hello
-Fold", that has been ran with 1 seed and 5 samples:
-
-```txt
-hello_fold/
-├── seed-1234_embeddings                       # Only if --save_embeddings=true.
-│   └── hello_fold_seed-1234_embeddings.npz    # Only if --save_embeddings=true.
-├── seed-1234_sample-0/
-│   ├── hello_fold_seed-1234_sample-0_confidences.json
-│   ├── hello_fold_seed-1234_sample-0_model.cif
-│   └── hello_fold_seed-1234_sample-0_summary_confidences.json
-├── seed-1234_sample-1/
-│   ├── hello_fold_seed-1234_sample-1_confidences.json
-│   ├── hello_fold_seed-1234_sample-1_model.cif
-│   └── hello_fold_seed-1234_sample-1_summary_confidences.json
-├── seed-1234_sample-2/
-│   ├── hello_fold_seed-1234_sample-2_confidences.json
-│   ├── hello_fold_seed-1234_sample-2_model.cif
-│   └── hello_fold_seed-1234_sample-2_summary_confidences.json
-├── seed-1234_sample-3/
-│   ├── hello_fold_seed-1234_sample-3_confidences.json
-│   ├── hello_fold_seed-1234_sample-3_model.cif
-│   └── hello_fold_seed-1234_sample-3_summary_confidences.json
-├── seed-1234_sample-4/
-│   ├── hello_fold_seed-1234_sample-4_confidences.json
-│   ├── hello_fold_seed-1234_sample-4_model.cif
-│   └── hello_fold_seed-1234_sample-4_summary_confidences.json
-├── TERMS_OF_USE.md
-├── hello_fold_confidences.json
-├── hello_fold_data.json
-├── hello_fold_model.cif
-├── hello_fold_ranking_scores.csv
-└── hello_fold_summary_confidences.json
-```
-
-## Confidence Metrics
-
-Similar to AlphaFold 2 and AlphaFold-Multimer, AlphaFold 3 outputs include
-confidence metrics. The main metrics are:
-
-*   **pLDDT:** a per-atom confidence estimate on a 0-100 scale where a higher
-    value indicates higher confidence. pLDDT aims to predict a modified LDDT
-    score that only considers distances to polymers. For proteins this is
-    similar to the
-    [lDDT-Cα metric](https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3799472/) but
-    with more granularity as it can vary per atom not just per residue. For
-    ligand atoms, the modified LDDT considers the errors only between the ligand
-    atom and polymers, not other ligand atoms. For DNA/RNA a wider radius of 30
-    Ã… is used for the modified LDDT instead of 15 Ã….
-*   **PAE (predicted aligned error)**: an estimate of the error in the relative
-    position and orientation between two tokens in the predicted structure.
-    Higher values indicate higher predicted error and therefore lower
-    confidence. For proteins and nucleic acids, PAE score is essentially the
-    same as AlphaFold 2, where the error is measured relative to frames
-    constructed from the protein backbone. For small molecules and
-    post-translational modifications, a frame is constructed for each atom from
-    its closest neighbors from a reference conformer.
-*   **pTM and ipTM scores**: the predicted template modeling (pTM) score and the
-    interface predicted template modeling (ipTM) score are both derived from a
-    measure called the template modeling (TM) score. This measures the accuracy
-    of the entire structure
-    ([Zhang and Skolnick, 2004](https://doi.org/10.1002/prot.20264);
-    [Xu and Zhang, 2010](https://doi.org/10.1093/bioinformatics/btq066)). A pTM
-    score above 0.5 means the overall predicted fold for the complex might be
-    similar to the true structure. ipTM measures the accuracy of the predicted
-    relative positions of the subunits within the complex. Values higher than
-    0.8 represent confident high-quality predictions, while values below 0.6
-    suggest a failed prediction. ipTM values between 0.6 and 0.8 are a gray zone
-    where predictions could be correct or incorrect. The TM score is very strict
-    for small structures or short chains, so pTM assigns values less than 0.05
-    when fewer than 20 tokens are involved; for these cases PAE or pLDDT may be
-    more indicative of prediction quality.
-
-For detailed description of these confidence metrics see the
-[AlphaFold 3 paper](https://www.nature.com/articles/s41586-024-07487-w). For
-protein components, the
-[AlphaFold: A Practical guide](https://www.ebi.ac.uk/training/online/courses/alphafold/inputs-and-outputs/evaluating-alphafolds-predicted-structures-using-confidence-scores/)
-course for structures provides additional tutorials on the confidence metrics.
-
-If you are interested in a specific entity or interaction, then there are
-confidences available in the outputs which are specific to each chain or
-chain-pair, as opposed to the full complex. See below for more details on all
-the confidence metrics that are returned.
-
-## Multi-Seed and Multi-Sample Results
-
-By default, the model samples five predictions per seed. The top-ranked
-prediction across all samples and seeds is available at the top-level of the
-output directory. All samples along with their associated confidences are
-available in subdirectories of the output directory.
-
-For ranking of the full complex use the `ranking_score` (higher is better). This
-score uses overall structure confidences (pTM and ipTM), but also includes terms
-that penalize clashes and encourage disordered regions not to have spurious
-helices – these extra terms mean the score should only be used to rank
-structures.
-
-If you are interested in a specific entity or interaction, you may want to rank
-by a metric specific to that chain or chain-pair, as opposed to the full
-complex. In that case, use the per chain or per chain-pair confidence metrics
-described below for ranking.
-
-## Metrics in Confidences JSON
-
-For each predicted sample we provide two JSON files. One contains summary
-metrics – summaries for either the whole structure, per chain or per chain-pair
-– and the other contains full 1D or 2D arrays.
-
-Summary outputs:
-
-*   `ptm`: A scalar in the range 0-1 indicating the predicted TM-score for the
-    full structure.
-*   `iptm`: A scalar in the range 0-1 indicating predicted interface TM-score
-    (confidence in the predicted interfaces) for all interfaces in the
-    structure.
-*   `fraction_disordered`: A scalar in the range 0-1 that indicates what
-    fraction of the prediction structure is disordered, as measured by
-    accessible surface area, see our
-    [paper](https://www.nature.com/articles/s41586-024-07487-w) for details.
-*   `has_clash`: A boolean indicating if the structure has a significant number
-    of clashing atoms (more than 50% of a chain, or a chain with more than 100
-    clashing atoms).
-*   `ranking_score`: A scalar in the range \[-100, 1.5\] that can be used for
-    ranking predictions, it incorporates `ptm`, `iptm`, `fraction_disordered`
-    and `has_clash` into a single number with the following equation: 0.8 × ipTM
-    \+ 0.2 × pTM \+ 0.5 × disorder − 100 × has_clash.
-*   `chain_pair_pae_min`: A \[num_chains, num_chains\] array. Element (i, j) of
-    the array contains the lowest PAE value across rows restricted to chain i
-    and columns restricted to chain j. This has been found to correlate with
-    whether two chains interact or not, and in some cases can be used to
-    distinguish binders from non-binders.
-*   `chain_pair_iptm`: A \[num_chains, num_chains\] array. Off-diagonal element
-    (i, j) of the array contains the ipTM restricted to tokens from chains i and
-    j. Diagonal element (i, i) contains the pTM restricted to chain i. Can be
-    used for ranking a specific interface between two chains, when you know that
-    they interact, e.g. for antibody-antigen interactions
-*   `chain_ptm`: A \[num_chains\] array. Element i contains the pTM restricted
-    to chain i. Can be used for ranking individual chains when the structure of
-    that chain is most of interest, rather than the cross-chain interactions it
-    is involved with.
-*   `chain_iptm:` A \[num_chains\] array that gives the average confidence
-    (interface pTM) in the interface between each chain and all other chains.
-    Can be used for ranking a specific chain, when you care about where the
-    chain binds to the rest of the complex and you do not know which other
-    chains you expect it to interact with. This is often the case with ligands.
-
-Full array outputs:
-
-*   `pae`: A \[num\_tokens, num\_tokens\] array. Element (i, j) indicates the
-    predicted error in the position of token j, when the prediction is aligned
-    to the ground truth using the frame of token i.
-*   `atom_plddts`: A \[num_atoms\] array, element i indicates the predicted
-    local distance difference test (pLDDT) for atom i in the prediction.
-*   `contact_probs`: A \[num_tokens, num_tokens\] array. Element (i, j)
-    indicates the predicted probability that token i and token j are in contact
-    (8 Ã… between the representative atom for each token), see
-    [paper](https://www.nature.com/articles/s41586-024-07487-w) for details.
-*   `token_chain_ids`: A \[num_tokens\] array indicating the chain ids
-    corresponding to each token in the prediction.
-*   `atom_chain_ids`: A \[num_atoms\] array indicating the chain ids
-    corresponding to each atom in the prediction.
-
-## Embeddings
-
-AlphaFold 3 can be run with `--save_embeddings=true` to save the embeddings for
-each seed. The file is in the
-[compressed Numpy `.npz` format](https://numpy.org/doc/stable/reference/generated/numpy.savez_compressed.html)
-and can be loaded using `numpy.load` as a dictionary-like object with two
-arrays:
-
-*   `single_embeddings`: A \`[num\_tokens, 384\] array containing the embeddings
-    for each token.
-*   `pair_embeddings`: A \[num\_tokens, num\_tokens, 128\] array containing the
-    pairwise embeddings between all tokens.
-
-You can use for instance the following Python code to load the embeddings:
-
-```py
-import numpy as np
-
-with open('embeddings.npz', 'rb') as f:
-  embeddings = np.load(f)
-  single_embeddings = embeddings['single_embeddings']
-  pair_embeddings = embeddings['pair_embeddings']
-```
-
-## Chirality checks
-
-In the AlphaFold 3 paper Posebusters results, a penalty was applied to the
-ranking score if the ligand of interest contained chiral errors. By running
-multiple seeds and using this chiral aware ranking, chiral error rates were
-greatly reduced.
-
-We provide the method `compare_chirality` in
-[`model/scoring/chirality.py`](https://github.com/google-deepmind/alphafold3/blob/main/src/alphafold3/model/scoring/chirality.py)
-to replicate these chiral checks. Chirality is checked against CCD structures if
-available, otherwise users can supply custom RDKit Mol objects for comparison.
diff --git a/docs/performance.md b/docs/performance.md
deleted file mode 100644
index 58717d7d8de97161dbb0add13eb123248a3c0092..0000000000000000000000000000000000000000
--- a/docs/performance.md
+++ /dev/null
@@ -1,236 +0,0 @@
-# Performance
-
-## Data Pipeline
-
-The runtime of the data pipeline (i.e. genetic sequence search and template
-search) can vary significantly depending on the size of the input and the number
-of homologous sequences found, as well as the available hardware (disk speed can
-influence genetic search speed in particular). If you would like to improve
-performance, it’s recommended to increase the disk speed (e.g. by leveraging a
-RAM-backed filesystem), or increase the available CPU cores and add more
-parallelisation. Also note that for sequences with deep MSAs, Jackhmmer or
-Nhmmer may need a substantial amount of RAM beyond the recommended 64 GB of RAM.
-
-## Model Inference
-
-Table 8 in the Supplementary Information of the
-[AlphaFold 3 paper](https://nature.com/articles/s41586-024-07487-w) provides
-compile-free inference timings for AlphaFold 3 when configured to run on 16
-NVIDIA A100s, with 40 GB of memory per device. In contrast, this repository
-supports running AlphaFold 3 on a single NVIDIA A100 with 80 GB of memory in a
-configuration optimised to maximise throughput.
-
-We compare compile-free inference timings of these two setups in the table below
-using GPU seconds (i.e. multiplying by 16 when using 16 A100s). The setup in
-this repository is more efficient (by at least 2×) across all token sizes,
-indicating its suitability for high-throughput applications.
-
-Num Tokens | 1 A100 80 GB (GPU secs) | 16 A100 40 GB (GPU secs) | Improvement
-:--------- | ----------------------: | -----------------------: | ----------:
-1024       | 62                      | 352                      | 5.7×
-2048       | 275                     | 1136                     | 4.1×
-3072       | 703                     | 2016                     | 2.9×
-4096       | 1434                    | 3648                     | 2.5×
-5120       | 2547                    | 5552                     | 2.2×
-
-## Running the Pipeline in Stages
-
-The `run_alphafold.py` script can be executed in stages to optimise resource
-utilisation. This can be useful for:
-
-1.  Splitting the CPU-only data pipeline from model inference (which requires a
-    GPU), to optimise cost and resource usage.
-1.  Caching the results of MSA/template search, then reusing the augmented JSON
-    for multiple different inferences across seeds or across variations of other
-    features (e.g. a ligand).
-
-### Data Pipeline Only
-
-Launch `run_alphafold.py` with `--norun_inference` to generate Multiple Sequence
-Alignments (MSAs) and templates, without running featurisation and model
-inference. This stage can be quite costly in terms of runtime, CPU, and RAM use.
-The output will be JSON files augmented with MSAs and templates that can then be
-directly used as input for running inference.
-
-### Featurisation and Model Inference Only
-
-Launch `run_alphafold.py` with `--norun_data_pipeline` to skip the data pipeline
-and run only featurisation and model inference. This stage requires the input
-JSON file to contain pre-computed MSAs and templates.
-
-## Accelerator Hardware Requirements
-
-We officially support the following configurations, and have extensively tested
-them for numerical accuracy and throughput efficiency:
-
--   1 NVIDIA A100 (80 GB)
--   1 NVIDIA H100 (80 GB)
-
-We compare compile-free inference timings of both configurations in the
-following table:
-
-Num Tokens | 1 A100 80 GB (seconds) | 1 H100 80 GB (seconds)
-:--------- | ---------------------: | ---------------------:
-1024       | 62                     | 34
-2048       | 275                    | 144
-3072       | 703                    | 367
-4096       | 1434                   | 774
-5120       | 2547                   | 1416
-
-### Other Hardware Configurations
-
-#### NVIDIA A100 (40 GB)
-
-AlphaFold 3 can run on inputs of size up to 4,352 tokens on a single NVIDIA A100
-(40 GB) with the following configuration changes:
-
-1.  Enabling [unified memory](#unified-memory).
-1.  Adjusting `pair_transition_shard_spec` in `model_config.py`:
-
-    ```py
-      pair_transition_shard_spec: Sequence[_Shape2DType] = (
-          (2048, None),
-          (3072, 1024),
-          (None, 512),
-      )
-    ```
-
-The format of entries in `pair_transition_shard_spec` is
-`(num_tokens_upper_bound, shard_size)`. Setting `shard_size=None` means there is
-no upper bound.
-
-For the example above:
-
-*   `(2048, None)`: for sequences up to 2,048 tokens, do not shard
-*   `(3072, 1024)`: for sequences up to 3,072 tokens, shard in chunks of 1,024
-*   `(None, 512)`: for all other sequences, shard in chunks of 512
-
-While numerically accurate, this configuration will have lower throughput
-compared to the set up on the NVIDIA A100 (80 GB), due to less available memory.
-
-#### NVIDIA V100
-
-There are known numerical issues with CUDA Capability 7.x devices. To work
-around the issue, set the ENV XLA_FLAGS to include
-`--xla_disable_hlo_passes=custom-kernel-fusion-rewriter`.
-
-With the above flag set, AlphaFold 3 can run on inputs of size up to 1,280
-tokens on a single NVIDIA V100 using [unified memory](#unified-memory).
-
-#### NVIDIA P100
-
-AlphaFold 3 can run on inputs of size up to 1,024 tokens on a single NVIDIA P100
-with no configuration changes needed.
-
-#### Other devices
-
-Large-scale numerical tests have not been performed on any other devices but
-they are believed to be numerically accurate.
-
-There are known numerical issues with CUDA Capability 7.x devices. To work
-around the issue, set the environment variable `XLA_FLAGS` to include
-`--xla_disable_hlo_passes=custom-kernel-fusion-rewriter`.
-
-## Compilation Buckets
-
-To avoid excessive re-compilation of the model, AlphaFold 3 implements
-compilation buckets: ranges of input sizes using a single compilation of the
-model.
-
-When featurising an input, AlphaFold 3 determines the smallest bucket the input
-fits into, then adds any necessary padding. This may avoid re-compiling the
-model when running inference on the input if it belongs to the same bucket as a
-previously processed input.
-
-The configuration of bucket sizes involves a trade-off: more buckets leads to
-more re-compilations of the model, but less padding.
-
-By default, the largest bucket size is 5,120 tokens. Processing inputs larger
-than this maximum bucket size triggers the creation of a new bucket for exactly
-that input size, and a re-compilation of the model. In this case, you may wish
-to redefine the compilation bucket sizes via the `--buckets` flag in
-`run_alphafold.py` to add additional larger bucket sizes. For example, suppose
-you are running inference on inputs with token sizes: `5132, 5280, 5342`. Using
-the default bucket sizes configured in `run_alphafold.py` will trigger three
-separate model compilations, one for each unique token size. If instead you pass
-in the following flag to `run_alphafold.py`
-
-```
---buckets 256,512,768,1024,1280,1536,2048,2560,3072,3584,4096,4608,5120,5376
-```
-
-when running inference on the above three input sizes, the model will be
-compiled only once for the bucket size `5376`. **Note:** for this specific
-example with input sizes `5132, 5280, 5342`, passing in `--buckets 5376` is
-sufficient to achieve the desired compilation behaviour. The provided example
-with multiple buckets illustrates a more general solution suitable for diverse
-input sizes.
-
-## Additional Flags
-
-### Compilation Time Workaround with XLA Flags
-
-To work around a known XLA issue causing the compilation time to greatly
-increase, the following environment variable must be set (it is set by default
-in the provided `Dockerfile`).
-
-```sh
-ENV XLA_FLAGS="--xla_gpu_enable_triton_gemm=false"
-```
-
-### CUDA Capability 7.x GPUs
-
-For all CUDA Capability 7.x GPUs (e.g. V100) the environment variable
-`XLA_FLAGS` must be changed to include
-`--xla_disable_hlo_passes=custom-kernel-fusion-rewriter`. Disabling the Tritron
-GEMM kernels is not necessary as they are not supported for such GPUs.
-
-```sh
-ENV XLA_FLAGS="--xla_disable_hlo_passes=custom-kernel-fusion-rewriter"
-```
-
-### GPU Memory
-
-The following environment variables (set by default in the `Dockerfile`) enable
-folding a single input of size up to 5,120 tokens on a single A100 (80 GB) or a
-single H100 (80 GB):
-
-```sh
-ENV XLA_PYTHON_CLIENT_PREALLOCATE=true
-ENV XLA_CLIENT_MEM_FRACTION=0.95
-```
-
-#### Unified Memory
-
-If you would like to run AlphaFold 3 on inputs larger than 5,120 tokens, or on a
-GPU with less memory (an A100 with 40 GB of memory, for instance), we recommend
-enabling unified memory. Enabling unified memory allows the program to spill GPU
-memory to host memory if there isn't enough space. This prevents an OOM, at the
-cost of making the program slower by accessing host memory instead of device
-memory. To learn more, check out the
-[NVIDIA blog post](https://developer.nvidia.com/blog/unified-memory-cuda-beginners/).
-
-You can enable unified memory by setting the following environment variables in
-your `Dockerfile`:
-
-```sh
-ENV XLA_PYTHON_CLIENT_PREALLOCATE=false
-ENV TF_FORCE_UNIFIED_MEMORY=true
-ENV XLA_CLIENT_MEM_FRACTION=3.2
-```
-
-### JAX Persistent Compilation Cache
-
-You may also want to make use of the JAX persistent compilation cache, to avoid
-unnecessary recompilation of the model between runs. You can enable the
-compilation cache with the `--jax_compilation_cache_dir <YOUR_DIRECTORY>` flag
-in `run_alphafold.py`.
-
-More detailed instructions are available in the
-[JAX documentation](https://jax.readthedocs.io/en/latest/persistent_compilation_cache.html#persistent-compilation-cache),
-and more specifically the instructions for use on
-[Google Cloud](https://jax.readthedocs.io/en/latest/persistent_compilation_cache.html#persistent-compilation-cache).
-In particular, note that if you would like to make use of a non-local
-filesystem, such as Google Cloud Storage, you will need to install
-[`etils`](https://github.com/google/etils) (this is not included by default in
-the AlphaFold 3 Docker container).
diff --git a/fetch_databases.sh b/fetch_databases.sh
deleted file mode 100644
index 0373abc84181ebb2e24d9ec9515ae470cd4aea54..0000000000000000000000000000000000000000
--- a/fetch_databases.sh
+++ /dev/null
@@ -1,46 +0,0 @@
-#!/bin/bash
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-set -euo pipefail
-
-readonly db_dir=${1:-$HOME/public_databases}
-
-for cmd in wget tar zstd ; do
-  if ! command -v "${cmd}" > /dev/null 2>&1; then
-    echo "${cmd} is not installed. Please install it."
-  fi
-done
-
-echo "Fetching databases to ${db_dir}"
-mkdir -p "${db_dir}"
-
-readonly SOURCE=https://storage.googleapis.com/alphafold-databases/v3.0
-
-echo "Start Fetching and Untarring 'pdb_2022_09_28_mmcif_files.tar'"
-wget --quiet --output-document=- \
-    "${SOURCE}/pdb_2022_09_28_mmcif_files.tar.zst" | \
-    tar --no-same-owner --no-same-permissions \
-    --use-compress-program=zstd -xf - --directory="${db_dir}" &
-
-for NAME in mgy_clusters_2022_05.fa \
-            bfd-first_non_consensus_sequences.fasta \
-            uniref90_2022_05.fa uniprot_all_2021_04.fa \
-            pdb_seqres_2022_09_28.fasta \
-            rnacentral_active_seq_id_90_cov_80_linclust.fasta \
-            nt_rna_2023_02_23_clust_seq_id_90_cov_80_rep_seq.fasta \
-            rfam_14_9_clust_seq_id_90_cov_80_rep_seq.fasta ; do
-  echo "Start Fetching '${NAME}'"
-  wget --quiet --output-document=- "${SOURCE}/${NAME}.zst" | \
-      zstd --decompress > "${db_dir}/${NAME}" &
-done
-
-wait
-echo "Complete"
diff --git a/legal/WEIGHTS_PROHIBITED_USE_POLICY-Bahasa-Indonesia.md b/legal/WEIGHTS_PROHIBITED_USE_POLICY-Bahasa-Indonesia.md
deleted file mode 100644
index 6c6fcc3f5f0d47c2b9597216c40bf3ff7d1cc822..0000000000000000000000000000000000000000
--- a/legal/WEIGHTS_PROHIBITED_USE_POLICY-Bahasa-Indonesia.md
+++ /dev/null
@@ -1,140 +0,0 @@
-# KEBIJAKAN PENGGUNAAN TERLARANG UNTUK PARAMETER MODEL ALPHAFOLD 3
-
-Terakhir diubah: 2024-11-09
-
-AlphaFold 3 dapat membantu Anda mempercepat riset ilmiah dengan memprediksi
-struktur 3D molekul biologis. Google menyediakan Aset AlphaFold tanpa biaya
-untuk penggunaan non-komersial tertentu, sesuai dengan pembatasan yang
-ditetapkan di bawah. Kebijakan ini menggunakan persyaratan yang sama dengan
-[Persyaratan Penggunaan Parameter Model AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_TERMS_OF_USE-Bahasa-Indonesia.md).
-
-**Anda tidak boleh mengakses atau menggunakan, atau mengizinkan orang lain
-mengakses atau menggunakan Aset AlphaFold 3:**
-
-1.  **Atas nama organisasi komersial atau sehubungan dengan aktivitas komersial
-    apa pun, termasuk riset atas nama organisasi komersial.**
-
-    1.  Artinya, hanya organisasi non-komersial (*yaitu*, universitas,
-        organisasi non-profit dan institusi riset, serta lembaga pendidikan,
-        jurnalistik, dan pemerintah) yang dapat menggunakan Aset AlphaFold 3
-        untuk aktivitas non-komersial mereka. Aset AlphaFold 3 tidak tersedia
-        untuk jenis organisasi lainnya, meskipun organisasi tersebut melakukan
-        pekerjaan non-komersial.
-
-    2.  Jika Anda adalah peneliti yang berafiliasi dengan organisasi
-        non-komersial, Anda dapat menggunakan Aset AlphaFold 3 untuk riset
-        terafiliasi non-komersial Anda, dengan syarat Anda bukan organisasi
-        komersial atau bertindak atas nama organisasi komersial.
-
-    3.  Anda tidak boleh membagikan Aset AlphaFold 3 kepada organisasi komersial
-        mana pun atau menggunakan Aset AlphaFold 3 dengan cara yang akan memberi
-        organisasi komersial hak apa pun atas Aset ini. Satu-satunya
-        pengecualian adalah menyediakan Output secara publik (termasuk secara
-        tidak langsung kepada organisasi komersial) melalui publikasi ilmiah
-        atau rilis open source atau menggunakannya untuk mendukung jurnalisme,
-        yang masing-masing diizinkan.
-
-2.  **Untuk menyebarkan misinformasi, memberikan pernyataan tidak benar, atau
-    menyesatkan pengguna**, termasuk:
-
-    1.  menyediakan informasi palsu atau tidak akurat sehubungan dengan akses ke
-        atau penggunaan AlphaFold 3 atau Output oleh Anda, termasuk mengakses
-        atau menggunakan Parameter Model atas nama organisasi tanpa memberi tahu
-        kami atau mengirimkan permintaan untuk mengakses Parameter Model di mana
-        Google telah melarang penggunaan AlphaFold 3 oleh Anda secara
-        keseluruhan atau sebagian (termasuk yang disediakan melalui
-        [Server AlphaFold](https://alphafoldserver.com/about));
-
-    2.  memberikan pernyataan tidak benar tentang hubungan Anda dengan kami;
-        termasuk dengan menggunakan merek dagang, nama dagang, atau logo Google,
-        atau menyiratkan dukungan oleh Google tanpa seizin Google - Tidak ada di
-        dalam Persyaratan memberikan izin semacam itu;
-
-    3.  memberikan pernyataan tidak benar tentang asal AlphaFold 3 secara
-        keseluruhan atau sebagian;
-
-    4.  menyebarkan klaim menyesatkan tentang keahlian atau kemampuan, atau
-        terlibat dalam praktik profesional yang tidak sah atau tanpa lisensi,
-        khususnya di bidang yang sensitif (misalnya, kesehatan); atau
-
-    5.  membuat keputusan dalam ranah yang memengaruhi hak atau kesejahteraan
-        individu atau material (misalnya, layanan kesehatan).
-
-3.  **Untuk melakukan, mempromosikan, atau memfasilitasi aktivitas berbahaya,
-    ilegal, atau jahat, termasuk:**
-
-    1.  mempromosikan atau memfasilitasi penjualan, ataupun memberikan petunjuk
-        untuk membuat atau mengakses, zat, barang, atau layanan ilegal;
-
-    2.  menyalahgunakan, merugikan, mengganggu, atau mengacaukan layanan apa
-        pun, termasuk membuat atau mendistribusikan konten untuk aktivitas
-        penipuan atau penyebaran malware;
-
-    3.  membuat atau mendistribusikan konten, termasuk Output, yang menyalahi,
-        menyalahgunakan, atau melanggar hak individu atau entitas apa pun
-        (termasuk, tetapi tidak terbatas pada hak atas konten yang dilindungi
-        hak cipta); atau
-
-    4.  mencoba mengakali, atau dengan sengaja menyebabkan (secara langsung atau
-        tidak langsung) AlphaFold 3 untuk bertindak dengan cara yang melanggar
-        Persyaratan.
-
-**Anda tidak boleh atau mengizinkan orang lain:**
-
-1.  **Menggunakan Output guna melatih atau membuat model machine learning atau
-    teknologi terkait untuk prediksi struktur biomolekuler yang mirip dengan
-    AlphaFold 3 ("Model Turunan"),** termasuk melalui distilasi atau metode
-    lainnya. Untuk menegaskan, pembatasan penggunaan yang ditetapkan dalam
-    Persyaratan akan berlaku sepenuhnya untuk semua Model Turunan yang dibuat
-    dengan melanggar Persyaratan.
-
-2.  **Mendistribusikan Output tanpa memberikan pemberitahuan yang jelas bahwa
-    apa yang Anda Distribusikan disediakan berdasarkan dan tunduk pada
-    [Persyaratan Penggunaan Output AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-    serta tentang modifikasi apa pun yang Anda buat.**
-
-    1.  Artinya, jika Anda menghapus, atau menyebabkan penghapusan (misalnya
-        dengan menggunakan perangkat lunak pihak ketiga), pemberitahuan dan
-        syarat yang kami berikan saat Anda menghasilkan Output menggunakan
-        AlphaFold 3, Anda harus memastikan Distribusi Output berikutnya
-        menyertakan salinan
-        [Persyaratan Penggunaan Output AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-        dan file teks "Persyaratan Penggunaan yang Mengikat secara Hukum" yang
-        berisi pemberitahuan berikut:
-
-        "*Dengan menggunakan informasi ini, Anda menyetujui Persayatan
-        Penggunaan Output AlphaFold 3 yang terdapat di
-        https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md.*
-
-        *Untuk meminta akses ke parameter model AlphaFold 3, ikuti proses yang
-        ditetapkan di https://github.com/google-deepmind/alphafold3. Anda hanya
-        dapat menggunakan parameter model ini jika menerimanya langsung dari
-        Google. Penggunaannya tunduk pada persyaratan penggunaan yang tersedia
-        di
-        https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md.*"
-
-    1.  Anda tidak boleh menyertakan persyaratan tambahan atau berbeda yang
-        bertentangan dengan
-        [Persyaratan Penggunaan Output AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-3.  **Mendistribusikan Output, atau mengungkapkan temuan yang didapatkan dari
-    penggunaan AlphaFold 3 tanpa mengutip makalah kami**: [Abramson, J et al.
-    Accurate structure prediction of biomolecular interactions with AlphaFold
-    3.](https://www.nature.com/articles/s41586-024-07487-w). Untuk menegaskan,
-    hal ini merupakan persyaratan tambahan selain persyaratan pemberitahuan yang
-    ditetapkan di atas.
-
-4.  **Mengakali pembatasan akses terkait Parameter Model, termasuk menggunakan,
-    membagikan, atau menyediakan Parameter Model ketika Google belum mengizinkan
-    Anda secara tegas untuk melakukan hal tersebut.** Google akan memberikan
-    akses ke Parameter Model kepada:
-
-    1.  Anda untuk penggunaan pribadi Anda atas nama organisasi Anda, dimana
-        Anda tidak dapat membagikan salinan Parameter Model Anda kepada siapa
-        pun; atau
-
-    2.  perwakilan resmi organisasi Anda, dengan kewenangan hukum penuh untuk
-        mengikat organisasi tersebut pada Persyaratan ini. Dalam hal ini, Anda
-        dapat membagikan salinan Parameter Model milik organisasi tersebut
-        kepada karyawan, konsultan, kontraktor, serta agen organisasi
-        sebagaimana diizinkan oleh perwakilan tersebut.
diff --git a/legal/WEIGHTS_PROHIBITED_USE_POLICY-Espanol-Latinoamerica.md b/legal/WEIGHTS_PROHIBITED_USE_POLICY-Espanol-Latinoamerica.md
deleted file mode 100644
index 2adcbd7224b596f6c1a8706d4364ca2b9932e907..0000000000000000000000000000000000000000
--- a/legal/WEIGHTS_PROHIBITED_USE_POLICY-Espanol-Latinoamerica.md
+++ /dev/null
@@ -1,146 +0,0 @@
-# POLÍTICA DE USO PROHIBIDO DE PARÁMETROS DEL MODELO ALPHAFOLD 3
-
-Última modificación: 9 de noviembre de 2024
-
-AlphaFold 3 puede ayudar a acelerar la investigación científica, ya que predice
-la estructura 3D de moléculas biológicas. Google pone a disposición los Recursos
-de AlphaFold sin costo para determinados usos no comerciales de conformidad con
-las restricciones que se establecen a continuación. Esta política usa los mismos
-términos definidos que en las
-[Condiciones de Uso de los Parámetros del Modelo AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Espanol-Latinoamerica.md).
-
-**No debe acceder o utilizar ni permitir que otros accedan o utilicen los
-Recursos de AlphaFold 3 en los siguientes casos:**
-
-1.  **En nombre de una organización comercial o en conexión con cualquier
-    actividad comercial, incluida la investigación en nombre de organizaciones
-    comerciales.**
-
-    1.  Esto significa que solo las organizaciones no comerciales (*por
-        ejemplo*, universidades, institutos de investigación y organizaciones
-        sin fines de lucro, y organismos educativos, gubernamentales y
-        periodísticos) pueden usar los Recursos de AlphaFold 3 para sus
-        actividades no comerciales. Los Recursos de AlphaFold 3 no están
-        disponibles para ningún otro tipo de organización, aunque realicen
-        trabajos no comerciales.
-
-    2.  Si usted es un investigador afiliado de una organización no comercial,
-        dado que no pertenece a una organización comercial, puede usar los
-        Recursos de AlphaFold 3 para su investigación de afiliación no
-        comercial.
-
-    3.  No debe compartir los Recursos de AlphaFold 3 con ninguna organización
-        comercial ni usarlos de manera que otorgue a una organización comercial
-        algún derecho sobre estos. La única excepción es poner los Resultados a
-        disposición del público (lo que incluye indirectamente a las
-        organizaciones comerciales) a través de una publicación científica o una
-        publicación de código abierto, o utilizarlos para apoyar la actividad
-        periodística, opciones que están todas permitidas.
-
-2.  **Para desinformar, tergiversar o engañar, entre lo que se incluye lo
-    siguiente:**
-
-    1.  proporcionar información falsa o errónea en relación con su acceso o uso
-        de AlphaFold 3 o los Resultados, incluido el uso o acceso a los
-        Parámetros del Modelo en nombre de una organización sin informarnos o
-        enviarnos una solicitud para acceder a los Parámetros del Modelo cuando
-        Google le ha prohibido el uso de AlphaFold 3 de forma parcial o total
-        (incluido como se pone a disposición a través de
-        [AlphaFold Server](https://alphafoldserver.com/about)),
-
-    2.  tergiversar su relación con nosotros, incluido el uso de marcas,
-        comerciales, nombres comerciales o logotipos de Google, o sugerir
-        recomendación por parte de Google sin el permiso de Google para hacerlo
-        (ningún punto de las Condiciones otorga ese permiso)
-
-    3.  tergiversar el origen de AlphaFold 3 de forma parcial o total,
-
-    4.  distribuir declaraciones engañosas sobre experiencia o capacidad, o
-        participar en la práctica de cualquier profesión sin autorización o
-        licencia, en particular si se trata de áreas sensibles (*p. ej.*, la de
-        la salud), o
-
-    5.  tomar decisiones en ámbitos que afectan el bienestar o los derechos
-        materiales o individuales (*p. ej.*, atención médica).
-
-3.  **Para realizar, promover o facilitar actividades peligrosas, ilegales o
-    maliciosas, entre lo que se incluye lo siguiente:**
-
-    1.  promover o facilitar la venta de sustancias, bienes o servicios
-        ilegales, o bien proporcionar instrucciones para sintetizarlos o acceder
-        a ellos,
-
-    2.  abusar, interferir, dañar o interrumpir servicios, lo que incluye
-        generar o distribuir contenido para actividades engañosas o fraudulentas
-        o software malicioso,
-
-    3.  generar o distribuir contenido, incluidos los Resultados, que incumpla,
-        se apropie indebidamente o infrinja los derechos de un individuo o una
-        entidad (incluidos, sin limitaciones, los derechos de contenido
-        protegido por derechos de autor), o
-
-    4.  intentar eludir o causar de forma intencional (directa o indirectamente)
-        que AlphaFold 3 actúe de manera que incumpla las Condiciones.
-
-**No debe utilizar ni permitir que otros:**
-
-1.  **Utilicen los Resultados para entrenar o crear modelos de aprendizaje
-    automático o tecnología relacionada para la predicción de estructura
-    biomolecular similar a la de AlphaFold 3 ("Modelos Derivados"),** lo que
-    incluye métodos a través de destilación o de otro tipo. En aras de evitar
-    dudas, las restricciones de uso establecidas en las Condiciones se aplicarán
-    en su totalidad a cualquier Modelo Derivado que se cree incumpliendo las
-    Condiciones.
-
-2.  **Distribuir los Resultados sin brindar un aviso claro de que lo que usted
-    Distribuye se proporciona de acuerdo con las
-    [Condiciones de Uso de los Resultados de AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-    y cualquier modificación que usted haga.**
-
-    1.  Esto quiere decir que si usted quita o hace que se quiten (por ejemplo,
-        con software de terceros) los avisos y las condiciones que
-        proporcionamos cuando genera Resultados usando AlphaFold 3, debe
-        asegurarse de que cualquier Distribución adicional de los Resultados
-        esté acompañada por una copia de las
-        [Condiciones de Uso de Resultados de AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-        y un archivo de texto llamado "Condiciones de Uso Legalmente
-        Vinculantes" que contenga el siguiente aviso:
-
-        "*Si utiliza esta información, usted acepta las Condiciones de Uso de
-        Resultados de AlphaFold 3, que se encuentran en
-        https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md.*
-
-        *Para solicitar acceso a los parámetros del modelo AlphaFold 3, siga el
-        proceso que se establece en
-        https://github.com/google-deepmind/alphafold3. Solo puede usarlos si los
-        recibe directamente de Google. El uso está sujeto a las Condiciones de
-        Uso disponibles en
-        https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md.*"
-
-    2.  No debe incluir ninguna condición adicional o diferente que entre en
-        conflicto con las
-        [Condiciones de Uso de Resultados de AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-3.  **Distribuir Resultados, o divulgar descubrimientos que surjan del uso de
-    AlphaFold 3 sin citar nuestro artículo** [Abramson, J et al. Accurate
-    structure prediction of biomolecular interactions with AlphaFold 3
-    (Predicción precisa de la estructura de las interacciones biomoleculares con
-    AlphaFold 3). *Nature*
-    (2024)](https://www.nature.com/articles/s41586-024-07487-w). En aras de
-    evitar dudas, este es un requisito adicional a los requisitos de aviso que
-    se establecen más arriba.
-
-4.  **Eludir las restricciones de acceso relacionadas con los Parámetros del
-    Modelo, lo que incluye utilizar, compartir o poner a disponibilidad los
-    Parámetros del Modelo cuando no recibió autorización expresa por parte de
-    Google para hacerlo.** Google otorgará acceso a los Parámetros del Modelo a:
-
-    1.  Usted para su uso individual o para usarlos en nombre de su
-        organización, en cuyo caso no puede compartir su copia de los Parámetros
-        del Modelo con nadie más, o
-
-    2.  Un representante autorizado de su organización con autoridad legal total
-        para obligar a esa organización con estas Condiciones (en cuyo caso
-        usted podrá compartir la copia de los Parámetros del Modelo de esa
-        organización con empleados, consultores, contratistas y agentes de la
-        organización, según lo autorizado por ese representante)
diff --git a/legal/WEIGHTS_PROHIBITED_USE_POLICY-Francais-Canada.md b/legal/WEIGHTS_PROHIBITED_USE_POLICY-Francais-Canada.md
deleted file mode 100644
index 57164aed382cdbf0b3ea7b29768f85930285d596..0000000000000000000000000000000000000000
--- a/legal/WEIGHTS_PROHIBITED_USE_POLICY-Francais-Canada.md
+++ /dev/null
@@ -1,150 +0,0 @@
-# POLITIQUE D'UTILISATION INTERDITE DES PARAMÈTRES DU MODÈLE ALPHAFOLD 3
-
-Dernière modification: 2024-11-09
-
-AlphaFold 3 peut vous aider à accélérer la recherche scientifique en prévoyant
-la structure 3D des molécules biologiques. Pour certaines utilisations non
-commerciales, Google met gratuitement à disposition les Éléments d'AlphaFold
-dans le respect des restrictions énoncées ci-dessous. Cette politique utilise
-les mêmes conditions d'utilisation telles que définies dans les
-[Conditions d'utilisation des paramètres du modèle AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Francais-Canada.md).
-
-**Vous ne devez pas accéder aux Éléments d'AlphaFold 3 ni les utiliser ou
-permettre à d'autres personnes de le faire:**
-
-1.  **Au nom d'une organisation commerciale ou en connexion avec des activités
-    commerciales, y compris la recherche au nom d'organisations commerciales.**
-
-    1.  Cela signifie que seules les organisations non commerciales (*c.-à-d*.
-        universités, organismes sans but lucratif, instituts de recherche et
-        organismes éducatifs, journalistiques et gouvernementaux) peuvent
-        utiliser les Éléments d'AlphaFold 3 dans le cadre de leurs activités non
-        commerciales. Les Éléments AlphaFold 3 ne sont pas offerts à d'autres
-        types d'organisations, même si elles effectuent des travaux non
-        commerciaux.
-
-    2.  Si vous êtes un chercheur affilié à une organisation non commerciale, à
-        la condition que **vous ne soyez pas une organisation commerciale ou que
-        vous n'agissez pas au nom d'une organisation commerciale**, vous pouvez
-        utiliser les Éléments AlphaFold 3 pour vos recherches affiliées non
-        commerciales.
-
-    3.  Vous ne devez pas partager les Éléments d'AlphaFold 3 avec une
-        organisation commerciale ni les utiliser d'une manière qui confère à une
-        organisation commerciale des droits sur ces éléments. La seule exception
-        est la mise à disposition publique des Résultats (y compris
-        indirectement à des organisations commerciales) par le biais d'une
-        publication scientifique ou d'une version open source, ou l'utilisation
-        de ces résultats pour soutenir le journalisme, qui sont toutes deux
-        autorisées.
-
-2.  **Pour désinformer ou déformer ou induire en erreur**, y compris:
-
-    1.  fournir des informations fausses ou inexactes concernant votre accès à
-        AlphaFold 3 ou à ses Résultats, ou à l'utilisation de ceux-ci, y compris
-        l'accès aux Paramètres du modèle ou l'utilisation de ceux-ci au nom
-        d'une organisation sans nous en informer ou sans soumettre une demande
-        d'accès aux Paramètres du modèle lorsque Google a interdit l'utilisation
-        d'AlphaFold 3 en totalité ou en partie (y compris tel que mis à
-        disposition par le biais du
-        [Serveur d'AlphaFold](https://alphafoldserver.com/about));
-
-    2.  présenter de manière inexacte votre relation avec nous, y compris en
-        utilisant les marques de commerce, les noms commerciaux et les logos de
-        Google ou en suggérant l'approbation de Google sans son autorisation.
-        Rien dans les présentes Conditions ne permet d'accorder une telle
-        autorisation;
-
-    3.  présenter de manière inexacte l'origine d'AlphaFold 3, en tout ou en
-        partie;
-
-    4.  distribuer des déclarations trompeuses quant au savoir-faire ou aux
-        capacités, ou exercer une activité professionnelle sans autorisation ou
-        sans licence, en particulier dans des domaines sensibles (*p. ex.* les
-        soins de santé); ou
-
-    5.  prendre des décisions dans des domaines qui touchent les droits
-        matériels ou individuels ou le bien-être (*p. ex.* les soins de santé).
-
-3.  **Pour effectuer ou faciliter des activités dangereuses, illégales ou
-    malveillantes**, y compris:
-
-    1.  la promotion ou l'aide à la vente, ou la fourniture d'instructions pour
-        synthétiser ou accéder à des substances, des biens ou des services
-        illégaux, ou l'accès à ces derniers;
-
-    2.  abuser, nuire, interférer ou perturber tout service, y compris en
-        générant ou en distribuant du contenu pour des activités trompeuses ou
-        frauduleuses ou pour des logiciels malveillants;
-
-    3.  générer ou distribuer tout contenu, y compris des Résultats, qui
-        enfreigne, détourne ou viole de toute autre manière les droits d'un
-        individu ou d'une entité (y compris, mais sans s'y limiter, les droits
-        sur les contenus protégés par des droits d'auteur); ou
-
-    4.  tenter de contourner, ou causer intentionnellement (directement ou
-        indirectement) AlphaFold 3 à agir d'une manière qui contrevient aux
-        Conditions.
-
-**Vous ne devez pas, et vous ne devez pas permettre aux autres:**
-
-1.  **D'utiliser les Résultats pour entraîner ou créer des modèles
-    d'apprentissage automatique ou une technologie connexe pour la prédiction de
-    la structure biomoléculaire semblable à AlphaFold 3 (« Modèles dérivés »)**,
-    y compris par distillation ou d'autres méthodes. Pour éviter le doute, les
-    restrictions d'utilisation énoncées dans les présentes Conditions
-    s'appliquent intégralement à tout Modèle dérivé créé en violation des
-    présentes Conditions.
-
-2.  **De Distribuer les Résultats sans indiquer clairement que ce que vous
-    Distribuez est fourni dans le cadre et sous réserve des
-    [Conditions d'utilisation des résultats d'AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-    et de toutes les modifications que vous y apportez.**
-
-    1.  Cela signifie que si vous retirez, ou faites retirer (par exemple en
-        utilisant un logiciel tiers), les avis et les conditions d'utilisation
-        que nous fournissons lorsque vous générez des Résultats à l'aide
-        d'AlphaFold 3, vous devez vous assurer que toute Distribution ultérieure
-        de Résultats est accompagnée d'une copie des
-        [Conditions d'utilisation des résultats d'AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-        et d'un fichier texte des « Conditions d'utilisation légalement
-        contraignantes » qui contient l'avis suivant:
-
-        « *En utilisant cette information,vous acceptez les Conditions
-        d'utilisation des résultats d'AlphaFold 3 qui se trouve à l'adresse
-        https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md.*
-
-        *Pour demander l'accès aux paramètres du modèle AlphaFold 3, suivez le
-        processus décrit à l'adresse
-        https://github.com/google-deepmind/alphafold3. Vous ne pouvez les
-        utiliser que si vous les recevez directement de Google. L'utilisation
-        est soumise aux conditions d'utilisation disponibles à l'adresse
-        https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md.*
-        »
-
-    2.  Vous ne devez pas inclure de conditions d'utilisation supplémentaires ou
-        différentes qui seraient en contradiction avec les
-        [Conditions d'utilisation des résultats d'AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-3.  **De Distribuer les Résultats ou de divulguer les résultats découlant de
-    l'utilisation d'AlphaFold 3 sans citer notre article:** « [Abramson, J et
-    al. Accurate structure prediction of biomolecular interactions with
-    AlphaFold 3. *Nature*
-    (2024)](https://www.nature.com/articles/s41586-024-07487-w) ». Pour éviter
-    toute ambiguïté, il s'agit d'une exigence supplémentaire par rapport aux
-    exigences de notification énoncées ci-dessus.
-
-4.  **De contourner les restrictions d'accès relatives aux Paramètres du modèle,
-    y compris l'utilisation, le partage ou la mise à disposition des Paramètres
-    du modèle alors que vous n'y avez pas été expressément autorisé par
-    Google.** Google accordera l'accès aux Paramètres du modèle à soit:
-
-    1.  vous, pour votre utilisation individuelle au nom de votre organisation,
-        auquel cas vous ne pouvez pas partager votre copie des Paramètres du
-        modèle avec quelqu'un d'autre; ou
-
-    2.  un représentant autorisé de votre organisation, disposant de la pleine
-        autorité légale pour lier cette organisation aux présentes Conditions,
-        auquel cas vous pouvez partager la copie des Paramètres du modèle de
-        cette organisation avec les employés, les consultants, les entrepreneurs
-        et les agents de l'organisation, tel qu'autorisé par ce représentant.
diff --git a/legal/WEIGHTS_PROHIBITED_USE_POLICY-Portugues-Brazil.md b/legal/WEIGHTS_PROHIBITED_USE_POLICY-Portugues-Brazil.md
deleted file mode 100644
index 0886a1091ed52469487131e720fb78569a194f30..0000000000000000000000000000000000000000
--- a/legal/WEIGHTS_PROHIBITED_USE_POLICY-Portugues-Brazil.md
+++ /dev/null
@@ -1,135 +0,0 @@
-# POLÍTICA DE USO PROIBIDO DOS PARÂMETROS DO MODELO ALPHAFOLD 3
-
-Última modificação: 2024-11-09
-
-O AlphaFold 3 ajuda você a acelerar pesquisas científicas ao prever a estrutura
-3D de moléculas biológicas. O Google disponibiliza os Recursos do AlphaFold sem
-custo financeiro para certos usos não comerciais, de acordo com as restrições
-abaixo. Esta política usa os mesmos termos definidos nos
-[Termos de Uso dos Parâmetros do Modelo AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Portugues-Brazil.md).
-
-**Você não deve acessar, usar nem permitir que outras pessoas acessem ou usem os
-Recursos do AlphaFold 3 nos seguintes casos:**
-
-1.  **Em nome de uma organização comercial ou em associação a atividades
-    comerciais, incluindo pesquisas em nome de organizações comerciais.**
-
-    1.  Isso significa que apenas organizações não comerciais (*ou seja*,
-        universidades, organizações sem fins lucrativos, institutos de pesquisa
-        e órgãos governamentais, educacionais e de notícias) podem usar os
-        Recursos do AlphaFold 3 para suas atividades não comerciais. Os Recursos
-        do AlphaFold 3 não estão disponíveis para qualquer outro tipo de
-        organização, mesmo as que conduzem trabalhos não comerciais.
-
-    2.  Se você for um pesquisador afiliado a uma organização não comercial,
-        você tem permissão para usar esses recursos em sua pesquisa afiliada a
-        organizações sem fins lucrativos, desde que você não seja uma
-        organização comercial nem esteja agindo em nome de uma.
-
-    3.  É proibido compartilhar os Recursos do AlphaFold 3 com qualquer
-        organização comercial ou usar os Recursos do AlphaFold 3 de modo a
-        conceder a uma organização comercial qualquer direito em relação a eles.
-        A única exceção é a disponibilização da Saída para o público (incluindo
-        indiretamente para organizações comerciais) mediante uma publicação
-        científica, versão de código aberto ou em apoio ao jornalismo, o que é
-        permitido.
-
-2.  **Para gerar desinformação, deturpar ou enganar**, incluindo:
-
-    1.  fornecer informações falsas ou imprecisas em relação ao seu acesso ou
-        uso do AlphaFold 3 ou da Saída gerada, incluindo acessar ou usar os
-        Parâmetros do Modelo em nome de uma organização sem nos informar ou
-        solicitar o acesso aos Parâmetros do Modelo caso o Google tenha proibido
-        totalmente ou parcialmente seu uso do AlphaFold 3 (incluindo conforme
-        disponibilizado pelo
-        [Servidor do AlphaFold](https://alphafoldserver.com/about));
-
-    2.  deturpar sua relação conosco, incluindo ao usar marcas registradas,
-        nomes comerciais e logotipos do Google, ou sugerir o endosso do Google
-        sem a nossa permissão – nada nestes Termos concede tal permissão;
-
-    3.  deturpar a origem do AlphaFold 3 total ou parcialmente;
-
-    4.  distribuir declarações enganosas sobre conhecimento ou capacidade, ou
-        participar do exercício não autorizado ou não licenciado de qualquer
-        profissão, especialmente em áreas sensíveis (*por exemplo*, saúde); ou
-
-    5.  tomar decisões em áreas que afetam o bem-estar ou direitos materiais ou
-        individuais (*por exemplo*, saúde).
-
-3.  **Para realizar, promover ou facilitar atividades perigosas, ilegais ou
-    maliciosas**, incluindo:
-
-    1.  promover ou facilitar a venda ou fornecer instruções para sintetizar ou
-        ter acesso a substâncias, produtos ou serviços ilegais;
-
-    2.  abusar, prejudicar, interferir ou interromper quaisquer serviços,
-        incluindo gerar ou distribuir conteúdo para atividades enganosas ou
-        fraudulentas ou malware;
-
-    3.  gerar ou distribuir qualquer conteúdo, incluindo a Saída, que infrinja,
-        se aproprie indevidamente ou viole de outra forma os direitos de
-        qualquer indivíduo ou entidade (incluindo, mas não se limitando a
-        direitos autorais do conteúdo); ou
-
-    4.  tentar burlar ou levar intencionalmente (direta ou indiretamente) o
-        AlphaFold 3 a agir de maneira que viole os Termos.
-
-**Não é permitido que você nem outras pessoas:**
-
-1.  **Usem os Resultados para treinar ou criar modelos de aprendizado de máquina
-    ou tecnologias relacionadas para previsão de estrutura biomolecular
-    semelhante ao AlphaFold 3 ("Modelos Derivados"),** incluindo pela destilação
-    ou outros métodos. Para evitar dúvidas, as restrições de uso definidas nos
-    Termos são totalmente válidas para quaisquer Modelos Derivados criados em
-    violação dos Termos.
-
-2.  **Distribuam a Saída sem apresentar aviso evidente de que o que você
-    Distribui é oferecido de acordo com e sujeito aos
-    [Termos de Uso dos Resultados do AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-    e quaisquer modificações realizadas.**
-
-    1.  Isso significa que, se você remover ou causar a remoção (por exemplo,
-        usando um software de terceiros) dos avisos e termos que fornecemos
-        quando você gera Resultados usando o AlphaFold 3, você precisa garantir
-        que a Distribuição da Saída posterior esteja acompanhada de uma cópia
-        dos
-        [Termos de Uso dos Resultados do AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md)
-        e de um arquivo de texto "Termos de Uso Juridicamente Vinculativos" com
-        o seguinte aviso:
-
-        "*Ao usar estas informações, você concorda com os Termos de Uso da Saída
-        do AlphaFold 3 disponíveis em
-        https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md.*
-
-        *Para solicitar acesso aos parâmetros do modelo AlphaFold 3, siga o
-        processo descrito em https://github.com/google-deepmind/alphafold3. Você
-        só pode usar os parâmetros se os receber diretamente do Google. O uso
-        está sujeito aos Termos de Uso disponíveis em
-        https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md.*"
-
-    2.  É proibido incluir quaisquer termos adicionais ou diferentes que entrem
-        em conflito com os
-        [Termos de Uso da Saída do AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-3.  **Distribuam a Saída ou divulguem descobertas provenientes do uso do
-    AlphaFold 3 sem citar nosso artigo:** [Abramson, J et al. Accurate structure
-    prediction of biomolecular interactions with AlphaFold 3. *Nature*
-    (2024)](https://www.nature.com/articles/s41586-024-07487-w). Para evitar
-    dúvidas, esse é um requisito adicional às exigências de aviso definidas
-    acima.
-
-4.  **Burlem as restrições de acesso relacionadas aos Parâmetros do Modelo,
-    incluindo usar, compartilhar ou disponibilizar os Parâmetros do Modelo sem
-    autorização explícita do Google.** O Google concederá acesso aos Parâmetros
-    do Modelo a:
-
-    1.  você, para uso individual em nome da sua organização, sendo proibido
-        compartilhar sua cópia dos Parâmetros do Modelo com qualquer indivíduo;
-        ou
-
-    2.  um representante autorizado da sua organização, com autoridade legal
-        total para vincular tal organização a estes Termos, sendo permitido
-        compartilhar a cópia dos Parâmetros do Modelo pertencente a essa
-        organização com funcionários, consultores, prestadores de serviço e
-        agentes da organização, conforme autorizado por esse representante.
diff --git a/legal/WEIGHTS_TERMS_OF_USE-Bahasa-Indonesia.md b/legal/WEIGHTS_TERMS_OF_USE-Bahasa-Indonesia.md
deleted file mode 100644
index c39f4de90741f5ed1501daf00a42af3c1da1a47d..0000000000000000000000000000000000000000
--- a/legal/WEIGHTS_TERMS_OF_USE-Bahasa-Indonesia.md
+++ /dev/null
@@ -1,309 +0,0 @@
-# PERSYARATAN PENGGUNAAN PARAMETER MODEL ALPHAFOLD 3
-
-Terakhir diubah: 09-11-2024
-
-[AlphaFold 3](https://blog.google/technology/ai/google-deepmind-isomorphic-alphafold-3-ai-model/)
-adalah model AI yang dikembangkan oleh
-[Google DeepMind](https://deepmind.google/) dan
-[Isomorphic Labs](https://www.isomorphiclabs.com/). Program ini membuat prediksi
-struktur 3D molekul biologis, serta memberikan keyakinan model untuk prediksi
-struktur tersebut. Kami membuat parameter model terlatih dan output yang
-dihasilkan menggunakan aset yang tersedia tanpa biaya untuk penggunaan
-non-komersial tertentu, sehubungan dengan persyaratan penggunaan ini dan
-[Kebijakan Penggunaan Terlarang untuk Parameter Model AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Bahasa-Indonesia.md).
-
-**Hal penting yang perlu diketahui saat menggunakan parameter dan output model
-AlphaFold 3**
-
-1.  Parameter dan output model AlphaFold 3 hanya tersedia untuk penggunaan
-    non-komersial oleh, atau atas nama, organisasi non-komersial (*yaitu*
-    universitas, organisasi nonprofit dan institusi riset, serta lembaga
-    pendidikan, jurnalistik, dan pemerintah). Jika Anda adalah peneliti yang
-    berafiliasi dengan organisasi non-komersial, dengan syarat Anda bukan
-    organisasi komersial atau bertindak atas nama organisasi komersial, artinya
-    Anda dapat menggunakannya untuk riset terafiliasi non-komersial Anda.
-2.  Anda tidak boleh menggunakan atau mengizinkan orang lain menggunakan:
-    1.  Parameter atau Output model AlphaFold 3 sehubungan dengan aktivitas
-        komersial apa pun, termasuk riset atas nama organisasi komersial; atau
-    1.  Output AlphaFold 3 untuk melatih model machine learning atau teknologi
-        terkait untuk prediksi struktur biomolekuler yang mirip dengan AlphaFold
-        3
-3.  Anda *tidak boleh* mempublikasikan atau membagikan parameter model AlphaFold
-    3, kecuali membagikannya dalam organisasi Anda sesuai dengan Persyaratan
-    ini.
-4.  Anda *dapat* mempublikasikan, membagikan, dan mengadaptasi *output*
-    AlphaFold 3 sesuai dengan Persyaratan ini, termasuk persyaratan untuk
-    memberikan pemberitahuan yang jelas atas setiap modifikasi yang Anda buat
-    dan bahwa penggunaan yang sedang berlangsung atas output AlphaFold 3 dan
-    turunannya tunduk pada
-    [Persyaratan Penggunaan Output AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-Dengan menggunakan, mereproduksi, memodifikasi, menjalankan, mendistribusikan,
-atau menampilkan bagian atau elemen apa pun dari Parameter Model (sebagaimana
-didefinisikan di bawah) atau menyetujui persyaratan perjanjian ini, Anda setuju
-untuk terikat oleh (1) persyaratan penggunaan ini, dan (2)
-[Kebijakan Penggunaan Terlarang untuk Parameter Model AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Bahasa-Indonesia.md)
-yang disertakan di sini sebagai referensi (secara kolektif disebut
-"**Persyaratan**"), dalam setiap kasus (a) sebagaimana diubah dari waktu ke
-waktu sesuai dengan Persyaratan, serta (b) antara Anda dan (i) Google Ireland
-Limited, jika Anda berasal dari negara di Wilayah Ekonomi Eropa atau Swiss, atau
-(ii) Google LLC, jika Anda berasal dari wilayah lain.
-
-Anda mengonfirmasi bahwa Anda berwenang baik secara eksplisit maupun implisit
-untuk masuk, dan sedang memasuki, ke dalam Persyaratan ini sebagai karyawan yang
-mewakili, atau atas nama, organisasi Anda.
-
-Harap baca Persyaratan ini dengan cermat. Persyaratan ini menetapkan apa yang
-dapat Anda harapkan dari kami saat Anda mengakses dan menggunakan Aset AlphaFold
-3 (sebagaimana di definisikan di bawah), dan apa yang Google harapkan dari Anda.
-Penyebutan "**Anda**" di sini mengacu pada individu atau organisasi yang
-menggunakan Aset AlphaFold 3. Penyebutan "**kami**", "**kita**", atau
-"**Google**" di sini mengacu pada entitas milik grup perusahaan Google, yaitu
-Google LLC beserta afiliasinya.
-
-## 1. Definisi Penting
-
-Sebagaimana digunakan dalam Persyaratan ini:
-
-"**AlphaFold 3**" adalah: (a) kode sumber AlphaFold 3 yang disediakan
-[di sini](https://github.com/google-deepmind/alphafold3/) dan yang dilisensikan
-berdasarkan persyaratan lisensi Creative Commons
-Attribution-NonCommercial-Sharealike 4.0 International (CC-BY-NC-SA 4.0) dan
-kode sumber turunan apa pun, serta (b) Parameter Model.
-
-"**Aset AlphaFold 3**" adalah Parameter dan output Model.
-
-"**Distribusi**" atau "**Mendistribusikan**" adalah mengirimkan,
-mempublikasikan, atau membagikan Output secara publik atau kepada orang lain.
-
-"**Parameter Model**" adalah bobot dan parameter model terlatih yang disediakan
-oleh Google bagi organisasi (atas pertimbangannya sendiri) untuk digunakan
-sesuai dengan Persyaratan ini, bersama dengan (a) modifikasi pada bobot dan
-parameter tersebut, (b) pekerjaan yang didasarkan pada bobot dan parameter
-tersebut, atau (c) kode atau model machine learning lainnya yang menggabungkan,
-seluruh atau sebagian, bobot dan parameter tersebut.
-
-"**Output**" adalah prediksi struktur serta semua informasi tambahan dan
-informasi terkait yang disediakan oleh AlphaFold 3 atau penggunaan Parameter
-Model, bersama dengan representasi visual, prediksi komputasional, deskripsi,
-modifikasi, salinan, atau adaptasi apa pun yang secara substansial berasal dari
-Output.
-
-"**Termasuk**" adalah "**termasuk, tetapi tidak terbatas pada**".
-
-## 2. Mengakses dan menggunakan Aset AlphaFold 3
-
-Dengan tunduk pada kepatuhan Anda terhadap Persyaratan, termasuk
-[Kebijakan Penggunaan Terlarang untuk Parameter Model AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Bahasa-Indonesia.md),
-Anda dapat mengakses, menggunakan, dan memodifikasi Aset AlphaFold 3 serta
-Mendistribusikan Output sebagaimana ditetapkan dalam Persyaratan ini. Kami
-memberi Anda lisensi non-eksklusif, bebas royalti, dapat dibatalkan, tidak dapat
-dipindahtangankan, dan tidak dapat disublisensikan (kecuali secara tegas
-diizinkan dalam Persyaratan ini) untuk hak atas kekayaan intelektual apa pun
-yang kami miliki dalam Aset AlphaFold sejauh diperlukan untuk tujuan ini. Untuk
-memverifikasi akses dan penggunaan AlphaFold 3 oleh Anda, kami dapat meminta
-Anda memberikan informasi tambahan dari waktu ke waktu, termasuk verifikasi
-nama, organisasi, serta informasi identitas Anda lainnya.
-
-Dengan mengakses, menggunakan, atau memodifikasi Aset AlphaFold 3,
-Mendistribusikan Output, atau meminta akses ke Parameter Model, Anda menyatakan
-dan menjamin bahwa (a) Anda memiliki kuasa dan wewenang penuh untuk menyetujui
-Persyaratan ini (termasuk telah berusia dewasa), (b) Google sebelumnya tidak
-pernah menghentikan akses dan hak Anda untuk menggunakan AlphaFold 3 (termasuk
-yang disediakan melalui [Server AlphaFold](https://alphafoldserver.com/about))
-karena pelanggaran Anda terhadap persyaratan penggunaan yang berlaku, (c)
-menyetujui atau menjalankan hak dan kewajiban Anda berdasarkan Persyaratan ini
-tidak akan melanggar hak pihak ketiga mana pun atau perjanjian yang Anda
-sepakati dengan pihak ketiga, (d) informasi apa pun yang Anda berikan ke Google
-sehubungan dengan AlphaFold 3, termasuk (jika berlaku) untuk meminta akses ke
-Parameter Model, sudah benar dan aktual, serta (e) Anda bukan (i) berstatus
-warga dari negara yang diembargo, (ii) berstatus menetap di negara yang
-diembargo Amerika Serikat, atau (iii) dinyatakan dilarang oleh program sanksi
-dan kontrol ekspor yang berlaku untuk mengakses, menggunakan, atau memodifikasi
-Aset AlphaFold 3.
-
-Jika Anda memilih untuk memberikan masukan ke Google, seperti saran untuk
-meningkatkan kualitas AlphaFold 3, Anda setuju bahwa informasi tersebut tidak
-bersifat rahasia dan eksklusif, serta Google dapat menindaklanjuti masukan Anda
-tanpa kewajiban kepada Anda.
-
-## 3. Pembatasan Penggunaan
-
-Anda tidak boleh menggunakan Aset AlphaFold 3 apa pun:
-
-1.  untuk penggunaan terbatas yang ditetapkan dalam
-    [Kebijakan Penggunaan Terlarang untuk Parameter Model AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Bahasa-Indonesia.md);
-    atau
-2.  dengan cara yang melanggar hukum dan peraturan yang berlaku.
-
-Selama diizinkan oleh hukum dan tanpa membatasi hak kami lainnya, Google berhak
-mencabut hak penggunaan Anda, dan (selama memungkinkan) membatasi penggunaan
-Aset AlphaFold 3 apa pun yang menurut Google secara wajar melanggar Persyaratan
-ini.
-
-## 4. Output yang Dihasilkan
-
-Meskipun Anda harus mematuhi Persyaratan ini saat menggunakan Aset AlphaFold 3,
-kami tidak akan mengklaim kepemilikan atas Output orisinal yang Anda hasilkan
-menggunakan AlphaFold 3. Namun, Anda memahami bahwa AlphaFold 3 dapat
-menghasilkan Output yang sama atau mirip untuk beberapa pengguna, termasuk
-Google, dan kami berhak mengklaim Output tersebut.
-
-## 5. Perubahan pada Aset AlphaFold 3 atau Persyaratan ini
-
-Google dapat menambahkan atau menghapus fungsi atau fitur Aset AlphaFold 3 kapan
-saja dan dapat berhenti menawarkan akses ke Aset AlphaFold 3 sepenuhnya.
-
-Google dapat memperbarui Persyaratan ini dan mekanisme akses untuk Parameter
-Model kapan saja. Kami akan memposting setiap perubahan pada Persyaratan
-[di repositori GitHub AlphaFold 3](https://github.com/google-deepmind/alphafold3).
-Perubahan umumnya akan berlaku 14 hari setelah diposting. Namun, perubahan yang
-berkaitan dengan fungsi atau yang dibuat karena alasan hukum akan langsung
-berlaku.
-
-Anda harus meninjau Persyaratan ini setiap kali kami memperbaruinya atau saat
-Anda menggunakan Aset AlphaFold 3. Jika Anda tidak menyetujui perubahan pada
-Persyaratan, Anda harus segera menghentikan penggunaan Aset AlphaFold 3.
-
-## 6. Menangguhkan atau menghentikan hak Anda untuk menggunakan Aset AlphaFold 3
-
-Google dapat sewaktu-waktu menangguhkan atau menghentikan hak Anda untuk
-menggunakan dan mengakses Aset AlphaFold 3 sebagaimana berlaku karena, antara
-lain, kegagalan Anda untuk sepenuhnya mematuhi Persyaratan. Jika Google
-menangguhkan atau menghentikan hak Anda untuk mengakses atau menggunakan Aset
-AlphaFold 3, Anda harus segera menghapus dan menghentikan penggunaan serta
-Distribusi semua salinan Aset AlphaFold 3 yang Anda miliki atau kontrol, dan
-Anda dilarang menggunakan Aset AlphaFold 3, termasuk mengajukan permohonan untuk
-menggunakan Parameter Model. Google akan berupaya memberikan pemberitahuan
-sewajarnya kepada Anda sebelum penangguhan atau penghentian tersebut. Namun,
-Anda tidak akan menerima pemberitahuan atau peringatan sebelumnya jika
-penangguhan atau penghentian tersebut terjadi karena Anda tidak sepenuhnya
-mematuhi Persyaratan atau karena alasan serius lainnya.
-
-Anda tentunya dapat menghentikan penggunaan Aset AlphaFold 3 kapan saja. Jika
-Anda berhenti menggunakannya, harap beri tahu kami alasannya (melalui
-alphafold@google.com) sehingga kami dapat terus meningkatkan kualitas teknologi
-kami.
-
-## 7. Kerahasiaan
-
-Anda setuju untuk tidak mengungkapkan atau menyediakan Informasi Rahasia Google
-kepada siapa pun tanpa izin tertulis dari kami sebelumnya. "**Informasi Rahasia
-Google**" berarti (a) Parameter Model AlphaFold 3 dan semua software, teknologi,
-serta dokumentasi yang terkait dengan AlphaFold 3, kecuali kode sumber AlphaFold
-3, dan (b) informasi lain apa pun yang disediakan oleh Google yang ditandai
-sebagai rahasia atau umumnya dianggap rahasia berdasarkan penyajian informasi
-tersebut. Informasi Rahasia Google tidak mencakup (a) informasi yang sudah Anda
-ketahui sebelum Anda mengakses atau menggunakan Aset AlphaFold 3 (termasuk
-melalui [Server AlphaFold](https://alphafoldserver.com/about)), (b) yang
-terungkap ke publik bukan karena kesalahan Anda (misalnya, pelanggaran Anda
-terhadap Persyaratan ini), (c) yang Anda kembangkan sendiri tanpa mengacu pada
-Informasi Rahasia Google, atau (d) yang diberikan kepada Anda oleh pihak ketiga
-sesuai hukum yang berlaku (Tanpa anda atau pihak ketiga tersebut melanggar
-Persyaratan).
-
-## 8. Pernyataan penyangkalan
-
-Tidak ada di dalam Persyaratan membatasi hak apa pun yang tidak dapat dibatasi
-berdasarkan hukum yang berlaku atau membatasi tanggung jawab Google kecuali
-sebagaimana diizinkan oleh hukum yang berlaku.
-
-**AlphaFold 3 dan Output disediakan "apa adanya", tanpa jaminan atau ketentuan
-apa pun, baik tersurat maupun tersirat, termasuk jaminan atau ketentuan tentang
-kepemilikan, ketiadaan pelanggaran, kelayakan untuk diperdagangkan, atau
-kesesuaian untuk tujuan tertentu. Anda bertanggung jawab sepenuhnya untuk
-menentukan kesesuaian penggunaan AlphaFold 3, atau penggunaan atau
-pendistribusian Output, dan menanggung semua risiko yang terkait dengan
-penggunaan atau pendistribusian tersebut serta pelaksanaan hak dan kewajiban
-oleh Anda berdasarkan Persyaratan ini. Anda dan siapa pun yang Anda beri Output
-bertanggung jawab sepenuhnya atas Output tersebut serta penggunaannya
-selanjutnya.**
-
-**Output merupakan prediksi dengan tingkat keyakinan yang berbeda-beda dan harus
-ditafsirkan dengan cermat. Gunakan pertimbangan sebelum mengandalkan,
-memublikasikan, mendownload, atau menggunakan AlphaFold 3.**
-
-**AlphaFold 3 dan Output hanya ditujukan untuk pemodelan teoretis. Aset tersebut
-tidak dimaksudkan, divalidasi, atau disetujui untuk penggunaan klinis. Anda
-tidak boleh menggunakan AlphaFold 3 atau Output untuk tujuan klinis atau
-mengandalkannya untuk saran medis atau profesional lainnya. Konten apa pun
-terkait topik tersebut hanya diberikan untuk tujuan informasi dan bukan
-merupakan pengganti saran dari profesional yang berkualifikasi.**
-
-## 9. Kewajiban
-
-Selama diizinkan hukum yang berlaku, Anda akan melindungi Google serta direktur,
-petugas, karyawan, dan kontraktornya terhadap kerugian dari proses hukum pihak
-ketiga (termasuk tindakan oleh otoritas pemerintah) yang timbul dari atau
-berkaitan dengan penggunaan Aset AlphaFold 3 oleh Anda yang melanggar hukum atau
-pelanggaran Anda terhadap Persyaratan. Perlindungan terhadap kerugian ini
-mencakup kewajiban atau pengeluaran yang timbul dari klaim, kerugian, kerusakan,
-putusan pengadilan, denda, biaya proses pengadilan, dan biaya hukum, kecuali
-jika kewajiban atau pengeluaran disebabkan oleh pelanggaran, kelalaian, atau
-perbuatan tidak pantas yang disengaja oleh Google. Jika Anda dikecualikan secara
-hukum dari tanggung jawab tertentu, termasuk perlindungan terhadap kerugian,
-tanggung jawab tersebut tidak berlaku bagi Anda berdasarkan Persyaratan.
-
-Dalam keadaan apa pun, Google tidak akan bertanggung jawab atas ganti rugi tidak
-langsung, ganti rugi khusus, ganti rugi insidental, ganti rugi sebagai
-peringatan, ganti rugi sebagai akibat, atau ganti rugi penghukuman, atau
-hilangnya keuntungan dalam bentuk apa pun sehubungan dengan Persyaratan atau
-Aset AlphaFold 3, meskipun Google telah diberi tahu tentang kemungkinan adanya
-ganti rugi tersebut. Total kewajiban kumulatif Google untuk semua klaim yang
-timbul dari atau sehubungan dengan Persyaratan atau Aset AlphaFold 3, termasuk
-karena kelalaiannya sendiri, dibatasi hingga $500.
-
-## 10. Ketentuan lainnya
-
-Secara hukum, Anda memiliki hak tertentu yang tidak dapat dibatasi oleh kontrak
-seperti Persyaratan. Persyaratan sama sekali tidak dimaksudkan untuk membatasi
-hak tersebut.
-
-Persyaratan merupakan keseluruhan perjanjian kami terkait penggunaan Aset
-AlphaFold 3 oleh Anda dan menggantikan perjanjian sebelumnya atau pada saat yang
-sama yang menyangkut penggunaan tersebut.
-
-Jika ternyata ada ketentuan dalam Persyaratan yang tidak memiliki kekuatan
-hukum, ketentuan lainnya dalam Persyaratan akan tetap berlaku dan memiliki
-kekuatan hukum penuh.
-
-## 11. Sengketa
-
-Hukum California akan mengatur semua sengketa yang timbul dari atau berkaitan
-dengan Persyaratan atau sehubungan dengan Aset AlphaFold 3. Sengketa ini akan
-diselesaikan secara eksklusif di pengadilan federal atau negara bagian Santa
-Clara County, California, Amerika Serikat dan Anda serta Google menyetujui
-wilayah hukum pribadi di pengadilan tersebut. Jika hukum setempat yang berlaku
-mencegah sengketa tertentu diselesaikan di pengadilan California, Anda dan
-Google dapat mengajukan sengketa tersebut di pengadilan setempat Anda. Jika
-hukum setempat yang berlaku mencegah pengadilan setempat Anda menerapkan hukum
-California untuk menyelesaikan sengketa ini, sengketa ini akan diatur oleh hukum
-setempat yang berlaku dari negara, negara bagian, atau tempat tinggal Anda yang
-lain. Jika Anda menggunakan Aset AlphaFold 3 atas nama organisasi pemerintah
-selain organisasi pemerintah federal Amerika Serikat (dengan ketentuan yang
-disebutkan sebelumnya akan berlaku selama diizinkan oleh hukum federal),
-Persyaratan ini tidak akan berlaku untuk pengadilan dan hukum yang mengatur.
-
-Mengingat sifat riset ilmiah, mungkin perlu waktu beberapa saat hingga
-pelanggaran terhadap Persyaratan terlihat jelas. Untuk melindungi Anda, Google,
-dan Aset AlphaFold 3, selama diizinkan hukum yang berlaku, Anda setuju bahwa:
-
-1.  klaim hukum apa pun terkait Persyaratan atau Aset AlphaFold 3 dapat diajukan
-    hingga:
-    1.  tanggal batas waktu berdasarkan hukum yang berlaku untuk mengajukan
-        klaim hukum; atau
-    2.  dua tahun sejak tanggal Anda atau Google (sebagaimana berlaku)
-        mengetahui, atau seharusnya secara wajar mengetahui, fakta yang
-        menimbulkan klaim tersebut; dan
-2.  Anda dan Google tidak akan memperdebatkan pembatasan, batas waktu,
-    penundaan, pelepasan hak, atau sejenisnya dalam upaya untuk menghalangi
-    gugatan yang diajukan dalam jangka waktu tersebut.
-
-Semua hak yang tidak secara khusus dan tegas diberikan kepada Anda oleh
-Persyaratan menjadi hak milik Google. Penundaan, tindakan, atau kelalaian oleh
-Google dalam melaksanakan hak atau upaya hukum apa pun tidak akan dianggap
-sebagai pelepasan hak atas pelanggaran terhadap Persyaratan, dan Google secara
-tegas memiliki semua hak dan upaya hukum yang tersedia berdasarkan Persyaratan,
-hukum, ekuitas, atau lainnya, termasuk upaya hukum yang menyangkut penyelesaian
-dengan perintah pengadilan atas setiap ancaman atau pelanggaran nyata terhadap
-Persyaratan tanpa perlu membuktikan kerugian yang sebenarnya.
diff --git a/legal/WEIGHTS_TERMS_OF_USE-Espanol-Latinoamerica.md b/legal/WEIGHTS_TERMS_OF_USE-Espanol-Latinoamerica.md
deleted file mode 100644
index e2cbd2407d3158f665d87507aaba7b3aa55526b8..0000000000000000000000000000000000000000
--- a/legal/WEIGHTS_TERMS_OF_USE-Espanol-Latinoamerica.md
+++ /dev/null
@@ -1,313 +0,0 @@
-# CONDICIONES DE USO DE LOS PARÁMETROS DEL MODELO ALPHAFOLD 3
-
-Última modificación: 9 de noviembre de 2024
-
-[AlphaFold 3](https://blog.google/technology/ai/google-deepmind-isomorphic-alphafold-3-ai-model/)
-es un modelo de IA desarrollado por [Google DeepMind](https://deepmind.google/)
-y por [Isomorphic Labs](https://www.isomorphiclabs.com/). Genera predicciones de
-estructuras 3D de moléculas biológicas, lo que proporciona confianza del modelo
-para las predicciones de estructuras. Creamos los parámetros del modelo
-entrenado y los resultados generados y los ponemos a disposición sin costo para
-determinados usos no comerciales de conformidad con las condiciones de uso y la
-[Política de Uso Prohibido de los Parámetros del Modelo AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Espanol-Latinoamerica.md).
-
-**Puntos clave para tener en cuenta al usar los parámetros y los resultados del
-modelo AlphaFold 3**
-
-1.  Los parámetros y los resultados del modelo AlphaFold 3 solo están
-    disponibles para usos no comerciales de organizaciones no comerciales (*es
-    decir*, universidades, organizaciones sin fines de lucro, instituciones de
-    investigación y organismos educativos, periodísticos y gubernamentales), o
-    bien en su nombre. Si usted es un investigador afiliado de una organización
-    no comercial, en la medida en que no pertenezca a una organización comercial
-    ni actúe en nombre de una, puede usar estos recursos para su investigación
-    de afiliación no comercial.
-    1.  No debe utilizar ni permitir que otros utilicen AlphaFold 3 ni sus
-        parámetros o resultados en los siguientes casos:
-    2.  En conexión con cualquier actividad comercial, incluidas investigaciones
-        en nombre de organizaciones comerciales
-2.  Para entrenar modelos de aprendizaje automático, o bien tecnologías
-    relacionadas para la predicción de estructuras biomoleculares, similares a
-    AlphaFold 3
-3.  No *debe* publicar ni compartir los parámetros del modelo AlphaFold 3,
-    excepto dentro de su organización, de acuerdo con estas Condiciones.
-4.  Puede publicar, compartir y adaptar los *resultados* de AlphaFold 3 de
-    conformidad con estas Condiciones, que incluyen el requisito de brindar un
-    aviso claro de que cualquier modificación que haga y el uso continuo de los
-    resultados de AlphaFold 3 y sus derivaciones están sujetas a las
-    [Condiciones de Uso de los Resultados de AlphaFold](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-Al usar, reproducir, modificar, realizar, distribuir o mostrar cualquier porción
-o elemento de los Parámetros del Modelo (como se definen a continuación), o bien
-al aceptar las condiciones de este acuerdo, usted se compromete a cumplir con lo
-siguiente: (1) estas Condiciones de Uso y (2) la
-[Política de Uso Prohibido de los Parámetros del Modelo AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Espanol-Latinoamerica.md),
-que se incorpora por referencia en este documento (en conjunto, las
-"**Condiciones**"), en cada caso, (a) según las modificaciones ocasionales que
-se hagan de acuerdo con las Condiciones y (b) entre usted y (i) si es de un país
-del Espacio Económico Europeo o Suiza, Google Ireland Limited o (ii) en
-cualquier otro caso, Google LLC.
-
-Confirma que tiene la autorización explícita o implícita para celebrar, y está
-celebrando, las Condiciones como empleado o de otra manera en nombre de su
-organización.
-
-Lea cuidadosamente estas Condiciones. En ellas, se establece lo que usted puede
-esperar de nosotros cuando usa los Recursos de AlphaFold 3, como se describen a
-continuación, y lo que Google espera de usted. Cuando decimos "**usted**",
-hacemos referencia al individuo o la organización que usa los Recursos de
-AlphaFold 3. Cuando decimos "**nosotros**" o "**Google**", hacemos referencia a
-las entidades que pertenecen al grupo de empresas de Google, que comprende a
-Google LLC y sus afiliadas.
-
-## 1. Definiciones clave
-
-Según su uso en estas Condiciones:
-
-"**AlphaFold 3**" significa: (a) el código fuente de AlphaFold 3 disponible
-[aquí](https://github.com/google-deepmind/alphafold3/) y con licencia en virtud
-de las condiciones de la Atribución/Reconocimiento-NoComercial-CompartirIgual
-4.0 Internacional (CC-BY-NC-SA 4.0) de Creative Commons, y cualquier código
-fuente derivado, y (b) los Parámetros del Modelo.
-
-"**Recursos de AlphaFold 3**" hace referencia a los Resultados y los Parámetros
-del Modelo.
-
-"**Distribución" o "Distribuir**" incluye cualquier transmisión, publicación y
-otras instancias en las que se comparten los Resultados de manera pública o a
-otra persona.
-
-"**Parámetros del Modelo**" hace referencia a las ponderaciones y los parámetros
-del modelo entrenado, que Google pone a disposición para las organizaciones (a
-su entera discreción) para su uso de acuerdo con estas Condiciones, junto con
-(a) las modificaciones a esas ponderaciones y parámetros, (b) los trabajos
-basados en esas ponderaciones y parámetros, o bien (c) otros modelos de
-aprendizaje automático y código que incorporan, en su totalidad o en parte,
-estos parámetros y ponderaciones.
-
-"**Resultados**" hace referencia a las predicciones de estructura y toda la
-información adicional y relacionada que brinda AlphaFold 3 o el uso de los
-Parámetros del Modelo, además de toda representación visual, predicción
-computacional, descripción, modificación, copia o adaptación que esté
-sustancialmente derivada de los Resultados.
-
-"**Lo que incluye**" significa "**incluido, sin limitarse a ello**".
-
-## 2. Acceso y uso de los Recursos de AlphaFold 3
-
-Sujeto al cumplimiento de estas Condiciones, lo que incluye la
-[Política de Uso Prohibido de los Parámetros del Modelo AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Espanol-Latinoamerica.md),
-puede acceder a los Recursos de AlphaFold 3, usarlos y modificarlos, y
-Distribuir los Resultados como se define en estas Condiciones. Le otorgamos una
-licencia no exclusiva, libre de regalías, revocable, no transferible y no
-susceptible de someterse a otras licencias (excepto como se indica expresamente
-en estas Condiciones) respecto de cualquier derecho de propiedad intelectual que
-tengamos sobre los Recursos de AlphaFold en la medida necesaria para estos
-propósitos. Para verificar su acceso a AlphaFold 3 y el uso correspondiente,
-podríamos solicitarle ocasionalmente información adicional sobre usted, ya sea
-que verifique su nombre, su organización o cualquier otra información
-identificatoria.
-
-Al acceder a los Recursos de AlphaFold 3 y usarlos o modificarlos, así como al
-Distribuir Resultados o solicitar acceso a los Parámetros del Modelo, manifiesta
-y garantiza que (a) tiene plenas facultades y atribuciones para celebrar estas
-Condiciones (lo que incluye tener la edad de consentimiento), (b) Google nunca
-rescindió en el pasado su acceso a AlphaFold 3 ni su derecho de uso (lo que
-incluye su disponibilidad a través de
-[AlphaFold Server](https://alphafoldserver.com/about)) debido a su
-incumplimiento de las Condiciones de Uso correspondientes, (c) el cumplimiento
-de estas Condiciones o el ejercicio de sus derechos y obligaciones no infringirá
-ningún acuerdo que tenga con un tercero ni ningún derecho de terceros, (d)
-cualquier información que usted proporcione a Google en relación con AlphaFold
-3, incluida la necesaria (cuando corresponda) para solicitar acceso a los
-Parámetros del Modelo, es correcta y actual, y (e) usted no (i) es residente de
-un país bajo embargo, (ii) es residente de un país bajo el embargo de EE.UU. ni
-(iii) tiene prohibiciones a través de controles de exportación aplicables y
-programas de sanción el acceso a los Recursos de AlphaFold 3, así como su uso y
-modificación.
-
-Si decide enviarle comentarios a Google, como sugerencias para mejorar AlphaFold
-3, asegura que esa información no es confidencial ni de su propiedad, y que
-Google puede actuar respecto de sus comentarios sin tener ninguna obligación con
-usted.
-
-## 3. Restricciones de uso
-
-No debe usar ninguno de los Recursos de AlphaFold 3 en los siguientes casos:
-
-1.  Los usos restringidos establecidos en la
-    [Política de Uso Prohibido de los Parámetros del Modelo AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Espanol-Latinoamerica.md)
-
-2.  En incumplimiento de las leyes y reglamentaciones aplicables
-
-En el sentido más amplio permitido por la ley y sin limitar ninguno de nuestros
-otros derechos, Google se reserva el derecho de revocar su derecho de usar y (en
-la medida que sea viable) restringir el uso de cualquiera de los Recursos de
-AlphaFold 3 que Google razonablemente cree que infringe estas Condiciones.
-
-## 4. Resultados generados
-
-Aunque debe cumplir con estas Condiciones cuando usa los Recursos de AlphaFold
-3, no reclamaremos la propiedad de los Resultados originales que genere usando
-AlphaFold 3. Sin embargo, usted reconoce que AlphaFold 3 puede generar los
-mismos Resultados, o bien otros similares, para varios usuarios, incluido
-Google, y nos reservamos todos nuestros derechos al respecto.
-
-## 5. Cambios en los Recursos de AlphaFold 3 o estas Condiciones
-
-Google podría agregar o quitar funciones de los Recursos de AlphaFold 3 en
-cualquier momento, y también podría quitar por completo el acceso a los Recursos
-de AlphaFold 3.
-
-Google podría actualizar estas Condiciones y el mecanismo de acceso a los
-Parámetros del Modelo en cualquier momento. Publicaremos cualquier modificación
-a las Condiciones
-[en el repositorio de GitHub de AlphaFold 3](https://github.com/google-deepmind/alphafold3).
-En general, los cambios entrarán en vigencia 14 días después de su publicación.
-Sin embargo, los cambios relacionados con funciones o realizados por motivos
-legales entrarán en vigencia de inmediato.
-
-Debería revisar las Condiciones siempre que realicemos actualizaciones o que use
-los Recursos de AlphaFold 3. Si no está de acuerdo con las modificaciones de las
-Condiciones, debe dejar de usar los Recursos de AlphaFold 3 de inmediato.
-
-## 6. Suspensión o rescisión de su derecho de uso de los Recursos de AlphaFold 3
-
-Google puede, en cualquier momento, suspender o rescindir su derecho de uso y,
-según corresponda, acceso a los Recursos de AlphaFold 3 debido a, entre otros
-motivos, su incumplimiento de estas Condiciones. Si Google suspende o rescinde
-su derecho de acceso o uso de los Recursos de AlphaFold 3, debe borrarlos y
-dejar de usar y Distribuir todas las copias correspondientes que tenga en su
-posesión o control, y se le prohibirá usar los Recursos de AlphaFold 3, lo que
-incluye el envío de solicitudes para usar los Parámetros del Modelo. Google
-tratará de darle un aviso con una antelación razonable antes de cualquier
-suspensión o rescisión, pero no se le dará ningún aviso ni advertencia previos
-si la suspensión o rescisión se deben a su incumplimiento de las Condiciones o
-alguna otra razón grave.
-
-Tenga en cuenta que puede dejar de usar los Recursos de AlphaFold 3 cuando lo
-desee. Si los deja de usar, le agradeceríamos saber el motivo (a través de
-alphafold@google.com) para que podamos continuar mejorando nuestras tecnologías.
-
-## 7. Confidencialidad
-
-Usted acepta no divulgar ni poner a disposición Información Confidencial de
-Google sin obtener nuestro previo consentimiento por escrito. "Información
-Confidencial de Google" hace referencia a (a) los Parámetros del Modelo
-AlphaFold 3 y todo el software, la tecnología y la documentación relacionada con
-AlphaFold 3, excepto el código fuente de AlphaFold 3, y (b) cualquier otra
-información que Google ponga a disposición y se marque como confidencial o que
-normalmente se consideraría confidencial en las circunstancias en las que se
-presenta. La Información Confidencial de Google no incluye (a) información que
-usted ya conocía antes de acceder a los Recursos de AlphaFold 3 o de usarlos
-(que se incluye a través de
-[AlphaFold Server](https://alphafoldserver.com/about)), (b) información que se
-comparte de manera pública por una razón que no lo responsabiliza (por ejemplo,
-su incumplimiento de las Condiciones), (c) información que usted desarrolló de
-manera independiente sin hacer referencia a la Información Confidencial de
-Google, o (d) información que recibió de manera legal de parte de un tercero
-(sin que usted o ese tercero hayan incumplido las Condiciones).
-
-## 8. Renuncias de responsabilidad
-
-Ninguna disposición de las Condiciones restringe ningún derecho que no pueda
-restringirse en función de la ley aplicable ni limita las responsabilidades de
-Google, excepto según lo que permite la ley aplicable.
-
-**AlphaFold 3 y los Resultados se brindan "tal cual son", sin garantías de
-ningún tipo, ya sean explícitas o implícitas, lo que incluye garantías o
-condiciones de titularidad, no incumplimiento, comerciabilidad o adecuación para
-un propósito particular. Usted es el único responsable de determinar la
-idoneidad del uso de AlphaFold 3, o bien del uso o la distribución de los
-Resultados, y asume todos los riesgos asociados con ese uso o distribución y su
-ejercicio de los derechos y las obligaciones según estas Condiciones. Usted y
-todas las personas con quienes comparta los Resultados serán los únicos
-responsables de estos usos y sus usos posteriores.**
-
-**Los Resultados son predicciones con diversos niveles de confianza y deberían
-interpretarse con cuidado. Sea prudente antes de basarse en el contenido de
-AlphaFold 3, o bien publicarlo, descargarlo o usarlo de cualquier otro modo.**
-
-**AlphaFold 3 y los Resultados deben usarse únicamente para el modelado teórico.
-No están pensados, validados ni aprobados para uso clínico. No debe usar
-AlphaFold 3 ni los Resultados con fines clínicos, ni basarse en ellos para dar
-consejos médicos ni de índole profesional. Cualquier contenido relacionado con
-esos temas se proporciona solo con fines informativos y no sustituye el
-asesoramiento de un profesional calificado.**
-
-## 9. Responsabilidades
-
-En la medida en que lo permita la legislación aplicable, usted indemnizará a
-Google y sus directores, funcionarios, empleados y contratistas por cualquier
-procedimiento legal de terceros (incluidas las acciones de las autoridades
-gubernamentales) que surja de su uso ilegal de los Recursos de AlphaFold 3 o del
-incumplimiento de estas Condiciones. Esta indemnización cubrirá cualquier
-responsabilidad o gasto que surja a partir de reclamos, pérdidas, daños,
-juicios, multas, costos de litigios y honorarios legales, excepto en la medida
-en que una responsabilidad o un gasto sean causados por un incumplimiento,
-negligencia o conducta inapropiada voluntaria por parte de Google. Si en su caso
-se aplica una exención legal de ciertas responsabilidades, lo que incluye la
-indemnización, no deberá hacerse cargo de estas responsabilidades según estas
-Condiciones.
-
-En ningún caso Google será responsable de daños indirectos, especiales,
-incidentales, ejemplares, resultantes ni punitivos, ni de la pérdida de
-ganancias de ningún tipo en conexión con estas Condiciones o los Recursos de
-AlphaFold 3, incluso si se le advirtió sobre la posibilidad de dichos daños. La
-responsabilidad conjunta de Google por todos los reclamos que surjan en conexión
-con estas Condiciones o los Recursos de AlphaFold 3, lo que incluye los que
-surjan de su propia negligencia, se limita a USD 500.
-
-## 10. Varios
-
-Por ley, tiene ciertos derechos que no pueden estar limitados por un contrato,
-como estas Condiciones. Las Condiciones no tienen la intención de restringir
-esos derechos.
-
-Las Condiciones son nuestro acuerdo completo relacionado con su uso de los
-AlphaFold 3 y sustituyen cualquier acuerdo anterior o contemporáneo sobre la
-materia.
-
-Si cualquier disposición de estas Condiciones resultase inejecutable, el resto
-seguirá plenamente en vigencia.
-
-## 11. Disputas
-
-La ley de California regirá todas las disputas que surjan de las Condiciones o
-en conexión con los Recursos de AlphaFold 3. Estas disputas se resolverán
-exclusivamente en los tribunales federales o estatales del Condado de Santa
-Clara, California, EE.UU., y usted y Google aceptan someterse a la jurisdicción
-personal de dichos tribunales. En la medida en que la ley local aplicable impida
-que ciertas disputas se resuelvan en un tribunal de California, usted y Google
-pueden presentarlas en los tribunales locales de su jurisdicción. Si la ley
-local aplicable impide que su tribunal local aplique la ley de California para
-resolver las disputas, estas se regirán por las leyes locales aplicables de su
-país, estado o lugar de residencia. Si usará los Recursos de AlphaFold 3 en
-nombre de una organización gubernamental que no sea del gobierno federal de
-Estados Unidos (donde se aplican las disposiciones mencionadas anteriormente en
-la medida en que la ley federal lo permita), estas Condiciones no se aplicarán
-en relación con la ley aplicable y los tribunales.
-
-Dada la naturaleza de la investigación científica, el incumplimiento de las
-Condiciones puede tardar algún tiempo en hacerse evidente. Para protegerlo a
-usted, y proteger a Google y a los Recursos de AlphaFold 3, en la medida en que
-lo permita la ley aplicable, usted acepta lo siguiente:
-
-1.  Cualquier demanda legal relacionada con las Condiciones o los Recursos de
-    AlphaFold 3 podrá iniciarse hasta la fecha posterior de lo siguiente:
-    1.  la fecha límite que establece la ley aplicable para interponer una
-        demanda legal; o
-    2.  dos años a partir de la fecha en que usted o Google (según corresponda)
-        tomaron conocimiento, o debieron haber tomado conocimiento
-        razonablemente, de los hechos que dieron lugar a dicha demanda, y
-2.  Ni usted ni Google alegarán prescripción, caducidad, demora, renuncia o
-    similares para intentar impedir una acción presentada dentro de ese período.
-
-Todos los derechos que no se le otorguen específica y expresamente en las
-Condiciones quedan reservados a Google. Ninguna demora, omisión o acto de Google
-en el ejercicio de cualquier derecho o recurso se considerará una renuncia de
-cualquier incumplimiento de las Condiciones y Google se reserva expresamente
-todos los derechos y recursos disponibles según las Condiciones, la ley, por
-acuerdo implícito o de cualquier otro modo, lo que incluye el recurso de medida
-cautelar contra cualquier amenaza o hecho de infracción de las Condiciones sin
-la necesidad de mostrar daños reales.
diff --git a/legal/WEIGHTS_TERMS_OF_USE-Francais-Canada.md b/legal/WEIGHTS_TERMS_OF_USE-Francais-Canada.md
deleted file mode 100644
index bacdc18a80984228abfd640211c29b9edf46cad0..0000000000000000000000000000000000000000
--- a/legal/WEIGHTS_TERMS_OF_USE-Francais-Canada.md
+++ /dev/null
@@ -1,324 +0,0 @@
-# CONDITIONS D'UTILISATION DES PARAMÈTRES DU MODÈLE ALPHAFOLD 3
-
-Dernière modification: 2024-11-09
-
-[AlphaFold 3](https://blog.google/technology/ai/google-deepmind-isomorphic-alphafold-3-ai-model/)
-est un modèle d'IA développé par [Google DeepMind](https://deepmind.google/) et
-[Isomorphic Labs](https://www.isomorphiclabs.com/). Il génère des prédictions de
-structures 3D de molécules biologiques en fournissant la confiance du modèle
-pour les prédictions de structures. Pour certaines utilisations non
-commerciales, nous mettons gratuitement à disposition les paramètres du modèle
-entraîné et les résultats générés à l'aide de ces paramètres, conformément aux
-présentes conditions d'utilisation et à la
-[Politique d'utilisation interdite des paramètres du modèle AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Francais-Canada.md).
-
-**Éléments clés à connaître lors de l'utilisation des paramètres du modèle
-AlphaFold 3 et les résultats**
-
-1.  Les paramètres du modèle AlphaFold 3 et les résultats sont **uniquement**
-    disponibles pour un usage non commercial par des organisations non
-    commerciales ou au nom de celles-ci (*c.-à-d.* universités, organismes sans
-    but lucratif, instituts de recherche et organismes éducatifs,
-    journalistiques et gouvernementaux). Si vous êtes un chercheur affilié à une
-    organisation non commerciale, **à la condition que vous ne soyez pas une
-    organisation commerciale ou que vous n'agissiez pas au nom d'une
-    organisation commerciale**, cela signifie que vous pouvez les utiliser pour
-    votre recherche affiliée non commerciale.
-2.  Vous **ne devez pas** utiliser ni permettre à d'autres personnes d'utiliser:
-    1.  les paramètres du modèle AlphaFold 3 ou les résultats dans le cadre de
-        **toute activité commerciale, y compris la recherche au nom
-        d'organisations commerciales**; ou
-    2.  les résultats d'AlphaFold 3 pour **entraîner des modèles d'apprentissage
-        automatique** ou une technologie connexe de **prédiction de structures
-        biomoléculaires** semblable à AlphaFold 3.
-3.  Vous ***ne devez pas* publier ni partager les paramètres du modèle AlphaFold
-    3**, sauf si vous les partagez au sein de votre organisation conformément
-    aux présentes Conditions.
-4.  Vous ***pouvez* publier, partager ou adapter les *résultats* d'AlphaFold 3**
-    conformément aux présentes Conditions, y compris à l'exigence de fournir un
-    préavis clair de toute modification que vous apportez et à celle stipulant
-    que l'utilisation continue des résultats et des œuvres dérivées d'AlphaFold
-    3 est soumise aux
-    C[onditions d'utilisation des résultats d'AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-En utilisant, reproduisant, modifiant, exécutant, distribuant ou affichant toute
-portion ou tout élément des Paramètres du modèle (comme défini ci-dessous) ou en
-acceptant autrement les conditions de ce contrat, vous acceptez d'être lié par
-(1) ces conditions d'utilisation et (2) la
-[Politique d'utilisation interdite des paramètres du modèle AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Francais-Canada.md)
-qui est incorporée aux présentes par référence (collectivement, les « Conditions
-»), dans chaque cas (a) tel que modifié de temps à autre conformément aux
-Conditions et (b) entre vous et (i) si vous êtes d'un pays de l'Espace
-économique européen ou de la Suisse, Google Ireland Limited, ou (ii) autrement,
-Google LLC.
-
-Vous confirmez que vous êtes autorisé, soit explicitement ou implicitement, à
-accepter les Conditions et que vous les acceptez, en tant qu'employé ou
-autrement, au nom de votre organisation.
-
-Veuillez lire ces Conditions attentivement. Elles établissent ce à quoi vous
-pouvez vous attendre de nous lorsque vous accédez aux Éléments d'AlphaFold 3 et
-que vous les utilisez (comme défini ci-dessous), et ce à quoi Google s'attend de
-vous. Par « **vous** », nous entendons l’individu ou l'organisation qui utilise
-les Éléments d'AlphaFold 3. Par « **nous** », « **notre** » ou « **Google** »,
-nous entendons les entités qui appartiennent au groupe d'entreprises Google,
-c'est-à-dire Google LLC et ses filiales.
-
-## 1. Définitions clés
-
-Telle qu’utilisées dans ces Conditions: \
-« **AlphaFold 3** » désigne: (a) le code source d'AlphaFold 3 rendu accessible
-[ici](https://github.com/google-deepmind/alphafold3/) et sous les conditions de
-la licence « Creative Commons Attribution-NonCommercial-Sharealike 4.0
-International (CC-BY-NC-SA 4.0) » ainsi que tout code source d'œuvres dérivées
-et (b) les Paramètres du modèle.
-
-« **Éléments d'AlphaFold 3** » signifie les Paramètres du modèle et les
-Résultats.
-
-« **Distribution** » ou « **Distribuer** » signifient toute transmission,
-publication ou tout autre partage de Résultats effectués publiquement ou avec
-une autre personne.
-
-« **Paramètres du modèle** » désigne les poids du modèle entrainé et paramètres
-mis à disposition par Google pour les organisations (à sa seule discrétion) pour
-leur utilisation conformément à ces Conditions, ainsi que (a) les modifications
-apportées à ces poids et paramètres (b) les travaux basés sur ces poids et
-paramètres ou (c) tout autre code ou tout autre modèle d'apprentissage
-automatique qui intègre, en totalité ou en partie, ces poids et paramètres.
-
-« **Résultats** » désigne les prédictions de structures et toutes les
-informations auxiliaires et connexes fournies par AlphaFold 3 ou utilisant les
-Paramètres du modèle ainsi que toutes les représentations visuelles, les
-prédictions informatiques, les descriptions, les modifications, les copies ou
-les adaptations qui sont substantiellement dérivées des Résultats.
-
-« **Y compris** » signifie « **y compris, sans s'y limiter** ».
-
-## 2. Accéder aux Éléments d'AlphaFold 3 et les utiliser
-
-Sous réserve de votre conformité aux Conditions, y compris la
-P[olitique d'utilisation interdite des paramètres du modèle AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Francais-Canada.md),
-vous pouvez accéder aux Éléments d'AlphaFold 3, les utiliser et les modifier, et
-Distribuer les Résultats comme indiqué dans ces Conditions. Nous vous accordons
-une licence non exclusive, libre de redevances, révocable, non transférable et
-non susceptible de faire l'objet d'une sous-licence (sauf si expressément permis
-dans ces Conditions) sur tout droit de propriété intellectuelle que nous
-détenons sur les Éléments d'AlphaFold, dans la mesure nécessaire à ces fins.
-Afin de vérifier votre accès à AlphaFold 3 et votre utilisation de celui-ci,
-nous pouvons de temps à autre vous demander des informations supplémentaires, y
-compris la validation de votre nom, de votre organisation et d'autres
-informations d'identification.
-
-En accédant aux Éléments d'AlphaFold 3, en les utilisant ou en les modifiant, en
-Distribuant des Résultats ou en demandant l'accès aux Paramètres du modèle, vous
-déclarez et garantissez que (a) vous avez les pleins pouvoirs et l'autorité
-nécessaire pour accepter ces Conditions (y compris avoir l'âge de consentement
-requis) (b) Google n'a jamais précédemment résilié votre accès à AlphaFold 3 ni
-votre droit de l'utiliser (y compris au moyen du
-[Serveur AlphaFold](https://alphafoldserver.com/about)) en raison de votre
-violation des conditions d'utilisation applicables (c) l'acceptation de ces
-Conditions ou l'exécution de vos droits et obligations en vertu de ces
-Conditions ne violera aucun contrat que vous avez avec un tiers ni aucun droit
-d'un tiers (d) toute information que vous fournissez à Google en relation avec
-AlphaFold 3, y compris (le cas échéant) pour demander l'accès aux Paramètres du
-modèle, est correcte et à jour, et (e) vous n'êtes pas (i) résident d'un pays
-soumis à un embargo (ii) habituellement résident d'un pays sous embargo
-américain ni (iii) autrement soumis à une interdiction, par les contrôles
-d'exportation et les programmes de sanctions applicables, d'accéder aux Éléments
-d'AlphaFold 3, de les utiliser ou de les modifier.
-
-Si vous choisissez de donner des commentaires à Google, comme des suggestions
-pour améliorer AlphaFold 3, vous vous engagez à ce que ces informations soient
-non confidentielles et non propriétaire, et Google pourra agir en fonction de
-vos commentaires sans aucune obligation envers vous.
-
-## 3. Restrictions d'utilisation
-
-Vous ne devez pas utiliser les Éléments d'AlphaFold 3:
-
-1.  pour les utilisations restreintes énoncées dans la
-    P[olitique d'utilisation interdite des paramètres du modèle AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Francais-Canada.md);
-2.  en violation des lois et règlements applicables.
-
-Dans toute la mesure permise par la loi et sans limiter aucun de nos autres
-droits, Google se réserve le droit de révoquer votre droit d'utilisation et
-(dans la mesure du possible) de restreindre l'utilisation de tout Élément
-d'AlphaFold 3 que Google estime raisonnablement être en violation de ces
-Conditions.
-
-## 4. Résultats générés
-
-Bien que vous deviez respecter ces Conditions lors de l'utilisation des Éléments
-d'AlphaFold 3, nous ne revendiquerons pas la propriété des Résultats d'origine
-que vous générez en utilisant AlphaFold 3. Cependant, vous reconnaissez
-qu'AlphaFold 3 peut générer les mêmes Résultats ou des Résultats semblables pour
-plusieurs utilisateurs, y compris Google, et nous nous réservons tous nos droits
-à cet égard.
-
-## 5. Modifications aux Éléments d'AlphaFold 3 ou aux présentes Conditions
-
-Google peut ajouter ou retirer des fonctions ou fonctionnalités des Éléments
-d'AlphaFold 3 à tout moment et peut cesser d'offrir l'accès aux Éléments
-d'AlphaFold 3.
-
-Google peut mettre à jour ces Conditions et le mécanisme d'accès aux Paramètres
-du modèle à tout moment. Nous allons publier toute modification apportée aux
-Conditions
-[dans le référentiel GitHub d'AlphaFold 3](https://github.com/google-deepmind/alphafold3).
-Les modifications entreront généralement en vigueur 14 jours après leur
-publication. Cependant, les modifications concernant la fonctionnalité ou celles
-apportées pour des raisons juridiques entreront en vigueur immédiatement.
-
-Vous devriez revoir les Conditions chaque fois que nous les mettons à jour ou
-que vous utilisez les Éléments d'AlphaFold 3. Si vous n'acceptez pas les
-modifications apportées aux Conditions, vous devez cesser d'utiliser les
-Éléments d'AlphaFold 3 immédiatement.
-
-## 6. Suspendre ou résilier votre droit d'utiliser les Éléments d'AlphaFold 3
-
-Google peut à tout moment suspendre ou résilier votre droit d'utiliser les
-Éléments d'AlphaFold 3 et, le cas échéant, d'y accéder pour différentes raisons,
-notamment votre manquement à respecter entièrement les présentes Conditions. Si
-Google suspend ou résilie votre droit d'accéder aux Éléments d'AlphaFold 3 ou de
-les utiliser, vous devez immédiatement supprimer toutes les copies des Éléments
-d'AlphaFold 3 en votre possession ou sous votre contrôle et cesser de les
-utiliser et de les Distribuer, et il vous est interdit d'utiliser les Éléments
-d'AlphaFold 3, y compris en soumettant une demande pour utiliser les Paramètres
-du modèle. Google s'efforcera de vous donner un préavis raisonnable avant toute
-suspension ou résiliation, mais aucun avis ni avertissement préalable ne sera
-donné si la suspension ou la résiliation est due à votre manquement à respecter
-entièrement les présentes Conditions ou à d'autres motifs sérieux.
-
-Bien entendu, vous êtes toujours libre de cesser d'utiliser les Éléments
-d'AlphaFold 3. Si vous cessez de les utiliser, nous aimerions savoir pourquoi (à
-l'adresse alphafold@google.com) afin de pouvoir continuer à améliorer nos
-technologies.
-
-## 7. Confidentialité
-
-Vous acceptez de ne pas divulguer ni rendre disponibles les renseignements
-confidentiels de Google à quiconque sans notre consentement écrit préalable. «
-**Renseignements confidentiels de Google** » désigne (a) les Paramètres du
-modèle AlphaFold 3 et tous les logiciels, la technologie et la documentation en
-lien avec AlphaFold 3, excepté le code source d'AlphaFold 3, et (b) toute autre
-information mise à disposition par Google qui est marquée comme confidentielle
-ou qui serait normalement considérée comme confidentielle dans les circonstances
-dans lesquelles elle est présentée. Les Renseignements confidentiels de Google
-n'incluent pas (a) les informations que vous connaissiez déjà avant d'accéder
-aux Éléments d'AlphaFold 3 ou de les utiliser (y compris au moyen du
-[Serveur AlphaFold](https://alphafoldserver.com/about)) (b) qui deviennent
-publiques sans que vous en soyez responsable (par exemple, par votre violation
-des Conditions) (c) qui ont été développées indépendamment par vous sans
-référence aux Renseignements confidentiels de Google ou (d) qui vous ont été
-légalement fournies par un tiers (sans violation des Conditions par vous-même ou
-par le tiers).
-
-## 8. Clauses de non-responsabilité
-
-Rien dans les Conditions ne restreint les droits qui ne peuvent pas être
-restreints en vertu de la loi applicable ni ne limite les responsabilités de
-Google, sauf si cela est permis par la loi applicable.
-
-AlphaFold 3 et les Résultats sont fournis « tels quels », sans garantie ni
-condition de quelque nature que ce soit, explicite ou implicite, y compris toute
-garantie ou condition de titre, d'absence de violation, de qualité marchande ou
-d'adéquation avec un usage particulier. Vous êtes seul responsable de déterminer
-la légitimité de l'utilisation d'AlphaFold 3 ou celle de l'utilisation et de la
-distribution des Résultats, et vous assumez tous les risques liés à une telle
-utilisation ou distribution ainsi qu'à l'exercice de vos droits et obligations
-en vertu de ces Conditions. Vous et toute personne avec qui vous partagez des
-Résultats êtes les seuls responsables de ces utilisations et de celles qui
-s’ensuivent.
-
-Les Résultats sont des prédictions avec des niveaux de confiance variables et
-doivent être interprétés avec prudence. Faites preuve de discernement avant de
-vous fier à AlphaFold 3, de le publier, de le télécharger ou de l’utiliser d'une
-autre manière.
-
-AlphaFold 3 et les Résultats sont uniquement destinés à la modélisation
-théorique. Ils ne sont pas prévus, validés, ni approuvés pour une utilisation
-clinique. Vous ne devez pas utiliser AlphaFold 3 ni les Résultats à des fins
-cliniques ni les considérer comme des conseils médicaux ou professionnels. Tout
-contenu concernant ces sujets est fourni à titre informatif uniquement et ne
-remplace pas les conseils d'un professionnel qualifié.
-
-## 9. Responsabilités
-
-Dans la mesure permise par la loi applicable, vous indemniserez Google et ses
-administrateurs, dirigeants, employés et sous-traitants pour toutes poursuites
-judiciaires intentées par des tiers (y compris des actions menées par des
-autorités gouvernementales) découlant de ou en rapport avec votre utilisation
-illégale des Éléments d'AlphaFold 3 ou à votre violation des présentes
-Conditions. Cette indemnité couvre toute responsabilité ou charge financière
-résultant de réclamations, de pertes, de dommages, de jugements, d'amendes, de
-débours et de frais juridiques, sauf dans la mesure où une responsabilité ou une
-charge financière est causée par une violation, une négligence ou une inconduite
-intentionnelle de Google. Si vous êtes légalement exempté de certaines
-responsabilités, y compris l'indemnisation, alors ces responsabilités ne
-s'appliquent pas à vous en vertu des présentes Conditions.
-
-Google n'est pas responsable, en aucun cas, des dommages-intérêts indirects,
-spéciaux, accessoires, exemplaires, consécutifs ou punitifs ni des pertes de
-profits de quelque nature que ce soit en rapport avec les Conditions ou les
-Éléments d'AlphaFold 3, même si Google a été informée de la possibilité de tels
-dommages. L'obligation globale et totale de Google pour toutes les réclamations
-découlant des Conditions ou des Éléments d'AlphaFold 3 ou en lien avec ceux-ci,
-y compris pour sa propre négligence, est limitée à 500,00USD.
-
-## 10. Divers
-
-Selon la loi, vous avez certains droits qui ne peuvent pas être limités par un
-contrat tel que les Conditions. Les présentes Conditions ne visent aucunement à
-restreindre ces droits.
-
-Les Conditions constituent l'intégralité de notre contrat concernant votre
-utilisation des Éléments d'AlphaFold 3 et remplacent tous les contrats
-antérieurs ou contemporains sur ce sujet.
-
-Si une disposition particulière des présentes Conditions s'avère inapplicable,
-le reste des conditions restera en vigueur.
-
-## 11. Contestations
-
-Les lois de la Californie régiront toutes les contestations découlant de ou en
-rapport avec ces Conditions ou en lien avec les Éléments d'AlphaFold 3. Ces
-contestations seront résolues exclusivement par les tribunaux fédéraux ou
-étatiques du comté de Santa Clara, en Californie, aux États-Unis, et vous et
-Google consentez à la compétence territoriale de ces tribunaux. Dans la mesure
-où la loi locale applicable s'oppose à ce que certaines contestations soient
-résolues devant un tribunal de la Californie, vous et Google pouvez les
-soumettre à vos tribunaux locaux. Si la loi locale applicable s'oppose à ce que
-votre tribunal local applique la loi californienne pour résoudre ces
-contestations, elles seront régies par les lois locales applicables de votre
-pays, de votre État ou de votre autre lieu de résidence. Si vous utilisez les
-Éléments d'AlphaFold 3 au nom d'une organisation gouvernementale autre que les
-organisations gouvernementales fédérales américaines (où les dispositions
-précédentes s'appliquent dans la mesure permise par la loi fédérale), ces
-Conditions seront silencieuses en ce qui concerne la loi applicable et les
-tribunaux.
-
-Considérant la nature de la recherche scientifique, il peut s'écouler un certain
-temps avant que toute violation des présentes Conditions devienne évidente. \
-Dans la mesure permise par la loi applicable, pour vous protéger, Google et les
-Éléments d'AlphaFold 3, vous acceptez que:
-
-1.  toute réclamation légale liée aux présentes Conditions ou aux Éléments
-    d'AlphaFold 3 peut être intentée jusqu'à la date la plus tardive entre:
-    1.  la date limite prévue par la loi applicable pour intenter la réclamation
-        légale; ou
-    2.  deux années à partir de la date à laquelle vous ou Google (selon le cas)
-        avez pris connaissance ou auriez dû raisonnablement prendre connaissance
-        des faits à l'origine de cette réclamation; et
-2.  vous n'invoquerez pas la limitation, la prescription, le retard, la
-    renonciation ou des arguments semblables pour tenter de faire obstacle à une
-    action intentée dans ce délai et Google non plus.
-
-Tous les droits qui ne vous sont pas précisément et expressément accordés par
-les présentes Conditions sont réservés à Google. Aucun retard, acte ni aucune
-omission de la part de Google dans l'exercice d'un droit ou d'un recours ne sera
-considéré comme une renonciation à une violation des Conditions, et Google se
-réserve expressément tous les droits et recours disponibles en vertu des
-Conditions ou de la loi, en équité ou autrement, y compris le recours à une
-injonction contre toute menace de violation ou violation réelle des Conditions
-sans qu'il soit nécessaire de prouver des dommages réels.
diff --git a/legal/WEIGHTS_TERMS_OF_USE-Portugues-Brazil.md b/legal/WEIGHTS_TERMS_OF_USE-Portugues-Brazil.md
deleted file mode 100644
index 2d049dae662c08efdc620a24539c5352fea10dd9..0000000000000000000000000000000000000000
--- a/legal/WEIGHTS_TERMS_OF_USE-Portugues-Brazil.md
+++ /dev/null
@@ -1,299 +0,0 @@
-# TERMOS DE USO DOS PARÂMETROS DO MODELO ALPHAFOLD 3
-
-Última modificação: 2024-11-09
-
-O
-[AlphaFold 3](https://blog.google/technology/ai/google-deepmind-isomorphic-alphafold-3-ai-model/)
-é um modelo de IA desenvolvido pelo [Google DeepMind](https://deepmind.google/)
-e pela [Isomorphic Labs](https://www.isomorphiclabs.com/). Ele gera previsões
-sobre a estrutura 3D de moléculas biológicas, apresentando a confiança do
-modelo. Disponibilizamos os parâmetros do modelo treinado e as saídas geradas
-por ele sem custo financeiro para determinados usos não comerciais, de acordo
-com estes Termos de Uso e com a
-[Política de uso proibido dos parâmetros do modelo AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Portugues-Brazil.md).
-
-**Observações importantes sobre o uso dos parâmetros e das saídas do modelo
-AlphaFold 3**
-
-1.  Os parâmetros e as saídas do modelo AlphaFold 3 só estão disponíveis para
-    uso não comercial por organizações não comerciais ou em nome delas (*por
-    exemplo*, universidades, organizações sem fins lucrativos, institutos de
-    pesquisa e órgãos governamentais, educacionais e de notícias). Se você for
-    um pesquisador afiliado a uma organização não comercial, você tem permissão
-    para usar esses recursos em sua pesquisa afiliada a organizações sem fins
-    lucrativos, desde que você não seja uma organização comercial nem esteja
-    agindo em nome de uma.
-2.  Não use nem permita que outras pessoas usem:
-    1.  os parâmetros ou as saídas do modelo AlphaFold 3 em relação a qualquer
-        atividade comercial, incluindo a pesquisa em nome de organizações
-        comerciais; ou
-    2.  a saída do AlphaFold 3 para treinar modelos de aprendizado de máquina ou
-        tecnologia relacionada na previsão de estrutura biomolecular semelhante
-        ao AlphaFold 3.
-3.  Você *não tem permissão* para publicar ou compartilhar os parâmetros do
-    modelo AlphaFold 3, exceto compartilhar dentro da sua organização de acordo
-    com estes Termos.
-4.  Você *tem permissão* para publicar, compartilhar e adaptar as *saídas* do
-    AlphaFold 3 de acordo com estes Termos, incluindo os requisitos de oferecer
-    aviso claro de quaisquer modificações e de que o uso contínuo das saídas e
-    derivados do modelo estão sujeitos aos
-    [Termos de Uso das saídas do AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md).
-
-Ao usar, reproduzir, modificar, realizar, distribuir ou exibir qualquer parte ou
-elemento dos Parâmetros do modelo (conforme definido abaixo) ou aceitar de outra
-forma os termos deste contrato, você concorda em se vincular (1) a estes Termos
-de Uso e (2) à
-[Política de uso proibido dos parâmetros do modelo AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Portugues-Brazil.md),
-incorporada aqui como referência (em conjunto, os "**Termos**"), em cada caso
-(a) conforme modificado periodicamente de acordo com os Termos e (b) entre você
-e (i), se você for de um país no Espaço Econômico Europeu ou da Suíça, a Google
-Ireland Limited ou (ii), caso contrário, a Google LLC.
-
-Você confirma que tem autorização explícita ou implícita para celebrar, e está
-celebrando, estes Termos como funcionário ou de outro modo em nome da sua
-organização.
-
-Leia estes Termos com atenção. Eles definem o que você pode esperar de nós ao
-acessar e usar os Recursos do AlphaFold 3 (conforme definido abaixo) e o que o
-Google espera de você. "**Você**" significa o indivíduo ou a organização que
-está usando os Recursos do AlphaFold 3. "**Nós**", "**nos**" ou "**Google**"
-significam as entidades que pertencem ao grupo de empresas do Google, ou seja, a
-Google LLC e suas afiliadas.
-
-## 1. Principais definições
-
-Conforme usado nestes Termos:
-
-"**AlphaFold 3**" significa: (a) o código-fonte do AlphaFold 3 disponível
-[neste link](https://github.com/google-deepmind/alphafold3/) e licenciado nos
-termos da licença Creative Commons Attribution-NonCommercial-Sharealike 4.0
-International (CC-BY-NC-SA 4.0), bem como qualquer código-fonte derivado, e (b)
-Parâmetros do modelo.
-
-"**Recursos do AlphaFold 3**" significam as Saídas e os Parâmetros do modelo.
-
-"**Distribuição**" ou "**Distribuir**" significam qualquer transmissão,
-publicação ou outra forma de compartilhamento das Saídas publicamente ou com
-qualquer outra pessoa.
-
-"**Parâmetros do modelo**" significam os pesos e os parâmetros do modelo
-treinado disponibilizados pelo Google às organizações (a critério próprio) para
-uso de acordo com estes Termos, com (a) modificações nesses pesos e parâmetros,
-com (b) trabalhos baseados nesses pesos e parâmetros ou (c) com outros códigos
-ou modelos de aprendizado de máquina que incorporam esses pesos e parâmetros na
-íntegra ou em partes.
-
-"**Saída**" significa as previsões de estrutura e todas as informações
-adicionais e relacionadas que são fornecidas pelo AlphaFold 3 ou usam os
-Parâmetros do modelo, com quaisquer representações visuais, previsões
-computacionais, descrições, modificações, cópias ou adaptações derivadas
-consideravelmente da Saída.
-
-"**Incluindo**" significa "**incluindo, sem limitação**".
-
-## 2. Acesso e uso dos Recursos do AlphaFold 3
-
-Sujeito à sua compliance com os Termos, incluindo a
-[Política de uso proibido do AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Portugues-Brazil.md),
-você pode acessar, usar e modificar os Recursos do AlphaFold 3 e Distribuir as
-Saídas conforme definido nestes Termos. Concedemos a você uma licença não
-exclusiva, livre de royalties, revogável, intransferível e não sublicenciável
-(exceto conforme expressamente permitido nestes Termos) para todos os nossos
-direitos de propriedade intelectual dos Recursos do AlphaFold na medida
-necessária para esses fins. Para verificar seu acesso e uso do AlphaFold 3,
-podemos solicitar informações adicionais periodicamente, incluindo a verificação
-do seu nome, organização e outras informações de identificação.
-
-Ao acessar, usar ou modificar os Recursos do AlphaFold 3, Distribuir a Saída ou
-solicitar acesso aos Parâmetros do modelo, você declara e garante que (a) tem
-total capacidade legal para celebrar estes Termos (incluindo a idade mínima de
-consentimento), (b) o Google nunca rescindiu seu acesso e direito de usar o
-AlphaFold 3 (incluindo conforme disponibilizado pelo
-[Servidor da AlphaFold](https://alphafoldserver.com/about)) devido à sua
-violação dos Termos de Uso relevantes, (c) celebrar ou exercer seus direitos e
-obrigações de acordo com estes Termos não violará nenhum contrato firmado entre
-você e um terceiro ou quaisquer direitos de terceiros, (d) quaisquer informações
-que você fornecer ao Google em relação ao AlphaFold 3, incluindo solicitar
-acesso aos Parâmetros do modelo (quando aplicável), são verdadeiras e atuais, e
-(e) você (i) não é residente de um país embargado, (ii) não é residente
-ordinário de um país embargado pelos EUA ou (iii) não tem nenhuma outra
-proibição de acessar, usar ou modificar os Recursos do AlphaFold 3 pelos
-programas de sanções e controles de exportação aplicáveis.
-
-Ao optar por dar feedback ao Google, como sugestões para melhorar o AlphaFold 3,
-você assume que essas informações não são confidenciais nem reservadas, e
-poderemos agir de acordo com seu feedback sem qualquer compromisso com você.
-
-## 3. Restrições de uso
-
-Você não tem permissão para usar qualquer Recurso do AlphaFold 3:
-
-1.  para os usos restritos estabelecidos na
-    [Política de uso proibido dos Parâmetros do modelo AlphaFold 3](https://github.com/google-deepmind/alphafold3/blob/main/legal/WEIGHTS_PROHIBITED_USE_POLICY-Portugues-Brazil.md);
-    ou
-2.  em violação das leis e regulamentações aplicáveis.
-
-Até o limite permitido pela legislação e sem limitação de quaisquer outros
-direitos, o Google reserva o direito de revogar e (até onde possível) restringir
-seu uso de qualquer Recurso do AlphaFold 3 que acreditamos razoavelmente violar
-estes Termos.
-
-## 4. Saída gerada
-
-Embora você precise cumprir com estes Termos ao usar os Recursos do AlphaFold 3,
-não reivindicaremos propriedade da Saída original que você gerar usando o
-AlphaFold 3. No entanto, você reconhece que o AlphaFold 3 pode gerar uma Saída
-igual ou semelhante para vários usuários, incluindo o Google, e reservamos todos
-os direitos nesse sentido.
-
-## 5. Mudanças nos Recursos do AlphaFold 3 ou nestes Termos
-
-O Google pode adicionar ou remover funcionalidades ou funções dos Recursos do
-AlphaFold 3 a qualquer momento e parar de oferecer acesso a elas completamente.
-
-O Google pode atualizar estes Termos e o mecanismo de acesso aos Parâmetros do
-modelo a qualquer momento. Quaisquer modificações nestes Termos serão postadas
-[no repositório GitHub do AlphaFold 3](https://github.com/google-deepmind/alphafold3).
-Geralmente, as alterações entrarão em vigor 14 dias após a postagem. No entanto,
-as alterações relacionadas à funcionalidade ou feitas por motivos jurídicos
-serão aplicadas imediatamente.
-
-Consulte os Termos sempre que forem atualizados ou você usar os Recursos do
-AlphaFold 3. Se você não concordar com quaisquer modificações nos Termos, pare
-de usar os Recursos do AlphaFold 3 imediatamente.
-
-## 6. Suspensão ou encerramento do seu direito de usar os Recursos do AlphaFold 3
-
-O Google pode suspender ou encerrar a qualquer momento seu direito de usar e,
-conforme aplicável, acessar os Recursos do AlphaFold 3 devido ao não cumprimento
-dos Termos, entre outros motivos. Se o Google suspender ou encerrar seu direito
-de acessar ou usar os Recursos do AlphaFold 3, você precisará excluir e parar de
-usar e Distribuir imediatamente todas as cópias dos Recursos do AlphaFold 3 em
-sua posse ou controle. Você não poderá usar os Recursos do AlphaFold 3,
-incluindo o envio de um aplicativo para usar os Parâmetros do modelo. O Google
-fará o possível para fornecer aviso prévio razoável antes de qualquer suspensão
-ou encerramento, mas não daremos nenhum aviso ou alerta com antecedência se a
-suspensão ou o encerramento for por não obedecer totalmente aos Termos ou outras
-justificativas graves.
-
-Você pode parar de usar os Recursos do AlphaFold 3 a qualquer momento. Nesse
-caso, queremos saber o motivo (via alphafold@google.com) para continuarmos
-melhorando nossas tecnologias.
-
-## 7. Confidencialidade
-
-Você concorda em não divulgar nem disponibilizar Informações confidenciais do
-Google a qualquer pessoa sem nosso consentimento prévio por escrito.
-"**Informações confidenciais do Google**" significam (a) os Parâmetros do modelo
-e todo software, tecnologia e documentação associados ao AlphaFold 3, exceto
-para o código-fonte do AlphaFold 3, e (b) quaisquer outras informações
-disponibilizadas pelo Google que foram marcadas como confidenciais ou que seriam
-normalmente consideradas assim nas circunstâncias em que são apresentadas. As
-Informações confidenciais do Google não incluem (a) informações que você já
-sabia antes do seu acesso ou uso dos Recursos do AlphaFold 3 (incluindo pelo
-[Servidor do AlphaFold](https://alphafoldserver.com/about)), (b) que se tornaram
-públicas sem sua culpa (por exemplo, sua violação dos Termos), (c) que foram
-desenvolvidas de maneira independente por você sem referência às Informações
-confidenciais do Google ou (d) foram fornecidas legalmente a você por um
-terceiro (sem que você nem o terceiro violassem os Termos).
-
-## 8. Exoneração de responsabilidade
-
-Os Termos não restringem quaisquer direitos que não possam ser restritos de
-acordo com a legislação aplicável nem limitam as responsabilidades do Google,
-exceto conforme permitido pela legislação aplicável.
-
-**O AlphaFold 3 e as Saídas são fornecidos no estado em que se encontram, sem
-garantias ou condições de qualquer tipo, sejam explícitas ou implícitas,
-incluindo quaisquer garantias ou condições de título, comercialidade, adequação
-para uma finalidade específica e não violação. Você é a única pessoa responsável
-por determinar se o uso do AlphaFold 3, ou uso/distribuição das Saídas, é
-adequado e assume qualquer e todo risco associado a esse uso ou distribuição e
-ao exercício dos seus direitos e obrigações de acordo com estes Termos. Você e
-qualquer pessoa com quem compartilhar as Saídas são exclusivamente responsáveis
-por elas e pelos usos subsequentes delas.**
-
-**As Saídas são previsões com níveis variados de confiança e devem ser
-interpretadas com cuidado. Tenha cautela antes de confiar, publicar, baixar ou
-usar de outra forma o AlphaFold 3.**
-
-**O AlphaFold 3 e as Saídas servem apenas para modelagem teórica. Eles não são
-destinados, validados nem aprovados para uso clínico. Não os use para
-finalidades clínicas nem conte com eles para aconselhamento médico ou de outra
-natureza. Todo conteúdo sobre esses assuntos é fornecido somente para fins
-informativos e não substitui a orientação de um profissional qualificado.**
-
-## 9. Responsabilidades
-
-Na medida permitida pela lei, você indenizará o Google e os diretores,
-executivos, funcionários e prestadores de serviço dele por qualquer processo
-judicial de terceiros (incluindo ações de órgãos do governo) decorrente ou
-relacionado ao uso ilegal dos Recursos do AlphaFold ou a violações dos Termos.
-Essa indenização cobre qualquer responsabilidade ou despesa decorrente de ações
-judiciais, perdas, danos, julgamentos, multas, custos de litígios e honorários
-jurídicos, exceto se a responsabilidade ou despesa for causada por violação,
-negligência ou má conduta intencional do Google. Se você for passível de isenção
-legal de certas responsabilidades, incluindo indenização, essas
-responsabilidades não se aplicarão a você de acordo com os Termos.
-
-Em hipótese alguma o Google será responsável por quaisquer danos indiretos,
-especiais, incidentais, exemplares, emergentes ou punitivos ou por perdas de
-lucros de qualquer tipo em relação aos Termos ou aos Recursos do AlphaFold 3,
-mesmo se o Google tiver sido advertido da possibilidade de tais danos. A
-responsabilidade agregada total do Google para todas as ações judiciais
-decorrentes de ou relacionadas aos Termos ou aos Recursos do AlphaFold 3,
-incluindo pela nossa negligência, é limitada a US$ 500.
-
-## 10. Disposições gerais
-
-Por lei, você tem certos direitos que não podem ser limitados por um contrato
-como os Termos. Os Termos não têm, de forma alguma, o objetivo de restringir
-esses direitos.
-
-Os Termos constituem a integralidade do nosso contrato relacionado ao seu uso
-dos Recursos do AlphaFold 3 e substituem quaisquer contratos anteriores ou
-contemporâneos sobre esse assunto.
-
-Se uma disposição específica dos Termos não for aplicável, o saldo dos Termos
-permanecerá vigente.
-
-## 11. Disputas
-
-As leis da Califórnia vão reger todas as disputas que surgirem com relação aos
-Termos ou em relação aos Recursos do AlphaFold 3. Essas disputas serão
-resolvidas exclusivamente nos tribunais federais ou estaduais do condado de
-Santa Clara, Califórnia, EUA, e você e o Google concordam com a jurisdição
-pessoal nesses tribunais. Se a legislação local aplicável impedir que alguma
-disputa seja tratada em um tribunal na Califórnia, você e o Google podem entrar
-com a petição no seu foro local. Da mesma forma, se a legislação local aplicável
-impedir que o tribunal local aplique a lei da Califórnia para resolver essas
-disputas, elas serão regidas pelas leis do seu país, estado ou outro local de
-residência. Se você usar os Recursos do AlphaFold 3 em nome de uma organização
-governamental que não seja do governo federal dos EUA (onde as disposições acima
-se aplicam até onde permitido pela legislação federal), estes Termos não se
-aplicarão quanto à legislação aplicável e aos tribunais.
-
-Considerando a natureza das pesquisas científicas, pode levar algum tempo para
-qualquer violação dos Termos se tornar aparente. Para proteger você, o Google e
-os Recursos do AlphaFold 3, até onde permitido pela legislação aplicável, você
-concorda que:
-
-1.  qualquer ação judicial relacionada aos Termos ou Recursos do AlphaFold 3
-    pode ser iniciada até o que ocorrer por último:
-    1.  a data-limite de acordo com a legislação aplicável para iniciar a ação
-        judicial; ou
-    2.  dois anos após a data em que você ou o Google (conforme aplicável) tomou
-        conhecimento, ou deve ter tomado conhecimento de forma razoável, dos
-        fatos que deram origem a essa ação; e
-2.  você não alegará limitação, prazo de prescrição, atraso, renúncia ou
-    semelhantes para tentar impedir uma ação registrada nesse período, e o
-    Google também não.
-
-Todos os direitos que não forem concedidos a você de maneira específica e
-explícita pelos Termos são reservados ao Google. Nenhum atraso, ação ou omissão
-do Google em exercer qualquer direito ou correção será considerado uma renúncia
-a qualquer violação dos Termos, e o Google reserva expressamente todos e
-quaisquer direitos e correções disponíveis de acordo com os Termos ou com base
-na lei, na equidade ou de outra forma, incluindo a correção da tutela de
-urgência contra qualquer violação real dos Termos ou ameaça disso sem precisar
-comprovar danos reais.
diff --git a/pyproject.toml b/pyproject.toml
deleted file mode 100644
index f0782cc1bb3dbe4725c6ce60156799caf1cbe1f4..0000000000000000000000000000000000000000
--- a/pyproject.toml
+++ /dev/null
@@ -1,56 +0,0 @@
-[build-system]
-requires = [
-    "scikit_build_core",
-    "pybind11",
-    "cmake>=3.28",
-    "ninja",
-    "numpy",
-]
-build-backend = "scikit_build_core.build"
-
-[project]
-name = "alphafold3"
-version = "3.0.1"
-requires-python = ">=3.11"
-readme = "README.md"
-license = {file = "LICENSE"}
-dependencies = [
-    "absl-py",
-    "chex",
-    "dm-haiku==0.0.13",
-    "dm-tree",
-    "jax==0.4.34",
-    "jax[cuda12]==0.4.34",
-    "jax-triton==0.2.0",
-    "jaxtyping==0.2.34",
-    "numpy",
-    "rdkit==2024.3.5",
-    "triton==3.1.0",
-    "tqdm",
-    "typeguard==2.13.3",
-    "zstandard",
-]
-
-[project.optional-dependencies]
-test = ["pytest>=6.0"]
-
-[tool.scikit-build]
-wheel.exclude = [
-    "**.pyx",
-    "**/CMakeLists.txt",
-    "**.cc",
-    "**.h"
-]
-sdist.include = [
-    "LICENSE",
-    "OUTPUT_TERMS_OF_USE.md",
-    "WEIGHTS_PROHIBITED_USE_POLICY.md",
-    "WEIGHTS_TERMS_OF_USE.md",
-]
-
-[tool.cibuildwheel]
-build = "cp3*-manylinux_x86_64"
-manylinux-x86_64-image = "manylinux_2_28"
-
-[project.scripts]
-build_data = "alphafold3.build_data:build_data"
diff --git a/requirements.txt b/requirements.txt
deleted file mode 100644
index f0ca3da3b71fbb7a2b2300bcaeaba4d3a7cc3f59..0000000000000000000000000000000000000000
--- a/requirements.txt
+++ /dev/null
@@ -1,553 +0,0 @@
-#
-# This file is autogenerated by pip-compile with Python 3.11
-# by the following command:
-#
-#    pip-compile --generate-hashes
-#
-absl-py==2.1.0 \
-    --hash=sha256:526a04eadab8b4ee719ce68f204172ead1027549089702d99b9059f129ff1308 \
-    --hash=sha256:7820790efbb316739cde8b4e19357243fc3608a152024288513dd968d7d959ff
-    # via
-    #   alphafold3 (pyproject.toml)
-    #   chex
-    #   dm-haiku
-    #   jax-triton
-chex==0.1.87 \
-    --hash=sha256:0096d89cc8d898bb521ef4bfbf5c24549022b0e5b301f529ab57238896fe6c5d \
-    --hash=sha256:ce536475661fd96d21be0c1728ecdbedd03f8ff950c662dfc338c92ea782cb16
-    # via alphafold3 (pyproject.toml)
-dm-haiku==0.0.13 \
-    --hash=sha256:029bb91b5b1edb0d3fe23304d3bf12a545ea6e485041f7f5d8c8d85ebcf6e17d \
-    --hash=sha256:ee9562c68a059f146ad07f555ca591cb8c11ef751afecc38353863562bd23f43
-    # via alphafold3 (pyproject.toml)
-dm-tree==0.1.8 \
-    --hash=sha256:054b461f8176f4bce7a21f7b1870f873a1ced3bdbe1282c816c550bb43c71fa6 \
-    --hash=sha256:09964470f76a5201aff2e8f9b26842976de7889300676f927930f6285e256760 \
-    --hash=sha256:0d3172394079a86c3a759179c65f64c48d1a42b89495fcf38976d11cc3bb952c \
-    --hash=sha256:0e9620ccf06393eb6b613b5e366469304622d4ea96ae6540b28a33840e6c89cf \
-    --hash=sha256:0fcaabbb14e7980377439e7140bd05552739ca5e515ecb3119f234acee4b9430 \
-    --hash=sha256:1607ce49aa42f010d1e5e616d92ce899d66835d4d8bea49679582435285515de \
-    --hash=sha256:181c35521d480d0365f39300542cb6cd7fd2b77351bb43d7acfda15aef63b317 \
-    --hash=sha256:1d7c26e431fc93cc7e0cba867eb000db6a05f6f2b25af11ac4e9dada88fc5bca \
-    --hash=sha256:1fe962015b2fe1282892b28ebe962faed53c7f98d942da9a4625cbf27baef913 \
-    --hash=sha256:250b692fb75f45f02e2f58fbef9ab338904ef334b90557565621fa251df267cf \
-    --hash=sha256:2869228d9c619074de501a3c10dc7f07c75422f8fab36ecdcb859b6f1b1ec3ef \
-    --hash=sha256:28c52cbf4f8b3dbd0beaedf44f69fa85eec5e9dede612e08035e06ada6ec9426 \
-    --hash=sha256:2f7915660f59c09068e428613c480150180df1060561fd0d1470684ae7007bd1 \
-    --hash=sha256:343a4a4ebaa127451ff971254a4be4084eb4bdc0b2513c32b46f6f728fd03f9e \
-    --hash=sha256:35cc164a79336bfcfafb47e5f297898359123bbd3330c1967f0c4994f9cf9f60 \
-    --hash=sha256:378cc8ad93c5fe3590f405a309980721f021c790ca1bdf9b15bb1d59daec57f5 \
-    --hash=sha256:39070ba268c0491af9fe7a58644d99e8b4f2cde6e5884ba3380bddc84ed43d5f \
-    --hash=sha256:435227cf3c5dc63f4de054cf3d00183790bd9ead4c3623138c74dde7f67f521b \
-    --hash=sha256:5483dca4d7eb1a0d65fe86d3b6a53ae717face83c1f17e0887b1a4a64ae5c410 \
-    --hash=sha256:694c3654cfd2a81552c08ec66bb5c4a3d48fa292b9a181880fb081c36c5b9134 \
-    --hash=sha256:75c5d528bb992981c20793b6b453e91560784215dffb8a5440ba999753c14ceb \
-    --hash=sha256:803bfc53b4659f447ac694dbd04235f94a73ef7c1fd1e0df7c84ac41e0bc963b \
-    --hash=sha256:81fce77f22a302d7a5968aebdf4efafef4def7ce96528719a354e6990dcd49c7 \
-    --hash=sha256:83b7764de0d855338abefc6e3ee9fe40d301668310aa3baea3f778ff051f4393 \
-    --hash=sha256:8c60a7eadab64c2278861f56bca320b2720f163dca9d7558103c3b77f2416571 \
-    --hash=sha256:8ed3564abed97c806db122c2d3e1a2b64c74a63debe9903aad795167cc301368 \
-    --hash=sha256:94d3f0826311f45ee19b75f5b48c99466e4218a0489e81c0f0167bda50cacf22 \
-    --hash=sha256:96a548a406a6fb15fe58f6a30a57ff2f2aafbf25f05afab00c8f5e5977b6c715 \
-    --hash=sha256:a5d819c38c03f0bb5b3b3703c60e4b170355a0fc6b5819325bf3d4ceb3ae7e80 \
-    --hash=sha256:ad16ceba90a56ec47cf45b21856d14962ac314787975ef786efb5e6e9ca75ec7 \
-    --hash=sha256:af4b3d372f2477dcd89a6e717e4a575ca35ccc20cc4454a8a4b6f8838a00672d \
-    --hash=sha256:b095ba4f8ca1ba19350fd53cf1f8f3eb0bd406aa28af64a6dfc86707b32a810a \
-    --hash=sha256:b9bd9b9ccb59409d33d51d84b7668010c04c2af7d4a371632874c1ca356cff3d \
-    --hash=sha256:b9f89a454e98806b44fe9d40ec9eee61f848388f7e79ac2371a55679bd5a3ac6 \
-    --hash=sha256:bb2d109f42190225112da899b9f3d46d0d5f26aef501c61e43529fe9322530b5 \
-    --hash=sha256:c0a94aba18a35457a1b5cd716fd7b46c5dafdc4cf7869b4bae665b91c4682a8e \
-    --hash=sha256:c5c8c12e3fda754ef6af94161bacdaeda816d941995fac415d6855c6c386af68 \
-    --hash=sha256:d1612fcaecd79023dbc6a6ae48d51a80beb5c385d6f3f6d71688e57bc8d07de8 \
-    --hash=sha256:d16e1f2a073604cfcc09f7131ae8d534674f43c3aef4c25742eae295bc60d04f \
-    --hash=sha256:d20f2faa3672b52e5013f4077117bfb99c4cfc0b445d3bde1584c34032b57436 \
-    --hash=sha256:d40fa4106ca6edc66760246a08f500ec0c85ef55c762fb4a363f6ee739ba02ee \
-    --hash=sha256:de287fabc464b8734be251e46e06aa9aa1001f34198da2b6ce07bd197172b9cb \
-    --hash=sha256:e4d714371bb08839e4e5e29024fc95832d9affe129825ef38836b143028bd144 \
-    --hash=sha256:ea9e59e0451e7d29aece402d9f908f2e2a80922bcde2ebfd5dcb07750fcbfee8 \
-    --hash=sha256:f7ac31b9aecccb2c6e1ab29706f6ded3eba0c2c69c770322c9c685929c3d6afb \
-    --hash=sha256:fa42a605d099ee7d41ba2b5fb75e21423951fd26e5d50583a00471238fb3021d
-    # via alphafold3 (pyproject.toml)
-filelock==3.16.1 \
-    --hash=sha256:2082e5703d51fbf98ea75855d9d5527e33d8ff23099bec374a134febee6946b0 \
-    --hash=sha256:c249fbfcd5db47e5e2d6d62198e565475ee65e4831e2561c8e313fa7eb961435
-    # via triton
-jax[cuda12]==0.4.34 \
-    --hash=sha256:44196854f40c5f9cea3142824b9f1051f85afc3fcf7593ec5479fc8db01c58db \
-    --hash=sha256:b957ca1fc91f7343f91a186af9f19c7f342c946f95a8c11c7f1e5cdfe2e58d9e
-    # via
-    #   alphafold3 (pyproject.toml)
-    #   chex
-    #   jax-triton
-jax-cuda12-pjrt==0.4.34 \
-    --hash=sha256:0c7cc98f962cc7fc8e0a5ea6331b42a0cee516f202f1c3019f6aa5cd9530cca0 \
-    --hash=sha256:6247459827550e7d11480f5707d7d2843cbf57bcda5d833565493456075cd143
-    # via jax-cuda12-plugin
-jax-cuda12-plugin[with-cuda]==0.4.34 \
-    --hash=sha256:15fa8ff678fad34df424e01f1a9151abc966700670d3b22f52b87a2740028602 \
-    --hash=sha256:1b037a408b9d9de59367c9513a9445b705da526657a0c4d593e84234312261e7 \
-    --hash=sha256:b2099a4407225122ff76f6dcdc8dbdae47e6f29343bdfd21460ad337dc34a209 \
-    --hash=sha256:d035ea72bd9b8a65a6ea621bca1affdd33127fa3a52e7bded7692670d360adab \
-    --hash=sha256:dadb507949b70ba148567219bf0e7752eb63baec551f7ec860f8fcbb4ee48c48 \
-    --hash=sha256:db988b7ba5063483a936ddbf162f04d1b4412e0d64340f11788c7bbc877e8a43 \
-    --hash=sha256:e23721d1654b311b47cd6b35768520284bd036f8c7e6b11600143258b4a0409a \
-    --hash=sha256:fb72bda44ae9f8a1e5ee9c5f82e2d273abe019874b0110b5c2d8395f1fe966b4
-    # via jax
-jax-triton==0.2.0 \
-    --hash=sha256:6db5f6147327f2462c35becab612d415cf9ee70c96e43020c3c7ea873eb8576e \
-    --hash=sha256:ed564a5ffb9e404557dc8d296e7eb30e501da5a4d7b03408acd0837c1c618c21
-    # via alphafold3 (pyproject.toml)
-jaxlib==0.4.34 \
-    --hash=sha256:096f0ca309d41fa692a9d1f2f9baab1c5c8ca0749876ebb3f748e738a27c7ff4 \
-    --hash=sha256:133070d4fec5525ffea4dc72956398c1cf647a04dcb37f8a935ee82af78d9965 \
-    --hash=sha256:1a30771d85fa77f9ab8f18e63240f455ab3a3f87660ed7b8d5eea6ceecbe5c1e \
-    --hash=sha256:3bcfa639ca3cfaf86c8ceebd5fc0d47300fd98a078014a1d0cc03133e1523d5f \
-    --hash=sha256:3e60bc826933082e99b19b87c21818a8d26fcdb01f418d47cedff554746fd6cc \
-    --hash=sha256:45d719a2ce0ebf21255a277b71d756f3609b7b5be70cddc5d88fd58c35219de0 \
-    --hash=sha256:48272e9034ff868d4328cf0055a07882fd2be93f59dfb6283af7de491f9d1290 \
-    --hash=sha256:571ef03259835458111596a71a2f4a6fabf4ec34595df4cea555035362ac5bf0 \
-    --hash=sha256:6b43a974c5d91a19912d138f2658dd8dbb7d30dcdff5c961d896c673e872b611 \
-    --hash=sha256:72e22e99a5dc890a64443c3fc12f13f20091f578c405a76de077ba42b4c62cd7 \
-    --hash=sha256:7be673a876ebd1aef440fb7e3ebaf99a91abeb550c9728c644b7d7c7b5d7c108 \
-    --hash=sha256:87f25a477cd279840e53718403f97092eba0e8a945fcab47bcf435b6f9119dda \
-    --hash=sha256:8ee3f93836e53c86556ccd9449a4ea43516ee05184d031a71dd692e81259f7d9 \
-    --hash=sha256:901cb4040ed24eae40071d8114ea8d10dff436277fa74a1a5b9e7206f641151c \
-    --hash=sha256:b0001c8f0e2b1c7bc99e4f314b524a340d25653505c1a1484d4041a9d3617f6f \
-    --hash=sha256:b7a212a3cb5c6acc201c32ae4f4b5f5a9ac09457fbb77ba8db5ce7e7d4adc214 \
-    --hash=sha256:c303f5acaf6c56ce5ff133a923c9b6247bdebedde15bd2c893c24be4d8f71306 \
-    --hash=sha256:c7b3e724a30426a856070aba0192b5d199e95b4411070e7ad96ad8b196877b10 \
-    --hash=sha256:c9d3adcae43a33aad4332be9c2aedc5ef751d1e755f917a5afb30c7872eacaa8 \
-    --hash=sha256:d840e64b85f8865404d6d225b9bb340e158df1457152a361b05680e24792b232
-    # via
-    #   chex
-    #   jax
-jaxtyping==0.2.34 \
-    --hash=sha256:2f81fb6d1586e497a6ea2d28c06dcab37b108a096cbb36ea3fe4fa2e1c1f32e5 \
-    --hash=sha256:eed9a3458ec8726c84ea5457ebde53c964f65d2c22c0ec40d0555ae3fed5bbaf
-    # via alphafold3 (pyproject.toml)
-jmp==0.0.4 \
-    --hash=sha256:5dfeb0fd7c7a9f72a70fff0aab9d0cbfae32a809c02f4037ff3485ceb33e1730 \
-    --hash=sha256:6aa7adbddf2bd574b28c7faf6e81a735eb11f53386447896909c6968dc36807d
-    # via dm-haiku
-ml-dtypes==0.5.0 \
-    --hash=sha256:099e09edd54e676903b4538f3815b5ab96f5b119690514602d96bfdb67172cbe \
-    --hash=sha256:2e7534392682c3098bc7341648c650864207169c654aed83143d7a19c67ae06f \
-    --hash=sha256:3e7d3a380fe73a63c884f06136f8baa7a5249cc8e9fdec677997dd78549f8128 \
-    --hash=sha256:54415257f00eb44fbcc807454efac3356f75644f1cbfc2d4e5522a72ae1dacab \
-    --hash=sha256:5f2b59233a0dbb6a560b3137ed6125433289ccba2f8d9c3695a52423a369ed15 \
-    --hash=sha256:60275f2b51b56834e840c4809fca840565f9bf8e9a73f6d8c94f5b5935701215 \
-    --hash=sha256:76942f6aeb5c40766d5ea62386daa4148e6a54322aaf5b53eae9e7553240222f \
-    --hash=sha256:7ee9c320bb0f9ffdf9f6fa6a696ef2e005d1f66438d6f1c1457338e00a02e8cf \
-    --hash=sha256:8c32138975797e681eb175996d64356bcfa124bdbb6a70460b9768c2b35a6fa4 \
-    --hash=sha256:968fede07d1f9b926a63df97d25ac656cac1a57ebd33701734eaf704bc55d8d8 \
-    --hash=sha256:a03fc861b86cc586728e3d093ba37f0cc05e65330c3ebd7688e7bae8290f8859 \
-    --hash=sha256:a38df8df61194aeaae1ab7579075779b4ad32cd1cffd012c28be227fa7f2a70a \
-    --hash=sha256:a988bac6572630e1e9c2edd9b1277b4eefd1c86209e52b0d061b775ac33902ff \
-    --hash=sha256:ab046f2ff789b1f11b2491909682c5d089934835f9a760fafc180e47dcb676b8 \
-    --hash=sha256:afa08343069874a30812871d639f9c02b4158ace065601406a493a8511180c02 \
-    --hash=sha256:c7a9152f5876fef565516aa5dd1dccd6fc298a5891b2467973905103eb5c7856 \
-    --hash=sha256:cb5cc7b25acabd384f75bbd78892d0c724943f3e2e1986254665a1aa10982e07 \
-    --hash=sha256:d3b3db9990c3840986a0e70524e122cfa32b91139c3653df76121ba7776e015f \
-    --hash=sha256:d4b1a70a3e5219790d6b55b9507606fc4e02911d1497d16c18dd721eb7efe7d0 \
-    --hash=sha256:dc74fd9995513d33eac63d64e436240f5494ec74d522a9f0920194942fc3d2d7 \
-    --hash=sha256:e04fde367b2fe901b1d47234426fe8819909bd1dd862a5adb630f27789c20599
-    # via
-    #   jax
-    #   jaxlib
-numpy==2.1.3 \
-    --hash=sha256:016d0f6f5e77b0f0d45d77387ffa4bb89816b57c835580c3ce8e099ef830befe \
-    --hash=sha256:02135ade8b8a84011cbb67dc44e07c58f28575cf9ecf8ab304e51c05528c19f0 \
-    --hash=sha256:08788d27a5fd867a663f6fc753fd7c3ad7e92747efc73c53bca2f19f8bc06f48 \
-    --hash=sha256:0d30c543f02e84e92c4b1f415b7c6b5326cbe45ee7882b6b77db7195fb971e3a \
-    --hash=sha256:0fa14563cc46422e99daef53d725d0c326e99e468a9320a240affffe87852564 \
-    --hash=sha256:13138eadd4f4da03074851a698ffa7e405f41a0845a6b1ad135b81596e4e9958 \
-    --hash=sha256:14e253bd43fc6b37af4921b10f6add6925878a42a0c5fe83daee390bca80bc17 \
-    --hash=sha256:15cb89f39fa6d0bdfb600ea24b250e5f1a3df23f901f51c8debaa6a5d122b2f0 \
-    --hash=sha256:17ee83a1f4fef3c94d16dc1802b998668b5419362c8a4f4e8a491de1b41cc3ee \
-    --hash=sha256:2312b2aa89e1f43ecea6da6ea9a810d06aae08321609d8dc0d0eda6d946a541b \
-    --hash=sha256:2564fbdf2b99b3f815f2107c1bbc93e2de8ee655a69c261363a1172a79a257d4 \
-    --hash=sha256:3522b0dfe983a575e6a9ab3a4a4dfe156c3e428468ff08ce582b9bb6bd1d71d4 \
-    --hash=sha256:4394bc0dbd074b7f9b52024832d16e019decebf86caf909d94f6b3f77a8ee3b6 \
-    --hash=sha256:45966d859916ad02b779706bb43b954281db43e185015df6eb3323120188f9e4 \
-    --hash=sha256:4d1167c53b93f1f5d8a139a742b3c6f4d429b54e74e6b57d0eff40045187b15d \
-    --hash=sha256:4f2015dfe437dfebbfce7c85c7b53d81ba49e71ba7eadbf1df40c915af75979f \
-    --hash=sha256:50ca6aba6e163363f132b5c101ba078b8cbd3fa92c7865fd7d4d62d9779ac29f \
-    --hash=sha256:50d18c4358a0a8a53f12a8ba9d772ab2d460321e6a93d6064fc22443d189853f \
-    --hash=sha256:5641516794ca9e5f8a4d17bb45446998c6554704d888f86df9b200e66bdcce56 \
-    --hash=sha256:576a1c1d25e9e02ed7fa5477f30a127fe56debd53b8d2c89d5578f9857d03ca9 \
-    --hash=sha256:6a4825252fcc430a182ac4dee5a505053d262c807f8a924603d411f6718b88fd \
-    --hash=sha256:72dcc4a35a8515d83e76b58fdf8113a5c969ccd505c8a946759b24e3182d1f23 \
-    --hash=sha256:747641635d3d44bcb380d950679462fae44f54b131be347d5ec2bce47d3df9ed \
-    --hash=sha256:762479be47a4863e261a840e8e01608d124ee1361e48b96916f38b119cfda04a \
-    --hash=sha256:78574ac2d1a4a02421f25da9559850d59457bac82f2b8d7a44fe83a64f770098 \
-    --hash=sha256:825656d0743699c529c5943554d223c021ff0494ff1442152ce887ef4f7561a1 \
-    --hash=sha256:8637dcd2caa676e475503d1f8fdb327bc495554e10838019651b76d17b98e512 \
-    --hash=sha256:96fe52fcdb9345b7cd82ecd34547fca4321f7656d500eca497eb7ea5a926692f \
-    --hash=sha256:973faafebaae4c0aaa1a1ca1ce02434554d67e628b8d805e61f874b84e136b09 \
-    --hash=sha256:996bb9399059c5b82f76b53ff8bb686069c05acc94656bb259b1d63d04a9506f \
-    --hash=sha256:a38c19106902bb19351b83802531fea19dee18e5b37b36454f27f11ff956f7fc \
-    --hash=sha256:a6b46587b14b888e95e4a24d7b13ae91fa22386c199ee7b418f449032b2fa3b8 \
-    --hash=sha256:a9f7f672a3388133335589cfca93ed468509cb7b93ba3105fce780d04a6576a0 \
-    --hash=sha256:aa08e04e08aaf974d4458def539dece0d28146d866a39da5639596f4921fd761 \
-    --hash=sha256:b0df3635b9c8ef48bd3be5f862cf71b0a4716fa0e702155c45067c6b711ddcef \
-    --hash=sha256:b47fbb433d3260adcd51eb54f92a2ffbc90a4595f8970ee00e064c644ac788f5 \
-    --hash=sha256:baed7e8d7481bfe0874b566850cb0b85243e982388b7b23348c6db2ee2b2ae8e \
-    --hash=sha256:bc6f24b3d1ecc1eebfbf5d6051faa49af40b03be1aaa781ebdadcbc090b4539b \
-    --hash=sha256:c006b607a865b07cd981ccb218a04fc86b600411d83d6fc261357f1c0966755d \
-    --hash=sha256:c181ba05ce8299c7aa3125c27b9c2167bca4a4445b7ce73d5febc411ca692e43 \
-    --hash=sha256:c7662f0e3673fe4e832fe07b65c50342ea27d989f92c80355658c7f888fcc83c \
-    --hash=sha256:c80e4a09b3d95b4e1cac08643f1152fa71a0a821a2d4277334c88d54b2219a41 \
-    --hash=sha256:c894b4305373b9c5576d7a12b473702afdf48ce5369c074ba304cc5ad8730dff \
-    --hash=sha256:d7aac50327da5d208db2eec22eb11e491e3fe13d22653dce51b0f4109101b408 \
-    --hash=sha256:d89dd2b6da69c4fff5e39c28a382199ddedc3a5be5390115608345dec660b9e2 \
-    --hash=sha256:d9beb777a78c331580705326d2367488d5bc473b49a9bc3036c154832520aca9 \
-    --hash=sha256:dc258a761a16daa791081d026f0ed4399b582712e6fc887a95af09df10c5ca57 \
-    --hash=sha256:e14e26956e6f1696070788252dcdff11b4aca4c3e8bd166e0df1bb8f315a67cb \
-    --hash=sha256:e6988e90fcf617da2b5c78902fe8e668361b43b4fe26dbf2d7b0f8034d4cafb9 \
-    --hash=sha256:e711e02f49e176a01d0349d82cb5f05ba4db7d5e7e0defd026328e5cfb3226d3 \
-    --hash=sha256:ea4dedd6e394a9c180b33c2c872b92f7ce0f8e7ad93e9585312b0c5a04777a4a \
-    --hash=sha256:ecc76a9ba2911d8d37ac01de72834d8849e55473457558e12995f4cd53e778e0 \
-    --hash=sha256:f55ba01150f52b1027829b50d70ef1dafd9821ea82905b63936668403c3b471e \
-    --hash=sha256:f653490b33e9c3a4c1c01d41bc2aef08f9475af51146e4a7710c450cf9761598 \
-    --hash=sha256:fa2d1337dc61c8dc417fbccf20f6d1e139896a30721b7f1e832b2bb6ef4eb6c4
-    # via
-    #   alphafold3 (pyproject.toml)
-    #   chex
-    #   dm-haiku
-    #   jax
-    #   jaxlib
-    #   jmp
-    #   ml-dtypes
-    #   rdkit
-    #   scipy
-nvidia-cublas-cu12==12.6.3.3 \
-    --hash=sha256:e1f70bee38b964eac1907293b336bceb24498a4243e61eaf91a52977c59aebc4 \
-    --hash=sha256:e531199ca4f1f764fb45bc1dde49a006f6765033f9c89c737e4553b9502ca1f5 \
-    --hash=sha256:f33fb68e101d99470c82d17f92a0dd9f74de2a21685c217f4716cdd63b1316eb
-    # via
-    #   jax-cuda12-plugin
-    #   nvidia-cudnn-cu12
-    #   nvidia-cusolver-cu12
-nvidia-cuda-cupti-cu12==12.6.80 \
-    --hash=sha256:358b4a1d35370353d52e12f0a7d1769fc01ff74a191689d3870b2123156184c4 \
-    --hash=sha256:a3eff6cdfcc6a4c35db968a06fcadb061cbc7d6dde548609a941ff8701b98b73 \
-    --hash=sha256:bbe6ae76e83ce5251b56e8c8e61a964f757175682bbad058b170b136266ab00a
-    # via jax-cuda12-plugin
-nvidia-cuda-nvcc-cu12==12.6.77 \
-    --hash=sha256:26e118b4dae4ebd316ab6f5ee3f3c4cb929f8265f717a8e016ba57e254c0b4f1 \
-    --hash=sha256:9a2aad43b8f4e4be9c237ece04f64450df77871eeebffad5a5a872714a97ca77 \
-    --hash=sha256:b66bb5dd6b8ae62262586691977d3b4a425e91db61b4b9bc2f6b42bcd4154b96
-    # via jax-cuda12-plugin
-nvidia-cuda-runtime-cu12==12.6.77 \
-    --hash=sha256:86c58044c824bf3c173c49a2dbc7a6c8b53cb4e4dca50068be0bf64e9dab3f7f \
-    --hash=sha256:a84d15d5e1da416dd4774cb42edf5e954a3e60cc945698dc1d5be02321c44dc8 \
-    --hash=sha256:d461264ecb429c84c8879a7153499ddc7b19b5f8d84c204307491989a365588e
-    # via jax-cuda12-plugin
-nvidia-cudnn-cu12==9.5.1.17 \
-    --hash=sha256:30ac3869f6db17d170e0e556dd6cc5eee02647abc31ca856634d5a40f82c15b2 \
-    --hash=sha256:9fd4584468533c61873e5fda8ca41bac3a38bcb2d12350830c69b0a96a7e4def \
-    --hash=sha256:d7af0f8a4f3b4b9dbb3122f2ef553b45694ed9c384d5a75bab197b8eefb79ab8
-    # via jax-cuda12-plugin
-nvidia-cufft-cu12==11.3.0.4 \
-    --hash=sha256:6048ebddfb90d09d2707efb1fd78d4e3a77cb3ae4dc60e19aab6be0ece2ae464 \
-    --hash=sha256:768160ac89f6f7b459bee747e8d175dbf53619cfe74b2a5636264163138013ca \
-    --hash=sha256:8510990de9f96c803a051822618d42bf6cb8f069ff3f48d93a8486efdacb48fb
-    # via jax-cuda12-plugin
-nvidia-cusolver-cu12==11.7.1.2 \
-    --hash=sha256:0ce237ef60acde1efc457335a2ddadfd7610b892d94efee7b776c64bb1cac9e0 \
-    --hash=sha256:6813f9d8073f555444a8705f3ab0296d3e1cb37a16d694c5fc8b862a0d8706d7 \
-    --hash=sha256:6cf28f17f64107a0c4d7802be5ff5537b2130bfc112f25d5a30df227058ca0e6
-    # via jax-cuda12-plugin
-nvidia-cusparse-cu12==12.5.4.2 \
-    --hash=sha256:23749a6571191a215cb74d1cdbff4a86e7b19f1200c071b3fcf844a5bea23a2f \
-    --hash=sha256:4acb8c08855a26d737398cba8fb6f8f5045d93f82612b4cfd84645a2332ccf20 \
-    --hash=sha256:7aa32fa5470cf754f72d1116c7cbc300b4e638d3ae5304cfa4a638a5b87161b1
-    # via
-    #   jax-cuda12-plugin
-    #   nvidia-cusolver-cu12
-nvidia-nccl-cu12==2.23.4 \
-    --hash=sha256:aa946c8327e22ced28e7cef508a334673abc42064ec85f02d005ba1785ea4cec \
-    --hash=sha256:b097258d9aab2fa9f686e33c6fe40ae57b27df60cedbd15d139701bb5509e0c1
-    # via jax-cuda12-plugin
-nvidia-nvjitlink-cu12==12.6.77 \
-    --hash=sha256:3bf10d85bb1801e9c894c6e197e44dd137d2a0a9e43f8450e9ad13f2df0dd52d \
-    --hash=sha256:410718cd44962bed862a31dd0318620f6f9a8b28a6291967bcfcb446a6516771 \
-    --hash=sha256:9ae346d16203ae4ea513be416495167a0101d33d2d14935aa9c1829a3fb45142
-    # via
-    #   jax-cuda12-plugin
-    #   nvidia-cufft-cu12
-    #   nvidia-cusolver-cu12
-    #   nvidia-cusparse-cu12
-opt-einsum==3.4.0 \
-    --hash=sha256:69bb92469f86a1565195ece4ac0323943e83477171b91d24c35afe028a90d7cd \
-    --hash=sha256:96ca72f1b886d148241348783498194c577fa30a8faac108586b14f1ba4473ac
-    # via jax
-pillow==11.0.0 \
-    --hash=sha256:00177a63030d612148e659b55ba99527803288cea7c75fb05766ab7981a8c1b7 \
-    --hash=sha256:006bcdd307cc47ba43e924099a038cbf9591062e6c50e570819743f5607404f5 \
-    --hash=sha256:084a07ef0821cfe4858fe86652fffac8e187b6ae677e9906e192aafcc1b69903 \
-    --hash=sha256:0ae08bd8ffc41aebf578c2af2f9d8749d91f448b3bfd41d7d9ff573d74f2a6b2 \
-    --hash=sha256:0e038b0745997c7dcaae350d35859c9715c71e92ffb7e0f4a8e8a16732150f38 \
-    --hash=sha256:1187739620f2b365de756ce086fdb3604573337cc28a0d3ac4a01ab6b2d2a6d2 \
-    --hash=sha256:16095692a253047fe3ec028e951fa4221a1f3ed3d80c397e83541a3037ff67c9 \
-    --hash=sha256:1a61b54f87ab5786b8479f81c4b11f4d61702830354520837f8cc791ebba0f5f \
-    --hash=sha256:1c1d72714f429a521d8d2d018badc42414c3077eb187a59579f28e4270b4b0fc \
-    --hash=sha256:1e2688958a840c822279fda0086fec1fdab2f95bf2b717b66871c4ad9859d7e8 \
-    --hash=sha256:20ec184af98a121fb2da42642dea8a29ec80fc3efbaefb86d8fdd2606619045d \
-    --hash=sha256:21a0d3b115009ebb8ac3d2ebec5c2982cc693da935f4ab7bb5c8ebe2f47d36f2 \
-    --hash=sha256:224aaa38177597bb179f3ec87eeefcce8e4f85e608025e9cfac60de237ba6316 \
-    --hash=sha256:2679d2258b7f1192b378e2893a8a0a0ca472234d4c2c0e6bdd3380e8dfa21b6a \
-    --hash=sha256:27a7860107500d813fcd203b4ea19b04babe79448268403172782754870dac25 \
-    --hash=sha256:290f2cc809f9da7d6d622550bbf4c1e57518212da51b6a30fe8e0a270a5b78bd \
-    --hash=sha256:2e46773dc9f35a1dd28bd6981332fd7f27bec001a918a72a79b4133cf5291dba \
-    --hash=sha256:3107c66e43bda25359d5ef446f59c497de2b5ed4c7fdba0894f8d6cf3822dafc \
-    --hash=sha256:375b8dd15a1f5d2feafff536d47e22f69625c1aa92f12b339ec0b2ca40263273 \
-    --hash=sha256:45c566eb10b8967d71bf1ab8e4a525e5a93519e29ea071459ce517f6b903d7fa \
-    --hash=sha256:499c3a1b0d6fc8213519e193796eb1a86a1be4b1877d678b30f83fd979811d1a \
-    --hash=sha256:4ad70c4214f67d7466bea6a08061eba35c01b1b89eaa098040a35272a8efb22b \
-    --hash=sha256:4b60c9520f7207aaf2e1d94de026682fc227806c6e1f55bba7606d1c94dd623a \
-    --hash=sha256:5178952973e588b3f1360868847334e9e3bf49d19e169bbbdfaf8398002419ae \
-    --hash=sha256:52a2d8323a465f84faaba5236567d212c3668f2ab53e1c74c15583cf507a0291 \
-    --hash=sha256:598b4e238f13276e0008299bd2482003f48158e2b11826862b1eb2ad7c768b97 \
-    --hash=sha256:5bd2d3bdb846d757055910f0a59792d33b555800813c3b39ada1829c372ccb06 \
-    --hash=sha256:5c39ed17edea3bc69c743a8dd3e9853b7509625c2462532e62baa0732163a904 \
-    --hash=sha256:5d203af30149ae339ad1b4f710d9844ed8796e97fda23ffbc4cc472968a47d0b \
-    --hash=sha256:5ddbfd761ee00c12ee1be86c9c0683ecf5bb14c9772ddbd782085779a63dd55b \
-    --hash=sha256:607bbe123c74e272e381a8d1957083a9463401f7bd01287f50521ecb05a313f8 \
-    --hash=sha256:61b887f9ddba63ddf62fd02a3ba7add935d053b6dd7d58998c630e6dbade8527 \
-    --hash=sha256:6619654954dc4936fcff82db8eb6401d3159ec6be81e33c6000dfd76ae189947 \
-    --hash=sha256:674629ff60030d144b7bca2b8330225a9b11c482ed408813924619c6f302fdbb \
-    --hash=sha256:6ec0d5af64f2e3d64a165f490d96368bb5dea8b8f9ad04487f9ab60dc4bb6003 \
-    --hash=sha256:6f4dba50cfa56f910241eb7f883c20f1e7b1d8f7d91c750cd0b318bad443f4d5 \
-    --hash=sha256:70fbbdacd1d271b77b7721fe3cdd2d537bbbd75d29e6300c672ec6bb38d9672f \
-    --hash=sha256:72bacbaf24ac003fea9bff9837d1eedb6088758d41e100c1552930151f677739 \
-    --hash=sha256:7326a1787e3c7b0429659e0a944725e1b03eeaa10edd945a86dead1913383944 \
-    --hash=sha256:73853108f56df97baf2bb8b522f3578221e56f646ba345a372c78326710d3830 \
-    --hash=sha256:73e3a0200cdda995c7e43dd47436c1548f87a30bb27fb871f352a22ab8dcf45f \
-    --hash=sha256:75acbbeb05b86bc53cbe7b7e6fe00fbcf82ad7c684b3ad82e3d711da9ba287d3 \
-    --hash=sha256:8069c5179902dcdce0be9bfc8235347fdbac249d23bd90514b7a47a72d9fecf4 \
-    --hash=sha256:846e193e103b41e984ac921b335df59195356ce3f71dcfd155aa79c603873b84 \
-    --hash=sha256:8594f42df584e5b4bb9281799698403f7af489fba84c34d53d1c4bfb71b7c4e7 \
-    --hash=sha256:86510e3f5eca0ab87429dd77fafc04693195eec7fd6a137c389c3eeb4cfb77c6 \
-    --hash=sha256:8853a3bf12afddfdf15f57c4b02d7ded92c7a75a5d7331d19f4f9572a89c17e6 \
-    --hash=sha256:88a58d8ac0cc0e7f3a014509f0455248a76629ca9b604eca7dc5927cc593c5e9 \
-    --hash=sha256:8ba470552b48e5835f1d23ecb936bb7f71d206f9dfeee64245f30c3270b994de \
-    --hash=sha256:8c676b587da5673d3c75bd67dd2a8cdfeb282ca38a30f37950511766b26858c4 \
-    --hash=sha256:8ec4a89295cd6cd4d1058a5e6aec6bf51e0eaaf9714774e1bfac7cfc9051db47 \
-    --hash=sha256:94f3e1780abb45062287b4614a5bc0874519c86a777d4a7ad34978e86428b8dd \
-    --hash=sha256:9a0f748eaa434a41fccf8e1ee7a3eed68af1b690e75328fd7a60af123c193b50 \
-    --hash=sha256:a5629742881bcbc1f42e840af185fd4d83a5edeb96475a575f4da50d6ede337c \
-    --hash=sha256:a65149d8ada1055029fcb665452b2814fe7d7082fcb0c5bed6db851cb69b2086 \
-    --hash=sha256:b3c5ac4bed7519088103d9450a1107f76308ecf91d6dabc8a33a2fcfb18d0fba \
-    --hash=sha256:b4fd7bd29610a83a8c9b564d457cf5bd92b4e11e79a4ee4716a63c959699b306 \
-    --hash=sha256:bcd1fb5bb7b07f64c15618c89efcc2cfa3e95f0e3bcdbaf4642509de1942a699 \
-    --hash=sha256:c12b5ae868897c7338519c03049a806af85b9b8c237b7d675b8c5e089e4a618e \
-    --hash=sha256:c26845094b1af3c91852745ae78e3ea47abf3dbcd1cf962f16b9a5fbe3ee8488 \
-    --hash=sha256:c6a660307ca9d4867caa8d9ca2c2658ab685de83792d1876274991adec7b93fa \
-    --hash=sha256:c809a70e43c7977c4a42aefd62f0131823ebf7dd73556fa5d5950f5b354087e2 \
-    --hash=sha256:c8b2351c85d855293a299038e1f89db92a2f35e8d2f783489c6f0b2b5f3fe8a3 \
-    --hash=sha256:cb929ca942d0ec4fac404cbf520ee6cac37bf35be479b970c4ffadf2b6a1cad9 \
-    --hash=sha256:d2c0a187a92a1cb5ef2c8ed5412dd8d4334272617f532d4ad4de31e0495bd923 \
-    --hash=sha256:d69bfd8ec3219ae71bcde1f942b728903cad25fafe3100ba2258b973bd2bc1b2 \
-    --hash=sha256:daffdf51ee5db69a82dd127eabecce20729e21f7a3680cf7cbb23f0829189790 \
-    --hash=sha256:e58876c91f97b0952eb766123bfef372792ab3f4e3e1f1a2267834c2ab131734 \
-    --hash=sha256:eda2616eb2313cbb3eebbe51f19362eb434b18e3bb599466a1ffa76a033fb916 \
-    --hash=sha256:ee217c198f2e41f184f3869f3e485557296d505b5195c513b2bfe0062dc537f1 \
-    --hash=sha256:f02541ef64077f22bf4924f225c0fd1248c168f86e4b7abdedd87d6ebaceab0f \
-    --hash=sha256:f1b82c27e89fffc6da125d5eb0ca6e68017faf5efc078128cfaa42cf5cb38798 \
-    --hash=sha256:fba162b8872d30fea8c52b258a542c5dfd7b235fb5cb352240c8d63b414013eb \
-    --hash=sha256:fbbcb7b57dc9c794843e3d1258c0fbf0f48656d46ffe9e09b63bbd6e8cd5d0a2 \
-    --hash=sha256:fcb4621042ac4b7865c179bb972ed0da0218a076dc1820ffc48b1d74c1e37fe9
-    # via rdkit
-rdkit==2024.3.5 \
-    --hash=sha256:01fd323f5902a720925293c0ce08a33e630422374cf263d04ef173c106c63c36 \
-    --hash=sha256:04079aef5f91965bd2a48bf432b32c36ea1bf088e26efb2c9a43b625b6a75d15 \
-    --hash=sha256:1cb7cdb29956649d4c875790b94142868c08c0735dee4d90b2d70dfd378e9d2e \
-    --hash=sha256:292141f0ba2359be07d8566d9a39ce697c1d6e7eb406031a2bf0387026503a47 \
-    --hash=sha256:2affa1b4cf601d27b157bbc44255c640baac9bc04cfdf5fa88f43c34c3f360d5 \
-    --hash=sha256:316bb5273bff5be76d4e5b0def998455e9b1a20898df44548b0e299f90786cb2 \
-    --hash=sha256:455d510beff8806e62e48b977d7acbfbc351474fa132124738a07223440c1b9a \
-    --hash=sha256:53638d0d94f7c511273ff5765abc6a1fe60fe6c8633db13cad03bc527550a7a9 \
-    --hash=sha256:6af38c62d4af9d669f8996551d3ae809de9ab245570b861be3f7a2b1a536f79f \
-    --hash=sha256:73fa2fe3a9a2334edf8448a5a3093a6f949ee715de77d3baa685751e2cf9317b \
-    --hash=sha256:7c91c5ccbf8d51cd3dd894bf770ca99da5fe37714f6e2a66016e8af4f57d2b56 \
-    --hash=sha256:7d5576bad6672959d0c1939e8d7e2fcd8656f8daf9788ce58e5c313db719b5ec \
-    --hash=sha256:89f7a72466ffbd45320d845ee1bcde1bddb1a322352836835d26ebb712228a41 \
-    --hash=sha256:8d4ebafb7e845bdc55eb6e2e188123ec84fb2bf724d3a7eb2da9bcfade7acc65 \
-    --hash=sha256:90376467f4988ee44f3f47d1e558ffc27646254a99fe65d19a7d9a123e832ef2 \
-    --hash=sha256:913494a03fcf6121c103e5db43fa33bca0fcc65ebd5a6c46661baa6851f79d91 \
-    --hash=sha256:98dac94a5e414ed1880b215eacec63e5fd77b0ea351e0a18fc5229acb8e886f5 \
-    --hash=sha256:a51cc403792ba37d1ee8ad84ad829177a4453547a4e085e1115ae2b237084ddb \
-    --hash=sha256:a98099cef42c1eb52512b343beb68a8b7cc4da79924a67181f58692a6376d91b \
-    --hash=sha256:c971eba2a67f8ae301b9b8c66b3431cd62472f648cdec9694e5413d8ebc59720 \
-    --hash=sha256:cf2747e7c82d6c90a8a631fe063d24d77b31f535e0f8a17ac9dbfbe4ab456886 \
-    --hash=sha256:d8714c03558086d022649617197c0c45c75c301f6a9fb67205695493a7e5b826 \
-    --hash=sha256:e5b0dfb28aa0949152ff816fba0a2f6267154f5c25159a9ec84c27cf18f72322 \
-    --hash=sha256:e69cec14cbb42c5ca912346b594d3f6a7aac572463949c55c7749da257e68123 \
-    --hash=sha256:f662ed10e14c7874d0e011c1f8260a6cf4a5547100806f9f4540f8550a3f1d36
-    # via alphafold3 (pyproject.toml)
-scipy==1.14.1 \
-    --hash=sha256:0c2f95de3b04e26f5f3ad5bb05e74ba7f68b837133a4492414b3afd79dfe540e \
-    --hash=sha256:1729560c906963fc8389f6aac023739ff3983e727b1a4d87696b7bf108316a79 \
-    --hash=sha256:278266012eb69f4a720827bdd2dc54b2271c97d84255b2faaa8f161a158c3b37 \
-    --hash=sha256:2843f2d527d9eebec9a43e6b406fb7266f3af25a751aa91d62ff416f54170bc5 \
-    --hash=sha256:2da0469a4ef0ecd3693761acbdc20f2fdeafb69e6819cc081308cc978153c675 \
-    --hash=sha256:2ff0a7e01e422c15739ecd64432743cf7aae2b03f3084288f399affcefe5222d \
-    --hash=sha256:2ff38e22128e6c03ff73b6bb0f85f897d2362f8c052e3b8ad00532198fbdae3f \
-    --hash=sha256:30ac8812c1d2aab7131a79ba62933a2a76f582d5dbbc695192453dae67ad6310 \
-    --hash=sha256:3a1b111fac6baec1c1d92f27e76511c9e7218f1695d61b59e05e0fe04dc59617 \
-    --hash=sha256:4079b90df244709e675cdc8b93bfd8a395d59af40b72e339c2287c91860deb8e \
-    --hash=sha256:5149e3fd2d686e42144a093b206aef01932a0059c2a33ddfa67f5f035bdfe13e \
-    --hash=sha256:5a275584e726026a5699459aa72f828a610821006228e841b94275c4a7c08417 \
-    --hash=sha256:631f07b3734d34aced009aaf6fedfd0eb3498a97e581c3b1e5f14a04164a456d \
-    --hash=sha256:716e389b694c4bb564b4fc0c51bc84d381735e0d39d3f26ec1af2556ec6aad94 \
-    --hash=sha256:8426251ad1e4ad903a4514712d2fa8fdd5382c978010d1c6f5f37ef286a713ad \
-    --hash=sha256:8475230e55549ab3f207bff11ebfc91c805dc3463ef62eda3ccf593254524ce8 \
-    --hash=sha256:8bddf15838ba768bb5f5083c1ea012d64c9a444e16192762bd858f1e126196d0 \
-    --hash=sha256:8e32dced201274bf96899e6491d9ba3e9a5f6b336708656466ad0522d8528f69 \
-    --hash=sha256:8f9ea80f2e65bdaa0b7627fb00cbeb2daf163caa015e59b7516395fe3bd1e066 \
-    --hash=sha256:97c5dddd5932bd2a1a31c927ba5e1463a53b87ca96b5c9bdf5dfd6096e27efc3 \
-    --hash=sha256:a49f6ed96f83966f576b33a44257d869756df6cf1ef4934f59dd58b25e0327e5 \
-    --hash=sha256:af29a935803cc707ab2ed7791c44288a682f9c8107bc00f0eccc4f92c08d6e07 \
-    --hash=sha256:b05d43735bb2f07d689f56f7b474788a13ed8adc484a85aa65c0fd931cf9ccd2 \
-    --hash=sha256:b28d2ca4add7ac16ae8bb6632a3c86e4b9e4d52d3e34267f6e1b0c1f8d87e389 \
-    --hash=sha256:b99722ea48b7ea25e8e015e8341ae74624f72e5f21fc2abd45f3a93266de4c5d \
-    --hash=sha256:baff393942b550823bfce952bb62270ee17504d02a1801d7fd0719534dfb9c84 \
-    --hash=sha256:c0ee987efa6737242745f347835da2cc5bb9f1b42996a4d97d5c7ff7928cb6f2 \
-    --hash=sha256:d0d2821003174de06b69e58cef2316a6622b60ee613121199cb2852a873f8cf3 \
-    --hash=sha256:e0cf28db0f24a38b2a0ca33a85a54852586e43cf6fd876365c86e0657cfe7d73 \
-    --hash=sha256:e4f5a7c49323533f9103d4dacf4e4f07078f360743dec7f7596949149efeec06 \
-    --hash=sha256:eb58ca0abd96911932f688528977858681a59d61a7ce908ffd355957f7025cfc \
-    --hash=sha256:edaf02b82cd7639db00dbff629995ef185c8df4c3ffa71a5562a595765a06ce1 \
-    --hash=sha256:fef8c87f8abfb884dac04e97824b61299880c43f4ce675dd2cbeadd3c9b466d2
-    # via
-    #   jax
-    #   jaxlib
-tabulate==0.9.0 \
-    --hash=sha256:0095b12bf5966de529c0feb1fa08671671b3368eec77d7ef7ab114be2c068b3c \
-    --hash=sha256:024ca478df22e9340661486f85298cff5f6dcdba14f3813e8830015b9ed1948f
-    # via dm-haiku
-toolz==1.0.0 \
-    --hash=sha256:292c8f1c4e7516bf9086f8850935c799a874039c8bcf959d47b600e4c44a6236 \
-    --hash=sha256:2c86e3d9a04798ac556793bced838816296a2f085017664e4995cb40a1047a02
-    # via chex
-tqdm==4.67.0 \
-    --hash=sha256:0cd8af9d56911acab92182e88d763100d4788bdf421d251616040cc4d44863be \
-    --hash=sha256:fe5a6f95e6fe0b9755e9469b77b9c3cf850048224ecaa8293d7d2d31f97d869a
-    # via alphafold3 (pyproject.toml)
-triton==3.1.0 \
-    --hash=sha256:0f34f6e7885d1bf0eaaf7ba875a5f0ce6f3c13ba98f9503651c1e6dc6757ed5c \
-    --hash=sha256:6b0dd10a925263abbe9fa37dcde67a5e9b2383fc269fdf59f5657cac38c5d1d8 \
-    --hash=sha256:6dadaca7fc24de34e180271b5cf864c16755702e9f63a16f62df714a8099126a \
-    --hash=sha256:aafa9a20cd0d9fee523cd4504aa7131807a864cd77dcf6efe7e981f18b8c6c11 \
-    --hash=sha256:c8182f42fd8080a7d39d666814fa36c5e30cc00ea7eeeb1a2983dbb4c99a0fdc
-    # via
-    #   alphafold3 (pyproject.toml)
-    #   jax-triton
-typeguard==2.13.3 \
-    --hash=sha256:00edaa8da3a133674796cf5ea87d9f4b4c367d77476e185e80251cc13dfbb8c4 \
-    --hash=sha256:5e3e3be01e887e7eafae5af63d1f36c849aaa94e3a0112097312aabfa16284f1
-    # via jaxtyping
-typing-extensions==4.12.2 \
-    --hash=sha256:04e5ca0351e0f3f85c6853954072df659d0d13fac324d0072316b67d7794700d \
-    --hash=sha256:1a7ead55c7e559dd4dee8856e3a88b41225abfe1ce8df57b7c13915fe121ffb8
-    # via chex
-zstandard==0.23.0 \
-    --hash=sha256:034b88913ecc1b097f528e42b539453fa82c3557e414b3de9d5632c80439a473 \
-    --hash=sha256:0a7f0804bb3799414af278e9ad51be25edf67f78f916e08afdb983e74161b916 \
-    --hash=sha256:11e3bf3c924853a2d5835b24f03eeba7fc9b07d8ca499e247e06ff5676461a15 \
-    --hash=sha256:12a289832e520c6bd4dcaad68e944b86da3bad0d339ef7989fb7e88f92e96072 \
-    --hash=sha256:1516c8c37d3a053b01c1c15b182f3b5f5eef19ced9b930b684a73bad121addf4 \
-    --hash=sha256:157e89ceb4054029a289fb504c98c6a9fe8010f1680de0201b3eb5dc20aa6d9e \
-    --hash=sha256:1bfe8de1da6d104f15a60d4a8a768288f66aa953bbe00d027398b93fb9680b26 \
-    --hash=sha256:1e172f57cd78c20f13a3415cc8dfe24bf388614324d25539146594c16d78fcc8 \
-    --hash=sha256:1fd7e0f1cfb70eb2f95a19b472ee7ad6d9a0a992ec0ae53286870c104ca939e5 \
-    --hash=sha256:203d236f4c94cd8379d1ea61db2fce20730b4c38d7f1c34506a31b34edc87bdd \
-    --hash=sha256:27d3ef2252d2e62476389ca8f9b0cf2bbafb082a3b6bfe9d90cbcbb5529ecf7c \
-    --hash=sha256:29a2bc7c1b09b0af938b7a8343174b987ae021705acabcbae560166567f5a8db \
-    --hash=sha256:2ef230a8fd217a2015bc91b74f6b3b7d6522ba48be29ad4ea0ca3a3775bf7dd5 \
-    --hash=sha256:2ef3775758346d9ac6214123887d25c7061c92afe1f2b354f9388e9e4d48acfc \
-    --hash=sha256:2f146f50723defec2975fb7e388ae3a024eb7151542d1599527ec2aa9cacb152 \
-    --hash=sha256:2fb4535137de7e244c230e24f9d1ec194f61721c86ebea04e1581d9d06ea1269 \
-    --hash=sha256:32ba3b5ccde2d581b1e6aa952c836a6291e8435d788f656fe5976445865ae045 \
-    --hash=sha256:34895a41273ad33347b2fc70e1bff4240556de3c46c6ea430a7ed91f9042aa4e \
-    --hash=sha256:379b378ae694ba78cef921581ebd420c938936a153ded602c4fea612b7eaa90d \
-    --hash=sha256:38302b78a850ff82656beaddeb0bb989a0322a8bbb1bf1ab10c17506681d772a \
-    --hash=sha256:3aa014d55c3af933c1315eb4bb06dd0459661cc0b15cd61077afa6489bec63bb \
-    --hash=sha256:4051e406288b8cdbb993798b9a45c59a4896b6ecee2f875424ec10276a895740 \
-    --hash=sha256:40b33d93c6eddf02d2c19f5773196068d875c41ca25730e8288e9b672897c105 \
-    --hash=sha256:43da0f0092281bf501f9c5f6f3b4c975a8a0ea82de49ba3f7100e64d422a1274 \
-    --hash=sha256:445e4cb5048b04e90ce96a79b4b63140e3f4ab5f662321975679b5f6360b90e2 \
-    --hash=sha256:48ef6a43b1846f6025dde6ed9fee0c24e1149c1c25f7fb0a0585572b2f3adc58 \
-    --hash=sha256:50a80baba0285386f97ea36239855f6020ce452456605f262b2d33ac35c7770b \
-    --hash=sha256:519fbf169dfac1222a76ba8861ef4ac7f0530c35dd79ba5727014613f91613d4 \
-    --hash=sha256:53dd9d5e3d29f95acd5de6802e909ada8d8d8cfa37a3ac64836f3bc4bc5512db \
-    --hash=sha256:53ea7cdc96c6eb56e76bb06894bcfb5dfa93b7adcf59d61c6b92674e24e2dd5e \
-    --hash=sha256:576856e8594e6649aee06ddbfc738fec6a834f7c85bf7cadd1c53d4a58186ef9 \
-    --hash=sha256:59556bf80a7094d0cfb9f5e50bb2db27fefb75d5138bb16fb052b61b0e0eeeb0 \
-    --hash=sha256:5d41d5e025f1e0bccae4928981e71b2334c60f580bdc8345f824e7c0a4c2a813 \
-    --hash=sha256:61062387ad820c654b6a6b5f0b94484fa19515e0c5116faf29f41a6bc91ded6e \
-    --hash=sha256:61f89436cbfede4bc4e91b4397eaa3e2108ebe96d05e93d6ccc95ab5714be512 \
-    --hash=sha256:62136da96a973bd2557f06ddd4e8e807f9e13cbb0bfb9cc06cfe6d98ea90dfe0 \
-    --hash=sha256:64585e1dba664dc67c7cdabd56c1e5685233fbb1fc1966cfba2a340ec0dfff7b \
-    --hash=sha256:65308f4b4890aa12d9b6ad9f2844b7ee42c7f7a4fd3390425b242ffc57498f48 \
-    --hash=sha256:66b689c107857eceabf2cf3d3fc699c3c0fe8ccd18df2219d978c0283e4c508a \
-    --hash=sha256:6a41c120c3dbc0d81a8e8adc73312d668cd34acd7725f036992b1b72d22c1772 \
-    --hash=sha256:6f77fa49079891a4aab203d0b1744acc85577ed16d767b52fc089d83faf8d8ed \
-    --hash=sha256:72c68dda124a1a138340fb62fa21b9bf4848437d9ca60bd35db36f2d3345f373 \
-    --hash=sha256:752bf8a74412b9892f4e5b58f2f890a039f57037f52c89a740757ebd807f33ea \
-    --hash=sha256:76e79bc28a65f467e0409098fa2c4376931fd3207fbeb6b956c7c476d53746dd \
-    --hash=sha256:774d45b1fac1461f48698a9d4b5fa19a69d47ece02fa469825b442263f04021f \
-    --hash=sha256:77da4c6bfa20dd5ea25cbf12c76f181a8e8cd7ea231c673828d0386b1740b8dc \
-    --hash=sha256:77ea385f7dd5b5676d7fd943292ffa18fbf5c72ba98f7d09fc1fb9e819b34c23 \
-    --hash=sha256:80080816b4f52a9d886e67f1f96912891074903238fe54f2de8b786f86baded2 \
-    --hash=sha256:80a539906390591dd39ebb8d773771dc4db82ace6372c4d41e2d293f8e32b8db \
-    --hash=sha256:82d17e94d735c99621bf8ebf9995f870a6b3e6d14543b99e201ae046dfe7de70 \
-    --hash=sha256:837bb6764be6919963ef41235fd56a6486b132ea64afe5fafb4cb279ac44f259 \
-    --hash=sha256:84433dddea68571a6d6bd4fbf8ff398236031149116a7fff6f777ff95cad3df9 \
-    --hash=sha256:8c24f21fa2af4bb9f2c492a86fe0c34e6d2c63812a839590edaf177b7398f700 \
-    --hash=sha256:8ed7d27cb56b3e058d3cf684d7200703bcae623e1dcc06ed1e18ecda39fee003 \
-    --hash=sha256:9206649ec587e6b02bd124fb7799b86cddec350f6f6c14bc82a2b70183e708ba \
-    --hash=sha256:983b6efd649723474f29ed42e1467f90a35a74793437d0bc64a5bf482bedfa0a \
-    --hash=sha256:98da17ce9cbf3bfe4617e836d561e433f871129e3a7ac16d6ef4c680f13a839c \
-    --hash=sha256:9c236e635582742fee16603042553d276cca506e824fa2e6489db04039521e90 \
-    --hash=sha256:9da6bc32faac9a293ddfdcb9108d4b20416219461e4ec64dfea8383cac186690 \
-    --hash=sha256:a05e6d6218461eb1b4771d973728f0133b2a4613a6779995df557f70794fd60f \
-    --hash=sha256:a0817825b900fcd43ac5d05b8b3079937073d2b1ff9cf89427590718b70dd840 \
-    --hash=sha256:a4ae99c57668ca1e78597d8b06d5af837f377f340f4cce993b551b2d7731778d \
-    --hash=sha256:a8c86881813a78a6f4508ef9daf9d4995b8ac2d147dcb1a450448941398091c9 \
-    --hash=sha256:a8fffdbd9d1408006baaf02f1068d7dd1f016c6bcb7538682622c556e7b68e35 \
-    --hash=sha256:a9b07268d0c3ca5c170a385a0ab9fb7fdd9f5fd866be004c4ea39e44edce47dd \
-    --hash=sha256:ab19a2d91963ed9e42b4e8d77cd847ae8381576585bad79dbd0a8837a9f6620a \
-    --hash=sha256:ac184f87ff521f4840e6ea0b10c0ec90c6b1dcd0bad2f1e4a9a1b4fa177982ea \
-    --hash=sha256:b0e166f698c5a3e914947388c162be2583e0c638a4703fc6a543e23a88dea3c1 \
-    --hash=sha256:b2170c7e0367dde86a2647ed5b6f57394ea7f53545746104c6b09fc1f4223573 \
-    --hash=sha256:b2d8c62d08e7255f68f7a740bae85b3c9b8e5466baa9cbf7f57f1cde0ac6bc09 \
-    --hash=sha256:b4567955a6bc1b20e9c31612e615af6b53733491aeaa19a6b3b37f3b65477094 \
-    --hash=sha256:b69bb4f51daf461b15e7b3db033160937d3ff88303a7bc808c67bbc1eaf98c78 \
-    --hash=sha256:b8c0bd73aeac689beacd4e7667d48c299f61b959475cdbb91e7d3d88d27c56b9 \
-    --hash=sha256:be9b5b8659dff1f913039c2feee1aca499cfbc19e98fa12bc85e037c17ec6ca5 \
-    --hash=sha256:bf0a05b6059c0528477fba9054d09179beb63744355cab9f38059548fedd46a9 \
-    --hash=sha256:c16842b846a8d2a145223f520b7e18b57c8f476924bda92aeee3a88d11cfc391 \
-    --hash=sha256:c363b53e257246a954ebc7c488304b5592b9c53fbe74d03bc1c64dda153fb847 \
-    --hash=sha256:c7c517d74bea1a6afd39aa612fa025e6b8011982a0897768a2f7c8ab4ebb78a2 \
-    --hash=sha256:d20fd853fbb5807c8e84c136c278827b6167ded66c72ec6f9a14b863d809211c \
-    --hash=sha256:d2240ddc86b74966c34554c49d00eaafa8200a18d3a5b6ffbf7da63b11d74ee2 \
-    --hash=sha256:d477ed829077cd945b01fc3115edd132c47e6540ddcd96ca169facff28173057 \
-    --hash=sha256:d50d31bfedd53a928fed6707b15a8dbeef011bb6366297cc435accc888b27c20 \
-    --hash=sha256:dc1d33abb8a0d754ea4763bad944fd965d3d95b5baef6b121c0c9013eaf1907d \
-    --hash=sha256:dc5d1a49d3f8262be192589a4b72f0d03b72dcf46c51ad5852a4fdc67be7b9e4 \
-    --hash=sha256:e2d1a054f8f0a191004675755448d12be47fa9bebbcffa3cdf01db19f2d30a54 \
-    --hash=sha256:e7792606d606c8df5277c32ccb58f29b9b8603bf83b48639b7aedf6df4fe8171 \
-    --hash=sha256:ed1708dbf4d2e3a1c5c69110ba2b4eb6678262028afd6c6fbcc5a8dac9cda68e \
-    --hash=sha256:f2d4380bf5f62daabd7b751ea2339c1a21d1c9463f1feb7fc2bdcea2c29c3160 \
-    --hash=sha256:f3513916e8c645d0610815c257cbfd3242adfd5c4cfa78be514e5a3ebb42a41b \
-    --hash=sha256:f8346bfa098532bc1fb6c7ef06783e969d87a99dd1d2a5a18a892c1d7a643c58 \
-    --hash=sha256:f83fa6cae3fff8e98691248c9320356971b59678a17f20656a9e59cd32cee6d8 \
-    --hash=sha256:fa6ce8b52c5987b3e34d5674b0ab529a4602b632ebab0a93b07bfb4dfc8f8a33 \
-    --hash=sha256:fb2b1ecfef1e67897d336de3a0e3f52478182d6a47eda86cbd42504c5cbd009a \
-    --hash=sha256:fc9ca1c9718cb3b06634c7c8dec57d24e9438b2aa9a0f02b8bb36bf478538880 \
-    --hash=sha256:fd30d9c67d13d891f2360b2a120186729c111238ac63b43dbd37a5a40670b8ca \
-    --hash=sha256:fd7699e8fd9969f455ef2926221e0233f81a2542921471382e77a9e2f2b57f4b \
-    --hash=sha256:fe3b385d996ee0822fd46528d9f0443b880d4d05528fd26a9119a54ec3f91c69
-    # via alphafold3 (pyproject.toml)
diff --git a/run_alphafold.py b/run_alphafold.py
deleted file mode 100644
index f49a757722a4e182eb2dedcbb82e1d6feb445a5d..0000000000000000000000000000000000000000
--- a/run_alphafold.py
+++ /dev/null
@@ -1,829 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""AlphaFold 3 structure prediction script.
-
-AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-
-To request access to the AlphaFold 3 model parameters, follow the process set
-out at https://github.com/google-deepmind/alphafold3. You may only use these
-if received directly from Google. Use is subject to terms of use available at
-https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-"""
-
-from collections.abc import Callable, Sequence
-import csv
-import dataclasses
-import datetime
-import functools
-import multiprocessing
-import os
-import pathlib
-import shutil
-import string
-import textwrap
-import time
-import typing
-from typing import overload
-
-from absl import app
-from absl import flags
-from alphafold3.common import folding_input
-from alphafold3.common import resources
-from alphafold3.constants import chemical_components
-import alphafold3.cpp
-from alphafold3.data import featurisation
-from alphafold3.data import pipeline
-from alphafold3.jax.attention import attention
-from alphafold3.model import features
-from alphafold3.model import model
-from alphafold3.model import params
-from alphafold3.model import post_processing
-from alphafold3.model.components import utils
-import haiku as hk
-import jax
-from jax import numpy as jnp
-import numpy as np
-
-
-_HOME_DIR = pathlib.Path(os.environ.get('HOME'))
-_DEFAULT_MODEL_DIR = _HOME_DIR / 'models'
-_DEFAULT_DB_DIR = _HOME_DIR / 'public_databases'
-
-
-# Input and output paths.
-_JSON_PATH = flags.DEFINE_string(
-    'json_path',
-    None,
-    'Path to the input JSON file.',
-)
-_INPUT_DIR = flags.DEFINE_string(
-    'input_dir',
-    None,
-    'Path to the directory containing input JSON files.',
-)
-_OUTPUT_DIR = flags.DEFINE_string(
-    'output_dir',
-    None,
-    'Path to a directory where the results will be saved.',
-)
-MODEL_DIR = flags.DEFINE_string(
-    'model_dir',
-    _DEFAULT_MODEL_DIR.as_posix(),
-    'Path to the model to use for inference.',
-)
-
-# Control which stages to run.
-_RUN_DATA_PIPELINE = flags.DEFINE_bool(
-    'run_data_pipeline',
-    True,
-    'Whether to run the data pipeline on the fold inputs.',
-)
-_RUN_INFERENCE = flags.DEFINE_bool(
-    'run_inference',
-    True,
-    'Whether to run inference on the fold inputs.',
-)
-
-# Binary paths.
-_JACKHMMER_BINARY_PATH = flags.DEFINE_string(
-    'jackhmmer_binary_path',
-    shutil.which('jackhmmer'),
-    'Path to the Jackhmmer binary.',
-)
-_NHMMER_BINARY_PATH = flags.DEFINE_string(
-    'nhmmer_binary_path',
-    shutil.which('nhmmer'),
-    'Path to the Nhmmer binary.',
-)
-_HMMALIGN_BINARY_PATH = flags.DEFINE_string(
-    'hmmalign_binary_path',
-    shutil.which('hmmalign'),
-    'Path to the Hmmalign binary.',
-)
-_HMMSEARCH_BINARY_PATH = flags.DEFINE_string(
-    'hmmsearch_binary_path',
-    shutil.which('hmmsearch'),
-    'Path to the Hmmsearch binary.',
-)
-_HMMBUILD_BINARY_PATH = flags.DEFINE_string(
-    'hmmbuild_binary_path',
-    shutil.which('hmmbuild'),
-    'Path to the Hmmbuild binary.',
-)
-
-# Database paths.
-DB_DIR = flags.DEFINE_multi_string(
-    'db_dir',
-    (_DEFAULT_DB_DIR.as_posix(),),
-    'Path to the directory containing the databases. Can be specified multiple'
-    ' times to search multiple directories in order.',
-)
-
-_SMALL_BFD_DATABASE_PATH = flags.DEFINE_string(
-    'small_bfd_database_path',
-    '${DB_DIR}/bfd-first_non_consensus_sequences.fasta',
-    'Small BFD database path, used for protein MSA search.',
-)
-_MGNIFY_DATABASE_PATH = flags.DEFINE_string(
-    'mgnify_database_path',
-    '${DB_DIR}/mgy_clusters_2022_05.fa',
-    'Mgnify database path, used for protein MSA search.',
-)
-_UNIPROT_CLUSTER_ANNOT_DATABASE_PATH = flags.DEFINE_string(
-    'uniprot_cluster_annot_database_path',
-    '${DB_DIR}/uniprot_all_2021_04.fa',
-    'UniProt database path, used for protein paired MSA search.',
-)
-_UNIREF90_DATABASE_PATH = flags.DEFINE_string(
-    'uniref90_database_path',
-    '${DB_DIR}/uniref90_2022_05.fa',
-    'UniRef90 database path, used for MSA search. The MSA obtained by '
-    'searching it is used to construct the profile for template search.',
-)
-_NTRNA_DATABASE_PATH = flags.DEFINE_string(
-    'ntrna_database_path',
-    '${DB_DIR}/nt_rna_2023_02_23_clust_seq_id_90_cov_80_rep_seq.fasta',
-    'NT-RNA database path, used for RNA MSA search.',
-)
-_RFAM_DATABASE_PATH = flags.DEFINE_string(
-    'rfam_database_path',
-    '${DB_DIR}/rfam_14_9_clust_seq_id_90_cov_80_rep_seq.fasta',
-    'Rfam database path, used for RNA MSA search.',
-)
-_RNA_CENTRAL_DATABASE_PATH = flags.DEFINE_string(
-    'rna_central_database_path',
-    '${DB_DIR}/rnacentral_active_seq_id_90_cov_80_linclust.fasta',
-    'RNAcentral database path, used for RNA MSA search.',
-)
-_PDB_DATABASE_PATH = flags.DEFINE_string(
-    'pdb_database_path',
-    '${DB_DIR}/mmcif_files',
-    'PDB database directory with mmCIF files path, used for template search.',
-)
-_SEQRES_DATABASE_PATH = flags.DEFINE_string(
-    'seqres_database_path',
-    '${DB_DIR}/pdb_seqres_2022_09_28.fasta',
-    'PDB sequence database path, used for template search.',
-)
-
-# Number of CPUs to use for MSA tools.
-_JACKHMMER_N_CPU = flags.DEFINE_integer(
-    'jackhmmer_n_cpu',
-    min(multiprocessing.cpu_count(), 8),
-    'Number of CPUs to use for Jackhmmer. Default to min(cpu_count, 8). Going'
-    ' beyond 8 CPUs provides very little additional speedup.',
-)
-_NHMMER_N_CPU = flags.DEFINE_integer(
-    'nhmmer_n_cpu',
-    min(multiprocessing.cpu_count(), 8),
-    'Number of CPUs to use for Nhmmer. Default to min(cpu_count, 8). Going'
-    ' beyond 8 CPUs provides very little additional speedup.',
-)
-
-# Template search configuration.
-_MAX_TEMPLATE_DATE = flags.DEFINE_string(
-    'max_template_date',
-    '2021-09-30',  # By default, use the date from the AlphaFold 3 paper.
-    'Maximum template release date to consider. Format: YYYY-MM-DD. All'
-    ' templates released after this date will be ignored. Controls also whether'
-    ' to allow use of model coordinates for a chemical component from the CCD'
-    ' if RDKit conformer generation fails and the component does not have ideal'
-    ' coordinates set. Only for components that have been released before this'
-    ' date the model coordinates can be used as a fallback.',
-)
-
-_CONFORMER_MAX_ITERATIONS = flags.DEFINE_integer(
-    'conformer_max_iterations',
-    None,  # Default to RDKit default parameters value.
-    'Optional override for maximum number of iterations to run for RDKit '
-    'conformer search.',
-)
-
-# JAX inference performance tuning.
-_JAX_COMPILATION_CACHE_DIR = flags.DEFINE_string(
-    'jax_compilation_cache_dir',
-    None,
-    'Path to a directory for the JAX compilation cache.',
-)
-_GPU_DEVICE = flags.DEFINE_integer(
-    'gpu_device',
-    0,
-    'Optional override for the GPU device to use for inference. Defaults to the'
-    ' 1st GPU on the system. Useful on multi-GPU systems to pin each run to a'
-    ' specific GPU.',
-)
-_BUCKETS = flags.DEFINE_list(
-    'buckets',
-    # pyformat: disable
-    ['256', '512', '768', '1024', '1280', '1536', '2048', '2560', '3072',
-     '3584', '4096', '4608', '5120'],
-    # pyformat: enable
-    'Strictly increasing order of token sizes for which to cache compilations.'
-    ' For any input with more tokens than the largest bucket size, a new bucket'
-    ' is created for exactly that number of tokens.',
-)
-_FLASH_ATTENTION_IMPLEMENTATION = flags.DEFINE_enum(
-    'flash_attention_implementation',
-    default='triton',
-    enum_values=['triton', 'cudnn', 'xla'],
-    help=(
-        "Flash attention implementation to use. 'triton' and 'cudnn' uses a"
-        ' Triton and cuDNN flash attention implementation, respectively. The'
-        ' Triton kernel is fastest and has been tested more thoroughly. The'
-        " Triton and cuDNN kernels require Ampere GPUs or later. 'xla' uses an"
-        ' XLA attention implementation (no flash attention) and is portable'
-        ' across GPU devices.'
-    ),
-)
-_NUM_RECYCLES = flags.DEFINE_integer(
-    'num_recycles',
-    10,
-    'Number of recycles to use during inference.',
-    lower_bound=1,
-)
-_NUM_DIFFUSION_SAMPLES = flags.DEFINE_integer(
-    'num_diffusion_samples',
-    5,
-    'Number of diffusion samples to generate.',
-    lower_bound=1,
-)
-_NUM_SEEDS = flags.DEFINE_integer(
-    'num_seeds',
-    None,
-    'Number of seeds to use for inference. If set, only a single seed must be'
-    ' provided in the input JSON. AlphaFold 3 will then generate random seeds'
-    ' in sequence, starting from the single seed specified in the input JSON.'
-    ' The full input JSON produced by AlphaFold 3 will include the generated'
-    ' random seeds. If not set, AlphaFold 3 will use the seeds as provided in'
-    ' the input JSON.',
-    lower_bound=1,
-)
-
-# Output controls.
-_SAVE_EMBEDDINGS = flags.DEFINE_bool(
-    'save_embeddings',
-    False,
-    'Whether to save the final trunk single and pair embeddings in the output.',
-)
-_FORCE_OUTPUT_DIR = flags.DEFINE_bool(
-    'force_output_dir',
-    False,
-    'Whether to force the output directory to be used even if it already exists'
-    ' and is non-empty. Useful to set this to True to run the data pipeline and'
-    ' the inference separately, but use the same output directory.',
-)
-
-
-def make_model_config(
-    *,
-    flash_attention_implementation: attention.Implementation = 'triton',
-    num_diffusion_samples: int = 5,
-    num_recycles: int = 10,
-    return_embeddings: bool = False,
-) -> model.Model.Config:
-  """Returns a model config with some defaults overridden."""
-  config = model.Model.Config()
-  config.global_config.flash_attention_implementation = (
-      flash_attention_implementation
-  )
-  config.heads.diffusion.eval.num_samples = num_diffusion_samples
-  config.num_recycles = num_recycles
-  config.return_embeddings = return_embeddings
-  return config
-
-
-class ModelRunner:
-  """Helper class to run structure prediction stages."""
-
-  def __init__(
-      self,
-      config: model.Model.Config,
-      device: jax.Device,
-      model_dir: pathlib.Path,
-  ):
-    self._model_config = config
-    self._device = device
-    self._model_dir = model_dir
-
-  @functools.cached_property
-  def model_params(self) -> hk.Params:
-    """Loads model parameters from the model directory."""
-    return params.get_model_haiku_params(model_dir=self._model_dir)
-
-  @functools.cached_property
-  def _model(
-      self,
-  ) -> Callable[[jnp.ndarray, features.BatchDict], model.ModelResult]:
-    """Loads model parameters and returns a jitted model forward pass."""
-
-    @hk.transform
-    def forward_fn(batch):
-      return model.Model(self._model_config)(batch)
-
-    return functools.partial(
-        jax.jit(forward_fn.apply, device=self._device), self.model_params
-    )
-
-  def run_inference(
-      self, featurised_example: features.BatchDict, rng_key: jnp.ndarray
-  ) -> model.ModelResult:
-    """Computes a forward pass of the model on a featurised example."""
-    featurised_example = jax.device_put(
-        jax.tree_util.tree_map(
-            jnp.asarray, utils.remove_invalidly_typed_feats(featurised_example)
-        ),
-        self._device,
-    )
-
-    result = self._model(rng_key, featurised_example)
-    result = jax.tree.map(np.asarray, result)
-    result = jax.tree.map(
-        lambda x: x.astype(jnp.float32) if x.dtype == jnp.bfloat16 else x,
-        result,
-    )
-    result = dict(result)
-    identifier = self.model_params['__meta__']['__identifier__'].tobytes()
-    result['__identifier__'] = identifier
-    return result
-
-  def extract_inference_results_and_maybe_embeddings(
-      self,
-      batch: features.BatchDict,
-      result: model.ModelResult,
-      target_name: str,
-  ) -> tuple[list[model.InferenceResult], dict[str, np.ndarray] | None]:
-    """Extracts inference results and embeddings (if set) from model outputs."""
-    inference_results = list(
-        model.Model.get_inference_result(
-            batch=batch, result=result, target_name=target_name
-        )
-    )
-    num_tokens = len(inference_results[0].metadata['token_chain_ids'])
-    embeddings = {}
-    if 'single_embeddings' in result:
-      embeddings['single_embeddings'] = result['single_embeddings'][:num_tokens]
-    if 'pair_embeddings' in result:
-      embeddings['pair_embeddings'] = result['pair_embeddings'][
-          :num_tokens, :num_tokens
-      ]
-    return inference_results, embeddings or None
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class ResultsForSeed:
-  """Stores the inference results (diffusion samples) for a single seed.
-
-  Attributes:
-    seed: The seed used to generate the samples.
-    inference_results: The inference results, one per sample.
-    full_fold_input: The fold input that must also include the results of
-      running the data pipeline - MSA and templates.
-    embeddings: The final trunk single and pair embeddings, if requested.
-  """
-
-  seed: int
-  inference_results: Sequence[model.InferenceResult]
-  full_fold_input: folding_input.Input
-  embeddings: dict[str, np.ndarray] | None = None
-
-
-def predict_structure(
-    fold_input: folding_input.Input,
-    model_runner: ModelRunner,
-    buckets: Sequence[int] | None = None,
-    ref_max_modified_date: datetime.date | None = None,
-    conformer_max_iterations: int | None = None,
-) -> Sequence[ResultsForSeed]:
-  """Runs the full inference pipeline to predict structures for each seed."""
-
-  print(f'Featurising data with {len(fold_input.rng_seeds)} seed(s)...')
-  featurisation_start_time = time.time()
-  ccd = chemical_components.cached_ccd(user_ccd=fold_input.user_ccd)
-  featurised_examples = featurisation.featurise_input(
-      fold_input=fold_input,
-      buckets=buckets,
-      ccd=ccd,
-      verbose=True,
-      ref_max_modified_date=ref_max_modified_date,
-      conformer_max_iterations=conformer_max_iterations,
-  )
-  print(
-      f'Featurising data with {len(fold_input.rng_seeds)} seed(s) took'
-      f' {time.time() - featurisation_start_time:.2f} seconds.'
-  )
-  print(
-      'Running model inference and extracting output structure samples with'
-      f' {len(fold_input.rng_seeds)} seed(s)...'
-  )
-  all_inference_start_time = time.time()
-  all_inference_results = []
-  for seed, example in zip(fold_input.rng_seeds, featurised_examples):
-    print(f'Running model inference with seed {seed}...')
-    inference_start_time = time.time()
-    rng_key = jax.random.PRNGKey(seed)
-    result = model_runner.run_inference(example, rng_key)
-    print(
-        f'Running model inference with seed {seed} took'
-        f' {time.time() - inference_start_time:.2f} seconds.'
-    )
-    print(f'Extracting inference results with seed {seed}...')
-    extract_structures = time.time()
-    inference_results, embeddings = (
-        model_runner.extract_inference_results_and_maybe_embeddings(
-            batch=example, result=result, target_name=fold_input.name
-        )
-    )
-    print(
-        f'Extracting {len(inference_results)} inference samples with'
-        f' seed {seed} took {time.time() - extract_structures:.2f} seconds.'
-    )
-
-    all_inference_results.append(
-        ResultsForSeed(
-            seed=seed,
-            inference_results=inference_results,
-            full_fold_input=fold_input,
-            embeddings=embeddings,
-        )
-    )
-  print(
-      'Running model inference and extracting output structures with'
-      f' {len(fold_input.rng_seeds)} seed(s) took'
-      f' {time.time() - all_inference_start_time:.2f} seconds.'
-  )
-  return all_inference_results
-
-
-def write_fold_input_json(
-    fold_input: folding_input.Input,
-    output_dir: os.PathLike[str] | str,
-) -> None:
-  """Writes the input JSON to the output directory."""
-  os.makedirs(output_dir, exist_ok=True)
-  path = os.path.join(output_dir, f'{fold_input.sanitised_name()}_data.json')
-  print(f'Writing model input JSON to {path}')
-  with open(path, 'wt') as f:
-    f.write(fold_input.to_json())
-
-
-def write_outputs(
-    all_inference_results: Sequence[ResultsForSeed],
-    output_dir: os.PathLike[str] | str,
-    job_name: str,
-) -> None:
-  """Writes outputs to the specified output directory."""
-  ranking_scores = []
-  max_ranking_score = None
-  max_ranking_result = None
-
-  output_terms = (
-      pathlib.Path(alphafold3.cpp.__file__).parent / 'OUTPUT_TERMS_OF_USE.md'
-  ).read_text()
-
-  os.makedirs(output_dir, exist_ok=True)
-  for results_for_seed in all_inference_results:
-    seed = results_for_seed.seed
-    for sample_idx, result in enumerate(results_for_seed.inference_results):
-      sample_dir = os.path.join(output_dir, f'seed-{seed}_sample-{sample_idx}')
-      os.makedirs(sample_dir, exist_ok=True)
-      post_processing.write_output(
-          inference_result=result,
-          output_dir=sample_dir,
-          name=f'{job_name}_seed-{seed}_sample-{sample_idx}',
-      )
-      ranking_score = float(result.metadata['ranking_score'])
-      ranking_scores.append((seed, sample_idx, ranking_score))
-      if max_ranking_score is None or ranking_score > max_ranking_score:
-        max_ranking_score = ranking_score
-        max_ranking_result = result
-
-    if embeddings := results_for_seed.embeddings:
-      embeddings_dir = os.path.join(output_dir, f'seed-{seed}_embeddings')
-      os.makedirs(embeddings_dir, exist_ok=True)
-      post_processing.write_embeddings(
-          embeddings=embeddings,
-          output_dir=embeddings_dir,
-          name=f'{job_name}_seed-{seed}',
-      )
-
-  if max_ranking_result is not None:  # True iff ranking_scores non-empty.
-    post_processing.write_output(
-        inference_result=max_ranking_result,
-        output_dir=output_dir,
-        # The output terms of use are the same for all seeds/samples.
-        terms_of_use=output_terms,
-        name=job_name,
-    )
-    # Save csv of ranking scores with seeds and sample indices, to allow easier
-    # comparison of ranking scores across different runs.
-    with open(
-        os.path.join(output_dir, f'{job_name}_ranking_scores.csv'), 'wt'
-    ) as f:
-      writer = csv.writer(f)
-      writer.writerow(['seed', 'sample', 'ranking_score'])
-      writer.writerows(ranking_scores)
-
-
-def replace_db_dir(path_with_db_dir: str, db_dirs: Sequence[str]) -> str:
-  """Replaces the DB_DIR placeholder in a path with the given DB_DIR."""
-  template = string.Template(path_with_db_dir)
-  if 'DB_DIR' in template.get_identifiers():
-    for db_dir in db_dirs:
-      path = template.substitute(DB_DIR=db_dir)
-      if os.path.exists(path):
-        return path
-    raise FileNotFoundError(
-        f'{path_with_db_dir} with ${{DB_DIR}} not found in any of {db_dirs}.'
-    )
-  if not os.path.exists(path_with_db_dir):
-    raise FileNotFoundError(f'{path_with_db_dir} does not exist.')
-  return path_with_db_dir
-
-
-@overload
-def process_fold_input(
-    fold_input: folding_input.Input,
-    data_pipeline_config: pipeline.DataPipelineConfig | None,
-    model_runner: None,
-    output_dir: os.PathLike[str] | str,
-    buckets: Sequence[int] | None = None,
-    ref_max_modified_date: datetime.date | None = None,
-    conformer_max_iterations: int | None = None,
-    force_output_dir: bool = False,
-) -> folding_input.Input:
-  ...
-
-
-@overload
-def process_fold_input(
-    fold_input: folding_input.Input,
-    data_pipeline_config: pipeline.DataPipelineConfig | None,
-    model_runner: ModelRunner,
-    output_dir: os.PathLike[str] | str,
-    buckets: Sequence[int] | None = None,
-    ref_max_modified_date: datetime.date | None = None,
-    conformer_max_iterations: int | None = None,
-    force_output_dir: bool = False,
-) -> Sequence[ResultsForSeed]:
-  ...
-
-
-def process_fold_input(
-    fold_input: folding_input.Input,
-    data_pipeline_config: pipeline.DataPipelineConfig | None,
-    model_runner: ModelRunner | None,
-    output_dir: os.PathLike[str] | str,
-    buckets: Sequence[int] | None = None,
-    ref_max_modified_date: datetime.date | None = None,
-    conformer_max_iterations: int | None = None,
-    force_output_dir: bool = False,
-) -> folding_input.Input | Sequence[ResultsForSeed]:
-  """Runs data pipeline and/or inference on a single fold input.
-
-  Args:
-    fold_input: Fold input to process.
-    data_pipeline_config: Data pipeline config to use. If None, skip the data
-      pipeline.
-    model_runner: Model runner to use. If None, skip inference.
-    output_dir: Output directory to write to.
-    buckets: Bucket sizes to pad the data to, to avoid excessive re-compilation
-      of the model. If None, calculate the appropriate bucket size from the
-      number of tokens. If not None, must be a sequence of at least one integer,
-      in strictly increasing order. Will raise an error if the number of tokens
-      is more than the largest bucket size.
-    ref_max_modified_date: Optional maximum date that controls whether to allow
-      use of model coordinates for a chemical component from the CCD if RDKit
-      conformer generation fails and the component does not have ideal
-      coordinates set. Only for components that have been released before this
-      date the model coordinates can be used as a fallback.
-    conformer_max_iterations: Optional override for maximum number of iterations
-      to run for RDKit conformer search.
-    force_output_dir: If True, do not create a new output directory even if the
-      existing one is non-empty. Instead use the existing output directory and
-      potentially overwrite existing files. If False, create a new timestamped
-      output directory instead if the existing one is non-empty.
-
-  Returns:
-    The processed fold input, or the inference results for each seed.
-
-  Raises:
-    ValueError: If the fold input has no chains.
-  """
-  print(f'\nRunning fold job {fold_input.name}...')
-
-  if not fold_input.chains:
-    raise ValueError('Fold input has no chains.')
-
-  if (
-      not force_output_dir
-      and os.path.exists(output_dir)
-      and os.listdir(output_dir)
-  ):
-    new_output_dir = (
-        f'{output_dir}_{datetime.datetime.now().strftime("%Y%m%d_%H%M%S")}'
-    )
-    print(
-        f'Output will be written in {new_output_dir} since {output_dir} is'
-        ' non-empty.'
-    )
-    output_dir = new_output_dir
-  else:
-    print(f'Output will be written in {output_dir}')
-
-  if data_pipeline_config is None:
-    print('Skipping data pipeline...')
-  else:
-    print('Running data pipeline...')
-    fold_input = pipeline.DataPipeline(data_pipeline_config).process(fold_input)
-
-  write_fold_input_json(fold_input, output_dir)
-  if model_runner is None:
-    print('Skipping model inference...')
-    output = fold_input
-  else:
-    print(
-        f'Predicting 3D structure for {fold_input.name} with'
-        f' {len(fold_input.rng_seeds)} seed(s)...'
-    )
-    all_inference_results = predict_structure(
-        fold_input=fold_input,
-        model_runner=model_runner,
-        buckets=buckets,
-        ref_max_modified_date=ref_max_modified_date,
-        conformer_max_iterations=conformer_max_iterations,
-    )
-    print(f'Writing outputs with {len(fold_input.rng_seeds)} seed(s)...')
-    write_outputs(
-        all_inference_results=all_inference_results,
-        output_dir=output_dir,
-        job_name=fold_input.sanitised_name(),
-    )
-    output = all_inference_results
-
-  print(f'Fold job {fold_input.name} done, output written to {output_dir}\n')
-  return output
-
-
-def main(_):
-  if _JAX_COMPILATION_CACHE_DIR.value is not None:
-    jax.config.update(
-        'jax_compilation_cache_dir', _JAX_COMPILATION_CACHE_DIR.value
-    )
-
-  if _JSON_PATH.value is None == _INPUT_DIR.value is None:
-    raise ValueError(
-        'Exactly one of --json_path or --input_dir must be specified.'
-    )
-
-  if not _RUN_INFERENCE.value and not _RUN_DATA_PIPELINE.value:
-    raise ValueError(
-        'At least one of --run_inference or --run_data_pipeline must be'
-        ' set to true.'
-    )
-
-  if _INPUT_DIR.value is not None:
-    fold_inputs = folding_input.load_fold_inputs_from_dir(
-        pathlib.Path(_INPUT_DIR.value)
-    )
-  elif _JSON_PATH.value is not None:
-    fold_inputs = folding_input.load_fold_inputs_from_path(
-        pathlib.Path(_JSON_PATH.value)
-    )
-  else:
-    raise AssertionError(
-        'Exactly one of --json_path or --input_dir must be specified.'
-    )
-
-  # Make sure we can create the output directory before running anything.
-  try:
-    os.makedirs(_OUTPUT_DIR.value, exist_ok=True)
-  except OSError as e:
-    print(f'Failed to create output directory {_OUTPUT_DIR.value}: {e}')
-    raise
-
-  if _RUN_INFERENCE.value:
-    # Fail early on incompatible devices, but only if we're running inference.
-    gpu_devices = jax.local_devices(backend='gpu')
-    if gpu_devices:
-      compute_capability = float(
-          gpu_devices[_GPU_DEVICE.value].compute_capability
-      )
-      if compute_capability < 6.0:
-        raise ValueError(
-            'AlphaFold 3 requires at least GPU compute capability 6.0 (see'
-            ' https://developer.nvidia.com/cuda-gpus).'
-        )
-      elif 7.0 <= compute_capability < 8.0:
-        xla_flags = os.environ.get('XLA_FLAGS')
-        required_flag = '--xla_disable_hlo_passes=custom-kernel-fusion-rewriter'
-        if not xla_flags or required_flag not in xla_flags:
-          raise ValueError(
-              'For devices with GPU compute capability 7.x (see'
-              ' https://developer.nvidia.com/cuda-gpus) the ENV XLA_FLAGS must'
-              f' include "{required_flag}".'
-          )
-        if _FLASH_ATTENTION_IMPLEMENTATION.value != 'xla':
-          raise ValueError(
-              'For devices with GPU compute capability 7.x (see'
-              ' https://developer.nvidia.com/cuda-gpus) the'
-              ' --flash_attention_implementation must be set to "xla".'
-          )
-
-  notice = textwrap.wrap(
-      'Running AlphaFold 3. Please note that standard AlphaFold 3 model'
-      ' parameters are only available under terms of use provided at'
-      ' https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md.'
-      ' If you do not agree to these terms and are using AlphaFold 3 derived'
-      ' model parameters, cancel execution of AlphaFold 3 inference with'
-      ' CTRL-C, and do not use the model parameters.',
-      break_long_words=False,
-      break_on_hyphens=False,
-      width=80,
-  )
-  print('\n' + '\n'.join(notice) + '\n')
-
-  max_template_date = datetime.date.fromisoformat(_MAX_TEMPLATE_DATE.value)
-  if _RUN_DATA_PIPELINE.value:
-    expand_path = lambda x: replace_db_dir(x, DB_DIR.value)
-    data_pipeline_config = pipeline.DataPipelineConfig(
-        jackhmmer_binary_path=_JACKHMMER_BINARY_PATH.value,
-        nhmmer_binary_path=_NHMMER_BINARY_PATH.value,
-        hmmalign_binary_path=_HMMALIGN_BINARY_PATH.value,
-        hmmsearch_binary_path=_HMMSEARCH_BINARY_PATH.value,
-        hmmbuild_binary_path=_HMMBUILD_BINARY_PATH.value,
-        small_bfd_database_path=expand_path(_SMALL_BFD_DATABASE_PATH.value),
-        mgnify_database_path=expand_path(_MGNIFY_DATABASE_PATH.value),
-        uniprot_cluster_annot_database_path=expand_path(
-            _UNIPROT_CLUSTER_ANNOT_DATABASE_PATH.value
-        ),
-        uniref90_database_path=expand_path(_UNIREF90_DATABASE_PATH.value),
-        ntrna_database_path=expand_path(_NTRNA_DATABASE_PATH.value),
-        rfam_database_path=expand_path(_RFAM_DATABASE_PATH.value),
-        rna_central_database_path=expand_path(_RNA_CENTRAL_DATABASE_PATH.value),
-        pdb_database_path=expand_path(_PDB_DATABASE_PATH.value),
-        seqres_database_path=expand_path(_SEQRES_DATABASE_PATH.value),
-        jackhmmer_n_cpu=_JACKHMMER_N_CPU.value,
-        nhmmer_n_cpu=_NHMMER_N_CPU.value,
-        max_template_date=max_template_date,
-    )
-  else:
-    data_pipeline_config = None
-
-  if _RUN_INFERENCE.value:
-    devices = jax.local_devices(backend='gpu')
-    print(
-        f'Found local devices: {devices}, using device {_GPU_DEVICE.value}:'
-        f' {devices[_GPU_DEVICE.value]}'
-    )
-
-    print('Building model from scratch...')
-    model_runner = ModelRunner(
-        config=make_model_config(
-            flash_attention_implementation=typing.cast(
-                attention.Implementation, _FLASH_ATTENTION_IMPLEMENTATION.value
-            ),
-            num_diffusion_samples=_NUM_DIFFUSION_SAMPLES.value,
-            num_recycles=_NUM_RECYCLES.value,
-            return_embeddings=_SAVE_EMBEDDINGS.value,
-        ),
-        device=devices[_GPU_DEVICE.value],
-        model_dir=pathlib.Path(MODEL_DIR.value),
-    )
-    # Check we can load the model parameters before launching anything.
-    print('Checking that model parameters can be loaded...')
-    _ = model_runner.model_params
-  else:
-    model_runner = None
-
-  num_fold_inputs = 0
-  for fold_input in fold_inputs:
-    if _NUM_SEEDS.value is not None:
-      print(f'Expanding fold job {fold_input.name} to {_NUM_SEEDS.value} seeds')
-      fold_input = fold_input.with_multiple_seeds(_NUM_SEEDS.value)
-    process_fold_input(
-        fold_input=fold_input,
-        data_pipeline_config=data_pipeline_config,
-        model_runner=model_runner,
-        output_dir=os.path.join(_OUTPUT_DIR.value, fold_input.sanitised_name()),
-        buckets=tuple(int(bucket) for bucket in _BUCKETS.value),
-        ref_max_modified_date=max_template_date,
-        conformer_max_iterations=_CONFORMER_MAX_ITERATIONS.value,
-        force_output_dir=_FORCE_OUTPUT_DIR.value,
-    )
-    num_fold_inputs += 1
-
-  print(f'Done running {num_fold_inputs} fold jobs.')
-
-
-if __name__ == '__main__':
-  flags.mark_flags_as_required(['output_dir'])
-  app.run(main)
diff --git a/run_alphafold_data_test.py b/run_alphafold_data_test.py
deleted file mode 100644
index 74ddbed9485eef20d2ce59f68de11cae7d0e45e5..0000000000000000000000000000000000000000
--- a/run_alphafold_data_test.py
+++ /dev/null
@@ -1,280 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Tests the AlphaFold 3 data pipeline."""
-
-import contextlib
-import datetime
-import difflib
-import functools
-import hashlib
-import json
-import os
-import pathlib
-import pickle
-from typing import Any
-
-from absl.testing import absltest
-from absl.testing import parameterized
-from alphafold3 import structure
-from alphafold3.common import folding_input
-from alphafold3.common import resources
-from alphafold3.common.testing import data as testing_data
-from alphafold3.constants import chemical_components
-from alphafold3.data import featurisation
-from alphafold3.data import pipeline
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.structure import test_utils
-import jax
-import numpy as np
-
-import run_alphafold
-import shutil
-
-
-_JACKHMMER_BINARY_PATH = shutil.which('jackhmmer')
-_NHMMER_BINARY_PATH = shutil.which('nhmmer')
-_HMMALIGN_BINARY_PATH = shutil.which('hmmalign')
-_HMMSEARCH_BINARY_PATH = shutil.which('hmmsearch')
-_HMMBUILD_BINARY_PATH = shutil.which('hmmbuild')
-
-
-@contextlib.contextmanager
-def _output(name: str):
-  with open(result_path := f'{absltest.TEST_TMPDIR.value}/{name}', "wb") as f:
-    yield result_path, f
-
-
-@functools.singledispatch
-def _hash_data(x: Any, /) -> str:
-  if x is None:
-    return '<<None>>'
-  return _hash_data(json.dumps(x).encode('utf-8'))
-
-
-@_hash_data.register
-def _(x: bytes, /) -> str:
-  return hashlib.sha256(x).hexdigest()
-
-
-@_hash_data.register
-def _(x: jax.Array) -> str:
-  return _hash_data(jax.device_get(x))
-
-
-@_hash_data.register
-def _(x: np.ndarray) -> str:
-  if x.dtype == object:
-    return ';'.join(map(_hash_data, x.ravel().tolist()))
-  return _hash_data(x.tobytes())
-
-
-@_hash_data.register
-def _(_: structure.Structure) -> str:
-  return '<<structure>>'
-
-
-@_hash_data.register
-def _(_: atom_layout.AtomLayout) -> str:
-  return '<<atom-layout>>'
-
-
-def _generate_diff(actual: str, expected: str) -> str:
-  return '\n'.join(
-      difflib.unified_diff(
-          expected.split('\n'),
-          actual.split('\n'),
-          fromfile='expected',
-          tofile='actual',
-          lineterm='',
-      )
-  )
-
-
-class DataPipelineTest(test_utils.StructureTestCase):
-  """Test AlphaFold 3 inference."""
-
-  def setUp(self):
-    super().setUp()
-    small_bfd_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/bfd-first_non_consensus_sequences__subsampled_1000.fasta'
-    ).path()
-    mgnify_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/mgy_clusters__subsampled_1000.fa'
-    ).path()
-    uniprot_cluster_annot_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/uniprot_all__subsampled_1000.fasta'
-    ).path()
-    uniref90_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/uniref90__subsampled_1000.fasta'
-    ).path()
-    ntrna_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/nt_rna_2023_02_23_clust_seq_id_90_cov_80_rep_seq__subsampled_1000.fasta'
-    ).path()
-    rfam_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/rfam_14_4_clustered_rep_seq__subsampled_1000.fasta'
-    ).path()
-    rna_central_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/rnacentral_active_seq_id_90_cov_80_linclust__subsampled_1000.fasta'
-    ).path()
-    pdb_database_path = testing_data.Data(
-        resources.ROOT / 'test_data/miniature_databases/pdb_mmcif'
-    ).path()
-    seqres_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/pdb_seqres_2022_09_28__subsampled_1000.fasta'
-    ).path()
-
-    self._data_pipeline_config = pipeline.DataPipelineConfig(
-        jackhmmer_binary_path=_JACKHMMER_BINARY_PATH,
-        nhmmer_binary_path=_NHMMER_BINARY_PATH,
-        hmmalign_binary_path=_HMMALIGN_BINARY_PATH,
-        hmmsearch_binary_path=_HMMSEARCH_BINARY_PATH,
-        hmmbuild_binary_path=_HMMBUILD_BINARY_PATH,
-        small_bfd_database_path=small_bfd_database_path,
-        mgnify_database_path=mgnify_database_path,
-        uniprot_cluster_annot_database_path=uniprot_cluster_annot_database_path,
-        uniref90_database_path=uniref90_database_path,
-        ntrna_database_path=ntrna_database_path,
-        rfam_database_path=rfam_database_path,
-        rna_central_database_path=rna_central_database_path,
-        pdb_database_path=pdb_database_path,
-        seqres_database_path=seqres_database_path,
-        max_template_date=datetime.date(2021, 9, 30),
-    )
-    test_input = {
-        'name': '5tgy',
-        'modelSeeds': [1234],
-        'sequences': [
-            {
-                'protein': {
-                    'id': 'P',
-                    'sequence': 'SEFEKLRQTGDELVQAFQRLREIFDKGDDDSLEQVLEEIEELIQKHRQLFDNRQEAADTEAAKQGDQWVQLFQRFREAIDKGDKDSLEQLLEELEQALQKIRELAEKKN',
-                    'modifications': [],
-                    'unpairedMsa': None,
-                    'pairedMsa': None,
-                }
-            },
-            {'ligand': {'id': 'LL', 'ccdCodes': ['7BU']}},
-        ],
-        'dialect': folding_input.JSON_DIALECT,
-        'version': folding_input.JSON_VERSION,
-    }
-    self._test_input_json = json.dumps(test_input)
-
-  def compare_golden(self, result_path: str) -> None:
-    filename = os.path.split(result_path)[1]
-    golden_path = testing_data.Data(
-        resources.ROOT / f'test_data/{filename}'
-    ).path()
-    with open(golden_path, 'r') as golden_file:
-      golden_text = golden_file.read()
-    with open(result_path, 'r') as result_file:
-      result_text = result_file.read()
-
-    diff = _generate_diff(result_text, golden_text)
-
-    self.assertEqual(diff, "", f"Result differs from golden:\n{diff}")
-
-  def test_config(self):
-    model_config = run_alphafold.make_model_config()
-    model_config_as_str = json.dumps(
-        model_config.as_dict(), sort_keys=True, indent=2
-    )
-    with _output('model_config.json') as (result_path, output):
-      output.write(model_config_as_str.encode('utf-8'))
-    self.compare_golden(result_path)
-
-  def test_featurisation(self):
-    """Run featurisation and assert that the output is as expected."""
-    fold_input = folding_input.Input.from_json(self._test_input_json)
-    data_pipeline = pipeline.DataPipeline(self._data_pipeline_config)
-    full_fold_input = data_pipeline.process(fold_input)
-    featurised_example = featurisation.featurise_input(
-        full_fold_input,
-        ccd=chemical_components.cached_ccd(),
-        buckets=None,
-    )
-    del featurised_example[0]['ref_pos']  # Depends on specific RDKit version.
-
-    with _output('featurised_example.pkl') as (_, output):
-      output.write(pickle.dumps(featurised_example))
-    featurised_example = jax.tree_util.tree_map(_hash_data, featurised_example)
-    with _output('featurised_example.json') as (result_path, output):
-      output.write(
-          json.dumps(featurised_example, sort_keys=True, indent=2).encode(
-              'utf-8'
-          )
-      )
-    self.compare_golden(result_path)
-
-  def test_write_input_json(self):
-    fold_input = folding_input.Input.from_json(self._test_input_json)
-    output_dir = self.create_tempdir().full_path
-    run_alphafold.write_fold_input_json(fold_input, output_dir)
-    with open(
-        os.path.join(output_dir, f'{fold_input.sanitised_name()}_data.json'),
-        'rt',
-    ) as f:
-      actual_fold_input = folding_input.Input.from_json(f.read())
-
-    self.assertEqual(actual_fold_input, fold_input)
-
-  def test_process_fold_input_runs_only_data_pipeline(self):
-    fold_input = folding_input.Input.from_json(self._test_input_json)
-    output_dir = self.create_tempdir().full_path
-    run_alphafold.process_fold_input(
-        fold_input=fold_input,
-        data_pipeline_config=self._data_pipeline_config,
-        model_runner=None,
-        output_dir=output_dir,
-    )
-    with open(
-        os.path.join(output_dir, f'{fold_input.sanitised_name()}_data.json'),
-        'rt',
-    ) as f:
-      actual_fold_input = folding_input.Input.from_json(f.read())
-
-    featurisation.validate_fold_input(actual_fold_input)
-
-  @parameterized.product(num_db_dirs=tuple(range(1, 3)))
-  def test_replace_db_dir(self, num_db_dirs: int) -> None:
-    """Test that the db_dir is replaced correctly."""
-    db_dirs = [pathlib.Path(self.create_tempdir()) for _ in range(num_db_dirs)]
-    db_dirs_posix = [db_dir.as_posix() for db_dir in db_dirs]
-
-    for i, db_dir in enumerate(db_dirs):
-      for j in range(i + 1):
-        (db_dir / f'filename{j}.txt').write_text(f'hello world {i}')
-
-    for i in range(num_db_dirs):
-      self.assertEqual(
-          pathlib.Path(
-              run_alphafold.replace_db_dir(
-                  f'${{DB_DIR}}/filename{i}.txt', db_dirs_posix
-              )
-          ).read_text(),
-          f'hello world {i}',
-      )
-    with self.assertRaises(FileNotFoundError):
-      run_alphafold.replace_db_dir(
-          f'${{DB_DIR}}/filename{num_db_dirs}.txt', db_dirs_posix
-      )
-
-
-if __name__ == '__main__':
-  absltest.main()
diff --git a/run_alphafold_test.py b/run_alphafold_test.py
deleted file mode 100644
index 38cdebcc7d81ecbb92126e7cb1433b02ff61e397..0000000000000000000000000000000000000000
--- a/run_alphafold_test.py
+++ /dev/null
@@ -1,405 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Tests end-to-end running of AlphaFold 3."""
-
-import contextlib
-import csv
-import dataclasses
-import datetime
-import difflib
-import json
-import os
-import pathlib
-import pickle
-
-from absl import logging
-from absl.testing import absltest
-from absl.testing import parameterized
-from alphafold3.common import folding_input
-from alphafold3.common import resources
-from alphafold3.common.testing import data as testing_data
-from alphafold3.data import pipeline
-from alphafold3.model.scoring import alignment
-from alphafold3.structure import test_utils
-import jax
-import numpy as np
-
-import run_alphafold
-import shutil
-
-
-_JACKHMMER_BINARY_PATH = shutil.which('jackhmmer')
-_NHMMER_BINARY_PATH = shutil.which('nhmmer')
-_HMMALIGN_BINARY_PATH = shutil.which('hmmalign')
-_HMMSEARCH_BINARY_PATH = shutil.which('hmmsearch')
-_HMMBUILD_BINARY_PATH = shutil.which('hmmbuild')
-
-
-@contextlib.contextmanager
-def _output(name: str):
-  with open(result_path := f'{absltest.TEST_TMPDIR.value}/{name}', "wb") as f:
-    yield result_path, f
-
-
-jax.config.update('jax_enable_compilation_cache', False)
-
-
-def _generate_diff(actual: str, expected: str) -> str:
-  return '\n'.join(
-      difflib.unified_diff(
-          expected.split('\n'),
-          actual.split('\n'),
-          fromfile='expected',
-          tofile='actual',
-          lineterm='',
-      )
-  )
-
-
-class InferenceTest(test_utils.StructureTestCase):
-  """Test AlphaFold 3 inference."""
-
-  def setUp(self):
-    super().setUp()
-    small_bfd_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/bfd-first_non_consensus_sequences__subsampled_1000.fasta'
-    ).path()
-    mgnify_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/mgy_clusters__subsampled_1000.fa'
-    ).path()
-    uniprot_cluster_annot_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/uniprot_all__subsampled_1000.fasta'
-    ).path()
-    uniref90_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/uniref90__subsampled_1000.fasta'
-    ).path()
-    ntrna_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/nt_rna_2023_02_23_clust_seq_id_90_cov_80_rep_seq__subsampled_1000.fasta'
-    ).path()
-    rfam_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/rfam_14_4_clustered_rep_seq__subsampled_1000.fasta'
-    ).path()
-    rna_central_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/rnacentral_active_seq_id_90_cov_80_linclust__subsampled_1000.fasta'
-    ).path()
-    pdb_database_path = testing_data.Data(
-        resources.ROOT / 'test_data/miniature_databases/pdb_mmcif'
-    ).path()
-    seqres_database_path = testing_data.Data(
-        resources.ROOT
-        / 'test_data/miniature_databases/pdb_seqres_2022_09_28__subsampled_1000.fasta'
-    ).path()
-
-    self._data_pipeline_config = pipeline.DataPipelineConfig(
-        jackhmmer_binary_path=_JACKHMMER_BINARY_PATH,
-        nhmmer_binary_path=_NHMMER_BINARY_PATH,
-        hmmalign_binary_path=_HMMALIGN_BINARY_PATH,
-        hmmsearch_binary_path=_HMMSEARCH_BINARY_PATH,
-        hmmbuild_binary_path=_HMMBUILD_BINARY_PATH,
-        small_bfd_database_path=small_bfd_database_path,
-        mgnify_database_path=mgnify_database_path,
-        uniprot_cluster_annot_database_path=uniprot_cluster_annot_database_path,
-        uniref90_database_path=uniref90_database_path,
-        ntrna_database_path=ntrna_database_path,
-        rfam_database_path=rfam_database_path,
-        rna_central_database_path=rna_central_database_path,
-        pdb_database_path=pdb_database_path,
-        seqres_database_path=seqres_database_path,
-        max_template_date=datetime.date(2021, 9, 30),
-    )
-    test_input = {
-        'name': '5tgy',
-        'modelSeeds': [1234],
-        'sequences': [
-            {
-                'protein': {
-                    'id': 'P',
-                    'sequence': 'SEFEKLRQTGDELVQAFQRLREIFDKGDDDSLEQVLEEIEELIQKHRQLFDNRQEAADTEAAKQGDQWVQLFQRFREAIDKGDKDSLEQLLEELEQALQKIRELAEKKN',
-                    'modifications': [],
-                    'unpairedMsa': None,
-                    'pairedMsa': None,
-                }
-            },
-            {'ligand': {'id': 'LL', 'ccdCodes': ['7BU']}},
-        ],
-        'dialect': folding_input.JSON_DIALECT,
-        'version': folding_input.JSON_VERSION,
-    }
-    self._test_input_json = json.dumps(test_input)
-    self._model_config = run_alphafold.make_model_config(
-        return_embeddings=True, flash_attention_implementation='triton'
-    )
-    self._runner = run_alphafold.ModelRunner(
-        config=self._model_config,
-        device=jax.local_devices()[0],
-        model_dir=pathlib.Path(run_alphafold.MODEL_DIR.value),
-    )
-
-  def test_model_inference(self):
-    """Run model inference and assert that output exists."""
-    featurised_examples = pickle.loads(
-        (resources.ROOT / 'test_data' / 'featurised_example.pkl').read_bytes()
-    )
-
-    self.assertLen(featurised_examples, 1)
-    featurised_example = featurised_examples[0]
-    result = self._runner.run_inference(
-        featurised_example, jax.random.PRNGKey(0)
-    )
-    self.assertIsNotNone(result)
-    _, embeddings = self._runner.extract_inference_results_and_maybe_embeddings(
-        batch=featurised_example, result=result, target_name='target'
-    )
-    self.assertLen(embeddings, 2)
-
-  def test_process_fold_input_runs_only_inference(self):
-    with self.assertRaisesRegex(ValueError, 'missing unpaired MSA.'):
-      run_alphafold.process_fold_input(
-          fold_input=folding_input.Input.from_json(self._test_input_json),
-          # No data pipeline config, so featurisation will run first, and fail
-          # since the input is missing MSAs.
-          data_pipeline_config=None,
-          model_runner=self._runner,
-          output_dir=self.create_tempdir().full_path,
-      )
-
-  @parameterized.named_parameters(
-      {
-          'testcase_name': 'default_bucket',
-          'bucket': None,
-          'seed': 1,
-      },
-      {
-          'testcase_name': 'bucket_1024',
-          'bucket': 1024,
-          'seed': 42,
-      },
-  )
-  def test_inference(self, bucket, seed):
-    """Run AlphaFold 3 inference."""
-
-    ### Prepare inputs with modified seed.
-    fold_input = folding_input.Input.from_json(self._test_input_json)
-    fold_input = dataclasses.replace(fold_input, rng_seeds=[seed])
-
-    output_dir = self.create_tempdir().full_path
-    actual = run_alphafold.process_fold_input(
-        fold_input,
-        self._data_pipeline_config,
-        run_alphafold.ModelRunner(
-            config=self._model_config,
-            device=jax.local_devices(backend='gpu')[0],
-            model_dir=pathlib.Path(run_alphafold.MODEL_DIR.value),
-        ),
-        output_dir=output_dir,
-        buckets=None if bucket is None else [bucket],
-    )
-    logging.info('finished get_inference_result')
-    expected_model_cif_filename = f'{fold_input.sanitised_name()}_model.cif'
-    expected_summary_confidences_filename = (
-        f'{fold_input.sanitised_name()}_summary_confidences.json'
-    )
-    expected_confidences_filename = (
-        f'{fold_input.sanitised_name()}_confidences.json'
-    )
-    expected_data_json_filename = f'{fold_input.sanitised_name()}_data.json'
-
-    prefix = f'seed-{seed}'
-    self.assertSameElements(
-        os.listdir(output_dir),
-        [
-            # Subdirectories, one for each sample and one for embeddings.
-            f'{prefix}_sample-0',
-            f'{prefix}_sample-1',
-            f'{prefix}_sample-2',
-            f'{prefix}_sample-3',
-            f'{prefix}_sample-4',
-            f'{prefix}_embeddings',
-            # Top ranking result.
-            expected_confidences_filename,
-            expected_model_cif_filename,
-            expected_summary_confidences_filename,
-            # Ranking scores for all samples.
-            f'{fold_input.sanitised_name()}_ranking_scores.csv',
-            # The input JSON defining the job.
-            expected_data_json_filename,
-            # The output terms of use.
-            'TERMS_OF_USE.md',
-        ],
-    )
-
-    for sample_index in range(5):
-      sample_dir = os.path.join(output_dir, f'{prefix}_sample-{sample_index}')
-      sample_prefix = (
-          f'{fold_input.sanitised_name()}_seed-{seed}_sample-{sample_index}'
-      )
-      self.assertSameElements(
-          os.listdir(sample_dir),
-          [
-              f'{sample_prefix}_confidences.json',
-              f'{sample_prefix}_model.cif',
-              f'{sample_prefix}_summary_confidences.json',
-          ],
-      )
-
-    embeddings_dir = os.path.join(output_dir, f'{prefix}_embeddings')
-    embeddings_filename = (
-        f'{fold_input.sanitised_name()}_{prefix}_embeddings.npz'
-    )
-    self.assertSameElements(os.listdir(embeddings_dir), [embeddings_filename])
-
-    with open(os.path.join(embeddings_dir, embeddings_filename), 'rb') as f:
-      embeddings = np.load(f)
-      self.assertSameElements(
-          embeddings.keys(), ['single_embeddings', 'pair_embeddings']
-      )
-      # Ligand 7BU has 41 tokens.
-      num_tokens = len(fold_input.protein_chains[0].sequence) + 41
-      self.assertEqual(embeddings['single_embeddings'].shape, (num_tokens, 384))
-      self.assertEqual(
-          embeddings['pair_embeddings'].shape, (num_tokens, num_tokens, 128)
-      )
-
-    with open(os.path.join(output_dir, expected_data_json_filename), 'rt') as f:
-      actual_input_json = json.load(f)
-
-    self.assertEqual(
-        actual_input_json['sequences'][0]['protein']['sequence'],
-        fold_input.protein_chains[0].sequence,
-    )
-    self.assertSequenceEqual(
-        actual_input_json['sequences'][1]['ligand']['ccdCodes'],
-        fold_input.ligands[0].ccd_ids,
-    )
-    self.assertNotEmpty(
-        actual_input_json['sequences'][0]['protein']['unpairedMsa']
-    )
-    self.assertNotEmpty(
-        actual_input_json['sequences'][0]['protein']['pairedMsa']
-    )
-    self.assertIsNotNone(
-        actual_input_json['sequences'][0]['protein']['templates']
-    )
-
-    ranking_scores_filename = (
-        f'{fold_input.sanitised_name()}_ranking_scores.csv'
-    )
-    with open(os.path.join(output_dir, ranking_scores_filename), 'rt') as f:
-      ranking_scores = list(csv.DictReader(f))
-
-    self.assertLen(ranking_scores, 5)
-    self.assertEqual([int(s['seed']) for s in ranking_scores], [seed] * 5)
-    self.assertEqual(
-        [int(s['sample']) for s in ranking_scores], [0, 1, 2, 3, 4]
-    )
-
-    # Ranking score should be between 0.66 and 0.76 for all samples.
-    ranking_scores = [float(s['ranking_score']) for s in ranking_scores]
-    scores_ok = [0.66 <= score <= 0.76 for score in ranking_scores]
-    if not all(scores_ok):
-      self.fail(f'{ranking_scores=} are not in expected range [0.66, 0.76]')
-
-    with open(os.path.join(output_dir, 'TERMS_OF_USE.md'), 'rt') as f:
-      actual_terms_of_use = f.read()
-    self.assertStartsWith(
-        actual_terms_of_use, '# ALPHAFOLD 3 OUTPUT TERMS OF USE'
-    )
-
-    bucket_label = 'default' if bucket is None else bucket
-    output_filename = f'run_alphafold_test_output_bucket_{bucket_label}.pkl'
-
-    # Convert to dict to enable simple serialization.
-    actual_dict = [
-        dict(
-            seed=actual_inf.seed,
-            inference_results=actual_inf.inference_results,
-            full_fold_input=actual_inf.full_fold_input,
-        )
-        for actual_inf in actual
-    ]
-    with _output(output_filename) as (_, output):
-      output.write(pickle.dumps(actual_dict))
-
-    logging.info('Comparing inference results with expected values.')
-
-    ### Assert that output is as expected.
-    expected_dict = pickle.loads(
-        (
-            resources.ROOT
-            / 'test_data'
-            / 'alphafold_run_outputs'
-            / output_filename
-        ).read_bytes()
-    )
-    expected = [
-        run_alphafold.ResultsForSeed(**expected_inf)
-        for expected_inf in expected_dict
-    ]
-
-    actual_rmsds = []
-    mask_proportions = []
-    actual_masked_rmsds = []
-    for actual_inf, expected_inf in zip(actual, expected, strict=True):
-      for actual_inf, expected_inf in zip(
-          actual_inf.inference_results,
-          expected_inf.inference_results,
-          strict=True,
-      ):
-        # Make sure the token chain IDs are the same as the input chain IDs.
-        self.assertEqual(
-            actual_inf.metadata['token_chain_ids'],
-            ['P'] * len(fold_input.protein_chains[0].sequence) + ['LL'] * 41,
-        )
-        # All atom occupancies should be 1.0.
-        np.testing.assert_array_equal(
-            actual_inf.predicted_structure.atom_occupancy,
-            [1.0] * actual_inf.predicted_structure.num_atoms,
-        )
-        actual_rmsds.append(
-            alignment.rmsd_from_coords(
-                decoy_coords=actual_inf.predicted_structure.coords,
-                gt_coords=expected_inf.predicted_structure.coords,
-            )
-        )
-        # Mask out atoms with b_factor < 80.0 (i.e. lower confidence regions).
-        mask = actual_inf.predicted_structure.atom_b_factor > 80.0
-        mask_proportions.append(
-            np.sum(mask) / actual_inf.predicted_structure.num_atoms
-        )
-        actual_masked_rmsds.append(
-            alignment.rmsd_from_coords(
-                decoy_coords=actual_inf.predicted_structure.coords,
-                gt_coords=expected_inf.predicted_structure.coords,
-                include_idxs=mask,
-            )
-        )
-    # 5tgy is stably predicted, samples should be all within 3.0 RMSD
-    # regardless of seed, bucket, device type, etc.
-    if any(rmsd > 3.0 for rmsd in actual_rmsds):
-      self.fail(f'Full RMSD too high: {actual_rmsds=}')
-    # Check proportion of atoms with b_factor > 80 is at least 70%.
-    if any(prop < 0.7 for prop in mask_proportions):
-      self.fail(f'Too many residues with low pLDDT: {mask_proportions=}')
-    # Check masked RMSD is within tolerance (lower than full RMSD due to masking
-    # of lower confidence regions).
-    if any(rmsd > 1.4 for rmsd in actual_masked_rmsds):
-      self.fail(f'Masked RMSD too high: {actual_masked_rmsds=}')
-
-
-if __name__ == '__main__':
-  absltest.main()
diff --git a/src/alphafold3/__init__.py b/src/alphafold3/__init__.py
deleted file mode 100644
index c36629dc32bbfe2b9437994328c50789f66832e4..0000000000000000000000000000000000000000
--- a/src/alphafold3/__init__.py
+++ /dev/null
@@ -1,11 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""An implementation of the inference pipeline of AlphaFold 3."""
diff --git a/src/alphafold3/build_data.py b/src/alphafold3/build_data.py
deleted file mode 100644
index 0c33338a7cfe646cd353ee37023948aeb2496834..0000000000000000000000000000000000000000
--- a/src/alphafold3/build_data.py
+++ /dev/null
@@ -1,40 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Script for building intermediate data."""
-
-from importlib import resources
-import pathlib
-import site
-
-import alphafold3.constants.converters
-from alphafold3.constants.converters import ccd_pickle_gen
-from alphafold3.constants.converters import chemical_component_sets_gen
-
-
-def build_data():
-  """Builds intermediate data."""
-  for site_path in site.getsitepackages():
-    path = pathlib.Path(site_path) / 'share/libcifpp/components.cif'
-    if path.exists():
-      cif_path = path
-      break
-  else:
-    raise ValueError('Could not find components.cif')
-
-  out_root = resources.files(alphafold3.constants.converters)
-  ccd_pickle_path = out_root.joinpath('ccd.pickle')
-  chemical_component_sets_pickle_path = out_root.joinpath(
-      'chemical_component_sets.pickle'
-  )
-  ccd_pickle_gen.main(['', str(cif_path), str(ccd_pickle_path)])
-  chemical_component_sets_gen.main(
-      ['', str(chemical_component_sets_pickle_path)]
-  )
diff --git a/src/alphafold3/common/base_config.py b/src/alphafold3/common/base_config.py
deleted file mode 100644
index 29cc1d860f3f2420338c6e66127eb465be12d232..0000000000000000000000000000000000000000
--- a/src/alphafold3/common/base_config.py
+++ /dev/null
@@ -1,149 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Config for the protein folding model and experiment."""
-
-from collections.abc import Mapping
-import copy
-import dataclasses
-import types
-import typing
-from typing import Any, ClassVar, TypeVar
-
-
-_T = TypeVar('_T')
-_ConfigT = TypeVar('_ConfigT', bound='BaseConfig')
-
-
-def _strip_optional(t: type[Any]) -> type[Any]:
-  """Transforms type annotations of the form `T | None` to `T`."""
-  if typing.get_origin(t) in (typing.Union, types.UnionType):
-    args = set(typing.get_args(t)) - {types.NoneType}
-    if len(args) == 1:
-      return args.pop()
-  return t
-
-
-_NO_UPDATE = object()
-
-
-class _Autocreate:
-
-  def __init__(self, **defaults: Any):
-    self.defaults = defaults
-
-
-def autocreate(**defaults: Any) -> Any:
-  """Marks a field as having a default factory derived from its type."""
-  return _Autocreate(**defaults)
-
-
-def _clone_field(
-    field: dataclasses.Field[_T], new_default: _T
-) -> dataclasses.Field[_T]:
-  if new_default is _NO_UPDATE:
-    return copy.copy(field)
-  return dataclasses.field(
-      default=new_default,
-      init=True,
-      kw_only=True,
-      repr=field.repr,
-      hash=field.hash,
-      compare=field.compare,
-      metadata=field.metadata,
-  )
-
-
-@typing.dataclass_transform()
-class ConfigMeta(type):
-  """Metaclass that synthesizes a __post_init__ that coerces dicts to Config subclass instances."""
-
-  def __new__(mcs, name, bases, classdict):
-    cls = super().__new__(mcs, name, bases, classdict)
-
-    def _coercable_fields(self) -> Mapping[str, tuple[ConfigMeta, Any]]:
-      type_hints = typing.get_type_hints(self.__class__)
-      fields = dataclasses.fields(self.__class__)
-      field_to_type_and_default = {
-          field.name: (_strip_optional(type_hints[field.name]), field.default)
-          for field in fields
-      }
-      coercable_fields = {
-          f: t
-          for f, t in field_to_type_and_default.items()
-          if issubclass(type(t[0]), ConfigMeta)
-      }
-      return coercable_fields
-
-    cls._coercable_fields = property(_coercable_fields)
-
-    old_post_init = getattr(cls, '__post_init__', None)
-
-    def _post_init(self) -> None:
-      # Use get_type_hints instead of Field.type to ensure that forward
-      # references are resolved.
-      for field_name, (
-          field_type,
-          field_default,
-      ) in self._coercable_fields.items():  # pylint: disable=protected-access
-        field_value = getattr(self, field_name)
-        if field_value is None:
-          continue
-        try:
-          match field_value:
-            case _Autocreate():
-              # Construct from field defaults.
-              setattr(self, field_name, field_type(**field_value.defaults))
-            case Mapping():
-              # Field value is not yet a `Config` instance; Assume we can create
-              # one by splatting keys and values.
-              args = {}
-              # Apply default args first, if present.
-              if isinstance(field_default, _Autocreate):
-                args.update(field_default.defaults)
-              args.update(field_value)
-              setattr(self, field_name, field_type(**args))
-            case _:
-              pass
-        except TypeError as e:
-          raise TypeError(
-              f'Failure while coercing field {field_name!r} of'
-              f' {self.__class__.__qualname__}'
-          ) from e
-      if old_post_init:
-        old_post_init(self)
-
-    cls.__post_init__ = _post_init
-
-    return dataclasses.dataclass(kw_only=True)(cls)
-
-
-class BaseConfig(metaclass=ConfigMeta):
-  """Config base class.
-
-  Subclassing Config automatically makes the subclass a kw_only dataclass with
-  a `__post_init__` that coerces Config-subclass field values from mappings to
-  instances of the right type.
-  """
-  # Provided by dataclasses.make_dataclass
-  __dataclass_fields__: ClassVar[dict[str, dataclasses.Field[Any]]]
-
-  # Overridden by metaclass
-  @property
-  def _coercable_fields(self) -> Mapping[str, tuple[type['BaseConfig'], Any]]:
-    return {}
-
-  def as_dict(self) -> Mapping[str, Any]:
-    result = dataclasses.asdict(self)
-    for field_name in self._coercable_fields:
-      field_value = getattr(self, field_name, None)
-      if isinstance(field_value, BaseConfig):
-        result[field_name] = field_value.as_dict()
-    return result
diff --git a/src/alphafold3/common/folding_input.py b/src/alphafold3/common/folding_input.py
deleted file mode 100644
index cf27df99549638d7a50fda02501c40fb78fc7b31..0000000000000000000000000000000000000000
--- a/src/alphafold3/common/folding_input.py
+++ /dev/null
@@ -1,1449 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Model input dataclass."""
-
-from collections.abc import Collection, Iterator, Mapping, Sequence
-import dataclasses
-import gzip
-import json
-import logging
-import lzma
-import os
-import pathlib
-import random
-import re
-import string
-from typing import Any, Final, Self, TypeAlias, cast
-
-from alphafold3 import structure
-from alphafold3.constants import chemical_components
-from alphafold3.constants import mmcif_names
-from alphafold3.constants import residue_names
-from alphafold3.cpp import cif_dict
-from alphafold3.structure import mmcif as mmcif_lib
-import rdkit.Chem as rd_chem
-import zstandard as zstd
-
-
-BondAtomId: TypeAlias = tuple[str, int, str]
-
-JSON_DIALECT: Final[str] = 'alphafold3'
-JSON_VERSIONS: Final[tuple[int, ...]] = (1, 2, 3)
-JSON_VERSION: Final[int] = JSON_VERSIONS[-1]
-
-ALPHAFOLDSERVER_JSON_DIALECT: Final[str] = 'alphafoldserver'
-ALPHAFOLDSERVER_JSON_VERSION: Final[int] = 1
-
-
-def _validate_keys(actual: Collection[str], expected: Collection[str]):
-  """Validates that the JSON doesn't contain any extra unwanted keys."""
-  if bad_keys := set(actual) - set(expected):
-    raise ValueError(f'Unexpected JSON keys in: {", ".join(sorted(bad_keys))}')
-
-
-def _read_file(path: pathlib.Path, json_path: pathlib.Path | None) -> str:
-  """Reads a maybe compressed (gzip, xz, zstd) file from the given path.
-
-  Args:
-    path: The path to the file to read. This can be either absolute path, or a
-      path relative to the JSON file path.
-    json_path: The path to the JSON file. If None, the path must be absolute.
-
-  Returns:
-    The contents of the file.
-  """
-  if not path.is_absolute():
-    if json_path is None:
-      raise ValueError('json_path must be specified if path is not absolute.')
-    path = (json_path.parent / path).resolve()
-
-  with open(path, 'rb') as f:
-    first_six_bytes = f.read(6)
-    f.seek(0)
-
-    # Detect the compression type using the magic number in the header.
-    if first_six_bytes[:2] == b'\x1f\x8b':
-      with gzip.open(f, 'rt') as gzip_f:
-        return cast(str, gzip_f.read())
-    elif first_six_bytes == b'\xfd\x37\x7a\x58\x5a\x00':
-      with lzma.open(f, 'rt') as xz_f:
-        return cast(str, xz_f.read())
-    elif first_six_bytes[:4] == b'\x28\xb5\x2f\xfd':
-      with zstd.open(f, 'rt') as zstd_f:
-        return cast(str, zstd_f.read())
-    else:
-      return f.read().decode('utf-8')
-
-
-class Template:
-  """Structural template input."""
-
-  __slots__ = ('_mmcif', '_query_to_template')
-
-  def __init__(self, *, mmcif: str, query_to_template_map: Mapping[int, int]):
-    """Initializes the template.
-
-    Args:
-      mmcif: The structural template in mmCIF format. The mmCIF should have only
-        one protein chain.
-      query_to_template_map: A mapping from query residue index to template
-        residue index.
-    """
-    self._mmcif = mmcif
-    # Needed to make the Template class hashable.
-    self._query_to_template = tuple(query_to_template_map.items())
-
-  @property
-  def query_to_template_map(self) -> Mapping[int, int]:
-    return dict(self._query_to_template)
-
-  @property
-  def mmcif(self) -> str:
-    return self._mmcif
-
-  def __hash__(self) -> int:
-    return hash((self._mmcif, tuple(sorted(self._query_to_template))))
-
-  def __eq__(self, other: Self) -> bool:
-    mmcifs_equal = self._mmcif == other._mmcif
-    maps_equal = sorted(self._query_to_template) == sorted(
-        other._query_to_template
-    )
-    return mmcifs_equal and maps_equal
-
-
-class ProteinChain:
-  """Protein chain input."""
-
-  __slots__ = (
-      '_id',
-      '_sequence',
-      '_ptms',
-      '_paired_msa',
-      '_unpaired_msa',
-      '_templates',
-  )
-
-  def __init__(
-      self,
-      *,
-      id: str,  # pylint: disable=redefined-builtin
-      sequence: str,
-      ptms: Sequence[tuple[str, int]],
-      paired_msa: str | None = None,
-      unpaired_msa: str | None = None,
-      templates: Sequence[Template] | None = None,
-  ):
-    """Initializes a single protein chain input.
-
-    Args:
-      id: Unique protein chain identifier.
-      sequence: The amino acid sequence of the chain.
-      ptms: A list of tuples containing the post-translational modification type
-        and the (1-based) residue index where the modification is applied.
-      paired_msa: Paired A3M-formatted MSA for this chain. This MSA is not
-        deduplicated and will be used to compute paired features. If None, this
-        field is unset and must be filled in by the data pipeline before
-        featurisation. If set to an empty string, it will be treated as a custom
-        MSA with no sequences.
-      unpaired_msa: Unpaired A3M-formatted MSA for this chain. This will be
-        deduplicated and used to compute unpaired features. If None, this field
-        is unset and must be filled in by the data pipeline before
-        featurisation. If set to an empty string, it will be treated as a custom
-        MSA with no sequences.
-      templates: A list of structural templates for this chain. If None, this
-        field is unset and must be filled in by the data pipeline before
-        featurisation. The list can be empty or contain up to 20 templates.
-    """
-    if not all(res.isalpha() for res in sequence):
-      raise ValueError(f'Protein must contain only letters, got "{sequence}"')
-    if any(not 0 < mod[1] <= len(sequence) for mod in ptms):
-      raise ValueError(f'Invalid protein modification index: {ptms}')
-    if any(mod[0].startswith('CCD_') for mod in ptms):
-      raise ValueError(
-          f'Protein ptms must not contain the "CCD_" prefix, got {ptms}'
-      )
-    # Use hashable containers for ptms and templates.
-    self._id = id
-    self._sequence = sequence
-    self._ptms = tuple(ptms)
-    self._paired_msa = paired_msa
-    self._unpaired_msa = unpaired_msa
-    self._templates = tuple(templates) if templates is not None else None
-
-  @property
-  def id(self) -> str:
-    return self._id
-
-  @property
-  def sequence(self) -> str:
-    """Returns a single-letter sequence, taking modifications into account.
-
-    Uses 'X' for all unknown residues.
-    """
-    return ''.join([
-        residue_names.letters_three_to_one(r, default='X')
-        for r in self.to_ccd_sequence()
-    ])
-
-  @property
-  def ptms(self) -> Sequence[tuple[str, int]]:
-    return self._ptms
-
-  @property
-  def paired_msa(self) -> str | None:
-    return self._paired_msa
-
-  @property
-  def unpaired_msa(self) -> str | None:
-    return self._unpaired_msa
-
-  @property
-  def templates(self) -> Sequence[Template] | None:
-    return self._templates
-
-  def __len__(self) -> int:
-    return len(self._sequence)
-
-  def __eq__(self, other: Self) -> bool:
-    return (
-        self._id == other._id
-        and self._sequence == other._sequence
-        and self._ptms == other._ptms
-        and self._paired_msa == other._paired_msa
-        and self._unpaired_msa == other._unpaired_msa
-        and self._templates == other._templates
-    )
-
-  def __hash__(self) -> int:
-    return hash((
-        self._id,
-        self._sequence,
-        self._ptms,
-        self._paired_msa,
-        self._unpaired_msa,
-        self._templates,
-    ))
-
-  def hash_without_id(self) -> int:
-    """Returns a hash ignoring the ID - useful for deduplication."""
-    return hash((
-        self._sequence,
-        self._ptms,
-        self._paired_msa,
-        self._unpaired_msa,
-        self._templates,
-    ))
-
-  @classmethod
-  def from_alphafoldserver_dict(
-      cls, json_dict: Mapping[str, Any], seq_id: str
-  ) -> Self:
-    """Constructs ProteinChain from the AlphaFoldServer JSON dict."""
-    _validate_keys(
-        json_dict.keys(),
-        {
-            'sequence',
-            'glycans',
-            'modifications',
-            'count',
-            'maxTemplateDate',
-            'useStructureTemplate',
-        },
-    )
-    sequence = json_dict['sequence']
-
-    if 'glycans' in json_dict:
-      raise ValueError(
-          f'Specifying glycans in the `{ALPHAFOLDSERVER_JSON_DIALECT}` format'
-          ' is not supported.'
-      )
-
-    if 'maxTemplateDate' in json_dict:
-      raise ValueError(
-          f'Specifying maxTemplateDate in the `{ALPHAFOLDSERVER_JSON_DIALECT}`'
-          ' format is not supported, use the --max_template_date flag instead.'
-      )
-
-    templates = None  # Search for templates unless explicitly disabled.
-    if not json_dict.get('useStructureTemplate', True):
-      templates = []  # Do not use any templates.
-
-    ptms = [
-        (mod['ptmType'].removeprefix('CCD_'), mod['ptmPosition'])
-        for mod in json_dict.get('modifications', [])
-    ]
-    return cls(id=seq_id, sequence=sequence, ptms=ptms, templates=templates)
-
-  @classmethod
-  def from_dict(
-      cls,
-      json_dict: Mapping[str, Any],
-      json_path: pathlib.Path | None = None,
-      seq_id: str | None = None,
-  ) -> Self:
-    """Constructs ProteinChain from the AlphaFold JSON dict."""
-    json_dict = json_dict['protein']
-    _validate_keys(
-        json_dict.keys(),
-        {
-            'id',
-            'sequence',
-            'modifications',
-            'unpairedMsa',
-            'unpairedMsaPath',
-            'pairedMsa',
-            'pairedMsaPath',
-            'templates',
-        },
-    )
-
-    sequence = json_dict['sequence']
-    ptms = [
-        (mod['ptmType'], mod['ptmPosition'])
-        for mod in json_dict.get('modifications', [])
-    ]
-
-    unpaired_msa = json_dict.get('unpairedMsa', None)
-    unpaired_msa_path = json_dict.get('unpairedMsaPath', None)
-    if unpaired_msa and unpaired_msa_path:
-      raise ValueError('Only one of unpairedMsa/unpairedMsaPath can be set.')
-    if (
-        unpaired_msa
-        and len(unpaired_msa) < 256
-        and os.path.exists(unpaired_msa)
-    ):
-      raise ValueError(
-          'Set the unpaired MSA path using the "unpairedMsaPath" field.'
-      )
-    elif unpaired_msa_path:
-      unpaired_msa = _read_file(pathlib.Path(unpaired_msa_path), json_path)
-
-    paired_msa = json_dict.get('pairedMsa', None)
-    paired_msa_path = json_dict.get('pairedMsaPath', None)
-    if paired_msa and paired_msa_path:
-      raise ValueError('Only one of pairedMsa/pairedMsaPath can be set.')
-    if paired_msa and len(paired_msa) < 256 and os.path.exists(paired_msa):
-      raise ValueError(
-          'Set the paired MSA path using the "pairedMsaPath" field.'
-      )
-    elif paired_msa_path:
-      paired_msa = _read_file(pathlib.Path(paired_msa_path), json_path)
-
-    raw_templates = json_dict.get('templates', None)
-
-    if raw_templates is None:
-      templates = None
-    else:
-      templates = []
-      for raw_template in raw_templates:
-        mmcif = raw_template.get('mmcif', None)
-        mmcif_path = raw_template.get('mmcifPath', None)
-        if mmcif and mmcif_path:
-          raise ValueError('Only one of mmcif/mmcifPath can be set.')
-        if mmcif and len(mmcif) < 256 and os.path.exists(mmcif):
-          raise ValueError('Set the template path using the "mmcifPath" field.')
-        if mmcif_path:
-          mmcif = _read_file(pathlib.Path(mmcif_path), json_path)
-        query_to_template_map = dict(
-            zip(raw_template['queryIndices'], raw_template['templateIndices'])
-        )
-        templates.append(
-            Template(mmcif=mmcif, query_to_template_map=query_to_template_map)
-        )
-
-    return cls(
-        id=seq_id or json_dict['id'],
-        sequence=sequence,
-        ptms=ptms,
-        paired_msa=paired_msa,
-        unpaired_msa=unpaired_msa,
-        templates=templates,
-    )
-
-  def to_dict(
-      self, seq_id: str | Sequence[str] | None = None
-  ) -> Mapping[str, Mapping[str, Any]]:
-    """Converts ProteinChain to an AlphaFold JSON dict."""
-    if self._templates is None:
-      templates = None
-    else:
-      templates = [
-          {
-              'mmcif': template.mmcif,
-              'queryIndices': list(template.query_to_template_map.keys()),
-              'templateIndices': (
-                  list(template.query_to_template_map.values()) or None
-              ),
-          }
-          for template in self._templates
-      ]
-    contents = {
-        'id': seq_id or self._id,
-        'sequence': self._sequence,
-        'modifications': [
-            {'ptmType': ptm[0], 'ptmPosition': ptm[1]} for ptm in self._ptms
-        ],
-        'unpairedMsa': self._unpaired_msa,
-        'pairedMsa': self._paired_msa,
-        'templates': templates,
-    }
-    return {'protein': contents}
-
-  def to_ccd_sequence(self) -> Sequence[str]:
-    """Converts to a sequence of CCD codes."""
-    ccd_coded_seq = [
-        residue_names.PROTEIN_COMMON_ONE_TO_THREE.get(res, residue_names.UNK)
-        for res in self._sequence
-    ]
-    for ptm_code, ptm_index in self._ptms:
-      ccd_coded_seq[ptm_index - 1] = ptm_code
-    return ccd_coded_seq
-
-  def fill_missing_fields(self) -> Self:
-    """Fill missing MSA and template fields with default values."""
-    return ProteinChain(
-        id=self.id,
-        sequence=self._sequence,
-        ptms=self._ptms,
-        unpaired_msa=self._unpaired_msa or '',
-        paired_msa=self._paired_msa or '',
-        templates=self._templates or [],
-    )
-
-
-class RnaChain:
-  """RNA chain input."""
-
-  __slots__ = ('_id', '_sequence', '_modifications', '_unpaired_msa')
-
-  def __init__(
-      self,
-      *,
-      id: str,  # pylint: disable=redefined-builtin
-      sequence: str,
-      modifications: Sequence[tuple[str, int]],
-      unpaired_msa: str | None = None,
-  ):
-    """Initializes a single strand RNA chain input.
-
-    Args:
-      id: Unique RNA chain identifier.
-      sequence: The RNA sequence of the chain.
-      modifications: A list of tuples containing the modification type and the
-        (1-based) residue index where the modification is applied.
-      unpaired_msa: Unpaired A3M-formatted MSA for this chain. This will be
-        deduplicated and used to compute unpaired features. If None, this field
-        is unset and must be filled in by the data pipeline before
-        featurisation. If set to an empty string, it will be treated as a custom
-        MSA with no sequences.
-    """
-    if not all(res.isalpha() for res in sequence):
-      raise ValueError(f'RNA must contain only letters, got "{sequence}"')
-    if any(not 0 < mod[1] <= len(sequence) for mod in modifications):
-      raise ValueError(f'Invalid RNA modification index: {modifications}')
-    if any(mod[0].startswith('CCD_') for mod in modifications):
-      raise ValueError(
-          'RNA modifications must not contain the "CCD_" prefix, got'
-          f' {modifications}'
-      )
-    self._id = id
-    self._sequence = sequence
-    # Use hashable container for modifications.
-    self._modifications = tuple(modifications)
-    self._unpaired_msa = unpaired_msa
-
-  @property
-  def id(self) -> str:
-    return self._id
-
-  @property
-  def sequence(self) -> str:
-    """Returns a single-letter sequence, taking modifications into account.
-
-    Uses 'N' for all unknown residues.
-    """
-    return ''.join([
-        residue_names.letters_three_to_one(r, default='N')
-        for r in self.to_ccd_sequence()
-    ])
-
-  @property
-  def modifications(self) -> Sequence[tuple[str, int]]:
-    return self._modifications
-
-  @property
-  def unpaired_msa(self) -> str | None:
-    return self._unpaired_msa
-
-  def __len__(self) -> int:
-    return len(self._sequence)
-
-  def __eq__(self, other: Self) -> bool:
-    return (
-        self._id == other._id
-        and self._sequence == other._sequence
-        and self._modifications == other._modifications
-        and self._unpaired_msa == other._unpaired_msa
-    )
-
-  def __hash__(self) -> int:
-    return hash(
-        (self._id, self._sequence, self._modifications, self._unpaired_msa)
-    )
-
-  def hash_without_id(self) -> int:
-    """Returns a hash ignoring the ID - useful for deduplication."""
-    return hash((self._sequence, self._modifications, self._unpaired_msa))
-
-  @classmethod
-  def from_alphafoldserver_dict(
-      cls, json_dict: Mapping[str, Any], seq_id: str
-  ) -> Self:
-    """Constructs RnaChain from the AlphaFoldServer JSON dict."""
-    _validate_keys(json_dict.keys(), {'sequence', 'modifications', 'count'})
-    sequence = json_dict['sequence']
-    modifications = [
-        (mod['modificationType'].removeprefix('CCD_'), mod['basePosition'])
-        for mod in json_dict.get('modifications', [])
-    ]
-    return cls(id=seq_id, sequence=sequence, modifications=modifications)
-
-  @classmethod
-  def from_dict(
-      cls,
-      json_dict: Mapping[str, Any],
-      json_path: pathlib.Path | None = None,
-      seq_id: str | None = None,
-  ) -> Self:
-    """Constructs RnaChain from the AlphaFold JSON dict."""
-    json_dict = json_dict['rna']
-    _validate_keys(
-        json_dict.keys(),
-        {'id', 'sequence', 'unpairedMsa', 'unpairedMsaPath', 'modifications'},
-    )
-    sequence = json_dict['sequence']
-    modifications = [
-        (mod['modificationType'], mod['basePosition'])
-        for mod in json_dict.get('modifications', [])
-    ]
-
-    unpaired_msa = json_dict.get('unpairedMsa', None)
-    unpaired_msa_path = json_dict.get('unpairedMsaPath', None)
-    if unpaired_msa and unpaired_msa_path:
-      raise ValueError('Only one of unpairedMsa/unpairedMsaPath can be set.')
-    if (
-        unpaired_msa
-        and len(unpaired_msa) < 256
-        and os.path.exists(unpaired_msa)
-    ):
-      raise ValueError(
-          'Set the unpaired MSA path using the "unpairedMsaPath" field.'
-      )
-    elif unpaired_msa_path:
-      unpaired_msa = _read_file(pathlib.Path(unpaired_msa_path), json_path)
-
-    return cls(
-        id=seq_id or json_dict['id'],
-        sequence=sequence,
-        modifications=modifications,
-        unpaired_msa=unpaired_msa,
-    )
-
-  def to_dict(
-      self, seq_id: str | Sequence[str] | None = None
-  ) -> Mapping[str, Mapping[str, Any]]:
-    """Converts RnaChain to an AlphaFold JSON dict."""
-    contents = {
-        'id': seq_id or self._id,
-        'sequence': self._sequence,
-        'modifications': [
-            {'modificationType': mod[0], 'basePosition': mod[1]}
-            for mod in self._modifications
-        ],
-        'unpairedMsa': self._unpaired_msa,
-    }
-    return {'rna': contents}
-
-  def to_ccd_sequence(self) -> Sequence[str]:
-    """Converts to a sequence of CCD codes."""
-    mapping = {r: r for r in residue_names.RNA_TYPES}  # Same 1-letter and CCD.
-    ccd_coded_seq = [
-        mapping.get(res, residue_names.UNK_RNA) for res in self._sequence
-    ]
-    for ccd_code, modification_index in self._modifications:
-      ccd_coded_seq[modification_index - 1] = ccd_code
-    return ccd_coded_seq
-
-  def fill_missing_fields(self) -> Self:
-    """Fill missing MSA fields with default values."""
-    return RnaChain(
-        id=self.id,
-        sequence=self.sequence,
-        modifications=self.modifications,
-        unpaired_msa=self._unpaired_msa or '',
-    )
-
-
-class DnaChain:
-  """Single strand DNA chain input."""
-
-  __slots__ = ('_id', '_sequence', '_modifications')
-
-  def __init__(
-      self,
-      *,
-      id: str,  # pylint: disable=redefined-builtin
-      sequence: str,
-      modifications: Sequence[tuple[str, int]],
-  ):
-    """Initializes a single strand DNA chain input.
-
-    Args:
-      id: Unique DNA chain identifier.
-      sequence: The DNA sequence of the chain.
-      modifications: A list of tuples containing the modification type and the
-        (1-based) residue index where the modification is applied.
-    """
-    if not all(res.isalpha() for res in sequence):
-      raise ValueError(f'DNA must contain only letters, got "{sequence}"')
-    if any(not 0 < mod[1] <= len(sequence) for mod in modifications):
-      raise ValueError(f'Invalid DNA modification index: {modifications}')
-    if any(mod[0].startswith('CCD_') for mod in modifications):
-      raise ValueError(
-          'DNA modifications must not contain the "CCD_" prefix, got'
-          f' {modifications}'
-      )
-    self._id = id
-    self._sequence = sequence
-    # Use hashable container for modifications.
-    self._modifications = tuple(modifications)
-
-  @property
-  def id(self) -> str:
-    return self._id
-
-  @property
-  def sequence(self) -> str:
-    """Returns a single-letter sequence, taking modifications into account.
-
-    Uses 'N' for all unknown residues.
-    """
-    return ''.join([
-        residue_names.letters_three_to_one(r, default='N')
-        for r in self.to_ccd_sequence()
-    ])
-
-  def __len__(self) -> int:
-    return len(self._sequence)
-
-  def __eq__(self, other: Self) -> bool:
-    return (
-        self._id == other._id
-        and self._sequence == other._sequence
-        and self._modifications == other._modifications
-    )
-
-  def __hash__(self) -> int:
-    return hash((self._id, self._sequence, self._modifications))
-
-  def modifications(self) -> Sequence[tuple[str, int]]:
-    return self._modifications
-
-  def hash_without_id(self) -> int:
-    """Returns a hash ignoring the ID - useful for deduplication."""
-    return hash((self._sequence, self._modifications))
-
-  @classmethod
-  def from_alphafoldserver_dict(
-      cls, json_dict: Mapping[str, Any], seq_id: str
-  ) -> Self:
-    """Constructs DnaChain from the AlphaFoldServer JSON dict."""
-    _validate_keys(json_dict.keys(), {'sequence', 'modifications', 'count'})
-    sequence = json_dict['sequence']
-    modifications = [
-        (mod['modificationType'].removeprefix('CCD_'), mod['basePosition'])
-        for mod in json_dict.get('modifications', [])
-    ]
-    return cls(id=seq_id, sequence=sequence, modifications=modifications)
-
-  @classmethod
-  def from_dict(
-      cls, json_dict: Mapping[str, Any], seq_id: str | None = None
-  ) -> Self:
-    """Constructs DnaChain from the AlphaFold JSON dict."""
-    json_dict = json_dict['dna']
-    _validate_keys(json_dict.keys(), {'id', 'sequence', 'modifications'})
-    sequence = json_dict['sequence']
-    modifications = [
-        (mod['modificationType'], mod['basePosition'])
-        for mod in json_dict.get('modifications', [])
-    ]
-    return cls(
-        id=seq_id or json_dict['id'],
-        sequence=sequence,
-        modifications=modifications,
-    )
-
-  def to_dict(
-      self, seq_id: str | Sequence[str] | None = None
-  ) -> Mapping[str, Mapping[str, Any]]:
-    """Converts DnaChain to an AlphaFold JSON dict."""
-    contents = {
-        'id': seq_id or self._id,
-        'sequence': self._sequence,
-        'modifications': [
-            {'modificationType': mod[0], 'basePosition': mod[1]}
-            for mod in self._modifications
-        ],
-    }
-    return {'dna': contents}
-
-  def to_ccd_sequence(self) -> Sequence[str]:
-    """Converts to a sequence of CCD codes."""
-    ccd_coded_seq = [
-        residue_names.DNA_COMMON_ONE_TO_TWO.get(res, residue_names.UNK_DNA)
-        for res in self._sequence
-    ]
-    for ccd_code, modification_index in self._modifications:
-      ccd_coded_seq[modification_index - 1] = ccd_code
-    return ccd_coded_seq
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class Ligand:
-  """Ligand input.
-
-  Attributes:
-    id: Unique ligand "chain" identifier.
-    ccd_ids: The Chemical Component Dictionary or user-defined CCD IDs of the
-      chemical components of the ligand. Typically, this is just a single ID,
-      but some ligands are composed of multiple components. If that is the case,
-      a bond linking these components should be added to the bonded_atom_pairs
-      Input field.
-    smiles: The SMILES representation of the ligand.
-  """
-
-  id: str
-  ccd_ids: Sequence[str] | None = None
-  smiles: str | None = None
-
-  def __post_init__(self):
-    if (self.ccd_ids is None) == (self.smiles is None):
-      raise ValueError('Ligand must have one of CCD ID or SMILES set.')
-
-    if self.smiles is not None:
-      mol = rd_chem.MolFromSmiles(self.smiles)
-      if not mol:
-        raise ValueError(f'Unable to make RDKit Mol from SMILES: {self.smiles}')
-
-    # Use hashable types for ccd_ids.
-    if self.ccd_ids is not None:
-      object.__setattr__(self, 'ccd_ids', tuple(self.ccd_ids))
-
-  def __len__(self) -> int:
-    if self.ccd_ids is not None:
-      return len(self.ccd_ids)
-    else:
-      return 1
-
-  def hash_without_id(self) -> int:
-    """Returns a hash ignoring the ID - useful for deduplication."""
-    return hash((self.ccd_ids, self.smiles))
-
-  @classmethod
-  def from_alphafoldserver_dict(
-      cls, json_dict: Mapping[str, Any], seq_id: str
-  ) -> Self:
-    """Constructs Ligand from the AlphaFoldServer JSON dict."""
-    # Ligand can be specified either as a ligand, or ion (special-case).
-    _validate_keys(json_dict.keys(), {'ligand', 'ion', 'count'})
-    if 'ligand' in json_dict:
-      return cls(id=seq_id, ccd_ids=[json_dict['ligand'].removeprefix('CCD_')])
-    elif 'ion' in json_dict:
-      return cls(id=seq_id, ccd_ids=[json_dict['ion']])
-    else:
-      raise ValueError(f'Unknown ligand type: {json_dict}')
-
-  @classmethod
-  def from_dict(
-      cls, json_dict: Mapping[str, Any], seq_id: str | None = None
-  ) -> Self:
-    """Constructs Ligand from the AlphaFold JSON dict."""
-    json_dict = json_dict['ligand']
-    _validate_keys(json_dict.keys(), {'id', 'ccdCodes', 'smiles'})
-    if json_dict.get('ccdCodes') and json_dict.get('smiles'):
-      raise ValueError(
-          'Ligand cannot have both CCD code and SMILES set at the same time, '
-          f'got CCD: {json_dict["ccdCode"]} and SMILES: {json_dict["smiles"]}'
-      )
-
-    if 'ccdCodes' in json_dict:
-      return cls(id=seq_id or json_dict['id'], ccd_ids=json_dict['ccdCodes'])
-    elif 'smiles' in json_dict:
-      return cls(id=seq_id or json_dict['id'], smiles=json_dict['smiles'])
-    else:
-      raise ValueError(f'Unknown ligand type: {json_dict}')
-
-  def to_dict(
-      self, seq_id: str | Sequence[str] | None = None
-  ) -> Mapping[str, Mapping[str, Any]]:
-    """Converts Ligand to an AlphaFold JSON dict."""
-    contents = {'id': seq_id or self.id}
-    if self.ccd_ids is not None:
-      contents['ccdCodes'] = self.ccd_ids
-    if self.smiles is not None:
-      contents['smiles'] = self.smiles
-    return {'ligand': contents}
-
-
-def _sample_rng_seed() -> int:
-  """Sample a random seed for AlphaFoldServer job."""
-  # See https://alphafoldserver.com/faq#what-are-seeds-and-how-are-they-set.
-  return random.randint(0, 2**32 - 1)
-
-
-def _validate_user_ccd_keys(keys: Sequence[str], component_name: str) -> None:
-  """Validates the keys of the user-defined CCD dictionary."""
-  mandatory_keys = (
-      '_chem_comp.id',
-      '_chem_comp.name',
-      '_chem_comp.type',
-      '_chem_comp.formula',
-      '_chem_comp.mon_nstd_parent_comp_id',
-      '_chem_comp.pdbx_synonyms',
-      '_chem_comp.formula_weight',
-      '_chem_comp_atom.comp_id',
-      '_chem_comp_atom.atom_id',
-      '_chem_comp_atom.type_symbol',
-      '_chem_comp_atom.charge',
-      '_chem_comp_atom.pdbx_model_Cartn_x_ideal',
-      '_chem_comp_atom.pdbx_model_Cartn_y_ideal',
-      '_chem_comp_atom.pdbx_model_Cartn_z_ideal',
-      '_chem_comp_bond.atom_id_1',
-      '_chem_comp_bond.atom_id_2',
-      '_chem_comp_bond.value_order',
-      '_chem_comp_bond.pdbx_aromatic_flag',
-  )
-  if missing_keys := set(mandatory_keys) - set(keys):
-    raise ValueError(
-        f'Component {component_name} in the user-defined CCD is missing these'
-        f' keys: {missing_keys}'
-    )
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class Input:
-  """AlphaFold input.
-
-  Attributes:
-    name: The name of the target.
-    chains: Protein chains, RNA chains, DNA chains, or ligands.
-    protein_chains: Protein chains.
-    rna_chains: RNA chains.
-    dna_chains: Single strand DNA chains.
-    ligands: Ligand (including ion) inputs.
-    rng_seeds: Random number generator seeds, one for each model execution.
-    bonded_atom_pairs: A list of tuples of atoms that are bonded to each other.
-      Each atom is defined by a tuple of (chain_id, res_id, atom_name). Chain
-      IDs must be set if there are any bonded atoms. Residue IDs are 1-indexed.
-      Atoms in ligands defined by SMILES can't be bonded since SMILES doesn't
-      define unique atom names.
-    user_ccd: Optional user-defined chemical component dictionary in the CIF
-      format. This can be used to provide additional CCD entries that are not
-      present in the default CCD and thus define arbitrary new ligands. This is
-      more expressive than SMILES since it allows to name all atoms within the
-      ligand which in turn makes it possible to define bonds using those atoms.
-  """
-
-  name: str
-  chains: Sequence[ProteinChain | RnaChain | DnaChain | Ligand]
-  rng_seeds: Sequence[int]
-  bonded_atom_pairs: Sequence[tuple[BondAtomId, BondAtomId]] | None = None
-  user_ccd: str | None = None
-
-  def __post_init__(self):
-    if not self.rng_seeds:
-      raise ValueError('Input must have at least one RNG seed.')
-
-    if not self.name.strip() or not self.sanitised_name():
-      raise ValueError(
-          'Input name must be non-empty and contain at least one valid'
-          ' character (letters, numbers, dots, dashes, underscores).'
-      )
-
-    chain_ids = [c.id for c in self.chains]
-    if any(not c.id.isalpha() or c.id.islower() for c in self.chains):
-      raise ValueError(f'IDs must be upper case letters, got: {chain_ids}')
-    if len(set(chain_ids)) != len(chain_ids):
-      raise ValueError('Input JSON contains sequences with duplicate IDs.')
-
-    # Use hashable types for chains, rng_seeds, and bonded_atom_pairs.
-    object.__setattr__(self, 'chains', tuple(self.chains))
-    object.__setattr__(self, 'rng_seeds', tuple(self.rng_seeds))
-    if self.bonded_atom_pairs is not None:
-      object.__setattr__(
-          self, 'bonded_atom_pairs', tuple(self.bonded_atom_pairs)
-      )
-
-    if self.user_ccd is not None:
-      for component_name, component_cif in cif_dict.parse_multi_data_cif(
-          self.user_ccd
-      ).items():
-        _validate_user_ccd_keys(component_cif.keys(), component_name)
-
-  @property
-  def protein_chains(self) -> Sequence[ProteinChain]:
-    return [chain for chain in self.chains if isinstance(chain, ProteinChain)]
-
-  @property
-  def rna_chains(self) -> Sequence[RnaChain]:
-    return [chain for chain in self.chains if isinstance(chain, RnaChain)]
-
-  @property
-  def dna_chains(self) -> Sequence[DnaChain]:
-    return [chain for chain in self.chains if isinstance(chain, DnaChain)]
-
-  @property
-  def ligands(self) -> Sequence[Ligand]:
-    return [chain for chain in self.chains if isinstance(chain, Ligand)]
-
-  def sanitised_name(self) -> str:
-    """Returns sanitised version of the name that can be used as a filename."""
-    lower_spaceless_name = self.name.lower().replace(' ', '_')
-    allowed_chars = set(string.ascii_lowercase + string.digits + '_-.')
-    return ''.join(l for l in lower_spaceless_name if l in allowed_chars)
-
-  @classmethod
-  def from_alphafoldserver_fold_job(cls, fold_job: Mapping[str, Any]) -> Self:
-    """Constructs Input from an AlphaFoldServer fold job."""
-
-    # Validate the fold job has the correct format.
-    _validate_keys(
-        fold_job.keys(),
-        {'name', 'modelSeeds', 'sequences', 'dialect', 'version'},
-    )
-    if 'dialect' not in fold_job and 'version' not in fold_job:
-      dialect = ALPHAFOLDSERVER_JSON_DIALECT
-      version = ALPHAFOLDSERVER_JSON_VERSION
-    elif 'dialect' in fold_job and 'version' in fold_job:
-      dialect = fold_job['dialect']
-      version = fold_job['version']
-    else:
-      raise ValueError(
-          'AlphaFold Server input JSON must either contain both `dialect` and'
-          ' `version` fields, or neither. If neither is specified, it is'
-          f' assumed that `dialect="{ALPHAFOLDSERVER_JSON_DIALECT}"` and'
-          f' `version="{ALPHAFOLDSERVER_JSON_VERSION}"`.'
-      )
-
-    if dialect != ALPHAFOLDSERVER_JSON_DIALECT:
-      raise ValueError(
-          f'AlphaFold Server input JSON has unsupported dialect: {dialect}, '
-          f'expected {ALPHAFOLDSERVER_JSON_DIALECT}.'
-      )
-
-    # For now, there is only one AlphaFold Server JSON version.
-    if version != ALPHAFOLDSERVER_JSON_VERSION:
-      raise ValueError(
-          f'AlphaFold Server input JSON has unsupported version: {version}, '
-          f'expected {ALPHAFOLDSERVER_JSON_VERSION}.'
-      )
-
-    # Parse the chains.
-    chains = []
-    for sequence in fold_job['sequences']:
-      if 'proteinChain' in sequence:
-        for _ in range(sequence['proteinChain'].get('count', 1)):
-          chains.append(
-              ProteinChain.from_alphafoldserver_dict(
-                  sequence['proteinChain'],
-                  seq_id=mmcif_lib.int_id_to_str_id(len(chains) + 1),
-              )
-          )
-      elif 'rnaSequence' in sequence:
-        for _ in range(sequence['rnaSequence'].get('count', 1)):
-          chains.append(
-              RnaChain.from_alphafoldserver_dict(
-                  sequence['rnaSequence'],
-                  seq_id=mmcif_lib.int_id_to_str_id(len(chains) + 1),
-              )
-          )
-      elif 'dnaSequence' in sequence:
-        for _ in range(sequence['dnaSequence'].get('count', 1)):
-          chains.append(
-              DnaChain.from_alphafoldserver_dict(
-                  sequence['dnaSequence'],
-                  seq_id=mmcif_lib.int_id_to_str_id(len(chains) + 1),
-              )
-          )
-      elif 'ion' in sequence:
-        for _ in range(sequence['ion'].get('count', 1)):
-          chains.append(
-              Ligand.from_alphafoldserver_dict(
-                  sequence['ion'],
-                  seq_id=mmcif_lib.int_id_to_str_id(len(chains) + 1),
-              )
-          )
-      elif 'ligand' in sequence:
-        for _ in range(sequence['ligand'].get('count', 1)):
-          chains.append(
-              Ligand.from_alphafoldserver_dict(
-                  sequence['ligand'],
-                  seq_id=mmcif_lib.int_id_to_str_id(len(chains) + 1),
-              )
-          )
-      else:
-        raise ValueError(f'Unknown sequence type: {sequence}')
-
-    if 'modelSeeds' in fold_job and fold_job['modelSeeds']:
-      rng_seeds = [int(seed) for seed in fold_job['modelSeeds']]
-    else:
-      rng_seeds = [_sample_rng_seed()]
-
-    return cls(name=fold_job['name'], chains=chains, rng_seeds=rng_seeds)
-
-  @classmethod
-  def from_json(
-      cls, json_str: str, json_path: pathlib.Path | None = None
-  ) -> Self:
-    """Loads the input from the AlphaFold JSON string."""
-    raw_json = json.loads(json_str)
-
-    _validate_keys(
-        raw_json.keys(),
-        {
-            'dialect',
-            'version',
-            'name',
-            'modelSeeds',
-            'sequences',
-            'bondedAtomPairs',
-            'userCCD',
-            'userCCDPath',
-        },
-    )
-
-    if 'dialect' not in raw_json or 'version' not in raw_json:
-      raise ValueError(
-          'AlphaFold 3 input JSON must contain `dialect` and `version` fields.'
-      )
-
-    if raw_json['dialect'] != JSON_DIALECT:
-      raise ValueError(
-          'AlphaFold 3 input JSON has unsupported dialect:'
-          f' {raw_json["dialect"]}, expected {JSON_DIALECT}.'
-      )
-
-    if raw_json['version'] not in JSON_VERSIONS:
-      raise ValueError(
-          'AlphaFold 3 input JSON has unsupported version:'
-          f' {raw_json["version"]}, expected one of {JSON_VERSIONS}.'
-      )
-
-    if 'sequences' not in raw_json:
-      raise ValueError('AlphaFold 3 input JSON does not contain any sequences.')
-
-    if 'modelSeeds' not in raw_json or not raw_json['modelSeeds']:
-      raise ValueError(
-          'AlphaFold 3 input JSON must specify at least one rng seed in'
-          ' `modelSeeds`.'
-      )
-
-    sequences = raw_json['sequences']
-
-    # Make sure sequence IDs are all set.
-    raw_sequence_ids = [next(iter(s.values())).get('id') for s in sequences]
-    if all(raw_sequence_ids):
-      sequence_ids = []
-      for sequence_id in raw_sequence_ids:
-        if isinstance(sequence_id, list):
-          sequence_ids.append(sequence_id)
-        else:
-          sequence_ids.append([sequence_id])
-    else:
-      raise ValueError(
-          'AlphaFold 3 input JSON contains sequences with unset IDs.'
-      )
-
-    flat_seq_ids = []
-    for seq_ids in sequence_ids:
-      flat_seq_ids.extend(seq_ids)
-
-    chains = []
-    for seq_ids, sequence in zip(sequence_ids, sequences, strict=True):
-      if len(sequence) != 1:
-        raise ValueError(f'Chain {seq_ids} has more than 1 sequence.')
-      for seq_id in seq_ids:
-        if 'protein' in sequence:
-          chains.append(ProteinChain.from_dict(sequence, json_path, seq_id))
-        elif 'rna' in sequence:
-          chains.append(RnaChain.from_dict(sequence, json_path, seq_id))
-        elif 'dna' in sequence:
-          chains.append(DnaChain.from_dict(sequence, seq_id=seq_id))
-        elif 'ligand' in sequence:
-          chains.append(Ligand.from_dict(sequence, seq_id=seq_id))
-        else:
-          raise ValueError(f'Unknown sequence type: {sequence}')
-
-    smiles_ligand_ids = set(
-        c.id for c in chains if isinstance(c, Ligand) and c.smiles is not None
-    )
-    chain_lengths = {chain.id: len(chain) for chain in chains}
-    bonded_atom_pairs = None
-    if bonds := raw_json.get('bondedAtomPairs'):
-      bonded_atom_pairs = []
-      for bond in bonds:
-        if len(bond) != 2:
-          raise ValueError(f'Bond {bond} must have 2 atoms, got {len(bond)}.')
-        bond_beg, bond_end = bond
-        if (
-            len(bond_beg) != 3
-            or not isinstance(bond_beg[0], str)
-            or not isinstance(bond_beg[1], int)
-            or not isinstance(bond_beg[2], str)
-        ):
-          raise ValueError(
-              f'Atom {bond_beg} in bond {bond} must have 3 components: '
-              '(chain_id: str, res_id: int, atom_name: str).'
-          )
-        if (
-            len(bond_end) != 3
-            or not isinstance(bond_end[0], str)
-            or not isinstance(bond_end[1], int)
-            or not isinstance(bond_end[2], str)
-        ):
-          raise ValueError(
-              f'Atom {bond_end} in bond {bond} must have 3 components: '
-              '(chain_id: str, res_id: int, atom_name: str).'
-          )
-        if bond_beg[0] not in flat_seq_ids or bond_end[0] not in flat_seq_ids:
-          raise ValueError(f'Invalid chain ID(s) in bond {bond}')
-        if (
-            not 0 < bond_beg[1] <= chain_lengths[bond_beg[0]]
-            or not 0 < bond_end[1] <= chain_lengths[bond_end[0]]
-        ):
-          raise ValueError(f'Invalid residue ID(s) in bond {bond}')
-        if bond_beg[0] in smiles_ligand_ids:
-          raise ValueError(
-              f'Bond {bond} involves an unsupported SMILES ligand {bond_beg[0]}'
-          )
-        if bond_end[0] in smiles_ligand_ids:
-          raise ValueError(
-              f'Bond {bond} involves an unsupported SMILES ligand {bond_end[0]}'
-          )
-        bonded_atom_pairs.append((tuple(bond_beg), tuple(bond_end)))
-
-      if len(bonded_atom_pairs) != len(set(bonded_atom_pairs)):
-        raise ValueError(f'Bonds are not unique: {bonded_atom_pairs}')
-
-    user_ccd = raw_json.get('userCCD')
-    user_ccd_path = raw_json.get('userCCDPath')
-    if user_ccd and user_ccd_path:
-      raise ValueError('Only one of userCCD/userCCDPath can be set.')
-    if user_ccd and len(user_ccd) < 256 and os.path.exists(user_ccd):
-      raise ValueError('Set the user CCD path using the "userCCDPath" field.')
-    elif user_ccd_path:
-      user_ccd = _read_file(pathlib.Path(user_ccd_path), json_path)
-
-    return cls(
-        name=raw_json['name'],
-        chains=chains,
-        rng_seeds=[int(seed) for seed in raw_json['modelSeeds']],
-        bonded_atom_pairs=bonded_atom_pairs,
-        user_ccd=user_ccd,
-    )
-
-  @classmethod
-  def from_mmcif(cls, mmcif_str: str, ccd: chemical_components.Ccd) -> Self:
-    """Loads the input from an mmCIF string.
-
-    WARNING: Since rng seeds are not stored in mmCIFs, an rng seed is sampled
-    in the returned `Input`.
-
-    Args:
-      mmcif_str: The mmCIF string.
-      ccd: The chemical components dictionary.
-
-    Returns:
-      The input in an Input format.
-    """
-
-    struc = structure.from_mmcif(
-        mmcif_str,
-        # Change MSE residues to MET residues.
-        fix_mse_residues=True,
-        # Fix arginine atom names. This is not needed since the input discards
-        # any atom-level data, but kept for consistency with the paper.
-        fix_arginines=True,
-        # Fix unknown DNA residues to the correct unknown DNA residue type.
-        fix_unknown_dna=True,
-        # Do not include water molecules.
-        include_water=False,
-        # Do not include things like DNA/RNA hybrids. This will be changed once
-        # we have a way of handling these in the AlphaFold 3 input format.
-        include_other=False,
-        # Include the specific bonds defined in the mmCIF bond table, e.g.
-        # covalent bonds for PTMs.
-        include_bonds=True,
-    )
-
-    # Create default bioassembly, expanding structures implied by stoichiometry.
-    struc = struc.generate_bioassembly(None)
-
-    sequences = struc.chain_single_letter_sequence(
-        include_missing_residues=True
-    )
-
-    chains = []
-    for chain_id, chain_type in zip(
-        struc.group_by_chain.chain_id, struc.group_by_chain.chain_type
-    ):
-      sequence = sequences[chain_id]
-
-      if chain_type in mmcif_names.NON_POLYMER_CHAIN_TYPES:
-        residues = list(struc.chain_res_name_sequence()[chain_id])
-        if all(ccd.get(res) is not None for res in residues):
-          chains.append(Ligand(id=chain_id, ccd_ids=residues))
-        elif len(residues) == 1:
-          comp_name = residues[0]
-          comps = struc.chemical_components_data
-          if comps is None:
-            raise ValueError(
-                'Missing mmCIF chemical components data - this is required for '
-                f'a non-CCD ligand {comp_name} defined using SMILES string.'
-            )
-          chains.append(
-              Ligand(id=chain_id, smiles=comps.chem_comp[comp_name].pdbx_smiles)
-          )
-        else:
-          raise ValueError(
-              'Multi-component ligand must be defined using CCD IDs, defining'
-              ' using SMILES is supported only for single-component ligands. '
-              f'Got {residues}'
-          )
-      else:
-        residues = struc.chain_res_name_sequence()[chain_id]
-        fixed = struc.chain_res_name_sequence(
-            fix_non_standard_polymer_res=True
-        )[chain_id]
-        modifications = [
-            (orig, i + 1)
-            for i, (orig, fixed) in enumerate(zip(residues, fixed, strict=True))
-            if orig != fixed
-        ]
-
-        if chain_type == mmcif_names.PROTEIN_CHAIN:
-          chains.append(
-              ProteinChain(id=chain_id, sequence=sequence, ptms=modifications)
-          )
-        elif chain_type == mmcif_names.RNA_CHAIN:
-          chains.append(
-              RnaChain(
-                  id=chain_id, sequence=sequence, modifications=modifications
-              )
-          )
-        elif chain_type == mmcif_names.DNA_CHAIN:
-          chains.append(
-              DnaChain(
-                  id=chain_id, sequence=sequence, modifications=modifications
-              )
-          )
-
-    bonded_atom_pairs = []
-    chain_ids = set(c.id for c in chains)
-    for atom_a, atom_b, _ in struc.iter_bonds():
-      if atom_a['chain_id'] in chain_ids and atom_b['chain_id'] in chain_ids:
-        beg = (atom_a['chain_id'], int(atom_a['res_id']), atom_a['atom_name'])
-        end = (atom_b['chain_id'], int(atom_b['res_id']), atom_b['atom_name'])
-        bonded_atom_pairs.append((beg, end))
-
-    return cls(
-        name=struc.name,
-        chains=chains,
-        # mmCIFs don't store rng seeds, so we need to sample one here.
-        rng_seeds=[_sample_rng_seed()],
-        bonded_atom_pairs=bonded_atom_pairs or None,
-    )
-
-  def to_structure(self, ccd: chemical_components.Ccd) -> structure.Structure:
-    """Converts Input to a Structure.
-
-    WARNING: This method does not preserve the rng seeds.
-
-    Args:
-      ccd: The chemical components dictionary.
-
-    Returns:
-      The input in a structure.Structure format.
-    """
-    ids: list[str] = []
-    sequences: list[str] = []
-    poly_types: list[str] = []
-    formats: list[structure.SequenceFormat] = []
-
-    for chain in self.chains:
-      ids.append(chain.id)
-      match chain:
-        case ProteinChain():
-          sequences.append('(' + ')('.join(chain.to_ccd_sequence()) + ')')
-          poly_types.append(mmcif_names.PROTEIN_CHAIN)
-          formats.append(structure.SequenceFormat.CCD_CODES)
-        case RnaChain():
-          sequences.append('(' + ')('.join(chain.to_ccd_sequence()) + ')')
-          poly_types.append(mmcif_names.RNA_CHAIN)
-          formats.append(structure.SequenceFormat.CCD_CODES)
-        case DnaChain():
-          sequences.append('(' + ')('.join(chain.to_ccd_sequence()) + ')')
-          poly_types.append(mmcif_names.DNA_CHAIN)
-          formats.append(structure.SequenceFormat.CCD_CODES)
-        case Ligand():
-          if chain.ccd_ids is not None:
-            sequences.append('(' + ')('.join(chain.ccd_ids) + ')')
-            if len(chain.ccd_ids) == 1:
-              poly_types.append(mmcif_names.NON_POLYMER_CHAIN)
-            else:
-              poly_types.append(mmcif_names.BRANCHED_CHAIN)
-            formats.append(structure.SequenceFormat.CCD_CODES)
-          elif chain.smiles is not None:
-            # Convert to `<unique ligand ID>:<smiles>` format that is expected
-            # by structure.from_sequences_and_bonds.
-            sequences.append(f'LIG_{chain.id}:{chain.smiles}')
-            poly_types.append(mmcif_names.NON_POLYMER_CHAIN)
-            formats.append(structure.SequenceFormat.LIGAND_SMILES)
-          else:
-            raise ValueError('Ligand must have one of CCD ID or SMILES set.')
-
-    # Remap bond chain IDs from chain IDs to chain indices and convert to
-    # 0-based residue indexing.
-    bonded_atom_pairs = []
-    chain_indices = {cid: i for i, cid in enumerate(ids)}
-    if self.bonded_atom_pairs is not None:
-      for bond_beg, bond_end in self.bonded_atom_pairs:
-        bonded_atom_pairs.append((
-            (chain_indices[bond_beg[0]], bond_beg[1] - 1, bond_beg[2]),
-            (chain_indices[bond_end[0]], bond_end[1] - 1, bond_end[2]),
-        ))
-
-    struc = structure.from_sequences_and_bonds(
-        sequences=sequences,
-        chain_types=poly_types,
-        sequence_formats=formats,
-        bonded_atom_pairs=bonded_atom_pairs,
-        ccd=ccd,
-        name=self.sanitised_name(),
-        bond_type=mmcif_names.COVALENT_BOND,
-        release_date=None,
-    )
-    # Rename chain IDs to the original ones.
-    return struc.rename_chain_ids(dict(zip(struc.chains, ids, strict=True)))
-
-  def to_json(self) -> str:
-    """Converts Input to an AlphaFold JSON."""
-    deduped_chains = {}
-    deduped_chain_ids = {}
-    for chain in self.chains:
-      deduped_chains[chain.hash_without_id()] = chain
-      deduped_chain_ids.setdefault(chain.hash_without_id(), []).append(chain.id)
-
-    sequences = []
-    for chain_content_hash, ids in deduped_chain_ids.items():
-      chain = deduped_chains[chain_content_hash]
-      sequences.append(chain.to_dict(seq_id=ids if len(ids) > 1 else ids[0]))
-
-    alphafold_json = json.dumps(
-        {
-            'dialect': JSON_DIALECT,
-            'version': JSON_VERSION,
-            'name': self.name,
-            'sequences': sequences,
-            'modelSeeds': self.rng_seeds,
-            'bondedAtomPairs': self.bonded_atom_pairs,
-            'userCCD': self.user_ccd,
-        },
-        indent=2,
-    )
-    # Remove newlines from the query/template indices arrays. We match the
-    # queryIndices/templatesIndices with a non-capturing group. We then match
-    # the entire region between the square brackets by looking for lines
-    # containing only whitespace, number, or a comma.
-    return re.sub(
-        r'("(?:queryIndices|templateIndices)": \[)([\s\n\d,]+)(\],?)',
-        lambda mtch: mtch[1] + re.sub(r'\n\s+', ' ', mtch[2].strip()) + mtch[3],
-        alphafold_json,
-    )
-
-  def fill_missing_fields(self) -> Self:
-    """Fill missing MSA and template fields with default values."""
-    with_missing_fields = [
-        c.fill_missing_fields()
-        if isinstance(c, (ProteinChain, RnaChain))
-        else c
-        for c in self.chains
-    ]
-    return dataclasses.replace(self, chains=with_missing_fields)
-
-  def with_multiple_seeds(self, num_seeds: int) -> Self:
-    """Returns a copy of the input with num_seeds rng seeds."""
-    if num_seeds <= 1:
-      raise ValueError('Number of seeds must be greater than 1.')
-    if len(self.rng_seeds) != 1:
-      raise ValueError('Input must have one rng seed to set multiple seeds.')
-
-    return dataclasses.replace(
-        self,
-        rng_seeds=list(range(self.rng_seeds[0], self.rng_seeds[0] + num_seeds)),
-    )
-
-
-def load_fold_inputs_from_path(json_path: pathlib.Path) -> Iterator[Input]:
-  """Loads multiple fold inputs from a JSON string."""
-  with open(json_path, 'r') as f:
-    json_str = f.read()
-
-  # Parse the JSON string, so we can detect its format.
-  raw_json = json.loads(json_str)
-
-  if isinstance(raw_json, list):
-    # AlphaFold Server JSON.
-    logging.info('Loading %d fold jobs from %s', len(raw_json), json_path)
-    for fold_job_idx, fold_job in enumerate(raw_json):
-      try:
-        yield Input.from_alphafoldserver_fold_job(fold_job)
-      except ValueError as e:
-        raise ValueError(
-            f'Failed to load fold job {fold_job_idx} from {json_path}'
-            f' (AlphaFold Server dialect): {e}'
-        ) from e
-  else:
-    # AlphaFold 3 JSON.
-    try:
-      yield Input.from_json(json_str, json_path)
-    except ValueError as e:
-      raise ValueError(
-          f'Failed to load input from {json_path} (AlphaFold 3 dialect): {e}'
-      ) from e
-
-
-def load_fold_inputs_from_dir(input_dir: pathlib.Path) -> Iterator[Input]:
-  """Loads multiple fold inputs from all JSON files in a given input_dir.
-
-  Args:
-    input_dir: The directory containing the JSON files.
-
-  Yields:
-    The fold inputs from all JSON files in the input directory.
-  """
-  for file_path in sorted(input_dir.glob('*.json')):
-    if not file_path.is_file():
-      continue
-
-    yield from load_fold_inputs_from_path(file_path)
diff --git a/src/alphafold3/common/resources.py b/src/alphafold3/common/resources.py
deleted file mode 100644
index bd2ed986d06f953c98693d318f3dc19bbb195228..0000000000000000000000000000000000000000
--- a/src/alphafold3/common/resources.py
+++ /dev/null
@@ -1,76 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Load external resources, such as external tools or data resources."""
-
-from collections.abc import Iterator
-import os
-import pathlib
-import typing
-from typing import BinaryIO, Final, Literal, TextIO
-
-from importlib import resources
-import alphafold3.common
-
-
-_DATA_ROOT:  Final[pathlib.Path] = (
-    resources.files(alphafold3.common).joinpath('..').resolve()
-)
-ROOT = _DATA_ROOT
-
-
-def filename(name: str | os.PathLike[str]) -> str:
-  """Returns the absolute path to an external resource.
-
-  Note that this calls resources.GetResourceFilename under the hood and hence
-  causes par file unpacking, which might be unfriendly on diskless machines.
-
-
-  Args:
-    name: the name of the resource corresponding to its path relative to the
-      root of the repository.
-  """
-  return (_DATA_ROOT / name).as_posix()
-
-
-@typing.overload
-def open_resource(
-    name: str | os.PathLike[str], mode: Literal['r', 'rt'] = 'rt'
-) -> TextIO:
-  ...
-
-
-@typing.overload
-def open_resource(
-    name: str | os.PathLike[str], mode: Literal['rb']
-) -> BinaryIO:
-  ...
-
-
-def open_resource(
-    name: str | os.PathLike[str], mode: str = 'rb'
-) -> TextIO | BinaryIO:
-  """Returns an open file object for the named resource.
-
-  Args:
-    name: the name of the resource corresponding to its path relative to the
-      root of the repository.
-    mode: the mode to use when opening the file.
-  """
-  return (_DATA_ROOT / name).open(mode)
-
-
-def get_resource_dir(path: str | os.PathLike[str]) -> os.PathLike[str]:
-  return _DATA_ROOT / path
-
-
-def walk(path: str) -> Iterator[tuple[str, list[str], list[str]]]:
-  """Walks the directory tree of resources similar to os.walk."""
-  return os.walk((_DATA_ROOT / path).as_posix())
diff --git a/src/alphafold3/common/testing/data.py b/src/alphafold3/common/testing/data.py
deleted file mode 100644
index 5695d457ab0614f82053d20d187ef802c76d0c40..0000000000000000000000000000000000000000
--- a/src/alphafold3/common/testing/data.py
+++ /dev/null
@@ -1,69 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Module that provides an abstraction for accessing test data."""
-
-import os
-import pathlib
-from typing import Literal, overload
-
-from absl.testing import absltest
-
-
-class Data:
-  """Provides an abstraction for accessing test data."""
-
-  def __init__(self, data_dir: os.PathLike[str] | str):
-    """Initiailizes data wrapper, providing users with high level data access.
-
-    Args:
-      data_dir: Directory containing test data.
-    """
-    self._data_dir = pathlib.Path(data_dir)
-
-  def path(self, data_name: str | os.PathLike[str] | None = None) -> str:
-    """Returns the path to a given test data.
-
-    Args:
-      data_name: the name of the test data file relative to data_dir. If not
-        set, this will return the absolute path to the data directory.
-    """
-    data_dir_path = (
-        pathlib.Path(absltest.get_default_test_srcdir()) / self._data_dir
-    )
-
-    if data_name:
-      return str(data_dir_path / data_name)
-
-    return str(data_dir_path)
-
-  @overload
-  def load(
-      self, data_name: str | os.PathLike[str], mode: Literal['rt'] = 'rt'
-  ) -> str:
-    ...
-
-  @overload
-  def load(
-      self, data_name: str | os.PathLike[str], mode: Literal['rb'] = 'rb'
-  ) -> bytes:
-    ...
-
-  def load(
-      self, data_name: str | os.PathLike[str], mode: str = 'rt'
-  ) -> str | bytes:
-    """Returns the contents of a given test data.
-
-    Args:
-      data_name: the name of the test data file relative to data_dir.
-      mode: the mode in which to read the data file. Defaults to text ('rt').
-    """
-    with open(self.path(data_name), mode=mode) as f:
-      return f.read()
diff --git a/src/alphafold3/constants/atom_types.py b/src/alphafold3/constants/atom_types.py
deleted file mode 100644
index fae510995d1d88e340e8c303bf9580ec5d1478ab..0000000000000000000000000000000000000000
--- a/src/alphafold3/constants/atom_types.py
+++ /dev/null
@@ -1,261 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""List of atom types with reverse look-up."""
-
-from collections.abc import Mapping, Sequence, Set
-import itertools
-import sys
-from typing import Final
-from alphafold3.constants import residue_names
-
-# Note:
-# `sys.intern` places the values in the Python internal db for fast lookup.
-
-# 37 common residue atoms.
-N = sys.intern('N')
-CA = sys.intern('CA')
-C = sys.intern('C')
-CB = sys.intern('CB')
-O = sys.intern('O')
-CG = sys.intern('CG')
-CG1 = sys.intern('CG1')
-CG2 = sys.intern('CG2')
-OG = sys.intern('OG')
-OG1 = sys.intern('OG1')
-SG = sys.intern('SG')
-CD = sys.intern('CD')
-CD1 = sys.intern('CD1')
-CD2 = sys.intern('CD2')
-ND1 = sys.intern('ND1')
-ND2 = sys.intern('ND2')
-OD1 = sys.intern('OD1')
-OD2 = sys.intern('OD2')
-SD = sys.intern('SD')
-CE = sys.intern('CE')
-CE1 = sys.intern('CE1')
-CE2 = sys.intern('CE2')
-CE3 = sys.intern('CE3')
-NE = sys.intern('NE')
-NE1 = sys.intern('NE1')
-NE2 = sys.intern('NE2')
-OE1 = sys.intern('OE1')
-OE2 = sys.intern('OE2')
-CH2 = sys.intern('CH2')
-NH1 = sys.intern('NH1')
-NH2 = sys.intern('NH2')
-OH = sys.intern('OH')
-CZ = sys.intern('CZ')
-CZ2 = sys.intern('CZ2')
-CZ3 = sys.intern('CZ3')
-NZ = sys.intern('NZ')
-OXT = sys.intern('OXT')
-
-# 29 common nucleic acid atoms.
-C1PRIME = sys.intern("C1'")
-C2 = sys.intern('C2')
-C2PRIME = sys.intern("C2'")
-C3PRIME = sys.intern("C3'")
-C4 = sys.intern('C4')
-C4PRIME = sys.intern("C4'")
-C5 = sys.intern('C5')
-C5PRIME = sys.intern("C5'")
-C6 = sys.intern('C6')
-C7 = sys.intern('C7')
-C8 = sys.intern('C8')
-N1 = sys.intern('N1')
-N2 = sys.intern('N2')
-N3 = sys.intern('N3')
-N4 = sys.intern('N4')
-N6 = sys.intern('N6')
-N7 = sys.intern('N7')
-N9 = sys.intern('N9')
-O2 = sys.intern('O2')
-O2PRIME = sys.intern("O2'")
-O3PRIME = sys.intern("O3'")
-O4 = sys.intern('O4')
-O4PRIME = sys.intern("O4'")
-O5PRIME = sys.intern("O5'")
-O6 = sys.intern('O6')
-OP1 = sys.intern('OP1')
-OP2 = sys.intern('OP2')
-OP3 = sys.intern('OP3')
-P = sys.intern('P')
-
-# A list of atoms (excluding hydrogen) for each AA type. PDB naming convention.
-RESIDUE_ATOMS: Mapping[str, tuple[str, ...]] = {
-    residue_names.ALA: (C, CA, CB, N, O),
-    residue_names.ARG: (C, CA, CB, CG, CD, CZ, N, NE, O, NH1, NH2),
-    residue_names.ASN: (C, CA, CB, CG, N, ND2, O, OD1),
-    residue_names.ASP: (C, CA, CB, CG, N, O, OD1, OD2),
-    residue_names.CYS: (C, CA, CB, N, O, SG),
-    residue_names.GLN: (C, CA, CB, CG, CD, N, NE2, O, OE1),
-    residue_names.GLU: (C, CA, CB, CG, CD, N, O, OE1, OE2),
-    residue_names.GLY: (C, CA, N, O),
-    residue_names.HIS: (C, CA, CB, CG, CD2, CE1, N, ND1, NE2, O),
-    residue_names.ILE: (C, CA, CB, CG1, CG2, CD1, N, O),
-    residue_names.LEU: (C, CA, CB, CG, CD1, CD2, N, O),
-    residue_names.LYS: (C, CA, CB, CG, CD, CE, N, NZ, O),
-    residue_names.MET: (C, CA, CB, CG, CE, N, O, SD),
-    residue_names.PHE: (C, CA, CB, CG, CD1, CD2, CE1, CE2, CZ, N, O),
-    residue_names.PRO: (C, CA, CB, CG, CD, N, O),
-    residue_names.SER: (C, CA, CB, N, O, OG),
-    residue_names.THR: (C, CA, CB, CG2, N, O, OG1),
-    residue_names.TRP:
-        (C, CA, CB, CG, CD1, CD2, CE2, CE3, CZ2, CZ3, CH2, N, NE1, O),
-    residue_names.TYR: (C, CA, CB, CG, CD1, CD2, CE1, CE2, CZ, N, O, OH),
-    residue_names.VAL: (C, CA, CB, CG1, CG2, N, O),
-}  # pyformat: disable
-
-# Used to identify backbone for alignment and distance calculation for sterics.
-PROTEIN_BACKBONE_ATOMS: tuple[str, ...] = (N, CA, C)
-
-# Naming swaps for ambiguous atom names. Due to symmetries in the amino acids
-# the naming of atoms is ambiguous in 4 of the 20 amino acids. (The LDDT paper
-# lists 7 amino acids as ambiguous, but the naming ambiguities in LEU, VAL and
-# ARG can be resolved by using the 3D constellations of the 'ambiguous' atoms
-# and their neighbours)
-AMBIGUOUS_ATOM_NAMES: Mapping[str, Mapping[str, str]] = {
-    residue_names.ASP: {OD1: OD2},
-    residue_names.GLU: {OE1: OE2},
-    residue_names.PHE: {CD1: CD2, CE1: CE2},
-    residue_names.TYR: {CD1: CD2, CE1: CE2},
-}
-
-# Used when we need to store atom data in a format that requires fixed atom data
-# size for every protein residue (e.g. a numpy array).
-ATOM37: tuple[str, ...] = (
-    N, CA, C, CB, O, CG, CG1, CG2, OG, OG1, SG, CD, CD1, CD2, ND1, ND2, OD1,
-    OD2, SD, CE, CE1, CE2, CE3, NE, NE1, NE2, OE1, OE2, CH2, NH1, NH2, OH, CZ,
-    CZ2, CZ3, NZ, OXT)  # pyformat: disable
-ATOM37_ORDER: Mapping[str, int] = {name: i for i, name in enumerate(ATOM37)}
-ATOM37_NUM: Final[int] = len(ATOM37)  # := 37.
-
-# Used when we need to store protein atom data in a format that requires fixed
-# atom data size for any residue but takes less space than ATOM37 by having 14
-# fields, which is sufficient for storing atoms of all protein residues (e.g. a
-# numpy array).
-ATOM14: Mapping[str, tuple[str, ...]] = {
-    residue_names.ALA: (N, CA, C, O, CB),
-    residue_names.ARG: (N, CA, C, O, CB, CG, CD, NE, CZ, NH1, NH2),
-    residue_names.ASN: (N, CA, C, O, CB, CG, OD1, ND2),
-    residue_names.ASP: (N, CA, C, O, CB, CG, OD1, OD2),
-    residue_names.CYS: (N, CA, C, O, CB, SG),
-    residue_names.GLN: (N, CA, C, O, CB, CG, CD, OE1, NE2),
-    residue_names.GLU: (N, CA, C, O, CB, CG, CD, OE1, OE2),
-    residue_names.GLY: (N, CA, C, O),
-    residue_names.HIS: (N, CA, C, O, CB, CG, ND1, CD2, CE1, NE2),
-    residue_names.ILE: (N, CA, C, O, CB, CG1, CG2, CD1),
-    residue_names.LEU: (N, CA, C, O, CB, CG, CD1, CD2),
-    residue_names.LYS: (N, CA, C, O, CB, CG, CD, CE, NZ),
-    residue_names.MET: (N, CA, C, O, CB, CG, SD, CE),
-    residue_names.PHE: (N, CA, C, O, CB, CG, CD1, CD2, CE1, CE2, CZ),
-    residue_names.PRO: (N, CA, C, O, CB, CG, CD),
-    residue_names.SER: (N, CA, C, O, CB, OG),
-    residue_names.THR: (N, CA, C, O, CB, OG1, CG2),
-    residue_names.TRP:
-        (N, CA, C, O, CB, CG, CD1, CD2, NE1, CE2, CE3, CZ2, CZ3, CH2),
-    residue_names.TYR: (N, CA, C, O, CB, CG, CD1, CD2, CE1, CE2, CZ, OH),
-    residue_names.VAL: (N, CA, C, O, CB, CG1, CG2),
-    residue_names.UNK: (),
-}  # pyformat: disable
-
-# A compact atom encoding with 14 columns, padded with '' in empty slots.
-ATOM14_PADDED: Mapping[str, Sequence[str]] = {
-    k: [v for _, v in itertools.zip_longest(range(14), values, fillvalue='')]
-    for k, values in ATOM14.items()
-}
-
-ATOM14_ORDER: Mapping[str, Mapping[str, int]] = {
-    k: {name: i for i, name in enumerate(v)} for k, v in ATOM14.items()
-}
-ATOM14_NUM: Final[int] = max(len(v) for v in ATOM14.values())
-
-# Used when we need to store protein and nucleic atom library.
-DENSE_ATOM: Mapping[str, tuple[str, ...]] = {
-    # Protein.
-    residue_names.ALA: (N, CA, C, O, CB),
-    residue_names.ARG: (N, CA, C, O, CB, CG, CD, NE, CZ, NH1, NH2),
-    residue_names.ASN: (N, CA, C, O, CB, CG, OD1, ND2),
-    residue_names.ASP: (N, CA, C, O, CB, CG, OD1, OD2),
-    residue_names.CYS: (N, CA, C, O, CB, SG),
-    residue_names.GLN: (N, CA, C, O, CB, CG, CD, OE1, NE2),
-    residue_names.GLU: (N, CA, C, O, CB, CG, CD, OE1, OE2),
-    residue_names.GLY: (N, CA, C, O),
-    residue_names.HIS: (N, CA, C, O, CB, CG, ND1, CD2, CE1, NE2),
-    residue_names.ILE: (N, CA, C, O, CB, CG1, CG2, CD1),
-    residue_names.LEU: (N, CA, C, O, CB, CG, CD1, CD2),
-    residue_names.LYS: (N, CA, C, O, CB, CG, CD, CE, NZ),
-    residue_names.MET: (N, CA, C, O, CB, CG, SD, CE),
-    residue_names.PHE: (N, CA, C, O, CB, CG, CD1, CD2, CE1, CE2, CZ),
-    residue_names.PRO: (N, CA, C, O, CB, CG, CD),
-    residue_names.SER: (N, CA, C, O, CB, OG),
-    residue_names.THR: (N, CA, C, O, CB, OG1, CG2),
-    residue_names.TRP:
-        (N, CA, C, O, CB, CG, CD1, CD2, NE1, CE2, CE3, CZ2, CZ3, CH2),
-    residue_names.TYR: (N, CA, C, O, CB, CG, CD1, CD2, CE1, CE2, CZ, OH),
-    residue_names.VAL: (N, CA, C, O, CB, CG1, CG2),
-    residue_names.UNK: (),
-    # RNA.
-    residue_names.A:
-        (OP3, P, OP1, OP2, O5PRIME, C5PRIME, C4PRIME, O4PRIME, C3PRIME, O3PRIME,
-         C2PRIME, O2PRIME, C1PRIME, N9, C8, N7, C5, C6, N6, N1, C2, N3, C4),
-    residue_names.C:
-        (OP3, P, OP1, OP2, O5PRIME, C5PRIME, C4PRIME, O4PRIME, C3PRIME, O3PRIME,
-         C2PRIME, O2PRIME, C1PRIME, N1, C2, O2, N3, C4, N4, C5, C6),
-    residue_names.G:
-        (OP3, P, OP1, OP2, O5PRIME, C5PRIME, C4PRIME, O4PRIME, C3PRIME, O3PRIME,
-         C2PRIME, O2PRIME, C1PRIME, N9, C8, N7, C5, C6, O6, N1, C2, N2, N3, C4),
-    residue_names.U:
-        (OP3, P, OP1, OP2, O5PRIME, C5PRIME, C4PRIME, O4PRIME, C3PRIME, O3PRIME,
-         C2PRIME, O2PRIME, C1PRIME, N1, C2, O2, N3, C4, O4, C5, C6),
-    residue_names.UNK_RNA: (),
-    # DNA.
-    residue_names.DA:
-        (OP3, P, OP1, OP2, O5PRIME, C5PRIME, C4PRIME, O4PRIME, C3PRIME, O3PRIME,
-         C2PRIME, C1PRIME, N9, C8, N7, C5, C6, N6, N1, C2, N3, C4),
-    residue_names.DC:
-        (OP3, P, OP1, OP2, O5PRIME, C5PRIME, C4PRIME, O4PRIME, C3PRIME, O3PRIME,
-         C2PRIME, C1PRIME, N1, C2, O2, N3, C4, N4, C5, C6),
-    residue_names.DG:
-        (OP3, P, OP1, OP2, O5PRIME, C5PRIME, C4PRIME, O4PRIME, C3PRIME, O3PRIME,
-         C2PRIME, C1PRIME, N9, C8, N7, C5, C6, O6, N1, C2, N2, N3, C4),
-    residue_names.DT:
-        (OP3, P, OP1, OP2, O5PRIME, C5PRIME, C4PRIME, O4PRIME, C3PRIME, O3PRIME,
-         C2PRIME, C1PRIME, N1, C2, O2, N3, C4, O4, C5, C7, C6),
-    # Unknown nucleic.
-    residue_names.UNK_DNA: (),
-}  # pyformat: disable
-
-DENSE_ATOM_ORDER: Mapping[str, Mapping[str, int]] = {
-    k: {name: i for i, name in enumerate(v)} for k, v in DENSE_ATOM.items()
-}
-DENSE_ATOM_NUM: Final[int] = max(len(v) for v in DENSE_ATOM.values())
-
-# Used when we need to store atom data in a format that requires fixed atom data
-# size for every nucleic molecule (e.g. a numpy array).
-ATOM29: tuple[str, ...] = (
-    "C1'", 'C2', "C2'", "C3'", 'C4', "C4'", 'C5', "C5'", 'C6', 'C7', 'C8', 'N1',
-    'N2', 'N3', 'N4', 'N6', 'N7', 'N9', 'OP3', 'O2', "O2'", "O3'", 'O4', "O4'",
-    "O5'", 'O6', 'OP1', 'OP2', 'P')  # pyformat: disable
-ATOM29_ORDER: Mapping[str, int] = {
-    atom_type: i for i, atom_type in enumerate(ATOM29)
-}
-ATOM29_NUM: Final[int] = len(ATOM29)  # := 29
-
-# Hydrogens that exist depending on the protonation state of the residue.
-# Extracted from third_party/py/openmm/app/data/hydrogens.xml
-PROTONATION_HYDROGENS: Mapping[str, Set[str]] = {
-    'ASP': {'HD2'},
-    'CYS': {'HG'},
-    'GLU': {'HE2'},
-    'HIS': {'HD1', 'HE2'},
-    'LYS': {'HZ3'},
-}
diff --git a/src/alphafold3/constants/chemical_component_sets.py b/src/alphafold3/constants/chemical_component_sets.py
deleted file mode 100644
index 81f1fe5d329fed2e881997e8370e79fd53b13949..0000000000000000000000000000000000000000
--- a/src/alphafold3/constants/chemical_component_sets.py
+++ /dev/null
@@ -1,37 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Sets of chemical components."""
-
-import pickle
-from typing import Final
-
-from alphafold3.common import resources
-
-
-_CCD_SETS_CCD_PICKLE_FILE = resources.filename(
-    resources.ROOT / 'constants/converters/chemical_component_sets.pickle'
-)
-
-_CCD_SET = pickle.load(open(_CCD_SETS_CCD_PICKLE_FILE, 'rb'))
-
-# Glycan (or 'Saccharide') ligands.
-# _chem_comp.type containing 'saccharide' and 'linking' (when lower-case).
-GLYCAN_LINKING_LIGANDS: Final[frozenset[str]] = _CCD_SET['glycans_linking']
-
-# _chem_comp.type containing 'saccharide' and not 'linking' (when lower-case).
-GLYCAN_OTHER_LIGANDS: Final[frozenset[str]] = _CCD_SET['glycans_other']
-
-# Each of these molecules appears in over 1k PDB structures, are used to
-# facilitate crystallization conditions, but do not have biological relevance.
-COMMON_CRYSTALLIZATION_AIDS: Final[frozenset[str]] = frozenset({
-    'SO4', 'GOL', 'EDO', 'PO4', 'ACT', 'PEG', 'DMS', 'TRS', 'PGE', 'PG4', 'FMT',
-    'EPE', 'MPD', 'MES', 'CD', 'IOD',
-})  # pyformat: disable
diff --git a/src/alphafold3/constants/chemical_components.py b/src/alphafold3/constants/chemical_components.py
deleted file mode 100644
index 6b106a40c3cc123fa53586faecf0f3799589bb53..0000000000000000000000000000000000000000
--- a/src/alphafold3/constants/chemical_components.py
+++ /dev/null
@@ -1,195 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Chemical Components found in PDB (CCD) constants."""
-
-from collections.abc import ItemsView, Iterator, KeysView, Mapping, Sequence, ValuesView
-import dataclasses
-import functools
-import os
-import pickle
-
-from alphafold3.common import resources
-from alphafold3.cpp import cif_dict
-
-
-_CCD_PICKLE_FILE = resources.filename(
-    resources.ROOT / 'constants/converters/ccd.pickle'
-)
-
-
-class Ccd(Mapping[str, Mapping[str, Sequence[str]]]):
-  """Chemical Components found in PDB (CCD) constants.
-
-  See https://academic.oup.com/bioinformatics/article/31/8/1274/212200 for CCD
-  CIF format documentation.
-
-  Wraps the dict to prevent accidental mutation.
-  """
-
-  __slots__ = ('_dict', '_ccd_pickle_path')
-
-  def __init__(
-      self,
-      ccd_pickle_path: os.PathLike[str] | None = None,
-      user_ccd: str | None = None,
-  ):
-    """Initialises the chemical components dictionary.
-
-    Args:
-      ccd_pickle_path: Path to the CCD pickle file. If None, uses the default
-        CCD pickle file included in the source code.
-      user_ccd: A string containing the user-provided CCD. This has to conform
-        to the same format as the CCD, see https://www.wwpdb.org/data/ccd. If
-        provided, takes precedence over the CCD for the the same key. This can
-        be used to override specific entries in the CCD if desired.
-    """
-    self._ccd_pickle_path = ccd_pickle_path or _CCD_PICKLE_FILE
-    with open(self._ccd_pickle_path, 'rb') as f:
-      self._dict = pickle.loads(f.read())
-
-    if user_ccd is not None:
-      if not user_ccd:
-        raise ValueError('User CCD cannot be an empty string.')
-      user_ccd_cifs = {
-          key: {k: tuple(v) for k, v in value.items()}
-          for key, value in cif_dict.parse_multi_data_cif(user_ccd).items()
-      }
-      self._dict.update(user_ccd_cifs)
-
-  def __getitem__(self, key: str) -> Mapping[str, Sequence[str]]:
-    return self._dict[key]
-
-  def __contains__(self, key: str) -> bool:
-    return key in self._dict
-
-  def __iter__(self) -> Iterator[str]:
-    return self._dict.__iter__()
-
-  def __len__(self) -> int:
-    return len(self._dict)
-
-  def __hash__(self) -> int:
-    return id(self)  # Ok since this is immutable.
-
-  def get(
-      self, key: str, default: None | Mapping[str, Sequence[str]] = None
-  ) -> Mapping[str, Sequence[str]] | None:
-    return self._dict.get(key, default)
-
-  def items(self) -> ItemsView[str, Mapping[str, Sequence[str]]]:
-    return self._dict.items()
-
-  def values(self) -> ValuesView[Mapping[str, Sequence[str]]]:
-    return self._dict.values()
-
-  def keys(self) -> KeysView[str]:
-    return self._dict.keys()
-
-
-@functools.cache
-def cached_ccd(user_ccd: str | None = None) -> Ccd:
-  return Ccd(user_ccd=user_ccd)
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class ComponentInfo:
-  name: str
-  type: str
-  pdbx_synonyms: str
-  formula: str
-  formula_weight: str
-  mon_nstd_parent_comp_id: str
-  mon_nstd_flag: str
-  pdbx_smiles: str
-
-
-def mmcif_to_info(mmcif: Mapping[str, Sequence[str]]) -> ComponentInfo:
-  """Converts CCD mmCIFs to component info. Missing fields are left empty."""
-  names = mmcif['_chem_comp.name']
-  types = mmcif['_chem_comp.type']
-  mon_nstd_parent_comp_ids = mmcif['_chem_comp.mon_nstd_parent_comp_id']
-  pdbx_synonyms = mmcif['_chem_comp.pdbx_synonyms']
-  formulas = mmcif['_chem_comp.formula']
-  formula_weights = mmcif['_chem_comp.formula_weight']
-
-  def front_or_empty(values: Sequence[str]) -> str:
-    return values[0] if values else ''
-
-  type_ = front_or_empty(types)
-  mon_nstd_parent_comp_id = front_or_empty(mon_nstd_parent_comp_ids)
-  if type_.lower() == 'non-polymer':
-    # Unset for non-polymers, e.g. water or ions.
-    mon_nstd_flag = '.'
-  elif mon_nstd_parent_comp_id == '?':
-    # A standard component - it doesn't have a standard parent, e.g. MET.
-    mon_nstd_flag = 'y'
-  else:
-    # A non-standard component, e.g. MSE.
-    mon_nstd_flag = 'n'
-
-  # Default SMILES is the canonical SMILES, but we fall back to the SMILES if a
-  # canonical SMILES is not available. Of canonical SMILES, we prefer ones from
-  # the OpenEye OEToolkits program.
-  canonical_pdbx_smiles = ''
-  fallback_pdbx_smiles = ''
-  descriptor_types = mmcif.get('_pdbx_chem_comp_descriptor.type', [])
-  descriptors = mmcif.get('_pdbx_chem_comp_descriptor.descriptor', [])
-  programs = mmcif.get('_pdbx_chem_comp_descriptor.program', [])
-  for descriptor_type, descriptor, program in zip(
-      descriptor_types, descriptors, programs
-  ):
-    if descriptor_type == 'SMILES_CANONICAL':
-      if (not canonical_pdbx_smiles) or program == 'OpenEye OEToolkits':
-        canonical_pdbx_smiles = descriptor
-    if not fallback_pdbx_smiles and descriptor_type == 'SMILES':
-      fallback_pdbx_smiles = descriptor
-  pdbx_smiles = canonical_pdbx_smiles or fallback_pdbx_smiles
-
-  return ComponentInfo(
-      name=front_or_empty(names),
-      type=type_,
-      pdbx_synonyms=front_or_empty(pdbx_synonyms),
-      formula=front_or_empty(formulas),
-      formula_weight=front_or_empty(formula_weights),
-      mon_nstd_parent_comp_id=mon_nstd_parent_comp_id,
-      mon_nstd_flag=mon_nstd_flag,
-      pdbx_smiles=pdbx_smiles,
-  )
-
-
-@functools.lru_cache(maxsize=128)
-def component_name_to_info(ccd: Ccd, res_name: str) -> ComponentInfo | None:
-  component = ccd.get(res_name)
-  if component is None:
-    return None
-  return mmcif_to_info(component)
-
-
-def type_symbol(ccd: Ccd, res_name: str, atom_name: str) -> str:
-  """Returns the element type for the given component name and atom name.
-
-  Args:
-    ccd: The chemical components dictionary.
-    res_name: The component name, e.g. ARG.
-    atom_name: The atom name, e.g. CB, OXT, or NH1.
-
-  Returns:
-    Element type, e.g. C for (ARG, CB), O for (ARG, OXT), N for (ARG, NH1).
-  """
-  res = ccd.get(res_name)
-  if res is None:
-    return '?'
-  try:
-    return res['_chem_comp_atom.type_symbol'][
-        res['_chem_comp_atom.atom_id'].index(atom_name)
-    ]
-  except (ValueError, IndexError, KeyError):
-    return '?'
diff --git a/src/alphafold3/constants/converters/ccd_pickle_gen.py b/src/alphafold3/constants/converters/ccd_pickle_gen.py
deleted file mode 100644
index 6d1dce50082f2b16caa76727ae817c373834025c..0000000000000000000000000000000000000000
--- a/src/alphafold3/constants/converters/ccd_pickle_gen.py
+++ /dev/null
@@ -1,50 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Reads Chemical Components gz file and generates a CCD pickle file."""
-
-from collections.abc import Sequence
-import gzip
-import pickle
-import sys
-
-from alphafold3.cpp import cif_dict
-import tqdm
-
-
-def main(argv: Sequence[str]) -> None:
-  if len(argv) != 3:
-    raise ValueError('Must specify input_file components.cif and output_file')
-
-  _, input_file, output_file = argv
-
-  print(f'Parsing {input_file}', flush=True)
-  if input_file.endswith('.gz'):
-    opener = gzip.open
-  else:
-    opener = open
-
-  with opener(input_file, 'rb') as f:
-    whole_file = f.read()
-  result = {
-      key: {k: tuple(v) for k, v in value.items()}
-      for key, value in tqdm.tqdm(
-          cif_dict.parse_multi_data_cif(whole_file).items(), disable=None
-      )
-  }
-  assert len(result) == whole_file.count(b'data_')
-
-  print(f'Writing {output_file}', flush=True)
-  with open(output_file, 'wb') as f:
-    pickle.dump(result, f, protocol=pickle.HIGHEST_PROTOCOL)
-  print('Done', flush=True)
-
-if __name__ == '__main__':
-  main(sys.argv)
diff --git a/src/alphafold3/constants/converters/chemical_component_sets_gen.py b/src/alphafold3/constants/converters/chemical_component_sets_gen.py
deleted file mode 100644
index dfc48e8e3f03944f5c53b559aae3481c6814f874..0000000000000000000000000000000000000000
--- a/src/alphafold3/constants/converters/chemical_component_sets_gen.py
+++ /dev/null
@@ -1,80 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Script for updating chemical_component_sets.py."""
-
-from collections.abc import Mapping, Sequence
-import pathlib
-import pickle
-import re
-import sys
-
-from alphafold3.common import resources
-import tqdm
-
-
-_CCD_PICKLE_FILE = resources.filename(
-    'constants/converters/ccd.pickle'
-)
-
-
-def find_ions_and_glycans_in_ccd(
-    ccd: Mapping[str, Mapping[str, Sequence[str]]],
-) -> dict[str, frozenset[str]]:
-  """Finds glycans and ions in all version of CCD."""
-  glycans_linking = []
-  glycans_other = []
-  ions = []
-  for name, comp in tqdm.tqdm(ccd.items(), disable=None):
-    if name == 'UNX':
-      continue  # Skip "unknown atom or ion".
-    comp_type = comp['_chem_comp.type'][0].lower()
-    # Glycans have the type 'saccharide'.
-    if re.findall(r'\bsaccharide\b', comp_type):
-      # Separate out linking glycans from others.
-      if 'linking' in comp_type:
-        glycans_linking.append(name)
-      else:
-        glycans_other.append(name)
-
-    # Ions have the word 'ion' in their name.
-    comp_name = comp['_chem_comp.name'][0].lower()
-    if re.findall(r'\bion\b', comp_name):
-      ions.append(name)
-  result = dict(
-      glycans_linking=frozenset(glycans_linking),
-      glycans_other=frozenset(glycans_other),
-      ions=frozenset(ions),
-  )
-
-  return result
-
-
-def main(argv: Sequence[str]) -> None:
-  if len(argv) != 2:
-    raise ValueError(
-        'Directory to write to must be specified as a command-line arguments.'
-    )
-
-  print(f'Loading {_CCD_PICKLE_FILE}', flush=True)
-  with open(_CCD_PICKLE_FILE, 'rb') as f:
-    ccd: Mapping[str, Mapping[str, Sequence[str]]] = pickle.load(f)
-  output_path = pathlib.Path(argv[1])
-  output_path.parent.mkdir(exist_ok=True)
-  print('Finding ions and glycans', flush=True)
-  result = find_ions_and_glycans_in_ccd(ccd)
-  print(f'writing to {output_path}', flush=True)
-  with output_path.open('wb') as f:
-    pickle.dump(result, f)
-  print('Done', flush=True)
-
-
-if __name__ == '__main__':
-  main(sys.argv)
diff --git a/src/alphafold3/constants/mmcif_names.py b/src/alphafold3/constants/mmcif_names.py
deleted file mode 100644
index fd191edafb57bf3fcf9a2d3eab6db59ab7a94b30..0000000000000000000000000000000000000000
--- a/src/alphafold3/constants/mmcif_names.py
+++ /dev/null
@@ -1,216 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Names of things in mmCIF format.
-
-See https://www.iucr.org/__data/iucr/cifdic_html/2/cif_mm.dic/index.html
-"""
-
-from collections.abc import Mapping, Sequence, Set
-from typing import Final
-
-from alphafold3.constants import atom_types
-from alphafold3.constants import residue_names
-
-
-# The following are all possible values for the "_entity.type".
-# https://mmcif.wwpdb.org/dictionaries/mmcif_pdbx_v50.dic/Items/_entity.type.html
-BRANCHED_CHAIN: Final[str] = 'branched'
-MACROLIDE_CHAIN: Final[str] = 'macrolide'
-NON_POLYMER_CHAIN: Final[str] = 'non-polymer'
-POLYMER_CHAIN: Final[str] = 'polymer'
-WATER: Final[str] = 'water'
-
-CYCLIC_PSEUDO_PEPTIDE_CHAIN: Final[str] = 'cyclic-pseudo-peptide'
-DNA_CHAIN: Final[str] = 'polydeoxyribonucleotide'
-DNA_RNA_HYBRID_CHAIN: Final[str] = (
-    'polydeoxyribonucleotide/polyribonucleotide hybrid'
-)
-OTHER_CHAIN: Final[str] = 'other'
-PEPTIDE_NUCLEIC_ACID_CHAIN: Final[str] = 'peptide nucleic acid'
-POLYPEPTIDE_D_CHAIN: Final[str] = 'polypeptide(D)'
-PROTEIN_CHAIN: Final[str] = 'polypeptide(L)'
-RNA_CHAIN: Final[str] = 'polyribonucleotide'
-
-# Most common _entity_poly.types.
-STANDARD_POLYMER_CHAIN_TYPES: Final[Set[str]] = {
-    PROTEIN_CHAIN,
-    DNA_CHAIN,
-    RNA_CHAIN,
-}
-
-# Possible values for _entity.type other than polymer and water.
-LIGAND_CHAIN_TYPES: Final[Set[str]] = {
-    BRANCHED_CHAIN,
-    MACROLIDE_CHAIN,
-    NON_POLYMER_CHAIN,
-}
-
-# Possible values for _entity.type other than polymer.
-NON_POLYMER_CHAIN_TYPES: Final[Set[str]] = {
-    *LIGAND_CHAIN_TYPES,
-    WATER,
-}
-
-# Peptide possible values for _entity_poly.type.
-PEPTIDE_CHAIN_TYPES: Final[Set[str]] = {
-    CYCLIC_PSEUDO_PEPTIDE_CHAIN,
-    POLYPEPTIDE_D_CHAIN,
-    PROTEIN_CHAIN,
-    PEPTIDE_NUCLEIC_ACID_CHAIN,
-}
-
-
-# Nucleic-acid possible values for _entity_poly.type.
-NUCLEIC_ACID_CHAIN_TYPES: Final[Set[str]] = {
-    RNA_CHAIN,
-    DNA_CHAIN,
-    DNA_RNA_HYBRID_CHAIN,
-}
-
-# All possible values for _entity_poly.type.
-POLYMER_CHAIN_TYPES: Final[Set[str]] = {
-    *NUCLEIC_ACID_CHAIN_TYPES,
-    *PEPTIDE_CHAIN_TYPES,
-    OTHER_CHAIN,
-}
-
-
-TERMINAL_OXYGENS: Final[Mapping[str, str]] = {
-    PROTEIN_CHAIN: 'OXT',
-    DNA_CHAIN: 'OP3',
-    RNA_CHAIN: 'OP3',
-}
-
-
-# For each chain type, which atom should be used to represent each residue.
-RESIDUE_REPRESENTATIVE_ATOMS: Final[Mapping[str, str]] = {
-    PROTEIN_CHAIN: atom_types.CA,
-    DNA_CHAIN: atom_types.C1PRIME,
-    RNA_CHAIN: atom_types.C1PRIME,
-}
-
-# Methods involving crystallization. See the documentation at
-# mmcif.wwpdb.org/dictionaries/mmcif_pdbx_v50.dic/Items/_exptl.method.html
-# for the full list of experimental methods.
-CRYSTALLIZATION_METHODS: Final[Set[str]] = {
-    'X-RAY DIFFRACTION',
-    'NEUTRON DIFFRACTION',
-    'ELECTRON CRYSTALLOGRAPHY',
-    'POWDER CRYSTALLOGRAPHY',
-    'FIBER DIFFRACTION',
-}
-
-# Possible bond types.
-COVALENT_BOND: Final[str] = 'covale'
-HYDROGEN_BOND: Final[str] = 'hydrog'
-METAL_COORDINATION: Final[str] = 'metalc'
-DISULFIDE_BRIDGE: Final[str] = 'disulf'
-
-
-def is_standard_polymer_type(chain_type: str) -> bool:
-  """Returns if chain type is a protein, DNA or RNA chain type.
-
-  Args:
-     chain_type: The type of the chain.
-
-  Returns:
-    A bool for if the chain_type matches protein, DNA, or RNA.
-  """
-  return chain_type in STANDARD_POLYMER_CHAIN_TYPES
-
-
-def guess_polymer_type(chain_residues: Sequence[str]) -> str:
-  """Guess the polymer type (protein/rna/dna/other) based on the residues.
-
-  The polymer type is guessed by first checking for any of the standard
-  protein residues. If one is present then the chain is considered to be a
-  polypeptide. Otherwise we decide by counting residue types and deciding by
-  majority voting (e.g. mostly DNA residues -> DNA). If there is a tie between
-  the counts, the ordering is rna > dna > other.
-
-  Note that we count MSE and UNK as protein residues.
-
-  Args:
-    chain_residues: A sequence of full residue name (1-letter for DNA, 2-letters
-      for RNA, 3 for protein). The _atom_site.label_comp_id column in mmCIF.
-
-  Returns:
-    The most probable chain type as set in the _entity_poly mmCIF table:
-    protein - polypeptide(L), rna - polyribonucleotide,
-    dna - polydeoxyribonucleotide or other.
-  """
-  residue_types = {
-      **{r: RNA_CHAIN for r in residue_names.RNA_TYPES},
-      **{r: DNA_CHAIN for r in residue_names.DNA_TYPES},
-      **{r: PROTEIN_CHAIN for r in residue_names.PROTEIN_TYPES_WITH_UNKNOWN},
-      residue_names.MSE: PROTEIN_CHAIN,
-  }
-
-  counts = {PROTEIN_CHAIN: 0, RNA_CHAIN: 0, DNA_CHAIN: 0, OTHER_CHAIN: 0}
-  for residue in chain_residues:
-    residue_type = residue_types.get(residue, OTHER_CHAIN)
-    # If we ever see a protein residue we'll consider this a polypeptide(L).
-    if residue_type == PROTEIN_CHAIN:
-      return residue_type
-    counts[residue_type] += 1
-
-  # Make sure protein > rna > dna > other if there is a tie.
-  tie_braker = {PROTEIN_CHAIN: 3, RNA_CHAIN: 2, DNA_CHAIN: 1, OTHER_CHAIN: 0}
-
-  def order_fn(item):
-    name, count = item
-    return count, tie_braker[name]
-
-  most_probable_type = max(counts.items(), key=order_fn)[0]
-  return most_probable_type
-
-
-def fix_non_standard_polymer_res(*, res_name: str, chain_type: str) -> str:
-  """Returns the res_name of the closest standard protein/RNA/DNA residue.
-
-  Optimized for the case where a single residue needs to be converted.
-
-  If res_name is already a standard type, it is returned unaltered.
-  If a match cannot be found, returns 'UNK' for protein chains and 'N' for
-    RNA/DNA chains.
-
-  Args:
-     res_name: A residue_name (monomer code from the CCD).
-     chain_type: The type of the chain, must be PROTEIN_CHAIN, RNA_CHAIN or
-       DNA_CHAIN.
-
-  Returns:
-    An element from PROTEIN_TYPES_WITH_UNKNOWN | RNA_TYPES | DNA_TYPES | {'N'}.
-
-  Raises:
-    ValueError: If chain_type not in PEPTIDE_CHAIN_TYPES or
-      {OTHER_CHAIN, RNA_CHAIN, DNA_CHAIN, DNA_RNA_HYBRID_CHAIN}.
-  """
-  # Map to one letter code, then back to common res_names.
-  one_letter_code = residue_names.letters_three_to_one(res_name, default='X')
-
-  if chain_type in PEPTIDE_CHAIN_TYPES or chain_type == OTHER_CHAIN:
-    return residue_names.PROTEIN_COMMON_ONE_TO_THREE.get(one_letter_code, 'UNK')
-  elif chain_type == RNA_CHAIN:
-    # RNA's CCD monomer code is single-letter.
-    return (
-        one_letter_code if one_letter_code in residue_names.RNA_TYPES else 'N'
-    )
-  elif chain_type == DNA_CHAIN:
-    return residue_names.DNA_COMMON_ONE_TO_TWO.get(one_letter_code, 'N')
-  elif chain_type == DNA_RNA_HYBRID_CHAIN:
-    return (
-        res_name
-        if res_name in residue_names.NUCLEIC_TYPES_WITH_UNKNOWN
-        else 'N'
-    )
-  else:
-    raise ValueError(f'Expected a protein/DNA/RNA chain but got {chain_type}')
diff --git a/src/alphafold3/constants/periodic_table.py b/src/alphafold3/constants/periodic_table.py
deleted file mode 100644
index d4e87714b03ff8f1974c1047b5f1e70eb98f5a1a..0000000000000000000000000000000000000000
--- a/src/alphafold3/constants/periodic_table.py
+++ /dev/null
@@ -1,393 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Periodic table of elements."""
-
-from collections.abc import Mapping, Sequence
-import dataclasses
-from typing import Final
-
-import numpy as np
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True)
-class Element:
-  name: str
-  number: int
-  symbol: str
-  weight: float
-
-
-# Weights taken from rdkit/Code/GraphMol/atomic_data.cpp for compatibility.
-# pylint: disable=invalid-name
-
-# X is an unknown element that can be present in the CCD,
-# https://www.rcsb.org/ligand/UNX.
-X: Final[Element] = Element(name='Unknown', number=0, symbol='X', weight=0.0)
-H: Final[Element] = Element(name='Hydrogen', number=1, symbol='H', weight=1.008)
-He: Final[Element] = Element(name='Helium', number=2, symbol='He', weight=4.003)
-Li: Final[Element] = Element(
-    name='Lithium', number=3, symbol='Li', weight=6.941
-)
-Be: Final[Element] = Element(
-    name='Beryllium', number=4, symbol='Be', weight=9.012
-)
-B: Final[Element] = Element(name='Boron', number=5, symbol='B', weight=10.812)
-C: Final[Element] = Element(name='Carbon', number=6, symbol='C', weight=12.011)
-N: Final[Element] = Element(
-    name='Nitrogen', number=7, symbol='N', weight=14.007
-)
-O: Final[Element] = Element(name='Oxygen', number=8, symbol='O', weight=15.999)
-F: Final[Element] = Element(
-    name='Fluorine', number=9, symbol='F', weight=18.998
-)
-Ne: Final[Element] = Element(name='Neon', number=10, symbol='Ne', weight=20.18)
-Na: Final[Element] = Element(
-    name='Sodium', number=11, symbol='Na', weight=22.99
-)
-Mg: Final[Element] = Element(
-    name='Magnesium', number=12, symbol='Mg', weight=24.305
-)
-Al: Final[Element] = Element(
-    name='Aluminium', number=13, symbol='Al', weight=26.982
-)
-Si: Final[Element] = Element(
-    name='Silicon', number=14, symbol='Si', weight=28.086
-)
-P: Final[Element] = Element(
-    name='Phosphorus', number=15, symbol='P', weight=30.974
-)
-S: Final[Element] = Element(name='Sulfur', number=16, symbol='S', weight=32.067)
-Cl: Final[Element] = Element(
-    name='Chlorine', number=17, symbol='Cl', weight=35.453
-)
-Ar: Final[Element] = Element(
-    name='Argon', number=18, symbol='Ar', weight=39.948
-)
-K: Final[Element] = Element(
-    name='Potassium', number=19, symbol='K', weight=39.098
-)
-Ca: Final[Element] = Element(
-    name='Calcium', number=20, symbol='Ca', weight=40.078
-)
-Sc: Final[Element] = Element(
-    name='Scandium', number=21, symbol='Sc', weight=44.956
-)
-Ti: Final[Element] = Element(
-    name='Titanium', number=22, symbol='Ti', weight=47.867
-)
-V: Final[Element] = Element(
-    name='Vanadium', number=23, symbol='V', weight=50.942
-)
-Cr: Final[Element] = Element(
-    name='Chromium', number=24, symbol='Cr', weight=51.996
-)
-Mn: Final[Element] = Element(
-    name='Manganese', number=25, symbol='Mn', weight=54.938
-)
-Fe: Final[Element] = Element(name='Iron', number=26, symbol='Fe', weight=55.845)
-Co: Final[Element] = Element(
-    name='Cobalt', number=27, symbol='Co', weight=58.933
-)
-Ni: Final[Element] = Element(
-    name='Nickel', number=28, symbol='Ni', weight=58.693
-)
-Cu: Final[Element] = Element(
-    name='Copper', number=29, symbol='Cu', weight=63.546
-)
-Zn: Final[Element] = Element(name='Zinc', number=30, symbol='Zn', weight=65.39)
-Ga: Final[Element] = Element(
-    name='Gallium', number=31, symbol='Ga', weight=69.723
-)
-Ge: Final[Element] = Element(
-    name='Germanium', number=32, symbol='Ge', weight=72.61
-)
-As: Final[Element] = Element(
-    name='Arsenic', number=33, symbol='As', weight=74.922
-)
-Se: Final[Element] = Element(
-    name='Selenium', number=34, symbol='Se', weight=78.96
-)
-Br: Final[Element] = Element(
-    name='Bromine', number=35, symbol='Br', weight=79.904
-)
-Kr: Final[Element] = Element(
-    name='Krypton', number=36, symbol='Kr', weight=83.8
-)
-Rb: Final[Element] = Element(
-    name='Rubidium', number=37, symbol='Rb', weight=85.468
-)
-Sr: Final[Element] = Element(
-    name='Strontium', number=38, symbol='Sr', weight=87.62
-)
-Y: Final[Element] = Element(
-    name='Yttrium', number=39, symbol='Y', weight=88.906
-)
-Zr: Final[Element] = Element(
-    name='Zirconium', number=40, symbol='Zr', weight=91.224
-)
-Nb: Final[Element] = Element(
-    name='Niobiu', number=41, symbol='Nb', weight=92.906
-)
-Mo: Final[Element] = Element(
-    name='Molybdenum', number=42, symbol='Mo', weight=95.94
-)
-Tc: Final[Element] = Element(
-    name='Technetium', number=43, symbol='Tc', weight=98
-)
-Ru: Final[Element] = Element(
-    name='Ruthenium', number=44, symbol='Ru', weight=101.07
-)
-Rh: Final[Element] = Element(
-    name='Rhodium', number=45, symbol='Rh', weight=102.906
-)
-Pd: Final[Element] = Element(
-    name='Palladium', number=46, symbol='Pd', weight=106.42
-)
-Ag: Final[Element] = Element(
-    name='Silver', number=47, symbol='Ag', weight=107.868
-)
-Cd: Final[Element] = Element(
-    name='Cadmium', number=48, symbol='Cd', weight=112.412
-)
-In: Final[Element] = Element(
-    name='Indium', number=49, symbol='In', weight=114.818
-)
-Sn: Final[Element] = Element(name='Tin', number=50, symbol='Sn', weight=118.711)
-Sb: Final[Element] = Element(
-    name='Antimony', number=51, symbol='Sb', weight=121.76
-)
-Te: Final[Element] = Element(
-    name='Tellurium', number=52, symbol='Te', weight=127.6
-)
-I: Final[Element] = Element(
-    name='Iodine', number=53, symbol='I', weight=126.904
-)
-Xe: Final[Element] = Element(
-    name='Xenon', number=54, symbol='Xe', weight=131.29
-)
-Cs: Final[Element] = Element(
-    name='Caesium', number=55, symbol='Cs', weight=132.905
-)
-Ba: Final[Element] = Element(
-    name='Barium', number=56, symbol='Ba', weight=137.328
-)
-La: Final[Element] = Element(
-    name='Lanthanum', number=57, symbol='La', weight=138.906
-)
-Ce: Final[Element] = Element(
-    name='Cerium', number=58, symbol='Ce', weight=140.116
-)
-Pr: Final[Element] = Element(
-    name='Praseodymium', number=59, symbol='Pr', weight=140.908
-)
-Nd: Final[Element] = Element(
-    name='Neodymium', number=60, symbol='Nd', weight=144.24
-)
-Pm: Final[Element] = Element(
-    name='Promethium', number=61, symbol='Pm', weight=145
-)
-Sm: Final[Element] = Element(
-    name='Samarium', number=62, symbol='Sm', weight=150.36
-)
-Eu: Final[Element] = Element(
-    name='Europium', number=63, symbol='Eu', weight=151.964
-)
-Gd: Final[Element] = Element(
-    name='Gadolinium', number=64, symbol='Gd', weight=157.25
-)
-Tb: Final[Element] = Element(
-    name='Terbium', number=65, symbol='Tb', weight=158.925
-)
-Dy: Final[Element] = Element(
-    name='Dysprosium', number=66, symbol='Dy', weight=162.5
-)
-Ho: Final[Element] = Element(
-    name='Holmium', number=67, symbol='Ho', weight=164.93
-)
-Er: Final[Element] = Element(
-    name='Erbium', number=68, symbol='Er', weight=167.26
-)
-Tm: Final[Element] = Element(
-    name='Thulium', number=69, symbol='Tm', weight=168.934
-)
-Yb: Final[Element] = Element(
-    name='Ytterbium', number=70, symbol='Yb', weight=173.04
-)
-Lu: Final[Element] = Element(
-    name='Lutetium', number=71, symbol='Lu', weight=174.967
-)
-Hf: Final[Element] = Element(
-    name='Hafnium', number=72, symbol='Hf', weight=178.49
-)
-Ta: Final[Element] = Element(
-    name='Tantalum', number=73, symbol='Ta', weight=180.948
-)
-W: Final[Element] = Element(
-    name='Tungsten', number=74, symbol='W', weight=183.84
-)
-Re: Final[Element] = Element(
-    name='Rhenium', number=75, symbol='Re', weight=186.207
-)
-Os: Final[Element] = Element(
-    name='Osmium', number=76, symbol='Os', weight=190.23
-)
-Ir: Final[Element] = Element(
-    name='Iridium', number=77, symbol='Ir', weight=192.217
-)
-Pt: Final[Element] = Element(
-    name='Platinum', number=78, symbol='Pt', weight=195.078
-)
-Au: Final[Element] = Element(
-    name='Gold', number=79, symbol='Au', weight=196.967
-)
-Hg: Final[Element] = Element(
-    name='Mercury', number=80, symbol='Hg', weight=200.59
-)
-Tl: Final[Element] = Element(
-    name='Thallium', number=81, symbol='Tl', weight=204.383
-)
-Pb: Final[Element] = Element(name='Lead', number=82, symbol='Pb', weight=207.2)
-Bi: Final[Element] = Element(
-    name='Bismuth', number=83, symbol='Bi', weight=208.98
-)
-Po: Final[Element] = Element(
-    name='Polonium', number=84, symbol='Po', weight=209
-)
-At: Final[Element] = Element(
-    name='Astatine', number=85, symbol='At', weight=210
-)
-Rn: Final[Element] = Element(name='Radon', number=86, symbol='Rn', weight=222)
-Fr: Final[Element] = Element(
-    name='Francium', number=87, symbol='Fr', weight=223
-)
-Ra: Final[Element] = Element(name='Radium', number=88, symbol='Ra', weight=226)
-Ac: Final[Element] = Element(
-    name='Actinium', number=89, symbol='Ac', weight=227
-)
-Th: Final[Element] = Element(
-    name='Thorium', number=90, symbol='Th', weight=232.038
-)
-Pa: Final[Element] = Element(
-    name='Protactinium', number=91, symbol='Pa', weight=231.036
-)
-U: Final[Element] = Element(
-    name='Uranium', number=92, symbol='U', weight=238.029
-)
-Np: Final[Element] = Element(
-    name='Neptunium', number=93, symbol='Np', weight=237
-)
-Pu: Final[Element] = Element(
-    name='Plutonium', number=94, symbol='Pu', weight=244
-)
-Am: Final[Element] = Element(
-    name='Americium', number=95, symbol='Am', weight=243
-)
-Cm: Final[Element] = Element(name='Curium', number=96, symbol='Cm', weight=247)
-Bk: Final[Element] = Element(
-    name='Berkelium', number=97, symbol='Bk', weight=247
-)
-Cf: Final[Element] = Element(
-    name='Californium', number=98, symbol='Cf', weight=251
-)
-Es: Final[Element] = Element(
-    name='Einsteinium', number=99, symbol='Es', weight=252
-)
-Fm: Final[Element] = Element(
-    name='Fermium', number=100, symbol='Fm', weight=257
-)
-Md: Final[Element] = Element(
-    name='Mendelevium', number=101, symbol='Md', weight=258
-)
-No: Final[Element] = Element(
-    name='Nobelium', number=102, symbol='No', weight=259
-)
-Lr: Final[Element] = Element(
-    name='Lawrencium', number=103, symbol='Lr', weight=262
-)
-Rf: Final[Element] = Element(
-    name='Rutherfordium', number=104, symbol='Rf', weight=267
-)
-Db: Final[Element] = Element(
-    name='Dubnium', number=105, symbol='Db', weight=268
-)
-Sg: Final[Element] = Element(
-    name='Seaborgium', number=106, symbol='Sg', weight=269
-)
-Bh: Final[Element] = Element(
-    name='Bohrium', number=107, symbol='Bh', weight=270
-)
-Hs: Final[Element] = Element(
-    name='Hassium', number=108, symbol='Hs', weight=269
-)
-Mt: Final[Element] = Element(
-    name='Meitnerium', number=109, symbol='Mt', weight=278
-)
-Ds: Final[Element] = Element(
-    name='Darmstadtium', number=110, symbol='Ds', weight=281
-)
-Rg: Final[Element] = Element(
-    name='Roentgenium', number=111, symbol='Rg', weight=281
-)
-Cn: Final[Element] = Element(
-    name='Copernicium', number=112, symbol='Cn', weight=285
-)
-Nh: Final[Element] = Element(
-    name='Nihonium', number=113, symbol='Nh', weight=284
-)
-Fl: Final[Element] = Element(
-    name='Flerovium', number=114, symbol='Fl', weight=289
-)
-Mc: Final[Element] = Element(
-    name='Moscovium', number=115, symbol='Mc', weight=288
-)
-Lv: Final[Element] = Element(
-    name='Livermorium', number=116, symbol='Lv', weight=293
-)
-Ts: Final[Element] = Element(
-    name='Tennessine', number=117, symbol='Ts', weight=292
-)
-Og: Final[Element] = Element(
-    name='Oganesson', number=118, symbol='Og', weight=294
-)
-# pylint: enable=invalid-name
-
-# fmt: off
-# Lanthanides
-_L: Final[Sequence[Element]] = (
-    La, Ce, Pr, Nd, Pm, Sm, Eu, Gd, Tb, Dy, Ho, Er, Tm, Yb, Lu)
-# Actinides
-_A: Final[Sequence[Element]] = (
-    Ac, Th, Pa, U, Np, Pu, Am, Cm, Bk, Cf, Es, Fm, Md, No, Lr)
-
-# pylint: disable=bad-whitespace
-PERIODIC_TABLE: Final[Sequence[Element]] = (
-    X,  # Unknown
-    H,                                                                   He,
-    Li, Be,                                          B,  C,  N,  O,  F,  Ne,
-    Na, Mg,                                          Al, Si, P,  S,  Cl, Ar,
-    K,  Ca,  Sc, Ti, V,  Cr, Mn, Fe, Co, Ni, Cu, Zn, Ga, Ge, As, Se, Br, Kr,
-    Rb, Sr,  Y,  Zr, Nb, Mo, Tc, Ru, Rh, Pd, Ag, Cd, In, Sn, Sb, Te, I,  Xe,
-    Cs, Ba, *_L, Hf, Ta, W,  Re, Os, Ir, Pt, Au, Hg, Tl, Pb, Bi, Po, At, Rn,
-    Fr, Ra, *_A, Rf, Db, Sg, Bh, Hs, Mt, Ds, Rg, Cn, Nh, Fl, Mc, Lv, Ts, Og
-)
-# pylint: enable=bad-whitespace
-# fmt: on
-ATOMIC_SYMBOL: Mapping[int, str] = {e.number: e.symbol for e in PERIODIC_TABLE}
-ATOMIC_NUMBER = {e.symbol: e.number for e in PERIODIC_TABLE}
-# Add Deuterium as previous table contained it.
-ATOMIC_NUMBER['D'] = 1
-
-ATOMIC_NUMBER: Mapping[str, int] = ATOMIC_NUMBER
-ATOMIC_WEIGHT: np.ndarray = np.zeros(len(PERIODIC_TABLE), dtype=np.float64)
-
-for e in PERIODIC_TABLE:
-  ATOMIC_WEIGHT[e.number] = e.weight
-ATOMIC_WEIGHT.setflags(write=False)
diff --git a/src/alphafold3/constants/residue_names.py b/src/alphafold3/constants/residue_names.py
deleted file mode 100644
index 3a5643f03e2a3fd53d1309f7c8fb4c6d63c65c06..0000000000000000000000000000000000000000
--- a/src/alphafold3/constants/residue_names.py
+++ /dev/null
@@ -1,419 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Constants associated with residue names."""
-
-from collections.abc import Mapping
-import functools
-import sys
-
-# pyformat: disable
-# common_typos_disable
-CCD_NAME_TO_ONE_LETTER: Mapping[str, str] = {
-    '00C': 'C', '01W': 'X', '02K': 'A', '03Y': 'C', '07O': 'C', '08P': 'C',
-    '0A0': 'D', '0A1': 'Y', '0A2': 'K', '0A8': 'C', '0AA': 'V', '0AB': 'V',
-    '0AC': 'G', '0AD': 'G', '0AF': 'W', '0AG': 'L', '0AH': 'S', '0AK': 'D',
-    '0AM': 'A', '0AP': 'C', '0AU': 'U', '0AV': 'A', '0AZ': 'P', '0BN': 'F',
-    '0C': 'C', '0CS': 'A', '0DC': 'C', '0DG': 'G', '0DT': 'T', '0FL': 'A',
-    '0G': 'G', '0NC': 'A', '0SP': 'A', '0U': 'U', '10C': 'C', '125': 'U',
-    '126': 'U', '127': 'U', '128': 'N', '12A': 'A', '143': 'C', '193': 'X',
-    '1AP': 'A', '1MA': 'A', '1MG': 'G', '1PA': 'F', '1PI': 'A', '1PR': 'N',
-    '1SC': 'C', '1TQ': 'W', '1TY': 'Y', '1X6': 'S', '200': 'F', '23F': 'F',
-    '23S': 'X', '26B': 'T', '2AD': 'X', '2AG': 'A', '2AO': 'X', '2AR': 'A',
-    '2AS': 'X', '2AT': 'T', '2AU': 'U', '2BD': 'I', '2BT': 'T', '2BU': 'A',
-    '2CO': 'C', '2DA': 'A', '2DF': 'N', '2DM': 'N', '2DO': 'X', '2DT': 'T',
-    '2EG': 'G', '2FE': 'N', '2FI': 'N', '2FM': 'M', '2GT': 'T', '2HF': 'H',
-    '2LU': 'L', '2MA': 'A', '2MG': 'G', '2ML': 'L', '2MR': 'R', '2MT': 'P',
-    '2MU': 'U', '2NT': 'T', '2OM': 'U', '2OT': 'T', '2PI': 'X', '2PR': 'G',
-    '2SA': 'N', '2SI': 'X', '2ST': 'T', '2TL': 'T', '2TY': 'Y', '2VA': 'V',
-    '2XA': 'C', '32S': 'X', '32T': 'X', '3AH': 'H', '3AR': 'X', '3CF': 'F',
-    '3DA': 'A', '3DR': 'N', '3GA': 'A', '3MD': 'D', '3ME': 'U', '3NF': 'Y',
-    '3QN': 'K', '3TY': 'X', '3XH': 'G', '4AC': 'N', '4BF': 'Y', '4CF': 'F',
-    '4CY': 'M', '4DP': 'W', '4FB': 'P', '4FW': 'W', '4HT': 'W', '4IN': 'W',
-    '4MF': 'N', '4MM': 'X', '4OC': 'C', '4PC': 'C', '4PD': 'C', '4PE': 'C',
-    '4PH': 'F', '4SC': 'C', '4SU': 'U', '4TA': 'N', '4U7': 'A', '56A': 'H',
-    '5AA': 'A', '5AB': 'A', '5AT': 'T', '5BU': 'U', '5CG': 'G', '5CM': 'C',
-    '5CS': 'C', '5FA': 'A', '5FC': 'C', '5FU': 'U', '5HP': 'E', '5HT': 'T',
-    '5HU': 'U', '5IC': 'C', '5IT': 'T', '5IU': 'U', '5MC': 'C', '5MD': 'N',
-    '5MU': 'U', '5NC': 'C', '5PC': 'C', '5PY': 'T', '5SE': 'U', '64T': 'T',
-    '6CL': 'K', '6CT': 'T', '6CW': 'W', '6HA': 'A', '6HC': 'C', '6HG': 'G',
-    '6HN': 'K', '6HT': 'T', '6IA': 'A', '6MA': 'A', '6MC': 'A', '6MI': 'N',
-    '6MT': 'A', '6MZ': 'N', '6OG': 'G', '70U': 'U', '7DA': 'A', '7GU': 'G',
-    '7JA': 'I', '7MG': 'G', '8AN': 'A', '8FG': 'G', '8MG': 'G', '8OG': 'G',
-    '9NE': 'E', '9NF': 'F', '9NR': 'R', '9NV': 'V', 'A': 'A', 'A1P': 'N',
-    'A23': 'A', 'A2L': 'A', 'A2M': 'A', 'A34': 'A', 'A35': 'A', 'A38': 'A',
-    'A39': 'A', 'A3A': 'A', 'A3P': 'A', 'A40': 'A', 'A43': 'A', 'A44': 'A',
-    'A47': 'A', 'A5L': 'A', 'A5M': 'C', 'A5N': 'N', 'A5O': 'A', 'A66': 'X',
-    'AA3': 'A', 'AA4': 'A', 'AAR': 'R', 'AB7': 'X', 'ABA': 'A', 'ABR': 'A',
-    'ABS': 'A', 'ABT': 'N', 'ACB': 'D', 'ACL': 'R', 'AD2': 'A', 'ADD': 'X',
-    'ADX': 'N', 'AEA': 'X', 'AEI': 'D', 'AET': 'A', 'AFA': 'N', 'AFF': 'N',
-    'AFG': 'G', 'AGM': 'R', 'AGT': 'C', 'AHB': 'N', 'AHH': 'X', 'AHO': 'A',
-    'AHP': 'A', 'AHS': 'X', 'AHT': 'X', 'AIB': 'A', 'AKL': 'D', 'AKZ': 'D',
-    'ALA': 'A', 'ALC': 'A', 'ALM': 'A', 'ALN': 'A', 'ALO': 'T', 'ALQ': 'X',
-    'ALS': 'A', 'ALT': 'A', 'ALV': 'A', 'ALY': 'K', 'AN8': 'A', 'AP7': 'A',
-    'APE': 'X', 'APH': 'A', 'API': 'K', 'APK': 'K', 'APM': 'X', 'APP': 'X',
-    'AR2': 'R', 'AR4': 'E', 'AR7': 'R', 'ARG': 'R', 'ARM': 'R', 'ARO': 'R',
-    'ARV': 'X', 'AS': 'A', 'AS2': 'D', 'AS9': 'X', 'ASA': 'D', 'ASB': 'D',
-    'ASI': 'D', 'ASK': 'D', 'ASL': 'D', 'ASM': 'X', 'ASN': 'N', 'ASP': 'D',
-    'ASQ': 'D', 'ASU': 'N', 'ASX': 'B', 'ATD': 'T', 'ATL': 'T', 'ATM': 'T',
-    'AVC': 'A', 'AVN': 'X', 'AYA': 'A', 'AZK': 'K', 'AZS': 'S', 'AZY': 'Y',
-    'B1F': 'F', 'B1P': 'N', 'B2A': 'A', 'B2F': 'F', 'B2I': 'I', 'B2V': 'V',
-    'B3A': 'A', 'B3D': 'D', 'B3E': 'E', 'B3K': 'K', 'B3L': 'X', 'B3M': 'X',
-    'B3Q': 'X', 'B3S': 'S', 'B3T': 'X', 'B3U': 'H', 'B3X': 'N', 'B3Y': 'Y',
-    'BB6': 'C', 'BB7': 'C', 'BB8': 'F', 'BB9': 'C', 'BBC': 'C', 'BCS': 'C',
-    'BE2': 'X', 'BFD': 'D', 'BG1': 'S', 'BGM': 'G', 'BH2': 'D', 'BHD': 'D',
-    'BIF': 'F', 'BIL': 'X', 'BIU': 'I', 'BJH': 'X', 'BLE': 'L', 'BLY': 'K',
-    'BMP': 'N', 'BMT': 'T', 'BNN': 'F', 'BNO': 'X', 'BOE': 'T', 'BOR': 'R',
-    'BPE': 'C', 'BRU': 'U', 'BSE': 'S', 'BT5': 'N', 'BTA': 'L', 'BTC': 'C',
-    'BTR': 'W', 'BUC': 'C', 'BUG': 'V', 'BVP': 'U', 'BZG': 'N', 'C': 'C',
-    'C1X': 'K', 'C25': 'C', 'C2L': 'C', 'C2S': 'C', 'C31': 'C', 'C32': 'C',
-    'C34': 'C', 'C36': 'C', 'C37': 'C', 'C38': 'C', 'C3Y': 'C', 'C42': 'C',
-    'C43': 'C', 'C45': 'C', 'C46': 'C', 'C49': 'C', 'C4R': 'C', 'C4S': 'C',
-    'C5C': 'C', 'C66': 'X', 'C6C': 'C', 'CAF': 'C', 'CAL': 'X', 'CAR': 'C',
-    'CAS': 'C', 'CAV': 'X', 'CAY': 'C', 'CB2': 'C', 'CBR': 'C', 'CBV': 'C',
-    'CCC': 'C', 'CCL': 'K', 'CCS': 'C', 'CDE': 'X', 'CDV': 'X', 'CDW': 'C',
-    'CEA': 'C', 'CFL': 'C', 'CG1': 'G', 'CGA': 'E', 'CGU': 'E', 'CH': 'C',
-    'CHF': 'X', 'CHG': 'X', 'CHP': 'G', 'CHS': 'X', 'CIR': 'R', 'CLE': 'L',
-    'CLG': 'K', 'CLH': 'K', 'CM0': 'N', 'CME': 'C', 'CMH': 'C', 'CML': 'C',
-    'CMR': 'C', 'CMT': 'C', 'CNU': 'U', 'CP1': 'C', 'CPC': 'X', 'CPI': 'X',
-    'CR5': 'G', 'CS0': 'C', 'CS1': 'C', 'CS3': 'C', 'CS4': 'C', 'CS8': 'N',
-    'CSA': 'C', 'CSB': 'C', 'CSD': 'C', 'CSE': 'C', 'CSF': 'C', 'CSI': 'G',
-    'CSJ': 'C', 'CSL': 'C', 'CSO': 'C', 'CSP': 'C', 'CSR': 'C', 'CSS': 'C',
-    'CSU': 'C', 'CSW': 'C', 'CSX': 'C', 'CSZ': 'C', 'CTE': 'W', 'CTG': 'T',
-    'CTH': 'T', 'CUC': 'X', 'CWR': 'S', 'CXM': 'M', 'CY0': 'C', 'CY1': 'C',
-    'CY3': 'C', 'CY4': 'C', 'CYA': 'C', 'CYD': 'C', 'CYF': 'C', 'CYG': 'C',
-    'CYJ': 'X', 'CYM': 'C', 'CYQ': 'C', 'CYR': 'C', 'CYS': 'C', 'CZ2': 'C',
-    'CZZ': 'C', 'D11': 'T', 'D1P': 'N', 'D3': 'N', 'D33': 'N', 'D3P': 'G',
-    'D3T': 'T', 'D4M': 'T', 'D4P': 'X', 'DA': 'A', 'DA2': 'X', 'DAB': 'A',
-    'DAH': 'F', 'DAL': 'A', 'DAR': 'R', 'DAS': 'D', 'DBB': 'T', 'DBM': 'N',
-    'DBS': 'S', 'DBU': 'T', 'DBY': 'Y', 'DBZ': 'A', 'DC': 'C', 'DC2': 'C',
-    'DCG': 'G', 'DCI': 'X', 'DCL': 'X', 'DCT': 'C', 'DCY': 'C', 'DDE': 'H',
-    'DDG': 'G', 'DDN': 'U', 'DDX': 'N', 'DFC': 'C', 'DFG': 'G', 'DFI': 'X',
-    'DFO': 'X', 'DFT': 'N', 'DG': 'G', 'DGH': 'G', 'DGI': 'G', 'DGL': 'E',
-    'DGN': 'Q', 'DHA': 'S', 'DHI': 'H', 'DHL': 'X', 'DHN': 'V', 'DHP': 'X',
-    'DHU': 'U', 'DHV': 'V', 'DI': 'I', 'DIL': 'I', 'DIR': 'R', 'DIV': 'V',
-    'DLE': 'L', 'DLS': 'K', 'DLY': 'K', 'DM0': 'K', 'DMH': 'N', 'DMK': 'D',
-    'DMT': 'X', 'DN': 'N', 'DNE': 'L', 'DNG': 'L', 'DNL': 'K', 'DNM': 'L',
-    'DNP': 'A', 'DNR': 'C', 'DNS': 'K', 'DOA': 'X', 'DOC': 'C', 'DOH': 'D',
-    'DON': 'L', 'DPB': 'T', 'DPH': 'F', 'DPL': 'P', 'DPP': 'A', 'DPQ': 'Y',
-    'DPR': 'P', 'DPY': 'N', 'DRM': 'U', 'DRP': 'N', 'DRT': 'T', 'DRZ': 'N',
-    'DSE': 'S', 'DSG': 'N', 'DSN': 'S', 'DSP': 'D', 'DT': 'T', 'DTH': 'T',
-    'DTR': 'W', 'DTY': 'Y', 'DU': 'U', 'DVA': 'V', 'DXD': 'N', 'DXN': 'N',
-    'DYS': 'C', 'DZM': 'A', 'E': 'A', 'E1X': 'A', 'ECC': 'Q', 'EDA': 'A',
-    'EFC': 'C', 'EHP': 'F', 'EIT': 'T', 'ENP': 'N', 'ESB': 'Y', 'ESC': 'M',
-    'EXB': 'X', 'EXY': 'L', 'EY5': 'N', 'EYS': 'X', 'F2F': 'F', 'FA2': 'A',
-    'FA5': 'N', 'FAG': 'N', 'FAI': 'N', 'FB5': 'A', 'FB6': 'A', 'FCL': 'F',
-    'FFD': 'N', 'FGA': 'E', 'FGL': 'G', 'FGP': 'S', 'FHL': 'X', 'FHO': 'K',
-    'FHU': 'U', 'FLA': 'A', 'FLE': 'L', 'FLT': 'Y', 'FME': 'M', 'FMG': 'G',
-    'FMU': 'N', 'FOE': 'C', 'FOX': 'G', 'FP9': 'P', 'FPA': 'F', 'FRD': 'X',
-    'FT6': 'W', 'FTR': 'W', 'FTY': 'Y', 'FVA': 'V', 'FZN': 'K', 'G': 'G',
-    'G25': 'G', 'G2L': 'G', 'G2S': 'G', 'G31': 'G', 'G32': 'G', 'G33': 'G',
-    'G36': 'G', 'G38': 'G', 'G42': 'G', 'G46': 'G', 'G47': 'G', 'G48': 'G',
-    'G49': 'G', 'G4P': 'N', 'G7M': 'G', 'GAO': 'G', 'GAU': 'E', 'GCK': 'C',
-    'GCM': 'X', 'GDP': 'G', 'GDR': 'G', 'GFL': 'G', 'GGL': 'E', 'GH3': 'G',
-    'GHG': 'Q', 'GHP': 'G', 'GL3': 'G', 'GLH': 'Q', 'GLJ': 'E', 'GLK': 'E',
-    'GLM': 'X', 'GLN': 'Q', 'GLQ': 'E', 'GLU': 'E', 'GLX': 'Z', 'GLY': 'G',
-    'GLZ': 'G', 'GMA': 'E', 'GMS': 'G', 'GMU': 'U', 'GN7': 'G', 'GND': 'X',
-    'GNE': 'N', 'GOM': 'G', 'GPL': 'K', 'GS': 'G', 'GSC': 'G', 'GSR': 'G',
-    'GSS': 'G', 'GSU': 'E', 'GT9': 'C', 'GTP': 'G', 'GVL': 'X', 'H2U': 'U',
-    'H5M': 'P', 'HAC': 'A', 'HAR': 'R', 'HBN': 'H', 'HCS': 'X', 'HDP': 'U',
-    'HEU': 'U', 'HFA': 'X', 'HGL': 'X', 'HHI': 'H', 'HIA': 'H', 'HIC': 'H',
-    'HIP': 'H', 'HIQ': 'H', 'HIS': 'H', 'HL2': 'L', 'HLU': 'L', 'HMR': 'R',
-    'HOL': 'N', 'HPC': 'F', 'HPE': 'F', 'HPH': 'F', 'HPQ': 'F', 'HQA': 'A',
-    'HRG': 'R', 'HRP': 'W', 'HS8': 'H', 'HS9': 'H', 'HSE': 'S', 'HSL': 'S',
-    'HSO': 'H', 'HTI': 'C', 'HTN': 'N', 'HTR': 'W', 'HV5': 'A', 'HVA': 'V',
-    'HY3': 'P', 'HYP': 'P', 'HZP': 'P', 'I': 'I', 'I2M': 'I', 'I58': 'K',
-    'I5C': 'C', 'IAM': 'A', 'IAR': 'R', 'IAS': 'D', 'IC': 'C', 'IEL': 'K',
-    'IG': 'G', 'IGL': 'G', 'IGU': 'G', 'IIL': 'I', 'ILE': 'I', 'ILG': 'E',
-    'ILX': 'I', 'IMC': 'C', 'IML': 'I', 'IOY': 'F', 'IPG': 'G', 'IPN': 'N',
-    'IRN': 'N', 'IT1': 'K', 'IU': 'U', 'IYR': 'Y', 'IYT': 'T', 'IZO': 'M',
-    'JJJ': 'C', 'JJK': 'C', 'JJL': 'C', 'JW5': 'N', 'K1R': 'C', 'KAG': 'G',
-    'KCX': 'K', 'KGC': 'K', 'KNB': 'A', 'KOR': 'M', 'KPI': 'K', 'KST': 'K',
-    'KYQ': 'K', 'L2A': 'X', 'LA2': 'K', 'LAA': 'D', 'LAL': 'A', 'LBY': 'K',
-    'LC': 'C', 'LCA': 'A', 'LCC': 'N', 'LCG': 'G', 'LCH': 'N', 'LCK': 'K',
-    'LCX': 'K', 'LDH': 'K', 'LED': 'L', 'LEF': 'L', 'LEH': 'L', 'LEI': 'V',
-    'LEM': 'L', 'LEN': 'L', 'LET': 'X', 'LEU': 'L', 'LEX': 'L', 'LG': 'G',
-    'LGP': 'G', 'LHC': 'X', 'LHU': 'U', 'LKC': 'N', 'LLP': 'K', 'LLY': 'K',
-    'LME': 'E', 'LMF': 'K', 'LMQ': 'Q', 'LMS': 'N', 'LP6': 'K', 'LPD': 'P',
-    'LPG': 'G', 'LPL': 'X', 'LPS': 'S', 'LSO': 'X', 'LTA': 'X', 'LTR': 'W',
-    'LVG': 'G', 'LVN': 'V', 'LYF': 'K', 'LYK': 'K', 'LYM': 'K', 'LYN': 'K',
-    'LYR': 'K', 'LYS': 'K', 'LYX': 'K', 'LYZ': 'K', 'M0H': 'C', 'M1G': 'G',
-    'M2G': 'G', 'M2L': 'K', 'M2S': 'M', 'M30': 'G', 'M3L': 'K', 'M5M': 'C',
-    'MA': 'A', 'MA6': 'A', 'MA7': 'A', 'MAA': 'A', 'MAD': 'A', 'MAI': 'R',
-    'MBQ': 'Y', 'MBZ': 'N', 'MC1': 'S', 'MCG': 'X', 'MCL': 'K', 'MCS': 'C',
-    'MCY': 'C', 'MD3': 'C', 'MD6': 'G', 'MDH': 'X', 'MDR': 'N', 'MEA': 'F',
-    'MED': 'M', 'MEG': 'E', 'MEN': 'N', 'MEP': 'U', 'MEQ': 'Q', 'MET': 'M',
-    'MEU': 'G', 'MF3': 'X', 'MG1': 'G', 'MGG': 'R', 'MGN': 'Q', 'MGQ': 'A',
-    'MGV': 'G', 'MGY': 'G', 'MHL': 'L', 'MHO': 'M', 'MHS': 'H', 'MIA': 'A',
-    'MIS': 'S', 'MK8': 'L', 'ML3': 'K', 'MLE': 'L', 'MLL': 'L', 'MLY': 'K',
-    'MLZ': 'K', 'MME': 'M', 'MMO': 'R', 'MMT': 'T', 'MND': 'N', 'MNL': 'L',
-    'MNU': 'U', 'MNV': 'V', 'MOD': 'X', 'MP8': 'P', 'MPH': 'X', 'MPJ': 'X',
-    'MPQ': 'G', 'MRG': 'G', 'MSA': 'G', 'MSE': 'M', 'MSL': 'M', 'MSO': 'M',
-    'MSP': 'X', 'MT2': 'M', 'MTR': 'T', 'MTU': 'A', 'MTY': 'Y', 'MVA': 'V',
-    'N': 'N', 'N10': 'S', 'N2C': 'X', 'N5I': 'N', 'N5M': 'C', 'N6G': 'G',
-    'N7P': 'P', 'NA8': 'A', 'NAL': 'A', 'NAM': 'A', 'NB8': 'N', 'NBQ': 'Y',
-    'NC1': 'S', 'NCB': 'A', 'NCX': 'N', 'NCY': 'X', 'NDF': 'F', 'NDN': 'U',
-    'NEM': 'H', 'NEP': 'H', 'NF2': 'N', 'NFA': 'F', 'NHL': 'E', 'NIT': 'X',
-    'NIY': 'Y', 'NLE': 'L', 'NLN': 'L', 'NLO': 'L', 'NLP': 'L', 'NLQ': 'Q',
-    'NMC': 'G', 'NMM': 'R', 'NMS': 'T', 'NMT': 'T', 'NNH': 'R', 'NP3': 'N',
-    'NPH': 'C', 'NPI': 'A', 'NSK': 'X', 'NTY': 'Y', 'NVA': 'V', 'NYM': 'N',
-    'NYS': 'C', 'NZH': 'H', 'O12': 'X', 'O2C': 'N', 'O2G': 'G', 'OAD': 'N',
-    'OAS': 'S', 'OBF': 'X', 'OBS': 'X', 'OCS': 'C', 'OCY': 'C', 'ODP': 'N',
-    'OHI': 'H', 'OHS': 'D', 'OIC': 'X', 'OIP': 'I', 'OLE': 'X', 'OLT': 'T',
-    'OLZ': 'S', 'OMC': 'C', 'OMG': 'G', 'OMT': 'M', 'OMU': 'U', 'ONE': 'U',
-    'ONH': 'A', 'ONL': 'X', 'OPR': 'R', 'ORN': 'A', 'ORQ': 'R', 'OSE': 'S',
-    'OTB': 'X', 'OTH': 'T', 'OTY': 'Y', 'OXX': 'D', 'P': 'G', 'P1L': 'C',
-    'P1P': 'N', 'P2T': 'T', 'P2U': 'U', 'P2Y': 'P', 'P5P': 'A', 'PAQ': 'Y',
-    'PAS': 'D', 'PAT': 'W', 'PAU': 'A', 'PBB': 'C', 'PBF': 'F', 'PBT': 'N',
-    'PCA': 'E', 'PCC': 'P', 'PCE': 'X', 'PCS': 'F', 'PDL': 'X', 'PDU': 'U',
-    'PEC': 'C', 'PF5': 'F', 'PFF': 'F', 'PFX': 'X', 'PG1': 'S', 'PG7': 'G',
-    'PG9': 'G', 'PGL': 'X', 'PGN': 'G', 'PGP': 'G', 'PGY': 'G', 'PHA': 'F',
-    'PHD': 'D', 'PHE': 'F', 'PHI': 'F', 'PHL': 'F', 'PHM': 'F', 'PIV': 'X',
-    'PLE': 'L', 'PM3': 'F', 'PMT': 'C', 'POM': 'P', 'PPN': 'F', 'PPU': 'A',
-    'PPW': 'G', 'PQ1': 'N', 'PR3': 'C', 'PR5': 'A', 'PR9': 'P', 'PRN': 'A',
-    'PRO': 'P', 'PRS': 'P', 'PSA': 'F', 'PSH': 'H', 'PST': 'T', 'PSU': 'U',
-    'PSW': 'C', 'PTA': 'X', 'PTH': 'Y', 'PTM': 'Y', 'PTR': 'Y', 'PU': 'A',
-    'PUY': 'N', 'PVH': 'H', 'PVL': 'X', 'PYA': 'A', 'PYO': 'U', 'PYX': 'C',
-    'PYY': 'N', 'QMM': 'Q', 'QPA': 'C', 'QPH': 'F', 'QUO': 'G', 'R': 'A',
-    'R1A': 'C', 'R4K': 'W', 'RE0': 'W', 'RE3': 'W', 'RIA': 'A', 'RMP': 'A',
-    'RON': 'X', 'RT': 'T', 'RTP': 'N', 'S1H': 'S', 'S2C': 'C', 'S2D': 'A',
-    'S2M': 'T', 'S2P': 'A', 'S4A': 'A', 'S4C': 'C', 'S4G': 'G', 'S4U': 'U',
-    'S6G': 'G', 'SAC': 'S', 'SAH': 'C', 'SAR': 'G', 'SBL': 'S', 'SC': 'C',
-    'SCH': 'C', 'SCS': 'C', 'SCY': 'C', 'SD2': 'X', 'SDG': 'G', 'SDP': 'S',
-    'SEB': 'S', 'SEC': 'A', 'SEG': 'A', 'SEL': 'S', 'SEM': 'S', 'SEN': 'S',
-    'SEP': 'S', 'SER': 'S', 'SET': 'S', 'SGB': 'S', 'SHC': 'C', 'SHP': 'G',
-    'SHR': 'K', 'SIB': 'C', 'SLA': 'P', 'SLR': 'P', 'SLZ': 'K', 'SMC': 'C',
-    'SME': 'M', 'SMF': 'F', 'SMP': 'A', 'SMT': 'T', 'SNC': 'C', 'SNN': 'N',
-    'SOC': 'C', 'SOS': 'N', 'SOY': 'S', 'SPT': 'T', 'SRA': 'A', 'SSU': 'U',
-    'STY': 'Y', 'SUB': 'X', 'SUN': 'S', 'SUR': 'U', 'SVA': 'S', 'SVV': 'S',
-    'SVW': 'S', 'SVX': 'S', 'SVY': 'S', 'SVZ': 'X', 'SYS': 'C', 'T': 'T',
-    'T11': 'F', 'T23': 'T', 'T2S': 'T', 'T2T': 'N', 'T31': 'U', 'T32': 'T',
-    'T36': 'T', 'T37': 'T', 'T38': 'T', 'T39': 'T', 'T3P': 'T', 'T41': 'T',
-    'T48': 'T', 'T49': 'T', 'T4S': 'T', 'T5O': 'U', 'T5S': 'T', 'T66': 'X',
-    'T6A': 'A', 'TA3': 'T', 'TA4': 'X', 'TAF': 'T', 'TAL': 'N', 'TAV': 'D',
-    'TBG': 'V', 'TBM': 'T', 'TC1': 'C', 'TCP': 'T', 'TCQ': 'Y', 'TCR': 'W',
-    'TCY': 'A', 'TDD': 'L', 'TDY': 'T', 'TFE': 'T', 'TFO': 'A', 'TFQ': 'F',
-    'TFT': 'T', 'TGP': 'G', 'TH6': 'T', 'THC': 'T', 'THO': 'X', 'THR': 'T',
-    'THX': 'N', 'THZ': 'R', 'TIH': 'A', 'TLB': 'N', 'TLC': 'T', 'TLN': 'U',
-    'TMB': 'T', 'TMD': 'T', 'TNB': 'C', 'TNR': 'S', 'TOX': 'W', 'TP1': 'T',
-    'TPC': 'C', 'TPG': 'G', 'TPH': 'X', 'TPL': 'W', 'TPO': 'T', 'TPQ': 'Y',
-    'TQI': 'W', 'TQQ': 'W', 'TRF': 'W', 'TRG': 'K', 'TRN': 'W', 'TRO': 'W',
-    'TRP': 'W', 'TRQ': 'W', 'TRW': 'W', 'TRX': 'W', 'TS': 'N', 'TST': 'X',
-    'TT': 'N', 'TTD': 'T', 'TTI': 'U', 'TTM': 'T', 'TTQ': 'W', 'TTS': 'Y',
-    'TY1': 'Y', 'TY2': 'Y', 'TY3': 'Y', 'TY5': 'Y', 'TYB': 'Y', 'TYI': 'Y',
-    'TYJ': 'Y', 'TYN': 'Y', 'TYO': 'Y', 'TYQ': 'Y', 'TYR': 'Y', 'TYS': 'Y',
-    'TYT': 'Y', 'TYU': 'N', 'TYW': 'Y', 'TYX': 'X', 'TYY': 'Y', 'TZB': 'X',
-    'TZO': 'X', 'U': 'U', 'U25': 'U', 'U2L': 'U', 'U2N': 'U', 'U2P': 'U',
-    'U31': 'U', 'U33': 'U', 'U34': 'U', 'U36': 'U', 'U37': 'U', 'U8U': 'U',
-    'UAR': 'U', 'UCL': 'U', 'UD5': 'U', 'UDP': 'N', 'UFP': 'N', 'UFR': 'U',
-    'UFT': 'U', 'UMA': 'A', 'UMP': 'U', 'UMS': 'U', 'UN1': 'X', 'UN2': 'X',
-    'UNK': 'X', 'UR3': 'U', 'URD': 'U', 'US1': 'U', 'US2': 'U', 'US3': 'T',
-    'US5': 'U', 'USM': 'U', 'VAD': 'V', 'VAF': 'V', 'VAL': 'V', 'VB1': 'K',
-    'VDL': 'X', 'VLL': 'X', 'VLM': 'X', 'VMS': 'X', 'VOL': 'X', 'X': 'G',
-    'X2W': 'E', 'X4A': 'N', 'XAD': 'A', 'XAE': 'N', 'XAL': 'A', 'XAR': 'N',
-    'XCL': 'C', 'XCN': 'C', 'XCP': 'X', 'XCR': 'C', 'XCS': 'N', 'XCT': 'C',
-    'XCY': 'C', 'XGA': 'N', 'XGL': 'G', 'XGR': 'G', 'XGU': 'G', 'XPR': 'P',
-    'XSN': 'N', 'XTH': 'T', 'XTL': 'T', 'XTR': 'T', 'XTS': 'G', 'XTY': 'N',
-    'XUA': 'A', 'XUG': 'G', 'XX1': 'K', 'Y': 'A', 'YCM': 'C', 'YG': 'G',
-    'YOF': 'Y', 'YRR': 'N', 'YYG': 'G', 'Z': 'C', 'Z01': 'A', 'ZAD': 'A',
-    'ZAL': 'A', 'ZBC': 'C', 'ZBU': 'U', 'ZCL': 'F', 'ZCY': 'C', 'ZDU': 'U',
-    'ZFB': 'X', 'ZGU': 'G', 'ZHP': 'N', 'ZTH': 'T', 'ZU0': 'T', 'ZZJ': 'A',
-}
-# common_typos_enable
-# pyformat: enable
-
-
-@functools.lru_cache(maxsize=64)
-def letters_three_to_one(restype: str, *, default: str) -> str:
-  """Returns single letter name if one exists otherwise returns default."""
-  return CCD_NAME_TO_ONE_LETTER.get(restype, default)
-
-
-ALA = sys.intern('ALA')
-ARG = sys.intern('ARG')
-ASN = sys.intern('ASN')
-ASP = sys.intern('ASP')
-CYS = sys.intern('CYS')
-GLN = sys.intern('GLN')
-GLU = sys.intern('GLU')
-GLY = sys.intern('GLY')
-HIS = sys.intern('HIS')
-ILE = sys.intern('ILE')
-LEU = sys.intern('LEU')
-LYS = sys.intern('LYS')
-MET = sys.intern('MET')
-PHE = sys.intern('PHE')
-PRO = sys.intern('PRO')
-SER = sys.intern('SER')
-THR = sys.intern('THR')
-TRP = sys.intern('TRP')
-TYR = sys.intern('TYR')
-VAL = sys.intern('VAL')
-UNK = sys.intern('UNK')
-GAP = sys.intern('-')
-
-# Unknown ligand.
-UNL = sys.intern('UNL')
-
-# Non-standard version of MET (with Se instead of S), but often appears in PDB.
-MSE = sys.intern('MSE')
-
-# 20 standard protein amino acids (no unknown).
-PROTEIN_TYPES: tuple[str, ...] = (
-    ALA, ARG, ASN, ASP, CYS, GLN, GLU, GLY, HIS, ILE, LEU, LYS, MET, PHE, PRO,
-    SER, THR, TRP, TYR, VAL,
-)  # pyformat: disable
-
-# 20 standard protein amino acids plus the unknown (UNK) amino acid.
-PROTEIN_TYPES_WITH_UNKNOWN: tuple[str, ...] = PROTEIN_TYPES + (UNK,)
-
-# This is the standard residue order when coding AA type as a number.
-# Reproduce it by taking 3-letter AA codes and sorting them alphabetically.
-# For legacy reasons this only refers to protein residues.
-
-PROTEIN_TYPES_ONE_LETTER: tuple[str, ...] = (
-    'A', 'R', 'N', 'D', 'C', 'Q', 'E', 'G', 'H', 'I', 'L', 'K', 'M', 'F', 'P',
-    'S', 'T', 'W', 'Y', 'V',
-)  # pyformat: disable
-
-PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN: tuple[str, ...] = (
-    PROTEIN_TYPES_ONE_LETTER + ('X',)
-)
-PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN_AND_GAP: tuple[str, ...] = (
-    PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN + (GAP,)
-)
-
-PROTEIN_TYPES_ONE_LETTER_TO_INT: Mapping[str, int] = {
-    r: i for i, r in enumerate(PROTEIN_TYPES_ONE_LETTER)
-}
-PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN_TO_INT: Mapping[str, int] = {
-    r: i for i, r in enumerate(PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN)
-}
-
-PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN_AND_GAP_TO_INT: Mapping[str, int] = {
-    r: i for i, r in enumerate(PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN_AND_GAP)
-}
-
-
-PROTEIN_COMMON_ONE_TO_THREE: Mapping[str, str] = {
-    'A': ALA,
-    'R': ARG,
-    'N': ASN,
-    'D': ASP,
-    'C': CYS,
-    'Q': GLN,
-    'E': GLU,
-    'G': GLY,
-    'H': HIS,
-    'I': ILE,
-    'L': LEU,
-    'K': LYS,
-    'M': MET,
-    'F': PHE,
-    'P': PRO,
-    'S': SER,
-    'T': THR,
-    'W': TRP,
-    'Y': TYR,
-    'V': VAL,
-}
-
-PROTEIN_COMMON_THREE_TO_ONE: Mapping[str, str] = {
-    v: k for k, v in PROTEIN_COMMON_ONE_TO_THREE.items()
-}
-
-A = sys.intern('A')
-G = sys.intern('G')
-C = sys.intern('C')
-U = sys.intern('U')
-T = sys.intern('T')
-
-DA = sys.intern('DA')
-DG = sys.intern('DG')
-DC = sys.intern('DC')
-DT = sys.intern('DT')
-
-UNK_NUCLEIC_ONE_LETTER = sys.intern('N')  # Unknown nucleic acid single letter.
-UNK_RNA = sys.intern('N')  # Unknown RNA.
-UNK_DNA = sys.intern('DN')  # Unknown DNA residue (differs from N).
-
-RNA_TYPES: tuple[str, ...] = (A, G, C, U)
-DNA_TYPES: tuple[str, ...] = (DA, DG, DC, DT)
-
-NUCLEIC_TYPES: tuple[str, ...] = RNA_TYPES + DNA_TYPES
-# Without UNK DNA.
-NUCLEIC_TYPES_WITH_UNKNOWN: tuple[str, ...] = NUCLEIC_TYPES + (
-    UNK_NUCLEIC_ONE_LETTER,
-)
-NUCLEIC_TYPES_WITH_2_UNKS: tuple[str, ...] = NUCLEIC_TYPES + (
-    UNK_RNA,
-    UNK_DNA,
-)
-
-RNA_TYPES_ONE_LETTER_WITH_UNKNOWN: tuple[str, ...] = RNA_TYPES + (UNK_RNA,)
-RNA_TYPES_ONE_LETTER_WITH_UNKNOWN_TO_INT: Mapping[str, int] = {
-    r: i for i, r in enumerate(RNA_TYPES_ONE_LETTER_WITH_UNKNOWN)
-}
-
-DNA_TYPES_WITH_UNKNOWN: tuple[str, ...] = DNA_TYPES + (UNK_DNA,)
-DNA_TYPES_ONE_LETTER: tuple[str, ...] = (A, G, C, T)
-DNA_TYPES_ONE_LETTER_WITH_UNKNOWN: tuple[str, ...] = DNA_TYPES_ONE_LETTER + (
-    UNK_NUCLEIC_ONE_LETTER,
-)
-DNA_TYPES_ONE_LETTER_WITH_UNKNOWN_TO_INT: Mapping[str, int] = {
-    r: i for i, r in enumerate(DNA_TYPES_ONE_LETTER_WITH_UNKNOWN)
-}
-DNA_COMMON_ONE_TO_TWO: Mapping[str, str] = {
-    'A': 'DA',
-    'G': 'DG',
-    'C': 'DC',
-    'T': 'DT',
-}
-
-STANDARD_POLYMER_TYPES: tuple[str, ...] = PROTEIN_TYPES + NUCLEIC_TYPES
-POLYMER_TYPES: tuple[str, ...] = PROTEIN_TYPES_WITH_UNKNOWN + NUCLEIC_TYPES
-POLYMER_TYPES_WITH_UNKNOWN: tuple[str, ...] = (
-    PROTEIN_TYPES_WITH_UNKNOWN + NUCLEIC_TYPES_WITH_UNKNOWN
-)
-POLYMER_TYPES_WITH_GAP: tuple[str, ...] = PROTEIN_TYPES + (GAP,) + NUCLEIC_TYPES
-POLYMER_TYPES_WITH_UNKNOWN_AND_GAP: tuple[str, ...] = (
-    PROTEIN_TYPES_WITH_UNKNOWN + (GAP,) + NUCLEIC_TYPES_WITH_UNKNOWN
-)
-POLYMER_TYPES_WITH_ALL_UNKS_AND_GAP: tuple[str, ...] = (
-    PROTEIN_TYPES_WITH_UNKNOWN + (GAP,) + NUCLEIC_TYPES_WITH_2_UNKS
-)
-
-POLYMER_TYPES_ORDER = {restype: i for i, restype in enumerate(POLYMER_TYPES)}
-
-POLYMER_TYPES_ORDER_WITH_UNKNOWN = {
-    restype: i for i, restype in enumerate(POLYMER_TYPES_WITH_UNKNOWN)
-}
-
-POLYMER_TYPES_ORDER_WITH_UNKNOWN_AND_GAP = {
-    restype: i for i, restype in enumerate(POLYMER_TYPES_WITH_UNKNOWN_AND_GAP)
-}
-
-POLYMER_TYPES_ORDER_WITH_ALL_UNKS_AND_GAP = {
-    restype: i for i, restype in enumerate(POLYMER_TYPES_WITH_ALL_UNKS_AND_GAP)
-}
-
-POLYMER_TYPES_NUM = len(POLYMER_TYPES)  # := 29.
-POLYMER_TYPES_NUM_WITH_UNKNOWN = len(POLYMER_TYPES_WITH_UNKNOWN)  # := 30.
-POLYMER_TYPES_NUM_WITH_GAP = len(POLYMER_TYPES_WITH_GAP)  # := 29.
-POLYMER_TYPES_NUM_WITH_UNKNOWN_AND_GAP = len(
-    POLYMER_TYPES_WITH_UNKNOWN_AND_GAP
-)  # := 31.
-POLYMER_TYPES_NUM_ORDER_WITH_ALL_UNKS_AND_GAP = len(
-    POLYMER_TYPES_WITH_ALL_UNKS_AND_GAP
-)  # := 32.
-
-WATER_TYPES: tuple[str, ...] = ('HOH', 'DOD')
-
-UNKNOWN_TYPES: tuple[str, ...] = (UNK, UNK_RNA, UNK_DNA, UNL)
diff --git a/src/alphafold3/constants/side_chains.py b/src/alphafold3/constants/side_chains.py
deleted file mode 100644
index 95118304912e44f9e0a413853ec61d75016c2e3c..0000000000000000000000000000000000000000
--- a/src/alphafold3/constants/side_chains.py
+++ /dev/null
@@ -1,111 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Constants associated with side chains."""
-
-from collections.abc import Mapping, Sequence
-import itertools
-
-# Format: The list for each AA type contains chi1, chi2, chi3, chi4 in
-# this order (or a relevant subset from chi1 onwards). ALA and GLY don't have
-# chi angles so their chi angle lists are empty.
-CHI_ANGLES_ATOMS: Mapping[str, Sequence[tuple[str, ...]]] = {
-    'ALA': [],
-    # Chi5 in arginine is always 0 +- 5 degrees, so ignore it.
-    'ARG': [
-        ('N', 'CA', 'CB', 'CG'),
-        ('CA', 'CB', 'CG', 'CD'),
-        ('CB', 'CG', 'CD', 'NE'),
-        ('CG', 'CD', 'NE', 'CZ'),
-    ],
-    'ASN': [('N', 'CA', 'CB', 'CG'), ('CA', 'CB', 'CG', 'OD1')],
-    'ASP': [('N', 'CA', 'CB', 'CG'), ('CA', 'CB', 'CG', 'OD1')],
-    'CYS': [('N', 'CA', 'CB', 'SG')],
-    'GLN': [
-        ('N', 'CA', 'CB', 'CG'),
-        ('CA', 'CB', 'CG', 'CD'),
-        ('CB', 'CG', 'CD', 'OE1'),
-    ],
-    'GLU': [
-        ('N', 'CA', 'CB', 'CG'),
-        ('CA', 'CB', 'CG', 'CD'),
-        ('CB', 'CG', 'CD', 'OE1'),
-    ],
-    'GLY': [],
-    'HIS': [('N', 'CA', 'CB', 'CG'), ('CA', 'CB', 'CG', 'ND1')],
-    'ILE': [('N', 'CA', 'CB', 'CG1'), ('CA', 'CB', 'CG1', 'CD1')],
-    'LEU': [('N', 'CA', 'CB', 'CG'), ('CA', 'CB', 'CG', 'CD1')],
-    'LYS': [
-        ('N', 'CA', 'CB', 'CG'),
-        ('CA', 'CB', 'CG', 'CD'),
-        ('CB', 'CG', 'CD', 'CE'),
-        ('CG', 'CD', 'CE', 'NZ'),
-    ],
-    'MET': [
-        ('N', 'CA', 'CB', 'CG'),
-        ('CA', 'CB', 'CG', 'SD'),
-        ('CB', 'CG', 'SD', 'CE'),
-    ],
-    'PHE': [('N', 'CA', 'CB', 'CG'), ('CA', 'CB', 'CG', 'CD1')],
-    'PRO': [('N', 'CA', 'CB', 'CG'), ('CA', 'CB', 'CG', 'CD')],
-    'SER': [('N', 'CA', 'CB', 'OG')],
-    'THR': [('N', 'CA', 'CB', 'OG1')],
-    'TRP': [('N', 'CA', 'CB', 'CG'), ('CA', 'CB', 'CG', 'CD1')],
-    'TYR': [('N', 'CA', 'CB', 'CG'), ('CA', 'CB', 'CG', 'CD1')],
-    'VAL': [('N', 'CA', 'CB', 'CG1')],
-}
-
-CHI_GROUPS_FOR_ATOM = {}
-for res_name, chi_angle_atoms_for_res in CHI_ANGLES_ATOMS.items():
-  for chi_group_i, chi_group in enumerate(chi_angle_atoms_for_res):
-    for atom_i, atom in enumerate(chi_group):
-      CHI_GROUPS_FOR_ATOM.setdefault((res_name, atom), []).append(
-          (chi_group_i, atom_i)
-      )
-
-# Mapping from (residue_name, atom_name) pairs to the atom's chi group index
-# and atom index within that group.
-CHI_GROUPS_FOR_ATOM: Mapping[tuple[str, str], Sequence[tuple[int, int]]] = (
-    CHI_GROUPS_FOR_ATOM
-)
-
-MAX_NUM_CHI_ANGLES: int = 4
-ATOMS_PER_CHI_ANGLE: int = 4
-
-# A list of atoms for each AA type that are involved in chi angle calculations.
-CHI_ATOM_SETS: Mapping[str, set[str]] = {
-    residue_name: set(itertools.chain(*atoms))
-    for residue_name, atoms in CHI_ANGLES_ATOMS.items()
-}
-
-# If chi angles given in fixed-length array, this matrix determines how to mask
-# them for each AA type. The order is as per restype_order (see below).
-CHI_ANGLES_MASK: Sequence[Sequence[float]] = (
-    (0.0, 0.0, 0.0, 0.0),  # ALA
-    (1.0, 1.0, 1.0, 1.0),  # ARG
-    (1.0, 1.0, 0.0, 0.0),  # ASN
-    (1.0, 1.0, 0.0, 0.0),  # ASP
-    (1.0, 0.0, 0.0, 0.0),  # CYS
-    (1.0, 1.0, 1.0, 0.0),  # GLN
-    (1.0, 1.0, 1.0, 0.0),  # GLU
-    (0.0, 0.0, 0.0, 0.0),  # GLY
-    (1.0, 1.0, 0.0, 0.0),  # HIS
-    (1.0, 1.0, 0.0, 0.0),  # ILE
-    (1.0, 1.0, 0.0, 0.0),  # LEU
-    (1.0, 1.0, 1.0, 1.0),  # LYS
-    (1.0, 1.0, 1.0, 0.0),  # MET
-    (1.0, 1.0, 0.0, 0.0),  # PHE
-    (1.0, 1.0, 0.0, 0.0),  # PRO
-    (1.0, 0.0, 0.0, 0.0),  # SER
-    (1.0, 0.0, 0.0, 0.0),  # THR
-    (1.0, 1.0, 0.0, 0.0),  # TRP
-    (1.0, 1.0, 0.0, 0.0),  # TYR
-    (1.0, 0.0, 0.0, 0.0),  # VAL
-)
diff --git a/src/alphafold3/cpp.cc b/src/alphafold3/cpp.cc
deleted file mode 100644
index bc3a927274d0a23c9bdb5a726f5216bfa028996c..0000000000000000000000000000000000000000
--- a/src/alphafold3/cpp.cc
+++ /dev/null
@@ -1,45 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include "alphafold3/data/cpp/msa_profile_pybind.h"
-#include "alphafold3/model/mkdssp_pybind.h"
-#include "alphafold3/parsers/cpp/cif_dict_pybind.h"
-#include "alphafold3/parsers/cpp/fasta_iterator_pybind.h"
-#include "alphafold3/parsers/cpp/msa_conversion_pybind.h"
-#include "alphafold3/structure/cpp/aggregation_pybind.h"
-#include "alphafold3/structure/cpp/membership_pybind.h"
-#include "alphafold3/structure/cpp/mmcif_atom_site_pybind.h"
-#include "alphafold3/structure/cpp/mmcif_layout_pybind.h"
-#include "alphafold3/structure/cpp/mmcif_struct_conn_pybind.h"
-#include "alphafold3/structure/cpp/mmcif_utils_pybind.h"
-#include "alphafold3/structure/cpp/string_array_pybind.h"
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-namespace {
-
-// Include all modules as submodules to simplify building.
-PYBIND11_MODULE(cpp, m) {
-  RegisterModuleCifDict(m.def_submodule("cif_dict"));
-  RegisterModuleFastaIterator(m.def_submodule("fasta_iterator"));
-  RegisterModuleMsaConversion(m.def_submodule("msa_conversion"));
-  RegisterModuleMmcifLayout(m.def_submodule("mmcif_layout"));
-  RegisterModuleMmcifStructConn(m.def_submodule("mmcif_struct_conn"));
-  RegisterModuleMembership(m.def_submodule("membership"));
-  RegisterModuleMmcifUtils(m.def_submodule("mmcif_utils"));
-  RegisterModuleAggregation(m.def_submodule("aggregation"));
-  RegisterModuleStringArray(m.def_submodule("string_array"));
-  RegisterModuleMmcifAtomSite(m.def_submodule("mmcif_atom_site"));
-  RegisterModuleMkdssp(m.def_submodule("mkdssp"));
-  RegisterModuleMsaProfile(m.def_submodule("msa_profile"));
-}
-
-}  // namespace
-}  // namespace alphafold3
diff --git a/src/alphafold3/data/cpp/msa_profile_pybind.cc b/src/alphafold3/data/cpp/msa_profile_pybind.cc
deleted file mode 100644
index 10ba5884d3e0a51cfd98364522a505379ccb7e4b..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/cpp/msa_profile_pybind.cc
+++ /dev/null
@@ -1,79 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <algorithm>
-
-#include "absl/strings/str_cat.h"
-#include "pybind11/cast.h"
-#include "pybind11/numpy.h"
-#include "pybind11/pybind11.h"
-
-namespace {
-
-namespace py = pybind11;
-
-py::array_t<double> ComputeMsaProfile(
-    const py::array_t<int, py::array::c_style>& msa, int num_residue_types) {
-  if (msa.size() == 0) {
-    throw py::value_error("The MSA must be non-empty.");
-  }
-  if (msa.ndim() != 2) {
-    throw py::value_error(absl::StrCat("The MSA must be rectangular, got ",
-                                       msa.ndim(), "-dimensional MSA array."));
-  }
-  const int msa_depth = msa.shape()[0];
-  const int sequence_length = msa.shape()[1];
-
-  py::array_t<double> profile({sequence_length, num_residue_types});
-  std::fill(profile.mutable_data(), profile.mutable_data() + profile.size(),
-            0.0f);
-  auto profile_unchecked = profile.mutable_unchecked<2>();
-
-  const double normalized_count = 1.0 / msa_depth;
-  const int* msa_it = msa.data();
-  for (int row_index = 0; row_index < msa_depth; ++row_index) {
-    for (int column_index = 0; column_index < sequence_length; ++column_index) {
-      const int residue_code = *(msa_it++);
-      if (residue_code < 0 || residue_code >= num_residue_types) {
-        throw py::value_error(
-            absl::StrCat("All residue codes must be positive and smaller than "
-                         "num_residue_types ",
-                         num_residue_types, ", got ", residue_code));
-      }
-      profile_unchecked(column_index, residue_code) += normalized_count;
-    }
-  }
-  return profile;
-}
-
-constexpr char kComputeMsaProfileDoc[] = R"(
-Computes MSA profile for the given encoded MSA.
-
-Args:
-  msa: A Numpy array of shape (num_msa, num_res) with the integer coded MSA.
-  num_residue_types: Integer that determines the number of unique residue types.
-    This will determine the shape of the output profile.
-
-Returns:
-  A float Numpy array of shape (num_res, num_residue_types) with residue
-  frequency (residue type count normalized by MSA depth) for every column of the
-  MSA.
-)";
-
-}  // namespace
-
-namespace alphafold3 {
-
-void RegisterModuleMsaProfile(pybind11::module m) {
-  m.def("compute_msa_profile", &ComputeMsaProfile, py::arg("msa"),
-        py::arg("num_residue_types"), py::doc(kComputeMsaProfileDoc + 1));
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/data/cpp/msa_profile_pybind.h b/src/alphafold3/data/cpp/msa_profile_pybind.h
deleted file mode 100644
index 19ac96dc5ccd48abf1d833cc29598f4afb784732..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/cpp/msa_profile_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_DATA_PYTHON_MSA_PROFILE_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_DATA_PYTHON_MSA_PROFILE_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleMsaProfile(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_DATA_PYTHON_MSA_PROFILE_PYBIND_H_
diff --git a/src/alphafold3/data/featurisation.py b/src/alphafold3/data/featurisation.py
deleted file mode 100644
index bdbbb3c4a6d5dc2410a17068c9ffd8ad569a601e..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/featurisation.py
+++ /dev/null
@@ -1,97 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""AlphaFold 3 featurisation pipeline."""
-
-from collections.abc import Sequence
-import datetime
-import time
-
-from alphafold3.common import folding_input
-from alphafold3.constants import chemical_components
-from alphafold3.model import features
-from alphafold3.model.pipeline import pipeline
-import numpy as np
-
-
-def validate_fold_input(fold_input: folding_input.Input):
-  """Validates the fold input contains MSA and templates for featurisation."""
-  for i, chain in enumerate(fold_input.protein_chains):
-    if chain.unpaired_msa is None:
-      raise ValueError(f'Protein chain {i + 1} is missing unpaired MSA.')
-    if chain.paired_msa is None:
-      raise ValueError(f'Protein chain {i + 1} is missing paired MSA.')
-    if chain.templates is None:
-      raise ValueError(f'Protein chain {i + 1} is missing Templates.')
-  for i, chain in enumerate(fold_input.rna_chains):
-    if chain.unpaired_msa is None:
-      raise ValueError(f'RNA chain {i + 1} is missing unpaired MSA.')
-
-
-def featurise_input(
-    fold_input: folding_input.Input,
-    ccd: chemical_components.Ccd,
-    buckets: Sequence[int] | None,
-    ref_max_modified_date: datetime.date | None = None,
-    conformer_max_iterations: int | None = None,
-    verbose: bool = False,
-) -> Sequence[features.BatchDict]:
-  """Featurise the folding input.
-
-  Args:
-    fold_input: The input to featurise.
-    ccd: The chemical components dictionary.
-    buckets: Bucket sizes to pad the data to, to avoid excessive re-compilation
-      of the model. If None, calculate the appropriate bucket size from the
-      number of tokens. If not None, must be a sequence of at least one integer,
-      in strictly increasing order. Will raise an error if the number of tokens
-      is more than the largest bucket size.
-    ref_max_modified_date: Optional maximum date that controls whether to allow
-      use of model coordinates for a chemical component from the CCD if RDKit
-      conformer generation fails and the component does not have ideal
-      coordinates set. Only for components that have been released before this
-      date the model coordinates can be used as a fallback.
-    conformer_max_iterations: Optional override for maximum number of iterations
-      to run for RDKit conformer search.
-    verbose: Whether to print progress messages.
-
-  Returns:
-    A featurised batch for each rng_seed in the input.
-  """
-  validate_fold_input(fold_input)
-
-  # Set up data pipeline for single use.
-  data_pipeline = pipeline.WholePdbPipeline(
-      config=pipeline.WholePdbPipeline.Config(
-          buckets=buckets,
-          ref_max_modified_date=ref_max_modified_date,
-          conformer_max_iterations=conformer_max_iterations,
-      ),
-  )
-
-  batches = []
-  for rng_seed in fold_input.rng_seeds:
-    featurisation_start_time = time.time()
-    if verbose:
-      print(f'Featurising data with seed {rng_seed}.')
-    batch = data_pipeline.process_item(
-        fold_input=fold_input,
-        ccd=ccd,
-        random_state=np.random.RandomState(rng_seed),
-        random_seed=rng_seed,
-    )
-    if verbose:
-      print(
-          f'Featurising data with seed {rng_seed} took'
-          f' {time.time() - featurisation_start_time:.2f} seconds.'
-      )
-    batches.append(batch)
-
-  return batches
diff --git a/src/alphafold3/data/msa.py b/src/alphafold3/data/msa.py
deleted file mode 100644
index 7c8e2eac63534d064462484673ba05e69893234e..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/msa.py
+++ /dev/null
@@ -1,343 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Functions for getting MSA and calculating alignment features."""
-
-from collections.abc import MutableMapping, Sequence
-import string
-from typing import Self
-
-from absl import logging
-from alphafold3.constants import mmcif_names
-from alphafold3.data import msa_config
-from alphafold3.data import msa_features
-from alphafold3.data import parsers
-from alphafold3.data.tools import jackhmmer
-from alphafold3.data.tools import msa_tool
-from alphafold3.data.tools import nhmmer
-import numpy as np
-
-
-class Error(Exception):
-  """Error indicatating a problem with MSA Search."""
-
-
-def _featurize(seq: str, chain_poly_type: str) -> str | list[int]:
-  if mmcif_names.is_standard_polymer_type(chain_poly_type):
-    featurized_seqs, _ = msa_features.extract_msa_features(
-        msa_sequences=[seq], chain_poly_type=chain_poly_type
-    )
-    return featurized_seqs[0].tolist()
-  # For anything else simply require an identical match.
-  return seq
-
-
-def sequences_are_feature_equivalent(
-    sequence1: str,
-    sequence2: str,
-    chain_poly_type: str,
-) -> bool:
-  feat1 = _featurize(sequence1, chain_poly_type)
-  feat2 = _featurize(sequence2, chain_poly_type)
-  return feat1 == feat2
-
-
-class Msa:
-  """Multiple Sequence Alignment container with methods for manipulating it."""
-
-  def __init__(
-      self,
-      query_sequence: str,
-      chain_poly_type: str,
-      sequences: Sequence[str],
-      descriptions: Sequence[str],
-      deduplicate: bool = True,
-  ):
-    """Raw constructor, prefer using the from_{a3m,multiple_msas} class methods.
-
-    The first sequence must be equal (in featurised form) to the query sequence.
-    If sequences/descriptions are empty, they will be initialised to the query.
-
-    Args:
-      query_sequence: The sequence that was used to search for MSA.
-      chain_poly_type: Polymer type of the query sequence, see mmcif_names.
-      sequences: The sequences returned by the MSA search tool.
-      descriptions: Metadata for the sequences returned by the MSA search tool.
-      deduplicate: If True, the MSA sequences will be deduplicated in the input
-        order. Lowercase letters (insertions) are ignored when deduplicating.
-    """
-    if len(sequences) != len(descriptions):
-      raise ValueError('The number of sequences and descriptions must match.')
-
-    self.query_sequence = query_sequence
-    self.chain_poly_type = chain_poly_type
-
-    if not deduplicate:
-      self.sequences = sequences
-      self.descriptions = descriptions
-    else:
-      self.sequences = []
-      self.descriptions = []
-      # A replacement table that removes all lowercase characters.
-      deletion_table = str.maketrans('', '', string.ascii_lowercase)
-      unique_sequences = set()
-      for seq, desc in zip(sequences, descriptions, strict=True):
-        # Using string.translate is faster than re.sub('[a-z]+', '').
-        sequence_no_deletions = seq.translate(deletion_table)
-        if sequence_no_deletions not in unique_sequences:
-          unique_sequences.add(sequence_no_deletions)
-          self.sequences.append(seq)
-          self.descriptions.append(desc)
-
-    # Make sure the MSA always has at least the query.
-    self.sequences = self.sequences or [query_sequence]
-    self.descriptions = self.descriptions or ['Original query']
-
-    # Check if the 1st MSA sequence matches the query sequence. Since it may be
-    # mutated by the search tool (jackhmmer) check using the featurized version.
-    if not sequences_are_feature_equivalent(
-        self.sequences[0], query_sequence, chain_poly_type
-    ):
-      raise ValueError(
-          f'First MSA sequence {self.sequences[0]} is not the {query_sequence=}'
-      )
-
-  @classmethod
-  def from_multiple_msas(
-      cls, msas: Sequence[Self], deduplicate: bool = True
-  ) -> Self:
-    """Initializes the MSA from multiple MSAs.
-
-    Args:
-      msas: A sequence of Msa objects representing individual MSAs produced by
-        different tools/dbs.
-      deduplicate: If True, the MSA sequences will be deduplicated in the input
-        order. Lowercase letters (insertions) are ignored when deduplicating.
-
-    Returns:
-      An Msa object created by merging multiple MSAs.
-    """
-    if not msas:
-      raise ValueError('At least one MSA must be provided.')
-
-    query_sequence = msas[0].query_sequence
-    chain_poly_type = msas[0].chain_poly_type
-    sequences = []
-    descriptions = []
-
-    for msa in msas:
-      if msa.query_sequence != query_sequence:
-        raise ValueError(
-            f'Query sequences must match: {[m.query_sequence for m in msas]}'
-        )
-      if msa.chain_poly_type != chain_poly_type:
-        raise ValueError(
-            f'Chain poly types must match: {[m.chain_poly_type for m in msas]}'
-        )
-      sequences.extend(msa.sequences)
-      descriptions.extend(msa.descriptions)
-
-    return cls(
-        query_sequence=query_sequence,
-        chain_poly_type=chain_poly_type,
-        sequences=sequences,
-        descriptions=descriptions,
-        deduplicate=deduplicate,
-    )
-
-  @classmethod
-  def from_multiple_a3ms(
-      cls, a3ms: Sequence[str], chain_poly_type: str, deduplicate: bool = True
-  ) -> Self:
-    """Initializes the MSA from multiple A3M strings.
-
-    Args:
-      a3ms: A sequence of A3M strings representing individual MSAs produced by
-        different tools/dbs.
-      chain_poly_type: Polymer type of the query sequence, see mmcif_names.
-      deduplicate: If True, the MSA sequences will be deduplicated in the input
-        order. Lowercase letters (insertions) are ignored when deduplicating.
-
-    Returns:
-      An Msa object created by merging multiple A3Ms.
-    """
-    if not a3ms:
-      raise ValueError('At least one A3M must be provided.')
-
-    query_sequence = None
-    all_sequences = []
-    all_descriptions = []
-
-    for a3m in a3ms:
-      sequences, descriptions = parsers.parse_fasta(a3m)
-      if query_sequence is None:
-        query_sequence = sequences[0]
-
-      if sequences[0] != query_sequence:
-        raise ValueError(
-            f'Query sequences must match: {sequences[0]=} != {query_sequence=}'
-        )
-      all_sequences.extend(sequences)
-      all_descriptions.extend(descriptions)
-
-    return cls(
-        query_sequence=query_sequence,
-        chain_poly_type=chain_poly_type,
-        sequences=all_sequences,
-        descriptions=all_descriptions,
-        deduplicate=deduplicate,
-    )
-
-  @classmethod
-  def from_a3m(
-      cls,
-      query_sequence: str,
-      chain_poly_type: str,
-      a3m: str,
-      max_depth: int | None = None,
-      deduplicate: bool = True,
-  ) -> Self:
-    """Parses the single A3M and builds the Msa object."""
-    sequences, descriptions = parsers.parse_fasta(a3m)
-
-    if max_depth is not None and 0 < max_depth < len(sequences):
-      logging.info(
-          'MSA cropped from depth of %d to %d for %s.',
-          len(sequences),
-          max_depth,
-          query_sequence,
-      )
-      sequences = sequences[:max_depth]
-      descriptions = descriptions[:max_depth]
-
-    return cls(
-        query_sequence=query_sequence,
-        chain_poly_type=chain_poly_type,
-        sequences=sequences,
-        descriptions=descriptions,
-        deduplicate=deduplicate,
-    )
-
-  @classmethod
-  def from_empty(cls, query_sequence: str, chain_poly_type: str) -> Self:
-    """Creates an empty Msa containing just the query sequence."""
-    return cls(
-        query_sequence=query_sequence,
-        chain_poly_type=chain_poly_type,
-        sequences=[],
-        descriptions=[],
-        deduplicate=False,
-    )
-
-  @property
-  def depth(self) -> int:
-    return len(self.sequences)
-
-  def __repr__(self) -> str:
-    return f'Msa({self.depth} sequences, {self.chain_poly_type})'
-
-  def to_a3m(self) -> str:
-    """Returns the MSA in the A3M format."""
-    a3m_lines = []
-    for desc, seq in zip(self.descriptions, self.sequences, strict=True):
-      a3m_lines.append(f'>{desc}')
-      a3m_lines.append(seq)
-    return '\n'.join(a3m_lines) + '\n'
-
-  def featurize(self) -> MutableMapping[str, np.ndarray]:
-    """Featurises the MSA and returns a map of feature names to features.
-
-    Returns:
-      A dictionary mapping feature names to values.
-
-    Raises:
-      msa.Error:
-        * If the sequences in the MSA don't have the same length after deletions
-          (lower case letters) are removed.
-        * If the MSA contains an unknown amino acid code.
-        * If there are no sequences after aligning.
-    """
-    try:
-      msa, deletion_matrix = msa_features.extract_msa_features(
-          msa_sequences=self.sequences, chain_poly_type=self.chain_poly_type
-      )
-    except ValueError as e:
-      raise Error(f'Error extracting MSA or deletion features: {e}') from e
-
-    if msa.shape == (0, 0):
-      raise Error(f'Empty MSA feature for {self}')
-
-    species_ids = msa_features.extract_species_ids(self.descriptions)
-
-    return {
-        'msa_species_identifiers': np.array(species_ids, dtype=object),
-        'num_alignments': np.array(self.depth, dtype=np.int32),
-        'msa': msa,
-        'deletion_matrix_int': deletion_matrix,
-    }
-
-
-def get_msa_tool(
-    msa_tool_config: msa_config.JackhmmerConfig | msa_config.NhmmerConfig,
-) -> msa_tool.MsaTool:
-  """Returns the requested MSA tool."""
-
-  match msa_tool_config:
-    case msa_config.JackhmmerConfig():
-      return jackhmmer.Jackhmmer(
-          binary_path=msa_tool_config.binary_path,
-          database_path=msa_tool_config.database_config.path,
-          n_cpu=msa_tool_config.n_cpu,
-          n_iter=msa_tool_config.n_iter,
-          e_value=msa_tool_config.e_value,
-          z_value=msa_tool_config.z_value,
-          max_sequences=msa_tool_config.max_sequences,
-      )
-    case msa_config.NhmmerConfig():
-      return nhmmer.Nhmmer(
-          binary_path=msa_tool_config.binary_path,
-          hmmalign_binary_path=msa_tool_config.hmmalign_binary_path,
-          hmmbuild_binary_path=msa_tool_config.hmmbuild_binary_path,
-          database_path=msa_tool_config.database_config.path,
-          n_cpu=msa_tool_config.n_cpu,
-          e_value=msa_tool_config.e_value,
-          max_sequences=msa_tool_config.max_sequences,
-          alphabet=msa_tool_config.alphabet,
-      )
-    case _:
-      raise ValueError(f'Unknown MSA tool: {msa_tool_config}.')
-
-
-def get_msa(
-    target_sequence: str,
-    run_config: msa_config.RunConfig,
-    chain_poly_type: str,
-    deduplicate: bool = False,
-) -> Msa:
-  """Computes the MSA for a given query sequence.
-
-  Args:
-    target_sequence: The target amino-acid sequence.
-    run_config: MSA run configuration.
-    chain_poly_type: The type of chain for which to get an MSA.
-    deduplicate: If True, the MSA sequences will be deduplicated in the input
-      order. Lowercase letters (insertions) are ignored when deduplicating.
-
-  Returns:
-    Aligned MSA sequences.
-  """
-
-  return Msa.from_a3m(
-      query_sequence=target_sequence,
-      chain_poly_type=chain_poly_type,
-      a3m=get_msa_tool(run_config.config).query(target_sequence).a3m,
-      max_depth=run_config.crop_size,
-      deduplicate=deduplicate,
-  )
diff --git a/src/alphafold3/data/msa_config.py b/src/alphafold3/data/msa_config.py
deleted file mode 100644
index 4670010bf75123229831f41f6e55275186158e08..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/msa_config.py
+++ /dev/null
@@ -1,167 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Genetic search config settings for data pipelines."""
-
-import dataclasses
-import datetime
-from typing import Self
-from alphafold3.constants import mmcif_names
-
-
-def _validate_chain_poly_type(chain_poly_type: str) -> None:
-  if chain_poly_type not in mmcif_names.STANDARD_POLYMER_CHAIN_TYPES:
-    raise ValueError(
-        'chain_poly_type must be one of'
-        f' {mmcif_names.STANDARD_POLYMER_CHAIN_TYPES}: {chain_poly_type}'
-    )
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True, slots=True)
-class DatabaseConfig:
-  """Configuration for a database."""
-
-  name: str
-  path: str
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True, slots=True)
-class JackhmmerConfig:
-  """Configuration for a jackhmmer run.
-
-  Attributes:
-      binary_path: Path to the binary of the msa tool.
-      database_config: Database configuration.
-      n_cpu: An integer with the number of CPUs to use.
-      n_iter: An integer with the number of database search iterations.
-      e_value: e-value for the database lookup.
-      z_value: The Z-value representing the number of comparisons done (i.e
-        correct database size) for E-value calculation.
-      max_sequences: Max sequences to return in MSA.
-  """
-
-  binary_path: str
-  database_config: DatabaseConfig
-  n_cpu: int
-  n_iter: int
-  e_value: float
-  z_value: float | int | None
-  max_sequences: int
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True, slots=True)
-class NhmmerConfig:
-  """Configuration for a nhmmer run.
-
-  Attributes:
-      binary_path: Path to the binary of the msa tool.
-      hmmalign_binary_path: Path to the hmmalign binary.
-      hmmbuild_binary_path: Path to the hmmbuild binary.
-      database_config: Database configuration.
-      n_cpu: An integer with the number of CPUs to use.
-      e_value: e-value for the database lookup.
-      max_sequences: Max sequences to return in MSA.
-      alphabet: The alphabet when building a profile with hmmbuild.
-  """
-
-  binary_path: str
-  hmmalign_binary_path: str
-  hmmbuild_binary_path: str
-  database_config: DatabaseConfig
-  n_cpu: int
-  e_value: float
-  max_sequences: int
-  alphabet: str | None
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True, slots=True)
-class RunConfig:
-  """Configuration for an MSA run.
-
-  Attributes:
-    config: MSA tool config.
-    chain_poly_type: The chain type for which the tools will be run.
-    crop_size: The maximum number of sequences to keep in the MSA. If None, all
-      sequences are kept. Note that the query is included in the MSA, so it
-      doesn't make sense to set this to less than 2.
-  """
-
-  config: JackhmmerConfig | NhmmerConfig
-  chain_poly_type: str
-  crop_size: int | None
-
-  def __post_init__(self):
-    if self.crop_size is not None and self.crop_size < 2:
-      raise ValueError(f'crop_size must be None or >= 2: {self.crop_size}')
-
-    _validate_chain_poly_type(self.chain_poly_type)
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True, slots=True)
-class HmmsearchConfig:
-  """Configuration for a hmmsearch."""
-
-  hmmsearch_binary_path: str
-  hmmbuild_binary_path: str
-
-  e_value: float
-  inc_e: float
-  dom_e: float
-  incdom_e: float
-  alphabet: str = 'amino'
-  filter_f1: float | None = None
-  filter_f2: float | None = None
-  filter_f3: float | None = None
-  filter_max: bool = False
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True, slots=True)
-class TemplateToolConfig:
-  """Configuration for a template tool."""
-
-  database_path: str
-  chain_poly_type: str
-  hmmsearch_config: HmmsearchConfig
-  max_a3m_query_sequences: int | None = 300
-
-  def __post_init__(self):
-    _validate_chain_poly_type(self.chain_poly_type)
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True, slots=True)
-class TemplateFilterConfig:
-  """Configuration for a template filter."""
-
-  max_subsequence_ratio: float | None
-  min_align_ratio: float | None
-  min_hit_length: int | None
-  deduplicate_sequences: bool
-  max_hits: int | None
-  max_template_date: datetime.date
-
-  @classmethod
-  def no_op_filter(cls) -> Self:
-    """Returns a config for filter that keeps everything."""
-    return cls(
-        max_subsequence_ratio=None,
-        min_align_ratio=None,
-        min_hit_length=None,
-        deduplicate_sequences=False,
-        max_hits=None,
-        max_template_date=datetime.date(3000, 1, 1),  # Very far in the future.
-    )
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True, slots=True)
-class TemplatesConfig:
-  """Configuration for the template search pipeline."""
-
-  template_tool_config: TemplateToolConfig
-  filter_config: TemplateFilterConfig
diff --git a/src/alphafold3/data/msa_features.py b/src/alphafold3/data/msa_features.py
deleted file mode 100644
index 2c385a767cd2edfc595c9fbdc473d19ade12a4da..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/msa_features.py
+++ /dev/null
@@ -1,202 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Utilities for computing MSA features."""
-
-from collections.abc import Sequence
-import re
-from alphafold3.constants import mmcif_names
-import numpy as np
-
-_PROTEIN_TO_ID = {
-    'A': 0,
-    'B': 3,  # Same as D.
-    'C': 4,
-    'D': 3,
-    'E': 6,
-    'F': 13,
-    'G': 7,
-    'H': 8,
-    'I': 9,
-    'J': 20,  # Same as unknown (X).
-    'K': 11,
-    'L': 10,
-    'M': 12,
-    'N': 2,
-    'O': 20,  # Same as unknown (X).
-    'P': 14,
-    'Q': 5,
-    'R': 1,
-    'S': 15,
-    'T': 16,
-    'U': 4,  # Same as C.
-    'V': 19,
-    'W': 17,
-    'X': 20,
-    'Y': 18,
-    'Z': 6,  # Same as E.
-    '-': 21,
-}
-
-_RNA_TO_ID = {
-    # Map non-standard residues to UNK_NUCLEIC (N) -> 30
-    **{chr(i): 30 for i in range(ord('A'), ord('Z') + 1)},
-    # Continue the RNA indices from where Protein indices left off.
-    '-': 21,
-    'A': 22,
-    'G': 23,
-    'C': 24,
-    'U': 25,
-}
-
-_DNA_TO_ID = {
-    # Map non-standard residues to UNK_NUCLEIC (N) -> 30
-    **{chr(i): 30 for i in range(ord('A'), ord('Z') + 1)},
-    # Continue the DNA indices from where DNA indices left off.
-    '-': 21,
-    'A': 26,
-    'G': 27,
-    'C': 28,
-    'T': 29,
-}
-
-
-def extract_msa_features(
-    msa_sequences: Sequence[str], chain_poly_type: str
-) -> tuple[np.ndarray, np.ndarray]:
-  """Extracts MSA features.
-
-  Example:
-  The input raw MSA is: `[["AAAAAA"], ["Ai-CiDiiiEFa"]]`
-  The output MSA will be: `[["AAAAAA"], ["A-CDEF"]]`
-  The deletions will be: `[[0, 0, 0, 0, 0, 0], [0, 1, 0, 1, 3, 0]]`
-
-  Args:
-    msa_sequences: A list of strings, each string with one MSA sequence. Each
-      string must have the same, constant number of non-lowercase (matching)
-      residues.
-    chain_poly_type: Either 'polypeptide(L)' (protein), 'polyribonucleotide'
-      (RNA), or 'polydeoxyribonucleotide' (DNA). Use the appropriate string
-      constant from mmcif_names.py.
-
-  Returns:
-    A tuple with:
-    * MSA array of shape (num_seq, num_res) that contains only the uppercase
-      characters or gaps (-) from the original MSA.
-    * Deletions array of shape (num_seq, num_res) that contains the number
-      of deletions (lowercase letters in the MSA) to the left from each
-      non-deleted residue (uppercase letters in the MSA).
-
-  Raises:
-    ValueError if any of the preconditions are not met.
-  """
-
-  # Select the appropriate character map based on the chain type.
-  if chain_poly_type == mmcif_names.RNA_CHAIN:
-    char_map = _RNA_TO_ID
-  elif chain_poly_type == mmcif_names.DNA_CHAIN:
-    char_map = _DNA_TO_ID
-  elif chain_poly_type == mmcif_names.PROTEIN_CHAIN:
-    char_map = _PROTEIN_TO_ID
-  else:
-    raise ValueError(f'{chain_poly_type=} invalid.')
-
-  # Handle empty MSA.
-  if not msa_sequences:
-    empty_msa = np.array([], dtype=np.int32).reshape((0, 0))
-    empty_deletions = np.array([], dtype=np.int32).reshape((0, 0))
-    return empty_msa, empty_deletions
-
-  # Get the number of rows and columns in the MSA.
-  num_rows = len(msa_sequences)
-  num_cols = sum(1 for c in msa_sequences[0] if c in char_map)
-
-  # Initialize the output arrays.
-  msa_arr = np.zeros((num_rows, num_cols), dtype=np.int32)
-  deletions_arr = np.zeros((num_rows, num_cols), dtype=np.int32)
-
-  # Populate the output arrays.
-  for problem_row, msa_sequence in enumerate(msa_sequences):
-    deletion_count = 0
-    upper_count = 0
-    problem_col = 0
-    problems = []
-    for current in msa_sequence:
-      msa_id = char_map.get(current, -1)
-      if msa_id == -1:
-        if not current.islower():
-          problems.append(f'({problem_row}, {problem_col}):{current}')
-        deletion_count += 1
-      else:
-        # Check the access is safe before writing to the array.
-        # We don't need to check problem_row since it's guaranteed to be within
-        # the array bounds, while upper_count is incremented in the loop.
-        if upper_count < deletions_arr.shape[1]:
-          deletions_arr[problem_row, upper_count] = deletion_count
-          msa_arr[problem_row, upper_count] = msa_id
-        deletion_count = 0
-        upper_count += 1
-      problem_col += 1
-    if problems:
-      raise ValueError(
-          f"Unknown residues in MSA: {', '.join(problems)}. "
-          f'target_sequence: {msa_sequences[0]}'
-      )
-    if upper_count != num_cols:
-      raise ValueError(
-          'Invalid shape all strings must have the same number '
-          'of non-lowercase characters; First string has '
-          f"{num_cols} non-lowercase characters but '{msa_sequence}' has "
-          f'{upper_count}. target_sequence: {msa_sequences[0]}'
-      )
-
-  return msa_arr, deletions_arr
-
-
-# UniProtKB SwissProt/TrEMBL dbs have the following description format:
-# `db|UniqueIdentifier|EntryName`, e.g. `sp|P0C2L1|A3X1_LOXLA` or
-# `tr|A0A146SKV9|A0A146SKV9_FUNHE`.
-_UNIPROT_ENTRY_NAME_REGEX = re.compile(
-    # UniProtKB TrEMBL or SwissProt database.
-    r'(?:tr|sp)\|'
-    # A primary accession number of the UniProtKB entry.
-    r'(?:[A-Z0-9]{6,10})'
-    # Occasionally there is an isoform suffix (e.g. _1 or _10) which we ignore.
-    r'(?:_\d+)?\|'
-    # TrEMBL: Same as AccessionId (6-10 characters).
-    # SwissProt: A mnemonic protein identification code (1-5 characters).
-    r'(?:[A-Z0-9]{1,10}_)'
-    # A mnemonic species identification code.
-    r'(?P<SpeciesId>[A-Z0-9]{1,5})'
-)
-
-
-def extract_species_ids(msa_descriptions: Sequence[str]) -> Sequence[str]:
-  """Extracts species ID from MSA UniProtKB sequence identifiers.
-
-  Args:
-    msa_descriptions: The descriptions (the FASTA/A3M comment line) for each of
-      the sequences.
-
-  Returns:
-    Extracted UniProtKB species IDs if there is a regex match for each
-    description line, blank if the regex doesn't match.
-  """
-  species_ids = []
-  for msa_description in msa_descriptions:
-    msa_description = msa_description.strip()
-    match = _UNIPROT_ENTRY_NAME_REGEX.match(msa_description)
-    if match:
-      species_ids.append(match.group('SpeciesId'))
-    else:
-      # Handle cases where the regex doesn't match
-      # (e.g., append None or raise an error depending on your needs)
-      species_ids.append('')
-  return species_ids
diff --git a/src/alphafold3/data/msa_identifiers.py b/src/alphafold3/data/msa_identifiers.py
deleted file mode 100644
index bd939ef16e69c4b136dc71454329da8a98ba7baf..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/msa_identifiers.py
+++ /dev/null
@@ -1,85 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Utilities for extracting identifiers from MSA sequence descriptions."""
-
-import dataclasses
-import re
-
-
-# Sequences coming from UniProtKB database come in the
-# `db|UniqueIdentifier|EntryName` format, e.g. `tr|A0A146SKV9|A0A146SKV9_FUNHE`
-# or `sp|P0C2L1|A3X1_LOXLA` (for TREMBL/Swiss-Prot respectively).
-_UNIPROT_PATTERN = re.compile(
-    r"""
-    ^
-    # UniProtKB/TrEMBL or UniProtKB/Swiss-Prot
-    (?:tr|sp)
-    \|
-    # A primary accession number of the UniProtKB entry.
-    (?P<AccessionIdentifier>[A-Za-z0-9]{6,10})
-    # Occasionally there is a _0 or _1 isoform suffix, which we ignore.
-    (?:_\d)?
-    \|
-    # TREMBL repeats the accession ID here. Swiss-Prot has a mnemonic
-    # protein ID code.
-    (?:[A-Za-z0-9]+)
-    _
-    # A mnemonic species identification code.
-    (?P<SpeciesIdentifier>([A-Za-z0-9]){1,5})
-    # Small BFD uses a final value after an underscore, which we ignore.
-    (?:_\d+)?
-    $
-    """,
-    re.VERBOSE,
-)
-
-
-@dataclasses.dataclass(frozen=True)
-class Identifiers:
-  species_id: str = ''
-
-
-def _parse_sequence_identifier(msa_sequence_identifier: str) -> Identifiers:
-  """Gets species from an msa sequence identifier.
-
-  The sequence identifier has the format specified by
-  _UNIPROT_TREMBL_ENTRY_NAME_PATTERN or _UNIPROT_SWISSPROT_ENTRY_NAME_PATTERN.
-  An example of a sequence identifier: `tr|A0A146SKV9|A0A146SKV9_FUNHE`
-
-  Args:
-    msa_sequence_identifier: a sequence identifier.
-
-  Returns:
-    An `Identifiers` instance with species_id. These
-    can be empty in the case where no identifier was found.
-  """
-  matches = re.search(_UNIPROT_PATTERN, msa_sequence_identifier.strip())
-  if matches:
-    return Identifiers(species_id=matches.group('SpeciesIdentifier'))
-  return Identifiers()
-
-
-def _extract_sequence_identifier(description: str) -> str | None:
-  """Extracts sequence identifier from description. Returns None if no match."""
-  split_description = description.split()
-  if split_description:
-    return split_description[0].partition('/')[0]
-  else:
-    return None
-
-
-def get_identifiers(description: str) -> Identifiers:
-  """Computes extra MSA features from the description."""
-  sequence_identifier = _extract_sequence_identifier(description)
-  if sequence_identifier is None:
-    return Identifiers()
-  else:
-    return _parse_sequence_identifier(sequence_identifier)
diff --git a/src/alphafold3/data/msa_store.py b/src/alphafold3/data/msa_store.py
deleted file mode 100644
index bb79e925af151c1310f0104e6ce6d412a99d8998..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/msa_store.py
+++ /dev/null
@@ -1,66 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Interface and implementations for fetching MSA data."""
-
-from collections.abc import Sequence
-from typing import Protocol, TypeAlias
-
-from alphafold3.data import msa
-from alphafold3.data import msa_config
-
-
-MsaErrors: TypeAlias = Sequence[tuple[msa_config.RunConfig, str]]
-
-
-class MsaProvider(Protocol):
-  """Interface for providing Multiple Sequence Alignments."""
-
-  def __call__(
-      self,
-      query_sequence: str,
-      chain_polymer_type: str,
-  ) -> tuple[msa.Msa, MsaErrors]:
-    """Retrieve MSA for the given polymer query_sequence.
-
-    Args:
-      query_sequence: The residue sequence of the polymer to search for.
-      chain_polymer_type: The polymer type of the query_sequence. This must
-        match the chain_polymer_type of the provider.
-
-    Returns:
-      A tuple containing the MSA and MsaErrors. MsaErrors is a Sequence
-      containing a tuple for each msa_query that failed. Each tuple contains
-      the failing query and the associated error message.
-    """
-
-
-class EmptyMsaProvider:
-  """MSA provider that returns just the query sequence, useful for testing."""
-
-  def __init__(self, chain_polymer_type: str):
-    self._chain_polymer_type = chain_polymer_type
-
-  def __call__(
-      self, query_sequence: str, chain_polymer_type: str
-  ) -> tuple[msa.Msa, MsaErrors]:
-    """Returns an MSA containing just the query sequence, never errors."""
-    if chain_polymer_type != self._chain_polymer_type:
-      raise ValueError(
-          f'EmptyMsaProvider of type {self._chain_polymer_type} called with '
-          f'sequence of {chain_polymer_type=}, {query_sequence=}.'
-      )
-    return (
-        msa.Msa.from_empty(
-            query_sequence=query_sequence,
-            chain_poly_type=self._chain_polymer_type,
-        ),
-        (),
-    )
diff --git a/src/alphafold3/data/parsers.py b/src/alphafold3/data/parsers.py
deleted file mode 100644
index a48d0e18f635e60b50c4cd9a1770fe12e87eea0b..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/parsers.py
+++ /dev/null
@@ -1,178 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Functions for parsing various file formats."""
-
-from collections.abc import Iterable, Sequence
-from typing import IO, TypeAlias
-
-from alphafold3.cpp import fasta_iterator
-from alphafold3.cpp import msa_conversion
-
-
-DeletionMatrix: TypeAlias = Sequence[Sequence[int]]
-
-
-def lazy_parse_fasta_string(fasta_string: str) -> Iterable[tuple[str, str]]:
-  """Lazily parses a FASTA/A3M string and yields (sequence, description) tuples.
-
-  This implementation is more memory friendly than `fasta_sequence` while
-  offering comparable performance. The underlying implementation is in C++ and
-  is therefore faster than a pure Python implementation.
-
-  Use this method when parsing FASTA files where you already have the FASTA
-  string, but need to control how far you iterate through its sequences.
-
-  Arguments:
-    fasta_string: A string with the contents of FASTA/A3M file.
-
-  Returns:
-    Iterator of (sequence, description). In the description, the leading ">" is
-    stripped.
-
-  Raises:
-    ValueError if the FASTA/A3M file is invalid, e.g. empty.
-  """
-
-  # The lifetime of the FastaStringIterator is tied to the lifetime of
-  # fasta_string - fasta_string must be kept while the iterator is in use.
-  return fasta_iterator.FastaStringIterator(fasta_string)
-
-
-def parse_fasta(fasta_string: str) -> tuple[Sequence[str], Sequence[str]]:
-  """Parses FASTA string and returns list of strings with amino-acid sequences.
-
-  Arguments:
-    fasta_string: The string contents of a FASTA file.
-
-  Returns:
-    A tuple of two lists:
-    * A list of sequences.
-    * A list of sequence descriptions taken from the comment lines. In the
-      same order as the sequences.
-  """
-  return fasta_iterator.parse_fasta_include_descriptions(fasta_string)
-
-
-def convert_a3m_to_stockholm(a3m: str, max_seqs: int | None = None) -> str:
-  """Converts MSA in the A3M format to the Stockholm format."""
-  sequences, descriptions = parse_fasta(a3m)
-  if max_seqs is not None:
-    sequences = sequences[:max_seqs]
-    descriptions = descriptions[:max_seqs]
-
-  stockholm = ['# STOCKHOLM 1.0', '']
-
-  # Add the Stockholm header with the sequence metadata.
-  names = []
-  for i, description in enumerate(descriptions):
-    name, _, rest = description.replace('\t', ' ').partition(' ')
-    # Ensure that the names are unique - stockholm format requires that
-    # the sequence names are unique.
-    name = f'{name}_{i}'
-    names.append(name)
-    # Avoid zero-length description due to historic hmmbuild parsing bug.
-    desc = rest.strip() or '<EMPTY>'
-    stockholm.append(f'#=GS {name.strip()} DE {desc}')
-  stockholm.append('')
-
-  # Convert insertions in a sequence into gaps in all other sequences that don't
-  # have an insertion in that column as well.
-  sequences = msa_conversion.convert_a3m_to_stockholm(sequences)
-
-  # Add the MSA data.
-  max_name_width = max(len(name) for name in names)
-  for name, sequence in zip(names, sequences, strict=True):
-    # Align the names to the left and pad with spaces to the maximum length.
-    stockholm.append(f'{name:<{max_name_width}s} {sequence}')
-
-  # Add the reference annotation for the query (the first sequence).
-  ref_annotation = ''.join('.' if c == '-' else 'x' for c in sequences[0])
-  stockholm.append(f'{"#=GC RF":<{max_name_width}s} {ref_annotation}')
-  stockholm.append('//')
-
-  return '\n'.join(stockholm)
-
-
-def convert_stockholm_to_a3m(
-    stockholm: IO[str],
-    max_sequences: int | None = None,
-    remove_first_row_gaps: bool = True,
-    linewidth: int | None = None,
-) -> str:
-  """Converts MSA in Stockholm format to the A3M format."""
-  descriptions = {}
-  sequences = {}
-  reached_max_sequences = False
-
-  if linewidth is not None and linewidth <= 0:
-    raise ValueError('linewidth must be > 0 or None')
-
-  for line in stockholm:
-    reached_max_sequences = max_sequences and len(sequences) >= max_sequences
-    line = line.strip()
-    # Ignore blank lines, markup and end symbols - remainder are alignment
-    # sequence parts.
-    if not line or line.startswith(('#', '//')):
-      continue
-    seqname, aligned_seq = line.split(maxsplit=1)
-    if seqname not in sequences:
-      if reached_max_sequences:
-        continue
-      sequences[seqname] = ''
-    sequences[seqname] += aligned_seq
-
-  if not sequences:
-    return ''
-
-  stockholm.seek(0)
-  for line in stockholm:
-    line = line.strip()
-    if line[:4] == '#=GS':
-      # Description row - example format is:
-      # #=GS UniRef90_Q9H5Z4/4-78            DE [subseq from] cDNA: FLJ22755 ...
-      columns = line.split(maxsplit=3)
-      seqname, feature = columns[1:3]
-      value = columns[3] if len(columns) == 4 else ''
-      if feature != 'DE':
-        continue
-      if reached_max_sequences and seqname not in sequences:
-        continue
-      descriptions[seqname] = value
-      if len(descriptions) == len(sequences):
-        break
-
-  assert len(descriptions) <= len(sequences)
-
-  # Convert sto format to a3m line by line
-  a3m_sequences = {}
-  # query_sequence is assumed to be the first sequence
-  query_sequence = next(iter(sequences.values()))
-  for seqname, sto_sequence in sequences.items():
-    if remove_first_row_gaps:
-      a3m_sequences[seqname] = msa_conversion.align_sequence_to_gapless_query(
-          sequence=sto_sequence, query_sequence=query_sequence
-      ).replace('.', '')
-    else:
-      a3m_sequences[seqname] = sto_sequence.replace('.', '')
-
-  fasta_chunks = []
-
-  for seqname, seq in a3m_sequences.items():
-    fasta_chunks.append(f'>{seqname} {descriptions.get(seqname, "")}')
-
-    if linewidth:
-      fasta_chunks.extend(
-          seq[i : linewidth + i] for i in range(0, len(seq), linewidth)
-      )
-    else:
-      fasta_chunks.append(seq)
-
-  return '\n'.join(fasta_chunks) + '\n'  # Include terminating newline.
diff --git a/src/alphafold3/data/pipeline.py b/src/alphafold3/data/pipeline.py
deleted file mode 100644
index 026ccfa2e5b8af1244141df8b1b98be8b59351ea..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/pipeline.py
+++ /dev/null
@@ -1,550 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Functions for running the MSA and template tools for the AlphaFold model."""
-
-from concurrent import futures
-import dataclasses
-import datetime
-import functools
-import logging
-import time
-
-from alphafold3.common import folding_input
-from alphafold3.constants import mmcif_names
-from alphafold3.data import msa
-from alphafold3.data import msa_config
-from alphafold3.data import structure_stores
-from alphafold3.data import templates as templates_lib
-
-
-# Cache to avoid re-running template search for the same sequence in homomers.
-@functools.cache
-def _get_protein_templates(
-    sequence: str,
-    input_msa_a3m: str,
-    run_template_search: bool,
-    templates_config: msa_config.TemplatesConfig,
-    pdb_database_path: str,
-) -> templates_lib.Templates:
-  """Searches for templates for a single protein chain."""
-  if run_template_search:
-    templates_start_time = time.time()
-    logging.info('Getting protein templates for sequence %s', sequence)
-    protein_templates = templates_lib.Templates.from_seq_and_a3m(
-        query_sequence=sequence,
-        msa_a3m=input_msa_a3m,
-        max_template_date=templates_config.filter_config.max_template_date,
-        database_path=templates_config.template_tool_config.database_path,
-        hmmsearch_config=templates_config.template_tool_config.hmmsearch_config,
-        max_a3m_query_sequences=None,
-        chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-        structure_store=structure_stores.StructureStore(pdb_database_path),
-        filter_config=templates_config.filter_config,
-    )
-    logging.info(
-        'Getting %d protein templates took %.2f seconds for sequence %s',
-        protein_templates.num_hits,
-        time.time() - templates_start_time,
-        sequence,
-    )
-  else:
-    logging.info('Skipping template search for sequence %s', sequence)
-    protein_templates = templates_lib.Templates(
-        query_sequence=sequence,
-        hits=[],
-        max_template_date=templates_config.filter_config.max_template_date,
-        structure_store=structure_stores.StructureStore(pdb_database_path),
-    )
-  return protein_templates
-
-
-# Cache to avoid re-running the MSA tools for the same sequence in homomers.
-@functools.cache
-def _get_protein_msa_and_templates(
-    sequence: str,
-    run_template_search: bool,
-    uniref90_msa_config: msa_config.RunConfig,
-    mgnify_msa_config: msa_config.RunConfig,
-    small_bfd_msa_config: msa_config.RunConfig,
-    uniprot_msa_config: msa_config.RunConfig,
-    templates_config: msa_config.TemplatesConfig,
-    pdb_database_path: str,
-) -> tuple[msa.Msa, msa.Msa, templates_lib.Templates]:
-  """Processes a single protein chain."""
-  logging.info('Getting protein MSAs for sequence %s', sequence)
-  msa_start_time = time.time()
-  # Run various MSA tools in parallel. Use a ThreadPoolExecutor because
-  # they're not blocked by the GIL, as they're sub-shelled out.
-  with futures.ThreadPoolExecutor(max_workers=4) as executor:
-    uniref90_msa_future = executor.submit(
-        msa.get_msa,
-        target_sequence=sequence,
-        run_config=uniref90_msa_config,
-        chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-    )
-    mgnify_msa_future = executor.submit(
-        msa.get_msa,
-        target_sequence=sequence,
-        run_config=mgnify_msa_config,
-        chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-    )
-    small_bfd_msa_future = executor.submit(
-        msa.get_msa,
-        target_sequence=sequence,
-        run_config=small_bfd_msa_config,
-        chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-    )
-    uniprot_msa_future = executor.submit(
-        msa.get_msa,
-        target_sequence=sequence,
-        run_config=uniprot_msa_config,
-        chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-    )
-  uniref90_msa = uniref90_msa_future.result()
-  mgnify_msa = mgnify_msa_future.result()
-  small_bfd_msa = small_bfd_msa_future.result()
-  uniprot_msa = uniprot_msa_future.result()
-  logging.info(
-      'Getting protein MSAs took %.2f seconds for sequence %s',
-      time.time() - msa_start_time,
-      sequence,
-  )
-
-  logging.info('Deduplicating MSAs for sequence %s', sequence)
-  msa_dedupe_start_time = time.time()
-  with futures.ThreadPoolExecutor() as executor:
-    unpaired_protein_msa_future = executor.submit(
-        msa.Msa.from_multiple_msas,
-        msas=[uniref90_msa, small_bfd_msa, mgnify_msa],
-        deduplicate=True,
-    )
-    paired_protein_msa_future = executor.submit(
-        msa.Msa.from_multiple_msas, msas=[uniprot_msa], deduplicate=False
-    )
-  unpaired_protein_msa = unpaired_protein_msa_future.result()
-  paired_protein_msa = paired_protein_msa_future.result()
-  logging.info(
-      'Deduplicating MSAs took %.2f seconds for sequence %s, found %d unpaired'
-      ' sequences, %d paired sequences',
-      time.time() - msa_dedupe_start_time,
-      sequence,
-      unpaired_protein_msa.depth,
-      paired_protein_msa.depth,
-  )
-
-  protein_templates = _get_protein_templates(
-      sequence=sequence,
-      input_msa_a3m=unpaired_protein_msa.to_a3m(),
-      run_template_search=run_template_search,
-      templates_config=templates_config,
-      pdb_database_path=pdb_database_path,
-  )
-
-  return unpaired_protein_msa, paired_protein_msa, protein_templates
-
-
-# Cache to avoid re-running the Nhmmer for the same sequence in homomers.
-@functools.cache
-def _get_rna_msa(
-    sequence: str,
-    nt_rna_msa_config: msa_config.NhmmerConfig,
-    rfam_msa_config: msa_config.NhmmerConfig,
-    rnacentral_msa_config: msa_config.NhmmerConfig,
-) -> msa.Msa:
-  """Processes a single RNA chain."""
-  logging.info('Getting RNA MSAs for sequence %s', sequence)
-  rna_msa_start_time = time.time()
-  # Run various MSA tools in parallel. Use a ThreadPoolExecutor because
-  # they're not blocked by the GIL, as they're sub-shelled out.
-  with futures.ThreadPoolExecutor() as executor:
-    nt_rna_msa_future = executor.submit(
-        msa.get_msa,
-        target_sequence=sequence,
-        run_config=nt_rna_msa_config,
-        chain_poly_type=mmcif_names.RNA_CHAIN,
-    )
-    rfam_msa_future = executor.submit(
-        msa.get_msa,
-        target_sequence=sequence,
-        run_config=rfam_msa_config,
-        chain_poly_type=mmcif_names.RNA_CHAIN,
-    )
-    rnacentral_msa_future = executor.submit(
-        msa.get_msa,
-        target_sequence=sequence,
-        run_config=rnacentral_msa_config,
-        chain_poly_type=mmcif_names.RNA_CHAIN,
-    )
-  nt_rna_msa = nt_rna_msa_future.result()
-  rfam_msa = rfam_msa_future.result()
-  rnacentral_msa = rnacentral_msa_future.result()
-  rna_msa = msa.Msa.from_multiple_msas(
-      msas=[rfam_msa, rnacentral_msa, nt_rna_msa],
-      deduplicate=True,
-  )
-  logging.info(
-      'Getting RNA MSAs took %.2f seconds for sequence %s, found %d unpaired'
-      ' sequences',
-      time.time() - rna_msa_start_time,
-      sequence,
-      rna_msa.depth,
-  )
-  return rna_msa
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class DataPipelineConfig:
-  """The configuration for the data pipeline.
-
-  Attributes:
-    jackhmmer_binary_path: Jackhmmer binary path, used for protein MSA search.
-    nhmmer_binary_path: Nhmmer binary path, used for RNA MSA search.
-    hmmalign_binary_path: Hmmalign binary path, used to align hits to the query
-      profile.
-    hmmsearch_binary_path: Hmmsearch binary path, used for template search.
-    hmmbuild_binary_path: Hmmbuild binary path, used to build HMM profile from
-      raw MSA in template search.
-    small_bfd_database_path: Small BFD database path, used for protein MSA
-      search.
-    mgnify_database_path: Mgnify database path, used for protein MSA search.
-    uniprot_cluster_annot_database_path: Uniprot database path, used for protein
-      paired MSA search.
-    uniref90_database_path: UniRef90 database path, used for MSA search, and the
-      MSA obtained by searching it is used to construct the profile for template
-      search.
-    ntrna_database_path: NT-RNA database path, used for RNA MSA search.
-    rfam_database_path: Rfam database path, used for RNA MSA search.
-    rna_central_database_path: RNAcentral database path, used for RNA MSA
-      search.
-    seqres_database_path: PDB sequence database path, used for template search.
-    pdb_database_path: PDB database directory with mmCIF files path, used for
-      template search.
-    jackhmmer_n_cpu: Number of CPUs to use for Jackhmmer.
-    nhmmer_n_cpu: Number of CPUs to use for Nhmmer.
-    max_template_date: The latest date of templates to use.
-  """
-
-  # Binary paths.
-  jackhmmer_binary_path: str
-  nhmmer_binary_path: str
-  hmmalign_binary_path: str
-  hmmsearch_binary_path: str
-  hmmbuild_binary_path: str
-
-  # Jackhmmer databases.
-  small_bfd_database_path: str
-  mgnify_database_path: str
-  uniprot_cluster_annot_database_path: str
-  uniref90_database_path: str
-  # Nhmmer databases.
-  ntrna_database_path: str
-  rfam_database_path: str
-  rna_central_database_path: str
-  # Template search databases.
-  seqres_database_path: str
-  pdb_database_path: str
-
-  # Optional configuration for MSA tools.
-  jackhmmer_n_cpu: int = 8
-  nhmmer_n_cpu: int = 8
-
-  max_template_date: datetime.date
-
-
-class DataPipeline:
-  """Runs the alignment tools and assembles the input features."""
-
-  def __init__(self, data_pipeline_config: DataPipelineConfig):
-    """Initializes the data pipeline with default configurations."""
-    self._uniref90_msa_config = msa_config.RunConfig(
-        config=msa_config.JackhmmerConfig(
-            binary_path=data_pipeline_config.jackhmmer_binary_path,
-            database_config=msa_config.DatabaseConfig(
-                name='uniref90',
-                path=data_pipeline_config.uniref90_database_path,
-            ),
-            n_cpu=data_pipeline_config.jackhmmer_n_cpu,
-            n_iter=1,
-            e_value=1e-4,
-            z_value=None,
-            max_sequences=10_000,
-        ),
-        chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-        crop_size=None,
-    )
-    self._mgnify_msa_config = msa_config.RunConfig(
-        config=msa_config.JackhmmerConfig(
-            binary_path=data_pipeline_config.jackhmmer_binary_path,
-            database_config=msa_config.DatabaseConfig(
-                name='mgnify',
-                path=data_pipeline_config.mgnify_database_path,
-            ),
-            n_cpu=data_pipeline_config.jackhmmer_n_cpu,
-            n_iter=1,
-            e_value=1e-4,
-            z_value=None,
-            max_sequences=5_000,
-        ),
-        chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-        crop_size=None,
-    )
-    self._small_bfd_msa_config = msa_config.RunConfig(
-        config=msa_config.JackhmmerConfig(
-            binary_path=data_pipeline_config.jackhmmer_binary_path,
-            database_config=msa_config.DatabaseConfig(
-                name='small_bfd',
-                path=data_pipeline_config.small_bfd_database_path,
-            ),
-            n_cpu=data_pipeline_config.jackhmmer_n_cpu,
-            n_iter=1,
-            e_value=1e-4,
-            # Set z_value=138_515_945 to match the z_value used in the paper.
-            # In practice, this has minimal impact on predicted structures.
-            z_value=None,
-            max_sequences=5_000,
-        ),
-        chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-        crop_size=None,
-    )
-    self._uniprot_msa_config = msa_config.RunConfig(
-        config=msa_config.JackhmmerConfig(
-            binary_path=data_pipeline_config.jackhmmer_binary_path,
-            database_config=msa_config.DatabaseConfig(
-                name='uniprot_cluster_annot',
-                path=data_pipeline_config.uniprot_cluster_annot_database_path,
-            ),
-            n_cpu=data_pipeline_config.jackhmmer_n_cpu,
-            n_iter=1,
-            e_value=1e-4,
-            z_value=None,
-            max_sequences=50_000,
-        ),
-        chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-        crop_size=None,
-    )
-    self._nt_rna_msa_config = msa_config.RunConfig(
-        config=msa_config.NhmmerConfig(
-            binary_path=data_pipeline_config.nhmmer_binary_path,
-            hmmalign_binary_path=data_pipeline_config.hmmalign_binary_path,
-            hmmbuild_binary_path=data_pipeline_config.hmmbuild_binary_path,
-            database_config=msa_config.DatabaseConfig(
-                name='nt_rna',
-                path=data_pipeline_config.ntrna_database_path,
-            ),
-            n_cpu=data_pipeline_config.nhmmer_n_cpu,
-            e_value=1e-3,
-            alphabet='rna',
-            max_sequences=10_000,
-        ),
-        chain_poly_type=mmcif_names.RNA_CHAIN,
-        crop_size=None,
-    )
-    self._rfam_msa_config = msa_config.RunConfig(
-        config=msa_config.NhmmerConfig(
-            binary_path=data_pipeline_config.nhmmer_binary_path,
-            hmmalign_binary_path=data_pipeline_config.hmmalign_binary_path,
-            hmmbuild_binary_path=data_pipeline_config.hmmbuild_binary_path,
-            database_config=msa_config.DatabaseConfig(
-                name='rfam_rna',
-                path=data_pipeline_config.rfam_database_path,
-            ),
-            n_cpu=data_pipeline_config.nhmmer_n_cpu,
-            e_value=1e-3,
-            alphabet='rna',
-            max_sequences=10_000,
-        ),
-        chain_poly_type=mmcif_names.RNA_CHAIN,
-        crop_size=None,
-    )
-    self._rnacentral_msa_config = msa_config.RunConfig(
-        config=msa_config.NhmmerConfig(
-            binary_path=data_pipeline_config.nhmmer_binary_path,
-            hmmalign_binary_path=data_pipeline_config.hmmalign_binary_path,
-            hmmbuild_binary_path=data_pipeline_config.hmmbuild_binary_path,
-            database_config=msa_config.DatabaseConfig(
-                name='rna_central_rna',
-                path=data_pipeline_config.rna_central_database_path,
-            ),
-            n_cpu=data_pipeline_config.nhmmer_n_cpu,
-            e_value=1e-3,
-            alphabet='rna',
-            max_sequences=10_000,
-        ),
-        chain_poly_type=mmcif_names.RNA_CHAIN,
-        crop_size=None,
-    )
-
-    self._templates_config = msa_config.TemplatesConfig(
-        template_tool_config=msa_config.TemplateToolConfig(
-            database_path=data_pipeline_config.seqres_database_path,
-            chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-            hmmsearch_config=msa_config.HmmsearchConfig(
-                hmmsearch_binary_path=data_pipeline_config.hmmsearch_binary_path,
-                hmmbuild_binary_path=data_pipeline_config.hmmbuild_binary_path,
-                filter_f1=0.1,
-                filter_f2=0.1,
-                filter_f3=0.1,
-                e_value=100,
-                inc_e=100,
-                dom_e=100,
-                incdom_e=100,
-                alphabet='amino',
-            ),
-        ),
-        filter_config=msa_config.TemplateFilterConfig(
-            max_subsequence_ratio=0.95,
-            min_align_ratio=0.1,
-            min_hit_length=10,
-            deduplicate_sequences=True,
-            max_hits=4,
-            max_template_date=data_pipeline_config.max_template_date,
-        ),
-    )
-    self._pdb_database_path = data_pipeline_config.pdb_database_path
-
-  def process_protein_chain(
-      self, chain: folding_input.ProteinChain
-  ) -> folding_input.ProteinChain:
-    """Processes a single protein chain."""
-    has_unpaired_msa = chain.unpaired_msa is not None
-    has_paired_msa = chain.paired_msa is not None
-    has_templates = chain.templates is not None
-
-    if not has_unpaired_msa and not has_paired_msa and not chain.templates:
-      # MSA None - search. Templates either [] - don't search, or None - search.
-      unpaired_msa, paired_msa, template_hits = _get_protein_msa_and_templates(
-          sequence=chain.sequence,
-          run_template_search=not has_templates,  # Skip template search if [].
-          uniref90_msa_config=self._uniref90_msa_config,
-          mgnify_msa_config=self._mgnify_msa_config,
-          small_bfd_msa_config=self._small_bfd_msa_config,
-          uniprot_msa_config=self._uniprot_msa_config,
-          templates_config=self._templates_config,
-          pdb_database_path=self._pdb_database_path,
-      )
-      unpaired_msa = unpaired_msa.to_a3m()
-      paired_msa = paired_msa.to_a3m()
-      templates = [
-          folding_input.Template(
-              mmcif=struc.to_mmcif(),
-              query_to_template_map=hit.query_to_hit_mapping,
-          )
-          for hit, struc in template_hits.get_hits_with_structures()
-      ]
-    elif has_unpaired_msa and has_paired_msa and not has_templates:
-      # Has MSA, but doesn't have templates. Search for templates only.
-      empty_msa = msa.Msa.from_empty(
-          query_sequence=chain.sequence,
-          chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-      ).to_a3m()
-      unpaired_msa = chain.unpaired_msa or empty_msa
-      paired_msa = chain.paired_msa or empty_msa
-      template_hits = _get_protein_templates(
-          sequence=chain.sequence,
-          input_msa_a3m=unpaired_msa,
-          run_template_search=True,
-          templates_config=self._templates_config,
-          pdb_database_path=self._pdb_database_path,
-      )
-      templates = [
-          folding_input.Template(
-              mmcif=struc.to_mmcif(),
-              query_to_template_map=hit.query_to_hit_mapping,
-          )
-          for hit, struc in template_hits.get_hits_with_structures()
-      ]
-    else:
-      # Has MSA and templates, don't search for anything.
-      if not has_unpaired_msa or not has_paired_msa or not has_templates:
-        raise ValueError(
-            f'Protein chain {chain.id} has unpaired MSA, paired MSA, or'
-            ' templates set only partially. If you want to run the pipeline'
-            ' with custom MSA/templates, you need to set all of them. You can'
-            ' set MSA to empty string and templates to empty list to signify'
-            ' that they should not be used and searched for.'
-        )
-      logging.info(
-          'Skipping MSA and template search for protein chain %s because it '
-          'already has MSAs and templates.',
-          chain.id,
-      )
-      if not chain.unpaired_msa:
-        logging.info('Using empty unpaired MSA for protein chain %s', chain.id)
-      if not chain.paired_msa:
-        logging.info('Using empty paired MSA for protein chain %s', chain.id)
-      if not chain.templates:
-        logging.info('Using no templates for protein chain %s', chain.id)
-      empty_msa = msa.Msa.from_empty(
-          query_sequence=chain.sequence,
-          chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-      ).to_a3m()
-      unpaired_msa = chain.unpaired_msa or empty_msa
-      paired_msa = chain.paired_msa or empty_msa
-      templates = chain.templates
-
-    return folding_input.ProteinChain(
-        id=chain.id,
-        sequence=chain.sequence,
-        ptms=chain.ptms,
-        unpaired_msa=unpaired_msa,
-        paired_msa=paired_msa,
-        templates=templates,
-    )
-
-  def process_rna_chain(
-      self, chain: folding_input.RnaChain
-  ) -> folding_input.RnaChain:
-    """Processes a single RNA chain."""
-    if chain.unpaired_msa is not None:
-      # Don't run MSA tools if the chain already has an MSA.
-      logging.info(
-          'Skipping MSA search for RNA chain %s because it already has MSA.',
-          chain.id,
-      )
-      if not chain.unpaired_msa:
-        logging.info('Using empty unpaired MSA for RNA chain %s', chain.id)
-      empty_msa = msa.Msa.from_empty(
-          query_sequence=chain.sequence, chain_poly_type=mmcif_names.RNA_CHAIN
-      ).to_a3m()
-      unpaired_msa = chain.unpaired_msa or empty_msa
-    else:
-      unpaired_msa = _get_rna_msa(
-          sequence=chain.sequence,
-          nt_rna_msa_config=self._nt_rna_msa_config,
-          rfam_msa_config=self._rfam_msa_config,
-          rnacentral_msa_config=self._rnacentral_msa_config,
-      ).to_a3m()
-    return folding_input.RnaChain(
-        id=chain.id,
-        sequence=chain.sequence,
-        modifications=chain.modifications,
-        unpaired_msa=unpaired_msa,
-    )
-
-  def process(self, fold_input: folding_input.Input) -> folding_input.Input:
-    """Runs MSA and template tools and returns a new Input with the results."""
-    processed_chains = []
-    for chain in fold_input.chains:
-      print(f'Running data pipeline for chain {chain.id}...')
-      process_chain_start_time = time.time()
-      match chain:
-        case folding_input.ProteinChain():
-          processed_chains.append(self.process_protein_chain(chain))
-        case folding_input.RnaChain():
-          processed_chains.append(self.process_rna_chain(chain))
-        case _:
-          processed_chains.append(chain)
-      print(
-          f'Running data pipeline for chain {chain.id} took'
-          f' {time.time() - process_chain_start_time:.2f} seconds',
-      )
-
-    return dataclasses.replace(fold_input, chains=processed_chains)
diff --git a/src/alphafold3/data/structure_stores.py b/src/alphafold3/data/structure_stores.py
deleted file mode 100644
index aed02eba9832722322b0adce4180e18d2169cefb..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/structure_stores.py
+++ /dev/null
@@ -1,100 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Library for loading structure data from various sources."""
-
-from collections.abc import Mapping, Sequence
-import functools
-import os
-import pathlib
-import tarfile
-
-
-class NotFoundError(KeyError):
-  """Raised when the structure store doesn't contain the requested target."""
-
-
-class StructureStore:
-  """Handles the retrieval of mmCIF files from a filesystem."""
-
-  def __init__(
-      self,
-      structures: str | os.PathLike[str] | Mapping[str, str],
-  ):
-    """Initialises the instance.
-
-    Args:
-      structures: Path of the directory where the mmCIF files are or a Mapping
-        from target name to mmCIF string.
-    """
-    if isinstance(structures, Mapping):
-      self._structure_mapping = structures
-      self._structure_path = None
-      self._structure_tar = None
-    else:
-      self._structure_mapping = None
-      path_str = os.fspath(structures)
-      if path_str.endswith('.tar'):
-        self._structure_tar = tarfile.open(path_str, 'r')
-        self._structure_path = None
-      else:
-        self._structure_path = pathlib.Path(structures)
-        self._structure_tar = None
-
-  @functools.cached_property
-  def _tar_members(self) -> Mapping[str, tarfile.TarInfo]:
-    assert self._structure_tar is not None
-    return {
-        path.stem: tarinfo
-        for tarinfo in self._structure_tar.getmembers()
-        if tarinfo.isfile()
-        and (path := pathlib.Path(tarinfo.path.lower())).suffix == '.cif'
-    }
-
-  def get_mmcif_str(self, target_name: str) -> str:
-    """Returns an mmCIF for a given `target_name`.
-
-    Args:
-      target_name: Name specifying the target mmCIF.
-
-    Raises:
-      NotFoundError: If the target is not found.
-    """
-    if self._structure_mapping is not None:
-      try:
-        return self._structure_mapping[target_name]
-      except KeyError as e:
-        raise NotFoundError(f'{target_name=} not found') from e
-
-    if self._structure_tar is not None:
-      try:
-        member = self._tar_members[target_name]
-        if struct_file := self._structure_tar.extractfile(member):
-          return struct_file.read().decode()
-        else:
-          raise NotFoundError(f'{target_name=} not found')
-      except KeyError:
-        raise NotFoundError(f'{target_name=} not found') from None
-
-    filepath = self._structure_path / f'{target_name}.cif'
-    try:
-      return filepath.read_text()
-    except FileNotFoundError as e:
-      raise NotFoundError(f'{target_name=} not found at {filepath=}') from e
-
-  def target_names(self) -> Sequence[str]:
-    """Returns all targets in the store."""
-    if self._structure_mapping is not None:
-      return [*self._structure_mapping.keys()]
-    elif self._structure_tar is not None:
-      return sorted(self._tar_members.keys())
-    elif self._structure_path is not None:
-      return sorted([path.stem for path in self._structure_path.glob('*.cif')])
-    return ()
diff --git a/src/alphafold3/data/template_realign.py b/src/alphafold3/data/template_realign.py
deleted file mode 100644
index 51963f09237d3e7d689b712519c58a7184559303..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/template_realign.py
+++ /dev/null
@@ -1,168 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Realign sequences found in PDB seqres to the actual CIF sequences."""
-
-from collections.abc import Mapping
-
-
-class AlignmentError(Exception):
-  """Failed alignment between the hit sequence and the actual mmCIF sequence."""
-
-
-def realign_hit_to_structure(
-    *,
-    hit_sequence: str,
-    hit_start_index: int,
-    hit_end_index: int,
-    full_length: int,
-    structure_sequence: str,
-    query_to_hit_mapping: Mapping[int, int],
-) -> Mapping[int, int]:
-  """Realigns the hit sequence to the Structure sequence.
-
-  For example, for the given input:
-    query_sequence : ABCDEFGHIJKL
-    hit_sequence   : ---DEFGHIJK-
-    struc_sequence : XDEFGHKL
-  the mapping is {3: 0, 4: 1, 5: 2, 6: 3, 7: 4, 8: 5, 9: 6, 10: 7}. However, the
-  actual Structure sequence has an extra X at the start as well as no IJ. So the
-  alignment from the query to the Structure sequence will be:
-    hit_sequence   : ---DEFGHIJK-
-    struc_aligned  : --XDEFGH--KL
-  and the new mapping will therefore be: {3: 1, 4: 2, 5: 3, 6: 4, 7: 5, 10: 6}.
-
-  Args:
-    hit_sequence: The PDB seqres hit sequence obtained from Hmmsearch, but
-      without any gaps. This is not the full PDB seqres template sequence but
-      rather just its subsequence from hit_start_index to hit_end_index.
-    hit_start_index: The start index of the hit sequence in the full PDB seqres
-      template sequence (inclusive).
-    hit_end_index: The end index of the hit sequence in the full PDB seqres
-      template sequence (exclusive).
-    full_length: The length of the full PDB seqres template sequence.
-    structure_sequence: The actual sequence extracted from the Structure
-      corresponding to this template. In vast majority of cases this is the same
-      as the PDB seqres sequence, but this function handles the cases when not.
-    query_to_hit_mapping: The mapping from the query sequence to the
-      hit_sequence.
-
-  Raises:
-    AlignmentError: if the alignment between the sequence returned by Hmmsearch
-      differs from the actual sequence found in the mmCIF and can't be aligned
-      using the simple alignment algorithm.
-
-  Returns:
-    A mapping from the query sequence to the actual Structure sequence.
-  """
-  max_num_gaps = full_length - len(structure_sequence)
-  if max_num_gaps < 0:
-    raise AlignmentError(
-        f'The Structure sequence ({len(structure_sequence)}) '
-        f'must be shorter than the PDB seqres sequence ({full_length}):\n'
-        f'Structure sequence : {structure_sequence}\n'
-        f'PDB seqres sequence: {hit_sequence}'
-    )
-
-  if len(hit_sequence) != hit_end_index - hit_start_index:
-    raise AlignmentError(
-        f'The difference of {hit_end_index=} and {hit_start_index=} does not '
-        f'equal to the length of the {hit_sequence}: {len(hit_sequence)}'
-    )
-
-  best_score = -1
-  best_start = 0
-  best_query_to_hit_mapping = query_to_hit_mapping
-  max_num_gaps_before_subseq = min(hit_start_index, max_num_gaps)
-  # It is possible the gaps needed to align the PDB seqres subsequence and
-  # the Structure subsequence need to be inserted before the match region.
-  # Try and pick the alignment with the best number of aligned residues.
-  for num_gaps_before_subseq in range(0, max_num_gaps_before_subseq + 1):
-    start = hit_start_index - num_gaps_before_subseq
-    end = hit_end_index - num_gaps_before_subseq
-    structure_subseq = structure_sequence[start:end]
-
-    new_query_to_hit_mapping, score = _remap_to_struc_seq(
-        hit_seq=hit_sequence,
-        struc_seq=structure_subseq,
-        max_num_gaps=max_num_gaps - num_gaps_before_subseq,
-        mapping=query_to_hit_mapping,
-    )
-    if score >= best_score:
-      # Use >= to prefer matches with larger number of gaps before.
-      best_score = score
-      best_start = start
-      best_query_to_hit_mapping = new_query_to_hit_mapping
-
-  return {q: h + best_start for q, h in best_query_to_hit_mapping.items()}
-
-
-def _remap_to_struc_seq(
-    *,
-    hit_seq: str,
-    struc_seq: str,
-    max_num_gaps: int,
-    mapping: Mapping[int, int],
-) -> tuple[Mapping[int, int], int]:
-  """Remaps the query -> hit mapping to match the actual Structure sequence.
-
-  Args:
-    hit_seq: The hit sequence - a subsequence of the PDB seqres sequence without
-      any Hmmsearch modifications like inserted gaps or lowercased residues.
-    struc_seq: The actual sequence obtained from the corresponding Structure.
-    max_num_gaps: The maximum number of gaps that can be inserted in the
-      Structure sequence. In practice, this is the length difference between the
-      PDB seqres sequence and the actual Structure sequence.
-    mapping: The mapping from the query residues to the hit residues. This will
-      be remapped to point to the actual Structure sequence using a simple
-      realignment algorithm.
-
-  Returns:
-    A tuple of (mapping, score):
-      * Mapping from the query to the actual Structure sequence.
-      * Score which is the number of matching aligned residues.
-
-  Raises:
-    ValueError if the structure sequence isn't shorter than the seqres sequence.
-    ValueError if the alignment fails.
-  """
-  hit_seq_idx = 0
-  struc_seq_idx = 0
-  hit_to_struc_seq_mapping = {}
-  score = 0
-
-  # This while loop is guaranteed to terminate since we increase both
-  # struc_seq_idx and hit_seq_idx by at least 1 in each iteration.
-  remaining_num_gaps = max_num_gaps
-  while hit_seq_idx < len(hit_seq) and struc_seq_idx < len(struc_seq):
-    if hit_seq[hit_seq_idx] != struc_seq[struc_seq_idx]:
-      # Explore which alignment aligns the next residue (if present).
-      best_shift = 0
-      for shift in range(0, remaining_num_gaps + 1):
-        next_hit_res = hit_seq[hit_seq_idx + shift : hit_seq_idx + shift + 1]
-        next_struc_res = struc_seq[struc_seq_idx : struc_seq_idx + 1]
-        if next_hit_res == next_struc_res:
-          best_shift = shift
-          break
-      hit_seq_idx += best_shift
-      remaining_num_gaps -= best_shift
-
-    hit_to_struc_seq_mapping[hit_seq_idx] = struc_seq_idx
-    score += hit_seq[hit_seq_idx] == struc_seq[struc_seq_idx]
-    hit_seq_idx += 1
-    struc_seq_idx += 1
-
-  fixed_mapping = {}
-  for query_idx, original_hit_idx in mapping.items():
-    fixed_hit_idx = hit_to_struc_seq_mapping.get(original_hit_idx)
-    if fixed_hit_idx is not None:
-      fixed_mapping[query_idx] = fixed_hit_idx
-
-  return fixed_mapping, score
diff --git a/src/alphafold3/data/template_store.py b/src/alphafold3/data/template_store.py
deleted file mode 100644
index b5cf84b90480e042605da618341947789761612c..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/template_store.py
+++ /dev/null
@@ -1,46 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Interface and implementations for fetching templates data."""
-
-from collections.abc import Mapping
-import datetime
-from typing import Any, Protocol, TypeAlias
-
-
-TemplateFeatures: TypeAlias = Mapping[str, Any]
-
-
-class TemplateFeatureProvider(Protocol):
-  """Interface for providing Template Features."""
-
-  def __call__(
-      self,
-      sequence: str,
-      release_date: datetime.date | None,
-      include_ligand_features: bool = True,
-  ) -> TemplateFeatures:
-    """Retrieve template features for the given sequence and release_date.
-
-    Args:
-      sequence: The residue sequence of the query.
-      release_date: The release_date of the template query, this is used to
-        filter templates for training, ensuring that they do not leak structure
-        information from the future.
-      include_ligand_features: Whether to include ligand features.
-
-    Returns:
-      Template features: A mapping of template feature labels to features, which
-        may be numpy arrays, bytes objects, or for the special case of label
-        `ligand_features`, a nested feature map of labels to numpy arrays.
-
-    Raises:
-      TemplateRetrievalError if the template features were not found.
-    """
diff --git a/src/alphafold3/data/templates.py b/src/alphafold3/data/templates.py
deleted file mode 100644
index 0de9eb13c852ccd347458350ba1b7fe13d30d6ed..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/templates.py
+++ /dev/null
@@ -1,973 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""API for retrieving and manipulating template search results."""
-
-from collections.abc import Iterable, Iterator, Mapping, Sequence
-import dataclasses
-import datetime
-import functools
-import os
-import re
-from typing import Any, Final, Self, TypeAlias
-
-from absl import logging
-from alphafold3 import structure
-from alphafold3.common import resources
-from alphafold3.constants import atom_types
-from alphafold3.constants import mmcif_names
-from alphafold3.constants import residue_names
-from alphafold3.data import msa_config
-from alphafold3.data import parsers
-from alphafold3.data import structure_stores
-from alphafold3.data import template_realign
-from alphafold3.data.tools import hmmsearch
-from alphafold3.structure import mmcif
-import numpy as np
-
-
-_POLYMER_FEATURES: Final[Mapping[str, np.float64 | np.int32 | object]] = {
-    'template_aatype': np.int32,
-    'template_all_atom_masks': np.float64,
-    'template_all_atom_positions': np.float64,
-    'template_domain_names': object,
-    'template_release_date': object,
-    'template_sequence': object,
-}
-
-_LIGAND_FEATURES: Final[Mapping[str, Any]] = {
-    'ligand_features': Mapping[str, Any]
-}
-
-
-TemplateFeatures: TypeAlias = Mapping[
-    str, np.ndarray | bytes | Mapping[str, np.ndarray | bytes]
-]
-_REQUIRED_METADATA_COLUMNS: Final[Sequence[str]] = (
-    'seq_release_date',
-    'seq_unresolved_res_num',
-    'seq_author_chain_id',
-    'seq_sequence',
-)
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True, slots=True)
-class _Polymer:
-  """Container for alphabet specific (dna, rna, protein) atom information."""
-
-  min_atoms: int
-  num_atom_types: int
-  atom_order: Mapping[str, int]
-
-
-_POLYMERS = {
-    mmcif_names.PROTEIN_CHAIN: _Polymer(
-        min_atoms=5,
-        num_atom_types=atom_types.ATOM37_NUM,
-        atom_order=atom_types.ATOM37_ORDER,
-    ),
-    mmcif_names.DNA_CHAIN: _Polymer(
-        min_atoms=21,
-        num_atom_types=atom_types.ATOM29_NUM,
-        atom_order=atom_types.ATOM29_ORDER,
-    ),
-    mmcif_names.RNA_CHAIN: _Polymer(
-        min_atoms=20,
-        num_atom_types=atom_types.ATOM29_NUM,
-        atom_order=atom_types.ATOM29_ORDER,
-    ),
-}
-
-
-def _encode_restype(
-    chain_poly_type: str,
-    sequence: str,
-) -> Sequence[int]:
-  """Encodes a sequence of residue names as a sequence of ints.
-
-  Args:
-    chain_poly_type: Polymer chain type to determine sequence encoding.
-    sequence: Polymer residues. Protein encoded by single letters. RNA and DNA
-      encoded by  multi-letter CCD codes.
-
-  Returns:
-    A sequence of integers encoding amino acid types for the given chain type.
-  """
-  if chain_poly_type == mmcif_names.PROTEIN_CHAIN:
-    return [
-        residue_names.PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN_AND_GAP_TO_INT[
-            _STANDARDIZED_AA.get(res, res)
-        ]
-        for res in sequence
-    ]
-
-  unk_nucleic = residue_names.UNK_NUCLEIC_ONE_LETTER
-  unk_nucleic_idx = residue_names.POLYMER_TYPES_ORDER_WITH_UNKNOWN_AND_GAP[
-      unk_nucleic
-  ]
-  if chain_poly_type == mmcif_names.RNA_CHAIN:
-    return [
-        residue_names.POLYMER_TYPES_ORDER_WITH_UNKNOWN_AND_GAP.get(
-            res, unk_nucleic_idx
-        )
-        for res in sequence
-    ]
-  elif chain_poly_type == mmcif_names.DNA_CHAIN:
-    # Map UNK DNA to the generic nucleic UNK (N), which happens to also be the
-    # same as the RNA UNK.
-    return [
-        residue_names.POLYMER_TYPES_ORDER_WITH_UNKNOWN_AND_GAP.get(
-            residue_names.DNA_COMMON_ONE_TO_TWO.get(res, unk_nucleic),
-            unk_nucleic_idx,
-        )
-        for res in sequence
-    ]
-
-  raise NotImplementedError(f'"{chain_poly_type}" unsupported.')
-
-
-_DAYS_BEFORE_QUERY_DATE: Final[int] = 60
-_HIT_DESCRIPTION_REGEX = re.compile(
-    r'(?P<pdb_id>[a-z0-9]{4,})_(?P<chain_id>\w+)/(?P<start>\d+)-(?P<end>\d+) '
-    r'.* length:(?P<length>\d+)\b.*'
-)
-
-_STANDARDIZED_AA = {'B': 'D', 'J': 'X', 'O': 'X', 'U': 'C', 'Z': 'E'}
-
-
-class Error(Exception):
-  """Base class for exceptions."""
-
-
-class HitDateError(Error):
-  """An error indicating that invalid release date was detected."""
-
-
-class InvalidTemplateError(Error):
-  """An error indicating that template is invalid."""
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True)
-class Hit:
-  """Template hit metrics derived from the MSA for filtering and featurising.
-
-  Attributes:
-    pdb_id: The PDB ID of the hit.
-    auth_chain_id: The author chain ID of the hit.
-    hmmsearch_sequence: Hit sequence as given in hmmsearch a3m output.
-    structure_sequence: Hit sequence as given in PDB structure.
-    unresolved_res_indices: Indices of unresolved residues in the structure
-      sequence. 0-based.
-    query_sequence: The query nucleotide/amino acid sequence.
-    start_index: The start index of the sequence relative to the full PDB seqres
-      sequence. Inclusive and uses 0-based indexing.
-    end_index: The end index of the sequence relative to the full PDB seqres
-      sequence. Exclusive and uses 0-based indexing.
-    full_length: Length of the full PDB seqres sequence. This can be different
-      from the length from the actual sequence we get from the mmCIF and we use
-      this to detect whether we need to realign or not.
-    release_date: The release date of the PDB corresponding to this hit.
-    chain_poly_type: The polymer type of the selected hit structure.
-  """
-
-  pdb_id: str
-  auth_chain_id: str
-  hmmsearch_sequence: str
-  structure_sequence: str
-  unresolved_res_indices: Sequence[int] | None
-  query_sequence: str
-  start_index: int
-  end_index: int
-  full_length: int
-  release_date: datetime.date
-  chain_poly_type: str
-
-  @functools.cached_property
-  def query_to_hit_mapping(self) -> Mapping[int, int]:
-    """0-based query index to hit index mapping."""
-    query_to_hit_mapping = {}
-    hit_index = 0
-    query_index = 0
-    for residue in self.hmmsearch_sequence:
-      # Gap inserted in the template
-      if residue == '-':
-        query_index += 1
-      # Deleted residue in the template (would be a gap in the query).
-      elif residue.islower():
-        hit_index += 1
-      # Normal aligned residue, in both query and template. Add to mapping.
-      elif residue.isupper():
-        query_to_hit_mapping[query_index] = hit_index
-        query_index += 1
-        hit_index += 1
-
-    structure_subseq = self.structure_sequence[
-        self.start_index : self.end_index
-    ]
-    if self.matching_sequence != structure_subseq:
-      # The seqres sequence doesn't match the structure sequence. Two cases:
-      # 1. The sequences have the same length. The sequences are different
-      #    because our 3->1 residue code mapping is different from the one PDB
-      #    uses. We don't do anything in this case as both sequences have the
-      #    same length, so the original query to hit mapping stays valid.
-      # 2. The sequences don't have the same length, the one in structure is
-      #    shorter. In this case we change the mapping to match the actual
-      #    structure sequence using a simple realignment algorithm.
-      # This procedure was validated on all PDB seqres (2023_01_12) sequences
-      # and handles all cases that can happen.
-      if self.full_length != len(self.structure_sequence):
-        return template_realign.realign_hit_to_structure(
-            hit_sequence=self.matching_sequence,
-            hit_start_index=self.start_index,
-            hit_end_index=self.end_index,
-            full_length=self.full_length,
-            structure_sequence=self.structure_sequence,
-            query_to_hit_mapping=query_to_hit_mapping,
-        )
-
-    # Hmmsearch returns a subsequence and so far indices have been relative to
-    # the subsequence. Add an offset to index relative to the full structure
-    # sequence.
-    return {q: h + self.start_index for q, h in query_to_hit_mapping.items()}
-
-  @property
-  def matching_sequence(self) -> str:
-    """Returns the matching hit sequence including insertions.
-
-    Make deleted residues uppercase and remove gaps ("-").
-    """
-    return self.hmmsearch_sequence.upper().replace('-', '')
-
-  @functools.cached_property
-  def output_templates_sequence(self) -> str:
-    """Returns the final template sequence."""
-    result_seq = ['-'] * len(self.query_sequence)
-    for query_index, template_index in self.query_to_hit_mapping.items():
-      result_seq[query_index] = self.structure_sequence[template_index]
-    return ''.join(result_seq)
-
-  @property
-  def length_ratio(self) -> float:
-    """Ratio of the length of the hit sequence to the query."""
-    return len(self.matching_sequence) / len(self.query_sequence)
-
-  @property
-  def align_ratio(self) -> float:
-    """Ratio of the number of aligned residues to the query length."""
-    return len(self.query_to_hit_mapping) / len(self.query_sequence)
-
-  @functools.cached_property
-  def is_valid(self) -> bool:
-    """Whether hit can be used as a template."""
-    if self.unresolved_res_indices is None:
-      return False
-
-    return bool(
-        set(self.query_to_hit_mapping.values())
-        - set(self.unresolved_res_indices)
-    )
-
-  @property
-  def full_name(self) -> str:
-    """A full name of the hit."""
-    return f'{self.pdb_id}_{self.auth_chain_id}'
-
-  def __post_init__(self):
-    if not self.pdb_id.islower() and not self.pdb_id.isdigit():
-      raise ValueError(f'pdb_id must be lowercase {self.pdb_id}')
-
-    if not (0 <= self.start_index <= self.end_index):
-      raise ValueError(
-          'Start must be non-negative and less than or equal to end index. '
-          f'Range: {self.start_index}-{self.end_index}'
-      )
-
-    if len(self.matching_sequence) != (self.end_index - self.start_index):
-      raise ValueError(
-          'Sequence length must be equal to end_index - start_index. '
-          f'{len(self.matching_sequence)} != {self.end_index} - '
-          f'{self.start_index}'
-      )
-
-    if self.full_length < 0:
-      raise ValueError(f'Full length must be non-negative: {self.full_length}')
-
-  def keep(
-      self,
-      *,
-      release_date_cutoff: datetime.date | None,
-      max_subsequence_ratio: float | None,
-      min_hit_length: int | None,
-      min_align_ratio: float | None,
-  ) -> bool:
-    """Returns whether the hit should be kept.
-
-    In addition to filtering on all of the provided parameters, this method also
-    excludes hits with unresolved residues.
-
-    Args:
-      release_date_cutoff: Maximum release date of the template.
-      max_subsequence_ratio: If set, excludes hits which are an exact
-        subsequence of the query sequence, and longer than this ratio. Useful to
-        avoid ground truth leakage.
-      min_hit_length: If set, excludes hits which have fewer residues than this.
-      min_align_ratio: If set, excludes hits where the number of residues
-        aligned to the query is less than this proportion of the template
-        length.
-    """
-    # Exclude hits which are too recent.
-    if (
-        release_date_cutoff is not None
-        and self.release_date > release_date_cutoff
-    ):
-      return False
-
-    # Exclude hits which are large duplicates of the query_sequence.
-    if (
-        max_subsequence_ratio is not None
-        and self.length_ratio > max_subsequence_ratio
-    ):
-      if self.matching_sequence in self.query_sequence:
-        return False
-
-    # Exclude hits which are too short.
-    if (
-        min_hit_length is not None
-        and len(self.matching_sequence) < min_hit_length
-    ):
-      return False
-
-    # Exclude hits with unresolved residues.
-    if not self.is_valid:
-      return False
-
-    # Exclude hits with too few alignments.
-    try:
-      if min_align_ratio is not None and self.align_ratio <= min_align_ratio:
-        return False
-    except template_realign.AlignmentError as e:
-      logging.warning('Failed to align %s: %s', self, str(e))
-      return False
-
-    return True
-
-
-def _filter_hits(
-    hits: Iterable[Hit],
-    release_date_cutoff: datetime.date,
-    max_subsequence_ratio: float | None,
-    min_align_ratio: float | None,
-    min_hit_length: int | None,
-    deduplicate_sequences: bool,
-    max_hits: int | None,
-) -> Sequence[Hit]:
-  """Filters hits based on the filter config."""
-  filtered_hits = []
-  seen_before = set()
-  for hit in hits:
-    if not hit.keep(
-        max_subsequence_ratio=max_subsequence_ratio,
-        min_align_ratio=min_align_ratio,
-        min_hit_length=min_hit_length,
-        release_date_cutoff=release_date_cutoff,
-    ):
-      continue
-
-    # Remove duplicate templates, keeping the first.
-    if deduplicate_sequences:
-      if hit.output_templates_sequence in seen_before:
-        continue
-      seen_before.add(hit.output_templates_sequence)
-
-    filtered_hits.append(hit)
-    if max_hits and len(filtered_hits) == max_hits:
-      break
-
-  return filtered_hits
-
-
-@dataclasses.dataclass(init=False)
-class Templates:
-  """A container for templates that were found for the given query sequence.
-
-  The structure_store is constructed from the config by default. Callers can
-  optionally supply a structure_store to the constructor to avoid the cost of
-  construction and metadata loading.
-  """
-
-  def __init__(
-      self,
-      *,
-      query_sequence: str,
-      hits: Sequence[Hit],
-      max_template_date: datetime.date,
-      structure_store: structure_stores.StructureStore,
-      query_release_date: datetime.date | None = None,
-  ):
-    self._query_sequence = query_sequence
-    self._hits = tuple(hits)
-    self._max_template_date = max_template_date
-    self._query_release_date = query_release_date
-    self._hit_structures = {}
-    self._structure_store = structure_store
-
-    if any(h.query_sequence != self._query_sequence for h in self.hits):
-      raise ValueError('All hits must match the query sequence.')
-
-    if self._hits:
-      chain_poly_type = self._hits[0].chain_poly_type
-      if any(h.chain_poly_type != chain_poly_type for h in self.hits):
-        raise ValueError('All hits must have the same chain_poly_type.')
-
-  @classmethod
-  def from_seq_and_a3m(
-      cls,
-      *,
-      query_sequence: str,
-      msa_a3m: str,
-      max_template_date: datetime.date,
-      database_path: os.PathLike[str] | str,
-      hmmsearch_config: msa_config.HmmsearchConfig,
-      max_a3m_query_sequences: int | None,
-      structure_store: structure_stores.StructureStore,
-      filter_config: msa_config.TemplateFilterConfig | None = None,
-      query_release_date: datetime.date | None = None,
-      chain_poly_type: str = mmcif_names.PROTEIN_CHAIN,
-  ) -> Self:
-    """Creates templates from a run of hmmsearch tool against a custom a3m.
-
-    Args:
-      query_sequence: The polymer sequence of the target query.
-      msa_a3m: An a3m of related polymers aligned to the query sequence, this is
-        used to create an HMM for the hmmsearch run.
-      max_template_date: This is used to filter templates for training, ensuring
-        that they do not leak ground truth information used in testing sets.
-      database_path: A path to the sequence database to search for templates.
-      hmmsearch_config: Config with Hmmsearch settings.
-      max_a3m_query_sequences: The maximum number of input MSA sequences to use
-        to construct the profile which is then used to search for templates.
-      structure_store: Structure store to fetch template structures from.
-      filter_config: Optional config that controls which and how many hits to
-        keep. More performant than constructing and then filtering. If not
-        provided, no filtering is done.
-      query_release_date: The release_date of the template query, this is used
-        to filter templates for training, ensuring that they do not leak
-        structure information from the future.
-      chain_poly_type: The polymer type of the templates.
-
-    Returns:
-      Templates object containing a list of Hits initialised from the
-      structure_store metadata and a3m alignments.
-    """
-    hmmsearch_a3m = run_hmmsearch_with_a3m(
-        database_path=database_path,
-        hmmsearch_config=hmmsearch_config,
-        max_a3m_query_sequences=max_a3m_query_sequences,
-        a3m=msa_a3m,
-    )
-    return cls.from_hmmsearch_a3m(
-        query_sequence=query_sequence,
-        a3m=hmmsearch_a3m,
-        max_template_date=max_template_date,
-        query_release_date=query_release_date,
-        chain_poly_type=chain_poly_type,
-        structure_store=structure_store,
-        filter_config=filter_config,
-    )
-
-  @classmethod
-  def from_hmmsearch_a3m(
-      cls,
-      *,
-      query_sequence: str,
-      a3m: str,
-      max_template_date: datetime.date,
-      structure_store: structure_stores.StructureStore,
-      filter_config: msa_config.TemplateFilterConfig | None = None,
-      query_release_date: datetime.date | None = None,
-      chain_poly_type: str = mmcif_names.PROTEIN_CHAIN,
-  ) -> Self:
-    """Creates Templates from a Hmmsearch A3M.
-
-    Args:
-      query_sequence: The polymer sequence of the target query.
-      a3m: Results of Hmmsearch in A3M format. This provides a list of potential
-        template alignments and pdb codes.
-      max_template_date: This is used to filter templates for training, ensuring
-        that they do not leak ground truth information used in testing sets.
-      structure_store: Structure store to fetch template structures from.
-      filter_config: Optional config that controls which and how many hits to
-        keep. More performant than constructing and then filtering. If not
-        provided, no filtering is done.
-      query_release_date: The release_date of the template query, this is used
-        to filter templates for training, ensuring that they do not leak
-        structure information from the future.
-      chain_poly_type: The polymer type of the templates.
-
-    Returns:
-      Templates object containing a list of Hits initialised from the
-      structure_store metadata and a3m alignments.
-    """
-
-    def hit_generator(a3m: str):
-      if not a3m:
-        return  # Hmmsearch could return an empty string if there are no hits.
-
-      for hit_seq, hit_desc in parsers.lazy_parse_fasta_string(a3m):
-        pdb_id, auth_chain_id, start, end, full_length = _parse_hit_description(
-            hit_desc
-        )
-
-        release_date, sequence, unresolved_res_ids = _parse_hit_metadata(
-            structure_store, pdb_id, auth_chain_id
-        )
-        if unresolved_res_ids is None:
-          continue
-
-        # seq_unresolved_res_num are 1-based, setting to 0-based indices.
-        unresolved_indices = [i - 1 for i in unresolved_res_ids]
-
-        yield Hit(
-            pdb_id=pdb_id,
-            auth_chain_id=auth_chain_id,
-            hmmsearch_sequence=hit_seq,
-            structure_sequence=sequence,
-            query_sequence=query_sequence,
-            unresolved_res_indices=unresolved_indices,
-            start_index=start - 1,  # Raw value is residue number, not index.
-            end_index=end,
-            full_length=full_length,
-            release_date=datetime.date.fromisoformat(release_date),
-            chain_poly_type=chain_poly_type,
-        )
-
-    if filter_config is None:
-      hits = tuple(hit_generator(a3m))
-    else:
-      hits = _filter_hits(
-          hit_generator(a3m),
-          release_date_cutoff=filter_config.max_template_date,
-          max_subsequence_ratio=filter_config.max_subsequence_ratio,
-          min_align_ratio=filter_config.min_align_ratio,
-          min_hit_length=filter_config.min_hit_length,
-          deduplicate_sequences=filter_config.deduplicate_sequences,
-          max_hits=filter_config.max_hits,
-      )
-
-    return Templates(
-        query_sequence=query_sequence,
-        query_release_date=query_release_date,
-        hits=hits,
-        max_template_date=max_template_date,
-        structure_store=structure_store,
-    )
-
-  @property
-  def query_sequence(self) -> str:
-    return self._query_sequence
-
-  @property
-  def hits(self) -> tuple[Hit, ...]:
-    return self._hits
-
-  @property
-  def query_release_date(self) -> datetime.date | None:
-    return self._query_release_date
-
-  @property
-  def num_hits(self) -> int:
-    return len(self._hits)
-
-  @functools.cached_property
-  def release_date_cutoff(self) -> datetime.date:
-    if self.query_release_date is None:
-      return self._max_template_date
-    return min(
-        self._max_template_date,
-        self.query_release_date
-        - datetime.timedelta(days=_DAYS_BEFORE_QUERY_DATE),
-    )
-
-  def __repr__(self) -> str:
-    return f'Templates({self.num_hits} hits)'
-
-  def filter(
-      self,
-      *,
-      max_subsequence_ratio: float | None,
-      min_align_ratio: float | None,
-      min_hit_length: int | None,
-      deduplicate_sequences: bool,
-      max_hits: int | None,
-  ) -> Self:
-    """Returns a new Templates object with only the hits that pass all filters.
-
-    This also filters on query_release_date and max_template_date.
-
-    Args:
-      max_subsequence_ratio: If set, excludes hits which are an exact
-        subsequence of the query sequence, and longer than this ratio. Useful to
-        avoid ground truth leakage.
-      min_align_ratio: If set, excludes hits where the number of residues
-        aligned to the query is less than this proportion of the template
-        length.
-      min_hit_length: If set, excludes hits which have fewer residues than this.
-      deduplicate_sequences: Whether to exclude duplicate template sequences,
-        keeping only the first. This can be useful in increasing the diversity
-        of hits especially in the case of homomer hits.
-      max_hits: If set, excludes any hits which exceed this count.
-    """
-    filtered_hits = _filter_hits(
-        hits=self._hits,
-        release_date_cutoff=self.release_date_cutoff,
-        max_subsequence_ratio=max_subsequence_ratio,
-        min_align_ratio=min_align_ratio,
-        min_hit_length=min_hit_length,
-        deduplicate_sequences=deduplicate_sequences,
-        max_hits=max_hits,
-    )
-    return Templates(
-        query_sequence=self.query_sequence,
-        query_release_date=self.query_release_date,
-        hits=filtered_hits,
-        max_template_date=self._max_template_date,
-        structure_store=self._structure_store,
-    )
-
-  def get_hits_with_structures(
-      self,
-  ) -> Sequence[tuple[Hit, structure.Structure]]:
-    """Returns hits + Structures, Structures filtered to the hit's chain."""
-    results = []
-    structures = {struc.name.lower(): struc for struc in self.structures}
-    for hit in self.hits:
-      if not hit.is_valid:
-        raise InvalidTemplateError(
-            'Hits must be filtered before calling get_hits_with_structures.'
-        )
-      struc = structures[hit.pdb_id]
-      label_chain_id = struc.polymer_auth_asym_id_to_label_asym_id().get(
-          hit.auth_chain_id
-      )
-      results.append((hit, struc.filter(chain_id=label_chain_id)))
-    return results
-
-  def featurize(
-      self,
-      include_ligand_features: bool = True,
-  ) -> TemplateFeatures:
-    """Featurises the templates and returns a map of feature names to features.
-
-    NB: If you don't do any prefiltering, this method might be slow to run
-    as it has to fetch many CIFs and featurize them all.
-
-    Args:
-      include_ligand_features: Whether to compute ligand features.
-
-    Returns:
-      Template features: A mapping of template feature labels to features, which
-        may be numpy arrays, bytes objects, or for the special case of label
-        `ligand_features` (if `include_ligand_features` is True), a nested
-        feature map of labels to numpy arrays.
-
-    Raises:
-      InvalidTemplateError: If hits haven't been filtered before featurization.
-    """
-    hits_by_pdb_id = {}
-    for idx, hit in enumerate(self.hits):
-      if not hit.is_valid:
-        raise InvalidTemplateError(
-            f'Hits must be filtered before featurizing, got unprocessed {hit=}'
-        )
-      hits_by_pdb_id.setdefault(hit.pdb_id, []).append((idx, hit))
-
-    unsorted_features = []
-    for struc in self.structures:
-      pdb_id = str(struc.name).lower()
-      for idx, hit in hits_by_pdb_id[pdb_id]:
-        try:
-          label_chain_id = struc.polymer_auth_asym_id_to_label_asym_id()[
-              hit.auth_chain_id
-          ]
-          hit_features = {
-              **get_polymer_features(
-                  chain=struc.filter(chain_id=label_chain_id),
-                  chain_poly_type=hit.chain_poly_type,
-                  query_sequence_length=len(hit.query_sequence),
-                  query_to_hit_mapping=hit.query_to_hit_mapping,
-              ),
-          }
-          if include_ligand_features:
-            hit_features['ligand_features'] = _get_ligand_features(struc)
-          unsorted_features.append((idx, hit_features))
-        except Error as e:
-          raise type(e)(f'Failed to featurise {hit=}') from e
-
-    sorted_features = sorted(unsorted_features, key=lambda x: x[0])
-    sorted_features = [feat for _, feat in sorted_features]
-    return package_template_features(
-        hit_features=sorted_features,
-        include_ligand_features=include_ligand_features,
-    )
-
-  @property
-  def structures(self) -> Iterator[structure.Structure]:
-    """Yields template structures for each unique PDB ID among hits.
-
-    If there are multiple hits in the same Structure, the Structure will be
-    included only once by this method.
-
-    Yields:
-      A Structure object for each unique PDB ID among hits.
-
-    Raises:
-      HitDateError: If template's release date exceeds max cutoff date.
-    """
-
-    for hit in self.hits:
-      if hit.release_date > self.release_date_cutoff:  # pylint: disable=comparison-with-callable
-        raise HitDateError(
-            f'Invalid release date for hit {hit.pdb_id=}, when release date '
-            f'cutoff is {self.release_date_cutoff}.'
-        )
-
-    # Get the set of pdbs to load. In particular, remove duplicate PDB IDs.
-    targets_to_load = tuple({hit.pdb_id for hit in self.hits})
-
-    for target_name in targets_to_load:
-      yield structure.from_mmcif(
-          mmcif_string=self._structure_store.get_mmcif_str(target_name),
-          fix_mse_residues=True,
-          fix_arginines=True,
-          include_water=False,
-          include_bonds=False,
-          include_other=True,  # For non-standard polymer chains.
-      )
-
-
-def _parse_hit_description(description: str) -> tuple[str, str, int, int, int]:
-  """Parses the hmmsearch A3M sequence description line."""
-  # Example lines (protein, nucleic, no description):
-  # >4pqx_A/2-217 [subseq from] mol:protein length:217  Free text
-  # >4pqx_A/2-217 [subseq from] mol:na length:217  Free text
-  # >5g3r_A/1-55 [subseq from] mol:protein length:352
-  if match := re.fullmatch(_HIT_DESCRIPTION_REGEX, description):
-    return (
-        match['pdb_id'],
-        match['chain_id'],
-        int(match['start']),
-        int(match['end']),
-        int(match['length']),
-    )
-  else:
-    raise ValueError(f'Could not parse description "{description}"')
-
-
-def _parse_hit_metadata(
-    structure_store: structure_stores.StructureStore,
-    pdb_id: str,
-    auth_chain_id: str,
-) -> tuple[Any, str | None, Sequence[int] | None]:
-  """Parse hit metadata by parsing mmCIF from structure store."""
-  try:
-    cif = mmcif.from_string(structure_store.get_mmcif_str(pdb_id))
-  except structure_stores.NotFoundError:
-    logging.warning(
-        'Failed to get mmCIF for %s (author chain %s).', pdb_id, auth_chain_id
-    )
-    return None, None, None
-  release_date = mmcif.get_release_date(cif)
-
-  try:
-    struc = structure.from_parsed_mmcif(
-        cif,
-        model_id=structure.ModelID.ALL,
-        include_water=True,
-        include_other=True,
-        include_bonds=False,
-    )
-  except ValueError:
-    struc = structure.from_parsed_mmcif(
-        cif,
-        model_id=structure.ModelID.FIRST,
-        include_water=True,
-        include_other=True,
-        include_bonds=False,
-    )
-
-  sequence = struc.polymer_author_chain_single_letter_sequence(
-      include_missing_residues=True,
-      protein=True,
-      dna=True,
-      rna=True,
-      other=True,
-  )[auth_chain_id]
-
-  unresolved_res_ids = struc.filter(
-      chain_auth_asym_id=auth_chain_id
-  ).unresolved_residues.id
-
-  return release_date, sequence, unresolved_res_ids
-
-
-def get_polymer_features(
-    *,
-    chain: structure.Structure,
-    chain_poly_type: str,
-    query_sequence_length: int,
-    query_to_hit_mapping: Mapping[int, int],
-) -> Mapping[str, Any]:
-  """Returns features for this polymer chain.
-
-  Args:
-    chain: Structure object representing the template. Must be already filtered
-      to a single chain.
-    chain_poly_type: The chain polymer type (protein, DNA, RNA).
-    query_sequence_length: The length of the query sequence.
-    query_to_hit_mapping: 0-based query index to hit index mapping.
-
-  Returns:
-    A dictionary with polymer features for template_chain_id in the struc.
-
-  Raises:
-    ValueError: If the input structure contains more than just a single chain.
-  """
-  if len(chain.polymer_auth_asym_id_to_label_asym_id()) != 1:
-    raise ValueError('The structure must be filtered to a single chain.')
-
-  if chain.name is None:
-    raise ValueError('The structure must have a name.')
-
-  if chain.release_date is None:
-    raise ValueError('The structure must have a release date.')
-
-  auth_chain_id, label_chain_id = next(
-      iter(chain.polymer_auth_asym_id_to_label_asym_id().items())
-  )
-  chain_sequence = chain.chain_single_letter_sequence()[label_chain_id]
-
-  polymer = _POLYMERS[chain_poly_type]
-  positions, positions_mask = chain.to_res_arrays(
-      include_missing_residues=True, atom_order=polymer.atom_order
-  )
-  template_all_atom_positions = np.zeros(
-      (query_sequence_length, polymer.num_atom_types, 3), dtype=np.float64
-  )
-  template_all_atom_masks = np.zeros(
-      (query_sequence_length, polymer.num_atom_types), dtype=np.int64
-  )
-
-  template_sequence = ['-'] * query_sequence_length
-  for query_index, template_index in query_to_hit_mapping.items():
-    template_all_atom_positions[query_index] = positions[template_index]
-    template_all_atom_masks[query_index] = positions_mask[template_index]
-    template_sequence[query_index] = chain_sequence[template_index]
-
-  template_sequence = ''.join(template_sequence)
-  template_aatype = _encode_restype(chain_poly_type, template_sequence)
-  template_name = f'{chain.name.lower()}_{auth_chain_id}'
-  release_date = chain.release_date.strftime('%Y-%m-%d')
-  return {
-      'template_all_atom_positions': template_all_atom_positions,
-      'template_all_atom_masks': template_all_atom_masks,
-      'template_sequence': template_sequence.encode(),
-      'template_aatype': np.array(template_aatype, dtype=np.int32),
-      'template_domain_names': np.array(template_name.encode(), dtype=object),
-      'template_release_date': np.array(release_date.encode(), dtype=object),
-  }
-
-
-def _get_ligand_features(
-    struc: structure.Structure,
-) -> Mapping[str, Mapping[str, np.ndarray | bytes]]:
-  """Returns features for the ligands in this structure."""
-  ligand_struc = struc.filter_to_entity_type(ligand=True)
-  assert ligand_struc.coords is not None
-  assert ligand_struc.atom_name is not None
-  assert ligand_struc.atom_occupancy is not None
-
-  ligand_features = {}
-  for ligand_chain_id in ligand_struc.chains:
-    idxs = np.where(ligand_struc.chain_id == ligand_chain_id)[0]
-    if idxs.shape[0]:
-      ligand_features[ligand_chain_id] = {
-          'ligand_atom_positions': ligand_struc.coords[idxs, :].astype(
-              np.float32
-          ),
-          'ligand_atom_names': ligand_struc.atom_name[idxs].astype(object),
-          'ligand_atom_occupancies': ligand_struc.atom_occupancy[idxs].astype(
-              np.float32
-          ),
-          'ccd_id': ligand_struc.res_name[idxs][0].encode(),
-      }
-  return ligand_features
-
-
-def package_template_features(
-    *,
-    hit_features: Sequence[Mapping[str, Any]],
-    include_ligand_features: bool,
-) -> Mapping[str, Any]:
-  """Stacks polymer features, adds empty and keeps ligand features unstacked."""
-
-  features_to_include = set(_POLYMER_FEATURES)
-  if include_ligand_features:
-    features_to_include.update(_LIGAND_FEATURES)
-
-  features = {
-      feat: [single_hit_features[feat] for single_hit_features in hit_features]
-      for feat in features_to_include
-  }
-
-  stacked_features = {}
-  for k, v in features.items():
-    if k in _POLYMER_FEATURES:
-      v = np.stack(v, axis=0) if v else np.array([], dtype=_POLYMER_FEATURES[k])
-    stacked_features[k] = v
-
-  return stacked_features
-
-
-def _resolve_path(path: os.PathLike[str] | str) -> str:
-  """Resolves path for data dep paths, stringifies otherwise."""
-  # Data dependency paths: db baked into the binary.
-  resolved_path = resources.filename(path)
-  if os.path.exists(resolved_path):
-    return resolved_path
-  else:
-    # Other paths, e.g. local.
-    return str(path)
-
-
-def run_hmmsearch_with_a3m(
-    *,
-    database_path: os.PathLike[str] | str,
-    hmmsearch_config: msa_config.HmmsearchConfig,
-    max_a3m_query_sequences: int | None,
-    a3m: str | None,
-) -> str:
-  """Runs Hmmsearch to get a3m string of hits."""
-  searcher = hmmsearch.Hmmsearch(
-      binary_path=hmmsearch_config.hmmsearch_binary_path,
-      hmmbuild_binary_path=hmmsearch_config.hmmbuild_binary_path,
-      database_path=_resolve_path(database_path),
-      e_value=hmmsearch_config.e_value,
-      inc_e=hmmsearch_config.inc_e,
-      dom_e=hmmsearch_config.dom_e,
-      incdom_e=hmmsearch_config.incdom_e,
-      alphabet=hmmsearch_config.alphabet,
-      filter_f1=hmmsearch_config.filter_f1,
-      filter_f2=hmmsearch_config.filter_f2,
-      filter_f3=hmmsearch_config.filter_f3,
-      filter_max=hmmsearch_config.filter_max,
-  )
-  # STO enables us to annotate query non-gap columns as reference columns.
-  sto = parsers.convert_a3m_to_stockholm(a3m, max_a3m_query_sequences)
-  return searcher.query_with_sto(sto, model_construction='hand')
diff --git a/src/alphafold3/data/tools/hmmalign.py b/src/alphafold3/data/tools/hmmalign.py
deleted file mode 100644
index c60eac2abbdd6429c76747cea20c8950faf76a9f..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/tools/hmmalign.py
+++ /dev/null
@@ -1,142 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""A Python wrapper for hmmalign from the HMMER Suite."""
-
-from collections.abc import Mapping, Sequence
-import os
-import tempfile
-
-from alphafold3.data import parsers
-from alphafold3.data.tools import subprocess_utils
-
-
-def _to_a3m(sequences: Sequence[str], name_prefix: str = 'sequence') -> str:
-  a3m = ''
-  for i, sequence in enumerate(sequences, 1):
-    a3m += f'> {name_prefix} {i}\n{sequence}\n'
-  return a3m
-
-
-class Hmmalign:
-  """Python wrapper of the hmmalign binary."""
-
-  def __init__(self, binary_path: str):
-    """Initializes the Python hmmalign wrapper.
-
-    Args:
-      binary_path: Path to the hmmalign binary.
-
-    Raises:
-      RuntimeError: If hmmalign binary not found within the path.
-    """
-    self.binary_path = binary_path
-
-    subprocess_utils.check_binary_exists(path=self.binary_path, name='hmmalign')
-
-  def align_sequences(
-      self,
-      sequences: Sequence[str],
-      profile: str,
-      extra_flags: Mapping[str, str] | None = None,
-  ) -> str:
-    """Aligns sequence list to the profile and returns the alignment in A3M."""
-    return self.align(
-        a3m_str=_to_a3m(sequences, name_prefix='query'),
-        profile=profile,
-        extra_flags=extra_flags,
-    )
-
-  def align(
-      self,
-      a3m_str: str,
-      profile: str,
-      extra_flags: Mapping[str, str] | None = None,
-  ) -> str:
-    """Aligns sequences in A3M to the profile and returns the alignment in A3M.
-
-    Args:
-      a3m_str: A list of sequence strings.
-      profile: A hmm file with the hmm profile to align the sequences to.
-      extra_flags: Dictionary with extra flags, flag_name: flag_value, that are
-        added to hmmalign.
-
-    Returns:
-      An A3M string with the aligned sequences.
-
-    Raises:
-      RuntimeError: If hmmalign fails.
-    """
-    with tempfile.TemporaryDirectory() as query_tmp_dir:
-      input_profile = os.path.join(query_tmp_dir, 'profile.hmm')
-      input_sequences = os.path.join(query_tmp_dir, 'sequences.a3m')
-      output_a3m_path = os.path.join(query_tmp_dir, 'output.a3m')
-
-      with open(input_profile, 'w') as f:
-        f.write(profile)
-
-      with open(input_sequences, 'w') as f:
-        f.write(a3m_str)
-
-      cmd = [
-          self.binary_path,
-          *('-o', output_a3m_path),
-          *('--outformat', 'A2M'),  # A2M is A3M in the HMMER suite.
-      ]
-      if extra_flags:
-        for flag_name, flag_value in extra_flags.items():
-          cmd.extend([flag_name, flag_value])
-      cmd.extend([input_profile, input_sequences])
-
-      subprocess_utils.run(
-          cmd=cmd,
-          cmd_name='hmmalign',
-          log_stdout=False,
-          log_stderr=True,
-          log_on_process_error=True,
-      )
-
-      with open(output_a3m_path, encoding='utf-8') as f:
-        a3m = f.read()
-
-    return a3m
-
-  def align_sequences_to_profile(self, profile: str, sequences_a3m: str) -> str:
-    """Aligns the sequences to profile and returns the alignment in A3M string.
-
-    Uses hmmalign to align the sequences to the profile, then ouputs the
-    sequence contatenated at the beginning of the sequences in the A3M format.
-    As the sequences are represented by an alignment with possible gaps ('-')
-    and insertions (lowercase characters), the method first removes the gaps,
-    then uppercases the insertions to prepare the sequences for realignment.
-    Sequences with gaps cannot be aligned, as '-'s are not a valid symbol to
-    align; lowercase characters must be uppercased to preserve the original
-    sequences before realignment.
-
-    Args:
-      profile: The Hmmbuild profile to align the sequences to.
-      sequences_a3m: Sequences in A3M format to align to the profile.
-
-    Returns:
-      An A3M string with the aligned sequences.
-
-    Raises:
-      RuntimeError: If hmmalign fails.
-    """
-    deletion_table = str.maketrans('', '', '-')
-    sequences_no_gaps_a3m = []
-    for seq, desc in parsers.lazy_parse_fasta_string(sequences_a3m):
-      sequences_no_gaps_a3m.append(f'>{desc}')
-      sequences_no_gaps_a3m.append(seq.translate(deletion_table))
-    sequences_no_gaps_a3m = '\n'.join(sequences_no_gaps_a3m)
-
-    aligned_sequences = self.align(sequences_no_gaps_a3m, profile)
-
-    return aligned_sequences
diff --git a/src/alphafold3/data/tools/hmmbuild.py b/src/alphafold3/data/tools/hmmbuild.py
deleted file mode 100644
index 64e2f45e3fb72cb312b218f31a1adc86583b9639..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/tools/hmmbuild.py
+++ /dev/null
@@ -1,144 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""A Python wrapper for hmmbuild - construct HMM profiles from MSA."""
-
-import os
-import re
-import tempfile
-from typing import Literal
-
-from alphafold3.data import parsers
-from alphafold3.data.tools import subprocess_utils
-
-
-class Hmmbuild(object):
-  """Python wrapper of the hmmbuild binary."""
-
-  def __init__(
-      self,
-      *,
-      binary_path: str,
-      singlemx: bool = False,
-      alphabet: str | None = None,
-  ):
-    """Initializes the Python hmmbuild wrapper.
-
-    Args:
-      binary_path: The path to the hmmbuild executable.
-      singlemx: Whether to use --singlemx flag. If True, it forces HMMBuild to
-        just use a common substitution score matrix.
-      alphabet: The alphabet to assert when building a profile. Useful when
-        hmmbuild cannot guess the alphabet. If None, no alphabet is asserted.
-
-    Raises:
-      RuntimeError: If hmmbuild binary not found within the path.
-    """
-    self.binary_path = binary_path
-    self.singlemx = singlemx
-    self.alphabet = alphabet
-
-    subprocess_utils.check_binary_exists(path=self.binary_path, name='hmmbuild')
-
-  def build_profile_from_sto(self, sto: str, model_construction='fast') -> str:
-    """Builds a HHM for the aligned sequences given as an A3M string.
-
-    Args:
-      sto: A string with the aligned sequences in the Stockholm format.
-      model_construction: Whether to use reference annotation in the msa to
-        determine consensus columns ('hand') or default ('fast').
-
-    Returns:
-      A string with the profile in the HMM format.
-
-    Raises:
-      RuntimeError: If hmmbuild fails.
-    """
-    return self._build_profile(
-        sto, informat='stockholm', model_construction=model_construction
-    )
-
-  def build_profile_from_a3m(self, a3m: str) -> str:
-    """Builds a HHM for the aligned sequences given as an A3M string.
-
-    Args:
-      a3m: A string with the aligned sequences in the A3M format.
-
-    Returns:
-      A string with the profile in the HMM format.
-
-    Raises:
-      RuntimeError: If hmmbuild fails.
-    """
-    lines = []
-    for sequence, description in parsers.lazy_parse_fasta_string(a3m):
-      sequence = re.sub('[a-z]+', '', sequence)  # Remove inserted residues.
-      lines.append(f'>{description}\n{sequence}\n')
-    msa = ''.join(lines)
-    return self._build_profile(msa, informat='afa')
-
-  def _build_profile(
-      self,
-      msa: str,
-      informat: Literal['afa', 'stockholm'],
-      model_construction: str = 'fast',
-  ) -> str:
-    """Builds a HMM for the aligned sequences given as an MSA string.
-
-    Args:
-      msa: A string with the aligned sequences, in A3M or STO format.
-      informat: One of 'afa' (aligned FASTA) or 'sto' (Stockholm).
-      model_construction: Whether to use reference annotation in the msa to
-        determine consensus columns ('hand') or default ('fast').
-
-    Returns:
-      A string with the profile in the HMM format.
-
-    Raises:
-      RuntimeError: If hmmbuild fails.
-      ValueError: If unspecified arguments are provided.
-    """
-    if model_construction not in {'hand', 'fast'}:
-      raise ValueError(f'Bad {model_construction=}. Only hand or fast allowed.')
-
-    with tempfile.TemporaryDirectory() as query_tmp_dir:
-      input_msa_path = os.path.join(query_tmp_dir, 'query.msa')
-      output_hmm_path = os.path.join(query_tmp_dir, 'output.hmm')
-
-      with open(input_msa_path, 'w') as f:
-        f.write(msa)
-
-      # Specify the format as we don't specify the input file extension. See
-      # https://github.com/EddyRivasLab/hmmer/issues/321 for more details.
-      cmd_flags = ['--informat', informat]
-      # If adding flags, we have to do so before the output and input:
-      if model_construction == 'hand':
-        cmd_flags.append(f'--{model_construction}')
-      if self.singlemx:
-        cmd_flags.append('--singlemx')
-      if self.alphabet:
-        cmd_flags.append(f'--{self.alphabet}')
-
-      cmd_flags.extend([output_hmm_path, input_msa_path])
-
-      cmd = [self.binary_path, *cmd_flags]
-
-      subprocess_utils.run(
-          cmd=cmd,
-          cmd_name='Hmmbuild',
-          log_stdout=False,
-          log_stderr=True,
-          log_on_process_error=True,
-      )
-
-      with open(output_hmm_path) as f:
-        hmm = f.read()
-
-    return hmm
diff --git a/src/alphafold3/data/tools/hmmsearch.py b/src/alphafold3/data/tools/hmmsearch.py
deleted file mode 100644
index 07de7071d446af47552a7924e82aa5c30996888b..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/tools/hmmsearch.py
+++ /dev/null
@@ -1,149 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""A Python wrapper for hmmsearch - search profile against a sequence db."""
-
-import os
-import tempfile
-
-from absl import logging
-from alphafold3.data import parsers
-from alphafold3.data.tools import hmmbuild
-from alphafold3.data.tools import subprocess_utils
-
-
-class Hmmsearch(object):
-  """Python wrapper of the hmmsearch binary."""
-
-  def __init__(
-      self,
-      *,
-      binary_path: str,
-      hmmbuild_binary_path: str,
-      database_path: str,
-      alphabet: str = 'amino',
-      filter_f1: float | None = None,
-      filter_f2: float | None = None,
-      filter_f3: float | None = None,
-      e_value: float | None = None,
-      inc_e: float | None = None,
-      dom_e: float | None = None,
-      incdom_e: float | None = None,
-      filter_max: bool = False,
-  ):
-    """Initializes the Python hmmsearch wrapper.
-
-    Args:
-      binary_path: The path to the hmmsearch executable.
-      hmmbuild_binary_path: The path to the hmmbuild executable. Used to build
-        an hmm from an input a3m.
-      database_path: The path to the hmmsearch database (FASTA format).
-      alphabet: Chain type e.g. amino, rna, dna.
-      filter_f1: MSV and biased composition pre-filter, set to >1.0 to turn off.
-      filter_f2: Viterbi pre-filter, set to >1.0 to turn off.
-      filter_f3: Forward pre-filter, set to >1.0 to turn off.
-      e_value: E-value criteria for inclusion in tblout.
-      inc_e: E-value criteria for inclusion in MSA/next round.
-      dom_e: Domain e-value criteria for inclusion in tblout.
-      incdom_e: Domain e-value criteria for inclusion of domains in MSA/next
-        round.
-      filter_max: Remove all filters, will ignore all filter_f* settings.
-
-    Raises:
-      RuntimeError: If hmmsearch binary not found within the path.
-    """
-    self.binary_path = binary_path
-    self.hmmbuild_runner = hmmbuild.Hmmbuild(
-        alphabet=alphabet, binary_path=hmmbuild_binary_path
-    )
-    self.database_path = database_path
-    flags = []
-    if filter_max:
-      flags.append('--max')
-    else:
-      if filter_f1 is not None:
-        flags.extend(('--F1', filter_f1))
-      if filter_f2 is not None:
-        flags.extend(('--F2', filter_f2))
-      if filter_f3 is not None:
-        flags.extend(('--F3', filter_f3))
-
-    if e_value is not None:
-      flags.extend(('-E', e_value))
-    if inc_e is not None:
-      flags.extend(('--incE', inc_e))
-    if dom_e is not None:
-      flags.extend(('--domE', dom_e))
-    if incdom_e is not None:
-      flags.extend(('--incdomE', incdom_e))
-
-    self.flags = tuple(map(str, flags))
-
-    subprocess_utils.check_binary_exists(
-        path=self.binary_path, name='hmmsearch'
-    )
-
-    if not os.path.exists(self.database_path):
-      logging.error('Could not find hmmsearch database %s', database_path)
-      raise ValueError(f'Could not find hmmsearch database {database_path}')
-
-  def query_with_hmm(self, hmm: str) -> str:
-    """Queries the database using hmmsearch using a given hmm."""
-    with tempfile.TemporaryDirectory() as query_tmp_dir:
-      hmm_input_path = os.path.join(query_tmp_dir, 'query.hmm')
-      sto_out_path = os.path.join(query_tmp_dir, 'output.sto')
-      with open(hmm_input_path, 'w') as f:
-        f.write(hmm)
-
-      cmd = [
-          self.binary_path,
-          '--noali',  # Don't include the alignment in stdout.
-          *('--cpu', '8'),
-      ]
-      # If adding flags, we have to do so before the output and input:
-      if self.flags:
-        cmd.extend(self.flags)
-      cmd.extend([
-          *('-A', sto_out_path),
-          hmm_input_path,
-          self.database_path,
-      ])
-
-      subprocess_utils.run(
-          cmd=cmd,
-          cmd_name=f'Hmmsearch ({os.path.basename(self.database_path)})',
-          log_stdout=False,
-          log_stderr=True,
-          log_on_process_error=True,
-      )
-
-      with open(sto_out_path) as f:
-        a3m_out = parsers.convert_stockholm_to_a3m(
-            f, remove_first_row_gaps=False, linewidth=60
-        )
-
-    return a3m_out
-
-  def query_with_a3m(self, a3m_in: str) -> str:
-    """Query the database using hmmsearch using a given a3m."""
-
-    # Only the "fast" model construction makes sense with A3M, as it doesn't
-    # have any way to annotate reference columns.
-    hmm = self.hmmbuild_runner.build_profile_from_a3m(a3m_in)
-    return self.query_with_hmm(hmm)
-
-  def query_with_sto(
-      self, msa_sto: str, model_construction: str = 'fast'
-  ) -> str:
-    """Queries the database using hmmsearch using a given stockholm msa."""
-    hmm = self.hmmbuild_runner.build_profile_from_sto(
-        msa_sto, model_construction=model_construction
-    )
-    return self.query_with_hmm(hmm)
diff --git a/src/alphafold3/data/tools/jackhmmer.py b/src/alphafold3/data/tools/jackhmmer.py
deleted file mode 100644
index 2874cf73640ec7df422aacdff752595508f22b8f..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/tools/jackhmmer.py
+++ /dev/null
@@ -1,134 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Library to run Jackhmmer from Python."""
-
-import os
-import tempfile
-
-from absl import logging
-from alphafold3.data import parsers
-from alphafold3.data.tools import msa_tool
-from alphafold3.data.tools import subprocess_utils
-
-
-class Jackhmmer(msa_tool.MsaTool):
-  """Python wrapper of the Jackhmmer binary."""
-
-  def __init__(
-      self,
-      *,
-      binary_path: str,
-      database_path: str,
-      n_cpu: int = 8,
-      n_iter: int = 3,
-      e_value: float | None = 1e-3,
-      z_value: float | int | None = None,
-      max_sequences: int = 5000,
-      filter_f1: float = 5e-4,
-      filter_f2: float = 5e-5,
-      filter_f3: float = 5e-7,
-  ):
-    """Initializes the Python Jackhmmer wrapper.
-
-    Args:
-      binary_path: The path to the jackhmmer executable.
-      database_path: The path to the jackhmmer database (FASTA format).
-      n_cpu: The number of CPUs to give Jackhmmer.
-      n_iter: The number of Jackhmmer iterations.
-      e_value: The E-value, see Jackhmmer docs for more details.
-      z_value: The Z-value representing the number of comparisons done (i.e
-        correct database size) for E-value calculation.
-      max_sequences: Maximum number of sequences to return in the MSA.
-      filter_f1: MSV and biased composition pre-filter, set to >1.0 to turn off.
-      filter_f2: Viterbi pre-filter, set to >1.0 to turn off.
-      filter_f3: Forward pre-filter, set to >1.0 to turn off.
-
-    Raises:
-      RuntimeError: If Jackhmmer binary not found within the path.
-    """
-    self.binary_path = binary_path
-    self.database_path = database_path
-
-    subprocess_utils.check_binary_exists(
-        path=self.binary_path, name='Jackhmmer'
-    )
-
-    if not os.path.exists(self.database_path):
-      raise ValueError(f'Could not find Jackhmmer database {database_path}')
-
-    self.n_cpu = n_cpu
-    self.n_iter = n_iter
-    self.e_value = e_value
-    self.z_value = z_value
-    self.max_sequences = max_sequences
-    self.filter_f1 = filter_f1
-    self.filter_f2 = filter_f2
-    self.filter_f3 = filter_f3
-
-  def query(self, target_sequence: str) -> msa_tool.MsaToolResult:
-    """Queries the database using Jackhmmer."""
-    logging.info('Query sequence: %s', target_sequence)
-    with tempfile.TemporaryDirectory() as query_tmp_dir:
-      input_fasta_path = os.path.join(query_tmp_dir, 'query.fasta')
-      subprocess_utils.create_query_fasta_file(
-          sequence=target_sequence, path=input_fasta_path
-      )
-
-      output_sto_path = os.path.join(query_tmp_dir, 'output.sto')
-
-      # The F1/F2/F3 are the expected proportion to pass each of the filtering
-      # stages (which get progressively more expensive), reducing these
-      # speeds up the pipeline at the expensive of sensitivity.  They are
-      # currently set very low to make querying Mgnify run in a reasonable
-      # amount of time.
-      cmd_flags = [
-          *('-o', '/dev/null'),  # Don't pollute stdout with Jackhmmer output.
-          *('-A', output_sto_path),
-          '--noali',
-          *('--F1', str(self.filter_f1)),
-          *('--F2', str(self.filter_f2)),
-          *('--F3', str(self.filter_f3)),
-          *('--cpu', str(self.n_cpu)),
-          *('-N', str(self.n_iter)),
-      ]
-
-      # Report only sequences with E-values <= x in per-sequence output.
-      if self.e_value is not None:
-        cmd_flags.extend(['-E', str(self.e_value)])
-
-        # Use the same value as the reporting e-value (`-E` flag).
-        cmd_flags.extend(['--incE', str(self.e_value)])
-
-      if self.z_value is not None:
-        cmd_flags.extend(['-Z', str(self.z_value)])
-
-      cmd = (
-          [self.binary_path]
-          + cmd_flags
-          + [input_fasta_path, self.database_path]
-      )
-
-      subprocess_utils.run(
-          cmd=cmd,
-          cmd_name=f'Jackhmmer ({os.path.basename(self.database_path)})',
-          log_stdout=False,
-          log_stderr=True,
-          log_on_process_error=True,
-      )
-
-      with open(output_sto_path) as f:
-        a3m = parsers.convert_stockholm_to_a3m(
-            f, max_sequences=self.max_sequences
-        )
-
-    return msa_tool.MsaToolResult(
-        target_sequence=target_sequence, a3m=a3m, e_value=self.e_value
-    )
diff --git a/src/alphafold3/data/tools/msa_tool.py b/src/alphafold3/data/tools/msa_tool.py
deleted file mode 100644
index a739f06331dc70d491c0d9e8e8db2ed004cea48c..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/tools/msa_tool.py
+++ /dev/null
@@ -1,30 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Defines protocol for MSA tools."""
-
-import dataclasses
-from typing import Protocol
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class MsaToolResult:
-  """The result of a MSA tool query."""
-
-  target_sequence: str
-  e_value: float
-  a3m: str
-
-
-class MsaTool(Protocol):
-  """Interface for MSA tools."""
-
-  def query(self, target_sequence: str) -> MsaToolResult:
-    """Runs the MSA tool on the target sequence."""
diff --git a/src/alphafold3/data/tools/nhmmer.py b/src/alphafold3/data/tools/nhmmer.py
deleted file mode 100644
index e9472f51ed50eb321e6177b4d20c62beceefc85f..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/tools/nhmmer.py
+++ /dev/null
@@ -1,166 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Library to run Nhmmer from Python."""
-
-import os
-import pathlib
-import tempfile
-from typing import Final
-
-from absl import logging
-from alphafold3.data import parsers
-from alphafold3.data.tools import hmmalign
-from alphafold3.data.tools import hmmbuild
-from alphafold3.data.tools import msa_tool
-from alphafold3.data.tools import subprocess_utils
-
-_SHORT_SEQUENCE_CUTOFF: Final[int] = 50
-
-
-class Nhmmer(msa_tool.MsaTool):
-  """Python wrapper of the Nhmmer binary."""
-
-  def __init__(
-      self,
-      binary_path: str,
-      hmmalign_binary_path: str,
-      hmmbuild_binary_path: str,
-      database_path: str,
-      n_cpu: int = 8,
-      e_value: float = 1e-3,
-      max_sequences: int = 5000,
-      filter_f3: float = 1e-5,
-      alphabet: str | None = None,
-      strand: str | None = None,
-  ):
-    """Initializes the Python Nhmmer wrapper.
-
-    Args:
-      binary_path: Path to the Nhmmer binary.
-      hmmalign_binary_path: Path to the Hmmalign binary.
-      hmmbuild_binary_path: Path to the Hmmbuild binary.
-      database_path: MSA database path to search against. This can be either a
-        FASTA (slow) or HMMERDB produced from the FASTA using the makehmmerdb
-        binary. The HMMERDB is ~10x faster but experimental.
-      n_cpu: The number of CPUs to give Nhmmer.
-      e_value: The E-value, see Nhmmer docs for more details. Will be
-        overwritten if bit_score is set.
-      max_sequences: Maximum number of sequences to return in the MSA.
-      filter_f3: Forward pre-filter, set to >1.0 to turn off.
-      alphabet: The alphabet to assert when building a profile with hmmbuild.
-        This must be 'rna', 'dna', or None.
-      strand: "watson" searches query sequence, "crick" searches
-        reverse-compliment and default is None which means searching for both.
-
-    Raises:
-      RuntimeError: If Nhmmer binary not found within the path.
-    """
-    self._binary_path = binary_path
-    self._hmmalign_binary_path = hmmalign_binary_path
-    self._hmmbuild_binary_path = hmmbuild_binary_path
-    self._db_path = database_path
-
-    subprocess_utils.check_binary_exists(path=self._binary_path, name='Nhmmer')
-
-    if strand and strand not in {'watson', 'crick'}:
-      raise ValueError(f'Invalid {strand=}. only "watson" or "crick" supported')
-
-    if alphabet and alphabet not in {'rna', 'dna'}:
-      raise ValueError(f'Invalid {alphabet=}, only "rna" or "dna" supported')
-
-    self._e_value = e_value
-    self._n_cpu = n_cpu
-    self._max_sequences = max_sequences
-    self._filter_f3 = filter_f3
-    self._alphabet = alphabet
-    self._strand = strand
-
-  def query(self, target_sequence: str) -> msa_tool.MsaToolResult:
-    """Query the database using Nhmmer."""
-    logging.info('Query sequence: %s', target_sequence)
-
-    with tempfile.TemporaryDirectory() as query_tmp_dir:
-      input_a3m_path = os.path.join(query_tmp_dir, 'query.a3m')
-      output_sto_path = os.path.join(query_tmp_dir, 'output.sto')
-      pathlib.Path(output_sto_path).touch()
-      subprocess_utils.create_query_fasta_file(
-          sequence=target_sequence, path=input_a3m_path
-      )
-
-      cmd_flags = [
-          *('-o', '/dev/null'),  # Don't pollute stdout with nhmmer output.
-          '--noali',  # Don't include the alignment in stdout.
-          *('--cpu', str(self._n_cpu)),
-      ]
-
-      cmd_flags.extend(['-E', str(self._e_value)])
-
-      if self._alphabet:
-        cmd_flags.extend([f'--{self._alphabet}'])
-
-      if self._strand is not None:
-        cmd_flags.extend([f'--{self._strand}'])
-
-      cmd_flags.extend(['-A', output_sto_path])
-      # As recommend by RNAcentral for short sequences.
-      if (
-          self._alphabet == 'rna'
-          and len(target_sequence) < _SHORT_SEQUENCE_CUTOFF
-      ):
-        cmd_flags.extend(['--F3', str(0.02)])
-      else:
-        cmd_flags.extend(['--F3', str(self._filter_f3)])
-
-      # The input A3M and the db are the last two arguments.
-      cmd_flags.extend((input_a3m_path, self._db_path))
-
-      cmd = [self._binary_path, *cmd_flags]
-
-      subprocess_utils.run(
-          cmd=cmd,
-          cmd_name=f'Nhmmer ({os.path.basename(self._db_path)})',
-          log_stdout=False,
-          log_stderr=True,
-          log_on_process_error=True,
-      )
-
-      if os.path.getsize(output_sto_path) > 0:
-        with open(output_sto_path) as f:
-          a3m_out = parsers.convert_stockholm_to_a3m(
-              f, max_sequences=self._max_sequences - 1  # Query not included.
-          )
-        # Nhmmer hits are generally shorter than the query sequence. To get MSA
-        # of width equal to the query sequence, align hits to the query profile.
-        logging.info('Aligning output a3m of size %d bytes', len(a3m_out))
-
-        aligner = hmmalign.Hmmalign(self._hmmalign_binary_path)
-        target_sequence_fasta = f'>query\n{target_sequence}\n'
-        profile_builder = hmmbuild.Hmmbuild(
-            binary_path=self._hmmbuild_binary_path, alphabet=self._alphabet
-        )
-        profile = profile_builder.build_profile_from_a3m(target_sequence_fasta)
-        a3m_out = aligner.align_sequences_to_profile(
-            profile=profile, sequences_a3m=a3m_out
-        )
-        a3m_out = ''.join([target_sequence_fasta, a3m_out])
-
-        # Parse the output a3m to remove line breaks.
-        a3m = '\n'.join(
-            [f'>{n}\n{s}' for s, n in parsers.lazy_parse_fasta_string(a3m_out)]
-        )
-      else:
-        # Nhmmer returns an empty file if there are no hits.
-        # In this case return only the query sequence.
-        a3m = f'>query\n{target_sequence}'
-
-    return msa_tool.MsaToolResult(
-        target_sequence=target_sequence, e_value=self._e_value, a3m=a3m
-    )
diff --git a/src/alphafold3/data/tools/rdkit_utils.py b/src/alphafold3/data/tools/rdkit_utils.py
deleted file mode 100644
index a9b61a1f53dcb6a977ac6d8e5bbe7c406be040b9..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/tools/rdkit_utils.py
+++ /dev/null
@@ -1,543 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Tools for calculating features for ligands."""
-
-import collections
-from collections.abc import Mapping, Sequence
-
-from absl import logging
-from alphafold3.cpp import cif_dict
-import numpy as np
-import rdkit.Chem as rd_chem
-from rdkit.Chem import AllChem as rd_all_chem
-
-
-_RDKIT_MMCIF_TO_BOND_TYPE: Mapping[str, rd_chem.BondType] = {
-    'SING': rd_chem.BondType.SINGLE,
-    'DOUB': rd_chem.BondType.DOUBLE,
-    'TRIP': rd_chem.BondType.TRIPLE,
-}
-
-_RDKIT_BOND_TYPE_TO_MMCIF: Mapping[rd_chem.BondType, str] = {
-    v: k for k, v in _RDKIT_MMCIF_TO_BOND_TYPE.items()
-}
-
-_RDKIT_BOND_STEREO_TO_MMCIF: Mapping[rd_chem.BondStereo, str] = {
-    rd_chem.BondStereo.STEREONONE: 'N',
-    rd_chem.BondStereo.STEREOE: 'E',
-    rd_chem.BondStereo.STEREOZ: 'Z',
-    rd_chem.BondStereo.STEREOCIS: 'Z',
-    rd_chem.BondStereo.STEREOTRANS: 'E',
-}
-
-
-class MolFromMmcifError(Exception):
-  """Raised when conversion from mmCIF to RDKit Mol fails."""
-
-
-class UnsupportedMolBondError(Exception):
-  """Raised when we try to handle unsupported RDKit bonds."""
-
-
-def _populate_atoms_in_mol(
-    mol: rd_chem.Mol,
-    atom_names: Sequence[str],
-    atom_types: Sequence[str],
-    atom_charges: Sequence[int],
-    implicit_hydrogens: bool,
-    ligand_name: str,
-    atom_leaving_flags: Sequence[str],
-):
-  """Populate the atoms of a Mol given atom features.
-
-  Args:
-    mol: Mol object.
-    atom_names: Names of the atoms.
-    atom_types: Types of the atoms.
-    atom_charges: Charges of the atoms.
-    implicit_hydrogens: Whether to mark the atoms to allow implicit Hs.
-    ligand_name: Name of the ligand which the atoms are in.
-    atom_leaving_flags: Whether the atom is possibly a leaving atom. Values from
-      the CCD column `_chem_comp_atom.pdbx_leaving_atom_flag`. The expected
-      values are 'Y' (yes), 'N' (no), '?' (unknown/unset, interpreted as no).
-
-  Raises:
-    ValueError: If atom type is invalid.
-  """
-  # Map atom names to the position they will take in the rdkit molecule.
-  atom_name_to_idx = {name: i for i, name in enumerate(atom_names)}
-
-  for atom_name, atom_type, atom_charge, atom_leaving_flag in zip(
-      atom_names, atom_types, atom_charges, atom_leaving_flags, strict=True
-  ):
-    try:
-      if atom_type == 'X':
-        atom_type = '*'
-      atom = rd_chem.Atom(atom_type)
-    except RuntimeError as e:
-      raise ValueError(f'Failed to use atom type: {str(e)}') from e
-
-    if not implicit_hydrogens:
-      atom.SetNoImplicit(True)
-
-    atom.SetProp('atom_name', atom_name)
-    atom.SetProp('atom_leaving_flag', atom_leaving_flag)
-    atom.SetFormalCharge(atom_charge)
-    residue_info = rd_chem.AtomPDBResidueInfo()
-    residue_info.SetName(_format_atom_name(atom_name, atom_type))
-    residue_info.SetIsHeteroAtom(True)
-    residue_info.SetResidueName(ligand_name)
-    residue_info.SetResidueNumber(1)
-    atom.SetPDBResidueInfo(residue_info)
-    atom_index = mol.AddAtom(atom)
-    assert atom_index == atom_name_to_idx[atom_name]
-
-
-def _populate_bonds_in_mol(
-    mol: rd_chem.Mol,
-    atom_names: Sequence[str],
-    bond_begins: Sequence[str],
-    bond_ends: Sequence[str],
-    bond_orders: Sequence[str],
-    bond_is_aromatics: Sequence[bool],
-):
-  """Populate the bonds of a Mol given bond features.
-
-  Args:
-    mol: Mol object.
-    atom_names: Names of atoms in the molecule.
-    bond_begins: Names of atoms at the beginning of the bond.
-    bond_ends: Names of atoms at the end of the bond.
-    bond_orders: What order the bonds are.
-    bond_is_aromatics: Whether the bonds are aromatic.
-  """
-  atom_name_to_idx = {name: i for i, name in enumerate(atom_names)}
-  for begin, end, bond_type, is_aromatic in zip(
-      bond_begins, bond_ends, bond_orders, bond_is_aromatics, strict=True
-  ):
-    begin_name, end_name = atom_name_to_idx[begin], atom_name_to_idx[end]
-    bond_idx = mol.AddBond(begin_name, end_name, bond_type)
-    mol.GetBondWithIdx(bond_idx - 1).SetIsAromatic(is_aromatic)
-
-
-def sanitize_mol(mol, sort_alphabetically, remove_hydrogens) -> rd_chem.Mol:
-  # https://www.rdkit.org/docs/source/rdkit.Chem.rdmolops.html#rdkit.Chem.rdmolops.SanitizeMol
-  # Kekulize, check valencies, set aromaticity, conjugation and hybridization.
-  # This can repair e.g. incorrect aromatic flags.
-  rd_chem.SanitizeMol(mol)
-  if sort_alphabetically:
-    mol = sort_atoms_by_name(mol)
-  if remove_hydrogens:
-    mol = rd_chem.RemoveHs(mol)
-  return mol
-
-
-def _add_conformer_to_mol(mol, conformer, force_parse) -> rd_chem.Mol:
-  # Create conformer and use it to assign stereochemistry.
-  if conformer is not None:
-    try:
-      mol.AddConformer(conformer)
-      rd_chem.AssignStereochemistryFrom3D(mol)
-    except ValueError as e:
-      logging.warning('Failed to parse conformer: %s', e)
-      if not force_parse:
-        raise
-
-
-def mol_from_ccd_cif(
-    mol_cif: cif_dict.CifDict,
-    *,
-    force_parse: bool = False,
-    sort_alphabetically: bool = True,
-    remove_hydrogens: bool = True,
-    implicit_hydrogens: bool = False,
-) -> rd_chem.Mol:
-  """Creates an rdkit Mol object from a CCD mmcif data block.
-
-  The atoms are renumbered so that their names are in alphabetical order and
-  these names are placed on the atoms under property 'atom_name'.
-  Only hydrogens which are not required to define the molecule are removed.
-  For example, hydrogens that define stereochemistry around a double bond are
-  retained.
-  See this link for more details.
-  https://www.rdkit.org/docs/source/rdkit.Chem.rdmolops.html#rdkit.Chem.rdmolops.RemoveHs
-
-  Args:
-     mol_cif: An mmcif object representing a molecule.
-     force_parse: If True, assumes missing aromatic flags are false, substitutes
-       deuterium for hydrogen, assumes missing charges are 0 and ignores missing
-       conformer / stereochemistry information.
-     sort_alphabetically: True: sort atom alphabetically; False: keep CCD order
-     remove_hydrogens: if True, remove non-important hydrogens
-     implicit_hydrogens: Sets a marker on the atom that allows implicit Hs.
-
-  Returns:
-     An rdkit molecule, with the atoms sorted by name.
-
-  Raises:
-    MolToMmcifError: If conversion from mmcif to rdkit Mol fails. More detailed
-      error is available as this error's cause.
-  """
-  # Read data fields.
-  try:
-    atom_names, atom_types, atom_charges, atom_leaving_flags = parse_atom_data(
-        mol_cif, force_parse
-    )
-    bond_begins, bond_ends, bond_orders, bond_is_aromatics = parse_bond_data(
-        mol_cif, force_parse
-    )
-    lig_name = mol_cif['_chem_comp.id'][0].rjust(3)
-  except (KeyError, ValueError) as e:
-    raise MolFromMmcifError from e
-
-  # Build Rdkit molecule.
-  mol = rd_chem.RWMol()
-
-  # Per atom features.
-  try:
-    _populate_atoms_in_mol(
-        mol=mol,
-        atom_names=atom_names,
-        atom_types=atom_types,
-        atom_charges=atom_charges,
-        implicit_hydrogens=implicit_hydrogens,
-        ligand_name=lig_name,
-        atom_leaving_flags=atom_leaving_flags,
-    )
-  except (ValueError, RuntimeError) as e:
-    raise MolFromMmcifError from e
-
-  _populate_bonds_in_mol(
-      mol, atom_names, bond_begins, bond_ends, bond_orders, bond_is_aromatics
-  )
-
-  try:
-    conformer = _parse_ideal_conformer(mol_cif)
-  except (KeyError, ValueError) as e:
-    logging.warning('Failed to parse ideal conformer: %s', e)
-    if not force_parse:
-      raise MolFromMmcifError from e
-    conformer = None
-
-  mol.UpdatePropertyCache(strict=False)
-
-  try:
-    _add_conformer_to_mol(mol, conformer, force_parse)
-    mol = sanitize_mol(mol, sort_alphabetically, remove_hydrogens)
-  except (
-      ValueError,
-      rd_chem.KekulizeException,
-      rd_chem.AtomValenceException,
-  ) as e:
-    raise MolFromMmcifError from e
-
-  return mol
-
-
-def mol_to_ccd_cif(
-    mol: rd_chem.Mol,
-    component_id: str,
-    pdbx_smiles: str | None = None,
-    include_hydrogens: bool = True,
-) -> cif_dict.CifDict:
-  """Creates a CCD-like mmcif data block from an rdkit Mol object.
-
-  Only a subset of associated mmcif fields is populated, but that is
-  sufficient for further usage, e.g. in featurization code.
-
-  Atom names can be specified via `atom_name` property. For atoms with
-  unspecified value of that property, the name is assigned based on element type
-  and the order in the Mol object.
-
-  If the Mol object has associated conformers, atom positions from the first of
-  them will be populated in the resulting mmcif file.
-
-  Args:
-     mol: An rdkit molecule.
-     component_id: Name of the molecule to use in the resulting mmcif. That is
-       equivalent to CCD code.
-     pdbx_smiles: If specified, the value will be used to populate
-       `_chem_comp.pdbx_smiles`.
-     include_hydrogens: Whether to include atom and bond data involving
-       hydrogens.
-
-  Returns:
-     An mmcif data block corresponding for the given rdkit molecule.
-
-  Raises:
-    UnsupportedMolBond: When a molecule contains a bond that can't be
-      represented with mmcif.
-  """
-  mol = rd_chem.Mol(mol)
-  if include_hydrogens:
-    mol = rd_chem.AddHs(mol)
-  rd_chem.Kekulize(mol)
-
-  if mol.GetNumConformers() > 0:
-    ideal_conformer = mol.GetConformer(0).GetPositions()
-    ideal_conformer = np.vectorize(lambda x: f'{x:.3f}')(ideal_conformer)
-  else:
-    # No data will be populated in the resulting mmcif if the molecule doesn't
-    # have any conformers attached to it.
-    ideal_conformer = None
-
-  mol_cif = collections.defaultdict(list)
-  mol_cif['data_'] = [component_id]
-  mol_cif['_chem_comp.id'] = [component_id]
-  if pdbx_smiles:
-    mol_cif['_chem_comp.pdbx_smiles'] = [pdbx_smiles]
-
-  mol = assign_atom_names_from_graph(mol, keep_existing_names=True)
-
-  for atom_idx, atom in enumerate(mol.GetAtoms()):
-    element = atom.GetSymbol()
-    if not include_hydrogens and element in ('H', 'D'):
-      continue
-
-    mol_cif['_chem_comp_atom.comp_id'].append(component_id)
-    mol_cif['_chem_comp_atom.atom_id'].append(atom.GetProp('atom_name'))
-    mol_cif['_chem_comp_atom.type_symbol'].append(atom.GetSymbol().upper())
-    mol_cif['_chem_comp_atom.charge'].append(str(atom.GetFormalCharge()))
-    if ideal_conformer is not None:
-      coords = ideal_conformer[atom_idx]
-      mol_cif['_chem_comp_atom.pdbx_model_Cartn_x_ideal'].append(coords[0])
-      mol_cif['_chem_comp_atom.pdbx_model_Cartn_y_ideal'].append(coords[1])
-      mol_cif['_chem_comp_atom.pdbx_model_Cartn_z_ideal'].append(coords[2])
-
-  for bond in mol.GetBonds():
-    atom1 = bond.GetBeginAtom()
-    atom2 = bond.GetEndAtom()
-    if not include_hydrogens and (
-        atom1.GetSymbol() in ('H', 'D') or atom2.GetSymbol() in ('H', 'D')
-    ):
-      continue
-    mol_cif['_chem_comp_bond.comp_id'].append(component_id)
-    mol_cif['_chem_comp_bond.atom_id_1'].append(
-        bond.GetBeginAtom().GetProp('atom_name')
-    )
-    mol_cif['_chem_comp_bond.atom_id_2'].append(
-        bond.GetEndAtom().GetProp('atom_name')
-    )
-    try:
-      bond_type = bond.GetBondType()
-      # Older versions of RDKit did not have a DATIVE bond type. Convert it to
-      # SINGLE to match the AF3 training setup.
-      if bond_type == rd_chem.BondType.DATIVE:
-        bond_type = rd_chem.BondType.SINGLE
-      mol_cif['_chem_comp_bond.value_order'].append(
-          _RDKIT_BOND_TYPE_TO_MMCIF[bond_type]
-      )
-      mol_cif['_chem_comp_bond.pdbx_stereo_config'].append(
-          _RDKIT_BOND_STEREO_TO_MMCIF[bond.GetStereo()]
-      )
-    except KeyError as e:
-      raise UnsupportedMolBondError from e
-    mol_cif['_chem_comp_bond.pdbx_aromatic_flag'].append(
-        'Y' if bond.GetIsAromatic() else 'N'
-    )
-
-  return cif_dict.CifDict(mol_cif)
-
-
-def _format_atom_name(atom_name: str, atom_type: str) -> str:
-  """Formats an atom name to fit in the four characters specified in PDB.
-
-  See for example the following note on atom name formatting in PDB files:
-  https://www.cgl.ucsf.edu/chimera/docs/UsersGuide/tutorials/pdbintro.html#note1
-
-  Args:
-    atom_name: The unformatted atom name.
-    atom_type: The atom element symbol.
-
-  Returns:
-    formatted_atom_name: The formatted 4-character atom name.
-  """
-  atom_name = atom_name.strip()
-  atom_type = atom_type.strip().upper()
-  if len(atom_name) == 1:
-    return atom_name.rjust(2).ljust(4)
-  elif len(atom_name) == 2:
-    if atom_name == atom_type:
-      return atom_name.ljust(4)
-    return atom_name.center(4)
-  elif len(atom_name) == 3:
-    if atom_name[:2] == atom_type:
-      return atom_name.ljust(4)
-    return atom_name.rjust(4)
-  elif len(atom_name) == 4:
-    return atom_name
-  else:
-    raise ValueError(
-        f'Atom name `{atom_name}` has more than four characters '
-        'or is an empty string.'
-    )
-
-
-def parse_atom_data(
-    mol_cif: cif_dict.CifDict | Mapping[str, Sequence[str]], force_parse: bool
-) -> tuple[Sequence[str], Sequence[str], Sequence[int], Sequence[str]]:
-  """Parses atoms. If force_parse is True, fix deuterium and missing charge."""
-  atom_types = [t.capitalize() for t in mol_cif['_chem_comp_atom.type_symbol']]
-  atom_names = mol_cif['_chem_comp_atom.atom_id']
-  atom_charges = mol_cif['_chem_comp_atom.charge']
-  atom_leaving_flags = ['?'] * len(atom_names)
-  if '_chem_comp_atom.pdbx_leaving_atom_flag' in mol_cif:
-    atom_leaving_flags = mol_cif['_chem_comp_atom.pdbx_leaving_atom_flag']
-
-  if force_parse:
-    # Replace missing charges with 0.
-    atom_charges = [charge if charge != '?' else '0' for charge in atom_charges]
-    # Deuterium for hydrogen.
-    atom_types = [type_ if type_ != 'D' else 'H' for type_ in atom_types]
-
-  atom_charges = [int(atom_charge) for atom_charge in atom_charges]
-  return atom_names, atom_types, atom_charges, atom_leaving_flags
-
-
-def parse_bond_data(
-    mol_cif: cif_dict.CifDict | Mapping[str, Sequence[str]], force_parse: bool
-) -> tuple[
-    Sequence[str], Sequence[str], Sequence[rd_chem.BondType], Sequence[bool]
-]:
-  """Parses bond data. If force_parse is True, ignore missing aromatic flags."""
-  # The bond table isn't present if there are no bonds. Use [] in that case.
-  begin_atoms = mol_cif.get('_chem_comp_bond.atom_id_1', [])
-  end_atoms = mol_cif.get('_chem_comp_bond.atom_id_2', [])
-  orders = mol_cif.get('_chem_comp_bond.value_order', [])
-  bond_types = [_RDKIT_MMCIF_TO_BOND_TYPE[order] for order in orders]
-
-  try:
-    aromatic_flags = mol_cif.get('_chem_comp_bond.pdbx_aromatic_flag', [])
-    is_aromatic = [{'Y': True, 'N': False}[flag] for flag in aromatic_flags]
-  except KeyError:
-    if force_parse:
-      # Set them all to not aromatic.
-      is_aromatic = [False for _ in begin_atoms]
-    else:
-      raise
-
-  return begin_atoms, end_atoms, bond_types, is_aromatic
-
-
-def _parse_ideal_conformer(mol_cif: cif_dict.CifDict) -> rd_chem.Conformer:
-  """Builds a conformer containing the ideal coordinates from the CCD.
-
-  Args:
-     mol_cif: An mmcif object representing a molecule.
-
-  Returns:
-     An rdkit conformer filled with the ideal positions from the mmcif.
-
-  Raises:
-     ValueError: if the positions can't be interpreted.
-  """
-  atom_x = [
-      float(x) for x in mol_cif['_chem_comp_atom.pdbx_model_Cartn_x_ideal']
-  ]
-  atom_y = [
-      float(y) for y in mol_cif['_chem_comp_atom.pdbx_model_Cartn_y_ideal']
-  ]
-  atom_z = [
-      float(z) for z in mol_cif['_chem_comp_atom.pdbx_model_Cartn_z_ideal']
-  ]
-  atom_positions = zip(atom_x, atom_y, atom_z, strict=True)
-
-  conformer = rd_chem.Conformer(len(atom_x))
-  for atom_index, atom_position in enumerate(atom_positions):
-    conformer.SetAtomPosition(atom_index, atom_position)
-
-  return conformer
-
-
-def sort_atoms_by_name(mol: rd_chem.Mol) -> rd_chem.Mol:
-  """Sorts the atoms in the molecule by their names."""
-  atom_names = {
-      atom.GetProp('atom_name'): atom.GetIdx() for atom in mol.GetAtoms()
-  }
-
-  # Sort the name, int tuples by the names.
-  sorted_atom_names = sorted(atom_names.items())
-
-  # Zip these tuples back together to the sorted indices.
-  _, new_order = zip(*sorted_atom_names, strict=True)
-
-  # Reorder the molecule.
-  # new_order is effectively an argsort of the names.
-  return rd_chem.RenumberAtoms(mol, new_order)
-
-
-def assign_atom_names_from_graph(
-    mol: rd_chem.Mol,
-    keep_existing_names: bool = False,
-) -> rd_chem.Mol:
-  """Assigns atom names from the molecular graph.
-
-  The atom name is stored as an atom property 'atom_name', accessible
-  with atom.GetProp('atom_name'). If the property is already specified, and
-  keep_existing_names is True we keep the original name.
-
-  We traverse the graph in the order of the rdkit atom index and give each atom
-  a name equal to '{ELEMENT_TYPE}{INDEX}'. E.g. C5 is the name for the fifth
-  unnamed carbon encountered.
-
-  NOTE: A new mol is returned, the original is not changed in place.
-
-  Args:
-    mol: Mol object.
-    keep_existing_names: If True, atoms that already have the atom_name property
-      will keep their assigned names.
-
-  Returns:
-    A new mol, with potentially new 'atom_name' properties.
-  """
-  mol = rd_chem.Mol(mol)
-
-  specified_atom_names = {
-      atom.GetProp('atom_name')
-      for atom in mol.GetAtoms()
-      if atom.HasProp('atom_name') and keep_existing_names
-  }
-
-  element_counts = collections.Counter()
-  for atom in mol.GetAtoms():
-    if not atom.HasProp('atom_name') or not keep_existing_names:
-      element = atom.GetSymbol()
-      while True:
-        element_counts[element] += 1
-        # Standardize names by using uppercase element type, as in CCD. Only
-        # effects elements with more than one letter, e.g. 'Cl' becomes 'CL'.
-        new_name = f'{element.upper()}{element_counts[element]}'
-        if new_name not in specified_atom_names:
-          break
-      atom.SetProp('atom_name', new_name)
-
-  return mol
-
-
-def get_random_conformer(
-    mol: rd_chem.Mol,
-    random_seed: int,
-    max_iterations: int | None,
-    logging_name: str,
-) -> rd_chem.Conformer | None:
-  """Stochastic conformer search method using V3 ETK."""
-  params = rd_all_chem.ETKDGv3()
-  params.randomSeed = random_seed
-  if max_iterations is not None:  # Override default value.
-    params.maxIterations = max_iterations
-  mol_copy = rd_chem.Mol(mol)
-  try:
-    conformer_id = rd_all_chem.EmbedMolecule(mol_copy, params)
-    conformer = mol_copy.GetConformer(conformer_id)
-  except ValueError:
-    logging.warning('Failed to generate conformer for: %s', logging_name)
-    conformer = None
-  return conformer
diff --git a/src/alphafold3/data/tools/subprocess_utils.py b/src/alphafold3/data/tools/subprocess_utils.py
deleted file mode 100644
index a736d7a1fdabfb594048cde4637a2511f43bb2dc..0000000000000000000000000000000000000000
--- a/src/alphafold3/data/tools/subprocess_utils.py
+++ /dev/null
@@ -1,106 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Helper functions for launching external tools."""
-
-from collections.abc import Sequence
-import os
-import subprocess
-import time
-from typing import Any
-
-from absl import logging
-
-
-def create_query_fasta_file(sequence: str, path: str, linewidth: int = 80):
-  """Creates a fasta file with the sequence with line width limit."""
-  with open(path, 'w') as f:
-    f.write('>query\n')
-
-    i = 0
-    while i < len(sequence):
-      f.write(f'{sequence[i:(i + linewidth)]}\n')
-      i += linewidth
-
-
-def check_binary_exists(path: str, name: str) -> None:
-  """Checks if a binary exists on the given path and raises otherwise."""
-  if not os.path.exists(path):
-    raise RuntimeError(f'{name} binary not found at {path}')
-
-
-def run(
-    cmd: Sequence[str],
-    cmd_name: str,
-    log_on_process_error: bool = False,
-    log_stderr: bool = False,
-    log_stdout: bool = False,
-    max_out_streams_len: int | None = 500_000,
-    **run_kwargs,
-) -> subprocess.CompletedProcess[Any]:
-  """Launches a subprocess, times it, and checks for errors.
-
-  Args:
-    cmd: Command to launch.
-    cmd_name: Human-readable command name to be used in logs.
-    log_on_process_error: Whether to use `logging.error` to log the process'
-      stderr on failure.
-    log_stderr: Whether to log the stderr of the command.
-    log_stdout: Whether to log the stdout of the command.
-    max_out_streams_len: Max length of prefix of stdout and stderr included in
-      the exception message. Set to `None` to disable truncation.
-    **run_kwargs: Any other kwargs for `subprocess.run`.
-
-  Returns:
-    The completed process object.
-
-  Raises:
-    RuntimeError: if the process completes with a non-zero return code.
-  """
-
-  logging.info('Launching subprocess "%s"', ' '.join(cmd))
-
-  start_time = time.time()
-  try:
-    completed_process = subprocess.run(
-        cmd,
-        check=True,
-        stderr=subprocess.PIPE,
-        stdout=subprocess.PIPE,
-        text=True,
-        **run_kwargs,
-    )
-  except subprocess.CalledProcessError as e:
-    if log_on_process_error:
-      # Logs have a 15k character limit, so log the error line by line.
-      logging.error('%s failed. %s stderr begin:', cmd_name, cmd_name)
-      for error_line in e.stderr.splitlines():
-        if stripped_error_line := error_line.strip():
-          logging.error(stripped_error_line)
-      logging.error('%s stderr end.', cmd_name)
-
-    error_msg = (
-        f'{cmd_name} failed'
-        f'\nstdout:\n{e.stdout[:max_out_streams_len]}\n'
-        f'\nstderr:\n{e.stderr[:max_out_streams_len]}'
-    )
-    raise RuntimeError(error_msg) from e
-  end_time = time.time()
-
-  logging.info('Finished %s in %.3f seconds', cmd_name, end_time - start_time)
-  stdout, stderr = completed_process.stdout, completed_process.stderr
-
-  if log_stdout and stdout:
-    logging.info('%s stdout:\n%s', cmd_name, stdout)
-
-  if log_stderr and stderr:
-    logging.info('%s stderr:\n%s', cmd_name, stderr)
-
-  return completed_process
diff --git a/src/alphafold3/jax/attention/attention.py b/src/alphafold3/jax/attention/attention.py
deleted file mode 100644
index 26320039000aa12c9aae34e8d8460334c7487642..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/attention/attention.py
+++ /dev/null
@@ -1,139 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Scaled dot-product attention."""
-
-import typing
-from typing import Literal, TypeAlias
-
-from alphafold3.jax.attention import attention_base as base
-from alphafold3.jax.attention import flash_attention as attention_triton
-from alphafold3.jax.attention import xla_attention
-from alphafold3.jax.common import triton_utils
-import jax
-from jax.typing import DTypeLike  # pylint: disable=g-importing-member
-import jaxtyping
-from jaxtyping import Array  # pylint: disable=g-importing-member
-from jaxtyping import Bool  # pylint: disable=g-importing-member
-from jaxtyping import Float  # pylint: disable=g-importing-member
-import typeguard
-
-Implementation: TypeAlias = Literal["cudnn", "xla", "triton"]
-
-
-@jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-def dot_product_attention(
-    query: Float[Array, "*B T H D"],
-    key: Float[Array, "*B t #H D"],
-    value: Float[Array, "*B t #H D"],
-    *,
-    bias: Float[Array, "*#B #H #T #t"] | None = None,
-    mask: Bool[Array, "*#B #H #T #t"] | None = None,
-    implementation: Implementation | None = None,
-    logits_dtype: DTypeLike | None = None,
-    precision: (
-        jax.lax.Precision | tuple[jax.lax.Precision, jax.lax.Precision] | None
-    ) = None,
-) -> Float[Array, "*B T H D"]:
-  """Performs scaled dot-product attention.
-
-  Scaled dot-product attention from "Attention is all you need"
-  https://arxiv.org/abs/1706.03762.
-
-  Computes self- or cross-attention. The following is computed:
-  softmax(qk_scale * query @ key^T + bias) @ value.
-
-  Supports both multi-head and multi-query attention
-  (https://arxiv.org/abs/1911.02150).
-
-  Arguments:
-    query: Query array of shape `[batch, seq_len_q, num_heads, head_dim]`.
-    key: Key array of shape `[batch, seq_len_kv, num_heads, head_dim]`.
-      `num_heads` can be 1 for multi-query attention.
-    value: Value array of shape `[batch, seq_len_kv, num_heads, head_dim]`.
-      `num_heads` can be 1 for multi-query attention.
-    bias: Optional bias array, broadcastable to shape `[batch, num_heads,
-      seq_len_q, seq_len_kv]`.
-    mask: Optional boolean mask, broadcastable to `[batch, num_heads, seq_len_q,
-      seq_len_kv]`. Attention weights are masked out if the corresponding mask
-      value is `False`.
-    implementation: if `None` (default), an implementation is automatically
-      chosen. 'xla' will use standard XLA and work on any platform, 'triton'
-      will use a fused Triton GPU kernel, and 'cudnn' a cuDNN FlashAttention
-      kernel. Only a subset of data types, shapes and GPUs are supported by
-      'triton' and 'cudnn', with an exception thrown in this case.
-    logits_dtype: Data type for attention logits (`query @ key^T`). If `None` is
-      passed (the default), the accumulator type from the `query @ key^T` dot
-      product will be used, which is FP32 for BF16/FP16/FP32 inputs. Note that
-      this default increases the memory usage for BF16/FP16 inputs when using
-      `implementation='xla'`, but does not increase memory usage when using
-      `implementation='triton'`.
-    precision: The precision for the dot products. Either `None` (default) which
-      uses the default JAX precision for a backend; a tuple `(
-      query_key_dot_precision, weights_value_dot_precision)` of
-      `jax.lax.Precision` objects; or a single `jax.lax.Precision` object
-      applied to both dot products.
-
-  Returns:
-    An array with the same shape as `query`.
-  """
-
-  if implementation is not None:
-    named_args = typing.get_args(Implementation)
-    if implementation not in named_args:
-      raise ValueError(
-          f"Unsupported named implementation. Must be one of {named_args}."
-      )
-
-  if implementation == "cudnn":
-    if logits_dtype is not None:
-      raise ValueError(
-          "logits_dtype is not supported for cudnn implementation."
-      )
-    if precision is not None:
-      raise NotImplementedError(
-          "precision is not supported for cudnn implementation."
-      )
-
-    return jax.nn.dot_product_attention(
-        query=query,
-        key=key,
-        value=value,
-        bias=bias,
-        mask=mask,
-        implementation="cudnn",
-    )
-
-  logits_dtype = base.AUTO if logits_dtype is None else logits_dtype
-  precision = jax.lax.Precision.DEFAULT if precision is None else precision
-
-  args = (query, key, value)
-  kwargs = dict(
-      precision=precision,
-      logits_dtype=logits_dtype,
-      bias=bias,
-      mask=mask,
-  )
-
-  if implementation == "triton":
-    if not triton_utils.has_triton_support():
-      raise ValueError(
-          "implementation='triton' for FlashAttention is unsupported on this"
-          " GPU generation. Please use implementation='xla' instead."
-      )
-    return attention_triton.TritonFlashAttention()(*args, **kwargs)
-
-  if implementation is None and triton_utils.has_triton_support():
-    try:
-      return attention_triton.TritonFlashAttention()(*args, **kwargs)
-    except Exception:  # pylint: disable=broad-exception-caught
-      pass  # Fallback to XLA.
-
-  return xla_attention.XlaDotProductAttention()(*args, **kwargs)
diff --git a/src/alphafold3/jax/attention/attention_base.py b/src/alphafold3/jax/attention/attention_base.py
deleted file mode 100644
index 1b12869c4bc2c3aea141d3ab60daaf4627e79326..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/attention/attention_base.py
+++ /dev/null
@@ -1,363 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Common types and utilities for attention kernels."""
-
-import abc
-import dataclasses
-import enum
-import functools
-import math
-from typing import Any, Self
-
-from alphafold3.jax.common import array_view
-from alphafold3.jax.common import precision as precision_lib
-import jax
-import jax.numpy as jnp
-from jax.typing import DTypeLike  # pylint: disable=g-importing-member
-import jaxtyping
-from jaxtyping import Array, Bool, Float, Int  # pylint: disable=g-multiple-import,g-importing-member
-import typeguard
-
-
-class AUTO:  # Used as a sentinel value.
-  pass
-
-
-DotPrecisionLike = jax.lax.Precision | precision_lib.DotPrecision
-
-
-@jax.tree_util.register_pytree_node_class
-@dataclasses.dataclass(frozen=True)
-class Mask:
-  """An attention mask.
-
-  `k_start` (inclusive) and `k_end` (exclusive) define range of enabled
-  k-sequence values for each row of logits.
-
-  For example, a local attention mask could be defined as follows:
-  ```
-  seq_len_q = seq_len_k = 4
-  window_size = 2
-  k_start = jnp.maximum(0, jnp.arange(seq_len_q) + 1 - window_size)
-  mask = Mask(k_start=k_start, is_causal=True)
-  assert mask.as_array(seq_len_q, seq_len_k) == jnp.array(
-      [[1, 0, 0, 0],
-       [1, 1, 0, 0],
-       [0, 1, 1, 0],
-       [0, 0, 1, 1]], dtype=bool)
-  ```
-  Or equivalently (but less efficiently):
-  ```
-  k_end = jnp.arange(seq_len_q) + 1
-  k_start = jnp.maximum(0, k_end - window_size)
-  mask = Mask(k_start=k_start, k_end=k_end)
-  assert mask.as_array(seq_len_q, seq_len_k) == jnp.array(
-      [[1, 0, 0, 0],
-       [1, 1, 0, 0],
-       [0, 1, 1, 0],
-       [0, 0, 1, 1]], dtype=bool)
-  ```
-
-  A mask for two independent causal sequences could be defined as follows:
-  ```
-  k_start = jnp.array([0, 0, 2, 2])
-  mask = Mask(k_start=k_start, is_causal=True)
-  assert mask.as_array(seq_len_q, seq_len_k) == jnp.array(
-      [[1, 0, 0, 0],
-       [1, 1, 0, 0],
-       [0, 0, 1, 0],
-       [0, 0, 1, 1]], dtype=bool)
-  ```
-  """
-
-  bool_mask: Bool[Array, "*#B #T #t"] | None = None
-  _: dataclasses.KW_ONLY
-  q_start: Int[Array, "*#B #t"] | None = None
-  q_end: Int[Array, "*#B #t"] | None = None
-  k_start: Int[Array, "*#B #T"] | None = None
-  k_end: Int[Array, "*#B #T"] | None = None
-  is_causal: bool = False
-
-  def tree_flatten(self):
-    return (
-        self.bool_mask,
-        self.q_start,
-        self.q_end,
-        self.k_start,
-        self.k_end,
-    ), (self.is_causal,)
-
-  @classmethod
-  def tree_unflatten(cls, aux, children) -> Self:
-    (is_causal,) = aux
-    bool_mask, q_start, q_end, k_start, k_end = children
-    return cls(
-        bool_mask,
-        q_start=q_start,
-        q_end=q_end,
-        k_start=k_start,
-        k_end=k_end,
-        is_causal=is_causal,
-    )
-
-  def as_array(
-      self,
-      q_len_or_indices: int | Int[Array, "*#B T"],
-      k_len_or_indices: int | Int[Array, "*#B t"],
-  ) -> Bool[Array, "*#B #T #t"] | None:
-    """Returns the mask as a boolean array."""
-    if isinstance(q_len_or_indices, int):
-      q_indices = jnp.arange(q_len_or_indices)
-    else:
-      q_indices = q_len_or_indices
-
-    if isinstance(k_len_or_indices, int):
-      k_indices = jnp.arange(k_len_or_indices)
-    else:
-      k_indices = k_len_or_indices
-
-    q_indices = q_indices[..., None]
-    k_indices = k_indices[..., None, :]
-
-    mask = []
-    if self.bool_mask is not None:
-      mask.append(self.bool_mask)
-      # Check `bool_mask` shape is compatible with `{q,kv}_indices`.
-      _ = jnp.broadcast_shapes(
-          q_indices.shape, k_indices.shape, self.bool_mask.shape
-      )
-
-    if self.q_start is not None:
-      mask.append(q_indices >= self.q_start[..., None, :])
-
-    if self.q_end is not None:
-      mask.append(q_indices < self.q_end[..., None, :])
-
-    if self.k_start is not None:
-      mask.append(k_indices >= self.k_start[..., None])
-
-    if self.k_end is not None:
-      mask.append(k_indices < self.k_end[..., None])
-
-    if self.is_causal:
-      mask.append(q_indices >= k_indices)
-
-    logical_and = functools.partial(functools.reduce, jnp.logical_and)
-    return jax.lax.broadcast_to_rank(logical_and(mask), 3) if mask else None
-
-  def take(self, *attrs: str) -> tuple[Any, ...]:
-    """Returns a mask with attrs removed and the removed attrs."""
-    default_mask = type(self)()
-    replacements = {attr: getattr(default_mask, attr) for attr in attrs}
-    values = (getattr(self, attr) for attr in attrs)
-    return dataclasses.replace(self, **replacements), *values
-
-  def __and__(self, other: "Bool[Array, '*#B #T #t'] | Mask") -> "Mask":  # pylint: disable=g-inconsistent-quotes
-    """Returns the intersection of two masks."""
-    if not isinstance(other, Mask):
-      other = Mask(other)
-
-    def combine(op):
-      return lambda a, b: b if a is None else a if b is None else op(a, b)
-
-    return Mask(
-        bool_mask=combine(jnp.logical_and)(self.bool_mask, other.bool_mask),
-        q_end=combine(jnp.minimum)(self.q_end, other.q_end),
-        k_start=combine(jnp.maximum)(self.k_start, other.k_start),
-        k_end=combine(jnp.minimum)(self.k_end, other.k_end),
-        is_causal=self.is_causal or other.is_causal,
-    )
-
-
-CAUSAL_MASK = Mask(is_causal=True)
-
-
-SoftmaxResidual = (
-    tuple[Float[Array, "*B H T"], Float[Array, "*B H T"]]
-    | Float[Array, "*B H T"]
-)
-
-
-@enum.unique
-class SoftmaxResidualMode(enum.Enum):
-  """The mode of storing softmax residuals for the backwards pass.
-
-  The stable softmax calculation performs two reductions calculating:
-    - the maximum input value (`x_max`),
-    - the sum of exponentiated values (`denom`).
-
-  We can store these values as residuals to avoid the need to recompute them
-  in the backwards pass.
-
-  It is also possible to combine the two residuals into a single residual,
-  `res = x_max + log(denom)`, as `exp(x - res) === exp(x - x_max - log(denom))
-  === exp(x - x_max) / denom`. Combining the residuals reduces the memory usage
-  of the residuals, but will reduce the accuracy of the backwards pass if
-  `abs(x_max) >> log(denom)`.
-  """
-
-  SEPARATE = "separate"
-  COMBINED = "combined"
-
-  def conform(self, aux: SoftmaxResidual) -> SoftmaxResidual | None:
-    match self, aux:
-      case None, _:
-        return None
-      case SoftmaxResidualMode.SEPARATE, (_, _):
-        return aux
-      case SoftmaxResidualMode.SEPARATE, _:  # pytype: disable=redundant-match  # b/300135240
-        raise ValueError("`aux` has been combined.")
-      case SoftmaxResidualMode.COMBINED, (x_max, denom):
-        return x_max + jnp.log(denom)
-      case SoftmaxResidualMode.COMBINED, _:  # pytype: disable=redundant-match  # b/300135240
-        return aux
-
-
-class DotProductAttention(abc.ABC):
-  """Dot product attention function."""
-
-  @jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-  def __call__(
-      self,
-      query: Float[Array | array_view.ArrayView, "*B T H D"],
-      key: Float[Array | array_view.ArrayView, "*B t h D"],
-      value: Float[Array | array_view.ArrayView, "*B t h D"],
-      *,
-      precision: (
-          DotPrecisionLike | tuple[DotPrecisionLike, DotPrecisionLike]
-      ) = jax.lax.Precision.DEFAULT,
-      logits_dtype: DTypeLike | type[AUTO] = AUTO,
-      bias: Float[Array, "*#B #H #T #t"] | None = None,
-      mask: Bool[Array, "*#B #H #T #t"] | Mask | None = None,
-      q_indices: Int[Array, "*#B #H T"] | None = None,
-      k_indices: Int[Array, "*#B #H t"] | None = None,
-  ) -> Float[Array, "*B T H D"]:
-    """Performs scaled dot-product attention.
-
-    Scaled dot-product attention from "Attention is all you need"
-    https://arxiv.org/abs/1706.03762.
-
-    Computes self- or cross-attention. The following is computed:
-    softmax(qk_scale * query @ key^T + bias) @ value.
-
-    Supports both multi-head and multi-query attention
-    (https://arxiv.org/abs/1911.02150).
-
-    Arguments:
-      query: Query array of shape `[batch, seq_len_q, num_heads_q, head_dim]`.
-        It must be a multiple of num_heads_kv.
-        Here's an example of how q/kv heads are interleaved:
-          For 8 key/value heads and 4 query heads:
-          - key/value heads [0, 1] see query head 0
-          - key/value heads [2, 3] see query head 1
-          - key/value heads [4, 5] see query head 2
-      key: Key array of shape `[batch, seq_len_kv, num_heads_kv, head_dim]`. It
-        must be divisible by num_heads_q.
-      value: Value array of shape `[batch, seq_len_kv, num_heads_kv, head_dim]`.
-      precision: The precision for the dot products. Either a tuple `(
-        query_key_dot_precision, weights_value_dot_precision)` or a single
-        precision applied to both dot products.
-      logits_dtype: Data type for attention logits (`query @ key^T`). If `AUTO`
-        is passed (the default), the accumulator type from the `query @ key^T`
-        dot product will be used.
-      bias: Optional bias array, broadcastable to shape `[batch, num_heads,
-        seq_len_q, seq_len_kv]`.
-      mask: Optional boolean mask, broadcastable to `[batch, num_heads,
-        seq_len_q, seq_len_kv]`. Attention weights are masked out if the
-        corresponding mask value is `False`.
-      q_indices: Optional indices for each token in query sequence.
-      k_indices: Optional indices for each token in key/value sequence.
-
-    Returns:
-      An array with the same shape as `query`.
-    """  # fmt: skip
-    return self.fwd(
-        query,
-        key,
-        value,
-        precision=precision,
-        logits_dtype=logits_dtype,
-        bias=bias,
-        mask=mask,
-        q_indices=q_indices,
-        k_indices=k_indices,
-    )
-
-  @jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-  def fwd(
-      self,
-      query: Float[Array | array_view.ArrayView, "*B T H D"],
-      key: Float[Array | array_view.ArrayView, "*B t h D"],
-      value: Float[Array | array_view.ArrayView, "*B t h D"],
-      *,
-      precision: (
-          DotPrecisionLike | tuple[DotPrecisionLike, DotPrecisionLike]
-      ) = jax.lax.Precision.DEFAULT,
-      logits_dtype: DTypeLike | type[AUTO] = AUTO,
-      bias: Float[Array, "*#B #H #T #t"] | None = None,
-      mask: Bool[Array, "*#B #H #T #t"] | Mask | None = None,
-      q_indices: Int[Array, "*#B #H T"] | None = None,
-      k_indices: Int[Array, "*#B #H t"] | None = None,
-  ) -> Float[Array, "*B T H D"]:
-    """Performs attention."""
-    if not isinstance(precision, tuple):
-      precision = (precision, precision)
-
-    q_k_dot_precision, weights_v_dot_precision = precision
-
-    if not isinstance(q_k_dot_precision, precision_lib.DotPrecision):
-      q_k_dot_precision = precision_lib.get_equivalent_dot_precision(
-          query.dtype, key.dtype, q_k_dot_precision
-      )
-
-    if not isinstance(weights_v_dot_precision, precision_lib.DotPrecision):
-      weights_v_dot_precision = precision_lib.get_equivalent_dot_precision(
-          value.dtype, value.dtype, weights_v_dot_precision
-      )
-
-    if logits_dtype is AUTO:
-      logits_dtype = q_k_dot_precision.accumulator_dtype
-
-    if not isinstance(mask, Mask):
-      mask = Mask(mask)
-
-    return self._fwd(
-        array_view.as_array_view(query),
-        array_view.as_array_view(key),
-        array_view.as_array_view(value),
-        q_k_dot_precision=q_k_dot_precision,
-        logits_dtype=jnp.dtype(logits_dtype),
-        logits_scale=1 / math.sqrt(query.shape[-1]),
-        bias=bias,
-        mask=mask,
-        weights_v_dot_precision=weights_v_dot_precision,
-        q_indices=q_indices,
-        k_indices=k_indices,
-    )
-
-  @abc.abstractmethod
-  def _fwd(
-      self,
-      q: Float[array_view.ArrayView, "*B T H D"],
-      k: Float[array_view.ArrayView, "*B t h D"],
-      v: Float[array_view.ArrayView, "*B t h D"],
-      *,
-      q_k_dot_precision: precision_lib.DotPrecision,
-      logits_dtype: jnp.dtype,
-      logits_scale: float,
-      bias: Float[Array, "*#B #H #T #t"] | None,
-      mask: Mask | None,
-      weights_v_dot_precision: precision_lib.DotPrecision,
-      q_indices: Int[Array, "*#B #H T"] | None = None,
-      k_indices: Int[Array, "*#B #H t"] | None = None,
-  ) -> Float[Array, "*B T H D"]:
-    """Performs attention."""
-    ...
diff --git a/src/alphafold3/jax/attention/attention_call_arg_specs.py b/src/alphafold3/jax/attention/attention_call_arg_specs.py
deleted file mode 100644
index 9f0cfc3af66655e681f8e9586c98d4796cec3ca9..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/attention/attention_call_arg_specs.py
+++ /dev/null
@@ -1,62 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Attention call argument specifications.
-
-Attention argument specifications used by users of the library.
-They are the most important test cases, and also cases for optimize
-performance of via autotuning.
-"""
-
-from typing import Any
-
-import jax
-
-ShapedArray = jax.ShapeDtypeStruct
-
-
-def _make_argspec(
-    *,
-    q_shape,
-    dtype,
-    k_shape=None,
-    v_shape=None,
-    bias_shape=None,
-    mask_shape=None,
-    **kwargs,
-) -> dict[str, Any]:
-  """Make argspec from shapes and kwargs."""
-  if k_shape is None:
-    k_shape = q_shape
-  if v_shape is None:
-    v_shape = k_shape
-
-  return dict(
-      query=ShapedArray(q_shape, dtype),
-      key=ShapedArray(k_shape, dtype),
-      value=ShapedArray(v_shape, dtype),
-      bias=ShapedArray(bias_shape, dtype) if bias_shape is not None else None,
-      mask=ShapedArray(mask_shape, 'bool_') if mask_shape is not None else None,
-      **kwargs,
-  )
-
-
-# A subset of the full set of argument specifications. Useful for tap-tests and
-# microbenchmarks.
-CALL_ARG_SPECS = dict(
-    vanilla_f32=_make_argspec(q_shape=(8, 1024, 4, 128), dtype='float32'),
-    vanilla_bf16=_make_argspec(q_shape=(8, 1024, 4, 128), dtype='bfloat16'),
-    alphafold=_make_argspec(
-        q_shape=(384, 384, 4, 32),
-        bias_shape=(1, 4, 384, 384),
-        mask_shape=(384, 1, 1, 384),
-        dtype='bfloat16',
-    ),
-)
diff --git a/src/alphafold3/jax/attention/flash_attention.py b/src/alphafold3/jax/attention/flash_attention.py
deleted file mode 100644
index e5befb11ef4e7e067d68fec4b5c2e967e9182148..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/attention/flash_attention.py
+++ /dev/null
@@ -1,703 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Triton FlashAttention implementation."""
-
-import dataclasses
-import functools
-
-from alphafold3.jax.attention import attention_base as base
-from alphafold3.jax.common import array_view
-from alphafold3.jax.common import precision as precision_lib
-from alphafold3.jax.common import triton_utils
-import jax
-import jax.numpy as jnp
-import jax_triton as jt
-import jaxtyping
-from jaxtyping import Array, Bool, Float, Int  # pylint: disable=g-multiple-import,g-importing-member
-import triton
-import triton.language as tl
-import typeguard
-
-
-@triton.jit
-def _fwd_kernel_inner(
-    start_loop,
-    end_loop,
-    q,
-    span_q,
-    k_block_ptr,
-    v_block_ptr,
-    bias_block_ptr,
-    mask_block_ptr,
-    k_start,
-    k_end,
-    seq_len_k,
-    acc,
-    m_i,
-    l_i,
-    bias_advance: tl.constexpr,
-    mask_advance: tl.constexpr,
-    is_causal: tl.constexpr,
-    use_attention_mask: tl.constexpr,
-    use_k_start: tl.constexpr,
-    use_k_end: tl.constexpr,
-    use_bias: tl.constexpr,
-    block_k: tl.constexpr,
-    use_mask_k: tl.constexpr,
-    k_boundary_check: tl.constexpr,
-    v_boundary_check: tl.constexpr,
-    dot_fn_qk: tl.constexpr,
-    dot_fn_kv: tl.constexpr,
-):
-  """Triton MHA forward kernel's inner loop."""
-
-  for start_k in range(start_loop, end_loop, block_k):
-    start_k = tl.multiple_of(start_k, block_k)
-    span_k = start_k + tl.arange(0, block_k)
-
-    k = tl.load(
-        k_block_ptr,
-        boundary_check=k_boundary_check,
-        padding_option="zero" if len(k_boundary_check.value) else "",
-    )
-    v = tl.load(
-        v_block_ptr,
-        boundary_check=v_boundary_check,
-        padding_option="zero" if len(v_boundary_check.value) else "",
-    )
-
-    if use_bias:
-      bias = tl.load(bias_block_ptr)
-
-    qk = dot_fn_qk(q.to(k.dtype), k)  # [block_q, block_k]
-
-    if use_bias:
-      # Prevent dot accumulating into the bias tensor. It appears that Triton
-      # doesn't pipeline the bias load as it does the `k` load, so the bias load
-      # blocks the matmul if the add is merged.
-      qk = qk.to(tl.uint32, bitcast=True) & 0xFFFFFFFF
-      qk = qk.to(tl.float32, bitcast=True)
-      qk += bias
-
-    if use_attention_mask | use_k_start | use_k_end:
-      mask_value = float(jnp.finfo(jnp.float32).min)
-
-    if use_attention_mask:
-      mask = tl.load(mask_block_ptr)
-      qk = tl.where(mask, qk, mask_value)
-
-    if use_k_start:
-      # This check is there to work around a triton compiler bug, but it
-      # shouldn't be strictly needed.
-      if tl.sum(k_start) != 0:
-        qk = tl.where(k_start[:, None] <= span_k[None, :], qk, mask_value)
-    if is_causal:
-      qk = tl.where(span_q[:, None] >= span_k[None, :], qk, float("-inf"))
-    elif use_k_end:
-      # When called with k_end and is_causal=True, the causal mask gets folded
-      # into k_end and is_causal is set to False.
-      qk = tl.where(k_end[:, None] > span_k[None, :], qk, mask_value)
-
-    if use_mask_k:
-      qk = tl.where((span_k < seq_len_k)[None, :], qk, float("-inf"))
-
-    m_ij = tl.maximum(m_i, tl.max(qk, axis=1))  # Shape [block_q].
-    p = tl.exp(qk - m_ij[:, None])  # Shape [block_q, block_k].
-    alpha = tl.exp(m_i - m_ij)
-    m_i = m_ij
-    acc *= alpha[:, None]
-    l_i *= alpha
-    l_i += tl.sum(p, axis=1)
-
-    # Add the new block of attention weights.
-    acc += dot_fn_kv(p.to(v.dtype), v)
-
-    k_block_ptr = tl.advance(k_block_ptr, (0, block_k))
-    v_block_ptr = tl.advance(v_block_ptr, (block_k, 0))
-    bias_block_ptr = tl.advance(bias_block_ptr, bias_advance.value)
-    mask_block_ptr = tl.advance(mask_block_ptr, mask_advance.value)
-
-  return (
-      k_block_ptr,
-      v_block_ptr,
-      bias_block_ptr,
-      mask_block_ptr,
-      acc,
-      m_i,
-      l_i,
-  )
-
-
-# Based on Algorithm 1 of https://arxiv.org/abs/2205.14135.
-# Inspired by the official Triton tutorial implementation
-# https://triton-lang.org/main/getting-started/tutorials/06-fused-attention.html
-@triton.jit
-def _fwd_kernel(
-    # Input arrays.
-    q_ptr,
-    k_ptr,
-    v_ptr,
-    bias_ptr,
-    mask_ptr,
-    k_start_ptr,
-    k_end_ptr,
-    # Scalar inputs.
-    q_offset,
-    k_offset,
-    v_offset,
-    q_stride_b,
-    q_stride_s,
-    q_stride_h,
-    q_stride_d,
-    k_stride_b,
-    k_stride_s,
-    k_stride_h,
-    k_stride_d,
-    v_stride_b,
-    v_stride_s,
-    v_stride_h,
-    v_stride_d,
-    bias_stride_b,
-    bias_stride_h,
-    bias_stride_sq,
-    bias_stride_sk,
-    mask_stride_b,
-    mask_stride_h,
-    mask_stride_sq,
-    mask_stride_sk,
-    k_start_stride_b,
-    k_start_stride_h,
-    k_start_stride_sq,
-    k_end_stride_b,
-    k_end_stride_h,
-    k_end_stride_sq,
-    o_stride_b,
-    o_stride_s,
-    o_stride_h,
-    o_stride_d,
-    num_heads_q,
-    num_heads_k,
-    seq_len_q,
-    seq_len_k,
-    # Output arrays.
-    o_ptr,
-    # Compile-time constants.
-    is_causal: tl.constexpr,
-    use_attention_mask: tl.constexpr,
-    use_k_start: tl.constexpr,
-    use_k_end: tl.constexpr,
-    use_bias: tl.constexpr,
-    sm_scale: tl.constexpr,
-    block_q: tl.constexpr,
-    block_k: tl.constexpr,
-    head_dim: tl.constexpr,
-    use_mask_q: tl.constexpr,
-    use_mask_k: tl.constexpr,
-    bias_bcast_sq: tl.constexpr,
-    mask_bcast_sq: tl.constexpr,
-    dot_fn_qk: tl.constexpr,
-    dot_fn_kv: tl.constexpr,
-):
-  """Triton MHA forward kernel."""
-  # pytype: disable=annotation-type-mismatch,unsupported-operands
-  block_d: tl.constexpr = jt.utils.next_power_of_2(head_dim.value)
-
-  # Each thread block processes one batch element (b) and one head (h).
-  start_q = tl.program_id(1) * block_q
-  off_h = tl.program_id(0)  # int in [0, num_heads_o).
-  off_b = tl.program_id(2)  # int in [0, batch_size)
-
-  off_h_k = off_h // (num_heads_q // num_heads_k)
-
-  q_ptr += off_h * q_stride_h + off_b * q_stride_b + q_offset
-  k_ptr += off_h_k * k_stride_h + off_b * k_stride_b + k_offset
-  v_ptr += off_h_k * v_stride_h + off_b * v_stride_b + v_offset
-  o_ptr += off_h * o_stride_h + off_b * o_stride_b
-
-  if use_bias:
-    bias_ptr += off_b * bias_stride_b + off_h * bias_stride_h
-  if use_attention_mask:
-    mask_ptr += off_b * mask_stride_b + off_h * mask_stride_h
-  if use_k_start:
-    k_start_ptr += off_b * k_start_stride_b + off_h * k_start_stride_h
-  if use_k_end:
-    k_end_ptr += off_b * k_end_stride_b + off_h * k_end_stride_h
-
-  q_block_ptr = tl.make_block_ptr(
-      q_ptr,
-      shape=(seq_len_q, head_dim),
-      strides=(q_stride_s, q_stride_d),
-      offsets=(start_q, 0),
-      block_shape=(block_q, block_d),
-      order=(1, 0),
-  )
-  k_block_ptr = tl.make_block_ptr(
-      k_ptr,
-      shape=(head_dim, seq_len_k),
-      strides=(k_stride_d, k_stride_s),
-      offsets=(0, 0),
-      block_shape=(block_d, block_k),
-      order=(0, 1),
-  )
-  v_block_ptr = tl.make_block_ptr(
-      v_ptr,
-      shape=(seq_len_k, head_dim),
-      strides=(v_stride_s, v_stride_d),
-      offsets=(0, 0),
-      block_shape=(block_k, block_d),
-      order=(1, 0),
-  )
-
-  q_boundary_check0: tl.constexpr = (0,) if use_mask_q else ()
-  q_boundary_check1: tl.constexpr = (1,) if head_dim != block_d else ()
-  q_boundary_check: tl.constexpr = q_boundary_check0 + q_boundary_check1
-  q_padding_option: tl.constexpr = "zero" if len(q_boundary_check.value) else ""
-  k_boundary_check: tl.constexpr = (0,) if head_dim != block_d else ()
-  v_boundary_check: tl.constexpr = (0,) if use_mask_k else ()
-
-  # If broadcasting in a given dim, use a 1D block (observed to be faster).
-  bias_start_dim: tl.constexpr = 1 if bias_bcast_sq else 0
-  bias_block_ptr = tl.make_block_ptr(
-      bias_ptr,
-      shape=(seq_len_q, seq_len_k)[bias_start_dim:],
-      strides=(bias_stride_sq, bias_stride_sk)[bias_start_dim:],
-      offsets=(start_q, 0)[bias_start_dim:],
-      block_shape=(block_q, block_k)[bias_start_dim:],
-      order=(1, 0)[bias_start_dim:],
-  )
-  bias_advance: tl.constexpr = (0, block_k)[bias_start_dim:]
-
-  mask_start_dim: tl.constexpr = 1 if mask_bcast_sq else 0
-  mask_block_ptr = tl.make_block_ptr(
-      mask_ptr,
-      shape=(seq_len_q, seq_len_k)[mask_start_dim:],
-      strides=(mask_stride_sq, mask_stride_sk)[mask_start_dim:],
-      offsets=(start_q, 0)[mask_start_dim:],
-      block_shape=(block_q, block_k)[mask_start_dim:],
-      order=(1, 0)[mask_start_dim:],
-  )
-  mask_advance: tl.constexpr = (0, block_k)[mask_start_dim:]
-
-  k_start_block_ptr = tl.make_block_ptr(
-      k_start_ptr,
-      shape=(seq_len_q,),
-      strides=(k_start_stride_sq,),
-      offsets=(start_q,),
-      block_shape=(block_q,),
-      order=(0,),
-  )
-  k_end_block_ptr = tl.make_block_ptr(
-      k_end_ptr,
-      shape=(seq_len_q,),
-      strides=(k_end_stride_sq,),
-      offsets=(start_q,),
-      block_shape=(block_q,),
-      order=(0,),
-  )
-  # pytype: enable=annotation-type-mismatch,unsupported-operands
-
-  # Each thread block processes a block of block_q queries.
-  span_q = start_q + tl.arange(0, block_q)
-
-  # m_i and l_i (see FlashAttention paper) are updated during the k,v loop.
-  m_i = tl.full([block_q], float("-inf"), dtype=tl.float32)
-  l_i = tl.zeros([block_q], dtype=tl.float32)
-  # acc is the buffer where we accumulate the output on sram.
-  acc = tl.zeros([block_q, block_d], dtype=tl.float32)
-
-  # Load q: it will stay in smem throughout. Indices form a matrix because we
-  # read, compute, and write all in 2d chunks. 1 element ~= 1 CUDA thread index.
-  q = tl.load(
-      q_block_ptr,
-      boundary_check=q_boundary_check,
-      padding_option=q_padding_option,
-  )
-  q *= sm_scale
-
-  # In FlashAttention algorithm 1 there are 2 loops: slow over tiles of kv (size
-  # (Bc == block_k here), and fast over blocks of q (size Br == block_q here).
-  # Here we only loop over blocks of kv to process entire seq_len, the loop over
-  # blocks of q is carried out by the grid.
-  k_start = None
-  if use_k_start:
-    k_start = tl.load(k_start_block_ptr)
-    start_loop = tl.maximum(tl.min(k_start), 0)
-    blocks_to_skip = start_loop // block_k
-    start_loop = block_k * blocks_to_skip  # Floor to multiple of block_k.
-    for _ in range(blocks_to_skip):
-      # Advance all block pointers to the first valid block.
-      k_block_ptr = tl.advance(k_block_ptr, (0, block_k))
-      v_block_ptr = tl.advance(v_block_ptr, (block_k, 0))
-      bias_block_ptr = tl.advance(bias_block_ptr, bias_advance.value)
-      mask_block_ptr = tl.advance(mask_block_ptr, mask_advance.value)
-  else:
-    start_loop = 0
-
-  k_end = None
-  if is_causal:
-    end_loop = tl.minimum((start_q // block_k) * block_k, seq_len_k)
-  elif use_k_end:
-    k_end = tl.load(k_end_block_ptr)
-    end_loop = tl.minimum(tl.max(k_end), seq_len_k)
-  else:
-    end_loop = seq_len_k
-
-  (
-      k_block_ptr,
-      v_block_ptr,
-      bias_block_ptr,
-      mask_block_ptr,
-      acc,
-      m_i,
-      l_i,
-  ) = _fwd_kernel_inner(
-      start_loop,
-      end_loop,
-      q,
-      span_q,
-      k_block_ptr,
-      v_block_ptr,
-      bias_block_ptr,
-      mask_block_ptr,
-      k_start,
-      k_end,
-      seq_len_k,
-      acc,
-      m_i,
-      l_i,
-      bias_advance,
-      mask_advance,
-      False,  # is_causal
-      use_attention_mask,
-      use_k_start,
-      use_k_end,
-      use_bias,
-      block_k,
-      use_mask_k,
-      k_boundary_check,
-      v_boundary_check,
-      dot_fn_qk,
-      dot_fn_kv,
-  )
-
-  if is_causal:
-    tl.debug_barrier()  # Help compiler schedule loops independently.
-    start_loop, end_loop = end_loop, tl.minimum(end_loop + block_k, seq_len_k)
-
-    _, _, _, _, acc, _, l_i = _fwd_kernel_inner(
-        start_loop,
-        end_loop,
-        q,
-        span_q,
-        k_block_ptr,
-        v_block_ptr,
-        bias_block_ptr,
-        mask_block_ptr,
-        k_start,
-        k_end,
-        seq_len_k,
-        acc,
-        m_i,
-        l_i,
-        bias_advance,
-        mask_advance,
-        True,  # is_causal
-        use_attention_mask,
-        use_k_start,
-        use_k_end,
-        use_bias,
-        block_k,
-        use_mask_k,
-        k_boundary_check,
-        v_boundary_check,
-        dot_fn_qk,
-        dot_fn_kv,
-    )
-
-  # It is possible that every value in a row was masked to f32 min or that the
-  # main loop has been completely optimised out, and that `l_i` is `0` for that
-  # row. Add epsilon value to avoid NaNs from `0 / 0`.
-  l_i += float(jnp.finfo(jnp.float32).tiny)
-
-  acc /= l_i[:, None]
-
-  # Write output to dram.
-  o_block_ptr = tl.make_block_ptr(
-      o_ptr,
-      shape=(seq_len_q, head_dim),
-      strides=(o_stride_s, o_stride_d),
-      offsets=(start_q, 0),
-      block_shape=(block_q, block_d),
-      order=(1, 0),
-  )
-  acc = acc.to(o_ptr.dtype.element_ty)
-  tl.store(o_block_ptr, acc, boundary_check=q_boundary_check)
-
-
-@jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-def _fwd(
-    q: Float[array_view.ArrayView, "*B T H D"],
-    k: Float[array_view.ArrayView, "*B t h D"],
-    v: Float[array_view.ArrayView, "*B t h D"],
-    bias: Float[Array, "*#B #H #T #t"] | None,
-    mask: Bool[Array, "*#B #H #T #t"] | None,
-    k_start: Int[Array, "*#B #H #T"] | None,
-    k_end: Int[Array, "*#B #H #T"] | None,
-    *,
-    logits_scale: float,
-    is_causal: bool,
-    q_k_dot_precision: precision_lib.DotPrecision,
-    weights_v_dot_precision: precision_lib.DotPrecision,
-) -> Float[Array, "*B T H D"]:
-  """Forward pass of Triton FlashAttention."""
-
-  orig_q_shape = q.shape
-  q = q.collapse(0, -3, allow_copy=True)
-  batch_size, seq_len_q, num_heads_q, head_dim = q.shape
-  *_, seq_len_k, num_heads_kv, _ = k.shape
-  # Maybe broadcast `k`/`v` heads dimension.
-  kv_shape = (batch_size, seq_len_k, num_heads_kv, head_dim)
-  k = k.collapse(0, -3, allow_copy=True).broadcast_to(kv_shape)
-  v = v.collapse(0, -3, allow_copy=True).broadcast_to(kv_shape)
-
-  def get_bias_mask_view(x, dtype):
-    if x is None:
-      x = jnp.array([], dtype=dtype)
-      return array_view.ArrayView(x, shape=(0, 0, 0, 0), strides=(0, 0, 0, 0))
-
-    shape = orig_q_shape[:-3] + (num_heads_q, seq_len_q, seq_len_k)
-    return (
-        array_view.ArrayView(x)
-        .broadcast_to(shape)
-        .collapse(0, -3, allow_copy=True)
-    )
-
-  bias = get_bias_mask_view(bias, dtype=q.dtype)
-  mask = get_bias_mask_view(mask, dtype=jnp.bool_)
-
-  def get_range_view(x, seq_len):
-    if x is None:
-      x = jnp.array([], dtype=jnp.int32)
-      return array_view.ArrayView(x, shape=(0, 0, 0), strides=(0, 0, 0))
-
-    shape = orig_q_shape[:-3] + (num_heads_q, seq_len)
-    return (
-        array_view.ArrayView(x)
-        .broadcast_to(shape)
-        .collapse(0, -2, allow_copy=True)
-    )
-
-  k_start = get_range_view(k_start, seq_len_q)
-  k_end = get_range_view(k_end, seq_len_q)
-
-  block_q = 64
-  block_k = 64
-
-  return jt.triton_call(
-      q.base,
-      k.base,
-      v.base,
-      bias.base,
-      mask.base,
-      k_start.base,
-      k_end.base,
-      q.offset,
-      k.offset,
-      v.offset,
-      *q.strides,
-      *k.strides,
-      *v.strides,
-      *bias.strides,
-      *mask.strides,
-      k_start.strides,
-      k_end.strides,
-      *jt.utils.strides_from_shape(q.shape),  # out strides.
-      num_heads_q,
-      num_heads_kv,
-      seq_len_q,
-      seq_len_k,
-      kernel=_fwd_kernel,
-      name="triton_flash_attention",
-      out_shape=jax.ShapeDtypeStruct(q.shape, q.dtype),
-      grid=(num_heads_q, triton.cdiv(seq_len_q, block_q), batch_size),
-      num_stages=2,
-      num_warps=4,
-      is_causal=is_causal,
-      use_attention_mask=(mask.size != 0),
-      use_k_start=(k_start.size != 0),
-      use_k_end=(k_end.size != 0),
-      use_bias=(bias.size != 0),
-      sm_scale=logits_scale,
-      block_q=block_q,
-      block_k=block_k,
-      head_dim=head_dim,
-      use_mask_q=(seq_len_q % block_q != 0),
-      use_mask_k=(seq_len_k % block_q != 0),
-      bias_bcast_sq=(bias.strides[-2] == 0),
-      mask_bcast_sq=(mask.strides[-2] == 0),
-      dot_fn_qk=triton_utils.get_tl_dot_fn(q_k_dot_precision),
-      dot_fn_kv=triton_utils.get_tl_dot_fn(weights_v_dot_precision),
-  ).reshape(orig_q_shape)
-
-
-def _as_batched_array_view(x, axis_size):
-  batched_shape = (axis_size,) + x.shape
-  batched_strides = (x.base.size // axis_size,) + x.strides
-  return dataclasses.replace(x, shape=batched_shape, strides=batched_strides)
-
-
-def _fwd_vmap_rule(
-    axis_size, in_batched, *args, fn: jax.custom_batching.custom_vmap
-):
-  """`vmap` rule for Triton FlashAttention forward op."""
-  q, k, v, bias, mask, k_start, k_end = args
-  (
-      q_batched,
-      k_batched,
-      v_batched,
-      bias_batched,
-      mask_batched,
-      k_start_batched,
-      k_end_batched,
-  ) = in_batched
-
-  if q_batched.base:
-    q = _as_batched_array_view(q, axis_size)
-  if k_batched.base:
-    k = _as_batched_array_view(k, axis_size)
-  if v_batched.base:
-    v = _as_batched_array_view(v, axis_size)
-
-  # Triton op requires `q`, `k`, `v` batch dims to be identical.
-  if q_batched.base and k_batched.base and v_batched.base:
-    if bias is not None and not bias_batched:
-      bias = jax.lax.broadcast_to_rank(bias, bias.ndim + 1)
-    if mask is not None and not mask_batched:
-      mask = jax.lax.broadcast_to_rank(mask, mask.ndim + 1)
-    if k_start is not None and not k_start_batched:
-      k_start = jax.lax.broadcast_to_rank(k_start, k_start.ndim + 1)
-    if k_end is not None and not k_end_batched:
-      k_end = jax.lax.broadcast_to_rank(k_end, k_end.ndim + 1)
-    out = fn(q, k, v, bias, mask, k_start, k_end)
-    out_batched = True
-    return out, out_batched
-
-  # Fallback to sequential loop.
-  q, k, v = map(jnp.asarray, (q, k, v))
-  in_batched = [
-      q_batched.base,
-      k_batched.base,
-      v_batched.base,
-      bias_batched,
-      mask_batched,
-      k_start_batched,
-      k_end_batched,
-  ]
-
-  def f(q, k, v, *args, **kwargs):
-    q, k, v = map(array_view.ArrayView, (q, k, v))
-    return fn.fun(q, k, v, *args, **kwargs)
-
-  sequential_vmap = jax.custom_batching.sequential_vmap(f)
-  return sequential_vmap.vmap_rule(axis_size, in_batched, q, k, v, *args[3:])
-
-
-def _decompose_mask(mask, q, k, q_indices, k_indices):
-  """Decomposes `mask` into a mask array, `is_causal`, `k_start` and `k_end`."""
-  if mask is None:
-    return None, False, None, None
-
-  is_causal = False
-  k_start = None
-  k_end = None
-  if q_indices is None and k_indices is None:
-    mask, is_causal, k_start, k_end = mask.take("is_causal", "k_start", "k_end")
-    if k_start is not None:
-      k_start = jax.lax.broadcast_to_rank(k_start, 2)
-    if k_end is not None:
-      k_end = jax.lax.broadcast_to_rank(k_end, 2)
-      if is_causal:  # Fold is_causal into k_end
-        k_end = jnp.minimum(k_end, jnp.arange(1, q.shape[-3] + 1))
-        is_causal = False
-
-  q_len_or_indices = q.shape[-3] if q_indices is None else q_indices
-  k_len_or_indices = k.shape[-3] if k_indices is None else k_indices
-  return (
-      mask.as_array(q_len_or_indices, k_len_or_indices),
-      is_causal,
-      k_start,
-      k_end,
-  )
-
-
-@dataclasses.dataclass(frozen=True)
-class TritonFlashAttention(base.DotProductAttention):
-  """Triton FlashAttention implementation."""
-
-  @jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-  def _fwd(
-      self,
-      q: Float[array_view.ArrayView, "*B T H D"],
-      k: Float[array_view.ArrayView, "*B t h D"],
-      v: Float[array_view.ArrayView, "*B t h D"],
-      bias: Float[Array, "*#B #H #T #t"] | None,
-      *,
-      q_k_dot_precision: precision_lib.DotPrecision,
-      logits_dtype: jnp.dtype,
-      logits_scale: float,
-      mask: base.Mask | None,
-      weights_v_dot_precision: precision_lib.DotPrecision,
-      q_indices: Int[Array, "*#B #H T"] | None = None,
-      k_indices: Int[Array, "*#B #H t"] | None = None,
-  ) -> Float[Array, "*B T H D"]:
-    if logits_dtype != jnp.float32:
-      raise ValueError("`logits_dtype` must be float32.")
-
-    kwargs = dict(
-        logits_scale=logits_scale,
-        q_k_dot_precision=q_k_dot_precision,
-        weights_v_dot_precision=weights_v_dot_precision,
-    )
-
-    def attend_fwd(
-        q,
-        k,
-        v,
-        bias,
-        mask_,
-        q_indices,
-        k_indices,
-    ):
-
-      mask, is_causal, k_start, k_end = _decompose_mask(
-          mask_, q, k, q_indices, k_indices
-      )
-
-      fwd_closed_kwargs = dict(
-          is_causal=is_causal,
-          **kwargs,
-      )
-
-      fwd_closed = functools.partial(_fwd, **fwd_closed_kwargs)
-      fwd_closed = jax.custom_batching.custom_vmap(fwd_closed)
-      fwd_closed.def_vmap(functools.partial(_fwd_vmap_rule, fn=fwd_closed))
-
-      return fwd_closed(q, k, v, bias, mask, k_start, k_end)
-
-    return attend_fwd(
-        q,
-        k,
-        v,
-        bias,
-        mask,
-        q_indices,
-        k_indices,
-    )
diff --git a/src/alphafold3/jax/attention/xla_attention.py b/src/alphafold3/jax/attention/xla_attention.py
deleted file mode 100644
index e095f4540a299893510a29a30ba9fa7079da17ad..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/attention/xla_attention.py
+++ /dev/null
@@ -1,140 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""XLA implementation of scaled dot-product attention."""
-
-import dataclasses
-
-from alphafold3.jax.attention import attention_base as base
-from alphafold3.jax.common import array_view
-from alphafold3.jax.common import precision as precision_lib
-import jax
-import jax.numpy as jnp
-import jaxtyping
-from jaxtyping import Array, Float, Int  # pylint: disable=g-multiple-import,g-importing-member
-import typeguard
-
-
-def _get_precision(
-    backend: str, precision: precision_lib.DotPrecision
-) -> jax.lax.Precision:
-  if backend == "gpu" and precision == precision_lib.DotPrecision.F32_F32:
-    return jax.lax.Precision.HIGHEST
-  return jax.lax.Precision.DEFAULT
-
-
-def einsum_with_dot_precision(
-    subscript: str,
-    a: jax.Array,
-    b: jax.Array,
-    *,
-    precision: precision_lib.DotPrecision,
-) -> jax.Array:
-  """Evaluate `fn` with the given precision."""
-  result = jnp.einsum(
-      subscript,
-      a.astype(precision.operand_dtype),
-      b.astype(precision.operand_dtype),
-      precision=_get_precision(jax.default_backend().lower(), precision),
-      preferred_element_type=precision.accumulator_dtype,
-  )
-  assert result.dtype == precision.accumulator_dtype
-  return result
-
-
-def _softmax(x: jax.Array) -> jax.Array:
-  """Computes softmax."""
-  # Always perform reductions in at least f32 precision.
-  dtype = jnp.promote_types(x.dtype, jnp.float32)
-  x_max = jnp.max(x.astype(dtype), axis=-1, keepdims=True)
-  unnormalized = jnp.exp(x - x_max)
-  denom = jnp.sum(unnormalized, axis=-1, keepdims=True)
-  return unnormalized / denom
-
-
-@jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-def _attend(
-    q: Float[array_view.ArrayView, "*B T H D"],
-    k: Float[array_view.ArrayView, "*B t #H D"],
-    v: Float[array_view.ArrayView, "*B t #H D"],
-    *,
-    q_k_dot_precision: precision_lib.DotPrecision,
-    logits_dtype: jnp.dtype,
-    logits_scale: float,
-    bias: Float[Array, "*#B #H #T #t"] | None,
-    mask: base.Mask | None,
-    weights_v_dot_precision: precision_lib.DotPrecision,
-    q_indices: Int[Array, "*#B #H T"] | None,
-    k_indices: Int[Array, "*#B #H t"] | None,
-) -> Float[Array, "*B T H D"]:
-  """Computes attention."""
-  logits = einsum_with_dot_precision(
-      "...qhd,...khd->...hqk", q, k, precision=q_k_dot_precision
-  ).astype(logits_dtype)
-
-  logits *= logits_scale
-
-  if bias is not None:
-    logits += bias
-
-  if mask is not None:
-    q_len_or_indices = q.shape[-3] if q_indices is None else q_indices
-    k_len_or_indices = k.shape[-3] if k_indices is None else k_indices
-    mask = mask.as_array(q_len_or_indices, k_len_or_indices)
-
-  if mask is not None:
-    mask_value = float(jnp.finfo(logits.dtype).min)
-
-    logits = jnp.where(jnp.asarray(mask), logits, mask_value)
-
-  weights = _softmax(logits)
-
-  weights = weights.astype(v.dtype)
-  out = einsum_with_dot_precision(
-      "...hqk,...khd->...qhd", weights, v, precision=weights_v_dot_precision
-  ).astype(q.dtype)
-  return out
-
-
-@dataclasses.dataclass(frozen=True)
-class XlaDotProductAttention(base.DotProductAttention):
-  """XLA dot product attention function."""
-
-  _: dataclasses.KW_ONLY
-
-  def _fwd(
-      self,
-      q: Float[array_view.ArrayView, "*B T H D"],
-      k: Float[array_view.ArrayView, "*B t #H D"],
-      v: Float[array_view.ArrayView, "*B t #H D"],
-      *,
-      q_k_dot_precision: precision_lib.DotPrecision,
-      logits_dtype: jnp.dtype,
-      logits_scale: float,
-      bias: Float[Array, "*#B #H #T #t"] | None,
-      mask: base.Mask | None,
-      weights_v_dot_precision: precision_lib.DotPrecision,
-      q_indices: Int[Array, "*#B #H T"] | None = None,
-      k_indices: Int[Array, "*#B #H t"] | None = None,
-  ) -> Float[Array, "*B T H D"]:
-
-    return _attend(
-        q,
-        k,
-        v,
-        bias=bias,
-        mask=mask,
-        q_indices=q_indices,
-        k_indices=k_indices,
-        q_k_dot_precision=q_k_dot_precision,
-        logits_dtype=logits_dtype,
-        logits_scale=logits_scale,
-        weights_v_dot_precision=weights_v_dot_precision,
-    )
diff --git a/src/alphafold3/jax/common/array_view.py b/src/alphafold3/jax/common/array_view.py
deleted file mode 100644
index c37c299cc080635bbba2fd3603c8130cce6107dc..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/common/array_view.py
+++ /dev/null
@@ -1,405 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Array view class and utilities."""
-
-from collections.abc import Sequence
-import dataclasses
-import math
-import operator
-from types import EllipsisType  # pylint: disable=g-importing-member
-from typing import Any, Self, TypeAlias, TypeVar
-
-import jax
-import jax.experimental
-from jax.experimental import pallas as pl
-import jax.numpy as jnp
-from jax.typing import ArrayLike  # pylint: disable=g-importing-member
-from jaxtyping import Int  # pylint: disable=g-importing-member
-import numpy as np
-
-ArrayT: TypeAlias = Any
-ScalarInt: TypeAlias = (
-    Int[ArrayT, ""] | Int[np.generic, ""] | Int[jnp.generic, ""]
-)
-
-Indexer: TypeAlias = int | ScalarInt | slice | pl.Slice | EllipsisType
-
-
-@jax.tree_util.register_pytree_node_class
-@dataclasses.dataclass(frozen=True)
-class ArrayView:
-  """A strided view of a JAX array."""
-
-  base: jax.Array
-  _: dataclasses.KW_ONLY
-  # These are set by `__post_init__` so `None` value is never seen after init.
-  shape: tuple[int, ...] = None  # type: ignore
-  strides: tuple[int, ...] = None  # type: ignore
-  offset: int | ScalarInt = 0
-  flatten_base: bool = True
-
-  def __post_init__(self):
-    if self.shape is None:
-      object.__setattr__(self, "shape", self.base.shape)
-
-    if self.strides is None:
-      object.__setattr__(self, "strides", pl.strides_from_shape(self.shape))
-
-    if len(self.shape) != len(self.strides):
-      raise ValueError("`shape` and `strides` must have the same length.")
-
-    # Within `jax.vjp`, we can get non-`Array` values here (such as `object`).
-    if isinstance(self.base, jax.Array):
-      if isinstance(self.offset, int):
-        if not (0 <= self.offset < max(self.base.size, 1)):
-          raise ValueError("Invalid `offset`.")
-
-      if self.flatten_base:
-        if len(self.base.shape) != 1:
-          object.__setattr__(self, "base", self.base.reshape((-1,)))
-
-  def tree_flatten(self):
-    if isinstance(self.offset, int):
-      return (self.base,), (self.offset, self.shape, self.strides)
-    return (self.base, self.offset), (self.shape, self.strides)
-
-  @classmethod
-  def tree_unflatten(cls, aux, children) -> Self:
-    base, offset, shape, strides = (*children, *aux)
-    return cls(base, shape=shape, strides=strides, offset=offset)
-
-  @property
-  def dtype(self) -> jnp.dtype:
-    return self.base.dtype
-
-  @property
-  def size(self) -> int:
-    return math.prod(self.shape)
-
-  @property
-  def ndim(self) -> int:
-    return len(self.shape)
-
-  @property
-  def T(self) -> Self:  # pylint: disable=invalid-name
-    return self.transpose()
-
-  @property
-  def _index_dtype(self) -> jax.typing.DTypeLike:
-    i32_max = jnp.iinfo(jnp.int32).max
-    return jnp.int32 if (self.base.size <= i32_max) else jnp.int64
-
-  @property
-  def offsets(self) -> jax.Array:
-    """Returns array of offsets into `base` for each element."""
-    with jax.experimental.enable_x64():
-      idxs = jnp.indices(self.shape, sparse=True, dtype=self._index_dtype)
-      return self.offset + sum(s * idx for s, idx in zip(self.strides, idxs))
-
-  def astype(self, dtype: jax.typing.DTypeLike) -> Self:
-    return self._replace(base=self.base.astype(dtype))
-
-  def broadcast_to_rank(self, rank: int) -> Self:
-    """Returns a new view with the specified rank."""
-    if rank < self.ndim:
-      raise ValueError(f"Cannot broadcast to lower rank: {rank} < {self.ndim}.")
-
-    shape = (1,) * (rank - self.ndim) + self.shape
-    strides = (0,) * (rank - self.ndim) + self.strides
-    return self._replace(shape=shape, strides=strides)
-
-  def broadcast_to(self, shape: tuple[int, ...]) -> Self:
-    """Returns a new view with the specified shape."""
-    view = self.broadcast_to_rank(len(shape))
-    strides = []
-    for dim_size, stride, target_size in zip(
-        view.shape, view.strides, shape, strict=True
-    ):
-      if dim_size == target_size:
-        strides.append(stride)
-      elif dim_size == 1:
-        strides.append(0)
-      else:
-        raise ValueError(f"Cannot broadcast {self.shape} to {shape}.")
-    return self._replace(shape=shape, strides=strides)
-
-  def collapse(
-      self, start: int, stop: int | None = None, *, allow_copy: bool = False
-  ) -> Self:
-    """Returns a new view with the axis range collapsed into one axis."""
-    lo, hi, _ = slice(start, stop).indices(self.ndim)
-    if hi < lo:
-      raise ValueError(
-          "Invalid dimension range passed to collapse: "
-          f"{self.shape} [{start}:{stop}]"
-      )
-    shape = self.shape[:lo] + (-1,) + self.shape[hi:]
-    return self.reshape(shape, allow_copy=allow_copy)
-
-  def reshape(self, shape: Sequence[int], *, allow_copy: bool = False) -> Self:
-    """Returns a new view with the specified shape."""
-    try:
-      return self._reshape(tuple(shape))
-    except ValueError:
-      if not allow_copy:
-        raise
-    return type(self)(jnp.array(self)).reshape(shape)
-
-  def _reshape(self, shape: tuple[int, ...]) -> Self:
-    """Returns a new view with the specified shape."""
-
-    if (num_minus_one_dims := shape.count(-1)) > 0:
-      if num_minus_one_dims > 1:
-        raise ValueError("`shape` may only contain a single `-1` dimension.")
-      pos = shape.index(-1)
-      shape = list(shape)
-      shape[pos] = self.size // math.prod(d for d in shape if d != -1)
-
-    if math.prod(shape) != self.size:
-      raise ValueError("Mismatched number of elements.")
-
-    # Logic copied from `numpy` C++ code.
-    # Remove axes with length 1, to simplify logic below.
-    old_shape = [d for d in self.shape if d != 1]
-    old_strides = [s for i, s in enumerate(self.strides) if self.shape[i] != 1]
-    strides = [0] * len(shape)
-
-    # Axes currently being worked upon.
-    old_start, old_stop = 0, 1
-    new_start, new_stop = 0, 1
-
-    while (old_start < len(old_shape)) and (new_start < len(shape)):
-      old_axes_prod = old_shape[old_start]
-      new_axes_prod = shape[new_start]
-      while old_axes_prod != new_axes_prod:
-        if old_axes_prod < new_axes_prod:
-          old_axes_prod *= old_shape[old_stop]
-          old_stop += 1
-        else:
-          new_axes_prod *= shape[new_stop]
-          new_stop += 1
-
-      # Check if original axes can be combined.
-      for i in range(old_start, old_stop - 1):
-        if old_strides[i] != old_shape[i + 1] * old_strides[i + 1]:
-          raise ValueError("Cannot combine axes non-contiguous in memory.")
-
-      # Calculate new strides.
-      strides[new_stop - 1] = old_strides[old_stop - 1]
-      for i in range(new_stop - 1, new_start, -1):
-        strides[i - 1] = strides[i] * shape[i]
-
-      old_start, old_stop = old_stop, old_stop + 1
-      new_start, new_stop = new_stop, new_stop + 1
-
-    return self._replace(shape=shape, strides=strides)
-
-  def split(
-      self, indices_or_sections: int | Sequence[int], axis: int = 0
-  ) -> tuple[Self, ...]:
-    """Splits the view into multiple slice views."""
-    if isinstance(indices_or_sections, int):
-      if self.shape[axis] % indices_or_sections != 0:
-        raise ValueError("Axis size is not divisible by number of sections.")
-
-      chunk = self.shape[axis] // indices_or_sections
-      indices_or_sections = [i * chunk for i in range(1, indices_or_sections)]
-
-    los = (0, *indices_or_sections)
-    his = (*indices_or_sections, None)
-    slice_prefix = (slice(None),) * _canonicalize_axis(axis, self.ndim)
-    return tuple(self[*slice_prefix, slice(lo, hi)] for lo, hi in zip(los, his))
-
-  def swapaxes(self, axis1: int, axis2: int) -> Self:
-    """Returns a new view with the specified axis swapped."""
-    axes = list(range(self.ndim))
-    axes[axis1], axes[axis2] = axes[axis2], axes[axis1]
-    return self.transpose(axes)
-
-  def moveaxis(self, source: int, destination: int) -> Self:
-    """Returns a new view with the specified axis moved."""
-    source, destination = source % self.ndim, destination % self.ndim
-    axes = list(range(self.ndim))
-    del axes[source]
-    axes.insert(destination, source)
-    return self.transpose(axes)
-
-  def transpose(self, axes: Sequence[int] | None = None) -> Self:
-    """Returns a new view with the specified axes order."""
-    if axes is None:
-      axes = tuple(reversed(range(self.ndim)))
-    if len(axes) != self.ndim:
-      raise ValueError("`axes` must have the same dimensionality as the array.")
-    shape = tuple(self.shape[a] for a in axes)
-    strides = tuple(self.strides[a] for a in axes)
-    return self._replace(shape=shape, strides=strides)
-
-  def __getitem__(self, idxs: Indexer | tuple[Indexer, ...]) -> Self:
-    if not isinstance(idxs, tuple):
-      idxs = (idxs,)
-
-    if len(idxs) > self.ndim:
-      raise ValueError("Too many slice indices.")
-
-    num_ellipses = idxs.count(Ellipsis)
-    if num_ellipses > 1:
-      raise ValueError("Multiple `...` are not supported.")
-    elif num_ellipses == 0:
-      idxs += (Ellipsis,)  # `[a:b]` is equivalent to `[a:b, ...]`.
-
-    # Replace `...` with slices that take the entirety of the missing axes.
-    ellipsis_idx = idxs.index(Ellipsis)
-    ellipsis_slices = (slice(None),) * (self.ndim - len(idxs) + 1)
-    idxs = idxs[:ellipsis_idx] + ellipsis_slices + idxs[ellipsis_idx + 1 :]
-
-    shape = []
-    strides = []
-    with jax.experimental.enable_x64():
-
-      def as_index(x):
-        return x.astype(self._index_dtype) if isinstance(x, jax.Array) else x
-
-      offset = as_index(self.offset)
-
-      for idx, dim, stride in zip(idxs, self.shape, self.strides, strict=True):
-        if isinstance(idx, int):
-          if not (-dim <= idx < dim):
-            raise ValueError("Slice index out of range.")
-          offset += stride * (idx % dim)
-        elif isinstance(idx, ScalarInt):
-          offset += stride * as_index(idx)
-        elif isinstance(idx, slice):
-          start, stop, step = idx.indices(dim)
-          if step >= 0:
-            shape.append(pl.cdiv(stop - start, step))
-          else:
-            shape.append(pl.cdiv(start - stop, -step))
-          strides.append(stride * step)
-          offset += stride * start
-        elif isinstance(idx, pl.Slice):
-          shape.append(idx.size)
-          strides.append(stride * idx.stride)
-          offset += stride * as_index(idx.start)
-        else:
-          raise ValueError(f"Unexpected indexer: {idx}")
-
-    return self._replace(shape=shape, strides=strides, offset=offset)
-
-  def _replace(self, **kwargs) -> Self:
-    if "shape" in kwargs:
-      kwargs["shape"] = tuple(kwargs["shape"])
-    if "strides" in kwargs:
-      kwargs["strides"] = tuple(kwargs["strides"])
-    return dataclasses.replace(self, **kwargs)
-
-  def set(self, value: ArrayLike | "ArrayView") -> Self:
-    """Returns a new view with the views values set to `value`."""
-    if any(s == 0 for s in self.strides):
-      raise ValueError("Cannot set values on a broadcasted array.")
-
-    # Try to just transpose the value, if possible.
-    major_to_minor = np.argsort(-np.array(self.strides), kind="stable")
-    value = jnp.array(value)
-    value_transposed = value.transpose(major_to_minor)
-    if (
-        self.transpose(major_to_minor).strides
-        == ArrayView(value_transposed).strides
-    ):
-      base = jax.lax.dynamic_update_slice(
-          self.base, value_transposed.flatten(), (self.offset,)
-      )
-    else:
-      base = self.base.at[self.offsets].set(value)
-    return self._replace(base=base)
-
-  def __jax_array__(self) -> jax.Array:
-    """Returns values as a dense array."""
-    # Try to express using transpose, slice, and reshape, to encourage XLA to
-    # fuse into other ops, rather than materialising the values. Otherwise,
-    # fall back to using a gather.
-    if (self.ndim == 0) or any(s < 0 for s in self.strides):
-      return self.base[self.offsets]
-
-    major_to_minor = np.argsort(-np.array(self.strides), kind="stable")
-
-    # Construct a shape that gives us the correct strides.
-    bcast_axes = []
-    shape = []
-    for axis in major_to_minor[::-1]:  # minor to major
-      stride = self.strides[axis]
-      if stride == 0:
-        bcast_axes.append(axis)
-        shape.append(1)
-        continue
-
-      if stride % math.prod(shape) != 0:
-        raise ValueError("Cannot express as a reshape, then slice.")
-      shape.append(stride // math.prod(shape))
-
-    if self.base.size % math.prod(shape) != 0:
-      return self.base[self.offsets]
-
-    shape = [self.base.size // math.prod(shape), *reversed(shape)]
-    slice_sizes = [
-        *(1 if a in bcast_axes else self.shape[a] for a in major_to_minor),
-        1,
-    ]
-
-    if shape[0] == self.shape[major_to_minor[0]]:
-      needs_offset_slice = False
-    elif not isinstance(self.offset, int):
-      needs_offset_slice = True
-    else:
-      start_indices = np.unravel_index(self.offset, shape)
-      end_indices = [s + size for s, size in zip(start_indices, slice_sizes)]
-      needs_offset_slice = any(e > dim for e, dim in zip(end_indices, shape))
-
-    if needs_offset_slice:
-      shape[0] = self.shape[major_to_minor[0]]
-      size = math.prod(shape)
-      # The pad is necessary to ensure that the dynamic slice is in range.
-      vals = jnp.pad(self.base, (0, size))
-      vals = jax.lax.dynamic_slice(vals, (self.offset,), (size,))
-      start_indices = [0] * len(shape)
-    else:
-      vals = self.base
-      start_indices = jnp.unravel_index(self.offset, shape)
-
-    vals = vals.reshape(shape)
-    vals = jax.lax.dynamic_slice(vals, start_indices, slice_sizes)[..., 0]
-    # Move axes from their physical ordering to their logical ordering.
-    vals = vals.transpose(np.argsort(major_to_minor))
-    return jnp.broadcast_to(vals, self.shape)
-
-
-def as_array_view(x: jax.Array | ArrayView) -> ArrayView:
-  return x if isinstance(x, ArrayView) else ArrayView(x)
-
-
-T = TypeVar("T", jax.Array, ArrayView)
-
-
-def zeros_like(x: T) -> T:
-  if isinstance(x, ArrayView):
-    return x._replace(base=jnp.zeros_like(x.base))
-  return jnp.zeros_like(x)
-
-
-def _canonicalize_axis(axis, num_dims) -> int:
-  """Canonicalize an axis in [-num_dims, num_dims) to [0, num_dims)."""
-  axis = operator.index(axis)
-  if not -num_dims <= axis < num_dims:
-    raise ValueError(
-        f"axis {axis} is out of bounds for array of dimension {num_dims}"
-    )
-  if axis < 0:
-    axis = axis + num_dims
-  return axis
diff --git a/src/alphafold3/jax/common/precision.py b/src/alphafold3/jax/common/precision.py
deleted file mode 100644
index e39aa840a8faf17310663147ea73888b9611b34e..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/common/precision.py
+++ /dev/null
@@ -1,92 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Precision classes and utilities."""
-
-import enum
-
-import jax
-import jax.numpy as jnp
-
-
-@enum.unique
-class DotPrecision(enum.Enum):
-  """Precision for `dot` operation.
-
-  Naming scheme: {OPERAND_DTYPE}_{ACCUMULATOR_DTYPE}[_{NUM_PASSES}x]
-  """
-
-  BF16_F32 = "bf16_f32"
-
-  # GPU only precisions.
-  F32_F32 = "f32_f32"  # Full f32 precision (doesn't use TensorCores).
-  TF32_F32 = "tf32_f32"  # Equivalent to `DEFAULT`/`HIGH` on GPU.
-  TF32_F32_3X = "tf32_f32_3x"
-  F16_F16 = "f16_f16"
-  F16_F32 = "f16_f32"
-
-  @property
-  def operand_dtype(self) -> jnp.dtype:
-    match self:
-      case DotPrecision.BF16_F32:
-        return jnp.bfloat16
-      case DotPrecision.F16_F16 | DotPrecision.F16_F32:
-        return jnp.float16
-      case _:
-        return jnp.float32
-
-  @property
-  def accumulator_dtype(self) -> jnp.dtype:
-    return jnp.float16 if (self == DotPrecision.F16_F16) else jnp.float32
-
-
-_JAX_GPU_PRECISION_MAP = {
-    (jnp.float16, jax.lax.Precision.DEFAULT): DotPrecision.F16_F32,
-    (jnp.bfloat16, jax.lax.Precision.DEFAULT): DotPrecision.BF16_F32,
-    (jnp.float32, jax.lax.Precision.DEFAULT): DotPrecision.TF32_F32,
-    (jnp.float32, jax.lax.Precision.HIGH): DotPrecision.TF32_F32,
-    (jnp.float32, jax.lax.Precision.HIGHEST): DotPrecision.F32_F32,
-}
-
-_JAX_CPU_PRECISION_MAP = {
-    (jnp.float16, jax.lax.Precision.DEFAULT): DotPrecision.F16_F32,
-    (jnp.bfloat16, jax.lax.Precision.DEFAULT): DotPrecision.F32_F32,
-    (jnp.float32, jax.lax.Precision.DEFAULT): DotPrecision.F32_F32,
-    (jnp.float32, jax.lax.Precision.HIGH): DotPrecision.F32_F32,
-    (jnp.float32, jax.lax.Precision.HIGHEST): DotPrecision.F32_F32,
-}
-
-
-def _create_jax_precision_map():
-  precision_map = {}
-  for (dtype, jax_precision), dot_precision in _JAX_GPU_PRECISION_MAP.items():
-    precision_map[("gpu", jnp.dtype(dtype), jax_precision)] = dot_precision
-  for (dtype, jax_precision), dot_precision in _JAX_CPU_PRECISION_MAP.items():
-    precision_map[("cpu", jnp.dtype(dtype), jax_precision)] = dot_precision
-  return precision_map
-
-
-_JAX_PRECISION_MAP = _create_jax_precision_map()
-
-
-def get_equivalent_dot_precision(
-    a_dtype: jnp.dtype, b_dtype: jnp.dtype, jax_precision: jax.lax.Precision
-) -> DotPrecision:
-  """Returns `DotPrecision` replicating default XLA behaviour."""
-  if a_dtype != b_dtype:
-    raise ValueError("Cannot infer precision if operand types differ.")
-
-  backend = jax.default_backend().lower()
-  if (jax_precision != jax.lax.Precision.DEFAULT) and (a_dtype != jnp.float32):
-    raise ValueError(
-        "`jax.lax.Precision` values other than `DEFAULT` only have an effect if"
-        " the operand type is `float32`."
-    )
-  return _JAX_PRECISION_MAP[(backend, a_dtype, jax_precision)]
diff --git a/src/alphafold3/jax/common/triton_utils.py b/src/alphafold3/jax/common/triton_utils.py
deleted file mode 100644
index ebf67fcefb68dc2915e144a763a8a90e732ff6eb..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/common/triton_utils.py
+++ /dev/null
@@ -1,125 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Triton utils."""
-
-from collections.abc import Callable, Mapping
-
-from alphafold3.jax.common import precision as precision_lib
-import jax
-import jax.numpy as jnp
-import triton
-import triton.language as tl
-
-
-_JNP_TO_TL_DTYPES: Mapping[jnp.dtype, tl.dtype] = {
-    jnp.bool_: tl.int1,
-    jnp.int8: tl.int8,
-    jnp.int16: tl.int16,
-    jnp.int32: tl.int32,
-    jnp.int64: tl.int64,
-    jnp.uint8: tl.uint8,
-    jnp.uint16: tl.uint16,
-    jnp.uint32: tl.uint32,
-    jnp.uint64: tl.uint64,
-    jnp.float16: tl.float16,
-    jnp.bfloat16: tl.bfloat16,
-    jnp.float32: tl.float32,
-    jnp.float64: tl.float64,
-}
-
-
-def jnp_to_tl_dtype(jnp_dtype: jnp.dtype) -> tl.dtype:
-  return _JNP_TO_TL_DTYPES[jnp_dtype]
-
-
-def get_tl_dot_fn(
-    precision: precision_lib.DotPrecision,
-) -> Callable[..., tl.tensor]:
-  """Returns a tl `dot` implementation with the specified precision.
-
-  Args:
-    precision: The `dot` precision.
-  """
-  if not is_precision_supported(precision):
-    raise ValueError(f'Unsupported dot precision: {precision}')
-
-  if precision == precision_lib.DotPrecision.TF32_F32_3X:
-    return _dot_tf32_f32_3x
-
-  in_dtype = jnp_to_tl_dtype(precision.operand_dtype)
-  out_dtype = jnp_to_tl_dtype(precision.accumulator_dtype)
-  allow_tf32 = precision == precision_lib.DotPrecision.TF32_F32
-
-  @tl.core.extern
-  def _dot_fn(
-      a: tl.core.tensor,
-      b: tl.core.tensor,
-      *,
-      trans_a: bool = False,
-      trans_b: bool = False,
-      _builder,
-  ):
-    if in_dtype == tl.float32:
-      tl.static_assert(a.dtype == tl.float32, _builder=_builder)
-      tl.static_assert(b.dtype == tl.float32, _builder=_builder)
-    else:
-      tl.static_assert(a.dtype.is_standard_floating(), _builder=_builder)
-      tl.static_assert(b.dtype.is_standard_floating(), _builder=_builder)
-    a = a.to(in_dtype, _builder=_builder)
-    b = b.to(in_dtype, _builder=_builder)
-    a = tl.trans(a, _builder=_builder) if trans_a else a
-    b = tl.trans(b, _builder=_builder) if trans_b else b
-    return tl.dot(
-        a, b, allow_tf32=allow_tf32, out_dtype=out_dtype, _builder=_builder
-    )
-
-  return _dot_fn
-
-
-def is_precision_supported(precision: precision_lib.DotPrecision) -> bool:
-  return precision in {
-      precision_lib.DotPrecision.F32_F32,
-      precision_lib.DotPrecision.TF32_F32,
-      precision_lib.DotPrecision.F16_F32,
-      precision_lib.DotPrecision.BF16_F32,
-      precision_lib.DotPrecision.TF32_F32_3X,
-  }
-
-
-@triton.jit
-def _dot_tf32_f32_3x(a, b, trans_a=False, trans_b=False):
-  """Perform the 3-pass tf32 dot function."""
-  tl.static_assert(a.dtype == tl.float32)
-  tl.static_assert(b.dtype == tl.float32)
-  a_ = (a.to(tl.uint32, bitcast=True) & 0xFFFFE000).to(tl.float32, bitcast=True)
-  b_ = (b.to(tl.uint32, bitcast=True) & 0xFFFFE000).to(tl.float32, bitcast=True)
-  a_err = a - a_
-  b_err = b - b_
-  if trans_a:
-    a_ = tl.trans(a_)
-    a_err = tl.trans(a_err)
-  if trans_b:
-    b_ = tl.trans(b_)
-    b_err = tl.trans(b_err)
-  # Add smallest terms first for better accuracy.
-  return tl.dot(a_, b_, out_dtype=tl.float32) + (
-      tl.dot(a_, b_err, out_dtype=tl.float32)
-      + tl.dot(a_err, b_, out_dtype=tl.float32)
-  )
-
-
-def has_triton_support() -> bool:
-  """Returns True if Triton is supported by the default JAX device."""
-  if jax.default_backend() != 'gpu':
-    return False
-
-  # Only currently supported for Ampere and above.
-  return float(jax.devices()[0].compute_capability) >= 8.0
diff --git a/src/alphafold3/jax/gated_linear_unit/block.py b/src/alphafold3/jax/gated_linear_unit/block.py
deleted file mode 100644
index 43c7e79e7e160d9a0e070b73080c509daf063389..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/gated_linear_unit/block.py
+++ /dev/null
@@ -1,126 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Pallas block load / store utilities."""
-
-from collections.abc import Sequence
-from typing import Any, TypeAlias
-
-from alphafold3.jax.common import array_view
-import jax
-import jax.experimental
-from jax.experimental import pallas as pl
-import jax.numpy as jnp
-import jaxtyping
-from jaxtyping import Int  # pylint: disable=g-importing-member
-import numpy as np
-import typeguard
-
-ArrayT: TypeAlias = Any
-ScalarInt: TypeAlias = (
-    Int[ArrayT, ""] | Int[np.generic, ""] | Int[jnp.generic, ""]
-)
-
-
-@jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-def load_block(
-    ref,
-    idx: Sequence[int | ScalarInt],
-    *,
-    block_shape: Sequence[int | None],
-    other=None,
-    **kwargs,
-) -> jax.Array:
-  """Loads a block from the given `ref`, masking where necessary."""
-  idx, mask = _get_block_indexer_and_mask(ref, idx, block_shape=block_shape)
-  if isinstance(ref, array_view.ArrayView):
-    idx = ref[idx].offsets
-    ref = ref.base
-  other = None if mask is None else other
-  with jax.experimental.enable_x64():
-    return pl.load(ref, idx, mask=mask, other=other, **kwargs)
-
-
-@jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-def store_block(
-    ref,
-    val: jax.Array,
-    idx: Sequence[int | ScalarInt],
-    *,
-    block_shape: Sequence[int | None] | None = None,
-    **kwargs,
-):
-  """Stores a block from the given `ref`, masking where necessary."""
-  if block_shape is None:
-    block_shape = val.shape
-  idx, mask = _get_block_indexer_and_mask(ref, idx, block_shape=block_shape)
-  if isinstance(ref, array_view.ArrayView):
-    idx = ref[idx].offsets
-    ref = ref.base
-  with jax.experimental.enable_x64():
-    pl.store(ref, idx, val.astype(ref.dtype), mask=mask, **kwargs)
-
-
-def in_bounds_mask(
-    idx: Sequence[int | slice | pl.Slice | jax.Array],
-    shape: Sequence[int],
-    *,
-    check: Sequence[bool] | None = None,
-) -> jax.Array | None:
-  """Returns a boolean mask denoting which indices are within bounds.
-
-  Args:
-    idx: Indices for each dimension.
-    shape: Shape designating the valid bounds.
-    check: Whether or not to check bounds in each dimension. Useful for ignoring
-      indices known to be in bounds. Defaults to all True.
-  """
-  if check is None:
-    check = [True] * len(shape)
-
-  # Remove `int` indexed dims (mask shape must match slice result shape).
-  shape = [dim for i, dim in enumerate(shape) if not isinstance(idx[i], int)]
-  check = [chk for i, chk in enumerate(check) if not isinstance(idx[i], int)]
-  idx = [idx for idx in idx if not isinstance(idx, int)]
-
-  mask = None
-  for i, (dim_idx, dim, chk) in enumerate(zip(idx, shape, check, strict=True)):
-    if not chk:
-      continue
-
-    if isinstance(dim_idx, slice):
-      dim_idx = pl.Slice.from_slice(dim_idx, dim)
-    if isinstance(dim_idx, pl.Slice):
-      dim_idx = dim_idx.start + dim_idx.stride * jnp.arange(dim_idx.size)
-    if dim_idx.ndim != 1:
-      raise NotImplementedError("Only one-dimensional indices are supported.")
-
-    bcast_axes = [a for a in range(len(shape)) if a != i]
-    dim_mask = jnp.expand_dims(dim_idx < dim, bcast_axes)
-    mask = dim_mask if mask is None else (mask & dim_mask)
-  return mask
-
-
-def _get_block_indexer_and_mask(
-    ref, idx: Sequence[int | ScalarInt], *, block_shape: Sequence[int | None]
-) -> tuple[tuple[int | slice | pl.Slice, ...], jax.Array | None]:
-  """Return indices and mask for loading / storing a block."""
-  shape = ref.shape
-  idxs = []
-  check = []
-  for dim, block_idx, block_dim in zip(shape, idx, block_shape, strict=True):
-    if block_dim is None:
-      idxs.append(block_idx)
-      check.append(False)
-    else:
-      idxs.append(pl.dslice(block_dim * block_idx, block_dim))
-      check.append(dim % block_dim != 0)
-
-  return tuple(idxs), in_bounds_mask(idxs, shape, check=check)
diff --git a/src/alphafold3/jax/gated_linear_unit/gated_linear_unit.py b/src/alphafold3/jax/gated_linear_unit/gated_linear_unit.py
deleted file mode 100644
index 304d8136aab9f982054db08c6605c99fdf96ead1..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/gated_linear_unit/gated_linear_unit.py
+++ /dev/null
@@ -1,124 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Public API for gated linear unit functions."""
-
-from collections.abc import Callable
-import typing
-from typing import Literal, TypeAlias
-
-from alphafold3.jax.common import array_view
-from alphafold3.jax.common import triton_utils
-from alphafold3.jax.gated_linear_unit import gated_linear_unit_base
-from alphafold3.jax.gated_linear_unit import matmul_ext
-import jax
-import jaxtyping
-from jaxtyping import Array, Float  # pylint: disable=g-importing-member,g-multiple-import
-import typeguard
-
-Implementation: TypeAlias = Literal['xla', 'triton']
-
-
-class PallasGatedLinearUnit(gated_linear_unit_base.GatedLinearUnit):
-  """Pallas gated linear unit."""
-
-  def _fwd(self, x, weight, *, activation, precision):
-    weight_view = array_view.ArrayView(weight)
-    return self.apply_vmap_rule_forward(
-        matmul_ext.gated_linear_unit,
-        activation=activation,
-        precision=precision,
-    )(
-        x,
-        weight_view[:, 1],
-        weight_view[:, 0],
-    )
-
-
-@jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-def gated_linear_unit(
-    x: Float[Array, '*B M K'],
-    weight: Float[Array, 'K 2 N'],
-    *,
-    activation: Callable[[jax.Array], jax.Array] | None = None,
-    precision: jax.lax.Precision | None = None,
-    implementation: Implementation | None = None,
-) -> Float[Array, '*B M N']:
-  """Applies a gated linear unit (https://arxiv.org/abs/1612.08083).
-
-  Computes `activation(x @ weight[:, 0]) * x @ weight[:, 1]`.
-
-  This is SwiGLU when `activation=jax.nn.swish`, GEGLU when
-  `activation=jax.nn.gelu`, REGLU when `activation=jax.nn.relu`, and GLU when
-  `activation=jax.nn.sigmoid` (https://arxiv.org/abs/2002.05202).
-
-  Args:
-    x: the input array.
-    weight: the combined weight array.
-    activation: optional activation function.
-    precision: specifies the matrix multiplication precision. Either `None`
-      (default), which means the default precision for the backend, or a
-      `jax.lax.Precision` enum.
-    implementation: if `None` (default), an implementation is automatically
-      chosen. 'xla' will use standard XLA and work on any platform, and 'triton'
-      will use a fused Triton GPU kernel. Only a subset of data types, shapes
-      and GPUs are supported by 'triton', with an exception thrown in this case.
-
-  Raises:
-    NotImplementedError: if `implementation='triton'` does not support a given
-      input or device.
-    ValueError: if the arguments are invalid.
-
-  Returns:
-    The output array.
-  """
-
-  match implementation:
-    case 'triton':
-      if not triton_utils.has_triton_support():
-        raise NotImplementedError('Triton not supported on this platform.')
-    case _:
-      ...
-
-  if x.dtype.name != weight.dtype.name:
-    raise ValueError(
-        f'Input and weight must have the same dtype. {x.dtype} !='
-        f' {weight.dtype}'
-    )
-
-  if implementation is not None:
-    named_args = typing.get_args(Implementation)
-    if implementation not in named_args:
-      raise ValueError(
-          f'Unsupported named implementation. Must be one of {named_args}.'
-      )
-
-  if implementation is None or implementation == 'triton':
-    try:
-      return PallasGatedLinearUnit()(
-          x=x,
-          weight=weight,
-          activation=activation,
-          precision=precision,
-      )
-      # When `implementation=None`, we must catch any exception, and use XLA
-      # as a fallback. As we rely on a third-party library (Triton), it might
-      # not be possible to enumerate all possible exceptions that could be
-      # thrown, hence catching the broadest possible one.
-    except Exception as e:  # pylint: disable=broad-exception-caught
-      if implementation == 'triton':
-        raise e
-
-  return gated_linear_unit_base.gated_linear_unit_xla(
-      x=x,
-      weight=weight,
-      activation=activation,
-      precision=precision,
-  )
diff --git a/src/alphafold3/jax/gated_linear_unit/gated_linear_unit_base.py b/src/alphafold3/jax/gated_linear_unit/gated_linear_unit_base.py
deleted file mode 100644
index 164bcf7f665194f6682aecbd6a1775801bf6200e..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/gated_linear_unit/gated_linear_unit_base.py
+++ /dev/null
@@ -1,130 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Common types for gated linear unit kernels."""
-
-import abc
-from collections.abc import Callable
-import functools
-from typing import Any
-
-import jax
-import jax.numpy as jnp
-import jaxtyping
-from jaxtyping import Array, Float  # pylint: disable=g-importing-member,g-multiple-import
-import typeguard
-
-
-class GatedLinearUnit(abc.ABC):
-  """Gated linear unit."""
-
-  def __call__(
-      self,
-      x: Float[Array, '*B M K'],
-      weight: Float[Array, 'K 2 N'],
-      *,
-      activation: Callable[[jax.Array], jax.Array] | None = None,
-      precision: jax.lax.Precision | None = None,
-      **kwargs,
-  ) -> Float[Array, '*B M N']:
-    """Applies a gated linear unit (https://arxiv.org/abs/1612.08083).
-
-    Computes `activation(x @ weight[:, 0]) * x @ weight[:, 1]`.
-
-    Args:
-      x: the input array.
-      weight: the combined weight array.
-      activation: optional activation function.
-      precision: specifies the matrix multiplication precision. Either `None`
-        (default), which means the default precision for the backend, or a
-        `jax.lax.Precision` enum.
-      **kwargs: additional keyword arguments.
-
-    Returns:
-      The output array.
-    """
-    return self._fwd(
-        x, weight, activation=activation, precision=precision, **kwargs
-    )
-
-  # Default vmap rule.
-  @property
-  def vmap_rule_forward(self) -> Callable[..., Any]:
-    def _vmap_rule(
-        axis_size, in_batched, *args, fn: jax.custom_batching.custom_vmap
-    ):
-      sequential_vmap = jax.custom_batching.sequential_vmap(fn.fun)
-      return sequential_vmap.vmap_rule(axis_size, in_batched, *args)
-
-    return _vmap_rule
-
-  def apply_vmap_rule_forward(
-      self, fn: Callable[..., Any], **kwargs
-  ) -> jax.custom_batching.custom_vmap:
-    fn_closed = functools.partial(fn, **kwargs)
-    fn_closed = jax.custom_batching.custom_vmap(fn_closed)
-    vmap_rule = functools.partial(self.vmap_rule_forward, fn=fn_closed)
-    fn_closed.def_vmap(vmap_rule)
-    return fn_closed
-
-  @abc.abstractmethod
-  def _fwd(
-      self,
-      x: Float[Array, '*B M K'],
-      weight: Float[Array, 'K 2 N'],
-      *,
-      activation: Callable[[jax.Array], jax.Array] | None,
-      precision: jax.lax.Precision | None,
-  ) -> Float[Array, '*B M N']:
-    """Gated linear unit."""
-    ...
-
-
-@jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-def gated_linear_unit_xla(
-    x: Float[Array, '*B M K'],
-    weight: Float[Array, 'K 2 N'],
-    *,
-    activation: Callable[[jax.Array], jax.Array] | None = None,
-    precision: jax.lax.Precision | None = None,
-) -> Float[Array, '*B M N']:
-  """Applies a gated linear unit (https://arxiv.org/abs/1612.08083).
-
-  Computes `activation(x @ weight[:, 0]) * x @ weight[:, 1]`.
-
-  This is SwiGLU when `activation=jax.nn.swish`, GEGLU when
-  `activation=jax.nn.gelu`, REGLU when `activation=jax.nn.relu`, and GLU when
-  `activation=jax.nn.sigmoid` (https://arxiv.org/abs/2002.05202).
-
-  Args:
-    x: the input array.
-    weight: the combined weight array.
-    activation: optional activation function.
-    precision: specifies the matrix multiplication precision. Either `None`
-      (default), which means the default precision for the backend, or a
-      `jax.lax.Precision` enum.
-
-  Returns:
-    The output array.
-  """
-
-  weight_reshaped = jax.lax.collapse(
-      weight, start_dimension=-2, stop_dimension=None
-  )
-  assert weight_reshaped.ndim == 2
-
-  y = jnp.dot(x, weight_reshaped, precision=precision)
-
-  # Apply activation and compute product of FP8/FP16/BF16 in FP32.
-  y = y.astype(jnp.promote_types(x.dtype, jnp.float32))
-  a, b = jnp.split(y, 2, axis=-1)
-  out = a * b if activation is None else activation(a) * b
-  out = out.astype(x.dtype)
-  return out
diff --git a/src/alphafold3/jax/gated_linear_unit/matmul_config.py b/src/alphafold3/jax/gated_linear_unit/matmul_config.py
deleted file mode 100644
index 062855f68260372183e7b24d07613e4ddb5f4247..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/gated_linear_unit/matmul_config.py
+++ /dev/null
@@ -1,78 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Auto-tuned configs for matmul."""
-
-import dataclasses
-import functools
-import math
-
-import jax
-from jax.experimental import pallas as pl
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True)
-class Config:
-  block_m: int
-  block_n: int
-  block_k: int
-  num_warps: int
-  num_stages: int
-
-
-@functools.cache
-def _get_best_block_size(
-    m: int, n: int, k: int, core_count: int
-) -> tuple[int, int, int]:
-  """Returns the best block size for the given shape."""
-  min_block_dim = 32
-  block_m = min(max(min_block_dim, pl.next_power_of_2(m)), 128)
-  block_n = min(max(min_block_dim, pl.next_power_of_2(n)), 256)
-  block_n = min(block_n, (128 * 128) // block_m)
-  block_k = 32
-  split_k = 1
-  num_blocks = pl.cdiv(m, block_m) * pl.cdiv(n, block_n)
-  while num_blocks < core_count:
-    if block_m > min_block_dim:
-      block_m //= 2
-      num_blocks = pl.cdiv(m, block_m) * pl.cdiv(n, block_n)
-    elif split_k * block_k < pl.next_power_of_2(k):
-      split_k *= 2
-      num_blocks *= 2
-    else:
-      break
-  return block_m, block_n, block_k
-
-
-def _abstractify(x):
-  return jax.api_util.shaped_abstractify(x) if isinstance(x, jax.Array) else x
-
-
-def get_config(
-    x: jax.Array, w: jax.Array, core_count: int | None = None
-) -> Config:
-  """Returns a config for the given args."""
-  if core_count is None:
-    core_count = jax.devices()[0].core_count
-  x = _abstractify(x)
-  w = _abstractify(w)
-  m, k = math.prod(x.shape[:-1]), x.shape[-1]
-  n = w.shape[1]
-  if n >= m:  # Prefer `block_n` > `block_m`.
-    block_m, block_n, block_k = _get_best_block_size(m, n, k, core_count)
-  else:
-    block_n, block_m, block_k = _get_best_block_size(n, m, k, core_count)
-  return Config(
-      block_m=block_m,
-      block_n=block_n // 2,  # Halve `block_n` as we read two `w` blocks.
-      block_k=block_k,
-      num_warps=4,
-      num_stages=4,
-  )
diff --git a/src/alphafold3/jax/gated_linear_unit/matmul_ext.py b/src/alphafold3/jax/gated_linear_unit/matmul_ext.py
deleted file mode 100644
index c29b5ec681ae5ba73abfd55dea7b8f82972eef14..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/gated_linear_unit/matmul_ext.py
+++ /dev/null
@@ -1,270 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Extended matmul ops."""
-
-from collections.abc import Callable
-import functools
-from typing import Any, TypeAlias
-
-from alphafold3.jax.common import array_view
-from alphafold3.jax.common import triton_utils
-from alphafold3.jax.gated_linear_unit import block
-from alphafold3.jax.gated_linear_unit import matmul_config
-import jax
-from jax._src.state import discharge
-from jax.experimental import pallas as pl
-import jax.numpy as jnp
-import jaxtyping
-from jaxtyping import Array, Float, Int  # pylint: disable=g-importing-member,g-multiple-import
-import numpy as np
-import typeguard
-
-ArrayView = array_view.ArrayView
-PyTree: TypeAlias = Any
-ArrayT: TypeAlias = Any
-ScalarInt: TypeAlias = (
-    Int[ArrayT, ''] | Int[np.generic, ''] | Int[jnp.generic, '']
-)
-
-
-def _get_group_cache_usage(
-    group_size_m, num_blocks_m, num_blocks_n, block_m_bytes, block_n_bytes
-) -> int:
-  """Returns the cache usage in bytes for the given group size."""
-  num_live_progs = jax.devices()[0].core_count
-  num_live_blocks_n = min(pl.cdiv(num_live_progs, group_size_m), num_blocks_n)
-  num_live_groups = pl.cdiv(num_live_progs, group_size_m * num_live_blocks_n)
-  num_live_blocks_m = min(num_live_groups * group_size_m, num_blocks_m)
-  return num_live_blocks_m * block_m_bytes + num_live_blocks_n * block_n_bytes
-
-
-def _get_pids(
-    pid, num_blocks_m, num_blocks_n, group_size_m
-) -> tuple[ScalarInt, ScalarInt]:
-  """Returns the program IDs in each grid axis."""
-  # Use `floor_divide` and `remainder` (instead of lax.div and lax.rem)
-  # to handle dtypes: pid (int32) vs. num_blocks_n (int64) when `jax_enable_x64`
-  # is set.
-  if group_size_m == 1:
-    return jnp.floor_divide(pid, num_blocks_n), jnp.remainder(pid, num_blocks_n)
-
-  num_progs_in_group = group_size_m * num_blocks_n
-  group_start_m = jnp.floor_divide(pid, num_progs_in_group) * group_size_m
-  group_size_m = jnp.minimum(num_blocks_m - group_start_m, group_size_m)
-  pid_m = group_start_m + jnp.remainder(pid, group_size_m)
-  pid_n = jnp.floor_divide(jnp.remainder(pid, num_progs_in_group), group_size_m)
-  return pid_m, pid_n
-
-
-def _get_best_pids(
-    pid, *, m, n, block_m, block_n, a_dtype_bytes, b_dtype_bytes
-) -> tuple[ScalarInt, ScalarInt]:
-  """Returns the grouped program IDs that minimize cache usage."""
-  num_blocks_m = pl.cdiv(m, block_m)
-  num_blocks_n = pl.cdiv(n, block_n)
-  block_m_bytes = block_m * a_dtype_bytes
-  block_n_bytes = block_n * b_dtype_bytes
-
-  num_live_progs = jax.devices()[0].core_count
-
-  def group_size_m_usage(group_size_m):
-    return _get_group_cache_usage(
-        group_size_m, num_blocks_m, num_blocks_n, block_m_bytes, block_n_bytes
-    )
-
-  group_size_m = min(
-      range(1, min(num_live_progs, num_blocks_m) + 1), key=group_size_m_usage
-  )
-
-  def group_size_n_usage(group_size_n):
-    return _get_group_cache_usage(
-        group_size_n, num_blocks_n, num_blocks_m, block_n_bytes, block_m_bytes
-    )
-
-  group_size_n = min(
-      range(1, min(num_live_progs, num_blocks_n) + 1), key=group_size_n_usage
-  )
-
-  if group_size_m_usage(group_size_m) <= group_size_n_usage(group_size_n):
-    pid_m, pid_n = _get_pids(pid, num_blocks_m, num_blocks_n, group_size_m)
-  else:
-    pid_n, pid_m = _get_pids(pid, num_blocks_n, num_blocks_m, group_size_n)
-  return pid_m, pid_n
-
-
-def _apply_epilogue(
-    epilogue: Callable[..., jax.Array], x: jax.Array, args: PyTree
-) -> jax.Array:
-  """Applies the epilogue to the output."""
-  # Convert array view arguments to JAX arrays. This means that we can use the
-  # array view slices, rather than the gather that discharging state gives us.
-  is_leaf = lambda x: isinstance(x, ArrayView)
-  args_flat, args_tree = jax.tree.flatten((x, args), is_leaf=is_leaf)
-  args_flat = tuple(map(jnp.array, args_flat))
-
-  def epilogue_wrapper(refs):
-    x_ref, arg_refs = args_tree.unflatten(refs)
-    x_ref[:] = epilogue(x_ref[:], arg_refs, 0, 0)
-
-  return discharge.run_state_reference(epilogue_wrapper)(args_flat)[0]
-
-
-def _gated_linear_unit_kernel(
-    x_ref,
-    w_ref,
-    v_ref,
-    _,  # Destination, aliased with `out_ref`.
-    epilogue_in_refs,
-    out_ref,
-    *,
-    block_m,
-    block_n,
-    block_k,
-    activation,
-    precision,
-    epilogue,
-):
-  """Pallas GLU kernel."""
-  m = x_ref.shape[0]
-  n = w_ref.shape[1]
-  pid_m, pid_n = _get_best_pids(
-      pl.program_id(0),
-      m=m,
-      n=n,
-      block_m=block_m,
-      block_n=block_n,
-      a_dtype_bytes=jnp.dtype(x_ref.dtype).itemsize,
-      b_dtype_bytes=jnp.dtype(w_ref.dtype).itemsize * 2,  # Two blocks.
-  )
-
-  def body(i, acc):
-    x = block.load_block(x_ref, (pid_m, i), block_shape=(block_m, block_k))
-    w = block.load_block(w_ref, (i, pid_n), block_shape=(block_k, block_n))
-    v = block.load_block(v_ref, (i, pid_n), block_shape=(block_k, block_n))
-    acc[0] += pl.dot(x, w.astype(x.dtype), precision=precision)
-    acc[1] += pl.dot(x, v.astype(x.dtype), precision=precision)
-    return acc
-
-  num_iters = pl.cdiv(x_ref.shape[-1], block_k)
-  acc0 = jnp.zeros((block_m, block_n), dtype=jnp.float32)
-  acc1 = jnp.zeros((block_m, block_n), dtype=jnp.float32)
-  proj, gates = jax.lax.fori_loop(0, num_iters, body, init_val=[acc0, acc1])
-
-  proj = proj.astype(x_ref.dtype).astype(jnp.float32)
-  gates = gates.astype(x_ref.dtype).astype(jnp.float32)
-
-  out = proj * (gates if activation is None else activation(gates))
-
-  if epilogue is not None:
-    out = epilogue(out, epilogue_in_refs, pid_m, pid_n)
-
-  block.store_block(out_ref, out, (pid_m, pid_n))
-
-
-def _gated_linear_unit(
-    x: Float[Array | ArrayView, 'M K'],
-    weights_projection: Float[Array | ArrayView, 'K N'],
-    weights_gate: Float[Array | ArrayView, 'K N'],
-    *,
-    dst: Float[ArrayView, 'M N'] | None = None,
-    activation: Callable[[jax.Array], jax.Array] | None,
-    epilogue: Any,  # Callable[..., Any] | None - breaks `typed`.
-    epilogue_args: PyTree,
-    precision: jax.lax.Precision | None,
-) -> jax.Array:  # Float[Array, 'M N'] | Float[Array, 'N M']
-  """Applies a gated linear unit (arxiv.org/abs/1612.08083)."""
-  if epilogue is None and epilogue_args is not None:
-    raise ValueError('`epilogue_args` is specified but `epilogue` is None.')
-
-  name = 'pallas_glu'
-  if activation is not None:
-    name += f'_{getattr(activation, "__name__", repr(activation))}'
-  if epilogue is not None:
-    name += f'_{getattr(epilogue, "__name__", repr(epilogue))}'
-
-  w = weights_projection
-  config = matmul_config.get_config(x, w)
-
-  m = x.shape[0]
-  n = w.shape[1]
-  kernel = functools.partial(
-      _gated_linear_unit_kernel,
-      block_m=config.block_m,
-      block_n=config.block_n,
-      block_k=config.block_k,
-      activation=activation,
-      precision=precision,
-      epilogue=epilogue,
-  )
-
-  if dst is None:
-    input_output_aliases = {}
-  else:
-    input_output_aliases = {3: 0}
-
-  return pl.pallas_call(
-      kernel,
-      name=name,
-      grid=(pl.cdiv(m, config.block_m) * pl.cdiv(n, config.block_n),),
-      out_shape=jax.ShapeDtypeStruct((m, n), x.dtype) if dst is None else dst,
-      input_output_aliases=input_output_aliases,
-      compiler_params=dict(
-          triton=dict(num_warps=config.num_warps, num_stages=config.num_stages)
-      ),
-  )(x, weights_projection, weights_gate, dst, epilogue_args)
-
-
-@jaxtyping.jaxtyped(typechecker=typeguard.typechecked)
-def gated_linear_unit(
-    x: Float[Array | ArrayView, '*B M K'],
-    weights_projection: Float[Array | ArrayView, 'K N'],
-    weights_gate: Float[Array | ArrayView, 'K N'],
-    *,
-    activation: Callable[[jax.Array], jax.Array] | None = None,
-    precision: jax.lax.Precision | None = None,
-) -> Float[Array | ArrayView, '*B M N']:
-  """Applies a gated linear unit (arxiv.org/abs/1612.08083).
-
-  Args:
-    x: Input activations.
-    weights_projection: Weights for linear projection.
-    weights_gate: Weights for gates.
-    activation: Optional activation function.
-    precision: Specifies the precision of the matmuls.
-
-  Returns:
-    `(x @ weights_projection) * activation(x @ weights_gate)`
-  """
-
-  supported_dtypes = {'float16', 'bfloat16', 'float32'}
-  if x.dtype.name not in supported_dtypes:
-    raise NotImplementedError(
-        f'Triton kernel does not support input datatype {x.dtype.name}. Must be'
-        f' one of {supported_dtypes}.'
-    )
-
-  if not triton_utils.has_triton_support():
-    raise NotImplementedError('Triton kernel not supported on current device.')
-
-  *batch, m, _ = x.shape
-  n = weights_projection.shape[1]
-  x = array_view.as_array_view(x).collapse(start=0, stop=-1)
-
-  return _gated_linear_unit(
-      x,
-      weights_projection,
-      weights_gate,
-      dst=None,
-      activation=activation,
-      precision=precision,
-      epilogue=None,
-      epilogue_args=None,
-  ).reshape(batch + [m, n])
diff --git a/src/alphafold3/jax/geometry/__init__.py b/src/alphafold3/jax/geometry/__init__.py
deleted file mode 100644
index 334d07b7a408f95f75a40ae4a3b4cee14f231dd4..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/geometry/__init__.py
+++ /dev/null
@@ -1,28 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Geometry Module."""
-
-from alphafold3.jax.geometry import rigid_matrix_vector
-from alphafold3.jax.geometry import rotation_matrix
-from alphafold3.jax.geometry import struct_of_array
-from alphafold3.jax.geometry import vector
-
-Rot3Array = rotation_matrix.Rot3Array
-Rigid3Array = rigid_matrix_vector.Rigid3Array
-
-StructOfArray = struct_of_array.StructOfArray
-
-Vec3Array = vector.Vec3Array
-square_euclidean_distance = vector.square_euclidean_distance
-euclidean_distance = vector.euclidean_distance
-dihedral_angle = vector.dihedral_angle
-dot = vector.dot
-cross = vector.cross
diff --git a/src/alphafold3/jax/geometry/rigid_matrix_vector.py b/src/alphafold3/jax/geometry/rigid_matrix_vector.py
deleted file mode 100644
index e6abb93c4de32e5144ca02240799754987013815..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/geometry/rigid_matrix_vector.py
+++ /dev/null
@@ -1,224 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Rigid3Array Transformations represented by a Matrix and a Vector."""
-
-from typing import Any, Final, Self, TypeAlias
-
-from alphafold3.jax.geometry import rotation_matrix
-from alphafold3.jax.geometry import struct_of_array
-from alphafold3.jax.geometry import utils
-from alphafold3.jax.geometry import vector
-import jax
-import jax.numpy as jnp
-
-
-Float: TypeAlias = float | jnp.ndarray
-
-VERSION: Final[str] = '0.1'
-
-
-# Disabling name in pylint, since the relevant variable in math are typically
-# referred to as X, Y in mathematical literature.
-def _compute_covariance_matrix(
-    row_values: vector.Vec3Array,
-    col_values: vector.Vec3Array,
-    weights: jnp.ndarray,
-    epsilon=1e-6,
-) -> jnp.ndarray:
-  """Compute covariance matrix.
-
-  The quantity computes is
-  cov_xy = weighted_avg_i(row_values[i, x] col_values[j, y]).
-  Here x and y run over the xyz coordinates.
-  This is used to construct frames when aligning points.
-
-  Args:
-    row_values: Values used for rows of covariance matrix, shape [..., n_point]
-    col_values: Values used for columns of covariance matrix, shape [...,
-      n_point]
-    weights: weights to weight points by, shape broacastable to [...]
-    epsilon: small value to add to denominator to avoid Nan's when all weights
-      are 0.
-
-  Returns:
-    Covariance Matrix as [..., 3, 3] array.
-  """
-  weights = jnp.asarray(weights)
-  weights = jnp.broadcast_to(weights, row_values.shape)
-
-  out = []
-
-  normalized_weights = weights / (weights.sum(axis=-1, keepdims=True) + epsilon)
-
-  weighted_average = lambda x: jnp.sum(normalized_weights * x, axis=-1)
-
-  out.append(
-      jnp.stack(
-          (
-              weighted_average(row_values.x * col_values.x),
-              weighted_average(row_values.x * col_values.y),
-              weighted_average(row_values.x * col_values.z),
-          ),
-          axis=-1,
-      )
-  )
-
-  out.append(
-      jnp.stack(
-          (
-              weighted_average(row_values.y * col_values.x),
-              weighted_average(row_values.y * col_values.y),
-              weighted_average(row_values.y * col_values.z),
-          ),
-          axis=-1,
-      )
-  )
-
-  out.append(
-      jnp.stack(
-          (
-              weighted_average(row_values.z * col_values.x),
-              weighted_average(row_values.z * col_values.y),
-              weighted_average(row_values.z * col_values.z),
-          ),
-          axis=-1,
-      )
-  )
-
-  return jnp.stack(out, axis=-2)
-
-
-@struct_of_array.StructOfArray(same_dtype=True)
-class Rigid3Array:
-  """Rigid Transformation, i.e. element of special euclidean group."""
-
-  rotation: rotation_matrix.Rot3Array
-  translation: vector.Vec3Array
-
-  def __matmul__(self, other: Self) -> Self:
-    new_rotation = self.rotation @ other.rotation
-    new_translation = self.apply_to_point(other.translation)
-    return Rigid3Array(new_rotation, new_translation)
-
-  def inverse(self) -> Self:
-    """Return Rigid3Array corresponding to inverse transform."""
-    inv_rotation = self.rotation.inverse()
-    inv_translation = inv_rotation.apply_to_point(-self.translation)
-    return Rigid3Array(inv_rotation, inv_translation)
-
-  def apply_to_point(self, point: vector.Vec3Array) -> vector.Vec3Array:
-    """Apply Rigid3Array transform to point."""
-    return self.rotation.apply_to_point(point) + self.translation
-
-  def apply_inverse_to_point(self, point: vector.Vec3Array) -> vector.Vec3Array:
-    """Apply inverse Rigid3Array transform to point."""
-    new_point = point - self.translation
-    return self.rotation.apply_inverse_to_point(new_point)
-
-  def compose_rotation(self, other_rotation: rotation_matrix.Rot3Array) -> Self:
-    rot = self.rotation @ other_rotation
-    trans = jax.tree.map(
-        lambda x: jnp.broadcast_to(x, rot.shape), self.translation
-    )
-    return Rigid3Array(rot, trans)
-
-  @classmethod
-  def identity(cls, shape: Any, dtype: jnp.dtype = jnp.float32) -> Self:
-    """Return identity Rigid3Array of given shape."""
-    return cls(
-        rotation_matrix.Rot3Array.identity(shape, dtype=dtype),
-        vector.Vec3Array.zeros(shape, dtype=dtype),
-    )  # pytype: disable=wrong-arg-count  # trace-all-classes
-
-  def scale_translation(self, factor: Float) -> Self:
-    """Scale translation in Rigid3Array by 'factor'."""
-    return Rigid3Array(self.rotation, self.translation * factor)
-
-  def to_array(self):
-    rot_array = self.rotation.to_array()
-    vec_array = self.translation.to_array()
-    return jnp.concatenate([rot_array, vec_array[..., None]], axis=-1)
-
-  @classmethod
-  def from_array(cls, array):
-    rot = rotation_matrix.Rot3Array.from_array(array[..., :3])
-    vec = vector.Vec3Array.from_array(array[..., -1])
-    return cls(rot, vec)  # pytype: disable=wrong-arg-count  # trace-all-classes
-
-  @classmethod
-  def from_array4x4(cls, array: jnp.ndarray) -> Self:
-    """Construct Rigid3Array from homogeneous 4x4 array."""
-    if array.shape[-2:] != (4, 4):
-      raise ValueError(f'array.shape({array.shape}) must be [..., 4, 4]')
-    rotation = rotation_matrix.Rot3Array(
-        *(array[..., 0, 0], array[..., 0, 1], array[..., 0, 2]),
-        *(array[..., 1, 0], array[..., 1, 1], array[..., 1, 2]),
-        *(array[..., 2, 0], array[..., 2, 1], array[..., 2, 2]),
-    )
-    translation = vector.Vec3Array(
-        array[..., 0, 3], array[..., 1, 3], array[..., 2, 3]
-    )
-    return cls(rotation, translation)  # pytype: disable=wrong-arg-count  # trace-all-classes
-
-  @classmethod
-  def from_point_alignment(
-      cls,
-      points_to: vector.Vec3Array,
-      points_from: vector.Vec3Array,
-      weights: Float | None = None,
-      epsilon: float = 1e-6,
-  ) -> Self:
-    """Constructs Rigid3Array by finding transform aligning points.
-
-    This constructs the optimal Rigid Transform taking points_from to the
-    arrangement closest to points_to.
-
-    Args:
-      points_to: Points to align to.
-      points_from: Points to align from.
-      weights: weights for points.
-      epsilon: epsilon used to regularize covariance matrix.
-
-    Returns:
-      Rigid Transform.
-    """
-    if weights is None:
-      weights = 1.0
-
-    def compute_center(value):
-      return utils.weighted_mean(value=value, weights=weights, axis=-1)
-
-    points_to_center = jax.tree.map(compute_center, points_to)
-    points_from_center = jax.tree.map(compute_center, points_from)
-    centered_points_to = points_to - points_to_center[..., None]
-    centered_points_from = points_from - points_from_center[..., None]
-    cov_mat = _compute_covariance_matrix(
-        centered_points_to,
-        centered_points_from,
-        weights=weights,
-        epsilon=epsilon,
-    )
-    rots = rotation_matrix.Rot3Array.from_svd(
-        jnp.reshape(cov_mat, cov_mat.shape[:-2] + (9,))
-    )
-
-    translations = points_to_center - rots.apply_to_point(points_from_center)
-
-    return cls(rots, translations)  # pytype: disable=wrong-arg-count  # trace-all-classes
-
-  def __getstate__(self):
-    return (VERSION, (self.rotation, self.translation))
-
-  def __setstate__(self, state):
-    version, (rot, trans) = state
-    del version
-    object.__setattr__(self, 'rotation', rot)
-    object.__setattr__(self, 'translation', trans)
diff --git a/src/alphafold3/jax/geometry/rotation_matrix.py b/src/alphafold3/jax/geometry/rotation_matrix.py
deleted file mode 100644
index 4d9c8377568360cc9a61165f1ed2b09bb4818357..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/geometry/rotation_matrix.py
+++ /dev/null
@@ -1,291 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Rot3Array Matrix Class."""
-
-import dataclasses
-from typing import Any, Final, Self
-
-from alphafold3.jax.geometry import struct_of_array
-from alphafold3.jax.geometry import utils
-from alphafold3.jax.geometry import vector
-import jax
-import jax.numpy as jnp
-import numpy as np
-
-
-COMPONENTS: Final[tuple[str, ...]] = (
-    *('xx', 'xy', 'xz'),
-    *('yx', 'yy', 'yz'),
-    *('zx', 'zy', 'zz'),
-)
-VERSION: Final[str] = '0.1'
-
-
-def make_matrix_svd_factors() -> np.ndarray:
-  """Generates factors for converting 3x3 matrix to symmetric 4x4 matrix."""
-  factors = np.zeros((16, 9), dtype=np.float32)
-
-  factors[0, [0, 4, 8]] = 1.0
-
-  factors[[1, 4], 5] = 1.0
-  factors[[1, 4], 7] = -1.0
-
-  factors[[2, 8], 6] = 1.0
-  factors[[2, 8], 2] = -1.0
-
-  factors[[3, 12], 1] = 1.0
-  factors[[3, 12], 3] = -1.0
-
-  factors[5, 0] = 1.0
-  factors[5, [4, 8]] = -1.0
-
-  factors[[6, 9], 1] = 1.0
-  factors[[6, 9], 3] = 1.0
-
-  factors[[7, 13], 2] = 1.0
-  factors[[7, 13], 6] = 1.0
-
-  factors[10, 4] = 1.0
-  factors[10, [0, 8]] = -1.0
-
-  factors[[11, 14], 5] = 1.0
-  factors[[11, 14], 7] = 1.0
-
-  factors[15, 8] = 1.0
-  factors[15, [0, 4]] = -1.0
-
-  return factors
-
-
-@jax.custom_jvp
-def largest_evec(m):
-  _, eigvecs = jnp.linalg.eigh(m)
-  return eigvecs[..., -1]
-
-
-def largest_evec_jvp(primals, tangents):
-  """jvp for largest eigenvector."""
-  (m,) = primals
-  (t,) = tangents
-  eigvals, eigvecs = jnp.linalg.eigh(m)
-  large_eigvec = eigvecs[..., -1]
-  large_eigval = eigvals[..., -1]
-  other_eigvals = eigvals[..., :-1]
-  other_eigvecs = eigvecs[..., :-1]
-  other_ev_times_tangent = jnp.einsum(
-      '...aj,...ab -> ...bj',
-      other_eigvecs,
-      t,
-      precision=jax.lax.Precision.HIGHEST,
-  )
-  nominator = jnp.einsum(
-      '...bj,...b -> ...j',
-      other_ev_times_tangent,
-      large_eigvec,
-      precision=jax.lax.Precision.HIGHEST,
-  )
-  prefactor = nominator / jnp.maximum(
-      large_eigval[..., None] - other_eigvals, 1e-6
-  )
-  grad = jnp.sum(prefactor[..., None, :] * other_eigvecs, axis=-1)
-  return large_eigvec, grad
-
-
-largest_evec.defjvp(largest_evec_jvp)
-
-
-MATRIX_SVD_QUAT_FACTORS = make_matrix_svd_factors()
-
-
-@struct_of_array.StructOfArray(same_dtype=True)
-class Rot3Array:
-  """Rot3Array Matrix in 3 dimensional Space implemented as struct of arrays."""
-
-  xx: jnp.ndarray = dataclasses.field(metadata={'dtype': jnp.float32})
-  xy: jnp.ndarray
-  xz: jnp.ndarray
-  yx: jnp.ndarray
-  yy: jnp.ndarray
-  yz: jnp.ndarray
-  zx: jnp.ndarray
-  zy: jnp.ndarray
-  zz: jnp.ndarray
-
-  __array_ufunc__ = None
-
-  def inverse(self) -> Self:
-    """Returns inverse of Rot3Array."""
-    return Rot3Array(
-        *(self.xx, self.yx, self.zx),
-        *(self.xy, self.yy, self.zy),
-        *(self.xz, self.yz, self.zz),
-    )
-
-  def apply_to_point(self, point: vector.Vec3Array) -> vector.Vec3Array:
-    """Applies Rot3Array to point."""
-    return vector.Vec3Array(
-        self.xx * point.x + self.xy * point.y + self.xz * point.z,
-        self.yx * point.x + self.yy * point.y + self.yz * point.z,
-        self.zx * point.x + self.zy * point.y + self.zz * point.z,
-    )
-
-  def apply_inverse_to_point(self, point: vector.Vec3Array) -> vector.Vec3Array:
-    """Applies inverse Rot3Array to point."""
-    return self.inverse().apply_to_point(point)
-
-  def __matmul__(self, other: Self) -> Self:
-    """Composes two Rot3Arrays."""
-    c0 = self.apply_to_point(vector.Vec3Array(other.xx, other.yx, other.zx))
-    c1 = self.apply_to_point(vector.Vec3Array(other.xy, other.yy, other.zy))
-    c2 = self.apply_to_point(vector.Vec3Array(other.xz, other.yz, other.zz))
-    return Rot3Array(c0.x, c1.x, c2.x, c0.y, c1.y, c2.y, c0.z, c1.z, c2.z)
-
-  @classmethod
-  def identity(cls, shape: Any, dtype: jnp.dtype = jnp.float32) -> Self:
-    """Returns identity of given shape."""
-    ones = jnp.ones(shape, dtype=dtype)
-    zeros = jnp.zeros(shape, dtype=dtype)
-    return cls(ones, zeros, zeros, zeros, ones, zeros, zeros, zeros, ones)  # pytype: disable=wrong-arg-count  # trace-all-classes
-
-  @classmethod
-  def from_two_vectors(cls, e0: vector.Vec3Array, e1: vector.Vec3Array) -> Self:
-    """Construct Rot3Array from two Vectors.
-
-    Rot3Array is constructed such that in the corresponding frame 'e0' lies on
-    the positive x-Axis and 'e1' lies in the xy plane with positive sign of y.
-
-    Args:
-      e0: Vector
-      e1: Vector
-
-    Returns:
-      Rot3Array
-    """
-    # Normalize the unit vector for the x-axis, e0.
-    e0 = e0.normalized()
-    # make e1 perpendicular to e0.
-    c = e1.dot(e0)
-    e1 = (e1 - c * e0).normalized()
-    # Compute e2 as cross product of e0 and e1.
-    e2 = e0.cross(e1)
-    return cls(e0.x, e1.x, e2.x, e0.y, e1.y, e2.y, e0.z, e1.z, e2.z)  # pytype: disable=wrong-arg-count  # trace-all-classes
-
-  @classmethod
-  def from_array(cls, array: jnp.ndarray) -> Self:
-    """Construct Rot3Array Matrix from array of shape. [..., 3, 3]."""
-    unstacked = utils.unstack(array, axis=-2)
-    unstacked = sum([utils.unstack(x, axis=-1) for x in unstacked], [])
-    return cls(*unstacked)
-
-  def to_array(self) -> jnp.ndarray:
-    """Convert Rot3Array to array of shape [..., 3, 3]."""
-    return jnp.stack(
-        [
-            jnp.stack([self.xx, self.xy, self.xz], axis=-1),
-            jnp.stack([self.yx, self.yy, self.yz], axis=-1),
-            jnp.stack([self.zx, self.zy, self.zz], axis=-1),
-        ],
-        axis=-2,
-    )
-
-  @classmethod
-  def from_quaternion(
-      cls,
-      w: jnp.ndarray,
-      x: jnp.ndarray,
-      y: jnp.ndarray,
-      z: jnp.ndarray,
-      normalize: bool = True,
-      epsilon: float = 1e-6,
-  ) -> Self:
-    """Construct Rot3Array from components of quaternion."""
-    if normalize:
-      inv_norm = jax.lax.rsqrt(jnp.maximum(epsilon, w**2 + x**2 + y**2 + z**2))
-      w *= inv_norm
-      x *= inv_norm
-      y *= inv_norm
-      z *= inv_norm
-    xx = 1 - 2 * (jnp.square(y) + jnp.square(z))
-    xy = 2 * (x * y - w * z)
-    xz = 2 * (x * z + w * y)
-    yx = 2 * (x * y + w * z)
-    yy = 1 - 2 * (jnp.square(x) + jnp.square(z))
-    yz = 2 * (y * z - w * x)
-    zx = 2 * (x * z - w * y)
-    zy = 2 * (y * z + w * x)
-    zz = 1 - 2 * (jnp.square(x) + jnp.square(y))
-    return cls(xx, xy, xz, yx, yy, yz, zx, zy, zz)  # pytype: disable=wrong-arg-count  # trace-all-classes
-
-  @classmethod
-  def from_svd(cls, mat: jnp.ndarray, use_quat_formula: bool = True) -> Self:
-    """Constructs Rot3Array from arbitrary array of shape [3 * 3] using SVD.
-
-    The case when 'use_quat_formula' is False rephrases the problem of
-    projecting the matrix to a rotation matrix as a problem of finding the
-    largest eigenvector of a certain 4x4 matrix. This has the advantage of
-    having fewer numerical issues.
-    This approach follows:
-    https://citeseerx.ist.psu.edu/viewdoc/download?doi=10.1.1.65.971&rep=rep1&type=pdf
-    In the other case we construct it via svd following
-    https://arxiv.org/pdf/2006.14616.pdf
-    In that case [∂L/∂M] is large if the two smallest singular values are close
-    to each other, or if they are close to 0.
-
-    Args:
-      mat: Array of shape [..., 3 * 3]
-      use_quat_formula: Whether to construct matrix via 4x4 eigenvalue problem.
-
-    Returns:
-      Rot3Array of shape [...]
-    """
-    assert mat.shape[-1] == 9
-    if use_quat_formula:
-      symmetric_4by4 = jnp.einsum(
-          'ji, ...i -> ...j',
-          MATRIX_SVD_QUAT_FACTORS,
-          mat,
-          precision=jax.lax.Precision.HIGHEST,
-      )
-      symmetric_4by4 = jnp.reshape(symmetric_4by4, mat.shape[:-1] + (4, 4))
-      largest_eigvec = largest_evec(symmetric_4by4)
-      return cls.from_quaternion(
-          *utils.unstack(largest_eigvec, axis=-1)
-      ).inverse()
-
-    else:
-      mat = jnp.reshape(mat, mat.shape[:-1] + (3, 3))
-      u, _, v_t = jnp.linalg.svd(mat, full_matrices=False)
-      det_uv_t = jnp.linalg.det(
-          jnp.matmul(u, v_t, precision=jax.lax.Precision.HIGHEST)
-      )
-      ones = jnp.ones_like(det_uv_t)
-      diag_array = jnp.stack([ones, ones, det_uv_t], axis=-1)
-      # This is equivalent to making diag_array into a diagonal array and matrix
-      # multiplying
-      diag_times_v_t = diag_array[..., None] * v_t
-      out = jnp.matmul(u, diag_times_v_t, precision=jax.lax.Precision.HIGHEST)
-      return cls.from_array(out)
-
-  @classmethod
-  def random_uniform(cls, key, shape, dtype=jnp.float32) -> Self:
-    """Samples uniform random Rot3Array according to Haar Measure."""
-    quat_array = jax.random.normal(key, tuple(shape) + (4,), dtype=dtype)
-    quats = utils.unstack(quat_array)
-    return cls.from_quaternion(*quats)
-
-  def __getstate__(self):
-    return (VERSION, [np.asarray(getattr(self, field)) for field in COMPONENTS])
-
-  def __setstate__(self, state):
-    version, state = state
-    del version
-    for i, field in enumerate(COMPONENTS):
-      object.__setattr__(self, field, state[i])
diff --git a/src/alphafold3/jax/geometry/struct_of_array.py b/src/alphafold3/jax/geometry/struct_of_array.py
deleted file mode 100644
index 916111e93e07f8c79cd36891825744dce26b08cc..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/geometry/struct_of_array.py
+++ /dev/null
@@ -1,231 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Class decorator to represent (nested) struct of arrays."""
-
-import dataclasses
-
-import jax
-
-
-def get_item(instance, key):
-  sliced = {}
-  for field in get_array_fields(instance):
-    num_trailing_dims = field.metadata.get('num_trailing_dims', 0)
-    this_key = key
-    if isinstance(key, tuple) and Ellipsis in this_key:
-      this_key += (slice(None),) * num_trailing_dims
-    sliced[field.name] = jax.tree.map(
-        lambda x: x[this_key],  # pylint: disable=cell-var-from-loop
-        getattr(instance, field.name),
-    )
-  return dataclasses.replace(instance, **sliced)
-
-
-@property
-def get_shape(instance):
-  """Returns Shape for given instance of dataclass."""
-  first_field = dataclasses.fields(instance)[0]
-  num_trailing_dims = first_field.metadata.get('num_trailing_dims', None)
-  value = getattr(instance, first_field.name)
-  if num_trailing_dims:
-    return value.shape[:-num_trailing_dims]
-  else:
-    return value.shape
-
-
-def get_len(instance):
-  """Returns length for given instance of dataclass."""
-  shape = instance.shape
-  if shape:
-    return shape[0]
-  else:
-    raise TypeError('len() of unsized object')  # Match jax.numpy behavior.
-
-
-@property
-def get_dtype(instance):
-  """Returns Dtype for given instance of dataclass."""
-  fields = dataclasses.fields(instance)
-  sets_dtype = [
-      field.name for field in fields if field.metadata.get('sets_dtype', False)
-  ]
-  if sets_dtype:
-    assert len(sets_dtype) == 1, 'at most field can set dtype'
-    field_value = getattr(instance, sets_dtype[0])
-  elif instance.same_dtype:
-    field_value = getattr(instance, fields[0].name)
-  else:
-    # Should this be Value Error?
-    raise AttributeError(
-        'Trying to access Dtype on Struct of Array without'
-        'either "same_dtype" or field setting dtype'
-    )
-
-  if hasattr(field_value, 'dtype'):
-    return field_value.dtype
-  else:
-    # Should this be Value Error?
-    raise AttributeError(f'field_value {field_value} does not have dtype')
-
-
-def replace(instance, **kwargs):
-  return dataclasses.replace(instance, **kwargs)
-
-
-def post_init(instance):
-  """Validate instance has same shapes & dtypes."""
-  array_fields = get_array_fields(instance)
-  arrays = list(get_array_fields(instance, return_values=True).values())
-  first_field = array_fields[0]
-  # These slightly weird constructions about checking whether the leaves are
-  # actual arrays is since e.g. vmap internally relies on being able to
-  # construct pytree's with object() as leaves, this would break the checking
-  # as such we are only validating the object when the entries in the dataclass
-  # Are arrays or other dataclasses of arrays.
-  try:
-    dtype = instance.dtype
-  except AttributeError:
-    dtype = None
-  if dtype is not None:
-    first_shape = instance.shape
-    for array, field in zip(arrays, array_fields, strict=True):
-      num_trailing_dims = field.metadata.get('num_trailing_dims', None)
-      if num_trailing_dims:
-        array_shape = array.shape
-        field_shape = array_shape[:-num_trailing_dims]
-        msg = (
-            f'field {field} should have number of trailing dims'
-            ' {num_trailing_dims}'
-        )
-        assert len(array_shape) == len(first_shape) + num_trailing_dims, msg
-      else:
-        field_shape = array.shape
-
-      shape_msg = (
-          f"Stripped Shape {field_shape} of field {field} doesn't "
-          f'match shape {first_shape} of field {first_field}'
-      )
-      assert field_shape == first_shape, shape_msg
-
-      field_dtype = array.dtype
-
-      allowed_metadata_dtypes = field.metadata.get('allowed_dtypes', [])
-      if allowed_metadata_dtypes:
-        msg = f'Dtype is {field_dtype} but must be in {allowed_metadata_dtypes}'
-        assert field_dtype in allowed_metadata_dtypes, msg
-
-      if 'dtype' in field.metadata:
-        target_dtype = field.metadata['dtype']
-      else:
-        target_dtype = dtype
-
-      msg = f'Dtype is {field_dtype} but must be {target_dtype}'
-      assert field_dtype == target_dtype, msg
-
-
-def flatten(instance):
-  """Flatten Struct of Array instance."""
-  array_likes = get_array_fields(instance, return_values=True).values()
-  flat_array_likes = []
-  inner_treedefs = []
-  num_arrays = []
-  for array_like in array_likes:
-    flat_array_like, inner_treedef = jax.tree_util.tree_flatten(array_like)
-    inner_treedefs.append(inner_treedef)
-    flat_array_likes += flat_array_like
-    num_arrays.append(len(flat_array_like))
-  metadata = get_metadata_fields(instance, return_values=True)
-  metadata = type(instance).metadata_cls(**metadata)
-  return flat_array_likes, (inner_treedefs, metadata, num_arrays)
-
-
-def make_metadata_class(cls):
-  metadata_fields = get_fields(
-      cls, lambda x: x.metadata.get('is_metadata', False)
-  )
-  metadata_cls = dataclasses.make_dataclass(
-      cls_name='Meta' + cls.__name__,
-      fields=[(field.name, field.type, field) for field in metadata_fields],
-      frozen=True,
-      eq=True,
-  )
-  return metadata_cls
-
-
-def get_fields(cls_or_instance, filterfn, return_values=False):
-  fields = dataclasses.fields(cls_or_instance)
-  fields = [field for field in fields if filterfn(field)]
-  if return_values:
-    return {
-        field.name: getattr(cls_or_instance, field.name) for field in fields
-    }
-  else:
-    return fields
-
-
-def get_array_fields(cls, return_values=False):
-  return get_fields(
-      cls,
-      lambda x: not x.metadata.get('is_metadata', False),
-      return_values=return_values,
-  )
-
-
-def get_metadata_fields(cls, return_values=False):
-  return get_fields(
-      cls,
-      lambda x: x.metadata.get('is_metadata', False),
-      return_values=return_values,
-  )
-
-
-class StructOfArray:
-  """Class Decorator for Struct Of Arrays."""
-
-  def __init__(self, same_dtype=True):
-    self.same_dtype = same_dtype
-
-  def __call__(self, cls):
-    cls.__array_ufunc__ = None
-    cls.replace = replace
-    cls.same_dtype = self.same_dtype
-    cls.dtype = get_dtype
-    cls.shape = get_shape
-    cls.__len__ = get_len
-    cls.__getitem__ = get_item
-    cls.__post_init__ = post_init
-    new_cls = dataclasses.dataclass(cls, frozen=True, eq=False)  # pytype: disable=wrong-keyword-args
-    # pytree claims to require metadata to be hashable, not sure why,
-    # But making derived dataclass that can just hold metadata
-    new_cls.metadata_cls = make_metadata_class(new_cls)
-
-    def unflatten(aux, data):
-      inner_treedefs, metadata, num_arrays = aux
-      array_fields = [field.name for field in get_array_fields(new_cls)]
-      value_dict = {}
-      array_start = 0
-      for num_array, inner_treedef, array_field in zip(
-          num_arrays, inner_treedefs, array_fields, strict=True
-      ):
-        value_dict[array_field] = jax.tree_util.tree_unflatten(
-            inner_treedef, data[array_start : array_start + num_array]
-        )
-        array_start += num_array
-      metadata_fields = get_metadata_fields(new_cls)
-      for field in metadata_fields:
-        value_dict[field.name] = getattr(metadata, field.name)
-
-      return new_cls(**value_dict)
-
-    jax.tree_util.register_pytree_node(
-        nodetype=new_cls, flatten_func=flatten, unflatten_func=unflatten
-    )
-    return new_cls
diff --git a/src/alphafold3/jax/geometry/utils.py b/src/alphafold3/jax/geometry/utils.py
deleted file mode 100644
index 7f2fc665c94f536685cbb313102b26f643e7f068..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/geometry/utils.py
+++ /dev/null
@@ -1,143 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Utils for geometry library."""
-
-from collections.abc import Iterable
-import numbers
-
-import jax
-from jax import lax
-import jax.numpy as jnp
-
-
-def safe_select(condition, true_fn, false_fn):
-  """Safe version of selection (i.e. `where`).
-
-  This applies the double-where trick.
-  Like jnp.where, this function will still execute both branches and is
-  expected to be more lightweight than lax.cond.  Other than NaN-semantics,
-  safe_select(condition, true_fn, false_fn) is equivalent to
-
-    jax.tree.map(lambda x, y: jnp.where(condition, x, y),
-                 true_fn(),
-                 false_fn()),
-
-  Compared to the naive implementation above, safe_select provides the
-  following guarantee: in either the forward or backward pass, a NaN produced
-  *during the execution of true_fn()* will not propagate to the rest of the
-  computation and similarly for false_fn.  It is very important to note that
-  while true_fn and false_fn will typically close over other tensors (i.e. they
-  use values computed prior to the safe_select function), there is no NaN-safety
-  for the backward pass of closed over values.  It is important than any NaN's
-  are produced within the branch functions and not before them.  For example,
-
-    safe_select(x < eps, lambda: 0., lambda: jnp.sqrt(x))
-
-  will not produce NaN on the backward pass even if x == 0. since sqrt happens
-  within the false_fn, but the very similar
-
-    y = jnp.sqrt(x)
-    safe_select(x < eps, lambda: 0., lambda: y)
-
-  will produce a NaN on the backward pass if x == 0 because the sqrt happens
-  prior to the false_fn.
-
-  Args:
-    condition: Boolean array to use in where
-    true_fn: Zero-argument function to construct the values used in the True
-      condition.  Tensors that this function closes over will be extracted
-      automatically to implement the double-where trick to suppress spurious NaN
-      propagation.
-    false_fn: False branch equivalent of true_fn
-
-  Returns:
-    Resulting PyTree equivalent to tree_map line above.
-  """
-  true_fn, true_args = jax.closure_convert(true_fn)
-  false_fn, false_args = jax.closure_convert(false_fn)
-
-  true_args = jax.tree.map(
-      lambda x: jnp.where(condition, x, lax.stop_gradient(x)), true_args
-  )
-
-  false_args = jax.tree.map(
-      lambda x: jnp.where(condition, lax.stop_gradient(x), x), false_args
-  )
-
-  return jax.tree.map(
-      lambda x, y: jnp.where(condition, x, y),
-      true_fn(*true_args),
-      false_fn(*false_args),
-  )
-
-
-def unstack(value: jnp.ndarray, axis: int = -1) -> list[jnp.ndarray]:
-  return [
-      jnp.squeeze(v, axis=axis)
-      for v in jnp.split(value, value.shape[axis], axis=axis)
-  ]
-
-
-def angdiff(alpha: jnp.ndarray, beta: jnp.ndarray) -> jnp.ndarray:
-  """Compute absolute difference between two angles."""
-  d = alpha - beta
-  d = (d + jnp.pi) % (2 * jnp.pi) - jnp.pi
-  return d
-
-
-def safe_arctan2(
-    x1: jnp.ndarray, x2: jnp.ndarray, eps: float = 1e-8
-) -> jnp.ndarray:
-  """Safe version of arctan2 that avoids NaN gradients when x1=x2=0."""
-
-  return safe_select(
-      jnp.abs(x1) + jnp.abs(x2) < eps,
-      lambda: jnp.zeros_like(jnp.arctan2(x1, x2)),
-      lambda: jnp.arctan2(x1, x2),
-  )
-
-
-def weighted_mean(
-    *,
-    weights: jnp.ndarray,
-    value: jnp.ndarray,
-    axis: int | Iterable[int] | None = None,
-    eps: float = 1e-10,
-) -> jnp.ndarray:
-  """Computes weighted mean in a safe way that avoids NaNs.
-
-  This is equivalent to jnp.average for the case eps=0.0, but adds a small
-  constant to the denominator of the weighted average to avoid NaNs.
-  'weights' should be broadcastable to the shape of value.
-
-  Args:
-    weights: Weights to weight value by.
-    value: Values to average
-    axis: Axes to average over.
-    eps: Epsilon to add to the denominator.
-
-  Returns:
-    Weighted average.
-  """
-
-  weights = jnp.asarray(weights, dtype=value.dtype)
-  weights = jnp.broadcast_to(weights, value.shape)
-
-  weights_shape = weights.shape
-
-  if isinstance(axis, numbers.Integral):
-    axis = [axis]
-  elif axis is None:
-    axis = list(range(len(weights_shape)))
-
-  return jnp.sum(weights * value, axis=axis) / (
-      jnp.sum(weights, axis=axis) + eps
-  )
diff --git a/src/alphafold3/jax/geometry/vector.py b/src/alphafold3/jax/geometry/vector.py
deleted file mode 100644
index 6d3bf84332c94e3ce3b69ecbb4b4ba52a08a65e7..0000000000000000000000000000000000000000
--- a/src/alphafold3/jax/geometry/vector.py
+++ /dev/null
@@ -1,222 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Vec3Array Class."""
-
-import dataclasses
-from typing import Final, Self, TypeAlias
-
-from alphafold3.jax.geometry import struct_of_array
-from alphafold3.jax.geometry import utils
-import jax
-import jax.numpy as jnp
-import numpy as np
-
-
-Float: TypeAlias = float | jnp.ndarray
-
-VERSION: Final[str] = '0.1'
-
-
-@struct_of_array.StructOfArray(same_dtype=True)
-class Vec3Array:
-  """Vec3Array in 3 dimensional Space implemented as struct of arrays.
-
-  This is done in order to improve performance and precision.
-  On TPU small matrix multiplications are very suboptimal and will waste large
-  compute ressources, furthermore any matrix multiplication on TPU happens in
-  mixed bfloat16/float32 precision, which is often undesirable when handling
-  physical coordinates.
-
-  In most cases this will also be faster on CPUs/GPUs since it allows for easier
-  use of vector instructions.
-  """
-
-  x: jnp.ndarray = dataclasses.field(metadata={'dtype': jnp.float32})
-  y: jnp.ndarray
-  z: jnp.ndarray
-
-  def __post_init__(self):
-    if hasattr(self.x, 'dtype'):
-      if not self.x.dtype == self.y.dtype == self.z.dtype:
-        raise ValueError(
-            f'Type mismatch: {self.x.dtype}, {self.y.dtype}, {self.z.dtype}'
-        )
-      if not self.x.shape == self.y.shape == self.z.shape:
-        raise ValueError(
-            f'Shape mismatch: {self.x.shape}, {self.y.shape}, {self.z.shape}'
-        )
-
-  def __add__(self, other: Self) -> Self:
-    return jax.tree.map(lambda x, y: x + y, self, other)
-
-  def __sub__(self, other: Self) -> Self:
-    return jax.tree.map(lambda x, y: x - y, self, other)
-
-  def __mul__(self, other: Float) -> Self:
-    return jax.tree.map(lambda x: x * other, self)
-
-  def __rmul__(self, other: Float) -> Self:
-    return self * other
-
-  def __truediv__(self, other: Float) -> Self:
-    return jax.tree.map(lambda x: x / other, self)
-
-  def __neg__(self) -> Self:
-    return jax.tree.map(lambda x: -x, self)
-
-  def __pos__(self) -> Self:
-    return jax.tree.map(lambda x: x, self)
-
-  def cross(self, other: Self) -> Self:
-    """Compute cross product between 'self' and 'other'."""
-    new_x = self.y * other.z - self.z * other.y
-    new_y = self.z * other.x - self.x * other.z
-    new_z = self.x * other.y - self.y * other.x
-    return Vec3Array(new_x, new_y, new_z)
-
-  def dot(self, other: Self) -> Float:
-    """Compute dot product between 'self' and 'other'."""
-    return self.x * other.x + self.y * other.y + self.z * other.z
-
-  def norm(self, epsilon: float = 1e-6) -> Float:
-    """Compute Norm of Vec3Array, clipped to epsilon."""
-    # To avoid NaN on the backward pass, we must use maximum before the sqrt
-    norm2 = self.dot(self)
-    if epsilon:
-      norm2 = jnp.maximum(norm2, epsilon**2)
-    return jnp.sqrt(norm2)
-
-  def norm2(self):
-    return self.dot(self)
-
-  def normalized(self, epsilon: float = 1e-6) -> Self:
-    """Return unit vector with optional clipping."""
-    return self / self.norm(epsilon)
-
-  @classmethod
-  def zeros(cls, shape, dtype=jnp.float32):
-    """Return Vec3Array corresponding to zeros of given shape."""
-    return cls(
-        jnp.zeros(shape, dtype),
-        jnp.zeros(shape, dtype),
-        jnp.zeros(shape, dtype),
-    )  # pytype: disable=wrong-arg-count  # trace-all-classes
-
-  def to_array(self) -> jnp.ndarray:
-    return jnp.stack([self.x, self.y, self.z], axis=-1)
-
-  @classmethod
-  def from_array(cls, array):
-    return cls(*utils.unstack(array))
-
-  def __getstate__(self):
-    return (
-        VERSION,
-        [np.asarray(self.x), np.asarray(self.y), np.asarray(self.z)],
-    )
-
-  def __setstate__(self, state):
-    version, state = state
-    del version
-    for i, letter in enumerate('xyz'):
-      object.__setattr__(self, letter, state[i])
-
-
-def square_euclidean_distance(
-    vec1: Vec3Array, vec2: Vec3Array, epsilon: float = 1e-6
-) -> Float:
-  """Computes square of euclidean distance between 'vec1' and 'vec2'.
-
-  Args:
-    vec1: Vec3Array to compute  distance to
-    vec2: Vec3Array to compute  distance from, should be broadcast compatible
-      with 'vec1'
-    epsilon: distance is clipped from below to be at least epsilon
-
-  Returns:
-    Array of square euclidean distances;
-    shape will be result of broadcasting 'vec1' and 'vec2'
-  """
-  difference = vec1 - vec2
-  distance = difference.dot(difference)
-  if epsilon:
-    distance = jnp.maximum(distance, epsilon)
-  return distance
-
-
-def dot(vector1: Vec3Array, vector2: Vec3Array) -> Float:
-  return vector1.dot(vector2)
-
-
-def cross(vector1: Vec3Array, vector2: Vec3Array) -> Float:
-  return vector1.cross(vector2)
-
-
-def norm(vector: Vec3Array, epsilon: float = 1e-6) -> Float:
-  return vector.norm(epsilon)
-
-
-def normalized(vector: Vec3Array, epsilon: float = 1e-6) -> Vec3Array:
-  return vector.normalized(epsilon)
-
-
-def euclidean_distance(
-    vec1: Vec3Array, vec2: Vec3Array, epsilon: float = 1e-6
-) -> Float:
-  """Computes euclidean distance between 'vec1' and 'vec2'.
-
-  Args:
-    vec1: Vec3Array to compute euclidean distance to
-    vec2: Vec3Array to compute euclidean distance from, should be broadcast
-      compatible with 'vec1'
-    epsilon: distance is clipped from below to be at least epsilon
-
-  Returns:
-    Array of euclidean distances;
-    shape will be result of broadcasting 'vec1' and 'vec2'
-  """
-  distance_sq = square_euclidean_distance(vec1, vec2, epsilon**2)
-  distance = jnp.sqrt(distance_sq)
-  return distance
-
-
-def dihedral_angle(
-    a: Vec3Array, b: Vec3Array, c: Vec3Array, d: Vec3Array
-) -> Float:
-  """Computes torsion angle for a quadruple of points.
-
-  For points (a, b, c, d), this is the angle between the planes defined by
-  points (a, b, c) and (b, c, d). It is also known as the dihedral angle.
-
-  Arguments:
-    a: A Vec3Array of coordinates.
-    b: A Vec3Array of coordinates.
-    c: A Vec3Array of coordinates.
-    d: A Vec3Array of coordinates.
-
-  Returns:
-    A tensor of angles in radians: [-pi, pi].
-  """
-  v1 = a - b
-  v2 = b - c
-  v3 = d - c
-
-  c1 = v1.cross(v2)
-  c2 = v3.cross(v2)
-  c3 = c2.cross(c1)
-
-  v2_mag = v2.norm()
-  return jnp.arctan2(c3.dot(v2), v2_mag * c1.dot(c2))
-
-
-def random_gaussian_vector(shape, key, dtype=jnp.float32) -> Vec3Array:
-  vec_array = jax.random.normal(key, shape + (3,), dtype)
-  return Vec3Array.from_array(vec_array)
diff --git a/src/alphafold3/model/atom_layout/atom_layout.py b/src/alphafold3/model/atom_layout/atom_layout.py
deleted file mode 100644
index 541fe7f8c867b316c3abd645d3e9f26b58ed684c..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/atom_layout/atom_layout.py
+++ /dev/null
@@ -1,1095 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Helper functions for different atom layouts and conversion between them."""
-
-import collections
-from collections.abc import Mapping, Sequence
-import dataclasses
-import types
-from typing import Any, TypeAlias
-
-from alphafold3 import structure
-from alphafold3.constants import atom_types
-from alphafold3.constants import chemical_component_sets
-from alphafold3.constants import chemical_components
-from alphafold3.constants import mmcif_names
-from alphafold3.constants import residue_names
-from alphafold3.data.tools import rdkit_utils
-from alphafold3.structure import chemical_components as struc_chem_comps
-import jax.numpy as jnp
-import numpy as np
-from rdkit import Chem
-
-
-xnp_ndarray: TypeAlias = np.ndarray | jnp.ndarray  # pylint: disable=invalid-name
-NumpyIndex: TypeAlias = Any
-
-
-@dataclasses.dataclass(frozen=True)
-class AtomLayout:
-  """Atom layout in a fixed shape (usually 1-dim or 2-dim).
-
-  Examples for atom layouts are atom37, atom14, and similar.
-  All members are np.ndarrays with the same shape, e.g.
-  - [num_atoms]
-  - [num_residues, max_atoms_per_residue]
-  - [num_fragments, max_fragments_per_residue]
-  All string arrays should have dtype=object to avoid pitfalls with Numpy's
-  fixed-size strings
-
-  Attributes:
-    atom_name: np.ndarray of str: atom names (e.g. 'CA', 'NE2'), padding
-      elements have an empty string (''), None or any other value, that maps to
-      False for .astype(bool). mmCIF field: _atom_site.label_atom_id.
-    res_id: np.ndarray of int: residue index (usually starting from 1) padding
-      elements can have an arbitrary value. mmCIF field:
-      _atom_site.label_seq_id.
-    chain_id: np.ndarray of str: chain names (e.g. 'A', 'B') padding elements
-      can have an arbitrary value. mmCIF field: _atom_site.label_seq_id.
-    atom_element: np.ndarray of str: atom elements (e.g. 'C', 'N', 'O'), padding
-      elements have an empty string (''), None or any other value, that maps to
-      False for .astype(bool). mmCIF field: _atom_site.type_symbol.
-    res_name: np.ndarray of str: residue names (e.g. 'ARG', 'TRP') padding
-      elements can have an arbitrary value. mmCIF field:
-      _atom_site.label_comp_id.
-    chain_type: np.ndarray of str: chain types (e.g. 'polypeptide(L)'). padding
-      elements can have an arbitrary value. mmCIF field: _entity_poly.type OR
-      _entity.type (for non-polymers).
-    shape: shape of the layout (just returns atom_name.shape)
-  """
-
-  atom_name: np.ndarray
-  res_id: np.ndarray
-  chain_id: np.ndarray
-  atom_element: np.ndarray | None = None
-  res_name: np.ndarray | None = None
-  chain_type: np.ndarray | None = None
-
-  def __post_init__(self):
-    """Assert all arrays have the same shape."""
-    attribute_names = (
-        'atom_name',
-        'atom_element',
-        'res_name',
-        'res_id',
-        'chain_id',
-        'chain_type',
-    )
-    _assert_all_arrays_have_same_shape(
-        obj=self,
-        expected_shape=self.atom_name.shape,
-        attribute_names=attribute_names,
-    )
-    # atom_name must have dtype object, such that we can convert it to bool to
-    # obtain the mask
-    if self.atom_name.dtype != object:
-      raise ValueError(
-          'atom_name must have dtype object, such that it can '
-          'be converted converted to bool to obtain the mask'
-      )
-
-  def __getitem__(self, key: NumpyIndex) -> 'AtomLayout':
-    return AtomLayout(
-        atom_name=self.atom_name[key],
-        res_id=self.res_id[key],
-        chain_id=self.chain_id[key],
-        atom_element=(
-            self.atom_element[key] if self.atom_element is not None else None
-        ),
-        res_name=(self.res_name[key] if self.res_name is not None else None),
-        chain_type=(
-            self.chain_type[key] if self.chain_type is not None else None
-        ),
-    )
-
-  def __eq__(self, other: 'AtomLayout') -> bool:
-    if not np.array_equal(self.atom_name, other.atom_name):
-      return False
-
-    mask = self.atom_name.astype(bool)
-    # Check essential fields.
-    for field in ('res_id', 'chain_id'):
-      my_arr = getattr(self, field)
-      other_arr = getattr(other, field)
-      if not np.array_equal(my_arr[mask], other_arr[mask]):
-        return False
-
-    # Check optional fields.
-    for field in ('atom_element', 'res_name', 'chain_type'):
-      my_arr = getattr(self, field)
-      other_arr = getattr(other, field)
-      if (
-          my_arr is not None
-          and other_arr is not None
-          and not np.array_equal(my_arr[mask], other_arr[mask])
-      ):
-        return False
-
-    return True
-
-  def copy_and_pad_to(self, shape: tuple[int, ...]) -> 'AtomLayout':
-    """Copies and pads the layout to the requested shape.
-
-    Args:
-      shape: new shape for the atom layout
-
-    Returns:
-      a copy of the atom layout padded to the requested shape
-
-    Raises:
-      ValueError: incompatible shapes.
-    """
-    if len(shape) != len(self.atom_name.shape):
-      raise ValueError(
-          f'Incompatible shape {shape}. Current layout has shape {self.shape}.'
-      )
-    if any(new < old for old, new in zip(self.atom_name.shape, shape)):
-      raise ValueError(
-          "Can't pad to a smaller shape. Current layout has shape "
-          f'{self.shape} and you requested shape {shape}.'
-      )
-    pad_width = [
-        (0, new - old) for old, new in zip(self.atom_name.shape, shape)
-    ]
-    pad_val = np.array('', dtype=object)
-    return AtomLayout(
-        atom_name=np.pad(self.atom_name, pad_width, constant_values=pad_val),
-        res_id=np.pad(self.res_id, pad_width, constant_values=0),
-        chain_id=np.pad(self.chain_id, pad_width, constant_values=pad_val),
-        atom_element=(
-            np.pad(self.atom_element, pad_width, constant_values=pad_val)
-            if self.atom_element is not None
-            else None
-        ),
-        res_name=(
-            np.pad(self.res_name, pad_width, constant_values=pad_val)
-            if self.res_name is not None
-            else None
-        ),
-        chain_type=(
-            np.pad(self.chain_type, pad_width, constant_values=pad_val)
-            if self.chain_type is not None
-            else None
-        ),
-    )
-
-  def to_array(self) -> np.ndarray:
-    """Stacks the fields to a numpy array with shape (6, <layout_shape>).
-
-    Creates a pure numpy array of type `object` by stacking the 6 fields of the
-    AtomLayout, i.e. (atom_name, atom_element, res_name, res_id, chain_id,
-    chain_type). This method together with from_array() provides an easy way to
-    apply pure numpy methods like np.concatenate() to `AtomLayout`s.
-
-    Returns:
-      np.ndarray of object with shape (6, <layout_shape>), e.g.
-      array([['N', 'CA', 'C', ..., 'CB', 'CG', 'CD'],
-       ['N', 'C', 'C', ..., 'C', 'C', 'C'],
-       ['LEU', 'LEU', 'LEU', ..., 'PRO', 'PRO', 'PRO'],
-       [1, 1, 1, ..., 403, 403, 403],
-       ['A', 'A', 'A', ..., 'D', 'D', 'D'],
-       ['polypeptide(L)', 'polypeptide(L)', ..., 'polypeptide(L)']],
-      dtype=object)
-    """
-    if (
-        self.atom_element is None
-        or self.res_name is None
-        or self.chain_type is None
-    ):
-      raise ValueError('All optional fields need to be present.')
-
-    return np.stack(dataclasses.astuple(self), axis=0)
-
-  @classmethod
-  def from_array(cls, arr: np.ndarray) -> 'AtomLayout':
-    """Creates an AtomLayout object from a numpy array with shape (6, ...).
-
-    see also to_array()
-    Args:
-      arr: np.ndarray of object with shape (6, <layout_shape>)
-
-    Returns:
-      AtomLayout object with shape (<layout_shape>)
-    """
-    if arr.shape[0] != 6:
-      raise ValueError(
-          'Given array must have shape (6, ...) to match the 6 fields of '
-          'AtomLayout (atom_name, atom_element, res_name, res_id, chain_id, '
-          f'chain_type). Your array has {arr.shape=}'
-      )
-    return cls(*arr)
-
-  @property
-  def shape(self) -> tuple[int, ...]:
-    return self.atom_name.shape
-
-
-@dataclasses.dataclass(frozen=True)
-class Residues:
-  """List of residues with meta data.
-
-  Attributes:
-    res_name: np.ndarray of str [num_res], e.g. 'ARG', 'TRP'
-    res_id: np.ndarray of int [num_res]
-    chain_id: np.ndarray of str [num_res], e.g. 'A', 'B'
-    chain_type: np.ndarray of str [num_res], e.g. 'polypeptide(L)'
-    is_start_terminus: np.ndarray of bool [num_res]
-    is_end_terminus: np.ndarray of bool [num_res]
-    deprotonation: (optional) np.ndarray of set() [num_res], e.g. {'HD1', 'HE2'}
-    smiles_string: (optional) np.ndarray of str [num_res], e.g. 'Cc1ccccc1'
-    shape: shape of the layout (just returns res_name.shape)
-  """
-
-  res_name: np.ndarray
-  res_id: np.ndarray
-  chain_id: np.ndarray
-  chain_type: np.ndarray
-  is_start_terminus: np.ndarray
-  is_end_terminus: np.ndarray
-  deprotonation: np.ndarray | None = None
-  smiles_string: np.ndarray | None = None
-
-  def __post_init__(self):
-    """Assert all arrays are 1D have the same shape."""
-    attribute_names = (
-        'res_name',
-        'res_id',
-        'chain_id',
-        'chain_type',
-        'is_start_terminus',
-        'is_end_terminus',
-        'deprotonation',
-        'smiles_string',
-    )
-    _assert_all_arrays_have_same_shape(
-        obj=self,
-        expected_shape=(self.res_name.shape[0],),
-        attribute_names=attribute_names,
-    )
-
-  def __getitem__(self, key: NumpyIndex) -> 'Residues':
-    return Residues(
-        res_name=self.res_name[key],
-        res_id=self.res_id[key],
-        chain_id=self.chain_id[key],
-        chain_type=self.chain_type[key],
-        is_start_terminus=self.is_start_terminus[key],
-        is_end_terminus=self.is_end_terminus[key],
-        deprotonation=(
-            self.deprotonation[key] if self.deprotonation is not None else None
-        ),
-        smiles_string=(
-            self.smiles_string[key] if self.smiles_string is not None else None
-        ),
-    )
-
-  def __eq__(self, other: 'Residues') -> bool:
-    return all(
-        np.array_equal(getattr(self, field.name), getattr(other, field.name))
-        for field in dataclasses.fields(self)
-    )
-
-  @property
-  def shape(self) -> tuple[int, ...]:
-    return self.res_name.shape
-
-
-@dataclasses.dataclass(frozen=True)
-class GatherInfo:
-  """Gather indices to translate from one atom layout to another.
-
-  All members are np or jnp ndarray (usually 1-dim or 2-dim) with the same
-  shape, e.g.
-  - [num_atoms]
-  - [num_residues, max_atoms_per_residue]
-  - [num_fragments, max_fragments_per_residue]
-
-  Attributes:
-    gather_idxs: np or jnp ndarray of int: gather indices into a flattened array
-    gather_mask: np or jnp ndarray of bool: mask for resulting array
-    input_shape: np or jnp ndarray of int: the shape of the unflattened input
-      array
-    shape: output shape. Just returns gather_idxs.shape
-  """
-
-  gather_idxs: xnp_ndarray
-  gather_mask: xnp_ndarray
-  input_shape: xnp_ndarray
-
-  def __post_init__(self):
-    if self.gather_mask.shape != self.gather_idxs.shape:
-      raise ValueError(
-          'All arrays must have the same shape. Got\n'
-          f'gather_idxs.shape = {self.gather_idxs.shape}\n'
-          f'gather_mask.shape = {self.gather_mask.shape}\n'
-      )
-
-  def __getitem__(self, key: NumpyIndex) -> 'GatherInfo':
-    return GatherInfo(
-        gather_idxs=self.gather_idxs[key],
-        gather_mask=self.gather_mask[key],
-        input_shape=self.input_shape,
-    )
-
-  @property
-  def shape(self) -> tuple[int, ...]:
-    return self.gather_idxs.shape
-
-  def as_np_or_jnp(self, xnp: types.ModuleType) -> 'GatherInfo':
-    return GatherInfo(
-        gather_idxs=xnp.array(self.gather_idxs),
-        gather_mask=xnp.array(self.gather_mask),
-        input_shape=xnp.array(self.input_shape),
-    )
-
-  def as_dict(
-      self,
-      key_prefix: str | None = None,
-  ) -> dict[str, xnp_ndarray]:
-    prefix = f'{key_prefix}:' if key_prefix else ''
-    return {
-        prefix + 'gather_idxs': self.gather_idxs,
-        prefix + 'gather_mask': self.gather_mask,
-        prefix + 'input_shape': self.input_shape,
-    }
-
-  @classmethod
-  def from_dict(
-      cls,
-      d: Mapping[str, xnp_ndarray],
-      key_prefix: str | None = None,
-  ) -> 'GatherInfo':
-    """Creates GatherInfo from a given dictionary."""
-    prefix = f'{key_prefix}:' if key_prefix else ''
-    return cls(
-        gather_idxs=d[prefix + 'gather_idxs'],
-        gather_mask=d[prefix + 'gather_mask'],
-        input_shape=d[prefix + 'input_shape'],
-    )
-
-
-def fill_in_optional_fields(
-    minimal_atom_layout: AtomLayout,
-    reference_atoms: AtomLayout,
-) -> AtomLayout:
-  """Fill in the optional fields (atom_element, res_name, chain_type).
-
-  Extracts the optional fields (atom_element, res_name, chain_type) from a
-  flat reference layout and fills them into the fields from this layout.
-
-  Args:
-    minimal_atom_layout: An AtomLayout that only contains the essential fields
-      (atom_name, res_id, chain_id).
-    reference_atoms: A flat layout that contains all fields for all atoms.
-
-  Returns:
-    An AtomLayout that contains all fields.
-
-  Raises:
-    ValueError: Reference atoms layout is not flat.
-    ValueError: Missing atoms in reference.
-  """
-  if len(reference_atoms.shape) > 1:
-    raise ValueError('Only flat layouts are supported as reference.')
-  ref_to_self = compute_gather_idxs(
-      source_layout=reference_atoms, target_layout=minimal_atom_layout
-  )
-  atom_mask = minimal_atom_layout.atom_name.astype(bool)
-  missing_atoms_mask = atom_mask & ~ref_to_self.gather_mask
-  if np.any(missing_atoms_mask):
-    raise ValueError(
-        f'{np.sum(missing_atoms_mask)} missing atoms in reference: '
-        f'{minimal_atom_layout[missing_atoms_mask]}'
-    )
-
-  def _convert_str_array(gather: GatherInfo, arr: np.ndarray):
-    output = arr[gather.gather_idxs]
-    output[~gather.gather_mask] = ''
-    return output
-
-  return dataclasses.replace(
-      minimal_atom_layout,
-      atom_element=_convert_str_array(
-          ref_to_self, reference_atoms.atom_element
-      ),
-      res_name=_convert_str_array(ref_to_self, reference_atoms.res_name),
-      chain_type=_convert_str_array(ref_to_self, reference_atoms.chain_type),
-  )
-
-
-def guess_deprotonation(residues: Residues) -> Residues:
-  """Convenience function to create a plausible deprotonation field.
-
-  Assumes a pH of 7 and always prefers HE2 over HD1 for HIS.
-  Args:
-    residues: a Residues object without a depronotation field
-
-  Returns:
-    a Residues object with a depronotation field
-  """
-  num_residues = residues.res_name.shape[0]
-  deprotonation = np.empty(num_residues, dtype=object)
-  deprotonation_at_ph7 = {
-      'ASP': 'HD2',
-      'GLU': 'HE2',
-      'HIS': 'HD1',
-  }
-  for idx, res_name in enumerate(residues.res_name):
-    deprotonation[idx] = set()
-    if res_name in deprotonation_at_ph7:
-      deprotonation[idx].add(deprotonation_at_ph7[res_name])
-    if residues.is_end_terminus[idx]:
-      deprotonation[idx].add('HXT')
-
-  return dataclasses.replace(residues, deprotonation=deprotonation)
-
-
-def atom_layout_from_structure(
-    struct: structure.Structure,
-    *,
-    fix_non_standard_polymer_res: bool = False,
-) -> AtomLayout:
-  """Extract AtomLayout from a Structure."""
-
-  if not fix_non_standard_polymer_res:
-    return AtomLayout(
-        atom_name=np.array(struct.atom_name, dtype=object),
-        atom_element=np.array(struct.atom_element, dtype=object),
-        res_name=np.array(struct.res_name, dtype=object),
-        res_id=np.array(struct.res_id, dtype=int),
-        chain_id=np.array(struct.chain_id, dtype=object),
-        chain_type=np.array(struct.chain_type, dtype=object),
-    )
-
-  # Target lists.
-  target_atom_names = []
-  target_atom_elements = []
-  target_res_ids = []
-  target_res_names = []
-  target_chain_ids = []
-  target_chain_types = []
-
-  for atom in struct.iter_atoms():
-    target_atom_names.append(atom['atom_name'])
-    target_atom_elements.append(atom['atom_element'])
-    target_res_ids.append(atom['res_id'])
-    target_chain_ids.append(atom['chain_id'])
-    target_chain_types.append(atom['chain_type'])
-    if mmcif_names.is_standard_polymer_type(atom['chain_type']):
-      fixed_res_name = mmcif_names.fix_non_standard_polymer_res(
-          res_name=atom['res_name'], chain_type=atom['chain_type']
-      )
-      target_res_names.append(fixed_res_name)
-    else:
-      target_res_names.append(atom['res_name'])
-
-  return AtomLayout(
-      atom_name=np.array(target_atom_names, dtype=object),
-      atom_element=np.array(target_atom_elements, dtype=object),
-      res_name=np.array(target_res_names, dtype=object),
-      res_id=np.array(target_res_ids, dtype=int),
-      chain_id=np.array(target_chain_ids, dtype=object),
-      chain_type=np.array(target_chain_types, dtype=object),
-  )
-
-
-def residues_from_structure(
-    struct: structure.Structure,
-    *,
-    include_missing_residues: bool = True,
-    fix_non_standard_polymer_res: bool = False,
-) -> Residues:
-  """Create a Residues object from a Structure object."""
-
-  def _get_smiles(res_name):
-    """Get SMILES string from chemical components."""
-    smiles = None
-    if (
-        struct.chemical_components_data is not None
-        and struct.chemical_components_data.chem_comp is not None
-        and struct.chemical_components_data.chem_comp.get(res_name)
-    ):
-      smiles = struct.chemical_components_data.chem_comp[res_name].pdbx_smiles
-    return smiles
-
-  res_names_per_chain = struct.chain_res_name_sequence(
-      include_missing_residues=include_missing_residues,
-      fix_non_standard_polymer_res=fix_non_standard_polymer_res,
-  )
-  res_name = []
-  res_id = []
-  chain_id = []
-  chain_type = []
-  smiles = []
-  is_start_terminus = []
-  for c in struct.iter_chains():
-    if include_missing_residues:
-      this_res_ids = [id for (_, id) in struct.all_residues[c['chain_id']]]
-    else:
-      this_res_ids = [
-          r['res_id']
-          for r in struct.iter_residues()
-          if r['chain_id'] == c['chain_id']
-      ]
-    fixed_res_names = res_names_per_chain[c['chain_id']]
-    assert len(this_res_ids) == len(
-        fixed_res_names
-    ), f'{len(this_res_ids)} != {len(fixed_res_names)}'
-    this_start_res_id = min(min(this_res_ids), 1)
-    this_is_start_terminus = [r == this_start_res_id for r in this_res_ids]
-    smiles.extend([_get_smiles(res_name) for res_name in fixed_res_names])
-    num_res = len(fixed_res_names)
-    res_name.extend(fixed_res_names)
-    res_id.extend(this_res_ids)
-    chain_id.extend([c['chain_id']] * num_res)
-    chain_type.extend([c['chain_type']] * num_res)
-    is_start_terminus.extend(this_is_start_terminus)
-  res_name = np.array(res_name, dtype=object)
-  res_id = np.array(res_id, dtype=int)
-  chain_id = np.array(chain_id, dtype=object)
-  chain_type = np.array(chain_type, dtype=object)
-  smiles = np.array(smiles, dtype=object)
-  is_start_terminus = np.array(is_start_terminus, dtype=bool)
-
-  res_uid_to_idx = {
-      uid: idx for idx, uid in enumerate(zip(chain_id, res_id, strict=True))
-  }
-
-  # Start terminus indicates whether residue index is 1 and chain is polymer.
-  is_polymer = np.isin(chain_type, tuple(mmcif_names.POLYMER_CHAIN_TYPES))
-  is_start_terminus = is_start_terminus & is_polymer
-
-  # Start also indicates whether amino acid is attached to H2 or proline to H.
-  start_terminus_atom_index = np.nonzero(
-      (struct.chain_type == mmcif_names.PROTEIN_CHAIN)
-      & (
-          (struct.atom_name == 'H2')
-          | ((struct.atom_name == 'H') & (struct.res_name == 'PRO'))
-      )
-  )[0]
-
-  # Translate atom idx to residue idx to assign start terminus.
-  for atom_idx in start_terminus_atom_index:
-    res_uid = (struct.chain_id[atom_idx], struct.res_id[atom_idx])
-    res_idx = res_uid_to_idx[res_uid]
-    is_start_terminus[res_idx] = True
-
-  # Infer end terminus: Check for OXT, or in case of
-  # include_missing_residues==True for the last residue of the chain.
-  num_all_residues = res_name.shape[0]
-  is_end_terminus = np.zeros(num_all_residues, dtype=bool)
-  end_term_atom_idxs = np.nonzero(struct.atom_name == 'OXT')[0]
-  for atom_idx in end_term_atom_idxs:
-    res_uid = (struct.chain_id[atom_idx], struct.res_id[atom_idx])
-    res_idx = res_uid_to_idx[res_uid]
-    is_end_terminus[res_idx] = True
-
-  if include_missing_residues:
-    for idx in range(num_all_residues - 1):
-      if is_polymer[idx] and chain_id[idx] != chain_id[idx + 1]:
-        is_end_terminus[idx] = True
-    if (num_all_residues > 0) and is_polymer[-1]:
-      is_end_terminus[-1] = True
-
-  # Infer (de-)protonation: Only if hydrogens are given.
-  num_hydrogens = np.sum(
-      (struct.atom_element == 'H') & (struct.chain_type == 'polypeptide(L)')
-  )
-  if num_hydrogens > 0:
-    deprotonation = np.empty(num_all_residues, dtype=object)
-    all_atom_uids = set(
-        zip(struct.chain_id, struct.res_id, struct.atom_name, strict=True)
-    )
-    for idx in range(num_all_residues):
-      deprotonation[idx] = set()
-      check_hydrogens = set()
-      if is_end_terminus[idx]:
-        check_hydrogens.add('HXT')
-      if res_name[idx] in atom_types.PROTONATION_HYDROGENS:
-        check_hydrogens.update(atom_types.PROTONATION_HYDROGENS[res_name[idx]])
-      for hydrogen in check_hydrogens:
-        if (chain_id[idx], res_id[idx], hydrogen) not in all_atom_uids:
-          deprotonation[idx].add(hydrogen)
-  else:
-    deprotonation = None
-
-  return Residues(
-      res_name=res_name,
-      res_id=res_id,
-      chain_id=chain_id,
-      chain_type=chain_type,
-      is_start_terminus=is_start_terminus.astype(bool),
-      is_end_terminus=is_end_terminus,
-      deprotonation=deprotonation,
-      smiles_string=smiles,
-  )
-
-
-def get_link_drop_atoms(
-    res_name: str,
-    chain_type: str,
-    *,
-    is_start_terminus: bool,
-    is_end_terminus: bool,
-    bonded_atoms: set[str],
-    drop_ligand_leaving_atoms: bool = False,
-) -> set[str]:
-  """Returns set of atoms that are dropped when this res_name gets linked.
-
-  Args:
-    res_name: residue name, e.g. 'ARG'
-    chain_type: chain_type, e.g. 'polypeptide(L)'
-    is_start_terminus: whether the residue is the n-terminus
-    is_end_terminus: whether the residue is the c-terminus
-    bonded_atoms: Names of atoms coming off this residue.
-    drop_ligand_leaving_atoms: Flag to switch on/off leaving atoms for ligands.
-
-  Returns:
-    Set of atoms that are dropped when this amino acid gets linked.
-  """
-  drop_atoms = set()
-  if chain_type == mmcif_names.PROTEIN_CHAIN:
-    if res_name == 'PRO':
-      if not is_start_terminus:
-        drop_atoms.update({'H', 'H2', 'H3'})
-      if not is_end_terminus:
-        drop_atoms.update({'OXT', 'HXT'})
-    else:
-      if not is_start_terminus:
-        drop_atoms.update({'H2', 'H3'})
-      if not is_end_terminus:
-        drop_atoms.update({'OXT', 'HXT'})
-  elif chain_type in mmcif_names.NUCLEIC_ACID_CHAIN_TYPES:
-    if not is_start_terminus:
-      drop_atoms.update({'OP3'})
-  elif (
-      drop_ligand_leaving_atoms and chain_type in mmcif_names.LIGAND_CHAIN_TYPES
-  ):
-    if res_name in {
-        *chemical_component_sets.GLYCAN_OTHER_LIGANDS,
-        *chemical_component_sets.GLYCAN_LINKING_LIGANDS,
-    }:
-      if 'O1' not in bonded_atoms:
-        drop_atoms.update({'O1'})
-  return drop_atoms
-
-
-def get_bonded_atoms(
-    polymer_ligand_bonds: AtomLayout,
-    ligand_ligand_bonds: AtomLayout,
-    res_id: int,
-    chain_id: str,
-) -> set[str]:
-  """Finds the res_name on the opposite end of the bond, if a bond exists.
-
-  Args:
-    polymer_ligand_bonds: Bond information for polymer-ligand pairs.
-    ligand_ligand_bonds: Bond information for ligand-ligand pairs.
-    res_id: residue id in question.
-    chain_id: chain id of residue in question.
-
-  Returns:
-    res_name of bonded atom.
-  """
-  bonded_atoms = set()
-  if polymer_ligand_bonds:
-    # Filter before searching to speed this up.
-    bond_idx = np.logical_and(
-        polymer_ligand_bonds.res_id == res_id,
-        polymer_ligand_bonds.chain_id == chain_id,
-    ).any(axis=1)
-    relevant_polymer_bonds = polymer_ligand_bonds[bond_idx]
-    for atom_names, res_ids, chain_ids in zip(
-        relevant_polymer_bonds.atom_name,
-        relevant_polymer_bonds.res_id,
-        relevant_polymer_bonds.chain_id,
-    ):
-      if (res_ids[0], chain_ids[0]) == (res_id, chain_id):
-        bonded_atoms.add(atom_names[0])
-      elif (res_ids[1], chain_ids[1]) == (res_id, chain_id):
-        bonded_atoms.add(atom_names[1])
-  if ligand_ligand_bonds:
-    bond_idx = np.logical_and(
-        ligand_ligand_bonds.res_id == res_id,
-        ligand_ligand_bonds.chain_id == chain_id,
-    ).any(axis=1)
-    relevant_ligand_bonds = ligand_ligand_bonds[bond_idx]
-    for atom_names, res_ids, chain_ids in zip(
-        relevant_ligand_bonds.atom_name,
-        relevant_ligand_bonds.res_id,
-        relevant_ligand_bonds.chain_id,
-    ):
-      if (res_ids[0], chain_ids[0]) == (res_id, chain_id):
-        bonded_atoms.add(atom_names[0])
-      elif (res_ids[1], chain_ids[1]) == (res_id, chain_id):
-        bonded_atoms.add(atom_names[1])
-  return bonded_atoms
-
-
-def make_flat_atom_layout(
-    residues: Residues,
-    ccd: chemical_components.Ccd,
-    polymer_ligand_bonds: AtomLayout | None = None,
-    ligand_ligand_bonds: AtomLayout | None = None,
-    *,
-    with_hydrogens: bool = False,
-    skip_unk_residues: bool = True,
-    drop_ligand_leaving_atoms: bool = False,
-) -> AtomLayout:
-  """Make a flat atom layout for given residues.
-
-  Create a flat layout from a `Residues` object. The required atoms for each
-  amino acid type are taken from the CCD, hydrogens and oxygens are dropped to
-  make the linked residues. Terminal OXT's and protonation state for the
-  hydrogens come from the `Residues` object.
-
-  Args:
-    residues: a `Residues` object.
-    ccd: The chemical components dictionary.
-    polymer_ligand_bonds: Bond information for polymer-ligand pairs.
-    ligand_ligand_bonds: Bond information for ligand-ligand pairs.
-    with_hydrogens: whether to create hydrogens
-    skip_unk_residues: whether to skip 'UNK' resides -- default is True to be
-      compatible with the rest of AlphaFold that does not predict atoms for
-      unknown residues
-    drop_ligand_leaving_atoms: Flag to switch on/ off leaving atoms for ligands.
-
-  Returns:
-    an `AtomLayout` object
-  """
-  num_res = residues.res_name.shape[0]
-
-  # Target lists.
-  target_atom_names = []
-  target_atom_elements = []
-  target_res_ids = []
-  target_res_names = []
-  target_chain_ids = []
-  target_chain_types = []
-
-  for idx in range(num_res):
-    # skip 'UNK' residues if requested
-    if (
-        skip_unk_residues
-        and residues.res_name[idx] in residue_names.UNKNOWN_TYPES
-    ):
-      continue
-
-    # Get the atoms for this residue type from CCD.
-    if ccd.get(residues.res_name[idx]):
-      res_atoms = struc_chem_comps.get_all_atoms_in_entry(
-          ccd=ccd, res_name=residues.res_name[idx]
-      )
-      atom_names_elements = list(
-          zip(
-              res_atoms['_chem_comp_atom.atom_id'],
-              res_atoms['_chem_comp_atom.type_symbol'],
-              strict=True,
-          )
-      )
-    elif residues.smiles_string[idx]:
-      # Get atoms from RDKit via SMILES.
-      mol = Chem.MolFromSmiles(residues.smiles_string[idx])
-      if mol is None:
-        raise ValueError(
-            f'Failed to construct RDKit Mol for {residues.res_name[idx]} from'
-            f' SMILES string: {residues.smiles_string[idx]} . This is likely'
-            ' due to an issue with the SMILES string. Note that the userCCD'
-            ' input format provides an alternative way to define custom'
-            ' molecules directly without RDKit or SMILES.'
-        )
-      mol = rdkit_utils.assign_atom_names_from_graph(mol)
-      atom_names_elements = [
-          (a.GetProp('atom_name'), a.GetSymbol()) for a in mol.GetAtoms()
-      ]
-    else:
-      raise ValueError(
-          f'{residues.res_name[idx]} not found in CCD and no SMILES string'
-      )
-
-    # Remove hydrogens if requested.
-    if not with_hydrogens:
-      atom_names_elements = [
-          (n, e) for n, e in atom_names_elements if (e != 'H' and e != 'D')
-      ]
-    bonded_atoms = get_bonded_atoms(
-        polymer_ligand_bonds,
-        ligand_ligand_bonds,
-        residues.res_id[idx],
-        residues.chain_id[idx],
-    )
-    # Connect the amino-acids, i.e. remove OXT, HXT and H2.
-    drop_atoms = get_link_drop_atoms(
-        res_name=residues.res_name[idx],
-        chain_type=residues.chain_type[idx],
-        is_start_terminus=residues.is_start_terminus[idx],
-        is_end_terminus=residues.is_end_terminus[idx],
-        bonded_atoms=bonded_atoms,
-        drop_ligand_leaving_atoms=drop_ligand_leaving_atoms,
-    )
-
-    # If deprotonation info is available, remove the specific atoms.
-    if residues.deprotonation is not None:
-      drop_atoms.update(residues.deprotonation[idx])
-
-    atom_names_elements = [
-        (n, e) for n, e in atom_names_elements if n not in drop_atoms
-    ]
-
-    # Append the found atoms to the target lists.
-    target_atom_names.extend([n for n, _ in atom_names_elements])
-    target_atom_elements.extend([e for _, e in atom_names_elements])
-    num_atoms = len(atom_names_elements)
-    target_res_names.extend([residues.res_name[idx]] * num_atoms)
-    target_res_ids.extend([residues.res_id[idx]] * num_atoms)
-    target_chain_ids.extend([residues.chain_id[idx]] * num_atoms)
-    target_chain_types.extend([residues.chain_type[idx]] * num_atoms)
-
-  return AtomLayout(
-      atom_name=np.array(target_atom_names, dtype=object),
-      atom_element=np.array(target_atom_elements, dtype=object),
-      res_name=np.array(target_res_names, dtype=object),
-      res_id=np.array(target_res_ids, dtype=int),
-      chain_id=np.array(target_chain_ids, dtype=object),
-      chain_type=np.array(target_chain_types, dtype=object),
-  )
-
-
-def compute_gather_idxs(
-    *,
-    source_layout: AtomLayout,
-    target_layout: AtomLayout,
-    fill_value: int = 0,
-) -> GatherInfo:
-  """Produce gather indices and mask to convert from source layout to target."""
-  source_uid_to_idx = {
-      uid: idx
-      for idx, uid in enumerate(
-          zip(
-              source_layout.chain_id.ravel(),
-              source_layout.res_id.ravel(),
-              source_layout.atom_name.ravel(),
-              strict=True,
-          )
-      )
-  }
-  gather_idxs = []
-  gather_mask = []
-  for uid in zip(
-      target_layout.chain_id.ravel(),
-      target_layout.res_id.ravel(),
-      target_layout.atom_name.ravel(),
-      strict=True,
-  ):
-    if uid in source_uid_to_idx:
-      gather_idxs.append(source_uid_to_idx[uid])
-      gather_mask.append(True)
-    else:
-      gather_idxs.append(fill_value)
-      gather_mask.append(False)
-  target_shape = target_layout.atom_name.shape
-  return GatherInfo(
-      gather_idxs=np.array(gather_idxs, dtype=int).reshape(target_shape),
-      gather_mask=np.array(gather_mask, dtype=bool).reshape(target_shape),
-      input_shape=np.array(source_layout.atom_name.shape),
-  )
-
-
-def convert(
-    gather_info: GatherInfo,
-    arr: xnp_ndarray,
-    *,
-    layout_axes: tuple[int, ...] = (0,),
-) -> xnp_ndarray:
-  """Convert an array from one atom layout to another."""
-  # Translate negative indices to the corresponding positives.
-  layout_axes = tuple(i if i >= 0 else i + arr.ndim for i in layout_axes)
-
-  # Ensure that layout_axes are continuous.
-  layout_axes_begin = layout_axes[0]
-  layout_axes_end = layout_axes[-1] + 1
-
-  if layout_axes != tuple(range(layout_axes_begin, layout_axes_end)):
-    raise ValueError(f'layout_axes must be continuous. Got {layout_axes}.')
-  layout_shape = arr.shape[layout_axes_begin:layout_axes_end]
-
-  # Ensure that the layout shape is compatible
-  # with the gather_info. I.e. the first axis size must be equal or greater
-  # than the gather_info.input_shape, and all subsequent axes sizes must match.
-  if (len(layout_shape) != gather_info.input_shape.size) or (
-      isinstance(gather_info.input_shape, np.ndarray)
-      and (
-          (layout_shape[0] < gather_info.input_shape[0])
-          or (np.any(layout_shape[1:] != gather_info.input_shape[1:]))
-      )
-  ):
-    raise ValueError(
-        'Input array layout axes are incompatible. You specified layout '
-        f'axes {layout_axes} with an input array of shape {arr.shape}, but '
-        f'the gather info expects shape {gather_info.input_shape}. '
-        'Your first axis size must be equal or greater than the '
-        'gather_info.input_shape, and all subsequent axes sizes must '
-        'match.'
-    )
-
-  # Compute the shape of the input array with flattened layout.
-  batch_shape = arr.shape[:layout_axes_begin]
-  features_shape = arr.shape[layout_axes_end:]
-  arr_flattened_shape = batch_shape + (np.prod(layout_shape),) + features_shape
-
-  # Flatten input array and perform the gather.
-  arr_flattened = arr.reshape(arr_flattened_shape)
-  if layout_axes_begin == 0:
-    out_arr = arr_flattened[gather_info.gather_idxs, ...]
-  elif layout_axes_begin == 1:
-    out_arr = arr_flattened[:, gather_info.gather_idxs, ...]
-  elif layout_axes_begin == 2:
-    out_arr = arr_flattened[:, :, gather_info.gather_idxs, ...]
-  elif layout_axes_begin == 3:
-    out_arr = arr_flattened[:, :, :, gather_info.gather_idxs, ...]
-  elif layout_axes_begin == 4:
-    out_arr = arr_flattened[:, :, :, :, gather_info.gather_idxs, ...]
-  else:
-    raise ValueError(
-        'Only 4 batch axes supported. If you need more, the code '
-        'is easy to extend.'
-    )
-
-  # Broadcast the mask and apply it.
-  broadcasted_mask_shape = (
-      (1,) * len(batch_shape)
-      + gather_info.gather_mask.shape
-      + (1,) * len(features_shape)
-  )
-  out_arr *= gather_info.gather_mask.reshape(broadcasted_mask_shape)
-  return out_arr
-
-
-def make_structure(
-    flat_layout: AtomLayout,
-    atom_coords: np.ndarray,
-    name: str,
-    *,
-    atom_b_factors: np.ndarray | None = None,
-    all_physical_residues: Residues | None = None,
-) -> structure.Structure:
-  """Returns a Structure from a flat layout and atom coordinates.
-
-  The provided flat_layout must be 1-dim and must not contain any padding
-  elements. The flat_layout.atom_name must conform to the OpenMM/CCD standard
-  and must not contain deuterium.
-
-  Args:
-    flat_layout: flat 1-dim AtomLayout without pading elements
-    atom_coords: np.ndarray of float, shape (num_atoms, 3)
-    name: str: the name (usually PDB id), e.g. '1uao'
-    atom_b_factors: np.ndarray of float, shape (num_atoms,) or None. If None,
-      they will be set to all zeros.
-    all_physical_residues: a Residues object that contains all physically
-      existing residues, i.e. also those residues that have no resolved atoms.
-      This is common in experimental structures, but also appears in predicted
-      structures for 'UNK' or other non-standard residue types, where the model
-      does not predict coordinates. This will be used to create the
-      `all_residues` field of the structure object.
-  """
-
-  if flat_layout.atom_name.ndim != 1 or not np.all(
-      flat_layout.atom_name.astype(bool)
-  ):
-    raise ValueError(
-        'flat_layout must be 1-dim and must not contain anypadding element'
-    )
-  if (
-      flat_layout.atom_element is None
-      or flat_layout.res_name is None
-      or flat_layout.chain_type is None
-  ):
-    raise ValueError('All optional fields must be present.')
-
-  if atom_b_factors is None:
-    atom_b_factors = np.zeros(atom_coords.shape[:-1])
-
-  if all_physical_residues is not None:
-    # Create the all_residues field from a Residues object
-    # (unfortunately there is no central place to keep the chain_types in
-    # the structure class, so we drop it here)
-    all_residues = collections.defaultdict(list)
-    for chain_id, res_id, res_name in zip(
-        all_physical_residues.chain_id,
-        all_physical_residues.res_id,
-        all_physical_residues.res_name,
-        strict=True,
-    ):
-      all_residues[chain_id].append((res_name, res_id))
-  else:
-    # Create the all_residues field from the flat_layout
-    all_residues = collections.defaultdict(list)
-    if flat_layout.chain_id.shape[0] > 0:
-      all_residues[flat_layout.chain_id[0]].append(
-          (flat_layout.res_name[0], flat_layout.res_id[0])
-      )
-      for i in range(1, flat_layout.shape[0]):
-        if (
-            flat_layout.chain_id[i] != flat_layout.chain_id[i - 1]
-            or flat_layout.res_name[i] != flat_layout.res_name[i - 1]
-            or flat_layout.res_id[i] != flat_layout.res_id[i - 1]
-        ):
-          all_residues[flat_layout.chain_id[i]].append(
-              (flat_layout.res_name[i], flat_layout.res_id[i])
-          )
-
-  return structure.from_atom_arrays(
-      name=name,
-      all_residues=dict(all_residues),
-      chain_id=flat_layout.chain_id,
-      chain_type=flat_layout.chain_type,
-      res_id=flat_layout.res_id.astype(np.int32),
-      res_name=flat_layout.res_name,
-      atom_name=flat_layout.atom_name,
-      atom_element=flat_layout.atom_element,
-      atom_x=atom_coords[..., 0],
-      atom_y=atom_coords[..., 1],
-      atom_z=atom_coords[..., 2],
-      atom_b_factor=atom_b_factors,
-  )
-
-
-def _assert_all_arrays_have_same_shape(
-    *,
-    obj: AtomLayout | Residues | GatherInfo,
-    expected_shape: tuple[int, ...],
-    attribute_names: Sequence[str],
-) -> None:
-  """Checks that given attributes of the object have the expected shape."""
-  attribute_shapes_description = []
-  all_shapes_are_valid = True
-
-  for attribute_name in attribute_names:
-    attribute = getattr(obj, attribute_name)
-
-    if attribute is None:
-      attribute_shape = None
-    else:
-      attribute_shape = attribute.shape
-
-    if attribute_shape is not None and expected_shape != attribute_shape:
-      all_shapes_are_valid = False
-
-    attribute_shape_name = attribute_name + '.shape'
-    attribute_shapes_description.append(
-        f'{attribute_shape_name:25} = {attribute_shape}'
-    )
-
-  if not all_shapes_are_valid:
-    raise ValueError(
-        f'All arrays must have the same shape ({expected_shape=}). Got\n'
-        + '\n'.join(attribute_shapes_description)
-    )
diff --git a/src/alphafold3/model/components/base_model.py b/src/alphafold3/model/components/base_model.py
deleted file mode 100644
index 45e2dc4baed4222f1b4d0ca566d65fa8cd41a588..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/components/base_model.py
+++ /dev/null
@@ -1,62 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Defines interface of a BaseModel."""
-
-from collections.abc import Callable, Mapping
-import dataclasses
-from typing import Any, TypeAlias
-from alphafold3 import structure
-from alphafold3.model import features
-import haiku as hk
-import jax
-import numpy as np
-
-ModelResult: TypeAlias = Mapping[str, Any]
-ScalarNumberOrArray: TypeAlias = Mapping[str, float | int | np.ndarray]
-
-# Eval result will contain scalars (e.g. metrics or losses), selected from the
-# forward pass outputs or computed in the online evaluation; np.ndarrays or
-# jax.Arrays generated from the forward pass outputs (e.g. distogram expected
-# distances) or batch inputs; protein structures (predicted and ground-truth).
-EvalResultValue: TypeAlias = (
-    float | int | np.ndarray | jax.Array | structure.Structure
-)
-# Eval result may be None for some metrics if they are not computable.
-EvalResults: TypeAlias = Mapping[str, EvalResultValue | None]
-# Interface metrics are all floats or None.
-InterfaceMetrics: TypeAlias = Mapping[str, float | None]
-# Interface results are a mapping from interface name to mappings from score
-# type to metric value.
-InterfaceResults: TypeAlias = Mapping[str, Mapping[str, InterfaceMetrics]]
-# Eval output consists of full eval results and a dict of interface metrics.
-EvalOutput: TypeAlias = tuple[EvalResults, InterfaceResults]
-
-# Signature for `apply` method of hk.transform_with_state called on a BaseModel.
-ForwardFn: TypeAlias = Callable[
-    [hk.Params, hk.State, jax.Array, features.BatchDict],
-    tuple[ModelResult, hk.State],
-]
-
-
-@dataclasses.dataclass(frozen=True)
-class InferenceResult:
-  """Postprocessed model result."""
-
-  # Predicted protein structure.
-  predicted_structure: structure.Structure = dataclasses.field()
-  # Useful numerical data (scalars or arrays) to be saved at inference time.
-  numerical_data: ScalarNumberOrArray = dataclasses.field(default_factory=dict)
-  # Smaller numerical data (usually scalar) to be saved as inference metadata.
-  metadata: ScalarNumberOrArray = dataclasses.field(default_factory=dict)
-  # Additional dict for debugging, e.g. raw outputs of a model forward pass.
-  debug_outputs: ModelResult | None = dataclasses.field(default_factory=dict)
-  # Model identifier.
-  model_id: bytes = b''
diff --git a/src/alphafold3/model/components/haiku_modules.py b/src/alphafold3/model/components/haiku_modules.py
deleted file mode 100644
index 0c20b69050d0f4e54ebaaa7f34554708eac7f24a..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/components/haiku_modules.py
+++ /dev/null
@@ -1,336 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Common Haiku modules."""
-
-from collections.abc import Sequence
-import contextlib
-import numbers
-from typing import TypeAlias
-
-import haiku as hk
-import jax
-import jax.numpy as jnp
-import numpy as np
-
-
-PRECISION: TypeAlias = (
-    None
-    | str
-    | jax.lax.Precision
-    | tuple[str, str]
-    | tuple[jax.lax.Precision, jax.lax.Precision]
-)
-
-# Useful for mocking in tests.
-DEFAULT_PRECISION = None
-
-# Constant from scipy.stats.truncnorm.std(a=-2, b=2, loc=0., scale=1.)
-TRUNCATED_NORMAL_STDDEV_FACTOR = np.asarray(
-    0.87962566103423978, dtype=np.float32
-)
-
-
-class LayerNorm(hk.LayerNorm):
-  """LayerNorm module.
-
-  Equivalent to hk.LayerNorm but with an extra 'upcast' option that casts
-  (b)float16 inputs to float32 before computing the layer norm, and then casts
-  the output back to the input type.
-
-  The learnable parameter shapes are also different from Haiku: they are always
-  vectors rather than possibly higher-rank tensors. This makes it easier
-  to change the layout whilst keep the model weight-compatible.
-  """
-
-  def __init__(
-      self,
-      *,
-      axis: int = -1,
-      create_scale: bool = True,
-      create_offset: bool = True,
-      eps: float = 1e-5,
-      scale_init: hk.initializers.Initializer | None = None,
-      offset_init: hk.initializers.Initializer | None = None,
-      use_fast_variance: bool = True,
-      name: str,
-      param_axis: int | None = None,
-      upcast: bool = True,
-  ):
-    super().__init__(
-        axis=axis,
-        create_scale=False,
-        create_offset=False,
-        eps=eps,
-        scale_init=None,
-        offset_init=None,
-        use_fast_variance=use_fast_variance,
-        name=name,
-        param_axis=param_axis,
-    )
-    self.upcast = upcast
-    self._temp_create_scale = create_scale
-    self._temp_create_offset = create_offset
-
-  def __call__(self, x: jnp.ndarray) -> jnp.ndarray:
-    dtype = x.dtype
-    is_16bit = x.dtype in [jnp.bfloat16, jnp.float16]
-    if self.upcast and is_16bit:
-      x = x.astype(jnp.float32)
-
-    param_axis = self.param_axis[0] if self.param_axis else -1
-    param_shape = (x.shape[param_axis],)
-
-    param_broadcast_shape = [1] * x.ndim
-    param_broadcast_shape[param_axis] = x.shape[param_axis]
-    scale = None
-    offset = None
-    if self._temp_create_scale:
-      scale = hk.get_parameter(
-          'scale', param_shape, x.dtype, init=self.scale_init
-      )
-      scale = scale.reshape(param_broadcast_shape)
-
-    if self._temp_create_offset:
-      offset = hk.get_parameter(
-          'offset', param_shape, x.dtype, init=self.offset_init
-      )
-      offset = offset.reshape(param_broadcast_shape)
-
-    out = super().__call__(x, scale=scale, offset=offset)
-
-    if self.upcast and is_16bit:
-      out = out.astype(dtype)
-
-    return out
-
-
-def haiku_linear_get_params(
-    inputs: jax.Array | jax.ShapeDtypeStruct,
-    *,
-    num_output: int | Sequence[int],
-    use_bias: bool = False,
-    num_input_dims: int = 1,
-    initializer: str = 'linear',
-    bias_init: float = 0.0,
-    transpose_weights: bool = False,
-    name: str | None = None,
-) -> tuple[jax.Array, jax.Array | None]:
-  """Get parameters for linear layer.
-
-  Parameters will be at least float32 or higher precision.
-
-  Arguments:
-    inputs: The input to the Linear layer. Can be either a JAX array or a
-      jax.ShapeDtypeStruct.
-    num_output: The number of output channels. Can be an integer or a sequence
-      of integers.
-    use_bias: Whether to create a bias array.
-    num_input_dims: The number of dimensions to consider as channel dims in the
-      input.
-    initializer: The name of the weight initializer to use.
-    bias_init: A float used to initialize the bias.
-    transpose_weights: If True, will create a transposed version of the weights.
-    name: The Haiku namespace to use for the weight and bias.
-
-  Returns:
-    A tuple[weight, bias] if use_bias otherwise tuple[weight, None].
-  """
-
-  if isinstance(num_output, numbers.Integral):
-    output_shape = (num_output,)
-  else:
-    output_shape = tuple(num_output)
-
-  if num_input_dims > 0:
-    in_shape = inputs.shape[-num_input_dims:]
-  elif num_input_dims == 0:
-    in_shape = ()
-  else:
-    raise ValueError('num_input_dims must be >= 0.')
-
-  weight_init = _get_initializer_scale(initializer, in_shape)
-  with hk.name_scope(name) if name else contextlib.nullcontext():
-
-    if transpose_weights:
-      weight_shape = output_shape + in_shape
-
-      weights = hk.get_parameter(
-          'weights', shape=weight_shape, dtype=inputs.dtype, init=weight_init
-      )
-    else:
-      weight_shape = in_shape + output_shape
-      weights = hk.get_parameter(
-          name='weights',
-          shape=weight_shape,
-          dtype=inputs.dtype,
-          init=weight_init,
-      )
-
-    bias = None
-    if use_bias:
-      bias = hk.get_parameter(
-          name='bias',
-          shape=output_shape,
-          dtype=inputs.dtype,
-          init=hk.initializers.Constant(bias_init),
-      )
-  return weights, bias
-
-
-class Linear(hk.Module):
-  """Custom Linear Module.
-
-  This differs from the standard Linear in a few ways:
-    * It supports inputs of arbitrary rank
-    * It allows to use ntk parametrization
-    * Initializers are specified by strings
-    * It allows to explicitly specify which dimension of the input will map to
-      the tpu sublane/lane dimensions.
-  """
-
-  def __init__(
-      self,
-      num_output: int | Sequence[int],
-      *,
-      initializer: str = 'linear',
-      num_input_dims: int = 1,
-      use_bias: bool = False,
-      bias_init: float = 0.0,
-      precision: PRECISION = None,
-      fast_scalar_mode: bool = True,
-      transpose_weights: bool = False,
-      name: str,
-  ):
-    """Constructs Linear Module.
-
-    Args:
-      num_output: number of output channels. Can be tuple when outputting
-        multiple dimensions.
-      initializer: What initializer to use, should be one of {'linear', 'relu',
-        'zeros'}.
-      num_input_dims: Number of dimensions from the end to project.
-      use_bias: Whether to include trainable bias (False by default).
-      bias_init: Value used to initialize bias.
-      precision: What precision to use for matrix multiplication, defaults to
-        None.
-      fast_scalar_mode: Whether to use optimized path for num_input_dims = 0.
-      transpose_weights: decides whether weights have shape [input, output] or
-        [output, input], True means [output, input], this is helpful to avoid
-        padding on the tensors holding the weights.
-      name: name of module, used for name scopes.
-    """
-    super().__init__(name=name)
-    if isinstance(num_output, numbers.Integral):
-      self.output_shape = (num_output,)
-    else:
-      self.output_shape = tuple(num_output)
-    self.initializer = initializer
-    self.use_bias = use_bias
-    self.bias_init = bias_init
-    self.num_input_dims = num_input_dims
-    self.num_output_dims = len(self.output_shape)
-    self.precision = precision if precision is not None else DEFAULT_PRECISION
-    self.fast_scalar_mode = fast_scalar_mode
-    self.transpose_weights = transpose_weights
-
-  def __call__(self, inputs: jnp.ndarray) -> jnp.ndarray:
-    """Connects Module.
-
-    Args:
-      inputs: Tensor of shape [..., num_channel]
-
-    Returns:
-      output of shape [..., num_output]
-    """
-
-    num_input_dims = self.num_input_dims
-
-    # Adds specialized path for scalar inputs in Linear layer,
-    # this means the linear Layer does not use the matmul units on the tpu,
-    # which is more efficient and gives compiler more flexibility over layout.
-    if num_input_dims == 0 and self.fast_scalar_mode:
-      weight_shape = self.output_shape
-      if self.initializer == 'zeros':
-        w_init = hk.initializers.Constant(0.0)
-      else:
-        distribution_stddev = jnp.array(1 / TRUNCATED_NORMAL_STDDEV_FACTOR)
-        w_init = hk.initializers.TruncatedNormal(
-            mean=0.0, stddev=distribution_stddev
-        )
-
-      weights = hk.get_parameter('weights', weight_shape, inputs.dtype, w_init)
-
-      inputs = jnp.expand_dims(
-          inputs, tuple(range(-1, -self.num_output_dims - 1, -1))
-      )
-      output = inputs * weights
-    else:
-      if self.num_input_dims > 0:
-        in_shape = inputs.shape[-self.num_input_dims :]
-      else:
-        in_shape = ()
-
-      weight_init = _get_initializer_scale(self.initializer, in_shape)
-
-      in_letters = 'abcde'[: self.num_input_dims]
-      out_letters = 'hijkl'[: self.num_output_dims]
-
-      if self.transpose_weights:
-        weight_shape = self.output_shape + in_shape
-        weights = hk.get_parameter(
-            'weights', weight_shape, inputs.dtype, weight_init
-        )
-        equation = (
-            f'...{in_letters}, {out_letters}{in_letters}->...{out_letters}'
-        )
-      else:
-        weight_shape = in_shape + self.output_shape
-        weights = hk.get_parameter(
-            'weights', weight_shape, inputs.dtype, weight_init
-        )
-
-        equation = (
-            f'...{in_letters}, {in_letters}{out_letters}->...{out_letters}'
-        )
-
-      output = jnp.einsum(equation, inputs, weights, precision=self.precision)
-
-    if self.use_bias:
-      bias = hk.get_parameter(
-          'bias',
-          self.output_shape,
-          inputs.dtype,
-          hk.initializers.Constant(self.bias_init),
-      )
-      output += bias
-
-    return output
-
-
-def _get_initializer_scale(initializer_name, input_shape):
-  """Get initializer for weights."""
-
-  if initializer_name == 'zeros':
-    w_init = hk.initializers.Constant(0.0)
-  else:
-    # fan-in scaling
-    noise_scale = 1.0
-    for channel_dim in input_shape:
-      noise_scale /= channel_dim
-    if initializer_name == 'relu':
-      noise_scale *= 2
-
-    stddev = np.sqrt(noise_scale)
-    # Adjust stddev for truncation.
-    stddev = stddev / TRUNCATED_NORMAL_STDDEV_FACTOR
-    w_init = hk.initializers.TruncatedNormal(mean=0.0, stddev=stddev)
-
-  return w_init
diff --git a/src/alphafold3/model/components/mapping.py b/src/alphafold3/model/components/mapping.py
deleted file mode 100644
index d5964879f713a4f517f35da4b7968d9d24a8dc93..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/components/mapping.py
+++ /dev/null
@@ -1,303 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Specialized mapping functions."""
-
-from collections.abc import Callable, Sequence
-import functools
-from typing import Any
-
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-Pytree = Any
-PytreeJaxArray = Any
-
-partial = functools.partial
-PROXY = object()
-
-
-def _maybe_slice(array, i, slice_size, axis):
-  if axis is PROXY:
-    return array
-  else:
-    return jax.lax.dynamic_slice_in_dim(
-        array, i, slice_size=slice_size, axis=axis
-    )
-
-
-def _maybe_get_size(array, axis):
-  if axis == PROXY:
-    return -1
-  else:
-    return array.shape[axis]
-
-
-def _expand_axes(axes, values, name="sharded_apply"):
-  values_tree_def = jax.tree_util.tree_structure(values)
-  flat_axes = jax.api_util.flatten_axes(name, values_tree_def, axes)
-  # Replace None's with PROXY.
-  flat_axes = [PROXY if x is None else x for x in flat_axes]
-  return jax.tree_util.tree_unflatten(values_tree_def, flat_axes)
-
-
-def sharded_map(
-    fun: Callable[..., PytreeJaxArray],
-    shard_size: int | None = 1,
-    in_axes: int | Pytree = 0,
-    out_axes: int | Pytree = 0,
-) -> Callable[..., PytreeJaxArray]:
-  """Sharded vmap.
-
-  Maps `fun` over axes, in a way similar to hk.vmap, but does so in shards of
-  `shard_size`. This allows a smooth trade-off between memory usage
-  (as in a plain map) vs higher throughput (as in a vmap).
-
-  Args:
-    fun: Function to apply smap transform to.
-    shard_size: Integer denoting shard size.
-    in_axes: Either integer or pytree describing which axis to map over for each
-      input to `fun`, None denotes broadcasting.
-    out_axes: Integer or pytree denoting to what axis in the output the mapped
-      over axis maps.
-
-  Returns:
-    Function with smap applied.
-  """
-  if hk.running_init():
-    # Guarantees initialisation independent of shard_size. Doesn't incur a high
-    # memory cost, as long as large concrete tensors are not encountered.
-    return hk.vmap(fun, in_axes=in_axes, out_axes=out_axes, split_rng=False)
-  else:
-    vmapped_fun = hk.vmap(fun, in_axes, out_axes, split_rng=True)
-    return sharded_apply(vmapped_fun, shard_size, in_axes, out_axes)
-
-
-def sharded_apply(
-    fun: Callable[..., PytreeJaxArray],
-    shard_size: int | None = 1,
-    in_axes: int | Pytree = 0,
-    out_axes: int | Pytree = 0,
-    new_out_axes: bool = False,
-) -> Callable[..., PytreeJaxArray]:
-  """Sharded apply.
-
-  Applies `fun` over shards to axes, in a way similar to vmap,
-  but does so in shards of `shard_size`. Shards are stacked after.
-  This allows a smooth trade-off between
-  memory usage (as in a plain map) vs higher throughput (as in a vmap).
-
-  Args:
-    fun: Function to apply smap transform to.
-    shard_size: Integer denoting shard size.
-    in_axes: Either integer or pytree describing which axis to map over for each
-      input to `fun`, None denotes broadcasting.
-    out_axes: Integer or pytree denoting to what axis in the output the mapped
-      over axis maps.
-    new_out_axes: Whether to stack outputs on new axes. This assumes that the
-      output sizes for each shard (including the possible remainder shard) are
-      the same.
-
-  Returns:
-    Function with smap applied.
-  """
-  docstr = (
-      "Mapped version of {fun}. Takes similar arguments to {fun} "
-      "but with additional array axes over which {fun} is mapped."
-  )
-  if new_out_axes:
-    raise NotImplementedError("New output axes not yet implemented.")
-
-  # shard size None denotes no sharding
-  if shard_size is None:
-    return fun
-
-  @jax.util.wraps(fun, docstr=docstr)
-  def mapped_fn(*args, **kwargs):
-    # Expand in axes and determine loop range.
-    in_axes_ = _expand_axes(in_axes, args)
-
-    in_sizes = jax.tree.map(_maybe_get_size, args, in_axes_)
-    in_size = max(jax.tree_util.tree_leaves(in_sizes))
-
-    num_extra_shards = (in_size - 1) // shard_size
-
-    # Fix if necessary.
-    last_shard_size = in_size % shard_size
-    last_shard_size = shard_size if last_shard_size == 0 else last_shard_size
-
-    def apply_fun_to_slice(slice_start, slice_size):
-      input_slice = jax.tree.map(
-          lambda array, axis: _maybe_slice(
-              array, slice_start, slice_size, axis
-          ),
-          args,
-          in_axes_,
-      )
-      return fun(*input_slice, **kwargs)
-
-    remainder_shape_dtype = hk.eval_shape(
-        partial(apply_fun_to_slice, 0, last_shard_size)
-    )
-    out_dtypes = jax.tree.map(lambda x: x.dtype, remainder_shape_dtype)
-    out_shapes = jax.tree.map(lambda x: x.shape, remainder_shape_dtype)
-    out_axes_ = _expand_axes(out_axes, remainder_shape_dtype)
-
-    if num_extra_shards > 0:
-      regular_shard_shape_dtype = hk.eval_shape(
-          partial(apply_fun_to_slice, 0, shard_size)
-      )
-      shard_shapes = jax.tree.map(lambda x: x.shape, regular_shard_shape_dtype)
-
-      def make_output_shape(axis, shard_shape, remainder_shape):
-        return (
-            shard_shape[:axis]
-            + (shard_shape[axis] * num_extra_shards + remainder_shape[axis],)
-            + shard_shape[axis + 1 :]
-        )
-
-      out_shapes = jax.tree.map(
-          make_output_shape, out_axes_, shard_shapes, out_shapes
-      )
-
-    # Calls dynamic Update slice with different argument order.
-    # This is here since tree_map only works with positional arguments.
-    def dynamic_update_slice_in_dim(full_array, update, axis, i):
-      return jax.lax.dynamic_update_slice_in_dim(full_array, update, i, axis)
-
-    def compute_shard(outputs, slice_start, slice_size):
-      slice_out = apply_fun_to_slice(slice_start, slice_size)
-      update_slice = partial(dynamic_update_slice_in_dim, i=slice_start)
-      return jax.tree.map(update_slice, outputs, slice_out, out_axes_)
-
-    def scan_iteration(outputs, i):
-      new_outputs = compute_shard(outputs, i, shard_size)
-      return new_outputs, ()
-
-    slice_starts = jnp.arange(0, in_size - shard_size + 1, shard_size)
-
-    def allocate_buffer(dtype, shape):
-      return jnp.zeros(shape, dtype=dtype)
-
-    outputs = jax.tree.map(allocate_buffer, out_dtypes, out_shapes)
-
-    if slice_starts.shape[0] > 0:
-      outputs, _ = hk.scan(scan_iteration, outputs, slice_starts)
-
-    if last_shard_size != shard_size:
-      remainder_start = in_size - last_shard_size
-      outputs = compute_shard(outputs, remainder_start, last_shard_size)
-
-    return outputs
-
-  return mapped_fn
-
-
-def reshape_partitioned_inputs(
-    batched_args: Sequence[PytreeJaxArray],
-    partitioned_dim: int,
-    subbatch_size: int,
-) -> Sequence[PytreeJaxArray]:
-  """Reshapes so subbatching doesn't happen on the partitioned dim."""
-  subbatched_args = []
-  for arg in batched_args:
-    shape = arg.shape
-
-    new_shape = (
-        shape[:partitioned_dim]
-        + (subbatch_size, shape[partitioned_dim] // subbatch_size)
-        + shape[partitioned_dim + 1 :]
-    )
-    subbatched_args.append(arg.reshape(new_shape))
-  return subbatched_args
-
-
-def reshape_partitioned_output(
-    output: jax.Array, output_subbatch_dim: int
-) -> jax.Array:
-  """Reshapes outputs as if reshape_partitioned_inputs were never applied."""
-  out_shape = (
-      output.shape[: output_subbatch_dim - 1]
-      + (-1,)
-      + output.shape[output_subbatch_dim + 1 :]
-  )
-  return output.reshape(out_shape)
-
-
-def inference_subbatch(
-    module: Callable[..., PytreeJaxArray],
-    subbatch_size: int,
-    batched_args: Sequence[PytreeJaxArray],
-    nonbatched_args: Sequence[PytreeJaxArray],
-    input_subbatch_dim: int = 0,
-    output_subbatch_dim: int | None = None,
-    input_subbatch_dim_is_partitioned: bool = False,
-) -> PytreeJaxArray:
-  """Run through subbatches (like batch apply but with split and concat)."""
-  assert len(batched_args) > 0  # pylint: disable=g-explicit-length-test
-
-  if hk.running_init():
-    args = list(batched_args) + list(nonbatched_args)
-    return module(*args)
-
-  if output_subbatch_dim is None:
-    output_subbatch_dim = input_subbatch_dim
-
-  if input_subbatch_dim_is_partitioned:
-    # Subbatching along the partitioned axis would induce an all-gather that
-    # undoes the partitioning. So instead we reshape such that
-    # [..., partitioned_input_size, ...] becomes [..., subbatch_size,
-    # partitioned_input_size // subbatch_size, ...] and then actually subbatch
-    # along the partitioned_input_size // subbatch_size axis in slices of
-    # size 1. Partitioning is then preserved on the partitioned axis, except
-    # that dimension is now of size subbatch_size instead of
-    # partitioned_input_size. Note that the module itself still sees inputs of
-    # size [..., subbatch_size, ...], just as it would if this reshaping were
-    # not applied.
-    batched_args = reshape_partitioned_inputs(
-        batched_args, input_subbatch_dim, subbatch_size
-    )
-    input_subbatch_dim += 1
-    output_subbatch_dim += 1
-    subbatch_size = 1
-
-  def run_module(*batched_args):
-    if input_subbatch_dim_is_partitioned:
-      # Squeeze off the singleton dimension (otherwise the module would see
-      # [..., subbatch_size, 1, ...]).
-      batched_args = [b.squeeze(axis=input_subbatch_dim) for b in batched_args]
-    args = list(batched_args) + list(nonbatched_args)
-    res = module(*args)
-    if input_subbatch_dim_is_partitioned:
-      # Add back in the singleton dimension so the outputs are stacked on the
-      # axis we are actually subbatching over (i.e stacked back to
-      # [..., subbatch_size, partitioned_input_size // subbatch_size, ...]),
-      # rather than on the partitioned axis, which would again induce an
-      # all-gather that breaks partitioning.
-      res = jnp.expand_dims(res, axis=output_subbatch_dim)
-    return res
-
-  sharded_module = sharded_apply(
-      run_module,
-      shard_size=subbatch_size,
-      in_axes=input_subbatch_dim,
-      out_axes=output_subbatch_dim,
-  )
-  output = sharded_module(*batched_args)
-  if input_subbatch_dim_is_partitioned:
-    # The is of the same shape as the inputs [..., subbatch_size,
-    # partitioned_input_size // subbatch_size, ...]. Reshape to
-    # [..., partitioned_input_size, ...] as if the reshaping due to partitioning
-    # had never been applied.
-    output = reshape_partitioned_output(output, output_subbatch_dim)
-
-  return output
diff --git a/src/alphafold3/model/components/utils.py b/src/alphafold3/model/components/utils.py
deleted file mode 100644
index b5ff4db55ff2d614c63973bb2a23b2cd450b3938..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/components/utils.py
+++ /dev/null
@@ -1,83 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Utility functions for training AlphaFold and similar models."""
-
-from collections import abc
-import contextlib
-import numbers
-
-from alphafold3.model import features
-import haiku as hk
-import jax.numpy as jnp
-import numpy as np
-
-
-VALID_DTYPES = [np.float32, np.float64, np.int8, np.int32, np.int64, bool]
-
-
-def remove_invalidly_typed_feats(
-    batch: features.BatchDict,
-) -> features.BatchDict:
-  """Remove features of types we don't want to send to the TPU e.g. strings."""
-  return {
-      k: v
-      for k, v in batch.items()
-      if hasattr(v, 'dtype') and v.dtype in VALID_DTYPES
-  }
-
-
-def bfloat16_getter(next_getter, value, context):
-  """Ensures that a bfloat16 parameter is provided by casting if necessary."""
-  if context.original_dtype == jnp.bfloat16:
-    if value.dtype != jnp.bfloat16:
-      value = value.astype(jnp.bfloat16)
-  return next_getter(value)
-
-
-@contextlib.contextmanager
-def bfloat16_context():
-  with hk.custom_getter(bfloat16_getter):
-    yield
-
-
-def mask_mean(mask, value, axis=None, keepdims=False, eps=1e-10):
-  """Masked mean."""
-
-  mask_shape = mask.shape
-  value_shape = value.shape
-
-  assert len(mask_shape) == len(
-      value_shape
-  ), 'Shapes are not compatible, shapes: {}, {}'.format(mask_shape, value_shape)
-
-  if isinstance(axis, numbers.Integral):
-    axis = [axis]
-  elif axis is None:
-    axis = list(range(len(mask_shape)))
-  assert isinstance(
-      axis, abc.Iterable
-  ), 'axis needs to be either an iterable, integer or "None"'
-
-  broadcast_factor = 1.0
-  for axis_ in axis:
-    value_size = value_shape[axis_]
-    mask_size = mask_shape[axis_]
-    if mask_size == 1:
-      broadcast_factor *= value_size
-    else:
-      error = f'Shapes are not compatible, shapes: {mask_shape}, {value_shape}'
-      assert mask_size == value_size, error
-
-  return jnp.sum(mask * value, keepdims=keepdims, axis=axis) / (
-      jnp.maximum(
-          jnp.sum(mask, keepdims=keepdims, axis=axis) * broadcast_factor, eps
-      )
-  )
diff --git a/src/alphafold3/model/confidence_types.py b/src/alphafold3/model/confidence_types.py
deleted file mode 100644
index 5ad948bae4731d7ec3a5c1e138fca9c8f85e8b9e..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/confidence_types.py
+++ /dev/null
@@ -1,301 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Confidence categories for predictions."""
-
-import dataclasses
-import enum
-import json
-from typing import Any, Self
-
-from absl import logging
-from alphafold3.model import model
-import jax
-import numpy as np
-
-
-class StructureConfidenceFullEncoder(json.JSONEncoder):
-  """JSON encoder for serializing confidence types."""
-
-  def __init__(self, **kwargs):
-    super().__init__(**(kwargs | dict(separators=(',', ':'))))
-
-  def encode(self, o: 'StructureConfidenceFull'):
-    # Cast to np.float64 before rounding, since casting to Python float will
-    # cast to a 64 bit float, potentially undoing np.float32 rounding.
-    atom_plddts = np.round(
-        np.clip(np.asarray(o.atom_plddts, dtype=np.float64), 0.0, 99.99), 2
-    ).astype(float)
-    contact_probs = np.round(
-        np.clip(np.asarray(o.contact_probs, dtype=np.float64), 0.0, 1.0), 2
-    ).astype(float)
-    pae = np.round(
-        np.clip(np.asarray(o.pae, dtype=np.float64), 0.0, 99.9), 1
-    ).astype(float)
-    return """\
-{
-  "atom_chain_ids": %s,
-  "atom_plddts": %s,
-  "contact_probs": %s,
-  "pae": %s,
-  "token_chain_ids": %s,
-  "token_res_ids": %s
-}""" % (
-        super().encode(o.atom_chain_ids),
-        super().encode(list(atom_plddts)).replace('NaN', 'null'),
-        super().encode([list(x) for x in contact_probs]).replace('NaN', 'null'),
-        super().encode([list(x) for x in pae]).replace('NaN', 'null'),
-        super().encode(o.token_chain_ids),
-        super().encode(o.token_res_ids),
-    )
-
-
-def _dump_json(data: Any, indent: int | None = None) -> str:
-  """Dumps a json string with JSON compatible NaN representation."""
-  json_str = json.dumps(
-      data,
-      sort_keys=True,
-      indent=indent,
-      separators=(',', ': '),
-  )
-  return json_str.replace('NaN', 'null')
-
-
-@enum.unique
-class ConfidenceCategory(enum.Enum):
-  """Confidence categories for AlphaFold predictions."""
-
-  HIGH = 0
-  MEDIUM = 1
-  LOW = 2
-  DISORDERED = 3
-
-  @classmethod
-  def from_char(cls, char: str) -> Self:
-    match char:
-      case 'H':
-        return cls.HIGH
-      case 'M':
-        return cls.MEDIUM
-      case 'L':
-        return cls.LOW
-      case 'D':
-        return cls.DISORDERED
-      case _:
-        raise ValueError(
-            f'Unknown character. Expected one of H, M, L or D; got: {char}'
-        )
-
-  def to_char(self) -> str:
-    match self:
-      case self.HIGH:
-        return 'H'
-      case self.MEDIUM:
-        return 'M'
-      case self.LOW:
-        return 'L'
-      case self.DISORDERED:
-        return 'D'
-
-  @classmethod
-  def from_confidence_score(cls, confidence: float) -> Self:
-    if 90 <= confidence <= 100:
-      return cls.HIGH
-    if 70 <= confidence < 90:
-      return cls.MEDIUM
-    if 50 <= confidence < 70:
-      return cls.LOW
-    if 0 <= confidence < 50:
-      return cls.DISORDERED
-    raise ValueError(f'Confidence score out of range [0, 100]: {confidence}')
-
-
-@dataclasses.dataclass()
-class AtomConfidence:
-  """Dataclass for 1D per-atom confidences from AlphaFold."""
-
-  chain_id: list[str]
-  atom_number: list[int]
-  confidence: list[float]
-  confidence_category: list[ConfidenceCategory]
-
-  def __post_init__(self):
-    num_res = len(self.atom_number)
-    if not all(
-        len(v) == num_res
-        for v in [self.chain_id, self.confidence, self.confidence_category]
-    ):
-      raise ValueError('All confidence fields must have the same length.')
-
-  @classmethod
-  def from_inference_result(
-      cls, inference_result: model.InferenceResult
-  ) -> Self:
-    """Instantiates an AtomConfidence from a structure.
-
-    Args:
-      inference_result: Inference result from AlphaFold.
-
-    Returns:
-      Scores in AtomConfidence dataclass.
-    """
-    struc = inference_result.predicted_structure
-    as_dict = {
-        'chain_id': [],
-        'atom_number': [],
-        'confidence': [],
-        'confidence_category': [],
-    }
-    for atom_number, atom in enumerate(struc.iter_atoms()):
-      this_confidence = float(struc.atom_b_factor[atom_number])
-      as_dict['chain_id'].append(atom['chain_id'])
-      as_dict['atom_number'].append(atom_number)
-      as_dict['confidence'].append(round(this_confidence, 2))
-      as_dict['confidence_category'].append(
-          ConfidenceCategory.from_confidence_score(this_confidence)
-      )
-    return cls(**as_dict)
-
-  @classmethod
-  def from_json(cls, json_string: str) -> Self:
-    """Instantiates a AtomConfidence from a json string."""
-    input_dict = json.loads(json_string)
-    input_dict['confidence_category'] = [
-        ConfidenceCategory.from_char(k)
-        for k in input_dict['confidence_category']
-    ]
-    return cls(**input_dict)
-
-  def to_json(self) -> str:
-    output = dataclasses.asdict(self)
-    output['confidence_category'] = [
-        k.to_char() for k in output['confidence_category']
-    ]
-    output['atom_number'] = [int(k) for k in output['atom_number']]
-    return _dump_json(output)
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class StructureConfidenceSummary:
-  """Dataclass for the summary of structure scores from AlphaFold.
-
-  Attributes:
-   ptm: Predicted TM global score.
-   iptm: Interface predicted TM global score.
-   ranking_score: Ranking score extracted from CIF metadata.
-   fraction_disordered: Fraction disordered, measured with RASA.
-   has_clash: Has significant clashing.
-   chain_pair_pae_min: [num_chains, num_chains] Minimum cross chain PAE.
-   chain_pair_iptm: [num_chains, num_chains] Chain pair ipTM.
-   chain_ptm: [num_chains] Chain pTM.
-   chain_iptm: [num_chains] Mean cross chain ipTM for a chain.
-  """
-
-  ptm: float
-  iptm: float
-  ranking_score: float
-  fraction_disordered: float
-  has_clash: float
-  chain_pair_pae_min: np.ndarray
-  chain_pair_iptm: np.ndarray
-  chain_ptm: np.ndarray
-  chain_iptm: np.ndarray
-
-  @classmethod
-  def from_inference_result(
-      cls, inference_result: model.InferenceResult
-  ) -> Self:
-    """Returns a new instance based on a given inference result."""
-    return cls(
-        ptm=float(inference_result.metadata['ptm']),
-        iptm=float(inference_result.metadata['iptm']),
-        ranking_score=float(inference_result.metadata['ranking_score']),
-        fraction_disordered=float(
-            inference_result.metadata['fraction_disordered']
-        ),
-        has_clash=float(inference_result.metadata['has_clash']),
-        chain_pair_pae_min=inference_result.metadata['chain_pair_pae_min'],
-        chain_pair_iptm=inference_result.metadata['chain_pair_iptm'],
-        chain_ptm=inference_result.metadata['iptm_ichain'],
-        chain_iptm=inference_result.metadata['iptm_xchain'],
-    )
-
-  @classmethod
-  def from_json(cls, json_string: str) -> Self:
-    """Returns a new instance from a given json string."""
-    return cls(**json.loads(json_string))
-
-  def to_json(self) -> str:
-    def convert(data):
-      if isinstance(data, np.ndarray):
-        # Cast to np.float64 before rounding, since casting to Python float will
-        # cast to a 64 bit float, potentially undoing np.float32 rounding.
-        rounded_data = np.round(data.astype(np.float64), decimals=2).tolist()
-      else:
-        rounded_data = np.round(data, decimals=2)
-      return rounded_data
-
-    return _dump_json(jax.tree.map(convert, dataclasses.asdict(self)), indent=1)
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class StructureConfidenceFull:
-  """Dataclass for full structure data from AlphaFold."""
-
-  pae: np.ndarray
-  token_chain_ids: list[str]
-  token_res_ids: list[int]
-  atom_plddts: list[float]
-  atom_chain_ids: list[str]
-  contact_probs: np.ndarray  # [num_tokens, num_tokens]
-
-  @classmethod
-  def from_inference_result(
-      cls, inference_result: model.InferenceResult
-  ) -> Self:
-    """Returns a new instance based on a given inference result."""
-
-    pae = inference_result.numerical_data['full_pae']
-    if not isinstance(pae, np.ndarray):
-      logging.info('%s', type(pae))
-      raise TypeError('pae should be a numpy array.')
-
-    contact_probs = inference_result.numerical_data['contact_probs']
-    if not isinstance(contact_probs, np.ndarray):
-      logging.info('%s', type(contact_probs))
-      raise TypeError('contact_probs should be a numpy array.')
-
-    struc = inference_result.predicted_structure
-    chain_ids = struc.chain_id.tolist()
-    atom_plddts = struc.atom_b_factor.tolist()
-    token_chain_ids = [
-        str(token_id)
-        for token_id in inference_result.metadata['token_chain_ids']
-    ]
-    token_res_ids = [
-        int(token_id) for token_id in inference_result.metadata['token_res_ids']
-    ]
-    return cls(
-        pae=pae,
-        token_chain_ids=token_chain_ids,
-        token_res_ids=token_res_ids,
-        atom_plddts=atom_plddts,
-        atom_chain_ids=chain_ids,
-        contact_probs=contact_probs,
-    )
-
-  @classmethod
-  def from_json(cls, json_string: str) -> Self:
-    """Returns a new instance from a given json string."""
-    return cls(**json.loads(json_string))
-
-  def to_json(self) -> str:
-    """Converts StructureConfidenceFull to json string."""
-    return json.dumps(self, cls=StructureConfidenceFullEncoder)
diff --git a/src/alphafold3/model/confidences.py b/src/alphafold3/model/confidences.py
deleted file mode 100644
index 35a3585e523c41cd0aff3d28b6381c1d34777044..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/confidences.py
+++ /dev/null
@@ -1,663 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Functions for extracting and processing confidences from model outputs."""
-import warnings
-
-from absl import logging
-from alphafold3 import structure
-from alphafold3.constants import residue_names
-from alphafold3.cpp import mkdssp
-import jax.numpy as jnp
-import numpy as np
-from scipy import spatial
-
-
-# From Sander & Rost 1994 https://doi.org/10.1002/prot.340200303
-MAX_ACCESSIBLE_SURFACE_AREA = {
-    'ALA': 106.0,
-    'ARG': 248.0,
-    'ASN': 157.0,
-    'ASP': 163.0,
-    'CYS': 135.0,
-    'GLN': 198.0,
-    'GLU': 194.0,
-    'GLY': 84.0,
-    'HIS': 184.0,
-    'ILE': 169.0,
-    'LEU': 164.0,
-    'LYS': 205.0,
-    'MET': 188.0,
-    'PHE': 197.0,
-    'PRO': 136.0,
-    'SER': 130.0,
-    'THR': 142.0,
-    'TRP': 227.0,
-    'TYR': 222.0,
-    'VAL': 142.0,
-}
-
-# Weights for ranking confidence.
-_IPTM_WEIGHT = 0.8
-_FRACTION_DISORDERED_WEIGHT = 0.5
-_CLASH_PENALIZATION_WEIGHT = 100.0
-
-
-def windowed_solvent_accessible_area(cif: str, window: int = 25) -> np.ndarray:
-  """Implementation of AlphaFold-RSA.
-
-  AlphaFold-RSA defined in https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9601767.
-
-  Args:
-    cif: Raw cif string.
-    window: The window over which to average accessible surface area
-
-  Returns:
-    An array of size num_res that predicts disorder by using windowed solvent
-    accessible surface area.
-  """
-  result = mkdssp.get_dssp(cif, calculate_surface_accessibility=True)
-  parse_row = False
-  rasa = []
-  for row in result.splitlines():
-    if parse_row:
-      aa = row[13:14]
-      if aa == '!':
-        continue
-      aa3 = residue_names.PROTEIN_COMMON_ONE_TO_THREE.get(aa, 'ALA')
-      max_acc = MAX_ACCESSIBLE_SURFACE_AREA[aa3]
-      acc = int(row[34:38])
-      norm_acc = acc / max_acc
-      if norm_acc > 1.0:
-        norm_acc = 1.0
-      rasa.append(norm_acc)
-    if row.startswith('  #  RESIDUE'):
-      parse_row = True
-
-  half_w = (window - 1) // 2
-  pad_rasa = np.pad(rasa, (half_w, half_w), 'reflect')
-  rasa = np.convolve(pad_rasa, np.ones(window), 'valid') / window
-  return rasa
-
-
-def fraction_disordered(
-    struc: structure.Structure, rasa_disorder_cutoff: float = 0.581
-) -> float:
-  """Compute fraction of protein residues that are disordered.
-
-  Args:
-    struc: A structure to compute rASA metrics on.
-    rasa_disorder_cutoff: The threshold at which residues are considered
-      disordered. Default value taken from
-      https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9601767.
-
-  Returns:
-    The fraction of protein residues that are disordered
-    (rasa > rasa_disorder_cutoff).
-  """
-  struc = struc.filter_to_entity_type(protein=True)
-  rasa = []
-  seq_rasa = {}
-  for chain_id, chain_seq in struc.chain_single_letter_sequence().items():
-    if chain_seq in seq_rasa:
-      # We assume that identical sequences have approximately similar rasa
-      # values to speed up the computation.
-      rasa.extend(seq_rasa[chain_seq])
-      continue
-    chain_struc = struc.filter(chain_id=chain_id)
-    # Rename the chain to 'A' as MKDSSP supports only single letter chain IDs.
-    chain_struc = chain_struc.rename_chain_ids(new_id_by_old_id={chain_id: 'A'})
-    try:
-      rasa_per_residue = windowed_solvent_accessible_area(
-          chain_struc.to_mmcif()
-      )
-      seq_rasa[chain_seq] = rasa_per_residue
-      rasa.extend(rasa_per_residue)
-    except (ValueError, RuntimeError) as e:
-      logging.warning('%s: rasa calculation failed: %s', struc.name, e)
-
-  if not rasa:
-    return 0.0
-  return np.mean(np.array(rasa) > rasa_disorder_cutoff)
-
-
-def has_clash(
-    struc: structure.Structure,
-    cutoff_radius: float = 1.1,
-    min_clashes_for_overlap: int = 100,
-    min_fraction_for_overlap: float = 0.5,
-) -> bool:
-  """Determine whether the structure has at least one clashing chain.
-
-  A clashing chain is defined as having greater than 100 polymer atoms within
-  1.1A of another polymer atom, or having more than 50% of the chain with
-  clashing atoms.
-
-  Args:
-    struc: A structure to get clash metrics for.
-    cutoff_radius: atom distances under this threshold are considered a clash.
-    min_clashes_for_overlap: The minimum number of atom-atom clashes for a chain
-      to be considered overlapping.
-    min_fraction_for_overlap: The minimum fraction of atoms within a chain that
-      are clashing for the chain to be considered overlapping.
-
-  Returns:
-    True if the structure has at least one clashing chain.
-  """
-  struc = struc.filter_to_entity_type(protein=True, rna=True, dna=True)
-  if not struc.chains:
-    return False
-  coords = struc.coords
-  coord_kdtree = spatial.cKDTree(coords)
-  clashes_per_atom = coord_kdtree.query_ball_point(
-      coords, p=2.0, r=cutoff_radius
-  )
-  per_atom_has_clash = np.zeros(len(coords), dtype=np.int32)
-  for atom_idx, clashing_indices in enumerate(clashes_per_atom):
-    for clashing_idx in clashing_indices:
-      if np.abs(struc.res_id[atom_idx] - struc.res_id[clashing_idx]) > 1 or (
-          struc.chain_id[atom_idx] != struc.chain_id[clashing_idx]
-      ):
-        per_atom_has_clash[atom_idx] = True
-        break
-  for chain_id in struc.chains:
-    mask = struc.chain_id == chain_id
-    num_atoms = np.sum(mask)
-    if num_atoms == 0:
-      continue
-    num_clashes = np.sum(per_atom_has_clash * mask)
-    frac_clashes = num_clashes / num_atoms
-    if (
-        num_clashes > min_clashes_for_overlap
-        or frac_clashes > min_fraction_for_overlap
-    ):
-      return True
-  return False
-
-
-def get_ranking_score(
-    ptm: float, iptm: float, fraction_disordered_: float, has_clash_: bool
-) -> float:
-  # ipTM is NaN for single chain structures. Use pTM for such cases.
-  if np.isnan(iptm):
-    ptm_iptm_average = ptm
-  else:
-    ptm_iptm_average = _IPTM_WEIGHT * iptm + (1.0 - _IPTM_WEIGHT) * ptm
-  return (
-      ptm_iptm_average
-      + _FRACTION_DISORDERED_WEIGHT * fraction_disordered_
-      - _CLASH_PENALIZATION_WEIGHT * has_clash_
-  )
-
-
-def rank_metric(
-    full_pde: jnp.ndarray | np.ndarray, contact_probs: jnp.ndarray | np.ndarray
-) -> jnp.ndarray | np.ndarray:
-  """Compute the metric that will be used to rank predictions, higher is better.
-
-  Args:
-    full_pde: A [num_samples, num_tokens,num_tokens] matrix of predicted
-      distance errors between pairs of tokens.
-    contact_probs: A [num_tokens, num_tokens] matrix consisting of the
-      probability of contact (<8A) that is returned from the distogram head.
-
-  Returns:
-    A scalar that can be used to rank (higher is better).
-  """
-  if not isinstance(full_pde, type(contact_probs)):
-    raise ValueError('full_pde and contact_probs must be of the same type.')
-
-  if isinstance(full_pde, np.ndarray):
-    sum_fn = np.sum
-  elif isinstance(full_pde, jnp.ndarray):
-    sum_fn = jnp.sum
-  else:
-    raise ValueError('full_pde must be a numpy array or a jax array.')
-  # It was found that taking the contact_map weighted average was better than
-  # just the predicted distance error on its own.
-  return -sum_fn(full_pde * contact_probs[None, :, :], axis=(-2, -1)) / (
-      sum_fn(contact_probs) + 1e-6
-  )
-
-
-def weighted_mean(mask, value, axis):
-  return np.mean(mask * value, axis=axis) / (1e-8 + np.mean(mask, axis=axis))
-
-
-def pde_single(
-    num_tokens: int,
-    asym_ids: np.ndarray,
-    full_pde: np.ndarray,
-    contact_probs: np.ndarray,
-) -> tuple[np.ndarray, np.ndarray, np.ndarray]:
-  """Compute 1D PDE summaries.
-
-  Args:
-    num_tokens: The number of tokens (not including padding).
-    asym_ids: The asym_ids (array of shape num_tokens).
-    full_pde: A [num_samples, num_tokens, num_tokens] matrix of predicted
-      distance errors.
-    contact_probs: A [num_tokens, num_tokens] matrix consisting of the
-      probability of contact (<8A) that is returned from the distogram head.
-
-  Returns:
-    A tuple (ichain, xchain, full_chain) where:
-      `ichain` is a [num_samples, num_chains] matrix where the
-      value assigned to each chain is an average of the full PDE matrix over all
-      its within-chain interactions, weighted by `contact_probs`.
-      `xchain` is a [num_samples, num_chains] matrix where the
-      value assigned to each chain is an average of the full PDE matrix over all
-      its cross-chain interactions, weighted by `contact_probs`.
-      `full_chain` is a [num_samples, num_tokens] matrix where the
-      value assigned to each token is an average of it PDE against all tokens,
-      weighted by `contact_probs`.
-  """
-
-  full_pde = full_pde[:, :num_tokens, :num_tokens]
-  contact_probs = contact_probs[:num_tokens, :num_tokens]
-  asym_ids = asym_ids[:num_tokens]
-  unique_asym_ids = np.unique(asym_ids)
-  num_chains = len(unique_asym_ids)
-  num_samples = full_pde.shape[0]
-
-  asym_ids = asym_ids[None]
-  contact_probs = contact_probs[None]
-
-  ichain = np.zeros((num_samples, num_chains))
-  xchain = np.zeros((num_samples, num_chains))
-
-  for idx, asym_id in enumerate(unique_asym_ids):
-    my_asym_id = asym_ids == asym_id
-    imask = my_asym_id[:, :, None] * my_asym_id[:, None, :]
-    xmask = my_asym_id[:, :, None] * ~my_asym_id[:, None, :]
-    imask = imask * contact_probs
-    xmask = xmask * contact_probs
-    ichain[:, idx] = weighted_mean(mask=imask, value=full_pde, axis=(-2, -1))
-    xchain[:, idx] = weighted_mean(mask=xmask, value=full_pde, axis=(-2, -1))
-
-  full_chain = weighted_mean(mask=contact_probs, value=full_pde, axis=(-1,))
-
-  return ichain, xchain, full_chain
-
-
-def chain_pair_pde(
-    num_tokens: int, asym_ids: np.ndarray, full_pde: np.ndarray
-) -> tuple[np.ndarray, np.ndarray]:
-  """Compute predicted distance errors for all pairs of chains.
-
-  Args:
-    num_tokens: The number of tokens (not including padding).
-    asym_ids: The asym_ids (array of shape num_tokens).
-    full_pde: A [num_samples, num_tokens, num_tokens] matrix of predicted
-      distance errors.
-
-  Returns:
-    chain_pair_pred_err_mean - a [num_chains, num_chains] matrix with average
-      per chain-pair predicted distance error.
-    chain_pair_pred_err_min - a [num_chains, num_chains] matrix with min
-      per chain-pair predicted distance error.
-  """
-  full_pde = full_pde[:, :num_tokens, :num_tokens]
-  asym_ids = asym_ids[:num_tokens]
-  unique_asym_ids = np.unique(asym_ids)
-  num_chains = len(unique_asym_ids)
-  num_samples = full_pde.shape[0]
-  chain_pair_pred_err_mean = np.zeros((num_samples, num_chains, num_chains))
-  chain_pair_pred_err_min = np.zeros((num_samples, num_chains, num_chains))
-
-  for idx1, asym_id_1 in enumerate(unique_asym_ids):
-    subset = full_pde[:, asym_ids == asym_id_1, :]
-    for idx2, asym_id_2 in enumerate(unique_asym_ids):
-      subsubset = subset[:, :, asym_ids == asym_id_2]
-      chain_pair_pred_err_mean[:, idx1, idx2] = np.mean(subsubset, axis=(1, 2))
-      chain_pair_pred_err_min[:, idx1, idx2] = np.min(subsubset, axis=(1, 2))
-  return chain_pair_pred_err_mean, chain_pair_pred_err_min
-
-
-def weighted_nanmean(
-    value: np.ndarray, mask: np.ndarray, axis: int
-) -> np.ndarray:
-  """Nan-mean with weighting -- empty slices return NaN."""
-  assert mask.shape == value.shape
-  assert not np.isnan(mask).all()
-
-  nan_idxs = np.where(np.isnan(value))
-  # Need to NaN the mask to get the correct denominator weighting.
-  mask_with_nan = mask.copy()
-  mask_with_nan[nan_idxs] = np.nan
-  with warnings.catch_warnings():
-    # Mean of empty slice is ok and should return a NaN.
-    warnings.filterwarnings(action='ignore', message='Mean of empty slice')
-    warnings.filterwarnings(
-        action='ignore', message='invalid value encountered in (scalar )?divide'
-    )
-    return np.nanmean(value * mask_with_nan, axis=axis) / np.nanmean(
-        mask_with_nan, axis=axis
-    )
-
-
-def chain_pair_pae(
-    *,
-    num_tokens: int,
-    asym_ids: np.ndarray,
-    full_pae: np.ndarray,
-    mask: np.ndarray | None = None,
-    contact_probs: np.ndarray | None = None,
-) -> tuple[np.ndarray, np.ndarray, np.ndarray]:
-  """Compute predicted errors for all pairs of chains.
-
-  Args:
-    num_tokens: The number of tokens (not including padding).
-    asym_ids: The asym_ids (array of shape num_tokens).
-    full_pae: A [num_samples, num_tokens, num_tokens] matrix of predicted
-      errors.
-    mask: A [num_tokens, num_tokens] mask matrix.
-    contact_probs: A [num_tokens, num_tokens] matrix consisting of the
-      probability of contact (<8A) that is returned from the distogram head.
-
-  Returns:
-    chain_pair_pred_err_mean - a [num_chains, num_chains] matrix with average
-      per chain-pair predicted error.
-  """
-  if mask is None:
-    mask = np.ones(shape=full_pae.shape[1:], dtype=bool)
-  if contact_probs is None:
-    contact_probs = np.ones(shape=full_pae.shape[1:], dtype=float)
-  assert mask.shape == full_pae.shape[1:]
-
-  full_pae = full_pae[:, :num_tokens, :num_tokens]
-  mask = mask[:num_tokens, :num_tokens]
-  asym_ids = asym_ids[:num_tokens]
-  contact_probs = contact_probs[:num_tokens, :num_tokens]
-  unique_asym_ids = np.unique(asym_ids)
-  num_chains = len(unique_asym_ids)
-  num_samples = full_pae.shape[0]
-  chain_pair_pred_err_mean = np.zeros((num_samples, num_chains, num_chains))
-  chain_pair_pred_err_min = np.zeros((num_samples, num_chains, num_chains))
-
-  for idx1, asym_id_1 in enumerate(unique_asym_ids):
-    subset = full_pae[:, asym_ids == asym_id_1, :]
-    subset_mask = mask[asym_ids == asym_id_1, :]
-    subset_contact_probs = contact_probs[asym_ids == asym_id_1, :]
-    for idx2, asym_id_2 in enumerate(unique_asym_ids):
-      subsubset = subset[:, :, asym_ids == asym_id_2]
-      subsubset_mask = subset_mask[:, asym_ids == asym_id_2]
-      subsubset_contact_probs = subset_contact_probs[:, asym_ids == asym_id_2]
-      (flat_mask_idxs,) = np.where(subsubset_mask.flatten() > 0)
-      flat_subsubset = subsubset.reshape([num_samples, -1])
-      flat_contact_probs = subsubset_contact_probs.flatten()
-      # A ligand chain will have no valid frames if it contains fewer than
-      # three non-colinear atoms (e.g. a sodium ion).
-      if not flat_mask_idxs.size:
-        chain_pair_pred_err_mean[:, idx1, idx2] = np.nan
-        chain_pair_pred_err_min[:, idx1, idx2] = np.nan
-      else:
-        chain_pair_pred_err_min[:, idx1, idx2] = np.min(
-            flat_subsubset[:, flat_mask_idxs], axis=1
-        )
-        chain_pair_pred_err_mean[:, idx1, idx2] = weighted_mean(
-            mask=flat_contact_probs[flat_mask_idxs],
-            value=flat_subsubset[:, flat_mask_idxs],
-            axis=-1,
-        )
-  return chain_pair_pred_err_mean, chain_pair_pred_err_min, unique_asym_ids
-
-
-def reduce_chain_pair(
-    *,
-    chain_pair_met: np.ndarray,
-    num_chain_tokens: np.ndarray,
-    agg_over_col: bool,
-    agg_type: str,
-    weight_method: str,
-) -> tuple[np.ndarray, np.ndarray]:
-  """Compute 1D summaries from a chain-pair summary.
-
-  Args:
-    chain_pair_met: A [num_samples, num_chains, num_chains] aggregate matrix.
-    num_chain_tokens: A [num_chains] array of number of tokens for each chain.
-      Used for 'per_token' weighting.
-    agg_over_col: Whether to aggregate the PAE over rows (i.e. average error
-      when aligned to me) or columns (i.e. my average error when aligned to all
-      others.)
-    agg_type: The type of aggregation to use, 'mean' or 'min'.
-    weight_method: The method to use for weighting the PAE, 'per_token' or
-      'per_chain'.
-
-  Returns:
-    A tuple (ichain, xchain) where:
-      `ichain` is a [num_samples, num_chains] matrix where the
-      value assigned to each chain is an average of the full PAE matrix over all
-      its within-chain interactions, weighted by `contact_probs`.
-      `xchain` is a [num_samples, num_chains] matrix where the
-      value assigned to each chain is an average of the full PAE matrix over all
-      its cross-chain interactions, weighted by `contact_probs`.
-  """
-  num_samples, num_chains, _ = chain_pair_met.shape
-
-  ichain = chain_pair_met.diagonal(axis1=-2, axis2=-1)
-
-  if weight_method == 'per_chain':
-    chain_weight = np.ones((num_chains,), dtype=float)
-  elif weight_method == 'per_token':
-    chain_weight = num_chain_tokens
-  else:
-    raise ValueError(f'Unknown weight method: {weight_method}')
-
-  if agg_over_col:
-    agg_axis = -1
-  else:
-    agg_axis = -2
-
-  if agg_type == 'mean':
-    weight = np.ones((num_samples, num_chains, num_chains), dtype=float)
-    weight -= np.eye(num_chains, dtype=float)
-    weight *= chain_weight[None] * chain_weight[:, None]
-    xchain = weighted_nanmean(chain_pair_met, mask=weight, axis=agg_axis)
-  elif agg_type == 'min':
-    is_self = np.eye(num_chains)
-    with warnings.catch_warnings():
-      # Min over empty slice is ok and should return a NaN.
-      warnings.filterwarnings('ignore', message='All-NaN slice encountered')
-      xchain = np.nanmin(chain_pair_met + 1e8 * is_self, axis=agg_axis)
-  else:
-    raise ValueError(f'Unknown aggregation method: {agg_type}')
-
-  return ichain, xchain
-
-
-def pae_metrics(
-    num_tokens: int,
-    asym_ids: np.ndarray,
-    full_pae: np.ndarray,
-    mask: np.ndarray,
-    contact_probs: np.ndarray,
-    tm_adjusted_pae: np.ndarray,
-):
-  """PAE aggregate metrics."""
-  assert mask.shape == full_pae.shape[1:]
-  assert contact_probs.shape == full_pae.shape[1:]
-
-  chain_pair_contact_weighted, _, unique_asym_ids = chain_pair_pae(
-      num_tokens=num_tokens,
-      asym_ids=asym_ids,
-      full_pae=full_pae,
-      mask=mask,
-      contact_probs=contact_probs,
-  )
-
-  ret = {}
-  ret['chain_pair_pae_mean'], ret['chain_pair_pae_min'], _ = chain_pair_pae(
-      num_tokens=num_tokens,
-      asym_ids=asym_ids,
-      full_pae=full_pae,
-      mask=mask,
-  )
-  chain_pair_iptm = np.stack(
-      [
-          chain_pairwise_predicted_tm_scores(
-              tm_adjusted_pae=sample_tm_adjusted_pae[:num_tokens],
-              asym_id=asym_ids[:num_tokens],
-              pair_mask=mask[:num_tokens, :num_tokens],
-          )
-          for sample_tm_adjusted_pae in tm_adjusted_pae
-      ],
-      axis=0,
-  )
-
-  num_chain_tokens = np.array(
-      [sum(asym_ids == asym_id) for asym_id in unique_asym_ids]
-  )
-
-  def reduce_chain_pair_fn(chain_pair: np.ndarray):
-    def inner(agg_over_col):
-      ichain_pae, xchain_pae = reduce_chain_pair(
-          num_chain_tokens=num_chain_tokens,
-          chain_pair_met=chain_pair,
-          agg_over_col=agg_over_col,
-          agg_type='mean',
-          weight_method='per_chain',
-      )
-      return ichain_pae, xchain_pae
-
-    ichain, xchain_row_agg = inner(False)
-    _, xchain_col_agg = inner(True)
-    with warnings.catch_warnings():
-      # Mean of empty slice is ok and should return a NaN.
-      warnings.filterwarnings(action='ignore', message='Mean of empty slice')
-      xchain = np.nanmean(
-          np.stack([xchain_row_agg, xchain_col_agg], axis=0), axis=0
-      )
-    return ichain, xchain
-
-  pae_ichain, pae_xchain = reduce_chain_pair_fn(chain_pair_contact_weighted)
-  iptm_ichain, iptm_xchain = reduce_chain_pair_fn(chain_pair_iptm)
-
-  ret.update({
-      'chain_pair_iptm': chain_pair_iptm,
-      'iptm_ichain': iptm_ichain,
-      'iptm_xchain': iptm_xchain,
-      'pae_ichain': pae_ichain,
-      'pae_xchain': pae_xchain,
-  })
-
-  return ret
-
-
-def get_iptm_xchain(chain_pair_iptm: np.ndarray) -> np.ndarray:
-  """Cross chain aggregate ipTM."""
-  num_samples, num_chains, _ = chain_pair_iptm.shape
-  weight = np.ones((num_samples, num_chains, num_chains), dtype=float)
-  weight -= np.eye(num_chains, dtype=float)
-  xchain_row_agg = weighted_nanmean(chain_pair_iptm, mask=weight, axis=-2)
-  xchain_col_agg = weighted_nanmean(chain_pair_iptm, mask=weight, axis=-1)
-  with warnings.catch_warnings():
-    # Mean of empty slice is ok and should return a NaN.
-    warnings.filterwarnings(action='ignore', message='Mean of empty slice')
-    iptm_xchain = np.nanmean(
-        np.stack([xchain_row_agg, xchain_col_agg], axis=0), axis=0
-    )
-  return iptm_xchain
-
-
-def predicted_tm_score(
-    tm_adjusted_pae: np.ndarray,
-    pair_mask: np.ndarray,
-    asym_id: np.ndarray,
-    interface: bool = False,
-) -> float:
-  """Computes predicted TM alignment or predicted interface TM alignment score.
-
-  Args:
-    tm_adjusted_pae: [num_res, num_res] Relevant tensor for computing TMScore
-      values.
-    pair_mask: A [num_res, num_res] mask. The TM score will only aggregate over
-      masked-on entries.
-    asym_id: [num_res] asymmetric unit ID (the chain ID). Only needed for ipTM
-      calculation, i.e. when interface=True.
-    interface: If True, the interface predicted TM score is computed. If False,
-      the predicted TM score without any residue pair restrictions is computed.
-
-  Returns:
-   score: pTM or ipTM score.
-  """
-  num_tokens, _ = tm_adjusted_pae.shape
-  if tm_adjusted_pae.shape != (num_tokens, num_tokens):
-    raise ValueError(
-        f'Bad tm_adjusted_pae shape, expected ({num_tokens, num_tokens}), got '
-        f'{tm_adjusted_pae.shape}.'
-    )
-
-  if pair_mask.shape != (num_tokens, num_tokens):
-    raise ValueError(
-        f'Bad pair_mask shape, expected ({num_tokens, num_tokens}), got '
-        f'{pair_mask.shape}.'
-    )
-  if pair_mask.dtype != bool:
-    raise TypeError(f'Bad pair mask type, expected bool, got {pair_mask.dtype}')
-  if asym_id.shape[0] != num_tokens:
-    raise ValueError(
-        f'Bad asym_id shape, expected ({num_tokens},), got {asym_id.shape}.'
-    )
-
-  # Create pair mask.
-  if interface:
-    pair_mask = pair_mask * (asym_id[:, None] != asym_id[None, :])
-
-  # Ions and other ligands with colinear atoms have ill-defined frames.
-  if pair_mask.sum() == 0:
-    return np.nan
-
-  normed_residue_mask = pair_mask / (
-      1e-8 + np.sum(pair_mask, axis=-1, keepdims=True)
-  )
-  per_alignment = np.sum(tm_adjusted_pae * normed_residue_mask, axis=-1)
-  return per_alignment.max()
-
-
-def chain_pairwise_predicted_tm_scores(
-    tm_adjusted_pae: np.ndarray,
-    pair_mask: np.ndarray,
-    asym_id: np.ndarray,
-) -> np.ndarray:
-  """Compute predicted TM (pTM) between each pair of chains independently.
-
-  Args:
-    tm_adjusted_pae: [num_res, num_res] Relevant tensor for computing TMScore
-      values.
-    pair_mask: A [num_res, num_res] mask specifying which frames are valid.
-      Invalid frames can be the result of chains with not enough atoms (e.g.
-      ions).
-    asym_id: [num_res] asymmetric unit ID (the chain ID).
-
-  Returns:
-    A [num_chains, num_chains] matrix, where row i, column j indicates the
-    predicted TM-score for the interface between chain i and chain j.
-  """
-  unique_chains = list(np.unique(asym_id))
-  num_chains = len(unique_chains)
-  all_pairs_iptms = np.zeros((num_chains, num_chains))
-  for i, chain_i in enumerate(unique_chains):
-    chain_i_mask = asym_id == chain_i
-    for j, chain_j in enumerate(unique_chains[i:]):
-      chain_j_mask = asym_id == chain_j
-      mask = chain_i_mask | chain_j_mask
-      (indices,) = np.where(mask)
-      is_interface = chain_i != chain_j
-      indices = np.ix_(indices, indices)
-      iptm = predicted_tm_score(
-          tm_adjusted_pae=tm_adjusted_pae[indices],
-          pair_mask=pair_mask[indices],
-          asym_id=asym_id[mask],
-          interface=is_interface,
-      )
-      all_pairs_iptms[i, i + j] = iptm
-      all_pairs_iptms[i + j, i] = iptm
-  return all_pairs_iptms
diff --git a/src/alphafold3/model/data3.py b/src/alphafold3/model/data3.py
deleted file mode 100644
index b166dc47553b7027e698e62d1cdf926c7f0be1bf..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/data3.py
+++ /dev/null
@@ -1,125 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Protein features that are computed from parsed mmCIF objects."""
-
-from collections.abc import Mapping, MutableMapping
-import datetime
-from typing import TypeAlias
-
-from alphafold3.constants import residue_names
-from alphafold3.cpp import msa_profile
-from alphafold3.model import protein_data_processing
-import numpy as np
-
-
-FeatureDict: TypeAlias = Mapping[str, np.ndarray]
-MutableFeatureDict: TypeAlias = MutableMapping[str, np.ndarray]
-
-
-def fix_features(msa_features: MutableFeatureDict) -> MutableFeatureDict:
-  """Renames the deletion_matrix feature."""
-  msa_features['deletion_matrix'] = msa_features.pop('deletion_matrix_int')
-  return msa_features
-
-
-def get_profile_features(
-    msa: np.ndarray, deletion_matrix: np.ndarray
-) -> FeatureDict:
-  """Returns the MSA profile and deletion_mean features."""
-  num_restypes = residue_names.POLYMER_TYPES_NUM_WITH_UNKNOWN_AND_GAP
-  profile = msa_profile.compute_msa_profile(
-      msa=msa, num_residue_types=num_restypes
-  )
-
-  return {
-      'profile': profile.astype(np.float32),
-      'deletion_mean': np.mean(deletion_matrix, axis=0),
-  }
-
-
-def fix_template_features(
-    template_features: FeatureDict, num_res: int
-) -> FeatureDict:
-  """Convert template features to AlphaFold 3 format.
-
-  Args:
-    template_features: Template features for the protein.
-    num_res: The length of the amino acid sequence of the protein.
-
-  Returns:
-    Updated template_features for the chain.
-  """
-  if not template_features['template_aatype'].shape[0]:
-    template_features = empty_template_features(num_res)
-  else:
-    template_release_timestamp = [
-        _get_timestamp(x.decode('utf-8'))
-        for x in template_features['template_release_date']
-    ]
-
-    # Convert from atom37 to dense atom
-    dense_atom_indices = np.take(
-        protein_data_processing.PROTEIN_AATYPE_DENSE_ATOM_TO_ATOM37,
-        template_features['template_aatype'],
-        axis=0,
-    )
-
-    atom_mask = np.take_along_axis(
-        template_features['template_all_atom_masks'], dense_atom_indices, axis=2
-    )
-    atom_positions = np.take_along_axis(
-        template_features['template_all_atom_positions'],
-        dense_atom_indices[..., None],
-        axis=2,
-    )
-    atom_positions *= atom_mask[..., None]
-
-    template_features = {
-        'template_aatype': template_features['template_aatype'],
-        'template_atom_mask': atom_mask.astype(np.int32),
-        'template_atom_positions': atom_positions.astype(np.float32),
-        'template_domain_names': np.array(
-            template_features['template_domain_names'], dtype=object
-        ),
-        'template_release_timestamp': np.array(
-            template_release_timestamp, dtype=np.float32
-        ),
-    }
-  return template_features
-
-
-def empty_template_features(num_res: int) -> FeatureDict:
-  """Creates a fully masked out template features to allow padding to work.
-
-  Args:
-    num_res: The length of the target chain.
-
-  Returns:
-    Empty template features for the chain.
-  """
-  template_features = {
-      'template_aatype': np.zeros(num_res, dtype=np.int32)[None, ...],
-      'template_atom_mask': np.zeros(
-          (num_res, protein_data_processing.NUM_DENSE), dtype=np.int32
-      )[None, ...],
-      'template_atom_positions': np.zeros(
-          (num_res, protein_data_processing.NUM_DENSE, 3), dtype=np.float32
-      )[None, ...],
-      'template_domain_names': np.array([b''], dtype=object),
-      'template_release_timestamp': np.array([0.0], dtype=np.float32),
-  }
-  return template_features
-
-
-def _get_timestamp(date_str: str):
-  dt = datetime.datetime.fromisoformat(date_str)
-  dt = dt.replace(tzinfo=datetime.timezone.utc)
-  return dt.timestamp()
diff --git a/src/alphafold3/model/data_constants.py b/src/alphafold3/model/data_constants.py
deleted file mode 100644
index eabdcfda922340cfbdd1f03f0cf11c6e4692bcb2..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/data_constants.py
+++ /dev/null
@@ -1,27 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Constants shared across modules in the AlphaFold data pipeline."""
-
-from alphafold3.constants import residue_names
-
-MSA_GAP_IDX = residue_names.PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN_AND_GAP.index(
-    '-'
-)
-
-# Feature groups.
-NUM_SEQ_NUM_RES_MSA_FEATURES = ('msa', 'msa_mask', 'deletion_matrix')
-NUM_SEQ_MSA_FEATURES = ('msa_species_identifiers',)
-TEMPLATE_FEATURES = (
-    'template_aatype',
-    'template_atom_positions',
-    'template_atom_mask',
-)
-MSA_PAD_VALUES = {'msa': MSA_GAP_IDX, 'msa_mask': 1, 'deletion_matrix': 0}
diff --git a/src/alphafold3/model/diffusion/atom_cross_attention.py b/src/alphafold3/model/diffusion/atom_cross_attention.py
deleted file mode 100644
index 05be014fc8956c0a1a1c489a9b624f95a6d9ba17..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/diffusion/atom_cross_attention.py
+++ /dev/null
@@ -1,413 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Per-atom cross attention."""
-
-from alphafold3.common import base_config
-from alphafold3.model import feat_batch
-from alphafold3.model import model_config
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import utils
-from alphafold3.model.diffusion import diffusion_transformer
-import chex
-import jax
-import jax.numpy as jnp
-
-
-class AtomCrossAttEncoderConfig(base_config.BaseConfig):
-  per_token_channels: int = 768
-  per_atom_channels: int = 128
-  atom_transformer: diffusion_transformer.CrossAttTransformer.Config = (
-      base_config.autocreate(num_intermediate_factor=2, num_blocks=3)
-  )
-  per_atom_pair_channels: int = 16
-
-
-def _per_atom_conditioning(
-    config: AtomCrossAttEncoderConfig, batch: feat_batch.Batch, name: str
-) -> tuple[jnp.ndarray, jnp.ndarray]:
-  """computes single and pair conditioning for all atoms in each token."""
-
-  c = config
-  # Compute per-atom single conditioning
-  # Shape (num_tokens, num_dense, channels)
-  act = hm.Linear(
-      c.per_atom_channels, precision='highest', name=f'{name}_embed_ref_pos'
-  )(batch.ref_structure.positions)
-  act += hm.Linear(c.per_atom_channels, name=f'{name}_embed_ref_mask')(
-      batch.ref_structure.mask.astype(jnp.float32)[:, :, None]
-  )
-  # Element is encoded as atomic number if the periodic table, so
-  # 128 should be fine.
-  act += hm.Linear(c.per_atom_channels, name=f'{name}_embed_ref_element')(
-      jax.nn.one_hot(batch.ref_structure.element, 128)
-  )
-  act += hm.Linear(c.per_atom_channels, name=f'{name}_embed_ref_charge')(
-      jnp.arcsinh(batch.ref_structure.charge)[:, :, None]
-  )
-  # Characters are encoded as ASCII code minus 32, so we need 64 classes,
-  # to encode all standard ASCII characters between 32 and 96.
-  atom_name_chars_1hot = jax.nn.one_hot(batch.ref_structure.atom_name_chars, 64)
-  num_token, num_dense, _ = act.shape
-  act += hm.Linear(c.per_atom_channels, name=f'{name}_embed_ref_atom_name')(
-      atom_name_chars_1hot.reshape(num_token, num_dense, -1)
-  )
-  act *= batch.ref_structure.mask.astype(jnp.float32)[:, :, None]
-
-  # Compute pair conditioning
-  # shape (num_tokens, num_dense, num_dense, channels)
-  # Embed single features
-  row_act = hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_single_to_pair_cond_row'
-  )(jax.nn.relu(act))
-  col_act = hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_single_to_pair_cond_col'
-  )(jax.nn.relu(act))
-  pair_act = row_act[:, :, None, :] + col_act[:, None, :, :]
-  # Embed pairwise offsets
-  pair_act += hm.Linear(
-      c.per_atom_pair_channels,
-      precision='highest',
-      name=f'{name}_embed_pair_offsets',
-  )(
-      batch.ref_structure.positions[:, :, None, :]
-      - batch.ref_structure.positions[:, None, :, :]
-  )
-  # Embed pairwise inverse squared distances
-  sq_dists = jnp.sum(
-      jnp.square(
-          batch.ref_structure.positions[:, :, None, :]
-          - batch.ref_structure.positions[:, None, :, :]
-      ),
-      axis=-1,
-  )
-  pair_act += hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_embed_pair_distances'
-  )(1.0 / (1 + sq_dists[:, :, :, None]))
-
-  return act, pair_act
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class AtomCrossAttEncoderOutput:
-  token_act: jnp.ndarray  # (num_tokens, ch)
-  skip_connection: jnp.ndarray  # (num_subsets, num_queries, ch)
-  queries_mask: jnp.ndarray  # (num_subsets, num_queries)
-  queries_single_cond: jnp.ndarray  # (num_subsets, num_queries, ch)
-  keys_mask: jnp.ndarray  # (num_subsets, num_keys)
-  keys_single_cond: jnp.ndarray  # (num_subsets, num_keys, ch)
-  pair_cond: jnp.ndarray  # (num_subsets, num_queries, num_keys, ch)
-
-
-def atom_cross_att_encoder(
-    token_atoms_act: jnp.ndarray | None,  # (num_tokens, max_atoms_per_token, 3)
-    trunk_single_cond: jnp.ndarray | None,  # (num_tokens, ch)
-    trunk_pair_cond: jnp.ndarray | None,  # (num_tokens, num_tokens, ch)
-    config: AtomCrossAttEncoderConfig,
-    global_config: model_config.GlobalConfig,
-    batch: feat_batch.Batch,
-    name: str,
-) -> AtomCrossAttEncoderOutput:
-  """Cross-attention on flat atom subsets and mapping to per-token features."""
-  c = config
-
-  # Compute single conditioning from atom meta data and convert to queries
-  # layout.
-  # (num_subsets, num_queries, channels)
-  token_atoms_single_cond, _ = _per_atom_conditioning(config, batch, name)
-  token_atoms_mask = batch.predicted_structure_info.atom_mask
-  queries_single_cond = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      token_atoms_single_cond,
-      layout_axes=(-3, -2),
-  )
-  queries_mask = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      token_atoms_mask,
-      layout_axes=(-2, -1),
-  )
-
-  # If provided, broadcast single conditioning from trunk to all queries
-  if trunk_single_cond is not None:
-    trunk_single_cond = hm.Linear(
-        c.per_atom_channels,
-        precision='highest',
-        initializer=global_config.final_init,
-        name=f'{name}_embed_trunk_single_cond',
-    )(
-        hm.LayerNorm(
-            use_fast_variance=False,
-            create_offset=False,
-            name=f'{name}_lnorm_trunk_single_cond',
-        )(trunk_single_cond)
-    )
-    queries_single_cond += atom_layout.convert(
-        batch.atom_cross_att.tokens_to_queries,
-        trunk_single_cond,
-        layout_axes=(-2,),
-    )
-
-  if token_atoms_act is None:
-    # if no token_atoms_act is given (e.g. begin of evoformer), we use the
-    # static conditioning only
-    queries_act = queries_single_cond
-  else:
-    # Convert token_atoms_act to queries layout and map to per_atom_channels
-    # (num_subsets, num_queries, channels)
-    queries_act = atom_layout.convert(
-        batch.atom_cross_att.token_atoms_to_queries,
-        token_atoms_act,
-        layout_axes=(-3, -2),
-    )
-    queries_act = hm.Linear(
-        c.per_atom_channels,
-        precision='highest',
-        name=f'{name}_atom_positions_to_features',
-    )(queries_act)
-    queries_act *= queries_mask[..., None]
-    queries_act += queries_single_cond
-
-  # Gather the keys from the queries.
-  keys_single_cond = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys,
-      queries_single_cond,
-      layout_axes=(-3, -2),
-  )
-  keys_mask = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys, queries_mask, layout_axes=(-2, -1)
-  )
-
-  # Embed single features into the pair conditioning.
-  # shape (num_subsets, num_queries, num_keys, ch)
-  row_act = hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_single_to_pair_cond_row'
-  )(jax.nn.relu(queries_single_cond))
-  pair_cond_keys_input = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys,
-      queries_single_cond,
-      layout_axes=(-3, -2),
-  )
-  col_act = hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_single_to_pair_cond_col'
-  )(jax.nn.relu(pair_cond_keys_input))
-  pair_act = row_act[:, :, None, :] + col_act[:, None, :, :]
-
-  if trunk_pair_cond is not None:
-    # If provided, broadcast the pair conditioning for the trunk (evoformer
-    # pairs) to the atom pair activations. This should boost ligands, but also
-    # help for cross attention within proteins, because we always have atoms
-    # from multiple residues in a subset.
-    # Map trunk pair conditioning to per_atom_pair_channels
-    # (num_tokens, num_tokens, per_atom_pair_channels)
-    trunk_pair_cond = hm.Linear(
-        c.per_atom_pair_channels,
-        precision='highest',
-        initializer=global_config.final_init,
-        name=f'{name}_embed_trunk_pair_cond',
-    )(
-        hm.LayerNorm(
-            use_fast_variance=False,
-            create_offset=False,
-            name=f'{name}_lnorm_trunk_pair_cond',
-        )(trunk_pair_cond)
-    )
-
-    # Create the GatherInfo into a flattened trunk_pair_cond from the
-    # queries and keys gather infos.
-    num_tokens = trunk_pair_cond.shape[0]
-    # (num_subsets, num_queries)
-    tokens_to_queries = batch.atom_cross_att.tokens_to_queries
-    # (num_subsets, num_keys)
-    tokens_to_keys = batch.atom_cross_att.tokens_to_keys
-    # (num_subsets, num_queries, num_keys)
-    trunk_pair_to_atom_pair = atom_layout.GatherInfo(
-        gather_idxs=(
-            num_tokens * tokens_to_queries.gather_idxs[:, :, None]
-            + tokens_to_keys.gather_idxs[:, None, :]
-        ),
-        gather_mask=(
-            tokens_to_queries.gather_mask[:, :, None]
-            & tokens_to_keys.gather_mask[:, None, :]
-        ),
-        input_shape=jnp.array((num_tokens, num_tokens)),
-    )
-    # Gather the conditioning and add it to the atom-pair activations.
-    pair_act += atom_layout.convert(
-        trunk_pair_to_atom_pair, trunk_pair_cond, layout_axes=(-3, -2)
-    )
-
-  # Embed pairwise offsets
-  queries_ref_pos = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      batch.ref_structure.positions,
-      layout_axes=(-3, -2),
-  )
-  queries_ref_space_uid = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      batch.ref_structure.ref_space_uid,
-      layout_axes=(-2, -1),
-  )
-  keys_ref_pos = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys,
-      queries_ref_pos,
-      layout_axes=(-3, -2),
-  )
-  keys_ref_space_uid = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys,
-      batch.ref_structure.ref_space_uid,
-      layout_axes=(-2, -1),
-  )
-
-  offsets_valid = (
-      queries_ref_space_uid[:, :, None] == keys_ref_space_uid[:, None, :]
-  )
-  offsets = queries_ref_pos[:, :, None, :] - keys_ref_pos[:, None, :, :]
-  pair_act += (
-      hm.Linear(
-          c.per_atom_pair_channels,
-          precision='highest',
-          name=f'{name}_embed_pair_offsets',
-      )(offsets)
-      * offsets_valid[:, :, :, None]
-  )
-
-  # Embed pairwise inverse squared distances
-  sq_dists = jnp.sum(jnp.square(offsets), axis=-1)
-  pair_act += (
-      hm.Linear(c.per_atom_pair_channels, name=f'{name}_embed_pair_distances')(
-          1.0 / (1 + sq_dists[:, :, :, None])
-      )
-      * offsets_valid[:, :, :, None]
-  )
-  # Embed offsets valid mask
-  pair_act += hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_embed_pair_offsets_valid'
-  )(offsets_valid[:, :, :, None].astype(jnp.float32))
-
-  # Run a small MLP on the pair acitvations
-  pair_act2 = hm.Linear(
-      c.per_atom_pair_channels, initializer='relu', name=f'{name}_pair_mlp_1'
-  )(jax.nn.relu(pair_act))
-  pair_act2 = hm.Linear(
-      c.per_atom_pair_channels, initializer='relu', name=f'{name}_pair_mlp_2'
-  )(jax.nn.relu(pair_act2))
-  pair_act += hm.Linear(
-      c.per_atom_pair_channels,
-      initializer=global_config.final_init,
-      name=f'{name}_pair_mlp_3',
-  )(jax.nn.relu(pair_act2))
-
-  # Run the atom cross attention transformer.
-  queries_act = diffusion_transformer.CrossAttTransformer(
-      c.atom_transformer, global_config, name=f'{name}_atom_transformer_encoder'
-  )(
-      queries_act=queries_act,
-      queries_mask=queries_mask,
-      queries_to_keys=batch.atom_cross_att.queries_to_keys,
-      keys_mask=keys_mask,
-      queries_single_cond=queries_single_cond,
-      keys_single_cond=keys_single_cond,
-      pair_cond=pair_act,
-  )
-  queries_act *= queries_mask[..., None]
-  skip_connection = queries_act
-
-  # Convert back to token-atom layout and aggregate to tokens
-  queries_act = hm.Linear(
-      c.per_token_channels, name=f'{name}_project_atom_features_for_aggr'
-  )(queries_act)
-  token_atoms_act = atom_layout.convert(
-      batch.atom_cross_att.queries_to_token_atoms,
-      queries_act,
-      layout_axes=(-3, -2),
-  )
-  token_act = utils.mask_mean(
-      token_atoms_mask[..., None], jax.nn.relu(token_atoms_act), axis=-2
-  )
-
-  return AtomCrossAttEncoderOutput(
-      token_act=token_act,
-      skip_connection=skip_connection,
-      queries_mask=queries_mask,
-      queries_single_cond=queries_single_cond,
-      keys_mask=keys_mask,
-      keys_single_cond=keys_single_cond,
-      pair_cond=pair_act,
-  )
-
-
-class AtomCrossAttDecoderConfig(base_config.BaseConfig):
-  per_atom_channels: int = 128
-  atom_transformer: diffusion_transformer.CrossAttTransformer.Config = (
-      base_config.autocreate(num_intermediate_factor=2, num_blocks=3)
-  )
-
-
-def atom_cross_att_decoder(
-    token_act: jnp.ndarray,  # (num_tokens, ch)
-    enc: AtomCrossAttEncoderOutput,
-    config: AtomCrossAttDecoderConfig,
-    global_config: model_config.GlobalConfig,
-    batch: feat_batch.Batch,
-    name: str,
-):  # (num_tokens, max_atoms_per_token, 3)
-  """Mapping to per-atom features and self-attention on subsets."""
-  c = config
-  # map per-token act down to per_atom channels
-  token_act = hm.Linear(
-      c.per_atom_channels, name=f'{name}_project_token_features_for_broadcast'
-  )(token_act)
-  # Broadcast to token-atoms layout and convert to queries layout.
-  num_token, max_atoms_per_token = (
-      batch.atom_cross_att.queries_to_token_atoms.shape
-  )
-  token_atom_act = jnp.broadcast_to(
-      token_act[:, None, :],
-      (num_token, max_atoms_per_token, c.per_atom_channels),
-  )
-  queries_act = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      token_atom_act,
-      layout_axes=(-3, -2),
-  )
-  queries_act += enc.skip_connection
-  queries_act *= enc.queries_mask[..., None]
-
-  # Run the atom cross attention transformer.
-  queries_act = diffusion_transformer.CrossAttTransformer(
-      c.atom_transformer, global_config, name=f'{name}_atom_transformer_decoder'
-  )(
-      queries_act=queries_act,
-      queries_mask=enc.queries_mask,
-      queries_to_keys=batch.atom_cross_att.queries_to_keys,
-      keys_mask=enc.keys_mask,
-      queries_single_cond=enc.queries_single_cond,
-      keys_single_cond=enc.keys_single_cond,
-      pair_cond=enc.pair_cond,
-  )
-  queries_act *= enc.queries_mask[..., None]
-  queries_act = hm.LayerNorm(
-      use_fast_variance=False,
-      create_offset=False,
-      name=f'{name}_atom_features_layer_norm',
-  )(queries_act)
-  queries_position_update = hm.Linear(
-      3,
-      initializer=global_config.final_init,
-      precision='highest',
-      name=f'{name}_atom_features_to_position_update',
-  )(queries_act)
-  position_update = atom_layout.convert(
-      batch.atom_cross_att.queries_to_token_atoms,
-      queries_position_update,
-      layout_axes=(-3, -2),
-  )
-  return position_update
diff --git a/src/alphafold3/model/diffusion/confidence_head.py b/src/alphafold3/model/diffusion/confidence_head.py
deleted file mode 100644
index 35bd38fe00c00b1383d871c4a19b2d01b28bed8e..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/diffusion/confidence_head.py
+++ /dev/null
@@ -1,320 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Confidence Head."""
-
-from alphafold3.common import base_config
-from alphafold3.model import model_config
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import utils
-from alphafold3.model.diffusion import modules
-from alphafold3.model.diffusion import template_modules
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-def _safe_norm(x, keepdims, axis, eps=1e-8):
-  return jnp.sqrt(eps + jnp.sum(jnp.square(x), axis=axis, keepdims=keepdims))
-
-
-class ConfidenceHead(hk.Module):
-  """Head to predict the distance errors in a prediction."""
-
-  class PAEConfig(base_config.BaseConfig):
-    max_error_bin: float = 31.0
-    num_bins: int = 64
-
-  class Config(base_config.BaseConfig):
-    """Configuration for ConfidenceHead."""
-
-    pairformer: modules.PairFormerIteration.Config = base_config.autocreate(
-        single_attention=base_config.autocreate(),
-        single_transition=base_config.autocreate(),
-        num_layer=4,
-    )
-    max_error_bin: float = 31.0
-    num_plddt_bins: int = 50
-    num_bins: int = 64
-    no_embedding_prob: float = 0.2
-    pae: 'ConfidenceHead.PAEConfig' = base_config.autocreate()
-    dgram_features: template_modules.DistogramFeaturesConfig = (
-        base_config.autocreate()
-    )
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='confidence_head',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def _embed_features(
-      self,
-      dense_atom_positions,
-      token_atoms_to_pseudo_beta,
-      pair_mask,
-      pair_act,
-      target_feat,
-  ):
-    out = hm.Linear(pair_act.shape[-1], name='left_target_feat_project')(
-        target_feat
-    ).astype(pair_act.dtype)
-    out += hm.Linear(pair_act.shape[-1], name='right_target_feat_project')(
-        target_feat
-    ).astype(pair_act.dtype)[:, None]
-    positions = atom_layout.convert(
-        token_atoms_to_pseudo_beta,
-        dense_atom_positions,
-        layout_axes=(-3, -2),
-    )
-    dgram = template_modules.dgram_from_positions(
-        positions, self.config.dgram_features
-    )
-    dgram *= pair_mask[..., None]
-
-    out += hm.Linear(pair_act.shape[-1], name='distogram_feat_project')(
-        dgram.astype(pair_act.dtype)
-    )
-    return out
-
-  def __call__(
-      self,
-      dense_atom_positions: jnp.ndarray,
-      embeddings: dict[str, jnp.ndarray],
-      seq_mask: jnp.ndarray,
-      token_atoms_to_pseudo_beta: atom_layout.GatherInfo,
-      asym_id: jnp.ndarray,
-  ) -> dict[str, jnp.ndarray]:
-    """Builds ConfidenceHead module.
-
-    Arguments:
-      dense_atom_positions: [N_res, N_atom, 3] array of positions.
-      embeddings: Dictionary of representations.
-      seq_mask: Sequence mask.
-      token_atoms_to_pseudo_beta: Pseudo beta info for atom tokens.
-      asym_id: Asym ID token features.
-
-    Returns:
-      Dictionary of results.
-    """
-    dtype = (
-        jnp.bfloat16 if self.global_config.bfloat16 == 'all' else jnp.float32
-    )
-    with utils.bfloat16_context():
-      seq_mask_cast = seq_mask.astype(dtype)
-      pair_mask = seq_mask_cast[:, None] * seq_mask_cast[None, :]
-      pair_mask = pair_mask.astype(dtype)
-
-      pair_act = embeddings['pair'].astype(dtype)
-      single_act = embeddings['single'].astype(dtype)
-      target_feat = embeddings['target_feat'].astype(dtype)
-
-      num_residues = seq_mask.shape[0]
-      num_pair_channels = pair_act.shape[2]
-
-      pair_act += self._embed_features(
-          dense_atom_positions,
-          token_atoms_to_pseudo_beta,
-          pair_mask,
-          pair_act,
-          target_feat,
-      )
-
-      def pairformer_fn(act):
-        pair_act, single_act = act
-        return modules.PairFormerIteration(
-            self.config.pairformer,
-            self.global_config,
-            with_single=True,
-            name='confidence_pairformer',
-        )(
-            act=pair_act,
-            single_act=single_act,
-            pair_mask=pair_mask,
-            seq_mask=seq_mask,
-        )
-
-      pairformer_stack = hk.experimental.layer_stack(
-          self.config.pairformer.num_layer
-      )(pairformer_fn)
-
-      pair_act, single_act = pairformer_stack((pair_act, single_act))
-      pair_act = pair_act.astype(jnp.float32)
-      assert pair_act.shape == (num_residues, num_residues, num_pair_channels)
-
-      # Produce logits to predict a distogram of pairwise distance errors
-      # between the input prediction and the ground truth.
-
-      # Shape (num_res, num_res, num_bins)
-      left_distance_logits = hm.Linear(
-          self.config.num_bins,
-          initializer=self.global_config.final_init,
-          name='left_half_distance_logits',
-      )(hm.LayerNorm(name='logits_ln')(pair_act))
-      right_distance_logits = left_distance_logits
-      distance_logits = left_distance_logits + jnp.swapaxes(  # Symmetrize.
-          right_distance_logits, -2, -3
-      )
-      # Shape (num_bins,)
-      distance_breaks = jnp.linspace(
-          0.0, self.config.max_error_bin, self.config.num_bins - 1
-      )
-
-      step = distance_breaks[1] - distance_breaks[0]
-
-      # Add half-step to get the center
-      bin_centers = distance_breaks + step / 2
-      # Add a catch-all bin at the end.
-      bin_centers = jnp.concatenate(
-          [bin_centers, bin_centers[-1:] + step], axis=0
-      )
-
-      distance_probs = jax.nn.softmax(distance_logits, axis=-1)
-
-      pred_distance_error = (
-          jnp.sum(distance_probs * bin_centers, axis=-1) * pair_mask
-      )
-      average_pred_distance_error = jnp.sum(
-          pred_distance_error, axis=[-2, -1]
-      ) / jnp.sum(pair_mask, axis=[-2, -1])
-
-      # Predicted aligned error
-      pae_outputs = {}
-      # Shape (num_res, num_res, num_bins)
-      pae_logits = hm.Linear(
-          self.config.pae.num_bins,
-          initializer=self.global_config.final_init,
-          name='pae_logits',
-      )(hm.LayerNorm(name='pae_logits_ln')(pair_act))
-      # Shape (num_bins,)
-      pae_breaks = jnp.linspace(
-          0.0, self.config.pae.max_error_bin, self.config.pae.num_bins - 1
-      )
-      step = pae_breaks[1] - pae_breaks[0]
-      # Add half-step to get the center
-      bin_centers = pae_breaks + step / 2
-      # Add a catch-all bin at the end.
-      bin_centers = jnp.concatenate(
-          [bin_centers, bin_centers[-1:] + step], axis=0
-      )
-      pae_probs = jax.nn.softmax(pae_logits, axis=-1)
-
-      seq_mask_bool = seq_mask.astype(bool)
-      pair_mask_bool = seq_mask_bool[:, None] * seq_mask_bool[None, :]
-      pae = jnp.sum(pae_probs * bin_centers, axis=-1) * pair_mask_bool
-      pae_outputs.update({
-          'full_pae': pae,
-      })
-
-    # The pTM is computed outside of bfloat16 context.
-    tmscore_adjusted_pae_global, tmscore_adjusted_pae_interface = (
-        self._get_tmscore_adjusted_pae(
-            asym_id=asym_id,
-            seq_mask=seq_mask,
-            pair_mask=pair_mask_bool,
-            bin_centers=bin_centers,
-            pae_probs=pae_probs,
-        )
-    )
-    pae_outputs.update({
-        'tmscore_adjusted_pae_global': tmscore_adjusted_pae_global,
-        'tmscore_adjusted_pae_interface': tmscore_adjusted_pae_interface,
-    })
-    single_act = single_act.astype('float32')
-
-    # pLDDT
-    # Shape (num_res, num_atom, num_bins)
-    plddt_logits = hm.Linear(
-        (dense_atom_positions.shape[-2], self.config.num_plddt_bins),
-        initializer=self.global_config.final_init,
-        name='plddt_logits',
-    )(hm.LayerNorm(name='plddt_logits_ln')(single_act))
-
-    bin_width = 1.0 / self.config.num_plddt_bins
-    bin_centers = jnp.arange(0.5 * bin_width, 1.0, bin_width)
-    predicted_lddt = jnp.sum(
-        jax.nn.softmax(plddt_logits, axis=-1) * bin_centers, axis=-1
-    )
-    predicted_lddt = predicted_lddt * 100.0
-
-    # Experimentally resolved
-    # Shape (num_res, num_atom, 2)
-    experimentally_resolved_logits = hm.Linear(
-        (dense_atom_positions.shape[-2], 2),
-        initializer=self.global_config.final_init,
-        name='experimentally_resolved_logits',
-    )(hm.LayerNorm(name='experimentally_resolved_ln')(single_act))
-
-    predicted_experimentally_resolved = jax.nn.softmax(
-        experimentally_resolved_logits, axis=-1
-    )[..., 1]
-
-    return {
-        'predicted_lddt': predicted_lddt,
-        'predicted_experimentally_resolved': predicted_experimentally_resolved,
-        'full_pde': pred_distance_error,
-        'average_pde': average_pred_distance_error,
-        **pae_outputs,
-    }
-
-  def _get_tmscore_adjusted_pae(
-      self,
-      asym_id: jnp.ndarray,
-      seq_mask: jnp.ndarray,
-      pair_mask: jnp.ndarray,
-      bin_centers: jnp.ndarray,
-      pae_probs: jnp.ndarray,
-  ):
-    def get_tmscore_adjusted_pae(num_interface_tokens, bin_centers, pae_probs):
-      # Clip to avoid negative/undefined d0.
-      clipped_num_res = jnp.maximum(num_interface_tokens, 19)
-
-      # Compute d_0(num_res) as defined by TM-score, eqn. (5) in
-      # http://zhanglab.ccmb.med.umich.edu/papers/2004_3.pdf
-      # Yang & Skolnick "Scoring function for automated
-      # assessment of protein structure template quality" 2004.
-      d0 = 1.24 * (clipped_num_res - 15) ** (1.0 / 3) - 1.8
-
-      # Make compatible with [num_tokens, num_tokens, num_bins]
-      d0 = d0[:, :, None]
-      bin_centers = bin_centers[None, None, :]
-
-      # TM-Score term for every bin.
-      tm_per_bin = 1.0 / (1 + jnp.square(bin_centers) / jnp.square(d0))
-      # E_distances tm(distance).
-      predicted_tm_term = jnp.sum(pae_probs * tm_per_bin, axis=-1)
-      return predicted_tm_term
-
-    # Interface version
-    x = asym_id[None, :] == asym_id[:, None]
-    num_chain_tokens = jnp.sum(x * pair_mask, axis=-1)
-    num_interface_tokens = num_chain_tokens[None, :] + num_chain_tokens[:, None]
-    # Don't double-count within a single chain
-    num_interface_tokens -= x * (num_interface_tokens // 2)
-    num_interface_tokens = num_interface_tokens * pair_mask
-
-    num_global_tokens = jnp.full(
-        shape=pair_mask.shape, fill_value=seq_mask.sum()
-    )
-
-    assert num_global_tokens.dtype == 'int32'
-    assert num_interface_tokens.dtype == 'int32'
-    global_apae = get_tmscore_adjusted_pae(
-        num_global_tokens, bin_centers, pae_probs
-    )
-    interface_apae = get_tmscore_adjusted_pae(
-        num_interface_tokens, bin_centers, pae_probs
-    )
-    return global_apae, interface_apae
diff --git a/src/alphafold3/model/diffusion/diffusion_head.py b/src/alphafold3/model/diffusion/diffusion_head.py
deleted file mode 100644
index 89bc95981b8be154fbc4f48a0416038b9ea4d020..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/diffusion/diffusion_head.py
+++ /dev/null
@@ -1,375 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Diffusion Head."""
-
-from collections.abc import Callable
-
-from alphafold3.common import base_config
-from alphafold3.model import feat_batch
-from alphafold3.model import model_config
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import utils
-from alphafold3.model.diffusion import atom_cross_attention
-from alphafold3.model.diffusion import diffusion_transformer
-from alphafold3.model.diffusion import featurization
-import chex
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-# Carefully measured by averaging multimer training set.
-SIGMA_DATA = 16.0
-
-
-def fourier_embeddings(x: jnp.ndarray, dim: int) -> jnp.ndarray:
-  w_key, b_key = jax.random.split(jax.random.PRNGKey(42))
-  weight = jax.random.normal(w_key, shape=[dim])
-  bias = jax.random.uniform(b_key, shape=[dim])
-  return jnp.cos(2 * jnp.pi * (x[..., None] * weight + bias))
-
-
-def random_rotation(key):
-  # Create a random rotation (Gram-Schmidt orthogonalization of two
-  # random normal vectors)
-  v0, v1 = jax.random.normal(key, shape=(2, 3))
-  e0 = v0 / jnp.maximum(1e-10, jnp.linalg.norm(v0))
-  v1 = v1 - e0 * jnp.dot(v1, e0, precision=jax.lax.Precision.HIGHEST)
-  e1 = v1 / jnp.maximum(1e-10, jnp.linalg.norm(v1))
-  e2 = jnp.cross(e0, e1)
-  return jnp.stack([e0, e1, e2])
-
-
-def random_augmentation(
-    rng_key: jnp.ndarray,
-    positions: jnp.ndarray,
-    mask: jnp.ndarray,
-) -> jnp.ndarray:
-  """Apply random rigid augmentation.
-
-  Args:
-    rng_key: random key
-    positions: atom positions of shape (<common_axes>, 3)
-    mask: per-atom mask of shape (<common_axes>,)
-
-  Returns:
-    Transformed positions with the same shape as input positions.
-  """
-  rotation_key, translation_key = jax.random.split(rng_key)
-
-  center = utils.mask_mean(
-      mask[..., None], positions, axis=(-2, -3), keepdims=True, eps=1e-6
-  )
-  rot = random_rotation(rotation_key)
-  translation = jax.random.normal(translation_key, shape=(3,))
-
-  augmented_positions = (
-      jnp.einsum(
-          '...i,ij->...j',
-          positions - center,
-          rot,
-          precision=jax.lax.Precision.HIGHEST,
-      )
-      + translation
-  )
-  return augmented_positions * mask[..., None]
-
-
-def noise_schedule(t, smin=0.0004, smax=160.0, p=7):
-  return (
-      SIGMA_DATA
-      * (smax ** (1 / p) + t * (smin ** (1 / p) - smax ** (1 / p))) ** p
-  )
-
-
-class ConditioningConfig(base_config.BaseConfig):
-  pair_channel: int
-  seq_channel: int
-  prob: float
-
-
-class SampleConfig(base_config.BaseConfig):
-  steps: int
-  gamma_0: float = 0.8
-  gamma_min: float = 1.0
-  noise_scale: float = 1.003
-  step_scale: float = 1.5
-  num_samples: int = 1
-
-
-class DiffusionHead(hk.Module):
-  """Denoising Diffusion Head."""
-
-  class Config(
-      atom_cross_attention.AtomCrossAttEncoderConfig,
-      atom_cross_attention.AtomCrossAttDecoderConfig,
-  ):
-    """Configuration for DiffusionHead."""
-
-    eval_batch_size: int = 5
-    eval_batch_dim_shard_size: int = 5
-    conditioning: ConditioningConfig = base_config.autocreate(
-        prob=0.8, pair_channel=128, seq_channel=384
-    )
-    eval: SampleConfig = base_config.autocreate(
-        num_samples=5,
-        steps=200,
-    )
-    transformer: diffusion_transformer.Transformer.Config = (
-        base_config.autocreate()
-    )
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='diffusion_head',
-  ):
-    self.config = config
-    self.global_config = global_config
-    super().__init__(name=name)
-
-  @hk.transparent
-  def _conditioning(
-      self,
-      batch: feat_batch.Batch,
-      embeddings: dict[str, jnp.ndarray],
-      noise_level: jnp.ndarray,
-      use_conditioning: bool,
-  ) -> tuple[jnp.ndarray, jnp.ndarray]:
-    single_embedding = use_conditioning * embeddings['single']
-    pair_embedding = use_conditioning * embeddings['pair']
-
-    rel_features = featurization.create_relative_encoding(
-        batch.token_features, max_relative_idx=32, max_relative_chain=2
-    ).astype(pair_embedding.dtype)
-    features_2d = jnp.concatenate([pair_embedding, rel_features], axis=-1)
-    pair_cond = hm.Linear(
-        self.config.conditioning.pair_channel,
-        precision='highest',
-        name='pair_cond_initial_projection',
-    )(
-        hm.LayerNorm(
-            use_fast_variance=False,
-            create_offset=False,
-            name='pair_cond_initial_norm',
-        )(features_2d)
-    )
-
-    for idx in range(2):
-      pair_cond += diffusion_transformer.transition_block(
-          pair_cond, 2, self.global_config, name=f'pair_transition_{idx}'
-      )
-
-    target_feat = embeddings['target_feat']
-    features_1d = jnp.concatenate([single_embedding, target_feat], axis=-1)
-    single_cond = hm.LayerNorm(
-        use_fast_variance=False,
-        create_offset=False,
-        name='single_cond_initial_norm',
-    )(features_1d)
-    single_cond = hm.Linear(
-        self.config.conditioning.seq_channel,
-        precision='highest',
-        name='single_cond_initial_projection',
-    )(single_cond)
-
-    noise_embedding = fourier_embeddings(
-        (1 / 4) * jnp.log(noise_level / SIGMA_DATA), dim=256
-    )
-    single_cond += hm.Linear(
-        self.config.conditioning.seq_channel,
-        precision='highest',
-        name='noise_embedding_initial_projection',
-    )(
-        hm.LayerNorm(
-            use_fast_variance=False,
-            create_offset=False,
-            name='noise_embedding_initial_norm',
-        )(noise_embedding)
-    )
-
-    for idx in range(2):
-      single_cond += diffusion_transformer.transition_block(
-          single_cond, 2, self.global_config, name=f'single_transition_{idx}'
-      )
-
-    return single_cond, pair_cond
-
-  def __call__(
-      self,
-      # positions_noisy.shape: (num_token, max_atoms_per_token, 3)
-      positions_noisy: jnp.ndarray,
-      noise_level: jnp.ndarray,
-      batch: feat_batch.Batch,
-      embeddings: dict[str, jnp.ndarray],
-      use_conditioning: bool,
-  ) -> jnp.ndarray:
-
-    with utils.bfloat16_context():
-      # Get conditioning
-      trunk_single_cond, trunk_pair_cond = self._conditioning(
-          batch=batch,
-          embeddings=embeddings,
-          noise_level=noise_level,
-          use_conditioning=use_conditioning,
-      )
-
-      # Extract features
-      sequence_mask = batch.token_features.mask
-      atom_mask = batch.predicted_structure_info.atom_mask
-
-      # Position features
-      act = positions_noisy * atom_mask[..., None]
-      act = act / jnp.sqrt(noise_level**2 + SIGMA_DATA**2)
-
-      enc = atom_cross_attention.atom_cross_att_encoder(
-          token_atoms_act=act,
-          trunk_single_cond=embeddings['single'],
-          trunk_pair_cond=trunk_pair_cond,
-          config=self.config,
-          global_config=self.global_config,
-          batch=batch,
-          name='diffusion',
-      )
-      act = enc.token_act
-
-      # Token-token attention
-      chex.assert_shape(act, (None, self.config.per_token_channels))
-      act = jnp.asarray(act, dtype=jnp.float32)
-
-      act += hm.Linear(
-          act.shape[-1],
-          precision='highest',
-          initializer=self.global_config.final_init,
-          name='single_cond_embedding_projection',
-      )(
-          hm.LayerNorm(
-              use_fast_variance=False,
-              create_offset=False,
-              name='single_cond_embedding_norm',
-          )(trunk_single_cond)
-      )
-
-      act = jnp.asarray(act, dtype=jnp.float32)
-      trunk_single_cond = jnp.asarray(trunk_single_cond, dtype=jnp.float32)
-      trunk_pair_cond = jnp.asarray(trunk_pair_cond, dtype=jnp.float32)
-      sequence_mask = jnp.asarray(sequence_mask, dtype=jnp.float32)
-
-      transformer = diffusion_transformer.Transformer(
-          self.config.transformer, self.global_config
-      )
-      act = transformer(
-          act=act,
-          single_cond=trunk_single_cond,
-          mask=sequence_mask,
-          pair_cond=trunk_pair_cond,
-      )
-      act = hm.LayerNorm(
-          use_fast_variance=False, create_offset=False, name='output_norm'
-      )(act)
-      # (n_tokens, per_token_channels)
-
-      # (Possibly) atom-granularity decoder
-      assert isinstance(enc, atom_cross_attention.AtomCrossAttEncoderOutput)
-      position_update = atom_cross_attention.atom_cross_att_decoder(
-          token_act=act,
-          enc=enc,
-          config=self.config,
-          global_config=self.global_config,
-          batch=batch,
-          name='diffusion',
-      )
-
-      skip_scaling = SIGMA_DATA**2 / (noise_level**2 + SIGMA_DATA**2)
-      out_scaling = (
-          noise_level * SIGMA_DATA / jnp.sqrt(noise_level**2 + SIGMA_DATA**2)
-      )
-    # End `with utils.bfloat16_context()`.
-
-    return (
-        skip_scaling * positions_noisy + out_scaling * position_update
-    ) * atom_mask[..., None]
-
-
-def sample(
-    denoising_step: Callable[[jnp.ndarray, jnp.ndarray], jnp.ndarray],
-    batch: feat_batch.Batch,
-    key: jnp.ndarray,
-    config: SampleConfig,
-) -> dict[str, jnp.ndarray]:
-  """Sample using denoiser on batch.
-
-  Args:
-    denoising_step: the denoising function.
-    batch: the batch
-    key: random key
-    config: config for the sampling process (e.g. number of denoising steps,
-      etc.)
-
-  Returns:
-    a dict
-      {
-         'atom_positions': jnp.array(...)       # shape (<common_axes>, 3)
-         'mask': jnp.array(...)                 # shape (<common_axes>,)
-      }
-    where the <common_axes> are
-    (num_samples, num_tokens, max_atoms_per_token)
-  """
-
-  mask = batch.predicted_structure_info.atom_mask
-
-  def apply_denoising_step(carry, noise_level):
-    key, positions, noise_level_prev = carry
-    key, key_noise, key_aug = jax.random.split(key, 3)
-
-    positions = random_augmentation(
-        rng_key=key_aug, positions=positions, mask=mask
-    )
-
-    gamma = config.gamma_0 * (noise_level > config.gamma_min)
-    t_hat = noise_level_prev * (1 + gamma)
-
-    noise_scale = config.noise_scale * jnp.sqrt(t_hat**2 - noise_level_prev**2)
-    noise = noise_scale * jax.random.normal(key_noise, positions.shape)
-    positions_noisy = positions + noise
-
-    positions_denoised = denoising_step(positions_noisy, t_hat)
-    grad = (positions_noisy - positions_denoised) / t_hat
-
-    d_t = noise_level - t_hat
-    positions_out = positions_noisy + config.step_scale * d_t * grad
-
-    return (key, positions_out, noise_level), positions_out
-
-  num_samples = config.num_samples
-
-  noise_levels = noise_schedule(jnp.linspace(0, 1, config.steps + 1))
-
-  key, noise_key = jax.random.split(key)
-  positions = jax.random.normal(noise_key, (num_samples,) + mask.shape + (3,))
-  positions *= noise_levels[0]
-
-  init = (
-      jax.random.split(key, num_samples),
-      positions,
-      jnp.tile(noise_levels[None, 0], (num_samples,)),
-  )
-
-  apply_denoising_step = hk.vmap(
-      apply_denoising_step, in_axes=(0, None), split_rng=(not hk.running_init())
-  )
-  result, _ = hk.scan(apply_denoising_step, init, noise_levels[1:], unroll=4)
-  _, positions_out, _ = result
-
-  final_dense_atom_mask = jnp.tile(mask[None], (num_samples, 1, 1))
-
-  return {'atom_positions': positions_out, 'mask': final_dense_atom_mask}
diff --git a/src/alphafold3/model/diffusion/diffusion_transformer.py b/src/alphafold3/model/diffusion/diffusion_transformer.py
deleted file mode 100644
index 58823e8a54c31993e77ef1b647bb6cac8a95d399..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/diffusion/diffusion_transformer.py
+++ /dev/null
@@ -1,404 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Diffusion transformer model."""
-
-from alphafold3.common import base_config
-from alphafold3.jax.gated_linear_unit import gated_linear_unit
-from alphafold3.model import model_config
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.model.components import haiku_modules as hm
-import haiku as hk
-import jax
-from jax import numpy as jnp
-
-
-def adaptive_layernorm(x, single_cond, name):
-  """Adaptive LayerNorm."""
-  # Adopted from Scalable Diffusion Models with Transformers
-  # https://arxiv.org/abs/2212.09748
-  if single_cond is None:
-    x = hm.LayerNorm(name=f'{name}layer_norm', use_fast_variance=False)(x)
-  else:
-    x = hm.LayerNorm(
-        name=f'{name}layer_norm',
-        use_fast_variance=False,
-        create_scale=False,
-        create_offset=False,
-    )(x)
-    single_cond = hm.LayerNorm(
-        name=f'{name}single_cond_layer_norm',
-        use_fast_variance=False,
-        create_offset=False,
-    )(single_cond)
-    single_scale = hm.Linear(
-        x.shape[-1],
-        initializer='zeros',
-        use_bias=True,
-        name=f'{name}single_cond_scale',
-    )(single_cond)
-    single_bias = hm.Linear(
-        x.shape[-1], initializer='zeros', name=f'{name}single_cond_bias'
-    )(single_cond)
-    x = jax.nn.sigmoid(single_scale) * x + single_bias
-  return x
-
-
-def adaptive_zero_init(
-    x, num_channels, single_cond, global_config: model_config.GlobalConfig, name
-):
-  """Adaptive zero init, from AdaLN-zero."""
-  if single_cond is None:
-    output = hm.Linear(
-        num_channels,
-        initializer=global_config.final_init,
-        name=f'{name}transition2',
-    )(x)
-  else:
-    output = hm.Linear(num_channels, name=f'{name}transition2')(x)
-    # Init to a small gain, sigmoid(-2) ~ 0.1
-    cond = hm.Linear(
-        output.shape[-1],
-        initializer='zeros',
-        use_bias=True,
-        bias_init=-2.0,
-        name=f'{name}adaptive_zero_cond',
-    )(single_cond)
-    output = jax.nn.sigmoid(cond) * output
-  return output
-
-
-def transition_block(
-    x: jnp.ndarray,
-    num_intermediate_factor: int,
-    global_config: model_config.GlobalConfig,
-    single_cond: jnp.ndarray | None = None,
-    use_glu_kernel: bool = True,
-    name: str = '',
-) -> jnp.ndarray:
-  """Transition Block."""
-  num_channels = x.shape[-1]
-  num_intermediates = num_intermediate_factor * num_channels
-
-  x = adaptive_layernorm(x, single_cond, name=f'{name}ffw_')
-
-  if use_glu_kernel:
-    weights, _ = hm.haiku_linear_get_params(
-        x,
-        num_output=num_intermediates * 2,
-        initializer='relu',
-        name=f'{name}ffw_transition1',
-    )
-    weights = jnp.reshape(weights, (len(weights), 2, num_intermediates))
-    c = gated_linear_unit.gated_linear_unit(
-        x=x, weight=weights, implementation=None, activation=jax.nn.swish
-    )
-  else:
-    x = hm.Linear(
-        num_intermediates * 2, initializer='relu', name=f'{name}ffw_transition1'
-    )(x)
-    a, b = jnp.split(x, 2, axis=-1)
-    c = jax.nn.swish(a) * b
-
-  output = adaptive_zero_init(
-      c, num_channels, single_cond, global_config, f'{name}ffw_'
-  )
-  return output
-
-
-class SelfAttentionConfig(base_config.BaseConfig):
-  num_head: int = 16
-  key_dim: int | None = None
-  value_dim: int | None = None
-
-
-def self_attention(
-    x: jnp.ndarray,  # (num_tokens, ch)
-    mask: jnp.ndarray,  # (num_tokens,)
-    pair_logits: jnp.ndarray | None,  # (num_heads, num_tokens, num_tokens)
-    config: SelfAttentionConfig,
-    global_config: model_config.GlobalConfig,
-    single_cond: jnp.ndarray | None = None,  # (num_tokens, ch)
-    name: str = '',
-) -> jnp.ndarray:
-  """Multihead self-attention."""
-  assert len(mask.shape) == len(x.shape) - 1, f'{mask.shape}, {x.shape}'
-  # bias: ... x heads (1) x query (1) x key
-  bias = (1e9 * (mask - 1.0))[..., None, None, :]
-
-  x = adaptive_layernorm(x, single_cond, name=name)
-
-  num_channels = x.shape[-1]
-  # Sensible default for when the config keys are missing
-  key_dim = config.key_dim if config.key_dim is not None else num_channels
-  value_dim = config.value_dim if config.value_dim is not None else num_channels
-  num_head = config.num_head
-  assert key_dim % num_head == 0, f'{key_dim=} % {num_head=} != 0'
-  assert value_dim % num_head == 0, f'{value_dim=} % {num_head=} != 0'
-  key_dim = key_dim // num_head
-  value_dim = value_dim // num_head
-
-  qk_shape = (num_head, key_dim)
-  q = hm.Linear(qk_shape, use_bias=True, name=f'{name}q_projection')(x)
-  k = hm.Linear(qk_shape, use_bias=False, name=f'{name}k_projection')(x)
-
-  # In some situations the gradient norms can blow up without running this
-  # einsum in float32.
-  q = q.astype(jnp.float32)
-  k = k.astype(jnp.float32)
-  bias = bias.astype(jnp.float32)
-  logits = jnp.einsum('...qhc,...khc->...hqk', q * key_dim ** (-0.5), k) + bias
-  if pair_logits is not None:
-    logits += pair_logits  # (num_heads, seq_len, seq_len)
-  weights = jax.nn.softmax(logits, axis=-1)
-  weights = jnp.asarray(weights, dtype=x.dtype)
-
-  v_shape = (num_head, value_dim)
-  v = hm.Linear(v_shape, use_bias=False, name=f'{name}v_projection')(x)
-  weighted_avg = jnp.einsum('...hqk,...khc->...qhc', weights, v)
-  weighted_avg = jnp.reshape(weighted_avg, weighted_avg.shape[:-2] + (-1,))
-
-  gate_logits = hm.Linear(
-      num_head * value_dim,
-      bias_init=1.0,
-      initializer='zeros',
-      name=f'{name}gating_query',
-  )(x)
-  weighted_avg *= jax.nn.sigmoid(gate_logits)
-
-  output = adaptive_zero_init(
-      weighted_avg, num_channels, single_cond, global_config, name
-  )
-  return output
-
-
-class Transformer(hk.Module):
-  """Simple transformer stack."""
-
-  class Config(base_config.BaseConfig):
-    attention: SelfAttentionConfig = base_config.autocreate()
-    num_blocks: int = 24
-    block_remat: bool = False
-    super_block_size: int = 4
-    num_intermediate_factor: int = 2
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name: str = 'transformer',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      act: jnp.ndarray,
-      mask: jnp.ndarray,
-      single_cond: jnp.ndarray,
-      pair_cond: jnp.ndarray | None,
-  ) -> jnp.ndarray:
-    def block(act, pair_logits):
-      act += self_attention(
-          act,
-          mask,
-          pair_logits,
-          self.config.attention,
-          self.global_config,
-          single_cond,
-          name=self.name,
-      )
-      act += transition_block(
-          act,
-          self.config.num_intermediate_factor,
-          self.global_config,
-          single_cond,
-          name=self.name,
-      )
-      return act, None
-
-    # Precompute pair logits for performance
-    if pair_cond is None:
-      pair_act = None
-    else:
-      pair_act = hm.LayerNorm(
-          name='pair_input_layer_norm',
-          use_fast_variance=False,
-          create_offset=False,
-      )(pair_cond)
-
-    assert self.config.num_blocks % self.config.super_block_size == 0
-    num_super_blocks = self.config.num_blocks // self.config.super_block_size
-
-    def super_block(act):
-      if pair_act is None:
-        pair_logits = None
-      else:
-        pair_logits = hm.Linear(
-            (self.config.super_block_size, self.config.attention.num_head),
-            name='pair_logits_projection',
-        )(pair_act)
-        pair_logits = jnp.transpose(pair_logits, [2, 3, 0, 1])
-      return hk.experimental.layer_stack(
-          self.config.super_block_size, with_per_layer_inputs=True
-      )(block)(act, pair_logits)
-
-    return hk.experimental.layer_stack(
-        num_super_blocks, with_per_layer_inputs=True
-    )(super_block)(act)[0]
-
-
-class CrossAttentionConfig(base_config.BaseConfig):
-  num_head: int = 4
-  key_dim: int = 128
-  value_dim: int = 128
-
-
-def cross_attention(
-    x_q: jnp.ndarray,  # (..., Q, C)
-    x_k: jnp.ndarray,  # (..., K, C)
-    mask_q: jnp.ndarray,  # (..., Q)
-    mask_k: jnp.ndarray,  # (..., K)
-    config: CrossAttentionConfig,
-    global_config: model_config.GlobalConfig,
-    pair_logits: jnp.ndarray | None = None,  # (..., Q, K)
-    single_cond_q: jnp.ndarray | None = None,  # (..., Q, C)
-    single_cond_k: jnp.ndarray | None = None,  # (..., K, C)
-    name: str = '',
-) -> jnp.ndarray:
-  """Multihead self-attention."""
-  assert len(mask_q.shape) == len(x_q.shape) - 1, f'{mask_q.shape}, {x_q.shape}'
-  assert len(mask_k.shape) == len(x_k.shape) - 1, f'{mask_k.shape}, {x_k.shape}'
-  # bias: ... x heads (1) x query x key
-  bias = (
-      1e9
-      * (mask_q - 1.0)[..., None, :, None]
-      * (mask_k - 1.0)[..., None, None, :]
-  )
-
-  x_q = adaptive_layernorm(x_q, single_cond_q, name=f'{name}q')
-  x_k = adaptive_layernorm(x_k, single_cond_k, name=f'{name}k')
-
-  assert config.key_dim % config.num_head == 0
-  assert config.value_dim % config.num_head == 0
-  key_dim = config.key_dim // config.num_head
-  value_dim = config.value_dim // config.num_head
-
-  q = hm.Linear(
-      (config.num_head, key_dim), use_bias=True, name=f'{name}q_projection'
-  )(x_q)
-  k = hm.Linear(
-      (config.num_head, key_dim), use_bias=False, name=f'{name}k_projection'
-  )(x_k)
-
-  # In some situations the gradient norms can blow up without running this
-  # einsum in float32.
-  q = q.astype(jnp.float32)
-  k = k.astype(jnp.float32)
-  bias = bias.astype(jnp.float32)
-  logits = jnp.einsum('...qhc,...khc->...hqk', q * key_dim ** (-0.5), k) + bias
-  if pair_logits is not None:
-    logits += pair_logits
-  weights = jax.nn.softmax(logits, axis=-1)
-  weights = jnp.asarray(weights, dtype=x_q.dtype)
-
-  v = hm.Linear(
-      (config.num_head, value_dim), use_bias=False, name=f'{name}v_projection'
-  )(x_k)
-  weighted_avg = jnp.einsum('...hqk,...khc->...qhc', weights, v)
-  weighted_avg = jnp.reshape(weighted_avg, weighted_avg.shape[:-2] + (-1,))
-
-  gate_logits = hm.Linear(
-      config.num_head * value_dim,
-      bias_init=1.0,
-      initializer='zeros',
-      name=f'{name}gating_query',
-  )(x_q)
-  weighted_avg *= jax.nn.sigmoid(gate_logits)
-
-  output = adaptive_zero_init(
-      weighted_avg, x_q.shape[-1], single_cond_q, global_config, name
-  )
-  return output
-
-
-class CrossAttTransformer(hk.Module):
-  """Transformer that applies cross attention between two sets of subsets."""
-
-  class Config(base_config.BaseConfig):
-    num_intermediate_factor: int
-    num_blocks: int
-    attention: CrossAttentionConfig = base_config.autocreate()
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name: str = 'transformer',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      queries_act: jnp.ndarray,  # (num_subsets, num_queries, ch)
-      queries_mask: jnp.ndarray,  # (num_subsets, num_queries)
-      queries_to_keys: atom_layout.GatherInfo,  # (num_subsets, num_keys)
-      keys_mask: jnp.ndarray,  # (num_subsets, num_keys)
-      queries_single_cond: jnp.ndarray,  # (num_subsets, num_queries, ch)
-      keys_single_cond: jnp.ndarray,  # (num_subsets, num_keys, ch)
-      pair_cond: jnp.ndarray,  # (num_subsets, num_queries, num_keys, ch)
-  ) -> jnp.ndarray:
-    def block(queries_act, pair_logits):
-      # copy the queries activations to the keys layout
-      keys_act = atom_layout.convert(
-          queries_to_keys, queries_act, layout_axes=(-3, -2)
-      )
-      # cross attention
-      queries_act += cross_attention(
-          x_q=queries_act,
-          x_k=keys_act,
-          mask_q=queries_mask,
-          mask_k=keys_mask,
-          config=self.config.attention,
-          global_config=self.global_config,
-          pair_logits=pair_logits,
-          single_cond_q=queries_single_cond,
-          single_cond_k=keys_single_cond,
-          name=self.name,
-      )
-      queries_act += transition_block(
-          queries_act,
-          self.config.num_intermediate_factor,
-          self.global_config,
-          queries_single_cond,
-          name=self.name,
-      )
-      return queries_act, None
-
-    # Precompute pair logits for performance
-    pair_act = hm.LayerNorm(
-        name='pair_input_layer_norm',
-        use_fast_variance=False,
-        create_offset=False,
-    )(pair_cond)
-    # (num_subsets, num_queries, num_keys, num_blocks, num_heads)
-    pair_logits = hm.Linear(
-        (self.config.num_blocks, self.config.attention.num_head),
-        name='pair_logits_projection',
-    )(pair_act)
-    # (num_block, num_subsets, num_heads, num_queries, num_keys)
-    pair_logits = jnp.transpose(pair_logits, [3, 0, 4, 1, 2])
-
-    return hk.experimental.layer_stack(
-        self.config.num_blocks, with_per_layer_inputs=True
-    )(block)(queries_act, pair_logits)[0]
diff --git a/src/alphafold3/model/diffusion/distogram_head.py b/src/alphafold3/model/diffusion/distogram_head.py
deleted file mode 100644
index 810eccba210b64e404d9a7751021b480e95874ed..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/diffusion/distogram_head.py
+++ /dev/null
@@ -1,81 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Distogram head."""
-
-from typing import Final
-
-from alphafold3.common import base_config
-from alphafold3.model import feat_batch
-from alphafold3.model import model_config
-from alphafold3.model.components import haiku_modules as hm
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-_CONTACT_THRESHOLD: Final[float] = 8.0
-_CONTACT_EPSILON: Final[float] = 1e-3
-
-
-class DistogramHead(hk.Module):
-  """Distogram head."""
-
-  class Config(base_config.BaseConfig):
-    first_break: float = 2.3125
-    last_break: float = 21.6875
-    num_bins: int = 64
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='distogram_head',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      batch: feat_batch.Batch,
-      embeddings: dict[str, jnp.ndarray],
-  ) -> dict[str, jnp.ndarray]:
-    pair_act = embeddings['pair']
-    seq_mask = batch.token_features.mask.astype(bool)
-    pair_mask = seq_mask[:, None] * seq_mask[None, :]
-
-    left_half_logits = hm.Linear(
-        self.config.num_bins,
-        initializer=self.global_config.final_init,
-        name='half_logits',
-    )(pair_act)
-
-    right_half_logits = left_half_logits
-    logits = left_half_logits + jnp.swapaxes(right_half_logits, -2, -3)
-    probs = jax.nn.softmax(logits, axis=-1)
-    breaks = jnp.linspace(
-        self.config.first_break,
-        self.config.last_break,
-        self.config.num_bins - 1,
-    )
-
-    bin_tops = jnp.append(breaks, breaks[-1] + (breaks[-1] - breaks[-2]))
-    threshold = _CONTACT_THRESHOLD + _CONTACT_EPSILON
-    is_contact_bin = 1.0 * (bin_tops <= threshold)
-    contact_probs = jnp.einsum(
-        'ijk,k->ij', probs, is_contact_bin, precision=jax.lax.Precision.HIGHEST
-    )
-    contact_probs = pair_mask * contact_probs
-
-    return {
-        'bin_edges': breaks,
-        'contact_probs': contact_probs,
-    }
diff --git a/src/alphafold3/model/diffusion/featurization.py b/src/alphafold3/model/diffusion/featurization.py
deleted file mode 100644
index 9b6e4c2db85fd450b609f5078f5fb2ac2bb3e3b7..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/diffusion/featurization.py
+++ /dev/null
@@ -1,269 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Model-side of the input features processing."""
-
-import functools
-
-from alphafold3.constants import residue_names
-from alphafold3.model import feat_batch
-from alphafold3.model import features
-from alphafold3.model.components import utils
-import chex
-import jax
-import jax.numpy as jnp
-
-
-def _grid_keys(key, shape):
-  """Generate a grid of rng keys that is consistent with different padding.
-
-  Generate random keys such that the keys will be identical, regardless of
-  how much padding is added to any dimension.
-
-  Args:
-    key: A PRNG key.
-    shape: The shape of the output array of keys that will be generated.
-
-  Returns:
-    An array of shape `shape` consisting of random keys.
-  """
-  if not shape:
-    return key
-  new_keys = jax.vmap(functools.partial(jax.random.fold_in, key))(
-      jnp.arange(shape[0])
-  )
-  return jax.vmap(functools.partial(_grid_keys, shape=shape[1:]))(new_keys)
-
-
-def _padding_consistent_rng(f):
-  """Modify any element-wise random function to be consistent with padding.
-
-  Normally if you take a function like jax.random.normal and generate an array,
-  say of size (10,10), you will get a different set of random numbers to if you
-  add padding and take the first (10,10) sub-array.
-
-  This function makes a random function that is consistent regardless of the
-  amount of padding added.
-
-  Note: The padding-consistent function is likely to be slower to compile and
-  run than the function it is wrapping, but these slowdowns are likely to be
-  negligible in a large network.
-
-  Args:
-    f: Any element-wise function that takes (PRNG key, shape) as the first 2
-      arguments.
-
-  Returns:
-    An equivalent function to f, that is now consistent for different amounts of
-    padding.
-  """
-
-  def inner(key, shape, **kwargs):
-    keys = _grid_keys(key, shape)
-    signature = (
-        '()->()'
-        if jax.dtypes.issubdtype(keys.dtype, jax.dtypes.prng_key)
-        else '(2)->()'
-    )
-    return jnp.vectorize(
-        functools.partial(f, shape=(), **kwargs), signature=signature
-    )(keys)
-
-  return inner
-
-
-def gumbel_argsort_sample_idx(
-    key: jnp.ndarray, logits: jnp.ndarray
-) -> jnp.ndarray:
-  """Samples with replacement from a distribution given by 'logits'.
-
-  This uses Gumbel trick to implement the sampling an efficient manner. For a
-  distribution over k items this samples k times without replacement, so this
-  is effectively sampling a random permutation with probabilities over the
-  permutations derived from the logprobs.
-
-  Args:
-    key: prng key
-    logits: logarithm of probabilities to sample from, probabilities can be
-      unnormalized.
-
-  Returns:
-    Sample from logprobs in one-hot form.
-  """
-  gumbel = _padding_consistent_rng(jax.random.gumbel)
-  z = gumbel(key, logits.shape)
-  # This construction is equivalent to jnp.argsort, but using a non stable sort,
-  # since stable sort's aren't supported by jax2tf
-  axis = len(logits.shape) - 1
-  iota = jax.lax.broadcasted_iota(jnp.int64, logits.shape, axis)
-  _, perm = jax.lax.sort_key_val(
-      logits + z, iota, dimension=-1, is_stable=False
-  )
-  return perm[::-1]
-
-
-def create_msa_feat(msa: features.MSA) -> chex.ArrayDevice:
-  """Create and concatenate MSA features."""
-  msa_1hot = jax.nn.one_hot(
-      msa.rows, residue_names.POLYMER_TYPES_NUM_WITH_UNKNOWN_AND_GAP + 1
-  )
-  deletion_matrix = msa.deletion_matrix
-  has_deletion = jnp.clip(deletion_matrix, 0.0, 1.0)[..., None]
-  deletion_value = (jnp.arctan(deletion_matrix / 3.0) * (2.0 / jnp.pi))[
-      ..., None
-  ]
-
-  msa_feat = [
-      msa_1hot,
-      has_deletion,
-      deletion_value,
-  ]
-
-  return jnp.concatenate(msa_feat, axis=-1)
-
-
-def truncate_msa_batch(msa: features.MSA, num_msa: int) -> features.MSA:
-  indices = jnp.arange(num_msa)
-  return msa.index_msa_rows(indices)
-
-
-def create_target_feat(
-    batch: feat_batch.Batch,
-    append_per_atom_features: bool,
-) -> chex.ArrayDevice:
-  """Make target feat."""
-  token_features = batch.token_features
-  target_features = []
-  target_features.append(
-      jax.nn.one_hot(
-          token_features.aatype,
-          residue_names.POLYMER_TYPES_NUM_WITH_UNKNOWN_AND_GAP,
-      )
-  )
-  target_features.append(batch.msa.profile)
-  target_features.append(batch.msa.deletion_mean[..., None])
-
-  # Reference structure features
-  if append_per_atom_features:
-    ref_mask = batch.ref_structure.mask
-    element_feat = jax.nn.one_hot(batch.ref_structure.element, 128)
-    element_feat = utils.mask_mean(
-        mask=ref_mask[..., None], value=element_feat, axis=-2, eps=1e-6
-    )
-    target_features.append(element_feat)
-    pos_feat = batch.ref_structure.positions
-    pos_feat = pos_feat.reshape([pos_feat.shape[0], -1])
-    target_features.append(pos_feat)
-    target_features.append(ref_mask)
-
-  return jnp.concatenate(target_features, axis=-1)
-
-
-def create_relative_encoding(
-    seq_features: features.TokenFeatures,
-    max_relative_idx: int,
-    max_relative_chain: int,
-) -> chex.ArrayDevice:
-  """Add relative position encodings."""
-  rel_feats = []
-  token_index = seq_features.token_index
-  residue_index = seq_features.residue_index
-  asym_id = seq_features.asym_id
-  entity_id = seq_features.entity_id
-  sym_id = seq_features.sym_id
-
-  left_asym_id = asym_id[:, None]
-  right_asym_id = asym_id[None, :]
-
-  left_residue_index = residue_index[:, None]
-  right_residue_index = residue_index[None, :]
-
-  left_token_index = token_index[:, None]
-  right_token_index = token_index[None, :]
-
-  left_entity_id = entity_id[:, None]
-  right_entity_id = entity_id[None, :]
-
-  left_sym_id = sym_id[:, None]
-  right_sym_id = sym_id[None, :]
-
-  # Embed relative positions using a one-hot embedding of distance along chain
-  offset = left_residue_index - right_residue_index
-  clipped_offset = jnp.clip(
-      offset + max_relative_idx, a_min=0, a_max=2 * max_relative_idx
-  )
-  asym_id_same = left_asym_id == right_asym_id
-  final_offset = jnp.where(
-      asym_id_same,
-      clipped_offset,
-      (2 * max_relative_idx + 1) * jnp.ones_like(clipped_offset),
-  )
-  rel_pos = jax.nn.one_hot(final_offset, 2 * max_relative_idx + 2)
-  rel_feats.append(rel_pos)
-
-  # Embed relative token index as a one-hot embedding of distance along residue
-  token_offset = left_token_index - right_token_index
-  clipped_token_offset = jnp.clip(
-      token_offset + max_relative_idx, a_min=0, a_max=2 * max_relative_idx
-  )
-  residue_same = (left_asym_id == right_asym_id) & (
-      left_residue_index == right_residue_index
-  )
-  final_token_offset = jnp.where(
-      residue_same,
-      clipped_token_offset,
-      (2 * max_relative_idx + 1) * jnp.ones_like(clipped_token_offset),
-  )
-  rel_token = jax.nn.one_hot(final_token_offset, 2 * max_relative_idx + 2)
-  rel_feats.append(rel_token)
-
-  # Embed same entity ID
-  entity_id_same = left_entity_id == right_entity_id
-  rel_feats.append(entity_id_same.astype(rel_pos.dtype)[..., None])
-
-  # Embed relative chain ID inside each symmetry class
-  rel_sym_id = left_sym_id - right_sym_id
-
-  max_rel_chain = max_relative_chain
-
-  clipped_rel_chain = jnp.clip(
-      rel_sym_id + max_rel_chain, a_min=0, a_max=2 * max_rel_chain
-  )
-
-  final_rel_chain = jnp.where(
-      entity_id_same,
-      clipped_rel_chain,
-      (2 * max_rel_chain + 1) * jnp.ones_like(clipped_rel_chain),
-  )
-  rel_chain = jax.nn.one_hot(final_rel_chain, 2 * max_relative_chain + 2)
-
-  rel_feats.append(rel_chain)
-
-  return jnp.concatenate(rel_feats, axis=-1)
-
-
-def shuffle_msa(
-    key: jax.Array, msa: features.MSA
-) -> tuple[features.MSA, jax.Array]:
-  """Shuffle MSA randomly, return batch with shuffled MSA.
-
-  Args:
-    key: rng key for random number generation.
-    msa: MSA object to sample msa from.
-
-  Returns:
-    Protein with sampled msa.
-  """
-  key, sample_key = jax.random.split(key)
-  # Sample uniformly among sequences with at least one non-masked position.
-  logits = (jnp.clip(jnp.sum(msa.mask, axis=-1), 0.0, 1.0) - 1.0) * 1e6
-  index_order = gumbel_argsort_sample_idx(sample_key, logits)
-
-  return msa.index_msa_rows(index_order), key
diff --git a/src/alphafold3/model/diffusion/model.py b/src/alphafold3/model/diffusion/model.py
deleted file mode 100644
index b6ab1495c13863e0b52a08cf0e8cf449cb0dcbf7..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/diffusion/model.py
+++ /dev/null
@@ -1,800 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Diffusion model."""
-
-from collections.abc import Iterable
-import concurrent
-import functools
-
-from absl import logging
-from alphafold3 import structure
-from alphafold3.common import base_config
-from alphafold3.model import confidences
-from alphafold3.model import feat_batch
-from alphafold3.model import features
-from alphafold3.model import model_config
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.model.components import base_model
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import mapping
-from alphafold3.model.components import utils
-from alphafold3.model.diffusion import atom_cross_attention
-from alphafold3.model.diffusion import confidence_head
-from alphafold3.model.diffusion import diffusion_head
-from alphafold3.model.diffusion import distogram_head
-from alphafold3.model.diffusion import featurization
-from alphafold3.model.diffusion import modules
-from alphafold3.model.diffusion import template_modules
-from alphafold3.structure import mmcif
-import haiku as hk
-import jax
-import jax.numpy as jnp
-import numpy as np
-
-
-def get_predicted_structure(
-    result: base_model.ModelResult, batch: feat_batch.Batch
-) -> structure.Structure:
-  """Creates the predicted structure and ion preditions.
-
-  Args:
-    result: model output in a model specific layout
-    batch: model input batch
-
-  Returns:
-    Predicted structure.
-  """
-  model_output_coords = result['diffusion_samples']['atom_positions']
-
-  # Rearrange model output coordinates to the flat output layout.
-  model_output_to_flat = atom_layout.compute_gather_idxs(
-      source_layout=batch.convert_model_output.token_atoms_layout,
-      target_layout=batch.convert_model_output.flat_output_layout,
-  )
-  pred_flat_atom_coords = atom_layout.convert(
-      gather_info=model_output_to_flat,
-      arr=model_output_coords,
-      layout_axes=(-3, -2),
-  )
-
-  predicted_lddt = result.get('predicted_lddt')
-
-  if predicted_lddt is not None:
-    pred_flat_b_factors = atom_layout.convert(
-        gather_info=model_output_to_flat,
-        arr=predicted_lddt,
-        layout_axes=(-2, -1),
-    )
-  else:
-    # Handle models which don't have predicted_lddt outputs.
-    pred_flat_b_factors = np.zeros(pred_flat_atom_coords.shape[:-1])
-
-  (missing_atoms_indices,) = np.nonzero(model_output_to_flat.gather_mask == 0)
-  if missing_atoms_indices.shape[0] > 0:
-    missing_atoms_flat_layout = batch.convert_model_output.flat_output_layout[
-        missing_atoms_indices
-    ]
-    missing_atoms_uids = list(
-        zip(
-            missing_atoms_flat_layout.chain_id,
-            missing_atoms_flat_layout.res_id,
-            missing_atoms_flat_layout.res_name,
-            missing_atoms_flat_layout.atom_name,
-        )
-    )
-    logging.warning(
-        'Target %s: warning: %s atoms were not predicted by the '
-        'model, setting their coordinates to (0, 0, 0). '
-        'Missing atoms: %s',
-        batch.convert_model_output.empty_output_struc.name,
-        missing_atoms_indices.shape[0],
-        missing_atoms_uids,
-    )
-
-  # Put them into a structure
-  pred_struc = batch.convert_model_output.empty_output_struc
-  pred_struc = pred_struc.copy_and_update_atoms(
-      atom_x=pred_flat_atom_coords[..., 0],
-      atom_y=pred_flat_atom_coords[..., 1],
-      atom_z=pred_flat_atom_coords[..., 2],
-      atom_b_factor=pred_flat_b_factors,
-      atom_occupancy=np.ones(pred_flat_atom_coords.shape[:-1]),  # Always 1.0.
-  )
-  # Set manually/differently when adding metadata.
-  pred_struc = pred_struc.copy_and_update_globals(release_date=None)
-  return pred_struc
-
-
-def create_target_feat_embedding(
-    batch: feat_batch.Batch,
-    config: 'Evoformer.Config',
-    global_config: model_config.GlobalConfig,
-) -> jnp.ndarray:
-  """Create target feature embedding."""
-
-  dtype = jnp.bfloat16 if global_config.bfloat16 == 'all' else jnp.float32
-
-  with utils.bfloat16_context():
-    target_feat = featurization.create_target_feat(
-        batch,
-        append_per_atom_features=False,
-    ).astype(dtype)
-
-    enc = atom_cross_attention.atom_cross_att_encoder(
-        token_atoms_act=None,
-        trunk_single_cond=None,
-        trunk_pair_cond=None,
-        config=config.per_atom_conditioning,
-        global_config=global_config,
-        batch=batch,
-        name='evoformer_conditioning',
-    )
-    target_feat = jnp.concatenate([target_feat, enc.token_act], axis=-1).astype(
-        dtype
-    )
-
-  return target_feat
-
-
-def _compute_ptm(
-    result: base_model.ModelResult,
-    num_tokens: int,
-    asym_id: np.ndarray,
-    pae_single_mask: np.ndarray,
-    interface: bool,
-) -> np.ndarray:
-  """Computes the pTM metrics from PAE."""
-  return np.stack(
-      [
-          confidences.predicted_tm_score(
-              tm_adjusted_pae=tm_adjusted_pae[:num_tokens, :num_tokens],
-              asym_id=asym_id,
-              pair_mask=pae_single_mask[:num_tokens, :num_tokens],
-              interface=interface,
-          )
-          for tm_adjusted_pae in result['tmscore_adjusted_pae_global']
-      ],
-      axis=0,
-  )
-
-
-def _compute_chain_pair_iptm(
-    num_tokens: int,
-    asym_ids: np.ndarray,
-    mask: np.ndarray,
-    tm_adjusted_pae: np.ndarray,
-) -> np.ndarray:
-  """Computes the chain pair ipTM metrics from PAE."""
-  return np.stack(
-      [
-          confidences.chain_pairwise_predicted_tm_scores(
-              tm_adjusted_pae=sample_tm_adjusted_pae[:num_tokens],
-              asym_id=asym_ids[:num_tokens],
-              pair_mask=mask[:num_tokens, :num_tokens],
-          )
-          for sample_tm_adjusted_pae in tm_adjusted_pae
-      ],
-      axis=0,
-  )
-
-
-class Diffuser(hk.Module):
-  """Full Diffusion network."""
-
-  class HeadsConfig(base_config.BaseConfig):
-    diffusion: diffusion_head.DiffusionHead.Config = base_config.autocreate()
-    confidence: confidence_head.ConfidenceHead.Config = base_config.autocreate()
-    distogram: distogram_head.DistogramHead.Config = base_config.autocreate()
-
-  class Config(base_config.BaseConfig):
-    evoformer: 'Evoformer.Config' = base_config.autocreate()
-    global_config: model_config.GlobalConfig = base_config.autocreate()
-    heads: 'Diffuser.HeadsConfig' = base_config.autocreate()
-    num_recycles: int = 10
-
-  def __init__(self, config: Config, name: str = 'diffuser'):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = config.global_config
-    self.diffusion_module = diffusion_head.DiffusionHead(
-        self.config.heads.diffusion, self.global_config
-    )
-
-  @hk.transparent
-  def _sample_diffusion(
-      self,
-      batch: feat_batch.Batch,
-      embeddings: dict[str, jnp.ndarray],
-      *,
-      sample_config: diffusion_head.SampleConfig,
-  ) -> dict[str, jnp.ndarray]:
-    denoising_step = functools.partial(
-        self.diffusion_module,
-        batch=batch,
-        embeddings=embeddings,
-        use_conditioning=True,
-    )
-
-    sample = diffusion_head.sample(
-        denoising_step=denoising_step,
-        batch=batch,
-        key=hk.next_rng_key(),
-        config=sample_config,
-    )
-    return sample
-
-  def __call__(
-      self, batch: features.BatchDict, key: jax.Array | None = None
-  ) -> base_model.ModelResult:
-    if key is None:
-      key = hk.next_rng_key()
-
-    batch = feat_batch.Batch.from_data_dict(batch)
-
-    embedding_module = Evoformer(self.config.evoformer, self.global_config)
-    target_feat = create_target_feat_embedding(
-        batch=batch,
-        config=embedding_module.config,
-        global_config=self.global_config,
-    )
-
-    def recycle_body(_, args):
-      prev, key = args
-      key, subkey = jax.random.split(key)
-      embeddings = embedding_module(
-          batch=batch,
-          prev=prev,
-          target_feat=target_feat,
-          key=subkey,
-      )
-      embeddings['pair'] = embeddings['pair'].astype(jnp.float32)
-      embeddings['single'] = embeddings['single'].astype(jnp.float32)
-      return embeddings, key
-
-    num_res = batch.num_res
-
-    embeddings = {
-        'pair': jnp.zeros(
-            [num_res, num_res, self.config.evoformer.pair_channel],
-            dtype=jnp.float32,
-        ),
-        'single': jnp.zeros(
-            [num_res, self.config.evoformer.seq_channel], dtype=jnp.float32
-        ),
-        'target_feat': target_feat,
-    }
-    if hk.running_init():
-      embeddings, _ = recycle_body(None, (embeddings, key))
-    else:
-      # Number of recycles is number of additional forward trunk passes.
-      num_iter = self.config.num_recycles + 1
-      embeddings, _ = hk.fori_loop(0, num_iter, recycle_body, (embeddings, key))
-
-    samples = self._sample_diffusion(
-        batch,
-        embeddings,
-        sample_config=self.config.heads.diffusion.eval,
-    )
-
-    # Compute dist_error_fn over all samples for distance error logging.
-    confidence_output = mapping.sharded_map(
-        lambda dense_atom_positions: confidence_head.ConfidenceHead(
-            self.config.heads.confidence, self.global_config
-        )(
-            dense_atom_positions=dense_atom_positions,
-            embeddings=embeddings,
-            seq_mask=batch.token_features.mask,
-            token_atoms_to_pseudo_beta=batch.pseudo_beta_info.token_atoms_to_pseudo_beta,
-            asym_id=batch.token_features.asym_id,
-        ),
-        in_axes=0,
-    )(samples['atom_positions'])
-
-    distogram = distogram_head.DistogramHead(
-        self.config.heads.distogram, self.global_config
-    )(batch, embeddings)
-
-    return {
-        'diffusion_samples': samples,
-        'distogram': distogram,
-        **confidence_output,
-    }
-
-  @classmethod
-  def get_inference_result(
-      cls,
-      batch: features.BatchDict,
-      result: base_model.ModelResult,
-      target_name: str = '',
-  ) -> Iterable[base_model.InferenceResult]:
-    """Get the predicted structure, scalars, and arrays for inference.
-
-    This function also computes any inference-time quantities, which are not a
-    part of the forward-pass, e.g. additional confidence scores. Note that this
-    function is not serialized, so it should be slim if possible.
-
-    Args:
-      batch: data batch used for model inference, incl. TPU invalid types.
-      result: output dict from the model's forward pass.
-      target_name: target name to be saved within structure.
-
-    Yields:
-      inference_result: dataclass object that contains a predicted structure,
-      important inference-time scalars and arrays, as well as a slightly trimmed
-      dictionary of raw model result from the forward pass (for debugging).
-    """
-    del target_name
-    batch = feat_batch.Batch.from_data_dict(batch)
-
-    # Retrieve structure and construct a predicted structure.
-    pred_structure = get_predicted_structure(result=result, batch=batch)
-
-    num_tokens = batch.token_features.seq_length.item()
-
-    pae_single_mask = np.tile(
-        batch.frames.mask[:, None],
-        [1, batch.frames.mask.shape[0]],
-    )
-    ptm = _compute_ptm(
-        result=result,
-        num_tokens=num_tokens,
-        asym_id=batch.token_features.asym_id[:num_tokens],
-        pae_single_mask=pae_single_mask,
-        interface=False,
-    )
-    iptm = _compute_ptm(
-        result=result,
-        num_tokens=num_tokens,
-        asym_id=batch.token_features.asym_id[:num_tokens],
-        pae_single_mask=pae_single_mask,
-        interface=True,
-    )
-    ptm_iptm_average = 0.8 * iptm + 0.2 * ptm
-
-    asym_ids = batch.token_features.asym_id[:num_tokens]
-    chain_ids = [mmcif.int_id_to_str_id(asym_id) for asym_id in asym_ids]
-    res_ids = batch.token_features.residue_index[:num_tokens]
-
-    if len(np.unique(asym_ids[:num_tokens])) > 1:
-      # There is more than one chain, hence interface pTM (i.e. ipTM) defined,
-      # so use it.
-      ranking_confidence = ptm_iptm_average
-    else:
-      # There is only one chain, hence ipTM=NaN, so use just pTM.
-      ranking_confidence = ptm
-
-    contact_probs = result['distogram']['contact_probs']
-    # Compute PAE related summaries.
-    _, chain_pair_pae_min, _ = confidences.chain_pair_pae(
-        num_tokens=num_tokens,
-        asym_ids=batch.token_features.asym_id,
-        full_pae=result['full_pae'],
-        mask=pae_single_mask,
-    )
-    chain_pair_pde_mean, chain_pair_pde_min = confidences.chain_pair_pde(
-        num_tokens=num_tokens,
-        asym_ids=batch.token_features.asym_id,
-        full_pde=result['full_pde'],
-    )
-    intra_chain_single_pde, cross_chain_single_pde, _ = confidences.pde_single(
-        num_tokens,
-        batch.token_features.asym_id,
-        result['full_pde'],
-        contact_probs,
-    )
-    pae_metrics = confidences.pae_metrics(
-        num_tokens=num_tokens,
-        asym_ids=batch.token_features.asym_id,
-        full_pae=result['full_pae'],
-        mask=pae_single_mask,
-        contact_probs=contact_probs,
-        tm_adjusted_pae=result['tmscore_adjusted_pae_interface'],
-    )
-    ranking_confidence_pae = confidences.rank_metric(
-        result['full_pae'],
-        contact_probs * batch.frames.mask[:, None].astype(float),
-    )
-    chain_pair_iptm = _compute_chain_pair_iptm(
-        num_tokens=num_tokens,
-        asym_ids=batch.token_features.asym_id,
-        mask=pae_single_mask,
-        tm_adjusted_pae=result['tmscore_adjusted_pae_interface'],
-    )
-    # iptm_ichain is a vector of per-chain ptm values. iptm_ichain[0],
-    # for example, is just the zeroth diagonal entry of the chain pair iptm
-    # matrix:
-    # [[x, , ],
-    #  [ , , ],
-    #  [ , , ]]]
-    iptm_ichain = chain_pair_iptm.diagonal(axis1=-2, axis2=-1)
-    # iptm_xchain is a vector of cross-chain interactions for each chain.
-    # iptm_xchain[0], for example, is an average of chain 0's interactions with
-    # other chains:
-    # [[ ,x,x],
-    #  [x, , ],
-    #  [x, , ]]]
-    iptm_xchain = confidences.get_iptm_xchain(chain_pair_iptm)
-
-    predicted_distance_errors = result['average_pde']
-
-    # Computing solvent accessible area with dssp can be slow for large
-    # structures with lots of chains, so we parallelize the call.
-    pred_structures = pred_structure.unstack()
-    num_workers = len(pred_structures)
-    with concurrent.futures.ThreadPoolExecutor(
-        max_workers=num_workers
-    ) as executor:
-      has_clash = list(executor.map(confidences.has_clash, pred_structures))
-      fraction_disordered = list(
-          executor.map(confidences.fraction_disordered, pred_structures)
-      )
-
-    for idx, pred_structure in enumerate(pred_structures):
-      ranking_score = confidences.get_ranking_score(
-          ptm=ptm[idx],
-          iptm=iptm[idx],
-          fraction_disordered_=fraction_disordered[idx],
-          has_clash_=has_clash[idx],
-      )
-      yield base_model.InferenceResult(
-          predicted_structure=pred_structure,
-          numerical_data={
-              'full_pde': result['full_pde'][idx, :num_tokens, :num_tokens],
-              'full_pae': result['full_pae'][idx, :num_tokens, :num_tokens],
-              'contact_probs': contact_probs[:num_tokens, :num_tokens],
-          },
-          metadata={
-              'predicted_distance_error': predicted_distance_errors[idx],
-              'ranking_score': ranking_score,
-              'fraction_disordered': fraction_disordered[idx],
-              'has_clash': has_clash[idx],
-              'predicted_tm_score': ptm[idx],
-              'interface_predicted_tm_score': iptm[idx],
-              'chain_pair_pde_mean': chain_pair_pde_mean[idx],
-              'chain_pair_pde_min': chain_pair_pde_min[idx],
-              'chain_pair_pae_min': chain_pair_pae_min[idx],
-              'ptm': ptm[idx],
-              'iptm': iptm[idx],
-              'ptm_iptm_average': ptm_iptm_average[idx],
-              'intra_chain_single_pde': intra_chain_single_pde[idx],
-              'cross_chain_single_pde': cross_chain_single_pde[idx],
-              'pae_ichain': pae_metrics['pae_ichain'][idx],
-              'pae_xchain': pae_metrics['pae_xchain'][idx],
-              'ranking_confidence': ranking_confidence[idx],
-              'ranking_confidence_pae': ranking_confidence_pae[idx],
-              'chain_pair_iptm': chain_pair_iptm[idx],
-              'iptm_ichain': iptm_ichain[idx],
-              'iptm_xchain': iptm_xchain[idx],
-              'token_chain_ids': chain_ids,
-              'token_res_ids': res_ids,
-          },
-          model_id=result['__identifier__'],
-      )
-
-
-class Evoformer(hk.Module):
-  """Creates 'single' and 'pair' embeddings."""
-
-  class PairformerConfig(modules.PairFormerIteration.Config):  # pytype: disable=invalid-function-definition
-    block_remat: bool = False
-    remat_block_size: int = 8
-
-  class Config(base_config.BaseConfig):
-    """Configuration for Evoformer."""
-
-    max_relative_chain: int = 2
-    msa_channel: int = 64
-    seq_channel: int = 384
-    max_relative_idx: int = 32
-    num_msa: int = 1024
-    pair_channel: int = 128
-    pairformer: 'Evoformer.PairformerConfig' = base_config.autocreate(
-        single_transition=base_config.autocreate(),
-        single_attention=base_config.autocreate(),
-        num_layer=48,
-    )
-    per_atom_conditioning: atom_cross_attention.AtomCrossAttEncoderConfig = (
-        base_config.autocreate(
-            per_token_channels=384,
-            per_atom_channels=128,
-            atom_transformer=base_config.autocreate(
-                num_intermediate_factor=2,
-                num_blocks=3,
-            ),
-            per_atom_pair_channels=16,
-        )
-    )
-    template: template_modules.TemplateEmbedding.Config = (
-        base_config.autocreate()
-    )
-    msa_stack: modules.EvoformerIteration.Config = base_config.autocreate()
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='evoformer',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def _relative_encoding(
-      self, batch: feat_batch.Batch, pair_activations: jnp.ndarray
-  ) -> jnp.ndarray:
-    """Add relative position encodings."""
-    rel_feat = featurization.create_relative_encoding(
-        batch.token_features,
-        self.config.max_relative_idx,
-        self.config.max_relative_chain,
-    )
-    rel_feat = rel_feat.astype(pair_activations.dtype)
-
-    pair_activations += hm.Linear(
-        self.config.pair_channel, name='position_activations'
-    )(rel_feat)
-    return pair_activations
-
-  @hk.transparent
-  def _seq_pair_embedding(
-      self,
-      token_features: features.TokenFeatures,
-      target_feat: jnp.ndarray,
-  ) -> tuple[jnp.ndarray, jnp.ndarray]:
-    """Generated Pair embedding from sequence."""
-    left_single = hm.Linear(self.config.pair_channel, name='left_single')(
-        target_feat
-    )[:, None]
-    right_single = hm.Linear(self.config.pair_channel, name='right_single')(
-        target_feat
-    )[None]
-    dtype = left_single.dtype
-    pair_activations = left_single + right_single
-    num_residues = pair_activations.shape[0]
-    assert pair_activations.shape == (
-        num_residues,
-        num_residues,
-        self.config.pair_channel,
-    )
-    mask = token_features.mask
-    pair_mask = (mask[:, None] * mask[None, :]).astype(dtype)
-    assert pair_mask.shape == (num_residues, num_residues)
-    return pair_activations, pair_mask  # pytype: disable=bad-return-type  # jax-ndarray
-
-  @hk.transparent
-  def _embed_bonds(
-      self,
-      batch: feat_batch.Batch,
-      pair_activations: jnp.ndarray,
-  ) -> jnp.ndarray:
-    """Embeds bond features and merges into pair activations."""
-    # Construct contact matrix.
-    num_tokens = batch.token_features.token_index.shape[0]
-    contact_matrix = jnp.zeros((num_tokens, num_tokens))
-
-    tokens_to_polymer_ligand_bonds = (
-        batch.polymer_ligand_bond_info.tokens_to_polymer_ligand_bonds
-    )
-    gather_idxs_polymer_ligand = tokens_to_polymer_ligand_bonds.gather_idxs
-    gather_mask_polymer_ligand = (
-        tokens_to_polymer_ligand_bonds.gather_mask.prod(axis=1).astype(
-            gather_idxs_polymer_ligand.dtype
-        )[:, None]
-    )
-    # If valid mask then it will be all 1's, so idxs should be unchanged.
-    gather_idxs_polymer_ligand = (
-        gather_idxs_polymer_ligand * gather_mask_polymer_ligand
-    )
-
-    tokens_to_ligand_ligand_bonds = (
-        batch.ligand_ligand_bond_info.tokens_to_ligand_ligand_bonds
-    )
-    gather_idxs_ligand_ligand = tokens_to_ligand_ligand_bonds.gather_idxs
-    gather_mask_ligand_ligand = tokens_to_ligand_ligand_bonds.gather_mask.prod(
-        axis=1
-    ).astype(gather_idxs_ligand_ligand.dtype)[:, None]
-    gather_idxs_ligand_ligand = (
-        gather_idxs_ligand_ligand * gather_mask_ligand_ligand
-    )
-
-    gather_idxs = jnp.concatenate(
-        [gather_idxs_polymer_ligand, gather_idxs_ligand_ligand]
-    )
-    contact_matrix = contact_matrix.at[
-        gather_idxs[:, 0], gather_idxs[:, 1]
-    ].set(1.0)
-
-    # Because all the padded index's are 0's.
-    contact_matrix = contact_matrix.at[0, 0].set(0.0)
-
-    bonds_act = hm.Linear(self.config.pair_channel, name='bond_embedding')(
-        contact_matrix[:, :, None].astype(pair_activations.dtype)
-    )
-    return pair_activations + bonds_act
-
-  @hk.transparent
-  def _embed_template_pair(
-      self,
-      batch: feat_batch.Batch,
-      pair_activations: jnp.ndarray,
-      pair_mask: jnp.ndarray,
-      key: jnp.ndarray,
-  ) -> tuple[jnp.ndarray, jnp.ndarray]:
-    """Embeds Templates and merges into pair activations."""
-    dtype = pair_activations.dtype
-    key, subkey = jax.random.split(key)
-    template_module = template_modules.TemplateEmbedding(
-        self.config.template, self.global_config
-    )
-    templates = batch.templates
-    asym_id = batch.token_features.asym_id
-    # Construct a mask such that only intra-chain template features are
-    # computed, since all templates are for each chain individually.
-    multichain_mask = (asym_id[:, None] == asym_id[None, :]).astype(dtype)
-
-    template_fn = functools.partial(template_module, key=subkey)
-    template_act = template_fn(
-        query_embedding=pair_activations,
-        templates=templates,
-        multichain_mask_2d=multichain_mask,
-        padding_mask_2d=pair_mask,
-    )
-    return pair_activations + template_act, key
-
-  @hk.transparent
-  def _embed_process_msa(
-      self,
-      msa_batch: features.MSA,
-      pair_activations: jnp.ndarray,
-      pair_mask: jnp.ndarray,
-      key: jnp.ndarray,
-      target_feat: jnp.ndarray,
-  ) -> tuple[jnp.ndarray, jnp.ndarray]:
-    """Processes MSA and returns updated pair activations."""
-    dtype = pair_activations.dtype
-    msa_batch, key = featurization.shuffle_msa(key, msa_batch)
-    msa_batch = featurization.truncate_msa_batch(msa_batch, self.config.num_msa)
-    msa_feat = featurization.create_msa_feat(msa_batch).astype(dtype)
-
-    msa_activations = hm.Linear(
-        self.config.msa_channel, name='msa_activations'
-    )(msa_feat)
-
-    msa_activations += hm.Linear(
-        self.config.msa_channel, name='extra_msa_target_feat'
-    )(target_feat)[None]
-    msa_mask = msa_batch.mask.astype(dtype)
-
-    # Evoformer MSA stack.
-    evoformer_input = {'msa': msa_activations, 'pair': pair_activations}
-    masks = {'msa': msa_mask, 'pair': pair_mask}
-
-    def evoformer_fn(x):
-      return modules.EvoformerIteration(
-          self.config.msa_stack, self.global_config, name='msa_stack'
-      )(
-          activations=x,
-          masks=masks,
-      )
-
-    evoformer_stack = hk.experimental.layer_stack(
-        self.config.msa_stack.num_layer
-    )(evoformer_fn)
-
-    evoformer_output = evoformer_stack(evoformer_input)
-
-    return evoformer_output['pair'], key
-
-  def __call__(
-      self,
-      batch: feat_batch.Batch,
-      prev: dict[str, jnp.ndarray],
-      target_feat: jnp.ndarray,
-      key: jnp.ndarray,
-  ) -> dict[str, jnp.ndarray]:
-
-    assert self.global_config.bfloat16 in {'all', 'none'}
-
-    num_residues = target_feat.shape[0]
-    assert batch.token_features.aatype.shape == (num_residues,)
-
-    dtype = (
-        jnp.bfloat16 if self.global_config.bfloat16 == 'all' else jnp.float32
-    )
-
-    with utils.bfloat16_context():
-      pair_activations, pair_mask = self._seq_pair_embedding(
-          batch.token_features, target_feat
-      )
-
-      pair_activations += hm.Linear(
-          pair_activations.shape[-1],
-          name='prev_embedding',
-          initializer=self.global_config.final_init,
-      )(
-          hm.LayerNorm(name='prev_embedding_layer_norm')(
-              prev['pair'].astype(pair_activations.dtype)
-          )
-      )
-
-      pair_activations = self._relative_encoding(batch, pair_activations)
-
-      pair_activations = self._embed_bonds(
-          batch=batch, pair_activations=pair_activations
-      )
-
-      pair_activations, key = self._embed_template_pair(
-          batch=batch,
-          pair_activations=pair_activations,
-          pair_mask=pair_mask,
-          key=key,
-      )
-      pair_activations, key = self._embed_process_msa(
-          msa_batch=batch.msa,
-          pair_activations=pair_activations,
-          pair_mask=pair_mask,
-          key=key,
-          target_feat=target_feat,
-      )
-      del key  # Unused after this point.
-
-      single_activations = hm.Linear(
-          self.config.seq_channel, name='single_activations'
-      )(target_feat)
-
-      single_activations += hm.Linear(
-          single_activations.shape[-1],
-          name='prev_single_embedding',
-          initializer=self.global_config.final_init,
-      )(
-          hm.LayerNorm(name='prev_single_embedding_layer_norm')(
-              prev['single'].astype(single_activations.dtype)
-          )
-      )
-
-      def pairformer_fn(x):
-        pairformer_iteration = modules.PairFormerIteration(
-            self.config.pairformer,
-            self.global_config,
-            with_single=True,
-            name='trunk_pairformer',
-        )
-        pair_act, single_act = x
-        return pairformer_iteration(
-            act=pair_act,
-            single_act=single_act,
-            pair_mask=pair_mask,
-            seq_mask=batch.token_features.mask.astype(dtype),
-        )
-
-      pairformer_stack = hk.experimental.layer_stack(
-          self.config.pairformer.num_layer
-      )(pairformer_fn)
-
-      pair_activations, single_activations = pairformer_stack(
-          (pair_activations, single_activations)
-      )
-
-      assert pair_activations.shape == (
-          num_residues,
-          num_residues,
-          self.config.pair_channel,
-      )
-      assert single_activations.shape == (num_residues, self.config.seq_channel)
-      assert len(target_feat.shape) == 2
-      assert target_feat.shape[0] == num_residues
-      output = {
-          'single': single_activations,
-          'pair': pair_activations,
-          'target_feat': target_feat,
-      }
-
-    return output
diff --git a/src/alphafold3/model/diffusion/modules.py b/src/alphafold3/model/diffusion/modules.py
deleted file mode 100644
index c796d051f99c171c705fd2578ab5a0d1bce6b2e2..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/diffusion/modules.py
+++ /dev/null
@@ -1,627 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Haiku modules for the Diffuser model."""
-
-from collections.abc import Sequence
-from typing import Literal
-
-from alphafold3.common import base_config
-from alphafold3.jax.attention import attention
-from alphafold3.jax.gated_linear_unit import gated_linear_unit
-from alphafold3.model import model_config
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import mapping
-from alphafold3.model.diffusion import diffusion_transformer
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-def get_shard_size(
-    num_residues: int, shard_spec: Sequence[tuple[int | None, int | None]]
-) -> int | None:
-  shard_size = shard_spec[0][-1]
-  for num_residues_upper_bound, num_residues_shard_size in shard_spec:
-    shard_size = num_residues_shard_size
-    if (
-        num_residues_upper_bound is None
-        or num_residues <= num_residues_upper_bound
-    ):
-      break
-  return shard_size
-
-
-class TransitionBlock(hk.Module):
-  """Transition block for transformer."""
-
-  class Config(base_config.BaseConfig):
-    num_intermediate_factor: int = 4
-    use_glu_kernel: bool = True
-
-  def __init__(
-      self, config: Config, global_config: model_config.GlobalConfig, *, name
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(self, act, broadcast_dim=0):
-    num_channels = act.shape[-1]
-
-    num_intermediate = int(num_channels * self.config.num_intermediate_factor)
-
-    act = hm.LayerNorm(name='input_layer_norm')(act)
-
-    if self.config.use_glu_kernel:
-      weights, _ = hm.haiku_linear_get_params(
-          act,
-          num_output=num_intermediate * 2,
-          initializer='relu',
-          name='transition1',
-      )
-      weights = jnp.reshape(weights, (len(weights), 2, num_intermediate))
-      c = gated_linear_unit.gated_linear_unit(
-          x=act, weight=weights, implementation=None, activation=jax.nn.swish
-      )
-    else:
-      act = hm.Linear(
-          num_intermediate * 2, initializer='relu', name='transition1'
-      )(act)
-      a, b = jnp.split(act, 2, axis=-1)
-      c = jax.nn.swish(a) * b
-
-    return hm.Linear(
-        num_channels,
-        initializer=self.global_config.final_init,
-        name='transition2',
-    )(c)
-
-
-class MSAAttention(hk.Module):
-  """MSA Attention."""
-
-  class Config(base_config.BaseConfig):
-    num_head: int = 8
-
-  def __init__(
-      self, config: Config, global_config: model_config.GlobalConfig, *, name
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(self, act, mask, pair_act):
-    act = hm.LayerNorm(name='act_norm')(act)
-    pair_act = hm.LayerNorm(name='pair_norm')(pair_act)
-    logits = hm.Linear(
-        self.config.num_head, use_bias=False, name='pair_logits'
-    )(pair_act)
-    logits = jnp.transpose(logits, [2, 0, 1])
-    logits += 1e9 * (jnp.max(mask, axis=0) - 1.0)
-    weights = jax.nn.softmax(logits, axis=-1)
-    num_channels = act.shape[-1]
-    value_dim = num_channels // self.config.num_head
-    v = hm.Linear(
-        [self.config.num_head, value_dim], use_bias=False, name='v_projection'
-    )(act)
-    v_avg = jnp.einsum('hqk, bkhc -> bqhc', weights, v)
-    v_avg = jnp.reshape(v_avg, v_avg.shape[:-2] + (-1,))
-    gate_values = hm.Linear(
-        self.config.num_head * value_dim,
-        bias_init=1.0,
-        initializer='zeros',
-        name='gating_query',
-    )(act)
-    v_avg *= jax.nn.sigmoid(gate_values)
-
-    return hm.Linear(
-        num_channels,
-        initializer=self.global_config.final_init,
-        name='output_projection',
-    )(v_avg)
-
-
-class GridSelfAttention(hk.Module):
-  """Self attention that is either per-sequence or per-residue."""
-
-  class Config(base_config.BaseConfig):
-    num_head: int = 4
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      transpose: bool,
-      *,
-      name: str,
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-    self.transpose = transpose
-
-  @hk.transparent
-  def _attention(self, act, mask, bias):
-    num_channels = act.shape[-1]
-    assert num_channels % self.config.num_head == 0
-    # Triton requires a minimum dimension of 16 for doing matmul.
-    qkv_dim = max(num_channels // self.config.num_head, 16)
-
-    qkv_shape = (self.config.num_head, qkv_dim)
-    q = hm.Linear(
-        qkv_shape, use_bias=False, name='q_projection', transpose_weights=True
-    )(act)
-    k = hm.Linear(
-        qkv_shape, use_bias=False, name='k_projection', transpose_weights=True
-    )(act)
-    v = hm.Linear(qkv_shape, use_bias=False, name='v_projection')(act)
-
-    # Dot product attention requires the bias term to have a batch dimension.
-    bias = jnp.expand_dims(bias, 0)
-
-    weighted_avg = attention.dot_product_attention(
-        q,
-        k,
-        v,
-        mask=mask,
-        bias=bias,
-        implementation=self.global_config.flash_attention_implementation,
-    )
-    weighted_avg = jnp.reshape(weighted_avg, weighted_avg.shape[:-2] + (-1,))
-
-    gate_values = hm.Linear(
-        self.config.num_head * qkv_dim,
-        bias_init=1.0,
-        initializer='zeros',
-        transpose_weights=True,
-        name='gating_query',
-    )(act)
-    weighted_avg *= jax.nn.sigmoid(gate_values)
-
-    return hm.Linear(
-        num_channels,
-        initializer=self.global_config.final_init,
-        name='output_projection',
-    )(weighted_avg)
-
-  def __call__(self, act, pair_mask):
-    """Builds a module.
-
-    Arguments:
-      act: [num_seq, num_res, channels] activations tensor
-      pair_mask: [num_seq, num_res] mask of non-padded regions in the tensor.
-        Only used in inducing points attention currently.
-
-    Returns:
-      Result of the self-attention operation.
-    """
-    assert len(act.shape) == 3
-    assert len(pair_mask.shape) == 2
-
-    pair_mask = jnp.swapaxes(pair_mask, -1, -2)
-    act = hm.LayerNorm(name='act_norm')(act)
-
-    nonbatched_bias = hm.Linear(
-        self.config.num_head, use_bias=False, name='pair_bias_projection'
-    )(act)
-    nonbatched_bias = jnp.transpose(nonbatched_bias, [2, 0, 1])
-
-    num_residues = act.shape[0]
-
-    chunk_size = get_shard_size(
-        num_residues, self.global_config.pair_attention_chunk_size
-    )
-
-    if self.transpose:
-      act = jnp.swapaxes(act, -2, -3)
-
-    pair_mask = pair_mask[:, None, None, :].astype(jnp.bool_)
-
-    act = mapping.inference_subbatch(
-        self._attention,
-        chunk_size,
-        batched_args=[act, pair_mask],
-        nonbatched_args=[nonbatched_bias],
-        input_subbatch_dim_is_partitioned=False,
-    )
-
-    if self.transpose:
-      act = jnp.swapaxes(act, -2, -3)
-
-    return act
-
-
-class TriangleMultiplication(hk.Module):
-  """Triangle Multiplication."""
-
-  class Config(base_config.BaseConfig):
-    equation: Literal['ikc,jkc->ijc', 'kjc,kic->ijc']
-    use_glu_kernel: bool = True
-
-  def __init__(
-      self, config: Config, global_config: model_config.GlobalConfig, *, name
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(self, act, mask):
-    """Applies Module.
-
-    Args:
-      act: The activation.
-      mask: The mask.
-
-    Returns:
-      Outputs, should have same shape/type as output_act
-    """
-    mask = mask[None, ...]
-    num_channels = act.shape[-1]
-    equation = {
-        'ikc,jkc->ijc': 'cik,cjk->cij',
-        'kjc,kic->ijc': 'ckj,cki->cij',
-    }[self.config.equation]
-
-    act = hm.LayerNorm(name='left_norm_input')(act)
-    input_act = act
-
-    if self.config.use_glu_kernel:
-      weights_projection, _ = hm.haiku_linear_get_params(
-          act, num_output=num_channels * 2, name='projection'
-      )
-      weights_gate, _ = hm.haiku_linear_get_params(
-          act,
-          num_output=num_channels * 2,
-          initializer=self.global_config.final_init,
-          name='gate',
-      )
-      weights_glu = jnp.stack([weights_gate, weights_projection], axis=1)
-
-      projection = gated_linear_unit.gated_linear_unit(
-          x=act,
-          weight=weights_glu,
-          activation=jax.nn.sigmoid,
-          implementation=None,
-      )
-      projection = jnp.transpose(projection, (2, 0, 1))
-      projection *= mask
-    else:
-      projection = hm.Linear(num_channels * 2, name='projection')(act)
-      projection = jnp.transpose(projection, (2, 0, 1))
-      projection *= mask
-
-      gate = hm.Linear(
-          num_channels * 2,
-          name='gate',
-          bias_init=1.0,
-          initializer=self.global_config.final_init,
-      )(act)
-      gate = jnp.transpose(gate, (2, 0, 1))
-      projection *= jax.nn.sigmoid(gate)
-
-    projection = projection.reshape(num_channels, 2, *projection.shape[1:])
-    a, b = jnp.split(projection, 2, axis=1)
-    a, b = jnp.squeeze(a, axis=1), jnp.squeeze(b, axis=1)
-    act = jnp.einsum(equation, a, b)
-    act = hm.LayerNorm(name='center_norm', axis=0, param_axis=0)(act)
-
-    act = jnp.transpose(act, (1, 2, 0))
-    act = hm.Linear(
-        num_channels,
-        initializer=self.global_config.final_init,
-        name='output_projection',
-    )(act)
-
-    gate_out = hm.Linear(
-        num_channels,
-        name='gating_linear',
-        bias_init=1.0,
-        initializer=self.global_config.final_init,
-    )(input_act)
-    act *= jax.nn.sigmoid(gate_out)
-
-    return act
-
-
-class OuterProductMean(hk.Module):
-  """Computed mean outer product."""
-
-  class Config(base_config.BaseConfig):
-    chunk_size: int = 128
-    num_outer_channel: int = 32
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      num_output_channel,
-      *,
-      name,
-  ):
-    super().__init__(name=name)
-    self.global_config = global_config
-    self.config = config
-    self.num_output_channel = num_output_channel
-
-  def __call__(self, act, mask):
-    mask = mask[..., None]
-    act = hm.LayerNorm(name='layer_norm_input')(act)
-
-    left_act = mask * hm.Linear(
-        self.config.num_outer_channel,
-        initializer='linear',
-        name='left_projection',
-    )(act)
-
-    right_act = mask * hm.Linear(
-        self.config.num_outer_channel,
-        initializer='linear',
-        name='right_projection',
-    )(act)
-
-    if self.global_config.final_init == 'zeros':
-      w_init = hk.initializers.Constant(0.0)
-    else:
-      w_init = hk.initializers.VarianceScaling(scale=2.0, mode='fan_in')
-
-    output_w = hk.get_parameter(
-        'output_w',
-        shape=(
-            self.config.num_outer_channel,
-            self.config.num_outer_channel,
-            self.num_output_channel,
-        ),
-        dtype=act.dtype,
-        init=w_init,
-    )
-    output_b = hk.get_parameter(
-        'output_b',
-        shape=(self.num_output_channel,),
-        dtype=act.dtype,
-        init=hk.initializers.Constant(0.0),
-    )
-
-    def compute_chunk(left_act):
-      # Make sure that the 'b' dimension is the most minor batch like dimension
-      # so it will be treated as the real batch by XLA (both during the forward
-      # and the backward pass)
-      left_act = jnp.transpose(left_act, [0, 2, 1])
-      act = jnp.einsum('acb,ade->dceb', left_act, right_act)
-      act = jnp.einsum('dceb,cef->dbf', act, output_w) + output_b
-      return jnp.transpose(act, [1, 0, 2])
-
-    act = mapping.inference_subbatch(
-        compute_chunk,
-        self.config.chunk_size,
-        batched_args=[left_act],
-        nonbatched_args=[],
-        input_subbatch_dim=1,
-        output_subbatch_dim=0,
-        input_subbatch_dim_is_partitioned=False,
-    )
-
-    epsilon = 1e-3
-    norm = jnp.einsum('abc,adc->bdc', mask, mask)
-    return act / (epsilon + norm)
-
-
-class PairFormerIteration(hk.Module):
-  """Single Iteration of Pair Former."""
-
-  class Config(base_config.BaseConfig):
-    """Config for PairFormerIteration."""
-
-    num_layer: int
-    pair_attention: GridSelfAttention.Config = base_config.autocreate()
-    pair_transition: TransitionBlock.Config = base_config.autocreate()
-    single_attention: diffusion_transformer.SelfAttentionConfig | None = None
-    single_transition: TransitionBlock.Config | None = None
-    triangle_multiplication_incoming: TriangleMultiplication.Config = (
-        base_config.autocreate(equation='kjc,kic->ijc')
-    )
-    triangle_multiplication_outgoing: TriangleMultiplication.Config = (
-        base_config.autocreate(equation='ikc,jkc->ijc')
-    )
-    shard_transition_blocks: bool = True
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      with_single=False,
-      *,
-      name,
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-    self.with_single = with_single
-
-  def __call__(
-      self,
-      act,
-      pair_mask,
-      single_act=None,
-      seq_mask=None,
-  ):
-    """Build a single iteration of the pair former.
-
-    Args:
-      act: [num_res, num_res, num_channel] Input pairwise activations.
-      pair_mask: [num_res, num_res] padding mask.
-      single_act: [num_res, single_channel] Single Input activations, optional
-      seq_mask: [num_res] Sequence Mask, optional.
-
-    Returns:
-      [num_res, num_res, num_channel] tensor of activations.
-    """
-
-    num_residues = act.shape[0]
-
-    act += TriangleMultiplication(
-        self.config.triangle_multiplication_outgoing,
-        self.global_config,
-        name='triangle_multiplication_outgoing',
-    )(act, pair_mask)
-
-    act += TriangleMultiplication(
-        self.config.triangle_multiplication_incoming,
-        self.global_config,
-        name='triangle_multiplication_incoming',
-    )(act, pair_mask)
-
-    act += GridSelfAttention(
-        self.config.pair_attention,
-        self.global_config,
-        name='pair_attention1',
-        transpose=False,
-    )(act, pair_mask)
-
-    act += GridSelfAttention(
-        self.config.pair_attention,
-        self.global_config,
-        name='pair_attention2',
-        transpose=True,
-    )(act, pair_mask)
-
-    transition_block = TransitionBlock(
-        self.config.pair_transition, self.global_config, name='pair_transition'
-    )
-    if self.config.shard_transition_blocks:
-      transition_block = mapping.sharded_apply(
-          transition_block,
-          get_shard_size(
-              num_residues, self.global_config.pair_transition_shard_spec
-          ),
-      )
-    act += transition_block(act)
-
-    if self.with_single:
-      assert self.config.single_attention is not None
-      pair_logits = hm.Linear(
-          self.config.single_attention.num_head,
-          name='single_pair_logits_projection',
-      )(hm.LayerNorm(name='single_pair_logits_norm')(act))
-
-      pair_logits = jnp.transpose(pair_logits, [2, 0, 1])
-
-      single_act += diffusion_transformer.self_attention(
-          single_act,
-          seq_mask,
-          pair_logits=pair_logits,
-          config=self.config.single_attention,
-          global_config=self.global_config,
-          name='single_attention_',
-      )
-
-      single_act += TransitionBlock(
-          self.config.single_transition,
-          self.global_config,
-          name='single_transition',
-      )(single_act, broadcast_dim=None)
-
-      return act, single_act
-    else:
-      return act
-
-
-class EvoformerIteration(hk.Module):
-  """Single Iteration of Evoformer Main Stack."""
-
-  class Config(base_config.BaseConfig):
-    """Configuration for EvoformerIteration."""
-
-    num_layer: int = 4
-    msa_attention: MSAAttention.Config = base_config.autocreate()
-    outer_product_mean: OuterProductMean.Config = base_config.autocreate()
-    msa_transition: TransitionBlock.Config = base_config.autocreate()
-    pair_attention: GridSelfAttention.Config = base_config.autocreate()
-    pair_transition: TransitionBlock.Config = base_config.autocreate()
-    triangle_multiplication_incoming: TriangleMultiplication.Config = (
-        base_config.autocreate(equation='kjc,kic->ijc')
-    )
-    triangle_multiplication_outgoing: TriangleMultiplication.Config = (
-        base_config.autocreate(equation='ikc,jkc->ijc')
-    )
-    shard_transition_blocks: bool = True
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='evoformer_iteration',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(self, activations, masks):
-
-    msa_act, pair_act = activations['msa'], activations['pair']
-
-    num_residues = pair_act.shape[0]
-
-    msa_mask, pair_mask = masks['msa'], masks['pair']
-
-    pair_act += OuterProductMean(
-        config=self.config.outer_product_mean,
-        global_config=self.global_config,
-        num_output_channel=int(pair_act.shape[-1]),
-        name='outer_product_mean',
-    )(msa_act, msa_mask)
-
-    msa_act += MSAAttention(
-        self.config.msa_attention, self.global_config, name='msa_attention1'
-    )(msa_act, msa_mask, pair_act=pair_act)
-
-    msa_act += TransitionBlock(
-        self.config.msa_transition, self.global_config, name='msa_transition'
-    )(msa_act)
-
-    pair_act += TriangleMultiplication(
-        self.config.triangle_multiplication_outgoing,
-        self.global_config,
-        name='triangle_multiplication_outgoing',
-    )(pair_act, pair_mask)
-
-    pair_act += TriangleMultiplication(
-        self.config.triangle_multiplication_incoming,
-        self.global_config,
-        name='triangle_multiplication_incoming',
-    )(pair_act, pair_mask)
-
-    pair_act += GridSelfAttention(
-        self.config.pair_attention,
-        self.global_config,
-        name='pair_attention1',
-        transpose=False,
-    )(pair_act, pair_mask)
-
-    pair_act += GridSelfAttention(
-        self.config.pair_attention,
-        self.global_config,
-        name='pair_attention2',
-        transpose=True,
-    )(pair_act, pair_mask)
-
-    transition_block = TransitionBlock(
-        self.config.pair_transition, self.global_config, name='pair_transition'
-    )
-    if self.config.shard_transition_blocks:
-      transition_block = mapping.sharded_apply(
-          transition_block,
-          get_shard_size(
-              num_residues, self.global_config.pair_transition_shard_spec
-          ),
-      )
-    pair_act += transition_block(pair_act)
-
-    return {'msa': msa_act, 'pair': pair_act}
diff --git a/src/alphafold3/model/diffusion/template_modules.py b/src/alphafold3/model/diffusion/template_modules.py
deleted file mode 100644
index 62dde95b42978115487308afa66dac86c758ed0f..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/diffusion/template_modules.py
+++ /dev/null
@@ -1,351 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Modules for embedding templates."""
-
-from alphafold3.common import base_config
-from alphafold3.constants import residue_names
-from alphafold3.jax import geometry
-from alphafold3.model import features
-from alphafold3.model import model_config
-from alphafold3.model import protein_data_processing
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.diffusion import modules
-from alphafold3.model.scoring import scoring
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-class DistogramFeaturesConfig(base_config.BaseConfig):
-  # The left edge of the first bin.
-  min_bin: float = 3.25
-  # The left edge of the final bin. The final bin catches everything larger than
-  # `max_bin`.
-  max_bin: float = 50.75
-  # The number of bins in the distogram.
-  num_bins: int = 39
-
-
-def dgram_from_positions(positions, config: DistogramFeaturesConfig):
-  """Compute distogram from amino acid positions.
-
-  Args:
-    positions: (num_res, 3) Position coordinates.
-    config: Distogram bin configuration.
-
-  Returns:
-    Distogram with the specified number of bins.
-  """
-  lower_breaks = jnp.linspace(config.min_bin, config.max_bin, config.num_bins)
-  lower_breaks = jnp.square(lower_breaks)
-  upper_breaks = jnp.concatenate(
-      [lower_breaks[1:], jnp.array([1e8], dtype=jnp.float32)], axis=-1
-  )
-  dist2 = jnp.sum(
-      jnp.square(
-          jnp.expand_dims(positions, axis=-2)
-          - jnp.expand_dims(positions, axis=-3)
-      ),
-      axis=-1,
-      keepdims=True,
-  )
-
-  dgram = (dist2 > lower_breaks).astype(jnp.float32) * (
-      dist2 < upper_breaks
-  ).astype(jnp.float32)
-  return dgram
-
-
-def make_backbone_rigid(
-    positions: geometry.Vec3Array,
-    mask: jnp.ndarray,
-    group_indices: jnp.ndarray,
-) -> tuple[geometry.Rigid3Array, jnp.ndarray]:
-  """Make backbone Rigid3Array and mask.
-
-  Args:
-    positions: (num_res, num_atoms) of atom positions as Vec3Array.
-    mask: (num_res, num_atoms) for atom mask.
-    group_indices: (num_res, num_group, 3) for atom indices forming groups.
-
-  Returns:
-    tuple of backbone Rigid3Array and mask (num_res,).
-  """
-  backbone_indices = group_indices[:, 0]
-
-  # main backbone frames differ in sidechain frame convention.
-  # for sidechain it's (C, CA, N), for backbone it's (N, CA, C)
-  # Hence using c, b, a, each of shape (num_res,).
-  c, b, a = [backbone_indices[..., i] for i in range(3)]
-
-  slice_index = jax.vmap(lambda x, i: x[i])
-  rigid_mask = (
-      slice_index(mask, a) * slice_index(mask, b) * slice_index(mask, c)
-  ).astype(jnp.float32)
-
-  frame_positions = []
-  for indices in [a, b, c]:
-    frame_positions.append(
-        jax.tree.map(lambda x, idx=indices: slice_index(x, idx), positions)
-    )
-
-  rotation = geometry.Rot3Array.from_two_vectors(
-      frame_positions[2] - frame_positions[1],
-      frame_positions[0] - frame_positions[1],
-  )
-  rigid = geometry.Rigid3Array(rotation, frame_positions[1])
-
-  return rigid, rigid_mask
-
-
-class TemplateEmbedding(hk.Module):
-  """Embed a set of templates."""
-
-  class Config(base_config.BaseConfig):
-    num_channels: int = 64
-    template_stack: modules.PairFormerIteration.Config = base_config.autocreate(
-        num_layer=2,
-        pair_transition=base_config.autocreate(num_intermediate_factor=2),
-    )
-    dgram_features: DistogramFeaturesConfig = base_config.autocreate()
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='template_embedding',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      query_embedding: jnp.ndarray,
-      templates: features.Templates,
-      padding_mask_2d: jnp.ndarray,
-      multichain_mask_2d: jnp.ndarray,
-      key: jnp.ndarray,
-  ) -> jnp.ndarray:
-    """Generate an embedding for a set of templates.
-
-    Args:
-      query_embedding: [num_res, num_res, num_channel] a query tensor that will
-        be used to attend over the templates to remove the num_templates
-        dimension.
-      templates: A 'Templates' object.
-      padding_mask_2d: [num_res, num_res] Pair mask for attention operations.
-      multichain_mask_2d: [num_res, num_res] Pair mask for multichain.
-      key: random key generator.
-
-    Returns:
-      An embedding of size [num_res, num_res, num_channels]
-    """
-    c = self.config
-    num_residues = query_embedding.shape[0]
-    num_templates = templates.aatype.shape[0]
-    query_num_channels = query_embedding.shape[2]
-    num_atoms = 24
-    assert query_embedding.shape == (
-        num_residues,
-        num_residues,
-        query_num_channels,
-    )
-    assert templates.aatype.shape == (num_templates, num_residues)
-    assert templates.atom_positions.shape == (
-        num_templates,
-        num_residues,
-        num_atoms,
-        3,
-    )
-    assert templates.atom_mask.shape == (num_templates, num_residues, num_atoms)
-    assert padding_mask_2d.shape == (num_residues, num_residues)
-
-    num_templates = templates.aatype.shape[0]
-    num_res, _, query_num_channels = query_embedding.shape
-
-    # Embed each template separately.
-    template_embedder = SingleTemplateEmbedding(self.config, self.global_config)
-
-    subkeys = jnp.array(jax.random.split(key, num_templates))
-
-    def scan_fn(carry, x):
-      templates, key = x
-      embedding = template_embedder(
-          query_embedding,
-          templates,
-          padding_mask_2d,
-          multichain_mask_2d,
-          key,
-      )
-      return carry + embedding, None
-
-    scan_init = jnp.zeros(
-        (num_res, num_res, c.num_channels), dtype=query_embedding.dtype
-    )
-    summed_template_embeddings, _ = hk.scan(
-        scan_fn, scan_init, (templates, subkeys)
-    )
-
-    embedding = summed_template_embeddings / (1e-7 + num_templates)
-    embedding = jax.nn.relu(embedding)
-    embedding = hm.Linear(
-        query_num_channels, initializer='relu', name='output_linear'
-    )(embedding)
-
-    assert embedding.shape == (num_residues, num_residues, query_num_channels)
-    return embedding
-
-
-class SingleTemplateEmbedding(hk.Module):
-  """Embed a single template."""
-
-  def __init__(
-      self,
-      config: TemplateEmbedding.Config,
-      global_config: model_config.GlobalConfig,
-      name='single_template_embedding',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      query_embedding: jnp.ndarray,
-      templates: features.Templates,
-      padding_mask_2d: jnp.ndarray,
-      multichain_mask_2d: jnp.ndarray,
-      key: jnp.ndarray,
-  ) -> jnp.ndarray:
-    """Build the single template embedding graph.
-
-    Args:
-      query_embedding: (num_res, num_res, num_channels) - embedding of the query
-        sequence/msa.
-      templates: 'Templates' object containing single Template.
-      padding_mask_2d: Padding mask (Note: this doesn't care if a template
-        exists, unlike the template_pseudo_beta_mask).
-      multichain_mask_2d: A mask indicating intra-chain residue pairs, used to
-        mask out between chain distances/features when templates are for single
-        chains.
-      key: Random key generator.
-
-    Returns:
-      A template embedding (num_res, num_res, num_channels).
-    """
-    gc = self.global_config
-    c = self.config
-    assert padding_mask_2d.dtype == query_embedding.dtype
-    dtype = query_embedding.dtype
-    num_channels = self.config.num_channels
-
-    def construct_input(
-        query_embedding, templates: features.Templates, multichain_mask_2d
-    ):
-
-      # Compute distogram feature for the template.
-      aatype = templates.aatype
-      dense_atom_mask = templates.atom_mask
-
-      dense_atom_positions = templates.atom_positions
-      dense_atom_positions *= dense_atom_mask[..., None]
-
-      pseudo_beta_positions, pseudo_beta_mask = scoring.pseudo_beta_fn(
-          templates.aatype, dense_atom_positions, dense_atom_mask
-      )
-      pseudo_beta_mask_2d = (
-          pseudo_beta_mask[:, None] * pseudo_beta_mask[None, :]
-      )
-      pseudo_beta_mask_2d *= multichain_mask_2d
-      dgram = dgram_from_positions(
-          pseudo_beta_positions, self.config.dgram_features
-      )
-      dgram *= pseudo_beta_mask_2d[..., None]
-      dgram = dgram.astype(dtype)
-      pseudo_beta_mask_2d = pseudo_beta_mask_2d.astype(dtype)
-      to_concat = [(dgram, 1), (pseudo_beta_mask_2d, 0)]
-
-      aatype = jax.nn.one_hot(
-          aatype,
-          residue_names.POLYMER_TYPES_NUM_WITH_UNKNOWN_AND_GAP,
-          axis=-1,
-          dtype=dtype,
-      )
-      to_concat.append((aatype[None, :, :], 1))
-      to_concat.append((aatype[:, None, :], 1))
-
-      # Compute a feature representing the normalized vector between each
-      # backbone affine - i.e. in each residues local frame, what direction are
-      # each of the other residues.
-
-      template_group_indices = jnp.take(
-          protein_data_processing.RESTYPE_RIGIDGROUP_DENSE_ATOM_IDX,
-          templates.aatype,
-          axis=0,
-      )
-      rigid, backbone_mask = make_backbone_rigid(
-          geometry.Vec3Array.from_array(dense_atom_positions),
-          dense_atom_mask,
-          template_group_indices.astype(jnp.int32),
-      )
-      points = rigid.translation
-      rigid_vec = rigid[:, None].inverse().apply_to_point(points)
-      unit_vector = rigid_vec.normalized()
-      unit_vector = [unit_vector.x, unit_vector.y, unit_vector.z]
-
-      unit_vector = [x.astype(dtype) for x in unit_vector]
-      backbone_mask = backbone_mask.astype(dtype)
-
-      backbone_mask_2d = backbone_mask[:, None] * backbone_mask[None, :]
-      backbone_mask_2d *= multichain_mask_2d
-      unit_vector = [x * backbone_mask_2d for x in unit_vector]
-
-      # Note that the backbone_mask takes into account C, CA and N (unlike
-      # pseudo beta mask which just needs CB) so we add both masks as features.
-      to_concat.extend([(x, 0) for x in unit_vector])
-      to_concat.append((backbone_mask_2d, 0))
-
-      query_embedding = hm.LayerNorm(name='query_embedding_norm')(
-          query_embedding
-      )
-      # Allow the template embedder to see the query embedding.  Note this
-      # contains the position relative feature, so this is how the network knows
-      # which residues are next to each other.
-      to_concat.append((query_embedding, 1))
-
-      act = 0
-
-      for i, (x, n_input_dims) in enumerate(to_concat):
-        act += hm.Linear(
-            num_channels,
-            num_input_dims=n_input_dims,
-            initializer='relu',
-            name=f'template_pair_embedding_{i}',
-        )(x)
-      return act
-
-    act = construct_input(query_embedding, templates, multichain_mask_2d)
-
-    if c.template_stack.num_layer:
-
-      def template_iteration_fn(x):
-        return modules.PairFormerIteration(
-            c.template_stack, gc, name='template_embedding_iteration'
-        )(act=x, pair_mask=padding_mask_2d)
-
-      template_stack = hk.experimental.layer_stack(c.template_stack.num_layer)(
-          template_iteration_fn
-      )
-      act = template_stack(act)
-
-    act = hm.LayerNorm(name='output_layer_norm')(act)
-    return act
diff --git a/src/alphafold3/model/feat_batch.py b/src/alphafold3/model/feat_batch.py
deleted file mode 100644
index fcdfad703c5396dd11b14588b9b5c1bd1c1e9a31..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/feat_batch.py
+++ /dev/null
@@ -1,76 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Batch dataclass."""
-from typing import Self
-
-from alphafold3.model import features
-import chex
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class Batch:
-  """Dataclass containing batch."""
-
-  msa: features.MSA
-  templates: features.Templates
-  token_features: features.TokenFeatures
-  ref_structure: features.RefStructure
-  predicted_structure_info: features.PredictedStructureInfo
-  polymer_ligand_bond_info: features.PolymerLigandBondInfo
-  ligand_ligand_bond_info: features.LigandLigandBondInfo
-  pseudo_beta_info: features.PseudoBetaInfo
-  atom_cross_att: features.AtomCrossAtt
-  convert_model_output: features.ConvertModelOutput
-  frames: features.Frames
-
-  @property
-  def num_res(self) -> int:
-    return self.token_features.aatype.shape[-1]
-
-  @classmethod
-  def from_data_dict(cls, batch: features.BatchDict) -> Self:
-    """Construct batch object from dictionary."""
-    return cls(
-        msa=features.MSA.from_data_dict(batch),
-        templates=features.Templates.from_data_dict(batch),
-        token_features=features.TokenFeatures.from_data_dict(batch),
-        ref_structure=features.RefStructure.from_data_dict(batch),
-        predicted_structure_info=features.PredictedStructureInfo.from_data_dict(
-            batch
-        ),
-        polymer_ligand_bond_info=features.PolymerLigandBondInfo.from_data_dict(
-            batch
-        ),
-        ligand_ligand_bond_info=features.LigandLigandBondInfo.from_data_dict(
-            batch
-        ),
-        pseudo_beta_info=features.PseudoBetaInfo.from_data_dict(batch),
-        atom_cross_att=features.AtomCrossAtt.from_data_dict(batch),
-        convert_model_output=features.ConvertModelOutput.from_data_dict(batch),
-        frames=features.Frames.from_data_dict(batch),
-    )
-
-  def as_data_dict(self) -> features.BatchDict:
-    """Converts batch object to dictionary."""
-    output = {
-        **self.msa.as_data_dict(),
-        **self.templates.as_data_dict(),
-        **self.token_features.as_data_dict(),
-        **self.ref_structure.as_data_dict(),
-        **self.predicted_structure_info.as_data_dict(),
-        **self.polymer_ligand_bond_info.as_data_dict(),
-        **self.ligand_ligand_bond_info.as_data_dict(),
-        **self.pseudo_beta_info.as_data_dict(),
-        **self.atom_cross_att.as_data_dict(),
-        **self.convert_model_output.as_data_dict(),
-        **self.frames.as_data_dict(),
-    }
-    return output
diff --git a/src/alphafold3/model/features.py b/src/alphafold3/model/features.py
deleted file mode 100644
index 3b02db0ac09305bbd43e148cb63a1cfddc309a53..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/features.py
+++ /dev/null
@@ -1,2081 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Data-side of the input features processing."""
-
-import dataclasses
-import datetime
-import itertools
-from typing import Any, Self, TypeAlias
-
-from absl import logging
-from alphafold3 import structure
-from alphafold3.common import folding_input
-from alphafold3.constants import chemical_components
-from alphafold3.constants import mmcif_names
-from alphafold3.constants import periodic_table
-from alphafold3.constants import residue_names
-from alphafold3.cpp import cif_dict
-from alphafold3.data import msa as msa_module
-from alphafold3.data import templates
-from alphafold3.data.tools import rdkit_utils
-from alphafold3.model import data3
-from alphafold3.model import data_constants
-from alphafold3.model import merging_features
-from alphafold3.model import msa_pairing
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.structure import chemical_components as struc_chem_comps
-import chex
-import jax.numpy as jnp
-import numpy as np
-from rdkit import Chem
-
-
-xnp_ndarray: TypeAlias = np.ndarray | jnp.ndarray  # pylint: disable=invalid-name
-BatchDict: TypeAlias = dict[str, xnp_ndarray]
-
-_STANDARD_RESIDUES = frozenset({
-    *residue_names.PROTEIN_TYPES_WITH_UNKNOWN,
-    *residue_names.NUCLEIC_TYPES_WITH_2_UNKS,
-})
-
-
-@dataclasses.dataclass(frozen=True)
-class PaddingShapes:
-  num_tokens: int
-  msa_size: int
-  num_chains: int
-  num_templates: int
-  num_atoms: int
-
-
-def _pad_to(
-    arr: np.ndarray, shape: tuple[int | None, ...], **kwargs
-) -> np.ndarray:
-  """Pads an array to a given shape. Wrapper around np.pad().
-
-  Args:
-    arr: numpy array to pad
-    shape: target shape, use None for axes that should stay the same
-    **kwargs: additional args for np.pad, e.g. constant_values=-1
-
-  Returns:
-    the padded array
-
-  Raises:
-    ValueError if arr and shape have a different number of axes.
-  """
-  if arr.ndim != len(shape):
-    raise ValueError(
-        f'arr and shape have different number of axes. {arr.shape=}, {shape=}'
-    )
-
-  num_pad = []
-  for axis, width in enumerate(shape):
-    if width is None:
-      num_pad.append((0, 0))
-    else:
-      if width >= arr.shape[axis]:
-        num_pad.append((0, width - arr.shape[axis]))
-      else:
-        raise ValueError(
-            f'Can not pad to a smaller shape. {arr.shape=}, {shape=}'
-        )
-  padded_arr = np.pad(arr, pad_width=num_pad, **kwargs)
-  return padded_arr
-
-
-def _unwrap(obj):
-  """Unwrap an object from a zero-dim np.ndarray."""
-  if isinstance(obj, np.ndarray) and obj.ndim == 0:
-    return obj.item()
-  else:
-    return obj
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class Chains:
-  chain_id: np.ndarray
-  asym_id: np.ndarray
-  entity_id: np.ndarray
-  sym_id: np.ndarray
-
-
-def _compute_asym_entity_and_sym_id(
-    all_tokens: atom_layout.AtomLayout,
-) -> Chains:
-  """Compute asym_id, entity_id and sym_id.
-
-  Args:
-    all_tokens: atom layout containing a representative atom for each token.
-
-  Returns:
-    A Chains object
-  """
-
-  # Find identical sequences and assign entity_id and sym_id to every chain.
-  seq_to_entity_id_sym_id = {}
-  seen_chain_ids = set()
-  chain_ids = []
-  asym_ids = []
-  entity_ids = []
-  sym_ids = []
-  for chain_id in all_tokens.chain_id:
-    if chain_id not in seen_chain_ids:
-      asym_id = len(seen_chain_ids) + 1
-      seen_chain_ids.add(chain_id)
-      seq = ','.join(all_tokens.res_name[all_tokens.chain_id == chain_id])
-      if seq not in seq_to_entity_id_sym_id:
-        entity_id = len(seq_to_entity_id_sym_id) + 1
-        sym_id = 1
-      else:
-        entity_id, sym_id = seq_to_entity_id_sym_id[seq]
-        sym_id += 1
-      seq_to_entity_id_sym_id[seq] = (entity_id, sym_id)
-
-      chain_ids.append(chain_id)
-      asym_ids.append(asym_id)
-      entity_ids.append(entity_id)
-      sym_ids.append(sym_id)
-
-  return Chains(
-      chain_id=np.array(chain_ids),
-      asym_id=np.array(asym_ids),
-      entity_id=np.array(entity_ids),
-      sym_id=np.array(sym_ids),
-  )
-
-
-def tokenizer(
-    flat_output_layout: atom_layout.AtomLayout,
-    ccd: chemical_components.Ccd,
-    max_atoms_per_token: int,
-    flatten_non_standard_residues: bool,
-    logging_name: str,
-) -> tuple[atom_layout.AtomLayout, atom_layout.AtomLayout, np.ndarray]:
-  """Maps a flat atom layout to tokens for evoformer.
-
-  Creates the evoformer tokens as one token per polymer residue and one token
-  per ligand atom. The tokens are represented as AtomLayouts all_tokens
-  (1 representative atom per token) atoms per residue, and
-  all_token_atoms_layout (num_tokens, max_atoms_per_token). The atoms in a
-  residue token use the layout of the corresponding CCD entry
-
-  Args:
-    flat_output_layout: flat AtomLayout containing all atoms that the model
-      wants to predict.
-    ccd: The chemical components dictionary.
-    max_atoms_per_token: number of slots per token.
-    flatten_non_standard_residues: whether to flatten non-standard residues,
-      i.e. whether to use one token per atom for non-standard residues.
-    logging_name: logging name for debugging (usually the mmcif_id).
-
-  Returns:
-    A tuple (all_tokens, all_tokens_atoms_layout) with
-      all_tokens: AtomLayout shape (num_tokens,) containing one representative
-        atom per token.
-      all_token_atoms_layout: AtomLayout with shape
-        (num_tokens, max_atoms_per_token) containing all atoms per token.
-      standard_token_idxs: The token index that each token would have if not
-        flattening non standard resiudes.
-  """
-  # Select  the representative atom for each token.
-  token_idxs = []
-  single_atom_token = []
-  standard_token_idxs = []
-  current_standard_token_id = 0
-  # Iterate over residues, and provide a group_iter over the atoms of each
-  # residue.
-  for key, group_iter in itertools.groupby(
-      zip(
-          flat_output_layout.chain_type,
-          flat_output_layout.chain_id,
-          flat_output_layout.res_id,
-          flat_output_layout.res_name,
-          flat_output_layout.atom_name,
-          np.arange(flat_output_layout.shape[0]),
-      ),
-      key=lambda x: x[:3],
-  ):
-
-    # Get chain type and chain id of this residue
-    chain_type, chain_id, _ = key
-
-    # Get names and global idxs for all atoms of this residue
-    _, _, _, res_names, atom_names, idxs = zip(*group_iter)
-
-    # As of March 2023, all OTHER CHAINs in pdb are artificial nucleics.
-    is_nucleic_backbone = (
-        chain_type in mmcif_names.NUCLEIC_ACID_CHAIN_TYPES
-        or chain_type == mmcif_names.OTHER_CHAIN
-    )
-    if chain_type in mmcif_names.PEPTIDE_CHAIN_TYPES:
-      res_name = res_names[0]
-      if (
-          flatten_non_standard_residues
-          and res_name not in residue_names.PROTEIN_TYPES_WITH_UNKNOWN
-          and res_name != residue_names.MSE
-      ):
-        # For non-standard protein residues take all atoms.
-        # NOTE: This may get very large if we include hydrogens.
-        token_idxs.extend(idxs)
-        single_atom_token += [True] * len(idxs)
-        standard_token_idxs.extend([current_standard_token_id] * len(idxs))
-      else:
-        # For standard protein residues take 'CA' if it exists, else first atom.
-        if 'CA' in atom_names:
-          token_idxs.append(idxs[atom_names.index('CA')])
-        else:
-          token_idxs.append(idxs[0])
-        single_atom_token += [False]
-        standard_token_idxs.append(current_standard_token_id)
-      current_standard_token_id += 1
-    elif is_nucleic_backbone:
-      res_name = res_names[0]
-      if (
-          flatten_non_standard_residues
-          and res_name not in residue_names.NUCLEIC_TYPES_WITH_2_UNKS
-      ):
-        # For non-standard nucleic residues take all atoms.
-        token_idxs.extend(idxs)
-        single_atom_token += [True] * len(idxs)
-        standard_token_idxs.extend([current_standard_token_id] * len(idxs))
-      else:
-        # For standard nucleic residues take C1' if it exists, else first atom.
-        if "C1'" in atom_names:
-          token_idxs.append(idxs[atom_names.index("C1'")])
-        else:
-          token_idxs.append(idxs[0])
-        single_atom_token += [False]
-        standard_token_idxs.append(current_standard_token_id)
-      current_standard_token_id += 1
-    elif chain_type in mmcif_names.NON_POLYMER_CHAIN_TYPES:
-      # For non-polymers take all atoms
-      token_idxs.extend(idxs)
-      single_atom_token += [True] * len(idxs)
-      standard_token_idxs.extend([current_standard_token_id] * len(idxs))
-      current_standard_token_id += len(idxs)
-    else:
-      # Chain type that we don't handle yet.
-      logging.warning(
-          '%s: ignoring chain %s with chain type %s.',
-          logging_name,
-          chain_id,
-          chain_type,
-      )
-
-  assert len(token_idxs) == len(single_atom_token)
-  assert len(token_idxs) == len(standard_token_idxs)
-  standard_token_idxs = np.array(standard_token_idxs, dtype=np.int32)
-
-  # Create the list of all tokens, represented as a flat AtomLayout with 1
-  # representative atom per token.
-  all_tokens = flat_output_layout[token_idxs]
-
-  # Create the 2D atoms_per_token layout
-  num_tokens = all_tokens.shape[0]
-
-  # Target lists.
-  target_atom_names = []
-  target_atom_elements = []
-  target_res_ids = []
-  target_res_names = []
-  target_chain_ids = []
-  target_chain_types = []
-
-  # uids of all atoms in the flat layout, to check whether the dense atoms
-  # exist -- This is necessary for terminal atoms (e.g. 'OP3' or 'OXT')
-  all_atoms_uids = set(
-      zip(
-          flat_output_layout.chain_id,
-          flat_output_layout.res_id,
-          flat_output_layout.atom_name,
-      )
-  )
-
-  for idx, single_atom in enumerate(single_atom_token):
-    if not single_atom:
-      # Standard protein and nucleic residues have many atoms per token
-      chain_id = all_tokens.chain_id[idx]
-      res_id = all_tokens.res_id[idx]
-      res_name = all_tokens.res_name[idx]
-      atom_names = []
-      atom_elements = []
-
-      res_atoms = struc_chem_comps.get_all_atoms_in_entry(
-          ccd=ccd, res_name=res_name
-      )
-      atom_names_elements = list(
-          zip(
-              res_atoms['_chem_comp_atom.atom_id'],
-              res_atoms['_chem_comp_atom.type_symbol'],
-              strict=True,
-          )
-      )
-
-      for atom_name, atom_element in atom_names_elements:
-        # Remove hydrogens if they are not in flat layout.
-        if atom_element in ['H', 'D'] and (
-            (chain_id, res_id, atom_name) not in all_atoms_uids
-        ):
-          continue
-        elif (chain_id, res_id, atom_name) in all_atoms_uids:
-          atom_names.append(atom_name)
-          atom_elements.append(atom_element)
-        # Leave spaces for OXT etc.
-        else:
-          atom_names.append('')
-          atom_elements.append('')
-
-      if len(atom_names) > max_atoms_per_token:
-        logging.warning(
-            'Atom list for chain %s '
-            'residue %s %s is too long and will be truncated: '
-            '%s to the max atoms limit %s. Dropped atoms: %s',
-            chain_id,
-            res_id,
-            res_name,
-            len(atom_names),
-            max_atoms_per_token,
-            list(
-                zip(
-                    atom_names[max_atoms_per_token:],
-                    atom_elements[max_atoms_per_token:],
-                    strict=True,
-                )
-            ),
-        )
-        atom_names = atom_names[:max_atoms_per_token]
-        atom_elements = atom_elements[:max_atoms_per_token]
-
-      num_pad = max_atoms_per_token - len(atom_names)
-      atom_names.extend([''] * num_pad)
-      atom_elements.extend([''] * num_pad)
-
-    else:
-      # ligands have only 1 atom per token
-      padding = [''] * (max_atoms_per_token - 1)
-      atom_names = [all_tokens.atom_name[idx]] + padding
-      atom_elements = [all_tokens.atom_element[idx]] + padding
-
-    # Append the atoms to the target lists.
-    target_atom_names.append(atom_names)
-    target_atom_elements.append(atom_elements)
-    target_res_names.append([all_tokens.res_name[idx]] * max_atoms_per_token)
-    target_res_ids.append([all_tokens.res_id[idx]] * max_atoms_per_token)
-    target_chain_ids.append([all_tokens.chain_id[idx]] * max_atoms_per_token)
-    target_chain_types.append(
-        [all_tokens.chain_type[idx]] * max_atoms_per_token
-    )
-
-  # Make sure to get the right shape also for 0 tokens
-  trg_shape = (num_tokens, max_atoms_per_token)
-  all_token_atoms_layout = atom_layout.AtomLayout(
-      atom_name=np.array(target_atom_names, dtype=object).reshape(trg_shape),
-      atom_element=np.array(target_atom_elements, dtype=object).reshape(
-          trg_shape
-      ),
-      res_name=np.array(target_res_names, dtype=object).reshape(trg_shape),
-      res_id=np.array(target_res_ids, dtype=int).reshape(trg_shape),
-      chain_id=np.array(target_chain_ids, dtype=object).reshape(trg_shape),
-      chain_type=np.array(target_chain_types, dtype=object).reshape(trg_shape),
-  )
-
-  return all_tokens, all_token_atoms_layout, standard_token_idxs
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class MSA:
-  """Dataclass containing MSA."""
-
-  rows: xnp_ndarray
-  mask: xnp_ndarray
-  deletion_matrix: xnp_ndarray
-  # Occurrence of each residue type along the sequence, averaged over MSA rows.
-  profile: xnp_ndarray
-  # Occurrence of deletions along the sequence, averaged over MSA rows.
-  deletion_mean: xnp_ndarray
-  # Number of MSA alignments.
-  num_alignments: xnp_ndarray
-
-  @classmethod
-  def compute_features(
-      cls,
-      *,
-      all_tokens: atom_layout.AtomLayout,
-      standard_token_idxs: np.ndarray,
-      padding_shapes: PaddingShapes,
-      fold_input: folding_input.Input,
-      logging_name: str,
-      max_paired_sequence_per_species: int,
-  ) -> Self:
-    """Compute the msa features."""
-    seen_entities = {}
-
-    substruct = atom_layout.make_structure(
-        flat_layout=all_tokens,
-        atom_coords=np.zeros(all_tokens.shape + (3,)),
-        name=logging_name,
-    )
-    prot = substruct.filter_to_entity_type(protein=True)
-    num_unique_chains = len(set(prot.chain_single_letter_sequence().values()))
-    need_msa_pairing = num_unique_chains > 1
-
-    np_chains_list = []
-    input_chains_by_id = {chain.id: chain for chain in fold_input.chains}
-    nonempty_chain_ids = set(all_tokens.chain_id)
-    for asym_id, chain_info in enumerate(substruct.iter_chains(), start=1):
-      b_chain_id = chain_info['chain_id']
-      chain_type = chain_info['chain_type']
-      chain = input_chains_by_id[b_chain_id]
-
-      # Generalised "sequence" for ligands (can't trust residue name)
-      chain_tokens = all_tokens[all_tokens.chain_id == b_chain_id]
-      assert chain_tokens.res_name is not None
-      three_letter_sequence = ','.join(chain_tokens.res_name.tolist())
-      chain_num_tokens = len(chain_tokens.atom_name)
-      if chain_type in mmcif_names.POLYMER_CHAIN_TYPES:
-        sequence = substruct.chain_single_letter_sequence()[b_chain_id]
-        if chain_type in mmcif_names.NUCLEIC_ACID_CHAIN_TYPES:
-          # Only allow nucleic residue types for nucleic chains (can have some
-          # protein residues in e.g. tRNA, but that causes MSA search failures).
-          # Replace non nucleic residue types by UNK_NUCLEIC.
-          nucleic_types_one_letter = (
-              residue_names.DNA_TYPES_ONE_LETTER
-              + residue_names.RNA_TYPES_ONE_LETTER_WITH_UNKNOWN
-          )
-          sequence = ''.join([
-              base
-              if base in nucleic_types_one_letter
-              else residue_names.UNK_NUCLEIC_ONE_LETTER
-              for base in sequence
-          ])
-      else:
-        sequence = 'X' * chain_num_tokens
-
-      skip_chain = (
-          chain_type not in mmcif_names.STANDARD_POLYMER_CHAIN_TYPES
-          or len(sequence) <= 4
-          or b_chain_id not in nonempty_chain_ids
-      )
-      if three_letter_sequence in seen_entities:
-        entity_id = seen_entities[three_letter_sequence]
-      else:
-        entity_id = len(seen_entities) + 1
-
-      if chain_type in mmcif_names.STANDARD_POLYMER_CHAIN_TYPES:
-        unpaired_a3m = ''
-        paired_a3m = ''
-        if not skip_chain:
-          if need_msa_pairing and isinstance(chain, folding_input.ProteinChain):
-            paired_a3m = chain.paired_msa
-          if isinstance(
-              chain, folding_input.RnaChain | folding_input.ProteinChain
-          ):
-            unpaired_a3m = chain.unpaired_msa
-        # If we generated the MSA ourselves, it is already deduplicated. If it
-        # is user-provided, keep it as is to prevent destroying desired pairing.
-        unpaired_msa = msa_module.Msa.from_a3m(
-            query_sequence=sequence,
-            chain_poly_type=chain_type,
-            a3m=unpaired_a3m,
-            deduplicate=False,
-        )
-
-        paired_msa = msa_module.Msa.from_a3m(
-            query_sequence=sequence,
-            chain_poly_type=chain_type,
-            a3m=paired_a3m,
-            deduplicate=False,
-        )
-      else:
-        unpaired_msa = msa_module.Msa.from_empty(
-            query_sequence='-' * len(sequence),
-            chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-        )
-        paired_msa = msa_module.Msa.from_empty(
-            query_sequence='-' * len(sequence),
-            chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-        )
-
-      msa_features = unpaired_msa.featurize()
-      all_seqs_msa_features = paired_msa.featurize()
-
-      msa_features = data3.fix_features(msa_features)
-      all_seqs_msa_features = data3.fix_features(all_seqs_msa_features)
-
-      msa_features = msa_features | {
-          f'{k}_all_seq': v for k, v in all_seqs_msa_features.items()
-      }
-      feats = msa_features
-      feats['chain_id'] = b_chain_id
-      feats['asym_id'] = np.full(chain_num_tokens, asym_id)
-      feats['entity_id'] = entity_id
-      np_chains_list.append(feats)
-
-    # Add profile features to each chain.
-    for chain in np_chains_list:
-      chain.update(
-          data3.get_profile_features(chain['msa'], chain['deletion_matrix'])
-      )
-
-    # Allow 50% of the MSA to come from MSA pairing.
-    max_paired_sequences = padding_shapes.msa_size // 2
-    if need_msa_pairing:
-      np_chains_list = list(map(dict, np_chains_list))
-      np_chains_list = msa_pairing.create_paired_features(
-          np_chains_list,
-          max_paired_sequences=max_paired_sequences,
-          nonempty_chain_ids=nonempty_chain_ids,
-          max_hits_per_species=max_paired_sequence_per_species,
-      )
-      np_chains_list = msa_pairing.deduplicate_unpaired_sequences(
-          np_chains_list
-      )
-
-    # Remove all gapped rows from all seqs.
-    nonempty_asym_ids = []
-    for chain in np_chains_list:
-      if chain['chain_id'] in nonempty_chain_ids:
-        nonempty_asym_ids.append(chain['asym_id'][0])
-    if 'msa_all_seq' in np_chains_list[0]:
-      np_chains_list = msa_pairing.remove_all_gapped_rows_from_all_seqs(
-          np_chains_list, asym_ids=nonempty_asym_ids
-      )
-
-    # Crop MSA rows.
-    cropped_chains_list = []
-    for chain in np_chains_list:
-      unpaired_msa_size, paired_msa_size = (
-          msa_pairing.choose_paired_unpaired_msa_crop_sizes(
-              unpaired_msa=chain['msa'],
-              paired_msa=chain.get('msa_all_seq'),
-              total_msa_crop_size=padding_shapes.msa_size,
-              max_paired_sequences=max_paired_sequences,
-          )
-      )
-      cropped_chain = {
-          'asym_id': chain['asym_id'],
-          'chain_id': chain['chain_id'],
-          'profile': chain['profile'],
-          'deletion_mean': chain['deletion_mean'],
-      }
-      for feat in data_constants.NUM_SEQ_NUM_RES_MSA_FEATURES:
-        if feat in chain:
-          cropped_chain[feat] = chain[feat][:unpaired_msa_size]
-        if feat + '_all_seq' in chain:
-          cropped_chain[feat + '_all_seq'] = chain[feat + '_all_seq'][
-              :paired_msa_size
-          ]
-      cropped_chains_list.append(cropped_chain)
-
-    # Merge Chains.
-    # Make sure the chain order is unaltered before slicing with tokens.
-    curr_chain_order = [chain['chain_id'] for chain in cropped_chains_list]
-    orig_chain_order = [chain['chain_id'] for chain in substruct.iter_chains()]
-    assert curr_chain_order == orig_chain_order
-    np_example = {
-        'asym_id': np.concatenate(
-            [c['asym_id'] for c in cropped_chains_list], axis=0
-        ),
-    }
-    for feature in data_constants.NUM_SEQ_NUM_RES_MSA_FEATURES:
-      for feat in [feature, feature + '_all_seq']:
-        if feat in cropped_chains_list[0]:
-          np_example[feat] = merging_features.merge_msa_features(
-              feat, cropped_chains_list
-          )
-    for feature in ['profile', 'deletion_mean']:
-      feature_list = [c[feature] for c in cropped_chains_list]
-      np_example[feature] = np.concatenate(feature_list, axis=0)
-
-    # Crop MSA rows to maximum size given by chains participating in the crop.
-    max_allowed_unpaired = max([
-        len(chain['msa'])
-        for chain in cropped_chains_list
-        if chain['asym_id'][0] in nonempty_asym_ids
-    ])
-    np_example['msa'] = np_example['msa'][:max_allowed_unpaired]
-    if 'msa_all_seq' in np_example:
-      max_allowed_paired = max([
-          len(chain['msa_all_seq'])
-          for chain in cropped_chains_list
-          if chain['asym_id'][0] in nonempty_asym_ids
-      ])
-      np_example['msa_all_seq'] = np_example['msa_all_seq'][:max_allowed_paired]
-
-    np_example = merging_features.merge_paired_and_unpaired_msa(np_example)
-
-    # Crop MSA residues. Need to use the standard token indices, since msa does
-    # not expand non-standard residues. This means that for expanded residues,
-    # we get repeated msa columns.
-    new_cropping_idxs = standard_token_idxs
-    for feature in data_constants.NUM_SEQ_NUM_RES_MSA_FEATURES:
-      if feature in np_example:
-        np_example[feature] = np_example[feature][:, new_cropping_idxs].copy()
-    for feature in ['profile', 'deletion_mean']:
-      np_example[feature] = np_example[feature][new_cropping_idxs]
-
-    # Make MSA mask.
-    np_example['msa_mask'] = np.ones_like(np_example['msa'], dtype=np.float32)
-
-    # Count MSA size before padding.
-    num_alignments = np_example['msa'].shape[0]
-
-    # Pad:
-    msa_size, num_tokens = padding_shapes.msa_size, padding_shapes.num_tokens
-
-    def safe_cast_int8(x):
-      return np.clip(x, np.iinfo(np.int8).min, np.iinfo(np.int8).max).astype(
-          np.int8
-      )
-
-    return MSA(
-        rows=_pad_to(safe_cast_int8(np_example['msa']), (msa_size, num_tokens)),
-        mask=_pad_to(
-            np_example['msa_mask'].astype(bool), (msa_size, num_tokens)
-        ),
-        # deletion_matrix may be out of int8 range, but we mostly care about
-        # small values since we arctan it in the model.
-        deletion_matrix=_pad_to(
-            safe_cast_int8(np_example['deletion_matrix']),
-            (msa_size, num_tokens),
-        ),
-        profile=_pad_to(np_example['profile'], (num_tokens, None)),
-        deletion_mean=_pad_to(np_example['deletion_mean'], (num_tokens,)),
-        num_alignments=np.array(num_alignments, dtype=np.int32),
-    )
-
-  def index_msa_rows(self, indices: xnp_ndarray) -> Self:
-    assert indices.ndim == 1
-
-    return MSA(
-        rows=self.rows[indices, :],
-        mask=self.mask[indices, :],
-        deletion_matrix=self.deletion_matrix[indices, :],
-        profile=self.profile,
-        deletion_mean=self.deletion_mean,
-        num_alignments=self.num_alignments,
-    )
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    output = cls(
-        rows=batch['msa'],
-        mask=batch['msa_mask'],
-        deletion_matrix=batch['deletion_matrix'],
-        profile=batch['profile'],
-        deletion_mean=batch['deletion_mean'],
-        num_alignments=batch['num_alignments'],
-    )
-    return output
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        'msa': self.rows,
-        'msa_mask': self.mask,
-        'deletion_matrix': self.deletion_matrix,
-        'profile': self.profile,
-        'deletion_mean': self.deletion_mean,
-        'num_alignments': self.num_alignments,
-    }
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class Templates:
-  """Dataclass containing templates."""
-
-  # aatype of templates, int32 w shape [num_templates, num_res]
-  aatype: xnp_ndarray
-  # atom positions of templates, float32 w shape [num_templates, num_res, 24, 3]
-  atom_positions: xnp_ndarray
-  # atom mask of templates, bool w shape [num_templates, num_res, 24]
-  atom_mask: xnp_ndarray
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_tokens: atom_layout.AtomLayout,
-      standard_token_idxs: np.ndarray,
-      padding_shapes: PaddingShapes,
-      fold_input: folding_input.Input,
-      max_templates: int,
-      logging_name: str,
-  ) -> Self:
-    """Compute the template features."""
-
-    seen_entities = {}
-    polymer_entity_features = {True: {}, False: {}}
-
-    substruct = atom_layout.make_structure(
-        flat_layout=all_tokens,
-        atom_coords=np.zeros(all_tokens.shape + (3,)),
-        name=logging_name,
-    )
-    np_chains_list = []
-
-    input_chains_by_id = {chain.id: chain for chain in fold_input.chains}
-
-    nonempty_chain_ids = set(all_tokens.chain_id)
-    for chain_info in substruct.iter_chains():
-      chain_id = chain_info['chain_id']
-      chain_type = chain_info['chain_type']
-      chain = input_chains_by_id[chain_id]
-
-      # Generalised "sequence" for ligands (can't trust residue name)
-      chain_tokens = all_tokens[all_tokens.chain_id == chain_id]
-      assert chain_tokens.res_name is not None
-      three_letter_sequence = ','.join(chain_tokens.res_name.tolist())
-      chain_num_tokens = len(chain_tokens.atom_name)
-
-      # Don't compute features for chains not included in the crop, or ligands.
-      skip_chain = (
-          chain_type != mmcif_names.PROTEIN_CHAIN
-          or chain_num_tokens <= 4  # not cache filled
-          or chain_id not in nonempty_chain_ids
-      )
-
-      if three_letter_sequence in seen_entities:
-        entity_id = seen_entities[three_letter_sequence]
-      else:
-        entity_id = len(seen_entities) + 1
-
-      if entity_id not in polymer_entity_features[skip_chain]:
-        if skip_chain:
-          template_features = data3.empty_template_features(chain_num_tokens)
-        else:
-          assert isinstance(chain, folding_input.ProteinChain)
-
-          sorted_features = []
-          for template in chain.templates:
-            struc = structure.from_mmcif(
-                template.mmcif,
-                fix_mse_residues=True,
-                fix_arginines=True,
-                include_bonds=False,
-                include_water=False,
-                include_other=True,  # For non-standard polymer chains.
-            )
-            hit_features = templates.get_polymer_features(
-                chain=struc,
-                chain_poly_type=mmcif_names.PROTEIN_CHAIN,
-                query_sequence_length=len(chain.sequence),
-                query_to_hit_mapping=dict(template.query_to_template_map),
-            )
-            sorted_features.append(hit_features)
-
-          template_features = templates.package_template_features(
-              hit_features=sorted_features,
-              include_ligand_features=False,
-          )
-
-          template_features = data3.fix_template_features(
-              template_features=template_features, num_res=len(chain.sequence)
-          )
-
-        template_features = _reduce_template_features(
-            template_features, max_templates
-        )
-        polymer_entity_features[skip_chain][entity_id] = template_features
-
-      seen_entities[three_letter_sequence] = entity_id
-      feats = polymer_entity_features[skip_chain][entity_id].copy()
-      feats['chain_id'] = chain_id
-      np_chains_list.append(feats)
-
-    # We pad the num_templates dimension before merging, so that different
-    # chains can be concatenated on the num_res dimension.  Masking will be
-    # applied so that each chains templates can't see each other.
-    for chain in np_chains_list:
-      chain['template_aatype'] = _pad_to(
-          chain['template_aatype'], (max_templates, None)
-      )
-      chain['template_atom_positions'] = _pad_to(
-          chain['template_atom_positions'], (max_templates, None, None, None)
-      )
-      chain['template_atom_mask'] = _pad_to(
-          chain['template_atom_mask'], (max_templates, None, None)
-      )
-
-    # Merge on token dimension.
-    np_example = {
-        ft: np.concatenate([c[ft] for c in np_chains_list], axis=1)
-        for ft in np_chains_list[0]
-        if ft in data_constants.TEMPLATE_FEATURES
-    }
-
-    # Crop template data. Need to use the standard token indices, since msa does
-    # not expand non-standard residues. This means that for expanded residues,
-    # we get repeated template information.
-    for feature_name, v in np_example.items():
-      np_example[feature_name] = v[:max_templates, standard_token_idxs, ...]
-
-    # Pad along the token dimension.
-    templates_features = Templates(
-        aatype=_pad_to(
-            np_example['template_aatype'], (None, padding_shapes.num_tokens)
-        ),
-        atom_positions=_pad_to(
-            np_example['template_atom_positions'],
-            (None, padding_shapes.num_tokens, None, None),
-        ),
-        atom_mask=_pad_to(
-            np_example['template_atom_mask'].astype(bool),
-            (None, padding_shapes.num_tokens, None),
-        ),
-    )
-    return templates_features
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    """Make Template from batch dictionary."""
-    return cls(
-        aatype=batch['template_aatype'],
-        atom_positions=batch['template_atom_positions'],
-        atom_mask=batch['template_atom_mask'],
-    )
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        'template_aatype': self.aatype,
-        'template_atom_positions': self.atom_positions,
-        'template_atom_mask': self.atom_mask,
-    }
-
-
-def _reduce_template_features(
-    template_features: data3.FeatureDict,
-    max_templates: int,
-) -> data3.FeatureDict:
-  """Reduces template features to max num templates and defined feature set."""
-  num_templates = template_features['template_aatype'].shape[0]
-  template_keep_mask = np.arange(num_templates) < max_templates
-  template_fields = data_constants.TEMPLATE_FEATURES + (
-      'template_release_timestamp',
-  )
-  template_features = {
-      k: v[template_keep_mask]
-      for k, v in template_features.items()
-      if k in template_fields
-  }
-  return template_features
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class TokenFeatures:
-  """Dataclass containing features for tokens."""
-
-  residue_index: xnp_ndarray
-  token_index: xnp_ndarray
-  aatype: xnp_ndarray
-  mask: xnp_ndarray
-  seq_length: xnp_ndarray
-
-  # Chain symmetry identifiers
-  # for an A3B2 stoichiometry the meaning of these features is as follows:
-  # asym_id:    1 2 3 4 5
-  # entity_id:  1 1 1 2 2
-  # sym_id:     1 2 3 1 2
-  asym_id: xnp_ndarray
-  entity_id: xnp_ndarray
-  sym_id: xnp_ndarray
-
-  # token type features
-  is_protein: xnp_ndarray
-  is_rna: xnp_ndarray
-  is_dna: xnp_ndarray
-  is_ligand: xnp_ndarray
-  is_nonstandard_polymer_chain: xnp_ndarray
-  is_water: xnp_ndarray
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_tokens: atom_layout.AtomLayout,
-      padding_shapes: PaddingShapes,
-  ) -> Self:
-    """Compute the per-token features."""
-
-    residue_index = all_tokens.res_id.astype(np.int32)
-
-    token_index = np.arange(1, len(all_tokens.atom_name) + 1).astype(np.int32)
-
-    aatype = []
-    for res_name, chain_type in zip(all_tokens.res_name, all_tokens.chain_type):
-      if chain_type in mmcif_names.POLYMER_CHAIN_TYPES:
-        res_name = mmcif_names.fix_non_standard_polymer_res(
-            res_name=res_name, chain_type=chain_type
-        )
-        if (
-            chain_type == mmcif_names.DNA_CHAIN
-            and res_name == residue_names.UNK_DNA
-        ):
-          res_name = residue_names.UNK_NUCLEIC_ONE_LETTER
-      elif chain_type in mmcif_names.NON_POLYMER_CHAIN_TYPES:
-        res_name = residue_names.UNK
-      else:
-        raise ValueError(f'Chain type {chain_type} not polymer or ligand.')
-      aa = residue_names.POLYMER_TYPES_ORDER_WITH_UNKNOWN_AND_GAP[res_name]
-      aatype.append(aa)
-    aatype = np.array(aatype, dtype=np.int32)
-
-    mask = np.ones(all_tokens.shape[0], dtype=bool)
-    chains = _compute_asym_entity_and_sym_id(all_tokens)
-    m = dict(zip(chains.chain_id, chains.asym_id))
-    asym_id = np.array([m[c] for c in all_tokens.chain_id], dtype=np.int32)
-
-    m = dict(zip(chains.chain_id, chains.entity_id))
-    entity_id = np.array([m[c] for c in all_tokens.chain_id], dtype=np.int32)
-
-    m = dict(zip(chains.chain_id, chains.sym_id))
-    sym_id = np.array([m[c] for c in all_tokens.chain_id], dtype=np.int32)
-
-    seq_length = np.array(all_tokens.shape[0], dtype=np.int32)
-
-    is_protein = all_tokens.chain_type == mmcif_names.PROTEIN_CHAIN
-    is_rna = all_tokens.chain_type == mmcif_names.RNA_CHAIN
-    is_dna = all_tokens.chain_type == mmcif_names.DNA_CHAIN
-    is_ligand = np.isin(
-        all_tokens.chain_type, list(mmcif_names.LIGAND_CHAIN_TYPES)
-    )
-    standard_polymer_chain = list(mmcif_names.NON_POLYMER_CHAIN_TYPES) + list(
-        mmcif_names.STANDARD_POLYMER_CHAIN_TYPES
-    )
-    is_nonstandard_polymer_chain = np.isin(
-        all_tokens.chain_type, standard_polymer_chain, invert=True
-    )
-    is_water = all_tokens.chain_type == mmcif_names.WATER
-
-    return TokenFeatures(
-        residue_index=_pad_to(residue_index, (padding_shapes.num_tokens,)),
-        token_index=_pad_to(token_index, (padding_shapes.num_tokens,)),
-        aatype=_pad_to(aatype, (padding_shapes.num_tokens,)),
-        mask=_pad_to(mask, (padding_shapes.num_tokens,)),
-        asym_id=_pad_to(asym_id, (padding_shapes.num_tokens,)),
-        entity_id=_pad_to(entity_id, (padding_shapes.num_tokens,)),
-        sym_id=_pad_to(sym_id, (padding_shapes.num_tokens,)),
-        seq_length=seq_length,
-        is_protein=_pad_to(is_protein, (padding_shapes.num_tokens,)),
-        is_rna=_pad_to(is_rna, (padding_shapes.num_tokens,)),
-        is_dna=_pad_to(is_dna, (padding_shapes.num_tokens,)),
-        is_ligand=_pad_to(is_ligand, (padding_shapes.num_tokens,)),
-        is_nonstandard_polymer_chain=_pad_to(
-            is_nonstandard_polymer_chain, (padding_shapes.num_tokens,)
-        ),
-        is_water=_pad_to(is_water, (padding_shapes.num_tokens,)),
-    )
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    return cls(
-        residue_index=batch['residue_index'],
-        token_index=batch['token_index'],
-        aatype=batch['aatype'],
-        mask=batch['seq_mask'],
-        entity_id=batch['entity_id'],
-        asym_id=batch['asym_id'],
-        sym_id=batch['sym_id'],
-        seq_length=batch['seq_length'],
-        is_protein=batch['is_protein'],
-        is_rna=batch['is_rna'],
-        is_dna=batch['is_dna'],
-        is_ligand=batch['is_ligand'],
-        is_nonstandard_polymer_chain=batch['is_nonstandard_polymer_chain'],
-        is_water=batch['is_water'],
-    )
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        'residue_index': self.residue_index,
-        'token_index': self.token_index,
-        'aatype': self.aatype,
-        'seq_mask': self.mask,
-        'entity_id': self.entity_id,
-        'asym_id': self.asym_id,
-        'sym_id': self.sym_id,
-        'seq_length': self.seq_length,
-        'is_protein': self.is_protein,
-        'is_rna': self.is_rna,
-        'is_dna': self.is_dna,
-        'is_ligand': self.is_ligand,
-        'is_nonstandard_polymer_chain': self.is_nonstandard_polymer_chain,
-        'is_water': self.is_water,
-    }
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class PredictedStructureInfo:
-  """Contains information necessary to work with predicted structure."""
-
-  atom_mask: xnp_ndarray
-  residue_center_index: xnp_ndarray
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_tokens: atom_layout.AtomLayout,
-      all_token_atoms_layout: atom_layout.AtomLayout,
-      padding_shapes: PaddingShapes,
-  ) -> Self:
-    """Compute the PredictedStructureInfo features.
-
-    Args:
-      all_tokens: flat AtomLayout with 1 representative atom per token, shape
-        (num_tokens,)
-      all_token_atoms_layout: AtomLayout for all atoms per token, shape
-        (num_tokens, max_atoms_per_token)
-      padding_shapes: padding shapes.
-
-    Returns:
-      A PredictedStructureInfo object.
-    """
-    atom_mask = _pad_to(
-        all_token_atoms_layout.atom_name.astype(bool),
-        (padding_shapes.num_tokens, None),
-    )
-    residue_center_index = np.zeros(padding_shapes.num_tokens, dtype=np.int32)
-    for idx in range(all_tokens.shape[0]):
-      repr_atom = all_tokens.atom_name[idx]
-      atoms = list(all_token_atoms_layout.atom_name[idx, :])
-      if repr_atom in atoms:
-        residue_center_index[idx] = atoms.index(repr_atom)
-      else:
-        # Representative atoms can be missing if cropping the number of atoms
-        # per residue.
-        logging.warning(
-            'The representative atom in all_tokens (%s) is not in '
-            'all_token_atoms_layout (%s)',
-            all_tokens[idx : idx + 1],
-            all_token_atoms_layout[idx, :],
-        )
-        residue_center_index[idx] = 0
-    return cls(atom_mask=atom_mask, residue_center_index=residue_center_index)
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    return cls(
-        atom_mask=batch['pred_dense_atom_mask'],
-        residue_center_index=batch['residue_center_index'],
-    )
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        'pred_dense_atom_mask': self.atom_mask,
-        'residue_center_index': self.residue_center_index,
-    }
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class PolymerLigandBondInfo:
-  """Contains information about polymer-ligand bonds."""
-
-  tokens_to_polymer_ligand_bonds: atom_layout.GatherInfo
-  # Gather indices to convert from cropped dense atom layout to bonds layout
-  # (num_tokens, 2)
-  token_atoms_to_bonds: atom_layout.GatherInfo
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_tokens: atom_layout.AtomLayout,
-      all_token_atoms_layout: atom_layout.AtomLayout,
-      bond_layout: atom_layout.AtomLayout | None,
-      padding_shapes: PaddingShapes,
-  ) -> Self:
-    """Computes the InterChainBondInfo features.
-
-    Args:
-      all_tokens: AtomLayout for tokens; shape (num_tokens,).
-      all_token_atoms_layout: Atom Layout for all atoms (num_tokens,
-        max_atoms_per_token)
-      bond_layout: Bond layout for polymer-ligand bonds.
-      padding_shapes: Padding shapes.
-
-    Returns:
-      A PolymerLigandBondInfo object.
-    """
-
-    if bond_layout is not None:
-      # Must convert to list before calling np.isin, will not work raw.
-      peptide_types = list(mmcif_names.PEPTIDE_CHAIN_TYPES)
-      nucleic_types = list(mmcif_names.NUCLEIC_ACID_CHAIN_TYPES) + [
-          mmcif_names.OTHER_CHAIN
-      ]
-      # These atom renames are so that we can use the atom layout code with
-      # all_tokens, which only has a single atom per token.
-      atom_names = bond_layout.atom_name.copy()
-      atom_names[np.isin(bond_layout.chain_type, peptide_types)] = 'CA'
-      atom_names[np.isin(bond_layout.chain_type, nucleic_types)] = "C1'"
-      adjusted_bond_layout = atom_layout.AtomLayout(
-          atom_name=atom_names,
-          res_id=bond_layout.res_id,
-          chain_id=bond_layout.chain_id,
-          chain_type=bond_layout.chain_type,
-      )
-      # Remove bonds that are not in the crop.
-      cropped_tokens_to_bonds = atom_layout.compute_gather_idxs(
-          source_layout=all_tokens, target_layout=adjusted_bond_layout
-      )
-      bond_is_in_crop = np.all(
-          cropped_tokens_to_bonds.gather_mask, axis=1
-      ).astype(bool)
-      adjusted_bond_layout = adjusted_bond_layout[bond_is_in_crop, :]
-    else:
-      # Create layout with correct shape when bond_layout is None.
-      s = (0, 2)
-      adjusted_bond_layout = atom_layout.AtomLayout(
-          atom_name=np.array([], dtype=object).reshape(s),
-          res_id=np.array([], dtype=int).reshape(s),
-          chain_id=np.array([], dtype=object).reshape(s),
-      )
-    adjusted_bond_layout = adjusted_bond_layout.copy_and_pad_to(
-        (padding_shapes.num_tokens, 2)
-    )
-    tokens_to_polymer_ligand_bonds = atom_layout.compute_gather_idxs(
-        source_layout=all_tokens, target_layout=adjusted_bond_layout
-    )
-
-    # Stuff for computing the bond loss.
-    if bond_layout is not None:
-      # Pad to num_tokens (hoping that there are never more bonds than tokens).
-      padded_bond_layout = bond_layout.copy_and_pad_to(
-          (padding_shapes.num_tokens, 2)
-      )
-      token_atoms_to_bonds = atom_layout.compute_gather_idxs(
-          source_layout=all_token_atoms_layout, target_layout=padded_bond_layout
-      )
-    else:
-      token_atoms_to_bonds = atom_layout.GatherInfo(
-          gather_idxs=np.zeros((padding_shapes.num_tokens, 2), dtype=int),
-          gather_mask=np.zeros((padding_shapes.num_tokens, 2), dtype=bool),
-          input_shape=np.array((
-              padding_shapes.num_tokens,
-              all_token_atoms_layout.shape[1],
-          )),
-      )
-
-    return cls(
-        tokens_to_polymer_ligand_bonds=tokens_to_polymer_ligand_bonds,
-        token_atoms_to_bonds=token_atoms_to_bonds,
-    )
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    return cls(
-        tokens_to_polymer_ligand_bonds=atom_layout.GatherInfo.from_dict(
-            batch, key_prefix='tokens_to_polymer_ligand_bonds'
-        ),
-        token_atoms_to_bonds=atom_layout.GatherInfo.from_dict(
-            batch, key_prefix='token_atoms_to_polymer_ligand_bonds'
-        ),
-    )
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        **self.tokens_to_polymer_ligand_bonds.as_dict(
-            key_prefix='tokens_to_polymer_ligand_bonds'
-        ),
-        **self.token_atoms_to_bonds.as_dict(
-            key_prefix='token_atoms_to_polymer_ligand_bonds'
-        ),
-    }
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class LigandLigandBondInfo:
-  """Contains information about the location of ligand-ligand bonds."""
-
-  tokens_to_ligand_ligand_bonds: atom_layout.GatherInfo
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_tokens: atom_layout.AtomLayout,
-      bond_layout: atom_layout.AtomLayout | None,
-      padding_shapes: PaddingShapes,
-  ) -> Self:
-    """Computes the InterChainBondInfo features.
-
-    Args:
-      all_tokens: AtomLayout for tokens; shape (num_tokens,).
-      bond_layout: Bond layout for ligand-ligand bonds.
-      padding_shapes: Padding shapes.
-
-    Returns:
-      A LigandLigandBondInfo object.
-    """
-
-    if bond_layout is not None:
-      # Discard any bonds that do not join to an existing atom.
-      keep_mask = []
-      all_atom_ids = {
-          uid
-          for uid in zip(
-              all_tokens.chain_id,
-              all_tokens.res_id,
-              all_tokens.atom_name,
-              strict=True,
-          )
-      }
-      for chain_id, res_id, atom_name in zip(
-          bond_layout.chain_id,
-          bond_layout.res_id,
-          bond_layout.atom_name,
-          strict=True,
-      ):
-        atom_a = (chain_id[0], res_id[0], atom_name[0])
-        atom_b = (chain_id[1], res_id[1], atom_name[1])
-        if atom_a in all_atom_ids and atom_b in all_atom_ids:
-          keep_mask.append(True)
-        else:
-          keep_mask.append(False)
-      keep_mask = np.array(keep_mask).astype(bool)
-      bond_layout = bond_layout[keep_mask]
-      # Remove any bonds to Hydrogen atoms.
-      bond_layout = bond_layout[
-          ~np.char.startswith(bond_layout.atom_name.astype(str), 'H').any(
-              axis=1
-          )
-      ]
-      atom_names = bond_layout.atom_name
-      adjusted_bond_layout = atom_layout.AtomLayout(
-          atom_name=atom_names,
-          res_id=bond_layout.res_id,
-          chain_id=bond_layout.chain_id,
-          chain_type=bond_layout.chain_type,
-      )
-    else:
-      # Create layout with correct shape when bond_layout is None.
-      s = (0, 2)
-      adjusted_bond_layout = atom_layout.AtomLayout(
-          atom_name=np.array([], dtype=object).reshape(s),
-          res_id=np.array([], dtype=int).reshape(s),
-          chain_id=np.array([], dtype=object).reshape(s),
-      )
-    # 10 x num_tokens as max_inter_bonds_ratio + max_intra_bonds_ration = 2.061.
-    adjusted_bond_layout = adjusted_bond_layout.copy_and_pad_to(
-        (padding_shapes.num_tokens * 10, 2)
-    )
-    gather_idx = atom_layout.compute_gather_idxs(
-        source_layout=all_tokens, target_layout=adjusted_bond_layout
-    )
-    return cls(tokens_to_ligand_ligand_bonds=gather_idx)
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    return cls(
-        tokens_to_ligand_ligand_bonds=atom_layout.GatherInfo.from_dict(
-            batch, key_prefix='tokens_to_ligand_ligand_bonds'
-        )
-    )
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        **self.tokens_to_ligand_ligand_bonds.as_dict(
-            key_prefix='tokens_to_ligand_ligand_bonds'
-        )
-    }
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class PseudoBetaInfo:
-  """Contains information for extracting pseudo-beta and equivalent atoms."""
-
-  token_atoms_to_pseudo_beta: atom_layout.GatherInfo
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_token_atoms_layout: atom_layout.AtomLayout,
-      ccd: chemical_components.Ccd,
-      padding_shapes: PaddingShapes,
-      logging_name: str,
-  ) -> Self:
-    """Compute the PseudoBetaInfo features.
-
-    Args:
-      all_token_atoms_layout:  AtomLayout for all atoms per token, shape
-        (num_tokens, max_atoms_per_token)
-      ccd: The chemical components dictionary.
-      padding_shapes: padding shapes.
-      logging_name: logging name for debugging (usually the mmcif_id)
-
-    Returns:
-      A PseudoBetaInfo object.
-    """
-    token_idxs = []
-    atom_idxs = []
-    for token_idx in range(all_token_atoms_layout.shape[0]):
-      chain_type = all_token_atoms_layout.chain_type[token_idx, 0]
-      atom_names = list(all_token_atoms_layout.atom_name[token_idx, :])
-      atom_idx = None
-      is_nucleic_backbone = (
-          chain_type in mmcif_names.NUCLEIC_ACID_CHAIN_TYPES
-          or chain_type == mmcif_names.OTHER_CHAIN
-      )
-      if chain_type == mmcif_names.PROTEIN_CHAIN:
-        # Protein chains
-        if 'CB' in atom_names:
-          atom_idx = atom_names.index('CB')
-        elif 'CA' in atom_names:
-          atom_idx = atom_names.index('CA')
-      elif is_nucleic_backbone:
-        # RNA / DNA chains
-        res_name = all_token_atoms_layout.res_name[token_idx, 0]
-        cifdict = ccd.get(res_name)
-        if cifdict:
-          parent = cifdict['_chem_comp.mon_nstd_parent_comp_id'][0]
-          if parent != '?':
-            res_name = parent
-        if res_name in {'A', 'G', 'DA', 'DG'}:
-          if 'C4' in atom_names:
-            atom_idx = atom_names.index('C4')
-        else:
-          if 'C2' in atom_names:
-            atom_idx = atom_names.index('C2')
-      elif chain_type in mmcif_names.NON_POLYMER_CHAIN_TYPES:
-        # Ligands: there is only one atom per token
-        atom_idx = 0
-      else:
-        logging.warning(
-            '%s: Unknown chain type for token %i. (%s)',
-            logging_name,
-            token_idx,
-            all_token_atoms_layout[token_idx : token_idx + 1],
-        )
-        atom_idx = 0
-      if atom_idx is None:
-        (valid_atom_idxs,) = np.nonzero(
-            all_token_atoms_layout.atom_name[token_idx, :]
-        )
-        if valid_atom_idxs.shape[0] > 0:
-          atom_idx = valid_atom_idxs[0]
-        else:
-          atom_idx = 0
-        logging.warning(
-            '%s token %i (%s), does not contain a pseudo-beta atom.'
-            'Using first valid atom (%s) instead.',
-            logging_name,
-            token_idx,
-            all_token_atoms_layout[token_idx : token_idx + 1],
-            all_token_atoms_layout.atom_name[token_idx, atom_idx],
-        )
-
-      token_idxs.append(token_idx)
-      atom_idxs.append(atom_idx)
-
-    pseudo_beta_layout = all_token_atoms_layout[token_idxs, atom_idxs]
-    pseudo_beta_layout = pseudo_beta_layout.copy_and_pad_to((
-        padding_shapes.num_tokens,
-    ))
-    token_atoms_to_pseudo_beta = atom_layout.compute_gather_idxs(
-        source_layout=all_token_atoms_layout, target_layout=pseudo_beta_layout
-    )
-
-    return cls(
-        token_atoms_to_pseudo_beta=token_atoms_to_pseudo_beta,
-    )
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    return cls(
-        token_atoms_to_pseudo_beta=atom_layout.GatherInfo.from_dict(
-            batch, key_prefix='token_atoms_to_pseudo_beta'
-        ),
-    )
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        **self.token_atoms_to_pseudo_beta.as_dict(
-            key_prefix='token_atoms_to_pseudo_beta'
-        ),
-    }
-
-
-_DEFAULT_BLANK_REF = {
-    'positions': np.zeros(3),
-    'mask': 0,
-    'element': 0,
-    'charge': 0,
-    'atom_name_chars': np.zeros(4),
-}
-
-
-def random_rotation(random_state: np.random.RandomState) -> np.ndarray:
-  # Create a random rotation (Gram-Schmidt orthogonalization of two
-  # random normal vectors)
-  v0, v1 = random_state.normal(size=(2, 3))
-  e0 = v0 / np.maximum(1e-10, np.linalg.norm(v0))
-  v1 = v1 - e0 * np.dot(v1, e0)
-  e1 = v1 / np.maximum(1e-10, np.linalg.norm(v1))
-  e2 = np.cross(e0, e1)
-  return np.stack([e0, e1, e2])
-
-
-def random_augmentation(
-    positions: np.ndarray,
-    random_state: np.random.RandomState,
-) -> np.ndarray:
-  """Center then apply random translation and rotation."""
-
-  center = np.mean(positions, axis=0)
-  rot = random_rotation(random_state)
-  positions_target = np.einsum('ij,kj->ki', rot, positions - center)
-
-  translation = random_state.normal(size=(3,))
-  positions_target = positions_target + translation
-  return positions_target
-
-
-def _get_reference_positions_from_ccd_cif(
-    ccd_cif: cif_dict.CifDict,
-    ref_max_modified_date: datetime.date,
-    logging_name: str,
-) -> np.ndarray:
-  """Creates reference positions from a CCD mmcif data block."""
-  num_atoms = len(ccd_cif['_chem_comp_atom.atom_id'])
-  if '_chem_comp_atom.pdbx_model_Cartn_x_ideal' in ccd_cif:
-    atom_x = ccd_cif['_chem_comp_atom.pdbx_model_Cartn_x_ideal']
-    atom_y = ccd_cif['_chem_comp_atom.pdbx_model_Cartn_y_ideal']
-    atom_z = ccd_cif['_chem_comp_atom.pdbx_model_Cartn_z_ideal']
-  else:
-    atom_x = np.array(['?'] * num_atoms)
-    atom_y = np.array(['?'] * num_atoms)
-    atom_z = np.array(['?'] * num_atoms)
-  pos = np.array([[x, y, z] for x, y, z in zip(atom_x, atom_y, atom_z)])
-  # Unknown reference coordinates are specified by '?' in chem comp dict.
-  # Replace unknown reference coords with 0.
-  if '?' in pos and '_chem_comp.pdbx_modified_date' in ccd_cif:
-    # Use reference coordinates if modifed date is before cutoff.
-    modified_dates = [
-        datetime.date.fromisoformat(date)
-        for date in ccd_cif['_chem_comp.pdbx_modified_date']
-    ]
-    max_modified_date = max(modified_dates)
-    if max_modified_date < ref_max_modified_date:
-      atom_x = ccd_cif['_chem_comp_atom.model_Cartn_x']
-      atom_y = ccd_cif['_chem_comp_atom.model_Cartn_y']
-      atom_z = ccd_cif['_chem_comp_atom.model_Cartn_z']
-      pos = np.array([[x, y, z] for x, y, z in zip(atom_x, atom_y, atom_z)])
-  if '?' in pos:
-    if np.all(pos == '?'):
-      logging.warning('All ref positions unknown for: %s', logging_name)
-    else:
-      logging.warning('Some ref positions unknown for: %s', logging_name)
-    pos[pos == '?'] = 0
-  return np.array(pos, dtype=np.float32)
-
-
-def get_reference(
-    res_name: str,
-    chemical_components_data: struc_chem_comps.ChemicalComponentsData,
-    ccd: chemical_components.Ccd,
-    random_state: np.random.RandomState,
-    ref_max_modified_date: datetime.date,
-    conformer_max_iterations: int | None,
-) -> tuple[dict[str, Any], Any, Any]:
-  """Reference structure for residue from CCD or SMILES.
-
-  Uses CCD entry if available, otherwise uses SMILES from chemical components
-  data. Conformer generation is done using RDKit, with a fallback to CCD ideal
-  or reference coordinates if RDKit fails and those coordinates are supplied.
-
-  Args:
-    res_name: ccd code of the residue.
-    chemical_components_data: ChemicalComponentsData for making ref structure.
-    ccd: The chemical components dictionary.
-    random_state: Numpy RandomState
-    ref_max_modified_date: date beyond which reference structures must not be
-      modified to be allowed to use reference coordinates.
-    conformer_max_iterations: Optional override for maximum number of iterations
-      to run for RDKit conformer search.
-
-  Returns:
-    Mapping from atom names to features, from_atoms, dest_atoms.
-  """
-
-  ccd_cif = ccd.get(res_name)
-
-  mol = None
-  if ccd_cif:
-    try:
-      mol = rdkit_utils.mol_from_ccd_cif(ccd_cif, remove_hydrogens=False)
-    except rdkit_utils.MolFromMmcifError:
-      logging.warning('Failed to construct mol from ccd_cif for: %s', res_name)
-  else:  # No CCD entry, use SMILES from chemical components data.
-    if not (
-        chemical_components_data.chem_comp
-        and res_name in chemical_components_data.chem_comp
-        and chemical_components_data.chem_comp[res_name].pdbx_smiles
-    ):
-      raise ValueError(f'No CCD entry or SMILES for {res_name}.')
-    smiles_string = chemical_components_data.chem_comp[res_name].pdbx_smiles
-    logging.info('Using SMILES for: %s - %s', res_name, smiles_string)
-
-    mol = Chem.MolFromSmiles(smiles_string)
-    if mol is None:
-      # In this case the model will not have any information about this molecule
-      # and will not be able to predict anything about it.
-      raise ValueError(
-          f'Failed to construct RDKit Mol for {res_name} from SMILES string: '
-          f'{smiles_string} . This is likely due to an issue with the SMILES '
-          'string. Note that the userCCD input format provides an alternative '
-          'way to define custom molecules directly without RDKit or SMILES.'
-      )
-    mol = Chem.AddHs(mol)
-    # No existing names, we assign them from the graph.
-    mol = rdkit_utils.assign_atom_names_from_graph(mol)
-    # Temporary CCD cif with just atom and bond information, no coordinates.
-    ccd_cif = rdkit_utils.mol_to_ccd_cif(mol, component_id='fake_cif')
-
-  conformer = None
-  atom_names = []
-  elements = []
-  charges = []
-  pos = []
-
-  # If mol is not None (must be True for SMILES case), then we try and generate
-  # an RDKit conformer.
-  if mol is not None:
-    conformer_random_seed = int(random_state.randint(1, 1 << 31))
-    conformer = rdkit_utils.get_random_conformer(
-        mol=mol,
-        random_seed=conformer_random_seed,
-        max_iterations=conformer_max_iterations,
-        logging_name=res_name,
-    )
-    if conformer:
-      for idx, atom in enumerate(mol.GetAtoms()):
-        atom_names.append(atom.GetProp('atom_name'))
-        elements.append(atom.GetAtomicNum())
-        charges.append(atom.GetFormalCharge())
-        coords = conformer.GetAtomPosition(idx)
-        pos.append([coords.x, coords.y, coords.z])
-      pos = np.array(pos, dtype=np.float32)
-
-  # If no mol could be generated (can only happen when using CCD), or no
-  # conformer could be generated from the mol (can happen in either case), then
-  # use CCD cif instead (which will have zero coordinates for SMILES case).
-  if conformer is None:
-    atom_names = ccd_cif['_chem_comp_atom.atom_id']
-    charges = ccd_cif['_chem_comp_atom.charge']
-    type_symbols = ccd_cif['_chem_comp_atom.type_symbol']
-    elements = [
-        periodic_table.ATOMIC_NUMBER.get(elem_type.capitalize(), 0)
-        for elem_type in type_symbols
-    ]
-    pos = _get_reference_positions_from_ccd_cif(
-        ccd_cif=ccd_cif,
-        ref_max_modified_date=ref_max_modified_date,
-        logging_name=res_name,
-    )
-
-  # Augment reference positions.
-  pos = random_augmentation(pos, random_state)
-
-  # Extract atom and bond information from CCD cif.
-  from_atom = ccd_cif.get('_chem_comp_bond.atom_id_1', None)
-  dest_atom = ccd_cif.get('_chem_comp_bond.atom_id_2', None)
-
-  features = {}
-  for atom_name in atom_names:
-    features[atom_name] = {}
-    idx = atom_names.index(atom_name)
-    charge = 0 if charges[idx] == '?' else int(charges[idx])
-    atom_name_chars = np.array([ord(c) - 32 for c in atom_name], dtype=int)
-    atom_name_chars = _pad_to(atom_name_chars, (4,))
-    features[atom_name]['positions'] = pos[idx]
-    features[atom_name]['mask'] = 1
-    features[atom_name]['element'] = elements[idx]
-    features[atom_name]['charge'] = charge
-    features[atom_name]['atom_name_chars'] = atom_name_chars
-  return features, from_atom, dest_atom
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class RefStructure:
-  """Contains ref structure information."""
-
-  # Array with positions, float32, shape [num_res, max_atoms_per_token, 3]
-  positions: xnp_ndarray
-  # Array with masks, bool, shape [num_res, max_atoms_per_token]
-  mask: xnp_ndarray
-  # Array with elements, int32, shape [num_res, max_atoms_per_token]
-  element: xnp_ndarray
-  # Array with charges, float32, shape [num_res, max_atoms_per_token]
-  charge: xnp_ndarray
-  # Array with atom name characters, int32, [num_res, max_atoms_per_token, 4]
-  atom_name_chars: xnp_ndarray
-  # Array with reference space uids, int32, [num_res, max_atoms_per_token]
-  ref_space_uid: xnp_ndarray
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_token_atoms_layout: atom_layout.AtomLayout,
-      ccd: chemical_components.Ccd,
-      padding_shapes: PaddingShapes,
-      chemical_components_data: struc_chem_comps.ChemicalComponentsData,
-      random_state: np.random.RandomState,
-      ref_max_modified_date: datetime.date,
-      conformer_max_iterations: int | None,
-      ligand_ligand_bonds: atom_layout.AtomLayout | None = None,
-  ) -> tuple[Self, Any]:
-    """Reference structure information for each residue."""
-
-    # Get features per atom
-    padded_shape = (padding_shapes.num_tokens, all_token_atoms_layout.shape[1])
-    result = {
-        'positions': np.zeros((*padded_shape, 3), 'float32'),
-        'mask': np.zeros(padded_shape, 'bool'),
-        'element': np.zeros(padded_shape, 'int32'),
-        'charge': np.zeros(padded_shape, 'float32'),
-        'atom_name_chars': np.zeros((*padded_shape, 4), 'int32'),
-        'ref_space_uid': np.zeros((*padded_shape,), 'int32'),
-    }
-
-    atom_names_all = []
-    chain_ids_all = []
-    res_ids_all = []
-
-    # Cache reference conformations for each residue.
-    conformations = {}
-    ref_space_uids = {}
-    for idx in np.ndindex(all_token_atoms_layout.shape):
-      chain_id = all_token_atoms_layout.chain_id[idx]
-      res_id = all_token_atoms_layout.res_id[idx]
-      res_name = all_token_atoms_layout.res_name[idx]
-      is_non_standard = res_name not in _STANDARD_RESIDUES
-      atom_name = all_token_atoms_layout.atom_name[idx]
-      if not atom_name:
-        ref = _DEFAULT_BLANK_REF
-      else:
-        if (chain_id, res_id) not in conformations:
-          conf, from_atom, dest_atom = get_reference(
-              res_name=res_name,
-              chemical_components_data=chemical_components_data,
-              ccd=ccd,
-              random_state=random_state,
-              ref_max_modified_date=ref_max_modified_date,
-              conformer_max_iterations=conformer_max_iterations,
-          )
-          conformations[(chain_id, res_id)] = conf
-
-          if (
-              is_non_standard
-              and (from_atom is not None)
-              and (dest_atom is not None)
-          ):
-            # Add intra-ligand bond graph
-            atom_names_ligand = np.stack(
-                [from_atom, dest_atom], axis=1, dtype=object
-            )
-            atom_names_all.append(atom_names_ligand)
-            res_ids_all.append(
-                np.full_like(atom_names_ligand, res_id, dtype=int)
-            )
-            chain_ids_all.append(
-                np.full_like(atom_names_ligand, chain_id, dtype=object)
-            )
-
-        conformation = conformations.get(
-            (chain_id, res_id), {atom_name: _DEFAULT_BLANK_REF}
-        )
-        if atom_name not in conformation:
-          logging.warning(
-              'Missing atom "%s" for CCD "%s"',
-              atom_name,
-              all_token_atoms_layout.res_name[idx],
-          )
-        ref = conformation.get(atom_name, _DEFAULT_BLANK_REF)
-      for k in ref:
-        result[k][idx] = ref[k]
-
-      # Assign a unique reference space id to each component, to determine which
-      # reference positions live in the same reference space.
-      space_str_id = (
-          all_token_atoms_layout.chain_id[idx],
-          all_token_atoms_layout.res_id[idx],
-      )
-      if space_str_id not in ref_space_uids:
-        ref_space_uids[space_str_id] = len(ref_space_uids)
-      result['ref_space_uid'][idx] = ref_space_uids[space_str_id]
-
-    if atom_names_all:
-      atom_names_all = np.concatenate(atom_names_all, axis=0)
-      res_ids_all = np.concatenate(res_ids_all, axis=0)
-      chain_ids_all = np.concatenate(chain_ids_all, axis=0)
-      if ligand_ligand_bonds is not None:
-        adjusted_ligand_ligand_bonds = atom_layout.AtomLayout(
-            atom_name=np.concatenate(
-                [ligand_ligand_bonds.atom_name, atom_names_all], axis=0
-            ),
-            chain_id=np.concatenate(
-                [ligand_ligand_bonds.chain_id, chain_ids_all], axis=0
-            ),
-            res_id=np.concatenate(
-                [ligand_ligand_bonds.res_id, res_ids_all], axis=0
-            ),
-        )
-      else:
-        adjusted_ligand_ligand_bonds = atom_layout.AtomLayout(
-            atom_name=atom_names_all,
-            chain_id=chain_ids_all,
-            res_id=res_ids_all,
-        )
-    else:
-      adjusted_ligand_ligand_bonds = ligand_ligand_bonds
-
-    return cls(**result), adjusted_ligand_ligand_bonds
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    return cls(
-        positions=batch['ref_pos'],
-        mask=batch['ref_mask'],
-        element=batch['ref_element'],
-        charge=batch['ref_charge'],
-        atom_name_chars=batch['ref_atom_name_chars'],
-        ref_space_uid=batch['ref_space_uid'],
-    )
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        'ref_pos': self.positions,
-        'ref_mask': self.mask,
-        'ref_element': self.element,
-        'ref_charge': self.charge,
-        'ref_atom_name_chars': self.atom_name_chars,
-        'ref_space_uid': self.ref_space_uid,
-    }
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class ConvertModelOutput:
-  """Contains atom layout info."""
-
-  cleaned_struc: structure.Structure
-  token_atoms_layout: atom_layout.AtomLayout
-  flat_output_layout: atom_layout.AtomLayout
-  empty_output_struc: structure.Structure
-  polymer_ligand_bonds: atom_layout.AtomLayout
-  ligand_ligand_bonds: atom_layout.AtomLayout
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_token_atoms_layout: atom_layout.AtomLayout,
-      padding_shapes: PaddingShapes,
-      cleaned_struc: structure.Structure,
-      flat_output_layout: atom_layout.AtomLayout,
-      empty_output_struc: structure.Structure,
-      polymer_ligand_bonds: atom_layout.AtomLayout,
-      ligand_ligand_bonds: atom_layout.AtomLayout,
-  ) -> Self:
-    """Pads the all_token_atoms_layout and stores other data."""
-    # Crop and pad the all_token_atoms_layout.
-    token_atoms_layout = all_token_atoms_layout.copy_and_pad_to(
-        (padding_shapes.num_tokens, all_token_atoms_layout.shape[1])
-    )
-
-    return cls(
-        cleaned_struc=cleaned_struc,
-        token_atoms_layout=token_atoms_layout,
-        flat_output_layout=flat_output_layout,
-        empty_output_struc=empty_output_struc,
-        polymer_ligand_bonds=polymer_ligand_bonds,
-        ligand_ligand_bonds=ligand_ligand_bonds,
-    )
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    """Construct atom layout object from dictionary."""
-
-    return cls(
-        cleaned_struc=_unwrap(batch.get('cleaned_struc', None)),
-        token_atoms_layout=_unwrap(batch.get('token_atoms_layout', None)),
-        flat_output_layout=_unwrap(batch.get('flat_output_layout', None)),
-        empty_output_struc=_unwrap(batch.get('empty_output_struc', None)),
-        polymer_ligand_bonds=_unwrap(batch.get('polymer_ligand_bonds', None)),
-        ligand_ligand_bonds=_unwrap(batch.get('ligand_ligand_bonds', None)),
-    )
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        'cleaned_struc': np.array(self.cleaned_struc, object),
-        'token_atoms_layout': np.array(self.token_atoms_layout, object),
-        'flat_output_layout': np.array(self.flat_output_layout, object),
-        'empty_output_struc': np.array(self.empty_output_struc, object),
-        'polymer_ligand_bonds': np.array(self.polymer_ligand_bonds, object),
-        'ligand_ligand_bonds': np.array(self.ligand_ligand_bonds, object),
-    }
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class AtomCrossAtt:
-  """Operate on flat atoms."""
-
-  token_atoms_to_queries: atom_layout.GatherInfo
-  tokens_to_queries: atom_layout.GatherInfo
-  tokens_to_keys: atom_layout.GatherInfo
-  queries_to_keys: atom_layout.GatherInfo
-  queries_to_token_atoms: atom_layout.GatherInfo
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_token_atoms_layout: atom_layout.AtomLayout,  # (num_tokens, num_dense)
-      queries_subset_size: int,
-      keys_subset_size: int,
-      padding_shapes: PaddingShapes,
-  ) -> Self:
-    """Computes gather indices and meta data to work with a flat atom list."""
-
-    token_atoms_layout = all_token_atoms_layout.copy_and_pad_to(
-        (padding_shapes.num_tokens, all_token_atoms_layout.shape[1])
-    )
-    token_atoms_mask = token_atoms_layout.atom_name.astype(bool)
-    flat_layout = token_atoms_layout[token_atoms_mask]
-    num_atoms = flat_layout.shape[0]
-
-    padded_flat_layout = flat_layout.copy_and_pad_to((
-        padding_shapes.num_atoms,
-    ))
-
-    # Create the layout for queries
-    num_subsets = padding_shapes.num_atoms // queries_subset_size
-    lay_arr = padded_flat_layout.to_array()
-    queries_layout = atom_layout.AtomLayout.from_array(
-        lay_arr.reshape((6, num_subsets, queries_subset_size))
-    )
-
-    # Create the layout for the keys (the key subsets are centered around the
-    # query subsets)
-    # Create initial gather indices (contain out-of-bound indices)
-    subset_centers = np.arange(
-        queries_subset_size / 2, padding_shapes.num_atoms, queries_subset_size
-    )
-    flat_to_key_gathers = (
-        subset_centers[:, None]
-        + np.arange(-keys_subset_size / 2, keys_subset_size / 2)[None, :]
-    )
-    flat_to_key_gathers = flat_to_key_gathers.astype(int)
-    # Shift subsets with out-of-bound indices, such that they are fully within
-    # the bounds.
-    for row in range(flat_to_key_gathers.shape[0]):
-      if flat_to_key_gathers[row, 0] < 0:
-        flat_to_key_gathers[row, :] -= flat_to_key_gathers[row, 0]
-      elif flat_to_key_gathers[row, -1] > num_atoms - 1:
-        overflow = flat_to_key_gathers[row, -1] - (num_atoms - 1)
-        flat_to_key_gathers[row, :] -= overflow
-    # Create the keys layout.
-    keys_layout = padded_flat_layout[flat_to_key_gathers]
-
-    # Create gather indices for conversion between token atoms layout,
-    # queries layout and keys layout.
-    token_atoms_to_queries = atom_layout.compute_gather_idxs(
-        source_layout=token_atoms_layout, target_layout=queries_layout
-    )
-
-    token_atoms_to_keys = atom_layout.compute_gather_idxs(
-        source_layout=token_atoms_layout, target_layout=keys_layout
-    )
-
-    queries_to_keys = atom_layout.compute_gather_idxs(
-        source_layout=queries_layout, target_layout=keys_layout
-    )
-
-    queries_to_token_atoms = atom_layout.compute_gather_idxs(
-        source_layout=queries_layout, target_layout=token_atoms_layout
-    )
-
-    # Create gather indices for conversion of tokens layout to
-    # queries and keys layout
-    token_idxs = np.arange(padding_shapes.num_tokens).astype(np.int64)
-    token_idxs = np.broadcast_to(token_idxs[:, None], token_atoms_layout.shape)
-    tokens_to_queries = atom_layout.GatherInfo(
-        gather_idxs=atom_layout.convert(
-            token_atoms_to_queries, token_idxs, layout_axes=(0, 1)
-        ),
-        gather_mask=atom_layout.convert(
-            token_atoms_to_queries, token_atoms_mask, layout_axes=(0, 1)
-        ),
-        input_shape=np.array((padding_shapes.num_tokens,)),
-    )
-
-    tokens_to_keys = atom_layout.GatherInfo(
-        gather_idxs=atom_layout.convert(
-            token_atoms_to_keys, token_idxs, layout_axes=(0, 1)
-        ),
-        gather_mask=atom_layout.convert(
-            token_atoms_to_keys, token_atoms_mask, layout_axes=(0, 1)
-        ),
-        input_shape=np.array((padding_shapes.num_tokens,)),
-    )
-
-    return cls(
-        token_atoms_to_queries=token_atoms_to_queries,
-        tokens_to_queries=tokens_to_queries,
-        tokens_to_keys=tokens_to_keys,
-        queries_to_keys=queries_to_keys,
-        queries_to_token_atoms=queries_to_token_atoms,
-    )
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    return cls(
-        token_atoms_to_queries=atom_layout.GatherInfo.from_dict(
-            batch, key_prefix='token_atoms_to_queries'
-        ),
-        tokens_to_queries=atom_layout.GatherInfo.from_dict(
-            batch, key_prefix='tokens_to_queries'
-        ),
-        tokens_to_keys=atom_layout.GatherInfo.from_dict(
-            batch, key_prefix='tokens_to_keys'
-        ),
-        queries_to_keys=atom_layout.GatherInfo.from_dict(
-            batch, key_prefix='queries_to_keys'
-        ),
-        queries_to_token_atoms=atom_layout.GatherInfo.from_dict(
-            batch, key_prefix='queries_to_token_atoms'
-        ),
-    )
-
-  def as_data_dict(self) -> BatchDict:
-    return {
-        **self.token_atoms_to_queries.as_dict(
-            key_prefix='token_atoms_to_queries'
-        ),
-        **self.tokens_to_queries.as_dict(key_prefix='tokens_to_queries'),
-        **self.tokens_to_keys.as_dict(key_prefix='tokens_to_keys'),
-        **self.queries_to_keys.as_dict(key_prefix='queries_to_keys'),
-        **self.queries_to_token_atoms.as_dict(
-            key_prefix='queries_to_token_atoms'
-        ),
-    }
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class Frames:
-  """Features for backbone frames."""
-
-  mask: xnp_ndarray
-
-  @classmethod
-  def compute_features(
-      cls,
-      all_tokens: atom_layout.AtomLayout,
-      all_token_atoms_layout: atom_layout.AtomLayout,
-      ref_structure: RefStructure,
-      padding_shapes: PaddingShapes,
-  ) -> Self:
-    """Computes features for backbone frames."""
-    num_tokens = padding_shapes.num_tokens
-    all_token_atoms_layout = all_token_atoms_layout.copy_and_pad_to(
-        (num_tokens, all_token_atoms_layout.shape[1])
-    )
-
-    all_token_atoms_to_all_tokens = atom_layout.compute_gather_idxs(
-        source_layout=all_token_atoms_layout, target_layout=all_tokens
-    )
-    ref_coordinates = atom_layout.convert(
-        all_token_atoms_to_all_tokens,
-        ref_structure.positions.astype(np.float32),
-        layout_axes=(0, 1),
-    )
-    ref_mask = atom_layout.convert(
-        all_token_atoms_to_all_tokens,
-        ref_structure.mask.astype(bool),
-        layout_axes=(0, 1),
-    )
-    ref_mask = ref_mask & all_token_atoms_to_all_tokens.gather_mask.astype(bool)
-
-    all_frame_mask = []
-
-    # Iterate over tokens
-    for idx, args in enumerate(
-        zip(all_tokens.chain_type, all_tokens.chain_id, all_tokens.res_id)
-    ):
-
-      chain_type, chain_id, res_id = args
-
-      if chain_type in list(mmcif_names.PEPTIDE_CHAIN_TYPES):
-        frame_mask = True
-      elif chain_type in list(mmcif_names.NUCLEIC_ACID_CHAIN_TYPES):
-        frame_mask = True
-      elif chain_type in list(mmcif_names.NON_POLYMER_CHAIN_TYPES):
-        # For ligands, build frames from closest atoms from the same molecule.
-        (local_token_idxs,) = np.where(
-            (all_tokens.chain_type == chain_type)
-            & (all_tokens.chain_id == chain_id)
-            & (all_tokens.res_id == res_id)
-        )
-
-        if len(local_token_idxs) < 3:
-          frame_mask = False
-
-        else:
-          # [local_tokens]
-          local_dist = np.linalg.norm(
-              ref_coordinates[idx] - ref_coordinates[local_token_idxs], axis=-1
-          )
-          local_mask = ref_mask[local_token_idxs]
-          cost = local_dist + 1e8 * ~local_mask
-          cost = cost + 1e8 * (idx == local_token_idxs)
-          # [local_tokens]
-          closest_idxs = np.argsort(cost, axis=0)
-
-          # The closest indices index an array of local tokens. Convert this
-          # to indices of the full (num_tokens,) array.
-          global_closest_idxs = local_token_idxs[closest_idxs]
-
-          # Construct frame by placing the current token at the origin and two
-          # nearest atoms on either side.
-          global_frame_idxs = np.array(
-              (global_closest_idxs[0], idx, global_closest_idxs[1])
-          )
-
-          # Check that the frame atoms are not colinear.
-          a, b, c = ref_coordinates[global_frame_idxs]
-          vec1 = a - b
-          vec2 = c - b
-          # Reference coordinates can be all zeros, in which case we have
-          # to explicitly set colinearity.
-          if np.isclose(np.linalg.norm(vec1, axis=-1), 0) or np.isclose(
-              np.linalg.norm(vec2, axis=-1), 0
-          ):
-            is_colinear = True
-            logging.info('Found identical coordinates: Assigning as colinear.')
-          else:
-            vec1 = vec1 / np.linalg.norm(vec1, axis=-1)
-            vec2 = vec2 / np.linalg.norm(vec2, axis=-1)
-            cos_angle = np.einsum('...k,...k->...', vec1, vec2)
-            # <25 degree deviation is considered colinear.
-            is_colinear = 1 - np.abs(cos_angle) < 0.0937
-
-          frame_mask = not is_colinear
-      else:
-        # No frame for other chain types.
-        frame_mask = False
-
-      all_frame_mask.append(frame_mask)
-
-    all_frame_mask = np.array(all_frame_mask, dtype=bool)
-
-    mask = _pad_to(all_frame_mask, (padding_shapes.num_tokens,))
-
-    return cls(mask=mask)
-
-  @classmethod
-  def from_data_dict(cls, batch: BatchDict) -> Self:
-    return cls(mask=batch['frames_mask'])
-
-  def as_data_dict(self) -> BatchDict:
-    return {'frames_mask': self.mask}
diff --git a/src/alphafold3/model/merging_features.py b/src/alphafold3/model/merging_features.py
deleted file mode 100644
index 81bc48e613c0a74a342176992f02ab62f64930a0..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/merging_features.py
+++ /dev/null
@@ -1,92 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Methods for merging existing features to create a new example.
-
-Covers:
-- Merging features across chains.
-- Merging the paired and unpaired parts of the MSA.
-"""
-
-from typing import TypeAlias
-
-from alphafold3.model import data_constants
-import jax.numpy as jnp
-import numpy as np
-
-NUM_SEQ_NUM_RES_MSA_FEATURES = data_constants.NUM_SEQ_NUM_RES_MSA_FEATURES
-NUM_SEQ_MSA_FEATURES = data_constants.NUM_SEQ_MSA_FEATURES
-MSA_PAD_VALUES = data_constants.MSA_PAD_VALUES
-
-
-xnp_ndarray: TypeAlias = np.ndarray | jnp.ndarray  # pylint: disable=invalid-name
-BatchDict: TypeAlias = dict[str, xnp_ndarray]
-
-
-def _pad_features_to_max(feat_name: str, chains: list[BatchDict], axis: int):
-  """Pad a set of features to the maximum size amongst all chains.
-
-  Args:
-    feat_name: The feature name to pad.
-    chains: A list of chains with associated features.
-    axis: Which axis to pad to the max.
-
-  Returns:
-    A list of features, all with the same size on the given axis.
-  """
-  max_num_seq = np.max([chain[feat_name].shape[axis] for chain in chains])
-
-  padded_feats = []
-  for chain in chains:
-    feat = chain[feat_name]
-
-    padding = np.zeros_like(feat.shape)  # pytype: disable=attribute-error
-    padding[axis] = max_num_seq - feat.shape[axis]  # pytype: disable=attribute-error
-    padding = [(0, p) for p in padding]
-    padded_feats.append(
-        np.pad(
-            feat,
-            padding,
-            mode='constant',
-            constant_values=MSA_PAD_VALUES[feat_name],
-        )
-    )
-  return padded_feats
-
-
-def merge_msa_features(feat_name: str, chains: list[BatchDict]) -> np.ndarray:
-  """Merges MSA features with shape (NUM_SEQ, NUM_RES) across chains."""
-  expected_dtype = chains[0][feat_name].dtype
-  if '_all_seq' in feat_name:
-    return np.concatenate(
-        [c.get(feat_name, np.array([], expected_dtype)) for c in chains], axis=1
-    )
-  else:
-    # Since each MSA can be of different lengths, we first need to pad them
-    # all to the size of the largest MSA before concatenating.
-    padded_feats = _pad_features_to_max(feat_name, chains, axis=0)
-    return np.concatenate(padded_feats, axis=1)
-
-
-def merge_paired_and_unpaired_msa(example: BatchDict) -> BatchDict:
-  """Concatenates the paired (all_seq) MSA features with the unpaired ones."""
-  new_example = dict(example)
-
-  for feature_name in NUM_SEQ_NUM_RES_MSA_FEATURES + NUM_SEQ_MSA_FEATURES:
-    if feature_name in example and feature_name + '_all_seq' in example:
-      feat = example[feature_name]
-      feat_all_seq = example[feature_name + '_all_seq']
-      merged_feat = np.concatenate([feat_all_seq, feat], axis=0)
-      new_example[feature_name] = merged_feat
-
-  new_example['num_alignments'] = np.array(
-      new_example['msa'].shape[0], dtype=np.int32
-  )
-  return new_example
diff --git a/src/alphafold3/model/mkdssp_pybind.cc b/src/alphafold3/model/mkdssp_pybind.cc
deleted file mode 100644
index 27ca7b58c3fe541abd630357a53c89ee229ffb56..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/mkdssp_pybind.cc
+++ /dev/null
@@ -1,63 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include "alphafold3/model/mkdssp_pybind.h"
-
-#include <filesystem>
-
-#include <cif++/file.hpp>
-#include <cif++/pdb.hpp>
-#include <dssp.hpp>
-#include <sstream>
-
-#include "absl/strings/string_view.h"
-#include "pybind11/pybind11.h"
-#include "pybind11/pytypes.h"
-
-namespace alphafold3 {
-namespace py = pybind11;
-
-void RegisterModuleMkdssp(pybind11::module m) {
-  py::module site = py::module::import("site");
-  py::list paths = py::cast<py::list>(site.attr("getsitepackages")());
-  // Find the first path that contains the libcifpp components.cif file.
-  bool found = false;
-  for (const auto& py_path : paths) {
-    auto path_str =
-        std::filesystem::path(py::cast<absl::string_view>(py_path)) /
-        "share/libcifpp/components.cif";
-    if (std::filesystem::exists(path_str)) {
-      setenv("LIBCIFPP_DATA_DIR", path_str.parent_path().c_str(), 0);
-      found = true;
-      break;
-    }
-  }
-  if (!found) {
-    throw py::type_error("Could not find the libcifpp components.cif file.");
-  }
-  m.def(
-      "get_dssp",
-      [](absl::string_view mmcif, int model_no,
-         int min_poly_proline_stretch_length,
-         bool calculate_surface_accessibility) {
-        cif::file cif_file(mmcif.data(), mmcif.size());
-        dssp result(cif_file.front(), model_no, min_poly_proline_stretch_length,
-                    calculate_surface_accessibility);
-        std::stringstream sstream;
-        result.write_legacy_output(sstream);
-        return sstream.str();
-      },
-      py::arg("mmcif"), py::arg("model_no") = 1,
-      py::arg("min_poly_proline_stretch_length") = 3,
-      py::arg("calculate_surface_accessibility") = false,
-      py::doc("Gets secondary structure from an mmCIF file."));
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/model/mkdssp_pybind.h b/src/alphafold3/model/mkdssp_pybind.h
deleted file mode 100644
index a1e4832b8d65ac28568424dbd2bf5001b896f646..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/mkdssp_pybind.h
+++ /dev/null
@@ -1,26 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_MODEL_MKDSSP_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_MODEL_MKDSSP_PYBIND_H_
-
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleMkdssp(pybind11::module m);
-
-}
-
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_MODEL_MKDSSP_PYBIND_H_
diff --git a/src/alphafold3/model/mmcif_metadata.py b/src/alphafold3/model/mmcif_metadata.py
deleted file mode 100644
index 52390463da1af9d41048d23cbbce6e2f397b6b9a..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/mmcif_metadata.py
+++ /dev/null
@@ -1,230 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Adds mmCIF metadata (to be ModelCIF-conformant) and author and legal info."""
-
-from typing import Final
-
-from alphafold3.structure import mmcif
-import numpy as np
-
-_LICENSE_URL: Final[str] = (
-    'https://github.com/google-deepmind/alphafold3/blob/main/OUTPUT_TERMS_OF_USE.md'
-)
-
-_LICENSE: Final[str] = f"""
-Non-commercial use only, by using this file you agree to the terms of use found
-at {_LICENSE_URL}.
-To request access to the AlphaFold 3 model parameters, follow the process set
-out at https://github.com/google-deepmind/alphafold3. You may only use these if
-received directly from Google. Use is subject to terms of use available at
-https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md.
-""".strip()
-
-_DISCLAIMER: Final[str] = """\
-AlphaFold 3 and its output are not intended for, have not been validated for,
-and are not approved for clinical use. They are provided "as-is" without any
-warranty of any kind, whether expressed or implied. No warranty is given that
-use shall not infringe the rights of any third party.
-""".strip()
-
-_MMCIF_PAPER_AUTHORS: Final[tuple[str, ...]] = (
-    'Google DeepMind',
-    'Isomorphic Labs',
-)
-
-# Authors of the mmCIF - we set them to be equal to the authors of the paper.
-_MMCIF_AUTHORS: Final[tuple[str, ...]] = _MMCIF_PAPER_AUTHORS
-
-
-def add_metadata_to_mmcif(
-    old_cif: mmcif.Mmcif, version: str, model_id: bytes
-) -> mmcif.Mmcif:
-  """Adds metadata to a mmCIF to make it ModelCIF-conformant."""
-  cif = {}
-
-  # ModelCIF conformation dictionary.
-  cif['_audit_conform.dict_name'] = ['mmcif_ma.dic']
-  cif['_audit_conform.dict_version'] = ['1.4.5']
-  cif['_audit_conform.dict_location'] = [
-      'https://raw.githubusercontent.com/ihmwg/ModelCIF/master/dist/mmcif_ma.dic'
-  ]
-
-  cif['_pdbx_data_usage.id'] = ['1', '2']
-  cif['_pdbx_data_usage.type'] = ['license', 'disclaimer']
-  cif['_pdbx_data_usage.details'] = [_LICENSE, _DISCLAIMER]
-  cif['_pdbx_data_usage.url'] = [_LICENSE_URL, '?']
-
-  # Structure author details.
-  cif['_audit_author.name'] = []
-  cif['_audit_author.pdbx_ordinal'] = []
-  for author_index, author_name in enumerate(_MMCIF_AUTHORS, start=1):
-    cif['_audit_author.name'].append(author_name)
-    cif['_audit_author.pdbx_ordinal'].append(str(author_index))
-
-  # Paper author details.
-  cif['_citation_author.citation_id'] = []
-  cif['_citation_author.name'] = []
-  cif['_citation_author.ordinal'] = []
-  for author_index, author_name in enumerate(_MMCIF_PAPER_AUTHORS, start=1):
-    cif['_citation_author.citation_id'].append('primary')
-    cif['_citation_author.name'].append(author_name)
-    cif['_citation_author.ordinal'].append(str(author_index))
-
-  # Paper citation details.
-  cif['_citation.id'] = ['primary']
-  cif['_citation.title'] = [
-      'Accurate structure prediction of biomolecular interactions with'
-      ' AlphaFold 3'
-  ]
-  cif['_citation.journal_full'] = ['Nature']
-  cif['_citation.journal_volume'] = ['630']
-  cif['_citation.page_first'] = ['493']
-  cif['_citation.page_last'] = ['500']
-  cif['_citation.year'] = ['2024']
-  cif['_citation.journal_id_ASTM'] = ['NATUAS']
-  cif['_citation.country'] = ['UK']
-  cif['_citation.journal_id_ISSN'] = ['0028-0836']
-  cif['_citation.journal_id_CSD'] = ['0006']
-  cif['_citation.book_publisher'] = ['?']
-  cif['_citation.pdbx_database_id_PubMed'] = ['38718835']
-  cif['_citation.pdbx_database_id_DOI'] = ['10.1038/s41586-024-07487-w']
-
-  # Type of data in the dataset including data used in the model generation.
-  cif['_ma_data.id'] = ['1']
-  cif['_ma_data.name'] = ['Model']
-  cif['_ma_data.content_type'] = ['model coordinates']
-
-  # Description of number of instances for each entity.
-  cif['_ma_target_entity_instance.asym_id'] = old_cif['_struct_asym.id']
-  cif['_ma_target_entity_instance.entity_id'] = old_cif[
-      '_struct_asym.entity_id'
-  ]
-  cif['_ma_target_entity_instance.details'] = ['.'] * len(
-      cif['_ma_target_entity_instance.entity_id']
-  )
-
-  # Details about the target entities.
-  cif['_ma_target_entity.entity_id'] = cif[
-      '_ma_target_entity_instance.entity_id'
-  ]
-  cif['_ma_target_entity.data_id'] = ['1'] * len(
-      cif['_ma_target_entity.entity_id']
-  )
-  cif['_ma_target_entity.origin'] = ['.'] * len(
-      cif['_ma_target_entity.entity_id']
-  )
-
-  # Details of the models being deposited.
-  cif['_ma_model_list.ordinal_id'] = ['1']
-  cif['_ma_model_list.model_id'] = ['1']
-  cif['_ma_model_list.model_group_id'] = ['1']
-  cif['_ma_model_list.model_name'] = ['Top ranked model']
-
-  cif['_ma_model_list.model_group_name'] = [
-      f'AlphaFold-beta-20231127 ({version})'
-  ]
-  cif['_ma_model_list.data_id'] = ['1']
-  cif['_ma_model_list.model_type'] = ['Ab initio model']
-
-  # Software used.
-  cif['_software.pdbx_ordinal'] = ['1']
-  cif['_software.name'] = ['AlphaFold']
-  cif['_software.version'] = [
-      f'AlphaFold-beta-20231127 ({model_id.decode("ascii")})'
-  ]
-  cif['_software.type'] = ['package']
-  cif['_software.description'] = ['Structure prediction']
-  cif['_software.classification'] = ['other']
-  cif['_software.date'] = ['?']
-
-  # Collection of software into groups.
-  cif['_ma_software_group.ordinal_id'] = ['1']
-  cif['_ma_software_group.group_id'] = ['1']
-  cif['_ma_software_group.software_id'] = ['1']
-
-  # Method description to conform with ModelCIF.
-  cif['_ma_protocol_step.ordinal_id'] = ['1', '2', '3']
-  cif['_ma_protocol_step.protocol_id'] = ['1', '1', '1']
-  cif['_ma_protocol_step.step_id'] = ['1', '2', '3']
-  cif['_ma_protocol_step.method_type'] = [
-      'coevolution MSA',
-      'template search',
-      'modeling',
-  ]
-
-  # Details of the metrics use to assess model confidence.
-  cif['_ma_qa_metric.id'] = ['1', '2']
-  cif['_ma_qa_metric.name'] = ['pLDDT', 'pLDDT']
-  # Accepted values are distance, energy, normalised score, other, zscore.
-  cif['_ma_qa_metric.type'] = ['pLDDT', 'pLDDT']
-  cif['_ma_qa_metric.mode'] = ['global', 'local']
-  cif['_ma_qa_metric.software_group_id'] = ['1', '1']
-
-  # Global model confidence pLDDT value.
-  cif['_ma_qa_metric_global.ordinal_id'] = ['1']
-  cif['_ma_qa_metric_global.model_id'] = ['1']
-  cif['_ma_qa_metric_global.metric_id'] = ['1']
-  # Mean over all atoms, since AlphaFold 3 outputs pLDDT per-atom.
-  global_plddt = np.mean(
-      [float(v) for v in old_cif['_atom_site.B_iso_or_equiv']]
-  )
-  cif['_ma_qa_metric_global.metric_value'] = [f'{global_plddt:.2f}']
-
-  # Local (per residue) model confidence pLDDT value.
-  cif['_ma_qa_metric_local.ordinal_id'] = []
-  cif['_ma_qa_metric_local.model_id'] = []
-  cif['_ma_qa_metric_local.label_asym_id'] = []
-  cif['_ma_qa_metric_local.label_seq_id'] = []
-  cif['_ma_qa_metric_local.label_comp_id'] = []
-  cif['_ma_qa_metric_local.metric_id'] = []
-  cif['_ma_qa_metric_local.metric_value'] = []
-
-  plddt_grouped_by_res = {}
-  for *res, atom_plddt in zip(
-      old_cif['_atom_site.label_asym_id'],
-      old_cif['_atom_site.label_seq_id'],
-      old_cif['_atom_site.label_comp_id'],
-      old_cif['_atom_site.B_iso_or_equiv'],
-  ):
-    plddt_grouped_by_res.setdefault(tuple(res), []).append(float(atom_plddt))
-
-  for ordinal_id, ((chain_id, res_id, res_name), res_plddts) in enumerate(
-      plddt_grouped_by_res.items(), start=1
-  ):
-    res_plddt = np.mean(res_plddts)
-    cif['_ma_qa_metric_local.ordinal_id'].append(str(ordinal_id))
-    cif['_ma_qa_metric_local.model_id'].append('1')
-    cif['_ma_qa_metric_local.label_asym_id'].append(chain_id)
-    cif['_ma_qa_metric_local.label_seq_id'].append(res_id)
-    cif['_ma_qa_metric_local.label_comp_id'].append(res_name)
-    cif['_ma_qa_metric_local.metric_id'].append('2')  # See _ma_qa_metric.id.
-    cif['_ma_qa_metric_local.metric_value'].append(f'{res_plddt:.2f}')
-
-  cif['_atom_type.symbol'] = sorted(set(old_cif['_atom_site.type_symbol']))
-
-  return old_cif.copy_and_update(cif)
-
-
-def add_legal_comment(cif: str) -> str:
-  """Adds legal comment at the top of the mmCIF."""
-  # fmt: off
-  # pylint: disable=line-too-long
-  comment = (
-      '# By using this file you agree to the legally binding terms of use found at\n'
-      f'# {_LICENSE_URL}.\n'
-      '# To request access to the AlphaFold 3 model parameters, follow the process set\n'
-      '# out at https://github.com/google-deepmind/alphafold3. You may only use these if\n'
-      '# received directly from Google. Use is subject to terms of use available at\n'
-      '# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md.'
-  )
-  # pylint: enable=line-too-long
-  # fmt: on
-  return f'{comment}\n{cif}'
diff --git a/src/alphafold3/model/model.py b/src/alphafold3/model/model.py
deleted file mode 100644
index 1d28772cc3abe36c8dc91777821a6d16d569b5aa..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/model.py
+++ /dev/null
@@ -1,516 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""AlphaFold3 model."""
-
-from collections.abc import Iterable, Mapping
-import concurrent
-import dataclasses
-import functools
-from typing import Any, TypeAlias
-
-from absl import logging
-from alphafold3 import structure
-from alphafold3.common import base_config
-from alphafold3.model import confidences
-from alphafold3.model import feat_batch
-from alphafold3.model import features
-from alphafold3.model import model_config
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.model.components import mapping
-from alphafold3.model.components import utils
-from alphafold3.model.network import atom_cross_attention
-from alphafold3.model.network import confidence_head
-from alphafold3.model.network import diffusion_head
-from alphafold3.model.network import distogram_head
-from alphafold3.model.network import evoformer as evoformer_network
-from alphafold3.model.network import featurization
-import haiku as hk
-import jax
-import jax.numpy as jnp
-import numpy as np
-
-
-ModelResult: TypeAlias = Mapping[str, Any]
-_ScalarNumberOrArray: TypeAlias = Mapping[str, float | int | np.ndarray]
-
-
-@dataclasses.dataclass(frozen=True)
-class InferenceResult:
-  """Postprocessed model result.
-
-  Attributes:
-    predicted_structure: Predicted protein structure.
-    numerical_data: Useful numerical data (scalars or arrays) to be saved at
-      inference time.
-    metadata: Smaller numerical data (usually scalar) to be saved as inference
-      metadata.
-    debug_outputs: Additional dict for debugging, e.g. raw outputs of a model
-      forward pass.
-    model_id: Model identifier.
-  """
-
-  predicted_structure: structure.Structure = dataclasses.field()
-  numerical_data: _ScalarNumberOrArray = dataclasses.field(default_factory=dict)
-  metadata: _ScalarNumberOrArray = dataclasses.field(default_factory=dict)
-  debug_outputs: Mapping[str, Any] = dataclasses.field(default_factory=dict)
-  model_id: bytes = b''
-
-
-def get_predicted_structure(
-    result: ModelResult, batch: feat_batch.Batch
-) -> structure.Structure:
-  """Creates the predicted structure and ion preditions.
-
-  Args:
-    result: model output in a model specific layout
-    batch: model input batch
-
-  Returns:
-    Predicted structure.
-  """
-  model_output_coords = result['diffusion_samples']['atom_positions']
-
-  # Rearrange model output coordinates to the flat output layout.
-  model_output_to_flat = atom_layout.compute_gather_idxs(
-      source_layout=batch.convert_model_output.token_atoms_layout,
-      target_layout=batch.convert_model_output.flat_output_layout,
-  )
-  pred_flat_atom_coords = atom_layout.convert(
-      gather_info=model_output_to_flat,
-      arr=model_output_coords,
-      layout_axes=(-3, -2),
-  )
-
-  predicted_lddt = result.get('predicted_lddt')
-
-  if predicted_lddt is not None:
-    pred_flat_b_factors = atom_layout.convert(
-        gather_info=model_output_to_flat,
-        arr=predicted_lddt,
-        layout_axes=(-2, -1),
-    )
-  else:
-    # Handle models which don't have predicted_lddt outputs.
-    pred_flat_b_factors = np.zeros(pred_flat_atom_coords.shape[:-1])
-
-  (missing_atoms_indices,) = np.nonzero(model_output_to_flat.gather_mask == 0)
-  if missing_atoms_indices.shape[0] > 0:
-    missing_atoms_flat_layout = batch.convert_model_output.flat_output_layout[
-        missing_atoms_indices
-    ]
-    missing_atoms_uids = list(
-        zip(
-            missing_atoms_flat_layout.chain_id,
-            missing_atoms_flat_layout.res_id,
-            missing_atoms_flat_layout.res_name,
-            missing_atoms_flat_layout.atom_name,
-        )
-    )
-    logging.warning(
-        'Target %s: warning: %s atoms were not predicted by the '
-        'model, setting their coordinates to (0, 0, 0). '
-        'Missing atoms: %s',
-        batch.convert_model_output.empty_output_struc.name,
-        missing_atoms_indices.shape[0],
-        missing_atoms_uids,
-    )
-
-  # Put them into a structure
-  pred_struc = batch.convert_model_output.empty_output_struc
-  pred_struc = pred_struc.copy_and_update_atoms(
-      atom_x=pred_flat_atom_coords[..., 0],
-      atom_y=pred_flat_atom_coords[..., 1],
-      atom_z=pred_flat_atom_coords[..., 2],
-      atom_b_factor=pred_flat_b_factors,
-      atom_occupancy=np.ones(pred_flat_atom_coords.shape[:-1]),  # Always 1.0.
-  )
-  # Set manually/differently when adding metadata.
-  pred_struc = pred_struc.copy_and_update_globals(release_date=None)
-  return pred_struc
-
-
-def create_target_feat_embedding(
-    batch: feat_batch.Batch,
-    config: evoformer_network.Evoformer.Config,
-    global_config: model_config.GlobalConfig,
-) -> jnp.ndarray:
-  """Create target feature embedding."""
-
-  dtype = jnp.bfloat16 if global_config.bfloat16 == 'all' else jnp.float32
-
-  with utils.bfloat16_context():
-    target_feat = featurization.create_target_feat(
-        batch,
-        append_per_atom_features=False,
-    ).astype(dtype)
-
-    enc = atom_cross_attention.atom_cross_att_encoder(
-        token_atoms_act=None,
-        trunk_single_cond=None,
-        trunk_pair_cond=None,
-        config=config.per_atom_conditioning,
-        global_config=global_config,
-        batch=batch,
-        name='evoformer_conditioning',
-    )
-    target_feat = jnp.concatenate([target_feat, enc.token_act], axis=-1).astype(
-        dtype
-    )
-
-  return target_feat
-
-
-def _compute_ptm(
-    result: ModelResult,
-    num_tokens: int,
-    asym_id: np.ndarray,
-    pae_single_mask: np.ndarray,
-    interface: bool,
-) -> np.ndarray:
-  """Computes the pTM metrics from PAE."""
-  return np.stack(
-      [
-          confidences.predicted_tm_score(
-              tm_adjusted_pae=tm_adjusted_pae[:num_tokens, :num_tokens],
-              asym_id=asym_id,
-              pair_mask=pae_single_mask[:num_tokens, :num_tokens],
-              interface=interface,
-          )
-          for tm_adjusted_pae in result['tmscore_adjusted_pae_global']
-      ],
-      axis=0,
-  )
-
-
-def _compute_chain_pair_iptm(
-    num_tokens: int,
-    asym_ids: np.ndarray,
-    mask: np.ndarray,
-    tm_adjusted_pae: np.ndarray,
-) -> np.ndarray:
-  """Computes the chain pair ipTM metrics from PAE."""
-  return np.stack(
-      [
-          confidences.chain_pairwise_predicted_tm_scores(
-              tm_adjusted_pae=sample_tm_adjusted_pae[:num_tokens],
-              asym_id=asym_ids[:num_tokens],
-              pair_mask=mask[:num_tokens, :num_tokens],
-          )
-          for sample_tm_adjusted_pae in tm_adjusted_pae
-      ],
-      axis=0,
-  )
-
-
-class Model(hk.Module):
-  """Full model. Takes in data batch and returns model outputs."""
-
-  class HeadsConfig(base_config.BaseConfig):
-    diffusion: diffusion_head.DiffusionHead.Config = base_config.autocreate()
-    confidence: confidence_head.ConfidenceHead.Config = base_config.autocreate()
-    distogram: distogram_head.DistogramHead.Config = base_config.autocreate()
-
-  class Config(base_config.BaseConfig):
-    evoformer: evoformer_network.Evoformer.Config = base_config.autocreate()
-    global_config: model_config.GlobalConfig = base_config.autocreate()
-    heads: 'Model.HeadsConfig' = base_config.autocreate()
-    num_recycles: int = 10
-    return_embeddings: bool = False
-
-  def __init__(self, config: Config, name: str = 'diffuser'):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = config.global_config
-    self.diffusion_module = diffusion_head.DiffusionHead(
-        self.config.heads.diffusion, self.global_config
-    )
-
-  @hk.transparent
-  def _sample_diffusion(
-      self,
-      batch: feat_batch.Batch,
-      embeddings: dict[str, jnp.ndarray],
-      *,
-      sample_config: diffusion_head.SampleConfig,
-  ) -> dict[str, jnp.ndarray]:
-    denoising_step = functools.partial(
-        self.diffusion_module,
-        batch=batch,
-        embeddings=embeddings,
-        use_conditioning=True,
-    )
-
-    sample = diffusion_head.sample(
-        denoising_step=denoising_step,
-        batch=batch,
-        key=hk.next_rng_key(),
-        config=sample_config,
-    )
-    return sample
-
-  def __call__(
-      self, batch: features.BatchDict, key: jax.Array | None = None
-  ) -> ModelResult:
-    if key is None:
-      key = hk.next_rng_key()
-
-    batch = feat_batch.Batch.from_data_dict(batch)
-
-    embedding_module = evoformer_network.Evoformer(
-        self.config.evoformer, self.global_config
-    )
-    target_feat = create_target_feat_embedding(
-        batch=batch,
-        config=embedding_module.config,
-        global_config=self.global_config,
-    )
-
-    def recycle_body(_, args):
-      prev, key = args
-      key, subkey = jax.random.split(key)
-      embeddings = embedding_module(
-          batch=batch,
-          prev=prev,
-          target_feat=target_feat,
-          key=subkey,
-      )
-      embeddings['pair'] = embeddings['pair'].astype(jnp.float32)
-      embeddings['single'] = embeddings['single'].astype(jnp.float32)
-      return embeddings, key
-
-    num_res = batch.num_res
-
-    embeddings = {
-        'pair': jnp.zeros(
-            [num_res, num_res, self.config.evoformer.pair_channel],
-            dtype=jnp.float32,
-        ),
-        'single': jnp.zeros(
-            [num_res, self.config.evoformer.seq_channel], dtype=jnp.float32
-        ),
-        'target_feat': target_feat,
-    }
-    if hk.running_init():
-      embeddings, _ = recycle_body(None, (embeddings, key))
-    else:
-      # Number of recycles is number of additional forward trunk passes.
-      num_iter = self.config.num_recycles + 1
-      embeddings, _ = hk.fori_loop(0, num_iter, recycle_body, (embeddings, key))
-
-    samples = self._sample_diffusion(
-        batch,
-        embeddings,
-        sample_config=self.config.heads.diffusion.eval,
-    )
-
-    # Compute dist_error_fn over all samples for distance error logging.
-    confidence_output = mapping.sharded_map(
-        lambda dense_atom_positions: confidence_head.ConfidenceHead(
-            self.config.heads.confidence, self.global_config
-        )(
-            dense_atom_positions=dense_atom_positions,
-            embeddings=embeddings,
-            seq_mask=batch.token_features.mask,
-            token_atoms_to_pseudo_beta=batch.pseudo_beta_info.token_atoms_to_pseudo_beta,
-            asym_id=batch.token_features.asym_id,
-        ),
-        in_axes=0,
-    )(samples['atom_positions'])
-
-    distogram = distogram_head.DistogramHead(
-        self.config.heads.distogram, self.global_config
-    )(batch, embeddings)
-
-    output = {
-        'diffusion_samples': samples,
-        'distogram': distogram,
-        **confidence_output,
-    }
-    if self.config.return_embeddings:
-      output['single_embeddings'] = embeddings['single']
-      output['pair_embeddings'] = embeddings['pair']
-    return output
-
-  @classmethod
-  def get_inference_result(
-      cls,
-      batch: features.BatchDict,
-      result: ModelResult,
-      target_name: str = '',
-  ) -> Iterable[InferenceResult]:
-    """Get the predicted structure, scalars, and arrays for inference.
-
-    This function also computes any inference-time quantities, which are not a
-    part of the forward-pass, e.g. additional confidence scores. Note that this
-    function is not serialized, so it should be slim if possible.
-
-    Args:
-      batch: data batch used for model inference, incl. TPU invalid types.
-      result: output dict from the model's forward pass.
-      target_name: target name to be saved within structure.
-
-    Yields:
-      inference_result: dataclass object that contains a predicted structure,
-      important inference-time scalars and arrays, as well as a slightly trimmed
-      dictionary of raw model result from the forward pass (for debugging).
-    """
-    del target_name
-    batch = feat_batch.Batch.from_data_dict(batch)
-
-    # Retrieve structure and construct a predicted structure.
-    pred_structure = get_predicted_structure(result=result, batch=batch)
-
-    num_tokens = batch.token_features.seq_length.item()
-
-    pae_single_mask = np.tile(
-        batch.frames.mask[:, None],
-        [1, batch.frames.mask.shape[0]],
-    )
-    ptm = _compute_ptm(
-        result=result,
-        num_tokens=num_tokens,
-        asym_id=batch.token_features.asym_id[:num_tokens],
-        pae_single_mask=pae_single_mask,
-        interface=False,
-    )
-    iptm = _compute_ptm(
-        result=result,
-        num_tokens=num_tokens,
-        asym_id=batch.token_features.asym_id[:num_tokens],
-        pae_single_mask=pae_single_mask,
-        interface=True,
-    )
-    ptm_iptm_average = 0.8 * iptm + 0.2 * ptm
-
-    asym_ids = batch.token_features.asym_id[:num_tokens]
-    # Map asym IDs back to chain IDs. Asym IDs are constructed from chain IDs by
-    # iterating over the chain IDs, and for each unique chain ID incrementing
-    # the asym ID by 1 and mapping it to the particular chain ID. Asym IDs are
-    # 1-indexed, so subtract 1 to get back to the chain ID.
-    chain_ids = [pred_structure.chains[asym_id - 1] for asym_id in asym_ids]
-    res_ids = batch.token_features.residue_index[:num_tokens]
-
-    if len(np.unique(asym_ids[:num_tokens])) > 1:
-      # There is more than one chain, hence interface pTM (i.e. ipTM) defined,
-      # so use it.
-      ranking_confidence = ptm_iptm_average
-    else:
-      # There is only one chain, hence ipTM=NaN, so use just pTM.
-      ranking_confidence = ptm
-
-    contact_probs = result['distogram']['contact_probs']
-    # Compute PAE related summaries.
-    _, chain_pair_pae_min, _ = confidences.chain_pair_pae(
-        num_tokens=num_tokens,
-        asym_ids=batch.token_features.asym_id,
-        full_pae=result['full_pae'],
-        mask=pae_single_mask,
-    )
-    chain_pair_pde_mean, chain_pair_pde_min = confidences.chain_pair_pde(
-        num_tokens=num_tokens,
-        asym_ids=batch.token_features.asym_id,
-        full_pde=result['full_pde'],
-    )
-    intra_chain_single_pde, cross_chain_single_pde, _ = confidences.pde_single(
-        num_tokens,
-        batch.token_features.asym_id,
-        result['full_pde'],
-        contact_probs,
-    )
-    pae_metrics = confidences.pae_metrics(
-        num_tokens=num_tokens,
-        asym_ids=batch.token_features.asym_id,
-        full_pae=result['full_pae'],
-        mask=pae_single_mask,
-        contact_probs=contact_probs,
-        tm_adjusted_pae=result['tmscore_adjusted_pae_interface'],
-    )
-    ranking_confidence_pae = confidences.rank_metric(
-        result['full_pae'],
-        contact_probs * batch.frames.mask[:, None].astype(float),
-    )
-    chain_pair_iptm = _compute_chain_pair_iptm(
-        num_tokens=num_tokens,
-        asym_ids=batch.token_features.asym_id,
-        mask=pae_single_mask,
-        tm_adjusted_pae=result['tmscore_adjusted_pae_interface'],
-    )
-    # iptm_ichain is a vector of per-chain ptm values. iptm_ichain[0],
-    # for example, is just the zeroth diagonal entry of the chain pair iptm
-    # matrix:
-    # [[x, , ],
-    #  [ , , ],
-    #  [ , , ]]]
-    iptm_ichain = chain_pair_iptm.diagonal(axis1=-2, axis2=-1)
-    # iptm_xchain is a vector of cross-chain interactions for each chain.
-    # iptm_xchain[0], for example, is an average of chain 0's interactions with
-    # other chains:
-    # [[ ,x,x],
-    #  [x, , ],
-    #  [x, , ]]]
-    iptm_xchain = confidences.get_iptm_xchain(chain_pair_iptm)
-
-    predicted_distance_errors = result['average_pde']
-
-    # Computing solvent accessible area with dssp can be slow for large
-    # structures with lots of chains, so we parallelize the call.
-    pred_structures = pred_structure.unstack()
-    num_workers = len(pred_structures)
-    with concurrent.futures.ThreadPoolExecutor(
-        max_workers=num_workers
-    ) as executor:
-      has_clash = list(executor.map(confidences.has_clash, pred_structures))
-      fraction_disordered = list(
-          executor.map(confidences.fraction_disordered, pred_structures)
-      )
-
-    for idx, pred_structure in enumerate(pred_structures):
-      ranking_score = confidences.get_ranking_score(
-          ptm=ptm[idx],
-          iptm=iptm[idx],
-          fraction_disordered_=fraction_disordered[idx],
-          has_clash_=has_clash[idx],
-      )
-      yield InferenceResult(
-          predicted_structure=pred_structure,
-          numerical_data={
-              'full_pde': result['full_pde'][idx, :num_tokens, :num_tokens],
-              'full_pae': result['full_pae'][idx, :num_tokens, :num_tokens],
-              'contact_probs': contact_probs[:num_tokens, :num_tokens],
-          },
-          metadata={
-              'predicted_distance_error': predicted_distance_errors[idx],
-              'ranking_score': ranking_score,
-              'fraction_disordered': fraction_disordered[idx],
-              'has_clash': has_clash[idx],
-              'predicted_tm_score': ptm[idx],
-              'interface_predicted_tm_score': iptm[idx],
-              'chain_pair_pde_mean': chain_pair_pde_mean[idx],
-              'chain_pair_pde_min': chain_pair_pde_min[idx],
-              'chain_pair_pae_min': chain_pair_pae_min[idx],
-              'ptm': ptm[idx],
-              'iptm': iptm[idx],
-              'ptm_iptm_average': ptm_iptm_average[idx],
-              'intra_chain_single_pde': intra_chain_single_pde[idx],
-              'cross_chain_single_pde': cross_chain_single_pde[idx],
-              'pae_ichain': pae_metrics['pae_ichain'][idx],
-              'pae_xchain': pae_metrics['pae_xchain'][idx],
-              'ranking_confidence': ranking_confidence[idx],
-              'ranking_confidence_pae': ranking_confidence_pae[idx],
-              'chain_pair_iptm': chain_pair_iptm[idx],
-              'iptm_ichain': iptm_ichain[idx],
-              'iptm_xchain': iptm_xchain[idx],
-              'token_chain_ids': chain_ids,
-              'token_res_ids': res_ids,
-          },
-          model_id=result['__identifier__'],
-          debug_outputs={},
-      )
diff --git a/src/alphafold3/model/model_config.py b/src/alphafold3/model/model_config.py
deleted file mode 100644
index 2040d8fc842f5e21053010411819516066bca285..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/model_config.py
+++ /dev/null
@@ -1,32 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Global config for the model."""
-
-from collections.abc import Sequence
-from typing import Literal, TypeAlias
-
-from alphafold3.common import base_config
-from alphafold3.jax.attention import attention
-
-
-_Shape2DType: TypeAlias = tuple[int | None, int | None]
-
-
-class GlobalConfig(base_config.BaseConfig):
-  bfloat16: Literal['all', 'none', 'intermediate'] = 'all'
-  final_init: Literal['zeros', 'linear'] = 'zeros'
-  pair_attention_chunk_size: Sequence[_Shape2DType] = ((1536, 128), (None, 32))
-  pair_transition_shard_spec: Sequence[_Shape2DType] = (
-      (2048, None),
-      (None, 1024),
-  )
-  # Note: flash_attention_implementation = 'xla' means no flash attention.
-  flash_attention_implementation: attention.Implementation = 'triton'
diff --git a/src/alphafold3/model/msa_pairing.py b/src/alphafold3/model/msa_pairing.py
deleted file mode 100644
index eaed4799cb8b02219d1957188be25d0ccadb5c34..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/msa_pairing.py
+++ /dev/null
@@ -1,312 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Functions for producing "paired" and "unpaired" MSA features for each chain.
-
-The paired MSA:
-- Is made from the result of the all_seqs MSA query.
-- Is ordered such that you can concatenate features across chains and related
-  sequences will end up on the same row. Related here means "from the same
-  species". Gaps are added to facilitate this whenever a sequence has no
-  suitable pair.
-
-The unpaired MSA:
-- Is made from the results of the remaining MSA queries.
-- Has no special ordering properties.
-- Is deduplicated such that it doesn't contain any sequences in the paired MSA.
-"""
-
-from typing import Mapping, MutableMapping, Sequence
-from alphafold3.model import data_constants
-import numpy as np
-
-
-def _align_species(
-    all_species: Sequence[bytes],
-    chains_species_to_rows: Sequence[Mapping[bytes, np.ndarray]],
-    min_hits_per_species: Mapping[bytes, int],
-) -> np.ndarray:
-  """Aligns MSA row indices based on species.
-
-  Within a species, MSAs are aligned based on their original order (the first
-  sequence for a species in the first chain's MSA is aligned to the first
-  sequence for the same species in the second chain's MSA).
-
-  Args:
-    all_species: A list of all unique species identifiers.
-    chains_species_to_rows: A dictionary for each chain, that maps species to
-      the set of MSA row indices from that species in that chain.
-    min_hits_per_species: A mapping from species id, to the minimum MSA size
-      across chains for that species (ignoring chains with zero hits).
-
-  Returns:
-    A matrix of size [num_msa_rows, num_chains], where the i,j element is an
-    index into the jth chains MSA.  Each row consists of sequences from each
-    chain for the same species (or -1 if that chain has no sequences for that
-    species).
-  """
-  # Each species block is of size [num_seqs x num_chains] and consists of
-  # indices into the respective MSAs that have been aligned and are all for the
-  # same species.
-  species_blocks = []
-  for species in all_species:
-    chain_row_indices = []
-    for species_to_rows in chains_species_to_rows:
-      min_msa_size = min_hits_per_species[species]
-      if species not in species_to_rows:
-        # If a given chain has no hits for a species then we pad it with -1's,
-        # later on these values are used to make sure each feature is padded
-        # with its appropriate pad value.
-        row_indices = np.full(min_msa_size, fill_value=-1, dtype=np.int32)
-      else:
-        # We crop down to the smallest MSA for a given species across chains.
-        row_indices = species_to_rows[species][:min_msa_size]
-      chain_row_indices.append(row_indices)
-    species_block = np.stack(chain_row_indices, axis=1)
-    species_blocks.append(species_block)
-  aligned_matrix = np.concatenate(species_blocks, axis=0)
-  return aligned_matrix
-
-
-def create_paired_features(
-    chains: Sequence[MutableMapping[str, np.ndarray]],
-    max_paired_sequences: int,
-    nonempty_chain_ids: set[str],
-    max_hits_per_species: int,
-) -> Sequence[MutableMapping[str, np.ndarray]]:
-  """Creates per-chain MSA features where the MSAs have been aligned.
-
-  Args:
-    chains: A list of feature dicts, one for each chain.
-    max_paired_sequences: No more than this many paired sequences will be
-      returned from this function.
-    nonempty_chain_ids: A set of chain ids (str) that are included in the crop
-      there is no reason to process chains not in this list.
-    max_hits_per_species: No more than this number of sequences will be returned
-      for a given species.
-
-  Returns:
-    An updated feature dictionary for each chain, where the {}_all_seq features
-    have been aligned so that the nth row in chain 1 is aligned to the nth row
-    in chain 2's features.
-  """
-  # The number of chains that the given species appears in - we rank hits
-  # across more chains higher.
-  species_num_chains = {}
-
-  # For each chain we keep a mapping from species to the row indices in the
-  # original MSA for that chain.
-  chains_species_to_rows = []
-
-  # Keep track of the minimum number of hits across chains for a given species.
-  min_hits_per_species = {}
-
-  for chain in chains:
-    species_ids = chain['msa_species_identifiers_all_seq']
-
-    # The query gets an empty species_id, so no pairing happens for this row.
-    if (
-        species_ids.size == 0
-        or (species_ids.size == 1 and not species_ids[0])
-        or chain['chain_id'] not in nonempty_chain_ids
-    ):
-      chains_species_to_rows.append({})
-      continue
-
-    # For each species keep track of which row indices in the original MSA are
-    # from this species.
-    row_indices = np.arange(len(species_ids))
-    # The grouping np.split code requires that the input is already clustered
-    # by species id.
-    sort_idxs = species_ids.argsort()
-    species_ids = species_ids[sort_idxs]
-    row_indices = row_indices[sort_idxs]
-
-    species, unique_row_indices = np.unique(species_ids, return_index=True)
-    grouped_row_indices = np.split(row_indices, unique_row_indices[1:])
-    species_to_rows = dict(zip(species, grouped_row_indices, strict=True))
-    chains_species_to_rows.append(species_to_rows)
-
-    for s in species:
-      species_num_chains[s] = species_num_chains.get(s, 0) + 1
-
-    for species, row_indices in species_to_rows.items():
-      min_hits_per_species[species] = min(
-          min_hits_per_species.get(species, max_hits_per_species),
-          len(row_indices),
-      )
-
-  # Construct a mapping from the number of chains a species appears in to
-  # the list of species with that count.
-  num_chains_to_species = {}
-  for species, num_chains in species_num_chains.items():
-    if not species or num_chains <= 1:
-      continue
-    if num_chains not in num_chains_to_species:
-      num_chains_to_species[num_chains] = []
-    num_chains_to_species[num_chains].append(species)
-
-  num_rows_seen = 0
-  # We always keep the first row as it is the query sequence.
-  all_rows = [np.array([[0] * len(chains)], dtype=np.int32)]
-
-  # We prioritize species that have hits across more chains.
-  for num_chains in sorted(num_chains_to_species, reverse=True):
-    all_species = num_chains_to_species[num_chains]
-
-    # Align all the per-chain row indices by species, so every paired row is
-    # for a single species.
-    rows = _align_species(
-        all_species, chains_species_to_rows, min_hits_per_species
-    )
-    # Sort rows by the product of the original indices in the respective chain
-    # MSAS, so as to rank hits that appear higher in the original MSAs higher.
-    rank_metric = np.abs(np.prod(rows.astype(np.float32), axis=1))
-    sorted_rows = rows[np.argsort(rank_metric), :]
-    all_rows.append(sorted_rows)
-    num_rows_seen += rows.shape[0]
-    if num_rows_seen >= max_paired_sequences:
-      break
-
-  all_rows = np.concatenate(all_rows, axis=0)
-  all_rows = all_rows[:max_paired_sequences, :]
-
-  # Now we just have to select the relevant rows from the original msa and
-  # deletion matrix features
-  paired_chains = []
-  for chain_idx, chain in enumerate(chains):
-    out_chain = {k: v for k, v in chain.items() if 'all_seq' not in k}
-    selected_row_indices = all_rows[:, chain_idx]
-    for feat_name in {'msa', 'deletion_matrix'}:
-      all_seq_name = f'{feat_name}_all_seq'
-      feat_value = chain[all_seq_name]
-
-      # The selected row indices are padded to be the same shape for each chain,
-      # they are padded with -1's, so we add a single row onto the feature with
-      # the appropriate pad value.  This has the effect that we correctly pad
-      # each feature since all padded indices will select this padding row.
-      pad_value = data_constants.MSA_PAD_VALUES[feat_name]
-      feat_value = np.concatenate([
-          feat_value,
-          np.full((1, feat_value.shape[1]), pad_value, feat_value.dtype),
-      ])
-
-      feat_value = feat_value[selected_row_indices, :]
-      out_chain[all_seq_name] = feat_value
-    out_chain['num_alignments_all_seq'] = np.array(
-        out_chain['msa_all_seq'].shape[0]
-    )
-    paired_chains.append(out_chain)
-  return paired_chains
-
-
-def deduplicate_unpaired_sequences(
-    np_chains: Sequence[MutableMapping[str, np.ndarray]],
-) -> Sequence[MutableMapping[str, np.ndarray]]:
-  """Deduplicates unpaired sequences based on paired sequences."""
-
-  feature_names = np_chains[0].keys()
-  msa_features = (
-      data_constants.NUM_SEQ_MSA_FEATURES
-      + data_constants.NUM_SEQ_NUM_RES_MSA_FEATURES
-  )
-
-  for chain in np_chains:
-    sequence_set = set(
-        hash(s.data.tobytes()) for s in chain['msa_all_seq'].astype(np.int8)
-    )
-    keep_rows = []
-    # Go through unpaired MSA seqs and remove any rows that correspond to the
-    # sequences that are already present in the paired MSA.
-    for row_num, seq in enumerate(chain['msa'].astype(np.int8)):
-      if hash(seq.data.tobytes()) not in sequence_set:
-        keep_rows.append(row_num)
-    for feature_name in feature_names:
-      if feature_name in msa_features:
-        chain[feature_name] = chain[feature_name][keep_rows]
-    chain['num_alignments'] = np.array(chain['msa'].shape[0], dtype=np.int32)
-  return np_chains
-
-
-def choose_paired_unpaired_msa_crop_sizes(
-    unpaired_msa: np.ndarray,
-    paired_msa: np.ndarray | None,
-    total_msa_crop_size: int,
-    max_paired_sequences: int,
-) -> tuple[int, int | None]:
-  """Returns the sizes of the MSA crop and MSA_all_seq crop.
-
-  NOTE: Unpaired + paired MSA sizes can exceed total_msa_size when
-    there are lots of gapped rows. Through the pairing logic another chain(s)
-    will have fewer than total_msa_size.
-
-  Args:
-     unpaired_msa: The unpaired MSA array (not all_seq).
-     paired_msa: The paired MSA array (all_seq).
-     total_msa_crop_size: The maximum total number of sequences to crop to.
-     max_paired_sequences: The maximum number of sequences that can come from
-       MSA pairing.
-
-  Returns:
-    A tuple of:
-      The size of the reduced MSA crop (not all_seq features).
-      The size of the unreduced MSA crop (for all_seq features) or None, if
-        paired_msa is None.
-  """
-  if paired_msa is not None:
-    paired_crop_size = np.minimum(paired_msa.shape[0], max_paired_sequences)
-
-    # We reduce the number of un-paired sequences, by the number of times a
-    # sequence from this chains MSA is included in the paired MSA.  This keeps
-    # the MSA size for each chain roughly constant.
-    cropped_all_seq_msa = paired_msa[:max_paired_sequences]
-    num_non_gapped_pairs = cropped_all_seq_msa.shape[0]
-
-    assert num_non_gapped_pairs <= max_paired_sequences
-    unpaired_crop_size = np.minimum(
-        unpaired_msa.shape[0], total_msa_crop_size - num_non_gapped_pairs
-    )
-    assert unpaired_crop_size >= 0
-  else:
-    unpaired_crop_size = np.minimum(unpaired_msa.shape[0], total_msa_crop_size)
-    paired_crop_size = None
-  return unpaired_crop_size, paired_crop_size
-
-
-def remove_all_gapped_rows_from_all_seqs(
-    chains_list: Sequence[dict[str, np.ndarray]], asym_ids: Sequence[float]
-) -> Sequence[dict[str, np.ndarray]]:
-  """Removes all gapped rows from all_seq feat based on selected asym_ids."""
-
-  merged_msa_all_seq = np.concatenate(
-      [
-          chain['msa_all_seq']
-          for chain in chains_list
-          if chain['asym_id'][0] in asym_ids
-      ],
-      axis=1,
-  )
-
-  non_gapped_keep_rows = np.any(
-      merged_msa_all_seq != data_constants.MSA_GAP_IDX, axis=1
-  )
-  for chain in chains_list:
-    for feat_name in list(chains_list)[0]:
-      if '_all_seq' in feat_name:
-        feat_name_split = feat_name.split('_all_seq')[0]
-        if feat_name_split in (
-            data_constants.NUM_SEQ_NUM_RES_MSA_FEATURES
-            + data_constants.NUM_SEQ_MSA_FEATURES
-        ):
-          # For consistency we do this for all chains even though the
-          # gapped rows are based on a selected set asym_ids.
-          chain[feat_name] = chain[feat_name][non_gapped_keep_rows]
-    chain['num_alignments_all_seq'] = np.sum(non_gapped_keep_rows)
-  return chains_list
diff --git a/src/alphafold3/model/network/atom_cross_attention.py b/src/alphafold3/model/network/atom_cross_attention.py
deleted file mode 100644
index 4ff3030375064e75814f731349477cae2c815492..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/atom_cross_attention.py
+++ /dev/null
@@ -1,413 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Per-atom cross attention."""
-
-from alphafold3.common import base_config
-from alphafold3.model import feat_batch
-from alphafold3.model import model_config
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import utils
-from alphafold3.model.network import diffusion_transformer
-import chex
-import jax
-import jax.numpy as jnp
-
-
-class AtomCrossAttEncoderConfig(base_config.BaseConfig):
-  per_token_channels: int = 768
-  per_atom_channels: int = 128
-  atom_transformer: diffusion_transformer.CrossAttTransformer.Config = (
-      base_config.autocreate(num_intermediate_factor=2, num_blocks=3)
-  )
-  per_atom_pair_channels: int = 16
-
-
-def _per_atom_conditioning(
-    config: AtomCrossAttEncoderConfig, batch: feat_batch.Batch, name: str
-) -> tuple[jnp.ndarray, jnp.ndarray]:
-  """computes single and pair conditioning for all atoms in each token."""
-
-  c = config
-  # Compute per-atom single conditioning
-  # Shape (num_tokens, num_dense, channels)
-  act = hm.Linear(
-      c.per_atom_channels, precision='highest', name=f'{name}_embed_ref_pos'
-  )(batch.ref_structure.positions)
-  act += hm.Linear(c.per_atom_channels, name=f'{name}_embed_ref_mask')(
-      batch.ref_structure.mask.astype(jnp.float32)[:, :, None]
-  )
-  # Element is encoded as atomic number if the periodic table, so
-  # 128 should be fine.
-  act += hm.Linear(c.per_atom_channels, name=f'{name}_embed_ref_element')(
-      jax.nn.one_hot(batch.ref_structure.element, 128)
-  )
-  act += hm.Linear(c.per_atom_channels, name=f'{name}_embed_ref_charge')(
-      jnp.arcsinh(batch.ref_structure.charge)[:, :, None]
-  )
-  # Characters are encoded as ASCII code minus 32, so we need 64 classes,
-  # to encode all standard ASCII characters between 32 and 96.
-  atom_name_chars_1hot = jax.nn.one_hot(batch.ref_structure.atom_name_chars, 64)
-  num_token, num_dense, _ = act.shape
-  act += hm.Linear(c.per_atom_channels, name=f'{name}_embed_ref_atom_name')(
-      atom_name_chars_1hot.reshape(num_token, num_dense, -1)
-  )
-  act *= batch.ref_structure.mask.astype(jnp.float32)[:, :, None]
-
-  # Compute pair conditioning
-  # shape (num_tokens, num_dense, num_dense, channels)
-  # Embed single features
-  row_act = hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_single_to_pair_cond_row'
-  )(jax.nn.relu(act))
-  col_act = hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_single_to_pair_cond_col'
-  )(jax.nn.relu(act))
-  pair_act = row_act[:, :, None, :] + col_act[:, None, :, :]
-  # Embed pairwise offsets
-  pair_act += hm.Linear(
-      c.per_atom_pair_channels,
-      precision='highest',
-      name=f'{name}_embed_pair_offsets',
-  )(
-      batch.ref_structure.positions[:, :, None, :]
-      - batch.ref_structure.positions[:, None, :, :]
-  )
-  # Embed pairwise inverse squared distances
-  sq_dists = jnp.sum(
-      jnp.square(
-          batch.ref_structure.positions[:, :, None, :]
-          - batch.ref_structure.positions[:, None, :, :]
-      ),
-      axis=-1,
-  )
-  pair_act += hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_embed_pair_distances'
-  )(1.0 / (1 + sq_dists[:, :, :, None]))
-
-  return act, pair_act
-
-
-@chex.dataclass(mappable_dataclass=False, frozen=True)
-class AtomCrossAttEncoderOutput:
-  token_act: jnp.ndarray  # (num_tokens, ch)
-  skip_connection: jnp.ndarray  # (num_subsets, num_queries, ch)
-  queries_mask: jnp.ndarray  # (num_subsets, num_queries)
-  queries_single_cond: jnp.ndarray  # (num_subsets, num_queries, ch)
-  keys_mask: jnp.ndarray  # (num_subsets, num_keys)
-  keys_single_cond: jnp.ndarray  # (num_subsets, num_keys, ch)
-  pair_cond: jnp.ndarray  # (num_subsets, num_queries, num_keys, ch)
-
-
-def atom_cross_att_encoder(
-    token_atoms_act: jnp.ndarray | None,  # (num_tokens, max_atoms_per_token, 3)
-    trunk_single_cond: jnp.ndarray | None,  # (num_tokens, ch)
-    trunk_pair_cond: jnp.ndarray | None,  # (num_tokens, num_tokens, ch)
-    config: AtomCrossAttEncoderConfig,
-    global_config: model_config.GlobalConfig,
-    batch: feat_batch.Batch,
-    name: str,
-) -> AtomCrossAttEncoderOutput:
-  """Cross-attention on flat atom subsets and mapping to per-token features."""
-  c = config
-
-  # Compute single conditioning from atom meta data and convert to queries
-  # layout.
-  # (num_subsets, num_queries, channels)
-  token_atoms_single_cond, _ = _per_atom_conditioning(config, batch, name)
-  token_atoms_mask = batch.predicted_structure_info.atom_mask
-  queries_single_cond = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      token_atoms_single_cond,
-      layout_axes=(-3, -2),
-  )
-  queries_mask = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      token_atoms_mask,
-      layout_axes=(-2, -1),
-  )
-
-  # If provided, broadcast single conditioning from trunk to all queries
-  if trunk_single_cond is not None:
-    trunk_single_cond = hm.Linear(
-        c.per_atom_channels,
-        precision='highest',
-        initializer=global_config.final_init,
-        name=f'{name}_embed_trunk_single_cond',
-    )(
-        hm.LayerNorm(
-            use_fast_variance=False,
-            create_offset=False,
-            name=f'{name}_lnorm_trunk_single_cond',
-        )(trunk_single_cond)
-    )
-    queries_single_cond += atom_layout.convert(
-        batch.atom_cross_att.tokens_to_queries,
-        trunk_single_cond,
-        layout_axes=(-2,),
-    )
-
-  if token_atoms_act is None:
-    # if no token_atoms_act is given (e.g. begin of evoformer), we use the
-    # static conditioning only
-    queries_act = queries_single_cond
-  else:
-    # Convert token_atoms_act to queries layout and map to per_atom_channels
-    # (num_subsets, num_queries, channels)
-    queries_act = atom_layout.convert(
-        batch.atom_cross_att.token_atoms_to_queries,
-        token_atoms_act,
-        layout_axes=(-3, -2),
-    )
-    queries_act = hm.Linear(
-        c.per_atom_channels,
-        precision='highest',
-        name=f'{name}_atom_positions_to_features',
-    )(queries_act)
-    queries_act *= queries_mask[..., None]
-    queries_act += queries_single_cond
-
-  # Gather the keys from the queries.
-  keys_single_cond = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys,
-      queries_single_cond,
-      layout_axes=(-3, -2),
-  )
-  keys_mask = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys, queries_mask, layout_axes=(-2, -1)
-  )
-
-  # Embed single features into the pair conditioning.
-  # shape (num_subsets, num_queries, num_keys, ch)
-  row_act = hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_single_to_pair_cond_row'
-  )(jax.nn.relu(queries_single_cond))
-  pair_cond_keys_input = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys,
-      queries_single_cond,
-      layout_axes=(-3, -2),
-  )
-  col_act = hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_single_to_pair_cond_col'
-  )(jax.nn.relu(pair_cond_keys_input))
-  pair_act = row_act[:, :, None, :] + col_act[:, None, :, :]
-
-  if trunk_pair_cond is not None:
-    # If provided, broadcast the pair conditioning for the trunk (evoformer
-    # pairs) to the atom pair activations. This should boost ligands, but also
-    # help for cross attention within proteins, because we always have atoms
-    # from multiple residues in a subset.
-    # Map trunk pair conditioning to per_atom_pair_channels
-    # (num_tokens, num_tokens, per_atom_pair_channels)
-    trunk_pair_cond = hm.Linear(
-        c.per_atom_pair_channels,
-        precision='highest',
-        initializer=global_config.final_init,
-        name=f'{name}_embed_trunk_pair_cond',
-    )(
-        hm.LayerNorm(
-            use_fast_variance=False,
-            create_offset=False,
-            name=f'{name}_lnorm_trunk_pair_cond',
-        )(trunk_pair_cond)
-    )
-
-    # Create the GatherInfo into a flattened trunk_pair_cond from the
-    # queries and keys gather infos.
-    num_tokens = trunk_pair_cond.shape[0]
-    # (num_subsets, num_queries)
-    tokens_to_queries = batch.atom_cross_att.tokens_to_queries
-    # (num_subsets, num_keys)
-    tokens_to_keys = batch.atom_cross_att.tokens_to_keys
-    # (num_subsets, num_queries, num_keys)
-    trunk_pair_to_atom_pair = atom_layout.GatherInfo(
-        gather_idxs=(
-            num_tokens * tokens_to_queries.gather_idxs[:, :, None]
-            + tokens_to_keys.gather_idxs[:, None, :]
-        ),
-        gather_mask=(
-            tokens_to_queries.gather_mask[:, :, None]
-            & tokens_to_keys.gather_mask[:, None, :]
-        ),
-        input_shape=jnp.array((num_tokens, num_tokens)),
-    )
-    # Gather the conditioning and add it to the atom-pair activations.
-    pair_act += atom_layout.convert(
-        trunk_pair_to_atom_pair, trunk_pair_cond, layout_axes=(-3, -2)
-    )
-
-  # Embed pairwise offsets
-  queries_ref_pos = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      batch.ref_structure.positions,
-      layout_axes=(-3, -2),
-  )
-  queries_ref_space_uid = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      batch.ref_structure.ref_space_uid,
-      layout_axes=(-2, -1),
-  )
-  keys_ref_pos = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys,
-      queries_ref_pos,
-      layout_axes=(-3, -2),
-  )
-  keys_ref_space_uid = atom_layout.convert(
-      batch.atom_cross_att.queries_to_keys,
-      batch.ref_structure.ref_space_uid,
-      layout_axes=(-2, -1),
-  )
-
-  offsets_valid = (
-      queries_ref_space_uid[:, :, None] == keys_ref_space_uid[:, None, :]
-  )
-  offsets = queries_ref_pos[:, :, None, :] - keys_ref_pos[:, None, :, :]
-  pair_act += (
-      hm.Linear(
-          c.per_atom_pair_channels,
-          precision='highest',
-          name=f'{name}_embed_pair_offsets',
-      )(offsets)
-      * offsets_valid[:, :, :, None]
-  )
-
-  # Embed pairwise inverse squared distances
-  sq_dists = jnp.sum(jnp.square(offsets), axis=-1)
-  pair_act += (
-      hm.Linear(c.per_atom_pair_channels, name=f'{name}_embed_pair_distances')(
-          1.0 / (1 + sq_dists[:, :, :, None])
-      )
-      * offsets_valid[:, :, :, None]
-  )
-  # Embed offsets valid mask
-  pair_act += hm.Linear(
-      c.per_atom_pair_channels, name=f'{name}_embed_pair_offsets_valid'
-  )(offsets_valid[:, :, :, None].astype(jnp.float32))
-
-  # Run a small MLP on the pair acitvations
-  pair_act2 = hm.Linear(
-      c.per_atom_pair_channels, initializer='relu', name=f'{name}_pair_mlp_1'
-  )(jax.nn.relu(pair_act))
-  pair_act2 = hm.Linear(
-      c.per_atom_pair_channels, initializer='relu', name=f'{name}_pair_mlp_2'
-  )(jax.nn.relu(pair_act2))
-  pair_act += hm.Linear(
-      c.per_atom_pair_channels,
-      initializer=global_config.final_init,
-      name=f'{name}_pair_mlp_3',
-  )(jax.nn.relu(pair_act2))
-
-  # Run the atom cross attention transformer.
-  queries_act = diffusion_transformer.CrossAttTransformer(
-      c.atom_transformer, global_config, name=f'{name}_atom_transformer_encoder'
-  )(
-      queries_act=queries_act,
-      queries_mask=queries_mask,
-      queries_to_keys=batch.atom_cross_att.queries_to_keys,
-      keys_mask=keys_mask,
-      queries_single_cond=queries_single_cond,
-      keys_single_cond=keys_single_cond,
-      pair_cond=pair_act,
-  )
-  queries_act *= queries_mask[..., None]
-  skip_connection = queries_act
-
-  # Convert back to token-atom layout and aggregate to tokens
-  queries_act = hm.Linear(
-      c.per_token_channels, name=f'{name}_project_atom_features_for_aggr'
-  )(queries_act)
-  token_atoms_act = atom_layout.convert(
-      batch.atom_cross_att.queries_to_token_atoms,
-      queries_act,
-      layout_axes=(-3, -2),
-  )
-  token_act = utils.mask_mean(
-      token_atoms_mask[..., None], jax.nn.relu(token_atoms_act), axis=-2
-  )
-
-  return AtomCrossAttEncoderOutput(
-      token_act=token_act,
-      skip_connection=skip_connection,
-      queries_mask=queries_mask,
-      queries_single_cond=queries_single_cond,
-      keys_mask=keys_mask,
-      keys_single_cond=keys_single_cond,
-      pair_cond=pair_act,
-  )
-
-
-class AtomCrossAttDecoderConfig(base_config.BaseConfig):
-  per_atom_channels: int = 128
-  atom_transformer: diffusion_transformer.CrossAttTransformer.Config = (
-      base_config.autocreate(num_intermediate_factor=2, num_blocks=3)
-  )
-
-
-def atom_cross_att_decoder(
-    token_act: jnp.ndarray,  # (num_tokens, ch)
-    enc: AtomCrossAttEncoderOutput,
-    config: AtomCrossAttDecoderConfig,
-    global_config: model_config.GlobalConfig,
-    batch: feat_batch.Batch,
-    name: str,
-):  # (num_tokens, max_atoms_per_token, 3)
-  """Mapping to per-atom features and self-attention on subsets."""
-  c = config
-  # map per-token act down to per_atom channels
-  token_act = hm.Linear(
-      c.per_atom_channels, name=f'{name}_project_token_features_for_broadcast'
-  )(token_act)
-  # Broadcast to token-atoms layout and convert to queries layout.
-  num_token, max_atoms_per_token = (
-      batch.atom_cross_att.queries_to_token_atoms.shape
-  )
-  token_atom_act = jnp.broadcast_to(
-      token_act[:, None, :],
-      (num_token, max_atoms_per_token, c.per_atom_channels),
-  )
-  queries_act = atom_layout.convert(
-      batch.atom_cross_att.token_atoms_to_queries,
-      token_atom_act,
-      layout_axes=(-3, -2),
-  )
-  queries_act += enc.skip_connection
-  queries_act *= enc.queries_mask[..., None]
-
-  # Run the atom cross attention transformer.
-  queries_act = diffusion_transformer.CrossAttTransformer(
-      c.atom_transformer, global_config, name=f'{name}_atom_transformer_decoder'
-  )(
-      queries_act=queries_act,
-      queries_mask=enc.queries_mask,
-      queries_to_keys=batch.atom_cross_att.queries_to_keys,
-      keys_mask=enc.keys_mask,
-      queries_single_cond=enc.queries_single_cond,
-      keys_single_cond=enc.keys_single_cond,
-      pair_cond=enc.pair_cond,
-  )
-  queries_act *= enc.queries_mask[..., None]
-  queries_act = hm.LayerNorm(
-      use_fast_variance=False,
-      create_offset=False,
-      name=f'{name}_atom_features_layer_norm',
-  )(queries_act)
-  queries_position_update = hm.Linear(
-      3,
-      initializer=global_config.final_init,
-      precision='highest',
-      name=f'{name}_atom_features_to_position_update',
-  )(queries_act)
-  position_update = atom_layout.convert(
-      batch.atom_cross_att.queries_to_token_atoms,
-      queries_position_update,
-      layout_axes=(-3, -2),
-  )
-  return position_update
diff --git a/src/alphafold3/model/network/confidence_head.py b/src/alphafold3/model/network/confidence_head.py
deleted file mode 100644
index 35fc86ccc16d89d143373f60e275732fff45ea43..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/confidence_head.py
+++ /dev/null
@@ -1,320 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Confidence Head."""
-
-from alphafold3.common import base_config
-from alphafold3.model import model_config
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import utils
-from alphafold3.model.network import modules
-from alphafold3.model.network import template_modules
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-def _safe_norm(x, keepdims, axis, eps=1e-8):
-  return jnp.sqrt(eps + jnp.sum(jnp.square(x), axis=axis, keepdims=keepdims))
-
-
-class ConfidenceHead(hk.Module):
-  """Head to predict the distance errors in a prediction."""
-
-  class PAEConfig(base_config.BaseConfig):
-    max_error_bin: float = 31.0
-    num_bins: int = 64
-
-  class Config(base_config.BaseConfig):
-    """Configuration for ConfidenceHead."""
-
-    pairformer: modules.PairFormerIteration.Config = base_config.autocreate(
-        single_attention=base_config.autocreate(),
-        single_transition=base_config.autocreate(),
-        num_layer=4,
-    )
-    max_error_bin: float = 31.0
-    num_plddt_bins: int = 50
-    num_bins: int = 64
-    no_embedding_prob: float = 0.2
-    pae: 'ConfidenceHead.PAEConfig' = base_config.autocreate()
-    dgram_features: template_modules.DistogramFeaturesConfig = (
-        base_config.autocreate()
-    )
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='confidence_head',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def _embed_features(
-      self,
-      dense_atom_positions,
-      token_atoms_to_pseudo_beta,
-      pair_mask,
-      pair_act,
-      target_feat,
-  ):
-    out = hm.Linear(pair_act.shape[-1], name='left_target_feat_project')(
-        target_feat
-    ).astype(pair_act.dtype)
-    out += hm.Linear(pair_act.shape[-1], name='right_target_feat_project')(
-        target_feat
-    ).astype(pair_act.dtype)[:, None]
-    positions = atom_layout.convert(
-        token_atoms_to_pseudo_beta,
-        dense_atom_positions,
-        layout_axes=(-3, -2),
-    )
-    dgram = template_modules.dgram_from_positions(
-        positions, self.config.dgram_features
-    )
-    dgram *= pair_mask[..., None]
-
-    out += hm.Linear(pair_act.shape[-1], name='distogram_feat_project')(
-        dgram.astype(pair_act.dtype)
-    )
-    return out
-
-  def __call__(
-      self,
-      dense_atom_positions: jnp.ndarray,
-      embeddings: dict[str, jnp.ndarray],
-      seq_mask: jnp.ndarray,
-      token_atoms_to_pseudo_beta: atom_layout.GatherInfo,
-      asym_id: jnp.ndarray,
-  ) -> dict[str, jnp.ndarray]:
-    """Builds ConfidenceHead module.
-
-    Arguments:
-      dense_atom_positions: [N_res, N_atom, 3] array of positions.
-      embeddings: Dictionary of representations.
-      seq_mask: Sequence mask.
-      token_atoms_to_pseudo_beta: Pseudo beta info for atom tokens.
-      asym_id: Asym ID token features.
-
-    Returns:
-      Dictionary of results.
-    """
-    dtype = (
-        jnp.bfloat16 if self.global_config.bfloat16 == 'all' else jnp.float32
-    )
-    with utils.bfloat16_context():
-      seq_mask_cast = seq_mask.astype(dtype)
-      pair_mask = seq_mask_cast[:, None] * seq_mask_cast[None, :]
-      pair_mask = pair_mask.astype(dtype)
-
-      pair_act = embeddings['pair'].astype(dtype)
-      single_act = embeddings['single'].astype(dtype)
-      target_feat = embeddings['target_feat'].astype(dtype)
-
-      num_residues = seq_mask.shape[0]
-      num_pair_channels = pair_act.shape[2]
-
-      pair_act += self._embed_features(
-          dense_atom_positions,
-          token_atoms_to_pseudo_beta,
-          pair_mask,
-          pair_act,
-          target_feat,
-      )
-
-      def pairformer_fn(act):
-        pair_act, single_act = act
-        return modules.PairFormerIteration(
-            self.config.pairformer,
-            self.global_config,
-            with_single=True,
-            name='confidence_pairformer',
-        )(
-            act=pair_act,
-            single_act=single_act,
-            pair_mask=pair_mask,
-            seq_mask=seq_mask,
-        )
-
-      pairformer_stack = hk.experimental.layer_stack(
-          self.config.pairformer.num_layer
-      )(pairformer_fn)
-
-      pair_act, single_act = pairformer_stack((pair_act, single_act))
-      pair_act = pair_act.astype(jnp.float32)
-      assert pair_act.shape == (num_residues, num_residues, num_pair_channels)
-
-      # Produce logits to predict a distogram of pairwise distance errors
-      # between the input prediction and the ground truth.
-
-      # Shape (num_res, num_res, num_bins)
-      left_distance_logits = hm.Linear(
-          self.config.num_bins,
-          initializer=self.global_config.final_init,
-          name='left_half_distance_logits',
-      )(hm.LayerNorm(name='logits_ln')(pair_act))
-      right_distance_logits = left_distance_logits
-      distance_logits = left_distance_logits + jnp.swapaxes(  # Symmetrize.
-          right_distance_logits, -2, -3
-      )
-      # Shape (num_bins,)
-      distance_breaks = jnp.linspace(
-          0.0, self.config.max_error_bin, self.config.num_bins - 1
-      )
-
-      step = distance_breaks[1] - distance_breaks[0]
-
-      # Add half-step to get the center
-      bin_centers = distance_breaks + step / 2
-      # Add a catch-all bin at the end.
-      bin_centers = jnp.concatenate(
-          [bin_centers, bin_centers[-1:] + step], axis=0
-      )
-
-      distance_probs = jax.nn.softmax(distance_logits, axis=-1)
-
-      pred_distance_error = (
-          jnp.sum(distance_probs * bin_centers, axis=-1) * pair_mask
-      )
-      average_pred_distance_error = jnp.sum(
-          pred_distance_error, axis=[-2, -1]
-      ) / jnp.sum(pair_mask, axis=[-2, -1])
-
-      # Predicted aligned error
-      pae_outputs = {}
-      # Shape (num_res, num_res, num_bins)
-      pae_logits = hm.Linear(
-          self.config.pae.num_bins,
-          initializer=self.global_config.final_init,
-          name='pae_logits',
-      )(hm.LayerNorm(name='pae_logits_ln')(pair_act))
-      # Shape (num_bins,)
-      pae_breaks = jnp.linspace(
-          0.0, self.config.pae.max_error_bin, self.config.pae.num_bins - 1
-      )
-      step = pae_breaks[1] - pae_breaks[0]
-      # Add half-step to get the center
-      bin_centers = pae_breaks + step / 2
-      # Add a catch-all bin at the end.
-      bin_centers = jnp.concatenate(
-          [bin_centers, bin_centers[-1:] + step], axis=0
-      )
-      pae_probs = jax.nn.softmax(pae_logits, axis=-1)
-
-      seq_mask_bool = seq_mask.astype(bool)
-      pair_mask_bool = seq_mask_bool[:, None] * seq_mask_bool[None, :]
-      pae = jnp.sum(pae_probs * bin_centers, axis=-1) * pair_mask_bool
-      pae_outputs.update({
-          'full_pae': pae,
-      })
-
-    # The pTM is computed outside of bfloat16 context.
-    tmscore_adjusted_pae_global, tmscore_adjusted_pae_interface = (
-        self._get_tmscore_adjusted_pae(
-            asym_id=asym_id,
-            seq_mask=seq_mask,
-            pair_mask=pair_mask_bool,
-            bin_centers=bin_centers,
-            pae_probs=pae_probs,
-        )
-    )
-    pae_outputs.update({
-        'tmscore_adjusted_pae_global': tmscore_adjusted_pae_global,
-        'tmscore_adjusted_pae_interface': tmscore_adjusted_pae_interface,
-    })
-    single_act = single_act.astype('float32')
-
-    # pLDDT
-    # Shape (num_res, num_atom, num_bins)
-    plddt_logits = hm.Linear(
-        (dense_atom_positions.shape[-2], self.config.num_plddt_bins),
-        initializer=self.global_config.final_init,
-        name='plddt_logits',
-    )(hm.LayerNorm(name='plddt_logits_ln')(single_act))
-
-    bin_width = 1.0 / self.config.num_plddt_bins
-    bin_centers = jnp.arange(0.5 * bin_width, 1.0, bin_width)
-    predicted_lddt = jnp.sum(
-        jax.nn.softmax(plddt_logits, axis=-1) * bin_centers, axis=-1
-    )
-    predicted_lddt = predicted_lddt * 100.0
-
-    # Experimentally resolved
-    # Shape (num_res, num_atom, 2)
-    experimentally_resolved_logits = hm.Linear(
-        (dense_atom_positions.shape[-2], 2),
-        initializer=self.global_config.final_init,
-        name='experimentally_resolved_logits',
-    )(hm.LayerNorm(name='experimentally_resolved_ln')(single_act))
-
-    predicted_experimentally_resolved = jax.nn.softmax(
-        experimentally_resolved_logits, axis=-1
-    )[..., 1]
-
-    return {
-        'predicted_lddt': predicted_lddt,
-        'predicted_experimentally_resolved': predicted_experimentally_resolved,
-        'full_pde': pred_distance_error,
-        'average_pde': average_pred_distance_error,
-        **pae_outputs,
-    }
-
-  def _get_tmscore_adjusted_pae(
-      self,
-      asym_id: jnp.ndarray,
-      seq_mask: jnp.ndarray,
-      pair_mask: jnp.ndarray,
-      bin_centers: jnp.ndarray,
-      pae_probs: jnp.ndarray,
-  ):
-    def get_tmscore_adjusted_pae(num_interface_tokens, bin_centers, pae_probs):
-      # Clip to avoid negative/undefined d0.
-      clipped_num_res = jnp.maximum(num_interface_tokens, 19)
-
-      # Compute d_0(num_res) as defined by TM-score, eqn. (5) in
-      # http://zhanglab.ccmb.med.umich.edu/papers/2004_3.pdf
-      # Yang & Skolnick "Scoring function for automated
-      # assessment of protein structure template quality" 2004.
-      d0 = 1.24 * (clipped_num_res - 15) ** (1.0 / 3) - 1.8
-
-      # Make compatible with [num_tokens, num_tokens, num_bins]
-      d0 = d0[:, :, None]
-      bin_centers = bin_centers[None, None, :]
-
-      # TM-Score term for every bin.
-      tm_per_bin = 1.0 / (1 + jnp.square(bin_centers) / jnp.square(d0))
-      # E_distances tm(distance).
-      predicted_tm_term = jnp.sum(pae_probs * tm_per_bin, axis=-1)
-      return predicted_tm_term
-
-    # Interface version
-    x = asym_id[None, :] == asym_id[:, None]
-    num_chain_tokens = jnp.sum(x * pair_mask, axis=-1)
-    num_interface_tokens = num_chain_tokens[None, :] + num_chain_tokens[:, None]
-    # Don't double-count within a single chain
-    num_interface_tokens -= x * (num_interface_tokens // 2)
-    num_interface_tokens = num_interface_tokens * pair_mask
-
-    num_global_tokens = jnp.full(
-        shape=pair_mask.shape, fill_value=seq_mask.sum()
-    )
-
-    assert num_global_tokens.dtype == 'int32'
-    assert num_interface_tokens.dtype == 'int32'
-    global_apae = get_tmscore_adjusted_pae(
-        num_global_tokens, bin_centers, pae_probs
-    )
-    interface_apae = get_tmscore_adjusted_pae(
-        num_interface_tokens, bin_centers, pae_probs
-    )
-    return global_apae, interface_apae
diff --git a/src/alphafold3/model/network/diffusion_head.py b/src/alphafold3/model/network/diffusion_head.py
deleted file mode 100644
index 4ca8190b5a6bb31b64bb7c9f3360f95b087e4d42..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/diffusion_head.py
+++ /dev/null
@@ -1,369 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Diffusion Head."""
-
-from collections.abc import Callable
-
-from alphafold3.common import base_config
-from alphafold3.model import feat_batch
-from alphafold3.model import model_config
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import utils
-from alphafold3.model.network import atom_cross_attention
-from alphafold3.model.network import diffusion_transformer
-from alphafold3.model.network import featurization
-from alphafold3.model.network import noise_level_embeddings
-import chex
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-# Carefully measured by averaging multimer training set.
-SIGMA_DATA = 16.0
-
-
-def random_rotation(key):
-  # Create a random rotation (Gram-Schmidt orthogonalization of two
-  # random normal vectors)
-  v0, v1 = jax.random.normal(key, shape=(2, 3))
-  e0 = v0 / jnp.maximum(1e-10, jnp.linalg.norm(v0))
-  v1 = v1 - e0 * jnp.dot(v1, e0, precision=jax.lax.Precision.HIGHEST)
-  e1 = v1 / jnp.maximum(1e-10, jnp.linalg.norm(v1))
-  e2 = jnp.cross(e0, e1)
-  return jnp.stack([e0, e1, e2])
-
-
-def random_augmentation(
-    rng_key: jnp.ndarray,
-    positions: jnp.ndarray,
-    mask: jnp.ndarray,
-) -> jnp.ndarray:
-  """Apply random rigid augmentation.
-
-  Args:
-    rng_key: random key
-    positions: atom positions of shape (<common_axes>, 3)
-    mask: per-atom mask of shape (<common_axes>,)
-
-  Returns:
-    Transformed positions with the same shape as input positions.
-  """
-  rotation_key, translation_key = jax.random.split(rng_key)
-
-  center = utils.mask_mean(
-      mask[..., None], positions, axis=(-2, -3), keepdims=True, eps=1e-6
-  )
-  rot = random_rotation(rotation_key)
-  translation = jax.random.normal(translation_key, shape=(3,))
-
-  augmented_positions = (
-      jnp.einsum(
-          '...i,ij->...j',
-          positions - center,
-          rot,
-          precision=jax.lax.Precision.HIGHEST,
-      )
-      + translation
-  )
-  return augmented_positions * mask[..., None]
-
-
-def noise_schedule(t, smin=0.0004, smax=160.0, p=7):
-  return (
-      SIGMA_DATA
-      * (smax ** (1 / p) + t * (smin ** (1 / p) - smax ** (1 / p))) ** p
-  )
-
-
-class ConditioningConfig(base_config.BaseConfig):
-  pair_channel: int
-  seq_channel: int
-  prob: float
-
-
-class SampleConfig(base_config.BaseConfig):
-  steps: int
-  gamma_0: float = 0.8
-  gamma_min: float = 1.0
-  noise_scale: float = 1.003
-  step_scale: float = 1.5
-  num_samples: int = 1
-
-
-class DiffusionHead(hk.Module):
-  """Denoising Diffusion Head."""
-
-  class Config(
-      atom_cross_attention.AtomCrossAttEncoderConfig,
-      atom_cross_attention.AtomCrossAttDecoderConfig,
-  ):
-    """Configuration for DiffusionHead."""
-
-    eval_batch_size: int = 5
-    eval_batch_dim_shard_size: int = 5
-    conditioning: ConditioningConfig = base_config.autocreate(
-        prob=0.8, pair_channel=128, seq_channel=384
-    )
-    eval: SampleConfig = base_config.autocreate(
-        num_samples=5,
-        steps=200,
-    )
-    transformer: diffusion_transformer.Transformer.Config = (
-        base_config.autocreate()
-    )
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='diffusion_head',
-  ):
-    self.config = config
-    self.global_config = global_config
-    super().__init__(name=name)
-
-  @hk.transparent
-  def _conditioning(
-      self,
-      batch: feat_batch.Batch,
-      embeddings: dict[str, jnp.ndarray],
-      noise_level: jnp.ndarray,
-      use_conditioning: bool,
-  ) -> tuple[jnp.ndarray, jnp.ndarray]:
-    single_embedding = use_conditioning * embeddings['single']
-    pair_embedding = use_conditioning * embeddings['pair']
-
-    rel_features = featurization.create_relative_encoding(
-        batch.token_features, max_relative_idx=32, max_relative_chain=2
-    ).astype(pair_embedding.dtype)
-    features_2d = jnp.concatenate([pair_embedding, rel_features], axis=-1)
-    pair_cond = hm.Linear(
-        self.config.conditioning.pair_channel,
-        precision='highest',
-        name='pair_cond_initial_projection',
-    )(
-        hm.LayerNorm(
-            use_fast_variance=False,
-            create_offset=False,
-            name='pair_cond_initial_norm',
-        )(features_2d)
-    )
-
-    for idx in range(2):
-      pair_cond += diffusion_transformer.transition_block(
-          pair_cond, 2, self.global_config, name=f'pair_transition_{idx}'
-      )
-
-    target_feat = embeddings['target_feat']
-    features_1d = jnp.concatenate([single_embedding, target_feat], axis=-1)
-    single_cond = hm.LayerNorm(
-        use_fast_variance=False,
-        create_offset=False,
-        name='single_cond_initial_norm',
-    )(features_1d)
-    single_cond = hm.Linear(
-        self.config.conditioning.seq_channel,
-        precision='highest',
-        name='single_cond_initial_projection',
-    )(single_cond)
-
-    noise_embedding = noise_level_embeddings.noise_embeddings(
-        sigma_scaled_noise_level=noise_level / SIGMA_DATA
-    )
-    single_cond += hm.Linear(
-        self.config.conditioning.seq_channel,
-        precision='highest',
-        name='noise_embedding_initial_projection',
-    )(
-        hm.LayerNorm(
-            use_fast_variance=False,
-            create_offset=False,
-            name='noise_embedding_initial_norm',
-        )(noise_embedding)
-    )
-
-    for idx in range(2):
-      single_cond += diffusion_transformer.transition_block(
-          single_cond, 2, self.global_config, name=f'single_transition_{idx}'
-      )
-
-    return single_cond, pair_cond
-
-  def __call__(
-      self,
-      # positions_noisy.shape: (num_token, max_atoms_per_token, 3)
-      positions_noisy: jnp.ndarray,
-      noise_level: jnp.ndarray,
-      batch: feat_batch.Batch,
-      embeddings: dict[str, jnp.ndarray],
-      use_conditioning: bool,
-  ) -> jnp.ndarray:
-
-    with utils.bfloat16_context():
-      # Get conditioning
-      trunk_single_cond, trunk_pair_cond = self._conditioning(
-          batch=batch,
-          embeddings=embeddings,
-          noise_level=noise_level,
-          use_conditioning=use_conditioning,
-      )
-
-      # Extract features
-      sequence_mask = batch.token_features.mask
-      atom_mask = batch.predicted_structure_info.atom_mask
-
-      # Position features
-      act = positions_noisy * atom_mask[..., None]
-      act = act / jnp.sqrt(noise_level**2 + SIGMA_DATA**2)
-
-      enc = atom_cross_attention.atom_cross_att_encoder(
-          token_atoms_act=act,
-          trunk_single_cond=embeddings['single'],
-          trunk_pair_cond=trunk_pair_cond,
-          config=self.config,
-          global_config=self.global_config,
-          batch=batch,
-          name='diffusion',
-      )
-      act = enc.token_act
-
-      # Token-token attention
-      chex.assert_shape(act, (None, self.config.per_token_channels))
-      act = jnp.asarray(act, dtype=jnp.float32)
-
-      act += hm.Linear(
-          act.shape[-1],
-          precision='highest',
-          initializer=self.global_config.final_init,
-          name='single_cond_embedding_projection',
-      )(
-          hm.LayerNorm(
-              use_fast_variance=False,
-              create_offset=False,
-              name='single_cond_embedding_norm',
-          )(trunk_single_cond)
-      )
-
-      act = jnp.asarray(act, dtype=jnp.float32)
-      trunk_single_cond = jnp.asarray(trunk_single_cond, dtype=jnp.float32)
-      trunk_pair_cond = jnp.asarray(trunk_pair_cond, dtype=jnp.float32)
-      sequence_mask = jnp.asarray(sequence_mask, dtype=jnp.float32)
-
-      transformer = diffusion_transformer.Transformer(
-          self.config.transformer, self.global_config
-      )
-      act = transformer(
-          act=act,
-          single_cond=trunk_single_cond,
-          mask=sequence_mask,
-          pair_cond=trunk_pair_cond,
-      )
-      act = hm.LayerNorm(
-          use_fast_variance=False, create_offset=False, name='output_norm'
-      )(act)
-      # (n_tokens, per_token_channels)
-
-      # (Possibly) atom-granularity decoder
-      assert isinstance(enc, atom_cross_attention.AtomCrossAttEncoderOutput)
-      position_update = atom_cross_attention.atom_cross_att_decoder(
-          token_act=act,
-          enc=enc,
-          config=self.config,
-          global_config=self.global_config,
-          batch=batch,
-          name='diffusion',
-      )
-
-      skip_scaling = SIGMA_DATA**2 / (noise_level**2 + SIGMA_DATA**2)
-      out_scaling = (
-          noise_level * SIGMA_DATA / jnp.sqrt(noise_level**2 + SIGMA_DATA**2)
-      )
-    # End `with utils.bfloat16_context()`.
-
-    return (
-        skip_scaling * positions_noisy + out_scaling * position_update
-    ) * atom_mask[..., None]
-
-
-def sample(
-    denoising_step: Callable[[jnp.ndarray, jnp.ndarray], jnp.ndarray],
-    batch: feat_batch.Batch,
-    key: jnp.ndarray,
-    config: SampleConfig,
-) -> dict[str, jnp.ndarray]:
-  """Sample using denoiser on batch.
-
-  Args:
-    denoising_step: the denoising function.
-    batch: the batch
-    key: random key
-    config: config for the sampling process (e.g. number of denoising steps,
-      etc.)
-
-  Returns:
-    a dict
-      {
-         'atom_positions': jnp.array(...)       # shape (<common_axes>, 3)
-         'mask': jnp.array(...)                 # shape (<common_axes>,)
-      }
-    where the <common_axes> are
-    (num_samples, num_tokens, max_atoms_per_token)
-  """
-
-  mask = batch.predicted_structure_info.atom_mask
-
-  def apply_denoising_step(carry, noise_level):
-    key, positions, noise_level_prev = carry
-    key, key_noise, key_aug = jax.random.split(key, 3)
-
-    positions = random_augmentation(
-        rng_key=key_aug, positions=positions, mask=mask
-    )
-
-    gamma = config.gamma_0 * (noise_level > config.gamma_min)
-    t_hat = noise_level_prev * (1 + gamma)
-
-    noise_scale = config.noise_scale * jnp.sqrt(t_hat**2 - noise_level_prev**2)
-    noise = noise_scale * jax.random.normal(key_noise, positions.shape)
-    positions_noisy = positions + noise
-
-    positions_denoised = denoising_step(positions_noisy, t_hat)
-    grad = (positions_noisy - positions_denoised) / t_hat
-
-    d_t = noise_level - t_hat
-    positions_out = positions_noisy + config.step_scale * d_t * grad
-
-    return (key, positions_out, noise_level), positions_out
-
-  num_samples = config.num_samples
-
-  noise_levels = noise_schedule(jnp.linspace(0, 1, config.steps + 1))
-
-  key, noise_key = jax.random.split(key)
-  positions = jax.random.normal(noise_key, (num_samples,) + mask.shape + (3,))
-  positions *= noise_levels[0]
-
-  init = (
-      jax.random.split(key, num_samples),
-      positions,
-      jnp.tile(noise_levels[None, 0], (num_samples,)),
-  )
-
-  apply_denoising_step = hk.vmap(
-      apply_denoising_step, in_axes=(0, None), split_rng=(not hk.running_init())
-  )
-  result, _ = hk.scan(apply_denoising_step, init, noise_levels[1:], unroll=4)
-  _, positions_out, _ = result
-
-  final_dense_atom_mask = jnp.tile(mask[None], (num_samples, 1, 1))
-
-  return {'atom_positions': positions_out, 'mask': final_dense_atom_mask}
diff --git a/src/alphafold3/model/network/diffusion_transformer.py b/src/alphafold3/model/network/diffusion_transformer.py
deleted file mode 100644
index 58823e8a54c31993e77ef1b647bb6cac8a95d399..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/diffusion_transformer.py
+++ /dev/null
@@ -1,404 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Diffusion transformer model."""
-
-from alphafold3.common import base_config
-from alphafold3.jax.gated_linear_unit import gated_linear_unit
-from alphafold3.model import model_config
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.model.components import haiku_modules as hm
-import haiku as hk
-import jax
-from jax import numpy as jnp
-
-
-def adaptive_layernorm(x, single_cond, name):
-  """Adaptive LayerNorm."""
-  # Adopted from Scalable Diffusion Models with Transformers
-  # https://arxiv.org/abs/2212.09748
-  if single_cond is None:
-    x = hm.LayerNorm(name=f'{name}layer_norm', use_fast_variance=False)(x)
-  else:
-    x = hm.LayerNorm(
-        name=f'{name}layer_norm',
-        use_fast_variance=False,
-        create_scale=False,
-        create_offset=False,
-    )(x)
-    single_cond = hm.LayerNorm(
-        name=f'{name}single_cond_layer_norm',
-        use_fast_variance=False,
-        create_offset=False,
-    )(single_cond)
-    single_scale = hm.Linear(
-        x.shape[-1],
-        initializer='zeros',
-        use_bias=True,
-        name=f'{name}single_cond_scale',
-    )(single_cond)
-    single_bias = hm.Linear(
-        x.shape[-1], initializer='zeros', name=f'{name}single_cond_bias'
-    )(single_cond)
-    x = jax.nn.sigmoid(single_scale) * x + single_bias
-  return x
-
-
-def adaptive_zero_init(
-    x, num_channels, single_cond, global_config: model_config.GlobalConfig, name
-):
-  """Adaptive zero init, from AdaLN-zero."""
-  if single_cond is None:
-    output = hm.Linear(
-        num_channels,
-        initializer=global_config.final_init,
-        name=f'{name}transition2',
-    )(x)
-  else:
-    output = hm.Linear(num_channels, name=f'{name}transition2')(x)
-    # Init to a small gain, sigmoid(-2) ~ 0.1
-    cond = hm.Linear(
-        output.shape[-1],
-        initializer='zeros',
-        use_bias=True,
-        bias_init=-2.0,
-        name=f'{name}adaptive_zero_cond',
-    )(single_cond)
-    output = jax.nn.sigmoid(cond) * output
-  return output
-
-
-def transition_block(
-    x: jnp.ndarray,
-    num_intermediate_factor: int,
-    global_config: model_config.GlobalConfig,
-    single_cond: jnp.ndarray | None = None,
-    use_glu_kernel: bool = True,
-    name: str = '',
-) -> jnp.ndarray:
-  """Transition Block."""
-  num_channels = x.shape[-1]
-  num_intermediates = num_intermediate_factor * num_channels
-
-  x = adaptive_layernorm(x, single_cond, name=f'{name}ffw_')
-
-  if use_glu_kernel:
-    weights, _ = hm.haiku_linear_get_params(
-        x,
-        num_output=num_intermediates * 2,
-        initializer='relu',
-        name=f'{name}ffw_transition1',
-    )
-    weights = jnp.reshape(weights, (len(weights), 2, num_intermediates))
-    c = gated_linear_unit.gated_linear_unit(
-        x=x, weight=weights, implementation=None, activation=jax.nn.swish
-    )
-  else:
-    x = hm.Linear(
-        num_intermediates * 2, initializer='relu', name=f'{name}ffw_transition1'
-    )(x)
-    a, b = jnp.split(x, 2, axis=-1)
-    c = jax.nn.swish(a) * b
-
-  output = adaptive_zero_init(
-      c, num_channels, single_cond, global_config, f'{name}ffw_'
-  )
-  return output
-
-
-class SelfAttentionConfig(base_config.BaseConfig):
-  num_head: int = 16
-  key_dim: int | None = None
-  value_dim: int | None = None
-
-
-def self_attention(
-    x: jnp.ndarray,  # (num_tokens, ch)
-    mask: jnp.ndarray,  # (num_tokens,)
-    pair_logits: jnp.ndarray | None,  # (num_heads, num_tokens, num_tokens)
-    config: SelfAttentionConfig,
-    global_config: model_config.GlobalConfig,
-    single_cond: jnp.ndarray | None = None,  # (num_tokens, ch)
-    name: str = '',
-) -> jnp.ndarray:
-  """Multihead self-attention."""
-  assert len(mask.shape) == len(x.shape) - 1, f'{mask.shape}, {x.shape}'
-  # bias: ... x heads (1) x query (1) x key
-  bias = (1e9 * (mask - 1.0))[..., None, None, :]
-
-  x = adaptive_layernorm(x, single_cond, name=name)
-
-  num_channels = x.shape[-1]
-  # Sensible default for when the config keys are missing
-  key_dim = config.key_dim if config.key_dim is not None else num_channels
-  value_dim = config.value_dim if config.value_dim is not None else num_channels
-  num_head = config.num_head
-  assert key_dim % num_head == 0, f'{key_dim=} % {num_head=} != 0'
-  assert value_dim % num_head == 0, f'{value_dim=} % {num_head=} != 0'
-  key_dim = key_dim // num_head
-  value_dim = value_dim // num_head
-
-  qk_shape = (num_head, key_dim)
-  q = hm.Linear(qk_shape, use_bias=True, name=f'{name}q_projection')(x)
-  k = hm.Linear(qk_shape, use_bias=False, name=f'{name}k_projection')(x)
-
-  # In some situations the gradient norms can blow up without running this
-  # einsum in float32.
-  q = q.astype(jnp.float32)
-  k = k.astype(jnp.float32)
-  bias = bias.astype(jnp.float32)
-  logits = jnp.einsum('...qhc,...khc->...hqk', q * key_dim ** (-0.5), k) + bias
-  if pair_logits is not None:
-    logits += pair_logits  # (num_heads, seq_len, seq_len)
-  weights = jax.nn.softmax(logits, axis=-1)
-  weights = jnp.asarray(weights, dtype=x.dtype)
-
-  v_shape = (num_head, value_dim)
-  v = hm.Linear(v_shape, use_bias=False, name=f'{name}v_projection')(x)
-  weighted_avg = jnp.einsum('...hqk,...khc->...qhc', weights, v)
-  weighted_avg = jnp.reshape(weighted_avg, weighted_avg.shape[:-2] + (-1,))
-
-  gate_logits = hm.Linear(
-      num_head * value_dim,
-      bias_init=1.0,
-      initializer='zeros',
-      name=f'{name}gating_query',
-  )(x)
-  weighted_avg *= jax.nn.sigmoid(gate_logits)
-
-  output = adaptive_zero_init(
-      weighted_avg, num_channels, single_cond, global_config, name
-  )
-  return output
-
-
-class Transformer(hk.Module):
-  """Simple transformer stack."""
-
-  class Config(base_config.BaseConfig):
-    attention: SelfAttentionConfig = base_config.autocreate()
-    num_blocks: int = 24
-    block_remat: bool = False
-    super_block_size: int = 4
-    num_intermediate_factor: int = 2
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name: str = 'transformer',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      act: jnp.ndarray,
-      mask: jnp.ndarray,
-      single_cond: jnp.ndarray,
-      pair_cond: jnp.ndarray | None,
-  ) -> jnp.ndarray:
-    def block(act, pair_logits):
-      act += self_attention(
-          act,
-          mask,
-          pair_logits,
-          self.config.attention,
-          self.global_config,
-          single_cond,
-          name=self.name,
-      )
-      act += transition_block(
-          act,
-          self.config.num_intermediate_factor,
-          self.global_config,
-          single_cond,
-          name=self.name,
-      )
-      return act, None
-
-    # Precompute pair logits for performance
-    if pair_cond is None:
-      pair_act = None
-    else:
-      pair_act = hm.LayerNorm(
-          name='pair_input_layer_norm',
-          use_fast_variance=False,
-          create_offset=False,
-      )(pair_cond)
-
-    assert self.config.num_blocks % self.config.super_block_size == 0
-    num_super_blocks = self.config.num_blocks // self.config.super_block_size
-
-    def super_block(act):
-      if pair_act is None:
-        pair_logits = None
-      else:
-        pair_logits = hm.Linear(
-            (self.config.super_block_size, self.config.attention.num_head),
-            name='pair_logits_projection',
-        )(pair_act)
-        pair_logits = jnp.transpose(pair_logits, [2, 3, 0, 1])
-      return hk.experimental.layer_stack(
-          self.config.super_block_size, with_per_layer_inputs=True
-      )(block)(act, pair_logits)
-
-    return hk.experimental.layer_stack(
-        num_super_blocks, with_per_layer_inputs=True
-    )(super_block)(act)[0]
-
-
-class CrossAttentionConfig(base_config.BaseConfig):
-  num_head: int = 4
-  key_dim: int = 128
-  value_dim: int = 128
-
-
-def cross_attention(
-    x_q: jnp.ndarray,  # (..., Q, C)
-    x_k: jnp.ndarray,  # (..., K, C)
-    mask_q: jnp.ndarray,  # (..., Q)
-    mask_k: jnp.ndarray,  # (..., K)
-    config: CrossAttentionConfig,
-    global_config: model_config.GlobalConfig,
-    pair_logits: jnp.ndarray | None = None,  # (..., Q, K)
-    single_cond_q: jnp.ndarray | None = None,  # (..., Q, C)
-    single_cond_k: jnp.ndarray | None = None,  # (..., K, C)
-    name: str = '',
-) -> jnp.ndarray:
-  """Multihead self-attention."""
-  assert len(mask_q.shape) == len(x_q.shape) - 1, f'{mask_q.shape}, {x_q.shape}'
-  assert len(mask_k.shape) == len(x_k.shape) - 1, f'{mask_k.shape}, {x_k.shape}'
-  # bias: ... x heads (1) x query x key
-  bias = (
-      1e9
-      * (mask_q - 1.0)[..., None, :, None]
-      * (mask_k - 1.0)[..., None, None, :]
-  )
-
-  x_q = adaptive_layernorm(x_q, single_cond_q, name=f'{name}q')
-  x_k = adaptive_layernorm(x_k, single_cond_k, name=f'{name}k')
-
-  assert config.key_dim % config.num_head == 0
-  assert config.value_dim % config.num_head == 0
-  key_dim = config.key_dim // config.num_head
-  value_dim = config.value_dim // config.num_head
-
-  q = hm.Linear(
-      (config.num_head, key_dim), use_bias=True, name=f'{name}q_projection'
-  )(x_q)
-  k = hm.Linear(
-      (config.num_head, key_dim), use_bias=False, name=f'{name}k_projection'
-  )(x_k)
-
-  # In some situations the gradient norms can blow up without running this
-  # einsum in float32.
-  q = q.astype(jnp.float32)
-  k = k.astype(jnp.float32)
-  bias = bias.astype(jnp.float32)
-  logits = jnp.einsum('...qhc,...khc->...hqk', q * key_dim ** (-0.5), k) + bias
-  if pair_logits is not None:
-    logits += pair_logits
-  weights = jax.nn.softmax(logits, axis=-1)
-  weights = jnp.asarray(weights, dtype=x_q.dtype)
-
-  v = hm.Linear(
-      (config.num_head, value_dim), use_bias=False, name=f'{name}v_projection'
-  )(x_k)
-  weighted_avg = jnp.einsum('...hqk,...khc->...qhc', weights, v)
-  weighted_avg = jnp.reshape(weighted_avg, weighted_avg.shape[:-2] + (-1,))
-
-  gate_logits = hm.Linear(
-      config.num_head * value_dim,
-      bias_init=1.0,
-      initializer='zeros',
-      name=f'{name}gating_query',
-  )(x_q)
-  weighted_avg *= jax.nn.sigmoid(gate_logits)
-
-  output = adaptive_zero_init(
-      weighted_avg, x_q.shape[-1], single_cond_q, global_config, name
-  )
-  return output
-
-
-class CrossAttTransformer(hk.Module):
-  """Transformer that applies cross attention between two sets of subsets."""
-
-  class Config(base_config.BaseConfig):
-    num_intermediate_factor: int
-    num_blocks: int
-    attention: CrossAttentionConfig = base_config.autocreate()
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name: str = 'transformer',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      queries_act: jnp.ndarray,  # (num_subsets, num_queries, ch)
-      queries_mask: jnp.ndarray,  # (num_subsets, num_queries)
-      queries_to_keys: atom_layout.GatherInfo,  # (num_subsets, num_keys)
-      keys_mask: jnp.ndarray,  # (num_subsets, num_keys)
-      queries_single_cond: jnp.ndarray,  # (num_subsets, num_queries, ch)
-      keys_single_cond: jnp.ndarray,  # (num_subsets, num_keys, ch)
-      pair_cond: jnp.ndarray,  # (num_subsets, num_queries, num_keys, ch)
-  ) -> jnp.ndarray:
-    def block(queries_act, pair_logits):
-      # copy the queries activations to the keys layout
-      keys_act = atom_layout.convert(
-          queries_to_keys, queries_act, layout_axes=(-3, -2)
-      )
-      # cross attention
-      queries_act += cross_attention(
-          x_q=queries_act,
-          x_k=keys_act,
-          mask_q=queries_mask,
-          mask_k=keys_mask,
-          config=self.config.attention,
-          global_config=self.global_config,
-          pair_logits=pair_logits,
-          single_cond_q=queries_single_cond,
-          single_cond_k=keys_single_cond,
-          name=self.name,
-      )
-      queries_act += transition_block(
-          queries_act,
-          self.config.num_intermediate_factor,
-          self.global_config,
-          queries_single_cond,
-          name=self.name,
-      )
-      return queries_act, None
-
-    # Precompute pair logits for performance
-    pair_act = hm.LayerNorm(
-        name='pair_input_layer_norm',
-        use_fast_variance=False,
-        create_offset=False,
-    )(pair_cond)
-    # (num_subsets, num_queries, num_keys, num_blocks, num_heads)
-    pair_logits = hm.Linear(
-        (self.config.num_blocks, self.config.attention.num_head),
-        name='pair_logits_projection',
-    )(pair_act)
-    # (num_block, num_subsets, num_heads, num_queries, num_keys)
-    pair_logits = jnp.transpose(pair_logits, [3, 0, 4, 1, 2])
-
-    return hk.experimental.layer_stack(
-        self.config.num_blocks, with_per_layer_inputs=True
-    )(block)(queries_act, pair_logits)[0]
diff --git a/src/alphafold3/model/network/distogram_head.py b/src/alphafold3/model/network/distogram_head.py
deleted file mode 100644
index 810eccba210b64e404d9a7751021b480e95874ed..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/distogram_head.py
+++ /dev/null
@@ -1,81 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Distogram head."""
-
-from typing import Final
-
-from alphafold3.common import base_config
-from alphafold3.model import feat_batch
-from alphafold3.model import model_config
-from alphafold3.model.components import haiku_modules as hm
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-_CONTACT_THRESHOLD: Final[float] = 8.0
-_CONTACT_EPSILON: Final[float] = 1e-3
-
-
-class DistogramHead(hk.Module):
-  """Distogram head."""
-
-  class Config(base_config.BaseConfig):
-    first_break: float = 2.3125
-    last_break: float = 21.6875
-    num_bins: int = 64
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='distogram_head',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      batch: feat_batch.Batch,
-      embeddings: dict[str, jnp.ndarray],
-  ) -> dict[str, jnp.ndarray]:
-    pair_act = embeddings['pair']
-    seq_mask = batch.token_features.mask.astype(bool)
-    pair_mask = seq_mask[:, None] * seq_mask[None, :]
-
-    left_half_logits = hm.Linear(
-        self.config.num_bins,
-        initializer=self.global_config.final_init,
-        name='half_logits',
-    )(pair_act)
-
-    right_half_logits = left_half_logits
-    logits = left_half_logits + jnp.swapaxes(right_half_logits, -2, -3)
-    probs = jax.nn.softmax(logits, axis=-1)
-    breaks = jnp.linspace(
-        self.config.first_break,
-        self.config.last_break,
-        self.config.num_bins - 1,
-    )
-
-    bin_tops = jnp.append(breaks, breaks[-1] + (breaks[-1] - breaks[-2]))
-    threshold = _CONTACT_THRESHOLD + _CONTACT_EPSILON
-    is_contact_bin = 1.0 * (bin_tops <= threshold)
-    contact_probs = jnp.einsum(
-        'ijk,k->ij', probs, is_contact_bin, precision=jax.lax.Precision.HIGHEST
-    )
-    contact_probs = pair_mask * contact_probs
-
-    return {
-        'bin_edges': breaks,
-        'contact_probs': contact_probs,
-    }
diff --git a/src/alphafold3/model/network/evoformer.py b/src/alphafold3/model/network/evoformer.py
deleted file mode 100644
index fb245cd1e780045ad8ae50e4813c95f16a29bdaf..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/evoformer.py
+++ /dev/null
@@ -1,347 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Evoformer network."""
-
-import functools
-
-from alphafold3.common import base_config
-from alphafold3.model import feat_batch
-from alphafold3.model import features
-from alphafold3.model import model_config
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import utils
-from alphafold3.model.network import atom_cross_attention
-from alphafold3.model.network import featurization
-from alphafold3.model.network import modules
-from alphafold3.model.network import template_modules
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-class Evoformer(hk.Module):
-  """Creates 'single' and 'pair' embeddings."""
-
-  class PairformerConfig(modules.PairFormerIteration.Config):  # pytype: disable=invalid-function-definition
-    block_remat: bool = False
-    remat_block_size: int = 8
-
-  class Config(base_config.BaseConfig):
-    """Configuration for Evoformer."""
-
-    max_relative_chain: int = 2
-    msa_channel: int = 64
-    seq_channel: int = 384
-    max_relative_idx: int = 32
-    num_msa: int = 1024
-    pair_channel: int = 128
-    pairformer: 'Evoformer.PairformerConfig' = base_config.autocreate(
-        single_transition=base_config.autocreate(),
-        single_attention=base_config.autocreate(),
-        num_layer=48,
-    )
-    per_atom_conditioning: atom_cross_attention.AtomCrossAttEncoderConfig = (
-        base_config.autocreate(
-            per_token_channels=384,
-            per_atom_channels=128,
-            atom_transformer=base_config.autocreate(
-                num_intermediate_factor=2,
-                num_blocks=3,
-            ),
-            per_atom_pair_channels=16,
-        )
-    )
-    template: template_modules.TemplateEmbedding.Config = (
-        base_config.autocreate()
-    )
-    msa_stack: modules.EvoformerIteration.Config = base_config.autocreate()
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='evoformer',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def _relative_encoding(
-      self, batch: feat_batch.Batch, pair_activations: jnp.ndarray
-  ) -> jnp.ndarray:
-    """Add relative position encodings."""
-    rel_feat = featurization.create_relative_encoding(
-        batch.token_features,
-        self.config.max_relative_idx,
-        self.config.max_relative_chain,
-    )
-    rel_feat = rel_feat.astype(pair_activations.dtype)
-
-    pair_activations += hm.Linear(
-        self.config.pair_channel, name='position_activations'
-    )(rel_feat)
-    return pair_activations
-
-  @hk.transparent
-  def _seq_pair_embedding(
-      self,
-      token_features: features.TokenFeatures,
-      target_feat: jnp.ndarray,
-  ) -> tuple[jnp.ndarray, jnp.ndarray]:
-    """Generated Pair embedding from sequence."""
-    left_single = hm.Linear(self.config.pair_channel, name='left_single')(
-        target_feat
-    )[:, None]
-    right_single = hm.Linear(self.config.pair_channel, name='right_single')(
-        target_feat
-    )[None]
-    dtype = left_single.dtype
-    pair_activations = left_single + right_single
-    num_residues = pair_activations.shape[0]
-    assert pair_activations.shape == (
-        num_residues,
-        num_residues,
-        self.config.pair_channel,
-    )
-    mask = token_features.mask
-    pair_mask = (mask[:, None] * mask[None, :]).astype(dtype)
-    assert pair_mask.shape == (num_residues, num_residues)
-    return pair_activations, pair_mask  # pytype: disable=bad-return-type  # jax-ndarray
-
-  @hk.transparent
-  def _embed_bonds(
-      self,
-      batch: feat_batch.Batch,
-      pair_activations: jnp.ndarray,
-  ) -> jnp.ndarray:
-    """Embeds bond features and merges into pair activations."""
-    # Construct contact matrix.
-    num_tokens = batch.token_features.token_index.shape[0]
-    contact_matrix = jnp.zeros((num_tokens, num_tokens))
-
-    tokens_to_polymer_ligand_bonds = (
-        batch.polymer_ligand_bond_info.tokens_to_polymer_ligand_bonds
-    )
-    gather_idxs_polymer_ligand = tokens_to_polymer_ligand_bonds.gather_idxs
-    gather_mask_polymer_ligand = (
-        tokens_to_polymer_ligand_bonds.gather_mask.prod(axis=1).astype(
-            gather_idxs_polymer_ligand.dtype
-        )[:, None]
-    )
-    # If valid mask then it will be all 1's, so idxs should be unchanged.
-    gather_idxs_polymer_ligand = (
-        gather_idxs_polymer_ligand * gather_mask_polymer_ligand
-    )
-
-    tokens_to_ligand_ligand_bonds = (
-        batch.ligand_ligand_bond_info.tokens_to_ligand_ligand_bonds
-    )
-    gather_idxs_ligand_ligand = tokens_to_ligand_ligand_bonds.gather_idxs
-    gather_mask_ligand_ligand = tokens_to_ligand_ligand_bonds.gather_mask.prod(
-        axis=1
-    ).astype(gather_idxs_ligand_ligand.dtype)[:, None]
-    gather_idxs_ligand_ligand = (
-        gather_idxs_ligand_ligand * gather_mask_ligand_ligand
-    )
-
-    gather_idxs = jnp.concatenate(
-        [gather_idxs_polymer_ligand, gather_idxs_ligand_ligand]
-    )
-    contact_matrix = contact_matrix.at[
-        gather_idxs[:, 0], gather_idxs[:, 1]
-    ].set(1.0)
-
-    # Because all the padded index's are 0's.
-    contact_matrix = contact_matrix.at[0, 0].set(0.0)
-
-    bonds_act = hm.Linear(self.config.pair_channel, name='bond_embedding')(
-        contact_matrix[:, :, None].astype(pair_activations.dtype)
-    )
-    return pair_activations + bonds_act
-
-  @hk.transparent
-  def _embed_template_pair(
-      self,
-      batch: feat_batch.Batch,
-      pair_activations: jnp.ndarray,
-      pair_mask: jnp.ndarray,
-      key: jnp.ndarray,
-  ) -> tuple[jnp.ndarray, jnp.ndarray]:
-    """Embeds Templates and merges into pair activations."""
-    dtype = pair_activations.dtype
-    key, subkey = jax.random.split(key)
-    template_module = template_modules.TemplateEmbedding(
-        self.config.template, self.global_config
-    )
-    templates = batch.templates
-    asym_id = batch.token_features.asym_id
-    # Construct a mask such that only intra-chain template features are
-    # computed, since all templates are for each chain individually.
-    multichain_mask = (asym_id[:, None] == asym_id[None, :]).astype(dtype)
-
-    template_fn = functools.partial(template_module, key=subkey)
-    template_act = template_fn(
-        query_embedding=pair_activations,
-        templates=templates,
-        multichain_mask_2d=multichain_mask,
-        padding_mask_2d=pair_mask,
-    )
-    return pair_activations + template_act, key
-
-  @hk.transparent
-  def _embed_process_msa(
-      self,
-      msa_batch: features.MSA,
-      pair_activations: jnp.ndarray,
-      pair_mask: jnp.ndarray,
-      key: jnp.ndarray,
-      target_feat: jnp.ndarray,
-  ) -> tuple[jnp.ndarray, jnp.ndarray]:
-    """Processes MSA and returns updated pair activations."""
-    dtype = pair_activations.dtype
-    msa_batch, key = featurization.shuffle_msa(key, msa_batch)
-    msa_batch = featurization.truncate_msa_batch(msa_batch, self.config.num_msa)
-    msa_feat = featurization.create_msa_feat(msa_batch).astype(dtype)
-
-    msa_activations = hm.Linear(
-        self.config.msa_channel, name='msa_activations'
-    )(msa_feat)
-
-    msa_activations += hm.Linear(
-        self.config.msa_channel, name='extra_msa_target_feat'
-    )(target_feat)[None]
-    msa_mask = msa_batch.mask.astype(dtype)
-
-    # Evoformer MSA stack.
-    evoformer_input = {'msa': msa_activations, 'pair': pair_activations}
-    masks = {'msa': msa_mask, 'pair': pair_mask}
-
-    def evoformer_fn(x):
-      return modules.EvoformerIteration(
-          self.config.msa_stack, self.global_config, name='msa_stack'
-      )(
-          activations=x,
-          masks=masks,
-      )
-
-    evoformer_stack = hk.experimental.layer_stack(
-        self.config.msa_stack.num_layer
-    )(evoformer_fn)
-
-    evoformer_output = evoformer_stack(evoformer_input)
-
-    return evoformer_output['pair'], key
-
-  def __call__(
-      self,
-      batch: feat_batch.Batch,
-      prev: dict[str, jnp.ndarray],
-      target_feat: jnp.ndarray,
-      key: jnp.ndarray,
-  ) -> dict[str, jnp.ndarray]:
-
-    assert self.global_config.bfloat16 in {'all', 'none'}
-
-    num_residues = target_feat.shape[0]
-    assert batch.token_features.aatype.shape == (num_residues,)
-
-    dtype = (
-        jnp.bfloat16 if self.global_config.bfloat16 == 'all' else jnp.float32
-    )
-
-    with utils.bfloat16_context():
-      pair_activations, pair_mask = self._seq_pair_embedding(
-          batch.token_features, target_feat
-      )
-
-      pair_activations += hm.Linear(
-          pair_activations.shape[-1],
-          name='prev_embedding',
-          initializer=self.global_config.final_init,
-      )(
-          hm.LayerNorm(name='prev_embedding_layer_norm')(
-              prev['pair'].astype(pair_activations.dtype)
-          )
-      )
-
-      pair_activations = self._relative_encoding(batch, pair_activations)
-
-      pair_activations = self._embed_bonds(
-          batch=batch, pair_activations=pair_activations
-      )
-
-      pair_activations, key = self._embed_template_pair(
-          batch=batch,
-          pair_activations=pair_activations,
-          pair_mask=pair_mask,
-          key=key,
-      )
-      pair_activations, key = self._embed_process_msa(
-          msa_batch=batch.msa,
-          pair_activations=pair_activations,
-          pair_mask=pair_mask,
-          key=key,
-          target_feat=target_feat,
-      )
-      del key  # Unused after this point.
-
-      single_activations = hm.Linear(
-          self.config.seq_channel, name='single_activations'
-      )(target_feat)
-
-      single_activations += hm.Linear(
-          single_activations.shape[-1],
-          name='prev_single_embedding',
-          initializer=self.global_config.final_init,
-      )(
-          hm.LayerNorm(name='prev_single_embedding_layer_norm')(
-              prev['single'].astype(single_activations.dtype)
-          )
-      )
-
-      def pairformer_fn(x):
-        pairformer_iteration = modules.PairFormerIteration(
-            self.config.pairformer,
-            self.global_config,
-            with_single=True,
-            name='trunk_pairformer',
-        )
-        pair_act, single_act = x
-        return pairformer_iteration(
-            act=pair_act,
-            single_act=single_act,
-            pair_mask=pair_mask,
-            seq_mask=batch.token_features.mask.astype(dtype),
-        )
-
-      pairformer_stack = hk.experimental.layer_stack(
-          self.config.pairformer.num_layer
-      )(pairformer_fn)
-
-      pair_activations, single_activations = pairformer_stack(
-          (pair_activations, single_activations)
-      )
-
-      assert pair_activations.shape == (
-          num_residues,
-          num_residues,
-          self.config.pair_channel,
-      )
-      assert single_activations.shape == (num_residues, self.config.seq_channel)
-      assert len(target_feat.shape) == 2
-      assert target_feat.shape[0] == num_residues
-      output = {
-          'single': single_activations,
-          'pair': pair_activations,
-          'target_feat': target_feat,
-      }
-
-    return output
diff --git a/src/alphafold3/model/network/featurization.py b/src/alphafold3/model/network/featurization.py
deleted file mode 100644
index de8ee57e2f0170f7cd566ff262d508811f4cd75b..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/featurization.py
+++ /dev/null
@@ -1,269 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Model-side of the input features processing."""
-
-import functools
-
-from alphafold3.constants import residue_names
-from alphafold3.model import feat_batch
-from alphafold3.model import features
-from alphafold3.model.components import utils
-import chex
-import jax
-import jax.numpy as jnp
-
-
-def _grid_keys(key, shape):
-  """Generate a grid of rng keys that is consistent with different padding.
-
-  Generate random keys such that the keys will be identical, regardless of
-  how much padding is added to any dimension.
-
-  Args:
-    key: A PRNG key.
-    shape: The shape of the output array of keys that will be generated.
-
-  Returns:
-    An array of shape `shape` consisting of random keys.
-  """
-  if not shape:
-    return key
-  new_keys = jax.vmap(functools.partial(jax.random.fold_in, key))(
-      jnp.arange(shape[0])
-  )
-  return jax.vmap(functools.partial(_grid_keys, shape=shape[1:]))(new_keys)
-
-
-def _padding_consistent_rng(f):
-  """Modify any element-wise random function to be consistent with padding.
-
-  Normally if you take a function like jax.random.normal and generate an array,
-  say of size (10,10), you will get a different set of random numbers to if you
-  add padding and take the first (10,10) sub-array.
-
-  This function makes a random function that is consistent regardless of the
-  amount of padding added.
-
-  Note: The padding-consistent function is likely to be slower to compile and
-  run than the function it is wrapping, but these slowdowns are likely to be
-  negligible in a large network.
-
-  Args:
-    f: Any element-wise function that takes (PRNG key, shape) as the first 2
-      arguments.
-
-  Returns:
-    An equivalent function to f, that is now consistent for different amounts of
-    padding.
-  """
-
-  def inner(key, shape, **kwargs):
-    keys = _grid_keys(key, shape)
-    signature = (
-        '()->()'
-        if jax.dtypes.issubdtype(keys.dtype, jax.dtypes.prng_key)
-        else '(2)->()'
-    )
-    return jnp.vectorize(
-        functools.partial(f, shape=(), **kwargs), signature=signature
-    )(keys)
-
-  return inner
-
-
-def gumbel_argsort_sample_idx(
-    key: jnp.ndarray, logits: jnp.ndarray
-) -> jnp.ndarray:
-  """Samples with replacement from a distribution given by 'logits'.
-
-  This uses Gumbel trick to implement the sampling an efficient manner. For a
-  distribution over k items this samples k times without replacement, so this
-  is effectively sampling a random permutation with probabilities over the
-  permutations derived from the logprobs.
-
-  Args:
-    key: prng key
-    logits: logarithm of probabilities to sample from, probabilities can be
-      unnormalized.
-
-  Returns:
-    Sample from logprobs in one-hot form.
-  """
-  gumbel = _padding_consistent_rng(jax.random.gumbel)
-  z = gumbel(key, logits.shape)
-  # This construction is equivalent to jnp.argsort, but using a non stable sort,
-  # since stable sort's aren't supported by jax2tf
-  axis = len(logits.shape) - 1
-  iota = jax.lax.broadcasted_iota(jnp.int64, logits.shape, axis)
-  _, perm = jax.lax.sort_key_val(
-      logits + z, iota, dimension=-1, is_stable=False
-  )
-  return perm[::-1]
-
-
-def create_msa_feat(msa: features.MSA) -> chex.ArrayDevice:
-  """Create and concatenate MSA features."""
-  msa_1hot = jax.nn.one_hot(
-      msa.rows, residue_names.POLYMER_TYPES_NUM_WITH_UNKNOWN_AND_GAP + 1
-  )
-  deletion_matrix = msa.deletion_matrix
-  has_deletion = jnp.clip(deletion_matrix, 0.0, 1.0)[..., None]
-  deletion_value = (jnp.arctan(deletion_matrix / 3.0) * (2.0 / jnp.pi))[
-      ..., None
-  ]
-
-  msa_feat = [
-      msa_1hot,
-      has_deletion,
-      deletion_value,
-  ]
-
-  return jnp.concatenate(msa_feat, axis=-1)
-
-
-def truncate_msa_batch(msa: features.MSA, num_msa: int) -> features.MSA:
-  indices = jnp.arange(num_msa)
-  return msa.index_msa_rows(indices)
-
-
-def create_target_feat(
-    batch: feat_batch.Batch,
-    append_per_atom_features: bool,
-) -> chex.ArrayDevice:
-  """Make target feat."""
-  token_features = batch.token_features
-  target_features = []
-  target_features.append(
-      jax.nn.one_hot(
-          token_features.aatype,
-          residue_names.POLYMER_TYPES_NUM_WITH_UNKNOWN_AND_GAP,
-      )
-  )
-  target_features.append(batch.msa.profile)
-  target_features.append(batch.msa.deletion_mean[..., None])
-
-  # Reference structure features
-  if append_per_atom_features:
-    ref_mask = batch.ref_structure.mask
-    element_feat = jax.nn.one_hot(batch.ref_structure.element, 128)
-    element_feat = utils.mask_mean(
-        mask=ref_mask[..., None], value=element_feat, axis=-2, eps=1e-6
-    )
-    target_features.append(element_feat)
-    pos_feat = batch.ref_structure.positions
-    pos_feat = pos_feat.reshape([pos_feat.shape[0], -1])
-    target_features.append(pos_feat)
-    target_features.append(ref_mask)
-
-  return jnp.concatenate(target_features, axis=-1)
-
-
-def create_relative_encoding(
-    seq_features: features.TokenFeatures,
-    max_relative_idx: int,
-    max_relative_chain: int,
-) -> chex.ArrayDevice:
-  """Add relative position encodings."""
-  rel_feats = []
-  token_index = seq_features.token_index
-  residue_index = seq_features.residue_index
-  asym_id = seq_features.asym_id
-  entity_id = seq_features.entity_id
-  sym_id = seq_features.sym_id
-
-  left_asym_id = asym_id[:, None]
-  right_asym_id = asym_id[None, :]
-
-  left_residue_index = residue_index[:, None]
-  right_residue_index = residue_index[None, :]
-
-  left_token_index = token_index[:, None]
-  right_token_index = token_index[None, :]
-
-  left_entity_id = entity_id[:, None]
-  right_entity_id = entity_id[None, :]
-
-  left_sym_id = sym_id[:, None]
-  right_sym_id = sym_id[None, :]
-
-  # Embed relative positions using a one-hot embedding of distance along chain
-  offset = left_residue_index - right_residue_index
-  clipped_offset = jnp.clip(
-      offset + max_relative_idx, min=0, max=2 * max_relative_idx
-  )
-  asym_id_same = left_asym_id == right_asym_id
-  final_offset = jnp.where(
-      asym_id_same,
-      clipped_offset,
-      (2 * max_relative_idx + 1) * jnp.ones_like(clipped_offset),
-  )
-  rel_pos = jax.nn.one_hot(final_offset, 2 * max_relative_idx + 2)
-  rel_feats.append(rel_pos)
-
-  # Embed relative token index as a one-hot embedding of distance along residue
-  token_offset = left_token_index - right_token_index
-  clipped_token_offset = jnp.clip(
-      token_offset + max_relative_idx, min=0, max=2 * max_relative_idx
-  )
-  residue_same = (left_asym_id == right_asym_id) & (
-      left_residue_index == right_residue_index
-  )
-  final_token_offset = jnp.where(
-      residue_same,
-      clipped_token_offset,
-      (2 * max_relative_idx + 1) * jnp.ones_like(clipped_token_offset),
-  )
-  rel_token = jax.nn.one_hot(final_token_offset, 2 * max_relative_idx + 2)
-  rel_feats.append(rel_token)
-
-  # Embed same entity ID
-  entity_id_same = left_entity_id == right_entity_id
-  rel_feats.append(entity_id_same.astype(rel_pos.dtype)[..., None])
-
-  # Embed relative chain ID inside each symmetry class
-  rel_sym_id = left_sym_id - right_sym_id
-
-  max_rel_chain = max_relative_chain
-
-  clipped_rel_chain = jnp.clip(
-      rel_sym_id + max_rel_chain, min=0, max=2 * max_rel_chain
-  )
-
-  final_rel_chain = jnp.where(
-      entity_id_same,
-      clipped_rel_chain,
-      (2 * max_rel_chain + 1) * jnp.ones_like(clipped_rel_chain),
-  )
-  rel_chain = jax.nn.one_hot(final_rel_chain, 2 * max_relative_chain + 2)
-
-  rel_feats.append(rel_chain)
-
-  return jnp.concatenate(rel_feats, axis=-1)
-
-
-def shuffle_msa(
-    key: jax.Array, msa: features.MSA
-) -> tuple[features.MSA, jax.Array]:
-  """Shuffle MSA randomly, return batch with shuffled MSA.
-
-  Args:
-    key: rng key for random number generation.
-    msa: MSA object to sample msa from.
-
-  Returns:
-    Protein with sampled msa.
-  """
-  key, sample_key = jax.random.split(key)
-  # Sample uniformly among sequences with at least one non-masked position.
-  logits = (jnp.clip(jnp.sum(msa.mask, axis=-1), 0.0, 1.0) - 1.0) * 1e6
-  index_order = gumbel_argsort_sample_idx(sample_key, logits)
-
-  return msa.index_msa_rows(index_order), key
diff --git a/src/alphafold3/model/network/modules.py b/src/alphafold3/model/network/modules.py
deleted file mode 100644
index 58d4ee4eca91fc4317a048524ef42fd47b03fc47..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/modules.py
+++ /dev/null
@@ -1,627 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Haiku modules for the Diffuser model."""
-
-from collections.abc import Sequence
-from typing import Literal
-
-from alphafold3.common import base_config
-from alphafold3.jax.attention import attention
-from alphafold3.jax.gated_linear_unit import gated_linear_unit
-from alphafold3.model import model_config
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.components import mapping
-from alphafold3.model.network import diffusion_transformer
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-def get_shard_size(
-    num_residues: int, shard_spec: Sequence[tuple[int | None, int | None]]
-) -> int | None:
-  shard_size = shard_spec[0][-1]
-  for num_residues_upper_bound, num_residues_shard_size in shard_spec:
-    shard_size = num_residues_shard_size
-    if (
-        num_residues_upper_bound is None
-        or num_residues <= num_residues_upper_bound
-    ):
-      break
-  return shard_size
-
-
-class TransitionBlock(hk.Module):
-  """Transition block for transformer."""
-
-  class Config(base_config.BaseConfig):
-    num_intermediate_factor: int = 4
-    use_glu_kernel: bool = True
-
-  def __init__(
-      self, config: Config, global_config: model_config.GlobalConfig, *, name
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(self, act, broadcast_dim=0):
-    num_channels = act.shape[-1]
-
-    num_intermediate = int(num_channels * self.config.num_intermediate_factor)
-
-    act = hm.LayerNorm(name='input_layer_norm')(act)
-
-    if self.config.use_glu_kernel:
-      weights, _ = hm.haiku_linear_get_params(
-          act,
-          num_output=num_intermediate * 2,
-          initializer='relu',
-          name='transition1',
-      )
-      weights = jnp.reshape(weights, (len(weights), 2, num_intermediate))
-      c = gated_linear_unit.gated_linear_unit(
-          x=act, weight=weights, implementation=None, activation=jax.nn.swish
-      )
-    else:
-      act = hm.Linear(
-          num_intermediate * 2, initializer='relu', name='transition1'
-      )(act)
-      a, b = jnp.split(act, 2, axis=-1)
-      c = jax.nn.swish(a) * b
-
-    return hm.Linear(
-        num_channels,
-        initializer=self.global_config.final_init,
-        name='transition2',
-    )(c)
-
-
-class MSAAttention(hk.Module):
-  """MSA Attention."""
-
-  class Config(base_config.BaseConfig):
-    num_head: int = 8
-
-  def __init__(
-      self, config: Config, global_config: model_config.GlobalConfig, *, name
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(self, act, mask, pair_act):
-    act = hm.LayerNorm(name='act_norm')(act)
-    pair_act = hm.LayerNorm(name='pair_norm')(pair_act)
-    logits = hm.Linear(
-        self.config.num_head, use_bias=False, name='pair_logits'
-    )(pair_act)
-    logits = jnp.transpose(logits, [2, 0, 1])
-    logits += 1e9 * (jnp.max(mask, axis=0) - 1.0)
-    weights = jax.nn.softmax(logits, axis=-1)
-    num_channels = act.shape[-1]
-    value_dim = num_channels // self.config.num_head
-    v = hm.Linear(
-        [self.config.num_head, value_dim], use_bias=False, name='v_projection'
-    )(act)
-    v_avg = jnp.einsum('hqk, bkhc -> bqhc', weights, v)
-    v_avg = jnp.reshape(v_avg, v_avg.shape[:-2] + (-1,))
-    gate_values = hm.Linear(
-        self.config.num_head * value_dim,
-        bias_init=1.0,
-        initializer='zeros',
-        name='gating_query',
-    )(act)
-    v_avg *= jax.nn.sigmoid(gate_values)
-
-    return hm.Linear(
-        num_channels,
-        initializer=self.global_config.final_init,
-        name='output_projection',
-    )(v_avg)
-
-
-class GridSelfAttention(hk.Module):
-  """Self attention that is either per-sequence or per-residue."""
-
-  class Config(base_config.BaseConfig):
-    num_head: int = 4
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      transpose: bool,
-      *,
-      name: str,
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-    self.transpose = transpose
-
-  @hk.transparent
-  def _attention(self, act, mask, bias):
-    num_channels = act.shape[-1]
-    assert num_channels % self.config.num_head == 0
-    # Triton requires a minimum dimension of 16 for doing matmul.
-    qkv_dim = max(num_channels // self.config.num_head, 16)
-
-    qkv_shape = (self.config.num_head, qkv_dim)
-    q = hm.Linear(
-        qkv_shape, use_bias=False, name='q_projection', transpose_weights=True
-    )(act)
-    k = hm.Linear(
-        qkv_shape, use_bias=False, name='k_projection', transpose_weights=True
-    )(act)
-    v = hm.Linear(qkv_shape, use_bias=False, name='v_projection')(act)
-
-    # Dot product attention requires the bias term to have a batch dimension.
-    bias = jnp.expand_dims(bias, 0)
-
-    weighted_avg = attention.dot_product_attention(
-        q,
-        k,
-        v,
-        mask=mask,
-        bias=bias,
-        implementation=self.global_config.flash_attention_implementation,
-    )
-    weighted_avg = jnp.reshape(weighted_avg, weighted_avg.shape[:-2] + (-1,))
-
-    gate_values = hm.Linear(
-        self.config.num_head * qkv_dim,
-        bias_init=1.0,
-        initializer='zeros',
-        transpose_weights=True,
-        name='gating_query',
-    )(act)
-    weighted_avg *= jax.nn.sigmoid(gate_values)
-
-    return hm.Linear(
-        num_channels,
-        initializer=self.global_config.final_init,
-        name='output_projection',
-    )(weighted_avg)
-
-  def __call__(self, act, pair_mask):
-    """Builds a module.
-
-    Arguments:
-      act: [num_seq, num_res, channels] activations tensor
-      pair_mask: [num_seq, num_res] mask of non-padded regions in the tensor.
-        Only used in inducing points attention currently.
-
-    Returns:
-      Result of the self-attention operation.
-    """
-    assert len(act.shape) == 3
-    assert len(pair_mask.shape) == 2
-
-    pair_mask = jnp.swapaxes(pair_mask, -1, -2)
-    act = hm.LayerNorm(name='act_norm')(act)
-
-    nonbatched_bias = hm.Linear(
-        self.config.num_head, use_bias=False, name='pair_bias_projection'
-    )(act)
-    nonbatched_bias = jnp.transpose(nonbatched_bias, [2, 0, 1])
-
-    num_residues = act.shape[0]
-
-    chunk_size = get_shard_size(
-        num_residues, self.global_config.pair_attention_chunk_size
-    )
-
-    if self.transpose:
-      act = jnp.swapaxes(act, -2, -3)
-
-    pair_mask = pair_mask[:, None, None, :].astype(jnp.bool_)
-
-    act = mapping.inference_subbatch(
-        self._attention,
-        chunk_size,
-        batched_args=[act, pair_mask],
-        nonbatched_args=[nonbatched_bias],
-        input_subbatch_dim_is_partitioned=False,
-    )
-
-    if self.transpose:
-      act = jnp.swapaxes(act, -2, -3)
-
-    return act
-
-
-class TriangleMultiplication(hk.Module):
-  """Triangle Multiplication."""
-
-  class Config(base_config.BaseConfig):
-    equation: Literal['ikc,jkc->ijc', 'kjc,kic->ijc']
-    use_glu_kernel: bool = True
-
-  def __init__(
-      self, config: Config, global_config: model_config.GlobalConfig, *, name
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(self, act, mask):
-    """Applies Module.
-
-    Args:
-      act: The activation.
-      mask: The mask.
-
-    Returns:
-      Outputs, should have same shape/type as output_act
-    """
-    mask = mask[None, ...]
-    num_channels = act.shape[-1]
-    equation = {
-        'ikc,jkc->ijc': 'cik,cjk->cij',
-        'kjc,kic->ijc': 'ckj,cki->cij',
-    }[self.config.equation]
-
-    act = hm.LayerNorm(name='left_norm_input')(act)
-    input_act = act
-
-    if self.config.use_glu_kernel:
-      weights_projection, _ = hm.haiku_linear_get_params(
-          act, num_output=num_channels * 2, name='projection'
-      )
-      weights_gate, _ = hm.haiku_linear_get_params(
-          act,
-          num_output=num_channels * 2,
-          initializer=self.global_config.final_init,
-          name='gate',
-      )
-      weights_glu = jnp.stack([weights_gate, weights_projection], axis=1)
-
-      projection = gated_linear_unit.gated_linear_unit(
-          x=act,
-          weight=weights_glu,
-          activation=jax.nn.sigmoid,
-          implementation=None,
-      )
-      projection = jnp.transpose(projection, (2, 0, 1))
-      projection *= mask
-    else:
-      projection = hm.Linear(num_channels * 2, name='projection')(act)
-      projection = jnp.transpose(projection, (2, 0, 1))
-      projection *= mask
-
-      gate = hm.Linear(
-          num_channels * 2,
-          name='gate',
-          bias_init=1.0,
-          initializer=self.global_config.final_init,
-      )(act)
-      gate = jnp.transpose(gate, (2, 0, 1))
-      projection *= jax.nn.sigmoid(gate)
-
-    projection = projection.reshape(num_channels, 2, *projection.shape[1:])
-    a, b = jnp.split(projection, 2, axis=1)
-    a, b = jnp.squeeze(a, axis=1), jnp.squeeze(b, axis=1)
-    act = jnp.einsum(equation, a, b)
-    act = hm.LayerNorm(name='center_norm', axis=0, param_axis=0)(act)
-
-    act = jnp.transpose(act, (1, 2, 0))
-    act = hm.Linear(
-        num_channels,
-        initializer=self.global_config.final_init,
-        name='output_projection',
-    )(act)
-
-    gate_out = hm.Linear(
-        num_channels,
-        name='gating_linear',
-        bias_init=1.0,
-        initializer=self.global_config.final_init,
-    )(input_act)
-    act *= jax.nn.sigmoid(gate_out)
-
-    return act
-
-
-class OuterProductMean(hk.Module):
-  """Computed mean outer product."""
-
-  class Config(base_config.BaseConfig):
-    chunk_size: int = 128
-    num_outer_channel: int = 32
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      num_output_channel,
-      *,
-      name,
-  ):
-    super().__init__(name=name)
-    self.global_config = global_config
-    self.config = config
-    self.num_output_channel = num_output_channel
-
-  def __call__(self, act, mask):
-    mask = mask[..., None]
-    act = hm.LayerNorm(name='layer_norm_input')(act)
-
-    left_act = mask * hm.Linear(
-        self.config.num_outer_channel,
-        initializer='linear',
-        name='left_projection',
-    )(act)
-
-    right_act = mask * hm.Linear(
-        self.config.num_outer_channel,
-        initializer='linear',
-        name='right_projection',
-    )(act)
-
-    if self.global_config.final_init == 'zeros':
-      w_init = hk.initializers.Constant(0.0)
-    else:
-      w_init = hk.initializers.VarianceScaling(scale=2.0, mode='fan_in')
-
-    output_w = hk.get_parameter(
-        'output_w',
-        shape=(
-            self.config.num_outer_channel,
-            self.config.num_outer_channel,
-            self.num_output_channel,
-        ),
-        dtype=act.dtype,
-        init=w_init,
-    )
-    output_b = hk.get_parameter(
-        'output_b',
-        shape=(self.num_output_channel,),
-        dtype=act.dtype,
-        init=hk.initializers.Constant(0.0),
-    )
-
-    def compute_chunk(left_act):
-      # Make sure that the 'b' dimension is the most minor batch like dimension
-      # so it will be treated as the real batch by XLA (both during the forward
-      # and the backward pass)
-      left_act = jnp.transpose(left_act, [0, 2, 1])
-      act = jnp.einsum('acb,ade->dceb', left_act, right_act)
-      act = jnp.einsum('dceb,cef->dbf', act, output_w) + output_b
-      return jnp.transpose(act, [1, 0, 2])
-
-    act = mapping.inference_subbatch(
-        compute_chunk,
-        self.config.chunk_size,
-        batched_args=[left_act],
-        nonbatched_args=[],
-        input_subbatch_dim=1,
-        output_subbatch_dim=0,
-        input_subbatch_dim_is_partitioned=False,
-    )
-
-    epsilon = 1e-3
-    norm = jnp.einsum('abc,adc->bdc', mask, mask)
-    return act / (epsilon + norm)
-
-
-class PairFormerIteration(hk.Module):
-  """Single Iteration of Pair Former."""
-
-  class Config(base_config.BaseConfig):
-    """Config for PairFormerIteration."""
-
-    num_layer: int
-    pair_attention: GridSelfAttention.Config = base_config.autocreate()
-    pair_transition: TransitionBlock.Config = base_config.autocreate()
-    single_attention: diffusion_transformer.SelfAttentionConfig | None = None
-    single_transition: TransitionBlock.Config | None = None
-    triangle_multiplication_incoming: TriangleMultiplication.Config = (
-        base_config.autocreate(equation='kjc,kic->ijc')
-    )
-    triangle_multiplication_outgoing: TriangleMultiplication.Config = (
-        base_config.autocreate(equation='ikc,jkc->ijc')
-    )
-    shard_transition_blocks: bool = True
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      with_single=False,
-      *,
-      name,
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-    self.with_single = with_single
-
-  def __call__(
-      self,
-      act,
-      pair_mask,
-      single_act=None,
-      seq_mask=None,
-  ):
-    """Build a single iteration of the pair former.
-
-    Args:
-      act: [num_res, num_res, num_channel] Input pairwise activations.
-      pair_mask: [num_res, num_res] padding mask.
-      single_act: [num_res, single_channel] Single Input activations, optional
-      seq_mask: [num_res] Sequence Mask, optional.
-
-    Returns:
-      [num_res, num_res, num_channel] tensor of activations.
-    """
-
-    num_residues = act.shape[0]
-
-    act += TriangleMultiplication(
-        self.config.triangle_multiplication_outgoing,
-        self.global_config,
-        name='triangle_multiplication_outgoing',
-    )(act, pair_mask)
-
-    act += TriangleMultiplication(
-        self.config.triangle_multiplication_incoming,
-        self.global_config,
-        name='triangle_multiplication_incoming',
-    )(act, pair_mask)
-
-    act += GridSelfAttention(
-        self.config.pair_attention,
-        self.global_config,
-        name='pair_attention1',
-        transpose=False,
-    )(act, pair_mask)
-
-    act += GridSelfAttention(
-        self.config.pair_attention,
-        self.global_config,
-        name='pair_attention2',
-        transpose=True,
-    )(act, pair_mask)
-
-    transition_block = TransitionBlock(
-        self.config.pair_transition, self.global_config, name='pair_transition'
-    )
-    if self.config.shard_transition_blocks:
-      transition_block = mapping.sharded_apply(
-          transition_block,
-          get_shard_size(
-              num_residues, self.global_config.pair_transition_shard_spec
-          ),
-      )
-    act += transition_block(act)
-
-    if self.with_single:
-      assert self.config.single_attention is not None
-      pair_logits = hm.Linear(
-          self.config.single_attention.num_head,
-          name='single_pair_logits_projection',
-      )(hm.LayerNorm(name='single_pair_logits_norm')(act))
-
-      pair_logits = jnp.transpose(pair_logits, [2, 0, 1])
-
-      single_act += diffusion_transformer.self_attention(
-          single_act,
-          seq_mask,
-          pair_logits=pair_logits,
-          config=self.config.single_attention,
-          global_config=self.global_config,
-          name='single_attention_',
-      )
-
-      single_act += TransitionBlock(
-          self.config.single_transition,
-          self.global_config,
-          name='single_transition',
-      )(single_act, broadcast_dim=None)
-
-      return act, single_act
-    else:
-      return act
-
-
-class EvoformerIteration(hk.Module):
-  """Single Iteration of Evoformer Main Stack."""
-
-  class Config(base_config.BaseConfig):
-    """Configuration for EvoformerIteration."""
-
-    num_layer: int = 4
-    msa_attention: MSAAttention.Config = base_config.autocreate()
-    outer_product_mean: OuterProductMean.Config = base_config.autocreate()
-    msa_transition: TransitionBlock.Config = base_config.autocreate()
-    pair_attention: GridSelfAttention.Config = base_config.autocreate()
-    pair_transition: TransitionBlock.Config = base_config.autocreate()
-    triangle_multiplication_incoming: TriangleMultiplication.Config = (
-        base_config.autocreate(equation='kjc,kic->ijc')
-    )
-    triangle_multiplication_outgoing: TriangleMultiplication.Config = (
-        base_config.autocreate(equation='ikc,jkc->ijc')
-    )
-    shard_transition_blocks: bool = True
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='evoformer_iteration',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(self, activations, masks):
-
-    msa_act, pair_act = activations['msa'], activations['pair']
-
-    num_residues = pair_act.shape[0]
-
-    msa_mask, pair_mask = masks['msa'], masks['pair']
-
-    pair_act += OuterProductMean(
-        config=self.config.outer_product_mean,
-        global_config=self.global_config,
-        num_output_channel=int(pair_act.shape[-1]),
-        name='outer_product_mean',
-    )(msa_act, msa_mask)
-
-    msa_act += MSAAttention(
-        self.config.msa_attention, self.global_config, name='msa_attention1'
-    )(msa_act, msa_mask, pair_act=pair_act)
-
-    msa_act += TransitionBlock(
-        self.config.msa_transition, self.global_config, name='msa_transition'
-    )(msa_act)
-
-    pair_act += TriangleMultiplication(
-        self.config.triangle_multiplication_outgoing,
-        self.global_config,
-        name='triangle_multiplication_outgoing',
-    )(pair_act, pair_mask)
-
-    pair_act += TriangleMultiplication(
-        self.config.triangle_multiplication_incoming,
-        self.global_config,
-        name='triangle_multiplication_incoming',
-    )(pair_act, pair_mask)
-
-    pair_act += GridSelfAttention(
-        self.config.pair_attention,
-        self.global_config,
-        name='pair_attention1',
-        transpose=False,
-    )(pair_act, pair_mask)
-
-    pair_act += GridSelfAttention(
-        self.config.pair_attention,
-        self.global_config,
-        name='pair_attention2',
-        transpose=True,
-    )(pair_act, pair_mask)
-
-    transition_block = TransitionBlock(
-        self.config.pair_transition, self.global_config, name='pair_transition'
-    )
-    if self.config.shard_transition_blocks:
-      transition_block = mapping.sharded_apply(
-          transition_block,
-          get_shard_size(
-              num_residues, self.global_config.pair_transition_shard_spec
-          ),
-      )
-    pair_act += transition_block(pair_act)
-
-    return {'msa': msa_act, 'pair': pair_act}
diff --git a/src/alphafold3/model/network/noise_level_embeddings.py b/src/alphafold3/model/network/noise_level_embeddings.py
deleted file mode 100644
index dc0381fabd7ddb7a024c052858e02640d3ee26e1..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/noise_level_embeddings.py
+++ /dev/null
@@ -1,141 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Fourier embeddings for given noise levels.
-
-We supply fixed weights and biases for the Fourier embeddings. These were
-initially generated by the following code, but we make them into constants
-to future proof against changes in jax rng generation:
-
-```
-dim = 256
-w_key, b_key = jax.random.split(jax.random.PRNGKey(42))
-weight = jax.random.normal(w_key, shape=[dim])
-bias = jax.random.uniform(b_key, shape=[dim])
-```
-"""
-
-import jax.numpy as jnp
-
-# pyformat: disable
-# pylint: disable=bad-whitespace
-# pylint: disable=bad-continuation
-_WEIGHT = [
-     0.45873642,  0.06516238, -0.07278306, -0.26992258,  0.64292115,
-    -0.40763968,  3.60116863,  0.54461384, -0.32644904,  2.10888267,
-     1.30805349,  1.19838560, -1.37745857,  1.99475312, -1.64120293,
-     1.07823789, -0.02288206,  0.88305283,  0.48099944,  0.17655374,
-     0.30281949,  0.80646873,  0.62605333, -0.23965347, -1.02609432,
-     0.75006109, -0.19913037,  0.07466396,  0.66431236, -0.60990530,
-    -0.69709194, -0.44453633, -1.77656078,  0.02299878,  0.04095552,
-     0.35485864, -0.47602659, -0.98820388, -0.24106771, -1.07254291,
-    -0.99741757,  0.22697604,  1.41390419,  1.54984057, -0.12237291,
-     0.20156337,  0.61767143,  0.23959029,  0.92454034,  1.84082258,
-     0.89030224,  0.39598912, -1.52224910,  0.29669049,  1.52356744,
-    -0.33968377,  0.24155144, -0.52308381, -0.23622665,  0.92825454,
-    -0.63864607, -0.62169307,  0.78623551, -0.80352145, -0.45496067,
-     1.30877995, -0.06686528,  1.00248849, -0.63593471,  0.16372502,
-    -1.46133232,  1.10562658, -0.01693927,  0.28684548, -0.72843230,
-     0.66133535, -1.92225552,  0.70241231, -0.96868867, -0.47309339,
-    -1.66894221,  0.46018723, -0.56806105,  0.32694784, -0.46529883,
-     1.02299964,  0.84688205,  1.19581807, -1.82454145,  0.05999713,
-    -0.59530073,  1.44862521, -0.34933713, -0.46564487, -0.55005538,
-    -1.61170268,  0.17502306,  0.38670063, -1.12133658, -0.29343036,
-    -0.52527446, -1.26285112,  1.07982683,  0.51215219,  1.48963666,
-     1.09847653, -0.01563358,  0.32574457,  1.94779706, -1.29198587,
-     1.06249654, -0.86965990,  0.22975266, -0.27182648, -0.21130897,
-    -0.41773933, -0.02329035,  1.31049252,  0.05579265, -1.23127055,
-    -0.99691105,  0.27058721, -0.72509319, -0.14421797, -1.48605061,
-     1.35041201,  1.29619241, -1.01022530, -0.79787987, -0.16166858,
-     0.87210685,  1.69248152,  1.42469788, -0.72325104, -1.24823737,
-     0.07051118,  0.71332991, -0.07360429, -0.91955227, -2.68856549,
-    -0.44033936,  0.35482934, -0.57933813,  0.97468042, -0.31050494,
-    -0.88454425, -2.08785224,  0.47322822, -0.02400172,  0.26644820,
-    -0.19147627, -2.10538960, -1.27962470, -1.35999286,  2.09867334,
-     0.65099514,  0.21604492, -0.45951018,  0.15994427, -0.31420693,
-    -0.65202618, -0.61077976, -1.06100249, -1.47254968,  1.18165290,
-    -0.78656220,  1.28182006,  1.80323684,  1.09196901,  0.26118696,
-    -0.30168581,  0.39749333,  0.26812574, -1.51995814, -0.46909946,
-     0.03874255, -1.36774313,  2.30143976,  2.06959820, -0.41647521,
-     1.85624206,  0.49019700, -0.06726539,  0.00457313,  0.23915423,
-    -1.84971249, -0.20482327, -0.34097880, -0.57933033, -1.10541213,
-    -0.30269983, -0.16430426, -0.82371718,  0.10345812,  1.78753936,
-     0.04786763,  1.86778629, -0.65214992,  0.81544143, -0.28214937,
-     0.31187257,  0.57661986,  1.21938801, -1.56046617,  0.38046429,
-    -0.18235965,  0.81794524, -0.40474343,  0.46538028, -1.15558851,
-     0.59625793, -1.07801270,  0.07310858,  0.61526084,  0.55518496,
-    -0.49787554,  0.92703879, -1.27780271, -0.83373469, -0.43015575,
-     0.41877759, -1.03987372, -1.46055734,  0.61282396,  0.15590595,
-    -0.34269521,  0.56509072, -1.17904210,  0.11374855, -1.83310866,
-     0.38734794, -0.58623004,  0.77931106,  1.53930688, -0.70299625,
-    -0.11389336, -1.14818096, -0.44400632,  1.21887410,  0.64066756,
-    -0.70249403, -0.27244881,  0.38586098, -1.07925785,  0.12448707,
-    -1.28286278,  0.37827531,  0.68812364,  1.65695465,  0.12440517,
-    -0.03689830,  1.10224664, -0.28323629, -0.47939169,  0.70120829,
-    -0.67204583
-]
-
-_BIAS = [
-    0.00465965, 0.21738243, 0.22277749, 0.68463874, 0.84596848, 0.17337036,
-    0.39573753, 0.78153563, 0.86311185, 0.21782327, 0.24377882, 0.42310703,
-    0.19887352, 0.10486019, 0.48707581, 0.22205460, 0.97263455, 0.29714966,
-    0.11244559, 0.53020525, 0.36796236, 0.37294638, 0.80261672, 0.04669094,
-    0.86319661, 0.75907171, 0.77297020, 0.01114798, 0.55850804, 0.91799915,
-    0.23032320, 0.12154722, 0.26701927, 0.42934716, 0.47951782, 0.96782577,
-    0.86785042, 0.61985648, 0.05743814, 0.41800117, 0.68881893, 0.60575199,
-    0.21058667, 0.64412105, 0.63958526, 0.89390790, 0.69755554, 0.89345169,
-    0.53330755, 0.56985939, 0.30724049, 0.00984561, 0.91407037, 0.92118979,
-    0.94153070, 0.81097460, 0.70537627, 0.32810748, 0.47227263, 0.11821401,
-    0.44983089, 0.30767226, 0.31756389, 0.62969446, 0.69892538, 0.16949117,
-    0.06207097, 0.46717727, 0.95348179, 0.62363589, 0.49018729, 0.06920040,
-    0.39333904, 0.41299903, 0.52514863, 0.61197245, 0.56871891, 0.65053988,
-    0.22203422, 0.46748531, 0.86931503, 0.87050021, 0.40208721, 0.32084906,
-    0.55084610, 0.94584596, 0.76279902, 0.36250532, 0.74272907, 0.66682065,
-    0.96452832, 0.64768302, 0.88070846, 0.56995463, 0.06395614, 0.69499350,
-    0.44494808, 0.39775658, 0.20280898, 0.33363521, 0.05999005, 0.44414878,
-    0.65227020, 0.01199079, 0.71995056, 0.19045687, 0.48342144, 0.25127733,
-    0.66515994, 0.22465158, 0.22313106, 0.06302810, 0.55783665, 0.93625581,
-    0.58800840, 0.72525370, 0.52879298, 0.77195418, 0.15548682, 0.01028740,
-    0.39325142, 0.45401239, 0.71494079, 0.33011997, 0.05050695, 0.26381660,
-    0.63064706, 0.47604024, 0.08593416, 0.00383425, 0.06352687, 0.05510247,
-    0.03552997, 0.35810637, 0.56094289, 0.60922170, 0.88599777, 0.45419788,
-    0.40486634, 0.71297824, 0.34976673, 0.97825217, 0.12915993, 0.09566259,
-    0.64318919, 0.16717327, 0.82308614, 0.32672071, 0.81688786, 0.84857118,
-    0.99922776, 0.07551706, 0.18766022, 0.13051236, 0.39136350, 0.08768725,
-    0.92048228, 0.87185788, 0.39158428, 0.79224777, 0.17492688, 0.68902445,
-    0.81980729, 0.70458186, 0.59489477, 0.93324888, 0.49986637, 0.40705478,
-    0.89202917, 0.20673239, 0.39339757, 0.20996964, 0.02923799, 0.53992438,
-    0.40119815, 0.10366607, 0.08044600, 0.95551598, 0.20518017, 0.68826210,
-    0.90159297, 0.69008791, 0.86880815, 0.16246438, 0.89628279, 0.11481643,
-    0.61353648, 0.41545081, 0.92478311, 0.78212476, 0.48292696, 0.79621077,
-    0.11947489, 0.01747024, 0.22928023, 0.87387264, 0.86349785, 0.89526737,
-    0.58904779, 0.13896775, 0.68194926, 0.55824125, 0.44428205, 0.55422378,
-    0.28189969, 0.27923775, 0.09979951, 0.66994715, 0.45943546, 0.71207762,
-    0.17300689, 0.83434916, 0.02573085, 0.45858085, 0.55934799, 0.30676675,
-    0.52219367, 0.34544575, 0.19280875, 0.26937950, 0.07147646, 0.06295013,
-    0.76382887, 0.38737607, 0.58825982, 0.17423475, 0.05509448, 0.97228825,
-    0.94380617, 0.91664016, 0.18800116, 0.41771865, 0.59420645, 0.77371931,
-    0.64687788, 0.27284670, 0.22310913, 0.15663862, 0.45573199, 0.50386798,
-    0.66712272, 0.71649647, 0.28475654, 0.83415413, 0.75261366, 0.61517799,
-    0.93544555, 0.76141870, 0.85474241, 0.74766934, 0.33459592, 0.78477907,
-    0.07250881, 0.10174239, 0.95332730, 0.80793905
-]
-# pyformat: enable
-# pylint: enable=bad-whitespace
-# pylint: enable=bad-continuation
-
-
-def noise_embeddings(sigma_scaled_noise_level: jnp.ndarray) -> jnp.ndarray:
-  """Returns Fourier noise level embeddings for diffusion model."""
-  transformed_noise_level = (1 / 4) * jnp.log(sigma_scaled_noise_level)
-  weight = jnp.array(_WEIGHT, dtype=jnp.float32)
-  bias = jnp.array(_BIAS, dtype=jnp.float32)
-  embeddings = transformed_noise_level[..., None] * weight + bias
-  return jnp.cos(2 * jnp.pi * embeddings)
diff --git a/src/alphafold3/model/network/template_modules.py b/src/alphafold3/model/network/template_modules.py
deleted file mode 100644
index 64a0d76788f5eac257df2c4ce5c5373dd01caa4b..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/network/template_modules.py
+++ /dev/null
@@ -1,351 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Modules for embedding templates."""
-
-from alphafold3.common import base_config
-from alphafold3.constants import residue_names
-from alphafold3.jax import geometry
-from alphafold3.model import features
-from alphafold3.model import model_config
-from alphafold3.model import protein_data_processing
-from alphafold3.model.components import haiku_modules as hm
-from alphafold3.model.network import modules
-from alphafold3.model.scoring import scoring
-import haiku as hk
-import jax
-import jax.numpy as jnp
-
-
-class DistogramFeaturesConfig(base_config.BaseConfig):
-  # The left edge of the first bin.
-  min_bin: float = 3.25
-  # The left edge of the final bin. The final bin catches everything larger than
-  # `max_bin`.
-  max_bin: float = 50.75
-  # The number of bins in the distogram.
-  num_bins: int = 39
-
-
-def dgram_from_positions(positions, config: DistogramFeaturesConfig):
-  """Compute distogram from amino acid positions.
-
-  Args:
-    positions: (num_res, 3) Position coordinates.
-    config: Distogram bin configuration.
-
-  Returns:
-    Distogram with the specified number of bins.
-  """
-  lower_breaks = jnp.linspace(config.min_bin, config.max_bin, config.num_bins)
-  lower_breaks = jnp.square(lower_breaks)
-  upper_breaks = jnp.concatenate(
-      [lower_breaks[1:], jnp.array([1e8], dtype=jnp.float32)], axis=-1
-  )
-  dist2 = jnp.sum(
-      jnp.square(
-          jnp.expand_dims(positions, axis=-2)
-          - jnp.expand_dims(positions, axis=-3)
-      ),
-      axis=-1,
-      keepdims=True,
-  )
-
-  dgram = (dist2 > lower_breaks).astype(jnp.float32) * (
-      dist2 < upper_breaks
-  ).astype(jnp.float32)
-  return dgram
-
-
-def make_backbone_rigid(
-    positions: geometry.Vec3Array,
-    mask: jnp.ndarray,
-    group_indices: jnp.ndarray,
-) -> tuple[geometry.Rigid3Array, jnp.ndarray]:
-  """Make backbone Rigid3Array and mask.
-
-  Args:
-    positions: (num_res, num_atoms) of atom positions as Vec3Array.
-    mask: (num_res, num_atoms) for atom mask.
-    group_indices: (num_res, num_group, 3) for atom indices forming groups.
-
-  Returns:
-    tuple of backbone Rigid3Array and mask (num_res,).
-  """
-  backbone_indices = group_indices[:, 0]
-
-  # main backbone frames differ in sidechain frame convention.
-  # for sidechain it's (C, CA, N), for backbone it's (N, CA, C)
-  # Hence using c, b, a, each of shape (num_res,).
-  c, b, a = [backbone_indices[..., i] for i in range(3)]
-
-  slice_index = jax.vmap(lambda x, i: x[i])
-  rigid_mask = (
-      slice_index(mask, a) * slice_index(mask, b) * slice_index(mask, c)
-  ).astype(jnp.float32)
-
-  frame_positions = []
-  for indices in [a, b, c]:
-    frame_positions.append(
-        jax.tree.map(lambda x, idx=indices: slice_index(x, idx), positions)
-    )
-
-  rotation = geometry.Rot3Array.from_two_vectors(
-      frame_positions[2] - frame_positions[1],
-      frame_positions[0] - frame_positions[1],
-  )
-  rigid = geometry.Rigid3Array(rotation, frame_positions[1])
-
-  return rigid, rigid_mask
-
-
-class TemplateEmbedding(hk.Module):
-  """Embed a set of templates."""
-
-  class Config(base_config.BaseConfig):
-    num_channels: int = 64
-    template_stack: modules.PairFormerIteration.Config = base_config.autocreate(
-        num_layer=2,
-        pair_transition=base_config.autocreate(num_intermediate_factor=2),
-    )
-    dgram_features: DistogramFeaturesConfig = base_config.autocreate()
-
-  def __init__(
-      self,
-      config: Config,
-      global_config: model_config.GlobalConfig,
-      name='template_embedding',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      query_embedding: jnp.ndarray,
-      templates: features.Templates,
-      padding_mask_2d: jnp.ndarray,
-      multichain_mask_2d: jnp.ndarray,
-      key: jnp.ndarray,
-  ) -> jnp.ndarray:
-    """Generate an embedding for a set of templates.
-
-    Args:
-      query_embedding: [num_res, num_res, num_channel] a query tensor that will
-        be used to attend over the templates to remove the num_templates
-        dimension.
-      templates: A 'Templates' object.
-      padding_mask_2d: [num_res, num_res] Pair mask for attention operations.
-      multichain_mask_2d: [num_res, num_res] Pair mask for multichain.
-      key: random key generator.
-
-    Returns:
-      An embedding of size [num_res, num_res, num_channels]
-    """
-    c = self.config
-    num_residues = query_embedding.shape[0]
-    num_templates = templates.aatype.shape[0]
-    query_num_channels = query_embedding.shape[2]
-    num_atoms = 24
-    assert query_embedding.shape == (
-        num_residues,
-        num_residues,
-        query_num_channels,
-    )
-    assert templates.aatype.shape == (num_templates, num_residues)
-    assert templates.atom_positions.shape == (
-        num_templates,
-        num_residues,
-        num_atoms,
-        3,
-    )
-    assert templates.atom_mask.shape == (num_templates, num_residues, num_atoms)
-    assert padding_mask_2d.shape == (num_residues, num_residues)
-
-    num_templates = templates.aatype.shape[0]
-    num_res, _, query_num_channels = query_embedding.shape
-
-    # Embed each template separately.
-    template_embedder = SingleTemplateEmbedding(self.config, self.global_config)
-
-    subkeys = jnp.array(jax.random.split(key, num_templates))
-
-    def scan_fn(carry, x):
-      templates, key = x
-      embedding = template_embedder(
-          query_embedding,
-          templates,
-          padding_mask_2d,
-          multichain_mask_2d,
-          key,
-      )
-      return carry + embedding, None
-
-    scan_init = jnp.zeros(
-        (num_res, num_res, c.num_channels), dtype=query_embedding.dtype
-    )
-    summed_template_embeddings, _ = hk.scan(
-        scan_fn, scan_init, (templates, subkeys)
-    )
-
-    embedding = summed_template_embeddings / (1e-7 + num_templates)
-    embedding = jax.nn.relu(embedding)
-    embedding = hm.Linear(
-        query_num_channels, initializer='relu', name='output_linear'
-    )(embedding)
-
-    assert embedding.shape == (num_residues, num_residues, query_num_channels)
-    return embedding
-
-
-class SingleTemplateEmbedding(hk.Module):
-  """Embed a single template."""
-
-  def __init__(
-      self,
-      config: TemplateEmbedding.Config,
-      global_config: model_config.GlobalConfig,
-      name='single_template_embedding',
-  ):
-    super().__init__(name=name)
-    self.config = config
-    self.global_config = global_config
-
-  def __call__(
-      self,
-      query_embedding: jnp.ndarray,
-      templates: features.Templates,
-      padding_mask_2d: jnp.ndarray,
-      multichain_mask_2d: jnp.ndarray,
-      key: jnp.ndarray,
-  ) -> jnp.ndarray:
-    """Build the single template embedding graph.
-
-    Args:
-      query_embedding: (num_res, num_res, num_channels) - embedding of the query
-        sequence/msa.
-      templates: 'Templates' object containing single Template.
-      padding_mask_2d: Padding mask (Note: this doesn't care if a template
-        exists, unlike the template_pseudo_beta_mask).
-      multichain_mask_2d: A mask indicating intra-chain residue pairs, used to
-        mask out between chain distances/features when templates are for single
-        chains.
-      key: Random key generator.
-
-    Returns:
-      A template embedding (num_res, num_res, num_channels).
-    """
-    gc = self.global_config
-    c = self.config
-    assert padding_mask_2d.dtype == query_embedding.dtype
-    dtype = query_embedding.dtype
-    num_channels = self.config.num_channels
-
-    def construct_input(
-        query_embedding, templates: features.Templates, multichain_mask_2d
-    ):
-
-      # Compute distogram feature for the template.
-      aatype = templates.aatype
-      dense_atom_mask = templates.atom_mask
-
-      dense_atom_positions = templates.atom_positions
-      dense_atom_positions *= dense_atom_mask[..., None]
-
-      pseudo_beta_positions, pseudo_beta_mask = scoring.pseudo_beta_fn(
-          templates.aatype, dense_atom_positions, dense_atom_mask
-      )
-      pseudo_beta_mask_2d = (
-          pseudo_beta_mask[:, None] * pseudo_beta_mask[None, :]
-      )
-      pseudo_beta_mask_2d *= multichain_mask_2d
-      dgram = dgram_from_positions(
-          pseudo_beta_positions, self.config.dgram_features
-      )
-      dgram *= pseudo_beta_mask_2d[..., None]
-      dgram = dgram.astype(dtype)
-      pseudo_beta_mask_2d = pseudo_beta_mask_2d.astype(dtype)
-      to_concat = [(dgram, 1), (pseudo_beta_mask_2d, 0)]
-
-      aatype = jax.nn.one_hot(
-          aatype,
-          residue_names.POLYMER_TYPES_NUM_WITH_UNKNOWN_AND_GAP,
-          axis=-1,
-          dtype=dtype,
-      )
-      to_concat.append((aatype[None, :, :], 1))
-      to_concat.append((aatype[:, None, :], 1))
-
-      # Compute a feature representing the normalized vector between each
-      # backbone affine - i.e. in each residues local frame, what direction are
-      # each of the other residues.
-
-      template_group_indices = jnp.take(
-          protein_data_processing.RESTYPE_RIGIDGROUP_DENSE_ATOM_IDX,
-          templates.aatype,
-          axis=0,
-      )
-      rigid, backbone_mask = make_backbone_rigid(
-          geometry.Vec3Array.from_array(dense_atom_positions),
-          dense_atom_mask,
-          template_group_indices.astype(jnp.int32),
-      )
-      points = rigid.translation
-      rigid_vec = rigid[:, None].inverse().apply_to_point(points)
-      unit_vector = rigid_vec.normalized()
-      unit_vector = [unit_vector.x, unit_vector.y, unit_vector.z]
-
-      unit_vector = [x.astype(dtype) for x in unit_vector]
-      backbone_mask = backbone_mask.astype(dtype)
-
-      backbone_mask_2d = backbone_mask[:, None] * backbone_mask[None, :]
-      backbone_mask_2d *= multichain_mask_2d
-      unit_vector = [x * backbone_mask_2d for x in unit_vector]
-
-      # Note that the backbone_mask takes into account C, CA and N (unlike
-      # pseudo beta mask which just needs CB) so we add both masks as features.
-      to_concat.extend([(x, 0) for x in unit_vector])
-      to_concat.append((backbone_mask_2d, 0))
-
-      query_embedding = hm.LayerNorm(name='query_embedding_norm')(
-          query_embedding
-      )
-      # Allow the template embedder to see the query embedding.  Note this
-      # contains the position relative feature, so this is how the network knows
-      # which residues are next to each other.
-      to_concat.append((query_embedding, 1))
-
-      act = 0
-
-      for i, (x, n_input_dims) in enumerate(to_concat):
-        act += hm.Linear(
-            num_channels,
-            num_input_dims=n_input_dims,
-            initializer='relu',
-            name=f'template_pair_embedding_{i}',
-        )(x)
-      return act
-
-    act = construct_input(query_embedding, templates, multichain_mask_2d)
-
-    if c.template_stack.num_layer:
-
-      def template_iteration_fn(x):
-        return modules.PairFormerIteration(
-            c.template_stack, gc, name='template_embedding_iteration'
-        )(act=x, pair_mask=padding_mask_2d)
-
-      template_stack = hk.experimental.layer_stack(c.template_stack.num_layer)(
-          template_iteration_fn
-      )
-      act = template_stack(act)
-
-    act = hm.LayerNorm(name='output_layer_norm')(act)
-    return act
diff --git a/src/alphafold3/model/params.py b/src/alphafold3/model/params.py
deleted file mode 100644
index 2fa34070524b46f65600d1f238be2ddc2df4001c..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/params.py
+++ /dev/null
@@ -1,210 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Model param loading."""
-
-import bisect
-import collections
-from collections.abc import Iterator
-import contextlib
-import io
-import os
-import pathlib
-import re
-import struct
-import sys
-from typing import IO
-
-import haiku as hk
-import jax.numpy as jnp
-import numpy as np
-import zstandard
-
-
-class RecordError(Exception):
-  """Error reading a record."""
-
-
-def encode_record(scope: str, name: str, arr: np.ndarray) -> bytes:
-  """Encodes a single haiku param as bytes, preserving non-numpy dtypes."""
-  scope = scope.encode('utf-8')
-  name = name.encode('utf-8')
-  shape = arr.shape
-  dtype = str(arr.dtype).encode('utf-8')
-  arr = np.ascontiguousarray(arr)
-  if sys.byteorder == 'big':
-    arr = arr.byteswap()
-  arr_buffer = arr.tobytes('C')
-  header = struct.pack(
-      '<5i', len(scope), len(name), len(dtype), len(shape), len(arr_buffer)
-  )
-  return header + b''.join(
-      (scope, name, dtype, struct.pack(f'{len(shape)}i', *shape), arr_buffer)
-  )
-
-
-def _read_record(stream: IO[bytes]) -> tuple[str, str, np.ndarray] | None:
-  """Reads a record encoded by `_encode_record` from a byte stream."""
-  header_size = struct.calcsize('<5i')
-  header = stream.read(header_size)
-  if not header:
-    return None
-  if len(header) < header_size:
-    raise RecordError(f'Incomplete header: {len(header)=} < {header_size=}')
-  (scope_len, name_len, dtype_len, shape_len, arr_buffer_len) = struct.unpack(
-      '<5i', header
-  )
-  fmt = f'<{scope_len}s{name_len}s{dtype_len}s{shape_len}i'
-  payload_size = struct.calcsize(fmt) + arr_buffer_len
-  payload = stream.read(payload_size)
-  if len(payload) < payload_size:
-    raise RecordError(f'Incomplete payload: {len(payload)=} < {payload_size=}')
-  scope, name, dtype, *shape = struct.unpack_from(fmt, payload)
-  scope = scope.decode('utf-8')
-  name = name.decode('utf-8')
-  dtype = dtype.decode('utf-8')
-  arr = np.frombuffer(payload[-arr_buffer_len:], dtype=dtype)
-  arr = np.reshape(arr, shape)
-  if sys.byteorder == 'big':
-    arr = arr.byteswap()
-  return scope, name, arr
-
-
-def read_records(stream: IO[bytes]) -> Iterator[tuple[str, str, np.ndarray]]:
-  """Fully reads the contents of a byte stream."""
-  while record := _read_record(stream):
-    yield record
-
-
-class _MultiFileIO(io.RawIOBase):
-  """A file-like object that presents a concatenated view of multiple files."""
-
-  def __init__(self, files: list[pathlib.Path]):
-    self._files = files
-    self._stack = contextlib.ExitStack()
-    self._handles = [
-        self._stack.enter_context(file.open('rb')) for file in files
-    ]
-    self._sizes = []
-    for handle in self._handles:
-      handle.seek(0, os.SEEK_END)
-      self._sizes.append(handle.tell())
-    self._length = sum(self._sizes)
-    self._offsets = [0]
-    for s in self._sizes[:-1]:
-      self._offsets.append(self._offsets[-1] + s)
-    self._abspos = 0
-    self._relpos = (0, 0)
-
-  def _abs_to_rel(self, pos: int) -> tuple[int, int]:
-    idx = bisect.bisect_right(self._offsets, pos) - 1
-    return idx, pos - self._offsets[idx]
-
-  def close(self):
-    self._stack.close()
-
-  def closed(self) -> bool:
-    return all(handle.closed for handle in self._handles)
-
-  def fileno(self) -> int:
-    return -1
-
-  def readable(self) -> bool:
-    return True
-
-  def tell(self) -> int:
-    return self._abspos
-
-  def seek(self, pos: int, whence: int = os.SEEK_SET, /):
-    match whence:
-      case os.SEEK_SET:
-        pass
-      case os.SEEK_CUR:
-        pos += self._abspos
-      case os.SEEK_END:
-        pos = self._length - pos
-      case _:
-        raise ValueError(f'Invalid whence: {whence}')
-    self._abspos = pos
-    self._relpos = self._abs_to_rel(pos)
-
-  def readinto(self, b: bytearray | memoryview) -> int:
-    result = 0
-    mem = memoryview(b)
-    while mem:
-      self._handles[self._relpos[0]].seek(self._relpos[1])
-      count = self._handles[self._relpos[0]].readinto(mem)
-      result += count
-      self._abspos += count
-      self._relpos = self._abs_to_rel(self._abspos)
-      mem = mem[count:]
-      if self._abspos == self._length:
-        break
-    return result
-
-
-@contextlib.contextmanager
-def open_for_reading(model_files: list[pathlib.Path], is_compressed: bool):
-  with contextlib.closing(_MultiFileIO(model_files)) as f:
-    if is_compressed:
-      yield zstandard.ZstdDecompressor().stream_reader(f)
-    else:
-      yield f
-
-
-def _match_model(
-    paths: list[pathlib.Path], pattern: re.Pattern[str]
-) -> dict[str, list[pathlib.Path]]:
-  """Match files in a directory with a pattern, and group by model name."""
-  models = collections.defaultdict(list)
-  for path in paths:
-    match = pattern.fullmatch(path.name)
-    if match:
-      models[match.group('model_name')].append(path)
-  return {k: sorted(v) for k, v in models.items()}
-
-
-def select_model_files(
-    model_dir: pathlib.Path, model_name: str | None = None
-) -> tuple[list[pathlib.Path], bool]:
-  """Select the model files from a model directory."""
-  files = [file for file in model_dir.iterdir() if file.is_file()]
-
-  for pattern, is_compressed in (
-      (r'(?P<model_name>.*)\.[0-9]+\.bin\.zst$', True),
-      (r'(?P<model_name>.*)\.bin\.zst\.[0-9]+$', True),
-      (r'(?P<model_name>.*)\.[0-9]+\.bin$', False),
-      (r'(?P<model_name>.*)\.bin]\.[0-9]+$', False),
-      (r'(?P<model_name>.*)\.bin\.zst$', True),
-      (r'(?P<model_name>.*)\.bin$', False),
-  ):
-    models = _match_model(files, re.compile(pattern))
-    if model_name is not None:
-      if model_name in models:
-        return models[model_name], is_compressed
-    else:
-      if models:
-        if len(models) > 1:
-          raise RuntimeError(f'Multiple models matched in {model_dir}')
-        _, model_files = models.popitem()
-        return model_files, is_compressed
-  raise FileNotFoundError(f'No models matched in {model_dir}')
-
-
-def get_model_haiku_params(model_dir: pathlib.Path) -> hk.Params:
-  """Get the Haiku parameters from a model name."""
-  params: dict[str, dict[str, jnp.Array]] = {}
-  model_files, is_compressed = select_model_files(model_dir)
-  with open_for_reading(model_files, is_compressed) as stream:
-    for scope, name, arr in read_records(stream):
-      params.setdefault(scope, {})[name] = jnp.array(arr)
-  if not params:
-    raise FileNotFoundError(f'Model missing from "{model_dir}"')
-  return params
diff --git a/src/alphafold3/model/pipeline/inter_chain_bonds.py b/src/alphafold3/model/pipeline/inter_chain_bonds.py
deleted file mode 100644
index 4038f909325d086d99a7f67b36943dec437fba7c..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/pipeline/inter_chain_bonds.py
+++ /dev/null
@@ -1,347 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Functions for handling inter-chain bonds."""
-
-from collections.abc import Collection
-import functools
-from typing import Final, NamedTuple
-from alphafold3 import structure
-from alphafold3.constants import chemical_component_sets
-from alphafold3.constants import mmcif_names
-from alphafold3.model.atom_layout import atom_layout
-import numpy as np
-
-
-BOND_THRESHOLD_GLYCANS_ANGSTROM: Final[float] = 1.7
-# See https://pubs.acs.org/doi/10.1021/ja010331r for P-P atom bond distances.
-BOND_THRESHOLD_ALL_ANGSTROM: Final[float] = 2.4
-
-
-class BondAtomArrays(NamedTuple):
-  chain_id: np.ndarray
-  chain_type: np.ndarray
-  res_id: np.ndarray
-  res_name: np.ndarray
-  atom_name: np.ndarray
-  coords: np.ndarray
-
-
-def _get_bond_atom_arrays(
-    struc: structure.Structure, bond_atom_indices: np.ndarray
-) -> BondAtomArrays:
-  return BondAtomArrays(
-      chain_id=struc.chain_id[bond_atom_indices],
-      chain_type=struc.chain_type[bond_atom_indices],
-      res_id=struc.res_id[bond_atom_indices],
-      res_name=struc.res_name[bond_atom_indices],
-      atom_name=struc.atom_name[bond_atom_indices],
-      coords=struc.coords[..., bond_atom_indices, :],
-  )
-
-
-@functools.lru_cache(maxsize=1)
-def get_polymer_ligand_and_ligand_ligand_bonds(
-    struct: structure.Structure,
-    only_glycan_ligands: bool,
-    allow_multiple_bonds_per_atom: bool,
-) -> tuple[atom_layout.AtomLayout, atom_layout.AtomLayout]:
-  """Return polymer-ligand & ligand-ligand inter-residue bonds.
-
-  Args:
-    struct: Structure object to extract bonds from.
-    only_glycan_ligands: Whether to only include glycans in ligand category.
-    allow_multiple_bonds_per_atom: If not allowed, we greedily choose the first
-      bond seen per atom and discard the remaining on each atom..
-
-  Returns:
-    polymer_ligand, ligand_ligand_bonds: Each object is an AtomLayout object
-    [num_bonds, 2] for the bond-defining atoms.
-  """
-  if only_glycan_ligands:
-    allowed_res_names = list({
-        *chemical_component_sets.GLYCAN_OTHER_LIGANDS,
-        *chemical_component_sets.GLYCAN_LINKING_LIGANDS,
-    })
-  else:
-    allowed_res_names = None
-  all_bonds = get_bond_layout(
-      bond_threshold=BOND_THRESHOLD_GLYCANS_ANGSTROM
-      if only_glycan_ligands
-      else BOND_THRESHOLD_ALL_ANGSTROM,
-      struct=struct,
-      allowed_chain_types1=list({
-          *mmcif_names.LIGAND_CHAIN_TYPES,
-          *mmcif_names.POLYMER_CHAIN_TYPES,
-      }),
-      allowed_chain_types2=list(mmcif_names.LIGAND_CHAIN_TYPES),
-      allowed_res_names=allowed_res_names,
-      allow_multiple_bonds_per_atom=allow_multiple_bonds_per_atom,
-  )
-  ligand_ligand_bonds_mask = np.isin(
-      all_bonds.chain_type, list(mmcif_names.LIGAND_CHAIN_TYPES)
-  )
-  polymer_ligand_bonds_mask = np.isin(
-      all_bonds.chain_type, list(mmcif_names.POLYMER_CHAIN_TYPES)
-  )
-  polymer_ligand_bonds_mask = np.logical_and(
-      ligand_ligand_bonds_mask.any(axis=1),
-      polymer_ligand_bonds_mask.any(axis=1),
-  )
-  ligand_ligand_bonds = all_bonds[ligand_ligand_bonds_mask.all(axis=1)]
-  polymer_ligand_bonds = all_bonds[polymer_ligand_bonds_mask]
-  return polymer_ligand_bonds, ligand_ligand_bonds
-
-
-def _remove_multi_bonds(
-    bond_layout: atom_layout.AtomLayout,
-) -> atom_layout.AtomLayout:
-  """Remove instances greedily."""
-  uids = {}
-  keep_indx = []
-  for chain_id, res_id, atom_name in zip(
-      bond_layout.chain_id,
-      bond_layout.res_id,
-      bond_layout.atom_name,
-      strict=True,
-  ):
-    key1 = (chain_id[0], res_id[0], atom_name[0])
-    key2 = (chain_id[1], res_id[1], atom_name[1])
-    keep_indx.append(bool(key1 not in uids) and bool(key2 not in uids))
-    if key1 not in uids:
-      uids[key1] = None
-    if key2 not in uids:
-      uids[key2] = None
-  return bond_layout[np.array(keep_indx, dtype=bool)]
-
-
-@functools.lru_cache(maxsize=1)
-def get_ligand_ligand_bonds(
-    struct: structure.Structure,
-    only_glycan_ligands: bool,
-    allow_multiple_bonds_per_atom: bool = False,
-) -> atom_layout.AtomLayout:
-  """Return ligand-ligand inter-residue bonds.
-
-  Args:
-    struct: Structure object to extract bonds from.
-    only_glycan_ligands: Whether to only include glycans in ligand category.
-    allow_multiple_bonds_per_atom: If not allowed, we greedily choose the first
-      bond seen per atom and discard the remaining on each atom.
-
-  Returns:
-    bond_layout: AtomLayout object [num_bonds, 2] for the bond-defining atoms.
-  """
-  if only_glycan_ligands:
-    allowed_res_names = list({
-        *chemical_component_sets.GLYCAN_OTHER_LIGANDS,
-        *chemical_component_sets.GLYCAN_LINKING_LIGANDS,
-    })
-  else:
-    allowed_res_names = None
-  return get_bond_layout(
-      bond_threshold=BOND_THRESHOLD_GLYCANS_ANGSTROM
-      if only_glycan_ligands
-      else BOND_THRESHOLD_ALL_ANGSTROM,
-      struct=struct,
-      allowed_chain_types1=list(mmcif_names.LIGAND_CHAIN_TYPES),
-      allowed_chain_types2=list(mmcif_names.LIGAND_CHAIN_TYPES),
-      allowed_res_names=allowed_res_names,
-      allow_multiple_bonds_per_atom=allow_multiple_bonds_per_atom,
-  )
-
-
-@functools.lru_cache(maxsize=1)
-def get_polymer_ligand_bonds(
-    struct: structure.Structure,
-    only_glycan_ligands: bool,
-    allow_multiple_bonds_per_atom: bool = False,
-    bond_threshold: float | None = None,
-) -> atom_layout.AtomLayout:
-  """Return polymer-ligand interchain bonds.
-
-  Args:
-    struct: Structure object to extract bonds from.
-    only_glycan_ligands: Whether to only include glycans in ligand category.
-    allow_multiple_bonds_per_atom: If not allowed, we greedily choose the first
-      bond seen per atom and discard the remaining on each atom.
-    bond_threshold: Euclidean distance of max allowed bond.
-
-  Returns:
-    bond_layout: AtomLayout object [num_bonds, 2] for the bond-defining atoms.
-  """
-  if only_glycan_ligands:
-    allowed_res_names = list({
-        *chemical_component_sets.GLYCAN_OTHER_LIGANDS,
-        *chemical_component_sets.GLYCAN_LINKING_LIGANDS,
-    })
-  else:
-    allowed_res_names = None
-  if bond_threshold is None:
-    if only_glycan_ligands:
-      bond_threshold = BOND_THRESHOLD_GLYCANS_ANGSTROM
-    else:
-      bond_threshold = BOND_THRESHOLD_ALL_ANGSTROM
-  return get_bond_layout(
-      bond_threshold=bond_threshold,
-      struct=struct,
-      allowed_chain_types1=list(mmcif_names.POLYMER_CHAIN_TYPES),
-      allowed_chain_types2=list(mmcif_names.LIGAND_CHAIN_TYPES),
-      allowed_res_names=allowed_res_names,
-      allow_multiple_bonds_per_atom=allow_multiple_bonds_per_atom,
-  )
-
-
-def get_bond_layout(
-    bond_threshold: float = BOND_THRESHOLD_ALL_ANGSTROM,
-    *,
-    struct: structure.Structure,
-    allowed_chain_types1: Collection[str],
-    allowed_chain_types2: Collection[str],
-    include_bond_types: Collection[str] = ('covale',),
-    allowed_res_names: Collection[str] | None = None,
-    allow_multiple_bonds_per_atom: bool,
-) -> atom_layout.AtomLayout:
-  """Get bond_layout for all bonds between two sets of chain types.
-
-  There is a mask (all_mask) that runs through this script, and each bond pair
-  needs to maintain a True across all conditions in order to be preserved at the
-  end, otherwise the bond pair has invalidated a condition with a False and is
-  removed entirely. Note, we remove oxygen atom bonds as they are an edge case
-  that causes issues with scoring, due to multiple waters bonding with single
-  residues.
-
-  Args:
-    bond_threshold: Maximum bond distance in Angstrom.
-    struct: Structure object to extract bonds from.
-    allowed_chain_types1: One end of the bonds must be an atom with one of these
-      chain types.
-    allowed_chain_types2: The other end of the bond must be an atom with one of
-      these chain types.
-    include_bond_types: Only include bonds with specified type e.g. hydrog,
-      metalc, covale, disulf.
-    allowed_res_names: Further restricts from chain_types. Either end of the
-      bonds must be an atom part of these res_names. If none all will be
-      accepted after chain and bond type filtering.
-    allow_multiple_bonds_per_atom: If not allowed, we greedily choose the first
-      bond seen per atom and discard the remaining on each atom.
-
-  Returns:
-    bond_layout: AtomLayout object [num_bonds, 2] for the bond-defining atoms.
-  """
-  if not struct.bonds:
-    return atom_layout.AtomLayout(
-        atom_name=np.empty((0, 2), dtype=object),
-        res_id=np.empty((0, 2), dtype=int),
-        res_name=np.empty((0, 2), dtype=object),
-        chain_id=np.empty((0, 2), dtype=object),
-        chain_type=np.empty((0, 2), dtype=object),
-        atom_element=np.empty((0, 2), dtype=object),
-    )
-  from_atom_idxs, dest_atom_idxs = struct.bonds.get_atom_indices(
-      struct.atom_key
-  )
-  from_atoms = _get_bond_atom_arrays(struct, from_atom_idxs)
-  dest_atoms = _get_bond_atom_arrays(struct, dest_atom_idxs)
-  # Chain type
-  chain_mask = np.logical_or(
-      np.logical_and(
-          np.isin(
-              from_atoms.chain_type,
-              allowed_chain_types1,
-          ),
-          np.isin(
-              dest_atoms.chain_type,
-              allowed_chain_types2,
-          ),
-      ),
-      np.logical_and(
-          np.isin(
-              from_atoms.chain_type,
-              allowed_chain_types2,
-          ),
-          np.isin(
-              dest_atoms.chain_type,
-              allowed_chain_types1,
-          ),
-      ),
-  )
-  if allowed_res_names:
-    # Res type
-    res_mask = np.logical_or(
-        np.isin(from_atoms.res_name, allowed_res_names),
-        np.isin(dest_atoms.res_name, allowed_res_names),
-    )
-    # All mask
-    all_mask = np.logical_and(chain_mask, res_mask)
-  else:
-    all_mask = chain_mask
-  # Bond type mask
-  type_mask = np.isin(struct.bonds.type, list(include_bond_types))
-  np.logical_and(all_mask, type_mask, out=all_mask)
-  # Bond length check. Work in square length to avoid taking many square roots.
-  bond_length_squared = np.square(from_atoms.coords - dest_atoms.coords).sum(
-      axis=1
-  )
-  bond_threshold_squared = bond_threshold * bond_threshold
-  np.logical_and(
-      all_mask, bond_length_squared < bond_threshold_squared, out=all_mask
-  )
-  # Inter-chain and inter-residue bonds for ligands
-  ligand_types = list(mmcif_names.LIGAND_CHAIN_TYPES)
-  is_ligand = np.logical_or(
-      np.isin(
-          from_atoms.chain_type,
-          ligand_types,
-      ),
-      np.isin(
-          dest_atoms.chain_type,
-          ligand_types,
-      ),
-  )
-  res_id_differs = from_atoms.res_id != dest_atoms.res_id
-  chain_id_differs = from_atoms.chain_id != dest_atoms.chain_id
-  is_inter_res = np.logical_or(res_id_differs, chain_id_differs)
-  is_inter_ligand_res = np.logical_and(is_inter_res, is_ligand)
-  is_inter_chain_not_ligand = np.logical_and(chain_id_differs, ~is_ligand)
-  # If ligand then inter-res & inter-chain bonds, otherwise inter-chain only.
-  combined_allowed_bonds = np.logical_or(
-      is_inter_chain_not_ligand, is_inter_ligand_res
-  )
-  np.logical_and(all_mask, combined_allowed_bonds, out=all_mask)
-  bond_layout = atom_layout.AtomLayout(
-      atom_name=np.stack(
-          [
-              from_atoms.atom_name[all_mask],
-              dest_atoms.atom_name[all_mask],
-          ],
-          axis=1,
-          dtype=object,
-      ),
-      res_id=np.stack(
-          [from_atoms.res_id[all_mask], dest_atoms.res_id[all_mask]],
-          axis=1,
-          dtype=int,
-      ),
-      chain_id=np.stack(
-          [
-              from_atoms.chain_id[all_mask],
-              dest_atoms.chain_id[all_mask],
-          ],
-          axis=1,
-          dtype=object,
-      ),
-  )
-  if not allow_multiple_bonds_per_atom:
-    bond_layout = _remove_multi_bonds(bond_layout)
-  return atom_layout.fill_in_optional_fields(
-      bond_layout,
-      reference_atoms=atom_layout.atom_layout_from_structure(struct),
-  )
diff --git a/src/alphafold3/model/pipeline/pipeline.py b/src/alphafold3/model/pipeline/pipeline.py
deleted file mode 100644
index 4ea7434574182e895e22e9ee828e7fd7a8b0e789..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/pipeline/pipeline.py
+++ /dev/null
@@ -1,447 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""The main featurizer."""
-
-import bisect
-from collections.abc import Sequence
-import datetime
-import itertools
-
-from absl import logging
-from alphafold3.common import base_config
-from alphafold3.common import folding_input
-from alphafold3.constants import chemical_components
-from alphafold3.model import feat_batch
-from alphafold3.model import features
-from alphafold3.model.pipeline import inter_chain_bonds
-from alphafold3.model.pipeline import structure_cleaning
-from alphafold3.structure import chemical_components as struc_chem_comps
-import numpy as np
-
-
-_DETERMINISTIC_FRAMES_RANDOM_SEED = 12312837
-
-
-def calculate_bucket_size(
-    num_tokens: int, buckets: Sequence[int] | None
-) -> int:
-  """Calculates the bucket size to pad the data to."""
-  if buckets is None:
-    return num_tokens
-
-  if not buckets:
-    raise ValueError('Buckets must be non-empty.')
-
-  if not all(prev < curr for prev, curr in itertools.pairwise(buckets)):
-    raise ValueError(
-        f'Buckets must be in strictly increasing order. Got {buckets=}.'
-    )
-
-  bucket_idx = bisect.bisect_left(buckets, num_tokens)
-
-  if bucket_idx == len(buckets):
-    logging.warning(
-        'Creating a new bucket of size %d since the input has more tokens than'
-        ' the largest bucket size %d. This may trigger a re-compilation of the'
-        ' model. Consider additional large bucket sizes to avoid excessive'
-        ' re-compilation.',
-        num_tokens,
-        buckets[-1],
-    )
-    return num_tokens
-
-  return buckets[bucket_idx]
-
-
-class NanDataError(Exception):
-  """Raised if the data pipeline produces data containing nans."""
-
-
-class TotalNumResOutOfRangeError(Exception):
-  """Raised if total number of residues for all chains outside allowed range."""
-
-
-class MmcifNumChainsError(Exception):
-  """Raised if the mmcif file contains too many / too few chains."""
-
-
-class WholePdbPipeline:
-  """Processes an entire mmcif entity and merges the content."""
-
-  class Config(base_config.BaseConfig):
-    """Configuration object for `WholePdbPipeline`.
-
-    Properties:
-      max_atoms_per_token: number of atom slots in one token (was called
-        num_dense, and semi-hardcoded to 24 before)
-      pad_num_chains: Size to pad NUM_CHAINS feature dimensions to, only for
-        protein chains.
-      buckets: Bucket sizes to pad the data to, to avoid excessive
-        re-compilation of the model. If None, calculate the appropriate bucket
-        size from the number of tokens. If not None, must be a sequence of at
-        least one integer, in strictly increasing order. Will raise an error if
-        the number of tokens is more than the largest bucket size.
-      max_total_residues: Any mmCIF with more total residues will be rejected.
-        If none, then no limit is applied.
-      min_total_residues: Any mmCIF with less total residues will be rejected.
-      msa_crop_size: Maximum size of MSA to take across all chains.
-      max_template_date: Optional max template date to prevent data leakage in
-        validation.
-      ref_max_modified_date: Optional maximum date that controls whether to
-        allow use of model coordinates for a chemical component from the CCD if
-        RDKit conformer generation fails and the component does not have ideal
-        coordinates set. Only for components that have been released before this
-        date the model coordinates can be used as a fallback.
-      max_templates: The maximum number of templates to send through the network
-        set to 0 to switch off templates.
-      filter_clashes: If true then will remove clashing chains.
-      filter_crystal_aids: If true ligands in the cryal aid list are removed.
-      max_paired_sequence_per_species: The maximum number of sequences per
-        species that will be used for MSA pairing.
-      drop_ligand_leaving_atoms: Flag for handling leaving atoms for ligands.
-      average_num_atoms_per_token: Target average number of atoms per token to
-        compute the padding size for flat atoms.
-      atom_cross_att_queries_subset_size: queries subset size in atom cross
-        attention
-      atom_cross_att_keys_subset_size: keys subset size in atom cross attention
-      flatten_non_standard_residues: Whether to expand non-standard polymer
-        residues into flat-atom format.
-      remove_nonsymmetric_bonds: Whether to remove nonsymmetric bonds from
-        symmetric polymer chains.
-      deterministic_frames: Whether to use fixed-seed reference positions to
-        construct deterministic frames.
-    """
-
-    max_atoms_per_token: int = 24
-    pad_num_chains: int = 1000
-    buckets: list[int] | None = None
-    max_total_residues: int | None = None
-    min_total_residues: int | None = None
-    msa_crop_size: int = 16384
-    max_template_date: datetime.date | None = None
-    ref_max_modified_date: datetime.date | None = None
-    max_templates: int = 4
-    filter_clashes: bool = False
-    filter_crystal_aids: bool = False
-    max_paired_sequence_per_species: int = 600
-    drop_ligand_leaving_atoms: bool = True
-    average_num_atoms_per_token: int = 24
-    atom_cross_att_queries_subset_size: int = 32
-    atom_cross_att_keys_subset_size: int = 128
-    flatten_non_standard_residues: bool = True
-    remove_nonsymmetric_bonds: bool = False
-    deterministic_frames: bool = True
-    conformer_max_iterations: int | None = None
-
-  def __init__(self, *, config: Config):
-    """Initializes WholePdb data pipeline.
-
-    Args:
-      config: Pipeline configuration.
-    """
-    self._config = config
-
-  def process_item(
-      self,
-      fold_input: folding_input.Input,
-      random_state: np.random.RandomState,
-      ccd: chemical_components.Ccd,
-      random_seed: int | None = None,
-  ) -> features.BatchDict:
-    """Takes requests from in_queue, adds (key, serialized ex) to out_queue."""
-    if random_seed is None:
-      random_seed = random_state.randint(2**31)
-
-    random_state = np.random.RandomState(seed=random_seed)
-
-    logging_name = f'{fold_input.name}, random_seed={random_seed}'
-    logging.info('processing %s', logging_name)
-    struct = fold_input.to_structure(ccd=ccd)
-
-    # Clean structure.
-    cleaned_struc, cleaning_metadata = structure_cleaning.clean_structure(
-        struct,
-        ccd=ccd,
-        drop_non_standard_atoms=True,
-        drop_missing_sequence=True,
-        filter_clashes=self._config.filter_clashes,
-        filter_crystal_aids=self._config.filter_crystal_aids,
-        filter_waters=True,
-        filter_hydrogens=True,
-        filter_leaving_atoms=self._config.drop_ligand_leaving_atoms,
-        only_glycan_ligands_for_leaving_atoms=True,
-        covalent_bonds_only=True,
-        remove_polymer_polymer_bonds=True,
-        remove_bad_bonds=True,
-        remove_nonsymmetric_bonds=self._config.remove_nonsymmetric_bonds,
-    )
-
-    num_clashing_chains_removed = cleaning_metadata[
-        'num_clashing_chains_removed'
-    ]
-
-    if num_clashing_chains_removed:
-      logging.info(
-          'Removed %d clashing chains from %s',
-          num_clashing_chains_removed,
-          logging_name,
-      )
-
-    # No chains after fixes
-    if cleaned_struc.num_chains == 0:
-      raise MmcifNumChainsError(f'{logging_name}: No chains in structure!')
-
-    polymer_ligand_bonds, ligand_ligand_bonds = (
-        inter_chain_bonds.get_polymer_ligand_and_ligand_ligand_bonds(
-            cleaned_struc,
-            only_glycan_ligands=False,
-            allow_multiple_bonds_per_atom=True,
-        )
-    )
-
-    # If empty replace with None as this causes errors downstream.
-    if ligand_ligand_bonds and not ligand_ligand_bonds.atom_name.size:
-      ligand_ligand_bonds = None
-    if polymer_ligand_bonds and not polymer_ligand_bonds.atom_name.size:
-      polymer_ligand_bonds = None
-
-    # Create the flat output AtomLayout
-    empty_output_struc, flat_output_layout = (
-        structure_cleaning.create_empty_output_struc_and_layout(
-            struc=cleaned_struc,
-            ccd=ccd,
-            polymer_ligand_bonds=polymer_ligand_bonds,
-            ligand_ligand_bonds=ligand_ligand_bonds,
-            drop_ligand_leaving_atoms=self._config.drop_ligand_leaving_atoms,
-        )
-    )
-
-    # Select the tokens for Evoformer.
-    # Each token (e.g. a residue) is encoded as one representative atom. This
-    # is flexible enough to allow the 1-token-per-atom ligand representation
-    # in the future.
-    all_tokens, all_token_atoms_layout, standard_token_idxs = (
-        features.tokenizer(
-            flat_output_layout,
-            ccd=ccd,
-            max_atoms_per_token=self._config.max_atoms_per_token,
-            flatten_non_standard_residues=self._config.flatten_non_standard_residues,
-            logging_name=logging_name,
-        )
-    )
-    total_tokens = len(all_tokens.atom_name)
-    if (
-        self._config.max_total_residues
-        and total_tokens > self._config.max_total_residues
-    ):
-      raise TotalNumResOutOfRangeError(
-          'Total Number of Residues > max_total_residues: '
-          f'({total_tokens} > {self._config.max_total_residues})'
-      )
-
-    if (
-        self._config.min_total_residues
-        and total_tokens < self._config.min_total_residues
-    ):
-      raise TotalNumResOutOfRangeError(
-          'Total Number of Residues < min_total_residues: '
-          f'({total_tokens} < {self._config.min_total_residues})'
-      )
-
-    logging.info(
-        'Calculating bucket size for input with %d tokens.', total_tokens
-    )
-    padded_token_length = calculate_bucket_size(
-        total_tokens, self._config.buckets
-    )
-    logging.info(
-        'Got bucket size %d for input with %d tokens, resulting in %d padded'
-        ' tokens.',
-        padded_token_length,
-        total_tokens,
-        padded_token_length - total_tokens,
-    )
-
-    # Padding shapes for all features.
-    num_atoms = padded_token_length * self._config.average_num_atoms_per_token
-    # Round up to next multiple of subset size.
-    num_atoms = int(
-        np.ceil(num_atoms / self._config.atom_cross_att_queries_subset_size)
-        * self._config.atom_cross_att_queries_subset_size
-    )
-    padding_shapes = features.PaddingShapes(
-        num_tokens=padded_token_length,
-        msa_size=self._config.msa_crop_size,
-        num_chains=self._config.pad_num_chains,
-        num_templates=self._config.max_templates,
-        num_atoms=num_atoms,
-    )
-
-    # Create the atom layouts for flat atom cross attention
-    batch_atom_cross_att = features.AtomCrossAtt.compute_features(
-        all_token_atoms_layout=all_token_atoms_layout,
-        queries_subset_size=self._config.atom_cross_att_queries_subset_size,
-        keys_subset_size=self._config.atom_cross_att_keys_subset_size,
-        padding_shapes=padding_shapes,
-    )
-
-    # Extract per-token features
-    batch_token_features = features.TokenFeatures.compute_features(
-        all_tokens=all_tokens,
-        padding_shapes=padding_shapes,
-    )
-
-    # Create reference structure features
-    chemical_components_data = struc_chem_comps.populate_missing_ccd_data(
-        ccd=ccd,
-        chemical_components_data=cleaned_struc.chemical_components_data,
-        populate_pdbx_smiles=True,
-    )
-
-    # Add smiles info to empty_output_struc.
-    empty_output_struc = empty_output_struc.copy_and_update_globals(
-        chemical_components_data=chemical_components_data
-    )
-    # Create layouts and store structures for model output conversion.
-    batch_convert_model_output = features.ConvertModelOutput.compute_features(
-        all_token_atoms_layout=all_token_atoms_layout,
-        padding_shapes=padding_shapes,
-        cleaned_struc=cleaned_struc,
-        flat_output_layout=flat_output_layout,
-        empty_output_struc=empty_output_struc,
-        polymer_ligand_bonds=polymer_ligand_bonds,
-        ligand_ligand_bonds=ligand_ligand_bonds,
-    )
-
-    # Create the PredictedStructureInfo
-    batch_predicted_structure_info = (
-        features.PredictedStructureInfo.compute_features(
-            all_tokens=all_tokens,
-            all_token_atoms_layout=all_token_atoms_layout,
-            padding_shapes=padding_shapes,
-        )
-    )
-
-    # Create MSA features
-    batch_msa = features.MSA.compute_features(
-        all_tokens=all_tokens,
-        standard_token_idxs=standard_token_idxs,
-        padding_shapes=padding_shapes,
-        fold_input=fold_input,
-        logging_name=logging_name,
-        max_paired_sequence_per_species=self._config.max_paired_sequence_per_species,
-    )
-
-    # Create template features
-    batch_templates = features.Templates.compute_features(
-        all_tokens=all_tokens,
-        standard_token_idxs=standard_token_idxs,
-        padding_shapes=padding_shapes,
-        fold_input=fold_input,
-        max_templates=self._config.max_templates,
-        logging_name=logging_name,
-    )
-
-    ref_max_modified_date = self._config.ref_max_modified_date
-    conformer_max_iterations = self._config.conformer_max_iterations
-    batch_ref_structure, ligand_ligand_bonds = (
-        features.RefStructure.compute_features(
-            all_token_atoms_layout=all_token_atoms_layout,
-            ccd=ccd,
-            padding_shapes=padding_shapes,
-            chemical_components_data=chemical_components_data,
-            random_state=random_state,
-            ref_max_modified_date=ref_max_modified_date,
-            conformer_max_iterations=conformer_max_iterations,
-            ligand_ligand_bonds=ligand_ligand_bonds,
-        )
-    )
-    deterministic_ref_structure = None
-    if self._config.deterministic_frames:
-      deterministic_ref_structure, _ = features.RefStructure.compute_features(
-          all_token_atoms_layout=all_token_atoms_layout,
-          ccd=ccd,
-          padding_shapes=padding_shapes,
-          chemical_components_data=chemical_components_data,
-          random_state=(
-              np.random.RandomState(_DETERMINISTIC_FRAMES_RANDOM_SEED)
-          ),
-          ref_max_modified_date=ref_max_modified_date,
-          conformer_max_iterations=None,
-          ligand_ligand_bonds=ligand_ligand_bonds,
-      )
-
-    # Create ligand-polymer bond features.
-    polymer_ligand_bond_info = features.PolymerLigandBondInfo.compute_features(
-        all_tokens=all_tokens,
-        all_token_atoms_layout=all_token_atoms_layout,
-        bond_layout=polymer_ligand_bonds,
-        padding_shapes=padding_shapes,
-    )
-    # Create ligand-ligand bond features.
-    ligand_ligand_bond_info = features.LigandLigandBondInfo.compute_features(
-        all_tokens,
-        ligand_ligand_bonds,
-        padding_shapes,
-    )
-
-    # Create the Pseudo-beta layout for distogram head and distance error head.
-    batch_pseudo_beta_info = features.PseudoBetaInfo.compute_features(
-        all_token_atoms_layout=all_token_atoms_layout,
-        ccd=ccd,
-        padding_shapes=padding_shapes,
-        logging_name=logging_name,
-    )
-
-    # Frame construction.
-    batch_frames = features.Frames.compute_features(
-        all_tokens=all_tokens,
-        all_token_atoms_layout=all_token_atoms_layout,
-        ref_structure=(
-            deterministic_ref_structure
-            if self._config.deterministic_frames
-            else batch_ref_structure
-        ),
-        padding_shapes=padding_shapes,
-    )
-
-    # Assemble the Batch object.
-    batch = feat_batch.Batch(
-        msa=batch_msa,
-        templates=batch_templates,
-        token_features=batch_token_features,
-        ref_structure=batch_ref_structure,
-        predicted_structure_info=batch_predicted_structure_info,
-        polymer_ligand_bond_info=polymer_ligand_bond_info,
-        ligand_ligand_bond_info=ligand_ligand_bond_info,
-        pseudo_beta_info=batch_pseudo_beta_info,
-        atom_cross_att=batch_atom_cross_att,
-        convert_model_output=batch_convert_model_output,
-        frames=batch_frames,
-    )
-
-    np_example = batch.as_data_dict()
-    if 'num_iter_recycling' in np_example:
-      del np_example['num_iter_recycling']  # that does not belong here
-
-    for name, value in np_example.items():
-      if (
-          value.dtype.kind not in {'U', 'S'}
-          and value.dtype.name != 'object'
-          and np.isnan(np.sum(value))
-      ):
-        raise NanDataError(
-            'The output of the data pipeline contained nans. '
-            f'nan feature: {name}, fold input name: {fold_input.name}, '
-            f'random_seed {random_seed}'
-        )
-
-    return np_example
diff --git a/src/alphafold3/model/pipeline/structure_cleaning.py b/src/alphafold3/model/pipeline/structure_cleaning.py
deleted file mode 100644
index 4043a3f8430fed7997c6e0656f0b6f0bf64487d1..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/pipeline/structure_cleaning.py
+++ /dev/null
@@ -1,368 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Prepare PDB structure for training or inference."""
-
-from typing import Any
-
-from absl import logging
-from alphafold3 import structure
-from alphafold3.constants import chemical_component_sets
-from alphafold3.constants import chemical_components
-from alphafold3.constants import mmcif_names
-from alphafold3.model.atom_layout import atom_layout
-from alphafold3.model.pipeline import inter_chain_bonds
-from alphafold3.model.scoring import covalent_bond_cleaning
-from alphafold3.structure import sterics
-import numpy as np
-
-
-def _get_leaving_atom_mask(
-    struc: structure.Structure,
-    polymer_ligand_bonds: atom_layout.AtomLayout | None,
-    ligand_ligand_bonds: atom_layout.AtomLayout | None,
-    chain_id: str,
-    chain_type: str,
-    res_id: int,
-    res_name: str,
-) -> np.ndarray:
-  """Updates a drop_leaving_atoms mask with new leaving atom locations."""
-  bonded_atoms = atom_layout.get_bonded_atoms(
-      polymer_ligand_bonds,
-      ligand_ligand_bonds,
-      res_id,
-      chain_id,
-  )
-  # Connect the amino-acids, i.e. remove OXT, HXT and H2.
-  drop_atoms = atom_layout.get_link_drop_atoms(
-      res_name=res_name,
-      chain_type=chain_type,
-      is_start_terminus=False,
-      is_end_terminus=False,
-      bonded_atoms=bonded_atoms,
-      drop_ligand_leaving_atoms=True,
-  )
-  # Default mask where everything is false, which equates to being kept.
-  drop_atom_filter_atoms = struc.chain_id != struc.chain_id
-  for drop_atom in drop_atoms:
-    drop_atom_filter_atom = np.logical_and(
-        np.logical_and(
-            struc.atom_name == drop_atom,
-            struc.chain_id == chain_id,
-        ),
-        struc.res_id == res_id,
-    )
-    drop_atom_filter_atoms = np.logical_or(
-        drop_atom_filter_atoms, drop_atom_filter_atom
-    )
-  return drop_atom_filter_atoms
-
-
-def clean_structure(
-    struc: structure.Structure,
-    ccd: chemical_components.Ccd,
-    *,
-    drop_missing_sequence: bool,
-    filter_clashes: bool,
-    drop_non_standard_atoms: bool,
-    filter_crystal_aids: bool,
-    filter_waters: bool,
-    filter_hydrogens: bool,
-    filter_leaving_atoms: bool,
-    only_glycan_ligands_for_leaving_atoms: bool,
-    covalent_bonds_only: bool,
-    remove_polymer_polymer_bonds: bool,
-    remove_bad_bonds: bool,
-    remove_nonsymmetric_bonds: bool,
-) -> tuple[structure.Structure, dict[str, Any]]:
-  """Cleans structure.
-
-  Args:
-    struc: Structure to clean.
-    ccd: The chemical components dictionary.
-    drop_missing_sequence: Whether to drop chains without specified sequences.
-    filter_clashes: Whether to drop clashing chains.
-    drop_non_standard_atoms: Whether to drop non CCD standard atoms.
-    filter_crystal_aids: Whether to drop ligands in the crystal aid set.
-    filter_waters: Whether to drop water chains.
-    filter_hydrogens: Whether to drop hyrdogen atoms.
-    filter_leaving_atoms: Whether to drop leaving atoms based on heuristics.
-    only_glycan_ligands_for_leaving_atoms: Whether to only include glycan
-      ligands when filtering leaving atoms.
-    covalent_bonds_only: Only include covalent bonds.
-    remove_polymer_polymer_bonds: Remove polymer-polymer bonds.
-    remove_bad_bonds: Whether to remove badly bonded ligands.
-    remove_nonsymmetric_bonds: Whether to remove nonsymmetric polymer-ligand
-      bonds from symmetric polymer chains.
-
-  Returns:
-    Tuple of structure and metadata dict. The metadata dict has
-    information about what was cleaned from the original.
-  """
-
-  metadata = {}
-  # Crop crystallization aids.
-  if (
-      filter_crystal_aids
-      and struc.structure_method in mmcif_names.CRYSTALLIZATION_METHODS
-  ):
-    struc = struc.filter_out(
-        res_name=chemical_component_sets.COMMON_CRYSTALLIZATION_AIDS
-    )
-
-  # Drop chains without specified sequences.
-  if drop_missing_sequence:
-    chains_with_unk_sequence = struc.find_chains_with_unknown_sequence()
-    num_with_unk_sequence = len(chains_with_unk_sequence)
-    if chains_with_unk_sequence:
-      struc = struc.filter_out(chain_id=chains_with_unk_sequence)
-  else:
-    num_with_unk_sequence = 0
-  metadata['num_with_unk_sequence'] = num_with_unk_sequence
-
-  # Remove intersecting chains.
-  if filter_clashes and struc.num_chains > 1:
-    clashing_chains = sterics.find_clashing_chains(struc)
-    if clashing_chains:
-      struc = struc.filter_out(chain_id=clashing_chains)
-  else:
-    clashing_chains = []
-  metadata['num_clashing_chains_removed'] = len(clashing_chains)
-  metadata['chains_removed'] = clashing_chains
-
-  # Drop non-standard atoms
-  if drop_non_standard_atoms:
-    struc = struc.drop_non_standard_atoms(
-        ccd=ccd, drop_unk=False, drop_non_ccd=False
-    )
-
-  # Sort chains in "reverse-spreadsheet" order.
-  struc = struc.with_sorted_chains
-
-  if filter_hydrogens:
-    struc = struc.without_hydrogen()
-
-  if filter_waters:
-    struc = struc.filter_out(chain_type=mmcif_names.WATER)
-
-  if filter_leaving_atoms:
-    drop_leaving_atoms_all = struc.chain_id != struc.chain_id
-    polymer_ligand_bonds = inter_chain_bonds.get_polymer_ligand_bonds(
-        struc,
-        only_glycan_ligands=only_glycan_ligands_for_leaving_atoms,
-    )
-    ligand_ligand_bonds = inter_chain_bonds.get_ligand_ligand_bonds(
-        struc,
-        only_glycan_ligands=only_glycan_ligands_for_leaving_atoms,
-    )
-    all_glycans = {
-        *chemical_component_sets.GLYCAN_OTHER_LIGANDS,
-        *chemical_component_sets.GLYCAN_LINKING_LIGANDS,
-    }
-    # If only glycan ligands and no O1 atoms, we can do parallel drop.
-    if (
-        only_glycan_ligands_for_leaving_atoms
-        and (not (ligand_ligand_bonds.atom_name == 'O1').any())
-        and (not (polymer_ligand_bonds.atom_name == 'O1').any())
-    ):
-      drop_leaving_atoms_all = np.logical_and(
-          np.isin(struc.atom_name, 'O1'),
-          np.isin(struc.res_name, list(all_glycans)),
-      )
-    else:
-      substruct = struc.group_by_residue
-      glycan_mask = np.isin(substruct.res_name, list(all_glycans))
-      substruct = substruct.filter(glycan_mask)
-      # We need to iterate over all glycan residues for this.
-      for res in substruct.iter_residues():
-        # Only need to do drop leaving atoms for glycans depending on bonds.
-        if (res_name := res['res_name']) in all_glycans:
-          drop_atom_filter = _get_leaving_atom_mask(
-              struc=struc,
-              polymer_ligand_bonds=polymer_ligand_bonds,
-              ligand_ligand_bonds=ligand_ligand_bonds,
-              chain_id=res['chain_id'],
-              chain_type=res['chain_type'],
-              res_id=res['res_id'],
-              res_name=res_name,
-          )
-          drop_leaving_atoms_all = np.logical_or(
-              drop_leaving_atoms_all, drop_atom_filter
-          )
-
-    num_atoms_before = struc.num_atoms
-    struc = struc.filter_out(drop_leaving_atoms_all)
-    num_atoms_after = struc.num_atoms
-
-    if num_atoms_before > num_atoms_after:
-      logging.error(
-          'Dropped %s atoms from GT struc: chain_id %s res_id %s res_name %s',
-          num_atoms_before - num_atoms_after,
-          struc.chain_id,
-          struc.res_id,
-          struc.res_name,
-      )
-
-  # Can filter by bond type without having to iterate over bonds.
-  if struc.bonds and covalent_bonds_only:
-    is_covalent = np.isin(struc.bonds.type, ['covale'])
-    if sum(is_covalent) > 0:
-      new_bonds = struc.bonds[is_covalent]
-    else:
-      new_bonds = structure.Bonds.make_empty()
-    struc = struc.copy_and_update(bonds=new_bonds)
-
-  # Other bond filters require iterating over individual bonds.
-  if struc.bonds and (remove_bad_bonds or remove_polymer_polymer_bonds):
-    include_bond = []
-    num_pp_bonds = 0
-    num_bad_bonds = 0
-    for bond in struc.iter_bonds():
-      dest_atom = bond.dest_atom
-      from_atom = bond.from_atom
-      if remove_polymer_polymer_bonds:
-        if (
-            from_atom['chain_type'] in mmcif_names.POLYMER_CHAIN_TYPES
-            and dest_atom['chain_type'] in mmcif_names.POLYMER_CHAIN_TYPES
-        ):
-          num_pp_bonds += 1
-          include_bond.append(False)
-          continue
-      if remove_bad_bonds:
-        dest_coords = np.array(
-            [dest_atom['atom_x'], dest_atom['atom_y'], dest_atom['atom_z']]
-        )
-        from_coords = np.array(
-            [from_atom['atom_x'], from_atom['atom_y'], from_atom['atom_z']]
-        )
-        squared_dist = np.sum(np.square(dest_coords - from_coords))
-        squared_threshold = 2.4 * 2.4
-        if squared_dist > squared_threshold:
-          num_bad_bonds += 1
-          include_bond.append(False)
-          continue
-      include_bond.append(True)
-    if sum(include_bond) < len(struc.bonds):
-      logging.info(
-          'Reducing number of bonds for %s from %s to %s, of which %s are'
-          ' polymer-polymer bonds and %s are bad bonds.',
-          struc.name,
-          len(struc.bonds),
-          sum(include_bond),
-          num_pp_bonds,
-          num_bad_bonds,
-      )
-      if sum(include_bond) > 0:
-        # Need to index bonds with bond keys or arrays of bools with same length
-        # as num bonds. In this case, we use array of bools (as elsewhere in the
-        # cleaning code).
-        new_bonds = struc.bonds[np.array(include_bond, dtype=bool)]
-      else:
-        new_bonds = structure.Bonds.make_empty()
-      struc = struc.copy_and_update(bonds=new_bonds)
-
-  if struc.bonds and remove_nonsymmetric_bonds:
-    # Check for asymmetric polymer-ligand bonds and remove if these exist.
-    polymer_ligand_bonds = inter_chain_bonds.get_polymer_ligand_bonds(
-        struc,
-        only_glycan_ligands=False,
-    )
-    if polymer_ligand_bonds:
-      if covalent_bond_cleaning.has_nonsymmetric_bonds_on_symmetric_polymer_chains(
-          struc, polymer_ligand_bonds
-      ):
-        from_atom_idxs, dest_atom_idxs = struc.bonds.get_atom_indices(
-            struc.atom_key
-        )
-        poly_chain_types = list(mmcif_names.POLYMER_CHAIN_TYPES)
-        is_polymer_bond = np.logical_or(
-            np.isin(struc.chain_type[from_atom_idxs], poly_chain_types),
-            np.isin(struc.chain_type[dest_atom_idxs], poly_chain_types),
-        )
-        struc = struc.copy_and_update(bonds=struc.bonds[~is_polymer_bond])
-
-  return struc, metadata
-
-
-def create_empty_output_struc_and_layout(
-    struc: structure.Structure,
-    ccd: chemical_components.Ccd,
-    *,
-    with_hydrogens: bool = False,
-    skip_unk: bool = False,
-    polymer_ligand_bonds: atom_layout.AtomLayout | None = None,
-    ligand_ligand_bonds: atom_layout.AtomLayout | None = None,
-    drop_ligand_leaving_atoms: bool = False,
-) -> tuple[structure.Structure, atom_layout.AtomLayout]:
-  """Make zero-coordinate structure from all physical residues.
-
-  Args:
-    struc: Structure object.
-    ccd: The chemical components dictionary.
-    with_hydrogens: Whether to keep hydrogen atoms in structure.
-    skip_unk: Whether to remove unknown residues from structure.
-    polymer_ligand_bonds: Bond information for polymer-ligand pairs.
-    ligand_ligand_bonds: Bond information for ligand-ligand pairs.
-    drop_ligand_leaving_atoms: Flag for handling leaving atoms for ligands.
-
-  Returns:
-    Tuple of structure with all bonds, physical residues and coordinates set to
-    0 and a flat atom layout of empty structure.
-  """
-  bonded_atom_pairs = []
-  if polymer_ligand_bonds:
-    for chain_ids, res_ids, atom_names in zip(
-        polymer_ligand_bonds.chain_id,
-        polymer_ligand_bonds.res_id,
-        polymer_ligand_bonds.atom_name,
-        strict=True,
-    ):
-      bonded_atom_pairs.append((
-          (chain_ids[0], res_ids[0], atom_names[0]),
-          (chain_ids[1], res_ids[1], atom_names[1]),
-      ))
-  if ligand_ligand_bonds:
-    for chain_ids, res_ids, atom_names in zip(
-        ligand_ligand_bonds.chain_id,
-        ligand_ligand_bonds.res_id,
-        ligand_ligand_bonds.atom_name,
-        strict=True,
-    ):
-      bonded_atom_pairs.append((
-          (chain_ids[0], res_ids[0], atom_names[0]),
-          (chain_ids[1], res_ids[1], atom_names[1]),
-      ))
-  residues = atom_layout.residues_from_structure(
-      struc, include_missing_residues=True
-  )
-
-  flat_output_layout = atom_layout.make_flat_atom_layout(
-      residues,
-      ccd=ccd,
-      with_hydrogens=with_hydrogens,
-      skip_unk_residues=skip_unk,
-      polymer_ligand_bonds=polymer_ligand_bonds,
-      ligand_ligand_bonds=ligand_ligand_bonds,
-      drop_ligand_leaving_atoms=drop_ligand_leaving_atoms,
-  )
-
-  empty_output_struc = atom_layout.make_structure(
-      flat_layout=flat_output_layout,
-      atom_coords=np.zeros((flat_output_layout.shape[0], 3)),
-      name=struc.name,
-      atom_b_factors=None,
-      all_physical_residues=residues,
-  )
-  if bonded_atom_pairs:
-    empty_output_struc = empty_output_struc.add_bonds(
-        bonded_atom_pairs, bond_type=mmcif_names.COVALENT_BOND
-    )
-
-  return empty_output_struc, flat_output_layout
diff --git a/src/alphafold3/model/post_processing.py b/src/alphafold3/model/post_processing.py
deleted file mode 100644
index 0f913429b97623c9f57f047d20d60c1dacfdf6cc..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/post_processing.py
+++ /dev/null
@@ -1,125 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Post-processing utilities for AlphaFold inference results."""
-
-import dataclasses
-import datetime
-import os
-
-from alphafold3 import version
-from alphafold3.model import confidence_types
-from alphafold3.model import mmcif_metadata
-from alphafold3.model import model
-import numpy as np
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class ProcessedInferenceResult:
-  """Stores attributes of a processed inference result.
-
-  Attributes:
-    cif: CIF file containing an inference result.
-    mean_confidence_1d: Mean 1D confidence calculated from confidence_1d.
-    ranking_score: Ranking score extracted from CIF metadata.
-    structure_confidence_summary_json: Content of JSON file with structure
-      confidences summary calculated from CIF file.
-    structure_full_data_json: Content of JSON file with structure full
-      confidences calculated from CIF file.
-    model_id: Identifier of the model that produced the inference result.
-  """
-
-  cif: bytes
-  mean_confidence_1d: float
-  ranking_score: float
-  structure_confidence_summary_json: bytes
-  structure_full_data_json: bytes
-  model_id: bytes
-
-
-def post_process_inference_result(
-    inference_result: model.InferenceResult,
-) -> ProcessedInferenceResult:
-  """Returns cif, confidence_1d_json, confidence_2d_json, mean_confidence_1d, and ranking confidence."""
-
-  # Add mmCIF metadata fields.
-  timestamp = datetime.datetime.now().isoformat(sep=' ', timespec='seconds')
-  cif_with_metadata = mmcif_metadata.add_metadata_to_mmcif(
-      old_cif=inference_result.predicted_structure.to_mmcif_dict(),
-      version=f'{version.__version__} @ {timestamp}',
-      model_id=inference_result.model_id,
-  )
-  cif = mmcif_metadata.add_legal_comment(cif_with_metadata.to_string())
-  cif = cif.encode('utf-8')
-  confidence_1d = confidence_types.AtomConfidence.from_inference_result(
-      inference_result
-  )
-  mean_confidence_1d = np.mean(confidence_1d.confidence)
-  structure_confidence_summary_json = (
-      confidence_types.StructureConfidenceSummary.from_inference_result(
-          inference_result
-      )
-      .to_json()
-      .encode('utf-8')
-  )
-  structure_full_data_json = (
-      confidence_types.StructureConfidenceFull.from_inference_result(
-          inference_result
-      )
-      .to_json()
-      .encode('utf-8')
-  )
-  return ProcessedInferenceResult(
-      cif=cif,
-      mean_confidence_1d=mean_confidence_1d,
-      ranking_score=float(inference_result.metadata['ranking_score']),
-      structure_confidence_summary_json=structure_confidence_summary_json,
-      structure_full_data_json=structure_full_data_json,
-      model_id=inference_result.model_id,
-  )
-
-
-def write_output(
-    inference_result: model.InferenceResult,
-    output_dir: os.PathLike[str] | str,
-    terms_of_use: str | None = None,
-    name: str | None = None,
-) -> None:
-  """Writes processed inference result to a directory."""
-  processed_result = post_process_inference_result(inference_result)
-
-  prefix = f'{name}_' if name is not None else ''
-
-  with open(os.path.join(output_dir, f'{prefix}model.cif'), 'wb') as f:
-    f.write(processed_result.cif)
-
-  with open(
-      os.path.join(output_dir, f'{prefix}summary_confidences.json'), 'wb'
-  ) as f:
-    f.write(processed_result.structure_confidence_summary_json)
-
-  with open(os.path.join(output_dir, f'{prefix}confidences.json'), 'wb') as f:
-    f.write(processed_result.structure_full_data_json)
-
-  if terms_of_use is not None:
-    with open(os.path.join(output_dir, 'TERMS_OF_USE.md'), 'wt') as f:
-      f.write(terms_of_use)
-
-
-def write_embeddings(
-    embeddings: dict[str, np.ndarray],
-    output_dir: os.PathLike[str] | str,
-    name: str | None = None,
-) -> None:
-  """Writes embeddings to a directory."""
-  prefix = f'{name}_' if name is not None else ''
-
-  with open(os.path.join(output_dir, f'{prefix}embeddings.npz'), 'wb') as f:
-    np.savez_compressed(f, **embeddings)
diff --git a/src/alphafold3/model/protein_data_processing.py b/src/alphafold3/model/protein_data_processing.py
deleted file mode 100644
index d2f800ab07c94dc6272bd2615f37ac5bdb6617b5..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/protein_data_processing.py
+++ /dev/null
@@ -1,126 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Process Structure Data."""
-
-from alphafold3.constants import atom_types
-from alphafold3.constants import residue_names
-from alphafold3.constants import side_chains
-import numpy as np
-
-
-NUM_DENSE = atom_types.DENSE_ATOM_NUM
-NUM_AA = len(residue_names.PROTEIN_TYPES)
-NUM_AA_WITH_UNK_AND_GAP = len(
-    residue_names.PROTEIN_TYPES_ONE_LETTER_WITH_UNKNOWN_AND_GAP
-)
-NUM_RESTYPES_WITH_UNK_AND_GAP = (
-    residue_names.POLYMER_TYPES_NUM_WITH_UNKNOWN_AND_GAP
-)
-
-
-def _make_restype_rigidgroup_dense_atom_idx():
-  """Create Mapping from rigid_groups to dense_atom indices."""
-  # Create an array with the atom names.
-  # shape (num_restypes, num_rigidgroups, 3_atoms):
-  # (31, 8, 3)
-  base_atom_indices = np.zeros(
-      (NUM_RESTYPES_WITH_UNK_AND_GAP, 8, 3), dtype=np.int32
-  )
-
-  # 4,5,6,7: 'chi1,2,3,4-group'
-  for restype, restype_letter in enumerate(
-      residue_names.PROTEIN_TYPES_ONE_LETTER
-  ):
-    resname = residue_names.PROTEIN_COMMON_ONE_TO_THREE[restype_letter]
-
-    dense_atom_names = atom_types.ATOM14[resname]
-    # 0: backbone frame
-    base_atom_indices[restype, 0, :] = [
-        dense_atom_names.index(atom) for atom in ['C', 'CA', 'N']
-    ]
-
-    # 3: 'psi-group'
-    base_atom_indices[restype, 3, :] = [
-        dense_atom_names.index(atom) for atom in ['CA', 'C', 'O']
-    ]
-    for chi_idx in range(4):
-      if side_chains.CHI_ANGLES_MASK[restype][chi_idx]:
-        atom_names = side_chains.CHI_ANGLES_ATOMS[resname][chi_idx]
-        base_atom_indices[restype, chi_idx + 4, :] = [
-            dense_atom_names.index(atom) for atom in atom_names[1:]
-        ]
-  dense_atom_names = atom_types.DENSE_ATOM['A']
-  nucleic_rigid_atoms = [
-      dense_atom_names.index(atom) for atom in ["C1'", "C3'", "C4'"]
-  ]
-  for nanum, _ in enumerate(residue_names.NUCLEIC_TYPES):
-    # 0: backbone frame only.
-    # we have aa + unk + gap, so we want to start after those
-    resnum = nanum + NUM_AA_WITH_UNK_AND_GAP
-    base_atom_indices[resnum, 0, :] = nucleic_rigid_atoms
-
-  return base_atom_indices
-
-
-RESTYPE_RIGIDGROUP_DENSE_ATOM_IDX = _make_restype_rigidgroup_dense_atom_idx()
-
-
-def _make_restype_pseudobeta_idx():
-  """Returns indices of residue's pseudo-beta."""
-  restype_pseudobeta_index = np.zeros(
-      (NUM_RESTYPES_WITH_UNK_AND_GAP,), dtype=np.int32
-  )
-  for restype, restype_letter in enumerate(
-      residue_names.PROTEIN_TYPES_ONE_LETTER
-  ):
-    restype_name = residue_names.PROTEIN_COMMON_ONE_TO_THREE[restype_letter]
-    atom_names = list(atom_types.ATOM14[restype_name])
-    if restype_name in {'GLY'}:
-      restype_pseudobeta_index[restype] = atom_names.index('CA')
-    else:
-      restype_pseudobeta_index[restype] = atom_names.index('CB')
-  for nanum, resname in enumerate(residue_names.NUCLEIC_TYPES):
-    atom_names = list(atom_types.DENSE_ATOM[resname])
-    # 0: backbone frame only.
-    # we have aa + unk , so we want to start after those
-    restype = nanum + NUM_AA_WITH_UNK_AND_GAP
-    if resname in {'A', 'G', 'DA', 'DG'}:
-      restype_pseudobeta_index[restype] = atom_names.index('C4')
-    else:
-      restype_pseudobeta_index[restype] = atom_names.index('C2')
-  return restype_pseudobeta_index
-
-
-RESTYPE_PSEUDOBETA_INDEX = _make_restype_pseudobeta_idx()
-
-
-def _make_aatype_dense_atom_to_atom37():
-  """Map from dense_atom to atom37 per residue type."""
-  restype_dense_atom_to_atom37 = []  # mapping (restype, dense_atom) --> atom37
-  for rt in residue_names.PROTEIN_TYPES_ONE_LETTER:
-    atom_names = list(
-        atom_types.ATOM14_PADDED[residue_names.PROTEIN_COMMON_ONE_TO_THREE[rt]]
-    )
-    atom_names.extend([''] * (NUM_DENSE - len(atom_names)))
-    restype_dense_atom_to_atom37.append(
-        [(atom_types.ATOM37_ORDER[name] if name else 0) for name in atom_names]
-    )
-  # Add dummy mapping for restype 'UNK', '-' (gap), and nucleics [but not DN].
-  for _ in range(2 + len(residue_names.NUCLEIC_TYPES_WITH_UNKNOWN)):
-    restype_dense_atom_to_atom37.append([0] * NUM_DENSE)
-
-  restype_dense_atom_to_atom37 = np.array(
-      restype_dense_atom_to_atom37, dtype=np.int32
-  )
-  return restype_dense_atom_to_atom37
-
-
-PROTEIN_AATYPE_DENSE_ATOM_TO_ATOM37 = _make_aatype_dense_atom_to_atom37()
diff --git a/src/alphafold3/model/scoring/alignment.py b/src/alphafold3/model/scoring/alignment.py
deleted file mode 100644
index f417007752d0db9d4eaccc4eecfbd1ffb663efe4..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/scoring/alignment.py
+++ /dev/null
@@ -1,147 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Alignment based metrics."""
-
-import numpy as np
-
-
-def transform_ls(
-    x: np.ndarray,
-    b: np.ndarray,
-    *,
-    allow_reflection: bool = False,
-) -> np.ndarray:
-  """Find the least squares best fit rotation between two sets of N points.
-
-  Solve Ax = b for A. Where A is the transform rotating x^T into b^T.
-
-  Args:
-    x: NxD numpy array of coordinates. Usually dimension D is 3.
-    b: NxD numpy array of coordinates. Usually dimension D is 3.
-    allow_reflection: Whether the returned transformation can reflect as well as
-      rotate.
-
-  Returns:
-    Matrix A transforming x into b, i.e. s.t. Ax^T = b^T.
-  """
-  assert x.shape[1] >= b.shape[1]
-  assert b.shape[0] == x.shape[0], '%d, %d' % (b.shape[0], x.shape[0])
-  # First postmultiply by x.;
-  # Axx^t = b x^t
-  bxt = np.dot(b.transpose(), x) / b.shape[0]
-
-  u, _, v = np.linalg.svd(bxt)
-
-  r = np.dot(u, v)
-  if not allow_reflection:
-    flip = np.ones((v.shape[1], 1))
-    flip[v.shape[1] - 1, 0] = np.sign(np.linalg.det(r))
-    r = np.dot(u, v * flip)
-
-  return r
-
-
-def align(
-    *,
-    x: np.ndarray,
-    y: np.ndarray,
-    x_indices: np.ndarray,
-    y_indices: np.ndarray,
-) -> np.ndarray:
-  """Align x to y considering only included_idxs.
-
-  Args:
-    x: NxD np array of coordinates.
-    y: NxD np array of coordinates.
-    x_indices: An np array of indices for `x` that will be used in the
-      alignment. Must be of the same length as `y_included_idxs`.
-    y_indices: An np array of indices for `y` that will be used in the
-      alignment. Must be of the same length as `x_included_idxs`.
-
-  Returns:
-    NxD np array of points obtained by applying a rigid transformation to x.
-    These points are aligned to y and the alignment is the optimal alignment
-    over the points in included_idxs.
-
-  Raises:
-    ValueError: If the number of included indices is not the same for both
-    input arrays.
-  """
-  if len(x_indices) != len(y_indices):
-    raise ValueError(
-        'Number of included indices must be the same for both input arrays,'
-        f' but got for x: {len(x_indices)}, and for y: {len(y_indices)}.'
-    )
-
-  x_mean = np.mean(x[x_indices, :], axis=0)
-  y_mean = np.mean(y[y_indices, :], axis=0)
-
-  centered_x = x - x_mean
-  centered_y = y - y_mean
-
-  t = transform_ls(centered_x[x_indices, :], centered_y[y_indices, :])
-  transformed_x = np.dot(centered_x, t.transpose()) + y_mean
-
-  return transformed_x
-
-
-def deviations_from_coords(
-    decoy_coords: np.ndarray,
-    gt_coords: np.ndarray,
-    align_idxs: np.ndarray | None = None,
-    include_idxs: np.ndarray | None = None,
-) -> np.ndarray:
-  """Returns the raw per-atom deviations used in RMSD computation."""
-  if decoy_coords.shape != gt_coords.shape:
-    raise ValueError(
-        'decoy_coords.shape and gt_coords.shape must match.Found: %s and %s.'
-        % (decoy_coords.shape, gt_coords.shape)
-    )
-  # Include and align all residues unless specified otherwise.
-  if include_idxs is None:
-    include_idxs = np.arange(decoy_coords.shape[0])
-  if align_idxs is None:
-    align_idxs = include_idxs
-  aligned_decoy_coords = align(
-      x=decoy_coords,
-      y=gt_coords,
-      x_indices=align_idxs,
-      y_indices=align_idxs,
-  )
-  deviations = np.linalg.norm(
-      aligned_decoy_coords[include_idxs] - gt_coords[include_idxs], axis=1
-  )
-  return deviations
-
-
-def rmsd_from_coords(
-    decoy_coords: np.ndarray,
-    gt_coords: np.ndarray,
-    align_idxs: np.ndarray | None = None,
-    include_idxs: np.ndarray | None = None,
-) -> float:
-  """Computes the *aligned* RMSD of two Mx3 np arrays of coordinates.
-
-  Args:
-    decoy_coords: [M, 3] np array of decoy atom coordinates.
-    gt_coords: [M, 3] np array of gt atom coordinates.
-    align_idxs: [M] np array of indices specifying coordinates to align on.
-      Defaults to None, in which case all the include_idx (see after) are used.
-    include_idxs: [M] np array of indices specifying coordinates to score.
-      Defaults to None, in which case all indices are used for scoring.
-
-  Returns:
-    rmsd value of the aligned decoy and gt coordinates.
-  """
-  deviations = deviations_from_coords(
-      decoy_coords, gt_coords, align_idxs, include_idxs
-  )
-  return np.sqrt(np.mean(np.square(deviations)))
diff --git a/src/alphafold3/model/scoring/chirality.py b/src/alphafold3/model/scoring/chirality.py
deleted file mode 100644
index 249fcca164b212288fee97b98c67aa8b3fda499b..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/scoring/chirality.py
+++ /dev/null
@@ -1,190 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Chirality detection and comparison."""
-
-from collections.abc import Mapping
-
-from absl import logging
-from alphafold3 import structure
-from alphafold3.constants import chemical_components
-from alphafold3.data.tools import rdkit_utils
-import rdkit.Chem as rd_chem
-
-_CHIRAL_ELEMENTS = frozenset({'C', 'S'})
-
-
-def _find_chiral_centres(mol: rd_chem.Mol) -> dict[str, str]:
-  """Find chiral centres and detect their chirality.
-
-  Only elements listed in _CHIRAL_ELEMENTS are considered as centres.
-
-  Args:
-    mol: The molecule for which to detect chirality.
-
-  Returns:
-    Map from chiral centre atom names to identified chirality.
-  """
-  chiral_centres = rd_chem.FindMolChiralCenters(
-      mol, force=True, includeUnassigned=False, useLegacyImplementation=True
-  )
-  atom_name_by_idx = {
-      atom.GetIdx(): atom.GetProp('atom_name') for atom in mol.GetAtoms()
-  }
-  atom_chirality_by_name = {atom_name_by_idx[k]: v for k, v in chiral_centres}
-  return {
-      k: v
-      for k, v in atom_chirality_by_name.items()
-      if any(k[: len(el)].upper() == el for el in _CHIRAL_ELEMENTS)
-  }
-
-
-def _chiral_match(mol1: rd_chem.Mol, mol2: rd_chem.Mol) -> bool:
-  """Compares chirality of two Mols. Mol1 can match a subset of mol2."""
-
-  mol1_atom_names = {a.GetProp('atom_name') for a in mol1.GetAtoms()}
-  mol2_atom_names = {a.GetProp('atom_name') for a in mol2.GetAtoms()}
-  if mol1_atom_names != mol2_atom_names:
-    if not mol1_atom_names.issubset(mol2_atom_names):
-      raise ValueError('Mol1 atoms are not a subset of mol2 atoms.')
-
-  mol1_chiral_centres = _find_chiral_centres(mol1)
-  mol2_chiral_centres = _find_chiral_centres(mol2)
-  if set(mol1_chiral_centres) != set(mol2_chiral_centres):
-    if not set(mol1_chiral_centres).issubset(mol2_chiral_centres):
-      return False
-  chirality_matches = {
-      centre_atom: chirality1 == mol2_chiral_centres[centre_atom]
-      for centre_atom, chirality1 in mol1_chiral_centres.items()
-      if '?' != mol2_chiral_centres[centre_atom]
-  }
-  return all(chirality_matches.values())
-
-
-def _mol_from_ligand_struc(
-    ligand_struc: structure.Structure,
-    ref_mol: rd_chem.Mol,
-) -> rd_chem.Mol | None:
-  """Creates a Mol object from a ligand structure and reference mol."""
-
-  if ligand_struc.num_residues(count_unresolved=True) > 1:
-    raise ValueError('ligand_struc %s has more than one residue.')
-  coords_by_atom_name = dict(zip(ligand_struc.atom_name, ligand_struc.coords))
-
-  ref_mol = rdkit_utils.sanitize_mol(
-      ref_mol,
-      sort_alphabetically=False,
-      remove_hydrogens=True,
-  )
-
-  mol = rd_chem.Mol(ref_mol)
-  mol.RemoveAllConformers()
-
-  atom_indices_to_remove = [
-      a.GetIdx()
-      for a in mol.GetAtoms()
-      if a.GetProp('atom_name') not in coords_by_atom_name
-  ]
-  editable_mol = rd_chem.EditableMol(mol)
-  # Remove indices from the largest to smallest, to avoid invalidating.
-  for atom_idx in atom_indices_to_remove[::-1]:
-    editable_mol.RemoveAtom(atom_idx)
-  mol = editable_mol.GetMol()
-
-  conformer = rd_chem.Conformer(mol.GetNumAtoms())
-  for atom_idx, atom in enumerate(mol.GetAtoms()):
-    atom_name = atom.GetProp('atom_name')
-    coords = coords_by_atom_name[atom_name]
-    conformer.SetAtomPosition(atom_idx, coords.tolist())
-  mol.AddConformer(conformer)
-  try:
-    rd_chem.AssignStereochemistryFrom3D(mol)
-  except RuntimeError as e:
-    # Catch only this specific rdkit error.
-    if 'Cannot normalize a zero length vector' in str(e):
-      return None
-    else:
-      raise
-  return mol
-
-
-def _maybe_mol_from_ccd(res_name: str) -> rd_chem.Mol | None:
-  """Creates a Mol object from CCD information if res_name is in the CCD."""
-  ccd = chemical_components.cached_ccd()
-  ccd_cif = ccd.get(res_name)
-  if not ccd_cif:
-    logging.warning('No ccd information for residue %s.', res_name)
-    return None
-  try:
-    mol = rdkit_utils.mol_from_ccd_cif(ccd_cif, force_parse=False)
-  except rdkit_utils.MolFromMmcifError as e:
-    logging.warning('Failed to create mol from ccd for %s: %s', res_name, e)
-    return None
-  if mol is None:
-    raise ValueError('Failed to create mol from ccd for %s.' % res_name)
-  mol = rdkit_utils.sanitize_mol(
-      mol,
-      sort_alphabetically=False,
-      remove_hydrogens=True,
-  )
-  return mol
-
-
-def compare_chirality(
-    test_struc: structure.Structure,
-    ref_mol_by_chain: Mapping[str, rd_chem.Mol] | None = None,
-) -> dict[str, bool]:
-  """Compares chirality of ligands in a structure with reference molecules.
-
-  We do not enforce that ligand atoms exactly match, only that the ligand atoms
-  and chiral centres are a subset of those in ref mol.
-
-  Args:
-    test_struc: The structure for whose ligands to match chirality.
-    ref_mol_by_chain: Optional dictionary mapping chain IDs to mol objects with
-      conformers to compare against. If this is not provided, the comparison is
-      to the corresponding ligands in the CCD if the ligand residue name is in
-      the CCD.
-
-  Returns:
-    Dictionary mapping chain id to whether chirality mismatches the ref mol.
-    Only single residue ligands where reference molecules are available are
-    compared.
-  """
-  ref_mol_by_chain = ref_mol_by_chain or {}
-  test_struc = test_struc.filter_to_entity_type(ligand=True)
-  name = test_struc.name
-  chiral_match_by_chain_id = {}
-  for chain_id in test_struc.chains:
-    chain_struc = test_struc.filter(chain_id=chain_id)
-    # Only compare single-residue ligands.
-    if chain_struc.num_residues(count_unresolved=True) > 1:
-      logging.warning('%s: Chain %s has >1 residues. Skipping.', name, chain_id)
-      continue
-    if chain_id not in ref_mol_by_chain:
-      ref_mol = _maybe_mol_from_ccd(chain_struc.res_name[0])
-    else:
-      ref_mol = ref_mol_by_chain[chain_id]
-    if ref_mol is None:
-      logging.warning(
-          '%s: Ref mol is None for chain %s. Skipping.', name, chain_id
-      )
-      continue
-    mol = _mol_from_ligand_struc(
-        ligand_struc=chain_struc,
-        ref_mol=ref_mol,
-    )
-    if mol is None:
-      logging.warning(
-          '%s: Failed to create mol for chain %s. Skipping.', name, chain_id
-      )
-      continue
-    chiral_match_by_chain_id[chain_id] = _chiral_match(mol, ref_mol)
-  return chiral_match_by_chain_id
diff --git a/src/alphafold3/model/scoring/covalent_bond_cleaning.py b/src/alphafold3/model/scoring/covalent_bond_cleaning.py
deleted file mode 100644
index 376340110d0df3a4a68905e9a898a20010791f44..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/scoring/covalent_bond_cleaning.py
+++ /dev/null
@@ -1,265 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Some methods to compute metrics for PTMs."""
-
-import collections
-from collections.abc import Mapping
-import dataclasses
-
-from alphafold3 import structure
-from alphafold3.constants import mmcif_names
-from alphafold3.model.atom_layout import atom_layout
-import numpy as np
-
-
-@dataclasses.dataclass(frozen=True)
-class ResIdMapping:
-  old_res_ids: np.ndarray
-  new_res_ids: np.ndarray
-
-
-def _count_symmetric_chains(struc: structure.Structure) -> Mapping[str, int]:
-  """Returns a dict with each chain ID and count."""
-  chain_res_name_sequence_from_chain_id = struc.chain_res_name_sequence(
-      include_missing_residues=True, fix_non_standard_polymer_res=False
-  )
-  counts_for_chain_res_name_sequence = collections.Counter(
-      chain_res_name_sequence_from_chain_id.values()
-  )
-  chain_symmetric_count = {}
-  for chain_id, chain_res_name in chain_res_name_sequence_from_chain_id.items():
-    chain_symmetric_count[chain_id] = counts_for_chain_res_name_sequence[
-        chain_res_name
-    ]
-  return chain_symmetric_count
-
-
-def has_nonsymmetric_bonds_on_symmetric_polymer_chains(
-    struc: structure.Structure, polymer_ligand_bonds: atom_layout.AtomLayout
-) -> bool:
-  """Returns true if nonsymmetric bonds found on polymer chains."""
-  try:
-    _get_polymer_dim(polymer_ligand_bonds)
-  except ValueError:
-    return True
-  if _has_non_polymer_ligand_ptm_bonds(polymer_ligand_bonds):
-    return True
-  if _has_multiple_polymers_bonded_to_one_ligand(polymer_ligand_bonds):
-    return True
-  combined_struc, _ = _combine_polymer_ligand_ptm_chains(
-      struc, polymer_ligand_bonds
-  )
-  struc = struc.filter(chain_type=mmcif_names.POLYMER_CHAIN_TYPES)
-  combined_struc = combined_struc.filter(
-      chain_type=mmcif_names.POLYMER_CHAIN_TYPES
-  )
-  return _count_symmetric_chains(struc) != _count_symmetric_chains(
-      combined_struc
-  )
-
-
-def _has_non_polymer_ligand_ptm_bonds(
-    polymer_ligand_bonds: atom_layout.AtomLayout,
-):
-  """Checks if all bonds are between a polymer chain and a ligand chain type."""
-  for start_chain_type, end_chain_type in polymer_ligand_bonds.chain_type:
-    if (
-        start_chain_type in mmcif_names.POLYMER_CHAIN_TYPES
-        and end_chain_type in mmcif_names.LIGAND_CHAIN_TYPES
-    ):
-      continue
-    elif (
-        start_chain_type in mmcif_names.LIGAND_CHAIN_TYPES
-        and end_chain_type in mmcif_names.POLYMER_CHAIN_TYPES
-    ):
-      continue
-    else:
-      return True
-  return False
-
-
-def _combine_polymer_ligand_ptm_chains(
-    struc: structure.Structure,
-    polymer_ligand_bonds: atom_layout.AtomLayout,
-) -> tuple[structure.Structure, dict[tuple[str, str], ResIdMapping]]:
-  """Combines the ptm polymer-ligand chains together.
-
-  This will prevent them from being permuted away from each other when chains
-  are matched to the ground truth. This function also returns the res_id mapping
-  from the separate ligand res_ids to their res_ids in the combined
-  polymer-ligand chain; this information is needed to later separate the
-  combined polymer-ligand chain.
-
-  Args:
-    struc: Structure to be modified.
-    polymer_ligand_bonds: AtomLayout with polymer-ligand bond info.
-
-  Returns:
-    A tuple of a Structure with each ptm polymer-ligand chain relabelled as one
-    chain and a dict from bond chain pair to the res_id mapping.
-  """
-  if not _has_only_single_bond_from_each_chain(polymer_ligand_bonds):
-    if _has_multiple_ligands_bonded_to_one_polymer(polymer_ligand_bonds):
-      # For structures where a polymer chain is connected to multiple ligands,
-      # we need to sort the multiple bonds from the same chain by res_id to
-      # ensure that the combined polymer-ligand chain will always be the same
-      # when you have repeated symmetric polymer-ligand chains.
-      polymer_ligand_bonds = (
-          _sort_polymer_ligand_bonds_by_polymer_chain_and_res_id(
-              polymer_ligand_bonds
-          )
-      )
-    else:
-      raise ValueError(
-          'Code cannot handle multiple bonds from one chain unless'
-          ' its several ligands bonded to a polymer.'
-      )
-  res_id_mappings_for_bond_chain_pair = dict()
-  for (start_chain_id, end_chain_id), (start_chain_type, end_chain_type) in zip(
-      polymer_ligand_bonds.chain_id, polymer_ligand_bonds.chain_type
-  ):
-    poly_info, ligand_info = _get_polymer_and_ligand_chain_ids_and_types(
-        start_chain_id, end_chain_id, start_chain_type, end_chain_type
-    )
-    polymer_chain_id, polymer_chain_type = poly_info
-    ligand_chain_id, _ = ligand_info
-
-    # Join the ligand chain to the polymer chain.
-    ligand_res_ids = struc.filter(chain_id=ligand_chain_id).res_id
-    new_res_ids = ligand_res_ids + len(struc.all_residues[polymer_chain_id])
-    res_id_mappings_for_bond_chain_pair[(polymer_chain_id, ligand_chain_id)] = (
-        ResIdMapping(old_res_ids=ligand_res_ids, new_res_ids=new_res_ids)
-    )
-    chain_groups = []
-    chain_group_ids = []
-    chain_group_types = []
-    for chain_id, chain_type in zip(
-        struc.chains_table.id, struc.chains_table.type
-    ):
-      if chain_id == ligand_chain_id:
-        continue
-      elif chain_id == polymer_chain_id:
-        chain_groups.append([polymer_chain_id, ligand_chain_id])
-        chain_group_ids.append(polymer_chain_id)
-        chain_group_types.append(polymer_chain_type)
-      else:
-        chain_groups.append([chain_id])
-        chain_group_ids.append(chain_id)
-        chain_group_types.append(chain_type)
-
-    struc = struc.merge_chains(
-        chain_groups=chain_groups,
-        chain_group_ids=chain_group_ids,
-        chain_group_types=chain_group_types,
-    )
-
-  return struc, res_id_mappings_for_bond_chain_pair
-
-
-def _has_only_single_bond_from_each_chain(
-    polymer_ligand_bonds: atom_layout.AtomLayout,
-) -> bool:
-  """Checks that there is at most one bond from each chain."""
-  chain_ids = []
-  for chains in polymer_ligand_bonds.chain_id:
-    chain_ids.extend(chains)
-  if len(chain_ids) != len(set(chain_ids)):
-    return False
-  return True
-
-
-def _get_polymer_and_ligand_chain_ids_and_types(
-    start_chain_id: str,
-    end_chain_id: str,
-    start_chain_type: str,
-    end_chain_type: str,
-) -> tuple[tuple[str, str], tuple[str, str]]:
-  """Finds polymer and ligand chain ids from chain types."""
-  if (
-      start_chain_type in mmcif_names.POLYMER_CHAIN_TYPES
-      and end_chain_type in mmcif_names.LIGAND_CHAIN_TYPES
-  ):
-    return (start_chain_id, start_chain_type), (end_chain_id, end_chain_type)
-  elif (
-      start_chain_type in mmcif_names.LIGAND_CHAIN_TYPES
-      and end_chain_type in mmcif_names.POLYMER_CHAIN_TYPES
-  ):
-    return (end_chain_id, end_chain_type), (start_chain_id, start_chain_type)
-  else:
-    raise ValueError(
-        'This code only handles PTM-bonds from polymer chain to ligands.'
-    )
-
-
-def _get_polymer_dim(polymer_ligand_bonds: atom_layout.AtomLayout) -> int:
-  """Gets polymer dimension from the polymer-ligand bond layout."""
-  start_chain_types = []
-  end_chain_types = []
-  for start_chain_type, end_chain_type in polymer_ligand_bonds.chain_type:
-    start_chain_types.append(start_chain_type)
-    end_chain_types.append(end_chain_type)
-  if set(start_chain_types).issubset(
-      set(mmcif_names.POLYMER_CHAIN_TYPES)
-  ) and set(end_chain_types).issubset(set(mmcif_names.LIGAND_CHAIN_TYPES)):
-    return 0
-  elif set(start_chain_types).issubset(mmcif_names.LIGAND_CHAIN_TYPES) and set(
-      end_chain_types
-  ).issubset(set(mmcif_names.POLYMER_CHAIN_TYPES)):
-    return 1
-  else:
-    raise ValueError(
-        'Polymer and ligand dimensions are not consistent within the structure.'
-    )
-
-
-def _has_multiple_ligands_bonded_to_one_polymer(polymer_ligand_bonds):
-  """Checks if there are multiple ligands bonded to one polymer."""
-  polymer_dim = _get_polymer_dim(polymer_ligand_bonds)
-  polymer_chain_ids = [
-      chains[polymer_dim] for chains in polymer_ligand_bonds.chain_id
-  ]
-  if len(polymer_chain_ids) != len(set(polymer_chain_ids)):
-    return True
-  return False
-
-
-def _has_multiple_polymers_bonded_to_one_ligand(polymer_ligand_bonds):
-  """Checks if there are multiple polymer chains bonded to one ligand."""
-  polymer_dim = _get_polymer_dim(polymer_ligand_bonds)
-  ligand_dim = 1 - polymer_dim
-  ligand_chain_ids = [
-      chains[ligand_dim] for chains in polymer_ligand_bonds.chain_id
-  ]
-  if len(ligand_chain_ids) != len(set(ligand_chain_ids)):
-    return True
-  return False
-
-
-def _sort_polymer_ligand_bonds_by_polymer_chain_and_res_id(
-    polymer_ligand_bonds,
-):
-  """Sorts bonds by res_id (for when a polymer chain has multiple bonded ligands)."""
-
-  polymer_dim = _get_polymer_dim(polymer_ligand_bonds)
-
-  polymer_chain_ids = [
-      chains[polymer_dim] for chains in polymer_ligand_bonds.chain_id
-  ]
-  polymer_res_ids = [res[polymer_dim] for res in polymer_ligand_bonds.res_id]
-
-  polymer_chain_and_res_id = zip(polymer_chain_ids, polymer_res_ids)
-  sorted_indices = [
-      idx
-      for idx, _ in sorted(
-          enumerate(polymer_chain_and_res_id), key=lambda x: x[1]
-      )
-  ]
-  return polymer_ligand_bonds[sorted_indices]
diff --git a/src/alphafold3/model/scoring/scoring.py b/src/alphafold3/model/scoring/scoring.py
deleted file mode 100644
index b19108f4bb91310448f608a9a6a8a92ff30be26e..0000000000000000000000000000000000000000
--- a/src/alphafold3/model/scoring/scoring.py
+++ /dev/null
@@ -1,68 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Library of scoring methods of the model outputs."""
-
-from alphafold3.model import protein_data_processing
-import jax.numpy as jnp
-import numpy as np
-
-
-Array = jnp.ndarray | np.ndarray
-
-
-def pseudo_beta_fn(
-    aatype: Array,
-    dense_atom_positions: Array,
-    dense_atom_masks: Array,
-    is_ligand: Array | None = None,
-    use_jax: bool | None = True,
-) -> tuple[Array, Array] | Array:
-  """Create pseudo beta atom positions and optionally mask.
-
-  Args:
-    aatype: [num_res] amino acid types.
-    dense_atom_positions: [num_res, NUM_DENSE, 3] vector of all atom positions.
-    dense_atom_masks: [num_res, NUM_DENSE] mask.
-    is_ligand: [num_res] flag if something is a ligand.
-    use_jax: whether to use jax for the computations.
-
-  Returns:
-    Pseudo beta dense atom positions and the corresponding mask.
-  """
-  if use_jax:
-    xnp = jnp
-  else:
-    xnp = np
-
-  if is_ligand is None:
-    is_ligand = xnp.zeros_like(aatype)
-
-  pseudobeta_index_polymer = xnp.take(
-      protein_data_processing.RESTYPE_PSEUDOBETA_INDEX, aatype, axis=0
-  ).astype(xnp.int32)
-
-  pseudobeta_index = xnp.where(
-      is_ligand,
-      xnp.zeros_like(pseudobeta_index_polymer),
-      pseudobeta_index_polymer,
-  )
-
-  pseudo_beta = xnp.take_along_axis(
-      dense_atom_positions, pseudobeta_index[..., None, None], axis=-2
-  )
-  pseudo_beta = xnp.squeeze(pseudo_beta, axis=-2)
-
-  pseudo_beta_mask = xnp.take_along_axis(
-      dense_atom_masks, pseudobeta_index[..., None], axis=-1
-  ).astype(xnp.float32)
-  pseudo_beta_mask = xnp.squeeze(pseudo_beta_mask, axis=-1)
-
-  return pseudo_beta, pseudo_beta_mask
diff --git a/src/alphafold3/parsers/cpp/cif_dict.pyi b/src/alphafold3/parsers/cpp/cif_dict.pyi
deleted file mode 100644
index 09d915c845fec7fe0235c7780092f90f1a262fd1..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/cif_dict.pyi
+++ /dev/null
@@ -1,125 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-from typing import Any, ClassVar, Iterable, Iterator, TypeVar, overload
-
-import numpy as np
-
-_T = TypeVar('_T')
-
-class CifDict:
-  class ItemView:
-    def __iter__(self) -> Iterator[tuple[str, list[str]]]: ...
-    def __len__(self) -> int: ...
-
-  class KeyView:
-    @overload
-    def __contains__(self, key: str) -> bool: ...
-    @overload
-    def __contains__(self, key: object) -> bool: ...
-    def __iter__(self) -> Iterator[str]: ...
-    def __len__(self) -> int: ...
-
-  class ValueView:
-    def __iter__(self) -> Iterator[list[str]]: ...
-    def __len__(self) -> int: ...
-
-  def __init__(self, d: dict[str, Iterable[str]]) -> None: ...
-  def copy_and_update(self, d: dict[str, Iterable[str]]) -> CifDict: ...
-  def extract_loop_as_dict(self, prefix: str, index: str) -> dict:
-    """Extracts loop associated with a prefix from mmCIF data as a dict.
-
-    For instance for an mmCIF with these fields:
-    '_a.ix': ['1', '2', '3']
-    '_a.1': ['a.1.1', 'a.1.2', 'a.1.3']
-    '_a.2': ['a.2.1', 'a.2.2', 'a.2.3']
-
-    this function called with prefix='_a.', index='_a.ix' extracts:
-    {'1': {'a.ix': '1', 'a.1': 'a.1.1', 'a.2': 'a.2.1'}
-     '2': {'a.ix': '2', 'a.1': 'a.1.2', 'a.2': 'a.2.2'}
-     '3': {'a.ix': '3', 'a.1': 'a.1.3', 'a.2': 'a.2.3'}}
-
-    Args:
-      prefix: Prefix shared by each of the data items in the loop. The prefix
-        should include the trailing period.
-      index: Which item of loop data should serve as the key.
-
-    Returns:
-      Dict of dicts; each dict represents 1 entry from an mmCIF loop,
-      indexed by the index column.
-    """
-
-  def extract_loop_as_list(self, prefix: str) -> list:
-    """Extracts loop associated with a prefix from mmCIF data as a list.
-
-    Reference for loop_ in mmCIF:
-    http://mmcif.wwpdb.org/docs/tutorials/mechanics/pdbx-mmcif-syntax.html
-
-    For instance for an mmCIF with these fields:
-    '_a.1': ['a.1.1', 'a.1.2', 'a.1.3']
-    '_a.2': ['a.2.1', 'a.2.2', 'a.2.3']
-
-    this function called with prefix='_a.' extracts:
-    [{'_a.1': 'a.1.1', '_a.2': 'a.2.1'}
-     {'_a.1': 'a.1.2', '_a.2': 'a.2.2'}
-     {'_a.1': 'a.1.3', '_a.2': 'a.2.3'}]
-
-    Args:
-      prefix: Prefix shared by each of the data items in the loop. The prefix
-        should include the trailing period.
-
-    Returns:
-      A list of dicts; each dict represents 1 entry from an mmCIF loop.
-    """
-
-  def get(self, key: str, default_value: _T = ...) -> list[str] | _T: ...
-  def get_array(
-      self, key: str, dtype: object = ..., gather: object = ...
-  ) -> np.ndarray:
-    """Returns values looked up in dict converted to a NumPy array.
-
-    Args:
-      key: Key in dictionary.
-      dtype: Optional (default `object`) Specifies output dtype of array. One of
-        [object, np.{int,uint}{8,16,32,64} np.float{32,64}]. As with NumPy use
-        `object` to return a NumPy array of strings.
-      gather: Optional one of [slice, np.{int,uint}{32,64}] non-intermediate
-        version of get_array(key, dtype)[gather].
-
-    Returns:
-      A NumPy array of given dtype. An optimised equivalent to
-      np.array(cif[key]).astype(dtype).  With support of '.' being treated
-      as np.nan if dtype is one of np.float{32,64}.
-      Identical strings will all reference the same object to save space.
-
-    Raises:
-      KeyError - if key is not found.
-      TypeError - if dtype is not valid or supported.
-      ValueError - if string cannot convert to dtype.
-    """
-
-  def get_data_name(self) -> str: ...
-  def items(self) -> CifDict.ItemView: ...
-  def keys(self) -> CifDict.KeyView: ...
-  def to_string(self) -> str: ...
-  def value_length(self, key: str) -> int: ...
-  def values(self) -> CifDict.ValueView: ...
-  def __bool__(self) -> bool: ...
-  def __contains__(self, key: str) -> bool: ...
-  def __getitem__(self, key: str) -> list[str]: ...
-  def __getstate__(self) -> tuple: ...
-  def __iter__(self) -> Iterator[str]: ...
-  def __len__(self) -> int: ...
-  def __setstate__(self, state: tuple) -> None: ...
-
-def tokenize(cif_string: str) -> list[str]: ...
-def split_line(line: str) -> list[str]: ...
-def from_string(mmcif_string: str | bytes) -> CifDict: ...
-def parse_multi_data_cif(cif_string: str | bytes) -> dict[str, CifDict]: ...
diff --git a/src/alphafold3/parsers/cpp/cif_dict_lib.cc b/src/alphafold3/parsers/cpp/cif_dict_lib.cc
deleted file mode 100644
index b0b0fdbc36b21e51238bbb03d629b132867e5634..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/cif_dict_lib.cc
+++ /dev/null
@@ -1,648 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include "alphafold3/parsers/cpp/cif_dict_lib.h"
-
-#include <algorithm>
-#include <array>
-#include <cstddef>
-#include <iterator>
-#include <memory>
-#include <string>
-#include <tuple>
-#include <utility>
-#include <vector>
-
-#include "absl/algorithm/container.h"
-#include "absl/container/btree_map.h"
-#include "absl/container/flat_hash_map.h"
-#include "absl/container/flat_hash_set.h"
-#include "absl/container/node_hash_map.h"
-#include "absl/log/check.h"
-#include "absl/status/status.h"
-#include "absl/status/statusor.h"
-#include "absl/strings/ascii.h"
-#include "absl/strings/match.h"
-#include "absl/strings/str_cat.h"
-#include "absl/strings/str_format.h"
-#include "absl/strings/str_join.h"
-#include "absl/strings/str_split.h"
-#include "absl/strings/string_view.h"
-#include "absl/strings/strip.h"
-
-namespace alphafold3 {
-namespace {
-
-bool IsQuote(const char symbol) { return symbol == '\'' || symbol == '"'; }
-bool IsWhitespace(const char symbol) { return symbol == ' ' || symbol == '\t'; }
-
-// Splits line into tokens, returns whether successful.
-bool SplitLineInline(absl::string_view line,
-                     std::vector<absl::string_view>* tokens) {
-  // See https://www.iucr.org/resources/cif/spec/version1.1/cifsyntax
-  for (int i = 0, line_length = line.length(); i < line_length;) {
-    // Skip whitespace (spaces or tabs).
-    while (IsWhitespace(line[i])) {
-      if (++i == line_length) {
-        break;
-      }
-    }
-    if (i == line_length) {
-      break;
-    }
-
-    // Skip comments (from # until the end of the line). If # is a non-comment
-    // character, it must be inside a quoted token.
-    if (line[i] == '#') {
-      break;
-    }
-
-    int start_index;
-    int end_index;
-    if (IsQuote(line[i])) {
-      // Token in single or double quotes. CIF v1.1 specification considers a
-      // quote to be an opening quote only if it is at the beginning of a token.
-      // So e.g. A' B has tokens A' and B. Also, ""A" is a token "A.
-      const char quote_char = line[i++];
-      start_index = i;
-
-      // Find matching quote. The double loop is not strictly necessary, but
-      // optimises a bit better.
-      while (true) {
-        while (i < line_length && line[i] != quote_char) {
-          ++i;
-        }
-        if (i == line_length) {
-          // Reached the end of the line while still being inside a token.
-          return false;
-        }
-        if (i + 1 == line_length || IsWhitespace(line[i + 1])) {
-          break;
-        }
-        ++i;
-      }
-      end_index = i++;
-    } else {
-      // Non-quoted token. Read until reaching whitespace.
-      start_index = i++;
-      while (i < line_length && !IsWhitespace(line[i])) {
-        ++i;
-      }
-      end_index = i;
-    }
-
-    tokens->push_back(line.substr(start_index, end_index - start_index));
-  }
-
-  return true;
-}
-
-using HeapStrings = std::vector<std::unique_ptr<std::string>>;
-
-// The majority of strings can be viewed on original cif_string.
-// heap_strings store multi-line tokens that have internal white-space stripped.
-absl::StatusOr<std::vector<absl::string_view>> TokenizeInternal(
-    absl::string_view cif_string, HeapStrings* heap_strings) {
-  const std::vector<absl::string_view> lines = absl::StrSplit(cif_string, '\n');
-  std::vector<absl::string_view> tokens;
-  // Heuristic: Most lines in an mmCIF are _atom_site lines with 21 tokens.
-  tokens.reserve(lines.size() * 21);
-  int line_num = 0;
-  while (line_num < lines.size()) {
-    auto line = lines[line_num];
-    line_num++;
-
-    if (line.empty() || line[0] == '#') {
-      // Skip empty lines or lines that contain only comments.
-      continue;
-    } else if (line[0] == ';') {
-      // Leading whitespace on each line must be preserved while trailing
-      // whitespace may be stripped.
-      std::vector<absl::string_view> multiline_tokens;
-      // Strip the leading ";".
-      multiline_tokens.push_back(
-          absl::StripTrailingAsciiWhitespace(line.substr(1)));
-      while (line_num < lines.size()) {
-        auto multiline = absl::StripTrailingAsciiWhitespace(lines[line_num]);
-        line_num++;
-        if (!multiline.empty() && multiline[0] == ';') {
-          break;
-        }
-        multiline_tokens.push_back(multiline);
-      }
-      heap_strings->push_back(
-          std::make_unique<std::string>(absl::StrJoin(multiline_tokens, "\n")));
-      tokens.emplace_back(*heap_strings->back());
-    } else {
-      if (!SplitLineInline(line, &tokens)) {
-        return absl::InvalidArgumentError(
-            absl::StrCat("Line ended with quote open: ", line));
-      }
-    }
-  }
-  return tokens;
-}
-
-absl::string_view GetEscapeQuote(const absl::string_view value) {
-  // Empty values should not happen, but if so, they should be quoted.
-  if (value.empty()) {
-    return "\"";
-  }
-
-  // Shortcut for the most common cases where no quoting needed.
-  if (std::all_of(value.begin(), value.end(), [](char c) {
-        return absl::ascii_isalnum(c) || c == '.' || c == '?' || c == '-';
-      })) {
-    return "";
-  }
-
-  // The value must not start with one of these CIF keywords.
-  if (absl::StartsWithIgnoreCase(value, "data_") ||
-      absl::StartsWithIgnoreCase(value, "loop_") ||
-      absl::StartsWithIgnoreCase(value, "save_") ||
-      absl::StartsWithIgnoreCase(value, "stop_") ||
-      absl::StartsWithIgnoreCase(value, "global_")) {
-    return "\"";
-  }
-
-  // The first character must not be a special character.
-  const char first = value.front();
-  if (first == '_' || first == '#' || first == '$' || first == '[' ||
-      first == ']' || first == ';') {
-    return "\"";
-  }
-
-  // No quotes or whitespace allowed inside.
-  for (const char c : value) {
-    if (c == '"') {
-      return "'";
-    } else if (c == '\'' || c == ' ' || c == '\t') {
-      return "\"";
-    }
-  }
-  return "";
-}
-
-int RecordIndex(absl::string_view record) {
-  if (record == "_entry") {
-    return 0;  // _entry is always first.
-  }
-  if (record == "_atom_site") {
-    return 2;  // _atom_site is always last.
-  }
-  return 1;  // other records are between _entry and _atom_site.
-}
-
-struct RecordOrder {
-  using is_transparent = void;  // Enable heterogeneous lookup.
-  bool operator()(absl::string_view lhs, absl::string_view rhs) const {
-    std::size_t lhs_index = RecordIndex(lhs);
-    std::size_t rhs_index = RecordIndex(rhs);
-    return std::tie(lhs_index, lhs) < std::tie(rhs_index, rhs);
-  }
-};
-
-// Make sure the _atom_site loop columns are sorted in the PDB-standard way.
-constexpr absl::string_view kAtomSiteSortOrder[] = {
-    "_atom_site.group_PDB",
-    "_atom_site.id",
-    "_atom_site.type_symbol",
-    "_atom_site.label_atom_id",
-    "_atom_site.label_alt_id",
-    "_atom_site.label_comp_id",
-    "_atom_site.label_asym_id",
-    "_atom_site.label_entity_id",
-    "_atom_site.label_seq_id",
-    "_atom_site.pdbx_PDB_ins_code",
-    "_atom_site.Cartn_x",
-    "_atom_site.Cartn_y",
-    "_atom_site.Cartn_z",
-    "_atom_site.occupancy",
-    "_atom_site.B_iso_or_equiv",
-    "_atom_site.pdbx_formal_charge",
-    "_atom_site.auth_seq_id",
-    "_atom_site.auth_comp_id",
-    "_atom_site.auth_asym_id",
-    "_atom_site.auth_atom_id",
-    "_atom_site.pdbx_PDB_model_num",
-};
-
-size_t AtomSiteIndex(absl::string_view atom_site) {
-  return std::distance(std::begin(kAtomSiteSortOrder),
-                       absl::c_find(kAtomSiteSortOrder, atom_site));
-}
-
-struct AtomSiteOrder {
-  bool operator()(absl::string_view lhs, absl::string_view rhs) const {
-    auto lhs_index = AtomSiteIndex(lhs);
-    auto rhs_index = AtomSiteIndex(rhs);
-    return std::tie(lhs_index, lhs) < std::tie(rhs_index, rhs);
-  }
-};
-
-class Column {
- public:
-  Column(absl::string_view key, const std::vector<std::string>* values)
-      : key_(key), values_(values) {
-    int max_value_length = 0;
-    for (size_t i = 0; i < values->size(); ++i) {
-      absl::string_view value = (*values)[i];
-      if (absl::StrContains(value, '\n')) {
-        values_with_newlines_.insert(i);
-      } else {
-        absl::string_view quote = GetEscapeQuote(value);
-        if (!quote.empty()) {
-          values_with_quotes_[i] = quote;
-        }
-        max_value_length =
-            std::max<int>(max_value_length, value.size() + quote.size() * 2);
-      }
-    }
-    max_value_length_ = max_value_length;
-  }
-
-  absl::string_view key() const { return key_; }
-
-  const std::vector<std::string>* values() const { return values_; }
-
-  int max_value_length() const { return max_value_length_; }
-
-  bool has_newlines(size_t index) const {
-    return values_with_newlines_.contains(index);
-  }
-
-  absl::string_view quote(size_t index) const {
-    if (auto it = values_with_quotes_.find(index);
-        it != values_with_quotes_.end()) {
-      return it->second;
-    }
-    return "";
-  }
-
- private:
-  absl::string_view key_;
-  const std::vector<std::string>* values_;
-  int max_value_length_;
-  // Values with newlines or quotes are very rare in a typical CIF file.
-  absl::flat_hash_set<size_t> values_with_newlines_;
-  absl::flat_hash_map<size_t, absl::string_view> values_with_quotes_;
-};
-
-struct GroupedKeys {
-  std::vector<Column> grouped_columns;
-  int max_key_length;
-  int value_size;
-};
-
-}  // namespace
-
-absl::StatusOr<CifDict> CifDict::FromString(absl::string_view cif_string) {
-  CifDict::Dict cif;
-
-  bool loop_flag = false;
-  absl::string_view key;
-
-  HeapStrings heap_strings;
-  auto tokens = TokenizeInternal(cif_string, &heap_strings);
-  if (!tokens.ok()) {
-    return tokens.status();
-  }
-
-  if (tokens->empty()) {
-    return absl::InvalidArgumentError("The CIF file must not be empty.");
-  }
-
-  // The first token should be data_XXX. Split into key = data, value = XXX.
-  absl::string_view first_token = tokens->front();
-  if (!absl::ConsumePrefix(&first_token, "data_")) {
-    return absl::InvalidArgumentError(
-        "The CIF file does not start with the data_ field.");
-  }
-  cif["data_"].emplace_back(first_token);
-
-  // Counters for CIF loop_ regions.
-  int loop_token_index = 0;
-  int num_loop_keys = 0;
-  // Loops have usually O(10) columns but could have up to O(10^6) rows. It is
-  // therefore wasteful to look up the cif vector where to add a loop value
-  // since that means doing `columns * rows` map lookups. If we save pointers to
-  // these loop column fields instead, we need only 1 cif lookup per column.
-  std::vector<std::vector<std::string>*> loop_column_values;
-
-  // Skip the first element since we already processed it above.
-  for (auto token_itr = tokens->begin() + 1; token_itr != tokens->end();
-       ++token_itr) {
-    auto token = *token_itr;
-    if (absl::EqualsIgnoreCase(token, "loop_")) {
-      // A new loop started, get rid of old loop's data.
-      loop_flag = true;
-      loop_column_values.clear();
-      loop_token_index = 0;
-      num_loop_keys = 0;
-      continue;
-    } else if (loop_flag) {
-      // The second condition checks we are in the first column. Some mmCIF
-      // files (e.g. 4q9r) have values in later columns starting with an
-      // underscore and we don't want to read these as keys.
-      int token_column_index =
-          num_loop_keys == 0 ? 0 : loop_token_index % num_loop_keys;
-      if (token_column_index == 0 && !token.empty() && token[0] == '_') {
-        if (loop_token_index > 0) {
-          // We are out of the loop.
-          loop_flag = false;
-        } else {
-          // We are in the keys (column names) section of the loop.
-          auto& columns = cif[token];
-          columns.clear();
-
-          // Heuristic: _atom_site is typically the largest table in an mmCIF
-          // with ~16 columns. Make sure we reserve enough space for its values.
-          if (absl::StartsWith(token, "_atom_site.")) {
-            columns.reserve(tokens->size() / 20);
-          }
-
-          // Save the pointer to the loop column values.
-          loop_column_values.push_back(&columns);
-          num_loop_keys += 1;
-          continue;
-        }
-      } else {
-        // We are in the values section of the loop. We have a pointer to the
-        // loops' values, add the new token in there.
-        if (token_column_index >= loop_column_values.size()) {
-          return absl::InvalidArgumentError(
-              absl::StrCat("Too many columns at: '", token,
-                           "' at column index: ", token_column_index,
-                           " expected at most: ", loop_column_values.size()));
-        }
-        loop_column_values[token_column_index]->emplace_back(token);
-        loop_token_index++;
-        continue;
-      }
-    }
-    if (key.empty()) {
-      key = token;
-    } else {
-      cif[key].emplace_back(token);
-      key = "";
-    }
-  }
-  return CifDict(std::move(cif));
-}
-
-absl::StatusOr<std::string> CifDict::ToString() const {
-  std::string output;
-
-  absl::string_view data_name;
-  // Check that the data_ field exists.
-  if (auto name_it = (*dict_).find("data_");
-      name_it == (*dict_).end() || name_it->second.empty()) {
-    return absl::InvalidArgumentError(
-        "The CIF must contain a valid name for this data block in the special "
-        "data_ field.");
-  } else {
-    data_name = name_it->second.front();
-  }
-
-  if (absl::c_any_of(data_name,
-                     [](char i) { return absl::ascii_isspace(i); })) {
-    return absl::InvalidArgumentError(absl::StrFormat(
-        "The CIF data block name must not contain any whitespace characters, "
-        "got '%s'.",
-        data_name));
-  }
-  absl::StrAppend(&output, "data_", data_name, "\n#\n");
-
-  // Group keys by their prefix. Use btree_map to iterate in alphabetical order,
-  // but with some keys being placed at the end (e.g. _atom_site).
-  absl::btree_map<std::string, GroupedKeys, RecordOrder> grouped_keys;
-  for (const auto& [key, values] : *dict_) {
-    if (key == "data_") {
-      continue;  // Skip the special data_ key, we are already done with it.
-    }
-    const std::pair<absl::string_view, absl::string_view> key_parts =
-        absl::StrSplit(key, absl::MaxSplits('.', 1));
-    const absl::string_view key_prefix = key_parts.first;
-    auto [it, inserted] = grouped_keys.emplace(key_prefix, GroupedKeys{});
-    GroupedKeys& grouped_key = it->second;
-    grouped_key.grouped_columns.push_back(Column(key, &values));
-    if (inserted) {
-      grouped_key.max_key_length = key.length();
-      grouped_key.value_size = values.size();
-    } else {
-      grouped_key.max_key_length =
-          std::max<int>(key.length(), grouped_key.max_key_length);
-      if (grouped_key.value_size != values.size()) {
-        return absl::InvalidArgumentError(
-            absl::StrFormat("Values for key %s have different length (%d) than "
-                            "the other values with the same key prefix (%d).",
-                            key, values.size(), grouped_key.value_size));
-      }
-    }
-  }
-
-  for (auto& [key_prefix, group_info] : grouped_keys) {
-    if (key_prefix == "_atom_site") {
-      // Make sure we sort the _atom_site loop in the standard way.
-      absl::c_sort(group_info.grouped_columns,
-                   [](const Column& lhs, const Column& rhs) {
-                     return AtomSiteOrder{}(lhs.key(), rhs.key());
-                   });
-    } else {
-      // Make the key ordering within a key group deterministic.
-      absl::c_sort(group_info.grouped_columns,
-                   [](const Column& lhs, const Column& rhs) {
-                     return lhs.key() < rhs.key();
-                   });
-    }
-
-    // Force `_atom_site` field to always be a loop. This resolves issues with
-    // third party mmCIF parsers such as OpenBabel which always expect a loop
-    // even when there is only a single atom present.
-    if (group_info.value_size == 1 && key_prefix != "_atom_site") {
-      // Plain key-value pairs, output them as they are.
-      for (const Column& grouped_column : group_info.grouped_columns) {
-        int width = group_info.max_key_length + 1;
-        size_t start_pos = output.size();
-        output.append(width, ' ');
-        auto out_it = output.begin() + start_pos;
-        absl::c_copy(grouped_column.key(), out_it);
-        // Append the value, handle multi-line/quoting.
-        absl::string_view value = grouped_column.values()->front();
-        if (grouped_column.has_newlines(0)) {
-          absl::StrAppend(&output, "\n;", value, "\n;\n");  // Multi-line value.
-        } else {
-          const absl::string_view quote_char = grouped_column.quote(0);
-          absl::StrAppend(&output, quote_char, value, quote_char, "\n");
-        }
-      }
-    } else {
-      // CIF loop. Output the column names, then the rows with data.
-      absl::StrAppend(&output, "loop_\n");
-      for (Column& grouped_column : group_info.grouped_columns) {
-        absl::StrAppend(&output, grouped_column.key(), "\n");
-      }
-      // Write the loop values, line by line. This is the most expensive part
-      // since this path is taken to write the entire atom site table which has
-      // about 20 columns, but thousands of rows.
-      for (int i = 0; i < group_info.value_size; i++) {
-        for (int column_index = 0;
-             column_index < group_info.grouped_columns.size(); ++column_index) {
-          const Column& grouped_column =
-              group_info.grouped_columns[column_index];
-          const absl::string_view value = (*grouped_column.values())[i];
-          if (grouped_column.has_newlines(i)) {
-            // Multi-line. This is very rarely taken path.
-            if (column_index == 0) {
-              // No extra newline before leading ;, already inserted.
-              absl::StrAppend(&output, ";", value, "\n;\n");
-            } else if (column_index == group_info.grouped_columns.size() - 1) {
-              // No extra newline after trailing ;, will be inserted.
-              absl::StrAppend(&output, "\n;", value, "\n;");
-            } else {
-              absl::StrAppend(&output, "\n;", value, "\n;\n");
-            }
-          } else {
-            size_t start_pos = output.size();
-            output.append(grouped_column.max_value_length() + 1, ' ');
-            auto out_it = output.begin() + start_pos;
-            absl::string_view quote = grouped_column.quote(i);
-            if (!quote.empty()) {
-              out_it = absl::c_copy(quote, out_it);
-              out_it = absl::c_copy(value, out_it);
-              absl::c_copy(quote, out_it);
-            } else {
-              absl::c_copy(value, out_it);
-            }
-          }
-        }
-        absl::StrAppend(&output, "\n");
-      }
-    }
-    absl::StrAppend(&output, "#\n");  // Comment token after every key group.
-  }
-  return output;
-}
-
-absl::StatusOr<
-    std::vector<absl::flat_hash_map<absl::string_view, absl::string_view>>>
-CifDict::ExtractLoopAsList(absl::string_view prefix) const {
-  std::vector<absl::string_view> column_names;
-  std::vector<std::vector<absl::string_view>> column_data;
-
-  for (const auto& element : *dict_) {
-    if (absl::StartsWith(element.first, prefix)) {
-      column_names.emplace_back(element.first);
-      auto& cells = column_data.emplace_back();
-      cells.insert(cells.begin(), element.second.begin(), element.second.end());
-    }
-  }
-  // Make sure all columns have the same number of rows.
-  const std::size_t num_rows = column_data.empty() ? 0 : column_data[0].size();
-  for (const auto& column : column_data) {
-    if (column.size() != num_rows) {
-      return absl::InvalidArgumentError(absl::StrCat(
-          GetDataName(),
-          ": Columns do not have the same number of rows for prefix: '", prefix,
-          "'. One possible reason could be not including the trailing dot, "
-          "e.g. '_atom_site.'."));
-    }
-  }
-
-  std::vector<absl::flat_hash_map<absl::string_view, absl::string_view>> result;
-  result.reserve(num_rows);
-  CHECK_EQ(column_names.size(), column_data.size());
-  for (std::size_t row_index = 0; row_index < num_rows; ++row_index) {
-    auto& row_dict = result.emplace_back();
-    row_dict.reserve(column_names.size());
-    for (int col_index = 0; col_index < column_names.size(); ++col_index) {
-      row_dict[column_names[col_index]] = column_data[col_index][row_index];
-    }
-  }
-  return result;
-}
-
-absl::StatusOr<absl::flat_hash_map<
-    absl::string_view,
-    absl::flat_hash_map<absl::string_view, absl::string_view>>>
-CifDict::ExtractLoopAsDict(absl::string_view prefix,
-                           absl::string_view index) const {
-  if (!absl::StartsWith(index, prefix)) {
-    return absl::InvalidArgumentError(
-        absl::StrCat(GetDataName(), ": The loop index '", index,
-                     "' must start with the loop prefix '", prefix, "'."));
-  }
-  absl::flat_hash_map<absl::string_view,
-                      absl::flat_hash_map<absl::string_view, absl::string_view>>
-      result;
-  auto loop_as_list = ExtractLoopAsList(prefix);
-  if (!loop_as_list.ok()) {
-    return loop_as_list.status();
-  }
-  result.reserve(loop_as_list->size());
-  for (auto& entry : *loop_as_list) {
-    if (const auto it = entry.find(index); it != entry.end()) {
-      result[it->second] = entry;
-    } else {
-      return absl::InvalidArgumentError(absl::StrCat(
-          GetDataName(), ": The index column '", index,
-          "' could not be found in the loop with prefix '", prefix, "'."));
-    }
-  }
-  return result;
-}
-
-absl::StatusOr<std::vector<std::string>> Tokenize(
-    absl::string_view cif_string) {
-  HeapStrings heap_strings;
-  auto tokens = TokenizeInternal(cif_string, &heap_strings);
-  if (!tokens.ok()) {
-    return tokens.status();
-  }
-  return std::vector<std::string>(tokens->begin(), tokens->end());
-}
-
-absl::StatusOr<std::vector<absl::string_view>> SplitLine(
-    absl::string_view line) {
-  std::vector<absl::string_view> tokens;
-  if (!SplitLineInline(line, &tokens)) {
-    return absl::InvalidArgumentError(
-        absl::StrCat("Line ended with quote open: ", line));
-  }
-  return tokens;
-}
-
-absl::StatusOr<absl::flat_hash_map<std::string, CifDict>> ParseMultiDataCifDict(
-    absl::string_view cif_string) {
-  absl::flat_hash_map<std::string, CifDict> mapping;
-  constexpr absl::string_view delimitor = "data_";
-  // Check cif_string starts with correct offset.
-  if (!cif_string.empty() && !absl::StartsWith(cif_string, delimitor)) {
-    return absl::InvalidArgumentError(
-        "Invalid format. MultiDataCifDict must start with 'data_'");
-  }
-  for (absl::string_view data_block :
-       absl::StrSplit(cif_string, delimitor, absl::SkipEmpty())) {
-    absl::string_view block_with_delimitor(
-        data_block.data() - delimitor.size(),
-        data_block.size() + delimitor.size());
-    absl::StatusOr<CifDict> parsed_block =
-        CifDict::FromString(block_with_delimitor);
-    if (!parsed_block.ok()) {
-      return parsed_block.status();
-    }
-    absl::string_view data_name = parsed_block->GetDataName();
-    mapping[data_name] = *std::move(parsed_block);
-  }
-
-  return mapping;
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/parsers/cpp/cif_dict_lib.h b/src/alphafold3/parsers/cpp/cif_dict_lib.h
deleted file mode 100644
index 5c16eaa87c2443061109673d06b6db24a1b998f9..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/cif_dict_lib.h
+++ /dev/null
@@ -1,149 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-// A C++ implementation of a CIF parser. For the format specification see
-// https://www.iucr.org/resources/cif/spec/version1.1/cifsyntax
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_CIF_DICT_LIB_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_CIF_DICT_LIB_H_
-
-#include <cstddef>
-#include <memory>
-#include <string>
-#include <utility>
-#include <vector>
-
-#include "absl/container/flat_hash_map.h"
-#include "absl/container/node_hash_map.h"
-#include "absl/status/statusor.h"
-#include "absl/strings/string_view.h"
-#include "absl/types/span.h"
-
-namespace alphafold3 {
-
-class CifDict {
- public:
-  // Use absl::node_hash_map since it guarantees pointer stability.
-  using Dict = absl::node_hash_map<std::string, std::vector<std::string>>;
-
-  CifDict() = default;
-
-  explicit CifDict(Dict dict)
-      : dict_(std::make_shared<const Dict>(std::move(dict))) {}
-
-  // Converts a CIF string into a dictionary mapping each CIF field to a list of
-  // values that field contains.
-  static absl::StatusOr<CifDict> FromString(absl::string_view cif_string);
-
-  // Converts the CIF into into a string that is a valid CIF file.
-  absl::StatusOr<std::string> ToString() const;
-
-  // Extracts loop associated with a prefix from mmCIF data as a list.
-  // Reference for loop_ in mmCIF:
-  // http://mmcif.wwpdb.org/docs/tutorials/mechanics/pdbx-mmcif-syntax.html
-  // Args:
-  // prefix: Prefix shared by each of the data items in the loop.
-  //   e.g. '_entity_poly_seq.', where the data items are _entity_poly_seq.num,
-  //   _entity_poly_seq.mon_id. Should include the trailing period.
-  //
-  // Returns a list of dicts; each dict represents 1 entry from an mmCIF loop.
-  // Lifetime of string_views tied to this.
-  absl::StatusOr<
-      std::vector<absl::flat_hash_map<absl::string_view, absl::string_view>>>
-  ExtractLoopAsList(absl::string_view prefix) const;
-
-  // Extracts loop associated with a prefix from mmCIF data as a dictionary.
-  // Args:
-  // prefix: Prefix shared by each of the data items in the loop.
-  //   e.g. '_entity_poly_seq.', where the data items are _entity_poly_seq.num,
-  //   _entity_poly_seq.mon_id. Should include the trailing period.
-  // index: Which item of loop data should serve as the key.
-  //
-  // Returns a dict of dicts; each dict represents 1 entry from an mmCIF loop,
-  // indexed by the index column.
-  // Lifetime of string_views tied to this.
-  absl::StatusOr<absl::flat_hash_map<
-      absl::string_view,
-      absl::flat_hash_map<absl::string_view, absl::string_view>>>
-  ExtractLoopAsDict(absl::string_view prefix, absl::string_view index) const;
-
-  // Returns value at key if present or an empty list.
-  absl::Span<const std::string> operator[](absl::string_view key) const {
-    auto it = dict_->find(key);
-    if (it != dict_->end()) {
-      return it->second;
-    }
-    return {};
-  }
-
-  // Returns boolean of whether dict contains key.
-  bool Contains(absl::string_view key) const { return dict_->contains(key); }
-
-  // Returns number of values for the given key if present, 0 otherwise.
-  size_t ValueLength(absl::string_view key) const {
-    return (*this)[key].size();
-  }
-
-  // Returns the size of the underlying dictionary.
-  std::size_t Length() { return dict_->size(); }
-
-  // Creates a copy of this CifDict object that will contain the original values
-  // but only if not updated by the given dictionary.
-  // E.g. if the CifDict = {a: [a1, a2], b: [b1]} and other = {a: [x], c: [z]},
-  // you will get {a: [x], b: [b1], c: [z]}.
-  CifDict CopyAndUpdate(Dict other) const {
-    other.insert(dict_->begin(), dict_->end());
-    return CifDict(std::move(other));
-  }
-
-  // Returns the value of the special CIF data_ field.
-  absl::string_view GetDataName() const {
-    // The data_ element has to be present by construction.
-    if (auto it = dict_->find("data_");
-        it != dict_->end() && !it->second.empty()) {
-      return it->second.front();
-    } else {
-      return "";
-    }
-  }
-
-  const std::shared_ptr<const Dict>& dict() const { return dict_; }
-
- private:
-  std::shared_ptr<const Dict> dict_;
-};
-
-// Tokenizes a CIF string into a list of string tokens. This is more involved
-// than just a simple split on whitespace as CIF allows comments and quoting.
-absl::StatusOr<std::vector<std::string>> Tokenize(absl::string_view cif_string);
-
-// Tokenizes a single line of a CIF string.
-absl::StatusOr<std::vector<absl::string_view>> SplitLine(
-    absl::string_view line);
-
-// Parses a CIF string with multiple data records and returns a mapping from
-// record names to CifDict objects. For instance, the following CIF string:
-//
-// data_001
-// _foo bar
-//
-// data_002
-// _foo baz
-//
-// will be parsed as:
-// {'001': CifDict({'_foo': ['bar']}),
-//  '002': CifDict({'_foo': ['baz']})}
-absl::StatusOr<absl::flat_hash_map<std::string, CifDict>> ParseMultiDataCifDict(
-    absl::string_view cif_string);
-
-}  // namespace alphafold3
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_CIF_DICT_LIB_H_
diff --git a/src/alphafold3/parsers/cpp/cif_dict_pybind.cc b/src/alphafold3/parsers/cpp/cif_dict_pybind.cc
deleted file mode 100644
index 130a8215abf89b54be76c9b5973fec8bf5b11222..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/cif_dict_pybind.cc
+++ /dev/null
@@ -1,652 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <Python.h>
-
-#include <cstddef>
-#include <cstdint>
-#include <cstring>
-#include <limits>
-#include <memory>
-#include <string>
-#include <type_traits>
-#include <utility>
-#include <vector>
-
-#include "numpy/ndarrayobject.h"
-#include "numpy/ndarraytypes.h"
-#include "numpy/npy_common.h"
-#include "absl/base/no_destructor.h"
-#include "absl/container/flat_hash_map.h"
-#include "absl/status/status.h"
-#include "absl/status/statusor.h"
-#include "absl/strings/numbers.h"
-#include "absl/strings/str_cat.h"
-#include "absl/strings/string_view.h"
-#include "absl/types/span.h"
-#include "alphafold3/parsers/cpp/cif_dict_lib.h"
-#include "pybind11/attr.h"
-#include "pybind11/cast.h"
-#include "pybind11/gil.h"
-#include "pybind11/pybind11.h"
-#include "pybind11/pytypes.h"
-#include "pybind11/stl.h"
-
-namespace alphafold3 {
-namespace {
-namespace py = pybind11;
-
-template <typename Item, typename ForEach>
-bool GatherArray(size_t num_dims, npy_intp* shape_array, npy_intp* stride_array,
-                 const char* data, absl::Span<const std::string> values,
-                 ForEach&& for_each_cb) {
-  if (num_dims == 1) {
-    const npy_intp shape = shape_array[0];
-    const npy_intp stride = stride_array[0];
-    for (size_t i = 0; i < shape; ++i) {
-      Item index;
-      std::memcpy(&index, data + stride * i, sizeof(Item));
-      if (index < 0 || index >= values.size()) {
-        PyErr_SetString(PyExc_IndexError,
-                        absl::StrCat("index ", index,
-                                     " is out of bounds for column with size ",
-                                     values.size())
-                            .c_str());
-        return false;
-      }
-      if (!for_each_cb(values[index])) {
-        return false;
-      }
-    }
-  } else if (num_dims == 0) {
-    Item index;
-    std::memcpy(&index, data, sizeof(Item));
-    if (index < 0 || index >= values.size()) {
-      PyErr_SetString(
-          PyExc_IndexError,
-          absl::StrCat("index ", index,
-                       " is out of bounds for column with size ", values.size())
-              .c_str());
-      return false;
-    }
-    if (!for_each_cb(values[index])) {
-      return false;
-    }
-  } else {
-    const npy_intp shape = shape_array[0];
-    const npy_intp stride = stride_array[0];
-    for (size_t i = 0; i < shape; ++i) {
-      if (!GatherArray<Item>(num_dims - 1, shape_array + 1, stride_array + 1,
-                             data + stride * i, values, for_each_cb)) {
-        return false;
-      }
-    }
-  }
-  return true;
-}
-
-template <typename Size, typename ForEach>
-bool Gather(PyObject* gather, absl::Span<const std::string> values,
-            Size&& size_cb, ForEach&& for_each_cb) {
-  if (gather == Py_None) {
-    npy_intp dim = static_cast<npy_intp>(values.size());
-    if (!size_cb(absl::MakeSpan(&dim, 1))) {
-      return false;
-    }
-    for (const std::string& v : values) {
-      if (!for_each_cb(v)) {
-        return false;
-      }
-    }
-    return true;
-  }
-  if (PySlice_Check(gather)) {
-    Py_ssize_t start, stop, step, slice_length;
-    if (PySlice_GetIndicesEx(gather, values.size(), &start, &stop, &step,
-                             &slice_length) != 0) {
-      return false;
-    }
-    npy_intp dim = static_cast<npy_intp>(slice_length);
-    if (!size_cb(absl::MakeSpan(&dim, 1))) {
-      return false;
-    }
-    for (size_t i = 0; i < slice_length; ++i) {
-      if (!for_each_cb(values[start + i * step])) {
-        return false;
-      }
-    }
-    return true;
-  }
-  if (PyArray_Check(gather)) {
-    PyArrayObject* gather_array = reinterpret_cast<PyArrayObject*>(gather);
-    auto shape =
-        absl::MakeSpan(PyArray_DIMS(gather_array), PyArray_NDIM(gather_array));
-    switch (PyArray_TYPE(gather_array)) {
-      case NPY_INT16:
-        if (!size_cb(shape)) {
-          return false;
-        }
-        return GatherArray<std::int16_t>(shape.size(), shape.data(),
-                                         PyArray_STRIDES(gather_array),
-                                         PyArray_BYTES(gather_array), values,
-                                         std::forward<ForEach>(for_each_cb));
-      case NPY_UINT16:
-        if (!size_cb(shape)) {
-          return false;
-        }
-        return GatherArray<std::uint16_t>(shape.size(), shape.data(),
-                                          PyArray_STRIDES(gather_array),
-                                          PyArray_BYTES(gather_array), values,
-                                          std::forward<ForEach>(for_each_cb));
-      case NPY_INT32:
-        if (!size_cb(shape)) {
-          return false;
-        }
-        return GatherArray<std::int32_t>(shape.size(), shape.data(),
-                                         PyArray_STRIDES(gather_array),
-                                         PyArray_BYTES(gather_array), values,
-                                         std::forward<ForEach>(for_each_cb));
-      case NPY_UINT32:
-        if (!size_cb(shape)) {
-          return false;
-        }
-        return GatherArray<std::uint32_t>(shape.size(), shape.data(),
-                                          PyArray_STRIDES(gather_array),
-                                          PyArray_BYTES(gather_array), values,
-                                          std::forward<ForEach>(for_each_cb));
-      case NPY_INT64:
-        if (!size_cb(shape)) {
-          return false;
-        }
-        return GatherArray<std::int64_t>(shape.size(), shape.data(),
-                                         PyArray_STRIDES(gather_array),
-                                         PyArray_BYTES(gather_array), values,
-                                         std::forward<ForEach>(for_each_cb));
-      case NPY_UINT64:
-        if (!size_cb(shape)) {
-          return false;
-        }
-        return GatherArray<std::uint64_t>(shape.size(), shape.data(),
-                                          PyArray_STRIDES(gather_array),
-                                          PyArray_BYTES(gather_array), values,
-                                          std::forward<ForEach>(for_each_cb));
-      default:
-        PyErr_SetString(PyExc_TypeError, "Unsupported NumPy array type.");
-        return false;
-    }
-  }
-
-  PyErr_Format(PyExc_TypeError, "Invalid gather %R", gather);
-  return false;
-}
-
-// Creates a NumPy array of objects of given strings. Reusing duplicates where
-// possible.
-PyObject* ConvertStrings(PyObject* gather, PyArray_Descr* type,
-                         absl::Span<const std::string> values) {
-  absl::flat_hash_map<absl::string_view, PyObject*> existing;
-
-  PyObject* ret = nullptr;
-  PyObject** dst;
-  if (Gather(
-          gather, values,
-          [&dst, &ret, type](absl::Span<const npy_intp> size) {
-            ret = PyArray_NewFromDescr(
-                /*subtype=*/&PyArray_Type,
-                /*type=*/type,
-                /*nd=*/size.size(),
-                /*dims=*/size.data(),
-                /*strides=*/nullptr,
-                /*data=*/nullptr,
-                /*flags=*/0,
-                /*obj=*/nullptr);
-            dst = static_cast<PyObject**>(
-                PyArray_DATA(reinterpret_cast<PyArrayObject*>(ret)));
-            return true;
-          },
-          [&dst, &existing](absl::string_view value) {
-            auto [it, inserted] = existing.emplace(value, nullptr);
-            if (inserted) {
-              it->second =
-                  PyUnicode_FromStringAndSize(value.data(), value.size());
-              PyUnicode_InternInPlace(&it->second);
-            } else {
-              Py_INCREF(it->second);
-            }
-            *dst++ = it->second;
-            return true;
-          })) {
-    return ret;
-  } else {
-    Py_XDECREF(ret);
-    return nullptr;
-  }
-}
-
-// Creates NumPy array with given dtype given specified converter.
-// `converter` shall have the following signature:
-// bool converter(const std::string& value, T* result);
-// It must return whether conversion is successful and store conversion in
-// result.
-template <typename T, typename C>
-inline PyObject* Convert(PyObject* gather, PyArray_Descr* type,
-                         absl::Span<const std::string> values, C&& converter) {
-  py::object ret;
-  T* dst;
-  if (Gather(
-          gather, values,
-          [&dst, &ret, type](absl::Span<const npy_intp> size) {
-            // Construct uninitialised NumPy array of type T.
-            ret = py::reinterpret_steal<py::object>(PyArray_NewFromDescr(
-                /*subtype=*/&PyArray_Type,
-                /*type=*/type,
-                /*nd=*/size.size(),
-                /*dims=*/size.data(),
-                /*strides=*/nullptr,
-                /*data=*/nullptr,
-                /*flags=*/0,
-                /*obj=*/nullptr));
-
-            dst = static_cast<T*>(
-                PyArray_DATA(reinterpret_cast<PyArrayObject*>(ret.ptr())));
-            return true;
-          },
-          [&dst, &converter](const std::string& value) {
-            if (!converter(value, dst++)) {
-              PyErr_SetString(PyExc_ValueError, value.c_str());
-              return false;
-            }
-            return true;
-          })) {
-    return ret.release().ptr();
-  }
-  return nullptr;
-}
-
-PyObject* CifDictGetArray(const CifDict& self, absl::string_view key,
-                          PyObject* dtype, PyObject* gather) {
-  import_array();
-  PyArray_Descr* type = nullptr;
-  if (dtype == Py_None) {
-    type = PyArray_DescrFromType(NPY_OBJECT);
-  } else if (PyArray_DescrConverter(dtype, &type) == NPY_FAIL || !type) {
-    PyErr_Format(PyExc_TypeError, "Invalid dtype %R", dtype);
-    Py_XDECREF(type);
-    return nullptr;
-  }
-  auto entry = self.dict()->find(key);
-  if (entry == self.dict()->end()) {
-    Py_DECREF(type);
-    PyErr_SetObject(PyExc_KeyError,
-                    PyUnicode_FromStringAndSize(key.data(), key.size()));
-    return nullptr;
-  }
-
-  auto int_convert = [](absl::string_view str, auto* value) {
-    return absl::SimpleAtoi(str, value);
-  };
-
-  auto int_convert_bounded = [](absl::string_view str, auto* value) {
-    int64_t v;
-    if (absl::SimpleAtoi(str, &v)) {
-      using limits =
-          std::numeric_limits<std::remove_reference_t<decltype(*value)>>;
-      if (limits::min() <= v && v <= limits::max()) {
-        *value = v;
-        return true;
-      }
-    }
-    return false;
-  };
-
-  absl::Span<const std::string> values = entry->second;
-
-  switch (type->type_num) {
-    case NPY_DOUBLE:
-      return Convert<double>(
-          gather, type, values, [](absl::string_view str, double* value) {
-            if (str == ".") {
-              *value = std::numeric_limits<double>::quiet_NaN();
-              return true;
-            }
-            return absl::SimpleAtod(str, value);
-          });
-    case NPY_FLOAT:
-      return Convert<float>(
-          gather, type, values, [](absl::string_view str, float* value) {
-            if (str == ".") {
-              *value = std::numeric_limits<float>::quiet_NaN();
-              return true;
-            }
-            return absl::SimpleAtof(str, value);
-          });
-    case NPY_INT8:
-      return Convert<int8_t>(gather, type, values, int_convert_bounded);
-    case NPY_INT16:
-      return Convert<int16_t>(gather, type, values, int_convert_bounded);
-    case NPY_INT32:
-      return Convert<int32_t>(gather, type, values, int_convert);
-    case NPY_INT64:
-      return Convert<int64_t>(gather, type, values, int_convert);
-    case NPY_UINT8:
-      return Convert<uint8_t>(gather, type, values, int_convert_bounded);
-    case NPY_UINT16:
-      return Convert<uint16_t>(gather, type, values, int_convert_bounded);
-    case NPY_UINT32:
-      return Convert<uint32_t>(gather, type, values, int_convert);
-    case NPY_UINT64:
-      return Convert<uint64_t>(gather, type, values, int_convert);
-    case NPY_BOOL:
-      return Convert<bool>(gather, type, values,
-                           [](absl::string_view str, bool* value) {
-                             if (str == "n" || str == "no") {
-                               *value = false;
-                               return true;
-                             }
-                             if (str == "y" || str == "yes") {
-                               *value = true;
-                               return true;
-                             }
-                             return false;
-                           });
-    case NPY_OBJECT:
-      return ConvertStrings(gather, type, values);
-    default: {
-      PyErr_Format(PyExc_TypeError, "Unsupported dtype %R", dtype);
-      Py_XDECREF(type);
-      return nullptr;
-    }
-  }
-}
-
-}  // namespace
-
-void RegisterModuleCifDict(pybind11::module m) {
-  using Value = std::vector<std::string>;
-  static absl::NoDestructor<std::vector<std::string>> empty_values;
-
-  m.def(
-      "from_string",
-      [](absl::string_view s) {
-        absl::StatusOr<CifDict> dict = CifDict::FromString(s);
-        if (!dict.ok()) {
-          throw py::value_error(dict.status().ToString());
-        }
-        return *dict;
-      },
-      py::call_guard<py::gil_scoped_release>());
-
-  m.def(
-      "tokenize",
-      [](absl::string_view cif_string) {
-        absl::StatusOr<std::vector<std::string>> tokens = Tokenize(cif_string);
-        if (!tokens.ok()) {
-          throw py::value_error(tokens.status().ToString());
-        }
-        return *std::move(tokens);
-      },
-      py::arg("cif_string"));
-
-  m.def("split_line", [](absl::string_view line) {
-    absl::StatusOr<std::vector<absl::string_view>> tokens = SplitLine(line);
-    if (!tokens.ok()) {
-      throw py::value_error(tokens.status().ToString());
-    }
-    return *std::move(tokens);
-  });
-
-  m.def(
-      "parse_multi_data_cif",
-      [](absl::string_view cif_string) {
-        auto result = ParseMultiDataCifDict(cif_string);
-        if (!result.ok()) {
-          throw py::value_error(result.status().ToString());
-        }
-        py::dict dict;
-        for (auto& [key, value] : *result) {
-          dict[py::cast(key)] = py::cast(value);
-        }
-        return dict;
-      },
-      py::arg("cif_string"));
-
-  auto cif_dict =
-      py::class_<CifDict>(m, "CifDict")
-          .def(py::init<>([](py::dict dict) {
-                 CifDict::Dict result;
-                 for (const auto& [key, value] : dict) {
-                   result.emplace(py::cast<absl::string_view>(key),
-                                  py::cast<std::vector<std::string>>(value));
-                 }
-                 return CifDict(std::move(result));
-               }),
-               "Initialise with a map")
-          .def("copy_and_update",
-               [](const CifDict& self, py::dict dict) {
-                 CifDict::Dict result;
-                 for (const auto& [key, value] : dict) {
-                   result.emplace(py::cast<absl::string_view>(key),
-                                  py::cast<std::vector<std::string>>(value));
-                 }
-                 {
-                   py::gil_scoped_release gil_release;
-                   return self.CopyAndUpdate(std::move(result));
-                 }
-               })
-          .def(
-              "__str__",
-              [](const CifDict& self) {
-                absl::StatusOr<std::string> result = self.ToString();
-                if (!result.ok()) {
-                  throw py::value_error(result.status().ToString());
-                }
-                return *result;
-              },
-              "Serialize to a string", py::call_guard<py::gil_scoped_release>())
-          .def(
-              "to_string",
-              [](const CifDict& self) {
-                absl::StatusOr<std::string> result = self.ToString();
-                if (!result.ok()) {
-                  throw py::value_error(result.status().ToString());
-                }
-                return *result;
-              },
-              "Serialize to a string", py::call_guard<py::gil_scoped_release>())
-          .def("value_length", &CifDict::ValueLength, py::arg("key"),
-               "Num elements in value")
-          .def("__len__",
-               [](const CifDict& self) { return self.dict()->size(); })
-          .def(
-              "__bool__",
-              [](const CifDict& self) { return !self.dict()->empty(); },
-              "Check whether the map is nonempty")
-          .def(
-              "__contains__",
-              [](const CifDict& self, absl::string_view k) {
-                return self.dict()->find(k) != self.dict()->end();
-              },
-              py::arg("key"), py::call_guard<py::gil_scoped_release>())
-          .def("get_data_name", &CifDict::GetDataName)
-          .def(
-              "get",
-              [](const CifDict& self, absl::string_view k,
-                 py::object default_value) -> py::object {
-                auto it = self.dict()->find(k);
-                if (it == self.dict()->end()) return default_value;
-                py::list result(it->second.size());
-                size_t index = 0;
-                for (const std::string& v : it->second) {
-                  result[index++] = py::cast(v);
-                }
-                return result;
-              },
-              py::arg("key"), py::arg("default_value") = py::none())
-          .def(
-              "get_array",
-              [](const CifDict& self, absl::string_view key, py::handle dtype,
-                 py::handle gather) -> py::object {
-                PyObject* obj =
-                    CifDictGetArray(self, key, dtype.ptr(), gather.ptr());
-                if (obj == nullptr) {
-                  throw py::error_already_set();
-                }
-                return py::reinterpret_steal<py::object>(obj);
-              },
-              py::arg("key"), py::arg("dtype") = py::none(),
-              py::arg("gather") = py::none())
-          .def(
-              "__getitem__",
-              [](const CifDict& self, absl::string_view k) -> const Value& {
-                auto it = self.dict()->find(k);
-                if (it == self.dict()->end()) {
-                  throw py::key_error(std::string(k).c_str());
-                }
-                return it->second;
-              },
-              py::arg("key"), py::call_guard<py::gil_scoped_release>())
-          .def(
-              "extract_loop_as_dict",
-              [](const CifDict& self, absl::string_view prefix,
-                 absl::string_view index) {
-                absl::StatusOr<absl::flat_hash_map<
-                    absl::string_view,
-                    absl::flat_hash_map<absl::string_view, absl::string_view>>>
-                    dict;
-                {
-                  py::gil_scoped_release gil_release;
-                  dict = self.ExtractLoopAsDict(prefix, index);
-                  if (!dict.ok()) {
-                    throw py::value_error(dict.status().ToString());
-                  }
-                }
-                py::dict key_value_dict;
-                for (const auto& [key, value] : *dict) {
-                  py::dict value_dict;
-                  for (const auto& [key2, value2] : value) {
-                    value_dict[py::cast(key2)] = py::cast(value2);
-                  }
-                  key_value_dict[py::cast(key)] = std::move(value_dict);
-                }
-                return key_value_dict;
-              },
-              py::arg("prefix"), py::arg("index"))
-          .def(
-              "extract_loop_as_list",
-              [](const CifDict& self, absl::string_view prefix) {
-                absl::StatusOr<std::vector<
-                    absl::flat_hash_map<absl::string_view, absl::string_view>>>
-                    list_dict;
-                {
-                  py::gil_scoped_release gil_release;
-                  list_dict = self.ExtractLoopAsList(prefix);
-                  if (!list_dict.ok()) {
-                    throw py::value_error(list_dict.status().ToString());
-                  }
-                }
-                py::list list_obj(list_dict->size());
-                size_t index = 0;
-                for (const auto& value : *list_dict) {
-                  py::dict value_dict;
-                  for (const auto& [key, value] : value) {
-                    value_dict[py::cast(key)] = py::cast(value);
-                  }
-                  list_obj[index++] = std::move(value_dict);
-                }
-                return list_obj;
-              },
-              py::arg("prefix"))
-          .def(py::pickle(
-              [](const CifDict& self) {  // __getstate__.
-                py::tuple result_tuple(1);
-                py::dict result;
-                for (const auto& [key, value] : *self.dict()) {
-                  result[py::cast(key)] = py::cast(value);
-                }
-                result_tuple[0] = std::move(result);
-                return result_tuple;
-              },
-              [](py::tuple t) {  // __setstate__.
-                py::dict dict = t[0].cast<py::dict>();
-                CifDict::Dict result;
-                for (const auto& [key, value] : dict) {
-                  result.emplace(py::cast<absl::string_view>(key),
-                                 py::cast<std::vector<std::string>>(value));
-                }
-                return CifDict(std::move(result));
-              }));
-
-  // Item, value, and key views
-  struct KeyView {
-    CifDict map;
-  };
-
-  struct ValueView {
-    CifDict map;
-  };
-  struct ItemView {
-    CifDict map;
-  };
-
-  py::class_<ItemView>(cif_dict, "ItemView")
-      .def("__len__", [](const ItemView& v) { return v.map.dict()->size(); })
-      .def(
-          "__iter__",
-          [](const ItemView& v) {
-            return py::make_iterator(v.map.dict()->begin(),
-                                     v.map.dict()->end());
-          },
-          py::keep_alive<0, 1>());
-
-  py::class_<KeyView>(cif_dict, "KeyView")
-      .def("__contains__",
-           [](const KeyView& v, absl::string_view k) {
-             return v.map.dict()->find(k) != v.map.dict()->end();
-           })
-      .def("__contains__", [](const KeyView&, py::handle) { return false; })
-      .def("__len__", [](const KeyView& v) { return v.map.dict()->size(); })
-      .def(
-          "__iter__",
-          [](const KeyView& v) {
-            return py::make_key_iterator(v.map.dict()->begin(),
-                                         v.map.dict()->end());
-          },
-          py::keep_alive<0, 1>());
-
-  py::class_<ValueView>(cif_dict, "ValueView")
-      .def("__len__", [](const ValueView& v) { return v.map.dict()->size(); })
-      .def(
-          "__iter__",
-          [](const ValueView& v) {
-            return py::make_value_iterator(v.map.dict()->begin(),
-                                           v.map.dict()->end());
-          },
-          py::keep_alive<0, 1>());
-
-  cif_dict
-      .def(
-          "__iter__",
-          [](CifDict& self) {
-            return py::make_key_iterator(self.dict()->begin(),
-                                         self.dict()->end());
-          },
-          py::keep_alive<0, 1>())
-      .def(
-          "keys", [](CifDict& self) { return KeyView{self}; },
-          "Returns an iterable view of the map's keys.")
-      .def(
-          "values", [](CifDict& self) { return ValueView{self}; },
-          "Returns an iterable view of the map's values.")
-      .def(
-          "items", [](CifDict& self) { return ItemView{self}; },
-          "Returns an iterable view of the map's items.");
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/parsers/cpp/cif_dict_pybind.h b/src/alphafold3/parsers/cpp/cif_dict_pybind.h
deleted file mode 100644
index ca4f94702bc5b961160be78af151aaf756619f7e..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/cif_dict_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_CIF_DICT_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_CIF_DICT_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleCifDict(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_CIF_DICT_PYBIND_H_
diff --git a/src/alphafold3/parsers/cpp/fasta_iterator.pyi b/src/alphafold3/parsers/cpp/fasta_iterator.pyi
deleted file mode 100755
index d5da60ec8ade9fa4658ad71e99465beb271a48a5..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/fasta_iterator.pyi
+++ /dev/null
@@ -1,22 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-class FastaFileIterator:
-    def __init__(self, fasta_path: str) -> None: ...
-    def __iter__(self) -> FastaFileIterator: ...
-    def __next__(self) -> tuple[str,str]: ...
-
-class FastaStringIterator:
-    def __init__(self, fasta_string: str | bytes) -> None: ...
-    def __iter__(self) -> FastaStringIterator: ...
-    def __next__(self) -> tuple[str,str]: ...
-
-def parse_fasta(fasta_string: str | bytes) -> list[str]: ...
-def parse_fasta_include_descriptions(fasta_string: str | bytes) -> tuple[list[str],list[str]]: ...
diff --git a/src/alphafold3/parsers/cpp/fasta_iterator_lib.cc b/src/alphafold3/parsers/cpp/fasta_iterator_lib.cc
deleted file mode 100644
index 82cac934313f2b9654f9aee54913ed5eb8f64dad..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/fasta_iterator_lib.cc
+++ /dev/null
@@ -1,121 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include "alphafold3/parsers/cpp/fasta_iterator_lib.h"
-
-#include <cstddef>
-#include <optional>
-#include <string>
-#include <utility>
-#include <vector>
-
-#include "absl/status/status.h"
-#include "absl/status/statusor.h"
-#include "absl/strings/ascii.h"
-#include "absl/strings/str_cat.h"
-#include "absl/strings/str_split.h"
-#include "absl/strings/string_view.h"
-#include "absl/strings/strip.h"
-
-namespace alphafold3 {
-
-// Parse FASTA string and return list of strings with amino acid sequences.
-// Returns a list of amino acid sequences only.
-std::vector<std::string> ParseFasta(absl::string_view fasta_string) {
-  std::vector<std::string> sequences;
-  std::string* sequence = nullptr;
-  for (absl::string_view line_raw : absl::StrSplit(fasta_string, '\n')) {
-    absl::string_view line = absl::StripAsciiWhitespace(line_raw);
-    if (absl::ConsumePrefix(&line, ">")) {
-      sequence = &sequences.emplace_back();
-    } else if (!line.empty() && sequence != nullptr) {
-      absl::StrAppend(sequence, line);
-    }
-  }
-  return sequences;
-}
-
-// Parse FASTA string and return list of strings with amino acid sequences.
-// Returns two lists: The first one with amino acid sequences, the second with
-// the descriptions associated with each sequence.
-std::pair<std::vector<std::string>, std::vector<std::string>>
-ParseFastaIncludeDescriptions(absl::string_view fasta_string) {
-  std::pair<std::vector<std::string>, std::vector<std::string>> result;
-  auto& [sequences, descriptions] = result;
-  std::string* sequence = nullptr;
-  for (absl::string_view line_raw : absl::StrSplit(fasta_string, '\n')) {
-    absl::string_view line = absl::StripAsciiWhitespace(line_raw);
-    if (absl::ConsumePrefix(&line, ">")) {
-      descriptions.emplace_back(line);
-      sequence = &sequences.emplace_back();
-    } else if (!line.empty() && sequence != nullptr) {
-      absl::StrAppend(sequence, line);
-    }
-  }
-  return result;
-}
-
-absl::StatusOr<std::pair<std::string, std::string>> FastaFileIterator::Next() {
-  std::string line_str;
-  while (std::getline(reader_, line_str)) {
-    absl::string_view line = line_str;
-    line = absl::StripAsciiWhitespace(line);
-    if (absl::ConsumePrefix(&line, ">")) {
-      if (!description_.has_value()) {
-        description_ = line;
-      } else {
-        std::pair<std::string, std::string> output(sequence_, *description_);
-        description_ = line;
-        sequence_ = "";
-        return output;
-      }
-    } else if (description_.has_value()) {
-      absl::StrAppend(&sequence_, line);
-    }
-  }
-  has_next_ = false;
-  reader_.close();
-  if (description_.has_value()) {
-    return std::pair(sequence_, *description_);
-  } else {
-    return absl::InvalidArgumentError(
-        absl::StrCat("Invalid FASTA file: ", filename_));
-  }
-}
-
-absl::StatusOr<std::pair<std::string, std::string>>
-FastaStringIterator::Next() {
-  size_t consumed = 0;
-  for (absl::string_view line_raw : absl::StrSplit(fasta_string_, '\n')) {
-    consumed += line_raw.size() + 1;  // +1 for the newline character.
-    absl::string_view line = absl::StripAsciiWhitespace(line_raw);
-    if (absl::ConsumePrefix(&line, ">")) {
-      if (!description_.has_value()) {
-        description_ = line;
-      } else {
-        std::pair<std::string, std::string> output(sequence_, *description_);
-        description_ = line;
-        sequence_ = "";
-        fasta_string_.remove_prefix(consumed);
-        return output;
-      }
-    } else if (description_.has_value()) {
-      absl::StrAppend(&sequence_, line);
-    }
-  }
-  has_next_ = false;
-  if (description_.has_value()) {
-    return std::pair(sequence_, *description_);
-  } else {
-    return absl::InvalidArgumentError("Invalid FASTA string");
-  }
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/parsers/cpp/fasta_iterator_lib.h b/src/alphafold3/parsers/cpp/fasta_iterator_lib.h
deleted file mode 100644
index 486d05f20808a4a5566714b45b41e7f4c27e4f51..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/fasta_iterator_lib.h
+++ /dev/null
@@ -1,94 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-// A C++ implementation of a FASTA parser.
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_FASTA_ITERATOR_LIB_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_FASTA_ITERATOR_LIB_H_
-
-#include <fstream>
-#include <ios>
-#include <optional>
-#include <string>
-#include <utility>
-#include <vector>
-
-#include "absl/status/statusor.h"
-#include "absl/strings/string_view.h"
-
-namespace alphafold3 {
-
-// Parse FASTA string and return list of strings with amino acid sequences.
-// Returns a list of amino acid sequences only.
-std::vector<std::string> ParseFasta(absl::string_view fasta_string);
-
-// Parse FASTA string and return list of strings with amino acid sequences.
-// Returns two lists: The first one with amino acid sequences, the second with
-// the descriptions associated with each sequence.
-std::pair<std::vector<std::string>, std::vector<std::string>>
-ParseFastaIncludeDescriptions(absl::string_view fasta_string);
-
-// Lazy FASTA parser for memory efficient FASTA parsing from a path.
-class FastaFileIterator {
- public:
-  // Initialise FastaFileIterator with filename of fasta. If you initialize
-  // reader_ with an invalid path or empty file, it won't fail, only
-  // riegeli::ReadLine within the Next method will then return false. That will
-  // then trigger the "Invalid FASTA file" error.
-  explicit FastaFileIterator(absl::string_view fasta_path)
-      : filename_(fasta_path),
-        reader_(filename_, std::ios::in),
-        has_next_(true) {}
-
-  // Returns whether there are more sequences. Returns true before first call to
-  // next even if the file is empty.
-  bool HasNext() const { return has_next_; }
-
-  // Fetches the next (sequence, description) from the file.
-  absl::StatusOr<std::pair<std::string, std::string>> Next();
-
- private:
-  // Use riegeli::FileReader instead of FileLineIterator for about 2x speedup.
-  std::string filename_;
-  std::fstream reader_;
-  std::optional<std::string> description_;
-  std::string sequence_;
-  bool has_next_;
-};
-
-// Lazy FASTA parser for memory efficient FASTA parsing from a string.
-class FastaStringIterator {
- public:
-  // Initialise FastaStringIterator with a string_view of a FASTA. If you
-  // initialize it with an invalid FASTA string, it won't fail, the Next method
-  // will then return false. That will then trigger the "Invalid FASTA" error.
-  // WARNING: The object backing the fasta_string string_view must not be
-  // deleted while this Iterator is alive.
-  explicit FastaStringIterator(absl::string_view fasta_string)
-      : fasta_string_(fasta_string), has_next_(true) {}
-
-  // Returns whether there are more sequences. Returns true before first call to
-  // next even if the string is empty.
-  bool HasNext() const { return has_next_; }
-
-  // Fetches the next (sequence, description) from the string.
-  absl::StatusOr<std::pair<std::string, std::string>> Next();
-
- private:
-  absl::string_view fasta_string_;
-  bool has_next_;
-  std::optional<std::string> description_;
-  std::string sequence_;
-};
-
-}  // namespace alphafold3
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_FASTA_ITERATOR_LIB_H_
diff --git a/src/alphafold3/parsers/cpp/fasta_iterator_pybind.cc b/src/alphafold3/parsers/cpp/fasta_iterator_pybind.cc
deleted file mode 100644
index 0b47933d42e3d5ea162ec405e8aec94ebca05320..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/fasta_iterator_pybind.cc
+++ /dev/null
@@ -1,127 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <utility>
-
-#include "absl/status/statusor.h"
-#include "absl/strings/string_view.h"
-#include "alphafold3/parsers/cpp/fasta_iterator_lib.h"
-#include "pybind11/attr.h"
-#include "pybind11/pybind11.h"
-#include "pybind11/pytypes.h"
-#include "pybind11/stl.h"
-
-namespace alphafold3 {
-namespace {
-
-namespace py = pybind11;
-
-template <typename T>
-T ValueOrThrowValueError(absl::StatusOr<T> value) {
-  if (!value.ok()) throw py::value_error(value.status().ToString());
-  return *std::move(value);
-}
-
-constexpr char kFastaFileIteratorDoc[] = R"(
-Lazy FASTA parser for memory efficient FASTA parsing from a path.)";
-
-constexpr char kFastaStringIteratorDoc[] = R"(
-Lazy FASTA parser for memory efficient FASTA parsing from a string.
-
-WARNING: The object backing the fasta_string string_view must not be
-deleted while the FastaStringIterator is alive. E.g. this will break:
-
-```
-# Make sure the fasta_string is not interned.
-fasta_string = '\n'.join(['>d\nS' for _ in range(10)])
-iterator = fasta_iterator.FastaStringIterator(fasta_string)
-del fasta_string
-iterator.next()  # Heap use-after-free.
-```
-)";
-
-constexpr char kParseFastaDoc[] = R"(
-Parses a FASTA string and returns a list of amino-acid sequences.
-
-Args:
-  fasta_string: The contents of a FASTA file.
-
-Returns:
-  List of sequences in the FASTA file. Descriptions are ignored.
-)";
-
-constexpr char kParseFastaIncludeDescriptionsDoc[] = R"(
-Parses a FASTA string, returns amino-acid sequences with descriptions.
-
-Args:
-  fasta_string: The contents of a FASTA file.
-
-Returns:
-  A tuple with two lists (sequences, descriptions):
-  * A list of sequences.
-  * A list of sequence descriptions taken from the comment lines. In the
-    same order as the sequences.
-)";
-
-class PythonFastaStringIterator : public FastaStringIterator {
- public:
-  explicit PythonFastaStringIterator(py::object fasta_string)
-      : FastaStringIterator(py::cast<absl::string_view>(fasta_string)),
-        fasta_string_(std::move(fasta_string)) {}
-
- private:
-  py::object fasta_string_;
-};
-
-}  // namespace
-
-void RegisterModuleFastaIterator(pybind11::module m) {
-  py::class_<FastaFileIterator>(m, "FastaFileIterator", kFastaFileIteratorDoc)
-      .def(py::init<absl::string_view>(), py::arg("fasta_path"))
-      .def("__iter__",
-           [](FastaFileIterator& iterator) -> FastaFileIterator& {
-             return iterator;
-           })
-      .def(
-          "__next__",
-          [](FastaFileIterator& iterator) {
-            if (iterator.HasNext()) {
-              return ValueOrThrowValueError(iterator.Next());
-            } else {
-              throw py::stop_iteration();
-            }
-          },
-          py::call_guard<py::gil_scoped_release>());
-
-  py::class_<PythonFastaStringIterator>(m, "FastaStringIterator",
-                                        kFastaStringIteratorDoc)
-      .def(py::init<py::object>(), py::arg("fasta_string"))
-      .def("__iter__",
-           [](PythonFastaStringIterator& iterator)
-               -> PythonFastaStringIterator& { return iterator; })
-      .def(
-          "__next__",
-          [](PythonFastaStringIterator& iterator) {
-            if (iterator.HasNext()) {
-              return ValueOrThrowValueError(iterator.Next());
-            } else {
-              throw py::stop_iteration();
-            }
-          },
-          py::call_guard<py::gil_scoped_release>());
-
-  m.def("parse_fasta", &ParseFasta, py::arg("fasta_string"),
-        py::call_guard<py::gil_scoped_release>(), py::doc(kParseFastaDoc + 1));
-  m.def("parse_fasta_include_descriptions", &ParseFastaIncludeDescriptions,
-        py::arg("fasta_string"), py::call_guard<py::gil_scoped_release>(),
-        py::doc(kParseFastaIncludeDescriptionsDoc + 1));
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/parsers/cpp/fasta_iterator_pybind.h b/src/alphafold3/parsers/cpp/fasta_iterator_pybind.h
deleted file mode 100644
index 091ea3fa21538a63aec87390583853a6964c6494..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/fasta_iterator_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_FASTA_ITERATOR_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_FASTA_ITERATOR_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleFastaIterator(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_FASTA_ITERATOR_PYBIND_H_
diff --git a/src/alphafold3/parsers/cpp/msa_conversion.pyi b/src/alphafold3/parsers/cpp/msa_conversion.pyi
deleted file mode 100755
index 3602032b91866c252af4f613904ed094a262a972..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/msa_conversion.pyi
+++ /dev/null
@@ -1,26 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Type annotations for Python bindings for `msa_conversion`.
-
-The type annotations in this file were modified from the automatically generated
-stubgen output.
-"""
-
-from collections.abc import Iterable
-
-
-def align_sequence_to_gapless_query(
-    sequence: str | bytes,
-    query_sequence: str | bytes,
-) -> str: ...
-
-
-def convert_a3m_to_stockholm(a3m_sequences: Iterable[str]) -> list[str]: ...
diff --git a/src/alphafold3/parsers/cpp/msa_conversion_pybind.cc b/src/alphafold3/parsers/cpp/msa_conversion_pybind.cc
deleted file mode 100644
index c192052f02bda88b00ceafb2cdbe222b141fcef3..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/msa_conversion_pybind.cc
+++ /dev/null
@@ -1,162 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <algorithm>
-#include <cstddef>
-#include <stdexcept>
-#include <string>
-#include <vector>
-
-#include "absl/strings/ascii.h"
-#include "absl/strings/str_format.h"
-#include "absl/strings/string_view.h"
-#include "pybind11/pybind11.h"
-#include "pybind11/stl.h"
-
-namespace {
-
-namespace py = pybind11;
-
-std::vector<std::string> ConvertA3MToStockholm(
-    std::vector<absl::string_view> a3m_sequences) {
-  std::vector<std::string> stockholm_sequences(a3m_sequences.size());
-  auto max_length_element =
-      std::max_element(a3m_sequences.begin(), a3m_sequences.end(),
-                       [](absl::string_view lhs, absl::string_view rhs) {
-                         return lhs.size() < rhs.size();
-                       });
-
-  for (auto& out : stockholm_sequences) {
-    out.reserve(max_length_element->size());
-  }
-
-  // While any sequence has remaining columns.
-  while (std::any_of(a3m_sequences.begin(), a3m_sequences.end(),
-                     [](absl::string_view in) { return !in.empty(); })) {
-    if (std::any_of(a3m_sequences.begin(), a3m_sequences.end(),
-                    [](absl::string_view in) {
-                      return !in.empty() && absl::ascii_islower(in.front());
-                    })) {
-      // Insertion(s) found at column.
-      for (std::size_t i = 0; i < a3m_sequences.size(); ++i) {
-        absl::string_view& in = a3m_sequences[i];
-        std::string& out = stockholm_sequences[i];
-        if (!in.empty() && absl::ascii_islower(in.front())) {
-          // Consume insertion.
-          out.push_back(absl::ascii_toupper(in.front()));
-          in.remove_prefix(1);
-        } else {
-          // Row requires padding.
-          out.push_back('-');
-        }
-      }
-    } else {
-      // No insertions found.
-      for (std::size_t i = 0; i < a3m_sequences.size(); ++i) {
-        absl::string_view& in = a3m_sequences[i];
-        std::string& out = stockholm_sequences[i];
-        if (!in.empty()) {
-          // Consume entire column.
-          out.push_back(in.front());
-          in.remove_prefix(1);
-        } else {
-          // One alignment is shorter than the others. Should not happen with
-          // valid A3M input.
-          throw std::invalid_argument(absl::StrFormat(
-              "a3m rows have inconsistent lengths; row %d has no columns left "
-              "but not all rows are exhausted",
-              i));
-        }
-      }
-    }
-  }
-  return stockholm_sequences;
-}
-
-std::string AlignSequenceToGaplessQuery(absl::string_view sequence,
-                                        absl::string_view query_sequence) {
-  if (sequence.size() != query_sequence.size()) {
-    throw py::value_error(
-        absl::StrFormat("The sequence (%d) and the query sequence (%d) don't "
-                        "have the same length.",
-                        sequence.size(), query_sequence.size()));
-  }
-  std::string output;
-  for (std::size_t residue_index = 0, sequence_length = sequence.size();
-       residue_index < sequence_length; ++residue_index) {
-    const char query_residue = query_sequence[residue_index];
-    const char residue = sequence[residue_index];
-    if (query_residue != '-') {
-      // No gap in the query, so the residue is aligned.
-      output += residue;
-    } else if (residue == '-') {
-      // Gap in both sequence and query, simply skip.
-      continue;
-    } else {
-      // Gap only in the query, so this must be an inserted residue.
-      output += absl::ascii_tolower(residue);
-    }
-  }
-  return output;
-}
-
-constexpr char kConvertA3mToStockholm[] = R"(
-Converts a list of sequences in a3m format to stockholm format sequences.
-
-As an example if the input is:
-abCD
-CgD
-fCDa
-
-Then the output will be:
-ABC-D-
---CGD-
-F-C-DA
-
-Args:
-  a3m_sequences: A list of strings in a3m format.
-
-Returns
-  A list of strings converted to stockholm format.
-)";
-
-constexpr char kAlignSequenceToGaplessQuery[] = R"(
-Aligns a sequence to a gapless query sequence.
-
-This is useful when converting Stockholm MSA to A3M MSA. Example:
-Seq  : AB--E
-Query: A--DE
-Output: Ab-E.
-
-Args:
-  sequence: A string containing to be aligned.
-  query_sequence: A string containing the reference sequence to align to.
-
-Returns
-  The input sequence with gaps dropped where both the `sequence` and
-  `query_sequence` have gaps, and sequence elements non-capitalized where the
-  `query_sequence` has a gap, but the `sequence` does not.
-)";
-
-}  // namespace
-
-namespace alphafold3 {
-
-void RegisterModuleMsaConversion(pybind11::module m) {
-  m.def("convert_a3m_to_stockholm", &ConvertA3MToStockholm,
-        py::arg("a3m_sequences"), py::call_guard<py::gil_scoped_release>(),
-        py::doc(kConvertA3mToStockholm + 1));
-  m.def("align_sequence_to_gapless_query", &AlignSequenceToGaplessQuery,
-        py::arg("sequence"), py::arg("query_sequence"),
-        py::call_guard<py::gil_scoped_release>(),
-        py::doc(kAlignSequenceToGaplessQuery + 1));
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/parsers/cpp/msa_conversion_pybind.h b/src/alphafold3/parsers/cpp/msa_conversion_pybind.h
deleted file mode 100644
index 65f5fe99ec45f0199a32dd90d544e82fa7f21ea2..0000000000000000000000000000000000000000
--- a/src/alphafold3/parsers/cpp/msa_conversion_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_MSA_CONVERSION_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_MSA_CONVERSION_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleMsaConversion(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_PARSERS_PYTHON_MSA_CONVERSION_PYBIND_H_
diff --git a/src/alphafold3/scripts/copy_to_ssd.sh b/src/alphafold3/scripts/copy_to_ssd.sh
deleted file mode 100755
index 9d53716db1122d2a733a5aceb2817175246c54f2..0000000000000000000000000000000000000000
--- a/src/alphafold3/scripts/copy_to_ssd.sh
+++ /dev/null
@@ -1,54 +0,0 @@
-#!/bin/bash
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-set -euo pipefail
-
-readonly SOURCE_DIR=${1:-$HOME/public_databases}
-readonly TARGET_DIR=${2:-/mnt/disks/ssd/public_databases}
-
-mkdir -p "${TARGET_DIR}"
-
-FILES=(pdb_seqres_2022_09_28.fasta \
-      uniprot_all_2021_04.fa \
-      mgy_clusters_2022_05.fa \
-      uniref90_2022_05.fa \
-      bfd-first_non_consensus_sequences.fasta \
-      rfam_14_9_clust_seq_id_90_cov_80_rep_seq.fasta \
-      nt_rna_2023_02_23_clust_seq_id_90_cov_80_rep_seq.fasta \
-      rnacentral_active_seq_id_90_cov_80_linclust.fasta)
-
-NOT_COPIED_FILES=()
-
-while (( ${#FILES[@]} )); do
-  # Get total size of files to copy in bytes
-  SOURCE_FILES=( "${FILES[@]/#/${SOURCE_DIR}/}" )
-  TOTAL_SIZE=$(du -sbc "${SOURCE_FILES[@]}" | awk 'END{print $1}')
-
-  # Get available space on target drive in bytes
-  AVAILABLE_SPACE=$(df --portability --block-size=1 "$TARGET_DIR" | awk 'END{print $4}')
-
-  # Compare sizes and copy if enough space
-  if (( TOTAL_SIZE <= AVAILABLE_SPACE )); then
-    printf 'Copying files... %s\n' "${FILES[@]}"
-    echo "From ${SOURCE_DIR} -> ${TARGET_DIR}"
-
-    for file in "${FILES[@]}"; do
-      cp -r "${SOURCE_DIR}/${file}" "${TARGET_DIR}/" &
-    done
-    break
-  else
-    NOT_COPIED_FILES+=("${FILES[-1]}")
-    unset 'FILES[-1]'
-  fi
-done
-
-printf 'No room left on ssd for: %s\n' "${NOT_COPIED_FILES[@]}"
-wait
diff --git a/src/alphafold3/scripts/gcp_mount_ssd.sh b/src/alphafold3/scripts/gcp_mount_ssd.sh
deleted file mode 100755
index 18f97888adec1005e347915ba3f6336cbbdaa3fe..0000000000000000000000000000000000000000
--- a/src/alphafold3/scripts/gcp_mount_ssd.sh
+++ /dev/null
@@ -1,47 +0,0 @@
-#!/bin/bash
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-set -euo pipefail
-
-readonly MOUNT_DIR="${1:-/mnt/disks/ssd}"
-
-if [[ -d "${MOUNT_DIR}" ]]; then
-  echo "Mount directory ${MOUNT_DIR} already exists, skipping"
-  exit 0
-fi
-
-for SSD_DISK in $(realpath "$(find /dev/disk/by-id/ | grep google-local)")
-do
-  # Check if the disk is already formatted
-  if ! blkid -o value -s TYPE "${SSD_DISK}" > /dev/null 2>&1; then
-    echo "Disk ${SSD_DISK} is not formatted, format it."
-    mkfs.ext4 -m 0 -E lazy_itable_init=0,lazy_journal_init=0,discard "${SSD_DISK}" || continue
-  fi
-
-  # Check if the disk is already mounted
-  if grep -qs "^/dev/nvme0n1 " /proc/mounts; then
-    grep -s "^/dev/nvme0n1 " /proc/mounts
-    echo "Disk ${SSD_DISK} is already mounted, skip it."
-    continue
-  fi
-
-  # Disk is not mounted, mount it
-  echo "Mounting ${SSD_DISK} to ${MOUNT_DIR}"
-  mkdir -p "${MOUNT_DIR}"
-  chmod -R 777 "${MOUNT_DIR}"
-  mount "${SSD_DISK}" "${MOUNT_DIR}"
-  break
-done
-
-if [[ ! -d "${MOUNT_DIR}" ]]; then
-  echo "No unmounted SSD disks found"
-  exit 1
-fi
diff --git a/src/alphafold3/structure/__init__.py b/src/alphafold3/structure/__init__.py
deleted file mode 100644
index 94da943b43f0bb69b6997d5bec3d8882e4c0e3ea..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/__init__.py
+++ /dev/null
@@ -1,46 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Structure module initialization."""
-
-# pylint: disable=g-importing-member
-from alphafold3.structure.bioassemblies import BioassemblyData
-from alphafold3.structure.bonds import Bonds
-from alphafold3.structure.chemical_components import ChemCompEntry
-from alphafold3.structure.chemical_components import ChemicalComponentsData
-from alphafold3.structure.chemical_components import get_data_for_ccd_components
-from alphafold3.structure.chemical_components import populate_missing_ccd_data
-from alphafold3.structure.mmcif import BondParsingError
-from alphafold3.structure.parsing import BondAtomId
-from alphafold3.structure.parsing import from_atom_arrays
-from alphafold3.structure.parsing import from_mmcif
-from alphafold3.structure.parsing import from_parsed_mmcif
-from alphafold3.structure.parsing import from_res_arrays
-from alphafold3.structure.parsing import from_sequences_and_bonds
-from alphafold3.structure.parsing import ModelID
-from alphafold3.structure.parsing import NoAtomsError
-from alphafold3.structure.parsing import SequenceFormat
-from alphafold3.structure.structure import ARRAY_FIELDS
-from alphafold3.structure.structure import AuthorNamingScheme
-from alphafold3.structure.structure import Bond
-from alphafold3.structure.structure import CascadeDelete
-from alphafold3.structure.structure import concat
-from alphafold3.structure.structure import enumerate_residues
-from alphafold3.structure.structure import fix_non_standard_polymer_residues
-from alphafold3.structure.structure import GLOBAL_FIELDS
-from alphafold3.structure.structure import make_empty_structure
-from alphafold3.structure.structure import MissingAtomError
-from alphafold3.structure.structure import MissingAuthorResidueIdError
-from alphafold3.structure.structure import multichain_residue_index
-from alphafold3.structure.structure import stack
-from alphafold3.structure.structure import Structure
-from alphafold3.structure.structure_tables import Atoms
-from alphafold3.structure.structure_tables import Chains
-from alphafold3.structure.structure_tables import Residues
diff --git a/src/alphafold3/structure/bioassemblies.py b/src/alphafold3/structure/bioassemblies.py
deleted file mode 100644
index 9eeba29c4e2794984d408bd2391040a63b6e08aa..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/bioassemblies.py
+++ /dev/null
@@ -1,327 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Utilities for parsing and manipulating bioassembly data."""
-
-from collections.abc import Mapping, Sequence
-import copy
-import dataclasses
-from typing import Self
-
-from alphafold3.structure import mmcif
-import numpy as np
-
-
-@dataclasses.dataclass(frozen=True)
-class Operation:
-  """A rigid transformation operation."""
-
-  trans: np.ndarray  # shape: (3,)
-  rot: np.ndarray  # shape: (3, 3)
-
-  def apply_to_coords(self, coords: np.ndarray) -> np.ndarray:
-    """Applies the rotation followed by the translation to `coords`."""
-    return np.dot(coords, self.rot.T) + self.trans[np.newaxis, :]
-
-
-@dataclasses.dataclass(frozen=True)
-class Transform:
-  """A rigid transformation composed of a sequence of `Operation`s."""
-
-  # The sequence of operations that form the transform. These will be applied
-  # right-to-left (last-to-first).
-  operations: Sequence[Operation]
-
-  # The chain IDs that this transform should be applied to. These are
-  # label_asym_ids in the mmCIF spec.
-  chain_ids: Sequence[str]
-
-  # A mapping from chain IDs (of chains that participate in this transform)
-  # to their new values in the bioassembly.
-  chain_id_rename_map: Mapping[str, str]
-
-  def apply_to_coords(self, coords: np.ndarray) -> np.ndarray:
-    """Applies the `operations` in right-to-left order."""
-    for operation in reversed(self.operations):
-      coords = operation.apply_to_coords(coords)
-    return coords
-
-
-def _get_operation(oper_data: Mapping[str, str]) -> Operation:
-  """Parses an `Operation` from a mmCIF _pdbx_struct_oper_list row."""
-  trans = np.zeros((3,), dtype=np.float32)
-  rot = np.zeros((3, 3), dtype=np.float32)
-  for i in range(3):
-    trans[i] = float(oper_data[f'_pdbx_struct_oper_list.vector[{i + 1}]'])
-  for i in range(3):
-    for j in range(3):
-      rot[i][j] = float(
-          oper_data[f'_pdbx_struct_oper_list.matrix[{i + 1}][{j + 1}]']
-      )
-  return Operation(trans=trans, rot=rot)
-
-
-class MissingBioassemblyDataError(Exception):
-  """Raised when bioassembly data is missing from an mmCIF."""
-
-
-class BioassemblyData:
-  """Stores and processes bioassembly data from mmCIF tables."""
-
-  # Not all of these columns are required for internal operations, but all
-  # should be present whenever bioassemblies are defined in an mmCIF to stay
-  # consistent with external mmCIFs.
-  _REQUIRED_COLUMNS = (
-      '_pdbx_struct_assembly.id',
-      '_pdbx_struct_assembly.details',
-      '_pdbx_struct_assembly.method_details',
-      '_pdbx_struct_assembly.oligomeric_details',
-      '_pdbx_struct_assembly.oligomeric_count',
-      '_pdbx_struct_assembly_gen.assembly_id',
-      '_pdbx_struct_assembly_gen.oper_expression',
-      '_pdbx_struct_assembly_gen.asym_id_list',
-      '_pdbx_struct_oper_list.id',
-      '_pdbx_struct_oper_list.type',
-      '_pdbx_struct_oper_list.name',
-      '_pdbx_struct_oper_list.symmetry_operation',
-      '_pdbx_struct_oper_list.matrix[1][1]',
-      '_pdbx_struct_oper_list.matrix[1][2]',
-      '_pdbx_struct_oper_list.matrix[1][3]',
-      '_pdbx_struct_oper_list.vector[1]',
-      '_pdbx_struct_oper_list.matrix[2][1]',
-      '_pdbx_struct_oper_list.matrix[2][2]',
-      '_pdbx_struct_oper_list.matrix[2][3]',
-      '_pdbx_struct_oper_list.vector[2]',
-      '_pdbx_struct_oper_list.matrix[3][1]',
-      '_pdbx_struct_oper_list.matrix[3][2]',
-      '_pdbx_struct_oper_list.matrix[3][3]',
-      '_pdbx_struct_oper_list.vector[3]',
-  )
-
-  def __init__(
-      self,
-      *,
-      pdbx_struct_assembly: Mapping[str, Mapping[str, str]],
-      pdbx_struct_assembly_gen: Mapping[str, Sequence[Mapping[str, str]]],
-      pdbx_struct_oper_list: Mapping[str, Mapping[str, str]],
-      assembly_ids: Sequence[str],
-      oper_ids: Sequence[str],
-  ):
-    for assembly_id in assembly_ids:
-      for table, table_name in (
-          (pdbx_struct_assembly, '_pdbx_struct_assembly'),
-          (pdbx_struct_assembly_gen, '_pdbx_struct_assembly_gen'),
-      ):
-        if assembly_id not in table:
-          raise ValueError(
-              f'Assembly ID "{assembly_id}" missing from {table_name} '
-              f'with keys: {table.keys()}'
-          )
-    for oper_id in oper_ids:
-      if oper_id not in pdbx_struct_oper_list:
-        raise ValueError(
-            f'Oper ID "{oper_id}" missing from _pdbx_struct_oper_list '
-            f'with keys: {pdbx_struct_oper_list.keys()}'
-        )
-
-    self._pdbx_struct_assembly = pdbx_struct_assembly
-    self._pdbx_struct_assembly_gen = pdbx_struct_assembly_gen
-    self._pdbx_struct_oper_list = pdbx_struct_oper_list
-    self._operations = {
-        oper_id: _get_operation(oper_data)
-        for oper_id, oper_data in self._pdbx_struct_oper_list.items()
-    }
-    self._assembly_ids = assembly_ids
-    self._oper_ids = oper_ids
-
-  @classmethod
-  def from_mmcif(cls, cif: mmcif.Mmcif) -> Self:
-    """Constructs an instance of `BioassemblyData` from an `Mmcif` object."""
-    for col in cls._REQUIRED_COLUMNS:
-      if col not in cif:
-        raise MissingBioassemblyDataError(col)
-
-    pdbx_struct_assembly = cif.extract_loop_as_dict(
-        prefix='_pdbx_struct_assembly.', index='_pdbx_struct_assembly.id'
-    )
-    pdbx_struct_oper_list = cif.extract_loop_as_dict(
-        prefix='_pdbx_struct_oper_list.', index='_pdbx_struct_oper_list.id'
-    )
-
-    # _pdbx_struct_assembly_gen is unlike the other two tables because it can
-    # have multiple rows share the same assembly ID. This can happen when an
-    # assembly is constructed by applying different sets of transforms to
-    # different sets of chain IDs. Each of these would have its own row.
-    # Here we group rows by their assembly_id.
-    pdbx_struct_assembly_gen = {}
-    for assembly_id, oper_expression, asym_id_list in zip(
-        cif['_pdbx_struct_assembly_gen.assembly_id'],
-        cif['_pdbx_struct_assembly_gen.oper_expression'],
-        cif['_pdbx_struct_assembly_gen.asym_id_list'],
-    ):
-      pdbx_struct_assembly_gen.setdefault(assembly_id, []).append({
-          '_pdbx_struct_assembly_gen.assembly_id': assembly_id,
-          '_pdbx_struct_assembly_gen.oper_expression': oper_expression,
-          '_pdbx_struct_assembly_gen.asym_id_list': asym_id_list,
-      })
-
-    # We provide these separately to keep track of the original order that they
-    # appear in the mmCIF.
-    assembly_ids = cif['_pdbx_struct_assembly.id']
-    oper_ids = cif['_pdbx_struct_oper_list.id']
-    return cls(
-        pdbx_struct_assembly=pdbx_struct_assembly,
-        pdbx_struct_assembly_gen=pdbx_struct_assembly_gen,
-        pdbx_struct_oper_list=pdbx_struct_oper_list,
-        assembly_ids=assembly_ids,
-        oper_ids=oper_ids,
-    )
-
-  @property
-  def assembly_ids(self) -> Sequence[str]:
-    return self._assembly_ids
-
-  def asym_id_by_assembly_chain_id(self, assembly_id: str) -> Mapping[str, str]:
-    asym_id_by_assembly_chain_id = {}
-    for transform in self.get_transforms(assembly_id):
-      for asym_id, assembly_chain_id in transform.chain_id_rename_map.items():
-        asym_id_by_assembly_chain_id[assembly_chain_id] = asym_id
-    return asym_id_by_assembly_chain_id
-
-  def assembly_chain_ids_by_asym_id(
-      self, assembly_id: str
-  ) -> Mapping[str, set[str]]:
-    assembly_chain_ids_by_asym_id = {}
-    for transform in self.get_transforms(assembly_id):
-      for asym_id, assembly_chain_id in transform.chain_id_rename_map.items():
-        assembly_chain_ids_by_asym_id.setdefault(asym_id, set()).add(
-            assembly_chain_id
-        )
-    return assembly_chain_ids_by_asym_id
-
-  def get_default_assembly_id(self) -> str:
-    """Gets a default assembly ID."""
-    # The first assembly is usually (though not always) the best choice.
-    # If we find a better heuristic for picking bioassemblies then this
-    # method should be updated.
-    return min(self._assembly_ids)
-
-  def get_assembly_info(self, assembly_id: str) -> Mapping[str, str]:
-    return {
-        k.replace('_pdbx_struct_assembly.', ''): v
-        for k, v in self._pdbx_struct_assembly[assembly_id].items()
-    }
-
-  def get_transforms(self, assembly_id: str) -> Sequence[Transform]:
-    """Returns the transforms required to generate the given assembly."""
-    partial_transforms = []
-    all_chain_ids = set()
-    for row in self._pdbx_struct_assembly_gen[assembly_id]:
-      oper_expression = row['_pdbx_struct_assembly_gen.oper_expression']
-      parsed_oper_id_seqs = mmcif.parse_oper_expr(oper_expression)
-      label_asym_ids = row['_pdbx_struct_assembly_gen.asym_id_list'].split(',')
-      all_chain_ids |= set(label_asym_ids)
-      for parsed_oper_id_seq in parsed_oper_id_seqs:
-        partial_transforms.append((parsed_oper_id_seq, label_asym_ids))
-
-    # We start assigning new chain IDs by finding the largest chain ID in
-    # the original structure that is involved in this bioassembly, and then
-    # starting from the next one.
-    max_int_chain_id = max(mmcif.str_id_to_int_id(c) for c in all_chain_ids)
-    next_int_chain_id = max_int_chain_id + 1
-
-    transforms = []
-    has_been_renamed = set()
-    for parsed_oper_id_seq, label_asym_ids in partial_transforms:
-      chain_id_rename_map = {}
-      for label_asym_id in label_asym_ids:
-        if label_asym_id not in has_been_renamed:
-          # The first time we see a label_asym_id we don't need to rename it.
-          # This isn't strictly necessary since we don't provide any
-          # guarantees about chain naming after bioassembly extraction but
-          # can make it a bit easier to inspect and compare structures
-          # pre and post bioassembly extraction.
-          chain_id_rename_map[label_asym_id] = label_asym_id
-          has_been_renamed.add(label_asym_id)
-        else:
-          chain_id_rename_map[label_asym_id] = mmcif.int_id_to_str_id(
-              next_int_chain_id
-          )
-          next_int_chain_id += 1
-      transforms.append(
-          Transform(
-              operations=[
-                  self._operations[oper_id] for oper_id in parsed_oper_id_seq
-              ],
-              chain_ids=label_asym_ids,
-              chain_id_rename_map=chain_id_rename_map,
-          )
-      )
-    return transforms
-
-  def to_mmcif_dict(self) -> Mapping[str, Sequence[str]]:
-    """Returns the bioassembly data as a dict suitable for `mmcif.Mmcif`."""
-    mmcif_dict = {}
-    for assembly_id in self._assembly_ids:
-      for column, val in self._pdbx_struct_assembly[assembly_id].items():
-        mmcif_dict.setdefault(column, []).append(val)
-      for row in self._pdbx_struct_assembly_gen[assembly_id]:
-        for column, val in row.items():
-          mmcif_dict.setdefault(column, []).append(val)
-    for oper_id in self._oper_ids:
-      for column, val in self._pdbx_struct_oper_list[oper_id].items():
-        mmcif_dict.setdefault(column, []).append(val)
-    return mmcif_dict
-
-  def rename_label_asym_ids(
-      self,
-      mapping: Mapping[str, str],
-      present_chains: set[str],
-  ) -> Self:
-    """Returns a new BioassemblyData with renamed label_asym_ids.
-
-    Args:
-      mapping: A mapping from original label_asym_ids to their new values. Any
-        label_asym_ids in this BioassemblyData that are not in this mapping will
-        remain unchanged.
-      present_chains: A set of label_asym_ids that are actually present in the
-        atom site list. All label_asym_ids that are in the BioassemblyData but
-        not in present_chains won't be included in the output BioassemblyData.
-
-    Returns:
-      A new BioassemblyData with renamed label_asym_ids.
-
-    Raises:
-      ValueError: If any two previously distinct chains do not have unique names
-          anymore after the rename.
-    """
-    new_pdbx_struct_assembly_gen = copy.deepcopy(self._pdbx_struct_assembly_gen)
-    for rows in new_pdbx_struct_assembly_gen.values():
-      for row in rows:
-        old_asym_ids = row['_pdbx_struct_assembly_gen.asym_id_list'].split(',')
-        new_asym_ids = [
-            mapping.get(label_asym_id, label_asym_id)
-            for label_asym_id in old_asym_ids
-            if label_asym_id in present_chains
-        ]
-        if len(set(old_asym_ids) & present_chains) != len(set(new_asym_ids)):
-          raise ValueError(
-              'Can not rename chains, the new names are not unique: '
-              f'{sorted(new_asym_ids)}.'
-          )
-        row['_pdbx_struct_assembly_gen.asym_id_list'] = ','.join(new_asym_ids)  # pytype: disable=unsupported-operands
-
-    return BioassemblyData(
-        pdbx_struct_assembly=copy.deepcopy(self._pdbx_struct_assembly),
-        pdbx_struct_assembly_gen=new_pdbx_struct_assembly_gen,
-        pdbx_struct_oper_list=copy.deepcopy(self._pdbx_struct_oper_list),
-        assembly_ids=copy.deepcopy(self._assembly_ids),
-        oper_ids=copy.deepcopy(self._oper_ids),
-    )
diff --git a/src/alphafold3/structure/bonds.py b/src/alphafold3/structure/bonds.py
deleted file mode 100644
index 176d79c7f5c33f45863217f17f3b70bb0c53eefc..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/bonds.py
+++ /dev/null
@@ -1,235 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Bond representation for structure module."""
-
-import collections
-from collections.abc import Mapping, Sequence
-import dataclasses
-import typing
-from typing import Self
-
-from alphafold3.structure import table
-import numpy as np
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True)
-class Bonds(table.Table):
-  """Table of atomic bonds."""
-
-  # mmCIF column: _struct_conn.conn_type_id
-  # mmCIF desc: This data item is a pointer to _struct_conn_type.id in the
-  #             STRUCT_CONN_TYPE category.
-  # E.g.: "covale", "disulf", "hydrog", "metalc".
-  type: np.ndarray
-
-  # mmCIF column: _struct_conn.pdbx_role
-  # mmCIF desc: The chemical or structural role of the interaction.
-  # E.g.: "N-Glycosylation", "O-Glycosylation".
-  role: np.ndarray
-
-  # mmCIF columns: _struct_conn.ptnr1_*
-  from_atom_key: np.ndarray
-
-  # mmCIF columns: _struct_conn.ptnr2_*
-  dest_atom_key: np.ndarray
-
-  @classmethod
-  def make_empty(cls) -> Self:
-    return cls(
-        key=np.empty((0,), dtype=np.int64),
-        from_atom_key=np.empty((0,), dtype=np.int64),
-        dest_atom_key=np.empty((0,), dtype=np.int64),
-        type=np.empty((0,), dtype=object),
-        role=np.empty((0,), dtype=object),
-    )
-
-  def get_atom_indices(
-      self,
-      atom_key: np.ndarray,
-  ) -> tuple[np.ndarray, np.ndarray]:
-    """Returns the indices of the from/dest atoms in the atom_key array."""
-    from_atom_missing = ~np.isin(self.from_atom_key, atom_key)
-    dest_atom_missing = ~np.isin(self.dest_atom_key, atom_key)
-    if np.any(from_atom_missing):
-      raise ValueError(
-          f'No atoms for from_atom_key {self.from_atom_key[from_atom_missing]}'
-      )
-    if np.any(dest_atom_missing):
-      raise ValueError(
-          f'No atoms for dest_atom_key {self.dest_atom_key[dest_atom_missing]}'
-      )
-    sort_indices = np.argsort(atom_key)
-    from_indices_sorted = np.searchsorted(
-        atom_key, self.from_atom_key, sorter=sort_indices
-    )
-    dest_indices_sorted = np.searchsorted(
-        atom_key, self.dest_atom_key, sorter=sort_indices
-    )
-    from_indices = sort_indices[from_indices_sorted]
-    dest_indices = sort_indices[dest_indices_sorted]
-    return from_indices, dest_indices
-
-  def restrict_to_atoms(self, atom_key: np.ndarray) -> Self:
-    if not self.size:  # Early-out for empty table.
-      return self
-    from_atom_mask = np.isin(self.from_atom_key, atom_key)
-    dest_atom_mask = np.isin(self.dest_atom_key, atom_key)
-    mask = np.logical_and(from_atom_mask, dest_atom_mask)
-    return typing.cast(Bonds, self.filter(mask=mask))
-
-  def to_mmcif_dict_from_atom_arrays(
-      self,
-      atom_key: np.ndarray,
-      chain_id: np.ndarray,
-      res_id: np.ndarray,
-      res_name: np.ndarray,
-      atom_name: np.ndarray,
-      auth_asym_id: np.ndarray,
-      auth_seq_id: np.ndarray,
-      insertion_code: np.ndarray,
-  ) -> Mapping[str, Sequence[str] | np.ndarray]:
-    """Returns a dict suitable for building a CifDict, representing bonds.
-
-    Args:
-      atom_key: A (num_atom,) integer array of atom_keys.
-      chain_id: A (num_atom,) array of label_asym_id strings.
-      res_id: A (num_atom,) array of label_seq_id strings.
-      res_name: A (num_atom,) array of label_comp_id strings.
-      atom_name: A (num_atom,) array of label_atom_id strings.
-      auth_asym_id: A (num_atom,) array of auth_asym_id strings.
-      auth_seq_id: A (num_atom,) array of auth_seq_id strings.
-      insertion_code: A (num_atom,) array of insertion code strings.
-    """
-    mmcif_dict = collections.defaultdict(list)
-    ptnr1_indices, ptnr2_indices = self.get_atom_indices(atom_key)
-
-    mmcif_dict['_struct_conn.ptnr1_label_asym_id'] = chain_id[ptnr1_indices]
-    mmcif_dict['_struct_conn.ptnr2_label_asym_id'] = chain_id[ptnr2_indices]
-    mmcif_dict['_struct_conn.ptnr1_label_comp_id'] = res_name[ptnr1_indices]
-    mmcif_dict['_struct_conn.ptnr2_label_comp_id'] = res_name[ptnr2_indices]
-    mmcif_dict['_struct_conn.ptnr1_label_seq_id'] = res_id[ptnr1_indices]
-    mmcif_dict['_struct_conn.ptnr2_label_seq_id'] = res_id[ptnr2_indices]
-    mmcif_dict['_struct_conn.ptnr1_label_atom_id'] = atom_name[ptnr1_indices]
-    mmcif_dict['_struct_conn.ptnr2_label_atom_id'] = atom_name[ptnr2_indices]
-
-    mmcif_dict['_struct_conn.ptnr1_auth_asym_id'] = auth_asym_id[ptnr1_indices]
-    mmcif_dict['_struct_conn.ptnr2_auth_asym_id'] = auth_asym_id[ptnr2_indices]
-    mmcif_dict['_struct_conn.ptnr1_auth_seq_id'] = auth_seq_id[ptnr1_indices]
-    mmcif_dict['_struct_conn.ptnr2_auth_seq_id'] = auth_seq_id[ptnr2_indices]
-    mmcif_dict['_struct_conn.pdbx_ptnr1_PDB_ins_code'] = insertion_code[
-        ptnr1_indices
-    ]
-    mmcif_dict['_struct_conn.pdbx_ptnr2_PDB_ins_code'] = insertion_code[
-        ptnr2_indices
-    ]
-
-    label_alt_id = ['?'] * self.size
-    mmcif_dict['_struct_conn.pdbx_ptnr1_label_alt_id'] = label_alt_id
-    mmcif_dict['_struct_conn.pdbx_ptnr2_label_alt_id'] = label_alt_id
-
-    # We need to set this to make visualisation work in NGL/PyMOL.
-    mmcif_dict['_struct_conn.pdbx_value_order'] = ['?'] * self.size
-
-    # We use a symmetry of 1_555 which is the no-op transformation. Other
-    # values are used when bonds involve atoms that only exist after expanding
-    # the bioassembly, but we don't support this kind of bond at the moment.
-    symmetry = ['1_555'] * self.size
-    mmcif_dict['_struct_conn.ptnr1_symmetry'] = symmetry
-    mmcif_dict['_struct_conn.ptnr2_symmetry'] = symmetry
-    bond_type_counter = collections.Counter()
-    for bond_row in self.iterrows():
-      bond_type = bond_row['type']
-      bond_type_counter[bond_type] += 1
-      mmcif_dict['_struct_conn.id'].append(
-          f'{bond_type}{bond_type_counter[bond_type]}'
-      )
-      mmcif_dict['_struct_conn.pdbx_role'].append(bond_row['role'])
-      mmcif_dict['_struct_conn.conn_type_id'].append(bond_type)
-
-    bond_types = np.unique(self.type)
-    mmcif_dict['_struct_conn_type.id'] = bond_types
-    unknown = ['?'] * len(bond_types)
-    mmcif_dict['_struct_conn_type.criteria'] = unknown
-    mmcif_dict['_struct_conn_type.reference'] = unknown
-
-    return dict(mmcif_dict)
-
-
-def concat_with_atom_keys(
-    bonds_tables: Sequence[Bonds | None],
-    atom_key_arrays: Sequence[np.ndarray],
-) -> tuple[Bonds | None, np.ndarray]:
-  """Concatenates bonds tables and atom keys simultaneously.
-
-  Args:
-    bonds_tables: A sequence of `Bonds` instances to concatenate. If any are
-      None then these are skipped.
-    atom_key_arrays: A sequence of integer `atom_key` arrays, where the n-th
-      bonds_table referrs to the atoms in the n-th atom_key array. These must
-      all be non-None.
-
-  Returns:
-    A pair of (bonds, atom_key) where atom_key is a unique atom_key array with
-    length equal to the sum of the input atom array sizes, and the bonds table
-    contains all the bonds from the individual bonds table inputs.
-  """
-  if not bonds_tables or not atom_key_arrays:
-    if bonds_tables or atom_key_arrays:
-      raise ValueError(
-          'bonds_tables and atom_keys must have same length but got'
-          f' {len(bonds_tables)=} and {len(atom_key_arrays)=}'
-      )
-    return None, np.array([], dtype=np.int64)
-  max_key = -1
-  atom_keys_to_concat = []
-  types_to_concat = []
-  roles_to_concat = []
-  from_atom_keys_to_concat = []
-  dest_atom_keys_to_concat = []
-  for bonds, atom_key in zip(bonds_tables, atom_key_arrays, strict=True):
-    if not atom_key.size:
-      assert bonds is None or bonds.size == 0
-      continue
-    assert np.min(atom_key, initial=0) >= 0  # Should always be non-negative!
-    offset = max_key + 1
-    offset_atom_key = atom_key + offset
-    atom_keys_to_concat.append(offset_atom_key)
-    max_key = np.max(offset_atom_key)
-    if bonds is not None:
-      types_to_concat.append(bonds.type)
-      roles_to_concat.append(bonds.role)
-      from_atom_keys_to_concat.append(bonds.from_atom_key + offset)
-      dest_atom_keys_to_concat.append(bonds.dest_atom_key + offset)
-
-  if atom_keys_to_concat:
-    concatted_atom_keys = np.concatenate(atom_keys_to_concat, axis=0)
-  else:
-    concatted_atom_keys = np.array([], dtype=np.int64)
-
-  if types_to_concat:
-    assert (
-        len(types_to_concat)
-        == len(roles_to_concat)
-        == len(from_atom_keys_to_concat)
-        == len(dest_atom_keys_to_concat)
-    )
-    num_bonds = sum(b.size for b in bonds_tables if b is not None)
-    concatted_bonds = Bonds(
-        key=np.arange(num_bonds, dtype=np.int64),
-        type=np.concatenate(types_to_concat, axis=0),
-        role=np.concatenate(roles_to_concat, axis=0),
-        from_atom_key=np.concatenate(from_atom_keys_to_concat, axis=0),
-        dest_atom_key=np.concatenate(dest_atom_keys_to_concat, axis=0),
-    )
-  else:
-    concatted_bonds = None
-
-  return concatted_bonds, concatted_atom_keys
diff --git a/src/alphafold3/structure/chemical_components.py b/src/alphafold3/structure/chemical_components.py
deleted file mode 100644
index e0365605c196f58f5bc9a664e4d1b00fad022332..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/chemical_components.py
+++ /dev/null
@@ -1,284 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Utilities for manipulating chemical components data."""
-
-from collections.abc import Iterable, Mapping, Sequence
-import dataclasses
-import functools
-from typing import Self
-
-from alphafold3.constants import chemical_components
-from alphafold3.constants import residue_names
-from alphafold3.structure import mmcif
-import rdkit.Chem as rd_chem
-
-
-@dataclasses.dataclass(frozen=True)
-class ChemCompEntry:
-  """Items of _chem_comp category.
-
-  For the full list of items and their semantics see
-  http://mmcif.rcsb.org/dictionaries/mmcif_pdbx_v50.dic/Categories/chem_comp.html
-  """
-
-  type: str
-  name: str = '?'
-  pdbx_synonyms: str = '?'
-  formula: str = '?'
-  formula_weight: str = '?'
-  mon_nstd_flag: str = '?'
-  pdbx_smiles: str | None = None
-
-  def __post_init__(self):
-    for field, value in vars(self).items():
-      if not value and value is not None:
-        raise ValueError(f"{field} value can't be an empty string.")
-
-  def extends(self, other: Self) -> bool:
-    """Checks whether this ChemCompEntry extends another one."""
-    for field, value in vars(self).items():
-      other_value = getattr(other, field)
-      if _value_is_missing(other_value):
-        continue
-      if value != other_value:
-        return False
-    return True
-
-  @property
-  def rdkit_mol(self) -> rd_chem.Mol:
-    """Returns an RDKit Mol, created via RDKit from entry SMILES string."""
-    if not self.pdbx_smiles:
-      raise ValueError('Cannot construct RDKit Mol with empty pdbx_smiles')
-    return rd_chem.MolFromSmiles(self.pdbx_smiles)
-
-
-_REQUIRED_MMCIF_COLUMNS = ('_chem_comp.id', '_chem_comp.type')
-
-
-class MissingChemicalComponentsDataError(Exception):
-  """Raised when chemical components data is missing from an mmCIF."""
-
-
-@dataclasses.dataclass(frozen=True)
-class ChemicalComponentsData:
-  """Extra information for chemical components occurring in mmCIF.
-
-  Fields:
-    chem_comp: A mapping from _chem_comp.id to associated items in the
-      chem_comp category.
-  """
-
-  chem_comp: Mapping[str, ChemCompEntry]
-
-  @classmethod
-  def from_mmcif(
-      cls, cif: mmcif.Mmcif, fix_mse: bool, fix_unknown_dna: bool
-  ) -> Self:
-    """Constructs an instance of ChemicalComponentsData from an Mmcif object."""
-    for col in _REQUIRED_MMCIF_COLUMNS:
-      if col not in cif:
-        raise MissingChemicalComponentsDataError(col)
-
-    id_ = cif['_chem_comp.id']  # Guaranteed to be present.
-    type_ = cif['_chem_comp.type']  # Guaranteed to be present.
-    name = cif.get('_chem_comp.name', ['?'] * len(id_))
-    synonyms = cif.get('_chem_comp.pdbx_synonyms', ['?'] * len(id_))
-    formula = cif.get('_chem_comp.formula', ['?'] * len(id_))
-    weight = cif.get('_chem_comp.formula_weight', ['?'] * len(id_))
-    mon_nstd_flag = cif.get('_chem_comp.mon_nstd_flag', ['?'] * len(id_))
-    smiles = cif.get('_chem_comp.pdbx_smiles', ['?'] * len(id_))
-    smiles = [None if s == '?' else s for s in smiles]
-
-    chem_comp = {
-        component_name: ChemCompEntry(*entry)
-        for component_name, *entry in zip(
-            id_, type_, name, synonyms, formula, weight, mon_nstd_flag, smiles
-        )
-    }
-
-    if fix_mse and 'MSE' in chem_comp:
-      if 'MET' not in chem_comp:
-        chem_comp['MET'] = ChemCompEntry(
-            type='L-PEPTIDE LINKING',
-            name='METHIONINE',
-            pdbx_synonyms='?',
-            formula='C5 H11 N O2 S',
-            formula_weight='149.211',
-            mon_nstd_flag='y',
-            pdbx_smiles=None,
-        )
-
-    if fix_unknown_dna and 'N' in chem_comp:
-      # Do not delete 'N' as it may be needed for RNA in the system.
-      if 'DN' not in chem_comp:
-        chem_comp['DN'] = ChemCompEntry(
-            type='DNA LINKING',
-            name="UNKNOWN 2'-DEOXYNUCLEOTIDE",
-            pdbx_synonyms='?',
-            formula='C5 H11 O6 P',
-            formula_weight='198.111',
-            mon_nstd_flag='y',
-            pdbx_smiles=None,
-        )
-
-    return ChemicalComponentsData(chem_comp)
-
-  def to_mmcif_dict(self) -> Mapping[str, Sequence[str]]:
-    """Returns chemical components data as a dict suitable for `mmcif.Mmcif`."""
-    mmcif_dict = {}
-
-    mmcif_fields = set()
-    for entry in self.chem_comp.values():
-      for field, value in vars(entry).items():
-        if value:
-          mmcif_fields.add(field)
-    chem_comp_ids = []
-    for component_id in sorted(self.chem_comp):
-      entry = self.chem_comp[component_id]
-      chem_comp_ids.append(component_id)
-      for field in mmcif_fields:
-        mmcif_dict.setdefault(f'_chem_comp.{field}', []).append(
-            getattr(entry, field) or '?'
-        )
-    if chem_comp_ids:
-      mmcif_dict['_chem_comp.id'] = chem_comp_ids
-    return mmcif_dict
-
-
-def _value_is_missing(value: str) -> bool:
-  return not value or value in ('.', '?')
-
-
-def get_data_for_ccd_components(
-    ccd: chemical_components.Ccd,
-    chemical_component_ids: Iterable[str],
-    populate_pdbx_smiles: bool = False,
-) -> ChemicalComponentsData:
-  """Returns `ChemicalComponentsData` for chemical components known by PDB."""
-  chem_comp = {}
-  for chemical_component_id in chemical_component_ids:
-    chem_data = chemical_components.component_name_to_info(
-        ccd=ccd, res_name=chemical_component_id
-    )
-    if not chem_data:
-      continue
-    chem_comp[chemical_component_id] = ChemCompEntry(
-        type=chem_data.type,
-        name=chem_data.name,
-        pdbx_synonyms=chem_data.pdbx_synonyms,
-        formula=chem_data.formula,
-        formula_weight=chem_data.formula_weight,
-        mon_nstd_flag=chem_data.mon_nstd_flag,
-        pdbx_smiles=(
-            chem_data.pdbx_smiles or None if populate_pdbx_smiles else None
-        ),
-    )
-  return ChemicalComponentsData(chem_comp=chem_comp)
-
-
-def populate_missing_ccd_data(
-    ccd: chemical_components.Ccd,
-    chemical_components_data: ChemicalComponentsData,
-    chemical_component_ids: Iterable[str] | None = None,
-    populate_pdbx_smiles: bool = False,
-) -> ChemicalComponentsData:
-  """Populates missing data for the chemical components from CCD.
-
-  Args:
-    ccd: The chemical components database.
-    chemical_components_data: ChemicalComponentsData to populate missing values
-      for. This function doesn't modify the object, extended version is provided
-      as a return value.
-    chemical_component_ids: chemical components to populate missing values for.
-      If not specified, the function will consider all chemical components which
-      are already present in `chemical_components_data`.
-    populate_pdbx_smiles: whether to populate `pdbx_smiles` field using SMILES
-      descriptors from _pdbx_chem_comp_descriptor CCD table. If CCD provides
-      multiple SMILES strings, any of them could be used.
-
-  Returns:
-    New instance of ChemicalComponentsData without missing values for CCD
-    entries.
-  """
-  if chemical_component_ids is None:
-    chemical_component_ids = chemical_components_data.chem_comp.keys()
-
-  ccd_data = get_data_for_ccd_components(
-      ccd, chemical_component_ids, populate_pdbx_smiles
-  )
-  chem_comp = dict(chemical_components_data.chem_comp)
-  for component_id, ccd_entry in ccd_data.chem_comp.items():
-    if component_id not in chem_comp:
-      chem_comp[component_id] = ccd_entry
-    else:
-      already_specified_fields = {
-          field: value
-          for field, value in vars(chem_comp[component_id]).items()
-          if not _value_is_missing(value)
-      }
-      chem_comp[component_id] = ChemCompEntry(
-          **{**vars(ccd_entry), **already_specified_fields}
-      )
-  return ChemicalComponentsData(chem_comp=chem_comp)
-
-
-def get_all_atoms_in_entry(
-    ccd: chemical_components.Ccd, res_name: str
-) -> Mapping[str, Sequence[str]]:
-  """Get all possible atoms and bonds for this residue in a standard order.
-
-  Args:
-    ccd: The chemical components dictionary.
-    res_name: Full CCD name.
-
-  Returns:
-    A dictionary table of the atoms and bonds for this residue in this residue
-    type.
-  """
-  # The CCD version of 'UNK' is weird. It has a CB and a CG atom. We just want
-  # the minimal amino-acid here which is GLY.
-  if res_name == 'UNK':
-    res_name = 'GLY'
-  ccd_data = ccd.get(res_name)
-  if not ccd_data:
-    raise ValueError(f'Unknown residue type {res_name}')
-
-  keys = (
-      '_chem_comp_atom.atom_id',
-      '_chem_comp_atom.type_symbol',
-      '_chem_comp_bond.atom_id_1',
-      '_chem_comp_bond.atom_id_2',
-  )
-
-  # Add terminal hydrogens for protonation of the N-terminal
-  if res_name == 'PRO':
-    res_atoms = {key: [*ccd_data.get(key, [])] for key in keys}
-    res_atoms['_chem_comp_atom.atom_id'].extend(['H2', 'H3'])
-    res_atoms['_chem_comp_atom.type_symbol'].extend(['H', 'H'])
-    res_atoms['_chem_comp_bond.atom_id_1'].extend(['N', 'N'])
-    res_atoms['_chem_comp_bond.atom_id_2'].extend(['H2', 'H3'])
-  elif res_name in residue_names.PROTEIN_TYPES_WITH_UNKNOWN:
-    res_atoms = {key: [*ccd_data.get(key, [])] for key in keys}
-    res_atoms['_chem_comp_atom.atom_id'].append('H3')
-    res_atoms['_chem_comp_atom.type_symbol'].append('H')
-    res_atoms['_chem_comp_bond.atom_id_1'].append('N')
-    res_atoms['_chem_comp_bond.atom_id_2'].append('H3')
-  else:
-    res_atoms = {key: ccd_data.get(key, []) for key in keys}
-
-  return res_atoms
-
-
-@functools.lru_cache(maxsize=128)
-def get_res_atom_names(ccd: chemical_components.Ccd, res_name: str) -> set[str]:
-  """Gets the names of the atoms in a given CCD residue."""
-  atoms = get_all_atoms_in_entry(ccd, res_name)['_chem_comp_atom.atom_id']
-  return set(atoms)
diff --git a/src/alphafold3/structure/cpp/aggregation.pyi b/src/alphafold3/structure/cpp/aggregation.pyi
deleted file mode 100755
index 8f4a8b37539b6b1996be654409fd1f1605cb53c2..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/aggregation.pyi
+++ /dev/null
@@ -1,13 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-from collections.abc import Sequence
-
-def indices_grouped_by_value(values: Sequence[int]) -> dict[int, list[int]]: ...
diff --git a/src/alphafold3/structure/cpp/aggregation_pybind.cc b/src/alphafold3/structure/cpp/aggregation_pybind.cc
deleted file mode 100644
index 5ac46d62cd5872658595ed5ab5bd73793853ad7a..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/aggregation_pybind.cc
+++ /dev/null
@@ -1,54 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <cstdint>
-#include <vector>
-
-#include "absl/container/flat_hash_map.h"
-#include "absl/types/span.h"
-#include "pybind11/cast.h"
-#include "pybind11/numpy.h"
-#include "pybind11/pybind11.h"
-#include "pybind11_abseil/absl_casters.h"
-
-namespace {
-
-namespace py = pybind11;
-
-absl::flat_hash_map<int64_t, std::vector<int64_t>> IndicesGroupedByValue(
-    absl::Span<const int64_t> values) {
-  absl::flat_hash_map<int64_t, std::vector<int64_t>> group_indices;
-  for (int64_t i = 0, e = values.size(); i < e; ++i) {
-    group_indices[values[i]].push_back(i);
-  }
-  return group_indices;
-}
-
-constexpr char kIndicesGroupedByValue[] = R"(
-Returns a map from value to a list of indices this value occupies.
-
-E.g. indices_grouped_by_value([1, 1, 2, 3, 3, 1, 1]) returns:
-{1: [0, 1, 5, 6], 2: [2], 3: [3, 4]}
-
-Args:
-  values: a list of values to group.
-)";
-
-}  // namespace
-
-namespace alphafold3 {
-
-void RegisterModuleAggregation(py::module m) {
-  m.def("indices_grouped_by_value", &IndicesGroupedByValue, py::arg("values"),
-        py::doc(kIndicesGroupedByValue + 1),
-        py::call_guard<py::gil_scoped_release>());
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/aggregation_pybind.h b/src/alphafold3/structure/cpp/aggregation_pybind.h
deleted file mode 100644
index 9547b9448d4b929699dcb88e2178d39ff292e5b9..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/aggregation_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_AGGREGATION_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_AGGREGATION_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleAggregation(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_AGGREGATION_PYBIND_H_
diff --git a/src/alphafold3/structure/cpp/membership.pyi b/src/alphafold3/structure/cpp/membership.pyi
deleted file mode 100755
index 305f36600f4dbee357b29ae35442c3382bedea4e..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/membership.pyi
+++ /dev/null
@@ -1,18 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-import numpy
-
-
-def isin(
-    array: numpy.ndarray[numpy.int64],
-    test_elements: set[int],
-    invert: bool = ...,
-) -> numpy.ndarray[bool]: ...
diff --git a/src/alphafold3/structure/cpp/membership_pybind.cc b/src/alphafold3/structure/cpp/membership_pybind.cc
deleted file mode 100644
index 2b3faf8a2afc990c42b812d35aa346009229b638..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/membership_pybind.cc
+++ /dev/null
@@ -1,82 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <algorithm>
-#include <cstddef>
-#include <cstdint>
-#include <vector>
-
-#include "absl/container/flat_hash_set.h"
-#include "pybind11/cast.h"
-#include "pybind11/numpy.h"
-#include "pybind11/pybind11.h"
-#include "pybind11_abseil/absl_casters.h"
-
-namespace {
-
-namespace py = pybind11;
-
-py::array_t<bool> IsIn(const py::array_t<int64_t, py::array::c_style>& array,
-                       const absl::flat_hash_set<int64_t>& test_elements,
-                       bool invert) {
-  const size_t num_elements = array.size();
-
-  py::array_t<bool> output(num_elements);
-  std::fill(output.mutable_data(), output.mutable_data() + output.size(),
-            invert);
-
-  // Shortcut: The output will be trivially always false if test_elements empty.
-  if (test_elements.empty()) {
-    return output;
-  }
-
-  for (size_t i = 0; i < num_elements; ++i) {
-    if (test_elements.contains(array.data()[i])) {
-      output.mutable_data()[i] = !invert;
-    }
-  }
-  if (array.ndim() > 1) {
-    auto shape =
-        std::vector<ptrdiff_t>(array.shape(), array.shape() + array.ndim());
-    return output.reshape(shape);
-  }
-  return output;
-}
-
-constexpr char kIsInDoc[] = R"(
-Computes whether each element is in test_elements.
-
-Same use as np.isin, but much faster. If len(array) = n, len(test_elements) = m:
-* This function has complexity O(n).
-* np.isin with kind='sort' has complexity O(m*log(m) + n * log(m)).
-
-Args:
-  array: Input NumPy array with dtype=np.int64.
-  test_elements: The values against which to test each value of array.
-  invert: If True, the values in the returned array are inverted, as if
-    calculating `element not in test_elements`. Default is False.
-    `isin(a, b, invert=True)` is equivalent to but faster than `~isin(a, b)`.
-
-Returns
-  A boolean array of the same shape as the input array. Each value `val` is:
-  * `val in test_elements` if `invert=False`,
-  * `val not in test_elements` if `invert=True`.
-)";
-
-}  // namespace
-
-namespace alphafold3 {
-
-void RegisterModuleMembership(pybind11::module m) {
-  m.def("isin", &IsIn, py::arg("array"), py::arg("test_elements"),
-        py::kw_only(), py::arg("invert") = false, py::doc(kIsInDoc + 1));
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/membership_pybind.h b/src/alphafold3/structure/cpp/membership_pybind.h
deleted file mode 100644
index d224fb1f64c92d6f3753da7b2e231077edde436b..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/membership_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MEMBERSHIP_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MEMBERSHIP_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleMembership(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MEMBERSHIP_PYBIND_H_
diff --git a/src/alphafold3/structure/cpp/mmcif_altlocs.cc b/src/alphafold3/structure/cpp/mmcif_altlocs.cc
deleted file mode 100644
index cea9a1b1c9df6f27c707b1507439f7fba40b770f..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_altlocs.cc
+++ /dev/null
@@ -1,249 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include "alphafold3/structure/cpp/mmcif_altlocs.h"
-
-#include <cstddef>
-#include <cstdint>
-#include <functional>
-#include <iterator>
-#include <limits>
-#include <string>
-#include <utility>
-#include <vector>
-
-#include "absl/algorithm/container.h"
-#include "absl/log/log.h"
-#include "absl/strings/numbers.h"
-#include "absl/strings/string_view.h"
-#include "absl/types/span.h"
-#include "alphafold3/structure/cpp/mmcif_layout.h"
-
-namespace alphafold3 {
-namespace {
-
-float OccupancyToFloat(absl::string_view occupancy) {
-  float result = 0.0f;
-  LOG_IF(ERROR, !absl::SimpleAtof(occupancy, &result))
-      << "Invalid Occupancy: " << occupancy;
-  return result;
-}
-
-// Deuterium is the same atom as Hydrogen so keep equivalent for grouping.
-bool AtomEquiv(absl::string_view lhs, absl::string_view rhs) {
-  if (lhs == rhs) return true;
-  if (lhs.empty() != rhs.empty()) return false;
-  // Both lhs and rhs are guaranteed to be non-empty after this.
-  char first_lhs = lhs.front();
-  char second_rhs = rhs.front();
-  if ((first_lhs == 'H' && second_rhs == 'D') ||
-      (first_lhs == 'D' && second_rhs == 'H')) {
-    lhs.remove_prefix(1);
-    rhs.remove_prefix(1);
-    return lhs == rhs;
-  }
-  return false;
-}
-
-// Calls group_callback with that start index and count for each group of
-// equivalent values in `values`, starting at `start` and ending at `count`.
-// Example:
-// GroupBy({"B", "B", "B", "C", "C"}, 0, 5, [](size_t start, size_t count) {
-//   absl::Printf("start=%d, count=%d\n", start, count);
-// });
-// Would print:
-// start=0, count=3
-// start=3, count=2
-template <typename GroupCallback,
-          typename IsEqual = std::equal_to<absl::string_view>>
-void GroupBy(absl::Span<const std::string> values, std::size_t start,
-             std::size_t count, GroupCallback&& group_callback,
-             IsEqual&& is_equal = std::equal_to<absl::string_view>{}) {
-  std::size_t span_start = start;
-  if (count > 0) {
-    for (std::size_t i = start + 1; i < start + count; ++i) {
-      if (!is_equal(values[i], values[span_start])) {
-        group_callback(span_start, i - span_start);
-        span_start = i;
-      }
-    }
-    group_callback(span_start, start + count - span_start);
-  }
-}
-
-void ProcessAltLocGroupsWhole(std::size_t alt_loc_start,
-                              std::size_t alt_loc_count,
-                              absl::Span<const std::string> comp_ids,
-                              absl::Span<const std::string> atom_ids,
-                              absl::Span<const std::string> alt_ids,
-                              absl::Span<const std::string> occupancies,
-                              std::vector<std::uint64_t>& in_out_keep_indices) {
-  std::pair<std::size_t, std::size_t> best_split = {alt_loc_start,
-                                                    alt_loc_count};
-  std::vector<char> alt_loc_groups;
-  float best_occupancy = -std::numeric_limits<float>::infinity();
-  char best_group = alt_ids[alt_loc_start].front();
-  std::vector<std::pair<std::size_t, float>> occupancy_stats;
-
-  // Group by residue type.
-  GroupBy(comp_ids, alt_loc_start, alt_loc_count,
-          [&](std::size_t start, std::size_t count) {
-            // This callback selects the best residue group and the best
-            // Alt-loc char within that group.
-            alt_loc_groups.clear();
-            occupancy_stats.clear();
-            // Calculate total occupancy for residue type.
-            for (std::size_t i = 0; i < count; ++i) {
-              char alt_loc_id = alt_ids[start + i].front();
-              float occupancy = OccupancyToFloat(occupancies[start + i]);
-              if (auto loc = absl::c_find(alt_loc_groups, alt_loc_id);
-                  loc == alt_loc_groups.end()) {
-                occupancy_stats.emplace_back(1, occupancy);
-                alt_loc_groups.push_back(alt_loc_id);
-              } else {
-                auto& stat =
-                    occupancy_stats[std::distance(alt_loc_groups.begin(), loc)];
-                ++stat.first;
-                stat.second += occupancy;
-              }
-            }
-            float total_occupancy = 0.0;
-            for (auto& stat : occupancy_stats) {
-              total_occupancy += stat.second / stat.first;
-            }
-            char group = *absl::c_min_element(alt_loc_groups);
-            // Compares occupancy of residue to best seen so far.
-            // Tie breaks alphabetic.
-            if (total_occupancy > best_occupancy ||
-                (total_occupancy == best_occupancy && group < best_group)) {
-              // Selects the best sub group.
-              best_group = alt_loc_groups.front();
-              float best_amount = occupancy_stats.front().second /
-                                  occupancy_stats.front().first;
-              for (std::size_t i = 1; i < occupancy_stats.size(); ++i) {
-                float amount =
-                    occupancy_stats[i].second / occupancy_stats[i].first;
-                char group = alt_loc_groups[i];
-                if (amount > best_amount ||
-                    (amount == best_amount && group < best_group)) {
-                  best_amount = amount;
-                  best_group = group;
-                }
-              }
-              best_occupancy = total_occupancy;
-              best_split = {start, count};
-            }
-          });
-
-  // Now that the best residue type has been selected and the best alt-loc
-  // within that has been selected add indices of indices to keep to the keep
-  // list.
-  auto [split_start, split_count] = best_split;
-  GroupBy(
-      atom_ids, split_start, split_count,
-      [&in_out_keep_indices, &alt_ids, best_group](std::size_t start,
-                                                   std::size_t count) {
-        // This makes sure we select an atom for each atom id even if it does
-        // not have our selected alt-loc char.
-        std::size_t best_index = start;
-        for (std::size_t i = 1; i < count; ++i) {
-          if (alt_ids[start + i].front() == best_group) {
-            best_index = start + i;
-            break;
-          }
-        }
-        in_out_keep_indices.push_back(best_index);
-      },
-      AtomEquiv);
-}
-
-// Finds the alt-loc group with the highest score and pushes the indices on to
-// the back of in_out_keep_indices.
-void ProcessAltLocGroupPartial(
-    std::size_t alt_loc_start, std::size_t alt_loc_count,
-    absl::Span<const std::string> atom_ids,
-    absl::Span<const std::string> alt_ids,
-    absl::Span<const std::string> occupancies,
-    std::vector<std::uint64_t>& in_out_keep_indices) {
-  GroupBy(
-      atom_ids, alt_loc_start, alt_loc_count,
-      [&](std::size_t start, std::size_t count) {
-        if (count == 1) {
-          in_out_keep_indices.push_back(start);
-        } else {
-          float best_occ = OccupancyToFloat(occupancies[start]);
-          std::size_t best_index = start;
-          char best_group = alt_ids[start].front();
-          for (std::size_t i = 0; i < count; ++i) {
-            float occ = OccupancyToFloat(occupancies[start + i]);
-            char group = alt_ids[start + i].front();
-            if (occ > best_occ || (occ == best_occ && group < best_group)) {
-              best_group = group;
-              best_index = start + i;
-              best_occ = occ;
-            }
-          }
-          in_out_keep_indices.push_back(best_index);
-        }
-      },
-      AtomEquiv);
-}
-
-}  // namespace
-
-// Resolves alt-locs returning the atom indices that will be left.
-std::vector<std::uint64_t> ResolveMmcifAltLocs(
-    const MmcifLayout& layout, absl::Span<const std::string> comp_ids,
-    absl::Span<const std::string> atom_ids,
-    absl::Span<const std::string> alt_ids,
-    absl::Span<const std::string> occupancies,
-    absl::Span<const std::size_t> chain_indices) {
-  std::vector<std::uint64_t> keep_indices;
-  keep_indices.reserve(layout.num_atoms());
-  std::size_t alt_loc_start = 0;
-  for (std::size_t chain_index : chain_indices) {
-    auto [residues_start, residues_end] = layout.residue_range(chain_index);
-    for (std::size_t residue = residues_start; residue < residues_end;
-         ++residue) {
-      std::size_t alt_loc_count = 0;
-      auto [atom_start, atom_end] = layout.atom_range(residue);
-      for (std::size_t i = atom_start; i < atom_end; ++i) {
-        char alt_loc_id = alt_ids[i].front();
-        if (alt_loc_id == '.' || alt_loc_id == '?') {
-          if (alt_loc_count > 0) {
-            ProcessAltLocGroupPartial(alt_loc_start, alt_loc_count, atom_ids,
-                                      alt_ids, occupancies, keep_indices);
-            alt_loc_count = 0;
-          }
-          keep_indices.push_back(i);
-        } else {
-          if (alt_loc_count == 0) {
-            alt_loc_start = i;
-          }
-          ++alt_loc_count;
-        }
-      }
-      if (alt_loc_count > 0) {
-        if (atom_end - atom_start == alt_loc_count) {
-          ProcessAltLocGroupsWhole(alt_loc_start, alt_loc_count, comp_ids,
-                                   atom_ids, alt_ids, occupancies,
-                                   keep_indices);
-        } else {
-          ProcessAltLocGroupPartial(alt_loc_start, alt_loc_count, atom_ids,
-                                    alt_ids, occupancies, keep_indices);
-        }
-      }
-    }
-  }
-
-  return keep_indices;
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/mmcif_altlocs.h b/src/alphafold3/structure/cpp/mmcif_altlocs.h
deleted file mode 100644
index fab57817c38b62d96b3370d4b67cc4358656cc19..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_altlocs.h
+++ /dev/null
@@ -1,51 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_ALTLOCS_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_ALTLOCS_H_
-
-#include <cstddef>
-#include <cstdint>
-#include <string>
-#include <vector>
-
-#include "absl/types/span.h"
-#include "alphafold3/structure/cpp/mmcif_layout.h"
-
-namespace alphafold3 {
-
-// Returns the list of indices that should be kept after resolving alt-locs.
-// 1) Partial Residue. Each cycle of alt-locs are resolved separately with the
-//    highest occupancy alt-loc. Tie-breaks are resolved alphabetically. See
-//    tests for examples.
-// 2) Whole Residue. These are resolved in two passes.
-//    a) The residue with the highest occupancy is chosen.
-//    b) The locations for a given residue are resolved.
-//    All tie-breaks are resolved alphabetically. See tests for examples.
-//
-// Preconditions: layout and comp_ids, alt_ids, occupancies are all from same
-// mmCIF file and chain_indices are monotonically increasing and less than
-// layout.num_chains().
-//
-// comp_ids from '_atom_site.label_comp_id'.
-// alt_ids from '_atom_site.label_alt_id'.
-// occupancies from '_atom_site.occupancy'.
-std::vector<std::uint64_t> ResolveMmcifAltLocs(
-    const MmcifLayout& layout, absl::Span<const std::string> comp_ids,
-    absl::Span<const std::string> atom_ids,
-    absl::Span<const std::string> alt_ids,
-    absl::Span<const std::string> occupancies,
-    absl::Span<const std::size_t> chain_indices);
-
-}  // namespace alphafold3
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_ALTLOCS_H_
diff --git a/src/alphafold3/structure/cpp/mmcif_atom_site.pyi b/src/alphafold3/structure/cpp/mmcif_atom_site.pyi
deleted file mode 100755
index 5f0ba34b062eeabcdcfff9b52c97c54d693b06fa..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_atom_site.pyi
+++ /dev/null
@@ -1,23 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-from collections.abc import Callable
-from alphafold3.cpp import cif_dict
-
-
-def get_internal_to_author_chain_id_map(
-    mmcif: cif_dict.CifDict
-) -> dict[str,str]: ...
-
-
-def get_or_infer_type_symbol(
-    mmcif: cif_dict.CifDict,
-    atom_id_to_type_symbol: Callable[[str, str], str],
-) -> list[str]: ...
diff --git a/src/alphafold3/structure/cpp/mmcif_atom_site_pybind.cc b/src/alphafold3/structure/cpp/mmcif_atom_site_pybind.cc
deleted file mode 100644
index 6037fe08ba30d169047a7f6644f0a33cebfdc2e7..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_atom_site_pybind.cc
+++ /dev/null
@@ -1,83 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <cstddef>
-
-#include "absl/container/flat_hash_map.h"
-#include "absl/log/check.h"
-#include "absl/strings/string_view.h"
-#include "absl/types/span.h"
-#include "alphafold3/parsers/cpp/cif_dict_lib.h"
-#include "pybind11/gil.h"
-#include "pybind11/pybind11.h"
-#include "pybind11/pytypes.h"
-#include "pybind11/stl.h"
-#include "pybind11_abseil/absl_casters.h"
-
-namespace alphafold3 {
-namespace {
-namespace py = pybind11;
-
-// If present, returns the _atom_site.type_symbol. If not, infers it using
-// _atom_site.label_comp_id (residue name), _atom_site.label_atom_id (atom name)
-// and the CCD.
-py::list GetOrInferTypeSymbol(const CifDict& mmcif,
-                              const py::object& atom_id_to_type_symbol) {
-  const auto& type_symbol = mmcif["_atom_site.type_symbol"];
-  const int num_atom = mmcif["_atom_site.id"].size();
-  py::list patched_type_symbol(num_atom);
-  if (type_symbol.empty()) {
-    const auto& label_comp_id = mmcif["_atom_site.label_comp_id"];
-    const auto& label_atom_id = mmcif["_atom_site.label_atom_id"];
-    CHECK_EQ(label_comp_id.size(), num_atom);
-    CHECK_EQ(label_atom_id.size(), num_atom);
-    for (int i = 0; i < num_atom; i++) {
-      patched_type_symbol[i] =
-          atom_id_to_type_symbol(label_comp_id[i], label_atom_id[i]);
-    }
-  } else {
-    for (int i = 0; i < num_atom; i++) {
-      patched_type_symbol[i] = type_symbol[i];
-    }
-  }
-  return patched_type_symbol;
-}
-
-absl::flat_hash_map<absl::string_view, absl::string_view>
-GetInternalToAuthorChainIdMap(const CifDict& mmcif) {
-  const auto& label_asym_ids = mmcif["_atom_site.label_asym_id"];
-  const auto& auth_asym_ids = mmcif["_atom_site.auth_asym_id"];
-  CHECK_EQ(label_asym_ids.size(), auth_asym_ids.size());
-
-  absl::flat_hash_map<absl::string_view, absl::string_view> mapping;
-  for (size_t i = 0, num_rows = label_asym_ids.size(); i < num_rows; ++i) {
-    // Use only the first internal_chain_id occurrence to generate the mapping.
-    // It should not matter as there should not be a case where a single
-    // internal chain ID would map to more than one author chain IDs (i.e. the
-    // mapping should be injective). Since we need this method to be fast, we
-    // choose not to check it.
-    mapping.emplace(label_asym_ids[i], auth_asym_ids[i]);
-  }
-  return mapping;
-}
-
-}  // namespace
-
-namespace py = pybind11;
-
-void RegisterModuleMmcifAtomSite(pybind11::module m) {
-  m.def("get_or_infer_type_symbol", &GetOrInferTypeSymbol, py::arg("mmcif"),
-        py::arg("atom_id_to_type_symbol"));
-
-  m.def("get_internal_to_author_chain_id_map", &GetInternalToAuthorChainIdMap,
-        py::arg("mmcif"), py::call_guard<py::gil_scoped_release>());
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/mmcif_atom_site_pybind.h b/src/alphafold3/structure/cpp/mmcif_atom_site_pybind.h
deleted file mode 100644
index 1f2104ecf0de171483b67370a91ff1acef0e0e28..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_atom_site_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_ATOM_SITE_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_ATOM_SITE_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleMmcifAtomSite(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_ATOM_SITE_PYBIND_H_
diff --git a/src/alphafold3/structure/cpp/mmcif_layout.h b/src/alphafold3/structure/cpp/mmcif_layout.h
deleted file mode 100644
index 51c67c528f60b71d009fd6ed9da199443bb5c5d4..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_layout.h
+++ /dev/null
@@ -1,146 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_LAYOUT_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_LAYOUT_H_
-
-#include <cstddef>
-#include <cstdint>
-#include <string>
-#include <utility>
-#include <vector>
-
-#include "absl/status/statusor.h"
-#include "absl/strings/string_view.h"
-#include "absl/types/span.h"
-#include "alphafold3/parsers/cpp/cif_dict_lib.h"
-
-namespace alphafold3 {
-
-// Holds the layout of a parsed mmCIF file.
-class MmcifLayout {
- public:
-  MmcifLayout(std::vector<std::size_t> chain_ends,
-              std::vector<std::size_t> residues, std::size_t model_offset,
-              std::size_t num_models)
-      : chain_ends_(std::move(chain_ends)),
-        residue_ends_(std::move(residues)),
-        model_offset_(model_offset),
-        num_models_(num_models) {}
-
-  // Reads a layout from a valid parsed mmCIF. If a valid model_id is provided
-  // the offsets will select that model from the mmCIF.
-  // If no model_id is specified, we calculate the layout of the first model
-  // only. Therefore it is a requirement that each model has identical atom
-  // layouts. An error is returned if the atom counts do not between models.
-  static absl::StatusOr<MmcifLayout> Create(const CifDict& mmcif,
-                                            absl::string_view model_id = "");
-
-  std::string ToDebugString() const;
-
-  // Returns the start index and one past the last residue index of a given
-  // chain. A chain_index of n refers to the n-th chain in the mmCIF. The
-  // returned residue indices are 0-based enumerations of residues in the
-  // _atom_site records, and therefore do not include missing residues.
-  std::pair<std::size_t, std::size_t> residue_range(
-      std::size_t chain_index) const {
-    if (chain_index > 0) {
-      return {chain_ends_[chain_index - 1], chain_ends_[chain_index]};
-    } else {
-      return {0, chain_ends_[0]};
-    }
-  }
-
-  // Returns the start index and one past the last index of a given residue.
-  // A residue_index of n refers to the n-th residue in the mmCIF, not
-  // including residues that are unresolved (i.e. only using _atom_site).
-  std::pair<std::size_t, std::size_t> atom_range(
-      std::size_t residue_index) const {
-    if (residue_index > 0) {
-      return {residue_ends_[residue_index - 1], residue_ends_[residue_index]};
-    } else {
-      return {model_offset_, residue_ends_[residue_index]};
-    }
-  }
-
-  // If model_id was provided during construction then this is 1, otherwise
-  // it is the number of models present in the mmCIF.
-  std::size_t num_models() const { return num_models_; }
-  // The number of atoms in the chosen model.
-  std::size_t num_atoms() const {
-    return residue_ends_.empty() ? 0 : residue_ends_.back() - model_offset_;
-  }
-  // The number of chains in the chosen model.
-  std::size_t num_chains() const { return chain_ends_.size(); }
-  // The number of residues in the chosen model, not counting unresolved
-  // residues.
-  std::size_t num_residues() const { return residue_ends_.size(); }
-
-  // Returns the first atom index that is part of the specified chain.
-  // The chain is specified using chain_index, which is a 0-based
-  // enumeration of the chains in the _atom_site table.
-  std::size_t atom_site_from_chain_index(std::size_t chain_index) const {
-    if (chain_index == 0) {
-      return model_offset_;
-    }
-    return atom_site_from_residue_index(chain_ends_[chain_index - 1]);
-  }
-
-  // Returns the first atom index that is part of the specified residue.
-  // The residue is specified using residue_index, which is a 0-based
-  // enumeration of the residues in the _atom_site table.
-  std::size_t atom_site_from_residue_index(std::size_t residues_index) const {
-    if (residues_index == 0) {
-      return model_offset_;
-    }
-    return residue_ends_[residues_index - 1];
-  }
-
-  // One past last residue index of each chain. The residue index does not
-  // include unresolved residues and is a simple 0-based enumeration of the
-  // residues in _atom_site table.
-  const std::vector<std::size_t>& chains() const { return chain_ends_; }
-
-  // Indices of the first atom of each chain. Note that this returns atom
-  // indices (like residue_starts()), not residue indices (like chains()).
-  std::vector<std::size_t> chain_starts() const;
-
-  // One past last atom index of each residue.
-  const std::vector<std::size_t>& residues() const { return residue_ends_; }
-
-  // Indices of the first atom of each residue.
-  std::vector<std::size_t> residue_starts() const {
-    std::vector<std::size_t> residue_starts;
-    if (!residue_ends_.empty()) {
-      residue_starts.reserve(residue_ends_.size());
-      residue_starts.push_back(model_offset_);
-      residue_starts.insert(residue_starts.end(), residue_ends_.begin(),
-                            residue_ends_.end() - 1);
-    }
-    return residue_starts;
-  }
-
-  // The first atom index that is part of the specified model.
-  std::size_t model_offset() const { return model_offset_; }
-
-  void Filter(absl::Span<const std::uint64_t> keep_indices);
-
- private:
-  std::vector<std::size_t> chain_ends_;
-  std::vector<std::size_t> residue_ends_;
-  std::size_t model_offset_;
-  std::size_t num_models_;
-};
-
-}  // namespace alphafold3
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_LAYOUT_H_
diff --git a/src/alphafold3/structure/cpp/mmcif_layout.pyi b/src/alphafold3/structure/cpp/mmcif_layout.pyi
deleted file mode 100755
index add1b05ea89b2ed34b645daad9c709fec551cb43..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_layout.pyi
+++ /dev/null
@@ -1,26 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-from alphafold3.cpp import cif_dict
-
-class MmcifLayout:
-  def atom_range(self, residue_index: int) -> tuple[int, int]: ...
-  def chain_starts(self) -> list[int]: ...
-  def chains(self) -> list[int]: ...
-  def model_offset(self) -> int: ...
-  def num_atoms(self) -> int: ...
-  def num_chains(self) -> int: ...
-  def num_models(self) -> int: ...
-  def num_residues(self) -> int: ...
-  def residue_range(self, chain_index: int) -> tuple[int, int]: ...
-  def residue_starts(self) -> list[int]: ...
-  def residues(self) -> list[int]: ...
-
-def from_mmcif(mmcif: cif_dict.CifDict, model_id: str = ...) -> MmcifLayout: ...
diff --git a/src/alphafold3/structure/cpp/mmcif_layout_lib.cc b/src/alphafold3/structure/cpp/mmcif_layout_lib.cc
deleted file mode 100644
index 91ad70c0b7b4f5bc38d3bcb994593e11bb2b7616..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_layout_lib.cc
+++ /dev/null
@@ -1,213 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <algorithm>
-#include <cstddef>
-#include <cstdint>
-#include <functional>
-#include <iterator>
-#include <string>
-#include <utility>
-#include <vector>
-
-#include "absl/algorithm/container.h"
-#include "absl/status/status.h"
-#include "absl/status/statusor.h"
-#include "absl/strings/str_cat.h"
-#include "absl/strings/str_format.h"
-#include "absl/strings/string_view.h"
-#include "absl/types/span.h"
-#include "alphafold3/parsers/cpp/cif_dict_lib.h"
-#include "alphafold3/structure/cpp/mmcif_layout.h"
-
-namespace alphafold3 {
-
-std::string MmcifLayout::ToDebugString() const {
-  return absl::StrFormat(
-      "MmcifLayout(models=%d, chains=%d, num_residues=%d, atoms=%d)",
-      num_models(), num_chains(), num_residues(), num_atoms());
-}
-
-// Changes layout to match keep_indices removing empty chains/residues.
-void MmcifLayout::Filter(absl::Span<const std::uint64_t> keep_indices) {
-  if (num_chains() == 0) {
-    return;
-  }
-  // Update residue indices.
-  auto keep_it = absl::c_lower_bound(keep_indices, residue_ends_.front());
-  for (auto& residue : residue_ends_) {
-    while (keep_it != keep_indices.end() && *keep_it < residue) {
-      ++keep_it;
-    }
-    residue = std::distance(keep_indices.begin(), keep_it);
-  }
-  // Unique residue_ends_ with updating chains.
-  auto first = residue_ends_.begin();
-  auto tail = first;
-  std::size_t num_skipped = 0;
-  std::size_t current = 0;
-  for (std::size_t& chain_end : chain_ends_) {
-    for (auto e = residue_ends_.begin() + chain_end; first != e; ++first) {
-      std::size_t next = *first;
-      *tail = next;
-      if (current != next) {
-        current = next;
-        ++tail;
-      } else {
-        ++num_skipped;
-      }
-    }
-    chain_end -= num_skipped;
-  }
-  residue_ends_.erase(tail, residue_ends_.end());
-
-  current = 0;
-  chain_ends_.erase(std::remove_if(chain_ends_.begin(), chain_ends_.end(),
-                                   [&current](std::size_t next) {
-                                     bool result = current == next;
-                                     current = next;
-                                     return result;
-                                   }),
-                    chain_ends_.end());
-  model_offset_ = 0;
-}
-
-absl::StatusOr<MmcifLayout> MmcifLayout::Create(const CifDict& mmcif,
-                                                absl::string_view model_id) {
-  auto model_ids = mmcif["_atom_site.pdbx_PDB_model_num"];
-  auto chain_ids = mmcif["_atom_site.label_asym_id"];     // chain ID.
-  auto label_seq_ids = mmcif["_atom_site.label_seq_id"];  // residue ID.
-  auto auth_seq_ids = mmcif["_atom_site.auth_seq_id"];    // author residue ID.
-  auto insertion_codes = mmcif["_atom_site.pdbx_PDB_ins_code"];
-
-  if (model_ids.size() != chain_ids.size() ||
-      model_ids.size() != label_seq_ids.size() ||
-      (model_ids.size() != auth_seq_ids.size() && !auth_seq_ids.empty()) ||
-      (model_ids.size() != insertion_codes.size() &&
-       !insertion_codes.empty())) {
-    return absl::InvalidArgumentError(absl::StrCat(
-        "Invalid _atom_site table.",  //
-        " len(_atom_site.pdbx_PDB_model_num): ", model_ids.size(),
-        " len(_atom_site.label_asym_id): ", chain_ids.size(),
-        " len(_atom_site.label_seq_id): ", label_seq_ids.size(),
-        " len(_atom_site.auth_seq_id): ", auth_seq_ids.size(),
-        " len(_atom_site.pdbx_PDB_ins_code): ", insertion_codes.size()));
-  }
-  std::size_t num_atoms = model_ids.size();
-  if (num_atoms == 0) {
-    return MmcifLayout({}, {}, 0, 0);
-  }
-  std::size_t model_offset = 0;
-  std::size_t num_models;
-  std::size_t num_atoms_per_model;
-  if (model_id.empty()) {
-    absl::string_view first_model_id = model_ids.front();
-
-    // Binary search for where the first model ends.
-    num_atoms_per_model = std::distance(
-        model_ids.begin(),
-        absl::c_upper_bound(model_ids, first_model_id, std::not_equal_to<>{}));
-    if (num_atoms % num_atoms_per_model != 0) {
-      return absl::InvalidArgumentError(absl::StrCat(
-          "Each model must have the same number of atoms: (", num_atoms, " % ",
-          num_atoms_per_model, " == ", num_atoms % num_atoms_per_model, ")."));
-    }
-    num_models = num_atoms / num_atoms_per_model;
-    // Test boundary conditions for each model hold.
-    for (std::size_t i = 1; i < num_models; ++i) {
-      if ((model_ids[i * num_atoms_per_model] !=
-           model_ids[(i + 1) * num_atoms_per_model - 1]) ||
-          (model_ids[i * num_atoms_per_model - 1] ==
-           model_ids[i * num_atoms_per_model])) {
-        return absl::InvalidArgumentError(
-            absl::StrCat("Each model must have the same number of atoms: (",
-                         num_atoms, " % ", num_atoms_per_model,
-                         " == ", num_atoms % num_atoms_per_model, ")."));
-      }
-    }
-  } else {
-    num_models = 1;
-    model_offset =
-        std::distance(model_ids.begin(), absl::c_find(model_ids, model_id));
-    if (model_offset == model_ids.size()) {
-      return absl::InvalidArgumentError(
-          absl::StrCat("Unknown model_id: ", model_id));
-    }
-    model_ids.remove_prefix(model_offset);
-    chain_ids.remove_prefix(model_offset);
-    label_seq_ids.remove_prefix(model_offset);
-    if (!auth_seq_ids.empty()) auth_seq_ids.remove_prefix(model_offset);
-    if (!insertion_codes.empty()) insertion_codes.remove_prefix(model_offset);
-
-    num_atoms_per_model = std::distance(
-        model_ids.begin(), std::upper_bound(model_ids.begin(), model_ids.end(),
-                                            model_id, std::not_equal_to<>{}));
-    num_atoms = num_atoms_per_model;
-  }
-  std::vector<std::size_t> residues;
-  std::vector<std::size_t> chains;
-  absl::string_view chain_id = chain_ids.front();
-  if (!auth_seq_ids.empty() && !insertion_codes.empty()) {
-    // If author residue IDs are present then these are preferred to
-    // label residue IDs because they work for multi-residue ligands (which
-    // are given constant "." label residue IDs).
-    // NB: Author residue IDs require both the auth_seq_id and the insertion
-    // code to be unique.
-    absl::string_view auth_seq_id = auth_seq_ids.front();
-    absl::string_view insertion_code = insertion_codes.front();
-    for (std::size_t i = 1; i < num_atoms_per_model; ++i) {
-      if (absl::string_view current_chain_id = chain_ids[i];
-          current_chain_id != chain_id) {
-        residues.push_back(i + model_offset);
-        chains.push_back(residues.size());
-        chain_id = current_chain_id;
-        auth_seq_id = auth_seq_ids[i];
-        insertion_code = insertion_codes[i];
-      } else if (absl::string_view current_seq_id = auth_seq_ids[i],
-                 current_insertion_code = insertion_codes[i];
-                 insertion_code != current_insertion_code ||
-                 auth_seq_id != current_seq_id) {
-        residues.push_back(i + model_offset);
-        auth_seq_id = current_seq_id;
-        insertion_code = current_insertion_code;
-      }
-    }
-  } else {
-    absl::string_view label_seq_id = label_seq_ids.front();
-    for (std::size_t i = 1; i < num_atoms_per_model; ++i) {
-      if (absl::string_view current_chain_id = chain_ids[i];
-          current_chain_id != chain_id) {
-        residues.push_back(i + model_offset);
-        chains.push_back(residues.size());
-        chain_id = current_chain_id;
-        label_seq_id = label_seq_ids[i];
-      } else if (absl::string_view current_seq_id = label_seq_ids[i];
-                 label_seq_id != current_seq_id) {
-        residues.push_back(i + model_offset);
-        label_seq_id = current_seq_id;
-      }
-    }
-  }
-  residues.push_back(num_atoms_per_model + model_offset);
-  chains.push_back(residues.size());
-  return MmcifLayout(std::move(chains), std::move(residues), model_offset,
-                     num_models);
-}
-
-std::vector<std::size_t> MmcifLayout::chain_starts() const {
-  std::vector<std::size_t> chain_starts;
-  chain_starts.reserve(chain_ends_.size());
-  for (std::size_t index = 0; index < chain_ends_.size(); ++index) {
-    chain_starts.push_back(atom_site_from_chain_index(index));
-  }
-  return chain_starts;
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/mmcif_layout_pybind.cc b/src/alphafold3/structure/cpp/mmcif_layout_pybind.cc
deleted file mode 100644
index 8eb69befc0e93baf084333b055e1466e5902f35e..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_layout_pybind.cc
+++ /dev/null
@@ -1,49 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include "alphafold3/structure/cpp/mmcif_layout.h"
-#include "pybind11/pybind11.h"
-#include "pybind11/pytypes.h"
-#include "pybind11/stl.h"
-
-namespace alphafold3 {
-
-namespace py = pybind11;
-
-void RegisterModuleMmcifLayout(pybind11::module m) {
-  py::class_<MmcifLayout>(m, "MmcifLayout")
-      .def("__str__", &MmcifLayout::ToDebugString)
-      .def("num_models", &MmcifLayout::num_models)
-      .def("num_chains", &MmcifLayout::num_chains)
-      .def("num_residues", &MmcifLayout::num_residues)
-      .def("num_atoms", &MmcifLayout::num_atoms)
-      .def("residue_range", &MmcifLayout::residue_range, py::arg("chain_index"))
-      .def("atom_range", &MmcifLayout::atom_range, py::arg("residue_index"))
-      .def("chains", &MmcifLayout::chains,
-           py::doc("Returns a list of indices one past the last residue of "
-                   "each chain."))
-      .def(
-          "chain_starts", &MmcifLayout::chain_starts,
-          py::doc("Returns a list of indices of the first atom of each chain."))
-      .def("residues", &MmcifLayout::residues,
-           py::doc("Returns a list of indices one past the last atom of each "
-                   "residue."))
-      .def("residue_starts", &MmcifLayout::residue_starts,
-           py::doc(
-               "Returns a list of indices of the first atom of each residue."))
-      .def("model_offset", &MmcifLayout::model_offset,
-           py::doc("Returns the first atom index that is part of the specified "
-                   "model."));
-
-  m.def("from_mmcif", &MmcifLayout::Create, py::arg("mmcif"),
-        py::arg("model_id") = "");
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/mmcif_layout_pybind.h b/src/alphafold3/structure/cpp/mmcif_layout_pybind.h
deleted file mode 100644
index c79b2dd50e0e48bc6065ae3e5468b1142126e659..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_layout_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_LAYOUT_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_LAYOUT_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleMmcifLayout(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_LAYOUT_PYBIND_H_
diff --git a/src/alphafold3/structure/cpp/mmcif_struct_conn.h b/src/alphafold3/structure/cpp/mmcif_struct_conn.h
deleted file mode 100644
index 821be658da838e72bd85bb884669414224a7a7f0..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_struct_conn.h
+++ /dev/null
@@ -1,34 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_STRUCT_CONN_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_STRUCT_CONN_H_
-
-#include <utility>
-#include <vector>
-
-#include "absl/status/statusor.h"
-#include "absl/strings/string_view.h"
-#include "alphafold3/parsers/cpp/cif_dict_lib.h"
-
-namespace alphafold3 {
-
-// Returns a pair of atom indices for each row in the bonds table (aka
-// _struct_conn). The indices are simple 0-based indexes into the columns of
-// the _atom_site table in the input mmCIF, and do not necessarily correspond
-// to the values in _atom_site.id, or any other column.
-absl::StatusOr<std::pair<std::vector<std::size_t>, std::vector<std::size_t>>>
-GetBondAtomIndices(const CifDict& mmcif, absl::string_view model_id);
-
-}  // namespace alphafold3
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_STRUCT_CONN_H_
diff --git a/src/alphafold3/structure/cpp/mmcif_struct_conn.pyi b/src/alphafold3/structure/cpp/mmcif_struct_conn.pyi
deleted file mode 100755
index d293e666a3aab8dba274d4380c2ab24018a66f35..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_struct_conn.pyi
+++ /dev/null
@@ -1,13 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-from alphafold3.cpp import cif_dict
-
-def get_bond_atom_indices(mmcif_dict: cif_dict.CifDict, model_id: str) -> tuple[list[int],list[int]]: ...
diff --git a/src/alphafold3/structure/cpp/mmcif_struct_conn_lib.cc b/src/alphafold3/structure/cpp/mmcif_struct_conn_lib.cc
deleted file mode 100644
index afb930fab350d1c39098c1f73f4deeb968b22a02..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_struct_conn_lib.cc
+++ /dev/null
@@ -1,380 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <cstddef>
-#include <iterator>
-#include <optional>
-#include <string>
-#include <utility>
-#include <vector>
-
-#include "absl/algorithm/container.h"
-#include "absl/container/flat_hash_map.h"
-#include "absl/container/flat_hash_set.h"
-#include "absl/status/status.h"
-#include "absl/status/statusor.h"
-#include "absl/strings/str_cat.h"
-#include "absl/strings/string_view.h"
-#include "absl/types/span.h"
-#include "alphafold3/parsers/cpp/cif_dict_lib.h"
-#include "alphafold3/structure/cpp/mmcif_struct_conn.h"
-
-namespace alphafold3 {
-
-namespace {
-
-struct AtomId {
-  absl::string_view chain_id;
-  absl::string_view res_id_1;
-  absl::string_view res_id_2;
-  absl::string_view atom_name;
-  absl::string_view alt_id;
-
-  friend bool operator==(const AtomId&, const AtomId&) = default;
-  template <typename H>
-  friend H AbslHashValue(H h, const AtomId& m) {
-    return H::combine(std::move(h), m.chain_id, m.res_id_1, m.res_id_2,
-                      m.atom_name, m.alt_id);
-  }
-};
-
-using StringArrayRef = absl::Span<const std::string>;
-using BondIndexByAtom = absl::flat_hash_map<AtomId, std::vector<std::size_t>>;
-using BondAtomIndices = std::vector<std::size_t>;
-
-// Returns whether each container is the same size.
-template <typename C, typename... Cs>
-bool AreSameSize(const C& c, const Cs&... cs) {
-  return ((c.size() == cs.size()) && ...);
-}
-
-struct ColumnSpec {
-  absl::string_view chain_id_col;
-  absl::string_view res_id_1_col;
-  absl::string_view res_id_2_col;
-  absl::string_view atom_name_col;
-  std::optional<absl::string_view> alt_id_col;  // Not used by OpenMM.
-};
-
-class AtomColumns {
- public:
-  static absl::StatusOr<AtomColumns> Create(const CifDict& mmcif,
-                                            const ColumnSpec& column_spec) {
-    StringArrayRef chain_id = mmcif[column_spec.chain_id_col];
-    StringArrayRef res_id_1 = mmcif[column_spec.res_id_1_col];
-    StringArrayRef res_id_2 = mmcif[column_spec.res_id_2_col];
-    StringArrayRef atom_name = mmcif[column_spec.atom_name_col];
-    if (!AreSameSize(chain_id, res_id_1, res_id_2, atom_name)) {
-      return absl::InvalidArgumentError(absl::StrCat(
-          "Atom columns are not the same size. ",                       //
-          "len(", column_spec.chain_id_col, ")=", chain_id.size(),      //
-          ", len(", column_spec.res_id_1_col, ")=", res_id_1.size(),    //
-          ", len(", column_spec.res_id_2_col, ")=", res_id_2.size(),    //
-          ", len(", column_spec.atom_name_col, ")=", atom_name.size(),  //
-          "."));
-    }
-    if (column_spec.alt_id_col.has_value()) {
-      StringArrayRef alt_id = mmcif[*column_spec.alt_id_col];
-      if (!AreSameSize(alt_id, chain_id)) {
-        return absl::InvalidArgumentError(absl::StrCat(
-            "Atom columns are not the same size. ",                   //
-            "len(", column_spec.chain_id_col, ")=", chain_id.size(),  //
-            ", len(", *column_spec.alt_id_col, ")=", alt_id.size(),   //
-            "."));
-      }
-      return AtomColumns(chain_id, res_id_1, res_id_2, atom_name, alt_id,
-                         column_spec);
-    } else {
-      return AtomColumns(chain_id, res_id_1, res_id_2, atom_name, std::nullopt,
-                         column_spec);
-    }
-  }
-
-  inline std::size_t size() const { return size_; }
-
-  absl::string_view GetNormalizedAltId(const std::size_t index) const {
-    constexpr absl::string_view kFullStop = ".";
-    if (alt_id_.has_value()) {
-      absl::string_view alt_id = (*alt_id_)[index];
-      return alt_id == "?" ? kFullStop : alt_id;
-    } else {
-      return kFullStop;
-    }
-  }
-
-  AtomId GetAtom(const std::size_t index) const {
-    return {.chain_id = chain_id_[index],
-            .res_id_1 = res_id_1_[index],
-            .res_id_2 = res_id_2_[index],
-            .atom_name = atom_name_[index],
-            .alt_id = GetNormalizedAltId(index)};
-  }
-
-  std::string GetAtomString(const std::size_t index) const {
-    std::string alt_id_col;
-    if (column_spec_.alt_id_col.has_value()) {
-      alt_id_col = *column_spec_.alt_id_col;
-    } else {
-      alt_id_col = "default label_alt_id";
-    }
-    return absl::StrCat(
-        column_spec_.chain_id_col, "=", chain_id_[index], ", ",    //
-        column_spec_.res_id_1_col, "=", res_id_1_[index], ", ",    //
-        column_spec_.res_id_2_col, "=", res_id_2_[index], ", ",    //
-        column_spec_.atom_name_col, "=", atom_name_[index], ", ",  //
-        alt_id_col, "=", GetNormalizedAltId(index));               //
-  }
-
- private:
-  AtomColumns(StringArrayRef chain_id, StringArrayRef res_id_1,
-              StringArrayRef res_id_2, StringArrayRef atom_name,
-              std::optional<StringArrayRef> alt_id,
-              const ColumnSpec& column_spec)
-      : chain_id_(chain_id),
-        res_id_1_(res_id_1),
-        res_id_2_(res_id_2),
-        atom_name_(atom_name),
-        alt_id_(alt_id),
-        column_spec_(column_spec),
-        size_(chain_id.size()) {}
-  StringArrayRef chain_id_;
-  StringArrayRef res_id_1_;
-  StringArrayRef res_id_2_;
-  StringArrayRef atom_name_;
-  std::optional<StringArrayRef> alt_id_;
-  ColumnSpec column_spec_;
-  std::size_t size_;
-};
-
-// Adds the atom index to any rows in the bond table involving that atom.
-absl::Status FillInBondsForAtom(const BondIndexByAtom& bond_index_by_atom,
-                                const AtomId& atom,
-                                const std::size_t atom_index,
-                                BondAtomIndices& bond_atom_indices) {
-  if (auto bond_index_it = bond_index_by_atom.find(atom);
-      bond_index_it != bond_index_by_atom.end()) {
-    for (std::size_t bond_index : bond_index_it->second) {
-      if (bond_index < 0 || bond_index >= bond_atom_indices.size()) {
-        return absl::OutOfRangeError(
-            absl::StrCat("Bond index out of range: ", bond_index));
-      }
-      bond_atom_indices[bond_index] = atom_index;
-    }
-  }
-  return absl::OkStatus();
-}
-
-// Checks that the CifDict has all of the columns in the column spec.
-bool HasAllColumns(const CifDict& mmcif, const ColumnSpec& columns) {
-  return mmcif.Contains(columns.chain_id_col) &&
-         mmcif.Contains(columns.res_id_1_col) &&
-         mmcif.Contains(columns.res_id_2_col) &&
-         mmcif.Contains(columns.atom_name_col) &&
-         (!columns.alt_id_col.has_value() ||
-          mmcif.Contains(*columns.alt_id_col));
-}
-
-// Fully specified ptnr1 atom.
-constexpr ColumnSpec kStructConnPtnr1ColumnsFull{
-    .chain_id_col = "_struct_conn.ptnr1_label_asym_id",
-    .res_id_1_col = "_struct_conn.ptnr1_auth_seq_id",
-    .res_id_2_col = "_struct_conn.pdbx_ptnr1_PDB_ins_code",
-    .atom_name_col = "_struct_conn.ptnr1_label_atom_id",
-    .alt_id_col = "_struct_conn.pdbx_ptnr1_label_alt_id",
-};
-
-// Fully specified ptnr2 atom.
-constexpr ColumnSpec kStructConnPtnr2ColumnsFull{
-    .chain_id_col = "_struct_conn.ptnr2_label_asym_id",
-    .res_id_1_col = "_struct_conn.ptnr2_auth_seq_id",
-    .res_id_2_col = "_struct_conn.pdbx_ptnr2_PDB_ins_code",
-    .atom_name_col = "_struct_conn.ptnr2_label_atom_id",
-    .alt_id_col = "_struct_conn.pdbx_ptnr2_label_alt_id",
-};
-
-// Columns used by OpenMM for ptnr1 atoms.
-constexpr ColumnSpec kStructConnPtnr1OpenMM{
-    .chain_id_col = "_struct_conn.ptnr1_label_asym_id",
-    .res_id_1_col = "_struct_conn.ptnr1_label_seq_id",
-    .res_id_2_col = "_struct_conn.ptnr1_label_comp_id",
-    .atom_name_col = "_struct_conn.ptnr1_label_atom_id",
-    .alt_id_col = std::nullopt,
-};
-
-// Columns used by OpenMM for ptnr2 atoms.
-constexpr ColumnSpec kStructConnPtnr2OpenMM{
-    .chain_id_col = "_struct_conn.ptnr2_label_asym_id",
-    .res_id_1_col = "_struct_conn.ptnr2_label_seq_id",
-    .res_id_2_col = "_struct_conn.ptnr2_label_comp_id",
-    .atom_name_col = "_struct_conn.ptnr2_label_atom_id",
-    .alt_id_col = std::nullopt,
-};
-
-// Fully specified atom sites.
-constexpr ColumnSpec kAtomSiteColumnsFull{
-    .chain_id_col = "_atom_site.label_asym_id",
-    .res_id_1_col = "_atom_site.auth_seq_id",
-    .res_id_2_col = "_atom_site.pdbx_PDB_ins_code",
-    .atom_name_col = "_atom_site.label_atom_id",
-    .alt_id_col = "_atom_site.label_alt_id",
-};
-
-// Atom site columns used to match OpenMM _struct_conn tables.
-constexpr ColumnSpec kAtomSiteColumnsOpenMM{
-    .chain_id_col = "_atom_site.label_asym_id",
-    .res_id_1_col = "_atom_site.label_seq_id",
-    .res_id_2_col = "_atom_site.label_comp_id",
-    .atom_name_col = "_atom_site.label_atom_id",
-    .alt_id_col = "_atom_site.label_alt_id",
-};
-
-}  // namespace
-
-absl::StatusOr<std::pair<BondAtomIndices, BondAtomIndices>> GetBondAtomIndices(
-    const CifDict& mmcif, absl::string_view model_id) {
-  ColumnSpec ptnr1_columns, ptnr2_columns, atom_site_columns;
-
-  if (HasAllColumns(mmcif, kStructConnPtnr1ColumnsFull) &&
-      HasAllColumns(mmcif, kStructConnPtnr2ColumnsFull)) {
-    ptnr1_columns = kStructConnPtnr1ColumnsFull;
-    ptnr2_columns = kStructConnPtnr2ColumnsFull;
-    atom_site_columns = kAtomSiteColumnsFull;
-  } else {
-    ptnr1_columns = kStructConnPtnr1OpenMM;
-    ptnr2_columns = kStructConnPtnr2OpenMM;
-    atom_site_columns = kAtomSiteColumnsOpenMM;
-  }
-
-  absl::StatusOr<AtomColumns> ptnr1_atoms =
-      AtomColumns::Create(mmcif, ptnr1_columns);
-  if (!ptnr1_atoms.ok()) {
-    return ptnr1_atoms.status();
-  }
-  absl::StatusOr<AtomColumns> ptnr2_atoms =
-      AtomColumns::Create(mmcif, ptnr2_columns);
-  if (!ptnr2_atoms.ok()) {
-    return ptnr2_atoms.status();
-  }
-  StringArrayRef struct_conn_id = mmcif["_struct_conn.id"];
-  if (!AreSameSize(struct_conn_id, *ptnr1_atoms, *ptnr2_atoms)) {
-    return absl::InvalidArgumentError(absl::StrCat(
-        "Invalid '_struct_conn.' loop. ",                  //
-        "len(id) = ", struct_conn_id.size(), ", ",         //
-        "len(ptnr1_atoms) = ", ptnr1_atoms->size(), ", ",  //
-        "len(ptnr2_atoms) = ", ptnr2_atoms->size(), "."    //
-        ));
-  }
-
-  absl::StatusOr<AtomColumns> atoms =
-      AtomColumns::Create(mmcif, atom_site_columns);
-  if (!atoms.ok()) {
-    return atoms.status();
-  }
-  StringArrayRef atom_site_id = mmcif["_atom_site.id"];
-  StringArrayRef atom_site_model_id = mmcif["_atom_site.pdbx_PDB_model_num"];
-  if (!AreSameSize(atom_site_id, atom_site_model_id, *atoms)) {
-    return absl::InvalidArgumentError(absl::StrCat(
-        "Invalid '_atom_site.' loop. ",                                //
-        "len(id)= ", atom_site_id.size(), ", ",                        //
-        "len(pdbx_PDB_model_num)= ", atom_site_model_id.size(), ", ",  //
-        "len(atoms)= ", atoms->size(), "."));                          //
-  }
-
-  // Build maps from atom ID tuples to the rows in _struct_conn where that
-  // atom appears (NB could be multiple).
-  const std::size_t struct_conn_size = struct_conn_id.size();
-  BondIndexByAtom ptnr1_rows_by_atom(struct_conn_size);
-  BondIndexByAtom ptnr2_rows_by_atom(struct_conn_size);
-  for (std::size_t i = 0; i < struct_conn_size; ++i) {
-    ptnr1_rows_by_atom[ptnr1_atoms->GetAtom(i)].push_back(i);
-    ptnr2_rows_by_atom[ptnr2_atoms->GetAtom(i)].push_back(i);
-  }
-
-  // Allocate two output arrays with one element per row in struct_conn, where
-  // each element will be the index of that atom in the atom_site table.
-  // Fill the arrays with atom_site_size, which is an invalid value, so that
-  // we can check at the end that each atom has been found.
-  const std::size_t atom_site_size = atom_site_id.size();
-  BondAtomIndices ptnr1_atom_indices(struct_conn_size, atom_site_size);
-  BondAtomIndices ptnr2_atom_indices(struct_conn_size, atom_site_size);
-
-  bool model_id_ecountered = false;
-  absl::flat_hash_set<absl::string_view> seen_alt_ids;
-  for (std::size_t atom_i = 0; atom_i < atom_site_size; ++atom_i) {
-    if (atom_site_model_id[atom_i] != model_id) {
-      if (!model_id_ecountered) {
-        continue;
-      } else {
-        // Models are contiguous so once we see a different model ID after
-        // encountering our model ID then we can exit early.
-        break;
-      }
-    } else {
-      model_id_ecountered = true;
-    }
-    AtomId atom = atoms->GetAtom(atom_i);
-    seen_alt_ids.insert(atom.alt_id);
-
-    if (auto fill_in_bonds_status1 = FillInBondsForAtom(
-            ptnr1_rows_by_atom, atom, atom_i, ptnr1_atom_indices);
-        !fill_in_bonds_status1.ok()) {
-      return fill_in_bonds_status1;
-    }
-    if (auto fill_in_bonds_status2 = FillInBondsForAtom(
-            ptnr2_rows_by_atom, atom, atom_i, ptnr2_atom_indices);
-        !fill_in_bonds_status2.ok()) {
-      return fill_in_bonds_status2;
-    }
-  }
-  // The seen_alt_ids check is a workaround for a known PDB issue: some mmCIFs
-  // (2evw, 2g0v, 2g0x, 2g0z, 2g10, 2g11, 2g12, 2g14, 2grz, 2ntw as of 2024)
-  // have multiple models and they set different whole-chain altloc in each
-  // model. The bond table however doesn't distinguish between models, so there
-  // are bonds that are valid only for some models. E.g. 2grz has model 1 with
-  // chain A with altloc A, and model 2 with chain A with altloc B. The bonds
-  // table lists a bond for each of these.
-
-  // Check that a ptnr1 atom was found for every bond.
-  if (auto row_it = absl::c_find(ptnr1_atom_indices, atom_site_size);
-      row_it != ptnr1_atom_indices.end()) {
-    if (seen_alt_ids.size() > 1 || seen_alt_ids.contains(".") ||
-        seen_alt_ids.contains("?")) {
-      std::size_t i = std::distance(ptnr1_atom_indices.begin(), row_it);
-      return absl::InvalidArgumentError(
-          absl::StrCat("Error parsing \"", mmcif.GetDataName(), "\". ",
-                       "Cannot find atom for bond ID ", struct_conn_id[i], ": ",
-                       ptnr1_atoms->GetAtomString(i)));
-    }
-  }
-
-  // Check that a ptnr2 atom was found for every bond.
-  if (auto row_it = absl::c_find(ptnr2_atom_indices, atom_site_size);
-      row_it != ptnr2_atom_indices.end()) {
-    if (seen_alt_ids.size() > 1 || seen_alt_ids.contains(".") ||
-        seen_alt_ids.contains("?")) {
-      std::size_t i = std::distance(ptnr2_atom_indices.begin(), row_it);
-      return absl::InvalidArgumentError(
-          absl::StrCat("Error parsing \"", mmcif.GetDataName(), "\". ",
-                       "Cannot find atom for bond ID ", struct_conn_id[i], ": ",
-                       ptnr2_atoms->GetAtomString(i)));
-    }
-  }
-
-  if (!model_id_ecountered) {
-    return absl::InvalidArgumentError(absl::StrCat(
-        "Error parsing \"", mmcif.GetDataName(), "\". model_id \"", model_id,
-        "\" not found in _atom_site.pdbx_PDB_model_num."));
-  }
-
-  return std::make_pair(std::move(ptnr1_atom_indices),
-                        std::move(ptnr2_atom_indices));
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/mmcif_struct_conn_pybind.cc b/src/alphafold3/structure/cpp/mmcif_struct_conn_pybind.cc
deleted file mode 100644
index 111715ab5b5d0bce3ea735b85302be3e5e852beb..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_struct_conn_pybind.cc
+++ /dev/null
@@ -1,68 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <string>
-
-#include "absl/strings/string_view.h"
-#include "alphafold3/parsers/cpp/cif_dict_lib.h"
-#include "alphafold3/structure/cpp/mmcif_struct_conn.h"
-#include "pybind11/gil.h"
-#include "pybind11/pybind11.h"
-#include "pybind11/pytypes.h"
-#include "pybind11/stl.h"
-
-namespace alphafold3 {
-
-namespace py = pybind11;
-
-constexpr char kGetBondAtomIndices[] = R"(
-Extracts the indices of the atoms that participate in bonds.
-
-This function has a workaround for a known PDB issue: some mmCIFs have
-(2evw, 2g0v, 2g0x, 2g0z, 2g10, 2g11, 2g12, 2g14, 2grz, 2ntw as of 2024)
-multiple models and they set different whole-chain altloc in each model.
-The bond table however doesn't distinguish between models, so there are
-bonds that are valid only for some models. E.g. 2grz has model 1 with
-chain A with altloc A, and model 2 with chain A with altloc B. The bonds
-table lists a bond for each of these. This case is rather rare (10 cases
-in PDB as of 2024). For the offending bonds, the returned atom index is
-set to the size of the atom_site table, i.e. it is an invalid index.
-
-Args:
-  mmcif: The mmCIF object to process.
-  model_id: The ID of the model that the returned atoms will belong to. This
-    should be a value in the mmCIF's _atom_site.pdbx_PDB_model_num column.
-
-Returns:
-  Two lists of atom indices, `from_atoms` and `to_atoms`, each one having
-  length num_bonds (as defined by _struct_conn, the bonds table). The bond
-  i, defined by the i'th row in _struct_conn, is a bond from atom at index
-  from_atoms[i], to the atom at index to_atoms[i]. The indices are simple
-  0-based indexes into the columns of the _atom_site table in the input
-  mmCIF, and do not necessarily correspond to the values in _atom_site.id,
-  or any other column.
-)";
-
-void RegisterModuleMmcifStructConn(pybind11::module m) {
-  m.def(
-      "get_bond_atom_indices",
-      [](const CifDict& mmcif, absl::string_view model_id) {
-        auto result = GetBondAtomIndices(mmcif, model_id);
-        if (result.ok()) {
-          return *result;
-        }
-        throw py::value_error(std::string(result.status().message()));
-      },
-      py::arg("mmcif_dict"), py::arg("model_id"),
-      py::doc(kGetBondAtomIndices + 1),
-      py::call_guard<py::gil_scoped_release>());
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/mmcif_struct_conn_pybind.h b/src/alphafold3/structure/cpp/mmcif_struct_conn_pybind.h
deleted file mode 100644
index acdbf7b773ba65c779bb88dffb7dc8b69ca8ee60..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_struct_conn_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_STRUCT_CONN_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_STRUCT_CONN_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleMmcifStructConn(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_STRUCT_CONN_PYBIND_H_
diff --git a/src/alphafold3/structure/cpp/mmcif_utils.pyi b/src/alphafold3/structure/cpp/mmcif_utils.pyi
deleted file mode 100755
index aa2dc23e90af680004747226cf88578693920177..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_utils.pyi
+++ /dev/null
@@ -1,71 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-from collections.abc import Sequence
-
-import numpy as np
-
-from alphafold3.cpp import cif_dict
-from alphafold3.structure.python import mmcif_layout
-
-
-def filter(
-    mmcif: cif_dict.CifDict,
-    include_nucleotides: bool,
-    include_ligands: bool = ...,
-    include_water: bool = ...,
-    include_other: bool = ...,
-    model_id: str = ...,
-) -> tuple[np.ndarray[int], mmcif_layout.MmcifLayout]: ...
-
-
-def fix_residues(
-    layout: mmcif_layout.MmcifLayout,
-    comp_id: Sequence[str],
-    atom_id: Sequence[str],
-    atom_x: Sequence[float],
-    atom_y: Sequence[float],
-    atom_z: Sequence[float],
-    fix_arg: bool = ...,
-) -> None: ...
-
-
-def read_layout(
-    mmcif: cif_dict.CifDict, model_id: str = ...
-) -> mmcif_layout.MmcifLayout: ...
-
-
-def selected_ligand_residue_mask(
-    layout: mmcif_layout.MmcifLayout,
-    atom_site_label_asym_ids: list[str],
-    atom_site_label_seq_ids: list[str],
-    atom_site_auth_seq_ids: list[str],
-    atom_site_label_comp_ids: list[str],
-    atom_site_pdbx_pdb_ins_codes: list[str],
-    nonpoly_asym_ids: list[str],
-    nonpoly_auth_seq_ids: list[str],
-    nonpoly_pdb_ins_codes: list[str],
-    nonpoly_mon_ids: list[str],
-    branch_asym_ids: list[str],
-    branch_auth_seq_ids: list[str],
-    branch_pdb_ins_codes: list[str],
-    branch_mon_ids: list[str],
-) -> tuple[list[bool], list[bool]]: ...
-
-
-def selected_polymer_residue_mask(
-    layout: mmcif_layout.MmcifLayout,
-    atom_site_label_asym_ids: list[str],
-    atom_site_label_seq_ids: list[str],
-    atom_site_label_comp_ids: list[str],
-    poly_seq_asym_ids: list[str],
-    poly_seq_seq_ids: list[str],
-    poly_seq_mon_ids: list[str],
-) -> list[bool]: ...
diff --git a/src/alphafold3/structure/cpp/mmcif_utils_pybind.cc b/src/alphafold3/structure/cpp/mmcif_utils_pybind.cc
deleted file mode 100644
index 52bd039b2984e6d8c599124bfc0c4b201c0a7041..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_utils_pybind.cc
+++ /dev/null
@@ -1,787 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <Python.h>
-
-#include <algorithm>
-#include <cstddef>
-#include <cstdint>
-#include <iterator>
-#include <memory>
-#include <new>
-#include <optional>
-#include <string>
-#include <tuple>
-#include <utility>
-#include <vector>
-
-#include "numpy/ndarrayobject.h"
-#include "numpy/ndarraytypes.h"
-#include "numpy/npy_common.h"
-#include "absl/container/flat_hash_map.h"
-#include "absl/container/flat_hash_set.h"
-#include "absl/memory/memory.h"
-#include "absl/strings/str_cat.h"
-#include "absl/strings/string_view.h"
-#include "absl/types/span.h"
-#include "alphafold3/parsers/cpp/cif_dict_lib.h"
-#include "alphafold3/structure/cpp/mmcif_altlocs.h"
-#include "alphafold3/structure/cpp/mmcif_layout.h"
-#include "pybind11/cast.h"
-#include "pybind11/gil.h"
-#include "pybind11/numpy.h"
-#include "pybind11/pybind11.h"
-#include "pybind11/pytypes.h"
-#include "pybind11/stl.h"
-#include "pybind11_abseil/absl_casters.h"
-
-namespace alphafold3 {
-namespace {
-namespace py = pybind11;
-
-struct PyObjectDeleter {
-  inline void operator()(PyObject* obj) const { Py_CLEAR(obj); }
-};
-
-using ScopedPyObject = std::unique_ptr<PyObject, PyObjectDeleter>;
-
-using StringArrayRef = absl::Span<const std::string>;
-using Indexer = absl::flat_hash_map<absl::string_view, std::size_t>;
-
-// Returns the reverse look-up map of name to index.
-Indexer MakeIndex(StringArrayRef col) {
-  Indexer index;
-  index.reserve(col.size());
-  for (std::size_t i = 0; i < col.size(); ++i) {
-    index[col[i]] = i;
-  }
-  return index;
-}
-
-// Returns whether each container is the same size.
-template <typename C, typename... Cs>
-bool AreSameSize(C c, const Cs&... cs) {
-  return ((c.size() == cs.size()) && ...);
-}
-
-// Stores references to columns in `_atom_site` ensuring they all exist and
-// are the same size.
-struct AtomSiteLoop {
-  explicit AtomSiteLoop(const CifDict& cif_dict)
-      : id(cif_dict["_atom_site.id"]),
-        model_id(cif_dict["_atom_site.pdbx_PDB_model_num"]),
-        chain_id(cif_dict["_atom_site.label_asym_id"]),
-        seq_id(cif_dict["_atom_site.label_seq_id"]),
-
-        comp_id(cif_dict["_atom_site.label_comp_id"]),
-        atom_id(cif_dict["_atom_site.label_atom_id"]),
-
-        alt_id(cif_dict["_atom_site.label_alt_id"]),
-        occupancy(cif_dict["_atom_site.occupancy"])
-
-  {
-    if (!AreSameSize(id, model_id, chain_id, seq_id, comp_id, atom_id, alt_id,
-                     occupancy)) {
-      throw py::value_error(
-          absl::StrCat("Invalid '_atom_site.' loop. ",                     //
-                       "len(id)=", id.size(), ", ",                        //
-                       "len(pdbx_PDB_model_num)=", model_id.size(), ", ",  //
-                       "len(label_asym_id)=", chain_id.size(), ", ",       //
-                       "len(label_seq_id)=", seq_id.size(), ", ",          //
-                       "len(label_comp_id)=", comp_id.size(), ", ",        //
-                       "len(atom_id)=", atom_id.size(), ", ",              //
-                       "len(label_alt_id)=", alt_id.size(), ", ",          //
-                       "len(occupancy)=", occupancy.size()));
-    }
-  }
-  StringArrayRef id;
-  StringArrayRef model_id;
-  StringArrayRef chain_id;
-  StringArrayRef seq_id;
-  StringArrayRef comp_id;
-  StringArrayRef atom_id;
-  StringArrayRef alt_id;
-  StringArrayRef occupancy;
-};
-
-// Stores references to columns in `_entity` ensuring they all exist and are the
-// same size.
-struct EntityLoop {
-  explicit EntityLoop(const CifDict& cif_dict)
-      : id(cif_dict["_entity.id"]), type(cif_dict["_entity.type"]) {
-    if (!AreSameSize(id, type)) {
-      throw py::value_error(absl::StrCat("Invalid '_entity.' loop. ",  //
-                                         "len(id)=", id.size(), ", ",  //
-                                         "len(type)=", type.size()));
-    }
-  }
-  StringArrayRef id;
-  StringArrayRef type;
-};
-
-// Stores references to columns in `_entity_poly` ensuring they all exist and
-// are the same size.
-struct EntityPolyLoop {
-  explicit EntityPolyLoop(const CifDict& cif_dict)
-      : entity_id(cif_dict["_entity_poly.entity_id"]),
-        type(cif_dict["_entity_poly.type"]) {
-    if (!AreSameSize(entity_id, type)) {
-      throw py::value_error(absl::StrCat("Invalid '_entity_poly.' loop. ",  //
-                                         "len(entity_id)=", entity_id.size(),
-                                         ", ",  //
-                                         "len(type)=", type.size()));
-    }
-  }
-  StringArrayRef entity_id;
-  StringArrayRef type;
-};
-
-// Returns a set of entity names removing ones not included by the flags
-// specified.
-absl::flat_hash_set<absl::string_view> SelectChains(const CifDict& mmcif,
-                                                    bool include_nucleotides,
-                                                    bool include_ligands,
-                                                    bool include_water,
-                                                    bool include_other) {
-  EntityLoop entity_loop(mmcif);
-  EntityPolyLoop entity_poly(mmcif);
-  absl::flat_hash_set<absl::string_view> permitted_polymers{"polypeptide(L)"};
-  absl::flat_hash_set<absl::string_view> forbidden_polymers;
-  for (absl::string_view type :
-       {"polydeoxyribonucleotide", "polyribonucleotide",
-        "polydeoxyribonucleotide/polyribonucleotide hybrid"}) {
-    if (include_nucleotides) {
-      permitted_polymers.emplace(type);
-    } else {
-      forbidden_polymers.emplace(type);
-    }
-  }
-
-  absl::flat_hash_set<absl::string_view> permitted_nonpoly_entity_types;
-  absl::flat_hash_set<absl::string_view> forbidden_nonpoly_entity_types;
-  for (absl::string_view type : {"non-polymer", "branched"}) {
-    if (include_ligands) {
-      permitted_nonpoly_entity_types.emplace(type);
-    } else {
-      forbidden_nonpoly_entity_types.emplace(type);
-    }
-  }
-  absl::string_view water_type = "water";
-  if (include_water) {
-    permitted_nonpoly_entity_types.emplace(water_type);
-  } else {
-    forbidden_nonpoly_entity_types.emplace(water_type);
-  }
-
-  StringArrayRef chain_ids = mmcif["_struct_asym.id"];
-  StringArrayRef entity_ids = mmcif["_struct_asym.entity_id"];
-  Indexer chain_index = MakeIndex(chain_ids);
-  Indexer entity_poly_index = MakeIndex(entity_poly.entity_id);
-  Indexer entity_id_to_index = MakeIndex(entity_loop.id);
-
-  absl::flat_hash_set<absl::string_view> keep_chain_id;
-  for (std::size_t i = 0; i < chain_ids.size(); ++i) {
-    absl::string_view chain_id = chain_ids[i];
-    absl::string_view entity_id = entity_ids[i];
-    if (entity_id_to_index.empty() ||
-        entity_loop.type[entity_id_to_index[entity_id]] == "polymer") {
-      if (auto it = entity_poly_index.find(entity_id);
-          it != entity_poly_index.end()) {
-        absl::string_view poly_type = entity_poly.type[it->second];
-        if (include_other) {
-          if (!forbidden_polymers.contains(poly_type)) {
-            keep_chain_id.insert(chain_id);
-          }
-        } else {
-          if (permitted_polymers.contains(poly_type)) {
-            keep_chain_id.insert(chain_id);
-          }
-        }
-      }
-    } else {
-      absl::string_view entity_type =
-          entity_loop.type[entity_id_to_index[entity_id]];
-      if (include_other) {
-        if (!forbidden_nonpoly_entity_types.contains(entity_type)) {
-          keep_chain_id.insert(chain_id);
-          continue;
-        }
-      } else {
-        if (permitted_nonpoly_entity_types.contains(entity_type)) {
-          keep_chain_id.insert(chain_id);
-          continue;
-        }
-      }
-    }
-  }
-  return keep_chain_id;
-}
-
-class ProcessResidue {
- public:
-  explicit ProcessResidue(const char* residue)
-      : residue_(PyUnicode_InternFromString(residue)) {}
-  bool IsResidue(PyObject* residue) {
-    return ArePyObjectsEqual(residue_.get(), residue);
-  }
-
-  static bool ArePyObjectsEqual(PyObject* lhs, PyObject* rhs) {
-    switch (PyObject_RichCompareBool(lhs, rhs, Py_EQ)) {
-      case -1:
-        PyErr_Clear();
-        return false;
-      case 0:
-        return false;
-      default:
-        return true;
-    }
-  }
-
- private:
-  ScopedPyObject residue_;
-};
-
-struct Position3 {
-  float x;
-  float y;
-  float z;
-};
-
-float DistanceSquared(Position3 v1, Position3 v2) {
-  float dx = v1.x - v2.x;
-  float dy = v1.y - v2.y;
-  float dz = v1.z - v2.z;
-  return dx * dx + dy * dy + dz * dz;
-}
-
-class FixArginine : public ProcessResidue {
- public:
-  FixArginine()
-      : ProcessResidue("ARG"),
-        cd_(PyUnicode_InternFromString("CD")),
-        nh1_(PyUnicode_InternFromString("NH1")),
-        nh2_(PyUnicode_InternFromString("NH2")),
-        hh11_(PyUnicode_InternFromString("HH11")),
-        hh21_(PyUnicode_InternFromString("HH21")),
-        hh12_(PyUnicode_InternFromString("HH12")),
-        hh22_(PyUnicode_InternFromString("HH22")) {}
-  void Fix(absl::Span<PyObject*> atom_ids, absl::Span<const float> atom_x,
-           absl::Span<const float> atom_y, absl::Span<const float> atom_z) {
-    std::ptrdiff_t cd_index = -1;
-    std::ptrdiff_t nh1_index = -1;
-    std::ptrdiff_t nh2_index = -1;
-    std::ptrdiff_t hh11_index = -1;
-    std::ptrdiff_t hh21_index = -1;
-    std::ptrdiff_t hh12_index = -1;
-    std::ptrdiff_t hh22_index = -1;
-    for (std::ptrdiff_t index = 0; index < atom_ids.size(); ++index) {
-      PyObject* atom_id = atom_ids[index];
-      if (cd_index == -1 && ArePyObjectsEqual(atom_id, cd_.get())) {
-        cd_index = index;
-      } else if (nh1_index == -1 && ArePyObjectsEqual(atom_id, nh1_.get())) {
-        nh1_index = index;
-      } else if (nh2_index == -1 && ArePyObjectsEqual(atom_id, nh2_.get())) {
-        nh2_index = index;
-      } else if (hh11_index == -1 && ArePyObjectsEqual(atom_id, hh11_.get())) {
-        hh11_index = index;
-      } else if (hh21_index == -1 && ArePyObjectsEqual(atom_id, hh21_.get())) {
-        hh21_index = index;
-      } else if (hh12_index == -1 && ArePyObjectsEqual(atom_id, hh12_.get())) {
-        hh12_index = index;
-      } else if (hh22_index == -1 && ArePyObjectsEqual(atom_id, hh22_.get())) {
-        hh22_index = index;
-      }
-    }
-    if (cd_index < 0 || nh1_index < 0 || nh2_index < 0) {
-      return;
-    }
-    Position3 cd_pos(atom_x[cd_index], atom_y[cd_index], atom_z[cd_index]);
-    Position3 nh1_pos(atom_x[nh1_index], atom_y[nh1_index], atom_z[nh1_index]);
-    Position3 nh2_pos(atom_x[nh2_index], atom_y[nh2_index], atom_z[nh2_index]);
-    if (DistanceSquared(nh1_pos, cd_pos) <= DistanceSquared(nh2_pos, cd_pos)) {
-      return;
-    }
-    std::swap(atom_ids[nh1_index], atom_ids[nh2_index]);
-    if (hh11_index >= 0 && hh21_index >= 0) {
-      std::swap(atom_ids[hh11_index], atom_ids[hh21_index]);
-    } else if (hh11_index >= 0) {
-      Py_DECREF(atom_ids[hh11_index]);
-      Py_INCREF(hh21_.get());
-      atom_ids[hh11_index] = hh21_.get();
-    } else if (hh21_index >= 0) {
-      Py_DECREF(atom_ids[hh21_index]);
-      Py_INCREF(hh11_.get());
-      atom_ids[hh21_index] = hh11_.get();
-    }
-    if (hh12_index >= 0 && hh22_index >= 0) {
-      std::swap(atom_ids[hh12_index], atom_ids[hh22_index]);
-    } else if (hh12_index >= 0) {
-      Py_DECREF(atom_ids[hh12_index]);
-      Py_INCREF(hh22_.get());
-      atom_ids[hh12_index] = hh22_.get();
-    } else if (hh22_index >= 0) {
-      Py_DECREF(atom_ids[hh22_index]);
-      Py_INCREF(hh21_.get());
-      atom_ids[hh22_index] = hh21_.get();
-    }
-  }
-
- private:
-  ScopedPyObject cd_;
-  ScopedPyObject nh1_;
-  ScopedPyObject nh2_;
-  ScopedPyObject hh11_;
-  ScopedPyObject hh21_;
-  ScopedPyObject hh12_;
-  ScopedPyObject hh22_;
-};
-
-// Returns the layout of the mmCIF `_atom_site` table.
-inline MmcifLayout ReadMmcifLayout(const CifDict& mmcif,
-                                   absl::string_view model_id = "") {
-  py::gil_scoped_release release;
-  auto mmcif_layout = MmcifLayout::Create(mmcif, model_id);
-  if (mmcif_layout.ok()) {
-    return *mmcif_layout;
-  }
-
-  throw py::value_error(std::string(mmcif_layout.status().message()));
-}
-
-std::pair<py::object, MmcifLayout> MmcifFilter(  //
-    const CifDict& mmcif,                        //
-    bool include_nucleotides,                    //
-    bool include_ligands,                        //
-    bool include_water,                          //
-    bool include_other,                          //
-    absl::string_view model_id) {
-  if (_import_array() < 0) {
-    throw py::import_error("Failed to import NumPy.");
-  }
-  auto layout = ReadMmcifLayout(mmcif, model_id);
-  std::unique_ptr<std::vector<std::uint64_t>> keep_indices;
-  size_t new_num_atoms;
-
-  {
-    py::gil_scoped_release release;
-
-    AtomSiteLoop atom_site(mmcif);
-
-    auto keep_chain_ids =
-        SelectChains(mmcif, include_nucleotides, include_ligands, include_water,
-                     include_other);
-
-    std::vector<std::size_t> chain_indices;
-    chain_indices.reserve(keep_chain_ids.size());
-    for (std::size_t i = 0; i < layout.num_chains(); ++i) {
-      if (keep_chain_ids.contains(
-              atom_site.chain_id[layout.atom_site_from_chain_index(i)])) {
-        chain_indices.push_back(i);
-      }
-    }
-
-    keep_indices =
-        absl::WrapUnique(new std::vector<std::uint64_t>(ResolveMmcifAltLocs(
-            layout, atom_site.comp_id, atom_site.atom_id, atom_site.alt_id,
-            atom_site.occupancy, chain_indices)));
-    new_num_atoms = keep_indices->size();
-
-    if (layout.num_models() > 1) {
-      keep_indices->reserve(layout.num_models() * new_num_atoms);
-      std::uint64_t* start = &(*keep_indices->begin());
-      std::size_t num_atom = keep_indices->size();
-      // Copy first model indices into all model indices offsetting each copy.
-      for (std::size_t i = 1; i < layout.num_models(); ++i) {
-        std::size_t offset = i * layout.num_atoms();
-        std::transform(start, start + num_atom,
-                       std::back_inserter(*keep_indices),
-                       [offset](std::size_t v) { return v + offset; });
-      }
-    }
-  }
-
-  layout.Filter(*keep_indices);
-
-  npy_intp shape[] = {static_cast<npy_intp>(layout.num_models()),
-                      static_cast<npy_intp>(new_num_atoms)};
-  PyObject* arr =
-      PyArray_SimpleNewFromData(2, shape, NPY_INT64, keep_indices->data());
-  // Create a capsule to hold the memory of the buffer so NumPy knows how to
-  // delete it when done with it.
-  PyObject* capsule = PyCapsule_New(
-      keep_indices.release(), nullptr, +[](PyObject* capsule_cleanup) {
-        void* memory = PyCapsule_GetPointer(capsule_cleanup, nullptr);
-        delete static_cast<std::vector<std::size_t>*>(memory);
-      });
-  PyArray_SetBaseObject(reinterpret_cast<PyArrayObject*>(arr), capsule);
-
-  return std::make_pair(py::reinterpret_steal<py::object>(arr),
-                        std::move(layout));
-}
-
-void MmcifFixResidues(               //
-    const MmcifLayout& layout,       //
-    absl::Span<PyObject*> comp_id,   //
-    absl::Span<PyObject*> atom_id,   //
-    absl::Span<const float> atom_x,  //
-    absl::Span<const float> atom_y,  //
-    absl::Span<const float> atom_z,  //
-    bool fix_arginine                //
-) {
-  std::optional<FixArginine> arginine;
-  std::size_t num_atoms = layout.num_atoms();
-  if (comp_id.size() != num_atoms || atom_id.size() != num_atoms ||
-      atom_x.size() != num_atoms || atom_y.size() != num_atoms ||
-      atom_z.size() != num_atoms) {
-    throw py::value_error(
-        absl::StrCat("Sizes must match. ",                   //
-                     "num_atoms=", num_atoms, ", ",          //
-                     "len(comp_id)=", comp_id.size(), ", ",  //
-                     "len(atom_id)=", atom_id.size(), ", ",  //
-                     "len(atom_x)=", atom_x.size(), ", ",    //
-                     "len(atom_y)=", atom_y.size(), ", ",    //
-                     "len(atom_z)=", atom_z.size()));
-  }
-
-  if (fix_arginine) {
-    arginine.emplace();
-  }
-  if (!arginine.has_value()) {
-    return;
-  }
-
-  for (std::size_t res_index = 0; res_index < layout.num_residues();
-       ++res_index) {
-    auto [atom_start, atom_end] = layout.atom_range(res_index);
-    std::size_t atom_count = atom_end - atom_start;
-    PyObject* resname = comp_id[atom_start];
-    if (arginine.has_value() && arginine->IsResidue(resname)) {
-      arginine->Fix(atom_id.subspan(atom_start, atom_count),
-                    atom_x.subspan(atom_start, atom_count),
-                    atom_y.subspan(atom_start, atom_count),
-                    atom_z.subspan(atom_start, atom_count));
-    }
-  }
-}
-
-std::vector<bool> SelectedPolymerResidueMask(
-    const MmcifLayout& layout,
-    const std::vector<absl::string_view>& atom_site_label_asym_ids,  //
-    const std::vector<absl::string_view>& atom_site_label_seq_ids,   //
-    const std::vector<absl::string_view>& atom_site_label_comp_ids,  //
-    const std::vector<absl::string_view>& poly_seq_asym_ids,         //
-    const std::vector<absl::string_view>& poly_seq_seq_ids,          //
-    const std::vector<absl::string_view>& poly_seq_mon_ids           //
-) {
-  absl::flat_hash_map<std::pair<absl::string_view, absl::string_view>,
-                      absl::string_view>
-      selected;
-  selected.reserve(layout.num_residues());
-  // layout.residues() is O(1) while layout.residue_starts() is O(num_res).
-  const std::vector<std::size_t>& residue_starts = layout.residue_starts();
-  for (int i = 0; i < layout.residues().size(); ++i) {
-    std::size_t res_start = residue_starts[i];
-    std::size_t res_end = layout.residues()[i];
-    if (res_start == res_end) {
-      continue;  // Skip empty residues (containing no atoms).
-    }
-
-    absl::string_view label_seq_id = atom_site_label_seq_ids[i];
-    if (label_seq_id == ".") {
-      continue;  // Skip non-polymers.
-    }
-
-    absl::string_view label_asym_id = atom_site_label_asym_ids[i];
-    absl::string_view label_comp_id = atom_site_label_comp_ids[i];
-    selected[std::make_pair(label_asym_id, label_seq_id)] = label_comp_id;
-  }
-
-  std::vector<bool> mask;
-  mask.reserve(poly_seq_mon_ids.size());
-  for (int i = 0; i < poly_seq_mon_ids.size(); ++i) {
-    absl::string_view poly_seq_asym_id = poly_seq_asym_ids[i];
-    absl::string_view poly_seq_seq_id = poly_seq_seq_ids[i];
-    absl::string_view poly_seq_mon_id = poly_seq_mon_ids[i];
-
-    auto it = selected.find(std::make_pair(poly_seq_asym_id, poly_seq_seq_id));
-    if (it != selected.end()) {
-      mask.push_back(it->second == poly_seq_mon_id);
-    } else {
-      mask.push_back(true);  // Missing residues are not heterogeneous.
-    }
-  }
-  return mask;
-}
-
-std::pair<std::vector<bool>, std::vector<bool>> SelectedLigandResidueMask(
-    const MmcifLayout& layout,                                           //
-    const std::vector<absl::string_view>& atom_site_label_asym_ids,      //
-    const std::vector<absl::string_view>& atom_site_label_seq_ids,       //
-    const std::vector<absl::string_view>& atom_site_auth_seq_ids,        //
-    const std::vector<absl::string_view>& atom_site_label_comp_ids,      //
-    const std::vector<absl::string_view>& atom_site_pdbx_pdb_ins_codes,  //
-    const std::vector<absl::string_view>& nonpoly_asym_ids,              //
-    const std::vector<absl::string_view>& nonpoly_auth_seq_ids,          //
-    const std::vector<absl::string_view>& nonpoly_pdb_ins_codes,         //
-    const std::vector<absl::string_view>& nonpoly_mon_ids,               //
-    const std::vector<absl::string_view>& branch_asym_ids,               //
-    const std::vector<absl::string_view>& branch_auth_seq_ids,           //
-    const std::vector<absl::string_view>& branch_pdb_ins_codes,          //
-    const std::vector<absl::string_view>& branch_mon_ids) {
-  absl::flat_hash_map<
-      std::tuple<absl::string_view, absl::string_view, absl::string_view>,
-      absl::string_view>
-      selected;
-  selected.reserve(layout.num_residues());
-  // layout.residues() is O(1) while layout.residue_starts() is O(num_res).
-  const std::vector<std::size_t>& residue_starts = layout.residue_starts();
-  for (int i = 0; i < layout.residues().size(); ++i) {
-    std::size_t res_start = residue_starts[i];
-    std::size_t res_end = layout.residues()[i];
-    if (res_start == res_end) {
-      continue;  // Skip empty residues (containing no atoms).
-    }
-
-    absl::string_view label_seq_id = atom_site_label_seq_ids[i];
-    if (label_seq_id != ".") {
-      continue;  // Skip polymers.
-    }
-
-    absl::string_view label_asym_id = atom_site_label_asym_ids[i];
-    absl::string_view auth_seq_id = atom_site_auth_seq_ids[i];
-    absl::string_view ins_code = atom_site_pdbx_pdb_ins_codes[i];
-    ins_code = ins_code == "?" ? "." : ins_code;  // Remap unknown to unset.
-    absl::string_view label_comp_id = atom_site_label_comp_ids[i];
-    selected[std::make_tuple(label_asym_id, auth_seq_id, ins_code)] =
-        label_comp_id;
-  }
-
-  std::vector<bool> nonpoly_mask;
-  nonpoly_mask.reserve(nonpoly_asym_ids.size());
-  for (int i = 0; i < nonpoly_asym_ids.size(); ++i) {
-    absl::string_view nonpoly_asym_id = nonpoly_asym_ids[i];
-    absl::string_view nonpoly_auth_seq_id = nonpoly_auth_seq_ids[i];
-    absl::string_view nonpoly_ins_code = nonpoly_pdb_ins_codes[i];
-    // Remap unknown to unset.
-    nonpoly_ins_code = nonpoly_ins_code == "?" ? "." : nonpoly_ins_code;
-    absl::string_view nonpoly_mon_id = nonpoly_mon_ids[i];
-
-    auto it = selected.find(std::make_tuple(
-        nonpoly_asym_id, nonpoly_auth_seq_id, nonpoly_ins_code));
-    if (it != selected.end()) {
-      nonpoly_mask.push_back(it->second == nonpoly_mon_id);
-    } else {
-      nonpoly_mask.push_back(true);  // Missing residues are not heterogeneous.
-    }
-  }
-
-  std::vector<bool> branch_mask;
-  branch_mask.reserve(branch_asym_ids.size());
-  for (int i = 0; i < branch_asym_ids.size(); ++i) {
-    absl::string_view branch_asym_id = branch_asym_ids[i];
-    absl::string_view branch_auth_seq_id = branch_auth_seq_ids[i];
-
-    // Insertion codes in _pdbx_branch_scheme are not required and can be
-    // missing. Default to unset ('.') in such case.
-    absl::string_view branch_ins_code;
-    if (i < branch_pdb_ins_codes.size()) {
-      branch_ins_code = branch_pdb_ins_codes[i];
-      // Remap unknown to unset.
-      branch_ins_code = branch_ins_code == "?" ? "." : branch_ins_code;
-    } else {
-      branch_ins_code = ".";
-    }
-
-    absl::string_view branch_mon_id = branch_mon_ids[i];
-
-    auto it = selected.find(
-        std::make_tuple(branch_asym_id, branch_auth_seq_id, branch_ins_code));
-    if (it != selected.end()) {
-      branch_mask.push_back(it->second == branch_mon_id);
-    } else {
-      branch_mask.push_back(true);  // Missing residues are not heterogeneous.
-    }
-  }
-
-  return std::make_pair(nonpoly_mask, branch_mask);
-}
-
-constexpr char kReadMmcifLayout[] = R"(
-Returns the layout of the cif_dict.
-
-Args:
-  mmcif: mmCIF to calculate the layout for.
-  model_id: If non-empty the layout of the given model is returned
-    otherwise the layout of all models are returned.
-Raises:
-  ValueError: if the mmCIF is malformed or the number of atoms in each
-    model are inconsistent.
-)";
-
-constexpr char kMmcifFilter[] = R"(
-Returns NumpyArray of selected rows in `_atom_site` and new layout.
-
-Args:
-  mmcif: mmCIF to filter.
-  include_nucleotides: Whether to include polymer entities of type:
-    "polypeptide(L)\", "polydeoxyribonucleotide", "polyribonucleotide".
-    Otherwise only "polypeptide(L)\". ("polypeptide(D)\" is never included.)
-  include_ligands: Whether to include non-polymer entities of type:
-    "non-polymer", "branched".
-  include_water: Whether to include entities of type water.
-  include_other: Whether to include other (non-standard) entity types
-    that are not covered by any of the above parameters.
-  model_id: If non-empty the model with given name is selected otherwise
-    all models are selected.
-
-Returns:
-  A tuple containing a numpy array with a shape (num_models, num_atoms)
-  with the atom_site indices selected and the new layout.
-
-Raises:
-  ValueError error if mmCIF dict does not have all required fields.
-)";
-
-constexpr char kMmcifFixResidues[] = R"(
-Fixes residue columns in-place.
-
-Args:
-  layout: layout from filter command.
-  comp_id: '_atom_site.label_comp_id' of first model.
-  group: '_atom_site.group_PDB' of first model.
-  atom_id: '_atom_site.label_atom_id' of first model.
-  type_symbol: '_atom_site.type_symbol' of first model.
-  atom_x: '_atom_site.Cartn_x' of first model.
-  atom_y: '_atom_site.Cartn_y' of first model.
-  atom_z: '_atom_site.Cartn_z' of first model.
-  fix_mse: Whether to convert MSE residues into MET residues.
-  fix_arg: Whether to ensure the atoms in ARG are in the correct order.
-  fix_unknown_dna: Whether to convert DNA residues from N to DN.
-  dna_mask: Which atoms are from DNA chains.
-
-Raises:
-  ValueError: If shapes are invalid.
-)";
-
-constexpr char kSelectedPolymerResidueMask[] = R"(
-Returns a _pdbx_poly_seq_scheme mask for selected hetero residues.
-
-Should be called after filtering the layout using mmcif_utils.filter.
-
-Args:
-  layout: Layout defining the _atom_site residue selection.
-  atom_site_label_asym_ids: Internal (label) chain ID, per selected residue.
-  atom_site_label_seq_ids: Internal (label) residue ID, per selected residue.
-  atom_site_label_comp_ids: Residue name, per selected residue.
-  poly_seq_asym_ids: Internal (label) chain ID, per residue.
-  poly_seq_seq_ids: Internal (label) residue ID, per residue.
-  poly_seq_mon_ids: Residue name, per residue.
-
-Returns:
-  A mask for the _pdbx_poly_seq_scheme table. If residues are selected
-  using this mask, they will have consistent heterogeneous residue
-  selection with the _atom_site table.
-)";
-
-constexpr char kSelectedLigandResidueMask[] = R"(
-Returns masks for selected ligand hetero residues.
-
-Should be called after filtering the layout using mmcif_utils.filter.
-
-Args:
-  layout: Layout defining the _atom_site residue selection.
-  atom_site_label_asym_ids: Internal (label) chain ID, per selected residue.
-  atom_site_label_seq_ids: Internal (author) residue ID, per selected residue.
-  atom_site_auth_seq_ids: External (author) residue ID, per selected residue.
-  atom_site_label_comp_ids: Residue name, per selected residue.
-  atom_site_pdbx_pdb_ins_codes: Insertion code, per selected residue.
-  nonpoly_asym_ids: Internal (label) chain ID, per residue from
-   _pdbx_nonpoly_scheme.
-  nonpoly_auth_seq_ids: External (author) residue ID, per residue from
-   _pdbx_nonpoly_scheme.
-  nonpoly_pdb_ins_codes: Residue name, per residue from
-   _pdbx_nonpoly_scheme.
-  nonpoly_mon_ids: Insertion code, per residue from _pdbx_nonpoly_scheme.
-  branch_asym_ids: Internal (label) chain ID, per residue from
-   _pdbx_branch_scheme.
-  branch_auth_seq_ids: External (author) residue ID, per residue from
-   _pdbx_branch_scheme.
-  branch_pdb_ins_codes: Residue name, per residue from _pdbx_branch_scheme.
-  branch_mon_ids: Insertion code, per residue from _pdbx_branch_scheme.
-
-Returns:
-  A tuple with masks for _pdbx_nonpoly_scheme and _pdbx_branch_scheme. If
-  residues are selected using these masks, they will have consistent
-  heterogeneous residue selection with the _atom_site table.
-)";
-
-}  // namespace
-
-void RegisterModuleMmcifUtils(pybind11::module m) {
-  m.def("read_layout", ReadMmcifLayout,
-        py::arg("mmcif"),              //
-        py::arg("model_id") = "",      //
-        py::doc(kReadMmcifLayout + 1)  //
-  );
-
-  m.def("filter", MmcifFilter,               //
-        py::arg("mmcif"),                    //
-        py::arg("include_nucleotides"),      //
-        py::arg("include_ligands") = false,  //
-        py::arg("include_water") = false,    //
-        py::arg("include_other") = false,    //
-        py::arg("model_id") = "",            //
-        py::doc(kMmcifFilter + 1)            //
-  );
-
-  m.def("fix_residues", MmcifFixResidues,
-        py::arg("layout"),              //
-        py::arg("comp_id"),             //
-        py::arg("atom_id"),             //
-        py::arg("atom_x"),              //
-        py::arg("atom_y"),              //
-        py::arg("atom_z"),              //
-        py::arg("fix_arg") = false,     //
-        py::doc(kMmcifFixResidues + 1)  //
-  );
-
-  m.def("selected_polymer_residue_mask", SelectedPolymerResidueMask,
-        py::arg("layout"),                         //
-        py::arg("atom_site_label_asym_ids"),       //
-        py::arg("atom_site_label_seq_ids"),        //
-        py::arg("atom_site_label_comp_ids"),       //
-        py::arg("poly_seq_asym_ids"),              //
-        py::arg("poly_seq_seq_ids"),               //
-        py::arg("poly_seq_mon_ids"),               //
-        py::call_guard<py::gil_scoped_release>(),  //
-        py::doc(kSelectedPolymerResidueMask + 1)   //
-  );
-
-  m.def("selected_ligand_residue_mask", SelectedLigandResidueMask,
-        py::arg("layout"),                         //
-        py::arg("atom_site_label_asym_ids"),       //
-        py::arg("atom_site_label_seq_ids"),        //
-        py::arg("atom_site_auth_seq_ids"),         //
-        py::arg("atom_site_label_comp_ids"),       //
-        py::arg("atom_site_pdbx_pdb_ins_codes"),   //
-        py::arg("nonpoly_asym_ids"),               //
-        py::arg("nonpoly_auth_seq_ids"),           //
-        py::arg("nonpoly_pdb_ins_codes"),          //
-        py::arg("nonpoly_mon_ids"),                //
-        py::arg("branch_asym_ids"),                //
-        py::arg("branch_auth_seq_ids"),            //
-        py::arg("branch_pdb_ins_codes"),           //
-        py::arg("branch_mon_ids"),                 //
-        py::call_guard<py::gil_scoped_release>(),  //
-        py::doc(kSelectedLigandResidueMask + 1)    //
-  );
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/mmcif_utils_pybind.h b/src/alphafold3/structure/cpp/mmcif_utils_pybind.h
deleted file mode 100644
index 7ba19420b228b6ad3fb81ce55d47608437ddc45e..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/mmcif_utils_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_UTILS_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_UTILS_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleMmcifUtils(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_MMCIF_UTILS_PYBIND_H_
diff --git a/src/alphafold3/structure/cpp/string_array.pyi b/src/alphafold3/structure/cpp/string_array.pyi
deleted file mode 100755
index b4b76c27f267ce43d2a126d9a53db580cf464772..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/string_array.pyi
+++ /dev/null
@@ -1,50 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-from collections.abc import Sequence
-from typing import Any, overload
-
-import numpy as np
-
-
-def format_float_array(
-    values: Sequence[float], num_decimal_places: int
-) -> list[str]: ...
-
-
-def isin(
-    array: np.ndarray[object],
-    test_elements: set[str | bytes],
-    *,
-    invert: bool = ...,
-) -> np.ndarray[bool]: ...
-
-
-@overload
-def remap(
-    array: np.ndarray[object],
-    mapping: dict[str, str],
-    default_value: str,
-    inplace: bool = ...,
-) -> np.ndarray[object]: ...
-
-
-@overload
-def remap(
-    array: np.ndarray[object],
-    mapping: dict[str, str],
-    inplace: bool = ...,
-) -> np.ndarray[object]: ...
-
-
-def remap_multiple(
-    arrays: Sequence[np.ndarray[object]],
-    mapping: dict[tuple[Any], int],
-) -> np.ndarray[int]: ...
diff --git a/src/alphafold3/structure/cpp/string_array_pybind.cc b/src/alphafold3/structure/cpp/string_array_pybind.cc
deleted file mode 100644
index 29fac727a3e689aa116bc82aba1d16d7a190e391..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/string_array_pybind.cc
+++ /dev/null
@@ -1,329 +0,0 @@
-// Copyright 2024 DeepMind Technologies Limited
-//
-// AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-// this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-//
-// To request access to the AlphaFold 3 model parameters, follow the process set
-// out at https://github.com/google-deepmind/alphafold3. You may only use these
-// if received directly from Google. Use is subject to terms of use available at
-// https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-#include <Python.h>
-
-#include <algorithm>
-#include <cstddef>
-#include <cstdint>
-#include <cstring>
-#include <iterator>
-#include <limits>
-#include <string>
-#include <vector>
-
-#include "numpy/arrayobject.h"
-#include "numpy/ndarrayobject.h"
-#include "numpy/ndarraytypes.h"
-#include "numpy/npy_common.h"
-#include "absl/algorithm/container.h"
-#include "absl/container/flat_hash_set.h"
-#include "absl/strings/str_format.h"
-#include "absl/strings/string_view.h"
-#include "absl/types/span.h"
-#include "pybind11/cast.h"
-#include "pybind11/numpy.h"
-#include "pybind11/pybind11.h"
-#include "pybind11/pytypes.h"
-#include "pybind11_abseil/absl_casters.h"
-
-namespace {
-
-namespace py = pybind11;
-
-PyObject* RemapNumpyArrayObjects(PyObject* array, PyObject* mapping,
-                                 bool inplace, PyObject* default_value) {
-  import_array();
-  if (!PyArray_Check(array)) {
-    PyErr_SetString(PyExc_TypeError, "'array' must be a np.ndarray.");
-    return nullptr;
-  }
-  if (!PyDict_Check(mapping)) {
-    PyErr_SetString(PyExc_TypeError, "'mapping' must be a Python dict.");
-    return nullptr;
-  }
-
-  PyArrayObject* array_obj = reinterpret_cast<PyArrayObject*>(array);
-  if (PyArray_TYPE(array_obj) != NPY_OBJECT) {
-    PyErr_SetString(PyExc_TypeError, "`array` must be an array of objects.");
-    return nullptr;
-  }
-
-  if (inplace) {
-    // We are returning original array so we need to increase the ref count.
-    Py_INCREF(array);
-  } else {
-    // We are returning a fresh copy.
-    array = PyArray_NewCopy(array_obj, NPY_CORDER);
-    if (array == nullptr) {
-      PyErr_SetString(PyExc_MemoryError, "Out of memory!");
-      return nullptr;
-    }
-    array_obj = reinterpret_cast<PyArrayObject*>(array);
-  }
-
-  if (PyArray_SIZE(array_obj) == 0) {
-    return array;
-  }
-
-  if (default_value == nullptr && PyDict_Size(mapping) == 0) {
-    return array;
-  }
-
-  NpyIter* iter = NpyIter_New(
-      array_obj, NPY_ITER_READWRITE | NPY_ITER_EXTERNAL_LOOP | NPY_ITER_REFS_OK,
-      NPY_KEEPORDER, NPY_NO_CASTING, nullptr);
-  if (iter == nullptr) {
-    PyErr_SetString(PyExc_MemoryError, "Out of memory!");
-    Py_XDECREF(array);
-    return nullptr;
-  }
-
-  NpyIter_IterNextFunc* iter_next = NpyIter_GetIterNext(iter, nullptr);
-  if (iter_next == nullptr) {
-    NpyIter_Deallocate(iter);
-    Py_XDECREF(array);
-    PyErr_SetString(PyExc_MemoryError, "Out of memory!");
-    return nullptr;
-  }
-
-  // Iterating arrays taken from:
-  // https://numpy.org/doc/stable/reference/c-api/iterator.html
-  char** data_pointer = NpyIter_GetDataPtrArray(iter);
-  npy_intp* stride_pointer = NpyIter_GetInnerStrideArray(iter);
-  npy_intp* inner_size_pointer = NpyIter_GetInnerLoopSizePtr(iter);
-  do {
-    char* data = *data_pointer;
-    npy_intp stride = *stride_pointer;
-    npy_intp count = *inner_size_pointer;
-    for (size_t i = 0; i < count; ++i) {
-      PyObject* entry;
-      std::memcpy(&entry, data, sizeof(PyObject*));
-      PyObject* result = PyDict_GetItem(mapping, entry);
-      if (result != nullptr) {
-        // Replace entry.
-        Py_INCREF(result);
-        Py_XDECREF(entry);
-        std::memcpy(data, &result, sizeof(PyObject*));
-      } else if (default_value != nullptr) {
-        // Replace entry with a default value.
-        Py_INCREF(default_value);
-        Py_XDECREF(entry);
-        std::memcpy(data, &default_value, sizeof(PyObject*));
-      }
-      data += stride;
-    }
-  } while (iter_next(iter));
-
-  NpyIter_Deallocate(iter);
-  return array;
-}
-
-// Convert 1D Numpy float array to a list of strings where each string has fixed
-// number of decimal points. This is faster than Python list comprehension.
-std::vector<std::string> FormatFloatArray(absl::Span<const float> values,
-                                          int num_decimal_places) {
-  std::vector<std::string> output;
-  output.reserve(values.size());
-
-  absl::c_transform(values, std::back_inserter(output),
-                    [num_decimal_places](float value) {
-                      return absl::StrFormat("%.*f", num_decimal_places, value);
-                    });
-  return output;
-}
-
-py::array_t<bool> IsIn(
-    const py::array_t<PyObject*, py::array::c_style>& array,
-    const absl::flat_hash_set<absl::string_view>& test_elements, bool invert) {
-  const size_t num_elements = array.size();
-  py::array_t<bool> output(num_elements);
-  std::fill(output.mutable_data(), output.mutable_data() + output.size(),
-            invert);
-
-  // Shortcut: The output will be trivially always false if test_elements empty.
-  if (test_elements.empty()) {
-    return output;
-  }
-
-  for (size_t i = 0; i < num_elements; ++i) {
-    // Compare the string values instead of comparing just object pointers.
-    py::handle handle = array.data()[i];
-    if (!PyUnicode_Check(handle.ptr()) && !PyBytes_Check(handle.ptr())) {
-      continue;
-    }
-    if (test_elements.contains(py::cast<absl::string_view>(handle))) {
-      output.mutable_data()[i] = !invert;
-    }
-  }
-  if (array.ndim() > 1) {
-    auto shape =
-        std::vector<ptrdiff_t>(array.shape(), array.shape() + array.ndim());
-    return output.reshape(shape);
-  }
-  return output;
-}
-
-py::array RemapMultipleArrays(
-    const std::vector<py::array_t<PyObject*, py::array::c_style>>& arrays,
-    const py::dict& mapping) {
-  size_t array_size = arrays[0].size();
-  for (const auto& array : arrays) {
-    if (array.size() != array_size) {
-      throw py::value_error("All arrays must have the same length.");
-    }
-  }
-
-  // Create a result buffer.
-  auto result = py::array_t<int64_t>(array_size);
-  absl::Span<int64_t> result_buffer(result.mutable_data(), array_size);
-  PyObject* entry = PyTuple_New(arrays.size());
-  if (entry == nullptr) {
-    throw py::error_already_set();
-  }
-  std::vector<absl::Span<PyObject* const>> array_spans;
-  array_spans.reserve(arrays.size());
-  for (const auto& array : arrays) {
-    array_spans.emplace_back(array.data(), array.size());
-  }
-
-  // Iterate over arrays and look up elements in the `py_dict`.
-  bool fail = false;
-  for (size_t i = 0; i < array_size; ++i) {
-    for (size_t j = 0; j < array_spans.size(); ++j) {
-      PyTuple_SET_ITEM(entry, j, array_spans[j][i]);
-    }
-    PyObject* result = PyDict_GetItem(mapping.ptr(), entry);
-    if (result != nullptr) {
-      int64_t result_value = PyLong_AsLongLong(result);
-      if (result_value == -1 && PyErr_Occurred()) {
-        fail = true;
-        break;
-      }
-      if (result_value > std::numeric_limits<int64_t>::max() ||
-          result_value < std::numeric_limits<int64_t>::lowest()) {
-        PyErr_SetString(PyExc_OverflowError, "Result value too large.");
-        fail = true;
-        break;
-      }
-      result_buffer[i] = result_value;
-    } else {
-      PyErr_Format(PyExc_KeyError, "%R", entry);
-      fail = true;
-      break;
-    }
-  }
-
-  for (size_t j = 0; j < array_spans.size(); ++j) {
-    PyTuple_SET_ITEM(entry, j, nullptr);
-  }
-  Py_XDECREF(entry);
-  if (fail) {
-    throw py::error_already_set();
-  }
-  return result;
-}
-
-constexpr char kRemapNumpyArrayObjects[] = R"(
-Replace objects in NumPy array of objects using mapping.
-
-Args:
-  array: NumPy array with dtype=object.
-  mapping: Dict mapping old values to new values.
-  inplace: Bool (default False) whether to replace values inplace or to
-    create a new array.
-  default_value: If given, what value to map to if the mapping is missing
-    for that particular item. If not given, such items are left unchanged.
-
-Returns
-  NumPy array of dtype object with values replaced according to mapping.
-  If inplace is True the original array is modified inplace otherwise a
-  new array is returned.
-)";
-
-constexpr char kFormatFloatArrayDoc[] = R"(
-Converts float -> string array with given number of decimal places.
-)";
-
-constexpr char kIsInDoc[] = R"(
-Computes whether each element is in test_elements.
-
-Same use as np.isin, but much faster. If len(array) = n, len(test_elements) = m:
-* This function has complexity O(n).
-* np.isin with arrays of objects has complexity O(m*log(m) + n * log(m)).
-
-Args:
-  array: Input NumPy array with dtype=object.
-  test_elements: The values against which to test each value of array.
-  invert: If True, the values in the returned array are inverted, as if
-    calculating `element not in test_elements`. Default is False.
-    `isin(a, b, invert=True)` is equivalent to but faster than `~isin(a, b)`.
-
-Returns
-  A boolean array of the same shape as the input array. Each value `val` is:
-  * `val in test_elements` if `invert=False`,
-  * `val not in test_elements` if `invert=True`.
-)";
-
-constexpr char kRemapMultipleDoc[] = R"(
-Maps keys from multiple aligned arrays to a single array.
-
-Args:
-  arrays: Numpy arrays of the same length. The tuple of aligned entries is used
-    as key for the mapping.
-  mapping: Dict mapping from tuples to integer values.
-
-Returns
-  NumPy array of dtype `int` with values looked up in mapping according to the
-  tuple of aligned array entries as keys.
-)";
-
-}  // namespace
-
-namespace alphafold3 {
-
-void RegisterModuleStringArray(pybind11::module m) {
-  m.def(
-      "remap",
-      [](py::object array, py::object mapping, bool inplace,
-         py::object default_value) -> py::object {
-        PyObject* result = RemapNumpyArrayObjects(array.ptr(), mapping.ptr(),
-                                                  inplace, default_value.ptr());
-        if (result == nullptr) {
-          throw py::error_already_set();
-        }
-        return py::reinterpret_steal<py::object>(result);
-      },
-      py::return_value_policy::take_ownership, py::arg("array"),
-      py::arg("mapping"), py::arg("inplace") = false, py::arg("default_value"),
-      py::doc(kRemapNumpyArrayObjects + 1));
-  m.def(
-      "remap",
-      [](py::object array, py::object mapping, bool inplace) -> py::object {
-        PyObject* result = RemapNumpyArrayObjects(array.ptr(), mapping.ptr(),
-                                                  inplace, nullptr);
-        if (result == nullptr) {
-          throw py::error_already_set();
-        }
-        return py::reinterpret_steal<py::object>(result);
-      },
-      py::return_value_policy::take_ownership, py::arg("array"),
-      py::arg("mapping"), py::arg("inplace") = false,
-      py::doc(kRemapNumpyArrayObjects + 1));
-  m.def("format_float_array", &FormatFloatArray, py::arg("values"),
-        py::arg("num_decimal_places"), py::doc(kFormatFloatArrayDoc + 1),
-        py::call_guard<py::gil_scoped_release>());
-  m.def("isin", &IsIn, py::arg("array"), py::arg("test_elements"),
-        py::kw_only(), py::arg("invert") = false, py::doc(kIsInDoc + 1));
-  m.def("remap_multiple", &RemapMultipleArrays, py::arg("arrays"),
-        py::arg("mapping"), py::doc(kRemapMultipleDoc + 1));
-}
-
-}  // namespace alphafold3
diff --git a/src/alphafold3/structure/cpp/string_array_pybind.h b/src/alphafold3/structure/cpp/string_array_pybind.h
deleted file mode 100644
index 85790ddd831cd560b9340c2c8b6047e50250ec94..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/cpp/string_array_pybind.h
+++ /dev/null
@@ -1,24 +0,0 @@
-/*
- * Copyright 2024 DeepMind Technologies Limited
- *
- * AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
- * this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
- *
- * To request access to the AlphaFold 3 model parameters, follow the process set
- * out at https://github.com/google-deepmind/alphafold3. You may only use these
- * if received directly from Google. Use is subject to terms of use available at
- * https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
- */
-
-#ifndef ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_STRING_ARRAY_PYBIND_H_
-#define ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_STRING_ARRAY_PYBIND_H_
-
-#include "pybind11/pybind11.h"
-
-namespace alphafold3 {
-
-void RegisterModuleStringArray(pybind11::module m);
-
-}
-
-#endif  // ALPHAFOLD3_SRC_ALPHAFOLD3_STRUCTURE_PYTHON_STRING_ARRAY_PYBIND_H_
diff --git a/src/alphafold3/structure/mmcif.py b/src/alphafold3/structure/mmcif.py
deleted file mode 100644
index f4b6ff6c4ceefa1fea21d46dda934c9aeae12f7b..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/mmcif.py
+++ /dev/null
@@ -1,329 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Low level mmCIF parsing operations and wrappers for nicer C++/Py errors.
-
-Note that the cif_dict.CifDict class has many useful methods to help with data
-extraction which are not shown in this file. You can find them in cif_dict.clif
-together with docstrings. The cif_dict.CifDict class behaves like an immutable
-Python dictionary (some methods are not implemented though).
-"""
-from collections.abc import Callable, Mapping, Sequence
-import functools
-import itertools
-import re
-from typing import ParamSpec, TypeAlias, TypeVar
-
-from alphafold3.constants import chemical_components
-from alphafold3.cpp import cif_dict
-from alphafold3.cpp import mmcif_atom_site
-from alphafold3.cpp import mmcif_struct_conn
-from alphafold3.cpp import string_array
-import numpy as np
-
-Mmcif = cif_dict.CifDict
-
-
-_P = ParamSpec('_P')
-_T = TypeVar('_T')
-_WappedFn: TypeAlias = Callable[_P, _T]
-
-
-@functools.lru_cache(maxsize=256)
-def int_id_to_str_id(num: int) -> str:
-  """Encodes a number as a string, using reverse spreadsheet style naming.
-
-  Args:
-    num: A positive integer.
-
-  Returns:
-    A string that encodes the positive integer using reverse spreadsheet style,
-    naming e.g. 1 = A, 2 = B, ..., 27 = AA, 28 = BA, 29 = CA, ... This is the
-    usual way to encode chain IDs in mmCIF files.
-  """
-  if num <= 0:
-    raise ValueError(f'Only positive integers allowed, got {num}.')
-
-  num = num - 1  # 1-based indexing.
-  output = []
-  while num >= 0:
-    output.append(chr(num % 26 + ord('A')))
-    num = num // 26 - 1
-  return ''.join(output)
-
-
-@functools.lru_cache(maxsize=256)
-def str_id_to_int_id(str_id: str) -> int:
-  """Encodes an mmCIF-style string chain ID as an integer.
-
-  The integer IDs are one based so this function is the inverse of
-  int_id_to_str_id.
-
-  Args:
-    str_id: A string chain ID consisting only of upper case letters A-Z.
-
-  Returns:
-    An integer that can be used to order mmCIF chain IDs in the standard
-    (reverse spreadsheet style) ordering.
-  """
-  if not re.match('^[A-Z]+$', str_id):
-    raise ValueError(f'String ID must be upper case letters, got {str_id}.')
-
-  offset = ord('A') - 1
-  output = 0
-  for i, c in enumerate(str_id):
-    output += (ord(c) - offset) * int(26**i)
-  return output
-
-
-def from_string(mmcif_string: str | bytes) -> Mmcif:
-  return cif_dict.from_string(mmcif_string)
-
-
-def parse_multi_data_cif(cif_string: str) -> dict[str, Mmcif]:
-  """Parses a CIF string with multiple data records.
-
-  For instance, the CIF string:
-
-  ```
-  data_001
-  _foo bar
-  #
-  data_002
-  _foo baz
-  ```
-
-  is parsed as:
-
-  ```
-  {'001': Mmcif({'_foo': ['bar']}), '002': Mmcif({'_foo': ['baz']})}
-  ```
-
-  Args:
-    cif_string: The multi-data CIF string to be parsed.
-
-  Returns:
-    A dictionary mapping record names to Mmcif objects with data.
-  """
-  return cif_dict.parse_multi_data_cif(cif_string)
-
-
-def tokenize(mmcif_string: str) -> list[str]:
-  return cif_dict.tokenize(mmcif_string)
-
-
-def split_line(line: str) -> list[str]:
-  return cif_dict.split_line(line)
-
-
-class BondParsingError(Exception):
-  """Exception raised by errors when getting bond atom indices."""
-
-
-def get_bond_atom_indices(
-    mmcif: Mmcif,
-    model_id: str = '1',
-) -> tuple[Sequence[int], Sequence[int]]:
-  """Extracts the indices of the atoms that participate in bonds.
-
-  Args:
-    mmcif: The mmCIF object to process.
-    model_id: The ID of the model that the returned atoms will belong to. This
-      should be a value in the mmCIF's _atom_site.pdbx_PDB_model_num column.
-
-  Returns:
-    Two lists of atom indices, `from_atoms` and `to_atoms`, each one having
-    length num_bonds (as defined by _struct_conn, the bonds table). The bond
-    i, defined by the i'th row in _struct_conn, is a bond from atom at index
-    from_atoms[i], to the atom at index to_atoms[i]. The indices are simple
-    0-based indexes into the columns of the _atom_site table in the input
-    mmCIF, and do not necessarily correspond to the values in _atom_site.id,
-    or any other column.
-
-  Raises:
-    BondParsingError: If any of the required tables or columns are not present
-    in
-      the mmCIF, or if the _struct_conn table refers to atoms that cannot
-      be found in the _atom_site table.
-  """
-  try:
-    return mmcif_struct_conn.get_bond_atom_indices(mmcif, model_id)
-  except ValueError as e:
-    raise BondParsingError(str(e)) from e
-
-
-def get_or_infer_type_symbol(
-    mmcif: Mmcif, ccd: chemical_components.Ccd | None = None
-) -> Sequence[str]:
-  """Returns the type symbol (element) for all of the atoms.
-
-  Args:
-    mmcif: A parsed mmCIF file in the Mmcif format.
-    ccd: The chemical component dictionary. If not provided, defaults to the
-      cached CCD.
-
-  If present, returns the _atom_site.type_symbol. If not, infers it using
-  _atom_site.label_comp_id (residue name), _atom_site.label_atom_id (atom name)
-  and the CCD.
-  """
-  ccd = ccd or chemical_components.cached_ccd()
-  type_symbol_fn = lambda res_name, atom_name: chemical_components.type_symbol(
-      ccd, res_name, atom_name
-  )
-  return mmcif_atom_site.get_or_infer_type_symbol(mmcif, type_symbol_fn)
-
-
-def get_chain_type_by_entity_id(mmcif: Mmcif) -> Mapping[str, str]:
-  """Returns mapping from entity ID to its type or polymer type if available.
-
-  If the entity is in the _entity_poly table, returns its polymer chain type.
-  If not, returns the type as specified in the _entity table.
-
-  Args:
-    mmcif: CifDict holding the mmCIF.
-  """
-  poly_entity_id = mmcif.get('_entity_poly.entity_id', [])
-  poly_type = mmcif.get('_entity_poly.type', [])
-  poly_type_by_entity_id = dict(zip(poly_entity_id, poly_type, strict=True))
-
-  chain_type_by_entity_id = {}
-  for entity_id, entity_type in zip(
-      mmcif.get('_entity.id', []), mmcif.get('_entity.type', []), strict=True
-  ):
-    chain_type = poly_type_by_entity_id.get(entity_id) or entity_type
-    chain_type_by_entity_id[entity_id] = chain_type
-
-  return chain_type_by_entity_id
-
-
-def get_internal_to_author_chain_id_map(mmcif: Mmcif) -> Mapping[str, str]:
-  """Returns a mapping from internal chain ID to the author chain ID.
-
-  Note that this is not a bijection. One author chain ID can map to multiple
-  internal chain IDs. For example, a protein chain and a ligand bound to it will
-  share the same author chain ID, but they will each have a unique internal
-  chain ID).
-
-  Args:
-    mmcif: CifDict holding the mmCIF.
-  """
-  return mmcif_atom_site.get_internal_to_author_chain_id_map(mmcif)
-
-
-def get_experimental_method(mmcif: Mmcif) -> str | None:
-  field = '_exptl.method'
-  return ','.join(mmcif[field]).lower() if field in mmcif else None
-
-
-def get_release_date(mmcif: Mmcif) -> str | None:
-  """Returns the oldest revision date."""
-  if '_pdbx_audit_revision_history.revision_date' not in mmcif:
-    return None
-
-  # Release dates are ISO-8601, hence sort well.
-  return min(mmcif['_pdbx_audit_revision_history.revision_date'])
-
-
-def get_resolution(mmcif: Mmcif) -> float | None:
-  """Returns the resolution of the structure.
-
-  More than one resolution can be reported in an mmCIF. This function returns
-  the first one (in the order _refine.ls_d_res_high,
-  _em_3d_reconstruction.resolution, _reflns.d_resolution_high) that appears
-  in the mmCIF as is parseable as a float.
-
-  Args:
-    mmcif: An `Mmcif` object.
-
-  Returns:
-    The resolution as reported in the mmCIF.
-  """
-  for res_key in ('_refine.ls_d_res_high',
-                  '_em_3d_reconstruction.resolution',
-                  '_reflns.d_resolution_high'):
-    if res_key in mmcif:
-      try:
-        raw_resolution = mmcif[res_key][0]
-        return float(raw_resolution)
-      except ValueError:
-        continue
-  return None
-
-
-def parse_oper_expr(oper_expression: str) -> list[tuple[str, ...]]:
-  """Determines which transforms to apply based on an MMCIF oper_expression str.
-
-  Args:
-    oper_expression: the field oper_expression from MMCIF format data.
-      Transform ids may be either numbers or single letters. Hyphens are used to
-      denote a numeric range of transforms to apply, and commas are used to
-      delimit a sequence of transforms. Where two sets of parentheses are
-      adjacent without a comma, the two sets of transforms should be combined as
-      a cartesian product, i.e. all possible pairs.
-      example 1,2,3 -> generate 3 copies of each chain by applying 1, 2 or 3.
-      example (1-3) -> generate 3 copies of each chain by applying 1, 2 or 3.
-      example (1-3)(4-6) -> generate 9 copies of each chain by applying one of
-        [(1,4), (1,5), (1,6),
-         (2,4), (2,5), (2,6),
-         (3,4), (3,5), (3,6)]
-      example (P) -> apply transform with id P.
-
-  Raises:
-    ValueError: Failure to parse oper_expression.
-
-  Returns:
-    A list with one element for each chain copy that should be generated.
-    Each element is a list of transform ids to apply.
-  """
-  # Expand ranges, e.g. 1-4 -> 1,2,3,4.
-  def range_expander(match):
-    return ','.join(
-        [str(i) for i in range(int(match.group(1)),
-                               int(match.group(2)) + 1)])
-
-  ranges_expanded = re.sub(r'\b(\d+)-(\d+)', range_expander, oper_expression)
-
-  if re.fullmatch(r'(\w+,)*\w+', ranges_expanded):
-    # No brackets, just a single range, e.g. "1,2,3".
-    return [(t,) for t in ranges_expanded.split(',')]
-  elif re.fullmatch(r'\((\w+,)*\w+\)', ranges_expanded):
-    # Single range in brackets, e.g. "(1,2,3)".
-    return [(t,) for t in ranges_expanded[1:-1].split(',')]
-  elif re.fullmatch(r'\((\w+,)*\w+\)\((\w+,)*\w+\)', ranges_expanded):
-    # Cartesian product of two ranges, e.g. "(1,2,3)(4,5)".
-    part1, part2 = ranges_expanded[1:-1].split(')(')
-    return list(itertools.product(part1.split(','), part2.split(',')))
-  else:
-    raise ValueError(f'Unsupported oper_expression format: {oper_expression}')
-
-
-def format_float_array(
-    values: np.ndarray, num_decimal_places: int) -> Sequence[str]:
-  """Converts 1D array to a list of strings with the given number of decimals.
-
-  This function is faster than converting via Python list comprehension, e.g.:
-  atoms_x = ['%.3f' % x for x in atoms_x]
-
-  Args:
-    values: A numpy array with values to convert. This array is casted to
-      float32 before doing the conversion.
-    num_decimal_places: The number of decimal points to keep, including trailing
-      zeros. E.g. for 1.07 and num_decimal_places=1: 1.1,
-      num_decimal_places=2: 1.07, num_decimal_places=3: 1.070.
-
-  Returns:
-    A list of formatted strings.
-  """
-  if values.ndim != 1:
-    raise ValueError(f'The given array must be 1D, got {values.ndim}D')
-
-  return string_array.format_float_array(
-      values=values.astype(np.float32), num_decimal_places=num_decimal_places
-  )
diff --git a/src/alphafold3/structure/parsing.py b/src/alphafold3/structure/parsing.py
deleted file mode 100644
index 3b89efdaba8cb839c6decc1ff31f7f5ae4074f6e..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/parsing.py
+++ /dev/null
@@ -1,1781 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Module for parsing various data sources and producing Structures."""
-
-from collections.abc import Collection, Mapping, MutableMapping, Sequence
-import dataclasses
-import datetime
-import enum
-import functools
-import itertools
-from typing import TypeAlias
-
-from alphafold3.constants import chemical_components
-from alphafold3.constants import mmcif_names
-from alphafold3.constants import residue_names
-from alphafold3.cpp import mmcif_utils
-from alphafold3.cpp import string_array
-from alphafold3.structure import bioassemblies
-from alphafold3.structure import bonds
-from alphafold3.structure import chemical_components as struc_chem_comps
-from alphafold3.structure import mmcif
-from alphafold3.structure import structure
-from alphafold3.structure import structure_tables
-import numpy as np
-
-
-ChainIndex: TypeAlias = int
-ResIndex: TypeAlias = int
-AtomName: TypeAlias = str
-BondAtomId: TypeAlias = tuple[ChainIndex, ResIndex, AtomName]
-
-_INSERTION_CODE_REMAP: Mapping[str, str] = {'.': '?'}
-
-
-class NoAtomsError(Exception):
-  """Raise when the mmCIF does not have any atoms."""
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class BondIndices:
-  from_indices: list[int]
-  dest_indices: list[int]
-
-
-@enum.unique
-class ModelID(enum.Enum):
-  """Values for specifying model IDs when parsing."""
-
-  FIRST = 1  # The first model in the file.
-  ALL = 2  # All models in the file.
-
-
-@enum.unique
-class SequenceFormat(enum.Enum):
-  """The possible formats for an input sequence."""
-
-  FASTA = 'fasta'  # One-letter code used in FASTA.
-  CCD_CODES = 'ccd_codes'  # Multiple-letter chemical components dictionary ids.
-  LIGAND_SMILES = 'ligand_smiles'  # SMILES string defining a molecule.
-
-
-def _create_bond_lookup(
-    bonded_atom_pairs: Sequence[tuple[BondAtomId, BondAtomId]],
-) -> Mapping[tuple[ChainIndex, ResIndex], Mapping[AtomName, BondIndices]]:
-  """Creates maps to help find bonds during a loop over residues."""
-  bond_lookup = {}
-  for bond_i, (from_atom_id, dest_atom_id) in enumerate(bonded_atom_pairs):
-    from_chain_i, from_res_i, from_atom_name = from_atom_id
-    dest_chain_i, dest_res_i, dest_atom_name = dest_atom_id
-    bonds_by_from_atom_name = bond_lookup.setdefault(
-        (from_chain_i, from_res_i), {}
-    )
-    bonds_by_dest_atom_name = bond_lookup.setdefault(
-        (dest_chain_i, dest_res_i), {}
-    )
-    bonds_by_from_atom_name.setdefault(
-        from_atom_name, BondIndices(from_indices=[], dest_indices=[])
-    ).from_indices.append(bond_i)
-    bonds_by_dest_atom_name.setdefault(
-        dest_atom_name, BondIndices(from_indices=[], dest_indices=[])
-    ).dest_indices.append(bond_i)
-  return bond_lookup
-
-
-def _get_atom_element(
-    ccd: chemical_components.Ccd, res_name: str, atom_name: str
-) -> str:
-  return (
-      chemical_components.type_symbol(
-          ccd=ccd, res_name=res_name, atom_name=atom_name
-      )
-      or '?'
-  )
-
-
-def _get_representative_atom(
-    ccd: chemical_components.Ccd,
-    res_name: str,
-    chain_type: str,
-    sequence_format: SequenceFormat,
-) -> tuple[str, str]:
-  match sequence_format:
-    case SequenceFormat.CCD_CODES:
-      atom_name = _get_first_non_leaving_atom(ccd=ccd, res_name=res_name)
-      atom_element = _get_atom_element(
-          ccd=ccd, res_name=res_name, atom_name=atom_name
-      )
-      return atom_name, atom_element
-    case SequenceFormat.LIGAND_SMILES:
-      return '', '?'
-    case SequenceFormat.FASTA:
-      if chain_type in mmcif_names.PEPTIDE_CHAIN_TYPES:
-        return 'CA', 'C'
-      if chain_type in mmcif_names.NUCLEIC_ACID_CHAIN_TYPES:
-        return "C1'", 'C'
-      else:
-        raise ValueError(chain_type)
-    case _:
-      raise ValueError(sequence_format)
-
-
-@functools.lru_cache(maxsize=128)
-def _get_first_non_leaving_atom(
-    ccd: chemical_components.Ccd, res_name: str
-) -> str:
-  """Returns first definitely non-leaving atom if exists, as a stand-in."""
-  all_atoms = struc_chem_comps.get_all_atoms_in_entry(ccd, res_name=res_name)[
-      '_chem_comp_atom.atom_id'
-  ]
-  representative_atom = all_atoms[0]
-  if representative_atom == 'O1' and len(all_atoms) > 1:
-    representative_atom = all_atoms[1]
-  return representative_atom
-
-
-def _add_ligand_to_chem_comp(
-    chem_comp: MutableMapping[str, struc_chem_comps.ChemCompEntry],
-    ligand_id: str,
-    ligand_smiles: str,
-):
-  """Adds a ligand to chemical components. Raises ValueError on mismatch."""
-  new_entry = struc_chem_comps.ChemCompEntry(
-      type='non-polymer', pdbx_smiles=ligand_smiles
-  )
-
-  existing_entry = chem_comp.get(ligand_id)
-  if existing_entry is None:
-    chem_comp[ligand_id] = new_entry
-  elif existing_entry != new_entry:
-    raise ValueError(
-        f'Mismatching data for ligand {ligand_id}: '
-        f'{new_entry} != {existing_entry}'
-    )
-
-
-def _get_first_model_id(cif: mmcif.Mmcif) -> str:
-  """Returns cheaply the first model ID from the mmCIF."""
-  return cif.get_array(
-      '_atom_site.pdbx_PDB_model_num', dtype=object, gather=slice(1)
-  )[0]
-
-
-def _get_str_model_id(
-    cif: mmcif.Mmcif,
-    model_id: ModelID | int,
-) -> str:
-  """Converts a user-specified model_id argument into a string."""
-  match model_id:
-    case int():
-      str_model_id = str(model_id)
-    case enum.Enum():
-      # We compare the enum's value attribute since regular enum comparison
-      # breaks when adhoc importing.
-      match model_id.value:
-        case ModelID.FIRST.value:
-          try:
-            str_model_id = _get_first_model_id(cif)
-          except IndexError as e:
-            raise NoAtomsError(
-                'The mmCIF does not have any atoms or'
-                ' _atom_site.pdbx_PDB_model_num is missing.'
-            ) from e
-        case ModelID.ALL.value:
-          str_model_id = ''
-        case _:
-          raise ValueError(
-              f'Model ID {model_id} with value {model_id.value} not recognized.'
-          )
-    case _:
-      raise ValueError(
-          f'Model ID {model_id} with type {type(model_id)} not recognized.'
-      )
-  return str_model_id
-
-
-def _parse_bonds(
-    cif: mmcif.Mmcif,
-    atom_key: np.ndarray,
-    model_id: str,
-) -> bonds.Bonds:
-  """Returns the bonds table extracted from the mmCIF.
-
-  Args:
-    cif: The raw mmCIF to extract the bond information from.
-    atom_key: A numpy array defining atom key for each atom in _atom_site. Note
-      that the atom key must be computed before resolving alt-locs since this
-      function operates on the raw mmCIF!
-    model_id: The ID of the model to get bonds for.
-  """
-  if '_struct_conn.id' not in cif:
-    # This is the category key item for the _struct_conn table, therefore
-    # we use it to determine whether to parse bond info.
-    return bonds.Bonds.make_empty()
-  from_atom, dest_atom = mmcif.get_bond_atom_indices(cif, model_id)
-  from_atom = np.array(from_atom, dtype=np.int64)
-  dest_atom = np.array(dest_atom, dtype=np.int64)
-  num_bonds = from_atom.shape[0]
-  bond_key = np.arange(num_bonds, dtype=np.int64)
-  bond_type = cif.get_array('_struct_conn.conn_type_id', dtype=object)
-  if '_struct_conn.pdbx_role' in cif:  # This column isn't always present.
-    bond_role = cif.get_array('_struct_conn.pdbx_role', dtype=object)
-  else:
-    bond_role = np.full((num_bonds,), '?', dtype=object)
-
-  bonds_mask = np.ones((num_bonds,), dtype=bool)
-  # Symmetries other than 1_555 imply the atom is not part of the asymmetric
-  # unit, and therefore this is a bond that only exists in the expanded
-  # bioassembly.
-  # We do not currently support parsing these types of bonds.
-  if '_struct_conn.ptnr1_symmetry' in cif:
-    ptnr1_symmetry = cif.get_array('_struct_conn.ptnr1_symmetry', dtype=object)
-    np.logical_and(bonds_mask, ptnr1_symmetry == '1_555', out=bonds_mask)
-  if '_struct_conn.ptnr2_symmetry' in cif:
-    ptnr2_symmetry = cif.get_array('_struct_conn.ptnr2_symmetry', dtype=object)
-    np.logical_and(bonds_mask, ptnr2_symmetry == '1_555', out=bonds_mask)
-  # Remove bonds that involve atoms that are not part of the structure,
-  # e.g. waters if include_water=False. In a rare case this also removes invalid
-  # bonds that are indicated by a key that is set to _atom_site size.
-  np.logical_and(bonds_mask, np.isin(from_atom, atom_key), out=bonds_mask)
-  np.logical_and(bonds_mask, np.isin(dest_atom, atom_key), out=bonds_mask)
-  return bonds.Bonds(
-      key=bond_key[bonds_mask],
-      type=bond_type[bonds_mask],
-      role=bond_role[bonds_mask],
-      from_atom_key=from_atom[bonds_mask],
-      dest_atom_key=dest_atom[bonds_mask],
-  )
-
-
-@dataclasses.dataclass(frozen=True, slots=True)
-class _MmcifHeader:
-  name: str
-  resolution: float | None
-  release_date: datetime.date | None
-  structure_method: str | None
-  bioassembly_data: bioassemblies.BioassemblyData | None
-  chemical_components_data: struc_chem_comps.ChemicalComponentsData | None
-
-
-def _get_mmcif_header(
-    cif: mmcif.Mmcif,
-    fix_mse: bool,
-    fix_unknown_dna: bool,
-) -> _MmcifHeader:
-  """Extract header fields from an mmCIF object."""
-  entry_id = cif.get('_entry.id')
-  name = entry_id[0] if entry_id else cif.get_data_name()
-  resolution = mmcif.get_resolution(cif)
-
-  release_date = mmcif.get_release_date(cif)
-  if release_date is not None:
-    release_date = datetime.date.fromisoformat(release_date)
-
-  experiments = cif.get('_exptl.method')
-  structure_method = ','.join(experiments) if experiments else None
-
-  try:
-    bioassembly_data = bioassemblies.BioassemblyData.from_mmcif(cif)
-  except bioassemblies.MissingBioassemblyDataError:
-    bioassembly_data = None
-
-  try:
-    chemical_components_data = (
-        struc_chem_comps.ChemicalComponentsData.from_mmcif(
-            cif, fix_mse=fix_mse, fix_unknown_dna=fix_unknown_dna
-        )
-    )
-  except struc_chem_comps.MissingChemicalComponentsDataError:
-    chemical_components_data = None
-
-  return _MmcifHeader(
-      name=name,
-      resolution=resolution,
-      release_date=release_date,
-      structure_method=structure_method,
-      bioassembly_data=bioassembly_data,
-      chemical_components_data=chemical_components_data,
-  )
-
-
-def from_parsed_mmcif(
-    mmcif_object: mmcif.Mmcif,
-    *,
-    name: str | None = None,
-    fix_mse_residues: bool = False,
-    fix_arginines: bool = False,
-    fix_unknown_dna: bool = False,
-    include_water: bool = False,
-    include_other: bool = False,
-    include_bonds: bool = False,
-    model_id: int | ModelID = ModelID.FIRST,
-) -> structure.Structure:
-  """Construct a Structure from a parsed mmCIF object.
-
-  This function is called by `from_mmcif` but can be useful when an mmCIF has
-  already been parsed e.g. to extract extra information from the header before
-  then converting to Structure for further manipulation.
-
-  Args:
-    mmcif_object: A parsed mmcif.Mmcif object.
-    name: Optional name for the structure. If not provided, the name will be
-      taken from the mmCIF data_ field.
-    fix_mse_residues: If True, selenium atom sites (SE) in selenomethionine
-      (MSE) residues will be changed to sulphur atom sites (SD). This is because
-      methionine (MET) residues are often replaced with MSE to aid X-Ray
-      crystallography. If False, the SE MSE atom sites won't be modified.
-    fix_arginines: If True, NH1 and NH2 in arginine will be swapped if needed so
-      that NH1 is always closer to CD than NH2. If False, no atom sites in
-      arginine will be touched. Note that HH11, HH12, HH21, HH22 are fixed too.
-    fix_unknown_dna: If True, residues with name N in DNA chains will have their
-      res_name replaced with DN. Atoms are not changed.
-    include_water: If True, water (HOH) molecules will be parsed. Water
-      molecules may be grouped into chains, where number of residues > 1. Water
-      molecules are usually grouped into chains but do not necessarily all share
-      the same chain ID.
-    include_other: If True, all other atoms that are not included by any of the
-      above parameters will be included. This covers e.g. "polypeptide(D)" and
-      "macrolide" entities, as well as all other non-standard types.
-    include_bonds: If True, bond information will be parsed from the mmCIF and
-      stored in the Structure.
-    model_id: Either the integer model ID to parse, or one of ModelID.FIRST to
-      parse the first model, or ModelID.ALL to parse all models.
-
-  Returns:
-    A Structure representation of the mmCIF object.
-  """
-  str_model_id = _get_str_model_id(cif=mmcif_object, model_id=model_id)
-  header = _get_mmcif_header(
-      mmcif_object, fix_mse=fix_mse_residues, fix_unknown_dna=fix_unknown_dna
-  )
-
-  chains, residues, atoms = get_tables(
-      cif=mmcif_object,
-      fix_mse_residues=fix_mse_residues,
-      fix_arginines=fix_arginines,
-      fix_unknown_dna=fix_unknown_dna,
-      include_water=include_water,
-      include_other=include_other,
-      model_id=str_model_id,
-  )
-
-  if include_bonds and atoms.size > 0:
-    # NB: parsing the atom table before the bonds table allows for a more
-    # informative error message when dealing with bad multi-model mmCIFs.
-    # Also always use a specific model ID, even when parsing all models.
-    if str_model_id == '':  # pylint: disable=g-explicit-bool-comparison
-      bonds_model_id = _get_first_model_id(mmcif_object)
-    else:
-      bonds_model_id = str_model_id
-
-    bonds_table = _parse_bonds(
-        mmcif_object,
-        atom_key=atoms.key,
-        model_id=bonds_model_id,
-    )
-  else:
-    bonds_table = bonds.Bonds.make_empty()
-
-  return structure.Structure(
-      name=name if name is not None else header.name,
-      resolution=header.resolution,
-      release_date=header.release_date,
-      structure_method=header.structure_method,
-      bioassembly_data=header.bioassembly_data,
-      chemical_components_data=header.chemical_components_data,
-      bonds=bonds_table,
-      chains=chains,
-      residues=residues,
-      atoms=atoms,
-  )
-
-
-def from_mmcif(
-    mmcif_string: str | bytes,
-    *,
-    name: str | None = None,
-    fix_mse_residues: bool = False,
-    fix_arginines: bool = False,
-    fix_unknown_dna: bool = False,
-    include_water: bool = False,
-    include_other: bool = False,
-    include_bonds: bool = False,
-    model_id: int | ModelID = ModelID.FIRST,
-) -> structure.Structure:
-  """Construct a Structure from a mmCIF string.
-
-  Args:
-    mmcif_string: The string contents of an mmCIF file.
-    name: Optional name for the structure. If not provided, the name will be
-      taken from the mmCIF data_ field.
-    fix_mse_residues: If True, selenium atom sites (SE) in selenomethionine
-      (MSE) residues will be changed to sulphur atom sites (SD). This is because
-      methionine (MET) residues are often replaced with MSE to aid X-Ray
-      crystallography. If False, the SE MSE atom sites won't be modified.
-    fix_arginines: If True, NH1 and NH2 in arginine will be swapped if needed so
-      that NH1 is always closer to CD than NH2. If False, no atom sites in
-      arginine will be touched. Note that HH11, HH12, HH21, HH22 are fixed too.
-    fix_unknown_dna: If True, residues with name N in DNA chains will have their
-      res_name replaced with DN. Atoms are not changed.
-    include_water: If True, water (HOH) molecules will be parsed. Water
-      molecules may be grouped into chains, where number of residues > 1. Water
-      molecules are usually grouped into chains but do not necessarily all share
-      the same chain ID.
-    include_other: If True, all other atoms that are not included by any of the
-      above parameters will be included. This covers e.g. "polypeptide(D)" and
-      "macrolide" entities, as well as all other non-standard types.
-    include_bonds: If True, bond information will be parsed from the mmCIF and
-      stored in the Structure.
-    model_id: Either the integer model ID to parse, or one of ModelID.FIRST to
-      parse the first model, or ModelID.ALL to parse all models.
-
-  Returns:
-    A Structure representation of the mmCIF string.
-  """
-  mmcif_object = mmcif.from_string(mmcif_string)
-
-  return from_parsed_mmcif(
-      mmcif_object,
-      name=name,
-      fix_mse_residues=fix_mse_residues,
-      fix_arginines=fix_arginines,
-      fix_unknown_dna=fix_unknown_dna,
-      include_water=include_water,
-      include_other=include_other,
-      include_bonds=include_bonds,
-      model_id=model_id,
-  )
-
-
-def from_res_arrays(atom_mask: np.ndarray, **kwargs) -> structure.Structure:
-  """Returns Structure created from from arrays with a residue dimension.
-
-  All unset fields are filled with defaults (e.g. 1.0 for occupancy) or
-  unset/unknown values (e.g. UNK for residue type, or '.' for atom element).
-
-  Args:
-    atom_mask: A array with shape (num_res, num_atom). This is used to decide
-      which atoms in the atom dimension are present in a given residue. Present
-      atoms should have a nonzero value, e.g. 1.0 or True.
-    **kwargs: A mapping from field name to values. For all array-valued fields
-      these arrays must have a dimension of length num_res. Chain and residue
-      fields should have this as their only dimension and atom fields should be
-      shaped (num_res, num_atom). Coordinate fields may also have arbitrary
-      leading dimensions (they must be the same across all coordinate fields).
-      See structure.{CHAIN,RESIDUE,ATOM}_FIELDS for a list of allowed fields.
-  """
-  num_res, num_atom = atom_mask.shape
-  included_indices = np.flatnonzero(atom_mask)
-
-  array_fields = (
-      structure.CHAIN_FIELDS.keys()
-      | structure.RESIDUE_FIELDS.keys()
-      | structure.ATOM_FIELDS.keys()
-  )
-  initializer_kwargs = {}
-  fields = {}
-  for k, val in kwargs.items():
-    if k not in array_fields:
-      # The kwarg key isn't an array field name. Such kwargs are forwarded as-is
-      # to the constructor. They are expected to be global fields (e.g. name).
-      # Other values will raise an error when the constructor is called.
-      if k in structure.TABLE_FIELDS:
-        raise ValueError(f'Table fields must not be set. Got {k}.')
-      initializer_kwargs[k] = val
-      continue
-    elif val is None:
-      raise ValueError(f'{k} must be non-None.')
-
-    if not isinstance(val, np.ndarray):
-      raise TypeError(f'Value for {k} must be a NumPy array. Got {type(val)}.')
-    if k in structure.CHAIN_FIELDS or k in structure.RESIDUE_FIELDS:
-      if val.shape != (num_res,):
-        raise ValueError(
-            f'{k} must have shape ({num_res=},). Got {val.shape=}.'
-        )
-      # Do not reshape the chain/residue arrays, they have the shape we need.
-      fields[k] = val
-    else:
-      assert k in structure.ATOM_FIELDS
-      if val.shape[-2:] != (num_res, num_atom):
-        raise ValueError(
-            f'{k} must have final two dimensions of length '
-            f'{(num_res, num_atom)=}. Got {val.shape=}.'
-        )
-      leading_dims = val.shape[:-2]
-      flat_val = val.reshape(leading_dims + (-1,), order='C')
-      masked_val = flat_val[..., included_indices]
-      fields[k] = masked_val
-
-  # Get chain IDs or assume this is a single-chain structure.
-  chain_id = kwargs.get('chain_id', np.array(['A'] * num_res, dtype=object))
-  # Find chain starts in res-sized arrays, use these to make chain-sized arrays.
-  chain_start = np.concatenate(
-      ([0], np.where(chain_id[1:] != chain_id[:-1])[0] + 1)
-  )
-  if len(set(chain_id)) != len(chain_start):
-    raise ValueError(f'Chain IDs must be contiguous, but got {chain_id}')
-
-  chain_lengths = np.diff(chain_start, append=len(chain_id))
-  chain_key = np.repeat(np.arange(len(chain_start)), chain_lengths)
-
-  chain_entity_id = fields.get('chain_entity_id')
-  if chain_entity_id is not None:
-    entity_id = chain_entity_id[chain_start]
-  else:
-    entity_id = np.array(
-        [str(mmcif.str_id_to_int_id(cid)) for cid in chain_id[chain_start]],
-        dtype=object,
-    )
-  chain_str_empty = np.full((num_res,), '.', dtype=object)
-  chains_table = structure_tables.Chains(
-      key=chain_key[chain_start],
-      id=chain_id[chain_start],
-      type=fields.get('chain_type', chain_str_empty)[chain_start],
-      auth_asym_id=fields.get('chain_auth_asym_id', chain_id)[chain_start],
-      entity_id=entity_id,
-      entity_desc=fields.get('chain_entity_desc', chain_str_empty)[chain_start],
-  )
-
-  # Since all arrays are residue-shaped, we can use them directly.
-  res_key = np.arange(num_res, dtype=np.int64)
-  res_id = fields.get('res_id', res_key + 1).astype(np.int32)
-  residues_table = structure_tables.Residues(
-      key=res_key,
-      chain_key=chain_key,
-      id=res_id,
-      name=fields.get('res_name', np.full(num_res, 'UNK', dtype=object)),
-      auth_seq_id=fields.get(
-          'res_auth_seq_id', np.char.mod('%d', res_id).astype(object)
-      ),
-      insertion_code=fields.get(
-          'res_insertion_code', np.full(num_res, '?', dtype=object)
-      ),
-  )
-
-  # The atom-sized arrays have already been masked and reshaped.
-  num_atoms_per_res = np.sum(atom_mask, axis=1, dtype=np.int32)
-  num_atoms_total = np.sum(num_atoms_per_res, dtype=np.int32)
-  # Structure is immutable, so use the same array multiple times to save RAM.
-  atom_str_empty = np.full(num_atoms_total, '.', dtype=object)
-  atom_float32_zeros = np.zeros(num_atoms_total, dtype=np.float32)
-  atom_float32_ones = np.ones(num_atoms_total, dtype=np.float32)
-  atoms_table = structure_tables.Atoms(
-      key=np.arange(num_atoms_total, dtype=np.int64),
-      chain_key=np.repeat(chain_key, num_atoms_per_res),
-      res_key=np.repeat(res_key, num_atoms_per_res),
-      name=fields.get('atom_name', atom_str_empty),
-      element=fields.get('atom_element', atom_str_empty),
-      x=fields.get('atom_x', atom_float32_zeros),
-      y=fields.get('atom_y', atom_float32_zeros),
-      z=fields.get('atom_z', atom_float32_zeros),
-      b_factor=fields.get('atom_b_factor', atom_float32_zeros),
-      occupancy=fields.get('atom_occupancy', atom_float32_ones),
-  )
-
-  return structure.Structure(
-      chains=chains_table,
-      residues=residues_table,
-      atoms=atoms_table,
-      bonds=structure_tables.Bonds.make_empty(),  # Currently not set.
-      **initializer_kwargs,
-  )
-
-
-def expand_sequence(
-    sequence: str, chain_type: str, sequence_format: SequenceFormat
-) -> Sequence[str]:
-  """Returns full residue names based on a sequence string.
-
-  Args:
-    sequence: A string representing the sequence.
-    chain_type: The chain type of the sequence.
-    sequence_format: The format of the sequence argument.
-  """
-  match sequence_format:
-    case SequenceFormat.FASTA:
-      if not all(c.isalpha() for c in sequence):
-        raise ValueError(f'Sequence "{sequence}" has non-alphabetic characters')
-      match chain_type:
-        case mmcif_names.PROTEIN_CHAIN:
-          res_name_map = residue_names.PROTEIN_COMMON_ONE_TO_THREE
-          default_res_name = residue_names.UNK
-        case mmcif_names.RNA_CHAIN:
-          res_name_map = {r: r for r in residue_names.RNA_TYPES}
-          default_res_name = residue_names.UNK_RNA
-        case mmcif_names.DNA_CHAIN:
-          res_name_map = residue_names.DNA_COMMON_ONE_TO_TWO
-          default_res_name = residue_names.UNK_DNA
-        case _:
-          raise ValueError(f'{chain_type=} not supported for FASTA format.')
-      return [
-          res_name_map.get(one_letter_res, default_res_name)
-          for one_letter_res in sequence
-      ]
-    case SequenceFormat.CCD_CODES:
-      return sequence.strip('()').split(')(')
-    case SequenceFormat.LIGAND_SMILES:
-      ligand_id, _ = sequence.split(':', maxsplit=1)
-      return [ligand_id]
-
-
-def from_sequences_and_bonds(
-    sequences: Sequence[str],
-    chain_types: Sequence[str],
-    sequence_formats: Sequence[SequenceFormat],
-    bonded_atom_pairs: Sequence[tuple[BondAtomId, BondAtomId]] | None,
-    ccd: chemical_components.Ccd,
-    name: str = 'from_sequences_and_bonds',
-    bond_type: str | None = None,
-    **constructor_args,
-) -> structure.Structure:
-  """Returns a minimal structure for the input sequences and bonds.
-
-  The returned structure will have at least one atom per residue. If the
-  residue has any bonded atoms, according to `bonded_atom_pairs`, then
-  all (and only) those atoms will be present for that residue. If the residue
-  is not involved in any bond then an arbitrary atom will be created.
-
-  Args:
-    sequences: A sequence of strings, each one representing a single chain.
-    chain_types: The types of each chain, e.g. polypeptide(L). The n-th element
-      describes the n-th sequence in `sequences`.
-    sequence_formats: The format of each sequence. The n-th element describes
-      the n-th sequence in `sequences`.
-    bonded_atom_pairs: A sequence of bonded atom pairs. Each atom is described
-      as a tuple of (chain_index, res_index, atom_name), where the first two
-      values are 0-based indices. The chain_index is the index of the chain in
-      the `sequences` argument, and the res_index is the index of the residue in
-      that sequence. The atom_name is the name of the atom in the residue, e.g.
-      CA. If the atom is not found in the standard atoms for that residue
-      (according to the CCD) then an error is raised.
-    ccd: The chemical components dictionary.
-    name: A name for the returned structure.
-    bond_type: This type will be used for all bonds in the structure, where type
-      follows PDB scheme, e.g. unknown (?), hydrog, metalc, covale, disulf.
-    **constructor_args: These arguments are passed directly to the
-      structure.Structure constructor.
-  """
-  chain_id = []
-  chain_type = []
-  chain_res_count = []
-  res_id = []
-  res_name = []
-  res_atom_count = []
-  atom_name = []
-  atom_element = []
-  chem_comp = {}
-
-  num_bonds = len(bonded_atom_pairs or ())
-  from_atom_key = np.full((num_bonds,), -1, dtype=np.int64)
-  dest_atom_key = np.full((num_bonds,), -1, dtype=np.int64)
-
-  # Create map (chain_i, res_i) -> {atom_name -> (from_idxs dest_idxs)}.
-  # This allows quick lookup of whether a residue has any bonded atoms, and
-  # which bonds those atoms participate in.
-  bond_lookup = _create_bond_lookup(bonded_atom_pairs or ())
-
-  current_atom_key = 0
-  for chain_i, (sequence, curr_chain_type, sequence_format) in enumerate(
-      zip(sequences, chain_types, sequence_formats, strict=True)
-  ):
-    current_chain_id = mmcif.int_id_to_str_id(chain_i + 1)
-    num_chain_residues = 0
-    for res_i, full_res_name in enumerate(
-        expand_sequence(sequence, curr_chain_type, sequence_format)
-    ):
-      current_res_id = res_i + 1
-      num_res_atoms = 0
-
-      # Look for bonded atoms in the bond lookup and if any are found, add
-      # their atom keys to the bond atom_key columns.
-      if bond_indices_by_atom_name := bond_lookup.get((chain_i, res_i)):
-        for bond_atom_name, bond_indices in bond_indices_by_atom_name.items():
-          atom_name.append(bond_atom_name)
-          atom_element.append(
-              _get_atom_element(
-                  ccd=ccd, res_name=full_res_name, atom_name=bond_atom_name
-              )
-          )
-          for from_bond_i in bond_indices.from_indices:
-            from_atom_key[from_bond_i] = current_atom_key
-          for dest_bond_i in bond_indices.dest_indices:
-            dest_atom_key[dest_bond_i] = current_atom_key
-          current_atom_key += 1
-          num_res_atoms += 1
-      else:
-        # If this residue has no bonded atoms then we need to add one atom
-        # like in from_sequences.
-        assert num_res_atoms == 0
-        rep_atom_name, rep_atom_element = _get_representative_atom(
-            ccd=ccd,
-            res_name=full_res_name,
-            chain_type=curr_chain_type,
-            sequence_format=sequence_format,
-        )
-        atom_name.append(rep_atom_name)
-        atom_element.append(rep_atom_element)
-        num_res_atoms += 1
-        current_atom_key += 1
-
-      if sequence_format == SequenceFormat.LIGAND_SMILES:
-        # Sequence expect to be in the format <ligand_id>:<ligand_smiles>,
-        # which always corresponds to a single-residue chain.
-        ligand_id, ligand_smiles = sequence.split(':', maxsplit=1)
-        if ccd.get(ligand_id) is not None:
-          raise ValueError(
-              f'Ligand name {ligand_id} is in CCD - it is not supported to give'
-              ' ligands created from SMILES the same name as CCD components.'
-          )
-        # We need to provide additional chemical components metadata for
-        # ligands specified via SMILES strings since they might not be in CCD.
-        _add_ligand_to_chem_comp(chem_comp, ligand_id, ligand_smiles)
-
-      assert num_res_atoms >= 1
-      res_atom_count.append(num_res_atoms)
-      num_chain_residues += 1
-      res_id.append(current_res_id)
-      res_name.append(full_res_name)
-
-    chain_id.append(current_chain_id)
-    chain_type.append(curr_chain_type)
-    chain_res_count.append(num_chain_residues)
-
-  chem_comp_data = struc_chem_comps.ChemicalComponentsData(chem_comp)
-  chem_comp_data = struc_chem_comps.populate_missing_ccd_data(
-      ccd=ccd,
-      chemical_components_data=chem_comp_data,
-      chemical_component_ids=set(res_name),
-  )
-
-  if bonded_atom_pairs is not None:
-    unknown_bond_col = np.full((num_bonds,), '?', dtype=object)
-    if bond_type is None:
-      bond_type_col = unknown_bond_col
-    else:
-      bond_type_col = np.full((num_bonds,), bond_type, dtype=object)
-    bonds_table = bonds.Bonds(
-        key=np.arange(num_bonds, dtype=np.int64),
-        type=bond_type_col,
-        role=unknown_bond_col,
-        from_atom_key=from_atom_key,
-        dest_atom_key=dest_atom_key,
-    )
-  else:
-    bonds_table = structure_tables.Bonds.make_empty()
-
-  chain_key = np.arange(len(sequences), dtype=np.int64)  # 1 chain per sequence.
-  chain_id = np.array(chain_id, dtype=object)
-  chains_table = structure_tables.Chains(
-      key=chain_key,
-      id=chain_id,
-      type=np.array(chain_type, dtype=object),
-      auth_asym_id=chain_id,
-      entity_id=np.char.mod('%d', chain_key + 1).astype(object),
-      entity_desc=np.array(['.'] * len(chain_key), dtype=object),
-  )
-
-  res_key = np.arange(len(res_name), dtype=np.int64)
-  res_chain_key = np.repeat(chain_key, chain_res_count)
-  residues_table = structure_tables.Residues(
-      key=res_key,
-      chain_key=res_chain_key,
-      id=np.array(res_id, dtype=np.int32),
-      name=np.array(res_name, dtype=object),
-      auth_seq_id=np.char.mod('%d', res_id).astype(object),
-      insertion_code=np.full(len(res_name), '?', dtype=object),
-  )
-
-  num_atoms = current_atom_key
-  atom_float32_zeros = np.zeros(num_atoms, dtype=np.float32)
-  atoms_table = structure_tables.Atoms(
-      key=np.arange(num_atoms, dtype=np.int64),
-      chain_key=np.repeat(res_chain_key, res_atom_count),
-      res_key=np.repeat(res_key, res_atom_count),
-      name=np.array(atom_name, dtype=object),
-      element=np.array(atom_element, dtype=object),
-      x=atom_float32_zeros,
-      y=atom_float32_zeros,
-      z=atom_float32_zeros,
-      b_factor=atom_float32_zeros,
-      occupancy=np.ones(num_atoms, np.float32),
-  )
-
-  return structure.Structure(
-      name=name,
-      atoms=atoms_table,
-      residues=residues_table,
-      chains=chains_table,
-      bonds=bonds_table,
-      chemical_components_data=chem_comp_data,
-      **constructor_args,
-  )
-
-
-class _ChainResBuilder:
-  """Class for incrementally building chain and residue tables."""
-
-  def __init__(
-      self,
-      *,
-      chain_key_by_chain_id: Mapping[str, int],
-      entity_id_by_chain_id: Mapping[str, str],
-      chain_type_by_entity_id: Mapping[str, str],
-      entity_desc_by_entity_id: Mapping[str, str],
-      fix_mse_residues: bool,
-      fix_unknown_dna: bool,
-  ):
-    # Len: num_chains.
-    self.chain_key = []
-    self.chain_id = []
-    self.chain_type = []
-    self.chain_auth_asym_id = []
-    self.chain_entity_id = []
-    self.chain_entity_desc = []
-
-    # Len: num_residues.
-    self.res_key = []
-    self.res_chain_key = []
-    self.res_id = []
-    self.res_name = []
-    self.res_auth_seq_id = []
-    self.res_insertion_code = []
-
-    self.chain_key_by_chain_id = chain_key_by_chain_id
-    self.entity_id_by_chain_id = entity_id_by_chain_id
-    self.chain_type_by_entity_id = chain_type_by_entity_id
-    self.entity_desc_by_entity_id = entity_desc_by_entity_id
-    self.key_for_res: dict[tuple[str, str, str, str], int] = {}
-
-    self._fix_mse_residues = fix_mse_residues
-    self._fix_unknown_dna = fix_unknown_dna
-
-  def add_residues(
-      self,
-      *,
-      chain_ids: np.ndarray,
-      chain_auth_asym_ids: np.ndarray,
-      res_ids: np.ndarray,
-      res_names: np.ndarray,
-      res_auth_seq_ids: np.ndarray,
-      res_ins_codes: np.ndarray,
-  ):
-    """Adds a residue (and its chain) to the tables."""
-    # Create chain table data.
-    if chain_ids.size == 0:
-      return
-
-    chain_ids_with_prev = np.concatenate(
-        (([self.chain_id[-1] if self.chain_id else None], chain_ids))
-    )
-    chain_change_mask = chain_ids_with_prev[:-1] != chain_ids_with_prev[1:]
-    chain_change_ids = chain_ids[chain_change_mask]
-    chain_keys = string_array.remap(
-        chain_change_ids, self.chain_key_by_chain_id, inplace=False
-    )
-    self.chain_key.extend(chain_keys)
-    self.chain_id.extend(chain_change_ids)
-    self.chain_auth_asym_id.extend(chain_auth_asym_ids[chain_change_mask])
-    chain_entity_id = string_array.remap(
-        chain_change_ids, self.entity_id_by_chain_id, inplace=False
-    )
-    self.chain_entity_id.extend(chain_entity_id)
-    chain_type = string_array.remap(
-        chain_entity_id, self.chain_type_by_entity_id, inplace=False
-    )
-    self.chain_type.extend(chain_type)
-    chain_entity_desc = string_array.remap(
-        chain_entity_id, self.entity_desc_by_entity_id, inplace=False
-    )
-    self.chain_entity_desc.extend(chain_entity_desc)
-
-    # Create residue table data.
-    num_prev_res = len(self.res_id)
-    res_keys = np.arange(num_prev_res, num_prev_res + len(res_ids))
-    res_iter = zip(
-        chain_ids,
-        res_auth_seq_ids,
-        res_names,
-        res_ins_codes,
-        strict=True,
-    )
-    key_for_res_update = {
-        res_unique_id: res_key
-        for res_key, res_unique_id in enumerate(res_iter, num_prev_res)
-    }
-    self.key_for_res.update(key_for_res_update)
-    self.res_key.extend(res_keys)
-    self.res_chain_key.extend(
-        string_array.remap(chain_ids, self.chain_key_by_chain_id, inplace=False)
-    )
-    self.res_id.extend(res_ids)
-    self.res_name.extend(res_names)
-    self.res_auth_seq_id.extend(res_auth_seq_ids)
-    self.res_insertion_code.extend(res_ins_codes)
-
-  def make_chains_table(self) -> structure_tables.Chains:
-    """Returns the Structure chains table."""
-    chain_key = np.array(self.chain_key, dtype=np.int64)
-    if not np.all(chain_key[:-1] <= chain_key[1:]):
-      # If the order is inconsistent with the atoms table, sort so that it is.
-      order = np.argsort(self.chain_key, kind='stable')
-      return structure_tables.Chains(
-          key=chain_key[order],
-          id=np.array(self.chain_id, dtype=object)[order],
-          type=np.array(self.chain_type, dtype=object)[order],
-          auth_asym_id=np.array(self.chain_auth_asym_id, dtype=object)[order],
-          entity_id=np.array(self.chain_entity_id, dtype=object)[order],
-          entity_desc=np.array(self.chain_entity_desc, dtype=object)[order],
-      )
-    return structure_tables.Chains(
-        key=chain_key,
-        id=np.array(self.chain_id, dtype=object),
-        type=np.array(self.chain_type, dtype=object),
-        auth_asym_id=np.array(self.chain_auth_asym_id, dtype=object),
-        entity_id=np.array(self.chain_entity_id, dtype=object),
-        entity_desc=np.array(self.chain_entity_desc, dtype=object),
-    )
-
-  def make_residues_table(self) -> structure_tables.Residues:
-    """Returns the Structure residues table."""
-    res_name = np.array(self.res_name, dtype=object)
-    res_chain_key = np.array(self.res_chain_key, dtype=np.int64)
-
-    if self._fix_mse_residues:
-      string_array.remap(res_name, mapping={'MSE': 'MET'}, inplace=True)
-
-    if self._fix_unknown_dna:
-      # Remap residues from N -> DN in DNA chains only.
-      dna_chain_mask = (
-          np.array(self.chain_type, dtype=object) == mmcif_names.DNA_CHAIN
-      )
-      dna_chain_key = np.array(self.chain_key, dtype=object)[dna_chain_mask]
-      res_name[(res_name == 'N') & np.isin(res_chain_key, dna_chain_key)] = 'DN'
-
-    if not np.all(res_chain_key[:-1] <= res_chain_key[1:]):
-      # If the order is inconsistent with the atoms table, sort so that it is.
-      order = np.argsort(res_chain_key, kind='stable')
-      return structure_tables.Residues(
-          key=np.array(self.res_key, dtype=np.int64)[order],
-          chain_key=res_chain_key[order],
-          id=np.array(self.res_id, dtype=np.int32)[order],
-          name=res_name[order],
-          auth_seq_id=np.array(self.res_auth_seq_id, dtype=object)[order],
-          insertion_code=np.array(self.res_insertion_code, dtype=object)[order],
-      )
-    return structure_tables.Residues(
-        key=np.array(self.res_key, dtype=np.int64),
-        chain_key=res_chain_key,
-        id=np.array(self.res_id, dtype=np.int32),
-        name=res_name,
-        auth_seq_id=np.array(self.res_auth_seq_id, dtype=object),
-        insertion_code=np.array(self.res_insertion_code, dtype=object),
-    )
-
-
-def _get_string_array_default(cif: mmcif.Mmcif, key: str, default: list[str]):
-  try:
-    return cif.get_array(key, dtype=object)
-  except KeyError:
-    return default
-
-
-def _generate_required_tables_if_missing(
-    cif: mmcif.Mmcif,
-) -> Mapping[str, Sequence[str]]:
-  """Generates all required tables and columns if missing."""
-  update = {}
-
-  atom_site_entities = _get_string_array_default(
-      cif, '_atom_site.label_entity_id', []
-  )
-
-  # OpenMM produces files that don't have any of the tables and also have
-  # _atom_site.label_entity_id set to '?' for all atoms. We infer the entities
-  # based on the _atom_site.label_asym_id column. We start with cheaper O(1)
-  # checks to prevent running the expensive O(n) check on most files.
-  if (
-      len(atom_site_entities) > 0  # pylint: disable=g-explicit-length-test
-      and '_entity.id' not in cif  # Ignore if the _entity table exists.
-      and atom_site_entities[0] == '?'  # Cheap check.
-      and set(atom_site_entities) == {'?'}  # Expensive check.
-  ):
-    label_asym_ids = cif.get_array('_atom_site.label_asym_id', dtype=object)
-    atom_site_entities = [
-        str(mmcif.str_id_to_int_id(cid)) for cid in label_asym_ids
-    ]
-    # Update _atom_site.label_entity_id to be consistent with the new tables.
-    update['_atom_site.label_entity_id'] = atom_site_entities
-
-  # Check table existence by checking the presence of its primary key.
-  if '_struct_asym.id' not in cif:
-    # Infer the _struct_asym table using the _atom_site table.
-    asym_ids = _get_string_array_default(cif, '_atom_site.label_asym_id', [])
-
-    if len(atom_site_entities) == 0 or len(asym_ids) == 0:  # pylint: disable=g-explicit-length-test
-      raise ValueError(
-          'Could not parse an mmCIF with no _struct_asym table and also no '
-          '_atom_site.label_entity_id or _atom_site.label_asym_id columns.'
-      )
-
-    # Deduplicate, but keep the order intact - dict.fromkeys maintains order.
-    entity_id_chain_id_pairs = list(
-        dict.fromkeys(zip(atom_site_entities, asym_ids, strict=True))
-    )
-    update['_struct_asym.entity_id'] = [e for e, _ in entity_id_chain_id_pairs]
-    update['_struct_asym.id'] = [c for _, c in entity_id_chain_id_pairs]
-
-  if '_entity.id' not in cif:
-    # Infer the _entity_poly and _entity tables using the _atom_site table.
-    residues = _get_string_array_default(cif, '_atom_site.label_comp_id', [])
-    group_pdb = _get_string_array_default(cif, '_atom_site.group_PDB', [])
-    if '_atom_site.label_entity_id' in cif:
-      entities = atom_site_entities
-    else:
-      # If _atom_site.label_entity_id not set, use the asym_id -> entity_id map.
-      asym_to_entity = dict(
-          zip(
-              cif['_struct_asym.id'], cif['_struct_asym.entity_id'], strict=True
-          )
-      )
-      entities = string_array.remap(
-          cif.get_array('_atom_site.label_asym_id', dtype=object),
-          mapping=asym_to_entity,
-      )
-
-    entity_ids = []
-    entity_types = []
-    entity_poly_entity_ids = []
-    entity_poly_types = []
-    entity_poly_table_missing = '_entity_poly.entity_id' not in cif
-    for entity_id, group in itertools.groupby(
-        zip(entities, residues, group_pdb, strict=True), key=lambda e: e[0]
-    ):
-      _, entity_residues, entity_group_pdb = zip(*group, strict=True)
-      entity_type = _guess_entity_type(
-          chain_residues=entity_residues, atom_types=entity_group_pdb
-      )
-      entity_ids.append(entity_id)
-      entity_types.append(entity_type)
-
-      if entity_poly_table_missing and entity_type == mmcif_names.POLYMER_CHAIN:
-        polymer_type = mmcif_names.guess_polymer_type(entity_residues)
-        entity_poly_entity_ids.append(entity_id)
-        entity_poly_types.append(polymer_type)
-
-    update['_entity.id'] = entity_ids
-    update['_entity.type'] = entity_types
-    if entity_poly_table_missing:
-      update['_entity_poly.entity_id'] = entity_poly_entity_ids
-      update['_entity_poly.type'] = entity_poly_types
-
-  if '_atom_site.type_symbol' not in cif:
-    update['_atom_site.type_symbol'] = mmcif.get_or_infer_type_symbol(cif)
-
-  return update
-
-
-def _maybe_add_missing_scheme_tables(
-    cif: mmcif.Mmcif,
-    res_starts: Sequence[int],
-    label_asym_ids: np.ndarray,
-    label_seq_ids: np.ndarray,
-    label_comp_ids: np.ndarray,
-    auth_seq_ids: np.ndarray,
-    pdb_ins_codes: np.ndarray,
-) -> Mapping[str, Sequence[str]]:
-  """If missing, infers the scheme tables from the _atom_site table."""
-  update = {}
-
-  required_poly_seq_scheme_cols = (
-      '_pdbx_poly_seq_scheme.asym_id',
-      '_pdbx_poly_seq_scheme.pdb_seq_num',
-      '_pdbx_poly_seq_scheme.pdb_ins_code',
-      '_pdbx_poly_seq_scheme.seq_id',
-      '_pdbx_poly_seq_scheme.mon_id',
-      '_pdbx_poly_seq_scheme.pdb_strand_id',
-  )
-  if not all(col in cif for col in required_poly_seq_scheme_cols):
-    # Create a mask for atoms where each polymer residue start.
-    entity_id_by_chain_id = dict(
-        zip(cif['_struct_asym.id'], cif['_struct_asym.entity_id'], strict=True)
-    )
-    chain_type_by_entity_id = dict(
-        zip(cif['_entity.id'], cif['_entity.type'], strict=True)
-    )
-    # Remap asym ID -> entity ID.
-    chain_type = string_array.remap(
-        label_asym_ids, mapping=entity_id_by_chain_id, inplace=False
-    )
-    # Remap entity ID -> chain type.
-    string_array.remap(
-        chain_type, mapping=chain_type_by_entity_id, inplace=True
-    )
-    res_mask = np.zeros_like(label_seq_ids, dtype=bool)
-    res_mask[res_starts] = True
-    res_mask &= chain_type == mmcif_names.POLYMER_CHAIN
-
-    entity_poly_seq_cols = (
-        '_entity_poly_seq.entity_id',
-        '_entity_poly_seq.num',
-        '_entity_poly_seq.mon_id',
-    )
-    if all(col in cif for col in entity_poly_seq_cols):
-      # Use _entity_poly_seq if available.
-      poly_seq_num = cif.get_array('_entity_poly_seq.num', dtype=object)
-      poly_seq_mon_id = cif.get_array('_entity_poly_seq.mon_id', dtype=object)
-      poly_seq_entity_id = cif.get_array(
-          '_entity_poly_seq.entity_id', dtype=object
-      )
-      label_seq_id_to_auth_seq_id = dict(
-          zip(label_seq_ids[res_mask], auth_seq_ids[res_mask], strict=True)
-      )
-      scheme_pdb_seq_num = string_array.remap(
-          poly_seq_num, mapping=label_seq_id_to_auth_seq_id, default_value='.'
-      )
-      label_seq_id_to_ins_code = dict(
-          zip(label_seq_ids[res_mask], pdb_ins_codes[res_mask], strict=True)
-      )
-      scheme_pdb_ins_code = string_array.remap(
-          poly_seq_num, mapping=label_seq_id_to_ins_code, default_value='.'
-      )
-
-      # The _entity_poly_seq table is entity-based, while _pdbx_poly_seq_scheme
-      # is chain-based. A single entity could mean multiple chains (asym_ids),
-      # we therefore need to replicate each entity for all of the chains.
-      scheme_asym_id = []
-      select = []
-      indices = np.arange(len(poly_seq_entity_id), dtype=np.int32)
-      for asym_id, entity_id in zip(
-          cif['_struct_asym.id'], cif['_struct_asym.entity_id'], strict=True
-      ):
-        entity_mask = poly_seq_entity_id == entity_id
-        select.extend(indices[entity_mask])
-        scheme_asym_id.extend([asym_id] * sum(entity_mask))
-
-      scheme_pdb_strand_id = string_array.remap(
-          np.array(scheme_asym_id, dtype=object),
-          mapping=mmcif.get_internal_to_author_chain_id_map(cif),
-          inplace=False,
-      )
-
-      update['_pdbx_poly_seq_scheme.asym_id'] = scheme_asym_id
-      update['_pdbx_poly_seq_scheme.pdb_strand_id'] = scheme_pdb_strand_id
-      update['_pdbx_poly_seq_scheme.pdb_seq_num'] = scheme_pdb_seq_num[select]
-      update['_pdbx_poly_seq_scheme.pdb_ins_code'] = scheme_pdb_ins_code[select]
-      update['_pdbx_poly_seq_scheme.seq_id'] = poly_seq_num[select]
-      update['_pdbx_poly_seq_scheme.mon_id'] = poly_seq_mon_id[select]
-    else:
-      # _entity_poly_seq not available, fallback to _atom_site.
-      res_asym_ids = label_asym_ids[res_mask]
-      res_strand_ids = string_array.remap(
-          array=res_asym_ids,
-          mapping=mmcif.get_internal_to_author_chain_id_map(cif),
-          inplace=False,
-      )
-      update['_pdbx_poly_seq_scheme.asym_id'] = res_asym_ids
-      update['_pdbx_poly_seq_scheme.pdb_seq_num'] = auth_seq_ids[res_mask]
-      update['_pdbx_poly_seq_scheme.pdb_ins_code'] = pdb_ins_codes[res_mask]
-      update['_pdbx_poly_seq_scheme.seq_id'] = label_seq_ids[res_mask]
-      update['_pdbx_poly_seq_scheme.mon_id'] = label_comp_ids[res_mask]
-      update['_pdbx_poly_seq_scheme.pdb_strand_id'] = res_strand_ids
-
-  required_nonpoly_scheme_cols = (
-      '_pdbx_nonpoly_scheme.mon_id',
-      '_pdbx_nonpoly_scheme.asym_id',
-      '_pdbx_nonpoly_scheme.pdb_seq_num',
-      '_pdbx_nonpoly_scheme.pdb_ins_code',
-  )
-  required_branch_scheme_cols = (
-      '_pdbx_branch_scheme.mon_id',
-      '_pdbx_branch_scheme.asym_id',
-      '_pdbx_branch_scheme.pdb_seq_num',
-  )
-
-  # Generate _pdbx_nonpoly_scheme only if both tables are missing.
-  if not (
-      all(col in cif for col in required_nonpoly_scheme_cols)
-      or all(col in cif for col in required_branch_scheme_cols)
-  ):
-    # To be strictly semantically correct, multi-residue ligands should be
-    # written in _pdbx_branch_scheme. However, Structure parsing handles
-    # correctly multi-residue ligands in _pdbx_nonpoly_scheme and the tables
-    # constructed here live only while parsing, hence this is unnecessary.
-    entity_id_by_chain_id = dict(
-        zip(cif['_struct_asym.id'], cif['_struct_asym.entity_id'], strict=True)
-    )
-    chain_type_by_entity_id = dict(
-        zip(cif['_entity.id'], cif['_entity.type'], strict=True)
-    )
-    # Remap asym ID -> entity ID.
-    chain_type = string_array.remap(
-        label_asym_ids, mapping=entity_id_by_chain_id, inplace=False
-    )
-    # Remap entity ID -> chain type.
-    string_array.remap(
-        chain_type, mapping=chain_type_by_entity_id, inplace=True
-    )
-    res_mask = np.zeros_like(label_seq_ids, dtype=bool)
-    res_mask[res_starts] = True
-    res_mask &= chain_type != mmcif_names.POLYMER_CHAIN
-
-    if not np.any(res_mask):
-      return update  # Shortcut: no non-polymer residues.
-
-    ins_codes = string_array.remap(
-        pdb_ins_codes[res_mask], mapping={'?': '.'}, inplace=False
-    )
-
-    update['_pdbx_nonpoly_scheme.asym_id'] = label_asym_ids[res_mask]
-    update['_pdbx_nonpoly_scheme.pdb_seq_num'] = auth_seq_ids[res_mask]
-    update['_pdbx_nonpoly_scheme.pdb_ins_code'] = ins_codes
-    update['_pdbx_nonpoly_scheme.mon_id'] = label_comp_ids[res_mask]
-
-  return update
-
-
-def _get_chain_key_by_chain_id(
-    resolved_chain_ids: np.ndarray, struct_asym_chain_ids: np.ndarray
-) -> Mapping[str, int]:
-  """Returns chain key for each chain ID respecting resolved chain ordering."""
-  # Check that all chain IDs found in the (potentially filtered) _atom_site
-  # table are present in the _struct_asym table.
-  unique_resolved_chain_ids = set(resolved_chain_ids)
-  if not unique_resolved_chain_ids.issubset(set(struct_asym_chain_ids)):
-    unique_resolved_chain_ids = sorted(unique_resolved_chain_ids)
-    unique_struct_asym_chain_ids = sorted(set(struct_asym_chain_ids))
-    raise ValueError(
-        'Bad mmCIF: chain IDs in _atom_site.label_asym_id '
-        f'{unique_resolved_chain_ids} is not a subset of chain IDs in '
-        f'_struct_asym.id {unique_struct_asym_chain_ids}.'
-    )
-
-  resolved_mask = string_array.isin(
-      struct_asym_chain_ids, unique_resolved_chain_ids
-  )
-  # For all resolved chains, use the _atom_site order they appear in. E.g.
-  # resolved_chain_ids     = [B A   E D F]
-  # struct_asym_chain_ids  = [A B C D E F]
-  # consistent_chain_order = [B A C E D F]
-  # chain_keys             = [0 1 2 3 4 5]
-  consistent_chain_order = struct_asym_chain_ids.copy()
-  consistent_chain_order[resolved_mask] = resolved_chain_ids
-  return dict(zip(consistent_chain_order, range(len(struct_asym_chain_ids))))
-
-
-def get_tables(
-    cif: mmcif.Mmcif,
-    fix_mse_residues: bool,
-    fix_arginines: bool,
-    fix_unknown_dna: bool,
-    include_water: bool,
-    include_other: bool,
-    model_id: str,
-) -> tuple[
-    structure_tables.Chains, structure_tables.Residues, structure_tables.Atoms
-]:
-  """Returns chain, residue, and atom tables from a parsed mmcif.
-
-  Args:
-    cif: A parsed mmcif.Mmcif.
-    fix_mse_residues: See from_mmcif.
-    fix_arginines: See from_mmcif.
-    fix_unknown_dna: See from_mmcif.
-    include_water: See from_mmcif.
-    include_other: See from_mmcif.
-    model_id: A string defining which model ID to use. If set, only coordinates,
-      b-factors and occupancies for the given model are returned. If empty,
-      coordinates, b-factors and occupanciesall for models are returned with a
-      leading dimension of num_models. Note that the model_id argument in
-      from_mmcif is an integer and has slightly different use (see from_mmcif).
-  """
-  # Add any missing tables and columns we require for parsing.
-  if cif_update := _generate_required_tables_if_missing(cif):
-    cif = cif.copy_and_update(cif_update)
-
-  # Resolve alt-locs, selecting only a single option for each residue. Also
-  # computes the layout, which defines where chain and residue boundaries are.
-  atom_site_all_models, layout = mmcif_utils.filter(
-      cif,
-      include_nucleotides=True,
-      include_ligands=True,
-      include_water=include_water,
-      include_other=include_other,
-      model_id=model_id,
-  )
-  atom_site_first_model = atom_site_all_models[0]
-
-  # Get atom information from the _atom_site table.
-  def _first_model_string_array(col: str) -> np.ndarray:
-    return cif.get_array(col, dtype=object, gather=atom_site_first_model)
-
-  def _requested_models_float_array(col: str) -> np.ndarray:
-    if not model_id:
-      # Return data for all models with a leading dimension of num_models.
-      return cif.get_array(col, dtype=np.float32, gather=atom_site_all_models)
-    else:
-      # Return data only for the single requested model.
-      return cif.get_array(col, dtype=np.float32, gather=atom_site_first_model)
-
-  # These columns are the same for all models, fetch them just for the 1st one.
-  label_comp_ids = _first_model_string_array('_atom_site.label_comp_id')
-  label_asym_ids = _first_model_string_array('_atom_site.label_asym_id')
-  label_seq_ids = _first_model_string_array('_atom_site.label_seq_id')
-  label_atom_ids = _first_model_string_array('_atom_site.label_atom_id')
-  if '_atom_site.auth_seq_id' in cif:
-    auth_seq_ids = _first_model_string_array('_atom_site.auth_seq_id')
-  else:
-    auth_seq_ids = label_seq_ids  # auth_seq_id unset, fallback to label_seq_id.
-  type_symbols = _first_model_string_array('_atom_site.type_symbol')
-  pdbx_pdb_ins_codes = _first_model_string_array('_atom_site.pdbx_PDB_ins_code')
-
-  # These columns are different for all models, fetch them as requested.
-  atom_x = _requested_models_float_array('_atom_site.Cartn_x')
-  atom_y = _requested_models_float_array('_atom_site.Cartn_y')
-  atom_z = _requested_models_float_array('_atom_site.Cartn_z')
-  atom_b_factor = _requested_models_float_array('_atom_site.B_iso_or_equiv')
-  atom_occupancy = _requested_models_float_array('_atom_site.occupancy')
-
-  # Make sure the scheme (residue) tables exist in case they are not present.
-  if cif_update := _maybe_add_missing_scheme_tables(
-      cif,
-      res_starts=layout.residue_starts(),
-      label_asym_ids=label_asym_ids,
-      label_seq_ids=label_seq_ids,
-      label_comp_ids=label_comp_ids,
-      auth_seq_ids=auth_seq_ids,
-      pdb_ins_codes=pdbx_pdb_ins_codes,
-  ):
-    cif = cif.copy_and_update(cif_update)
-
-  # Fix common issues found in mmCIF files, like swapped arginine NH atoms.
-  mmcif_utils.fix_residues(
-      layout,
-      comp_id=label_comp_ids,
-      atom_id=label_atom_ids,
-      atom_x=atom_x[0] if not model_id else atom_x,
-      atom_y=atom_y[0] if not model_id else atom_y,
-      atom_z=atom_z[0] if not model_id else atom_z,
-      fix_arg=fix_arginines,
-  )
-
-  # Get keys for chains in the order they appear in _atom_site while also
-  # dealing with empty chains.
-  resolved_chain_ids = label_asym_ids[layout.chain_starts()]
-  struct_asym_chain_ids = cif.get_array('_struct_asym.id', dtype=object)
-
-  chain_key_by_chain_id = _get_chain_key_by_chain_id(
-      resolved_chain_ids=resolved_chain_ids,
-      struct_asym_chain_ids=struct_asym_chain_ids,
-  )
-  entity_id_by_chain_id = dict(
-      zip(struct_asym_chain_ids, cif['_struct_asym.entity_id'], strict=True)
-  )
-  entity_description = cif.get(
-      '_entity.pdbx_description', ['?'] * len(cif['_entity.id'])
-  )
-  entity_desc_by_entity_id = dict(
-      zip(cif['_entity.id'], entity_description, strict=True)
-  )
-  chain_type_by_entity_id = mmcif.get_chain_type_by_entity_id(cif)
-  auth_asym_id_by_chain_id = mmcif.get_internal_to_author_chain_id_map(cif)
-
-  chain_res_builder = _ChainResBuilder(
-      chain_key_by_chain_id=chain_key_by_chain_id,
-      entity_id_by_chain_id=entity_id_by_chain_id,
-      chain_type_by_entity_id=chain_type_by_entity_id,
-      entity_desc_by_entity_id=entity_desc_by_entity_id,
-      fix_mse_residues=fix_mse_residues,
-      fix_unknown_dna=fix_unknown_dna,
-  )
-
-  # Collect data for polymer chain and residue tables. _pdbx_poly_seq_scheme is
-  # guaranteed to be present thanks to _maybe_add_missing_scheme_tables.
-  def _get_poly_seq_scheme_col(col: str) -> np.ndarray:
-    return cif.get_array(key=f'_pdbx_poly_seq_scheme.{col}', dtype=object)
-
-  poly_seq_asym_ids = _get_poly_seq_scheme_col('asym_id')
-  poly_seq_pdb_seq_nums = _get_poly_seq_scheme_col('pdb_seq_num')
-  poly_seq_seq_ids = _get_poly_seq_scheme_col('seq_id')
-  poly_seq_mon_ids = _get_poly_seq_scheme_col('mon_id')
-  poly_seq_pdb_strand_ids = _get_poly_seq_scheme_col('pdb_strand_id')
-  poly_seq_pdb_ins_codes = _get_poly_seq_scheme_col('pdb_ins_code')
-  string_array.remap(
-      poly_seq_pdb_ins_codes, mapping=_INSERTION_CODE_REMAP, inplace=True
-  )
-
-  # We resolved alt-locs earlier for the atoms table. In cases of heterogeneous
-  # residues (a residue with an alt-loc that is of different residue type), we
-  # need to also do the same resolution in the residues table. Compute a mask
-  # for the residues that were selected in the atoms table.
-  poly_seq_mask = mmcif_utils.selected_polymer_residue_mask(
-      layout=layout,
-      atom_site_label_asym_ids=label_asym_ids[layout.residue_starts()],
-      atom_site_label_seq_ids=label_seq_ids[layout.residue_starts()],
-      atom_site_label_comp_ids=label_comp_ids[layout.residue_starts()],
-      poly_seq_asym_ids=poly_seq_asym_ids,
-      poly_seq_seq_ids=poly_seq_seq_ids,
-      poly_seq_mon_ids=poly_seq_mon_ids,
-  )
-
-  if not include_other and poly_seq_mask:
-    # Mask filtered-out residues so that they are not treated as missing.
-    # Instead, we don't want them included in the chains/residues tables at all.
-    keep_mask = string_array.remap(
-        poly_seq_asym_ids,
-        mapping={cid: True for cid in resolved_chain_ids},
-        default_value=False,
-        inplace=False,
-    ).astype(bool)
-    poly_seq_mask &= keep_mask
-
-  chain_res_builder.add_residues(
-      chain_ids=poly_seq_asym_ids[poly_seq_mask],
-      chain_auth_asym_ids=poly_seq_pdb_strand_ids[poly_seq_mask],
-      res_ids=poly_seq_seq_ids[poly_seq_mask].astype(np.int32),
-      res_names=poly_seq_mon_ids[poly_seq_mask],
-      res_auth_seq_ids=poly_seq_pdb_seq_nums[poly_seq_mask],
-      res_ins_codes=poly_seq_pdb_ins_codes[poly_seq_mask],
-  )
-
-  # Collect data for ligand chain and residue tables. _pdbx_nonpoly_scheme
-  # could be empty/unset if there are only branched ligands.
-  def _get_nonpoly_scheme_col(col: str) -> np.ndarray:
-    key = f'_pdbx_nonpoly_scheme.{col}'
-    if f'_pdbx_nonpoly_scheme.{col}' in cif:
-      return cif.get_array(key=key, dtype=object)
-    else:
-      return np.array([], dtype=object)
-
-  nonpoly_asym_ids = _get_nonpoly_scheme_col('asym_id')
-  nonpoly_auth_seq_ids = _get_nonpoly_scheme_col('pdb_seq_num')
-  nonpoly_pdb_ins_codes = _get_nonpoly_scheme_col('pdb_ins_code')
-  nonpoly_mon_ids = _get_nonpoly_scheme_col('mon_id')
-  nonpoly_auth_asym_id = string_array.remap(
-      nonpoly_asym_ids, mapping=auth_asym_id_by_chain_id, inplace=False
-  )
-
-  def _get_branch_scheme_col(col: str) -> np.ndarray:
-    key = f'_pdbx_branch_scheme.{col}'
-    if f'_pdbx_branch_scheme.{col}' in cif:
-      return cif.get_array(key=key, dtype=object)
-    else:
-      return np.array([], dtype=object)
-
-  branch_asym_ids = _get_branch_scheme_col('asym_id')
-  branch_auth_seq_ids = _get_branch_scheme_col('pdb_seq_num')
-  branch_pdb_ins_codes = _get_branch_scheme_col('pdb_ins_code')
-  branch_mon_ids = _get_branch_scheme_col('mon_id')
-  branch_auth_asym_id = string_array.remap(
-      branch_asym_ids, mapping=auth_asym_id_by_chain_id, inplace=False
-  )
-
-  if branch_asym_ids.size > 0 and branch_pdb_ins_codes.size == 0:
-    branch_pdb_ins_codes = np.array(['.'] * branch_asym_ids.size, dtype=object)
-
-  # Compute the heterogeneous residue masks as above, this time for ligands.
-  nonpoly_mask, branch_mask = mmcif_utils.selected_ligand_residue_mask(
-      layout=layout,
-      atom_site_label_asym_ids=label_asym_ids[layout.residue_starts()],
-      atom_site_label_seq_ids=label_seq_ids[layout.residue_starts()],
-      atom_site_auth_seq_ids=auth_seq_ids[layout.residue_starts()],
-      atom_site_label_comp_ids=label_comp_ids[layout.residue_starts()],
-      atom_site_pdbx_pdb_ins_codes=pdbx_pdb_ins_codes[layout.residue_starts()],
-      nonpoly_asym_ids=nonpoly_asym_ids,
-      nonpoly_auth_seq_ids=nonpoly_auth_seq_ids,
-      nonpoly_pdb_ins_codes=nonpoly_pdb_ins_codes,
-      nonpoly_mon_ids=nonpoly_mon_ids,
-      branch_asym_ids=branch_asym_ids,
-      branch_auth_seq_ids=branch_auth_seq_ids,
-      branch_pdb_ins_codes=branch_pdb_ins_codes,
-      branch_mon_ids=branch_mon_ids,
-  )
-
-  if not include_water:
-    if nonpoly_mask:
-      nonpoly_mask &= (nonpoly_mon_ids != 'HOH') & (nonpoly_mon_ids != 'DOD')
-    if branch_mask:
-      # Fix for bad mmCIFs that have water in the branch scheme table.
-      branch_mask &= (branch_mon_ids != 'HOH') & (branch_mon_ids != 'DOD')
-
-  string_array.remap(
-      pdbx_pdb_ins_codes, mapping=_INSERTION_CODE_REMAP, inplace=True
-  )
-  string_array.remap(
-      nonpoly_pdb_ins_codes, mapping=_INSERTION_CODE_REMAP, inplace=True
-  )
-  string_array.remap(
-      branch_pdb_ins_codes, mapping=_INSERTION_CODE_REMAP, inplace=True
-  )
-
-  def _ligand_residue_ids(chain_ids: np.ndarray) -> np.ndarray:
-    """Computes internal residue ID for ligand residues that don't have it."""
-
-    # E.g. chain_ids=[A, A, A, B, C, C, D, D, D] -> [1, 2, 3, 1, 1, 2, 1, 2, 3].
-    indices = np.arange(chain_ids.size, dtype=np.int32)
-    return (indices + 1) - np.maximum.accumulate(
-        indices * (chain_ids != np.roll(chain_ids, 1))
-    )
-
-  branch_residue_ids = _ligand_residue_ids(branch_asym_ids[branch_mask])
-  nonpoly_residue_ids = _ligand_residue_ids(nonpoly_asym_ids[nonpoly_mask])
-
-  chain_res_builder.add_residues(
-      chain_ids=branch_asym_ids[branch_mask],
-      chain_auth_asym_ids=branch_auth_asym_id[branch_mask],
-      res_ids=branch_residue_ids,
-      res_names=branch_mon_ids[branch_mask],
-      res_auth_seq_ids=branch_auth_seq_ids[branch_mask],
-      res_ins_codes=branch_pdb_ins_codes[branch_mask],
-  )
-
-  chain_res_builder.add_residues(
-      chain_ids=nonpoly_asym_ids[nonpoly_mask],
-      chain_auth_asym_ids=nonpoly_auth_asym_id[nonpoly_mask],
-      res_ids=nonpoly_residue_ids,
-      res_names=nonpoly_mon_ids[nonpoly_mask],
-      res_auth_seq_ids=nonpoly_auth_seq_ids[nonpoly_mask],
-      res_ins_codes=nonpoly_pdb_ins_codes[nonpoly_mask],
-  )
-
-  chains = chain_res_builder.make_chains_table()
-  residues = chain_res_builder.make_residues_table()
-
-  # Construct foreign residue keys for the atoms table.
-  res_ends = np.array(layout.residues(), dtype=np.int32)
-  res_starts = np.array(layout.residue_starts(), dtype=np.int32)
-  res_lengths = res_ends - res_starts
-
-  # Check just for HOH, DOD can be part e.g. of hydroxycysteine.
-  if include_water:
-    res_chain_types = chains.apply_array_to_column(
-        column_name='type', arr=residues.chain_key
-    )
-    water_mask = res_chain_types != mmcif_names.WATER
-    if 'HOH' in set(residues.name[water_mask]):
-      raise ValueError('Bad mmCIF file: non-water entity has water molecules.')
-  else:
-    # Include resolved and unresolved residues.
-    if 'HOH' in set(residues.name) | set(label_comp_ids[res_starts]):
-      raise ValueError('Bad mmCIF file: non-water entity has water molecules.')
-
-  atom_chain_key = string_array.remap(
-      label_asym_ids, mapping=chain_res_builder.chain_key_by_chain_id
-  ).astype(int)
-
-  # If any of the residue lookups failed, the mmCIF is corrupted.
-  try:
-    atom_res_key_per_res = string_array.remap_multiple(
-        (
-            label_asym_ids[res_starts],
-            auth_seq_ids[res_starts],
-            label_comp_ids[res_starts],
-            pdbx_pdb_ins_codes[res_starts],
-        ),
-        mapping=chain_res_builder.key_for_res,
-    )
-  except KeyError as e:
-    raise ValueError(
-        'Lookup for the following atom from the _atom_site table failed: '
-        f'(atom_id, auth_seq_id, res_name, ins_code)={e}. This is '
-        'likely due to a known issue with some multi-model mmCIFs that only '
-        'match the first model in _atom_site table to the _pdbx_poly_scheme, '
-        '_pdbx_nonpoly_scheme, or _pdbx_branch_scheme tables.'
-    ) from e
-
-  # The residue ID will be shared for all atoms within that residue.
-  atom_res_key = np.repeat(atom_res_key_per_res, repeats=res_lengths)
-
-  if fix_mse_residues:
-    met_residues_mask = (residues.name == 'MET')[atom_res_key]
-    unfixed_mse_selenium_mask = met_residues_mask & (label_atom_ids == 'SE')
-    label_atom_ids[unfixed_mse_selenium_mask] = 'SD'
-    type_symbols[unfixed_mse_selenium_mask] = 'S'
-
-  atoms = structure_tables.Atoms(
-      key=atom_site_first_model,
-      chain_key=atom_chain_key,
-      res_key=atom_res_key,
-      name=label_atom_ids,
-      element=type_symbols,
-      x=atom_x,
-      y=atom_y,
-      z=atom_z,
-      b_factor=atom_b_factor,
-      occupancy=atom_occupancy,
-  )
-
-  return chains, residues, atoms
-
-
-def from_atom_arrays(
-    *,
-    res_id: np.ndarray,
-    name: str = 'unset',
-    release_date: datetime.date | None = None,
-    resolution: float | None = None,
-    structure_method: str | None = None,
-    all_residues: Mapping[str, Sequence[tuple[str, int]]] | None = None,
-    bioassembly_data: bioassemblies.BioassemblyData | None = None,
-    chemical_components_data: (
-        struc_chem_comps.ChemicalComponentsData | None
-    ) = None,
-    bond_table: structure_tables.Bonds | None = None,
-    chain_id: np.ndarray | None = None,
-    chain_type: np.ndarray | None = None,
-    res_name: np.ndarray | None = None,
-    atom_key: np.ndarray | None = None,
-    atom_name: np.ndarray | None = None,
-    atom_element: np.ndarray | None = None,
-    atom_x: np.ndarray | None = None,
-    atom_y: np.ndarray | None = None,
-    atom_z: np.ndarray | None = None,
-    atom_b_factor: np.ndarray | None = None,
-    atom_occupancy: np.ndarray | None = None,
-) -> structure.Structure:
-  """Returns a Structure constructed from atom array level data.
-
-  All fields except name and, res_id are optional, all array fields consist of a
-  value for each atom in the structure - so residue and chain values should hold
-  the same value for each atom in the chain or residue. Fields which are not
-  defined are filled with default values.
-
-  Validation is performed by the Structure constructor where possible - but
-  author_naming scheme and all_residues must be checked in this function.
-
-  It is not possible to construct structures with chains that do not contain
-  any resolved residues using this function. If this is necessary, use the
-  structure.Structure constructor directly.
-
-  Args:
-    res_id: Integer array of shape [num_atom]. The unique residue identifier for
-      each residue. mmCIF field - _atom_site.label_seq_id.
-    name: The name of the structure. E.g. a PDB ID.
-    release_date: The release date of the structure as a `datetime.date`.
-    resolution: The resolution of the structure in Angstroms.
-    structure_method: The method used to solve this structure's coordinates.
-    all_residues: An optional mapping from each chain ID (i.e. label_asym_id) to
-      a sequence of (label_comp_id, label_seq_id) tuples, one per residue. This
-      can contain residues that aren't present in the atom arrays. This is
-      common in experimental data where some residues are not resolved but are
-      known to be present.
-    bioassembly_data: An optional instance of bioassembly.BioassemblyData. If
-      present then a new Structure representing a specific bioassembly can be
-      extracted using `Structure.generate_bioassembly(assembly_id)`.
-    chemical_components_data: An optional instance of ChemicalComponentsData.
-      Its content will be used for providing metadata about chemical components
-      in this Structure instance. If not specified information will be retrieved
-      from the standard chemical component dictionary (CCD, for more details see
-      https://www.wwpdb.org/data/ccd).
-    bond_table: A table representing manually-specified bonds. This corresponds
-      to the _struct_conn table in an mmCIF. Atoms are identified by their key,
-      as specified by the atom_key column. If this table is provided then the
-      atom_key column must also be defined.
-    chain_id: String array of shape [num_atom] of unique chain identifiers.
-      mmCIF field - _atom_site.label_asym_id.
-    chain_type: String array of shape [num_atom]. The molecular type of the
-      current chain (e.g. polyribonucleotide). mmCIF field - _entity_poly.type
-      OR _entity.type (for non-polymers).
-    res_name: String array of shape [num_atom].. The name of each residue,
-      typically a 3 letter string for polypeptides or 1-2 letter strings for
-      polynucleotides. mmCIF field - _atom_site.label_comp_id.
-    atom_key: A unique sorted integer array, used only by the bonds table to
-      identify the atoms participating in each bond. If the bonds table is
-      specified then this column must be non-None.
-    atom_name: String array of shape [num_atom]. The name of each atom (e.g CA,
-      O2', etc.). mmCIF field - _atom_site.label_atom_id.
-    atom_element: String array of shape [num_atom]. The element type of each
-      atom (e.g. C, O, N, etc.). mmCIF field - _atom_site.type_symbol.
-    atom_x: Float array of shape [..., num_atom] of atom x coordinates. May have
-      arbitrary leading dimensions, provided that these are consistent across
-      all coordinate fields.
-    atom_y: Float array of shape [..., num_atom] of atom y coordinates. May have
-      arbitrary leading dimensions, provided that these are consistent across
-      all coordinate fields.
-    atom_z: Float array of shape [..., num_atom] of atom z coordinates. May have
-      arbitrary leading dimensions, provided that these are consistent across
-      all coordinate fields.
-    atom_b_factor: Float array of shape [..., num_atom] or [num_atom] of atom
-      b-factors or equivalent. If there are no extra leading dimensions then
-      these values are assumed to apply to all coordinates for a given atom. If
-      there are leading dimensions then these must match those used by the
-      coordinate fields.
-    atom_occupancy: Float array of shape [..., num_atom] or [num_atom] of atom
-      occupancies or equivalent. If there are no extra leading dimensions then
-      these values are assumed to apply to all coordinates for a given atom. If
-      there are leading dimensions then these must match those used by the
-      coordinate fields.
-  """
-
-  atoms, residues, chains = structure_tables.tables_from_atom_arrays(
-      res_id=res_id,
-      all_residues=all_residues,
-      chain_id=chain_id,
-      chain_type=chain_type,
-      res_name=res_name,
-      atom_key=atom_key,
-      atom_name=atom_name,
-      atom_element=atom_element,
-      atom_x=atom_x,
-      atom_y=atom_y,
-      atom_z=atom_z,
-      atom_b_factor=atom_b_factor,
-      atom_occupancy=atom_occupancy,
-  )
-
-  return structure.Structure(
-      name=name,
-      release_date=release_date,
-      resolution=resolution,
-      structure_method=structure_method,
-      bioassembly_data=bioassembly_data,
-      chemical_components_data=chemical_components_data,
-      atoms=atoms,
-      chains=chains,
-      residues=residues,
-      bonds=bond_table or structure_tables.Bonds.make_empty(),
-  )
-
-
-def _guess_entity_type(
-    chain_residues: Collection[str], atom_types: Collection[str]
-) -> str:
-  """Guess the entity type (polymer/non-polymer/water) based on residues/atoms.
-
-  We treat both arguments as unordered collections since we care only whether
-  all elements satisfy come conditions. The chain_residues can be either
-  grouped by residue (length num_res), or it can be raw (length num_atoms).
-  Atom type is unique for each atom in a residue, so don't group atom_types.
-
-  Args:
-    chain_residues: A sequence of full residue name (1-letter for DNA, 2-letters
-      for RNA, 3 for protein). The _atom_site.label_comp_id column in mmCIF.
-    atom_types: Atom type: ATOM or HETATM. The _atom_site.group_PDB column in
-      mmCIF.
-
-  Returns:
-    One of polymer/non-polymer/water based on the following criteria:
-    * If all atoms are HETATMs and all residues are water -> water.
-    * If all atoms are HETATMs and not all residues are water -> non-polymer.
-    * Otherwise -> polymer.
-  """
-  if not chain_residues or not atom_types:
-    raise ValueError(
-        f'chain_residues (len {len(chain_residues)}) and atom_types (len '
-        f'{len(atom_types)}) must be both non-empty. Got: {chain_residues=} '
-        f'and {atom_types=}'
-    )
-
-  if all(a == 'HETATM' for a in atom_types):
-    if all(c in residue_names.WATER_TYPES for c in chain_residues):
-      return mmcif_names.WATER
-    return mmcif_names.NON_POLYMER_CHAIN
-  return mmcif_names.POLYMER_CHAIN
diff --git a/src/alphafold3/structure/sterics.py b/src/alphafold3/structure/sterics.py
deleted file mode 100644
index 34f99a7607b73c9ed8c410bb04401bdd077c4973..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/sterics.py
+++ /dev/null
@@ -1,140 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Functions relating to spatial locations of atoms within a structure."""
-
-from collections.abc import Collection, Sequence
-
-from alphafold3 import structure
-from alphafold3.structure import mmcif
-import numpy as np
-import scipy
-
-
-def _make_atom_has_clash_mask(
-    kd_query_result: np.ndarray,
-    struc: structure.Structure,
-    ignore_chains: Collection[str],
-) -> np.ndarray:
-  """Returns a boolean NumPy array representing whether each atom has a clash.
-
-  Args:
-    kd_query_result: NumPy array containing N-atoms arrays, each array
-      containing indices to atoms that clash with the N'th atom.
-    struc: Structure over which clashes were detected.
-    ignore_chains: Collection of chains that should not be considered clashing.
-      A boolean NumPy array of length N atoms.
-  """
-  atom_is_clashing = np.zeros((struc.num_atoms,), dtype=bool)
-  for atom_index, clashes in enumerate(kd_query_result):
-    chain_i = struc.chain_id[atom_index]
-    if chain_i in ignore_chains:
-      continue
-    islig_i = struc.is_ligand_mask[atom_index]
-    for clashing_atom_index in clashes:
-      chain_c = struc.chain_id[clashing_atom_index]
-      if chain_c in ignore_chains:
-        continue
-      islig_c = struc.is_ligand_mask[clashing_atom_index]
-      if (
-          clashing_atom_index == atom_index
-          or chain_i == chain_c
-          or islig_i != islig_c
-      ):
-        # Ignore clashes within chain or between ligand and polymer.
-        continue
-      atom_is_clashing[atom_index] = True
-  return atom_is_clashing
-
-
-def find_clashing_chains(
-    struc: structure.Structure,
-    clash_thresh_angstrom: float = 1.7,
-    clash_thresh_fraction: float = 0.3,
-) -> Sequence[str]:
-  """Finds chains that clash with others.
-
-  Clashes are defined by polymer backbone atoms and all ligand atoms.
-  Ligand-polymer clashes are not dropped.
-
-  Will not find clashes if all coordinates are 0. Coordinates are all 0s if
-  the structure is generated from sequences only, as done for inference in
-  dendro for example.
-
-  Args:
-    struc: The structure defining the chains and atom positions.
-    clash_thresh_angstrom: Below this distance, atoms are considered clashing.
-    clash_thresh_fraction: Chains with more than this fraction of their atoms
-      considered clashing will be dropped. This value should be in the range (0,
-      1].
-
-  Returns:
-    A sequence of chain ids for chains that clash.
-
-  Raises:
-    ValueError: If `clash_thresh_fraction` is not in range (0,1].
-  """
-  if not 0 < clash_thresh_fraction <= 1:
-    raise ValueError('clash_thresh_fraction must be in range (0,1]')
-
-  struc_backbone = struc.filter_polymers_to_single_atom_per_res()
-  if struc_backbone.num_chains == 0:
-    return []
-
-  # If the coordinates are all 0, do not search for clashes.
-  if not np.any(struc_backbone.coords):
-    return []
-
-  coord_kdtree = scipy.spatial.cKDTree(struc_backbone.coords)
-
-  # For each atom coordinate, find all atoms within the clash thresh radius.
-  clashing_per_atom = coord_kdtree.query_ball_point(
-      struc_backbone.coords, r=clash_thresh_angstrom
-  )
-  chain_ids = struc_backbone.chains
-  if struc_backbone.atom_occupancy is not None:
-    chain_occupancy = np.array([
-        np.mean(struc_backbone.atom_occupancy[start:end])
-        for start, end in struc_backbone.iter_chain_ranges()
-    ])
-  else:
-    chain_occupancy = None
-
-  # Remove chains until no more significant clashing.
-  chains_to_remove = set()
-  for _ in range(len(chain_ids)):
-    # Calculate maximally clashing.
-    atom_has_clash = _make_atom_has_clash_mask(
-        clashing_per_atom, struc_backbone, chains_to_remove
-    )
-    clashes_per_chain = np.array([
-        atom_has_clash[start:end].mean()
-        for start, end in struc_backbone.iter_chain_ranges()
-    ])
-    max_clash = np.max(clashes_per_chain)
-    if max_clash <= clash_thresh_fraction:
-      # None of the remaining chains exceed the clash fraction threshold, so
-      # we can exit.
-      break
-
-    # Greedily remove worst with the lowest occupancy.
-    most_clashes = np.nonzero(clashes_per_chain == max_clash)[0]
-    if chain_occupancy is not None:
-      occupancy_clashing = chain_occupancy[most_clashes]
-      last_lowest_occupancy = (
-          len(occupancy_clashing) - np.argmin(occupancy_clashing[::-1]) - 1
-      )
-      worst_and_last = most_clashes[last_lowest_occupancy]
-    else:
-      worst_and_last = most_clashes[-1]
-
-    chains_to_remove.add(chain_ids[worst_and_last])
-
-  return sorted(chains_to_remove, key=mmcif.str_id_to_int_id)
diff --git a/src/alphafold3/structure/structure.py b/src/alphafold3/structure/structure.py
deleted file mode 100644
index 215372674696a634c5afeab91d21b917ccbcedfa..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/structure.py
+++ /dev/null
@@ -1,3261 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Structure class for representing and processing molecular structures."""
-
-import collections
-from collections.abc import Callable, Collection, Iterable, Iterator, Mapping, Sequence, Set
-import dataclasses
-import datetime
-import enum
-import functools
-import itertools
-import typing
-from typing import Any, ClassVar, Final, Literal, NamedTuple, Self, TypeAlias, TypeVar
-
-from alphafold3.constants import atom_types
-from alphafold3.constants import chemical_components
-from alphafold3.constants import mmcif_names
-from alphafold3.constants import residue_names
-from alphafold3.cpp import membership
-from alphafold3.cpp import string_array
-from alphafold3.structure import bioassemblies
-from alphafold3.structure import chemical_components as struc_chem_comps
-from alphafold3.structure import mmcif
-from alphafold3.structure import structure_tables
-from alphafold3.structure import table
-import numpy as np
-
-# Controls the default number of decimal places for coordinates when writing to
-# mmCIF.
-_COORDS_DECIMAL_PLACES: Final[int] = 3
-
-
-@enum.unique
-class CascadeDelete(enum.Enum):
-  NONE = 0
-  FULL = 1
-  CHAINS = 2
-
-
-# See www.python.org/dev/peps/pep-0484/#support-for-singleton-types-in-unions
-class _UnsetSentinel(enum.Enum):
-  UNSET = object()
-
-
-_UNSET = _UnsetSentinel.UNSET
-
-
-class Bond(NamedTuple):
-  """Describes a bond between two atoms."""
-
-  from_atom: Mapping[str, str | int | float | np.ndarray]
-  dest_atom: Mapping[str, str | int | float | np.ndarray]
-  bond_info: Mapping[str, str | int]
-
-
-class MissingAtomError(Exception):
-  """Error raised when an atom is missing during alignment."""
-
-
-class MissingAuthorResidueIdError(Exception):
-  """Raised when author naming data is missing for a residue.
-
-  This can occur in certain edge cases where missing residue data is provided
-  without also providing author IDs for those missing residues.
-  """
-
-
-# AllResidues is a mapping from label_asym_id to a sequence of (label_comp_id,
-# label_seq_id) pairs. These represent the full sequence including residues
-# that might be missing (e.g. unresolved residues in X-ray data).
-AllResidues: TypeAlias = Mapping[str, Sequence[tuple[str, int]]]
-AuthorNamingScheme: TypeAlias = structure_tables.AuthorNamingScheme
-
-
-# External residue ID given to missing residues that don't have an ID
-# already provided. In mmCIFs this data is found in _pdbx_poly_seq_scheme.
-MISSING_AUTH_SEQ_ID: Final[str] = '.'
-
-
-# Maps from structure fields to column names in the relevant table.
-CHAIN_FIELDS: Final[Mapping[str, str]] = {
-    'chain_id': 'id',
-    'chain_type': 'type',
-    'chain_auth_asym_id': 'auth_asym_id',
-    'chain_entity_id': 'entity_id',
-    'chain_entity_desc': 'entity_desc',
-}
-
-
-RESIDUE_FIELDS: Final[Mapping[str, str]] = {
-    'res_id': 'id',
-    'res_name': 'name',
-    'res_auth_seq_id': 'auth_seq_id',
-    'res_insertion_code': 'insertion_code',
-}
-
-ATOM_FIELDS: Final[Mapping[str, str]] = {
-    'atom_name': 'name',
-    'atom_element': 'element',
-    'atom_x': 'x',
-    'atom_y': 'y',
-    'atom_z': 'z',
-    'atom_b_factor': 'b_factor',
-    'atom_occupancy': 'occupancy',
-    'atom_key': 'key',
-}
-
-# Fields in structure.
-ARRAY_FIELDS = frozenset({
-    'atom_b_factor',
-    'atom_element',
-    'atom_key',
-    'atom_name',
-    'atom_occupancy',
-    'atom_x',
-    'atom_y',
-    'atom_z',
-    'chain_id',
-    'chain_type',
-    'res_id',
-    'res_name',
-})
-
-GLOBAL_FIELDS = frozenset({
-    'name',
-    'release_date',
-    'resolution',
-    'structure_method',
-    'bioassembly_data',
-    'chemical_components_data',
-})
-
-# Fields which can be updated in copy_and_update.
-_UPDATEABLE_FIELDS: Final[Set[str]] = frozenset({
-    'all_residues',
-    'atom_b_factor',
-    'atom_element',
-    'atom_key',
-    'atom_name',
-    'atom_occupancy',
-    'atom_x',
-    'atom_y',
-    'atom_z',
-    'bioassembly_data',
-    'bonds',
-    'chain_id',
-    'chain_type',
-    'chemical_components_data',
-    'name',
-    'release_date',
-    'res_id',
-    'res_name',
-    'resolution',
-    'structure_method',
-})
-
-
-def fix_non_standard_polymer_residues(
-    res_names: np.ndarray, chain_type: str
-) -> np.ndarray:
-  """Remaps residue names to the closest standard protein/RNA/DNA residue.
-
-  If residue name is already a standard type, it is not altered.
-  If a match cannot be found, returns 'UNK' for protein chainresidues and 'N'
-    for RNA/DNA chain residue.
-
-  Args:
-     res_names: A numpy array of string residue names (CCD monomer codes). E.g.
-       'ARG' (protein), 'DT' (DNA), 'N' (RNA).
-     chain_type: The type of the chain, must be PROTEIN_CHAIN, RNA_CHAIN or
-       DNA_CHAIN.
-
-  Returns:
-    An array remapped so that its elements are all from
-    PROTEIN_TYPES_WITH_UNKNOWN | RNA_TYPES | DNA_TYPES | {'N'}.
-
-  Raises:
-    ValueError: If chain_type not in PEPTIDE_CHAIN_TYPES or
-      {OTHER_CHAIN, RNA_CHAIN, DNA_CHAIN, DNA_RNA_HYBRID_CHAIN}.
-  """
-  # Map to one letter code, then back to common res_names.
-  one_letter_codes = string_array.remap(
-      res_names, mapping=residue_names.CCD_NAME_TO_ONE_LETTER, default_value='X'
-  )
-
-  if (
-      chain_type in mmcif_names.PEPTIDE_CHAIN_TYPES
-      or chain_type == mmcif_names.OTHER_CHAIN
-  ):
-    mapping = residue_names.PROTEIN_COMMON_ONE_TO_THREE
-    default_value = 'UNK'
-  elif chain_type == mmcif_names.RNA_CHAIN:
-    # RNA has single-letter CCD monomer codes.
-    mapping = {r: r for r in residue_names.RNA_TYPES}
-    default_value = 'N'
-  elif chain_type == mmcif_names.DNA_CHAIN:
-    mapping = residue_names.DNA_COMMON_ONE_TO_TWO
-    default_value = 'N'
-  elif chain_type == mmcif_names.DNA_RNA_HYBRID_CHAIN:
-    mapping = {r: r for r in residue_names.NUCLEIC_TYPES_WITH_UNKNOWN}
-    default_value = 'N'
-  else:
-    raise ValueError(f'Expected a protein/DNA/RNA chain but got {chain_type}')
-
-  return string_array.remap(
-      one_letter_codes, mapping=mapping, default_value=default_value
-  )
-
-
-def _get_change_indices(arr: np.ndarray) -> np.ndarray:
-  if arr.size == 0:
-    return np.array([], dtype=np.int32)
-  else:
-    changing_idxs = np.where(arr[1:] != arr[:-1])[0] + 1
-    return np.concatenate(([0], changing_idxs), axis=0)
-
-
-def _unpack_filter_predicates(
-    predicate_by_field_name: Mapping[str, table.FilterPredicate],
-) -> tuple[
-    Mapping[str, table.FilterPredicate],
-    Mapping[str, table.FilterPredicate],
-    Mapping[str, table.FilterPredicate],
-]:
-  """Unpacks filter kwargs into predicates for each table."""
-  chain_predicates = {}
-  res_predicates = {}
-  atom_predicates = {}
-  for k, pred in predicate_by_field_name.items():
-    if col := CHAIN_FIELDS.get(k):
-      chain_predicates[col] = pred
-    elif col := RESIDUE_FIELDS.get(k):
-      res_predicates[col] = pred
-    elif col := ATOM_FIELDS.get(k):
-      atom_predicates[col] = pred
-    else:
-      raise ValueError(k)
-  return chain_predicates, res_predicates, atom_predicates
-
-
-_T = TypeVar('_T')
-
-
-SCALAR_FIELDS: Final[Collection[str]] = frozenset({
-    'name',
-    'release_date',
-    'resolution',
-    'structure_method',
-    'bioassembly_data',
-    'chemical_components_data',
-})
-
-
-TABLE_FIELDS: Final[Collection[str]] = frozenset(
-    {'chains', 'residues', 'atoms', 'bonds'}
-)
-
-
-V2_FIELDS: Final[Collection[str]] = frozenset({*SCALAR_FIELDS, *TABLE_FIELDS})
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class StructureTables:
-  chains: structure_tables.Chains
-  residues: structure_tables.Residues
-  atoms: structure_tables.Atoms
-  bonds: structure_tables.Bonds
-
-
-class Structure(table.Database):
-  """Structure class for representing and processing molecular structures."""
-
-  tables: ClassVar[Collection[str]] = TABLE_FIELDS
-
-  foreign_keys: ClassVar[Mapping[str, Collection[tuple[str, str]]]] = {
-      'residues': (('chain_key', 'chains'),),
-      'atoms': (('chain_key', 'chains'), ('res_key', 'residues')),
-      'bonds': (('from_atom_key', 'atoms'), ('dest_atom_key', 'atoms')),
-  }
-
-  def __init__(
-      self,
-      *,
-      name: str = 'unset',
-      release_date: datetime.date | None = None,
-      resolution: float | None = None,
-      structure_method: str | None = None,
-      bioassembly_data: bioassemblies.BioassemblyData | None = None,
-      chemical_components_data: (
-          struc_chem_comps.ChemicalComponentsData | None
-      ) = None,
-      chains: structure_tables.Chains,
-      residues: structure_tables.Residues,
-      atoms: structure_tables.Atoms,
-      bonds: structure_tables.Bonds,
-      skip_validation: bool = False,
-  ):
-    # Version number is written to mmCIF and should be incremented when changes
-    # are made to mmCIF writing or internals that affect this.
-    # b/345221494 Rename this variable when structure_v1 compatibility code
-    # is removed.
-    self._VERSION = '2.0.0'  # pylint: disable=invalid-name
-    self._name = name
-    self._release_date = release_date
-    self._resolution = resolution
-    self._structure_method = structure_method
-    self._bioassembly_data = bioassembly_data
-    self._chemical_components_data = chemical_components_data
-
-    self._chains = chains
-    self._residues = residues
-    self._atoms = atoms
-    self._bonds = bonds
-
-    if not skip_validation:
-      self._validate_table_foreign_keys()
-      self._validate_consistent_table_ordering()
-
-  def _validate_table_foreign_keys(self):
-    """Validates that all foreign keys are present in the referred tables."""
-    residue_keys = set(self._residues.key)
-    chain_keys = set(self._chains.key)
-    if np.any(membership.isin(self._atoms.res_key, residue_keys, invert=True)):
-      raise ValueError(
-          'Atom residue keys not in the residues table: '
-          f'{set(self._atoms.res_key).difference(self._residues.key)}'
-      )
-    if np.any(membership.isin(self._atoms.chain_key, chain_keys, invert=True)):
-      raise ValueError(
-          'Atom chain keys not in the chains table: '
-          f'{set(self._atoms.chain_key).difference(self._chains.key)}'
-      )
-    if np.any(
-        membership.isin(self._residues.chain_key, chain_keys, invert=True)
-    ):
-      raise ValueError(
-          'Residue chain keys not in the chains table: '
-          f'{set(self._residues.chain_key).difference(self._chains.key)}'
-      )
-
-  def _validate_consistent_table_ordering(self):
-    """Validates that all tables have the same ordering."""
-    atom_chain_keys = self._atoms.chain_key[self.chain_boundaries]
-    atom_res_keys = self._atoms.res_key[self.res_boundaries]
-
-    if not np.array_equal(self.present_chains.key, atom_chain_keys):
-      raise ValueError(
-          f'Atom table chain order\n{atom_chain_keys}\ndoes not match the '
-          f'chain table order\n{self._chains.key}'
-      )
-    if not np.array_equal(self.present_residues.key, atom_res_keys):
-      raise ValueError(
-          f'Atom table residue order\n{atom_res_keys}\ndoes not match the '
-          f'present residue table order\n{self.present_residues.key}'
-      )
-
-  def get_table(self, table_name: str) -> table.Table:
-    match table_name:
-      case 'chains':
-        return self.chains_table
-      case 'residues':
-        return self.residues_table
-      case 'atoms':
-        return self.atoms_table
-      case 'bonds':
-        return self.bonds_table
-      case _:
-        raise ValueError(table_name)
-
-  @property
-  def chains_table(self) -> structure_tables.Chains:
-    """Chains table."""
-    return self._chains
-
-  @property
-  def residues_table(self) -> structure_tables.Residues:
-    """Residues table."""
-    return self._residues
-
-  @property
-  def atoms_table(self) -> structure_tables.Atoms:
-    """Atoms table."""
-    return self._atoms
-
-  @property
-  def bonds_table(self) -> structure_tables.Bonds:
-    """Bonds table."""
-    return self._bonds
-
-  @property
-  def name(self) -> str:
-    return self._name
-
-  @property
-  def release_date(self) -> datetime.date | None:
-    return self._release_date
-
-  @property
-  def resolution(self) -> float | None:
-    return self._resolution
-
-  @property
-  def structure_method(self) -> str | None:
-    return self._structure_method
-
-  @property
-  def bioassembly_data(self) -> bioassemblies.BioassemblyData | None:
-    return self._bioassembly_data
-
-  @property
-  def chemical_components_data(
-      self,
-  ) -> struc_chem_comps.ChemicalComponentsData | None:
-    return self._chemical_components_data
-
-  @property
-  def bonds(self) -> structure_tables.Bonds:
-    return self._bonds
-
-  @functools.cached_property
-  def author_naming_scheme(self) -> AuthorNamingScheme:
-    auth_asym_id = {}
-    entity_id = {}
-    entity_desc = {}
-    auth_seq_id = collections.defaultdict(dict)
-    insertion_code = collections.defaultdict(dict)
-
-    for chain_i in range(self._chains.size):
-      chain_id = self._chains.id[chain_i]
-      auth_asym_id[chain_id] = self._chains.auth_asym_id[chain_i]
-      chain_entity_id = self._chains.entity_id[chain_i]
-      entity_id[chain_id] = chain_entity_id
-      entity_desc[chain_entity_id] = self._chains.entity_desc[chain_i]
-
-    chain_index_by_key = self._chains.index_by_key
-    for res_i in range(self._residues.size):
-      chain_key = self._residues.chain_key[res_i]
-      chain_id = self._chains.id[chain_index_by_key[chain_key]]
-      res_id = self._residues.id[res_i]
-      res_auth_seq_id = self._residues.auth_seq_id[res_i]
-      if res_auth_seq_id == MISSING_AUTH_SEQ_ID:
-        continue
-      auth_seq_id[chain_id][res_id] = res_auth_seq_id
-      ins_code = self._residues.insertion_code[res_i]
-      # Compatibility with Structure v1 which used None to represent . or ?.
-      insertion_code[chain_id][res_id] = (
-          ins_code if ins_code not in {'.', '?'} else None
-      )
-
-    return AuthorNamingScheme(
-        auth_asym_id=auth_asym_id,
-        entity_id=entity_id,
-        entity_desc=entity_desc,
-        auth_seq_id=dict(auth_seq_id),
-        insertion_code=dict(insertion_code),
-    )
-
-  @functools.cached_property
-  def all_residues(self) -> AllResidues:
-    chain_id_by_key = dict(zip(self._chains.key, self._chains.id))
-    residue_chain_boundaries = _get_change_indices(self._residues.chain_key)
-    boundaries = self._iter_residue_ranges(
-        residue_chain_boundaries, count_unresolved=True
-    )
-    return {
-        chain_id_by_key[self._residues.chain_key[start]]: list(
-            zip(self._residues.name[start:end], self._residues.id[start:end])
-        )
-        for start, end in boundaries
-    }
-
-  @functools.cached_property
-  def label_asym_id_to_entity_id(self) -> Mapping[str, str]:
-    return dict(zip(self._chains.id, self._chains.entity_id))
-
-  @functools.cached_property
-  def chain_entity_id(self) -> np.ndarray:
-    """Returns the entity ID for each atom in the structure."""
-    return self.chains_table.apply_array_to_column(
-        'entity_id', self._atoms.chain_key
-    )
-
-  @functools.cached_property
-  def chain_entity_desc(self) -> np.ndarray:
-    """Returns the entity description for each atom in the structure."""
-    return self.chains_table.apply_array_to_column(
-        'entity_desc', self._atoms.chain_key
-    )
-
-  @functools.cached_property
-  def chain_auth_asym_id(self) -> np.ndarray:
-    """Returns the chain auth asym ID for each atom in the structure."""
-    return self.chains_table.apply_array_to_column(
-        'auth_asym_id', self._atoms.chain_key
-    )
-
-  @functools.cached_property
-  def chain_id(self) -> np.ndarray:
-    chain_index_by_key = self._chains.index_by_key
-    return self._chains.id[chain_index_by_key[self._atoms.chain_key]]
-
-  @functools.cached_property
-  def chain_type(self) -> np.ndarray:
-    chain_index_by_key = self._chains.index_by_key
-    return self._chains.type[chain_index_by_key[self._atoms.chain_key]]
-
-  @functools.cached_property
-  def res_id(self) -> np.ndarray:
-    return self._residues['id', self._atoms.res_key]
-
-  @functools.cached_property
-  def res_name(self) -> np.ndarray:
-    return self._residues['name', self._atoms.res_key]
-
-  @functools.cached_property
-  def res_auth_seq_id(self) -> np.ndarray:
-    """Returns the residue auth seq ID for each atom in the structure."""
-    return self.residues_table.apply_array_to_column(
-        'auth_seq_id', self._atoms.res_key
-    )
-
-  @functools.cached_property
-  def res_insertion_code(self) -> np.ndarray:
-    """Returns the residue insertion code for each atom in the structure."""
-    return self.residues_table.apply_array_to_column(
-        'insertion_code', self._atoms.res_key
-    )
-
-  @property
-  def atom_key(self) -> np.ndarray:
-    return self._atoms.key
-
-  @property
-  def atom_name(self) -> np.ndarray:
-    return self._atoms.name
-
-  @property
-  def atom_element(self) -> np.ndarray:
-    return self._atoms.element
-
-  @property
-  def atom_x(self) -> np.ndarray:
-    return self._atoms.x
-
-  @property
-  def atom_y(self) -> np.ndarray:
-    return self._atoms.y
-
-  @property
-  def atom_z(self) -> np.ndarray:
-    return self._atoms.z
-
-  @property
-  def atom_b_factor(self) -> np.ndarray:
-    return self._atoms.b_factor
-
-  @property
-  def atom_occupancy(self) -> np.ndarray:
-    return self._atoms.occupancy
-
-  @functools.cached_property
-  def chain_boundaries(self) -> np.ndarray:
-    """The indices in the atom fields where each present chain begins."""
-    return _get_change_indices(self._atoms.chain_key)
-
-  @functools.cached_property
-  def res_boundaries(self) -> np.ndarray:
-    """The indices in the atom fields where each present residue begins."""
-    return _get_change_indices(self._atoms.res_key)
-
-  @functools.cached_property
-  def present_chains(self) -> structure_tables.Chains:
-    """Returns table of chains which have at least 1 resolved atom."""
-    is_present_mask = np.isin(self._chains.key, self._atoms.chain_key)
-    return typing.cast(structure_tables.Chains, self._chains[is_present_mask])
-
-  @functools.cached_property
-  def present_residues(self) -> structure_tables.Residues:
-    """Returns table of residues which have at least 1 resolved atom."""
-    is_present_mask = np.isin(self._residues.key, self._atoms.res_key)
-    return typing.cast(
-        structure_tables.Residues, self._residues[is_present_mask]
-    )
-
-  @functools.cached_property
-  def unresolved_residues(self) -> structure_tables.Residues:
-    """Returns table of residues which have at least 1 resolved atom."""
-    is_unresolved_mask = np.isin(
-        self._residues.key, self._atoms.res_key, invert=True
-    )
-    return typing.cast(
-        structure_tables.Residues, self._residues[is_unresolved_mask]
-    )
-
-  def __getitem__(self, field: str) -> Any:
-    """Gets raw field data using field name as a string."""
-    if field in TABLE_FIELDS:
-      return self.get_table(field)
-    else:
-      return getattr(self, field)
-
-  def __getstate__(self) -> dict[str, Any]:
-    """Pickle calls this on dump.
-
-    Returns:
-      Members with cached properties removed.
-    """
-    cached_props = {
-        k
-        for k, v in self.__class__.__dict__.items()
-        if isinstance(v, functools.cached_property)
-    }
-    return {k: v for k, v in self.__dict__.items() if k not in cached_props}
-
-  def __repr__(self):
-    return (
-        f'Structure({self._name}: {self.num_chains} chains, '
-        f'{self.num_residues(count_unresolved=False)} residues, '
-        f'{self.num_atoms} atoms)'
-    )
-
-  @property
-  def num_atoms(self) -> int:
-    return self._atoms.size
-
-  def num_residues(self, *, count_unresolved: bool) -> int:
-    """Returns the number of residues in this Structure.
-
-    Args:
-      count_unresolved: Whether to include unresolved (empty) residues.
-
-    Returns:
-      Number of residues in the Structure.
-    """
-    if count_unresolved:
-      return self._residues.size
-    else:
-      return self.present_residues.size
-
-  @property
-  def num_chains(self) -> int:
-    return self._chains.size
-
-  @property
-  def num_models(self) -> int:
-    """The number of models of this Structure."""
-    return self._atoms.num_models
-
-  def _atom_mask(self, entities: Set[str]) -> np.ndarray:
-    """Boolean label indicating if each atom is from entities or not."""
-    mask = np.zeros(self.num_atoms, dtype=bool)
-    chain_index_by_key = self._chains.index_by_key
-    for start, end in self.iter_chain_ranges():
-      chain_index = chain_index_by_key[self._atoms.chain_key[start]]
-      chain_type = self._chains.type[chain_index]
-      mask[start:end] = chain_type in entities
-    return mask
-
-  @functools.cached_property
-  def is_protein_mask(self) -> np.ndarray:
-    """Boolean label indicating if each atom is from protein or not."""
-    return self._atom_mask(entities={mmcif_names.PROTEIN_CHAIN})
-
-  @functools.cached_property
-  def is_dna_mask(self) -> np.ndarray:
-    """Boolean label indicating if each atom is from DNA or not."""
-    return self._atom_mask(entities={mmcif_names.DNA_CHAIN})
-
-  @functools.cached_property
-  def is_rna_mask(self) -> np.ndarray:
-    """Boolean label indicating if each atom is from RNA or not."""
-    return self._atom_mask(entities={mmcif_names.RNA_CHAIN})
-
-  @functools.cached_property
-  def is_nucleic_mask(self) -> np.ndarray:
-    """Boolean label indicating if each atom is a nucleic acid or not."""
-    return self._atom_mask(entities=mmcif_names.NUCLEIC_ACID_CHAIN_TYPES)
-
-  @functools.cached_property
-  def is_ligand_mask(self) -> np.ndarray:
-    """Boolean label indicating if each atom is a ligand or not."""
-    return self._atom_mask(entities=mmcif_names.LIGAND_CHAIN_TYPES)
-
-  @functools.cached_property
-  def is_water_mask(self) -> np.ndarray:
-    """Boolean label indicating if each atom is from water or not."""
-    return self._atom_mask(entities={mmcif_names.WATER})
-
-  def iter_atoms(self) -> Iterator[Mapping[str, Any]]:
-    """Iterates over the atoms in the structure."""
-    if self._atoms.size == 0:
-      return
-
-    current_chain = self._chains.get_row_by_key(
-        column_name_map=CHAIN_FIELDS, key=self._atoms.chain_key[0]
-    )
-    current_chain_key = self._atoms.chain_key[0]
-    current_res = self._residues.get_row_by_key(
-        column_name_map=RESIDUE_FIELDS, key=self._atoms.res_key[0]
-    )
-    current_res_key = self._atoms.res_key[0]
-    for atom_i in range(self._atoms.size):
-      atom_chain_key = self._atoms.chain_key[atom_i]
-      atom_res_key = self._atoms.res_key[atom_i]
-
-      if atom_chain_key != current_chain_key:
-        chain_index = self._chains.index_by_key[atom_chain_key]
-        current_chain = {
-            'chain_id': self._chains.id[chain_index],
-            'chain_type': self._chains.type[chain_index],
-            'chain_auth_asym_id': self._chains.auth_asym_id[chain_index],
-            'chain_entity_id': self._chains.entity_id[chain_index],
-            'chain_entity_desc': self._chains.entity_desc[chain_index],
-        }
-        current_chain_key = atom_chain_key
-      if atom_res_key != current_res_key:
-        res_index = self._residues.index_by_key[atom_res_key]
-        current_res = {
-            'res_id': self._residues.id[res_index],
-            'res_name': self._residues.name[res_index],
-            'res_auth_seq_id': self._residues.auth_seq_id[res_index],
-            'res_insertion_code': self._residues.insertion_code[res_index],
-        }
-        current_res_key = atom_res_key
-
-      yield {
-          'atom_name': self._atoms.name[atom_i],
-          'atom_element': self._atoms.element[atom_i],
-          'atom_x': self._atoms.x[..., atom_i],
-          'atom_y': self._atoms.y[..., atom_i],
-          'atom_z': self._atoms.z[..., atom_i],
-          'atom_b_factor': self._atoms.b_factor[..., atom_i],
-          'atom_occupancy': self._atoms.occupancy[..., atom_i],
-          'atom_key': self._atoms.key[atom_i],
-          **current_res,
-          **current_chain,
-      }
-
-  def iter_residues(
-      self,
-      include_unresolved: bool = False,
-  ) -> Iterator[Mapping[str, Any]]:
-    """Iterates over the residues in the structure."""
-    res_table = self._residues if include_unresolved else self.present_residues
-    if res_table.size == 0:
-      return
-
-    current_chain = self._chains.get_row_by_key(
-        column_name_map=CHAIN_FIELDS, key=res_table.chain_key[0]
-    )
-    current_chain_key = res_table.chain_key[0]
-    for res_i in range(res_table.size):
-      res_chain_key = res_table.chain_key[res_i]
-
-      if res_chain_key != current_chain_key:
-        current_chain = self._chains.get_row_by_key(
-            column_name_map=CHAIN_FIELDS, key=res_table.chain_key[res_i]
-        )
-        current_chain_key = res_chain_key
-
-      row = {
-          'res_id': res_table.id[res_i],
-          'res_name': res_table.name[res_i],
-          'res_auth_seq_id': res_table.auth_seq_id[res_i],
-          'res_insertion_code': res_table.insertion_code[res_i],
-      }
-      yield row | current_chain
-
-  def _iter_atom_ranges(
-      self, boundaries: Sequence[int]
-  ) -> Iterator[tuple[int, int]]:
-    """Iterator for (start, end) pairs from an array of start indices."""
-    yield from itertools.pairwise(boundaries)
-    # Use explicit length test as boundaries can be a NumPy array.
-    if len(boundaries) > 0:  # pylint: disable=g-explicit-length-test
-      yield boundaries[-1], self.num_atoms
-
-  def _iter_residue_ranges(
-      self,
-      boundaries: Sequence[int],
-      *,
-      count_unresolved: bool,
-  ) -> Iterator[tuple[int, int]]:
-    """Iterator for (start, end) pairs from an array of start indices."""
-    yield from itertools.pairwise(boundaries)
-    # Use explicit length test as boundaries can be a NumPy array.
-    if len(boundaries) > 0:  # pylint: disable=g-explicit-length-test
-      yield boundaries[-1], self.num_residues(count_unresolved=count_unresolved)
-
-  def iter_chain_ranges(self) -> Iterator[tuple[int, int]]:
-    """Iterates pairs of (chain_start, chain_end) indices.
-
-    Yields:
-      Pairs of (start, end) indices for each chain, where end is not inclusive.
-      i.e. struc.chain_id[start:end] would be a constant array with length
-      equal to the number of atoms in the chain.
-    """
-    yield from self._iter_atom_ranges(self.chain_boundaries)
-
-  def iter_residue_ranges(self) -> Iterator[tuple[int, int]]:
-    """Iterates pairs of (residue_start, residue_end) indices.
-
-    Yields:
-      Pairs of (start, end) indices for each residue, where end is not
-      inclusive. i.e. struc.res_id[start:end] would be a constant array with
-      length equal to the number of atoms in the residue.
-    """
-    yield from self._iter_atom_ranges(self.res_boundaries)
-
-  def iter_chains(self) -> Iterator[Mapping[str, Any]]:
-    """Iterates over the chains in the structure."""
-    for chain_i in range(self.present_chains.size):
-      yield {
-          'chain_id': self.present_chains.id[chain_i],
-          'chain_type': self.present_chains.type[chain_i],
-          'chain_auth_asym_id': self.present_chains.auth_asym_id[chain_i],
-          'chain_entity_id': self.present_chains.entity_id[chain_i],
-          'chain_entity_desc': self.present_chains.entity_desc[chain_i],
-      }
-
-  def iter_bonds(self) -> Iterator[Bond]:
-    """Iterates over the atoms and bond information.
-
-    Example usage:
-
-    ```
-    for from_atom, dest_atom, bond_info in struc.iter_bonds():
-      print(
-          f'From atom: name={from_atom["atom_name"]}, '
-          f'chain={from_atom["chain_id"]}, ...'
-      )
-      # Same for dest_atom
-      print(f'Bond info: type={bond_info["type"]}, role={bond_info["role"]}')
-    ```
-
-    Yields:
-      A `Bond` NamedTuple for each bond in the bonds table.
-      These have fields `from_atom`, `dest_atom`, `bond_info` where each
-      is a dictionary. The first two have the same keys as the atom dicts
-      returned by self.iter_atoms() -- i.e. one key per non-None field.
-      The final dict has the same keys as self.bonds.iterrows() -- i.e. one
-      key per column in the bonds table.
-    """
-    from_atom_iter = self._atoms.iterrows(
-        row_keys=self._bonds.from_atom_key,
-        column_name_map=ATOM_FIELDS,
-        chain_key=self._chains.with_column_names(CHAIN_FIELDS),
-        res_key=self._residues.with_column_names(RESIDUE_FIELDS),
-    )
-    dest_atom_iter = self._atoms.iterrows(
-        row_keys=self._bonds.dest_atom_key,
-        column_name_map=ATOM_FIELDS,
-        chain_key=self._chains.with_column_names(CHAIN_FIELDS),
-        res_key=self._residues.with_column_names(RESIDUE_FIELDS),
-    )
-
-    for from_atom, dest_atom, bond_info in zip(
-        from_atom_iter, dest_atom_iter, self._bonds.iterrows(), strict=True
-    ):
-      yield Bond(from_atom=from_atom, dest_atom=dest_atom, bond_info=bond_info)
-
-  def _apply_atom_index_array(
-      self,
-      index_arr: np.ndarray,
-      chain_boundaries: np.ndarray | None = None,
-      res_boundaries: np.ndarray | None = None,
-      skip_validation: bool = False,
-  ) -> Self:
-    """Applies index_arr to the atom table using NumPy-style array indexing.
-
-    Args:
-      index_arr: A 1D NumPy array that will be used to index into the atoms
-        table. This can either be a boolean array to act as a mask, or an
-        integer array to perform a gather operation.
-      chain_boundaries: Unused in structure v2.
-      res_boundaries: Unused in structure v2.
-      skip_validation: Whether to skip the validation step that checks internal
-        consistency after applying atom index array. Do not set to True unless
-        you are certain the transform is safe, e.g. when the order of atoms is
-        guaranteed to not change.
-
-    Returns:
-      A new Structure with an updated atoms table.
-    """
-    del chain_boundaries, res_boundaries
-
-    if index_arr.ndim != 1:
-      raise ValueError(
-          f'index_arr must be a 1D NumPy array, but has shape {index_arr.shape}'
-      )
-
-    if index_arr.dtype == bool and np.all(index_arr):
-      return self  # Shortcut: The operation is a no-op, so just return itself.
-
-    atoms = structure_tables.Atoms(
-        **{col: self._atoms[col][..., index_arr] for col in self._atoms.columns}
-    )
-    updated_tables = self._cascade_delete(atoms=atoms)
-    return self.copy_and_update(
-        atoms=updated_tables.atoms,
-        bonds=updated_tables.bonds,
-        skip_validation=skip_validation,
-    )
-
-  @property
-  def group_by_residue(self) -> Self:
-    """Returns a Structure with one atom per residue.
-
-    e.g. restypes = struc.group_by_residue['res_id']
-
-    Returns:
-      A new Structure with one atom per residue such that per-atom arrays
-      such as res_name (i.e. Structure v1 fields) have one element per residue.
-    """
-    # This use of _apply_atom_index_array is safe because the chain/residue/atom
-    # ordering won't change (essentially applying a residue start mask).
-    return self._apply_atom_index_array(
-        self.res_boundaries, skip_validation=True
-    )
-
-  @property
-  def group_by_chain(self) -> Self:
-    """Returns a Structure where all fields are per-chain.
-
-    e.g. chains = struc.group_by_chain['chain_id']
-
-    Returns:
-      A new Structure with one atom per chain such that per-atom arrays
-      such as res_name (i.e. Structure v1 fields) have one element per chain.
-    """
-    # This use of _apply_atom_index_array is safe because the chain/residue/atom
-    # ordering won't change (essentially applying a chain start mask).
-    return self._apply_atom_index_array(
-        self.chain_boundaries, skip_validation=True
-    )
-
-  @property
-  def with_sorted_chains(self) -> Self:
-    """Returns a new structure with the chains are in reverse spreadsheet style.
-
-    This is the usual order to write chains in an mmCIF:
-    (A < B < ... < AA < BA < CA < ... < AB < BB < CB ...)
-
-    NB: this method will fail if chains do not conform to this mmCIF naming
-    convention.
-
-    Only to be used for third party metrics that rely on the chain order.
-    Elsewhere chains should be identified by name and code should be agnostic to
-    the order.
-    """
-    sorted_chains = sorted(self.chains, key=mmcif.str_id_to_int_id)
-    return self.reorder_chains(new_order=sorted_chains)
-
-  @functools.cached_property
-  def atom_ids(self) -> Sequence[tuple[str, str, None, str]]:
-    """Gets a list of atom ID tuples from Structure class arrays.
-
-    Returns:
-      A list of tuples of (chain_id, res_id, insertion_code, atom_name) where
-      insertion code is always None. There is one element per atom, and the
-      list is ordered according to the order of atoms in the input arrays.
-    """
-    # Convert to Numpy strings, then to Python strings (dtype=object).
-    res_ids = self.residues_table.id.astype(str).astype(object)
-    res_ids = res_ids[
-        self.residues_table.index_by_key[self.atoms_table.res_key]
-    ]
-    ins_codes = [None] * self.num_atoms
-    return list(
-        zip(self.chain_id, res_ids, ins_codes, self.atom_name, strict=True)
-    )
-
-  def order_and_drop_atoms_to_match(
-      self,
-      other: 'Structure',
-      *,
-      allow_missing_atoms: bool = False,
-  ) -> Self:
-    """Returns a new structure with atoms ordered & dropped to match another's.
-
-    This performs two operations simultaneously:
-      * Ordering the atoms in this structure to match the order in the other.
-      * Dropping atoms in this structure that do not appear in the other.
-
-    Example:
-    Consider a prediction and ground truth with the following atoms, described
-    using tuples of `(chain_id, res_id, atom_name)`:
-      * `prediction:   [(A, 1, CA), (A, 1, N), (A, 2, CA), (B, 1, CA)]`
-      * `ground_truth: [(B, 1, CA), (A, 1, N), (A, 1, CA)]`
-    Note how the ground truth is missing the `(A, 2, CA)` atom and also
-    has the atoms in a different order. This method returns a modified
-    prediction that has reordered atoms and without any atoms not in the ground
-    truth so that its atom list looks the same as the ground truth atom list.
-    This means `prediction.coords` and `ground_truth.coords` now have the
-    same shape and can be compared across the atom dimension.
-
-    Note that matching residues with no atoms and matching chains with no
-    residues will also be kept. E.g. in the example above, if prediction and
-    ground truth both had an unresolved residue (A, 3), the output structure
-    will also have an unresolved residue (A, 3).
-
-    Args:
-      other: Another `Structure`. This provides the reference ordering that is
-        used to sort this structure's atom arrays.
-      allow_missing_atoms: Whether to skip atoms present in `other` but not this
-        structure and return a structure containing a subset of the atoms in the
-        other structure.
-
-    Returns:
-      A new `Structure`, based on this structure, which, if
-      `allow_missing_atoms` is False, contains exactly the same atoms as in
-      the `other` structure and which matches the `other` structure in terms
-      of the order of the atoms in the field arrays. Otherwise, if missing
-      atoms are allowed then the resulting structure contains a subset of
-      those atoms in the other structure.
-
-    Raises:
-      MissingAtomError: If there are atoms present in the other structure that
-        cannot be found in this structure.
-    """
-    atom_index_map = {atom_id: i for i, atom_id in enumerate(self.atom_ids)}
-    try:
-      if allow_missing_atoms:
-        # Only include atoms that were found in the other structure.
-        atom_indices = [
-            atom_index
-            for atom_id in other.atom_ids
-            if (atom_index := atom_index_map.get(atom_id)) is not None
-        ]
-      else:
-        atom_indices = [
-            atom_index_map[atom_id]  # Hard fail on missing.
-            for atom_id in other.atom_ids
-        ]
-    except KeyError as e:
-      if len(e.args[0]) == 4:
-        chain_id, res_id, ins_code, atom_name = e.args[0]
-        raise MissingAtomError(
-            f'No atom in this structure (name: {self._name}) matches atom in '
-            f'other structure (name: {other.name}) with internal (label) chain '
-            f'ID {chain_id}, residue ID {res_id}, insertion code {ins_code} '
-            f'and atom name {atom_name}.'
-        ) from e
-      else:
-        raise
-
-    def _iter_residues(struc: Self) -> Iterable[tuple[str, str]]:
-      yield from zip(
-          struc.chains_table['id', struc.residues_table.chain_key],
-          struc.residues_table.id,
-          strict=True,
-      )
-
-    chain_index_map = {
-        chain_id: i for i, chain_id in enumerate(self._chains.id)
-    }
-    chain_indices = [
-        chain_index
-        for chain_id in other.chains_table.id
-        if (chain_index := chain_index_map.get(chain_id)) is not None
-    ]
-    residue_index_map = {
-        res_id: i for i, res_id in enumerate(_iter_residues(self))
-    }
-    res_indices = [
-        residue_index
-        for res_id in _iter_residues(other)
-        if (residue_index := residue_index_map.get(res_id)) is not None
-    ]
-
-    # Reorder all tables.
-    chains = self._chains.apply_index(np.array(chain_indices, dtype=np.int64))
-    residues = self._residues.apply_index(np.array(res_indices, dtype=np.int64))
-    atoms = self._atoms.apply_index(np.array(atom_indices, dtype=np.int64))
-
-    # Get chain keys in the order they appear in the atoms table.
-    new_chain_boundaries = _get_change_indices(atoms.chain_key)
-    new_chain_key_order = atoms.chain_key[new_chain_boundaries]
-    if len(new_chain_key_order) != len(set(new_chain_key_order)):
-      raise ValueError(
-          f'Chain keys not contiguous after reordering: {new_chain_key_order}'
-      )
-
-    # Get residue keys in the order they appear in the atoms table.
-    new_res_boundaries = _get_change_indices(atoms.res_key)
-    new_res_key_order = atoms.res_key[new_res_boundaries]
-    if len(new_res_key_order) != len(set(new_res_key_order)):
-      raise ValueError(
-          f'Residue keys not contiguous after reordering: {new_res_key_order}'
-      )
-
-    # If any atoms were deleted, propagate that into the bonds table.
-    updated_tables = self._cascade_delete(
-        chains=chains,
-        residues=residues,
-        atoms=atoms,
-    )
-    return self.copy_and_update(
-        chains=chains,
-        residues=residues,
-        atoms=updated_tables.atoms,
-        bonds=updated_tables.bonds,
-    )
-
-  def copy_and_update(
-      self,
-      *,
-      name: str | Literal[_UNSET] = _UNSET,
-      release_date: datetime.date | None | Literal[_UNSET] = _UNSET,
-      resolution: float | None | Literal[_UNSET] = _UNSET,
-      structure_method: str | None | Literal[_UNSET] = _UNSET,
-      bioassembly_data: (
-          bioassemblies.BioassemblyData | None | Literal[_UNSET]
-      ) = _UNSET,
-      chemical_components_data: (
-          struc_chem_comps.ChemicalComponentsData | None | Literal[_UNSET]
-      ) = _UNSET,
-      chains: structure_tables.Chains | None | Literal[_UNSET] = _UNSET,
-      residues: structure_tables.Residues | None | Literal[_UNSET] = _UNSET,
-      atoms: structure_tables.Atoms | None | Literal[_UNSET] = _UNSET,
-      bonds: structure_tables.Bonds | None | Literal[_UNSET] = _UNSET,
-      skip_validation: bool = False,
-  ) -> Self:
-    """Performs a shallow copy but with specified fields updated."""
-
-    def all_unset(fields):
-      return all(field == _UNSET for field in fields)
-
-    if all_unset((chains, residues, atoms, bonds)):
-      if all_unset((
-          name,
-          release_date,
-          resolution,
-          structure_method,
-          bioassembly_data,
-          chemical_components_data,
-      )):
-        raise ValueError(
-            'Unnecessary call to copy_and_update with no changes. As Structure'
-            ' and its component tables are immutable, there is no need to copy'
-            ' it. Any subsequent operation that modifies structure will return'
-            ' a new object.'
-        )
-      else:
-        raise ValueError(
-            'When only changing global fields, prefer to use the specialised '
-            'copy_and_update_globals.'
-        )
-
-    def select(field, default):
-      return field if field != _UNSET else default
-
-    return Structure(
-        name=select(name, self.name),
-        release_date=select(release_date, self.release_date),
-        resolution=select(resolution, self.resolution),
-        structure_method=select(structure_method, self.structure_method),
-        bioassembly_data=select(bioassembly_data, self.bioassembly_data),
-        chemical_components_data=select(
-            chemical_components_data, self.chemical_components_data
-        ),
-        chains=select(chains, self._chains),
-        residues=select(residues, self._residues),
-        atoms=select(atoms, self._atoms),
-        bonds=select(bonds, self._bonds),
-        skip_validation=skip_validation,
-    )
-
-  def _copy_and_update(
-      self, skip_validation: bool = False, **changes: Any
-  ) -> Self:
-    """Performs a shallow copy but with specified fields updated."""
-    if not changes:
-      raise ValueError(
-          'Unnecessary call to copy_and_update with no changes. As Structure '
-          'and its component tables are immutable, there is no need to copy '
-          'it. Any subsequent operation that modifies structure will return a '
-          'new object.'
-      )
-
-    if 'author_naming_scheme' in changes:
-      raise ValueError(
-          'Updating using author_naming_scheme is not supported. Update '
-          'auth_asym_id, entity_id, entity_desc fields directly in the chains '
-          'table and auth_seq_id, insertion_code in the residues table.'
-      )
-
-    if all(k in GLOBAL_FIELDS for k in changes):
-      raise ValueError(
-          'When only changing global fields, prefer to use the specialised '
-          'copy_and_update_globals.'
-      )
-
-    if all(k in V2_FIELDS for k in changes):
-      constructor_kwargs = {field: self[field] for field in V2_FIELDS}
-      constructor_kwargs.update(changes)
-    elif any(k in ('atoms', 'residues', 'chains') for k in changes):
-      raise ValueError(
-          'Cannot specify atoms/chains/residues table changes with non-v2'
-          f' constructor params: {changes.keys()}'
-      )
-    elif all(k in ATOM_FIELDS for k in changes):
-      if 'atom_key' not in changes:
-        raise ValueError(
-            'When only changing atom fields, prefer to use the specialised '
-            'copy_and_update_atoms.'
-        )
-      # Only atom fields are being updated, do that directly on the atoms table.
-      updated_atoms = self._atoms.copy_and_update(
-          **{ATOM_FIELDS[k]: v for k, v in changes.items()}
-      )
-      constructor_kwargs = {
-          field: self[field] for field in V2_FIELDS if field != 'atoms'
-      }
-      constructor_kwargs['atoms'] = updated_atoms
-    else:
-      constructor_kwargs = {field: self[field] for field in _UPDATEABLE_FIELDS}
-      constructor_kwargs.update(changes)
-    return Structure(skip_validation=skip_validation, **constructor_kwargs)
-
-  def copy_and_update_coords(self, coords: np.ndarray) -> Self:
-    """Performs a shallow copy but with coordinates updated."""
-    if coords.shape[-2:] != (self.num_atoms, 3):
-      raise ValueError(
-          f'{coords.shape=} does not have last dimensions ({self.num_atoms}, 3)'
-      )
-    updated_atoms = self._atoms.copy_and_update_coords(coords)
-    return self.copy_and_update(atoms=updated_atoms, skip_validation=True)
-
-  def copy_and_update_from_res_arrays(
-      self,
-      *,
-      include_unresolved: bool = False,
-      **changes: np.ndarray,
-  ) -> Self:
-    """Like copy_and_update but changes are arrays of length num_residues.
-
-    These changes are first scattered into arrays of length num_atoms such
-    that each value is repeated across the residue at that index, then they
-    are used as the new values of these fields.
-
-    E.g.
-    * This structure's res_id: 1, 1, 1, 2, 3, 3 (3 res, 6 atoms)
-    * new atom_b_factor: 7, 8, 9
-    * Returned structure's atom_b_factor: 7, 7, 7, 8, 9, 9
-
-    Args:
-      include_unresolved: Whether the provided list of new values per residue
-        include values for all residues, or only those that are resolved.
-      **changes: kwargs corresponding to atom array fields, e.g. atom_x or
-        atom_b_factor, but with length num_residues rather than num_atoms. Note
-        that changing atom_key this way is is not supported.
-
-    Returns:
-      A new `Structure` with all fields other than those specified as kwargs
-      shallow copied from this structure. The values of the kwargs are
-      scattered across the atom arrays and then used to overwrite these
-      fields for the returned structure.
-    """
-    if not all(c in set(ATOM_FIELDS) - {'atom_key'} for c in changes):
-      raise ValueError(
-          'Changes must only be to atom fields, got changes to'
-          f' {changes.keys()}'
-      )
-
-    num_residues = self.num_residues(count_unresolved=include_unresolved)
-
-    for field_name, new_values in changes.items():
-      if len(new_values) != num_residues:
-        raise ValueError(
-            f'{field_name} array of length {len(new_values)} does not match '
-            f'{num_residues=} - is include_unresolved set correctly?'
-        )
-
-    # We cannot assume that atom_table.res_keys are the relevant indices of the
-    # residue table.
-
-    # Therefore we need to construct a map from res_key to the new values and
-    # update the atoms_table with that.
-    if include_unresolved:
-      target_keys = self.residues_table.key
-    else:
-      target_keys = self.present_residues.key
-
-    new_atom_columns = {}
-    for field_name, new_values in changes.items():
-      value_by_key = dict(zip(target_keys, new_values, strict=True))
-      # pylint: disable=cell-var-from-loop
-      new_atom_columns[field_name] = np.vectorize(lambda x: value_by_key[x])(
-          self.atoms_table.res_key
-      )
-      # pylint: enable=cell-var-from-loop
-
-    return self.copy_and_update_atoms(**new_atom_columns)
-
-  def copy_and_update_globals(
-      self,
-      *,
-      name: str | Literal[_UNSET] = _UNSET,
-      release_date: datetime.date | Literal[_UNSET] | None = _UNSET,
-      resolution: float | Literal[_UNSET] | None = _UNSET,
-      structure_method: str | Literal[_UNSET] | None = _UNSET,
-      bioassembly_data: (
-          bioassemblies.BioassemblyData | Literal[_UNSET] | None
-      ) = _UNSET,
-      chemical_components_data: (
-          struc_chem_comps.ChemicalComponentsData | Literal[_UNSET] | None
-      ) = _UNSET,
-  ) -> Self:
-    """Returns a shallow copy with the global columns updated."""
-
-    def select(field, default):
-      return field if field != _UNSET else default
-
-    name = select(name, self.name)
-    release_date = select(release_date, self.release_date)
-    resolution = select(resolution, self.resolution)
-    structure_method = select(structure_method, self.structure_method)
-    bioassembly_data = select(bioassembly_data, self.bioassembly_data)
-    chem_data = select(chemical_components_data, self.chemical_components_data)
-
-    return Structure(
-        name=name,
-        release_date=release_date,
-        resolution=resolution,
-        structure_method=structure_method,
-        bioassembly_data=bioassembly_data,
-        chemical_components_data=chem_data,
-        atoms=self._atoms,
-        residues=self._residues,
-        chains=self._chains,
-        bonds=self._bonds,
-    )
-
-  def copy_and_update_atoms(
-      self,
-      *,
-      atom_name: np.ndarray | None = None,
-      atom_element: np.ndarray | None = None,
-      atom_x: np.ndarray | None = None,
-      atom_y: np.ndarray | None = None,
-      atom_z: np.ndarray | None = None,
-      atom_b_factor: np.ndarray | None = None,
-      atom_occupancy: np.ndarray | None = None,
-  ) -> Self:
-    """Returns a shallow copy with the atoms table updated."""
-    new_atoms = structure_tables.Atoms(
-        key=self._atoms.key,
-        res_key=self._atoms.res_key,
-        chain_key=self._atoms.chain_key,
-        name=atom_name if atom_name is not None else self.atom_name,
-        element=atom_element if atom_element is not None else self.atom_element,
-        x=atom_x if atom_x is not None else self.atom_x,
-        y=atom_y if atom_y is not None else self.atom_y,
-        z=atom_z if atom_z is not None else self.atom_z,
-        b_factor=(
-            atom_b_factor if atom_b_factor is not None else self.atom_b_factor
-        ),
-        occupancy=(
-            atom_occupancy
-            if atom_occupancy is not None
-            else self.atom_occupancy
-        ),
-    )
-    return self.copy_and_update(atoms=new_atoms)
-
-  def copy_and_update_residues(
-      self,
-      *,
-      res_id: np.ndarray | None = None,
-      res_name: np.ndarray | None = None,
-      res_auth_seq_id: np.ndarray | None = None,
-      res_insertion_code: np.ndarray | None = None,
-  ) -> Self:
-    """Returns a shallow copy with the residues table updated."""
-    new_residues = structure_tables.Residues(
-        key=self._residues.key,
-        chain_key=self._residues.chain_key,
-        id=res_id if res_id is not None else self._residues.id,
-        name=res_name if res_name is not None else self._residues.name,
-        auth_seq_id=res_auth_seq_id
-        if res_auth_seq_id is not None
-        else self._residues.auth_seq_id,
-        insertion_code=res_insertion_code
-        if res_insertion_code is not None
-        else self._residues.insertion_code,
-    )
-    return self.copy_and_update(residues=new_residues)
-
-  def _cascade_delete(
-      self,
-      *,
-      chains: structure_tables.Chains | None = None,
-      residues: structure_tables.Residues | None = None,
-      atoms: structure_tables.Atoms | None = None,
-      bonds: structure_tables.Bonds | None = None,
-  ) -> StructureTables:
-    """Performs a cascade delete operation on the structure's tables.
-
-    Cascade delete ensures all the tables are consistent after any table fields
-    are being updated by cascading any deletions down the hierarchy of tables:
-    chains > residues > atoms > bonds.
-
-    E.g.: if a row from residues table is removed then all the atoms in that
-    residue will also be removed from the atoms table. In turn this cascades
-    also to the bond table, by removing any bond row which involves any of those
-    removed atoms. However the chains table will not be modified, even if
-    that was the only residue in its chain, because the chains table is above
-    the residues table in the hierarchy.
-
-    Args:
-      chains: An optional new chains table.
-      residues: An optional new residues table.
-      atoms: An optional new atoms table.
-      bonds: An optional new bonds table.
-
-    Returns:
-      A StructureTables object with the updated tables.
-    """
-    if chains_unchanged := chains is None:
-      chains = self._chains
-    if residues_unchanged := residues is None:
-      residues = self._residues
-    if atoms_unchanged := atoms is None:
-      atoms = self._atoms
-    if bonds is None:
-      bonds = self._bonds
-
-    if not chains_unchanged:
-      residues_mask = membership.isin(residues.chain_key, set(chains.key))  # pylint:disable=attribute-error
-      if not np.all(residues_mask):  # Only apply if this is not a no-op.
-        residues = residues[residues_mask]
-        residues_unchanged = False
-    if not residues_unchanged:
-      atoms_mask = membership.isin(atoms.res_key, set(residues.key))  # pylint:disable=attribute-error
-      if not np.all(atoms_mask):  # Only apply if this is not a no-op.
-        atoms = atoms[atoms_mask]
-        atoms_unchanged = False
-    if not atoms_unchanged:
-      bonds = bonds.restrict_to_atoms(atoms.key)
-    return StructureTables(
-        chains=chains, residues=residues, atoms=atoms, bonds=bonds
-    )
-
-  def filter(
-      self,
-      mask: np.ndarray | None = None,
-      *,
-      apply_per_element: bool = False,
-      invert: bool = False,
-      cascade_delete: CascadeDelete = CascadeDelete.CHAINS,
-      **predicate_by_field_name: table.FilterPredicate,
-  ) -> Self:
-    """Filters the structure by field values and returns a new structure.
-
-    Predicates are specified as keyword arguments, with names following the
-    pattern: <table_name>_<col_name>, where table_name := (chain|res|atom).
-    For instance the auth_seq_id column in the residues table can be filtered
-    by passing `res_auth_seq_id=pred_value`. The full list of valid options
-    are defined in the `col_by_field_name` fields on the different Table
-    dataclasses.
-
-    Predicate values can be either:
-      1. A constant value, e.g. 'CA'. In this case then only rows that match
-        this value for the given field are retained.
-      2. A (non-string) iterable e.g. ('A', 'B'). In this
-        case then rows are retained if they match any of the provided values for
-        the given field.
-      3. A boolean function e.g. lambda b_fac: b_fac < 100.0.
-        In this case then only rows that evaluate to True are retained. By
-        default this function's parameter is expected to be an array, unless
-        apply_per_element=True.
-
-    Example usage:
-      # Filter to backbone atoms in residues up to 100 in chain B.
-      filtered_struc = struc.filter(
-          chain_id='B',
-          atom_name=('N', 'CA', 'C'),
-          res_id=lambda res_id: res_id < 100)
-
-    Example usage where predicate must be applied per-element:
-      # Filter to residues with IDs in either [1, 100) or [300, 400).
-      ranges = ((1, 100), (300, 400))
-      filtered_struc = struc.filter(
-          res_id=lambda i: np.any([start <= i < end for start, end in ranges]),
-          apply_per_element=True)
-
-    Example usage of providing a raw mask:
-      filtered_struc = struc.filter(struc.atom_b_factor < 10.0)
-
-    Args:
-      mask: An optional boolean NumPy array with length equal to num_atoms. If
-        provided then this will be combined with the other predicates so that an
-        atom is included if it is masked-in *and* matches all the predicates.
-      apply_per_element: Whether apply predicates to each element individually,
-        or to pass the whole column array to the predicate.
-      invert: Whether to remove, rather than retain, the entities which match
-        the specified predicates.
-      cascade_delete: Whether to remove residues and chains which are left
-        unresolved in a cascade. filter operates on the atoms table, removing
-        atoms which match the predicate. If all atoms in a residue are removed,
-        the residue is "unresolved". The value of this argument then determines
-        whether such residues and their parent chains should be deleted. FULL
-        implies that all unresolved residues should be deleted, and any chains
-        which are left with no resolved residues should be deleted. CHAINS is
-        the default behaviour - only chains with no resolved residues, and their
-        child residues are deleted. Unresolved residues in partially resolved
-        chains remain. NONE implies that no unresolved residues or chains should
-        be deleted.
-      **predicate_by_field_name: A mapping from field name to a predicate.
-        Filtered columns must be 1D arrays. If multiple fields are provided as
-        keyword arguments then each predicate is applied and the results are
-        combined using a boolean AND operation, so an atom is only retained if
-        it passes all predicates.
-
-    Returns:
-      A new structure representing a filtered version of the current structure.
-
-    Raises:
-      ValueError: If mask is provided and is not a bool array with shape
-        (num_atoms,).
-    """
-    chain_predicates, res_predicates, atom_predicates = (
-        _unpack_filter_predicates(predicate_by_field_name)
-    )
-    # Get boolean masks for each table. These are None if none of the filter
-    # parameters affect the table in question.
-    chain_mask = self._chains.make_filter_mask(
-        **chain_predicates, apply_per_element=apply_per_element
-    )
-    res_mask = self._residues.make_filter_mask(
-        **res_predicates, apply_per_element=apply_per_element
-    )
-    atom_mask = self._atoms.make_filter_mask(
-        mask, **atom_predicates, apply_per_element=apply_per_element
-    )
-    if atom_mask is None:
-      atom_mask = np.ones((self._atoms.size,), dtype=bool)
-
-    # Remove atoms that belong to filtered out chains.
-    if chain_mask is not None:
-      atom_chain_mask = membership.isin(
-          self._atoms.chain_key, set(self._chains.key[chain_mask])
-      )
-      np.logical_and(atom_mask, atom_chain_mask, out=atom_mask)
-
-    # Remove atoms that belong to filtered out residues.
-    if res_mask is not None:
-      atom_res_mask = membership.isin(
-          self._atoms.res_key, set(self._residues.key[res_mask])
-      )
-      np.logical_and(atom_mask, atom_res_mask, out=atom_mask)
-
-    final_atom_mask = ~atom_mask if invert else atom_mask
-
-    if cascade_delete == CascadeDelete.NONE and np.all(final_atom_mask):
-      return self  # Shortcut: The filter is a no-op, so just return itself.
-
-    filtered_atoms = typing.cast(
-        structure_tables.Atoms, self._atoms[final_atom_mask]
-    )
-
-    match cascade_delete:
-      case CascadeDelete.FULL:
-        nonempty_residues_mask = np.isin(
-            self._residues.key, filtered_atoms.res_key
-        )
-        filtered_residues = self._residues[nonempty_residues_mask]
-        nonempty_chain_mask = np.isin(
-            self._chains.key, filtered_atoms.chain_key
-        )
-        filtered_chains = self._chains[nonempty_chain_mask]
-        updated_tables = self._cascade_delete(
-            chains=filtered_chains,
-            residues=filtered_residues,
-            atoms=filtered_atoms,
-        )
-      case CascadeDelete.CHAINS:
-        # To match v1 behavior we remove chains that have no atoms remaining,
-        # and we remove residues in those chains.
-        # NB we do not remove empty residues.
-        nonempty_chain_mask = membership.isin(
-            self._chains.key, set(filtered_atoms.chain_key)
-        )
-        filtered_chains = self._chains[nonempty_chain_mask]
-        updated_tables = self._cascade_delete(
-            chains=filtered_chains, atoms=filtered_atoms
-        )
-      case CascadeDelete.NONE:
-        updated_tables = self._cascade_delete(atoms=filtered_atoms)
-      case _:
-        raise ValueError(f'Unknown cascade_delete behaviour: {cascade_delete}')
-    return self.copy_and_update(
-        chains=updated_tables.chains,
-        residues=updated_tables.residues,
-        atoms=updated_tables.atoms,
-        bonds=updated_tables.bonds,
-        skip_validation=True,
-    )
-
-  def filter_out(self, *args, **kwargs) -> Self:
-    """Returns a new structure with the specified elements removed."""
-    return self.filter(*args, invert=True, **kwargs)
-
-  def filter_to_entity_type(
-      self,
-      *,
-      protein: bool = False,
-      rna: bool = False,
-      dna: bool = False,
-      dna_rna_hybrid: bool = False,
-      ligand: bool = False,
-      water: bool = False,
-  ) -> Self:
-    """Filters the structure to only include the selected entity types.
-
-    This convenience method abstracts away the specifics of mmCIF entity
-    type names which, especially for ligands, are non-trivial.
-
-    Args:
-      protein: Whether to include protein (polypeptide(L)) chains.
-      rna: Whether to include RNA chains.
-      dna: Whether to include DNA chains.
-      dna_rna_hybrid: Whether to include DNA RNA hybrid chains.
-      ligand: Whether to include ligand (i.e. not polymer) chains.
-      water: Whether to include water chains.
-
-    Returns:
-      The filtered structure.
-    """
-    include_types = []
-    if protein:
-      include_types.append(mmcif_names.PROTEIN_CHAIN)
-    if rna:
-      include_types.append(mmcif_names.RNA_CHAIN)
-    if dna:
-      include_types.append(mmcif_names.DNA_CHAIN)
-    if dna_rna_hybrid:
-      include_types.append(mmcif_names.DNA_RNA_HYBRID_CHAIN)
-    if ligand:
-      include_types.extend(mmcif_names.LIGAND_CHAIN_TYPES)
-    if water:
-      include_types.append(mmcif_names.WATER)
-    return self.filter(chain_type=include_types)
-
-  def get_stoichiometry(
-      self, *, fix_non_standard_polymer_res: bool = False
-  ) -> Sequence[int]:
-    """Returns the structure's stoichiometry using chain_res_name_sequence.
-
-    Note that everything is considered (protein, RNA, DNA, ligands) except for
-    water molecules. If you are interested only in a certain type of entities,
-    filter them out before calling this method.
-
-    Args:
-      fix_non_standard_polymer_res: If True, maps non standard residues in
-        protein / RNA / DNA chains to standard residues (e.g. MSE -> MET) or UNK
-        / N if a match is not found.
-
-    Returns:
-      A list of integers, one for each unique chain in the structure,
-      determining the number of that chain appearing in the structure. The
-      numbers are sorted highest to lowest. E.g. for an A3B2 protein this method
-      will return [3, 2].
-    """
-    filtered = self.filter_to_entity_type(
-        protein=True,
-        rna=True,
-        dna=True,
-        dna_rna_hybrid=True,
-        ligand=True,
-        water=False,
-    )
-    seqs = filtered.chain_res_name_sequence(
-        include_missing_residues=True,
-        fix_non_standard_polymer_res=fix_non_standard_polymer_res,
-    )
-
-    unique_seq_counts = collections.Counter(seqs.values())
-    return sorted(unique_seq_counts.values(), reverse=True)
-
-  def without_hydrogen(self) -> Self:
-    """Returns the structure without hydrogen atoms."""
-    return self.filter(
-        np.logical_and(self._atoms.element != 'H', self._atoms.element != 'D')
-    )
-
-  def without_terminal_oxygens(self) -> Self:
-    """Returns the structure without terminal oxygen atoms."""
-    terminal_oxygen_filter = np.zeros(self.num_atoms, dtype=bool)
-    for chain_type, atom_name in mmcif_names.TERMINAL_OXYGENS.items():
-      chain_keys = self._chains.key[self._chains.type == chain_type]
-      chain_atom_filter = np.logical_and(
-          self._atoms.name == atom_name,
-          np.isin(self._atoms.chain_key, chain_keys),
-      )
-      np.logical_or(
-          terminal_oxygen_filter, chain_atom_filter, out=terminal_oxygen_filter
-      )
-    return self.filter_out(terminal_oxygen_filter)
-
-  def reset_author_naming_scheme(self) -> Self:
-    """Remove author chain/residue ids, entity info and use internal ids."""
-    new_chains = structure_tables.Chains(
-        key=self._chains.key,
-        id=self._chains.id,
-        type=self._chains.type,
-        auth_asym_id=self._chains.id,
-        entity_id=np.arange(1, self.num_chains + 1).astype(str).astype(object),
-        entity_desc=np.full(self.num_chains, '.', dtype=object),
-    )
-    new_residues = structure_tables.Residues(
-        key=self._residues.key,
-        chain_key=self._residues.chain_key,
-        id=self._residues.id,
-        name=self._residues.name,
-        auth_seq_id=self._residues.id.astype(str).astype(object),
-        insertion_code=np.full(
-            self.num_residues(count_unresolved=True), '?', dtype=object
-        ),
-    )
-    return self.copy_and_update(
-        chains=new_chains, residues=new_residues, skip_validation=True
-    )
-
-  def filter_residues(self, res_mask: np.ndarray) -> Self:
-    """Filter resolved residues using a boolean mask."""
-    required_shape = (self.num_residues(count_unresolved=False),)
-    if res_mask.shape != required_shape:
-      raise ValueError(
-          f'res_mask must have shape {required_shape}. Got: {res_mask.shape}.'
-      )
-    if res_mask.dtype != bool:
-      raise ValueError(f'res_mask must have dtype bool. Got: {res_mask.dtype}.')
-
-    filtered_residues = self.present_residues.filter(res_mask)
-    atom_mask = np.isin(self._atoms.res_key, filtered_residues.key)
-    return self.filter(atom_mask)
-
-  def filter_coords(
-      self, coord_predicate: Callable[[np.ndarray], bool]
-  ) -> Self:
-    """Filter a structure's atoms by a function of their coordinates.
-
-    Args:
-      coord_predicate: A boolean function of coordinate vectors (shape (3,)).
-
-    Returns:
-      A Structure filtered so that only atoms with coords passing the predicate
-      function are present.
-
-    Raises:
-      ValueError: If the coords are not shaped (num_atom, 3).
-    """
-    coords = self.coords
-    if coords.ndim != 2 or coords.shape[-1] != 3:
-      raise ValueError(
-          f'coords should have shape (num_atom, 3). Got {coords.shape}.'
-      )
-    mask = np.vectorize(coord_predicate, signature='(n)->()')(coords)
-    # This use of _apply_atom_index_array is safe because a boolean mask is
-    # used, which means the chain/residue/atom ordering will stay unchanged.
-    return self._apply_atom_index_array(mask, skip_validation=True)
-
-  def filter_polymers_to_single_atom_per_res(
-      self,
-      representative_atom_by_chain_type: Mapping[
-          str, str
-      ] = mmcif_names.RESIDUE_REPRESENTATIVE_ATOMS,
-  ) -> Self:
-    """Filter to one representative atom per polymer residue, ligands unchanged.
-
-    Args:
-      representative_atom_by_chain_type: Chain type str to atom name, only atoms
-        with this name will be kept for this chain type. Chains types from the
-        structure not found in this mapping will keep all their atoms.
-
-    Returns:
-      A Structure filtered so that per chain types, only specified atoms are
-      present.
-    """
-    polymer_chain_keys = self._chains.key[
-        string_array.isin(
-            self._chains.type, set(representative_atom_by_chain_type)
-        )
-    ]
-    polymer_atoms_mask = np.isin(self._atoms.chain_key, polymer_chain_keys)
-
-    wanted_atom_by_chain_key = {
-        chain_key: representative_atom_by_chain_type.get(chain_type, None)
-        for chain_key, chain_type in zip(self._chains.key, self._chains.type)
-    }
-    wanted_atoms = string_array.remap(
-        self._atoms.chain_key.astype(object), mapping=wanted_atom_by_chain_key
-    )
-
-    representative_polymer_atoms_mask = polymer_atoms_mask & (
-        wanted_atoms == self._atoms.name
-    )
-
-    return self.filter(representative_polymer_atoms_mask | ~polymer_atoms_mask)
-
-  def drop_non_standard_protein_atoms(self, *, drop_oxt: bool = True) -> Self:
-    """Drops non-standard atom names from protein chains.
-
-    Args:
-      drop_oxt: If True, also drop terminal oxygens (OXT).
-
-    Returns:
-      A new Structure object where the protein chains have been filtered to
-        only contain atoms with names listed in `atom_types`
-        (including OXT unless `drop_oxt` is `True`). Non-protein chains are
-        unaltered.
-    """
-    allowed_names = set(atom_types.ATOM37)
-    if drop_oxt:
-      allowed_names = {n for n in allowed_names if n != atom_types.OXT}
-
-    return self.filter_out(
-        chain_type=mmcif_names.PROTEIN_CHAIN,
-        atom_name=lambda n: string_array.isin(n, allowed_names, invert=True),
-    )
-
-  def drop_non_standard_atoms(
-      self,
-      *,
-      ccd: chemical_components.Ccd,
-      drop_unk: bool,
-      drop_non_ccd: bool,
-      drop_terminal_oxygens: bool = False,
-  ) -> Self:
-    """Drops atoms that are not in the CCD for the given residue type."""
-
-    # We don't remove any atoms in UNL, as it has no standard atoms.
-    def _keep(atom_index: int) -> bool:
-      atom_name = self._atoms.name[atom_index]
-      res_name = self._residues.name[
-          self._residues.index_by_key[self._atoms.res_key[atom_index]]
-      ]
-      if drop_unk and res_name in residue_names.UNKNOWN_TYPES:
-        return False
-      else:
-        return (
-            (not drop_non_ccd and not ccd.get(res_name))
-            or atom_name in struc_chem_comps.get_res_atom_names(ccd, res_name)
-            or res_name == residue_names.UNL
-        )
-
-    standard_atom_mask = np.array(
-        [_keep(atom_i) for atom_i in range(self.num_atoms)], dtype=bool
-    )
-    standard_atoms = self.filter(mask=standard_atom_mask)
-    if drop_terminal_oxygens:
-      standard_atoms = standard_atoms.without_terminal_oxygens()
-    return standard_atoms
-
-  def find_chains_with_unknown_sequence(self) -> Sequence[str]:
-    """Returns a sequence of chain IDs that contain only unknown residues."""
-    unknown_sequences = []
-    for start, end in self.iter_chain_ranges():
-      try:
-        unknown_id = residue_names.UNKNOWN_TYPES.index(self.res_name[start])
-        if start + 1 == end or np.all(
-            self.res_name[start + 1 : end]
-            == residue_names.UNKNOWN_TYPES[unknown_id]
-        ):
-          unknown_sequences.append(self.chain_id[start])
-      except ValueError:
-        pass
-    return unknown_sequences
-
-  def add_bonds(
-      self,
-      bonded_atom_pairs: Sequence[
-          tuple[tuple[str, int, str], tuple[str, int, str]],
-      ],
-      bond_type: str | None = None,
-  ) -> Self:
-    """Returns a structure with new bonds added.
-
-    Args:
-      bonded_atom_pairs: A sequence of pairs of atoms, with one pair per bond.
-        Each element of the pair is a tuple of (chain_id, res_id, atom_name),
-        matching values from the respective fields of this structure. The first
-        element is the start atom, and the second atom is the end atom of the
-        bond.
-      bond_type: This type will be used for all bonds in the structure, where
-        type follows PDB scheme, e.g. unknown (?), hydrog, metalc, covale,
-        disulf.
-
-    Returns:
-      A copy of this structure with the new bonds added. If this structure has
-      bonds already then the new bonds are concatenated onto the end of the
-      old bonds. NB: bonds are not deduplicated.
-    """
-    atom_key_lookup: dict[tuple[str, str, None, str], int] = dict(
-        zip(self.atom_ids, self._atoms.key, strict=True)
-    )
-
-    # iter_atoms returns a 4-tuple (chain_id, res_id, ins_code, atom_name) but
-    # the insertion code is always None. It also uses string residue IDs.
-    def _to_internal_res_id(
-        bonded_atom_id: tuple[str, int, str],
-    ) -> tuple[str, str, None, str]:
-      return bonded_atom_id[0], str(bonded_atom_id[1]), None, bonded_atom_id[2]
-
-    from_atom_key = []
-    dest_atom_key = []
-    for from_atom, dest_atom in bonded_atom_pairs:
-      from_atom_key.append(atom_key_lookup[_to_internal_res_id(from_atom)])
-      dest_atom_key.append(atom_key_lookup[_to_internal_res_id(dest_atom)])
-    num_bonds = len(bonded_atom_pairs)
-    bonds_key = np.arange(num_bonds, dtype=np.int64)
-    from_atom_key = np.array(from_atom_key, dtype=np.int64)
-    dest_atom_key = np.array(dest_atom_key, dtype=np.int64)
-    all_unk_col = np.array(['?'] * num_bonds, dtype=object)
-    if bond_type is None:
-      bond_type_col = all_unk_col
-    else:
-      bond_type_col = np.full((num_bonds,), bond_type, dtype=object)
-
-    max_key = -1 if not self._bonds.size else np.max(self._bonds.key)
-    new_bonds = structure_tables.Bonds(
-        key=np.concatenate([self._bonds.key, bonds_key + max_key + 1]),
-        from_atom_key=np.concatenate(
-            [self._bonds.from_atom_key, from_atom_key]
-        ),
-        dest_atom_key=np.concatenate(
-            [self._bonds.dest_atom_key, dest_atom_key]
-        ),
-        type=np.concatenate([self._bonds.type, bond_type_col]),
-        role=np.concatenate([self._bonds.role, all_unk_col]),
-    )
-    return self.copy_and_update(bonds=new_bonds)
-
-  @property
-  def coords(self) -> np.ndarray:
-    """A [..., num_atom, 3] shaped array of atom coordinates."""
-    return np.stack([self._atoms.x, self._atoms.y, self._atoms.z], axis=-1)
-
-  def chain_single_letter_sequence(
-      self, include_missing_residues: bool = True
-  ) -> Mapping[str, str]:
-    """Returns a mapping from chain ID to a single letter residue sequence.
-
-    Args:
-      include_missing_residues: Whether to include residues that have no atoms.
-    """
-    res_table = (
-        self._residues if include_missing_residues else self.present_residues
-    )
-    residue_chain_boundaries = _get_change_indices(res_table.chain_key)
-    boundaries = self._iter_residue_ranges(
-        residue_chain_boundaries,
-        count_unresolved=include_missing_residues,
-    )
-    chain_keys = res_table.chain_key[residue_chain_boundaries]
-    chain_ids = self._chains.apply_array_to_column('id', chain_keys)
-    chain_types = self._chains.apply_array_to_column('type', chain_keys)
-    chain_seqs = {}
-    for idx, (start, end) in enumerate(boundaries):
-      chain_id = chain_ids[idx]
-      chain_type = chain_types[idx]
-      chain_res = res_table.name[start:end]
-      if chain_type in mmcif_names.PEPTIDE_CHAIN_TYPES:
-        unknown_default = 'X'
-      elif chain_type in mmcif_names.NUCLEIC_ACID_CHAIN_TYPES:
-        unknown_default = 'N'
-      else:
-        chain_seqs[chain_id] = 'X' * chain_res.size
-        continue
-
-      chain_res = string_array.remap(
-          chain_res,
-          mapping=residue_names.CCD_NAME_TO_ONE_LETTER,
-          inplace=False,
-          default_value=unknown_default,
-      )
-      chain_seqs[chain_id] = ''.join(chain_res.tolist())
-
-    return chain_seqs
-
-  def polymer_auth_asym_id_to_label_asym_id(
-      self,
-      *,
-      protein: bool = True,
-      rna: bool = True,
-      dna: bool = True,
-      other: bool = True,
-  ) -> Mapping[str, str]:
-    """Mapping from author chain ID to internal chain ID, polymers only.
-
-    This mapping is well defined only for polymers (protein, DNA, RNA), but not
-    for ligands or water.
-
-    E.g. if a structure had the following internal chain IDs (label_asym_id):
-      A (protein), B (DNA), C (ligand bound to A), D (ligand bound to A),
-      E (ligand bound to B).
-
-    Such structure would have this internal chain ID (label_asym_id) -> author
-    chain ID (auth_asym_id) mapping:
-      A -> A, B -> B, C -> A, D -> A, E -> B
-
-    This is a bijection only for polymers (A, B), but not for ligands.
-
-    Args:
-      protein: Whether to include protein (polypeptide(L)) chains.
-      rna: Whether to include RNA chains.
-      dna: Whether to include DNA chains.
-      other: Whether to include other polymer chains, e.g. RNA/DNA hybrid or
-        polypeptide(D). Note that include_other=True must be set in from_mmcif.
-
-    Returns:
-      A mapping from author chain ID to the internal (label) chain ID for the
-      given polymer types in the Structure, ligands/water are ignored.
-
-    Raises:
-      ValueError: If the mapping from internal chain IDs to author chain IDs is
-        not a bijection for polymer chains.
-    """
-    allowed_types = set()
-    if protein:
-      allowed_types.add(mmcif_names.PROTEIN_CHAIN)
-    if rna:
-      allowed_types.add(mmcif_names.RNA_CHAIN)
-    if dna:
-      allowed_types.add(mmcif_names.DNA_CHAIN)
-    if other:
-      non_standard_chain_types = (
-          mmcif_names.POLYMER_CHAIN_TYPES
-          - mmcif_names.STANDARD_POLYMER_CHAIN_TYPES
-      )
-      allowed_types |= non_standard_chain_types
-
-    auth_asym_id_to_label_asym_id = {}
-    for chain in self.iter_chains():
-      if chain['chain_type'] not in allowed_types:
-        continue
-      label_asym_id = chain['chain_id']
-      auth_asym_id = chain['chain_auth_asym_id']
-      # The mapping from author chain id to label chain id is only one-to-one if
-      # we restrict our attention to polymers. But check nevertheless.
-      if auth_asym_id in auth_asym_id_to_label_asym_id:
-        raise ValueError(
-            f'Author chain ID "{auth_asym_id}" does not have a unique mapping '
-            f'to internal chain ID "{label_asym_id}", it is already mapped to '
-            f'"{auth_asym_id_to_label_asym_id[auth_asym_id]}".'
-        )
-      auth_asym_id_to_label_asym_id[auth_asym_id] = label_asym_id
-
-    return auth_asym_id_to_label_asym_id
-
-  def polymer_author_chain_single_letter_sequence(
-      self,
-      *,
-      include_missing_residues: bool = True,
-      protein: bool = True,
-      rna: bool = True,
-      dna: bool = True,
-      other: bool = True,
-  ) -> Mapping[str, str]:
-    """Mapping from author chain ID to single letter aa sequence, polymers only.
-
-    This mapping is well defined only for polymers (protein, DNA, RNA), but not
-    for ligands or water.
-
-    Args:
-      include_missing_residues: If True then all residues will be returned for
-        each polymer chain present in the structure. This uses the all_residues
-        field and will include residues missing due to filtering operations as
-        well as e.g. unresolved residues specified in an mmCIF header.
-      protein: Whether to include protein (polypeptide(L)) chains.
-      rna: Whether to include RNA chains.
-      dna: Whether to include DNA chains.
-      other: Whether to include other polymer chains, e.g. RNA/DNA hybrid or
-        polypeptide(D). Note that include_other=True must be set in from_mmcif.
-
-    Returns:
-      A mapping from (author) chain IDs to their single-letter sequences for all
-      polymers in the Structure, ligands/water are ignored.
-
-    Raises:
-      ValueError: If the mapping from internal chain IDs to author chain IDs is
-        not a bijection for polymer chains.
-    """
-    label_chain_id_to_seq = self.chain_single_letter_sequence(
-        include_missing_residues=include_missing_residues
-    )
-    auth_to_label = self.polymer_auth_asym_id_to_label_asym_id(
-        protein=protein, rna=rna, dna=dna, other=other
-    )
-    return {
-        auth: label_chain_id_to_seq[label]
-        for auth, label in auth_to_label.items()
-    }
-
-  def chain_res_name_sequence(
-      self,
-      *,
-      include_missing_residues: bool = True,
-      fix_non_standard_polymer_res: bool = False,
-  ) -> Mapping[str, Sequence[str]]:
-    """A mapping from internal chain ID to a sequence of residue names.
-
-    The residue names are the full residue names rather than single letter
-    codes. For instance, for proteins these are the 3 letter CCD codes.
-
-    Args:
-      include_missing_residues: Whether to include residues with no atoms in the
-        returned sequences.
-      fix_non_standard_polymer_res: Whether to map non standard residues in
-        protein / RNA / DNA chains to standard residues (e.g. MSE -> MET) or UNK
-        / N if a match is not found.
-
-    Returns:
-      A mapping from (internal) chain IDs to a sequence of residue names.
-    """
-    res_table = (
-        self._residues if include_missing_residues else self.present_residues
-    )
-    residue_chain_boundaries = _get_change_indices(res_table.chain_key)
-    boundaries = self._iter_residue_ranges(
-        residue_chain_boundaries, count_unresolved=include_missing_residues
-    )
-    chain_keys = res_table.chain_key[residue_chain_boundaries]
-    chain_ids = self._chains.apply_array_to_column('id', chain_keys)
-    chain_types = self._chains.apply_array_to_column('type', chain_keys)
-    chain_seqs = {}
-    for idx, (start, end) in enumerate(boundaries):
-      chain_id = chain_ids[idx]
-      chain_type = chain_types[idx]
-      chain_res = res_table.name[start:end]
-      if (
-          fix_non_standard_polymer_res
-          and chain_type in mmcif_names.POLYMER_CHAIN_TYPES
-      ):
-        chain_seqs[chain_id] = tuple(
-            fix_non_standard_polymer_residues(
-                res_names=chain_res, chain_type=chain_type
-            )
-        )
-      else:
-        chain_seqs[chain_id] = tuple(chain_res)
-
-    return chain_seqs
-
-  def fix_non_standard_polymer_res(
-      self,
-      res_mapper: Callable[
-          [np.ndarray, str], np.ndarray
-      ] = fix_non_standard_polymer_residues,
-  ) -> Self:
-    """Replaces non-standard polymer residues with standard alternatives or UNK.
-
-    e.g. maps 'ACE' -> 'UNK', 'MSE' -> 'MET'.
-
-    NB: Only fixes the residue names, but does not fix the atom names.
-    E.g., 'MSE' will be renamed to 'MET' but its 'SE' atom will not be renamed
-    to 'S'. Fixing MSE should be done during conversion from mmcif with the
-    `fix_mse_residues` flag.
-
-    Args:
-      res_mapper: An optional function that accepts a numpy array of residue
-        names and chain_type, and returns an array with fixed res_names. This
-        defaults to fix_non_standard_polymer_residues.
-
-    Returns:
-      A Structure containing only standard residue types (or 'UNK') in its
-      polymer chains.
-    """
-    fixed_res_name = self._residues.name.copy()
-    chain_change_indices = _get_change_indices(self._residues.chain_key)
-    for start, end in self._iter_atom_ranges(chain_change_indices):
-      chain_key = self._residues.chain_key[start]
-      chain_type = self._chains.type[self._chains.index_by_key[chain_key]]
-      if chain_type not in mmcif_names.POLYMER_CHAIN_TYPES:
-        continue  # We don't need to change anything for non-polymers.
-      fixed_res_name[start:end] = res_mapper(
-          fixed_res_name[start:end], chain_type
-      )
-    fixed_residues = self._residues.copy_and_update(name=fixed_res_name)
-    return self.copy_and_update(residues=fixed_residues, skip_validation=True)
-
-  @property
-  def slice_leading_dims(self) -> '_LeadingDimSlice':
-    """Used to create a new Structure by slicing into the leading dimensions.
-
-    Example usage 1:
-
-    ```
-    final_state = multi_state_struc.slice_leading_dims[-1]
-    ```
-
-    Example usage 2:
-
-    ```
-    # Structure has leading batch and time dimensions.
-    # Get final 3 time frames from first two batch elements.
-    sliced_strucs = batched_trajectories.slice_leading_dims[:2, -3:]
-    ```
-    """
-    return _LeadingDimSlice(self)
-
-  def unstack(self, axis: int = 0) -> Sequence[Self]:
-    """Unstacks a multi-model structure into a list of Structures.
-
-    This method is the inverse of `stack`.
-
-    Example usage:
-    ```
-    strucs = multi_dim_struc.unstack(axis=0)
-    ```
-
-    Args:
-      axis: The axis to unstack over. The structures in the returned list won't
-        have this axis in their coordinate of b-factor fields.
-
-    Returns:
-      A list of `Structure`s with length equal to the size of the specified
-      axis in the coorinate field arrays.
-
-    Raises:
-      IndexError: If axis does not refer to one of the leading dimensions of
-        `self.atoms_table.size`.
-    """
-    ndim = self._atoms.ndim
-    if not (-ndim <= axis < ndim):
-      raise IndexError(
-          f'{axis=} is out of range for atom coordinate fields with {ndim=}.'
-      )
-    elif axis < 0:
-      axis += ndim
-    if axis == ndim - 1:
-      raise IndexError(
-          'axis must refer to one of the leading dimensions, not the final '
-          f'dimension. The atom fields have {ndim=} and {axis=} was specified.'
-      )
-    unstacked = []
-    leading_dim_slice = self.slice_leading_dims  # Compute once here.
-    for i in range(self._atoms.shape[axis]):
-      slice_i = (slice(None),) * axis + (i,)
-      unstacked.append(leading_dim_slice[slice_i])
-    return unstacked
-
-  def split_by_chain(self) -> Sequence[Self]:
-    """Splits a Structure into single-chain Structures, one for each chain.
-
-    The obtained structures can be merged back together into the original
-    structure using the `concat` function.
-
-    Returns:
-      A list of `Structure`s, one for each chain. The order is the same as the
-      chain order in the original Structure.
-    """
-    return [self.filter(chain_id=chain_id) for chain_id in self.chains]
-
-  def transform_states_to_chains(self) -> Self:
-    """Transforms states to chains.
-
-    A multi-state protein structure will be transformed to a multi-chain
-    single-state protein structure. Useful for visualising multiples states to
-    examine diversity. This structure's coordinate fields must have shape
-    `(num_states, num_atoms)`.
-
-    Returns:
-      A new `Structure`, based on this structure, but with the multiple states
-      now represented as `num_states * num_chains` chains in a
-      single-state protein.
-
-    Raises:
-      ValueError: If this structure's array fields don't have shape
-        `(num_states, num_atoms)`.
-    """
-    if self._atoms.ndim != 2:
-      raise ValueError(
-          'Coordinate field tensor must have 2 dimensions: '
-          f'(num_states, num_atoms), got {self._atoms.ndim}.'
-      )
-    return concat(self.unstack(axis=0))
-
-  def merge_chains(
-      self,
-      *,
-      chain_groups: Sequence[Sequence[str]],
-      chain_group_ids: Sequence[str] | None = None,
-      chain_group_types: Sequence[str] | None = None,
-      chain_group_entity_ids: Sequence[str] | None = None,
-  ) -> Self:
-    """Merges chains in each group into a single chain.
-
-    If a Structure has chains A, B, C, D, E, and
-    `merge_chains([[A, C], [B, D], [E]])` is called, the new Structure will have
-    3 chains A, B, C, the first being concatenation of A+C, the second B+D, the
-    third just the original chain E.
-
-    Args:
-      chain_groups: Each group defines what chains should be merged into a
-        single chain. The output structure will therefore have len(chain_groups)
-        chains. Residue IDs (label and author) are renumbered to preserve
-        uniqueness within new chains. Order of chain groups and within each
-        group matters.
-      chain_group_ids: Optional sequence of new chain IDs for each group. If not
-        given, the new internal chain IDs (label_asym_id) are assigned in the
-        standard mmCIF order (i.e. A, B, ..., Z, AA, BA, CA, ...). Author chain
-        names (auth_asym_id) are set to be equal to the new internal chain IDs.
-      chain_group_types: Optional sequence of new chain types for each group. If
-        not given, only chains with the same type can be merged.
-      chain_group_entity_ids: Optional sequence of new entity IDs for each
-        group. If not given, the new internal entity IDs (entity_id) are
-        assigned in the standard mmCIF order (i.e. 1, 2, 3, ...). Entity
-        descriptions (entity_desc) are set to '.' for each chain.
-
-    Returns:
-      A new `Structure` with chains merged together into a single chain within
-      each chain group.
-
-    Raises:
-      ValueError: If chain_group_ids or chain_group_types are given but don't
-        match the length of chain_groups.
-      ValueError: If the chain IDs in the flattened chain_groups don't match the
-        chain IDs in the Structure.
-      ValueError: If chains in any of the groups don't have the same chain type.
-    """
-    if chain_group_ids and len(chain_group_ids) != len(chain_groups):
-      raise ValueError(
-          'chain_group_ids must the same length as chain_groups: '
-          f'{len(chain_group_ids)=} != {len(chain_groups)=}'
-      )
-    if chain_group_types and len(chain_group_types) != len(chain_groups):
-      raise ValueError(
-          'chain_group_types must the same length as chain_groups: '
-          f'{len(chain_group_types)=} != {len(chain_groups)=}'
-      )
-    if chain_group_entity_ids and len(chain_group_entity_ids) != len(
-        chain_groups
-    ):
-      raise ValueError(
-          'chain_group_entity_ids must the same length as chain_groups: '
-          f'{len(chain_group_entity_ids)=} != {len(chain_groups)=}'
-      )
-
-    flattened = sorted(itertools.chain.from_iterable(chain_groups))
-    if flattened != sorted(self.chains):
-      raise ValueError(
-          'IDs in chain groups do not match Structure chain IDs: '
-          f'{chain_groups=}, chains={self.chains}'
-      )
-
-    new_chain_key_by_chain_id = {}
-    for new_chain_key, group_chain_ids in enumerate(chain_groups):
-      for chain_id in group_chain_ids:
-        new_chain_key_by_chain_id[chain_id] = new_chain_key
-
-    chain_key_remap = {}
-    new_chain_type_by_chain_key = {}
-    for old_chain_key, old_chain_id, old_chain_type in zip(
-        self._chains.key, self._chains.id, self._chains.type
-    ):
-      new_chain_key = new_chain_key_by_chain_id[old_chain_id]
-      chain_key_remap[old_chain_key] = new_chain_key
-
-      if new_chain_key not in new_chain_type_by_chain_key:
-        new_chain_type_by_chain_key[new_chain_key] = old_chain_type
-      elif not chain_group_types:
-        if new_chain_type_by_chain_key[new_chain_key] != old_chain_type:
-          bad_types = [
-              f'{cid}: {self._chains.type[np.where(self._chains.id == cid)][0]}'
-              for cid in chain_groups[new_chain_key]
-          ]
-          raise ValueError(
-              'Inconsistent chain types within group:\n' + '\n'.join(bad_types)
-          )
-
-    new_chain_key = np.arange(len(chain_groups), dtype=np.int64)
-    if chain_group_ids:
-      new_chain_id = np.array(chain_group_ids, dtype=object)
-    else:
-      new_chain_id = np.array(
-          [mmcif.int_id_to_str_id(k) for k in new_chain_key + 1], dtype=object
-      )
-    if chain_group_types:
-      new_chain_type = np.array(chain_group_types, dtype=object)
-    else:
-      new_chain_type = np.array(
-          [new_chain_type_by_chain_key[k] for k in new_chain_key], dtype=object
-      )
-    if chain_group_entity_ids:
-      new_chain_entity_id = np.array(chain_group_entity_ids, dtype=object)
-    else:
-      new_chain_entity_id = np.char.mod('%d', new_chain_key + 1).astype(object)
-    new_chains = structure_tables.Chains(
-        key=new_chain_key,
-        id=new_chain_id,
-        type=new_chain_type,
-        auth_asym_id=new_chain_id,
-        entity_id=new_chain_entity_id,
-        entity_desc=np.full(len(chain_groups), fill_value='.', dtype=object),
-    )
-
-    # Remap chain keys and sort residues to match the chain table order.
-    new_residues = self._residues.copy_and_remap(chain_key=chain_key_remap)
-    new_residues = new_residues.apply_index(
-        np.argsort(new_residues.chain_key, kind='stable')
-    )
-    # Renumber uniquely residues in each chain.
-    indices = np.arange(new_residues.chain_key.size, dtype=np.int32)
-    new_res_ids = (indices + 1) - np.maximum.accumulate(
-        indices * (new_residues.chain_key != np.roll(new_residues.chain_key, 1))
-    )
-    new_residues = new_residues.copy_and_update(
-        id=new_res_ids,
-        auth_seq_id=np.char.mod('%d', new_res_ids).astype(object),
-    )
-
-    # Remap chain keys and sort atoms to match the chain table order.
-    new_atoms = self._atoms.copy_and_remap(chain_key=chain_key_remap)
-    new_atoms = new_atoms.apply_index(
-        np.argsort(new_atoms.chain_key, kind='stable')
-    )
-
-    return self.copy_and_update(
-        chains=new_chains,
-        residues=new_residues,
-        atoms=new_atoms,
-        bonds=self._bonds,
-    )
-
-  def to_res_arrays(
-      self,
-      *,
-      include_missing_residues: bool,
-      atom_order: Mapping[str, int] = atom_types.ATOM37_ORDER,
-  ) -> tuple[np.ndarray, np.ndarray]:
-    """Returns an atom position and atom mask array with a num_res dimension.
-
-    NB: All residues in the structure will appear in the residue dimension but
-    atoms will only have a True (1.0) mask value if the residue + atom
-    combination is defined in `atom_order`. E.g. for the standard ATOM37_ORDER,
-    atoms are guaranteed to be present only for standard protein residues.
-
-    Args:
-      include_missing_residues: If True then the res arrays will include rows
-        for missing residues where all atoms will be masked out. Otherwise these
-        will simply be skipped.
-      atom_order: Atom order mapping atom names to their index in the atom
-        dimension of the returned arrays. Default is atom_order for proteins,
-        choose atom_types.ATOM29_ORDER for nucleics.
-
-    Returns:
-      A pair of arrays:
-        * atom_positions: [num_res, atom_type_num, 3] float32 array of coords.
-        * atom_mask: [num_res, atom_type_num] float32 atom mask denoting
-          which atoms are present in this Structure.
-    """
-    num_res = self.num_residues(count_unresolved=include_missing_residues)
-    atom_type_num = len(atom_order)
-    atom_positions = np.zeros((num_res, atom_type_num, 3), dtype=np.float32)
-    atom_mask = np.zeros((num_res, atom_type_num), dtype=np.float32)
-
-    all_residues = None if not include_missing_residues else self.all_residues
-    for i, atom in enumerate_residues(self.iter_atoms(), all_residues):
-      atom_idx = atom_order.get(atom['atom_name'])
-      if atom_idx is not None:
-        atom_positions[i, atom_idx, 0] = atom['atom_x']
-        atom_positions[i, atom_idx, 1] = atom['atom_y']
-        atom_positions[i, atom_idx, 2] = atom['atom_z']
-        atom_mask[i, atom_idx] = 1.0
-
-    return atom_positions, atom_mask
-
-  def to_res_atom_lists(
-      self, *, include_missing_residues: bool
-  ) -> Sequence[Sequence[Mapping[str, Any]]]:
-    """Returns list of atom dictionaries grouped by residue.
-
-    If this is a multi-model structure, each atom will store its fields
-    atom_x, atom_y, atom_z, and atom_b_factor as Numpy arrays of shape of the
-    leading dimension(s). If this is a single-mode structure, these fields will
-    just be scalars.
-
-    Args:
-      include_missing_residues: If True, then the output list will contain an
-        empty list of atoms for missing residues. Otherwise missing residues
-        will simply be skipped.
-
-    Returns:
-      A list of size `num_res`. Each element in the list represents atoms of one
-      residue. If a residue is present is present, the list will contain an atom
-      dictionary for every atom present in that residue. If a residue is missing
-      and `include_missing_residues=True`, the list for that missing residue
-      will be empty.
-    """
-    num_res = self.num_residues(count_unresolved=include_missing_residues)
-    residue_atoms = [[] for _ in range(num_res)]
-    all_residues = None if not include_missing_residues else self.all_residues
-
-    # We could yield directly in this loop but the code would be more complex.
-    # Let's optimise if memory usage is an issue.
-    for res_index, atom in enumerate_residues(self.iter_atoms(), all_residues):
-      residue_atoms[res_index].append(atom)
-
-    return residue_atoms
-
-  def reorder_chains(self, new_order: Sequence[str]) -> Self:
-    """Reorders tables so that the label_asym_ids are in the given order.
-
-    This method changes the order of the chains, residues, and atoms tables so
-    that they are all consistent with each other. Moreover, it remaps chain keys
-    so that they stay monotonically increasing in chains/residues/atoms tables.
-
-    Args:
-      new_order: The order in which the chain IDs (label_asym_id) should be.
-        This must be a permutation of the current chain IDs.
-
-    Returns:
-      A structure with chains reorded.
-    """
-    if len(new_order) != len(self.chains):
-      raise ValueError(
-          f'The new number of chains ({len(new_order)}) does not match the '
-          f'current number of chains ({len(self.chains)}).'
-      )
-    new_chain_set = set(new_order)
-    if len(new_chain_set) != len(new_order):
-      raise ValueError(f'The new order {new_order} contains non-unique IDs.')
-    if new_chain_set.symmetric_difference(set(self.chains)):
-      raise ValueError(
-          f'New chain IDs {new_order} do not match the old {set(self.chains)}'
-      )
-
-    if self.chains == tuple(new_order):
-      return self  # Shortcut: the new order is the same as the current one.
-
-    desired_chain_id_pos = {chain_id: i for i, chain_id in enumerate(new_order)}
-
-    current_chain_index_order = np.empty(self.num_chains, dtype=np.int64)
-    for index, old_chain_id in enumerate(self._chains.id):
-      current_chain_index_order[index] = desired_chain_id_pos[old_chain_id]
-    chain_reorder = np.argsort(current_chain_index_order, kind='stable')
-    chain_key_map = dict(
-        zip(self._chains.key[chain_reorder], range(self.num_chains))
-    )
-    chains = self._chains.apply_index(chain_reorder)
-    chains = chains.copy_and_remap(key=chain_key_map)
-
-    # The stable sort keeps the original residue ordering within each chain.
-    residues = self._residues.copy_and_remap(chain_key=chain_key_map)
-    residue_reorder = np.argsort(residues.chain_key, kind='stable')
-    residues = residues.apply_index(residue_reorder)
-
-    # The stable sort keeps the original atom ordering within each chain.
-    atoms = self._atoms.copy_and_remap(chain_key=chain_key_map)
-    atoms_reorder = np.argsort(atoms.chain_key, kind='stable')
-    atoms = atoms.apply_index(atoms_reorder)
-
-    # Bonds unchanged - each references 2 atom keys, hence ordering not defined.
-    return self.copy_and_update(chains=chains, residues=residues, atoms=atoms)
-
-  def rename_auth_asym_ids(self, new_id_by_old_id: Mapping[str, str]) -> Self:
-    """Returns a new structure with renamed author chain IDs (auth_asym_ids).
-
-    Args:
-      new_id_by_old_id: A mapping from original auth_asym_ids to their new
-        values. Any auth_asym_ids in this structure that are not in the mapping
-        will remain unchanged.
-
-    Raises:
-      ValueError: If any two previously distinct polymer chains do not have
-        unique names anymore after the rename.
-    """
-    mapped_chains = self._chains.copy_and_remap(auth_asym_id=new_id_by_old_id)
-    mapped_polymer_ids = mapped_chains.filter(
-        type=mmcif_names.POLYMER_CHAIN_TYPES
-    ).auth_asym_id
-    if len(mapped_polymer_ids) != len(set(mapped_polymer_ids)):
-      raise ValueError(
-          'The new polymer auth_asym_ids are not unique:'
-          f' {sorted(mapped_polymer_ids)}.'
-      )
-    return self.copy_and_update(chains=mapped_chains, skip_validation=True)
-
-  def rename_chain_ids(self, new_id_by_old_id: Mapping[str, str]) -> Self:
-    """Returns a new structure with renamed chain IDs (label_asym_ids).
-
-    The chains' auth_asym_ids will be updated to be identical to the chain ID
-    since there isn't one unambiguous way to maintain the auth_asym_ids after
-    renaming the chain IDs (depending on whether you view the auth_asym_id as
-    more strongly associated with a given physical chain, or with a given
-    chain ID).
-
-    The residues' auth_seq_id will be updated to be identical to the residue ID
-    since they are strongly tied to the original author chain naming and keeping
-    them would be misleading.
-
-    Args:
-      new_id_by_old_id: A mapping from original chain ID to their new values.
-        Any chain IDs in this structure that are not in this mapping will remain
-        unchanged.
-
-    Returns:
-      A new structure with renamed chains (and bioassembly data if it is
-      present).
-
-    Raises:
-      ValueError: If any two previously distinct chains do not have unique names
-        anymore after the rename.
-    """
-    new_chain_id = string_array.remap(self._chains.id, new_id_by_old_id)
-    if len(new_chain_id) != len(set(new_chain_id)):
-      raise ValueError(f"New chain names aren't unique: {sorted(new_chain_id)}")
-
-    # Map label_asym_ids in the bioassembly data.
-    if self._bioassembly_data is None:
-      new_bioassembly_data = None
-    else:
-      new_bioassembly_data = self._bioassembly_data.rename_label_asym_ids(
-          new_id_by_old_id, present_chains=set(self.present_chains.id)
-      )
-
-    # Set author residue IDs to be the string version of internal residue IDs.
-    new_residues = self._residues.copy_and_update(
-        auth_seq_id=self._residues.id.astype(str).astype(object)
-    )
-
-    new_chains = self._chains.copy_and_update(
-        id=new_chain_id, auth_asym_id=new_chain_id
-    )
-
-    return self.copy_and_update(
-        bioassembly_data=new_bioassembly_data,
-        chains=new_chains,
-        residues=new_residues,
-        skip_validation=True,
-    )
-
-  @functools.cached_property
-  def chains(self) -> tuple[str, ...]:
-    """Ordered internal chain IDs (label_asym_id) present in the Structure."""
-    return tuple(self._chains.id)
-
-  def rename_res_name(
-      self,
-      res_name_map: Mapping[str, str],
-      fail_if_not_found: bool = True,
-  ) -> Self:
-    """Returns a copy of this structure with residues renamed.
-
-    Residue names in chemical components data will also be renamed.
-
-    Args:
-      res_name_map: A mapping from old residue names to new residue names. Any
-        residues that are not in this mapping will be left unchanged.
-      fail_if_not_found: Whether to fail if keys in the res_name_map mapping are
-        not found in this structure's residues' `name` column.
-
-    Raises:
-      ValueError: If `fail_if_not_found=True` and a residue name isn't found in
-        the residues table's `name` field.
-    """
-    res_name_set = set(self._residues.name)
-    if fail_if_not_found:
-      for res_name in res_name_map:
-        if res_name not in res_name_set:
-          raise ValueError(f'"{res_name}" not found in this structure.')
-    new_residues = self._residues.copy_and_remap(name=res_name_map)
-
-    if self._chemical_components_data is not None:
-      chem_comp = {
-          res_name_map.get(res_name, res_name): data
-          for res_name, data in self._chemical_components_data.chem_comp.items()
-      }
-      new_chem_comp = struc_chem_comps.ChemicalComponentsData(chem_comp)
-    else:
-      new_chem_comp = None
-
-    return self.copy_and_update(
-        residues=new_residues,
-        chemical_components_data=new_chem_comp,
-        skip_validation=True,
-    )
-
-  def remap_res_id(self, res_id_map: Mapping[str, Mapping[int, int]]) -> Self:
-    """Returns a copy of this structure with residue IDs remapped.
-
-    Example structure with 2 chains:
-    Chain A: residues 1, 2, 3; chain B: residues 6, 7, 8
-    res_id_map: {'A': {1: 1, 2: 5, 3: 6}, 'B': {6: 1, 7: 2, 8: 8}}
-    Will result in:
-    Chain A: residues 1, 5, 6; chain B: residues 1, 2, 8
-
-    Args:
-      res_id_map: A mapping from internal chain ID to a mapping from old residue
-        ID to new residue ID. A mapping must be provided for each residue in
-        each chain.
-
-    Raises:
-      KeyError: If residue ID in a given chain is not found in the mapping for
-        that chain.
-      ValueError: If residue IDs are not unique in each chain after remapping.
-    """
-    chain_ids = self._chains.apply_array_to_column(
-        column_name='id', arr=self._residues.chain_key
-    )
-    flat_res_id_map = {}
-    for chain_id, chain_res_id_map in res_id_map.items():
-      flat_res_id_map.update({
-          (chain_id, old_res_id): new_res_id
-          for old_res_id, new_res_id in chain_res_id_map.items()
-      })
-
-    try:
-      new_res_id = string_array.remap_multiple(
-          (chain_ids, self._residues.id), flat_res_id_map
-      )
-    except KeyError as e:
-      raise KeyError(
-          f'Could not find new residue ID for residue {e} in {res_id_map=}'
-      ) from e
-
-    residue_chain_boundaries = _get_change_indices(self._residues.chain_key)
-    res_boundaries = self._iter_residue_ranges(
-        residue_chain_boundaries, count_unresolved=True
-    )
-    for idx, (start, end) in enumerate(res_boundaries):
-      chain_id = chain_ids[idx]
-      chain_res_ids = new_res_id[start:end]
-      if len(chain_res_ids) != len(set(chain_res_ids)):
-        raise ValueError(
-            f'New residue IDs not unique in chain {chain_id}: {chain_res_ids}'
-        )
-
-    return self.copy_and_update(
-        residues=self._residues.copy_and_update(id=new_res_id.astype(np.int32)),
-        skip_validation=True,
-    )
-
-  def rename_chains_to_match(
-      self,
-      other: 'Structure',
-      *,
-      fuzzy_match_non_standard_res: bool = True,
-  ) -> Self:
-    """Returns a new structure with renamed chains to match another's.
-
-    Example:
-    This structure has chains: {'A': 'DEEP', 'B': 'MIND', 'C': 'MIND'}
-    Other structure has chains: {'X': 'DEEP', 'Z': 'MIND', 'Y': 'MIND'}
-
-    After calling this method, you will get a structure that has chains named:
-    {'X': 'DEEP', 'Z': 'MIND', Y: 'MIND'}
-
-    Args:
-      other: Another `Structure`. This provides the reference chain names that
-        is used to rename this structure's chains.
-      fuzzy_match_non_standard_res: If True, protein/RNA/DNA chains with the
-        same one letter sequence will be matched. e.g. "MET-MET-UNK1" will match
-        "MET-MSE-UNK2", since both will be mapped to "MMX". If False, we require
-        the full res_names to match.
-
-    Returns:
-      A new `Structure`, based on this structure, which has chains renamed to
-      match the other structure.
-    """
-    sequences = self.chain_res_name_sequence(
-        include_missing_residues=True,
-        fix_non_standard_polymer_res=fuzzy_match_non_standard_res,
-    )
-
-    other_sequences = other.chain_res_name_sequence(
-        include_missing_residues=True,
-        fix_non_standard_polymer_res=fuzzy_match_non_standard_res,
-    )
-
-    # Check that the sequences are the same.
-    sequence_counts = collections.Counter(sequences.values())
-    other_sequence_counts = collections.Counter(other_sequences.values())
-    if other_sequence_counts != sequence_counts:
-      raise ValueError(
-          'The other structure does not have the same sequences\n'
-          f' other: {other_sequence_counts}\n self: {sequence_counts}'
-      )
-
-    new_decoy_id_by_old_id = {}
-    used_chain_ids = set()
-    # Sort self keys and take min over other to make matching deterministic.
-    # The matching is arbitrary but this helps debugging.
-    for self_chain_id, self_seq in sorted(sequences.items()):
-      # Find corresponding chains in the other structure.
-      other_chain_id = min(
-          k
-          for k, v in other_sequences.items()
-          if v == self_seq and k not in used_chain_ids
-      )
-
-      new_decoy_id_by_old_id[self_chain_id] = other_chain_id
-      used_chain_ids.add(other_chain_id)
-
-    return self.rename_chain_ids(new_decoy_id_by_old_id)
-
-  def _apply_bioassembly_transform(
-      self, transform: bioassemblies.Transform
-  ) -> Self:
-    """Applies a bioassembly transform to this structure."""
-    base_struc = self.filter(chain_id=transform.chain_ids)
-    transformed_atoms = base_struc.atoms_table.copy_and_update_coords(
-        transform.apply_to_coords(base_struc.coords)
-    )
-    transformed_chains = base_struc.chains_table.copy_and_remap(
-        id=transform.chain_id_rename_map
-    )
-    # Set the transformed author chain ID to match the label chain ID.
-    transformed_chains = transformed_chains.copy_and_update(
-        auth_asym_id=transformed_chains.id
-    )
-    return base_struc.copy_and_update(
-        chains=transformed_chains,
-        atoms=transformed_atoms,
-        skip_validation=True,
-    )
-
-  def generate_bioassembly(self, assembly_id: str | None = None) -> Self:
-    """Generates a biological assembly as a new `Structure`.
-
-    When no assembly ID is provided this method produces a default assembly.
-    If this structure has no `bioassembly_data` then this returns itself
-    unchanged. Otherwise a default assembly ID is picked with
-    `BioassemblyData.get_default_assembly_id()`.
-
-    Args:
-      assembly_id: The assembly ID to generate, or None to generate a default
-        bioassembly.
-
-    Returns:
-      A new `Structure`, based on this one, representing the specified
-      bioassembly. Note that if the bioassembly contains copies of chains
-      in the original structure then they will be given new unique chain IDs.
-
-    Raises:
-      ValueError: If this structure's `bioassembly_data` is `None` and
-      `assembly_id` is not `None`.
-    """
-    if self._bioassembly_data is None:
-      if assembly_id is None:
-        return self
-      else:
-        raise ValueError(
-            f'Unset bioassembly_data, cannot generate assembly {assembly_id}'
-        )
-
-    if assembly_id is None:
-      assembly_id = self._bioassembly_data.get_default_assembly_id()
-
-    transformed_strucs = [
-        self._apply_bioassembly_transform(transform)
-        for transform in self._bioassembly_data.get_transforms(assembly_id)
-    ]
-
-    # We don't need to assign unique chain IDs because the bioassembly
-    # transform takes care of remapping chain IDs to be unique.
-    concatenated = concat(transformed_strucs, assign_unique_chain_ids=False)
-
-    # Copy over all scalar fields (e.g. name, release date, etc.) other than
-    # bioassembly_data because it relates only to the pre-transformed structure.
-    return concatenated.copy_and_update_globals(
-        name=self.name,
-        release_date=self.release_date,
-        resolution=self.resolution,
-        structure_method=self.structure_method,
-        bioassembly_data=None,
-        chemical_components_data=self.chemical_components_data,
-    )
-
-  def _to_mmcif_header(self) -> Mapping[str, Sequence[str]]:
-    raw_mmcif = collections.defaultdict(list)
-    raw_mmcif['data_'] = [self._name.replace(' ', '-')]
-    raw_mmcif['_entry.id'] = [self._name]
-
-    if self._release_date is not None:
-      date = [datetime.datetime.strftime(self._release_date, '%Y-%m-%d')]
-      raw_mmcif['_pdbx_audit_revision_history.revision_date'] = date
-      raw_mmcif['_pdbx_database_status.recvd_initial_deposition_date'] = date
-
-    if self._resolution is not None:
-      raw_mmcif['_refine.ls_d_res_high'] = ['%.2f' % self._resolution]
-
-    if self._structure_method is not None:
-      for method in self._structure_method.split(','):
-        raw_mmcif['_exptl.method'].append(method)
-
-    if self._bioassembly_data is not None:
-      raw_mmcif.update(self._bioassembly_data.to_mmcif_dict())
-
-    # Populate chemical components data for all residues of this Structure.
-    if self._chemical_components_data:
-      raw_mmcif.update(self._chemical_components_data.to_mmcif_dict())
-
-    # Add _software table to store version number used to generate mmCIF.
-    # Only required data items are used (+ _software.version).
-    raw_mmcif['_software.pdbx_ordinal'] = ['1']
-    raw_mmcif['_software.name'] = ['DeepMind Structure Class']
-    raw_mmcif['_software.version'] = [self._VERSION]
-    raw_mmcif['_software.classification'] = ['other']  # Required.
-
-    return raw_mmcif
-
-  def to_mmcif_dict(
-      self,
-      *,
-      coords_decimal_places: int = _COORDS_DECIMAL_PLACES,
-  ) -> mmcif.Mmcif:
-    """Returns an Mmcif representing the structure."""
-    header = self._to_mmcif_header()
-    sequence_tables = structure_tables.to_mmcif_sequence_and_entity_tables(
-        self._chains, self._residues, self._atoms.res_key
-    )
-    atom_and_bond_tables = structure_tables.to_mmcif_atom_site_and_bonds_table(
-        chains=self._chains,
-        residues=self._residues,
-        atoms=self._atoms,
-        bonds=self._bonds,
-        coords_decimal_places=coords_decimal_places,
-    )
-    return mmcif.Mmcif({**header, **sequence_tables, **atom_and_bond_tables})
-
-  def to_mmcif(
-      self, *, coords_decimal_places: int = _COORDS_DECIMAL_PLACES
-  ) -> str:
-    """Returns an mmCIF string representing the structure.
-
-    Args:
-      coords_decimal_places: The number of decimal places to keep for atom
-        coordinates, including trailing zeros.
-    """
-    return self.to_mmcif_dict(
-        coords_decimal_places=coords_decimal_places
-    ).to_string()
-
-
-class _LeadingDimSlice:
-  """Helper class for slicing the leading dimensions of a `Structure`.
-
-  Wraps a `Structure` instance and applies a slice operation to the coordinate
-  fields and other fields that may have leading dimensions (e.g. b_factor).
-
-  Example usage:
-    t0_struc = multi_state_struc.slice_leading_dims[0]
-  """
-
-  def __init__(self, struc: Structure):
-    self._struc = struc
-
-  def __getitem__(self, *args, **kwargs) -> Structure:
-    sliced_atom_cols = {}
-    for col_name in structure_tables.Atoms.multimodel_cols:
-      if (col := self._struc.atoms_table.get_column(col_name)).ndim > 1:
-        sliced_col = col.__getitem__(*args, **kwargs)
-        if (
-            not sliced_col.shape
-            or sliced_col.shape[-1] != self._struc.num_atoms
-        ):
-          raise ValueError(
-              'Coordinate slice cannot change final (atom) dimension.'
-          )
-        sliced_atom_cols[col_name] = sliced_col
-    sliced_atoms = self._struc.atoms_table.copy_and_update(**sliced_atom_cols)
-    return self._struc.copy_and_update(atoms=sliced_atoms, skip_validation=True)
-
-
-def stack(strucs: Sequence[Structure], axis: int = 0) -> Structure:
-  """Stacks multiple structures into a single multi-model Structure.
-
-  This function is the inverse of `Structure.unstack()`.
-
-  NB: this function assumes that every structure in `strucs` is identical
-  other than the coordinates and b-factors. Under this assumption we can safely
-  copy all these identical fields from the first element of strucs w.l.o.g.
-  However this is not checked in full detail as full comparison is expensive.
-  Instead this only checks that the `atom_name` field is identical, and that
-  the coordinates have the same shape.
-
-  Usage example:
-  ```
-  multi_model_struc = structure.stack(strucs, axis=0)
-  ```
-
-  Args:
-    strucs: A sequence of structures, each with the same atoms, but they may
-      have different coordinates and b-factors. If any b-factors are not None
-      then they must have the same shape as each of the coordinate fields.
-    axis: The axis in the returned structure that represents the different
-      structures in `strucs` and will have size `len(strucs)`. This cannot be
-      the final dimension as this is reserved for `num_atoms`.
-
-  Returns:
-    A `Structure` with the same atoms as the structures in `strucs` but with
-    all of their coordinates stacked into a new leading axis.
-
-  Raises:
-    ValueError: If `strucs` is empty.
-    ValueError: If `strucs` do not all have the same `atom_name` field.
-  """
-  if not strucs:
-    raise ValueError('Need at least one Structure to stack.')
-  struc_0, *other_strucs = strucs
-  for i, struc in enumerate(other_strucs, start=1):
-    # Check that every structure has the same atom name column.
-    # This check is intended to catch cases where the input structures might
-    # contain the same atoms, but in different orders. This won't catch every
-    # such case, e.g. if these are carbon-alpha-only structures, but should
-    # catch most cases.
-    if np.any(struc.atoms_table.name != struc_0.atoms_table.name):
-      raise ValueError(
-          f'strucs[0] and strucs[{i}] have mismatching atom name columns.'
-      )
-
-  stacked_atoms = struc_0.atoms_table.copy_and_update(
-      x=np.stack([s.atoms_table.x for s in strucs], axis=axis),
-      y=np.stack([s.atoms_table.y for s in strucs], axis=axis),
-      z=np.stack([s.atoms_table.z for s in strucs], axis=axis),
-      b_factor=np.stack([s.atoms_table.b_factor for s in strucs], axis=axis),
-      occupancy=np.stack([s.atoms_table.occupancy for s in strucs], axis=axis),
-  )
-  return struc_0.copy_and_update(atoms=stacked_atoms, skip_validation=True)
-
-
-def _assign_unique_chain_ids(
-    strucs: Iterable[Structure],
-) -> Sequence[Structure]:
-  """Creates a sequence of `Structure` objects with unique chain IDs.
-
-  Let e.g. [A, B] denote a structure of two chains A and B, then this function
-  performs the following kind of renaming operation:
-
-  e.g.: [Z], [C], [B, C] -> [A], [B], [C, D]
-
-  NB: This function uses Structure.rename_chain_ids which will define each
-  structure's chains.auth_asym_id to be identical to its chains.id columns.
-
-  Args:
-    strucs: Structures whose chains ids are to be uniquified.
-
-  Returns:
-    A sequence with the same number of elements as `strucs` but where each
-    element has had its chains renamed so that they aren't shared with any
-    other `Structure` in the sequence.
-  """
-  # Start counting at 1 because mmcif.int_id_to_str_id expects integers >= 1.
-  chain_counter = 1
-  strucs_with_new_chain_ids = []
-  for struc in strucs:
-    rename_map = {}
-    for chain_id in struc.chains:
-      rename_map[chain_id] = mmcif.int_id_to_str_id(chain_counter)
-      chain_counter += 1
-    renamed = struc.rename_chain_ids(rename_map)
-    strucs_with_new_chain_ids.append(renamed)
-  return strucs_with_new_chain_ids
-
-
-def concat(
-    strucs: Sequence[Structure],
-    *,
-    name: str | None = None,
-    assign_unique_chain_ids: bool = True,
-) -> Structure:
-  """Concatenates structures along the atom dimension.
-
-  NB: By default this function will first assign unique chain IDs to all chains
-  in `strucs` so that the resulting structure does not contain duplicate chain
-  IDs. This will also fix entity IDs and author chain IDs. If this is disabled
-  via `assign_unique_chain_ids=False` the user must ensure that there are no
-  duplicate chains (label_asym_id). However, duplicate entity IDs and author
-  chain IDs are allowed as that might be the desired behavior.
-
-  If `assign_unique_chain_ids=True`, note also that the chain_ids may be
-  overwritten even if they are already unique.
-
-  Let e.g. [A, B] denote a structure of two chains A and B, then this function
-  performs the following kind of concatenation operation:
-
-  assign_unique_chain_ids=True:
-    label chain IDS : [Z], [C], [B, C] -> [A, B, C, D]
-    author chain IDS: [U], [V], [V, C] -> [A, B, C, D]
-    entity IDs      : [1], [1], [3, 3] -> [1, 2, 3, 4]
-  assign_unique_chain_ids=False:
-    label chain IDS : [D], [B], [C, A] -> [D, B, C, A]  (inputs must be unique)
-    author chain IDS: [U], [V], [V, A] -> [U, V, V, A]
-    entity IDs      : [1], [1], [3, 3] -> [1, 1, 3, 3]
-
-  NB: This operation loses some information from the elements of `strucs`,
-  namely the `name`, `resolution`, `release_date` and `bioassembly_data` fields.
-
-  Args:
-    strucs: The `Structure` instances to concatenate. These should all have the
-      same number and shape of leading dimensions (i.e. if any are multi-model
-      structures then they should all have the same number of models).
-    name: Optional name to give to the concatenated structure. If None, the name
-      will be concatenation of names of all concatenated structures.
-    assign_unique_chain_ids: Whether this function will first assign new unique
-      chain IDs, entity IDs and author chain IDs to every chain in `strucs`. If
-      `False` then users must ensure chain IDs are already unique, otherwise an
-      exception is raised. See `_assign_unique_chain_ids` for more information
-      on how this is performed.
-
-  Returns:
-    A new concatenated `Structure` with all of the chains in `strucs` combined
-    into one new structure. The new structure will be named by joining the
-    names of `strucs` with underscores.
-
-  Raises:
-    ValueError: If `strucs` is empty.
-    ValueError: If `assign_unique_chain_ids=False` and not all chains in
-      `strucs` have unique chain IDs.
-  """
-  if not strucs:
-    raise ValueError('Need at least one Structure to concatenate.')
-  if assign_unique_chain_ids:
-    strucs = _assign_unique_chain_ids(strucs)
-
-  chemical_components_data = {}
-  seen_label_chain_ids = set()
-  for i, struc in enumerate(strucs):
-    if not assign_unique_chain_ids:
-      if seen_cid := seen_label_chain_ids.intersection(struc.chains):
-        raise ValueError(
-            f'Chain IDs {seen_cid} from strucs[{i}] also exist in other'
-            ' members of strucs. All given structures must have unique chain'
-            ' IDs. Consider setting assign_unique_chain_ids=True.'
-        )
-      seen_label_chain_ids.update(struc.chains)
-
-    if struc.chemical_components_data is not None:
-      chemical_components_data.update(struc.chemical_components_data.chem_comp)  # pytype: disable=attribute-error  # always-use-property-annotation
-
-  concatted_struc = table.concat_databases(strucs)
-  name = name if name is not None else '_'.join(s.name for s in strucs)
-  # Chain IDs (label and author) are fixed at this point, fix also entity IDs.
-  if assign_unique_chain_ids:
-    entity_id = np.char.mod('%d', np.arange(1, concatted_struc.num_chains + 1))
-    chains = concatted_struc.chains_table.copy_and_update(entity_id=entity_id)
-  else:
-    chains = concatted_struc.chains_table
-  return concatted_struc.copy_and_update(
-      name=name,
-      release_date=None,
-      resolution=None,
-      structure_method=None,
-      bioassembly_data=None,
-      chemical_components_data=(
-          struc_chem_comps.ChemicalComponentsData(chemical_components_data)
-          if chemical_components_data
-          else None
-      ),
-      chains=chains,
-      skip_validation=True,  # Already validated by table.concat_databases.
-  )
-
-
-def multichain_residue_index(
-    struc: Structure, chain_offset: int = 9000, between_chain_buffer: int = 1000
-) -> np.ndarray:
-  """Compute a residue index array that is monotonic across all chains.
-
-  Lots of metrics (lddt, l1_long, etc) require computing a
-  distance-along-chain between two residues.  For multimers we want to ensure
-  that any residues on different chains have a high along-chain distance
-  (i.e. they should always count as long-range contacts for example).  To
-  do this we add 10000 to the residue indices of each chain, and enforce that
-  the residue index is monotonically increasing across the whole complex.
-
-  Note: This returns the same as struc.res_id for monomers.
-
-  Args:
-    struc: The structure to make a multichain residue index for.
-    chain_offset: The start of each chain is offset by at least this amount.
-      This must be larger than the absolute range of standard residue IDs.
-    between_chain_buffer: The final residue in one chain will have at least this
-      much of a buffer before the first residue in the next chain.
-
-  Returns:
-    A monotonically increasing residue index, with at least
-    `between_chain_buffer` residues in between each chain.
-  """
-  if struc.num_atoms:
-    res_id_range = np.max(struc.res_id) - np.min(struc.res_id)
-    assert res_id_range < chain_offset
-  chain_id_int = struc.chain_id
-  monotonic_chain_id_int = np.concatenate(
-      ([0], np.cumsum(chain_id_int[1:] != chain_id_int[:-1]))
-  )
-  return struc.res_id + monotonic_chain_id_int * (
-      chain_offset + between_chain_buffer
-  )
-
-
-def make_empty_structure() -> Structure:
-  """Returns a new structure consisting of empty array fields."""
-  return Structure(
-      chains=structure_tables.Chains.make_empty(),
-      residues=structure_tables.Residues.make_empty(),
-      atoms=structure_tables.Atoms.make_empty(),
-      bonds=structure_tables.Bonds.make_empty(),
-  )
-
-
-def enumerate_residues(
-    atom_iter: Iterable[Mapping[str, Any]],
-    all_residues: AllResidues | None = None,
-) -> Iterator[tuple[int, Mapping[str, Any]]]:
-  """Provides a zero-indexed enumeration of residues in an atom iterable.
-
-  Args:
-    atom_iter: An iterable of atom dicts as returned by Structure.iter_atoms().
-    all_residues: (Optional) A structure's all_residues field. If present then
-      this will be used to count missing residues by adding appropriate gaps in
-      the residue enumeration.
-
-  Yields:
-    (res_i, atom) pairs where atom is the unmodified atom dict and res_i is a
-    zero-based index for the residue that the atom belongs to.
-  """
-  if all_residues is None:
-    prev_res = None
-    res_i = -1
-    for atom in atom_iter:
-      res = (atom['chain_id'], atom['res_id'])
-      if res != prev_res:
-        prev_res = res
-        res_i += 1
-      yield res_i, atom
-  else:
-    all_res_seq = []  # Sequence of (chain_id, res_id) for all chains.
-    prev_chain = None
-    res_i = 0
-    for atom in atom_iter:
-      chain_id = atom['chain_id']
-      if chain_id not in all_residues:
-        raise ValueError(
-            f'Atom {atom} does not belong to any residue in all_residues.'
-        )
-      if chain_id != prev_chain:
-        prev_chain = chain_id
-        all_res_seq.extend(
-            (chain_id, res_id) for (_, res_id) in all_residues[chain_id]
-        )
-      res = (chain_id, atom['res_id'])
-      while res_i < len(all_res_seq) and res != all_res_seq[res_i]:
-        res_i += 1
-      if res_i == len(all_res_seq):
-        raise ValueError(
-            f'Atom {atom} does not belong to a residue in all_residues.'
-        )
-      yield res_i, atom
diff --git a/src/alphafold3/structure/structure_tables.py b/src/alphafold3/structure/structure_tables.py
deleted file mode 100644
index 16323ae966fac1014ecdf7f596162e60c0bb1526..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/structure_tables.py
+++ /dev/null
@@ -1,819 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Table implementations for the Structure class."""
-
-import collections
-from collections.abc import Mapping, Sequence
-import dataclasses
-import functools
-import itertools
-import typing
-from typing import Any, ClassVar, Self
-
-from alphafold3.constants import mmcif_names
-from alphafold3.constants import residue_names
-from alphafold3.cpp import aggregation
-from alphafold3.cpp import string_array
-from alphafold3.structure import bonds as bonds_module
-from alphafold3.structure import mmcif
-from alphafold3.structure import table
-import numpy as np
-
-
-Bonds = bonds_module.Bonds
-
-
-def _residue_name_to_record_name(
-    residue_name: np.ndarray,
-    polymer_mask: np.ndarray,
-) -> np.ndarray:
-  """Returns record names (ATOM/HETATM) given residue names and polymer mask."""
-  record_name = np.array(['HETATM'] * len(residue_name), dtype=object)
-  record_name[polymer_mask] = string_array.remap(
-      residue_name[polymer_mask],
-      mapping={r: 'ATOM' for r in residue_names.STANDARD_POLYMER_TYPES},
-      default_value='HETATM',
-  )
-  return record_name
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class AuthorNamingScheme:
-  """A mapping from internal values to author values in a mmCIF.
-
-  Fields:
-    auth_asym_id: A mapping from label_asym_id to auth_asym_id.
-    auth_seq_id: A mapping from label_asym_id to a mapping from
-      label_seq_id to auth_seq_id.
-    insertion_code: A mapping from label_asym_id to a mapping from
-      label_seq_id to insertion codes.
-    entity_id: A mapping from label_asym_id to _entity.id.
-    entity_desc: A mapping from _entity.id to _entity.pdbx_description.
-  """
-
-  auth_asym_id: Mapping[str, str]
-  auth_seq_id: Mapping[str, Mapping[int, str]]
-  insertion_code: Mapping[str, Mapping[int, str | None]]
-  entity_id: Mapping[str, str]
-  entity_desc: Mapping[str, str]
-
-
-def _default(
-    candidate_value: np.ndarray | None, default_value: Sequence[Any], dtype: Any
-) -> np.ndarray:
-  if candidate_value is None:
-    return np.array(default_value, dtype=dtype)
-  return np.array(candidate_value, dtype=dtype)
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class Atoms(table.Table):
-  """Table of atoms in a Structure."""
-
-  chain_key: np.ndarray
-  res_key: np.ndarray
-  name: np.ndarray
-  element: np.ndarray
-  x: np.ndarray
-  y: np.ndarray
-  z: np.ndarray
-  b_factor: np.ndarray
-  occupancy: np.ndarray
-  multimodel_cols: ClassVar[tuple[str, ...]] = (
-      'x',
-      'y',
-      'z',
-      'b_factor',
-      'occupancy',
-  )
-
-  def __post_init__(self):
-    # Validates that the atom coordinates, b-factors and occupancies are finite.
-    for column_name in ('x', 'y', 'z', 'b_factor', 'occupancy'):
-      column = self.get_column(column_name)
-      if not np.isfinite(column).all():
-        raise ValueError(
-            f'Column {column_name} must not contain NaN/inf values.'
-        )
-    # super().__post_init__() can't be used as that causes the following error:
-    # TypeError: super(type, obj): obj must be an instance or subtype of type
-    super(Atoms, self).__post_init__()
-
-  @classmethod
-  def make_empty(cls) -> Self:
-    return cls(
-        key=np.array([], dtype=np.int64),
-        chain_key=np.array([], dtype=np.int64),
-        res_key=np.array([], dtype=np.int64),
-        name=np.array([], dtype=object),
-        element=np.array([], dtype=object),
-        x=np.array([], dtype=np.float32),
-        y=np.array([], dtype=np.float32),
-        z=np.array([], dtype=np.float32),
-        b_factor=np.array([], dtype=np.float32),
-        occupancy=np.array([], dtype=np.float32),
-    )
-
-  @classmethod
-  def from_defaults(
-      cls,
-      *,
-      chain_key: np.ndarray,
-      res_key: np.ndarray,
-      key: np.ndarray | None = None,
-      name: np.ndarray | None = None,
-      element: np.ndarray | None = None,
-      x: np.ndarray | None = None,
-      y: np.ndarray | None = None,
-      z: np.ndarray | None = None,
-      b_factor: np.ndarray | None = None,
-      occupancy: np.ndarray | None = None,
-  ) -> Self:
-    """Create an Atoms table with minimal user inputs."""
-    num_atoms = len(chain_key)
-    if not num_atoms:
-      return cls.make_empty()
-    return Atoms(
-        chain_key=chain_key,
-        res_key=res_key,
-        key=_default(key, np.arange(num_atoms), np.int64),
-        name=_default(name, ['?'] * num_atoms, object),
-        element=_default(element, ['?'] * num_atoms, object),
-        x=_default(x, [0.0] * num_atoms, np.float32),
-        y=_default(y, [0.0] * num_atoms, np.float32),
-        z=_default(z, [0.0] * num_atoms, np.float32),
-        b_factor=_default(b_factor, [0.0] * num_atoms, np.float32),
-        occupancy=_default(occupancy, [1.0] * num_atoms, np.float32),
-    )
-
-  def get_value_by_index(
-      self, column_name: str, index: int
-  ) -> table.TableEntry | np.ndarray:
-    if column_name in self.multimodel_cols:
-      return self.get_column(column_name)[..., index]
-    else:
-      return self.get_column(column_name)[index]
-
-  def copy_and_update_coords(self, coords: np.ndarray) -> Self:
-    """Returns a copy with the x, y and z columns updated."""
-    if coords.shape[-1] != 3:
-      raise ValueError(
-          f'Expecting 3-dimensional coordinates, got {coords.shape}'
-      )
-    return typing.cast(
-        Atoms,
-        self.copy_and_update(
-            x=coords[..., 0], y=coords[..., 1], z=coords[..., 2]
-        ),
-    )
-
-  @property
-  def shape(self) -> tuple[int, ...]:
-    return self.x.shape
-
-  @property
-  def ndim(self) -> int:
-    return len(self.shape)
-
-  @functools.cached_property
-  def num_models(self) -> int:
-    """The number of models of this Structure."""
-    leading_dims = self.shape[:-1]
-    match leading_dims:
-      case ():
-        return 1
-      case (single_leading_dim_size,):
-        return single_leading_dim_size
-      case _:
-        raise ValueError(
-            'num_models not defined for atom tables with more than one '
-            'leading dimension.'
-        )
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class Residues(table.Table):
-  """Table of residues in a Structure."""
-
-  chain_key: np.ndarray
-  id: np.ndarray
-  name: np.ndarray
-  auth_seq_id: np.ndarray
-  insertion_code: np.ndarray
-
-  @classmethod
-  def make_empty(cls) -> Self:
-    return cls(
-        key=np.array([], dtype=np.int64),
-        chain_key=np.array([], dtype=np.int64),
-        id=np.array([], dtype=np.int32),
-        name=np.array([], dtype=object),
-        auth_seq_id=np.array([], dtype=object),
-        insertion_code=np.array([], dtype=object),
-    )
-
-  @classmethod
-  def from_defaults(
-      cls,
-      *,
-      id: np.ndarray,  # pylint:disable=redefined-builtin
-      chain_key: np.ndarray,
-      key: np.ndarray | None = None,
-      name: np.ndarray | None = None,
-      auth_seq_id: np.ndarray | None = None,
-      insertion_code: np.ndarray | None = None,
-  ) -> Self:
-    """Create a Residues table with minimal user inputs."""
-    num_res = len(id)
-    if not num_res:
-      return cls.make_empty()
-    return Residues(
-        key=_default(key, np.arange(num_res), np.int64),
-        id=id,
-        chain_key=chain_key,
-        name=_default(name, ['UNK'] * num_res, object),
-        auth_seq_id=_default(auth_seq_id, id.astype(str), object),
-        insertion_code=_default(insertion_code, ['?'] * num_res, object),
-    )
-
-
-@dataclasses.dataclass(frozen=True, slots=True, kw_only=True)
-class Chains(table.Table):
-  """Table of chains in a Structure."""
-
-  id: np.ndarray
-  type: np.ndarray
-  auth_asym_id: np.ndarray
-  entity_id: np.ndarray
-  entity_desc: np.ndarray
-
-  @classmethod
-  def make_empty(cls) -> Self:
-    return cls(
-        key=np.array([], dtype=np.int64),
-        id=np.array([], dtype=object),
-        type=np.array([], dtype=object),
-        auth_asym_id=np.array([], dtype=object),
-        entity_id=np.array([], dtype=object),
-        entity_desc=np.array([], dtype=object),
-    )
-
-  @classmethod
-  def from_defaults(
-      cls,
-      *,
-      id: np.ndarray,  # pylint:disable=redefined-builtin
-      key: np.ndarray | None = None,
-      type: np.ndarray | None = None,  # pylint:disable=redefined-builtin
-      auth_asym_id: np.ndarray | None = None,
-      entity_id: np.ndarray | None = None,
-      entity_desc: np.ndarray | None = None,
-  ) -> Self:
-    """Create a Chains table with minimal user inputs."""
-    num_chains = len(id)
-    if not num_chains:
-      return cls.make_empty()
-
-    return Chains(
-        key=_default(key, np.arange(num_chains), np.int64),
-        id=id,
-        type=_default(type, [mmcif_names.PROTEIN_CHAIN] * num_chains, object),
-        auth_asym_id=_default(auth_asym_id, id, object),
-        entity_id=_default(
-            entity_id, np.arange(1, num_chains + 1).astype(str), object
-        ),
-        entity_desc=_default(entity_desc, ['.'] * num_chains, object),
-    )
-
-
-def to_mmcif_sequence_and_entity_tables(
-    chains: Chains,
-    residues: Residues,
-    atom_res_key: np.ndarray,
-) -> Mapping[str, Sequence[str]]:
-  """Returns raw sequence and entity mmCIF tables."""
-  raw_mmcif = collections.defaultdict(list)
-  chains_by_entity_id = {}
-  written_entity_poly_seq_ids = set()
-  present_res_keys = set(atom_res_key)
-
-  # Performance optimisation: Find residue indices for each chain in advance, so
-  # that we don't have to do redunant masking work for each chain.
-  res_indices_for_chain = aggregation.indices_grouped_by_value(
-      residues.chain_key
-  )
-
-  for chain in chains.iterrows():
-    # Add all chain information to the _struct_asym table.
-    chain_id = chain['id']  # Saves multiple dict lookups.
-    auth_asym_id = chain['auth_asym_id']
-    entity_id = chain['entity_id']
-    chains_by_entity_id.setdefault(entity_id, []).append(chain)
-    raw_mmcif['_struct_asym.id'].append(chain_id)
-    raw_mmcif['_struct_asym.entity_id'].append(entity_id)
-
-    res_chain_indices = res_indices_for_chain[chain['key']]
-    chain_type = chain['type']
-    is_polymer = chain_type in mmcif_names.POLYMER_CHAIN_TYPES
-    is_water = chain_type == mmcif_names.WATER
-    is_branched = len(res_chain_indices) > 1 and not is_polymer and not is_water
-    write_entity_poly_seq = entity_id not in written_entity_poly_seq_ids
-
-    # Iterate over the individual masked residue table columns, as that doesn't
-    # create a copy (only a view), while residues[res_chain_indices] does.
-    for res_key, res_name, res_id, pdb_seq_num, res_ins_code in zip(
-        residues.key[res_chain_indices],
-        residues.name[res_chain_indices],
-        residues.id[res_chain_indices],
-        residues.auth_seq_id[res_chain_indices],
-        residues.insertion_code[res_chain_indices],
-        strict=True,
-    ):
-      is_missing = res_key not in present_res_keys
-      str_res_id = str(res_id)
-      # While atom_site uses "?" for insertion codes, scheme tables use ".".
-      ins_code = (res_ins_code or '.').replace('?', '.')
-      auth_seq_num = '?' if is_missing else pdb_seq_num
-
-      if is_polymer:
-        raw_mmcif['_pdbx_poly_seq_scheme.asym_id'].append(chain_id)
-        raw_mmcif['_pdbx_poly_seq_scheme.entity_id'].append(entity_id)
-        raw_mmcif['_pdbx_poly_seq_scheme.seq_id'].append(str_res_id)
-        raw_mmcif['_pdbx_poly_seq_scheme.mon_id'].append(res_name)
-        raw_mmcif['_pdbx_poly_seq_scheme.pdb_seq_num'].append(pdb_seq_num)
-        raw_mmcif['_pdbx_poly_seq_scheme.auth_seq_num'].append(auth_seq_num)
-        raw_mmcif['_pdbx_poly_seq_scheme.pdb_strand_id'].append(auth_asym_id)
-        raw_mmcif['_pdbx_poly_seq_scheme.pdb_ins_code'].append(ins_code)
-        # Structure doesn't support heterogeneous sequences.
-        raw_mmcif['_pdbx_poly_seq_scheme.hetero'].append('n')
-        if write_entity_poly_seq:
-          raw_mmcif['_entity_poly_seq.entity_id'].append(entity_id)
-          raw_mmcif['_entity_poly_seq.num'].append(str_res_id)
-          raw_mmcif['_entity_poly_seq.mon_id'].append(res_name)
-          # Structure doesn't support heterogeneous sequences.
-          raw_mmcif['_entity_poly_seq.hetero'].append('n')
-          written_entity_poly_seq_ids.add(entity_id)
-      elif is_branched:
-        raw_mmcif['_pdbx_branch_scheme.asym_id'].append(chain_id)
-        raw_mmcif['_pdbx_branch_scheme.entity_id'].append(entity_id)
-        raw_mmcif['_pdbx_branch_scheme.mon_id'].append(res_name)
-        raw_mmcif['_pdbx_branch_scheme.num'].append(str_res_id)
-        raw_mmcif['_pdbx_branch_scheme.pdb_asym_id'].append(auth_asym_id)
-        raw_mmcif['_pdbx_branch_scheme.pdb_seq_num'].append(pdb_seq_num)
-        raw_mmcif['_pdbx_branch_scheme.auth_asym_id'].append(auth_asym_id)
-        raw_mmcif['_pdbx_branch_scheme.auth_seq_num'].append(auth_seq_num)
-        raw_mmcif['_pdbx_branch_scheme.pdb_ins_code'].append(ins_code)
-        # Structure doesn't support heterogeneous sequences.
-        raw_mmcif['_pdbx_branch_scheme.hetero'].append('n')
-      else:
-        raw_mmcif['_pdbx_nonpoly_scheme.asym_id'].append(chain_id)
-        raw_mmcif['_pdbx_nonpoly_scheme.entity_id'].append(entity_id)
-        raw_mmcif['_pdbx_nonpoly_scheme.mon_id'].append(res_name)
-        raw_mmcif['_pdbx_nonpoly_scheme.pdb_seq_num'].append(pdb_seq_num)
-        raw_mmcif['_pdbx_nonpoly_scheme.auth_seq_num'].append(auth_seq_num)
-        raw_mmcif['_pdbx_nonpoly_scheme.pdb_strand_id'].append(auth_asym_id)
-        raw_mmcif['_pdbx_nonpoly_scheme.pdb_ins_code'].append(ins_code)
-
-  # Add _entity and _entity_poly tables.
-  for entity_id, chains in chains_by_entity_id.items():
-    # chains should always be a non-empty list because of how we constructed
-    # chains_by_entity_id.
-    assert chains
-    # All chains for a given entity should have the same type and sequence
-    # so we can pick the first one without losing information.
-    key_chain = chains[0]
-    raw_mmcif['_entity.id'].append(entity_id)
-    raw_mmcif['_entity.pdbx_description'].append(key_chain['entity_desc'])
-    entity_type = key_chain['type']
-    if entity_type not in mmcif_names.POLYMER_CHAIN_TYPES:
-      raw_mmcif['_entity.type'].append(entity_type)
-    else:
-      raw_mmcif['_entity.type'].append('polymer')
-      raw_mmcif['_entity_poly.entity_id'].append(entity_id)
-      raw_mmcif['_entity_poly.type'].append(entity_type)
-
-      # _entity_poly.pdbx_strand_id is a comma-separated list of
-      # auth_asym_ids that are part of the entity.
-      raw_mmcif['_entity_poly.pdbx_strand_id'].append(
-          ','.join(chain['auth_asym_id'] for chain in chains)
-      )
-  return raw_mmcif
-
-
-def to_mmcif_atom_site_and_bonds_table(
-    *,
-    chains: Chains,
-    residues: Residues,
-    atoms: Atoms,
-    bonds: Bonds,
-    coords_decimal_places: int,
-) -> Mapping[str, Sequence[str]]:
-  """Returns raw _atom_site and _struct_conn mmCIF tables."""
-  raw_mmcif = collections.defaultdict(list)
-  # Use [value] * num wherever possible since it is about 10x faster than list
-  # comprehension in such cases. Also use f-strings instead of str() - faster.
-  total_atoms = atoms.size * atoms.num_models
-  raw_mmcif['_atom_site.id'] = [f'{i}' for i in range(1, total_atoms + 1)]
-  raw_mmcif['_atom_site.label_alt_id'] = ['.'] * total_atoms
-  # Use format_float_array instead of list comprehension for performance.
-  raw_mmcif['_atom_site.Cartn_x'] = mmcif.format_float_array(
-      values=atoms.x.ravel(), num_decimal_places=coords_decimal_places
-  )
-  raw_mmcif['_atom_site.Cartn_y'] = mmcif.format_float_array(
-      values=atoms.y.ravel(), num_decimal_places=coords_decimal_places
-  )
-  raw_mmcif['_atom_site.Cartn_z'] = mmcif.format_float_array(
-      values=atoms.z.ravel(), num_decimal_places=coords_decimal_places
-  )
-
-  # atoms.b_factor or atoms.occupancy can be flat even when the coordinates have
-  # leading dimensions. In this case we tile it to match.
-  if atoms.b_factor.ndim == 1:
-    atom_b_factor = np.tile(atoms.b_factor, atoms.num_models)
-  else:
-    atom_b_factor = atoms.b_factor.ravel()
-  raw_mmcif['_atom_site.B_iso_or_equiv'] = mmcif.format_float_array(
-      values=atom_b_factor, num_decimal_places=2
-  )
-
-  if atoms.occupancy.ndim == 1:
-    atom_occupancy = np.tile(atoms.occupancy, atoms.num_models)
-  else:
-    atom_occupancy = atoms.occupancy.ravel()
-  raw_mmcif['_atom_site.occupancy'] = mmcif.format_float_array(
-      values=atom_occupancy.ravel(), num_decimal_places=2
-  )
-
-  label_atom_id = atoms.name
-  type_symbol = atoms.element
-  label_comp_id = residues.apply_array_to_column('name', atoms.res_key)
-  label_asym_id = chains.apply_array_to_column('id', atoms.chain_key)
-  label_entity_id = chains.apply_array_to_column('entity_id', atoms.chain_key)
-  # Performance optimisation: Do the int->str conversion on num_residue-sized,
-  # array, then select instead of selecting and then converting.
-  label_seq_id = residues.id.astype('str').astype(object)[
-      ..., residues.index_by_key[atoms.res_key]
-  ]
-
-  # _atom_site.label_seq_id is '.' for non-polymers.
-  non_polymer_chain_mask = string_array.isin(
-      chains.type, mmcif_names.POLYMER_CHAIN_TYPES, invert=True
-  )
-  non_polymer_chain_keys = chains.key[non_polymer_chain_mask]
-  non_polymer_atom_mask = np.isin(atoms.chain_key, non_polymer_chain_keys)
-  label_seq_id[non_polymer_atom_mask] = '.'
-
-  auth_asym_id = chains.apply_array_to_column('auth_asym_id', atoms.chain_key)
-  auth_seq_id = residues.apply_array_to_column('auth_seq_id', atoms.res_key)
-  pdbx_pdb_ins_code = residues.apply_array_to_column(
-      'insertion_code', atoms.res_key
-  )
-  string_array.remap(pdbx_pdb_ins_code, mapping={None: '?'}, inplace=True)
-
-  group_pdb = _residue_name_to_record_name(
-      residue_name=label_comp_id, polymer_mask=~non_polymer_atom_mask
-  )
-
-  def tile_for_models(arr: np.ndarray) -> list[str]:
-    if atoms.num_models == 1:
-      return arr.tolist()  # Memory optimisation: np.tile(arr, 1) does a copy.
-    return np.tile(arr, atoms.num_models).tolist()
-
-  raw_mmcif['_atom_site.group_PDB'] = tile_for_models(group_pdb)
-  raw_mmcif['_atom_site.label_atom_id'] = tile_for_models(label_atom_id)
-  raw_mmcif['_atom_site.type_symbol'] = tile_for_models(type_symbol)
-  raw_mmcif['_atom_site.label_comp_id'] = tile_for_models(label_comp_id)
-  raw_mmcif['_atom_site.label_asym_id'] = tile_for_models(label_asym_id)
-  raw_mmcif['_atom_site.label_entity_id'] = tile_for_models(label_entity_id)
-  raw_mmcif['_atom_site.label_seq_id'] = tile_for_models(label_seq_id)
-  raw_mmcif['_atom_site.auth_asym_id'] = tile_for_models(auth_asym_id)
-  raw_mmcif['_atom_site.auth_seq_id'] = tile_for_models(auth_seq_id)
-  raw_mmcif['_atom_site.pdbx_PDB_ins_code'] = tile_for_models(pdbx_pdb_ins_code)
-  model_id = np.array(
-      [str(i + 1) for i in range(atoms.num_models)], dtype=object
-  )
-  raw_mmcif['_atom_site.pdbx_PDB_model_num'] = np.repeat(
-      model_id, [atoms.size] * atoms.num_models
-  ).tolist()
-
-  if bonds.key.size > 0:
-    raw_mmcif.update(
-        bonds.to_mmcif_dict_from_atom_arrays(
-            atom_key=atoms.key,
-            chain_id=label_asym_id,
-            res_id=label_seq_id,
-            res_name=label_comp_id,
-            atom_name=label_atom_id,
-            auth_asym_id=auth_asym_id,
-            auth_seq_id=auth_seq_id,
-            insertion_code=np.array(pdbx_pdb_ins_code),
-        )
-    )
-  return raw_mmcif
-
-
-def _flatten_author_naming_scheme_table(
-    res_table: Mapping[str, Mapping[int, str]],
-    chain_ids: np.ndarray,
-    res_chain_ids: np.ndarray,
-    res_ids: np.ndarray,
-    default_if_missing: str,
-    table_name: str,
-) -> np.ndarray:
-  """Flattens an author naming scheme table consistently with res_ids."""
-  if not set(chain_ids).issubset(res_table):
-    raise ValueError(
-        f'Chain IDs in the chain_id array must be a subset of {table_name} in '
-        'author naming scheme:\n'
-        f'chain_ids: {sorted(chain_ids)}\n'
-        f'{table_name} keys: {sorted(res_table.keys())}'
-    )
-
-  chain_change_mask = res_chain_ids[1:] != res_chain_ids[:-1]
-  res_chain_boundaries = np.concatenate(
-      ([0], np.where(chain_change_mask)[0] + 1, [len(res_chain_ids)])
-  )
-
-  flat_vals = np.empty(len(res_ids), dtype=object)
-  for chain_start, chain_end in itertools.pairwise(res_chain_boundaries):
-    chain_id = res_chain_ids[chain_start]
-    chain_res_ids = res_ids[chain_start:chain_end]
-    chain_mapping = res_table[chain_id]
-    flat_vals[chain_start:chain_end] = [
-        chain_mapping.get(r, default_if_missing) for r in chain_res_ids
-    ]
-
-  return flat_vals
-
-
-def tables_from_atom_arrays(
-    *,
-    res_id: np.ndarray,
-    author_naming_scheme: AuthorNamingScheme | None = None,
-    all_residues: Mapping[str, Sequence[tuple[str, int]]] | None = None,
-    chain_id: np.ndarray | None = None,
-    chain_type: np.ndarray | None = None,
-    res_name: np.ndarray | None = None,
-    atom_key: np.ndarray | None = None,
-    atom_name: np.ndarray | None = None,
-    atom_element: np.ndarray | None = None,
-    atom_x: np.ndarray | None = None,
-    atom_y: np.ndarray | None = None,
-    atom_z: np.ndarray | None = None,
-    atom_b_factor: np.ndarray | None = None,
-    atom_occupancy: np.ndarray | None = None,
-) -> tuple[Atoms, Residues, Chains]:
-  """Returns Structure tables constructed from atom array level data.
-
-  All fields except name and, res_id are optional, all array fields consist of a
-  value for each atom in the structure - so residue and chain values should hold
-  the same value for each atom in the chain or residue. Fields which are not
-  defined are filled with default values.
-
-  Validation is performed by the Structure constructor where possible - but
-  author_naming scheme and all_residues must be checked in this function.
-
-  It is not possible to construct structures with chains that do not contain
-  any resolved residues using this function. If this is necessary, use the
-  structure.Structure constructor directly.
-
-  Args:
-    res_id: Integer array of shape [num_atom]. The unique residue identifier for
-      each residue. mmCIF field - _atom_site.label_seq_id.
-    author_naming_scheme: An optional instance of AuthorNamingScheme to use when
-      converting this structure to mmCIF.
-    all_residues: An optional mapping from each chain ID (i.e. label_asym_id) to
-      a sequence of (label_comp_id, label_seq_id) tuples, one per residue. This
-      can contain residues that aren't present in the atom arrays. This is
-      common in experimental data where some residues are not resolved but are
-      known to be present.
-    chain_id: String array of shape [num_atom] of unique chain identifiers.
-      mmCIF field - _atom_site.label_asym_id.
-    chain_type: String array of shape [num_atom]. The molecular type of the
-      current chain (e.g. polyribonucleotide). mmCIF field - _entity_poly.type
-      OR _entity.type (for non-polymers).
-    res_name: String array of shape [num_atom].. The name of each residue,
-      typically a 3 letter string for polypeptides or 1-2 letter strings for
-      polynucleotides. mmCIF field - _atom_site.label_comp_id.
-    atom_key: A unique sorted integer array, used only by the bonds table to
-      identify the atoms participating in each bond. If the bonds table is
-      specified then this column must be non-None.
-    atom_name: String array of shape [num_atom]. The name of each atom (e.g CA,
-      O2', etc.). mmCIF field - _atom_site.label_atom_id.
-    atom_element: String array of shape [num_atom]. The element type of each
-      atom (e.g. C, O, N, etc.). mmCIF field - _atom_site.type_symbol.
-    atom_x: Float array of shape [..., num_atom] of atom x coordinates. May have
-      arbitrary leading dimensions, provided that these are consistent across
-      all coordinate fields.
-    atom_y: Float array of shape [..., num_atom] of atom y coordinates. May have
-      arbitrary leading dimensions, provided that these are consistent across
-      all coordinate fields.
-    atom_z: Float array of shape [..., num_atom] of atom z coordinates. May have
-      arbitrary leading dimensions, provided that these are consistent across
-      all coordinate fields.
-    atom_b_factor: Float array of shape [..., num_atom] or [num_atom] of atom
-      b-factors or equivalent. If there are no extra leading dimensions then
-      these values are assumed to apply to all coordinates for a given atom. If
-      there are leading dimensions then these must match those used by the
-      coordinate fields.
-    atom_occupancy: Float array of shape [..., num_atom] or [num_atom] of atom
-      occupancies or equivalent. If there are no extra leading dimensions then
-      these values are assumed to apply to all coordinates for a given atom. If
-      there are leading dimensions then these must match those used by the
-      coordinate fields.
-  """
-  num_atoms = len(res_id)
-
-  for arr_name, array, dtype in (
-      ('chain_id', chain_id, object),
-      ('chain_type', chain_type, object),
-      ('res_id', res_id, np.int32),
-      ('res_name', res_name, object),
-      ('atom_key', atom_key, np.int64),
-      ('atom_name', atom_name, object),
-      ('atom_element', atom_element, object),
-  ):
-    if array is not None and array.shape != (num_atoms,):
-      raise ValueError(f'{arr_name} shape {array.shape} != ({num_atoms},)')
-    if array is not None and array.dtype != dtype:
-      raise ValueError(f'{arr_name} dtype {array.dtype} != {dtype}')
-
-  for arr_name, array in (
-      ('atom_x', atom_x),
-      ('atom_y', atom_y),
-      ('atom_z', atom_z),
-      ('atom_b_factor', atom_b_factor),
-      ('atom_occupancy', atom_occupancy),
-  ):
-    if array is not None and array.shape[-1] != num_atoms:
-      raise ValueError(f'{arr_name} last dim {array.shape[-1]} != {num_atoms=}')
-    if (
-        array is not None
-        and array.dtype != np.float32
-        and array.dtype != np.float64
-    ):
-      raise ValueError(
-          f'{arr_name} must be np.float32 or np.float64, got {array.dtype=}'
-      )
-
-  if all_residues is not None and (res_name is None or res_id is None):
-    raise ValueError(
-        'If all_residues != None, res_name and res_id must not be None either.'
-    )
-
-  if num_atoms == 0:
-    return Atoms.make_empty(), Residues.make_empty(), Chains.make_empty()
-
-  if chain_id is None:
-    chain_id = np.full(shape=num_atoms, fill_value='A', dtype=object)
-  if res_name is None:
-    res_name = np.full(shape=num_atoms, fill_value='UNK', dtype=object)
-
-  chain_change_mask = chain_id[1:] != chain_id[:-1]
-  chain_start = np.concatenate(([0], np.where(chain_change_mask)[0] + 1))
-  res_start = np.concatenate(
-      ([0], np.where((res_id[1:] != res_id[:-1]) | chain_change_mask)[0] + 1)
-  )
-
-  if len(set(chain_id)) != len(chain_start):
-    raise ValueError(f'Chain IDs must be contiguous, but got {chain_id}')
-
-  # We do not support chains with unresolved residues-only in this function.
-  chain_ids = chain_id[chain_start]
-  if all_residues and set(all_residues.keys()) != set(chain_ids):
-    raise ValueError(
-        'all_residues must contain the same set of chain IDs as the chain_id '
-        f'array:\nall_residues keys: {sorted(all_residues.keys())}\n'
-        f'chain_ids: {sorted(chain_ids)}.'
-    )
-  # Make sure all_residue ordering is consistent with chain_id.
-  if all_residues and np.any(list(all_residues.keys()) != chain_ids):
-    all_residues = {cid: all_residues[cid] for cid in chain_ids}
-
-  # Create the chains table.
-  num_chains = len(chain_ids)
-  chain_keys = np.arange(num_chains, dtype=np.int64)
-  chain_key_by_chain_id = dict(zip(chain_ids, chain_keys, strict=True))
-
-  if chain_type is not None:
-    chain_types = chain_type[chain_start]
-  else:
-    chain_types = np.full(num_chains, mmcif_names.PROTEIN_CHAIN, dtype=object)
-
-  if author_naming_scheme is not None:
-    auth_asym_id = string_array.remap(
-        chain_ids, author_naming_scheme.auth_asym_id
-    )
-    entity_id = string_array.remap(
-        chain_ids, author_naming_scheme.entity_id, default_value='.'
-    )
-    entity_desc = string_array.remap(
-        entity_id, author_naming_scheme.entity_desc, default_value='.'
-    )
-  else:
-    auth_asym_id = chain_ids
-    entity_id = (chain_keys + 1).astype(str).astype(object)
-    entity_desc = np.full(num_chains, '.', dtype=object)
-
-  chains = Chains(
-      key=chain_keys,
-      id=chain_ids,
-      type=chain_types,
-      auth_asym_id=auth_asym_id,
-      entity_id=entity_id,
-      entity_desc=entity_desc,
-  )
-
-  # Create the residues table.
-  if all_residues is not None:
-    residue_order = []
-    for cid, residues in all_residues.items():
-      residue_order.extend((cid, rname, int(rid)) for (rname, rid) in residues)
-    res_chain_ids, res_names, res_ids = zip(*residue_order)
-    res_chain_ids = np.array(res_chain_ids, dtype=object)
-    res_ids = np.array(res_ids, dtype=np.int32)
-    res_names = np.array(res_names, dtype=object)
-  else:
-    res_chain_ids = chain_id[res_start]
-    res_ids = res_id[res_start]
-    res_names = res_name[res_start]
-    residue_order = list(zip(res_chain_ids, res_names, res_ids))
-
-  if author_naming_scheme is not None and author_naming_scheme.auth_seq_id:
-    auth_seq_id = _flatten_author_naming_scheme_table(
-        author_naming_scheme.auth_seq_id,
-        chain_ids=chain_ids,
-        res_chain_ids=res_chain_ids,
-        res_ids=res_ids,
-        default_if_missing='.',
-        table_name='auth_seq_id',
-    )
-  else:
-    auth_seq_id = res_ids.astype(str).astype(object)
-
-  if author_naming_scheme is not None and author_naming_scheme.insertion_code:
-    insertion_code = _flatten_author_naming_scheme_table(
-        author_naming_scheme.insertion_code,
-        chain_ids=chain_ids,
-        res_chain_ids=res_chain_ids,
-        res_ids=res_ids,
-        default_if_missing='?',
-        table_name='insertion_code',
-    )
-    # Make sure insertion code of None is mapped to '.'.
-    insertion_code = string_array.remap(insertion_code, {None: '?'})
-  else:
-    insertion_code = np.full(shape=len(res_ids), fill_value='?', dtype=object)
-
-  res_key_by_res = {res: i for i, res in enumerate(residue_order)}
-  res_keys = np.arange(len(residue_order), dtype=np.int64)
-  res_chain_keys = string_array.remap(
-      res_chain_ids, chain_key_by_chain_id
-  ).astype(np.int64)
-  residues = Residues(
-      chain_key=res_chain_keys,
-      key=res_keys,
-      id=res_ids,
-      name=res_names,
-      auth_seq_id=auth_seq_id,
-      insertion_code=insertion_code,
-  )
-
-  if atom_key is None:
-    atom_key = np.arange(num_atoms, dtype=np.int64)
-
-  atom_chain_keys = string_array.remap(chain_id, chain_key_by_chain_id).astype(
-      np.int64
-  )
-
-  try:
-    atom_res_keys = [res_key_by_res[r] for r in zip(chain_id, res_name, res_id)]
-  except KeyError as e:
-    missing_chain_id, missing_res_name, missing_res_id = e.args[0]
-    raise ValueError(
-        'Inconsistent res_name, res_id and all_residues. Could not find '
-        f'residue with chain_id={missing_chain_id}, '
-        f'res_name={missing_res_name}, res_id={missing_res_id} in all_residues.'
-    ) from e
-
-  atoms = Atoms(
-      key=atom_key,
-      chain_key=atom_chain_keys,
-      res_key=np.array(atom_res_keys, dtype=np.int64),
-      name=_default(atom_name, ['?'] * num_atoms, object),
-      element=_default(atom_element, ['?'] * num_atoms, object),
-      x=_default(atom_x, [0.0] * num_atoms, np.float32),
-      y=_default(atom_y, [0.0] * num_atoms, np.float32),
-      z=_default(atom_z, [0.0] * num_atoms, np.float32),
-      b_factor=_default(atom_b_factor, [0.0] * num_atoms, np.float32),
-      occupancy=_default(atom_occupancy, [1.0] * num_atoms, np.float32),
-  )
-  return atoms, residues, chains
diff --git a/src/alphafold3/structure/table.py b/src/alphafold3/structure/table.py
deleted file mode 100644
index 287850bf44fa77b2d3b7dcf1d4af16fa987e9e3c..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/table.py
+++ /dev/null
@@ -1,563 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Table module for atom/residue/chain tables in Structure.
-
-Tables are intended to be lightweight collections of columns, loosely based
-on a pandas dataframe, for use in the Structure class.
-"""
-
-import abc
-from collections.abc import Callable, Collection, Iterable, Iterator, Mapping, Sequence
-import dataclasses
-import functools
-import graphlib
-import typing
-from typing import Any, Protocol, Self, TypeAlias, TypeVar, overload
-
-from alphafold3.cpp import string_array
-import numpy as np
-
-
-TableEntry: TypeAlias = str | int | float | None
-FilterPredicate: TypeAlias = (
-    TableEntry
-    | Iterable[Any]  # Workaround for b/326384670. Tighten once fixed.
-    | Callable[[Any], bool]  # Workaround for b/326384670. Tighten once fixed.
-    | Callable[[np.ndarray], bool]
-)
-
-
-class RowLookup(Protocol):
-
-  def get_row_by_key(
-      self,
-      key: int,
-      column_name_map: Mapping[str, str] | None = None,
-  ) -> Mapping[str, Any]:
-    ...
-
-
-@dataclasses.dataclass(frozen=True, kw_only=True)
-class Table:
-  """Parent class for structure tables.
-
-  A table is a collection of columns of equal length, where one column is the
-  key. The key uniquely identifies each row in the table.
-
-  A table can refer to other tables by including a foreign key column, whose
-  values are key values from the other table's key column. These column can have
-  arbitrary names and are treated like any other integer-valued column.
-
-  See the `Database` class in this module for utilities for handing sets of
-  tables that are related via foreign keys.
-
-  NB: This does not correspond to an mmCIF table.
-  """
-
-  key: np.ndarray
-
-  def __post_init__(self):
-    for col_name in self.columns:
-      if (col_len := self.get_column(col_name).shape[-1]) != self.size:
-        raise ValueError(
-            f'All columns should have length {self.size} but got "{col_name}"'
-            f' with length {col_len}.'
-        )
-      self.get_column(col_name).flags.writeable = False  # Make col immutable.
-    if self.key.size and self.key.min() < 0:
-      raise ValueError(
-          'Key values must be non-negative. Got negative values:'
-          f' {set(self.key[self.key < 0])}'
-      )
-    self.key.flags.writeable = False  # Make key immutable.
-
-  def __getstate__(self) -> dict[str, Any]:
-    """Returns members with cached properties removed for pickling."""
-    cached_props = {
-        k
-        for k, v in self.__class__.__dict__.items()
-        if isinstance(v, functools.cached_property)
-    }
-    return {k: v for k, v in self.__dict__.items() if k not in cached_props}
-
-  @functools.cached_property
-  def index_by_key(self) -> np.ndarray:
-    """Mapping from key values to their index in the column arrays.
-
-    i.e.: self.key[index_by_key[k]] == k
-    """
-    if not self.key.size:
-      return np.array([], dtype=np.int64)
-    else:
-      index_by_key = np.zeros(np.max(self.key) + 1, dtype=np.int64)
-      index_by_key[self.key] = np.arange(self.size)
-      return index_by_key
-
-  @functools.cached_property
-  def columns(self) -> tuple[str, ...]:
-    """The names of the columns in the table, including the key column."""
-    return tuple(field.name for field in dataclasses.fields(self))
-
-  @functools.cached_property
-  def items(self) -> Mapping[str, np.ndarray]:
-    """Returns the mapping from column names to column values."""
-    return {col: getattr(self, col) for col in self.columns}
-
-  @functools.cached_property
-  def size(self) -> int:
-    """The number of rows in the table."""
-    return self.key.shape[-1]
-
-  def __len__(self) -> int:
-    return self.size
-
-  def get_column(self, column_name: str) -> np.ndarray:
-    """Gets a column by name."""
-    # Performance optimisation: use the cached columns, instead of getattr.
-    return self.items[column_name]
-
-  def apply_array(self, arr: np.ndarray) -> Self:
-    """Returns a sliced table using a key (!= index) array or a boolean mask."""
-    if arr.dtype == bool and np.all(arr):
-      return self  # Shortcut: No-op, so just return.
-
-    return self.copy_and_update(**{
-        column_name: self.apply_array_to_column(column_name, arr)
-        for column_name in self.columns
-    })
-
-  def apply_index(self, index_arr: np.ndarray) -> Self:
-    """Returns a sliced table using an index (!= key) array."""
-    if index_arr.dtype == bool:
-      raise ValueError('The index array must not be a boolean mask.')
-
-    return self.copy_and_update(
-        **{col: self.get_column(col)[..., index_arr] for col in self.columns}
-    )
-
-  def apply_array_to_column(
-      self,
-      column_name: str,
-      arr: np.ndarray,
-  ) -> np.ndarray:
-    """Returns a sliced column array using a key array or a boolean mask."""
-    if arr.dtype == bool:
-      return self.get_column(column_name)[..., arr]
-    else:
-      return self.get_column(column_name)[..., self.index_by_key[arr]]
-
-  def get_value_by_index(self, column_name: str, index: int) -> Any:
-    return self.get_column(column_name)[index]
-
-  def get_value_by_key(
-      self,
-      column_name: str,
-      key: int | np.integer,
-  ) -> TableEntry:
-    """Gets the value of a column at the row with specified key value."""
-    return self.get_value_by_index(column_name, self.index_by_key[key])
-
-  @overload
-  def __getitem__(self, key: str) -> np.ndarray:
-    ...
-
-  @overload
-  def __getitem__(self, key: np.ndarray) -> 'Table':
-    ...
-
-  @overload
-  def __getitem__(self, key: tuple[str, int | np.integer]) -> TableEntry:
-    ...
-
-  @overload
-  def __getitem__(self, key: tuple[str, np.ndarray]) -> np.ndarray:
-    ...
-
-  def __getitem__(self, key):
-    match key:
-      case str():
-        return self.get_column(key)
-      case np.ndarray() as key_arr_or_mask:
-        return self.apply_array(key_arr_or_mask)
-      case str() as col, int() | np.integer() as key_val:
-        return self.get_value_by_key(col, key_val)
-      case str() as col, np.ndarray() as key_arr_or_mask:
-        return self.apply_array_to_column(col, key_arr_or_mask)
-      case _:
-        if isinstance(key, tuple):
-          err_msg = f'{key}, type: tuple({[type(v) for v in key]})'
-        else:
-          err_msg = f'{key}, type: {type(key)}'
-        raise KeyError(err_msg)
-
-  def get_row_by_key(
-      self,
-      key: int,
-      column_name_map: Mapping[str, str] | None = None,
-  ) -> dict[str, Any]:
-    """Gets the row with specified key value."""
-    return self.get_row_by_index(
-        self.index_by_key[key], column_name_map=column_name_map
-    )
-
-  def get_row_by_index(
-      self,
-      index: int,
-      column_name_map: Mapping[str, str] | None = None,
-  ) -> dict[str, Any]:
-    """Gets the row at the specified index."""
-    if column_name_map is not None:
-      return {
-          renamed_col: self.get_value_by_index(col, index)
-          for renamed_col, col in column_name_map.items()
-      }
-    else:
-      return {col: self.get_value_by_index(col, index) for col in self.columns}
-
-  def iterrows(
-      self,
-      *,
-      row_keys: np.ndarray | None = None,
-      column_name_map: Mapping[str, str] | None = None,
-      **table_by_foreign_key_col: RowLookup,
-  ) -> Iterator[Mapping[str, Any]]:
-    """Yields rows from the table.
-
-    This can be used to easily convert a table to a Pandas dataframe:
-
-    ```py
-    df = pd.DataFrame(table.iterrows())
-    ```
-
-    Args:
-      row_keys: An optional array of keys of rows to yield. If None, all rows
-        will be yielded.
-      column_name_map: An optional mapping from desired keys in the row dicts to
-        the names of the columns they correspond to.
-      **table_by_foreign_key_col: An optional mapping from column names in this
-        table, which are expected to be columns of foreign keys, to the table
-        that the foreign keys point into. If provided, then the yielded rows
-        will include data from the foreign tables at the appropriate key.
-    """
-    if row_keys is not None:
-      row_indices = self.index_by_key[row_keys]
-    else:
-      row_indices = range(self.size)
-    for i in row_indices:
-      row = self.get_row_by_index(i, column_name_map=column_name_map)
-      for key_col, table in table_by_foreign_key_col.items():
-        foreign_key = self[key_col][i]
-        foreign_row = table.get_row_by_key(foreign_key)
-        row.update(foreign_row)
-      yield row
-
-  def with_column_names(
-      self, column_name_map: Mapping[str, str]
-  ) -> 'RenamedTableView':
-    """Returns a view of this table with mapped column names."""
-    return RenamedTableView(self, column_name_map=column_name_map)
-
-  def make_filter_mask(
-      self,
-      mask: np.ndarray | None = None,
-      *,
-      apply_per_element: bool = False,
-      **predicate_by_col: FilterPredicate,
-  ) -> np.ndarray | None:
-    """Returns a boolean array of rows to keep, or None if all can be kept.
-
-    Args:
-      mask: See `Table.filter`.
-      apply_per_element: See `Table.filter`.
-      **predicate_by_col: See `Table.filter`.
-
-    Returns:
-      Either a boolean NumPy array of length `(self.size,)` denoting which rows
-      should be kept according to the input mask and predicates, or None. None
-      implies there is no filtering required, and is used where possible
-      instead of an all-True array to save time and space.
-    """
-    if mask is None:
-      if not predicate_by_col:
-        return None
-      else:
-        mask = np.ones((self.size,), dtype=bool)
-    else:
-      if mask.shape != (self.size,):
-        raise ValueError(
-            f'mask must have shape ({self.size},). Got: {mask.shape}.'
-        )
-      if mask.dtype != bool:
-        raise ValueError(f'mask must have dtype bool. Got: {mask.dtype}.')
-
-    for col, predicate in predicate_by_col.items():
-      if self[col].ndim > 1:
-        raise ValueError(
-            f'Cannot filter by column {col} with more than 1 dimension.'
-        )
-
-      callable_predicates = []
-      if not callable(predicate):
-        if isinstance(predicate, Iterable) and not isinstance(predicate, str):
-          target_vals = predicate
-        else:
-          target_vals = [predicate]
-        for target_val in target_vals:
-          callable_predicates.append(lambda x, target=target_val: x == target)
-      else:
-        callable_predicates.append(predicate)
-
-      field_mask = np.zeros_like(mask)
-      for callable_predicate in callable_predicates:
-        if not apply_per_element:
-          callable_predicate = typing.cast(
-              Callable[[np.ndarray], bool], callable_predicate
-          )
-          predicate_result = callable_predicate(self.get_column(col))
-        else:
-          predicate_result = np.array(
-              [callable_predicate(elem) for elem in self.get_column(col)]
-          )
-        np.logical_or(field_mask, predicate_result, out=field_mask)
-      np.logical_and(mask, field_mask, out=mask)  # Update in-place.
-    return mask
-
-  def filter(
-      self,
-      mask: np.ndarray | None = None,
-      *,
-      apply_per_element: bool = False,
-      invert: bool = False,
-      **predicate_by_col: FilterPredicate,
-  ) -> Self:
-    """Filters the table using mask and/or predicates and returns a new table.
-
-    Predicates can be either:
-      1. A constant value, e.g. `'CA'`. In this case then only rows that match
-        this value for the given column are retained.
-      2. A (non-string) iterable e.g. `('A', 'B')`. In this
-        case then rows are retained if they match any of the provided values for
-        the given column.
-      3. A boolean function e.g. `lambda b_fac: b_fac < 100.0`.
-        In this case then only rows that evaluate to `True` are retained. By
-        default this function's parameter is expected to be an array, unless
-        `apply_per_element=True`.
-
-    Args:
-      mask: An optional boolean NumPy array with length equal to the table size.
-        If provided then this will be combined with the other predicates so that
-        a row is included if it is masked-in *and* matches all the predicates.
-      apply_per_element: Whether apply predicates to each element in the column
-        individually, or to pass the whole column array to the predicate.
-      invert: If True then the returned table will contain exactly those rows
-        that would be removed if this was `False`.
-      **predicate_by_col: A mapping from column name to a predicate. Filtered
-        columns must be 1D arrays. If multiple columns are provided as keyword
-        arguments then each predicate is applied and the results are combined
-        using a boolean AND operation, so an atom is only retained if it passes
-        all predicates.
-
-    Returns:
-      A new table with the desired rows retained (or filtered out if
-      `invert=True`).
-
-    Raises:
-      ValueError: If mask is provided and is not a bool array with shape
-        `(num_atoms,)`.
-    """
-    filter_mask = self.make_filter_mask(
-        mask, apply_per_element=apply_per_element, **predicate_by_col
-    )
-    if filter_mask is None:
-      # No mask or predicate was specified, so we can return early.
-      if not invert:
-        return self
-      else:
-        return self[np.array((), dtype=np.int64)]
-    else:
-      return self[~filter_mask if invert else filter_mask]
-
-  def _validate_keys_are_column_names(self, keys: Collection[str]) -> None:
-    """Raises an error if any of the keys are not column names."""
-    if mismatches := set(keys) - set(self.columns):
-      raise ValueError(f'Invalid column names: {sorted(mismatches)}.')
-
-  def copy_and_update(self, **new_column_by_column_name: np.ndarray) -> Self:
-    """Returns a copy of this table with the specified changes applied.
-
-    Args:
-      **new_column_by_column_name: New values for the specified columns.
-
-    Raises:
-      ValueError: If a specified column name is not a column in this table.
-    """
-    self._validate_keys_are_column_names(new_column_by_column_name)
-    return dataclasses.replace(self, **new_column_by_column_name)
-
-  def copy_and_remap(
-      self, **mapping_by_col: Mapping[TableEntry, TableEntry]
-  ) -> Self:
-    """Returns a copy of the table with the specified columns remapped.
-
-    Args:
-      **mapping_by_col: Each kwarg key should be the name of one of this table's
-        columns, and each value should be a mapping. The values in the column
-        will be looked up in the mapping and replaced with the result if one is
-        found.
-
-    Raises:
-      ValueError: If a specified column name is not a column in this table.
-    """
-    self._validate_keys_are_column_names(mapping_by_col)
-    if not self.size:
-      return self
-    remapped_cols = {}
-    for column_name, mapping in mapping_by_col.items():
-      col_arr = self.get_column(column_name)
-      if col_arr.dtype == object:
-        remapped = string_array.remap(col_arr, mapping)
-      else:
-        remapped = np.vectorize(lambda x: mapping.get(x, x))(col_arr)  # pylint: disable=cell-var-from-loop
-      remapped_cols[column_name] = remapped
-    return self.copy_and_update(**remapped_cols)
-
-
-class RenamedTableView:
-  """View of a table with renamed column names."""
-
-  def __init__(self, table: Table, column_name_map: Mapping[str, str]):
-    self._table = table
-    self._column_name_map = column_name_map
-
-  def get_row_by_key(
-      self,
-      key: int,
-      column_name_map: Mapping[str, str] | None = None,
-  ) -> Mapping[str, Any]:
-    del column_name_map
-    return self._table.get_row_by_key(
-        key, column_name_map=self._column_name_map
-    )
-
-
-_DatabaseT = TypeVar('_DatabaseT', bound='Database')
-
-
-class Database(abc.ABC):
-  """Relational database base class."""
-
-  @property
-  @abc.abstractmethod
-  def tables(self) -> Collection[str]:
-    """The names of the tables in this database."""
-
-  @abc.abstractmethod
-  def get_table(self, table_name: str) -> Table:
-    """Gets the table with the given name."""
-
-  @property
-  @abc.abstractmethod
-  def foreign_keys(self) -> Mapping[str, Collection[tuple[str, str]]]:
-    """Describes the relationship between keys in the database.
-
-    Returns:
-      A map from table names to pairs of `(column_name, foreign_table_name)`
-      where `column_name` is a column containing foreign keys in the table named
-      by the key, and the `foreign_table_name` is the name of the table that
-      those foreign keys refer to.
-    """
-
-  @abc.abstractmethod
-  def copy_and_update(
-      self: _DatabaseT,
-      **new_field_by_field_name: ...,
-  ) -> _DatabaseT:
-    """Returns a copy of this database with the specified changes applied."""
-
-
-def table_dependency_order(db: Database) -> Iterable[str]:
-  """Yields the names of the tables in the database in dependency order.
-
-  This order guarantees that a table appears after all other tables that
-  it refers to using foreign keys. Specifically A < B implies that A contains
-  no column that refers to B.key as a foreign key.
-
-  Args:
-    db: The database that defines the table names and foreign keys.
-  """
-  connections: dict[str, set[str]] = {}
-  for table_name in db.tables:
-    connection_set = set()
-    for _, foreign_table in db.foreign_keys.get(table_name, ()):
-      connection_set.add(foreign_table)
-    connections[table_name] = connection_set
-  yield from graphlib.TopologicalSorter(connections).static_order()
-
-
-def concat_databases(dbs: Sequence[_DatabaseT]) -> _DatabaseT:
-  """Concatenates the tables across a sequence of databases.
-
-  Args:
-    dbs: A non-empty sequence of database instances of the same type.
-
-  Returns:
-    A new database containing the concatenated tables from the input databases.
-
-  Raises:
-    ValueError: If `dbs` is empty or `dbs` contains different Database
-      types.
-  """
-  if not dbs:
-    raise ValueError('Need at least one value to concatenate.')
-  distinct_db_types = {type(db) for db in dbs}
-  if len(distinct_db_types) > 1:
-    raise ValueError(
-        f'All `dbs` must be of the same type, got: {distinct_db_types}'
-    )
-
-  first_db, *other_dbs = dbs
-  concatted_tables: dict[str, Table] = {}
-  key_offsets: dict[str, list[int]] = {}
-  for table_name in table_dependency_order(first_db):
-    first_table = first_db.get_table(table_name)
-    columns: dict[str, list[np.ndarray]] = {
-        column_name: [first_table.get_column(column_name)]
-        for column_name in first_table.columns
-    }
-    key_offsets[table_name] = [
-        first_table.key.max() + 1 if first_table.size else 0
-    ]
-
-    for prev_index, db in enumerate(other_dbs):
-      table = db.get_table(table_name)
-      for col_name in table.columns:
-        columns[col_name].append(table.get_column(col_name))
-      key_offset = key_offsets[table_name][prev_index]
-      offset_key = table.key + key_offset
-      columns['key'][-1] = offset_key
-      if table.size:
-        key_offsets[table_name].append(offset_key.max() + 1)
-      else:
-        key_offsets[table_name].append(key_offsets[table_name][prev_index])
-      for fkey_col_name, foreign_table_name in first_db.foreign_keys.get(
-          table_name, []
-      ):
-        fkey_columns = columns[fkey_col_name]
-        fkey_columns[-1] = (
-            fkey_columns[-1] + key_offsets[foreign_table_name][prev_index]
-        )
-
-    concatted_columns = {
-        column_name: np.concatenate(values, axis=-1)
-        for column_name, values in columns.items()
-    }
-    concatted_tables[table_name] = (type(first_table))(**concatted_columns)
-  return first_db.copy_and_update(**concatted_tables)
diff --git a/src/alphafold3/structure/test_utils.py b/src/alphafold3/structure/test_utils.py
deleted file mode 100644
index fc25ae428d18bb2c51b7b785503628c8447e6e79..0000000000000000000000000000000000000000
--- a/src/alphafold3/structure/test_utils.py
+++ /dev/null
@@ -1,169 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Utilities for structure module testing."""
-
-import dataclasses
-
-from absl.testing import parameterized
-from alphafold3 import structure
-from alphafold3.common.testing import data
-import numpy as np
-import tree
-
-
-class StructureTestCase(parameterized.TestCase):
-  """Testing utilities for working with structure.Structure."""
-
-  def assertAuthorNamingSchemeEqual(self, ans1, ans2):  # pylint: disable=invalid-name
-    """Walks naming scheme, making sure all elements are equal."""
-    if ans1 is None or ans2 is None:
-      self.assertIsNone(ans1)
-      self.assertIsNone(ans2)
-      return
-    flat_ans1 = dict(tree.flatten_with_path(dataclasses.asdict(ans1)))
-    flat_ans2 = dict(tree.flatten_with_path(dataclasses.asdict(ans2)))
-    for k, v in flat_ans1.items():
-      self.assertEqual(v, flat_ans2[k], msg=str(k))
-    for k, v in flat_ans2.items():
-      self.assertEqual(v, flat_ans1[k], msg=str(k))
-
-  def assertAllResiduesEqual(self, all_res1, all_res2):  # pylint: disable=invalid-name
-    """Walks all residues, making sure alll elements are equal."""
-    if all_res1 is None or all_res2 is None:
-      self.assertIsNone(all_res1)
-      self.assertIsNone(all_res2)
-      return
-    self.assertSameElements(all_res1.keys(), all_res2.keys())
-    for chain_id, chain_res in all_res1.items():
-      self.assertSequenceEqual(chain_res, all_res2[chain_id], msg=chain_id)
-
-  def assertBioassemblyDataEqual(self, data1, data2):  # pylint: disable=invalid-name
-    if data1 is None or data2 is None:
-      self.assertIsNone(data1)
-      self.assertIsNone(data2)
-      return
-    self.assertDictEqual(data1.to_mmcif_dict(), data2.to_mmcif_dict())
-
-  def assertChemicalComponentsDataEqual(  # pylint: disable=invalid-name
-      self,
-      data1,
-      data2,
-      allow_chem_comp_data_extension,
-  ):
-    """Checks whether two ChemicalComponentData objects are considered equal."""
-    if data1 is None or data2 is None:
-      self.assertIsNone(data1)
-      self.assertIsNone(data2)
-      return
-    if (not allow_chem_comp_data_extension) or (
-        data1.chem_comp.keys() ^ data2.chem_comp.keys()
-    ):
-      self.assertDictEqual(data1.chem_comp, data2.chem_comp)
-    else:
-      mismatching_values = []
-      for component_id in data1.chem_comp:
-        found = data1.chem_comp[component_id]
-        expected = data2.chem_comp[component_id]
-        if not found.extends(expected):
-          mismatching_values.append((component_id, expected, found))
-
-      if mismatching_values:
-        mismatch_err_msgs = '\n'.join(
-            f'{component_id}: {expected} or its extension expected,'
-            f' but {found} found.'
-            for component_id, expected, found in mismatching_values
-        )
-        self.fail(
-            f'Mismatching values for `_chem_comp` table: {mismatch_err_msgs}',
-        )
-
-  def assertBondsEqual(self, bonds1, bonds2, atom_key1, atom_key2):  # pylint: disable=invalid-name
-    """Checks whether two Bonds objects are considered equal."""
-    # An empty bonds table is functionally equivalent to an empty bonds table.
-    # NB: this can only ever be None in structure v1.
-    if bonds1 is None or not bonds1.size or bonds2 is None or not bonds2.size:
-      self.assertTrue(bonds1 is None or not bonds1.size, msg=f'{bonds1=}')
-      self.assertTrue(bonds2 is None or not bonds2.size, msg=f'{bonds2=}')
-      return
-
-    ptnr1_indices1, ptnr2_indices1 = bonds1.get_atom_indices(atom_key1)
-    ptnr1_indices2, ptnr2_indices2 = bonds2.get_atom_indices(atom_key2)
-    np.testing.assert_array_equal(ptnr1_indices1, ptnr1_indices2)
-    np.testing.assert_array_equal(ptnr2_indices1, ptnr2_indices2)
-    np.testing.assert_array_equal(bonds1.type, bonds2.type)
-    np.testing.assert_array_equal(bonds1.role, bonds2.role)
-
-  def assertStructuresEqual(  # pylint: disable=invalid-name
-      self,
-      struc1,
-      struc2,
-      *,
-      ignore_fields=None,
-      allow_chem_comp_data_extension=False,
-      atol=0,
-  ):
-    """Checks whether two Structure objects could be considered equal.
-
-    Args:
-      struc1: First Structure object.
-      struc2: Second Structure object.
-      ignore_fields: Fields not taken into account during comparison.
-      allow_chem_comp_data_extension: Whether to allow data of `_chem_comp`
-        table to differ if `struc2` is missing some fields, but `struc1` has
-        specific values for them.
-      atol: Absolute tolerance for floating point comparisons (in
-        np.testing.assert_allclose).
-    """
-    for field in sorted(structure.GLOBAL_FIELDS):
-      if ignore_fields and field in ignore_fields:
-        continue
-      if field == 'author_naming_scheme':
-        self.assertAuthorNamingSchemeEqual(struc1[field], struc2[field])
-      elif field == 'all_residues':
-        self.assertAllResiduesEqual(struc1[field], struc2[field])
-      elif field == 'bioassembly_data':
-        self.assertBioassemblyDataEqual(struc1[field], struc2[field])
-      elif field == 'chemical_components_data':
-        self.assertChemicalComponentsDataEqual(
-            struc1[field], struc2[field], allow_chem_comp_data_extension
-        )
-      elif field == 'bonds':
-        self.assertBondsEqual(
-            struc1.bonds, struc2.bonds, struc1.atom_key, struc2.atom_key
-        )
-      else:
-        self.assertEqual(struc1[field], struc2[field], msg=field)
-
-    # The chain order within a structure is arbitrary so in order to
-    # directly compare arrays we first align struc1 to struc2 and check that
-    # the number of atoms doesn't change.
-    num_atoms = struc1.num_atoms
-    self.assertEqual(struc2.num_atoms, num_atoms)
-    struc1 = struc1.order_and_drop_atoms_to_match(struc2)
-    self.assertEqual(struc1.num_atoms, num_atoms)
-
-    for field in sorted(structure.ARRAY_FIELDS):
-      if field == 'atom_key':
-        # atom_key has no external meaning, so it doesn't matter whether it
-        # differs between two structures.
-        continue
-      if ignore_fields and field in ignore_fields:
-        continue
-      self.assertEqual(struc1[field] is None, struc2[field] is None, msg=field)
-
-      if np.issubdtype(struc1[field].dtype, np.inexact):
-        np.testing.assert_allclose(
-            struc1[field], struc2[field], err_msg=field, atol=atol
-        )
-      else:
-        np.testing.assert_array_equal(
-            struc1[field], struc2[field], err_msg=field
-        )
diff --git a/src/alphafold3/test_data/alphafold_run_outputs/run_alphafold_test_output_bucket_1024.pkl b/src/alphafold3/test_data/alphafold_run_outputs/run_alphafold_test_output_bucket_1024.pkl
deleted file mode 100644
index 5061d10e1fae82c1be476ef761cd75704058d854..0000000000000000000000000000000000000000
Binary files a/src/alphafold3/test_data/alphafold_run_outputs/run_alphafold_test_output_bucket_1024.pkl and /dev/null differ
diff --git a/src/alphafold3/test_data/alphafold_run_outputs/run_alphafold_test_output_bucket_default.pkl b/src/alphafold3/test_data/alphafold_run_outputs/run_alphafold_test_output_bucket_default.pkl
deleted file mode 100644
index 7548c6594f6a28b58e9727cfd0dfa09bc0d1502b..0000000000000000000000000000000000000000
Binary files a/src/alphafold3/test_data/alphafold_run_outputs/run_alphafold_test_output_bucket_default.pkl and /dev/null differ
diff --git a/src/alphafold3/test_data/featurised_example.json b/src/alphafold3/test_data/featurised_example.json
deleted file mode 100644
index 257fa69478f21202bd2c7d93abe984b411c46bf9..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/featurised_example.json
+++ /dev/null
@@ -1,68 +0,0 @@
-[
-  {
-    "aatype": "46551530df4e79371352989100ae6af82ccd939009517b788173bdbb323ae40a",
-    "asym_id": "42c714885d17f6c0fcfebebd171b5ed7d7e77a56cf9c4983d9ff9ff90995bd1c",
-    "cleaned_struc": "<<structure>>",
-    "deletion_matrix": "54f980b5b3be8ce80cb6490c527e38d681deade50f239f2cb7d23cf9d0108c37",
-    "deletion_mean": "655a3ef0465a9f30fddf25f4dde0c19a05c6f9069b83961800c1944165955273",
-    "empty_output_struc": "<<structure>>",
-    "entity_id": "42c714885d17f6c0fcfebebd171b5ed7d7e77a56cf9c4983d9ff9ff90995bd1c",
-    "flat_output_layout": "<<atom-layout>>",
-    "frames_mask": "e8a48532fba32c318f7d809fae3ea0999baa01376b29d94ef3c27d82f12f6a90",
-    "is_dna": "1d83518b897b14e2943990eff655838246cc0207a7c95a5f3dfccc2e395f8bbf",
-    "is_ligand": "cfa4e080dc2885de94224db5075c2feb0805567d31e8898abdebaebc6646ce12",
-    "is_nonstandard_polymer_chain": "1d83518b897b14e2943990eff655838246cc0207a7c95a5f3dfccc2e395f8bbf",
-    "is_protein": "569b0e93b5f77c1a9d430b643f29e600c7db6f44ded72b96ab1dd25351d26075",
-    "is_rna": "1d83518b897b14e2943990eff655838246cc0207a7c95a5f3dfccc2e395f8bbf",
-    "is_water": "1d83518b897b14e2943990eff655838246cc0207a7c95a5f3dfccc2e395f8bbf",
-    "ligand_ligand_bonds": "<<None>>",
-    "msa": "871c93669d8a7dd046f8ba6a1ea7b9fc52e1a2e040c8d9bdc4ae73a77f95d3f7",
-    "msa_mask": "13a46a8a2c5305d2a07bb9587ad092d97749d2b2a2d10ad5d64474a4f0f4c803",
-    "num_alignments": "26b25d457597a7b0463f9620f666dd10aa2c4373a505967c7c8d70922a2d6ece",
-    "polymer_ligand_bonds": "<<None>>",
-    "pred_dense_atom_mask": "1e388e40167a4d31291903d74c98544868d0dc574706cdfd259ddd65f56d2993",
-    "profile": "6ec7da33d5f9801357ca6c82725416ef59025c7a8810bfd67fed2262845b480b",
-    "queries_to_keys:gather_idxs": "e0a2fd867fbae573b5613a98ee037eeb575cc5aa3285db2fe5158cda0e8c49cd",
-    "queries_to_keys:gather_mask": "7ddcbfda2904f013d9ab73c55517ac933ecb3dbfbfab9bb351ee43b5fd66e54e",
-    "queries_to_keys:input_shape": "cf801b14d3da833c486e3d73e355c3c2068523012b42c2b17decc45dbd8b9972",
-    "queries_to_token_atoms:gather_idxs": "3c2d0028564167c93b2f33e877974d45756c1e2e8934270c024fc5f1e85fcf14",
-    "queries_to_token_atoms:gather_mask": "1e388e40167a4d31291903d74c98544868d0dc574706cdfd259ddd65f56d2993",
-    "queries_to_token_atoms:input_shape": "cf801b14d3da833c486e3d73e355c3c2068523012b42c2b17decc45dbd8b9972",
-    "ref_atom_name_chars": "043f3242ff4dff04fd36699ccefdff718c57c325f72c71f33f4c4774e75a64dc",
-    "ref_charge": "27898ee238963105942db19f27a980c1fe4f7aeb396c1e5ea4e82da3876deef4",
-    "ref_element": "cc437747adeea094daf8a0e551be02f406c7e7d9b0a9328a84a59d907c5492b5",
-    "ref_mask": "1e388e40167a4d31291903d74c98544868d0dc574706cdfd259ddd65f56d2993",
-    "ref_space_uid": "97afd7d9d3ba835731457ef090ba4939d707bb2a270d48fde56369bde8e58e9f",
-    "residue_center_index": "dfef3704f73a7ee9a3be86b74e25ecd43e056c76574bc9bb65b6b446eeed87a7",
-    "residue_index": "6bf4ea803d0fcd31446e07f6ba9e012f794ced1fe5ad60b7181f66bb92601638",
-    "seq_length": "5a667734987b65ef5c4d07bf176148504bcf8378a5a1a0e23a7fa2c1121cc143",
-    "seq_mask": "a795c048f28bc4307f8599dc5140fe6e971bce6a34a0349b6c18d6cbb197f75f",
-    "sym_id": "5f170600b904a3464c72817993120957c1ce2eec8c2421af02d4912b5e8d8372",
-    "template_aatype": "6c5c3e7a5e23f064f1e8791f61bde8fb59ccf837095144b29e6c8e1607081398",
-    "template_atom_mask": "8a282b7476e13f6de5afbb52c14ea7baa3434281ed77b542bb790287e8c92e82",
-    "template_atom_positions": "b032ac0c813748a81b8d50ce94487c66510a177ad25e84581c7ea5f4b524987f",
-    "token_atoms_layout": "<<atom-layout>>",
-    "token_atoms_to_polymer_ligand_bonds:gather_idxs": "a0ee989ed2a0a2e3626520afa4032e06144865c8c8f6357293c9f4cd2069eaf2",
-    "token_atoms_to_polymer_ligand_bonds:gather_mask": "d13d4a8b3b8add19b5970157f09d00c12cbda4fed4d74d8493156523f7069b66",
-    "token_atoms_to_polymer_ligand_bonds:input_shape": "6ed5c8b9711af5b9c7c3d98ba048bed4dfe5974be758f1a632abd746b8278ed2",
-    "token_atoms_to_pseudo_beta:gather_idxs": "3fd8de4dd02450c6e249f33de9c6573694f7991e6a36528d6f32b6c6334a4d4f",
-    "token_atoms_to_pseudo_beta:gather_mask": "a795c048f28bc4307f8599dc5140fe6e971bce6a34a0349b6c18d6cbb197f75f",
-    "token_atoms_to_pseudo_beta:input_shape": "6ed5c8b9711af5b9c7c3d98ba048bed4dfe5974be758f1a632abd746b8278ed2",
-    "token_atoms_to_queries:gather_idxs": "50a1708678bb3d848be6fb49816196b13fcac36891817dac585f4a7556a8310e",
-    "token_atoms_to_queries:gather_mask": "3f4ac4f311cea0c7f6b8464e225815b791a767c9a8d15f9c7fb488c49f674fa9",
-    "token_atoms_to_queries:input_shape": "6ed5c8b9711af5b9c7c3d98ba048bed4dfe5974be758f1a632abd746b8278ed2",
-    "token_index": "77627a5d3856b90a27ae1f5bf5aa14754743c03c00a97bab68f4e7961a405454",
-    "tokens_to_keys:gather_idxs": "bc16a2a2b81bdbb3fb3ff180d984704b201866a7cdc373fb345a9be417aa246e",
-    "tokens_to_keys:gather_mask": "7ddcbfda2904f013d9ab73c55517ac933ecb3dbfbfab9bb351ee43b5fd66e54e",
-    "tokens_to_keys:input_shape": "5545412ee9a21a04712910d53fc1447c73ff94a29ddd1268131b4ed30d1dbe07",
-    "tokens_to_ligand_ligand_bonds:gather_idxs": "bac3003591bd8ef44d85b82cd4d23191d48496c1992e61d3fca2a37e6ddd34ea",
-    "tokens_to_ligand_ligand_bonds:gather_mask": "4d33ec9784aaf54079b4445118c1be26b4a5555e1d6034ccc4182defd86f2068",
-    "tokens_to_ligand_ligand_bonds:input_shape": "5545412ee9a21a04712910d53fc1447c73ff94a29ddd1268131b4ed30d1dbe07",
-    "tokens_to_polymer_ligand_bonds:gather_idxs": "a0ee989ed2a0a2e3626520afa4032e06144865c8c8f6357293c9f4cd2069eaf2",
-    "tokens_to_polymer_ligand_bonds:gather_mask": "d13d4a8b3b8add19b5970157f09d00c12cbda4fed4d74d8493156523f7069b66",
-    "tokens_to_polymer_ligand_bonds:input_shape": "5545412ee9a21a04712910d53fc1447c73ff94a29ddd1268131b4ed30d1dbe07",
-    "tokens_to_queries:gather_idxs": "f82b61cc7f007a744fc9186107647ff333b598642a681b046d61aef4994931e1",
-    "tokens_to_queries:gather_mask": "3f4ac4f311cea0c7f6b8464e225815b791a767c9a8d15f9c7fb488c49f674fa9",
-    "tokens_to_queries:input_shape": "5545412ee9a21a04712910d53fc1447c73ff94a29ddd1268131b4ed30d1dbe07"
-  }
-]
\ No newline at end of file
diff --git a/src/alphafold3/test_data/featurised_example.pkl b/src/alphafold3/test_data/featurised_example.pkl
deleted file mode 100644
index 05e9b100206fa4de80ff5df6ae479aadf364f2f1..0000000000000000000000000000000000000000
Binary files a/src/alphafold3/test_data/featurised_example.pkl and /dev/null differ
diff --git a/src/alphafold3/test_data/miniature_databases/bfd-first_non_consensus_sequences__subsampled_1000.fasta b/src/alphafold3/test_data/miniature_databases/bfd-first_non_consensus_sequences__subsampled_1000.fasta
deleted file mode 100644
index 98c1e3d93365a662dcfc9950ff465f012f8b0a87..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/bfd-first_non_consensus_sequences__subsampled_1000.fasta
+++ /dev/null
@@ -1,2000 +0,0 @@
->SRR5689334_7619591
-TFRYLCRQMERRLDGRPTLVVIDEAWTKIRKQPEWLEESLRTLRKKNCAVVLATQSLSEVVESPIASVVFESCQTRLLLPNPEARTPAIRALYTQRLGLTEPQVDALASVAPKRWYMYVGGGRTRLFTLDLGPVALAFVGASGRVDVAQIDALHRR
->SRR5262249_54877602
-WRLEHPAVREAEVVKRLVNGREAVTAVVVSDSGVSPAELCAHLGRTLPAWMIPRQFEFVGELPRTTSGKVDYPRLRSSPSHLVGEGGSRSESGEGYFMAGTPEAILAEIWSAVLGRPADPDAGFFDQGGDSLGVLQVVAGAHARGVTVPPELVAEGRSLRDIAAVLPTVDHSVAPGALTGSELEYDTAAVLDGWPSPSARRRPAGPAX
->SRR3546814_5789022
-IVCLFYVSSCCFLFVYVFFFKQKTAYEMRISDWSSDVCSSDLTPAQIDRSFHRNTAHQVTRPAATHRRNTLAANPELLAGLRALGDFQLHATVEGRDLKLTAQGLINETDRHFAEQMLEIGRAHVX
->B9TJ46_RICCO
-RGDRGDGDRLLLGDRARAAGRGDRAHLHCPADRARPCRDLPEGEDRRALDPRLAARAGRSRHHPGRPAGRAAPARFGARHGGGARLGGVLRSQPRHRAPPGAAGRADRDRLLPELVHPRPVRAAGALAAGDSGGGAMAAGRARRRAGDHVAAAAFLGLCAGGSAGAAHGRIYRLCLGSDHGLAVLPRAAYAGYHRRHLADRRGMLDGGAQSARHRRARSGARTVMIAIRTATPDDVPLILDLVRELAVYEREPDAVVATEAMLHDALFARRVAESLIAELDGRPVGFALFFHNFSTWTGKPGIYLEDLYVTPGARGAGAGKALLRHLAGIALDRDCGRFEWAVLDWNTPAIDFYRAMGAQAMAEWTVQRVTGDALVALAGR
->SRR3954452_1678131
-PEAARARAAARAPAPRPPRWSLRRPGSTRRRILAGSRRVPELRELEAESLRRRLVACGVGESELDPVGAARQRPLLDAQKRQDVLALLHLQRRLAGAAEGAPAWRTAEDCRLQRAGLRRSELEDQRPTAGVTLDLAGEARCGGVGGSRRRRGDRFRRWRGCRRGGARPCAGAGAGAG
->SRR5450756_2573138
-LHRVDRRQRQMCIRDRAYTAGLLLVCVSLIRLSSVRSEYSPGLEDAPVWNSDSPVGSKPGPAKFQPPRSRICQVVVASSPMIAENDRGTRLMSMPACAASAWYAATSCWKNVTPVTX
->SRR6266446_6012191
-VSDLPLDSYRALKLPRCRGVGVGRGVGVGLGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGLGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGLGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGVGLGVGVGRGVGVGRGVGVGRGVGVGRGVGVGRGVGRGVGRGVGVGRGVGRGVGRGRGVGSGGLIEARIAPLFFASLSNQTSPLASCRMIACFNLX
->ERR1712048_306589
-VARMTISRVALAFGCVLTCAHAADPTSPAGNVEAVCEYVSNGLENYGERLLRFPLPPSCQKYQGIGEEVLFKFGLQSQSCYQALSGPLCALQFSEYEASSTCKSTLDLFTTLIETCSNKNVMAATYSDCVSYDPNTRTISNPEAFCKSSFLRVDKGESPEGTSAGFEKKTFGQSEIMDCKRIAENFNACQIVGVGLLGYSNRFCMGKGFPAYCQKYPTVVRDGTFTRICKNLVIPYLLESNRRLGTKREINHCDGIYENYLMFLKSRKDAYSQKAEAAKESLESMKNSSEMFSSFKRVAQALSQDNDSLERDSTEVLNQFHQMSSQNMAFDAQILTEFQNLGASLAAAEQAATVIEYPEMTENAEENIKIFAKESPSIESLDQAITKSSVSVKNLEALIAQGGHVSYSQAYGFYPIELASIEELRTRIKKMSESLKPFTTTYSEEVLALEEPPQPGVDASFLNAAQTFGKLNDIYGEQMALLTKLQRYGSQTGNVFTAASRSFKX
->SRR5580765_3802522
-GLGLDDAGRIADRRRSGRHRLQHHRVRADPGVVADGEAAQHLRVGADDDAAAERRMALGAAGERGAAERHPLVDGAVVTDLRGFAHDHAHAVIDEDAAADLRPRMDLDAGDETGQVRDPARHPVEAVTAPPGRLAVQDDRMQAGVTRQHLPRRPGGRIAFTDADDVFAQALEHTIFARVTRSASLSGSLFHCSGDAAQDLDLLHGERGPIGQPVQPRHQFPGRGRVEKADRCQRLLPVCDQAAHRDRIGQDAGVGPRLDRIAAQRLAPVIGEELHRLSEVERAVARIGRDREAGVAGVEVVVRQAEALRAEHERDRAAAGRQFAEDRARGEGRRAEVTRRHRRRPDPGHAVERVAESRDDAGALQHVGPSRRHQHELGKAHHLDRPRCRADVAGVAGADEDEAGRIGGHLSRPLKLRLSILQPRPGGPPPARARLQTILPMSQALHPMLNIAVKAARAAGAIINRASLDLDRLQVSAKSTNDFVTEVDHAAEAAVIDVLLGAYPGHGILAEESGSTRGAKDSDYLWIIDPLDGTTNFIHGLPTYAVSIGLSFRGQMQQAVVYDPARNDLFYATKGRGAFLNDKRLRVSKRTRMAEALIGTGFPFRQGDDLTHYLKVLEMVMKSCAGVRRPGAAALDLCYVAAGWYDGFFETGLSPWDVAAGSLIVTEAGGLVGNFTGEADFLYRREVVAGCPKVYGQLVQVLSPYSTLSGSAX
->SRR3989441_2692536
-AASRDALLATQRTRKRVAVEHARRSSFLAPRVAGVDIDRLDDPDKWGKIPPLTKDELRALGTDEFYSGFCIQPPSAAVEFWRSGGATGRPLFYPRSAEDLPYCLLGFRRIWECIGVGAGDVVHDSFPLGIHPIGQMVARSAQEIGAGVVWAGAGTPPPSALQLELIATLRPTVWAGMSSYALHPANVAEAQGVDRAASGGGPVVCPAEQLPGARRAKLERAWGARVYDTFGMTEGSMMAAERDGVDGMRLWADLFLVEVVDEVTGKPVAEGQPGALVMTPLWSHTATPFLRWLSGDIVTLRWPEPDADPFSVFPVLKHAHRTSGFFKIRGVNVNHTELEDFMFRQPGVLDFRAELVTHHDREVLRLLIEVVRGADPAGLYFALLTKKADPAHEVTVLERTRADATFGFGVVFSDATLDNFIEADRPTGEAITRAFAHWDDIDIHYQGQVLTSTGHGFSGMSRQVLLDILHTRCAALGVTLRFQTDVTDLEPYRSADLVLAADGVNSLVRSQYAAHFQPHVDARGNRFVWLGTTFPFRAFTFIFKDSPHGLWRVPAYRYDARYSTFIVETTEATWRRAGLDQASEDDTVAFTERFFARELEGHRLLKNRSLWRSFPTIRNAHWHWDNVVLVGDAAHTAHFSIGSGTKLAMEDAIALAAALQRHRDVPSALDAYEEERRPQVESIQRAAQVSLEWFEQTERYHGRLEPLQFAFSLLTRSLRVTHDNLKVRDAKFVETVDRWFAAKAADQSKVPVAAQPMPPPMFTPLRLRELVLANRVVVSPMCQYSADDGTPNDWHVVNLGSRAVGGAGLVIAEMTDVSREARISPGCTGMYKPEHVTAWKRVVDFVHAHSPARIALQLAHAGRKGSTRRLWEGIDEPLAEGNWPLISASAIPYFPHSQIPKAMDRADMERVQADFVKAASMAEAAGFDMLELHMAHGYLLASFVSPLTNTRTDAYGGTLDNRLCYPLAVFDAVRAVWPAAPPISGKISATHSADGGVTPEESVEFARRLKAHGCDLVTVSTGQTVAHQHPAYGRLYQTPFSDRIRHEAGIATMTVGAVASYADVNSILAAGRADLCALARGHLYDPYWTRHAAWEQGFEVAWPDQYVSVKGFTPRLRX
->ERR1700679_3575755
-ARRESGSRGRWRPEHQSATCQHRIRPRCAGAHVRRSAREAPHKVSMVSWDFLNWLEIYGSELLVKYDIGLESSGVLHRRFHPECRFELQLSWMSGSERSRQPKIMPRQIGEHWPTFQDLLSKX
->ERR1700756_3832034
-KLVQLLKASSYLSSILSSSSVVSFSGSNRARRPESMDWNPIPLTSGYKASFPSPPRVHWATLFAAIAGSEGLVLWLVPQPYRDFFVNLAIAAWAIYLCLWIRKIDIRSLSLYWALASFATGFLFSWLLWIVVIFEIREELLEHYNRREPIGLRLNLVMTLLFSFVYFQYHLNKIAKEKNQQRSIELVGAGRAFLQX
->SRR6267378_1761704
-LARPGAGRLGARDVRARGGTAARRASARRHRGVARRAARARPAPGGRRRRRGAPARKPAARAPARPADACALPFGPPGRRAQDLPRGSPAAGRRARHRAGPRAAAALRPDPPAGADPRDDGRRRAAGHRRRLGGGLGRHPRRAPRAGARHRRHVERRQRRAPAGARPAGGVPRADVRRPARTCGRPREGRAVHRRHPRGRPALRRAAHDLQPRLRAAAGAPLPRGPAPAPAHGGRAATADRDDALRPRARARLRRGGRAVRRRLLHLARSRARKVPTSLRGGRRARDPAPERVRRRAARAAACDPEDPRRGRPRARAGVRELRRQRGRPHRVPRGDGPRRRPSRHARRAPAAKPLPLPRLRAPRLEPACVPAPAVVGRAGRLSLVGGAAGGGPRGAGVLEEARRGAELARPRRVRVAAADTARGRVARGSRAVTTVTEAVRTPYKGLSPFDDTELDALLFFGRERETKIVVANALASRLTVLYGPSGVGKSSLLRAGVVHSMRKLTELDPIAVGYYSSWAGDPLVGIEEAARGALTETFGGDPGEAAGDLADRLDAWTAALGCE
->GraSoiStandDraft_16_1057320.scaffolds.fasta_scaffold7416948_1
-MSNKYGDGGMKRDNTSLTMIDPTMIDPIGTQQMGVDTGSFQLNLAGDTPAYTPGKGVSWMKRAGMNIGEAFGGVGSKLSNMSAGSKMGIMSGVGGILQGIIGGGARRARQRDAKTEYTKQRKAYAALDARNLSENIKNPYENMENVYEDMTVNQQQAQFEAQQGAQSRANIMQNLQGAAGSSGIGALAQAMANQSQLATQRAGASIGMQESRNQALAARGADTVQQLERRGAFEAELHKVRGAEKARDLEWQKQEMALGMAMQEKAEADRARQQATNALVGGIGTIAGSVLTGGASSVLGGLVKGDNX
->SRR5450631_843885
-PRQRARDRPAGPPSDRRQPRGAPHANRVRAVASPGDEPGPRADPRLSAANRPRLGLRGRAGQSADLYRSAPPQARARTKPSTLDRHRARRGLPLSSRRLARKDDIVLLQARALMKRPVVPVVLSPPRRSLIDW
->SRR5690349_11316732
-DHRRADAWRRGLCRELWRYRLRAGRRHGARLARKRFDARRVDGEQGLRGAGRGAASTREQMNELLARLAALRRNKTAVNAATATVIALAMALLAMLAVDRISFFTSADRFVRDWEVAYQSTPEDQDPNILILAVNEQTMQNFPYRSPLDRGFLANLLT
->SRR4029077_5045757
-XKTKDITGGLPRVAELFESRKPKEHAVIAEIDGTVSFGKDTKGKRKVLVTPDRGDAKEYLISKGKHLAVREGDKIRAGEPLMDGAANPHDILKVLGEKALAKYLVDEVQEVYRLQGVKINDKHIETIVRQMLRRIRVIDVGDTGFLVDEHVEKYLFEEENERVMGKGAKPAQGEPLLLGITKASLSTESFISASSFQETTKVLTEAAVQGKVDYLRGLKENVIMGRLIPAGTGLGAYKRLSVHVEDGGAQDLPAPPMAPAAAAAAPRTCLQLRWPLRPPRRRRFPWRSSAHGTPSACNGANVGSLRARRX
->SRR6266404_2839436
-XMDRRSRAPWAHRQELRAAHTDSRAARPGPHPPPATARTHRARFAGERHEAFGVAVVATEAREAPGPDATAQELAELIGNSSGLSGRAGCHNVQSRTLVCKPQMKMSGFSKVEMSALPPGGRDRGDGDVDHGGTGALGGADAACRAAPDTTAGRRTAGAECTPGPAARSALCRRRRRGTRVAP
->SRR5262245_52145018
-ESYGIFHALSGASSGGIADFMYESALLNPALDDCGAVSCDEVTVRRRVALLLKGFRGYFDFLKNDSEEAAIFEVVRRFYEEIKNRKIEALLDVGKDLKALKAVRKILKNEDIRSLINTEILELFELENVPSLPKNLRRLVNAVKEGAALGKTNI
->SRR5688500_19911985
-PTPHLLTLALIARSPTALSTLPLHDALPISARVVEPDQRHTNPERQVHQLDDLFGVRRAERAAKYRKILRKDADGAAVDARMARDRKSTRLNSSHLVISYAVFCLKKKNKTSE
->SRR6266576_2342774
-XMQRKNARVDPDGKLPKEFPLTSHPNGQYSKKHAQKPFYFGRIADGWRAALERFNHDWPYILADQVPPPMGTDPTTVEYVARMFLARSLKRLERGQLSGGSFVDMRVAVGIAATSLRQAKKVRHLKPSDFAELREDLSFRWEKQGEGETARWAKREQRIGVAALKRR
->SRR5438552_10607511
-FLSLMCLRLLLFFSFILLPPPRSTLFPYTTLFRSVDLPDAGLPHDPRGVPLVDPPDGHHGDSTGRLRHHRRDDRHARLRRRGDRSEEHTSELQSPDHLVCRLLLEKKNRNIQKGKHE
->SRR3954454_14771217
-RRGAARGHRPRARHHASDHAPHLRALLHLRRRRAGRRAGPGDRVGARGPHERPPDRPLPDRHDDLHLGAAGMTGPARRTLVAAAACAALAAGCGGGKDTHVVHTTTTRVEVLKGIGSAKGAFDPRAIYAKEAPGVVTIISLFAGGSITDLLGGGGGSGGQTGLGSSIVLDGKGDILTNAHVVTT
->SRR6185503_6756615
-XMVFIDPIQAKHERLTLSQGNIKTNPNPFLIRGKARRHKHVRQCCRNRVANLSVDRAVVVIDRMTASHSSTPRKESTILLRKAACLQFPAAGNLAAYFFGLQPGFLQNLPIIERFCPGRREWNRELRE
->SRR5581483_2541413
-AGPAHRRALQADAALRGLRARRSEQGRLAGSRRAGDDADEDRLRLVGGDREALDARDDRCGRRRRPAALARGRILRAARRRQARRRLRRLGHDEAPAVDPSRRDALRHQREPRPRPHRHPLPRGPLNLNAVAAARRTSNVELLWDLVFVFAVTQISSLMTGDLTWPGLGRALLVMALVWWAWSAFVWTANADDPNSGIVRAVLLLATVLIFITALALPHAFAAGAVLFAISYAIVRLLHLALYMDLWRRHLATFSAIAGFAVTVLAGMGLLVAGAFAGGLWLIGLWAVAAAIDYAGPGLLTRRRLVALQAVAVEHFAERYSLFVIICLGESVVAVGVGAAARGLDATVIAGATLMLLITIALWWAYFDRLAAAAEDGLRASTAPVLAASDAYSYIHLVLVAGIIVFAAGARIAVGRIDAPLPLAASLAFGGGIALYLLGVVAFRLRITQRLGVATVAGAAVAAVVAIAGVNAPAWVEAVVLLVVLAAVQLLERRSAWRX
->SRR5688572_11341527
-AAEASVGEVTCAVREARDAAARFVGIPLTLSTRTAAIEMLQRLMARDAGRARWVCFLNSHSFNIATLDGQCREALNGAYAVFPDGCAMQVAARLCGIRIPENLPGTDLVPALLESCSGRCFLIGDRPEWIERAVCELERRFPTWSVVGFAPGYFDSEEGARRVVDRVNGAKPDLLLIGMGSPLQE
->SRR6476661_7197889
-SDIRTCSKAAANSPGGASLATRLAVAGGGGGGGGLGTDAKSPGTILGGAGGSGGGPGGPGGPDAHADLGGQPGQQGNQASGGAAGANSAESPATAGQLGDGGYGGTAPSGGGGGGGGGLFGGGGGGAGTTTIVDPQKLIIATAGGGGGGGGSSGVPPGASG
->SRR5690606_8821431
-XIGEDTAEMATTTKEAVVATHIFSHYTARPDERSEAEPLQRLMHYPAMRLIPILILCALSGCSLFGADFDDLDPGTFRMKADGKEMSGQATYYPERDLASQEPLVFLESDEGDFMFIRSEAFLNAISGQSVTPRASYRPLTGGVFTRRSGRVEX
->ERR1035437_2281458
-IDEEYGTGPGGLSGNEDAGQMSAWLVLSMMGFYPVCPGKPEYVIGTPAFDEVQIKTGIKAKPFIIKAIHNSSKIQEFKSVTLNGLPLEGSIIQQIGRASCRERVXX
->SRR6266478_5987559
-GGETAPGWSQFKFCRSSRTVIGWDHTGPRGAAARWGWTDPGAKGPPSTPKPPVYYVGCSSLNSAPQIGGAVSYRGGPIDRRRVLFRYFAMIAGLNVPTKLSNGGSRHGRRCLAEQGGRILGEGTCDQRSTTCSASSRAGAQLSQVCX
->JI10StandDraft_1071094.scaffolds.fasta_scaffold2749928_1
-MILVSGLPATGKTTFSEWLSSEICIPLLSRDRVLEKYVEIAKVHCEYEEQRGNVADNIPAVFLGHSIPALLFWFFCEEIMKSSSALIIETVFTNQMKETIGNLIEKYKYQTVNVHLDASVEIKRHRINERSPNKKISLENLKKAHESEKIKDAKNFRYGNCIIYVDTTDFSMVSYKDISEQIRQFILRNVX
->SRR3989344_2742104
-RSTFGPRFNIATKQDEREQGGRRFPERMIDVEKEKADRTIEISRRSAENHQNIHVGHANTKGGESVTIEWPSNNKLNRGGQHPVNIVQIQTPNFMHMFQIKHVNEHIINNDRGRNDEGKENAATSLFDLLHLFLLFFLKCPAFLLRPDQIVTQLIDELINFLKRDHRFVKLESHLLGAITSARLNHPRLLPHQLINQDRAGGAMHALNFKYEFGHCVX
->ERR1700722_7849674
-STRAALTHWAQCLAFLSPPSVYQVSSNSAGRSSSNPCSMARPWSSLSRWQALRSEGAVSCDRFARSTIRVRKRIAGGHNGVFARSPRSAAIGPSPKCRTPRLRSRTARQQLIGRIRMSRFYMIGGGLLASAAIAGLHAGVAQAADDEFMKMAKDYIAQASAPVTTWDGPTTGPKAQGKKVVIYVSADQKNGGASGVGDGVPEAAKAIGWDFRILDGQGSVPARSSALTQAIALKPDGIILGTIDAAEQAPIVEQAIAAGIKVVGWHAGPGPGKIEAVPGVFTNITTDPNEVAKASGLYAVVDSGGTAGVILFTDSIYAIATAKTNAEKAAVEGCTGCKVLSIEDTPIGDLSNRMGQLTTSLLAKYGKAWTYSIGVNDLYFDFAAPSLQSAGVDPATGYPRNIAAGDGSVPAFQRIREKQYQIATVAEPLHLHGWQCIDEMNRALAGQPPSGYVAHVHLFIKANIDKDGGAQNIFDPDNDYKGHYKKIWGGMX
->GraSoiStandDraft_35_1057300.scaffolds.fasta_scaffold1321871_1
-ITAQTGSFAGIVHVATEAGGLETGQKISIGREVSASHDGIWINRFNYWFTTADFRVGDATNYIQVTGSGGNFGNDTRIKMDTFTLEAGNLDINSTDETIRLGSVTDFAKDGSAKGILMGKESSGNYDFFVGKEDGNYIHWDDSDNSLKVVGTIEIGSAGSFTPDTATQNQLAALNATTGSLSSETGSLQNATASLYTSASAQYLTGSILRQDSGSMATQVTLANDGMTLNQADGTNLASYGSTIRIGKSGEGRVEITDTALDMYDGAGSPVSRVNLNSSGQLTLGKSSDNRVQITDTSFKLYEGSNERINITSTGVQILEDGNNFTEVSASGLSIHAGGQPKAYFTDKWTTLSNDARSQKENSVQIWNGGGIGIYRDANNYASMSADGMKLYQGGSHVATFGQDVYLGEVGSSKRNIFIDADAGIKIRNNTTTIAEFGEDAIIGEVGSNKRNILIDADDGISIRDNTTVKAKFDTDVILGEVGSSKRNILIDADDGISIRDNTTVKAKFDTDIVLGEVGSSKRNILIDA
->SRR5271165_1503329
-APRSPGTTSSWTGCLATPPGRCSSASFARYPGRVGIEPATSPEGEEQATLAEPAASSRKLERSSGRLSDLPSGESTGSRITSVITPRETLHLQEINRTRIFTVMVVALSAFVLATLTVIGGDPMAKRVFAFALLAIASSCGWLRWELRRDEGYTVERATSVAYISIFCAFTGIWFFGVFSPAPMILPFGIAFFSVGQSQRAVFGTYITCAILQAGLMLAVLGGVLPDQGLIRSSGLAPLEQ
->SRR5258708_2540147
-LQVPGHALPHAGVGAQPVEQKQRRPPVGLGRPPLQPLQTHARAFDPTLSHERIVWEAGRRNAPQWPATTGSPAPWAGAGARCRRLMARQLAAPIASATTGTSSVGRIASMNALANTSCAIRAICSATWGGRPARWPAAELLDAPTSRPLLPALLKPSMKRWRAAAGTVLGSWAAYWMAWLWRVTPSWFCSPPPVIAPPIPPP
->A0A0R1K2P3_9LACO
-MLRERFDKGEKKMSLRVLLVCGTGASSSFMAVSMRKAVQQLGLDYKIQARSESELENYLDEVDVIMVGPHLSFMEEEIKKSIGGRKIKVILMNPAYYAVLDGKKALDHLQSELDYKEEDSNK
->A0A2A4RMB9_9BACT
-MNPDLKVYDTQIMIDGKTENIRTGMSCKATILIEDHEDTLFVPLQAVVGKAGETVVYVVNGKTSEARVVETGLDNNAMVHIISGINAGDKVLLTPPLGDDLFSASSKPKDAQAKGKPKGERQGKPQRGSSSQGMPKGKRP
->ERR1719320_184571
-QSCLTSLHTNHSYTPGITNSWIMEEALLRKKAKKLRLFTFWVENHAESSSPWLRRALARADSGGKRLLADLERFLEEVEKTGGRRDGTVLCNSEMTGGNDISLIYPWLHISSSLVTINTWVRREESRDIEAAGGSLSSYPCYGSLERHEYLRSSSLRKRKVVQGTYSIVESVVPSQEVLPAGEELCILLGFRTTDDNCVDTVEAETERSGEARTWREWTGIGTLYQNMTQEDSVEVIKVEFMESHIPDHAAVFHYLVLMFLQVTSHRGKLGVLDAVARFRVRNMSGYVTVYSNLSDVTVDDRADDCLGDNLKTLQHSKQEAKKMFFKQEIIQVEQSGRKMEEX
->SRR5215204_6862387
-GIFFFFFIFFVVEKKWNFFFFFFSSRRRHTRSLCDWSSDVCSSDLRHPNSRRRRGKGGPDQSRTRSRAGCRFRALPRCHGLPHRAGSVGRRRAHGLRRCWRPTPSRLRFLLLHQASGEAAKRGMLALLEICTEVPRSSVLRSWAREERVGASFGVSPPPTKGARWTIRKGKX
->ERR1719195_1908659
-RRRTRMLIGEVQIQEWRLAVPSLPTCRLVVVPQSPLADQPVPLPLAARPKRSPRRRPPNQSLTPTLTWAWDFSTKQLKKPLKLFHPNFSTPLLVCLLGSGLQNCILDDSWVEIDLFLHSLKKK
->ERR1719313_113703
-RRAGVRFQRRRALPQQALLLCTLAVVAVVAPYMWESAQRGAASLEYSNAQVSSGGRSLLSAITPHEDSAPCCSTACCKASDGRTDRDSFCAKRLESNGALNLTGTCMKRSTVLKDDQWGPSVALGLRATNASSGMLYCYSHLDCPVGHECKTAVTIQTNVNCSTNSDCSADRVACLTNTLNCTEPKCEGGTLSESGVRTTCRVQSPDSWGVCRVFDVDTEPTCDVSKGGINPRDLFSCTQKRQGALILHLIGIYWMFNALAIVCDDYFVAALEELVERWGISEDVAGATFMAAGGSAPELFTSIVGVFLAQNDVGFGTIVGSAVFNVLLVIGACSVAAGKVLELTWFPLFR
->ERR1719245_442272
-FSLTLRAHLPSTIAAEHTAVSPSSLRVPDSPGSPPGSNKESPSKARKASLQGAGITSKLPLKQLADFAVTLSSPDEKSGGKSFGNIAKPPTPKASSPSESTPFLPAPAPADPSMPLSPTDQLKLRRKRLVHYKSNAARNNNRSDPDSPHNQLLDLESGGGAGVGGFHQRRGSGHSLPGRLLKRTNQMKRRESQALLEQIRKRGSR
->ERR1712194_41197
-HGDAPEHMAIREAVMRTNMDTVHGEMKGSDGDHVLFSPKALLESLGEMGQGISAYVVDAHKKLLVPYVVLEFVSGIPLEIAPLSLGGSLPDEIWPKLGHVCALDILLNNMDRLPLPIFPTLGNLNNIMVQDSGRRAVAIDQQVNTITDDIGLMVYLEKVRTFVRDVARLAGEDSAETDDILGHMRDSLKTRAQTELTESNARLVLQGMWETLKHIAKAWESGDLKAAIDASVLAAGESLVSGVIEKEWSFLEDGVLAPPASCDHGPYQGVVEASAAQLRVVACEISTSVRSAGAFQLGASANGSTLQGTSSARQLADLTSSFVKX
->SRR4051812_43875519
-AHKKGSFDEARQLYKQSEQSARAALDLARSYPPAHFELCRVLHRQALLPGPDVDALFEGAIGACRQATTVDPDDESIVAKAGTALMSAAERDLARGREPSTIDEAQLDVEHAIALNPKRSNSYRNLCDVLLVRAESLSARGRDAGPAFAA
->A0A1V2Q3A6_9PSEU
-MQTISRGSVHIEQCENCKGVFLDGGELEQIIAAERAHYAQPYRPEGFPVPPPAPTMAVPVNVGVPVDAAVPVDVGVPVDTGVPVDVGVPVDAPVPADGAVPVEGAVPVDGEQPPPATPAPAPAPTTGPPPPYQPPPGTPMPGTPAAAPPPYQPPPGTVTGPPPPVYPPGYYQPYPHRKRSFLEELLD
->ERR1043166_9773265
-VFFFNGTATTEIYTLSPTRRSSDLKAVSASATSAFRLRNRQRFRAGPDSRRSEEHTSELQSRFGISYADFWLKKKQHENIFDSWWRSGDRVLNHRGSTKFSQPRSEERRVGKECRSRWSPYHX
->SRR4029434_590066
-PLSHSHTHTHTHTLTLTHTHTTHTHSNTHTHTHTHIHTHTHTHSTHTHTHTHTHTHTHTYTHTHTLPTHTHSYTHTHNYPRDGLEPVSQAWFSLLRDICFADSSGWQTGKSSDSHKTHSDEREGLDMRV
->SRR5690554_368104
-XMELKKKVPEVRFKGFSGEWEEKELGKLFDITSASRVHKNEWTESGIPFFRSSDVVADYKGQENIKAFISYELYKELSSKTGCVQKNDILVTGGGSIGIPYLVKNDEPLYFKDADLLWLKNGNIINGNFLYTFFSTLGFRRYVNSITHIGTISHYTVEQAKLTPFKVPVRAEQDKIGDYLLKLDQLISLHQKKYNKLTNIKKAMLEKMFPKNGADVPEIRFEGFEGKWEEKKLNQVSEIIGGGTPSTIIPEFWDGDIDWYSPTEIGDKVYAEGSVKKITALGLENSSAKILPANNTVLFTSRAGIGDMAILRKDGATNQGFQSFVIKEDNDPYFVYSKGHLIKDYALKHASGSTFLEVSGKQLGNMNFSIPIALEQSRIGTWFQHLDQLITLHQKKYNKLTNIKKAMLEKMFPKNGSDVPEIRFEGFEGKWEEKKLGDFTNFRRGSFPQPYGNKEWYDGKGAMPFVQVVDVSDNLLLVNDTKQKISKLAQIRSVFVEKGKVIVTLQGSIGRVAITQYNAYVDRTILIFEGYENKTDSRFWAYTIQKIFEIEKMKAPGGTIKTITKEALSVFIVKLPVFEEQRSIGTYFQKLDHLISLQQTQIDKLKNIKKACLEKMFVX
->ERR1700679_1367360
-KLLSYILLTHLFSIWMNEAQTAINVKPGRGTQAGKNPAVRILFYRLCRLLTLPIIPVFVFDGPDCPKMKRGVNVKTGKSHWLSSPFKKFIEVFGFSWYMVSFTSCDLGFPFKYL
->SRR3954454_14908726
-YRLRRTPEYPAPARRAARLQLSERPARGGGRARSRCVPDLIVAGLARGERRKGTAVRLEVDQGRAVETIEATHEHTLAFDPHQPDKLRPDRIGPHGCAQRKGPTRDAVIAGALPDEVAARQVQPVEHLQALVFRDPIERCDPGLEHLDPAGRTIRTALAWARQTIDPGRVDPADEHEPGVGRRWRLYRHLAGADLVLPDHAARLYWSTATITSEVFTTAX
->SRR5436190_15766111
-XMPPATRTELNARKLFRTRCAKNTSTPPATRPINVRPVSLIRPLPMAYCMSNPMPITSTAIPILLIRFSPMNFSRSGWRSKNEGRGGGGGVRSGGGCATNGGGVLAAVTGARTTVGAGCGGTSRTGSWIASFSAVGGLKTGGVTAGGEGTGGGAALDAPSAMDDGPDRNRSASFSMLWRVLVSSRDTLPSRANRTIINTMIAIGTSASRTKYSSIQPGFWKQSTHEAAHRSGRMQDRRLAPSIFQGYLPSICTGCRIRVRQDSRGGGGPFLPPX
->SRR6266540_2703125
-GRDAPERRAAARLAHARAGPQADRRAQGRAREGEDRGEAPVPARRAAVEALQARGGAEGRREDPRGARDGGGGAGGRRGGGEDRREARRRRGEARRVRRGDRKARGGAGQGRRGARGARGGGRGGRAEALLGGPALLGRGRRWARRRGGGPPRRVAPVGPPLPRAARHARLRLGRVGRAALGRRARGLGADRAAPARRGRMGEEGRGALRARLSRDPRGREGARRLEAGGAEGGGRPRRRRGCGRGRVAEPARRMGARARCAGRARREGEGGGRAAGRRDAPRLRGRRVRARRPLDRFGAPAARGGRGGPRGAGRPRRRAPGAGASTARGRSAPDAARARRGRTRREPHGRGPRRGAEGVPGALRPLVPAAAGGAGGRPRQRAGPDRRPTRPGDDPRARGPRSRLHRAQALVRRAGPRRREGDRDRGGRVRRPLGGGAALRGAAPQADREAGATPPRDDRSVVPGGGGPRRLIVAEGPRDGGRRARGREAEALAAAFLEERGYRILARNHALRRGEVDLVCETGGLLCFVEVRSRTGDAHGGPEETVDRRKARRVVLAATDWAERNGGSGRNIRFDVVAVTFGESAPRVVHFPA
->SRR3984957_4909703
-TNAAIRRRRVKPRFLKVGNAVFAWGLDRRRMGRLINSYFRAAGQLDGCFDSPSFLLRRRTLYAFSLQRFYERGQVVAHEVEVRSRQLVSAVKLTSLAVGRVDRGLGRWQRKEQPTSAGVDSAKIENITKESTVGLRVVAVEEDVSASDSGNHDDSENTILKTPRIVRPGRRRAFEEFPSGGRLSNAGVFVIRRSVLELLPFTSIYRFRGIDRLIVDLFIDDFSGFVDQESCTPRRFHRNSLNVELLGQSITACYWAPPVPENRGGHSILLGKCEVREGAVHAHTQHLGVGAFQLGQILLESLHFAGSTTGESKDKKCQGDIFLSPIVLQX
->SRR5579862_538352
-XMVVSYPKLTPKARNAGDLGVPYARVKGLSRQARAGIAGPVLARWRAPPWPLRLRFRLRSVVYRIWYTRWVTRMAMNAKKNRGRVDHGGSSFDSFLEQEGIREEVEVEAVAVKRVLARQLQRAMQKQQKTKQAMAKQLRTSRSQLDRLLDPGNASVTLDTIARAARALGKRLIIRVADAKAEKRAX
->SRR5262249_1788368
-ALGQWPGETAQHQALTLAQLRRRRAPPPPWRRFERGDPLFQDAGIRAAVDDRPRLGDGCGGPITIAQRLQHLGLLEQAERANRRLAESAERLETAVDVVSSRGHVPAHQLGDRSGKMDLAVDALDTALASELHRLLREQGLVLPPPLLAGDE
->SRR5438270_12444290
-RNEGLSPHDSQLLCTRKLRTQPLSILFFRFISRVIIAEFAFDPYICLCYKYRSATREYSRSRTLLSSSMAEHSAVNRRVVGSSPTSGAKFINDFQHLPPITSPNCLQILRFRREPPDIAPLQTQPLNHRSPAIEYRVGVRVDRAHDARLDHLHVDIACRRDAGVAX
->SRR6476620_8373323
-GPLPVSSSVAADSTLPTTRFTRWWLSSSIGPFGGTPTCQNPTRPGASWTVVNGPAVSTSKADVSGEPSSTGGTGRRRPGSGATSVIGSGHLGRVVAEDDHAHRRRIEAVARVVDLRAVRDEDDHVALGPDVEVQAGRRDAVDDAERAIGADG
->G7IQB2_MEDTR
-MEGEEGGGVRLSKRFNDDKGGGEVDYKTKSGTAWSHNFLNQKPWHPLSYPNQRRKWIAEQTHAQRERRTEEVAREYAQEQEFYRTTSLISKKDKEKVELMQAVSFMYVRPPGYNPESAKAAELNDEKKKEDTVNNEPTQTNPDGPSSLPPHGEKKKPRPKDVFGRALPTEEEFEVLKNAPRHETGVAARAKPFGVEIRNVKCLRCGNYGHQSGDRECPLKDAIMPNEENRLKRDDPLNAILAHTDLTEPLKWELKQKPGISPPRGGFKPDDPNQQIVAEEEDIFDEYGGFLNMGDIPDLLTNLSKKPKKSKNKKHKKQKLLHSEREASLDDGESRSKKKRVKESKKKRDYKESSSSGSFASEKVHGKSRNKHSDDFDSDRNDPSRKTKPERSLSLKDYDHPRHGRSKHGKRRHSFSSEESGPDCYNGNYKNRDRRSYSSEDPDSDRDDRGRKNIQKHKRKHGRKRHYNSDEKDSGPADYHLKQKGRDEHSYKSDDCNHQRQPEDKISSHKYSSIIHCDSQRHHVSFSHDRYRGSQKSRSEHSCSSNDSDVEKNDQSRRIKEERGSQKRREEHLYSSDDSDVVKNDRSRRICSSNDSDVEKNDQSRRIKEERGSQKRRAEHLYSSDDVVKNNRSRRIKEKHGNQKRRTEHSYSSDDSDEKNDRSRRIKEKYGSVKRRAEHSYSSDDSDVEKDNRSRRIKEKDGSVKRRAEHSYSSDDSDVEKDCRSRRIKEKHRSQKSRAERSYSSVDSDVEKDGRSRRIKEKHCGTPDGSEHAEIDVRQQNREKPSYHRSEKSYIHREKHKLRKRSKNLPHHESVVYLLYDSSAFSQAQSLQSVLEKVDVKATIFNQQDSGCRDLHGSRLALDCQDRFCLRHRPWQSGHFLLAYIRGLLEVGMLTNLPIADLHVGGLAWSVKWIE
->SRR2546423_6060734
-SPVWATSCPMAACAGDPLTATDVAARAEMSMVLRRRGFISISLLAARGRAKAICPCARGAQRPGERNTSGARRLRAPVRTLLAVPSVRKPVMVRTFGELVRRWALGGAVVGAAALLGGPAAPAPAAVDRSLAR
->SRR6187399_628079
-TYSVLQHQFADTLRAQKLAALTAEQPDVIATANVGCQLHLRDGAAVPVRHWLELLGYRAPQRSASMQDFPHHYRVGTRLTAAEDGVVLAADGLPDLDTAPPMEFGGKGDRWSPETLLVAAVCDCFVLGFKAIAAASRLTWTDLDVRVDGTLDRIDRKMRFTHFVVSARLTVPAGQETRAPRILEKAEEACLITNSLSAEVQLSSEVIVGX
->ERR1719375_252775
-ALSMGLLGTGLRVGEDRRLRGRPSWDPENRGASAAGSTPGRPACTRRPWRGQRPRRRVRGPEPRRRPCPWTSSEASPAFALDRKRLASRASRASQASLATAAAVAPRGLLGAYQAPCPTWPLEYTGPGRPVQRPASHQFMPHPSAAAALSNYELAQRTPRGWMSTRQAAPSAPKLPGLNNGALGAACRVDIHPR
->SRR5579859_4059679
-AIRTATATLLPLGQTGTIINRIHHSCPDSPWVARGTDLAHCCFDGNRISGRRMTDVITLIRVKRDNKRPLTDQEITWLFAAYAGGEVADEQMAALLMAIYLNGLDAAELRAWTGAMIDSGERLKLGGDTRAGGRPTVDKHSTGGVGDKVSLVLAPLVASCGAI
->SRR2546428_4694028
-GTLGFIYGMSEPMPDLLAEHSRWAATRAQELGAQSLNATNFGETFSAGAFRDPVTGRVYNAVGSRLPGGGLQGGATARPGEFVIRGYFGHAEYQLLQWAAEKGLVPVSIGASRPHCWVCADLTLHMGGTNASPLKGVS
->ERR1719343_138255
-PGGAFIFGTFCASSVRDRFSSGPKLLLYRSEGAVLSRGVFLLLGAAPRPHAASTRGVVRPRMPREFRTYSIMAMVRMPHQRGVSSGRECQGNSGHIRSWPWSACRINEGCRQAENAKGIQDIFDHGHGPHAASTRGVVRPRMPREFRTYSIMA
->ERR1039458_2685568
-FFLMIRRPPRSTLFPYTTLFQSISDTNILPAVSISLFLLTACRSDIALVLRKNGAPMTYKYLFASACEELKLSVWAKGESALGYNPIFYRRDIFGAWMQYNAHGDTLTHFGWEIGYITPVEQGGTNELSNLQPVQWRNNRNRTAPQPX
->SRR5712672_4201355
-HSEKSGAGGRRLFSPDARGTVRQASGRGRRRPRQGSRGLSQIARSDAADAEQPKLSRRRRAELCRLHRVRRVSVGARRQPVQAARRRRSGLCGARALARCVRGHGAKVAELSRVRISAALNLTAAVSTARFWTSRPPSFANNPDTGSRRRPTASAGGTIHRNTSTAPTGCRRTPRHNRSRRAAARVGFLTDLSSKGPLFRPAFNSGFIRDGVMIRRKSYLDDGPREARWPAIRKPPWSRSIDSDLVHAAGPRAISSTRRPIRAVLSRPS
->SRR4051812_7757704
-TRPRTSPRTATRCGSACGWPIPAGCARSCWAPPDRSRSCRRTGSPRASATKLCGRLRPTPRSRVPDVTWVPIAAWGAAAFIALAVLGFCAYEIMWKARRLERDLGRLQTMTGELADLQSRLALAQQRVVAARQRX
->ERR1711998_154733
-GELSIIIAISGARPRMDMSLTNCEPWLTQESRNRRELTYPFGSSVSRTGSAYFARDAVNTTTSNISATFSRKTSTPGRFATKTSWWIPSISTLIWKSKNAVGWKEECTNVSSRSSTRHFLFLNFGSGGGRRGCLLEVLX
->ERR1719424_536034
-RSHHTASLHESMNGMHGPMVQTEEDEALPPIISLDDLVAQQELKEEPPSTVQYIHCGSTPEERRTCIRLMQRCLQCPVLPAPRPTLSARRALLQLVCDESGQPAADDPATLRLPEPKAAAAAALADLTAQLEQCHGDDLEDQSDRDAARRAEAVRSSSSAMATTWRIR
->SRR5947207_3404454
-IPPTFKDFVGRIEGAFLHPGSRIGGIVADLSDLTTFLPLDAQYDQITVGSWVVVENLDSTGTAIRTFHQVTDVKTITLTPLDFLSRGVFVGIEGIELQQISAILTIATTITLLTLDPAWLPRERGKDRNDLFTVLRTTTIYAQSECLPLAEVPSSESTDNQSASGEPTSQSASSGATSQCIIENDTIELDRLYPDLKSGQRLIISGERADVPGVRVSELVMLAGVKQDVGQVIVEVNGVKQSIPLSNDKLHTFLQLAVPLAFRYKCGTVTIYGNVVRATHGETRSETLGSGDGTK
->SRR4051812_28246904
-DYVRLHQWVARRFHVHRTVLVSVSMGAIAGLQLAAHHDVPRLAGWVGVSPVLDLTSAAASGPLSDDIHLSAAQVHGLDPTRLAPGRLRGLPMAVAISREDRVVSVPAAESFARRTGARLIACAGGHATGDCYRPGVVEKMLRX
->SRR2546428_178850
-PRDSRAGPRAVRSGHRRRAREACARRIRARLLRPAARSRGLAPTPRRGAPSPARPCSPQHLWAPSMRLWAFSAGLLSLGSPPNFAQSGQFFVYYGTATGTPPDPWHSVIAGYRVSARDPNRADPSSGRILLQVKRQKGPQHFGGGFCFGSDGMLYIGNGDSA
->SRR5215472_1953996
-RLCSPACRPINASFIKGPSLLVLFGIESGRGGIRTHEGLAPLAVFKTAALNHSATLPRSQRQLLTHWPSQTKVDIAAESRRRPPFAGPLFGPDLSQTSRVHHGESGRRSGVDRLSGAGPALALPDQIEARRTRPQKRKPRGSAGLVPGSAYVRTARGLGESER
->A0A2H1WYH1_SPOFR
-MKLTKHLFATIINKNLQLLPRITMGCGFALIKTSIIFGAGLYTGVYVAQNYKIDKVEDPKVLFERAQTFVKDKLAEVGDKKDK
->SRR5580765_5835986
-LGRGPVPHLAPAALGRGQAGLDQRLQVLDDGLAGDGEVHRQVAGRLRPVVDEPLQETPPGRVGQRVEEGVDGVDQTLASAQTESQSDSTRKSHDVAAAMAVSTEAAAVSVMTRRLPRSAGSMANTTVEAACSSSSGHQRKLTYSPSTTPS
->SRR3990170_974992
-GGRHARAGPRAGASGGCAGIGDGQPDLGREFDRAGRYRSRLELVFLHGCRQREIPLVQALDFLFEMFAIAIVVDHVIRLLQTLRATHLGGHDFTDLRFGQSAARGRALNLRAFRGVHHQNTIHEIDEPGLDQQRHHEDAVGRVKYIQFFADYFADARMQDRLKPLTFAGILEYAFAQSVPVNPAMGVENILPEGADDFVEYRLPGFGQAMRDFVGIDDRYATRGKERRHRGFSAANATGKANPQHGAGAQTAIRANCRX
->SRR4030095_11228013
-GTRDQRGTRQGACPSDRRLSRLPGGGVPGGRNRPQPWQVQTGRGFPPAQEGGQSRRAKLQAQSAIGSEARRRFIVPGEGIVRAAAILISVGALELTGCATARMHTEADLNSAATAFGLALGQLAQDDEEKRLLFVMEANPSAPKQVCVKNWARRNHLKAVFIDALDWVGPWGGGFAALLPLPRG
->SRR6266567_941993
-ISAASGIIVRPAAAASRTADAVRSASRPAMATAAPAWASAVANAFPSPRFPPVTSAFRPCSANWSRTFMNRSLRPRTSRCASMVRMTETDLGALYGMVRVRLSGLAAEVSEPAGVPVPACPAWSVHDVVAHVVAVAEDVLSGRLTSPPTDDWTAAQVTARKDRSVADLVAEWGELAPRIEALISKGGMWAGFLDVLSHEHDIRGAIAAPAGRDAPELLLAAEFLVSRWRPDVAVTVRMGEREFSVGPADESAIGLVTSPF
->ERR1712020_113728
-EPVGAGVHGSQWWKVKLGAVSSHELGSCPGSLSLLATLATILATTLIITASLKIAMNGLKEEGWPTPGAATRPTADGSGGRTLQYLSGGQADGQDLALPVSDGRGLGRGLRARHRVDDLLERNEWTRVWSSPEPQRISFFVPSPHTTLLHYCVSMFVVCYRVVVFVKTFVICVX
->SRR5262245_7284194
-ESGLSLLLDVLDGARQRGISGDGFCCSRRSSTEPAVVAIPPSQAKFEIEAVAQFEMRVQALLEDDPVLGMHQFEENIAPRREAAAVVSQQLAKARREPGVSRRDVEFPDSVLCAADRTIEPQPCFVLLGDIL
->SRR5216683_8145363
-REEPRLLRALVAVDVKRKVQAGPDHATSTQLTRHDHAVRSRSQHRLGPAPHPRRGRHLPRAATVPSWSEAREVAAVCDRRALRAESPVAIHPEAGRSRDWKRLACTGAAGQGRSARLEDHAPARLDVTVQQFERPGIVVRAAAIDHHLVELSQVLGSVVVNVPTSLDRYGSGSVEVAERKVAKDQLVVLGPAN
->ERR1719282_30391
-KMHLGTAVEDVRCDVVRWRSVRQHHVYRCRCCPKSQEGCQAQGPSCPSSIRCHDQGCCQGSCLCCCRWKEGSRILQACCQGTQGKEACCQETKGQEASCQETKEGCQEASSX
->SRR3984957_655891
-KPPARSAAHFDRAAVTLINQAIRDSDVFRLAAAEAEDRPSRAERAVSHGRKLTASEERAGVVLRHDVAVRHIHVNATDEMKPVVVVIDAVVNVDAVEMDVPALDGPDAVIGAGVEKNIPDDQILATIKQQQMRPMIAADSRRRRDAASRAAKRVALAVDGARPFDADIPGKDGVDQPNISVAERGIPAQWDGVSRPILLSVRAPQEFSAGGDVEGDIALEFDCSDDKTAGRHHDGSALIGSAGIDSSLNGRRIECLSIARGAKIADVVDARP
->SRR4029077_904125
-KAARQGRRQRLRHNKMHSEAQQLYEHTVWNEEFGGNLIARFARKIPAAFRSTAIPDYQMIASALAMGDLETKGGAHNWPQRRVWERFAHHFQNSKKRPDVFAAIDAHTKRFQQDMVFCQAHAALHCRKADPPDLLWDDKLLPREIAPHL
->SRR2546429_6251402
-GCGAARWRGVLAECVWRMRNSGSRSTSYCFFFFLMIRRPPRSTLFPYTTLFRSSAHRRKHEPGRNVGRHVLHAVHRKIDGRADRSEEHTSELQSRLHLVCRLLLEKKNELRLTRSCHRGTDHPHADALRPLPPRHS
->SRR5438046_2863571
-STFLTSFLAQQESPAALAFSAQQADFALSQVLASPACKAGMKAKAASVKQTTSFFIMVLFRTAVNIVNTPFIPNQTVLSMDHSKRIPAVLDFVGLPRGGMLSIFVCLQQRSRFTIDIAPLRGWGAAVSLPLFRARVAAGHTDADPSDGSVKA
->ERR1719491_2917382
-KWLLVTWHLLLSISISWWHLTRRHLTWRHLTWRVHAWLHLHLRILTRWELAWRSVLAWWELAWWELAWWILWICSSIMMHGFLLVVYLDDLVNATRGVTARIMRTNVLAMTRANQNANNDANTAEKDADADEAAAMTATTEVTAVS
->ERR1700736_6027844
-ITESGREGRIDPVKKLLLLPVVLTTLLLAFAFIMPATAANVLRSLAPATHLNLPSVISAGSGNEVAARPAASAANPGSAAFPGGSSAPGGSSPTHQDSTSRPLITVQDRGHAVTTSGGVISGCFGVGCYGVKHHELCPNWLYPLPAVHYAPPALLAGNDAAA
->SRR6476661_8427451
-EAPNGTFVSLGSNAHGPWGPLVGSQVGCHRIRSETGQTRRETGTQSQGSSRRQSTRPPGYQAPHRQALLKGTSMVQPERTALDEPRQERQVRQAGPMAPTRGWSLDFTGSRRASVVLSLVLLLTALGTSGASAAGYDPA
->SRR6266540_5744156
-XMSAEPLAKAELPYTLTRGGHKPRSVRVPRSRCSLSSEGLCPSARLHNATAMSAEPLAKAELPYTLSRGPQAPLRSRASLAVLAIIRGALPLGTPPQCYGDVRRTLGEGGTPLHAHSRAPSTAPFACLARGARYHPRGFAPRHACTMLRRCRPKPWRRRNSPTRSLAGPKHRSVRVPRSRCSLSSEGLRPTARLHNATAMSAEALAKTELPCTLTRGGP
->ERR1719259_1225225
-GFHLIRIDARWFKTAKNWDVNTRLLANLFACLLTQLAHLLALHCLLHLRATLRSFIRSPTNFTHSQACENVGILMSHNQAVLNHGAATLNSVHADIPSSERVHNCVTDAVGVVLVAFALSVILPRKCETRRQHEQFLX
->SRR5579871_1117583
-XMPGITTLRQPARKGKSQPAKKSSSGKNTRRSPASNVRKKIKHAGQSRQPATLKQTDQPSTGGVSMKFRLNDNNPKEKAIIDALAACGEREMSRFIKRAAYQLATGRDYDTGLPLYATIPSAHERNESEIPVSSGGDIQRRMSILADLDSGLDDWDSLSAX
->JI8StandDraft_2_1071088.scaffolds.fasta_scaffold684990_1
-MALTLRLVKGTELTFDELDENFTYLNANKYEANDDAQFGTLTFGTLTDGVLDVIAFTNDVTLSSQTPEQVVPTEFAITSYIAAYHAANPYSTSDLTDVSASGTYTGVLVYDGLGEYIPTVPTMSFLQDVDVSSVSDGQILAYDADSEMWTTVTTGALSNIYLAGLTDVDLTTTPPITNDLLSFNGSEWVPATPILNLDGLQDVDLTTNPPVDGESLIYDAGTWVAGTPSTVGKMEVYAAAGETISAGRAVTIGLQDTSKTVAFPIQYADPEFGQSISLGAAVGSQSHSIWCTAQEKYIIAYINDTTGDGEFRVGELDDQGIEITLDPTIHYFGENIGGEFSVSYDIATTRTVFAWRDSITNIGYARVITLAGFSVTMSEFPIDFSLSSPIGTHSVSCDTASGNVVFHYADQESLGTGVGRLAELDGLDLLFQPPIPFTTKEVYQIHTVYNSIGNRHVSVFIDELGTGWSFVTIVSGLFLTFRTPRGIWDNMTTPFVTLMKGGSECWVAYRRTNTVPAQGWITRFTNSNNGTTNTNYTGAQYTHYPFENGQDSVETPYKMSNIDPAIIGSQDTRGATIVWGREDQLGNVSLHSTLLTFSEFGGYPIVDTDDAIKASDDSNVEFLITDQLWPVLLTNKEESRMLIPLTQPGGIKAITFGTNPITNIRDWFGIADESFSSPINPQSGFPEWNTGQITILGGTSEATSFAGGIGGVLVPGTKIYIDNSRIYRGALRTSDVGSGAIGIAVAGNKVLVTGDIEPNPDVSGVPKSLNELEDVDTKSVAPQSQQFLQWNTNKQNWVPAYAEVQGEINNLSDVDTFTNYNTGIPNSHLFAWDDFNTEWVPKLINDIIAEIGVSINELNDVNILIPQDRHVLTYSSEAGQWLSQSLELTSKLEDLLDVDMDDQSYPRSTGHFLQWQGQKWVPNAPSIPPISALPDTVIGASPITGQALVWNGTTQKWVNSFISIAGNLNSLSDVDTTATAPINGQALVWNSEAAKWVPGTVSGGGSGGGNNEGSPVGPLPGGGSSEGTVETEDGDTIVIPPLEEGDSIDDAILTGQGIVDQTYSNSTIIGFTDVISGNVHPGDIVDNVALLPKPFPIILSIAEDRLSVTVSRSVSIPQGAVCAFGTPPVIQNVAGTEGIVVSPTMSPGEYDTILTQPALPEGVVPGVAVYVSSITEYPVITGISADRLSLTVSYPIQVIPGEVITFNIVIPVKTTGGEGTLVLDDQDAGPIGPMTIASFSAGGVTINFTEDRLPLVDSGMNIIAYDELGEVEYVYIYGVDGGSTDSVNITNPTRAAELLSVGQEVYFENQASKGQTNGTLIRVQSEIDDEVKIGDYVISPRLIDAPKVTSIDINLLYVTVNKNIDVLEHGDFVTFGESVDKAIEVNIRLDELKDTAIEPGLLRDGELLVWDAELEKWTTKDLQLATSLDSLTDVRIDNRDTGQILRYVDNVEFGIRMENITPSWTADDLQDFDYSTVAENSVLAGNNGQWIQKDIVETIKSVNTLELTDLSNVSVLSATSGQGLVYNGSAWTAQNFPDEIGDLLNVNAASPSTLDALIWSGSSWNSAEIPRALEDLNALNVFELDQFPVGGFTDVPIGTANTSRFVKWTGSGFITTRFNNDDGYGIGLKLENLDDVNLENPYTADFISWDPETQMWITRSVEGAVIDIGLTVLSDVDLQTVLPQSRNTLEYDEPTGQWRPTERQGLAHYVPHEDLVLGDLVALRSDGKVEKVGEVSSSESVLFTTTATPSSASDYYGKSVYVSDNYYIVGAPGFENSTTGGKIEIYDTSTNSLLQVITNPTPGLATKFGESVSISDNFFVVGAPGYNSNAGRIYIYDLPGFTLSETIENPNLSTSTLDDQFGNRVQITNDYIVVSAITEEPINLSDNNTGVVYIFNPATGNLLHSIQSPTPSITGWGQSVAVGASGYIAIGHPLNNEVRVYQAATAGLLYTLTSPNNFEGNFGNSMGISTSGRLVVGAPNSEGGKIFVYNLVTGDFNYTITNPDRNISGGADKFGNTVAISNDYIIASATDERTIGTSWGTVYIFDVNTGRFLNEFKNPTDTNINWGYSLAVTNDYTIIGAPRLTIAGVGEIHTFSSSSFLTSNADNWVGIVEEDRLVADNKDVLVTTVGSVNKFVSGLETNKNYYLDGRGFLTLTETDYGVLGKATAETELLITGNVVSAETGVSYLNDIRDVDTVSKPPANNQGLVWDSANNRWSPKTIGYSNITTFGGLSDTSVASPTPGQSIQWTGTHWALANYIPQGSFVLNELSDVNTAGLEHGDSLVYSFILDKWIPQQTGTSNVFILDDLTDVDLQEITPVSNDVLVYNLEEDKWIPGAVSRVASLDDLTDVDLQTQAPTEADVIAYNSITSKWEPQLIANITVTSLSGLDEVDITSLGNNPLEGETLVWNAIDSVFRPGSPSLDTISLGSLGDVDTTTGGNVPEAGESLFWDGSNWVPGPTGDAVAAFIGDLVDVNVISYPPKELQVLTWDSSINRWYPRNGHSGGIEDFIAEGDILQGEVVSINLNGSVSRTGQSPFQPAWYKENPTPFGTASNDFFAYSLAASTDKLLVSADREDETGEIDSGKVYVYDALGFLEATINNNNINASPANDRFGFSLAIHGNLFAISAPFEDSGLNYQTGAVYLYNRTTNAITSQIVHPGLATFGSVQSYSPNNSQFGHSISLGGERLAVGAPFDSGNIAINSGVVYIVNPSPAVGEAQFPHIITNPNETGGSYNDQFGTKVALNSTGQYLAVASKNEGPSSTKGGVYIFDISNEEIDPVQVAYIANPGLGGGFSYNFASALKWDQVYPNLLAIGSYDSDTDYPEGYDQGRVFIWDLNTLDFRTVITNPNSYNNPTTGDRFGWSVDMKEGKLLAGATYEEQGYVGGKYTNAGKAYLLDATSGQLEAIFSNPNIYGDSTNEQFGYSVAIGGQGFNDLYHVGTPYVRNTISSDFNSGAVVTFDSQITTNADAWIGIAFEDIADGEVGNVTLFGGVAKNLFGLEAGSNYYLQVDGGYTLTLSPYGIIGKALSPNTLLITGDVESNTADQVNVLNDLNDVTSVTPQVGDGLVWNGSGWVTGAVSGGVSNIGELDDVFLPVPNLLQSGQVLTWNGVAQSWVNAATGSSNVAIINDLTDVDLDTIPPLEDQVLQFDGATWRPTDLPEGQRITGVASENITEGSIVLYGNTGQFKNVEISIGAFLASIPASVPSNYALFGSVITHQGDYYAVSAPGASAQGVGSYFGVVTVYDAVTDAPVRTFYPPREGYQVIANVSNQYFGESISIYGDYLAVGAPKGTINGAVQTGIVYVFRISTGSLVYIIPCPFNQNANDNFGASVSIDDTAILIGSPGYDSPTSFNTGRAYLYDFNDLDGYSYDVEEEEWPIIPPSKIFENSNDEGTPAGDAFGSVVSITPSSVIISAPSEDTGGTLSTGRIYIRNRVTTASIATLVNPNIDSEGFGTVLAYWPEKIIVGAPGYNANQGIVYIFSATTGALLHTIQSPEAIGDRFGVSVAIGEYQIVIGSETGKEGYPDSGKIHVYSNAAPPVYYGGFDNPGYNVSPSGERMGTAVAITPAGKAIAGAPYSDLSAGSQQNPAIDRGAVHLFDVSESAISSDAGEWIGIAAGTMTQGETGEVVILGGLTPFVYSGLVPATYYYANFDGTLTTNTTDYGLVGIATNSQQLLILGSISGVATMPDLSDVDFSSGLTPSHALTWNGQFWEGKFVSTITSITELDDVSLIDTPPEDTQALVFESLSGKWKATDIGYSNVFAFNDLNDVSISNVAVGQSLSWNGSQWVPETFSQVSTLDELTDVNTNVFKTDRDILEWDGEALEWTVARNVFGNFINIEAEGSIAAGEPVYITNNSKVAQIRGTEEITGTAVFENDFFQDISLSGYGRSIDIYEDLIVAGNPEFDLPGITNTGKAFVYSASSGELLQVLYPPTSYTYQQFGNTVATNGDLVAIIAAENPYANGKGKVHIYKGTTGEYLRSIEHPDPSRTTSNGFGYHQKSIDFQGNFLLVGDKNYRDPISNASLGRAFLFNAYTGNLVHTFEHPNSSAVNSRSFGTQVAMLDDGSKILIYDVLQDGLNSATAYIYDYAYDLVSTIEVPHYNADTIAINSNYLIVASTYSGYLYIHSLLDGTLLYTSGSAYLDYGQKSLSANEKTLVVTYGSNKGFRVFDIASRILLASETTSSVGSCASLFKTRLVYSTGYQAITYNLNDISISSKAADWVGISEGAYLAGDTTTIITGSGFVSALSGLIPGANYYVAVDGTLFPGATGFGKIGRAVSETELLVSSNTSNIDLDSDSTASLIAGIGDLTDVDTFTLFPTDGQYLQYNSVTSTWSPGDVSLPSLTDISLADIENNDLLLYSEGIWSNGTLATTNLSDIDTTVAPTASQTLIWNENTSKWEAGIPERALDSLSNMGSSVSTPTTGQILVYNTIGDQWSAVDNEFSLDGLTDVNLEGVTDNQFLQYNSTSSEWEPGTVATAVSELTDVDLTGVTEGQYLVYNDQDKWVPTTIEFAAALTDLTDVNAVGATQGQGLIYDTGTNKFELAIVGTSNVDTLEDLSNVSIPTTPNNGDVLKYNGNTDTWEATPTPSPAVVYATRNSFPAIGNLGDLSFAQDTGVLYVWEGTIWYNLKRTNAFYLVRAGQFTGPLTGTQLFQPQQTITLHEIRAQVDQPSGASLIFSVMRSGAEVQQFVIPPAAPFIEAAFTAGVVVGPADEITVDIISGPGTNLSIKFIYSX
->EndMetStandDraft_2_1072991.scaffolds.fasta_scaffold3645261_1
-TIQMSVTFNQPVRIYKYNNSSNNGVIAPDNTGVASATQQSYILNPISAANSGTVTFQTADVGQTTATPFVLPAGAQISNIRLYQTTAAANLAGGVITVSIIQTNPTTSANTTTAIGTITPTAAGGVITWVPTATAATATILNNIGTLDATLTFAAAXVTALTXGSLXGTFDVSYTPRNYDGSIINVGQGYTNSX
->ERR1712185_45118
-LGKGCCRAGGSVLLRDCTLEGRAVAKIRLTVVEGLNQRVVLGMDVLGREGIVLDCERGAVAFRPDVSGPGLIDSPNGLTVLDDDEDAAEYEFFYVTAKDILQAGGLDDNEEDLPNQQAVSAGDSATGQPVITDARMQQIIDDHSRVFQKRESLPGRRGLYDFAIDLYDDARPERRTLYRLSTAETKALRAEVMGLLDRGWIARSHSAWSSPVLFAKNQKKDGSLRPVYDYRSINSRTVPFNGPLPRWTEILPKLRGAAVFSVFDLAKGFQQIRVRAGDEPKTAFATPWGLYHHLVMTMGSANAAAHMQSVGNAMIEGDAEALPEFPVGHPLHDLAEENLARYSLERGAARRQQRRRDGRDEIARIALDSLGSFIILYVDDIIVYSADREAHYGHVEALLERLELFDLRLNEFSRFGESSGEFLGFTISRNEVRVKESRVQSILDWPVPTSAAAVRTFLGLVNFYRDHHLSYATWAAQITPLTGKGVPWRWTAQHDRAFAQIKEGIAARIALRLPDPDRPFVLATDASLHAVGGVLLQADPDAAIPDRLEIVACFSKQCSPAEGRYSQHSLEMLALVRCITHWRWLLDGATDLVIYTDSQALVTGKLFSESQPSWASHRMARWIARIASTRADLRHHPASARLAVAVDALTRRPDYVNGTAKDMDGWIRELSELHAARKQRAQQTQSMQVMSGIAATPQGAKCMYTLVVAESPLARIKAGTLGSDDRRMQRLGCEWRDGIWTRFGRIVVPLDAALRADLIREVHDVGHPGRLATCQVLRRRYWWPRMIDDVAEFIKQCATCSHVKSGRRHGRGSHPLPLATEVWSEVQLDFIVSLPPSGPRGFTRICTVSCRRSKEVILIPCWDAMTAADFADLFLDYVWKTKGMPRVVRTDHDPLFISQLWRRFAARLGFAATQSAPYRHQQMGGVERVNQHVEQLLRTWVASQEARWSEYLPMVQFALNYTPASTLGISPFEVVQGWLPRRGFDASDDVPLATTSLDPGQRAAEVIQWVNERLMDSEIHNTRSGSTWRPGVGDRVYLSSEHLSAKTVGVASDSRLRDRWVGPYVVVGLDDNTEAVHVELPLRWQVQQPISLDRLKPCFLAGLPPVQVEVDPDTGTKYVVAEVERIVGHTCSGRGRNRVVATLTVRFAGYEADFDRVYSIDGDDAIAGLLDTSAGVVQDYLEQHGLRLPPDLQKCLTAECAFLELDPMDVPWMFSVEAV
->SRR3954468_8813130
-LSQGGSGPAYGDFPPGRPLTGSVTTRAGRRLAGRLVYDLDESETTETLDAPSQGVDYTIPFGLIASIVPPGRGARRARVTLHNGEELQLERIGDLGEGNAGMLIVVDGRQRAEYVPWTDVEQVDFDRPPAMSPPAVGGVYPATGAASTLCSTASSSWRLTGLVRWARKPASRLCRMSSSMPKPVRQMPLTSSPQRARIWRMRSSPLPSGRPRSLMIRSKQGSKGGVSRWARAAATEAAVSTEXX
->A0A1Q6RLF7_9FIRM
-MEGLEKAIEQIKENIPKLDLRENEPMRNHCSFKVGGAVRAFAVPGDLFEMSKVMFYLHMNGVSPLTLGKCTNVIFPEEGLDIMVISTENLRKLRLGETENTIYAEAGVSLAKLAQFARDNGLSGLEFASGIPGSVGGGVLMNAGAYGGEMKDVIESVVVYYVPTQALTEVRGSDCGFEYRRSGFEKINCAIMGAVFKLTPDDPEAIGARMKEMNEKRTASQPLDMPSAGSAFKRPVGGYAVALIDQCGLKGYTVGGAQISRKHAGFAVNTGSATYDDVVELLDHVRREVYAQTQVTLEPEIRIYPKGMLLVDDWRERKQTIIDGMLEQAKQNAADSAAESSDVRPS
->SRR5689334_5448804
-SGTSAALSGTRRTIFVVDRTGNARARAALEAFKDRWNSESFGRTSLPLVGIVAGRPADGCALPAAGSETDTGDVILCLDDTLTSAGVGGPLRVDAHKHTELALVKLKSATLRWTECSLRTAVAHEMGHVMGLAHNDKGGALQPSIMMSAAGPYKYGCAVWFNA
->U2SVQ8_9FUSO
-MVVISGIIEFRNVSYSKNNNMILENISFSLKKNKYNVIIGKNGSGKSTILKLIVGLEKISGGQIFIDNEELVYKRDELYKIRKKTGIVFQESNEHIIGETVAESLIFGMENNRIPLEKMKENMTKYVKLFQLENIIDKKTVNLSGGEKQKVALAGAVITEPEIILLDEVTEMWDKVTKDKMNGIIEEFLKDGKTVVSVTHNLEEIKRSDNIVFITEEGKIVTGKSEEVNKIIEKKENTEINHEVISEYSADLTKMSLKEEEIKVKIKDISYYYEKERKIIDSFSVNIPKDSITAITGKSGTGKTTLIEIISGLAFLGENFSGEIGYNFRNENKEKEDEKLLLYKNISERELYEIRKRMGIVFQNTGEQFFSGTVLEELEYNITKKYKIKNRKSKELNDKIKEIAELFGYDEKFLMKSPFVLSGGEKKMLGLALAVCLEPEILILDEPTGALDYNMTIKFMQIVEKTKKNGTTVILVTHDENIVKQYSDYILKM
->SRR5439155_21550961
-GVPGTQASRLHTLHNALEDECFSAGFPREARPFHPHLTSARLRSAKGSRGLAQRHKELSFEPERFNVSEVGVFRSDLLSEGPKHTAISRHNVRRANRKSQVDAYXX
->SRR4051794_8769673
-CDGARRRRLRAGRRHGRTRHGGARARGGRRAARRAARRRRRELGRPAVGQRAQPLRRRLALLVRASDRRAAATAARARAGDGGGRRGSVRDLVVGPAADRRARHLERPATGRERADEGALARARPPRHPRERGGAGPDRHRSRAVQRRRPRRAHRPPGRGREGRVGARGAARSLRGARGDGPRGRVPALRRRVVRERRGRTGGRRAGDRAAMSDFLRVAAAQLENVVGDLDGNADRILDAMRWAEEQDADVIVFPELALTGYPLADLVLRDEFVDASLDCLRRIAARSGRTAAVIGTVDRVPPRRAWDTRPRDVAISAALACDGELRGSYHKTLLPNYEVFNEARNFAPGNDPAVLWRIGTAIAGVAICEDSWSGDGPPEDQAAAGARILLIPNASPFNLEKPAGRLELVSSVARRNAAPVVYVNFVGGQDELVFDGGSLVVDADGELLYRARQFEPERFCLDVPLGRDRPLARDPRTVHARPPAPRRRMPQPEPAVQLSDDEQVWRAIVLGTRDFV
->SRR6478735_3307528
-SSPVGRRSEGCVASATPNSGRYRKSGDCRTASITAARPDVKVSPLVTLFSSASSASASPAASGRRYALGTQLSTNVRAQLSWLVEVVALAAQGASLASGVACTARLAISPATSLYPETRSAETVCWAASLLKPFPSTSGGRLMAGEVVSPSNSATVLLNSLRVRRRIGAELGSNVWLVQAETCVSPALALAPPRPCVAPPFAPAKPELFGPAPEPFPAVDPRLGAPGASRFALQATPSNRHKRTVTSAGAPIAGGDLLVIGGX
->ERR1039458_4032371
-PPRSTLFPYTTALPIYALFVERCTGKIAAECANEPARPAKLFVITTEFYLRPHERSLSFDHFDGHAGQVIGQPVRPGKSKGSFADGFDQRFRLEIAIDPAARRQGVTTKRPACRIACFRDPIRVKDHNVSRLERQGYLVVDFSFTDSERQIISVYQVAQARLAVKVNYPRMQAINENEIALIQVQSDITESHETFEIDQMRRQFRMGQRDDLFRLRQLAMLGQEIGRAP
->SRR2546423_9850065
-IQHKRNCLIASEPRFPPCGIGNTTGKDPAIRNIAKSNPDRFRISATSVINSGECLFQRNTFAESRLAGQDEAFFGQELIKMFRYLMVSIPFTIWIVEKSIAMHAARDVRAKRDPESFPGNYHCLIX
->SRR6185437_1912756
-GDRAGARKRRRSLAAHRRKAGRNAAGSLGNAPFLEEDAVLKPASCQIPSAASLRGLGAFAPAPILEQTLAARGIARLERVRRGDPVGAEMAKALPQLTPGHDDALLVEKANPERPDGALGPCALRVVINEREFAFGADRGADLREVGRGRAFGFX
->SRR5678815_2292360
-STTTARVRAASSRPADVTVWTRAGASDFLPGRRRLNPSMPETIDLFVPLAELDEPLAPRVEQALGWRRGQVGELRVLRRSLDARKGRPLGQRLRVLVGREGEALGPAAARGSQRAGHDRRTGQARAAAPPRSRAADARRADAELELLFRRGRGR
->ERR550532_1119739
-AAGVASQVLGVRCNLAGHCNCLEGNLLSSFGAAVMDVEDVEEDNVPEVFVLLTQEVPYQLEVDPQEEEDLHPNFLHKALVAVGPDSRMECYSDARIHHNCCYLGVHSHQDHPFACRNAHLGAVVLLGDLHNKDVGLGQEDLEGHLYYYTSYVAGVPX
->SRR5690349_19480509
-KAPFPICSSSTAARASCTRRSPQRTTSACRRSRCRATRARRSSRWSASRRAASSTTGRRGWCRGGAPGALRSSPRPFAASEAESKGAALADAAEATSRGFVGELERTPERVFLPGRKDPVVLRQNSAELFLLTRLRDEAHRFAITFHRKLRRSRNFQSVLEEIPGIGAGRRKALLRTLGSLKRIKEARVEEIAAVEGFGPKAAQAVWDFFHGSAAAGDADAARAPGGLADQVDAGSGAGTGTAEALGDVTEADIDAALAEDDDAGDATAVRX
->ERR1740129_664351
-VLLSSFSFGAAGRMCLLKRLVFIWHYSTLIEGVFLRGGLVEDPRQTLVTTPIESYIVASRSFSEDYNAVVVDYYMKSFGIYSSLHPSVVLRRDKLGVESGGGTEVINFDKTYGFGTKITFESDHFGRPRLACVDGYLPCLARNCLRTRVVRVLSHLSTVLKTCCGNLTNGWTTPGMLTVPAAFMTLHAEAERVYNPWAFQGVTNCSEAIEALNMASHKFRRSSELAGAAVHAALLHYHSDAAGHTPGATAPIPRKVVFHRYIGSHRSTILLSLLEGMSKLMESPQESLNAVEIGVYTAYTSAFILENLWQLRVWSVDPYRVERPKNRGIGSWQNVYDVDIFGQVRQLLSRYGHRSTLWRLTSKEAAQRFNDTLDLVFIDGDHSYEAVREDINLWEPFVRLGGIVAGHDYHTDSVIQAVHGHLDGTNTVLHIAPDFMWWYIVGSSGSCEVGSERPARDHTQPLRFPSX
->SRR6202011_3201054
-XVRVVGGFGNDGCLLALAQYLDRELRPESCELRLDVADREALADAMSIITRCCASNYTAVSIEKRLVAERIGVRDAMYFERDEPVRHAGSQLLLELCLADEVALVHAHEAVETGLERRVVRRHVATPHX
->ERR1700756_1693894
-HQTSGPREFTRLIDRRYLVSECKHRKPLRLAVEKWIGAYDEDAGFQLGKTSERSLDLGFRTCPQNMKLKSARERRRLHIFHDDVGTGVGRVDKQRNEGCGRHHFMSQLQ
->SRR3712207_7425182
-LKERHTGGKEKREVTIVFFSSRRRHTRYWRDWSSDVCSSDLQELLGRGRLVGREAHARGELEVERRGHRDQDGAGAVGRLHLAGSEERRVGKEGRSRWSPYHLKKYIDTLAHAVTHSTISTTIS
->ERR1719174_1663456
-PDLLFRSAGRVSSVEPIDLAGNAAAVEAVARARSYRGELIVLAATASHWPYAINAVSELALLGMEHYVFIAPSRTDCDVLRARRPGLACVFSTLVSNTTMAQEKSFTVWTTRKRYVGRWAALGLGVLQADLDVIWYANPYPALKGALRNVSLVHLQEGKCNEGRANGGMLYAQSACDGSMAHWVLREVYERVRRNEDDPRILETHYPGLFSD
->SRR6185312_1149132
-XMNWNSPRADEVLAAAFGLKLDSIFAVASRYSKLAPVVDAACLIEPAILARTGSTPAAIVAFDVSTAMSLVPCPSRTSRGRSGAGNQRPYAAETAAIIVNDRLRAPPLRLGFVIAGDLVDLFRGHLAGDVAHLLADVVAAGAGRERLQLRLDVDSRLTAKPGTTGLVVDVAMAGAARCDVAHRRPRRDDRRCRHRRIELVRWHARQIG
->A0A1V9EVA1_9BACT
-MATIEFLDQLLSDNKAREAKKLALIMDPAKKPFHILSFIGINEVYFIYKAFVEGDFKAARQHLYNMGMTNAWYYEKINGEIFDVLATFTYPLLSDSSFLIERYLTYTRMDSPGSFAACFGKAIQNVLKNDIDGLSLNIEGLKKRSGQGWEKNYNGVIPVFEGFIDNDKAKIEEGLMSLLAKHNKQNQPPVLKDFMNLEATALAKLAWRKGISVDVKSHLIPIVLLPVQEPDQYSGYEFFNEVS
->SRR6478735_9024146
-TARPPRTCRRASGRRPAPARPTGRRASPRGSASSGAPPTRTRPPGPSRPGARSRRHGPSPPSPHGTRRVPRPRPVRCWACSPSSVGRGGALGVGDRGAAIGDRPLLPASGPPLGLEDAHVDLIPPSAVAPDRLPRAALVDEADPLVGPDGALVEGEHGQGDAMEAERAQGVVHHQRGRLAAVAPAPGVALADG
->ERR1017187_5434680
-XMLVFKTTSTANQPVGATSAYHILFRILIISGSRAKSQPFPVPNGSCSGQSRKWVQGRGLLRKKRFSRGLTHGLRSSYVRLLLSKFWPRCSFDDTPFQRKRSEVQERIDAREILFEGDRGCGRGIVLVAIGCAKLQPLRHEILGANPALPNIVYAAYSGVLIMLVGATSIDQELLPVNLLVDLKICAGRGDGGX
->SRR2546423_1398384
-DGITEVARRSLQCWLYRTIALERACPQFWNSVVSWFFSVTYNADRSITYTPGFLTALRQLLRQPRPEVVTASSLPNARLSDFAEVMSWLGTAFPFPAGAAAVAHAGFEDAGFEAALAMTRSALAGMRQAPYVPPTTYTAAPPPGATGTLLPPAPL
->SRR5699024_12166037
-SLLPSDTVTLYLHSFPTRRSSDLRIIKRHSTFHLLFQILPGIVLRLQLLPATAWFSCFLHFTHAAPAAVHPGRGRKSSSCRCNQDRKSTRLNSSHVSISYAVFCLKX
->SRR6266536_896491
-GTMSHDERACEHEWRRWVDKDGIAHRECWRCATYYAWPVNGEPRAGVAKGTVYYNFASKAALFEEVHTQSDYIQRYRLTKLAIVGSRHLTTQQADLVHVIIDAVLDDYPDDAVICSGGAPGVDTMAITRAHQAGRTTRLFLPHHQRWEPDGYKARNMLIASWCDDLVAIMATDSKTFGSGWTANYAESLGKNVRRLYVX
->SRR4051794_24080993
-LARLARRTRWSSTASCAASGCALRPPARRSSSPSTRSPARNAACPIGAFGVLTQDEARREARAILGAAAKGGDPYIDRKQKAAAGCQAKAEAEFTFSRMVEAWAAAREGDRRASYLREAVSCLRRNLPGWW
->ERR1719310_114900
-SARYVGRSQAAWQAASQRMGGLDAPPRKTAWSSSPDGLKSPRLDSRNASMQPPSGDIRGRRPSHLGLAHEVKERRPLFDALDTEKIKQQARESLQGRPAYNVFEFYHETGVFQFVAKHPLFENITLGVISLNAVYMAIDTDYNKSDTLLQAHPFFIACENMFCLYFFGEWFIRFMAFKNKCNG
->ERR1719193_2294297
-LYCCLLRRGLLLFGPFLYFLVPGVLLRIHVLLVVLLRTGLGALLPIRVGRRGRGDVRRGGAAGPAARGDAADDPPHPRLEVPLDQGTEIDLVCEVIARDEPDVQRRVPLKLAPIFLHVYACAPFVAVPAQLLAVHLVVQVILPLARRLLRARRLPGRRLLLFGEQAVLPAVLDEGGAELPPSVAR
->ERR1719433_1424020
-ASAICILATGRASFLNFLRQNPRKSLTSLIHRNFYEFEMAEKTIQFKAKKEIFDKAAARLACSDCKVVPRDVPIFQTGQGDVLCSICKPNSKLTGIFRSSVLEDLLMSLPISCKFQKNECPVVLQDRENLSYHEEDCEHRDVLCPYGFCKERIPAIQFKNHFLEKHEIDLEEYMKAVTKMTENGMYKVK
->ERR1700730_4647339
-XMISACRQWVRLSPRIPLFQQNPLWFESEDFARFSFAPLPRASPDHFAGAPRGLDRLAKIGQKALLPLFVVSHPPASRALHPCRLPCASALPVSAPLEPRLLRCSAGRPRRCDAGPAGNSRLPEFRPAKGRSSGGSI
->SRR5947209_14544591
-VGNKVRPRSSDAQVVRLAQADVIDRNDGDGMCRQLPAARPGRDDVLRETNPLREVARECKLRLSRAVDAPVTSVANRDEIPNVSRLGLIEPDGNDVVGVKAAAGFAAPDAREPVLLVNDGCMFRRPAADVLPVGAEATTPEV
->SRR6267378_108524
-XMPPSLTSALRRASSGPMPDRRLSSMCNWRWLSISCASSRSRRSLPNIPANRNNQPRSVLIGTPAETSSSRLLVAQRHHRIHTHCATRRDVASRERNECEQDCDTRECRGVRRFHLEKQTGHKASQRKRSCNPGGDAEERDSRSISHNEPQHVALLRTQCCPYADLMRSLVHGISHRAERSEEPEKQHVEAFLRKRHSDELVH
->A0A1E5NXB1_9ACTN
-MAERVILVDDLDGKSTEGVERVEFSWQGKDYEVDLSSAHIERYSDLLDPLLKAARLRQVTGRKTGRTAAGKSKADAAETKRIRDWGKTSGLDVPDRGPVPKEVRDAYAAAQASGEAAVPSQAQPGAPVSASQG
->ERR1719507_515787
-FFLRFVCNVFIPLSLASHIRNFWQRKKGKKAIKKGPNLWGRFQVLVVEVEAESLGVVILDDLGEEVDVACELAYVVRVRLNEVLLEEVRDRRIVARLEAGLGRNNVLVHRVLVEADRLLGRLLHHVQRRAQGVQLSKLLGDLSIFNLEAVSYRSAPLDNVLHERQPIIPHLVRVPAEVSVDAHAVDLVGVEDASHEEEAEAISEVMAHQLVQVVRVSLEVAVDGVAGTAVVLPLGPDFVITTVLDVVGAGVLPVAVGRGSRSRQYEGGGX
->ERR1740120_427324
-RTTISLKRPRAWCRCRRRRRRLIRLCIVDRCHDPGVRLLGSGEDIAHWRSEGSAPGGRRAHFEADAQSADFVGVIHGGARCRVEHLGCSPLGVCDTIDLPHGGLHERADLTVLSSARIVCCGVGISRNDQLSEGMDVNVHSARCLIQSAMREVDGITYTEGAAAQVLYTASGTTMDYADKIGALGICFEMRPASSGGGAFAPPVSDILPGSLESYAGVMAAIDYAKNPPPPTPAPPPSANCPWFCSIICMSPDCDGCP
->SRR5512145_1624320
-PGGGARGGSIGSVLVSPRSAGRQPRSPAPPGPRGRGAAELRAARRARVGGRSGSGSRAAKAGGERRLRQRPNKALQLASASGACSDTPPVRLTPPGGLGRLAAHFGGVSYRSAALAAERLV
->A0A0H4L3H5_9RHOB
-MTAIIATPAALTTDLTEELAALIDAALEIRDLTAPLSFVDFFDGDEGDEENEGNEGDEDDEDNEGDEFDEGDENDEGDEDNEGNEGDEQNEPDGGDEADEGNEGNEGDEGNEDNEGNEADEGNEGDEGEEGNEDDEGNEGDEGNEADEGDEGNEGDEGNEDDEGNEGNEPDGNNEGNEGDEGNEGDEGNEDDEGNETSASGDEGDEADEDNEGNEADEGNEGNEGNEGNEGNEGDEDDEGNEGDEANEGNEGDEGNEGNEGDEGNEDNEGNEGDEGNESEGDEGDEGNEQDERDEGDEADEGDEGDEADEDDEGNEDNEGNEGDEDFNEGDESNEGDEGDEADEDNEGNEGNEGNEGDEGDEGDEPGVDPQDEGDEENEGDEGDEDDEGDEGDGTDTFDDEGDEGNEDDEDDEADEANEGNEHGTNPDDDDNEGNEGDEGNENVPGQEDNEGDEGDESNEDNEDDEGNEDDEADENDEGDEGDENDEGDEANEDDENDEGDEGDENDEFNEGNEDNENDENDENDEGDEGNEGDEDDENNEGNEALPDTGNENDENDEGDEGNEGDELDEHDEDDEGDENDEDDENDEGDEGQEGDEGDEGDEDNEFDENDENDEGDEANEGDEYDEGDEGDEANEGDEGDEGDEPVAGTGDEGDEGNEGDEIDPDIDNSGDEADEGDEGDEADEGDEADEHDENDEGDEEDEGDEGNEDDESDEDDEGDEDNEGDEADEDDEGDEHDEENEGDEADENNEGDEGNEGDESDENDEADEGDENNEGDENDESDEGDEGGINNEGDEGDEDNENDENDENDEDDEANEDDEGDEFDEGDEENEGDENDEEDENNEGDEGNEDFEGDEGDEGQEGNEGDEDDEDNEGDEDDENNEGDEGNEGDEGDEGDEADEADEENEGDEGDENDELNEEDSDDEGDEANEGNENDEGDEGDEGNEADSQADNNEGDEGDENNEGNEGDENDEDDEGNEHDEDDEGDEGDEGNEPV
->SRR3954447_5641343
-VHVERLQVGLLPVGVARRRRAHAVALEQVLVALRVAEALVDLLELDGVLAPVGRPGNRAVRVHVRAGPVVVADVPDLRALVGRAEVLDVEREDAVLPALHQVGLDEAVLALAGARVAGALEADARRVAAGHPQPVQEPALVGLRIGDGRIRLRVDQLGDVVVVVLRARVLDPLALLRVEVTVVAGAGATEGEGRALEDARAVRRDAEDAGAAVRLVRLPPAVHRVRARLPGGDRARVRDRRARARQVDRAARVAAAGTELVAVPRVHLRERAAEVRGARRS
->ERR1700712_4604191
-DVSIIAHGNQGEIELGSTIVTEATLNANAAALRTIGHALAPGADILLYGCDTGEGSAGQQFVDTLAAATGATVAAASHLVGDVAAGDGWNLDVTSPGAAVAAPQVLSAAALNSYDHPLVINSPPTGLPISVTTFTGNTSFVETGTAVTTTSSGYLQLTNTSTNQAGIAVYSQAFPSTAAVSVQFTYYSGGGTGADGLSFFLLNADTIT
->ERR1719161_2539103
-LVQTDPRVACSVFGPTLVQRGLGAKRPALPRLEARMRFGFLCIAWVLEFRLQGSSALDHQGVLRSWSPSTANRNMALSAERVQLRAEESCPPGVPCSCNCHCNPGRYPPPPPPPMPYPPPPPTPPGGWPGVPYPPPPPQENPEPPPPLPLPWDAPPPPKMPPLFGIGSYKGAPKIVALRNNAGPIKAPPGFGVPPKPPWETPAPPPPPLIMPRAMTDAPPYSKPPPFTTTLPPTTTTVDAWWLRTTFPWWHYTTKEYEWTTTTEAPTTTTTAAPTTTTTPAPTTPPPTTTTTPAPTTTTAAPTTTTMPTTTTPAPTTTTPAPTTTTPVPTTTTPAPTTTTPAPTATTPAPTTTPAPTTTTSAPTTTGPAVVLAQAGMKWNAQKGKLQLHAGPDDLNPNKGGWGGGQSGDEYKLGDAYHARAAEYLGYGSRKAPNPAEEYAIPQFQEEQSAECKSICPPCEAX
->SRR4029453_7064880
-XGGALSTQTSPPAARRRVRGWRRSNRRNGVSFGPPTLRTDQPGNLAPALTMGRFGRSLLPMKRHLFGIAAGVPLACAMAGLVSVSSSAQAPAAAPDVTFTKHIAPILQRSCQRCHRPDGGAPMPLITYEQVRPWARSIKTRTGLGPHAGVMPPWFVEKNIGIQGFKQDPSLSEAEIAMVAKWVDSGAPRGNAADMPKPLDFENADKWQLGEPDLIVRSPDVVVPASGPDRWGSLGMVPTGLKEDRYVSSVEVREVNDIPVGGAKGTVGGRYV
->ERR1719342_652718
-TRQRYAHTLRNIILHSTPTLYPILHLDASSAWYDLKELNAISGEPIFQVMMIQVKKIQILKRRPLPLLLTMLVMMLSTTPRTRLWRKVQVTMKIMRRRIQSIRRRKSSRSIFDRLCPASQRYPFQRLNDVLLHLNSKHSGRGGGLSNVVFPGNKNDLTGLGLATCKHCGFIVYGLGQTLYKHHEKKHSGVGCMKFNVFCRLCQISSKSMVTPFEDVRALQVHISEAHTNIFDLLPEKX
->SRR5450756_449411
-TNYSVPWTVTQAVGTYTLWVRYCSSAGKVIRSDASDAALGITPFPTPSPPNLPAGPFNVMDYGAKADGVTDDSPFIQAAVNACYSAGGGTVYMPAGTYRLNYADSSWAPPGIHGSRNNDCSCLLYTSDAADDLLCVDLGGRRIIKNKK
->SRR5258708_35312273
-GEEGPGRIELKADPESGAEGDDEEAQRGRGREEVEGSVSDGPDHSRSGQRHDDAEADDPEPLTGDFGDDLLPLMSSDARVEEGQDAADDSGERDEGSGDQEAPATKVFSFDPLIDGQADHGREGRLDRHEGVVTFVRRELNEKAPEERPATQEAPGRAVGGIAEPARQPHNPRHEWQHGTPLPEPITITHL
->SRR3984957_2613687
-PRVVSRIESLAFPAKLEQPLGDSPLISRIQVDGPPPLRGPAYDLDWEGLGIVHETTIAFETGLGGNFDRRFVRPPHPGRGYIGEFPLTHVHVVRSCDEISELCRAEGRLVSRFPARAQDRVSRSGRPRRRQACGRSSRQX
->SRR6266536_1781336
-DAGDVLVTQRRESRRSSSGAEVPSHGTKDPCRVRMAAEEAGGTARVTTRHPWEAAMSPTVSDHPSIRGALDRAEALAARRRAYAPEVVALLANAEFAGRVADLAGSLGRPAAEVRGEVAGYLREMGETRTRRATSDWARFS
->SoimicMinimDraft_7_1059735.scaffolds.fasta_scaffold44147_1
-LPKHAHMQLFGFFLSQKATKVRCRFIQLMHSAAEEAERIYRFEMGLLSKEFFPVTISKLGRYKARLFVCTFICIAYTKYTTKHKIKKDDNDSYEMLQISSEIAYTPFSMPATEDFIDKKQKEEAAGLMYKIISSINIELSNRPSPIVGESTKGLENLFTIYEGIFVESIGQKNYNSEIKERLKVRIFSHIWSGFNTMIKISQSRSISQVLFKNELGLPRLSSPX
->SRR3954453_3871201
-LGVPLWLDRRGKYRGEEAVGQVLAGVLAGDAHRVEQAAVAAIGGELDRLDPALNSRQALEAVVPLGVDVDDRARALQEGLPGEELQGDRLAGPEAAGEQAGWWTGALAGLGEVEEDRRTAAAEGVPYIWTDLRSGVTDRVRDHRPDLVGQQVLGVLGQREPGGGKGGEEEAVLLAAGTMQLGAPVGL
->J3L6R9_ORYBR
-MQRLLVKKNAARIAETPRVVWVNRFSCLRSSMASRAPIAIQDENLPIFRGIGGKKAGAAAAARAVGRQERKALGDLSKARKAPPASAGGGPPAAAAAAASGSKNLVKPSYLSDEEWMKCCEWAKDGIEAASFTGNDMQKLLSDKREERIRKKVEKAMRTMKLSMDNLYDIDVHSEACMVDPEDKTKLDLDTEFLPPKPYLSSRLGEHEANYVLSDMEFEHETFANCNLDLKLKDEYGT
->SRR3990172_7523137
-XMQFVAIDMETANADMASICQIGLVKCENGILSHEWKTYVDPENYFDVINVSIHGIDEKVVEGAPTFPELADTLHSYLDGTVVVCHTHFDRVAMHQAARRYGVSTPECTWLDSARVARRTWKEFAWRGYGLSSVCQRLGYEFKHHDALEDAKAAAQILLAASNETGLDLDGWLRRVRQPIDPTAGSSDSAIRRKGNPEGPFYGEVLVFTGALEIPRRKAADLAAAIGCQVASGVTKNTTMLVVGDQDIKRLAGHEKSSKHRKAEELIEKGTPIRIVKESDFEELARVSNELQANARWTTLRSRSVLAAAGTSLHTGVWMEKKGLLQYYGLDTWWQSVLTPAERERVESLFHPLCSPHAQPLTDGVVGQIIGATSTPVSFLSELVGWLHSTPEDLAIRRKIRDKMTELVSTEPNVISRHFSLQVLLSEYYRDRDVDPSALAAAINACRQQIAIAPAVAIVMRTDFPGGLPGHVGYQQLAIILEKEKSYTDAIGVCEEAKGAGWGGEWDKRIARCTACRDKATAS
->SRR5260370_27521811
-ALVDFEVDDLRGLMPDVQPRDEARLLVEEELLDLVLRLAQERCHLYREVTAECVLEREVVVVRHLRTDGMSRRRRETERPETNQTGDVVRLEEIVLLEGGVWRLGVPAVARPHNRARIQAVRQSDARLPFGIGEDLTRHIEDRGRRVYCVERIIEKRPSSRVCRIGADELVIVESHAEVDVEAIGRLPDVRDRAGPELRPPRLX
->ERR1719507_1551978
-ATKGELHMCRKGCIACFIPQGDTDSCQNSRVLMQPEFSGALRIGEPQMSMQFFQDESCPNWFDKLDSKIAQQDVFVGDCFKARELVKNQKYAFIKEASEGKPMTLWACAAADCRTNSCEETTVAVESCATSHYVGIPDNAWYKKLRFMRYQPTEAMHVWDDPYCRERVGLIRQTMGLVQQAVDRVAAFKHLEPSCSFGTAVQDEIVEKKFAEFRGHVTDLRPQYPKRGVLWX
->SRR5690349_24626955
-RPTLFPYTTLFRSLAGKKTVDLARRDVQRAKQNGHRRGEVFAVPRASDEKKIRQRIRTRLATEVQRVAVAAAQKTFHGGRFVVRSASACGDLRGQVRNARVERIGKLEILSAHLVGIIGRGSAQLGD
->SRR5687768_17364510
-DKAVSTYDYFASYYTNVAMTFDQRYTLSLSGRLDQSNLFGAKTNRKIIPLYSAGIKWDISEEPFYNKAWPFITARVTYGLSGNLNKSTTAYTTSIATLVNDNTILSVITPANPYLQWERSAMWNYSIGLTDQGGHFQLNFEYYHRRSTLLTGPGDQDATLGMTSLWGNNAALKSR
->SRR5262245_62041426
-IANLARVGILAVTQIDVLHLIAMRVDHPLQLPAEDALMIVYTGVVRLAKEIADAIGRLPLPAAALAPFEAHEAALILKAVAAIVERHELFPTAIDKGILRIHIRRQTILGPPLDKWYAQLPAHSPGAVAIAAVIVKRNLRLKLX
->SRR5690554_5011345
-LKVSTMDCVAPRLPSGETVTVGGVLPPPPPPPPPPPPPPPPPPPPPPPPPPPPELPPQAASEMANITATRMRMAPPENGFEIFNIVRLHGESYETKPVEMTVNTPSTAGNPRKHLPWFARCSVIRKPYNGPCKKTLKGCESEVVKTRGITRCCNRETKRLSDVDVEHDEFLEVQTAFAQGAHEILFICHTAEIYRGDLDEQRLGDLEQSRAAFAERLREEDAPLGLQQCADVSKRFLGFGKQHEARGKVHCIIRSADMIVDGFQRERDVVMQACLGDAFAGALHVFIIDVYAADVKLLVTDQRRVVRERTGGADTDIEQVRAVGEARQHLRIPARRQWAEQRVVNQASDHGRRFPVGGKVFVWTMRDRIKAERKGTQCVPGQFIVSTGSADRSAPFSRR
->SRR6185295_1157811
-XSRVGRVEPRREHLLAAAAVWLWAIAAPAAAGASGAAGNDVQRYIQAAAKLYESLDYDQALEQLAHAKALAVRADDGVEISLYEGIIYADMSGHRDQSQAAFRAALLLRPDARLPVKVSPKVEKEFEQLRKQVTQEQAKEQKEQAKRKVASKPPSPAASDRPVAGAPPTPPSLVPLEPSGRGPAPSSGFSAFGVRVPLX
->SRR6266480_734243
-DPGFELEAARLDKLGPETDRLFFGASRPITDGGDLQVRRRGKAAAGDVRRTIARRQAGGRVQLVDRRRILEVDLVYARDPEVAAAVIAAGGGRRLVGAEESRPRDRDGRSDRFFARAQRQHPALGAEEIALRSEQLRAARRTKGHVLQAVVGRVEQIRLGNRGYRADVRRIDIGELAVLEHVIAVGDGRIERVLPVAX
->SRR4051794_34720228
-SIERKSEGCTLPVAGWNNLQPSTCNPQRTVQFYFFLAGAAALAAGAAEVLAPAAGAAALAPAAPFAPAAGAAAAPAAGAAPGAPGTAPSAVSSFSAFASAILRCATFGRPSGLLLSSHFSSSLSLSKRSPRVSTLRX
->SRR5258706_1188100
-FALFAGNSFAVKNVVLFQFNIVSPRLIEIRKFVRRKLALDLRRRTYDKRIRRYLRSRRQQAPGCDERIASDANAVHQDRPNADQASALDMTSVQRDAVADGDVFLKDGGMRLGADMDDSRVLDISPCADPYKIHIAANDRAKPDARVLADLNIAYDDRVVRYKRCVVNFRFDX
->ERR1043166_2789281
-PGRKICSERKSGRNYLGADNALGQPEELTADLHRFNPVNPAFLSELSVFICGRSSFDHIQYRIGFWLRLGFWMFGMTKFAESKEHVALIRRVGQSVLLGHDTTANHLFDLTVESLHAFGLTLLHRVEQRLTFGLAAFDVFARSGRCFQNLNRCEATVAVGARX
->A0A1X2JM77_PARBF
-MSLLKLILQNELCSINFNKNVACATNIYYNNFKISTLVYGGVEMKKYEPLGDLIYFISKELKSRMDESLKDRNLGQGQLLTLMTLFKLKNYDEITQEDLAKVMGINKANTSRNLAKLKESGFIVINQSKDDQRKKNIELTNKAFEEFLYLEKIMREIHNEMIFGLDSPSLDCTLSTLIKMKENLLNK
->SRR5260370_10911006
-GTAGFSMDTDVMPISSCDGPSLERPASTKLRVPDLSAWLQARAEQLDLDRDLATDTLPQLGRAGPLRVGVPTDMGGSGGTILHAIEAVAAVAEDSLAAAFVFWGQRAFIECLLQSDNAVLRASLLPSLLSGDLAGAVGLSNAMKFLANMERLQVSAASLPSPGDAQRWTLTGNHPLVSNLRPEGFVAAIAADHGDGRPPSIFVVSDEVPGVIRSDDLDLVGLRASNTAAVRLNDAIADEHFQLASSAPDFLARVRPNFLGLQCGLSIGLARRSLRALDSMGPTARATIGEDGRKLEAELPLCFLSLLDGISTGEFVTRPTQLFRLRLLLATLVEDAIILEVHATGGRGYIRGQADVARRRREAAFIPIVTPSVVQLRSLLQEX
->SRR5512139_1340698
-XMAVAQRTPEWIAARQMGIGSSDIPVLAGESPYRSPYSLWAEKTGQIMPEPDEAQAELFEIGHLMEPVLLTIYERRTGRHPRRARMMRTHPDLPWAHASLDAVAPVRRVVEAKWTTSQRWGDEGVPDDVLLQVQWQLFVVGWQVADVVALAGRRARVVEVPRDDGLIDRLVALATDFWQGVEHRVPPPVDGSEATRQTLVALHPAATAPALSPTPELVSLVDRYVEAKAVTRAAADDESTIGNALRAVIGEADGIAGLVTYRQSADVTRVNWPAVAAAYRQLLEGSGADLDALEAIHSVTSQGPRSLRLSKGVTSX
->SRR5882757_368707
-VIPECPLRDVGWDRDVRARLLDPVRDLVRRHAGWRLRVPACAGPARGRLHGGGPHDQARLVADHRRRLGRALSVPAARQHLHPVDGGPGRGARLHRGRAAETERGPARQPVVTGSLASGLRWQGFGGGPPITLVAPGLGATPGEARIPASGLSGTRVVVTFPSHGEAADAPAGYWTYPTISTDLERVADEVGATRAVGVSMGAGGLTALLTRRPDYFERIALLLPAALDKPRATPAMWAFEQLADAVEAGDVDGLRELVAAEVPAGVGVGEHISSRADALLRLGGALRTLPEQTPTNDAALLQRVSAAALVIGAVGDPMHPEQVARDVAAALPNSRLELVDSPAPLLTHRREVRSLLVDFFVGXX
->ERR1712082_453316
-YLKEHLDTIGPHLFVNKNSWNILGRKLGKNCKVRFLLIKRSILVRFSKFLKCYLQNYQTKLTICVIFLCDLYGPHNGPSKMNDPEKKGKKLESSFFANKTLNFGPIFKIFKMLFAELSDKTHYMCNFFVRLIRPAQWSVKDERPRKKGKFRRVX
->SRR5271166_3589085
-QGRIAGVTTGDRSVHFEYDASGGWVIHDKDAAGERILRYDASGSLTARTDEKGRTTQYAYDGQHRLASVSDPDGSVLRYQYDDAGRVASVTGNADGSPASIAFSYDASGRPLSVTHEDGTREQYAYDAAGRVAQTTNRFGQTLSYTRDDAGRVLSIAGPSGTLANKYDGQGRLIEHDDPVEGTTRFEYAPGHIALVDAADDRTQFAFDAK
->SRR5262249_39470886
-GSKMTVLVRFNDDILLGTRLESQPDWEGYVAPVEILLLLERQLDFSAFLEQLGRKHRFERQGERLRSLWGDTTRRKLVDERLAGDQLDGLVDRFGRRRLGNGRDVLGIDRSNLKLAFQNDRLTVAIGQLVSGDAGIIPVLIEPALGDDEVDX
->ERR1719421_1404448
-HYVAGRGRREYEELPDVLDAVLEVSEGREALALQDAEARTALVVAVAGDSELELKDLYEELDDEETVVERSAGSPWFVRAVLACAEGRALLPQTWPAEVMTLLHLAAHADTVAAILEHAEGRKLLEARLPGQLRPVVGQHVRLRDSAQKTDGVLAEGATGIVADDDWTDQPFCVRPLENPDEDYDWYY
->SRR5437773_2629605
-GGGCVCRCASSWSPVRWRADPLRVRLWLTAVVPPPEHSTRAATPRVVFPSRSHVLAGARDRRPVSRHCIHRLRPRLGKGVGVPGRSCRTHYPRLPPTDALSVVRRRHRGLATRSDRFWLLACRLEVRLRVSSDCCSLGAGQLAKARPX
->SRR2546425_291204
-DSAVSAYPFCLSFRLPGAASLSPQRSRLTQVLLCRSVVRRPPRRPLIILRPSFRTVRVAFMCPVPPRTEYTAWLQMVRSVWSRVPQQKGFSGDSGLATSAELKYPVGVAVDGSGNLFIADPGNSRIRKVTPAGVISTVAGDGTSGFSGDGGPAASAQLNASSGVVADRSGNLFIADAGNSRIRKVTP
->GraSoiStandDraft_43_1057313.scaffolds.fasta_scaffold3636311_1
-RFFYDEDDNLNLDFYSEYIKAIKKITNEEFLSTFFEKRKKNINKINSAIYSDYFLVDNNSYLKYGPGLYYFNQEDLLFRAEILKKKIKQKLNKISAIETNDQITIENKDIPGNISLTVDGLICEKLQNNWRKNFTYKIISAEYLKNKVEIKKDSPYLSNSRCIYVKFKDKFDNEVFLKKINYSLPVLFNEKEIKEKYLNYFYKKNNILFLKNKETEINEDIIIPENFTVRIKSGENIKILNNAFIISNSQWEVGDKNGRVLITGAKDNFGGGLVIKRVKQISKFYNTDFKYLSGVENRFLNNKKSEKTSFILTKYFENKKNSYIYSQVTSNDYNYGFSDKFSYTGAVNLYETKAQFQNCRFIRIDSEDALNIISSQFLIEDSIFEENSSDSIDIDFGEGIIKNSKFTSVDNDAIDLSGSKVYLENLYFLDVDDKLISSGENTKVNIKKIEGKNSYVGIASKDGSETIAEDINFINVKIPFASYQKKKSFKHGILKINDPINLENYVVKNIKDRNSYIYINKKQIRNSNKQALNIVYKKKLSLINEHX
->SRR5690606_2703104
-NREPLVTNRFADGRERIERPACGRTNLEIVELAGREAAIAGIRDHGGVVRAELRARIHHAHVHAAAELAELGAQLAVRADAACDDERRKRRLLERALALGDERLDDGILKLASNVGARRVIELESSRRDDDRRFQAAETEVEPGPIEHRPRKTKAARFPGIRQLRERGAAGVRQPEQLCGLVERFAGRVIDRRAYDVVLPEPANFREQGMPARDEQREKRKFGRLALEHRREQMAFEMMYAX
->ERR1043165_1439568
-XMIVQTKIEDSMTLKLVSERAEAELRLINSRELEQELANRDNHFNVRDIVAAALWKTDLMEAVIIRKIYEAIIKIDMKDLTKVENWAEEINRASQNPLAIESMKSKKKQAMPREEIITPEMYIEKVRQETDSVDVVMNEKESRQDTSPEEKERQKRRKGKEVTDIEVINTKMEMTTLDEIEEVKTKATEAGFQQQNYKDIITAIRNENDTREIEEMQDTVHQKKENSFAEAPLEQSIWSPSNRSCNSKATYAAKIPAYNVPGSSQEERTKFVRRLLAFNDHVKEVKEVFERGNAWVRAVFDYKYSREEAINKIQKKHNDWFRMIPDTDEREEDKIREHERPKQKENLVKEEEERREEGLLALTIWDLPQEISEQEVRYLVKRIGKVISCKVKRSAYRTIDRKR
->SRR4051812_11463556
-RHAYRDRPAEPKPNIGNYLEKTSRFGTPRVLEGDRIAHNGIRQRERTNMGATATWAGTGAGRRRMEAVIETLASVHEHGESVSELAHDARTMVTALSLYCDLLDEPGVLASSHRHYASELRLVAEASRRLVEKLAQLEGGDEETSCPGRTSALQACLFPEIAQPHGGAFQGALNGMPGMEPVSGGLIHDLREELLSSRGLLAAIAGPSVTVNTATEGGAQPVRMSGENLIRALVNLVKNSAESIDGAGTIDLRLIEQWEPGKVHTLVLTLEDTGCGIPPEFLEKIFDPGFSTHPARQPGGSWTSGHRGLGLAITRSIFTAAGGRIHAENRTARGARFVIEMPVRN
->SRR5688572_23826730
-GVLALEALGLIALSLLLGNALTLFTLGRIIGMVLRVFSFAAATVDIAIGRLGSDGRLLVGDTVVWLIVLEWLAQSILAFAVGAFVLWVSSDTIGLAGAVLSGFVRTIRRIGIHAHNGRVGLTVVLAAFAAALAGAINS
->SRR3972149_4567815
-PPRSTLFPYTTLFRSDGLAYPFGRWSAFIVLTLAALNAFWLLKRFLGQLRLGGKVPAFFRGHLIENTMLLVSLAVFRGALGRADFPHISYNVFFTYLLALYLVVKHGLAGFVERVGGERAASRVAM
->ERR1700722_15463975
-GITVAQELRDREREPLAAEYVVLAGPDHEPDAPLTQGVEDRQQPRASLGQAVQGRGDRRRSFFPADQPGSFQLADAVGEKVRRDSRQSVFEVGVPQSVADQQFTDDQQAPTVAHDIQSFGDRAVLSVAPHDLSLSVLQLNFKSKRLTSSSLRVTLASMRTGCRRX
->ERR1719253_2112
-CSHETALPMILRGPHSLTSDLMSALISSVASSSIPTVLCITAQGPRYIGTLLSCLSFASLALIHRLHDWCVVLRLMDDDVVWQRHLGTHLALRVMRKHDLDLNAKHPLTHGHVADSLANVVLLRLTSGNE
->A0A1Y4JJG6_9BACE
-MHATKEFSSISELKHIREQKSRLSEREAELVSPILTNLECIPYIYELFKNIVRTMNIPLREEIIQRKEFLFIVLFLFVPSVLAGGRIPNGVRKALEHVFPKVKPCTISNNIADVFFLYQQYKYFRSDIEIIYKEMLKRLENDDVSNGLKRFIIK
->SRR5471032_1837456
-MLLVDVDGLSSLVVAVIPLHEIGLDLRDTQAGQLAGASGPKERTAEHSRKRDSLQCAAQVGGLAFAGFGQRQVGAARMLAGQSPGGFPMANEVNLRCHRARIAIRSSLPMDETRSSPGELPGAIVGSSTRTIGPKFEHMRPTLRVL
->ERR1019366_9306790
-AMPITPSSANLRFSDRAVTNVPRSSANTRFFAHQQASPAARVPFAQQQRAVGQAATGAPNRATAAAPGASQAGPAQNAVRPQTPQAGAASGWRRFGEPGGSQQAPRSQTAPQNNRGWTGFGTPGSSSSAPRQQYSQPQPGYRGNSGSSAPQSLRIAPPVVQQRSGGGSYSAPRSYSGGSNGSRPSGGGGASHSSGGGSSRRGSRREKLGSREISVSSPRPRPASAGSRP
->A0A098LH02_9BACT
-MAVLSWAQTPLSMNGRLSVTDGKLVNECGTAVQLRGLSTHGVMFHQECYTESSVKAIAQDWKADLLRLALYTENSDGATKGFAQSTNKEFYYQWIDKMVSLTEKYGIYVIIDWHILKDGNPSKYQNEAKAFFTLMSSKYKDKKHVIYEICNEPNGGTQWNQIKTYAEDIIPAIRNNDPNAVILVGTPEWSSRIDQARSNPLSGNNAKNVMYTLHFYAGSGAHNQYKNYLRDAVSAKFPVFVSEWGTTEASGAGNIDSGNSRDWLSLLEQNKISWANWQFSDKNESSSLLKEGSCIRESWIDFRTDNSGNSGKLIYDELRKTKNYTACGSVTIPVTPKPPVCPNATGSNLNIYGCPVTNTFNTNYCQGYNTKQAYVRTDFSKDTVPYFTYWKKPSEGSTVYSAVIQNEKLVITSVNADPNYSTFGFDFGKLNATTHVPIDLRANAVLKFDVSFQKTNYSANDIALYIELVDANEKSINATALGSYNRFILPVNGTTKTIVADFTNGVKRTPPATPGTNGDPKEDTYDRTTFDFSKVTKITIWVNPNVSGVYSRPPFTGTWTIDNFSLGYDETKAVSCEEYVDVDLCPEDPNKTKPGKCGCGVPEDGCDCNGVAGGTAFIDLCGVCVGGNTGKIECDGNAYSGTPYPIPGTIEAENFDKGGQGVGYYDITEGQPASSYRPGDKVFTELAGGSTNNWNVGYTSTGEWLNYTVDVKYPGTYHVSFRAASERATGKWHLEVNGQKIPNSDFSLASTGGWQTYTTLKTTQPIALSQGKQVIRLVFDGPDANIDNMTFEAFEVITSIPAKAERKVTVYPMPANGLINIRQEEMSYNKAVMMDMTGNVIKTKTLSGLTEELPLQNVARGIYMLELTGAKGTEHVRVVVE
->DeetaT_19_FD_contig_21_9884499_length_257_multi_3_in_0_out_0_1
-MKDYIGLVDTLNMKGMVVLERGGGALLSRTYPSNKIDVKDCAFKFPLYTTEYKMGKETPELVRTQSWNGAIQVHTSKAFTAEYGYDLFMNIPPWIYYNHTNLKSQTKKQIKTASETKIMLQIKIPSIKSLFLSNAFKDWLSSGTTKENNNQPDKLLWDYILHHHDFRVYGIKPWGKSNYLHYRDLPITQMDLHIDIRGIETKDVLGLTSVAGYYARKNMAIWHNTDATENEKVVIYQSPNGIEFRKGKKSSEIYKFYDKKLQQQQQYYDAIYTPQSFASDRYKKAMKPFFEKLTDAERTTLRYEVSLRKVPSQRNAVNKVYAKYSDGIEKDIHLDDIIGNTTIYSRVASKVLQVGLYNIFGSEITKEISNLESGDNAMNDTDILQKYKSKGLKYLGIKYLMKNEGLNNEQVWKYLTNAIAGNSSYEVVRRLRNEFRDEGLALDLLDTHQQTLDRLKDVYKNALSX
->SRR5580698_6036952
-PHHKIFDSVNFLLRTWLHWTLRVRKISESHPVPAIVSQIAGFRCCTTETSAPPQSSSPALSRSMQVREYKESDLAQLKAIHASQGFDYAFPDLSNPLFVTKLVLIDANANAATSENRQSIDSTATANGKILAAAFLRLTAETYLLLDPNAG
->SRR5690348_4651858
-LTPGEVMQLDPEEEIILAAGQPPIRAHKLRYYADAALRARVLAPPEVTCPDRPSQMSSPWEDEGPKALAPGSRRAPRGMADTEDTEEEGHVIERGVDEDDAGPGEEEAIEEEGYVLX
->A0A085GHN3_9GAMM
-MINNICISLYGSIEDICKQQLVNAGFRVPKETTNGYLPLLLNMNKRLIEPRKRNVHFHSTLIVPEKNRNGFALLINKMQCGSNINGYQSHHLERTNFNDDFLNDFGLHHFHLGETTQKTGKHKRYIERTGNTIFAKVDQNDIYLLGVFGHNSEEKQFIYSDEQLLKSLYDEWPHLLEQCRVRGVTGQTLSPEERNALRSNGTNVITALSDDIAIMSPGGGFMANKMSAYVSIEMIHLYRTISLLKKSLFKIQEQHYPFDADFKVITFGHDELSLFCDKNCFFTKIQILDGNHKTMSLAPGYGPVYTHGFVRGQTTKLYVALIEALNTTASRNYLHPFPSLYIRHL
->SRR5205085_12251670
-XMNDCGALCAPFVCQGGTWEKSRKCRCFPGMRQERRKLWLEASQGAILVAALLGAVLSSRASDWHPASLVLLLLALVVATDQFAIATKRMRISGGHVSFVLAMALX
->ERR1700748_1727377
-DSAGDPRAIYNRLAEETDESNLFLDVEAIGAGENWRTRIDNMLQKVNAVVVVIGPRWLDLLNARAAAGAFDSVRGEIAASLKRSDVQVIPVLVNGARLPAQSTLPDEIKGLTDLNAIEVRGSAWTSDVERLVKALRKSGALPTSRTRWMIRAAALAAVPVVVLAVVIAFFELRREVPNLPKNISYRFARELVSNAGLKVVGHKIEPRNGTIDVVSAQRRAPGSHLFTWQSVEVDLVAVEPYRLVCREGQNFAYGSDDDGFRFEQYKGQASIDMTEGSCAWIDRPMRQEEANVLKPLGFERNLAKHFHSAPGGLLAFCAISDYDKHNKSPRLLALSLEWYARKEGSGQLVPIIGDYMCVDRLEX
->SRR6478672_9921535
-KLYVSHKVTVARSAVDNSETCRAYGDSVAQRRRRGLGRAPLYVARLQGDVLRTRRRELLGAGVQRLLGFVSPSHEREQRIDGELRGRRASLRGALNESHASGGGMAGGQTDLHVPELGFFTGVDLDGLCALERECRDLDLGLGLAGILCGCRRGALPLDDRVRLARLVVPETSQRHSFEFDCTGEAPGVLVEEARGNREISGEAETGSRIGAEEVX
->G7DWE7_MIXOS
-MVNQDAKGKLKKLEPVEAAKRLAAYAAVDAHIKPHHRVIGIGSGSTVPYVVERILEQGSEINEDRWFIPTGFQSKQLIVQAGLNLGDVDQFPSIDVTIDGADEVDDDLNAIKGGGACHLREKVLAEAAADFILVADSRKDSRVLGTTWTQGIPVEVAPFAWAKVYQNLALLGCEEPILRMGKAKAGPIVTDNGNFVIDAPFSAVYMRDPADLLHRIKMLTGVLEVGLFAGMAKAAYFGQNDGSVIVRYVDASPPNSARGPPSPSLAVLQSFSFTFQNGPPEHRARIMPSTSLFSQRSVMSMFTESHIRSIKSLDDLDNAPGGRSAKPKYPYVITLRAALLGSPNGQLTLQEIYAEIANRFPYYKHAGKGWKNSVRHNLSINRCFKRIKSADPSKGSLWSVDEDEEVTTTRIRNKKRYATSSRSNYRYRARAAKSRRSFADDDEDEEEEDDRSSVSESASAAFIARSPIRTRRAVLAVDTQTKSSASSHPSATMPSSPTTSELSDANSVNSTFSPLSPAHKPIQHIQREPAPIDSFGRAGTRPTPITALNAGQSVAPRASESPRSAAFPHTESHMRSFAGHVQSPSYRFSAVQGHQMDDHYPTVWPSLGTYTPRQTTFAGAASSTVAGTGPSYPDARHSLGNYALKSDNNHEHVPSTSGAENAQPYYDYPPETEETPTSSYYRDYATVTQSDPHWWQQVYQHSSAAQQHSPTQATHPAPPPYYHHQVHQPPVTMSPLHAGHPLSSGYGTWYPAPNLPPIGHAPNGDVTSPHYPTLLPISQQKRMLQAAQ
->SRR5437870_1888551
-ARCCFLIRELQFWVLGPSRSASWSGFSRIMPLRSSPKLRRRYSVRRVVTVRRSPQNRLARRLEPTEAVLRWMSGVSEPPFVWVTPTRVRRLQSSRAPAGIGEKARGLLWLPAAWVPPFFVLSPEFHQTLSECPAARRNALIDSWATVFERAIVAAGLGRAEKLYLRSNAVDETIEARGRYKSEVCERKHWKPVLRNL
->SRR3972149_5390364
-RLLRGGLLLGLFACLRLLCGGLLLDRLLLGGPLPRPLACPPPLPPTPLPPPGPLPPQSPPRQPPPQPYRPAAPRSRSPACERFASASPPPRGRRGPGSDDGGRPACAPARCRCPPGASPRCRGRSRSRTTCPVRQRAPRX
->ERR1719354_373981
-NLVKLSNTTDLLIVPRKSRRTKDSLLSSRELEQMSSVLAQVLVCWLVSTKCKQHTSTTSSAQKTKTYIRKHNQFLLKPPSLKSKFAIPTTNSPSRKHTTNYEHLFIEVKPTRKHKRKKELSLFQRDGASGFDHEFLNMTNNLLERSSTHTPKEGVIFWKCLSKVDSFLPRPLQRFFLLYILTSASRGVNSLSX
->SRR3954463_10117746
-LSFFFFLMIRRPPRSTLFPYTTLFRSVGEVAALGQGQALGQGVGAATELQDRKSTRLNSSHTIISYAVFCLKNKRIKRHEAREVACLVVVFAENPSPRLRYVIGRDAHLQIFFFLITRRPRNYTLFPNAALFD
->ERR1700722_4865254
-VQQQFVPSLATRVDCGKMGEAQNAKGTTCDHQHFLERVFLLFLELYHSMRYTFIPRTLLLLISLSRGSLSSPGSFVSTRFPPVLQDGISCPIEQGDSHMQPLLHNHDLGTKTKLWAKVARLQGDNASVSANALX
->ERR1035441_2809112
-GLSGREITWSPVNFRADGNGIPAPSTEDPQVTVERCNAHLNVTPTGKSDQPLRIVIPHLVVTTILIEELHHSIPLEVKQATGDRLPHGISPRQLCFSHVETVAEAISGALSGLHQHDYSIDRSVRTLPVGRLRRNRRPACLLRSEWWSTTVVAASPDR
->SRR5215472_7227805
-GTPIVIGEASEGATLGVVAADATNILFQRYDSAGTAQGTPITVAPSPPAPRPTFIGSGGGSSLVVWGQGGGLHGSVVSSSGAGAPFDFAPGSWARTLYLSIADAGNGTFAIAWTGDTATGVTVSGFALAGAGGITGGPSIITAGSVEFRVIKLVHTPAGFGLLIAGLPGNDTVYVVPLDSAGNVTGSAHRFLGADVAWDMGAQGGGLGI
->SRR5580700_8890822
-VLAGYSRRPVPGRSHRPLAWSRVRPGKARTRLWARRCHGANAPSMPGRRRPANRHEQPSLAIVFLSPVFVPSASCEGFPHFEIRTMKGEPHETSSSQLPCELFAAVARSRNRPRTCPRSSGLRTARQFPLGERGQRAHDRVYQHHRARTVARCNRRVRTHFRFWGRGIQKGPRRRAVRRGNGDRCGELSGLALSGGVRAEYEHMAETRRINKVHRSLSRPLTILGAERKLFFFAMCMGAATFNLLGSLLGGLLMFLLLYAMARSATQTDPQILRFLLSAARLRRQYDPMKFSPIVIRREGDAX
->SRR6266545_3341769
-RNGSDRVLLLKREPGRKRPKPCSDTLKRLAALRLRCVTPGTCDEFSRAPADRAFPVLQESCPGIDTALANERIGVLRRGKMFGIDNEKRGAPTGTGGLFHRSRGGRVAGPVAVETKRHGVDPERCEPFKQTRAHTRSTKGGDVVDAASAELVEVEDSLDEDELLPV
->SRR5438128_2375330
-XMRSMASGGSFHCAYRHATQQAFLEAHELAFAYFGGVFRLLRYDNLTSAVKKILRGYQREETTRFVAFRSHWGYEAQFCNAAKGNEKGGVEGDVGYSRRNYLVPIPQARDLVELNAHLLARSQEDEGRKIGDRAQSVGAGMVIETEHLLPVASEGFELGEVSFLVVDGKGCVKARTNWYSTPLRAGAKARVNVLPAWLEVWHEGRCVARHERNYGRGRQVFNLEHYLDVLERKPGALAGSTPLQQWREQGRWPDSYDRLWKNLIQRNGKLSGTREMVELLLLGRHPDFIRGYAIMVRGGSQMFPSHANLIDGFGADYKRRIKRNHPAWVIVYARGEPLQTFGNHVDIDKNVVDAWGIPVLWIHYERTENEQKMAKDAFQNLQELMHTAGAEVLSADDTLSTPGAISHEMGTTRMGNDPKSSVLNGFCQSHDLRNLFVIDGGCWPSATCQNPTETMLAVAWRASDYLAEQLRRGELX
->SRR5262249_4210377
-FPDEGNEDREIDEPPYRLHGWIRTVSHDGALDDQDPLRNSISRSESLPGRALWSAFDLQAGQPPAKEWFRAGSLTFRTGVWSDLPESYDDSRPYRRRAGSHGSRVQIRSDLLTDLLRSVQMDLIVSVHIERSIESEYGRSYDTSTKKRKEFERIFIFRSDGX
->SRR5258706_5404908
-DAPPLLTPPETPANVLNPQWRRIGAQAAPDAEQLRRRGFRQGVIVAAGVVLAAVALTLFLLPVRRPAASPGAASALAPGVNAAPGANATPGANAASAAADAVDLQQLAQQKSSAESWYTRVAPRVRMLADSGAAEWDAAGMSSASAALATVDALLAGRDYIAAQRQLQALDVTLRQLEAGRAAALKAALQHGADALHQHDAAAAATAYAAALRIDVSNRDAMHGARRAASLDSVLAAVARAREAEQAGRLADASAGYRKALSLDPLTSEAQAGLARTSAQVASDQFGRAMARGYAALQARPPP
->H1UR20_ACEPA
-MRILNQCVTKCFALDLAGTAKGINLNRKGWENVTFQAARQQNSYPMPYPKDKDMETARNLMVDDQLRPSEITNLSLLSVMRELPRECCVMPDQHSVAYADITLPLGQGRVLPQPLLTARLVQAVMPAEKARVLVVGAATGYTAALFAALGANVTALESNTRLAEQGQLFCQQEALSVSWVIAPLNEGAAGNAPYDVIYFDGAILRFPAFCAAQLAASGTMAGVMASPNKLAKAFIAMREPKSASSFIVTNLFETQLPLLPDLAAPITFEF
->SRR5687768_16770258
-ISAAPARRPPSRIGAFPPERTGFRVARMGRGMHRLPLRCQMARASVGRDASSVHRIDLPCEQTGFLCPPPFDVHLKFLPNLPPLQGWTLLAHAAAGRPDALARWLAGHRGVTDVRVEPGLAPKILRAKVAVLPELWAAASPYVRVHHLDLSTEGHASWFIEGSKKDVLAF
->ERR550537_1009424
-GKPWPPRTTSDPTSQRAGHVYLIHAAVSNVNGFLDLGVGDKFGEAASAVDPGSAAVKQRVAAVTLDHALDHESVIHVLKSDTQGFEVNVMSGGKQIHRKARLVIYELWPKGLAFAEASVKDFFTELADAGFVICYDLYQQRPANALE
->ERR1719378_273336
-QVHFKTRLEFLKLDLQQIMKEEEIPLFPTKGLFHRTEDIAIMVQHFVSELLILPNLCSAREIYRDDFLKLLQQKSNTLFSYIEAKSLRGVDPFTHADIRQMKIDLSLNSEADFRIVLAEAEKLHPGLVSFLFQDPGSGTPYQAIRTAFVX
->SRR5260370_18266583
-DRTGPVRPDRFAQPRNSGANVGRQTSRFLIGSKYWDVDYTRTQTASNADTDAIMRRNRKVLVGVFAPIRVVFATPGRALLGATEGNGRVGSIWHGTRFQVPKREFGSLVCSSSKYLILHDRNNLSVRS
->A7T0A9_NEMVE
-MKSSPTFRFWNAILHYQMLVLLVVRAQRQRNFVLYVEALEELVPLFFVLDHVNYAKWTSIHIRDMKSLPQSITEKFQDEGQFVLSRTDNDFSAMPFDQAHEQENKIVKSAGGAVGLTENPTAFRRWMLPGPETTRLLQQFEGQYLDDTDSETGDRANHETGLSSQKTFKIQVNNLIDVIRKMGNPFLDNFPELVTLDSRDCMDNEEAETIVNLDALGKSQYSSFLKDVTKDRTVAIGKPLMQNKLPLFRKQASRNKPKQSKTTPLLQNNAALFAQLYIAMQSRDAEFFSHEVQPSPPSLSEFGSLRLPTAKSDLLKCLSQPPQPEPPTEVDCKVCDGAVIVHCLPVTGVMTFDDYAENVFLPYIRNLRSRRVDIVWDSYIPNCLKEATREKRGTGLRRKVEGRTKIPPKWMEFLRDPRNKQELFQFLSVKVAEFPWFTVRKEVYITRRWMLSGPETTRLLQQFEGQYLDDTDSETGDRTNHETGLSSQKTFKIQVNNLIDVIRKMGNPFLDNFPELVTLDSRDCMDNEVAETIVNLDALESNVASSGEADSFLRVTYLKDQKLKSEAFSHSGDQLTTAEWEQTMKSSPTFRFWNAILHYQMLVLLVVRAQRQRNFVLYVEALEKLVPLFFVLDHVNYARWTPIHIRDMKSLPQSITEKFQDEGQFVLSRTGYDFSAMPFDQAHEQENKIVKSAGGAVGLTENPTAFRRWMLSGPETTRLLQQFEGQYLDDTDSETGDRTNHETGLSSQKTFKIQVNNLIDVIRKMGNPFLDNFPELVTLDSRDCMDNEVAETIVNLDALGKSQYSSFLKDVIKDRTVTIGKSLKHNKLPLFRKQASRNKSKQSKTISLLQNNVALFAQLYRSSMVTVEIKKLLNIQFLVSLCGFALFIKEL
->SRR5262249_55098951
-TLLAGDVGLYSDFRYDQTGTDILWMGSYPPASTAGIYEWHRSDGSIVQLSPTGDVVGSFAHNADWSIIAYTAKRDSGFVYDQRVLNRAVPGKALQLSNPAGTAGVLLYTGSYFFTKX
->SRR5215218_3154104
-SPDVAAATSVPATSGAAPRTRSRGSMDAAVRVADEAVMPGTSGCWGPPLGGTMAAESPMLRPVTFRLPVPALPEGCTRDRLHPERREPPRPRRRPSLRRGGDPPVHPRVGREGRGPPRGLREDGGARVPGSSDPGTVRRIRDGLRLVRAPVRGAGARGHRVPRRAERPRRPELAHAPPVGDGGAEAALAGAPGEGREARDVRADGARRGDRRGVAGVHGTTRRRLVRAQRAQDLDLARGPRRPLP
->SRR5699024_12259917
-SCALIILLSFPTRRSSDLKVVCAADDAAAGHLGAGLRVLRIVESLVVLGPDIDAAPADALAVRVLFLDQIEHAADDEGAGDLGTEEVLFLESDAGEFGGEGMGIRIGREIDIVGQPVQWDAHIKPSFRIGSRSAHRLRPCRAYRX
->SRR6185437_13271781
-SVKNRVSARRCAAHAADYVGGFIAAHAALDVRLQVNGQFDGVKAGLAGLCNFVVNTAEAGGGEELLRHIVLDPGGGAQSGIGVALQIALLNGLRVFHHIPAVAGKVRSVNDKHADGAQTRGFLVLVCPAAVVGERFALEEAVVIRWRFVDDDEGYFSFHIDAGVVVPVVLGRIDAVAGEDDRRINVGALLPCLVLGNDVGAVVEIDGCAARGCEGEARLVFHGVDGNERDFLEIGAVIACRLEAGHRELRADVFGGELVAACAGAAAFEQIERKKADVRANLLRINGVCGSARGGRHAGNVGNGGLLRAEQRKRGEREYESKMHVPKLHSGGSFGLHRYAAMVIAGTAQFKAQTLRALCGALQASRADGRGX
->ERR1700731_1967141
-WPAQLKISEISTGPVQPAFRWQRTTIPLLHDCDRAKSYRSIAPRHWRELMDSPTRSPSRPEFRTRPATPAGRQVESFFRCADNEPDAQNCSRVLLPTPRVSDRLPLKMPFRRETEPLHALKSRAGIRLCHLTGSLILEFVCCEIRFDLRASLREPTASPRTAXX
->ERR1711974_545716
-CLRYELVPLFKSACCPPFFAKQTVSSKRTISIGSDRATSELSLELGWPIASAWGVCTEMATTGGHPPKGCLLRQATTCMGGHFVACLVRMLLNDVALKSIVLPARX
->ERR1719506_2640246
-SAQLAGGMGGYSQHRVAETGSSKAMLGSLGVFRYVNLKFPSLAHAKRRALMLFLATWSSSHRRAVPLLTKPALQDLAVCEETLCLWDVYGLNWPHGDRTATFQLNKRYGSTVSEMISMCGHGPWSSIPSREDKGDANRLQPVGVRVASPVDEQEISRASAGNHQGKITGRGRLPQIASAASGGSTLAKASILSARTFTSSGGIVSPLKTNRKHVSSEELSSPRHRKMTLRCITGSSFSIG
->SRR5574344_946438
-PRSLRADTLKRRSRRMVEKMTKYSFVLLSGETEGFLKWLQGLGIVDVTRSTKPVDEKSSQMLDKVSRVTKTLSILEKLDYSADPDFELIRQAADKTCIEGCKAVNTLGATARLEELKAELAAARKTMNDVA
->ERR1712128_216805
-TAAAVFLLQLVMARSSSLVVRMVGSVWSSPSRPTAKPKEVICTKTRGHARIDIASAASQVLQPLSHQHLHQLNLQSWHHAQSHSNVEAPSASLFMKIKMIFLIGMKLEFDVWPWERELTWQNLMTWLTLX
->SRR6266568_2358632
-PSTASSAYALVTVPRAMPRSAASTRVDGIRVPAASRPSRIAFRIASASPWPRPAAQSRCRSRPALDHSIAMPLDHTDGPVSAYRGRYERQAQSEPQGGGRIGVSRGLRTATGSAQAGRGRGDSGRSGSETGRVDQDPGVAAQRLRVLPRHAQPRRAQDRRGRAAAVRAVGLARDRLLHRTGTGRAGTDRGHDGSPPAPGRAERDLRPGRRGFQLPPVDRRGLARQRNQHVQPLRCHRPGTATVPGMNNIELAATLKSLHVPGRPLVLANVWDAASAKLVAAAGFPAVATSSVAVAETLGYPDGHGAPVAEMLGAAARIARVVDVPVTVDAEGGYGLPADEFVDRLLATGAVGCNLEDTDHAASGGLIDIDRQAKYLADVRAAADRAGVPLVLNARIDVVLATGRPADQAPLVAPIVERAQAYLAAGADCVYPIALRDPEAIRQVVAAVAPAPVNTNCPPDKAGIAAAAKLGSGRLSMGGGLWAVVRTGLAARLA
->SRR5882762_5772273
-SRPLFAVYHQTFPRTCFGRVYRRGSRMKLSVGRYFTQASLGCGECCIFIEIGELIDWVVFSLNKENIPSRAYIAFKNEEQLATFSQGYDGHLFRDKAGAFVFVVRHSCPSSNWHCFGGLIMSLVPGNESIAVVEFAPYQKIPTEKKKADARGGTIEKDEDYLSFLESLSNKNKPTGENGEPPNLESLSVYLLSSRIPSFPHTLPLHPLLQHLYDYSLTHAFICSCRNATRPPTKNHPTSX
->SRR5262245_8502620
-XMSWLRIEKFFLVAVATVLAHQALGAELIHPGARRVAFTRAVVNLEYLSGRLGHDEPPSIRRSAPLGESVWFGEIPRQLVGEELDSRRHYVPFAVMLDGNTVVRAWCDANMNGDLADDPSPALSAYPGSMTTRSFRVMLRWRARVGDRTLPIERLVRVVVEGPDTVGAVPTYRLQDVYGMLGTIEVEGVQRAALLYDANHDGIYTRGRSDGVFIDLDGDRHFTIDPMAPDFGPFAIPFTILHASYAVDSVALDGSSIVWRRLSPAYAAPAELGRPAPDFAFQDMQGRSVRLSGLRGKTAVLYFWATWCGICRRQAEDLRSLYAQSSRTDWELVGVCYDTDRDAAQRFQSEHSFTWPASFSGGLPAEDPVGRLYREAGAGVFYVIDHDGTLARKVFDVTELEAVLDSLRTAPTESSLTGHHYPKX
->SRR5262249_12765844
-RAIWAAWRRFCCHERVGIIRPPKMSYPAYFFNSGCVDHTAAHGSLQDSRVRRTQQAHFQDLGAAAAIGRCAGARTRTPDAAAGRSRAARFSSPTAARAVAPATPTVAAADAGAPRTIYQGPYSAAPCSRELVNGRSMLPX
->SRR5438132_851461
-XMADLDTTQDHRTRTLVDTAAYQPGAIAPDDATGYRDHAAVIGQTSAGPTRPVPADRRIREGEGAAGIFNAAAVAAGGVAADGAVGQRGRAAKAGQAAAETEGCAAGGVAADGGVGQRRTAAAADHSAACQAGGVAAAGAVGKRGGPDQVVHATAEDCRVAAHGGVGHHKIAVVEDAAAAGKAAKAVVFASRGVAAHGAVVQRKRAGIEHTATGVGGVAADAA
->SRR5262249_12382799
-RPDRPTASSTNRSSALGRRADDRAVISAFLQMAAAVLAIAPLGICMNTQRGLCPPSHLMQECAMSVRDDTPAVRDLNGRAALVTGGASGIGAACARELAARGATVTVADVDEAGAKDLAQGIGGRAWAVDLLDVSSLENLRIEADILVNNAGVQSINSIVDFAPX
->ERR1740117_695841
-LRIKYLNETQQKNPKHFQDPETGAQLEIKDQQTLSDWLLMYYGKFGIKIELVTDQSSESFQFVKGFGGIGGFLRYKLELDDIIGDAAGQYDDQPVPITVIPISNSRESTFTTTKPPVEDTFQEPSSWISNQEPWTPSELDHSDNSSDQTTSSSDKLVPVTTGLKDITPRVPSSSTPSSTSLEKKLKVAIAFKVSKSPTLSVEELDPVWEPSLSPRSERNTQTEX
->SRR5258706_2253991
-TVEDVAILRCVAAAPHDHAQPDLALVSVAVGELVFPAPIGPIVREVPLVTIAVVPCVGAFAVLETFAEFAFVLECLRDVLALAVKALAAHGAAVDRSVGERELAYARRDFASGSRVRLRRGRRGGRRWREWRLGGNRRPWCHLRRSRGNGDRCGGYDRLFRDLVPRALGRRAVRGCDLLGRFRGGFGRSRGGLHASLRR
->SRR6476619_4763585
-PKAQPRLHREHELRLLHVAVLRTRLSHHLCRVARPGPTRPLARRARDPHHVRTASANLSRSRRMYPRLLAAALLSPAQPPKADPNDVGVLPLGADGKPLNLDFETGDLKDWTATGDAFKGQPIKGDTVAPRRGDNRSRHQGQ
->SRR4029079_7780467
-PEPDSGTGAVGGGVPDVSAERQADYRELVEEGPVALTALDPRGTDAVAAYCLLPTAYCLLPTAYCLLLVFPVHVVIHELLEARRQLVVGSAQRRDVLAVDEDGAVGRLARAGQADADVCGLRFAGAVDDAAHDGEGEGLDAVVLLLPRWHLLSDVALDALGQLLERRARRAAAAGTRRHARRERAEAERLEDX
->SRR5215204_4095657
-VHGLAGLRGGQGAVARDRAVGRVARRSSALRAGSVALAEAVAVAAGVRVAAAVAVAAAVAVAARVAAAVDRVAGHGIAGVGAALAGVSAALAGVVPTALTGVPTAALAGVAAALLVVGRLGRGRADRHLRVAHAGAALGPRSRGRRGDDERDQAQQTQKSGDPAHIGPVAMRSRRLEX
->SRR5512147_2844591
-RAYFNAERPPWFLDPAMSGGGMFGNVGLHRLALSRSCLPGLRPAAVTASVSTLPEHPVEACTAAIVTYAGGGAVLYEEVGYFPKPSWLNTGTHYIFENGIVSWDEKLW
->SRR5579859_1021161
-DAGTVAGAGRQPRADCRDTDAESAAAAAKTRLDLGRGRRRRRGGGDQHRPRRRSGSRQGSFAVDRRRHVGQVMRAVWLCLLLAGCRTGPCKSGTLLVSVHFTGAAATADSVDVTVTVDGMNGHTTLLPLRSSSGTIEIDFAPNYPVGHTANLTVVARREGNLVGTGQLDVK
->SRR4029079_5257423
-VRLDVSAGSDVPKEVDLVHDRPVVTACDRGCIVDDQPAGGELSEMDTAEVCRLDLANRHLCLAEPDVELLGQTAICDRPEARYGRRHLQVETRGIDDVELESSGYIPAHQPIVPTTRPARSAVAPAREACDQLPGRVRRDVTGLTTRPSRGASILENGRRSSRSSSSAGDPLDEPDVVAAPTHRARQTCGQRRVVX
->SRR5215218_4007277
-XMKQSVLVLASVALAVLLAATGVVWAEPLAAEDQEGSGQSAASVTEASQPAGRVWSWGFNRDGQLGDGTTANRSTPVRVEGLSGVVDVSSGRQHSLALKTDGTVWAWGGNDAGQLGDGTTANRITPIRVIGLINVVEVEAGWNHSLALKDNGTVWAWGNNFQGQLGDGTTTNRRSPVKVDGLGDVVDVSAGGGGGGIGLYNHSLAVKDDGTVWAWGRTLGEFGDVVNSSKTPTKVSGLNNVADVEAGWHHSLALKDNGVVRAWGYNGGGQLRVDGLRAVKDVSGGGGHSLAAMRDRTVQASGARSFGQLGVRSLRFVVDV
->SRR5688572_11278665
-ICRAPSCTSGTARCSISTTSLRRCCSARGWCCRRTNTRSSARTCSTCSTPAAASASRSGPRTSCASVSLRSRWRRRGWARTTGTRAAARPRERRIMDRELLIEIGVEELPAAWMPDLTVQLAKRLEARLKEYRIAPGAPVESFTTPRRLTARVAGIAERQDDLDETITGPPVSAAYGADGQPTPAALGFAKKQGVPFEQLTRVKTPKGEYLACQKRHRGRSAV
->SRR5947208_11212059
-AFALSNPPFRESVVDVGNRILMIHETRIQREGQKPAELMSFRHLANRVSIAICFLWPTITAIPALAVEPYIPLSLAIRRNSYQRKASAALATTRCCIKKNAFICVAIILYFVKRRNPLRRFAPQLCARFARTTDALPPYPAVSRLYLLX
->SRR5439155_26842666
-XLQDDATDQGALRHARHRVRRCRQPPAPGRASSGVNGALTPMPSALIVSVGGTPDPVAFTLREHRPDFVCFLASQRSVDLVGQIKSAASLPIQDEKVLVDDADDLLACYRAALDCVGX
->SRR6266480_5487073
-VLAEANVLPETDMDYFGDDGDRMHMMFNFQVNQNLFYALAAADTRPLIKALKATNRGRRRHSGGSFCEITTNLTSVVCKRSSGKPCLRHLDRTNRCSFTIVGSDAGLPQCSGAISAGLSWPTVX
->ERR1719433_450597
-TGCATPKEVLTAAAAAAATAAAAEVAIAGIAAACSVQQFLSPKQEKQLGSPWNLPRGLLSRGNATVPGVRSCREGLAPAGTTPARRYAAAAREPTWSSRVWASAGPGQAGPVPPHSGGSWSVGARFRMQLGTSPGATRVHFRLIR
->SRR6218665_3920812
-XMARAVTRIREENGVSATRRFVVPIAIVMLLVGAAMVAVILYSARKMDENIVSSQTELIDNSLNARLTRSLSEVRSVAWWDEAVTKSRGTIDTGWLDLEVGAFMTESFHHDRIMILDEQNRPVYGYNGEGRNVSPPITDSSYTEGATEGTTERRYGRSAAAVVRIGDHGELASAMAITPSVDMSLQSARPRILVSFIKLDQAYWAAAGRDMLLPDLGFGRPSGERRGDYQLKTDTGQALGTLTWTPRRPGQLLMKNVLPLVLAGLAISLLVIGAFARRLFSASRAIEAREAKAQHLANHDSLTGLPNRRKLEAEFARFTDAAKAEGHTLAIACVDVDRFKDINDTLGHHTRDQLIPSLADRLRRAMREGDFIARLGGDEFAVMRNCRDAEDGEGLLADLRDCFRTPFRVVGHLVEANSSVGVAFAEPGRSFDDLMREADIALYEAKASGRGCDVRFEAEMGQKIEKRRMLEAALKPAIAKGELSVLYQPIVEASTGQIASVEALCRWNSPRHGFVPPDVFIPIAEEAGLMADLGRVVMESAGQDSLRWAQARTPINVSAAQLRAVSILEYLISPTEKYGVNPERITI
->SRR3989338_8474758
-XMKHGEMARRSRKPASSCKSRDCLIGSTEDFYHVEQLRDLLDNKLPLPLTVFGHLCEGKRVGRQTIERAVRDLQAIAVQFKTGPTKAERRGNMTTVGSQYRGTQEFLRVYRQLITAAEHRGLVTYTQVAHILGIHSLGHHMARQVGQILGEISEDEHRANRPMLSVVAVGSGGMPGEGFFGLARRLKKFSGSDPSSKRRFWATEQERVYKVWQPEXX
->SRR5215472_2857866
-AERGADSKVRCRDEYDYASQKVAVCASVLVVGGLLVERGAIRADDLAVALQEQESGDRRRLGEILVALGWCRQEEVSAAQQILDSRSRATVVFETVRVAVDVLDTLTVLQCSITSVITHVNDISGTIASAAEDQSATTRETTRNVSEAAKASDEITSNIAGVADAAHGTANNAHESQKSAEDLAQMFSQLRSLVEQFKIDRNMSSARTRTAHSRERQPGWX
->SRR5215216_7579447
-EGYLQHGNTHSDRWASVRWQACTPSLPPSWLPFRWRRARFASLFLSLGVATPSALDWQPLAPSSILYNILQLYHQKGAGVATLGLGLRVLSGPQQETNVFGLQSLAHPTHQVLVQPVQVGLLAQPRRRTRSRSLLRQHFLHYFSEDVSRGQRGIRTSMRRHICQRRRGGPLRSRALRLRVLRAMLPSALLMSQLSSDPVHRMRSFFSDYX
->ERR1719150_3364345
-SSSSSSSDKILWFPFQPPINTGCGGVEVEVTKSTGTMLHSAAPQPFNMFPFGHPAQHPQTSHPGDMFSHPPAHHHNPQPAAQQPEAAPKPRFLFKMPRVVPNQKEKFESDEFLKRHSREGEVRYTGYRDRPIHERQNKFLNAARDGSTEIAFVATGFNLIMNFDTSSHFNPAHRQCDFDREVGKLHLKAPMILNGVCIRWRGWLDLERLDGVGCLEFDEENAMVEDAKLREQVESYNRRLREFEEQSKARSRHLAGLVSSQHSQFPSHHHLQSDILRRLDLDILQGLFPPSTANSLHTIICSQTFSLRLGRSRSNLQQRPSSPSDAGSGARLHQVHQAPEKQLPPVEASSLTATTTPSPTFDLLPLLGLPHPPDFAQHPPPALWVEVTEQQASLAAPLPAGQARLKQTNTSQSFGRRGTFRPGTCLEKINASKLGGDLLRPKKKLDPWTFVRASQLSAQMLQYHNRX
->SRR6185312_8718178
-QPVGHAALSRFVSPPRSKGIGWAIAGYFRLTTACLLRIVSPQSRLACVGGQLPTHISISRQSRLQFAQRDVLQRFLDEPSSYSVAEVKLGLSKLQPEIARRIKGPPSPETHSFVATAVRSLGRIKGSSNCELRIQCLFDCAIYSYNNGDTAGFVTSIQLLDELGKYSNSPSWTRRIQMFGGVCHADIGNVAEAVMRYAQALEISRRANDIPGQVATLCNLGGALNYGGLHREAIPALRLAIRLAQX
->SRR5438132_413551
-QGQANALGNLAIAYHETGKLDDALNAYQDALGIYRQIQNRLGEAATLNNIGIFERERGKLDVALSNVRESLAINRQIDDKDGIAEALNNLGNIYRDQGKFDLAISSTREALDMYREIQKPMGEAICQTTMGEIYTAQGKLSDALIALQRALELDEQAKYVPGIANVSGDMGIVFAKQKDEGKALEQLKKAIDLYVKNGIRGPELKLYQEWVTRLEGGTRTMSRX
->ERR1719318_1879121
-KVIMVRADMLVHHATIEKAITEYDDDDKVIICSGSEKTIVSKRILILFSPIIRTLIASLPCCTPATIMIPEFSSSAVQHLTRILETGFTLGVPIESFKQVYEIIDLAKSLNIEMSDLRREVKAKVLEDEKDVKTEETHLVNNEVVNATNEETEELQSDKILILKDKQKTISKDILSFISQFRNGVEKLTCSECSETVTRANVVDHFKEHIMDLNQKIDELSKGNQSSTDKEEKITKKPEIATPAEAFKTESELDNVDIVTDMKVEENYVNEIKER
->SRR5689334_23174827
-GRGHRGREKQISHLQARVSRQLAQQRRSLVMGLGIDLAVKDLRPVTCLRRDRDAVVDNLRISRNLLRYGQDPREVDAEVHAASLGAVSAGVSGRPGYRSSPTSASKASVYAARNDEAPAMKAARDWFTSASIRS
->SRR5271157_4508164
-RLKHGFVARSTSIGHHVGKWRAASGGTIERCAPRLTRRVERRTRRRVGTRKLARQGGSMPEELAYARKASGLVRGLSFWDVLGIGLAFLTPIYAIWYVIGFSLSVFPRAQLLIAIGISVLTVVWASPIVWGILGGTMPRSGGEYVYNSRIITPAVALGASFAAIVAQFYWNLFNASLLGVPSLCTLGQSLGWK
->ERR1719433_1034072
-PSYRVFVGLFTLKKRLCWFVYIEKMAVNDHPFILTSIYVAYLFLMNLGTMVGNACFGCKWWLDVILLKGDQAKNHSCTDAALFNHTQHSYTYTLGFVVFVCGLAHSWVDGDMETDAIYGPPAQDVATALGVWFLLLAVVNFYTMLGCSAGCGDIKCSEDFEFFNILVNLCFDLLLAIWLLLYSNASWSDEGEPPLYDWRVTKVVVWVGYVILVLCIIGDWIVQSVRKNIMGCGACGMKCCDDESQEVVGVGVNQEEVMPMSPNAQGMQGGMQGGGQGQVMVSGNNFDTQMVDMQQPQYGHVNYNQQYGGQPVTYGHQQYGPSGQSLMX
->SRR6516225_9276130
-SAPRGTRRFGFESQAMIVNFPRKNIRHDIKTTALGLLPAIKTTRDIVEEIREVLKQVLAAIHNEQRRRRLRFQVFPRLMTKAQAANYCGVCVESFAVNCPVEPIRIRSGEKSVRWDTHDLNEWIESKKQDLIGSNGVDWLKRVGX
->SRR5215831_4168361
-TDRRRGDRGFDRRAGGQVDPVPRRRAWQGPVPAAGYRRRVRAVQAAGRGRRTGAAAPAPRLVCGAGGAAGGLRARPGSMAHRPGRRSREPSRRLGVLPVGPAGGGRGGEDGVRPVAVLGNPRASHRGPPHPDRAAGQAGPGRRGAAPGPVGRRLPGAVSRRHPAARALLEAGLSAARTAGDIGAEAWASSFLGWDLYYFGDTKAGDALAQTALKLHRESGDQVGVVYALAQIGFTRLCAGEALAAADAWGECARVCESSGNVWFHAYAQWGLGVAALLRADYDSAAGLECAALRTMRHMDDPMGVV
->SRR2546428_4767028
-GRTVRAIGAGGEQKVEPLGDRGWMGDPRPQPARAEEVPQRDFAAHPVAVGVDVRREGDAPARLQDARDRLRGPGALGGNADAICGHDNNISAAGAASRLASSAQACQLPLQHAVLAAVAEVNPEPDYQPYEQPDPRVHGEKTNITKTGGLPQQRPHGDD
->ERR1740121_3388036
-PEPPQMAPPRDSKPTGTAWPQGNSLQSLAGVLAQIDRAVWDFDISQDELQAKFYEALEARKRCTEIVVEGELPEEEWDWRPGEDDGAVLALPPPPLAPPAKRARPSLPDLNLPVQEYGNVQEVPKHEKGPRLELILEEVVRMLKEAGGRMKLQDLGTRRLMELRKGACGNLAKFLYTQPETVFVDDSTNV
->SRR5579859_1509829
-SCQPEVEVREHSTRNSLPLRARLSLQARVFLFALRARAGITCCVFYPGETIRLLHALPDSGLPQFAEGRVLSLRRDEHNQIIDVEVDFHRDSHTLKAELPLGDVELVISDSSLAQTAVFWGLDEPPRKVIEAAMHSLLDSGFLMRDGLNLVQLHYDRENRWWKWGEKLMDPTGALVATAAAAWDGFVVAFSGQQRFHLEFRQQRLREAVRMLHERHEVYLEQARTTHPAMSLMRVLLNLSNAAGARYCAFPVATPWIYDQDFASVLRPPLYPDFLLVPEKELPRSISTPFRLIRLTGQRSILTVLPVKSSPTETGFERSERELQVDRLRKCKALGEKYYDQMYEARFGTSGLYADAKDAFRDAIAAANELGLKEEAAELEKRLDHIKAVYRSQFSX
->SRR5256885_8719643
-RKKEKGPAPWGARASPSPELLRGCGSGAAFFVRVFRGIAGGLAVGLTLRLVGFQLVFVRLDGVFVAGLAIGFDLVLVLLDLLLVGLHGVLRGGLRERGPAERQESGKDESRQQFHTSSCGVGLPASFNARTLNPDDTQTGPAFPRTIDDAMTRQSAIAAAQKYFDAGGFHADLARRVAIPTESQNPERQAELERYLETEMAESLAKLGLQSRIFPNPRGKGGPFLVAELLEDPKRPTVLLYGHGDVIRGQENEWRPGLGPWTLRQEGDRIYGRGTADNKGQHTINLAAIETVLRTRGRLGFNLKVLIETGEGMGSPGLKEFCEQNKALLRADVLISSDGPRLQPQRPTIYLGTRGALNFHLTVELRKGAHHSGNWGGLLANPGIVLAHAIASITDARGAIRAPEWRRGRRX
->SRR5258706_15926144
-GFGAGGRAGLGAGGPPARRFGAGGGGAGGAGGRGGAGAERNDRRERGAQVLEPPRQVVENREDRTSHSASSMPSGRHHCHTAQRDNGSPFIVGLIVVHCGEHGGELEQLPFKTPPRX
->SRR3972149_2856803
-TVYNAVRQGAMPRMTDERVKQLQDEILKMPQAEGSVRHIFMPGIYMRELTIPAGVVSVGHNHRYNHISMLTKGRITVLNNDGSLTELVAPFTMISSPGKKCAYSHDEVVWVNIHAAPCTDVETMEQLLYDWSDAPDRIKELPDNTSSDDYQQMLIEWGLTEDDVQAETQVDNVAPMPYGIHKCKVSDSKLHGKGVFATANISDGELIAPVFMDGLRTPIGRYMNHSGNPNAVVIKAPNGDNYLMATRNIQGCMGGNDGEEITTNYRETLRLLGGAGWSGRRDPSRAARASREACRSCPRPISPVP
->ERR1719162_375500
-LMAGALSQPSHVDPLPGWDFICNGYVPGNLPGREGLGTTSPQWLGEVGCMRACENQGRCDFVTYDTFNGNCWMEIIPDRPTECDSNTGGWAYWRNSQPAPAPSPAPVPSHVDPLPGWDFICNGYLAGNIPGRQGLGAASTQWLGEVGCMRACENQGRCDFVTYDNLNGNCWMEIIPDRPNECDSNTGGWAYWRNSQDEVRRRSTTQQNDVRRRSTTQQNDVRRRSTTQ
->SRR6266849_10918975
-VQMLGPQAASQALAVLEAGREEPLGLVDHLFSPIRTKAASIVPSALSRCSSMGLSGWHPGAPSPARCGARRAAPGASARGSYAERTTPSAHPDRLPVVQSPPLEEVAGIRGRPALRDQTGGPGFQGEDAPHPLVLRGLDMDVRDRDEDLVQDARPLKRREDHCPALTVQVAHVELVEESLVRADEPARLDPLLAGEEERDALSLTPFRAKTARAGVRRDDDR
->ERR1711972_1082418
-RSKGRAMPCCYMEDGAHQHHRKRCLGRQDLAPNRAKLTTLAPLASWPSWPLPFLFRISGRPLSKLGSFWAAPEQALGGSAFDLAWEPSESAPRSPLRQRPAQLIMLGTLKPNLSRHVPPGADAPNTLMPTKASAHSPQPIVTAASTLILGTLFGKSASLQLSGCARKSSQHGMDTTRTFWRISLAASTQRCTSEPVATRMSSGSSHSTTAX
->SRR5512136_1229453
-DTPEAEKAKNRVTRPHYTAHGYARSFFCQSTHMYLQTLSLENFRNYKKGIIEFSPYGAFFEGENGSGKTNLIESIHLLCTGRSQRNAQKKEMVNFNASYASVRGVFVSRD
->SRR5712692_9023375
-TLGIERIECNAQDARRRDACGKCKVWLCEAAQLAMLTKLGKYEIQGELGRGAMGIVYRAEDPRLGRPVALKTTTAEVAGNPNLLKRFHREAQAAAKLTHPNIVTIYEIDEANGVPFIAMEFLEGESLQKIIADRANIPILRKVHILIDTCKGLDYAHQHGIVHRDVKPGNIVVLNNGQVKIVDFGIARVGVSSMTRTGVVLGTVMYMSPEQVQGQTVDARSDVFSLGVVLYELLTYQAPFRGDDVPSIFFKIINEPPEAITKYIPQCPALLEQIVQRALATDREERYQSAEDMGFDLQRIGDSLKRDTIDVFLQQGQRSLRQGDFTIAKESLQKVLEIDSSHQLAKSLLAQVREQIQSRQRAQKVDHNLGQAKEALQAEQYEDALSLFEEVLRLDPGNEEAKQCKQLAVERRDRSEKVRRHLERAEKLAAEADFQRAKAELEAVLTIEPGNAAALEMIDWVVKELTEQERLRQVRQYLEGARAHLAGKNFVKALETLERAREIDPINIEVEALTRLVRSSQEKEERRKVLVTRVAEIEEALSKGKLDLALACVEQALREFTDDAQVLRLHEQVLRRTEVDKKRRYVEEQLQAARDFVQKNQYSSALAVLERAIQAVPDDPRLGPFLKTVQESQEQSVLEASRRDAVREANEQIRAQNFLAAIETLEKSLVRAGQSPELIDLLQFARERYAEQQQQERVRQALARAHSHLRDEQHEEAIRVLARAQDELKSSEIDALLAAAREQQEAFERRREEVIASALKLLQSGEAARAVALFETAPKVYFTQEEFQRVYSQCRQSLDRANFVHSAVEQAEKSLAEEDIGSAHSVLEQALKPYPGEPALLALQKRLREEEFRLRREERVKLLEEAQVAVGRMEYGRAAELLTSVTWESRDLPELAVQAELLLEEAQRRERERQVLSRAQGYLRNEQYVEAEQFLLGIRNELKTGEIDALLATVRKEREAFERRREEIIAIALQFLQSGEAAKAVAIFEGAPKVFFKNENFQRVYSQCRQNLDRANFVHAAAEQIKKCLAEEDISAAESLLEQALKPYPSEPALLALQKQLREEEFRLRREERTKLLEEAQVAVGRMEYGRAAELLTSVTWESRDLPELAVQAKLLLEEAQRRERERQVLSRAQGYLRNEQYVEAEQFLLGIRNELKTGEIDALLATVRKGREAFERRREEIMAIALQFLQSGEAAKAVAIFEGAPKVFFKNENFQRVYSQCRQNLDRANFVHAAAEQIKKCLAEEDISAAESLLEQALKPYPSEPALLALQKQLREEEFRLRREERTKLLEEAQVAVGRMEYGRAAELLTSVTWESRDLPELAVQAKLLLEEAQRRERERQVLSRAQGYLRNEQYVEAEQFLLGIRNELKTGEIDALLATVRKGREAFERRREEIMAIALQFLQSGEAAKAVAI
->ERR1719240_1252999
-IRDTTRGVSDFDYCLCGEAGAKFLVWLHDCTNKLINFEDRDHFDYEHEVWFRPPNATCASPKVKLCAESARCTLCVDPVADDHTFLVQLFGISQLIKCVGPREYAPRLPVVYEAEQNERRSLX
->SRR6266511_3081427
-SAPMTVTPTRIFLRYGLIVSVCCGRCLYSLSPRVASETSGADHQVVRITSLAVAVAFMLIGPLLSSAAQEDVLATLRKGHPRLLVLDDDIARIKKQIETDPTARKYFEHLKIAAEKVIQQPVTERVLVGPRMLGASRAVLARVTLCAGLYRLT
->SRR6185312_7578494
-SSDLCVHGHEAGSGDRAGGGRGSRQALLRTARLAPGRGDLPPDARDIPGPRPGSGATKLRLVRHLQGPGRQRLVGPRGPAALAGTVKGPTTMGATSTEPTSAELIRDLLEQAAAAHGMHEREIGRPDPDWPRWYAEHMARALRAGGYEVHPSHGDGGTTLPVGSRRPELAGQTVVVIGGSSGIGLETARRARAEGAELIIAGRNPERLRTAAQEIGAQGSRAFDATHPASLDRFFQELPAHIDHLMLTGGGPSYGRLVDMDLADLRRGLDEHILLILQVARRAATKLRPGGTLLFMAGTGARRPHLGLGIVPTVTAALPALAASLAIELAPVRVNSIAAGFVDTPLSASLLGEDLERRRDQLRATLPIHH
->ERR671919_521420
-XMRGRGPGEASRRAAPRPFFPLPPRAAGRRGEGSCLSLCFEHSGGERILGRFARPQHELEGLIIALASLERSPKQRLALAGMGVGAGEQEPVAIEQKPVLAPQIEMAKPELLVDQRHQLIDFREPPLRDLEIESASEMQRLQIVAPVQRDVIVAPGARDGQREFVRGGALEAPGMNGGDVLDHIHWVGEMVVDRQCRSHTSPLWPRQSFAFPSCPSANHFVNQLYIGESRSTNAGRDPKTGFAKDSCGLRARPKPLEARATPQANDARTVKTFGASRSPGPAQESLRLLGEALDDGGLERRDPLLQGLVFLARFLRHRLDGLELLAL
->SRR3990172_7588517
-RRCGNARSPARRVVVRGSVKPERPAMSIVRSSFLAALTLVSLTACSGTTAPTGEAARQGVVVEVTPESVSVSSGVAAAFDASVTGAADTSVRWSVLEGSPSGGSVSAAGLYTAPGTPGTYHVVATSSADATKSATATVRVAAGYGGGAGAGGEGGGEGACRDEKLRAAG
->SRR5439155_1739346
-QASVPVESARTGLVSSSLKCSDNVAGSKRARRTARAHRCGTVAGRVPTAWLSQSARSTSREPAHLHPQTARASASGDRRDRPGQCRGRQVVRRGGGLRALLPRRTRRPRHRAPCLGAPALGLCARCPGGDGPRSGTDGLCRLPKPRSARPDADDQLGEGDHSVGEIAPARTDRELAKLRGSARTERELSLLRGAIDADVTELRTRISRDVDPRRLARRQPVAFFGTLGSVIAVLGFAVASRVKSFRRSRTETELDQVIQRLGGRLDRLKGRTRKRFRESLRKEIGEVESGPRAKQMFWETATAALVSAATLLARSIASRTVGIAPATAAPTTNAKRLMSTSGRAPGAATSNSGNEITTVAVMSAPADSSRAPRRRAMRGPTSAEGENARIVTAGSSTX
->SRR6185312_8989730
-QIDAVAGFHRGIDNQNPYSADENVPYVYYNYERSLYDFADLEGTSQIAKCQDGGPNDPYPMIRNCPVTAYGEQGLGYLERDTKDRTSLVASITQRVKAAGYHVIKAGVDAEFETFDINKNYTGGVVWRHDAPSVATGANGRWNQREFLKVVRNLTPAEIADPTSVQLDMGQLLCAGDRAICAVASSITANTTDSNYGAYLQDSWQLRPNFTINAGLRYEDQIGYAASQLAGQETPVGEKVPSQVFNLNDLWAPRLGFIYD
->SRR5258707_393308
-GLNSGQPSLDAQNVGATAARAVHAIADRAEVVAEHEPRIARRKGVNVAEHPRFPLAEDPQVTGITGGHPQPGRHVHAMLSAGAHYGVELNHVEAVPDPAAPVELKDADQQLDQFLTWHGLTGRALPAARGNDQSAVRTEIDAAVLLLHPRGELQDKHRRPDQDRLDALLPIEEPLDQLIGEEPSVPYVEFRRVDEVDDAEHIGEPEVGGLNGVGPEDIEAGRPLRVKVEDLQGGGDAAEKPLERPAVAVDHAPAALGPAARAAPELAVERPGHQVASLEDRG
->SRR5213594_1844093
-NPGSVCSRIHRHVMMACFNSRLLLHESQKRSPTPRVSRSPRYSTTQQLATDHFRATGHSIPYQRPFLAQNRSCRPASQPGLGLRQDQSTIQYTFAIQQPRPQHLPRGLAQRIFSQPPRLSTSRLPLPHGSPRRSAKNALLSVTSPQSAKPRKWPPDTCGIAFEKLILKAKHADPIPYCQLGKMDVVKASNKNKALTDFRSEPQWPVRTPTPPLRLGVCRGRRRYKRPDSHPIRGRVDRRPASDRYRPVAIDWRACVAX
->SRR5947209_20053041
-NACENYSIICCYSDGYSVAGQLISTRSLPVCCFFFFNDTATTEIYTLSLHDALPICQRTIRLVSWPQVNHFALPPLFRGSEKGRSEEHTSELQSRQYLVCRLLLEKKKKDDAKRKKIHHVVILDSKERSTEWX
->SRR5436190_7157327
-PSLNPAPESLPSSRIVDLMLSVHKDLVPVSETGKQRFRSQFYSGRDLDDVLERVQRAGVFKREARIAGGLIRPTLADAARLNEERRAAIATALERTSEGLGAILDEAASVFRLPGRIDLRIVIVPGDGPCRFFVGAESLALSAPPGPGDAILLRAAIAIAVGCQNDMIGPMPRGIVATPCDSFLLAAIALQLAARGWVTSYGADVLESAAQRETFATEDDDAALQLCRLAVAVRPMFDDVYVRKTSFADALVAARHVWRGLYAIQYVHGAPGEIPEGW
->ERR1700739_2321498
-XMRAVMDRTAPKRFAHSNRPARTVAGPPRHRKAVAGGRGSRIRTCDLQYPKLPRYQAAPYPAGSRHWIAFSPAPSKRRGQSMRFAENRAADTVACLDTEAAGDAGIDFEDRADREYGRDEVIGHRLGIFGDAYDPPVA
->SRR5579862_6422017
-TRLYREAAAGCRPARREFLSSPCQRSEYGPAPSVALPPAKPGGRSEAQPSVQSQCISCLFLLNPLHHYVFTLFTWAMQRIGWGNCLAARWTRSFFASQGVPSLPGSSAAQFPLRPDRRLGKSITGQL
->SRR5258706_10244772
-EDAVARVVGALEEDFADDALPALLEAVGDLDLVFLAVEAQFGFEELPRGRPQRRVRDVPALSVVLPQRPFVGVLRRALVALAGREPADLQELRLREEEIDGLLDRFLVRAGRIGLRLEGSDGEFGNPVRLALVDDDVDHHVAAIRRELQRVELDDGVEEALVAVDLAHREDVGLERVLDEPLALPVEEPWAVELDAGELPQSPLPEPGPGLGKRVIPADLH
->ERR1719491_1280783
-VRDVLGRPSSLLLDCGHGPLLTAACAVRPFAPVQTVEGAGACTGARCEDPSHCRSKWGWCNAGGSYCNKDSTWTSACDGSATTTEAATTTQEHDATTSTFLPRGACTGARCEDRSHCRLKWGWCNAGGNHCNKDSIWTSACDGSATTTQAATTTKQSDATTTMRAATTATTTRVATTTATKPMLADLAPCTYSKTFTHAGWPVQQDSTDVAQMVDRCQGQHFVNNVDAATCVINSNADGYDYDKWTPQTACPYPLGQSPDVSQAQCQAEFTRWKSMGVRMVSLAGGVEAMTGIGHGVFNGVRGECALMEFQGRYAVIMQVDIRSWSMEFTEQTLNHLTNNVNPGGHCFVPNVKVIDCATVRAX
->SRR4029453_3979317
-AVGLDPETTVQEFLDEMKQSENEAARVASTPSEVTPEDRAFLERQKRAIRLLQIAGVLVVVAAGTGAALAYMKWKKSAPADAPAAAVAPPSSPSPPTNSPAPPPGPPRPPGAGVSAPAPKSSTTTPASPPPAAGTSQSPPVTVVPPEAPAPVPVPPAPAEPLTIEFEGTSACFV
->SRR5437868_9650668
-PNSHYSTHIIDILSLLPLYLYMQLLYFLSFFFNAPPTPDISTLSLHDALPISHLRSPETRRHRWRGRCLSPRLAGQLGKGSDHADRKSTRLNSSHVSISYAVFCLKKKKTLNHRKYLAYDYPSLINLSRIIRTLL
->SRR3989339_1542112
-WHFLFFMDLFLIHCKSIFLKNKIERYLRVPYDFMHTGLFLCYTITMTNELGTLYVVATPIGNMEDITLRALRVLKEVDVILCEDTRTTKNLLNKYDIHTKTLSYNAHSSDNKHSNIIEMLREGKNLAMVSDAGTPCISDPGVLLVAYVREEFGKEAKVVPIPGASALVSALSASGISSAEFIFIGFLPHKKGRETLFKEMATTNRTIVFYESTHRILKTLASLDTFCKNHRVMIAREITKQFEEFVKGTPAEVLEYFTVNTDKQRGEFVVIVDPKX
->SRR5438552_9638688
-LFRLVPVAFAVGAVPLGPPPPAGMAGRDFRLDGLQMELAWIPPGTFVMGNAEGDEDERVTTRVTISRGFWLGKDEVTQGQWDQVTGDDPSGYRDAGPTVPVENVTWYEAMAFCHRLTESEGVAGGRLPPGYEFRLPTEAEWEYACRAGGPGARSTATALDEIAWYGGNSHGRTHPVGQKK
->SRR5580693_6454278
-RTLTKLCYILFVWNVDSALFSQKLLLSGQCLNRADQSPGNRNGQKATKVFGQTENMKTLKARVLSVLSFQPFRRGNKSDGQSKDTIIKFWRMRCSYPGPETPYECELREPLENFASKKYTVGLNGFVEFELLSKPNVAAGDSIQIDAYEPEEKILEGGNGEHNPRAGAIDDC
->A0A1H1AGA9_9GAMM
-MATSKPHRLSSCIALALHCARAGIIGGLGCAAAFSAYAGCDSTAPVSGQTVTCDANVPNPQTTGVQAVAGSTGVTVNIVDGATLQIAAGPGVQVRDQSQVNNDGSINLSAADTFDAIFAEGSGNTVVNTGAIATAGGASDGIQSNGSNNTLTNGVGGSIVTTGANANGMLSLNGSGNALANNGTITVSGAGSSGIRIDGAAGGTNTVVNDGSIASQAGIGVLFNGSAGSTLINRGTISGATGGVTSGTGNDRLEMLGGSISGAVAQGAGDDTLIISAGQLSAVNQGDGADRFEISGTGSVTGTVQQGSGIDTFLMSGGQLGALLQGDNLDTFTMSGGRIVGAFEDGDRATMTGGRIGRVDMKLDDNVFDMSGGTIDGNLVTGFGNDTIRLSNGYIGGNISVSGGNDSITVTGGTVRGEVRVSAGDDTFEWAGGGVIYGAIDLGEGTDTATLRNLNQSHLGATPSLSGGNGVDSLSFANVTSGGVARFGNWETINAGNDTELTFDGNLVLGDAASGTGVLNVDASSTLFAGNGASASLMAFGAGQLATVNNAGRIDLTNGAASATDTFTIVGNYVGNNAALFLQTQLGDDSSPSDRLVISGGVASGTTGLEIINLNGSGGSTLLDGIMVIQAINGASSSNSAFALMGPVAAGAFEYFLFKGGVSGGTSENWYLRSTLVAPPASPPPTPAPAPDPLEPTPPPVPPTPPEPPAPPPPTLPPPPPPEVPDNPDPEVPPAPPPAPPTAPPPAEPPAPPPPLPPVPEDPAPLPTPSPEPPPVLPTPPTPGATPATGTVIPLYRVETPTYAVVPPIVHQLGLATLGTFHERQGEQALLDSEGALRSAWGRVIGQNTEQSWTGTVAPTFDGSLWGVQAGVELFAREGDDGRRDHFGLFVGRTRADGDVRGFALGWNNLTVGQTRLDDTHLGLSWTRIGTSGAYLDAVIVASRYDGEATSSRGIGIDLEGDGVTVSLEVGYPTRWGEDSRWSLEPQAQLVWQHVSLDRQQDDFASVDFDSDDALTGRIGLRLSADYSTSAGLLQPYLKLNYLRGFSGEDRLHFNTDIVETDQQFDAVELGAGLVVQFNANISAYVVLDYTTDADDADRERKTVEGNVGLRITW
->SRR6266849_3749832
-XMGRGKSYLEESHELQEGTVWTSVQGNGRSGCEDGHDGGRGAGVADCGRRRSGDCYAKLARIREAGETNGDNTRQILLQHQGADAGGAGASQAIERKTDGGAEADRGVGERVRIPVWPGGRIAGGIGGLGGGGEQVLPVFX
->NGEPerStandDraft_8_1074529.scaffolds.fasta_scaffold152358_1
-MAGSTAMARRLSPCPALPATARTAAGPGPGGGSGRCAGPGRHLGVPAPELGELVLRAQIHELRGEVDHAQGGDVRHAERLSGDEAGGRELVVQTAVESPGRTLPLLLRRGNLLAVRQQPGHHRAVDPRLAHGAEQLELELPVGHVHQADRHRVGAEQGRFRVERLEITADGHGFGDAGAVVELQHRHLAAGIAAQKLRRAVLAAPHVHLDGGHLDPLLGEEHPHPPRVGRRGHVVELQIRLPGCRX
->ERR1711990_8348
-FQLVSPGTNDVNRVCIDIDPQVVIVPHHYHVHPEGHPRDTGGPPSLPSRQESPCPVRVAAEAVVQEVQVSLSSHHQEVSSAPLHGDGDVCTVALPPAPHIHHPGLHVQFPLESQQYKYGGRVLQLFIFLCNQFDL
->SRR6185503_5987732
-GQPRAVRAHAQRAEREELAPAGERVAVEQHLLAVEGSAVRGYRRRGLVRADGTPALDAVLLALLGAGVVPVALLAHRQREVGLLGARLDLGEERLAQGGQVPRGGVGVRVLGLEVLGRRRVFLVPEPGVLVDHGVDVDRPFGRDGLGYLRLLSRHVDDVTIRSSWNTRSRDCENPEGLRKYLSGHCQ
->ERR1700694_3206782
-KRQRAMENLFTGADQPRKLRRQPLSGLRKWTRNYIPYLEVLEDRNLLSAGTKGFGAQIRDPGFEMPAAGTGNILYDPPTSPWTFNGSAGLAGINSGFTAGNPAAPQGPQVAFLQGVGSLGQTTTFAAGTYNVSLSAAQRGNGLASSQTFQMLVDGTVV
->Q19Z88_9CAUD
-MTLDALASLPGVAVIQLPEPTEAVTMQDCAGSGKPFKPGTLSRDGEVAKCSACRTNRYVRDDGSMWAPSGARCCGCGYRGESMILSHVRTELERSRNHRFYDRPVNKNVQAMYVWWEYMDEIDLVNGENDTMRITLTEEEVHPPPGDLFHEKPKVIRAIQTWTKISLEYQINGAYVDLRTLSAAESIRDDRWIPLEQYQIQRYCIQGRIRPGGNGYEPYRIVILAGEVSPPGVWYPWPGQPEGVPNEVLDGTYHGMFMADK
->SRR5690554_76201
-XMRAYLSRFVLFGGFIMEIIQNIAVAIDNLRISKGLTVSELCLDICDESSYRRYKSGNRDIPIAKIKQFCDKLGIGLDEFLYNVSVKNSYEYKKIHKMFLDLQSKKYDEIRKSLPLIKVDDIGIDRNKVLFKFILYTYQYETKKITSSNYYELLLKLLPEQSGFYTFNDLIIFEKLALLEVNQNESPSLKILLDILLNTEKLYVTNTNQYVLATTYANVANYLTKRKEYEEALKICNKGLEYSKSFYVTKNIHYLYYLKAYCLFHTEDKEGATFNLSIVISWVFAIQDEYMSNYFINLIMKEFNMTKSMIYQMHQKVLANYLX
->SRR6185369_2141686
-SSDLRAGVEVRQRRQRRLRDAREVRRQALAVRRDAALLLLRRFPLLDGGVERRLGAGRDLRLLDLRRLLDLVLLLLGFLDLLRRRRLGRVLVLRRGRLVLIALGDGLARRRAAAHRRRSEQQRQPISVELLHYFISSCWTGVLSMTMS
->SRR5262249_26280313
-MGRLQTPFQSKEDCMDDAEAKVIELIFGSWRSQLLYGGVQLGVFDALRRGPVSADQVARELQVDARLLYRLMRALGSLELVHEDPHQHFTLTPLGEVLCRDHPQTLRGLTLLEAGPEHSAAWMQLPELITTGQQDAFGREVGQPVYAYADQDPSYAAVLDEGLNTYALLDNPLVLEALAAYDFAGIAHLCDVGGGHGLTLCSLLVQHPHLRGTVLERPHVLAQPDAFWADKLGVSDRCTYVVGDMFHAVPPADAYLLKRMLRHWNDVEGGQLLATLARAAPAQGRVFIIEQIVPGPDTPHFAKLFDLHMLILLTGRERTLEEYTRLLAGAGWTYRQTWYPASKQLGVVEAVKASDFNVLGSEQSEINGFEHHRLFHRLRNPCLIIHRASYFRSCFAEREEILVDLILVRRAHAVRRALVDRALGQFIRLHGKAVAQRGMPHANRSSIFTGSSRTRMPVACX
->SRR5882757_3079952
-DAVEDGVAGHFQGAFQADVAEALVLEVLEDLVADGHRRGAGVLAVDVVPGVDRRGGGHHLEGGARGGDAAHPLVGVVGGGAGHRDDLAGVVVHHHGRAGVGLVVLVGDRVVGLAGVLHGRVELLFGDRLDLGVDAGDQVVAGGGRGVALLADHPAQVVDLVVGDAGLAAQLGVVRALQAGAADLVRAQQRVVAALRGGQLGVGDRGEVAEHLRGVGVVRRRVAAYGGGLGGDAREVLAALHDLQRLLGGGLVGDRDRLVGRAVPAGLRGLRVAQPHLVQHVLRLHAEHVGQLRQYGLAVVALLEQVGPVGGDHQPGLVVGERHPAVVQYRAAHRGRDDLLDLVARGFLVVLLAVADLQVPQPAAEGEQQGQGEDLQDDQPDGDPRGPAGLRDVTHLATRSPGRRIDLSHLACAPEQAALGGQAGSGGTHAGAVQASGPGTRAGAAAGAAQTAEAATEAAEAPAETAGRVLGQRVVV
->SRR3972149_160959
-LVNCWPVFPSFFFWWWSLRLYGSSGDKIRMRCEALLAAILLLAAIPIPTATALQNTALYAPTGDVQAADSFAVNGCTYAARHTCVDEIPPGPNDGDTTRLQSNVTQDESQIDLTAYWQLDPEDSVVGMRIHFFVKTLTGSWPIGTTLMIFIQENIGGGRICYFETFSPPTSTGSYRRFSYPAGYDETCINSDVNTWEILVVLDCDTPPNCSNWLRITSIYLEILYFDRFGFPSSPENFAWIIYAILIGSGCLIAAWRIKKWRETIX
->SRR5262249_38322783
-GLRGRGDGRMSAAVRRVLCTVLLSGLFVTVTAAQDAKMPVPAERKKALLEGTHVFRRILYDNDCTSLKNFKELVDEPSKSILIVFGDLDRIADVPGGLANFVKDGGAVLLASDRPLVDRDARAQLLAVAGVSINVETVFMNPAGGQLYRGWPYCPFPDPAAGASPALFSGDSREGGGTLSVATNVPTHLVVHGRPRGINVLARLPANCQYDVTEAERQRGFWVGRFPHDRTFLVGGDVGDGRILVAADHSVFINEMMLPDDTNNVEFSINCIRYLRGGEQRSRV
->ERR1700745_413936
-KTENVRIPKTLLLFVYYRTRPLPHLSGVRFAMAKLCTPCRRVDVALLDALDGSLHLDLITFSCNHYRPCPPHFPGPSHRVKSAGCLRLLLWRGLSPCIPVRRSRARSGSFFLARYDRLSRYALFGSPLSSERDNEYAFCPGDVVLRPRRGMAIATLPTWNRCRVGLTGLSRAGLSSSPAV
->SRR3954463_761953
-GPALLDEQELAARMAVPGRARTGFETPAARDGARCVERRSLPGKPRRFRVGGGLLGAHPRGRSAKQHEERAGNLYSLHGSDTTPAKLVRLKPEATNRDRSRTLRQMNRRTFLKSSGMAMVSGLAQRGAAPMERTIQTPVLSIGFEESGSPSGFPIVLLHGFPDDVR
->SRR6266566_9387372
-APAVSCGQEKFLAAPAQPEGLVVQPLNNCIVFRAVIKPSGVEVNDMVSRDPCHLLENGIDKEYVITIVSNHNAFVQRLQNALHLFQPVRLYNIHDVFHFVHSATCVSCQNGHLAASLSDPARHKCVRRDRGSVPTCTSSSSLSRETRRX
->SRR6516225_4656599
-RAVRADLSQRACHENATHVCPTCSNRRAARVPKAPCGMGYGNGRTPSCPLQRRSRKPRCPSRRARRARSSGRGLLSGRLDGGLPPCNLPAGDEAIGDGKNVVKYIDAFNHFFPRRFFAGVLETPAARKDMGKRIRGIPALWDLEVRLGIVDSFPDYSQILSLAMPAIDRLWDAEHAPEWARIGNDELARARCQVSAAFSGLCGIASDERAAGRDSGSGTGPAQRRQCDPA
->SRR3954451_7163765
-RQCFDQLLFLAGVADGAPSGIDARRQSGVRDDATIPDASDEVVLTDDTFPVPDQIVQKVEYLRGDSNRVGSLPQLPPFRIQHEIRKGVKQMHPPVVRSQCKQTVRRMEGACKALLMTLAHPRARLSSMNCLRIPRHEGEYHEADGCTDVGCHCSEALDLGRMRSRLCEPRSRSMLAAX
->SRR5262249_15769881
-VVDANFNPVAGGDDGDKVTITTSLSSKVLLSPIAPGLSLTTVLSNQSGMRLLGFPDVIFGYAQAPFADVLLNAYDQVFRDWPIDVKDKRTVGTSSMCTEASFTVTATVRATPAPGLSSHDSVLSAAGTLGAQAPPCP
->ERR1719265_1088395
-SVLPTSHVRFGDRRNIRPLQGAKIVYRAFDPVAGWSPLLVNNHHSVLVHGGANAVPQSWPRVLPHPYHDGPEDLGIARGSGAHNDHHVAGGNAVPPTHASLDADLPDDIQLPHPRGVGTGNLEILRRRRREVHECDESRNGAHHQRKPFARTIASASLLHLATPRARQLPDLEATQPWLVDDGLSAGX
->SRR5680860_510741
-GSGAAGGARPRYGAGRPRCRGGRRGGPARAGRPGRCAAAGGDPVVTPVKVWPYVVGAAACALLQVAVTLGFAATVTMSGDISSASPSEPAPPLPLPGLPTPGPPPSEPSEPPSGAYAEPRDDRPVVRLRFDVADDLTTVAGSETVVFTPDLRVCELVFRLWPNKPETALAGNELSVTSASVDGASVTPVVEAAGAPSGTTGTLVELPVEGCAEPGEQVTAELEFALVLGEDTPERVGWSAEESMAWFATAFPLLAWEHGVGWMRNPAVGLAGETVASETFRLESLEVVALEGLEVMGTGASRGETDVGSSGRVAHVFSADAVRDVAVVVGELEVSTTEVDGTAVHVAVPVAGSVAGVDLWESASVESLGLVSGYLGPYPYTDLWVTVVPDFPTGVEFPGAIFYGDVDPAVFVQLVPHETAHMWLYGLVGNHQGRDPWLDEGITSFVEAHVLGVSEFLVDQPVPPPADGYLGASMPFWAELDPSGDLYGAGVYGAGASVLASARAVADPAAFDASLRAYVSAQAYQIATPEDVREAFGSVPEALAVLEDAGAFAGDAGDPX
->SRR6266849_1400336
-VRTCSTNSGVSDGSNRSLQAPNDLDSEMRIVNDRDLRVVIEHHLQQSCARPGTADDKQIGVSNRTVFAPAFVPDHDFSEPYSLRVYARFTCASNRTCPANLFRLSRATDPAEEKPPTSRPLAEGDSAGAIPQRNQVAGTPHRPQSRAARHLFGRGIVSFGIVDASPARFADHGHGAPNEDX
->SRR6185503_8510077
-LVEAMRGSIAVDSTPGRGTTFSVDLDLSIDASAERPLQSARTVIGYAGTRVSIVIADDDAVSRGLVADFLAGLGFEVRRAPDGAAALEQLRNAATDLLITDLVMPRVDGIELIRAVRSGLSARAPRILAVSASASDYTSHEALDAGCDAFLPKPLHLGDLLDRMTELLHIDWQYQDTPAAVGQRSAASSTFALQRELADELYHLAMQGDIAGLVERANARLSDDPSACGFCDELRALASEYDTGGIRRMLSAHSPA
->SRR4029434_6363074
-SRCAAVGSNTARFGGRESPGNGAIVNGTAFGVSGWALDAEDATLTVQLLVDGAVVSSSPTRSARPDVCAAFPSVSHCGSSQPGVTFAWNTTAVADGPRTIAPRATGPAGLPATSATRTEMRRAHA
->SRR4051812_49403107
-HVVRHGGIAKAAAAGCGDLSSLSKLMKGLEEELCTELFKRNPFRLLSHGRIYFAALERAREVRDAAMDQIWTETRPTLQLISAEVVTLCYFPGITRELERKHPNLQCSTESGGEEQIQRMLRDGDVNLAIAPEHEGWRGFQRAPLLELRPVLICPEKMPFRSAKEIWALPEP
->B4ND15_DROWI
-MAKKGAVQQLQADLQNDEDFARFLERPGLLVLDVYSDWCGPCLGMVGSLRRVKLEYGGDNLQLAICKSDTITDLKRFNKRSEPTWLFVTGGKAVNIMYGTDAPKLLAVVIKELEKTLQKLPRSHVYDIAELQPIEVEQLRVKTEALEKLERIERDAKNKKQNDYLNQVTDAIMENMPDIGVTVFGPQVNRDMFKKLTEPAEPLKMQCKDRKVVQVTAEQFDIVNYACRNPMPPDVLEQLDGKELLMCFWKIDETVGTVPNVLAAYAHELTKERSAPPNEQFFEEHAIPPIISPMKIKFEVELKEGEVWVEDVSSEEEQKPVKGKKQPKLKSPTHQEDATPVPVDEEVGEQDGEEEGSEEDGPEYGADGLPSLPSMPFDIDLDLDLGDDMGEEEEEVKEEEPPKPLTRTKTVKMPAVWVPNNRRTHAALIYMFFRGQTTGFLAPDPKPEPPHIIMAFDATKRREIMHVVERHREEVPLYGYFTNDDPDGTELIANSTDKYDYYPEQLLSDKIVLKVNKVQSNMMLSLVSYGPSYVSPNVTAGHDEALKFFPDDYRQQEEPPADVKQKKVKKGKKGEEIPEKAREKAASLEPQRTTLPADAGAAVSADVQQPGEDIEKETSQTAVQGAEGEAAVPPTTEGEGAPAPEGESVVAEVTHESAPTEAAAEEAPQPGEAVAETSAPPESAPPEVAPEPPKEETPPVEAPPTEAPPPEPTPPEPTPPEAAPTEAPPAEEPPTEAPPPEAPPPDAE
->SRR5690606_34130643
-XGLQHTPTGHRRSNRRRDRTDPLRLGVVERLIDRLARRCAPPDRLPARPERRPFDRHNPRPSQRHHEPLAQRHVITRRLQPSRPQPAIAVATVAAIALTRCALAYSNVLLTASTGVAPPSIASKIARSVAPLIASARDRADALTNPSVSASSX
->ERR1719410_660988
-GSNLVKGVMPIWCGGSSRSRSRGNRQPHRRRSSSRRFSPPRGRGYSPPQRKDPPWRRSISRCRRRSSSRQSSLPRRSDGSRERSCSRKHSPRRPNRARSVSGGRNYSPRRVGGTKPDVPVPVDGEPAEFGKARVLKNPSTGRDETWKAEIDIETGEVNHVGRRRVMSIRGPSRTTKERAEEDARRLEAAVPQGPQAVRAVGNQLQKTKRGALGVLAELPGVHVLATYTDLPPLPALRSSGTCRRPIPCMLPDVKTIMDLRLRMGEVYMKDEAVLLRVATLRVTLGLAPEAAPC
->SRR6266487_7083492
-WREDFARGTEVGVEVGIDRAVSQDRGGRLGAGRVDQRRSGMAIIRYHMVAVIGRDCEAQELIRRWLVADQGPGNLDLNEAAWQLAVGRADQLRSAAVATRRSGGAAVESRWVKITARRRGESCLNHIFPAGSAGYVGADAVRQRVDSAGGVIGIDRDHHLRRWIVRDSTDAIYLDQKIEVVAVAGDAERIQIGLAGDVYGTGDDSLVVEGVIEDELALIGGVEI
->SRR5574344_1391919
-KLKPQHGALIFYVLFAAGAGLELLEEVIALVIHEDECREVFYGNLPDSFHTEFGILNALDALDGALRENSSNTADGAEIESSVLLASLSDTVATVTLGNHHERSAVCLELIHVGIHTVGSGRTHRTARIAFGSLGRSCIENRVILEVVGHTLTGIQASLELGMCDVASHDDSALEVDAGADGILRQFGTHGVDTLVEIDFDPLGTFARIAHFGRDKLCGVVVHLLKPYTVLVDLCLDVAVGRAAYTHTDGTACSVARQTDDTDVVGEILTAKLCSKSNLVSLFEQLLLKVDVAEGTTCLVACGGQX
->ERR1700722_5898992
-VDLGAREHQVGGIERKTGQDAQRLEIGRRGNASQDGEEHQRNGAAKEPHIAAVTPRGAEGARTVVTAPERGPAWIAHGRCKAQCAYPLRGPAECGRESSARGYLNAAPPPNKSPCNYGCDTAVPSLRTCSGMGKNVLTGPAREVEAGPIGQEAETGGGKLGAPLARQHEVKLVLEGVQKQHIGGRIGDLSIGQLGRTPIGXX
->ETNmetMinimDraft_35_1059890.scaffolds.fasta_scaffold1061826_1
-MRSLRIDAGMRGFCGVLALSVLLAGCGGVSDLAGSINPFSREKKLSGERQPVFDGADPATVATARPASVGPASGGQEWPSAGGGLANDPGNQAISVTGARVWRSNIGATGGGLTTDALRASARPVSAGGRIFIYKPNGDVVALSTNGGRQWVKNLRPEGERDVAPGGGVAVSGGRVYAATAYRQVAALDAGSGQVLWTADLSTPARGAPAVGQGHLVVVTQSNEVIALKLEDGSQAWSYQGIEEIGGILSAADPAIAGNQVVVPFSSGEIMSLDIKSGEPQWADGVTRGFRTQALSGLADVSASPVISGDTVYATGVAGRTVAASLKTGTRIWGTDLGSVHTPVVSGNALFMVDLEDRMVALDRKTGETLWSTVLPRPEKKKRRRNWAGPILASGALVAFSSDGRFAAVDAASGQIILTKDVNTKVYVTPIVAGGRVIVLDGDRAVAAFNX
->SRR2546427_1622280
-PAFSRCHEIMVPPIFVTDSPETSAGARKEPASLGAQSRASPTPSPSASVEHASPMPSPFASACVGLGQVGQLSSTSAKPSPSVSRRTREQGDPLGREAPLDWLPRPDSPQRFLDETRX
->SRR4051812_6966754
-SLRPRRPTKEGCSMSLRRRAVTTAFAALAVAGLTAGCASTGSQAADSGGGDVHATPDAAYPKDLGWEPMDNSLTNLACTDNSYANAVKKGIKLGIYSAAPYEYMDNGKPAGLDWDVNMAVLKYLGIKKYTTVTLQWDAMIPALKSNRID
->SRR5262249_18224374
-TLAPLAVLIVASRSPALRLWQRRQVMELTGKQIAVTGATGFLGRYIVDALLKRGARVIGVVRNPDRVPALAQRGVEFRKADLTQRDQLVKGFAGADAVVSNAALFSVRKMFALGSSVWDEHERTNIAGTRNVFEAVTAAGVKRVVHVSSVAVYG
->ERR1719430_1578260
-GWSSPPGGTRGGWSCPPRSSPWSPWWPAGLKWFPGHFVISECLPEILSSSPSVLSYYRSPWDFHRKRRVAIQHLIQDHTQGPPVAPGVVPTLGEHLGGDVVRGTHSGVSQLASSSLPTLSLPLGLRWVGCQVERLSLRIVFVEFCSMSFLESSAKTKVGQLDVSAGIKKDIVRLNIPVYEAKLVYX
->ERR1712156_240685
-LNLMKQAAGKFTFQIFLFKPQSRILKRSLVSLERSNRSPFQKFTVLEGQRGLLLFVLLLKNKEKLPLKDSMVLLLKEESLEFELTKDVLSVLNKTLLIVVVAVADHKNKDLNSQNQLKDVPRFTSGIFRGSLMKRSWNNYFRSLVQSRTHEL
->SRR5581483_5340204
-VRVFVVKQRVAARRVARGLPGVGEARLDVGEFLAMLGRVAAVAVTATQVERLLVVRVVLVLVTREAAGALHGRRLRVLAQQVEDRLADDDRFLAPAWRDPRPAAAQHQANDDRRGHPEQDGKAREKLRLDRHEGRQGTLRAGFGAAHPWRSRCFVAGRVFSVNGKPRPPRRRADRAELACFPRLPNLPSGHYPSCRIPWASCPCTQGETPMFPHLARARSRRRPFSWKPRLEVLEDRRTPSGIAKVQDLGTKADTTMAQSVSINVPAQGVAKGDTILVTVATTEADPTQGVSVTDGAGNLYHRDADVLKSNERLLVFSAPVYHALSGGGSITFTQSGMAGSPTALSATEFSGLLLHDKSAKATGIGTTASSGPTPITSEANELLFGAIAANAFNVNNPPPSTMITAGQAYTGLPQKTVVDSVERTDLKPEFAVVAATGAYTADGTIAANREFLAALTTYRQVPPLSAVAVTATVGPHTKDNRILVLAGNTDPSGGTLSVQSVSHPAHGTASX
->ERR1719323_1321519
-GKCGNLEGVRVLLVLVHGFGVNGLGLLWPRGNRRGRRLRLVILGRRQRRHGGRGGGRAGSPDRGDGRQRGSVVRLLLQLLLLERVVVMVVGRGCLLLRVDVLLLLGVRGRRRRRRRPRPAAHGRGERRGQRRGRDRVGWSRRRVCRGGLRHK
->SRR5690606_29123364
-LEGVPARATIRAEYTKMKQERYTFLTAELAQQVRDLIAFKHRERNLACRNSKDGTYYIAKLKPKVRPNDLLFAIYRRDETAKMAPKVQSLYNMYNVKLNALLDTMGLDAKEDDARRRRITEYSLRRYVKSAISNAX
->SRR6516165_751239
-XMRFSTIIVLLLFASMGWGQAQVNEKLETAFIYVDVNTGSDSNPGTASQPLKTIGAATSKALSNNHQGVGSRVIINPGTYRESISMGKNVRSTSLPMTFEAATSGTVFVSGADVWTGWTPYSGNPSIYTQSWPFQWGLCQTVTGSPNNLEDIVLRREMIIVNGTSLTEVLALTAMRPGTFFPDEANATVYLWPPSGTDMSTATVEVATRPVLFSDQGQSGVVLRGLTFQYANSCREKVAVGFNSASNVLIDKDNFFWNNADGLGMFYSQNFTVQSSVGNHNGEHGLDTAFVKYGVWQSDRASYNNWRGAQGAFYLWDTGKFLYNHNNTFNDHRALFNQGPGVWFDTDAADTTLTGLIAVGNMMNGIFVEKSEGPVTLSNSYVCGNNPQGWAPYGGVGLRNSSSVSLIGNTVFGNGFSQISIVGEAGGILVTNWETGQVYNLQTENLALSQDIVVGGPTAQVFSDGTLGGEDWNVFASTLSSDYNSWWAGPNTQAFTVPSPSFENLDLSGWQNMTAQDTNSSWTSSTSPAACNVQSQGRDYWLVADLIVPVTVSPAGVAAYNLTTMPLGGMTGTVNLSLDGLSGIPGVTASFAPSSVSTSGASVLTLTTSPSTPAGTYPFTVIGTSGSITRTVTIPLVVPTTSVRLSTTSLSFATQTLGTTSSAQAVTLTNTGTLPLAMSGISVNGSFAETDTCGASVAAGASCAISVTFSPQWLGTATGTLTLNDADPTSPQLVSLTGTGQGALVTWAPTSLTFAGQAVNTTSPAQALTLSNTGNAAMTITSIATNGDFAESNNCGSRLAAGASCSVRITFTPQRVGTRNGSVTIVTNATLNPGVGLTGTGLGPLVTWSPTSLTFAGQTVKTTSPARPVTLSNTGNTAMTIASITANGDFAQSNNCGSRLAAGASCSVQITFTPQWAGTRNGNVTIVTNATSNPGVGLTGTGLGPLVTWTPTSLTFAGQAVKTTSPAKPLTLSNTGNATMTITSITANGDFAQSNNCGSSLAAGASCSVQITFTPQWVGTRNGNVTIVTNATLNPGVG
->SRR4028118_1117479
-FNDPATTEIYTLSLHDALPISHVASTKGSIQSRPVAIACPSLVLKLSASEDRKSGSAGMPRPISYAAFCLHKTTHLRAHRLHHAPSNLAQALTCARPRLSADASSRALRPGHDRWLCVVFFLMMRRPPRSTLFPYTTLFRSDRGRASRRRSGRWGRRSAGRRGAX
->SRR5690348_14199435
-AIVSRLVERGNTDRFAIDLCRRPDLVRPADIAWLGSKAQRASEPARALWLDLLDWVFYPLMASSARALLDAAAVNPIVHERFADWLDPVEFGSAREVTHRDRYENATRSEAPERPLGPSPRTIVRRFLRRFESGDVDAYWHLQRALQAEAATGRSHLSEMDLC
->SRR5215217_5590548
-QADTFPPRITLTESPPANATLTSNPTIRGVVVDNPPPGVQLTVKVDGAAPVNVPLDATGQFQFTSNFTTDGGHTLEFQARDPAANLSAPKIVTFTLQTGALTVDLAAASDTGVQGNRTTTLNSVTLTGKGPANQTITLVPTGTTTTADANGNYS
->SRR5262249_54389218
-PALGARQRDHGAVPDTERKWDDDRSGDAFGGERVLWVADYPAARWLGGRRLARQTIVICRTSKRRQFPESPVAVAHWPADTTEESPQEPALAPRVLIADDQPDVLEALRLLLKGEGYQIDSAGSPAAILDAVDAEEFDVALVDLNYTRDTTSGQEGLDLL
->SRR5262245_362740
-AVGLPAIGMLKQALESGDPEIARQSELILKKVEKVPSEALAAAVARMLGRTKPDGALDTILAQLPVADDEQVADALRGALAQLAAKDGKPEPKLIAALSDREPARRGAAAEALIKSKLTAVEADVRKLLKDSDPGVRLRVALGLVRVWRAKDAVPTLIELLATGPANRVWLADEVLRHLAGEDAPAVSPFGTAAERARAREAWTTWWKTNGERVDLARLDKEPPHLGYTLVLKMNRNTGLGEAVELAPDGKTVRWRISGLQYPTDAQVLPNLNHVLVAEHESGAVNERDLNGKVVRTWPVSMPIACQRLPDGNTLVAHRGGLIEFNAKDEKIFAYDRNSHDIVAARKDRDGTYVFLTRNGLCERIDAKGKSVKAFNGGRTYSYASLELLPNNRVLVSQLTGVAEYDLATGKLEWSATAKRNVTSATRLPNGNTLMSSITSNSILELDRDGKVVKETRMDDGS
->ERR1719242_22332
-SHSHFSTEHTAFNQYNQAPSSPTQNYSTHSSLPCPLSATIHVIVQYKKTKCHTLSTVTPILKEGFAEQNGGTKFIVVPLGDPHWSKRLQRRQQRSSNPGDIVPLQWRIHFDLGLGLTHFVLQFRHQSASKVLGVGGPSREHNLFIQIPSQIQIALIDAVKDTVLNAAIFRTDNGGIEQDLRCSIPGTSNTQFRTVRQLIFRCISQSTTNATRCTIPQIEVVHNIRVIRIVFGIVISTRCCTTSTTAGCSQGTDTRGSTTSHDLX
->ERR1719359_2831734
-AQHKNLGKGVGVRNDPVFKVSNQDMLKQMDSHDFSGEGSRTQAATGIVDLMKIIKEDLQSDMKKADKIEGDAQAEYDQYKKESDKMLDDLKDKIDDYQSQKADRNTDIDDTEDAKQDEESDLADYNQAMNVLMGKGADDIPFPCEFMLREFHNRRHRREAEVEGLHE
->SRR5437773_2584272
-PESDAKPFQHAGLSGCRGGSFLFDSRRTEGFEVDVLFRNAPLRQAVSDPAHHRPRATQEIVIVTRRQHLLENINGEPAGVLIISPQDIGFLGPAIADVHVNVVMLSRHLLNVGLLNMVGSTSRSEEHTSELQSHHDIVCRLTPRLTLFPYTTLFRSQEIVIVTRRQHLLENINGEPAGVLIISPQDIGFLGPAIADVHVNVVMLSRHLLNVGLLNMVGSTSRAVEEPYFPPX
->SRR4029453_10054290
-TFDKDTGHPQHGTSPITRTTGELSLATNVVIQGPGASALTITRDGSGATFRIFHNQANVTSTISGVTVTGGNVPASGAFYGGEGGGILNDEGTLTLQSVVVTGNFAAHDGSGVLNGTVNGGAHATMTILDSTISGNGSVFTNAGGAIFNHPARGNIGVTATDTTISGNTAFGHGGGIQNRNDDEGTGHTAQVTLTNCTITANQANAGGGGINNLDTVSLRNTIVAGNTTGG
->SRR5579859_1338868
-EVILAGLNDSGVLAGWYMNDVTAAAIFELVNGRFQTVSLPVPDVISASVSGLNNEGQLVGSYETSTSGHGFILSGRHLRTLDLPPNWGGTGLTPGRINDEGVVIGTYEIESDFVTVHSVVWTDGVFRKIDFPGAAATIASYLNNRGEIVGTYSTSPAGGIANTHPFLLKDGVYSDLSSLFPGTFAIVGINNRGQ
->SRR3990172_9676722
-LLFIDEGTEMFQFPWFASRPYGFRPGWPDTTPAGFPHSGIPGSTPVCGFPGLIAAYHALHRLLVPRHPPYALSSLTPLPSGRCGQRPEPPLAPSRRGQCPGSPPTLFTCQRTRGISPPEPSCPHSPGSPGGDERSRTADPLLAKQVLSRLSYIPTESPAGTAVPFWDRPPPAGGGPFW
->SRR5580692_1321847
-DLGLAWSYYDLAQKMTQKSLSANVSLLYFSESQKINAALERIPKSYAQGHIEERNGHKSFVDSSGTVVGQERWPGTLMSEKVRRKQAEYNTWLETRAKETSLSNIRLVPQYPRQFLVVGANGALSADHAEIAEIRVPRHIELTGVLDLDTLAIGYYKSAIEWAELCKAAGANNQGLTRPTKEEDFKE
->SRR5262249_47273405
-XVQIHVLLAVDGNHPGAGVFVLGDDANPPPDVVRPGRAGSVGGDQAVPAHTVRVALEQRERHGATGAGAPGPVGAGLAARGSAAVGAGTAERIRAACGSVVDEPVAVLVLPVANLDPLGRVVGHAPEVRPGGSAVLVSGRSHRIGAGCCIGGSRQRNTHPIAVLDASTSIGQLAGLSSLGPVAVRRAATVTGDRAAASVGEGAPGSGTRATGRRVAAPETAVQVAGLRTRGAAGSEAPAVAGRIQLALAPDGGGVAHAGAGALVQQRATCTAX
->SRR5438093_5564102
-SHIPDAVKILCDTRIVDHARTGEVNITNVRLAYHKRIGARAWVKDYTIECELAGDGNVSDVRNIKGRDICVFVRHRFGCPVSGCVPIIVGRIQLPSRAPSVSGGERQQTGYEETEGSFHTTVISTANAA
->SRR5919201_5360144
-FRWFAASAETVVQPSSPTYWRSSAQIGQTRGGGPGGPAWFPQVRQTGASAVASSATAAEPFAKRRQVVVEIGRGLVAVVGLLGERLQDGVLELRIELPPHSRRRSRLSPDMLGEERKGTLLLGRLERRLAAEDLVAQDPCAVDVGAAVDGPVHNLLRRHVLRGSDHRATTVARRGRALVRGARDPEVGHFDVPGVGDHDVLRLDVAVDNALAVRTVERREHTVHPSER
->SRR4029077_8001983
-RDSSQVQEVSRRNPGTSACTALRAARKLRATRPWMPRTLLERSGGGSGTQRDKTRRHAESWCRSFPLHDGFFLESTLGAGVSLQHAAELPVWPAAGHAPTKLEASRTTLALGIGVGLQLALQRGVLIHEFVELQLHFCQLEHQVRDQLLELRVPAPLTDDSQAGCEGYGTRNPRKQIAHTDSIGRVAGSPRLFAVSLRRASHRVRKFGGPTHIRARGGSRPPPPHR
->SRR6266508_4076808
-WLAFAVIAVTLLVQGLTLSKVVRALKVPRDDPTQDLLAEASVQSQASQAALTRLAAEGDGAPPDVVQRLREHAEKRTNHAWERLGSQVRETPAHAYRRLRRSMLEAERDVFRQARDAGRIPEEIMAQAQRALDLEESILTRECPSMSLPVGCEDLAAAPADIEPTSKRCVDCEAIGRVGWVHLRQCLAGGRV
->SRR6266404_7425182
-GIVRRHEVILGSPCPVPRGLEQKRQLRSYRPALFPVTTEQRLRYRRAQLSPSRWPERSVQRVLIKHVDEPITQRQHMSGKLPFTDEPNQRIDSLQRLEALFNIRRIQLESFRHDSRIELISLHARSNQQAPIFVAQLRDLALNHPAQ
->A0A1G9LFL1_9RHOB
-MRSECVECHDGPVHCTAIKKTIEYRGNDALMRNILNAAILASFGGILLATTALADWTYSGPPYPNATIQTNDMSLEVQCDRIRFAPAGYEDSQDIVRKNGLSFRFLVNGSQEVASFQMGRENSFVQIVDNYPVEIQLSDEADYAFVLDQIAANATLNLSMVDQDVSYGIFDLKGSGAAIQSLRAECRALDQTSAPLEAPEGVVYCGGGGIKRQIEFEILDDASDEWDARVTVNGETQRAMTAYSYFGNSEPVKDFVVALLAEDRSEFLIFRNRMENWLEFGDYRYDQCN
->SRR6218665_3367076
-XMKLSMCSKCPPLTCTHAFRRLVKSFTALLIGSCGMSSHINCKEAFSPVIVFGFGCSYDTFPAWPPHVIVKGVEIWGIWWPTVLHNDLRTVCVQLLLRDTCRVCWSAILLENEPGWHQLFAVLDKLNFHSLYGYARTIAFAPHPCSRSVCIRILSACDTFPILTALTKYWLLTAILPKHRVLYLHIRLSDEFAWLQLGCKVIKRGILSVQIAX
->SRR5258705_1672816
-XMFGWEVDGQRSLMRRFFHIWSFVFHKFISVVTMYRCAKGVRRRTSCLADPGDAGRRVVGEAAGEALAGARAAAGAAAARRNKQVMPEVLGKWVENRMGVAEGVHGAGQVMVKALDGFSDRVSGFLGGVTSPPRIVFLVLVNRLQFALDLGLDRPELGFVVEDGFQLLLLAPERPGGP
->SRR6266850_6431312
-CAWTCRAWGAARSRSCSIATTARRAPMRATRLWRPRWWCAARAGPGPTTRAATAPPGTGTLHRRSRAARLRLGTLRAVALAFALALALIPTAPARWCAADGRPEALSRGEIAFLDTLEQRTFRWFWELSDPRTGLTPDRAPTRSFSSVSAIGFALTAYPIGVDRTWVTRGEARERVGRTLEFLWAARQDTSRAGATGLRGFYYHFLDPASGTRFENVELSTMDTALLLAGVLFCQSYFDRRNPGETHIRALAESLYARVDWTWAQVRPPTISHGWTPEQGFLPYDWRGYNEAMVLYVMALGSTTHPVGADAWNAWTGGYRWGAFHGEPHVGFAPMFGHQYTQVWLDLRGIRDAWMRARGIDYFENSRRATLAQRAYAIANPDGWRGYGPALWGLSACDGPLDGTVSIAGRARSRRIRPTPTRTTRSATPIRRGATIATRWRCSSARCRWNATRTSSG
->SRR6266545_636481
-EWAEGAGGVGLVGPGSGDGLGQVEFGGGGGDAAVVGLGGGQADGGDFGLGEHDPGDAGVVGAVGFAEDGVGDDPGLVLGDMGEQGVAGDEVTDPRLFPVQQPGAALDDGDLGAHAGQKLAQLDADRAAADHHHPAWDVAQGGGFPVGPHRHLVQAVDRRTYRVGAGCNDDVGCGELLPGDLYPPRATAGQPGGAFDHGGALFLVAGDLVGVVEVADHVVAVVAQPRPVQVRGGQAGGVAGLGARLDRAQQGLGRDARPVGAFPADQLPLDQRHPQPAGKQPGGGDLAAGTGANHDRVEVGAHRFYLRLLVGWGWGRRWRSAHAASVTAATASPX
->SRR4051794_24386335
-MLSSSACEVRCWSTRATGLARGAAGGPEPYATLPASMPETRVSGAPRLDLSPYPLASHLGRIFAGRGFPLHLVGGSVRSLLLGLPAGDLDFTTPARPADITQLIRQAGGHPVPIGERFGTMAGVFAGHVTVEITTYR
->ERR1719330_1029551
-LLQALIVTTWPDADGPRIPAAGSEPKRNRLHSILPSPSSGIQPRLHEPPCEHRSIAGANHTRRAGTRCRPWLPSALCLVQSCLTRALATQPRYLPYWNSSLPEHWNPMFASLLNLSSAVRSLLEHPSLLWLLLSSPFPGPCSTSRASQSHLSSPRIWSRMRPMLQGVPPEQLCAHETRSLPALQFLFLQYLRGQQWRRVRPGCPNSYRLDLPQKVLPSAEPCTTSDYRICSACFWQMQALLWPLCQMPSRPCTRRSDPCAEPSLQSSDLLPKRCNGLFGLRDGSFLACYTALKRLLVLIVVLFGFQNSHHVVNHLNDLVEASPGDILLTGQCQHQQFQPRFVLHGCSLHG
->SRR6188472_3631345
-RRLLREKQFLGRRFRDSRGLARRLRGKLGGRRLPSRSDRDRAGRLVERSRRARVSPAPAIEAAVLGKKLVDALATRNPDKAVAPRLLPSAELSLSQERPNRLRRCSKRPRGFGHSEVVGHFGKMLAQPAWPSETFX
->SRR5262249_43660061
-XEIIDAVVGSDVRDWRVVEGDHALGSEADDGEGGRSYHSLAVYRAEPAVSLVWGLTENPNFREIEWANNFADPSAKSAWFDIRYNGVPVLRELLVVVDGGRCYLPMPSRHGETRSVPSAYSRVVRLMQKLKGRHEYDDYFARAGLIETGDEWPTT
->R8G6Q3_BACCE
-MLPEDILIVDNFYSNPDAVRKLALEINYQEFGEMQNFPGFESEKSFSSTSIKERFQKLIKNEIIISPREYIFGKFRYSTENDYAHTEVHLDHDVDWTGIVYLTKDEDCQGGLSIYHHKKLGLDSAPVQSELQDFNCKNIAEFDSKYIYPYTKLAENWNLLYYIPIKFNRLILFRGSKYFHGITEQFGNSIYNSRLTQNFFFKEKVKKGVGL
->SRR4029079_2700613
-CQARAAAPTMYRPGQVRTTRSECGQAASSLSLDVITAQALAQERAHARVRRLAGGRIGADMDALPRMHAVGDIEPLHDGSRRRIERLITARIRRHEELAPAARHRRAERDAGGSRRPVVELADMNAPR
->SRR5579875_498642
-XMGGGPGSGSVLQAHGGDDRRDRGDAAADGPSAGRDWQAHAAPSCSRARRAGSCRAAWRAARVIAAGLNVKTRKNPVNTRCERVREVCPPGYCRVMGRGEPVRGSGRPSGRRGGAGDRGGAGSARKGDRMRGMALAAALAGAALLGVAGCGAAPAPQGSRPAVSPSPAGHRAGPPSCVTPGTAGRARTFTITEKDNGRSYCVTSGTRLLVFLHGTLARKWGPIQASSPALRRRPSPVMMLAIGVTGGYFVAASLGTATLTSVRGSCPPGASHCRDRQVFRVSVLVRGTMX
->SRR5215472_4865484
-SANGRSVAPLIPLPEAAQARIKAREAQAAAELEILYRACESDLSNARRNPAGYGTRHGRLDLVTEQVRQTMREAQSVGAQYIFNVHAVEYRAVTPDPVELKAVLEQLRETIIIHYGEHCRTVVQVMETREFEEAWKQKPAVDSAAPIERRGEAVGSSDYPHPLRRGDGSNHQAIPAVRRSPASRGRQVKSESGHRRLDPVVQRIKAKVREYKKANLTFKEMCERLGNSERPPRATWTHLPWPKAYEKHTSAVSKWLSEA
->ERR1700722_18781964
-XMSWSSDIRCLYCDGKLPLYRKLTSGQFCSAGHRKLYWQEQERLGVERLHETHDSLRAFRPKEAVEALLGYPPSYPMPEPARAHGVPIQAELPPVAANPIEATPVADSYPGSYLNDADLSPQTPLWAPQEISEPDHGVEPPAPMGGFIVVHAMMPQPRWPLDRLVIPEPNPLATTGPVWIPLRTMAALIRDVLGAGAAAMPMAPRPYEGTRRLEPVHPAMLPCLDVSHSATPAGNALAAEEDAPRAEKLLALAAFAAHEPAPDGTRRDPWPAAPFSKVHKAHLPPATMERNVRLTIAAPPQAGLRSLAIDQVPLVHGTWIDSLRALKSEGELPRYELSTPAMRPRLRLATGSRYPVATRDQNPGVATVEPQNLQPSATAVAIPERAMAAAASCSAQNVPDAAGLIPLLAAVKPNEPAAQLAPSTQSLNLPQPLLTEPMRPASHLEPLDAKPVMDFMAPTPQIPSQIIKMAADEPKKDSPAMENAAALPPSESGDVTPWTVVAGFWQHAPRDLKLLVFGIPILLALALHPSLKKIPYAAPLKAGGIERNLEHNFQSKLKDQWVTVKQTMVDRGAIALA
->SRR5947209_11779987
-PPRRPAPASPPRSRPRSGRRSGGRPRPPARPSPGPARTPRRPAAAPPARPRPPRWPARPWTRPGAGPPTWAAPSRPPPRTRSTGPPGWPPAAPPASGRRRPAAAGRRAGSARTGSAGSGSRPARPPAPRPGSRPASAASAGTSPTGRSPGRPGWSRRTPFFPPRQGGLDRLGRDRQHPVAGLELGSPEQFGVALGGQHIGQAAQVGLTGRRQRGEDAVGLGALLGGQFRSAHGSAPANEFRRPTHTPRPAAKNPPTSETHTPPGIATWELIAPPLRRGYNG
->SRR4051812_12632978
-GRRSTARAGRSPAGTARRGTGWGPAGGSGRGSARSCRSPAAARRRPRPAGRHCGRPWRTLPRPSPRDGSRTAGESPCRLLPPASSTRGSGRPACTPATTPPLAGTVDRGREPGQTHVAGGCSGVPASYRARSGPSAVVRVTLDRPPRPATAGLGRLVAVGYPERASGASGGIGRRARFRSVCPKGRGGSTPPSRTRRRAPDPGTPRAGASSSARTAGQEAVSTVRPPRRPRAPSADDPGARDGVAGHASIYYSAGPDGCHAARHRDSRLAGPLCHKRTQIRTWRPSTGGGPPRPVTSAGSTESATPKPGVRPSRQESAPFERESAPTQRVLYRGTMDVGPCSPLRSDPRGPGRQTYQRASRTRCVTTATSHATETSPARATGPAISLRGLVKRFDDVRAVDGVDLDIARGEFFSMLGPSGSGKTTVLRLIGGFERPTSGTVELDGSDVTALAPFERNLTTVFQDYALFPHMNVLDNVAYGLRVRGVGRTERHDRAAEALATVALHGMEKRRPAQLSGGQRQRVALAPPGRPAAGGAPPRGLGRRPGRAAARRAARSARPEAARAHAGRAQADPARRRDHLRLRHPRPGGGADHERPGRGLRPRPDPAGGDPREIYERPASRFVAGFVGTSNLLSAQAAQELLGRAGTFTVRPEKVRMAAADALGDDRHVVAEGTVAEVVYAGPVTRYLVDLDVGERLTAVLQN
->SRR5207247_1084271
-DDSKCSLAQQKGEHCVSMPPAWSEWIVQVLPISDGRSTAFSNPTQGVGGSFILSLQRDSRARPKSHQRSWWIVHTQPTKRLARPSRIPPTALVGLSGLPDGRPLGLFQQPARAQAKVRSW
->ERR1719350_1727719
-GKPPSRRQRLFDMVVSPAFQGFFAVLIATDSVVLGVETEYVSRHRDDDRNPGFFAIRQIFAFLFFVELALKAVALRVRFFADPALRNWNVFDTLLVTNSIVELFIDGALGGDQVSELRLLRIIRTVRIFRVFRFVRMFPALKLLVNSILATLQSLLWTIFLLLVFLYLFGIVFTQVATNHFEKVGEVDE
->SRR3954447_23639997
-YRDVVGLWVAVGTCQYDGGGNAEVEHGDDRDGRADRARNVPAGVGELPDEVRDGLPPGEREEQDDDTSADRGDAMRGERGQALQRHEWCGGGDREDQRRGHPAGESELNATADTQAEKVRADGRGEDRGGYRVGAPGPDLQRLGDVVAASERDD
->SRR5688500_19711690
-RPLSPPSPLSLHDALPISLGGAEQRDLPAPDQRQRGQCRAHGREDATQPGHGAVTAPRCRTVAAWHAERVVGRRTVLTGAALLRSEEHTSELQSPCNLVCS
->SRR5512143_883754
-LERIFFHDVLGAANAVQGLARLVAGDDAERAKSAAQSLVRATDQLLEEIQAQRDLMLAERGALTIREDETAVSDILEAVRQQYQWSPLAEGRELVVETAVANKRLRVDRTQLIRSLGNLVRNALEATADGQRVTVSTQPLAEGVLFQVTNPGAIAAPLQR
->SRR5579863_223257
-ALDWEGVVLVVIGESESELVHQRGSDRVVIRGHHAASLFVRAVAGQKVARRRYRPRVVELGIERILEAVAHVNLLLGIEVVVDSNIEAVRVRWDGRERLVVIGRVCYTQVRVRHWIVLQQCGRYGIDAGRARSGWNGVVRERRTGKWVEQGSGSNRLHQVIQVAGSFGCRGHQKFFGIGLCFAVALVVGEDEGLVAPVIEPWDCDRASYASTEGVKGAGRLYVEVEHGGVESAVLEVFERTALPSIGPALCDEGYVADLRELRIVIECGDLHFIDALKRWIRICEX
->SRR6266404_1434125
-XMRVLVSHEAVSVSPLISSSLFVSLIVFATSDLVLACPASCWFPLTRLRARGVFLQDRKSTGIEVVDNPAYHLWWECTRLIDSLSRCQKFPASRHRVVLRYCHRAITFIHKSAHLQX
->SRR4051794_20682467
-VGRGGLPRAAVVGKRTLTLDMPAATRWHVRHERAHLPVAPRRPVLGRPDRAGRRRRPAVLRGRPRLDVRRRRAGVRRLRDRAGGRGSGGRHRPAAAGDCDRLDALLRQRRRRGDREAVTDSGGTLLLPRGDVGPLGRLCVAADPTGAVFGVWQAGQHIGAGHVNAPGGLTWEDLRSPDPATAQAFYTAVFGHVVDPMPEAAPDYGLFHLPHEQAPLGGMGPIFGRDDASAHWLVYFGVADTAGAVEAAQNAGGSVTNPLFESPYGRMAGLADPAGGRFWVVETDGSCQPDRSDX
->SRR4051794_34313143
-PVADFAHVAPSSEPVAQPEERVAVLLGDRLAELDAVLLLDLLEPVLVTELQEKTVGEVDAHARAEEPARARLPGDRAVGERAVQHREVSALGVKDAVVKLELRAQARVRLRVALLVVLEKGPDAPPRTEVIEVRLGEQRR
->SRR5450759_4329672
-CVEETGRDVQLRALLPCYEVAVAIFDHAFHGDRFTTDREIELRAEGGRAERHTEGDVRLEVVARGVLARRPVWRGDVGVRGNLRRHLARDGLRQRPRTVGELTIETGQHDGAKLRWLDGAGHRVYGHVHGLSGGHDTVVGQGIETRAARDDERLLELALLLGETKIDFGPDRRRHRRDVAAGFARAATNPDGKMHIRARRHTQQA
->SRR6185295_8040175
-RFSPGSGRSRPSSLSLPVLDDSVKSTPTPSGQPEHESSSIKAAVVSTAPSKRGFLVGGLGLVALALAVVIAVRPGGAPASPGPAVRAAEAVGMVSITSEPPEAMLSWNGRVLGKTPLKADLPPGTQSMVVSRPGFFDETLVITVPPAGTVERSVTLRRREDPAPLTAX
->ERR1719401_1546905
-KLLPLLAARQTATGTGDELRFALLQAKSRTHPRTRRAQITALKRPGTRPPAKLTSSPSTHVLVSLASLHSRPDLHVVASVLPSQVAPLSAVPVLFVAAPVTKNRQDRTSAIIFSIFSMANELERQCAGLVVRX
->SRR5207248_7680326
-GPIPRAQPRCPAYPAGRHCREPSTVCLLECSAGPRDLHSFPTRRSSDLPGTYFGTAGSALIRAAALWDDLEAAGVPGIKGVWKIDRKSTRLNSSHRTSSYAVLCFIKKRVPDNACLVEARLPGRQNVAGHT
->ERR1039458_7977961
-VLISGPTGVSQADLSSPLLPWILPCGPVFFFNDPATTEIYTLSLHDALSISNKLFVESPATRRFLSPSNCSRTDRKSTRLNSSHLGISYAVFCLKKKPTVLLVALGYGLASLYYLDHFDKLSVLIKRQFSCIRVSIVVSVLTLSNFFFNDTATTEIYTLSLHDALPIWKRRACRCLRHLSCFWCSPCGPRDRKSTRLNSSHLGISYAVFCLKKKX
->ERR1700760_2163761
-SPHPTAPIGDVVPSTPPANALGKPRTSAVWKTATTAGGAGARTARSRRWWYVSRRGLLSPAKFERRPSVGRFVLGDDVRGNPAALIHLVAVRPRPLADSGTLLAAGAVALTAAANLSATRFACVIHVLSKLGAELARVAGTQIDLIGQAIETKADGLSCLTAVDVIDQX
->SRR6185437_11610463
-QDRRVWQRLQLLLHGQDHWAGSRAPVLRSAPRHRGPSAMRPTPRPISATRRRSQRVRRIARLLAAGLALAALVAGAATAEATSTGQLQQKISSGRAHISSLSGAVSAANRKVRQLDASVTATSNRLDAVQRDLDAKRAQLLSLRAQLNAAQARLKRLQATEAADEQVLATQLVGSYEGQRPDIVTVVLEARGFNDLLERLDFAQRIGHHNAQIVGAVKSARRAVAAEAIRLGVLSARQQRLTEEVLTERDNVASLRISLLSQRLGAARARDTTAGRLSSAKAQVASLTTQLNRLQAAQRAAAQRAANAGSSPAASTGSRRSSSSSGPPPSAPPSRGFPFPMPTGAVSPPD
->SRR5260221_13052907
-SLQPTRARATRTCWACSTSCSATASGRSACSPVRREARDWRAPCHPFAHADIARTGPSVVQKSERPRAPRQVTGKWLALILALLVQAAFVAVLVVSVRWQNRTPEPVTAELYAPAPRNPVAEAPPAPAPEPAPPPAPPPAPPKPVVATPSPKVDQPDTRAADIALRA
->SRR5437868_12203378
-LVRRGVLGPGPTDAGIHYVVSLRFGLDPMLRVAPGFVVHFFFLMSRRPPSSTLFPYTTLFRSPHQSVYCFTGSLFYRVPCSRSRSEEHTSELQSRFDLVCRLLLEKKKQWRTMCPVGVRVRSGACVLILSVCASAPACGVVRTAL
->ERR1740130_985408
-VVTKNHAAVLKMSTRHMQGTSDSRSDRKRKNAEVAREELQRQKQRLDFHRHKTRDLKARLKDIEKGTCKEYLAQCKTLDSTTQKEIRTIALLREAHMTSTSQLYSFDTMAARHGNRDSKDALKLQLRNTVIEELKEIDDLVKSESSFRRVSKRNLRSKSKTDDVPNGTNHAGTSCLDSFRLHFPLTMREVDEDLRIIADDWHKAALEFKKSQDMIPVTVTHGKLKYDDLVIERGANILVQSELTQTQTEGHVLSIRRNEIRIKCKNGKKWQVQVEHLRTGRVHLFPAGSAEX
->_1
-FPEDIAHTAVRNLGVPFYMIEIADDPRYRAVVGIENTTASQWLAPPDLVSVPSNGEIPIDFCLDSTFPYTTNMTYTHLMWRFVEPTRQQDDFGPTEWITVPWEMSGFVDAGNSCELLDGSNGTVLQAQIPLPDSSVGKIHYKAMLGTTNGAFPFSYPTVEEGPNYYELSIPYRASFGSSVLALLMFSLIATMVWGGLGYTLKEMFNDERDVLGLPLKCVIWRKLKWKLRMKQAQMSLVEDX
->SRR5262245_59441811
-SGIRVLERERLRQSTAAAWRHRISGGRSAHTHSDETPCGCHRGVLSAAGPVEGCRSVQGRASSADERRIRCHVEPERPEPYAGRVVGADADHRSAKMVCPTVREEVERLVRDPRVDVYAAVVRRSGVPLAVVIRIVICGEPEVRRLMWIVHVTECVAGDAWC
->SRR5689334_15183997
-RLGDVVLDALLQRRERFVDDAEGVIAVGHRIDEHADREEVIDLLVRPLAGLHLFVDRPQMLRSTRDFEVLDAGARQRSFERLTHLANELFSLATLGRDLLGERFVPVALEVLEREILKLPPQLRHTKAMRERRVEIARLLGNATPLFGRQPLERPHVMEAVRELDDDDAGVFGDREQQLAVALDLPLFLRATGRQLGDLRETVDDRGNVFSELPLDVGDGNLGVFDDVVDQPAGDGNRVQLEVGQNLGDIHAMRDVRVARVAHLPAMGSLAEAIGAHEQVPVELVVERSLLLPPTRYDLANRRCRRHPFSNVFSGIPSAIPTGRWGFGTLPSACSARLPSWDKQGPTTTDGPRSSTANIRGS
->SRR5437773_4994510
-TIKIGNGTGCAVTFLRKEDGMPLRRTLELTDSQRQDLVHYRDHDPRPYVRERCAALLKIADGQSPHAVARHGLLKRRDPDTLYDWLNWYERLVSAVSGCFSTAGNIGSVFDRSDELVERLQHAPGEQARQELAPTADGPPPSRWTLRGVREIGRAHVX
->SRR5512137_1013993
-LWHTLSAATVRMTALATRVLYQRGGGSWRERLLDQLAWPREAARSRFSGSVSSRRIVEGVGFDMEEVRRIRKWVSGATTNDVFMATVGGALRSYLQLCGDPLPPGLAAAVPVGHHDTLPGGEPGNKLNQHRVSLHIDCESGLARLRALRQASEDA
->SRR6267143_4187927
-LGEALRADARRLAAVDLAYGRDHPVGCPVDVLGEDAARVIELRGNLSAVVWSSGRATSRSKDGRRVLRADDRVRVTKIDERDRTRIRLDVVKRVHQSDLVGARGLQRLVLPVPLLNRDEGDVIARVVRVPEGERRRVREAFGQGGRLHILQPSEVSK
->SRR5215211_5171990
-PPWRRALPSRSPSRLLGWRNSPSLGRAPSPADGHSSSRPKLLLVLLAPMLPHRGYGPFIAEQTLGPGAGRLAAEQPHGEVSARNEQLVEGLAHVPVGNDELSPLLRGEERCPAQQLLDKGSAHASGAGYYGVEVFEFEVEALAVERDQAPPAARVGERYLRGLVYAAGSRGERRLEQVWTVGSEHEDDVCVLGEAIHLVQX
->ERR1043166_75354
-YRLLLGSDPAEPLLNEAHGFRFEADTEIKGQPVYVLRWQQDARSFLNAMGLTNTPTSGRSFPVKAWVNTTNHLVLQLQSDLSNWAKEIMGKRPEFPVTGLLITESHSAIETAAIAASVRVFSTQLQEGVRTVERIELPPPNFAILAAPRRHFSKLIPARLSMASSNQIDLTDYYNGALIQAWHPGPPGNNLSALPNGLLQLGGVVFDVRGVVQLAGVDLLRAGGRFPQQISGIRIAQVCHELHFLQAAGWRSRDGTRIGTYLIHYADGRTQAIPVIYGEDVRDWNAAADPGPQLKRAVIAWGGINSEGRPVRLFKTTWDNPWPDTEIVSMDYVSAMAASAPFLVAITVE
->SRR5689334_14209035
-IANNGIIATVSLIISTFIGAILYNISPGLPHTAMGVVHLVGFLLAFRLVEPKIKDAAKEKFTFKAYRQQLSNGFRHLMTPALWGFLPMMFGLLGITELMRASLVQPALAFNMGFGPEAQSGIFALQLFVAMFAANAMPFLRRRIGDWIGLVAMTLLLMVG
->ERR1719265_2530241
-PTNTDPRCAGRVHAVRQPTLVVRVGSLDKEVVRLVQLFPQHVLVQVASVVIQETTVKIPVHVNGLATWSVIANVLAEILVSANRVACDVVVAAVVPTAETVVSRARRVQTTLSVALVFLDVHHHAGKRNLYLVQIHVA
->SRR6266545_7407710
-ASRRRHAAAVRAGDRDPAAGGEGAHVQADRRAVGDLDSYGAEPRPEHAGEAAAAQPYRAGPVRHRNRPRPGRLTSGVPMTVLAAPGATWGITGPQFLALYGGLILVSFARRGHQRPARCRQPRRPAGRAGRRPVAGAPLPDGFDPRTVRAAAAALLRKRASGSPPT
->SRR6202166_3668028
-KDGPAAVAPAPAPPKPDMAGLDLPLPDPVRERPASNPGANASGLNLNKPGEKIPAGKAVPGPAAPRETFRRLVPDFAPLEEQRRPARAFMSENMMPDVRATFPVRKKVLGTAFLQALLRQWWPLLVAILLVVGALWLLLPHPARREAPSARVLPETPSTDAGTPARPLGLYVDSSGPVWRVSWNPGATAFRGARGVALFVRDGDDQNRIDLSPQDLQSGTYQYAAKNQEVTFRLEVTDDRGRLSAESFRLVKSVPVPPEKPTGESVRRTAEPPRPASTAKNLVHPRATHKVPPVVPAGIRPRIKSPIPVDILVHVDSHGRVTDAAPAVKQHAGLESYLAERAVTAAKQWRFDPARENGRAVPGTETIHFVFERXX
->SRR5215217_2643638
-DDASPAVRGKVGPDVPAMQLDDLPADIEPQAESLGGIIRSSLEEALEDPVTCVGRDPDATITDRELDRAGRRQGESHDDRCSTGTVLEGVIEENGEYLLESQRIDPRFERCRHLQHDRVPVAPGSRAGDYLFQQRRQISWPPAAMSSGRPPAVRHPG
->ERR1035438_2618940
-SSDLTDLSRQPHGTNAEVDLAFLEAKSWFVKTNQAKAERMLLSLLDAHPDDLILLNRAKGLFAAFASYTNALRITDRQLQHEPDNLQLLQEKGFLCLKAGQFSNAIPTFTRILSVTNSYPVLMSRALAYLQPRRWGEATKDYDRARQASPDSSEPYYGLSDVARHRGDPNTASQYYQQGVSNGLRVIEER
->SRR5437762_5397717
-RAATGEKAPDARQLVAVDVQGDAHASGEQAFAQHTLPYHPRSAEQKHLHNASTIARQTASIKEARYGVRLQATRWLGGGAGDRVARGVCRVFRVQRGRRARRRRRSADLGRRSGRRGPAGGPAGVLVRIWIWMASAVGIRVLPVLLYSVLAVRPAGAVLGRRVAPAPMLWLWRLLRSSADLRRLAPARPRAHDEGAGSIANRGATNRX
->SRR5882762_3560359
-RAPGQIFFRLHDDCIYLGGDVAQIGSLHRTEDIERRRGVVVGHDRGRDTAVNVRHAREDLRRSARSVQRRVAEIIEILQAKLRRLRRDLVLSSALGIDPERGRRLETARQRYQHVGGNRLLGQTQQLRLAAIDIHVELRIVARLVDVQIDGARNGAEFLQQLVGKFTVAVHVEAGYLHVDGGGQPEVQYLADHIGGQERERGRRIGGGEFR
->SRR4030081_1498409
-RRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLPATLSDLGVLERDEGNIDAARRHLEDAGAHERALVQADPAPHHRRSLAITLSDLGVLERDEGNIDAARRHLEAARAHERALVQADPTPNHRRRLAITLSDLGVRERDEGNIDAARRHLEAALEHNQALVQAD
->I1BUC6_RHIO9
-MLYSRLSPAKDRIFLQKILPACNTTSKLFLNQNKLFVIRLASTRSTLYNNQSKPDNVSLNGDAKKPKRRFVKVDSEFSKANKFTYVMPQDPYVASDRVTSILKNGSVDDAIEYIKALPLDLQSVVVWNHLIGYCAQQGKAKFAEQSYVQMRRRGIAPNDRTFTHMISVYSKSTTPNAVENAEEWLKKMKNFDIKPSIIHINNLLKVYNHAQQPSKTIKLLHEMPSRRIHPDAFTYSIALKACSELSEPGQAAKEIKQIWQNIVYRLEGEDHGDSLKIENLNLKIDDGLVISLLTAISRTLSKESDMIPGLEAIHRLYSLYPPRAAAVIEKHQLFNVNQQYGFGMQPSIKALDTILRFCGKTKQYALAIKSILDGCMTLSHKYIHDQKDQHKSKYNVWNQSGRGSTYATATKSRNDTTRGPIIAAAATNLTIAVSIIASANFRC
->SRR3984893_10676208
-QLRRAYPKWRKAGRPAGAGSDPVRAGDKPQDCEGDRPRSAADAARACRRGDRITAAVRESVPGTKRRKPRRRVYVSFWGSSGSAWTDGLGCLRRKCRVGPGELHPEPLTDPDLTLSRHPARATARRLPPSVENWRLLLLPVGSLPTAMTCLLRSTSITPASSLLQGSPPLSGASVLSASRLEPLAPFPLPSPARFSRSVPEPDX
->SRR6185369_3836006
-IGELLSSLRLQIVRIDIELAVAVRAKVDRVSHPHRVYVVGAALGLGKLLGGVVAKTIKPYRRVEAAAIMLPLGKRLRQRVVSQSRSVGRIGRLECVWQLERLFDAAFDRNGEQLGVASGEDSARRSEQHRRSIGCESLNYVRTRMPRQPRRHSAGNRHYIDVGVSFILGGKRDERSVRREPRAGLLAFVAG
->ERR1719376_375132
-FYPGMVNTDKMKKTSLTYTITPEQMKAEDRIFEQQIEKERRHTLMLRQARKRKKRANKNRGSVPGTLVPIRAYNSYKTRERGTRIDELRNVDQQVAQRIPEQQPKAPVIINWNDDDDGSVTDPGHHLHQTFIEAITTNIKGLDPPKENEGPSKHNIRAGAGTPWQHGMKEIPSSFVDQISIVGVKKSSFFQLMVTGNLFWLRMFLKGKEQMLLPDKLGGKSLDLDTLKVSTPALSGLSDNNYFNNCSQIIELGKTLMSKDFPHLKVYRCHNKESKKNCNLVSKFRHWTVSEDLKYLDLNGNEAFESAAHNTPDILIADTVKKYLEDVNQHDSMIEVMTMIVKILCNHLHVPLRVLKRERSFKEIIKCLVEYCMNKSITFDGTKQLQYSINKLMSKASKWIGGKRMYRKLLQSYLNELFIRRWIEYDSDKSITDLINDFSGRTMVDISDMSSITKSSFCSDVSENVRGGGGGGERYNSSSPISSKRSGLYSFRCNEMSDLLLLIVRMRSTKNLGGKIESSSEKMILDEYLLDWFFNKIKEMNLIESQVSNTNLNEGSAKITALENFMLTLALPNTDNEVTDTTTTSDASVATAIHYKWNYIEEDKYGSLESFNGTNHSDMMKHLILDNVDIDKEERKEEKLSDYIKTVDESIQNSLTNLLNNEKCWGPIRVIWGTTSYIRLLLHKYSNVLDLYSESCHVIEEIPSFKVILLRGRRX
->ERR1719191_268510
-RNLLVLGARNAAGIIRVFHRLARLPVGAYIRIALATWRARRFVFLLRAATHGNVEKSRSARLLEQDGFCRSCCRVLFCDRRKRDLLLMLLLVFPKNSSSTTVLCFRSTGKRSETSQDTEYPKMNMNTTRTRNSIVSKPRSNSADSTALITILRKCCKEMGGCKSQRQTARSLRRTNTSYVASVRG
->ERR1740124_282413
-RDDRRPCCEEMYVLVRESPRAAGTELRFASKPCAGEKAAMDQWRDAYNTSRSSAQLKREGKVVSVALTEQLAHEYRRFRSDHPSWLSLEPPAAVRAVAMVEADEPEAAAAAGGGDSGGGGGGGGGGGGG
->SRR5271168_1700852
-LALLPHISHGRGIVTLFVAHCRWISGPDNYYGPTIDLESIGVRDGLVEDLVVGVVNVGPVCRVADVKGGGGIIVGIGPLGLPGRRVVIEGTYLYLVGKAGVVQGRQYGGHACGTPAGDRTCSAKVGAKKVQPGLTRLANPG
->SRR5712692_205962
-KLFERSSKMNTMIRCLGAAFVLSLLTLCICPDASGQGWTSTATKAYLVQNLSNATLIGPLDSSTTLHVVVGLQGQNANQIQPTLRRMLTPGDPLYGTSLTVPQFITQFGPADRKSTRLNSSHSSISYAVFCLKKKKQNKKTSCYEKKKIKKTKQETTIQKQ
->SRR5271156_1441549
-CVGAATQVLLVLIPPVLIDALGLFWTRWASLLINSIGPFDQQHLLILVDLLQLHFDDFALGGRNVAPDKRRLNRKLAMPAVDQHQQLDSLGTPMIKQGVERSTDGSPGVQHVVDQDDIASVHIKADSAGADHGANIVGREVVAVKADVQHAVVDWGLFNRADDLRQPLGQRYAAAFDADQPYIFAPVVLLNDLVGQPDQRA
->ERR1719300_424020
-SGDQLFRSFTKFICSFFRFLTLSFATRFTLALHGFGRFLGCFSSWLLLLSSYSRTRSGCWCSTLFRSGKDLIVIRDIIIIRVFLWFRCWTFFTLGRFFLFSLFFLFLFFFFIIRSPQLLRRRIVWIHKPVGARKSLSTDLLKPTFGX
->SRR6267378_6278353
-RLSVPKRIIHGEGIWGSDKLARVEPVWARPEYANLIPLALANGVFEINPKKIWSSVYSYNRPEITVEKVEEILAAFVKAALLFIWDDPATGKQWGFWIGIDKAGRLPAASRLKKGHDSVGPTPPLDSLQQYMKQPMASHGSANGLVGSGSGSGSGSGKDVRADSSSPHESVTPQTPKPPDEKLLVVERVWAYYVQKLGKNPKQLSFTAGRKQKGLARLRECLEKEGGDLGHAEGLMRLAVDALAESPFHRGENNRKKRYDSWEKNLFKDQDQAENWLDSTGGSKRGPVPVPLLDRRGELNDAGRTVYDKAGVSMSX
->SRR6185503_10073111
-SSSLASRLDQQRQFARENYNWEKRAEEWERWLSGFGNATSRLPAAVADTALSAKTAGNFLRFVGEPEAAIAMYRRSLEIEPDYLPALYNLGMMLHQTDRFEEAEESFRRVIAIDP
->SRR5438552_10382664
-SYCYSSLLYSCRHLFISLLLWFMVYFFFFLLIRRPPRSTLFPYTTLFRSTRQFLTESLVDGERSQSKSFSSCARIGRILRPFADRKSGSAGMPRPISYAVFCLKKKKNILKEALALEHTTGERWYAPELYRLKCK
->SRR5947209_3319617
-CRAMRVLMRFYQKIGFRIIVGAVLLVSAVAGLLAWRIQGLSKEVLRTHEYADVFDETNLRFREVSSDIQTLRDELLGLFNDPVVRQLQWSEHYKEGWLPIAPPGLEDKAAFSKHARKQATEVFVQLLRRHVRYFRIEYYLDRTRT
->W8CC99_CERCA
-MKFLLTLCFAACFIATLQAAAVDSTTAQPKAAEAADASTTVAPTEASDVVEECHQPKETGRCFGLFYRYAYNVENRQCEEFVYGGCNGNKNNFESKEDCEAKCLAAKKDEAPKEAEEGEESSTLAKEGDEDAPVVPVVEAKPVAED
->SRR4030042_5098232
-KGDAFLLIESQRGVRRSNYCQIGKASLENLVDCDTLQAAEVLSHALPWLAGTAVECFGDDCRFSLPGREVGRERWAEKSHDRSRRCGRDVHRAAVRADKQGGATDDLPELDHVELSGQX
->SRR5688572_19060020
-KIFRIYIQANSYFTILPACFTFTQLKILIMKTIISALFIMAAMFTACNSKSGSADAQSTPEGAANMIFDAAKSGDYSKLKGLCDASLDTDVDSKKICEVSDGNEELKKMFKDYFSKGKVVGTPTIEGDDAKVAIMFGPEGTNDETMNFKKKDGKWY
->SRR5438552_950382
-AYRYVPATPAPDLFLADESIRLGVTAPGTSVTRDLRLANQGTAPLEICDIATDDARFAVRPASLRLAPGAHATVQVTWSASDGNPALGTLTLGSDDPGSPRRTVQLVAGAGRVAVGQPAPEVVATLLDGTTFRLSAERGHVVVVAFFATFCPACSF
->SRR5208337_2690271
-XMAFALLVRLAEQPPMEVNIFEDAECWIKIAAKALGHVGNPANLGVPVYLAGHIAAKHMDLALLNDSDACGEPEQRRLAGAVRPDQSDHPAGGNIDGNVIQRDRLAVTMGNALDLGHDVIRHWEASRQVFPARQRRDWCGRTPFREFRSSREYDI
->SRR5262245_35595640
-GRRHVRAVGGAQAPDRRAGRRDGRARGQPADRRRARAARRPGDRPAREDALGHRAGRLAVLPRQLRHQPLRGAGHTDGALDTADGAAHRARPHQGRARARAEPRVPDPGRGRVRLREVPRADAEARLPGPHQPRDLAHGPAPTGLRRGRGDGADLPRGRGRLRAERRATRAADDLIRAALLLGVLLAALVPGGARAQSLPDVSDDGGVLFRSELRRLGGVQTVGYPLTGRFVWEGFTVQAFQRAIFQWRPESRAVAFVNVFDRLYELGHDDWLLVHRQTPRHDPSLGDASARLALLEARPAIRAAYFGVVGDPVQANGLPTSRVQDMGNHYALRAQRVVFQEWKEDVPWARRGQVTVALGGSIARELGVLPSVA
->ERR1719499_2701023
-LKQFCKKTCCKKAEMAVADPCYWTDDCDEKAVGSSSDESSEDSAEKAVANNRFDWSDQKGWCQGERARFNGAKKYPGKRYTSREQCLADCEKENYSGWAPKGCEYSARYGTCNVFFGKSVSGTNRGSSYRCNINRSKAADYERAYGDFILQSNANAAKDEKAVGSSSDESSEDNAEKAVANERFDWSDQKGWCQGERARFNGAKKYP
->A0A2E9IMM2_9BACT
-MTRRLYTMALMVLGLSMLLSSTGCHEPTSRDPRVLRVGVIVSLKGPARYWGVVTMRSAQVVADYYNERGGFEVAGERVKIELVVLDDEFDATEANRVAHQLVSEGIHYTIGPLGDATVDAARRVLEGANVFYLHYGFDPALQGSGGLAVLGMPRPEQTLSIMFRHLRQEHHVSRAVVMAYGTEAGIRQKRVAEQLALDAGMELVRIARYDVSKETFDVSLDPQGIQRRVAGVVAAAPDLVVLAGCPPEAFVVIVDRLRSAGYRGFVGTQTTQDPRALAKLGEASDGIYYVGGEPADALRSEYFRTLKERYLDLAGEWDAEANKKFYALELIVSCIRAAGLEALDETSLIYPVLSELNIEDPFYQEPRALRLIGGQEEGLPRQLEIPIYITKMSGGRAVLVEESPRVLP
->SRR5262249_35545196
-GDFGSAQGGDWHSSRKEEHLAANADAEQQTREERVDPVEHSGQAMDDPQELFDLINEDDVVVGRVRRGEAHRNPALLHRSVQVLVLDSSGQLLLQRRSQQKDLFPGYYCASASGHVMAGERYAETAARELAEELGIAPPLTYLGTTLVRSAFETEMTQVFLARSDGPFRFHPTETEGGLFLTRRALQRAQSAGSLPLTPAVLAALDILDRQLPDADARTGE
->SRR6266550_8732594
-AAIGQRRVTRPGERDRDRVLPPVVGGSRLVVLGRAVGGRSRSIRSRLVDVDASDGGQRSIARLVEHRARERLTLTLVRESVVRLTCVYTGEIVVAGELSRNSRVVPTVRVRPRRSGAGDGWRRGIEAEALRSASTVAGVVHATARDSRRISVRDAVARRWIAALDSAQIVKLVCDRIAERVVVPVIVVGSPRERHVERWRRLVELEAL
->SRR5438874_2142771
-LRRRKGTDMKRRDRRNGGRWGRSVLASLLVVGGLGGLGLPVVAATCVLEPQLRAITANQGIGSYATVARGKETLVRLYLSLPSCAASGSSIKVTGASLTADNGSGVKKTVSPFSPTPTSTPEIVAAGMAPAFDSDGDPKFVLPGTYLAPSYTTARFDVTFTATVNYQATANSTSSPVVSSKTFDKLSDSTPLKVTVERKTNALRLLVVPMGDGHQTYSSQFGNLDKITTQNGLTTLARLLPVPDGTGDLTSTARGGVRYRIAPTLLDLSSLMTAGKFCGKSTTWGALQSLLLGFLSSWNAANTANPAATADRVLGVVSENISVGGSGDCVDGYATFGEKQAWVRAIADTAFAPSKTGALMAMEIGHTLGAVPPDRDDDFNVRHSPNVAAVPSTALAPNRGYNVDKRAFVPNDRSAMKVSPSGAWNNTNVLFEAADWAWIQCQLSNTASTACPSPGKVGSAVGVGANPTLTITGRTDGTRSGTDVVESGFAPGGFAPGGLLTEPDPTSVYRLVQRDGATILRDDGVEVSFEESQHDGGAVFLDNPFGVFSVAFPFDTGANSIELWNGTPDGPTSVLLYARDRTAPPTLTSVNAQPPSTGTAATERASVSSAEAQTTSGSTGAQPSISADGRFVAFPSTATSLSVEADTNAQSDIFVRDRQSGTTERVSVSDSEAQATGGPSTDPVISGDGRYVAFVSSATHLVPGDTNGQPDIFLRDRQAGATVRVSVATAGTQANNRSIHPSISDDGNLVAFTSLASNLVTADTNSTDDVFVHNLTTAVTERASVSTSGTATITSTTGAVVGVAAPVSVRPNAAVSDDDIIAFDEQPGDAPSARAPAGGLNVDVTNGTADRTHALSPSTIPAGTTVKTHLLHADRPNNPVDFKSFTGTATFGADILGVIVRQSRLEATDGLSSVGTTYPVANDPQLQGLRGLDF
->SRR3954447_7250895
-XMEAGWEMPAMSSIALAVLVSVVAFVCVWCQRAQDRADKRAELLLQQHLTTEQLAHLNRTGSLQVPSKSFESRVYTVPIRGFVSVHDEGRLVMRLCVRPGTFLPGREAILAHKMYIEAAEDEYVESATVVWRAMSLKTSATAVX
->SRR6185437_774131
-RLHGRGDETSRYSAKSVRDLGNGAVVSLKVPSRCNLMTRKKITGLDQALGASAKLEATASAAYSRKRSITEVIPPDVTRAKAGAWLDLISPLSEWAGLKGDALRAKREQLRLQREDVLGEIARRARARITAQGLSVTPVPNKFLVPFLEQASLEDPDSSLVEIWRNLLVSAASDFSSHHTHFVSVIARLSPKQGDIFRAIIKAESLDELEYARDEIGMWFEAHSVRQGIAREYGKIPKRTRADLSDDDFAEFIHGYMKTAGISIVHGSFENEQTKS
->ERR1719456_362451
-AMTATTLSAPILTTMTATIALVRLTTRPATDLTTTGMLLAMTLIRMTTTTLPLTLRTAMTAATLSAPILTAMTATIALVRLTTRPVTDLTTTGMLLAMTLIRMTTTTLPLTLPTATTPTTPFAPTMKAMTVTIALIISTTKLTTDWTMTLMDSVIRVTLTTTMILIPTP
->SRR5690348_12433932
-LENVTSFDPKTGKALWSKKVFPNAPATVLSVSPDGKRVAVGGWAEICVLDARTGKEEARVPGKDLSIKLIKWLPDGKTALVVRKNPDRQGIPEDRTITLYDTATWKKV
->SRR5438093_595488
-YNIGTYPTKSMIWVFLPSLEGLFYAVITASYLGLNKTLPRFLDKSLAWLGSLSYSFYLNHLFVIDVSYKICTALGWKVARFADALIFALLIVFPPLIVTSAATYYLIELPFLSLRRRYFRDEHDGVYSSRQPSNHESPHLPFERDDAKNVQLSSX
->SRR6267378_3168319
-GLRRELSTMNSQTYRLQLCSSDLKVFQRTNRFCTGQRCTKLHLFQSGWTVSMTNVKMQISGKDRTHAPATTVFASIGFASLLTIIIAAPAAWDSRRTEDERVAPLSAKSAAGRPRGLWYIRSGQWQAHARTLVAAIRYILQNDSETNSGKSDGSCPALHLAMP
->SRR5919106_1596169
-LSRSFLRCGHASAAVRSRCTDELFALRSALDLNRQDRADALRVVLALDDVGLERVDLLGHEHFVVRTDRHGDRLGKAEHLGLVLGLAGVVLLPVRVADLWLGRHDDARLGTIHPGLPRTLGADDLAVLVLGALFTEIPDGAVGVLGEPVVRVLDDLAVEGDGVAYDDARHAHHLARLVCDLHNGALKAVLGATLVHPLSTRLQWEIGVVHRGGERCRIDGRCVRDLGFVRAARSFVILVAHSRGEDDGSDRRNDGCGPDRDEGGARDRHRQSSPSSASPASSSAPTTLNDSSSWTSTWRPLSRVTSTSYMLSSSPTSVPVTSPPPVCSRAASAARSYASPEMGRSFSASSPPAATAVPTPAPTTVTPAAAAAASLDLRFIADSSRRGWTLTSCGQPAESRLKARAYPAPASYPGSRTVNRAPPSVLSAIETSPPCAVTNSATMASPSPAPPASRARASSSLTNRSKTRTLSSAPMPGPSSSTSRTTQPSRSASRSRTRERACRAALSARFRTTRRAATASASTRPADTAVVSMWRRVFARSRRASSKTRSSRSSGLACRWRACSSAAARSIRSSTRPWSLRHSALTVAPRSAGGVAFGX
->ERR1700674_3395430
-XMALRPARPRLAGRWLEPRGDPRPRGMAAGPTGFARMGPQNPAYRPSPTAFYVPVGFVIVPPAYSWHNLGMAVLAKIGKPNTAPALFRLLEDSALSRAALGCCGIPLAMLDANAKSSPVTYVNSAFEAFFGYREGEALGRSLAAVLLRNDEPLLQRLLAESPKRWEISAWGKDGEARHVEAALAALRDASGKLTHWVVAFSDRAELERLRSEVESLKSLAAASLGIGIEAGGKPARGSQKARIEVPAADELHPDRQS
->SRR6478672_5938487
-SVRRLSKETILAAPEKIFTALLREINASPDPKIKRACGNSWIAPHNWEGFFLNFGDMIVKNGEFEAAKEIYSTAKLSPSYNEWVYEPALEKRLLEMKENNIAFNKKQDVFALNGNDQIMINSSMSCTGCHQMSNSEFIKAGYKEP
->SRR5262245_38459693
-KSVAAGQQECAERLTPHKRGKAFPRDERRKSGTVWRLGLTFAPAGVCEVYKFTTLIGCILAQTLGAARTGIAAGPDRPTERTGSPGPVRPFYGRGAIGGVCGFGAMPVVEPPPGAVVVRAGGLWYWKSGAFLSCSFVHVTCSFTLVGSSLPMAAPAPVVLPVLAGTTLNEFMSMATLFSPMPRKPPTPTISARILPCLSNRMSLTSPTWALSGPSTSVPLNFENTHX
->SRR5215831_1038994
-TPDGTSESNWTNFFNIEKNLLSSNVIFPAIGNHEADGVLFAKYFALPQNGASGLSPAERTYWFKYGNSMFIALDANNPSGGSQVQWLQQELAAARADSSVQNIFVFYHQCAYSNGTGHGDTSTVDSAWVPSLEGNGGVTLVFQGHDHIYSRITHGPNTYIVAGGGGAPLYGTGASTAGTVVKTEASHHYIRVQVNGTYIQATVFRPDGTQIEAFTVGQPGGSGGSGGGGAGGGAGGSGGNPGSGGSGGTTGSGGSGNGTTDSGGCQM
->SRR5215212_9325299
-NKCDHLSTLRLAVIVVAFGRIAGVDPILFSTCVVRHVCISHIRQFTGGHFGCRSGRFRAIDNYLGVLIGQNGGCEFRDLIGRQIERTRKVFVMVSSITECLYEHEVFSSIDLPFQIFSGNCIHSIFLLFRGHNSHDAVVVLCCGAPAVAIRGGKINESVRTFLHFTYAAVCAFEKILLTHDVSTVEYHADDPGASKAAKKVISLKLRKCQAGVKHPACGCASRRVFKKGRFHSLLCLPVMDDRPAVILAPLDEIKLIASISKPFKATWAVLSFENKIRAWLPVDPLRISDSIGPDLGTRSLLIDEWIVRGN
->SRR3990167_6373537
-CALPICREEARDLKNEDRKATRITRAKLRGQNIIERATIRIDKLEKLNIKATDLARKMQEKEIDITLATASLQAATEKIALARASISEAKTMLDQLENAEDPLAVAKNFKSKMTEVYKTLVDARQSIKEVFAKNADTSYMRTFIEPMKNKNAVIGIVIIIIIIALLVAVRKQKYAIAPIDEQPATTAPTTPPPSITPDTTTSINDESALRELDIELNAEDDTVLPDELNIETELXX
->A0A0J8TGQ0_COCIT
-MASMRLAFCGTEVPGIRGTVICPLLLVDESFWLGEKVRPWVLAGLNLLEFDHCTYSRLAKSV
->SRR5262245_63831105
-LSRLLVKSFMGTFLCAVVFLVVSNSIIVYEVISYERSQLDAYRSQWGRASAWVSGLGRLFFFSSRRRHKICLSDWSSDVCSSDLCSAFGRTGRNYPRRREVGYAPLASSARFSAQQGLASLSHKCLLAPSLPGFPRTVQPVRQTRSEERRVGKECRSRCALKTIDKK
->SRR5262249_16412955
-EVVLQARKGLRRVFRFQLRIGHRDDSRVVVHGDRATEVAVIGAEDGLTERELAAELLREVVLDAAAQEPVVVFAMPLGKRAVVVLIEQALDGAGRKTRCNHVARGTDIGDPRRRLRLLVTQTQIEPSVADARLTFDVRGIDLFLYALVVVELALX
->SRR5579875_1120949
-TIGVDDLPIAKGTLIDQQVATNEDANGGDHAGDIVADVELVHGDLAGIASSRFVRLNDHTGADPQQADGRSDQAEGAENQWKENPADIACNLEKGHTEDHGADVLSGGGLEEVGPTSGAVAHVVAHEVGDDGGVTRVIFWNAGLDLAHEVGSHISRFSIDTTAELGEERDETGTKAETHDQRWSGSRQRGTGQAAVGRENDGDAQERKRDDQEARDRAAAQRNHQCFTKTAPCRAGGTNVRTYRDQHADVAGDTGAESPDQKCQCRVPGQANLDGLAALTEYGQYNGDHDSRDDCQCGNGSILSVEESYRSX
->ERR1719436_269911
-IIHKFSCMPEGPFSPPSKGQYQRMMGSSSLSFLCQQALPFTSLFLINKNIPSTRLRAESGAPPKSKAIGLSFGFVEAASVEELALAKLLGWKVRVIGIFACFIVFRISPCFFCFTFSSFFQIILFLDRTDIRISSGGVHNNTKTKRFFLPCNRVLFVRVRTWFYSHFLQNQSSGDKLSX
->A0A137STU4_9FIRM
-MKILIVGAGRLAQRVVRMLSLENHKLTVVDANAEKLGKLRRFKNHTYIEADPLGLDFYKSVNLGDFDVVVCLTRSDKTNIIIGSAAKRLGAKKTIALFKEVSPIEDLDDLKSSIGIDEVVSLNRESAQAIADLVFDDFSGKSDFFAKGKMQVLSFRANNSPDLINKTIEKVGALMPFLIVALARDNKVFIPNGNTIIEKDDLIYIAGLTKDIQKFRHIYFPAKTQVESKNIMIVGGGEVCEYAAELMSKKSCNIKLIAKDEKNVKRLRRNLSDALVVRGDFEDFRVLEGEDIEKQDVFIAATDSDELNIVTGLMSKKYKVGMAISKVEGLSYSLLLDELSIDQFVNPIGICANRIVEIIRGNKGLNTFVSFSGRAEMWEVKLRQKLPIVDKKIKDLNLADGIIIAGIEREDGLILVPRGETVIRQNDKLIVFCKNESLKNLCKVVNPESTPTFFGEIFR
->SRR3990167_1971404
-VASAEQADAVFLLDQRNVQAIEAGTGHHAEVEGHGLALIVEGEHGGLFFVHLCHQRFAQLHKAGFLAAGDRVSHGQLLTQWVNVYAVNLELIVQVRPGGQAGGADITDDLTLLDVAAAADALGKAIHVGIQGAVALAVLNDYRIAIATVAAGQGNAAITGGLDRRAAWGSVIHTFVRTNLVQHRMAAPGAETRTDAGEIDRGADKGFAHAFASGAVVAAIALLVGVTHGGVGLAAVGEARREDIASADLLAVDHFLFVDQLELVAFTNIHGEVDVVAKYVGQIHGQTVRQAGAFGREKQRAVDHAVAIGGLDFRFDQFALETEALLALRQGNAFQVAELAVQAFQLAVGIQVELKRLAYFQACQLLGFLTAIKHVMQSGCAQAHLGKYRGQRVAVFHANRVLQWVDFFLRFFSLCGLQLIASWLLCSCCIGERXX
->ERR1719397_1477701
-QRSRGSQRWMGTRRTLMERFSTTHSSCLLLEMEEVVSRTEEWRWKAMEEQKLDRSKKRSNLCNISKLSNGGNGGTNALWDFFFAKIQTQCLISKQKLCNISQHSYGGTGEQMLDRSKKLANVQTQCLISKQSFISKQNLCNISQYSNGEEWGEQMLDRKELAKMVISQHSNSX
->SRR5690606_35020854
-ALVRAPARRVATPPAAATAGDGDRRLRAGLVFIARHRLLRTLTLVTALMNVWWAAWTAVLVVHAVSPGPVGVSEGGYGLLLTAMAAGGVAGAALAEPARRRFGARTVLALDVVGTAAMVGVPALTTDPWLIGAAIVAGGAGSAVWRVIGASVRQLVVPDRLLGRVYSASRVVSWGVLPLGAALRGALGEALGVRSVFAVGGIAGLALLQVFAIAVRPGDLAAVGLGAQRTSRGRSVRWATSRPASTRASVPPHTGSSCSTDSTPSKPPSYRASTSRTQSTX
->SRR6266498_1588512
-ICRSWERSTLEVNSTSSRGPGMDPALGWSQGLAVEVGGAGTVASAEIVLPRLLADRVGLTTGLSGALARAGFIPLRDRGRALTDAACALAAGASCLSDIEAMTAQVEIFGPGGGASDTTMLRVLNELAARLGSDGLPGRKLAKTMAGARAKAWAQIVARHGQLPAVKVAGTGHTRPGVDQDQDAGAPRPVLFVRLDATLIEADSTKTGAAGNYKGGFGFHPLTAWCSNVGDNLAVMLRPGNAGSFTASDHIVVLDAAIAQIPAAWRTDVLVTIDGAGASHDVINHLTALNSAAAHGRRGRRIEYSIGWPVDERTLTGIGELRESDWTDALSADGKPDPNASVADLTGILRHGPGGDTMSGWPPDQRIIARRVPRPVGEQAKLGRPPRLALRRVRDQHRHRTDPMAGRPPPHPGPRRGQDEGTKDLWRRQPALSRLGPQQRLATAGGAGLLAERLAAPPRPRRRTRQSRTQNAALPAPGRPSPPRHPRPPQDPEDPTRLAMGRRSGHRLRTTPRPPRLNKRPVPTNSTTPADQWTRRPPEHIGPTNLDPDHHPAHDNRKSHYHEPRTPPRIIQVHAVRRADDSAAR
->SRR6266481_5783698
-ERDQYLRARPHVGRSRERQCPDLGSVGAPDVRQPQRERPEPRGLRRHSADVLLVRPRERCASRDPGRQAPRWVRPERLGDGLMALLSILTSVLSVLTPPAKPLVPKPDPVVSTPTPGGADVQTGRALPVSSGPSRGLASWYPMRPATCDGISVPTWVKAWTASLTLPCGSLVRLSGPTGSITVPVWDRGPEGWTGRLFDLNPAAFIAVAGNLWSGVVPVSWQPAX
->SRR5918996_3897299
-ASRWFARVRFDHVAMVTPRQAPALALLGVAAVLTSCGADEDDPEPPPPPTAVASCGEAFLGSGDPNWRRDATTSGPFGLFGAGRHFQRPVMRELDNGQLLTKLPVIVDGTRPVVLSVPEDELGRVGLDYGDLRTERAIED
->SRR4051794_24721663
-SGDGSVRRQQGSPRRRPVPGSAAQVCDLQRGGPAGVRQPRLDLLPGCEATRCDGCQPAGPRRRRPPQGAGRACRGGRRPMTGGHANARRDMSTRSLISTDDLSDAELRALVERGATLAAGARPNDALAGQVVGIYFPLTSRRTRTAFSSGALRLGGQIIAYGPNDLQTNTGGSTEDTGAVLSRMLDLLVARTGGTDAELRGWAANGRMSVVNAMSAQEHPTQALADLSRITRHFG
->SRR6185437_8036068
-RGAGRFRFAGAESTLRLWAAGRPPTGLAMRCRSPRLPVRFSRTTDSWRSSAKRADKDENLRNDEPTGVCCLRRLFQLADLAQLVVQGLEAHAELLGRLGLVAAMAVEGLLDGLQLDLAQTERAEGLEVRAAQPAVGELAGQMGRGDRPAVAQNCGVLDDVGQLAHIAGPYVLFERGDRIGGEQLVAGLRVRAKARQQVPSERGHVVDPVAQRRQMNX
->SRR5215471_7291055
-APGLPQPTSEQPTKPKTPLSPPPWFVRGFFARRLNVCRAPDMEGRSLGHHLEFDMQAARQVRWTKTLHLGVLALLERVLHAARALLPRSIKRHLARFARVAEFALTPSVQLRFDARSTALVDWQALLPADTFADGPIVHANNGLAPGGVERQIVNTLVGLQRRQRAAGLLCLRLHDDA
->ERR1719233_1599910
-FAYAGSFLKDPAQSTLGSSFFLSWACNHHQSHLSLVLYHLQNLNYHSERLWLPWKFLQSFLLLLEIVFWILFWVRLPLFPQLLGQLSYPSLKGLCYQQFQTLPX
->ERR1700722_19934493
-QLPWRNSQFSDAPGIEVSLTIETVLSNLNSLSRKSQCHDVAGVRNRPESLRSNAAVKNPPVPSLRWRADPSPPGPRVRAPRGGKSGKMTRRRRRKVTTTRSLDARLTSAGPKRILALDCGGVRGVISLAYLERLEAILRGRFGPATVLADYFDLIGGTSTGAIIATGLALGLTVERLIEIYLDLAHKGFRRSAFSAFLGPKFRAASLLEQIQIQVGDETLGSARLRTGLAIVAKRIDTGSVWVFHNNPRGPWFDPAGLDPAAVANKDLKLTRLLRASTAAPTYFAPEHLEIAAGVTGTFVDGGVSPHNNPGLLLFLLATLEGYGFRWPAGAEQLMLVSVGTGHHPMTQARLPGKGSPSALLAVLALRSVLDDCSWLGQTMLQFLGT
->GraSoiStandDraft_51_1057287.scaffolds.fasta_scaffold520000_1
-VSRNPHGSGSGFATPQVKRGRPASTPPGVDTRALANPTTMHTMSPDTSCKEERPKLRKIDLGEPITVDFTGASRVATSTSMAGSLGQDADATAKVNELRQQCIAAHTEGQVNFERLDGRALHLEAEVTKMALVVAEVQRVVVDIHAQQERLKVETTRVGDELHGQQAAIVEMGDRLVGTTTSFTQHLEDMKAKLEETAGETLKKHEDNFTDVQGFAKLVDNKVVQVEATFAVMQKTMEDIHVRLQATESMAKRAEHQPPPGPPAGVRAGRWMGSAMGNAFSIGKATASCSPGCTDDHTASQSSAGKSSAMAEMTNIINEAMTMVSSQFEMV
->ERR550519_1962169
-ELSASKSQGQMALEMILDEATGVFCHDERQNLSGLFESENCKINNHENVDIITGNDENESLGEHELEVMKGLEVEQLSTSKLTTKKRKAKESDEVMKENRGLDGNILSTVLKSQSGNKKLKVTGLDGSFLSSVKKTYPRDRKLGTKITCSKCDYTTTRKDNLNRHCDRVHLKILYNCNQCDYKTSCGQSLKRHIEAVHEKIPQTKLACSKCDFTTKRKDNLNRHFDSVHKKILYNCNQCDFKITWKRALTRHIEAVHEKKLETKLACSKCDYTTQRKDTLNSHFNRMHKKILYNCNQCDYTTMWRENLIKHNEAVHENNSYSCDKCDFMSTSKLIVKKHVERVHQEINFHYNCSKCEFTTTHKQNLKNHIDVVHLKISQNCDQCDFTTKYKRALKKHIQVAHQKLGFNCTQCEFKTMWKNSLKYHIKGMHAGVSHTNYQHNAINVHKPSLSSRKSVDGEVTTNCRTRAQNVSRDVTGAVNPIRKVSENPSSISDNTEQKRVQKKSETKGGTRFTMKKRKQDEKTSRLEX
->SRR5687768_17643082
-LLYTGLYHSLLLLFFLFQHPSTTQTYPLSLHDALPICRRVLDQAAARRCRRHHAVQLPGDGPDVDVRQRTRLREHVRAQAERERSEEHTSELQSRLHIVCRLLLEKKKENINNTRLTEYR
->SRR4029434_9585403
-VIFFSLSVSLFLSLSLPFSLSLSLSLCLSLSLPLSLSLCLPLPFGCQATQLGCAPWWLCCVGIREPIPSHSHGNRVPECLCVFVCVCACVRVCMCVCVCLSVCVCVCVCVCVCVCVRADRERTRLHYTHSCISYSVLFHKNRTSAAVDHIAS
->SRR5271168_4498088
-RAGGVGRRVEVVLRCRRRWRRRLRADRTGARQQERGDGAHEQAGRSGGLNHRTASPTGAPLRCPRRAAPGAPRCFCIPRRRPRSKATKGCPTMPRLAFALALLATGSTSPAGATWLYCTATGTDGTGAIEFQTTAADVGAVPPARVAYFKQRLVQHATQADADARGMQANCFSFDDQTAAMSDYS
->SRR5713101_1804337
-HARIQARLNAARDRAEPGEGRPLAYSHRHRRAQDRNRMRLRAHRCTPARVDEYLSAVRLQSDTSIVWCCSNRRIAVLLVLYSSSMSPATPESGKAAGSTHERILRVSKSLFANRGYEHTSTSAIARQAGTSESQLMKHFGNKAGLLEAIFVEGWTQITDAARVAIQDVTSPLLKLQTISGCVLRSLERDPELKLLLLLEGRRIRKEGQMVSLTQGFLGFVQLVDGVLYEMRDLKILRPNISAQAVRSALMGMLEGMLRDRFLAERLGFPADFNHEQIREMLATAMAAFVRAX
->SRR3954470_16959927
-VSTGLVLVGAAIPLAWLTGVVGLGWPPNASARPASAIGLDRFGAALHLTNDPLGVLRAEIALQLTGFAALVVVHRAHGLDACGESGGSSDTVIARRLRHVVADVPTTSRRPAATTSASRGLGIVLGAPTARPDRPSARDTAAAARRLRARTSWRSIVLKEHGARRRPRGP
->SRR3954468_5071070
-NGALIGSNTGGAALGGEQVVTVTGGGIDLKGGGIGVNNRASITAVNANQTINATGTITVIGGDSGGVANSSNSSNGAFIVDNTTVGPVRTQTINAGSIELKGGAGGTENFAAIGAAKQVITSVGDVKLTGGNSDGVFTGTRIGGQGGAAPTATDLTLTTLTGDVILTGGSQANAGARLGSSGLTATTPATPVAVANKVTVNAGGNVILNEGTAVGALIGYSSAALPSAGDISVTAGKSIQMNGTTFGTAIRTTGNVELHADQPAATITQSSASRVLASGLTTTSDGSTSLNGQNQVSTYNGKSTSAGITLNNSGPLTVTGLQAATSSSITNNGAMVINGALNTGAGSLNLTTLGATSGLSLSSGAALRAVGSTVQLTAGGAITEASDAVIQSGSLITSSGGATTLVGANQVSSFNGTTTGGDLTLINSGTLDVTGLGVAGNVSVTNNGDLTISGVASSTGSQSYGAATISEASNAFILANGLTTTSAGNTTLTGPNEVSSFNGTSASGDVSLRNIGGLNLTGLNAAGSATLAAESLNGAGNVSTGTGFTVTVASDSLLSGVISGAGGLNKKGGGTLTVSGNNSYAGDTNVLVGTLALGGSDRTNSGVVNISSGATYRGSAGSFTNAGIIGGNGTLDVAATSFTNTGTLRPGGAGAIGTLTVAGNATLAATSIVDIEAQSATSHDVLAVTGAAALGGNLNVTPINGYAPANGDTLTPLTYASRSGTVFVPGTWLPTYNPSNLQLGFDSTINRWVGTTGNWNVAANWRPGHTPLASETVLIDVMGTQLVTLSDGSRFGGKLVSFENFLLSGGSLSLGGPSAFNGALSLTGGTLQGAGNVTASGAFNWTGGTLAGAGQFITGPGSLV
->SRR6185312_6080286
-RAEEVEELLARHPAAPPHHRLFHERDVRRRSAERGEAEPQEEQRDLDERALHAGVKRARSAIPSVSSSRATASTIFSKPPCGSAFSLSSKRSCSLASSFSPTSSRNAGKSTVSSRAACGSYMRMNLASASASGLRPASLFMPAAVASLSTSAVTRR
->SRR5215213_10844578
-XMPKTCTRCNSEPVLSARSAAVRAARSASLEPSVAKRTLVGKMLIWCPPRWTLALRLHDASRTYPVRTSENYPSTHFTWVNRGRKGILRTSASVLALVASGTSETASFGKEDTKMYWYNPTTHSSENVAAPSNDSQAIQMLAGTQDSAEFVKEYCQLRRSGTPIEQVLVLVGHEFRLRQPEYQLVLRX
->SRR6266496_2280139
-ELTMQYVLRLFENDVEVSTSSVAITPDAQSYSSVGQTIDDTWRVTDVISQARTEQLRKEQSPPRFYNYDGSVDPINVSGKEHSAQGPFMNLHCLITVVNTTQAPIKVNPVRLVVDGQERTLENAFFRLKDGSRERLKKISLRGNDKEDYELHFMFPDDQCPTSKDGELWVSSDNRPEPITLKVKFRX
->SRR5439155_630595
-RTAAAIVVPPSVASASASGPSDSEPTRSTLSERAGGSAKTGPKSGCVPGLANPLMRTSNASRSGRSKIPTSVATTAVPPAETNFFTFWASAGVIASVAPRMNSTDAVDASGANRSHARGADEQLAIGERRVPADRLARDERGEREKVERVDRLARPTGGERVVRGAEVAGRIGTLRADRLTQRHLGAHALAEAAAERRDDEEDDRRAEDPEKRPHQTEIDARTLEPREEPLDRARDGVEERRRGSRVVNGAQRVAQRRVRTRSLDRRX
->ERR1719277_1000244
-PDRASKAAGLRCAAEVELWEEMVVAGVRQVLQHHFGEVLARAPTTFVAWVALRTVRGDNPVQWVPQEDRLRPVLALHGIHAELASLLEPRVHHVAHAGRKEIGRGASTICPFLDAVQGVDHPGELRAGVLRDEAEEQPEPGHRENVLGDWLGQAVYPSSSPLLGVALIPAQVEVGSERPAQ
->SRR5947207_102588
-DRREGQIPAVLAPRRHVLTCLSNNASQGVLAMSRIPGLRALFVCSALSFMAVAATAQTKVAVLNLQRAVLESDEIQKASAAMEAKFKPRQQEIEKLQRDLQGIQQQLQAGAGKLTQQAEADLTAQGQRKQRDLQRMTDDLQADVTADRNDVLGKSSQKMSEVVKKLAEKRTEEFLALLRKGDYKGAYRLWGCTDEKPCRDYAFKNFMDDWGPQSVRADNPPTITKSRACGSGVIVTVNSSKGDATLWVQQGD
->SRR5207247_709107
-DVLAAHPRLQLSGEHNASLLRDREVHVPGRPPEPERGRPYAVTECAVRAVRAAVRVGAGDERAGENELLLGEVEVEDPVARRRAVAASGQVTSGGRRTDSGNSRRPTLIIPPERRISSSCGDSAAGSYVLPRVSLLSFLVFGSNENASPSCASSTASRLWTTVSPRFSALRRKMSPIAAPHTMNISRPASSATPLRPAGLISRELPMAQRSPATTNVSPRCTRSRKLGLRX
->ERR1700688_3359193
-RRRRRTLERRRLSAARARDARRDGTIGVHRTGRRLRPRSALRRDHSRRVACDDRGRAGLARCARRFRPAQRTPRRALRRARSRHDHLERHPHPRPDPSPRFRGVRKIQGDRQRSQRPARRRLRRDADRATARNRRSDRRRDLERPWRPARRGASLEEPRRRRLRRPGGAPRDPRALQPRRALHSVRPPCERRLHRSREPGERRTCPRDGDRCRARCALVRRRRLPLTARALRRARWRRRGGVFRRAPFRRVRRRRHRVPWRFWGTCSGRRRLSRGRALSREPGARKSRRRRGHSAPHRRRSAARRVAAASAANACPLHRRGSGRGSRIPPTSRASARRLRDCARCPARRRRARGRGRCGAHRSLGNVAGAGSYGRTRRGRADSALRARYLPRRMSELEAIRTEIPGPRSRELTAVLARTETRGVTYVAHNFPMVWDSAQRATVTDVDGTRYLDLTSAFGVAVTGHANPAVARAIAEQAARLPHAMGDVHPSDVKIALLAKLASLTPLDEPRTFLCSSGAESIEFALKTAFLATDKPDLLSFEGAYHGLSYGALEVGGIEKFRAPWRRQLLDRTVFARFPDRRIPSTAARALAEIEAAPPRRSSIGAVVVEPIQGRAGVVIPPDGFFHALQTLCRDRDVFLIVDEIYTGFGRTGTLFACERESVRPDMLCVGKALGGGFPLSATILARRVADAWTPSRGEALHTSTYLGNPMGCAAALANVGEIERLDLPARGRAGEAKIAARLEPLRERPDVVDVRGRGMLWAIEFRDGAAAAATVVRALQNGVITLQSGVRGESLAVTPPLVIDDAQLERALALLCDAVAEKVMTX
->SRR5262249_19266331
-XTLAARQLASRFGGDRGSCDWRHFGRLAVFTNQKKERRLQSGFQPFVRLRSSEGYVYSAANEFLREVEALKREHLSCRQRRESPRLPRETDTPVRAITSFHADLRYGGDLHRADLAWAVHAAARGLSLKKQDSRAPHRLRDRQVLNRVVWRACAVTX
->SRR5512143_347789
-GFTGCRRVRGVECCESILQLRGETVLGSVRQVKATDQRNEIVDLSRHRTRELEREGVDVEGPRARNGIDNSPDAVAHADVAERLVNAWRVGDLVEIPCADVVDKNVVTCSRLRLEGDQVSGDSDVALLAGNGDLRLCAASDGLVIDVGLAAAGRRINRDLAVGVRETVLARCAGECSNGEYAWRGLGRRVDVTARDIRLALLPNDGVAIRTDGGVHVVQAIVGQPGHGSSAQVIDTDFALL
->ERR1739838_676663
-EIVSHFESDTNSSLGQISDNIGFSLGEGGVSCNGGGDQSVVHFLVFSAASSVFRSVFSVTGQTKTSVLGGEIPAILVESSVASVGLVDTVQVLLLRKALPLSRDYCVVGLDGTDSSESPARSTASLVLDSGSFTLRSPVLGCGDISYKGAGEGPVSVGGGVVSEISCLLFDRQVSELVEALPPX
->SRR5918995_363747
-HQPSSFGSSSPAAASPSSASKSTPKRSKVSPCSASTPSPTTRPSSNKPASPSTSTKRRRDGPTASIRRSANSSAPATRATARWASAPPPALSEAMLTVAVRPYPAECTSLPDDPTDLPWSVPHVVELLHPAPARRARRQLSGQLLDNSTSHRASVLDTLLMLPIGMDALDARLIRAMWETARAGVMELTRQLGVRRATVRTRLDKLQQRGIICGFEPDLDLRAMGYEVLAFVSLEIAPGRLQAVAKHLREIPEVLEIHSVTGPADLHCRVVARTNDHLQHIIGCILEAQGINRTTTQIALTEQLRHRVLPLVDLVIDHGEQATTEDPWRGGPPNPPAPTAVRSPGRSA
->SRR3954452_4728668
-DRDDRPHRRVAASDLLDDQAVARVVERADAVLLRDRSAEIAQVPKSPGEVDVEPLRPIAVAGARDDLAVGEVASGLGDQPLLIAELEVHLNPPRRQTLQLSSSSRARTPANASAASRVRGPGASSSTSSIAATGWTSRTVEARNASLAASRSPRANVPSSTWSSRISAARVIDSRMPTSIAGVLRTPSPTQKIEEVGGSRTTPSGRTRTASSAPAARAIRLACMLAPX
->SRR5215813_7369292
-CIDTTSMGVSSAVARVGASVRVLHPQDTPSQGSRFVAQSSSHRIRRHRLFFLWNVTQIELPRCILGERSMGGRPVDTPEDEILIDRMRQGRTDALGVLFDRYARLVFTVARRILRNDAEAEDLTQEVFIEIYKKAGLYDSGKGSVK
->SRR5260221_1576336
-QITLLAVDRTAARNPRHGDELSSSLKLGCARPIRLPHASQHWHAAQGGPGVEHPGLGRRHGDAQDLRGFFHGKFPKLVHLHYFSTAWPKAPDGRTDNLPALTVAVIFFRIRRPVRELPLRPCLFRGARLVHRNFPDSAFLSELSQRGVDGNASQPGGKTRAPIETCEVYKCAQEGVLHCVLRVLAIACDSKRHAENHFRMPFAKYPERGAMPASCGGYQFAFAPSLDAARRVCFVKFGLTCTHQASVHRLLLTPVSTQQLCPAVLRVSFSNPLPDVGGTIFQMHSCCFTACQELLNLPVHQPYILQIQDNQSRAALKAEKGLQFPDMLSLQTTDX
->ERR550514_625570
-ETFKIISVTCTNEWTLPNPFLGAAWVTSPLVGAPNGVRPSDYVFNWDYQQKEYPLISIDTTVNNAIVPNAQYQFEVFINGNLNNPKQVISEKKGSGTFQYQPDVAGTYTFRVYVSDQCKTQIYDMPTAFTVGCGFTPEPQITGSENVAFGVTFDNFEYRVRYDNRKAGFYRVRLSCKESKMTGLPVSFKWRDVCKWNFENSNNLPTNTTKDGEITLQPIQKSGTDG
->SRR5262249_32914110
-XAGVLTMSIAGSVAWQVREGSEISELRGADLELEVNSAYRSGGDRKHESNIVAVRITEMVIHNNLKLLGGADIRVDTLVVHGKRPGGKSDLYQPGTLRFPDVRDEQHLPFGEKGVLIYLGEPRYFLDIFINVSRDNKDAPDLHKLLTGESARNFASX
->SRR5581483_4550651
-TVPSFIAAVAVPEITIPTCSTSQNATPACGPTCSDHLHPGSYVAQPMVIPPTLTISNFPFANKRTSSGFSNRFKITSSMLFPRFAFLLLSFYFCLPHSGHHLQPSSVHLQGRTDAVTRPRRTEEHKEVGQFLRRSEPPDRSFLPGDPVKILSPVGPGPGHSLSCRFLPGSRQDQAGVDAVDTDVVPDQFIGQALX
->SRR6478609_4614806
-SHAMEGERPAYARIAGSDFAALSIEEQELVMKIRHVFGALTVTAITCGMTAGVSIVRAQDHHDPFLSGTSPEAVQQSSPEAVHQSSPEAVEPVVVEQTSPQVETVQKDTPRDPYILKTSPKAPKVKKVKHEKEAYSGLPKGHITIVGCFYRDVDGDGDHAHYMLADAKMGPATAVADQNCTPSGAGQLIRLKDADDVGLTQVASNRWVELYGEMGSPKDADDARKFEVKSFREVPLAQRPRIAILIPPAPAPQAAVETPPAQEVGVTESPKPMATTGETPYERKLPKTASELPLIALLGLFALAGGLVLGLVDRQKVLGRGX
->A0A1W9U6M8_9DELT
-MEIKINRDVLLKGVSRVQGILEKRSHMPILSTILLTTKQDNIEISATDLEIGFQNSYPAEIIKPGSITISGKKLLDITRETNSKNIYILEKENNWIYISDNKAHYNLSCLPADEFPILTEPEGIIMIEINSKILTEMINKTIYSITMEDTAFKLSGVFMEIVNKNKEDFLRMVATDGHRLSLIDKKIPKLQEIDIQQGVMIPKKGLIELNKLCLENGNILFGIKQNNLVGKKEEALIVIRLLDTEFPDYKDVILPKKEDKRNIITVNRKLLLESMRRMIIIGGDQYQGVKITIGTDYLEMVSVNPDLGDVEEKIEIKYDGEPIDKKKYTASNIKVLKDLLAVRKRPAMYIGNTSTEGLHHLLYEVVDNSVDEALAGYCDQIDIKILGDNSVIVKDNGRGIPVDIHKTEKLPALEVVMTKLHAGGKFDNKTYKVSGGLHGVGVSVVNALSEYLEVEVYLNGSVYYQTTDFSFDIIRQRMRELAFLNTGLKINIYDDRTHKEKKLFYKGGIVS
->SRR4030081_3248946
-WPPAAKRAPPTSVLSTLSWRFSLASHRRADRRPLWVRGCVKTLEPPRAQCIFGHVGSISHDFVGLNRALANLHGMLFAFSHSLGRERSFERQVGIRSAFGAARPEQAVWRGSALGPCR
->SRR5262245_55954626
-PRAPIRPTRTASTTCRATSGNGCPIGTARITMGGERCAIRRARRSGRCGSCAAGRGSTRTSRCCGAPIVTRSRPTPTRTASDSGSYAADSGSLARADLRRRGAGAGAAAAERRRDGRRGDDPARTGSRVRHRRRRDAREEPARGAAPQRRSDERRAAASRAGAPRVRHPAHDRLRSAAGVRLRAGQTRAARVRCPQRHRSPPRRHRPNRGNPRRGGAVGRDVGERHPLRSEGSRRRRARSAAPGGRRCARPSRCRGLWRRPGRRARAARRRRPRTVDQPAAADGPDDDRRGVGGADAGRTGDDRNPRARDPDCFAAMTDADYQKARRWLIRRDPILADAIKRIGPCRMAERQRKDHLTALIGAIVSQQLSTKAAATIFGRFAALFPDNQITTAAAIDAFDDATLRGVGLSGQKVSYLRDLAARIADGRLNLDELDALPDEQVIERLTAVKGFGRWTAEMFLMFRLHRPDVLPAGDLGIVNAIQRLYRLRKRPDPKRILKMGELWRPYRSVASWYLWQTLRNEPLSTAPRSRPRSPAKSHARX
->S3BF76_9BURK
-MNALGVWGQFFSMAILGLVLWAAVSDLLFRRIPNAAVVSIVLVEAAALAAAALGGNGGAALGLLQSGSVWAVGVLIAGFLLYLTGRMGAGDVKLAAVLSFWAGSEALLFLILLSLVGGLMVLGLPILRMIETKTGFWAERLAEAFGRPLECTPIGLLGGEAQKGLPYGLAIAAGFAAVQFGVFSHIF
->SRR6266545_3847418
-SWRLPGRQGRPPPPSTWARSASTSVTRMGPTARCGSAAASPAACPCPRTRVPPATTTAPTPCGSARRTPTATCTSKAPTAWNAGHARPTRSTAPERRQGRLVADPLWMEHQIKFLCPTRLLGRSIPRSAAAVAQALVIPLVIQTIRRVPSGSVWIDEAPNLSGADPSGPTTSTWSTRLRIWRLGLRIPRGVDADRHGPGWRLPRGRGPLPVAAMHHLLERAPVGPLNRREGAVGGDAERDQQRTEPVLGKAQQAPRQLLVMHARMGAADAEIGGGQHDAHRRLAQVELDQVAQAGVVGLRGHQRDRRRRAGDVPGGAPHPGQLSELLPVSADHEIPRLLVAGRRCAPRGLQDPVQVLGRDRSLVVGPHVAPGPDRIPRLHLDLPQTRPERRARRPRPQX
->Q4DQ35_TRYCC
-MVIFLAYWRNETTQTGKHANRRKCVQMIIKRWFSRVHERICVFRLCSFLFPFFFLYYFYTCKCNSIATYVMHIYIYIYIYIYIYIYLPFPLFFYLFCISIELVKKRSQMVKANYIRAGRLVRIIRGPRQDRVGVVVDIIDGNRVLVENPADKKMWRHVQNLKNVEPLKFSVELSRNCSTRTLKNVLAEKKILEKYAATKSARRIAAKRAFARSTDFERYQLRVAKRSRAFWTRKVFDENDKKKPVSWHKVALKKLQKNAKKVDSKPAAKKRIEKARAARKAKAAAGKK
->U2C1V5_CLOSY
-MGADSMFEILLNSLGDTAVYVVRKDDYRILYFNDIVGEMVPGIRKGDFCRELWTGYKEACIFSGIGSKKPYSAVGFDETFGATVMLTASEIEWGEKKTPAFAITVKPYAMSGTEENGKEEKELLLCAMRLFGEVFLLDINTGRYLVYKSDGLPDTMFEEADFCDFNRLYGENLIHPHDRQVFYDSFTLENIRNRARERQQMISAEVRRKDRSGEYRYCELIGIFYKDREGISEKMMLTYRDTDELAKARIRERQANRRFVRAVNESYDEIYEGELYTDYLRQWKGEKSTPYFRSSPSFSEQIKWAADTIVHPEEKEVFLSRLSPDRLKEDFENGKSEVTISYRRLTPSGSYRWHSLYVRLSEMTTDCIRVMLYLKDIDDVKKEEERKQRELQNALAMAEKANEAKTDFLSRMSHDIRTPMNVIVGMASVARFVLQSEAKETANLQCDEKTGNYAKLLNCLEKIEMSSAFLLSLINDILDMSKIESGKMKIANREMNLKDTIRNIKVMIEAQAEERRQTFLVSVAPEVGEFYYCDSLRLNQILLNLLGNALKYTPEQGEIRLCVTAGKVEAGEQLIWFIISDTGIGMSEEFMARMFDPFEQQDFGGSRIFEGTGLGLSISRKLVELLNGTISAESEPGKGTVFTVKIPMKISDKKQKVRKLGETQHRETDREDSLRNKRVLLVEDNEINREIAVMLLEQTGIRCETAVNGAEGVSSFEKTVPGWYDAILMDIRMPVLNGIESAKKIREMERRDAKTIPIIAMTANAFSEEREEALEAGINDYLTKPIDAEVMYACLRNYMRR
->SRR4029078_11775012
-IAEGAVNLPIGDTAAMRVSGRWNQSGEGWQESLLTGKDHGKKDLWSDRALLLADIGESTELLVNVHGSADNSETPLGRGIGLYDASTGGFCAAVLAGHQDDANCAMEATFYDPQFRYPSVQGDSGRKTLSDPINQFDNDGHGASIRLTSEFDAATLTSITAYERFNYGLVFDYDGSDGEFAHQHAKSQIEAWSQELRLASTTNGPLSPLPGVALATGALRA
->SRR5260370_25801032
-THRLCLARRQIRVHRSNPSQKSGPMRCSEAPAMHPAPPAAFPGSLEAGTERHKLNQVTGFEIKVFFVLQLAVINSDYRREITGTLRPGVIVIVTGGYYVDAFQVGEIDPRFVAMDVFSYAATKAAIQNFVAVIQRQINSLTDYIDAIGVVLVQNPETSDLGF
->SRR3990172_1850163
-VGRRGAAGHIPAVVDGDAVEPGREARVLPEGGERQVGLEEDLLHHILGLLPALAQQPPGQPPDPARVPEDQGLEGVRVPPLAAGDPGRVVLRLGRRTHQPHPPGCGSVRLRGPPLYQEGSKGARLAESSRCLVRRPRVPPPGGGGYIMAGNQGFGADSGVKPREAGGEGGRGWPFGRRWRGRRGRWAAGSFTWWPPRATWPS
->SRR5580700_5373870
-XMPRSQSRLLDGLTPTERWQPQPGLVLSAQLGSLAATGCIVWLLAVRSRPHVHSLPGAVTQSVVVGLVAFVCSGMFMTAFQLATARSLGFDALRTSLPTARTAVWLAPTAILLTRSSPFAVGAALALVIGTTKMLYFQWAEFESVGGPLPGRSNRWLRTSAYGVALAGQTTIVCLWMGSPLLAAALLCVSAAGLTLMCLVADAYRAREPSTLPDSLLRILFTLILGVGLTVGGRIGGFGSSSETSGEPDDRARPELIT
->SRR3954452_18840074
-IARDALRRGYSRNPAHFLLWSEILPFWPKTLDGWFRDAVRRSAVLLASLIAHGRGPHAGGEPAGASRLPLRVELPWGRRGAPRPPRGGCRQAGRLLPRRADLVVPLAQGDPARARRRLPLHRPRLRRLRPLRQAHRPRLVHLRPPRRADGGAAGGIGPARRNRRRPRLGRADRAPLG
->SRR6185437_12615591
-XVHPRAGLSQAPGQVVLSFPLHVLLQAGNPRWPRRPAVLPLHLIVRAVHLPETGRTPSTGEGSEAGEGRAMTTPAEQPVAQPAAPADRLVPSARSISPWTTRQKIARVLWMFVRATLFRWSFHNWYAWRVMLLRLFGAKLGHAVRIRPTVSIEIPWNLEIGADTGIGDHAILYSLX
->SRR5689334_22958838
-LSDPERRADYDEQRFAGIRGAADLPPAAQRAAPPMRAPAIATAVLAFVLSFGVWMSQQPAVPAAKSAVVRPAAHVSPVPMVELEPESERLARLHAQSGVVATAPAPPDPQLEAVADVPAPSPVLPTSRVPDRRLAPAVRVSAHVPPPAPSTA
->SRR5215469_4716775
-PCLSITHDDVYRMPKHLADLERRARPYQACYVRWLASNIATIGGCVAFAAENFPQFAEMRNSARTPVGKRIIAGSSTMGNPMADDEITLETLLTFQLGDMEGGIALVLGYATSAEKLSKREMDTFAIGMTREKAAELGRALVEITDKAPVTRGPRRREHX
->ERR1711865_1142824
-IHPFFACLSHRAIRHFPGLLSSFITPDTRISVAFLGEVQTYIHLLPPGVHLVPDTPCRGFTQPRLVPQVTRAEQYRPVRLPFTLSFLSYLRLVRCTYPIAVHHNSFIPFHPSSPAPATACTPRLYLRPYRPCPAICYPHLLSCLQPLLLFNRYDYPLFVDPKHHFFYLLWLPCALLPLFSTIFILYSGTACQPLHQCRX
->SRR5688572_31128903
-FLVVTFIILFFFFFQAEDGIRDLTVTGVQTCAFRSGCSRQAPPSRSGPVFATRCSTLGLVSPLQWLRRQFRAACMARQRCCLTRSEERRVGKECRSRWSPDHLKKKKKKDMKIKEX
->SRR5436305_2025442
-IRARVEWFVQKCRCDRQGAEERAAERTGPLGQFGNIVEIARAPALLRMESVKRSEQAPAALIGVVVVSMFRGGNQKRASDGVTNLNFEPVIAARQCSDRDLMTASRSRIDDCQMARSSVFEMKNAFDVSGGKRAIEPDFGRPLPPDHAHRLKHSSIASFFDPCDCILYVSIFX
->ERR1700722_19574956
-LQLADQRTGKVVSTSYQDHDIAGYKRPAPALQRHAAASLPRDPTRQRLGKDWRGGGKPLVLFGHHPWFWFGGLGRLGQRPQLHAASLSGPVSVVGQHVTFPHHPGSRQRVGEYAVDQIEHGARGPEGYIEPRFAPWFAGRLDPLAQQLVRMIERFDIRALKRI
->SRR5512141_2661244
-XMGGPTWELFSCAIGNPNDFSALYPSERLAPSLNDSLPGIQITPFERGSEMKRILAAVMAVAFVISVAGFAVAAEKAAAPAAEKAAASAEKAATSAEKAATSAEKSAASAKKSAKAAKSYLLTGTIETLDPAAGTFSVKGRKGNVELKAGEKVKLGDFKVGDKVIVKHADGTASSVKAVKAAKVAKKAAAKAEKSAVAAEKSATAAEKSADAAKKAAPAAAPAMPAEKKX
->B3ZYH5_BACCE
-MNIKSVYKCIATTVLLSQIMSPSILHAQEVSDKAESGVVTQPENKRTGLMGYYYNDSNFSELVMMTPEKNGELKIIKEDHGELLPEGKRNIQSIRWIGYIKPSEDGEYIFSTSSDQNIVMQIDGKTVINQSPMENKIELDKDKLYEIRLEYRQDENGKHQNLSDLKLFWSRTNSDKIVIPEENLVLPNFAPGENKTKLIPETHSFDDNSIPDTADLCLDTDDDSIPDYWETNGFTIKGNKFVEWTDDLAKKGYIKYVSNPMTAYTTGDPYTDFEKSAGQMPAAVAKEAHNPLVAAFPAVGVKMEKMIISENKDYTNAEEHAMSSNQSSGTTVGTEVHVGVSENYGITGGVSASFSHSNTTENTISKSNGNTIHLNEADAAFTNLNVRYYNSGTAPIYRVAPTTSFVLGGETIGSFTAQANQIGNDLNPGDTYPNKELHALSLNTMDQFNAQPIKMNRQQLERLRAGAPVKLETPQVAGKYAKVLSNGDISVAGDWAPKLGQIENKTADIILNTGDTVKEEKVAAREYNNPEDKTPELTLADALKLAFGAKEENGKLTFNGHNISEHSVELFYDENTKKEMKKQLEKMSNKNMYDIKLTPKMKIVIKTPTILESGTDSNIDWETTNTNQPGLDDVGYSTANIGYGILKSKLEPNTSYVLSAYFKGTKHEKEIEFGIGSGKGDYAVNQKFELSQGGNWKKVELKFTTGDDVSKFNTVRVKNDRNDETRQVYFDNIAITKLGKAEKKFDGVSEDYIKEAHTFKSVHSDKKNGTNYINSINLNVNKPIKWKYKVKMNGKEVGDLKNISEPDANGVIKINFLDLNNGSGFLSTDHIEVYAVKEGLRPVKIAENHKYNMEAILKFKNAGESGMIEPYGDIRFINNGEVFEIWKDAIENSSREYTQDQPYKKDITFRTFTPITEESNIRFIANVKEEDYLANQDDILAYGENDPKDSKGLNGNIYFTGDVADDSVNIEYKITK
->ERR1719506_2373094
-ANGQAAHAAANYDSYTEAEPPIMASGAGSATYGTGAAYGTGAATYQRANEYTGGAGSLPIEAGAGAGQSWQYTYSSGGASTKYHDSAVSGSPGSTHVVTGSSWTNDRTHRINIDEGSRVIVTVNGRDVEGGAQPVRQAVPNNFPKPPPAQFAAFGGDSIATMRARAERHAKEEAEQILRAEQGRERTEEVRKAEQILRAEAKQNPALIIEEAQRIEAKRHRGRPAAAAQPVEEEEDCPAPPELLTLPGKGCPGNVVTHCLNENKAYATLDEAWQACHTTSGCAYIEKNDLDKMYVLRRESDPDNAGPHVTMMRFM
->SRR5919107_2884606
-SRPTTSLRRFLTVGCKSPETVVSTRSRWEMPLPSPNIKSDGCRYYVCSQHRKRGPCESVRCILGDHLCILSAGQLSQHSPLLRCPYPSCRKLRVLPLPLRSHEKAPQLLGRNPRRTRSAKRVEDQVPFPAGGHDGSPYQAQGLLGGMVAVQLLFLGHRRDRPDGGDLCRGVSAVNEVVVEGVVGPSLASPEQRLVGVGPRKSGQRRDRASTRWSDQTTSPMYSKWSSRDAEERTNALHSLRRNGX
->SRR3990172_5150764
-LRLVNSVSYQGDALRRFSSRCGGLGGGFLVANACDLRPLAAIPLDAISALRRDTPLSLDDNIRSVPPLIGTPRCAWASGVTHEYVAVFMKRSTYASGNAPLRLAGFGRILPRPADRWNNRVSGYRMDDHAVTMDIVAQRAEVFGPADLRGPGPVPPGGEREDGRFHHHPHLRLDQRHSGDGGRELRVPPDPQSGAPEQPVPHVSRRRRVPRRRPEVRPLRVDRDRPLVPAGDRHGATERGGPPRAGPRRVRAVLRGGVRSALMDLWLVRHGEAVPEREDPARPLSPEGARAIRALVESHAGEAGPFDLVAASGKKRAIQTAAIWAEAAGYPAVKIAETAALAPNATPEAFLAFLEDRGEEGRILCVGPLPSIAAIASFFLSDGDPVRLAFSPGTVCRIRVEATRRGAGELLLFVX
->SRR2546426_2734100
-GRASTAPDRARGRRRWKRRRPRRSAGSIAWSARRRYEIRKEANLTDANAIIERLGAVFVESFHVEVPSSDTDLLETGILDSFQFVELLFELEQRFGFRIKIESIDLDDLRTLSRIARLVAANGEAAQPVAARSSSDTAAYIVRLAGRSSIAKNQSCHGHAAYLCRGRYARR
->ERR1700722_10537092
-LQPAAGKRRAQITRSPVLDKRHLALGHAARSVAVDIEYSHALAAQRKCDRQRQPDVTASPNHAQVKAHRKLLDLKSIRTLLPSLRRPLSNHEHLFAQKPLRRPHAKVQAYHPTGGRKSRLEAVGKELRNQQLDFEPVLHQSFTQAQMGEGCYVIVKVPVACAEIPDVRLEHQQSSAGTKPLPGLRE
->SRR6266511_848920
-FGAEPAALVRDALGARRQAPLPTPAAPSPRLALAVMAELTAERATFTRREVVQAVARCLDAADAATIRERAKELADAVLADLEVVCLHAPERVEVPAALRRRDGWSVWDAPQAIRYTTREMLALEGRILHTAEMGRAPIAPAGVVELQTLERAVADEARPLGTDQHDALRAVTSRGRRIEVVVGPAGAGKTAMVRVAARAWHATGCEVIGLAHTAVAADVLRTEADVGAETVAKFLDWHARGEVPAGWRLTPRTVLVVDEAGMLSTRDLDRLRELVARRVGTKLVLVGDDRQLGAVRGPGGMFAALAHELGAVELRDTHRYQHSWEAHALGELRRGEGSWLEDFAAHGRVHGGTDTSARNECFARWWRAHQARRDAVMLAQDHATAGELAAKAHATRVLAGDAQPGGLRVRTETGTQTVGVEDLVETRRNDRRLTYGPAPDQWVRNHDRWHVRAIDQHRGTLEVEHARHHARLRLP
->SRR5207249_3827138
-KMVVLNSIVSVLSAILALAKSGRPSPLRSTATTDPGWWPTAGEKARAKPPLPLLVSTERVFASGFALTKSILPSPLTSAAATHQGKLVPLGKEENIKPPLPLLVRTTSPNDAQTKSCFPSPLTSATAIETVVLLSNCEAKTKPPLPPLVNTETVGLSS
->SRR3546814_18573071
-ILSLHDTLPFLGSSKVAVVWPAWGAKAGTQGWLENARVRRYDEEQHALQAASAGHGLGLASNVLVAEAVGRGELVEYRPEVRLAGARYTVVCVPGRERQAAVRVFSEWLLGRSIAEAEDRKSTRLNSSHX
->SRR5436190_12017692
-PTGVQDILQRVLDDGADCQAETQVAKTLEAVAAKPFGLDSTRHGKREWQIEDDEQQERRQGKIAGRIREDGKAADQKNSGEQEYGRKIEARLPLDKQPGGQTIDRHQAEAHGKIRQHLYPEH
->SRR5438309_4153540
-CWTRRMQSFPHVRKSFSKTFIPPRGNDAQLRRQRGRRQFKTNLIIPLSSCPVRDGIRRLRARDLDYSLRNQGTGDAGPEKILSFVSRARLKYGKNKITSEFFAQISMMHFIVPAGRAFSSRPSSSSSCPIIGAEGDNLCVVVVPKPAKNYRSAEPAGIRENNLHLRTRRRQSPKLISTSRAVCTISPVGGTSRKRLTASAIGTWR
->SRR5678815_2528847
-TRHLCACRPSSRMDDMTTCPRTRCGTASSMRSLTPRSTSSNEAVTRRSSSSRSDLSRWSVDGWRVPAHLGDNEPPASSESPLSASSPERLAEWISASPEARSRALAKCLETITLKDPRIHAWVQINPQSATETGPLSGIPFGAKDIIDTRGLVTEYGSAIYRGRVGVDDADIIAELKDRGAILIGKTQTTAFAYMTPGPTRNPRNVEHTPGGSSSGSAAAVAAGMVPLALGTQTKGSVLRLSLIH
->SRR4051794_18478678
-RRDERRADPDFGRVHRRRPLVRLEGRRICVGAGRLRPADRSEPGRAVPDRAGARGDRGRRPDALQGGLAVRAGPAVRRGGEHGEAPRLRGVVGGGERVPRHARRLRLRRGVRRRAQVPRDTALLGRARLEQPDPRVPRPARARHAALVLMRYTRVFTETDGETRFEELETPGETIQAVESDLVGTVSVTLAVKGIYFREVVEESSPVPHTAPYPLFIIGLRGTFSIEISSGETREFPPGSVVLVEDTTGKGHTTRRVGDEPRATLMAPLAX
->SRR5512138_1963781
-GAPTRDAVTRTTSYCVRCPPSRGACSHSAISLCGICTRRRDAMAKRRDNKEDLPEQVAGNGLLHRRVFLQSGAAMAGAAAALGAGAAQAQSIGAGSPPSMLKPGAPFSAYGVPSHWRNNITRIVTQNPPPGREGAGSSRTPLQMLEGTITPAGLHYERHHNGVPDIDPDKHELMIHGMVRQPLVFNLNSLLRYPMETRVHFVECAGNSGGIAGAAEPQQANAGVLHGLLSCSEWTGVKLSV
->SRR4051812_18625933
-GTPEAVVLALQGGTEVLAFRTGQEPLLATARIHPGEPLAFAYRNGGRWPWLMVFARDPRGAVSWFHPQWTDAAQDPKAVPLEVEPGLHELTTAVAHPFAPGPLALCAMVLPAPLSVRQVEAALATGSEAPAGGAAALRDPGGVPLGPPRFRRRFCWWARPGPP
->SRR5215216_1715194
-ILYEAATSRKPFAGDSVIDSLHKIVYMQAPPIRESNPNAPAELQRIVRKCLAKDPADRYQSIRDVAIDLRDLLREYDSQQSISASFPPAPPSGSYTRDPSTGSHSQPHMTDSHSQIAPTMMHPQSTITGPEEALSSGPVSGATSAPQRESNRR
->ERR1711871_72301
-NSVQSLRSPCASIDDNKSIALDPLRVSSFKPRRSIIDMVTFEESDEDDEIAGGPADEAPIWGDDRPPSVQPRRLSVRERFRNSVSTPLIGYWRRNAVTFAVKLVRHPRFDHFVLLLIVTSSVCLALESPRTANDAGLMNALRVLDVIFTMLFTLEVILKSIAMGFVTGLKPYLSNNWNRLDFFVVLTSWINLIFTWSGMGGEFGYVRALRMLRCLRPLRMISRYPGMKKVVGALLLSFWPMINVIMVLMLVWLIFAIVGVQLFGGTMYHCLPSVESCILNGTHCVTSRTQCLSRGGAWTRHDSNFDDVLNSIMVLFTVSSLEGWPEIMWNAIDGTGSDYASLYFIFFILLGVFFFLNLFVLTIFRNFMYLKQTMDGVGFLTPEQQNWVDSQKRIMASNAVRRLKPPRSVWRLTAWRVVRYRWFEPFILSMIAINVMLMATVGVKVDDWEEILDDLNTFFVVVYTLEMLLKIVALHFSQYISDRWNQLDFALVVLSLADLAIGSIDGGAVLTVRILRLTRLIRVLRMVKRAEGLRRIFLTIYLALPSLVNVGSLLLLLFFIFAVLGVNLFGEVQFDVFVNDHANFRDVLVSALTLFRCTTGEGWQDIMYELRRTGPSPYTATAFFVVFLTLASYMLINLFVMVLIDTFDGVTTRASGMRDEHMSDFKECWGVLDPNASEMVHAYQVEALLRMLLPPLGVGPHEPLHTVLEVVDQLQLIAYDGKIEYHKTFLAILNVSFGDVMEAKTKNHAMVKADNDGLKRRATHNFIHGDKSGGIGSKLRVMTRRLSSEFGLLKGGMMNELALLKARPTSVKDEVAAFRLQTWARAITGNRKWLSLVQQAKANSPKRMPSTNLAAVFLAPVPDTVLLPPVQQSSPISDKLHSPHKLPPMRTKRIESEPSVQPVTGSTRQQPLRKPARAGSLPTSPSATDVVIDLDAVLHDFQKQGINLSTGGSTQSEESPVDIEHAMAMARLTGGSVX
->SRR6266567_3171955
-TQPLLIGALSLSSTFRLGLRDLADLQKVAVRIAEEAADLTTPVDRRRQEDGPTGFERLIRCLAVWHTQRQLMADGIRIGRRGKRDGRLVPGGPTTSHQQQPVPLKREDAGRAPIVTVDRGSQHVSIELPRAVKFTDHQQVGEGNPFRGEASVRHASAPSVVRAALATKRHAASLWMISQVCYPSNVYGKDRRLKRSSFLHRTVYPTTNHILESSAFYPADDSKEKERHDKMSMKERTITEDQPGEKMADHEDVLAQAQPFGRMGRPEAIALLLHALSPRMKLASX
->SRR5580704_9526292
-XMASHTGISSANRRIESDFPSVFGWECCKRAKPATDRMQAATLSAWVRMRFAFPLRLAMNLALLLGAALHCFGQRELFHEYGSSDGLANLNVKCLFQDRVGFLWVGTDNGLFRYDGSTFRGYGHADGLTNTEILSLAESPNGTLWVGTNSGVAQASGERFVSVDGSEEGATR
->SRR5215469_13096766
-TGFSALLSNGTFDFLYGRNPSVPIAQIDTGDSATSQLVIDPSSNVRGIVEVSSSAANPFLLDNYTDYDAYGNPISGSGGSVNAGGLTVDGKSGDADSASSYGFGGGYEDATSLVYLINRYLEPAIGAFASLDPALRTTGAPFAYATDSPPNRVDPHGLNTGGVCVGASAVDSITLGLLQFSTVFGQACLAETVNTPKTNNDVGFLLVSGVGKKGWGF
->ERR1719424_287230
-WLKKAALSGAAIYIVAMAILGRWQGAVVAVAAFVLPLSAHSNAAAATAAEARLHLRGGEGVMAAGEAQGPMDVTLKSSTKPPPPPVPNPLGYGDLRAGGLGVLPTPTPMPPPPPPDPPIPPLGLPNMEEIGMDKLWEMDMPKGPVMVTGPSTTRAIGSTGVRPRRKRKRMTQPSTSLLVHMQKCLRRMKLLRRTGENDCVRPSCRSELISLHRLGRPGHERLLC
->SRR3954454_10920512
-VSMIAMRPTWACAAVAGLVLPLLLAACSSDAAAAAAKEGCELVMSGNGIDESQLDALSTRAQNVTQAAGMLADAAAENPDYAELSGTAAAAAADLAAQLQFAEVNGFDPQGWSAEVLADYQREFPATRDDPYARLTSACAAQVTGX
->SRR5947199_9062679
-RKKPVTWAFAASGCSRSAPNVVTMAPTSLCERDWSHRAENDKPAAHAVGVHPAAVLPGPSRRPGGDRRAARRRAVLRAVPAVLRPRHRPAVDPHRDLPADDVPEVPLPARLRTAVPGGGRLHRLAALLPCA
->SRR3989338_3014829
-RRFGQAEGSSMILPPGQCIKSAIDFATLDFFVLLQELTKKSFTGYLTMMIRGVGGLEEGTLVYDGGKIVACTYEYLKYDNLLLGSDAFLRIVNASTAKKGIVDLYQLSSDQIKLVIAFNEKMVFVPNEKDLRNIKVTEFSPFLEDQIKEKVKTDRTEILKKLKMGEVANSGDGGKPDANADQPAETDSDM
->RhiMetStandDraft_4_1073278.scaffolds.fasta_scaffold4497251_1
-MKIPLTFAFLIIPCFSCSAEITGYWNFNGSLKATIGENLEWAWEQGDATFGTTETFEIPGIQGNSANVLKIPDSDEFSDFSGIEVWIGDGLDEDSWLHNEYSIIVDILYPETSSAEIRAIVSNAPVEQASIIINGEGKIGGTSFHGEILANTWYRVGIVVSHASKKIMYYLDGQKVGHESIGGLVDGEGEHSLWDFFYLFTTSGLSKGGYISSLQFHNEALSDTVINDLGGTTKLDEPEDITLPGDEVMPTSDNSPGGERAPNAIDDNPSTKYLNFDKVDTGLTITTGGGVVTGLGLTSANDAPDRDPANFILSGSNDDGATFTEIASGEIPEFLERFERQTVSFDNDVAYTTYKLIFPEVVNPDGANSMQIAEIELLAGAPEAGGDEPDDNQEHHIDDMVLAPFGFRFGFSINTEEGESYTVEATGDLLQWNKIETINGTGSSVQFTDTRNEVFQYQYYRVRMAEX
->SRR4051812_32645189
-TFNGSSTPQTFTITPTATGTITLTPTNSGGLTNPSPRTYLVTLQTATAYTVTGPTTGIVNTASTAFTVTPNGLFTGSITITPTPGFGLTPIVLNWNNTNAAESFTITPTAVGTVTLTPTNSDSLANPTAPTYVVTLPAATSYSLTGP
->SRR5690625_3194486
-XMTMPQIVPTTSKNAMALIAGGGISMTSQEIAELVEKRHDNVKRTIETLAYQGVISRPQIEDGIKSANGVVPRHYRFTGEQGKRDSIIVVAQLSPEFTARLVDRWQELERIHSGPALPNFSNPAEAARAWAEQYEARIAAERTKAEIGSRREATAMATASAATRKAKRLEAELDQSMQYASVKRMEMLYHGQKFNWRHLKSTGTEMGIPSIDIFDANYGTVKAYHADVWREAYALDINQTEVAX
->SRR6267142_3947303
-TQGKLEKPASEERSLHVITADRDYTEQEIAGNQSHESGYDQERDRTNLLKHPEQHREYEVQLDEQAEIPPCSIQIVENGFGRVKTIAGQAEQEAVVDRFTGPRKWRDEIYDVRSPVHRIQPQQPIPVPSGPSRWRINEVRERVGQAESAEQQKYADGMIPTLDCEYVDALEPALQHRENAVRX
->ERR1700761_8280655
-RYVRTAACQSRSCASARRSKSEASLRRRDEQFLCIVRRSQTIRAAGEIAPGQIGRRDVPCVGDPSVASERHDLGWCEVTEERRAAGTRSLLRHLKPGADLGVRQLQREQERHGERRSGGKRGDFAERACVRLLAEVHAHAGGVYDGWLAVIKAGSHELVAP
->SRR4029078_20332
-SAPRGWCCACSCWLWSWSWSSVMSAPGEGLAERVGFEPTDLSVSGFQDRRNRPLCHLSAGDSTAGGSESRCRCRRRARLPEQALEVEDRGVARRDEHDLDLVAQLLDVLVLEDLVRQRRRARLVGRGLGGRERDVRVGLALSLGDDLLGLDLPLGQDLLL
->SRR2546423_8221276
-LRFNGVLKALYAPAAADCKAAAGGDSVRVFVHLSVIDLDIEKLSTDRSWWARLLPGDRFAKWVVNHVLSFAGAYIERHDARALSVWEKGGEKGLPLVPIGFPLCWGKTTDCGYVAKKSAPPGFKTATVALGKLGSITFASAGTAAPYLSASSRRFLC
->GraSoiStandDraft_11_1057310.scaffolds.fasta_scaffold1002834_1
-MSSLDDELAEIESQTAYGVSAADYAQVTSNKRASPISTYRLASSSPTATNSPTSLNGGGGAGTATTSSGVAKVKASQLKSKSRGRRGSGFKPDDPAGEGGGAGSGAAGTNGAGGGDSAPVTKLPMSAYINPNMTPQQQAALQAMLERNPGLAKYAPPGAFSPLPGATPATQTTGGRGPPTSHRMGDMAPPPSIRMGGAAMPPSMKMGEPISRGADLTAGGQGQRGADLLVGWGQDLGEEEESDEDVYKPPVSKKMGQSAPPPTTRPGGAVSPRDAIGGQPLNPPELHESTQESLKNPTKPGADKEDDEEGGITYRPTVDAMARGGEAERIMRKQNEMYDLQMPAHRTYVGGFAAAAYETAREYHYIQKAEKAAEDNMVNKARIRDKRPPPSIX
->ERR1039458_81816
-FAQVLVGGGNDAQVELDIFEAAETAEALIFEHAQELGLEHERDLADFVQEKGAFVGQFEDAALLLAGIREGAFFVAEQFAFEQGFRDGGAVDGDERFGLADALVVEGFGDEVLAGAVFAFEQDGGGFAGGHAAHEVERFAHCGRDGFDFEFLRGGLFGDVLGGGHRAFQAAFVIEHLGGAHDDQALHAVIGVQADGRMRRGGRLIETDEDAATGFADTAAKDVLAVAADHVLGGHTEEVFSSAVNSGYGEIRRIQDQRPDAADHHHDGEGRSEAGLGDDGHAGPSPEHCRLHLDRQFGHRRSRVHGPKEWAAAAPGGREPVGGGPPGGLTLGSFEAHPSLVNVRVTNRQLPSTFTRVSAYLPEWVT
->ERR1719162_2616429
-GRELEQARQRCCDPHCGEGGHCPCAKDSPNPSAQPSAGDTDGSARADPGSCQERSTRSANSGASADSGACSSANLRQARWSMQFEVIDLTGAYCGPARGFEVVCVLPFCPKTKCKA
->SRR6266571_5669770
-PTSSTAPRPTSATPTSRAPASTPSTTSTGRGSGSSSTRPPRFPDYDWGARSRNGPPIRLERSEWLDDAGYPPLHRPAAAADHGDRAHRLLDRLHRHPPAARERLPQRAQPQPLGGAGPGPPLRPRPALARPVPELADGRAARGPRRVAGQPRRQDHATVAARS
->ERR1700722_2864867
-VLERVARALEPLDAPLEQRDRRARIADRAVGASEALRELGLLDGVEPAGLDRLAEQRDRLRVVAFPEREAAEACERLGACGPGLLVRRERPFVEAPCGLGIVEAQRDVGVDERGVVLRAEEPGGEEVGADREPRSQLTQQLDRRDALAELEPGDVGGRACLAGELALAQPGALAGLPQALSDRGRVVDMLCLLFRHALY
->SRR5437879_7003822
-SKREWPGGSVERLISAGEDLSHEMAPAAQKDVCHLLLGLDNRAQDSRQCWVQRDDLLELVEHDDHATLALHRELLRDREQLLDCQVLILWQRQRTELDSWSAVLANGELGLEWKGPKQVKGLRPCTGHRTAQPTVERGAELVDKALLAGRAEQVCVGDEHLPVLELLACVQRDRCLAVAPRX
->SRR5918993_323855
-APASSRPCGYWDANAACSAPGRRQEDAAPSCLERLTKAHGSTVLTKRRLSGKLFQLQAARPHRLEAKDIALSRRKPGFESRWGHSRKPASPGESLLTRGDRIGLVWWSGGAAKTISVQRSTSDVAKSDPQRWSIPTKKPIAQNSHPIRCSGRREAIRGPTVEKATVIAVACAQYWX
->ETNmetMinimDraft_11_1059920.scaffolds.fasta_scaffold246889_1
-MSIKTINGTKPNINPDYIAPATDNFWDKLNAAAAFTVGGSVINNIAPNDYQIQNVDYVLSNLPDREQDENFFDDRWNRKKRGLIADIIPSINEYRKQNDLEELNYKAYRYLTDSDTVSEFEKRYNELDKLAFANRTMARNPASVLGLTVGLSMVEPWNLFAGPYALVGQATAGKAALRAGAATAAIAATEEAILYRNDPHRTPGMSLLNIGAAGVIGSTIGGIVGARKSNQKALIKDISARMKSIDDEQHVVLDVDNFYTGSSPDTINLNLASFEDILEATKSIPGVGKKTAQLIVKLRNSKPNKVFDSYADLLDDPDLTKAQKKQLEIALGHCTSPCRFHVNGMPYGGDEATIIGSYGLDKVAAITSPLARLLQSEFPEIRREAVSLLNTPFMLSDNLQGVATKKSLEEIIDGNRIHYTRLIDSLENNYFNYLNIKTAPNGSVRKHIAKTRAGRILRTPSNVVRNGLRGNFSKMGTPAGKMSFEEFKLAAVKHRTGAVVSLDKNVIAASKSIDNLFDSNADAVKKLMKSIYRGKEFTWIDSEPYTHRLWNKAVISSNKEGFISFLHEQLIKKYGSKEAVEEAIGDGMQHIDASIRRSVDKIVMSPEERIDLSNIFEPLKRGATHNRFWNFVDDSDLYNTDWAVHDIEAIANSYIMGPLADVSFYNTYKTLNPETVTLRIRKAAIDNARMRYRQEGIQLDDDVVLFEKHMESLDNSLSLLESMLKRVRGSYVDVWSPVPGGTIQGVLDNIKRYNNIRLGGAFGLRSAADVGRTVMFLGLKKAYGPLFESYIKRNRKAMMMYDQASAELAAINVGNEINSMSLVSAITNTNFNTPYSDKFTQLMSKANSSMFVFNGLVLWNQSMKRNAGIGVMNEIITSAKAATLGKLDSKKASNLAKLGLEREDLYEIAKEFKAHGASYRGVHLMNFENWNADSTIADKLARAVKKEVDTIIVTPGIGDTPLLMENSFVSMMMQYRSFPMAAMLRQTIPLAQNMNRNALSGLLISVVTGMAARQYINFANDKDGPDDLDELLYQGLEDTGTLSTIGEFANYGQMIYNRNPFFLGPTVTGAGDMYKVGSSLISGEEMNQYEINAASRLVPYDGLKKLVTAIVPEIGEX
->ERR1711988_1839548
-KSAEKQKIAARVKRRVDEKVAEAKESFQKKADKEIAKDRADEAEEVSELKEKAKAGNVGKKVKDVNDHLEAKASDKDKIDAALKSKTAANVTQVYVKANSTLHQQEEQQKTDVSQIDSQIKDLEAKKGKSQDPVEQHKIDSQIKELHAKGGNMPADYFHKTGPASK
->SRR6266542_965261
-NNRIFLPYKPKNGLFHSDFSVHSITSTKEISIALAKKAQDDIVSYKNMEEDLKWIVHTKCKTHGSSCGGSLSQKITSGIFTINEKKVEKFAENYFSYLDEEPREILKSSLISLFDTEGYSWTHKYIDISCEESDVNKSITGDFFFMYAEEGSGEKHKVFIGLAQLTKRPATNYYFLKDYYKGNEDRVEQALKHMLYKDVKSKGLITNX
->SRR4051812_43011536
-LNEFKSARDSVYHQMVTPERPLPERAAAMGASLDEYFSYRGLALSCGFSLAGLEKLDRMESWRTGARLTGGHQPQILRDIFGNPFRPVSFDTAWRTPSVLAVAQVIYEERRFGELPILADALEEAGAVDEQLLAHFRQQGQVHVRGCWALDLVLERRX
->ERR1719272_2699062
-RRHAGGCWVVWIYAARMLHEVVKERVHLLLDGGRLVNGHVALGIFGERDAPRPRHTIFFAEVPKNGALYRHSPPRLNHARRGAGERLEHIHEVIAAERVRLDGGERHRLRVVDQVHVLHNHVLAPNLAGAKEAPHLDHEAAAQDVQLAHGQPLLGNEAAHHELLCELCDEVRAALDLLDVPEEPDVVKPLLVGHHRDGALEX
->SRR4051812_6490251
-EGGIDLSDTGWGTPNQLAGAAPNTLSGGGGDASTDAAPGDPLGVPPPTEADSNAEPQPPTAPARAAKKRLNWRSGFVQLAVIGAIAGGALVFRDRLTGNATDLRVGDCFDEPAGVVTEVKDVQHHPCIEPHDGEVFFVGKHPDSGSFPGRPALEAWAGEQCVPAFATYVGQAYDVNRELDFAGFVPVQDGWNSGDHEVVCYIVRVDHAKLTKSVKAAGX
->SRR5690242_7610662
-LNHWNYPDTEFTAQYTQQTRHRIGPYTEQPFHYCFLLGPTNSCGVLLDEPRQNKKIADFVFLATATDALDKLHGELVDQEIPLTGLDGVGCPTHYLSFGLNTIEFPLLAVQHVLSMHMARRILESWTAEQDYQRLGLPREAEEMFRVAEVGAR
->SRR5207248_4090244
-FSCLCILYLFHNPPPPDIYTLSLHDALPISFRTIYRPSENISHTVGVIADIVTLCDASDDFVSDAMVSEFTPIRNSRHSVGQRRDVAVGNEKSADVLLNCLRESTNRCCNDRHTSDDGLESDESKRLCPERWRNECPGX
->SRR5260370_35461453
-GGAGWEERRGQLGGGGAEVGGPVTRVREQQRRRGPTPYLDAGLAAFRQDSTAHARAGQRTMAQPLLNPLSERERDVLQLLARGDSNPEIAEVLVLSVDTVKRHVYNIFSKLGVKNRVQAVTRARALGLLSEETCFLFGLVVSTASFLTNGSVMRNNGTLAAAWARAQALPIEGSFTITFFYAIASTKYCDWIKMALX
->SRR5438128_2108134
-RRYPVPAAQRAIPAIRRPLSAIRRSQYATLSFQSCGAGPQVRKEFHRTFATVPFVQPTVFRTRIEQVWGAWEKLADNDLRQRVAALREERRRLKDKQTDLETRGQTLNAADQRRLDESNFELDVSDFEAELRDYERQPWLNVQDPVLRNRQQLAHYYRVVGQFV
->SRR5450755_1345668
-GTRCLGGRLEQHDSFGHLTAQITLAACQLALEFVAPAGEGVGPRLDRVLPAPGPVELDLGLPAHPVEVGVDWPQLGLAPLPLPGSAVADNRADDLVPVPEHVGGNRDGVPDAPLGRKSPTVDGRGGVLDHDPLRRPARAAVLRGSPSGELRADGACGHHCESIQNRRSGKHPGVKTFPRSSGIQLHITSLPGARLGPEAYRFLDWLASAGQSWWQVLPLGPPDRHRSPYKSSSAFAAWRGLLAQPRARVSASEIAEFRERQRFWIGDWERFSGAGAVADQVRFEREWTALRRYGAERGVRLMGDVAIYVSPGSADHVAHPELFQRGFVAGAPPDAYAVEGQLWGNPLYYWPALRRSRYRWWVERLRRTLECFDLARIDHFRGFTAYWAIPDGAANAIGGSWRRGPGRAPFDAAVRELGRSLPLVAEDLGVITPAVHRLRDSLHLPGMAVLQFGLDPEERRSPHRLENQVERQVVYMGTHDQDTARGWYESLAPARRAAVDSQLQRHGVAERQPWWALTRLALSSPARLAIAQAQDVLGLGSAARMNDPSRAGGNWRWQMEPGALTPALARRLRELTGAADRRDGRSPGQAWSERTSTELPAPVGIGRVVAQTSPPRRLELDQRRWSRRRGQAVALERRQRSLRDRDLAQRRRMHAISHHQVARAQLAQIHDQPTELVRDALDRITQLVHLGPGAGTAELQRRREGQQPVAALAQKSRGGAEARLESGYVPLGRPNVVDSDVQASKLVTCARVGGAPLERGDLGPHDIAYVCAVDRVSGKRQSERARHPQCPRLKRHAPLQLAPAVGDRIAEREQAEAASVVGIFVGGHGRRAX
->SRR4030095_10399445
-SALSAPVTTQHRGSNSAARVSCLVTRHHDVCGRRSCVHNPRAALISVIRHSQSLRSRARHRNGGVRTSLSLTRSGQVVEDGSELRFGPLAGFLCGFKGGTTFHRIGNRFDLQALSDAFEVGNAGAFHGKRLPARRHWTVVTHKPVRALFQGVVCKITLPFDDRCAFLHLRRWSSEQGFFNLGRILRLSEGTERKCHHNNQGHESHGMTSTRSSIRFNPPIPRLISCFEISAVVNSPEMRNVLLILLLLLLASIAALPQTAGDPTTEERLRPPRAGDWLSYRRTDDVFGFSPLTQINRANVKNLRAVWSYPVQDDSRWVPTPIVANGIMYVAEGKGRVLAFDVPTGEIKWIHTRSYPEDIRASQAYLRARGVAVYDDKLYWGTAESYLVALDARTGKQVWQVKTADYKKGVGHAHPPMIVDGKVI
->SRR5256885_12855722
-RSSSSNSLILYIYSTASLFFFFFLMIRRPPRSTLFPYTTLFRSLGLRRGGDQDRGDLAGGRALVGYERRGIAAHRDDPQEHRWRSEEHTSELQSPCNLVCRLLLEKKKKNNTMLDGHTSRTTVCCH
->SRR5262245_11139375
-ECIRLLNYPAVECSRQAVSTGKHIERTQRFQLASKVRELSICFLDRYANCPAKASVEFVEARLPVTHLVERRTECAPFDNCFKPLLGHFDSPRHPLAHSTLAIAKERQQLGTIGGQISHRMAWRQGPVVGDHVGDRKVGLVADSADYRNARGKNGVGDDLLVERPEVFEAPAAAANDHGVEPKSRSQLQPIQAMNGVGNFRSRAFALHSYWDDQDAGDGPASAQX
->ERR1711871_676384
-VHGGFSEIAKVPHHPEHTATTSAVPLVTETQLPLPQTIFVVDPVVVRRAEEDKSTEEEKDVFLSDADQKEAADAIRKWMKMLRKNRRAGRHKRLRELERMRRMRLQRLKAARLQMKRKMQADFGGYDPGLEKRSSQEKDEAMTP
->SRR6266852_8977469
-KRSQVKFKDHKEKLHIIFFFSSRRRHTRCYRDWSSDVCSSDLGAWLRRRRRHHRRAGVAKRLLQKDQGVRVRSEERRVGKECRSRWSPHQSKKKEAVSGTLRVQSVHESCYRYGSASRCLL
->SRR5262249_17805584
-TGPGTPRATGAALPGAGPPHPDAARGPGRGGPGLERLPAPCACVPGAADNAGHGGGAHGPWLDEARPAVVAGAAISFGTTEAAWASFTGAAASDCTVVRTVTTVHCGATHCFFNTAFPDLTSQRPRCDIYGPAHDVKGVSRRGTRVRTDAVIYPTSQ
->SRR5262249_30216735
-LRNGSTRNIALLTLLIAEAGAFAASGATGCSSGETTSSAEPDASPSVPPPPPLENGQTAAPHTPTAHSPRTPTHDPATDAGVTPGKANVVFVLADDFSMNLLDYMPHVQDMMKNGLTFSHYYVTDSLCCPSRTSIFTGKFPHESHVYTNGGDAGGFATF
->SRR6266540_3007965
-ASDGIHRNIRRMRGAGANTSLKTHCMRHPGSRPPAYLLLYSLKYRLFKRTGFRELFTNTKQMLIGADEDSSVGNRGRGQATFIQQVFLQQSELSPGFQHKGFPGFVQKEDFPITPNGGCGKNTSNPFLPDHFARIGIRANYNAVFSSHVNELSVTKKRRDIRSTGGDAPCYVGLGDVSLPSRSNRHVGTTAISSACVEHSVDINRHGNRHWAE
->ERR1712159_79709
-PVTKRPTANYSQTCFTPQMSSATWEINYEPIQGANCMWMIMCTCLTGFVIGHWVMTYVKGGLNDFRNQLLCGFPISFVNTALLDDPESVPKWPVVTWKKALEKFYLFVVVIIVIFGEAALPTHQVFPEWLYVDIWCTGGAQIFWVILPRSAFLGFMEHMHHACEITLPYTHGAVWFTVFLTVLGAGIASTINTSFSGEYNRDLEYW
->SRR5215468_965392
-NDPLILAALRQHYQRYARFLTGLIQGAQRAGQVRKDVMAAGMAWQLIHSAIGFAFIKPLQIPGHATPAAVEQAIGLLLEQLSSLKPALPTNGRVAVRRARPPRRTIHHKPARRSKX
->GraSoiStandDraft_49_1057285.scaffolds.fasta_scaffold1147020_1
-MTKKWKLSLLRILLLASPVYAASVAGGATLDIDTGDPLSCPPSNSFWWSNERGSAFYSYCTDPRDEGACDGKGQNGETTGNASTGCCGASAEKGKEECDTCRDPEAGGGSGTNGEDPADSSTEAGRKIDKDQSCQDCPEAGMPLWSVEEPLLSVRLVDVPMWYKPAFGPKMALKLHYKSLEGSFGHADTRQANVFGFGPGWSTPWRSYIRAKAGSSPAEVWVFDGVGNVRSYFVGSPGGNAPYYHKKTGAFVETDTVGYVLTHNNGAKDFYAEEVENNSNGAGNGEKIYFLSRREDAVGRGLTFNYSTTTSGGFDQMRLANIVDAAGLSTTFTYTNVGPMNSLIHKVTNPHGFAAMMLYDANGRLETIVDTISLTSKFVYDGTDRITSVKTPYGTNRFEYVSLSDTNCLAVRVIEKEVRKHLFVFGDLPVDPWPNVADVITSLNNYMDMATNVLATTDFFYKLLDDLKGRNPAAFTNHPSARCSAYWGPLQYQNLTNTIDSSLNNSTFAINSVTTNSYNLAHVTRWRAAWGGFISNIKSFERLPGAAINGSEVGPFVFYAYDMGATHEAGTKEGFDNLPAQIFRETMLTDPTDSNLRVWDATQIEYYGLGTVRPGYVKKKMVLERNDFPEPALGIPQFCFRIHRPIRPLTGCSGSGCNRYASGVIQDENEFTCMGVSSYSTNWLASLSGTDGRYIEIIAFPWDPSTGAGIGGPGGAPIHYEYHGTNKELTKVTYEGIVEKIRAFNAAGQLQSEMFQQTTGGVTVTLWTNSWTYLNGFVRTNINPRGLAISYDTDPMGRVTKIGFPDSTYVSNRYDRLDLVETIDRNGFSTRYVYDAFRKLLYTTNAMTNVVSSSYCNCGSLSSVTDGNGQVTSYTYDNRGRKTQVTFPGGSWVATKFDAWSHPTNLTTSGGIEQGILYNLKGQVREKWLKSG
->ERR1044072_1391978
-RNWCCSALAVPKHSQHPKEAAELAAWLTAPEQQIKAFQKTGNFPSQVEALSSPELLGTTNDYFGDVKTGELFAAQAQKVGQAQYKGPGDGQIQENATSPALQAVEQGKSPEDGWQQAVEARWCGARAPPRAAEAGERTPAGPGAGAGGAGRRAARRAPPPPRKPRL
->SRR4051794_8328619
-XMSHPPIPPILASVIACIAAAVPARGRATFLDLLLGAAATKSGHVTDAILASGLSRGWSTYYWFLEQGRWSWLRVWAALLEVLTMLFRPAVWYAVIDDSVVERVSTEAPGALTHHNHNAKPNRPKFLRGQGWLCLAAVIERNDFAVGAVPLLLRLVRRGTNRGKLRSAGLLLHLLGQRLGHVRLLLDAWFMRAWLIHRALAAGHIVIGCVRRDLALFDVPKPPRKRRQGRPLKYGPRLTPGCGIAGAPQRPDPLRQAGSRALSHLPGCCAVPARAGGAGGVGGTGASRPARQTVPAAIADLHRPGAVRTAGDQRICQEMGGGVAVQEPQARLWPEGCLAAVASGADALGHRTGGRICDPADAGLHRPGAPGRPGPARPLACARHPHRRANPGRHRPHFTRGRAGGLHRGDLGKNRRRGIKHKRIVSAARRQSRVSHPTPPSSFRSCGANPAPRRRNVAWKLQICKTTSGSENRRDRPQGRNAPRIRPELQFNEPADLGQAETPEFPRFRPSCCRAAITGWRADTAADDTRRRDVDRGRPDLDDALYAGIDPARPSLRDDRGRDPHDDHRLFVRVRAGAAPLRPAVGPLRPAPGRARLPRALCR
->SRR6184192_2552679
-LQAAVPEYWYRRRQSDLRSRDLLWEWTAIETTPDCTSQNYWAVDFAFRVTGNTRPTAILSIPCRKHLGDFYQTTLTKEDYVAGGRASVARVKRYRHRVVAIRGEWAHIETRSRIAKSQLENKANESIPLGFGYCPTRAVX
->SRR5512141_912622
-XMIGSRPGCGATPILMVGQPPRAVAAGSQRPNVYRRIELINHYGRGFHEADNEQRDYKQGLMGSSPEPVVAAWIYKLRGCGRSLPRNSRFYFTEKGWREIGRMVVSACRKSGQEYRVIAIKETDAQVVWRDKHTGYEVAVQPARRRAX
->APWor3302396189_1045246.scaffolds.fasta_scaffold344749_1
-ADPTTISLPTLTWDINVNMPANETLTIRFRGITTAAPGGSSVNDSTATGTLGTLTYSASDKATVDISGLQITKTSNATGPLNPGDDIHYTIDVTNIGSIGQNNIIIRDPQPAGTHYLDDTTLVTGYTLVSGDYLDEFGAASYSNDDGSETWSTPWTEGGLESGNDPNNGRIVIIGGRLRFHDTTATGADYWLQRNVDLTGVTTATLTLSYEEAGTLEASDRVRVQVSGDNGASWTNALDINNDFGGPTNLSWDVPIPSVGNTNTVIRILVNNYQEAGVEYLYIDDVRIALTKPGAAIKDNAAGGNPDLLNGDPEQLVLAGDGFMLAPGATMRVEYDVSVNNPLLTPGLTDITNVAYASSVEEPVEISATREDPLNFIDVSLDKQINDDTPLVNDTVTFTLRVSNAMGSQTATNLTVTDIVPVGYTYVVGSILGGDTNNGDDPTGTGLTWTINSLSAGNFVDLTYQATVNLTGPYENYAEITAYAQYDLDSIPGNGQQTPDEDDDDTVTVVPEATPDLTLDKVYVDYTDNDTSGDITAGDDLNYTVTMTNTGNTTLTNVVVSDPELIPTSQTCASVAPLGTCVLTGSYTVIQSDVDAGEFENTATVTDDNICTTTPGPECEDTETVPIPQA
->SRR5262249_48298838
-MDVKSERSSARDRQQSEPCESGTEVTRSRTGRPEASSDRAASSSHRRSERGIDPAKPRTDDRDVARDRSVRRIPDQRTGPAIASRVPAMLTPEEVALLLRTSKKAVYAMVERGQLPGIVRLGRRVLVREEALVDWLRQKSLTPSSERX
->ERR1700737_2044360
-HRGPGVSQKCGHFAGKHVIPAGEMVQKINAAVDARHDGDLQIVARTDARAIEGLEAAIARAHAYVEAGADVTFVEAPLNFAEMQRIAREIAVPQIANMVFGGLTPPLRQTELATLGFGGVLYANAALQAALKAVSDVMQALRRDGSLDAVAEQLAGFEERQRMVGKAHYDELELRYQSAGPRRSRSAPRLSPFGRSCPLGSQPRAGAVSRQAWVCKRAVT
->SRR5580704_900937
-PRDRHLFGAYVRKNITSTGTAVNQGARLDKQFPLVSMTRPPSDPLERDKIGKQVWTGIGLLFVMSLSDRDRSLWANPPTRPEESPEHLRLLHAFDDFLLCQFAEWGWRLLMSAEVLHRISEWEKHDPVLLERLGKELGLRSKVLRGEKCAPLGKNIHKFADPTIKELKILLRRQQLDFGSKRKAVSCEKIALRIRSEVAAHPTKFPLLSANLEQLCGFIHNLPKNHQRAAQKFERGDLRENSFFYLWYASCSNRSVKDVRNQISRSRGAHRSSX
->SRR5947207_3184146
-NDKKEPRSGGAEVKAFRLTLSCSSAPLPLCPLLLSLVTCHFRIGASSHREWSSVIGAICFPNLNRPGEDLMSHLPFRSLAATHCLRKLWRCARTAATLATVCALLLAAAPRTAAQTFRGTILGTVTDPQGAVVAGATVTAKNLDTGVERSTVTDDAGNYSLPELPIGRYEVKVQATGFQVYLITNVRVEVAGERRVDPELSLGGSDTVTITANAVQVETTANTLGGTISGSAVVDLPINGRQFTKFQ
->SRR3954471_2680322
-LAHHRRGVVQPDVHPTGPGHHRVEVVEGTAARANFEVVGVEDAASRTARPGDAQGGGLARLRQGRVHRVGAALGDRLDVRWREHAELLEVPAVVVVDPGGAHDVEGVAVLDRLAAVADGHGGAAGGTGQAVGVVEAEVVPHLVRRDLHGEGAVDPGVRAGHVAHPTPVAV
->SRR5580698_10972885
-SGRPSPSTRTTWSITPTGTRATSSGPAGSCRAARTRWSRNTEVTAQQSLGRSAPARCRCRCRCRPATTGAGGQRRGSPSRRAGRAAPARPPCTRRTLLAACSPQYPGRAGLGEADCLVVGHAAAALVGVVEGILAELFPGGRADTGRVEAAVVDRAADRVG
->ERR1700674_1031357
-VWRGWWVSVAGAPRRRVAGGRLDDERQGGSACREVDAEPLHGAGAQVVGGEVRDAVLLGPCRAPLGQVVLRRGLGGIACHLDGRTLPPVLGQPRAALERQARVGEGVALDRRGPDDGVAGPGAELALETPHGLPERRLDLPDLLAEDVGQRREVAPPRPGQRGVDPFPAVPHALPLLVVLAGKQQGEAGGTFGGGPEAGARHLPTPPPAAR
->ERR1712151_647775
-PLPSRCRGSLQQIARERAGLTSLHLRVFFARSRERLRSLALSFLARVGLPPRAFTFAVSAPWLLLRRLFWTSFSLSRLSSLSFTLRFRFTFSFDRSSLVRSSSRFFLSLSFSFARSFPFSFSFSLR
->SRR5258706_534337
-WGSRAPAHRHGKRARLVPTRTFGSVRAEVAVTPARGSQHSPFSLEGVSMSMDASETLERSVLESKDREQLLAIASALGAKAGSRTKKADIIDKILEQTGSGAPASNGKTPEARASDGPRTSDGPRTSGGPRTSDGPPGDAAPAAGGARAGGGTPGGAPPGGGGENVRASPAGAPGGPGSRRPRRPRPRGDDAFVGGKKPRQYGLRRGDHVTGACRPAGRN
->SRR5215471_3001876
-XMVPENASPTRVRSNVVPGGAFMLNIGPAATSTQLAGTSAALAIPKLNTAASRLPVTRRIASSSENSRAKKLVLWAASGNGRRRVAIFRRGRDAADQQDAGNDSRGDDREGGRGREGQPLVGGVSVGQDREGIEIERPQHQRRRKLLHHIDEDKKRRGKHARTDQRQIDSHQRIPGTARQQFRSAANRRRHPLET
->SRR6266702_5134999
-XMSCCSNPFTLFPLNTMVIRKTIGEVSSLLFQFTCKCDILNTDDAYYQPHPAETALARVFLHAILIDTGNSASSEAPPYPYNRGLIETIMHEKSLITLEYPKILEKVAKEAAFSASKELILNLEPTPNLEEARRRLAYTTEAYQLIEQYADTGIRGARDIRPILTRAAREGILSPGELLEVLATAQSAMYVAKLLERPDPENFPLLHKWVTDIPRRPQIIRRIEETISAEGEVLETASPTLHRLRANIRAANQRLQERLRRLVNEFGPSLQEPIVTIRNDRYVIPVRRSEERRVGKECRSR
->SRR6266480_5337023
-YGFEELGALVVRRHGIGGLPQDAILVRVGKSRVREQRVEVLPLRVIGVHQVRLVQHGVRSALLEQQRHTGLGKPCGAPFDGEQRVREPAIPIDVEGRVAIETPAIVQCAVDVSDANLAAVIAGALFYFHKVVDAFEAAEVGPGREVTTRVDSELTVTITQANGGGSRLCITVDV
->SRR5580658_3392266
-DRVALPSRRTVQAPHWARPQPNFGPLKPTTSRRTYSSGVSGAAVTSCLRPLRCRVVLVLTGRMIRPECAEGNRVKRTLLLATLGALALGAAALAAPAITTLPTGWKILGSDGPVATVGTLPEGLALARDGSRVFELEGGHRKPTLRVLDAATLHELRTVALNGAYGVPLRDPDGDGVWVNVAGTFQEQLAHVDTESGTVDRDVSLPLPFFPVALARSPDGNLLAVAGDLGGRLAFVDPRAERVVAIERVGLHPAAVAFSADGTAVFVAERGERYVDVVPVPGSGPATPADPDAPRPFSVAMRIPVGLHPDALVL
->SRR5437879_9218440
-PRGSKAYSLKNVMRATSSPGAQTPKSPQASFGPSLSPGLNPSPPTFTDRISGHGRGRTATPAFWRIPRMGPAHPPVGGPARSVSPGIFWLRQGDFGSGLLLVVTRICDPVRAMARGSFEPPVRIPPAVDPRSLGRHGLARLRAERALVVRYADEYRRLEPRLGHIGAISTLVRRHTKEYGRMVTASAAGAPEQPGFVRRRLSA
->SRR5438105_2884871
-AATRRTTTCGPRPWAGSSRPRGEMPSRNTRSPRRKDHSMSDKQQYAVPQHYHALDTSELAALRTALAKAERTAAGTGPWVDRTRAEQDVKIIQRQLHSAETAARSELELQRLNAPRPSETPAGNQAAGQQYVVPEPYFAEQQDYDQPSSS
->SRR4029453_17137562
-PPPRRPVLARRRPGVRPRVGCRGRQRLARRPPGHLGLRQWLVRGALGRRAGDDRRDLAAPAPGLGGGGAVDRGPRRLPGRPRPRSPPATGPAARPAARGHADAAVRPRAPPGLGSARGADHRRNGHRVVGVRPPGRRPGRHRGHGAEPRVALGRAGHPAGGRRDRRLCRRLHLRQADPQRPAGGLRLAPELRVGPLVDDDRGSVARRRRRRRPGPAAGAEGGPVRRAAVILGVLVVMLVLAEVGARALAPYLPEPSLWTDDTTEGKVEQLDALAPGPGCVDVVFAGNSMTRDGLVPDTFTEADPEGRTTYNAALDAATPALLERWVLQEVDDRVDPDGVVLGLSSFDLNDEAKIGQSALDAYDDAPLX
->ERR1700733_14753379
-NGLLELTPYNTPSISMSNIIEEKDNRIHTEEESQADYTPELRPTIRTDNQTIDLEISKHSTVLRPLHNLSHRLIHNRLKGPTGVELPAIIVEDSDIWKRTVGGNWDCVX
->SRR3972149_5498235
-EPRGREHVGQHDVVFVEDGGRVIVEILDAADLRRQVEADVHPLQRPLGLAPLAQVSLEELHRRVRLQIGVALGEVVNDPDLMSPLQQPAHHGAADEPGASGYQYHAPPPLPKTRSSTLAARARSSSQTPQQSTRIGRGPEVFSRSRNDRSRKARWLVASTTTSASRTAVFRSGVSWKGSLTATRAPSAFSSSARRTAGDCRVSSISALNPIPSTATLAPTRLWERSSRRRS
->ERR1700722_8398492
-HAPIGRGSHNRSALNGSRAVSGGAVVMERACPRVSPDECGSGNLCDRLHDLRADARSKSHLAHFVVSPIERHPQQRITPFVGVRRIQVHEVLPVGKMLRSHIHTWTDSVPMLNCSFFPGRAPVARSFPHGHSSEGSNWTFAGSGATQKSSSAYYFFRNLMVEISLKIGDAIAHRARSHKEIQPFLEDQHTGPSAGDLVGQVLAQRSLGRDWIVGFADTREK
->ERR1719253_1353614
-RSLLRKSALSHKLHNHMLGTRIFQDQSLHWDHAPLGLSLVSFLPCGWCRALAESVLETARHSLQVLHAARAWSTTTLWLGSPLVGSDLSCRVAATCASLLLVVEGPLAATEAKPVSLGVPLSHAWSTVTHGCRCAENCQMLPANEMEP
->SRR5206468_5774351
-GCSGYDGEILTEPFPAAVVLTDVPNTPRMHLSRVIVTFAVGFVPVASPSQYRKTQPLAEVAVIVTTELLRYGPDGGAIVKVPPPAASRESEYVGTKRAVTCSFRSIVTLTVRFVPVASPAHPSNTQPAAGLALSVTTVLLE
->SRR5690625_4794838
-XMESVHAPIRSCTHQANGTSAQVGHIGSRTDQYTAVSHLLGHYLRGPLTIISATYSRRSVRYFRRSVTRSPPSVDCLPAFGGAAEAQHARSVAGRPHIDLFADTPLEFADMADDADESPSGAQRAELVHNRIQALGIQGAKSLIDEERAQAYSAARAGDHIGQSQCQAQRGVKSFAAGQCARLTLTPGDVIEYPKSQTGAPAAAGLDFFAADQAQPAGRHFREPRVSRLDNVFEASQQHIX
->ERR1719284_851324
-RTVAYPVLSERCTASIHSWDSKKGLTSKDLLENSLLSTTQVRLMGKSPNKVKQQEKAAHAKNKVISVLSNKLRGACKMGGKLETNPKKNYNLAKVIAEVEKAGMN
->SRR5579875_2658053
-WDAVLRKPRPHPGRASADDPRTRPQRQADRSRSRRARPLEDPHPARLQECQVGESNRGGEHVLAPLFRKGRILGRQRLQLVRRDLIRRLLFPAFFIGAVIGIASAAEPAHFSYIPPPPGKMVESRLVALSGAGTQGRWRAVLSRKVVGREGDQRFYQWYLTIYAPNAAGDYVQKYRAPGNGTSSLLTVVEKARGANLWFPVQTVKIVGSAELMQPGVQQLVVAVHESGADCGAATVTILRYDQASGKIAPAVSVRNGCRLDAGIVRTSSGDALRLKARITALRPLCAVRPSPRPARSSGTVPAGGSRARRIMKCRSGRTRSAGNAGYIRNTPKLVREGGAHEATSRPMPRTX
->SRR5215469_13482869
-LGGHRVLAGPGAWRADGSIGVWDSSGCGCAYSAILHLRLSYVDSKFGTDVYGPRLDEFDALGARLLGWRDNGDAVVDRDQPGGHFAPAAATYPLDGQAELVALSPGGGAQRLVSLPGGTNRVEVAARLLDRFGGASPSIGYRLADWLRTHLDDLVGLVALTAVVVAIVLLRRRFRRRPVTX
->SRR3954453_2381136
-RRHDHHEPDRPDPDHPAAPRGLRRRDLRGRPGRRAGGHRQLPGGLHGLPAVPAVLHHPVVGDQPGRLLLGAQGALRGGRPVRPERQLRPVQQGRLRRLRRRHPHPDPLHEQHPVRRPDRQLAGWRGAGLAARPDRGRRPLLPLLRRGAPQRPGGCLGARRTRRPRHGPGAAPDRQGAGVKYDPAVEKSPLPYSPFKSCTVPRPIGWLSSVSPDGVENLAPYSQWQTLTFDPPMVMFSANQYPDGRRKDTVLNAEQTGWFVWNMATWDLREAVNISAMALPFAESEFDRAGISKRYADLSATPMVRESPVHFECRYLSTHRLAGHSAVGTIDVVYAAVERI
->SRR5436853_886914
-GSSPRISLWEHGSDPEEMEELPLQSPHLGPSPRISLWKRGSGLREMKALRLSQAAGASVVDVDAFLRCVYALQEETDPPRPVGSHGRELQWPLGLVQGHRPRPNDWGRKGRADPPWLHTCGLX
->SRR2546423_1658942
-AAWDADVVVKVAPTSEEEVGRLTGDSVLIGFLSHLTNAAGVRALAAGGATAFALEAVPRISRAQSMDALSSQSNVAGYRAALMGATLLGRYYPLLVTPAGTIRPAQALVLGAGVPGRRGGRQLRALRAGRDRGQARRDDRGAAEPGQRHGRGRLPDVRAQHPVAARAHDRRGRRAEARLRRRDHRRRLRHARRRDRARGRQAGRGSGRLMLVTNLAILVLAGFVGFVVISKVPNTLHTPLMSGTNAIHGIVILGGLLVLGLSGSGTLNKVLLVIAITFGTINVVGGFLVTDRMLEMFKGRKPARQEEIEEAQDEEEKKAAX
->SRR6185295_6827403
-XSGTYVVQDYDLAMKFIVSARGLTSGWTAHTTFTDGNATAQGTVVSAAAGNPPISGATVQCIAGCNNISITTTNGTGSYSLTFQFGGNGPTSITLQASAPGFTSQSITLTNVTKGQTRTNVNFVLTPTFRNTSTTVSCTPNPTVVGGGVSCTSTVS
->ERR1719499_497600
-MWSSLPTELTDTVDGLASDLTAFGFNDLESLTDYDSMLETTWQNVQDNSGIDVSDIEGQMNSLIGDFEDYLTGGTDMTLDTIIADIDDAMTAVSAELEENVDNEQLVELYQNLEIVDWGVTTWNQFASETELLTDFTGNLDIVLQSIQFTSEFGDVLTYDWLDNFMTSLNDILRVDGNQYSVCDEEYIKDQVWNLYDAEYDWYTARSEYMTNCYTTNFADTWTNSLASLMSGDLSGAFTPDCSCWEDLWNDQDLVSTMNCVMDAGDSITVEGQIAECNGVIMDTVDEVSLITGALETFEELANDLTSLETD
->SRR5574343_384457
-YLKTSKSSIYYYIKSILFYFILFYLHIKNLFIILYLYLEINLIGDNMESLTIKDLKHGKAFASDMLRENFNNYNDTDIIINFAYTDYGGTFFDNVCIEYFVQNYPNNIVQENTSWNGKNAILFGNNLVQNFIEQFENYPLGFEVLEDFYYEKESELLESDFIEFIKNNFSTDEYSYNEIDLLNFIIDNCSYNLTSNSVDYNENGLIEYIIQHYKRLNKIX
->SRR6185503_2167616
-RVESATGCGTAWLMASRLDSYERDEVAEPAIGEQPAEARIRREPVAQRRGKRIGVYRPQRIGGQSPDLPSEGAELPAERCDTHAIDAVMTPVVIALPLLAEHLMAEASRIRRVDEQHGARPGDGAQRVDHLEGLVKMFEHGPHDDGAK
->SRR6266567_1659920
-LYRCGASACSEHTFHPAIYKNYAHSIERELTILCYERVDRKLQSDLSTVHPPLQCCSRLFTHCNEKSPTKLEIPSSSCTPAPGSSPIATPVLLPPHGKPLRLALCERRFNPMKKERPFSWIHTIRAALFQSPGEIYQWPLATIINQRLNDT
->SRR6187431_3469506
-CFILYLLSDFELRAVCVRPLLFFFFFLMIRRPPRSTQQSTPFPYTTLFRSPPPSAPVARHARPLVFCAARARSSSARGDRKSTRLNSSHGLLSRMPSSAXX
->SRR5574338_764212
-DTGEPPADIRRETSRDTTGVVWYASTSPVKVQTASKKEDSDLDDNHKITISGLSSGTKYYFIIVGKDNDGDTATSTERSFTTDQVNDTTAPTISNISITVGTTTANISWKTNESSTGF
->SRR5690606_34928301
-VDLTRFYGADANTLQTVYPVEVSEQIGQTVIIQIVPITARMNTCQHNFLIACSDELPRLLQHAFRITASGQPSRPRNNTKCTKIVTSFLNFQKGTCPFGKIGHVKLLEFPRLHNVAHSIDRLTLALQISDVIEQFVPX
->ERR1719424_1028065
-RFAALSSPTNTALPRRRRRRRVEAIMWRTRARAAVRMPGVLRSSRRPLSNEISATSYAAALATRKDATMGRELISTEDTSIKNFTLNFGPQHPAAHGVLRLVLELQGELVARADPHIGLLHRGTEKLIEYKNYQQALPYFDRLDYVSMMAQEHTYSMAVEKLVNCDVPRRAQVIRTLFLEITRILNHLLAVSCHALDVGATTPFFTGFEEREKLMEFYERVSGARMHAAYIRPGGVHVDMPVGMAEDIYTFCEQFPSRLDEMEELLTGSRIWKGRLVDIGTVTAQEALDWGFTGVMLRGSGVPWDLRRAQPYEIYPEVEFDVPVGTSGDCYDRYLIRVEEMRQSIRIMVQCLNLLEPGCIKADDRKLCPPSRAEMKDDMESLIHHFKLYSEVRPPASTAPRPHLGRTSAAPRLHLGCTSAAPRLHLGRTSAAPRPHLNCISPRLHLGCTSATPPRSGCGRRMARRSTGGRLVACSTRWCAACLPFGATRSRTSTRRSSTRSQSTPAX
->ERR1712137_1537553
-PPARPAPVKRTFRPAAYSLADKPVEASFDTSEGIYQLQRTHRMPPYPIPLKEAFDTIHNHPTRCSLTPCPAPAFLSSRIHEARSEKRILLSEDTGMPTDDDGFLLVYNKKDSLFLDRYFHQPLQPYQVLELPPAPKEGAPFKALTVTQWPHQIRCKRFPSCHLVAHRVTASPPREALLIVFGFSTGELIVYEPWREANCPRVSEPLHLFRTAITCMIWVPLQEGRLLLVGLLDGTVALINLEHKQISTSTAPSAETMQEYLPQDRTGRFVMWKNPHSRTHNPVMKWKFSSHPIYDIKYAPDAVQVALACGDGYIRVLPLLESKSNDLHPLETDQPGAAGFHMEVGQVAVAFQSYFGSVCCLDWSFDGEYLLAGGEDDLVALWSMRKLAVVVRGKGHRSWVSSVAFDSWRCKDGTYRFGSVGQDGRLPLWEYSKETVHRPRSLSAMAIRRRNGRHHASDQGAREGTKPMEPKELARLGHGMIVPAAGSTEVPMLEPIVEHQAHLVPSHSICFTPQAIVTAGNEPCVRVWARPGHYVAPPPKKEPVVPEVEKIPLSVLDAATPLSKSEPADPSIKDTSGNSEITDSKEEQTTVEETETTSTASLSESEEDTHLVTMKDGTSTTSPRVNGKEYDSVHDEAGAPESREIQIPHSMANEKEEKAALPVAEESFLPEQPSDPLIVQX
->SRR5437868_9687141
-RRADRPSVEKLIGHAPAAHAGNGGAALFDGPEIAVGGAAIQPAAVLRAPRIRIGLGRYGGDAAEDQYRSCRESNAHHDLLWMAAFNAARISRLNPHRCCLVVSPVSPRYGLYRVPPGIAAVSIRGAPPSLTANVLAERRFLSHQH
->ERR687886_608271
-ESVISDVDAIALFSLSEVTAVLFVTGEVSTTETDGFSIAGARSSELAEVTSVSVLAGSDVAAAVVTTAVSDFDTSEAIASELLFVTTAESGFFGGLVDAGWPELVDVGSVSVLAGSDVAAAVVTTAVSDFDTSEAIAAELLFVTTAESGFLGVSDTIATASPVTLAEDSVVTNGCSDDTGAVDPESSGAIGTFSVEVMETSGVLDX
->SRR5262245_18501370
-CALHSRSASASSKAFNVSSTVPRTTRSRWLLIRSSSIVMTLFSRLGVSSDMAAPSCWPGCVWPPPVQPDSGPPALPNCAKDSVRHPIESNSGRRNAVLAAAEIYFGAYWENKFVKQSLQDIINAVGWASRRRDDIAHGIIWGNIVVDHVSYGAFLFPPEYNTGRTLAFMADTPDPLRFMRTKYRYTAANIAKWGSKFTKLRDAIIDYFKAIKREDGRFPVLEARLEPLMDRAEKKRX
->SRR4051812_41527219
-VTGAIEPTLERAEVDRVRSRPARNQDAYDFYLRALPLRLQTTRVSSEEALALLRRALELDPGFAPAQAHMLTCIIERVAQGWSAPEEQEEGTQLARKAYTDHGDDPLVLTSVADALGFLAYDPEGSLEAASRAVTLNPNSSWAQSAAGWAN
->SRR6478672_26151
-ARRAAGGHPGPGRAPARGAAAPAGRPRGPRRSVGAQRRPGPDPGPAGPRPGRPHQPAHPVQAAAGRRPGSGTPPHRTRPARRRPADPGRRHPRPAGRRHPGSAAGRPRGGARPTARSARRGPHRARRHRHRTRPGGAPGGRPGRGARAGGRRGTSNRDVGRPHRRRAARPARGRRDRGVLLLQRGPAERRQVRPSRSDRGCGPGEHRGGGVRRDRRRRRIRSGRRAGPGRRPARPGRPGIAGRRRHRGRHGSGPRDPAARRDPPRRPGRGPLRRPGSGPTRRPGRHRAHRPGRRRARTVGRRWVVTGRGVAARPLLLGAARFVIALAVYAGAAALWWSASGDPDRMPGWVAVLATGVVAVAFGMLRRPLDALADRLLLGGRNTGYATVRALLARMATTLPVDEVIPALAETAGRTVHADRAEVRVLLSDGADLSRVWAAPAVPPARTADTVTVGVRHHGTAVGEIEVEVTDQAQADHDRRLLRDLAGPAGVAVSTVRLTVELRRRAADLELLAGELAESNRRIGDARRSQLAAVHAEMTERVLPLVDRARAGLDSASGAGARGAPDITGTADAVAGALDALRTLARGVYPPRLTEAGLAVSIEGWQHRTGRVLRLRIVGDQAVLRRDEDLESLVYFGVVGMVDGLRAGGAEPPAVTLDVERAQVRLTVTGESDGPALDRAVDALRDRVEAFGGTLERTSTAAGDDARVRIVTRLPYGEGSDDMAARHRGAEA
->ERR1719505_362534
-STSSIILSQASFAASIGYIAHIVLTAFSMNSILALTVFTSNVMNRTTALQTVHPMGPPKFLRPSHGSRRPNPPNPGLSKSPKSSPRPPNRPRPRPPHNPRFGDNPFRPHWPRHRHGGRHGGRHGGRGLW
->SRR6266536_3216943
-RPVGWCAATVLGPRGATRPARRGRSSPSTGGLPEHRVAGLVALPAGGGYAVRAGAAERVAHLRPARASVLTPTVRRVGLNNAVVYPPEGGCGGGDEQGDVVVQRGDAPPAAFQAGFDELVGVAPVHLRAGWAARGAAVAAGRVDDPVGHVRGGVGGDALAVAVVDVDRAFQADRVSAAGRGSHVVQPLVVVAGGGAGDDGRGFGHTTGPCRDGGGCGGLRPRPVPVIGGGRVEERRLAVGARTRGEGVLLPGYEGPRRDAHRSAPTGVPLWTLVFEVVEMVPRAARICSAVLVLMPSRTASX
->SRR5713226_9196200
-KLYGWKLYGLEVIWMEAVWVGSYMDGSCMGWKLYGWKLYGLEVICMAVVWFGSHMDGSCMGWKLYEWKLYGLEVIWMEVVWVGSYMDGSCMGWKLYGWKLYGLEVIWMEVVWVGSYMYGSCMVWKSYGWKLYGLEVIX
->SRR5829696_2428463
-SRPVRIADAIPSIGSPACSQASARRTFCTSLARNGAGPGRATRMPSSTSRPTSASVVPARSASPDAESPVMPPSSYERGNLRGECRSVPDRHLASVAPARPTTASRQALDCASWLFSPGLGRNAGLTCAYDPARTYEPDHLACRPYKHGSIGCLQDQPGVDLNAGGWVLTGRPVADEGQRPGWRQAPQPVSRAPATLASTGPVVVEERRVGLVGLEGPGPAPRVGADRLAVGEAELQPEVAEEMAVGPVWIVAGLLELVWVRSGGEGERQAGGVGAQVGDQDGMGVGAGRHELNRDDAGNHGLGWSRPGRDPVARGRLPGRHREEAHGGLGSGHRVWARAAAASTSPASSAACEGGICSAGQWQAKVSGPGGGRPHSHTWPPSGPLTLWYSRGGSGGWSPVGRGQRRGSLSARRPSAKRTSSRRSSPQRCSGWRGWLGRRRTARSKSNPVGYTSRPSTRTAW
->ERR1719375_709491
-AFIALKEVLDGAASRLDRDGGAFAHEPRLGFLTSCPSNLGTALQASMLLRLPLLVQQEEAWPWRDWCREQRVQVQAAFSEEYKPVPDTFLLSNMDRIGTSDVHLVNLLVEAASLLVQMELCLETAGAGGTVDLRDLMVDIKVPGDGEAEEFPGFPAEECPDALPDLSGHCSFLADVLQKDPACYANLRNVRTPLGVSFGRCIKAALDNRGHPLVKFPGLVAGDEQCFEVFREVFDPVIKLCNVGFGEGAGGQGTGLLSTPIDPS
->SRR3546814_8950902
-XMRISGWSSDVCSSDLVDIEQHALRALEQDALAPRPRIIQRQPDGPRELKHELGDLAQVRLQPCAIDGTLAEAGAEGIVMSAEPVDMRAELAQMGKIADPDRAAADLVFIGRTDAAPGGADLALFARLLPTRIEVAMEGEDERAIIGYLQGFRGDRKSTRLNSSHX
->SRR5205814_2128888
-NLGVTTAGQPIANEKVTIALAASTPADYSGVAVKSASVNSSFARTTVNGATINLKSAGVFDMIQKASLQVAIPDINKTMNVAQAFSPPSTQPAATQPSAPLQIGGGAVVNVDLQREGQTTHITIPELAASKVSLVRGKRRFAFDKAIAVKLAADLAAGEKIDKIDV
->SRR5262245_33090118
-HWALGQNHVALFLQPVAKVGPEWRGLLLTQANAQRVSAVAVQVFRLDAFLGFLLQGVELTIPGQGSMAADRIAVLRLIERAPRMRVAGHLDNGAARGQVDAVVTTERVRLQIALEAGQKALRPIAGPSRRVVEHVVRMTAIAGIDPEPALAGRVTRFVLHRQ
->ERR1700744_713940
-QPIVEKQGIKAACHFFILSMRKLLRPAFDFLLFSNVFMSLCAVAQGLLTFYLISSKPIYPVLGLLFTSTLGIYNFSILISKPKHPEKSPYRRISWFFSHYRLMVTFTIVSLLSFIPLFFFISTPSKILMIFLAVLSFGYGLPLFTIGEQKFGLRNIPGLKLIMITLVWTMSCVLLPILESQAAHLATISMRDTTILIAKRFLFICALAIPFDIRDLFEDKQLGLKTIPVAWGEKNAYLFCQVLLAGYVALLFLFRNNGFSTDFWALTLSVVLTGWLIFRSKWEKNEYYYFFYLDGVLILQYVFVLTFNYVSRYLX
->D4D873_TRIVH
-MLRKGAINPDIDSLAPKNTSFFLFFLCTYSFFSPTSISSCINHPFSKVHLVQVLNYTAHQTFPSASRNTNRFTHLGAMAEMRYISPDGPPLGGMPPQDFAFLQAFHMPHFMAYPSIIQNPPPGPPPASTPAPAPAAGAPAATPAPQVSTFPLTIYVVQHGLTDQVILHQTFTTNVPPPAPAPMAPASSPPRAPNPNPTAAQAPSPASPPSAAPAQGRRLPSGAYPPDSERAMVLPTGQGYIFPKKHTTLHIIEAFTAPWDNPGSTFQWRSYRVPSSMSISELIDQLCPTKAPDGRDATSRGVIECLEIGDGTWLKGSEFWIGGRRGGDDNMKRRVSQSLTAVGWTEQRGTIAQPVWITLSIAV
->SRR5690554_8049497
-YPLLILSFFFFLMIRRPPRSTLFPYTTLFRSGKNQGVGPQFDFNGVGPASTHTLGIPNFGAHGLAFVVTRTRKIGVPAVCSQCEGPVFIIAVTFLIQEQDRILPVAPGILNHAVDARKALAGNAVLMALLFAGSAHGGKEX
->ERR1719239_204793
-GKVAVKVSLPTRNNSCKRSSVDQESTPASTFQGHSLKYKLCSLHGCHDVDVHTSPPTSHIAVDSSIIAEDVHLGVEMFLATIIKGNQIIFFGHIAPDKSNFVLPKLLPQLDQGFFAHLTVDVRQANLGSSGQESDCKSFAEPLSRTRDDX
->SRR5271157_3087616
-XMKLLLKILFAGILIYMVGMTTWVSLHKSILLSPDEFSWAQHPWAVATLFDAYFGFVTFYAWVFYKETSWLARMGWFAAIMGLGNIAMSGYVLIQLFRLRPEQAGIGHPVAESRVTRGFFHRRVVRPIVDLLTQGITPEKIALSIAFGLVLGVFPALGWTTLLCLLVAVWLKLNVPAMQLVNYLAYPLQLALLVPFIRAGEVLFRAPKLVISLAQILAMVRADLWHAIAALWVATLHAIVAWTLIAPVAVYLIYKILLPILTRLAQVTGLAKQEGSAASVAEVCX
->SRR3546814_2889336
-XMLRHGKYVLVPASAHIDDDDTVFRHRRRDLGKGSDGVTGLKRRDDTFGSAKKLERLERFGVGHGGIVDPPDFLEPCVLGADARIIETCADRIAFDDLPVRSEEHTSELQSLMRISYAVFCLQKKTNRQKSA
->SRR5262245_5483048
-DTMKQLVNAFGDYARPPKLELRPLDLNRVLGEVLDLYEDEQRLDVTRALAPDLPPLRADPVRIRQLLHNLIRNTLEAMPEGTRPRLEVATRCGSGNGVAMELEVGDNGPGLPPDFDASWFEPYTTTKPKGGGLGLAIVKKIAEEHGATVSARNRDQGGAEFLVRFPAX
->SRR6266699_1496226
-AGIGPVPRAAEPSDPGSTPWGRLRGRLRDSLRPTVSLYVIRSCQGRSTMAGQFAGRAVTGGRGRGPRGRLTTLSSGVRHCPISGCGDQIDPSRLMCRRHWYMVPKETRDEVWATWRSGHGAYSRGHRNAVRRAVAAVLEAAGHADGHRTGHADGHADGRTTGNADGHASGHASGHASGMATVGDSAGX
->SRR6218665_631217
-XMMLQTTYTVELHPETWYVLKVTATSSAGSTECILKFGTKSYFGATIEPLRLVHRFETPFYENIYIMVPLAVVTISCLIVIVAVALFCYRRRLRKRHKASSALRMHQEAKTALSLLRDIEKPVAAVGTEKSRDTQTYVAVPGLSTNVLKLVPQVSMDAKDNEDDEAIFRERTLSTGGLDIGLPNRVRVTAETGSQDESGTVCKDVLYGYPQKSSLF
->SRR3972149_6447067
-RERAARALVHKGIALGHLGRPDHAIAVFDEVVGRFGEAAEPALREPVATAVFSKGVALGGRGWRPTTRSSGASARRPSRRYWNRWRWHWSTGPSRSASWSGRRMNSRP
->SRR5678815_2305109
-XMCIRDRQPGGTWVDADRGIQVEFPTFVGSAPDAACRVNIQYAAAGAKPDPMFLTVGAGTVDLWMDNMQNGTGVYPSTQPLDGDGVPTGPGDPFAPGKVNLLNFRVRNLGAAPTPSLAVRLIAEQPPHVTCGVNPPRILDKIRLVDPIAPGGVALDGVNLEIPDNRLVRVRAEILSVPGETTTSNNKGERTFTTGANSAVLDQQYAGPVTINATFINGCPGDQLATAVPMTMPVKTGPPIPDPIFDRWRVTDPGLTLVGPGEQAQLAFTFLPPSPVTPGSGVTIPISFRAGGGLAAAGGMFGESRPQIDSMEVTIPVVEQAT
->ERR1039458_8973043
-PPSLNRKKWGRAEPPREQKIIWQHGPPAVSPHQFSRSDTACSRKTCSADAGFPARRRPPATLPRCRNGFSPPGFSTAADNPAPSAKAAAASAHPPPPLDRIAEIVEVLDLVFGRHRLGLRLAETGTARVRQIAEREHVHRMAVRADLAVDLETALQLRLVVFSERAGERPFQPRWGHLLGQLRGPRGPDGGQRTGEDKGEDGALYVHDHPHALAPRTDSEIEFGSGFVFSKMPSSGRTIRKKAKX
->SRR2546421_543181
-GCFRREAGAAGRDTHGMFRVHQFEKVEMFVWAPPEESWEEHERLLAIEEELVQELGLPYRVLNIAAGDLSASAAKRYDIEAWFPSQERYREITSCSNTTDYQARRLGTRFRRDGKAEAPHTLNGTGCERVPAQEVELSGVAGVFHVGVRSSFHQLVVESCDDVLPWLVEDDDAVVAVRAVFGENTHGVVDDLVSSSGVHPAVVAAEAVRRVGFLLELARQRVGFFLAGRALGVRSLLRTDRRLGAEDDPRGEQEVEDARREVEVGX
->SRR5262249_31764099
-DDPHTLVIQGDTKTFNCNFSQDAIDRLIKDDPESAKAEIEGEFRTDLSAFLEDAVIDAAIVNDRPKEIEPRKGVYYTAFVDAAAGGCDAYCIAIGHSEGSGDSGVVEIDVLRGRRATDPYQITAEYVELCRKYGIKKVMGDKFGKSWVEMA
->SRR5574337_5095
-NLKSGSVIPPAPFFFLKTVLAIWGRLCFHMNCEIFCSSSVKNATGNLIGIALNLQIAFGSIFAILSLPTQEHGISLHLSISSSIFFTSVLEFLSIVLSSPKVSLFLDIYFFVAMVNGIYSLIALFDFSLLVYRNVGDFCVLILYPATLLNSLISSSNFLILSLGFSMYSIISSANSESFTSFRIWIPFISFSSLIAVASTSRTMLNNSGX
->SRR3989338_7824970
-RWNCDWSSDVCSSDLSLFCLFCISEIHAVFLFNFLGSSRIFRVVFFACFTCDPCTFLFLVLRSLGGGGCIFFFFSFFLFLTLAPDALEGFLIDGEESFEGETDTSLVDIDINDLCVNTLADREDLCRVVDVVMCEFGEMNETVDIFLESYECAVVRETHNRPCYFLANWVAFRHFLPWVICQLFHTEGKLVTIDANHFHGHSVACFCMLGRILHVAPCDLX
->SRR5688572_19622849
-TDDEMQNPGSWTQDGRLLFSQGIRGVDGDIRILTLDSPPRVDTLLGGPAIEVLPAMSPDGRLLAYMLVEPVGQIFVRPYPNINDARIPVSNGPGMGPEWSQDGRDLYFMVRQTELFAARLESTNPIAFGKPRLVRSLREPTGDPIRVTLPPVNGRLLRQVRPQVSLSNPTEYRVVLNWTEELKARVGTKX
->SRR5687767_14888222
-VIDAHTGKQLQVVDRLELEHGEGAGARYRAGRLDLVDGTPEQRPGAVTVVEVYRRVAPGNVVRQPLRVDAGDGSDLLTQAKTEVAATLDHEHVGIGVDRALGEGHDILADGKAGGPTQIVRDSCLGACLNAEETGVQLGITAGGRIAAVRX
->SRR5216684_2934442
-YASRKTLPSDAKPQQHHSQGLETWLREKSKRVYARASVLLRAPVSSPHKESLGRLPINRAGFLFTLFIASFNCLRTDLLIDLLISNALVVKPDGLLRDVQSWVKPFAVSIQVSDPLVSIFAKDANFLVERVVVQSQVLQKVPLESIRICDDSFPRVVPISFAEELAPVEHAHIKEITVYGIPEVSTVRVRFEQVSELHRPSSAVVGHVAPKRPAQSLNVSEDLASRX
->SRR5215469_11197210
-SLQVQPVRSKRLWPAIASVLLVALVGVSAIHFREHPPDSPKPIRFQLAPANVIIGSSARPSFSPDGTKLAYYATGSDGVARLWIRSMDTLESRSLSATELNANVPIFWSYDSRFVLFPSAGRLKKIDISGGPAQPLCDVAAQVVGGSWNREGVIVFGTNNTAIQRVPSEGGNATPVTALDSTLGESAHLGPVFLPDGRHFLYLRRGRPESTGIYIGSLDLKPDQQSLKRLFASDYIPEFVPFQDGRSGEILFLREGTLLAQPFDLRRLELTGDAIPLAERVGSYLGDPLFSSSRTGALVYRSGGAGEFSTLTWFDRQGKMLSNLADAFYGPFTLAVSPDGSRAVAERLETTGVNLWLVDLARGGRTRFTYTRSGIDRYAAWSPDGAKIAFSSNRGGHEDLYLHAANGAGEDELLLKSDSDKSVTDWSRDGRFLLFNQLSGKAIRELWVLPMDAAGGQKPIPFLRSDFDSRSGRFSPNGRWVAYGSNESGGNYEIYVRPFPPSAGGGKWMVSQGNGAYPRWRRDGKELFYLRPDGELMVADVGADGAVFQAGVPRPLFKATYVQGWDMSADGTKFLFPMAGGETTQFPFTVVL
->SRR5215471_2447632
-SWRRSSGSPSRRRASTWGSSPAWPCWRASGAGRGRCTGSGRNSSAAYSSRRRTGSCGPSRSDLPNGDQRMQLVPAVLIVEDPVARRLDAGADSWDHEVVVVALTGRHGVSLGDVPLADRLEHEVTVLLLDVLRVGARLSIAALSDVELEADVVVAIGLRPLVLDQPLQRGRLAAVQQPEPARMIDMSGRRRAVGGAERNGTGRRIELGRRT
->SRR4029077_541644
-SPASLRPAKANSAHTGPAFSSPSVPIPSAASPNFHSSICTAQIARTPTPHVFPLAPAPDPKSSVSSFPNTARSHNRHTSTHQTPFPNNQSPAQCESARIAPSEIHPARLLQQAPEKPASRPAPDSLSPPFRSSGTSLSASQIAGRAASRPPN
->SRR3989344_1047100
-AYFEIIEKRQAPSETSAKVRVPAVFLANSRSIPIKAPNRTANANWPNISKFSPPKNPILVHQKYLVAFSDALADFNPDFFAFWRHGNLLVIILHGFNHLIKIRRRPAETKFRARFNRFFKFYDRDFNVSVEMSNYSDGLALSLPNGLFHLHRRLCFRHRFLGGFLRCFFNYFSHGHIFRNXX
->SRR5215510_3565519
-WPRALLHRTCRRGRWRLQTGELGHGLQVQTMTVGCMRVVTFSQLPSSMPTALIQINDGVKPCSPLIKARPRPATGRPRPRSGAAVEGQADPASDISSMPRPVGLVASRHLGIAKSLRWFAELPIGDVLSRTGTRARHRHNRDRYSRRPX
->SRR3974390_2059552
-ARVIHTCLNKDAEERFQSAHDLKLQLEVLVSFAEQPAKAAPPVATKPWTARAQWVAIAVLVFVVGVTAFAWWQLRNELKPVVRSYLTAPDKSNFNTESVALSPDGRFLAFSAVSATGGKMLWVRPLSSLI
->SRR6266566_5267620
-PLPRPPLPRRTGRSDGRAGGAACRGLPRDDGNRRRPVLRIRGGGEPARGARGELAGGGVGSGRRAGGAGAGSRGVRGGRAALAARRARSPARLRRRFRDRGDDGELPRARRRPPGRPAARARGAWVHVDGAFGLWAAAAPAREHLVAGIAAADSWALDAHKWLNVPYDSGVALCRDGAALRAAMATQAAYLLQ
->SRR6476620_1160279
-LSNNKGTIITLAVAKKKEPTSPSSSSSHHKRTMTSNTNTANTIHPSPKPNHLHRGKNQDLHSAIPKTTTTTTSPSLSPSTLSLSPSSERPSDVPAPSPEEQQATVQKLYAASAVAASDPTNFNSPMDQQTQQQQQSCSYSDSIDKFILPFKEARFTHIRPCVTMTGTVISGLKVNADGDISFNIAVDPAYEGMLGPGNLDPSHATSSGEHGIHIEVICQEPVNSSAPMDVGACNGYNGPDFHSLLPTDHEHVMVTGRFQIEWNEAPGGLTEIHPVYDIKTIPKTX
->SRR5580700_450720
-DMPIGDDVIVLVEHHPPCLRMMLEDDGPLLGRSLVARILAAQSQPLETTIHALAQPVQRIARHGIDGRHLVDVQLDEVFEEIHPIPTPAHDVVMAADPIRRQQPAYAVDDFADVAVVGDFKIFQLADGDEVVGQSVGRNYGAVDQDRQDLESVLLAQIQSGFELATDEIMAAVETVLGVPLRTDERDHHLARLQLAHDLGDDLVARLRDVDVEENLFLRKGRFQRLVEPTRNRPGIVAPIADEDTLRHGSPSAFLGLPGNDLALELRQQCRSDEAKEADHHDADEHGIDLEQLPGIPDHVADADLGGNEFGGDQHDEGHRDRDAQPSEDHRQRAEEHDTREHHPKARAIIARDIPVDFLDISRTRIGVDDHREEHADGDQRDLRGIAEAEGEQHERHQRHFRDREQHGNQRIEEDAHRTEHRHEEADRNRRHDADDEAGDDT
->SRR5580658_247251
-RAKLLRALPAALFFRRRLTRRTQRAHNVLAGAVDRKKNPPGESLGLPCCRRLERTALPAEPRLHHAVAAHALIHAAGDRLHLGQLRHSKILTDYLRSAFICGRPIISGQRWCDQAPQQSCSPRSSQSSTRPEGLPHTRAYSGSFLKYRRPAWCPVCRRSTSPAPLSHKSAPCG
->SRR4051812_49755575
-XMAIFVTRWIRRLSWSSWRVFRLSRQNSGVLWFGNSLLCLGEGRTSRVSFFERSSPHPRSDALLLLADGIRVDRCRGELGMAEPLLHHIEGDAPADSLHPEAMAQALGVGVGAVRDARRRDNLLHPPVGRHAAPRPQPHFCWAAPGCSAAGPCPPACARLPDAPGPCARSAX
->ERR1719445_2651091
-NIYVVLLFFYVGVAFVAGEQYWWKFVHADCGYDDVSPQPACGRSHKGDVEALKACCLNTTGCGGFNTNGIIKKTDCLSNKKFESACDLYVLEDRPQPPPGTKFPPIWPLPKKYSNGTSYASVSTAFKFTSGKTTTTLTDAFTRYTNLIFLHDIKSSTVNAAVNATALSGLDVSCDSYDESHPQLETDESY
->SRR5215211_4540433
-AAGGLQRGGAGVGGEVMLGREPANVADLAQEPGRQHRPHPEQPQQAGVGPGDRGLDSRLDRGDLLLHLAGVGDEFCGQLPTGDRRRTGRGHFTEQGGGPLGGEVTPGAAGDQVHQQPMQPVDGLGPRGHRSWRRLVNKCRTTAWSSTPTWRGAGILNAATTTETASSGSLLRPCPTDSTRTRAASLAGTSRTCSPSPTSRWASARPMPWAPSTAQQALWPALGPSPQGLVALKGGSDALLAEQLAVFVKRGAGVGGLVRGRRRSSPACGRLLEGRREQPGGQADIGALAILCXX
->SRR5215471_16031673
-ANGSNVQNEQPGSRRHDNETGKHNSRRAPAFAVRTAFRLHGSGRKDRGLEREKIARPPTCTAPLAPYRSERGVRWINWQAYSLEQRAGWSRDRFASETSVRAARMAALFRKGSESRQPLEHHFVAADWRSPQDSMGVDTLHPX
->SRR3984893_4885850
-CCRRAATGSSRCPRRRSCVPRLSTSTAPDRPRTALPVPGQVVDHLDDLAAAVPLLPGELQQVSDLGQDGTAFGGARHRDAASAAELQQPFLAQDVQRAQDRVLFHAEDGRQVLGQRQAFARAGLAVGDGAADLRGDLVVQRSRAGSVDVDINHGPSHSSPMLDEWHGPVSAVLAPPGPSAPSEAEALFAEARRRRRPRRLAVRVACLLLAGSAAAGLMTAWPSHGAGTQYGHPGRAAVPHTPDFTLPRVRVAWVDYGGQLHIGDLATGTSRSWRRSMPRQPTP
->SRR6266568_5935642
-YSAIRLNSLKALAALAAQKADTNVSTAKATSNPPTTTTARPSGARGRRPKPTPTRIAHHSTIPTIARAVRPEPPFSYAMQKTRIATTPAIHHVSKATRGLRRGVGSTDRTAWVRGATDMGGARLAL
->A0A061IJV5_CRIGR
-MLCFEGLVSLVSGASCFPFFRADYWKSQPKKFCDYCKCWIADNRPSVEFHERGKNHKENVARRISEIKQKSLDKAKEEEKASKEFAAMEAAALKAYQEDLKRLGLESDIPEPSISPVTSTVQPTSTSDQPKEKKKKKEKKKKDPSKGRWVEGVTADGHCYYYDLITGASQWEKPEGFQGNLKKTAAKAVWVEGLSEDGYTYYYNTETGESKWEKPDDFIPHTGDVPSSKDKEKSPESLEESKSSDSHSDSDGEQKKPGEASAETKKLVIKFKEKNKSTEKRTDPEIQKEKSTPKQNPSTTNEEKSKPLKKLTNPYGEWQEIKQEAESQEEVDLELPSTESEYLSAPEAAAGEIKVVFKEKTVSSLGVAADGVAPXFKKRKIENGRSRNLRQRAAEMSHHLCIHLFRNPSYTRRHVFLYCQRFRQISLDTRLWDFKQNKSHVLHQVLNKSWSRSYCHQDPKMLWKHKALQKYMEGLNEEYQTLDGCLQDISGNEDSRRALCRRHAKLAPLAAIYQEIQEAEQAIEELESMCKTLHKQDEKQLQELVSEERQIIDQKINTLYSELLEQLVPKEKYDKSDVILEVTSGRTTGGDICQQFTREIFDMYQNYSYYKHWKFELLNYTPADYGGLHHAAARISGDSVYKHLKYEGGIHRVQRIPDVGLSSRMQRIHTGTMSVIVLLQPDEVDVKVDPRDLRIDTFRSRGPGGQHVNTTDSAVRLVHIPTGLVVECQQERSQLKNKEIALRVLRARLYQQILEKDKCQQQSARKLQVGTRAQSERIRTYNFTQDRVTDHRIAFEVRDIKEFLRGEKCLDQLIQRLLQSADEEAIAEFLDESLKSVK
->SRR4051794_32399155
-ADVGRASAGSCMVRRSFRTLPGDGGGATTVLSLETQTLATSSWRAELPFALSRPRISPRVALALEAGAVLAILLLAAIVRADSYMVVPRLTDETLEVMLGLRLARQGGLPLVGYAPHIGSLFTYLTAGAFLLLGPKIEAGRLLVLTTGVLTVLPTYLLGRDLGQLLVARGEGRGARDNTRRAEAERLTRGRIVGLIAALLLALSAPHVATSSRIAYSNSLTPLFIMTGLWLVSRAIGRRSDRALIGSGVAFGLALQSHVSAVTVLPGVAAAILLPLLASWKRGELARVTPGGQ
->SRR3954453_11447405
-AENDRKNQDYDPENFRLLAGRRVERCWSDAGINECDDLDDEQRQADDQEDAVQRPEDEHRSSTVARWRRDVIECRKIFRRRFPGTGGDIRADLFWLRRSSDDRRNRRLSGEATDSDVEQAATTLGGVLLEFLTDVEDTFGERLGSGGKSSPLRRWLSAPVLAGQQSACEREIGQDAEPEALARRSHLRLDVAFEQAVVVLHADEPVETPDAHRPVRVRDLPALEVGAAEVANLATFHQLVX
->ERR1719182_1343932
-LLKAKYVEVNALRVNGKSLADYIVMTAKKSNLCKCGGGGPTKKPTKKPKCPVAMIKCKCGHTYTMVKGCKMAKCKPCGDKTLSGGNNGGAKNLKACTGECDSEAQCAKGLKCFQRSKGEKIPGCKGNGGGKDWDYCYNPVHGGIKELGGPNDSKAKNLQRCVGECDADSQCAYGLKCFQRSKGEKIPGCKDGKKKMPGHYDYCYDPKTEVKKPDPCKKNNGGCDKARKCMNSNGKAKCGNCPKGYTNSGATKCQKNRPRGKEPERRQQRWCQEPEGVHWRMRCGFAMREGPEVLPALQGREDSRMQGQWRRQRLGLLLQSVARRRQDAERRKQRQCQEFATLHWRVRRRLAMRVRSEVLPAFQGRADSRLQGSWRRQRLGLLLRPQDRSEEARACNEVRSRQCIQLQSYQDQHPQVLRRELHPQVDWWX
->SRR5574341_165588
-XMGGYLSSKLFRIIESGDRTMNPEQPQIFGLIGNPVTHSLSPLIFEYLFKKHRIKGSYHLFPLQPEQLKSALEGMKILGMSGLNVTAPYKEQVLPHLYNLDESATKIGAANVICNHKGKLKGYNTDVIGVRRTLKEIMYIQAKIGAVALIGAGGAARACLQVLKELKPEKIVLFNRTAEKAKQLAQQFNSSIPLQHRNLGELENCRSERDFNLVINATSGRNPAIKKAMLKGLSLGSHLFDLNYNRDYGINHRFHKRFCDGLYMLSCQAAESFRIWFGKRTEAEEIHRYLKKRLKX
->ERR687887_1747641
-AGEAAQAQGDGAQRRVAGLDAAAGVEGAEAVDVDERQRRGPAVALGTAQLVGGGAAEGVVDEEARPGVAVAPFVELGLQRAQARLRVSQLAAQRLLLAGSEHGGSSAERRRSHSRWTRFGARSPELGTAHRRYPARPASAAARX
->SRR5215218_6855622
-PSVRRAVMPYWSVLLGGFARIPSGENRHDDMPVRLSAFVSLLAGVWAVLAVLSVWGAGSAAAAAGTRLVISGAFHATSARTVARDEACAYRPNHTLIYQSDALRLGRSPKAVVRVQFFIRRYRGLARYPAAGSAPYRRTAVQVVTARNAATGVATAFYIATSGSVAISQAKGVARAGHRASLSGSVHAKLREQDGSRRLRLDGTWHCRIEPDANGGRPRTSRRVQERSPSMTDVGSSRHCSGEAAAGLEPTNRRPGRASAGRARGRARX
->SRR6476619_648836
-LFFTTYIGWQPVLVTRDRHGELHCLLNTCRHSGTIVCPFQDGNAKLHVCRYHGWSYDAAGINRAITGEQDGQYPVAFKNANHNLINVARFGNYRGLLFASLCVDVPSLEEYLGDARIFLDIVLDQSENGFEFVPGPVIYTYDGNWKLQFENGLDFYHFNLLSPKSGAAADKIAALGPRLAHWNVIGASNVRNVASSRCYLRHHRNSMPFSVLARLSTYWCIAANDAMCRX
->SRR3954447_23271464
-NWRRLWRRYRFVATLEGRLERLGLLCPPDMMQGWNKGPAIWFPPPGRARCTAETAAQCAGPNAHRQYGQRPVAPSNEIIMSARMPARGGLGVECQEAKRHGRSRKSGALEKVRGFRPRCAQGAFRRPWARTAFGLX
->SRR5437588_9293553
-ASAAEMAAAAGLSLAGASALAAGADPATAKLATEPVGPSALMDGRTAVLGGDEVAQPPVSPPGPPAGGDQGAGRLRPVALLAVVLVALAAIGIALALRGNSGSTPTTTTTSVPATTAVTRPPTTRPPVTTTSAPTTTTTSPTTTSSSSTTTSSTTSTTSGVLGRVGGRDHKNADAANIGGGX
->ERR1719421_986179
-GSSSEDFGDQSSIQRCATLDDAYAKLQRESAVAGQFEAFAAATLDNALAERAALYRLDGAESYVDACEREASGAIMGLLDSLPGDDAPGALRALVGRALPQALRERLWSRRLTDIKVQREFRESRGDWSVRSPHEADVTAFCVRVLSDTDGDKLCCARSAFSFLDQKARESGGPLPSDVYWLAKPLLEVLALDDAVLASAVRCVLERGLEPATKPEGTLAFGDESTDNQSVLEGGAGAAALALRLGVQRKNTQRWWVPRDWLRRCRTLLVELCPSLAKALKCEEDTDDSENVIARAIGRSMRRGLSDILSTEVLLFVWDQCVLTSFDLVIPYAAACVLALLDEPLQFFLRDNEDPQVHEALMRLGKDLPLIDVEACFRRVVPKIAPDARELTDAISARPPPGLLVEASLPGAAALGGLADVVVDSLADGAGFTMHGTLHCFLRNLDCRLEWCEVFPAKDSLPNVVDRLLALPANRKCILKARQQWGDQGGFDASLREACAVAACRALPGLAALYAGSYPATIQDALKDIMKECVRFSLPVRADDDDRDGDGVKDEVEYEPTTGALLGEHVPQVDVLLRKNSKPQDPGLGPGSALLQAAGIFAIRAAPGSLWPHYSPGLMHLVYLAYNMLREQHHLAGIEESKQKEIAAAEKAIDNCRRAEAKKKELAQKERDSMNAQEQAKLDEQYRKEAREQQRKRIEAADAADEKVKDAFLACVNAAKECGDTYKKCREAFEAKERWRKQLIFRWSRGSKRP
->SRR6266571_3544720
-ERFPERGPVPTVPDSLVKSSPSNPSGNSPHSHSSPKQHLLRILEALSLSTDKALLRNMSILENNLRGNRASVTQLVDMLTRLRRPCVNEECRGPFRRLGEEEVEVAVAAICGEHLRTIHHPLSTLETGGGLKIACVGARARLGQRKAGELLAAYHLRKILLLLTRITELANALATGTVNGERKSGAGASLPAHLHSCDVNRPGKLQSTKVFWKAHAGESLLEEFPNVLARKLCLQVGLASCRLDLLLEEIAQRLKEEQIIFRSXX
->SRR5918994_7596206
-TQERPRRNRPGGDPAAGDARRGRGGDPGKGADDVPRVRAAQGPREPGGPQPGVGNDDGGPGPPAGVRGRGQVRAGRDEQCDPVAGGDPVVGEPDGQLVHAPDEQVPGDRADIRFDDGGGGVAGAGVERGPQRGVRALRVTARWTSGPFVRTYPTNGP
->ERR1039457_7143814
-XMLSIIGSVLVLGSVLGSFLMEGGSLLLLWHPSEFIIILGAALGAFITSNPLKVVKGSFVAIFGLLKGPRYGRADYLDLLKLLYDILVKIRKFGMLAIEADIESPGKSKMFTEYPRILADHHMIEFITDCLRLIVGGNLDPQELESLLEYELETHHKEAAEPGHAVQKVADALPGFGIVAAVLGIVNTMAAIEGADTATIGKKVGAALVVTFLGILVAYGFVGPIASAIENRAHEEGKAFEVVKMALVASVRGYAPAVAVEFARKLLWSDVRPIIVKKVKKSAAGHHGGAWKVAYADFVTAMMAFFMVMWLIAAVTKEQRAAIFEYFKNPSMEQGKSVRASLGQMGPGGASTSVINMGGGLDARRSASALSTGIGTPHNAEPTADKEKAQDKERAASSEEQARKLTEAADHKKLESLMQELRKAIDMSQALRPFKDQLLLDITPEGLRIQIVDAQNRPMFDLGSAKLKDYTATILHELAPYLNTVPNHISLSGHTDTTPYLAQNGATNWDLSADRANAARRALESGGLATEKIARVVGLSSSVLFDQDNPRNPINRRISIIVMTKQAEESALAPDAAPQAKVSELPATLAPQAPAVPSVAHX
->SRR6185436_12656879
-PHKNFLAPLARCFRHLDRGDKKMNSAKQRGISLTVLLALSVAVVALNAAPAAAQTSTYMKVDGITGSATDPRHIGWINIASLGQSASMPVQASSLGGTSAGHVVGACDVEVLKGLDAAGPLLWAALFAGKHI
->A0A2D6A177_9PROT
-MGQIFLATANLLALLISISASAQSNQDQFYRYFTKRIELTANGQEMALEVHAPASELPAEAGLFAEVDGLLQPFGQSQRISMNRSKGAWVMTMAFRKVPNEGRVYLVTRSSTGTKTYRFTERPWESPREGELESTRPRAIAAKPLPEMKDSDVFRPVDSYYFPAMTARFGGVTLETETNVQRTVQAITTVCPQEPLNYDPLRHKRFVVEYFPAQDDADKVEAALQAPPLSTQSLRTTPQGCLALSIEVSHLWYQCQRYFLLPIRFTDPTTGISETLTLGVNPWDEGWVFARDARDLQPHQLEQVQCRPPQIHLNSYSLDGAGMNYSIDHNLSLVVEKNYYLKLSPRVQRADSITRGRFGGAALRDGFYLLNIGLFYRAEEGEITPKDYVSSWEQIVEVKSSEIVAPLKFDLKDMTLMGARNQILMQLQPIDESKVVLKPATASGNREIDQDATLRAENLVLENTGLHSPVYQGPIIPLSAGQGPILRPSHINLEQSIKLGQLQLAELAGDFQRRYRMTHFDRMFRLKSMLHSEPEARLWLQQTFGKYILAGPLFDFSVSPDINRSYLDKQRLQASLCDGWAGRFLRQQIQLDDQTTAAQRTMQIHYFEQFLRDFRQACIRETLDDRQTFSLSPSMMIRDIDPERTKYIGGTSFNYNINESFSLGRSENWGTSQSTSSSLSFSASLKAEIGVTSLGASRTETLSSSENYGRNLNESNSISYGRGTYLVVQHSQVEFVPTEYQACQVIRPKSEFIMDLLDKEVIERRTERPRSRMVHLWDRIVDFFKVDTDDVSVDTMTYRDVFGRDLSLDLMETGLRLCEDGTRTNDDSVIEDYYYVTQHFTAGDMQDTFDNRNRPWLMMIRSTRDFNVFLSNLQGQSRLEHRGVENIAPVEILADAYDDFAGTLPAWPGIYNPTERTRSDQTRCDNQVSAPDLLVSAIRQVIAGPFVQPDGNHIFSDRDFRRIWHCGEE
->ERR1712176_1124453
-KMKANNNMAAATANSAHADVVNASNKTERDRLAEKMKANKNMAAATANSAHAEVAKDTRRHTKALRKRTFATSNYKRFYGGAKAPVFYHQLLNNVYTVLELYTARINPTLEKDMLTEGLNDFMSLLQNDAFKNNKTLQTVDAVAEYLWTSCKRHAIVQDMEL
->ERR1719473_1570082
-RGGDLHKKCSSGKARGTKSAQSPEEGRPTKMITRTCRTERHLVFPNNAITMKKKHFSVIVPQEPSAQQDPRDIHLLSVTQTSRALDSDFGIRRLTAWQVPHSSRLAAFEQKKERRQLCNRAIMCCVTLYEFIPLTGLKRPEILFYLSRATDSQVPHASRLPLFWPTLSQADKX
->ERR1719473_2414288
-AGYDFNSCVPVPQATTATAGTMSMAEGEPTTLPECTCEGENGEMFCPGDSYTAPDGCNSCTCTETGVGACTLMACPEEPTTLPECTCEGENGEMFCPGDSYTAPDGCN
->ERR1719473_87410
-ISKMMRAVVLMCGFLALASSTNLRGASEDQKKKKDGPWPKLPLEHLGLKDFLDWEEPEDPIPPERPARPEGGLAAVDWDYNDAERARMEIEHSRNNEWVNGHAPTGQIDPVEPPMTEPERTLLYQLFGKATNLLEFGTGGSTIAALNFENIKKVTSIDSAERWKKLIEHRDDAKAAIEAGKLNLIYSDIGKVGTWGHPKKPNTKPIYKKTASSPGFHEDGSENGPHRSSPFGGLKMIDRIAMKRRAHEAVAQFAQYSGETPAAAGVADLILVDGRFRVASLLKALQRTPADKRSETVFAMHDYGYVSTKYNAVEQFVDKVQQADSLAVFKAKPNIDESALAQVIKTFEKNPKX
->SRR5437660_4872881
-PLARCRRASRVTARAHPRADSASSTRLSKRGLHPGIGGNIAQAGLPELYADLRHAGIKQAVRVPIAHGVAARLTASQVSFFASDPRVDRIIYDAPVQLSDTPFDPGALASLYPQVVDAAASWSNRPSPLTGNGIGIAVIDSGIAAHPDLAGRVVVRKGFSPDVKEASDTYGHGPAVAGIIAGDGTASGGAYVGVAPRASLIHIRVNDGTGAAPTSAILNALLWATVNRKTYNIRVINLSLQASVQESYQTSPLDAAVEYAWLKGILVVVAAGNKGPNSELYAPANDPYIGVIRGRVQLAVRTLVAGGNDHQDALEPGILHRRVQRAGLIRLLDGCLQRQVDDADVVGLAVDGCPEQGVQDGGRGRRPGAVVNPDVDQAGPRRDADIRASTGRSVARDDAGHGGAMPIGVTRVVDIRVEVLAGDDPTGQVGVGRNSAIDHSDPDSIAGQRRRAIAPAGRRVHDLRIQARQRTWIEWSVGELHRGVINDPVDPGVAREEADLRRRKPGCNPVGDRNPDRLLDAGVSQVGIELGQACLGNQDHIDGGANARRAAGFTVEPFVSPRRGERWSRRQGSERQADPEAGRESCPEQGGHPVTGRX
->SRR5674476_1677054
-GRPVAMDVSAQAVVVGATEVIDSSLPAAPVRVGASSRRAVSCSHPNPSTINRTIWFASRAGEGSQVGGCPASPLPPANPDNRAGTRVARQPPSSTGRSGTADPSEREDAAITSDGTP
->SRR5258708_27400449
-SRRVCSALLTDGSAMFLLRHLACSVFFFFNDPAPAEISPLPLHDALPISRGRPRAALDDAPERRAVAHRRGGRRGPGDHPDGARDLKSTRLNSSHQIISYAVFSLKKKNGGLADQPPDFPPRAHLHRGAGQD
->SRR5260221_9098150
-LVPDATPASPHRDAKVSAPRHPQPNNACRCPAPARARKDAPEAVATAPARSTRLGNTSFLPSRETSHQVAACARTLRSRAAQKACAETLRHLGTATRKGLRAAEVAWPQARIALCSCPTSRCRTPRQSPRSKKTKPHMAGQLRIVPMSRLPPRVRGDFGPAPLEQLPPIAPPCIV
->A0A151A617_STASA
-MFDMLKTLKLYLAKDATINQYCKNRIRAYTIPETADRTDTNILIIPLIAPTPSTYASDKNLTTDYLFQIDVRSKSYEETKLVSEAIRLVMKGIGFGQQDGTDEYDSELKAYFETRRYRGNPYTIDELRHIDKDIEPTLNT
->SRR5882724_11345676
-RQRLSRPARASMRPVACAITASGSRRWRSSIARTAKSPRTPRSTTCWPTSTSSTTGRSKGWPPRRVRSARTRRCAGTATWSTRRSSRWPTTRATIARRRSCVGSGRRRPPSSRKPRATTPAPRCASERRRCSKVQVGRGRHLGRRPARRQAFSTDRKVTSHTIGHAGNIWSVRLRSRSMRMLRGLPRGEPSRPATIETAVHPDGGLVSLLEEQVLELRGALEDAAEAICRTDASGRLISVNRAFTEMLGYAAPEILGRSWQTVIAAHDRALVSADLEAGIRAKIERQAVGLRRDGTSFAMHLVLVPLFSRRDHHDAVQGHYFYIRDLTERRRT
->SRR5882762_10441494
-XMCSTEAIDGNVDDAAKEQRAALAFELKIQIGAPVLPLITDGKFVRQWSKLSEQDRKFSLLQEPAFVISWYRQHEALFEPIVCLGYDFSGELLGVMALARCREDGAITHAGDFHAEYSGWVALSTIDERFVEESLIAIKRTLGLKRWAWKWLAPGTPVGFLSSSRLAQNGIFATFRTERSPVWNLEDPERLNQLLKTKSIKNQINRFTKKGGFFLERVRDKERTRQLLKHLRLQCDFRQEAIQGVRPFADNPCKEPFFVERQEYPESNHFTVLWSNDRPVSFHFGACNRDTLLLGLTAYDPTESRNSPGKVHLIELARMLREEGIRRIDLTPGGDQYKEFVANESQELVVPTFYFSRAAKLWADLVEAARRTTKAALTLARISPNALRALPTRLRRATLGRLLKRIRRIFYENVVYLQYTTECKPSEAARDPEIFVQRYEDLLLYDDDNPWLGRRQLLSAALKRFGSGETLYSASRGGKLLHYGWMTPGGQTHLLQGVNATFHSPSDSVVLYDFFTHPEYRGQSWYQRTLRQMLQDLSAAGVRRAFIGVLQGNESSQRAIENVGFSPYRSFGRRRILWFEKKDERAMKPQNMTX
->ERR1711974_149456
-NAEYMGGTSLKCYSLVSGTSDDMGTETTCPSIANKFCQKTYDSNSGIVIKNCQLTGTNGCTSVGTLPLASRHRSVQWVGNYRDQTNDCHHYCPVDNLLRKNVLGWVEENPSNFSKSLSCHX
->SRR5919202_1515199
-GQLDHLEDPDPDPRRRRAARTTGRAQLGRPADGLADGHQRPQPEAAGRGGVCRARAAGPRRLKRIATNTPSRGDTPMNTFQKYLLVTLAVGLPATALSLPLWPPQPGADPSPLQIALFFGIFAAEGLLFGFGVAFVLFGGPLVRAATGAAGVRSWPVFVSLAWTLLSWWPHDGFHRASPLGDLDATLRIDYAFHLTLIIAAVVMARFFLATLRAT
->SRR5947207_7774739
-SGGPRAAGCEANRPTESGTTACPVASRPANGGSPLLLRSPVPARLQTRSRRPSVRFPATHATPGRDRQDRAPARTPPPPRPAGRETAWARTTESNGAPTPPALLHRVTPTVSRRRGTRAGARAWACGRHLQIDERLWIPX
->SRR6516225_11363389
-NVCARRVSTGANSAEGTVDPLTTRNAATLQEAKEELLDLEIPEHRGRSLHHFGDVLARQRTRIPLAERNVRDNLGLAHLHGLGYGLLLGRVGLARKVIAQFLDLRVTGPAKHSLVAGRIHEASEDWIADVSRHPSGYEGMPAARIRRVLLRTTRNQGLPVHRLHVDLEAGFLQQRLGHWRKVGKRGQIRRLHENDRGAVVP
->ERR550534_489957
-PHPPASSGAAPRAAGRAPRQMSAADLWAQLQGALELLSNVPLTHLTQQACVPYWVFGAVFLTHLTLLTITWIFWRRIRNVYSQLEQSSEDAATLSELFSSELGRLRVQLSQSQEDSESLDEMLGSILKGGLPGHLELTSKDYWCVKTMQVVYTDQDGKRQEWRQSGYRVNCFVPGGARDIEVTFGVVGGAECKQVDRSKPKFPYVYDESGRTKLERFSYERCPANVRYEIRGPSIAAFISHVTEVHGAAQPSGGDAAKETSPDAKRERSLSDHFSVAESRVCSX
->SRR5262245_51303680
-SRDAVRALLPRNENVVRRQHSKVVEDVVDGKPCPGYELQVCIHSCAFDGVPTCVPTSHAALAVDEHKILALRCDEMGDPPDETVSHPKCVLELPGEQSLPPRVDFPPTHGELFGDVLFVGVPYYFSLLKARHECSVTRPPGRITWCGSNPASPIRS
->SRR5690625_3526233
-RECFFFSSRRRHTRWPRDWSSDVCSSDLYDYDYQNVGGRWVHGFGVTSPADEPFSQPGDSGGGVYQGDTAVGVISGGGNLGGESFTWVADLDHSLEQSGTDFNLEKPGDEAPENPDAPKAKDQTIEPGEEVTGKAEAGAEVEVTWKPAEEGEEEGTDNHAGEEGSETVKADEDGNFSVEGPEAEGAYTYTATATVDGEESETTEFEVTVEKDESETPAPDEREISVDPKEIAASDFVKEDEGVTITVKGFDEGEKVTLEVASGPENVKGITLEETANENGAAAFAIYGTSASDPSAYLGKYDVEVTGANDTEDEDALTGSFEVVANEDGNGGGTGGEDLKSTRLNSSHVAISYAVFCLI
->ERR1051325_2865591
-WLEAAAGRHGGLGTKEFSRSGLLFGRDRGGSQPLHFVNATAGNRPLDLPSLPAFRFGGYSGASKVDGPSNAHDRRWLRLLLSIDSVFERQVFFRMGVGFGGGYTGRFTAELCAVAGGWQAGIGGRRHLSGALPGISHYRRVCGLAPRNGPALPGSRDLGCADQFAKSRPK
->SRR4051794_2477398
-VSDRRWFGISVCARRSNAPRQECWRPPDQIAEAIYLMCNAMFGIMCIVTVSAATPTITILLFCAAGVSWWASEICLVFFLPATLQDLLGVLRHQRVGVPGQFRHSLHPHLLSDVETVPLEAPQNHLRVARIQQPRHCFLA
->SRR2546422_7969508
-SATSRLLMFCFPSIHASPFYFFFFFLMIRRPPRSTLFPYTTLFRSKKQTRSVRPDSPLRPGGETHAYDEQPPVRCSSFSSRTQRDRKSTRLNSSHGYISYAVFCLKKKKKRNIKRVEAKVCARPPNAQ
->ERR1719506_1077933
-EKADENIEEYFAHLENKSGTCRQVGTVRIGKIYNDVWSYNLACDRQYDTPCNSEGWRLLDRGSLYGGCIIVNQIEVCQFPQERYGHMATVHLNKLWVYGGFAMFCEDYCIDMWTFELPDYRGYEQNVYVPGIGVVPGQTPLPWGYDVDLYGIDPIDGHMKKLRDHQTIGHEQTKTGDFPRWNE
->ERR1719159_229085
-PMQASMETLPCLISVCRRLAKSSALPSAVKPRGSQKPTGGCTPSSFSKALSGDASYNAQSPYAEPVSPSWKNIPMIAIIASLPFAISAASFFSFSAGSLDVSTLNPKSPFAAGVPGDWSCESSQKAPYAKICPQPATGTLEIAPKPFGMSANFKVPVAGWGQILAYGAFCELSQDQSPGTPAAKGDFGFKVLTSSDPAEKEKKLAAEIANGRLAMMAIIGMFFQDGLTGSAWGDWALYEASPLRAFEDELGVQAPVGFWDPLGYTAEGNAEDFARRRQTEIKHGRVSMLACMGYITPELTGKLPVYLSPSMGLKFADIPNGLGAISKVPLAGWGQILAYGAFCELSQDQSPGTPGAKGDFGFKVLTSSDPEEKTKKLAAEIANGRLAMMAIIGMFFQDGLTGSAWGDWSLYTASPLRAFENEL
->ERR1700751_3884456
-LASSIYGGEQGLGDPSTVLVASQWAKWTKDYLPTDFGLLSGFPYPFPINGGLNSRTVLPPPAVQRLVEKKVYVRGYMIPLEMDAKGVSQFILVGDLNTCCYGLTGDPNTWVVVYMKKTTAFTRYDPLTVFGTLHATEIAHGNGYETIE
->SRR3569833_572735
-LPIIPRRDAPAQIGRDTQSPALSVRLRHMGLDRVARGEIPKFDQGVLAGGEQESLGRNVKDHRLSRLFVFQALRPRLDEMEPGNLVFVSAKFELASLRHQVPYDDIRVLGTAREPHARAVKSQDGHGRAVAIEVDYSGCDLAIPEPDAAIFVSNSKHILVRLALRDSRNLGLALIVSTSTQYKTSSLAATSACPTPVPERSLDVHTMVEVLEVTRPNDLVYSYFLYD
->ERR1719329_115142
-SGIPKGTEADTFERTVESIHTALNHGDTIHHTFSVDAVGNQHDLQTSSPGGQGGCCKLHLINSNGISKPGGGSRPGGTSNPGGKRNNASASTSESLSARVELSSCRDLLAEGQSSSSSSLSSAKYTAVSTACEQTX
->SRR5690606_4275788
-YIGVIFNKEVAFELVEPAKPSSIHGRVLVLNQSYEPLTVCSVQRAFVLVYLQKAEIVSSLNGKRLHSVNASYAFPSIVRLSKYRRVPFKEIILSRKNIIRRDGNRCQYCGTTRPPITVDHIIPKSR
->SRR3990172_6323865
-VVDMVDGAGVAEPCREGKETGVERPAACRDATMLPAMYFLATLFNGEIPPRAVPNRFQIFCAPAQDLSQKDGWQHDTHSVAKALGRGVWVREVPVASDEDVYIARQQGQGNGHVLLAAHQVALLANEVGGRHRELFVVRAGQEGIEHVRLSGRLEMPPRLYDDLFRQDQVEIVRQRRPHDLVRPARQPDTGDEHVGVQSDTEPTLRHS
->ERR1719186_79813
-LILLDSLLQEIFAKSLNRKLNVKRMGDDMEYLTLKVVGTDSNEFHFKLKWVTQLGKLKQSYSERMGVPVSSVRFLFDGQRIGDDDTPKSLKMENNDEIEVFYGKGGPIDRAKTALQDAVQKDNTNVIKFLLKFGANVNAKFDGETPLDLALAAGKIANCKILIEHGAEFGLGCWFGEDYEYLLRYQQSYKKAVKQVTNNEELISENRYTELTCEEIQWLKELKAKKVKEVDSQMISMDHKLDEVTTVNKNKIKVIQNQVDEVKENCDEKITALENEITIARKKLNDLEFEKNAETLNMKTRIKTLEQQEKEIRDSTDKIEFERLVTVATKSKLNKEFKMIDFELKRKGFSESTKRTVTGKTPSKTDGLEFVEHLKQQISSMEQELECPVCLEVSEVPIYTCPSQHHICAKCWSDVKSQDYESGRYPCRRPCPVCREYIQDPPSKHRSLEKMAQQLKQARAKLDKIL
->ERR1719186_361628
-TEETLLARRHQSRGKMSKLTDPAALKSSPQVWTLYLVPQDLLTRSLACQVLGRSLPHKTAPAHCPLTLHLVTVQSSPSTSGGGEGDPRGREGRHAGGQTRTGTAGRTRTTTRPTTLPRSWRWTEPASSPRTVWQLX
->SRR5215208_4256899
-LCHTVSLHPKTKSLLWQICVRCAIWFCVLSRSDMLVCRRQVSPSTAVSCNRSHELVTDASGLTFGTDVVKRHGSLAHDASCSPMIHRANSGHTASSLDLKAHRGCFAINNRLDPCLLALLLGEPKGADERHRRTAGGVGAADSTCPDPGDHGLPVGSLRVEMADPLLGLVAHPVTVVTHVFGQSPCPAPALGVAYALARLRVYRRLSGELRWDLDQGLGDEDGDGVEVGAVGFEAKALGFEGDRTSPAEGVX
->UPI0003AA342E
-MFNSGAETVSGAYIELRVDGELVNSWNVTLAEGGLRELEYDYIWAEHNPTVMGYADPGKVIDELDESNNYKSIWVAIAAPRHDVQLGAISHSGGQWVELTVELQNLLGEVPHYRLSLFVDNATAPEYQDPNQVQELYYVEGFNLAYNESRVVSIWWYNTVGFGWHNLSVEVEVVDHSYPDLNLSDNRNSTSFYLKQIFYQLSLEIEPLPEKIRLNETVRVIVHAFNFGPEILSEGAEVVITGNGTQCEPGLQRTRELDRATGEDTLEFFCTPNSTGPYVIEARIDPDNIHDEPNEDDNFATGVVNVTNEEFTPVTPPVISDDSFITQPIVWVPLATLAIIGAGMFAYYRLRGDDDFLPGTRGRQSGGSAPEQASGSATFRYDAESGITYDANTGEVIGEKKKDX
->ERR1712099_209071
-ILLCAGEEHISSGNRSISMERKRKGGSGEHTHTTEEGNYYANTSAVFNFFLFLSFFTVGARKERESISLHYHVSFRLSLNLYLLRSSEIRYGHLLIFIYTYPPGQPEFERHSIKYHQKYKKNKKKKKKKKKKKKKKKKKKKSKTKKKKKKKKKKKKKKKKETH
->SRR5437762_3435613
-GQRTGVRDVDEPGRWRSGEVWELGQRAGRRVELVDQRVQAGQRRGQLSTQISALRKLIVDRLDREQKLGLLSEAEVLAREGEAVPVAVRDAGVGVGRAAARLRRGKAAADGEVAARVAKTSIQGRLGDRRGAHGERGVGEGLEVLR
->SRR5579883_1301911
-PDLPRYGEFHAAVGRAVMLAAAYAGGWIMSAAIAESYMEEGVVGLEPRIVRIESNVANLNEKVGRVETRVDTLDAKVDRLDESVRSIDRGVAVLEANTENIKENVATLQIDMREMDAKLDRRFDSIDRKFESLDRKFDSMDRKFDSIDGRFDSIHQELRGVTRTLMGIVITFFTTLIGFGAAILGVLAKG
->SRR5438034_829519
-RPDWQSGQPGRITNPSYTIGTSAPVLENTAVPKQGEIDYVSRLTPDELRFALDKPFSDAECGRYLMELGALMYLLPAPPARLLDLGCGTGWTSCFFARRGYDVVGQDIAPAMVSQAQLNKERYGVPNANFVDCDYEGLPFRDEFDCALFYDSLHHAVSEEQALRGVYRALKPGAVCVTSEPGVGHARRQSSLDAMRKFNVTERDMPPTRIIRVARRIGFRRFRLYPHMKPFGMLLYGKSESGILAKLRWLPYWVRSLALMFYASFYKRFNGLVVLEKX
->ERR1719411_249020
-KSTVYIKPTISNSFEHEPNHHPHSPSASYSFSETNNSSTNPDFPLIEPQYGHFAHLKQRHNRPQSTPQKLVQFKAFKFDENAYDVTANSQSIHSPQFIQANTPNTITPIQTPSNQQQQQQTQNERFQQLIPNDSTTVMTPTPSPAPSINIPPVINLDLIDLGSVNKSTARDNGGHKF
->SRR5262245_60002328
-TRLFQGFLSTLLERSDGWQAHGSAWEEALLSFGNRSQPSGRRRCHWRKEPSRYRPARSTQRLVFEDKKSCWEKPICSIQPALRLPPRGRLPRITSEPACIAQSPAAFAQRKPNCKRPASTQSPAPKPNVSSSALRMPLRGLRRLRH
->SRR5438132_1115162
-SRNLYRAEASRGTGFPPYASDFAEAPSLARVYAQERGRVMGGELAELAARVRVGDRHGAVFRHRVEATAIRAARNAGDGPAGGDDRQIEDAERAPRVEVKHVDEGPAVGVVVEAEVPLPIAARDRRLVDAVHDAVDARLGVVAICLRGELHVDDQRLRELRGWDVVDPDAIGVGGVHADQRLRGLRSDPLDQIQGGSVVADRVIGEGTRDVDVGGDLEETRVHDGESASLAGRSDEHKPPAVRRESGGSRTVLVGERESAWKLNARDRPPGLRLDQLQCGRGCAVERVVPGSVWSRDGAAKGAQEITLRVADLDVTGGSDDELVAGRRRGRGLARPSARGEEQAGRGX
->SRR3990172_10122028
-APRPSRARGDPRSLAPGPRGGVARAGGCAPRAGDRGGARAGHPARPPDALGECHPPADAVVLLAADPRSAGGARDRRHPRAGAPAGLRPRAALLGPRRRPSPRPRRLAALAANPLARAPRRDGRGGCRDGADVADGRGLTPAPVTGCWWGVAE
->SRR5262245_24698148
-ADLVVPLLQPGIEHVARQPGHIRGLEHLDGHLDAAARSEEQQTQEELEESPEDYTAKPRGRVGLSVSERAAPQTAGSHQDDTGFGDSLEDVGSSAGWSESLDAVALDVPRRPQNECASLLEAILDRVNRCLDLRA
->SRR5579863_8325721
-ALPADSPRIARQRLEQLVHRGKPLFRTRAETAEQDLAQPPRYLRVLRHRLDPSADHGVADLEKAIALEGTFPVERLVQRHAKTELIRALVGLKTAVLLGRHVVRGAEDGASL
->SRR5216684_4526886
-LSRGDIGDATGAAAAALRAAIGGARLRERRPEILGRRDGLIDVFLLRGVEAHQSFDRLDQSLGIANEIAIDLLRRHVLGNAGEEASEMQDLAVRPAHGGEAVALSQDFGELWIDIALVVALVRNYLLLNHPVCLGDQRGRALGGGVVERIDERSPPGPAAASRRSPPTWPGSKAPCRRRCFRSRSAVPVARSX
->SRR5262245_20684417
-IALPEPLPGLIRRVRAPAPVLGALGLDEEGDDLGVTGLDSPLEPRGDLLDVARGQLVGKIHVEGGDDLTRPQVHAEHRGRGLDAGLLARDAGHGRHGLRRRALADEEGLALAGEEQRHPTQQEADRDGGEAVQNRQVQPGGGDGAGERDEQTEHRRGVLEEHDESRRILALSNGLVVPLCALGRAELSKGDPPGAALEEHRETDHRVVHHGTGHRARAEHVHEALVERDAGSQGEDQQRDDEAREIELTAVAEWVSRIRRPGGAAKTVEEQRLVGRVDERVHPFADHDRAAREAARGELRGGHEQIAEQGRVDHLPRCAARHGARPARHRPRAYQRGASDRAAFRYTAGVTKLGVLALLALLAVSPLVALLPYDTGSIRLLGVSLGWWYAVAVAPVVAVLVAALSAPRRSPSPPAX
->SRR6218665_887351
-RHNRHNRHNRHNRHNRHNRHNRHNRHNRHNRHNRHNRHNRHNRHNTNSSYRQNAHDPETSAWISRCNSVGPHIRLLDGSALNPDRTTWGPSLGGGPQSGLVNLHRCSAPASPGQSSTLAGQPTPIQDKVRNTYPAGRGCRWISGCQRHGQQHLPRRTIYPNTTHNPPSTPPLTPPNNLRRHETESTLQRAEDPRPLGVLGQSVGERGVGRRLSFWVVSHVIYREAFFWSTVTX
->SRR6266516_6846987
-LAGWPPGRPGLAATATWASAAFEFGGQSRNSAGVAAAEQPGSWRDWLVVRPFQVDVRLSEPLGDLDGMRSLPVRRDQVQAWHQSLARVVHFEQRDSPALAGLDAVQTMSEQALTDAARVYAEASRQLGDGDARGKDGRVLGGGSRQRVVGSQIACGKVGEVHASLFEECDLGLRQLRSRVGGGALRQDVLNGLHDQLLKVGQGQVETRTPK
->SRR5450432_930278
-VVRKSLVACLGALLVLQACGSSSNSGSAGSMAGSPATGGASGAAGASAAAAGGSSGSPAASGSGGLAASGSGGLAASGSGGSAGSGGSAGSGGSEPAPPWDSSLRARATAGMVPLATWYSADTGLWNKTDWWTSANQLETVIDYTREVGDPKYNDEIDNTFVKNSGNDFDQFGFYDDDGWWALAWIKAYDLSHQQKYLDMAKVIFQRMTGGWDDKCGGGIYWASAKAGSNGLMNKNAIPNSLFMQVAAKLHQRTPGDTGPGSFLDWAQREWTWFKGTGMLTAKHQVVDGLDGLTTCKAGGPIFTYNNGVLVGALVDLGVGTGDATLIDEASAIASATMTLMNDGKGTLKEAPCGGDICTQFKGVFMRNLAALYRARPAADLQAYAGHQSDQLWTANRNAQDQFGYEWYVPFDKADASRQSSALDALVAAVMTANLNLALVGSTATGSAPCSAAGAASNAIDGSSRWDSKWCAGGMGGQTLVVDLGATRKIVGFRVRHAGAGGESSGWNTRDFELETSADGQTWTRVVSVTGNTADVTTHGIPPVMARDVRFHVTAAQTATDNLAARIYELEIFGTGLX
->SRR5512147_282644
-GGEISHMLRETVVSAVVSSGLRQATFAFCPYLLPDCGAVIVFGRHLRQQAIAKPKRRVGEAAQSESIDQFLIDRRPCDNNLRTARSQTFHQTTLSKVAFREFCIHLGQGLSRDKALASGAIHIFRKRRQRCRCSRCRDHPLRSALSHALFKLAYLFPDELPHPLEFLRFGRIALDEVLGETNRSKGK
->SRR3972149_3229708
-PQNLDALYPPRRFAEPFTGTPCTPLKHGDGARRRMDRRGTNAAGDGNRRVHTPSVQIRVYGVGHVARRRKEASNVVAYTARSYYGHAPSHIDAPRQHVEIGDGGRMIDAGDVRGSREGPGGYHYGIVPVTQHLLGTHSRVETDIDTMQFELCSVITQHFAKLRLSRDAQRKIDLSADLAACFVKRDAMPPQSGIDCHRQSGRSRAHDSNATRDPPRSKRKSRFPAGAGIHEATGRFISENVVETGLIAGNAGIDLRCATRRAF
->SRR3954451_16501819
-WCGAGRSADRRSPPATNPPGPGRRGTPVRRPRALARLESAGRSARLRRVGGVAVGGRVDRGCVGRLVRLSWRRRPGATFRREAGGRAPGRLGPAGQLGQPGLQHLGHGQPVAVRGLVVQQGLDAARVQGPYPLAQRGDRKVVVVRQGELVVAGHAGSLPRPATAEPFPRDSSGRCRGVTDRNRLVLAATASEAPRRCRMTSPTGSPRWYWVTPSTAWSSSTASSSTAARLRSSPTATRVAPTVPX
->SRR3989442_4700027
-SVCRRQGRGLTSHASKDTAANENPLVVEYCHLGGALDAGLVRGTPLLNLRNEKAAPDGQVQRRSQIFCNRISGNAEPGAQYPAVADKVIHNAPDRARGNGETYADVSPADGEYRSVDPDHFTGAVEQRSPRISGIDGRVRLNDVIDQFPALSLNRSPX
->SRR5215472_13468930
-CEKGMQWTFFGQEKTLSLSGLFRNLIPENECRFLSDKRPAHAFYEFKTPATIAAVEESMNKLRRLPFLILLAPVRSSICLGAKALCRNELQNKRSLRPALIHGHNTTKNCVNPRSMVKARSDCAPVAAARSFDSEKNRGSK
->ERR1719158_407498
-DDLSNHPLSSSRVSKYFIKFFSIKYKFYTSVCVCANYSTIRSNAPAVTCPNKTLNARTIATTSGDAVFIWIRTADIRTAEIRTSDIRTLEIRTAEITTAEIRTAEIRTAITPVSSEEYRPAVTRRGWIYGSTVATMPGRFTVX
->SRR5262245_10967354
-DATTSSIGSLAGSNGAATVSGTGSKWTVAGGFTAGDSGNASLTIQNGGLLTATSSIVGNLLGSSGTATVSGTGALWSTSGALTVGNLGTGSLSIQNGGIVSAVSSTIGNAAVSNSTATVTGAGSQWSITGALVAGNQGVANLTIQNGGLVSTASSTMGSVAGSSGTATVTGVGSKWSTTGDFTVGDSGSATLSILNQWTFSVGNTLLIGNQGTVNLDGGTLRLGFAFGLIHLNYTSGTIQLAGNSTTGNTDVVGQIFGLSPVIPANKTLAVEGNLTVQNFSPLTIMNQGSVNVGGSLTLLGNSTVNLYGGTLRFSSYAKDPTATFNYLAGTIQLASDRSIGTDAAIQSLFGSSPTIPAGKGLTVEGTATLLTPVALNGGTLTVGDIINPGLLNFQSGMFRLTTANLQVSGGQFGSTLNVASGQNYLIDHTTNLSIDALLSISSGASFASAQTNNSGEIA
->SRR6266481_4594428
-DFQHALGTAAIGGTVSRAAVDPARLRLWSVGAASRPAGSADDFQHALGTAAIGGTVSRAAVDPARLRLWSVGAASRPAGSADDFQHALGTAAIGGTVSRAAVDPARLRLWSVGAASRPAGSADDFQHALGTAAIGGTVSRAAVDPARLRLWSVGAASRTAGSADDFQHALGTASRAAAGTTGAVWQHSWRHRSAARRRHWWCLGAASAGATAGRPRRAVQPPAAVCSRATVDPARLRLRSVGAA
->SRR6185312_13763440
-HFYEKKGLITSRRTSGNQRRYRRDTLRRVALVRIGQRVGIPLAEIAEVLATLPEGRTPNRRDWQELSARWQERLDDRIRDLQHLRDDFDDCIGAGCSPRPADRHPTARRSAQSAPVTAPPSGSADSARRTTPVTAGSVGSAEWVTRAPGHSACSWTWTVPANRAATSGGVTVSSSAVHTANQGSASPTRSRASSVISALPGASCRQAAGQASGATTDAVAARDVPARGAPRVTTRRALAAPSSRATH
->SRR4029453_7084716
-XRESAPCPTGSRPRTTLEMLAPLVGVLEQRRVDRHGKWPCAHPSSFSLSLLASRSWGVVGAMAERRPASPAREPGRVAARPGTTATRTPADGGQPVSKATAARVRHPSWRDGRDQPPHPATSVQPPVSVPPASAGGTFLRVLNGWPRVDGVQGRGPAIAGTAGP
->SRR6266850_5569252
-RRGQAAEKSGALQYCLCGQSHDGIPPAKHCEQCTSCVVLLTEPHSECAHDALDGEVAVNTQSVKESIMSITKVFRTNAIGVAWVILASGPMTWLANAAQAGESLPHKVVSFKDLNLSSTEGAGVAYRRIKSAADEVCGKRDRFELSQSHAIQTCINQAVSRAVAQVNSPMLTSLYNAKTGKADKQTTTLAQTHX
->ERR1700690_1151612
-HHLVIHKTEGELPAFLKDLVQKLIALLDGPLHALMLDREHDRGLDGHVQGASEPQPLRLELFAIQHGKNALSARGNGALDKYGSACALRQRDHSYPASGSNLGNSAVRAKNSGSPGNPAEWNGGRRSATAWPSPTAFPQASFAAKAPASRPKYGSSAGPHAGRGRTSGMPWAGPSPRSVRLRTWFPELFPPWSCPSSPPCASX
->SRR2546430_15524557
-IYTLSPHDALPISVERLHGARHAVTVWKIEPPASKLPNRSGVPAEATGGSSIAPPAERSPGRYVKSPIPTPLATVEPFASFRGSARPVGRPPWLFAAARCPWVTFPVVFTRCLNGSGPDRSSAMX
->SRR5687767_7487181
-EPGPDLALEQRLRTASPYIEWSLEQTWDYWQLDIQSSRPGSDPAQRTNYIAQLNTQLRSAQVIRAVHAQNQLQEVMTWFWMNHFNVNLPDDIVRFTIHDYERQLRRHALGKFKDLLSASAHHPAMMVYLDNNLSTVSRYDNRGRLLSGLNENYGRELMELHTL
->SRR3546814_18830037
-FLFVYIMVLHYLCFFFLVVGRIPGSPRTDTLFPDTTLFRSWGLRRGYPRRPFQRLGRRSAPVRRRRANGDGSAVPTAMRPPDRNCLRCLAGGSGRSSHRASGRIAGLATPDRSRRRPEPSQATPKAAPRRTPPPCGGYRHRTRRDRKSTRLNSSHX
->SRR6185312_7772205
-RRTSMPLSLPDYDTLWQQIVAFFRNRFTGKDDHAESFIGKLARSVGMAIYGLLQAVAAVDADSPPSESTSSQGLRDWAFVFGVPADTDGDYGPKGPSLATGGQGDCTGTLGTVFADGLLLTAPDGQTSIKLSGAVSIPGTPPGAGSVLGSFVAVTPGSSGNLAAGTVLAWESPPSGADSTVTLKAPLRGALDAESDPSLLGRTRQRMQTPPKGGTAADFRFWAESVPGVFRAYVYPLRGGMDSVHTVVTTAGSGLARVPSDAVRSAVDVEVAADRSVTVEGYKTLVPRMVAPGMALRLRVAPYPKFGFHWSSAGASYTVTAYAPPGSAVATLX
->ERR550525_1171417
-EKSSLFVHQCSQCSQNGFCRKCWIQFVRLQKDDDDEKSHPVSQQKTGNSKQNAVDLTSVSDEEIDDGNDESSPTFPRRKRKRPMNGQDTQERNAKKAKRTVNVDCNTQSNGDGNNSGATPIMPLVHTERGIDKSNGLNETEHSNDRK
->SRR5690242_17665658
-RLLRHARGNLAAGSPGAQARRPRPVALSGAMARMSFANVVVWIGALAACGDNLGPVEETVDAGVTLERAFRGEDLPGCTLASPVLVDVAGDLRIVAATSEGRIAAYGRDGSARWSFDLPRAEGERAEVASTPVVVGTRVVVVWQAFAADGARIS
->ERR1700687_127959
-RIAPPDEEQAFRLQPCGAMQQRGFERLAGHFAAGDYVLGGFAHGGIGALDGRCRLIFFASVFFATVEHHYDEAIGFQLRRDGGREVCIHDGVSSVSTVEGGTRNSAADVCRAKSLSPGRRLDAGTTGSCRAALGLGGEGARPHTSRVQQRWIHSTLVFFPGRWPPALPCRRCDGARSRACPIAVCPSPARVRLX
->SRR5256885_2151122
-NSILKKEQIGIHICDRTPMDPIAFNEDSEVSAKAKFITERLSPGKSRRKAQQGQVILLTGAPEELETRVVGRHKQSPAALIGDLQKRLQRIFAGAIRPSVVDTFGLSIPQVIKRVARIVLLEEYCPSDLATRLKELEKVGFFPPETPTX
->SRR5205085_4486535
-CRTRTRSLAEGGRGWRCGYAVGLYLDRSCGRRSCRDVRCILASAEPGQAKTPSWTKRAASHAGKRHRGARSWLSLKNVGMCLTCPRVPVASGAVRSRSYDPANPRAGEEAPNRDGEARGRGAIADRRGRRVVRVPRGDPRAARRSVSGGRALGVGPPPAAHARDQGATREASPGGRLVAAWRADGLEPANGSFAERTRSRIRNSPFHRPPRYWNEIEQLARERPHAEAGAEGGRDLRQPLARVDLEAVRLLEPQDEPKLVQREHRQVDARQEHRGTDDPVLARERRDEPLADRAA
->SRR6266545_2846328
-WRSRARAPACAGRRARRTRAAGRQRGAEADRKGGPGDSIDRPGSRAAHRRRSVLAARRRPPAPGRTDRRAPRPAGTGGRSRGHDPSRGPGPPHGWQGAGDRASRHRVARRGEGSPGRLRGGLRPAQRDPGAQVLVARRPDRARPRAPGPGRRRRQRRVRFDRPDRHAGGEPRRSPRGSARLRRAAGSRHRRAPPEEDPRPMRPWRRAGPVLALAAALLALARAAGWAGPPPGAAAADLLVEAGAALGAGEHERAAALAGRVAHDPRPIARQDRAEAWRILGLAEYALGRRDRAESSFYAYLKLDPDAHLDPALVAPEVLSVFEDVRARHAAELAALRPRPQRRRSFWLNFVPLAGQWQNGEHRKMWVMGSAGALLLGANITSYALLRSWCGNSGASATCDDPDGTNSRAESARTMQVVNIASGVGFIAL
->SRR3990172_1023493
-DLDDLGRTSGRCEMSARGAAACAFLLASTVALAQSPRVLRLEGGAAQIRQKERTARAAGVFGGLWRVEGPRLASLASAAFTWAGDSATAAQGIVAAAWRPTVESAWHTEGGVTASAFGVYALGRGGNRSAYARERVVLDDGGFWAGGAAGHTTRDGRSWHSTVVDVGAFLRSGGLETSVAFARLRTNDWPLMQASGIFLETDAAAHDLDDVTLAMRYARGALALDASHTWRGGARKTLARQTAFLWSAAYELSPRYAVIVGGGRQLADAVRGVPDAMVASAVLRVVLFPWRADAAERATARSSARVEQTAEGAVLVVRVAVNDSARVEVAGSFSGWEPVPLQRTSEGWEARVPLGPGTHRVAVRLGGGPWRAPRNLGKVRDEYGGEAGIVVVPX
->SRR5438132_1110025
-VRGHDVTRVSAGAVLGANIRALRAQQGLSLSELARQSGIAKGTLSQLENGQGNPTIETVFSLSNALNVPVSSLLAEVPEPSVMVVRSAGLDVLSGTAVDLRLLRRMDVTDTVLELYDQRVRPGQVQQSAGQPGVERGRAAGHRAGPRRARLRHHRGRRGQCAALGQGARAGARPGHGVAAALAGADRRARAGSGVGAQGRAGRVHCGPRAAARVRR
->SRR5581483_1731585
-VRAPADGTVAVAIDHLDDNAVGESDFYNLAGNQVVIDTGSNRFVLLAHLQKGSVLVTTGEVVHAGQPVARCGNSGKTTGPHLFLQVQDQPRFGASGVKTFPIRFRDVTCLRSGHPRTDAPFFVRRNDRIVMDPPAPVKSDTIGQTWFPNGDTIELLSVERNDDQIVARGRYHLASHDHATLGLYITSTNISRVHEGREQTMVIGRGDGSFQLIHPHPVPGMPHVTMYADGKGIATVYFGTEDEAARSKKMHLQPLASTETWTPAFATGETPDMSKILEQAQKL
->SRR6266496_2749558
-ELGGLLGLRPSCPPPYRRGTDASPHRSRWRCPEAVDLWQVSGLPMPGPDGCPTDRERSGIGVANAGPLVDAKRDALDQAHRAPRPPGHPPLVVVSERLRMLLHSDEIPVIAQPLDDLPGGRDVAAVRRYVASQAERRDESMSASVGRVLTDLLAKDEARDLNVKVX
->ERR1017187_5553991
-RRRNSGPARACPAMCCGARLGTGWRSVGRVEAVDVIQVLDALDEAGVRHWAGGGWGVAALAGRQTRPHRDLDLAVDARDLGSCLTALGRLGYAAETDWLPARIELRSPGDRWVDVHPVAFGEGGHGRQADLDGGSFDYPPDAFSHGLIAGRSVPCLSAGQQRRFRAGYEHRPQDVHDLAQLDALRESATHGPDSWPLTNLRSYPLRISECPVCTGSSGSGPGPATVQFVPARVPAAGVTRRRWSIKGLRCGSRSEEHTS
->A0A2G9SB67_LITCT
-SNKVPVVQPSHAVHPLTPLITYSDEHFAPGAHPSHIPSDVCSKQGMNCNSKYEKTLSCILLGEDALHYVDALQNTKHSVTKQEERKSEQKTRSALTDLLYFFILLRYSHHMVPGPPGPHTTGIPHPAIVNPQVKQEHHHNDNDLMHVKPHHEQRKEQEPKRPHIKKPLNAFMLYMKEMRANVVAECTLKESAAINQILGRRIFASQSGTIILHRNLAFYIAGSAPVHCDARREQSLAQRGFGQRTEPSDRGTLQDPGDKWHALSREEQAKYYELARKERQLHMQLYPGWSARDNYRHAASIPGKFEAHVDVESLFSQGKKKKRKREKLQESTSVASRSVQWNRSNRSDASRSDLEERFLYYFGGDLHRLLYRSRLASRHGSRVQVTSVRRPASRAASNVNRR
->ERR1739844_819532
-MGEEYMEDHRGNIDLELLQEEITAQICLRILERSCNTNEAIDRMCLEDEDGDGELLPESGGKMMTKRRRKQRNAERDLTRIKVKLDRDIEELLGTNKHLINNVGLGVWDILSQMTIPTLSSQANVRALDLRGGAYDSS
->SRR4029434_248713
-SRSCEERMMGWEGREEKVRGGEVWGGQGERGGERRRGVGVCSEGNLSGQRRCEKTGSQWCSVMFTPHIHTHTRTHAHRHTCTRTRIRNTHTHTCTLRSPLQSRQTVTRATNKSAANTEVELSVTYQHTPTHSTGQTICCHT
->SRR5207248_268926
-ISLDAGAHVEVAIVKQRPAAVRALQAAKINADLALKLGIDGLGEIVPHQHIFTRYRGIGFQLEYPMAVGLLPLEKGTGGALNVLFEGGNAAIVHRSRDHFVYEGRLSPRAVVPAERRSLRKQAWAREPGPIP
->SRR2546428_1292487
-GRVHAGRFQLAANSLDSQRMTPKPRAFPLLLSLVLAMFAPQQTRAGEPHRLQVKPEQQILTAQEYFAAVLKLPDSHGTPLRNRVKPAGARDEFGELSDYEEVIVFKQLAAGYRAGIPVERVQRWISAYDAGRSHDNIFRRLASLATRPGLIDCLHNIEGRKDSLGRNVSPHMAFRYCAAGAQPDEITAQSLEGRALVILSYSDFNGALEVQQFARLLDNVRLSYRLSFALARTPADVHAAVAKHRNGPRIIAGHPVRGGIELMRESPDGILSSVAAQTLVEHLGGEALVVYSCRGGERFAPALAAGGARGRGRPRGRSAPHAGGHAERAPYTERRTPLPRRKG
->SRR3954454_11295577
-LAMLTPVVFGFLSKQQESMDLNADGLANLLVGQKDNIKAAMPAGLEAALSSALPGGGQVLGGNGPTEPELAQVEGKSAASANRTADWHSRAVYSKPHRDAGKRLSVPVLLVLGALAVGILWARHQHNRQNDPPSVGAPAASPSETVTGSSSSVVPNMTRLINQASGTLAGIKDPASAEAATLRLRQINQQISGLRSSWSRLPESARSAASTALEPQIVKLKE
->SRR5207245_10474605
-FFPAGCGPAPYADERMPGDSLHNAEQGRWAVYAAVLLEPRAKVRDPERVAVGQRDDRHENVGVWQVLLGRREMFRSRGSGNREAPAVGVQDAAEHRRAIGPWQTHPVNGPRVADQR
->SRR6266480_972767
-DVVARQDHEELRPGGAQDVEILVNRIGRAAVPGRLVEPLLRRQQIEKFVHLGAQKRPAHLQMPQQAVRFVLGEDSDATDVRIEAIRQRKIYDAELAAEKHGGLGAAVRQLFEPTAAAARQHQRERTPRQPFLDPRRGQHGGVPPTTRLTQSGPRGEPIRKGKANEAKNWAYKMNRDRSAFLASSPTRSRTX
->SRR4051812_21032643
-XMKKVMVTSCSHSHGWRSVRVTTSQMTVTVNPEMAMPHSTISASSSGSSARHFRWRWVCWTSEGMAPALLDVAHHVQDLDGVGTEVLGELVLDGFAHGLEAGLVDRGDDLDADLLQARARVTLHLEGLGRLHLVHVVGGL
->SRR5579875_2506212
-PNPLVPRGSRVSEPASTPVVVHSRRPSPLFPGRTRAATQTNWAPRAATSASWPSTKSRLAWSSPCLPDQRAENTPGMPCSASTHRPESSATAGSPVYDAIARALSSALSANVRPVSGTSGAPGNESRPATPSANPAADRIRESSAILLRFRVASTRRGPAGSAIEGFGLPPGQLRTPGCRQVEQRRQHRPAERLAFGRALDLHKVPGPGADHVHVGLRHRVLLIAQVAPGLAVHDPDAHRRHRSDQRGPLAPPAGLQPCDGIRQRHIPAGHRGGAGAAVGLQHVAVDDDRILAERLVVHAGTQRAADEAGYLLSPPAEPPLDRLPLAPRVRRAGQHRVLGGHPAEPAPPPPPRHLLGDTRRAQHPRGAELDEHRSLGVVKPPPGKAHRTQRVRRPSIWSCHIAFLIGLIGAGSFPRAGSVYPTGIAPGCGPGTGYGPGTGCGSGAQEPGREPGQAPGAETGARAPGAGPGPARRCCSFMPTAGGCLGCSRARFERIAX
->ERR1719468_912648
-AFDEFLIVSVNFIEKFTVKLFFNRENVTEFRSMAAHIFAIFVFFRSSFSIFSLPDFSQQGGFEGWNSRDRLFWVGNALETANLGNICNHWRAEVPPVCRLGTSFLQNLICRAGEDPLGSGSFESIALIRSFIANAGEIAVDLLTNLFNGIFRGSASDSSESFAKRTKTVFTRNRLFGRDRFASSWIFLQKQIGCFAVLDNRANGEFIRESVNWSFWPNX
->ERR1017187_631561
-LRPRPDRRQEAADQHGSGIEGASKPRRQHQTRRGQEVLPPRYALAWQKRLQGRSDELQLRALVRTQCGRDQPKARRGPGGAGQARWTGDKVAMTAASQGPDDVGPSVSSSSPGNGFTSTKIGARLGRYEIVGTLGHGAMATVFRARDTQLGRDVAIKVMSMVHAARGGAGERFRREAHAVAALKHPAIVEIYDFVSATENEPSYIVVELIPGPTLRTMLEERGGRFLPEIAALIALPLAEALAAAHDHGVIHRDVKTDNVMIQTSGQSSRVVLTDFGVAHITGMETMTATGALVGSPAYMSPEQSRGHEVTAAADLWTFGAMLYELVTGVVPFSGKDPFTMIAAIVRGTFRRPSQVVATVGPDFEAMIMRCLKASPAERYPSASALATDLREFTRTAGLVPEAKGLRGFLDEPDAMLADLRPRVADMAVERARQFARRGQLARALAEIGHATASVPSHTGADKLLRRLSASRIAIKIAVVAAGLLAALGIVLAAKPLLTPHVPAPVAPIASPVASPIASPAGTTPAPVRKVQAVAPPT
->SRR5699024_12213394
-XHYSAASALSPLSLHDALPILPHFAGAFVLRAPNVYGDSLRFGRGGERTADFELYTAAGDRRVRSDERKLVYIQHGIRRGGNGGEDRKSTRLNSSHVSISYAVFX
->SRR6266508_47967
-RGSDPGAFDIELGPVAEREVEHVPRTADVISAVEQRAQSVQGDPAADLQRRGTAGDPGTADEPASPFEARRPSYRTGLVAGHRRTPDDVLGTVAERLAQDVRARGVAAGQLGAEGAGVRRLGDRVLRTDVPAGDAQLGTLVGQVRPDRERQQVAAVGELDGTAVPVRPPRYVQRRTVQPHLTVVAAGQRTQEGQIALVQLGADPARGAIEVDRRGQPVLAGQLVGDIRGRRVVESTGTPGQPQVLQPVLGEDQHLRLLGGRVVGLDRADPSLEDPPAAVLRAERDGERGTEVEDVAAEVEIAGGVVAEPVVVQPRLAPAHPDRRLLHGQGKEVARRLGVGCAGDGEDGSGYERGHSHGVLNQRSGAVGVRRSRVAAGAVARGWVRYGRGPQEYRTPAVARAVPAPRSRX
->SRR5215831_1420303
-RMRVSVRRVKARPGIRCCAGEESVRIGGPVAHGGRTGARPRLEQSLANSGGPIEIHTFREVGQFQVVIAVFYGDGIGIRPIGVAAVSHSIKSVAPNVDGFGRLMRPDNFPRRAVHDIWPALARDQVSLTSPHLVDARIARGIRVTVPRGRGPAKRGTAIAPAVWGGRLRISDVVGSHRIFMNELHKSRNGVAPPQTCARFQLHNESEIIVAGPGAVRKRVVVNLHGSAAAMDVRSQPVGLQPGVSSDVIVAEHKARSGNAIERPAVSRKSVVFGKHEVVSPKIRAVCPRRIAVAIGVALAVPTRRGKLYKEQISSLVEKIVVNYAVEPALSLESVRTVSSD
->SRR5690606_9332282
-RQMADSSSSLVPATKQKSFNRWEERRVGKECKAMFTVYALYSEKYNKIYIVVTSNIQQRMLSHNHLGKKGWTVRFRPWVIVYTEEFQDKQLALKREKQLKTAKGREFIREIIAAGSYPPDGGQQFESGPRYX
->SRR5688572_13872492
-PAGGRANGQVRLRDGVPPMVAAVLRTATARRPADRYPDGAAFGAALDRAVGRRPVSPAGARRVARFRRVAALVAVPSAVVWASAASTSAGGRARGVPGSVTDRSGQFTVALPDGWQAWRARLTDTPRLAERSPAAMLITPSLGGWQSDPAVPGAFVLFTRG
->SRR5581483_4009571
-RVREEVARAYVRRELVVPELDGGDRRAPDRLASRELAASLREVDAEAGPLGDDHVDLAVAVHVAEELLPADLVVGGAPEERLAGYDLLRRDLEVGLAGRALGRVERVGPDAVVADEDDLLRLPGREDVAHVHDHGARVDLEAEVGLLPERARGALEEDPHLAAEEEDQVLQSVAVQVLEQDLX
->SRR4051794_2395804
-RHGSDRELQERECRRVVPCSPHRDRPYLRLCRSSGRASRRSPEAEALLHRPSDRRLEDGRHIQSTCRTWRFARSQSCHRICLCLNNQSRGISLSFSSLSRVWRDAQFFSGAGMKKISRTSMGKRHALTPLRAHAITSSTSAHSSIHKPPTCSLVSRYGPSVTSNSPLGCGRSVFVGPRPPANFLTPAAIISRLSAWISSIIASSWVDGSKLSGRX
->GraSoiStandDraft_16_1057320.scaffolds.fasta_scaffold8539811_1
-RQRHPRLRARQHLEPQRRGEVGLDGVQPEPIAQPHRRPVHKPLTGLRDLALERALGLAAGAQGQRRQEAAHLQAARAEHAQLGQAQVHRADVAQGDLHGERPLRHQPLAARRARQPPHELQVAPPQERRARRELQVAAKEQRRRAQARGGQRPAAAAHPDDQKDQAQREQVAAAHGQGRLFAAPGRQALASFIRLDRLARPRPLARADGDLGERLGDDAGGAHAFHLGLGDEQQAVGDDVRGERLDIVGQHEVAPLQQRPRPPRVQERQRGARRGPERDPPVPPGEVDELHHIVEDLLVDVHARRHAAQLEDRLRRQHRLQLRPRLRVGAQHLLLGPELGIRHVQLHEEAVKLRLGQRVGALVLDGVLGRQDHERLWQRPRLALERDLALLHRLEQRRLRLGRGAVDLVAEDDLGEDRPLAQDKVPRRLIEDVGAGDVRRQQVGRELDAAELAADHQRERLGQGGLGDPRHPFQEHVAAAEQADEQPLHQTRVTDKYLADLLDHRLAEVLGLHQALRVX
->A0A0C3LW61_9HOMO
-MKYSIAYFDGYKRHVLPKGKSETMWLGRPGIPKGLQAGLFHLKEGQSGTWTCNAEDGFERDIDLVDHGKQFKIPAKTQLDFEVDLESVIVGAASN
->A0A1I2KW36_9BACI
-MKRHLTGKRLKYKSMTFIDRFSAVQLDVLKEVGNIGAGHAATALSYLLERKIGMFVPSVQLADFDEVVELSGSAEEVVVSVFLKIEGDAPGGMFFILSPPQAESFVRIMTGDASFTIHNPKSMGIGVSALKELGNILAGSYLTALSDLTQLTLYPSVPSLNIDMAGAILSFGLLELSLVSDQGIVIETCLTDPSNETKESVEGHFFLFPDPDSYDTLFKALGVSAYD
->GraSoiStandDraft_57_1057295.scaffolds.fasta_scaffold1415339_1
-MKTYRRTELDRTGLTRIAGCGVGRAAAAMAVITACLAAVGCSTDVNARRTIGAERELPTLAGADATHGINAERATRLDRGDWEPVDFRLPVDGTVHNALLKSEPSFGDEQPRAHGLYPTAESALDLGSDRGAEAWRGVVEPVRSFVDLAIMPVRAFTDPAWGKRQSASNFKRWRSGAWYAGPVPEADSGADEDGG
->SRR5690625_3860754
-EVFSHARGNAAFEAASFDGQYKGSLDLFTGSDTERADDALRRIISKVRVGEVDVPEMRIGHSILFRPEMVLPACVIASILDTHSFGGLRNFAIAGSAGGAIRRVVRQVKLHHAAPDGLDPLAAGGNLQALCYGSGTGGWRPASPRDLHQAKPAGAECLHHVVCTKLGNFNSSQACRAHDRGAFRHADLFSIDRELDELVRFCSGGAVVGFFHERHLFSPAPGX
->SRR5689334_12383051
-ELQRERHPRHRDVCRRGSRFPASRRQRCHNCVLDRFRQSPEDLESRPVLRGLHIYQLPDGSGLCRYRDLHQRVRRRRIELCIVQRLDPPLHVPHPGSLGNPGIRKPQLLGHPDVHLDRPVEIHSKNESPMHTLDHVQRRRKLTFLGALLAALLAAGTASAQVGLGLIPMREELALGPGAAHSGVLTLNNDSPARVRVVAELLDFFIDSTGTPQFGRQWTQEADYSCRSWLSVNPMEMELEGNSQISVRYTVRTPPAAPARGYHCAVGFSTQPTAGQARGTGLRTAVQIVAAIYVVVGKPAAQGSLKDLTLEYVADARQPGWRAVVVLANPGVMHYRPSGDLDVFDQSGKVVESVKFVPMPVLPGRDQRFLFPLKLASGPGKYTLRARVDLGDSEIQEATALVVAAKDSRX
->ERR1719375_951704
-ENAPDGGAHATWSGFSYWWDLLRPDVELHAELRVRVGVRDLPLRTRREGGLPLRPCQLRQDPPRRPPDRLRRLLHRPSCLLLLQSLFFGVTLRVLRGLQLARLFGCGPQVPLEGRRVHLPKQRRVPLVRGRWGRHNPRPFFPLREGDVERPTGPGRGGRPPEAALWSRPGGQPKEGARGHQPASQRQGLVEGEERRAFPDGAPEFGGWRAGCPLGPKVPEEVRERQNGCDLLLIPLPLGIPAELEE
->SRR5690606_30224247
-KPLALQWCVDSWGALKERRDLITDAWHKCCVSLFNVMDPAKRIEAVAAVARQELEHTHVPAEIEEQHDSSESDSDDAGGTDGDTEDDDELDVSQPKEFGSRKSQRQRTQATAFGFQLDSSAIALTEDSEHXX
->SRR3954447_19024062
-LGAVARQQALEPPRGVEPAEAAAGDDDAPSHASASPIEGRSKLFRKPAPHAPGAAREGVIRNCGEADLVAAEREQQVGDAIGRRQLLVGGRDAEAVDTTLPVEEQDPAGFADQPGPEPAPFQDDAGLALELTRVMTEQVAEKALRDGLRVLAARPFSAQDAGAAECVQLRNDPGMRDARDRHRCGEWLD
->SRR5205085_4690665
-RRVGWRERHEEERGDCRPISQGHGHVHGRQGRADVRSERRRPEVQLQGSLTLRARRRSSRLPRASSMFLYGRFAWSSGDDVAADSTRWSAGAGWAALAVALCWCNCADAETEVYLVRGWFGVFSTGMDSIAQKLRAKGIRAEAIMHLSSKSTAAKIIGEREAGRTSRLVLVGHSQGX
->SRR5712692_4144902
-RNRKEETGGVQLMDPYRLRPHLDIQRGHKERRTRKVQAWLQSLPSLQKPTDTEHIIRLDPIALFLIFFAVTSFVLVIVLTNTPINIAGPATDLGGIAVNYLLITAPIAGFAPLLVGSYFYDPRQLGPILRPVTFGKKVRRESFPDVAILGIVAALAVVTVIDYAGTYGGFTPTLSFWNTTTNRIVYADGGIFEEF
->SRR5262249_38079830
-FADGMFEGVVRAFVPEAQTWADVRENRSYADALAAGVASDEGLMLCAGLFADELAELVGVEATPDQRESAIAVLKGTFQLPLRIYNALMYRILKDGVNVRRPEIANTIWDMQLALTIPISSQMVRTPLWLISGDSAFADAGRAAGVPHVVHRLDDYIALX
->SRR5581483_8213852
-ITITYTAMNGHQYSVRKSAPLLITYGFHQQRPWPIIVVLVTRRVLQGMPHHSRQRSVTAFKHQRVAVPPGHGRPRRHLRGSRAHRAGAAAVLLMAAGCALIGCAGSVQGLGSSSHRVDLTGGGNPPRAGNSLPLPEATARRLPAGVFYLLAGPNPLSCNVWEVSRSGKETELTHNRPNFGISSFGASRAGIVMADASTGADELVRLTAHGIVPLPGQHLGSPAINRRGEIAAVRPPGGTGTKAYFYLVVKKSFSAQPHRTYRQHPALGGLAWGPHSS
->SRR5579863_3949436
-SDLRDRRPGRGRLAGVDGIHCARADSRLDHLAFLLRRGAQSSTICVSGDAGGVLLLVALAAGRGPSRRGTCGRRRKRDDFHDAPAIGCAMSAHPFRLNSEKLSVALRVSLFVLIAWSGLILFPWLISGVTGDFTGSALSTFAAAAVANAILVRIYEHGQLSAVGLVWQETSTRELFTGMAAAAAGAVAIVAAALILQMAMFESAPRVENAWANLAFLGLVLLFGAAGEEMLFHGYAFQLLVRALGQFATILPVAVLFGLMHLNNRNVTALAVANTMAWGVLLGYAYVRTGALWLSIGLHFGWNAASPLLGVNLSGFTIGVAGYELHWRAGILWSGGGYGLEGSLFTTVIAIALFFVVYRVIPDRDRQVIPERGTX
->SRR5438876_2751381
-YRREHHVEDPRRRGGRHLPRAEQHGRRSRVRPAAGTGCAAVRRCGAEGGGGEEAQPSEGVTRMLDIKLIREDPEPFRTALARRGLAERVDELLAADERRRQLTGRVEELRAEQNRASKAIGRASGDEKRTLIGEVAKVSAELKEFEPELAEAETALTL
->SRR5215831_6834791
-RFQHGCLAVSIHLFASALNSSTFAGPSFHDGSNPPGCPTLGAAHDLARFGRKAQFPKSSNPTRRSPAVGAFQHPTLTGALLPRSGRPAMRLRALIGRQRRVKKLLLRLSNREIHGAITDLTIPQVLSHRLKKGTASIWLERRTTAHDGIELTVAQFDRRHVAEFRGGQRGYVVGRX
->SRR4051794_29872810
-EQVLLQLKLMMETELGITGGISEREVEVLELRRQGKGPAASGYQRTAVQLSPGAPVYLRHVDAAYLADLLNTPGNLPFVMDATGLLVSFDLELGKLPATLAEWNAALKGSGLCLVRGRRELPVFVLRENGGRQLTGSHQSPANS
->ERR1719217_1201603
-GRACRWRSWAAWRGVAWRGVAWPSLPLAFLGSVAYIGARVRSMTSSALWSAFTSSRWRSSIVMGESSPEALWLRNPFGSPDAHGTIRHEITLAIMKVVRLDEPVRAAQPMAIARGDVMQGLEQLAPGRTYLLREITLAKGR
->SRR5579884_3263431
-XMSKGLILGHTDGKASKLRSFKALFDRSLDDKVACQRFLQAFQRKSAKHLLRLTPAIHTAVFAPSGAGKNVSVVEPFLFTSEESAFVTDIKGENAELTGRFREEVFGHKIMRLDPWHLTTDKPARWNVLDLIKTDDPEALDKARALAEAIVEKNPNDQQPHWPKKAQDFIAGAIAAVTHFCPPELRSLQQVAEILADKTLLAQVIEKMKQSTAHGGLLARKGYEMSASADKELDGILSTANQSLAFLSTPAVMESTKCTSDFDLSALYEGKGATIYTIIPLQYLKSHAALMRLWVTAFTKYVVSRGIKNARPVHVILDECAAVMAGHGDTLDEMLTVGRGFNMKVTAIFQSMAQLKKLFPPGQEGVLLANASLLFFAVNEVEDAKYVASRLGEETIIVQDWGTSDSESEQPSGQGGRSKSYSRSRSLNFRQVGRQLLKPEEVIGLHPRVALTFTPGRPPIWTWLTRYYEKDFGAPTGLSPAKMIFDTACLFLSSAMLAALWTAGLFHHWFQX
->A0A1Q9BUH2_SYMMI
-MCAEWEPRWTAQLQAPGQAWQSVLQRAGVQPTPPGDFANVSVEEMRTAISEGAGGAGFDGWTAKELRGXCTSCAWLVDDLVSLFNETLQHQSPEVLQACRDSVFAWRVVGIPKRTEAATRPIAVASSLVRAFNRAILKRCPEPPEGQQCGVSGQSAVTATLQWLAVRAQRGAELDLRRAFDTIDHRLAGCAASTYGVHPVVIRYLQQLVWCAPRSCVVGGEPPPRSIQATCGLPQGDPVSPLFLSFVLGPWFKIVCALPAISAFLYMDDRSLLDSGDRNSLEPALRLTEWHDHTLGLQEHLGKRQQWAIDGSYAARAVEHLGLTATPGVDVLPSTRAGPDDLKALASQLQYLPGAMEMKERLLAAFILPKISWAAPLIPAVEFSIVRSCFRAIRGHVTWWCQGRVWADCINLHPLFAACGCKCGQGLKSPQGYHLQAYGRRXTPKESTTSTSKLKVQLALAPVVIFKDIAYSSAAIPDFDLALPVPLLGSVGSCPGCCPRGSIGER
->ERR1700730_765710
-HRLWCDSLHSAVAARGFNRDTTTPDKKTCSALSRSMSQRNGACGRAQLRRNCAYAGRLCRTRSGAWTDHGITDTGGPAIRAPSGMPGPVALSTQARARRSGSGCLEPGAGSALRERNLLFRHLLCNFPAQPARFRVPTQRRHVEPLVGRHEIDGNIASHRIHHAELIEGLGRRRRTPEGCAVDAVHLETSHVSVSQFPAARRCGLRGCTPSPPAETWRISGENLKGGLSKSMNRIX
->SRR6476620_3825097
-TERCRSGSARSRGARREHRRRRGGPGCGRHFRRTRRYRAGLHEVDARALPRARGRDAAAPSARRRLDSPFRRRGGGAVSAYPHLFSPLRIGNITVRNRIMQTAHVKLFAYNAVDSQRNVAYQAARAKGGAGLLITGNRVVHPTSTTGFPRVAWAYLSEALDADQKLTDAVHEHGAA
->SRR5438132_6851853
-APPSRFFSIRSTMRIWSLLRRGCLETLDDALQQLNLLLLDVQQLDPFLYPQVVDAAVQLFDQHLGLQVGVQVELGLQTVFGRLAILAHHDDGRGVRGLEAQGQVEQDERVWVPRASKNFVDVQHDPGCKQKRLDDDEPPAAHGGRDTV
->SRR4051794_37294934
-XMRSCRASSCCVIPRSSRNRRTSNASHSSSEALGSSSSARDIATPRGRVYPCLSDRGFASHGSDAGPCWVAIHPKKEDRRMDATRNVDYSVYLHAHHGATPCARDVLAGKLTEWHMPELIEDGSIIVAELVTNAARLGEVFRMTLRNPGDGMLRIEVEDRSRAIPVRKDPLADLGNDDYDANGGRGLVLVDALADDWGYELLPDGKVVWAVLSKX
->RhiMetStandDraft_4_1073278.scaffolds.fasta_scaffold432969_1
-MYRSRFEVFFEDEFEHPFMIMIIMIMIIMIIIIMIIIIIIYRYNNIIHTMWIEDELQKDQTGIQESIQRLTRDYQSQLSRNIRSHLSENREKTTDFLKHFYHKLRNAEYILYHQHAGTGTGTGTGADCENDAYCRLTFNITEIKNSAHDLPHPRILSELQRKYEHNRGIAQPNDNGDNGDTYIPYKVYTYIREKSEFCIQFQATIYGRVITLYFITFPESHISVCNRSSSGSGGSRCAAETAVYQTYAYKAFIWLSIVTSMADKECSEKSLNVYFYMTPFKKQRPKQSASGETDTVLSAIHVNTGLTRNCETHGEIVVYRTEEWFKVFIHESMHNFNMDFIDLDLRAANEQLRRTFCIPHDDILLFETYTEAWARIINTIFNVYFVSAATSATSATSQAHFIRNVREKLTTNALFYAHQAVKVLNIMGLTYGNITIQSPENTEVSRKRYAENTNVYAYYILGGILSVYSLPFISWCCENNRSRVSAIRFSQHPSNLTKFVDFISSAARDPVMLSMVAFIEKAATTTATAATAATAVVTKTMRMTMDX
->SRR5215217_9088951
-RRGSDRPVFPPPRRRRRNRRGRWRGCRAPCAAKGEGTRKPSTAPPEGWLKASGNHGRKERRSWAAGLFELGRREGPMGLHDVFRLGVQLLGKRDQQRLVGYDIVEDPGEETRGRGGRADGVGAQAGDRQEPTQALLVARKERKSAECDIFGLLAGNSFX
->SRR5260221_1043445
-LHDSTTNRATRLAQTPDDLRGLIKSRLDQWDTLTPGLRREFLDNERTLRYFTHVDATNNPAERHHGPSDDEQARWNSLSENERQKITAQFNQFFELTPDEKQKTLKTLSDAERAQMEKTLQSFDKLPLPQRRECIHAFAKFADMSTQDRAEFLKNAERWSQMLPAERKIWRDLVTNIPQWPPLPTSLIMPPMPPMPIIPNNIRPLVATN
->SRR5215204_1812972
-PFALRELVGDTVKSLALRAHAKGLELACRVAPDVPDWVVGDDDRLRQVLVNLLGNAIKFTDRGEVVLSVSRELGNSGDRELGNSGDRELGRSEDRARHQAAGKQPSSVCPEFPNSRT
->A0A0B2WMB5_9HYPO
-MDQQLDFSTLNKSLVIKAATLFLMIVGLLACITRISMKWFTVRSLGLDDQLAVGATCLAVAQSIVVVEATSNGLGKHVGGLQAGQIDHVLKSEYAAHVIFIASLTLAKLSAITTLWALAPLYHRRTVVITSSLVVAWTLSSILPALLQCQMPRPWDYISGQCFQRAAFWMYVSVGNIVTDVAIVVIMTTIFVNLQLPLSKKLLVGGIFGSRILVTPAIIGHISTWHEAITNPGDATFRMVMPTILAELVQCLSILTACLPYLKPFLDSFQSGAMVVVDATSQNARSKGSKAGTATSAAYGGNSKNDTSTSNNNNNHINHNNMNNMNNINQHHHSQSHSQSRSHGHSYSNSSGHGRAASGVTTPRGHPDEFELADMPSSKTATTVTANQGMMDAAMEAWDGQSHTSQTVLVQQSWQVDIEHNLPARGNGRRV
->SRR4029453_5233173
-DPRPSRTRDRSSLSRSSSHPTGLAGALRSDPWTGRPAMLAKLQLPVVAGRLPGRAGRAAIASTVSAMEPAAVVGQIGVTTIVATRDRTPPGGGSATGWPGPAARLERAAGDLAGGPRSVVAGDQAGLVPGSSVRTVLHGRATERSVIDRLLEGVRAGRGGALVIRGEVGIGKTTLLDYAAVAAGTAGTRNATVGGTAPPGRVAVRVLRGAGIQSEAEPPFAGLHP
->SRR5690606_9372909
-YLTKSSFTMPHVAEGCIIEFSYKIISPFFFSIDDFSFQSGIPIKKLEAKFEAPSYFQFKPTYKGYLPVNPKHETKNSPQLGDVIKRTSYSLIDVPALKSEVYVDNINNYRSGISYELSAIDIPGGMYKSYTQSWDDITKNIYAYSSFGAELEKTGYFEEDLDILIKGVTDPSEKINLIFNHVKSTMNWNKYMGYGCNEGVRKAYKEKTGN
->SRR6266436_1748777
-IEFLRRLTDVEVAAQHAQKLLDPKLLRRARTSENRALRTLVAMAKPIWQSLTGRKPSVNKVAGKRKSDFVTFVQELAKIAGGPEPTFKQVQNAFRARTLPILLTAKEVGARLKVSLSWLAKARMRSDGPPYIRIGRSIRYTEATTMTRPVAHRAAFEAQTPTEVRAKTRAGAPCIMRVVPGKRRCRFHGGLSTGPKTKAGRVVSPHAMLKLTSSPANTPHHCSPSFGKV
->ERR1700722_19782650
-XMAHCEASAIAERFVRLRGSVVGENENCGSIKAHDCAPPFDVMAGLLPALHAGALAVNFLIHGLPAGMAGPPPAMTREGWATGLTELDTPAPRSRGEPLAEHRQAADRLRRGRLVLKNVPMLGEPAVFEAHDVGGDPRRGTTVAGKTAVGDHIIPSGEDDVIFIAQRIRQGANEIEQAIAARRNMGAVLDVSVRPEALCGGVVAFVEQRVEGFENKRLVLRSE
->SRR6185295_4310521
-TAEEVREYVVRSSEVGKAVGARVVISSAAGMVAIKAAGRPLGARSIDLAAIEASALLGVTHQIVGRRHLLELLLGLLVAGVEVGVELLGQRAIGLLDVLLGGILGDTQNLIGIGAQGFLPSATRHLTTSAVAGHDGAWRRQRGRGAAADRGSCSRLPTPAGLCRTSPPDRRAPSPPRAAPGRKPHPRPRSFARRSARRRPPACARWLRPLRETPHHRFRARRRPRPSX
->SRR2546428_4765453
-FNCTPVTLPDAARVCPAGREKLVSVLAIVARFDIHDRGRRFGAATLTRQQQGECTMTPRNFVVRSLLMAGLFASALPGWADCQSNFVNRITQLRPIKLGTSGSNLRDRVIFRNLECCGGTLGALLTDTNGNYYVLGNNHAMGRLNKGKKGESITQPGLIDADC
->ERR1700722_5782801
-PTNFSCPQIEPDHDGTMLDFECEDTRYCRYREDCRRAELHDTVVTNYAHWVTMLRSPTGSRIGGFSTLILDEAHLVPDLVTDYLRVRLSRAYVQARLGLDMPEPDQSLRIWRSWATGARREAEQRAERAPERSKEGRRVSGLADTLARIADIQDGEEWLVDQTPRGAELTPVWCARYLERYLYAGIEQVVLSSATLLPAITRYMGVGAGQSVTHEIDSTFPIERRPFIYVWPQTRLQETRVQYNMSNTVRRAWAAKMDRFIGDRLDRKGLIHTRSYDRGGEIPGLSQWSSAMIVADRRNGRAATDLFKRAEAPSILLSPVVEEGVDFPDGAARWGFIAKLPSVDRRG
->SRR3712207_4962885
-IVLIIKHVVLFFFFFQAEDGIRDIGVTGVQTCALPILRVSFNSIGADYLRTAGLPLLRGRGFTTAEATQAGGPAVALIDDALAKKLWPNGDAIGQQLQLAGERITNTSGDVTPGEAIEVVGIVPVVRSSILEKAPAGAIYLPFARGFQNNAFFYVRFKAGAQANSAATGELLRSTVRSVDPALPVLSLKTAAQHLDD
->SRR3954447_3399888
-AQLTAWNLATVRRLNSWIIRATTSLPDPVGPRISTEISDFAAVRIHSKTISIFSSRPIISRNRCTDGDWSSVLTAARRSRNVSRSSTVASLAGRSARYRGGLLPATTAATPKSTSSLIQFSTSRRSRPNVCINDSTSKLSSGRALMYRSNPARSGDCTRLRNRVSRSAGSAVLVALAALARRALKIRSSMDRLSLSAGYRRADRGGPLAAIILGLVALDQRFHRHRVAFTVSVADDRRAATAGFDENVRQQHACINFDGGDMRHVDCFFLPPDPPWLVLHDAGRRNQDLRREKVIAGTEAAGAEHI
->SRR5688572_24783379
-ATVICGMNRPIVWRTPIASMRMSAAQTSTVRVDFISSCCRVARGLPNDHRASRACARLMAIQGMTNRNTRQVPGNALGPRVAQNAPIPKSRSTRSMNPRHLALATFLACAMPAAADCKWEWLCNGDGACKQMPVCGSVYDRPPPRPTESTPPATPPLAMRHNTFAGRGANRGPPLTCEHIMRKDHTGRWYWSEACFCTDAARAKDPTPPFANIVRCENGTKX
->A0A1E5AL09_ALIFS
-MIVNSNNILSLTSTSRVMSINWALMNNCNYKCKYCHSDLNSGSIKSPEYNIVVVFVKKIIKQCQQLNLTPYFEFGGGEVTLLRYFSELIELIHKNDGLISIISNGSKSLDWWKANTPYLGGVSLSYHVNDIKDNNHFIDVAKILEQSKNTRLHINVMMDPERFSDCLFFAKQLKKEIRCSIALQPLYEGFGHGGITKKYTYTQEQEKEMQTFRGRADNKNLPEPRAYLDVIYLDGSKKTLSTFDLLITDNVNFIGWDCYAGIESMVITFSGEIYRAWCMQDGPIGSIYDEIITLPTTPIRCRTKICQCGADISAKKVNTTLLKHYQNSIETKYIE
->SRR5262245_57968688
-XMICLQILVPFRFSIVSARTHWASDAKQYNKSHARPPPAPGNCPRAAVDHWAMARQFRWCLRGASRMAVLILGNDRDEHAECMRAYLSTKGAVVEFLDSQRFPAELQIAHDPAAGSGTIRLPSGSTWEFAEIESVYWRSYGGATAAELPDAEQAFIAANDARSLLESLLLCLPARWVNGLAGYRWHQTKPAALARVAALGVAVPATVVTNDPQAVLAFADRHGRCIFKPVQGGAHTQRVTREHLTEQNLASLAVAPVTIQEEVPGVDVRVFVAGPRVLACEIRTEVLDFRKDPRADIVAIDLPGGVAETCR
->SRR2546425_387409
-PKSGWTLAAAGLLLYASASHVQAAGAFVRAGASYTVDKWDAADFVGFDSAALPPNEIIAMTQNRDGYLWLGTLNGLVRFDGVHFKVFDEENISGLSGSPVIRLFEDSQGNLWVGTEIGAIALMKDGQITTPLETGLGGRERRLMSVCEDSSGAVWLYTANGDLWRCRNGECRAFPENPRAQSVYRGVIAEPSGTVWVGSDHRQFAIGPVPGSASFELPVARQLPVAKLDFLLASQHGGHWRLADGRIQKRRGDQIEDLGAYPWGLASVSAACEDRDGNLVVGTRGAGVFWFEQDGKVASLSTTNRLSHNYIL
->ERR1700751_958828
-LDGETGLQPGVATHVQALGAELGHAPGDHILHLPGLDPGPLDHRAIGRAQQLVGMSVLVVALLQVPAPNRGARGLDDHYLTASCRHQLSLSGTGPAPEPALRVYKHQLTVTVPRRAGPAGPRSHPSRPAPRRGRDAEPPG
->SRR6185437_9543277
-LWSMRGSLRFGLGCRSVRALTVDVPSPCFVRGFHASARSALPRCALPSPRVTRRRRMECGCFHCIQTFEATAVIDWIDDGETPLCPYCGMDSVMLEVTDLTTLWRMRARRFGMEGLAALGEGPFSVAGPLDD
->SRR3954464_8629952
-PLEHAIARVHGRVISFDPATSTLTARVPASALRRLSGRRDVASVAAVPVRRRLALSDFVATTGAPNFWAAGYTGGQGTNDSVPATLWIDEDLDTAHPDFHGVNWENIPGAAPGPLCGSPSNDAGGSCEHGTQVASLAIGQGVDAAHCPSGITCTASDAQQKGVAYGIAHAISTQGGGAAAPPGGYWDIFGFALGIYQTGGSSCSSPLPGATWPAQVTNESYGSGAGTVTAANLRDDSIFSAYGVLPVPGAGNDGPTASSVASPCIGYDTLCVGSYETNASVSDPADDSISDWSSRGPGPA
->SRR5450759_3105029
-SGWSEEGEMFVQSADSATRPQFSASYSHLITCSRSSPSPSHPLSSPSHLQSPSRLKSPTLLALPLNHMVKATIFIHMKTTLNIDDALLADARRLSRIEEKTALVHAGLEALIARESALRLAALGVTERRRRPVRRRRPARTATRX
->SRR5580765_3100358
-LPAPGDAPRALSTKNTEHQEHWAPRARRAATARIATKLTSHPIVTRIPMLAEFSAVLETVANSGPGIGAGLAAGLGAVGAGLGIGQIGSAAGEGIARQPEAADVIKGNALVLSALVEGVALFAAVIGLLLVGKGX
->SRR5690242_3907823
-RAHPDRPPRRPRLPPFAVARERRRALDRGDAPRAGAARRGRARDVPVAEARRARAPARLLARGARAARRGRRLGAPSGGIRRGRSPSPRPPSGDSPMSKPEVLRQHAEELFSEELAELSRADDKQKPPNWKLSPWAVRTYLCGGKLPNGFEVSVKYI
->SRR4051812_6319949
-PRPAEVMRDDRRHAADGAIGAERAATIEVSRREMIRVGAAARNHPGFESRARRRVMLPVGEYVDGRLGFGLPAHRAAQGDGLLAIERRAIGDVVDHAVVLVPREGEPAEQDVGGEGQVDVSGRAALVVIAEAGGERAGGLVLRLVLDEGNRADFRAAAKKRALGSFQHFHALEIEELDNTAPRTADRYA
->SRR5580658_5004565
-YLKARQRTRTKRGHERNVGGIAPARHQNTADARLVMAGIECVPAFSQIGLKPGAKIHWGRIRWYADVTEIARAVAHRDVHAAAQGDGEMSKVPTYPALFGMDIPCCFGRTRVFITKFNAIVDVVADRLNKAPSSGNICELRPCDLDEAIRLAISAAEEEDERVDGEVLQCMLLRPQVHRVRFALVLHKEVRRHCELACGSMNDMAEIAENVVIGIGKNRRIELQAIPGQQVGCPGWMNTQLQDHVRGLRAIIRDLVARMNLHRYPLRTSQPRACRSLAKIIAPQKFHCDAARNKQHKSSALGSIRSLCRX
->SRR5919197_97304
-QSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSTERSAGGATQAAPAQSPKRSRERSAGGGTPAAPAQSPKRSRERSAGGATQGAPAQSPKRSTERSAGGATQAAPAQSPKRS
->SRR5215470_420408
-EIQPGKFETLSNASKRALVAAMNKSRSSRGNARNGAELGSINLRSTAVKVDLAEPCSPARHKTGYGPLAQRRKDKGHAENEIPVLIFGSIFILWHAHVQELAKLIDRSTTGRLRQWQHSAGAAKRDGCLINDAPAVGIDFNRAPTRISEVEIQAAIECADPNVHRALPTVEMCTRLDDVERRLDRVGVRSARR
->ERR1719223_2153901
-QAQTVSAPANFASKTVWGQNVINIRPFSIESHKTFEFVGSYKNNGQIPIFPSPEIAFLGRSNVGKSSLLNQLTALNKNIAVVGKTPGRTQSINLFKCSERQ
->SRR2546430_7123832
-TRRRTQTRWAAPPRSTGAAPLSAPAHPPTRNLRCSPRTGEMGVAAQPCVRSPIGLQPQRCINVGKRLPAPRTNDGRRLGPRGPATSRHHLARETPSAPPDRERVRRRARARAKQRGSASGRARAPGREPRVRPGHRCRSNPPSPHPRSEEHTSELQSQSNLVCRLLLEKKTGAHAHDMRLTGTGSATIFRDGLRQEATWSRANNTDPFIFKNASGERILLDQGQTSVHVIPNDWETPSQX
->SRR5207245_1019995
-XMYPARGPAAERKRSNWLSASSGSGLFHSVSSSAGYSRSIASRRAPAYGTSGRPSRISLRFWRARSGSAKPVARSASRLGSRSRRRGGAARSLKKSVNARWTAVVTARCRARKTPAAGAQLDVAARRPAAPAQRAVDLALHRADRGQDALVHAGPVDDGARPVHEARADARIAGGHPGLEQRLALPQLGALVVIRAEGVERQRHRAHAALRAQAQVHAEDVALLGDRLDDRDDVAADAREVLAVGQPPLGPAGGVAVGAVGEHQVECGRVIQLLAAQLAHADHRQARLVAVDVPRRADAGAEVGGGHAPGLAEADVGQPRQLLRRDAEVX
->A0A1H8BLI9_9MICO
-MTDHISRSYRRPLTLTPTHHNGASQRGPAAHRLEPPRPDLNRPDLPGAVRLERKRARFTATTRTPALVAAATLAVLIPLAGLAAPAQAAIAGIARAATAGAGTTGVPAGTTLKVHNGDLNITRAGTVISGLDIRGLVKINAINVTIKNSIIRGRSVSAPAALINNLGGRSDLKVIDSELYPSKPSPDINGINGYNFTLTRVDIHGVIDAAHITGSNVTIANSWLHGNLHYVSDPNQGGKPSHDDSIQIQKGSNIKVYGSTLSGSHNAGVQITQDTGDVSNFSFTNNFADGGACTINVAQKSYGPIHGTVIQDNKFGRNTRLLNCAVISPTTTKISTARNYYTPDSKTVAVRTG
->SRR5262245_45043355
-TGSMLLIGVFGGPGFAQQPATNDTLKQNKNEAVPPAPSATAPGKTVFEKVEPAKPPEKSQEAKPPVVKPDGTPAKVDEVPKPVVVKETQPAGAPVPPPDGKPELSAPVPPATVIPPVRYFVMIFGSESVPKRARFSHTWYTIVKATPKQNLPPGYDPDGNLVKYYDLTAHTISWLPSSLHIRVLKLRPDCGHNFSLH
->SRR5512132_3388807
-TDLEILAAARAHFPTEERLAIIQASAQRALLRHAEAEAGLRAHLAANPGAHGCLMTLGQALLDQKRSAAARELAESTLRAEPRGEVAVGAHFLLATAYQQEGEREKARPHLEAMLALEPGNTRIELLLASLDREAGRLEESLARLDRLVEREPRPGNHDWDRMVTATLLGRWDAVRASAARIGMNLKGAGPIEEAWGLCRIELREPDGEIGIHHALRTGPVTARILDVARPRAPQHYGDEIVFEAAPRNAGPRPGEADHSYLYPALATRKPGGYEAFLLDGVHPGAEALDTLRRELAALGCVLAVQSDTTYVVTEAATGEARPGLFAYLAAPAGCSRRELHDLLVQHGGSPARPLVWPGLAQALEQASELEDELARQAAIIERLGLX
->SRR5215472_956881
-RSWSPPGGCTRCRPLGVVIRPVDLAEDLIRRATAWHAGSRGAGRSGGAGRARIALWSSRARGTSWTCRPSRAGCALLGQILPRRARWRRGHVARQGDPARAVVEDRVVLQVRGRRGLPVAAPVDARQARRSSRARGALWTLRARGASRARRPGRAGGTRRASLRQHAPVGRVLGWWHVVGGVVERDVARALITDAVVFGVGRGRRPRAAPLHRDAPAAGHRWTVGALAIVVVAADRVEQAVGHPPRLRQPPLQVRLDIVAPRVLQKADHVRLERHTADX
->SRR5258707_121040
-GRDEMCEASASNRKRTREGCSPIRFSSIVITAVRPGGELSLMPLSVALAILMCPAMRLRDLRMHRYHWAMLEARRRIHERRIRMNPPRVRLRVPVAVATIVAVVRRAVAIGRVILIMLIALILLIAALDFAAAIIRFAIAVVPIPATIINIAIAIISIVIAISGRPVLMRPVALFAEHQPIWMGLELX
->ERR1039457_2916573
-FFFNDTATTEIYTLSLHDALPIWDAEARRDLQAGRLAGQAQAQVVGGLEGLLIEPHGAVHHAFGGSAVDLERHQVRGNQGEGAGGTEVFDDRHTQRAALLRVGGGAQFVQKHQRCGRHIERHLADIRNVGREGTEILLDGLIVADIGQDLLEEGEFGFGGGHRQRGLRHQAEEADGLESHGLAARIGAADEQRAALLREFERDRDGGFAAAAQDVFEQRMARVAQHQALPKTRDHAIELGAEAGLGEDQLQLGHGDEGLADGIAVAAQTVGDFEQDAADLALLLFGEADQLIIQVDGFERLDEQGVAAGAGAMDDAIELAALAGDHRHHETLVADGDELLLEDAILAVGAQEALERFLDRLFLTFHIAAPAGARAI
->SRR5918993_1097003
-GCAPDITPGGRAMRNRTMALVGPFAAATVLLLAPTAAADPPPPEFGRSNMGLCSSFLGPREAARQRSSRARVPPTALDAVAAAHPVPSYRPGGPLMNRLLGMLATCAVLLGLSAFLAPAAGGQEPVPTFTYTTPEGGATPAQACANSDDAVIGQFRLDGEVVEEFPLSGPGDLTRGGCVTTITMQELSTPAYVANCKILEPEFAAANESGRPYPYAFYGNPDYTANNRADCVSFLRGFHTGTLIPGPX
->ERR1700722_7859116
-XMKYRVYKPFLLAVVLLCVVAPHARAQAFQNLNFEAANIPPGTQPASMISASAAIPGWTTSQNTWYDAFSGGGALVSVNDSLTPIMNFSPLQGRYSAILFGGAFVPSTSISQMGLVPANAHSIQMDISLLIPSAPFTVSLGGQLITMVPLQVFPNYTVYGGDVSPFAGMIENLTITQFAPAPPNVPPAALELDDIIFSPQIVPE
->SRR5437773_11503562
-SRWRVKARRFTRATAQRVTNPALNLQTRWLLSPRLGLIRSGCIRGRKMPRPRQTGASRNWASIVHQWRRPRIHTDTSRLHWMESGSARLTLHNGSVPTLHDLLNPPNERPQTFHRGYDVFDPVKIGFKEPPPQPTGPNGTLTQPYFFAIPEKKETAIKVTPTAPSYPARTKRNCWNIX
->ERR1712178_671869
-SVKTIRVEIRVNENKCLLNLRSIMLQRKVLIIKLSTPDRFTTGSVTSCEITTLNHKIFNNSMKLTAFITKTFSTGGEFAKVFYGFWDSFSKETNFDCTSGFPSDSDVKEHFVSNNW
->SRR5258708_11690673
-GVPRRPQRDVDVLGSRIGVGEESLDGLIGCAEQRPARDSRVPFRAPLFLQRRLDARGVGGVTREVEADVDGAPDGRRLPTLDLAPVVQHAAEAPELIWSDVRNVPAIGVTGDEEEGASFAHPTKPDRKAVLHGTWQARRVLRGEVLAAEGGALLGEQAADDLRGLVEHVEPYADLRKRVPERAGLGF
->ERR1017187_4658610
-LFRSDVPAVHKGATQPGKWIARPTKKRPLRLGGPLLPGRQAENFQLPAIAVAIPVPVTVVITITVAISVAIEISAPVVPIEIAAHKAVPIAVADKVPAARNPIAAVHVSGAPGVTRSRGRWNVGKRCVHVNSKLGSLSRDACQPRCASQYRCSQHPVLHTSHNASVPAGPWFKISVTIDRPGSVPVX
->SRR5690554_4605005
-ALSLTMKNGFNFGSHQAEVQGGSWGRRVVTVESGGNDGTWGYYLNATGFEEDGWRDLSDSDALNVYGSLSWRAGDTSALNLNLQHGDSELRGNGASPVGLLATRRAAIFTAPDITENDMRMVSLDGSHFITPSIQLAGSAF
->SRR6201996_3122915
-PFDWERSVASGCKFSRGPICSKIAPIEPYSLSQSVSRRVLLLDPPLLRFSHCVLCLLPDLLELLQPAGYLGHRAVRCFPISAGVSSHQKIKRGLPCCGVLPIVMREFCQWEVLRPIVLLIVYEKPEIGFEPLIGPFRLSVRSRVVGRRNVLPYLQEATQLRCKFX
->SRR5438477_5602888
-RCGPDCRRGDPHPRQRGRTPGLPPAGHGRDPDRDPRPAAPGPARDRARRGGRVPVRHHAPEGHDQKEERQGEEREERHDAQERRARARSRKRARGHRRGGDRAGHARPGRHAVHGGRQGPRGLGGAARTGRMAAATARSAAANVRGRGPAARRGRPAQADHRRRRPAPDQPAAARRQRCRSDALGRSGRRGDGLGRAPDGSAGPARGHVHRPERPPARAGVLSVGSPHLRGPAHGAWPGRDRSLRSGRDRRRRAAPSGRNDPARPPGTLAVGQADGGRLGVGGGSAREAPGGVGVVHVAHRSARDRAGRVAARAARRRHRLLPARFPDRDGARQGRGVGLLDAHGVAAPRQLPGRVRGCGRRRGARGPGGRRRHRRPRGPDVRAGLDLAERGLVDGDGAAALAGRAGRPRAPAQKPRRRLPRRARALSDARAGRGDRAQAGPALLDLPADAVSGRPLPRSRLDALVPSLLTGQALVSLVPATGDHVWAAGAAWDVARAAATTDRRVALVDLWLERPTLHEVVGLSPAEGIVDAFEYDVSLTKAAHEIDRVFFIAAGTVTAHAGDLFANPRWRKLHGGFRSEDALLLLYLSAGALARLSTVPDGLIVLSADGYEPESSIGQGITAAMERGIPLLGVVRERWTPLATPAPDPRAMAPPPGRISAAVRPGLRGGGVSHRRTRPVVIAATLVAGTAGGWALLARGAEHRAPNAAVRAAPTPTATSAPAPAAPAPSQPRVDSLAWTVQLAAYARLDRALALADRLTADGITPFVTPVTLGPRRGGTVWYRVLAGGYRTRDSAVSVRATLWNRRLAQRGQGDVLRAPYSYAVSGTTTPDELRARGIPALARDGAGRLLVGALETPEQGGVLEARLKRAGVRAKLVTRMGATPX
->ERR1719231_1158533
-HLVPYAARLNPTMVICFFPNIFMNSKNEPGGELNQDSSFFSSPSSEAVASCTSSAPLDMPKRAQMFSSTHGASASAMPIRNGTANRASVRKPRDHADTLPASSTFDMSGTCPLVARNANAASGTDTTQKSSSNSPYEMPPAMPYFLICAVISLTLSIASSPFSASSAIISSGAERGAGAGSPGSTTLRATKRCGATVDGTKAAAGMMSSSARASIV
->SRR3954468_1616850
-AGSAVLHVGRDARASAGHETRRARARAVLAGGAGAAGLTAGSAILTVGLNVDAGAVALVLIATALRVHRPATAFGAAGEQDQRREKSRGQRRQGRLAFVHDRLLRGKLPRLKKERAAASAPAGGLEGRRHAYHNSRLGALLETYGVIARNGVPRX
->SRR6516225_4192873
-TSASVTSTSWPLGVTPPSGIDAVLAGALSATVADNTGSGSGLIVFTFGAGDALDFLAAGEKLTITYDVTVTDNNGASSTQLVTITVIGTNDAPVITSSAQTGAVTEHTNVDNSGNLNAAGAITFSDLDLTDTHTVSFTPDGNNYLGTFKPTLTQDATGGSTGVVGWTFSVSEKTVEFLAAGQTLTQTYTVQVADNNGGFTTQDVTITITGTNEAPVITSGVQSGLVTEIADGAPGENTAPHSLNGAVTFTDVNLSDIEASSISNTQVVATLANGYTLSAAQRSALVNAFTIDAATHSTTDGTGSIGWHYNINDSALDFLGKNDQVVLTFTVQVADGNGGFASQDVKITVLGAEDAPVITSGVQSGLVTEIADGAPGENTAPHSLSGAVTFTDVDLSDIEASSISNTQVVATLANGYTLTAAQRSALVNAFTIDAATHSTTDGTGSIGWHYNINDSALDFLGKNDQVVLTFTVQVADGNGGFASQDVTITVHGAEDAPVITSGVQSGSVAHGTTTTHSLSGAVTFTDVDLSDIETSAISNTQVVATLANGATLSAAQQSALVNAFTIDAATHSTTDGTGSIGWHYNINDSALAFLGQNDQVVLTFTVQVADGNGGLTTQDVTITIGGSNEAPVITSGPQSGSVTEIADGAPGENTAPHSLNGAVTFTDVNLSDIETSSITNTQVVATLANGYTLSAAQRSALVNAFTIDAATHSTTDGTGSIGWHYNINDSALDFLGKNDQVVLTFTVQVADGNGGFASQDVKITVHGAEDAPTITAGSTTATGSFSESTGVTGSTALDSASGNIVFADVDLSDAHTVSQAAPTFSWSGGTLSASQIAALTSASTLTLTRTADSTGTGSGSVAWSYSAQDQTFDFLAAGQLLTITYQVTINDGNGGAAVQNVAVTVTGTDDAPVLSVAGTALYTQNGPPVTLLSAATVSDVDNQTMQSAIVSISSGFLTGDMLAFTNTSSTTYGNIVANYNAATGVLTLASAGATATLAQWQAALDAVQYSSTSSDPTNFGNDPGRTISWVVNDGTLASAPLQTTTLNIKASTLTIPAGSTTTLNGGTLQASVIDVEGTVIGFGTIIANVLTNNGTITSKSAHTLTIEITSGIQGTGLLEITNNTTLALDGPVGSGQTVQFDIGNGPAPILILNDPSDFQGKITGFQGSDQIDFVNIDPARIHYLNGILTITGTTNAITFVGSPNLKFASDNHGGTLIIDPPLSTTTAAVTTTAAATTTADAAVTPVAKTSTLTATKTTSSQTKATSATETASSRTNATLAAVDEASVVALSTAVAVAVALDTAVADPGKMSSLTISGDGTAVDITGTGSGLDSSTVNSSAALGFSSISHEMAGAPADKAVEVSNGKPQTADTVSETGAFKIDAAATPQLDGSDAVDALVITAGTNADAINVPGDHATKTAWHVSDDGRGGKTVHESPVSATSEEASAQSTSADHHVIVGGPLTETLSGNGDHSASPFKPNADHDATVDPGINLDSIPKNHLLQHPADNLIHIPAQPDHGADPAHPHVDGNQSANVKFADDGSAPSGALPSDPSALTALPSDPSEAHGPAARALAPGDDTPVQPTPADNGHHWGTDPEMKFASIPQNNPPEHPADNSLHAPAQQDAPAATDGTHPLRGQVDASESASPNFAANGSPQSAHATGEDTSVPVALLDNGHHGDADPKNNDIAKDPPPQHPADNSSHMQHDDGTIAATDGAHPGLGQVDGSESASPNFADNGSPQSAHATGEDTSVPAALADNGHHGDADPKNNDIAKDLPPQHPADNSSHMQHDDDGSSAASDGTHPGRGQVDGSESASPNFADNGSPQSAHATGESLSVPSTPADNGHRPITDPDINLASIAPNQPPEHPADHLPPTPAQPDDGPHPADPSVDVNEVSSFKFADNGSDHGTGPDGAHPADPQVDRNQLKLADDGSDHGTGPDGAHPAHPQVDGNQSDSFKFADSADHPGTVTNDPTAVTAPSSDSTGTHGPAAPTLAKTDVPDAGLSAAPDQFVFVDNTGHGPVTDHKTDVVEIDHTVPADIQHLLDTAHETNAVSALDPNHATASQDMTKVPPHHQGDFHFAX
->SRR5271156_26155
-RCLPVGNFRSNRGVEHTMSSPYTFVPIWSIWRELPSPLKLFCLVLVIVCIRTLISALTTLVGLRAFPTSRKAADESRVHPCLATLCLRVENMRQLLSATVYLFVFIFCWILPWVMVTLDNSKTPGGILVMRHFFIDIAFAANVFLAFLVLHSVQWFVSSRVNTINLSAKTSPAG
->SRR5580698_4360037
-DHLHHLTACRLSLNLTFGLGHGARLVGPATSLAQLLQPCERGCLGRRRRRGWRARLRFGDSPIGLLLIPGGVALSLRDQAGLIGPAARARELGRSLSSGVCPLLSRRDTRRRRGRGARLCVRARGPAERYARDNHTYFGNSVHRKHGVLSSSSSPFVAGFVLTVRCWS
->SRR5947208_1864857
-SSWSQFGPRLASLGATRANAAPGMARATPPAAPMRNCRRLGSDGVFWGGVGGMCGVPDMSLATPSRPAIELTVVDSGRRERGASPGSQPTPTSGGAGATVAERRPLRNHRGRGGAVFYINSEYLSNRGPGSDGRX
->SRR3989344_4462318
-XMDFRTRRTENIYNRIHCMKNTLTISIATLVGVLLSDTRHIVAQSVTPVPNMIWINSGTFVMGSPLNEEGHTIYEEQQTRVTLTYGFYMNKFEATQQEYLDLTCLNPSTTTNLDAPVTKTSWNGAVNYCFLLTERERSAGRIPSNWEYRLPTDAEWEYCCRAGTTTRYSFGDDPTYTLINQYEWYIGNTGTNGLFPRSVGIKLPNRWGLYDMQGNVSEYALDWFIDNPFRGSLPGGSLVDSHGPTTGDWRVFRGGSFFEGVSSCRAAVRGGISPTSTSGLIGFRVVLAPATPEWRQVIETQLERPKYSSGPVKEVGKSKLVLVTHGWIPSWDIPQLSTAWVDEMTNSIDRYLTDKGLDGWQVVGYKWIEGAHPLDLLSIAFPTRAAQTALENAKREGRKLGEYLAGQGWSEIHFIAHSAGSGLIQAATEAIKDISPSTIVHVTFLDPFVGLDYSGVSSYGNRADWAENYYSRDLDTGGENWPFTQGLFDYCYNIEVTWVDDNKILGPVYISTPLGTQRCTQTVSSHGWPIQFYQNTIPPNTQLGSAGFGFPLSRAGGNWDYAISNYMVSSNALWVLGTPDDPQCNQLYTSTPPMIGERVDFSNSPIEKSSTGEVKIHGIDSFSLITGSPVWLAAVINPTNSVNLVSFDAKFVNANGSEGLLSLYWDTNSIGSVDEPAIQLGFKRYAFMFPRAASNTLHILGFRLDAFTNVPSSVLVTNVSLVSMGVSEPFTLSFAGVYTNMLPIFALTGPTGVVYTIETSSNLVDWTTSVVLVNNSGKVRFSDLASTNALQRFYRAVAPX
->SRR5262245_14032018
-XMSEDIDTAPPAALPPRNCTTCGKPATVAYTWEWGESGMACPEHAATLQQNAGNLNRTVTVVPLPAQGPTPLTRDERIKYNATILALEAEIEDLKSRGLELVRSNEDLAKQAQLFSMREREKTAYLEDAQAEVKQLSARLEEVETELADAVTEVERLRSIVKFTPGAQPPQQPPAGPTVVDGPRX
->SRR5260370_42043382
-RSGGFPELTIHQTGHGLGLGVHAAPRVLIGNEQRCANPSVIILDEPSRGVDIGARRRIHDFVVEAAAGGAAVLLISSELEEVMGLSHRSYLMSEGRILGEIDPRKTSVADVLFPLFNVVGARAVAASLSRAAAPASX
->SRR5690242_10536872
-SVAPSPMSPLPVDPQTGGLRSMDTALVTSTQPLATGPSLAGSTVFHDASGRIGYISDSAFPTLKSAWTYDIRGRLATTKLLQPQSSLASLTPITDHHMPTAFRDLRDTGSLSVTDVGHLGVPAALATEPAKWIVNDGPAHEITSKTLFLDGHVVTPTMQLGVVPPPNQIPATFNFTFEGGRRTSDGVWNTSFDEFGRLMRLENADRVIDYVYDPRGRLIGRTASQKTSSGNVLETRSEVLNRDGLPAETTFVWDPVVDRLVAMYEAGKSTQPNATA
->ERR1719203_2165260
-DRTIDKFDQSIRVSNIALSASNAQIRIVSLVPITLQKATAMMASTAIRCPSRSPSQSSSASECKGSLLSLCRLLGRLGLLLGALPSVANVPAAPLEVLLHQLPLVFLGAPHVVVGHLRHAHQLALLGFVQVRHRRLGEVAVARHLALGLLLRHQVGDHLLPVVAVFAPAPCP
->SRR5690349_23072571
-YFFFFFFSSRRRHTRSLRDWSSDVCSSDLLGIPTLPTGGISVALLIAFVWIVAFALPVCLWMLAFWCRPAHTFVLVIAVAALLRSEERRVGKECRSRWAPDDVRTKGVALLD
->SRR5262252_5786708
-IRTAARDQQEHMPTGVQIIATRRKSPAHDLSSIVNIVGFYKLQTRIRRNHSVQVDDGPIVPEDYSKGIGVAIERITDDLMLRINRSREAGAISGRIQIRDTPVLPQCGVKLPIAGIGATDRLPIVVKPERHG
->A0A0N1ILD7_LEPSE
-MSKYFEPDTTFGKDAECAVCCCLWTNPVEVNNCQHIFCRECVANLDLCPVCCGPVDHLNTPGKFILRLLDLTRGKCSACAWRGTYKDFISKHAKCLKEGEVMRSREDTNATAPEAEPMHEYYLEEGWPAAHSLARLAAASPTLTSTNSATQNAPQPAPAIAADNPEKRDLSHVSNAAREVSAEPTHAQRARWQQTLTSTARDFGMPEGEFKELVRRFPDFASLVTDRSSRLELRWRDACRLLRFMNYPSHPDDVKNLFEMAERSPKTDSISFNTLCLWLMMNRRSPAQWYQMSDAPYRQILQVAQLLDVEATGLFTVEQCRILAEQYFERDVEDSEWSQITPLLRSKDAGIRQSFIPSNRCHPDPLEDFTQSAVKLPLHDALCSFARHVNELKSLKLQSPVQQRQADFVHRIKKIVGYYEPDALPQLETTLQKFNGEEESLLMTLTAMYGPEPM
->ERR1700733_3340046
-VVGANTSTGGSNPPLSASKPFRIPANASNPRHDRYLRLQNEGPRAFSYYVCARVSAPAIASTARFSYSCEWAMLRSDMEFRVIWEIDIHADSPKQAVEAAREVQLSTDMPATVFEVWDHARQKMHRIDLATVTGRLENGEVASLRAAFRQLQCAPDLGAGVRDFLSVMLIFLDADGGYWRRRX
->SRR5262245_2448521
-XMNSRSRANSARRVAFLIIRLILLTTVLVRFPVQAQTDAAARFAQRLQEARQVDAAAQDDVGVMYAEADGVKRNYSKAVFWLKRSAAQGNVLGACNLALHYARGEGVRKNPILAMKWTFVSHSLDGLKCFPDDLLQFFKPRRSAVRKAWSLANAFLRSHPDLKNEFGERPWLKSGTQPNKSLDRSPDVSGFARLECLVRX
->ERR1711873_241630
-PELTDSEGEEDSEDETEDDMLVEYRPSGNIASGISRSPKPDGYHLSERLLTSKTTIKNKSTSNTDADSSDEDTEKPQMNKEINKNRLHRKRLTYPCHPPGRYSPMIEDQQHTETSKEIGSITVKEEEVSNTDLSSSLTWGKDQEVSWLSGTSIRLELT
->ERR1039458_8309614
-RKTSRPDRPLQQTLDYVEPQTWVPQVSPLRPGTAANQSKVRAAIAKPESMYPEATMLNSTRPAGSGESSVLSTGHSNSGFALAAISNGHLYNLRNSRRYRERRLNYTKTRPTTVSISERRKPDPRGQPGYLRIDTDQGDSPTAKGVYHINAVDEVTQWQLPPHGRRPVRGDPGAX
->SRR4030042_4963036
-YTPSDCSTPGVIPFPSPLYVVLPVLLLAGFQLLKPKLRSSLSFVLLLCLFFFFNMSSSLRLVEASRDRHLRIVGLTSAMEETGRRYWLGEYWRCWLLTAVSKEKLIVDSYTTESSLPYSLAYWNQAESDNYVFVSPSDRERPAYYARFGRWLETIGVRSEKKEGGTFRLVYDLEPRVFQRVLFMDPPGQIPRLDLEMIEPRQGYLPLLFPNPAPGKSDLGFWLTVEIPGFSGRKELFSLNQPEVRVKIPHPSEASFSIRYFIDYIGVRIPASERKVHGSLPPDAVLVRSDPVVLLRGIPPEAPLRKAGRMICEKESWLELNRMSPGASRLRLILNSPFKFRSWLWYGKYVQQVDIAVNGTSLGKRTLDDGRNVLDVQVAKDILKPGPNLVCLRFRYHGWFPTRSPWPFSAFLERVKL
->SRR3954469_24847718
-VACSAQAPEWTSVLGSRPQEALKRFGRALLGAVAGLRAALGLGVMVGQEGARSVAPRAADRGRRAAQVGDQRPRPPAHGAGHGVVDVGCLLVGAPGDGERSGTGPAATSPTGPVRRPGASLASRPCSMSPPPPLPPPPRPARRRX
->SRR6478609_5279812
-RVGGRRGPRARRHRDQHHRRGAQREPVHQRGAHGRVAGRVRRDHRRARDREGRLRRGLPADVAESVTTARVRLNAALEALRKVDDSLGADVATRKARVTNAVTALVTDIDAFVSPRVDDVMWVDELAGEHRLQVAPLDVGLTLDRLLWDPPDRGGLEIAAAGPADPEDDPRYGLPTSVVLTSATIP
->ERR1700736_2808299
-HTIRGAVTRARGLLAPNKLFRSRDKGKGRGFCPRPGFPRMADGTAGATRRDTRCQQTQCFMQILVQPGISGQSFATPEVGCQASEYRRIHFQETLDSARGTKHCGKETSGIVLLAGRRQPALKEPAGNLPKQLMLGWDPRFREXX
->SRR5580700_6228722
-SRGSVNADARLAEDNVHRRVPAIAEGERTELNEMFARPSLPSRAGALHPDVHEALAGRLDAAAADGKVQSSRRGVVHSFVVVRQVRDGVVNGRVLSHADVLAAGGLELGQDGDAGAARVLQEHPPACKERLGVGLTGDHVYE
->ERR1051326_2460312
-VLEFVFRRLFACAAFRGLWFLTRCASRGNSLGLGGFEAGEPPLCGAWRAKADDGQVGVFRLSKEQRIFSAAPFIELERPHEQGIAAEEGAAPGFAVAIPEFRVPGGAPDRSPDRTPQNERQGVIQPDEGISALPDHLADHIAIDDPAIPADCPSDTLAQDIRWRGCPVWPPMEGVHLYMGEH
->SRR6185437_12123836
-PHSPTDRARRGKSNAAATARRPSGYAAPASRACTAPPSPLPRQIAQKVVVAPSRCLGSESRAKFLRSPPPVPSCAPSRVVSPPARRRCFRHRELHDALTQRTEIESHRRRGLRQQAQWCHPRQCVRLETEKFTAVRHTEVDARVAVKLERAECSQRQPLNFRRLACRELGRELLARHARRVFALVIVDLVTRENFAHRQRLVAEHAHRQFSSRNKSLDHYLIIVLQRLGHRRREISSSTNQRKTNSRPLLRRLHDHRPAQLLLDLLGLWTRTGRLANEQPVRRGHAGRPKQHLXX
->A0A1F8KNI6_9CHLR
-MLTNVLGDYLDSISERNFDFPFMALLRAQGFYDIHFTHGQVEFGKDFIAKQSLNGNIFQYSFQLKAGNINQATWRNDIQGQMLEAVISRLSHPCFDHTVPHQNVLVITGRLIGNASLGMEDLNRTIVDKYRSRRIQLWDREKLIDMLVSAGLEEFYSTTSSGHMGYGDFHILYGKSLKGYISEKDIENHSKNWLDDLVISKNRVLGAILESEIITQNCRRNGFFYESIHSQLSALRVILFEINNVQDPSDDIFLNKILSSAVINLARDCFEYTTHVQKSWEESGHDLVKIIPGTGKIFTYLVNCARILEIAGLAFFLVQSPDEKQVLCKFISNFILSEQGCSHIPSDRYAVSIVFPVLALKKCERNEVALEFLHRLTIWLCDRYEQGNGIAGIGKSPLEEISILLGAPFSFIATMKRNDNYLATVLSDLAAFFEDDIFYSKVINDIRAVKIFPTYWQISDNNDLFIIEGRSIISYPNIEYLDHLKRFNDYDFAQHIIHEERTYGLSQKVSPVSIMTLMLLLRDRYFPTLWNLLIE
->SRR4051794_33743283
-ARSGWPGLADLRERRSRRRRASCRDAARAVKRRCRLVDREGSAGGGGKPLARGVACVVDAAVQVRADRDVRQRTCRGDRRRRGARRERERRDRGQESNYDHGERPSVAFERATELFHLPRQSPPNRERLRVSGIAAPACREPQGHQLVRRKPRQKSSPKRASRPSKGGLPRRRSRSNGPKCEGAARDTRPPSSFQGPAGPLQLSPCLAPTYAVCCEVTQPYVMCVGPCRVRPWSVQTSAALPPLSIAIEIESARSRLPSFTVQKIPFVQIPPTCMTELDADVWLNFGTASYPSVVCANVVYHGDCSGSLGVX
->A0A1T5DHB0_9SPHN
-MARPYRNGINRSAGANGASAALRVRGTMAAAVIIIIIALTFSAAMLTGVMLIAWRSFGRPRHALLWAAAFAVATVEWIANLAFRIAHAQDNAAIYAAIAGLSCLSNALIAAGFVQRSRPQTGPGPFLIAAAGAALLIAGAAIVVPHDGVRDATGLLFGGAMMAISAAHVGRGFRSASLPERSVTLMLMLFAMLDGAMAVIALRQGIAGQGEAFALFRTILVLLYPPAFIGVGLFSVFLVAADLAETMRTLATSDVLTGVYNRRGFEDAAERAIRNAHRQRQPLSVVVADIDGFKAINDRYGHGVGDRALRHFASRVERLVRRGDLIGRIGGEEFALLLVNTRPQDAVEVVERIRRDIAAMPVSGPDRIVMTASFGVTGLRPGDISLASLLTRADRALYRSKLDGRDRVTSAEELEEA
->ERR1017187_5107048
-MMRRPPRSTLFPYTTLFRSVGVGGKHHRRGGARVRQGIGGARRVEIRQGRRPARCRYGGGGGAEIEIRGQAVVIADGSLVKRDAIAGGIGAAIEQAEQSPGGTVVGEVGSGGRAEHGGREGSSAAIEVVGRRRAYSNELVRGKGEVDAAANAGAGQIDDIGAGILYLDELEVLVLIRAVRGRRRGVIVDLRDAQRGKGGDIKGFGRSAPCIGVEGAGDDSGIIGQRDCAAI
->SRR5450756_1904656
-IVTPNGPGRLSSGGDGGLGGGGGKAYRAWLDAEQPAGQRLRGTLGLGEPDACRGDVEVGEAGAAEGAACRLGHGDRKHRVLLAARGEPAKHAAAPHRDPDVAVRVHGQPIGDALDPGQVDEDPSLEGVAGRRIIVEPVSYTHL
->SRR6267143_246127
-PPSTSTRCRRAACPSRCYSAGPSSKRASKEPCRFRRSPGASRPASRCRWRPGKRSSTCISRTRATSRCSARCWTGSTATRSGAGCPPGSGRWNRCSRARRRKHEPRRDRPDRPGRALRGLPPVPVPGLGGEEPAAVQFRDAPPGILGGRASGAQLPPGRGPRPWRGAARGRSGALPPPRRAAVPLRTLAAGTRTGGRDPLPSRPGAVLLRPRGRWTGAAGRVHRALLGRARARFAPRLRAAAQPRRARSLCLPRGGAPPRAGLGAPAPGSARRRVRLAPGASGRGGRGRCGLPQPRVLAGPGGRAGNPRHHARLAHHPLRLPGGRPREPRRPLRRGRDRRDPVAPDPHPDRRREGGGPRDRSPRAGLARSDGSALPGRSDEAPRSAARAARGAPPGSARAHPTPAGRGRLRPGARGEGGHRGGRRARRPGPAAPGGHRRRRSGPRPRRLRPPLLLPRRRGGAAAMKRILVAGVGNIFLGDDGFGVEVSRRLAGRPLPDGVRVVDFGIRGLDLTYTLLDGWDAAILVDAAPRGGRPGTLYVLEPRLDPDAPAALEPHAMDPAKVLALVREMGGTPPLMRVVGCEPEAAGDFEVGLSPAVQAAVDSAVALVERIVAQLGAADAX
->SRR3954471_23318179
-XMSTPPCRRAAPDALNAIRPAVGGCICGGARPAAISAAATTPWRVTLLRTGGSPAIPSFARSNRARTGSGTSRPTSITTVQNSLRPNAVPRTRPFPVRGAGCPATGPTSCVAASERSLRGYSVAVNKEKPDTADSDSGPSGADDDVVSDPAKSDGASGDWSDEGGAPPSGPADTGDHTQX
->SRR2546422_8761933
-RCSLFVMRRHSLRGLARLCLLCFLCTHTALSYFFFFFFFNDTATTEIYPLSLHDALPIYLARHDGHASGDERLARHPGGGVLGEDRKSTRLNSSHGYISYAVFCLKKKKKTKKLTERIEHNTTDSPPAHADSCHTQHSPDX
->SRR5258705_435907
-YTSYGKVRDLNELLPETAKAIAKVENPTLRDALAMELFGRGGVKMIQALTTIGNDMEGTGKKAKDLGVLLSTDVINAGKQTSIAFQRLSLAVQGLLLAIGTPLLSRITKMTEALVTWLAAHQHIIALRVHEVFEHINNSLNAFLAIAKYIVNNSGLV
->ERR1719362_736321
-LKPYLANIAFFFSSGSCIWSHSLFGFTGVDLGSVFSIDLVVVFSLKYEGMLCCLLTVLLLCRFCISGTIWACFMGSMITLGFFTFGFNESSDIVLDMPEPFVVSKNFLIIDVLSSEPGTSVVFFSVMEGLLSKNEDASTLPMFFFVSAIVPGLLNSSRNFDFFESSLKGDVISGSVFVLTSVDFSSIKSRNALIPSLNATSLVFSQGLLEKSCKSSMKPFIALSLSLMLLASCSDF
->SRR5262245_8711603
-CPPTEKRVGSSAAVRNDRPFGTSIGFVRRLLPALHNPPGRAGGPARLTRNRMTSRALITLLSWLTLLALSGLGSTHVGAQSGKPATAPAAAPAVPNRSGYLRFPDLNGSQVVFCAGGDLWITSDRGGASRRLTTHVGNEVYPKFSPDGRQV
->SRR6478752_7265712
-FVSLVLLCFRPCSSLLWLDCCFLHCLFFFFLMIRRPPRSTLFPYTTLFRSHPVGELLADRPEVHARHSSIWVLATPASTCFITLPDAVRGRASSVSSTTVGTLYAANCAAQNSRSSSASTSAPGRTTTTALTSWPYTALSTP
->ERR1740124_914837
-AAAKTRATEDARGRAREMSSMNVIMLEDGWAKLKTGGVKKIEDILEDMKDGVYKDKITTDEYSALYTTVYTMCTQKPPNNWSEHLYNNYCEAVKDYLSSRILPRIKEKHDEYMLRELVRRWENHKLMIRFLSHVFKYLDRFYVKRLSLPELAEVGSQAFHEIVFNAVKREVRTAILALIQREREGEMIDTKLVKDVVAIFVEMGGNRTSLEVYVVDFGEMLLSSTADFYSRCSSKWAEEDSFPDYMCKAEDRIKQEADRVRSYLHSSTEDKLLRVCDEQLLQTPETQLLEKENSGCEALLRDNKPDDPQEPQPNSDPPKRRRSPPPLPTVAGGSGQIDVISRLLKDRILLLGTDVNDEVANVLVAQLLYLAQDDPDADITLYINSPGGSVSAGLAIYDTMKFIPCDVQTVCFGMAASMGAFLLGAGTPGKRKSLPNARIMIHQPLGGAQGQAADIEIQAKEILFIREVRCVD
->SRR6478735_628956
-QRRSERPWNAATWLTASWCRSDRRVLSDVGSEPLVAVSAANPLRCRSPQPSLHTEPDMDLGLTDDQRAIEQMFSSFFANEAPPAVARAAEPLGFDRSLWQRLLETGAPGMGAPESAGGGGARLSDLVVVAEAFGRSIAPAPLLEHIVASRVVYDADVLSGDAIATVALRPADADVVWRIVPA
->SRR5256885_2358642
-FGGKTCYETENSSLLVMRFKLKASGYDVDGTDQTSLGQFSGRVQQTYKHSVPRFFVPEHGTMFTLALVRFPPTATTEIQYLNAKGTLTYTDIAVFFSSRRQHTRLQGDWSSDVCSSDLDPEATAVFPRLLASERLAGDSEPAGPDLASVTRPAERSSDDELPTAIQAPPAAGAPEPTQIGRASCRERVX
->SRR5258705_12133918
-YVIIIKSASMNCMTDRPPGITALDERIPFLLSQLGAHIAGEFQRRMSATGVAPRTYAVLMALATEDGQSQRQLSARLGIHRNTMVSVVDALEADGLVKRTAHPDDRRAFVITLTDQARSLLPDLDNAGHALENAVTAPLSAVERNTLREMLQRIATGAGLIPGVHPDLAHSVAAIAKQRLSSDETSRRKRVDQPWPNRDPMS
->ERR1043165_342850
-GTTAGTNFLGTTDNQALDIRANNLVRLRLNTNNSIQRDNAGNARGQNAIDLQASRANTTMVASGNYSVLSGGMDNKVLGTYAVIAGGEDNIANGDDNAIGGGASNWTNGGAATVAGGGGNDASGNYSTVGGGGNNTAQNTYSTVSGGHYNNAAGIYSSISGGLENHVLGLSSTILGGQNNYIDGNFSTIAGGAHLAITSGY
->SRR6516162_8751238
-RFVFNGGPMRRLLLGSAIAMLGMFFAAPAMANPTPATGYLELCKYSDQTAPVTGPFTFTVTDGSYSSTQTVTTGTCTSPFQVPVGTATVKEQSVPYASVTAISALPSGNLVPGSVHLGQGGSAQFTITGGDESTTTTAEFTNKEVTGYIEICKQAVPGSGLTGSFQFAISGAMGYKQNVTVPVGACSDSIQVPAGSVIAQENPGSSTYVVSITSTAGFTTLPMGWTSNPDLLNARASVPVAAGDTSAETILTFTNSPSVLKLCKAVTNSSMLGVNYPFTVNGSPISVPAALAPNATCEIVPGIFTAGTTVNIAEGVVPGTQVQSIAVTPSGREVSGSNNPAARTDSVILGSGETVVTYTNEPAPPGTLKICKIAGFGVAPGSMWSFTVAGVPGTI
->SRR5262245_26240924
-KANPKPEGVKTPPEKEAITVPSKAKAEPAKPKPTYVTVVGQLLDDATGQPIEKAGWEWGQADPKKPEQIAWGHSRQGDGNYPGGKFAGRVNIGADGHHHTWRVYSAGYETAIVVDDLAKPYPERIERVVRLKRGRNITGVLRDHAGKPVANGWVFFIPKGHRANIVEGVPGTDAHELPGRARDDAVAEVRTNADGTFAFSTGADGALAASTDLVDLWPFPLPEDGHAVLKMPTPSYLVIDLTYWYLDELAKKGKRELSPNSEDPNQCWLAVD
->SRR3990172_2002343
-YTLSLHDALPICRRGIQDIFYAKSFDGGLTWTDPNLRVDDDTGSAWQAFPSVAVGPPGNVFIAWGDQRNGDADIYVARLAPAPPFVEAPTVDGFAPGSAEIDHLIGNVPAFGFTYRDLDLDRLTAYNVTVLDGALAPLWTCNRTLSAPLPDGFPIFVNYNVWPCPTSGPALADGSDYAVDLTVQDATGRWSVPERVGFHLNEVLGPTAPVQPAPGAVVPCSRSHTLSWTAPPADVEGELPVSFSYQVASDPAFTAIVASGNSTFNVTDPFTTCPGGPYHWRVRATDGWEASTWVSWNFSTFTPPNAPPSALNPAVEGYGEGSPGILRIGPDRPTFLWNYTDAEGDPQVEARVTVGTANGSNDIWDSGNLTLSGSALVYGGGTALVDGAEYWYGVRVHDGKDWSPWASVRFRVNTPPRAPLAGGGGRGGRPPHLSGLDQHHARVRVPLGLRAGLGPLRHGHGGGLHDVLLAGPGPRPARRRPEQLDVPVHHVPGPRQRDGPCHLRRAGPLRRSGDRRGVHPHVSWRRLVQPRCERHDGERRAGGLPPRPQDVPRARRDRHAPRGGPLGEPYRFLTEYLPPHP
->SRR5262245_7034097
-YVLVTEGTTSFDTADVQVSTNNFATFTTVASRSTNLPNSSTWRSVAPVSLASFAGQTVQIRWVFDTRDGIANNFEGWYVDDVQITAPGTWNDYYSFTLGAGETATVALKNLTGSGTSLTLEDGTGATVATGLAGPTNFDRVISNFTGAPGAYFLHVSGAVAATYSAVVTRNAAFDTEANDTFLTAQPIAGGQAALGAVATSASTASTVIPNANTNVEGDFSNGFPFHISAFSLPSMRYQQIYASSQFTGGGVIDQIRFRKDVSAGTNFSTSNIDVKINLSYSATSPTAPSNIFANNVGAGVVTVFDGLLSLSSTGTGTPNPFDIVIDVANSFNYDPTQGNLLVDVFMRNSPVTTFFDAVGNSPGVTSRIFSNNTVNDTSGSSFQSGLVTRFDFVTTGAAQEDWYTVNVTNAASALRLETATPADGPNQFVNTLTPRIALFDPTGVQVASGTPLADGRNEFVQYQPLATGAYRVRLSAEAGTSGEYFLTKNFKPAVTSLSVTSPINENDVATLTGTFTDADPLDTHTVLIDWGPGEGTTTLTLAAGVTSFNSTHTYLDDNPTGTSSDNYPVSVTVTDSPGVSGSASTSVTVNNVAPSHVVLNSGNINENGTFTLTGSFADPGIQDAHTVVIAWGPGEGSSTLTLPAGVLNFTASHLYLDDNPTATDADTYPVSVTVADDDGGSGTGNTSVTVSNVAPSNVVLNSGSINENGTFTLNGSFTDPGTQDTHTVVITWGPGEGSTTLNLAAGVLSFSAAHQYLDDNPTGTASDTYPVSVTVTDDDTGVGTGTTSVTVNNAAPSNVVLNSGTINENDTFNLNGSFTDPGTQDTHTVVITWGPGEGTTTLSLAAGVLTFSAAHQYLDDNPTGTASDVYPVNVTVTDDDTGVGTGTASVTVNKLAPSAVTLSTGTINQHVTFTLTGSFADAGTLDTHHVVITWGPGEGSTTLDLPAGVLTFTASHQYLDDNPTGTPSDVIDIGVTVTDDDGGSATASTSVTVNNLAPVVTPIVAPTDPVAAGSPSPVAVSSSFTDVGTVDTHTAVWDWGDGTNTPATVTEAGGSGTVAGTHTYLAAGVYTVTLTVTDDDAGAVSVSSGYIVVYDPSAGFVTGGGWIDSPAGAYAADPGLTGRASFGFVSQYHVGTSVPDGNTQFKLHAAGFDFRSTSYDWMVIAGPKAQYKGTGTVNGIGTYKFLLTATDGQRPGGGGVDKFRIKVWDPVTGMVVYDNQMGASDTSNPVTALAGGSIQIHDNSHX
->SRR5690349_22883871
-LYPLMSSLYSFLFVFFRLFSFTIFFFSMIRRPPMSTLFPYTTLFRSDARSAGSRSRHRPSRRRSRRSARASTPPARRRTRRRPRSEEHTSELQSRREIVCRLLLEKKKRPHLVCLLLLEKKKNTAQNTQ
->ERR1700731_2171409
-LQDPTGAVASRGCGKVDLGVVDTVEDVGEDGGRESQADLDQLRVAIARSLDRGEILVADGATGLCELADEADQRVALGAAGGLTLADLPEHFRLRPGELGEMVVGGDAIVAAAGGADDELDHFLIALGQRARSENRTGGEDRLEGGRAVGCNGSECFRDAADGLLIPDDQQLLRTFNSPWRKNRATLVRAIKVSGAAICRGRTCARCAPNITRRIAARVLVQRAFTTQFEYSDRCFRPTRAFQSLKPCLSANSTMRRARWEPQVSASKLACRSCRRRSRTRSTMRLANAYGRSADRTGKAPTKAVLAQRYRPFICPRRFLFPF
->SRR5688572_8862321
-ERKLRWDNQQRRLPAGETGQPLAHADGHGKVLSVERVELGLVVEQFQMRRPAGLEEVDDALGLGREVGRLERSGRGRRAAGSRENGWVDQRGHRQRAQAQARARQQLTAGNEASLFQEFVHMLSRYFVITSSRFSSMLATVVYAASSVASSFSSRGDSPIERSFAAVSGFALYAANRRSKVSRSTFSSSADGACAVARRNANVIRSSAAVPPSCIIRSAS
->SRR3546814_633682
-IDHDILYFLFFKQKTAYEMRISDWSSDVCSSDLIGKFGGEPIVDRENDGARGGSERAHRAVLAARRPHDITAAMNVEDGTPRPVRNIKQPAYRAAFAEGYGARLDAIRMAQGNFAAGHQTAEMRQIVEGKIVEIGNRRQGADQLRIDRRQCAGSRFIHLLSLPIAGLSAKQARRSVGPCGNKIGRAX
->SRR6185369_2348986
-LVGITPPALPTLPQTSAHTTASVEPPDGTSQSARATLVGIADSATPSGPAPIGQRPTPTLNPVIEQARGTLLYFALQNNSYDLYTLNLNTRAEQQLTFNVGGDSYGIYSPDGKQIAFESDRDGDFDIYVMDADGQNLRRLTQNVVTDRLPSWSPDGQWIVFSSDVRGDTNYDLYEIHPDGTGIQLVFSDGERSSHASWSPDGRSLIFTHGNNLDGSTW
->SRR5262245_26026989
-EPDLWPGKNDGSDFAGSAQYTIAIAIRTTPRMIAAAARRRLLLTRKKSRGPLGGGRVRGVRELAEFARDQVGRLLADVDRAVADPLDRACDDHHPQPPLAKAGLGHDVDEALDEPAVRPVDELVEIDEALGTMPLAPAERVERNADHLLRAVTHLRQDVDERRVRLGAGDELRELRNRDAPVCRPLEQQIDVEDREEEPQVACDRSLQRQXX
->SRR5687767_9486488
-DEVSRMRVSTCLGFAVTLFVTGCDKAVGNASVTRTLDSLTTIVDSLNTRLGALEWDKLISGVEGVAVLRPSDAGYDRLATDFGSITVSLEDVVPYANGSRITLKFGNVTSATINDAAANIQWGSVDSA
->SRR3954452_6150108
-PGHVPRQQEMRAEDLENPCKQVDFCRTAELPERAEEQREVRAVLVVAAVRDRPGVEVCGGLVVVTARRVVRQTQHPEQERADQCDRQPDGEPVAPPAGEQRGIERKRAPGTQPGAHPQPTARAAAAAASATCSTSASVSSGYMGSETTVRASSSAPASDRP
->SRR3954453_16503950
-DRRRHVPAARRQTAVGVCVNWSRRWASRWRSTTWTVVTAVTLAQAAAWRGLAGQLVGGCASGLDARFDRTTVFTVDRVGRSAVDAGRDLTIDAPAVNQRGRRIERIHRFDRGRWRQRRQWLDHRRGQRLDGRRW
->SRR3546814_3464296
-MSFLQYVVLLVISFFFFLRNRRPPRSTRTDTLVPYTTLFLSDRRRPGGCACRGRPHAPAGARPARPGQGAAAGVHARRHLLRRLPVAPEGPRRHRDSQWRGQPRRQQRRSEEHTSELQSLMRISYAVFCLKKKQHKKIDKSTSKTPNTQQK
->ERR1017187_7010674
-PYTTLFRSSELRNSGRSFWDVRRATGGIHLFPCHFRLAGLDKSYQNSAATMLGGPVLPLMISVESTMAILFPSQPLGATASSFLIWLGSVRNSPAIRVPKQVIPAAVTTICSVFGSLSRRTIAX
->SRR6266545_5506238
-RLSAALPPAACAGPRCRGGRAAGRGRSTRPGAACRSSRSAEDRDPVHGVRRAAHARVVAERRRPRDHRPRRSRHHPPVPAALPARDRRGAAAFVRHALSLHRHAAVERRGLNVRSLSRVVAATLAGVVIGLVVGYIPSLLAYGLVAGATQNTISRTGGWAEAGAVGGVVWLASAGLIVGFLQQRVLPPTARSIWWVVALAAVWAAAHVINMALRGLAGDVDLAAILPALVVISLVAGVAALRLATRVTRXX
->ERR1041385_9034566
-RSDLGFLTDRRDDVRRDVPAEISRRDAQERDGALGAFLANPFLRRSTDRLQGREVGCIHEQDASVAPTVNYHLVQQGKIRRQYILLEAVAVDALLLIHVTIPARQEDRDSRFFGRGQSWSNRLCVSPLRDDEVVLLTDRANDPIS
->ERR1719323_877409
-FTSTREWLVIMQNPNEDTEWNDVLRKKGIIPEKPKEAEVNEEDLVRMLEETIREKSGVKRTEDMDLDELDELEDEEEEKILLQMRNRRMAEIKARMEKSKYGGHGPGRAGRARGRGGGEDLAPDEEPEDGRDQGQNGKIKIWRRKRDYCSRLCSGSEQGRRRCVCDPALVQAGRAPLRPGQRVHEQAGAQVPHHQVHQGHLDHMHPQLPRQELAHDLRLPRGRLEVPDHRTRADARNELDRERVX
->ERR550517_2316039
-SEASLEGTAMEEETTTVTDAVVAGGEGGDGRMEEVDEAMEEEAVDEAMVEETATVVEAVEAKTANPSQNSLAPRSTNSGAQAKLQVSAQKGSPSTMLQRPKTAVQICPQTELSVGAKAAMPKCASTAVX
->SRR5689334_23514466
-HLRPCTVLIMRVPCFYLFFFKDAATTEIYTLSLHDALPICADHVDADVRGTPVGRVGRILFRTDERGRVPGVAGPPFLDDPSDADRKSTRLNSSHSSISYAVFCLKKKRTRPEDRTEPSLRAF
->SRR6266436_2860317
-SPRCSKRGVMLIESSFMILFKALWLDNPKSKRSPGTLLSVKRIANNWRRNCNRVFHPQNLPVQLSSELLAVGVAFAQVIEMHRRLNGALAAQVDEMRHERHVLPVTNLLAHIAVAEFVSEKTRRQRMSLPRGGFXX
->SRR5271166_360653
-CDARDVEFQIAERRDRDVADGEGKIERPEVVGVADIDVGDSIGKSDVNVPFDGDLYRDRDVHVLQQGMRRVEGEADVAERETAHRDRPDAQLTDRNRLQACLLYRELRDLELHDPCPPLGNELIAMSTELQNARAARPRASFLPVRRKYSLETDQRQLRREPIALSRRANGASAARSMVEEPLPPRLTRSAFAIAPLPARGX
->SRR5438128_8400954
-IAGARSDWSRSGVAVRRGRRAARRVDGVGFPAPAQRRKRGPTGSPSDRGARSPGSVAVQSLAGTFQVFNSENRHPVRFGRGVARRGALAHPTLLRRRPMLPAVISVRAGKPASASRPSRASARVGLGIVLVALLTLSTASIVSAHAFLASTTPRAGERLLGSPSEVVLQFSEPVSVESGGVVVHTAQGAAIPLGPSESNGRSQLRIPLPPLAPAVYSVSWSVVASDGHQSAGEFAFGVGTEAIEASTAVTSDAPIAWPAAAAGAMLLVGFALGAGGLLSELAV
->SRR5262249_6274811
-LFALAAQPDWPMAQVWREPLKSTLRRRSWGGDLDGPQESVQHVNGRVPFAGTSDDLRGRIAFRFDRRGDRLCALRGACNQKPARGLRVGQEMALPVRASRWKLDAILVAFPIAMRSAGDEALLRQLRSLVEQRDVPQIDCQPQSGAARHLQCMAEQAKARHVGX
->ERR1700710_2726627
-CVTTRSRRTRRSGRDFPATSAGVPATRASSTRCTAPLRPQKRGKSGVLGCVPQCALGLQVFVEPVLAPLATVSAALVAAERGVEVERVVDRHLAGADPARQSTRSVQIGGX
->SRR5438105_150411
-AADRSHGERRGRHEAHVVPALLVRRHAHPRRPATQVERGAHAAAPDLGLALLAGKAQARRAAARFVEAVHVHVLVGDPHRGPDAQAPEAEIVAPHELGRCVRAAGLRGGGARYLPQAERAADIVEVEVRVRHYAGAIEPAPLHGAEERPGVLAGAEASRFPTEAGVELAAPIGDAQGRALRYAHREAHGGGGDVAADAGIAGA
->SRR5919112_1724051
-RGARRAALRDQGPHRARARHTALLQQDHHLPGSTELGRPRGSLPLARAREVLPYAFERAFQGADPRAQAATPDHGHPHHEQPGQPQRPFLRVQAGRGDGGSGVRDRPCLHGGARDLLYALPVGCYRGPGQYVRGEGADQDDARRPQTRRACDPLAAPLPPRAAPRRGDDLALLRGCCRTLRAHPWDPARRRPRSGGERGPPPYRGERTTGRGGAGREPRPAVLRTGRFRRGQLHGRVPRDDSGLILHPRRQAQAPLAATPYPGSPPRQSLAHARALGPARRHLQPAGRPRRRDTKRYSGRQTRQRTHRGMGRSQQGARRPHPAGSRRHKLERYLRPLHPLGRAAGDPKPHHDAGGPARGGGCAKWLKPRCELSDISYLFLLMADSAIWGGSMTLPKSLERLSVGGGALYVLAGAAGYFPGLLVAHVADAFGGDADYEAPGWELAGLGDDGAGGDDGTRADLRAVEDGCAHADETVVLDLAPVHDGVVADDASFADDRRVAWVRVQDAAVLDVGSGPDADRLCVTAQHGPVPNARFFVQVDVPDDVGSRRDPGGLCDPGEGVAVGKHVALFVQIQRGALTLYSRYTSPNFRSRX
->SRR5258708_1650640
-PMKSRAPVMHDRCCDGARRARRSAMKRGASSGGSGGGVATLLAVVVGAAIVAGAGAARADVVLEGLPTVSVGYTDNAALAPTPVVAPGLPPRSDEFGIVAGIARARLRKAHAEHSLGYRLAETFYFHGRGPSSLAQELAWLSDLSLSAPTQLRLGASVAYGRTSNPTGVDASGAGPGAQLAISSNIISLGATEELVHIVGRRSRILQNLRFAGVHYLNAPGAFDGTFVVGAFVRGEHEVGQSLFSLELDVADNIVPGAVGVSDQVLLLQSLAGWRRDLGLAWWVELKAGALGVLDFHGTEILEPAALASLNYRQIYWFATLSGSQTATANLFIGAATISDQAMLRLALPLARSERYLLAGYGGHTYARLIDDTGPHRGYTLPPAAPPF
->SRR5205823_11678186
-FGTMALSRFVIIRKGAIKRILSRREFYRNVIAPISRIWIVQAAVVLGQSLSHELTRFGTGLLGAGFSPIQKTVVTIWLFHGKRCPGSIGFRANCPGVNAIELTSTTRSSADFWDFLLNLVLAGSVFEAVPCAX
->SRR5690348_5794318
-GGRGGASGSGGGAVRGDANKNRRGGGRGGASAPAPSDPTSLQPFDFEKANSLFDKDKLREEDGPLVPSAEAEAAVDDEPPAYSKDSFFDSISCEALEKQDRANYNAGRVTMDEQRRRDMETFGAVSVNDRNRYRGRGGRRYHNHNNRGGGYQRNYRVCL
->SRR5208337_1056505
-SSSPLSSANGPTAPADDPSSSSPSSAHSSASSSSSSPTSSSPSTPASPSSSSISPASSTASPAATSPSPPPTSQISPPPRTAPKAWGSSAPPSASASSSVPSSVASSENTSAFTGFPSPPPSSPPPHSPSPSSPSPNPTTPATPTPKVSAATTPPPSSTSSHAPSSACX
->ERR1700722_2816766
-LNRITNCGLVSKSCRIWFPFQCSGVESGEEDEDDKNAKEETAAVGDGVDNRVFVELAARALEPETHDPEEKNGDEKPETPRVLVELCRVQVRDVEGQDNDRGKAACGAEGAELLDVGDVVAAASSGDAAAFAQAFELGEALNQGEGEEEEDAEASEPGGDLDSSGGGAGDDTDGVETRQDDNVDQDGALQTQGVSEGGEEIDAKPQKEIIRFDQGQRVRX
->SRR5262245_51317312
-CRVFSALITTKQSMMAMMAPTSISAIASPFLADAAAAAARARRRVSGCELVKRPGTPTSSLASVEAALPNDSLDPGRDESVDGTSGRESFPDRRGRHVESRDRKVFDLPSRSGWFGMLAGALDDDKRRERTGVLEPLPRRHVGDRVGPGDQEELVAVAAERLERVGGDGRLVALDLDRATIQAVDAVDRGLDERESITRRGNHEPALLPRVAGYDEEHAVERKGRARVHRGDDVPDVHRIERATEHADALRVPAHHGSVRAPVF
->SRR5439155_7586424
-XWDAESVVDLVGHLVPVGELTARRVSRCEDGLQVGECGLSSDSSKDRVGEVIRRQLAVLVRRPARSPAVAVARPADLVRGELILTAAAFGCKARRDDDRILELARQECGGDGGAEVVVGVAARAVNHDHRAGDLLVLLVHSIRAIDQRAAGPAADRDPFRAFLLRDRARRGVSRHRRREADENTGGKDQRAFHVADDTTLTSTAWRLAPTCPCALYSIQPQDMVESX
->SRR5262249_42789402
-GVLAVAQLDHARDAHEIDARAEIERADDRRARQDQHRELLEAVDERVRDRAAAAQVPQPERVVAVDHDATVVAALPHGDALPPAGAVFYNVPKMVTLLMFSGGLDSTAALYKLLTQDSGALRVHHVHLINREARARAERDACAAIIDWC
->SRR5437667_1021999
-LETICLKCLEKEPGRRYATARELAEDIARFLNHEPIRARRANPVRRVWSWFIRHPWIVTGAASLVVLLTVGFAYRMWERVDALEWQHAHPKESPPFNSEYFLPVWFNFLLLFEFLFLQGVPVLSFLTLRARQQRANWFHWVFAMMGAVQLLFGLEILRRAVATQAWQPQFILGPILASIAALTNVWFGSALAWKALREARLDLPGVDLSEEPIEHPLEFTNQK
->ERR1740121_1965673
-ASWLAQERPAAAAGLAFRRARHGRTPACAEDCELRSREAVERIRQYAWQLVLQSRENISMAGKSAEWRLNNTLYERSREEQRNLQHASKQHREQALVQEREWLAAQTAHNESLRSAAEYELLSSAFSAMMKEFSKDRGLWQQLSQNATRLRQEFGDAVQDWSSAVGESSLASQTGEVLLRNSTATLYEDMRWLKEAHREVGVRLVRVGLQARPRGRVPGAAGGEPGAARAAGHADQCREAGQAGGDDYRGRGPGAGGGPLRSAQARVPSSGRARKRLFPAVSX
->ERR1740122_63733
-TSAEPTAEADNDEPDEERQDPIFEALAILSLDGDVRGLLVAACCGARYVRRQLCRHPDADGAGFVLDAAQVHTTLELEEASVAPRVAPRVLRYPILHLTSGSLRLDTEPHEHDHVPTDDLTVVTTMLLEVHCFGVVLPEREQIDAHAEVHSQRSVGRQLCSHHVGGATSQCGLLQRQLVEGHDFDVAVGHAALLLSVCAPGPLRTRACSARIELVLNVAPSALVGHLVLPDCCCDQRVVSVGGCAAVAAPPAARDGAPHDVLNAEMSLAEHVGAIAAVIALAVLHASALPGHRGDGKRPAAAAGTLGAWLQLEAVGPLRAGVERRRHVVRNVR
->SRR4029453_18409069
-MTMRRSDPRRLHAGRMPPLRAGLAVGETVGPRARPSGGPGSRQAPRREAHGPGVGEPAMAPRSSEVAGRLPRARRGAMAVGYTPGAGLDVQPKTGTAWRVTPAPRGPQAAGILERTAWGTITADRRALADWRAATGVTPVAMASPAASGRPVDPLREGPVAVWLVHAAHVQQGPGHQTDQAEARWWAPH
->SRR6185503_13583503
-RLDFVARAEGWETCAVTVPRPDDVWLVSRRATAVRGRVTDAAGRPLADAQVWRVEPPNEATMTPTDSSGAFESFFTAPGAGQFRVSHPAFLEKTVAVAAPSTDVVVALEHGREVSGRVAFPDGRPLPGVPMYGENERVATTDADGRYVVTGLTEGRVDIRCGLGNDIERRFVESGTTGVDFVVDRPVARIRFVDADGRPFRFVTPRMRVCKDGKDLW
->SRR5579875_218622
-PSSGRFCRLPRGRLIPAEVSAEALARERRMHSIVQAQDSFHNQLILLHRFGGAGADAIGERQQHQIGQRQPVDGRYERGSDAGGHRSQIGKPAQDLEETDHGSENAEGWRKSAGDFERARAAFQLALAQADAAEQRVLQFGSLRHIQREGERFSEERTAHAFEHRLNRQQAAGARVFHQRHDLVDQFGVIQLRRNKELARPPEGLNQRGAGGGHEKGPQGSAGDDQRSGGLKEIDEPYAAGRDAGQQCGGRDGDAGQHPNIQARRRRRARHFFQGGGGGQRATPARCEAIRLPRAGGRKQRRARRRRFVTGTSLKPSCLEMTRREAIVIAFGQPLAASDTRPFWEGKKPEDWTEEERRELLSRSPWTREAEVKFNGGPGPLGGPDGWLMAQPGVILNEPNGSTTRTPKKFAATVRWESALPIRLAGGNKSGKEPANYVLSVTGDLPMLGGAGEETDEEHQSRLENLKQYTRIEKRGGPLYLADFADQRGKGTEAGTRFFFDRSDPITLHDGSVTFVTRLGPIDLKCKFALKEMVYHGRLELX
->SRR5277367_2534031
-QITSFCEEHHIDLLSTPRSRRIRTLPSRFKDAFITISVGQRVNMNNEDQYRANLYYPLINSVLIELNDRFSFENMQMLNGISALCPDSDNFLQSEVLKPFEVQMKADLSSLFNEIQVLKSMLKDTKLKSIV
->SRR6266568_6098953
-GVTITVSAPSSAPAGLKGVHPAWSPMQPANVKSPAALMVKWLTVLPRVEVAYSCLPSAVTATPCAQSSAPAGEVGVHPARSPMQPANVGLPVASIVKWLTAPAWSPNLVVVX
->SRR5207244_11792182
-GARGEPLGLWWARRVAGPAGARLGGALRQGAGASLPPRHALPPLAARQGSGCLHLGERPPPAGAERPDGRRAARRRSLTCSPARHRTIVGVGVRTRSALAAPAVAALVLAASAAAGPPGQWTPISKGSPLSSDEVGVARTPDGVLHVX
->SRR6266852_3314374
-RTTSACRRCRSRVPRQRHSYDVSDQRECGPGRDNGDIRVASRSLLVGTDRPERGALRMNHNHWDDLARENAEYYICPSETDYSTPEGRRHFFAEGQLQVNRLLEDIGQDIHSHRRALEIGCGVGRLAIPMSQHFDRLSAVDVAPRMLKALAKN
->SRR5688572_20022461
-MIRGSLGRLSSVPEAALRQRYWWSCRSSRRNQKVATAGIRMRRWKPARSPRRGTDPATRADRTPPPCSRRGACRWSGAPGGPALCTCRAALDAFPGAAGVGGELGRFILGVSDDFIDGRHAVADQPPAILAQALHALLDGRLADVMRWSALQDQRADLIAEEHHLEDAATTMVAAPLALSAAGAPVENRRH
->SRR5579859_288497
-LSCRKSAGDNEREERKNGAAQTTHLDGTARRTLRAGGPFGAGRRHFLRDGGGNDRAEVSLDYVFAGGLRTVERRAGATGRRGSRKRGIDPPGPTNSGEGQGEEPEYRGGDAREQAIRKRYFDGFRGEPGDGRIAWEPLRQYQPGDHRCAIERRSGSSRDRRKSHEGSGRTERGSARQSPGVVGKRPGSDHRCEAGQRLAGKDSDRX
->SRR5688572_26030911
-SRRGDRLRAHPSPARPRHGRHHRRNRVRDALRRRGPTQASCARGRSVLGAGLRSYLRRRLPMGAPYVVREPVGGSAGHRVSDYAVVHRSWLRWTVRGWPGSEPPEMALAAQRPHRLHLLDHRRGARAGRRPRRVGALRAGRVLGDPHRPAGARRVWSTAGRRDHRLDRPPGRDQPRCGHRASSHHRRPAALRVVRGVVAGGVLGSRRRARLRGARPGKLTAAKSEAFRVDRLGRSIVIAAGGTGGHIFPGLALADALRLRAPETPVSFIGTPHGLEQAIIPKRGYPLHLIDMKPFVRRIGPGPLIAIGSLILATGQATRLLRTHGAAAVVGMGGYASLPVLAAARRLHLPSLLHESGAIPGLSNRVAARMTRHVALAFDEAARSFPRSVRPRTVGMPLDASITDLERGSLRSDARSALDLPPDARVLLVLGGSLGAMRLNRVGVDLASRWRHRGDLRILLKTGAEHIEAVQAELHRREVSHLVRCFAFFERMDLAYAAADVALCRAGAGTVAELAASALPAILVPYPHAPRDHQTRNAAPLARAGGAVIVPDAEANGARIGAIAEELFGDEER
->SRR5437867_1173916
-SAWADVALLHAALFGATIVSSRPIDDVEAEGVVLIKQHLKVGCARSPKVSRAPLTNEDAVGGGTGNRGENAAAAGESRAVGLCIGAQVVLICDNGLDDRLIRQGTVCAQIICIARKLQVAIGTDVCTGKTRTVKAYRKRKRNGGCAIIAMVAYVRVPGHDCVRRSRRGIVAASAGGSARERLLNGNHIWLDHWFGDALLGDPATAGLRQRKWDRADCDEQKX
->A0A0T9YTR4_MYCTX
-MRSFCPGRSPQITVVRARSGRASVVISTRPGTSTSCSIPAAIISALARVRCMRSAPRSVRSCSTACSGLSRMADTRGSAEVSGTSSLVTSSDCTVTRTNSSIASTTYSIAATLRWASDTSRVDVTLTCLPAGERQCARRVSVPARRSRIRSWEINSPYRTSNGSSPTNRRKILPLVTSTTVWPASGYP
->SRR5882724_3941186
-SLPSEGHAEGDEDTARGSGRERAVRDQRRLRLAVEVRRVAVFAEAILRVEEIGRDDAKLKRYPGRGGGCVDREDVVARLAVREWTWSDVRDAGAERPAQGPSEDEPWEVVKEGSVGAQDRAWHVRDGGARVVVCRADERQVRGFVEERSRTPQRAEPPRSSRADADDVAPLRLIEDEILVDNRLEDDRAGDERGVTQVAREGGAGLVSRDAGERGADVGDDVAGIDRADALAPAQRERKAAQWPRDQRSARQERSSRGRSDLVGLARAAEVLLCEAALVDGRVAGRRMRDGLRGAVVMHVIREQLGAAAPAEREPATEAQVGVAVEAD
->SRR5258708_38243777
-HDVDRVVVGGQAADQLQPLAVRRGRELLVGDRVLAVALVAAAGDRLAGRARGIRTDVVVERNRTETTAAGTARSQSGCGEGGAGENRHALPDTVGPSPHLASNAELRLEWLPDRREDRRLWPAGRPALPRCTTSIARASSPATPTATSRTLALPNGVHR
->SRR5262245_54597287
-GAVIASVGCAFTTVDAIDAPHVLAAKLSIESPLKETYHQYVPAAADEMPALGLQRPSPVGDAVPSVVPPEVPVEGAVAPVKYLNVSVPLVWPELLASVARIDVGRIAVPVPAVSGDVSERVGDHLPLRTCVTGMLAPQALLAAAFVPSVGIDA
->ERR1700689_1111789
-AGCMRRHGENIDEALRRYEETRRPATAAIVQANRGFGPELPMQLVEERAPDGFANVADVITPEEIAEVTERYRTTAGVSLAALQRRTSLFEDPYPLSEHRGQGARKGIRDGGESPGTRATVWGKMRQWFHPIGMPQTEV
->SRR5439155_12922379
-FFRRLMRLTGMGAETGSQKSVSRDALPVREQTPSLPVLPQRLDRSFTPARPLALETGAATKAMLALALANGDDFAGSLADAGSALDWRWMAAALALGVDRWAEPPARRSKQTNFSPKRK
->ERR1711871_374509
-VQQHRDSNTESHTRAHSNITTQEQAIIDHANEQLRNNGLPNFQLSSDELNPYSQSTVSIVNGSGRQDVDVCSNNEGFQPIYDGPNLACPDGLLQFSHEIPGQNDWYCCMLPDDPMNISTDENGHKSSKFASMVASNLERLQSAPRAFKIGLGVTIIGITLSSKFRSLVSKIAT
->ERR1711871_1877964
-KDYSVASEVTAVLSLILERAKYDDLGVSSSLLSEVYATLALLAQACQDNLAIGETPMSFVDDNLRMTVAMTDSIDMRNKSFAVPVSTYESYAGETSASLGMSDMADSENAAGSVGLMVLQYLSNPNAVPTNSTSLLLEATKYDSSSRRRTKRRLTSITDRRFNSGLRGRSSRQKRLARNQD
->SRR5579859_5275108
-RPVLPAELAYAAADRVQPGRGKAREKVVLDMPIQSAQDRPPTPPDDEVLARLDLKAAPGIGTFLAEIRIVVRRDLVADAAPHLKARENEISDHGRDQPCREHLFPAVAGHRREKHILISDEDRKSVVX
->A0A257SWG7_9GAMM
-MSAGTDSRRAPRGGALFVWCGLALVLLLIPSLAPRAAGRCGADRVDAQVRVTYVYDGDTVRLADGRHLRLIGIDTPELHPDHGGPQPLAEAARDQLRALLQRHRYQLRLRFDQDRQDRYHRLLAHAFLNDGSSVERRLLDAGLGTALVVPPNLWHLTCYHDAQAVAQHARRGLWALPAYQPVAAARLPRDADGFHLLTGRVTAVRGGRRGIWLQLDGPVVLRIPRGDLIYFVGHDLPALKGQRVLAQGWLHRSFGDRSGWFMAVRHPEALEVLR
->SRR6266542_84348
-RDRHCRNLLRFQVLRAGPHEVYGYGPRGQEISRQTRRAVSGGAHTKGVHVKIRFARGRGGSLVAGGALLALTLAVLVQSASPSGEEGATTRFAPVDISMSGDRPSSFTPAALAGSSRTLMLQLGPAPLAAHDAAAARQGRKLSQNERAAIRAEIKSKQEPLLGRIRQGGADVVGQLQSAYDGIMVRGGDLARLAALPGVVAVRPLEKFQASNERGVPFVGTPPVWASSLTGAGVKVAIIDSGIDYTHANFGGPGTRAAYLDAFAHGTEAPPPTLVGAGAPK
->SRR6266511_5884634
-WTSAALGTLPPHATTAAVAEGVGVGVGVGVAAGFFLGLFRMRAYAAKPRPPTATAMATDAARMRWRRRRTRSRRRRSANFANCRSRVFLLLWGMVRTDEPTGWWLLRPCDRRCRRACRSQRSGP
->SRR4051794_24959122
-XMFSSAGSAIIGSSDEAGGGPPIPRVHHVQGQPIMEAKLRLATLVAISLMPSARSLAHAARPDVVLADFEGDDYDGWTTTGDAFGRGPAHATLPGQMPVSGFHGKGWVSSFAGGDRTTGTLTSPAFAVERNFVVFLIGGGGWEGTTCVNLLVDGRVARTARGPNTQ
->SRR5437762_3811764
-FRPRDRVKASRVNAFQLPQDGRRPRLRWRRALILGKIPAHRDFSGVAGRQHGTIEGRLALGDDIVKRDLLDRLCQQLADAIRQRAVVDEIRRLAGDPLVVQRRPLLQVGGNVIGDRKVLSEHVSPAGGKSSRRVARYGKWFPNIAPRSGTYFRCRLPKAAAMPSGLPMRSISMSMRSPPQNNSPLNTMVGTPNTPSVSASSMMRSCSARAG
->A0A2E6AYA7_9BACT
-MNFTAIECSTNVCSIASYKSNKLLNVIDISDSYNHSTNLPIIFKSIDDDLKKIDTKVNYYAISIGPGSFTSLRISLSFLKGIVFSKNIPILPVQTHAALNVGTEKIGKHYIIIDSSKDRCFIQKFNNHTQIGTPYIEKILNLKNLDYPIYGYSKNIEKNNYIKPSSLLIGAYVTKNYKRLIKKPAKDISPIYLSENVYKKIDDT
->SRR5258707_10299995
-FAQDDRNGVVWWEADDGIVVIGVIVVQWFVFFFQAEDGIRDIGVTGVQTCALPISYNRTAMSRTPPPSQPDSPELLSEADYEERSEERRVGKECRSRWSPYHX
->SRR5882757_10583142
-RINDAERRVERPAAREGQAVRPRMAGDAIPRDGEVAAPFHERGIRNPSPCAVGDSGIRCVREVGYDETGYDEAGYDETGAQAGGAIELHRGDGHGMTACQNMAPTPVPIFGGMPRARFSSTGSAVAESPRPRLPPARAVS
->SRR3954468_7113634
-LDGHPEAPTGERSACELNVDGCTWDAIAGELNRQEIRRPTASSWSLVNTSKIARRAALVLDIYSRRIVGFALGQHHDTALAYAAFAMAECVRGGAVDGVVLHTDGGSNTPHGPSRLTAPDLGQPVDGPARAGARQTPRSSPGTPPX
->SRR4029077_1358176
-SRSRKVPRQRCLRRSPSTGKTRGWTCAVPSPTLQGMGMDTYERPAGAGMEATQGPPQVGAVDSLLAGVLRLSHLADSTGEPREIFHALASELFAELGVEEVHVHHHAEQEDMVVVYMFGGDGRLSYLAPLGERPHGVAWVAESGKHIVPHGTRELAAAVPRLAVGGRVGAALLLPLAVRGEVEAVVILARADGRGAIGVGGSTRAAGGAAQA
->SRR5271154_6067984
-TMRVLKPGDRILVSTSLKRANCRSLGRQDILALMYFNNYLSRDIASAEQSARKGKSIKFGNSMPTQAISSSWLSWRICKLMGHLIPSSMVSLFINVSDRRRRWDLSCCESLSFQASRQRKRFTSPGDKRDDKYPEFRTEGTVCQAHRYYFNDGNYITYRKRSMAWKSVX
->SRR5437763_77052
-AAFHAGWHVPQLVHDQRPVSRRYRAVFDSVVVIIAGHADHFPPHAGKILAYALADRLLRIMPQIARKFLRKDDVIPLGVSIRPRVIAPGDDPVSHRLEVARRDEFIPPQGRQLAFGGRLVLGEDRIVALPPVHRDGTGRGHLGDARNRGDLVQDFVVHLYDAIVALDCRVRNRYPQRLYVLRILEPGIDAP
->A0A1J6JVT2_NICAT
-MGSLMDESKMERMGDESKEAILYVNGRALLVYDVSKRHTFERLSSWLEDILQQRDTTVIVVGNKYDAGEIIRTVSAEGGEEFAKSNGCLFMEASVKTAVNVVAAFDKTTERICEKMGYGDVEEVDEALEINMWNWKGFRIGKNTGVK
->ERR1700728_2000873
-GTAPLFSASQAIGRLLPCEQAHGASAHPAEPFAPDEERTPGIRCSCGQFEVANHPRALAHQRCVGSGTGAAPAMTAQRESTVTDLLLLQLIRLKGLVDAAGLASSTDAPVEAIRSTCAAWAREGLVLETPRGVRLTATGRERLADLLEQERAGLDLRALQAVYDRFGEHNGKLKAAITAWQVRDATTPNDHS
->SRR5262245_41074620
-GRDLVREDGRRGRGHAQLGRGARRGPVDSIRALAGARAHGVREPPVAVADRRALPPAELRPDGRLLGADRPGGRQPQESIHPLRRAAQSVPAARRGGWECFAMNDVNVAVPVLIEQSGLEHQGNGRAGAERLGKVAAPPNKESTSEFFHFWVEKGKLCERTQIVTTSSQLGGRTVEFVGLVEEVYRQSRQRDMGEEVDRFDADSAVTPPFASAGFTYAKVTILRTDPVTHAPPTEESTVYLGGEREAEKGYGVDRMGKPMRVGLLRNGGTPFAGPATIDLDYLLGENGGHLNVNGIAGLGAKTSFLLHVNALLLHEAERQITALGISHSGRLQVVPVIFNVKNYDLFFIDHWGKQWQKEKLTALPEWRDYLGINTPTPFRDVQFFAPEDEGGNPAKVGRTDEKVRGYSWSLSDIIEHRLFKFLFSEEDIYDANFGGLVGELEEELTDESSGAPRLNTQGGDTATFAKLLQWFRANRDTFTDSAPGTRGKLLRRLKYIVQEG
->SRR5262249_55421997
-XDQCANIEIIENFLRSGYDILRHDCTVTGSNLCHKMTAVRCANNGASERHDPSRVLPIQNHVIARREQSLEPIAESNALPTELVGSEHDTAQHRIQSRAIATAGQNTNPWPHVIKTRSERLGRIDESTPSRPLIVQLPPFIHQSRALSESVSA
->ERR1719460_1257335
-AMGLGYTKKNWDNQSGKEKYPASAMKYWSELTSCGCKNQQAAATKFGYTQLTWDNKSGKEQQPHSAYKETWSLLTDDEKAAAMVLGYSQTIWDDSSKQTYPASAGKYWSQLITCAPPATAAGDAAGDANIVEDQQDQIGEDFIIGGVIALAIVLVVALVVTIAIVAAQSNKADEYSEESHNANVLDKKTDDDL
->SRR5258705_15912
-PPFWRTWWFLISVIGAGIGIVLGVVWFLLSRQKNLFKQHALQAEQEILRLQNENLEKDICSKQAQLNASVLQSAHKNQFLEDLKANIQKIDSAETKSKSKELHRLTRSIDTELTQKNYWEQFQLTFNQVHQDFVHKLHQRHPHISATDSRLCCFIRMGF
->SRR5665213_2795117
-QSRSSAASDVYKRQCPKPPAMFVSVLLVVAGLSSHAQQPVYPVTCILSNGDRLSGDLISISKFRLRLQHVTLGRLVLKRSSVAVCETTDSTTRVKLGDLALDTLPENSRTTVGVLPDVMPLPPGSVAPVVSLEHLMHPPKPTPLASRALPTYVSHVGWKRAIGMNYMLTRGNANVSNLGFTGSVARRADRSQVALSAKREFGSQDGNATENYFSATLRYDLALGPNDSAAKSRPSFFSEAVVEHDPFAQIGSRAVENTGVSVPLTRNKQNDIALEIGTGITHEAPTGVPSYTRFGGLLRLAARQIFGKAKSDQQLAIFPDLSGPHGHYRSNGDFNLSAPLISGVALKLGVADRYDTRPQARVRKNDVTVQSGIGIEFX
->ERR1719443_2623778
-VHDFKRKRTMDKYVSDDSDRKPTPPLEAPRAEKGEVAAPQANAPASDTVAGVSVRGGFAGQRQLRDLKASQEKEGGGGTSKPRGEPLEEWTYSDYQNGEVLNPVNFDQQRDCGAWTAIALHAFQADISKKPIRVRENNQPQAVQKAKFSINGGPNDVINRDQDECMARNPFVSMYSDVRPNRVLRTRPPRTTLAVKKMGSVPAYTHRDAVTAKAIERSNARRTASKATYNEAAKTIQQIWRHYSDYLSSTKEWFLQCKMAAMQIQWTWRQYHVWRRQVDKLMTRVQAVARGFLVRRHIRKHFHIVRAQKICVGAHQRSKLKNMARCVRVIQRWGRGHLVRVKLRVFKGFLVQTVRVIQSYWRMRKANQEVALLQEEKQAQALLVKSAIHMQRLFRGWKGRQRVLVRQQEHAQAQLKAMMAVKCQGQMRGASCRSKVAKLRQAKLTRMNNAATYLRKMWLGYVQRKRHAEWKNFRVDQIPYIVTMQRIARGFLVRNRMWRAVEKEEREFYAVHKISRLWRGNRGREKWQRLKHSQLEREIAAACIQPVVRGWLARLSIRRGTDRTRYAHFELLKRRHLAALKILKQWKVMLPRIKISITLRKKQKAACTIIALCKGVRTRAMNALRLRQMCAILIQAHFRGALARARAEARFPRVREIRLAAVASQEICFPNRLKRKAFLIMCSGLSAPAWSTDLEVSKSKPAKTPEAKEAQLMLLEAVQRARAAGMGLIM
->SRR3569832_936138
-AMTIRSSAARCGRTLAVMIALHVVPVLAAPADQAFRQGLSAYRSGDYGKAMKIWLPLAQKEDAAAQAGIGFMYHRGQGVALDDSKAAYWLRKAAEHGQPEGQLMLGSLYFYGTGVEKSYVKAYAWCDLAQDGGNADAQMCRDAALQSFKSEDDVKAAFRLSLELHQRFRRSRRAARYSCLFFLFFSVGFSVLPVI
->SRR6185312_8416935
-TMWLLVRASHDERLRDSSLGWAVLTAGLAIGTKFSNGLVMLIFVPLVPWLYRRSIFSKGRLAIPWTLYGFPLTVFLPTILSWPWIWQDSGAHLGETFGHWNNYVVNELFLGRTAPAPIYYFLVAFCFTMPIGIAPLFVSGISQMFRPRAEALLRPLPPGSAFSARGWWVFLTIWLAVPFVWTFAGMRQDGIRYVYSAYGPFAILCGAGIVALGRGVAALWKNPRARYATAALTAVTACYLAVADVRTYPFX
->SRR5919199_676836
-RKWRFNAEEVGKMRRIALEQAQLATTLFALFSIIRFSTGVGHPRQHLGIKSRLQLKTEDEGRELQEMSVIAICGEGRIAVSALRYTHHLLLASIPNIRLVACPNYSDRGYDTWYPSLSKAARAMGVDVVELDSLAAEQDLLLLSLEYRRIVKVDRFASKRLFNLHFSRLPKYRGVYMATWPILNGETEAGVTLHLMDEGIDSGPIVDQRSFALPSHITARGLYETYMDEAFELFKENFLRLIYGDYRLIEQDHSKATYYAKDSIDFAQHTKLDLSQPASRVERTVRGFYFPEYQLPTLENRPVRACHIIHGRSSEQPPGTEVCNTSIGAIYVAGDNSLVELVWAXX
->SRR6185312_187726
-PRDVFPEHRSRRVAGYPEGVVVDTMRREEQPILMHAVMFEIFAVPLADIEEAVEAPQDAREDDRLGQADEHAAPCHELRVAAYEDGHPGAPARVRRLEIGPQTPARHDEGIEAAVGDLARDPGRIAAAKVLGRRPGCDVLEELAV
->SRR6266851_1047964
-NCGLQVISSGGIASSTTVLSGGQEQVKTLGHALGTVLSSGGVQVVSAGGVANGTIVSNGGSVIASSGGTAGGTIVSNGGSVVASASGTASGALISSGGQEIILAGGIAKSAVLLSAGQELVSGGVASAATVSSGATLNVAAGGLVSGTQLSGGVTNISTGAVASRTTLFSGGVENVSSGGKTVSATISSGGVVNVLSGSHVGSSVIFNGGIENVLLGGVTGKARISSGGVQNMFGSTNNAIVFSGGLQNVFSGATVTATTVSLGGSTVVSSGGTVINTTIASGGTLELQGGALVSGTTTRVAGSIERIVSGYGLNNFTVQSGVTLQVGAAGAASGTIVSSGGAENVL
->SRR6185312_1756791
-XMRAKPLCFSPASINGTSCCLSPEKLRATKVAPSVIASSTGSIGGWKLVSPFFALVPMSAEAENCPFVNPYTPLFSMMYSMFRLRRMAWQNCPSPIDRVSPSPETPMKLRLRFAALAPMAIDGMRPWTELNPWPPLTKYAVVFEEQPMPESFTTFCGSSDSSQAASTIAAVIESWPHPAHRVDSAPSYCRRVNPSAFLGREGWATLGFARNVMWTPAQRYAPAPWAVLGSALSSLRGRISWSTPSTMNEEEM
->SRR3954471_24146024
-TGARRRRKPGPGGHRAVGVPAARAAAGLANRSDASTQGSPGMIQAQELLRRLADPGHDMVITPILDARQQIGAASVDLRLGPDIIVSRRATGTTAFDASDPQGFSRALQERQAYVRRRLGDTFHIQPGEFVIARTLEFVRLPPDLSAQALGRSSWGRLGLII
->SRR5690606_23903138
-LEPSVITVESPEHKFLNKLMGVIEARMAESDFGVEELVMEMNMSRTVLYKKVQSITGFSVGDLVKNMRLKKAAMLFSQTSMNVSEVAYQVGFNDRKHFSREFRKFHELSPSEYIKKVKDESLNGSDL
->SRR3569623_980461
-LVDLEVRRHKKKNTGQHHRMAAVVQGLRMPVEALHPLQFGLEFGALDRIAVRRIEAGHDHAFHRGFQVAALLVLWIAGQAAAAFDRFRSFRQDRHAVPRSLAVPETVVALRLDGRDGELLVRRLQFLQAGDVRRLALQPFEQVGEAGAYAVAVERGDAQGPGAFPGGFLYRGHRQCFFVAGLDSAGFSAGFAAGFAAGAAASLRRDSSSGRQAISRSWLGAISAPSAASGARVARAAAATPRISSGPLFTPTSGFDSVPRTCSGERSESRRRRLACGCTVRSSFSVPRSMLPSTVISASSVSMLNSRGVSTPSFATRSAAAQWMR
->SRR5262249_45364707
-TVEVEQPALSDHLRAELAVGERGVGEFHVHPEVACRTVGEANNGNGAEIRDPMVAVARDARVDAVGLAADEPAEKIEVVDALTHEQAGLRVAVPRAGPDDRLRPRRGKEGPDPHLAGAADAPLVEEALGLLVDAAEALALDDHQLHPSGGTVS
->SRR3990172_9952057
-RRGKEKRRRNARLIHAGILGICTSTASTIPRYSQSRAGKKRRCLPSGRGGWGTMSSEGVQTVMPVDASPIHLNPQAGKFESIKQTTPVCFHDPQTELGQLLLGLVRVRYRLPLKPELPCTAAAEALDQETLARGIFLPVHHPDRVEAMVSAVAGKILAAGLGSRLFLGLIAGLFRQLHGSGRSWIDNTVAVEVDIGPGDEETQWKGTGYPETTRVEHPPWHGGCGDIRGLQTLFSEIEEXX
->SRR6185369_2406511
-FWASTNGGVDWTRYPAPDGSGQQFYPPYMDPYDPKHMLIAGHGSDLLAETTNGGMTWTKVTQAAGMAGGATAEVAFIDNGDPAATRKTWLWLATGTGGKIGTWRTTDGGVTWKHVESNEHVAGSTQVYQPDTKGVVFMAGVYSTQGAGVLRSTDYGQTWTHVGRNSPETIVFGTARSLYALYGVGLPADVGLEVSPVPGTGTWTTPGTPAAMKLGPAQAAILNDGQTSIILLAN
->SRR5258706_8531874
-AMGFDLRSRNSQDRAGATNGNECDQGEPHAHATIETVQCRPPSNGRNVVSAQTQGAGPSLLRRGTRVLWRFISLHPLPFSAAVTGSVVYAITSVIGAGVLGRVTDRVITPSFSSHGHVRASTVWFYAFLIVLVALLRGCGVVSRR
->SRR6266481_2504579
-TLRRGNDQNSRARQGRHPRRRYRQGLRAGPDLSRQPDAHHRLSLQRSDLSVLRGHDLRCSQDFSRAASESEIVLESLANQIQESMMQSSPLNLRRAIIWIGRLVLGGIFVYAGLSKLLMPNTHLWPMFVLRFSISMNISSFAQQVESYKLISPDASQVVAHTLPFVEIVLGLLLLIGWRLRIWATAITAIMVGFLAVVTRAYLLHMDINCGCFGTPEKLNGMTVVRDGAFTALALAMTIFAFIEAREPHPWSAPEKACAGLAAMKTLAEYLDLAAVAHGHLCAGQVLGVRLAMLGLRELGIDDPVSERKRIVTYVEIDRCVTDAVALVANCRLGKRALKFRDWGKVAATFVDLQTGRAVRVAAKESSKQAAREMFPELGKDAGQQKAYAQLSDEILFDKQRVKVEVQPEDLPGFKGPRVVCAQCGEGINFKREVVVKGRALCRSCAGEKYYETLSX
->SRR6185312_10010982
-LLTGGSLNQDHIDILQNSMKPFGSNKDEDPPPDSTSLISSSNASHTELKSVSTIISAFKTLPKCVSLYAQHYISIDPANTDRLEPKFTNYGEYYKGTLDYIFYLGKSNNNNRDNIERETNEEIEMQVVKLLKMPREMDI
->SRR5437899_3944324
-SDVCSSDLNISCGRDLRCCRPSGLSRIRFLYDGLALFWSCRRRGNIRRTGEIMRQQAHNRPERIAGHGSLQTLNPSKRNQRCPLGDPSQANLEFRFLRGPREDGRATKARGRKSVGGTPTWPAVGSRLPPRSVTRHVSLLAAQTTQWRRSDGX
->ERR1712112_183966
-LMFDGIKDHPLNFGTLNYWVLREWASHCLGQDTREVGICPLGEKFAFVQALDPEGEHSLPSVHVCHRHTEQYPGYVGEVYMDGEVMDWETYQKRTGTLYPVQWSGYSFYLDDVGGSLQRVMVDHTVQYPTPSAYGMFASRALISGSGGDFSLGGVFPTVHVPTRPLDTSRDMGKVVYKKSPFSGDAAVLQELTENGYGFLVDKEEGFIYYSNSVAVAKGYPPVASALGWHKVPLRPLPSDWMVQLDQGQMAIGIAX
->SRR5437660_607594
-RLGPPLPDSRRRRRSLLAPTGEGLDARLQPVRARLAPQAELDPRLLAPAEGLRPGRGAARGQVARALQPRGPPVVGRADVRARADPPAVPQAAGLSRQLGPGSLPDALPAVARNACLAPADAGVVPADRGARRALGARTPVVAAPGGGATARRGGRGRARSGGKERGARGVPGAATIAPGTGRSAHAHRLPVPDAVLRPPLGPARARPVALAHARASGPQAPPPTHAHALGGVLALARRSPPGDRDDPGRGGNGHPPGRGLRPLGPGGPRRRFGVRAHPPRSRGAWRRQTALAPSLLAAPFGRRVADTALAHGALGCGRARGRGSGRRRARCPRRDRCRAFAARVLRSDR
->SRR5581483_1442169
-RARAQPHPHAGRLCGDLCRAGHAARLPRPSRHLHGAHRAHRCHPARPQPGAHGHHAGLPQRGLQRHQRRRRALVAAVGPDRLVLRAGGGVGAPAETDGVDARQGAGLAARRAPPRARAATARCDRPLGLCRLRAGPGLRRGLAHHQAAPHRLRRVPRHRGHGARPPRPLSPGPAAPLRAASPRVASGILGIADLGHPRALPRFRHARAMARARQLLAVNKPATVAHPPGRRVAVPRTRKTLGWRVGSTPPAADVAADGERPPERGLDLMQQDATKAELAPMTGAARVRHLRQILLWPVQLLPIEGDLQYWEHLAKGTDPSPWREVDDEFGDPTEFQERHYNEFVTFLPPVQRFLYGQGVGKAVRRIYGESPIKTMRRTDVATARVTLSRGDKPVELRIVHTDLYFFFDIDIAILAMEIAADDLPLPVAQEAVFRFGRAYPAYX
->ERR1712159_470442
-NGAPEQDRLLPDETDLLSKPLHIELAKVGAVEGDGPLVRIIKSFHQLNRSRFTTPTRTHERHGSTCLHLEAVSVADFGVGAAWVTEMHILKHDPALDAGQSFALVTMGIDHRLSVDHFENSLGSFTCLSHRCEPWGNATKTLCSNLQAKHRDQDVAAREVTCRCGETATVLTRAVSGVLKLLRVFDGTVEEAECAHDVPGGKHET
->SRR3546814_65869
-YCVFFHSFLLLFSLRSLLMCSLVCWIYTFSLLLFFFFFKQKTAYEMRISDWSSDVCSSDLFAGFVVSTQSVSAPGVQFTGVVCDHCADDSDGTCDACQSLCLELPRAVRVRHAGVLIAAGVRDFFAAKPAARTVTVVHPAAGRIHGPRAGIRDRRRARAALAQRAQGVWRGGCAGRGRRCRDCDPPSVVAVIAPRPRSRLRPGAGVHAX
->SRR4051794_20208749
-PGQYGVVGLARNVDSMHPKSGGAKGLNAKIRNTLLCASAILVLTTVARAQPADPIGDLLAQAQTTPAMPPSLRQTVAHPISSADQALFAQAMSAAKRGDVSGARNAIANLSDPIAKKTATWWLVDQNAESLSFWEVDAA
->SRR6266852_3879948
-XMGRLNANQPRELALTVSKNLASYADGGPELGVRFHLFLSFLQRSRHVNENRYRSVFMSIRDRSIRRSGLLVRTAVRRPSSCTKARRVLPNSLAQNEFPIALDQGRTWX
->SRR5215204_675534
-GEIAGFEEAAAAAPAALAAAPGAGDDMRLGVREGAEALHDDGRWGVLGEVGHGARSFWCGAGARNPPGAPGRVRLRCQRARVLFRPPGEGRWDAGGPAGLGLNAGHDRRPTRFLPGFPVPGPGFHDRLDPTSRALRPRRIGENSAPSGQRGRPVVAGEWCSWG
->F2U329_SALR5
-MMMGVAPVIACCLVLSLLALGAVAQDVDVTVYPGRLFRADLSLQFGAAASVEAIATLTGNPAPPAWLRVNLLPIIYGQVPDDIAGDRFSAAILLRINDQPVTRTLNLMVDRTQGLPRVAFEVHATNANETQLVGDRYDDLETAVGITRARLSADTGQVGSGVLFVRSVAPFETDRRNINPMTSNPPLPVNNAYINGTAWLTLGSKLSDSQLTCAELEATAGSLFAAQGLQLDFDLCTPFPISTNATIDRSRVLATVEMRTWARTKDDFNETIIPASVIAAFIFFPFALIFIIHYFARSSDEAIEQQMHRLVKNMLRRNRAHTLRVISDDNTIAAAWLANSEEEEVVPPRLSTVSKPSNTSLPTSEHSRNLRYRTHTRPPTYRPPPQHDF
->SRR5919199_6745454
-RVPKTTDGESHKEEETHSSLDFPSRLCYPGNIITCRMGQNLLNYTTEIPVEKTITEIQQVLVKAHATSILTEYDNGAIKAIMFKIRGKNGQELPFRLPAKVDEAYQVMYGNRQQWEVRRYGEKWQQHARRTAWRILLTWVKAQLALIELELAKPEEVFLPYLLVKGNKTLFEDVQDKQFLLGSGTEEX
->ERR1700761_7736419
-GQRFDSAQLHQPSLAMRAKAAAAQPAQQAKTGCRQVRKPARSALQHPRFSALGALPMLFPVIDSLLYVFNTVLGIYEFVVILAILVTWLIPAGVISMRNDVVRSIVNALDALTDPVLRRIRRVIPPIGGVDLSAIALLIALEVIKRLVNGYAPLLYTVX
->ERR1719296_360158
-THRTGPLADCVAWPSREGQPQALLRRAAARQPTALRAGTRSRACSLAEAESFSTGATCEAAARVAATEGAGAIVLLCRRRRRRRRRRCGPRGGEHAADVDGNLGCLLLVAPKLGNVLVAEDVQRTFLELAPIVLFKCD
->SRR5262245_40312332
-AGRRDRTFCSGERPAAARLRLPAAGRGAQFLYGQAGGGKMPFNVWGRVKNMTRETKLGLVVSCSFLCLLGVVLGLKMTEPPEEDQGAEVAATEPAEGPPAPPTGAQPDTQPRPAKAADKSAPPAKADTAPPPLPPNVNNAIELTAGTAGQKKAAPG
->SRR5579871_2118101
-ESTQDPGMSDLELPPEVTLRAAPLLGDRRKVEQDRPLEEVRPARELVDAVQEHGALRVEDRLGVVRVELPRREASSGGQPAERIGDPRLEPAQVVEGKTPRVLRGDREIPLLPRQATERGGRGVHTRPEETRRRALGAALLADQDYDLVRTTRSKGRNEPANEEDEVVVAGDVDEPTKLLNGTTASRAGERTHSSGPTEPYERHSHDPPPLLRHLHAGPRVVSEVEVDRSFVLGEADVDLALRTAERGFALEHSRRVHDGLTPGRLLRPVEVKLREEPPELLRAEGPRLAMTAASDRGVTDAVGVVEEFDTSLASELDELRRNGPAVLLLVVVGGTRAAPRRLDPLGSLLPRAELRGEELEERLLEAARPLGRAP
->SRR5256886_992629
-MFAQLSYAQAPNGTIPATFFGMTFSGGNAPSEYAAQPAAITSSMGTMGKESAAEWSYIEQNAPTGSGCPGTTNCTHTYNWTVLDGYVNTAFNHGLPFMFFFTEAPPWATNSVGCRSIAPGQACRGPIVSGHTADQQAFVTALVTRYGSKIGSYELGNEEDYQGTWAQYAAQSDLYVKAIKAVSPSALIVGMGWDHPDGHYAQGGDFDQFWSAWGAIPNNSRHLDVVSFHGYPHTFCAPSCVVPEIVISNNGLGTQGSGDCATTGFAKCAQNAIARNGVTTFTGGTPLLRDTEGSWGTTNYTIPAPAFISRMLLLNWAAGVSEHQWSYPDGGSVYGQLDGITANISAYQQTYNWMAGSTMTSPCAIQSGTVWTCGLTESSGKSALAVWNTAGASSYTITAGAYPDYKGLSGNTTTIASGVTSINIGAQPILLERNGSHAPRAP
->SRR5688500_8464034
-AVELDPGSRVLLMAVDRWVQLGAKDKARRTLLNAPSSTWENVPRTQGAEALLNMGESKAAAALLRGAPDSEQEPAAKLALARVLTANGEFKSARELYLIALTKSPYVALETRIEYFEFERLHGSARDALAAYDKLRGEGFAADSLARHRLSLFVSRPGLAWAWRDALGVLTLLGVTLAFCIMPLLIIVPVHYRGLALRASGRAPAREGTSWTLLDAWYASGVFLLVGFVCSYVFALPYLE
->SRR5215218_300340
-SPATSPRDSGAARWQQRSSSAAAFPLAPRNSTTGSPKNVRPTGAWVRSFDQLAAYQPFFGNCTRLLRGFGQRYLCFRSQGTNRFCTIRNLGLAAAFSKWGRAAGSREAFMPAYRLRDVAVLVGAVVVGAAAGFNGGWFAAVPPKVVTVDAPNKLATGTADTRTPATAPAPAPQAPPPIQGTAAPVTPAPPAAPAEATPQSDARNVRVIRPVEQANEISATARQ
->SRR4051794_31039054
-PGCAGSPRPVHRRDDPSAVAAGPEEAEGVSRVRPVGRGARAPRGGWRKERRRLTLGATGVHAMVHQVRYSVWVALGWIGVYMMLWVALAMVPVLGLFLEKKSPWGWAALGVFLVCWVAHSRQYWRRLFDRTPQIEL
->SRR5688572_28435885
-GALLPIYFFYDSAPSFLTLLLDTNGAMLGSILIFIGLRKLAKLLDIQTHFASPAVLASTLLVFLLLGLLFPENGSVSKNAVVQFIAQVGPIVDALRYGFSASLVWVIRKNANRTYSWALGWFFVALLSNALNTALIALDPLLMMTGLPVELLSMPFILNTFIFAIAGAAFYKMAHAAPKPTQDAGVLEVVMFTASLTSKPSDVDPILDPVRKITARHQAGDFTPQEIATLSGVYTKLEDYLVTQEPLRRVTREHLQAMIKERFDWSPSAAX
->SRR5450759_1044538
-SCATATTTEWPVASRNVTRPAMKSAETTLPNPSGVRATPWMWLITVSWLGSSTSVVGIPSRLRELGATDPATPAPKYDRTSSSPRHASRPYHGEKWRPRFAVQMRVEGRMDESFRANQRKPLVVNVAAVQAGVGAGSLKTIKPSVYPRPVGYDEX
->ERR1043165_7129941
-RRPAGGIVPWLARAGDQTAFAGGALGTETHIFRPGKVLHRLEGVSTSSFDASPEQLRAAAQKAHAALDPSRPRFLYVHVMWMHRPLWNHPAYHEALPELDVALGALHAEIGPEALWIVTADHGEEYGEHGGSFHANTLFDE
->SRR5258708_5362479
-GRAKLRRAQGHALCPLAAQRRQPAHAALVALPAGGDSFARPQRLALAQLVEPRRGGALRNQNSLRPFVEAGIALVVLAQRAAVEPQGAARQPRQERAVVADQQQPGAVRCQPLFQPFDGGDVEVVGRLVEQQDVGIAGQRTGEADPPSLAAGQRRQRLAGTDPDLVQRRFDQMPVDKPPAHIFGGREIRIERRQLRRVGDPRAWLPEHRPGLQLDLAGQRLEQGRLAGAVAPDQAYPVAEPERYRDAGEDRPPVELNAGIAQSNKRRRGHDDAAAGSTRVGESPAGSTTYNSIASCPRRCPSVLGKFRTQLTAHAALPLTLWRDWSWXX
->SRR5665811_2613661
-RSTRVRSSAASDVYKRQPICRSAARVRRSSDFCHLLTRAIRTKSVGSSMKVQAMAPPVTWSVSGEACQLYIGCLLYTSDAADDLTRVDLGGRRIIKKKKKKKKINKYL
->SRR5256885_2171212
-VRGRRRNGAGVTGGTRTGAKARALEPLGAKVAASPGEAAAGAERVHMTLPDDVVVDRIVDDVRRHLGKDAIVVDHSTTSPRGAAARIPRLNAAGVRFLHAPVFMSPQMARDGVGIILVSGPRAVFDDVKPALETMTGDVWYIGEEPDRAAAYKIFGNSMLFVIAAGVADVFAMAKGLGIAPADALAVFSKFQPGGVIAGRPPNPSAPANFVSRRARVIALAHARVIDGTGAPPREDQTLVIRDGRIADLGDAAAVAPPPGAAIVDLAGKSVVPGLVMMHEHLYYTTGPGVYGQLGVSFSRLYLAGGVTTMRTAGNLNGIMDINIARRIAAGEMRSEEHTSELQSPCNLVCR
->SRR5437016_5746367
-CLSPAYHPVRSTAFRMAIRGKAQLDTRVSVEDNPPRLSSRTICLTQVSNLLGKSSSSAARKKEVGMRRALVCILPFCVIAFSAFAQDAVKVDPQHYKVEFENDQVRVLRIHYGPHEKSIMHAHPNAVAVFLTANRSKFTLPDGKSEERSWKVGDARWTPAETPARKPDGSAARSSFGRAKKVAGFKNTHARSREX
->SRR6266481_1587377
-RRKPRRPIGRSASGQAAEVRDIRPSVDMPVSGAKAASGNLLFSPSVTSLARLAIESGCELHRNRSIGGNLSHQVYLTRAVVAGDAAGVDLRRQATGLRRWQAAWTQGPQYCHRSRRWKTSQGSX
->SRR6185369_7209777
-IVLGDTACPSSSCGRVNAQRGRTTMDLPSKTVFEVLLNNGVDTLHHANSVITSCQFLRQKSLLSRGSAERSGLKQTSQSSDATDLRYSLWYDVFMDSVDIHRRARKQNHYGPVLFLLDVEKLAATRTGRIWVTKLNPTKWAGVPVEDRWFRSKKELVTGFRRGTFDQMIVFRHSGGALPLADCLDEIILDDPDLKVDGYDLCSTAHGALTLAMSDFGLQVPITKRRCAPTCTCGHYYGSTNADIKDGVVKMFFPYQ
->ERR1719183_2396889
-LVVGTGPRRPASRRKAGRMSALARHDDGAGRETAHSLAKDGGCPPAAPYSATTHEGGTAVDVVQYGADAPPGLTRPIGDPRPVSVSSGSAQQRSGPSLQSRAGTGASSLDSRSSRSSSSSSSTASGWSSVSSSSSGSWPDDEYPPPPPPPPR
->SRR5438045_3528744
-PGAVAHEVAVAAANVGQAEREDPVQHPEGPLAVQSIEVDDDLGIARGVKLQSRGAALFAQPAIVVDLAVEDDAGAAVDVPKRLRAGGAEIDDAQPAVAEDGVASSCDAVAVRAAMREGRVHRIDPRANVAARLEHAMDAAHSVESDPLGDLVXX
->ERR1700691_2800241
-HAIVVGIGDIVERAVGIESFDLAVGFLEDECTAGLLGEDAVVAGLGEVVAASAIGLEDTLFTVGHVNRDGPVGRDREEILPVVGPAVSQRSERVAGADRVKKRPREVQRYAARYS
->SRR3989338_1552555
-GWDERGDDYKTFFFVRIAKQSEQRKIFIKEQKVFLTMEEYMLSNSTAQGKQELLAPLLHQNSDDTLFIRAFEERVARTIKTFGLLDGKKNIVVAASGGKDSTAVLYILSKLGYPVTALSIDTHIGCYTEQNKRNVITFCKTHNIPLLLKDFNTEFG
->SRR5215470_13194424
-THVRCGEPLHLATEQSRGAAGEQAAGLTPCPARGWMGEACGGTPSFRRPGPRADEHACKVMGLSLVHQGEVPTRITLGTAPGKITCWYSGGTLAGRTDPGRRERGCPALATNFGQLMTPRPFRSVCKSGLA
->SRR6267378_3904149
-VLRLLNRLHELKLSDEELAKVGAAVGSDVPFFVYGGTALVEGRGERVRPLSVVAETWLVVIAPSIDVPGKTARAYGSLTVEDFADGDHTKQMVACVDKRKNVPAAFLYNSFDSTKLGISLATRVYAGL
->Dee2metaT_26_FD_contig_111_7158_length_345_multi_4_in_0_out_0_2
-MDTSKLKSNLNINMRLINLDNIGEISRKNIRKFISTIYGFKATTKDLKKIAIDMGLDIGKRKDTQKTRTYKFFGEMYNDDIEKKKNISQQLDKQIKILEKKRGKTYTALDLNKDLLTKRPFKNMFKSSKSKRKPFSVNLISRVVSNVKLSTNFNNYWQFRNWLENEEKWNGMEMNSGETIIKIGNEEAEVWDLFNMTINFIEGGKTWGENKKTITRNIKFLNYECKVLDPATSHVGDNNCGIRVLSKLLDIKLNPKSIRKEINSPAGTLINTEQLNYIYKKNNGRKNLIIIDENYEGEFNLKDTDYVLYKDNHYTAIIEAKRQNHKETGKKKQKGKLAFDIETRHTEEIIMVGETKSKVLKSTILSMVYKCVRGKKMKKTFTTDNNKNCCVKFLDWLGHEANNGRYYNCVAHNGSRFDFYLLMSYFTEEDLLDSKTQLRGTSIIGLQYKSHTFKDSCCFLTDNLNNLCNGYLITPEEKAFSKLTNIKIGDKTITNHQLCFYKPELNFNEFMELETKEPEFWTEYVKYCEYDCESLFLVWEKFKFQIDTIIGKMGEWLKKSVSLNTCNTIGSLSKKLIDANNGVKSKKQPTKEMQIIRNKYKNGNKWKYGVCKADYNEEVKKLKESGNELYEVGGITGKPNFRKYCEFMSNDEEKYEFIKNFKRGGISHSNQKGYHKEGVCGFDIKSQYPTALMNMKIPVGKSRWVENYEPTAYGFYLINNIKWCSNVKLFKPVANKKDDGILDWATNKFNELYCDSYMIKYLKENCGLVNFNVIKGLVSNEEMISNKLFGTYVDTLYKEKAHQDYLKDSNQEYNKPYREAIKLLMNSLTGKLVEDPSRYFKLEFKSNDEKTQSINNVKINKTDANKGINYWVVAGVMVYSYSKRLLWEYINCLPNKADDVIHIETDGIYFGLPNKDAFIKNLKEKNDPIIRIGRELGNVEQEICTKEESFFIGKKDYMIGEPILNNDKSINYNKSKIRNKGIPKTTINDEGNKIDLLNKQFYIDRYNGKTCYKTFKTIGKALYDTKHHSGITLTGYDMVRKSTPHDFKNFKMYEEKDGKVIIKDWKKY
->GraSoiStandDraft_4_1057263.scaffolds.fasta_scaffold10840448_1
-DNNEAFTLTATPAGGQAATGTGTIKDDGTGDIYKADGTTDTSAVKNDDRVVAVTSPTVNEASPYAVFTVTGTAGQTVSLGLTAGTATGGGTDFGSATATTNLQYSIDGGANWLDYSTTGAFALPAGGSVLVRTPINNDATPDNNEAFTLTATPAGGQAATGTGTIKDDGTGDIYKADGTKDTSAVKDDDRGLTVTSPTVNEASPYAVFTVTGVSGQKLTLALGNTSTVSDKDAQLGTDTGNAGTGVPLQVYDPSAAAGAGAWVDYTPASLATIPSGGVLLVRTRIANDSILEGAETFTLVATNTGGTSAEGICTIRDDGQGSIYPDNKTGADDPAAVKDDDREPIAVDDTYTVAEGGTITGNINANDTDPDGKTLVGSSVAVVNGSTFTSLTDSAHPIYTAADGYKQLTLATGTLYVKSSGQFAYVHNGGETPADSFTYKVSDGSELSVAAAKVSLAVTAVNDPPVPGKLPGGANDPAYNASAGRYEISTPEDTPISGRASASDVDGGPLTYALTNQPAKGTVVVNPDGSYTYTPAPDFNGTDSFAITVSDGKGGTAVITVFVTVTPVNDPPVPGKLPDGAADPNFNPAAGRYQTTTPENTPVSGRVRAYDVDGDPLTFAKASDPQNGTVTVNPDGTYTYTPKPGFNGNDSFTVTVSDGKGGTATITVAVTVTPVNDAPQGGKLPSGAADPNFNPTAGRYEISTGQDKPVSGRVSAFDPDGDRLTYTAKTAPANGSVVVNPDGSYTYTPAPGFNGEDRFVVLASDGNGGVVEILVVVRVSAAPVNTVPNGPMKFRGEPARVVGPDGSVFRVADADSSELTVELSCGHGLLSLPVRTGLQIVKGTGSNDTVVAFRGTKESINAALAQLVYQPITGYFGLDTITITSVDERGNSDRDQIDPPFTVELVTLGGNDANASVASLAAQGKTVVGSAVTSFDSTLIKGAQVVGDGPVGRLAIGTPLRQDGSVQETTVKVELAYADGSKETFDVRVTIYNPKLELITQLRLNPQTSLYEQRVQVTNTTPFVIDSFRVIVPTLPAGVSLYSRSTTTSDGRAAIEDQRPLQANEARVFIVEYFAPNVQRFTEPVLALEINTSGGVSTPIGTNSPVDRVVVGANNRTYVEFATQSGRTYFVQYRDGANGAWQTSPVAVNGTGTTIHWLDEGMPKTLTPPTAAREYRLLVTSGIATPLLITTQPQSTQVASGGATTLRVAMGAGGPYTYQWFRDGVAVSAATGASLAISDATLASEGDYHVVVSDGRSSIQSQTATVSLASNNPGRIVNLSVRAQLEASGTPLITGFVMEGAGSRPILVRAVGDTLANFGVQTAVRDTALKLYRGQSVLSENDDWTRDSEAAQTRSASANVGAFALAETAKDAALVRRLLAEPYTIHVDNRTTQEGIVLVEMYDALGAYDSGNRIANVSARARVSSGDGVLIAGLVVGGNTTCRLLARVVGPTLSSLGVTGTLADPTLELYAAGGSTPIATNDDWGTVQGAVLGERLFRRVGAFDLPLGSRDSVIVTRIQPGAYTLVAQGKGGAQGQALIEIYLIDX
->SRR5450759_2854005
-HSVTNDLPEKRYILDERGAVIDQSAQSLSLPPPILTRSAPLLDSGSVVGRFVTSRSLVPLLQDTALVALFGLVLALAVYFSLSVLPLRALKRTLGALVQERERLRAIVDNAVEGIITFDPQGKLQSSNPAAGRMFDYSAAELVGRSAGDLLPEIDMANTDPAGRQAHLGTQETVGRRKDGTRFPIELAISQAIL
->SRR5919197_598751
-AANPGLHGILFDTAEGVGDARDVLPERAEIVTGDFFEHVPGGDAHMIKSVIHDWDDEHSITILRRVREAMQPHGKLFLVEPVLPDDHEGLARSKVTLMSDLNMLIMLGGRERTEGEFRALLTAAGLRLGDVTPAPPGSFSVLTAGAGITKGRAGGLRRGPPRPVLPAALRRRARLARGLAGRPGRLX
->SRR3712207_1410375
-XMNCKKILISSLLISFISCNLSTDFEPITQEEKSNYLGTRSQQSLVIFEDDFEQTGRIPDTTKWSLCPRIEPAWGKHLSESYDQAFVENGNLVLLAEKKEGEYKAGGIQTLGKFDFQYGKVEVCARFTKTAQGGWPAIWMMPSIHRYAGSSWPACGEIDIMEQLNHQSIVHQTIHSHYKNTLHFYLPVPAMISSYKRDEYNVYGLEWTPDYLIFSINGQSKLKYPNMHFASEPSKKQWPFNAPFYLILNYALGGPDTWPGEIKDADLPAKMEIDWVRIYSHTLSEHHITSGDTYNILTALNAKSAVDVAGAGTTDGTSVILWHGNSAVNQKWIVTELDNGYYRLSPVYVPDQALSAPLDSSATNQQLEIRTYKGELSQQWKIKSVGNGFFTLSPASSPEMSMDVIGEETEDGTSIALWKTTEKINQRFMFKKTRXX
->SRR6056297_976187
-DDVGKIGIPDAILLKPGRLDDDEFDTMREHVDVGVRLLAQGQSELMVLAEKVALTHHERWDGSGYPRGLSGDEIPLVGQIVAIADVFDTLINARPYKPAWKLETAIAEIRRKSGRWFSPRIVEAFMTVLADQPELLARLERESWEDAQNGRLLGTVVAERRKRRHLAVLEAELPQARPRGGRDLGRRQDAADRRPRRLAHPPHVAVELMDGVVAGSAPLELDDHQTPLAVASVQIDPAHADGKLDLEQDEAVLDQLGTPGQRPLHLGLAAVQEQAALVAWSQRQSERGVEERHANQLGGRGSLRDQHGPSRLLDQLHRVDPRLPVQRLDAARRVHLQAAVRLEQQQVVAGVGGAGRPPVVDDLHLAADLEPAARLRELLAQEREQLAGAWLEQLRCDHGPDGTTGPGRHPRPVPCRHGTAWSARIGIRRRREGGGASRRPPLRRLPDLRQEPQPLVRAAEVRGGRRDVPRAAWYRRSTGGGARGLPDQPREPQAGGGPEVARGRSEEHTSELQSLRRISYAVFCLKKKKKKKKKQKKKIKIKQKKTHQQKKRK
->C1N8J1_MICPC
-MHAVASTPCAAAAAARGRGRRRRPEDAARGGGGGGGCENASSWSSSCRRWEVAPSPRRLLATPRRATPRLRALRGDEWKAIAPPGFTPSALNLSYDEHEADALFERVTEVMDEVDVDAQSAPGGGVKLTASQKRALDAFWLSCGVASASHRASLVREGGKRGLFRDPRRVVERVTELEDSLWRAVGISEIDVGLCVGRFPKVLFFEPDFLIERLRLLRDLLPNVNLRKVIERNPQVLGMDMTCTLPAKMRELSVLLPHVDVIHLIETHPKILSTNVSGNVAGNLRQLKRLMSEVGVEDIGVEMMVTRAPRLLTSDVDGTVRERMRAIERASPGTFRRYADKPASAARMLCASEKVIDRIAFLHETVEEGERGSEIAAVNAPAGTFSKKHPGFEAWQRERSKARERERSADTGAL
->SRR6202050_3633006
-FFYGYGDHQELHSFPTRRSSDLGRRQHSHHGYRPAIKGQRSSHNVRVRPEKRKSTRLNSSHGSISYAGFCLKKKNHHSHSGVLVQSDLLARDTCHAPNACSFSMPKENGPSVVCARSMSQSSGGPRHRHGSPRPRSSFFPDG
->SRR5882724_974133
-ICIGFGLNIDDSGPATPNTNTLTVQLDGVTIISNGTNVSSGTATVTRIGASTAISYSQSALLASLSSHTVHVTFSGTGFSGTIDETRNFTVAFYPTLPVSVRTPVGSGSQPGFRVKVWQINNAFSFVNGWLNRIVFDEQQLAGLISTNTADLTSFTNNGSFYESSTINYSLTLASGFIQPDAALPGVPGSLTVNDDVVYEMLSFVEFPTNGLYTMGVASDDGFKITVGDRTGPDVGLKVLAPASVAGRYFGVPTASDYGDAFGAALPKTPLVARAVLCDLPWPPSLPNNAAALSNNIALLHRDPSGGVAVHGIWAKQAGAVAVVLVDQDDQGATVDQRGAGRLPGNWGGSIAGFTIPVVMMDYALGTNIFALATSNTSSPVIMSIGDDSSYELAEFNGGRGDGTPTVFNVNVPQAGVYPLRLVYENGGGGAAVELWTVSGGTTISSMIRVVWLRRIERAPSRLDQP
->SRR5882757_10675725
-XMTISDMSSRQAACAFSVPVSERDQLLGKRTPLKATIDFHPTIVREEQQLTSRLCSDQRVPIRLKGKLYNFGQLVSLVRLELMSRRVIQSAILAICGSPPSVEAPSLIRRGAFIPAVAADAEQEMQVCLGKNDAGADGEVVWSCLDADVESVEARPARPGAGE
diff --git a/src/alphafold3/test_data/miniature_databases/mgy_clusters__subsampled_1000.fa b/src/alphafold3/test_data/miniature_databases/mgy_clusters__subsampled_1000.fa
deleted file mode 100644
index dfb824c59b7bf072a88e818aec4baca30f982a1d..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/mgy_clusters__subsampled_1000.fa
+++ /dev/null
@@ -1,2000 +0,0 @@
->MGYP001379502932 FL=0
-KNNVKKNNANKNNVKKNNVENIIKQEDDSESNEKLMFKISDDISNDISEIYSYNVDKSKKVYKTYNFYILILVLFILFFIYINEDSSILPFSYTPTPSPEFLNSSTEF
->MGYP001093304395 FL=0
-MGVPVGVGVSVEVGVPVGVGVPVEVGVSVEVGVPVEVGVPVEVGVEVGMEVEVGMEVEVGMGVEVEVEVEVGVEVEVGVEVEVGVEVEVGVGVEVEVGVGVEVEV
->MGYP000080920170 FL=0
-MPVLSGLKPESVFSYFEKLCAVPHGSGNTQIISDLCVSFARELGLKCRQEDCGNVVIWKDGSTGYENAAPIILQGHIDMVCAKTDDCTKDMTREGSGRLAGRKWSGQSNPRRTPPFVRRAARSPYAYRRRRTR
->MGYP003331872083 FL=0
-LDYEYVATVFDLNASKWNAVLMEEYLQWIIDIFSDTHPDVPNFLFFFAIFLRDIHIDPIKSEHELILNQIEALQQQFPNKVTTIKRLKPIPIPILEDWIRDLGEQNQAVIEDTIKEIVASLPKEKREQYQNENQNLMLYIGSFEFVRNFS
->MGYP001589871100 FL=0
-REVKRAVYEALKVLSGSGSPEELLNSVIKGTKSVVGLKVNVYFGEPNNATHPAVAYALAELINKIGVNRNNIIIWDRAEDELNKANYQTNKSAKDVRCLATLTHRNPRFAKPFIGYEDSPITIGKAQVRLSKLVNMSNVIINMPVLRTYKFKDNTGISNAITNMYHVVDIAEADMPFFYDNECNPGAAEIYNIPAIKTRTGLTVCDAIYPLYNGGPGDDQRYHWRANAVIASLDPVALDTVAQNIIQKYRDKVMPGEQPLKSAYLETCAKAPYLLGASDIKQIDVIEREI
->MGYP000312263992 FL=0
-FSPFFNKNKKLQSLCDLLLKYAPDFDHKQLSRPVLHQKIFKTKTYKVTQINNLISDLLKMLYAYLAFVNYEAKPALGKDLLLEELLHKDIHQDVERVSRAFEKIQQHTPFENYDFHLNEYQRYDKLDRFFFTKGIRTYDENLQLKNDHLDLYYFINKFRIACDMASRNIVTNAQYQCNFLKDLLKHFESKHELLDQIPALQIYYKILRMIQEHEVEAHYQEI
->MGYP001087948731 FL=0
-MSRAADPLLFGTAGVPDTTPQTSTLAAVKRVRELGLDCLEIEFVRGVRIMPDSAAKIRERAAALGVALSAHAPYYVNLNSPEPGKRMQSQDHLLRSARMAAACGARTVVFHAGYYGADSPEKAMSAIRAELSQVISILRSERNPVRMRIETMGKPSQFGTLDEVFEAITLIQTRKMPPIPIVLFGRDYWEKAINFQ
->MGYP000560073095 FL=0
-RRSKGGSDFFQCLAQGPTQGQAKPRSDLGFRSRQSSVVMVTVAAVGVADNLATWLQGSDAAVPQGVDGATQTTRLGRADGRIGAQTSYELALRMWRAYQPWPGVWVEIPGVADRLILSGVSAVEGGALVAPGVLELRDDTLLLGLAGGTVRLDRVTPAGGKSMTGGEFARGRQGELAARGRIAE
->MGYP000244154749 FL=0
-SIVFNVGSKSTFMQRDYKLDVSWLWNVYVLVICPILGHPLFPLISNRISKSILFLQNAISSALIALHSCVFAIANIFTCATPYKVTPLHIKKSSLKC
->MGYP001210306911 FL=0
-DFRPTYNEEDEEPVVLPVRFPNFLVNGSEGIAVGMATSTPPHSLSEVIDALLALLDDADISNEALMRILPGPDFPTGGIIVNRDDLPAIYETGQGRIRIRGKVETEKGRNGHINLVITEIPYTMVGAGIGKFLSDVAALAENKVTNDIIDITNQSSKEGIRIVIELRKDTDVENFKNLLYKKTRLEDTFGVNMLALVEGEPRLLPLKRALQIFIDHRVVVITRRTRFELEKAKHRAHILEGLLIALNNLDEVIKTIRSSADADIAKTNLIHRFKLTEIQAQAILDMQLRRLAQLEREKIENEYKELMDRIAYLEDLLAHPKKILGLIQE
->MGYP001762835755 FL=0
-QRRAGRGEEGGGAARGREPIGETQAEVAMRNQLRTAVDRAEHDAGVVDLYGQRPAANQKARKDMNLLDVGRYTLAGNRLW
->MGYP001516588361 FL=0
-QMCIRDRINSTQEFAIFAESRNLNRNQNENGIDE
->MGYP001111298869 FL=1
-MITELRIADLGVINDANFVPGVFPQAR
->MGYP000402828031 FL=0
-EHILEYQNQFYYVGGKVPEKECVDKTENENYYLLTLAALAQEMRFRGLTDASVKMGAALPPRRFQQQKESFKKYLLKTKELHFRYEGGTLSCVVGKCVCFYAGACGDPYAFRSGSPVIAF
->MGYP001006094493 FL=0
-AVIPATDLTKSPEEAAKPEAGNDINTPADKAVVKDPAKLTDAEKKAIEDKVKAVNPGATVAVDDKGNATVTTPEGKTAVIPATDLVKSPEEATKPNAGNDIVKPADKTVAANPEKLTDAEKKAIEDKVKEVNPGATVVVDDKGNATVTTPEGKTAVIPASDLTKSEKDVNDGKAKDNAVTPAAKTKVANPEKLTDAEKKAIADKVKAANPGAEVVVDDKGNATVVKDGNVSVIPSTDLVKVQDDATKPNGGNDANTPAAKTVVKDPANLTDEEKAKVKKAVEAV
->MGYP003389908322 FL=0
-VSTDISSRYDAFLFIDETHALHPLHMQTIKDEDLPETFPTGL
->MGYP000520683910 FL=1
-MVGRNGGMRSGDSLAIVERKKMSASQRNKGQRGERELFGILSDLLGTCVRRNVDQARNGGADGLDVPGWAIECKRVESGFREAWWVQAVNQSVDTDRKPALVYRASRQPWRVRMFLHDCNPGMYCSHAWVEMNLETFAFVVRESLETETT
->MGYP000427244613 FL=0
-VDIFKISNVLNIGDIIHGDLDTKTITLPSLIVNDGINVIVPSNGVNKNIIGSDASGLTNLSFDKVEKKKLSFEDYGFVIDPANRLGIIEETVNTGNDNRQVTYLGNSAVDTGSIWGVAKTSNDGALWESVIAATQAGNIGIDKNNPESKLDVNGDIRFQTVNPITRLANGSSPTHVTLLRNLLTNEIEHYENTEWFTYRNVDIINGASANSVQSRIVNGRVQLRIFNLSNFTANQRFLILGPTFRPSNPMHAGALFPNNPADTSSFVNIQVRNNGSLFIDKDSAGLVYGGIITYDLW
->MGYP003153183859 FL=1
-MKHPIKVSPVSRKPVLRKKVKVGDIVTCKWGSPFGVVVKVLAADQWRIVEACRVRWIDDPHGLGEEFSADLKVISRG
->MGYP001561007815 FL=0
-IEKNTITVSKKINKDELPNGKIEITLKNINWINRKPNIGESLEARSRYRQTLEKIKIKDEKTIIFEKPQYTLSSGQSLVIYDGDICLGGGIIS
->MGYP001231096471 FL=0
-LKILLLGGDTGESEGGAVAKEDFGKVSGDDCPVSCPDDSLWGVFAGTAAPEIHSGNENGRPFVLGLVDRVIPGFSIGGITDIPEEMLAETVKGDAPHVAGGDDAVRVDIVPHHGDGSARHLLDGNQRHFRQRPGGRR
->MGYP001181966303 FL=1
-NTLTNYNSFYADEMNTTNRVENAFVQNAGSSSETSNNGLSSFHGGATDLPDMKFNKERNYDGGGTFLPTYDNGGMTTEHGMAMLQKGETVIPKTQNMLSGGGGITLNIGGDIVTNDAEDFAQRIADVLPEALRRQDDMGGI
->MGYP001558603255 FL=0
-MLCDNCKERDAVINLTQVEHDSKVTLHLCEQCAQQKGVETGETVLKSPLGGFLTALGKGGGGAALLPTPTDGLRCAACGATLRDFRDSGRLGCDQCYVTFDFHLRDLLRRLHGSSQHVGERYELPGVDDADPKGRLLELRAQL
->MGYP000721412648 FL=0
-VSMGSDGAVLLDENGYSYKINALNTKDAINTVGAGDSMIAGFIAGYKLSSKYEEALDMGIAAATATTASMFLGKKEKIYNIYNDIKDARLSKKGECIDW
->MGYP001793408712 FL=0
-MQEKDIQEKDIQNYIKKIILDEKTLDKKPEILVSYPEKTDEKGHITVICGKNHSGKSYVLKKISEALTKTEERKKYNKDEGILQCAETNLKVEFSSLGDDLPEVGKILSIGDSTSTKRIYEQINSITFKELRDNKIFTCALYFNDDKNSFLKILTSTNLKENFRFSSIHPPVLYSNKFFDTLLKNRCQQYLEQYFQQYFQQYLKHYLKRYLQQNFRQDFKQYLKQYLKQYLKQNFQQDFKQYFQQYLKQDLKQYFQQYFQQYLKQNFQQDFKQYFQQYLKQDLKQY
->MGYP001036737385 FL=0
-MAGKLAIQGGEPAITIKDPE
->MGYP000214490624 FL=0
-RSLALYDTLLDEMHDDAISHTEVAAELAQKTIGNGESDDDDTGAGIASDSPAEASKVKAEESEDDLRLGPDDAESWSDDPVRMYLTQMGEIPLLTRKEEIALAERIETTRAAFRRKLLECDFVIRASAKVLNRVFQGELPFDRTVQVSVTDQLEKEQILGRMPHNLRTLDILLQRNREDYEIATNKRQRVAHRRAAWRRLGRRRHRAVQLVEELGLRTQRIEPMIKVVEDFSRRIDELKATLTSMKKTRRSLTERKPLMLEYRSILRCTQETPTSLRNRINYLKAVYCEYQTAKRGLSEGNLRLVVSIAKKYRNRGLSFLDLIQEGNAGLMRAVDKFEYRRGFKFCTYATWWI
->MGYP001362031269 FL=0
-GGPGGGPAAGPRRPFEGVGVGGKDTRIEQKKQRCLLGGEEGGDDDGE
->MGYP001241401404 FL=0
-KDIFLKIILLFPLLLNSQIQRVDPPNWWIDFKNNSFQLLFKGESISNLSPTIKYQGLKINNITRSNSSDNYLFVDFAMDSTIKPGKFTIYFNGNPQIKYKYELKERSFDKLRFNGFDSSDVIYLITPDRFANGDYANDVIHKLRENKINRSDDYARHGGDIKGIIDNIDYLSRMGFTALWTNPFLINDMEKHSYHGYAITDHYKIDPRLGSLNDVINLSEKLNSKGIKLIMDQIVNHCGLEHWWMKDLPFDDWLNFQQEFQSKPISIDKMRISNEYNQDSINKYLIKTNHRRTINQDKYSSQFDEIKMLNGWFVSSMPDLNHNNQFMSRYLIQNSIWWIETLGLGGIRQDTYPYSDKKFMSKWASEIMYEYPNITIVGEEWSYNPLSINYWHKDSNNSDGYVSNINSVMDFPLQKSIIEGINEKESWNTGFIKIYESLSNDFYYSNPFELMIFIDNHDINRAYTQFNKNIENFKMAFGYILSIPRIPQILYGSEILLHNSDRIGSHGKIRSDFPGGWKDDKKNGFNDIGITNNQKDAKLFFKKILNFRKSSRAIQKGETIHFAPFENIYVLFRIFQEELLMIVLNKNLESYKLNLNRFREIDILDKTYLDIIRNDSIKVKNSIIIPEKGFYIFSIR
->MGYP001468330683 FL=0
-KKLTPIMTFGKMPIANGFIDKKDLKKEFFFDMSIGFSEDLSLLQLLDHPKPEAMFNNNYPFFTSSSRFMVDHFKSFSNWLKKNYSNHIKNIIEIGSNDGTFLLNFKGEDMNLIGFEPSSNVSDLAKKKGINSVNDFFNTSSIKNYSNYINQTDIICAANVICHIPNLPDLFETINMCLNKNGLFIFEEPYLGSMFSKVSYDQIYDEHIYIFSATSISKICSLYELELIDAIPQTTHGGSLRYVCGRKNHHKQSINVKKILDQEKKMNLDNIESCLQFKKNCKNSKKKLREKLIKFKMQNKKISGYAATSKSTTILNYCDIGPDVIDYICDTTKEKIGKLSPGKHIPIKPMEYFYNNQPDVAFLFAWNHKKEIFEKEKEFSKKGEWMAHVEL
->MGYP003628530332 FL=1
-MILLDSAQSMIRNEPITLSAVILVLTGTISYLYRERDKDRKAERERFLDQIDRLEEEINDLRNRKEKRKTL
->MGYP002780399917 FL=0
-TGQIERRRETGNVVSSISADDVEPAAVSDIADMLTARAPGVIVQNNSGTTGTSQRIRIRGSNSISLSNQPLLIIDGVRVNNNALGLNTVEARAVWVGGQETS
->MGYP001284371659 FL=0
-HGVGETQVRGSSSSASSSSSLKRNAKEHRNPLARTKGENDAASLGGKYERSKSKLGDVLVPPKAPARGVAEEGKLGSTTIESLSRDGDEERARDDRETDETMKKLDGYFNFDDNASNNKASEEKKSSASSLSSNDDAETAEEAKTKVEFSARKNEEDGSKTITSGTKIDESISDKDALDAYFSAKSSSSQAASVASSSSGSSSGGGDLSSAVKTALDARADEDPSLEDLKSSLKSGKTVNGEELEGKVETKPIASTPKASSLTSSVNMEVEAEKLLKEASEETEKSLSSTTKTAATGSIDSTSSTAAASEKSKYVPITTSHSMRSLSPIAQKYLRPRATSAYASTSSTSSASAAAAAAPSLHSDLASSARSLYSRDASTSGKSASSNKNAIAAKYANMFSLRSSDASSSSGKPSTGYA
->MGYP003656136555 FL=1
-MLINLNVKNKYTNCVMKKGRRYIEPELGKGDKKGKNIKPKKTKGFAWDGKSRPVDDAYRENWKVIFGKQEKTTAEKENEEYLEEIKNKL
->MGYP001595159463 FL=1
-MKQLNDMMRVGLGVRKMLSVCPHNPQPTTHSGNCLFQSCRAQSILEFTFSTIVFLAMVSGMVLIFRWAMMDLAERRFDHDRNLTVNSLTPEQQLAPDFHRVRAMDTFLFKKP
->MGYP001794431668 FL=1
-MYVQVAGLQCNNAVNCSTVTLIWTDVNSVTVIAGSQENFPVVSDSTMTVLLTDLIVVQHSC
->MGYP000352505163 FL=0
-VVISAPVFSKQLINTEIVTGGNSSTQVVAGEILTYSIVITLPEGTIPNLLLSDTLGSTSGALAYVNCVSITASANVTRTGGSGGTTGNWPSFALMAPPTELPTDTVSLTDWAMFETRLEPMQSRAHSFSVLLPISGPGSDIATLQRDMDLVRRVVSLEKPAHTRFDIQPYWTLFRLGQVRLGLDTLLGDGSRDPQLAPAMVLGQGHIGSSRTASRRDVPPDRILLEC
->MGYP003280527331 FL=0
-MSDGTAVQFKTEKRRFLCFFY
->MGYP003443885239 FL=0
-GVTSIGNDAFRGCSSLSSLVIPDYVVNIKGNPFSGWNGELKCLSPYFIYDNKVLFNKDKSKIIAFRDKNTTSYVIPDSVTSIGSGAFRGCWSLSSLVIPDGVTSIGDYAFVGCGSLRSLVIPNSVTSIGGGAFSDCESLGNLVFPNSITSIGDCAFDECFSLRSVVIPDSVTSIGDYAFDSCRSLTDIVIPDGVTSIGDCAFRGCRSLSSLVIPDSVTSI
->MGYP001559223103 FL=0
-MLAFRRDVQTTQRLGGRSLRFDGRRPVRGLGSAVVVGSGGGMTVHGVELQNCNSLPFGAQYSCSLA
->MGYP001074122584 FL=1
-GIAVGMATNIPPHNLREVAEAVLWALDHPEATDEELLNALLARIQGPDFPTGGLIVGRQGLEEAYRTGRGSIRMRAVVEVDEDARGRTQLVVTELPYQVNPDNLALSIAELVKEGRIGGIADVRDEGSLRTGQRLVIVLKRDAVAKVVLNNLYKHTQLQFTFGANMLAIVDGVPRTLRLDEFVRYYVAHQVEVIVRRTRYRLRKAEERAHILRALGKALDALDAVIALIRGAESADAAREGLMQLLDIDEIQAVAILDMQLRRLAALERQRILDELAEREAEIADLTAILADGARQRRIVGEEMTEIVDKYGDERRT
->MGYP001605154428 FL=0
-RLIKSLRAGFLADSFGRSKRQWRGGSHWIICNHXHRYNTHHRGHHDSRTIISSNSWRGRRIEHSWTGLLYMYVRFKVX
->MGYP000199882868 FL=0
-MGKAKKFFMYLILTVASILSVFPLYYMFCASTNRSIDVIAGKLIPGTYLIDNFKALIAQQNLRLALCNSFRNATVLTILCLLVCSIAGYGFEIYHDKGKDILMSILLLAMMLPFVAIMIPLFKMFTSWKLVNTWIALALPSISTPFMIMLFRQAARSFPHDIIEAARPERNTDFLPDVHSGDEIYLWSGDDGYIYECVEQLSVADDHFTGQQGDHHADVSSQSEEWIQCGLWYADAGSIDLYTSYSDHLPVFTEELCKWNYGSSEIMQQKMPKQETMTQAHIRKAQGAFLLAHRMGLIEDPSMEGLKARRKKHNEELRRMEQEGQRFYGPHYFSAPAYLQYELTRFKMDFAEPCEK
->MGYP000548054597 FL=0
-MLRKILVPVRGDGKGDNVLAHAAALARGFNAHIEITHCRAKPENLLPFGVPIPAALRAQLVESTSQVFDIEDYNLPYFIMFSDYRVATNKKYPEIENDIAESLCFFLLPFVYDNETYDEYLSFYNSYEEDEEFNLYSYKTKSGKYI
->MGYP001129376977 FL=0
-MNDFSETNPYTPLVFNSLEVNEQNFCSNLLNRLIVFTQASFHYSSIESLHLFREIVNSSRSSQGSLFSPFFFFKTKKTNLKFQISNQKDKDKEKEKEKEKDKEKEKDKEKEKEKEKDRPKMFKTDAQLLFYCYLIAPSFRLAKANVKLSQDVIFFFLSK
->MGYP003295116401 FL=0
-LREAYDYLLLDLPPVAEVTDAMAVAPKVDGMLLVVRQNYCDRIVLSETVQQFAFINAKILGVVFNCTSEHGGKYYGKGYYKGYYRRYYKRYKGYGYNQENQNA
->MGYP000887695439 FL=0
-KGEYYLEAMVFDLNSKGQYLPEWYDNAKDMTEATPVILDCADAATADFYLEKMPEPVYHKVSGTVKDAETGDPIQWAIVEFYGNDPNGYGYSSYASTDEDGYYEAQILEGVSYIAYANSGYRGKKDYDTIPYQDIYLPQYWDGKSDPSEADPIVAYEDVENINFNLEKYVFHENLITGIVVGEDEKELSDIMVFAYLIDGENVDESNYKYHGFMGYTDHNGKFYLNNLVPGTYVLFAVPARPMKYAPGFYMEDDLAILTWEDATQIEITEDGEFGPYTITLPLFENIFGEGIVKGKVSSEIGKVKVDEEVQGNEDGLQGAFVHVTDYLGARIKTSETNSKGNFELKGLANGTYTVTVDKVGFKSTSFQITITDDNKVIEHGVTLVKDDNTTDVNDDVLSPLSITVYPNPSVESFNVQFNSISGKSDLQIFDNMGRVVYQQTVNSTNGANYININSDNFTNGTYYIRLSNGNSTVLTPVVIAK
->MGYP001202805109 FL=0
-GVDGEGGAVRTWLGLGSGLRVGVGSGIGLGIGLGIGIGLGLGLGLPGI
->MGYP000917578306 FL=1
-MNKKFTSLLLLSSVILITTADKTRTKADTTDSSIEQQENIINEAQSAKDKSLSDISLLQSKIDGIRVEKNKTEQKISEIKKQAQNLNNKIEELSKNIEKRTDVLESQARSAQVNSNATNYVDTIVNSKSLSDIIQRLSAMATISSANKSMLSLQIKEQKDLNNKSDEVKKNYIEYDNLVKNQALQEKDLTSQEKQLKVASLNYQSTIETAQDKKENLLKQKSTAEKEAKIAQAEKEKVASAQKSAKEAYTSSSVTNTPSSSVEKSSSPKKENTKTSSNTGTTVEQGTGTSSNNDTNNSTSGTGNPNYNPYAGGGCTDFVWQYFAAKGIYIANIVNGNGGYWGTNGVSQGVLRRTNLAPGVIASGFTFHFTGYGTSTTARTSPYGHVAVVTGVNPDGTFNVQEAGYGGTFPWGNVRTNISPENVVFLLPN
->MGYP000491110560 FL=1
-GTAIYGETRAIPLNLVDFTLRDFATRQSDDSQTISYLETDYSNSYQFNLDSNNILRLVYDLAPTARGFSRSFDGSTSATNFTVAVIPISARAPVIVSDGGGPTASLSIAENGAAVTTVVTRSNFRHLAEIVRLATRMMTGAGLAVVLIAMTAAVLVIFAVRSGLAIHRETIEVLHLIG
->MGYP001489963689 FL=0
-SERNKYSRSIQVSLKNIIILMFFGISLFGLAVIGTLRIINKEPLTRELNDLRADRLLLKQIVSDLHASGIIDSTKAYEHFVYEFYNSHKMSFPDLAPVMGYVTRGVHMGNNHLGIDIAAKYKDDIYAPADGRIIFSGVGDDLGNTIIMSHDGGFITVYGHNATNLVNTGDSIHKGQVISQVGDTGKSKGPHLHFEIWKNNQVLDPREIIKKYKEKDVSIRETRK
->MGYP003582534822 FL=1
-MLFFAQKGTVTDGHQYIPAVIEAGAAAIVCKDLPEVLQPEVCYIQVDEVAPVIGLMASAFYDHPTRKLQVVGVTGTNGKTSVATLLYKLFNQLGEDSGLVSTVENRIMDNVIPSTHTTPDPVSLQALFRQMVDASCTYAFMEVSSHAVHQHRIAGITFRGGIFTNITHDHLDYHQTFDEYIRVKKQFFDHLPKGTFALTNIDDKRGMVMLQNTKAAKKAYGLRVPCDFKGKVFENNLTGLLMNIDGQDVHFRMSGLFNAYNLLAVYGAAVLCGKDKIDILTALSNMQGAAGRFETYHSENEKILGIIDYAHTPDALQNVLSTIKQFGQQANIITVIGCGGDRDKLKRPEMAQVACELSTKVILTSDNPRSEDPEAILDDMEAGLTPGMMRKALRISDRKAAIKTAVSMAHADDVILVAGKGHETYQEIKGVRHHFDDREVLLEMFKLLEK
->MGYP001208310892 FL=1
-MKKKKAYVVGTNVSKSLSPLIFNYWFKKYKINGSYNYKEIKEKKFDLEIKKILQEEGVRGINVTIPFKEKIIKHLNQQNKHAKLIGAVNCVSIVKEKTKGINTDWTGFKDCTKHIKKRNVAIVLGYGGSAKAVIYALKQMGFKKIRVFNRTFNKIKRLKNIKPHKLEEIPDYFYTADIIVNTIPKNFISKLLKAKQKPTNKTNKTGYGFDLVYNHPTLFLDSISKTKRIYGVEMLAHQAAPCFYKWFGKKPKVDKKLIKKLINS
->MGYP000076073552 FL=0
-DLVLGVFGWVVRSDKLGKGTLDHTLKIQVESELQYWRSVLNRVVAVIKFLSSRGLAFRGEN
->MGYP001544161807 FL=0
-MGLQQRLDSLALNDFFTLYHFIWTHSKESICNTTHCGTFYIPPRQIVPKVYNIITRTFPSVARIQGRDKDCTEICFAVAFCNSGEHVTGSSGDGFQLRRCCFALISPRTCLRPDCNDASVHRSVXERASLAVRTTHGEGNAGXTKLLRRRCXLX
->MGYP000196507220 FL=0
-RFMAEKRELQMKEITEQLEQGVKELFTSEMYTEYLRTMSQFHNYSFNNTLLIAMQKPDATLVAGYQAWQKKFKRQVRRGEKAIQIIAPAPIREKQEVEKIDPETQEPVLRFDGQPETEEVEIVIPRFRVASVFDISQTDGEPLPELETPELMGSVENFKVFMKAVQEVSPVPVRFDEISSGAKGYYSNTEKEIVIQNGMSESQTMKTGIHEVTHAMLHDRDFMEEQGEKKNQMTKEVEAESVAYTVCQYFGLDTSDYSFPYIAGWSSSMDMKELRTSMDTIRKTAGSFIDSMTEVIQRLMWEQPELSLSAMKQAEILIDRVEQERTLFSGEERNLLVNYAYKFDNAEETEKLIRKLAEAKAIPDLRSATEICRDIQKEIEFLPDGMVGMTELHRYGYQNEGCFRLKGRGHMNCFRKVLRYSPCIRMIRRQCWMMKENLIRMTVFSG
->MGYP000592636036 FL=1
-MTDRPLWQMTATETANAIRDGQITAQQATEAALSRMQEVNPHLNAVVEDLSREALEQALGMESGYVLDFSDRTFNDFFYETIAIDPEDQSQLFNGRGTSKAKRLRSFIERAQPALVAKILREMWEYRDAMVFAPSAHNEEKLKESYFTTVARIEGRADVIDTSAIETFEPNETLEELVASIRRDLDANKPQAALDRLHTYCMKRFASLVRKHGGGECGKDDALHARVAKYVKILGAQKNLNPISERIVKSSISVFEAMNPVRNDQSFAHDNPDLVQMEEARFVFDSVTAFLRFSKAIDGRFFED
->MGYP000923000473 FL=0
-GISVENTSMFEITNFDIVIEVIISGTISIHFIYNTDVFENETIKRLSGHFRNVINVIVNNLEIEVSRVELLTEYEKKQIKYGFNNSKTLFPDNLAVHEVFEEKVKNTPENKALSFNGFELTYKELDEKANQLAWFIRSKGIIQNSIVAIIFKRSIEMIVSILAILKAGGAYLPIDPMYPIERIDSIIEDSGAKLVLTQKNIFDQANISENGMFHRNNIELVFLNDVEYLLSQYEKNYIQNINVPGDVAYVLYTSGSTGKPKGTLITHYNICSKIVNANF
->MGYP000510006770 FL=0
-RVGKRTWWYENGQIRQESNFKDGKIDGKLTEWNENGQIRLESNFKDGKRVGKRTWWYENGQIEREENYKDGKKNGKWTWWYENGQMEREENWKDKIPDGNWVSWFENGLQSSEGNFKDGTGVFLQLHENNQKSYEVIYKDGLGKMTEWYENGQIAGERNYKDGELHGKHTYWHENGQIFEEANLKDGKWDGKYTRWYENGQID
->MGYP000191306956 FL=0
-LRTQTSGVQIRTMEAEKPPLRIISPGRVYRNDYDQTHTPMFHQVEGLMVDKNVSFTDLKGILHDFLHHFFEESLEIRFRPSYFPFTEPSAEVDVMGKNGQWLEVLGCGMVHPNVLKAVGIDPEEYTGFAFGMGVERLTMLRYGVNDLRAFFENDLRFLKQFN
->MGYP002707266309 FL=1
-MNKFGLDNVVTEKANVELTDLDNGVKVSFSGDIDVQNPEPIFVPFFEQIHNKIIENGIKYVELDFSKLTFLNSSGIKTLIKWITKVTPLPADKKYNFKVIANSQITWQETSLKMLSMLAPGLIEIQIQ
->MGYP000629646757 FL=0
-MPFVTTPDGTEIFYKDWGPRGGQPIVFHHGWPLSADDWDNQLLFFRDKGFRVLVAQRGAGHHAVALEKLDVPVVVDGNPRQRRLWFPLRSGRDAQDLVGRVVVDVAVLDLAQVDAGLH
->MGYP003443031209 FL=0
-PSVMVSVTTVSTVYVPIMVSVVVSVAVKIPVVVIMSAIDVTPVMIPVVHCCTGRAVACTIMMVAIVSAVPSVTHTEMTGGVMVDIVVTTTMVPTSSSYDMPGMSTTIRGVEDRATIVEIVTMRIACIDGEVPETVTPVEWTIEVGGCTESA
->MGYP004007491671 FL=0
-TTQSVHDTLFELDAAGKLAPGLVEAWEWKDSLTIVLTTRSGVKFHDDTEFNAEAVRYNLERIRNPDTGSIRGGEISALDTVEVLDAKTVRLRLKQPFAAFLYPLVDVAGCVVSPTAAERWGKEYGLHPAGTGPFKLVEYLKDAHSILERNGDYWIPGKPHLDRLVLRPIPVDSTRLAELRSGGVQFAESLPWQDIQRLRAGNEVVVSEKVGFRWEWFGFNVREEYPGHSK
->MGYP002477604874 FL=1
-MESMHFLHLLTAVAALLLGALLGGRIASLLHIPRVTGYLLTGLLAGPSFTQLVGLPSLLTTDALQELAVLSKVALALILLNIGGQFRTEQLRRFRHRILLFSASESLGTALLVSGGTVAVNQFYLQQVVPGLSLLGTSLAFGLLLGLVAIATAPAATLMVIREYEAEGPVTGTLLTLVGLNNILAILSFSVAAHLMFHGDSGMGQLAIKMFGPLLVGGSLGFFLSIWGQRLELDTEFKLLLLGGAVATAALCSALGLDVLLASMALGIVLANSSPRWHRMQEALRQVDYPLYVAFFVLAGAQLHLETLSHIGLLGVVYVVARTLGKLGGAWFGAKLGHFGERERKWIGITLLAQAGVAIGLAEQIAQLWPVGGHLIETVVLGSVVIFELIGPLAVRHGLVSAGEVPILSLLQKRAPQNAIEGFHSVLSHFRSSIGLPAGHRMRDPGDILIRHVMRQNVETIRNDTPFNELLRHISHSRYDRFPVVDESGHFLGMINYTEIRELLFEPALAKLVVASDLVSTSHLAVNPDQPLREALQLLQKHRDISYFPVVDPEDQNLLLGILRQNDVLAAFRRLDLQ
->MGYP001551819414 FL=0
-TLDASLGDVAVLYRTRDQGEVIANALGKLGLPVKMTGKATLEQSENIDRVLGALEFIAGRKTPPVDFEGVLETSSALADLSAREVIHKVSETLFEEDGSASADIAPLVRIAKKVDEHWAKKVTKKVSFVKPGRPIDDFLDRIALQGKADLHESKVDSITLTTLHASKGLE
->MGYP000703270391 FL=0
-MPKSEKLRDVLIGFDSAWTDSLRNPGAISACILDGGQHVTFYRPRLATFEEALHFTRQVGGDADYVLIAIDQPTVDPNRDG
->MGYP001030102971 FL=0
-GRYRSEPPPRAGGDRSSRADGTLVIPVEGAGLSVRVAFASPIQERGYAPLVEACGMLVGLARAPSAEASASLRPVPPPPEPATVAPAVRHLYADALRVAQGDVSVLIRGESGTGKEILARYIHAASRRAAAPFVPLNCAALPRDLLEAELFGVEKGTATGVDARPGKFELADGGTLFLDEIADMAPDT
->MGYP000938480968 FL=0
-FEAKLKELSDDAQVNGFRHGKAPRRLIENRYKKEISEQLKNELLYQSLEQMSEDKKLNPISPPNIDPNRIEIPMEGDFVYEFEVEVRPEFNMPEYKGLKLNKPVHHYTPEEIVREERRILATYGTPLPKEEAVALEDMVILSGPVKYGEQQIGMIKSHPFRVDGQLAFKDGVAPKFAEQ
->MGYP001617072387 FL=0
-MNRDEFADKTVESYKAACLEHLRQFLRSMRLRDKVSSNPTRLGNLSVECIWHEGQNHYIENYHKQQWAWGFTLFCPQGHEIARRLVISQEQVGAFLAHQERPCYACKEAKP
->MGYP003654168572 FL=1
-MEELVDNFERLDGPQKRKKLEELLRIDRRLGEIDDLPFGVPPNRLEACYYDVLRWLRSGEDVRAPEVGDLVDVLAGTYHTGFGRMRDTPAYHGAIVLKLDSHGRIVARLPDSAGPFAAEDRAMHLGWNVKPTRKLYLSFDEYKLKRKE
->MGYP002623322284 FL=0
-PPEETHRLLPCLQTGIIDDRGAAAWQWRNRGRASPGGPLTMDMAANRTIRHKGGFPPATPGRAQEWRKPMFKKTAAAMALSLGLVLGAGAIAPEAAAQTRVTLKSAKAGTSYYVMMVQLGEMMKAQSGGKIQATVEESQGSVQNVKESARRPGNFLFTTPPSLLVSAREGKKPFEGETGYDRVRALFVVPFVTIHFAVQQDSGITDVMQLEGKKFIAGGKG
->MGYP001568520366 FL=0
-HQLRVWLTVGDVLAVRQQPQALIVMLIVSLFRHLFVSYMVNRFSSPIS
->MGYP000925408016 FL=0
-MVEHIGYHTLKEGKTLLAIFNALEGFANNLTGLAGKNIEISTDIPSSAKAPVKQT
->MGYP003579269052 FL=0
-MNSDVPGPDDGAAPDALDFASLDVVYIDDALAVVDKPAGLMVHDSALARGETDFAADRLREQFGRPIFLVHRLDRATSGCLLLAFDREVASALGKTLMARDVEKDYVAVCRGWPAEERFTIEHPLDGGPGKPVQKPATTPVG
->MGYP003309607925 FL=0
-MSVKRIFLIVLDSVGVGELPDAAKYGDEGSNTLKACV
->MGYP000957236481 FL=0
-MVEGALDARHLPGLAPFLSRETLDRLALKIGEGQIDAGCLTSLAPFLSQEALSRLVDQAAEGTFDAVHLTGLAPFLSRETLDRLALKIGEGQIDAAHLPALAPFLSQEALTRLLGLAGAGKLGAETIVALAPFLDSAVLGELIKNSARQK
->MGYP000599625106 FL=1
-MIENNQKLGSLSSGKNFDRTQSWVERSDQISNSNTGIFIQISLPAKISGFYGLKEFNFMNCEMSGMFGPNLAKCISFYNTDWVKNEKYFSMPTNGIQKVTIPTSAVYKITAFGAGWQNYGAMAKSNVKLENGTQIYVGIGQRGKHISDGCGGTFVTFRKNGKFVPLIIAGGAGGGDYENEYGNGSTDEFGKKSDSIEESNRNIGKGGKSGYSNCYNGGNGFEGEINENWEKT
->MGYP001217081736 FL=0
-SFADKFLEVLIFRTALFLFLLTIILQIIMPFCIYFLAPGFLDNSLVLDQITTLTRITIIFMPLISIVALLGVATNVSGKFWILSFTPIILNFCLIISCFFISDNWTVKSLPLALATVLGGVLQLIFTLIMIKKFGILKLSFKSKTIKEYDQIKLYLKQTWKKFLPAAFGGGILQVNLLVDTVLASLLGFGSVSYLYFADRIAQLPLGIIGIALGTALLTSLSKSSAIKDTKQFSKELIISLKIGLFFSIPASFVFINFSELFIKVLFERGEFSSLETNQTAQALIAYAFGIPAFIIIKSCQPAFLADGNTKTPMYIGFILLLLNVFLSYTLMHYLKHSGIALATSLVSWTGSIMYIVLLIKKGKISKFKFTFKYDQFNLFAVLIYALKIIFTSCLMVLVMKSIFYFLNIYKINEISILLFIVLFGMLTYFSTTYFLKYIPQELLKINVFKFRKVN
->MGYP002526846326 FL=1
-MIRRSSDKISVTKPSPFNGIGEITVRSLLNGPEEMENKGRVFGHTTVYPGSKIGLHMHKGDSETYYILSGHGKYNDNGTIIDVQPGDVYYCADGESHSIEAIDEPIEMIALILYTT
->MGYP003577118151 FL=0
-MIPSQINDTSLKIFRDGMAAYVVFEDTEWEILKNYIELKVLQKKDHFAVSGKICDHIGFIVNGSVRYYHIKDGTEITGYFSFENDFVSSYKSYVTRTPGTGYIQALEQTEFAIISYNNLEQMLNHPL
->MGYP000225436725 FL=1
-MRNTFHLKTLAVAIAAFSVASVTNAAGLDRSGQDVTAFLQDGIYAEAVYTYIDADVSGYDNGRVATDDAGYVQGNKTGDIAEYYDFFRYGVKADVNDTFSVGILYDEPFGAAAAYTGDSNFT
->MGYP003337284868 FL=0
-MKEGYGEENSDIRRYSGDYLNDVPHGYGTIIYGKNIYTGNMKNGKKDGIGTIRNFTGKFEYHYYYQGKKYRGPLYRFPIYEEKKAFWKEDKFIVDFYIKKGELMIQNYLNSMNEKDIKYCKSNNIRNYIYKNFH
->MGYP003906308351 FL=0
-AYGFVRDCDGAERHQGPLVEAALAAKRPGDAGELANELARVCLESGNADKAENWYRKGHDAGIAQPDFTPATKDLWEFRTAHALAALVGDQGRQRRDRVDARAHERVGVAEAEPIVPVASAPATAAFSRGCVAAKITGLPRDVLYAHALTMKPEEPARS
->MGYP001106728357 FL=0
-MINAIIFSKDRAPQLRLLIYSIQKNAPHAFNLNVIYKYSNDKFKEGYEKVKGEFSSICNFVEQ
->MGYP000556042202 FL=0
-MRLKLLVALVAALLLSACNDPHTGTFIFTAIPDQDESQLEKRFGTIALYLEDQLGVPVKYVPVKSYAAAVTAFRNCLLYTSPSPR
->MGYP003339182432 FL=0
-MISRRNFLGLSLSTVALQRLSIFDAFAANADISHGLRTKKEVALTFHGAGDLKIARDLLAIASDAKTPISVMAVGSWLSANPEIGKEILAGGHDLGNHTYNHKAMLHLNLNEAKSEIAKGKAAIIKSVGSAQKYFRPSGTPKSNATIRKAAIASGYSNCITYDVDTLDYRSEEHTSELQSLRHPRMPS
->MGYP000070210673 FL=0
-MRSKYISKLILLCAIIIISNINVFSQDEDSIKTIEMKEVMVSANKTEKPFVELTVPAKIISKKEIENSGHSRLDEIISEQVGIITVPGFGGSEGIQLQGIDPEYTLILIDGLPVIGRVAGILDLSRISLASVERIEIVKKALFYDLKLNKKKVVVISFSSLTTELCKKYKSNIILRGLRAVSDFEYEFQLAGMNRKLNKNIETLFLMSDVENQIISSRFVKEIVNLKGDIKKFTTKSTIKLLKRKYE
->MGYP000373531853 FL=0
-TYWFLIHFIFERNKWRYAKINESPGILTIREPNGTDRVELERLEVEEARETLGVFIAMDGNQDAQTQALKDKAATWADKIRTGSFSHAEAWFSLQYCLMKSLEYPLMATCLTKKQCEDIMTPVRKAVLPALGINRKLSLVVSQAPKKYQGLGVLDLWTVQGSLKTWLAINHGDASTITGHQLRASMELHTLEIGLPGQLTQHDFEIYGAITTTSWIKNLWKFCQHSKIQLNTTTPQLQLACTNDSLLMGTFAEYGYREPQLSLLKLCRLHCHAVRVSDISTGDGRRI
->MGYP000570708825 FL=0
-LERYDVDPANVLGAGDGGNDVGWLSGIGFPVAMGNARPEVHEIARAVAPSNADDGAAHLLERLAAAHGGA
->MGYP000034617079 FL=0
-RVRNGAGRAVVVQRLGQDRNVGTGRVWPYQDREVFDTADGARFDLDSAPGGLPNEGYFGTRSTSRA
->MGYP003372218023 FL=0
-MTNYSVYIDESGDLGINKGTHWFVISAVVV
->MGYP000394300602 FL=1
-AKERMKLVDLDPAFGARSVNEGFSGGEKKRNEVFQMAVLEPRLAILDEIDSGLDIDALRIVAGGVNALRRADRAILLVTHYKRLLEYVEPDHVHVMAGGRIVRSGGPELADELERTGYAWVAGAAPETAAAGA
->MGYP003610839716 FL=0
-MIEMKLLVTGGLGFIGSNFIRLMLHEREDCRIVNVDAMHYGSNPDN
->MGYP000586146873 FL=1
-MQDELKVYEEKMEKSIEAMMSEFASIRAGRANPHVLDKIKVDYYGTPTPIQQVGNISVPEARMILIQPWEKSLIKPIEKAIQTSDLGINPNNDGSCIRLVFPELTEDRRKELAKDIKKKGEAAKVAVRNIRRDANDAFKKMEKNNEISEDDLKDAETGIQKITDKAIEKIDKAVDNKTKEVMTV
->MGYP003291547436 FL=1
-MLSFFVGALSSCAAQLLKLMIHGIHHLVEHYLIEQHHWWYLITPMIGITLAGLFVKYVVKDDISHGITKILYAISQRKSIIKLHNTWSSLVGSAITIGFGGSVGAEAPIVMTGAAIGSNLAKLFRLDQKTMMLMIGCGAAGAVGGIFQAPIAGLVFTLEVLMMDLTMTRMAPLLISSVTATAISFLANGQEAMFPLTNSEPFFVERLPWYILLGVMCGLVSLYFTRGMNHLEQFFKHHVQNIWLKFVVGGSVLGLLLFLFPPLYGEGYDVIKQLINGDSVSAIVNSPFEQLGKSNWVLVGYFVAILLFKIFASVATNGGGGVGGIFAPSLFMGAITGFICARLMNMIGISVPEANFALAGMSGLMAGVMHAPLTGIFLIAELTGGYHLFMPLMAVAVISFLTIKIFEPHSLYAMRLAQKGELLTHNKDRSVLTLMKMENVLETDLRTLHPEMTLGELVKVIAESSRNIFPVIDEEGRLLGILLLDEVRNIMFQPRLYDRFIVKQLMNSPQAILTNTMPMGKVMEVFEDTGAWNLPVVDEQKKYLGFVSKSKIFNSYRHVLVHFSEE
->MGYP000629932273 FL=0
-KSDVSIARTIWQENEIRRLERAVTGYFDYIEDLIERENTFNMEQFAASVNEFLTFRKYQILPDKGRISAAQARQRQKANTIFLIKTNGLILTLTKKLGGCWVKSNKMK
->MGYP002789926533 FL=0
-REALDALDASERAAQEALLKAREAADAASAAAGEKARDKRGVVLEPGDAVEVATLGGKTGKLIERRGSDAVVMVGALKLTVPFAALRRVSQRHLKDQAPAIAIIDVPEVMAKTEVDLRGLRVHEVDDAIVQAIDAAHRADLRALRIIHGKGTGALRERVNQLLKGDKRVKSFRLGAWNEGGAGVTVAELS
->MGYP000243790712 FL=1
-MKTGFRKSQKGAVAIEFALVFIIFFAVFYGLVSYSLPLVMMQSFNQATSEAVRRSVAVDPNTPNYSTVVLNTANATLTQQLSWIPPVFNLVVGVDTSSQYSASGLLTVRVDYPVSKLNQVMPFLVLPVVGTVPNLPTYLTAKSSLQF
->MGYP003301794412 FL=1
-MNKTKLLILLFFIALATNVNAQFGIGLKGGLDFNSVTRSNSGRIDETYHAKNGADYGIILSYQINEWFALRANVEMLSRSHTMKRNLNAVKGLYTDYKNQYLTVPVMADFTFGGARVRGQFMMGGYVSYWMMANVSGNTFDLYNKIRPFNEKMEFNEYHNRFVAGLVAGPGLSVALTEKISLELDALLYYDLVSYMKVSKVSPDPRYNNTASLTLGVIYKL
->MGYP003383111361 FL=0
-MYKTSKLRKLVFQRLTTPEGTRAQQSLSSGTGQSLHDLVVQAMINVKLVKW
->MGYP003686761737 FL=0
-TPHAPIHARDTRQEAPVFFQAEDGIRDRSPSRGLGDVYKRQVQLNEKFSDGKYIVKSQYGNSKSTVNTSSFLIATSNISSMESTSSEIPTWIKNNAGWWADGSIDDDSFVQGIQFLVQEGFMKITN
->MGYP001302444474 FL=1
-RSNSDSNWANEGNLENEVVLEAEFDLGS
->MGYP002051420820 FL=0
-GRQDRQGGQRAWTPNQTTSTITSKKIILLAYTYTYVISNYFSPTGSLLYYVSCNPEIQDKIFDEILDTIGSDEITHDNISKLDYLEACIMETLRTCPPVIEHDRVCTNDCVVQGIPVKKGVKICMPNYPAHYDADFFPEPEMFKPERFLKENADQIIPYTWRPFGSGNRVCIGQRFALMEIKIFISKLLYKFKVERTPRTELKYSPGGFFIISYPEIRVALHPRNWTNKILQKKVFMRSGILRKINFRACKEKPSYKKLCQKMVDK
->MGYP000789720163 FL=0
-SSSSPMVLVDGMEYSLNELNPGDIETISVLKDASASIYGSKAANGVILINTKNGRNSEKMNVSVRLENTFSMPTMVQQVADGVTYMQLYNEAVFNTAKETGTLHAYQPFYSADKINGTKAGLNKYLYPNNDWYDLMFKDFSVNQNLNLNIRGGGRKVSYFLNAAVSNEN
->MGYP003304858611 FL=0
-MVTERTRELDESNHLLEQKQLLIEQRNKDLEQALQEKDRLLSVIAHDLKNPMFAIVGALDSVLKNHSSLESTWKTLKDIYLSALNLQSAMVKLLEWARGKQTDVVCHVEDASVRKMVQEVVSLLNGLFKEKKIKVSTSFNVSHCALMDSRMIGTALRNVLSNAVKFTPEEGSVEIEVLEESGYITMKVTDTGVGMTEEQLVSIRNNENVISTMGTKMEKGTGLGFKMAKDFVEKSGGVLLVDSKKNEGTVITIKLPVALTDD
->MGYP000358995731 FL=0
-PSGYHEERVMSKCENIYDTLLQVFEISSEKDIPTFEAANHMVEERLETIAHIKSIKS
->MGYP001565574238 FL=0
-MKALTLPFPPSANRYWRHTAGRVYVSEEAKDYKYYAVMEALRQGILAPLVGKLSLVARFYFPFPVKGDLENRLKVLDDAMNKILWDDDSQLWRIVLERHYDRANPRVELEV
->MGYP000188450185 FL=0
-QITASLGGVSTGFPREAGFDITVASEVMAILCLAKDLSDLQKRLGDMIVAYTRERKPIYARDIKADGAMTVLLKDAMQPNLVQTLENNPAFVHGGPFANIAHGCNSVIATTTALKLADYVVTEAGFGADLGAEKFLNIKCRKAGLAPSCVVVVATVRAMKMNGGVAKADLGAENVEAVQKGCPNLGRHIANVKSFGVPVVVAINRFPTDSDAEVELARKAAEAAGAEAAVMSNHWEEGGKGAVELAEAVVAACEQPADFKLLYPDDMTIKQKIETIAKEIYNADGGTFE
->MGYP000733041054 FL=0
-SPCSFYTIGTQQIFANTSDWSSEFFARGEEVGLIPSSLSQSKKSYITRKNFSEIAINFYSLYTGNPAVSINISPFMDEKSPKIVKAYELGIVNGYIEEMMEGQKVVKVFTHEEESIADFNRLNDQLFHSADNANKFGNILMPVNAQIGNISYVLCAIVGGILALGGYGGFTLGKLASFLTYNKSFGQPINQLSMQLNNIVMALAGSERIFALLDEQPEVDDGYVTLVRAKWENGQIVESKERTGMWAWKHTHQADGSVDYIELKGDVVFDDVDFGYVPEKTVLHNVDLYATPGQKIAFVGSTGAGKTTITNLINRFYDIQDGKIRYDGININKIKKDDLRHSLGIVLQDTHLFTATVMENIRYGKLDATDEEVMAAARLANADTFIQQLPNGYDTLLTGDGANLSQGQRQLLAIARAAIADPPVLILDEATSSIDTRTEKIVQDGMDKLMAGRTTFVIAHRLSTVRNSDCIIVLEQGRVIERGSHDQLIEKHGKYYQLYTGNLAEG
->MGYP003499035801 FL=0
-MTNSSFSVLIVDDEPNIRSGLAKGLISEADSIETAKDADEALLAFGKHDYQLVLADVRLNCSMNGIDLMRKMLLARPQTAVIVITAHGTMETAVEAMRAGAFDFIAKPLDLNLVRQQVRKAREHYQLQLENRNLRNQLANAGEISNIIGNCTAMQEVFHQIRQVANTDATVMIHGESGTGKELIARALHELSDRSGGPFLAVN
->MGYP002865127206 FL=0
-MERNELKKKAKEALRSTDLDEKVGAAANEMKEKVQDVLDKTDLDEKIKAGADRLREKADANVDALKAQVHANAEQLKDKVQDALDKTDVDERVK
->MGYP000383000818 FL=0
-MTLLVAGPEVEEQCRQLGLPLAAPLAEGWALPTKPRCLHLEKGPQGFGFLLREEKGLDGRPGEWEPWGRWGKVGLGVGTQAYIHLSVHRRGVPV
->MGYP000367940092 FL=1
-LMSGESVLLEPILSFVIEVDSGDLGRVLFDIQRMQGEAEPPQAAGERMEVRGRAPAACMADYPQTLISATRGTGRISLRFEGYAPCHNAQEVIEAKGYDPERDVENTPDSVFCSHGAGYPVKWDQVPNHIHCK
->MGYP001277400934 FL=0
-CARSVLKPRPPPVPPAPPKPLVCAAEPARQLTPRELPRVPPAVVQAEIHEHLADVSTGPDENMMRMLFEAEPDPALVFLKAVRPSPLPRTGPRAVLASSCPAER
->MGYP000821197694 FL=1
-MIMQNLSLIHISEPTRLLSIS
->MGYP000868773532 FL=0
-MLSINERDGVRLDALALPHRPQFFSGLGLHVDLPGLDAQGPGNGVAHGLAVRRHAGCLGHNGAIDIADLPPLLAHPPDGLGKQAQRVGAPENRVGIGEMRADVAQRGRPQQRVGDGVQQHVGIGVAEQAHGMRDGDPADDQRAARHQGVDVPALADTEIDGCVHAARLFRMASARAKSSG
->MGYP003609178968 FL=1
-MLRKPVYRSWAYTADADAKSKSNAEYFEELSHLRSKEHMSFTTSPQYAHTTFSGELLSEEALALTADEILLLMDHGNLCFGGRCSKSGNKFSGSYNTD
->MGYP003113185133 FL=0
-KKKKKIRIGIIDAKADQILTGIGTVADNPELGNIIDIVVGMGITQTLVGKTSIGAGSTSSLSGYLKGMVTEVGEGQVSVKKKKKVEGSTETPRDYQEGGAFPFDDLGSLGIHTAGISTAAATVPYAGRQDWFSQQTVAISTSTVGGSTITTTQPWNTVADKPGTSQYAADRGTRFDEVHVVVIDGAGKVSGNAGTILEKHLGLSKAKDAEFSAGAPSYWRSYLKTNSAFVFGGDEPSGTIDVGFDVGGFSPAGGSWDKTAEGTIFKSIGKFNGVMGGGKNYDGNTDITGDNALAVDLSKLVTGYSLFENADNFKVDFLLMGSADYSKEIAQALANKLIAVADTRKDALAFISPYRKAFLTDTVAGSVTVNNDETITENVLEFFSPVTSSSYAIFDSGYKYMYDRFANTFRYVPLNGDIAGLCARNDIDNFPWFSPAGTTRGAILNAVKLTYNPSQTQRDRLYSARINPVIVSPGGGIILFGDKTGLAKASAFDRINV
->MGYP000828330599 FL=0
-MRKLNYSLKELVLADLYRYEGKTDTKSFLHAYATYEGFKFSVWLRMCSVARKKKLTKIFILPICRMIYRHYKYKYGYDIPYACLLYTSPSPRDKRQSR
->MGYP001429112534 FL=0
-ESGGITQHIGAYEVIVEGDKKITFLDTPGHAAFTAMRARGAQVTDIAIIIIAADDDVKPQTIEAIDHAKAASVPMIFAINKSDLPEADIDRVKKSLSGINILVEDWGGKYQSQTISAKTGDGIKELLEKVLLEADVMDLKASREVSAQGVVVESRLDKGLGPVATVLVNKGTLK
->MGYP001154957988 FL=1
-DVCFCKANKGCAVGESSTDGSFTNDSIIWRTIDGGKTWKQTYAGEGEGGLGAVTFTSKKKGWAVGRGGTILKTKTGGRKWKKVTVPAGAEHYDLTDVSFPDKMHGWAIGGLSQGATDYNIFLRTRDGGHSWDLTTFNMTEPLSILWKISFPTDTEGWAVGDEGRIYHTSDGGTTWSEQESPHTDTFIQATDVHFTDADTGYVVTSDGYLLTTINGGADWEIAHHENSGFYGIAFGDLLNGWAFGADGMAVTTLDGGETWQRTTEGATEVLLGCSFADLSAGWAVGAFGTALGTSDGGHTWRDLQTGTVEHLRAVKFIDRDHGWAVGDSGAILHTYDGGESWAPQESGTGQALAGVDFVDSLHGWAVGGDTTLLRTVDGGETWTASSADAAIDLYTVDFVDTMHGWAAGKGPGHVLRTEDGGETWDAVEVVFIQGQTVAGYFSVRFRDAYEGWLCGAVQVGLDDATVIGHTTDGGWTWDSQHLSRSTDHILQAMAVTEDGRGWA
->MGYP004345682747 FL=0
-ALMISIKNFPNPSLKVYNVSALICFQSTQNPNKTAPDSPATQHRTGFKDGLATSPIDRHFP
->MGYP003480708303 FL=0
-MYHSGYKKSFKITGFALVELLVSISILVMVTGAVMANHGAFNSAVLLRGQAYEVAFQARDTQLFAVSIMSDAGQYRNIYGLHFDKNNNTGYKIFRDSNRNSYFGTSEEFGRQGSLDSRFVIGDVRWVHSNGSETSINNVSVLFERPNFDAKFFEAAAPGGELSNAMAVEIDIRTKGTSGNTNGEVRTVEITRTGQI
->MGYP001578248368 FL=1
-MKEEIKRLPQTLSELRKQEDEDDYSPRPRGGKPYKRKFLISFKKNEGK
->MGYP001074384480 FL=0
-RHHRGPGDHGQRGQLSGRGVHHEGRLAWGPASQDPALHPAPQREGGEVQPADGR
->MGYP003184699802 FL=1
-MYKKKQITCSPCFSDNPSESLDFNPFVDKVAVARPMSYYLNGGVDLDGISTRKPLPDAFDDAESIASGDVNVFTDLTVGKLDLMDMASTMASESQARALKDGARETNFD
->MGYP003330398148 FL=0
-LLPSFAIIVLGTIGSIPGAIVGSIIVGFVRALSSPVLIGVGLPLGRSNYSALDGVMPYIFLVAILMIMPEGIGDAYEKWKIDRLRKKREASVRDDKLQSTTYKCFMERSYYVYLLASRRMGTLYCGVTNELMRRVYEHKLGQADGFTRKYGVSRLVWFERHELVNNAITREKRIKRWRRDWKIELIEKDNP
->MGYP001273406180 FL=1
-MAIIYMLFKHISQLFSYKITLLFVFIVLFSIVYMFLDDKHFSGVNFIKDAIKEEVIKKKIEKKVDKTLENFTGDVFSFKPITANDEEDVDTKIDRVAEVTEQEVKEQDLSAEKIETSYPQKLFDRFYFSINTTTLLGYGDIYPVTNVCKSLAMTQSLLTIFLIVV
->MGYP003308729374 FL=0
-MIAKIEKCTLSGTAYAPTSKSIAHRLLICAALSEGVSIIKKVTFSEDIYATLECLKTLGANYTVDGDTVIINGIENIQQSEEKIFNCRESGSTLRFIIPLLLLSDVKQILTGKGRLIERPQDVYEDICNEQNLLFEKNDKITVRGRITAGNYYVKGNISSQFITGLLFALST
->MGYP000219845609 FL=0
-TTTTTANITEPTAVVISGAPVTDANCTGANNGSITINANGGTGTLQYSIDNGITYQIGNTFSSLSPGSYIIVVQDANGCTATTTAIALPAGQLILSGFGSGSLKSKIIKAKSIFRANECDEHSGEQLYILYTSAMMEKILGDTTLTSADFMAGKMIQEGGVGGKWMGFNWIPYEKLSQGAAVGELRTVAYCGSAIHFGEADITGFDITTRSDK
->MGYP000496951928 FL=0
-MSIEAMKQALETFKMLNLTQVIEVQWTINALRQAIEEAEKQFNPDWDQQAVLVKRIRELEAQQALDKKADNARELGLDYEPTHTDHPMRHWDRTCPACVEQAEKQEPSRAQTKQIVEGLKHCHHPDSQHEFLRVWIKDWTAHKSAQPRKEWQAVNGKLEVEPIKGTLLPQAQGQEPVANEKEGSPCPEFWDWLPKAYNFAGNGVFTKYNMEVAFLAGKQFSSTAPSRTSIEHAVIAGVLFDFMGWLTS
->MGYP001105606284 FL=0
-YGMIPCYKWPRNSSRLESFLQKQGTLHPKGYTYSEVKKMTKSFAHKLGQGGYGAVYRGNMPDGREIAVKMLKGIEGDGEEFMNEVASISRTSHVNIVTLVGYCLQGSKRALLYEYMANGSLERYTFGNNSTQGEDTLSWDKLFNIVIGIARGLEYLHTGCNTPIVHFDIKPQNILLDQDFCPKISDFGLA
->MGYP001562148884 FL=1
-MILIGLVTGLGAMIALSYWLTGSVGSNPAAADVCAEVATPVLDGPVADVTLGTVCGDIDLRLDEPISGTDGFEGDFRYSGPPSDPDRPRPGYLVWESDGCSAPVLGRGPFDFTLACNRHDFGWRNLKHIDGDDVPTWQVENKDRVDAGFLHDMRKRCAAVPAIVRIGCDTTARVYYTAVRLNPSGVKGIPGSG
->MGYP000254919864 FL=0
-RYHKIIIMTDADVDGSHIRTLLLTFFFRQMPELVERGHIYIAQPPLYKLKKGKQEQYIKDNDALETYLISNAIDELELHVSADAPAIRGEALAKVIADYQTSQKSLSRLTLRYPASLLDGLLELDAFKIDQAVSSYQTAKVKPKVIGSP
->MGYP003314355870 FL=0
-KESSAASDVYKRQVQESVLRKEETPLVSHVRTIVGHIILMENYWQQRA
->MGYP003594184147 FL=0
-NDKFRGQSMMSIDQMELFFQLLISQNSDRKVVEVFPSYYNKETTFGQCEILKETYGVNSKHDYAETISLSSERLIVRFRNIFVVGILFKRDFITWKEGKPIENEFVPFYKHLLNFVSFEDKV
->MGYP000202344024 FL=1
-METATKASDQQATNAALAALAATGNSYALGQLWELNKGLLRSMFWKWYPAHKAQADAHGLTADDFEQEGIFCCPARRPDLRPGTGSLYHLADCRHAAPDPAHPYQRPRPQRDRR
->MGYP000205932652 FL=0
-HQARMAPLRHQVDAGRVVQIDLHIPETSHMQHAPFLDEQPPLALRPVRPHAADGHAQPDHPGDGERRAKQHAQPVEREIGQSDDPQRRDRRGQRHRRLEPPFQQGRRLGADHRETLA
->MGYP000157303393 FL=0
-MKAKLLSTLKYLFFLGIGIAILIVVFKDKDLDKMVEDLRNAEYKWLIFSMIFGYAAYLFRGLRWLLLLETMNYKSSANHATQAI
->MGYP001265825478 FL=0
-MLRFILLTLLALIVWVVAFVGGTIAGLWREPIAPRGDTAAFVKAATARIDREHKGNVAFTLVEHGRKVA
->MGYP000910426799 FL=0
-MNMNAVTRAERGCVEAPTVSFTLNGRQISALASETLIEIATRESIDIPQLCYRPGLEAVGNCRACMVEVKGERVLATSCCRFPLPGMDVTTDSERARKAQQMVLELLQSDLPKTALTRNNEVDEWAARLEVCSPRFAPRPAVAADLSHPAIAVNMDACIQCTRCL
->MGYP001021135751 FL=0
-FKARFFALWAQNDKKHTQNDKKHTQNDKIFSEWQYILRMTKHT
->MGYP001288254412 FL=0
-MAGHNASKRLPLATQGRDRGVPHEKPRELLPNQRAARTLRKVPAHDQAQASPAAAQVPRLWKRDRVEHYRSQRGEAVRTWDIQQGDCLDLLRALPDNCIDAIVTDPPYGLSPDGRCRTWDDIESGRKGGGFMGKQWDAAVPGVTWARECLRVCKPGAHIVAFGGQRTIHRLICGLEDAGWEIRDLGAWQQWQGFPKSLAVGKAIDAHHGAEREVVGHADRKTGPGRHLAALAGNPGESATPSITAPATEDARRWEGYGTALKPCLEPWTLARKPLDGTVAANVLRWGTGAINVDGCRYGYGDPAWPGPQGDPGGRHNSADRSGSPTVHLPPVSLDSHDLGRWPANVYACPKASRAEREAGCGHLKGRAGFEAVERTEGSAGLDNPRAGAGRTAGEVRNHHPTVKPTALMAWLCRLVGGQPGSLILDPFCGSGTTGIAALREGFRFLGFELDPEYIQIAEARIAGDAPLLNRRESVLG
->MGYP001416122492 FL=0
-SEKEHHPDYERNTNHIKWRFVMDNANFCSDHKQVEFCAHELDFTCDYDAAITKKTGKHHKHTKNKTKRQYSGRDSEDNGSDMDLFEYTLNSDSESDTSQRGSGRKTSKKPKKRSNTGDGVKDSFLRDSMQFHPYNKSEHDTLNSTEMRWSGRKSYRDNRRNIGLNNNKSRARVVTVVS
->MGYP000266266674 FL=0
-MGMEDFWEQLPTGKEDKPLLFEMGPLEYDFHDIDGLYFMLDRRLSGCLLMMLSLIHISEPTRRV
->MGYP001810632152 FL=0
-ALENMPLEELQGQVQARQQDLEGLFRFVNSQEEELTLQRQDIEELQVKLSRSSEGERPGLEAELADQQEQYNMLNETLVGQRRNLREREEILSKHQEVLWRRLGNPPGLGRSKRLDVGSALQKAEAWRQNFGAAVQNLTGSVESLQQSLGELRETVTQKAAAMEGKQQELKEKESALATRQQEVLELAGRVSLYQEMLQPERDRLHSLHEKLEELGAAIAHLDETKDYQQQAITQIRDALMPIISPSA
->MGYP000787850220 FL=1
-MCKAKAWVLALTAGLLLLLIPAQARADVTRLLILNDEQTSETSAAATDVLRRFALYSSWTCTFVSSEDVPDTCLLYTSPSPRD
->MGYP003299208211 FL=0
-ENRCQNGPVQGQFSGRNRDVADEGAEGTKYEHGCHKHPGGASGVLHGNHFLSKMVLIVPEDGAVCKMYLIRQEPKNFFKMRIIPIDK
->MGYP003980343243 FL=0
-MMKSKIDPTVLYPSRRSMYKQDALAIERNEELPLFDATLLDTDVIIVVGKRQKVKDVAAYPFYLVKENNTVNSLVTTVEIQLGIYEVSVNKEEEYLDDTGTIDISLIGKPLLHTFVTKTLLESILSPTPTVNNHNNNNHNNNNHNNNNYNNGFNANNENPEENNNNNNNNTLQPSETERKRKSNSKTALEAEAENYIDIMTPTKT
->MGYP001799802231 FL=0
-YVIYINTFSKVLVPGLRIGYLVVSGPVRQLLLQQKLNHDRTTSDLMQRALEAYMTVGKYQVHVRRVCRAYRQRQVAMHQALKRHMPQGVTWQRPNGGLFFWVKLPDGVTAVSLFQQALRQGVVVSPGTSYTTPIDNESPYLRLNFTVHDTAVLEEGIARLGQIVRERLD
->MGYP003466254295 FL=1
-MSLSKIIGYASAALAVYFYKQSSDLENEIKSEKKAHEAYVRELLAANSALENKIDPNLGSYQSPIIFSATMRSGGQMLEQNEITLNCTNPTDSIIEISDFQARIWVAGYMADLCVPANILSIKIPAKKTVSFRLYARYGKMFRNYVEVKRALNLLYDGKNTSTMRAGTFIPLDKEPVLMNMQYLWVGKGFEDKCYVYDVPGSFRWKYAGWTVGAYVGYNAGNENQQKANPSYWTDTQEIDSIDE
->MGYP001158205152 FL=0
-MHANQYNFISSVSSNIIQVNIDITPKYNDYEMAQIIQNHAINQNGYIKNHGLMIYQKKDVYLVYAMDYVGFEFAWKYMIDAHSGKIVDQIPLIYDSGPTIGSGINLLNESITDLKVYEGSSFETMGGDLITPNLICEQFCWDYGDCDGQNYSDCIVVAEQYNCDDGYIVDCDGICFNEWYMQFPGVGNGFCNDPWIEYEEANI
->MGYP003680783999 FL=0
-QATIFGILAGALVIIFSKNLQAIFHTQSHWMFVLFGIGIPLYFFMSVNRGTFQGHQDFKNLSITYQTEMWSRLFLIPWEPSFLVALGIGLSFLFGLIPSNLKDISFKSKAKLLPENSKRVTQFMLLTACYEFTQIIINNSDILLVKHYFNALDAGLYASLALIGRVVYFVAWMFVMLLLPTVVQKQKD
->MGYP001343183673 FL=1
-MSNTYERLQKVIAQSGVTSRRKAEKLIEEGKVKVNNKVVTELGTKVSPDDKIEVNGIQLEKEVPVHYLFYKPRGVISSVKDEKGRKVVTDFFPEIEERIYPVGRLDYDTSGILLLTNDGEFANLVMHPKHGVEKVYVAKIKGIPSKLELGRLRKGVKDNGELLKAIKYRVISSDKKKNTMILELTLQEGKNRHVRRMMEQLGYPVIKLKRERYGMLTLDGMRVGEYRKLTPKEVKQMINLATQIVED
->MGYP001231558494 FL=0
-KNSDLILINGDKDIDFEKKLFSYNAKVKIYYSVYKPINADKFKNKKILALAGIGNPENFFNLLKNSNLSVSEKNFFPDHYEFSKSELSKIILKAKRNNFCIVTTEKDYFRVKDYNLAEIEYLKTELVIENKKQFLKDIMKIYD
->MGYP000160763201 FL=0
-MINKSIKYIGVILLAYTLNACNEQRMSSSSETTTPVWLAEVGKRDVLELTTTTGTAKAAKTVEVKSETNGKYELMINPKTKRPYKLGDIVEEGAVIIKLNNKEHENTVSLPTKKMQVDIAKKEWDGQKAVFEKGGATEKDVLNAESSYIQAQTALETAYTELAKLTIKAPFKGAIVSLPYFTPNVEIASGETMVGLMDYSHMRSEERRVGKECRSRWS
->MGYP003702127599 FL=1
-MSAMKRASSVVKMKPLSSRSKPLPVNDVIAATDLPTPSPASPRGGRASGSAMIRCEFFARDVCENFFLAIFPFMHKFQDDPMITNLKVSEVKNLRKFSSNIWTAIKYMGRNLYSHL
->MGYP001407002453 FL=0
-GFAVLGGLKPALNLLGNVPLSVLTDYNLAVIPMFILMGAFASHSGMSRELFGAGRAWLGHRRGGLAYASIAACAGFAAINGSSVATAATMTQVALPEMRKSGYDAGFSAGLIAAGGTLGIMIPPSVIFVLYGIMTETDISKLFAAGVMPGLLAVLLYFAVVQFLGWRYPASMPLGEPHSWPERWTSLRALWAVLLLFLFVLGGIYGGWFTVQEAAGIGAAGTLGIGMMRGRLRWQQIRAALIDALRVSSAIMLIVVGAYLFGYFLTITQFTQKAVAFLTTLPIGAYGVLALVMLGYLILGAVMDELAMILLTVPIVFPAMMQLGFDPVWFGVIIVMAVTFGMICPPVGMNVFVINSIARDITLARIYRGTLPFATELWDPVLR
->MGYP000300748531 FL=0
-MTVEFTFQAIFGFLSNFVEYLCTIQKRIYGIKRLHHSDRCLLLDDIGPPIETLRSIPLLVSRYELLAHCLYAVTSYQFSFNLVCLDKVTIHITISTIHKMQNILVSKNNKITSTS
->MGYP003495590882 FL=0
-MPTGHWPAEAAHTDEYLQVAPGICYMNIPARDKYVPGGEMWVTESGDAGGGGDTWASTYLDVLRTLNELGSFCTLTNGVIFHNTLASSDYGFLQHGSFDPRPNYFAALLWNRLMGSECYKVEDAPQTEGAHVYCHSSKDGRGNYCYLIINNSLAEETLVSVPKHSY
->MGYP001249907410 FL=1
-MWARIEQTMAKQIRHVRPIARDHADPTTQRIAAQIERDFGAFVPPFALHAPAPAVLAACWMMLRESLVPAHVDRRTKEAVASAVSRLNACTYCVDAHTAALHALGETATAAAIADAAPALDASGALGPFIAWAAATRSPDNRLLRQPPLSAAQGPEVIGIALCFHYINRLVSIFLAPSPLPFKSARLKAIARRLLSPILTGLLQRPLEPGESLAWLPEAPSPPDFAWAAGNPTIAAAFARAAASFESAGAAVLPATVRALVRDRLHAWHGEEMGLGRRWLEDAVDLVDAELRPAARLTLLTAFAPFQVDDVLLREVRRTLPDDAALIAATAWASFAATRRIGTWLTVDQFTSGSRK
->MGYP003567298226 FL=1
-MFSAEVFRLSGFRHDIQAGDPPLPLWWKIEQNKNMNLSRKPRPQLSLGPAAPDLALGRMHEATGPSAVIFAALAAGRLTGPILWARPAWEGGVLNPEGLAPLFDPTRLVVASCPRPLDILWTAEEALRSGAVQMVVAETAEPPALTPLRRLQLAAEAGGANTKRPPLGLILPPRAGTAGAVESRWRCRPSPAWASGQPARWRFERSYGKSGPPLVWETGVSDTIQRRAA
->MGYP003550943715 FL=0
-MLLCPPRLIAERQAAQYEIIFSHGDSLARSIMIRGVVDAVLTLPLVLPPTVTRYFLLRLLGSRRVIGAWLMTY
->MGYP003599591953 FL=1
-MKLIEDWKQAWKLKSVQVGAMSAFFYALILFSEQFVNIWNVIPQDLKNYIPAQWQEYMGMFVGVAIVLARLKKQPELHAPELSGINSLLSMPTQTNDLAWMIEAKKHIGLKEVSGKAHNPTILNWLKSLGAWWSEDETAWCGTFIAHCLKVAGAKYPKHWYRALDYVNYGSKLTKPAYGCVAIKTRQGGGHVCFVFGRDEKTRKLVCIGGNQSNMVCYALYAESEFQEFRWYGMTDRPADKRYNLPIMTGVTATKVSEA
->MGYP001120090256 FL=0
-VRLLLRLLLLLLLRRTRFDLDSRSSLLLPPLLLALLLSS
->MGYP000141974819 FL=0
-MSVIERVLKTGDTMQVSDYELTPLTEVVKIQLPGKHAGLIWNHPKAVIVRTTDGRESHLPVRDVTRIVMWATLAGGLLGAIMVARIYRKN
->MGYP002637710184 FL=0
-TQRKKEDGTLDPIKDLFRSPDIKTIGIHLDVPKGLVLKKSDGAVAEVGIQSGDEVTAINGIPVFTFGDLQYYYDQVGRKSTSITL
->MGYP001617737781 FL=1
-MGEILLIWMVGGWKMYKKRSYDGKNTPRLIHVLMAIIPILVLGGLLVYFAYIKVPEYQQSDTTYSSRQPAYDEYSQQWQSVQSREKQQRENVTAAYKQMSQYTQDQLQQLRTERELQKTQQKVIYPFK
->MGYP000263732607 FL=1
-MPLFIFIRLFHHRKMSAAELDAKLVELKKNLFMLRMQHATNQLDNPLQIAVVKKDIARIKTIIRENETK
->MGYP001213662979 FL=1
-MAFNNFLEGVATQLINTGLRKVAGNLPGLNISVNSSNSSPVADVTRNSRSTKFFRFPLDVEADPGIGNQGHYMMFEINEQDHARLKFGGKGSPMRRVKAVSPVLSNLDQPPPARLDPIQQMNRYGSIQNYEKAVSDYKTKSVGTKRASTTEISAHIAMYMPESVTTGYSAQYTDTEIGYITSAAIDAYEKFAQGNMRGGLEEIGRRDKDLAAALNAMMLNTAGALPGLSGLKAAAEMRSGVVLSDRMELAFKGIDKRTFQYEFKMVPKSEDEAKEIKEIVNMFKLNMLPEFAGNDVHGRSLIVPNTFNIRYMYAGAENEFLHKISECVLESMNVTYGGERYKTHSATDGGAPPIQTTMSLTFKELDLITREQVMMGM
->MGYP003703380869 FL=0
-MVPLLNSPGASWKVLAPYILSTANSPGANWRVMVPLILSACTLP
->MGYP000959007105 FL=0
-MSGTQTETVACDVLCIGGGGAAVMAAISAKKAGADVVIASKGKIGNSGDTIMIGGSYSMDGESAKKKYGFKKANASVTKDVLFEQIVKQGFLPFRTEPCGAVRGGRPGGGLSVLAVGGARK
->MGYP003576775111 FL=0
-MASAPSISDAFRTTLDLFQTGCDLMRQNLRRRYPDAHEHEIDRLLQTWLLERPGAERATAPAGRSTSSPDLRDGTRSGAQNDCGTRISPRTRARDRVRRTVAPAASLX
->MGYP003283773441 FL=1
-MEQGGTLAARQRTRQVDVGGVTLGGGAPVRVQSMLTAPTADAGGALAQTRALAQAGCEIVRAAIPNEAALAGFEALCAASPIPVVADVHFDHRLAVEAARRGAAGLRINPGNIGSWEKVDLVIDAAARAGIPIRIGVNAGSIGRDLAERDDLSVADKMVRSAVSFVEHFEGRGFTDVVLSAKAHDVPTTVETYRRLSRDLPLVPLHLGVTEAGTALQGTVKSAVGLGILLEEGIGDTLRVSLTADPVDELPVAWGILGALGLRRRGAELVSCPTCARCQVDLIPIAREVECRLAALELPITVAVMGCEVNGPGEARGADIGVACGRGSGAVFYGGKIVARAPEDRIVDVLFGEIASRFGC
->MGYP000469828058 FL=0
-SYRRDLVKLQSGRLVCGYIYASAGEGESSTDLVFAAHNLIAENGTILAQSKRFENEIVTADLDIHRIRAERRRMTTYPTTQEEYEWTEFELKTEETKLERTFARTPFVPQNKNDRERRCEEILSIQALGLKKRLVHTNCKSLVVGISGGLDSTLALLVAARACDMAGIGRDHILSVTMPCFGTTDRTYQNACELTRRLGATLKEVDIRKSVTCHFEDIGQDINCHDVTYENGQARERTQVLMDLANKSGGMVIGTGDMSELALGWATYNGDHMSMYGVNVGVPKTLVRHLVAYCANTCSESEKVLQEVLLDVLDTPVSPELLPPEDGKISQKTEDLVGPYELHDFFLYQLLRCGFGPAKIYRLACRAFEGIYSKETIGKWLKTFCRRFFAQQFKRSCLPDGPKVGSVAVSPRGDLRMPSDASSA
->MGYP001221173772 FL=0
-MTIPSALASLLLSQAAAEQQTLIMESLDLISQNSSEDLIASSGSSTQSSSLPSSFGEI
->MGYP001563734490 FL=0
-MSGRAMGWVTVALLFAGCAGVNYRDKYERYLEEGHKLPPSTAEEVKLQRQAYVDAVGRDSPFKEVLWDVAINGHRIARVTLRGDHVYVETRDYWLYAIEAKTGITKWALDVTRPIQYPPTVVHGLDDAMAAQRALLANIQE
->MGYP000046061924 FL=0
-KLDAFFNDNVNYIKRFTNPEHLGIAADVEVPDLVMSSIITGAEIYLPLADLLNVEEELARLEKELAKWQKELDMSVRSSLTNAS
->MGYP003435272778 FL=0
-FIFCLVAFNYTMRELKRGRILNKVTFLEKVIKQIKL
->MGYP000462850367 FL=0
-YIYKRYGTSWRIDKKVVANDPAEDDQYGISVAIDGDYVAVGAPYKNANAADQGTIYVIEHNASANAGSAQVYNYDGTSWIQIGQTLYGKTELSHFGVSVSLDYDGDIVAIGAPDVNNGVVGVYKFGTDGSWAQLGSDIVGEADGDYFGISVSIDSDGSHVAIGGAGNNAAGDDAGHARVYEYNGTRWREVGYDIDGDGDGDYFGNAVSIDS
->MGYP000891392761 FL=0
-YNFFPFCYISRFFVQFICQIPFFFVFMRPSVFLREKRWDASTRKFWIYFNNVELPYLNNLNFS
->MGYP000314751283 FL=0
-YQEAVKWYRLAAEQGIAKAQYNLGVMYRDGKGVLQDYQEAVRLFRLSAEQGHAKAQYNLGVMYANGQGVPQDYKEAAKWYRLAAEQGVAEAQSNLGVMYEKGHGVPQDYKEAVKWYRFAAEQGTAEAQYNLGGKYYFGKGIPQDYQEAFKWYRLAAEQGIAEAQYNLGTMYN
->MGYP001575587140 FL=0
-FLEHMCFKGTFKRPRAIDITSELDSLGAQYNAFTGHEYTGYYAKVEARHLDKALDVVADLYQNPIFNEREIEKEKGVVIEEINMYEDLPQKKVQDLITKLLYGDQPAGWSIAGNKETIKILTKADFLKDRNQHHVASATTVVVAGKFDDKNIFKKIETKFAVFSDLRKKGYIVKTALKFGAEFRVYEKGVKPGEDHAKWILYTV
->MGYP000040707706 FL=1
-MGMLNTSCFYSFGKEMFRKIFYKSCKRHSFCINDTKGLACGSFISLIEYEIASRKTRLPTLPFLSILFMSLFR
->MGYP001557050405 FL=1
-MLEQYKKTAFHESGHIAMTYFAEYACQEVEVLISGDGKTTMEYGNDLLLISAITNCKEYPEMFNDLPHATKLNSPGVAFKASLILLAGSIEESIYMNNGIVDGDMEVELSGPDLLRVQNIDYLLSSIAKNHPSNFIQSNIENIMMTFSIPEIWTSITALAESIYSKDGMKLTKDEIEQNLTSTGYFDHIKKYL
->MGYP002626139264 FL=0
-NNDTAALLAPIAISVAASMGVAARPLVMTVAVAASASFLTPVGYQTNTMIYGAGHYRFGDFVRLGGPLSLLTGIVATLLIPWLWPL
->MGYP001591609445 FL=0
-LTESGSCPTFPIFYGTYSGVAKEFKADITEEYSLMKNQDWFDFFNNKLFTIEKNKLDSINKSKNSFELNLEFDNNLGEDINLETHDLEENNEDITKEENSEDIKLETHDLEENSDSDGKWSDITSEEEYKDVIRVAEKIDIPYFSVNFVEEYRENVFKNFVQEYRDGFTPNPDILCNREIKFKVFFQKAMELGADYFATGHYCQHEYIDGKSILTKGIDAGKDQTYFLYTMQEEILNKVLFPIGHLEKKIVRKVALDFELATATKKDSTGICFIGERNFKNFLSQYIKEQKGEFVRLDDGKTVGPHDGYCYYTIGQRKGLGLGGPGGPWFVAGKEVDTNIVYVVEGEN
->MGYP000075518654 FL=0
-AQIGKGVHLSAGVQIGGVLEPLQASPVIVEDHAFIGAGSIVVEGVLVRRSAVLAPGVVLSGSTPIVELNEKHEKVAEYKGEVPENAIVIPGIRMKGNSGYGYQTPLIIGYKSEGTSAKVALNTLLRDF
->MGYP001377906329 FL=1
-METDQIMSAIFLIAVLALILPGFLSTNNRAKQFMKNLSIWTIIVLIIIVIIYLIKQ
->MGYP003341019630 FL=0
-MLFRSIGAFWALTLAAKPADRTHHYGHFKAEYFSSGLESVLIVVAALAIIHTAIARLQQPQPLEQLGLGLAISLVATALNGLVAWALLRAARRFDSITLRADAQHLLSDVWTSCGVVLGIGLVKLTGLTILDPLIAIAVALNIVVTGWMLLRETASGLLDRSLPDHEQQLVERSEEHTSELQSHSDLVCRL
->MGYP001601917572 FL=0
-LKALATSRAINLIEVEENKLKLRQKNNYLQVGGRFPRLGGRQAGDRFDEIREWIAKLAVARAAE
->MGYP000576050399 FL=0
-MADSKKNDKTEAPKNNIEDSKEQIKEKFRNKDNMVDLDSDPTKLIEIVEI
->MGYP000088332676 FL=0
-MSSWGRPERVVVLLVGEGAVGDTSAVRERIVHQQSTYAWEFVLVDVKRGRRRAAFNHGKLARALQQATGKEFDDDRLPLEQLRFSPDRTACWFRVAGKGWTCVLKTCVLE
->MGYP000901407724 FL=0
-MDSAGERFEAIRAALADRNNILTVKDLCELAGVSRSGYYNWVRSEKNRELREAKDRAAFEQILEAYRFRGYAKGVRGIHMRLLHMGIRMNVKKIRRLMRKYKLTCPIRKPNPYRRLQRSIRMGSAAENLVNREFESHGPRAILLTDITYIPLCGRFCYLSTILDACTKQVLAYAMSESLEVDFVLETVQLLVKHHGISLSKETVIHSDQGTHYTSLKFIQLVENSALRRSMSRRGNCWDNAPQESFFGHMKDELASEIPGWTSFEAAKASIDRWMDYYNNDRCQWDLAKLSPNEYYHYITTGEYPAGTMRRCREELSKLFKRLYEDNVLGRVTDEQYRMLAGDYTGEQKALEEQIPEKEARLEKLKAASANVNTFVEKAKQYTAIDELTPELLRLFIQRIEVGERTEKYSRSSHQSIRIVYRDIGTVDSAMEQGEAQPHIAPPLSEVFELPA
->MGYP001844006787 FL=0
-FGNFVKITXPNLAKRHIYRPRAFIXSQHEISRPLRSRDIARTNKKSIFVGFFLAILSRSRDQIGQNGQKAHLQAESFHLSPTXNLXASPFSRXWPHKQKSIFGVFCQFRQDHVIKFGQNGQKAHLQAENFYLRPTSNL
->MGYP000461460321 FL=0
-MERKSFASLDCSIAQCLEVVGEWWSLLIVRDAFLGVHRFDDYQRRLGISRNVLRQRLTHLVEAGILEKVPYSTRPPRSEYHLTDKGTDLWPVLTAMRQWGDRHAAPNGPPALFVHRSCGATTDTLLVCESCREPVRAGDMKLVPGPGRTLASLVSTSRTDK
->MGYP001244209094 FL=0
-MARNWCSAHAPVGNSESPAHSLESPRLHSSAKRRGDRFTGQIVVGRVGLEPTTTRESVRTSTCQRAIDPLKVTRKKYRLREDGHDPSSSYSASATSGLMPSDGCSARLVTGRDGFLWFPLLFLFVFLFVCLALWVFLKCSGICLVCHSGEEQPMCCVVVDHRVQALLVSELVPS
->MGYP002522304077 FL=1
-MLNNTSTDMDTHPPTQAGIGIATPVCYSEIGAKANQEDALFPLAGEATARQRVFLVCDGMGGHEHGEVASQCVAHTVGTLTAAQPPCDTATMRTTFEQALATAYDRLDEIDTPPSEGRTMGTTLTFLALCTDGILIAHIGDSRVYQLRPGEDVVMRTRDHSLVSDLIAAGELTEDEARTFPQRNVITRAIQPHQERRDRATYNVVRDVREGDVFLLCCDGVVEQLDDASLCALLLAPGSLTDRLAALRDECLRRHTRDNNSAYLIGITAVDSPARPQAAMPTSPVTQPRGRHNWVYVAIALLIALACFLLAQVFMGSKDGARAGKTDPPATETTADSAPLRTIQHR
->MGYP002571109560 FL=1
-MKNILFVIGSGIYPHVVGGMEIFNYYLIKKLSSFFKIHYLSYKRYDYDEGKQLKCFKIKPTKFFAPLQLAYYLLIKPQIQTVVFSYSAAHWILWHLYQKVTRLFNRNYIVVIHYGHTPPVEKKQAYQKFFQQAKAVIAVSNDIKKNYDAYFNINCEVIYPLVPFEHSNLNKKELRENYNLPIKSNIISMIGSLKPMKNPETIIHALCLFTQEEIAKYNPHIVYAGKGESMVKLQELAKQYNLTERISFLGFIPKEKVNDIMKLSNIYLIASDFEGTSVSLLEAMYNELPILASRAPGITNTLNENKDCLMFETKNAQQLKMQLLRLLSNESLSKQLAINAYRNYCNKFSYESIVNSYQKIL
->MGYP000323132695 FL=0
-MIERLLRIDNPPAHRRRAGAVLFDKPRGKTVGVVVQHVCDIALLPKLDLLGLVPCDFFVTHARKKIAQFLRVGRRKFNKFKAVGASGVLWRDLRFRRAVGERTHGNASLVVRG
->MGYP001035366785 FL=1
-MSPRRSFHTISCPLQKAAGLQDDDRPAFIAKPCAQYYKLRAPSSVLGPSRGQQVPEPELVRQDLDAAGLGARAPAAALHGPHRLLAQPRRQLQAHPIHERVHVLGEVQQVPVQELGHRQPPRRRHAHGRLQVLPLRRLQLLLHARRRVHPHLKSEETTASPPGQAHIVTRTIASADCCYCRRPAAAGRNLINYRGGGPAPAGEREGDEGLRPLQPERAALRRHVVAGAGAALAPFRIHLPGHESSIRSAHSATATRGVAPLYRARR
->MGYP000942704436 FL=0
-MAAISKGTVAFSFGVDETYTGGTVTSLSVNESWGNIGEVRNETGTMISKRYDDIRKEGTITVLLEDATVPSSALGSTFTYDAVVYYIDGISEARSNEGYAEYTFNIKEYENMSSVTIV
->MGYP000205166280 FL=0
-EINIERAFPDADHVVLEKAGTAMARILEAINTI
->MGYP003568659006 FL=0
-FYAAYTRSPYFLLQNYRNENDVDRVTGNFTITYKPMEWLDIVERVGADVYADRRRLKYPKFTYYPVDETTGNYTRANVQSATGEYRETQFNVSEIVHDLMITARKKMGSITGSLMLGHNVRQRTSTILEASTNESAGLIVPGWYNLDNSNGPVSNYNNFSRRRLTGLYAQLTLGFNEMLFLDLTARNDWSSTLPKSNNSFFYPSASASFAFSELMKNGNLSDVLS
->MGYP000466899968 FL=0
-ARYGTRKLKKGYRSHKLKPYREVAKAEKAAFKANVNFQYHKALQENPQLTSNPFSRFMQKQKIKRQYAKTVKKGGAATAKAAAGASQTAAKEAAAFAGRHPAGVIIAIAALLLFIMVSVGLSSCGAMFSGTLNGVLGTSYTSEDSDLVEVENSYAGLENELQSRIDNIERDNPGYDEYRYDLANIGHNPHELASYLTAKYQSYTCAEVQSELQRIFNQQYKLTLTEEVEIRYREEERTDTWTDEDGNEHTDTYTVQVPYEYYILNVKLTNKPISELAEKLLTPEQLEMYRVYLETSGNKPLIFGGGSPDGSPSEDLSGVEFVNGTRPGNQ
->MGYP003111832576 FL=1
-MSIATSLGKRLRDWQLVYVADNAFFPYGDQAESLVIDRCATLISSVMAETPIDMVVVGCNTASTVVLPALRAILSCPVVGVVPAIKPAAALSRNRRIGLLATPATIQRPYLDQLIAEFASDCTVTRIGSSELVRLAERWMGTGEIALGDCQRILRPFAEAEVDTVVLGCTHFPLIRYLLEPVLGPGVGWVDSGEAIARRLEALWQQSAAGGLGRAEQEDPVEFSFYFTGLEPPRIRSYLAATGWPTARIHPEYVPSAPGSAPGLARGVKGAG
->MGYP004300484681 FL=0
-PPPHSTQAARWPDARTSSSGSWHACKYAADTVRRLLRTELADALQHGAEAPAEGAPELTRLGEAIVALLLQKEGAIDVRDLFNAAFAAHWHGIDHLAAHFRVGAHHRRPHRRHEAGVDRVDPDIVTCELHGSGFCRKAPLAALAPRAVPLHSLPGAGVPYSQSARSMIMPRSTSGPGSVPNSCVTWSARSHAP
->MGYP001071452416 FL=0
-PFIKSLKLWVNAVSKSPALKPLVQPLVIVLLSAIRAKESHLIFLPYVSIILGMVNDLSLSCETFVPIISSCLSALNMCSNKLASKSLTAEGREPNISDVVRVSDRQLKDKRVVRTLTLMILKELTRHLCFLARTGAFPEVAWPVAQTLRKLAKSNSTLKPEVASLIDSIDKTIVDIKEKRAAEIGTSLFQFSFEETPMGKEYEKVLTKMEKSWEYKDEEGDEEEEDDEDDDEEDEENTKKSMSKEERSKRSIKRQRQNEKKRALKQTVPEDALVA
->MGYP003153901614 FL=0
-DTARAVVDGLAAKGIACPAVTGAGTGTFELEAASGVFTELQAGSYAFMDADYGRILDADGNRIDAGEWENAFFILTSVMSHAKADKAIVDAGLKAQSVDSGLPVIYGRDDVEYVKCSDEHGVVADPKGVLKVNDKLKLIPGHCDPTANVHDWYVGVRNGKVETLWPVSARGKAY
->MGYP003386720413 FL=0
-MGQKVNPVGIRLGITRDWTSKWFASTKNFPSYVHSDWLVRDYLKRRLAEASVSRIQIERAAKKANIMIHTARPGVVIGKKGEDIEKLRVDVARLMKMAVSDVRVNIAEIRKPELDAQLVAEGVAQ
->MGYP001336422905 FL=1
-MKILKKSQERTEEDRRELSRLVQDIIDNVRANKDEALKEYGRKFDACEREQIRVSKDEIEEAYAQLSEEEKELAEQYADLE
->MGYP000344590912 FL=0
-KGDVDFAQKLARLGNVWVNDAFGTAHRAHASTAVIGQFFTDKVSGYVMQAELDNAQKILEYSERPFTAIMGGSKISDKILIIERLLDKVDNLIIGGGMTYTFSLAEGGKIGKSICEPDKVELAKQLIEKAKAKGVNLIMPLDNVCADDFNNNANRQIVERGCIPDGWEGMDAGPKSLELFDAVVNQCKTILWNGPMGVFEKEKFSLGTEAICKSLREAKSNGVNVIVGGGDSIAALKKLGNKDWVTYISTGGGALLESLEGKALPGVKALSNDY
->MGYP001550816469 FL=0
-MVLNYTRFFGVFTGAIERVAVTGREGNIGPSPTDSNLMPTPLVFAHNAQDDIALLPAMSNRHGLITGATGTGKTVSLQVMAERFSSIGVPVFMADVKGDLAGMSQPGAGSPKLTER
->MGYP003138151264 FL=1
-MAKAAATARPRRRERKNIAAGIAHVNSTFNNTIITITDAQGNSIAWSSAGAQGFKGSRKSTPYAAQVAGEVVGRAAMEHGMKTLEVEVKGPGSGRESALRALQSVGFTITAIRDVTPIPHNGCRPRKRRRV
->MGYP003443083341 FL=0
-MGDTLLVRIDPRLIDPLMEQAEACGAAFADELCLVLLGLSTGARDSALERILGRLAHNMTLTLHGPAEFI
->MGYP001435087364 FL=0
-IIESDIVKTFNGDMQASEPKYFDIEEILMKTYLPVWA
->MGYP001431098935 FL=0
-MSHYNLILKNYKIDKTQNNNIKYSFNNIDQDSNSVSETFILSEGSNFLKNEIKGYKGSVEKINSQGDPVKKHAR
->MGYP003304349197 FL=0
-GIRDPLWSRGLGDVYKRQVKYKAPNSWKWVKLN
->MGYP001141817981 FL=1
-ITTIHGFAQRCLRRPALEAGMAPDLSLDTDPATLIAQVVHDYWQQQVLALPPDWLAALQRAALNPALLETLLGTLDGDPALALDPPPPELPPELPLPVGLPVLWQRLWDSFADAWRRDGRALQDELCEQAAEWRGLGVEDTGEYRPTFRKTNDRAAAIDGFVAAAGEQPPGYEAVLAIKPLTTYFHPGPFTKEARKAEGEDRPIRLPRPDLMEAVAALVDGPLEAVLAHACSWGRAELRRRRQRAGTLSYADLLAGLDPGAAATGPTPLLQAVGERYRVALIDEFQDTDPVQWRVLRLAFGGPDHLLVMVGDPKQAIYRFRGGD
->MGYP000931218709 FL=0
-MRTVLAVAALGVALGTVSLGLRSALDGGVLPRLLGVLEGLGGAQLLAGAPGGASVTGDLRRGGEDGRGRRCGAVRLSRRRLQGLLGGGLGLFDGALMPAGHTAHRCDGLGLRRLCGDRRR
->MGYP002812137160 FL=0
-VRNLPFSAVRPFVRGLPLLRSSERFGQFGYFNVRLQSRIDGSEIKSADLKIHQCNESLFPEFALHARQNPLWGLNVTLAAN
->MGYP000364897687 FL=1
-MNSPFRIFLLARAVPALVAAAVITFSANHAVIVGQIVFIAYGFVLAPLFVWAAFSNSFTTIVRRSFLAIGLTSLAAAAAAALTIGQGLIAFTLTIGIWAAISGLLELFAGWSSTNKDQTREMLLLGALTAVLGLVEAVVPLNDVYAVGLFGAYAAIVAVFSAIAGFSGSSATPAPSSSAPSPRLPSGRPT
->MGYP003364664002 FL=1
-MSIFNFFKKSSKNEPTTAPTAQTCESSVEMQSVAVPKASSDEQPVQPKIDTTGAKRVHNLIIVDESGSMSSIYQPALTGLNETLQTIREAQKEHENQEHIVWLVTFDTSHFKQIYANTPAEKAEDITREQYRPCGGTPLYDAMGKSINQLRQMATADDVVLVTVITDGYENASREYNGKAIKALVEEMKGKGWVFTYIGANQDVEAVAASMSIDNHLAFEEDAEGAKEMFARECRSRKKFFGKLNDNMPMCDISKDYFEEE
->MGYP000037013818 FL=1
-MAHRIDERVVLVLRRDVGEARALQEALDGGVRRADARPLLLLAQVRLARGQSRDVQGEAKKMGRP
->MGYP001133519274 FL=0
-MKTRYVVQRKPLIVGLAGLTMLAALAAPNAAWSPLATAAAQDSHGSSHSSGTHGSQNKGGQGQGKGKSSSGDASGSSSHGNSGSKSVESKVLHGSGDASAAADESSDRRGPKYGGGKASTGKPTGAGTKKGDLLGDLNVILRDANGIPILDQYGHVQPLDASGNLIPLTPEGDIVAGSEDLVVPVEFSRLSVSRSPSKVTDKAYDEAIAALNAATAITTDSSGRLVTTVDGVAKTIDSPLENLALYEALMNNGYLPGFVPKDGVSLGSLSFLVDKSATNSDMLQAASFLAAASDKAGSINEDMVVYTDSILGVTGATPLVGADGKDYVDFSNVTYDRSATYTGTVTYLKSNGDGTYSTVTAPIIDAVFGGTTYTGTQLDAFTQAADDARAVIEYVHDNPLPAQ
->MGYP001272594557 FL=1
-MKFGRKKDTNYFELLNSMAECTSRAAEQLDEMLHNYTDVAAKAEAVHGTEHECDNYLHRLVRELNRAFITPIDREDLLQIGSMIDTITDAIEDVANSFEMLSIRKVEKPALDMSELIKAVCTALSKAVKEFEHFRSSKKLSEYVIEVNHLEEQADVLYRSTIKALYNNTHMTVLDVIKWKEIYDYMERIFDACEDVANLLEGTAIKNR
->MGYP003517379434 FL=0
-TLPLYLVRNYESGVNLSGSNATTTTTTTTTPAVCSGRCKWIWDLTNEIWELDSSNCSTATTTTTSTTTTAGSTTTTIALDCECVSGTTTTTNTSTSTTTTTTTASPCSCSYPAYCGTEDGECTYTNCVAGYVTTTLECTTTTSCDCNTTTTTPDCSSCANYICTPTGWVLVDDNCTGNCTAEEPSSDCNFGTSGSCSGLGGISVAGYGCSGECIYIYYDALDDWYFAYGNC
->MGYP003652714744 FL=1
-MSVATSAGYDNLSGGKWNPSIYSQKVLKFFRRSSVAEAITNTDYSGEIENFGDTVKIIKEPTITVSSYTRGAVVNTQDLTDSEITLTVDQGNYFAFKVDDIEERQSHVNWESLSTSSGAFSLKKAFDYNVLKEINDSAVQGTAGTDTGAAGAAISCNTGNKAANVLARYSQQLDANDVPQENRWFVANSGFYELLKQADAKLMDASVTGESMSALMNGAVTSRQVHGFTLYQTNVIQTASVGSAAAFTFGPSATSGETTCLAGHISAVATASHIAKTEVIRDPDSFADIVRGLHVFGRKVLRGSGDGYKGVLQGVVDLNS
->MGYP002630153343 FL=0
-HLTPVSSPLHSLPLQAWTMASLTDLLNEMLELVFLQLEDWQDLISLGSSSTALRQVFIQPRMWRELLEKTRIVQRGVGFEEVTESQVKKIMTFLKTVVGHEPLLEVLNDSICDQHQSIMWRRTIMKLGALRKMGAMRKMGAMRKLRAMRKIGATKKIGAMQWGEFGPQLWEELGQAAAR
->MGYP002515195457 FL=1
-MGSLFLSVFCVFSTLHLISSWKNDRTRRAKTKPFLISSLALAYLVSAEVPSALLLAALVTSWLGDVLLIPRGNRWVILGGISFLGSHFLLMVLFLHHIHFAAIPWFRLLPVAAVYALLSVISIRSIWDNTPTLMLLSFGLYLLTNSCMNLLALMQLLTSRHPGAAVAYAGAVLFFLSDCILLLVRYHRNPDLVPKKHFPVMLCYLSGEFLITLGIFMMA
->MGYP000652960749 FL=1
-MLNSFKNLSTVLKLRKQPASLKAARQFHDCGNFQMLYIASGITVTILLEHPQA
->MGYP001560261255 FL=1
-MTPAPPTLLAGQGAQPGDIINAIAVQRNQLMDALAMAEANFAAFRRAHQGGGCGLDEVVPGERKVPDDAPA
->MGYP001590704470 FL=0
-REAAAGFIPEGGTITLKALEVDSSLSGLRETWPASMPPVTLGLKLDDLSFRLKGFDEPFSGVGGTVSLKGDNITVENVSARYGKSVLKSADATLRGITGNTAYGISAEGTLDAGAGLSLARDITGGNTLPGQRGFPGPRPPAL
->MGYP001590172643 FL=0
-AKSQREIASDSVKLNVLSCFDYSLQTEKTLLSVCDHTTTIVPITLVNSGSLSNIYDLSLKGPSWVGLDNNNILVNSGNQGKVNLIVSPDYGINGNFDLIVESKSKNGEIVKSSDIKVNVKGCNSVNVNIADDKIKMCGSLTNQYNVLVKNTGEVTNRFNLRTSGVDWVSLDKSLVELRGGEETNVILTIKPDKDVISGVYDVRIEAVNIEGNVKSDDTIKIEVVNMEKCYEPNLNISKKSVEIVIGDSVTIPILIENKGSNTADYNVGISGDAVNFVQVNPASITLEAGKSEIVYLYLAPSIQNRQGPYSLTVSVRYDSTTIIDSDTIEINVVEKQGVKITSEEKKEEKKEKGVFSLIWSYKWYILIALILLFVIVKVISTKGEEEYLDEIEELNKEKKIEKKEVKEKKLIEKPKEKKKEEKREEIIKEDVEERNYGFVKYIVGLVVLAALAYVIYRYNSYLGVYKWYILSAIALLIIVILIIRGFGGLIKFFEEDEEFEEVKEEKKIEKKEVKEKKLIEK
->MGYP003651019918 FL=0
-MEFMEFYFYISDITLPQQEYLRDRIERMNVHFNEEEGYVAYGRGMMEGIDRSLSHPLTRTPLSRDTTYLPGAPALPFTVRTIFNGSYTYDPESEWARNSSTILHAFNRDRFSLSLSLSLSLSLSLSLIC
->MGYP003348846132 FL=0
-ASTVTVEANATVDASATQNGNGGYISIWSAVKTAVAGILNATGGQFGGNGGVIETSSKGSLQLPNSLAVNTTAPNGKTGTWTLDPTAIIVDSADVAVVPVVCVTID
->MGYP000962646007 FL=0
-GGCGGPAPGAAKDLRRVVRRDGNRRCHGGRGALEEPKGAVAIASLQEISDTSFERGLVCHRPGSGGVGGGRNQLVPQDPERAEVLDLLDGGDQVVQERRGHHGLQ
->MGYP003955760495 FL=0
-MWAQERVLVTGGRGFLGRHIVDFLRQAGA
->MGYP001189459322 FL=0
-MNKILLIIKREYLSRVRKKSFIIMTILGPVLMAGLILAPILLMDSSDEEKKEIWVCDENNLFEPQFEDINGTDYQFFKNDIIEVKERFNTSDGYALVHIPKFKNESIDVLESSVKVYVRKPMSFSNQNQISNNIESVIESIKLKEEGLTRDIIDRTRSNVNLNTIILGESGSEKTGSTEVSMGISMFGGFLIYIFIFLYGAMVMRGVMEEKTSRIVEIIISSV
->MGYP000827854766 FL=0
-MDNNNLVNDLSGILDGLDSSQEQLEKDAFDVINSSDTSLNLVKESISSVEEILKMIDELNEVAEESATRIKELEKLSKDIEQFAGVISSISNRTNILSLNASIEAARAGEHGRGFAVVASEVRNLAAQSAKSSKEITDTITMVQQSVGKTVDSMKNIYENSNQQKEKADEIGNVLNKVVEAAYTCLLYTSDAADDMQC
->MGYP003969404433 FL=1
-MPLPSKSTNMDNNNNQALRIHQSDNVYVALADLVPGKDILANGNKIHVSEPIPAKQKFSISGLKKGEVVRMYGVTVGEVIRNIPAGGLLSRSNIKHKSDGFVSTDSRYHWDEPDVSPWQGRTFKGFYRSNGSVGTANTWIFVPMVFCENKNIHVLRDSLNKSLGYEKTTIYQDYAKKLAEMVRNGASEEELADFEISKLKSSTPHVNRAFPNVDGIKFLTHNIGCGGTRQDSNSLCGLLAGYITHPNVAGATVLSLGCENAEVSILKDEVIKRDPEFDKPLLIYEQQKFGSEMDMITSAIRETIINLSVANECERKPAPLNKLLIGLECGASDGFSGISANPAIGACTDRLIALGGGAILSEFPELCGAEQSLVNRCITKEIGDRFIKLMRDYAARAEAVGSGFDMNPSPGNIRDGLITDAIKSTGAARKGGTSPIVDVLDYPEKVINTKGLNLLCTPGNDLESTTAMAGSGANLILFSTGLGTPTGNPVTPVIKVSTNDKLSNTLSEIIDFNTGSIITGNKTVDELGSELLNLCIDTASGDYITCTNKMSQDDFLPWKRGVSL
->MGYP001828137919 FL=1
-MLPDKADIVVIGGGVIGASIAYHLSKQKVKVVLLEKSDPAGGSSGACGGTIFLQTKSPGIHLEMALASARRFVHLEEELGDGFEYQRNGGMIVIEHEEELQAVKRHVENQKKFGLDVSLLDRKQAREFEPSLSETILGATFSPMDAQVNPMLLTFAFIKAAKKNGAKFFSHTRVTGFRKTFNRINIVKTDQGEIETQMVVNAAGVHAAEIGALVDLEIPITPRRGQLVVTEAAESVIGRCMLSAQYIAAKFNPDQAQKSGGVSIEPTANRNFVIGSTREFVGFNKGITLEGIHHIAKHVFRIVPCLKKLQFIRVFSGLRPYTPDGLPILGKVTGLPGFIMAAGHEGDGIALAPITGRIIADLIVDNQTTFPLKEYNLERFSS
->MGYP003643276008 FL=0
-RGFKKIAKSPLGKMALMYFGGNLLQGNALFGNPLSGNLTNKLGSMFTGGGGGGGGGGFKGITEGFKNIAKSAFKPENAFATISGISGLSGLYTSYMNNKREDESMADYQRRLEEERGNFAPIPTDFVQFAANGGRMGFADGGDDDDDDESFRSKALGALYSMKRPQFSMGGGAGMPPVTMMSEGQDTQSFGDDESTGMVNATPTMPNQTPMRSPM
->MGYP000011570578 FL=0
-NRFDAEIIIIVDKIFQSEVVDYALQLGITNAFIQEGDVAKESFIPDFDTTGV
->MGYP002350897487 FL=0
-MQIDAIDRRILYRLQENGHLSNQ
->MGYP001584058516 FL=0
-VLYSNKLTALPESLGQLAQLQSLNFSNNQLTALPSFIKQLVNLTVLNIGDNPFDKSIEIIGSLHQLKELYCFKINVPLPKTIGELKNLERLSIMQNKLELLPEFVCELSNLNWLWLFDNQLTELTSSISQLKNLKEISLHKNKLTDIPSSLVYLEHLEKLSLDDNPLNPALQSAYKQGLVALKAY
->MGYP003693669217 FL=1
-MASPTVAANAYAALSRIMESGGAEKGGQSAGGPSFGALLKDAVGSVLDAGKKSDAQTMAMSSGKANVMDVVTAVAETDVAVSTLVSVRDRVIQSYEDIMKMPI
->MGYP000343390212 FL=0
-MNIAIIAHDAKKELMVQFCIAYCRVLSQHSLVATGTTGKLVAEATGLP
->MGYP001158220473 FL=0
-EMSELVQIKDHDQTSNHENEWAEKAKGKEVLMIMSELNYEVLEQLELMQKCLSEYDLYNNTDGKFCTIFMLNKDIGNESQLVSVGMAVGAEVEKVWETYSENNNPPEWVKSFAESYNRNMELLEKWNNLNAKLKKAYGY
->MGYP000395984138 FL=0
-MKKEIAVTERPEIFTEQYLAAFGNMSWYDFVTAMPSLVFVVTGWKSNGKENACLHSWSSFAGSGADNFICILGKVNKDGHMYQSLKETKACVLNFPSNDIYDRCIKTIGNNQFETDEITASGLTAEAALKVNAPRIKECFL
->MGYP001462322588 FL=0
-QATISSDARFGILSKSGADAKKMFTDKVVPISVNYPFFFKPIQDGMDRPKTELAYRVPASKLTRRKLESNEQLRELDGLDTTIDWKNTGDNSYDGEKLKLLAHDESGKWERPDNILNNWRVTKTTLRLGSRVVGKCMMGSTSNALNKGGDEFKKLYQDSDVTKRNGNGQTKSGLYSLFIPMEWNMEGFIDIYGMPVFTNPEKPVLGIDGEMIHQGAVDYWVAVIKPGAVLFEINGLEEERAYKVLKLASYKLPIKTKIISR
->MGYP001101270620 FL=1
-MDRIIFHIDVNSAYLSWSALEKLHNGSCVDLRTIPAIIGGDMAKRHGVVLAKSIPAKAYGIVTGEPIVNARRKCPNLTLEPPDHKLYSRRSRELMTLLSDFSPDLEQVSVDECYMDFTPIRRQYPSPETAAHLIKERIETELGFTVNVGISDRKVLAKMASDFRKPNLVHTLYSYEIQEKMWPLPLSSLFMCGHSSVETLRNLEILTIGDLARTDRAIVESHLKSHGTLLWEYANGIDASEVATVQADAKGIGNSTTLTKDAEDKETAHLVLLSLAESVSRRLRSSGQSAGMVSTEIKYNNFRKVSHQTTLLSPTGQTDAIHQTACALFDEIWDGTPVRLLGIRSSKLVSNEDPVQLSLFDLQTADAGTAADDSFAPAYTRSPRRQPSTKKKEQLDAALDSIRKRYGADAVVRGSLLSDSKKPKYD
->MGYP001545760421 FL=0
-MKRRVAALYGLAIRNAALSQNPMLSTAARPLPHSALQRVQRSGSWQIGLDFDKTALSKAAAESRVLHIELDVVTRVA
->MGYP000446957473 FL=0
-EIQCVTGVQTCALPISGGDGIYLVGVGVGDTGYNDELMDTVTDAGKGASVFIHEPAEAWKVFNQNFVNTMAIAARDVQVQLDMPPGFDIVKFSGEEYSGDPTEVEPQHIAPNDAMVFHQVIETCAPESVDGSAEITVTARYRDAWTFLPKEVSHTYTFDELSAQTTPLMYKGAAILAFAEMIDAWDQLST
->MGYP000532152884 FL=0
-LDVMDGHFVDNISFGPAFVEATAAVATRPIDVHLMIERPDHYVPRFLKSATNITVHVEAKHNVNKTLRAIREAGKSCGLALNPATPVEAAVPYLDLIDLLLVMTVVPGFGGQPFMPETMEKVRHAHAARQIKACAISCQRFMIAAAHMIGAQARPKRQCAQSQPTAKPRFGANEISERRYFSICASRL
->MGYP001076569615 FL=1
-MDDRLTGKLIQMIGELTGKEMKRFEDFVDSPFYNKKEKLQKLSRFIAKYHPNFQHRNFTKQA
->MGYP001614764691 FL=1
-MRGLRAGVYTNGPWGRLRGMSSAMGQMTDVKDRDELFLEG
->MGYP000090456593 FL=0
-MCDDFSSPFQQISSYTLTIEPYLNTYSKQYENIIVIDKMPLGPLSQLVSHFNAPRLSPFAKQTNSCCKYAIRRHYNNTLRRENCFLTADDVPSLLSYLSANGYTINSEITKIVQKTNYNKKNFVCVFYYTV
->MGYP002742331534 FL=0
-YFVCDMYPLLELVCTDTYFIGLTVFVNGGTICIVVFTLLLISYGVILNSLKTYSQEGRHKALSTCSSHVTVVILFFASCIFIYVRPVSNFPTEHFMFNP
->MGYP002712581081 FL=1
-MATLASAARPDDAARVLSEAIARIARFWSLSNAQAGAILGLSAPTVSRLRAGNWRLEPGSKPFELAQHLLRLFRSLDSWLGQDDAAARSWLATPNLDLGAAPIALIASVRGLLRTADYVDALRART
->MGYP000897634123 FL=0
-MDDVGPEAQLGSGRPVAVSGEEEIGIDGDRRGDHQGVGKFHRPVGGTDERSGPRDVVVDGVHPNGEPLEPSVDRSDAPWPAL
->MGYP003681647399 FL=0
-MYPLDTIHFKKPETVLALAKSLELTGNAFTFARLRLETNIETNRVMRSSITWDSMSEAPSQGKASAP
->MGYP003287676207 FL=0
-MLAGLAKFAYDVVLDNLSESAVLAAHHFGRANSIFEMLSDRYRAARAKFLLGRAYSAAQPERAAEHEPAADGPADGSEAIRWTSPDWPTSPTKPKPSCGCGVCDPAETLMNIGSFICS
->MGYP001816890121 FL=1
-MSDGRPPFHLAFPVNDLEQARHFYAEVLGCPVGRESDRWIDFDFFGHQITAHLSEPGDAGSANLVDGDAVPVRHFGAVLPWARWRDLADRLAGQDLEFLIEPKIRFKGQAGEQGTFFVRDPAGNALEFKSFRDPARLFARA
->MGYP003627722903 FL=0
-MDIFKTLILDTPDTLSNISGILPVSNGGTGADNAPDARVNLLPSYTGNANKVLSLNGGATDVEWTSNGAGDVVGPASATDNAVVRYDGTTGKLVQNSGVAIDDSGNVNLADNSSLNWSTAPGRPYIVGNKASDLIKLGTPTGGDLLNLVGSNVGIGSTAPAKNLAISSNANSQTTA
->MGYP001002779910 FL=1
-MTAPSAPPHPGNTVPDAPYDARPASASTNRLKLGIDFGTTNSVVVLAHPDGKTETLRFRFPEHAESDTCRTLLCFWQDEVGSRIIQQEAIGAAAIDAYLEDPAESRMIMSMKSYLAQKSFRETQVFSRRLTLEMLIARFLSNLMQAVAIDPASVDVTVGRPVEFAGDFPDDALGAQRLRDSFTAAGFPSVELAWEPEAAGWRFAQRLENPTTILVGDFGGGTSDFSVLRFDPARPGHAEPLGHSGVGIAGDQFDYRILNTVIAPLLGRDCTYRVMGGEPLPVPIEWYASLGRWHRLALMRTPQTLRAMEDVARTVSEPQKLRALIDLVQDQQGQALYRAVGAAKNALSSADSTVLRFQHRSFKVEQTITRAEFESWIAPDLAQFDSAVDQALTHAGLTAADVDRVFLTGGTSFVPAVRNLFIRRFGTERVDTGGEFVSVAEGLALMSGKAAHAA
->MGYP000271019841 FL=1
-GTAADARSPVHRATLGDPRGGDRIRRPDSRGHRRASSLAPHGRLGRIPLRPDDVRGVAGRGRLRGADARGTRRGRRLADRAGAVRLSGRDAEDLGVPARWNPRRVRRASTEHESGDLLGSTSGRDRRTRPRRGSTRHREACASDVLRDRLPKTPRRAPAKARLRLVRSPPALGRSTPAGPIHGLRRRPAAARRRGRRRERQLLIGTREAAAQTRSRGSSRGINALRAARRVAPSARPEVHRLAQERRQAVRGGHAVEPAEPPCAVRLVTERGEDAHG
->MGYP000735556993 FL=0
-MKKNILYVLLIFIFIACDLTKEDKKNTVRGDIVSIPITEMETDYGKLSDFAEDIKMIPLEFKDECILGEIRKVVMSDSYIFIMERNNPKGVYVFDHMGKYLYKIGNRGQEPEEFVDLSDFSLNEEERVVYLYDLMRTKVLTFSYEGDFIKDIPMNYYADN
->MGYP003340149605 FL=1
-MGPNIANAIIIYLSGRVIDELINESNTKVEQGDFKLLDILHHFTSGMKSISTDMMYRGTDELRSSCGGAGFHVASGLVTGFTDHAPLATFEGVNTLMTQQSSRYLIKQVKKAKSGKTCKDYFEYINHLSKLVSSKSEAKTLEDC
->MGYP003571959109 FL=0
-GADSRVAFTENNSQTIGDYGTESHGSIDQKDGQPGCLLQAKSEETLGRKATGPFSMKKG
->MGYP003329312794 FL=0
-RRGAETSGDIDIIINDQPTFDQFIKDLVDKNIIVEMLTDGKTKKLTVAQLPGKTPRRIDFLYSPPDEYAFAILYFTGSKEFNTSVRERSLKLGFSINEHGFSKMEGKKKGDKLNQEFKSEKDTIDFLKIKYREPSQRNSDNLEEIIEISQPKSDNSPKKTTRKKRDSNKKNKILEKIEELLL
->MGYP003570303464 FL=0
-FLICQTFHFXLXKKHTTAXSTLCQIFTTQEKPRALLELFLKMLSKFLIFKVKKKLDAAALTLFKNIQIRLFQQEPVQYILEQAD
->MGYP003863973903 FL=0
-MRLCLSPRRPYRHRRQARVDGLHSVIVKAEPIDIYRMLRLHNPSPYMYLFQFSDGISVVGSSPEALVKVNQKEVMVHPIAGTRKRSASPEIDKKLAEELLADPKERAEHLMLVDLGRNDLGRICTAGTVEVVDFMHIERYSHVMHIVSTVIGELNDGVSVVQALSAVFPAGTLSGAPKPRAMEIIEELEPTRRGLYGGIVGYI
->MGYP000597221545 FL=1
-DQVADARLDHHRRVHAGKLRERQLAAHHLGILLVAARCAGRGDIVLAVDRRQTVGVLRNADHEARIGTEGFANDTGGGRQGLAQRLGPAILDFVPGDDRHRALGFKDRRAGLGARGCALGNIAFHRRGRIALPRDDDLVQFRRCGLLGDSSGMKGKETGSGEKGYPGVHGPSNKTKEIHD
->MGYP001178354147 FL=0
-MEIMQDDLHKVEYRVWFSDSHRTLYLDTYMVWERKSKRHGWVVKASYHRLYDRYSTLTLAEVPFGDDIREMVKKEFMDSVTVKVWEDRK
->MGYP003521894557 FL=0
-DYHPVTEVLMALRQRPFDKAPAFDLDDIWKKYRWQLATVGVLITLVLLLAASLDRYNRRLRQLKVRAEEGDNRRTIRMSATPCSSCTKQRPKP
->MGYP000829874590 FL=1
-MFEMKIHTVRKYGLTINDEDVYFSSKGKAIEAGKISIKLNPNTKLFEEYKLCLLYTSDA
->MGYP002763718406 FL=0
-MFTADAHYKRCGYPFFCKYLCPQGVLEGAIPLSAVDSGIRAALGTLFSWKLGILIAVIVLSVLFYRPFCKWLCPLGAFYALLNKVS
->MGYP003059114969 FL=0
-MPDRIPVAEKDFMFSAITEEFGLIFSIALLLVCLNNLILMMNIASRCKTLFYRLVAVVAFAQITPHFGNGPVLANLND
->MGYP000926614758 FL=0
-PNWVPSIWGVLETDPATLAQPRAAALRTKARTMVVASEASGKLVELDTMLSDLRHKADAMSLSLSDGSLRQQRSRLNSLRDQAAVQEAAVFDTSGHVIAFTSDEKDALAPVLPSSEVLRDIRMQRSSSRIRVAVIEPRFSPRSPARCSKCALAGAACARRSQARWALPARLASTRR
->MGYP000302371285 FL=1
-MAKMAPGNAVHGDAYKYDLMGEYQMLADVAFKLSVNNLTDKHYADMLYRGHYIAGKPRTLQLTATAKF
->MGYP001304573571 FL=0
-LLNEIPFPKNLKNVPTIASNHHEKLDGSGYPFGKQEKDLSIQSRILGFSDIFEALTAPDRPYKRANTLRESLDIMYDMCNKGKIDKEIFKVFLNKKLYKKYAKKHIHKNQIDGIDINQYSFS
->MGYP001161862952 FL=0
-MKERGISSSLWKQSSMLIETFTENHTIECAVDNIAYCSCHNCTDSQNQSSGCFFTDKGRKEPSYTENCYNSEDTKNEFPGFAPHFHPEGHPVIFYEMQNTPVTKQVNFLPDLHMGFDPYLQNLIRQ
->MGYP001557844164 FL=0
-KTNLFVFFNRIGLKDEGSYYLAELEDLGKDLKIRHN
->MGYP000311311414 FL=0
-LVMFFIFSLSLSFSFYCVFSLIH
->MGYP003155641669 FL=0
-MIWSNRFQEILADLDRPYAPMFRLQIGTTAITYHMSETERISGHKVLEILSHPGTASYPDLSAPNPQLEGQGNFSNGYTSGPYKYVVGLTSRISMGAQSVSPRSFKYTGASLQVDVSRKAFSLATKIYVGAMAVLQVCLDDPDDPT
->MGYP000405580788 FL=0
-AAQANLQAAKQDANRLQAERSAAVQQRQNTRLIAPADAVVISRDAESGSTVVAGQAVLRLANPLSLWVKLRVDQARSAGLATGLPAQIVLRSRPQQLLSGKVERVELQADAVTEERIAQVAFEQIPAALSIGEMAEVTLKLQPADQDLDADFGGGDRIGDALGRAVARKGRRQRLARRQKHLPEPT
->MGYP000037092074 FL=1
-MINLKLIATNILSNENKLVYEIIYDAAGTRYSYLDGELDGGDGPAVEKTNGDKEWYINGELNREDGPAIEHANGDKYWYVNDKLHREDGPAVEYANGRDVWYLDGHKIKHDSKTWSQLVKDSEMEREIGRVMDA
->MGYP001501362630 FL=0
-QAFIQHGNTAGESGFSSVDTTSVAAGVGGEIAFHGKYNTGAQDYAYYGHIRGIKENATNGNTACALTFHTRPNATAPIERLRIDSSGRLIVGGGTHAGGSALVVKGGNQNNYSTIGMFSNHTNPANNTLLTQIRFGANASAVGADIRVYADADWGTNDYPTRMEFHTTPDGSNSKQVRLKIEKDGRVNVLGPKLKLPTGTSNPGSSVAGDSYYNTSDGTFKIYDGSIWGSVVVAAKGTQQNPAANSTELAATGALAQYYFKPNTGDTAFQQYACGGLSNLGTIPSGGPSWVNSHSSLIIIEKGQVGATSTMKMSQANYGKFIKESITRNSGTTPYVYWAVFDGGTLWGIWRIRWTGATYSTWFSNHNYSEGVNTAPSGTPSSDVWKTGSGTTGNALATGTYTISNNTSLNRAVLPEQDYNSAGSWGIHYKRLGSGEHYPWRNSAGNYTSNGYFEPSTSYSMGTDTRYIHYVYLADN
->MGYP001058876537 FL=0
-KSISTSRISSAKEKEKLEEESLKSTSQLLPVIDDIIIKEDPRKFLKNIVQFDKGSTCTIYTAEYNGEEIIVKEMIIDKDNEQPLLEETRLMASMDSQYIVKFIAAYRVDDHLWILMEYMDGGSLTNIATLCDCQEEHIAYFAREILHALDYMHKQHKIHRDIKTDNVLLKKNGEVKLADFGFTAQLDKKRPVRKSIVGTPYWMA
->MGYP000564650396 FL=0
-LTVSSTKLDALKKDFDNWAHVSESADFPQQ
->MGYP000266732317 FL=1
-MAQILFYTLTVLIWGSTWLAITFQLGRVDPETVGISPERLEFLTRTFQDYVDNGQLPGAVVLVARGSQVAYLALLLPLPDGQPHGSRLRQRLDYQHPGHYRFLREVPLEERLVVGDVLDALEGVPLLGDEGVDHEERVTVRKYGACLLYTSDAADE
->MGYP000394770065 FL=0
-PWLKELAGIRHEFEARMAQLLPDSADALAAFLAEYDLGPATAFEGILQGIENTNYRLETPAGRFVLTLFERRAAAHDLPYFVALMAHLAGAGFPAPKPIPRRDGATIGEIAGKPAAIVEKLSNYALVALEFSSFAPDSASAMMARLALGVAGQKVVDLEAVLVTMLKQAAGEHIGHPEVLGDILRKATRKR
->MGYP003657985056 FL=0
-GVVIASYRPTLAAEEATGGNTIATLGNYTVHTFTSSGTFTIPADKRVPIQYLVIAGGGAGADGGGGGGAGGYRNSTIGELTGGGGSAEATLASAAGSYTVTVGAGGAGTSSDGNNGANSAFGSITATGGGGGGGGGRVGLAGGSGGGGGYFTKSGGSASSPTQGFNGGTGGGAGGGCAASPHNGGGGGGASAVGTNTAGSTDGSGGDGLSSSITGTSVQRAGGG
->MGYP000700515465 FL=0
-SSDVCSSDLGFADQGADRASLVAKGQHGPAYHEADHRHTQGGHTQKTQKRTECFADGNGQRMNDGAEAPDHDRPGISFFGTEFIDDTSGEQHADGITELEYRCDIGIIAVRPPEFFSKVGLQQAQYLPVEVIDRGGKKQQGADRPAVFADCFPIHMKHFIFCRPG
->MGYP001095249562 FL=0
-KSLLDITKCEEGASLQFKQTDLRDFIRNIIEESAICVLGKQLNLIENVQDIPNFIPIDETALKRAIMNIMMNAIEYSPTKGDLMFSVEMISEKLQFIVEDSGRGFTEEEMHSATEQFYRGDKSRNSKDHHGMGLYIAKSFAKQHGGNLYLSNSEKLHGAKVVLEISA
->MGYP000020363101 FL=0
-LLKQLKPTSVQQLAATLAIIRPAKRHLANQSWEKILKEVWVKPTNNEYFFKKAHAFAYAMSVIVHINLLCEKIKS
->MGYP000387930855 FL=0
-MTIDEKLQHFYEVSVEEAKEDAAKAIQEHRESLSQMLEDHKAARRQSAEAEVKAEAEHVRREINKALAAEQITLKRGWSRKQEELKETLFVEVQEKLADYMATQEYQQLLISQIREILKFAGNEEVTIYIDPADQSCLSGLTAAVNHPLTVSEYSFSGGTRAVIPGRHILIDNSFA
->MGYP003117850129 FL=1
-MADTNGFWTTAGARDPKRGFRFRVSFAGGTNSVLNGIAWYAKKATKPSVSFSEASHQYLNHTYYWPARTEWNEVDITFVDPVEPDLCDGLTSLIESVGYVVPAGGAFAPADFSTVSKSRSVAALGNVQVEQIDEDGAPLETWTLNNGWVKELTFGDLDYGSDDLTEVTMKIRYDWASVQIRNAVTKKFSLRT
->MGYP001108639497 FL=1
-MKRFALIGAAGYIAPRHLKAIKEVGGELVAAYDPSDSVGHMDAYFPKAAFFTEFERFDRHLNKLQEAGTPVEYISICSPNYLHDSHIRYALRNGAHCICEKPLTLRPWNIQGLTNTAQATGNKVFTILQLRLHEQVIALKERVEQKWLKEPDHVFEVDLTYITSRGNWYYASWKGDEEKSGGIATNIGVHFFDMLQWIFGPLTSQKVYLRTHDRASGMLSFERANIKWFLSINESTLPETATNEGKRTFRTLSFDDWSFDFTEGFTELHTQSYQHILDQGGFDEKAAENAISIVHQMRETALTPLDDQAHPFAHLPLEEHPFYPKR
->MGYP001328585271 FL=1
-MRHVIDARESGSQDYKCWFFISVVNRLTVRMSYPYVTHNNNVTKEQSGFAQNRIQVVRHKVDLMFDRRRQRPSTVPLL
->MGYP001616298175 FL=0
-MAKQFKTNVVVLGAGPGGYTAAFRAADLGLNV
->MGYP000014566423 FL=0
-DKSFPKVSIIIPVKNEEETITELLDSIFELDYPKDKMEVIIVDGKSTDKTVEKASKYPVKILFEEGKSPNNARRIGIQHASGDIYIFTDGDCVVPKDWIRRIIDDINEEEIGCVGGSVFVEKSLQDNLLAAYSDHSIMRVMPLVEEKEEISEVRVFKHLAFCNMAIKKRALERTGGLDPTLKTFEDVDVVTSICKIGYKVLRDPKVYVWHKHRHTIREIIRQTYNYGRGGPKFRRKHPDTPIARFYTFGLTIFTAYFFILILSSLSGIILSNIRPI
->MGYP003409085276 FL=0
-MAIESTLYGDRKVFTVAAFNSGVATWLRRLPELWVEGEVTELRRNEAWANVFFTLKDPASGSCLAATMPRRRFDALE
->MGYP001804777217 FL=0
-MLVLHPSCEINLLISLIQVLSSTVNAVFHPIVTTSRELLVNIMLCWFLLESYISGAVKRH
->MGYP000216902384 FL=0
-VPADQAGMVVDGDAAAADGDAIPSDFIQGTFKPSETTVQAQDSYEYPFLGLTMKLPEELLKQIKEQTIAMITNEGWNDNADAIKYAYISWSEMTEEQKEAEVDKLGTAYDDWYNSSVEEILYEDPDGIGDMIQAVCKLIHSCVDAGEYKEAFRTGRRLFMQEILTDDEYMTGPLEVEDFICCNELDIDLKKIALDTLYACYQVKKEAERADIMYEIWSNSGIHDLKLEDVMQHGD
->MGYP003292492700 FL=1
-MNKKISLVTLGLSLSSILILTGAMIISQPKYTLKNIVGKQSSLGDVVVYSQSKRGIYSNDSVILSKDKYQFNKNVNQNPDLYKYSKNFNKNRDIFPGYIHDTGSIYSDENSIGYIEYIDEQYGETDITLSTTIKDKNLDTGEFTQFKIEIPNSLKSENNNNHKGLVTKYNGEVYIALLGEQENNPDIKMGEKDELENFVEISKVNFNSKEAKSVNNINLKIDDKSKYRIVYHNPFVIDNKIYFYLENQDKLENSYYLAYYDMENNKFDYIDNKINLEFPLESYQQDIEGEKLNLLADIDNKNKVDLRISTIDLTTGKVITNNEEYSIKKLNKEMGIDGFRIIDNKIYILASALKSYYDVRDYTENIIVLDKTSKSTLYIGEYKQGNEFKANSYILKKDEL
->MGYP001325456118 FL=1
-MNVAVFSDKFSGTLTAKEALSIIKDVFQASSINAEFFSVTDGGEDSSKIFKEYGFKQFEAFRSYNCDGTEVEVESLNINGLKYFETAQLIGINSIKDSLEINSASLFKVLQKVNILGTGGSKTVDFGVGLLSKLGIDFLSNGERINNPTPKDFPLINSVSTKEFDPDINLKVLADTTIPLLGQNSAYDVFGPQKGLKQEFIKQHQIETERLIELLAKELSLELNPYEQLSGAAGGLSFCLHQILGCEISSGSKYFMETTNLAEKVKEYEIGVFCEGKFDESSFEGKIIGELLKNFNGNSYFLGGQYKAESKKLFTNIFECGEAGLNDPKGTLKIATNNLIKELT
->MGYP000616556949 FL=1
-KPTEEAIFYAACKKAKLLMYMKKMKIINTQNLLRLCYVLQELKHQKQEFIR
->MGYP000530409509 FL=1
-SPPVNSEAQEDAAGISKDATIEALQKTADSNVLIQEYSNTTQEKTTETVDVLKEILELMKKMSADNQSGTAGGDGGDGGGMDIDLPDRRRGPRRSRGRLRARARMASRGIRGRVGGLARGLVSGARTVGSAILSGGARTLGMLGLGTAGATGAAGLGTAGATGLAATGATGAAAGGGCGHAAGPQQHRP
->MGYP000350425517 FL=0
-HRPEDFLAVDPHGGRHVVEQARADEVALLVTGHLEAATVDDELRAFRDAQSWRRLEVGAAWIEAQEEWRGARFYPDANSTLRVTYGTVRGYRPTPDAPNGGRRLATDRARPGRSRPG
->MGYP003641307857 FL=0
-GGTWQXSGHAHSAYPLQDXSLSPVDKALSFAGLLWKKLIMSSAKRTRSRSIWMLRWLPCMSRVSHGESFGQTCTRETGAAIWYPAKPALSPFDRLTAASYLRAHPFAFKRDALLLRQHNSVQSANGHGSSLTDRNDRETDISLFSQLLGRRCATVFSLHSAIFFVNY
->MGYP002623368859 FL=0
-IKFPKVTIPVKPGRNIAMIVEVAAKNMRQKRLGYNAAEELNKRVLKSIEERKASKTLG
->MGYP001326310147 FL=0
-SQADLGKTQYGSAPSPNKLMDAYHSMYQDQKEQTLDEEGRNIFGSTPQLDKVEKIKKYKENADRVLRNKKPESGNDNTKNLNNSVDLLAAYRAVYEHHKKDEDGNTIPHEDDVKEGKIPAGLQAYLDKKKGKKKDDDDNGNDEKESKKKAKKDVKEGYDLVYNHFISEGFSEEETYERMSNLTEEQLDEFLKALAQAGMRGAESIGKKTQGLAARAAQQGAMTDPKFRKLEKVQGPRPNRADQVLDDLRTRRKQQSDNLRGRLDTAVTQLRSKEGLKFGGSQSSTLKSTPTPTSSTSKSTATQTSSGNTTIKPQQKKNNNLLSTDNLVKAQVVGSMLSGGGNQQKKKTGQVSSVQGPSQAGALSSIRRSRGQVMQDSFDLISNELIKEGYSEKETYKIMSNLTEDQIEELNEAIVSGTLATLGVLGKLLGGGVAKAAAVGKGLATAAKGGAMAVKGAAKGAMSAAKTTMTGTKDLANKALTKVQSIAKPPSKGPKITSSGGDIVQGSDQAKNKILSTDNMMKAQMASSMLSGGGGQKKEKTATVSASADLFDIVKGQLLDEGLSEEEIKDIMLTLTPEEILNEMGAKFPAGKGAKYRETPKPNPQKRLGDRTDGTAGSYVEKPQKPQK
->MGYP001574869672 FL=0
-MNTPTESAAQESELLKGIVTEAMRRARHFRAVVGSDYDFAYKELETFLYGILRGAPQPPITKDAKPTNGHAADNENAIPPGAYRDGYAAG
->MGYP001569408988 FL=1
-MTRKKEEFKSIVKGKVGMYTCGPTVYWYQHIGNLRTYLFSDFLKRVLLYNTYKVNQIINITDVGHLTSDADEGEDKMEKAALKEGKRAQDIAKHYFDVFHVDLHKLNILEPLNWTKATDHIPEQVTLIEQLEKKGFTYKTDDGIYFDTSKLEDYGILAGIQKDQIKAGKRVDIGGKKHTTDFALWKFSGEVGKRQQEWDSPWGVGFPGWHIECSAMSMKYLGKTFDIHVGGEDHRQIHHPNEIAQSEAATGKKFVHYWLHGAFLLDKEGKKVSKSTGGLYTLSELEEQGYAPMHYRYFCLQTHYRKPLQFSFENLDSAKNAFERLKRKVFELKATEHTGRDKTKEYEKEFHSAINNDLNIPEALQVFLKMLDDSAFDTCKRIALLEKFDTVLGLGVVEFKEEKFTVPQDIQELIDAREVLRKEKKWAESDILRQRILEKGFRVIDMPQGSKAEKI
->MGYP000341628933 FL=0
-QRGPKIASAKINDTGKKKSYRKSTIHQAEKKEKEPSKFKRNIRESNTSIKTKNTNLHIAGRTGALAAGAVTEQVEGGQEVSQAAYLAYEVSRPVTGTASRGASLFRRKAAAEAKRRIKKVETGKKLAKKMGKKAASDTAKKVAGDTTKTAAKETAKNTAKETAKNTAKETAKNTAKETAKTTAKAATTAAGTAVAPGAGIAVGMAAGYAT
->MGYP001115643208 FL=1
-MCSRKKWPNSSGSFVLSLFFPMDGKWWLTFHIVGLGTASFEIHDQHGLQKIIYEEVCWKWCFSLLLEANRLVYIGYRLAS
->MGYP001336892370 FL=0
-SKLGIKALFKILFAENDVVVSYPGDRMIIPSKSTWAETQILRVLPIPEVFCPVGSRILPPDKFINSKLTYFKENFDKEDEILSESICEYAFSFPFEGETQFELVLQKDSLLGEILPTAKSILTLALEDDDRTITMETTLGFPSSGVVYIENEAIFYTSKSLNQLFDCKRGYNGVAVNHPNGSRVF
->MGYP003760760195 FL=0
-ARIPAELVVLEVGLGGRLDATNIIDRPAACAIASISLDHREMLGDTLAAIAFEKAGIIKPGIPVATGAQPAEALEVIAARAAALGAPLLARGADWHVAPTATGFTWRDASAKLDLPRPSLPGIHQLDNAGIAIAAIRASGLAVADAAIAQGIARAQWPARMQRLTGHLAALL
->MGYP001290313395 FL=1
-FRSALARFKDAEAFILLNRWSIKYFHSDGPIMPYVLFQVWSFIAPGLYEKEKKLAMPLFISSVLLFYLGIAFCYYIVFPLVFGFFTSVAPVGISVTPDINSYLNFILKLFFAFGLAFEIPVATVILVRTGITSHSALAKKRPYIIVCCFIFGMLLTPPDVISQSLLAIPTWLLFEFGLILSRFISVKS
->MGYP001572697057 FL=0
-ADEVNFPSLPGGIGQKLILRTAFSPPVTINLAATSPEGQRGGDSQGGAATAVMNALKPSIEEPATGLRIEPWGSPGDWRIPLGILLALAAFGVYALARG
->MGYP000217052795 FL=0
-TLFRSFFNDPCDLLLSLSLAPIMSFDEDYLVVSLNELSYEDESLPNNTLKISDVAELIPLTEIAFSGYDRKFSTGMIWTHPSKYQFDDTFLDFSKLQIRKDAEKNFNFLNEVYNFNEVERHINEDIKKEIIEASICKRLLKKSDLNIKGNEFPHVYCSLMIYEQGSHLSRESAMGFLMHAVGVYILHKGYGSQLTSKIELNNST
->MGYP000907485586 FL=0
-MLRWQFVLVGVVALTLSACKKNEQPTAMPAE
->MGYP000122865995 FL=0
-MEGVGRGMGFITSLESYSILTRLNQHHKSELFLTSLNHMSESFPISLIQHKFASSTPIWNDALANLKRLRIAYLRLIYPVLSLAGQFV
->MGYP001557166919 FL=0
-TPLEHTIPADSLLPVELCWRVLAEVEKDYSIMVQVIGPENSLISNRRTFPGLGRYPTSTWQPGAAWCDLIHLLVADKGIPKTLVYKIEVGMLYPELDDRISIYGTAGDQIETFAADVLITQDADESVSLLDTDEIMTLLDYQVEPVWRPGQANQFVLTWAVSSPISEDYQLYVHLRDT
->MGYP000281517610 FL=0
-MREHRRLGAASLAVGATLLLSGCIGAGPSVVVGSEVNIGSTVSFTSMNPQSQSGRTDTNIAVAAATGARFFNFDETAAVVFDPSFGSVTKLSGDPLVVRYTVADGVRWSDGVAVDGADLLLNWAALSGVLNDPRLSRADVFEENTDGDGEEFRADLPTDAVYFDTGVNPARPRGIQLARAIPQLSDDRKSITMTYSAPFADWAIAMPSAGLPAHVVAGEGLDVEGSNQAKDAVIAAVLEGDTAALGPLSRFWNTGFNVADTAIDGTSSLLVSNGPYLISDIVAEQFVTLSPNPNYVGAHRPEFETVTFRYFSDPLAAIQGLSIGAIQVATPPLTASVVSALGALQLDTQAGYSARWEHLDLRVTESKSGVFDNPLVREAFLKIVPRQLIAGMLTEDADAPAGPRDSFLFQPGQDGYTSASRANGDYLLASPGGATAAVALLAEAGVTAPEVCILYPSDDPLRAREFLAIQGAAAPAGFVVTDCSSADWQDRLGAAGEYDAALFSWELATPGISDLEQIFATEGFENLTGYSNPELDALFSEITASTSVPERRALRLKADALIFSDHYGLPLFNYPRVTLFDEDEVSGILPSPTASGPYWNIWAWKPVLPG
->MGYP000572280030 FL=1
-MKDKDLLKLLLKNGWKDVPVGLLNAILKRTGLK
->MGYP000287529352 FL=1
-TMEKALKIEKYREIREKKERTSQDLEGSPKVP
->MGYP000977872181 FL=0
-MMTKNPGQDEIHMIATNRRARHDYTIENSLEAGLVLQGTEVKSLRE
->MGYP003566039669 FL=0
-ERQLAEAVMKLKPTTSIQEKLWSRITADVDLMSDYRLIRLDNALAEPPVYVFVIIIGFILTMSCFGVYQPQAPLVGLVVLYTVFIGLVRFLLLTLSDPFHGIGVQPTSFELKYALP
->MGYP003578873141 FL=0
-EGHLRAQLRRAAEFEEDVEVTSEMTHAKENVFALRVKGTSMIDALVNEYRTCRPDLVLTHSTDDPYNPDHPTAHQISLQARVYAQAEGYPASGRPIGAPPVFMFEPHQPERCGFMPDVLLDITAVWEQKRKAMESMEAQRHLVDYYSDLGRRRGTQAVRNSGRKGITVLTGEVGTGKTTLLRAALEPMKSTAVRYAHLSNPTLTRSEFYEFL
->MGYP003526032744 FL=0
-MRLSLRWQEALLLVSGYTLLALQPSWMPNVGLFALHGLLVLLLGWMAGQRLFGSGYTAFERFGGGVLTWASSLSLVHTAAYYASIPLTTLNTTLLEAVIAAVVFAIPPLPETSPTNAPVAPVALHQRFLGLLAGAVGIGSAAFLFRAALLHPATVSIRTPWPLLPNGVFLFFALCFASGLVAAHVTRSVQTTWLAAVSWFTISALPALLYPLGYGFDGFIHRASQELLLRTGTLTPKPLYYIGQYVWTVWLSRWTELPLTIIDTWLVPASIGVVIFAFVGLLRRSSPSLRWAPWPLLLLLPLGAFVTTTPQTWSYLLGFSALLIALWPGLQGRAWIFPLLISLWAGLVHPLGGLPFASIVWALGIGALPIFKRYAVPVRIIGFIGALLLIPLAFWAQSRLGNTPIRWSWDWLRWEVLRTSFADLLLAPRQTLTLWLDGAEWARTAVSLGGILVGAWLCLRPK
->MGYP001228241971 FL=0
-INLSLKETGSMKIELIIDAIAVLFLAIGGSLYFSYSKSRIKGLQIWTPISKRLILNFLVPLATGGLFIIILYVQNQWQLIVPSMLIFYGLAIINAGKFTYSEVFYLGLAEILTGLISAISPEHAIFFWSFGFGLLHIAYGLFMYRKYEV
->MGYP003467506258 FL=0
-EHVFDDEHALRPAEPAERGLRRLVRLRDPSLRHEIRDPVGVVDVAERTPHDRLREVEAPTAVGGERRREREDVADSAVRIGRKIIELLGARDENGYVFRVDMRLRPSPEVTPIAIPVEAAISYYESSALAWEQAAFIRARAAAGDKALGDYFLKSIQPFVWRRSLDFGQLANIRKMSGQIRDHYHKGQVLGPGYDLKRGRGGIRECEFFAQAHQLIHGGRDPGLRMADTRTALAALA
->MGYP000492251796 FL=0
-DMTGSASVALPQITAGAITSTGLNSTTGTVQYTDGGSAFDSSDADGYPRFTVTNGSAQLGLFRAGSSVGGSYIGADDSKLLRVYNTSFASKFDIDTSGNVTALGTISSGALATTGNSTHGGYSSWTAGNGTSGIFQHYNSSNSYRGYFDWRTLQLGNNGANNILAGNSSTGGYFKFWVNATGISQTGGTSGINALTISAAGNSTFSGSIDSGAISSTDRVTVTTAGADGLVLAPDTGSTNNSARLFLNGSVGNWAIFNNSNILKFNSSATAGSTSGNLAASLTTAGLLTVVSLTESSSIRYKENLKPITNGLEVIKKLEPVTYDRTDNDSKDEPGFIAEEVLKFLPN
->MGYP000299415252 FL=0
-LQKEGKDRSAYRVSEADKRELLAAYQRRGYCEGYYHQHNGRDMISLKRPKNAKDGNTEEKPWQDIKVQEKINGILTFSVGKRAKLTVSYGNITVECTGQEVQEAQKQPLDPKRIEKQMRKTGNTEFVFERLKIHTEGNVFLPMQALNELRREGIEELTEQIQMQYRREKAGCGMKTATAGFDSDADGVTETAGKKE
->MGYP000035781564 FL=0
-FDRLLSIYNRFPLKELIIHPRVLKDFYKYTPRMEAFRNAFANSAAPVCYNGDIVDRESYERLTAAYPALDAVMIGRGLLADPFLIETLSGQAGTERRRTQIERLSAFHQQILEGYCQTMSGDKNVLFKMKELWFYMGHLFEENKKQMKKIKKSQKLSDYMEAVDSLFEEGEFHAWGTFE
->MGYP000547744649 FL=1
-LLFGFETQEEYKELLELLIQLRTPKLSSLFNSI
->MGYP001288746208 FL=0
-FFDCKRCFFFDLKFGIKRPHGTPLVLNNKIIQQVKKEFDFFREKKKPHPEIIKLKRGFIPSNHENLLKWKNSFNGVFFVDKKTNLKFHGTIDDLWFDNQTNSHISVIFKSTSRKDQLNQSEIWDGYWKQLSFYSFLLSKNSIEMSQSGLILYINVLNEDNFEKEIKLDFNLFEQILDFSWIENTIENIHELLNKDAIPDQNRKCKFCNYFNNIKKIHE
->MGYP000877297596 FL=1
-MLFRSADAVEAVIRGLKRAGVSVATYLPDSLLKELYPALDADPDIRTIPVTNEGEGAAIAGGVFLSGKRAVLVMENSGLRAATEHLARMGLGAGIPVVMIMSYRGEMGENNWWAIPHGITMEPLLQALRTPYTIVRDVDQLETAIVRAYDTAYASYYHAAIVLGGDLVR
->MGYP000780934939 FL=1
-MTLKEAYETGRDLDVYVDSEMADQDSHSFDDLWQSIYDICLLYTSPSPRDS
->MGYP003414964913 FL=0
-FMKKNEEINMFTVYILYSPSMSKYYVGSTSMDISERLARHLHDHQGFTSRAKDWEVIYTEKYDDKTEALSKEKAIKKRGAKRYLEQLGHL
->MGYP000195956432 FL=0
-MIGYLEGKLLKKDSDRILLLANQVGYEVLLPAVVMETFGAQKIGDQISLYIYYQQTERQPKPVLIGFNLEAEREFFQLFISVEDIGPLKAVRALNIPIRDIARAIEARDVQKLNQLKGVGKRTAQKIIATLAGKMDKFA
->MGYP000654245701 FL=0
-MSETRYSKDHEYIRVEGDVGIVGISDYAQSQLGDVVFVELPATGKALSKGAEAAVVESVKAASEVYAPVSG
->MGYP001494102332 FL=1
-MADYKPIEAGFTKIRMLRKYDVFDLLSISLFNAVVFGCGLGVGWLVWCY
->MGYP003981121435 FL=0
-GTLCHFDSXYYXQSDSDCISSGFXNDSPFLKCLAFYYQSIGEEGKTRKELQNHVLQVEETFISNFS
->MGYP000559679233 FL=0
-DILEDIRAFFERNVHMKMPENNVQQAELPEGCTVFDNPVGTAPGCAFEADGVHVLMLPGPPFEMLTMLKGHVVPYLRGFSSEVIVSHDIMTFGMGESSVDQLLHEKMSHMENPTLATYAKPAEVRLRATAKAETAEAAEAMLAPVVKDVTDFLGDYVYGVDVSSLEETCFRLLKEKGMTLATAESCTGGRVAERMTALPGVSAVYRGGVVSYWTSVKAAVLGRQTFLRPAQHNRLDGSPVAAPAPTVEGDHNPRRSHPPRHSPHCAAHWRGVQAAIAPQ
->MGYP003443514059 FL=0
-MASLIDYIHLYGGVSFSKKRFNDVDNVILSLVAYIDMSNTAAATSDGIRLADALENFIRSHTQKEISRYGLAIKDAYLVAKELIGAPRFADVRVSDYVYLADGDTQFGAMVFHLTKYLDYICFEGTDHTIGGWREDCLLACYHPVSSHILGADYLKKHIKLSGPTVILGGHSKGGNTALVSALMTTPMRRKKIRMIYSNDGPGLRRRELLSKEYKSIRSKYKHIVPQNSIVGML
->MGYP000585668832 FL=0
-TRSSHALALNLGNITDARMKSMPESLKTAASLHIPVMLDLVGTACSNLRYEFANRLMNIHMPELLKGNMSELLAMSGQTAHAIGIDAGDEDTVTDINRLHLQELFQEKAAQWNTTLLITGKEDMIVSANKCSFIKRGTPAMSQITGTGCQLSGLMTLIWQRIRTTCWSRGRSCLRHGTGG
->MGYP000681108114 FL=0
-MKDQDLIQAIEQLVTDHNPPVSDLPGHVDFIKETNRSLVTKIKELFFKSVPVGSTKATIQVHAVMSFWYAQRNIERWSLIDKVFGEEDEGVVNHLKDLFMKAKYCINDFMIDLDEEKRMKLIQYVMDQYNGFTLESAKRYVDQLEK
->MGYP000336411506 FL=1
-MDIINIVAVISFFLIEIHTLPLVESLIVLLVEFFLHVNQRFAIDVGFDEKAEVF
->MGYP001129885005 FL=0
-QLLRDLVSRLRLPDSPTATAVAEIRPFDFVAADDYELPAAYDQRRPPSPSAATVAKALSGEKPPPYWAGQAAPEADATHLTRLELASVEPELCVALRAEGKRRGVSLHAILFTACAAALRAAFDVPPALGIKAATPISARRFCEPPVDADEVGNFIGGVETWLPLVSAADPSDDAGEFWASCAAYSRHLSANLREGAALPGLLAHVGEWPAAWER
->MGYP000989466621 FL=1
-MNQSIKNQNIFSSVLLAALGYFVDIYDLILFS
->MGYP003369514027 FL=1
-MNNSEIITCVNGALSHDQKSVERLYQYTYPNASALARHLCSNPNDVDDILQESYITAFTQLNPLREKASFPFWLRKIVINTWRAFAKNKSNYYEILVQDIPGEELVDESLQLSVQDEVELSENQREINDLVEALPESHRLCVRLFYYEEISVEEIAEILDIPVGTVMSRLYYGRKRLKEQIEQRGLHTFHASPTAASAADPLLLSQILSALQAASGGVSAGGIALKLCLGLASLLTIGGLIGIPVLMKDDSKPAQPSITAHSTTATTAAATSSTSSMTSATASSTTVTTTATTIAATTPRSYISFEFEDYDGGIMLTSYTGTEPDVTIPDSIDGKPVTAVGSGAFKKNRILRSVKIPPSVRRIDSNAFRDCRALQSVAFGSGVSYIGDMAFLGCSSLRKINIPSNVDEIPESVKVEKRRS
->MGYP003580237746 FL=0
-MEMTITEKPARTLPVQDARIYPRGGLDVLSRAEVARLRDASGGGMHELLRRCALAVLTSGSASDDPRAARDLYPDFDIQVAQQDRGVRID
->MGYP002553410909 FL=0
-MGDFGGVEQDANRCLYPSLATGENAGLSARLFWEQGKARSNKKINCRGLNNLYQSGIDKAIVSALPFGPQYSNQQLCCFNNYIKQQVALFPHRLKGFCTINPLEQDALSYLEQLIGSEGFKGLKLHNNMQQFYPDDTKLYPIYQKMQEYQLPILFHCGGIGLPPTRDSYGQPIRFDAIACDFPDLPIILGHAGRTWYDETAMMLRKHKNIYADISTNIGRLKSHAGKPMADLLEKVKVWAGHTNTLFLGSDYPFYGQAETVEIL
->MGYP001481087062 FL=0
-FIEDKALDFFKNQTLKSAIVQSVEIMESKGDFEQIKRLVDDALNAGSERNIGHDKKPARMKAGFQVVIYPVSKGLKDSN
->MGYP001410066015 FL=1
-MNITGIKKLAKEGKSPYFFSPDTMRFFSSKVYKDVRAVKEGHLFITSEVFGDDSRHYSLRLIDSKGSIETLITKDNLKIIKQLMRAY
->MGYP000418322004 FL=1
-ATANKKAQQRESNSRPQHSNPKRGREAGFTPTHEKRPNPHANYGVHFDMYSASDEERQNSLGRYGKQAPWAQPKQSHTPRTPEQEASLKRKIRALEGKLEDAKRDQASGRNDFPQVMLVDGTSSSLSVHVRKSMETELRAWNFDVPPRVSKDLVTIRFLLDYGEFIQELNCPVDMAYLNLRLMSQKWKEARLTPLRTAVS
->MGYP001323574780 FL=1
-MYSLELFVIAIYCLIEDALYPHFCHQHGQPRRAGFPPALSDSECLTLEVVGHYLGYGTQKQLYEQLCDRFGTWFPGLRIGWPLPGSRPTCGRSKPGSTSTL
->MGYP003297312165 FL=1
-MDNASNTLLGKVKKLIGVEPGTKLQPMVAYNSAVFFTGGGPYILGCYLLPFLTKVEGLDAVPESVSAEVDVLQIAENWSLFMSNDLPFSTVAKDLIPSSYQYEVATKYANGIDITFTSIHTLLDPAFVDEKVTNFVWITDNLFSVDISFVKRMLLSSGTTIEDSMNDRFYFVKYDDTNDYSDNPTWKLLSMKEIVGNAE
->MGYP001502702574 FL=0
-MINPINLAILGLICGGLMKFFWQMGLENKVDIASFLAVDALFIFLFTVITFLYLKQPFVLSGRMSIAAALAGIFGGIAMTAVAYAIKLGGAGSVIFPIISLETLLVVILAFV
->MGYP000531888355 FL=0
-RKRNIHRSIHVESDDYPFVAIFKERINIMREKYESLSLGALKEIAKARGMRGISTLKKSELVERMVQEDDKERQMKESSAPQESEQESRNGSRAGKAEERQESRASGRQEERQETRASGRQEERQETRTSGRQEDRQESRTYVRKEEKQESRTERPPMEQSDLDSGMSVSGILEVLPDGYGFIRSENYLPGENDVYVSPSQIRRFNLKTGDILRGNTRVKSQNEKFSALLYVTSINGIKPNEMRRLNFEDMTPIFPNERLHLERPGGSLAMRIVDLVSPIGKGQRGMIVSPPKAGKTTLLKDAAKSILKNNPEMHLIILLIDERPEEVTDIREAIQGPNVEIIYSTFDELPEHHKRVSEMTIERAKRLVEHKKDVTIFIDSITRLARAYNLTVPPSGRTLSGGLDPAALHMPKRFFGAARNMREGGSLTILATALVDTGSKMDDVVYEEFKGTGNMELVLDRRLQEKRVFPAIDISKSGTRREDLLLTKEEHEAVDIMRKALNGMKADDALENILNMFAHTRNNNEFVQTVKKQRFL
->MGYP001261365442 FL=1
-MTFDITKPFAPSTRSPNSTPIASWSSWAEERRCRETLASAQQLKQVALSKRHRITFYMERTTVADFVVDDLVSPADVVRIGPCLVVDDHAQHPVVGAQIHHPLRSDDVGIGQDGNAVFGRTSRHDRVVGEASRLRKVPSARLSVPTGVDRALGSRIISTGGGREWIG
->MGYP001159235774 FL=0
-DGDVYYVAGGGDWHTSGNNGYYSDPNYIRLATTQENATGYYWDDDSDSDTPDVWHAPVVLNLVHHDTSPYTDVTHTLRAVNDQPMSGLVNGQAYFVVNRTATSFQLSNTPNGSPIAFSNGGLTGGHHTFAVEGIDLTSAGSGSQDLVLDIDNGATGSFSGMGGARGASGAPSGDLQFTVSTTGSTGGAVTVGYAKADGTASIDTDLTINSAKIFGADVNIETKSFMNVSAVSDSGAFGGVAIGESNTSALGTNDSDITINSGAVIESTTDLKVSATIDS
->MGYP001146147798 FL=1
-MRSKSQKLQLKLTIEFALFFIVVSVFIFIHFTKKFEDQINDKYVYKADVFVNFFKQSPNAFTGEKLADKEAVSNLLDLNGAVYLVIEKPTGEILDAINLDIAENNLYVLSKTNREGISKDEKVYRIALPVEGDNISGKIYVGFESRDDAQKILKNRMLTALFSLSILLAGIVFTYFLSSISFRPLAKIFKALDSANIYADIKGKKNVNKSELRVLEDRVNILLGELDRSSGEVESLNRKLHDVFKDKIAELNFEINQRKKAEILLQKSEEQFRLVFQNAPIGIVIISTEGKIISVNRSFCNTVGFERDEIIGIPIKYLFEKNDLEGFENDSLVYDGKPIADISTERTLLKKEGKEINVIVKLVSVLDEKNKVKHYVMQLLDITEIKRVQQELVAALKKAEESDRLKSAFLAQMSHEIRTPLNVILTSIPLLADEISSKDEELKIILDSVKSAGRRLQRTIDMILNMSSVQSGNYKPVFEKFDLLTDLKKLMNEFKSLSDDKGLELKFKQSADESFIVADRYTVNQIFQNLINNAIKYTLKGYVEVFVRNENDNKVRVEIRDSGIGMSDEYLKKIFTPFSQEDVGYKREFEGNGLGLALVKKYVELNKAEIEVESEKSIGSVFSVTFDLSVNFEDESQVKKYSNYQ
->MGYP000699489815 FL=0
-MQINITIEPEYSGTVWCKETMDGINEKVSSLRYSVNFCSDVSEAKDAMDWAGR
->MGYP003287736390 FL=0
-GLLHGLWFIGQGEEGGVLFIGDDWAEAHHDIEIEDEAGRLLVRKRLPEGLAGVTLLHELVAEHLDPSGEPDQVLVGIETDRGPWVQALLATGYLVYAINPLQVARYRERHSTSGAKSDQGDAHLLAEIVRLDRAHHRPVAGDSEIAEHIKVAARAHQTMIWSRVRQVNTLRSMLREYYPAALAAFGADLAGREALAVLAAAPSPDPGRRLAQARLESLLRKAGRQRNVAATAAKIRATLATEQLTARPGVVPAYAPARRR
->MGYP003686838251 FL=1
-MQDIPYAHEVLSAETQTLALEAIKKAGPYEPQTAAAKLERTETAIIELIEQQAAGIANKVHDEMTELAPNESCLIEVYPSRFGNLYLLQKVPCLQTIVENINRISGLDISAMLATEEQDIGDRNPLYVTVAGILIQKGKSLHRGQHLLRTRS
->MGYP000072504175 FL=0
-RIGPHLVGVARDQPEAPARLGTKMDLGVRFAQLHVAPQRGHMAVGAPLDGIVGAELDLIAQKRLERAAELGREFVVKVEGVVRERSSKNMKIPTGEIEIQVINMTILNESKVPPFTIEDESDGGDELRMKYRYLDIRRRPVKENLIFRSRVTMEVRKYLSDKGFIEVETPYLIKSTPEGARDFVVPSRMNEGEFYALPQSPQTFKQLLMVGGMDKYFQIVKCFRDEDLRADRQPEFTQIDCEMAFVEQEDILQAFGGLTLHLLETICGVRLDSIPRMTYDEAMRRYGSDKPDIRFGMEFGDLNEVARHRDFKVFNEAELVVGFAVPGGNAYSRKEIDALTEWVKRPQVGAKGLVYVRCNEDGSFKSSVDKFFGQEDLAAWAERTGAQQGDLILVLSGEADSTRTQLSALRMELAERLGLRNPGEFAPLWVVDFPLLEFDEETGRYHAMHHPFTAPKPGQLELLDSDPAAVRANAYDLVLNGNEIGGGSIRIHDRETQEVMFGHLGFSPEEARQQFGFLMDAFQYGAPPHGGIAFGLDRLVAILGGQESIRDFIAFPKNNAGRDMMIDTPSTISGEQLDELKLRVIKD
->MGYP001564172474 FL=0
-IVVASLNFFDTYLAVIRFVDYKLITRLIRGYLVAAVVLYGIARYLDSAAWSERMLLMFVILGPAIALQVRLLAQWFLRPYLRKDQREPVLIYGAGHAGTQLAAALVTSARYKVKGFVDDRPSLQGREMLALPVHAPARLRALKEEDVFRQIIVAIPSITKSRRRAILESLEDLSVKVQVVPGLDEVASGQRKFEDVREVQVEDLLGRDPVEPIAGLVEAQVRGQCVLVTGAGGSIGSELCRQIAMLGASK
->MGYP000465940127 FL=0
-YAAKRTRRQAQPKVCVLVENMEYANIGQFGYEIVAGFRLAAAARGWAVDVLPTTPEAQARTKYGSLLLEGGYGGAFILGLTPQDAYMRALAGTGTPTVLLDNCVPNASVGYVGTDSWEGVELGDILSSGFEAASFDAALSECAFFLTGDPEGALREAARLLRPGGALLYSDICPGGEARLRRAAEAAGFAVEALTDVTEDWKRYYIAALWRGEAECPPDGARNCRYLCAVFRKEAR
->MGYP000176012788 FL=0
-NIAKITLKNLSEKVLTIHPLGKAVVRCFKNDHSATIPEASDFKMIPGRGVSANVEGYHVLAGNMAMLNENNITVSQPIMAKTEEYINRGCTITYVALDNEFAGYVILSDTIRALIADEKSPA
->MGYP001150477923 FL=0
-MMMEVQDEANEVDSDLMENKTHLDANEGELLILRRVLHTQDSPYD
->MGYP000662722262 FL=0
-MTYVVTDNCIKCKYTDCVSVCPVDCFYEGENTLVIDPDECIDCGVCVPECPAEAIFPESPDLANWVEINRKYAKQWPVITKKKDALPEAKDFDGMKNKYEKFFDPRGFQGQTRK
->MGYP003721390011 FL=0
-XXSLKSSXVSPPAXFLHTXLLPXEVYSKSASLLXQVDRLIESLLLPISQQQIRKLESERTMLVDRNVGIQAELDQLKQQSRDRIAAVAATQQN
->MGYP001010919623 FL=1
-MYPVLFHIGDNPVHSYYLLWTLALTLAVVFSRRRMTFFYGIDDDDARSVIIWAFIGMLLGARAGSVYDSWSIYSADPLKILRIWEGGLSAVPAFLGAGAVSFVYSKRRKIPYWMIVDAGALPAALTVAIGRWGCFLNGCCTGIETTVPWGVRFPSDALGLLRHPTQLYYSFGALFIAALLQWTESSWLGYHNDRRIRGAVLCPLFAILYSLLRLAADPFRSDFSRIGMQTNRSVLFVVLGISMLWLGYSVFYEKKCIRS
->MGYP000546373282 FL=1
-MSHQRVKRLTQFIAATAIASLITLPAAADGLSLGSRPDQAPRTSQSGNSISVEAWAGGTTATTNTADTTATEFDSTAWTRWAPVSYTHLTLP
->MGYP001816006016 FL=0
-MSRKCIVVIGAAGRVGSQIVAELLRRHHRVVMVDALPGDALTRRAGRLLNDARLAVSPCSGSLRAYGGIDALNCAAMTDILIRENPDLVINYAIPITWDAAKRLPNYKAISAAGLGAFTPIQVLTPLKVAQAIHDSGVESRYMVGNLPDITIPIINGIAQGGTLQPALCGAGNVGLNQIAMRHQAALELAASFDDVDVALVSHHLHWVAPREPGYSNEGPFLATVSLAGEDVSASFKDLRALMNEGVRRHYEADASFSSTTGILASQVAMALLDDTDTTHHLHTPAPNGLPGGYPVEIQHGAINVNLPKQWSLDDAVAAMAICHTLDGVASIIADGTVTFTDLARDILRDELSFDLPSQMLPHDIETVAREQIDCMRCLLYTADAAD
->MGYP001138444575 FL=0
-MPTIEVEGSKVELDDEGYLVHPEDWNEKIACILAEREGIIKKCPMTKEKVGILKFMREYYKNFEAFPIPRGICVNIHQPRNCTYEEFPDPSIAWKIAGLPQPSRHVVAQLKGLGGVS
->MGYP000402310384 FL=0
-MTRDPLDEVTVTFQPRRPNSIFRQKVLVQYSEQFNTFGFGMVVKKHGIYREYRMNVKRKTLWISDLIFNVEESRHSMNNPVSFCFDRKIICGKRPRSMYQTSVNRPMPFPQCKFDAVWMRPGAIF
->MGYP000123267625 FL=1
-MFKDKLAVEQEQGCKVPITLLESLTTFLGKNSTKRLDQVKGALTLWMSGILIKTLPATSDPACGKGIFFFFTTHLFA
->MGYP000748431043 FL=0
-LRALGTSSTAESHVPAISFQSDQGDGVTARASISADRDGGATKGSLIFSTRISDNITEAMKIDSSGRVGIANDTPGDFDADGDDLVIGNSTGNRGLTVRSSASGFGSMYFAMGTSTTAQKVDGFLVYDHGTSFSGTSGLHIGTGASTRIGIDESGKIGINETAPTATLDVRGSSSQPICNFGDDNIRDSDALDIFGSDSFRYQFQNGQQARPAIIEGGGDVAANESAVYFTGFSSSQTDGHRNLGGMIVYRKNTGGADSGQYGSQIQFRSKADGTATPAQNMVLSENGSLGIGVGAPSATRLQLVRADGVTDSTEFTQTIQNLDTTEGQGSGLFIQAGNGSTDKILQCQTRGGTFVLDLNGAGRFNTTANVAND
->MGYP001244487380 FL=1
-MQYHVKAMQSLDMVVELNVDCVEADDARRQVERLGYEGVTLRSKRAGLAAYLKRRTTFPLTLFSQELIALLGAGLSLVEALETLREKERHPDLKQVLEQILTKLREGLTFSSSVEQLPSSFPALYVATIRASERTGDLREALSRYIAYQVQLELVRKKLVSASIYPVVLLVVGGLVMLFLMMYVVPKFSRIYEDAGKDLPVLSQLLLEWGKVMEAHGLLVMGCLACVGIASAYGLTVPAVKARILSQLRSIPAIGSRLQVFDLARFYRTLGMLVKGGIPIVSAIEMVSGILPLSLRGPLHAAVRDLREGKPVSQAMESHGLTTPVAHRMLRVGERTGQMGEMMERIAVFYDEDIARALDWVTKLIEPALMAAIGLVIGTIVLLMYFPMFELAGSIQ
->MGYP001368835617 FL=0
-FTWKSLQISSFILNNLSVRKRSLFAKKKLRGSFFRKLLFYYLSEKSKTTQTSIYLKNNLIITIFLL
->MGYP003476759632 FL=0
-AGQAFEQTGLKLTPWQQYEKDLAEYNEYIKQNPNAATQSTAASAANVAKGNGTGNVPMNTDTISLKDQFPETTTTGGGASWQGIGDTDRFGDVEPPLKDQFPDTPQGTGASFLGTPEAPPDDPIPPDIITTPPPDVAPPPGGPCPQPTTYSQCTSYHPESTIPGKMSQAATVRSITAYINSKGFRHDPDGIPWLAPSAWKTWDGVTTINPCTSTTAQIMAFVFPPPGSVNTMRGLRERFYQVNPFADNQNPTVAEIENWNVEVIRHFRRLLGFNQTTHPVYNDKCTYLKAAWAEERARTNYWSASYPGVQDSASGPCTQPSSSNAHCGASFLPSPADQAPYLCPATMPACTTTAGAEGISNQNKDIPWGIKMSRIIGNYLSADGITGHTG
->MGYP001453318140 FL=1
-MREFGAELGELRLHRRTHGEGILLAAVGHNATVDLEELCVRRQGDVGPVGALANGRPLLLAQVADHEHRAVH
->MGYP000100214384 FL=1
-MNIEKFYDDDLSGQIKAKNFQGKIFEILCLLAILLGISILLILLIDVTLDGIPWLRPQLFNSFPSRFPDQSGLRSALQGTLWMAILTAIIAFPIGVSAAIYLEEYASDNRFSRFIEINIANLAGVPSIIYGLLGLGLFVRGLGLNRSVLAGSLTMTLLILPTIIVTSREAIRAVPRSLRMASLALGATQWETIRYHVLPYAMPGILTGLILGMSRAIGETAPLITIGALTYIAFDLRGPMDIFTVLPIQIFNWISLPQKDFHDLAAAGILILLAILLSLNSIAIYLRNRLQHRW
->MGYP000373900305 FL=1
-MKDYAKKFYLSQAWRKTRDAYAKSQNGLCERCKQAGDIVHHKQYITPKNISNPLITLDWANLELLCQDCHNKEHTKKQNSRYAIDEFGNILPPGCVKNKRPREPVKGS
->MGYP000933484466 FL=1
-MKIGNLNLDNRVFLSPMAGVTDLPFRLICKEQDCGMLYTEMVNAKALCYDDQNTKKMLKIEEEEHPVAIQIFGSDPEYMGGAAKIFNSYPNEILDINMGCPAPKVVKNGDGSALLKNPELAAKVLKAVVGNSEKPVTLKIRKGWDDTCINAVEIAKIAEDCGISAIAIHGRTREQYYSGKADWDIIRQVKENVSIPVIGNGDVFEVEDAINMLNQTNCDAIMIGRGAQGNPWIFKRINHYMQTGEILPEPTLEEKINTAKKHLKLAVEEHGEYVAVREMRKHIAWYLKGLRNSARVRDEINKIESYEEVVNKLESYMQDCLTLE
->MGYP003298397327 FL=1
-MKKIYENIEIAIILMPTMDIVTLSINQKDDVADDIFAPNN
->MGYP001558061087 FL=1
-MNILQRLKLRLGLQVCLGERTREGWSGALPFYAFKCPVHGLVENYPSGWAEILRCPLCIEAEKLRHGESRPP
->MGYP000481936423 FL=0
-RTQIGKASLNVGWPRDYAKLPVIRRYSFAPHVSPRDGTMPVELIGPVNSPGGNGPSNGMYALQKALRKRIDEGLDWLSIKPLPASKGSLPWFWHWDDRRYAAWWDSEGQPFVQGPNMLFTYSGKPRSDTEECALLDAVNCRAMFCHSEWYRDLIAKHRGPANQSPIVLWPYPIDPWPGEPLPDEYDLLLSLIHISE
->MGYP003150238574 FL=0
-IGPYFKSETGTGNTGKTPIQAYVPAGPAPATSTIQSSYWTNLGHRVYGYGTVYGCGVFRDPLSVEHLLVATSDGVYATKEANPSVLLSGITSITNDVTFVQCFNVVVMFRGEGEEPYVMERIDEGFKAISQVASDTDLDENDSDGTESIPNASTGLFFANRLLIPHSDDQVAVSDFLNYTRYQPIMSNFRINQGSEDELVGLRRINNSTLACFKTNSVYIVSNIYGNLTDIVLDEVTREYSAVSDKSIVQVGSDVLFLSSKRGVCSLTVATNGKVSAVDQPVSEAIQPLVDRINWNHSSKAVAAYHNNRYYLAVPLDGSTYNNAILIYDTFNKAWAGYDDGDAVKVKDFVETKHQGKRRLFFLSTDGFVNLYDDDITECGFVDEIPSSTTITDSDFGQVTVKDIKDELVTRGYTAGDVSPKKWRSAEVHLSTNDPWFQVKTQYDGPEEDDQELTAAATIDANGYITAGGKTFSRSAYDRPFDKTAFVESMTNNDFFTQHRQDYSVDPDTEIVLGSNGFDPDIHQKSVNRYR
->MGYP001768574441 FL=0
-FPDPSTQDLAGYISTDPETKDELKYY
->MGYP001452703586 FL=0
-SVLIFLIAAGIVLFAVTSSMMSWDFVMSIDSHWFSTMFGWYTFAGIWVSGLTMIGLMTVYLKRKNLMAAVTSHHVHDIGKFMFAFSVFWTYLWVAQYMLIWYSNLPEEIVYFRTRLDHYRWTFWIAFFLNFIIPFLVLMTRDAKRQFNILFFGGIVILCGHWLDSFNMIIPGTLTAHGNHWQLSWMEVGTTIGFLGGFLYVTFRSLAKAPLLRTKHPLMMESVQHAI
->MGYP000024922526 FL=0
-MEDIYKLIDDINLQKIDNIDSRVNDALTSPNDDALFILGETLYNFGLMPQGLEVFRTLYHKYPDESELLIYFIEGLMAENQTDEALEYLSHVETSTEKLMLEADLYQQINMLEVAIDKLIEARDLEPNDPIIHFALAEILYYDGQYLRATHEYQTVLDTGEYEINGINLFARMADCSLQSGNYSDAIRLFDEISDEEMTSDDYFKKAIAYEKNDLSLEAIKIMTTLLTKNPDFLQGYYYLQQLYEHEKNYADAIEIGKEGLRLSQFYKELMVSTGSIEIEHGDANEGVALLKQALEVDNAYHEPLLLLADLFRSEEDYEALINLLQYVDEEDLDPVFTWHLAFAFGQEERDKEAQHFFELAYPTLKTQSAFLSDYYYYLLEIGDKNHAQQILNQLLELDPSNEIWHEETARLEN
->MGYP000184957940 FL=1
-MLSDSLADGKAIHPRHIDIQQNQVWLFTRLLDGLPAAVGGEDLVLGGEVGFHGIDNAGLIVHYQQGRFQGDAPFHGVFFILP
->MGYP000054682017 FL=0
-MHIHILGICGTFMGGLAALAREAGHRVTGCDAGVYPPMSDQLRALGIEALSRGAGHVTFVDTSPRALAAVRDPGVIDDKIELVGAHRRVAAGAVDDQIDATETDHQTAQRFAQARCVEHIDRQRQTARMRLLEGEQFSLHRGALRDARWIGLLEDPHRGDRVALADGRVLRDARRLEPDLAGLDAIAPV
->MGYP001618312234 FL=0
-MMLHRIHPVVNPWHAQNCSRSTPSKRVSSPSQPWALCMAWAWPQAHSGPGAGQGRDLRRVSLYVTMSLLSLSLFGLGWTSDL
->MGYP003315070702 FL=1
-MGDDIMGSSTFIPRWVKIDDNASIYNRKVSYLSGNNKIIERSFECKTQKNNQKLVVEIWDIEFVVTKFDENSIQIGDSAESIPCKARSPVLYLFVKFSNFNINYSFLKSQAHIKSLA
->MGYP001373614446 FL=0
-RQVRVETTLPEIKTQDFSAASVAAIADPKLRRALDRVASGFEVARLARVADATPEVWDAWRQEARDIKAHTIEHLDYYLDLLHTNVTAAGGHLHFAKDAGQANEIVAQIARTRNVKVATKSKSMVSEELGLNPILEAVGVEVWETDLGEYIIQLAEETPSHLVAPALHKSKEDVAELFSEKLGIPYDEDIFHMAATAREVLRDKFMEADLGISGANFVIAETGTLVIITNEGNGRLCTSAPRIHIGITGMEKVIPSLQDLSIFLRLLPQSATGQRITSYVSMTTGPRRSDDEDGPEEFHLVLVDNGRSRMLADPALREALYCIRCGACLNICPVYARVGGHAYGWVYPGPIGAVVSPMLVGLKKAKELPQASSLCGACREVCPIKIDIPKMFLHLRNQTAESPDPNLRSAPIVERTMAKMYARLMSSPRLLGLFRKFGRALQLAEGMIPFSPLTKDGEWIRMAPLPPLSKWTRSRDLPTLPKQSFHEIWKKGLSRDDS
->MGYP000395248815 FL=0
-NKSYTMYFTEINFTEIDFTEIYFTKIFLNYLVCILPPTIVQKGKSQK
->MGYP001502370584 FL=0
-AAGSTEYTTGVETNGTPGNSGAYTRITVAADAPTLYYYCTNHSGMGSFVTIGANVQFNNDADPPNITITPKTDFTVGQRYALSYPSGVFTQTGAGGSFVGTGYTFTARNYSYQLWTWGDNEFGNLGLNAPETSRKSSPTQIPGLTWENSLSSSSQSKHSAVAKNDGTLWTWGRNDWGQLGQNSEVNYSSPVQIPGTTWAGPTATDSEGTTYATKSDGTMWAWGRNTMGNLGQNSTNTGYSSPVQVGSDTTWPTDLGSDDGVIKLATGSDNVFAIKTDNTLWSWGTNLTGQLGLNNTVKYSSPVQVPGSWKSIGDDGYTKFGVKTDGTAYYWGQSNDGYSGINLFEPKRSSPTQLHGGGTTWNHIAFGGTIALAVKTDGTMWGWGENTYGQAAIGNPDTFPQGTPGKSAPIQIGNQTNWKFVQSSASGGASPQFAGLKTDGTLWIWGLAPFGTAGNNTVTPGSAGYSSPVQIPGTDWKTVALSYGKVAATKQI
->MGYP001024040911 FL=0
-LDIRLTPARNDAGRVVAIRDMGKAQFLQIQDQSGRVQVYAGNKTLGEDDYFVLRNLDLGDIIGIKGRPFRTKTGEASIHADELKILSKNLAPLPVVKEKDGETYDGISDIELRYRQRYIDLAVNAEARATFTLRSAILREIRDFLHRKGFMEVETPMMQAIASGAAARPFTTHHNALDIDLYMRIAPELYLKRLIVGGYEKVFEMNRNFR
->MGYP003311824185 FL=0
-RLRIGEQEHLLELRRFTPWILLEFRAGFTMKIRGICRFYLLEKAPHMRLYMSPVNIDPENPALPISYPATYSMYLAKTQGRFSTLGLAEDTWALNERVLDEDAFLEQAYLVHEEREKMFLDAIEKTEQGLAVCVFDITDRVQHMFWRYLEKDHPSNVDKDVTRHKNAIFDLYERMDGLVGKVMKNISDDTVMLVMSDHGFKSFQRGVNLNSWLHQEGYLAVHSGPSGAEWFAEVDWERTRAYAVGLGGIYLNVRGREAQGIVD
->MGYP000397936239 FL=0
-GVFAENHSLALGVFGNFGQRVANNTIGQADTILNVMRTWWKAVCLVTSTCLAASMNLT
->MGYP003982510387 FL=0
-IKDAPNIQKWTNPISWPGLHLKNDDDIYAIPGNTIVRADGMMIRKDWLDAVGLDLPADNEVTLDEYTEILKRFTENDPDGNGEDDTYGMGVAASGGNMYLVFGWPFGVGRRATEDWWQKVDGEEFDYMPMKYAKNHENMIDALEYHQMLWDKSYVDKNWPSNNGTMRNDRVWSGVSGGRESFGGHVYGNWLPNIQKNFPEAE
->MGYP001965651419 FL=0
-THARTHARTHARAHTHTHTQEGALLQVLCADMVERFQMFIFLLLVTVQNWAKDGRVSSHSFAWLQEWVQAILLVFASELGVLRASC
->MGYP001756801604 FL=0
-YIFTGLRIGIGLSWLVIVAAEMLTGGVGIGFFIWDAWNSSRISDIILALVYVGVIGFLLDRLVAWAGRLITRGTTAAQRMRRVDRWLTDVHGPLLRRTPRPLAVDLGFGAEPVTAVEMAQRLRVQNPALELVGLEIDPARVARARERAGGLPGVTWAVGGFELPVPRPPTVVRAFNVLRQYREEDVPAIWSLLCAGLADDGVLVEGTCSEDGRRAAWVDLRRDGPASLTVALRLGSFARPSDVAARLPKVLIHRHVPGEPVHRLLAEADAAWAAHAPLAAYGTRQGGRARRVGRE
->MGYP001019934495 FL=1
-MFLPVKRRGLLFILSSPSGAGKTTITRSLLERDDQLSISVSATTRAPRVGETDGKDYHFVSKEAFDQMVERHELLEHAKVFNNYYGTPLVPVEQALANSQDIIFDIDWQGTQQLKQKLVNDLVTIFILPPSKDELERRLRSRQQDDEDVIRERMKKASDEISHYSEYDYIIINHDLEKSILQARAILEAERCKRRRLTELPDFVRTLMQESI
->MGYP000405630647 FL=1
-GYPSQVSPVVKTPSQRCKVNLSRTQQIPSRKLAQATKKEVTSFVFVTVLGSSVVTLI
->MGYP003603128023 FL=0
-MSLNIAFIGLGAMGWHMASHLPKLGHPVWVWNRRAERASSRAKTVVAWAYEM
->MGYP001304718576 FL=1
-MHCSRCGSREYFKNGKMNGKQRYRCKGCGYNFTNLHGRGYPPALRLYALKLYTENVGIRSIARLLGIDPSTIVHWVRDEGKKVMEQLKASIPDSLPEMDIIEIDEMWHYTQKNSANYGYGLLCLDSPDKSLPSKWDLVVQSHSKNSGNV
->MGYP001796365966 FL=0
-MSQGRLKRRGTGFTAVPNSFLRDDSLSGDARMLFMLLSSHSENWVFRVPQIQKNLRYGKDRLRNAKNGLIKRGFLTLWQPKDENGSVIPGPWSWEICIDPALPISAGRKTAQADARPAETRIALKEQDQEDQVQEDYVDSAREPNLLDRLDAGLKTAT
->MGYP000859918013 FL=0
-KGWTLDGNAVNGTNNSYSFTVTKAAEVKVSFESDSTPLPQYAVNFSVEGGNGTLKAKADGVAETATSPISVQKGKTVIFTAFPAAGYEVKEWQIFGTGAVFEAGTGTPANNTAQVNLKEGLTDLVVKVSFQVQTLTPKHKVTMSAGANGSISAEPALPAGGMVNENTTIVFTASPNSASYTVDAWTITGGQVLSGGSPGSSTAMVKITEPVTVAVSFKLKPPTTYTVSFGVAGTPPNGTISATYKTDGAAFTSGTAVAENTALVFTASPAAGYKVEKWTVNGTAVPGNTSNTYEHTVTQPADIRVTFVSSVTIPDTFTLPNGAEYKVTDKAQKLVIMTKRENNASGTVYTVNVKPEYSGITYTLTGFSESV
->MGYP003019047097 FL=0
-EKYQSPVYKVLSVPIEKIVANSYNPNIVAPPEMKLLEVSIWEDGYTMPVYVIISPVSYTHLRAHETRSN
->MGYP001083449663 FL=1
-MDDSAPIRDFEKLLRETIGLSMETVGASVIRHALKRRMTACAISDLHAYWAFVTSSPAERQELVDAVIVPETWFFRDREAFGAMVRHLRENRASCRPLKLLSLPCSTGEEPYSIAMALLDAGFPDGSFQIDAIDVSSRNLVHAERAIYGKNSFRGADIAFRDRYFEACNGGFRPHDIVRRHVRFRIGNVLSAAAQTGNEAYAVAFCRNLLIYFDRETQGAALNQLRQMLADDGLLLVGPAESGLPPLHGFNSTRVPRAFAFIKAEAAPVKPPEPPAARRPRPAPAKAAPLPRAQTAKASSAPRPFAQKTASAQPSAPSPDRVAASLAEIERAADAGHLAEVSAAAERHIAEFGPSPDAFYWLGLAHDAADAVEDAMRNYRKALYLAPDHQRALAQLRLLQQRQGDHGAAKALADRLDRLAKRSGT
->MGYP000234632724 FL=1
-RDVERSRGLGDVYKRQIAGIATPTEASAIGAMGALIITFVNGKFSIDFIKEASEKTAIVSTMIFTILIGASIFSLIFRGVGGDELIDLIFGSLPGGPYMALIFVLLLVFLLGFILDFIEICYVIVPLVAPPLLMMGFDPVWLAILLAINLQTSFLTPPFGFSLFYLRGVADESIKTSDIYKGVIPFIFIQLLILALVLIFPFIVL
->MGYP001050647894 FL=0
-MATTKNKKEGLARKRQSPMVLISPSFPWNFRVLPGDVAHLAVQKHREPAADGVSGAF
->MGYP001636256112 FL=0
-MIFRPQGLEAKGLSAGTGRV
->MGYP001782636417 FL=1
-MFVQGNAFRYGSDVDTDVIIPARYLNTSSAEELASHCMEDIDPDFVKRVKKGDVIVAEDNFGCGSSREHAPLAIKTSGVSLVIANSFARIFYRNAINIGLPILECPDAVKAIKAGDVVSCDLSTGVITDVTTGETFRAEPFPPFIQNIIDAGGLIASLASKED
->MGYP003367769974 FL=1
-MDQSLNMVKIAYDALDDKLAEDIKIIDIRSISVLADYFIIADGNNKNQVQAMYRKNFLKLDMR
->MGYP003688882127 FL=0
-EREREREREIEKNREREKEKEEKESEKEKEIERQRDIDSCDFDVFSDF
->MGYP003700002783 FL=1
-MLPAFVLRAIEEGVSLQEILKEHNIYLAFAKLSGRVHGLTYADSSGYYLIIINENLSITAQYKTLLHELKHIIYDLPKMKYIVGKDMNSNIEKEADKIAEEWFKEIVKKLRKG
->MGYP000043255058 FL=0
-MEFNYTVTDKVAIISWNMTTSPMNVLNDVSIPEFEQNVDKALADESLKGIIITSDKNEFIAGADVKMILKNADKDPKEIHKLSMDLNRLATRLERCGKPVVAAINGTALGGGYEICLGCHH
->MGYP001157010399 FL=0
-MKSLRKQGIILFTILALVLVACGGDAAEEEVVEAKEDEPAAEEAPAEEESPAEEEVVEAK
->MGYP000411183089 FL=0
-MSLTLREASKDTLQAENKTWHYYSLPLAARTLGDISRLPKSLKVLLENLLRWQDDDSVTAEDIQALAGWLKNALALIQISWPHESMGKRVIRLLVSKKDRRV
->MGYP000600471748 FL=1
-MTTTRRLSLAYLALTAGVAVLFALNLFWGSVSLTPGAVAAALLGRGEDALAVGIVLQLRLPRAVMVVLLGAALSAAGYLLQTFFANPIAGPFVMGVSSGAKLAVALTMVVFLQQGLLTGSATLIIAAFAGSMAAMAFVLVVARRVPRMSILVICGIMIGYICSAVTDIVVTFAQDSNIVNLHNWSMGSFSGMTWENVLTAALIVLPCLALSFMLSKPMAAYQMGEAYAQSVGVSVRPFSVTLVLLSSLLAACVTAFAGPISFVGIAVPHLVKRTLRSAKPLHVLPGCVLGGAAFCLLCDLIARSIFAPTELSVSSVTAIFGAPVVILLLVRKQRREAAA
->MGYP000149143676 FL=1
-MQFVEDYIVLTAVLSLWQRVNVYVTNSTQETFVIQVKKLCLLLNTLTFNTTMLTISSHTLSIIYYNDNTLDAVFD
->MGYP001584307752 FL=0
-IREGRHDPVLYSVGPVPPGKDRNSHGVVVSWEGRSLRTVFSRMVSDSPVTILEERLLSEDGREMTVRNVSDRDGSETVQLYXXXXRQLSVEHGYQGRGINTSETVTDVYLRQAR
->MGYP001913057525 FL=0
-YRCRDHGFEWPGQAYRIHSMGEPGSAEGMNAENPKHLILKAPHPSPLSAFRGFFGSRPFSKTNAFLEEHGIEPIDWQID
->MGYP003393519970 FL=0
-ENALKALAKNIKGDRYDDAILSAPLPDNANAWKELVDVKALKKSLADQKAEQARLKELLGAIENREQLATERAQVQEECDRRLSSLSLWERLQKEKIEEPRLKKRLSELTKEKAQAEHTRVDARAKLDELSVKLFEQRTALNKEDERFNRLLRLMEQCVPPPSMEAQPSGPMAVPADAEDAIALYTKLTLSYKDMSREMDQLRSKIENVLKSDIIGATENETVRLMKEQIEGLPTFEEALRKDWDNYLHLLRANFANVLSGLSDIRNAAEKLNKRFGSVRVSNLESLRMDVLDQSDLVEPLKELAETDHTGLFDSSTKLDAAYQSFRNKLSERITLNYGDLFTLRFSVVIKGKTHSYDNLQVESHGTAITIKVLFNLLVLRSMLKEDPKTRAPLSNVPFFLDEIHSLDAANRGAVLRMARDLGFMAITAAPEPVSEVDALYFLRPINGRLVVRNELRVGVKYDAVEA
->MGYP000523383570 FL=0
-MQIENNYGNDVYNGDIGFVAGIDLDEQELSVSFDGRTVRYAFGELNELVLCYATTIHKSQGSEYPAVVIPLSTQHYIMLKRNLVYTGITRGKRLVVLVDQKRALAIALKGEQLERRWSKLEERLREPGSIRYRPESLRHLDCPRSGRVHQALESGQVVAHPAEHPEIVSARLPLLVLRLPSYLRRSGVGFISLAHCYNITA
->MGYP002653935032 FL=0
-NDALLREVGSDVKRGDPLASVGNSGGQGRPALYFELRRNGQPVNPASWLSAAR
->MGYP003551677296 FL=0
-QDGMGIRFTGQYAEVLPGFRLDFSGRAGISDAGNFAANIDFQSSEPDASIKIDLGKFSPQLTDLSFEGNIGMSGSCQVTGSTVTSNAVLSTHNAKIEIPGRKMTLEGIDLNLNLQDLYQFHSAPDQVLKFKRFAWGDIEMNEGEVLFQIESLSSFFLQKSSFSWCGGHVYTHGLQITSGKREIDIICYCDRLKLATLLQQ
->MGYP000229859498 FL=0
-MEKEVSFVYCNNNNNVVLFYVAELRPHGLLY
->MGYP001544784897 FL=0
-MPVVEAARYQVHRLQRISPVSQAQLKAERATPLHTLDTLTVATKKGRLFREEAPVLRRLSAAQARPVLAALSPAQAEEFLAGYRTRIRAAYPAAPYGTVLPFRRVFVVARVKA
->MGYP001256815242 FL=0
-MVPETQLRAFRPPLRTPASLYQRDAGWDLSHAQVRGLARHPDTHDLDKIKPIALSHSDKTYLIDNCCNDKV
->MGYP000824429490 FL=0
-RMKGQKNVKDVGRQKGKHSKDQKKQKIKDVRNVIRHQL
->MGYP001586178734 FL=0
-EQLAKGQARTKAYLASEQSCAAEELRADLVDASDVRVVLREAEGESFLLVADGEDELVEDLDAVLRGLDPLFQGHDRVELGVDDREQLAAEVIDQRYVEGAEELVAGEPSFDRGERGELESECARERAVRVRGVAGESVEDAGLVAGQGELVVRRENNRRLRFLAFENNLRG
->MGYP000104835098 FL=0
-SLLIYIIHENIILMSLVERILPYERNLFLWLNDQHTSYWDVFMWIYSGKLVWLPLAIVAIGVFVYKIKWKEALLLLLCAVLVGVLCDYVSSSLIKPFFERLRPTHHPDFQNYVDTVRNYRGGKYGFISNHAANGFGIVAFISLLFRYKYYTITVLLWACITGYSRIYLGVHFVSDVVGGAIWGALVGISMYYVYLTSRRYILKVPKDELKIPVYTKVRAQILMCTIWVLVISIAIYS
->MGYP001657250507 FL=0
-MQTKQTLLKTKRINNKQTKKLEDQLXRLFIHLSLSQSYXVSLLAQLQRMKQSKKILFLNQXKVLMEXKMLHIMX
->MGYP003575916264 FL=0
-VLLVIAGMFLTWRFMIGGLWLGLAGNSRVLAFSAAPYVILPLFVLPAILIMEQPIMDWIAENSRRLLPPLVWIAAAGVVIKFWLAAFSWRKIEPRYVRRYLPVWLGGAVCLTVLAFMLGVLLSLFLPEDTYRL
->MGYP002282927298 FL=0
-MEWTSGVSAVAFKSSLRSVPGSSAANGTSFSVFGHDDSSRGSMDRGAGSGPGSRADSPVEFRFHDHFDFQRQIGRSPTSEAWLVRSKQSNKPYCVKKVTAKFRTPAERSRYIHEVEAVCFLPPHANVVKYYRAWQEHRHFYAQM
->MGYP001843998727 FL=0
-MLLTMSLDSTWRDGKKVRWFAVQATNKTQRNKFTQDCYYSHAQGSQEKWARDXMXSRKSRMCVWQTSNKIIAGDRSCHLRHQRPQPADGEISHSAQLKATDQPIIVKRTVLX
->MGYP000291769357 FL=1
-SAGGADRCAESGVNMSNDRTIGFIGAGNMAEAMIRGLLRGGDFAIAQIAASGPREERMRELRDTYGIYATTDNKVPAASEIVVLSVKPQILSRVLDDVLEYGGDYSIDRFEVGKTPLDPSYARLTVTADTEEDLARLVMRLQTHGVNLTDPGELTVREVEQDGVFPDDFYSTTNLETVVRTGGHWVPVENPEMDCGILVEGDDEHPRARTIAVSDVKRGDRIVCGASGVKVVPLPAIDRSVGGFEFMNSEVSSEKPQALLVRQIAQQMREIKAEGRKVLWVGGPAVVHTGAAPAMVALVEAGYVDVLFAGNALATHDIEAALFGT
->MGYP001585133350 FL=0
-MFSCSFIDKLPIRILSDVKESFLNLGMMCKXKXFKRSYXLHKTTSIWNXIFQSSNRILX
->MGYP003587374593 FL=0
-LNDLSFSELAHKRISLIHQSAIRLLNLINKILDFRKAETRNMLLKISQGYLSKLIREIGLKYKELNRNENITLQIVLESDEQPIRVDEEKVYIIVDNLLSNAFKYTQKGEIVLTLRTIYKQKTAWAEIEVRDTGNGIPVSRQAAVFEAFSQADDSTTRRYGGTGLGLTICTHLVQMMGGRVWLESVEGEGSCFYFTARFGVDSSSSAISSVLQFGDLRVLLIESNPAVAAQLSAFLAQLGVQVTHMAASEAAVDAIEKSRSLGFPFDCVLADIKMAPPGGMDLAESWHGYDHSEKLIMVMDSEEQRRHMSKLRGLGVD
->MGYP003618342538 FL=0
-MEHLFDHAASSTPLDDLLKQLHLTDPSSAIPQDDAFSSLLSDANMVAPPHDADWNAPTFDAAQHESPFDPTNWQDPAHLSSEDMLTSAFET
->MGYP003539180734 FL=0
-LLACVFSLSLVFAVACEEEETEEVVFAPTYTYTDYTQDTDALITNGDFTKGLAEKTEKDFPVSSIGSWNVGADTNSDASVVTNGVISVSDNGWKELMGTFHGVSNFKSWAEKTFNGNNKIDTKEAFQDFMVGQNGLKNPGKASGTTLNDDKVLMLANFTNSTTVDGRGTAMKASSTSTISIAKGKMA
->MGYP000164259871 FL=0
-QIPKGYESRLRYEKFPKKSVDTHATNRKADEAP
->MGYP001127871448 FL=1
-MQAPTKYALVINLKTAKALGLAVPPSLLGRADKLIE
->MGYP001811598644 FL=0
-MTWMCAGLEPLLEDIQQPPLLSGRPVQHTNLWMCSRCVLQAVAGAAGVGLCXAAPCKSXKVX
->MGYP003351460088 FL=0
-MTDLGTGAGRLAWPPPASLLPWRQPVKFPGVAAPEFRRGRRGDPANPRLHQPRDFRVFGRELAYRPVGSEQHLVLRDRLRVLHDQRVDVVRGVAAQVHPHVGLVDDHCESVLVPREGRVREDDLQVGEVRGDVVEIFPAYEEERAIRVEFFGDEIESISEIDPLRGVRIQKIPRITIYPGSHYVTTVENRKRAVDSIRIELQQRLQERALALISIAHPKYRADLLKRSEEHTSELQSRVDIS
->MGYP002526488509 FL=0
-MAGNVDNRVVQLTFENRQFERNIAKSKKSLDELKASMNFDETSKGLNKFAEGMDKLSFSHLEDNIQKLTDKFTGLGTATELVVSQIRRKIEEAARSMSGFVESMTTQQIGVGKDKYDMLNKSVRTIMNATGKEEKEVLAVMERLNNRRSE
->MGYP001359237027 FL=0
-NSVNNQFTPLFQDEIKPGCRIISNTTFENLNNFRINLDIHDSKKWNKNIIYGELRNGYRIAERYKTQQYATFEIINKNDGSICTLQAKVRISGDAADHINLEKFQASIDVELIDENIFGYTDFKLFLPETRNNENEIFVTTLLRHLNYLAPNTFFIDIFVNDQKVKYLFQEKINK
->MGYP000346659406 FL=0
-MGTRIGSIHANVTAKDLSWSDTMRRVREETKRTADLLQGISDRGGGLGSLGSIMPTIDIGNVINRSIGLVTDAYRQLSEAREKAEIKADKADVLGLSMADLQGLSVGAALANTDIETVTGATDKRGTEVHFWADEAIFSHVEFHYDILAKRIRELSFLNNGVHIKL
->MGYP002611241135 FL=0
-SPATPLGSKRRFIRVPSNNFVWHILGGSNAVMGFISSTSAWMEVPFMLLCGFLLTKYSCASLLRISSFFYILKPSILLLASSIPMVALGQYMQGPSYAIFTIASVYYMNHMVDIKDNAKAQALLGICTKGLSGIVANLVSGIMLDRFGINGMLGFCMACTICGFCVIQVMTLQKEKGR
->MGYP001764798971 FL=1
-MSATPVLPRHAANAAGLIARPAWKGRLDWRGLLGWLRDDRLISAEDEQRVTQRFGAGASSQHALVRLGGAGLKRAGTQQPLDTEALTEWLAARCRLPYLRIDPLKADVGRVADVMSVHYAESRCALPLQLNNTEVVIATSEPFDAGWVGEIEAHTRRSVKLVLANPQDVRKYTTEFYALAKSVRAAQKTGEVSPAASFEQLVELGKTAKQLDANDQGVVQVVDWLWQYAFDQRASDIHLEPRREMGAIRFRIDGVLHTVYQVPLGVMNAMVSRIKLLGRMDVVEKRRPLDGRIKTKRPDTADKIGAEVEMRLSTLPTAFGEKLVMRIFDPETAVKSIEALGFGAHDTARWQELIARPHGIILVTGPTGSGKTTTLYSTLKTLATDEVNVCTIEDPIEMIEPAFNQTQVHAAIDMGFAEGLRALMRQDPDIIMVGEIRDLATAEMAIQAALTGHLVFSTLHTNDAASAITRLADLGVPSYLISATVIGVLAQRLTRMLCPACKQRDEDTTRETLDELAKPWRLSGGVRPYKPVGCLECRHTGYRGRVGLYELLVMTDGARAAVHPALDATALRRQAVKDGMRALRLAGAMKVAEGLTTVEEVLRSTPSLDVRA
->MGYP000601219188 FL=0
-GGGLFYMYYVETRSHYVAWAGLELLASSDPPTSASQNAGIIGLSHQAGPGYSKYIIILRSIHHLDHSLTIYFYFPVIVLISWVRHSSLDI
->MGYP000591043049 FL=1
-LARGVARALWLPGLSLSPLRIPFCEFSQIYIYSNALYKQVIYGQRPDHNTGNYVPYSLR
->MGYP003318478948 FL=1
-MIYLFLANGFEECEALCPLDLMRRAKIEVTTVGVGGKYIEGAHGITVCADITDAELCDDAPDGVILPGGMPGTLNLDACAAVHKALDAPEKRGALICAICAAPSVLGKRGYLRGKQAVCFPSFEEYLDGAILQPKGIKVVTDGKIITAVGMGAAVEFGLALVRVLKGDEAANALCSAILAD
->MGYP004071202169 FL=1
-MIVLSAINEPKRYAPLSPKKIFALGKLNNKIDNKIIIWAINIKEISVFALIRLIYTKTKLIIIRLITSKPLKPSIKFAPLTMNKKHRRTKITENISLFVKEIKKGISIFVILIGKKNIMELKKKIINNSLLKGLILNLRSSRNPIKNIE
->MGYP003151139587 FL=0
-MDVEQTEEAVAEAPPAEIVDQAQINEWLDDKLGPAEPEVTEEPEATEEPEPEPAAAEPETPEPETPRVSKAFSKVAKKEREVQQQKQELNKEKEKLKPLQEAQAAADRGDMLGALEKVGWTYEAATNSVLQDGKLQTPKAEPAALTPEVEGRLAKLETMERQKQIDNYVNRMKTKVEGDERFELVKDNWDNAWPTILEMQKIVAQETGTIKQDEEILQEVENFYEQQAQKLAKSGKFKNLLQPDAGPPEKP
->MGYP004197989809 FL=0
-FHVKSEKIEISQKNHLKHDLN
->MGYP001807843292 FL=0
-MCVKEHKEHNTRRTVYARCVCVCVCVCVCVCVCVC
->MGYP000196272724 FL=1
-MALRICSQLTVGGFVPTIMVLGSATEVDRIKPIQPLGTFIFIVFIYLFIYFLRRSLTLSPRLECNGTISAHHNLHLPSSSN
->MGYP000647749030 FL=0
-MEVGAEGDPITFAERRTMSVAGRKIIAGS
->MGYP000363977344 FL=1
-VQHDRNCSRNVSPNRMCLCVFPKGTQMVRMGPDSIGICRGSVKIDVSTMRNPGDALPNIAPKSNVSDNRNENRSKQHIYSTYLNSTRGQNIKSGTGGTLFFSGNFAPGVDFGRPDAHNHQGMISRDTSLQNRPWEPTQGRKPTLFIQIISTSFLF
->MGYP001764752421 FL=0
-MFENLSERLEKSFKLLKGQGRITEINIAETLKEVRRALLDADVNFKIAKQFTDNVKQKAIGQEVLKSVNPSQMMVKIVHDELVELMGGD
->MGYP003108819162 FL=1
-MACFHPLEDFDFINRILPKISFFGGLDDEQLAYIFSRLESAEFSQGEIIGRPGTVPSHIHVIQEGAVDLLISHDQRLVRKRQFTVGDCFGEAALLSLINDTATFTAAGPTSVASLSRLQLLRLHSEKPDIFLQLVLNMARDLARKLQYSDELLLRR
->MGYP001799047598 FL=1
-MYSLYIPVVDSFYVYCIQEAEAAQASTEDDSYEQEIEEATSQEIETDDQVFH
->MGYP000061367530 FL=1
-MGSTYTRQSSTEIVDGEVIAASDFNNEFAQLVSAFASSTGHTHDGTTAEGGPITKLLGTAITIGDGSSGTDIAVTFDGETSDGVLTWMEDEDYFKFSDDVLIVDDEKDLREIIRYNLEQEGINSIQASNGDKAIESLSQNPSLI
->MGYP003345690776 FL=1
-MRNFLKSHFWVLAGCFLFYSVHADQHGTTERILFDGQSLDNWEKTDYAGGGEVRLDGKGGVVLEFGIALTGIHWIGEKVPRCNYEISWSAKKVSGTDFFGSLTFPYLNEHATLVLGGWGGALVGISCLDGFDASENQTATAHLFNTNQWYRCVLRVTEAHFKFWVDQEKLIDCDIQGRTISMRTGEIELSKPLGFSTFDTTGLIKDVRLSSLVP
->MGYP000806452421 FL=1
-MEEKVDIVALGELLIDFTEAGHSQGGRKLFEQNPGGAPANLLTVASHFGYRTSFIGKVGNDMHGKFLKRTLQTEGINTDAIVEDPDYFTTLAFVEIGENGERNFSFARKPGADTRMEKEEIDVDILDKTHIFHVGSLSVSYTHLTLPTILRV
->MGYP001393538896 FL=1
-MKCKDCRKQFSVTGNKRIIYELRGDMACVHVICDVRRDLRALLLRRLVEAPRSPGP
->MGYP003366091699 FL=0
-LRMSRGLGDVYKRQPLASGAKAADQAEIDIIIAELSALAAQYTE
->MGYP001054490991 FL=0
-RRLGHGELKLGGGNGGRGDGAPALMCSPRFKRLR
->MGYP004024396583 FL=0
-MITLILHYXSNRFKIFLFLKYLFHQIXFVMXTRLVXTRLGLIXQCHCFCLVLSGIYMRKMGTSILYGTNRHLRCRLWPKKKKIVTCMTVGLVSCGYFGTIALQADMFI
->MGYP001796939300 FL=0
-FDTVTIKDIAKALNFSTSTVSRALRGSYEISAETKKLVLEYAEKINYRPNPVALSLKERRSRAIGVVVSEIANNFFSQAIDGIESIAYNRGYHVIITQSHESEAREKVNVQHQASISVDGLLISLSSETVDLSYLKELHDKGFPIVFFDRITDEIETHKVTANNYLGALQATEH
->MGYP000574954487 FL=0
-MKKFSLITLLLITVGFSSCTQEDSTFLEEPTAQVLLKSFTLNKSTSGDYSLDYQLNNGAASDNVLDAKTNTSNIYLYSSENVSKSIKNEGIALKDGELRISFNDTEKHKKHSITVLDEEIKASRSEDDTDLGYLNSYSVTTNNDGTFTLDFKVNEWVVVDYIFDLCDGYQYSDSRTSGKANTHATPRKTKGR
->MGYP001104094517 FL=0
-TVFGEEYKNVISSLTDWKMYGFFKINGTIGLKYFDNKVVTLDYKNKKIAVSNNALDYSRLQNEKYTVLPLIKSNLSNEQDLLFFEGDVNGEKSTIYLDTGSSRSFYNLDGTREEIEVKLGEKAYTFNSNKFRHDEIGFKDTFKYPLKLAINSDLLKANHFIIVVDKQKKVVFFRFI
->MGYP004251094059 FL=0
-MNQLIIRTKIICTFTCNPIKRFRYAQVIITKIFKNINAKSKK
->MGYP001561011533 FL=0
-LTLLRFANDDIKMRELGNSIIDEIVNDANVPHEQHLIIEQDREDIMNLTKKAHS
->MGYP003626153934 FL=1
-MPAVHAPRLLMIGAGGHARVCLDVMVDNDDVAIVGAVSAEGVVSEPLGVPLLGTDAQLRELTQSYAVTTFCVSIGSNPIRQAFGELLTQSGRHVTRIISRSAVISRSAKLGDGVQIMPAAVITAATVLGDGTIVNTNASVDHNCRVGRFVHIGPGAVIGGDVTIGSRAFIGLGSRILPGVTIGADAIVGAGAVVLSDVPAGATVVGVPARIIKSKSAQQ
->MGYP003586072608 FL=0
-PLFTIAQIVAAHIGSTPGVLRVLASSFILISLSSIFFGLFCVXXRSPGLCQKNLXNTWCTASVCGSSGEVRARKRLQICPKTIAKVCNRFWADFLCXLFPFAVSHRVKEVRKRLFSCAWALFSEKPFFESDRIRSGXKNMX
->MGYP003337571193 FL=1
-MSKITDLIVPNIGDFKNVEIIEILTKPEQNINKNDGLITLESDKSSVEVPSQFSGKIKNIKVKIGDRVSQGDIIGQIELTADEKIEERIIKNRSNHDLTTEVFSKKKELQTIAISPNKDENNFVKSASPKIKKYARELGVDLQLVNGSARKGRIVEEDVKQFIKNTLNTKIIKEEVIKNIETKEEKLPFEHEEFGEIDIQKIPRIKRLSGPHLVKAWNEIPHVTQFDEVDVTDMEYFRKNLIDLNTKEKITITPLAFIMKALVNAMKKYPNFNCSLETINENIIYKKYFHIGIAVDTPHGLMVPKIRNVDQKNLLTLSNELRRISKLSKELKIDKKEFFGGSMTISSLGGIGGSFFTPIINSPEVAIIGIGKTETKQIFIDGKFISRAMMPISLSYDHRIIDGAEAARFCQDLKTSLGKNFAFKIGRAHV
->MGYP002417791626 FL=1
-MLKMEESKININRIHFLYEALAKRHASPEETYHAILNEGLKAFNLSLGIISQIEGERYSLLAVSPTRGDISAGMVFELKDTYCQRVVSENRIISVEHAGEHPGFNNHPVYIGMRLESYISAPIWVRENLWGTLNFSSTQVRAISFSEDDYEFISLMAEGIGSLIEMNLLISENENVISALRKNNDILESIFENSTIGMALVAPSGQWMKVNSSLTRMLGYTEDHLLSINFQNITHPDDLTTDLKQLEALSQGNIPFYQLEKRYLTASGHYIWILLSVSLVREDNGDVKYYIAQIQSIDERKKMEMELKNQKEALHKVNIILERMATEDSLTEIANRRKFMLWFESEITRMARHPVPVSLAIADIDFFKSYNDDYGHQEGDFALQNIARALSHPLRSQDKIARFGGEEFIMLFPETDEKGCLLACERLRKRVENLTSLRRTVTISIGAVTCHPKEGELVHFDDLLKVADSKLYEAKRSGRNQVKVTSLEDHQE
->MGYP003123586391 FL=0
-VWGRWLRRRLRKDRGEQLLSIVRSLDYAMNNTSLILLFEVGDTKLLFPGDAQYENWMYALGQDWVKKLLEGVDVYKVGHHGSLNASPRSMLDLFEKKRSRTDDPEKVMHSLLSTMHGVHGSVSSRTEVPRKTLVKTLEDETQLTATSDFGGEISHTVTLPL
->MGYP003322783177 FL=0
-MLSNVNDIDEEKLKTISNNQYAIVKTEDLNNIKDENRIIFAIGDLHNKINNPDLKIIILGNVFVETEDFTSTEGIQSISGSLYIQSKGGLETPNLESVYGNIYIDDSLFTQIYVKEIYGEINIKNSIKTYILADNAYGKIKCNKSVDTQLD
->MGYP000483552797 FL=0
-GRPVAVPDLPGLPEAVSEAMTITLNPIGVIRSPHLAAPGTPIQPAFAQQYEGHVLVNNEFEAALADIEGFERLWLIYLFDRAGRYKPRVVPYRDTREHGLFATRSPCRPNPIGLSVVRLLGREHNMLRIAGVDILDGSPLLDIKPYVPSFDAHPSSMAGWLDERREDRTEADSRFHGENGPETAHDGAARHGKTTVKP
->MGYP002514261527 FL=0
-SRVTRDLPANEVAVGTTCRVLRKIGEKDREYYFRDKKIKL
->MGYP003501294569 FL=0
-NEEAYELTVKTGKMTYFSRSRNEIWVKGLTSGHFQYLMSMEIDCDNDTLLAKVRQVGAACHTGERSCFYRNLMSREYANTNPLKVFSDVMATILDRKENPKEGSYTNYLFEKGIDKILKKVGEEATEIIIAAKNPDKEEIKYEVADFLYHVMVLMAVKDVTWDEIITELARR
->MGYP001567805989 FL=1
-MNATITTIIISFAVLPILVLSYQLGTPSIGESAVGEYLKQPALTTFALAKKQESKEVLPRRRPEIADLVVDSSEALAWDSKQNVTLFSKNSEVTRPIASLTKLITAAVVLDYTQPRETVAVSLKAIRTEGNSGNLKEGEVLTVYDLIAAALLESSNDAAYALAEYTGNKIISNQETPPDPVKTFVRSMNQKFNDLGLVHTNFTDPSGLADKTSFSTAEDFSRFIKYLRDNQRYLPIWEILKMNTYTTESQNGVSAHEFRNTNPFLAELSGVIGGKTGYTPAALGNMALVMSGPNGTEIIYLVLGSADRFGDIRKMVGWVSEAWVWPAPM
->MGYP003352111790 FL=1
-MREWNLEEIKMNKAQSKENIFLLKGWKGVVVLYTVMIATAAITIGIAQFGGGVLSP
->MGYP002236981273 FL=0
-DNNRKEINEARRDFENSFFNMLNLLQVKIKDMRVVNKITKEVHAEDVGYSFISLSHSEVKYCKEITLEYLKRIINESWTEWPKQSANNICNIFIAAHRIYLIIIDFCLIHLSLLMSLKLVMLIKKRYANILGRKISNYELLMLFYNCLSEDGRKFQYYFEKYEILDNLPIIKMAYKNHVLLVNKKCWGDNKQALELINGE
->MGYP001471266083 FL=0
-MNVFCALRSLPHIMSIGILSQKTLFLIMLTSSTNLNFMIKDHPIFLESIRYIRSNLEANDFNYLEKKVLERLVHSSGDFSIQNLVNFSEGACEKGLQALKNGAPILTDTDMAAAAIKSMAENTTRNKVFTASMWFGE
->MGYP000742235348 FL=0
-MAQATESRSSSSSQPNIQDVFLNYARRERLPVTLHLL
->MGYP001188259027 FL=0
-EQYGLDHDNFIGSTVQKNNLELDASIVWHATDYLDITLEAANLLNEALVLRQPKAGNIVHSVDEFGTRYFVGASIRF
->MGYP004019405559 FL=0
-MKLQNYFPYFSLFKFSIYFLISSIYLLDMSVYISVSIIEKIIIDSPKATPYVMELFAISLANSFGLKPIKRIKEK
->MGYP000810644476 FL=0
-MTVAEDGSVTVADETLTTLRVPQGVAWMAQPVLRSVNGGDAAENRYPMEPNGTVALVPDTVGPTGGLYLYGVPGADLESKTYQWNGSKVTLCAVYTDVNGKKVDASVFTYKKGNTLFFYFPVTIGGEAKEIEITDLDVPTHGQPLDRTATASVGTVTKVRYEMLRKEINEVSKGDNISVGVQVKIPKGFTFADGSYAVWNGQTSEYRIRTSSMGSDEYLYVF
->MGYP000110014348 FL=0
-LLRKNELSSCIPLAKSIISLGTSGFIMQLTNSLVSICCNHVLSVTGGDVYVSVMTIVSSVRQMVETPIYAINEGTSPILSYNYGAQRPKKVKKAICVLTCMILIYTAITWSVIIFEPEFLIGIFSTDRELLADCVGALKLYFAAFIFMDLQYIGQTVFKSLNKKKQ
->MGYP000289551974 FL=0
-KRNCAKAGIQQEIRKREHYEKPSVRRKKKAEAARRKNAKK
->MGYP000993698250 FL=0
-LTVHVDKRPDLESHTMTNLLVEDEKLENLVQETGVPNLFVVPSDTSLAGVEQVLANRIGRETILREALEVFPAGKEFDFVLFDCPPSLGVLSANALVAADFVVIPMQAEYLSLQGMAKLLEVIQLVQKRLNPQLQIACVLPCMLDARTNLSTEVLREIDAHFGSLLAKTRIRNNVKLAEAPSFGRTIFEHAPDSNGARDYEAFGAEFLAMILVLVYVGAVAVLFLFVVMMLDVDFVELRQGMLNYLPVG
->MGYP002735085997 FL=0
-EDAFGFVNAECRYPENGANWTEEVFQNYGGTLKWISYNSGVGIPEPEPDITGKCGDNVTWGFVERSGKLTLSGTGATWDYGSYGPEEFKSFRDRVRVIEVKPGVTDLGTSLFVFCENAEKVILHEGLKTIDMFTFQRCDSLTELIVPESVTYIESAAFRDCPSLVSVRLPSHFTRIPDVLL
->MGYP001200674681 FL=0
-NGWIITIVLINLLGCLWLLWWTRKRPEDTIKEGESLGHSFDGIEELNNPLPHWWLNLFYFTIAFAFIYLTLYPGWGDAKGILGWTSVGQWETEVEKAENRYDRLFEEYAQVPVEQLAGNEEVVKTGQRLFGNNCAICHGSDARGNVGYPNLADDDWLYGGQPENIKTSIVQGRNGIMNPWGDVIGEEGVVASANYVLKLSGRDHDAGQAAE
->MGYP003380670323 FL=0
-MKKRYXQSAXYGCASRXAHKNYXLIREMVIQYRPSGXWRKGKMVQPHFEXLHQPARFHARETERXXGYRKDPMDRQSLXQFLLLXSIHGKIPXRRXYXISILSDSPTNIMXELLGIRKRXIYLPTGKVNVFCCSWNVPIXKQPYGXTDKRQECRIVFVFPINMIXPIMSVPENVLSLSGWIIVSKKSMSDRIRTAXPTRPKETGTALXDASVCKRLRKHISMIFKYIRNRNKTGTCQSRHQRYRHCKSKIISRELQYGXKHIVPAIQQEIKLNKGVTETEMVLPMGNDMLLWDEFHPALYKLKAEVTNGKKLRXKKYNSVCADLKSKVNGFMXTGAKPSFAEQLKTVTSRXPVTPRWMXKVGNGYSVSVAVMDXITCVSIHSVLPKPLLWLPTGXDSICNPKVRAGPIMVPNXVWDNLLTNIXWTKPSHXPKNMATMLLIACWHAETNLADAGXNGXPSSXNIGKRRIPDMYIPEHRXATDGNGNLATNIMXRLGHVAXPGPRNNRPPKTTIVSKIILTPXDSPTYPMKQVNGALSPISMKYVNIQASIKPRTSRFSKTFWLTTTXATKPIYLXWPAESCKPFVTNMKXKRHSARPIMPVSNYWHXTIIRVRELHWXVFSMFSLKKKDISTLQNGDVSAHLQFHXCVQINLYIITRKFXRRILKSLILVPRHXNKQKLYIRXKTNMAKYMRKAHWQHKTFLSEIXIAQVALSFRLLISKRLKAESGNTHYGNRSCKXLEFLGLSRPSDNSRRKSIHYRHLGFESPGNSSEWWKCAYYSCGQSELWXRSGPAIHSCILEHLLVQNASSSYHRYLSEPQTPVIPSVSDRISQQSAMVGTAESCSSDAIHPLSTRFPTYGSKHRHLVYKPQDRYVIRSQCIKWESAHDKHGHYLPARETHCSPSDAXSHFGLYEFGPVPSAIYCNASTNQXVVHKTAGDIX
->MGYP001753171793 FL=0
-EMTSSLVGSEMCIRDSDRLLSLLGLARRAGRLSLGNDPVLSSMEEGKAKLVLVCPDLSQRTLKGIESRAEAFGVPLVTIEQTMDQVSMSLGKRCGVLALNDEGFARKALTLTKTNGEDLII
->MGYP001606986961 FL=0
-MKSQEKNCIIIHGCPSDAEKAMNPETRTYDKHWIPWLKRNLVAARIKTDFPFYMQIVNRWVKIEPAVWNLFYRNNGAKVNFSGQIFQAVQYGLNPETEQIDYDQVATLAQEHRPKVIVAGA
->MGYP001452258850 FL=0
-MHDKKIVNERLISSTVEITKEAGEAITEIYNSDFDYQLKKDLSPITAADNLSHNIIVERLESLTPEIPILSEENCDIPYKIRTQWTKYWLVDPLDGTKEFIKKNGEFTVNIALIEKDTPVFGVVYAPAIDLLFWGSMQLGAWRKNAQESEKRISISTQTSKKIKIAGSRSHPSEKMKSFLSQFVDYELQPMGSSLKICLVADGTVHLYPRLGPTMEWDTAAAHAILQSAGG
->MGYP000432580839 FL=0
-GYAFFGSHRIGESYRTGLDGVYYLTAAGVLAKYRSSTEMLRRLVLSAMKELAARSPLGRIETIMSEKDPKLRRIFESLGFETTARYRSFIKRP
->MGYP001553361461 FL=0
-GPRHRRRRISEGPQGPHPVIDGRRMTAFCSNDYLGLASHPQLVTALKRGAERYGVGSGAAHLVTGHSGAHHALEQELADFLGRPRALLFSTGYMANLGVISALAGRGDLVLEDRLNHASLLDGATLSRARLIRYAHGDAAALAAALEGDAGGECLVATDGVFSMDGDLAPLPDLARAARERGAWLMVDDAHGLG
->MGYP000983384177 FL=0
-MKGKILGVNGDGSGGVILGDDNKRYNFTQEEMKNSSNPEVNQSVDFNADGRDAKDVYTVASGLFDVSQLKIPSFSIGDNFQVVILSLLVLFFAFTYYKNSKIEEAFVEFIATQEEYKITFEDYDCSGLFSTDCTLENIEFTTGGVLDFEAESLEISNIYELGTFDQSYRKSKIPFSVEIEGIKFAERIQETYFKSFVNNGGFISAREKELSEEVYNYLIDSLDSDTITLDGKLEVANKKLNRLEIIELSYDNDILPISIDMKVDNLGEEKRIVRNVTLRLSSENLL
->MGYP003554407810 FL=0
-ILCFVTRLLMGLCVGLVYGAMAKACKNATANCFVASLSAPLLNTLFFMGYIVLAFYNCDYVQNLVSVKGAANPLMFVVLLVGVQGVAEFLVSGILGGIVARAVHKFLK
->MGYP003431497335 FL=1
-MHQQVSLELLEILEIGCSKSNPASAGHLKLKHED
->MGYP002928876319 FL=0
-ALHVMDEANRCLQCKVPQCQKGCPINTNIPMAIRLLKENKLNEAGKMLFENNPLTTGAVSSAIMRTSVKVTVYLDCLLYTSDAADDKA
->MGYP003442291329 FL=0
-RDNTMNTINAYYEYSIDMQPNMSIGQNYITDIRTSKQTFPNGSTTGARWIQFKIPVAQPENTIGNISDFRSIRFMRMFMTGFSDAVTVRFGALDLVRGDWRRYTNTLDPNDTNPTDDKTHCDESTPPDYGVPEYTAATRPAPVRLEAAH
->MGYP000852449644 FL=0
-AINFKFSLSPLLDSTKSQVTVFINGIYAGTTKLKTVPGRKMNFKVKIPPQARDRQLLEVAVRYYLDTEQQVNLDCGRRDYDKAWFIIHGDSWLDYKHRDKNVFYLSDLPGPYLLRKKVNLPLFVMPDQPTAADLTALERLSMSMGQLMPKNENWFSVKKASQITKEDLKTNHLIVIGLAERQ
->MGYP000542208118 FL=0
-HTTAAALPMMRKAGWGRVVNIASAHGLTASPFKGAYVAAKHGIVGMTKVVALETAREPITCNAICPGYVLTPLVEAQIPDTAKEYNMTEEEVVEQVILQRQPSKEFATVEQIGGTAVFLCSDAAAQITGTTISVDGGWTAL
->MGYP001017409220 FL=0
-ACRTTRAITRRSNPRTSRASNKMTSSSMAVFGQVNLMVLVARRSFRQHLLDDELGNIGAVGLLMVHRADRPVAHIANRPAMRFRRAVAAVLGGAGFAAIQPAVQLGQGAGGDHGMHHVLQVGGLLDGERLRVRDRLFAVDQIGRQGLGGADRGGLGRQRHRGYQHLALTDGVGCHGDRVVGRRHGTVEGVEAGVEIHAHAQACGRCGQLTGCEIPGLVHEGGVAGLLEGGAQRDLADELGRIAVVVAEYPAVDLGGL
->MGYP001607760096 FL=0
-MSDTGTEAPGGATHFTVSKGNLDLFDYTRACEEDRKSPNCK
->MGYP003410680479 FL=0
-MKNNLLKYGLFTFSLAFAISCGTPKANLTAIQKDPIAQRVDSVLKLMTLEEKVGQMNQYNGFYDVTGPAPSEGEASKKYENIKKGLVGSMLNIRGAKEVRAMQKIAVEETRLGIPMLFGFDVVHGYKTVSPIPLAEAASWDLEAMKKSAEIAAAEAAAAGLNWTFAPMVDITRD
->MGYP000424193527 FL=0
-CDSVVISSFVRTGYTTRRTRLIKHVIPPGLLGLVGCQIENVEPVISTFL
->MGYP001346217960 FL=1
-MGDAFKALADPTRRRILELLAQGDLTAGEIAAHFDMTKPSVSHHLNILRSAALITDERGGQNIVYSVNLTVFQELMKWFYDCGLVKGDDSNEKE
->MGYP003339884708 FL=0
-MSVSKFRFVSPGVQVAEIDNSQLPRLPSAMGPVIIGRSL
->MGYP003507622094 FL=0
-VELSADDGDPTEPDHALVWMSASEALSKMRHEAHAWAILHWLRGRRGV
->MGYP003457963375 FL=0
-RSSETRAALASSGVPRGVYAGKKPEKLLLDPGFVITQANLAEKQEEMWGFTVWKKQNG
->MGYP002508125824 FL=1
-MRAGCNPGGGIGVPRDNSVSTGSVRVLSRSESSWIWAEKSLSAFTAGSFWSSVSTDTGAGIPEEEREQIFKPFTRVRNLAEGDGLGLPICAFINALGESSVA
->MGYP003488338009 FL=1
-MDHVWLRNPPRPSGPDRGPPRTLNELHYDQLMLRLKFVEKIEKELGHKGLAAKGSIEEIMSADFNQEFEVEREHVPGKIASCWEVCYWVRTNYGNRHMEVLLTGELLRFSDDVVKLKEKFAKQDSAFAYSGR
->MGYP003140940673 FL=0
-MSASGPAGQDGGGSKESNKKARKDLEVSAYEREIEKQNKLKSQKQLTT
->MGYP003132782948 FL=1
-MASAPPTGFVLKAYLTEANARADSNALQVTTNTAYLINKEQDANYNFFTHIEYYFRIEANDPVIEFYIDWDDGENNDPKGKANFSLIKLDTPNNIAITSHIFTRDKLHFPKIRVKSVDGFLSKFYQAAGDDTFEGIDVLAVGDALIDEGRNDRYRLENDKTNAERIPILAPTPRPPVGILKADKKRVFAGITNKYLAGVGGTYDGVTCRLIGSHALMDTTRDNVKVKVTYYAGGADQNDLGNTGSGELIETEMSITTTPTISNVLSVVKMELVDLRENTSENQADIADGTASSFNTSRLFAGEKMILVVDGSSAYQNDTPSVIGEVSMGNPILVLDDPKFSVSLDATESFCRSPEQTIDEYKIWDGDYVTNHGFDENTALFSASSTDTSDIFGAGAGRDTLRAASGIKTTSYAFHPSMTFTDEYHRWLPKQLLAIAQVKSSESAAKAATGTVNDTRATYDHSFVEHWVDESQSNNYGEDRAGIEEYNWPSDMTSSAFFAFKGPSDSDNWHDLNPFNRLTGLDMEHTLFHQTDRASVTGGTRRYANTSTNDLDQVNAQGAYMICARDSKWTKQHFVTKAYSRDTNRTASVGENGPYRAAPITVNGVANKTTANEWSGVSHAAVRVEIFYTARQDGSTNIIWKPLKRIDKTKHPYLSDSTFYSSGAMEWMEPEDWVECDPGDIPDRFWPGGDFESSLEPDTERDSFAYDSDATGNYFDVSNRWNATNKKYGLMWVLTSDGGVDSQHDTFGWGPDVHYSFPASNKNSVLIDIVDPMHVSLNTHAIAQSVSYNHKGKYQIIEDRMGKSEIRKIGATGGTLTFGGVDLKDKDGTFTRDKFYEYQKRAIPVFFDIEHKSRNISRFFGVITDMSEDHPVGKQHGKFGITMQCSHMIYFAGSGSSLGDGSILSDGYVSLGGDMIDEFDYI
->MGYP000711591066 FL=1
-MKTNTIITIGRQYGSAGREIGSKVAEAFGIKLYDKEMLARAAKESGICEEIFETHDEKPTNSFLYSLVMDTYSFGYSSAAFADMPINHKIFLAQFDTIRKIASEGPCILVGRCADYALEDNPYAVSVFIKASLDERVQRIKRIYELNDSKAA
->MGYP003326832321 FL=0
-TIEQVLYRRVYDASDDEVQLRACAPKGYVKSFTVPGFHGPKPLQIRHQILLDYHNSRAGGHPGRAATVDAISKDWWWPGLYEDVKQWIQRCPFCSKEKGISGVSAWTRTELHSRPFRMLQFDTVSAIGGGDSGYKHILTARCPFSRYYWLIPLVGETAEEIAEALVTHVLLGLANFPTILQSDNGLLNQVMTCLMKTFEIEHITSSSYHPQSQGKVERMHGHLNELIKGLVRSEPSNWVKMLPYAQC
->MGYP001544677532 FL=0
-LLDRDLSLHFRLLLALTGTLGRAVAARPTQRYDYFTTDDTDETGCWRPDAGWNGGRPGS
->MGYP001464162734 FL=0
-IMFLLRKPSVKILAIDNFSNSKPNFVNNIKKKYKNKFFFKKIDIRDEEKLTNFFFKNSIDVVIHLAGKIDAIDSFKNKDEYRSVNLDSTKKLINISASNNVKRFIFASSAAVYGEVTQGNCSEKKKTNPINPYGKYKLQAEKYIINKKKELNFVILRLFNIAGIDKIFYS
->MGYP003602224053 FL=0
-YSFLLTKNILMILRRQYGKSQLIFPEAFLFPYALIINRTKHKINLFVRFLVYFFVFVE
->MGYP000042883827 FL=0
-WKVQIQVLQIVLARAFENQARRALSHHALEPETHLLAPTQIGAGQGIGLAQILGRAVEHDAPALRAGKNEAEPHPFPATMHPVIEAHRAQLLALARRHGMRSIKVFGSMARGAAGPDSDVDLLVEPEPGQSEPVRMFALGALLMDAEELLGRHVDVVTVALLHPLLRGRVLSEARALGVIAAA
->MGYP001545084500 FL=0
-RMAPAIQDLWMLLSGDRADQIAQLSEVVEGYNEFYDFHPRELNLIEALRALRILYHTAWIARRWDDPAFPRAFSWFNTERFWGEHILELREQCVVLREPPLSLT
->MGYP000472409418 FL=0
-SGDAMDLIKNFKLHVLALVIVIIAEMIGVLRFGLIMFLPLFYALVIGGIISYPSFKIMKLPEMERASRILTVGMLVLVTKILGIGPNLEMLSHSSLALLVQEFGHFFGTLVFGLPVAFLVGMKREAIGACYSIDREPNIAIIAERYGLDSAEGRGVMGMYICGTVFGALWVSILAGVIAQLGIFHPHSLAMGAGIGSASMMAAEWEMQGGTSVPVSGPYGSRLMETPISSTASIVATHPEWAETVQAYAAAANLLTSVLGIYFALFVSLPVTIKVYDWLDRFRSKKKAA
->MGYP000294864057 FL=1
-MKHRMKRAAAPLAGIGAVVLVWYMVSRLGLLSAYVLPPPPKVWSSFIKMLVTGELWKDIYISYVRVMKGFSIAFVLAFLLGMVRSLLPASGRYYEFIVQFFRNVPPLSMIPLLILWCGIGEMTKTVIIVLASFFPMYLNIVKGFTGCDRKLMEVGEMFGYSKGRRFLRIVLPYALADILVGMRIGLGYSWRAIIGAEMVAASTGLGHMILFAQQMSRTDKVIVGILVIGIVGYVTDRVFALAISKLLKGSGDNGWD
->MGYP003498844063 FL=1
-MSNDTTSTRPALTTLSDDEAAFRDAVAAFAEGEVRPRVQAMEREEGAARDLVRSLLERGRGEVLFQVETLTDHVTQNLPRVEIVEQVGQIDIEHVSQNSGRVCRDMVAGFIRWVTFDRKIENFTE
->MGYP003578506829 FL=0
-MLMVTPKTLVATTAELIAYAKARPGKLNFPTGLGGAPHLAGLSFAQRAGIDWVYVPTKGGANSVAAMMAGEGDAMFLGMLQSLPHVNAGGLKLIGISAG
->MGYP002788440824 FL=1
-MSRISLAKNYDYNCELIIIGDSTVGKSSILSIYNNNTNPLKQISTIGIDYIIKDEKINDKLVKVKIWDTSGQERFKSLADNVLKTSHGVILVFDLNNKETYDNLKTWIQFITIKISENIPLLLIGNKSDLEANILYGESIKFADKFNMKYFETSVKNNTNILESINWLVTQTIEKGIIKLIDKNINK
->MGYP001490688083 FL=0
-VVIRRRVIPAAVAVVRQRAGTTADGEITDRQRVAFNVRRVRQQRRARDRVRPAVLGNGGQRHPTRYRGVVDRGDVHRRGTGDGTIVRNTVRRAVVGDRVAEAHIAVVVIRRRVIPAAVAVVRQRTQTIGNDQVTDRQRVAFNIQRVDQQRRARDRVRPAVFGNGGQRHRRTRRGVVDRGDVHRRGTRDRTVVWSAVRRPIVGDRVAEADIAVVVIRR
->MGYP001613389359 FL=0
-LEFLLSQVDKMCVGGKIANVFLAAQGILKSELYPADEIAVAKHLLESYSNKIIVPSDIVIGNDDGSYVQTIDAGNIPESVGGVWDIGPKSVAQIQAACEGAKTIIWNGPVGRVEVPAYEQGTKSLVDFLASHSAYRVVGGGDTVNVLEKMKKIDAFNHVSVGGGAMLEFLEGKRMPGLEPLKI
->MGYP001822186784 FL=0
-AKSEVPGPPKAIPVEKLAPAQTELGLRLVGTVVAYDSRLSRAFIGNRQTRRQKIYSEGDTIDDVLIKKILRNKVIIATKAGDRLLTVRSAASGNSNETYSAAPQVSRASMPQSQSPGRPSNSARVRHISLDRQEVEDSLANVDQVLQELTLTPYMRFQKPAGFRISNLSRNSIFNKMGLSSRDVIMGINDQKITSPDQAAEFLQTLAEGDEVTIKARRRLRTRRIILSIQ
->MGYP001418701337 FL=0
-VKPLMSSSGKGQSLIKNDSDIQKSWDYAMEGSRGDLMEIIIEEFIDFDYEITLLTLTQKNHNTLFCPPIGHRQERGDYQESWQPIDMREEHLKMAQEMALQVTESLGGNGIWGVEFFIKENKVYFSELSPRPHDTGMVTLAGTQNFSEFELHARAVLGLPIPEIKLMKNGASAVVLANNISVEQPKFSGLEEAMNVTDSDLRIFGKPTTRPFRRMAVTLTYGKEDVDSLVERAKELAA
->MGYP001258882498 FL=1
-MADAFFVCVVFCSAGAGAPHDWPGHQARRAGPRALLQNGGDARRHRGRQREAPRRGHQLRGEVLRGQAQAGGHGKLILFKSSRMCALRWRPASRCLERESNNSEQQ
->MGYP002553949049 FL=0
-TESTKCVIALIDEIPDRITLDESVIAKVEAARKAYDAITDLTQKSLTRNFGKLTGAETNIERLRAGQQSSSSDSSSSAQSKSAPVALFIVLGVLLVSCAAAAVVFVLRKKKNK
->MGYP000347212883 FL=0
-NRIVLRNYGSSPPTLQIWLLLSHLASHCPIHTHTHTHTHNTYMHVTMYMYVSMSMSMSMSMSMSMSMYMNVYMHMYMYVSVSVSVYVCVYVYVYVYECVYAYVYVCVCVCACACGCACLCLCLCLCLCLSRVCVYVYHICICVCVCVCVCGSIFLCLSLSTAFPACV
->MGYP003507787529 FL=1
-MSEQSTHDAYEAKAKSTFSAERKEDYFVLAVAAITVALVLSGVIGPNFFKSLFF
->MGYP000959777104 FL=0
-KEAKDARRLERAVFRSRPVERDEAEWVEADDPEDALAPLFTWVGPDLPEHIGPDCDPEEDMLCAVGSNLLVIANYKVGKTTQVFGMCYRLAGAPTPWLGVFATPQPLTVAYFDFELLASQHKRWRRRASDALGVRHDEDVQSRFRSLPLRSASAPNPATKAGRKALVRVWLAYQPDVAVLEPATAWVEGDGNSAEVVIAWTRGLDLAKGKYDRARMRAWEEAGAVGVPPPPLTCVISLHTPKSVKPGEETAIGSGRWMGWADE
->MGYP000823295119 FL=0
-KIADFLAGMYPETIDRSLLLTGTLLHDMAKAQEFVFSQLGLATDYSIKGQLLGHLVMGAQDAAETAARLGVPEEKSVLLQHLILSHHGEPEFGAAVRPLCAEAELLSYIDLIDSRMEIYAETLPAVPAGSFSARIFALEKKIYHHN
->MGYP000922530624 FL=0
-MSPTTVRRPIRPAALLRSVLR
->MGYP000535681885 FL=0
-VWLKDYELPGVGDFLGRPPGYLMGSDLDRAYAHCRRIAKKHAKNFYYAFRTLPREKRRAIYAAYAFCRHCDDIADEELSHEEKMRLFADTRRRLSQAQNGSAQDPVFMALGHAAKAFGIPSEYFEQIIEGVEMDLTKARFQDFDELRTYCYHVASVVGLVCIEVFEYE
->MGYP003610816290 FL=0
-CCSMSPSVHSIWSPPCILAPRFLAPARLGALVGXDFPLGMPLDDVFFDLVTVWAP
->MGYP001477694372 FL=0
-MPRGGTAGKAQESNRRLGSVRGATRAKTPPPCAYAQTSQITIKVEGKFVSRGSREQA
->MGYP000729372693 FL=0
-LLGTLCGDPRATSGRIVFDDKDITDWQTAKIMREAVAIVPEGRRVFSRMTVEENLAMGGFFAERDQFQERIKWVYELFPRLHERRVQRAGTMSGGEQQMLAIGRALMSNPRLLLLDEPSLGLAPIIIQQIFDTIEQLREQGMTIFLVEQNANQALKLADRGYVLENGHVVLSDTALDKLESIPGFDIFPDDNRFREIIKDVGVAIIGQTSSLAPADKRFYATRDITATVDSIPLITASILAKKLAEGLDALVMDVKVGSGAFMPTYELSEALAEAIVGVANGAGVRTTALLTDMNQVLASSAGNAVEVREA
->MGYP003294174267 FL=0
-PQIDQRFVNFGVVAAEDAGVGRGLVKTDKNNIAPRLGIAWRLTDSSVLRGGYGIYYPTSAAQGMRDAFAANAFNQRITKSSTTATPLGGLPGGVNPRGVTPFSGGSVVVQGVAINAIRFDLQSPRIEQFNVTFEQEVKWNTGVRVSFVGSRQHNLIAGIDLNMLAPNDTPFGVHNADGDLCTPGDDCEESAADSARRPFPAL
->MGYP002514170153 FL=0
-LKSARIYREEQMKNLEIKNPERHTERLMNAMQRELRLDRQPRHIECFDNSNLQGTNPVASCVVFRDGKPSRKEYRHFNVKTVVGPDDFASMREIVYRRYSRLLEEKAELPDLIIVDGGKGQLSSAYEVLCALGIENQVPIVGLAKRLEEVYYPNDPMPYYLSRTGEPLKVICHLRDEAHRFGITFHRQKRSKNFIVSELESIEGVGPKSIEALLRRFRSVSKIRAASVEELAEVVGPKRAELIEQWRSKS
->MGYP000515275479 FL=0
-MASRVKINNIKELEKRKNSTHPSLVNIRKILSLLKNPQKNLGITIGITGTNGKGSVAKTLSTILNDSNLKTGLYTSPHLYSINERISIGKKNIPTKELNQILTEIFETEIKANIKLSFFELITVVAIIFLSKKKNIFNIFEVGLGGRFDATNVIDSDISIITNIGKDHKEYLGNTLLKIAKEKIGIIKKDSFFITGMKPYPFYRVKDYILKKTKKIYIFKKDFQIENNKEFYKYENLTFKPSLKGSHQIENMALVLKTCSIIKNNLGFNLKNQNIVDSLESVKWEGRFSILSSSPYKIVDVAHNYEAIKVLVQNVKKITSKKFIVILGMLNDKDPIKCINELLNIANKIILFKVNNQRTFIPEKIAKKINNKKVVLGKSEELGALIEKDINTLYCGSIYFIGDLLKKYKNLRSC
->MGYP000931687007 FL=0
-MKNYLNEKYNDLDSVAKLHCKSYITADPYPHIVFDNFFNDVMLNEILNEFPSELDKVGSKYNTNQERKSFSNNPDQLSPKINNFLNFTNSHKFINFINILSGIERSLIPDPYLFGGGLHELKDGGFLNIHCDFNKHPQMNLDRRINALIYLNHDWQEKYGGALELWDKNMKNCVQKIQPIFNRMVIFNTTNFSFHGNPEKVTLADKSKSRKSIALYYYSNGRPANEVSSKDHSTLWQNRPNTSDT
->MGYP001385379217 FL=0
-INLILIYQIFIYLLKNKYWTFIENDATNYHYLHLLYRNSVLEVAKHIIEGCKAEDQKCCKQLYSMFKDKMYGVCLRYAESEHDANDIFQEGFIKVFRDISSFRGEGSFEGWMRRLFVNTSLHFLKQKRKSGFVFEDDFSQYDNADELDDSIEISENRQNLLIDLMQKLPSGYRTVLNLYIMEDYSHVDIANQLGISVSTSKTQLMRAKKMMKLMVESALIKN
->MGYP001196022355 FL=0
-MLHAPVLHREAVIPNLATQRGFRRRVAVVDFPWSDRERVRGDAHALLVRISGKALRVVRAGPDRHALALRALLVLVVDRLVVEEVADLHLAAVPRAPAIFVVAVVVPTRSLGDGSPLFCIRFALQVAVRLLPRVVPGPGKTERPAYHVRVGVRVLVDPVAPGVDRVRRQARAQLKRGLGVGGLGAFYLVLCALRFEPEALFKA
->MGYP003389695985 FL=0
-DEIQYRVWEMTPHLELPGSDHRSPGPRTPNPNRRQVRVPPATQSSHGQHAPGGQMGXIPPAHPRLLPARFQWCQKYSTGTALNRRLVGVX
->MGYP000014734933 FL=1
-LGRYGVRTIGELSKCSEEMLETLMGKMGSQLYRYANGLDDSPVRGAADREPIKSVGNSTTFRRDLTRWDEVQSGISLLSDSVAMRLRRYGLYCGGVQAGIKNSRFQVFSRQTTLDHSTHLMREINDTALRLTKDLWKQSQARALCVFQHSGCYRHRSLQVPGCASQVGGHNFGGRGHGPFFISILFIQHRVSGSVHHHGTLSAGGRQRPHRHQQKQT
->MGYP000109000080 FL=0
-NVFYQDMGFSKTDIANAVKLVGVIMVIAGGFLGGILAQKLRMMQAMMVGAILACVTNLLFVLLTYHPGSLPHMYVAVIFDNLAAGLASAVFIAFLSALTSIRFSAVQYAIFSSLMTLLPKVMGGYSGAIVDNMGYPFFFIFTFAIGMPILILIYLVDKHIVIGDNDDIYGDNDKLTKANPNLTDTSEPPRASE
->MGYP003723858749 FL=0
-ARGESQRTGQRSREEIQQEAGQGLRCEDHSACAGTRQGQGSCAANLRQRQGPLQSVFRCHVVKEAA
->MGYP001454151373 FL=1
-VSEDDGVDKIDRVVSNGEANTVVITVVVSST
->MGYP003345151193 FL=0
-DLRVRCLVACCSWRGDECESAVWRVAVIATPFQSLGDHVVE
->MGYP004046731215 FL=0
-MSADPFXIXSGTLLLAAXSIGSQAFRLRLRFIMPKRTSKTSGRATRKTSPIPASPGPLFPSTPERRSSPKRSRSKSSPRSPPRREVRRRVTFADGTEGEGDASHSTSDESVVNNSD
->MGYP003232878591 FL=0
-MSTLFCVARAPHCSASVPHEARIAPPRLLEESIEGAHGALINIAGPSDLKLQEAAAATQLVGKAIHPEAQIIWGLSLDDAYGDEVRVTVIAAGFDANSKKAAQAEAQKQAEPAESTVPLSALSAAPRA
->MGYP002780757469 FL=1
-MRESSFIRQNFDKWKYIETRLELKKGENPDELASLYIQLTDDLSYAKTFYPKSKVTDYLNDLTGLAYANLYKNKREKSNRFITFWKSELPLLYFKYQKTLALAFFVLIISFVFGYLSAAFNEDFVRGILGDRYVNMTIENIESGDPMGVYGKSEPFEMFITITGNNIYVSFLTFIWGGVNFGFPVFIFLSGGSIFSLLYNGIVLGAFMRFFYDYSLTTTASSALWIHGVFELTAITIAAAAGIIMGNGILLPGTRTRIESFAIAAKDGLKILLGLIPFFIVAGFLEGFVTRHYKNELVAWFIIILSLVFVIWYFVIYPINVKKNYGSTE
->MGYP003421169975 FL=0
-ASNLALLVRSLYKHWSSIKSSIWFDLFSRLVNDIYDQKIGIKKAWEYIQNIKNAIPSKYPLDETSNNSDSNKAGYAKVLDDYNWSIRSNINIDNFGWTIEKIVNDMSYWTLPYQYIIPQLFKNDIYVSYKINKINNEYTNDFKIYDGKTKTFNIINIFNGTVVDWLDLAVKEIKDVWAKNQVPIVVGGTGMYIDNLING
->MGYP002515247338 FL=0
-LSRIVVELSPATPADRMPQMWDELRRKVQNVQNELPEGASAISVGDDFGDLYGIYYGLKGDDGIDNEELREWAQEIKRRVVTVDGVQKVVLYGEQQPVVNVYVSMARLSNFSIRPESIIAAMSGQNRVVDSGEKLAGEMQIRILESGTYRTLDDIANQLLTSSDGKQFRLGDVARIEREVIEPPTSIMRIDGDRAIGIGIATDPSRDVVRSGRAVAEQLRQLSSQMPLGMEIVTLYPEDEIAREANNQFIINLLESVAIVVAVIMLVMGLRQGVVIGSSLLLAIGGTMLIMLVVGEGLNRTSLAGFIIAMGMLVDNAIVVTDNAQRGVAQGVDLQTSFISGANRPMWGLLGATLIAMISFLPLYLAPSSVAESIKPLFVVISLSLLLSWVLSLTQVP
->MGYP000642399635 FL=0
-DAPLAEEIAEELGAELVPVEPSAGAQRVPVPLFYPVLFDRLSIRRRDK
->MGYP001211563207 FL=0
-MSSSSIVNKKIPVTVLTGFLGSGKTTLLNHI
->MGYP001099929414 FL=1
-PVDPNKSANKTVLLLIKGLLTINSTNRFFFRRKYIFQPTDLRLFFYMLIGTIIYIST
->MGYP003481454472 FL=0
-VVLNSQTKRAELTVEGADMVGFVFFAPSPRHLSLETARELGRQAKGRAAKVALSVDADDATLENIVETLQPDLLQLHGKETIARVRDIKAKFGLPVMKVIAVETSADLAVLPGYASVADRILFDARAPKGATRPGGLGAVFDWNALAKLELDLPYLVSGGLTADNLAEAVRVTRAGGIDVSSGVESAPGIKDPEMIRNFIRAARASE
->MGYP003404440343 FL=0
-PGLTAHEEEPTASIDRIVEPGRQLPQLALPPDKHITGTAGSDVILALVHGPIVPTCAPARIPR
->MGYP003306851604 FL=0
-IKIPANRGAGCCLGGNSYLTVTGCRNLLISGISTTVNGAVLISVPTNLGTGCCLSFNRYLVMACCRDLHIGSISTLGAVLIGIPADFGTACGLCLYNSQAMAGCGDCFIRGVITAGTSNILLPAIFGTGCCLTLMGLVIMTQLCLFDIGGVITVCTVLIGFPADFGTGGSLCLY
->MGYP001507408964 FL=0
-PELCIAGVKEGDSGLYWCEAAPEGGQGQKTSPPRELCGRGWGAEGWKQSLQSPPRKEATGLTALPTLTPKQ
->MGYP000892867995 FL=0
-GSAPRMRRLHELGFAVLGIDYRGFGRSEGSALPSEAMAYEDARAAWDWLKRDAEKTGAPEAGAVRRFVFGHSLGGAIAVDLAAQVEDDASGLIVEGSFTSLRELLATFKWGWLPVGPLLTQRFEAAARIAQVRAPVLVVHGSDDHLVPPTLGRALYERAPGRKRFLLVEGGSHHDSSARGLDEYRVAVRELFGVAAVE
->MGYP001570592810 FL=0
-KLEMITTENAPTIAPHINPNVTITDGNVLTIKQNAVPLPHTEGWSAASGAISPYLIDMCFDKNGNMYFVCRFSWASMGNLDGTQDGDMAGIHKMAPDGTITYKWWYYSDPSIEPTKGEAGIWSGTSWDNAFNLSTAIWCEGNDIYLGCGDHGTANCLKISISDTSDILSTKVLRLNRAAAAGSVDGPYSAPVKGVSVEGDSATTCPPIAKIRSFSNGDICMVIGARN
->MGYP000867335061 FL=0
-MDPVRRDVLAMGAAATAVAATSPAAFAQDGAAASFFEKDGVRIRYGIVRQLGSFNLLWAVFHEWIGIARDVWRAPWRAKLPYMFAPPGWSHDGSRDTSDSIRARWQERQEAVPAE
->MGYP000426411893 FL=1
-MQSSVFYFPHCRNETEVESKLIVDFLLPRLGYTPHTWHQEVAFGHIRLDFLVFAVNRAPLRLADNQPVSLVIEAKSPQHGLDRFEGKLREYLTKLRIGHGVLTNGKDFRVYGRDKDSVRLLFRCPGEAIEQSLPQIRELIGREALITLSSSEPVLLDPVQEVDDLPSLRVVPIPASTEGIPETQGLSNVSSLEYSVIREDSSMIIIAIYHNKGGVGKTTTTVNLSATLSKMGYRVLLVDLDSQANSTFAVGLMKFPDEIDDDIKKSYVYHVILEKNQFSIPEVARKSSFCNPEFDVIPSHIDLMTHEFELKEGGSGITKYRLLKKLEEVQNSYDVVLIDTPPSLNLFAEIALITADYLLIPSDLKPFANEGLNNVRRFIDDINEDREDRGKTTLEVLGILPSKIATHARFVEHTLPKMEKTVEERYGYKLLNSRIYERRDASAAIEKTIVVGDLDIPDPQSVLDFKPDSASALEFKRLAEEIISLTGL
->MGYP000549342313 FL=1
-MLKNIIWRDIEVVITLSLIHIS
->MGYP001554259151 FL=0
-PFWSKVRQVSIDSDQESQRELFLFEDMSSQNEMFEKVQRLSQAVEQSSNSVVITDIDGIIEYVNRTFIKTTGYSSNEVIGRNLSFLSPDQAASSVYEEMWTAVRAGKEWAGELINKKKNSELYEENVVVSPIRNEQNEITHIITTKENITDLKKARQQADSANKAKSQFLANMSHEIRTPMNAII
->MGYP001144722731 FL=1
-MCYWNCPLASRLFRKSKASWRVAPAWSRWQLQLPWPIFIASQPTRAVPWLVV
->MGYP001076062122 FL=0
-MSKRLILFVAVAVMLLSSAGIVTFLSAQEGEIPAGAPQDSPGNAPAGGEPLETQYAPDRIYRTGSPDVWRVSTGDGILLSRDSGRTWENRGTGLPARAVWPFDKPRPPIVTGLSVDPAHTDRVGLTTLDPLYLSEDAGGTWEKVELKDPLKANDQLTCIALSPLQPASLLIGTSFHGFFETR
->MGYP001119048589 FL=1
-MKQNIITKKDFDINKDRDVKNFLLNFGPQHPAAHGVLRLVLELNGEVVLKADPHIGLLHRGTEKLLEYKTYSQGLPYVDRLDYVSMMAQEHAFAYVVESFFNKKVPKRASYIRVIFLEITRILNHLLALTTHALDVGAMTPFLWAFEEREKLMEFYERVSGARMHANYIRPGGVAQDIPVGLLDDIFKFIKQFGSRIDELEELLTGNRIWKQRLVDVGIVSAEEALAWGFTGVMLRGSGIPWDLRKKESYEIYDELSFEIPIGSKGDCYDRYLIRIEEMRQSLKILEQCLDKIPETGNYKIFDFKLVSPPRALIKFDMHALIHHFKFFSEGYSLPKGESYVGVEAPKGEFGLFLVSVGSNKPYRFRIRAPGFFHLQSLNQMSYKHMIADVVTIVGTQDIVFGEIDR
->MGYP000170037481 FL=1
-SGPLFVFHGIEKTFAEDEVLRKVDLSLYPTKCILLTGKNGSGKTTLLKIVAGLEKPEKAEIEISGKLHCWKKVMPIIRKEIIYLHQQAFLFSGTVESNVAYGLRFTSLTREKRRESLKKALEWSGLTDMAKQEANTLSGGVQQRVAFTRAQIMKPKVLLLDEPMANMDHESREQTYQLLVRMKLAGMSLVITSHFMQYFEGIVDQHFQLKNGALELKSKS
->MGYP001203790631 FL=0
-MIKNFKQLILFHRLKPFMNFEESIAEVHAISMSIKWCRPGALLGLFASPIRSYLLAAKPYIE
->MGYP001549860555 FL=0
-LSLEGKSGPAAQSARAFARNFAKRSDIPIALVDERFSTAAVTRTLLEADSSRKRRAEVVDKMAAAYILQGALDLVRGLKLELANLKEADIVACPPFTALSEVSKATLDSNIRLGAQNMSEHNVGAYTGEIAAVMLKEFSVRYVILGHSERRQYQKESNELIAKKAPEVHVDALRPIVCVGESMAEREQ
->MGYP002065815634 FL=0
-VAYRQPLYLLRTAVEWDVVQDRVMAYSLPMVEATMHMPFRVAEYTDFYASRHHATNVGTMFRGPENALPPNWLHIPIGYNGRASSVVVSGTDIRRPWGQLKGAEYDAPIFAPSRHRRTVQNASIPSRSSRSSVLRVPLSRNHAVR
->MGYP001354736308 FL=0
-QKKKKMGIRNVSPIYTPAAARTKPPHRLAPLNDSSSSTGAFNGLKPLGKISIDSPWDAFGKPKSITAVEKKK
->MGYP003506483410 FL=0
-XSPLLPKXATSNGHNHDNKQWFYQFATELDGSVGTKVRAEHQAKSHGNAQLVVNVT
->MGYP001354348586 FL=0
-DTGTGIHAAAGAAAGWGGEARINWALLQLQNNLWRYAFGNVLAARVRAMAMNWVQFQEGLSMAEFMARYGSEAKCRRALCRARWPKGFRCPACGDRRHSTFQRGGQTYYQCRACGHQTTLLSGTLLQATKLPLTTWFLAMHLLTSTKTNMAALELKRHLGVCYRTAWRLKHKIMQAMATREETRRLDGFVQIDGAYLGGERNGGKAGRGSEDKQAFVVAVETDETLEHPRYAVIEPVSTFSNATITAWAQRRLA
->MGYP003378432903 FL=0
-MGSRKKKNGKFLSENNNNCDYEGFTKVLSKRRIIVTIYFYLEVQ
->MGYP001118074481 FL=1
-VNCPLCSPSRASLLTGQYAVTHGYTVNAAVNAVPDERLPIYQHTLRGAGYRTGHVGKWHKDSYVEPRPGFDYWVTYHGQGVHTDPQLRVKQYDAPVRTVNETGFTTNVLTEYALDFLDDYGTGGDRTEPFALTLSFKAVHGPHGDQYTQSGGAYAGQTIDRPPNAR
->MGYP001597331187 FL=0
-MWLSLAGLVETLRGGCGACSLGCGILLLPYGPHILRQCLELLNFISIHVSDVVRLWARELALSSLRHPMQMEVGEIGIERGGFCSQ
->MGYP001567613541 FL=1
-MDNNNKWYISSTGSGLSLTIKGVLVGIVPLIAGLARTYGYDLTEGELFNFIEAGFQAVSLSMVVFGLARKLFFKFKPL
->MGYP000114959871 FL=0
-MRPVLASARALSQNPHESSFPSTNGNCGFVGQYFDRKDLTDLRLSRLDSRIAFDWGNGSPDRRIEPDTFSVRWTGRIVPRYTEVYTLSTVSDDGVRLWVDGALVIDNWTDHAQTENSASVELAAGRHPIRLDFYEKTGGASIRLEWEGPGIGRQIVPRTVLAPSNADEKAEGLLGTYYQGGPGESIFAWTDENDDGRVQPPEVRTGTITFEGAPWRQVAATWQTRMNDRFEIAFSDGEYGRAGIAFFNVRGFNRRGYPLYELPKSFVPIPGLAHASDAVMRDRAGNAISLDEYVVSVSPDGRILWRYKNRWPGLHAGHYTTAAGDEPGVLIATTRFLGSAVVNETLGEVIAILSNLGATYLFTADGLYIDRVFQDCRQGLSWSFNAPPSDELLKRVSLGDEHFGGTFQKVKTADGSFRCRYVVSPGSPHNSVVELHGLENVIRLEGGSFEVTAEHLSRAEHLRQRRTLAATEPRRLIVR
->MGYP002866891791 FL=0
-TSIDTMITRHHQKGDAASVAVYTACESYRYLLTRTWDASGPRALFVMLNPSTATEVQNDPTVERCERRSRALGFGAFRVTNIFAFRATDPKVMRAQTDPTGPANDDTIVGSAIDWIRGGDDRVICAWGTHGAHLDRGPAVEALLRQTDRPLWHLGLSKAGHPKHPLYIAYDQQPQLWRTT
->MGYP000706738672 FL=0
-MSSKFYTKATTLALLTGGGTSAAALAWFPLRQNSKDTDDNVDSPFSDEGLEAGMLLLEHAQDVPGLLPIAFLVSAIVKSSEHSGHSDATRFARLIETLEILLLQASSLPLPFLAQLTTVLEQAEV
->MGYP000526671817 FL=0
-MTKQKSIMTNGIIMKFKNNNTMRNIFYSLIFIFVIWVLMQPRPTNDIVTYHNDYRIDSNYLTPIEPLTESVNTMSVIPKQKENAVDLYIKRYSKTAIEEMRLYGIPASIT
->MGYP001798615877 FL=0
-MNQDRTVSFKNGHSGYTNCDFTILDIYDCDFTILDMYDCDFTFLDMYDCDFTI
->MGYP003125760673 FL=0
-MKQRKLKVRKGHWAYTLKSQPYSGNRITPFLLLKGTWLEQAGFNIDTPVSVSVEDGRLSIIRDHTRXEPRPGHRPGHSVLXQIRGMX
->MGYP001490802382 FL=0
-MPLHLNVQQSNSSAAVKKLWFVPEVLMFIMQIVYISDTFSLLISNFYYFWAVLCT
->MGYP003141655914 FL=0
-VDGVKNEGLLQPDNVTEPKKINIPRSVAGTHTDGNIHTYLINSALDIGPPDGLGFPVFYNNQIPIREEHITVIKKGPKNILNLDLDTGRDSDISTYINQQKTIKVAIRSDLNGNQDFNLLGWESYKGKTVVLKEFENDTAPSIPIADYRIKGIITDWHNFQNPELISDTGLQDISYPDGDSTGIIEIEILPTAVQGLPPLAPSGETLNYAIDLFDEEEKLFEFKFPRFSYRYKYEDGE
->MGYP000069741418 FL=0
-REAPPAEAPPAPETPAPRREKAATAREVAVQTAAVAAEIEEKMATGEDAYRFPPVTLLHENREENHVEAGAELRNNSRRLAETLTSFGVDASPGDVVHGPAVTRYEFVLDQGVKLSKITNLADDIALALGATGVRIAPIPDKISVVGIEVPNKQVTPVLIRDVIESRDFTEHKSHVAFALGRDIGGRNVIGNIEKLPHVLIAGTTGSGKSVCTNSLIISLLYKSTPDEVRFIMVDPKMVELAPYNGIPHLLIPVVTDPKKAAGALQWAVFEMMKRYKTFSEHGVKKLEEFNRLARATEGMETLPAVVVVIDELADLMLVAAKEVEESICRVAQMGRAAGVHLVIATQRPSADVITGLMKANIPSRIAFAVASSLESRIILDTTGAEKLVGKGDMLYAPLGAGKPTRVQGCFISPEEIEDVVACVKQSGEAQYSDEVIAKIEESIQEKEKGGKGASAASADPGEDEGDELLPAAVDVVLETGQASVSMLQRRLKLGYSRAARLVDQMEERGIVGPFEGSKPRQLLITRAQWQEQQMGGAPDAGEPPFPVEGDEGL
->MGYP000844791533 FL=0
-PRRTFIDFSENDKVASRRDSPLDRALSESESEVTTIRARSIIAAPKGDSAEPMSNFSREAPRKVVTKPAPSPAATPAPPVLVATPAAPYEAVRPVRPFEDFKEFSSPPLVVPKTVVRPIPVETVVVPEPTPAPAPEIATSVANIETTTVKSEPREGFIKSIAPATLTFVRTGYYSAKYRKFDDRMKNEASMLGLGAARGIETSWGSFEARAAVDIYHAMDQSMTIDNIRMMSVRTEVAYWLSHSRVKPGLSLGLGWADYSIRSYRSISGANEDIVTLRTHAKGKAFSIIPATSLRIEVADSDTSQLVVDVQTEFVALLGGESPDAAQGLG
->MGYP000545153660 FL=1
-MSADPHVVYVTVPEMLDAARIAREVVSARLAACANIMPNIQSVYHWDGEVCLSDEVVIVFKTTGDRVVELTHMVVDEHPDEVPCVTSWPITDGNPEYLKWVRDEATGQPQG
->MGYP000168519987 FL=0
-MASITIPYAVADFIEMRERGFYYVDKTQYIAKLEDYKAPVFLRPRRFGKSLLVSTLACYYDRTKAHRFEELFGDTWIGNHPTKEHNRYMIIRYDFSAMVMSDHIQGLAQNFNDLNCGPVEVMVAHNRDLFGDFEFSNRGDASKMLEEVLTYARSHELPKVYILIDEYDNFTNTILSTYGTEFYRKATHGEGFIRGFFNVIKSATTGTGAALERLFITGVSPVTMDDVTSGFNIGTNITNDSWFNDLVGFSEKELREMLTYYKEQGVLQESIDEIVAMMKPNYDNYCFSRSRLVDCMFNSDMVLYFMKSFVLHGEKPEEIVDPNIRTDFNKLAYLIKLDHGLGENFSVIKEIAEQGEITTDIVTHFSALE
->MGYP000057883855 FL=0
-KNLLKPGDHGTTYGGNPFCSVLQLIRCFEMIGARPHHRPCERNHTISWKKNYDELVASYDFLTARRGLWTDAGLWYPKSRSDRSLQMALEEGLIVITAGSERTPFCTTAHHRETTCG
->MGYP003384944733 FL=0
-MPVYRYYVPHAIVFLTQTVANRAPIFREPRWVDLLRATLHRVQERHPFRMRGYVFSPDHFHLLIQPTPPETHSSVMHSLKRAFTLAYKQATGIPGSLQFWQRSFYDHLIRDERDFEQHLHYIHFNPVKHGLVARPEDWPDSSLAAWKARGAYPEMWRWSLEERAAA
->MGYP002790362313 FL=0
-GKWQSVWRLDLNTEGLLLFTNSGELANQLMHPRFGVEREYAVRVLGTLEPDARKKLLEGVKIDGQPASFKSIEDGG
->MGYP001259587854 FL=1
-MLTNRIAKLLSVLLLLTLASACGGGGGGGNDDSSSPPETINLGQFYDGDLSSKNSETWSFSAAANTFISVELYGARLDQTSWNTPLNAPIVKLLNSNGSTILAHNITDSAGDLTSYWYFGYRDTEIPLYYLTDAGDYSIEVSKKTTNSGAPYKIRVNNENKSILAQFGSAQEETEPRGLGTNNILASAETILRDGPGTDEIIFGLFEDDDPDTYAIDIAADTTTPAVISCFEIISQRLGILTPQTGQSYPDLELTLYDTTDTKVNFVDDFYFTDPKVCRKITNTDTANDTYKIQVTETTGASNPTTDAYYFLKYTEEKILN
->MGYP000577366278 FL=0
-MPWEIGDIVRQVKKQVKIPLGIHAHNDSGCAV
->MGYP002519074643 FL=1
-MQTAVFTRETSVAMPSDMFAARNSGILSAAAVIAAETGVPVFELDMIMHGSSYFDSMYRNIDTLKGALG
->MGYP002064227981 FL=0
-LLRRAAISRPEIGDADRRAGCRLRQRRHRIHQHVRCLVDDVLGAQLDAVGKSHLADGHDPPIADRHVANQRFRARTVVDRAALKQQILKAVPSIPDLVRPAWASASTFRGSDKRGGANGARIRLEPQASWDVNVRSGVGEVVAKLDAADLVARRRMRPVRRLRRWSPTSITGDDAGLMALPVAAAAVSSDCSPLPPAIAPDRRSVTIGRAPWIAGVSGLASQATTRPAAHTANSATSSGSRCRSGSMSTSAAKELADLGYTNVVELDGGMRAWSA
->MGYP000874961551 FL=1
-MISKISNDFPVFDFKKDARYLGFFDFSCPEGPIFSWSGCSIQTNFNGTGIYAKIIDKNMTGNSWISVIIDYKESDPINIKPDKDMYVIAKGLKNEAHNLEIHKRTEALLGQLQFCGFELSSGGRFLTPPSEKARKIEIIGDSITCGAGNEGVYSGDDAEFLGKEENNYMSYGPIAARILDADIAMVSISGSGCYQNYGGAKENTIGDLYLKTNLSTSYDEWNLKKWTPDVVVVNLGTNDFSAEIDTDKFKEKYKRLIKHIRNKYSKAAIFCSIGPMNLQPGKYIDSVVNELKIEGDSSIFYCEFDPIDLKDEGLGWGTHPTIKTHEKMAKKLANEIKLRLCW
->MGYP000873909662 FL=0
-IYYLETGANQRGSTVVYDRAASSVALAAAEEYDFRSALGGVARVHVTGITPAISENGFLATRALLRLASQQGAKVSCDLNFRKKLWRWRKGVPPGELARQCMTELLPMVDLVIGNEADAEDVLGIKAEGTEVERGRVSAEAYVEVARGIAERFPNVSRVAITLRESVSASHNNWGAMLFDARSASAHFAPLDGQGRYRPYEIRNIVDRVGAGDSFAAGLLYALDSEKYAAPADAVRLINKGALVIDVRDPAAFATGHIVNAKNVPLAEIESGTEVAKKKNKVLVTVCDRG
->MGYP001229117954 FL=0
-NREAKLPPRQELFECNLAVAADIELGHDQVLLLRLQLVPHVPAQQLQLVGVERDHVHAVGAVRLVGVALAEGADVDPPQAPRPLDRARAFPGREFGPPLEDLEAAWVVAVADFLRPARDSLGIGEALNGRDRERDRRQRAPAALRKEVVTPSADLLDSEVLVAWSAELPDLTLLRA
->MGYP003486854474 FL=0
-ALGLSGERAGRIDANLAEHRLRDRTLAEEAVQDAFLRVVRHRQRFDPARRFAPWFYTMLFNLCADHWRKAARYAARLKAFVPEIDTVQFAHNFRCHGTHPWLAHKMAETDRISAVX
->MGYP000004611563 FL=0
-SDSPASASQVAGTTVAHHHAWLSFVFLVEMRFHHVGQAGLELLTSCDPPTSTSHSAGITGVSHCA
->MGYP000261681696 FL=1
-MDFEQFYQDKYPAGVPRNVDLDKYTSMVDVFDQAVKKFAERPAFSAVGATLTYKDLDTQSRNFAAWIQNRTDLKPGDRIAVQMPNVSQYPVIVFGAMRAGLIVVNTNPLYTTREMEHQFNDSGAKAIVVLANMANNVEKVLPHTGIEHVIVTEIADMHSPLKRTVMNAAVKHLKKMVPAYNLPQAHKLPAVLSAGSKEKFSPVECKKDDIAVLQYTGGTTGTETECTRFRPYDRGYHFNALLLIDNIFHSAKDFLHLLG
->MGYP000082023964 FL=0
-PFVPRRMPDGSGYELMMLEPELAPPLEDAETTARWIERCLAGSEPVPASLKIQMACCLVATGESASLAEGLARVEQSF
->MGYP000378578682 FL=0
-MEKMRFSISSSPHIRQSQTVQSIMRDVVIALIPTAIYGVIQFGYQAALVMLSGVAGAVLTEFVGNKLTGRPVTVTDFSAIITGLLLAMCCPAYVPLWVPFIGSVFAIAIGKLPFGGLGQNFLNPALVGRAFLLASWPALMTHWAPADAVSAATPLAAYKATGAMASYGDLFFGNIPGCIGEVSKLCILIGAAYLLLRHVITLATPIGYLGGLALMIFAFGGQDGLFTGDALFAILSGGAMFGAFFMCTDYVTSPVTQKGQFIMGLGAGILTALIRTFGGYAEGVTYAILFMNVVTPLIDRFVHPKLYGEADRKSVV
->MGYP002628574471 FL=1
-MKINFHHPAPEKTPRIWRSLRELENDPEFEKHLHTEFPRGADVYQDSGLSKRDFIKLMGASIALAGVGLTGCRRPESYLVPFTKGVEFTIPGKFLYYATSMPARFGAIPLVATTSDGRPTKLEGNPLHPFSNGGTDTFAQAETLNLYDPHRSKQITENGKPSSREAFDAYVASVAQSDGSNLAILTEPSSSPTRARLRAALQTKFPKLVWAEYDPLAPTAANAANEASFGSSVRLVPQFSRADVILAIDSDFLNPIETGIGYAQGFSARRNPEQKGASMNRLYAVENHYTVTGGMADHRLRCKISETGEFARQLGLALAAATNNAALAEVANAFPASQTSIDPAWIKECAADLAKNAGSSIVLAGPMTPAPVQVLVNAINNALGNIGSTLLPVKADLVPAASIEDLAAAIDKGNVKTLFLMGVNPVYNAPANLGFKELLSKVPDTVHLGFFEDETGTASRWHVPAAHFLESWGDCRTFDGTYTSVQPMILPLWNGVSEIEVLNILSGATAPEGPSLVRETFNAIAPQATAESWNAFLRDGFLPESAFQQIQPTFNAATASGLAKKGAPAKADALELVFLQSSSVDDGRYANNSWLLETPDFVTKVTWDNVLMVSPATAVRLGIKTNNFGLLGDVAEKMGNDVNYDLIGDIVELSDGKSTIEAAAIVAPGHADDSLSIALGYGRKGVSALMDGVGFDAYPLRSSNSMRFLDGVTIKVTDRNYPIAQTQEHRSMEGRDLVREGSLERYAKDNAFAQTMGMDSHIPPNISLYTHPELNAKDQWGMTVDLNTCTGCNACVVACQAENNVPVVGKDQVRKNRDMAWIRLDRYFAGDSSDPEMLSHAIMCQHCENAPCETVCPVNATVHSEDGLNLMAYNRCIGTRYCANNCPWKVRRFNYFDYNQRPIDELYWGPLAKKGMADSLKMSKNPNVTVRMRGVMEKCTFCIQRIEEAKISRLVEAGPTPASDTPIAPFKVACQQACPNDSIVFGNIADPKSQVSRMRKDPRGYVMFKYLNVSPRVTYLARIRNPNPKMPGADLVGMANGSGHHGDAHGEHADQGHVDSHSDHHTEPAAH
->MGYP000967004213 FL=0
-SSEGALPGNGRFFAVTRPALVDALDAQGGEHPT
->MGYP003580660516 FL=0
-MPIINRNIESPINILIIFLFITVSFYSNHKKSRHSGGNDGLRSNSIDSEFXDQSPSSIPGSFTALX
->MGYP003382547724 FL=0
-MRWVRFRENEDRVIRKSMLCEAVIRRKKRRMMPPFSTIFDQNAVTGITSRPRQRSGMVNLPCGRKSVTIAILLLVSWLNSLAGDAFADDVQSRRQGSFAAGGTDGKILQQHEASFQASDDGQENGSWQKAEFKAETKVTSLPQQPASFRSLLSGTPDFLNYDAP
->MGYP000595587323 FL=0
-NVTATDPATGAVVSSATQVVDAERVLGNVAVVSHPGTKGPRLEPALYAFDDWTITGEGVAHHPGQTFGPIACAQHTLSRGVLKMTAQFLPMDDNAPSGVDLQVNQGGQWVTVDTAELDTLSWTAGFRVPDWDDTVDQDCSGADLTDVDGDQYDAEAAGGGDCDDDDPEVHPGAIDIEGDGVDSDCDGVDGRGGGDDTGGGDDTGGGDD
->MGYP000311212580 FL=1
-MLTGVDQAKAVRALLPELPAENFIIEPLRRDTAAAMALAAGSIARRNPHATAVVLPADHHIPSTIDFQKTLHCAVQAAETSGSIVTVAIKPDWPCPGFGYLELGDPVERESGAVYPVVRFHEKPSAETASEYLAQGNFRWNAGMFVWSVPVLCEALQKTAPALFDFYTGLKQASDAVEFLNANFESVPKVSFDYAVMEKLSGVLAVEAGFAWDDLGGWAAAGKYFPSDQHGNSGNTAIQSIDARNNIVFSKEPNQHVALLGVENLIVVNTGDALLVCPRGQAERLKELVAGLPSDLQ
->MGYP000202157561 FL=0
-AQVRTLGCVGDCVAQASELIDQSALQRLIAAPYASLTDLIDLFRGLVAIGGDLGDEILVAGVDHRLQDFTDARIEELHAKHIFCVLNRRRQALAYLGGELGHQALAVGLGALPGSLRGQLGGQQRRADENADEAEGDDAAEDAEHDQQQRQAAAAADQVGLDEVVDAADHQQAPGGHEDGPAHRTLGQQPQRGPTPHQRRPHRHHGQQEGGRGQGWRAGYAGHQEADQGHQGLGQRRAEDAVHHAGDGAGDGGQQLVGQAAGQLVQDGARGQDQLVTVAVEEEGDEGRESELQQAAAQGLAA
->MGYP000361399541 FL=0
-MGAPPALCGRAADRPALRPSTFGLPLRRVPGLAPAAQRSPSRLSPALHTQRAARCLRVAVPVTGLAAARRRSAALHAPVHDPDAVRDAQRLLGEVHAQKLRELSVERADLLRCQHGADALAGPDAPAPAAVRVRHRVIVREGLDVADAAFRQIADEGGVEARGHGEADVRLELRRVVALDQRLGPLDDVAAERDPVEGRDHDVPTGAQLRADLTQRRRPIEPVPALTRADHVEALGAKRDLLGAPEHIIDPQPRLRIEAARRREQRLRDVQADDPAAVAGEAARHDPGPGPQVQDRLAAGADSLVGEAAEQGVWEPDPVLPVVLCGAIKVDLHVCLPVQCPALFNALPCSAPCLRGTAYQRGAVSVRGQRLLQGDVRLDAAQRLRLARHAARQLRRHAREDAAAAQKLDGADDAQELGHRGLVQHLGAGEVEDDPQRPQLDDLLEQPRRHVAGALGVEPTDDREGERALPDLDHRRRQEQQLLLFRGQRLQLPIEPLFIRDAVVGRAGHAGGVAEHHDVGRAEGVRLRAGEPVGADAADIAQDRDEEARADAQAAAGAALRAPFGVGLDVRDVQELRVAHHPAGVS
->MGYP003362107572 FL=0
-MSLFSKKTTQQPIPEEQRVEQAYLAGMTTLRDLIAPSSLEIFSNYFRLGTKFGRTLYVYGYPRQVHTGWLSPLINIDEILDISMFIYPVDTQIVLNNLRKKVTQLEATMNINTEKGRVRDPGLETALQDAEELRDQLQIGAEKFFRYGLYITIYADSMDELNFVQHKIETIFGQQLVFSKVASSQQEQGLNSTIPQLTDELQIRRNMNTGAISTSFPFTSADLTDGKGVLYGINMHNNGLVIFDRFSLENANMVVFAKSGAGKSFTVKLEALRSMMTGSDIVIIDPENEYQKLCEAVGGSYIRLSLNSDTRINPFDLPRVIDTEEADDALRANLVTLHGLLR
->MGYP001412591253 FL=1
-MTRISLPFAPQVRSGIPKSPCHSNVVYECVCEKKITVSLICAGGKEGFASPAAEPQSPVPLSHTPRPVASTLTCFPPLPLGPAHGRKDRL
->MGYP001520358773 FL=0
-IFANEYPNEFIGEAGTINGPNNIRKRKNKVPGALYIAITSLYLK
->MGYP002525796693 FL=0
-MNKKLITLLVALLSGSAAFPQVHKMERKDSSAVDRTYNLNPVVVTGSGHHQRLKSTATPVHVLSNQEISEQGISTFDGALTRMMPQISMSPNSMGTFLRLNGLGNKYILILINGQKLSGDISNNVDLNRINMSRVKRIEVLDGAASSLYGSDAIAGVINIITDQPTQNLISVTSDTRVSGHGQLTENVTLDIYKNGFGSYTSFSHDRADSYRHNDLEYVKGSDTETQQTIAPFFTGYRSNVIGQKFTYAPIEQLALNAGLDYSYKITDRPETRQDITGGTDYEMRYKGFRWNVGGIYKFTAKNSLQANFTVDRFRYGKQYDVKTKDYAVGDYVQSKKQMMMDGELKAILGLTKNSTTIFGADWRKDYLTATSGNIEENVYSLAAYAQHEHKLFKDFTATLGLRLTHHE
->MGYP001301746093 FL=0
-MTQEVQITRDQVLEQLREVYDPEIPVNVVDLGLIYDVQVSGKNEGFVQMTLTAAGCGMGPYIAQQAEWSISELEGVEE
->MGYP004005692463 FL=0
-GVAAHGPSRVVRDPEQASGVERALVVRLGGVHDILVAELFEHRLAAQYHQDLTLARRRPEHRFAVLFLDLDHFKVVNDSLGHHVGDRLLVEVARRLRTCVRPGDTIARLGGDEFIILLTDLAESADVDRVTARVQEVFEAPFNVASHEVQTSASVGVAAGELSYTRAEELLRDADTAMYRAKALGRSRTEQFEASMRVKALARLGTEIGIRQGLDDDQFVVHYQPIVSLGTRKILSFEALVRWEHPEAGLVGPDQFIQVAEETG
->MGYP001224191517 FL=0
-LNYVGHLRGYHDITESTNIDLGASYSYGHNPAGVINDIDIGRFTTKLFGVDATLRWRPLTRAIYHQFVGRSAVIWSHRQQFGGPQDRLGYYVPGDYQFARRWFAGGRFDHSDRVDDSAIVETGGSAVLTYWPSEFSQVRGQYRRTSYAEGVVANEFLFQFLFSIGAHGAHTF
->MGYP001086061371 FL=0
-AAYGAVFTIRALQQNTEDEPQPGHAFSFVTALKFALVLAAILLASAALREWFGETGVILAAAVAGFVDAHSAAISIAALVASGKMDAADAVMPILAGFTTNTISKMVFAGTSGGYGFALRVIPGLILVAVAAWAGAGTTRIGR
->MGYP000610080798 FL=0
-MSIGGLTKDKLSNFDKLSQPRD
->MGYP001730562506 FL=0
-LNVLHHSSVKYFISFPSIQDFEIIILKSVKKSTIILTISGKNRFSFCAFHPDILIEK
->MGYP000961376923 FL=1
-MKHHVENQCDEPRVSVVILNWNGRKLLEQFLPLVLEHTLGDEFRVVVADNGSTDDSVEFLQTLFPEVPLILLDENHGFAEGYNRALEQVRSEYVVLLNSDVETTPNWLQPLVDFMDNHPEVAAVQPKLLSYHQRDHFEYAGAAGGFIDRYGYPFCRGRILEEVEEDRGQYDTVIPLFWATGACLMIRKSDFVENGGLDGRFFAHMEEIDLCWRLNARGRKVMCVPSSTVYHVGGASLDKENPKKMYLNFRNNLLMLYKNVPRTRYFTTFAVRYFMDLLAFVHLVMKGNFKNARAVVKAYVDYWKMRPSYKQVRRENLAKTLIEIPTQYPKSILMRFYTGKKTYQSLYSK
->MGYP003987264985 FL=1
-MEDIKKAIIKAKGEGNKHLVQRLQQELDALQEISNNLDWPRYEKVIRKLEDKPDMEDFPDGPKKNNS
->MGYP001575371671 FL=0
-EESALDTLPGLAALCNALSPKLVSGAVELGAEGTA
->MGYP002783228703 FL=1
-MSDEIGRLDIMVEAEANRANRALGGMEKRLNRIADSLEKVTALTAGINGFDKFDLKGLESFRKELDSVFKSSSKKSVKVDDSDLKYAKKSMDELQRQYKNAKLEVNISTIGEEELKKFINQTERRYRKLKQTLADTIELNGSDMVGGKAWYKANMQLMQYENALDDATEALGRMKSMRDRIPEITIDRGETYNNDTDIPEYPKIVEIGNCEQYDASEIEEYINNFAGARKEANTFEAQIKSLKSELSDLASQGFSQYDPEYDSVARELAEVTIAQKQYNKELRESARESLGISNSERSAEAMKKASKQAGVFKRTIDGIKSSAKNINALKRNFDNVSKSIRSAIKLSKSALHPIRSLKQVISGDGGNRKGMSWGRMIGSSVLFSFVFQGINAIQKAIKEGSDNLVKYSAEYNYSISSMLSSLLYLKNAFAAAFSPIVNVVSPYISQFIDMMASAANAVGQFMAALTGKGFAVQAKKAWKDYAAGLDTTKDSAGDAAKAIKDLQNYTLRIDELNVLQPNDNSSSGSGSGGSGSGGADISPSDMFETVEVSNSMSKLAEMFKEAIANSDFTEIGRMISNKLSDELESIDWQSIYKKADNFGKDLATFLNGLITPRLFYNLGKTIANSINTAFHSANAFAINFDWSNLGDSLASSVKGFFENWDAKLTGETFSNFVKGVLESITSFVNSLNSNDTFEDIGQKFVDLLCGVDWAGLTWDMGKFFKALSDAMTDFPKDFSKGVAESILEHMFDSEFSDGMKQKFNDSIQPLNDIWDYLFSSLNPAINAFKIMDFVRETVSSKGQNILDFLSDCWESIKIIFSPVVKWFKDTFSGAYEAIKSPFEFIASWFGEKWTAIKGVFDKDKVRNFFKSAFKAALDAVKNIWDGIGDYFKKIANHIISPIGKAVNGIIKGINWVLDKVGSKKPPLDLWEIPKFARGAAGLPEDTIGIVNDQKGSVYKELIVPPDGKPFIPEGRNVMLPLQKGTKIMPADETKALMSAFPHFAGGIGDFFGNAWAKFKDFTGNVLDYITHPNKIVQIALDKFVDISNMAEPISSIAKGTVDTVFDGIVDYIKGIFDSETTVKYNPTAGVEQWRSLATKALQMTGQFTESNLSRMLMQMQTESGGNPNAINNWDINAKNGTPSKGLMQVIDPTFRAYAYPGYNANIYDPLSNMLAAIRYTVSRYGSLAKGWKGHGYASGIGKINFADFLPQLAGGGAVKSGQMFIAREKGPELVANYGNKSFVMNNDQIVQSVSNGVEAAFERQNARTNALLQQIAECQKMLIHKDTSVNIDGKKADKQLSKARKNSGYSFSPA
->MGYP000278592768 FL=0
-RPPRSTLFPYTTLFRSRKVMAYNDQVMMCEITFEKGAKGNFHTHPHIQTTYIVKGSFAFTIDGETQVVNAGDSILMPSNSLHGCECLEAGVLCDVFTPMREDFIKK
->MGYP000014633898 FL=1
-MSDGKKILITGGAGYLGSVMTPLFLHAGHSVTVLDNFMWRQSSLAAVCHHPRFELINGDARTESTMKPLVNEADIAIPLAALVGAPLCDKDPIAATSTNLDAVRMMLDMLSKDQWVLLPNTNSGYGVGEGCCVGKLGVPSREPAPSVGTCGGRGRRARKMKPVPTSRATMKLMKAIW
->MGYP001266816030 FL=0
-MEHYGKKLKFRPLNYVFILL
->MGYP000960759586 FL=1
-MRVDPVTQTTMARMMDHAVLNPAMTENDIRRAAAMCRARGVGNLCVRPTDAALAASLLKGSATTVAVVVGFPHGASRSEVKALEARLAIGDGASELDMVMNIGKFLSGDYEYVKRDIEAVVAVAKPQGVLVKVIQESCLLTLDQVAKACELTIAAGADFVKTSTGFNGDGATVEQVEVMLKTCAGRTKVKPSGGIRDWERAAMFVRMGVDRLGVSSTDKILDGAPTEDGC
->MGYP001420375246 FL=0
-PEQLAGVLSIVARQSAAAKGQPYDEEADTAIRAAVEQQIEAESLPVFLSGRLYDDGVIDPRDTRTVLGLCLSAVHSAPVEGVHGGFGVFRM
->MGYP003296810821 FL=0
-CQGYFTEERGDCYGGNFNIVKVIIESPIAPTSCEGLFQGLTACKVIEGIEKLDTSRATSMEDMFASCFKLYNPDVSGFDTSNVTDMSGMFTSCHAITKLDLSNFDTSKVTDMSKMFVACHGLATELNLSSFIFCYF
->MGYP002731676114 FL=0
-NTKALRQKILDLAIHGKLVPQDPNDEPASVLLERIRAEIVEGVTTEATNALGEKVQMDFAANRTSLPMDLRAAEVQENAIQENQNPKKFVVHSGANENRKTLDSKKNL
->MGYP000800539561 FL=0
-MKNICIGLFEGETLPESLAAFKDVKLDLEFGKVTTIYTLHQLDCEKVVVVGLGDGKKNIKEAFSKVEADDYLAYVTENTAYAAGFGLVYAVSYTHLRAHETDS
->MGYP000365574991 FL=1
-MNEATYISELGEAIYPHLNKPDVKFNENGEYKVILKVSQGRATKMVAQFEKAMQDSISKAESELKGKTVKVAPSPYSEEGGFVNFKFKMKATGVNRKTKEPFSQRPALFDAKKNPLNPTSCNIWGGSKIKVAYQLRPYHTPLIGAGVTAILKAVQVIDLVEGKQMNLFSKEDGYENTTSPEEMNNVPETEVQTSTDF
->MGYP001556904936 FL=0
-SLTEILITVFLGFIGFVAFIGFVAFIGFDRLLGVFRPLLSATLQPSYHPCITLGL
->MGYP004044994415 FL=0
-FSGSGFLGENKKFKIIKPILRLKATKKKIIIDKYSFKKSASILYVYLYSTFFYTYRREIDAK
->MGYP000469735265 FL=1
-MFHVNLICKRCAKTVSYTHLRAHETG
->MGYP000883239672 FL=1
-NPEAIKKHKGIIANPNCATIIGLVAVNPLHKAAGIRRITGQAIADI
->MGYP003386468952 FL=0
-KLLSTNALDGIELPPKGEQIPKALYSVEEIEKF
->MGYP001795370918 FL=0
-MIGIVLYLELKLISEANKSSNIVFELLMSASQISIWAYMLQGTYPTATNIIHLSQLVMVDRGKGSQ
->MGYP000051665382 FL=0
-MTDPAALAREYYRTIDADEYDALADLLAPEFVHARPDRTLSGRDRFVAFTRDERPMTETTHVVETVYDVGPGDSGSVAVRGRLLDADGAELFAFVDVFTVRDCHLTRVETYVSAGTETG
->MGYP001510798038 FL=0
-MVKFKYSKAWWGKTSYKIIGLHEQLDQELLNFITTIQNQESSTVTALENSVDLLISSLNSCIAKVGLNQGTIANYESNSFYTDKDVYALANISELFYQQHEDNKDVYDAICEAEQNLKAVSYTHLRAHETV
->MGYP003638701188 FL=1
-MAKRLPEFLPHKYQEDVIQEMEDAGVLALLLDPGLGKTSIVLEYFRRQMDCMAATRMLVVAPLRTCWGVWPQEVQKWKGFKHLKVHVAHGKTGKDAALCNDADIVVINPEGLTWLEGEMKAKRIERFDVLAVDESTLFKSGSSLRTKTLFRIAHKHQGGIPNRFILTGTPAPNGVEDLFGQFAILDPDVLGKTLTAFRTNFRFSASKRPWGMVWAPSVHTAQLVQDAIRTHSVRLEATDHLDLPDLIQVQREVVLPKGVMDLYKELQAEMLVNLDGNTSVVAVNPAVLSAKCRQVANGAVYVDDNGEAGDSSARRIEYLHQAKVKELAQLFDELGQKPLLVAYEFRHDLKQIRNHMKASYKLDVPFIGGGSSGEETAQAIDDWNAGNLPMLLVNPASAAHGLNLQSGGSHLCWYAMTWNLEHYQQLNARLWRQGQREAVIVHHLLAKDTVDLVVWEAVQRKDATQRDLLLGLKRSKS
->MGYP001045944336 FL=0
-LVWRSYRPYAVGQSRRDATPPCPSSKNHDELLPSSTRNPKRDELLHPSSRNPMVCA
->MGYP003142759631 FL=1
-MKKARNIKNKKHNQIVNDYDKIKSRHLEKLANKILKDEERRDNLRSKDIKGDFLKNF
->MGYP001277206801 FL=0
-VAAGLAGGLLDEHIAYVTSDESFRTPFARGYVVVEQLPYREKALKAALRERGVGRLAIKKRGVDVIPDQLRKRLDLRGDAEATIVLTRARGHGIALLVQPF
->MGYP000667709688 FL=0
-ACTDITGFGLIGHGLEMAVASQVGLVIQSGAVPVFPEALDYAKIGLVPGGAHSNRQFFSCKVEVHPGVPDLLLDIFYDPQTSGGLFISLPRDGAETLVQRLKDRGHVNTAIIGEVVPEPKGKIRIF
->MGYP001758919174 FL=0
-RDSVASRGLGDVYKRQEVVKDE
->MGYP003402598952 FL=1
-MRHGNKNNALGRKKAHRDALLSNLAISLIDHKRIETTLAKAKALRLYVEPLITKSKDDTTHSRRVIFSELQNKEATAALFRDVAPKVASRPGGYTRIIKLGNRLGDAAEMAMIELVDFNTTYTKEKSAGAAKKTRRTRRATAKPTTAKTDGGDEAKSE
->MGYP002859056165 FL=1
-MANKIMKFFHEEFGNVRGRYIGGECRFAGKDVAQALGYKDTKSALADHVFDDYKQVFNAKTIRQMASQSKGGETPPLETTSPRGMIYIKEPGLYQLIFSSKMPKAIKFQRWVFEEILPKMRREALREEARAEGKRVRRELTDVIKSFIEYLTARGELDRAEVAWYSAFSNLVNKMTATNDKRDNLLMLPLLRLSDCEDILTDAIEEGMAEGKGHHDIWLACQGKLDAWRQLTK
->MGYP003351460330 FL=0
-MAGQMDTMPGERAGRREQNKAENRAALLKAARSVFAEIGYNAAGVRDIVRRTDLASGTFYNYLDRKSTRLNSSHVSESRM
->MGYP001464310971 FL=0
-QALDVLLLRAGEDGAGGDGHFQERAGLVRVDVLEGLHGDLAGFGALGHDVHNLAAHQALGSHALAHVHDDPQGAFGGHGLGSLAADVLERVAEQRVAREDGHLLTIYLVVGGLASAEVVVVHGRKVVVDEGHGVNHLERARGGHGDIHSPAHEFAGGDAEAGADALA
->MGYP001323269287 FL=0
-VGDRGGGTSSPSPSAPPPMAISPRSTARGDPGEEPGTVSHRLTPGTAAPLISPRTDPAPRRGRGRSAAGAGGVGEPEEYGYPCGGAGGVGEPAKCMGIPLEGNAGAERMINPPAKVLARRRTGLCRTPPVGIYLNPVQKVHYYWLQIISCNG
->MGYP003154234093 FL=0
-DDPIEGSYEALEQISKKYTIIIFTTKAKSDRGLVNGKTGTELVWDWLKKHDMAQFVSKVTAEKPRAVAYIDDKAVRFENWKDALENVL
->MGYP001373085551 FL=1
-FCIHTTGSAFDDLRKLIESGGGYTPAWKGRIRGKETAIVPVTMYTYFIIGLAEKPLFMGQVELAKRLGMENDFILANLIKAQDQWIIDIKGNSSLYGSFINNSSRNEKDILIQWLEKT
->MGYP001489405527 FL=0
-VTASSAVPVVFDPVVVENYAACSAGLPSWLEAARSRQSMDANLRMVVADDAAYADKTGHRYAHFVDGGITDNLGLRALLETVEVIGGAQEYVAQLGMQPPRRIAVISVNAAADPRQGIDASRQQPTIGQTLDAVTNIQLQRYNTDTLQEMQQSLQRWSKALSTPQWQVQNYFIRLSFEGVPDLPLRRFL
->MGYP002718885158 FL=1
-MSLILPNSKGKSTLVNMIDTPGHVNFVDEVASVARLVDGVVVVVDVVEGVMHGTEAVIRHAMQEKLKIVLVVNKMDRLILELRLPPSEAFFKIKHTIEEVNSFIA
->MGYP003566853254 FL=1
-MKYIGVKRKKNRGNRYKFVVDIHVNGVRYFFGNYDDPKEAAKAYDLLVIRKGLDRPTNFFKKKLV
->MGYP001092313238 FL=0
-TYYKVMNNLASRTDEELVVLYSKGNNEAFDILLNRYKNRIYSYIYYIVKDRELTEDIFQETFVKVITTIKQGRYVETGKFPSWISRIAHNLIIDYYRQEKSENHLSNDEMNPDVFNRKELSEGTIEDSLVQTQIQADIRKLVAALPDNQKEVLIMRYYKNMSFKEIADATNVSINTALGRMRYAILNMRKMAEDHHIELSL
->MGYP001474034502 FL=0
-AKAALELVQAKDFKGLVALARKHADSIAEKALDASQSFEAQVLAQKERLQTLARAAEAPAIPPRAMIPTDAKEPADESIRLAGKFDELGAVVPRGVLRVVSAERVAIPSDHSGRLELADWIIDPQAGAGRLTARVLVNRLWHHSFGRGIVRTVDNFGRTGEAPSHPEL
->MGYP000079457881 FL=0
-MSSTSRDASAVVAGPALEAVAAELEAQGPLAVLSWAFETFGPGVAIATGFGVEGAALIDMAARVNPRPFVFFVDTGFHFEETLALRTRIERRYRIEIRAVEPDLTPDEQADAYGVRLWHYDPDFCCSLRKVEPLERFLAGRDAWVTAIRRDQTAARATARTVEWDA
->MGYP001330772963 FL=1
-MQVPEDIGVNEINIFLLLPSPIMLIGLTGRNASGKSTLVEWFSEKGMNSYSCSDSIRAWLREQDKEITRDTLIEGGRELRRQGGGGILAEMLIEILDGEDAVIDSIRTPAEVSVLRSRGDFFLIEVKASEEVRWSRLQERARPGDPTEKNIFLEQENKEIKAKDSAGQDLDATAKMSDFQIFNDGSVENLYTKLDDLWEKLHNSKN
->MGYP002627366002 FL=0
-MTNQVRPESMKRITTTELAQAFIDEQIIELKKQVGNGKVLLALSGGVDSSVAAVLLNKAIGKNLTCVFVDH
->MGYP003117035852 FL=1
-MSLLRNSVIVGGATFLVGSAFMEIGKADSKSDIGKWPYVATFLSGALGFYLLKQNVIPVPKALELNADYTDSDLSHFGKPLEDDEKFTTMQVRIGSPSGSTTSWTTAFNLQCVGDDDNLTYFTGLLEDSVRDRVRKWNGDELGDFIPMQIVIGSPSGSTTSWYRAFTVQPVDVDEENLYYLSGEIQDLLVDKAKWWNGHEVIYDAEIEYDGAKSYARSLDSKFDGANDEGYFPVDEDDFSEMVVDEIGEHTTLDAESFDADSLKGRWEEGTTRIVHGVSVTKSRYGEYEKPQYRASYNGYSCRIFYEGVAFYLPCWMYHGYGGVGRGGCFKNPMEAILDFKRRAEGGFQQISHRKDFDADTSLLQSFAAEVFMADRKIRRRTRWTWTRGNEKGFEIENDDLSELPYNIDYTAYTGRGYYRNSQPMYSIDEAYYISDLPEGYHLHLYKPSVRSGEWRAFSKSPTSEDWNEYRNYKKSNLTGDLLNWYNQDIAQPEEKTLSPIEKLMISKGMKSGTVQIERVVIPKTNYTPEKVQYFALGGPTNMSPTKFCEIEGGVIALENLRYEDEPNLFAFGQGLKFMTEKAGTLRSVNRFNKNPEAWVKSYPAWFQNAVKNKLTDIDVQFKFYQEHDGGIRINNIRVLKFLNGVDRLSWRPINESERKMMDTPYGEMPQFEIYELDMSDPAPITPRPSTMRKIYGKSFKQNLNGEWKFDKDMFMMAVVDKYKFENGGSERVHKSMVDEPLYSIDIIPYMTPMAELMARRYKKKE
->MGYP002788159078 FL=0
-TQTLIRDTARGFAERVLAPQATKLDREGGFPVESLAQAAELGLLGIAVPEELGGVEAGQQLAFLDLHAF
->MGYP001798696378 FL=0
-MLTGGEMAVSVITIQTKDIKAETKETHPNHYQKTNLXCHWSXKWRHAVKKTSCCMX
->MGYP001406754757 FL=0
-MRPLGSMCAIEYPAIPLPVFFLLEMMIPSSFDWSFTNRIILKFFWLRFGPIGARPPALVLRSLLAAPGDDVDRVGSPNVSSSPCP
->MGYP000997370353 FL=0
-FECGICKYLEHVDYRDLFLFRFGLVYRLWWFSQVESLVTDLHDVFGLDPGSLALAQSLRRAERLLSGTVLWAIGEGLQFASVVALIVSFGLGLSATIHFLNRLRLENTPDTTAEAAVEKATVLVGPALILTTVVLACGLVVTVFSDLPSLRLFGWLSAFSMVAALVADLFILRPTSMWLIGMAQKIRGRGADGKAI
->MGYP002214501719 FL=0
-IIIHVIFDKNSRANDVYKKQISSTTITTTATKKKKILVTTGIDSTSLFYNQGKGGNSGTSGYIAILAAIDAL
->MGYP000390568609 FL=0
-PISCFLPCVCFLCVFFFGGGVGGGSSILLAKKLISLKFAII
->MGYP000957035233 FL=0
-MSPLAAASPARPAIEPRGVVIAVRGSVVDARFPRHLPALRQQLHAGRDRSVVIEVSDHLAADTVRGIALTPTQGLARGDPVQDCGGSLTVPVGPELLGRMINVFGQTIDEGPALADGERRSIHQPPIPLAQRRVGLEMFETGIKVIDLLCPLERGGKAGLFGGAGVGKTVVITELIHNMVGRYQGVSLFCGIGERCREAEELYREMREAGVLLSTDGPFDNVLKIKPPLAFGKPEADMLLAALADAAPVEAELLRG
->MGYP003548451047 FL=0
-VARAMGGAVFLLMIAAGSAFDLVTQNAALSIGLGVTRETLFRVALGCGLAGLVLLTYAFVRSRLRNQSNDAQLAELEDEYADLLDRKNSSSEND
->MGYP001276729923 FL=0
-AFAALSLQSPPQRQTLESIPESMNECVHESMDDSVNE
->MGYP002536854477 FL=0
-MADKIRVLLSEDEVNKRISEVAAQISRDYQGKEIHLICILKGASFFTCELAKRITVPVEVEFMSVSSYGSGTESSGIVKIVQDLSTSIEGKNVIVVEDIIDTGRTLSYLLENLKTRSPKSVRLCTLLDKPERRVVDVKVDYVGFEIPDEFVV
->MGYP000601791154 FL=0
-MPALRHMSQTYALCANTSLHRRSWLVRSNTAGLLKRTAPERKKSNGAVPPKRSTSSKNTLLTRVLLGRFPMRPVPQSASSCGLASWTGQYFPSCSPRVCLGASCPRFSVTFIIEHFYLSMACQIDRVKNRRPFPARETRKTLLDRTSASVLWSS
->MGYP000636477196 FL=0
-MNTLNVKLSHSISQLYETLCQVGKSTFAELQRATNLKTRSPVWLYARSCTTTKYIRHVSAIPFITLLNNVLHRKFDLTKPDHRIKQANQRVRDKSCGRITAGTILPFPNRDARIVPSNKGTSGVSHWLPFHKAILAIDVSVKTPSRMIKISSASPF
->MGYP000562867999 FL=0
-NSFFYGWAFGFGYFFSNLYWISISLTFDSNFKFLIPFSLFLIPAFLALFYGFISFLFFKINLRSTLTSFFLLTLLFSIFEFLRGHILTGFPWNLIAFSFSNYPKFLSIISLIGTYGFNTICISLFLIPGLLYLRNSYINRFVCGIFFLILIFFNVYGNYYSNIFLNLKKIKLDYQIRAIASNFEIKKFYNNFSTEEIIKELIDISNPSTTTKKTLFLWPESIIPGVTKEQFQNQNVGSSINYFLLMLNIYALSV
->MGYP003365983449 FL=0
-MLVAVAPLARMLFIALLEPASIAWLTSTALGGQLGVLCWG
->MGYP001155155630 FL=0
-MLMVNHALSLVAECRAEARAVFMVFSFCFLELYVVCVRACASRGWLLSSPLGIGNE
->MGYP001568236931 FL=0
-MISSQAGQQSSPVEWVSAPELGESMFYMVQRTPDAELLLTPNEAFFPKLGLNAGGEGEFPLEKPELNQNKNFKWISGWDPGDAAEWGLWVEKPGSLKVSVAMDGAEGSYLLSLSGEEKKLSGKVVSFNVRKPGMHVLRITCRADADAEKLHALKLSGSAVENAGLLRKRWRPSAAHARFSSSANPKDVRLVIIEMDAKPGTLGFYAPITTPFGYYGPTWKADGLVNTGFNFSLWSYGRGKEEPPVERLSHLIAIGDPTAEFSGFGHEGTGVKIRGW
->MGYP001201323188 FL=1
-MYTTFTQITPAINLRRRRTLSAAGTVMVRLGQKVSADDVIAEAVIPTRHELVDVVRLLGLSKRKTADTLIQRKIGDTLAEQDIIAETGGLFSRVIRTPAPGKIISIRDGQVLIETETRKVQVLAIYSGVIDEIIANRGAVINTTGSIIQGAWGNGKIAVGPLLCKAETSSSNLTQADLEITARGSIIASASCSEEKLFDLAAQLPIAGLILGSMPAALIEKALAQPYAVMLIEGFGKSGMNSAAFKYLSMYNNHEITLNAGVDNETTEHQIEALISAAVEGEIGRGQSRVTSGQTVRIHTAPFLGQSGTIEKVLPGLTLLPNGLRVCAASVIMDNKDRKTIPVNNLDGIGFTQSNLG
->MGYP000016403168 FL=0
-LQTVEQIALMLPLCSDLKYRFHYIGNSFIALDCFCAFY
->MGYP001020068561 FL=0
-DFVKVCRHAGIAAEAGVQLFFQELAHIQIHIAARRRGLPPQDPAPRRAHQFAGSFMAEPHPTSAEEDLELLRASAVTAGIIAAGYFRRDLKSWTKEFGSPVSEADIVLDKFLHSALTTARPDYGWLSEESVDNADRLGRNRVFIVDPIDGTRGFIRGEDSWTVSLAVVENGIAVAGVVYAPARDQMYEAFAGGGARLNGASLQRQQEPGRRAPLIPAPGAVHQELQAAGLDYTRGPAYPSLAYRLVQVASGTLDAAVARRGAQDWDIAGAAVILAEAGIAFEDVCAGAM
->MGYP001126300050 FL=0
-WMVWKEKMMLNWFEKSNRQIYYGILITVSFHIFVVAFQ
->MGYP001386794033 FL=0
-PLGGNAAVALLDAAMERQAALIVEWMRVGFIHGVMNTDNMTLSGETIDYGPCAFLDAYDPAATFSSIDRQRRYAFANQPPIAQWNLARLAESLLPLIDEDENKAVEIASERIGRFKPLHEERWKAMMRGKLGLAGEEEGDATLALELLEWMRASRADYTNTFLALAGRVVEGGNAPLPVGTDAWNLQRRARIERPEGGGGAAHAPGGRHNQR
->MGYP002527839631 FL=0
-KAFERTHQMYNLGIEGLPYELIINSNPSIAYLMKQNPLHLQILIMAHCVGHSDFFKNNRMFKDTRPDSSVSRSRNARKRIQGYSEDPLIGRKKVEKFLDVLHTIRFQTERNGRKRNTRNDIKKGLIEEYNRNRSSGKNIPVPDLDRKLLHQDDDLLSFFIEYGNHFSD
->MGYP001804104866 FL=0
-MLTFPHANTLLFLGIPTYYVSFVPCAWHVCDMHMAFVHFRDWVXKRQNRTHXQKRRLLYSLVSTSINLQXHGRGXWTLTIDSSERLLXDRVLLNKAEQGRXVQCXKSYFFX
->MGYP000506167729 FL=0
-SKETMDKCPNLKAIAVLATGYNVVDYEYAKAKGIPVMNVPVYGTDNVSQFAVSLLLEVCSHIGHHNESVHKGEWASNADWCYWHYPMIEVSGKTAGIIGLGRIGRDTASLCTGIGMKVAGYDPFLTKEQIEGMGYEYYANYEDLLKDCDVISIHVPLTKETENMVSAKQLKEMKNTAIIINCSRGGIINEADLIEALDSGEIAGAGLDVF
->MGYP000552990992 FL=0
-GGMHEKFLNLRTKIQMLGGGFGNVQGGNLSFYGGDSNLGNGGDLLLAGGPTVSGDGGSIAFEGGIGEEGVGGSINFSSGQGVDLPSEGEINFNTNYKPVFFNTAGNKYKLLTTTQRDALPTTESLLLWNTSTKNFNWYNGTSFASPITDLDNAAGDVTGLFSNLQLGANVVTNIEVADNAIGSAEIINSSITNADLAPNSVTSGA
->MGYP001062954301 FL=0
-IYNECHIDKLDSYQGYTVFVDDYDGYVTLYDELKDKRIGIHLFFDSIFDINELKKINVIIKMIIIAMSFILIIVQVWLELKMPDYMSEITKLVQTKGALMSDILIQGGYMLLCAFGSLVSAIIVGYLISNIAASFSMRTRKSLFEKVENLSMEEVKNFQASSLITRTTNDITQIQMFIAMGLQLLIKSPITAVWAVTKILGKNLTWSMITAIAVVILLVTILVLMIIVMPRFKIVQNLIDKINGVTRENLTGIRVVRAFNAEKYQEDKFEKVNNDLTKNQLFNQKAFSVMQPVMYLVMYFLTLSIYFIGAGLIESANMTDKISLFGDMVVFSSYAMQVIMSFLMLAMIFMMLPRANVSAKRVNEVLDTVISVKDGKGAKAKEVGTVEFKNVSFKYPDAEEYLLEDISFKAKKGETIAFIGSTGSGKSTLINLIPRFYDATKGEVLVDGVNVKEYKLKDLYNKLGYIPQRAVMFNGSVSSNIAYGENGKGEITKEKIKDAVKVAQAEEFVSKMENAYDAHIAQGGTNVSGGQKQRLSIARAIARDPEIYIFDDSFSALDYKTDSVLRKELKKYTKDATILIVAQRIGTIMNADKIIVLDNGKCAGIGTHKELLKTCDVYKEIALSQLSKEELENE
->MGYP000237869789 FL=0
-GGGREKNTERSGRVGPNGPRVQLRFRVTSSGVTRIKGLTFNDGAREIFSRNSLRPRLPPPIFVSPSVSGA
->MGYP003956841209 FL=0
-SDISSIELLERARAVIPGGVNSPVRAFKSVGGSPVFVREASGPW
->MGYP000266856341 FL=0
-MSDCNLDKRITRRQFLTFAGGLTDAGFGALPRWVREASAQAKQGRKVLIVLFQRGAADGLNIVPPFNDEVYRKARPSIKIEAPIAGSRTIDLDGKFGLHPKLASLMPLWKDNRFAIVQAAGSPEETRSHFDAQDYMESGTPGVKVTEDGWLNRALVSGKIPQDPMAAISVTARL
->MGYP000179581380 FL=0
-MYFHFTVILDIIKELWADFFRKHHVRPIAVGLQPVKQGAKIGAPSVNVQRKYGILPRCFISLPALICSMFRI
->MGYP000648191730 FL=0
-IGIEKTNSGSIFKGKEDITKADPSKRGMGIVFQNYCLFPNMTVLQNVMYALNIKIKNKDEARKLSLEMLELVKMEEHKNKYPHELSGGQQQRVAIARTLVLKPDIILFDEPMSALDADNRLTLRKELKNIQSKFKTTMIYITHDQEEAFSLSDRVMVMKDGNIVDNLCATIKLVLPSINFRIRCQ
->MGYP001537497899 FL=0
-AASDVYKRQICKQAKNLFLEITIPEQKAYHVQTMLETSGNFQHSWQKFPA
->MGYP000667005491 FL=0
-QGQEHPADTAPRQAEQTGAEPDVRFYAVELDRGSQIAYGVWDDQNDRIYVDDEGVSEEFTSRWQAEEYARQLNQVNPLARYYGEGETILIRQYPNGQYYVQYCYDDQDNTVYATAGGFDTFEQAEAALYTHRPKAKKDPIAAQDLAYRQAAEYWSGDEHLVIFREPNGTFCNQYGFISGRVTPTTGSFAKLEEAEKQLYADRPLAQKVQAREKPPAHAPADRDEAERRYQVVVYHHLENGMDEKLEYATPEEAEQAARGYLEGTMEPDGFAYEGTAVYDLLEKKWLRVIGDFPTPEPPAAKEEQPLPSREDTETAASDRDLLGKEITLEGRRFRVEKIDEDGRASLRDLTFEGAVGFPIERVEHISVIRRLMGPAEKTAGPGKGVESLADGHDQGGTEPPLAPQRRARVSPFVLHPEVPNADRHEYHITDDAIGTGTPGERFSNNVRVIRLLKRLEAEDRLATPEEQEVLAQYVGWGGLADCFDERHSKYAELKALLTEEEYAAARESTLTAFYTPPVVIRSIYQALTNMGFQTGNLLEPSCGIGNFIGMRPEALADSKIYGVELDGISGRIAQQLYQQSSIAVQGFEKTDLPDSFFDAAIGNVPFGSFKVIDKRYDRYNFLIHDYFFARTLDKVRPGGVIAFVTSKGTMDKDTPTVRKYLAQRADLLGAIRLPNNTFKDAAGTDVTSDILFLQKRDALSSEEPDWVHLNTDANGLKMNQYFIDHPEMVMGEMREISGPYGPETACLPIEGRDLGEQLAAAIQNIQGSITEYVMDDPEIEGEDKSIPADPEVRNFSYTIVDGKVYYRENSRMNPVEVSVTAANRIKGLIGIRDCVRTLIEYQTEDWPDQDIQAQQRKLNALYDAFVDKYGRINSRANSSVFSMDSAYFLLTSLEVLDDERNFVRKADMFTKRTIKQRVTITHVDTASEALAVSLAEKAKVDMDYMAELTGKTEQEVYADLTGVIFLNPMHGYGGGSEEKYLTADEYLSGNVREKLEWAKRSAELYPEDYTAHVQALERVQPVDLTASEIAVRLGATWLPTEVIDQFIYELFGTSPRSQRMIRSHYSQHTGAWNIESKFADRGNVKAENTYGTTRVNGYKIIEETLNLRDLRIFDYVEDEHGNRVPILNKKETAIAQGKQQLIKQSFQDWIWKDPQRRERLTRLYNDKFNSIRPREYDGSHLNFVGINPEITLRPHQVNAIAHILYGGNTLLAHVVGAGKTFEMVAAAQESKRLGLCQKSLFVVPNHLTEQWASEYLQLYPSANILVATRKDFETKNRKRFCGRIATGDYDAIIIGHSQFEKIPVSVERQRYLLEQQRSEVLNGIAELKANHGERFSIKQMERTKKSIDAKLAKLNDQSRKDDVVTFEELGIDRLFVDEAHYYKNLAAFSKMRNVGGISQTEAQKSSDLYMKCRYLDELTGGRGVVFATGTPISNTMVEMYTMQKYLQYHTLEEHGLLNFDAWASTFGETVTAIELAPEGTGYRAKTRFSRFYNLPELMSMFKEVADIQTADMLKLPVPKANSHNIVLKPSEQQKEMVAALGERAEKVRNRMVDSTEDNMLLITNDGRKLALDQRLLNPLLPDSDTSKINACADNVFEIWQRTADQRSAQMVFCDRVAIRCYK
->MGYP003718977623 FL=0
-SKQHVNSAGTNTRGDLSPLSFPPPAPQPFPLVAPHHQLNCQTPYNQGSLLESGDLQKKSHTVGLHLR
->MGYP001491601391 FL=0
-EDSFQKSSSLLKHGFLDAIIERDALNEKIGNLCSILLKKNEIETSDAQPQQDREFIKKTAASS
->MGYP002264516364 FL=0
-IRYNDVPADLRTADEDLIGGVQTHDHADGDDHLELAVLVVGILAADLGKQVGPAPAEQGNEGKPEPHVFFFLLYYVCVIFVFWIIFSLKGYKIKIKGKRFFHALFFIPSMLPIALMATVFGSMLEYKNGIVNQILRGVGLGALAQRWLADPKLAMGAVCSVSIFMIGIPIMYYTADLTTISRSILEAATIDGAGMKDQLLLIIFPVLKNTHKTIILSMLLGGFREMERVYLMTDGGPGGSTEIIGTYIYRATRSAGSNIGLVCAAAIIVLIVAFIISFIQLKMTSKNG
->MGYP001571232008 FL=0
-PLCEYEYGVHWFWPSAECAREMIDSDSEDDWNHSGVSQCEKDASVLSVFYQESMHLLKLDISIAEFVIKHSKGRSXXXXKFKRHQRACGSRFAASAQIIRTEWKCSPLLVAILRELQPCCQRRSEDFIETVLGRSSQLRFGKIDG
->MGYP001478861697 FL=0
-MEKNPSLILVVAAAMLGHDGRVLMQRRRHDAQHGGLWEFPGGKVEPAETLQSALVREIAEELGVVVQQAGLVPLTFAAAESASDGRQIVILLYTCREWVGEPVCVDAEELGWFHPRELPGLAMPPLDYPLANALILSN
->MGYP003588991860 FL=1
-MKKMGSRCLAALAMVLCSSAFAADKVDLARAEEIVSGRCFLCHGLEGESASPVFPLPVGA
->MGYP000788765185 FL=0
-MDMTNIMYELVNTKTSLTIADRTIETLQKQNRRLNRRCLRQSLMIAGLTLSLIHISEPTRRSYIS
->MGYP001606674547 FL=0
-ASRDHIRRVIPLTNEVLAQSGQALEAIDMVAFTRGPGLAGALLVGAGMACALGAALGKPVLGVHHLEGHLLSPFLSADPPSFPFIALLVSGGHTQLMRVDGVGRYQLLGETIDDAAGEAFDKTAKLLGLPYPGGALLSQLAEQGDPRRFTLPRPMLRSGDFEMSFSGLKTAVLTLVRQQEALSPTGQLDDRTRADICRAFQEAIVEVLVTKSLAALKHTG
->MGYP000296153156 FL=0
-METPTKSKKRFLPAGRRIFLLQAATSVKKKREGKGEHVKSKKGAEAKEIELT
->MGYP001120318111 FL=0
-SIATCESEAETTCAFIIDIAGDQDHIANCVGSVY
->MGYP002231636691 FL=0
-VGIIGFGRMGRFYWEAMTKSDGWNIAYICDTDPASRQLAKKLSPNSIIVEDNQKIFEDEKLCRLVGLFTLADSLEWKQIEKAIRYGKHIISEKPVADTMENEWKVVEMAEVQMSFLR
->MGYP001205799662 FL=0
-NMVSHTVDKLVGTDATNGATRTVYSLTESPTNPDAVSVYLNGVYQRSGSGGANNYDVSGSTLTFTSSLATTDQIDVHHHTFRSTLTKVADNSVGDAQLASGTLTTKGALTVTGNVIIANAGNIGSVGDTDAIAIASGGDVTMTQNLVVNGNMTVSGTTTTVDTTLTLSDAMVINNAGSDVGLLINSTSTGNIIQLQDGGVNKFVIADGGALTYTGAATI
->MGYP000237547906 FL=0
-IREQAWSQLLPGLGFMRWPIFRGAVVLAESLHNGYSALKFSTEHGLPPDDDGKPHDAEPHANHRRDHVRVPLGERVKVQEGPRVRRGLPAARRPAGEGDVEAEAFQHLQRGDGGARGELVDEAGREERDAHCRDGAIGQRTDGLLIMGHKQQRRPVAAQMLHPLEAALLEQGIAHRQRFVDDQDLRLDAHLHRKGQPHQHPARIGLAGLVDELADIRKSLDVGDPGFHLLPREPEHGAVHEDVFPPGELWVESRPELQQGGDPATGFNAPRGRVQGAADELQEGGLP
->MGYP003113969438 FL=1
-MAHLPPLYHLRPAWLRQAFFLIALTCAVCAGQASACVGSADPVISRLEIEVGRNPLAALDSITQEIADTDPLDKRRLAELYIVQAKALNMGGLDSAPALKKARSAASKLSERAPANILLQMNAYYDLPDEAAKRRAMSSLLRGYRSLPDGSSAKTCRAVDLAFNYSFQEKPREAFTFASQAYLNSADDKSSPARAEAASALAYLVSNSHDFDYAKQLHSEALAIQLKLGMSDLAANELLVRGYTKLKDGEWTDAVADFRESAKQARSYGNQYAVDYALLGVCQAASEGGKIADAAPECERAYQGLGKPDEAMALPATALMAKLFVERGNPGRALAILDPMIAKGKQENASDDWVMALETRAQALFALGRNAQAYEQMREANEAAKTFHNADMQSGAAALQARFQTRELQNLLAEEERASSTRLRLAIAVIAGSTTTLLLLGTLIFFLLRHRRRFRRLAMTDPLTGLANRRATLERVGAALPGPDAPHPRASFALLDIDHFKSCNDTFGHDAGDQVLSQFARVVERCVRPTDIVGRWGGEEFLVILPATGLKDALDIIERVRSEAALEEFDFAPGYRLRFSAGIAMPSETGGVTDACIKLADRRLYAAKHNGRNRTCIDAGIAWAGPPAPTPPPSSGVSGTGSGSAQAA
->MGYP000344450175 FL=0
-STQGVSSAASDVYKRQNKAYIVGEEGPEIMISKSSGKVLSNDDSQIFAMLLAANPQLQKVSKARAEKIMRSRFPEYFE
->MGYP001069234379 FL=0
-MVSLSERTDLLGAAIEAARLGGVVLREFFGQKKEIAFKGAIDPVTNADVASERAIVEFISRRFPGHDIVTEETRPDLSGSSYRWVIDPLDGTVNYAHDHPMVAVSVGVEVDGVV
->MGYP001488139253 FL=0
-MDNLIGKKLDGLYEVKELIGSGGMANVYKAVMLGRNGPVPAGTVVAVKVLRQEYTHDPELVRRFKNESKAISLLNHPNIVKVYDVSVNDQLQYIVMEYVDGMTLREYLNERGGKLTSRETVHFISQILKALEHAHANGVVHRDIKPQNIMLLDNGQLRMMDFGIARISRAENQLLSGKTMGSVHYISPEQAKGDETDCTSDIYSVGVMMYEMLSGQLPFDAEDAVEVAIKQISDQPKSLHEIAPQVPAALVEITEKAMAKLPQNRYASAREMLDALDTYVQNPSVMFEYQYITEDAPEKVVKRTMNQNKAARQNHPNESAAPRGKNAKRKRRTIFLPVLFGITIAFALACLALCWLILNDSSNLMNNKADITLNDYIGMTQEEAQATEQVASGQISVTWEQEYNSNYAAGYIYKQSPVSGRTVREGQGVTLTVSLGTQYVTVPDLTNYVQADAEQQLKSLGVSVLVTQAVDTSVASGAVI
->MGYP000855914706 FL=0
-VSSDKMEKTITVSVETVKQHPLYKKTIRTSKKYTAHDENNEAKTGDVVKIMETRPLSKNKRWRLVEIVRQQETMLQVGDNTGAKKVLCIKIPGGSSRRYATVGDVIVASVKEAAPGGVVKKGEIVKAVVVRTKKEIRRPDGSYIAFSENAAVIIDDNNNPRGTRIFGPVARELREKNFMKIVSLAPEVL
->MGYP000079949637 FL=0
-EQEALYPFGYGLSYTEFSLSEPEITVYEGDKVSETGIIRKGTGMTVRTVIRNIGKMAGGETVQVYVKSCCDGTPNPQEVVLTLKPEAFELFDIDGAAQILSGEYCVYTGTSQPDKRSKTLTGKGGFVNTFAAEV
->MGYP003113302263 FL=0
-KKKKKSSKLTVDVVFDSLYSSLSRNEINGFRSKRINFTGLIGDAVYEVEVPLEDDKDYEGFETGIFSLQNLSTGRFGDFISHTVMVSDNELPEIKIEIVENLNKKVLVLHNLESRELDLRNWELVKGDIKIVFPKNTRLKVGESIVILAGEDQGLFANSLLLDNEKAELLNSNGTIHLKNYEGTKVAEVSISKKEESSNSLVASGQVSSN
->MGYP001378584181 FL=0
-ITIVVTNVLDLAGNPIDLYNNSGTDVGIGVSPTVIISSTATNPTNSSPIPIIVTFSEPVTGFDLTDVTVGNGTADNFASSSATTYTFDITPSADGLVTVDIPAGVATDLAGNGNEEATQFSITYTSITYDETPPQVISVDVTDPFTVDVTFSEAMGDGVTTADNYAISGDGQGTLADHPDSVVHKSDNTYTLTWNTGEMRNGASITIVVTNVLDLAGNPIDLLHNFGTDVGIGVSPTVVISSTATNPTNSSPIPITVTFSEDVTGFDLTDVTV
->MGYP000737688134 FL=0
-MYRIAVLTNSRAQEAFLTEQILQFCAEHCLFPQMDCYHDQESFFETARSEPLTNAVIALPGVDGLNAVEHLRALCPQTRVIWCSDLDFSLHAFRLRVDYFLLEPITEEAFQQGLSTWLDGKKTSALFRADHNKHNNEEDY
->MGYP000609830271 FL=1
-MDFNDTTEEAKFRKEVGDWLSANATLKEDEESGSYPGMGEDDALSLAKKWAAKLYDSGWACLHWPKEYGGRGSTPIERVIWGQEASKYRIPGGFFEIGQGMAGPVLMMYATEEQKKRYLPPMAKGEEIWCQLFSEPGAGSDLAGLKTKSVLEGDTWTINGQKIWTSGAHYSDYGILVTRSDPSAQKHKGLTYFFLDMKSPGVEVRPIKQISGGANFNEVYFTDVKIPDEQRLGSVGDGWKVALTTLMNERLAVGDASGPDFQEAFNLACGHDLNGDLAIKDGSVRDKLADWYCQASGLKYTKYRNISALSRGETPGPQASITKIVSGNKLQEIANFGMDIMDAAGIVRPESADAEQNMYQMGFFGAAGIRIAGGTDEILRNIISEQVLGLPQDMRADKGIPFNEIPSSNK
->MGYP001094161847 FL=0
-MNPRYILVLFSGIVVCTLEYYIHILRPQLESAPPMKKPVLQVGNRAKHSTEIVNEMQVTFAYLEGTFLKSAMGMDELTTEMHNYTLLAGIVSASGGPYYFKDSGSAATMIEHKKMFKSFIYSIDVL
->MGYP002524929742 FL=0
-MKAVDNDEDFALVTPRDTGDGPVNEVVATVKAKDLWDDIAESAWKTGDPGVVFVDRVWETAPNPQMGKIKTSNPCGEEFLENYSNCCLGSINLDLHINGTDFNWELLEDTTRTAVRFLNDVIEVKDRKSTRLNSSHSWISYA
->MGYP003440339087 FL=0
-IIHRINMDTHVVIMAGGIGSRFWPMSTPQMPKQFVDVMGVGKTMIQMTVDRLASLCPMKNFWVVTSERYVDIVRKQLPEIPVDHILAEPAARNTAPCIAYACWKIRKHHPEANVVVTPSDALVLNIEEYRRVISSALEFTRSGERIVTVGICPTRPETGYGYIKTGEYVESEICTVSSFREKPSLEVAEEYLADGGYLWNAGIFVWNINTITEALRRHSPGLASIMDEMSISFYTTEEKAVVEKLFPTCEKISSDYAVMEKADNIYTLPAEFGWSDLGTWGSLWTLKERDENGNAVVGDDVRLFDCKNCIIHTPDLKRVVIQGLEDCIVSKHGDRLLISRKDHEQQITDYSKD
->MGYP001086002945 FL=0
-AEQSTRYSMWTEITRPKYERKGLGYSSDLGDAEWAMIEPRLPQRHRLGRPPKTEMRRVVNALLYMVRTGCQWRQLPREFPPYTTVQHYFYAWRDDGVLQRINFELLLEARETAGRAARDHRRNSRTTTVAAHVMRSD
->MGYP003329493463 FL=0
-SCKLHEDGSTRRTYQNEIASVWSKEIPIEIPSSEWSNDDVEPETIASLIQRNQKLKALIYEDAESLNLVKEKISKLPV
->MGYP001213017408 FL=0
-GPGSGPGQGDARQDTGLGTPGPPLLQVCSLTQRYGNKIVLQDVDLEVRSGEIVGVMGDNGSGKTTLLLSIMGILRPVSGRVMLEGEDITNVPVSARARRIGMVFQNPNHQLFTDQVWREVVAGPLSRAVRRRRAVPRPRRFSTGLTSSRFARATR
->MGYP003197570824 FL=0
-KDSEGWLKHTDFIILDMICLQLAYVLAYAISGYGFNPYETIIYRNMAVFLELADLVMIFAYGTMKSVLKRGFCSYVKSCDYGRCLSGFIFIPAS
->MGYP001590617569 FL=0
-YNTLFIHFRQSIHTLLRSRPVGKRFSKFLAITGEAFWASLGSFGGVQYWYGAVVNEWIVADAWASSCVPHAILYRMDSGTHVEVDQAFERAYEHSLFLCAVFCDCTFWSAPREVEWVFVFFALGTPFKRKNTILISNVKCTDELACLIPHHQIQRGFRFTDPVLQYVTRHWISLMVYLILCASQCRT
->MGYP000882899174 FL=0
-MLLNVTLIVLCAGNSTRFEHKTKKQWIRIENEPLWLNVSKRLASFSQFDKIIIASHEDELNYMKNFTDNFIFVKGGETRQKSIINALELVTTKYVMMSDVARACVPQSAIKNLL
->MGYP001793805036 FL=0
-MRGNSKYMRREILFDSTRPILCNTLTSGVCDGILLLARCIRFDISPYDPPSPPI
->MGYP001580518470 FL=1
-MSWIGGIDKVSRERRGIKDLVNGWDKGVGFGIYLLNI
->MGYP000055909560 FL=0
-EALLVWTAHRCITSLELVLTAMSEHAPLDDRPFWALVGDAGYNKDPITAFGISDAFRDAQLLSEAIDDGMSGRAGLEEALGEYERRRNESAMPLYETTLRAAEYDQHHPRSLELRAALRGNQPDTDLFMGVLTGSVPKEEFFNSQNIRRILSQAKDGGSAA
->MGYP000181573229 FL=0
-MGSKKILLVEDDPNFGTVLKDYLALHDYNVTHAKDGIEGLIEFKNGEFDLCILDVMMPRKDGFSLAADIRSTNKEIPIIFLTAKTMKEDVLRGYQVGADDYLNKPFDSEVLLFKIKAILQRKESDVNKESELLQEIRQFCIAAGRNPNLDSIITYNYDDLLESCLANIEVDIPFKSIHASGMKHKPHELPIYHVHGFLPQKSKLTNKNRVVLSEDGYHQQYTDVYGWSNLSQINKSVSYTHLRAHETVLDL
->MGYP002759741552 FL=1
-MSNPVPASPFSPVAIGPLTLKNRFIKAATNEGMSAGGVPSKQLAQLHGNLAAGGVALTTVAYCAVSRDGRTLPNQLILEPASLPHFKALTDAVHGNGGLASAQITHGGCFTFIRERSTRRPLSASGGFNKIGVMSGMFFKQAMSEADMAQVVADFAQGARLAREAGFDAVEIHMGHGYLLSQFISPIYNKRRDQYGGSLENRLRFPRRVLRAVLDAVGQDLAVICKYSITEGTRAGNSADDGARIARMLEAEGAHLLVLSAGMNAESITTMFGSSFPKENRVQQKNPLIALAMAIQRRTEPEVKFRELYLLEHARKVRAAVKMPLAYLGGAQGLAGIEQVIGEGFELVAMGRALIAEPGYVNKLASGEERNNRCTACNRCVAMMYTPGGTSCVLGEPGDAALNRVPAGSA
->MGYP003289090808 FL=1
-MKKSILLWLMVLCVGIVSAQTIEINTVEDLSALATNNESQNGYVGQTIDLKADLTITKVWRPIGTRDYPFRGTFKGNGHIISGLGAIAGTDGVGLFGYVGEEGVIEEVGIGTGHIKTMKNDECQYVGALVGRNNGTIRRCWNMATLEVNAIHVGGLVGQNSGTTEDCYNAGPILKAIDYIGGLVGTNTNTGAIRYCYNIGYAANGYGVVAQNTGTINDCYYDRQLYIQNPDAGHQDPTGVTAMEKSADMYTIFSARSAWQQMGDNYPILKVFQNQDAAIVSAASIDLTNKGDALADNHMNLLTSDFIVNSKNGVHWEVTSPLMEQWVYPDAANANQWRVAFPCRPTDVIMQVSKNGNVREVYAFPKPVPDFIPGKFAADSFVVCLSETLNFKDIEFKEKGYEAPSGGAGNYQVKLMLNYLDEKGEVDHNEILISAPSWGDYIALYNSGSWTPSEPGHYTLQRYAADEQCHPELMEAEGVVPIFVPANLTAGDIAGDAILCGIDQTITIHSVEPAICEGTEVYYFWTKNGIEITGEDNASLENYPMNTSGTFVFKRYAYNNACVSKDHPLEAEHSVTITVYEEFVWGAIVEPSDTIIGCTVQDVLNQLSVISEQETVRGGKKPYSYQWMMKIDDGAAQPITGADQHDLNLRDAGLEDAHDYVIYRTVKDSHCQTEWIKSDGQVKIQIYSKITGGKIETKTIQADCIMPEEKGAIPVQIQSRQPAQGRGDIDYKWYMVVNDETFNPIDLKQHTESLDYKLDYGSVQNNATYTFFRTATNKSCGGEEVRSEGETTLQVVIATNVDSTLLICESMFENGQYTFYYPNAENPRQTNIFYKDDLQIWEFNDKLESGCEPRVTIRPVLTLAPKIHADNVSTICQDGDAGTLTIYFEMLEGKADTYNIELSESLRPFFDGKQYISGTIPTVTAGNSGAITVQCQRIGISGGDKIMNLQVAQQIDGQELCYSAMSEIVLNVTQGGYVLDKYGKVLFIDNNPKHPTDPKFIAYQWYKNGQPVEGATGQYYHEDGASLNGSYFADLFYFNGGREMILRTCPIEMENGTKREQENATDSVSKRLENSQIIIQRGDAEYTILGSEL
->MGYP000988737932 FL=1
-MRLILVFLTLLLAAASAMPQDAHPHEESLPAWFAETFLDLREDVAEAAKAKKRLLVYFGQDGCPYCRELLQTNFSQKRIVDKTQRHFTAVAINIWGDREVTTMDGRTQTEKEFARALGVQFTPSVLFLDEKGQVVARMNGYYPPHRFEAVLDYVAGHMERKRSITAHLRTAAREAASPDLHAEPFLIPPPHDLRRRPGGKPLAVLFETRHCAGCDELHRDGFRRPEMRNLLNGFDIVRFPLFGTEKITAPDGRATTAGDWARRLKIAYSPSIVFFAPDGREVFRIEAYLRPFHLAGSFEYVATGAYASEPEFQRFLQGRAGRLRERGEAVELWK
->MGYP003328125236 FL=1
-MNIKTNISLKSYNTFGIDVNAKYFFEFSSVDDLQYLLSDKSLKNEEKLVLGGGSNILFTRDVDALVLKNEIGGIELINEDDTHFYIKAGAGVVWHEFVLYCINHGYAGIENLALIPGNVGASPMQNIGAYGVEIKDVFHSLEAIDIIENKKVVFTNSECEFGYRESVFKNIYKNQFVITSVVYQLNKTPKYNIEYGAIREELDNMKIDHLSINSIAQAVMNIRRSKLPDPKIIGNAGSFFKNPEISSAEFENLKTEFPKLVGYKNENNSVKVAAGWLIENCGWKGYRIGDAGCHEKQALVLVNFCNASGDEIYDLSEKIIESVKNKFGIQLQREVNII
->MGYP000122910653 FL=1
-MLDLATAEYSLVGCVLIDARCLPAAREILPTAEAFASEPCRKAYAAACRLEDEDKGIDPVIVGRAAGLSNDFLMQCMDLAPTCTRAAEYAKAVLDGYQRRQLQALGEKLQTEALCAGSTADQLLTEARSTLDDLASTPGRCSVKSARDSLLDFMTFRAEVQQGKRQAIRTGFPSLDRILGGFAQGGFYVMAARPGVGKSALGIALADMMARDRRVLYVSLEMTEAELNARRVAAVSDITCTFGKLLFGKTTEEQDAAIANACGKLYAHKLQISAVSTLTVPELELQARNVGAEVVIVDYLGLLSAEDKRLSEYDRVTRISGDLKRLAKRLGCVVLALCQLNRESVSAPGQDTRPRLSQLRSSGAIEQDSDGVLLLHRPEYGRTETPREASAPQQFFVDVAKNRHGRTGTAELAWYAPVNRFEDYGGKWTVKSWM
->MGYP001552508999 FL=0
-LAGAGISTLDPLEDNERGVIISTASVAAYEGQIGQAAYAASKGGVVSLTLPAAREFAQFGVRMNAIAPGIFLTPMLQGLPEDVQQCLAASVPFPKVLGNPAQYAALVLHIDHHHRADRARQVVX
->MGYP003447821379 FL=0
-SCTKNRFLINNNIQLLKQQTIMDLNEFVAHFAEQFEDTDASVFTPETKYHDLEEWSSLIGLSVIAMVDDEYDVTLKGNDVKNSVTIEDLFNIVKERA
->MGYP001289232407 FL=0
-ELTVSENRLVYDSLVRAGEAPPVVWDTVKAGNYGRVYIYTDDERAENLKISNLQSASRRILLSDKTINGQHYTTQVYLDKTLFLSTDGPKGPITIQVKSVSEDYFTYLKGYEQFEASSDFNALSQPVRVNGNVQNGLGVVGGAYVQEFQYLYDRW
->MGYP000237473348 FL=0
-MTPVGLWALGWQNTATGRWSRAAASWSGGNIVARQAGNVNMLCYVVWASLFSIPPLFALSLWLEGWSAMVHGVRSADALTWVAVLWQAVGNTMLDRKSVV
->MGYP002446805835 FL=1
-MLRVQLICTGKLKESFYAAACEEYNKRLQRYCSPEIIELPETGDIKARRRGDARAHRLWRPRRRHVH
->MGYP001329416472 FL=0
-ETIQSKNGCLIKGNISSSGDRIYHVQEGQYYNETKISMSLNSARKCSECNGIGAKNASDVKTCTKCDGSGVFVQIQQIGPGMISQSTQTCGICQGKGKMLDPSKLCKRCNGKKVEKKRVKLDLQLNRSHKDGDKVVFSEMADFDPEATTQGDLIIILKEKNNQQFLRIDDDLVYTKTITLLDALCGMDLTITHMDNRKLFIKTSEVIQPDSIYRISGEGMNKNSNLFVKFKVVFPSKLSEERKKYLRKLIQTKVTENVQDKEENTKDREIKFLDDLNENEVVYINEKINILNLKGKTSSDNQPEYEYSGEEEGIPACAQQ
->MGYP000295350481 FL=0
-MVRNRPKVRKKFVVIRPKNHRKKAAGCPIEQPAAYLFT
->MGYP003428885701 FL=0
-NMITGAAQMDGAILVVSAADGPMPQTREHILLARQVGVPYVVVFLNKCDMVDDAELLELVEMEVRELLSKYEFPGDDTPIVHGSALKALEGDQSDIGVPAIVKLVAEMDRYIPLPERAIDGAFLMPVEDVFSISGRGTVVTGRIERGIVKINDEVEIVGIKDTVKTTCTGVEMFRKLLDQGQAGDNVGVLLRGTKREDVERGQVLCKPGSIKPHTKFEAEVYVLTKEEGGR
->MGYP001619181529 FL=1
-MKRTVLWSAIGIALALTAPPVQAEPARSADLPTLIDQAMRKSPGLQAKKRAYEAARGRVVSAWLPDDPMVGVDVEGQPDLFNFGGRTNNEYMVSQTIPFPTTLILRGQVALRDAQMAFQQYKEKERDVVWHLEQPYYEFYLAKKTRAALEEVRALLEKLAETARRRYEANQASLQDVLKAQIERSKVDIELYQTAQEEHIAQAHLSHILNLPLNTPYELPEERHSPPLSWTHEELEHLAVRMRPELRAAELGIKRAKASRMLALTRWLPDVTGRIEARQFKADGRANERDTFIGVTVPVWSLLKGAGGEWKSAGKDVEETEAAYQELKNEVLLSVHEAYAKAKTAEHALGVYEQFTLPQAKQQVELALSAYEAGRAGFXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXSPSATCTTARNSTRASRAR
->MGYP001234761162 FL=0
-SGYKCGIDLVFIFIVVFKLILNLHYDLRLNPIDICKTVSTNFKTEIFDVRDRHEGTHI
->MGYP000998860503 FL=0
-MKRMLSYVVWVLSAALLWGCSKRAMGRMESGAKLPVHFSCEGFSKTGGAATRVTGENFEPGDVVGMFSYPSDGPMFGSGDFTKGNVPYVYMQEGELLVREGEVPLYFPDDPSVPLTFKGYYPYSEQMTADGLLTLDLADQRAGEKNAVLYSDNAQRIVRTANYVGLEFGYAMAQVIIRIQYDPDEMPDGDLAAVSAVTLEGEGIYSACDFHMADGSVTAAAGVPARGTIGMRPGSAETTATVAPATARDLTVSVTTPAHTYVARPKDITYERGRQYTYNVTLKGGGEAQIGEASIVDWEPGNDGIPPIIGVPEYEQR
->MGYP003398871467 FL=0
-YALIDLPEFFDWLEANAEKLRAGDKAALAEAVRVSCASKARIVAIDPATYADAVTWSEQFGADVDEVIEALSSSTEESIPVIAIEGEPVPEVGSFGLGRTYPYRVVATVRGFPTAGNRSVSVLASADAINEYAARGGDEDAPAVTESFRRTAVSQAGADVLTSLAQAQRIRRTPGTAAERDKARVDWLTQYNRSSAKDNAK
->MGYP002477722919 FL=0
-CICVHQAEEEGASLGGWDERAESAWHATWVASLSRCIAYASKASAVAFVQKQVRVATLVVEIMIDHACVSLDLSLADQAANNNSDLVIMEDHKFTNPYEEQKDHINEYTAQEIATLQSRLDKQLGPEYISTRPGNGGGKVHYLAAEKVINLANEVFGFNGWSSAIRDVQIDFVSFSDSPRSLVMLTTTVRRESNNRKDQLRTVYHCARLFERWHIPRGKLSSALIYPLELTGVDIGYGHIENCKGKAAAFEKAKKEATTDALKRALRNFGNVLGNCLYDKDYLQRVTKVRIAPSKWDAENLHRHPDYAPIKKEAIAGPSAPTTIASNPPARMPSAQSNTSEFEDEFGGNLFDEVDFSHPDEVRLDNSITEVSVETPVRPPANSVSAQAMNRQQPNRVASMPNVRQFSGGPQQNGQQNGQQARPQVPSQTFKNTNGMNNQPPNRMMGPPHQASNQNGFRSNPSSASESTTTNGRQITPPESVITPSQVPSHVPSGFVSGAAASALVQPPESGAVPPIKLFDPHHESPSIRRTQGVDLRKSAPIKRSEVGAPTVPIPNPKPMMNGGAPANRSNFVNPAMDAGRRIGMPGMQQSPLANRSAYKPPAMKRPLPAEAPVGRPPLADMSNVQQTDGASDPKKLKMDAVQEPPNPASGETGAAA
->MGYP003292343469 FL=1
-MPVLYISHDETLIEKTANMVIHLEQLKRKTEPKFTVAKMPYRQYVEERLHNFDRQEQQALNERREKRKRDERFAEIYQKVQTQLAGCSRQAPSVAKNLKDKMHSVKAMGKRFEREDENMTEMPEQEEAIFFKLGNKEDSIPAGKVVLEYELDEVFRYNSKTKKIMSDYWVKVKIAKNKVAPPFKTAEFDIIYGKGISREGDILDLAADVDIVNKSGAWYAYEGNKIGQGRENAKLFLQNNPEICNLLDAKIREYYSLGGAISGEKSE
->MGYP002583638056 FL=1
-MGLFDFFKSLTNSKTEITSTDNDVTHLTNITKSGLSIHPDLVDLIWIGDGKYQNYSNQPHPTMTYPYRGFVVKVAAFGAEEPSLLYLKYPIEQVQPSEQIERPPYYPFYGELTPKQKYLYWKFLNDPYNPHNDIGYVFIFYYGLERHLLYGDFEKAFNVILKLRDVYNNRSFQHYSAGALILSTLIHKRADYTQKFINSLDKDYEFQMPGELYFLCKLSLGIPITAFDIMKFHKFFNFTNTRYIKNNSDMFLKNLRQNICYQNNGRESLDASLYCTESNFSHLPTISLPIFANVSIREKEVTIPNLSCDSHFMGCIFLLLDKAHQDTKQELANLRKGKSANSTTEEQSTESHTPYAGSYFDDKKFMSLQQIYYDNSQKIESQWSILYNLKTYTGSNADRYMELCRLNIQQYTKMNDRGKHYTDYESPLGVPAYRRLAMLYEKQGNYEASFEVCIEAIKSGILYDGNKSGFKGRAARMIKKGNIQPDEEIITLLME
->MGYP001139541149 FL=0
-MDIQEILEHLPHRYPFLLVDRVLECEPGKR
->MGYP003566972480 FL=1
-MRLSIRNNGRYLVEFDRLDVQGRNAISGCGLVFSLKGSSPGSEKNVNIFGIQIGLYHSEDSKFIVPSISCADSLRQVSQYSNNNENFHFEAVLTSEQINAIEEIRQDGDLKLTLTLKALLSSSSGLANSYERSEVVVPRELWLKALRSSGFCRTVLYEIPLPASDIDIEGLITKARGFIETGHYKDAVMQCRHIIESLEELRGDKRQAQAANRMAHSDSRKDMTSIERLLSLREQLKNVCQLGGHGREAFTRSQALSVLGMTMALVSEPTVGALVNAVSEGTERGEA
->MGYP001095359691 FL=0
-MNSRRSWSRNRCRFDARTDAAGEPVLLADQDRTRWDRTLVMHGLAALDRATTLGRPLGPYTLQAAIAACHSRAPRFADTDGEAVVALNDSRPQLAPSSVV
->MGYP000548248604 FL=0
-MDEQKRPRAWVYARIPGDYDGTMNSYKVCSMQALHDGCDIVGGSIDERGGWLLRPGYRDNPFGGDRPSQT
->MGYP000364143963 FL=0
-GDGTFQPAASYTAGIPYWDPAHAVAVGDFNGDGRADLAVANLGTVSILLGNGNGTFQSEVKYGTAGGSTIQPIAVGDFNGDGKTDLAVASLGGTNVAILLAKSDGTFQPAANYAVGHQPYGVVVGDFNGDGWADLAFASNVDKNVTILLGIGATSTPDLIISKTHVGSFVQGQTGATYTITVSNRGGSTTSQVTVTDSLPVGLTATALSGTGWTCSLGDRKSTRLNSSHLVIS
->MGYP000838638459 FL=0
-YTRLFVGSSDVYKRQAAGQLLYEKGFFFVTFVWGAALAAALIKRWRDGGSLSTVKK
->MGYP000110898291 FL=0
-CKIICQKLAEMGFFDSAMNDADQQFGVLLRNNDPDAYTGYLRWAKPVVELLEGKGSATFRKVVFFWVRDEQRRQQMQSNIVAHYLDVIARPWAEEMAYRMQAQGYDKSNPAGRFIMNIGLPMCRVISKFGKKTELPMWLKTALIWGTTTVLLVAVSAISGTDKVLNKLRKHLYRDWE
->MGYP001080633953 FL=1
-MSPGQAASLQLSTARLRILPLDSENLRLSLEAPEQMEMNLGLQVTGNRPQGEVRDAVESMLAHVQQDPENWLWHTHWQIVLKRDKLIVGGCCFKGPANVRGEVEIGYGIEPEHRRQGYMEEALSETVRWARQQPGIRSVTAET
->MGYP003432707236 FL=0
-MAGGSQIIISSDGIIIKTPGEFKVFAGQHIFNEASVASLKATHLQHLLPPCDVIPKAKITPDVHFPVMGILARIERLDGEKINSTDKLLINGSPLKEVWIAENAYEPAYGARPLKR
->MGYP000920430015 FL=0
-RELAEVWDELREYGEQVIIELKSQPSVYRIKDKLVKWDYGYDLFNDKLVAIKGSLTLNAFH
->MGYP000639132496 FL=0
-MGAYILRRLLLVIPTLFGVMVINFALTQFVPGGPVEQVIARLEGGGDSIQNLGGSENAGVQEEEAVGEGGDNGYVGARGLPPEFIAKLEVQFGFARITCDEGFTGTPSVTAPECRKEKIPAVERFFIMMGNYLTFDFGQSYFRSISVVDLVIEKMPVSITLGLWSTLIAYLVSIPLGIRKAVRDGSGFDTWTSGVIIAAYAIPGFLFAILLMVVFAGGSYFQWFPLRGLTSDNWEELSLWGKIVDYLWHITLPVTAQLISSFAVLTLLTKNSFLDEIKKQYVLTARAKGLSESRVLYGHVFRNAMLIVIAGFPGLFLAVFFGSSLLIEVIFSLDGLGQLGFRSAVERDYPVIFGTLFAFGLIGLVVGILSDLMYVFVDPRIDFERRG
->MGYP001328790198 FL=1
-MSELYEKTAVELGKVLSSGEASSEEVARSFADRTAKVDDKVHAFLNRDDEDFIRQAKESDERRSKGAALGPLDGVPVALKDVISHKGQPLTAASRILENYVSPYDATTTRKLKEAGALVWGRLNLDEFAMGSSTENSAFGATRNPWDVDCVPGGSSGGSAAAVAAREAPLTLGSDTGGSIRQPASLCGVVGMKPTYGMVSRYGLAAFASSLDQIGPFSQTVEDTALALGVIAGHDPLDSTSFPTEVPNYLETITKPCPKMKLGLPKEFFGEGIDEEVRKLVDEAISFYRKEGHELVEISLPTTDLAVPVYYLIATAEASSNLARYDGIRYSHRSERAENAVDVYAKSRGEGFGEEVKRRCILGAYALSSGYYDAYYLRAQKTRTLIRRDFEQAFQEVDAILTPTSPTPAFKQGERAEDPIAMYLSDVFTISVNLAGLPAISVPCGHTSSGLPVGLQVIGQAFGETEMLAVANAYDSVHGFGRKCPEL
->MGYP003694182255 FL=1
-MKLNCAAIPTGLLESELFGHEKGAFTGAMAQRIGRFELANGGTVFLDEVSEIPLDLQTKLLRVLQEREFERLGSGRTLRTDARLIAATNRELGALVDEQKFRADLFYRLNVFPIHVPSLRERPEDIRCSSGISSSTMRAG
->MGYP000441261351 FL=1
-MRLNIRKSIITGISLATLLPAFSLLQSCDDSEAEKWVDLRYRVEDSYLVEAKNPEPVSFQVKSTDPWEVFGKYDWYTISPSTGEAGETYTVTVTCKENTELDDRIDTLNIKSDYWTGKRFVLTQKGTAYLNVEGVDMIDQEGNSETFSVLSNQKWTAKVTDGDVWLLHPIRSIGRNERRNYCHRFTEYRRTTYRYCNHL
->MGYP002925163669 FL=0
-FAARKAFVRECIDANLVLETPDPVIDTQFRYAKLRAAESIVATRGGYMHAPGGESYYAAIWANDQAEYVNPFFPFLGYGVGNASALNSFRHFARFMNPAYEPLPSSVIAEGDDIWITDPKGREHRLAMLRNQTRGQDNLSLADFIAPKGDWIGCFAVTAGIGLKELCEKFRAGGDDYNAITVSYTHLTLPTNSR
->MGYP000555143592 FL=0
-FTTTGLKNNITRYMIASANWNLGGTSSKTLYANQLYTSERGTAVYSGHTTMWQGKVALPYASDYAYAAAFGNGSSLLCSSNINSYSSTNCKNNNWLYTQFKSGSAWLITPYSGNQYDPWLVDTTGIGNYGSVAYNANAIYPTVYLNPDIVISKGTGTSDEPYQLSADTVTSSQVGEYFNGYTSYKNLDFAYYDFGSSVSVIAKFKIDDYPIKFADIVANWETGGFGLVIDTDKKLKFGIRTTTGSDYVYAASSGAVSLSEWHTAVGTYDGTTIKVYLDGSLVGSTTISGSIKSTSAQIAVGADPYTGGSASGEYFPGYVSEVSVIDQAIGASTIATYFSKSTPSTTTYTNTKTLVKAKSTSLNSPTLVKDSIYRGKYFDGTIESGSYVARAELTGDTYFSLGTQWNDITKAYGLSDKEMFNLFNTRALDDAVRQGKSIRFSQNPLEWKGTALGDEWLYLQSKHGYTRLKKIGDYWYAK
->MGYP001202979195 FL=0
-LCLIRNEYLWYPTPKQSPLLGVAGLGGGIASRLGGKAPNPYRGLVGNGSLRSGFTNLQMAFPFTDSKNGLDLSGNNRNLSNWSTNTPVEYAVTGVDKNGDPPPYTTSYGKTQSGPDYGWKNLSSDFNFQGSKTYTMECWFQVNSPDTGILMISMRSNESEGQVLTASTSYGIKSLAWSGSEDYTLSGGTIVVGQWHHGAYTRDSSTSPDTHTLFLDGTQVAQITSDTYGDAYDYNQYGFATFGGGGVAYYPNSFMQDLRVFDTVKYTSDFDIAEYLPTLDA
->MGYP003457825976 FL=0
-LEAACRRDEPAALIVEPLVLGAGGMLMYAPQVLADMARICAEHGVLFIADDSGAYDVYDIPASGGPVRRLTRLAAGALDPLELDGNLYFAGYRAAGWDLARASPFEYTAICLSNASGAVISSIFSARSNRVTMSSTESDCSA
->MGYP000975471581 FL=0
-MSNYVINHLRELESEAIFVIREIAAQFENPVLLFSGGKDSILLTHLAKKAFYPAKIPFPLIHVDTGHNFPETIAFRDMLVKELGVQLIVGSVQESIDKGRAKEETGADASRNALQIVSLLDTLEENKVDAAMGGARRDEEKARAKERFFSHRDEFGQ
->MGYP002779293856 FL=0
-YHWLTETIKRNSMKYKRVLLKLSGEALMGNQGYGIDTTVLTTYAQEIKNVVDKGVEVAVVIGGGNIYRGIEATATGIDRVQGDYM
->MGYP001768057102 FL=0
-ISEHDALLATHVATILSGGDRSPGVASEQDFLDLEREAFLSLLGTQKTKERIQHMLKSGRPLRN
->MGYP000742296790 FL=0
-MKTRNDTNFTSTKKFLPLFVAIIITAIFLSNCVPIEQPKPEAPMAVTEPAPEPR
->MGYP003387108590 FL=0
-QLAKAEGLRVIADSSTEDKELVTELGADVVVPRGDNISEQIRNIMPEGVDGLADGSVQNELSVGAIREGGSFASVRYWEGTGERDIKFHRTSVSDYFQRSDLLDQLSKQVDDGILTLRVAETFSAEQATEAHKKLEAGGTRGRCVILL
->MGYP001556444362 FL=0
-MKLKIQQIKNPLLFIGLLLGLVFMVTSCQKETNEPDQAFHKAKKGPQKEEIVVVANRLDGSISFIDAISDQVQNTLSIAGSEPMYVVYVPDNDRLYVGDRAQDKVHVIDPATRQVESSIDVGNGVFHMWAGGNGDQLWVNNDQDETTSVIDLSTNTVIQTISIVLK
->MGYP002617661281 FL=0
-GRGGVAGHDDHLASLRDEAGDGLVGEDVTENLKTIRSIPMTLEGAPARLIVRGEVFMPRASFARLNEAREAAGKSLFANPRNAAAGSIRQLDTSVTASRPLRFLAYGFGDVRFGGVQPWSTYEEVMGRLRDFGFETPPGGRLCRGSEEVEAYYASLSEKRESLAYEIDGVVMKLNDLEAQEALGYTARAPRFAVAWKFPAQQATTLLLDITVQVGRTGVLTPVAELEPVNVGGVLVSRATLHNEDEIRNRDVRIGDRVVVQRAGDVIPEVVRAVLSERAPDSQ
->MGYP000022545691 FL=0
-IAQKGGIIMDGRDIGTVVLPQANLKIFLVASVDERAERRYKENLSKGIPTDLERLKVEIAERDRKDSTRVVSPLKQAEDAILLDSTGKTIKEIVQFIEEKAKKLMENEFFYIFLYYKSFASFCRNYQTLI
->MGYP000539356882 FL=0
-PPAWAVYIPIETPNTRSGETATAANADDAGYIDANKKCHWYSQENTGNAVANVKGAWFTYIVFFNGVHITNNTDPAIWNTGAAGTGTNGTSGRAVLTLKLIHQDPREYVLQLNGVDLKATDNYSVMRMTYVQPNFNNMPSSPYTIGSSSYEEFRHHNESQAAFTLPAAGYWISADEVSYSFWEEISGDATLDATITQHLQDDLITGFRNNYIGLNQPITYMSYDEVTAFCSGQLSAKIGTTARLPNEAEWEFACRAGKDSTYSNMKGYTLDGISSNPFDAGNNDPVDDNNIKDYYEKVEVYVNGSNTMPCPVPTILSNENQWINGAWESKAFSVFYTIESEIKAIKQMI
->MGYP001030690318 FL=0
-MHVLLDELAEFVRSHRLENEKFHEGAPGAANILLIWRIDVICKNLTFKQVLPSLLILAKVFDQW
->MGYP001004560480 FL=1
-MARKVGFVIGLILLVCLTPMFATGAAETPVTGAGPKVINLWSFTDEVPKMLEKYKELHPEFDYEIKTTIIATTDGAYQPALDQALIAGGADAPDIYCAESAFVLKYTQGDAAQYAATYKDLGIDVDTLLKQADIAQYTIDIGSNERGLVGLGYQATGGAFIYRRSIAKAVWGTDDPAVIKTKVGPGWDKFFEAAAALKAKGYGILSGDGDLWHAVEGASEKGWVVDGKLYLDPDREAFIDMSMELMQKGYHNDTRDWTDAWFADMKDANPKQVFGFFGPAWLINYVMAGNSGGTKPGEGTYGDWAVCEPPVGFFWGGTWLLANKDSKVKDAVADIIEWITLDSSDTGLQYFWANGTLAGPGGTKDTVASGTVMKKSDGSLPFLGGQNMFDVFVPAGQFATGKNKHQYDETINTYWRDQVREYTGGKKSRAQTIADFKQMVADNLAIPVK
->MGYP000510584249 FL=0
-MEVLVENLTFLTWQQVLMWIIGGTLIYFAIVKEMEPSLLLPMGFGAILVNLPNSGAAGVIAHLFQLGIAGHELFPLLLFIGIGAMIDFQPLLANPKLMIFGAAAQFGIFFTLGLASLLGFELNDAASIAIIGAADGPTSIFVANVLKSHYTAAIIVAAYSYMALVPIVQPFCIRLITTKKERMIRMEYTPGKITKTTR
->MGYP001059407761 FL=0
-NGTQAKDEGALPLTAAQSATLKQGLKLVTGPNGTAASAFANLGYNDFLGKSGTAEDSGEQSHVDFVAAAPAETPTVLCTVFLDHGTSGSTQAGPIARDIVLAALAEGL
->MGYP002518956829 FL=0
-MVSWNNLDTLASYKELSEVARVNLAEAMTGENGAERVKKYSVPMAAGMAFNYAAKQVDDNVLAVLAKLADEMQLVEKFQALYNGEVINTGEKRMVLHHMTRGQLGEAVTADGGDKRAFYLNEQKKIAEFANKVHNGEITNVQFGLYADADMIADDGKVIPKGALLETAYCDKDGNIIKSGKCDPWIIKELYPTENGYMTKVVGSNVALDLIILPSLKNSLPLCQTEVTPTVDTSTACPLVKSII
->MGYP001810087265 FL=0
-IMRRCSQTADLLNAALSGSHGXCPGREFLCTLHRCGFKWXDVQTDAVCRHTCFRRLWVGCVCMLCVCVXGXGXVSXEGVVIGVWLAGTGALCVCLXRCGFLLX
->MGYP000952481259 FL=0
-FELESHFVAQAGQQTDSVSKNKTKQNKNKKQN
->MGYP000924557708 FL=0
-WRTDHQSFAENGVNRWLRTWPGNELTKTNIAFYWFRGLHLSMDYVPDVAIRQPDHAERIHQALMQSPHEAPMPEAVQAQFAQLAADNRAREPWIARLWVPLVHLQTMLMQASAYPEVARLLDRVAPGLGQIVLALLRAGILVGLLLLVLHWRRLRLWDQQVRLARGFINALAGDCEVIRVQFNSRPVTAHALASDKG
->MGYP003568761090 FL=1
-MSRLDSMLRRFTAQRDGLNWAASFIEGMEGDALDMGLGNGRTYDHMREIMPDRRLWVMDRILQCHPSCVPPEEDFLQGEAEDGLAGLKEMGAKIVISHYDFGFGVKEKDVEEAARFSPLIAEVMAPNGVIVSGQPLIGFEAVKGPDHIAPDRYYFYRT
->MGYP000894995155 FL=0
-TLPLFGGCTGQDGDKGQSNAKTAGKDSPLVTIRWFQEARGQDPNKDRILQEIQNKLNIKLEFVAAPAGQESEKLNLMVSTGEQLELVTAFDIDRAAIQWAKDDFIYAYDEFMESGDYPRIKAILDSDVYKDLKVNGKSYFKPQPLWPGLRGYVIRKDWLDNLGLEIPTTIDEYYNVLRAFRYDDPDNNGKEDT
->MGYP001069368337 FL=0
-PALGGGEQALEDRPIVDALDKAEIPATIVIAFEIVVIELRADAPDRPAIADRQPIGDLGMIEIRIGFRIEMVAPLKHQRRDPMGVIGVDVERDSDEAVYTGTVADLLDAEISHRQRHRSLRRAQSTAL
->MGYP001036930292 FL=1
-MRCIFLFVFLISHLVMPFLFFLLYFCFLTLCYDSNSK
->MGYP000703538265 FL=0
-MLSYPVNVAGLEKLDIGFAAYTRYVAPLLEEALKGLIIVALLRSHRIGFLVDAAIFGFAVGAGFAIFENLFYLQALPQTQMGTWIVRGFGTAIMHGGATAIFAIVSHTLIEQERSFALLPGFAGDVIKTVQAMPGVARPTATDPGAVVVRGSGNYDTRFFVDGIDLLVVVLANEITALSGGQPHPGTAHDTQGRRRKPVDLYALAQAALGNGLFAVLLWLLLDPKLWYTDGVSPDPVATTESPEDPAVAAPSGDAADKSAKAESVRPHDVLRSAGRLLAALILVATALGYVRLANFVFHRGVLLAAFLISVWSVRVLAAWGLSRLPAAKPPGAHA
->MGYP001563729933 FL=0
-MVERNLLREGFVVNTRTPLGTISGTQVVTPQEIDRLADSDIATTALIASGTKLLSLDADLGARFKISRLELYTAE
->MGYP000417054785 FL=1
-MTTAEASGKNFGSLKITFKYPCDFYISGHHVVITIVFEYHGDIEELLSHNPNYD
->MGYP003967751787 FL=1
-MIYEKYNNMIQQLVMFNCTSVIIINELTQSNTDYYIGLCIKILTIFLIILYKI
->MGYP000178255560 FL=0
-MIKKTIKYVDFNGVERTEDHYFNLTKAEITEMQLGVKGGLDKYIEEKVYENDTE
->MGYP000422954699 FL=0
-MSARGLWIKSLEAILLVVLCFVIFAPMLGLLLWSIAIRWYWPHVLPQQVGLDYWKQALGFERSLAIGAVSITDAFNTSVLIALIVVAIVMVIATPVGYVLAR
->MGYP000957065041 FL=0
-MKNDVNKSLERRFSTVQLYSQSEDFELSISGEEGTYYKFRSEDLLYVTKK
->MGYP001611453920 FL=1
-MMLFHISGVLAEANPDSNPESVPAATTGARRINQSPTSQNDFMSSLANASEPSG
->MGYP003568452137 FL=0
-MDDGFRRCQAATFKMSCFEFSHSNTDEKEIHIFIWTEKRKSYN
->MGYP001429666462 FL=0
-FTQRAFRVTIRLVTDTPGMRAWVKLSGDDLVTGGNIGRPMADALLDEHDRRVEAGTLYGFQPFVTLVAERV
->MGYP001129982810 FL=0
-LYDKENRREVFKSGQKGTLMRMYEDKPIYYDNWDVDLFHMLKHEEAAADGAPELIAEGALRVTLRFHYTYRHSTFEQDVIFHAGSRRIDFETRADWHETHRLLKAAFPLDIRTTKATYDIQYGHVERPTHFNTSWDYARFEVVAHKWADMSEEGYGVSVLNNCKYGHSAHDNVLRITLLKSGKYPDTEADMGRHEFTDALLPHAGSVVEGDTIEESVKLNLPLHKAEGMLWAAAPLVETGSRSVIVDAVKKAEDDGCLVVRIHECRG
->MGYP000615634015 FL=1
-VKLEANTSDGYKDESYSVDGNILEVVNGSVLSISNNGYNGYNYGKPSEIGKDTALGRKDRLADFHNALVLFFGEDIGKELYQEVKNSSAYAICRVNQTAISEEEKFDVYCQTVFAYSDPKMDCPEDFSSFLYKANTKRKNLNSLRAALQGHYGKDKGMKYYSLFKSHIKIMNRM
->MGYP001275058744 FL=1
-MSEMTPREIVEELDKHIIGQAQAKRAVAIALRNRWRRRQVPDEFLRSEITPKNILMIGPTGVGKTEIARRLARLARAPFIKVEATKFTEVGYVGREVDSIVRDLVDMAIKMTREEALERVRPRAEDAAEERLLDLLLPPARGSSAPDQETAPTNEEGAGRQRLRKLLREGTLDEKEVEVEVASPTVGVEIMGPPGMEQMTDQLQGMFQNLGGQRKITRKVRVREALRLLTEEEASTLVNDDDLKHEALERVEQDGIVFLDEIDKIVGHSERQGGDVSREGVQRDLLPLIEGCTVSTRSGMVKTDHILFIASGAFQLNKPSDLIPELQGRLPIRVELDALGTTDFVRILTEPDASLTEQYAGLMNTEGVTLEFDPAGIDRIAQVAWQVNEQTENIGARRLHTVMERLLEGVSFEAADRSGQHVVVDQDYVDGQLVGLAEDEDLSRYIL
->MGYP000812623567 FL=1
-MKRKVTLRKKQVLAIAVAVIAVIGAIAAWQTWGATTRIAFLNFQVTELGQISKANDNSMIELCEISADDIADLDSYDMVMVTAMGLKLTEEQRAMLKEKAEKVAVYTRMATNPDNYICSVDSVDADFISQYLDNGGRTNYRSMLAYIRKFIDGKKLNAPEPELVKERPDCLLTHYDPSDVDGEELGFNSVAEYNAFLAKHGLYSEGSPQVMLTGFMGATDDMTRALEKKGMTVYRVNKPQLFIGGKHADSIHVAAVVNMAHGRMGDYMVEFLKMKNVPLFSPVNVNRLVDEWLDDKQGMSGGFMSQSIVTPEIDGAIRPFVVFGHRTNDDGLRETYGIPGRMDDFVETVSRYITLQKKSNAQKRIAVYYFKGPGQNSLTASGMEVIPSLYNFLCQLRSEGYNVSGLPATVKEFESMIMAQGAVFGTYAEGAYANFIKTQHPALVTAAQYSEWTGKALSTQQIKEMNEINGEFPGKYMATADGRLAVARLQFGNVMLLPQVIAGAGDDSFKIIHGTNVAPPHTYIASYLYARYAFNADALIHFGTHGSLEYTPRKQAALDSNDWPDRLIGTLPHYYVYTIGNVGEAMIAKRRTYAQIQSYLTPPFRESELRNTYRQLNDAIDSYNKAPNAAAAQKVKQLTDKMEIAAELGLSKKAAYTADDIQRVESFAEELANEKITGQLYTMGEAYSQADIRTSVFAMTTDPIAFGLLGIDKLKGRADGNAEKHKQTFNRQYVEKAKAIVTRLMAAGGNMTDEEICRTAGITAAELKMAREVEAMQAAPDPIMMMMQMAEKMGAKSGKPQMQASQKKLTVSELRKMRLPRHGKIPQLSKAVFDKMEQSGRFPEKMMTAIRNEQKWYKESLKKGAKKPAAKKANAPRFSRSEIRLAQAITAVEHALKNVKAYSDALAESPRMEMASMINALNGGYTAPTPGGDPIVNPNALPTGRNLYSINVENTPTEDAWDKAKELCDNTIKMYRERHNGEYPRKVSYTLWSSEFIETGGATIAQVLYMLGVEPVRDAFGRVADIRLIPSSQLGRPRIDVVVQTSGQLRDLAASRLFLVNRAIAMAANANDDKYDNLVKAGVTESERLLVEKGMSPKEAREVSMFRVFGGVNGNYGTGIQSMVTAGDRWDKESQIAEVYLNNMGAYYGDDKNWESVRKDAFEAALTRTDVVVQPRQSNTWGALSLDHVYEFMGGVNLAVRNVTGKDPDAYLADYRNHQNMRMQEVKEAIGVESRTTIFNPAYIREKMKGGASSAGTFAEIVTNTYGWNVMKPKAIDQHIWNEIYNVYVKDKHNLGTKEFFEKQSPAALEEMTAVMMETIRKGMWKATPQQTADIARLHVEMVNKHKPSCSGFVCDNAKLRQFIASKTDAASAREYQANVENIRQEQLADGKKSTVMKKETLNDDSNKTKAVVSGVLVAAIAIVAVIAIVVLIRRRRKNLN
->MGYP001306074617 FL=0
-DIMRTKELQNGVLWNPETGQKVEQIEKGLHVVVLARRRRDRPARLPRIVETSIHV
->MGYP001598923031 FL=1
-MVNAITQVGNVMGIMSVAVLVESRVVLDTLVAIGF
->MGYP000619228673 FL=1
-MYMHFLHSWIFVCYRAMFVCIFLHLDCLSFFHSFQSIFKNLTISSPLC
->MGYP003648209433 FL=0
-GFQIVGIPLIDGGFGFELHWHQRSVDLFLGLPFNIASYAALGLILEKITGYKCIAVQGDLKNVYLYENSYSSAAEIMKRGVEVIS
->MGYP002561378225 FL=1
-MMDSPKHEAYENGGTIVNRYARIAIAVLASVGLLTSASACGTSQDGAGSAHGAIPVVSSINQWGTLAEQLGGSGVQVTSIINSTNVDAHDYEPTTSDIAKLQKARIVIVNGAGYDSWAVKAAQSAKSQVINAAEIGGVKDGGNPHVWFSAAVRKAVAQAITRAYEGTRPDGKADFDKLNQQWRSKEDEVARKITETKRKADGEAYAATESVAEYLAGDLGLKDATPTGYMRATANESEPTPTDIKQFTDMLEAGKVGLLVVNIQEETELTGKIVTVAKSSNIPIVELTEQMPEQYDSLTDWMAALVDAFSQAI
->MGYP000499357948 FL=0
-MRLFSDFFQPSIYIFLLLNKNALNGCPKIPNFYEKIAEYYDRHSAAKKNIFTTFHLLNQFYYQKNILERILAD
->MGYP001675491746 FL=1
-MTHEYTIFEIKARGVGRNKTTCYSIFMSEKRSDNIKKQRQRTKPKRLSVKQYMFIAVVLVLLITTVGIFGIIRYSDTRRLDVAYYGVPESIATAINAVLENPDNATVQKKYSRLRIVQLAESDIRNTKRIAKKYDLLFMWNGANAANAAEKAVVLPESVYNLFPASVRHTGKVNNVPKMLPLLLDHYELACYRTYRNNAGLALPETFNELESYLHTIKGYADYPLICAGKTDATLTAFISAFTESLAGSEGYATLVKAAAGADCLSDVLDVSLGKNISLASILGIIKQWQHEGLIHPQWYNVTEKDIESYMEEHRLGAIFMPLSEHRVKPLILIKYYDTVQFPKGDVANHALIAPVLVGMAFRNDASQLAVLEHFAHTDLQMLLSQHSKLAPASARAEAHDVQADDVRFWAASCTDGPVPELGKAAFASPVKTAAFAEEIRAYMAFTQE
->MGYP000328593210 FL=0
-MVPVIALVGRPNVGKSTLFNRLTKSRDAIVAEYAGLTRDRQYGEARWQGRTYIVIDTGGISGDEEGIDAKMAEQSLQAIEEADAVLFLVDSRAGMTAADQMIAEHLRKRNKRSFLIANKVDTIDPDLARAEFSPLGLGDALPIAAAHGRGINHMLQEALGIFPKDNAEEEGEGEPASEEVAEGEEPTRIPGPSEKDGIKIAIIGRPNVGKSTLVNRMLGEERVIVYDQAGTTRDSIYIPFERNEEKYTLIDTAGVRRRGKIFEAVEKFSVVKTLQAIQDANVVIFVMDAREGVVEHDLNLLGFVLETGRALVIALNKWDGMEAAERDYVKTELERRLLFVDFADIHFISALHGTGVGHLYKSVQESFRSAVTRWPTSRLTSILEDAVQVHQPPMVNGRRIKLRYAHLGGANPPLIVIHGNQVDAVPKAYTRYLEKTYRRVLKLVGTPIRIEYKGGENPYEGKKNSLTARQVNKKRRLMSHHKKAEKKKKKDKRR
->MGYP000632763877 FL=1
-MASEDGCGGGNRRVVEPEARISRFAEPVVEVEFVDVGDLVEAHAHDPDEDEDPDGGHDHAEAETEIGYSERVSLFIPTGDW
->MGYP003625842865 FL=1
-MKSLFDFIIQPLGGKYDNEITIGDKKLILNNKIESFKSVNNLAIVIETPKAYKTPIKKGDIIVIHHNVFRTFYDMKGKKKKSRGFFHDNLYFCQIDQIYLYKKNQQWKSFGDRCFIMPLKNDNYLTADKERKLIGIVKISNSSLEAAGINTGDLVGYTPNGEWEFIIDDQRLYCMKSNDIVIKYEYEGNEVEYNPSWAHSVCLYII
->MGYP003126176265 FL=0
-MATIITADRVSGSFTSTGSLGQLSLGGTSTSGSIQPSSSLHIQGNNAEGGIHMFRDAFPGAYGMRMYLVDSGADGQYLRFDSQRNLNWTEVLRIGNGGNTSNQTLQLVTGNLSGSVESTASFGALRVESEEDGTTITTDRFGLTIDGQAGYYPLTVQSPYETAARFISTDGTANIEIGDNSSTTNYNRIQVVGDTRLQIIQNNVDKVRFNQNTTIFNENSNDINFRVESNNDQHMLFIDAGKDKISIGSDIFGDDKMLVAGNVGITGSLHVSGNISTSGSIIAKEFRTEFVNQIIATSSGSTEFGDSIDDTHDFTGSIEVSGTLNIPTGSITVEGGIGGANIARFSRNQGTT
->MGYP001636533327 FL=0
-AAAAVLVLLAAGLLAAVVVPEDPGAGKAGGLAGLAFQGQAMDTVL
->MGYP000052352460 FL=0
-IDKQFRLLELILFYYETAGEALRKGAPMQPVFDIPARTDWVLLNANYYVREFFALGKTLLFD
->MGYP001423369931 FL=1
-SMIAKLIVTADDRPRAVARLSRALSEFVVEGIRTNLPFHRRVVEHPDYLSGNLDTHFVERLLGPQAT
->MGYP000606642193 FL=1
-MDPILLAIIVVTVIGLIGAVILVAASIFMYVPVDERVEQITAVLAGANCGACGCAGCADYAKSIVEDGNAVNKCTPGGAACAAKVAAIMGVEAGSSTPMKAVVACSGTCGKTGKKYEFQGIQSCQAVKGLYGGDGLCKFGCLGYGDCTRACAFDAIHIVDGIAKVDRSKCTGCGACAAVCPNAVISIVPEHKRKPVVLCQNKDKGADTRKACTAGCIGCMKCAKACPKEAITVENFLAKIDQDKCVGCQLCVKECPMGVIHVPASE
->MGYP001134501289 FL=1
-MFFAVLAVQIYLLKTTTTRDHQNITEFTFMIHHVCMNKPMVTCTLDELDVDFLLYPLSIPNSAKKFEDFGGATCPLIWLSSELLPVLAAGAFSTYSNREVQDLLLVIVLSVTDGRTGAGSSGFCS
->MGYP002743407678 FL=0
-MAKIFDDLGYNWKFKVLNSKEYGIPQNRERVFVVGFRNDLNINDFNFPNKLELNKTMQDFLLDSVSGKYYLAKKGVEFVTSKKNIDKRYTQIDGEIQLCQKKNQQFNWHGDFIFQAAREFEFDDFIFDVNSVEEKYYLSEKIKNYVLAGGTKNFKTSTETDLPVARPLLQTMHKMHRAGVDNYVTHNRGRIRKLTPRECLRLMGFRDDFKILVSDTQMYRQAGNSIVVD
->MGYP000205383798 FL=1
-IHAIEAHHGVAEDAHAGDWHRQVSLLAWESIEKARARGLELGGLDVSLESWKEVLEAMARLPE
->MGYP000432900193 FL=1
-LIPMDIIEEMAELGVFGLTIPEEYGGLGLGALELCVVAEELGRAAAPVPFSSSVYLGTEAIVKYGTNSQKEKWLPKLSSGELISTFALPETNSEPTEKNIKTTFSNGKINGKKLPVADGSYADISIVVVKNTDNDDIALAIAELTSENVKRKQISTLDPSRDHAEIIFENSEAEIMDIGDEGWGAVDSILNSAAVLMAFEQIGGAEASLNMAKEYALDRYAFGRQIGSYQAIKHKLADMYIAVELARSNCYYGAWALSCLLYTSPSPRDS
->MGYP000580577341 FL=0
-MKIVPLTLESMWPSAALLSANKEASRENFLKFLEGGFKATQLKFKNMGPSFKNLKMWMDHLRTGVQDQAGQHGETPPLLKIQELARCGGR
->MGYP001331097511 FL=1
-LNLNSARQLSFQGDVAGAQKEILNQVRQMGDFNKMNVFQQEALAKATGYSAVELTKMLKNEEKLAQLSDKEKASYEKALEAMKEQNEETGKDLLMKTQMQSAMAQLNNTYEAFKQILADILTPVVNVAVKLLIPALKLALLVFNLILIPVKVLANALYKLFEPLEPVVQSISDAFDGINSKIEEAVQF
->MGYP000153268017 FL=0
-MIVSCLYCGYVAPIHRVMKRQARALACLALAATVVGFMLRGAALTGGIDGMVDPEMLGLLWQTSVGDVLVYRLIGAVMILVGLSPALGTFLAGVVLANSEFRHELESDIAPFKGLLLGLFFITVGAGINFAVFFRDPFELLGFTLLLMGGKGMVLYLLALIFRMKGRDKWLFTLGLAQAGEFGFVLISFSLQQNVLGAALGERLLLVVALSMLLTPLFFIAYERFQHRMSGDTSDAPEADQIDEKQKIIIAGIGRFGQVVNRLLMLAGFRAVVLDHNLEAI
->MGYP000930301694 FL=1
-MADDVIPDVIGGAIPVTVIGGYLGSGKTTLLNALLRGGHGRRLAVLVNDFGSINIDADLITAHGGDTISLANGCICCSLQDNLGTTLHSLAARSDPPDQIVIEASGVANPSRIGHYAMSLPGLHLDAVIVVADAEGIRRQARDKYVGDVVLQQLAAADLLVLTKTDLVAPQVVQEVRQWLETQVPCVPCVERGNDQVPPALILGLRSELAGPDHGLGCDHEPYEHVHGEEPHDHRFAQVTFTTEEPLDRGALVAAIDALPPGVVRAKGIFYLADALGEQVILQMAGRRREWQTGEPWGDERPYSRLVLIGPRALVDEESLHARLSVLLTPTIE
->MGYP001478987189 FL=0
-MRMRRGVIFAALAFFLSAGAFAQDKRPDPKFFIYLCFGQR
->MGYP001414076324 FL=1
-MLDDFFTRAVIGGIGVALVAGPIGCFIIWRRLAYFGDTLSHSALLGIALALLLEVNITLTVFLISVMISFLLLLLQRRAVLSSDALLGLLAHSTLAIGLVVLAFMTWVRVDLMGFLFGDILAITSYDLVIIWGGGVIVLIVLSFIWQPLFAATVSYDLATAEGVRPEIINMIFMVILAGVIAVSMKLVGVLLITALLIMPAATARRFSTSPEWMAVIAAAVGAGSVLIGLNGSLKWDTPAGPSIVVAALVCFLFSLLPFPNFLGKKHK
->MGYP000072544056 FL=0
-MAIPMTTGNIFSSCTDDFEKLNTSNIQVDPADLPFAAQCTEPMTYCYPPQQNMFQFWTNLTIDLYGGYFMTPNGNFTNGDMGENRGHSGGMYENYYLHIFNNTRRIIAQCDASGERGLSGVMRIVQAYGTLMTTDAYGPIPYSSILSGENEVYFEFDSQKDLYKAMLEDLSTAITDISAMGADEIAKLKSFDCWCNGDKDLWVKIANTMKLRMALRLSKRETEAGNAGMNLKAIATEAAQNTLATVNKDILIDKSLENEMWLMFNWGDCGFNANLVTIMSGTKDQRQPLYMTPVS
->MGYP002856813101 FL=1
-MSLNLMYITNKPAVAKIAEEVGVDWIFLDMEFIGKDSRQGGLDTVQNHHTVEDIKNIRKAITKAKLLVRVNPIHEALTDYPSSKDEIDAAIQAGADILMLPFFKTVKEEGQFIRFVGGRAKTLLLLETVEAANLIDDILKVPGIDMIHLGLNDLHLEMGMKFMFQLLADGTVDKLGDKIKAKGIPFGFGGLATLDGGALPGSMVLKEHYRTGSSMVIVSRSFCNTDIVTDLDEVRHIFETGIAAIRDLESKVQHESKEYFEKNHREVVAAVNQIVKNIEAKEHGNQ
->MGYP003291001117 FL=0
-RSRRPATSNARTGAPMRTIWALCAAAACVVALAATQTTEFPLLIVLMAVLTMVVSWL
->MGYP002777180191 FL=0
-VRVIVVGTALPTWAAGADVVLPITTMAEEEGTFTNLRGRVQRYLQAKPAPGLARPSWFAAGDLLAAAGEGQGFFTASEAFDAMAAQHPKFAGLSYARLGLRGLPVIEAEPAGELAGVGA
->MGYP003430828053 FL=0
-WLNDLLYTHSENPPLEFIENVKGDLAQDALYVFTPKNELIRLPAGSTPVDFSYAIHTNLGNRTVAAKVDGQFVPLASPLTHGQTISIVTNPNATPNPAWLSFIKTPRARQAIRDQLKTLREDEARKLGKRVLTLAMSSVGLSSQRIKKSQLAKTLNQWGEPSLDSLYTSIGLGQKLAPVVARQLLPQDDAHSDRETLPLVLDGSETQVVEYAKCCKPLPGDPIVGHMSAGRGLVIHRKQCTQIGQKRHKNMPPPQKQDGNWLSVTWGGQV
->MGYP003343356212 FL=1
-MKVSIDKSVGGLQQGLTFLASTGATAPFIGLFCTVWGIYHALISISTSGSAQIDQVAGPIGEALIMTALGLAVAIPAVLGFNAINRANKLLVADLNRFGNDLLAYFVTGARVHSGE
->MGYP002238360443 FL=1
-MSQQELASMVGVSYRTIRSWEVEGRFPKQNVLYQKLADALQCDVSYLMSENEAFITEASEQFGNRGARQAQQILEQAAAMFAGGSLTDEDKIAFMDEIQSLILGFPKDVQRKFTP
->MGYP003335923377 FL=0
-DSCCRGCFSFVSALFNLVASGCLSGRFSLVSSCFARPSRFFRMSFWGNGDHSLVARGXSTQFPGGYILHDKGTPLQTRTVRRVLQILGRSPEMELCLCLREKRESSCHTSDAQKCEVHAXRRGWRERQLHLWSTPXAEPMDTACAPGRTQQDSMLHSAGGLLLRPRAKPACTRPAESAADPTVLPSVFPWRPWTDIPLTX
->MGYP003595024705 FL=0
-HPWFVATQYHPEFKSQPLAPHPLFSAFVAAALRHAGERP
->MGYP001183065379 FL=1
-MNDHQNITGIYPGTFDPVTFGHLDIVERACNIVDKLIQNHKIAWICGAFVAAMNNYLCSKYLLFDD
->MGYP001772517118 FL=1
-MSTYIRAVVAAMAIEEKYGIPLGDLVDTFADIPAADVVEVVHGRWVFGKDLADSFGSINKNKYHLYCSECRNQAFNKTVDNDPDFDVDTPFCPWCGAKMDKEVIL
->MGYP000932959631 FL=0
-MAELLKVEKLWAGYGEAVVLEDIAFSLQEGDSLALLGRNGVGKTPLLSTLMGAARHRSGTIQFAGRDQDRIAVGIFE
->MGYP001710201224 FL=0
-MEKELDLLIATEMSGDGDSVAEELRSVFAKRGVTVHRIEFRSGKDSVIRSVRANPQIHAVVLSQYQDQEKLSPRDIDQICSTAEGDLQVFVVVSEMRGSDYMKEIESLGIYTAVYQEDASFEKIADCEAIRPDIAGIMGAFGAALIAREHYEDGYVTTMLDYQKICELQFETSMAKCKGCTNNCRLTINKFSGGRQFISGNRCERGIGGQKNAHNVPNLYEYKLHRLFSYESLDADKAPRGVVGIPRVLNMYEDYPFWFTFFTELGYRVVLSPSSNRKIYELGIESIPSESECYPAKLAHGHVTWLIRQGIKFIFYPALFYERNEFEDANNHYNCPIVTSYSENIKNNVEEIAGGEITFRNPFMSFRDLGTVTDALTKEFTEIPAGEIAAACEKGWQELANARHDMEKKGEETLEYLRQTGKRGIVLAGRPYHVDPEINHGIPELITSYDMAVLTEDSISHLAKPERPLIVSDQWMYHSRLYAAASYVKT
->MGYP002084656506 FL=0
-LLGFVDVVGGEDDGHARVAQRAHHAPHVLAQLDVDARRRLVEKQDARLVRQRLGDQEAALHAARQSEDLAVLLVPQREVFQHLLDVGRVRALAEQAERIDLAVVSANFFEVFGARAAQGRLFSSADEQAGHAPVVVLSHAFWERRLGADNAARVAELVGANASFELCETLKDLANLPRVVQAKRN
->MGYP003719918597 FL=0
-LGLTVSGPLEPEPGPALDKIVTFVPVGPSIAAVHTALSDAGAGAIGNYSHCSFATAGTGQFLPLDGAAPVIGSVGRLERVAETRLEMVLPRSRRRDVVAALRAAHPYEEPAFDLLEMAPLPSSLGLGRVGELAALGQQRHAVQQLDGAALVLPRGAGVAQPGDQRMRRVX
->MGYP003357866643 FL=0
-FVLQMIWKNKSQQSFSRLFYHSTGLLAPGGWNGAFRSIYPTLLCITISGAATLYGSIQKFVPTTWVEFYFHPTINPFSLEPAHLGSFYNQRLVYLYYLVHGSYRFVASWTVSTSSYSFYRTCLHLCDSLSNLYHHCSKLCRLSSPLDLLDLCYFAVSQSTLYNTVLWQLRSRNTSARNLPILWRNQQIVAHSR
->MGYP001703284989 FL=0
-SNLETACCQIVSCSLXNXXXFYIHLGXGNKKQFIKIRIFRNSFWXFFFYIYKRFNFKIXRYNPNRQNRVYKXVDVLX
->MGYP000305843427 FL=1
-MAQIIVLGAGTGGVPAAYELKSALGSDHQVTLVNASSRFQFVPSNPWVAVGWRKPDDTSLDLT
->MGYP003518858476 FL=1
-MILAGITLFNPDVARLEENISSIYGQVDRVICVDNGSDNIKSIEDCVLKNWKNITIINIERLKSGQF
->MGYP000766296581 FL=1
-MVCSIEKVSLRHERRVSRLAEDYVIEMLHITKEFPGIKANDDITLQLRKGEVHALLGENGAGKSTLMSVLFGPVSYTHLTLPTILR
->MGYP000585817851 FL=0
-AVLVAFDTAEEFEAYQEGIEDAFLIALNGLFETSESVCNRDFRFVESVQAKLGVDVNQDYFDRRLQEDSLTTSNPSERPLNEPISFQATVEPANQEPTTNPSISLGPSTSHQPTFEPTYAFSSSLNAILFVSGICNGCENSIIWTNQINGRARHLGGEDDQPQNWSPRRSLEEEQAESSCFCPISAIVQDVALVASDVEQQFQSQLSRSS
->MGYP000583006313 FL=0
-MTGQRFSNKQVRDMERLAHLTSALLVAV
->MGYP001048952483 FL=1
-MKRNRILIVEDEQKLARTMGDFLRFQGYETCRAANGREALAIFYRERKTLDLILLDVMMPDISGYEGLKEIRKTSNIPVIMLTARSSVEDQMSGFEKGADDYITKPYTLELVKLHIEAVLKRSGKLAKVLEYQDISINVEAQKVYWKGNYIETTRKEYELLVYFIENSGIVLARNKILDAVWGYDYVGDIRTVDTLVKQLRKKLTEECTYIKSVYGVGYLFGEGGYEE
->MGYP000370032573 FL=0
-TATTEIYTLSLHDALPISARFWYAAASMKSHLSGGKALTAQKY
->MGYP003323358317 FL=1
-MASIRSRNGRYQVQVRRADLGSRSRTFVLKQDAERWARKMEAQFDQGELQQLRTKDVVLHDLIDRYRREIAPAKKSRDTEGVRLARLMRDPIASLSVGKLTAHELALFRDRRIKDGIRTCQYDLVLIRHILEIARKEWNLGLAVNPVDQIRKPNGLRPRNRRLEPHEETLLLDGCSKSSVTHLKPIITLALETAMRRGEILAIQWGDINESLRILSIPVTKNGRLGHPTIKYGPDDSPGDSKGHF
->MGYP003316122480 FL=0
-PKVTRLTHPHRRHLAAARLDVHHRGELRVGLGGERRGDAHALDAGLGGGHGRAVIVLARWRCWRRIAQAVRAARGVTIFAREVRQLGELKGNSAQLPADA
->MGYP004316249655 FL=0
-MIRNDTLRLYNQRLTSGDKMSTNPDEWKDNLIRQLAEMFKGMNMPFDENMIRQMMEQFSEQFEEMGIDPEKLGSVDMKVDMKNFAKAFSGGADMTEIFSNFGFNVEVNSPPVEVEVDGTPNSSKNEIMKLPEADWYLDGWNMCLTVDCNNSLSSDDEKVNLSIVNNGGLLEISLENAPQPFARIELPHPCESVEEIEINNGIVDVILKLMPQGSALDDEDD
->MGYP002631629027 FL=0
-KPEITLNMTDGSNNRFAKIYYLDNATTSFDNGYDGETFGGIANTTDVFTHLVANSEGKKYQVQSLPNSDFENMIVPVGIKAAAGKEITFSAEAINLPDGIKVYLEDRTANSVTLLSEANATYKVTLGESLDGIGRFYLHTKASGVLSTSEVALDNISIYSPAKSTLRIAGLTQGKASVKIYSVLGKQVFANTYNTTGVIDMNLPTLATGLYVVQLATEKGTLNKKITLE
->MGYP001549131463 FL=0
-QLARRFCTVTITRMPDHKGRKTMKFILIAPVLANLLFFASIASAEKTILAGGCFWCMEADFEKLEGVSDVISGFTGGTLIDPTYNGNHEGHVEAVQITYDPDTISYQDLLKHYWVNIDPFDARGQFCDKGPSYLSAIFVSNETERGIAEQLKKDVEEQFPDKTVVTPILDASTFYPIKGSEGYHQDYYKKSPFRYKTYRWNCGRDKRLKEIWGDKAVDT
->MGYP001793035123 FL=0
-MRTLWVSAAAGAPLQSNPTTPGTQARGVEDGHRATTAAAGKCHR
->MGYP000255802630 FL=0
-MEEKNISRHPDQSLKQGRKCVTYMYENRPNIWLQIQRDFNMIRAQTPAKVEMDPEEIYILG
->MGYP004001795269 FL=0
-GETIGFWDGDALITWTSNIQGWMSHSGFEFSNKMQTIEIYKSNYDSNGNFSGINHEAIFYDPEALLEPVRIVRDLNKLSSFREGDPIVFTECIQTIFPQNGRGEPVAPGTVIEYKVPDMYGQPWRQIWEEYFEQDMDIPKEDDIFSF
->MGYP000644120371 FL=1
-MKKRTPWKLIPLKSVPIFILLLLSLGGTQAFSFSPTVVLGGRLDQVFSPQSAALWGDMYGFGSWRTTLGSEAYAVFNADSSFSLPLDQQAASVDQHSLSAQVGLSLPRGSLLLSSETFFSIKDPLYGLTMLPDWRGRYGIALDQKSTKKAYVGYSGSYLYQEKGTEDRLSQSTAIGFIYEPSFTRSYRFELNGSLDDLRQRETSSGQQRRDYGTAGEFEVSGLAGYFMDWSLQILAGARLSNDPTYEASIADLEAQISWGPTRNLNLSALLYGEGLSYWERTTEDGSDELTRIDIGGQVELDWTFNNSLYYTVRLTGAHILSNEPSLASWDISLGLGIEWGF
->MGYP002638041597 FL=0
-KAYRENMPFDQFTIEQLAGDMLPDATEQQRLATAFNRNHRQNGEGGALAAEYFVENVIDRVETTSTVWLGLTTGCARCHDHKYDPISQKEFFQLYGYFNNIGEKGIGNGTKANPLMSIGSPLERAPADHAEKVAALDAAVATAEKDLPARFNKWVTGAHAAAIDPEAVWFSADSVMSNTVAGKKGSLKLLPDSSFRYSGKTTTGVDYNLKLAPG
->MGYP000692869867 FL=0
-MESRTVAQAGVQWRDLRSLQAPPPGFTPFFCLSLPSGWGYRHPPPLPANFFVFLVETGFHHVSQDGLE
->MGYP000986204494 FL=0
-MKRLILVPLALILLKVLAACSSDEEAEPEINQVAYSAMDNYFVGPQYLPAGMTKLTLTNDGQELHHQQLIAIPEGMTADRLLVGMAEGGDAPPPPGVEAAGGASALNPGLAGLVTQNLAAG
->MGYP003576055532 FL=1
-MFRTALMAGVAVLAGVAVGFGAIEASAPVSAAEAIPNFAPDRNTGWVLDRGNHDDLLPDGSRPGPVTFDKAHPYIPNAQAKGRQPTYRVADLSNPILQPWAKEQMKKANDQVLAGKMPFRARELCWPIGVPGFAVFSAVEPTYIFQKRDEVIMINQGGPEIRRIRLNAQHSANPKPSWYGESIGRYENGDTLVIDTIGVTTRTFVDNFRTPHTDKLHTVERYKLVDGGKAIEISIEVDDPGAFTTKWYARQRWNRVQEPLTEIHCNENNEDLFNLYPMPSPKAEKPDF
->MGYP001236546810 FL=0
-MKQAIRVAEAQEIVLQSVQPLGIEKVDLLQALHRLTAEEVIAQRYIPLEDNSAMDGYAVQHHDIATATTERPALLTVLETLPAGKTPHYQVAPGTAIKIMTGAPLPAGAE
->MGYP001162411550 FL=0
-MLSRIVTLKVLLKELLGHTTPIIPLMISWMIFKFSTNFYDGSTDSSKEKLKSLDINVISHPHNLGYGAALKTGIKNAKFDTIVISDIDGSYPPKHIPELIKIYEDSFDLGNGLDMVVGARKGKEYDGSFAKFIFRKLLKFLVEWTTGRTIVDINSGMRVFSKKTVSNFLQQLCNTFSFTTSLTLAYMLNAKFVKYESIEYDARQGNSHVRIFRDSLRTLQYIVEAIIYYNPLKLFLLFFIFFIFISLIFLILSIYIKSILFMMIMASSVIVAFISLFFGFLLDLIRQNSKQK
->MGYP001489463811 FL=1
-MFAGACCRVEKADSVLCGDDQFVSVGHDVAYNIRGQCGRVARFHPVNGKAVGVQVEFVQSSQVCADPHNLLCPVVIDCLELLCEILFLPSSWRYQR
->MGYP001439564737 FL=1
-MSFIIRAARMDDVQALYEMAKRTGGGFTNLPPDRKSLTAKLERASAAFARTGDGIADDLFVFVLENLDSGEVRGTCQIFAQVGQKWPFYSYRIGTLTQHSVELDKTFRAEMLTLTTDLEGSTEVGGLFLHPGERAGGLGMLIARSRYLFIRNHRARFGDRTIAELRGVIDEAGGSPFWDGVAGRFFGMNFQQADEFNAVHGNQFIADLMPKHPVYTAMLPESARSVIGIPHPSGRAAMRMLENEGFAWENYVDIFDGGPTMTARTDQIKSLREAIDSRIVAIDPSLSERSSGETASPAHGQLPPPRAAYDLLDRREDGIAIDPDAARLLAVEPGNEVSHVSRA
->MGYP000479884579 FL=0
-MRLKNPELFRQQCFVAGEWIDAKSGKTFEVYNPATGGSVGHVPVMGRDETRAAIAAAEAAWPAWRQLTARRRSRIVRRWYELIMENQEDLAVIMTVEQGKPLVESRAEIANGANFVEWFAEEAKRVYGDTIPMAQAGKRIVVIKQPIGVCGAITPWNFPSAMITRKAAPALAVGCPVVVKPASRTPFSALALARLAEEAGMPAGVFNVLTGPAVEIGAELTGNPVVRKLSFTGSTEVGKKLMRACASTVKKISLELGGHAPFIVFDDADLDEAVAGAVASKYRNSGQTCVCANRFLVQEGIYQTFADKLIRAVSAGLTVGNGFTEGVNQGPLISLDAVQKVERQIEDALSRGARIGCGGKRIEGNGFFFEPTILLDVTPDALISREETFGPVAPLFSFATEEEAIVMANDTPYGLASYFYSRDVGRIWRVAEELEYGMVSINTGIMSTEAAPFGGVKESGIGREGSKYGIEEYLEIKYLCLGGLDKT
->MGYP001249954087 FL=1
-MRPGFAPDFAEANQDKLMIFGLLRKNNVNAVIVERQYGILTTAARRPEFYLEANVPDTVMGRFEMLSAVLILYFRRTRQSGEAVKTIAQEIVDAFFEDLDHSMRELGIGDNGVPKRMKKLASMFYGRVDSYGTALDANDSQALAAALKRNFHPENSDETLTMERLALYMTEAARALDSVPESVLERGELELPPFNGGAADAAHV
->MGYP001276526933 FL=1
-PQHSDTKGFTTTSVALPDGTAGVQVSMTIVSAGSSILEFAAQADNRTEKMINGAVRKRVS
->MGYP003150834777 FL=0
-MALISRSQHEAFECFENDVLMMAESDEMSGSSDDKTPVERLQVA
->MGYP000526089798 FL=0
-PYAEWIAGYGDPAYAGTVDRAMGIGSEIAETLKTEERLAMTAAFLRSNRLEWMFWDAAWRLEAWPPIHRDAGVPPRQ
->MGYP003495424184 FL=0
-MEQIVANLALMKKNLKQIGYQGEILLESLDYHEGGAYERVTEPDFIREVVEKSGVKLLVDFGHLLMAATNNSLYKPDQ
->MGYP000214496963 FL=0
-QHPNVPEAHYELIPKRAANPMKTDWLHPVRTWRRRRATSVPFPREWDEILARNFPLDARLPERDRKELRKRIQIFIAEKHFEGLGGLKLTDEVRVTVAAQACLLLLHCGEKDYPRLSSILVYPTAYKAREVSRSADGLVTEGEEVRLGEAWNLGAVVLSWHDVQFGAGDYHDGSNLVLHEFAHQLDMENNVANGAPLLPRRSMYVAWARVLGREYEHLRQEVAKHHRTILDRYGATNPAEFFAVATETFFEKPAQLHDRHPELYELLREFYRQDPRSYFTRPPGAGSPGSETAG
->MGYP000694618993 FL=1
-MVSLAFISVHLSAVIGPVGRLHGLAHDLAIRVLGQLLHKLDMARALETAQAIGAEAVDGLVDARVTGCLPLLEHDVGSHGFAPFVVGAGDDGGLEHVGVAVEDVLDLDRGDVLD
->MGYP000858948085 FL=0
-WTRRVPHPVLIGHAASLTSVLLSPLRGAARAGGRTAQARRGPAAQVRGAPGARRPAPPTRDAPRLRPDIGRASGPRRGALTCGVLAEGYHGLGSRTRRLQCPHRHPRCGEVVGEPRRGARRVAAGRRRRRPKWTRSVQLVREGGGGGGGGGEGAGGGGRTLRVGSSPAVHSRQHNQYVFQAA
->MGYP001041972360 FL=0
-HGGDYNPDQWIRTPEIWDEDMRLMKLAGCNAMSTGIFSWSSLEPEEGRFEFGWLDTIMDKLAANDAYAVLATPSGARPAWMSEKYPEVNRVNEAGVRALHRGRHNHCSSSPVYRDKCNIMNSKLAERYRDHPALLVWHLSNEYNAGACHCDYCYAAFEKWLRAKYNDDLDELNHQYWSGFWSHSYSKWNEVRPVDGSVHALMIDWRRFLSDQLIDFCKAEIAPLKKFTPDVPVTTNFMGF
->MGYP000630167433 FL=0
-NFTRKYPTLESGSKVKIFRKKKNFEKERTSTWQNEIHEVISIGTSHGQTFFKLDSLPKEYLHNELLKVS
->MGYP003587511970 FL=1
-MGKILLVDGSSILFRAFFALPHFTTTSNIPTSAVYGFLRMLIRIIKDEKPDYLAVAFDKKAPTFRHIEFKEYKAQRPKMPDELSLQFDIAREILQSFGINYFEIDGFEADDIIATFVERLKGENIKISILSSDFDLSQLIDDNVELISPKKGVTKIEKIDKEKFIQEYGFEPTSVPDYKALTGDPSDNIEGIKGIGEKTATKIIQEFKNVENLLKNEETCKKYGIIGNEEKILQNKSLCVLVRNVPIAFELESLKLRDFKTENVKAILEKYEFKSIVKELGLDKVDFNEESIFNSLPKEIGKEEYRVNLESENTAVVYLISSEKRIDKAILFYNERFYDFDFSSNLFLNPSELDVLKKVLEDETVIKYTNSYKSLLKLGNFLYTFVNNVKLDSTLASYLIDPDQSEFSLKNLAFLLGKDETFNSFSDEVVFLKKNGDYILDFLKKEKLFELYETLEMPLSRVLFEMERKGITVDVKVFKSLKEEVEAELSKLENEIYKLAGLSFNILSPKQLSSVLFDVLGLEAPPDSKGSTGSSTLLEIVNKHPIIPLILKYRHLTKLLNSYIEPIPRLVSKETNKLHTIYHQIGTATGRLRSTNPNLQNLPVKDEWGERIQSGFVVSSPDSVLLSADYSQIELRVLAHLSSDENLIDSFLNNYDIHERTAMEVFNLKKQEVTKDKRNLAKAINFGIIYGISPYGLSKQIGTSKEEAADYIDKYFKKYPKVYEYINVAVEEAKKTGETRTILGRRRLIRGLDDRSAAVRDAARRVAINSPIQGSASDIIKLAMVKIFNDVSDVDILLQIHDELVFELKEALVSEKGEQIRNIMESIVNLKVPLKVDVSFGKNLGTARK
->MGYP001804161484 FL=0
-YWMIGTNSSNLRPPTGEQSREGIMLYFTMKTICTKISCLXQSQMALVHRTXSCNQPLNAMFTFMLLWDFAKKTQPTXSLFFGSIVIFSLAHIGSQIWVEKNFMKNHWPD
->MGYP001421152768 FL=1
-MLVGGAAGDAGPPVRPVPPRPGRPAGVDPWSPRGAALSAARTGLSPGAPGLGASGDTTRAARRAPRASDAQKTLRPPRPGDVAARRGPARVRPRAR
->MGYP000446294339 FL=0
-LIVAYPITKNGAPATAADIDGTNNHGDLNDGDRITFTFETTVTGTVDQWVEAEGRLDWEDDTITSPYHNESKGRVQIQDDEQTYTPKDTDDMSIQSVPVYFNHGTNPIMSTAQTYHLHSMNYQSNTKVVTDGFYTRIKDDRAISTGWKLTAKLSDFKDSSNAPMPNGTGTSLKLENMSIERVTDRDTPQETIDPSPTGTDVPSSVQSTETIVAGQPTAKTLVTAQPNQGQDTWQLRMPFDKISLNLPANAGKKGTVYKAKLTWSLDDTP
->MGYP001472249376 FL=0
-MDYSVSEGINFFDTAEIYSVPPTAESYGKTEEMIGNWFEKRKNREKIILASKVAGPGCDWIRGGGNSFDEKKIGEAIDGSLKRLKTDYIDLYQLHWPERSTNFFSKLGYRHNKNEGSWTAFEDILATAQKFVDQGKIRYLGLSNETPYGLSKYLHLASTHKFPRVVSVQNPYSLINRTYEVGMAEMSVREKVGLLAYSPLAFGMLTGKYLNGQMPEGSRLKLYSKNFPRYQGTRSQLAVEEYYKIAQKYEMSLTQMSLAFVNMQPFVDSNIIGATNMKQLEENINSIHIDLSDEIIKDINAIHENNPSPAP
->MGYP001245916141 FL=0
-VDTMQSTPVESGTTTFTAEEEEMAQFVSVVLKDTETIWGEIFKQAGSTYRQPSLVLFSGQVQSACGYASAASGPFYCPGDEKVYIDLSFCDELKTKFGAYGDFAVAYVLAHEIGHHVQNLMGILDQVNAQRSRLSETKANQLLVRLELQADFLSGMWAHYEQQMDYLETGDIEEAMNAAAS
->MGYP003647845281 FL=0
-DYVTMPDSDVFDWGTGDFSISWSIYFTTIHTTTAAYVNNMFGSSLSGVGLVIAYKNGANLFLLMNNTTVIDQSYSLSTGQWYQMEITRSGTSINWFIDGVSRATATSSANADKAAPLAIGASNEGGYRASDRDIAGYMDEIQIIKGRALNTSNFTAPSAAYSDPQAPANNFTNNNTVTTTTHTPTNLNCLLSPLDKNSATVLSNGNRTQSDLGASW
->MGYP000974398092 FL=0
-MVRRQEADRYGLAAVDHRAPAAVVFRRVEVAQRLRNVVVVNLGVVLGDDAVERRQRTVVDGVGIPVARHLPVGHAQREVGVGVEGPLAVPFAQTFNIGGVEFVENFAVEVAQRLGSQHPRDMVEHAFGLLAQSGGRLHGHAVGAFPDGLEKGVGMGFRRFVAGYAFGEGGYAVDLRATAVFAECLAPERPLGGLAPCETLLGAFFGGIGCRQRRQRFAGDLVSEIGIHDTAVFGAQAHHFGVFGVLHGPESELRLVIEFCCDGPAAVDAQRFALPFFPGVGDRGVFGGIVDAQRGVGLLRFGDDVEAPRADSDLGRIGTFGDVGHGVGKDILLRVARESVDHREIALFDPFRRYREMFFRTIRNVPGRVGRRAVVFRSIDAEHREVARVAGPDPVVGVAAELADRRGRRGHEAHVVELLVDEQELLVAVVHLLDRGPETLAFGLGPADDLLGRLPGLQAVGHLLHAHEEADVEPFVGQLFGPRHGPESVREVVVLDGRVALDGVVAAVVVGQQQPFGRDQLARAAAVEEHYGVLHRGLVDRIDVFGREAESFRAHVVDALRDEARKPHALVGQSRQDSEGREQ
->MGYP000161612758 FL=0
-MAKQSKNLAKVQSMLDGTYGGKTQVGYGDQDSKHRSVGDTWTDSEGYEWEQKEGFRVKNSVMPAVGMFNHQCKDCKKNCSPKTAKPWDRDCFKADGRCYYCQLDYEVELKTKPIRWFAYRRLKDLQNMESLEKDMIQWVDEMTKQREKNPFDMKVANAMANGEVEMSIKKNTQ
->MGYP003493975136 FL=0
-CIQPXRXMXGFLIVKLRPIHQLPLPQVQHGHPGAIQLGQDIRVRYXHETSESPNHALQIIVYPKSKDLVSQSMCNHSIKDTNMPSITWILKLVSKRYSR
->MGYP000200203148 FL=1
-IWGVLPVFGGILIFVSMASLGLPGLNGFPGEFAITRSAWGIYTWQVAISMVGLLMTGAYVLKGIGETLHGPVKPEWRNLPKMTITEHAVVWPLMILILSLGIWPQWLQAVINDTATMILGG
->MGYP000071017550 FL=0
-MKKFLSLMLAGLMSASLFVVGAAAEEPKKETVVGKDGGVLDADFTKNETSNDNNINVKVEAVTHKYAVDLTFNFTDLTIGGLVWNVETLRYDFAEGKALTDSEQTITVTNRSDKPVYAWGTVTDGDANDYVTVGMKTGETGSGTNDRLEVAKATAGQTANGTATNGKLTVSISSANWANVANYYGKKVAETEDPSTVNFKAATVTVTISKNATK
->MGYP003685103309 FL=0
-MKKNIISNIVKQVRTNEPIEPDTVLLGLILVSLGPLNIFPTT
->MGYP000129413943 FL=0
-NLKSIQYGGSLQFPACTHRKDKYDGIREEIELWLDDMMVKVNDFTVEKRYGEALNYYVHDIFPTALKLIVKIERWMAREKRREMEKRLARSMLGNINTHMVDPEELTNKRLRGLDTYFYGMMNEQIVVLIEHLKKCRMEGKNGWDPSFLRRDLIMRLAELYRGEFRSKNYKKKPEYVGEKYRYLITR
->MGYP004202648141 FL=0
-FQTQFFEFCNEIEPFLYELAQILLRGEKRENDVRRLSQNTYKRLGM
->MGYP003594687530 FL=0
-MYPQLTTQPGAIASAAAIARGELSPLEAVDAAIARIEALDGPLNAVVVRDFDRAREAAKALDGKQPGADQPLFGLPMTIKESFDIAGLPTSWGIAEHKGHIAQGDAVVVRRLKRAGALFLGKTNVPPFLADWQCDNPNYGRTSNVHDHARSPGGSSGGSATALASGMVAAEYGSDIGGSIRIPAHFSGVWGHKTTWGAVSGDGQNFPETDGHEIALGVVGPLARNGEDLALLLDLTLDLPLPKADKPIGQSRFLYIDRHPLCEVDDAVRGP
->MGYP001596028094 FL=0
-SERAGGSAIPRERDSGGVRRSDSEIRGSDNRRFGKRKPHHEKSDRKNEKKLLHKC
->MGYP001229890441 FL=0
-TGRIPVWWGFVHIVSKAVVSASIAGIPCAHDLASIDATLANDRIDDPHVAMELAEFIRDCFMKSKSKLYQLDNTATLTEAENKSTAWIGSKYFLQKSGYYDSNYSESGRKDWSFNPTRDAGFESSKTPGGKGGHPICSEWWLDRNVGLRKKLIGSIDNNYFTNLMTIIGSPKYFNPVGNATDRENILLRKYLALQTNNSGYSGSGLNQSFGNSYAERWTLDRSQGSDIQASISYGLGNVAIDGLVVASAAVGGLLKGPGALVEGVMIREGVTLFQGFLLMVFVIILPFL
->MGYP003333085768 FL=0
-MDGLKFDLAQFCKEIRTLLQVAAEGHVAFGMRNETYCFDFAYRKFVTAEASRRKEEVNWETTMSEIQEITADSGDLLGEVDTHVVSVALSHAVFGRADWAIMLSCFACLWHEVKTKYVDKEKWSLTILLDLLRSGRLSSIVAEYKQKHGYAPHPCTLLELYEKEHPDELDLHPPTPRMKKKRGAPTQLLDAKADPDQRTASNGEDAFMLAATLRTAH
->MGYP001563487917 FL=0
-YNSQSPSYTQSNSILANVHANARSVYYNVLMSLVRGAQCDPADPYIQQPYMQQPFVYQPLMSPQFRAFVNSRYKGVGIGIKQADSLHIVKATTLPPFYLYVLAQSEVASHYVKGVPAAGGEAAPVNVLTYTLVPNVLFDADAGLVRIVNDDAEQSPIIIASTKDDQLNYNLGAASSLVLVGDQLHDTN
->MGYP001435143440 FL=0
-MKEVIELRLSCIVYARIRVILPPNLDQTKRKRFSKRADIWGTQDPGPQRPDI
->MGYP001552004220 FL=0
-NQAIFQLAQLEYLANMPGNEGLRPLVEAQRQVIMGGMPPSGAGATPSVTTGATPRVVPAGGAPGATPSVVQPADQYLADQAILLDSETGGVNADGTPFEPPAPVVTPSEPLPEAAPTPDVAAPTETPAPQSTILDDLQQEIDQNNALIAQRREELEAAIEQYGRAETGAGMGLPTSPGGAELIVEQIQSDINNLTNRNETLEQRIFEQRQVERETQAAAEQEAAEQAETESRMQPLIDDA
->MGYP003921459353 FL=1
-MENLKKQGRLIMPQKKPKGNQKLLLIKKNNGTYLEEEFFDVKFVPLLNKDIK
->MGYP000745101651 FL=0
-RSEKRLRTLAWQYEGKHIVVANATIFIEEKPAMPNRRIRRNRTENASKRGTKETLREICNRNFNVVTLINLLVMTAYPLIFTFVYSFTDYNLLRSLKKGSHFIALQNYTKLLSDPYFQQSILNTVKFTILAVIFEMFIGLVMALFVNSLKRGQKTMRTLLLLPYLLPTVTVALSWRMMLSPNYGIVNQVLQALHLPVYNWFSDIHTAFGMLVLIDVWQSAPFVFLLLYAALQSVPQSQYEAARIDGANRFKILFYVTLPNIKNSLALCALLRTIDSFRLFDKVNLLTGGGPANSTSTITQYLYNYGIKSLDFGFGSAGAIVMTVLVLLLSSVYIKRAIS
->MGYP000475249838 FL=1
-DALPICFNLDFTYQRGFIKTWECNTSNVLIRLGVAF
->MGYP000373718212 FL=0
-AAEMWYSMHSKVLGDSFTVKNPLIIYNDHPGFQQTNAIQGAISVGTGGVTEGLRNRVIFPVAPTNQQTNHVLGHELVHAFQYHMIINGDSTNIRNLGNIPLWMIEGLAEYLSIGRIDPHTALWMRDAVLNDEVPRIKDLDNGKFFPYRWGQAFWAYVTGIYGDEVIAPLFENTAKYGLKMSVPMTLGVKVDSLSENWRSALKSHYGRWAIKGKKEDLPGKTLLDDANAGEMNISPVLSPNGKYVIFLSEKNLFTTDLFLADAKTGKLMRKVASTASDGNVDHFNFLESAGTWSPDSKRFAFDVYENGRSVLVIKGIFKGAKSEKIRIPDVPAFSNPTWSPDGKTIVVSGLVRGQTDLYEYNLKSKKVRRLTNDLYSEILPTWSADGLTLAFSTDALSVQRGRTNGAWAMNLAVMDIAFGKTENLDVFPGADNMNPQFDKNGNLFFLSNRDGRRNLYRYDMLTKKVFQLTDLMTGITGITPYSPAITVADDRDRILYTHYNKGRYTIHQAKDADFSPKEIDPMSVDQVPATLPPFSTKQRDMVNTSLRLMDTAKDSVSMTSKKFKPKFKLDYLGGSTGVGVNTGNSSFGTQTGLAGGIDALFSDILGNNQLYAGAVLNGDIQDAGGQVSYINQKNRIGWGLNASHIAYQTGGYSYLAYTPVETSPGQTDTVLASVFGLERVFQQRLGASAFYPFSVTKRVEVGAAAEFYSSRVTEYSDYYDPVFQNYLGSDQKKQPKGPSLNLNNINAAFVGDNSYFGLTAPLQGWRYRFGAEQYFGDYQFTALLADARKYLYLKPITLAVRGLSYARTGGNSTAFSLQYPLFAANSNFVRGYDRKVFAATDDPDFIYRTVGSKMIVGNVEIRLPFTGPRRLSVIKSN
->MGYP000608946936 FL=1
-MLSLAKRALASDYVKSAELAKKADDKQAEIDALYSQWEQAQQALDELCEESSKQG
->MGYP001546073984 FL=0
-LIAAREERQRRKEEERRAAAEAIERAKREAEEARVRAEEEARAEAGRKKEEELQKMMQLLAEQKAARDARYAARKERLKKGRR
->MGYP003398203515 FL=0
-LLPPWEQGYKNVFVNKAKEILAMLLFNEESLEGQLKVRTSGTPDGAETHATTQVYPLPTFHPDCQVVSPSDFSMKPVPCGYDLTRLLPTPDIARTHIKLANSVSTSSMLVIDPDNVIKHKIVPPPILDKIYIYQAINPYNGLVYGHGAPKIFPVDGLRKLDLSKFPIDGDFTLWAAREIGCGVEVLNETVAVHEFGTSQTSGAITAYREAYKLQRTLVGAAPYDSLFVPRIDSPRMGAPRTANTDAKNSTMDSVFNVTDALLEAERRTVLKRLETWISVNCYPSTFKYMA
->MGYP001150268012 FL=0
-MQLESTGESGEDMGAVSDDMFTEFFTQVLNPELGCVDMVIFLLCSFC
->MGYP001140916756 FL=1
-MISLIFLVMEVGICYNKWEKIFYTNGGCIIMSEENFNTENGTNEQTCSQPQQAYSQPQQTYSQPQQTYSQPQQAYEQPQQNYDQQAYNQNQQYAQQNYGYDQSQQGYGTYQQPQQQAYGSFDQTQYGYNQPASSGKGMAIASMVLGIISIPAICFWIVGLPCAIVGLILGILYNKKNEHSPMATAGIVCSIITIALLVLVLILCIVGAVSLSSLEYSYYY
->MGYP001587054973 FL=0
-MQPKPVTNRRSTAQEIFAGCADSARQPYMNTPLQLRPVHTLLCPWPXFPGRSSRPNGAFSPVRTESSPANRAGSRAGSHAESAPTFVLRGRVCGAXXLX
->MGYP000208465860 FL=0
-SSDLQLVEYPVISAELIMMPQNMTEISDEETAGKVLKLIDVLEDHDDVQNVFANFSIDDELLEKINF
->MGYP003351738706 FL=0
-MKQSGGFIWVYSELGRGTTFKIYFPRVGQTVEPRTVETPRIILPADTGATILLVEDEDSLRRSIQQMLTKAGYPNGFSTELVTYVLPQWAASVQGYLKAVGIDAKISQLQVQALVQRCQGRGECPMDMGSWGSYSINDVSAVMPVFLGGGV
->MGYP000525123928 FL=0
-MFDLFIKEVDKKLADKSLNNEITSKEYYAEKQKLKYLKPAKEYTNNLKYAKIEDMILDFKTKLEQLKFDTKLTTFEQKEFNIKDLEKNKKNNQTELEYQKEDIQKEKYDYEYHKIYQERDELSEEKLKEKIKELEDKEIEPPTEKEVDDMYNDLGYKYLGKEMSDRENYKLAETWKNLEKQDINEEHESMYMNYDELDNKITRYTFDNDLDNNEIKTYIGKRLGEDYGKNLDREKKELASKFAELEVSGRYRDIDINNPKLLLQLEKVDGLNIETLEETIGLDTKDLKKEIYIATYEEYLDENKGIMSPAKEYYTKDEKGEYIKIGESDKEETTITVDGFDFKLKNDEILKGEELEKVTQKEMVEELIKNEVEKSLGDGKRVTGISKVLDVNFLKELEKQCGYDKKDETLWDRVSLVSTINEKGEEDFQILEKYYDEDGNITYKDLEGISTLENSNRDIAIETEEIIYGKYKKVESTKTLKEYQTESGDRYAITRDEDGNLGFSEIYSEIHREDYHILEAKEIDTYSFETKWLTEGYDEFDINQSDIENAKEIFDRSKDEMEKTQENTKEDKGREL
->MGYP001623022299 FL=1
-MEVDLEHLRKPCTCGRAHEISVRGIWIESGASGRLYEMLTEGELREFTAPVIVWDDNTSEAAEKILGDVSEICQEICLSAGNLRADSRSVEILEETLPEETDLILAVGGGTIHDLSRYVAAQRRIPFLSVPTAASMDGFLSTTADLSQDGMKKRVPARAPLYVFADTDIFSKAPYRLTAAGISDLLGKYICLADWRIAHAVTGEYICEEICSLEYKAVKDVVKRLDDIREGDAEACERLMYALLLSGLAMQMAGGPRPAFCAEHHLSCLWEMEVINESTDALHGEQVGVGLLLAEKYYRRIQKAIENGRCEIRRHEGLEKELLQTTFGSHGLYEAVMDENTPDPLDEVDPERLRRAFLEIAEILDDIPSRERLMDMMEEGGCRVSLSEIGLPESLEEESLALAPYVGRQMSLLRLGKLLVI
->MGYP003326090123 FL=0
-VYKRQIVKTVEESFSNDFNVDKCLLKFYKNKDIEKIEKETGLSLHKGAIHCGSFSSEKADILFGDNKIESMVIAVIILEKEIGLLKLGSLDRAKYLGDEDTTFIQAHDYVDLDWYGNYDTWADFPDGNTTYRQILMHYDMRCSSSGCSGWDYTTKIIILKPNGEYNADGDPTFINAQTLANVVTPYGTYMQEGNSQGSGFSPNWVQRYTYDVTDFAHLLVDSVKMRAFYGGWSTGFNVTLNFEFIEGTPPRDVLDVQQLWSGSTS
->MGYP001037461204 FL=0
-MTRMLAKRIIPCLDVTAGRVVKGVNFVELKDAGDPVEIGRASCRERVSDTV
->MGYP001119331046 FL=0
-LEERIKAIMKRKHISITALVAVLVVMCVTTTVFASAAPEDREDPHQNAPETGYVYDHLGIVEDNGVSIMSKGGENGEKLYSADDGKTWMTEERYHAEYGSCYKGKLSAFESGGSPFPVGL
->MGYP001570668198 FL=1
-MSLNKRLSWTLLTLFFIFDNFVSYYAVTYHGGREANLAIAWLVEKYPLLYFVCIPGQIVIIYFIVKWLTRFASEKVILTALVIYWPIANSSMNLTFILGHRQPAKNWLMFTAVGVLLAVVYALRNWKNKNHRKF
->MGYP000837251816 FL=0
-GLGDVYKRQHFKAKREMEASHQLEKVGEGIRAMYSWNGDDKYAEK
->MGYP003705394679 FL=0
-TDLNKVVTLAENGNREAQIGIAHVFEQRGQSRENIMRAIAWFHLAHNTDEDHFSSGRERGSRITDEFKRIRVESELFTEGLRSELTGTNVGVAMAGRNCSAEQRA
->MGYP000950492884 FL=0
-MSEMHATVEAVTARIVERSKRGRQAYLDLIAKQRDAGVNRPVLSCGNLAHGFAASGEDKASIRDGKAMNIGIISAYNDMLSAHQPYGRYPEQMKIFAREVGATAQVAGSTPAMCDGVTQGQQRDVLDAASQLNRMLDERVDDPEIANKVNEELRLQYRYLDLRRPEMIRNLRLRS
->MGYP000774599694 FL=0
-MALEKISDKQKEILEFIKSEILNRGYPPSVRDICEGVHLKSTSSVHAHLETLERKGYIRRDPAKNRAIEIIDDSFGLQRREMVNVPLVGRVACLLYTSDAADDL
->MGYP000900149593 FL=1
-MKIKINRFKNIHDGTIGKLTITDDGKKLFECFTLEPAGADTIERGKDRRIPAGLYNVEWYNSPSQRRICPLLWNELVPKSRYILIHTGNFPKDTAGCVLVGDGHNAAGVTNSLKTYNTLFKLAQKHGLQSVEIINGAGV
->MGYP003625506155 FL=0
-MKEVKVKLTLDDKGAVVAAKNIQDSIKDIGDEAEKTGGKVGEVGKSASKSKKGFATMAKGLKSVGVALKAAGIGLVVALVAGLTEAFSRNKRIMDGVSIVLGTIQEVFTQVADALIATYDAVAQSSDNFDALGKVMGGILTLFINPFKISFFAIQLALQAAQLAWEDSFFGGGDEEKMAQLRLDIEDTKTSISEVADEMVEAGSTIVDNFAEAVTEVGKITDIASENLSKVSIKAANETAKAHKAATDAAIIAQAMAAKNIALFDRQAEQQRQIRDDANKSIKERQEANIKLGEILEKQEEALLKQAAAVEAGARAEFAKNNSIDNRAALIAAEAATAQVLADIEGKRSEQKSNTNTLL
->MGYP003576697368 FL=0
-ITTKLDLNALHAGIFTEGEVTENSAFYLSARGSIQQYLFGDKAKEDLEKEDGIRVQQVPQDSDYQFKYQYNLDDANSITLSANGATDLAEAEFLDLSTDVLEDPDMAGDARIKNNFQNAFISWRSQPDDSSQLNVQLGQYINKGDTFWGDKKYFFNIKTTDSYVTAQYEFLLAKDHSLTLGAEAHSTDY
->MGYP000113647356 FL=0
-VTLWIVAEGRYEPQNFQWYAIRNDDLEWDWAVGASNYKDIRAERSAVQPGKMWEIESSVDILRQQVETPLRNGFFGASGGPGGGSVTAARSSASRRSLSARSASSLAWRSAASRCLRSASSLASRTSVSAVRWALTSVLRNVSSKSGMGAGGAPGGMGVCEGLRASISRASADQRAGRAGRTQPGIAVRLWRAEQNAALPAFTPPEI
->MGYP003702691201 FL=1
-MLSRFGYKRFIKSYKYIIGKEAVILLQFYNKDIGHYSLLINTRSSLSDPFPSIFSDFPVVSEVGGGPTLIH
->MGYP001051415245 FL=0
-EALAVYKELVDKGADFFKSQAMFDQARVLAKKGDTAGAKDLYKKILEKQATGPLHDEVQARLGAIGG
->MGYP000892997868 FL=0
-LSYSLAQGDGINDAHNSLVEIIDNLGVVAQDADINFEADPVLRIFLEVSDGDLSYQQSFAIDVLNLDEIAPAITSGATATAIDENSGAAQVVYTATSDDSSDVSGGVSYSIKPGSGDGEAFSIDSSTGVVSLIGNPDFESKPSYAFTVVATDAAGNSTEQTVALSINNLDEIAPLITS
->MGYP003509546382 FL=0
-NTAEDARRAVAAVKFGPGNHRGLAAGTRPDNYGLAKSMEEFVERSNAETLVCVQLEHAAAISNVDEILAVDGVDVLFVGPSDLSQSMGFPGNPTAEPVRAAIEETLRKIAAAGRISGMPASTDSVVSVLKTGAKYIYTHLPRLIGAGAAQFRNAAASSK
->MGYP002781630755 FL=0
-AYIRRGDGGFEEVMRIRVADVIKTVRVKATVIGSGSRARVLGVDLDITDQLLAQEKIEETAENLQAVLDGSP
->MGYP000437988234 FL=0
-TTVASASSATGAGATGVALLEIYEVP
->MGYP001158237079 FL=0
-MNRNLFTSESVTEGHPDKVCDQISDAILDDILTHDPNGRVACETLTTTGLVVISGEITSSYNPNYEQIIRDTIKKIGYDDPKSNFCSKTLKVLLYIDRQSSEIAQGVNENNNQEQGAGDQGLMFGYACLETPEFMPLPIQLSHRLTQRLSDVRKNKKLPWLRPDGKSQVTIEYDGYKPVSVSKVVIATQHEDLIEKFSSEEKEHSYIKEEVIKEVVLPVL
->MGYP001046820937 FL=0
-MPEVLDGLRAAGVNDVPVIVGGIIPEADAARLLGWGVAAVFTPKAFSITDLRGDVVRLIRPAPRLAAAVCVWGLALLALSQPVADQVHLG
->MGYP000228404273 FL=1
-MSLTMADLLFIWQLFILFEIVLFASYTFIMYIYSRKEEEFPINNNLPNVTLIIPMYNEEKVIREKIENTAHLDYPKDKLEVI
->MGYP003201765208 FL=1
-MLTSGLGVDKNGVENTLYELLLGEADVKKTIVKDVVENLDLIPSNINLSGAEIELINMDDKEYILRKITEKLRRKYDYIIMDCPPSLNMLTINALTAATSVLVPIQCEYYALEGLSQLIHTIDLVKDRLNKKLVMEGVVFTMYDARTNLSLQVVENVKDNLEQNIYKTIIPRNVRLAEAPSYGQPINLYDSRSAGAEAYRLLAEEVINREDK
->MGYP000603741297 FL=0
-MVPFQETPIEEPQQLALPRPQDVEQAPQEPGVEYGGILEALRDTGRQALASFPTLVAMANKPGIYDPGIYQDKEEYIEKVNDFRAEMLTDALKILEGKENEKQAYHDLFDLIKNGEWDKLDNWAGTFLGQTVPQLAMSYLTKGISGFVLESASSYQESVRKISEKKGISVEDVIREGHDKPALDFLIGTINASLELMGAKSVIKPGATGVRSIFRRIFQSAGTESGTEALQGNITKLG
->MGYP004409704841 FL=0
-LKQVSKDFAQPARNTLCDVQWLMRNNVSLHGLLKQGSPSPALVTKLAKASPGCLMQRDGDGLLPLQFAAAYKSRFGDALVSTIREVTVRAVPGSVWPARSDEARGLRKGLRPVRTRVSGVIVAA
->MGYP000111574240 FL=0
-HGMAEEHEPAVPALLRDWIPEVQDYRMLVFGAFLAAMMVVRPGESKPERLREIIDDINSQPKGPASAFSNMAQQLARDNIRVNSVAPGSILFEGNNLYAKDIDPVEVRYRIGMVFQKPNPFPKSIYENIAWGARIHGYTGNMDELVEQSLRGSALWDEVKDVLKKSAYEVSGGQQQRVALARALITQPKLILLDEPFAALDERSRFRMQDLLLDLKQGRHAPVHTLIDLTFVHEMAALEVRGDDLYIGAAVPVNRVALDPLVGTHAQALVEACNLIAGPQVRNTATLGGNVAHALPAA
->MGYP001611773216 FL=0
-DDITKSLEAGAFWDAHLKEAFDQTPADGWAIDLGANIGFFSLYFAERFERVVAVEAHPDTARLLYQNVMVNGQGGKVLVITAAAYDRHTTLELATSKVHGWLEDERSFLDTDSVLHSAGFSFVEDPSQQHHLHEIRVPTVVLDEIIPESAPIRLLKVDVQGAALRALHGCDRILARC
->MGYP000527795113 FL=0
-MKTTQYKDQSAIKTIQYKDQSAIKTTQYKDQSAIKTTQYKDQSAIKTTLYKDQSAVKTTQYKVQSAIKTTCFWSLTSLFQCN
->MGYP000852577756 FL=0
-MARNRAEEEVEQLHFLRVGEVFEPFVPWRRNEQGKQVYIKLTRAEEVSFLYVGSQLSVRAELQQALMRLVNDGWSVEGEVVVQFDGRSEPGTDPYVYREPLVIELGKGLLPLIDPQNGAPLISKFEQIREEVAREVGLVIPPARVVDNLQLDNQYLLRVKDSPIAMGEVFLDRLLALGSLELLGQVEGWTCQDPVHRMPAKWITEEH
->MGYP001572973866 FL=0
-GLKKLGFNTGMSETPITPVIVGDAALAHQFSRDLFAEGVFAMSVGFPTVPVGKARIRTIVTATHSEEELSQALEILGSVGKKLGII
->MGYP000527111928 FL=0
-GLKSIWIPWLWPVFNQIFLMVFLSIWLRRSKVTTGAEWITTRFGRTRDSNLSHGVVVVFALIMCLGYLAYGFIGLGKFVMIFIPWEIVQPYIPVHIPLEYVPHVYGIAFTLFAVFYAVLGGMSSIVWADVLQYIIMTISAILIGILAMKALAVETLNVPETWKSPFFGWNLDKLDWRGIIDEVNTKIASETKT
->MGYP000292924687 FL=0
-MKKILYMTIGIVSVILGLIGVFVPGLPTTPFLLLSSWLFYKSSKSLHDRLHRSRLGKYIRHYEAREGVSWLSKLISIVCMWNMIRIFSNREFTCTDLIIGAGMYWNWKCVVYSAYSKEVKDELSKNILDSFLLFLDHYVYNFSGNNDHFADFFAFKPFCSFRGRFYCSFNFGIGGS
->MGYP000084281174 FL=0
-EALGGPGDRHPDDGVADGHDGGTDVGREPRDALAPARVLGQPEEAHPLSILNDPGGRELAQEEGRLRRGDRGRAHAFRPDEPGDQREEGFDVSPANERLYGRVVRNYYRFVDGVIADYLAEVGENS
->MGYP003569383907 FL=1
-MPTYTFRNEETNEEFTTLMSLNEREIFLKENPHIKQCLSTPAFGDAVRMGMHKIDRGFNDVLQKAKSAHLHSTIDTL
->MGYP000625040987 FL=1
-MSKRHLHLGQTLTFTADPFVEGPGAARHDTQGALVVEDGVITQVGEAGALRQGEFASVTDHGQALLLPGFIDAHAHYPQTAMIASWGKRLIDWLNTYTFPEEMRFGDPDYAAEIAGRYLDLLLAQGTTTVCSYCTIHPTSVTAFFEAAEARGMRVLAGKTCMDRNAPEGLRDTAQSAYDDSKALLGRWHGQGRASYVITPRFSPTSTPDQLSALGALWAEHPDCLMQTHLSEQTDEIAWVKSLYPQARDYLDTYEAHGLLGANGLYGHAIHLEPREKDRLREVGAALIHCPTSNTFIGSGLFDMDGLTRAGHRVGLATDTGGGSSFSMLRSMAAAYEIAQLRGRALHPAELIWLATTGSARALRLDDRIGSLAPGMEADFIALDLASTTAIAQRSARANDLWEALFPTIMMGDDRAIASTYVAGRRVA
->MGYP003399258141 FL=0
-AGSADILTAGIAIIAASDIIIAILFIVLSIKFL
->MGYP000308143635 FL=0
-MKRIAWVDAARGFAIILVVFGHVLGGVMSRRRLDGEGLYRAIYNYIYLFHMPLFFMISGLFCIEAMRKSPINAFISRTESIASPYIFWDFFVRTAALPLIGAFMSNPPSDIGWHARLEQALTGEVSWFLWTLYVMQILLIPFARMPIWVLFLVSLAVILYLPNSHLGTINSVVDHLPFLLFG
->MGYP000676410644 FL=0
-MDGNISLENRLELCNSKLSEKEKMKKITAALCDMPLFKGLSEPQIQQALESFHAYTRCYDKGTYLLSCGQPPQFGLVIAGEVHIIKEDFWGHRSLLAQLGPGALFGESFSLSATPSLPVSVLAGTQVEALFFRAELFFQPSVVSACSISLVTNLLGILAEKNQLL
->MGYP000176506859 FL=0
-MVVNKLLITSTILIATTLITYSCTEDTKSKDRLSLEQKTSVKSDAKKVCELVSNIKIAISEVSNAINEGANSSYVEALNAKAKALDVRIKEIQKRNAGNEEFMKLQQSCYEVMNK
->MGYP001197552457 FL=1
-MSNFVQLGRYRHYKGKEYQVLGCARHTETEEEFVVYQALYGERRLWIRPKSMFLEHVQIGTKLIPRFILIERA
->MGYP003478946207 FL=0
-MSPQSVNTRQATRQVRDVVFVDGVRTPFGKAGDKGIYHGTRADDLVVKCIRDLMRRNPSLPAERIDEVAIAATTQTGDQGLTIGRTAAMLAGLPQSVPGFAIDRMCAGAMTAVTTTAGSIAFGAYDVVIAGGVEHMGNHPMGAGADPNPRFLSERIVDPAALNMGNTAENLHDRF
->MGYP001199610918 FL=1
-MQSIGTYLKQRRESLSLKQKDVANSVGVSSAYLNKVEKGDSIPAPAFLEKIARTLELDFIDLYLRSLEDRPLPDTLMHAMREYRSLRPLLAPGMPVERFRSFIRSMSPEQTHRILLMIESVVLMIHEAEDRGAGARAIREPVPGDGTGADRIPPE
->MGYP003348169323 FL=0
-HQPLLHAKEKLASIINTTSGRGGKIIAPAFAVGRTQQLVLMIHELIHEGKIKEIPVFVDSPLAVNVTDAFRAQRHARKTGGHAKEKTGPALPAGEHGAHLGARQAGEVDHGVGGLAVVPGMNGRAHLERIGGIDRAHRIGEARRLHRIERRLRPVERQQPHIRPRPSRRRHRQHARLARADE
->MGYP001430805213 FL=1
-MRIESREDLKTWASFKNISVYLDQKKILSNININIKHGENILILGPNGSGKSTFLKLLNRSIYPITKKDSSLKLFNKENINIWDVRKRIGFLFKEMEGRVNHGVKLYDLITSGFSGTFNSRYSKLLSEIEKVKVDNLINEWELNNIVNNEFLSLSDGEKRRALLARALVYEPDILILDEPFCNLDIKSSFILNQNLNRLIEQSINILYVTHNLESILPKTNRVILIKEGKIIKEGNPNEIINSKIISDLFKISINVVKQDGYWRSYPVSI
->MGYP001428761037 FL=0
-MRIDGIQGVYVPSKKPPINPLKKAVGRIRDVIATPKKYTHKDRLREQWSNSGSSLSYREYATTHDHTIKTPASELVKRFK
->MGYP001559191903 FL=0
-MLILMAYIYKKTIHGKQYYYLRVSKRVKGKIVVKDIAYLGNDASKLDYAMQKLPLLYKKDIRKAYRNIRKFVQEESFSVANKSPATIACAGAINPPETKEKIQYLKKSFKGMPYGAAF
->MGYP003492916345 FL=0
-TMGKNAKFFPENIWKFELKKHELLIIMP
->MGYP001589567138 FL=0
-VQDVEQIVARALAEFAAAPDPAALENSKARYLGKSGELTALLKSLGTLAPEARRSAGAAINTAKARLEQALEQRRAELANERMQARLAQEALDVTLPGRGRGRGGVHPISRTWARIEAIFGSIGFEVADGPEIETDWYNFTALNNPENHPARSMQDTFYVDLRDSGGLPLVLRTHTSPMQVRYARTHRPPIKVIAPGRTYRVDSDATHSPMFHQVEGLWIDEDVSFADLKGVFADFMRRFFESDDIEVRFRPSYFPFTEPSAEIDMKFDSGPLKGRWLEISGAGQVHPEVVRNFGLDPERCIGFAFGAGLERLTMLRYGIDDLRLFFDGDLRFLRQFA
->MGYP001206066660 FL=0
-MIVTLNKKVLIVIRVVKIFMTFLTSKAFNFN
->MGYP001314004753 FL=0
-FHTPNYKYEVFGSFINSKNSVKETFGLANPTEFDQLSGRAKTYAGTANFYDASNLFIDRTWSITQFFRPGKRTIQLNDTTIVPDTNTSNIKSQWFHELRYRRHINRFTDSDTNTDLFPVRYVSLETHDSMFHAVLSNRIGKVIKSKSQLIKLWGLHEAIQVKQQYFHSSNLSHLRFGAEMSKTLLSVKHDFYAHISALGYYQGDIKALYGFNPELEKVDVRAEASITRRRPDYNDQFFGSNNYYWNQDLNQTQTSKLLLTIDNKKATQGIELAYFNINQFVYYDTSGFAQQFNESINHLRATAKLQLQLGSWFWQHRLTYQSTSSNVLALPDLSVKTRLYKEGYLFNKNMWARMGVDLQYFTPFTGTVYNPIVRQMTLSNTEIGGFP
->MGYP001770970470 FL=1
-MIRSIKYGLLLLLPGMLFTAQAADRQDVKCHLITSKGEQIAFYRWDLDKQQLFMARLSGKSLKDARGKRYFIREARECVLLKEAFSSEKARKLDEMALR
->MGYP000978871530 FL=1
-RAEPAELDAELARLILLSEQRRLAILAPLLTGLTLLVACFGVLANARGTLPNGFGWILCIASVACAYEWLAGLFVARLAQKGRQPARFRFYLNALVELGALAVMTLVLARTNNPVHAISGPASYSYFLFIILATLRLDFRICVFTGTVAAAAYTLTGLLHWNALEASFSE
->MGYP003540537710 FL=0
-TPTAVTPAAPVITPTIVPNAPSVTGQAIVAASTTVTPPAAPKTVAEAYPTLISNDRGVTSLDKAFSLRKIASRFLGSVSPIETLVNALSSTKAMINFVGSTTTKHTLTPLAQVFYRETLPEIAGKLINTLNTRLSAALDGTNGKSALGDLFSNPTMSKKGELNIPQDMVRGRVFNITEMDA
diff --git a/src/alphafold3/test_data/miniature_databases/nt_rna_2023_02_23_clust_seq_id_90_cov_80_rep_seq__subsampled_1000.fasta b/src/alphafold3/test_data/miniature_databases/nt_rna_2023_02_23_clust_seq_id_90_cov_80_rep_seq__subsampled_1000.fasta
deleted file mode 100644
index 193fa1d6db4ad25c28e64e6fc0f0521312caad5b..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/nt_rna_2023_02_23_clust_seq_id_90_cov_80_rep_seq__subsampled_1000.fasta
+++ /dev/null
@@ -1,2000 +0,0 @@
->XM_032924760.2 PREDICTED: Daphnia magna juvenile hormone acid O-methyltransferase (LOC116918952), mRNA 
-CAACAGTGTCTCAAAGAGTCCGTGACGACCGAGTGACCGATGCTTCAAGCAGAGCGGAGAGATGGAACTGCCTGAACTCTACGCTGGCGCGAGTCCGTTCCAAAAACGTGACGCTGTGCACGTACTTACGCAGTACCTTCCTCAGTTCGATTGGGCGGAGGGCGACTCCGTTTTGGACTTCGGTTGTGGTGATGGTGACCTGACTGAGTATTTGGCCCGTTGCATCCCCAGGTGTGCGTCGTTGACGGGCATAGATATTTCAAAGAAAATGATAGACTACGCCAGGTGCCATCACCAAGAGCATGATTTGCGCCTTGGATTTCAGCAAGTCGACATCATGAAATCTATTGACGCCAGAGATGTATTTCCAGATGGATTCGATAAGATATTTTCTTTCTATTGTCTCCACTGGATCAAAGACCATCAACGGCTAATGGAGCATATGTACGACATCCTCAAGCCAGGCGGGGATATCTTGTTGGTATTTTTGGCATCCAATCCTATTTTTACCATGTACGAACGCATGGCAGAACGGACGGAGTGGGCCGAATACATGAAGGATGTTGCTGATTATGTTCCTCATTACCAGTACGCTGCTCGACCAGCTGAAATGTTTTCTTCTATTTGTCGCTCAGTTGGTTTGCAGGTGGTCGAATGCACGGCCCAGGAAAGGAGCTTTTCGTTTCAGAATATCAATATTGTTAAGAATGCGGTGGCTGCTGTCAACCCGTTCCTTCGTCGGGTCCCTGTTCGACTGCGCGAGAGCTACCTTCTGGATTGTTTGATGGAATTGCAGAAATTAAAGGCACCATCTGCAGATGAAACAACTGTTGCAAGTTACCGTTTGATGATTGCGCACGTTCGCAAACCATAAGCGCAGGATGGCTGTTGAGACTTGTGGAGGGGGCAAAACCCGGAAGGCTCCCATAAGACAAGTGCTAAAATAGCAAAAAACAAAACAAAAAAAACAAAAAACAAAAAAACAAAAAAAAATTAGTTATCTCATAATCCGCATCAAGGTGAGGTAAGATGATGACGAATCTAATGGCAAACCGGTGCTGTTACTGTAAATAAGGTTTGGGTGGTTATGGGATGGTTACAGCCAATGGCTGCAGTGAGTGATTCCAGTGACAAAGAGAGCTTTAAAACATTAAAGAATAAAAAACAAAAACAAAAAAACATTGCGGTACAGTACGTGTTCGAAATGGAAATAATGATCTCGTTTTCGGGGTCCGAACGGTATGGATGGATTTTTCTAGATTTGCATAAAGGGCGGTCGATGCGGATTTGTAGTCACGCAGTAGTAAAAACCTCAATACTCCCGGTTCACTGAAATCAGCAAAAAACAAAAAGATTAGATGTACAATACGTACTCCGTGTAGTACGTAACATTTGGAATTTCAGATTAATACAAGTATGATCCACA
->XM_052522147.1 PREDICTED: Oncorhynchus keta serine/threonine-protein kinase DCLK1-like (LOC118377397), transcript variant X16, mRNA 
-TGAGAGAGGAGGGAGCATTCGCGAGGTGAGATGCTTGGTGCTTCCCTCGGAAGGCCTGCATGTCAATGAGGGACGGCCATCTGGAAATCACTGCTTAAGACACAGAAACCAGCTGCAGCTCTTGCAGCGCACACTTGCTCAATCACAGGGCAACAAAGGGACGGATGCTTTTTCTATCGCTCGGGCCATTATACTACACATATATGCACTGACACAGTCTGTTGGAGAGCTGCTATATGCAATTGCTAAAGAATTGACGCGGTTGACTGCATCAGACTTCAATTAAAGTTATGGAGCTGGAGCACTTTGACGAGCGGGAGAAAGCCCAGAGAAACACCCGCCGAGGCTCCAGGAACAACGGGCTGCCGAGCCCCACTCACAGTGCCCACTGTAGTCTGTACAGGACCCGGACACTGCAGTCCCTGGCCTCGGAGAAGAAAGCCAAGAAGGTCCGCTTTTACCGCAACGGAGACCGCTACTTCAAAGGGATTGTCTATGCCATTTCCCAGGACAGGTTTCGGTCTATAGACGCCCTGTTAGCCGATCTGACCCGCTCCCTGTCAGATAATGTGAACTTGCCCCAGGGGGTCCGGACCATCTACTCTATTGACGGGACCAAGAAGATATTGGGCATGGAGCAGCTGGAGGAAGGAGAGAGCTATGTGTGTGGCTCCATAGAGCCATACAGGAAGCTGGACTACACTAAGAATGTCAACCCCAACTGGTCAGTTGGGGTGAAGACAGCTGCCTCGGCACGTGGCCCATCCTCCCTGGGCAGTGCCAAGGCTGGGGCCCCAGAGACCAGGGAGAGTAAGGACTTCATCCGGCCCAAACTGGTCACCATCATCCGGAGCGGGGTGAAGCCTCGAAAGGCCGTCCGCATCCTCCTCAACAAAAAGACGGCCCACTCCTTCGAACAGGTCCTCTCTGACATCACAGATGCCATCAAGATGGACTCTGGGGTCGTCAAGAGACTATACACCGTGGATGGGAAGCTGGTGACATGCCTTCAGGACTTCTTTGGTGACGATGACATCTTTATGGCCTGTGGTCCAGAGAAGTTTCGCTACCAAGATGACTTCCTCTTAGATGAGAGTGAGTGTAGGGTGGTGAAGTCGACGTCATACGGTCGGATCTCCTCTCTGCTGGGACGCTACTCACCCAGAGGAGGAGGCTCACGCCGAAGCTCAGGTTCAGCCAATGGGACGGCAGGCAGTCAGCTGTCGACTCCTCGCTCAGGGAAGTCCCCCAGCCCCTCTCCCACCAGTCCTGCTAGTCTCCAACGACGCAGGGGGTCCCAACACAGTGGCTCGTCCCTGTCTCTAGCCTCCACCAAGGTGTGTAGCTCCATGGATGAGGGAGACGGAGCAGGTAGTGAAGCGGAGCTGAACCTGCTGAGTGATGAATGTCCCTCCATCCCTCCGTCCATCGCTGAGAGGTACAAGGTGGGGAGGACTTTAGGTGACGGTACCTTTGCTGTGGTTAAAGAATGTGTGGAGAGATGTACCGGCAGAGAATACGCCCTGAAGATCATCAACAAAGGCAAATGTAGGGGAAAGGAACACATGATCCAGAACGAGGTGTCCATCCTCCGTCGTGTCAAACACCCCAACATCGTTCTGCTGATCGAGGAAATGGACACCTACAGCGAGCTTTACCTGGTCATGGAGCTGGTCAAGGGGGGTGACCTGTTTGATGCCATCACTTCCTCTAGTAAATACACAGAGAGAGATGCTAGTGGGATGCTGTATAACCTGGCCAGTGCCATCAAGTACCTGCACAGCCTCAACATCGTGCACAGAGACATCAAACCTGAGAACCTGCTGGTGTATGAACATCAGGATGGTAGTAAGTCTCTGAAGCTGGGAGACTTTGGCTTGGCTAGCCTGGTGGATGGACTCCTCTACCTGGTCTGTGGCACCCCCACCTATGTAGCACCTGAGATCATCGCTGAGACAGGGTACGGGCTGAAGGTCGATATCTGGGCAGCTGGAGTAATCACATACATCCTGCTGTGTGGCTTCCCTCCCTTCAGTGGGAACAGTGAGGACCAGGAGATTTTGCTGGACCAGATTCTAACGGGACAACTAGACTTCCCTTCCCCGTCCTGGGACAACGTGTCTGTCACTGCTAAGGAGCTGATTACTGGGATGCTGCAGGTGAAGGTGGAACAGAGATACACAGCTCTGCAGGTTCTGGATCACCCCTGGGTCAATGATGATGGGCGATTAGTGAACGACCAGCAGCTCTCTGTGGCTGGGAAGATTAAGAAACACTTCAACACGGGTCCTAAAGCCTGCAGCACCACTGCTGGAGTGTCTGTTATCACAACCACCCCTCTTGATAAGGAGCGGCAGGATTTCAGACTAAGACACCAGCAGGATGTGAGATTGAAGCCCCGCCCCTGCCCCCAACCAACCGGCTTCCCCACCAGTGCCAGCCAAAGCTCAGCCCACAGCTCCAATAACCCTGCCCTCTCTCCCGCTGACTTTACCTCAGAGTCAGAAGATTACTCCCCCAGCCCCTCCCCCACCTCTCCTAGCTCCGCTGATACCGTCCGCTCCCCCACCTCCCCCTTCTAGACCCCGAAGGAAGAGAGAGGGGAGAGGAGGAAGGATAGGGGGTGCGTGTCCCTGTACTAACACTAGCCCATGTCCCTGTATTCACGACGACACTGTCAAGATGCCTGCCAATTACTTAAACATTGATTTTCCATTCCGGCTACAGTGTCAGTTTACCAAAAGATACACTGGGGTCAGAGCCATGCATAGGGGTCAGTTAGGGTGGGGTTAGGGTTAAAGGTTAGAGGTTAGGGTCAAGGATAAAGGTGTATTCTGGATGGGTTCTGCTCTGGCCCTGAGAGGTTACTAAGGCTGAGAATCTGTATCTGCTTATCTTTTTAAGACACCACACAGACATACAAGAGTTAAGCCTTATTTCAGCAAATACTGAATAATGATCCACTGAGGTCCCCTGGTGTTGGGAGGTGAGTACTGCAGGCCAACCAACCTGCTAACAGGACAGCTTAAACTGCAACACAACTAACCTACAGATCAAAATCTTCCATTTAACTTGACGGGACCTCATACGCCCTAAATAGGGCATCTTAAGTATTTATGTGATTATACATACATTTTGAAAATAATAATGATGATAATAATAATGACGTTGGGTCCTTGAAAAGTGCTGTATAAACAAAATGCCGCGTATTATTATTCATTTTGACAATGTATGTATCAAGTCAGGTATCTATTTGTGTGAAGTTATATTGCACCCAATTCATTACAACTTGTACAGTTCATTCTGTAGAAAAACACTTTCATGTCAATAAGACATGCTGTATGATGTAACGTGAAGATATAATCTACGTGTGTCTGGAAGGACACGTGGCTACGGTCATGTCCACTCCAGTCCACTTTCATTTATCCAACTGTCTAGTGTTCAGCTATTCTCCAGTTCTTGGTGCTGTTGTAGACATAATATACTACACACTTTACAGAGGACCAGAGAGGGGCGCTGGAAGATCTCCAGGCATTCTGCGATACCATATCTATTGGTTGATTGATTGTGTTTTTGTCCATGACTGTTATGCCACTGTGCCAGTTCATGTACAGTCGTCATTTAATGGACTACGAAAAAGGTTGTGTATTTGGTAGAGTATTAACAGACATTTTCATGGCTTTTTACTTTTGTACAAAATTGGCCTTGTTTCAGTTAATATGTTAATATGTTGATAGTGAAATAATGACCTATTTAAAGTACGATTATTGGCCTGAACACAATGGACCAAGTGCAATTAGGTTCTGGATCTCTTACCAATATTAGACAGCACAGACTTTTTCAAGCTATTGTTAACTATAAACAATCCATACATTGTGAATGTATGTCAGAACAGAGGTGCTATGGCAGCGTCTTTCAGTGCTGCCTGAGTTTTCCGCTTGCTGTGTGTGAGCCAGGGGTTGGAACCGGTTCAGTGAACAGAACTGAAAACTGGAAAATCATGTAGTTCAAAACAAGATGCCCAGCACTTCAAGCCTCCTCCTCCACCCTCTCTTCCCACCCACAACATTTTAGTCACATCTCACTCCCTACAATTGTCTGTCCAATGCATGTAAACAACTACAGCTTGCCCACTCCATAGCAAGCTACTATATCCGCACTGATTGGTAAAGTAATTTAATGTTGAGTTCAATGTTTTTTAGAAACTATGATTGCAGAGGTTTAAAAAGGAACAGAAAGGAACAATATAAACTGCTACTAATTTGGGGAATCAATCCGGTTCAGAACTTTATTTTGCTGGTCAGAACAATGGAACTGAACAAAAAAAATGGTTTTGTTAAAAACGATGCGATTGGAAAATACTTTTGCTTCCAACCCCTGGTGTAAGCACAGTGAGTTGGCAGGTCTAGAGAGAGAAGCACAGTGAGTTGGCAGGTCTAGAGAGAGAAGCACAGTGAGTTGGCAGGTCTAGAGAGAGAGAGAAGCACAGTGAGTTGGCAGGTCTAGAGAGAGAGAGAAGAACAGTGAGTTGACAGGTCTAGGGAGAGAAGAACAGTAATTCAGACAGGTCTAGAGAGAGAAACACAGTAATTCAGACAGGTCTAGAGAGAGAAACACAGTAATTCAGACAGGTCTAGGGAGAGAAGAACAGTAATTCAGACAGGTCTAGAGAGAGAAACACAGTAATTCAGACAGGTCTAGGGAGAGAAGAACAGTAATTCAGACAGGTCTAGAGAGAGAAACACAGTAATTCAGACAGGTCTAGGGAGAGAAGAACAGTAATTCAGACAGGTCTAGAGAGAGAAACACAGTAATTCAGACAGGTCTAGAGAGAGAAACACAGTAATTCAGACAGGTCTAGGGAGAGAAGAACAGTAATTCAGACAGGTCTAGAGAGAGAAACACAGTAATTCAGACAGGTCTAGGGAGAGAAGAACAGTAATTCAGACAGGTCTAGAGAGAGAAACACAGTAATTCAGACAGGTCTAGGGAGAGAAGAACAGTAATTCAGACAGGTCTAGAGAGAGAAGCAAAAAGCACAAGAGAAGCATGAGATGATTGATGTGTGGAACACTTGTTTGTCCTCTAGGACAGACAAACAACTATGTTAGTACTGAATTTTAATCATAGAAACAGAGGAAGTGAAGTGTATCTATCTGCTGAATGTAATTGTCCAAATTTCTGTTGTGAGAGAATGAAAAAGTACAGATTGAAATTATGTTGCTATGCAAAATATGTATTGATACCCAATGATATGTAAGAATTAGTGACTACATGTGAAGCCAATTTGATCGGGATTCATCACCAGTAGCACATCTTTTTTCCTGATGATGGTAGTGAATGGTCATTGTTCCTGTATAGCAACCCTTTAACAGTGGTCATCACCAAGCCAAACCTGTGAATAAACCACTTCCTCAATCTGAGAGCCTGGTCATTGTACTGCGTCCGTCCAGGGGGACTACAGTCGGACAATCTGGGATTTACAAACAGCAGCCACAGACGCAGCAATAACATCATCCAGCCAGTAGATGGCAGTATAGGATAATCTGTACCAGATCTAGAAGGTAGTAAGTAATAAGACAACAAACACATGCATTTTGAGTTTCCACTATTGAGATACCTTTTAAGTGCATGGGGTTATATTCCATTTTTTGTTGTTTAAGATATGAGTAATATACATATAGATATTCTATTGGGGCGGCAGGTAGCCCAGTGGTTAGCGCGTTGGACTAGTAACCGGAAGGTTGCAAGCTCGAATCCTTGAGCTGACAAGGTTGTTCTGCCCCTGAACAAGGCAGTTAACCCACTGTTCCTAACTGACTTGCCTGGTTATAATTCTATATGTCAGAATATTCGAAAAACAAACTACTAGTTTTGTTCAAACTGCAATTAACATTTGAGAATTCAGTCGCATAAGAGCTTGCTTTATTTATTGTTATTATAAACACAACAAAAAGGAAAACAATAAAAAATGTTACTGTTCATCAATCTTTATATATTGTCATAAGTTAATGTATAACAGCTCCAAACAAACACAGGGTAAATGCCTCAGACATTGCAATCTACACAAAAAAACAACATGTAAATACAAATAACTTGTGAAATCATGATATACTTAAATCTATACTTAAATCAACAAAAATACAGATCAACTAAATATTTTACAAAAAAATCTAAATTTGTTTTTTAAAGCAACAATGTCAACACAAATAAAATGCATTTATTTAGCAAAATCCTCCAAAATCCTCCTTACACAAAGATTTAAGTCAAATATTCAAAATAAACCCAGTATGTCAAATTCATATTGATGGGTATTATGAACCAAAGCAGTAAAGTCA
->XM_051681377.1 PREDICTED: Myxocyprinus asiaticus CDC-like kinase 4b (LOC127431112), transcript variant X2, mRNA 
-GCCAAATGGAGCAGGTCAAAGAGACCGAGAGGGAGAAGAATGGTTACCACTACAGCAAGTCATCCGGACGCAGTGGGAGGAGTCGGCACAGCAGTAGAGAACGCCAGCGATCACGCCATCACAGCCCCTGCTCAGACTCGATGAGATTGTAGGCACCCTGGGCGAAGGAGCCTTTGGAAAAGTGGTGGAGTGCCTTGACCGTTCAAAAGGTGGTGCAAGAGTGGCCCTGAAGATCATCAAAAATATTGAGCGCTATCGGGAGGCAGCCATGACAGAAGTAGATGTGCTTGAGCGGATAAACTCGCTTGATGGCGATAAGAAATTTGCCTGTGTTCGGATGCTGGATTGGTTTGATCACCATGGTCACATCTGCATAGTATTTGAGCTGCTGGGACTGAGCACATATGACTTTCTTAAAGAGAATGGATTCATGCCCTTCTCAGTGGACCAGATCAGATGCATGGCAGATCAGATCTTTAAAGCTATACGCTTTCTGCATCAAAATAAACTGACGCACACTGACCTTAAGCCTGAAAATATTCTCTTTGTGGACTCCACGTATGACATGGATTATAACTCCAAGATGAAACGAGATGAGAGGACCTTGAAGAGGTTGGATGTCAAAGTGGTAGACTTTGGTAATGCTACATATGACCACGAGCATCACACCTCTGTGGTGTCAACTCGCCACTACAGAGCCCCCGAAGTTATTTTAGAACTGGGCTGGAACCAGTCATGTGATGTGTGGAGTTTGGGCTGTATTCTGATTGAGTTCTATCTAGGATTAACATTGTTTCAGACTCATGACAGTAAGGAGCATCTTGCCATGATGGAGAGGGTTCTAGGCCCCATTCCTACTCACTTACTCCAGAAAACCAGGAAGCGACGCTATGTGCATCATGATAAACTGGACTGGGATGAACTCAGCTCGGCTGGGAGATACGTGAGGAAACACTGTAAACCTCTAAGGCAATACATGTCCTCTAAAACCCCAGAGCACGAGCTGTTGTTTGACCTGCTTCAGAAGATGATGGAGTATGACTCATCGAAACGGATCACCCTGGAACAAGCCATCGGACATCCTTTCTTCAACCCATTACGAAAAGTTAGGAGAAATTGACTTTGAAGGGGACACTTGAACATTAATGCTCCCGGGGAGACCTGCTGCTGACTGTATCAGTCAGCTTAAAGACTGCCTACTTTACATCCTCTGTCTGTTTTTATTGTCTGTTTGAATATATGGGCCAAATTCCTGTGTATTTTCGGCAAAATAAACTTGAATGCTTTGTATGCA
->XM_039837429.1 PREDICTED: Pteropus giganteus SEC22 homolog C, vesicle trafficking protein (SEC22C), transcript variant X2, mRNA 
-CCTCGGCTTGTCAGTCCTGTCCGCTACCCTGGCAGGAATCGAGCTTACACCGCGAAGCCTCCTCGCATCTCCAGACGTGGGAATTACAGGCCTGGACCTCAAACCCAAGCGTGTGTCCTCATGACTTCTCTTGCGGACCATGTCCATGATCCTCTTTGCCTGTGTGGTAAGGGTGAGGGACGGACTGCCCTTCTCGGCCTCCACTGACTTTTACCACACCCAAGATTTTCTGGAATGCAGGAGACGGCTCAAGACTTTAGCCTCGCGACTGGCCCAGTATCCAGGTCGCGGTTCTGCACAAGGATGTGACTTCAGTATACATTTTTCTTCTTCGGGGGATGTGGCCTGCATGGCTATCTGCTCCCGCCAGTGTCCAGCAGCCATGGCCTTCTGCTTCCTGGAGACCTTGTGGTGGGAATTCACAGCTTCCTATGACACCACCTGCATTGGCCTCGCCTCCAGGCCGTATGCCTTCCTTGAATTTGACAGCATCATTCAGAAAGTGAAGTGGCATTTTAACTATGTAAGTTCCACTCAGATGAAGAGCAGCTTAGAAAAAATTCAGGAGGAGCTCAAGTTCCAGCCTCCCACTGTTCTCACTCTGGAGGACACAGATGTGGCAAACGGGGTGATGAATGGTCACACGCAGATGCTCCTGGAGCCTGCTCCTACCTTCCGAATGGAACCAGTGACAGCCCTGGGTGTCCTGTCCCTTATTCTCAACATCATGTGTGCTGCTCTGAATCTCATTCGTGGAATTCACCTTGCAGAACATTCTTTACAGGTTGCCCATGAGGAAATCGGAAATATTCTGGCTTTTCTTATTCCTTTTGTAGCCTGCATTTTCCAGTGTTATTTGTACCTGTTCTACAGTCCAGCCAGGACTACGAAGGTGGTGCTGATGCTGCTCTTCATTTGCCTGGGCAACGTGTACCTGCACGGGCTGCGGAACCTCTGGCAGATCCTTTTCCACATCGGAGTGGCTTTCCTGTCTTCACATCAGATACTGACGAGGCAGCTTCAGGAGAAGCAGTCCGACTGTGGAGTGTGAGGGTGACAGTGTGCGAGGAATGGATCCTTTGATTTTCTTAGAGGGTCAGCCGTGTGTCCCTTTCGGCTTCTCGACTTCACCTCAAGTTTCCATTCTTGAAGTTCATCTTGACCAAACCCGACTGATACCGAGACTTGGGGACTTTGAACGGGTGCAGTTGAGGGTACGAGGTCGCTTGACACCCAGCCCCGGTTTTGTGCTGAGTATAAATTCCTGTGAGACCTCCAGTTCGGCACGTTTACTTAGGACAGCAGACGCTGGGGGCTCATTCAGAGAGAGCATTATTACAAGATCAGAATGGAATTATTTTGGTCTTTCAAATTGAATGATGTAATAAACCACTAGGCTCAGTAATACTAGTTTATGTTATTGGCAGTTGTCTCCAGGGAGCTACCTTAAAATCCATATCAGCTTTTCAGTATAAGTGTGACTTGGTTAGCTTTTATAGTGGGTCAGTACAGGTGCATTAAAAACTTAAAAACATGGTTCATAAATGTAAGCAAGGTAAATTCTGTTTACATATTTGATAACAGGTTCAATACAATACCTTTAGAATATTTAAATATATTTTGGATATAAATTGAACTTGGTTTAGGGTAAGGACAGACAAAGAAAATGGTTTAAAAGCTGAGTTTAATTTGTACATAACCTTTTGTGGTGGGACTGTGTGGGCACAGAAATATTTTGTATTTATTTGCAGGGTATATCTGAATATTTTAAAAGTTGAATAACCAGTGCTACTGGATCGTAAGCTTTTAAGCATGAACAGAAATGAGACTATCAGGATTCTTTGCGGTGGGCCACAAACTGGAGTAGGTGAGTCACGTGGATTCACACAGCGGCACTTTTCAGACGTAGGTGGGAGCGGCCGCCGTCATCAGCCTTGTACAAGGTAGTCGAGTGCCTGCCATTTTAATGATGGTGAATGCTTGACCCGTGTACCTGTTCCCAGAACACCTCCCAAATTAATTACTCCTCTACACCATTCTCAATCCTCTTAATTAGATCAAGGGCTTCATTTTTTATGAATAAGAGTTAAGTAGATATTAACTTTTTAAAAGCTTTATGAAGATATAATTAGCCCTCTGAAAAGTTCCTTTTGTTTTTTCTCAACTATGATTGATCATAGTTTTCCAAAACGTAGACCCGAATCAGGTCCCTTAGCTCTCTGGACATTGCAGCCTGGGCTGTCCGGCACCACTTAGGAGGCCTTTTTGGGAGCCTGCCCTTAGGTTGTTCCTGGTATAAGTCTGGAATATGAATGGCTCAACCACAATTGCATGGAATACTTGGGGTTGAATTATGTAGTCTTGAAAATTCAACACATCCTATTTCGATAGTTCTTCAAAGTTGAAAACCATTGATTGCAAGAGTTACTGAGCACATGAGGGAAGCAAGGAGGTTTTTCAGGGAATTCCGTTAGACGTGGTTGTTACCAGTGGTGTATCGTTGCTGAGCTACCTTGATATCGTTTTAAGAAAAACAAGTTTACGTAACTGGAAACCGTTGGGGGAAATGTTGCCAAAGTCATTTTATTTTCTTATAATAGAATTTTCTATTTTTCATCAAATAAAATATCTGGGTATGAAAGTTCTGTTGGCAACACCGTCAGATGGAAACTTCAGAGCTGTTTCTCTGTCGACTACGTCTACATGATTTTCTGCATACCCAGCAGGTGAATGTTCAGGCTTTCCGGGAGATAATTTTGAAGAGACAGTAAAATGGAACGGGAAGACAAGGAGGAGAAAAAAATTCCTTTTTTGTGATAGAAGCACAAAAAGCTTGAAAAGTTGGTAAGAACAGCTTACCAATGAATTGTTTTCTTTTTGAGCCCCTGTGCCATTGGTGTTGCCATGTAGCCCTGTACCCCAGAAGCTCTGGGGGTCTGGGCCTGTGACCCACATTCAGCAAGCAGTACAGAACAATCCTTGAGGAGGACTCCCTCCTAGTGAAGGCTTTCTACCCTAGCAGAGATGTTATCCTCACTGGGTTGAATGTGGTCTTAATCCGTTAACATCTGCTTGGAGGTTGAGATTAATTTTGCAAACAGGAAGGAAAAGATGCACTGGGTGAGCAGCACCAAATAATGGCCACGAAAACATAGTGTGACTAAAACCCAGCTAAAACTCAGCTCACTGTGGGGAGAAACTAGTGATGGGAAAGAATTTCTGAAGATTTTGTCCAAAGGAAGTCCCAGGCTCAGGGTTGGCTTGGTCCAGGCCTGGAGTTTCGTGGCCCCCGTGTCATCCTGGGTGCCAGAAAGCGGGCTCCACATCGCAGTGGTTATCCTCACCCCACCATGACTCAGTGCCGCTCCAGCACCTTTTGTTTTCCCAGTGGTTAAATGCCGCCTGCCTGGCCCACCTCACAGGGCTAGATCTGGGAATAGATGAAATCACGTTGAACACAAAACCTTAAAAGTGCCTTCTGGTACCAGATGCTGCAAGGTCTGGAGCATCAGAGTGTGTTACATCTCGACTACTATATTGGGGTGGGAGTGTGGCTCTGTTCGCAGGCTTTGCCCCTTTCTCAAGCATAACTAGTGAAGGACAGCTGTAGACTTTGGTTTTCTTCTCCCCGGGCTAGCCTAACTGTGATAGGACCATTTCTGGGTTTCTGTTTCCTGTGTGGGGACAGTCAGGGCATATTTGGGGTGGTATCTGCCTCGGTGCTAGGAGCCCCCACTGCCCGCAGCAAGAGGAGTACGACCACAGCCTCCCGGCGTTGCTTTCCAGCCTCGCACCCCTGTTACCTGTGAGCTCTGTTGATGGACAGTGTGAATCGAGGCCCAACATTTTAAAGTTCTTTAAGAGGTGGGAAAAGGGCGTCGGGACGAGTGCTGAAATGAAAATGTGTAATCATCGTTTCTACCCACCTCACTTTGAGCTCCCTGTTCTTTTCCTAGGTGCCCCTGTTCTCCAGGTCCCCCCGCCCCCACTGCTTCCCACCTCTGCCCCCCACACTCCAGCCCTGGGGACAGAGGCTGGAACCGGAGTCTCTGAAAGGGAGGGAAAGCCACCTTTAATTGTATCAGTAGGGTGGGTGCAGGAGCTTCCGAGGAGAGCAGAAGGTGCACTGTGCACCCTGGGGAGCTCAGCACATACTGGGAGTTGGGTCTCGGAGGGAAGTAGCACTGCTTAGAGTCAAAGACAATAGCCAGCAAGGTGGGCTGTTTGGGGTGCTGGAAGCAGGGGGGTAGGTGGGAAGCAGAGCTGGAAGACAGCAGCCTCCCCTTGGTGTGTGGGAGCTGCCGCTTGCTGTTCCTCCAAAGAGTCAGCCACTCATTGTAACAATCAGGACAGGTGGCCCTCAGAGAATCTGCTGCTTGCACTGTGTAACACAGGTGAGGGCCAGTGGATGGGAGTGTTCACGGGGACCGGATGTGGGCCCCTGCCCTGACCGGATGTGGGCCCCTGCCCTGATGCTCCCGGTCCGATAGTTCCTACGGGGAATCCTGCCTGAGGACAGGGAGGCGCCACCTGAGTGCTGTGAATGTTCACGGTGGTGGAAGAAGAGAGAGCAGACGTGCCCTTGAGAGAGGAGGCTGGGGAAGGAGTGTACTGGTCAGCTGGCTGGAAGCCTGGCTTGGCTCTGACATTCGGTCTTGCACCACAGTGGCCAAGTCACTGCCCTTCGGCCCCAGTGTTCCCATCTGGGAAATGGTGATAACATCCGCCTGTCCCCTGCTGTCACGAGGATAAAAGCCTAGTGGAGGGGAATACTGGGTGAACCCATTGTGTGTGTGCAGGCGGGAGGCTTTGAGTTCACCTGCCACACGGAGGTGTCTTCTGGCCTTTACACAGAAAAAGACACCGCAGTGTAAATGGCTGTATTCTTTCCCTCCAGAAAGGAAGCGGACTCTTCCCCTTCCCCTGACCCTGCCTCCTTCCTCCAGGCACAGAGCCCCTTGGTACCGCTGGCTGGGGTCCTCCAGGGTCCAAGGAGGCCAGTTCTGCTGGTTGTGTTTGAGGCTTGTCCTGGGGAACCAGGGGCTGAACCTCAAGGTTTGTCCCTGACCCAGATGAGGAAAGCTCTGCTTCTCCCATCGGGGAGCAGTGATGTCAAACGTCTGTTGCTGGGGAAATGTCATTGGCAGGGGACCTGTGGAAAGGGCTTGTTGGTAAAATCTGGGAATGGCCGGATATGGAAACATCTGGCTGTGTGTACCGATGGCAGAGCCGTTGCCCACAAGCGCCCTTTATTTAGGGTGAAATTATCAAGTCCATTCTGTTCCTCTAATCTGTACTTGGTACATATGACCTTCTCGAACGCTTATCCGTGTATGGTTCTGGGGTTGCTTCAGAAGTAGTATTTAATGAGTTGTTTATATGACCCCAAGATTCTATTTTGTTTAATGAACTTTTCTACTGAGAGCGTAAAAGACTGAGTCTGATTTAGCCAGGGCAAAACCATTCATTTCATATATTCATTTTGAATGCTTGCTGTCCGTGTTATACAAGCTTCTTAACTGTTTTCATGTAATAACAAAGATCTATTTTGAATAAACGATGGGTACGTTTTAACAAACTTCCACACAGTAGTAAAGCCTAACCTTGTGTTAACGTATGTGCAGAATGTTGCATAGCCATTTATATACTGTGTATATGTAAATTAAATGGGGTGGCTTCAGAAGTGAGAAGAGAATAAATCTAAGGTGCTTCTTAACGA
->XM_028554974.1 PREDICTED: Dendronephthya gigantea vegetative cell wall protein gp1-like (LOC114533457), mRNA 
-TTACTGAATACAGTACAATGATTTTTAGTTTAAATTACAAAGTCAGAGGGGCTGAAGCACCATGTTACGCCTATGCTCTGTTCTTTCGATATTTTCCATCATCTTATCAAATTGTGGAGAAGTACACACAAAAAAAGAAGCAGACAAACTTACTTTGTTAATGAAAACAAAATGCAAGCAATGTACTCATATTTTCATATGTCCTATGATATGCGGTAAAAATAGCACTAAGCCAACCATTAAACCCCCACCCACCAAGCTACCTCCAACCTCTACACCGATCTTTCCACCAACGCCACGTCCGCCGACACTACCACCCCTTCCTCCAGTAACCCCTGCTCCACCGATCATACCGCCATCTCCATCCCCTCCAACCAAACCTTCCCCACTGCCGCCAGCAACCCCTGCTCCACCGATCATACCGCCATCTCCACCCCCTCCAACCAAACCTTCCCCACTGCCGCCAGCAACCCCTGCACCACCGATCATACCATCTCCACCCCCTCCAACCAAACCTTCCCCACCACAGCCAGCAACCCCTGCACCACCCATCATACCATCTCCAGCCCCTCCAACCAAACCTTCCCCACTACCGCCAGCAACCCCTGCACCACCGATCATACCATCCTCACCGCCACCCACAACCCCTACTAGTCCTTCTGGTGGTCAAGAAAAAATCCGACCACCCTCACCAGTGACCCAAGCCCCACCAGTTATTGTTCCCACATCTGCCCCAGTCCCACCACCATCGCCATCCATTCCTGGAGAATTATCATGTCTAGTACGTCTTGAGAAGAAAGGATGTTTTAAAGACGATCAAATTCCTCCACGTCCTCTTCCAAACTACATCTTAACTGATCGCGACAATACTTTATCGATTTACAGTGGCAAAGGAATTGACTGGGGAAATTGGGTGAACTATCTTCCTGATTTCGTGTGCCGTTGTGCCCAACTTACTAAGTCTAAAAATTTTAAATACTTCGGAATACAATATTATGGTGAATGTTGGTCAGGTCCTTCAGGAGACGAAAATTCTTTCAAAGAAGATGGAGTTTCAACAGAATGCGTCAACACGAACTGGAAGACATGTTCTGATCAATCAAAATTAGCTTGTGCTGGAAAGGAGAAAAATAACTATGTTTACGCAATTGTTTAATGTATTTTGTAGTAGTTTGAAATGATCTGTAACCTAGTCTGGGAGGAATATAAATAGGAAATAGCCTAAAGTGTTATTGCATGCATTCACCGCTAGATCATAATGTTATTGTTAGATCATAATGTTACTGTTAGATCATAATGTTACTGTTAGATCATAATGTTACTGTTAGATCATAATGTTACTGTTAGATCATAATGTTACTGTTAGGTCATAATGTTACTGTTAGATCATAATGTTACTGTTAGATCATAATGTTACTGTTAGATTATAATGTTACTGTTAGATCATAATGTTACTGTCAGCGTTAACCTATAGTTAACATGGCTCCAGTTTCGGCTGACCGTTGATAAATAGAAACGAAAATGTCAGCAAAAAGGAAATGAAATTTATTATAAAAATTATTAAAATTTCTCCTGCTGCATGGGCATATATATGCTTCACTAAAGTTTTACATTACCCCATGCTGAACTTCGACATAATTTAATTTGTTCGAAATGCCTTTTTCAAACAAATCTATCCCCTTTCATGAAAAAGTTCCAATTCCATCTCAAAACATTTACATATCCGGGGGCATAAAATATTCCTTACCGCTACATGGCTGGTTTGGGGTTGGTTTATTACTGTTTCCTTGGCACAGTTTATAGACAAACAGTCGGACTGCAGTGTGGAGAGTACTACTTAGCTATATACGGTGCCGTTTATAAGTAACACGTATCAGGCCGAACGAAAATTTTACAAAATATACTGATAACAGTGAGTCAAATCCAACGGGGGTGGAAGTCAATTTGATACCTCCTCACCTCGTCCTTTCATATCTATAAACTGTGCCAGGGAAACAGGAATAAACCAGCCGTAAACTAGATAAAATGAAAATATTTGTTCCGTTGCACGAATAAAAACATTCAATACAGCAAATACACAAAAATAGAGCTAATGCGTTTACCGTAAACGTCGAATTCGTACTATTAATGTA
->XM_039788533.1 PREDICTED: Perca fluviatilis E3 ubiquitin-protein ligase MARCHF7-like (LOC120551252), mRNA 
-GCAACAGGGCGCTGAAAACCTCATTAGGCGCTGAATACAGATCAAAAGTGGTAGATACAGAAGTGAAACGACAGATTCCAGGCATGCAGGCTTTTTCGACACTGTTGCAGCGCATGTCTGCAAGGAAGGCCTCAAAGCAGCCGTCCCCCTGCAGCGCTGGGAAAAGTGCTTTGTCTGAACCAGAGAGCCAATTGAATAAAGATTCGGAGTCCTGCCTTCAGGCTATCTCCAGTGGAACCCGGAGCATGTCTGCAGAGCTGGCAATGACTTCAAAGATTCCCCACAGAGAAAAGGCGCCCCTGGCATCCAGATTACTCCCCGCAAAGGATCACAACGATCACAGGTCTGAGCGTGTGAAACACAAAGGATTAAAAGGATCCACCCAAGCGAGCAAGCAAACACAAAGCCGGGACGTCCTGAAGAGCAACAGCAAGATGAAACACCTTTTCAACAAAACAAACGTTGAGGATGTCATACACCCCAAAGCTGAGACTACGTTTGCCTTCCCAGCAAGTACTGACACTGTCCCGCATGTTCCCACACGTGATACAGGCTCACTGTACAGTGAATCTGAAGAAGAGGAGGAGGCAGATAATGACCCATCAAGCTCACTGTACAGTGAATCTGAAGAAGAGGAGGAGGCAGATAATGACCCATCAAGCTCACTGTACAGTGAATCTGAAGAAGAGGAGAAGGCAGATAATGACCCATCAAGCTCACTGTACAGTGAATCTGAAGAAGAGGAAGAGGCAGATAATGACCCATCAGGCTCCTGTCAGGGCACATTTAGAGAGGCCACCTATCCATGGCAAGTTTCTCGGTCAAGCTCAGCCTTCCGTTGCTTCTCTCACAGTTCACACCTAAGTACATCAACAGTTTCACCTGTTGGTCGTCATGGATACGGTCCTGGTCCTTTCCTGGAGCGAACAAGGCGACCTCATGCAGCATCGCTGTTATCTACCACTGACAAACTCAATAGGGGTTTTGTAGGCTGTGTGAGTAGCACTCAGCAGACACACCAACATCTCCATAAGTTTCAAAGCAGCTGGCCAAGCACAGCCTCTTCACACAGGACTGTCGGCTTCTGTTCTGCTGGGTTTGCTGAGAAGCAAAGCTACCGTACCACTGACTACAAATCGAGGTCTTCTAATGAGTCCTGGCGTCTAAGTGCCTCTGGACAGGTAGATAATCTGAATGTGGATGATATGACGACGTGTAGTGATATCAAAGAGCGAGTACCCAGTCAAGAATGTCAAGAAGCCCGGGAAGGAGCTACTGCTGCCCAAAACGCTCAGTCTCTAAAGGATCGCAGCAAAGAGACTGTTTGCAGACCCAAACAAAGGTTATTAGATGAGTCATCTGATGAGGAAGAAGGGGAGCAATGTCGAATCTGCCACAGTGGCGAGAGTTCACCAACCAACCCACTGATATCACCGTGCCTGTGTTCAGGCAGTATGCAGTTCGTTCACCTCGACTGCCTGAAGAAATGGATTAGGACAAAAATCGAGTCAGGGTCAGGGCCCTATACTGTCAAAAGATGTGAACTTTGTATGGGGAGGCTGACTCTGGACCCGGATACACTTCACTTGGACGTTTACTACAGAGAACAACAGCAACAGATGTTGGGCAACCCTGACCTGTATGATCTCAATGATGTGTTTGGAATGCTAAGGCGGCCAAGACTTGTGCACGTTCCGATATGGTCATTGCTTTCCAACCTAAGGAGAAGACTCCTCAGAGGGAGGAGGAACCCCTCACCACAAGAGACATCGGACACTTGATCCTCAGCCAAACTCCTTTTTTTTCCACATCTTTGCTGATGTGGAACTAAACACACATGTTTTACAATAAACCACCATGCATCTAA
->XR_006693933.1 PREDICTED: Macaca fascicularis uncharacterized LOC102122981 (LOC102122981), ncRNA 
-TAGAAACAGGGGTTTCACAGTGTTGACCAGGATGGTCTCGAACTCCTGGACTCAAGTGATCCTCCCACCTCAGCCTCCCAAAATCCTGGGTTTACAGATATGAGCCACTACGCCCAGCGTGACAGAGCATGACTTCTGAGGGTAGGTCATAAAAGACATTGTGACTTCCGGTTTGTTCTTTGAACACTTGTCTAAAGGAAGTCAGCTGCCATGTCTCAATGACACTCAAGTGGCCCTATGGAGGGGCCTAAAACAGCATCCTCCCGCCAACAGCCATCAAGGAACTGAGGAACTGAGGCCCTTTGCTAACAGCCATGAGGGCACGATCATGGAAGTAGATCTCCCGCCCCTGTCAAGCCTTCAGATAACTGCAGCCCCAGCTGACTGCTCAACTGCAACCTCGTGAGAAACCCTCAGTTAGGACAACCCAGCTAAGCTATTCTCAAATTCCACAGAAACTGTGAAATAATACATGCTTTTGTTTTAAGCAACTAAGCTTTGGTTAATTTGTTACACAGTAATAGACAACGAATACAGCTGGCTTATCAGCCTCTCCTCTTTTTGCAGGCTGCAGGACTGCCGAGCTTCGAGGGAGCTGAGAGGAATGCTGTATTCAGGCCCTCTTACCTGACTTGACCTTGAGACCAATGGGTGTGTTGGAAAGAGGCTGGCAAGGTCTGAGGGTACAGCCTGTGGCGGAGGTGGGGCCAGGCAGGCCCAGCCCCTCAAGCCAGGCCGTGGGCCCCAGGGCCCTGCCGGATGGCCGCTCTCTGGGAGCTGCATGCAGAGGTGCCTGGCACCCCCAACCGCGCCCCACGGGGCACCTGACCTCCAGAGGAAGGAAATGAGTCTGGAGATGCCGTAGACGAAAGAGTTGCCGCTTCCTCCGCCTGGGATCACTCACAGATGCCTCAGGGAGGCGGCCGGCCCTGAGTCACGCTGAGCGCTGAGCCGGCTGTGACTCAGCGGGACCGCGGTCCCTTGGTTGCGCCTGGGTTGATTTGCGCCCCGCTTGTTTTCTGCAGAAGACAAGGCCGTCTCGGATTAGACTGCCCCTCCTAAACAACCAGCAACTGTTTTTCTTCCTCAAAGTGCAGTTTCCCTCTGGCACAACCAAAAATAAACACAAACCAGGCTCCTGCCCAAGGAGGAGGGGGGGAGGAAGACAGTCCCCGGGGCGCCCACCGAACGCATGTGAGAGCTCGCAGGTCACCTGCTTGCATGAATCTGTGAAGCAAGCAGCCATGAAGGCAGAGAAACCTCTCCCATCGCAGGCTGCCAGCACAGAGGCTCTGATTGTTGAGTTGGCGCTCTGTTTATTTCCCCAACTGCCTCCTCTCAGGTTCCGTCCTAACTGCTGGACTCACTGCCGCGTGGGCCTGAGCACATTTCCTTGGCAAATTGTCCTCAGTGGAAGTTTTTTCTTCTCGATGTGGTGAGTCAGAGCTGGCTCACACACAAACACCAAGCAGCAGCCTCAGGGACTAAAGTGCTTTAAGGACACGAGGACCTATCCTCCCTCCCCCTATCTCAGTGGGGTGGGCCCACAGTTCCTGAAAGCTGGCCCAGTGCAGTTCATTTGACAGGCAGAGGCTGAAAATGCAAATCACCCCAGCATAGGTGAGTGCACAGCAGAGACCACGCCCGGGCTGCAGCTTATCCTGAAATCCTGAAGGCAGGAAACACCGTGCCCACAGGAAGAGCTGGGAAGCCTGAACCATGCTAAGATGTCCCAGGGTGAACCGGAGCCACTGGTTAGTCACACTGACTTCACATTTCCTTCGTGAGAAGGAACTGAAGACAGATTCCAGACTTGCTGTGCATAGAATGTATAGTTCATTGCATGTGAGAACACAGCAACAAGGCACCATCTTGGAAGCAGACAGCAACCCTCA
->XM_043685587.1 PREDICTED: Chiloscyllium plagiosum uncharacterized LOC122546987 (LOC122546987), mRNA 
-ATGGGAAATCAGACTTCTAGACTTACTAAGGAGAAGTCAGGGAAGACTGCAAATGGGAAAGAAATACCCCCCGATAGTCCACTAGTTCGGAAGGTAACTCTATGGACGGACAGTCGTAGAACGAAGGACTTAAAGAAAGACACCATGATAAAATATTGTTGTTTTATATGGACCAAAGAATCTATCCGCGCCCCCTCGGTAGTTTGGCCCGAGTATGGTTCTGATGAAGACTGGGTGTGTCTAATCCTAAATGTATATGTTAACAGAAAACAACCGTTTGACCCAGAAGAGAGCAAATACGCCGCCGCCTGGTTGGCGGGCGACGGCGAGAGTCCCACGCGTCTCTATCCTCTGATTCCCCAAACAGACCCGAGGAAGCCCCAGAAGTCTTGGGACATCCTCACTGACGGTGCCGTTGGGAACGAACGGACCGGGTTCGTAGTACAACCTTTAAATTCTGGGGATATCCGGCAACTCCGTAACGAACTACCCCATCTACTGGACGACCCCATCAGTGTGGGAATACAACTGGACCAATTTCTGGGGCCCAGTATATACACATGGGCTGAACTGCAGGCCATGATGAGAATACTATTTAATTACGATGAAATTGTTATGATCCGGAATAGTGCAATGGCCATTTGGGATAGGGAGCATCAGGACGGCCCTCAGCGTGGAGAGCAGAAGTACCCCTTAGAGGACCCCCGGTGGGATCATAAAGACGCGGGGGGATGGGCCAATATGACAGATCTCAGAAGCCTTATAATCAGGGGGATCCAAACCTGCGTGCCCAAACAGCGGAATTTAGCGAAAGCATTCGAAGTTGGACAGAAAAAGGATGAATCCCCGAGTGAGTTTTTAGACCGTTTGCGGGAGTCCATGCGAAAGTATTCAGGTTTAAACCCCGATGGGGAAATAGGCAAGGGCATGCTTAAGGTGCACTTTGTGACTAAGTCATGGCCTGACATTCAGAAGAAATTACAGAAAGTGGAGGATTGGGCTGAAAAAGATGTTGCAGAATTATTACGGGGAACACAGAAGGTGTACGTTCAGAGGGATGTAATAAGGGAGAAACAAAAGACAAAAATGATGGTGGCAGCCGTACGGGAAGCTTGTAAGTCCACCGGAATGGGGGAGGGAGGTTATGGGGTGGAAAGAGGAACGTCGAAGAAAAGTTGGAGAGGGAGAGAAGAGAGACGGGGCAGAAGTGAGAGAGGAGGATCTTATGGAATTGAGCGGCCTCAGGTGGCCGGATGTTATCATTGCGGGAAACTGGGACACTTCAAAAGGGATTGTCCCGAGTTTAAAAGGGAAAGAGAAGGGATGTATGAAATGGAGCGTGAACAAATGGATTAGGGAAGTCAGGGGAGGATCGGACAAACGTGCGAATTGTACGCCTTGCACC
->BT024918.1 Arabidopsis thaliana At5g50110 mRNA, complete cds 
-ATGAACCTTACAGCAACTAAAGAAGCTGATGAAGTAATGGAGAGGCATATCGAAGATTCTCTTGCGATATTGCCTCCTATAAAGACTTGTTACAACTTACATTCCAGTGATTTGTTTGATCACATCAATTTAATCGATGTTGGAAGCGGGGCTGGTCTTCCTGGGTTGGTTCTAGCCATTGCATGCCCAGATTGGAGAGTTACTCTACTGGAGTCTATAAATAAGCGATGTGTTTTCTTGGAGCACGTTGTGAATGTTACCGGGCTTACAAATGTTACAATCGTTAGGGGCAGAGCAGAGAGTTGTGGGCACGATGTTATGTACAGAGAGAAGTTTGATGTGGCTATTGCAAGAGCTGTCGCGGAGATGAGAGTCTTAGCTGAATATTGTCTTCCTCTGGTTCGGATTGGTGGATTGTTTGTAGCTGCTAAGGGTCATGACCCAAAGGAGGAAGTTCAAAATGCAGAAAATGCTGTTCGCTTGTTGGGTGGTTCAATACTACAAATTAGTCCAGTGGATTCACATAGCCCATACGGACAGCGGACAACGGTTGTTTGTCGTAAAGATCATTCCACCCCACAAAAATATCCACGTGAAGCAGGTACTCCTGCTAAATTACCGTTGTAA
->XM_041034442.1 PREDICTED: Toxotes jaculatrix potassium channel subfamily K member 15-like (LOC121179542), mRNA 
-ATGAAGACGCAGAACATCAGGACCCTGTCTCTCATCCTCTCCATTATTTTCTACCTGCTCATAGGAGCCGCCGTCTTCGACGCACTGGAGTCCGAAAGTGAAACTTCGAGGAAAAAGACGCTGGAGCAGAGGCTGAACGAGCTGAAGAAAAAGTACGGCTTCACCGAGGATGACTACAGGGAGATTGAGAGAGTGGTCCTTCTGTCGGAGCCGCACCGAGCCGGCAGGCAGTGGAAGTTCACCGGCTCGTTTTATTTTGCCATCACTGTGATCACCACGATTGGTTATGGCCACGTTGCTCCTCGAACTGATGCTGGCAAGGCCTTCTGTATGTTTTACGCAGTCTTGGGGATTCCTTTGACGCTGGTCATGTTCCAGAGCCTGGGCGAGAGGATCAACACTTCTGTCCGCTACCTGCTGCGAAGAGCCAAGCAGGGCCTGGGCTTTCAGAAGACGGAGGTGTCCATGGGGAATATGGTCCTGGTGGGTCTGCTGTCTTGCATGAGCACTCTGTGCATCGGAGCTGCAGCCTTCTCCCATTTTGAGGACTGGACCTTCTTCAACGCCTACTACTACTGCTTCATCACACTCACCACCATCGGCTTTGGGGATTTTGTAGCCCTGCAGAAGAAAGATGCTCTCCAGAAGCGACCCCCCTATGTGGCCTTCAGCTTTATGTACATTTTGGTCGGGCTGACAGTGATTGGGGCTTTTCTTAACCTGGTGGTCCTGAGGTTCCTCACTGTAAGCTCAGATGAGCCCGACGTGAGGCTTGAGGATGGGGAGGTGTCACACGCTGAAGCAGAAGCTGCTGAAGTGGCATATAAAGACAGAGAAGATGGACACAGCAGCCAGTGCAACCTGAGCCTGCCCATGGAGGGGGGCACTAGCTGTACGAACCTCCTCCCTTCACCTGCAGAGGATCGCAGGCTTATTATATCCGAACAGAGAGAGCACTCTAAGCTCCCTGAACCCAGCAGACTCAGAGCCTTGTTCTCCTGCATCTGCTGTGGCCTGGACATTTACGACAGCCACCCTCCATCTCACCATGAGCAGGAGCGCGGCCACAGCAACCCCGTCTTCTACAACTCCATCTCCTACAGGGTGGACCAGGCCTCATGCAGCTCCTGCACCGTGTCGTCACAGGACTCCCCCACCAGCATAGCACTCTGCCTGGGCAAGAACAATCCTCACAGCAGGAGGAAGTCACTCTGA
->XM_015424951.1 PREDICTED: Gekko japonicus serum amyloid P-component-like (LOC107121936), mRNA 
-ATGGCTGTGGAGCATTTGCACGGCGGGCCGACAGACCTCAAACAGAAGACCTTGGTTTTCCCAGAAGCGTCCAACACGGCTCATGTGGTTTTGAGGCCTGCGCGCCAGCAACCTTTGACCAGCTTCACTGTCTGCCTGAGATCCTACACAGACCTGAGCCGTGCCCACAGCCTTTTCTCGTACGCCACCAGGACGGTCGACAACGAGTTGCTGGTCTTCAAACCCAAACCCAACCAATACAGTTTGTATGTGGGGGGGTCAGTTGTGACCTTCAGCGTTGCAGACAATCCGGTCCCCAAACCGCTGTGGGAGCACATTTGTGTGAGCTGGGAGTCCGTCACAGGAATAGCAGAGCTTTGGCTGAACGGGGTTAGCTTGCCCCGCAAGGGAATGAAGAGAGGTTACACCATCGGTCCGGAAGCTTCTATCGTCCTTGGGCAGGAGCAGGATTCCTTTGGAGGAGGCTTCGACACCAACCAGTCCTTCATAGGGGAGCTCATGGATGTGTCTATGTGGGATCGGGTGCTTTCCTCAGATGAGCTGGTCGTCATTCAGAACAGCGGCCGCCTTTCCAACTATTTGATTGACTGGCAGTCCCTAAATTACGAAATCAAAGGCTATGTGGTGGTGAAGCCCTCCTGGGGGTGAAGCCCTCCTTTGTAAGCCCCCCTGTAGGCTTCGCAAAACAAAGCAGAGAGCTGGAAACAAATCGATAGTCTTCCCCATAATTAATGTTTCTGTTAGTAGTAAGGCAGCATTCCTACAAACGATTTCCTGGACGTAAACTCCTTGGAGTAGCATGGGACTTCCTTCTGAAAAAGACCTGCAGAGACTTGTTCTCGTAGTCCTCAATCTGTTTGTGCAAACGCATTCATGAAGCTTGTAGATCTGTATTCTCCAATGAAAGATTTCAACCCCCCCCCCCCAAGTATTTTGCATTCCCTGACACC
->XR_005453858.1 PREDICTED: Tachyglossus aculeatus small nucleolar RNA SNORA7 (LOC119936833), ncRNA 
-CCCCTCTTAGGGTCACACCTGGAGAGTTTCTAGTACTCTACCAGTCTCAGTTATGGGAGGGAGAGTCAAGTAGAGGCATACCCATTCCATTCCTAGCTTGGCCAGTGACTAGCGAGTGGAAGACAATCTGCTACAAGT
->XR_008035993.1 PREDICTED: Dreissena polymorpha uncharacterized LOC127851864 (LOC127851864), ncRNA 
-TTGGCAAGCGTGGTTAAATGTTATCCTGTCACATAACGTGTTACATAGTTACTTTTGTTTACTGGAGACATAACCTTGCGAAACAAACTTCAAGTTGATTTTAATTAGACTCCGTTAAGGTTGACATTACGTGTTGAGACTTTGGACAAATGCTAGATTGGTGTGTTTTGTTTTGTTTAATAATCAATTAGCTTTAATACCTAAGTTATTTGAGTTAAATCAAATATATTGAGATCAAAAGCTTCAGGGTTGAACAAAATGGCGACCTTTTCACAGTCCACCATCGAAAAAGGATCTGACATCGTCCAAGACTTCTTGTGTTCGGCGTGCGAAGACAAGAAACTGGAAATCTCAGCTGATAATATTTGCGGATCTTGCGTGAAGTTTTACTGCCAATCATGTATTCATTTGCATCGCCAGTTGTTTACAAACCATTCTACTCATGGAAGGGGAAATATGAAGAAATGGCCAGTTGCGAAGACGGTGGAAGATTTTCTTCTTAAATGTGATGTTCACAAAGAAGAAAACTTGGCAATGTTTTGCAAAGACCACTGCAAGCTGTGTTGCAATAATTGTGCATTCCTTAATCACAGGCAATGCCAAACAGTGATGATCTTATCAGACTTAGTAAAACATACCTCCACAGACCTCAAAAAAGTATCAGCTACTATCCAAACTACTCTGGCAGAACTTAAAAAACTTCAAGACAACCAGGAGGCAAGCGTACGGTCTGTGCAAAGTTCCTTCGATGAGCAATTAAAAGAGATACAGGAAACTCGCAAAAAATAATTGAAGCCTTAAACATGCTTGAAAAGAAGACACTGAACGATATGAAAGATGCGCTGGGAAATCTGCAAGCCTCTCTAAAAGCAAATGTTGACAAATGTGCCACTCTTCGTGATCAATTAAAGCAACTTGGAGATGCAATACATGACTTAAGTGATAAAAGCAAGCAATAACTATCTCTTATAGCCAGATTTAAATGCCAGGACAAAATACAGCAGTTTGAAAATGAGAAGAAGAACTTTGTTCAAGTAAGATCTTCAATCACTTTCCAACCTAATAGAAAAATTGTGAAGTACCTTTCTAAGTTGTCAGGTCTTGGGAGGGTTGAAACCAGTACCCAGATATTGACAATGCCGGGAAATCCAGACAAAGTAATAAGGCTGAAAGAGAAGTATGAGTATGACGTGCGCACGCGAGGTGATTCATATGAAGAGTATGCAGTATGCAGTATCAGAGACATTTGTGTTCTCCCTAGGGGACAGGTCTTGGTTGCAGACGCGATGAATAATAATGTCAAGCTGTTGAACCAGCAGTACAAGGTGTTGAGTCACTGTGTTAAACTTGATACGCCATCGGGCATTTTTCAGATCACACCCAGTGAGGTTGGCGTCACTTCTGGTTCAGTAGTCCAGTTTATCAAAGTCAACTAAAGCCGACTGGTGACAGACAGAAAGCTAACATTACAACGTGAATGTAAAGTAGATGTATGTGCAGTGAGCCCGACAGGTGACAAATTGTACATCACCAGCCACTACCAGCACAGGATACTCACCCTTGCCAGAGATGGATCAGTCCTTGCCACATTCAGGGACCAAGAATTACAATGGCCAACTGGTGTACACGTTACATCTGCAGGCCAGGTGCTGGTATGTGGATATGATTCAAAGACAATCATTCAGGTTAACCGTAATGGCAGTAAAAAGCTGGCAACTCTGGCTACAGAGAGGGATGGGCTTCAGGGAGGCACATGGTCCGTCTGCTACAACAGCAACAATGATTCCATTATCGTGGGGCAGTTGAACAACAGGATACTGGTGTACAAATTACAATAGCTTATCATTCTTGTATTTTATATGAGTAACAATAAGTGATATACATTAAAATAGCTATTACATTGAGTGCTTTGTTACTTTGCAAAAATATTTTAAACATATAATATGTTTGTAGGAATAATGTATGTAAATAACAATAGTTGTTTATGTAATAGTGCTGTGTAACCATGCAAACAAACTTCAAATGTGCATACCAATAGTTTTGTAAAAAATAATCTAATATTTTTTTTGTTTTTAAAATCTAGCGTGTTTCTTAATTGATGAGTCTTAAGTGGCAAATATGAATGTTTACTTTTGTTCTTAGAACTCAATATCTTAACATATTATTTATGATACAATATGTTTGTAAAATAGTTTATAAGACATTTTTTACTATAAAGAACTCGTACAGAACAATCATGCTAGTGTTAGACCGTCATGTATAAGATGCATAGCAATTAGGTTATTAATTTATTTCTATTTAAGTAGCAATCATAAATCTATCTTTAACTCACTGGTCTATAAAAATAGCTGATATAATGTCAGTAGCATTTATTAAAACACCTTTTAAATG
->XM_028615390.1 Sodiomyces alkalinus F11 IKI3 family protein (SODALDRAFT_45849), mRNA 
-ATTTGATGCGCAAGAGTTACATCTGCGGAACCCCCACCAAAGTACCAACGTAGTCCCTTTTCATACCTCGAAGATTTTCATCGCAACCACAACGGCAGCAGCACAAAGCGTCCATCGTGACCACCTCAGTCAATAACTCGAAGACGACCTCCACCTCCCTCTCCCTCCCAAGCCCAAACGCCGGGACAGGGAACACTTATTATGACCAGTGATTAGTGACTTCATCACCAACCCGAGAATGCGGAATTTGCGCAACATCCGCTTCGATGCCTGGCGCCTCGCCGACATCACTTCCACCTGCTGGGACCCCGCCAAGGATGAACTCCTTTGCACTCTAGGTCCGACCGAGACGAGACGCTCCATCGAGCTTGTCCGGATTGCAGATACATTTGAGCTACAATCTCACACTATTGCTTCGTGGGACGTCCCGAGTCCCCATCCCGATGTCCCAGCCGACTCAGTAGTGAGCCTTCACCACTTCAGCGACACGTCTACCACGTGTGTTATTCTTGCCGGCGGCGATATCGTCACTATCAAGGAACCCGATGCCTTCTCTTCCCAGGATGACGTCCACATTGAGATTATCGGCTCCATCGATGCCGGAATTACGGCGGCCCGCTGGTCTCCCGACGACGAGCTACTCCTCGTAACCACCAAAGATGGCAAGGCCGTCTTCATGGGCCGCACCTTCGATGCCATCGCCGACGTGTCCATGACCTCGGAGGACCTCAAAGCATCCAAGCACGTCTCCGTCGGCTGGGGGAAGAAGGAGACCCAATTCGAGGGGCGGGGCGCGAAGGCCCTCAGAGACCCCACCATCCCCGAGAAGGTGGACGAGGGCGTTCTCAGCCCGAAGGACGACGGCTCGTCGTCCATCAGCTGGCGCGGGGACGGCGCCTACGTTGCCGTCAACTCCGTCGAGGGCGGCTTTCGGAGAGTCGTGAGGGTGTACTCGCGAGAAGGCGTCCTGGACAGCGCGAGCGAGCCTGTTGATGGACTGGAGGGAACTCTGAGCTGGCGGCCGGCGGGGAATCTCATCGCCGCCATCCAGCGTCGGTCGGACAGGATCGATGTCGTGTTCTTTGAAAGGAACGGTCTGAGGCATGGCGACTTTACCTTGCGCTCGCCTGGTGGAGATATCCTGTCACACGATGGGATCAGGCTGGAGTGGAACAACGACTCGACTGTTCTTGCCGTCATCTTGTCGGATACGATCCAGCTCTGGACCATGGGGAACTACCATTACTACCTCAAACAAGAGGTGCCCATCACGTCCCCGTACGTCCACTTGGCCTGGCATCCTGAAAAGGCCTTGCGCTTTGCCGCGGCGACGTCCAGTCTCCTCACCTCCGCCGAGTACATTTTCACTGTGGCAAGGGGTTCTCAGAGGCCACCCCACGATCATGGCGCCGTTGCGGTCATCGACGGCCACACGGCGAAAATTACCCCCTTCCGGACGGCAAACATGCCTCCTCCCATGACCATGTTCGACTTGGAGGAGGCATCGAGTGTTGTTGACGTCGTCTTTGATTCTGCCAATTCCTCCATGGCCGTCCTGCATCGTACCGGAATAGACGTCTATGCATGGCAAACTAAAGGAAGCCGCTCCCTTCACCCCAAGAGGGTGAGCCGAACAACTTTCTTTGAATCATCATCAACGGACGACTCGCCTCGGGTTCCACTTCAAGCATGCTTTTCCTCGTCTGAAGAAATCTCTGTCCTCGTTCACGACGGAGGGGACCTAAAAGTTGAAGTATACAGCTTTGGGCCTGGGGATAGTAACCTCCAGGATGTCGTGGAAATCGATCGATCGGAGCCGATTTCTTCCATTTCGAGCTACTGCGGTCTACCCGATATAGGGGCCTACGCCCAAGATCGCTCTGGAAAGTTATACAACTTATCCGGACAACAGGGCCTTATGCCTCTCGGACTTCGACTGCCCGTCCAACTGCCATGGTGTCAGCTGGTTGCCGTCGGAGACAATACGGTGGCGGTGGGAATGGCTCGCAACGGACGCCTCTACGCTGACAGTAGGCTGATAGCCAAGAACTGCACTTCCTTTGTGGTTACTGATGCCCATATCATCTTCACAACAACCAACCACTTCCTCAAGTTCGTCCATCTGGTGGATCCTCAAGAAATGGAAGTCCCGGAAGACGACCCTGAGGTGGATGAAAGGTGTCGCAGCATCGAGCGAGGTGCTCGGCTCGTCACGGCCATGCCTACCAACATGAGCCTCGTGTTGCAGATGCCCAGGGGTAACCTTGAGACTATATACCCTAGAGCCATGGTGGTCGCGGGTATCAGGCAACTCGTCGAGGAGAAGAACTACGGTCGTGCTTTTTCATATTGTCGTACACAACGGGTGGACATGAACATTCTCTATGATCACCGCCCGAACCAGTTCCTAGCCAACGTTGGCCTCTTTCTCGACCAGATTCAGGACGTGGCATATATCGATCTCTTCCTCTCGTCTCTCAGAGAGGAGGACGTCGCCCAAACGATGTACAAAGATACCAAGCGGACAACAGCTCGCGACCCGGACATTATCGCCGAGGAAGCGGCCGCAGATTCACTGGCTCCGCAGAACTCGGGGAACAAGTCCAAAGTCAACAAGATCTGCAATGCTGTTCTCAAGGCTCTGCAGCATAAGAAAGAAACCCACCTCCAAAACATCATCACCGCCCACGTCTGCAAGGTGCCTCCCGCCTTGGATGACGGCTTGACTCTGGTTGCCGAGTTGGTGCAAGAAGACGAGAAGCTTGCAGAGAAGGCCGTAGAGCATATCTGCTTCCTCGTAGATGTCAACCTTCTCTATGACCATGCTTTGGGGCTTTACAACCTCGACCTTGCCTTGCTCGTTGCCCAGCAATCACAGCGAGACCCGCGGGAATATCTGCCCTTCATCCAAAACCTCCACAAACTCCCCGAGCTTCGCAGACGGTTTGAGATTGACGACCACCTTAACCGGCGATCCAAGGCCCTAGCACATCTGAAGGCGTTAGATGCGTTTGACGAACTACAGGCATATACTACCAAGCACGCTCTGTACCAAGACGCACTCGGCCTCTGCAGGTACGAGAGGCAAAGACACCGTACTCTCATCAACCTCTTTGCCGAATATCTCGAATCCAAATCCAAGTTCCGGGAGGCTGGTCTAGCCTTCGAGTCTCTCGGGAACTACGAAAAGGCCATGGTCTGCTACCGCAGCGACGGCGCCACGAGCTGGCGCGAGTGCCTCTTCGCCGCCCAGCAGGTACAACCGCCTCTCTCCAAAGAAGCGCTCACCGACCAAGCCACCACCCTCGCCGAGGCGCTCACAGAAGCCAAAGACCACGCCTCAGCGGCGACCCTGCACCTGGACTACCTCGACTCCCTCGAAGGCGCCGTCCGCTCGCTCTGCAAGGGGAACCACTTCGCCGAAGCGCTCCGCCTCCTCGCCCACCGCAGCCGGGCCGACCTCGTCCCCTCCGTCTTCGACCCCGCCCTCGTCGACACCCTCAGCACCACCACCGAGTTCCTGGCCGACTGCAAATCCCAGCTCCGCGCCCAGGTGCCCCGCATCCTCGAGCTCCGTCGCCGCGCGGCCGAGGATCCCCTGGCCTTCTACGAAGGCGAGCGCGCCGGCGGCGCCGACGGGATCCCGGACGACGTGTCGGTGGCGGCCAGCTCGCGGCTCAGCACCGGCGGCGCGAGCTTGCTCACGCGGTACACGGGCAAAGGCGGCGGCGGCGGGGCGAGGACGACGAGCACGGGCACGGTGGGGACGGGGGTCAGTCGGGCTACGAGCAAGAATCGGCGGCGCGAGGAGAAGAAGCGCGCGCGGGGCCGCAAGGGTACCGTTTACGAGGAGGAGTACCTCGTGAACAGCGTGAGGCGGCTCGTGGACCGCGTCGGTGCCGTGCGCGGGGAGGTTGGGGCGCTTGTTTTCGCGTTGGTGAGGCGGGATATGGCTGAGCGGGCTCGGGCGGTGGAGACGCTGGTGGATGAAGTTGTGGAGGGATGCAGGACGGCTGTGGCGGAGGTGTTTGGATCCCCCGAAGAAACCGAGCAACAGGATGGGGAGGACCCGAACGAGGGTCTGGCTGGTGGTGGTGGTGGTGGTGGTGGTGGTGTTGGTGGAGACATGGGATATGTGGCTACAGGAGGTGCGGGTGTCTTCCATGAATACTTGGAGGCGAGGAACAGGAGGCAGGAAGTTCCCCTTGTCCAGGCGGTCCAAAAGCTATCCTTGCTCGGAGGATAGCGTAGTCCTAGATTATGGCAATCCACATAGATGATGTACATAGAAACGATTTTTCCAAGGTGGGAAAATTCCGGAACCATTCACACGACTAAAGATGATCATGATAGCTGCAGTGCTATCTGCTGATAAAAGTACACTATTGCACAAGTGAAGATCGCCT
->XM_002560539.1 Penicillium chrysogenum Wisconsin 54-1255 hypothetical protein (Pc16g02130) mRNA, complete cds 
-ATGGACGCCTACCCCGAAGACTACGTCAATCACAATCTGCCTTTAGTCCTACTCTCAGGGCTGGAGGCAGACACTGAAAATGAGCCAGGAACACCATCGGATTATCCTCTGCTATCAGAGAAGGGGACGCATATCTTCTCAGACTTCCCACCTCTGAGCGGGGCTGTTGCGGAGGAGCTCCGGAGCTTGCTTCTAGAGGAAGATAGCTCTCAATCGCCATGGAAGTCTAGAGTTACTGTAAGCGGGAATACTACGATTGCGAATATTGGTTACCGCATCAAAAGTTCTGGCCGCTCATGCAGACTCCCTCCACAAAAAGCTGACCCCCCTATCCCCTCACCACCAACTACTCCCAGTGATGACCATGATAATGAACACTCCGAGCCTAGCGCACACTATGTCCTCCACTCCCCGATATCGCCTCTGTCACCGGGTTCCCCAACTTTCCCAGATGGCTTGCTCACACCTCTATGGGTAACTAAACACCAGGACCTGGTTCCAGCAGCAGTGATAAATTTCTTCCCGTTTTCGCTGGACCCAAATATGAACTCGCTGCGAGACAATCAACTCAAGATCGAGATCAATAGCTTGAAAAAAGAATGGCAATCCTCCGGGTACAAGACGCGGTTCGTGGTCGTTCTGTTATCAGAAGACGGAGAAGAAGGCGGCTATGAGGGCGAGATTGATGACCGAATTGCGGGGATTCGGCGGGCAACAAACCTTGACCCCAGGTCAATATTTGTGATTCCACCAGACGCGACTTCATCGGAACTGCAAGACTTTGTGAAATCACTCTTCTCTTTACTGCAACCGTCGGTTGTTGAATACTATCGGGATCTGTCAAAGCATGCCAGGCGTAAACGGAACAGGGGGAATATCCCCCCTCCGACCGCACCACCAACGACCGGAACTTCTCAGACCCTATCGTCCCAAGGCTGGAACGTACGGTATGAATTCAAGCTTGGAATTTTTGCCGAGTTTCGCCAAGAAATGGATGCAGCCTGCCGGAACTATGAGAGTGCGTACGAAACCCTGTTTGGGCATGAAGTCTTCGAAAATATTGCAGGCTGGAATCCTCGATTCAACGATGCGCGCCTTTTGGCCGACGCCCTGGCCATTCGGATTATACGCTGCCTGCTATGGACGGGCCAGACGACCACTGCAGCTCGGCTTTGGGTTGACCACAGAGTCCGTGTAAAGGATATTGTCGATCGCAGAGGAAAGGGCAGTAAACACTACGGGTGGGAGGCCTGGGAGGCGCGTTGGTCGATGGTAATGGCACAGCTTATCCGCCGAGCGGAAATTCCGCCTATCTCCAGCGAAATCTCTTCTGAGCAGCCCAGAAAGCTCTATGCTCTACCTGAGAAATCGATTCCAACCGGGGAAAGAGTCAGGCCCTGGGAACATCTCCATCACGAGGGTTACTGGCTACACCGTTCAGCGAAACATACGATGTTGCGACGTGCCCTTGCCCAGGAAATCCCCTTGGAAGATCGCAAGCCCCCCGGGCAATCACCCGCCTCACAACTCGCAAATAAATCCTACTTGTACGACACGTACCTTGTTCCCGACGCTCACGCCGAAGCACCCCAAGAAGGACGAACTGGCTTCGACCATTCTGGTCTAATATTAAGCACGCTGAAGGCTGCTATCGAGGAATTCGCAAAACGCGACCAAACAAGGAAAGTCGAGAGCTTGAGTCTTGAGGCGGCCGAGGAGTATATGCGTATTGGCTCATGGTCCGAAGCGCATGGCCTTCTTCGGCCGCTGTGGTCTACTCTTAGCTGGCGCCGCTCAGGGTGGTGGCATCTGATGGCCAATTTCGGGCGGGCGCTCAGAGAATGTGCCCTCAGGATGCAGGACAGCGAGACAATCTTGCGAGTGGACTGGGAGCTGTTGAATAAGAATCTCAAACCTAGATCTGCGTGGCATTATGACATCCACAAGAGTCTTGAAAGTTTACCCTCAGAAAAGCCTAAACCTTCTCTTATCCTTCGCGCAGAGGATGTTATAACAAGTCTGACCGCGTCGCTGGTGTTCGAGAAATCTGATGGCAACGTTGGCGAACCTCTACATGCACAGCTTGCCATCACATCCTGTGCTCATAAATTCTCGGCGCCTATTCGGCTTTCGGAGGTCAAACTGGTTTTCGAAGGATGTCTTCGACCGGTAAAGGTTCAATCTGACCAGAACCAGGATGCTGACACCACAACCTCATGTTGTATCGCAACTCTTCCACTCCGGGAACCGAGCAACGCTGATACTGCGGTTCAATCCCCAGCCGGTGGACTGACCGCATTGACCAAGGTGTTTGACCTCACCTGTGTTCCTCGCGAAGCTGGTGAAGCCAGGGTTGCTTCAATCACCATGCTGATTGAAGAAGAACAATTCGATTTGGGTTATGCGGTCACTGAACCAGAACAGCGTGAATCGTTCTGGTGGGAGCAGACCCAGAAGGGCGTGACCCGTAGGAGAGTGGGCAAGGATAGGGATACTGGCAGGTGCAAGGTTATGCCTAAGCCTCCCAAGATCCGCCTCACAACTCCCAACCTGAAGCGGACCTACTACACCAATGAACGAGTGATGCTTCAGATTGGTATACACAATGAAGAAGACGAAGCTGCCGATATATCTGCTGAGATCAGACTATTCGGCACCGAGTCCGCAGCTCAAATCCAGTGGCTCGACGGCGACAGCAACCCCGAACTCCTCGAATCAGGCGCCAGCACTCCGATTGAGGGGCCGTCTCATTACTTGAAACGATCTGTGGGTGTTCTGGAGCGCTCCTCCCAGAAAACTCTTACAATTGTGTTGGTCGATACCCAGGAGGCTACGGATTTCACCTTGGAAGTTTCGACTGTGTACCATTTGGTGTCTGATACCCAGACCCCGATTATGAAGAATACTACCGTGGATCTATCATTTATTCGGCCGTTTGAAGCAAACTATGAATTCTTGCCGGCAATTCACCCTCAGCCATGGCCCAATTTCTTCGCAGTTAGCGACAACTTACTCGAGGATGGCTCTGCGCCAAGTCCTGGAGGCCTGTTCCAGAAATGGTACCTCAATTCCAAGGTAGTTTCCTTTGCACTGGAGCCATTGGTAATTGACAAGATGTCCCTGGTTCTTCTCGAAGCCAACGGGGGAGTCGTTTGCGATGTTCACTCAGAGGAGCTTGTGACTCCCGGAACACCACATCTCGCACCGGAAGAACTGCGAGAATCCAACTTCTGCCTCGATGTCCAGAAGCTCCTTCTCGGAGACCGCCGGCCAACTGCGCTCACCTGCACATTGGAGATCAATTGGCGCCGGCAGTCATCTGAATCTGTAGCTTCCTCGGACGCAGAGAACTCAGTCACAACCACCGTCCTTGATATTCCCCGATTTGTGGTCCCAATGGGCGAACCTCGAGTCCTTGCATCAGCCACCCCATCCAGCAGTATGGCGGGGTTGATTCATATGGGCTATGTACTGGAGAACCCCTCCACCCATTTCCTCACCTTCAACCTGGTCATGGAAGCTAGCGAGCACTTTGCCTTTAGCGGACCGAAGACCACCGTTGTGCAGCTTGTGCCGCTGAGTCGCCACACAGTGAACTTCAATTTGTTTGCAGCGAAGCGTGGCTTATGGATTCAGCCACAACTGGTAGTTATTGATACCTACTTCAACAAAACGCTCCGCGTCCTTCCAACGGGGGATATGAGGTCGGACAAGAAGGGGGTTCTGGTATGGGTTGATGCCGACGATTGA
->XM_011327141.1 Fusarium graminearum PH-1 hypothetical protein partial mRNA 
-ATGACATCCTCCATCGTGGAGGCATTGGCGAATGTTCAACCACCAGAAACACCAGACAGCGAAGATCATGACATCGAAAACGAGACCCAAGAATCACCACAACCTACAAACGAACCTTCCCTAGACGACCCCCAAATCGGAAAGCCCATATCTCATGGCCAAATTGTCGACCTTTGGAAGCGCTCCAAAGCACAAGACGATGCAAACTACACTCTAGAACAACTCCTTCGCGGCGCATCCGTCTACATCCCTCCTCCACCACCTAAACCCGAACCTCTAACCAAGTGCAGTCTCCCGAATACAAAGCCCTCATGGCCCGTCTTCGCCGCCAAGAAGAAGCCCGCTCCTACGAACGAATGA
->XM_039262098.1 PREDICTED: Dioscorea cayenensis subsp. rotundata uncharacterized LOC120253894 (LOC120253894), mRNA 
-ATGGCCACAGTTCAAGGACCAATAGTTCTGGTTCCTGAACTAGAACCGAACTGGCTAGGTTCCAGTTTTAGGACAATTACGGTTCTGCCGGTTCCAGCCCGAAGAAAGAGTAACTACTTATTGGCCCACTTCATCTCTCTTCTACTCAGCCCTAATTCCTCTTCTTCTCTGTTTCATCACCACGCTCCTCCACCATCGAACCCGTTGCCGATCACCCGCCCGTCACCACGGTCCTCATCTTCGCACCATCGTCGGACCCGTCGCCGGTCACCCACCCGATCACCACGATCCTCATCTTCACCATATCATCGAAACTCGTCACCAGTCACCTACCCGTCACCCGCTCGTCACCCACAAGCCTGCAGACCTTCTTTTTCTTCGAAGAAGGAAACGATCTTCATCTTCTTCTTTGATGATTCTAGGGTGGGTGGTGGTGATCTTCCTGATGACACTGTGTTGACTTGTTCTCACGGCTTAGAAAGGTGGGCTTATTACATTCTTTGTCTGGCTTCCTATCCGTCATTAGGTCCTCACATTATGTTTGTGATGCATTTGCATCAACATTAAAGGGCTCTCCAAACAGTGTTACAGTTGCGAGAACCCGAATTGAAGGAGGTGCAAAGGCTGTTTGGACTAGTGGAAGCCTGGTGCTTCAAAGTATACGAGCCATCTATGCTCGCTAAAGCATCTTCTTCTGGTTCGAAGTTGGGGAAATGATTGTTGCCTAATGATAGCCCTTGTGTATGTAATGTTGTACTTTGAGTTCCTCATCATCTGATTTGTATGTCATTTAAGCATTAGTGCTTTTCCAATTGAATCAACTTCGACAAACGAATATATTTGCTTGT
->XM_040352829.1 PREDICTED: Rana temporaria histone deacetylase 9 (HDAC9), transcript variant X3, mRNA 
-TCCCTCTATTGAGATGCTATTTTTAGCAAATCCTACTCGTGTCGCCACGGGCTGTGATCACATCTTTCTCTCCCCGTTTCTGCCTCCCTCCCATCCTCAGCCATCCCTTTCCCTCTCTGTCTGCAGATTTGAAAACATCACTGGCAGCGCTCCCCGGCGACTCAGCACTCATGTAACCTGCACGGGCAGCGAGCACGGCGTCAACTTTCTTCTGCTTTGTGTTGTACGCTTCCTGGCAGCCTCCTTTCTGAGGATGGATGGTCTGGATGAGCGGCCAACTTCTCCGAGCAGCTACTGAATGAGCAGCAAGATCCTGCTTTTCAGTTACAAACCACTGAAATACATTCCTATCAGATCTGGGATCTCTATCAAACAGCTGGTCGGCATGTCTTCTCCAACCATGAGCACCACAACACAGTCAGATGGGGTATCTGGACGGGAGAAGCTCCTGGCACAGCACAGAATGCACAGCATGATCAGTCCAGATGTGAAGACTGAAGTCCCAGTAGGTTTGGACCCCATCACACCACTGGACCTACGGACAGATCTAAGGACAGTCATGCCTATGTTAGATCCTAGCTTACGAGAGAAGCAGCTGCAGCAAGAGCTTTTACTGATTCAGCAGCAACAGCAGATTCAGAAACAGCTGCTCATTGCCGAGTTTCAGAAGCAGCATGAAAACCTCACAAGACAACACCAAGCCCAGCTGCAGGAGCACCTCAAGCAAGAACTTCTAGCAATGAAACAAAAACAAGAGATCTTAGAACGGGAGAAAGAGCACAAAATGGAACAACAGAGACAGGAACAAGAAGCAGAAAGGCATCGCCGCGAGCAACAGCTGTCTCACCCTCGCAGCAAGGACAGAGCAAAAGAGCGAGCCGTTGCCAGCACTGAAGTCAAGCTGAAACTACAGGAATTCCTTCTGAGTAAATCTGCCACAAAAGATTCCTATACAAACGGAAACAGTCATTCCATAGGCCGCCACCCAAAGCTTTGGTACACGGCAGCACATCATACTTCATTGGATCAAAGCTCTCCTCCATTAAGTGGGACCTCTCCATCATATAAATGTCCTCTTCCTGGAGCACATGATTGCAAAAACGACTTTCCTTTGAGAAAAACCGCTTCAGAGCCCAATTTGAAAGTTCGCTCTCGATTAAAACAGAAGGTAGCAGAGAGGAGAAGTAGCCCTTTACTAAGAAGAAAAGATGGCAGTGTTACCAGTTCATATAAAAAGAGAATATTTGAAGTGGCAGAGTCTTCAGTTAGTAGCAGCTCTCCAGTATCTGGACCCAGCTCTCCAAATAACGGCCCAGTTAACATGGGTGTGGAGAATGAAAACTCAGCATCACCATCCAGCTCACATGTCGAGCACTTGGTTTCCCAACAACATATAGTTCATCATGAAAAGTCGATGAATCTGCTAAGTCTTTACACATCTCCATCATTACCCAACATTACTCTAGGACTTCCAGCAGTAGCTCCCCAACTCAGTGCCTCATCTTCATTAAAAGAGAAACAAAAGTACGAGCCTCAGGCACCCAGGCAGGGGGTGTCACTGCCTGGATCGTATGGAGGAGCCCTGCCTGTTTCTTCAGCTCATGCATCCCTGGAGAGCAAGACCAACAGCAGCCACCAGGCCTTACTGCAGCACTTACTGCTAAAAGAACAGTTGCGACAACAAAAGATTTTAGCTACAGGTAGTGCTGCAATTCTTCACCAATCTCCACTTACAGCAAAAGAGCGGGTTTCTCCGGCGGGCAGGGTGGCGCACAAACTTCCTCGGCACCGGCCACTGCACAGAACACAGTCGGCTCCGCTGCCTCACAGCACTTTGGCCCAGCTTGTCATTCAGCAGCAGCACCAGCAGTTTTTGGAGAAGCAGAAACAATATCAGCAACAAATCCAAATGAACAAAATGCTTTCAAAATCAATCGAACAACTCCGCCAGCCTGGAAGCCATCTAGAGGAATCGGAGGAAGAACAGCATAGTGATTATCTGATGCAAGAAGAGAAGGTGTCCTCCTCGGCTTACATACGAAGTTACAGCAGTACTGACATCAGAACTGACCACCTCAGACCTGTGAAGGTGAAGGAGGAGCCACCGGACAGTGATGACGAAAGCCAAATGCCACATGAATCTATTCACAAAATGGCTTTTGTGCAACAGGTAATAGGCCAAGAAATAGCTCCAGGATTTGTTATTAAAGTTGTCCTTTGAACTTTAGGACTGACTAAGAAAAAGTAAGACCCCTACATTATGTAAATAGACATTTTTATTTGAATATGTTAATACAGGTTCTTTTCTTTTTTTAATCTTAGTAAAGCTGGTCATATACTAGATTTTTGAATAACAGTCCTTATAAATATCTGTGCAAACATTTGCAATGAAATTCTCAGTACATCAGATGACTGGACAAATGTCATTCGATTTTGGAGTGAATGGAATTTCCTAAACAAAAACTACATACACTATTGAGAAAAAAAATCCATCCTGCACCTTCAAGCTTTCTCATTACTATGGTTTAAAAAAAAAAGTTATTTTTATCCCACTAACAATTAGAAAGTCAAATGAATGTCAACAAAAATCCTATAATGCCGTGTACGGAAATTCCGTGGATTTTTTTTTCCGACGGAATGTTGACTACTTGTGTTGCATACACACGGTCACACAAAACA
->XM_039196864.1 PREDICTED: Hibiscus syriacus probable prolyl 4-hydroxylase 3 (LOC120194605), transcript variant X1, mRNA 
-AAATTCTCTGATACTTTTCATCCGAGTTTTACCCAGAATCAGGGGTGATTTTCTTCCACCGATCCCTGGGTTTTGAGCTGATTTCTCTCGTGTCATCTCCGTAAATTCAAGAATGCCGAAATTGAGACATTCTCGGTTGCAGGCGAAGAAGCTGCCGACAGCGACGCTTGTATTATTCATGTTGTTTATGTTAACGGTAGTTTTATTGATGCTTTTAGGACTAGGGATTTTCTCTCTTCCGATAAACAGTGATGATTCTCCGCCCACTGATCTTACTTCTTATAGACGCATGGCCTCTGAAAGAGGAAAAGGCTTGGGGAAAAGAGGGCAGCAGTGGACTGAAATCCTTTCTTGGGAGCCTAGAGCTTTCATTTATCATAAATTCTTGTCCAAGGAAGAATGTGAATACCTAATCAGTCTTGCTAAACCTCACATGGCAAAGTCCACTGTTGTTGATAGCAAAACAGGGAAAAGTACAGATAGCAGGGTGCGTACAAGTTCTGGTATGTTTCTGAGAAGAGGGCAAGATAAAATCATTAGAAACATAGAAAAAAGGATAGCTGATTATACTTTCATTCCTGCAGAGCATGGAGAAGGCCTTCAAGTTCTCCACTATGAGGTTGGACAGAAATATGATGCACACTTCGATTACTTCCTTGATGAATTCAACACTAAAAATGGAGGCCAGCGGATGGCTACTGTGCTTATGTATTTGTCAGATGTTGAAGAAGGAGGTGAGACAATATTTCCAGCGGCCAAGGGAAATGTTAGTGCTGTGCCTTGGTGGAATGAATTGTCTGAATGTGGTAAACAGGGTCTAGCTGTGAAGCCAAAGATGGGAGATGCATTGCTGTTCTGGAGCATGAGGCCTGATGCCACACTAGATCCTTCAAGTTTGCATGGTGGGTGCCCTGTGATTTCGGGGAACAAATGGTCCTCAACAAAGTGGATTCATGTTGAAGAATACAAGGCTTAAGCTGCTGTATAGAGGGTGCAGTTCTGAGGAAGTGTGATTGAAGCAACCCCCTTTAGACTCGGGTCCATCAATCTCTTTTTGACGGGGCACGGTGTCTCTAGACCTAATCCTTAGGTTGAGAAGTAATTGTTCTCGTGTATTCTGCTGGAAACTATCGGGTTAAGAGAATGCGGTTCATACGTGTTAGGTCCTATAAAATCCGATTGTAAAGTAGCTAAATAATAATGAATAGAAGTATCTTGGAGCTATTGTGAGTCTGGTGGTTTTAAAATCAAAAGTACGTACTAAAGTTACCGGCTATTTTGTTGTTAACACACTGATGTGGCCCATAGTTCATAAAAACAGAAACAAGCTGGATAGACAAAA
->XM_045620325.1 PREDICTED: Harmonia axyridis 26S proteasome non-ATPase regulatory subunit 14 (LOC123681941), transcript variant X2, mRNA 
-TATAAACCAGCTGTCAATCTGTCAGTGGAAGTCAAATATCGTCAAATAACAAACGGTGATTTGCAAAATTAACACTCCTTGTTTTTTCACTTTATAAATAAGAATATTAATTCATTTAATAGTACTTTTATATTATAGCCATGGATCGACTACTCAGGCTTGGTGGTGGAATGCCCGGATTGTCTCAGGCAGCCCCTGCTTCTGATGCTCCTGTTGTAGATACTGCAGAACAAGTTTATATTTCTTCATTGGCCTTATTAAAGATGTTAAAGCATGGAAGAGCAGGTGTACCCATGGAAGTGATGGGGCTCATGCTGGGTGAATTTGTTGATGACTACACCGTTAGAGTAATCGATGTATTTGCTATGCCCCAAACTGGTACTGGTGTAAGTGTCGAAGCTGTGGATCCTGTATTTCAAGCAAAAATGTTGGATATGCTTCGACAAACAGGCAGACCTGAAATGGTTGTTGGCTGGTATCATTCCCATCCTGGTTTTGGATGCTGGCTTTCTGGAGTGGATATAAATACGCAACAATCATTTGAAGCATTGTCAGAAAGAGCTGTTGCAGTTGTTGTTGATCCTATCCAGTCTGTAAAAGGCAAGGTTGTTATTGATGCATTCAGACTGATAAATCCTAATATGATGGTACTAGGTCAGGAACCCAGACAAACCACATCAAATTTGGGACACCTTCAAAAACCTTCCGTCCAGGCTCTCATTCATGGTCTAAACCGTCATTATTATTCAATCAGTATAAACTACAGGAAAAATGAACTTGAACAAAAAATGTTGCTTAATTTACACAAAAAATCTTGGATGGATGGCCTCACTTTGGCAGATTATTCAGAAAATTGTAGTGTGAATGAAAAAACCGTATCAGAAATGCTGGAACTGGCTAAAAATTATAACAAAGCCTTAGAGGATGAGGAGAAAATGACACCTGAACAGTTAGCAATTAAAAATGTTGGAAAACAGGACCCTAAAAGACATTTGGAAGAGAAAGTTGATGTACTTATGACGAATAATATTGTTCAGTGCTTAGGTTCAATGTTGGACACTGTAGTGTTCAATTAATTTATTATTTTTACAATAAATTATCAACATATTCAACTTCATCATTTTGATTCAATAGTTTTTCATTTCACTTATCGTTTGCTGCAAGTTAAACACTACAGTAGGCAAAAATTACTCCAATCTTCTATTGGAACTCATAATATTAATTCATTAATTCTCAAATGAACTAAAGTTTATTTTCAATGAGTATGAAAATATTAAGATAAATAAGGATTTTATAAGAATAAAATTTCAATGATCTGTAATAAAAAAACCAAATGTCAA
->XM_018196263.1 PREDICTED: Atta colombica NADP-dependent malic enzyme-like (LOC108689497), transcript variant X2, mRNA 
-CAATAATGGAGAAGCCAACGTACCTCGTCCGCCGATTTAATTACAAGTGAACGAACCGCAACCGGTTCGTCGTGCCGCGCGTTTGCTTCGGGAGTGCCGTTAAAGTTATCGGACTCAAGTTATGGTCCGCGCGCGATTATAGTGCACTATTCGCGAGTGTTTTACGGGAGTGGATGTCAATCCAATTCTGAGAGGAGGAGAAGGGAGAGACATCGGGCACCGGCGGAGCATTTACCTTGCAAATTATCGACGTTGCAGATAACTCCACTGTTGCGCATCGGGATGATAACGATGTTCAGAACAGACAGCTGAGAGACATGCCGCTATCGATGAATGGCTGTCAGAAAAAATTTGCTCGCATTCTAGAAGACTCGAGCGAGGAATTGTCTTCTCAGTCGCATGAAGCCATCCCTCTCTGCGCACGACACACAAAGTTACGCACGCATGACCCAGAGCAGTACACAACCTAACTGTAGCAAGAATAAAAGCATGTCGAGCTTGGAACGCGATCAGCTGGGCCAACGAGGAAGCGGCGACACGGTCTCCGCTGGTCTTCTGCGTGGCCTCGATCACATTAGAGATCCGCACTTGAACAAGGGTATGGCGTTCAGTATTGAGGAAAGGCAGATACTGGGTATACATGGTCTTCTACCGGCAGCCGTAAAAACCCAAGAAGAACAGTTAGAGCTTTGTCGTCTTAATCTGGAACACTACACGGATGATCTCTCAAAATACATATATCTCATAGGCCTACTGGATAGAAACGAGAAACTCTTCTACCGTTTGTTGGCAGAAGATGTAGATAAAATAATGCCATTGGTATATACGCCGACCGTGGGTTTAGCATGTCAGAAATTCGGTCTGGTTTACCGTAGGCCGCGTGGCCTTTTCATAAGCATTCACGATAAAGGCTATGTCTATGACGTTTTGAAAAATTGGCCCGAACACGACGTACGAGCAATCGTTGTCACGGACGGTGAGAGAATATTGGGATTGGGTGACCTAGGTGCTCACGGCATGGGCATTCCCGTAGGTAAATTGTCATTGTATACCGCATTAGCTGGTATCAAACCCCATCATTGTTTGCCTATCACTTTGGACGTCGGCACTAATACCCAGTCTTTGTTGAATGATCCCCTATATATCGGTCACAGACACAAACGTGTTACTGGACAAGAGTATGACGACTTCGTGGACGAATTTATGAAGGCTGTTGTGAAGCGATTTGGTCCGAATACGTTAATTCAATTCGAAGACTTCGGAAATGTTAATGCGTTCAGATTGCTTCAAAAATATCACAAGGAATATTGCACCTTTAATGATGATATTCAGGGTACCGCCTCTGTCGCTGTTGCCGGGTTATTGGCATCACTTCGTGTTACGCAGACAAAGCTCTCAGAGAATACAATCGTATTTCAGGGTGCTGGAGAGGCGTCATTAGGTATCGCGGCATTGTGCGTGATGACAATGCTAAAAGAAGGAATAACTAAGGAAGAAGCTAAGAGCAAAATTTGGATGGTAGACTCGAAAGGATTGATAGTGAAAGATCGTCCAAAAGGCGGACTGACGGAGCATAAATTGCACTTTGCTCGTGAGGATAAGCCAATCGACACTCTGTTCAATGTTGTTAAGACCGCCAAACCTTCGGTTATTATTGGCGCAGCTGCTATCAGGGGTGCCTTCACAACAGAAATATTGAGGGAAATGGCGCGTATCAATGAGAGACCCATTATTTTCGCTCTGAGTAATCCAACGAGCAAAGCAGAGTGCACCGCGGAAGAAGCATATATTGCTACAGAGGGAAGATGCTTATTCGCAAGCGGCTCGCCTTTTCCACCAGTCACATATAACAATAAAACTTACTATCCTGGTCAAGGTAATAATAGTTACATATTCCCTGGAATCGCGCTGGCCGTAATATGCGCTGGTATGCGCACCATTCCCGAGGAAACTTTCCTTATTGCTGCGACGGCTCTCTCCGACTTGGTAACGCAAGCCGATTTGGACAGCGGTAATCTTTACCCACCATTGGCCGATATACAGAAATGTTCGTTGTGTATAGCATGTGCAATCATGAAATATGCTTATGAAAAATCTCTAGCAACTGTCTATCCGGAGCCTTCAGATTACGAGAGTTTTATCAAGGCACAATTATACGATCCAAGCTATAAATCGGCAATTCCTCCAGTTTATTCATGGCCAACAATAGAATTCTTTGGGAATCTTCCTCGCTTTTTTAAAGTCTGTTGACCGGGCTTATTTCTAACAAGTATGTGCAAACGTGATCAATATTTAATTATTAAAATTCGCAAGAATGAATTTGTGTTTAA
->XM_051723159.1 PREDICTED: Myxocyprinus asiaticus protein EFR3 homolog B-like (LOC127455345), transcript variant X3, mRNA 
-TGCATGCATGCACATGTGTGTGTTTGAGTGTGTATTTGTGTGCATGTGTATATATGTGTGTGTGTGTGTGTGTGTGTGCACCTGTGTGTTAAACCAGCATTGTTCCTGATAGAGGGAAAGCTGTGCCGCACTGTTTGGAAAATCCAAGGTCATTGAAGCCCGGTCACATGCACCATATGTGAGCGTGCATGTGTGATTTAGTGTCTGAGTGAGTGAGTGTGTATGTCTCTCTTCCTCTCTCTCTCTGGCTGGAAAGAGGCTTCAGGCAAAGAATAGTGAATTTCATCAGGTTTTCCATCAATGTACGGTGTGTGTGGATGCTGTGGGGCCTTGAGACCTCGTTATAAGAGGCTGGTGGATAACATCTTTCCTGAAGACCCTGAGGTATGTTTGTATTGCTATGGAGGCTTTGGACCAGCTGCTGATGGCCTGTCACTGTCAGAGTATAAACCTTTTTGTTGAGAGTTTTCTCACTATGGTGCGCAAGCTTTTGGAGGCAGACAAACCCAACTTGCAGATCCTGGGCACTAACTCATTTGTGAAGTTTGCAAACATCGAGGAAGACACACCATCATACCATCGCAGCTACGATTTCTTTGTCTCACGCTTCAGTGAGATGTGCCATTCCAGTTATGAAGATCCAGACATTCGCACCAAGATTCGTATGGCAGGTATCAGAGGTCTGCAGGGTGTGGTGAGGAAGACTGTCAATGATGAACTGCAGGCAAATATTTGGGACCCTCAACACATGGACAAAATAGTGCCATCCCTTCTGTTCAACCTCCAGCAGGAAGAAGGCATAGAGAGATCTCCCTCCCCAGAGACAGAGAAGGAAAGTCCAGTGGAGCTGACCGAGAGGTGTTTCAGAGAGCTGCTAGGACGAGCAGCTTATGGTAACATAAAGAATGCCGTCAAACCCGTGCTCATGCACCTTGATAACCATTCACTCTGGGAGGGCAAAACATTTGCTGTGCGCTGTTTTAAAATCGTTATGTACTCCATCCAGTCCCAACATTCACATTTGGTGATTCAGCAGCTGTTGGGTCACTTGGATGCTAACAGTAAGAACTCAGCCAGAGTGCGTGCTGGGATTGTGGAGGTGATCTCAGAGGCAGCGGTCATAGAGGCCAGTGGCTCAATAGGGCCGACAGTACTGGAGGTGTTTAATACTCTGCTGAAGCAGCTGAGACTCAGTGTGGACTACGAGCTCACCGGATCATACGACTCTTTTGGAAACATGGGAACCAAAGTCATTAAAGTGCACGAGGAGAGACAACTCCAAGAATCTGTCATCAAAACTATTGGCTCATTTGCGAACACGCTGCCCACCTACCAGCGCTCAGAAGTCATGCTGTTCATCATTGGTAAAATTCCTGTGCCAGGGATGTATCCGGCTCTGGGGTCAGCCAACACAGGGGTTGAGGGCAGTAGGATGATACAGATTATGCTGCTAAAATCTTTGCTGCAGGTAACAGCAGGATTCCAGTCTACGAACATTCTGACAACTCTTCCCACCTCATTCCTGGACCCTCTCTTGTCCTTTACTCTGATGGAGGAGGCAGAGATCCGGCTACTTGTTCTGGACATCCTCATCAGCATCATTGATCGCCATGACAACCGTCACAAATTCTCCCCTGTCAGAATTGTGTCAGATATCGCTGTACTGAAACTGAAAGTAGACAAGTGCTCAAGGCAGGATAATCTCTTCATGAAGAAACACAGCCAGAGGCTCTACCGCCACATTTACCTGGCCTGCAAAGAGGAGAGCAGTGTCCAGTGGCACTTTGAGTCTCTTTATACGCTGCTGGGGTTGATCAGTGTTGAGCTGGCCAATGAGGAAGTGGTGGTGGACCTGATTCGACTGGCTTTGGCCTTACAGGACCTGGCCTTGACTGAAGAGGCACTTCCTGTGTATAACCGCTGTGCCATCCATGCTCTATCATCTGCATACCTGAACCTCATTAGCCAGCTGACCACTGTGCCCACCTTCTGCCAACACGTCCATGAGGTGATTGAATCAAGAAAGAAACTGGTCCCCTGTCTGCTGCCTGAGGATGTGCTTGTTGAGACCTCAAAGATCCCAGAGAAACTGGAGAAGGTGGAAGGTGAGGTTCTGTTCATGCAGGCTAAGATAGCGGAGATGCTGGGCGGCAGTGGATACAATACAGAGAGACTGGCCACTCCATACATCCCACAGATCACAGATGAAGACAGACTATCTAAGAGGAAGAGTATTGGTGACACCATTTCCCTGCAGTTAGAGATGGAGTCCAGAGACAGTCCAGAAAAAGAGCAGAGATCCAAAGCTGAGCAGATAACATTTGAAACCCTTAAACAAGCCATTGTAGACAGTGTGAGTGTGGAGGAGCTGGAGAGAGAACGCAGGAGGCAGGTGGTGGAAAGGTTTCAGACGGCTCCATTTGAGGAGATCGCAGCACACTGTGGGGCCAGGGCTTCCTTGTTGCAGAGTAAACTCAACCAAATCTTCGAAATCACAATCAGGCCTCCTCCGAGTCCGTCTGGCTCTGTCGGGAATGGCCGAAATCGTTCTGTACCAGTCTATGAAATGACGTTTCCAGACCTTTGTGTGTACTGAGAAAACCTGGAGCCACAGTCACCAGATACAGACCTATTTCAATCCCTACAATATTGTCACTCCTTCTCAATGTCCAGTTGAAACTATGCGTCTTCTAAACTGTGTCCTTTAGTTTAATATCTTTAGATAAAGATCAAAACTTGACTTGATCCCGAGGTGTTCACCAAAAAAGACAACCAAACCAAGAGAATATACATTGGTTATATATGCACTGTATCACTAAAAATGACAAAACAATGTTCACACAGCTTAATCTAAATGCAAATAGATTGAATGTATTTAGAAACATTTGTGCCATTGTCTGATACTAGCATACATAGCAGAACAAGGTTTTCATGTTTAATCAAATGTCCAGTGAATAGGCCAGGTTACTGTGTAAGTCTATTGTTCAGAGCAAGTGGATGATATTCTTGTACAAATAAAAAGTACAGCTGCCTTACATTTTGTATCTTAAGTTAAGACTTAAAGAATTGTTAAAGAATGTTCTCGGCATGTTTTCTGTAACTATGTTTTTCAATCTATTGATTATTAAAGTGACGGTGCACTTAAAGGTAGATAAATATAAGGTTGTTTGCCTGGTATATACTGTATTTCTTTGTGCATGTTTAAACCTTCTCTACATTCTGCAATAATATTTGTATTTAAAGCAATAATTAATGAATTTAATAATGCAGATTCTTCTGAGATAAAAGCTGAAGAAAAAATGCAACACATTTTGTTTGCGAACACTGGATGATGCAGTATTACAATCAGAACTAACAGCTTATTGACACGCTGTGTGCAAGAAAGTAAATTCAGTAGAGCCTCTGGTGTATTTGCATAGTAACGTCATGTTAATTATGTTCTAATTGAGTTCTGTACATCTGTACCTCATTACCACAAGAAATATGTCATATATTTCAAAGAATATGTCAGTGAAGGGTAGGAGTTTTCATTTGCTTAATAGTCTAACAATGATTGTGTACATTTCCCAAATGACCATTTTCCTTTTTTGAACCAGAGTGAAGTGGTAACACTTCTCATAGTCCCCTACATTTGGGGTCTAAAGGGGCCAATTAGCTCTCTATTTGTTTTTGTTTTTTAAATTAGCTATGATATATGTTTGTTCCTTTTGTCACTTGTATAACTTTTCTCTCTTCATAAATCCTGTAATTTCAGGTTTACGTCAAGATTTGGTTCTCTCTTGTATTTTATTGCAGCACTTTAAAGATCATTGTGTAAATGTGGTGTATGCTAAAAAATATATGTTCTGTGATTTTCCACCTTGACATGTGAATGTGTTCTTGAGTGTCATTTTAAAGTGAATTATCTTTTATCGTCTCATATTTTCCTATTCCACATGAAAGTTTGCCTGTTTTTCTGCTATAATTCCATGAAGTCCTTTTAACTTTTTTTTTTCTTTTTAAAGTTATTTAATCAAGTCATTGTGTTTTTTGTGATGACTTGAATTTATTTACTGTTTCTACATACTGGTTTTAAAAGCAAAGCATCCAAAAAGAACTTGACTTTTGCCATCTTTAATATGGGTATAATGTCCAACTGATAGAACATTCTAGACTTCTTACATGTGAGGTGTTTGACGATGTACTGCATGTATGAAATATCAAAGTTTAGTCTTTCCTCTCAAAAAACTGTGTCCTTGACAGTTGCCGCATGCACTGGGAGTTTTGTCTGTGCTTTTACTATTTTTGTTGTTGTTTAATTTTTTGGGTTGAATCCTTATTAAGAAAATTAAAACATTGTGGATTGTAATTAGTAATTATTACATGTCAGCTTAGTCCCTGTTATGTGTTTGGTACCGTCAATGCAAACTGATGACTTCAGAACTGTGTTCTGTGAATGTTTGCCTAAATGAAACAATTCCTAAGTAATGTACAGAAGTGGTGTGAATAATAAGAATATCAATTAAAGACTAATTTTATGAA
->XM_039521359.1 PREDICTED: Mauremys reevesii poly(rC)-binding protein 3-like (LOC120396454), transcript variant X13, mRNA 
-GAGGGAGGGGGGGGAAAGAAAAAAAGAAAAAAAAAAAAAAAAAAGCAAAGCTTTGCCTCATTCCAGTAGGGCTCAGGGCTCCCGGCCATCTGTCCACCCTTGGAATCAGAAGACAAATAGAGGGACCACACTCACTATAACTGTGCAGAAGGAAATTGTTCGGAAAGTCTGGCTGAGCTTTGCATTTGAAGTGCGGGCTTTGAGAGCAGCTCAGCAGGTTGACGAAGTGAAAAAACTAAGAAACTGCTTTCAAGCATTGAAGATACCAGGCCAGGATGAACACGAAGGACACAAAAGTGACAGAAGGAGGTCTCAATGTCACACTTACCATACGTCTTCTCATGCACGGCAAGAAATATTCACTTACTGTGGTGTTGTTTTTTCCTGTTCCAGGAGGTTGGGAGCATTATTGGAAAGAAAGGGGAGACAGTTAAGAAGATGAGGGAGGAGAGTGGTGCACGAATCAATATTTCAGAAGGTTCCTGTCCAGAAAGAATTGTGACAATAACAGGCCCAACAGATGCGATTTTTAAGGCTTTTTCTATGATTGCATTAAAATTTGAAGAGGACATAAATGCTTCAATGACAAACAGCACAGTGACAAGCAAACCACCTGTGACATTGAGACTTGTAGTCCCTGCAAGTCAGTGTGGATCCCTTATAGGAAAAGGTGGCTCCAAAATCAAAGAAATCAGGGAGTCCACAGGGGCCCAGGTACAAGTAGCAGGGGATATGTTGCCAAATTCAACAGAACGTGCTGTAACTATATCAGGCACTCCGGATGCCATTATTCAGTGTGTAAAACAAATCTGTGTGGTCATGCTAGAGTCCCCACCCAAAGGTGCCACCATTCCCTACCGTCCCAAACCTGCCTCTGCACCTATCATTTTTGCAGGTGGCCAGGTAAGAGCAGACACCATTTTGGCTTCAGCTGGAAACCACACCGTCTTGGCCCAACCTCAGCCAGCGCCTGCATTTACAATTCAGGGGCAGTATGCCATCCCTCATCCAGATTTGACCAAGCTTCACCAGTTGGCTATGCAGCATCCCCCCTTTACTCCCCTTGGGCAGACCACCCCTGGTTTCCCTGGATTGGATGCCACTACTCCAACCAGTTCCCATGAGCTTACTATTCCAAATGATTTAATAGGCTGCATTATTGGCAGACAAGGCAGTAAGATAAATGAAATCAGGCAGATGTCAGGAGCGCAGATCAAGATTGCTAATGCCACAGAAGGCTCGGCAGAGCGACAAGTTACAATCACAGGCTCCCCGGCAAACATCAGCTTAGCACAGTACCTCATTAATGCAAGCTTAGAGATGGCTAAAGTCAGCACCCAGACTGCTTCCGTCACGACCCCTGTTGACCTCAACATGAACCTCTCTCAGTCTGCCACCCCTACCTCCACCCCCACCTCTATGGCTGTCTTGGCGGCAGCAGCAGCTGCCTCCGCGGTTAACGTCAGTACCCCTCCCCCTTTACCAACTTTACCAACCACCCACTATGCCGTTCCTGTCTCCAGTCTGCTTGGCATGAAAACTGTCCCACTCCTGGCACTAAATGCCGCGGCCGCTGCGGGGGCCACGGGGAGTTTATCTGCTTACACTGCCAAAATTCCATCGACGAGTGGGGTTAAGAAATCTGACCGCCAGAAGTTTGCTCCATATTGAAGGGATGAGAAACAAATGCAAGGTTTTTCGAGCTCTACCAAGATTCTGTGGTAGATAATAGCTATCAAGGAAACAATATGGCATATTTTTATTTTCTGTTAAATTGCTAGTGTTAACTGTTGCCACCTCAAATTGTCTTCCACTTTCCATAACTATTAACACGTGTGCACGCACACACCCACCCAAAATGTAGCAACTAGTTCCAACAGCCTCCCTGAGTCTTTTAAACTCTAGTTGGTAACCATACTTAGCTAAAGTTTGTCATGTAACGGGTATGGTTCCCACATAATCTAGCGTGTTTAGCTTAATACAGCTATTAATAAAGGGTCCAACACTAGGCTTAGAATGGAGACAGATTTTCATTCTGAGGCATCACTGCTCTGACAACAATAATAGAGAGCTGCAGGCTCAAGTGTTGACACAAACAAATGCTGCCTGGTCTAGCCAGCGTATAGGAAAAGACTCCTTCCCAGGGCTAAGTTCTGTCCTCATTTATGCTTGATGCATTTCAGTAGGGTTGCATGGGGGACAGCAAGGACAGAATTGGGACCTTCAAAAAGGGGGGGGAAAAATGATACCTAAGACAAACGTCTTTGGCATTAGAAATAGTTATTAATTACTGCCTAGCGCATCAGTATTTATATCTATTTGAAGTGATCCCTTCAGCTGTGAGACTACTTCTCAGTTGATGTATCCTTCAAATTTGACATTTGTCTTCATGAACATTTTGATAGGCCTATAGCTAGAAAGCACCATGCGTCTCTGAAAGGAAATGCCCATGCATGCCTGACCTCCAGCGGTCATTCTACTAAAGTTCACAAAGCACTGAGACTTGTATTAATCTGCTTGGCATTTACATCTTACTAGATAATGAAGCTAAAAAGAACACCAAATATTCTTCTAATACATACATGCATATAGTCATGGATCGCCCATGTGTATGAATCTTGCTGCACTGAGAAACTCTTAACAGAATGGAAAGAGAGAGAAAAAACATTAAAGGAAGAGAAATATTAAGTGGTAACATGAGGTAATTTTAACAAGCTTTTAAATCTTCTATGTGCCATCCTTATAGCCATACTAATGTATCAGCCAAGCCTCAGTACTCACTTAACCAATCTGTTTCTATAGGATATTTACAGAGCACAATGGTTCATCTTAATTTAGGATACTAGTGAAGGATAATGTACTTTAAGGAGGCCATTTTCAGGAGGGCAGGCTCCCTTTTGGATGCACAATTTGCCCCTATATATTTTGCTCCTGCTTATGACCTGGAGGTGCAACTCCAAATACATGCATCTCGAAGTATTGAATTATGGGTACAAATCAGAGGAGCAAGTATTCAGATTTGTGCCCACAGTTTGTTTTGCAGGCCCAAGATACACTCCCACAGCCAGGCATCAGACTGGCTGAAACTAGACCCCATGTAATTTAGGGCCCAGATCATCCTCCCGCTGAAGTCAATAATAAAACACCCATTGACTTTTTCATGGGAGCAGGGTCACATGGCCTTCTTGGCCAACATGCATTGGCTAAGGTTTACTAAGGTTACTGTACAAATCCTAAATACATTCCAGTTTAAAAGCTTGGCAACTCATTTCACAGTGTAAGTTATGGTTAGAAAACAGGCATTTAAAAATGAACTACACGTACAAGCTATTTCATATCAAATGTTATTTGAAGGTTGTCACGTTGATTGGATGCCAGCCAGCAAACATAATTACACACAAGTTTACTATGAAAGGAAAAATAATTGCAAGCAAACTGAAAGTAGCTGGGAGATGTACGAGCTGGTTGCTAGCTGTTGGAACTAGTTTTTAATTGCATTTTCTGTTTGTCCATTCACCTTATTTTTAGTTTACGTTGCATAGCACTGGCTCAGTAATGCAATATTGTTTTCCTCACAACTTCAAAATTCAGAATCCCATTAGCCTGCCATGTTCATCCACTTTGCACTCCTTGGACACAAAGCTTTAACGAATTGAACTGTATTCGGTGCATTTTAATATAAACTAAAAACACAGAATGCAAATGCAATACTTTTTAAACCATGGTATTTAAAAGTGTGTTGTTATTGTATAGGGCTAAGTACTATTTCAGTATTCTTTGTCATTTCTGTATTTTATAGGCTTTTCTCCACCTTCGTACCTTTGCGCTAAGTTTTGTCACTGTAACCATTTGTAGAACTGTCGTTGTTACAATTTTCACTTAACAAAATGGGGAGGCGGGGCTGTTTGTATATAATGAAGGAAAAACTGGAACAAATGTCATGGTACCTCAGATATTTGACAGCTCTAGAAAACTGCTGTAAAATTGTTCTGGACTATTGTAACTGTTTTAATAACTGAAGTAAAAAAATGTGAGAAAACTTGCCTGCATTGAAATGCTGTTCTATGCTAGTTGTACTCAAGTGTAATTTTTTTAATGGTGCGAAGATTTTTTTTTCTTTTTTTTTTCTTTTTCTCCTCATTTTTGTTCCTACA
->XM_039832640.1 PREDICTED: Medicago truncatula lichenase-like (LOC25491909), mRNA 
-ATGATTATTTTGTTTCTTATTGTTCTTATTGGGTTGAAGACTTCAGGAATAGGAGCACAATCTATTGGAATATGCTATGGGAGAGTGGCAAACAACTTACCTCCTGCAAAGGAAGTAATAGATCTTTACAAATCAAATGCTCTTGAGAAAGTTGGAGGTGCTAATTTGGAAGTAGTCATATCAGAAAGTGGATGGCCTTCTCATGGTGATGTTGCTGCATCAGTTGAAAATGCACAAATCTACTATGAGAATTTAATTAAGCATGTTTCTAATGGGACTATTAGTAGACCTAATCAAGCATTAGAAACTTATTTATTTGCCATGTTCGATGAAAATAAAAAAGGACCTGCTGAAATAGAGAGACATTACGATGTCTCGTCACTGCAGTCAGAGTTTGTTGTGCTCGAAAGAGCCGTAATGCTTGTTGTGCTTTGTTGTTGCAGGGATAGTTGGTCCGTGGATCTGTCCGTGTTGGCGGTCAGTTCATATACCATGTCTGAAAAGATGGGTTTGGTTTTGTTCAGATCCGTCTCTGGTTTGATTATGATGCTCGCGAATGTATTGCTCCTCCAAGATCATGATGTGCTTCGTAACATGTCTTCTAGGCTAGAAATAGTCATGTACATGTTGTCCATTGTTGTTGCGAATGGAGGGTACGGGTGTTACCGTGTTGGCGGTGCTCAGACTCGTTGA
->XR_005989539.1 PREDICTED: Vulpes lagopus uncharacterized LOC121497833 (LOC121497833), transcript variant X2, ncRNA 
-GGTTCTGCGTGATTGGCCCGGGCTGCGGCCGACCTAGACTTAAAGGGACGGCGCCCTCCAGGGGCAGGAGGGAGGGAGGTGACCTGGGGAGTTCGTAGCGGGGTTGGACCACGAAGTTCCAGGGTTCTTTCTGGCGCTGGAAGGAATTTAGAAATCGCCTGGCCTGGTCCTGGTCACCTGTTCTTTCCAGAAGCCCAGAGAGACCGTGCTGCTCGTTCAGCTCCACACGGCGCTCCTCCCGCTTTCAGTGTGGCGGAAAGGCGGAGTGAGGAGTGAGATTCCCAATGTACAGAAGAGGAAACCGGGACCTACACACGGTTGCTTCCCCAAGCAGAGGACTGCAGAGGTGAATGGTGCTGGGCCACCCCCTCATCAGGTCTACTCCTCTTTGGGCTCAGGGCCCATGATTCTAGGCCTGTGTGCAGATGGAGGAGTAGTGCCTGCAAGCAGCCCTCAGTAGGCCTCCCGCATAAATACCTTGTCTCCGTGTCTACTTCAAGGATCCTGAACCCAGATGAGGTGGCCCCCGAGACAGCCATCCAGCCATGGGACCTCCTACGTACCAGGCCTGCACTAAATGAGGAGACGGGCCATAGCACATACATGACACACATAATACGAGGCGGTGCTCTGGAAGAAAGCGAAGGACAAAGGGTAGAAGGAGGGAAGATGCCATCTGTTCTGAGAGCTGTATGAGGTGAGAAGAAGCCACAGAAAAGTCTGGGTGTGGAACATTCCAGACAGGGGGAACAGCAAGTGCAAGGGGCCCTGAGGCCAAAGAATTTGAGGGACAAGGAAGCCAGTAGACCCAGAATGGAAAGAACAAGGGCCAGAGCGACAGGCGACAAGGCAGCAGAGGTGAGAGGACGCTGGTCACGCGGGGCTTGTGAGGCCGAGGAAAGAGTTTGGATTTTATTCCAAGTGGGAAGCTGATGGGAGGCTCAAGGGTGGCGGTTAGGAGGCTGTCGGCACTGCCTGGCTAGTGGAGAACTTTCTGCAGAAGGGAAGCCGGAGGCCTCGTTCTCAGGAGAGGGCAGCTGTCCTGAGCAGGGATGGTGCTGGCCCGGCGGGGCCGGGCGACGGGGGTGGACACGGGATGGAGCAGGCGGAGAGCTGACGGACGCCCCTGTGGGTTGCCTGACATGACGGAGATATCACAGGATGACACCTGCGCTTTGAACCCCTGGTTTTTATGTGACTACTTGGTTACTTTCTATCTTTTTCGTCCAAGAGAGCAGGGACTTTGTCTGCTCTGTTTTGCTCACTGCACTTAGCCTAGACTCCAGTACACTGTAGATGCTTCGTGAGTGTTTGTTGAATGACTGAATGATGGAGATATGGCATTTGCTAGGACTTGAACCCTGATCTTTTGGCTCCAGGCCCCAGTGCCTTTTCTCTCCCACCAGGGTTTTGATGAGGATCAAAGAGATAGGAGTTGTGCAAGGGGGTTGCAGGTGGCAAAACAGCCCACAAGCTGGTGGCTCTGGGGCCATTTACCAAACAGTAGCTCAACAGACTCGCCTCAGAGCCCAGCACAGGCTACAGCCTGTGCTGCCTGCAGGGTGGGCACCCCCCTAAGCCAGCCTGGCCAGCCTCCCCTGGGGAGCAATCCTGCCCCTACTCACAGCCCCTGGAGCCCACGCTCGGAGCAGCTCTGCCCAAAGAGTACACAGGTGCCCAGGCTGATGCCCAGGGGAGGGGACGGTATACTCTGCTCTTCGGACCCCAGGGGCCTAAGCCAGCCCCCCACCCCCTTCAGGAGATGTGGAGCAGATGTGAAGGGAATGTAGGCCTACCCACAGGCTCGCTCCCCCAGGCCTCGCCCCAGGGAGGCTCCTCTGGGAGACCTCTCCTTCCCCTGGGCCAGCTTGGGCCCCCCTGTTCCTTCACCCTACCTCATTGGTGCCCTGGGGCAGCTGCCTGCCCTGTCCTGAGATTTGGGGTCTCCACCGAGGCCCTGGGAGTAAGAGTCATCCTTGGCCACTGCTGGGCGGCTTTGTGGAGACCGAATCCTTTGTGATTCTCCTGACCCCTGTATTGTTCTCCCCAAGCCCTTAATCCACTTGCTACCTAGACATTCATTTGTGTGATGAACTACCTGGTGTCAGCTCTCTGGGTGCCAGGAAGCGCCTTCACCAGGAGATACCCAGCCCCCAGCCTGGGCTGGTTTTCACAGGAGGCACCCAGTAAATGTTGAATGAATGGCTGAAAGCGCTTAGCAAGCTAGGGAGCAGGAGTGATGGGAAAGTTTGGGTCATGAGGGTGGAACAGTAACTGTTCTGTCCACAGGCCGTGGGGGCAACACAGCAGGAGGCCACCAGCCCATGGCTGTGGCTGGGGTGGGGGTCGGTGTAAGCTGAGCGGCCTCCCCGCCCCACTTCTACACCCCAGCACTTAAATAACAGTAATAACAGCCTTTCCATCCATCCCTGAGTCTGTGCAACAAAATTACGAGGTGAGGACTACCGTTAATCCCATTGTGAAGATTTGGAAACCGAGGCTCAGGGAGTTTAAGGAATTTATCCAAGGTAAATAAATGGTGGGGCTGGGATTCAAATCCAGGTCTGTCTGAGGTCGGGTCCACCAGAGGGTTAGCCATGGCATCCTTCTGCTCCTCTCCTCACCTTTAAACTTCTCAGCCTCCCCCATCCACATCTGGCCTCCTCCAGACTCTGCTCTGTCCTCAGGCGCCTCTCAGAGCCTCTGTTTATCCATCTGTAAAATGGACACACTAACCCCTGCCTGTTTTGTAGTGAAGGTCCGTGAGGATGGGGATGCTTTCTGTCAGACAAGGGCTGGGCGAGCTGGCACCGAGGGAGTGGAAGCCACTGCAGGGTCCCGTCCGAGGCCACCAAGAGGGGCCGATGAGCAGGGCCCTCTCCCAGCTCTGTGGCTGCGCACGGCGGGCGAGGATTTGTTTGCAGTGGCTCCCTGGATGAATTCCCGGCAGACCTCTCCTCTTCCCTTGACATTCCTGCTGGAGGCTGAGTCTGCGGTGAAGGCCATGCAGCTTCTCCCATCCCGGACCTTGCTCCTGAGGTGGCCTCCACATTTTCCCCTTCCTGCCCTTATAGGTCTCATCTCTGCGTGGTTGCTTTAGGGCCTCAGGGCAGGGCAAGGTTAGGAGCCTCCTCTGCGATCTGGAAACTCTGTGCTTCCCTTTGGGAAAGCCTTGAGGGAAGGCAGATGTGTGTGAGGGAAGTGGTTTAGGAACCACATCTGCCCTTTATCAATCTGCCTTCCTCACTAGACTTTTGGTGCCTTGAGAGTGGGGGCTAGTTTGTGGGTTTTCTTTTGTTTTACTTTAGGGTTTTTTTTTAAGATTATTTATTTATTCATGGGAGTCTCAGAGCCCAAGTCATAAGCAGAGGGAGAAGCAGGCTCCCTCCGGGGAGCCTGATGCGAGACTCGATCCCAGGACCAGGGATAGCAACCTGAGCCAAAGGCAGACACCCAACCAGACGCTCAATGCCTGAATCACCTAGGTGTCCTGGTTTTTTTTTTTTTTTTTTTTTTTTTTAAATAAATCTTGTATTCATTCACTGATTTGTTAGGTTGTTCACAAAGGTTTATGGAGCACCTATTCTGTGTTCTGAGATCAATTCTGAGCTCTGGAGATGCAGCAGCTAAGAGAACAGACTATAGGTCCCTGCTCTCAGGAAGCCCACAGTCTAGGTGGGAGCTGGACGCTCAAGAAGGAAATCAGGCCCTATAAGCAGTGAAGAATGCCCTGGAAGGGATTAACGGGGACTGAGAGGATTACTGGAGATCCTGGCGCCCAGTGTAGGGTCTGGCAGAGAATTGGCACCAAAAACATTTGAATTCGAACTAAAGGGCCTCAAATCAACTTGTTAAGCGGCAGGATCAAGGGCCTCACCACCCCTCTCCTGTGTAGAGAGGAGCTCTTCTGGCCCACCTCCTTAGCTGCACAGCCTTAGGAAAACTCCTTCACTTCTCTGTGCTTCAGTTTCTTCATCTATATAATGGTACTAAGTGTTCCCTGCCTTTTAAGATTGTTCCAAGAACTAAATGTGCTACAGGCTTGAAAAGGGCTGAACACTCAGCCTGGAATATCTTCAGTGCTCAATAAATGAAAGGGTGAAGATGAGGATGAAGAGGATGGAAGCCAGGAAAATGGGAGGAGTGTTGGCCTGGCTCCCCTTGCTCTTGGAAGTCGGGGCTCTACTCCGCCTGGATAGGCAGTTTCAGGAATGGCCACGAGATGGTGCCCAAACACCAGTTATTCAGGAATCTTGATTTCTCCGCAGATGAAGCTGTTTAGGGAAGTAGGGGCCAGAGAAGCAGGTGCATTCTGTGTTGTAAGATGGGCTGGGGTGGGGATTTTCAGCTACTTGAAATCCAGCCCCTTCCCACCATTCTCTTCCTTCAGTTTTCTTCTTGGGGTTCCTGTCCGTGTTTGGGGGTCCAGCCCTCCCTTGCCCCTCAGGCCCCCAGCACTGGAGTCCAAGGCTTCTGTTGAGTAGGTCCTGGTTCTTGTCTACCCAATGAGGGCACCCTGGGTCCTCAAGCCATCACTTCTTCCCCTTCTCATTCACGAACCAGGCAGGGGTACTTAACTGAACACTTCCTTGGGGGCCTTGAAGGATGGAGAGCCAGAGGAAATGACCCTGTTTCTGTTCATCATATCCTGGGGGGGTGGGAGTGGGGGGAGGGGGCAGTAGAAACCGAAAGAGGGAAAAGGAAAACATGCAACAGTTACCAAAGACCTCCTTCTCATCAGCACGTAGGAAACAGCCTCATTTCACACACGCAGGAACCGAGGCTCAGAAGCACTAGGCCACACGAATGCGTTGCCCTTTCCAAGCACCAGGGGCTCCTTCGCCAGCAGCGAGGTGTGGCCCAAAGTGAGTATATTCCTAAATTCATTCCACAGCATCTACTGAGCTCTGCAGATCCAGCGAGAATCAGACCTGGCCCCTGCCCTTGGGAGCTGGGAGTCTGGAGGGAGATGCTGGCAGAGAAGCACACAAGGGCAGCTTGTCCCCGAAGTCTGTGCTGCACCGCGGTGACCCAGAGGCTGCTGTTGCTGGTGCCACCTGAACAGATGGGGGGGGGGGCAGGAGGGATGGAAGGTGTGAGAGACTTTGTAGATTCCATGGGGACCGAGGGTCTGTGGAAATATCATTTTCAAGAAGGTGAAATCATGACCCTCATACAATAAAAACAAGTGAATGCACGTCCAAGATTTCCTTTAGCTCATTAATTGACAAGGAACCAGCAAAATGTTAACACAGCTCAGATGAGGATTCCACTTCAGGCATTTACATTCTCTACTGGACAAAACTTCTTTGTGTTATGAACAGGACTCATTTGCTTGCTCTTGGGCAGGAATCATTTCCATGATTATCTGTTTTCTACAAATCGCCTCTATCCCTACAGAGTTATAAAATCAATCAAATAATCAATAGCACACAACCCTAAAGAATCAGATGATCATCCAGAGGACACGTAGCTGACACCCAGACCTCCTCTGAAAGGACACCCAGGAATCGCTCAGGCCTTTTTCCAAGGCTTTGATATGTTTTCTTGACTGACCCCAGAAGGATCGGGATAAATTAGGTAGCAGGTGTTCCAGAGGAGGCAGGTCATCTGGGTTGTCTAGTCTCAGCCTTCTGGGGTTCCCTTTCGGCTCCCAGGAGACAGACTTCCCAGTCCGGGGGGAGCTGGCCCCGCTCAGTGCCCACCAGCAGGTGGCGCCGAGGCAAATTCGCAGCAGGAACCTAGTGGGTTCTGGGGCTGGGAACAGGGGGGCAGCTCCCAATTTTCCGCCATTCCTGGTCTCCAGCAGTCAGGTTTCACGATTTCAGAATTTCAGAGGGCCCTTCCCACCTAGAGTTGTTGGTTTAGTCATTCACTGATTCAGTTTTGTTTTTTTTTTTCATTTGACAAACGTGCCCAGGCCCACAAGTCAGGTTCCCGAGTTTCTCCTTCTCCAGACAGAAACTCACAAGTATCAAAGAATCAGTCCTTGTCTTTGCTTGTCTGGCTTTGCTGCCAGGATTTGGAGCCACCTGAAATTCTGAAATCTCACTCCACCCCACTCCTGCCCTGCCTACCAGGGTGT
->JQ061302.1 Uncultured Pneumocystis clone CS13 large subunit ribosomal RNA gene, partial sequence; mitochondrial 
-TGTGAAATACAAATCGGACTAGGATATAGCTGGTTTTCTGCGAAATTTGTTTTAGCAAAGAGTTTATAATAACATTATTAGTGGGTATAGCACTGAGTATTTTTAAGAAGGAGTACTAGTAATACTTATTTCGAATACTTAATCTCAAAATAACTAATAAGTAATTAAAATAAGCTTTCAAACTATATGCGATAAGGTATATAGTCTAAAGGGAAACAGCCCAAAACAGTAATTAAAGCTCCCCAATTATTATTAAGTGAAATAAAGGAAGTTATTCTTTTGAGACAGTCAAGAAGGGGGCT
->MF242562.1 Uncultured bacterium clone denovo36630_N25_23851 16S ribosomal RNA gene, partial sequence 
-ACCAGACTCCTACGGGAGGCAGCAGTGGGGGATATTGCACAATGGGGGGAACCCTGATGCAGCGACGCCGCGTGGGTGAAGAAGCGCCTCGGCGCGTAAAGCCCTGTCAGCAGGGAAGAAAATGACGGTACCTGAAGAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGGGCGCAGACGGCGATGCAGGCCAGGAGTGAAAGCCCGGGGCCCAACCCCGGGACTGCTCTTGGAACTGCGTGGCTGGAGTGCAGGAGGGGCAGGCGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCGGTGGCGAAGGCGGCCTGCTGGACTGCAACTGACGTTGAGGCCCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCGGGTACC
->XM_044441890.1 PREDICTED: Varanus komodoensis zinc finger SWIM-type containing 5 (ZSWIM5), mRNA 
-AGATTAGGTTTTCTTTCCCTTTGTGTGTGGCAACACCTGCCCAGGGAGTCTGTGTGTATCAAAAGAGCAACAAAAAGTGGGTTTAATTGCATGCATCTTCAGTGGAGGCTTTCTGGCACTTACAGCACAAAAGGCCATTACTGAGCTGTTTTCAATGGAGACTAGGAGTGCAGGACTGAGAAGAACTCTCCACTATTCTCACAGGCAAGCAAATCACTTTACAGGAGCATTGTCATGTGGAAATGAGTTCATGAGCCCATCTTCTTCCAACTGCAAGGTCAGGGAGAGAGCAATTGTCAGTTTCAGCTGGCTGGAGCAATTGATCTGTTTGCTTGAAAATGTTTGCTTACCTCCCTTCCCTGCTGTGCTAGTATATAGATATCTCTCTGTGTGTGTCTGTGCACAGGCATGTGTACACTCCACCATATGCTGAATGACTGAAGTTCATAACTATATGTTAGCAGTTGCTTACCATATGACCATTAGTGTGTCATAGGGATGTACAGTTTTTGTTAAATCCATTCCATCTGCATTTCACAGATTGTGAGGTACTTTTCAATCTCTCCTCCATTCTCATTGACAGTGTGTGTGTGTGTGGGGGGGGAATTGTTACAAGTTCCTGAACTTCTTGCATACATGTGCTTTTTTGCAAATCTCCACTGTTAAAAATGCACAACCTCCTCCAGAATGTGCATTTGCATGCTTTAGTATGCGGGGAAATGTGCTTCTTTTCTTTTTCTTTTCAACAGGAATGTTTGTGCAAAATTCTGAAAAGTAAAGTAGTGGTTCACAAGTCCACAGAATCCATGTGATTCAGAAAGGGCTGGTAGACTGCAGAATCTGGGGAATCCTAGAAATCTGAACTCATTTAAAACCCATGGCAGGTTCTCCAATATCCCTAGAGTGTTATAAATAACTAATAGTACAGCAACCTTAATTTAATGCTAGTTAAAGCTCTTTTTGAAGAGGGAAAATCATCAAGGTCCCCCACACACATCCCCAGTCAGGCTTTCAAATATGTTTTTGGATCATGGTCAATACTGTCAGTTCCTGTGTTAGGTGTGTGTTCTTTCCCCACATATTTGCATCTCTGAAGAATTATGGCTTCTCATCTTAAGATGAAAGGCTCAAACAGTGATGCAGCTTTGGCTGGACTCTGGGGCCAAAGTCCAGGGCCCTGCATTCCAGGAAGGCCTGAATAACCACCCAGAAAATGTCAGGTGATGAAAGTCAAAGAAGCAAGTTCCATGTTATTCCTGTAGTCACGATAATACAAGGATTTCAATATATTTTAAATGCAAAACTGCACATGCTCTGTATTTTATTACTATTTTTATTATGGAGGGCAAATAGCTTTTTCATTGTTCTAACACAGCAGGTGTGCAGAAGCAGTTGTAAAGCGTGGAATAGTGGTGGTGAAGGAGGAGAGAGTCGCATGCTTCACAACTTGAAGTAATACAGCCATTTAAAAGGGGGACATAATAAGAACTGCTCTCACTCTTTGGCCTCACAGGGCATCCTGAATTGTGCTGCTGGTCAAGACTTTTGTTCTAAGATGAAAAGCTATATTCTTCAGATATTCAAATATGCGGAAAAAGAACAAACAAACAAGAATCTAAAATGACTAAGCTGCACCCCTGTCTCAAACCCAGGCAAACCATTCTCCAGATAGCTCATGATGTCCCATGATTGACCTTCACTCTGGTCTGGAAGAGTGATGTGTTTAGGGAAGGGGAAATGCTGTTCATTTGTCCAACAGAAAAGAAGAAGCTGGTAAAGTCAGAAAGAACCATGTGATCTTAGCCATTCATCACTACCACATTTTCTTGGTGTCAGGCAGCTTTATAATCGGACAGCAAGCTGTTATGCAGCAGACAGTTGAAATTGGGTTAGTCTGATTAGATGTGGGTGTTTTGGAGCTGGAGGCTGAACATGCTCAGTAAGATGATATGCTACCTCAGGGTGACAGAGAAAGGCAGAAAGCCTCTTTGTTATGGAGCGGCAGCACCTTGCTGGAAGCATGCTAGAAAGTATCAGCAATGCCTGCTAGAAACAAAATATATGGGGCACAGCTTTCTGCAATATTTTTTTAAAAAAAATTCAGATTCTGTAACAAAAAGAAACAAATACTGAGCAGCATGTAGCTTGCTGCTTCTAGAATTTATACTGCTACTACTTAAACAGCCCCACAATTTGGATAGCTTTAAAGGGGATGGGACAAATTTATGAAGGCAAAGCTATCTGTGGCTACTAGTCCTGGTGGTTGTTTGTTACCTGCAGTATCAGAGGCAGTGTGCCTATGCACAGCTACTGTTTGCTTCTGTTCTTTAACCAGTTACTGATCCATGAGAGGACCATGATGCTAAGTTTGTTCAGGAACCTTTGGTGAAGGACTTCGTGAAAAGTGCTAGAATACACTGCCTGATGAATTGTGATGTATCATTCAACAATTTGAATATGTCAGTTCTTGATTTAGGATACAGCCTGCCTCCTACTGACAGCTCAGGGCAGACATCCATATTCATCTGTAAACATAAAAACAGAAATTTAGATAAAATGAATAGAGCCTAGCAAATCTTAGAACACTACCTTATATATCAGGTGCTTTTAGGCATCCAAGGAAATAAACTTGTACCAGATTGGGGAAGCGAGATAGAAGAGAAGCACTTCATTCCCCAAAGCCAAGAAATTATATTATTTATGAGTGAACATAATGTCTTACAGAATAGCACCAACAGAAAACTGGTATCTTTCTCGAAGTGCTTAAAATCTAAATTAAGGCCACAGCTTTTGCAGGTGGGCAAAGAGAGAAAACAGAATGAAGGCAATGAGAACAATGGTGTGAACCCTCTACCTTTTTCCAAAAGTTCAAAGTAAGTTGTTGCCAACTTAATTTGCACATATGTTATAAGAATCATGAGAACAATTGGGATAAAAACTGTTTGGCATTCTGAATTGTTTCCTTCTCTTATATTTCGTATTTGAAAGTGTCCAAATTTGGCCAAATGCACATATTTCTAATTATGTAGTATTTTCTAAGCCCCATAATTCAGGATACTCCATTATTCAGCCCCATAATTCAGGATACTTGCTCATTTTCCAGACATTCACACACCACTCACCACTCACCAGGAGACCATTCTTTTCCTACATTCCATGTTGTATATTTGGGAAACAAACAGGCTCAAAGTATTATCGTGGCATTTTAATTCCATTCTTCTTTGGCATATATGCTTCCCTCTTTTATACTCACAACACCCTGAGCTAAGTTAGGCCAACCAGTCTAGATTTTACTGAAGAGAAAGGTATTTAAAAATAAAATTACTAAAATAAAAGACAATAGTAACAGGCTCAAGCTTACAGTAAGTTTCACAACTGAGTGAAGAATTGAACACAGGTTCCCATGGTTAAAGTTCAGCGTGTTATCTGTTACAGCACACTAGCTCTTACTACTGCTTTGACAGCTGCATCTGTAAGTGTTTACTGAATGAACCTGCATTGTTTCACTTTCAATGAACTTTTCTTTCCTGTACCAGATTCACATTTCTGGGGCTTGAAGTACCTGACAGCCCAGTTTTCTTTGTGGGAAGTATGGTTGGGGCAGTAACCTTTCGTAAAACATGTATTCCTATATTGGCTTTGCTAGTGATTATTCAAAAGTATGACTACTGAGGCAGCCAGTTGAACAAAAGCATCCCATGTACTCATGTAAATACTTCAGATAAAATAAATATCCTGATGAACTTTTTTCCAGAGCAGTGTTTAATCTTTGGCTAAACATTTGATAAATATTTTACATTTTTTCCTAGTTGATATTAAATATATGTGCTGTCATGAAAGCTAGAAATTAAACTAATGCTTGATTTAAAGCCTAAACATCAGATAAACTTGGCAGACTCCAGAGATACTTGCGCAAGACGTGAGTTGTGTCCCTTTCCCCTTAGACTGTTTTCCAGCTGTCATCAACACCAGACCAAGATATTTTAAGGTAATTTAATATGCCTAAAAGCCAGTGTTTAAAATGGAGCAGCTACTCAGTTGGTTCCTGGTCTATTTTTCTGATTTGCCTGCAGACACAGATCACAGAACAAGGTTTATACTTGGTTTGGATACTGGTTGGAGAATGAGAAATAAGCTGTGGGCTTACACACTTTGCTTTCCCTTTGCAAGTAGATTTCTTTCCTTGCCCCCTGGCTTCTACCGCATCTTCTTCATTCTCTAACAATCAGCCCTTCTCCCATCCACCTATGAACCAAACAAATGCATACAATATTTTACTTTGAATGTAATATATGCAGGTATTGATGAATGGGAGGCAATTAAAGAGGAACTGATTGAATTTTGCAGCAGAATCTGGATAGGAATTGGGAAATTAATTGAGGTGATATCCTGACCCATCCTTGGCTGGCTTTGTAATTTTCAATAAATAAATACATAAATTTTAGGGATGTGTGTAAGAGGACTTATTTGGAAAAGTTTCCCAAACATTGTTTCTTGTTTGTTTTTTCACTTCTGTTCACAGCCATTGCAAAGTAATTTAAAATAGTTGATGCACAATTTAGCTAATTAAAAATTATATGGTTTTATAGTTGATTAACCAACTGATAAATTGCAGCCCTTGTATTTGTACAAGCAGACAGTGTGACTATGGCCAAGATAACTATAGTATCAACTGAGGTATTGTCAACTTGGTAAATGTCTGTAAGTTTCTATCCCTGATCAGATGTAGTCTGTAGGCTACCCAGTATAGCCTTAAGGGACAAGAGCCTCCACGACTCTGGCTGCTCATTTGCATGAAATATTTCTTTATAGGTGGTAAGGATTTCAGTTCAATTGCCAGTATTAAAATATGAGTGGAAAGAAATCTAGTAATGTGGCTAAAGATTATTTTTCAAAGAACAGGTAAAATATAAATGCCTTTGAATTTTTGCCTTTTTGAGTGTTATCCTTTAACAAAAATTCTAATAGAGACTCTAGAATGAAATTGCTAAATTAGAAATTATCAAAGGTTGGATTATGTTGGGTTAGACCTGATCTGAGATATTGGTGGGGTTTACATGATCATGAGGAGAAGAAACCACAGTGGCATCTTTTCCCTGCCACTGTGCAAGGCAGCCATTCCTACGCAATTATGGTGTGTGGGTTGCTCTGTTGTCCAAGCCCAGTGGGGCAGCTTTCAGAGCATGGCTTGTTGTAGGTTTCTGGGGTCGTGGTGAAGCCACGTCCTCCTGTGCACCTTGCTTGATTTGGGCAACACAGCAATGGATGTGCTGTGAGGGTAGTTAGGTAAACTGTGCAGCGCACAGCTGTGTCTTATTTTTCCTATGATCTTGCCACAATAAAAAATCTACTAGTCTTTAATGTGCTACAAGTCTGCTGCTTTTGCTCAGCAGACCTTTTTTAGGATTTGTATGATGAACACCTCACAGGAAGAATGGAGCTCTTGGCTAAGATTTTCTTGTATAAAATGCATACCTTTGTTCCTATCTGCTCATGAAGAATCATACAATGGGATATCAAGAGAGGAAAAGAGAGGAGAGTGAGGCTGTTGATGATAATGTTACGGAGTCCTTTATACTGAGCTGTCTTTACCCTCAGCATGCAGTATCATTATGTAGGGGTAAAGAAAGGAAGTTGCTCCTGCTGTTGCAAAGGAATAATTGTACAGAACTGGGAGTTACCATGCATATTGGTTAGAATGAATTAAATGAAGAACATGGATATGTTGATTGGACAGGTTTTGAATGGAGGTGGTTTTTTGGGTATATTCCTGGTTTTTAGATCAGTCTAAGGAGTCTATGATTTGTTTAGAAGGCCTTTAGAAAAATCTAGTTCCTAAAGCGAAAAAGAAAACCCCTCTTAGTACTTAATCAGATCTTGATGTGGGTTTTGGCATCACTTTAAAGAAGATGGTTTTGATACTGTTGATTAAAAACTTCTGGTAGAATTTGACTCAGAATGGTTGTGCTGTTTGGCAAGCACACAAGGGCTATATGCAGTTAATGTAGTTAAATAAATTTTCTCTTTTGCTGTCTGTAAGCCTTTCAGATTCCTCTGGTATGAGTTAACATTTGGAATCATAAAAAATTTCTAGCAGTATAGTCAATAGTCATCTGAGAGGAAAATTACAATGTGGTTGAACTTGTGCGGTGGGAATCTGGACTCACAGATAACTTTTTTTCCAATCATATTTTAAATTTAGGGAAGTCATCTGATATTTCACCTTACTGTTTTCATATTTAACTAACTGGAATATTAGATGATGACTATTCTGTATCCACACATTTTGGGAACTATTTTCCTTACATTTTGTTGGTTGGAAGCTGGTGTGTTGAAATATTAGTGAATTTTCTGCTATGAATTGTGTGAATTTTCTGTTGACCACTTTGGAATGTCTTGGCTGTCAGTCTTTCCCTCCTTCTTTAGGACAGCCAAGACCTGCATGCCACATTAACAAACATTCCTTTGCAGTTACCAGAACTGAAAGCATCTCATTTAGTTCCTTTGAGAGCCTAGTGGGTTGAAGAGCTCTTCTCAAGGACTGTCTTGATTGCATAAGATGATGATCAAGTGTTGGTACCCCCTTTTTTCTGGATCACCATTTATTTTGACTGCTGTCTCTCTAAGCATGTGGATCTGTGCTGTGGAGTAATGCTCCAGGATAGCGTCTATGTACCTTATACAATACTGGTACAAAGGTGAATGCCATTTTGGTCTGTATGTATCCATGATCATGGTCTCTAGTTCTAGCCTCCTGTAGTAAAGATCCAGGAGAGAGTAACAGCATAGATTTTTCCTATTACTTTTGTCCTGGTAAAATAGCAGTTGAAAACTGGGTTTTCAGAGTTGGGGTAGGAAAAGAAACCACAGTTGGACCTTATTTCCCCACCTGGGCCAATTGCATACTGCTTCACTTCCATAATTATCCATGCCAAATGTGGGTTGCTGTGTCATCCAAACCTGATTGGGGGGGGAGGGGGGAATGTTCTAAAGCACTTGAGAACCCTAGAATAAGCAAGGTGGTTTGGAAGTCATCTCTGTGGGTCTGGTCAAGCCAAGGCACCTCCCTTCAGATTCAAGCATGCTCAGAATGGAACAAAACCACTTGTCAAGAAATGATATACAGTTTATGAATACAATGGTGAAATACGGATGCAAAACATAAACTAGCAAACAAAAGATTATAGTCCCCTTATTTGTGGCCATTTGTTGTTGTTCCCTAAGTAGGTCAGGGATGCTCCATGGGCTTCCAGAATTGCCTGAGTGAATGACTCATTAATTCTTCTCTTCAAGCCAAGAACAAAAGATAATGCCTTTTGGCACAGATTTTATAAAGTTCTTTTCTCACCTTGTTTTGTAGGCTTTCAGTACAAACAGCTTTTAATTTCATTCCTGGGAGACAAGAAAGGACAAAGCTGCTACAATAAAGCAACAGTTTTTGTTCTTACAGTAAGAGCAGGGCTTATCTATTTATGTTTGCTGTTATAACCTTGCATTTCTTATACAGATGGTTGTTAAATTTCCTTGGAGTTGTTTCAGTGCTTCCTTTATCTTAAAGTTTCTACATGGCTTTAATATTTATATATTACTTTCCTCAAGAGTATATAGGCATTTATGTTACCTCAGTAATATATAGAAATCTGTATGGTAGGATTGAATTATTATTCCTAAATTGCAGATGTGATAACTGAGATTGAGAACAATTTGCTTAAGGGCTAATGTAGACATCTTGGCTGCAAGCCCATCTGTTACAGTGTGGATCGTGCAGCTTTCTCATAAATCAGGGGGGGAATTAAGCACAATTTGACATGGGTGGATAAGATGTATGCTCAACTTTCCTGCTACTCTTTCTCTGCTGCCATTTATTATTTAAAATATTTATATGCCATCCTGTCACGAAAGCCTCAGGACAGCTTACATATATGAAATAACATAAAATATAACATAAATATTTATTTATTCCCCTTCTTGTGGCTGCAGTGTGGAAAGTAGCCATCACTGGGAGGAAACATCTGAGAAGAAGCATTTTTGTGTGGAAGTGTACTTTATGGAAAATTGATATGATCTACATTGTAGATCACTTACTTCATTGTCCACGTTCTTAGATGGAAATACACAGAGAATTGTGTTTTTCACCTGGAATAATGAAGGAAAGAAGACATTATCTACAATTTTACTTAAATTGATTGAGGTCTTGAAGGGAAGGGCTGCATAAATATTTTAATGCAGTGTGGTTTTGCTTTCGTATTTGCTAAAATGCATTGGTGCTCTTTCTCACTCAGTTTGTGTCCATTACACCATCACAAAATAAAGGGTGAATATTTTTGTTTCTTTGCTTTGAACTGTACCATTTTCTGACACAAAATAATTTTCTGTTAAGTTTCTGAGCCATTCTAGATGTGTCTTAAGATTGGGTCTGCTCAGCTGCAGCATTTATATGTCATGGGAATGAATATAGACTATTTTACCATAGCAAGTTTATATATAATTTTCCCTAGATTTGTGTTGTCTTTGTTAGTGAGGCATTGTACTTTTTGTTCTTTTTCCCTAAGAGCACAATCTTATGCAATTTTATAAAGAAAGTATAGACTGCTGGGTGGGGCATGCTGGATGCTATAGGCCTTTTTCTGGCTAAACTTGCATAGGCTTGTGTCTTAAAGCAATGAAATATGAATTGATATGTTGCAATGTTGTTCAACGGCAATTAATGACCTTTTAAATCAGATTTGGTGGTGTGTTATATTTTGCATGGATATCTGGCAGTTGACTGATTTTTGCAAAGCCTACCTTTCCCAAAAATACTAAACCATATTTTCTGGCAGAGAAAATGTCCAAGATGCAGCATGATATTAAACCCCTTTTGCCATCAGATGAAGTATCTCTCAGTTGCAGCCAATCCTTGCTTATTTGGCAATAAAGGACTGGAAGGAATGCAGTTACGTTACAGGGACATGAGACTGAAAAGGGAGCAACCACTCTTTTCTCCAAAAGTTTAATGAATTTGCCCATGGGTTTGATAGTAGCTGAAAAGTCTGAGACAATTTTGGAGTGGGTCTTATGCTAGTCCAACTGATTTGAAAGCAAATTGAATATTTTACATTCCGTTGAGTACTACAGTTCATTCAGCTTGGAATCATTCTAAGCTGGCTAAAGAATGCAGAATGTGACTGTTCAACTGGAAGCAGCCTTCATGCTGGGTAGATAATTTTCTTGAGCCCTGAATATATTTTGGTTTTGGAGAGAGGGTACTGCTGCCAGTGGCTATGACCTGTCTTTTGTGCTCAACAGTTTCAAGGAGGGTAATGTGTGCATTCTTGTAAGCATTATTGAAGCCTGAGCTTAGTGGTGTTCTATTAAGATGAAGTTTCCTTGCAAAGCTAAATATCCTTCTCCCTGTTTTATTCTCCTTCTCACAGGATTCCACCTGAGTGGCACAGTTACAGAGCCTGCTACTTCAGCAGAGCCAGAAATGACCTATAAAGTGGCCATCAGCTTCGACCGATGCAAAATAACTTCCGTGACGTGTGGTTGTGGGAACAAGGACATTTTTTACTGTGCTCATGTTGTGGCACTCTCGCTGTACAGGATACGAAAACCTGATCAGGTCAAACTCCGTCTTCCTATCTCAGAGACCCTTTTCCAAATGAACAGGGACCAGCTCCAAAAGTTTGTTCAGTATTTGATCACAGCCCACCACACTGAAGTGCTCCCAACAGCTCAAAAACTGGCTGATGAAATTTTGTCCTCCAACTCTGAAATCAATCAAGTTCATGGTGCACCAGACCCCACTGCAGGGGCCAGCATTGATGATGAGAATTGCTGGCATTTGGATGAGGAACAGGTGCGGGAGCAAGTGAAGCTGTTCCTCTCCCAAGGAGGGTACTATGGCTCTGGGAAGCAACTCAATTCCATGTTTGCTAAGGTCCGTGAAATGCTGCGCATGAGAGATTCCAATGGGGCCAGGATGTTGACACTAATAACAGAGCAGTTTATGGCAGACCCACGTCTTGCTCTTTGGAGACAGCAGGGAACAGGCATGACAGACAAATGCCGACAGCTCTGGGATGAGCTGGGGGCGCTGTGGGTGTGCATTGTGTTAAACCCACACTGCACGCTGGAAGAGAAGGCATGCTGGCTGCGACAGCTCCGGAAGTGGGGAGATATGGATGTTTGCCCGCTGGAGGATGGGAATTATGGCAATGAACTTCCCAACATCACTAGTGCACTTACTCAGAGCTCCAGTCACAGGCAAAGCTCTTTAGCAAGGCCGAGACGCACAGTGTTCACTCGTGCCATCGAAGGTTGTGATCTGCACTGGCAGGATAGTCACCTTCAGCGGATAATCAGCAGTGACTTCTATATTTCTCCCTCTTACCAAAGGGATGGAGAGGGCCTTCTCTTCAACTCGCAGGGGCAGCCATTGTGGCTGGAGCATGTCCCTACAGCCTGTGCCCGTGTTGATGCCCTTCGTTCACATGGATACCCCAAGGAAGCACTCCGTCTCACTGTAGCTATAATCAACACCCTGCGATTGCAACAGCAGAGGCAGCTGGAGATATACAAGCATCAGAAGAAAGAACTGCTGCAGAGAGGAGCGACCACTATCACAAATCTGGAAAGTTGGGTAGGGCATCCGCTCAATCCCATTGGCTGCTTATTTCTCACATTGACCGAAGCATGCCGAGTAGAAGACGAGAACTGCCTTGAAATTTCAGATGCTGGTGACCCGAAGCCTCCAGTGTATCAACACGTGCCAGTGGCCAATGGCACTCCTGAGAATGGGGAATCCTACCTCTCCCTAGCTCTGGAAGTAGCACTGATGGGAATGGGGCAGCAGCGGGTGATGCCCGAGGGCCTTTATGCTCAAGACAAAGTGTGGCGGAATGAGGAGCAGATTATTGCCTGCCTGCAGGAGCTGGAGCTGGATGCCGTGCTGGTGCAGACACTACGCAAGCAGTGCATCCTGCTCCTGGAAGGTGGCCCCTTCAGTGGCCTTGGCGAGGTGATCCACCGAGAAAGCGTGCCCATGCACACCTTTGCCAAGTTCCTGTTCTCTGCCTTGCTGCCCCACGATGCTGACCTAGCCTACAAACTGGCACTGCGTTCCATGAGACTTCCTGTTCTGGAAACAACTCCTTCAAGTGATGTCACACATTCTCACCATCTGGTTTCAGTGGTGCCTAGTAGGTACCCACGTTGGTTTACTCTGGGACACTTGGAATCACAGCAGTGTGAGCTGGCTTCCACCATGCTGACAGCAGCCAAAGGTGACATGCTGCGTCTACGGACGGTCCTGGAAGCAATTCAGAAAAACATCCACTCTTCCTCCCTGATCTTCAAACTGGCACAGGATGCCTTCAAGATTGCAACTCCTGCTGACAACAGCTCTGACACAACCCTGCTCAATGTGGCACTGGAGCTTGGGTTGCAGGTGATGCGCATGACCCTATCAACCTTGAACTGGAGACGGAGGGAAATGGTGCGATGGCTGGTGACCTGTGCGACAGAAGTGGGTGTTCGGGCCTTGGTCAGCATACTGCAGAGTTGGTATACCCTCTTCACCCCCACTGAAGCCACCAGCATAGTAGCAGCGACAGTGATGTCTCATAACACCATCTTGCGCCTCAGCCTGGACTATCCGCAGCGAGAGGAGCTGGCCAGCTGTGCCCGTACACTGGCCCTCCAGTGTGCCATGAAGGACCCGCAGAACTGTGCGCTCTCAGCCCTGACTCTGTGTGAGAAAGACCACATCGCCTTTGAGACAGCCTACCAAATTGTCATAGATGCTGCTTCCACGGGCATGACTTACTCGCAGCTTTTCACCATTGCACGGTACATGGAGCACCGAGGGTACCCACTGCGGGCCTTCAAGCTAGCCTCGCTTGCCATGACGCACCTCAACCTTGCCTATAATCAGGACACACACCCTGCCATCAATGATGTGCTTTGGGCATGTGCACTCAGCCACTCCCTGGGCAAGAATGAGCTGGCAGCCATTATCCCGCTGGTGGTGAAGAGCGTTCACTGTGCCACTGTTCTGTCTGACATCCTACGGCGCTGCACCATGACAGCACCTGGTCTGGCAGGCATTCCTGGCCGCAGGAACTCTGGGAAACTGATGTCAACGGACAAAGCACCTTTGCGCCAACTGCTGGATGCTACAATAAGCGCTTACATCAACACCACACACTCCCGGCTCACCCACATCAGCCCTCGGCATTACGGAGAATTCATAGAGTTTCTTAGCAAAGCTCGGGAAACTTTCCTGCTGGCTCAGGATGGCCACATCCAGTTTGCGCAGTTCATAGACAACCTCAAGCAGATCTACAAGGGCAAGAAGAAACTCATGTTGCTAGTGAGAGAACGGTTTGGATGAGCTGCTGCACGAGGAAACCCTGATCCCTGTTGGTGGAATTACGCTTACCAGGCAAGACTGATGGAGTTTTCCATTCAGAGAAGATTGGACTGTAAACCAAAAGCAGCATGGCAGGAAGGGTTTGCGTCCTACCTACCATTCATTTGCAAACACCTCGGCAATACCAAAAGCTAACTAGGAAACTGAATACCTCTTTCCCAAAGGGCATGGCAAATGGAGGCTGGAAAGCAAACCCCCACC
->XM_031777163.1 PREDICTED: Contarinia nasturtii U1 small nuclear ribonucleoprotein 70 kDa (LOC116346891), mRNA 
-GTCCGACGACCAACGAAGACACTTCACAGCAGATATTCATTGCGAACGATACATTGTAAAAATGTATCGGTAAAAAAGTAAATTTGGAAATTAACCAACTCGTTCTCAAAAGTTACAAAGAAAAAAAAAAAGAGTGAAAAATCTGTCATTTTATGCAATATCAACGAAAAAGTGCACTTTTAAAGTGAAAATTATAAAATATTAGTGAATTGCGTTGTTTGATACATCGACATAAACATTAGCACAAGAAAAGAAACATTCAGATCTTGTGTCATTTGAAATTGTTTTTCATACGCATACTGCGAATAGTTTTGAAATAAAGACGACGAAAGGTTTATTCAGAAATGACACAATATTTGCCACCAAATTTATTGGCACTATTTGCTCCACGCGATCCATTACCATTTCTACCACCACCCGATAAATTGCCACATGAAAAGAAAACAAAAGGTTATTTAGGCGTTGGACAGTTTTTGTCGAATTTTGAGGATCCTAGTGAAACTCCGCCACCAACCCGTGTTGAAACACGTGAGGAACGTTTAGAGCGACGTCGAAAAGAAAAGGCTGAACAAGTTGCTTATAAATTAGAGCGTGAGATCGCCATTTGGGATCCAAATCAACTTCAAGATGCCACAGAAGATCCCTTCAAAACATTATTCATCGCTCGTATCAACTACGATACCTCGGAATCGAAACTGCGTCGTGAGTTTGAAGTGTATGGGGCAATTAAAAAAATTGTCCTAGTTCACAATGTTGACACAGGAAAGCCTCGTGGCTATGCTTTTATCGAGTACGAACATGAACGTGATATGCATTCTGCGTACAAACATGCTGATGGTAAGAAAATTGATGGTAAGAGAGTATTGGTCGACGTTGAGCGCTCAAGAACGGTCAAAGGATGGCTTCCTCGTCGTTTAGGTGGTGGTTTGGGTGGAACAAGACGTGGCGGTCCTGATGTAAATATTAAACATTCTGGACGAGAAGACAATGACAGAGAACGAGAAAGATATCGCATGGAAAGAGAGCGTGATGATTATAGACGCGACTTTCGAGACAGAGAACGACGTGATCGTCGATCACGGTCTCCGAAAGTTCGTGACCGTGTTAGAAGTAGAAGTCGAGATCGCAAAGAACGGAAACGACGACGATCAGAGGAAATTGAATACGAGAGAAGAGACTCACGTCGTGATCGTGAAAGAGAAAAGGAACGTAAACGTAGTAAGCGATCGAGATCCCGAGAAAGAAAGCGAGATAAACGTGATAAATCACGTGACAAACGCGATAAAGAGCGTAAAGAACGAAAACCAGAATATGGTGAAATTAAAATCAAAGAAGAACCAGTTGATGATGATTATCCTGACTATAATTCACGTATCTACAGTTCATACGGAGCCGAAGTCAAGTATGAAGATGGCGAAGAACAGAAATATCGACCGCAGGAAAACAATGGCCAGTACGGACATAATGACGATGATGACTATGATGACAGAGGATACTAAGTTTTATAAGTTTTTAGCGTGTAGCAGCGGAGCTCATACAAATGCGTTACTGTCAATTTATACGGTATTGAAGTAACGCAATATTGAACTCTCCACAATTAATATTAATCAAGCAAAAATGATTCGATTAATTATTAATTTTTATTTTTATTTTTGAATCTAAGAAAAACAAGTTAAATGCTCCGTAAAATATTTCATTTGCGCTACTTTTATCTCGCTTTCGTTCTCCAAAATATACAAAAATCGTTTTTTTGGTAGGTATACACAAGTTAATTACAATTTTCCTATAAACAAACAACAACAAAATTAATAACTTTGACAGGCGCTATGATTTGTAAATTTTATTAATCAAATGTTATTTTGCAAACGGAATAAAGTGAACGAAAACGGCTTTTGCAGTGGCAAACACAATAAAAATTACAAACATATTTTCA
->XM_047789246.1 PREDICTED: Phacochoerus africanus adenine DNA glycosylase-like (LOC125132267), transcript variant X10, mRNA 
-GCGGGGAGGGAAGGGGAAGGCGTGTCCTCGGCAGCCGTCAGGCCAAGTCCTCTGTCGCTCGTGAGATGTGGCAGAGGTCACAGCCTTCCGGAAGAGCCTGCTGAGCTGGTATGACCGAGAGAAGCGGGACCTGCCCTGGAGGAGGCTGGCGGAGAGTGAGGTGGACCCCGACAGGCGGGCATACGCTGTGTGGGTGTCAGAGGTCATGCTGCAGCAGACCCAGGTGGCCACGGTGATCAACTACTACACCCGGTGGATGCAGACGTGGCCGACCCTGCGGGACCTGGCCAGCGCTTCCCTGGAGGAGGTCAACCAGCTCTGGGCTGGCCTGGGCTATTACTCTCGAGGCCGCTGGCTACAGACAGGCGCCCGGAAGGTGGTCGAGGAGCTAGGAGGCCACATGCCACGAACAGCAGAGACCCTGCAGCGGCTCCTGCCTGGCGTGGGGCGGTACACAGCCGGGGCCATTGCTTCCATTGCCTTTGGCCAGGCAGCTGGTGTGGTGGACGGGAATGTAGTTCGGGTGCTGTGCCGCGTCCGAGCCATAGGTGCTGACCCCCGCAGCCCCCTCGTCTCCCAGCAGCTCTGGAGCCTAGCCCAGCAGCTGGTGGACCCAGCCCGGCCAGGGGACTTTAACCAGGCAGCCATGGAGCTAGGGGCCACGGTGTGCACCCCCCAGCGCCCACTCTGCAGCCAGTGCCCTGTGCAGAGCCTGTGCCGGGCGCACCAGAGGGTGGAGCGGGAGCAGCTTTCAGCCCCCCAGAGCTTACCGGGCACTTGTGACATAGAGGCGTGTGCTCCCGACACCGGACAGTGCCAGCTCTGCGCACCTCCCACAGAGCCCTGGGACAAGACCCTGGGAGTGGCCAACTTTCCCAGAAAGGCCAATCGCAGGCCCCCCAGGGAAGAGAGCTCTGCCGTCTGTGTTTTGGAGCAGCCCAGGGCCTTTGGAGGTGCCCGACTTCTGCTGGTACAGAGGCCCAACTCAGGTCTGCTGGCAGGACTGTGGGAGTTCCCGTCTGTGGCCGCAGAGCCCTCAGAGCAGCTCCAGTGCACGGCTCTGCTGCAGGAACTGCAGAATTGGGTCGGACCCCTCCCAGCCACCCGCCTCCAGCACCTGGGGGAGGTGGTCCACAGCTTCTCTCACATCAAGCTGACTTACCACGTGTACGGGCTGGCCCTGGAAGGACAGACCCCGGTGACGGTCCTGCCCGCTGACGCTCGCTGGCTCACCCGGGAGGAGTTTCACGCCGCAGCTGTCTCCACAGCCATGAAAAAGGTGTTCCGTGTGTATGAGGGCCAACGGCCAGGGACCTGCAAGGCTTCCAAAAAATCCCAGGTGTCTACCCTGTCCAGACGGAAAAAGCCCAGCCCAGGCCAGCAAGTCCTGGATAATTTCTTGCGACCCCACATCCCCGCTGATGCACCCAGCCTCGACAGTACAGCCCAGTGATGCCTCTGGAAGTTCTCATCCCCTGAGAATCTTGTTTAATAAAGTGCTTATTTTTGTAATCA
->XM_007261321.1 Fomitiporia mediterranea MF3/22 uncharacterized protein (FOMMEDRAFT_143842), mRNA 
-CGAGTGGTTACAATATTATGCGCGATGACATCGCACTGCTCGAGGTGCATGAGAAGCACCCTCCGTCTTTCTCAGCAAATCTCTATCCTGACTACTGGACTCTCAATCACGGACCCAAGTTCTCATATAATAATTCTGTTTCGTCAATTCTGGAAGATATACGGGCCTTCAGGATACCTACTGACTTCATTAAAGTTTTCGACGAGGCAGGTATACAGTATTATAATGGGTGCTTAATTGTTGAACTCTTGGATTTCCGACCTGCAAGGGCGAAGGAACCAGTACTGGAGAAGCCAGATAAGCAGCGCGTAGTACTGCGACCTAACGCTGAAACAATATGGGCAGACATTTGCAACATGAACGAGAAGACGGGGTCGAAATGGTCAGATATGGATGCTCTACTAGTCGAATCAAAGATTCTGTTGTGTACTTCGGCTCCGTTATGTCTGGATCCGGATCCGTCTTTGACACGAGTTGTTAATAGTATTCTCCGTGTCTCCACGCCAAACGTTCCGAATTCACTAAAACGCAAGGCAACTGCTATGGTTGACATCGAAGAAGACGAAACCGAGAAGGCCAAACGTGCGAAGATTATGCAGTTCATGAATCCGCAATTTAGCAATACGCATAAGCCATTTCATCCTAGTTATAAAATTCTCTCAGTTATGGAACAGAAGCGTGCAGCGGCAGCCTCTCAGCAGACCTCACAGCCTGCGACGACTACATCAGTTCCAAACAACATATCTTCTGGTACTATGGCTCCGCAGAACCTGACTCGCCAACAAGCACCTGAAAAACCTTCAGCGCCTGTCGCGCCTATCGCACCCACACTTACCACGTCGTACTCACAAACAAATACGAACACGATTCCACAACCCGCACCCACCACAGTCCCCCAGACGCAGGCGCCACCTGCTATTGATCCTGCCCATAGGCAGTCGCCTTCAAAACAACAGCAATCCGCAAGTCAGCCTCTCCCACAACGCCCACCGTCGCAAACTGCCGCTCCGCCGCAGGCGAGCGCGGTTAGCCAACCGCCTCAAGCTCAAGTTCCTCAGCCAACTCGACCTCAACCGACTCAGTTCAACCCCCCATTACCTCCGGCCAATTTCCTCAACCCTGCTCTTCCCCCTGGTCGGCGCCGACCTTCGACAGTTGTTAAACCTAGCACTCCTGCTGTTGCGACCTCTTCGCTGCCGACTCAACAACCGGTAAATCAGAGTCAACCGCAGACTCAAACACAAATACCGACGCAGACTCCGGTTCAATCTCAACCGCAAACACAACCGCAGCCAGCATCGCAACCACAACCGCAGCAGCCCGCACCACAGCCAATTGCACATCCAACGCAGGTACAGGCACAGGCTCAACCGCGTCTCGCACAGATTCCTGCAAATATGGCACAATTCTACCAGACCGGTAGACCAACAATGGCCATGACACAGGCTGCAGCTGCGACCATTGCAGCGCAGAGACAGGCACAGAGTGGTCGAAACACGCCTATTACTGTGAACAACCCAAGTTCCTCGCCCGCACCACCTCCGTCGGCGCTAGCACGGAGCCCTATGGTACCGCCGGCTGTAGCTGCAGCGATGATGTCAAGGCAGAGCACACCGGTAGCAACAAGCAACCAAGTCATGCGTGGTAGTCCGCTAGTTGGAAGTCACCCAGTTGTCGCACGGCCAGTTGCAGGACAGACACCAGCTCCAGTCCAACAGCAACCCCAGCAACCTCAGCAGCCGATCCCGGGCAGCCAGGCGATGATGATGCAACCAGGTGCGAGCGCGAATCCCCAGGCAGTCCTCCAGTACCAGCAGCAACGTATGGCCATGTATAGGTCGCTACAAGCGCAGGCGGCCCACGCACAGGCAATGCATCAAGCGCAGATGCAACAGCAAGGTCATGTGTCACCGGCGCCGCAGCAACAGCAGAATCCACAAGGTGGCAATACCCAAACAATCCAGCAGACCGCGCACGATCAAGCTCCCAGAACACAGCAAAACTTCGCCGGCGTCCAGATGCCTCTCAATTATATGCATATGGGCCAAATGGGCCAGATGGGTCAGATGGGTCAGATGGGTCAGTTGACTCTACAGCAGCAACAGCAATTCCTTTGGGCCCAGGCCCAGGCCCAGACTCAGCGAAGCATGGGTCGAGGAATGCCCCAAGTCGGACCAAACGGGCAGCAACAGATGCCAACTATGCCTGCAAACATGACACTCCAGCAATATCAGCAAATGCAGGGGTTGGGACGTGGTGGAGCCCCACCGAATCGATGAATGTTATTCTTTCCACTTTTTCTTTTCCAATTTGCCATGTATTTCAATCTGTGTTTCCTCGTCATGCTTGCGTCCGGACAGGTGTTAACGTAGATGTACCTCAGTGTATCTTTATCTCAGCTTCTTCGTAACGAACAACGCCATGAAATGCTCCCG
->XM_045941201.1 PREDICTED: Trifolium pratense germin-like protein subfamily 1 member 17 (LOC123891348), mRNA 
-ATAATTCACACGAGCAATATATAACTTTTACATAAGAAGAATAAATAATTAAAGAGTATTAGCTAGTGAGTTTGAAAATGAAGGTTCTCTACTTCCTAGTTAGCATCTTGGCTTTGGCATCATCAGTTACCTTTGCTTATGACCCCAGTCCTCTCCAAGACTTTTGTGTTGCAATCAAAGACCCCAAAGATGGTGTATTTGTGAACGGAAAATTCTGTAAAGACCCTGCTCTTGTTAAAGCTGAAGATTTTTTCAAACATATTGAAGCTGGGAATACATCAAATCCATTAGGCTCTCAAGTAACTCCAGTTACTGTAGACCAACTGTTTGGACTTAACACACTCGGTATATCTTTTGCACGCATTGATTTTGCACCTAAGGGTTTAAACCCACCCCACACTCACCCCCGAGGCACAGAGATCCTTATAGTCCTCGAAGGAACTCTTTATGTTGGATTTGTCACGTCCAATCAAGGCAATACTAATCGCCTTTTCACCAAAGTCCTCAATAAGGGTGATGTATTTGTGTTCCCAATAGGCCTAATTCATTTTCAACTAAACGTGGGATATGGCAATGCGGTTGCTATTGCTGGGCTTAGCAGTCAAAATGCAGGAGTTATCACAATTGCAAATGCTTTGTTTAAATCTAATCCAGCCATTTCTGATGAGGTTCTTACCAAAGCTTTCCAGGTGGATAAAAGCATAATTGATTATCTTCAAGGACAATCTTGGTATGACAACAACTAGTTCGAGAACATGATTAATCGTTTTATTATTATTAATAGATGATTCATCTCATCTTTAGTGTTACAATCACCTAGTGGAATCGACCTTCTCTACTTACTTATTTTTATTGTAATAAATAAAATAAATGTTGTTTTATTTAAACACATGGTTGTTTTAATTTTAGTTTAATTTGGTTCAATAATAGATTGTTGTTGCTGATATGTTCACCAATAAATAAAAAGATTGTTGTTGAGGTTTTTGTAATATAATAATTTTCTATCCCA
->KX055998.1 Phytophthora gonapodyides isolate H18 internal transcribed spacer 1, partial sequence; 5.8S ribosomal RNA gene, complete sequence; and internal transcribed spacer 2, partial sequence 
-ACGTGAACCGTATCAACCCCTATAATTTGGGGGCTTGCTCGGCGGCGTGCGTGCTGGCCTGTAATGGGTCGGCGTGCTGCTGCTGGGCGGGCTCTATCATGGGCGAGCGTTTGGGCTTCGGCTCGAGCTAGTAGCTATCAATTTTAAACCCTTTCTTAAATACTGAACATACTGTGGGGACGAAAGTCTCTGCTTTTAACTAGATAGCAACTTTCAGCAGTGGATGTCTAGGCTCGCACATCGATGAAGAACGCTGCGAACTGCGATACGTAATGCGAATTGCAGGATTCAGTGAGTCATCGAAATTTTGAACGCATATTGCACTTCCGGGTTAGTCCTGGGAGTATGCCTGTATCAGTGTCCGTACATCAACCTTGGTTTTCTTCCTTCCGTGTAGTCGGTGGAGGATATGCCAGACGTGAAGTGTCTTGCTGGCGGTCTTTCGAGTCTGCCGGTGAGTCCTTTGAAATGTACTGAACTGTACTCTCTCTTTGCGCGAAAAGCGTGGCGTTGCTGGTTGTGGAGGCTGCCTGTGTGGCCAGTCGGCGACCGGTTTGTTAGCTGTGACGTTTAATGGAGGAGTGTTCGATTCGCGGTATGGTTGGCTTCGGCTGAACAATCTGCTTATTGGGTGCTTTTCCTGTCATTGGCGGTACGAACTGGTGAACCGTAGCTGTGTGGTGCTTGGCTTTTGAACCGGCTTTGCTTTGCGAAGTAGTGTGACGGCTTCGGCTGTCGAGGGGTCGATCCATTTTGGGAAACTTTTGTGTGTGCGGCTTCGTGCTGCGCGC
->XM_008173413.3 PREDICTED: Chrysemys picta bellii NECAP endocytosis associated 1 (NECAP1), transcript variant X1, mRNA 
-CCCTTAACAAAAATGGCGGTCGGAAGCATCCCCGGTTACTAGGACCCCCCGCCCCTCCCGCTGGGGTCTCAGATCCGAGATGGCGGCGGCCGAGGCGGAGTACGAGTCCATCCTGTGTGTGAAGCCCGATGTCAGCGTCTACCGCATCCCGCCGCGGGCCTCCAACCGGGGATACAGGGCATCTGACTGGAAACTGGACCAGCCGGACTGGACAGGGCGTCTCCGTGTCACGTCAAAAGGCAAAATTGCATATATAAAGCTAGAGGATAAAGTTTCAGGAGAGCTCTTTGCTCAGGCTCCCATAGACCAGTTCCCTGGCCTTGCAGTGGAGACTGTGACAGATTCCAGCCGGTACTTTGTCCTCCGAATTCAGGATGGGAATGGGCGAAGCGCTTTCATTGGCATCGGCTTTTCAGATCGGGGTGACGCCTTTGACTTCAATGTCTCCCTGCAGGATCACTTCAAGTGGGTGAAACAGGAGACCGAAATCTCCAAGGAGTCACAGGAAACTGACACACGCCCCAAACTGGACCTAGGGTTCAAGGAAGGACAGACCATCAAACTAAACATTGGGAACATGCCAACAAAGAAAGGAGGGGCACCCAAACCCCGTGCAGCTGGATTGGGGGGGCTGAACCTGCTCCCACCCCCTCCAGGTGGCAAAATCACAGCCCCTCCAATCCCTCCCCCATCTTCAACAGCCATTTCCAACCATGTGACGCCGCCACCAGTGCTGAAATCCAGCAACATGGGCAATGCTGATATCCTGTTGGATTTGGACTCTCCTGCATCCATCTCTAAGGCACCAGCACTTGCTGCTGTTCCAGCCACCACAGACCTCTGGGGAGACTTCAGCACTGCATCCAGATGTGCTCCAGCCTGGAATAGACAGGAGGTGGTGGATCTCTTGGGCCTGTGGAGAGAAGTGGCTGTGCAGGAACAGCTCTGAACCAGCCATAGAAAT
->XM_029877336.1 PREDICTED: Aedes albopictus nuclear inhibitor of protein phosphatase 1 (LOC109424494), mRNA 
-CTTTTGCTCAGGTCAAGGAACACAAATCGCCCATTATGTGGTTAGTGCGTGAATTTCGTTCCAATTTACTTATTTTCCACCGTAAAAACTTCTAAAACTATCGTAATTAGTGTATTAAGTTGAGGATTCGTGTTTTCCTGATCTGGGACAACAACTCATTCTGAGCGTAATGTCCAACCACTACGACATACCCTCTTGGGCTGGTAAGCCGCCCACGGGGCTACATCTGGACGTGATGAAGGAAGACAAACTGGTTCAAAAGTTGATGATTGACGAAAAGAAATGTTATCTCTTCGGTCGGAATCCCCAGATGAACGACTTCTGCATCGATCATGCGTCCTGTTCCCGCGTACACGCCGCATTCGTTTATCACAAACACTTGAACATTGCCTACCTGGTGGATTTGGGCTCCACTCACGGGACGTACATCGGCTCGGTCCGGCTGGAAGCTCACAAACCCACCCAGTTGCAAATTAACTCGACGTTCCATTTCGGCGCTTCGACCAGGCACTATATGCTCCGGGAGAGACCCAATGTCCGATCCAACATTATGGAAGACATCCCGATGATGGACACCAGCGATGGAACCTATCTAGGCCTTCCCGAGAGCCAAACGGAACTTGATAACTTGACTGAATACAATACCGCTCATAACCGGAGGATTTCCATGCTTGGAATATCGGACGAAACCAGCACTTTCAAGAAGAATATGAAGAACAAAAGGAAAAGGAAAGGCGTCCAGTTCAATGAGGATGAAATCGTTATAAATCCCGAAGATATCGATCCAAGCATAGGACGCTTCCGTAATCTCGTATCGTCCACAGTTGTTCCAGTACAGGCGAAACGTGCAAAACTAGAAGTTCACTCAATGGGTCTCTCTACGTCGCCCTCATCCAGCAAAATCCTTCATCATCCGCACAGCTTGGTACCAAATTTGTATCATGGAATCGACGACCAAGCGCATGATCCACGAGGTCCGCCCGGCAATGGTTCCGGATTCGGGTTCGGCATGGACACCACACCCAGTGGACTCACCACTAAGCTGGGTATAATTTTGCCGAATCCAGCACCGGATGTGAATCCGGCCAGTTCCAGCACTGCTCTAATGCCTCCTCCTATCTACAGCAGCATGGCTCCCAAAAGTGTTAAAATTGTCGACAAACCGGACCTATCGGACGAACCCAAAAAGAAGAAATACGCCAAGGAACAGTGGCCCGGAAGGAAACCTCTGGGATTGGGAGGTTTCTAAGCGGTTACAATACAAATGTAACGTTACATTTATCTTATATTGGTGTGACTATTTGGTAAGTGAATAAGGTTTACCGAATTTAATCTAACATCATAATAATCGAAAGTTAA
->XM_053193968.1 Colletotrichum fioriniae uncharacterized protein (COL516b_007061), partial mRNA 
-ATGGGAAAGTCAAGACGAAACAGAGGCGGCCCAAGCCATCGCAAGGACCCCATCGCCAAAACCGTCAAGCCCCCCTCCGACCCAGAGCTCGCCGCCCTCAGGGAAAAGTCCATCCTGCCCGTCATCAAGGACCTGCAGAGCGCTGACCCCAAGTCGCGCACCGCCGCCGCCGAGGCCGTCTCCAACCTCGTCTCCAACGAAAAGTGCCGGAAGCTGTTGTTGCGTGAGCAGATTGTCCACATCGTCCTGAACGAGACCCTCACCGACGCCAGCCTCGACAGCCGCGCCGCTGGTTGGGACATCTTGCGCGTTCTCGCCGAGGAGGAGGAGGCCGACTTTTGCATTCACCTGTACCGTCAAGATGTTTTGAGCGCCATTGGTTTTGCTTCTCAGACTATTCTCCAAAACCTTGCAAAGGGCTCATCTCTGAGCAAGGGCGAGACAAAGGTCACCTGGACCATCACCGAGTCTGTCATTGGCCTTTTGTCTGCTCTTGCCGAAGCCCAGGATGAGGTTCTCGAGGCCATTGTGGGTATCGAGGGCATCAAGCACTTGCTCTTTACTGTCATCGCTCACCCCGACACACCATCAAGCATCTGCCTCGACGCCCTCTCAGCCCTCCTGACCCTGTCCGAAGACAACCAGCGCCTGGCGCAGGATGTCGTCGCCGACGAGAGCCCCAAGCCGCTCACGTCGTTGACCAAGCTGCAAGAGGTCGCTGGCGCAAAGGGCGTCCTAGCCTGTGGTATTCTGCATAACATATTCACCACCTTGCATTGGTTCGACAGCACGCCGGGCCCCAAGGACCTCTCTGACGCCTCTCTCATCCCAACTCTGTCATCGGCACTCAAGAACACCACGCCGGAAACTGATTTGCCACCCAGAAGCCAATGGTCTAACCCGACCGAGGTTCTTCAGCTTGCCCTGGAAATCCTCGCCGATGTTGGAACGACGCTGCAGCAGTCTCTCCAGGGAGGCGACAGCAAGAAGGCCAAGAAGGAGGAATGGAACGGAATCGAAGACGACGACACCGCCATGGACGAGGACGTCAAGGAGGACAACGGCTCCGGCGACGAGGACATTGGCGAGGGCGACGAGGAGGACGACAATGACGACGACTCCATGGACGAAGACGAGATGCAGGCCGACATGGACCTCGTCACCGGCGCCGACGACGACGTCGACGAGGAGGCGAGCATGGACGACCTGCCCACCCTGCGCGAGCTGGTCCAGCAGGCCATCCCGCAGCTCATCACCCTCGCGACGCCGTCATCACAAGCAGAGGGCGACAACGTCCGGGTACAAGCGCACGCCCTGGCCGCCCTCAGCAACATCGCCTGGTCCATCTCCGTCTTTGACTTCTCCGACGATCACAACGCCGGCATCCTCAAGGCCTGGGCCCCGTCCGGCAAGGCCGTCTGGGCCCAAGTCATCGCCCCTATCTTGGCCGCCAACACCGCCGACGTCGAGCTCGCCACAAAAGTCACCAGCCTCGCGTGGGCCGTGTCCCGCAGCTTGCCCCGCCGCCTACCCCTCAGCGGCGACGAGCACACCAAATTCATGGCGCTGTACCACGCGACCAAAAACCTTCCCTCAAAACAGGCGGCCGAGACGGCGGCCAACGGAGACAAGGCAAAGGACGAGGATCCCGAAGATCCTTTCCAGGGTCTCGGCGTAAAGTGCATCGGCGTCCTGGGCCAGCTGGCGCGGGACCCGGCACCCCTTGCGCTCAACAGGGAGATTGGTGTGTTCCTTATCGCGGTGGTGACTGCATTGCCAGAGACCCCGGCGGCGGATGCCGTCGAGGCCCTGAACCAGCTTTTTGACATTTACGGAGACGAAGACATGCCATGCGACAAGGAGGTCTTCTGGAAGGACAACTTCATCCAGCACCTCGAGGCGGTTCAGCCCAAGGTCAAGGCCTTGGTCAAGACGATTGATAAGCGAACTCTCCCCGAGTTGCGCACTCGTACTGAGGAGGCTGTGTTGAACCTTGGACGGTTCATTCAGTACAAGAAAAAGAACAAGGCATAA
->XM_046724795.1 PREDICTED: Haliotis rubra E3 ubiquitin-protein ligase parkin-like (LOC124288282), mRNA 
-AACAACAAATCGAGTGTCAAGCACGTGTTTCTTGTCATTATAGGAGGGGATTTTTTTGTTTGTCGTTATCGGATGTGGACTACACAAAACTGACGACACCAAAACAACCCAGGGTGCACGTTTCTCTGTCTTTAAGCAGATGACAAGTGTGCCAGGTTGTGCTTTCGATCGCATACCTGTGCTAACTACGATGCAGGAAGTTGTTTGACAGCCACACTTAGCCTTCAGGGAACATACGGCGCATTATATGCAGCGAATGAACATGGTGTAATCTTATCTACATAACTTGCATCATGATTACCGTGAATGTGAAATTTCACAGCAATTGTGCAGTTCTTGTTGAAATTAACCCCGACAGCAGCTTGCATGAAATCAAAAGAGAAATATCAAAGAAGGTCAATTTGCCACTGGAAGAAGTCAAGATTATATTTGGGGGGAAAATTGCTGACGGACGATTGTGTGTTTCAAGATTTGGATTTTGGTGATCAAAGCACTCTCCATATCTTCAGACAGATATCAGGGAGTGAAAAAACTCTGACATCAGAAGCAAGCGAGGAAAGAGAGCTCAAGAACCAGTACTATGTGTACTGTAAGGAATGTAGATCAATACAGCCAGGCAAGCTTAGGGTCAAATGTGCTACATGCCAGGATGGGGCCTTTGTTCTCAGCAGGGACCCCGAGGGCTGGAGCGATGTGTTGCAGTCAAGGAGCATGGGTGGGGAGTGTCGGAATGATGGCTGTGAAGGGACAACTGCGGAGTTTGTGTTCAAATGTGGCAAGTCCCACGCTGATGGCATATCAGCTGTCGTTCTACGACATGTCCGACCAAACAGACGGGAGGTTGAGTGCATTACCTGTGCAGATGTGAGATCTCCTGTGCTGGTGTTCCCCTGTGAGTCAGGACACGTGATGTGCATCGAATGCTTCAAAATATATGGAATCACCCAGTTGAGTGAACGCAGGTTCATTAAGCACCCAGAGCATGGGTACACCCTGCCTTGCCCAGCTGGCTGTCCCAGCTCGGAGATCCAGGAGAGCCACCATTTCCACCTACTGGGAGATGAGCAGTATGAACGGTTCAACACGTTCGCTACAGAAGAGTATGTACTACAAGATGGTGGCGTGCTGTGTCCAGGACCAGGATGTGGGATGGGCTTCGTCCTTGACACAGCGGGGAGGAAAGTCACCTGTGTTGCCAAGGACTGCATGATGACATTTTGTCGTGACTGCAAGAATGAGTACCATGACGGGCCTTGTGATGTCAACCCTCTCCTCACACTCTCACCTCTGGACTACTTGGTGGACCCACTCCAGGCTGACGGTCTCTGGGAGGACCAGTCTCGAACGCTGATAGACCGCACCACCAAGCCCTGTCCAAAGTGTGGCTCCAGGACTGAGAGAAACGGTGGTTGTATGCACATGCTGTGTCCACGGTGCGGGGAAGACTGGTGCTGGGTGTGCAACAAGGTGTGGGATCGGGACTGCCAAGGCCAGCACTGGTTTGGATAGTGTGCATATCCTTCCAGATAGTGATTACAATAATAATATACAGGATATACAATTCGGGAAGAAACCTCCTATATTTTCATACACTCTGAACCTCCACCATTCATATGTATAAATGATATTGATGTCATGTTGATATATGTGTGAAATATTCCAGAGACCTGCTGAAATGGTATTTGATGGCTATGTTGTATGTGATGTCAAGAGTGAGATGCTATGCTGTTGCCATTGGAAACTCACAAAACATGATATTCACGGCTAGATTTAAGCATTTAGAACTTGCACTGGTGCAGCCTGAAACTGCAAAATGCAACCTCATACTTATACCGGTACCAACTGGCACCCACTGCATGTTTTTATTTTTGCTGCTCAAAGAACACAGACTTCAGTTTGAAAACAGAATGGCAAGGAAATGACTTGGAGCAGTGACTCTGATGGCTGCATGGACAGTAAGACCATGACCGTTAGTGTTCATATGATGGAATTTTATTAAGTTAGATAAAGTGACCTCATCAGACTCTTACTAATTTTGTCTCAGCACCAGATGCAAACTGTTTTTGTCTGGTGCTACAAGGTTAATACCAGTTGGAAGTAGGTTTCCTGTTTTTAAATCAAGCCCTGATATCTGTTTCAGTTTCTACTATCAGCATGGTGATCTCACTCTGTACACAAAAATAGACAGTATTCTTCAGGAAGTTAACATGGGAAAGTATTTTTAGATGTCTTTTACATATAGAAATATATGGTAAGTGATGCTCAGGTTTATTCATGGGCCATGTTTCACAAAGCAATATTGGAGTTACGACCATCATAAGCAAATGTT
->KC455192.1 Uncultured eukaryote clone T2S303B03 18S ribosomal RNA gene, partial sequence 
-AAAGATTAAGCCATGTTTGTCTAATTATAAGCTTTTATACAGTGAAACTGCGAATGGCTCACTAAATCAGTTATGATCTACTTGACAAATTTACTACTGGATATCCGGGGTAATTCTAAAGCTAATCCAGTGCATTCAACCCCGGATGTTTTGATGGGAGCACTAGTTAGATCCATAGACCAAACCCCCAGGGCAACCTGGTATTGCTTAGTCATAACTATTAACCTTACCACCCGCAAGGCCGACGGTTCAATCAAATTTCTGCCCAATCATTGCCCTGTTGGTAGGAAAAAGGCCTACCATGGCTGCAACGGGTAACGGGGAATAAGGGTTCTTTTCCGGAAAGGGCCCCTGAAAAATGGCGACCCCATCCAAGGAAGGCAGCCGGGGCGCAAATTACCCAATCCCCACCCGGGGAGGTAGTGACAATAAAAAACAAAGCAGGGCCCTTTTGGGTCTTGTAATTGGAATGAGCTCAATTTAAACCCCTTAACAAGGAA
->XM_047242661.1 PREDICTED: Schistocerca piceifrons protein O-mannosyl-transferase TMTC2-like (LOC124712366), mRNA 
-CGGCGCCGCGAACGTCGGAGGCAGCAACGACGCGTCGCGACGCTTTCGACGCACGACACGTGGACACATCCTGCAAAAGCTGCTTCTGGTCGCCGCGGAACTGTCAGCGAGCTTCTCTTGTACAGTCGTCCGCCCCTGTGAGCGCGCCTGTCGCCCCGCTGCCCCTGGCGGGGTGTCTGCAGCCAACAAGTGTGGGAGCGAGAGGCAACAGGTAGTCTGCTGGTGTGACGCGGCCGCCCTTATCTGGATGGACGGCACGGCCGTGGCGTGCGCGCTGCTCGCCGCCGCCGCCTACTACAACACGCTGGACGCCGGCTTCGTCTACGACGACAGGCGGGCCATCCTCGGCAACCCGGACGTGACGGGCAACGAGACGTCGCTGTGGCGGCTGGCGACGTCGGACTTCTGGGGCACGCCGCTGCGGCTGGCCGGCTCGCACGGCTCGTGGCGGCCGCTGGCGGTGCTCAGCTTCCGCGCCAACCACCTGCTGGGCGGCGGCTGGCACGCCGCCAACGCCGCGCTGCACGCCCTCTGCGCCGCGCTGCTGGTGCGCGTCGCGCGCCGCCTCCGGGCCGCCCCCGGCGTCGCGGGGGCGGCGTTCGCGCTGCACCCGGCGCACTGCGAGGCCGTGGCCGGGCTGGTGGGCCGCGCCGACGTCGCCGCCGCCGCCTGCTCGCTGCTGGCGCTGCTCTGCTACGCGCGCCACGCCGACCTGCGCGACGCCGCCGACGCCCGCCGGCGGCGCTGCCGCGGCTGCGGGGGCCCCGTGCACCGCCAGCAGGGCTGCGCCCTCCGGAGGGCTCTCGCCGCCGCCAAGGGCCTCCTCGGCGCCGCTCTCTGCTCGGCGAGCGACCGCCTCTCTTGCCAAACCCGCAACTCCTCTCACCCCCCTGCCACCGGCACAGTCACGACGAACGGTACTGCTTATAAATCCGGCGCCTGGCTGGGACAAACTTCTAAGTCACCTCGAGCTGACATCGTCACTGAGTCCAATGACGCCAACAACAACACCAGTACGAACGCACTCGCGTGTCAACAGGCTCCGTCGAAAACATCCGTCGACTTCGATACACCGCCATCAATCTCGAAAGCGATCACGGCAGAAATCACTCGCATTAACGCCTCTCACACCACATGTTGCAAACAACCTCGCACTTCAACGCAACATTACAATGGAACTGTTCCTCTCGCCTCTTGGCCGTCGACCGAACGGACGGAAAATGAGGACGTTGCCGAAGGCAGTGATGCGACACGAGACGCTAATCACAACACTGAGTTCGTCAGTTCGTCGCAATTGTTTTCAATTAGCCAGTGGCGATACCAGAACGCTTTCGACCATCATCTTGAAGAAAAGGTTGTGAGACGCAGCCTCTTCAGAGCCAAAAGGGAGGCGTCCAGCAGGCTCGGAAGTAATGTGTTGAGGAGGAGGTGGAAGAAGTGTTTCAAGGACAAAAATTTAATCACAGACAGCGGTGAAGATCAGAAACGGCTTCTGAAGACAGCAGAGAGGAGCACCTGTTGCGCCGCGGAGGGCTGCAACAAGGAAGAGTCGCGCTCGTGTCGGAACAGCGCCAGCGGCGGGCCGCTGCTGCAGCTGGTGGCGTGCGTTCTTCTGAGCGCATGCGCGCTGCTCTTCAAGGAGACGGGCATCGCGGCGCTCGCAATCTGCGTCGCCTACGACGTGGCGCTGCTCGCAGAGAGGGGCGTCGCCGGGCCGCGGCAGCTGCTCGCCACTCGAGCGATCGAACGCCGCCGGCTGGCGCAACAGGTGTCGCCTGTGGAGAGCCAGAGGCGGCCTGCGGCCTGCCCCTCCAACCGAGCCAAGGGCAACCGCTGCTGCCTGCTCGGCGGATGCGCCGAAACGCACGCGTGCGCCGACAACAGCGTCAGTGGCCCCTGTGGCAGAGGTGCGCTGCTGGTGAGCCTGTCGCTGCTGGTGGTGCCGTTCCTGCCGGCCAGCAACGTGGCGCGCTACGTGGGCTTCGCGGCAGCGGAGCGCGTGCTCTACCTGCCCAGCGCCGGGCACTGCCTGCTGCTCGGCCTGGGCTGGCAGCGCCTCAACCGGAGGTCCCACCACCACCAGCACCAGCACCACCACCACCACCACCACTGGGCGTGGCTGTCAGGGTTTGCACTGGCTGCCACACTGGCCAGTCTTGGAGCACGGACCGTACTCCGCAACAGGGACTGGTACGACGAGGAGAGCCTCTTTCGCTCTGCGCTTCACATCAACCCACCCAAAGCGTACGGCAACCTGGGCTGCGTGCTGAGCTCTGCGGGCCGCCTGGAGGAGGCGGAGTGGGCGCTGAGGCAGGCGCTCAAGCACAGGCCCAACATGGCGGACGTCCACTACAACCTGGGCAACCTACTGCAGGCTAGAGGCCGCCCGGAGGAGGCAGAGCGCAGCTACCGGCTCGCCATCCACTACCGGCCCTCTCTCGCAGCGGCGTACGTGTCACTGGGGCAGCTGCTGGAGGCACGGGGTCGGCTGCGGGAGGCGTCGCAGGTGTACGAGGACGGCACACAGCTGGACGGCGAGCGGCTGCGGGACCCGGCGGCGCACCTGCAGGCCACCCTCAGGGCGCTGCTGAGACTGGCCCGGCTGCGGGCCCAGCAGGGCGACTGGCAGGCGGCGGCCGACAGCTGCAGGCAGGTGCTGCTCAGGCACCGCACTGCCCAGCTGCAGGGGCTGTTGACACAGGTAATGGCGCAGCAGGGTGCTGACCACTTAGTAAACAAGTGCTGTTCAGGCACCGTGCTGCCCAGCTGCAGGGACTGTTGA
->XM_020923618.1 PREDICTED: Boleophthalmus pectinirostris sodium bicarbonate transporter-like protein 11 (LOC110159053), mRNA 
-ATGAACAGCAAGAAGAACGCAGAAGAAACACCCACGGTCATCGTCACCAGATTCACTGAGGAACTCAAGGATGGGGAGAAGGAAGAAACAAACATTTATGAAATCCCAGTTAGTACTACAGCCACTGAAGGGCCCGGATTTGGACTTTTAAATACAACCAGAAAGTATGTGAAGCCAATGAACTTCCAGGAGGAGGTACGAGCTCATAGAGACCTGGACAGCTTTCTGGCCCAGGCTAGCATCGTCTTGGATGAGAAGGCTGCCACTCTGGACGAGGTGCTGAGGAGAATGTTGACGAATCTGGTTCAAGAGGGACATGGGAGCTGTGACACTGAAGAGGTCATGAACACACTGTTCACAGACGCAGGGGGACAGGACTGTGATGTGCACCTTCTAACAGAGACCATTCAAGGAGTAACGGCTAATTCTACTGGGGTTCACTATCAGCAATCATGGCTTTGTATACTCTCTACAGTGAGGACTCTGCAGCGGCGCCATGTCTGTGTCACTCGTTTAGAGCGACCTCAGAACTGGGGAGTGAACTGCTGCGAGGCGCGATATGTCATACTAATCCTCGCTCCTCCCAGAACGAAAAGCACCAAGACAGCCATTGAGCTCGGTAGAACGTTCGCGACAATGTTCTCGGACATCTCCTTCAGACAGAAGCTTTTGGAGGCCAGAACACAGGACGAGTTCAAACAGGAGCTGGTCCTCCAACGACAGCAACTCTCCATGGTGACAGAGAAGCCAGTGATCGAGGAAGTGGTGGACTCGGACCCCCGCAGGGCCAAAGATCTACAGTGCATGGACTTCTTCAAAGCCGGCAAAGGTGTTTATGAAGATCTCCGCCGCAGACTCCCACTCTACCCGTCAGACTTCACAGATGGAATTACTGGAAATGACCGCTCACTACTCAAGTACACCACCACAGCTATTTTCCTCTACATTGCTATTCTGCTCCCAAACATCGCATTTGGCTCTTTGAATGATGAAAGTACAAGAGGTGAAATTGATGTTCAGAAGACAATAGTTGGCCAGAGCATTGGTGGAGTTATATACGCGCTGTTTGCAGGCTCTCCTCTTGTCATCCCACTAACTACAGCTCCGCTTGCTATCTTCATTAGTGTGATCCGTGGCATCTGTGACGACTACAACCTGGACTTTGATGCCTTCTACGCCTGCATTGGTTTATGGAACAGTCTCTTCCTTATCCTCGGGGGCCTATTCAATGTCAGTCTGCTGATGAAGCTCTTCAAACGCTCCACAGAAGAAGTCATTGCTCTGTTCATCTCCATAGCATTTGTCGGCGACGCGGTGAAAGGCACAGTCAAAATTTTTGAACACTACTACTATGGACCTACCCTTGCTACCTCCAACAGTACAGTGGTGCTCCAGCAGATTAATGAGATTCTGGAGCGGGCAAACAACCACACCTCCACCAATGGCACTGGGTCAGAGACTGGACACTCAAACCTCCTCCTCCTGCCTGAGTCTCTTATCGTGTGCACCAGGGAGAGACCCATCCTATGTCTGCTGCTCATGCTCGGGACACTGTGGCTGGGATATGCTCTCTACCTCATCAAGAGAAGCCCATATCTGAATGCCAAAGTGCGGGAAGTGGTGTCGGACTGTGCTTTGCCCATATCAGTCGTCATTTTCTCATTCATTGGGTCCTACCTGTTTATCGATATTCAGCTTCCTCAGTTTAGCGTCCACAATGGTCCAGTTTTCAACTTCCCTCCCTTTGACAGGCTGAGTGGCATGACAACATTAAGTGCAGTAGGGCTTGGGTTCTTACTCGCTCTGCTCATCTTCATCGATCAGAACATCGTCATCTCACTCACACATGTACCTGAACACAAGCTGCTAAAGGGCACCACATTCCACTGGGACTTAGTGCTGACCGGCCTCATCAACATCCTCATGTCCTGTCTGGGGTTGCCATGGATGCACGCCGCTTTCCCACACTCGTCTCTGCACGCCCGTCAGCTGGCCAAAATGGAGCAGCATGTGGAGAACGGACATGTCTACTCTACCATCGTAAGTGTGAAGGAGACTCGGCTAACGGCGCTGGTAGCAAACATCCTGATCGGCGTGTCTGCCTTCATGCTGCCCGTTCCCCTGCAGTGGATCCCCAAGCCTGTGCTCTACGGCCTCTTCCTCTACATCGCTGCCACTTCTCTTGATGGGAACCAGATGGTGGACCGCATGGCTCTACTGCTGAAGGAGCAGACGTCGTACCCTCCCACTCACTACATCCGCCGTGTCCCCCAGAGGAAAGTGCACTATTTCACCGGGGTGCAGATGGTTCAGCTCGTGATCCTGTGCGCGTTTGGCATGTACCCTTTGCCCTATATGAAGATGGTATTTCCTCTCCTCATGATCCTGCTCGTTCCTGTCAGGACAAGTCTCCTTCCGAAATTAATTGACGCCAAATATCTGGATATCATGGACGCCCAGCACATGTAG
->XR_545375.1 PREDICTED: Equus przewalskii uncharacterized LOC103553015 (LOC103553015), ncRNA 
-CGTCTACACAAAGACTTGCACACGAATGTTCACAGCAGCACTATTTGTAATAGCCCAGAGTGGAGACCACTCAAATGTCCCTCAGCTAGTGAACGGATAAGCAGGGTGTGGCCCTTCCACACAATGGAATGTTTTTCAGCCATAAGAAGGAATGAAGTACTGACACAGGCTGCAACGTGGAGGACCCTTGAACACATTCTGCCAAGTGAAAGAAGCTGGCCACAAAGGACCACATGTTGTGTGATTCCTTATATGAAATGTCCAGAACAGGCAAATCCATAGAAATGGAAAGTAGATGAGTGGCTGCCTAGAGCTTGGGTAGGGAAAT
->XR_002766617.1 PREDICTED: Eurytemora affinis uncharacterized LOC111708265 (LOC111708265), ncRNA 
-CTGGTGAATTATAGCTGAAATTGTGATAAAGTTACGCATCTATTTTGTATCAAAAATAGCCGATAATTGTTTGTGAAAATTTTCAGATGTCGTCAAATATTTTTTCTGAGGTACTATGGAATGGAATTTTAGGCGATGAAGAAGAGAGGGGACCCGAAATGTCCAATATTATAAACGGTCTGTCAGTGCCAATCAAAGCTCCAACATGTATAATACAGAGCTGCAATCCAAGAGTATGAGGATCACGGTTTAGATTTCCAGCAAGAAAAAAATTGTGGCTGAAGGCCCTTCATTTAAATCAAGAGTATATCACAGTAAAAGATCCAAGAGTATGTGAAAAACATTTCAAACCCTCTGATTTTAAAAGTAATTTATAGTATAATAAATATTACGACGTTAA
->XR_006947954.1 PREDICTED: Xenia sp. Carnegie-2017 uncharacterized LOC124444429 (LOC124444429), transcript variant X1, misc_RNA 
-GCTTAATTTTAAAATCAAAGTACTTTCAGAAAAACGCTATTGGTTTTGAATTTGTAAAGATCATAATTTTACCAATTAACTTGTCTCTTAATTGCTTAGAAATTTAAATATATTCCAAATTGCGCTGCGGTAATTAATTTTGAGGCACCTCAGATCCTCCAAGGGTTTACTACATACAATTTGGGACATCTTTTCGTAGGTTGCCACCGGCGGGCAGTGACGCATTTGACTTTATCACTCAATCGTTTTAGCTGTTTGAAAAGTACTTGACTCCTTTGAGAAAAAAAGTTCACATCACGTTGGGTAAAGATAGTCATCTTGGCCGTTATGAAACAGGAAGGTGGTGGGGAACTTTGATTGTTGCTCTCGTCGTTCTGTTCACGTCAATGGCAACGATGACAAGTGTCGCAGTAAAGCAAACGCAAAATTTGTTTCGTCGACGACCTATTGTGGAAAAATTGACAAAATGGTATTCGTCGTTGTCTCGGAAACTTTTTTTAAGTTCAGTGATCGCACAACTGCTTATCATCGTCATTCTCAACGCATGCGCAGGAATAACATTCCTCCTGGCATCCAACATGTCTCTTGTGTGTGACGTCACCTCTCATCATGAAAATATTGACAGGATCTTCGATATTTCAAGTGTGTTACCAAAGTCTACAATGCTTCCCAGGACAAAATCAATACAATTATTCAAGAAACTTAGCGAATGTCCCGAGAACGGCACTCTCTGGACGATGTTGGATCTGGATGATAAAGTGGACATCAATTCTGGTATTAGTCAATTACGTAAACTTCCACATTTTGCTGAGCGTCTGTTTCTCGTCGGTGACACATTCCATGATTTCCAAGCCGATAAAAAATATGCAAGACTTTTTTTGAAATGGAAACGGTTCATGTTGGAAAGCCTCGAGATTGATTCTATGGTGAATGAGACTATAGAATCGTTCAAAACGTACCGAAAGAAGGCTGTTAAAAATGGGAATGCAATCCGGAACGTTCATATTGAAATTTTTCCCATATTGTTGAAGCGACTTCGGCAAGATTTCAAGAGATTCCAAGAATCCAGAGCTCAAATTTCCAAAAGCATTAAAGAAATAAAAGACACTTATTTTGATATTACTTCAAATACTTCAAAAAAGGTCGGTCTTCAGGCTTCCAACGGTCTCGCCGTCCAAACTATCGAATCACTGAAGTCGTTTATCAACGAGGGTGTTTTCAAGATCAGAAGTCACGTGGGAAAATGTTTGCCAATGAAAAAAGCCTATTACAACATCACGTGTCTGTTATGCCATGACATCTTCCGATCTTGGAATCGCTATTTTCTGTTGTTTTTTGCCTGCGCCTTCCTTACGACAATCTCCATCATCGTTTCCATGGTTACTGTGATCTGAATAATCGTGTTTTATCGCTGGAAAGTTCGCGTAGACTGGTAACGAATTAGGACTGAGCTCTGAAATTCGCTTTGGAGATCGAGAACGAGACGAGGGAAAGACAGCTCCTGCTCAATTCCCGAGATGATTTG
->MW805831.1 Corticium thailandicum isolate MG242 TYPE large subunit ribosomal RNA gene, partial sequence 
-TCTAGCATATCAATAAGCGGAGGAAAAGAAACTAACAAGGATTCCCCTAGTAACTGCGAGTGAAGCGGGAAAAGCTCAAATTTAAAATCTGGCGTCCTTAGGGCGTCCGAGTTGTAGTCTGGAGAAGCGTCTTCCGCGCTGGACCATGCATAAATCTCTTGGAACAGAGTATCATAGTGGGTGAGAATCCCGTCTTTGGCATGGACTACCAGTGCTTTGTGATGCGCTCTCAAAGAGTCGCGTTGTTTGGGAATGCAGCGCAAAATGGGTGGTAAATTCCATCTAAAGCTAAATATTGGCGAGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGATGAAAAGCACTTTGGAAAGAGAGTTAAACAGTACGTGAAATTGTTGAAAGGGAAACGCTTGAAGTCAGTCGCGTCGTTCGGGACTCAGCCTTGCTTCTGCTTGGTGTATTTCCTGTACGACGGGCCAGCATCGATTTTGATCGTTGGAAAAAGTTCAGGGGAAGGTGGCACCTCCGGGTGTGTTATAGCCCCTGTTCGCATGCAACGGTTGGGATCGAGGTTCGCAGCACGCCTTTATGGCCGGGGTTCGCCCACGTACGTGCTTAGGATGCTGGCGTAATGGCTTTAAACGACCCGTCTTGAAACACGGACCAAGGAGTCTAACATGCCTGCGAGTGTTTGGGTGTAAAACCCATCCGCGTAATGAAAGTGAAAGTTGAGATCTCTGTCATGGAGAGCATCGACGCCCGGTCTTGAGCTTTGGCGACGGATCTGAGGTTGAGCATGTATGTTGGGACCCGAAAGATGGTGAACTATGCCTGAATAGGGTGAAGCCAGAGGAAACTCTGGTGGAGGCTCGTAGCGATTCTGACGTGCAAATCGATCGTCAAATTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCTGCCGA
->XR_004926052.1 PREDICTED: Halichoerus grypus uncharacterized LOC118553476 (LOC118553476), ncRNA 
-GCCCAGACAGAAGAGGCAGGCGCGTGTAACACAGAGCCTGGCCCTGGCCTGTCACGGCCTTCCTGTCTCTGCAGCTGGGCTGGGGCAGAAGCCGAAGTGAACTCGGGCCTGCAGACAGAGGCTTACCGCCAAGGTTTTCCAGAAGAGGGAAGTCCACTCTTTCAAAGACACAGCTGGAGTCAGACGGGGCAGGACAGCCCCTCTGAGGCTGACCCCTGCACAGTGTCCCTTCCTGACTCAGGAAAGGTCTACTCCTGCGCTGTCCCAACATGCCGGCCGCCAGCCACGCGGGGCTCCTGGGCACTTGAAATGCGGCTGGCGTGACCCTAGGTGTGCTACAAAGTACCAGTACACCCCAGGTTTTGAAGACTTGGTATGGAAAAAAAAAAGTAAAATATCTGTAATAATTTTCTGTATCGACTGCATGTTGAAATGACAGTACTTGGAGTAA
->XM_028734882.1 PREDICTED: Podarcis muralis zinc finger protein 341 (ZNF341), transcript variant X4, mRNA 
-ACATTAGTCCAGGGGAATATCTTAGTGAGTGATGAGGTCTTGATGTCAGCTATGTCTGCTTTTACAACCCTGGACCAACCAATGTCCACAGTACAACCCTCTGTGCAGCCTGAATATGCATACTGGAGCTGGCTACCTTTCTCAACCACCACCTCCTCCTCCTCCTCCACCACCACCACCTCAGCCTCCTCCTCCCACACCTCAGTCTCTTGGAGCACCAGGTCAGGCCAACTCAGGCAGCAATGGAGTGGTGGAAGTGTACAGTGCATCAACCCCCATGACTGGGAATAGCACAGTAGAGATACAGAATCTGGGGATGCAACCCTACCCACCTATGGAGGTGCCCAATCAATGTGTGGAAACCCCAGTGTACCCCTCCCCTCCAGTATACAGTCCAGGGAAGCAAGGTTTTAAGTCTAAAAGCCCCAACACTGTTTCTCCCTTGAACAATGCCTGCGGAGGAAATGTGACCAGTTTTGATCCGGCTTCAGCTGCCAAGAACCGTCGTCTTAAGACAGACAGCAGCCTGCTAGAAGGGAAACCCAAGTCACCAAAACTGAAATGCACATACTGCGATAAGGCATTCACCAAGAACTTTGACCTGCAGCAGCATATCAGAAGTCACACAGGGGAGAAGCCATTCCAGTGCATCGTATGTGGTCGTGCCTTCGCCCAAAAGTCCAACGTGAAAAAGCATATGCAGACGCATAAGGTGTGGCCACCAGGAATTGGGTGTACCATCTCTCGGAGCTCTGTCACTGTGCAAGTCATGGCACTCAACCCCAACCAGCAGGAGGAGGAGAATGCAGGTTTGAACACGGTTCCCAGAAGCAGCCCCCCACCGCCACAGGTCATGCCTCCTGCAGAAGAGCATGAGGCTTGCAAACTGGAAGCTAAGCAAGTGGTCTTGATAGACAGTTCTTACCAGTGCCAGTTCTGCCCCAACAAATTCTGCACATATTTCCAGTTGAAATCGCACATGACCCAACACAAACATGAACAGGTTTACAAGTGTGTTGTGAAAAGTTGTGCTCAAACATTCCAGAAGCTGGATTCCTTCTTGGAGCACATCAAGAACCATCAGGAGGAGCTGAGCTACCGTTGCCACCTTTGCAGCAAGGACTTCCCCTCCCTCTATGAACTGGGTGTCCATCAGTATTCCCACAGCTTGCTCCCTCAACACAGTCCCAAGAAGGACATTGCCATTTACAAGTGTGTCAAGTGTGTAAATAAATATTCTACCCCAGAAGCCCTGGAGCATCACTTACAGACAGCAACACACAACTTTCCCTGTCCTCACTGTCAGAAGGTGTTCCCTTGTGAGAGGTACTTACGGCGACATCTACCTACACATGGGGGTGGAGGGAAATTCAAATGTCAGATCTGCAAAAAATTCTTCCGCCGAGAACACTACCTCAAACTACACGCTCACATTCACTCGGGTGAAAAACCTTTTAAATGCTCTGTGTGTGACTCAGCCTTCAACAGGAAAGATAAACTCAAACGGCATATGTTGATCCATGAGCCTTTCAAGAAATATAAATGCCCCTTCTCAAATCATACAGGCTGCAATAAAGAGTTCAACAGACCGGACAAATTGAAAGCTCATATTCTCTCCCATTCAGGGATGAAGATCCACAAGTGCCAATACTGCAGCAAGGCCTTCAGCCGGCGAGCTCACATGGTGGAACACCAGCGCTCTCACACTGGAAACTATAAGTACCGCTGCCCTACATGCAGCAAAGGCTTTACACGCCAGAAGTACATGAAGGACCACAAGTGTAGACTGAGTTCAGCCAAGGACAAAGAGCTGCCAGTGAGAAAATCCCAGAAGAAGTGGGGGACTCGTGGCCGGAAAGTGGGGCTTCCTGTTTCAGCTCAGTTGACCTTGACAGAACTGAAAGACAGTACAGATGGAGGAAACCCTCAGAAAGGTGGTCCCAATAAAGAACAGTTTCCAGTGTCTGACACAGTCCTGTCCATTGTGGTTGGCAGATCAACGGCCGTGTCGGCAACAGACTCTGATCTTGGCAACCCTACCCAATGCAGTGGCATTCCATCCAACCTTGCTCTGGCCGAGTTGCAGCCTGGCTCGGAGAGTCCATGCGCCATGCTAGCAGTTCCTGTATACATTCAGGCTACTGAATAACTGAATAGTACTGTGACTTAATGGGGGAAATAATTCCTCTGCTGTTTGATGGAGATACGCTGCTGCAGGGGATTGGAAATGAATGAAATGTGTATGTGTACTGTATGTGTGAGTGTATGTTTCAGCTGCCGTGATGCAGTGATCAGCATTCATAAAGAATTTTGTTGATAAAA
->XM_046012474.1 PREDICTED: Meles meles microfibril associated protein 5 (MFAP5), transcript variant X3, mRNA 
-CAGCCCCCTTCTCATTCCCGCCTCATCACACTCCTCTAGCCTGGCTTTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCCCTCGCTCTCCCTCATCTCATTGTTTCAGAGTAGGCCGAATTTGAAGTCCTTCCCAGGGAGTGGCCCTGTTCATCTTATTCGCCAGCCAAAGTAGAAACAGTGTGAGAAGGAGAGAGGCCCATTCGGCAGCCAAAGGACTCGGTGGAAAAGAGCAGAGGAAAAATACACAATATGCTGCTCGTGGGACCCAAGGTGCTGCTGTTCCTCACCGCCCTCATCATCCCCTCTGATGATGTGACTCCAGTGACTCCAGAGACATTCACAGAAGATCCTAATCTGGTGAATGAGCCTTCTACAGATGAAACAGTTCTGGCTGATATGGAGCCTTCCACAGATGACCTGGCTTCTCCTGCTGATAAAAATACCACAACAGACTGCCGGGATGAAAAATTTGCTTGCACGAGACTCTACTCTGTGCATCGGCCAGTCAAGCAATGCATTCATCAGTTATGTTTCACAAGTTTACGACGTATGTACATCATCAACAATGAGATCTGCTCTCGTCTTGTCTGTAAAGAACACGAAGTTATGAAAGACGAACTTTGCCGTCAGATGGCTGGTTTACCCCCAAGACGACTCCGTCGCTCCCACTACTTCCGACTTCCACCCTGTGAAAATGTGAATTTGCAGAGACCCAGCGGTCTGTGATCACCAAGGAAGAGGAAAGAATAATGTGTGGGTGGGAGGAAGAGAATGCTCTAACAAGAGGGAACTCCTTCTTGTCCAACCATTGTCCACTAACCCATAGACATTAGGATTTCTTAAACCAATCCCTTTGCAGCGCCTAACTTTTGCCTCCATTCCCTGACTGATAACAAAGTCTATATTATTGCATGGTTTTGCTGTTTCTCAGTATCATAGATGTAGATTAATGATAACCATGTGGCTTATATACAAACATCCTACACACAATTTCAAAGGAAAATAAACTTTAGGTTAATATTTA
->XM_052001689.1 PREDICTED: Antechinus flavipes supervillin (LOC127564871), transcript variant X20, mRNA 
-CTTCCCATCCTATTCGTCTTCCCTTTTGTCATGATTTTTCCTTTTTTCTGTTTCCTTTCTATCTTCTTTATTTTTCTCTTCCTGATTTTCCCTCTCCCTTTTTGTGTTTTTTCTTTCCTTATCTCTTCTCTTACCTTTATTCATCTTCTGAAACCAAAATCAAGATCTCTACTCATGAATATCTATTTCAACAAGAAAAGATCAGACCTTTTCCAGCTACCACATCAAAGAAGAATATCAAGCTTTCAGAGAGAATTTTCACTTGAAGAAAAGGAACAACTTGTCAACAATAGAAAGGATATCGATGCTAATCTTTTAACTGTACTTCCCAAAGTTGCAGAACTAAGAAAACTCTTTGAGCCAAAGAGAAAAGAAGTTTTAGAAATGAAGAGAAAAGAACGGATTGCCAGACGCTTGGAAGGCATTGAAAATGATTCGCAGCCCATACTCTTGCAGAGCTGTACAGGATTAGTTACCCACCGATTACTAGAAGAAGATACTCCCCGATATACGCGAGCTACAGACCCTTATAGCCCCCATATTGGTCGATCCAATGAAGAGGAGGAAACTTCAGATTCTTCTGTAGAGAAGCAACCTCGATCCCGATATTGCATAGAAACTACCACCCTCAATACAGAGTCATCCTACAGCCCAGTGACGATGGACACCCAGGGACTGGACTCCAAAGCTGAGAGAATAGCCAGATATAAGGCTGAAAGAAGGAGACAGCTTGCTGAAAAATATGGGCTGACTCTGGATTCCGATGCAGACTCTGAATATATGTCGCGTTATACTAAGACCAGGAAGGATCATGATGTCGAGAGGAGGGGAGGTAAAAGTGAGAAGCAGGAGGAGGAGAGCAAAGACTTGACTTATCATTATTCTAGGACTGAGACTGTGGAGCCCAGGAGCACCACAGCTGAATCCAAGGACTATAGCTTTCATGGGAGTGATGGTGTTATTGATAAGGAGGCGCTGTTGAATGTGGAAAACCACAGAAGAGCCCAAGAATTGAGTGCAATTGGCCAGATCCGTGACTTGCCACCTGCAGCTGATGGTTCCCCCTCCTTTTCCTTTTCTGGACGAGAATCCTCATTCAGTGACGTGCCAAGGTCTCCCAAGCAGACCCGCAGAGTATCCCTTTCTTCACCTAAGCAGCCAGCATCACCAAGTCATTCACTTACTGACTCATCATTACACGGTGATTCCAGAACGAGATCCACTTCAAATTCAGAAATGCCAACTGCTGAGGATGAAGAAAAATTGGATGAACGCGCCAAGCTGAGTGTTGCTGCCAAAAGGCTCCTTTTCAGGGAAATGGAAAAATCATTTGATGAAAAAAATATTCCAAAGCCACGTTCCAGAAATGCAGCCGTGGAGCGACGCCTTCGCCGTTTGCAGGACAGATCTCACACACAGCCCATCACCACTGAGGAAGTGGTCATTGCAGCAACTTTGCAGGCATCGGCACACCAAAAGGCACTAGCTAGAGAACAGGCAAATGAGGCCAAAGATTCTGCTGAACAAGGTGAACCTGATTCCTCCACTCTGAGCTTAGCAGAGAAGCTGGCCTTGTTTAACAAATTGTCCCAGCCAGTCTCAAAAGCGATTTCTACCCGAAACAGAGTGGATGCTAGGCAGAGGAGGATGAATTCTCGTTACCAAACTCAACCAGTCACCCTTGGAGAAGTGGAACAGGTTCAGAGTGGAAAACTCACTCCTTTCTCTCTTACTATTAACACATCTGTGTCTACTGTGGCATCGACAGTTGCTCCAATGTATGCAGGGGATCTACGGACAAAGCCATCGGTGGAAGAAAATGCAGGTGCTGCCGACTTTGGATTCCATTCACCAATGGAAAATGCAGACTGTTCAGTGAAGAGCATCCTAAAGCCACAAGGGTGGCAACCTTTGGGGGAAGATATCAGAAGCAAGCGAGGATCGAGGGAATTTGGGGAGATGGAAACTGAGAGAATCTTAGCTCAAGAGGAGAGGGAAGTGAGAAAGAACAGGTCCTTTGAGGAAGAAGGGAGTTCCTCCCTTTTCCTAAATAAAACTGGGGAAAGGGACAACCAAAGAAAATATACTCCAAGAAAAGGCAGCATGGAACATGCTGACCTCCTAGTGCCATGTCATGAAGAAATACGGGAGTTTTCAGTCACCAAAAGCACTGGACAGAGCAAACAGGACCTGAAGGAAGTGCAAACCTTGGAGGAAAAGATGGATTTGGAGAATGTTGCAAAAAGCAGGTTCATGCTACGAGAGCCTGCTGAGCCCACGTCCGAACTTCCTGGCACGATAGCTACAAAAACTGTTTCTCAGACCACATCCCTGGTCTCCAGTAGACGAGAGTCTTCAGAGCAGTCGGAGGAAAGACTTTCCAAGAATCCATGTAGGATGTTTGCTGGTGGAGAGAGCAAAATATCAGAGGATGCCCTTGATGCATCTAGCAAAACCATGTCCATCAAAGAAAGGTTGGCACTATTGAAAAAGAGTGGAGAAGAAGACTGGAAAACCCGGATTAGCAAAAAGCAAGACTACAGCAAAGTGTGCGTCACTGAACGAAGCACGAGGCTGCAAGAGGCTGAGCAGTCCTTCAAGAAGAAGGAAGAAGGAGGATTTACAGATGATAATGCCATTTCTAATCTGCTTTGGGAACCTGTATACGCTTCTACTTATTTTCCTGCTATGCCTGCTGTCCATAAATACCAGTCTTTTGTACCCATTAATCAGCAGAGGATGGCAGAAAGTCATGAAAGCCAAATGACAATTGAAGAGAGGAAACATCTTATTACTGTAAGAGAAGAAGCCTGGAAGACCAGAGGAAAAGGAGCAGCCAATGATTCCACCCAATTTACCGTTGCTGGCAGGATGGTAAAGAAAGGTTTAGCATCACCTACTGCCATAACTCCAGTAAGCTCCCCCTTTAGCAATCGAATGAAGGGCACTACACCGATCTCCAAACCCCTTGAAGATATAGAAGCCAAACCCGATATGCAGTTAGAGTCGGATCTGAAGCTAGATAGGTTAGAATCATTTCTGGGGAGACTGAATAACAAAGTCGGTGGTATGCAAGAAACCATTCTCACTGTTACTGGAAAAACTGTGAAAGAGGTGATGAAACTGGATGACTATGAGACCTTTTCCAAATTTTACCGCAGCGTGGATTCTGTGCCTCTAGGAAGAGTAGAGTTGGATGAGGATTTTGATGCAATTTTTGATCCTTATGCTCCCAAGCTGACATCTTCTGTGGCAGAGCACAAACGTGCTGTTAGACCTATGCGCAGGGTTCAATCTTCAAGAAATCCCTTGAAAATGCTGGCAGCAAGAGAAGATATTCTTCAAGAATATACTGAACAGAGATTAAATGTTGCTTTCATGGAGTCAAAACGGATGAAAGTTGAAAAAATGTCTGCCAACTCAAATTTCTCAGAAGTCGCCCTCGCCGGTTTAGCTAGTAAAGAAAATTTCAGCAGCGTCAATCTACGGAGTGTCAACCTAACAGAACAAAACTCCAACAATAGTGCTGTGCCCTACAAGAAACTTATGTTGCTACAAATTAAAGGAAGAAGAAATGTGCAGACAAGATTAGTGGAGCCACGAGCTTCATCGTTGAATGGCGGCGATTGCTTTCTCCTGTTAACTCCCCATTACTGCTTCTTGTGGGTAGGAGAATTTGCAAATGTCATCGAGAAAGCTAAGGCATCAGAGCTTGCAACTCTAATTCAGACGAGGAGAGAACTCGGCTGTAGAGCTACTTATATTCAGACCATAGAAGAAGGAATAAATACGCATACCCATGCAGCAAAAGACTTCTGGAAACTCCTGGGTGGCCAGACAAGTTACCAGTCTGCCGGAAATCCAGAAGAAGATGAATTGTATGAAACTGCCATCACAGAAACTAATTGTGTTTATCGCTTAGTGGAAGATAAACTTGTTCCTGATGACTACTACTGGGGCAAAATACCAAAATGTTCTCTTCTGCAGCCAAAAGAGGTCTTAGTGTTTGATTTTGGCAGTGAAGTTTATGTATGGCATGGAAAGGAAGTCACATTAGCACAGAGAAAAATAGCATTCCAATTGGCAAAACACTTGTGGAATGGAACCTTCGACTATGCCAATTGTGACATAAATCCTTTAGATCCTGGAGAGTGCAATCCTCGTATACCCAGAAAAGGACAGGGGCGACCTGATTGGGCAATATTTGGGAGACTTACTGAGCACAATGAGACTATTCTCTTCAAAGAAAAATTTCTTGATTGGACTGAAATGAAGAAGCCTTGTGAAAAGAACTCAAGTGAACTCACCCCACAGAAGGAAGAGCCAAGGTCTGAGGTTAAGGCTTACGATATCATGCTGATGGTCCCCGTGCCCCAAGTGACCGTCGGCACCATCTTGGATGGAGTCAACGTCGGCCGTGGCTACGGGTTTATCGAAGGAGATGACAGGAGGCAGTTCGAGATTGCCAGTGTTTCTGTGGACGTCTGGCACATCTTGGAATTTGACTACAGTAGGCTCCCCAAACAGAGCATCGGGCAGTTCCACGAGGGAGATACGTATGTGGTGAAATGGAAGTACATGGTGAGCACTGCAGTTGGGAGTCGGCAGAAAGGCGAGCACCCGGTCAGGACGGCCGGCAAGGAGAAGTGCGTCTACTTTTTCTGGCAGGGCAGACATTCGACCGTGAGTGAGAAAGGCACGTCGGCGCTGATGACTGTGGAATTAGACGAGGAGAGGGGGGCCCAGGTTCAAGTGCTTCAGGGAAAGGAGCCACCATGTTTTCTGCAGTGCTTTCAAGGAGGAATGGTTGTACACGCAGGGAAGCGAGAAGAAGAAGAAGAAAATGCACAAAATGACTGGAGATTGTACTGTGTCCGAGGAGAAGTTCCCATTGAAGGAAATTTGCTTGAAGTTGCCTGTCACTGTAGCAGCCTGAGATCCAGGACTTCCATGATTGTTCTTAGTGTCAATAAAGCACTCATGTACCTTTGGCATGGGTGCAAAGCACAGGCCCATACAAAGGATGTTGGGAGAACTGCTGCAAATAAAATCAAAGAACAATGTCCCTTGGAAGCAGGATTGCACAGTAGCAGCAAAGTGACGATCCATGAGTGTGATGAAGGGTCAGAGCCACTGGGATTCTGGGATGCGTTAGGAAGGAAAGATCGGAAGGCCTACGACTGCATGCTACAAGATCCTGGGAAGTTTAATTTCACGCCCCGCCTGTTCATCCTCAGTAGTTCATCTGGAGATTTCTCAGCCACGGAATTCATGTATCCTGCCCGTGATCCTTCTGTGGTCAATTCCATGCCCTTCTTACAGGAAGACCTGTACAGTGCCCCTCAGCCAGCACTTTTCCTCGTCGACAACCACCATGAAGTGTATCTCTGGCAAGGGTGGTGGCCAATTGAGAACAAGATAACGGGGTCTGCCAGGATTCGCTGGGCCAACGACCGAAAGTGTGCCATGGAGACGGTGCTTCGGTACTGCAAAGGAAAAAATGTTAAGAAACCCCCCAAGTCCTACCTTCTTCATGCTGGGTTAGAACCTCTGACCTTCACCAATATGTTTCCAAGTTGGGAACATAGAGAAGACATTGCTGAAATCACAGAAATGGATGCAGAAGTTTCTAATCAAATAATTCTTGTGGAAGACGTGTTAGCCAAGCTTTGTAAAACCGTTTATCCGTTGGCTGATCTCTTAGCCAGGCCCCTCCCTGAAGGAGTGGATCCTCTGAAGCTTGAAATCTACCTTACTGATGAAGACTTTGAAATTGCACTAGAGATGACCAGAGAAGAATATAGCATGCTGCCATCTTGGAAACAGGTGAACCTGAAGAAAGCGAAAGGGCTCTTCTAAGCATCGATGCTGCCAGTGGAAGATGAGGCTGGAGAAATCTCTGTGGTCACTTTCAATACCGTTGGGCCAGGAAGATTGACATCTATGTGTCCTGGTCTTCAAATTGTTTAAAAGTCAAAGTAGAAATGATTTGAAGTTATTAGATACTGCCTGAGCTGGAGTTGTGTAATTTTGTAAATGTGTAAGAGAACTCTCTGAAAACTTTCTCCTCCCCGACTCAGAGGGTATTTCCTGTTTGTAAACTTGGCTCTCCCGTGCACTTAAAGCAGTAGCACCTCACAGCTGCTGCTCAGCCCTCCTGGCTCCATCCAGCCTTCGCCTATTCATTTTTGAAGATGCTCTCTTTGTAAAGTGTTATTTTGTTAGCTTGTGGATTATTAAAAAAAATTATATTTATATAAACACCATATAGTTCAAGTATGTATTTAACAAAACAAAATATGTATTCACTTAAAAAAAAATTTTTTTTTGGTGTCAAAACAATACCGAGAAGTAGATGGAGTTGCTTCTACTGAATTATCTATTCCACAGTCTATGTATCTTATACACGTTCTGAAACGTTTCCTTTGGCAGTGGGCAAGGGGCTATTCTAAGGAGTACCACCGGTGCTTAAAGGAACAAAACTTTTATACTTAGGGCTGGAGACTCTGGAGAAACTCTGTGACCTTCATACCTTAATATCCAAAAACAAACAAAAACATGTATAGTGCCTTGTTTTGTGTACAGTTTATATACAAAAAAGTTTGGGTCTGCGTTTTTGAAGATGGTTTGGAACAGTATCAACAATTTTACTTTACAATGATCGAGGTTTAAAAAAAAAAAAAAACATCTCAGTTTATAATACTTGTAAACACATCTTTTTGTGATATAAGATTCCAAAGTACGAGCTTCAGAATAAAACTTTGGCAATGA
->XR_003381398.1 PREDICTED: Zonotrichia albicollis uncharacterized LOC113459830 (LOC113459830), ncRNA 
-TACTATGATGATGAAGATGCTCTAAAAATATACAGAATCTAATCTAGTTTAGATTTGACTGAAATAAACATGGACAAGGATATGTTGGGAGATGATCCTTTTACTTGGAACTTTCACCTTAGTGTGGGACTGTGCAGATTGATCTGGAGGATTTCTATTTTGGATGCCATTAAGCCATCTTGTATCTTCTAGCAGGAAGTCAGAGTAGCATCTCGACTGCATCTTCAAACAAGACTTTTGCAAGCTGATGCTCACAAGGGGCTCTGTTTAGAGGTTTGTTCCTGTGGGGAGGCAGGCAGCTCCTCCTGGTTGCTTCTGAAAGCTTCTCTTCATTGCACTTTCCATCTGCACTGGCTTCTGTTTTAGCCACTAAGGTCAAGTCGGTGTGGTTTTCCCACTCTGCCTGTTGCATTAGTGGCACTCTGGAAGTGAGACTTGCACTGGATGGGAAGTGTTTGGTGAATTTTTAAATACCATTATTGATTTCACATTAATTTTCTTTATGAACCGGGCAAAGCTCTTATGCGAGGGTATAACAGCCAAGAAATATTTGACAAGTTGTTTAAAATCTATTGCCTGGAAGAAGCCTGATAGATCAATTAATTTATTTCCCTGCTATTTCAATATATCCTTTAAACATATTTTCACTGATTGTTATTACCCATCCTGAAGTATACAGCACAAAAGCAATCATATATTACCTGCAGCAGAGGGGGCTGCCTCCTGGATCTCTGTCCACAAGAGATATAGATATTTTGCCCAAAGTTGGTTTTTTCCTTGCCTTCAATGAAACATGATTAGAACATAATGATTTTGCCTCTGCATCAGTCCACACCAACTCTATGGTGTTTTAGGGCATCAAACCTGTAAAAAGGGCAGATTCTTTTACATATGCAAACTCCTCTACCTGTTACATCAGTTTATTTCACATTCCACCAGTGTTCCTTTGGATACAGATTATTGATTGCTCCCTAGTGAATACCTTTTTAGTCATTCTTTGGCCTCAGAAAATTACCTTTGAATGTTTTATGCAAGAGTATTCATTATGAACAATTAATGTACTGAAAATGTCAGCACCTCAAGCAGGCATTTTATAAAAGATGAGTAAATTTATGGTAATGCATCATTCAAACTTCCTGCACTTTTCATTCTTTTAAAATTTATGTCTTACATTGCAGTTCAATAGCCTGTAACAATTTGATGACCTGAGTGGAATAATGTCAAAAATGTCTGTGTATTTTAGAAAAAATTTAGAAATTAAGATTTTTATTTTTGCTATTACTGTTTTTAGGTATGTCACAGCTTTATAGTAACGCGAAGTATTTGCTTTATGACAGCTCTTCACATGCTTTTTAATCAGAAGTGAAAAAAACTTGGTTCAGAGCAAGCTTCAGTCTACATAGATCCATTCATAGAAAGTGAGGAAAGTCTTTTGTATCAAGTGGAGGGTGAAAAGACTACTTGTACCCATTTATATTGATATTTGTTAAGTTTTATAATATAGAACACCCTGAATTTAAACCTCTTAAACTTTTCCCTTTGACATGTGGAAGGATCTCAGATTGTTTTGCTTAATTTAGTAAGCTTTAAGCCTCGAAAATGATGCGTGTTTCACATCGCTGTCCAAACGCTCTAAAAAAGTATTTTTAAGGCACTGCCAGCTAATTACCCAA
->XM_020665074.1 PREDICTED: Amborella trichopoda ABC transporter G family member 11 (LOC18430567), mRNA 
-TAATCTGTCTCGATCTCTTCAAGAATTGGGTTGATCTCTCTCTCTGTGTCTCAATCTCAATGGCCTCACTCCATTCTGTCCCAAAATGGATGCCGAGCTCGAGCCCAACACAATCCACAAACCCTCTCCTCAGCCACCCTCCCTTCCAACAAGAATCCGAAGACCACATCTCTCTTGATGAAATTACTCCGAAACCATTGCAAAGAAACCCGAGCCTAAAAATCTCTGACATTGATGAAAATGCATCGGGCACCAGCAAGCGCTTCTTCCACCTCCATGCACCAGCTCTCCAACCAGGCAATATTCGCTCCGAGCCCACTTCTGGGAGGAGTGTCGAAATGGGCAGGACCCAGCACAAGTCGGTTCAAGTGGATATGGATCCACTTGGCTCGGCTGGTTCCGGTGTGTCACTAACGTGGACCAACCTATGTGTCATGGCTGATGGGAAAGAGGGTGGAAGCACAATTTTAAGGGGGCTCAATGGGTGCGCCCAACCAGGCGAATTTTTGGCTATCATGGGTCCATCAGGCTGTGGAAAGTCGACCCTTCTCAATGCACTTGCTGGGAGGTTAAATTCTAATGTAGTGCAANNTATCAACGGTCGTAAACAAGCCCTGGCATATGGAACCTCGGCTTATGCGACCCAGGATGATACACTCATGAGCACTCTAACAGTATGGGAAGCGGTGTACTACTCAGCCCAGCTCCGATTGCCAAGCTCCATGTCGAGCTCTCAAAAGATAGAGGGGGCTGAGATAACCATTCAAGAGATGGGTTTACAAGATGCAATACACACAAGGATTGGGGCCTGGGGGGTTAAGGGACTCAGCGGTGGCCAAAAGAGAAGAGTGAGCATTTGCATTGAGATCCTCACGAGACCTAGCCTTCTCTTTCTTGATGAGCCCACTAGTGGGCTCGACAGTGCTGCGTCTTACCATGTCATGACTCGAATTGCCCGTTTGGCCCTGCATGATGATCGAACTGTGGTTGCTTCGATACACCAGCCTAGTGCTGAGGTCTTCGGCCTCTTCAACACACTATGCCTCCTCTCCGGTGGGAAGACACTGCATTTTGGCCGGGCTTCCGAAGCCAATGCCGTTTTTACACTCAATGGCTTCCCTTGCCCTTCATTGAGAAACCCCTCGGATCATTTCCTCCACACCATTAACACCGATTTTGACAAGGATATTGAGCAAGGTTCCGATGCCGAGGCAACAGAAGCTGCTAAGGCGATTGATATCTTAGTCAACTCTTACAATTCCACCATTGCAAACCAAGTCTTTGCTCATGTAGCTGATATCTCCAAGAGGGAGGGAGAAGCATTGACAAAGAAAGGGAGCCAAGCAAGCTTCTTTACACAAGCGTCCGCCTTAACAAGAAGATCTTTTGTGAATATGTATAGGGATTTCGGTTACTACCGGTTGCGCCTAGCAATCTACATTGCGTTGTGCCTGTGCATAGGTACCATCTTCTTTGACATTTGCCACAGCTTTGGCTCTATTCAGGCAAGAGGGTCCATGCTCATGTTTGTTGCAGCATTCTTGACGTTCATGGCGATTGGAGGCTTCCCCTCCTTTGTGGAGGACATGAAGGTCCCTTTTAATTACTATATTTTCATATAG
->XM_457077.1 Debaryomyces hansenii CBS767 DEHA2B02508p (DEHA2B02508g), partial mRNA 
-ATGTACGATTCGTTCGCTAGTTATCCGCATAATTACTATACTAAAAGTGATGATGAGACAGAAATTCCTCCAACTACTTTTCCTGGTGAAAATTTGTTGACCAAGGACCATTTGCTAGAACAATTGCAGCCAATATTAATCATCAGTGATCCATCCGAATGTAACAATAACTTAAGTCTTTTTATGAAGTTAATCGTTGAGAATATATATGACCAAAATGAAGAAACTACACATAATTATCAAAAATTATCATCTTATGCACTTAAATTGTTGACCCTGAATTTATTTATCAAGAACTACGAATTGTGCCTCGGTAAAATATTAGGATTATTGGCAGCTTTAAGTCGGGACACATTGTGCTCAAGTGAAGGTATCGATGAAGATGTGAAGTTTGAAATCGAGTCATTACGGGAGTTCATTTGCATTATTTTACTTTTACTTTTGAAGTTGACTAATAGCCCAGGAGAGAAGAGCGAAAGATCAAAAATATTGGAAACAGTCGATAGAAATGAGTTGTACGAGATCTTGTCCGACCTTGGAATTATACCTATCATCGCTAATGTTATAACAAATCATATTGTGACCACCGATAAATCTAAATCCCCGTTCTTGTTATTGAAATTTGGTGGGGATATTATATTTGAATATCTCTACAATTGTGAATTATTGTCTGATGTCGAGTTTAATAGTTTGACTAGCGAGACCAACTTAATCCCTACCATTATTAAGCATTTACTAACAAACGACGATTTTGATAATTATGATACTGATGCTGACGATTGGGAGGGTGAAAATAAACTATTTATATATGAGGAGTTTAAGTTATTGTTACTCATCAATGAACAATATTTGATGAAATCATATTCGTCCAAAGAATCAAAAAATAAAGTTTTTGATGGCTTAATGATGGGAGATGCTCATCTATCCTCAGAAAATTCACAACCAAGTAATAAACAGATTAATGGGTTTATCAACTTGTTGATTTATTACATTAATCGTGAGGAGTCTCAAATTATTAAAATCCTTATCTTAAAATTCTTATACCTTATATTTACAACTTCCTACACTGCAAAATTGTTTTATTTGAACGACCTAAAGATTTTGTTGGATATAATCATTCGTGAATTGAACAATCTAGACTATAGTGGGAATGCGAATGGAATATTGATTGTCACATATTTAAAAGTTTTGTATCCTTTGTTGATGTTCTCTCAATTAAGTGAATTGCCCGAAGGTTATAAGAATGAAGGTATATTAGAAATTTTGAGAAACTTGGTTCTTAATTCTGAGTCAGGTAATCGTAAGACAACTGAAATTTCTGAAGCAACCGACGAAAACCAAGCAGATATTATTGCAAAGCTATCATTACGGTGTATGTCTATACCTTGGTTGAGGAAGCCACAATTGAGTAAGAGAAAAAACCAAGACAACCCTAACTTGATAAATAACGTTTATGGAAAGTTATCTGCTGCTTCCTCTTCATCATCCTTGAATTCGAAACTGAGCTTTGTGGGAAAACGTTCTGAATTGTACGAGAGTTCTGATATTTCAAGTGAATCGCTTGGTAAGGCCTTCACCCGAATTGCATCCGTCAGAACTTCAGTAAGAAGCGACTATCATAAGCATGCACTAGTGCATAACGAAAACGACCAAGTGGGCCCAAACGGTCTGAAGAGCTCTTATGTCGAAAATAACCATAATATTTTCTTAGATAATGATTTTAAGTCATTATCAATTAATACCACGGAAGATTTTGCTAATTCTCCTTGGATTCCAATATCAGATGAGTCGAATTTGCTAGATTTACCAAAAGAATATTTAAAAGATGAGCCAGTACAGCCCTTAAAAAGACCAGAGTCTGCATCATCCTCAATTAAGTCAGATTCGAGTCTAGCACAAAAGGCATCAAAGAAGAAGGCACCGCCACCACCTCTTCCACCGAAAAGTTTCCTGCCGAAACCTAATCATATACATTTCGAAAAGAGATCTCAATCACAAACACCACCACCACCACCACCTCCTCCTCCTCCAAGACGCAGGCGTTTGTTACATCTATGTGAGCATTAA
->XM_042466471.1 PREDICTED: Sceloporus undulatus RNA binding motif protein 46 (RBM46), transcript variant X1, mRNA 
-GGCGCGGGAGAGGCTCAGAGGCGCTGGCCTCTGCGTGGGGCAGTTGTTGTTTGTTTCTCCACGTGGGAGGAAGGAAGAGGGGAGGCATTGCTGCTGCTTCTTCTTCCCTCAAGGCGATATTTTCCCTGTCAGGTTTGTTGGATGTGGATGACTGACCAAGTCGGAATCTAATTGTGCACATTGTGGATTTGAAAACTGTTCAGATTTTATTTCTGAAGGCTACAGAACAGAGTAAATAAATTACAAAAAGTAGAACTCTGTAAGTTTCCATCATAGTTATTTCTTAACGTTTTCTGAAGACGGTAAAGCAATGAATGAAGAACAGACAGATGTTACAAATGGCTGCAGCAAAGTTAGAACGGGTACTCAGAACGAAGCTGCGTTATTGGCTCTTATGGAAAAGACTGGTTACAATATGGTTCAAGAAAACGGTCAAAGAAAATTTGGTGGACCTCCACCAGGTTGGGAAGGTCCACCACCACCACGAGGCTGTGAAGTTTTTGTGGGAAAAATTCCCCGTGATATGTATGAAGATGAACTAGTTCCTGTTTTTGAAAGAGCTGGGAAGATCTATGAATTCAGGCTGATGATGGAATTTAGTGGCGAGAATCGTGGATATGCATTTGTAATGTATACAACCAAAGAAGAAGCTCAGCTCGCTATTCGGATCCTTAATAATTATGAGATTCGTCCTGGGAAGTTTATTGGAGTTTGTGTAAGTTTGGACAACTGCAGACTATTTATTGGAGCTATTCCAAAAGAAAAGAAAAAAGAAGAGATCTTAGATGAAATGAAAAAAGTCACCGAAGGTGTAGTGGATGTTATTGTGTATCCAAGTGCAACCGATAAGACAAAGAATCGTGGGTTTGCTTTTGTTGAATATGAATCCCACAGAGCTGCAGCTATGGCAAGAAGGAAACTCATTCCTGGAACATTCCAGTTATGGGGCCATACTATTCAGGTAGATTGGGCAGACCCAGAAAAAGAAGTGGACGAAGAAACAATGCAGAGGGTTAAAGTATTATATGTTCGAAACCTGATGATCTCAACTACAGAAGAAACAATTAAGGCTGAATTTAACAAATTTAAGCCAGGAGCTGTTGAGCGTGTGAAAAAACTTCGAGATTATGCTTTTGTTCACTTCTTCAATCGAGATGATGCAGTTGCAGCTATGTCAGTTATGAATGGGAAGTGCATTGATGGAGCTAGTATTGAGGTAACACTAGCCAAGCCAGTAAACAAAGAAAGCACTTGGAGACAGCATCTTAATGGTCAAATTAGTCCCAGTTCTGAAAATCTTCTTGTCTTTGCAAACAAAGAAGATGGTCATCAGAAGTCTCTAGCAAAGCCAGCAAATCTTCCAATTCGCCTTAATGGACAGCATAGTCCTAGTCCTCCTGAAATTGAAAGGTGTTCTTACCCATTTTTCCCAGGAACAAAGCTTACTCCAATTAGTATATTCTCATTAAAATCTAGTCATTTTAGTTCTGCAACAATGCAGCTAGATTATTATTGCAATAAAAATAACTGGGCACCTCCAGAATATTACTTGTATTCAACAACAAGTCAAGATGGAAAGGTACTACTAGTATATAAGATTGTTATTCCTACTGTTGCCAATGGATCCCAGAGTTATTTTATGCCAGACAAACTTTGCACTACAGTAGAAGATGCAAAAGAGCTGGCTGCACAGTTTGCTTTGCTGCACTTGGATTACAATTTCCGCCGAAGTTCAATAAATAACATTTCCCCAGTTAGTGCTACTCTTTCTTCTGGAACCACCAGTGTGCTGTCATATACATCAAGACCATACTCTTATCCAAGCTATCCTTTGTCACCATCAATTCCACTTGCTAGTAACAACCATGTTGGGCAGCGTCTGTATATCTCCAATCAGGGCTCATTCTTTTAAGGAAAAGAAAAACATGGATGAAAATAGTATACTCTTATTTTAATATTATGTAGTTTCAGTTTTAATTGTGTCCATGCAATTGGTTTTGATGAGTTCAGTATATCTATATATTTCAAATTACATATAAATTAACTGAATTTGGGTGAAGATAAAAGTTCCAAATGTGTTCTATCTTGGCAAGAAGAAATGCTTCCTAAAATATGGCACAGAATTTTATGATTGTCAAACAAGACAAGAAAACCCATTTAACATTTTTAAAGTAATTACTTTCCTGAATAGTAGCTTTAAAATATTTAAAGTGCATGCAATTGTTGGTTCTAATCTTGTTACCAAGGATCACCTCTGTTTTTTGGAGATGAAAAACAAAATAGTCAAAATGCATGTAATCAAAAAGCAAAGTATTATGTAAGAAAGAAATGATGCTGATGAAAGATTTTTTTAAAGAATACAAACTTTATTTAACTCCAGATTAATAACCTCTATACTACTGTGGTCCTTATAAATCACTTTGCATATTTTAGTTGCATGACAAATATTTGTTTTATGATTAGAATATATTATTTTGTGTTACTTTATCCATGTTAACACTGTTAATCTCTATTTGTTAAAGGTACTGTTCTGTTTACGTGTTGTCATGTTT
->XM_019277554.2 PREDICTED: Larimichthys crocea E3 SUMO-protein ligase RanBP2 (LOC104918663), transcript variant X1, mRNA 
-TTGACGGTATTGAGACTGCGCAATAGCATCATGGGGAGCTAACGTCAGTCGAGGCTCACATTAATGTCGGTTTGTTTTATAGTTTGTTAAATCCTCCCGCTGTTCGGTTGTGCCCGGAATAATCAGCCGTTTTTAGGGAGCCATGAGGCGGAGTAAGGTTGAAGTGGACCGGTACGTCTCCTCCGTGCAGAGCTCCTCTCCTTCACTCAAAGAGAAGCCAGTCAAAGGGTTTTTATTCGCTAAATTATACTTTGAAGCAAAGGAGTATGAACTTGCAAAAAGACACGTGTCGGAGTATCTGAAAGTCCAGGAGAGAGATCCCAAAGCACACAAATTCCTTGGACAGCTCTACGAGAGAGAGGGAGACCTCAACAAGGCGATAGGATGTTACAAGCGTTCGGTGGATTTGAACCCAGCCCAGAGGGACCTGGTACTGAAGGTGGCTGAGTTACTGGTCAGTAAGGAGGAATGTGACAGCAGAGCAGAGTTTTGGGTGGAGAAAGCTGCCAAGCTCCTGCCAGGAAACCCTGCAATCTTCAACCTGAAGGAGCGTTTGTTGAGTCGTCAGGGTCAGCAGGGTTGGAACCGGTTGTTCGACCTCCTCCAGGCCGAGCTGGCAGCGAGGCCAGCTGACGCTCATGTGAATTTGAAGTTGGTTCAGCTGTTCTGTCAGGACGGGCGGCTAGAGGAAGCCGTTAAGCACTGCCTGGCTGCTGAGAAAAGGGGTGTGCTGAACCACAGTCTGGACTGGTACACCATCGTGCTGCGCACACTGCAGGAGTATCTTGCTCAGCCCAGCGTCTCTAGTAATGAGAAGATGTGTCGACGTCTCCAGAGGGAGCTCCTGTTGGCCCACTGCAGCCTGCTGAGAATCACACTGTCTCAGAGCAGCGTGCAGCCCAGCCTCGATGCCCTCAGAGGTTTTGATGAAGCTATGCAGACGCTGAGCAGCGTTGCTGCTCGCCACATGGACGATCTTTGGGAGGTGTTTGTGGAGATGAGAGGTCACCTCTACATGCATGCTGCCACACTGCTGTTGAAGCTGGCTCAGGATCGCCAACAGACCTGGAGGGCTGTCATTGACCTGGCTGCACTATGCTACCTGTTGGCTTACCAGGTTCCCAGACCAAAGCCTAAAGTGACCAAAAGAGACCAGTCAGCCCCACAGCCACTGGAGCTGCTGGCCAACAGCCGACAGAGTCAGGCCGGCCACATGTTGCTAAACCTGAGCACGGATTCATCCACCTTGATCAGAGAGGTGGTGGAGGCGTTTGGGAACCGTAGTGGTCAGGACTCTCTGTTTGAACTCCTGTTCGGACCACAGGCCTCTGCTGCATCGTCCTTTATTGCAAATGATGACATTCATTCTGTTAACACCACGGCTCCAGAGCTCTCTCAACTGGCCAAATGGGACGCAGGCTCCATCTTGCTGCATGGTGGTAACTTGCAACATCTGAGCTGGCTGGGGCTTCAGTGGACCCTTCTGGCCCAAAGACCGGCCCTGCGAGACTGGCTACAGCAGCTCTTCCCTAGACTTACTCTGGAAACCTCCAAACTGGACACAAACACACCGGAGTCAATCTGCCTGCTGGACCTGGAGGTGTTTTTATACGGCGTGGTGTTCTGCAGCCACTGTCAGCTCCAGGAGACAGCGAAGCTCAGCAGCGGAGTGAACCAGCAGCAACAACAGCAGCTGTATGAACCACGCTGCCTCCCTCTTCCCCTCATTCGCCTCTTGACCACCGACAGACAGAGGGAGTGGTGGGACGCCGTCTACAGCCTCATTCACAAACAAGCAGCTCCTGGTACTTCAGCCAAACTTCGGATGATTGTGCAGCACGGACTGAGCACGCTCAGGGCTGGAGAGAAGAATGGGCTCCAACCAGCACTGGCCATCCACTGGGCTCAGTGTCTCAGCCAGACGGGTGATGGAGTGAACTCGTACTACGACCAGAAGGAATACATCAGCCGCAGTGTCCACTACTGGAAAGTTGTACGTCCTCTGTTGGACAAGATCAAAAACAGACGCAGTATACCAGAACCACTTGAGCCCCTCTTCATGCACTTTCAATCCAAGGATATTCAGATTTCTTCTGTTAGGGGATACGAAGACGAAGCAAACATAGCGTATGCGGCTCTCCTTGACATTGAGGGCAAGACAGAGGAGGCTATCGCTACGTTGGAAACCATCAATAACATGTCATCCATCTGGCATTTGGCACAGATCTACCAGCGGCTATCAGAGGAGGCCAGCAACGGGGTTGAGGAGACCCAAGATAGATGCATAACATTTCTGAGAAAATTCAGGACGTATTTGTCAAAGATCTATAATGCTAATGCAGATGACATCGAGAAGCTGCCTGTTTCTATGGAGGACATTGTGGACCTTCTGAATGATGTGAACCAGCAGCTGGGAGAGAGTGGTGAGGCCATGGATGAAGAAGAAGAGAAGGAGGAACCGGGCCGAAGAGGACCAGCCCACTCCAGCCCTGCTCATCCCACAGAAACCTCTGCCACCATATCCCACATCAAGTTTTCCACTCCCTCCCCGAACAAAAGCCTCATCTCTCCCTCCAAAAGACACCTGATTTCTCCCAAGACACCACCTCACTGGGTCGAGGACCAGAAAAGTCTTCTCCAGATGCTGTGTCAGCAAGTTGAAGCCCTCAAGAATGAGGTCCATGATCTGAGACACAACTCTTCAGGGAACGCAGGTTCCCCTCATCACAAAATGTATGGAGAGAGCTATGGAGCCGAGGGTCTACAGGAGCCTTTTACCCCAGTTCAGTCTTATCATGGGGCCCCCCTAACAGTTGCCACAACAGGCCCCTCTGTGTACTACAACCAATCTCCTGCTTATAACTCTCAGTATCTCCTGCACACAGCAGCAAATGTAACCCCCACCAAGGGCCCAATGTATGGTATGAACCGTATGCCACCTCAGCAGCACATGTATGCCTACCAGCAGCCCACTCATACACCTCCATTGCAAACAGCCCCAGCCTGCATTTACCCTCCTCAAGAACAGGTCTTTGGTGCCCCTCTTCGGTTTGAATCGCCAGCCACAAGCCTACTTTCCCCATATAGTGAGGAATATTATGGCCAGAGTGTAACCCAACAAACGACTAACCCTCCCCTGCCTGAACCTGGCTACTTTACCAAGCCGTCTGTAGTCCCCGTTCAGCCACCAAAGAGCATCGAGGGCAAGCCTGGGAAGCTCTCCTTCAGCCAGCAGGCACCTGCTGAAGTCCCCAAAGTGCCTAGTTTTGGAGCAGGGGCAGTTGCTCAGTCAACACCCTCAAATGCTTTTAAATTCAACTCCAACTTCAAATCCAATGATGGAGATTTCACTTTCTCAGCCTCTCAGGCCAAGCACAGCGAAAGTCTGCTTGGTCTTCTTACATCAGACATTCCCACTAAAACTGACACCGTTCCAGACAAGCCTGCAGCCCACGAGCAGCCCCAAAGCCAAACAGGCATCTTCACCTTTGGCAATAAAAATATTTCTGGCTTTTCTTTTGTTGATTCCACGCAGAACACAGTCAACACTGGAAGTCTATTTGGAAAGGTGGACCAGCCATTTAAATTTGGTGTTGCAAAGTCTGCAGCAGAGGAGGAAAGAGCAGTAGAGAGCGACAATGACAGCACTCATGTTGAGGAGGATGAGGATGGTCCACACTTTGAACCCATTGTACCCCTTCCTGATAAAGTAGATGTGAAAACAGGTGAGGAGGAAGAGGAGGAAATGTTTTGCAACAGGGCAAAGCTATATCGATTTGACACAGAAACAAAAGAGTGGAAGGAGCGGGGCATTGGCAATGTTAAAATCCTAAGACACAGCACAAAAGGGAAGGTCCGCCTCTTAATGAGAAGGGAACAAGTCCTTAAGATTTGTGCCAATCACTACATCACTGCCGATATGCTTCTGAAACCGAATGCCGGCTCAGACAAGTCCTGGGTCTGGAATGCCATTGATTATGCGGATGAAGAACCTAAGCCCGAACAGCTGGCCATCCGCTTCAAAACAGTAGATGAAGCATCACTATTTAAAGCTAAATTCGAGGAAGCCCAGAAAATTGTGCTCAAATCCCCAGAAAAGGACAAACGACAGGAGGAGAAAGAGGAAACTGTAAAAGTTCCTGAATCACTGGCAGCCCAGTTTGCAGCCAAAGCAGGGGAATGGGACTGCACTGTGTGCTATGTAAGAAATAAACCCACGGATATGCAGTGTGCCGCTTGTCAAACTGCCAATCCCAACGCTTCATCCAAGCCAGATATTCAGGCTACTGGTGAAACCAAAGCCAGTCCTTTTACTTTCAAATTTGGAACTGATGCGTCAAAACCCAGTAGTTCTGGCTCTACGTTTACTGGATTTGGTGCTTTTGGAGCTTCTATACCTTCGTCATTTACATTTGGCACCAGTGCCTCAAAGCCTGCTGACACAGTGACCAGTGCATTTGGTTCTGGCTTTGGGGCTCAGTTTGGCAAGAAGCCAGGGCAATGGGACTGTAACACATGTTATACAAGAAATGAGTCCTCTGCAGACAGCTGTATTTCTTGTAACGGTCTTAAAGCAGGCCCTAAAACAACTGTGACGGCACAAACGGCACCAGCTGCTCATGTACCTGATGCACCCTCTGTATCTGCTGTTGATTCTGGGTTTGGTGCCCAGTTTGCCAAGAAGCCGGGGCAGTGGGACTGTGATACATGCGCACTGAGAAATGAAGCCTCTGCTGACAAATGTGTTGCCTGTCAAACCCCCAACCCTGCAGCTAAATCAACAGAGAAGGTTCCCGTGGCATCAAATCAGCCTGCAGTGTCAGGATTTGGGGCAGATTTTGTAAAAAAGGATGGCATGTGGGACTGCAATGCCTGCCTGGTCAGAAATGATGCAACAGCTGTTGAATGTGTTTCCTGTCATGCACAACGTGACACTTTAGGAGCCATGTTTGCCAAGAAGGCTGGAGAATGGGATTGTGACACTTGTCTGGTGAGAAACGATGCCTCTGCCAATCAGTGTGTGTCCTGTCAGACACCAAATCCAAATGCTAAAAGCACAACTAGCACTGCTCCCTCAGCCTCTTCATTTAGCTTTAGCTTTGGAACAAAGAATTCATCAAGCCAGCCTACCGCAACTGGATTCACAATGCCTTTTGAAACTGGAAGCGGTTTTCAGTTTGGTCAAAGCAAAGATAAAAGCTCAGCGGCCTCTTTCAAGTTTGAAGCTCCTCAGTCTGGATCTAATACCACAAGTTCTTCACCCTTCTCTTTCTCAATGCCCATTCCAGCTGGTGGCTTCAAGTTTGGCATTCAGGAGCCTGCAAAAGAAACCCCCTCAACTGATACTCAAGCACCTCCATCAGGGTCAGCTTCCAGTTTTCTGAAAAGCATAGCTGACAAACACAAGGAGAAAGAAAATGTGCCCACACCCTCCGTGGCCCAAACAGAAGAAGATCAAAATCCAATAATTGCTGTTAAACCCAATACATTCAGCTTTGCAGACTTGGCAAAGTCCTCTGGAGGAGATTTCCAGTTTGGCCAGAGTGACCCAAATTTCAAAGGTTTTTCTAGAGCCGGTGAGCAGTTGTTCTCATCATTAGAGGCAACCCCCACCAAGAAGGATGCCTCAAATGAGCCGGAGGACGATGACATGTACAAAACGGAGGAAAATGACGACATTCAGTTTGAACCAGTGGTCCAGATGCCTGAGAAGGTGGACTTAGTAACAGGGGAGGAGGATGAACAAGTGCTTTATTCTCAGCGTGTCAAACTGTTCAGATTTGACTCAGGCACCAGTCAGTGGAAAGAGCGTGGTGTGGGAGTTCTTAAATTCCTGAAGAACAGCACCAATGGCAGGCTAAGGGTGCTGATGAGAAGAGAGCAAGTTCTGAAGGTGTGCGCCAACCACTGGATCACCACCACCATGAATCTGAAGCCCCTGGCAGGCTCAGACAAGGCATGGATATGGTTGGCCAATGACTTCTCTGATGGCGATGCTAAACTTGAACAGCTGGCTGCAAAGTTTAAAAGCCCAGAGCTTGCTGAGGAGTTTAAGCAGAAGTTCGAAGAGTGTCAAAGACTTCTCTTGGACATCCCCCTACAAACCCCCCACAAGCTTGTTGACTCAGGCAGAACAGCACGCCTCATACAGAAAGCAGAGGAAATGAAGTCTGGTTTGAAAGACCTGAAATTCTTTTTGACGGATGAGAAAACTAAGATCAAAGATGATGACAGCCAGGCAGACATTACAAGCAATGTTTCAAGCCTTGTAATCAAGCCACACGGTGAGACCACCGGCCCCACCTTGGAGTGGGATAACTACGACTTAAGAGAAGAGGCTTTAGATGACACTGCCGACTCATCAGTTTATGCATCTCCCATTGCCAGTAGTCCACTGAGGAAAAACCTTTTCCGTTTTGGAGAATCCACTGGCGGCTTCAGCTTCAGCTTCCAACCAGGCATCAGCCCCTCCAAGTCTCCTGCTAAGCTAAACCAGAGTAGGGCCTCAGTGGGCACTGATGATGAGCAGGATGTAACCCAGGATGAGGAGAGGGATGGCCAGTACTTTGAACCTGTAGTCCCCTTGCCTGACCTGGTGGAGATTTCTACAGGAGAGGAGAATGAACAGGTGGTCTTCAGTCACAGGGCCAAATTGTATCGCTATGATAAGGCTCTGGGTCAGTGGAAGGAAAGGGGCATCGGAGACCTCAAGATCTTGCAGAATTATGACACCAAACGAGTCAGGTTGATAATGAGGAGAGACCAGGTCCTTAAGATATGTGCCAACCACTGGATCACATCTGTCATGAAGCTTGAACCTATGAAGGGTGCCGAAAAGGCCTGGGTCTGGAGTGCCTTTGACTTTGCTGAAGCAGGAGAGGGTAATATTGAGCAGCTGGCTGTGAGATTCAAGTTGCAGGACACTGCAAACACATTCAAACAAGTCTTTGAAGAGGCCAAAGTTGCACAAGAAAACAAGAAACTGATGACTCCAGTGACACCTCGGGTCACCACACCCCAAGACAGTGGACCCACAGGATCTGCTCAGACTGCTCCAACTGTATGTGGAAAGGCAGCCATCGCTGTTCTTGAAGAGACCACAAAGGAACGCACAGAGCTTTCCACCGATGGTAAGCCATGTGCAGCTGGGTCTCCGAGTCCAGCCAACCCAACCCAACCCAAGACAGTAGTGTCACCCCCAAAGTTTGTCTTTGGCTCTGATAGCCTTCAGAGGTTTTTTGGTTCTCCAAAATCTCACTCTGAGTCTGAGGAGTCTGCATCCAGCTTGAAAGCCAAAGATTCTGGACGTCCTGCCAAGGCTTCACCTGCAGCGCCTGCATTCAAAATCCCAGAGAGAGGGCTGGATTTTAGGCTTTTCAAAGATAACCCAATGGCTTTTTGGACCAGCACATCAACCACCCAATTTGAACCCCCAGGGCCGCCTCAGACAGAAGGAGGCAGTGCAGGGTCGGATGAGGACTCAGAGGTGGAGGTTGTGTATGTCAGGGAGCCCACTGCTGAACAGGCAGCTTTAGCCAGAAAACTCCTGCTGCCTCTCACATTCTTTTGCTACAAGAATGAACCGGGCTACACAAGCAACGATGAAACTGATGATGAGGACTACGAGTCAGCAGTAAGAGCCTTGAATGGAAAGCTCTACCTTGATCCTCCCGAGAAAAAGGCTGCAGCATGTGGTGGTGATGAGTCAGACTGTCAAGTTGTGTGGGAGAAGAAGCCGACGCCAGAGGAGGAGGAGAAGGCCAAAAGCCTTCAGCTTCCACCCACCTTCTTCTGCGGCCTGAGCACCACAGACAGCGACCCGGATCACGACAAGCCCGAAGACTTTGAGACAGAAGTCCGCAAGGCACAGCAAGACCTGGATGCTCAGTTAAATCAAGCTGACAAGGCCTCCAGCAGCGATGCAACAGCCACAGAGGAGCCAACGTCGAGCCTGGCATCAGGTAGCGCAGACGCTGATGGCAGCGTAGAAGCTGAAGGTAGCACATCTACATCGAAAGAGCAGACCTCAGACCAGCCAGCAGAGACTCCGAGTGAAGCTCCCAGGAGCAGCTCTCCCATTGACCTGTCAACAAAAAAGTGCCCAGAGCCAGAGTCCAACTTTGGGACTGCAGCTGCAGCACCTACTGCTACGACTGCAGCAGGGCTTACTGTTACCACGGCGGCGTCTACTGCCACAACAGCTTTTACAGCTACAGCGCCTTTCACAGCCATGACAGCGGCGTCCACTGCTACAACAGCTTTTACAGCTACAACAGCTTTCACTGCTACTACAACCGCTAGTCAAGACACCTCCAACTTTGGCTTCAACGCATCAGGAGGCTTCTCTTTTGCTGACCTGGCCCAAAACACAGAAGGATTTGCATTTGGATCTAAAGACTCCAACTTTTCATGGGCAAACGCTGGAGCGACAGTGTTTGGGTCGGCTGTGGCCTCTGCACCAAAAAACAACGGCAATGAGGAGGGCAGTGATGAAGAAGACGCTCCTAATAATGTGGACATTCACTTTGAGCCAATAGTGTCCCTACCAGAGGTAGAGACAAAGTCCGGAGAAGAGGACGAGGAGATCCTGTTCAAGGAACGTGCCAAGCTGTACCGATGGGACCGGGACCTCGGCCAGTGGAAGGAGCGTGGCATCGGTGATATTAAGATCCTCTTCCATCCAGTCAAACGTTTCTATAGAATCCTGATGAGAAGAGAGCAGGTGCTGAGGGTTTGCGCCAACCACACAATCTCACCGACGATGGAACTCCAACCCATGAACGCCTCGGCCAACGCACTCATCTGGACGGCCACCGACTACTCAGACGGCACCGGCGTCGTGGAGCAGCTGGCGGCCAAGTTTAAAACCCCAGAGATAGCCGAATCCTTCAAGAAGACTTTCTGCGGGTGTCAGAGCCGAATTGGCAACACTGGTGACGATGCCTCATCTAGTTTCACACAACAGATGTCCAGAGTTCAAGAGCACTCCAGAGACACTAACCCGCGGGTGTTCCTCAAAGTGGCAGCCGATGGCGAAACACTGGGCACGATCACCATCGAGCTTTTCTCCCATATTGTCCCCAAAACTGCAGAGAACTTCAGAGCTCTCTGCACCGGCGAGAAAGGCTTCGGGCTTCTGAACTCCATCTTCCACAGAGTCATACCATCCTTCATGTGTCAGGGTGGTGACATCACCAACAGTGACGGCACAGGAGGCAAGTCCATCTACGGCAGCCAATTTGAGGATGAGAACTTTGACGTTCGTCACACAGGCCCGGGCATCCTGTCTATGGCCAATCGTGGGCGCGACACCAACAACTCGCAGTTCTTCATCACCTTGAAGAAAGCCGAACACCTGGACTTCAAACACGTGGCTTTCGGCTGGGTTCTGAACGGCATGGATGTGGTTCTGCAGATGGGAGAGCTGGGCACAAAGGGAGGACCGCCCACGAAGAAGCTTGTCGTCACAGACTGTGGACAACTCTGACTTTTTTAAATGTTAAGATCAAGATTCACAGCTTGGTTTAGGTTATAAAGACTTTGGATAATGATGCGTTCCCCGTGCAGTGCATACTTTCCTGATTATACTGAGTCCATAGTCATTAGACAGCTGAGAATCAAACACTGATCACACAGGCCTATTGATCAATCATAATAGAAATTGGCTACAGTAGCCTGAGATTAGAAAATATTTTGCTATCCTCTAACAGTCACAGATGGGAAACATGGAGTAGTATGCGGGAGGAGACAAATATAGTACACTTCTTCTGTGTTGCACTTGCATCTTCATCATCGTCTGTCAATAAATTCTGTTTATTTTGTGTACATAATTGTATATGAACTACTTTTTTAATGTTTTTTGTCTTGCATGTGCTCAATTTGAATGTTCTGGTCGTCTTCATAAGCTCCACTCGGGTATTTTTTTTTCTCCCCTTTTTTCTTTTGAAGTCTTAACTATAATTGAAAGGTGAGGCTGTTCTTTGAATGCACTTGTTGGTTTATAACTGTGCCCCTGCCTTCACTCCAAATGCTGCCTCTGTGTACTGTTTACCGTAGGGCTCCCCCAGTGTTTTTTTTTTTTCTTTCTTTCTTTGTGTATGTGGATTTCACAGGTGAATTGGACTTCATACTTTCTCAGAAACTCGAGTCATCTCACTGTGTGGCTAGATGATGACGTTCCATCTGTTTTGAATTTTACCAGGCGATCCTCCAGAATTTGAGATTATTATTACATCGCTGAAGTGAAAAAATAATATGCTGATAAAGGAGAAATAAAGTTTGCTTCACAAGTAA
->XM_051564479.1 Radiomyces spectabilis CAP domain-containing protein (BYT42DRAFT_497200), partial mRNA 
-ATGGTTTCTCCCACCTTCATTTCGTTGCAAGTGTTATTCATTGTGGCCGCTTTGATTCAATTGGTCTCGGCGACATCGGCCAAGTCAGCTCAGCACATTGTGGAGCTGCATAACCAGTACCGGGCCAAGCATCAAGCGCCTCCTGTCAAATGGGATCCGAAATTAGCAAGATTTGCTCAAAAATGGTCGAATCGTTGCATATTCGAGCATAGTACCAGCCCGTATGGCGAGAACCTGGCAATGGGCCATAAGAACTGGGCTTCCGCCATTGCTGGTTGGTACAACGAAGAGAAAGACTATGATTACAGCAATCCTGGCTTCACTTCGTCTACGGGTCATTTTACCGCCGTAGTCTGGAAAAGTACCACTCGCATCGGTTGCGGTGTCAAGAATTGCAACGGTGCCAAGCTCTACACATGCTCTTACTCTCCTGCCGGTAACGTTGTCACCACTGACAATCTTCGCTTCAAGCAGAACGTCTTGCCCCCTGTATAA
->XM_043120008.1 PREDICTED: Carya illinoinensis HVA22-like protein k (LOC122307253), transcript variant X1, mRNA 
-ATCCTGAAAATTTCCATGATCGCCACTCTTAGGAACCTGCAAAATTCGGTGGGTTTGCGGTTGCTTCTTTGTCCTCTCGGTTCTAATATTGTAATACGGACAGCTTGCTGTTCTGTTGGGATTGCTTTACCTGTGTACTCTACATTCAAGGCAATTGAAAGGAAAGATCAAAATGAGCAACAAAGGTTGCTTTTATATTGGGCAGCTTATGGATCTTTCAGCATTGTGGAAGTCTTTTCTGACAAGCTTCTTTCTTGGTTTCCTTTGTACTACCACGTGAAGTTTGCATTTCTTGTTTGGCTTCAACTTCCATCCACAGATGGGGCCAAGCAATTATACATGAACCACCTACGACCATTCTTCTTGCGGCATCAAGTTAGAATTGATCAAATTATGGGTATTGCATATGGTGAAATGCTTAAACTTATAAGCGCACATCAAACTGAAATTCAATTCGCTAGGAATGTGTTTGTGAAGATTATGGGGGCAGCGGACCAAATGTTAAGAGGGGCTATGAAGCCCGATCAACCTCGACAGAACACTGCAATTGAAGGCCCGTTAAGATCCCCAGATACCCACTCAGATCATAACGATTGATTCCTCTTGTAAGTTTGCATACAACTGAATCATTTTTCCTTGCCGATGAATATAGTCAGCTTGTAGCTGTTATCACTCTTTTTCATTTCCTTGTAAGATGAAGGACCCTTTGCTGTATCTTATCCAGGGGATAGGTGGTATTAGTCTTTGAATGTAAATATTCGGCCATACATGTGGACCTTTAGCGTACATGCGGTTGATTAAAACTCGTATCTATTTGTTTTACCCTGTAATAACACTTCATTTTGTTTTTGTTTTTA
->XM_007831313.1 Pestalotiopsis fici W106-1 hypothetical protein mRNA 
-ATGGATTCTCGCTTTCCAGTGTTTCGAGAAGAACTATACAATGTTCAGATGGACGTGAAGCAGCTTGCTCATGTGCAGGTCAGCCACGCTGAAAGATTGGCTCGGCTGGAGAAGCACCAAGCAAATGAGTCGGCTATCAAGTCTGCCTGGAACTCTCCATTCCCCAGCGCTATCGGTGGCACCCCGCAGCATGGCCCTATTCAAATGCCCCCAGTCGATTTATTCGATGACTTTGATGAGGAGCAGGGCCAGAACTTGCTAGGCAGCCTCCATCTCGATGCTGAAGAGGAGCCTGTCCGGCGCGGCGCGGCCTCAAGGGCGAACAGTGTTCGTTTTGACGAGAGCGCCCTTCAGGGCTCTAGCTGGGCTCAGAACGGCCGGCAGTCTGGCGAATTTGTGCCTATCCGACCTGGCAGTGGCATGGGAAACATGATGGAACGCACGTATTCCCACAAATCGGATGGCCGACATAGTTCTGCCGGTTATTCTGTGCACTCTGTGCATTCCCATCATTCTGTAGCTTCTGGTCGTGGCAGTAGTCTTGGTCTAGATACTAACTACGCAACGACTGGTTCCGAGGAGGACTCGCCCATTGATGCACCGGCACCGCCGCCCGGTTTTTTCATTCTGGGCTCTGTTCCGTCCATTGTTCGTTGTTGGCTGACAACAAATTTCGCACACGAGACGCTCTTGTATGCAGATATCTGCTCTGGCTCACAGCAATCAGTGCTGGACTATTCACTGATCAAGGAGCTGGAACTATCAGACGAAGTGCACAAGGACCTGGACGGAGTGTATCGAATTCGCTTGCCAGTCTACCTGACTGAGGCCACTGTCACCCACCCGAGCTCAAGAAATTCAAGCCCAACACCGCAGATGCCGAATTTGATTGTTGGCTTTGAAGTCGTTGGACTAGAGCAAGCAGAGTTTCCTGATTTGAAAAAGGGCATCCGCATTTTCATAGGAAGTGAGACTTTGCGAGAACATTCTGCTGACATCTTCTTCTCCCAAAACCGCATGACGCTGTACGGCAGTGAAAGAGAGAAGCTCTCCGTGCCCTTCGTGCGCCCGGAAGATCACAGTGTGTTCAAGTACATTCGTACAGTGGCTGTCCTGCCCGAGAAGCCGCGGCTGAATGCTACAGCGCGTCCTTTCGTCTTGGGTGAGCCCAAGGCGGCGGAAATCTCCAATGAATCTGTCAACGAGATCCAAGAGAAACACGAGCGAGGCGCGCTCGACAAGGAAATACAGTCTCGTGCGCCTGAGGTATCACAGCAACCGACGACTGACCGTGTTACAAGCAACCTGCCTGAAGCCGCAAACGACCGAGACACCCAGGGCAAAGAGGACACTGATGTCTACGAAGCTTCGAACCAAGACCTGTCCGTCTCTGGTGACAATCGCAGTGAGACCACCAGTGACAGCCAGCGCCGTGAGCCAACTGCTAGTGGCATATGGTCTTCTTGGAGACAAGGCTCTTCAACAAACAGTGGTGACCCGAAGGAAAATGCCCCATTGAGCGGATATCAACCACCTGGTCGAGTTCGAAACATGAAAGTCCTGAAGCCAAGCAAAGCCAGTACGTCTTTGTCTACCCGAGCTGGAGTCACTTCGGAGGCGCTTCCGAAATCCAACGGTGAAAATCGTCGTAAAAGTCAACCTGCGGACACTACTCCCACAGGTGTCCTTCGATGGGGCAAGCTTGATCGGGGTTCTGCTTCAGGATCAGACAAGGACTCCAAACCAGCGGCCATCAATGCGGTGCATCGCGAAACCCGGAGCGTGTCCAGCACACCGCGCACTTCTGCCAACCCCGTCGGCGGAGCCTCGGCTTTCTCATGGATGACGCCGATAACTAAAACAAAGCCTTCTACAACCACTGCAGATTAA
->XM_047249926.1 PREDICTED: Schistocerca piceifrons uncharacterized LOC124775103 (LOC124775103), transcript variant X2, mRNA 
-ACAGCACACCACAGCGCGCGCGGTCCAGCTGCGACGCAAGCCCGGTGTCCGGAAGCGCCGAGGCCGACGCACACATCCCGGAAACTCACCTCTACGTACCTGCGAACACGCGCACCGTCAGAAGTTGCTTTTTCCAGAGCAGTTCGACCGGATCGGTGTTGCCATTCAGAGACACACCGCATGGTGGCCACCAAAACTGTGAATTGCTCGCCTCACGTGCTCCTTGGACCACGTCAGTGGTCCTTTATGTGCTCTTGGCCACAGTTATTGGGCAAATGTTATCCTATTACGAAGTTACTGCAGGGCTGGCCCAGACAATGGACAGAAATGGTGTTCAAAATCCCTCTAAATTGACTTGGTGCTCCAATGGTGGAAACATTAGGGAATGGATTTAAACAAGAACATAGAATTACCATGATGCTACAAGTTACCAATAACTGATCTTATTTATTTGCTGTTTCAAAATTCCTTATTTTTAGTGCATTGAGAAATAAGTGTATAAACAACCCGCTTCGTTATGGTGACTCCACCATCAGAGGAAACACCTACAGATGCATCACACCAGAAACGGTTGTCAGTGGATTTGTCATTGCCAGCCCGTTGCCATGGTGTAGATATTGCTTTCGATGTGAGAGAAATAATTCCTCGTGACAAACTAAAACAGGAATTTAATGGTAAACTGGCTCAATATGGCAACTTTCCAGATTTCAAAAACGATTTTAGAAATTCTTACCCATCTCAAGTGTCAGATACATCTCCAATCTTGGAGCCCATCTCCACCATTTCATTACACACTGACCAGAAAGCAGTCAGTGACACAGCAAATTGTGCAGTTAAATTTGAAGAAGGTACAAAATCATCAGCAGACAAAAATTCAGAAAAGGATAGCATCTGCAGCAGTAGCCCCTCCAGCAAGGATCATTCAGAGAAGACCAAAGTGCCGGATGGAGGTTGGGGCTGGGTGGTTGTGATTGCATCACTTGTCATCAGCATGATTGCTGATGGTGTAAGTTTCTCCTTTGGGTTATTGTTCATACAGTTGCTGGATCATTTTGGTGAGAGCAAGAGCAAAACATCTTGGATTGGAAGTCTGTTCATGGCAGTCCCACTTTTATCTGGACCGGTTGGAAGTGCTTTGGTAGACAGGTATGGCTGCCGTTGGATGACCATTATAGGAGGCATTGTTTCTGGCATAGGTCTTACATTGAGTGCGTTTGCTGATTCTGTGGAGATGTTGTACATTACATTTGGTCTGATTGCTGGCTTGGGATTAGGACTGTGTTACGTGACAGCAATTGTTAGCATTGCTTACTGGTTTGATAAGAAGAGGACTTTGGCGACTGGTCTGGGCTCATGTGGCACTGGAATTGGTACCTTCATCTATGCACCAATGACGACTTACTTTATTGAAGAGTATGGATGGCGTGGGACGACGTTGCTCCTAGCTGGTACATTCTTCAACATGTGTGTATGTGGAGCACTGATGCGTGATCCAGATTGGTTGGTACTTGAGCAGAGAAAGCAAGCCACAAGCCACTTGTACAAATCTGGACGAGCATCTTCAAGTTGTGCCTCTGTATCTGGCCGATCAGATAATGCTGGTGACTTCCCGGGTGTAGATGGGATCCGCAAAATGCTCTCAAGTGGCCATTCGCCAGAATATGTGCTGACGACATTAGCTGCCAATTTGCAGGACACAGACTTACCCCCAGGAGAATCGGAGGTGGATGGTACAAAAACTCCAGCTTATAGTTCAGTTGTAAATCTCCCCACATTCATTCATAGAAGTGAGAAGGTTCCACTGGAAGTGCTGGAATCACTCTGCACTAAGAGGAGAGTGTTCAGTGTAATAATGGAAAATTATCCAAGCCTACTTTCGTGCAGAAGTATGTCAGATAAAGGTATCAACAAGCTTCCTGTAACATCACACTCAGTTTCTCACCGTATCCCAGTGTCAATGGAGGTCCACATTCCCAAGAAAGAAGAATCAATTCCAGCTTGCGAGTACGAAGGAAACGATGCAGAAAAACCTACTCAGCAGGCTACATCACCACTGCTGCCTAATGGAGGAGTGACACAGCCAATGAATATAATTCCACTGGCTACAGGGCCATCAAACTACCTAAAAGGCATCCGTATGCACAGGAATTCTGTAATGTACAGAGGCGCTATGTTGAAAATACACAAGTATCGGTTGAGAGCGTCATCCTGCCCTGATATCTATCGTAACTCTATGACCACCATAGCAAAGGAAACAGAGGAGAAATGGTATTCTGATATACTGGACCTTTTGAGGGACATTGTGGACTTCTCAATGTTCTTGGAACTGCATTTCCTATTTACATCACTTTCAACTATCCTGCTTTTTACATGGTTTATCGTCCCGTACTTCTATTTGGCTGATTACATGATGCTCTATGGATACACTGAAAATGAAGCATCACTTCTGCTCAGTATTATTGGCCTCACTAACTGCATTGGAATGATTGCTCTTGGATGGGCTGGTGACAAACCCTGGGTGAATGTAACCAAGTCATATGCTTTGTGCTTAGTGATGTGTGGTGTGGCAACTGGATTAATGCCACTAGTCATTACTTCATACTGGATGTTGGCATTACTTTCAGCTCTATTTGGTTTATTTTTTGCATCTTCATTTTCATTTACTCCAGCCATTTTAGTGCAGCTAATACCTCTTGATCGTTTCACAACGGCGTATGGACTGATGCTGCTTTGTGAAGGAATTGGAAATCTTCTTGGCCCACCATTAGGAGGTTTGGTTTTTGATCTGACTGGTTATTGGGATCTTTCCTTCTACTTAGCTGGTGTTTGGATTGTTTTATCAGGCATTCTCATTGCCCTGATACCCATCACGAAGAATCAAGTTATATGTGGCAAAGGAACACTTGAATTGGAAAAAGAACAAGATCAGGACTCTGTTGATGTACCATAAAACTTCTTAAGGAAAAAAATCATTTTCATGGAAAATGAGGCATCTTGATTCATGTTTGAGGCACATAAGAACCTCAGCATCCTGTAATACTCTTATTAGGTTGTGACACCAATCTAAAAAAAGCTGTTGGGTAAATGTTATGTATGTGAAACTTGTTTGTTGCAATTGTAATAAATAGCTTTAATCTCTTCAGTGACTGACGACCTAATGATAAACTGGCTTAATATACACAATTTCCATCAGAGGAACTTCACTTTAATAGATTTTCACAGCCTGATTATCAGTAAGGAAGAATGCTAAATAGGTTATGTTCAATTATTAATTGTATATTTGTGTATAATATTTAATTTTGTCTTATATTAAGCGCAATCAATATGAACAGAGACTGACCATAACTGGAGAGGTTCTTACTGGATTTGATAGTATTTGGTTTCTCTTAAGGATAAGAACACTTACAACCACGTTTATGATTGCAGAGCTCCAGGATAGTCAAAATAGCTATTTTGTAGCCAATAAATTAGTGTCAAGTGTCAGAGGTTGATGTTCACAAGGGGATAACGTGCTAACAGCTCTGATTATAATATGCAGTTATGGTCTAGGCAACACCAAAACACTGACAGTAATTTAGTAGTGACAACACAAATTCTTTTATCATTTTAGTATTTGAAATCATAATCACAGAAATAAAAACAAAATCTTTTGACATACCGTGTCTAGTTGAGTAGAATGTATTGGATATTATTGTGTTCATACAGCATGTGAAACACATTTGACAATTATACAGTGTGTCTTAAACAGATTGAGGCTATGCTCTTATAAATGCAGGTAGCATTAATATTAATCCTTTAAATTGCTTGCCTGTAATTAAAAATTTAATATACTCCTTCTTTTTACAAAGAAAGAATTATAGAAGTTCCTGAACTTTTTGTGAATGTTGTAGTTGCACAATTAAGTGGAAAAAATTCGTAGCAGATCTACTTCTCTCCTACACACATTCTTAGCTTTGCATAGCATAACAGTTATTGCTCCAAGTTTGACAGTTATTTTATTTTCATTGATAAAAAGTTATTGTTATCTAAATTAGTTGCACTTAAGTGTTAGATATGAGCAGTTAAAGTTAAAATGATCTGAGTGAGGAACAATTCCATAAATTCCCCAGAAAATGTGTCCAGACCTTAAATAAAAAGAGTACTCCATTAATTGGTTTAATTACATATACAGTTGTCACACCATAACCTACCGGAATCAGTTTTCTATTCTATGACTACTTATACCACATATATGCGAATAATATAATTCACCAAATAATCTGCGCACCCAAATTTTAAGGGGGGGGGGGGAGACTGGTTTTAATTTGTTTTTGTTTATACATTGTGTATCTTGCTGTTTAAGTGCAGCTTATATATCGAGTTGTTGCAGGATGGATGTTATGCCTCCGGGGGTAATAACAGCTAATTTTCCCTTTTTGTAACTTGTCTCGCACTTCCTCAATTCTGTCTCTAAAAGCTGCCCAGGACTGACATGGTACATAAATTCAGTAACGCTACAGGGTGACATTGCCAAACCATGCCACCCAGTCAACCGCAAGGTCATTGTCCATCCGCCCCTTCACGTTCACTGTCACCAATATGGCTTTCAGTGATCTTTTTGCAATAGTTTCTTTTACATTTTACGTTAGGTGGTAGCTATCATCCATTGCCAGTTACACACATCACTGTACACCTTTGCCACTCATTGCTGCCAGTTCGAATCATGACGCTGCAGTCCCCTTGGATCTGTATTAGCAACTTGCAATAATATAAAGGAATGTTTGCAGTGCAAATTTATCACTTAGTGATGAAAATTCACTACTTTTCCTCCAATCATCTGGCAGCTGTTGAGCAATGGTAGTTTTGCTCTGGAAGCCTAATCCATTGTGATGGAAAAATATTGATAGCCAGCCCTAGCTAACATTGAAACCGGTGATGCTTAGTTCTTTGGCTGAAGCCAATGCTTTGATTTGGCACCTTTCACTTGTCACTGGGCATCCACATTGTCACTTCTTGCCCACGTAATTGCAGAGCCTTTTTTCGAGATCCATATGCTTTGCTTTTTGGCTGTGAAATCGCTGGCGATTACAGTTTGTTTCTTGGAGGCGCATTTTGTTTTTTCACCATTCGCAAATAACACTTGCTCACATCCTACTTTATTCCCACTGCACGGTTTCCAATGTTCTCTGCTCCTTCAGTAATTTCAAGTTTTTTTTAGCTGTGTATGAGCAGTATTGAGAACATCCATAATTAATTAGTGGTTAATGCACTTCTAATGTGCTATTGATGTCACAGACTGAGGCCACGACAACACTATAGTATAATGGGATCTATTGTTGGAGGTGGACAGTACCAACCTTATTACAATTAATCTACACAACCCAGCATTTCATCCTTAAATTCAGGGTAAAAACGAAGCCCAGACTACTCATGTCTATACGGTATTTGAACTCTTCGATTTTGTGCTGAGATTGATTTCTAGATTCCTTATTCTAGTGAACATATAGCAGTAAGAGTACAAAGTGTATTTGGAATGGGATGTTGCATTCATTTGTCGTAGATAATTTTCTGAATGTTTTCCATTTGAGAATCCCTAACACAGTACTTGAAAGTCTGCTACAGTTTTTCTATAATATCTTCTGTTTTCATCAATGTGGAAGCAAACTATTCTTTACCCAAGTCTTTTTCGTTTGTAAGGATGATTTTTATCTTAGAATCATTAAAAGACTCATCCTAGGGCTGTGAAGAAAAATCTGTTAGAACGACTATTACAGTGGTAGAAAATTATTTATTTCATTTGACTGTTGTTGCAATTTGAAATGCAGCAGCTGCTTCTCAATTAGTTGGTTTGGCATTGTTATAGTTTTTCTTTGGTTCTTTTTTACTTCTGGAGAAAATTTTAAATTATCCATAGAAAAATATTTTAAAACATTGTGTTTGGAATATAATGTGACTTGTGGCTCCCAGTTTTGCAATAGAATTGAGAAAGATGTAATAGGATCTGTCTGCTTAATTGATTTTTCCCTCCTCTGCATTTCCTGAAATGGTTGATTGTATTAAAAGTGTGACGTTTAAGACTGTGAGCTATCAGTGAGTTATTGAGTTATCAAGTGAATTATTGAGTTATCAAGACAATGAAAATCTCAAATGCACATACTCATCAGTGGAAATTCACTTGGGAAACTGAATTAGTGGAAATAAGAGGTGAAATGAGCTTCATGTATGATAACAATATCTTAATGTCCATGAGTAAGGCATATGTTGAACAAAAGTAGTAGCTAATTGGTGGCTACTTGTCTCTAAATTACTGATGTAGTAAAATATGACGTTAACAATTGGATGTCGATTGTTAACCATTGTGATTAGAACTTCACAAGTGTATAGTAAATGCTGAAACCATGTCTACAATAAATCCTTTTGGATCTTCTGAATCTGTAACGACATTTTGCTTTCTTTTCTTAAGACACGAAATTTGAAGGATGTAGCAAAGAATTCTGCATCTTCGTCAATCATCCCGTTGAAAATTTACCTCCTGTGTAGGAGGCTTTTAGCAAGCTAGACAGTTCTGGATGTGATGTTTCTGGGTGTCCAGTCATATACTTCATTTAACTCATTTTTGAATGTCCTGTTGTAAGCATAATAAATTTGTTGTTAACTTTTGCATACAATAATTATTACACGCCATGCTGAATGACAGAATAGTGGTTTGCATCCTTGTGGCCTACAACGAACCACACCAGTATATTGATGCCCTTTTTCTGTGCAGTACAGGTGTAACAATTTGTACATACATGATTGTACACGATGACAATGTATTCATTCCAGCTTTTGCTGGAGATAATGAATGTGAATTTCCACACCATTAGAATTTCAAACTTTCCACAGAAAGTTATAATCATGCATGAAGTTTCTGATACAATTGATAAGTACTCCTATTTGACAGGGCAGATTTTTTTAAACATCACATAATTTTGGACTAATGATAAATGGTAGTATTGCACAAAATGATTTTTTTGAAATCTGGAGATGATCAGAATTCATTTAGACTGGTTACTCTCCTTCCTTGTGCTTCAATAATTATTAGTCTGTGGTAGCCTTAATTTCAGTTTATTGTGATCTTAAGAGATTAATATATTAGCATTTATACAAGGAAATTTGTAATTTTGATAGCATAGTTTGTCAAGCTGGTTATTGAAAGTGCATGAAGAAGTTCACAGAGAAAGTTTGATGCTGTATTGAAGAAATAGATCTTGTGCCTTTTCTTGTCTATATAGTGTATTGATTGATCTGTCTTCGCCAGTCATCATTCACATTTCATTGTTAAAATTAAAATTAATGTATTTACATAAGCAAATTGTTGTTTGTAGTATTCTCAGGACCATAATTGTATTCATTAGCTTTTTCATAGTGTCCTCAATTTATATGAAATGAGACATTACTTTTACAAATTTATTCTCAGAACTGTTCTAAAATTATTGCACTCAAATGTAGTGCTTCGTTGAATTTTGTAAAGTCTAAACTAAAGCAATAATGTTTATTCTACTAGCTATAATTATTTTTGTGTGTAATGTCTTTCATATGCTGTTATGGCATGTGATACATAGTGGTATTAATTAGGAAAGCTCAAAAAAAGGTAATTACTTGTGAAGATTTCATTTGATTTCCCAACTCTGTTTGAAATTACACATGACATGTACATAATCTGTGTCTTTCAAGTGAAGTGCTATATCTTTTAATTGTATTTATCTTGCTACAGTTTATCTCACTTTCACATTAAGAGTAGAGGAAGAGAGAAATTGAGACGAGGAAACCTTCATGCATGGAAATAAGATTCTCTCTCCCCTACATTACGGGTTATCAGACTGTTTATTTTTGGTAATCATGCAGTTACATTCTCTGCATTTGTTTAATACTGATCAGATGCTGTAAAGCCAAAGTGATATTATTTTACAGATGACATATTTCTTTATTTGATGAAGAGTCAGTGAAGTATCTATGATCAAACATTATTACGCCTACTTTGAAATGTAAATACATACTGAAATTTTGTTCTGATACAAAATTCAGCGACTGAAAATATTGTGGTTGTAATAATTATATATATCACTGAAATCATTTTTTTTAATTGTTCATATCATCTGCCATGTTCCTCTCACTAAGTGTTAGGCAGACTAGGCTGTGATTGTGAAGTATTGTTTGGTTTGTTGTAGAAAGTTTCTCTTTATTTCTGTCAAAGTACAACTTACATTACCAAAGTCCTGCTCAGTATTTTAAGTAGATTCTATTGAAAGTACTAATGTAAGTACTCACAATTTAAAGACTGTAGTAGTATCATAATTATACATTTATTATTAATTCATTTAGTAAAAAAAGAATTTATCTTGTAATTTGTTAAACACAAATTAAAGGGGGCTGTCAAGTTTATTGGGTGTAATGTAGTGCCTTTCAAAATGAAAATTTTAGAAATACAGGTTTATTGTGAGACTGATCTCTTGTCTTTTTTTGTGAAATAGTATTCATTGGTATTGACTTGTTTAAAATTACAAGAACTCTGATTGTGTATGTCGCATTTTTGCCAAGACATAAATTTCTCAAATGTAAGTAGTTACAGTAAATGATTGGTAAAATTACTAACAACAGGTTTCATTGTCTCAGAGATGATTATAGTTACAAATGAAGCAATAATGTTAAAAATTTATATATAAAAATTTTTTGATGGCCAGTTTGTACATATTTTTCTGTCCTCAGTGGAGCAGATGTGTTGAGTCCACAAGTAAAACAAGCAGCTACTGCAGGCCAGTTGCCTGGCCTCATTGAGTTTAATCGTA
->MW362430.1 Lactobacillus acidophilus strain BCCS A50 16S ribosomal RNA gene, partial sequence 
-ATTCACTTCGGTGATGACGTTGGGAACGCGAGCGGCGGATGGGTGAGTAACACGTGGGGAACCTGCCCCATAGTCTGGGATACCACTTGGAAACAGGTGCTAATACCGGATAAGAAAGCAGATCGCATGATCAGCTTATAAAAGGCGGCGTAAGCTGTCGCTATGGGATGGCCCCGCGGTGCATTAGCTAGTTGGTAGGGTAACGGCCTACCAAGGCAATGATGCATAGCCGAGTTGAGAGACTGATCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCACAATGGACGAAAGTCTGATGGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAGCTCTGTTGTTGGTGAAGAAGGATAGAGGTAGTAACTGGCCTTTATTTGACGGTAATCAACCAGAAAGTCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGCGAGCGCAGGCGGAAGAATAAGTCTGATGTGAAAGCCCTCGGCTTAAC
->XR_006102310.1 PREDICTED: Sceloporus undulatus uncharacterized LOC121923102 (LOC121923102), ncRNA 
-TGGCGAGGAGAAGGAGGAGGGGGAAACAGGAGGAGGAGGAGGTACCAAGTATCAGGTTGTGGCTTGCATCAACAGGTCCCATGCACCTGACCAAGAGAACAGGCTTTCTATTGCTCAGGCTTGTGATATACAGATGAAGGTAATAGACTGGAACCGTGAAATGCAGTTGTGAACTGCTAAAGCCTCATCGAAAGTTTACGCCAACAACTGCAATTTTATAGGCACTTCAGGAAAAGAAGACAGCATTGGCCATTTAACATAGCAGTAATGTTTGTTTTCCTTCTGCCAAGTATACAACATTATGATTAAGAAAGAGAGGAGCCCATAATTTTTCTTGGTTAACATGGGAACGCAAAACAGGAGGGTGTGTTTATCTTGTTTAATGTTTTTTCTCTCCTCTGACCTCTAAAAGGCTTTAAGTAAATTTTGTGGTAAAGCAAAGCACATGAGCAGCGAGGGAGTCTCAGACAGTTATAGTGTCTGAATACACTCTTTGTGGTATTGGCAAAGATGCTGTGATTAAGAATTGGCAAGCTGGTGGCTTCGACTGATAGAACTTTTATTTTCCTTCCAAGAAACCTGCAACATGAGGATGGACAT
->JF772131.1 Bacillus sp. NA-107 16S ribosomal RNA gene, partial sequence 
-ATACATGCAAGTCGAGCGGACAGATGGGAGCTTGCTCCCTGATGTTAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCTGTAAGACTGGGATAACTCCGGGAAACCGGGGCTAATACCGGATGGTTGTTTGAACCGCATGGTTCAAACATAAAAGGTGGCTTCGGCTACCACTTACAGATGGACCCGCGGCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTTTTCGGATCGTAAAGCTCTGTTGTTAGGGAAGAACAAGTACCGTTCGAATAGGGCGGTACCTTGACGGTACCTAACCAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAGGGTCATTGGAAACTGGGGAACTTGAGTGCAGAAGAGGAGAGTGGAAGGTGTATGGTAACCCTTGTTGTGTGGGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGT
->XM_047969201.1 Xylaria bambusicola uncharacterized protein (F5B22DRAFT_156494), mRNA 
-CACAGAACGACATCTCAGGTGAAAGAGGTGAACATCATCTAAGACATTATCGGATTGGACGTAACCATGTCACCAGATCGAGTCCCTAGTAATCGAGTTCCGCCTCGCCCGAAGACGCCTACAGACTACGTCCCTACGCCGATTCGTGCAAAAATAACCCCCTCAGAGACTTTCAGCCACCTCGTGAATAAGAAACAGAGATCCGCCAGAGTGCACGCGCTTGCTAAAGAGCGACTCACAAGTTCTAGGCCAACCACGCCTCGGACCCCTACTACCGTAAACTCCATTATCAAGTCCGCAAGAACCAGCCGGTCCGCTCTCAGTTCCGCAGGCAGAAATATAGCGTCCAGCCTTTCAAAGGCAAAGCCGGTGGTGGAAACAGCAGTCGCAGCCAGCAAGAAGGCTGCCGTCACAACTGCAAATCGCTTGACAAGAATGGCAACTGATGTGCCGAAAGTGGCCAAGCAGAAGGGAAAGGAGGTCGATGTATTGTCGACTCCATCTAGCTCATCATCGCAAAAATCACTGTATCATCGACCTAGGCTGCCCAAGCTCAAGATCCCCGAAGTTGATGCTGCAGTAAGAGACGCGTTAAATAGTGCATGTTCAACTGATACACAGAACAGCGAGAACTTTCGAATACTCCAAATTTCGCCCACGAGCCGAGAGCTCGAGTATGAATGGCAGAACGATGATAACCCACCTGACGTTGCTGCAGAGTTTCACAACATGTTAAGCGCACGCCGCAGAGTTCGTAAAGGTAAGTTTGGATCGAGGGTCACAAGATATTGCCGGGAGCGGCCAACCTGGCAAGACAGTTTCGTTGCCAGAGCCCATCTCGATAACCACGAGGATAGGGCGCTGTTGAAAGAGCTTACAGACGCTGTCCAGGAACAAAAGGATTACGCCGCCCGCCTAGTACAGAGAATCCCAGATCGTTTCCCCGGGCTCGAGGCTGTATCTGTGCCGGGGTCAACATTAAAATTATACTGGCAACACAAAAGCACATGGCCTAAGCAGTAAGGGCTCATGGGAATGATGGTCCATTCAGTTAATGATAGAACTGGCCGGTTCCAGGGGTCAAATATGGTCAAGTATGCGTACTCACTACTAATATAGATCTAGACTGTGATTTTGTGTCTA
->AB726205.1 Uncultured fungus gene for 18S rRNA, partial sequence, clone: a70-1 
-AGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAATTTCGGGATCAATTTATCGGTCGTGCCTATGGTATGAACTGGTACAATTGGTTTCTCCCTTCTGACGAAGCATGATGTCATTAATTTGGTGTCGTGGGGAATCAGGACTGTTACTTTGAAAAAATTAAAGTGTTTAAAGCAAGCATTAGCTTGAATACATTAGCATGGAATAATGTAATAGGACGTTTGATCCTATTTCGTTGGTTTCTAGGATCGACGTAATGATTAATAGGGATAGTTGGGGGCATTAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGATGATGTTAATTTTTTAATGACTCA
->KX928124.1 Williamsia sp. strain AC048_ELMA209 16S ribosomal RNA gene, partial sequence 
-GCTGTGGATTAGTGGCGAACGGGTGAGAACACGTGGGTGATCTGCCCCAAACTTTGGGATAAGCCTGGGAAACTGGGTCTAATACCGAATATGACCACTGGATGCATGTCTGGTGGTGGAAAGCTCCGGCGGTTTGGGATGGGCCCGCGGCCTATCAGCTTGTTGGTGGGGTAATGGCCTACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGCGACCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCGACGCCGCGTGAGGGATGACGGCCTTCGGGTTGTAAACCTCTTTCACCAGGGACGAAGCGAAAGTGACGGTACCTGGAGAAGAAGCACCGGCCAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCGAGCGTTGTCCGGAATTACTGGGCGTAAAGAGTTCGTAGGCGGTTTGTCGCGTCGTTCGTGAAAACTTGGGGCTTAACTCCAAGCGTGCGGGCGATACGGGCAGACTTGAGTACTACAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGTAGTAACTGACGCTGAGGAACGAAAGCGTGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGGTGGGTACTAGGTGTGGGTTCCTTTTCACGGGATCCGTGCCGTAGCTAACGCATTAAGTACCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGCGGAGCATGTGGATTAATTCGATGCAACGCGAAGAACCTTACCTGGGTTTGACATACACCAGAAAGCCATAGAGATATGGCCCCCCTTGTGGTTGGTGTACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAAC
->XM_023377893.1 PREDICTED: Centruroides sculpturatus glutamate receptor 2-like (LOC111633339), mRNA 
-TTATAAATCTATTCATGCCACAACGGAACTTCAAAGGCTAGCTACGAAATACGAAATTACACTGCTTTCTATTCAGAGATTTCCTTTGTCTGACTCAAAATCTCTCGATGTAACACCACAATTAAACGCCATTAAGGAAAAGGACGTGAGAATAATAATTCTTTATTGTGATATAACGATAAGTAAAACTGTTATAAAGCAAGCTGAACGCATGAACATGTTTCGTTCTGGATGGACCTGGCTCGTCATGGATAGCATTACATCGTTCAGTCTTAAATACTTATCGGACGATGACGGATATATACCATCTTCTTTAGTCGGATTAATAGGAACAGCATTTGTAGTTCCTGATACCATTTTGTATTTAAAATTAATGAATCAATTAAAAGCGAATAATTTGGAAAATCATATAGAAAATCAGCAAGCTATCACTCGTGTGTATGATGCAGTGTTAGCAATTGCCAACGGACTTCACAGAATTCTTTACGAAGAGAAAGTATCTTTCGAACTTCCTACTTTCCAAAAAGGAAGTTGCGCAGATTCTGTCAATGACTGGAAATGGGGTAGAAATTTGTTGGAAAGTATTCTTAATTTGAATAACGTTAATGGAAGTTTAGGGCCTATAAAGTTCACGAAATTTGGTTACCATCATCTCACCAGTTTTGACATCGAAAACCTTCAAACGAGAGGTTTCGTTAAAGTAGGAAAATGGTTAGGAAACGAAAAACACTTGACAATTAATTCAGAAATCATATTTCCTGGGCAAACTGTGAAACCTCCTGATGACTCTCATCACAGTCTTCACGGAAAAACTCTTAATATTGGAATAGTTATAGATGAGCCCTTTATAATGAAAATCCCTTATTATAAAGAAGGAGATCCTATACATTCTAAATACGAAGGATTACTTATAGACCTTCTTTTGAAATTACAAGAAATGCTTAACTTTAAATTTAAATTTCACGAAATAAAGGAATATGGAATTGAAAATCCCAAAACAAAAGAATGGAACGGATTAGTTAGACAATTAATGGATAAGAAAATAGATTTGGGCCTAGCTGCCTTCACGGTATCTTGGAAAAGACAAGAAGTTATCACCTTTACAGCTCCTTACTACGATTTAGGTTTGGCTATATTAATGCCAAAATATAATGCAAAAACTAAACAAAATTATTTTGCATTTTTATCACCTTTCGAAACAACAGTGTGGCTTACCATTGCTGTGTCGGTGATTTTTACTTCTCTAGTGCTTGCAATATGTGTAAATTTAACACCAAGTAATTTTAACAATAGAAGAAAGGAGATAAGGAAAACAAGTCAAAGCGTTAGAGATTCTTCTTGGATCACTTTTCCACAAGCACTTTGGTGGAGCTTCTCGTCGCTTGTAGCCCCGGGAACAGAATTTGAACAACAAAAGAATCTTCCGGCAAGAATTGTAATGGTGACATGGTGGCTAACTACGGTTATTCTTATTGCAGCATATACAGCAAAATTGGCAGCATTTATGACAGTCCAGAATATGAAACAAGAAATTAATTCTCTGGAAGATTTGGTGAAATTGAGTTCAATTTCATTTGGAAGTCTGAATGATTCTTATGTTGAGAACTTCTTCGCCAACAGTCACTGCGAAACGCATAAAATAGCTTACAAACTGATGAAAAATTATAATACATTCATAAACGATACTTTCGAAGGCGTAGAGAGAGTTAGAGCATCGTATTATTTGCCAGAGGGCCACAAGGATCGTTTTGCTCTTATTTCTGATTCACCACTTGTGGATTACGCTTCTATGCAGAGGCCATGCAATGTCGAACGAGTTGGAAGACTTTTTGGATTAGTAAATTATTTTTAA
->XR_004836665.1 PREDICTED: Folsomia candida uncharacterized LOC118438235 (LOC118438235), ncRNA 
-CTGAGAACAAGGCGATGGGGATGAGCAGCATAATACTGGCTTCGTCGGGGGCGAGGGTTTTAATTCTACGGTAAACTTGTACTTTCGTTTCGAGCACAGGGTTTGGAGTGAAGCCAAAACTTTCTTCGGGCTAAGGTCTGTCATGAAACTTTAAGCAACTGTCGGTTGCACCACAGTCGGAGAACAGAACAACAGCAACCATCAACATGATACTGGCTTCATCCGGAGCATTGGTCCGAATTCTTTTGTGAAGTTGCATTTGCATCTCTTTCACCCCGTCGGCACAATTACAGGCACATTCGCCACCCTGCACAGAAAAATACACATATTCAAAAAGTGTACACAGATTTCTGAAATTACATATGTAACTTCTTAGTGGAAAACCAAAATGTGTATAAATTTTGAACCAAATTAAAAATTTTGAGGATATTCATCATGTTATAACATGAAATGTATATATTTCACATTTATCTTGCGAATTAAAAATGGTGTAAAAATTATTAATATGCA
->XM_039871033.1 PREDICTED: Pteropus giganteus Scm like with four mbt domains 2 (SFMBT2), transcript variant X6, mRNA 
-CATATCTCCTTCTGCAGACTTCGACCAGTTGGTTGGTGTCAAGAGAATAAATACAGAATGGACCCACCTTCAGAAATCTATCCTTTGAAGATGGCCTCTGAATGGAAATGTGCTCTGGAAAAATCCCTTATTGATGCTGCAGAGTTTCCTCTTCCGGTGGAAGTGTTTAAGGATCATGCAGATTTGCGAAGCCACTTCTTCACAGTTGGGATGAAGCTCGAAACAGTGAACTTGAGCGAGCCCTTTTCTATCTGTCCTGCATCAGTGACCAAGGTTTTTAACAATCATTTTTTTCAAGTGACTATTGACGACCTGAGACGAGAACCTAGCAAACTCTCAATGCTCTGCCACGCGGATTCCTTGGGGATTTTGCCCGTGCAATGGTGCCTTAAAAACGGAGTCAATCTCACGCCTCCCAAAGGCTACCCTGGTCCGGACTTTGACTGGGCAGATTATCACAAGCAGCATGGAACAGAAGAAGCACCTCCCTTCTGCTTCAAAAACACGTCATTCAGTCGGGGTTTCACAAAGAACATGAAACTGGAAGCCGTGAACCCCAGGAATCCAGGAGAACTCTGCGTGGCCTCTGTCGTCAGCGTGAAGGGGAGGCTGATGTGGCTTCGCCTGGAAGGCCTGCAGACTCCCGCTCCGGAGTTTATCGTTGACGTCGAATCCATGGACATCTTCCCAGTGGGCTGGTGTGAGGCGAATTCTTACCCGTTGACCACACCGCACAAAACGGTCTCACAAAAGAAGAGAAAGATTGCAGTTGTACAACCAGAAAAACAGTTGCCATCCACAGTGCCTGATGAGAATATACCTCATGATCTTTACTTATTCCCTCACTTGGACAACACAGGTACTGTCAATGGGAAGTACTGCTGCCCTCAGCTGTTCATCAATCACAGGTGTTTCTCAGGGCCCTACCTGAACAAGGGGAGGATCGCAGAGCTGCCTCAGTCGGTGGGGCCAGGCAAATGTGTACTGGTGCTCAAAGAGGTTCTTAGCATGATAATCAATGCAGCTTACAAGCCTGGAAGGGTCTTGAGAGAACTGCAACTGGTGGAAGATCCACACTGGAATTTTCAGGAAGAGACACTGAAGGCAAAGTACAGAGGCAAAACGTACAGGGCCGTGGCCAAGATTGTACGCACGTCTGACCAGGTAGCAGACTTTTGCCGACGGGTTTGTGCCAAGCTGGAGTGCTGTCCAAACTTGTTCAGTCCTGTGCTGGTTTCTGAAAACTGCCCAGAAAACTGCTCCGTTCATACCAAAACCAAATACACCTATTACTACGGGAAGAGAAAGAAGATCATTAAGCCCCCAATCGGGGAAAGCAACGTTGAGAGCGGATGCCCGAAACCAGCCAGGCGTCGGAAACGGCGAAAATCCATTTTTGTGCAGAAGAAACGGAGGGCTTCTGCCGCAGACTTTGCCGCAGGCTCGGGGGAGGAGAGTGAGGAGGAGGAAGCGGATGCCGTGGACGATGACACAGGGAGCGAGGAGACCGGCTCCGAGCTCCGGGATGACCAGACGGACACCTCTTCGGCCGAGGTCCCCTCCGCCCGGCCCCGGAGGGCTGTCACCCTGAGGAGCAGCTCCGAGCCTGAGCGCCGCCCACCTGTGGACAGGGCACGACGGGGCCGTCGCGTGCAGGCCACCTCCTGTGCCGTGGGCGACAAGGGCCCGGCAGCCGGCCAGGACACGGCAGAGGAAATAAAACAGGAGGAGGAGGGGAGACTGGTTCTGGAGAGCAACCCGCTGGAGTGGACGGTGACTGACGTGGTGAGGTTCATTAAACTGACGGACTGCGCCCCCTTGGCCAAAATATTTCAGGAACAGGACATCGACGGGCAGGCGCTCCTACTGCTGACACTTCCCACCGTGCAGGAGTGCATGGAGCTGAAGCTGGGACCCGCCATCAAGCTGTGCCATCAGATCGAGAGAGTTAAAGTGGCTTTCTACGCCCAGTATGCCAACTGATTCTACCTTCAGGGGATGTGGCCCATTGTGTTGGTGATGCCGCGTCTTGGGAAGGTTTTCGGGACTGGAACTTTTATTTTTCTGGGTTATGAGAGATGGTTCATATACTGTTACTGAAAAGCAAGAAGCGTGAAGGACCTCCTTCACTTTCATCCACCAGCCTGTTTCATAGTTTCATGTTTTAAAGCTCATGCCAGGACCACAGCAGTGGCCTCTGGAGAGTGTAAATTAAAGTTCTGTGTCAGA
->XM_028176078.1 PREDICTED: Bombyx mandarina disheveled-associated activator of morphogenesis 1 (LOC114244323), transcript variant X2, mRNA 
-GGACGCGATGCCTGGGTCGCTCAAACGTACGATTCCGACGAATTGACGATTTTGGGCTGAATACAACGAGGACGCAGTGCTTTAAAAAACAAAACAAAAATTTTGACAGTTAAAATTACGCGCGTTTTTTAATCTGTGGACAGTGCTTTAATGGTATTTGTGGGAAAAGTGTGCATAGTTTTTCGGACAAATACTTCGGTTGTAAAATGATGATTGAAATCGAGTGATAGATGTAAAATGTGATAAAGTGAATAAATAGTTAATTGATAGCAACAAGACAGCAAAATGTGCAGCAAGGATCAGATCAATCACATACTCGGGAAGATCAATGTGGGTCTGCCGTCGTGGTCCCGCGGTGTGGAGGCGGTGGAGGCGGCCCGGACGCGTCTGGTGCGTTGGGCATGTGGCGACCCACCTATCGAGCCTGACCCGCCAAGGAAGAAGATGCCGCATGCGCTAAGACGGAGGTGGCCGCTCTGTCCTTGTTTACAGAATGACGAACCGCCCGAGATCACGTACTGCGTGGTGGGCGGCGAGGGAGGTCTCGCCCTCCAAGCGGTCACCCCCACGCATCCCATGCCCCCGGAAGATGAGCTGGACGCCAAGTTTGCGGAGCTGGTCGAGGAGTTGGACCTGACAGCAGTTAACAAGGCCGCGATGATGGCGCTACCGGCTGCCAAGAAATGGCAGATCTACTGCAGTCGTAGGCCGCCACCGGGCCAGGCGCCTCCACTGGCCACCGCACCACAAGTCGAGGAGTACATCAAGGCTCTTAACGAGATCGCTGATGCATTTGCGTCGTCTGAAGGCGTCCCCCCGACGGAATCCTGCGGCCTACTCGAGGGCCTGAAGACAGCGCTCAGGACGAGGGCTCACAGCTTCGTCCTCCGGTTTATCAAGCAAGGAGGACTCGGTGCCATATTGGACGCGTTGCAGAAGGCGCCCAGGGACGATGCTGTCACGAGACATAACCTTATAGCTGCCATAAAAGCCTTGATGAATAATTCGACTGGTCGTGCTCATGTATTAGCTCATCCCACGAGCATCGATCTGATCGCTCAGTCCTTGGACACGGAGAACGTGAAGACGAAAGTCGCAGCACTTGAGATACTCGGCGCTGTATGTCTTGTCCCCGGGGGACATAAAAAGGTGCTAGAAGCGATGGTCAACTTCCAAAAGTATTCCGGCGAGAGGGCCCGCTTCCAGAGCATCGTCAACGAGCTGGACCGCAGCACCGGCGCCTACAGGGACGACCTCGGCCTGAAAACGGCCATCATGTCGCTCGTCAACGCCGTGCTCAACTACGGGCCCGGCGAGGAGAGCCTCGAGTTCAGGCTCCATCTGAGATACGAGCTGCTCATGCTGGGGCTTCAACCAGTGATCGAAAAACTCCGCAAATACGAAAACGAGACGCTGGACCGGCACATCGAGTTCTTCGAGATGGTCCGCGGCGAGGACGAGCGCGAGCTGGCGCGGCGCTTCGACCGCGAGCACGTGGACACCAAGAGCGCCTCCGCCATGTTCGAGCTGCTGCGCCGCAAGCTGGGCCACTCCGCCGCCTACCCGCACCTGCTGTCCCTGCTGCAACACCTGCTGCTGCTGCCGCTGGAGTACGGCCCGCAGTCCCAGCACTGGCTGTTGCTGGACCGTGTGGTGCAGCAGGTGGTGCTGCAGCAGCCGGCGGCGGGGGCGCGCGCCGACAGCGAGCAGGGCAGCGAGGGCGGCAGCACCAGCGACCAGACCAGGATATACGATCCGGACGTGGCTCCCCTCGAGATAAACGTCGGCGAGATAGTGCATTTGCTCGCCAAGGAGGAAGAGCTCGTCGCCGCCAGGACCAAGGCCGAGAATCTGGAACGGGAGAACATCGACCTGGCCACAGAGCTGGCTAAGAAGTTGACCCAAGAGAGAACCGAGAGAGCGAGATTTGAAAAACTAGTCAGCGAGGGAAGCATACCTGATGATGCTAAGGTGAACAATCTGAAGAACGCGGTGATCGAAACGTCATCGGTACCTCCCCCTCCTCCGCCGCCGTCAATGTTCCCCGCGCCCCCCGCCGTGCCGGCTCCTCCCCCCGCGCCGCTCGCGCCTCTCGCCCCCCTGGCGCCGCTCGCCCCCGCCCCTCCCAAGCCCAAGAAGAACGTCCCCACTCCCGGGAACCCGCTCAAGAGCTTCAACTGGAGTAAATTACCTGATACCAAGCTGCACGGCACGATATGGCAGGAGCTGGACGACACGAAGCTGTACAACGCGATGGATCTGCACACCATCGACAAGATGTTCTGTGCCTACCAGAAGAATGGCGTCCAGAACGAGGGGTCCGTCGAGGACCTCCGCCAGCTCGGGTCGAAGCCCAGGACGAAGATACTGTCCGTGATAGACGGCCGCCGCGCCCAGAACTGCACCATCCTGCTGTCCAAACTTAAAATGACCGATGAGGAGATTTGCAGAGCGATCCTCAAAATGGACAGCGGCGAACAACTGCCCATCGATATGTTGGAGCAACTCCTGAAGTTCACGCCGAGCGCCGAGGAGGCCGCCATGCTAGAAGAGCACCAAGATGAACTGGACAGCATGGCGAGGGCGGATCGCTTCCTCTACGAGATCTCCAAGATCCCGCACTACTCGATGCGGGTGCGCACGCTGCTGTTCAAGAAGCGGTTCGCGGCGGCGAGTGCGGAGGCGAGCGGGCGCGCCACCACCGTGCTGCGCGCCGCGCGGGACATGACGCGCTCGCGCCGCCTGCGCGCGCTGCTCGAGCTGGTGCTGGCGCTCGGGAACTACATGAACAGGGGAGCCCGCGGCAACGCGTCAGGGTTCCGGCTCTCGTCACTGAACAAACTCGCCGACACCAAGTCCAGTGTTACAAGAAACACCACGCTCCTGCATTTCCTGGTCGAAATGTTGGAGACACAGTTCAAAGACATACTGCTGCTCGAGGAGGATTTACCGCACGTCCGAGCCGCGGCTAAGGTTTGCGTGGAACAACTGGAGAAGGATGTGGGTGCTTTGAGGAGTGGCCTCCGTGAAGTCGCGAAGGAGGTGGAGTACCACGCGTCGCTGCCCTCTCCGCAGCCCGGTGACGCCTTCCTACCAGTCATGAGGGAGTTCCATGCGCATGCTGTTTGTACCTTCACACAACTGGAAGATCTTTTCCAGGACATGAAGAGTCGTCTCGAAGCATGCGCCCACGCCTTCGGTGAAGAGACAAGTGCGTCCCCGGAGCAACTGTTCGGCGCCATGGACGCGTTCCTCACGCAGCTCGCGGAGGCGCGCGCCGAGTGCGACGCCATCAGGAGGCGCCGCGACGACGAGCAGCGCCGGACCAGGCACGAGCAAGAGTTGAAAAAGCGTACAATGGAACGTAAGCAATCAAACTCGCTAGGCTCGGTGAGCAAATCCCTAGCGAAATCCAACGGGGATTGCAACGGACACTCCAACGATAGCTCCCGGGACGGCACCATGAGTAACGGACAAAAAGGAGAGTTCGATGACCTTATATCCGCATTACGAACAGGAGATGTCTTCGGAGATGACGTGGCCAAATTCAAAAGATCAAGAAAGACTTCCAAAGTCACTCAGAAGGGTCGCGACTCTCCTCCCAGGGGCGTGTGCAGGGAAGACTCTAGGGAGAGACAGAAGAATTGAGATTGACAGCAGTTATTGATGTGTCAAAGAACGTGAGTACGGCTCTATGCGTGAACGTTGCTTGTAAGTACAGAAATTTGTTACACCAACTTTTCTGTTACTAGAATCGACCACATGTTTGTCAATATTTCGAAATACCCTCAAATAAATAATTAGGCATTAAACTGTAAGTTTTGAAATAGTATACATGTACTTATTCGTCGATGCTAATTAAAGTTTGGGAACGGAGAGCCGATGACCGTCATACGTCGGAATATCGATTAGAATGACTGCTTTAAAATAATCGATTAGTATAATTGTAACAAGTGATATTTTCGAAGTAGATTAGTTTGGACGGTGATGGTGTGTACGTCACAAAATATTTAGAGATTTATACAGAATAAAAGATAGGACGTTTAATGTGCTAAATACCAATTAATTAGCGTGATCGCTTATATATTAAATCGATTAATAAATAATCGATATTAAATCGACTAATAAATAATCGATATTAAATCGATTAATATATAGCAGAGTTAATTTAATTGTTACACAAATGTATTAACTATAGACGATGGAATAATTTTAAACGAAGTCAGCATTAACTATTAATTTAGACCTTAAATTGCAGTGGATAAGGACTGATCTGTGATTTCACAAATTGTTTACCTTGTGTCTGTTTTTAATTATCACAGGTATATGTTTGCGGCTTGGTCTTAATTAATTAATTTCATAATAAGTAGCGTTTTGCCTTTAATACTTTGTAATTTTTGTATGCATTTTACCACGTATTTTAGTGGTGTTTTTTGGTACTAAAATAAAGTATTTTGAAGAGTATTTTTTTTGTAATAATTTTTGCAAAAATTGAAATAATTGTAGATTGAGATACAGTTTCAATGTTTTGTATTTTTTCGTAACGACTGAAGTAGTGAAAAGGCTGCAAATAAATGATTCCGTAAACAATTTTTTTTGATAGTCTTAATCTTACTATAGAGCTATATGTGTTTGTATTATCTATGTACGTAGTATTTAGATACTGTATTTAATGCGTTCGATTTGACACCGTACCCGGTGTTGCCAACACACAAAAACAAACCTAACATATCCCCGTTAGG
->XM_042445786.1 PREDICTED: Sceloporus undulatus transmembrane protein 258 (TMEM258), mRNA 
-GAGAGAGGAGGCGAGAGGGGACTTTCATTCTGGCCTGGACAGGAAGTTCCCGGATGGATTTCCGGCGTCTCCGCCGAGGAAGAGACGTGTCCCTGCGTGGCCTGGGAGGAGGAAGAGGAGCCTGAGCTGACTAGAGAAGGGGCCAGGGAGCAAGATGGAGCTTGAGACGATGAGCAGATACACCAGCCCAGTGAACCCGGCTGTGTTTCCACATCTGACCGTGGTGCTCTTGGCCATTGGCATGTTCTTCACTGCCTGGTTCTTCGTTTATGAAGTGACCTCTACTAAATATACTCGGGATATTTACAAGGAACTGCTCATTTCCCTGGTGGCTTCACTTTTTATGGGCTTTGGAGTACTCTTCTTACTGCTCTGGGTTGGAATCTATGTTTGACAATAAGCCAAGAGCTGTTTCAGGTTCCAGAAGAATTGCTGAAGTTTCTTTTTTATTTTTGTACTTAATGTAGCTCATCACACCTGTAGTCTGTGTAAATCCTGACACATTGTTACAGCCCAGAATATCGTAACATCAGATGAATAAAGCTGACTGTGATGACATGAA
->XM_024284361.2 PREDICTED: Oryzias melastigma peptide Y (LOC112153899), mRNA 
-TCTCTCTTCCTGATAATGTAATCAACCGCGCGCGCGCGTCAGGTGTCCGTGGCTCTATAAAAGCCTCAGATCCGCGAGGAGAGGAAGAAGAATCCACGGAGACACCAGTCCAGCTGACGATGGCCAGAATCCTGAGGTCGTGGGCGATGCTCGCCGCGCTCGTGCTCTGCCTGCTCGTGTGTCTGAGCAGCCTGGCGGACGCCTACCCGCCCAAACCGGAGAGTCCCGGGAGCAACGCGTCACCGAAGGACTGGGAGAACTACCAGGCGGCGGTCCGGCATTATGTCAACCTCATCACCAGGCAGAGGTACGGGAAGAGATCCTCCCCTGAGCAGGCCGCGGCTTGGCTGCTGTTTGGGGCGGATTCAAGTCAAGATGCTGAGCCCCGGTCTGACTACGTTGAACCGTGGTAAATGAGCTCAACTCTACCCTGCACTACTGGACAAGTCCTCTAGATTTGATTATTTAATGAGCATGCAAATTTCTTTCTCTCTCATCCTGTTTGTCTGCTGCTGTCAGTAAATGTTTGTCCTTTTCTCAAAATTTGTAAATAAATTCTTGTATGTAAAATAATCTCTTTACAATAAAGATTTAAGTGGA
->XM_004989695.1 Salpingoeca rosetta mitotic checkpoint protein BUB3 (PTSG_08955), mRNA 
-CGTTAATAACCGCCAGTGCCAAAAAGGAAAGGAAGCACAGAAGACCGTGAGGAAGCACAAGCACACGACACCACACCACACCACACCACCGCACGCACACCGACACACCACACCACTCGCCAACATGACGGACACTGAGCTTGTGTCGCCACCCCAGGATGGCATCTCCTCTGTTGTGTTTTCTCCGACCAGCAACTTGCTTCTCGTTGCTTCCTGGGACAAGACGTGCCGGCTTTACGACGTGGACTCCAACACGCTCAAGTTCACGTTTTCGCACGATGCACCGGTGCTGGACTGCGCCTTCCTCGACGACACAACAGCTTTTGGTGCGGGGATTGACAAACAGCTGCACAAGTACGACTTGACGACTGGCAAGAGCTCCGTTGTCGGGTCGCACAGCGAGGCCATCAAGTGTGTGGAGTGCTCGATCAAGCACGGCGTGGTCATAACCGGCAGCTGGGACAAGACCATCAAGCTGTGGAATCTCGAGTCCCTCGAGTGCGTCGGCGAATACGCCCAGCCAGACAAGGTGTACACGATGGCGTTGGCTGATGACCGCGTGATCGTCGGCATGGCTGGTCGACACGTGTGGGTGTGGAACCTCAACAATATGAGTGCGGTGGAGCAGCGACGAGAGTCGAGTGTGAAATTCCAGACCCGGTGCATCCGTGCAATGCCGGACGCCCAAGGGTATGTGCTCGCGTCGATTGAGGGCCGTGTTGCTGTGGACTATCTCGACCCGTCTGAATCGTCGCAGAAGCGCAAGTTTGCGTTCAAGTGCCACCGCTCGAAGGAGAACGGGCGTGATGTCATCTACCCGGTCAACGCCGTCGCCTTCCACCCAACCTTTGGCACGTTTGCGACGGGCGGGTGCGATGGGCTCGTGAACGTGTGGGACGGCGTCAACAGGAAGCGCGTGTACCAGTTCCACGAGTACCCGACGAGCATTGCGTCGCTGTCGTTCAACCACGACGGGTCGCTGCTCGCCATTGCCGCATCGTACACATATGAGGAGGGCGACAAGCCCCACCCGCCCGACGCCATCTTCATTCGTCGAATCACGGAGGAGAACGTCAAGCCAAAGCCACGCTCATAGACACACACGCGCGCACGCACACACACACGCACACGCACACGCACACGCACACGCACGCACACTCAAATCAACACACGCACCATATGTTCCACGTTTTTTTCTGGTGTTGTTTCTTCACTGACTAACAATACAATCACGTTTCGTTTCAAACAAATGAACAAGAAACAAGCAATAGC
->XM_002366755.1 Toxoplasma gondii ME49 hypothetical protein partial mRNA 
-ATGTTCCATCTAGCCTGGGTTGTCAGTCGAGAGATCCCCTTCTGTTTCGTCTCAAGCGTCTCAGCTACTTTGCCTCTCGCTCTGTTGCCTGTAAAAACGCTTTGTCAGAAACGATCTCTTCAGATGCAGAAGGAAGTTGAACAGAGAGGCTTGCTCCGTCTTGAGCAGTCACGTCTCATCCAAAAGGTCAAAGAGGAAAGCCAACTCATGGAGGAGTACGTGGTCGAAATCGACCGGCTAAACAACGTCATCAACGTCCTTGAGAAAGAAATGCTCAACACCAAGAGGGTGTATCAAACAGCGATTGAGTCGCGAAATCTCACTGGCATTCAGCTGATTGACAGGCAAGCGCAAGACAAGGACACAGAAAAGAAAAGCCAGCGCGCCCTCCACGAGAAAGAGCAGGATGTCAACACGCTCCGGCTTCAACTGCAAGAAGTCGAAAGGCAACTGCTTTCGAAAAAGAGAAGGGCGAAAGAGGTGCCCATTTTGACGGCGGAAGTCGAGAACTTGAAGACGCAACTTCAGGAAGAAAAACAACTGGCAGAAAACATCAGTCGCAAACTAGAAAACCCAACTGAGGGCAGACAGTGGCAAGAACTTGGAGGGGAAGATCCAGATATGGAAACATTGGAGGCGAAATATCGGGTGATTGAGCAACGTTTCAGAAGTGTAAAGAGCGAGCTCATTGATCAAGACTTGCGCCTTGAAGACTTAACGGAGTTGACAGAAAAACAGAAAGCGAGAGCCGCAGAAGAGCACTCGGACGCGATTCGAATTCGCAGCGAAATTCTTAGACTCCACGGCAAACTGATCGAAATGAACCGGCGCATGAAGGTGACGATGTCTGAGTTGACGCTCTACAAGGAGTATTTGCCGAGACTTAAGCAGCTTCAGGCAGAAATAGCACAGAGCGTGGAGAACGCCCGTGAAAATGTCTTCTTCGGTAGACCTGCTACACCAAACGCAGAGGAAGAACTTGCCGATATGCTCAAGAGAGAGGTGGCTAGAAATCAGATCCTCTACGCAGCTAAATTGCGCACTCTCGAAGAGCAGCGTGAGGTAACAACATTACGGTAA
->MW050496.1 Uncultured Ascomycota clone OTU1949 5.8S ribosomal RNA gene, partial sequence; internal transcribed spacer 2, complete sequence; and large subunit ribosomal RNA gene, partial sequence 
-GAAATGCGATAAGTAGTGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCCTTGGTATTCCATGGGGCATGCCTGTTCGAGCGTCATTTGTACCCTCAAGCTCTGCTTGGTGTTGGGTGTTTGTCCTCTCCTTTGCGATTGGACTCGCCTTAAAATAATTGGCAGCCAGTGTTTTGGTATTGAAGCGCAGCACAATTTGCGATTCTATCCGGTAATACTGGCGTCCATAAGCCTATTTTACACTTTTGACCTCGGATCAGGTAGGGATACCCGCTGAACTTAA
->XM_053179842.1 Colletotrichum chrysophilum uncharacterized protein (COL26b_007034), partial mRNA 
-ATGGAGCCAGAAGGCCCATTGAATGATGAGGACTCGGATGAAGACTGGTTCTGTGGATCACCCGCATTCCCAAACCAGTATGCCTGTATCACTCTTCGCGGTGGCTCTTGGAATGGTCCTCCGGAGTGGGAAATCCCTGACGATGGCGAAGGGCCGGTTTTTGAGGGACCGGGAAGTACTCCCAGTCTCTCCATTCTGGAAAACCCAGCCTCGCCGCCCACAAATATGCAAGAAGGCATCGCGTCTGGCTGCAACCGCTACGTCCAGGCCAACATCACGATTGCCTCATGTTGGAAGATTACCAATGATGGCGGCACCTTGCAAGCACGCTTGTTCGAGGTCGACCTCGTTGTCGGCAAGCCGGGCGAGCGCTGCGATACGCAGGTGTGGCTTGGCTACTAA
->XM_012089747.1 PREDICTED: Cercocebus atys germinal center-associated, signaling and motility-like (GCSAML), mRNA 
-AGATGCAACGTCCTGCCTCATGCATTTTCCTCTTGGTGCTTTGGTCAGAACTTCCCCAAGTGGAGTGAAACTCAGGAGCTGAGAAACCGAGTCACTGTGAAAAGATGGGAAATTATCTCCTGCGAAAACTCAGTTGCCTGGGAGAGAATCAAAAGAAGTCCAGGAACGGAAACCCAGATGAGGAAAGAAAACGGCAGGAAATGACTACATTTGAAAGAAAACTTCAAGATCAAGATAAGAAAAGCAAAGAAGTTTCATCCATTTCTAATCAGGAAAACGAGAATGGCAGTGGTTCTGAAGAAGTGTGCTACACTGTCATTAATCACATCCCCCATCGGAGATCTTCCCTGAGCTCCAATGATGATGGCTATGAGAACATTGACTCCCTCACAAGGAAAGTGAGAGAATTTAGAGAAAGGTCAGAGACAGAATATGCCCTTCTTAGGACTTCTGTTAGTAGGCCTTATTCCTGCACCCATGAGCATGATTACGAAGTTGTGCTTCCACACTAAAACCCTCAAGCCGCTTTATCACCTTGTAGCAATGAAGATGATGCAGAACAGCAGACTCTGGAGAAGTTCTTCACCCTGAGCAGTGCATGAAACATTCCTTTCTGGCTAAAGTTTAGAAATATTATCTTATTATATATCCTTAGGCAACTCTGAAATGTGGCATCTCTGTGGTTTAGGTGGAATCATAGAAATTGAAACAATGATCTAAAATATTCTATGTGTTTTTGCTTGCAAAGTTTGAGGACATGGAGGTGATAAAAAAACTTTCTTAGGACAATAATGTAAAATGAAAATAAATTCCTAATCCCCCTGACTAACTGAATGGACCACCTTCTGGGCCAAGGAGACCTCAGATGATCTTGAAAGACTGAATTCTGGCCATGATAGGAAGGGAGATGAGACACACCTTGTTATACCCCTTCCCTTTTGGAGTTTAGGCACAAGTGACCAGGATGAGTCATAAGACTGATGAAACAGACTGATTGTGGCAATAAGAGTCCAAATTCCTACCTGACTCTGGTGTAGATCACACGCTGTCTGAGGGGTTCCATCTATGAGACTTTGTCTACATAACAAAGACCTTGGTTTCCACAACCCCTTTATTTTAGCTAAAGCATTCTTCTCTACTGACTTCTTAAGTCTTTAGACAAAGCTTAACTCTTTCAACCAATTGCCAATCAGAAAATATTTGAATCTACCTATGACCTGTAAACTCTCTCCTGCTTCAAGATCTTGCCTCTTTAAGCTGAACCAATGTGCACTTTCCATGTATTGATTTGTGTCTTTGCTTGTAACTCCTGTCTCCCTAAAATGTATAAAACTAAACGGTAACCTGACCACCTCAGGCACACTTTCTCAGGACCTCCTGAGAGTGTACCCCAGGCCATGGTAACTCATATTGGCTCAGAATCAACCTCTTTAAATATTTTACAGAATTTGGCTTTTGGTTACCAATAAATCTCCACAAATAAATGTCCAAGAATCTTCAATTCCAACCCTGCTCACCAAAGTTCAAATGCCAACATCTCCCCATCCAATTACCTATTTCATTTTTGAGGTGTAATCTACTCAATAAACTGTATAAGACCAGTGACCAGACCCTTTGCTAACCTGATATTTACTTCAATTTTTCTTTTTCTGTGTACTGGAGATTTTTGCTTATAAACTTACAGTAATAGTTCAGAAATTAATAGTTTTTGACATTGGCTTTTCTGAGAAGAAAATTGAAAGTGTCACAAAATAAAAAAAAAAGATGAAATGAATCATATATAATTGTCCATTTTTTCAATTTTCTAGCCAGTAGAGGATTGAAGGATTCTGTTTAAAGATTAGTAAAAATTGAAAATAAACTTGTGCTTATACTTTGTGTGCAACACACTAGTTAATTTAACCTGTGACTAGTTATCTCTACTGAAGGTGGATGTATAGTTTCTGGTTTTAAAATTCAAGCAAACTGGAAAATGATCCATCTAATTATACTTTCTTTCCCAAGAAATTTTTAAATGATATGCCAGCTTCCTAATTTGGAGATAAAAGCCTTAATTGACAATGCATTTATGATATATATTTTTTGTATAGTTACAGTATACAAGTTGAATATCCCTTAGATAGATGCTTGAGAGCAGAAGTGTTTTGGATTTAAGATTTATTTTTGGATTTTGGAATATATCCATACACATAATGAGGGAGTTGGAAGATGGGATTCAAGTCTAATCATAAAATTCACTGACAGACTGGATTAAGAAAATATGACACATATACACCATGGAATACTATGCAGCCATAAAAAAGGATGAG
->XM_028615259.1 Sodiomyces alkalinus F11 hypothetical protein (SODALDRAFT_392700), partial mRNA 
-ATGATGGGAATGCACCCAAGCCACGAACTATCCGCCATCGAGGAAGTTCTCTCAGATGAAGATGAAGATGATAACAACAAGAAGCTGAATGATGTTGACCATGAAGTCTCGGACCAACCGTACCCTGCCCTTGGTTCGGGTCCCATCGCCGAAGAGAGTCAGAATGGCCAACAATTTCCGCCGGAATCTGCTGAACATGACACGAAAGACTCCCACCGCTCGCAACAGGTAGATGCTCAGCATAGCCCTGATGCGAACACGGTTGGCTTGGCCATCTCGGAGCACGAGGACGGCCAAGTTAACCAGTCTGGTTTCTTTGGCTATGTCCAACGGAACGACGAGGGGCACTATGCTAATGCCCATGATACCTCCGATGGGGATTCGTATGATCCGATGGACCTTGCTCCGCTTCAAGACATGGTCCGTAGCGTTCCCAGCTCGGGGGGCTGGGAGCCCGAGGAGCAATATGAAGCCAAGGCTCTTGAGGGTCTTCAACGGGAAGAAGAGGTTGTCCATACTCGAAAACCAGTCCGTTCAGCCTCCCTGGAAGAATTATATAAACTTACTACCGAGGGGTGGCTGGATGCCAACGAAGGATCGAACGGTTGGTATCCTATCAATGGCCGTGATGATCCAGAGGGAGACGAGGTTGTTCATGCGAATCAACCCACCCGTCCAGCCTCCCTGGAAGAGCTATACCGGTTCACCACAGAGCAGTGGCTAGATGCCAATGGAGAAGAGGACGGCTGGTATCCTATCAATGGCAGTGGCCGTTTATCGGACCCTCCGGCGTCCGAGTCTCGTCAAGATGACAGCCCAGTTAACTTCGACCTATTTCACGCGGTGGTTAATTATGTTCCTCCTTACTTCACTACCAATTACCAAGGGAGACAGGCCGGAGACCGTACTGGTCAGCCTGAGGCCACTGGCGGTGCTGTCTATTCCCCGAACACCCGTGACTGGGCCGATTATGGAAGCGCTCTCGTCGACTACGCCCCTGAGACGGCGATTCCCAAGGTTCCTGGTTGCACAGCTGGCCAGCATCATGCCCAGAATTGGACCTTCGGTGCTTCTGCCTTCATAGCATATGCTGCCATGCGTGGTTCGGGCATGGATACGGGCAACCCGCTCCAGACCTGGATGGGGGTTAAGGGTATAGAGCGTCACGGCCATGACCACGACCTCGACTACGACCACAACAACTCCCGGGCCACGGACTCGAAGGCCGACGACTTCAAATTCAAGCAACTAAGAAGTTTCACCGCCGAGGTTGAAGTGGCCCTTTGGGAAAGACCCTTGGTCATTGATGAGAACCGTCAGCAGCGAGTTGAGATCCCCCGACCCAAATACAAGCACCTGAACCCTCCCGAGGGGTTTGAATATCCCCATCACCTCGCGTCGTCGATCAACGGCATCGCCGCGGATAGCTGGGAGAGAGCGAAGACTTTCGAAGAGGAGTACGATATCTCGGATGACGAAGGATCGCCTCCCTCTGGTCGTATATCACCTTGCACATTCCGCGTCCTGGCCGAGGGTTGCAAGCGCTGGGAAGACCCGGCCAAGGACCACAGAGTCGAGATGCCCCCTGAAACGAAACGACTTCGACCTGAGACTCCTCCCCCGACAGACATGCCGACATATCATCGCAACCGTATGGGCCACAAACGCACCTTGCAGCAAGACGTGGAAGACGGTAGCTGGCTCTCTCCCATCTACTCTGTGACTGAAGACCCGAGTATCATCTACACGCCTCCCGGAACCCAACGTCATCCGACAAACTTTGCCATATGTAACTGGCAAGACAACGTCCACGAGGTCATGGACCCTCTTGGCGCCCAACATCTGCGTGAATTCCAGCCCACCAGCCATATCGCCCCTAAAATCACCACGCCCAACGACCTGGCCCCGGCCCGCATAGCCTCAGCACACACCGCCGCGACGCGAAGCTCAGAGAACCGGCCCTACACAGCAGCAGAAGTGCAAGCAGCCCTGCTCTCCCCGCAAGCGCGACCGCTAGTAGACGGCAGCATAGCGCCCGAACACGCAGCGGCGGTGCTCGGAGCCCACTGGCAATGGGCATGCCAGATGCGCGACGCCGCGGCGCAGCAGTCACAGCGCAACGAAGAAGCGCGGCAGCGCATCAATTCTCTGCGCGACGAGCTGCGCGACATGGAACTCTGCGTCGACCACGTCCTGCAGAGGCGCGAGGAGGAGGAAGAAGAGGTGGTGGAGGAGGAGGACCAGCGCCGCGTCGAGCGCCGGAACCGCCGCATCATACGCCAGGTCAGCGCACACCTCCGCGAGGTCGCGTACGAGGTCCACCGTCGTAGGGAGCAGCTCTGCGTTGTCCTCGGCGAGGCGGCGCAGCTGGAGTGCGAGGAGCAGGTCCTTACTGCCGATGTCCGGGCTGAGATTGCGCGGTCTGGTCTTCCCGATGCTGATGCCGTTCGTGCGGAGGCTGGGCGGGAGTTTCTTGAGCTTGCAGGAACTACGTGA
->XM_017399093.1 PREDICTED: Daucus carota subsp. sativus histone deacetylase HDT1-like (LOC108224459), transcript variant X2, mRNA 
-CGAAATTATAGTGGTCCGCGATACACAGTATCCTCACCCCCTTCCTATATAAACATATGCATTCTTCATCTTCTCCGTTAATTAGCCCTAGCTTTTACTCGAAAAATTACTCGAATTAGCATCAACACAGCTGCAATGGAGTTTTGGGCTGCTGAGGTCAAAGCTGGAGAATCTTTCAAGGTGAAAATTGATGAAAATAAGGCGTTGCATCTCTCACAGGCTTGTATTGGTGATGTCGAGAAGGACATTCCTGTGTCCATTTGTCTCTATGTGAAAGTCGATGAGAAAAAGCTTGCCCTTGGAACACTTAACTCTAAAAAGTTATTTCAGCAGAGCTTTGACTTGGTGTTTGATAAGACATTCGAGATATCCCACAACTGGAAAAATGGAAGTATATTCTTCCTTGGATATACAGCTGATAATGAAAAATCTGATCGAGCTTCAGATGTGGATGATTCTGATGCTGAATCGGATGAAGATATCCCAGTTATTGCTGCAAATGATAAACAAAAGGATAAAGAAAAGGCGAAGATTGTAGAACCCAGAAAAGCTGCGAGTTCAGATACTACTGATGACTCTAGTGAAGATGATGAAACTTCAAGTGAGGATGACCCGAAGGTTAGTGTTAAGAAAGATTCTGCTGCTGGAAAACAGAAGGCGAATATTGTAGAACCCACAAAAGATGTGAGTTCAGATGATACTGATGACTCTAGTGATGATGATGAAACTTCAAGTGAGGATGACACGAAGGTTAGTGCTGAGAAGGTTTCTGCTGCTGGGAAACAGAAGGCGAAGATTGTAGATCCTAAAAATGATGCCGACTCCGGTGATGATGATGCAATGTCTGAGGATTATTCAGAGGAAGCTGATGAGTCAGATGAAGATAGTGACAGTGATGAGGATGAAGAGACACCAGTGCAAGTTAAATCTAGCAAGAAAAGAGCTCTGACGCCTGCTAAAAAAGCTCTCCCCGAAAAGAAAGCTAAATTGATTACTCCTCCAAAAACTGATGGCAAGAAGAGCAGTGTCCATGTGGCTACACCCTATCCTTCAAAACAGACTGGAAAAACTCCTGCTAATAAGCTGAACCAGCAGACTCCCAAGACTGACGGGTCTCATACTTGCAACTCCTGTAAGAGGACATTCAAATCGGAGGTTGCTCTGGAATCTCACAACAAAGCAAAACATACTGGTGGAAAGTAAATAGGATGCGAACATTGATTTTTGGTGATGTACTTTAGAATTGCGATGAACTAGGTATATGGTAGGCTTTTGGTTGTTTGTGGTGAAGTAGTTTGTTTCCTTGTCTCTTCAAGTTGTTTTCAATTGGATGCTGTGCCTCTGTAACTGAAGAAACTTGGAGGGTATGGAATTTGAAAGACTATGTTTGATGTTTCTTGTTTGTCTTTTTA
->XM_009911451.1 PREDICTED: Picoides pubescens F-box only protein 15-like (LOC104310052), mRNA 
-ATGGACTTGCTCAGAAATCCTCTGCCATGTGAAAACAAAGAAGCCATGAGAGCTGCTGGCTTGAGCTGGATGCTTGTCCTGAAAGAGAAGNNAAAGGAACACCTAAAGGAGAAGAGAAAAGTATCATTTCAGGATGCATTTCTTAACATATTTTGGTATGGTATCAACTGGCCATGTCTGGATGTCCTCGCAACACTCAGGCTCTATGGAGTTGCGCCTTTATTTCCTTAGAGCAGGAAGGGACCTCGCTACCATTCCCTGGTTGCTGAATACCATCTTGCTGATCTGACAGCACCTGGTGCTGACAACATTCTCCAGCTCTTCACTCTGAAGCCAGGACTCTTAGTAGGCCTTTGGAAGGACACAAAGGAGATCGCTTCTGTCTCAGCCAGTCTTCATTATCATCAGTTCATGGAGAGAAGCATCTTGGGTTCTGCTGCTTCTTCTTATGCCCGTCCACTTCATCAGCCTCTACTGGGTGATACTGACCCAGAGTATGGACTGCATGGCTACTGTCTACACTTTGAAATCCACAATGGAACCTGTGCCTACATGTGTGCAACATTCAGGGACCTCTTCTGCAAAAAAGGTGAGATTGCAGATGGGTATGTGAGGCTCACAGCTGTCAGCAGCCTGCAGGACAACATGGACCACTGTCTTTTAGCCACCATGCCTGGCTTGCCCTGTCAGCTGGAAGGCACTGTGAAGGAGTGCTGTGTGCTGGATGTTACTCTCTTGTATGAAGACGGAAAAGCCTTCTGTTGTTTCAGTGGCCCAGTCTCTGTGGGACTGTCTTCCAGGACTTCAAGCTGTTATGACTTGCTGGGTCACAGCTCCAGCAGAGAGTATTGTGAACCTTCAGAAGGCGGAGTCCGTGCTCGGTTCACCTGTGTGAGTGAAAGCAGGCAGCACCTTGGAGTCGTCTTTGCTGTCTGTCCACCTAACTCGTGA
->XM_019704704.3 PREDICTED: Aedes albopictus 60S ribosomal protein L29 (LOC109428867), mRNA 
-ATGGCCAAGTCCAAGAACCACACTAATACACACAACCAGAACCAAAAGGCCCACAAGAATGGGATCACCAAGCCANAGCGCCAGCGTAACGAATCGACCCGCGGTATGTGCCAGAAGTTCCTGCACAACCTGCGATTCTCCAAGAAGGGAAACCTGTCCCGTGAAGAATCCCTGAAGCGCGCCGAGGAACGCAAGGCCAAGTTTGCCGGACAGCCAGCTCCGGTCAAGCTGTAAACTGCTTCCTTCTCGATTCCGCTTCGGATGATGATGATGATGGTTGGGTGGTGTATCCGTTTTGATCCGTGATCAACATCAATTCCTAATCTGGTACGCGTTACGATATCCAATGATACCGTGCAGTTGATGAGTACAAGTGAGTTCAATGCGGAATGAAAATTCAGTTGGA
->XR_007260822.1 PREDICTED: Pyrus x bretschneideri uncharacterized LOC103942768 (LOC103942768), ncRNA 
-CAATTATGGAGGCCAGAGAGAGAGGGGGTGCGGCATAGAGAGAGAAGAGATAAATGTGTAATTGTGAGATAGACGGTTCTATGCTCACATAATTTTCTGCTTGGTTCTTCAGATACCTTCCGTGCAACATTTGATGTGGTATGGTTTTCCAATTTCCCCTTTGCAACAATTTCTTTTTGGTTTTTGGAGTATGTATGATTTATTTTTAATTAGAGAAGAAAAATTAATAAAACACAAGAAGCAATTGGAAACATGGCTGCAAGTGATAAGCCAGAGTCTTTTTTTTCAATTAACTATATTACTTTTGTAGTATATGCATGCGCAGGAAAAATCCAAATCGTACTACAAGATCTTAGGGCTCTGTATTTTGTGTCAAACCAATGCATTGAGAGAATATGAACTATTGCGTCTGGTTTGGATATGTGTCTATGGTGGTACCCCTATTTCAAGGCAACTGAGAGCGCTTGACTATGGTAACCCAATGGCTTTCTTTGTTGTTTTTCCTTAAGAGGTTATCGATTCCTTACTTTTTTAACTGAGTTTTTGACTATCAATATTTTGCATTTCTGAGCTTAAAGGCACAAAATGATTATTTGTTATTGGGTAGATGGGTTGCTAAAGGCAAGCAAGACACATAAAAATGACCATTGGGAACGAAAAGTCGCTTCTTCGGTGTATTTATACTTTTTTTAGTTGTATCATGCGAAATTAAGTATCGATTTGCTATGTGTATTTTGTTGAAGTTATGTTTTGATGAGCTTGGATTCCTGAAACGTTTGATACTAAAATGACATGAATAAGCATAATGAATGGTTTGAAAGATGCTATTAATGGTTTTGCGAGTATATCGTTAGTCGTTTGGTTGTATGATTTGTTTTTGTTTTTTCTTTCAAAGCACTTTGCTCTTAATTTTTTGGGGCTGCAGCTTTCGAAGCCCTTTATGCTCAAGGTAAACAATTTTGGATTTCAGCCTTCCAACAATTTTTTTATTTATTTGAATATTGTGAAAGTTGTGTTTTATATGCTATGAAAGTTGAATCTGTGAATTTTTTTTTTTTTAATTCATGGTATATATTCTATTTCATAGTTTTGGATGATGTTGGATTGAAAAGCTTTTCTATAGAACTTATAGTTATTTAAAGTGTTTTATCCATTCTTACATTTACTCTCATAAATTATAGCTGATTTGTTAATCTCTTACCAAAATACGCAAATTATTTTGTAAATTTGTTCTTATTCTAGCAGGAACAACAAATGCAGAAGGGGAACACATATATAATCAGTGTTATTCTAGCCAAAACCTTTATTCTCACAACATTGGGTACGATTGTTATAAGTTTCAATTCATTGTACCTAAATTGAAACAATTTACTATTAGCACAAACTTTTTTATATTTTAAACATGATATTTCATGCATTTTCTAATCCTGCAGCAACGTGCGGGTAGTACTTTCTAATATCTTCTATACATCAAATACATTTCCTTGGCTCCA
->XM_022304284.1 PREDICTED: Myzus persicae uncharacterized LOC111026242 (LOC111026242), transcript variant X2, mRNA 
-ATTTCAAATTTTTCTATATAGTATGAATACAGAATATATGATAATATTTAGGAATAAAATTACCTATGTCCTATATTAATATAAACATATTTAAGTACAAATCAAAGTATAAACGCATGTCGTTAAGTTAAATAAGGGTTTAATTTGGTTTATCTGCTGATATTATTTTTTTTACTAAGTATTTTATTCTAATTTCTGTGTATCATGTCGTCAGTAAAGGAAGTTTTCAAAATAAGTTTTCAATTTTTGGCTCAACAAACAGATAATGTTATCAAGGATTTCTTGAGGCTCACCAAAGATTTTATGGACAACGGACCTAATTCCAGTCTTTATAACAAAGCTGCAGAAAAAATGCAGGTTGATGAGGACAAAATAATATCAGTTGTAAAAAGCATATGTCTCATGTGTGTGCAAAGCTGTAAGCATAAACTAACTGATTTGGAAATAAAAGAATCACTGACAGAATATGGTTTTAGTGAAACCAAATTAGATATGATTATATTATTTTTGGAAAACCAAAAACCTCATTTACTAGATATTTTGTCATTAAGTGCGTTTGTATTCCCACACTTCAAAGAACTGGAGTGGCGATTTGAAACCGATATGGGATCCAGATCTTTATTACATCAAACCGTGCCAGTTGTTACATTGAAATTAGATTTAGAAAAAAAGGATATTTCCGAATCGTTATTCCTACAAACAAATCCATTAAACTTGGTTCATATCAAAGATACACTAGAGACTGCTTTGAAACAGAACCAATCTCAATGGATAAGGAAAATACGTAGAAAATTGAAATAAAGGTATAACTGTTATAAACAATATAAAT
->KY530257.1 Liriodendron chinense AT4G19003 mRNA, partial sequence 
-ATGGCTCCTGGGAAAGCCATAGTAGGGGCTGCTGCTGCAGCAATTTCCATGTCTATACTCTCCATCTTCCTCTGCAAATCTCTCTGCAATCTATCAATGAGAAAATTCCAAAGACCCATCTCAAAAACCAAAGCTAGAAAAGGCCTCATCGACGCCATCGGCAATACCCCTTTAATCAGAATCAATAGCCTTTCAGATGCCACTGGCTGTGAAATTCTGGCGAAAGCTGAGTTCTTGAACCCTGGAGGCAGCGTGAAAGATCGAGTAGCGGTTAAAATCATAGAAGAGGCTCTGGAGTCTGGTCATCTTGTTCGAGGCGGTGTAGTGACTGAGGGGAGCGCTGGAAGCACTGCCATTAGCCTTGCTACGGTGGCTCCTGCTTATGGATGCAAATGTCATGTGGTTATACCCGATGATGCTGCTATTGAGAAGTCTCAAATACTCGAAGCTCTTGGAGCTACTGTAGAAAGAGTAAGACCCGTTTCGATTACACACAGAAATCACTTCGTCAATATTGCAAGGAGAAGGGCATCTGAGTTTACCGAATTAGCATCAAGACAGCGAGAAGCCGAACGCTCCGTACATGTCAACGGTCATGTCTCAGAAGAAGGAGACCGCCCATGCGCTTTCGCTAAAGATTGCAAAGGTGGTTTCTTTGCTGATCAGTTTGAAAACCTGGCTAACTTCCGTGCTCACTATGAAGGCACTGGCCCTGAGATCTGGGAACAGACTGGTGGCTACTTGCATGCTTTCGTTGCAGCTGCTGGTACAGGTGGGACCCTTTCCGGCGTTTCGCGTTTTCTTCAGGAACAGGATCCTAATATCAAGTGCTTCCTGATCGATCCACCCGGTTCGGGTCTCTTCAACAAGGTGACAAGAGGGGTGATGTATACACGGGAGGAGGCTGAGGGTCGGAGGTTGAAAAACCCGTTCGACACCATAACTGAGGGGATCGGAATCAACAGGCTAACCAAGAATTTCATGATGGCAGAATTGGATGGAGCTTTCAGGGGTTCAGACATGGAGGCCGTTGAAATGTCTAGGTTTCTTTTGAGGAATGACGGGCTATTCCTCGGGAGTTCTTCAGCCATGAACTGTGTTGGAGCCGTGAGGGTCGCACAGTCGTTGGGCCCCGGGCACACGATTGTGACCATCCTGTGTGACAATGGGATGAGGCATCTGAGTAAGTTCCATGAT
->XM_052888826.1 PREDICTED: Bicyclus anynana jerky protein homolog-like (LOC112047489), transcript variant X2, mRNA 
-CGCACTGTACGCGACGGCCGTAAACCCGCGCTCCATCTGAGCCCGCGTGCAGAAGGCAGTCAACGTCATAGGGACTTGGTTCCGCCTTTGGCGGATAGAAGTCAACCCAGAGAAGAGCGCAGCTGTGCTCTTCACTGGCAAACCGTTTTGCCAGAACAAACTCAAAGAAGTCTCACTCTACGGAGCTCCCATCCCCTGGCAACGTACTGCCAAATACCTAGGCGTGACCTTTGATAACCGCATGAGCTTCTCCATGCACATTAGGGAAGCTAGAAAAAAGGCTGCATACGTAATGCACCGCCTCTACTCGATGATTAACGTTAAAAGTAAATTGTCCCTCCGCTTAAAACTAACGCTTTATAAAACTACGATCCGTCCGATCCTAACCTACGCTAGTGTAGTGTTCGCCAACCGTCCCAAAGCGACCCTTAAGCCGCTTCAAAACTCTGCAAAATCGATTCCTACGGCAAATCACGGGCGCGCCGTGGTTTGTACGTAATAACGACCTCCATAGAGATTTAGAACTACCTTCAATAGCTAATCACATGAAACAGCTCTCTCAAAACTATTTTGAAAGAGCTGCCATCCATCCCAACCAACTAGTGGTTGAGGCTTGCAACTATACTCTCAACCTTAACGCTAACTCCAAGCAGAGACGTCCCAAAAACATCCTTTACGATCCTGACGATGACATGACAACTGACAATGCTTCTCAGGCAACACAATCACAAGCTACACAGCGTCTTCGCCGGCGAAGACGAGGTCCCCGATATCTAACGTCACCCGGAAGTGGGTTTTCTAACTCACGATCTCGGGGGCGTCCGGACTGATTCACTCAGGTCACGGTCAAACCCTCCCGAATGGCCCTCTAAGCCGAGGCCCGAGTCTCATAGGAGACGACCTTACAGAGCCGTTCCGTCCTCTGTTTTTATTTCAGCCTTCGTGCACAGGCGATGCTTCCGCGCTCGCCCACCCCCTACCGGTGACGTCGTAGTGGTTCCACAGGGAGCTAAACGGCATTTACTCAACAAAAAAAAAAATATTTTCATTTGTGGTCTCGCGCGCAATAGATGATACTTACGCCTTCTCTACAGTACTCGCGAAGTTGAACGTATTTCTCAAAGCAAAACAATGTCGGAAGTAAAAAAGAAGAGACGGCAATACTGTGCGGAATATATTAAATTCGGATTTATTGAAAATCCCACAAACCCATCGTCGCCTTTTTGTCTTCTATGTCTAAAAACATTTTCGAATGAAGCAATGAAGCCTTCAAGGCTGCAAGATCATTTGAATAAAATGCATCCAGATAAGAAAGACAAGAATGTAGCATATTTTCAAGACCTAGAGAAGAAGCATAATACACAGCCAAGTGTAGCAAAACTATTTGTCCAAGCGCAGACGTCGGACGACTACGCGGGTTGCGGGGTGCGGGGACACCGCGCCGGCCCGTCGTGCCAGCGACCGACGCGCGGACACTTCGAAATTGATTCGCACGGACTGTGTGCGCATACACAATACAATATTGTTGTTTGGTCTTTTATATACTTAAATAAAATTCACGAAGAGCACCAGTATTCATATTTACAACCACCAGCTCGTTAACACATCACTATTTTTGGTCTTTCGCCCTTCTAACTTTGTGGATTTGGAAACAAGCCATACGACAAACAAGAAAGGATTTCTGCAAATGGGAATACCTACAACACACAGCTGTGAAGAATTACGAGAAGAACACCACGGAAACAAAGGACGAGGGACACGATACTGAGTGAGTTCGTTCCATTTTCCTTCTTATTTTTCCGTCTTCCTTGCGCCTTCCTTTCGATTTTTCAAAATTAGAATTTCTTCACACGCTTAAGGTAATCATTATTACGTAATAAACTTACATCTAATTCTTATAATAATCATAATCTTCATATGTACTTAAATACTTTTATTGAGAATTATAATAATCATTCATTATGCTCCAAGCTAATTTTTTTAATTAATTGCTTGCTTATTCATTTAATATTACACGTAGTTAACTACCTACACGTATTCAACTCGCTTCGACCGCTCGGCCGCTCGGCCGCTCGGACAAAAAACCGGTTCCTTATCGCTAGCGACGTAGTTCTCATACCTATCTTGCAGTCAATTTGCATCGTAATAATATAATATGAATGCATCAAATAGGTAACTACTCATCACGCGCGGCTTTTTAGCTGTTTTCGGCGGCTGCTAAGCAAGTTGACGACGACCTTCGAGCTTCGTACAATATCTCTTTGTTAATTGCTCAAAAAGGCAAACCACATAACATCGGAGAAGAGTTAATATTGCCAGCAATAAATCAAGTTATAACTACAGTGGACCCCCGGTAATCCGGCCTCTGACTAATCCGGCGCCCCCTGTAATCCGACATGACAGAATTATGTTTGACAATTCTTGCTAATATCACGCAAGTTTGAACAGGTCACAACTCGTACGCGCCACCGCTATTGTGCTCGACGCGTATGCATTGTTTTACTTAGTTTGAATTTGACTACTAGTGATAGCGGTACGGCTTAGCGTACGTTCATTGTTTACTACTTATTTATTCATTGTGTATTAGGTATATGTAGTACCTAGTAATGTCGTCATAAACCCACAAGCGAAAGCACAAAACGTTGACAATTAAAGAAAAATGTGATATTTTAGATCGCTTAAATCGCAATGAAACTTTCAGTAGTTTAGCAAGTGAATACGGCGTAGGCCGATTTACAATTTATGACATTAAAAAAAAACCACGAGAAGAAGTTCGTGTCAACTACTGACTGCGGGCCAGGTAAGAGATAGACACTCAAGGAAGCTGAACATCCAGAAGTGGAAGAAGCTTTGTACATGTGGTTTCTTCAGGAAAGAAACATGCATGCACCAATTTCGGGACCCATGTTGGCGATGAAAGCTAAGTTTTTTTATAAGGAAATAACAAAAAAAGATGATTTTGTGGCCAGCAAAGGATGGCTAGAACGTTTTAAAAGTCGTCATGGCATACGTTTAATGACTATTACAGGAGGGAAACTTTCTAACGATGCCACCTGCATAGAGCCCTTTAAATTAAGATTTTTGCAAAAGGTGAACGATTTAAATCTTGGCCCGTCACAGGTGTATAATGCAGACGAATCAGGGCTTTTTTTGCGTGTGATGCCTAACAAAACTTTCGTTTCTTGTAACGAAAAAGACGTACCTGGACGAAAAGTGAGTAAAGAGCGTGTAACCATACTACCATGTGCTAATGCTGCAGGTACACACGCGCTTACGATGGTGGTCATTGGGAAATCTAATAAACCAAGGGCATTCAAAAACATTGATTTACCTGTACACTATTACGGACAAAAAAGTGCATGGATGACAAAAGACCTTTTCAAAAAGTGGTTTGATGAATGCTTGGCACCTGAAGTTAGAAAATGGTTAAAAGATCATAATTTTCCTCAAAAAGCGTTGTTGCTTCTTGATAACGCTCCCGATCATCCGTCTGAAGAAGAACTGACAACTGAGGATAAATGCATCACTGCGATGTTTCTTCCGCCAAATTGCACTGCACTGATTCAACCAATGGACCAGAACATCATTCAGTTTGTTAAGCAAGACTATAAAAAAAACCTACTTTTAAGAGCCGTATCAAAAGACCAACCAATAGAAAAAACTTTAAAAGAATTTAATATGAAAGACTTGGTTTTTGCTCTTAGTCAGTCGTGGAGTGCGTTACCGTCATCAACTATTAAATCGTCTTGGAAAAAGTTATGGCCAGATATAATCACCACTCCTAGCAACGATCCACAAATCAGTGTAACTTCGGAAGTTATAGAACAAGTCTCTACTGAAACACAGATAAGTCCGGAAGATTTGGAAGTCTGGTGTCGTGGAATGGATAAAGAAGAAAATGTTTTTCTTGAAATGCCTGACGAAGATATTATAAAAGAGGTTTCTAATAATACAACAAACGATCAGGAAGATAACGACGACGTGATTGCAACTGCTCCACAAGTCACAGATCAAGACGCAGTTAACGCTTTTGAGCTAGGTTTTGTGACGGAGTAAAGCGCCATCTGTTGGTATGATGACGAAATCCGTAGAAAACGCGCTCATAAAAGGTGCGAAGAATTGATTATATTATGGGTCGCTAGTGAATGGCCGTCTAAATCATAGATGGCGACAGGATCGTGTCTCTTCGTGTGAAATTGCGTTTCGTTTCAGGGTCGGGGTGTGCAAATTGGCAATTTTCGGGTAAAACAAACTTCGTGGGGGTTCAAAAACATAAAATAAGGCACTAGAATGGTGTTGGCAAGCTTATGATTTGTGAATACAAAAATAAAAGGGATAAAGATTTTCTATTGTTATAGTTAAGATTTGTATGAACGAACGAATTTTTTGATGCGTCGAACGAAAACGTGTGAGCAAAGTTCTCGCCGGGGACAGGGTTTCGGTGATTTTCTGGAAACAGCCACCATGAGCTGAACAAAAATATCCGGGGGGAAGGATTTAATGTAGCAGGTCTGCTGAGACCAAAAACCTTAACTAAAATATTATGTTCAGCTCATTGAAAATATAAGTTTTATTAAGTCTTGGGAAAATCACAGGAGTCTTCCTTCCCGTTGGCAATGAATTCGTATAGCGACTAAATTTAATATTCGGGGGGGTGGGCCAGAGAGAACTGATATTATCAGGTAAGAAATATTTTTCACTTTACGGGACATTGTGCGGGGTCATTGACCACGCCGGTAGAACTTGACAATGACGTGTCATTTTTTTCGTTTCAGTGGGAAAAACAAGAAAGAAATATATAAGAATGAGTTTCGAGAACCTTTGAGAATGTAAAAGGGTAATTTATGAGTTTTTACGAGTTTCGAAGAGGTTGTACGAATCCGTCGTGACGTCGCGGGATTCGTGGAAGGCTTTAAGAAGATAGTCATTTGCCGGTTACAACATCCGGGAACGTCGCAAGCTGAGGCAGACGGAGTAGCCGTACCAGGTCAAGGGAGTCCGGCAGGACATATAACCGGGTAAATACCCAGACAAGGTCAGTCCTAACCTGTTTACCAAGCTTGCGTTGATCTTCGGTGTTATGGACGAGAACATATCTATACAGTGTTAATTTCGGGGGGGGGGGGGGGGGATTTTTGGATATTTGGACATTGGATCTGAACCGTGTTCGGATATAATTTAAAGTTTAGTGCTTAACGATTTATGGTGGTATTTTGTATGTGGAATTTTGTATTTTGTACGCGGTATTTTGGTATATTATGATACTTTGTGTAATTTTGTCCAACAGCAAATATTATGCTGTTTGAGGATTCTATAGTAGTACATGCTTAATTAAAGGTTTGGTTATGCTTTCTCTTACGGAGGTGGGATTGTGGGAAAATAAACAAACTTTCCGTTTGGTTGGTTAGTGACCGGTAGTGTGATTTGGACCCACGGGCTCTCAATTCAACGACTGAGATACCGGGACATTAGAGCCTTTGAGTCCGGTCCAAGTAACCCACATCTTCTTTCCTCCGTGGGACGAGAAAA
->XM_029190890.2 PREDICTED: Osmia bicornis bicornis bromodomain-containing protein 7 (LOC114877834), transcript variant X1, mRNA 
-CGTTTCTCGTCACTTTTAATTGTCTCGTAACATCATCTTGACATCGCCAGGTCGTCGCGTTATGTGCCGTCTTATATAAATAGTCGTTGTACTTCGTGCTGTACAGTGTGTTCCAAATGAGCTCGCTACGCGCCTTCAATTCAAACGTTTCGATTGTCGCTTTAGTGCGATATTTGTTTTTATGTTCGCTGATCAAATCATATCCGCGATGACAGCTCATTGCTACGTTATCAGGTGTTCTCATTGCATACTGTTTTCACAGCTTTTTGTACTTGAATGCATACATACGTTCATCGAAGCAACGGCAGAAGGGCACTATACAATCACGGATAAACCCCGTACCTTGAAGTTAATTTTAAAGGTGGGGGGTAGTAGTGGCACACCTGAATACGGCAACGAATCTCCAAGTCAAACAACAATGTTGTCTCAACATTTAGGTGTGTACCAGCAACAGTTGGGTCTCAACTGTTCCGTAACGCAGGAGTCTGAATACGATAGGTATTTGGGGCATAAGAAACTCAAGAAGAAAAAGAAAAAGAAGGATAAAAGACACAAGCACCATCATAAAGATAAGAAAAGACGAAGAGAAGAGTCAAGTCAAGAATCCGTAGGAGATGCGGATGAAAGTTTCGCAGAAGTCCCCAAAAAGATTCCTAATCACCAGTTGCTACCTCCTAGACCCCCATCGAGCGGAGAGCACAGAGTTGGCATTACTAGCCATATTAGCTCTCTGTCTCCGCATCGTGAGCCTCGAACTTGTGTGCTTCGAAAAATTGCCGAGCGTACACCCCTTCAACGATTGTTAGAACATCTTCTCAGGTCAATGGAAAAACGTGACCCACAGCAATTTTTTGCTTGGCCAGTCACAGATAGCATTGCGCCTGGTTACTCTCAAATCATTACTAATCCTATGGATTTCAGTACCATAAAACAGAAGATAGATGATAACAATTATCAAAATTTAAACGAATTTATAGACGATTTCAAGTTAATGTGTGATAATGCTACTACTTATAATCACCCAGATACAATTTATTACAAGGCAGCTAAGAAATTGTTACACGTTGGTCTAAAAATGGTTACACCCGAGAAGCTTCGTCAATTAAGACCCGTTTTAACTTATATGCAGGATATTTCAAGAGAGGAACTTGGATTCGAATTAGGTACAGAAGATCCTAACAATCCAGATGTTCCAGTAACGGAAGAGCAAATCGAACGGGAACGAGAACAGGAGGAGCGCAATGAGGAAGCGGAGGAACTTAGAAAGGAGAATCAGAGGAAAATGAGATTAGCGAATTTAGGTAAATTCGAAGCTATCCCGGACGATTTGACTCCTGAAGAGATCTTGAAACAAGCGCGAGGTGCTGCTAAAGCAGCATCCGAAAAGTTAACGTTGAAAAGGTTGAACTCGAAGATGGGTTTCCTTAGACAAAAGAAAGATGGAACTACTAGTTTACAGATAATAGTACCCGGAGATGGAGTGATTCCAGGAACCAATCAAAGACCGGTATCGTTAGGTCAACTGATAGGAAAATTGAATCATGGTACTGGGGCATTAGCAGGATTTCGTGAAGACAGGAGAAATATGTCTAAACCAGTAAAACCTTTATACTACGGTGCCTTTGGCTCATACGCGCCAAGTTATGACTCTACGTTTGCCAATCTTACAAAAGAGGAAACAGACTTGGTGTACCAAACGTATGGCGATGAGACGGCTGTACAATACGCGGAATCTATTTTAGACTTTGCTAAAGACTGTGATTATACTCTGACTATGGTCGACGATTTACTGGATATATTGACAGGAGGTGATCACAGAAAGACCAAGAAGTTCCTCGAGGAAAAACGAAGGCTCAAAGAAGAGGAGGAGAAGATAAAGCATTTACTAGAGAAACCTATGCAAGATATAATTCGAAATATCTCAACTGTTGACAACGTTAAAGTTGATATTGATCAGTTGAAAACACTTTCAGAGCTAGGAATCGATGTCAATTTCTTGGAAAATCTAGATGTTGATTTAAAGACCACTGAGGAACGTACAGCCTTGCAAAGTCGTTTGGACGATACGTCGCAAATGTTGAATCGTTTGAAGCAGGTACAACACGAACGACTCTCGGCTCCACCACCCCCTCATTTGTCGAATGTTCCTAAACCATCAGAAATCGAGGTGGCGATAGCTGACAAAATCACAGACAATTTAACGGAAATAGCTAAGAAGCTTCCTCCTTCGGCTATCGCACCCGTGGAAGGTTTGAGAAAGGCCATGGGTATAGCACCTCTTGGAGGACCAGAGCCTATGGAGGTTGAACCTATCACTCATAACCCGACTATCGTCGCAGAAAGTAATCTATTATCGCAAGCTAACGCTAATCAAGTTCCGCCGAATTTGTTGCCAACTCCCTCACCGATTCCAAACACAAATTTACTCAGTTCAACGACTAGCCAACAAGCTCAACCGATCAGTATCGTGAACGCGAATCAGCCACCTATTCAAATACAGATTGGCATGGCGCACAGTCAGACGCCGCCATCTTTACTTGGTACGACAGAAACATCCGCGGTTCCCGATTTGGAAACCGAACTTCGTGAATTTCTAGAGAGCGATCCTACGTTAGGACACTCCCCTCTTCACGACGATAAAACATTGGAGGACATTTTATCTGAGTCTTAGTGTGTACGATTCGCGATAATATATTTTTCGTTTATATACCTCCCACAGGTTGTACATTTTTCTTACGTATCAACAGCAATAGGTTTAATGCGAAAATGCGTACTGTTTAATAAATATAAGGTCGTGTCCCCATATCGTGTTGTCATGCAATCAACACCGTGCTTATTTTATATAATTATTTATGAAGTTTGCGTAACAAATAATATTAATGGAACACTTGTAAAATTTTTATGAGATACACATGTAATGCGGAATATTGTTTCATTATAAATGTTGAAGAGATTTTAATGAATTATACCCAAAGATAAATCAAATGGAATTTACTTTATTCTTACTTTTGTTTTTAATCCTAAATTTTGATGTTAATCGTTTGTCGAAATGTTACGCAAACGCAAATACGTATTTTAAGAGCAAGGAAAATACTTTGTATTCGAATAAATTCAGACTTTTCTGTTGCACA
->XM_028730195.1 PREDICTED: Podarcis muralis actin binding LIM protein 1 (ABLIM1), transcript variant X39, mRNA 
-ACAGTTGCCATAGATATGCCATCTTTCCCCAGTCTAAACAGTTTTGGGAAGCTTTGTGGATCAGGGAAAAGCAAGAGGTTGGTGTCTGAGCGGATAAAGTACAAAAACTCTATCAAAAGGATGTCTATTATAGAGGACGGTGATATTGCTGAGGTCTTGTACCTCATCCCCAAGCAGTCTGTGATGAAGCAGCTGCCATACCTGAATCCAGATGACTACTATTTGTGTGAATGGTTGTTTGATTATCCAGAAGGTTCAGTGGCACATCCTCAGGAGCCTCACCATTCCACAGAGAAGCCAGTCATCCACTGCCATAAATGTGGGGAGCCATGCAAAGGAGAAGTTCTTCGGGTCCAGGCCAGGCATTTCCACATCAAATGCTTTACCTGCAAAGTGTGCGGGTGCGACTTAGCTCAAGGTGGCTTTTTCATTAAGAATGGAGATTACCTTTGTACTGTGGATTACCAGCGGATGTACGGGACCCGATGCAATGGCTGTGGGGAGTTTGTGGAAGGAGAAGTTGTAACTGCTCTTGGGAAGACCTATCATCCTAACTGCTTTGCCTGCACTGTATGCAAACGTCCTTTCCCACCAGGAGACCGGGTTACCTTTAATGGAAGAGACTGTCTCTGTCAAATGTGTGCTCAGCCTATGTCATCCAGCCCAAAAGAACTCTCCAGTTCCAGCAATTGTGCAGGCTGTGGAAGAGATATAAAGAATGGACAAGCATTACTAGCACTGGATAAGCAGTGGCATCTGGGATGCTTCAAATGCAAGGCCTGTGCAAAAGTCCTGACTGGAGAATACATCAGCAAAGATGGTGCACCTTACTGTGAAAAGGACTATCAGGTTCTCTTTGGTGTCAAATGTGAAGCATGCCACCAGTTCATCACTGGGAAAGTCCTAGAGGCAGGGGACAAGCATTACCATCCAAGCTGTGCACGATGCAGCAGATGCAATCAGATGTTCACAGAAGGAGAAGAAATGTACCTGCAAGGTTCTACAGTTTGGCACCCTGACTGTAAACAGTCCACAAAGGGTGAAGAAAAGCTAAGGCTGTTTTCACCACCTTGTATAATGAACTCCATCAAAAAACTAAGGCAGCCTACAAGAACATCTTTGGAAAGTATTTATTCCAGGCCTGGATCCAGTATACCTGGCTCACCAGGCCATTCAATCTATGCAAAAGTAGACAATGAGATCCTTGATTATAAGGATTTAGCAGCCATTCCCAAAGTCAAGGCCATTTATGACATTGAGCGTCCAGACCTAATTACTTATGAGCCCTTCTACACTTCCGCCTACGAGGAGAGACAGGAGAGGCAGAGTCTTGGAGAGACTCAGAGTTCAAGATATGGCAGTTCTCCTGTGCACGATGAAAGTTCTCCAAGGACACTCTCTCCAACTCCATCTGCAGAAGGATATCAGGATCTTCGGGATCGGATGATACACCGGTCTACCAGCCAGGGGTCCATTGGTTCTCCTGTGTACAGTCGTCACAGCTACACTCCCACAATGTCACGTTCACCACAACATTTTCACAGACCTGATCAAGGCATCAATATTTATAGAAAACCTCCTATCTACAAACAGCATGTACTGTTGGAAGGCATGTTTTTGTAATTCCCTGAGCAATGAGCCAAGATAGCTGCTCCTTATCCATTAAAGGCAGGGATGGGAAACCTCCGATCTGGGCATCAAATGAGACTTCTCTTCTGGCCCTCAGGACTCTCCGCAAGCTACACACCCTCCTCAGTCACCCACCCCTGCTCCCCAGCCACACCATTCTAGGACTGATCTTGGCTGGCTGGAATGTGTCCCTTGCTTGCCTGGGTGGAGGATAGAAAGGGGTATATTCAGTATGTTTAGAAACTGACCTACTGTAAACAGGTTAAATCTACATTCATTGCTCTGCCCACTTTTGCCTGTGAGCCCCCCCACCCTTGGGAGGCTGCCTAGAAGGGAATGTGCCCTCAGTCTGAAAAAGGTTCTTCACTTCTGCATTAAGACTTCACAGTTTTTCAGGAACTTTTCTTGTTCATAAGCCCCCTTTGAAATGAAAGAGAGCTGCTAGTCTGCACAGGATGAAACTCTTGTGCAGCTTTCATTTGTTTCACTTAAGCCTGTGCACAAGATATTTCCAGTTAGTTACATCTCTTATGAACAATTTTTATTATATTTCAAAATAGTAAGGGGGCTTCTGCAAGTAAACATCTTTTGTTTCTTGTTTGCTCTTCCCTAAAAATTCTACATTTTATTATAACTTGCAAACTTTAAAAAGTTAGTATTCTTTCACTCTGCTTTCTCTTCTTCTGGAGAATGAATCTAGTTAAGGTTTTAACTATGTAGTAGCATCTGATAAAGACTTTCCCTTCCATCATGCATGACTAAATAGTTGCAGGACTTTCATTTAAAAATGTACTTTAAGAAATGTTAAAAAGTCTTAAAATATCATGGAGTTGCAGTCTAAGGCTGAGATGGCCATGGTTTAGGGGAAAGGGTCTTAAGGGTCAAATTGAGAACCGTTCAGGGCCTGATTAGGTCCATTGGCTGGTGGTTTCCCACCTCTCCTCTAAGTGATCACAGGTAAAATGGCCAAATTCATTTGAACGGAGCATTAAAACATTGAAGTATATTTATATAATATGCAGATGGACAATCAATATCTGGATTTACCCTTTCTCTTCTTATGCAAGCATGGCCCTGTATAACTTTCTAACATTTTCTGATACAGGCCTCGGTTTTAGCTAAGTTTGTGACATCTGAAAATACTCTTTGGAGGCTTTCAGAAACACAAACCATAAAATAGTAAAGACACAAAATATATCTTGGGAAATAGTTTTTTCTAGTTCACATTCTTTTCTATCTTTTTTTAGTTGCTTCATACACAGTGGAATCAGCCTAACATTTGGTTATTGAAAACAGCAAAGGGTGAAACTACACTGTCATTTTGTATATGTAAAACTCTGCCCTGAGGTGATGTTTTTTCTTTGTTATTTACTGGCATTAAATCTGCCTTCTTCTTTTCAAATATACATGAATCTTAAGAACAGTTGCATGCATCTCATGGCGATGTTCCCTCATACATAATGATAGTATAATTTCACCCTAAGTGAATTGCCAGGATAAATATTACACTATTACTATACCTTGCTTTGGGATCAATTTCACATGGTGATGACAATGCTCTGAAGTAAACATCAAGGATGCTTAATAAGAGATTTAACCAAAATAAACTGAAGCTAATTATTATGTAGCA
->XM_030853958.1 PREDICTED: Globicephala melas ubinuclein 2 (UBN2), transcript variant X2, mRNA 
-GAGGAAAAGAGGAAAACTGAGCCACAGCCACGACGGTGGATGTGAGCGTCTCCTGTCTGCGCATGCGCCCGCTCAGCGGCCTGCTTCTATTTATGTGGGGGATCCAACATGGCGGCCGCAACGATCCTGGCGATGGCGGTGGAGCCCATCAGAACATAGTGGCGGGGAAGGGGGGACAGTCCGCACTCACGGTGGCGTCGGCGGCGACGGCTGAGGGTGGTGGAGGGAAGAAAAGCGACGGAGAGCAAAAGGAAGGGCAGGCAGGCAAACAACTCGGCGTAGAACCGAGCGCCGGCTCGAGCGAAGGCAGAGGGCCAGAACAGTGGGGATGGCGGAGCCACGCAGAGTAGCGTTTATTAGCCTGTCACCGGTGAGGCGGCGCGAGGCCGAGTTCCCGGGGGCCGAACGCGAGCCCGACTACCCTCGCGAGCCCCCCCGACTGGAGCCGCAGCCGTACCGCGAGCCGGCCCGGGCGGAGCAGTCGGCCCCGCGGGAGGTTGCCCCCCGGTCGGACGCGCAGCCCCCGCCGCGGGAGAAGCCGCTCCCCCAGCGCGAGGTCAGCCGCGCCGAGCCGCCCATGTCGCTGCAGCGCGAGCCCCCTAGGCCCGAGCCGCCGCCGCCGCCGCCGCTCCCGCAGTTGCACTTGCAGCCGCCTCCGCCACGAGAGTCGGCTTCCCGGGCCGAGCCGCAGCAGAGGCCGTCGAAGGAGACAGTGCGCCTGGAGCTGGTGCTCAAGGATCCCACCGACGAGAGCTGCGTGGAGTTCAGCTACCCGGAGCTGTTGCTGTGCGGAGAACAACGGCAGAAGAAGCCCATTTACATGGAAGACCCGTTCAATGATGATCATCAAGAGAGGCAAGAAGTGGAAATGTTGGCTAAGAAGTTTGAAATGAAATATGGTGGGAAGCCCCGTAAACACCGGAAGGATCGGCTACAAGATTTAATCGATATAGGCTTTGGCTATGATGAGACAGATCCATTTATTGATAATTCAGAGGCTTATGACGAATTAGTTCCTGCTTCTCTAACAACAAAATATGGAGGGTTTTATATCAACACTGGCACTCTCCAGTTTCGCCAAGCTTCAGATACTGAAGAAGAAGATATTACAGACAACCAAAAGCACAAGCCACCCAAAATTCCCAAAATGAAAGAAGATGATATTGAGATGAAGAAGCGGAAGCGGAAAGAGGAAGGGGAAAAGGAGAAGAAGCCAAGGAAAAAAGTACCGAAACAACTGGGAGTTGTGGCTCTAAATTCACACAAATCTGAAAAAAAGAAGAAACGTTATAAAGATTCTCTTTCTCTAGCTGCCATGATAAGAAAATTTCAAAAAGAGAAGGATGCATTAAGGAAGGAGTCTAACCCTAAAGTCCCAGTGAACTTCTCGACCTCCTCTCTGCATAAAACCCCCTCTGCTGCTGTGGCATTGGGGAATGATGTCTCGGACTTAAATCTGAATAGTGCTGATCCGGACCTCCCCATTTTTGTTAGCACAAATGAACATGAACTATTTCAGGAAGCTGAAAATGCCCTAGAGATGCTAGATGATTTTGACTTTGACAGATTACTGGATGCTGCTTCTAATGGTAGCCCCCTGTCTGAGTCAGGAGGAGAGAATGGAAACACCACCCAGCCAACCTATGCCTCTCAAGTTATGCCCAAGGTGGTACCTACACTCCCAGAGGGTCTGCCTGTCCTTCTTGAAAAACGTATCGAAGACCTCCGTGTAGCTGCCAAACTTTTTGATGAAGAAGGAAGGAAAAAATTCTTTACACAGGATATGAATAATATTCTTCTGGACATTGAGTTACAGCTGCAGGAACTAGGCCCTGTCATTCGTAGCAGTGTCTACTCCCACCTTGAAGCTTTTGTGCCATGCAATAAAGAAACACTGGTAAAACGTCTAAAGAAGTTACATCTCAATGTCCAGGATGATCGTTTAAGAGAACCTCTGCAAAAACTGAAACTGGCTGTTAGCAATGTCATGCCTGAACAGCTATTTAAATACCAGGAGGACTGCCAGGCTCGTAATCAAGCTAAGTGTGCCAAGTTTCAAACAGATGAAGAACGAGAAAAAAATGGATCTGAGGAAGATGATGATGAGAAACCAGGGAAACGTGTCATAGGACCAAGGAAGAAATTCCACTGGGATGACACCATTAGAACTTTGTTATGTAACCTTGTTGAGATCAAATTGGGATGCTATGAGTTAGAGCCAAATAAAAGCCAGTCTGCTGAGGATTATCTTAAATCCTTTATGGAGACAGAGGTGAAACCATTGTGGCCTAAGGGCTGGATGCAGGCAAGAATGCTTTTTAAGGAAAGTCGGAGTGTACATAATCATCTTACTTCTGCTCCGGCAAAGAAAAAGGTGATTCCTGCACCTAAACCCAAAGTGAAGGAGTGTAGTCCAAAAAAGGACCAGAAAACTCCTGCATCCTTGGTGGCTTCAGTTGGTGGCCCTTCAACGAGCTCTAGCACATCTGCTGTGGCCTCCACCAGTTCTAGCTCTACACCGGCCCAGGAGACGATCTGCCTTGATGACTCACTAGATGAAGAACTTTCTTTTCATCCACCTGCACTGGATCTTGTTTCTGAAGCTTTAGCTGTTATCAACAACGGGAACAAGGGCCCTCCATCTGGCTCAAGGATAAGTATGCCAACTGCAAAACCTCGTCCAGGACTGAGAGAGGAAAAATTAGCAAGTATCATGAGTAAACTGCCACTGGCTACTCCCAAAAAACTAGATTCTACTCAGACCGCACATTCATCAAGTCTTATTGCTGGCCACACAGGGCCAGTACCAAAGAAACCCCAGGATTTAGCTCATACTGGCATCTCTTCAGGCCTTATTGCTGGTTCTTCAATTCAGAACCCTAAAGTTTCCTTAGAACCTTTGCCAGCCAGGCTACTTCAACAAGGACTACAGAGGTCAAGCCAGATTCATGCTTCTTCCTCTTCGCAGACCCATGTCTCCTCTTCTTCCCAAGCCCAAGTTGCTGCCTCCTCTCACGCTCTGGGAACATCAGAGGCCCAAGATGCTTCTTCGTTAACACAAGTAACAAAGGTGCACCAGCATTCAGCTGTCCAACAGAACTATGTGTCTCCATTACAAGCAACTATTAGTAAATCACAGACCAATCCAGTGGTGAAATTAAGTAATAATCCCCAACTTTCCTGTTCATCCCCACTTATTAAGTCTTCAGATAAGCCACTTATGTACCGCCTTCCCTTATCTACTCCCACACCTGGAAATGGTTCTCAAGGGTCCCACTCCCTGGTTTCTAGGACAGTACCTAGCACCACTACCTCCAGTAACTATTTAGCCAAGGCAATGGTGTCACAAATCTCCACGCAGGGTTTCAAATCTCCCTTCTCAATGGCTGCATCCCCAAAACTTGCCGCATCTCCGAAACCTGCCACGTCTCCTAAACCCTTGCCCTCACCTAAGCCTTCTGCCTCACCCAAGCCCTCTCAGTCAGCTAAGCCTTCAGTATCAACTAAACTTATTTCTAAATCCAACCCAACTCCCAAACCTACTGTATCCCCAAGTTCTTCCAGTCCAAATGCACTAGTGGCCCAGAGTAGCCACTCTAGCAGTAACAACCCAGTCCATAAACAGCCCAGTGGAATAAACATCAGCAGACAGTCTCCCACCTTGAATTTATTGCCCTCTAATCGCACTTCAGGCCTTCCATCTACAAAAAATCTTCAGGCCCCTCCAAAGCTAACAAACTCATCATCCACTGGAACTGTCGGCAAGAATAGCTTGAGTGGAATTGCAATGAATGTACCGGCCAGCAGAGGTAGCAACCTTAACTCAAGCGGAGCTAATAGGACTAGTCTATCTGGGGGAACAGGAAGTGGAACACAGGGTGCTACTAAACCGTTGTCTACTCCACATAGACCATCCTCTGCCTCAGGGTCGTCAGTGGTAACAGCCAGTGTGCAGTCCACAGCAGGAGCATCATTATTGGCTAATGCCTCACCTCTGACTCTCATGACATCACCTTTGTCTGTAACAAATCAAAATGTGACTCCTTTTGGGATGCTGGGTGGCCTTGTTCCAGTGACCATGCCCTTCCAGTTTCCCTTGGAGCTACTTGGCTTTGGAACGGACACAGCTGGAGTGACAGCCACCTCGGGATCTACCTCAGCCGCTTTCCACCATAGCCTAACTCAGAATTTACTAAAGGGTTTACAGCCAGGAGCTCAGCATGCAGCAACACTTTCCCACTCACCTCTGCCTGCACATTTACCGCAAACATTTAATGATGGAGGCCAAAGTAAAGGGGACACTAAATTACCACGGAAATCTCAGTGACTTCCAGCAAGCAAAGGAGATGACACACTTGGCTGGCTGATGGAATCTACCTGATGGAAAAGTACTCATGTGGTCATAGGGCTGCTGTTCTGTCGATGTTTACATTCTCTCGTCCCAAGCACTGTGTTTCACCAGAAACCCCAAAGGCTGAGAACAAAACAGTAGGTGCCAAGTCCATCCACATTCTAAAGGGAAAAGGAGCTAGATCACCTGTGCGCCACATGCTAAGAGATTGTGAACTAGATACTGGGAAGCACTGGCTCAGTGCTGGGAAGGAAGAGCTCGGCACCCACCTTCAGGCTCTGTGAGAGAATGTGAGAAGATTCCTTTGGAAGCAGCTGTCAGTATGCTGGACGTTTCCATTCCGCTCCCCAAGCAGGAGAGGGTGGAGGTGCTTCCTCTTCACCTCATGCCAAATGAGGAGGCTGCTAGAGGACCATTGGGAGAGCGTGACACATCCTGTGGAGTATGAGGGACACAGAAACTGGTGTCTGACTCACTCCTAAAAGTCTAAAGACAAATGAGGAGTAGGTGGCTAGCTCCTGGAGAAGACAGAAAAGGAGAGAAGGCTGCAATGGGAATGGTTTACACTCCCAAAGTTTCCGAGTTCCTGTGGGCCTGATGTGGTTCTCAAGAAAGGGAGCCAGATTTGGTCATTTTAAGAAGGAACCCAGCCAAAGGGAACACCTGGACGGATGGAATGACCTCAGTGGAGGGGAGGCTCCTGGAAACTAAGGGGCCGGGGAAGGAATTCTAAGTAACTAGAGAAGGCATGGCCTACAAGGGAACTACAGCTGAGAGATCCCCAGAGAAGGAGAAACTATTGAGAACCTATAAAAAAAGAAGCAACACTGGAATCTGCTGCTCCCGGAGGACACGGACACCAGCTTATCTCTACCAACAAAGAAAGCTGTGTGAGCCACCCACGATTTCATGCCGGAGAGGAAGAAATCCACAAGCAGCAGTGGAAGGAGGAATAAATTGCTCTCTGCTTGTATCTAGCAAGTCCAGCTTGCTGGGTAATAGTCACCTCTACTTCTGAGTATTATAATGTACTGCAGTCTATATGCTACAGGATGTTATCAGTAAGGTTAATTTGCTTAAGAGTAAGACATTTAAATGGCAGAAACTACTATGTAATGGGAAGTAAACGACATAAAAATCTGTAAACTACACAGATGGAATGATTATCTTGCTGAAAAGTATTTACAAGAGTTGTCAAACTTAAAAATTACCTATTTTTCTTTTGCAAAAGAGGCAAGTGTTTCTCATTTGCTGTCCTCCTCTGTGATGACAAGAGGGTATGAGGAGTATGCTGCTGTGTGGTCTGCAGTCTGGTTTTTGGCAGCCAGCATTCATTCCCATATCCTTATGTATTACAGGGGCTAGATTTATGGAAACATTCCCAAACTCCTTGCCTTCAAGGTTCTGGATGTGATTTCTTTCTGCTAGATGTATTCATGAGGTATTTTGTAGGTGGGAGGAAAAAGTGATATTTTTTCTTCTGGCAGCACCTAGCAAAACGGGCAGGCCATGGGAGACTTAAAGTTCTGCCGTAGCTCCCAAGTAATCTCCTATCAGCCCCTACGTGAGCACTTGGGGACCAGCTCTGATCAGCAGTGGGGGGACCTGTATTTTTCTGACCTAGGTGATAGCAGCAACCTCCCAATACTCTGAACTGCTGAACGTTAGTGGCAGCTTTCCTTAACTCCTGCAGCTCTTCTAATAGTGCCGTCAAGCGTCTACTGAATTGAATGCCCTGCACTCAGTTCCTTTCTGCTTGAAAAGCCTGCAGTGGTTTCTCTTTTTCTGACTGAGCCCTGATGGATACAGGTGCATAGCTGATCTTCTGAAAGAAATGAACATACTTAATGGGTCCTTTTAAGCTAAAAGTGATATTTTAAAGCTAAGTGAGGCACTGACTGCCTTTTTAAAAGAAACTCAAGCAATGAAGAAATTTGAGAATGGATGTTTAGAAATGTTTTATCACTATGTGATTTTGTTGTCCCAAATGATGTGTTAAACCAAGATTTTCAAAATAATAAAACATACTGTATTACATTGCATTTTCAATAAAATAAAGAATAATAATCTTTCTTTACTGAGAGAAATTAGTACTTTTTTACTGTTAATAAATAAAATAAAAATATTTTCAAAA
->XM_011942543.1 PREDICTED: Colobus angolensis palliatus ADP-ribosylation factor-like 2 (ARL2), transcript variant X3, mRNA 
-CGTCGGCGAGCGTGATAGCCAATAGGAACCGGGAGCGGGGTCCCGGGACTGGGAAGAAACGGCGGCCGGGAGGGGCTCCAGGGACCATGGGGCTCCTGACCATTCTGAAGAAGATGAAGCAGAAAGAGCGGGAGCTGCGACTGCTCATGCTTGGCCTGGACAATGCTGGAAAGACAACCATCCTGAAGAAGTTCAATGGGGAGGATATCGACACCATCTCCCCAACGCTGGGCTTCAACATCAAGACCCTGGAGCACCGAGGATTCAAGCTGAACATCTGGGATGTGGGTGGCCAGAAGTCCCTGCGGTCCTACTGGCGGAACTACTTTGAGAGCACCGATGGCCTCATCTGGGTAGTGGACAGCGCGGACCACCAGCGCATGCAGGACTGCCAGCGGGAGCTCCAGAGCCTGCTGGTGGAGGAGGCCCTGGAGCTGGACTCCATCCGCAGCCACCACTGGTGCATCCAGGGCTGCAGCGCCGTCACCGGGGAGAACCTGCTGCCAGGCATCGACTGGCTCCTGGATGACATTTCCAGCCGCATCTTCACAGCTGACTGAGCCACTCCAGATGTCCCTCCACCTAGCAGTCCAGGTCCCCCAACCCTCACCAAACACTATCCATGGGGGCATGGGAGTCAGCCAGCCAAACTAACACTCCCCCTCCTCCATCCCAACCTGCTGCTGCTACTGCTGCCCGCTGCTGCTCTGTGGCCACCCAGCTCCTGTGGCGGGAGGGCTGTGCCCTGGCTGTTTCCCTGGCTCCTGACCTGGCCTTTGGCTACCATACCAAGAAGAGAGGACTGGGCGGGGAGGAGCTGCTACTGCTGCTACCGAGGCTGTGGGCCTCATCCTTCACTCAGCGGTGAAATAAACCACTCCTTGCCCTGA
->XM_021957819.1 PREDICTED: Prunus avium uncharacterized LOC110756391 (LOC110756391), mRNA 
-ATGCATTGACTTGGAGTCTTTGATAACATTGACTTCGGGTCTTTGAGTCCATGAAAAACCGTTCGCATTTTCCATGATCTTTCTTTCTGTCTGTGACCCAAACCTGCTTCCCGAGTATATTCCAAAATCGCCATTTCAACCTCGAAGTTATAATCAATTTACGAATCAAACCATCGGTTTCAAAAAGAATCATCAACGCACCGCTCGTTTGTTCATTGTCGCGTTACGATTTTCCATTTCAATTGGACGCTTTGAAACTGCTCATACTCGAAGATTTTCCGGTTTTTGAGCATTTCATTTCATTCCATTGGGTTAAGAGTTGGAATGGGGGTCGTAGGGGCGACGAAGCATTTGGAATCATCGAGAATAATTGCTGCGCTTGATGTAAGTCATTCTGAGGAAAGACTGGGACAATTTACCATGGAAAATGGTGAGTTATTTTTCCATACCAAGTCAACTAAGTTCAAGAGGCAGATAGTATCTGCTGTTCGTGATTTCCCCCCGGGGTGTGGACGATTTGCTCATTTGAACTCTTTGAGACATGCTAAGGATGCCACTTCTGTGGGTACTTCAACAGAAAGTTTGCTTAGTGGGGGTAAAAATGTTGGTGGACATCGTGGGGTTGAAAAGCTGATGCTCTCAAATGGTCAGGGAGACGAGACTGACTTGATGAATGGTAATGATGTGGATTCTGTGGAGACAGTTGAATCAGTAAGCGCCTTAGAGCATGAAAGATCTGATTCTCTGAAGAATCTACTTCAGTTAAACAATTCGAGAACTGTTGAAGAGGCAGCTTCTGTTGGTACTGAGGAGAGTTTGATCAGCAGGGATACTAATGTTCATGGAAAAAGGGTTGAAAACTTAATGCTCTCAACTGATCATGTGCATGAGACTGACTTGATGAATGGTAAGGCTTCTGGTACTGTGGAGACAGTTGAACCTGTGACAGATTTGGAGCATGAAGCATCTGATTTGCTGAAGAGTATGCATCAGTTGTCAAACAATTTGAGACCCGTTGACGAGATAGCTTCTGTTGGTACCGCTGAGTATTTGCTGAGAAGGGGTAAGAATGGTGATGGGCAGGAGATTGATAAGCTGATGGTGTCAACTGGTCAGGTGGATGTGACTGTCTCGATGATTGGTACGGCTTCTAGTACTGTGGAGACGGTTGAATCTTTAATGGCCTTACAGAATGAAGTATCTGATTTGTTGAAGAACCCATATCAGCTTGGTGTGGCTACTCCAAAGGAAGAGATGGTTGCTGTTCTTTCAGATAGAAATTTTTGTTCGCCACGTGATGGATCCATTTCTGTTTCTATTGGAAATGGTCTTGAGAAGACTGCAGCGAAGAAATGTCCTTCTCGAAGACTAGTATCAGCTGTTCGGGACTTCCCTCCTCTCTGTGGAAGAAATGCTTGTAAGTTTGGTCAAGTGAAGTCGTGTATGGGTGATGAACCAACACAATCGAACACAGCGAAGACTAGTGTAAAACAAATAAGAGAGGATTTTCAAGAAGAGTTTCATAAGAATGAATTGGGAGGGAATGTTTCTGAAGTTATTAGAGACAAGGTTCAACCTAAATGCAAGGGGCATGCTGTACAAGAAATGGAGAGACGGGATAAATGTAAACCAAGTTATAAGCTGAAGGCGGTTTGGAAAGATACAAGAGAAAAGTGCATTGAGAAAAGTCCGCAAGAAAGTTCACAGCTTCCGTCGAATAGAGTAATTGTGCTGGCTTTGATGGCTCCGTCAAATTCTCAATTTAGGAAGGGGAGAAGGGTCCGCAAGCATATACCAGATTGCATTTGATGAAAGGAAACGAAAGAAACTTCGTCTTAAATGTTAGCTAGAAAGACCTAAAACTGCTTCCAGGACAGAAAAGGCAGCTAAACTCATCAGAACCATTCATCAACAAATGAGCCTTCAAGTTTTGACGTGGAGGTTGAACGCTGACATTTTTCAATGAGCCGGCTGCCCTGTTTTTGCCTAAAAGCTAAAATGATCTGTTATTGGCACTTTGAAAATTACACGTGGAGGAGCATGATGACTTTTGTGGAGTGCCAATAACAGCTTCCGTTTTTTTTATTTTTGTAAAGTGAAGTATGAATCCTGGAAGCATGCTGTGGAGCATCACAATAGGAGTTGGTTAATTGTTACATCTGTTCTTTTTTACACCATGAAAATTTCCCCAAGCTACGGATTTCTAGCATGAAATTTGGCTTTA
->JF936918.1 Taeniopygia guttata clone F5CD66-14 T cell receptor alpha chain (TCRa) mRNA, partial cds 
-ATTGCTCGAGTAGAAAACTCAGCAAACACGCAGCTCGCTCTCGGCATGCACCTCGCATGTCTCATCCTCAGCGTCCTGCTGGCCCAGCTCCTGGGCACCTCGGGGCAGGACACGGTCACCCAGAAAGATGGAACCGTCACGGTGAAGAAGGGACACCCCTTCCACACCACCTGCAAATACCAGGCCAGTAATTTTGGGGGATTGCTCTGGTACCAGCTGCAGAAAGGCCAAGCCCCACAGCTGCTCTCCTATCAAACAGGGACCGGCCGCAAGCACAGCGGCCGGATCACCACGTACCTGAACACCACGGGCAAATCCAGTGTCCTGCAGCTGGAGGAAGTGGAGCTCTCTGACAGTGCCTTGTACCTCTGTGCTCTGGTAAATGTGGCAGCCAGAGTCATTTTTGGCAAGGGGACGGTGCTTTCAGTCCTGCCAGAAATTACTCCATCTCCCTCAGTCTACAGGCTGACCTCCAAAGATGACCAGGGTCTGGAAATGTGCCTTATCACAGATTACTCCCCTGAGAAGCTCACTCTGAACTCAGCTGAGCAGCACACATCTGCTGTTGTGGAGGTGGCAACCATGGAGAACAGCGAGGA
->XM_041785118.1 PREDICTED: Cheilinus undulatus N-sulfoglucosamine sulfohydrolase (sulfamidase) (sgsh), transcript variant X2, mRNA 
-GTTGAGGAACTGCGCTGTGTTTTCTTAGATTTTAATGTCAGCTCTATCAGTCAGTAACTGTTCACCATGCATTGATTTAAACGAATACAATGACTCTATTTAAATGATGTATTTATTATGAGTTAGACGAAATGTTTAAAATCATAACCAGCGCAGTTTTTCAGCCTTTATAGACAGGTTTTAGGGAAGGTCTGAGAGAAAATCATCATGGTCAAGCTGCTTTTTCTCATTTTGGCATCATGTTGCATCGGAGAGTCAAAGAGGAGAAATGTCCTGTTAATAATTGCTGATGATGCAGGCTTTGAGACGGAGGTGTACAACAACTCTGTGGTCCATACTCCACACTTACGATCTCTGGCCCAGCGCAGCCTGGTGTTCAACAACGCATTCACATCTGTCAGCAGCTGCTCCCCCAGCCGCTCCACCATCCTCACAGGACTTCCACAGCACCAGAATGGCATGTATGGGCTTCATCAGGGTGTTCACCACTTTAACTCGTTTGATGGAGTACAGAGTCTACCGCTGCTCCTTGGCCAAGCAAACGTACACACAGGTATAATTGGGAAGAAGCATGTAGGTCCTGGATCTGTTTACCCGTTTGATTTTGCCTACACAGAGGAGAACAACTCTGTGCTACAGGTGGGAAGAAACATCACCCGCATCAAACTTCTGGTCCGCAAGTTTTTCCAAACCCATAAGGAGGAAGACCATATAAAAGATGAAGAGAGGTCGTTTTTCCTCTATGTTGCCTTCCATGACACCCACAGATGTGGACATTCACAGCCTCAGTACGGGGCTTTCTGTGAGAAATTTGGAAATGGTGAAATGGGAATGGGAAGAATACCTGACTGGACTCCAGAGTATTACACCCCAGAACAAGTGAAGGTTCCTCCTTTTGTGCCAGACACGCCTGCAGCACGAGCAGATTTGGCTGCACAGTACACAACAGTTAGTAGGCTGGACCAAGGTATTGGTCTGGTCCTGCAAGAGCTCAGGGACGCTGGATATGAAAACGACACTCTGGTCATCTACAGCTCAGACAATGGCATCCCTTTCCCAAACGGCAGGACTAACCTGTATCACTCTGGGACTGCAGAGCCCATGCTGGTGTCCTCTCCAGAGCACCGGGAGCGATGGGGCGACATTAGCCAGGCCTACGTCAGCCTGCTAGACATAACTCCCACCATTCTGGACTGGTTTTCTGTCCCCTACCCGTCCTACAGCCTCCCCGGCAGCCCTTCAACCCCCGTCCACCTGACTGGGCGCTCCTTACTGCCCGCCCTTGTCTCTGAGCCCAGCAGCTGGCACACGGTCTACGCCAGTCAGTCCCTCCATGAGGTTACCATGTACTATCCAACCCGCTCTGTCCACCAGGGGGCGTACCACCTCCTCCACAACCTTCACTACCGCATGCCCTTCCCCATTGACCAAGATCTGTACGTGTCACCCACCTTCCAAGACCTGCTGAACCGCACCCACCTCAGAGAGCCCACACACTGGTTCAAAAGCCTGCAGCAGTATTACTACAGAGAGCGCTGGGAGCTGTACGACTCCAGGGCAGATCCACTGGAAACAAAGAACCTGGTATCAGACCCCTCCTACAGCACCGTGCTGGAGAGCCTGAGGCAGAGTCTGCAGAAGTGGCAGTGGGAGACAGGAGACCCCTGGGTCTGTGGACCTGACTACGTCCTGGAGGACAAACTGGAGCCGCACTGTAGACCACTCTACAATGGACTCTGATGATATTTGTACATTTCTGACCGACTCAAAGTCTGCTTAAAGTGACACATTCTTCTAATGAAATAAATTACTTTTATAGGCATTTGTATTATATTAAAATGTTGCTGCTTTGTTCAGAAATAAAAAAAACTTGAATTA
->XM_026823756.1 PREDICTED: Diaphorina citri dipeptidase 1 (LOC103509407), partial mRNA 
-GCACAACGATCTACCGTGGAACATTCGTAAGTTCATTCACAATCATCTGGTCAATTTCAACCTCTCCTCGGATCTCAGTGTGACGGAGCCGTGGTCCAAGAGCAGCTGGTCTCACACCGATCTGCCTAGACTGAGAAAAGGTATGGTAGGAGCCCAATTCTGGTCGGCCTATGTGCCATGTTCGTCACAACATATGGATGCAGTACAGATAACAATGGAACAGGTGGATGTTATACGCAGGTTCACGGAGTTGTACAGCGACGACCTTAAGCTGGTCACCTCAGCACAAGAAATCCGAGCGGTCCATCGGGAGGGTAAAATCGCCAGCATGATAGGCGTGGAAGGTGGCCATTCTTTGGGGAACTCGATGGCCGTTCTGCGCATGTTCTACAAGCTCGGGGTCCGATATTTGACCCTGACCCACGCCTGTCCTACACCATGGGCCGGATGTTGCAGTTCTCTTTTCTCTCCCTCCCCTGGTTCCCAGCTGGTGGTGCGGGAATGCAACCGGCTCGGCATGCTCATAGACCTCTCCCACACCTCCGTGCAGACCATGCGACACGTCCTCAACATCAGTTCCGCCCCTGTGATTTTCTCCCACTCGTCTGCCTTCGCCCTCTGCCCTTCTCCCCGAAACGTGCCCGACCCTGTGCTCAAACTAGTGGCCTTAAACGACGGAATAGTAATGGTTAGCTTCTACTCTCTGTATCTCACCTGCAGTCTGAACTCCAGTATAGATGACGTTATAGCTCATCTGGATCATATCAAGAATGTAGCGGGTGAGGATCATGTAGGTCTAGGTGCTGGATATGATGGAATTAACTAG
->NM_001168050.1 Saccoglossus kowalevskii cripto-like protein (LOC100313583), mRNA
GU075970.1 Saccoglossus kowalevskii cripto-like protein mRNA, complete cds 
-GGCAGAATAAGCTATATAAGACATCTTGGCGTTATCTGGTCACTTGTAGCGTGGACTCACAACTCCGCACACTCTCTATCATAACCTTGGATCTTACACTGTAGTCTTCCCCAGTACCCTAACTTTGAGTTGACCATGAATTGTCACCTTGCCAATTTGTTAGCAGCGATTTTACTGCTCGTGATGGTCACTAACGTTTCGTCAGTAAGTCTAGGAGAATGGACTAACACCCGATCTTCCGCCAACATCTGCCATAACGGAGGGATAATGATCCTTGACAGTTTCTGCATATGTCCCATTGGATATGGTGGTCAATACTGTGAAAGCAAGCCTTGTGGCGCAGTTGCCCACGATGAAAAACTCACCGTACAATGTAATACCTGTCTGTGTCGAGACGGGAAACTCTACTGTGTACCACTGGGATTCCCTGCTTGTGAAACTACAGATGAAGTGATTATTGTGATTACGTCAGCCCCGATCACCACCAGCACCTATGCGCCGACGGAGGCCGAAGACGTCATAATGTTTTCTTACGGTGAATTCGAGGCGTTGTCATCTGTTGCAGCAATCACTCCCCGTTTTATACAGTTAGTTCTGCCCGCATTGGTGTTGCTTATGACACTGTGGACATGAGTTGCATATCTGAGAAAAGGGACAGCGAGGTTTATTGGATCCAGGCAATGATAGTTCTGATAAGACGACCGAAATCCCCGACTTCGCGGATTTACAACCATACAAGATGGTAGTTTACCGTCCAACAGCCCGGATAGGGTGATTGAGAAATAACAGTGGACGCACTCCATGTTTCCTCTGGGCCAAGAGGCAATACAGTATACATTCAATGTATCTTCCTAATTCAGGCATTATGCTGTTTAATTGTGATACAAACCGGGAAATGTACTAGGGCCTGTGCTATTATATTATCATCAGAAATTATGTTTATATATGCAGTATTGTGAGTTGTATTGTAAGTTGTATTGTAAGTTATTTGTAAATAAGCTACATATATTTGTAAATTATGCATTTTTATATGAAAAAAATAACAAAAGACAATACAAATATAGAGGAATGAGATTTTAATAAATAATTTAACATAATTATGTAATTTTATATTTTTAAACTGGGTATCACTAAATAAAATCATAAAATCACAAAAAAAAAAAAAAAAAAAAAAAAAAA
->XM_053452891.1 PREDICTED: Spea bombifrons zinc finger protein 217 (LOC128471049), mRNA 
-AGAGAGGATGAGAGCCTCACACCCAGGAAGTGCTTTCCCAAAATGACTAGAAGAAGAATAAGAGGCAGCAGGTACAGCGGCCAGAGGTAGCCCCAGCTCCAAGTGATGGACCTTTTGGGTTTCCCATGACGATGCGCAAATTCAGTCCTATTTACATCTGAAGGAAACGTGTGCATTGTTCAGGGGTTCTTCTCTCATCCATTATAACAAAGGATACATACCAATGTCTTCACAGAATTGACAAATGAAGAATTGACAGCTAATCTTCTCTGGAAGGAAACTACGAGCAGTACTTGAGATCTACAGTGGCATTCACATGTATGTGTCTTTAATTGCCCACAGCTTTCCTTATGTTCCTAAGGAACTTCTAACTAAAAAGTTGGCCCGCAGCACTGGAATTCTAAATCTGGCAGCAACCATGCCGGTTCAATCAATTTCCGATGGTTCTGATGTCTTGGGTACTGGCTTTAATTCCCAAATGGAAAGTTCTCATTCATCATTGGCACTCCAGCCTGCAAACACCCTTTCCAATGCAGCATTGCATGAAAAATGTTTAATGCAGACAGAGGGGGACATGCTGTTCGATTGCATGTTTTGTGACAAAACCTATACCTTTCATGAAGAACTTGGGAAACATGTCTTGGTCCAACACAGGCCAATACTGTGTGAGCCAGCCGTTCTTCGTGTGGAGGCAGAGTACCTCAGTCCCCAAGATAAACGCAGGAAAAGTGGAGAGCTTTCAACGAACGATGAACTTGATGAAGCTGAACATAGACTAGGCTTTGACTGCGAAGTATGCGGCCAGACCTTTAATGATTCTTCAGATGTGGAAGGTCACATGAAGAAGCACAAAGATTCGTTCACGTACTCTTGTGATATCTGTGGACGGAGATTCAAGGAGTCGTGGTTTCTGAAGAACCACAAGAGAACACACAGTACAAAGTCTGGAGGCAAAAACAAGCAACTGATAATCAGCGAGATGCCTATGACCATTAATGAAGTGGTATTGGAGCAAGTGGACAAAAATGTCCTGTGTCCTTACAAGCTGTGTGTGGTTTGTGGATTCTTTTTCCCCAATAAAGAATGCTTAATGGAGCACAGTAAGATACACCTTAAGGAATCTACCTCATCCGAAAATGGCTTAAATGAGCTGCCACCTCCAACAAATAATTCTGTACAATCTGAGGCTAGCGAAAATGCAAAAGGAGATGCTTCAAAAGAAGCCTTAATGAGGATGTTAAACTTACAACCTAGATCTGCAGGACCAAAGAACGCTGAAACATCTAGAAGATGGATTGGGGCCTTAGATCCATTCAACACCTACCAAGCCTGGCAACTGGCTACCAAAGGTAAAATTGCACTTGCCCATGGTAGAGTTAAAGAACCTTCGCATGAAGTAAACTTTCATATAGATCCATGTTCGGACAAGGACAAACCCAGTAAACTTTGGAAAACGGGAAAGGTTAGTCGTGCTGGAAGCACCCATCAGACCAAGAGTGAGGTCTGCGAAGGACACACGACTTCCCAGGATGGCCAACATGTACATCTGCAAAACGAAGCCAACGACGTGCCTTACGTAGACGACAAAGACAGGCCAACGTTTTGTGACGATTGTGGGAAAACGTTCAAGACCTACCACCAGCTTGTGTTACATTCACGAGCGCACAGAAAAGAGAGGAGCGATTCCGAATGTTCCGCGATGAGCGGGGAAGTCCTCTTGCCTAAGGTGGCCTCGCCGGATATCGCCAGCAGTTTGGAAGACGCTGATGCTATGAAAATGCACGATGATTCCGAGGATGGGTCAGAAGATCCTGGAGGCGATCCTACACAGATTGATGATAAAAATGAAGACGATCTAGAAAGGGGGAAAGCAAAAGGCCTCTCTGTATCTCGGAACTGCAGTTATTGTGGAAAGAGTTTCCGCTCAAATTATTACCTCAATATTCATCTCAGGACTCACACAGGTGAAAAGCCATACAAATGTCAGTTGTGTGACTATGCCGCAGCACAGAAGACCTCGTTAAGATACCATCTGGAGAGACATCATAAATTTAAACCAGGAGATTCCAACGCCATGGTGAAAAGCATCAGCAAAACCGTACAACTCGCTCAACAATCTGGCGAACATGCGTCTCTTACTTCCAACCTAACAGAAACAAAACCTCTGAAAAAGCTTGAGGCAAACTCTAAAGAGGAGAGCCCACCATTAAAACCGAAACGTGTTTCTTCTTCGCGTAACAAGTTTGTGACCGCAGCTCAGTCTCCAGAAACCGAAGAAGCCGTCGTTGATGGATACCCAATCTTTCCAAACGACTCCAATGTGAAAGAGCTACCTCCTTCCCAATCTGTGACCAAAGACAATGTGCCTGTTGATATGGAAGTTGACCGAGAAAGCCATACCACCATGGATGAAAGCTTTGCCGAGCAGGGTCATTTTGAAATCACTCCTATGCTGGCCGAGGAGTTGGTCCTATTAAACTTGTGTTTAAAATCGGATAATGGCCTTTCAGCACCTCTGGATACCAATGCCTTGCTTTTTAAGACCTGCCCTTATTGTACTTTCAAAACCTTGCACCCAGAAGTGCTGGAAATTCATCAGAAATTGACTCACAAACCTAATCTTGCCGAGAAGAATGGCGGCAAACTCAAATCTGTGCTGAATGCCATTAAAAAGAGGCGTACCGGCTGCCCTCCTGCACTTAACGGAATGGACATTTCTCCTGCACCTTGCAGTGGTCTTAAAGCCAAAGCTCCTCTAACGCAACCAAAAACCCTCAACAATGAAAAGGTGAAACGGGCGGCTTTTTTGCCTGCGAAAGCCGTGCCCTTGGATCAAGAGAATGCAATGCTTGCACATAAACACAATGGGGCTTTGCTGAACAATTACACGTACGTGCAACCTGACTTACAAGGAATTTCTCACCTGCTTGAAAGGATGCAACCGCCTGAACCAAGTAGGGCTTCTTGGAATGCGCCAACTACCAGCAGGGGGAATTCTACCGCTGCAACTACAGAATACGCCTATCAGACATCCCAGGCCTGGCCTGGCGCTCAGAATCTGTTTGCCAGACCCCTGAACTCAAATCACGAGCCGTGCCCAAAGAAGGCCAAGTTCAATATTACGACAAAGGATGACATGTTCAAAAAACCGCTTCCACTTGGGCATACTGGGATGTTTCCACAAGATATGGCAGCGGCAACTGGAAGCTCATTGCTACCTAACAAGGGCTATAACACCTGTGAAGCTGGTTCTTCAAAAGCAATGAAGCCTCCTGCCCAAAGCACTGCTAGATTTGCATGCGTTAATCCGGGATCTACCTCCGCCACCGACGGAAGAAGTCCACCATACCGTCGTGTATCCAAGAGAAGCTTGACACCAAATGATAAACGGGTGTGAAGGATACCCTTTGTTTAAAAAGGGTAAGCAATGATTTGCTGTTCTTTGAGCCACTGTAGCGTGAGTGAGTGTGGGATCGAGTATTGTATAAAAGAGAAGTGGAGCGATTCTATCCAGCTGCGAGAGCCTGTCTC
->XM_039175744.1 PREDICTED: Hibiscus syriacus profilin (LOC120166485), transcript variant X2, mRNA 
-AAAAGACAGAATTTCATCAACGGAAAAATAATATATTCGAGAGAAGTAGAGGAAGGAGAAAATGTCGTGGCAAACGTATGTAGATGATCACTTGTTGTGTGAAATCGAAGGCAACACTCTCTCTGCCGCCGCCATCATCGGTCAAGACGGCAGCGTTTGGGCCCAGAGCTCCAATTTCCCTCGGTTCAAGCCAGAAGAAATCTCTGCTATTATGAATGACTTTGTTGAACCTGGATCACTTGCCCCCACCGGATTGTACCTTGGTGGCACAAAATATATGGTGATCCAAGGAGAAGCCGGAGCTGTTATTCGAGGGAAAAAGGGGCCTGGAGGAGTTACTGTTAAAAAGACCAATCAAGCCTTGATCATCGGGATCTATGATGAACCAATGACTCCTGGCCAATGCAACATGATTGTTGAAAAGCTCGGTGATTATCTCATTGAACAGGGTCTTTAATTTATTTAGCTTGCCTTAATTGTCGCAGTTCTTCTTGGCTTCTTTTTTCTATACGAAAGTGCACCTGCCACCTCCCGTAATAATGGTTGGATCGAGTTAAAATAACAGTATTAGTAGTATTAAAAGTCAAGGGGAACCTTTTTCCAGAAACAATAAGCTTGATGTTTGTAATAGTGATATGCTTGTGATCCTCTTGCTTTGTTTCTGTTCTTGTTTGATGAATGGTATTGTCAAGATTGTGGAGCGAGGTACTTTTGTCTACATTT
->XR_004882887.1 PREDICTED: Helianthus annuus uncharacterized LOC110916910 (LOC110916910), transcript variant X15, ncRNA 
-TTGTGTACTCTCCCATGGTTTGTGGCCCATCTTCTCCACTAGGCACGGTTGCTAGGACGTGGGTAGAATGCAGTTGCCCAGTGGTCTTATATAATATAGACCCTTGCATCCAAATATTCACCTCCATACATCTTTCAGTTTGTAGCAGATATGATATATGCACATAAATAAACACACCGTTGGTACCGCGTTCTTCAATCGTGATCTCAAACTTACATTCAATTGTTCTTCATTCAAGATCTGCCCTTCTCCTCTACTCGCCGCCGCTGTTGTTTGAGTCGGACATCGGCGCCGCCTCCGTTCTACACCCTTTTGTCATTTAACACACCCTGGCGCCACAAAATTTCTGAAATCAATCACAAGGTCGTTGATGTTCTTGGATAGGTTACTATCTCAGTTAAGGCTTAGTGGAGATAAATTATTAGTTGCAGAAGATCCTAAAGAGAAAGACATATCAACTTGAAAGTCCCAAGTGAGAGGAGGACAAAGGTCATTACTTGAGGCTAGCAATCTGATTGTTCTCAAGGGATATAAAAAGTAGTTGAGTGGAACCCATACACTAAAATTACTAAGTACTAATTACACTAGATAATGTGAGTTTGGAAGAAGGGGGCAAGGGGCCATGTGTAAGCCACTTAATGCTGGTATCCATGCCTATAGGCGTGTCGATATCAACCCAGACAATAAAGTTTCGATCTTTGGGGATGGACCCATCTCCACTTTTACACGGCAGGCTGAGCTCACGGTACTGGTTGGTTATTTTGGGACACAACAAAGTATGCCATGAATGGTTCAGCAAAACTTGATGCCAATCTTCAAGAGATATTTTTAATGGAAATTTGAAGGCTATTCAGGGATTGGGATAGTTTCAATAGCACCAAACCATGAGGGCTACTAACGGGCCAACCAACCCAACCCTTCTGAACTTGTGCAGAATTCTTGCTTGAAGCAATAAATGGACTTCTTTCGGACACCAGGTTTCAAATATGGCATTCAGAAAAGTGTACCCGTTGTCTGGATGAATACCCACCATTGTCGAATGAATCATTTGTCAATGAATGATGGGTATTACGTTCTTCAAGAAGGCTTTTGTAATGGTGTCAATCTTGATTCTGTTAGCTCTCAAGGTTGCCTATTATTTGAGTATATGGAATGGAATCAGCCTTGGGGTAGAGAACCTTTAGCTGATAAGGTTAAGCCTTGCCACACGCCATCCTATTTACGAGGGTTACGCCTTGCCACATGCCATCCTCCGGTTAGATCTAGCAGGACGTTATCTAACCGTCTGGTTGATGAGATTCTACCAGAACGTAGAACGTGGGTATACATTCACCAGAACCGCAAAACGGGAAATTGTTAGAGACATGAAAGAAAAACGGGCGTACATCGCTCTAGACTATGTTAGAGACATGAGAAGAGTTTCGAACTGCCCGGCGAGCAGGTCATTACCATTGGTCAACAATGTTAATATTCCTAAGAATCAATCCAGATTCTTTGAGCAACAATCAATCCAGATTCATATTTCACTAAAGATGTAAACAACTACTTCCAATTCTTTAATTTGCAAATAGAGTTTGAAATTGTTTATTAGTTTGATTTCATAAACTTGAAACGATACCATCATACAGATTCTAATCATTGTATTT
->XR_007968113.1 PREDICTED: Xyrauchen texanus putative uncharacterized protein FLJ46204 (LOC127624086), transcript variant X2, misc_RNA 
-CACACACACACACACACACACACTCACACACACTCACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACATGTTGTGTTTCCATGTTTTATGGGGACTTTCCATAGACATAATGGTTTTTATACTGTACAAACTTTATATTCTATCCCCTAAACCTAACCCTACCCCTAAACCTAACCCTCACAGAAAACTTTCTGCATTTTTACATTTTCAAAAAACATAATTTAGTATGATTTATAAGCTGTTTTCCTCATGGGGACCGACAAAATGTCCCCACAAGGTCAAAAATTTCGGGTTTTACTATCCTTATGGGGACATTTGGTCCCCACAAAGTGATAAATACACGCTCACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACACAGGCTGGTGATTCTCAACGGATGGGTCTCAGGTCTCATTTAAGAGCAGACAGCAGGTTAAAACAATTCAATGCAACTAACCATATAATCATTAATAGACAAGATAGAGAAACAAATAGACTTTATCGACTTTTGAAAGGTTGGAGTAATCACTTCCCATATCAG
->XM_026403930.1 PREDICTED: Urocitellus parryii CUGBP Elav-like family member 3 (Celf3), transcript variant X37, mRNA 
-ATGAAGGAGCCGGATGCCATCAAGCTGTTTGTGGGGCAGATCCCGAGGCATCTGGAGGAAAAGGACCTGAAACCCATCTTCGAGCAGTTTGGTCGGATCTTCGAGCTGACTGTCATCAAGGACAAGTACACCGGGCTGCACAAGGGATGTGCCTTCCTGACATACTGTGCCCGCGATTCAGCCCTGAAGGCCCAGAGTGCCCTGCACGAACAGAAGACGCTTCCAGGGATGAACAGGCCGATCCAGGTCAAGCCCGCCGACAGCGAGAGCCGAGGAGACCGGAAGCTCTTTGTGGGGATGCTAGGGAAGCAGCAGACAGATGAGGACGTCCGGAAGATGTTCGAGCCCTTCGGGACCATAGATGAGTGCACTGTGCTCCGGGGGCCAGATGGCACCAGCAAAGGCTGCGCCTTCGTGAAGTTCCAGACCCATGCTGAGGCCCAGGCCGCCATCAACACCCTCCACAGCAGCCGGACCCTGCCTGGTGCCTCATCCAGCCTGGTGGTGAAGTTCGCTGACACCGAGAAGGAGCGAGGTCTGCGACGCATGCAGCAGGTGGCCACCCAGCTGGGCATGTTCAGCCCCATCGCCCTCCAGTTTGGAGCCTACAGCGCCTACACCCAGCTGATGCAGCAGCAGGCGGCCCTGGTAGCGGCCCACAGTGCCTACCTCAGCCCCATGGCCACCATGGCTGCCGTGCAGATGCAGCACATGGCCGCCATCAATGCCAACGGCCTCATCGCCACCCCCATCACCCCCTCCTCAGGAACCAGCACCCCTCCTGCCATCGCTGCCACGCCCGTCTCTGCCATCCCTGCTGCCCTGGGCGTCAACGGCTACAGCCCGGTGCCCACCCAGCCCACTGGGCAGCCTGCCCCCGATGCTCTGTATCCCAACGGGGTTCACCCCTACCCAGCCCAGAGCCCTGCGGCCCCCGTGGACCCCCTGCAGCAGGCCTACGCAGGGATGCAGCACTACACAGGCCCAGCAGCCTACCCGGCAGCCTACAGCCTGGTTGCGCCCGCGTTCCCGCAGCCTCCTGCCCTAGTGCAGCAGCAGCAGCGAGAAGGCCCTGATGGCTGTAACATCTTCATCTACCACCTGCCCCAGGAGTTCACGGACTCAGAGATCCTCCAGATGTTTGTCCCCTTTGGCTTTGTGAGTTTCGACAATCCGGCCAGTGCCCAGGCGGCCATCCAGGCCATGAATGGTTTCCAGATCGGCATGAAGCGCCTCAAAGTCCAGCTAAAGCGGCCTAAGGATGCCAACCGGCCCTACTGA
->XM_034920330.1 PREDICTED: Acipenser ruthenus E3 ubiquitin-protein ligase TRIM52-like (LOC117972083), transcript variant X1, mRNA 
-CAAACATCAGAAACAACCATAAATCTAGAGGACCACTGTCACTGTCATTGTGAAATACACAGCGGGAAATGAACTGACTCATACTGAGACTGAGAGAGAGAGAGGAATTGAAATCAGCAATTAAGGTTTGAGAGATTTTCAGCCTGTCCTCAACATAATGATGTCATCGTCTCCGGAGGCGGAGCTGGCGGAGAGCCTGACCAATGAGGTGACGTGTCCCATCTGCCTGGAGCTGTACTGCGACCCTGTGCGGCTGGAGTGCGAGCACAATTTCTGCCGTAGCTGCATCAGTAAGTACTGGCTGCGGGGCGGGGAGGAGGGCAGTGCCCCGGAGGGGCAGAGCCAGGCCTTCACCTGCCCCCAGTGCCGCGAGATCTTCCCCCAGCTCCAGCTCAGGACCAACCGGCTGCTCTGCAACATCGTGGAGCGCGTGCGCAAGCTCCGAGTGGACTCCTGGGGCACGGCTTCGGCCTCTCCACCAGAGGGCAGCGGCGCAGCAGAGAGGGGCACTCCGGCGGGGTTCTGTGCGAAGCATGGCGAGAGACTGAAGGTGTACTGCCAGGATGAGCAGGTGGCAATCTGCGTGGTGTGCGCTGTGTCCAGAGATCATAAAGACCACAGCATGGCACCCATACAAGAAGCACTGCAAGAGTGCAAGGAGAGGTTTGAGTCGGCGCTGACTGAGTTTGAAGAACAGAAGGAAAAAATCCGGACTATGCACTCGAAACACGAGAGAGAGCTGAATGACCTAAAGGACTCTGCTGCCTCTCTTGAGAGGGGGATCTGCTCCCAGGTGGAGGAGCTCCTGCAGTTCCTGGAGGCTGAGAAGAAGGCGCTGTGCTCCCAACTGCAGGCTGACCTGCGCAGGCTGGAGCAGCAGAGAGAGGGGGTGCTCAGCGCAGCACAACAGGAAGTGACCCACCTGCAGCAGGACGTGACCTCACTGCAGGGCAGGCTGGCAAGGGAGGGGCTGGAGAAGGATGGGCAAGAAGTGGGCGACGCCCCAGCGCTAATTAAGGAAAGTGACTTCCTGTTTTTTTTTATTATTATTATTATGGAAGTTTATGTAAGTTTGTTAGCGTGAAGGATTGCGATTCTTTTAACTTTTGAGCAGCTTTTTGGCTGGATTTGAAAGTGTGTATACAGCTTCATACCTGCAGAGGAACTGAACTGCTTGACTCAGTTTCTTCTAGTTTCTGTAACACTGATGAAGGCACTCGCTGAAACGCTTGTCTGC
->XR_007189094.1 PREDICTED: Ursus arctos uncharacterized LOC125282004 (LOC125282004), transcript variant X1, ncRNA 
-TTTTTTTTTTTTTTTTTTTTAACACAGATAGAGACAGCCAGCGAGAGAGGGAACACAAGCAGGGGGAGTGGGAGAGGAAGAAGCAGGCTCATAGCGGAGGAGCCTGATGCGGGGCTCGATCCCATAACGCTGGGATCACGCCCTGAGCCGAAGGCAGATGCTTAACCGCTGTGCCACCCAGGCGCCCCGGAAATTTAAATACTTTTAACATATTTTTCCAGTTCCTTGGTCCTTCTCTCCCCAGTCATTCAATGGGAAGTAACGTAGATTTTTTTAAAAATATTCAAATTATACGTACATATATATCTATCTGTGTATACGTGTGTGTATTCAAATTAAACATACATATATGTATATATGTATACATATATATGTATATGTGCATATGCATGTATTGTGTGTATATATGTACATGTATGTATGTACACACACGTTTTAAGTAACTCTTGTATTATAGGAGATCCACTGTTTCCCCTTAGGATCAGATTTTGAATGTGTTCAGTTGTTGCTGTTAATTATCTTTCCATCTGTTTATGATGTTTAGTTTTCCTGCTTTTAGTGACCACTCTTATTATCTATAAGATGCATGGAAAGACTGCATCCCAGAAGAGCAGTAGTCAGTATTATAATGGTTTTATTTAATTAACTGAAAAAGGTTTTTTTCCTAAAATAATATCTTTCTAGGAAGTTAAAAAAATGTTCTCCAGAATACCTTCTATCTTAATGGATTGAAGGCTGCAGGTACAGGTAATTTTTTAGATTTCAACCTTTTATGGGGCTTAAGTTGAAAATGTTGTATAGTGTTTCAGCTTATAATTTTGCCTACTTTTCAAATGTAGTACACTAAAGGGCATGACTGTGGGACTGGTAAGTTTTGAGTTGCTTTTTTACATTTGCTCTTGGAGGTGTGCAGAGGCCTTATAAGGAGTTTCAGTTTGGGAATTAGGAACAGACAGACTGTCCTTGAGGTAGGTCAGGATCTGATCTTCTTCTCAGGTCAATTAAGGTCCCTCAGTGGGACAGGCGGAGGCAGGAAGGTGCCCACAGTTCGTGTCCCAGGTGAAATGGATTGCCAGCCGGTTGCTCCTTTTGTCTTGGTTGGGGTGTCTTTTCCAGCACGGCTCCCGACCCGCTCCCCAGTCTTACCTGTTAGCCACTTGTAGACTTTGTGATGCTCTGTGCATTTAGCTGTAAATGTTGCTTCATCTGTACGTGTTTTTCTTCTGTTGACCTCCTCAGGGATTTTAGATTTATAAAAAGTAAAATGCCCGTTGCGTCTTCTGGTTTGGCCACTGTTGATTGTATTAGTTAAAAAAAGATTTGAATTGAGAAAGGTTTGACCTACTCTGAAAGGATAAAGACATACTGAGAATTAAGATTACATAGATTGTCAGCACATTAAAAAAAAGTACTTCCCTTTTGTTGGTTTCAAATAACAGAGTGAATCTGAGATAGGGCTTCAGAAGCCGGTTTAGAACTGGATCTTGGCTTCAGATCCCTGAATCCCTCGTAGTCCGCCCAGGATGAGATAACCCTGTATGAGCAGGGAGGTAACTTCCTTATGGGAGGACGTGTCCAGTCAGGGGTCCCTGCAGCCAGAGAGTCATGGATACATCCGAGTCTCCGTATTGTTTATACTGAGAATCTGTCAGGATAAGTTATGATGAGACCTACCTGCTCACCTCTGCACCAGGGGAGCTGCACCTTTGGTGAATTGTAATCTTGATTCTGGATCCCTTCTCAAGACATTCATGTGAACATTTTTTCCCAGAGTAGCCTGTGCTATAATGTGTGTAATAGAGCAGTTTCCTGGAGCATTGCACGGGTGGGAAATGTTGCTTCTTTCTTCATTTTGGTTCTCTCAGTTGTGGATGGCTTGCCTGGCAGACATGCAGAAAACATCTGTATACTGCTGAAGTTGTTCTGCCCCCACACTTTCCTTTAAAACTCTCTGGATTCTGATTGGCTCTACACGTTAAACATACTGACTTCTGATTACGGGCTTAGGGTGTGTGTGACAACGTTGTATTTACAGTGCTGCTTCATCTTTAACTCAGTTGGGTGTTAGAAAAATAAATGTGTGTGGTAGGTGTTCCCTCAGTTCTTTTAAAAGACTTTTTGTGGAAATTTTGGAAAAATTGGATAATGAACCCTTTTTCAACCTTCTGCCCTTGTTTGTCCTATTTCTTCTCTCCCAGACTTTTGTTTCCTGGGGTATTTTATTACTTTTAAAAATTTTTTTATTTTTTAATATTTATTTATTTGAGAGAGAGAACACAAGTAGGGGGGAGTGGCAGGCAGAGGGAGAGGGAGAAGCAGGCTCCCCACAGAGCAGAGAGCCCCATGCGGGGCTGGATCCCAGGACCCTGGGATCATGACCTGAGCTGAAGGCAGACGTTGAACTGACTGAGCCACCCAGGCACCCCAGATTGACTCCTTTCAATATGATTTATTGCCCAGTTTGAGGTATACTATGTGTGTCAGAACATGCCATCTAAAACATACCTGTCTATATGCAGAAAGTCAAACATAATATAATCATTATGTAAGATAGTGTTGTTCCCCAAGTACTACCATTAATAACAAAGTTCTAGCATTTTTTTCAAATGTTTAAGAATTAAAATATACCAGGATAATTAAGAATAATGTTTGGCTCTTTATTTAATTCAGCCTGAGGATAAACCTGAAAGATTAGGGGCCTTAAGATATTTTTCTTTTTTTTCTTTTTTTTTTTTTTTTTTTTTAAGGATTTTATTTATTTGTCAGAGAGAGTGTGTGCGTGCGTGCTTGAAGGGGGAGTGGCAGGCAGAGGGAGAGCAGGTTCTGTGATGAGCAAGGAGCCCAATGAGGGACTCGATCCCAGGACCCTGAGACCATGACCGGAGCCAAAGGCAGACACTTAACTGACTGAGCCACCCAGGTGCCCCTGTTTCGCTGGAGTATTTTAGAGCTAATCCCAGACATTGTATAAAGTTTCACCCATGAAAGTTCATTGTATGTCCCTAACAGATAAAATATATAACCATAATACCTTTACCATGCCTCACATAGTTAAAAGTAATTTAAAATCTTTTCTCTCAGGGCACCTGGGTGGCTAAGTCGGTTGTGTGTCCAACTCTTGATCTCAGCTTAGCTCTTGATCTCAGGGTTGTGGGTTTGGGCCCTGTGATGGGCTCCACACTAGGTGTGGAGCCTACTTAAATTAAAAAAAGAAAGGAAGAAAGAAGGAAAGAAAAAAGTAATAAAATCTTTTCTCTAATAAAACTCGGTAATGTTTAATTTTCAAATTTCCCCATTTTTTTAAAAAAGTCTTTGACCTATCAGTTGGCATATCTCTAACATTTCCCACTCCTGCCTTGCACCCTTTCCGTTTTATTTTTAAATAACAGCTTTTGTTGATGCTCTGGAAGAAACTGTCATTTATCCTATAGAATCTCCCACATTCTGAATTTGGCTGATTGTATTATGTGATGTCATTTAATTCATAAAGTTTAAAACTGGTTGCTAGAAGTCCAGCTAGAATGAGCTTCAACTCTGGGGGTAAGAATACTTGCTGTTGGCTTCACCTCTTAGGGACGGTGACATTAATCATTTGTTCAGATGGTGGTGTGATCCTTCCACCTTGTGGCTTTTGTGGGTGTTGATGGTGGCTGCCTGGGTACTTTGTATCAGAATTGCAGACACGGTGACGATCTGATTCTGCCTTCTGTATTTGTTTGCTGGAGCCCGTGCAGAAAAGGTGGGATAAATGGATAATTCTTGTATTTACTAGCTTCAGAATGAGTTTGTTCTCTACAAGTGAAAATTATTTTTAGTCTCATAAATGCATAGATGTTAAGATGACCTATATATGTGTATGTGTACACACATACGTAGATGTTAATTTACAGCATTCTTTCTGATGGTCAGATTGCCCTTCAGAGGTATCTTCTGTGTCATATGCAGACAATGAATCATTGCCACTAGATCAAAAACTAATGACGTACTGTATGGTGACTAACGTAACATAAAAAAAAAAAAAAGATATCTTCTGTGTCCTTTGGAAATGGCTCCAGTAATGTTTTTATAGTTTTCTTGTTTATGGGCACTATAAAATAGTTTCAGACTCAGTTTGTACCCTTATTGCCGCAGACCTGAAACCAGCCATCTCTCTAAGGAGCCTTGATTCCTTGTCACGTTTTAGTGGGAAATGGTGTTCAGGGACTAGAATCTGGATACTGTGATAGGTAATGCTGGAATCTTATTTCTTCTGGGCTTTTTTAGGGTATAGAGATAGGAAGTGTGTATTTTTCAGAAAGAAAAAAAGTCATGAGTTTATCTCGATACTTCCAACTTAAATTTAAGATTACAGTGGGGCGCCTGGGTGGCTCAGTCAGTTGGGCACCTGCCTTCTGCTTGGGGTCATGGTCCCAGGGTCCTGGGATCTGCCCTGCGTCGGGCTCCCTGCTCAGCGGGGAGTCTGCTTCTCCCTCACCCTCTGCTGCTCCCCCTGCTCGTGCTCTCTCTCTCTCTCTCTCTCGCTCTCAAATAAATAAAATCTAAAGTAAAAAAATTATAAGATTAAAATGGTTTACTTCTTTGATTTTATGTTTGTATGTCATTTCTCTTTTGCTTAAAATCTTGGTTCTTAACACTAACACGTTTGTGTCATTGCTTCATCATTCATGTCTGTGAAACTTGCGTGTCATTTCAGAATAACAGTGCCAGTGTTGTCACTAACAAGACCTCTGAACGTGTTTGAACGTGGTTTCTCTGTTTCATCTTGGTTTCAGTGATGCTATTACTAAAAGCAGTGTTAGACTTCATTATAGCTCTTGTACGCCATAGGGTGTAGCACACTGGGATGTACGGTCAGATTACAGCTCCGCGCTGAAGTTACACCACGCTTTGAAAGTTAGGCTTATTTCTTTCGTTTTTGAAGGGTAAGGAGCAGTGGGAACTCTCAGACACAACTGATGGGAGTATCGTTTTGTACGTCCACTTTGGACAGTAGTTTGGTGGCACTTACTACAGTGGAACGTGCACACTGGCCTCGTGGTTCCGTTCCAGGTGGACACACAGCAGAGATGCGTGCACGCGTGTACCAAGAAACAAGTGATTTGTACTAGTCCCAGACTGGAACGGAGAGAGAACTGGGGTACATTCATATGATGACGTGCTCTCCAGCAGTGACTGTGAAGCTCCAGGACACAGCGTGGGTGCTTTTCACAGCATACTTTGTAAAGAATGGCTAAGCCCCAAAGGATACATACTGTGTGATTTTCTTGTAAATTAAAAAAAAAAAGGATGTTTTTGAGTCTCCATGTTCTAATGTACACGCGTGCATATTTCTCAGTGTAGCTCATCTTGACCGCTTTATTTCACGCTGCAGCCTGCATTCCCCTGCGCGCCCACTTCCTGTCCCTCCGACCCTGCTGAACTTAGTAATTTTTAAAATAACACCACTTGACAATATACCGTATAATTTAGTTATTTATGATTTTATTGTTGTCTGTCTCGCCTAATAGAATGTAAACTCCATGTGGGCAGAAAAAATGTGTGTGTGTGTGAGAGAGAGAGAGAGAGAGAGAGAGAGAGCTACAGAGTCGGTGGTAGCTGGTTGACGCCATATTGGTAGCTTGAAACCGAACAGGGTGGGTGTATTTATACCACAGAAATCAGCACACACCACAGAGCGGGGCTGCCCCCACTGACTCCGCACAGAGCCAGTTGTTACACACTCACCAGGGCGTCCTGGTGCACATCTCTGTCTTTGCACACACACTGAGGTAGGGATTCATGGTATCGGAACAGTGCCCGGCATGCAGGAGGTGCTCACTAAATTCTGAGGTGAATTTTATTATTGAAGAAATGTTGAGGTGCAAATGGCAGAAACTTACACTAGCTAAAGTGAAAAAAGGGAATATATCATTTTATGTAACTTGGAGTGTATTTAACGAATAAGTTACCGGTTGGTATCTGGAAATAAGTCTCTAGAAAGTCAAATGAGAAAAAGAAGTACCAATAAATCCTAAAGGAACTGTAACTACCGTGGAAAATAAATAAGTCTAATAGTTCTTTGATGTAGCCTTGTTTAAAATTACAAGAAGTTAAACATCAACTCCCAGTCCGCCCAGCGCCGCCAGCCGCACACCCGCTGGTAGTTGCTGCATCCGTCTTTCTCCCCAGCCCTCGGCAGCCGACCACTGAGCTCTCTGACCCACAGATGTGCCTGTTGTGCACATTTCATGTGATCGGAATCCCGCATCCCGTGCTCTTCCGTGTCCAGCATCTCACTTAGGCTTCCATCCACGTGGGAGCACGTGTGGGCACCGTCGCTTTTTGTCGTGAGTGACGTGCAGCCGTGAAGACGCTGCGTTTGCCTCTGGGTGTCCGGCCCGCCGGAGCGTGCGAGCTGCCCTGGCCTCTGGCGGCAGTCGTGTGCGCGGAGCCCGGGTTCCACTCGTTCCCCAAGTTGACAGATACGTGGCAGAGGTGGACGCAGCTGCGGAGGCCCAGCCCAGCTTCTCGGCTCTTCACCCTCTGAAGCTCTCGCGGCCTCTCTTGTCCCCACTGCCTCAGCGGCTCTCTGAACGGTGTATTTTATGTGCTTTTCACCATTTTCTACTGCCAGCTGTTGCATCCGTCTTGGATTCAGAAATCTCACGTCTCTTTTTTTCATTTTACCTGTTAGAGACTAATTTTTTGATTTAAAAGAAGGAGGAAGGAGGAATGTTTTAATAAGTCAGCCATTTACAAATGTCCTTTTGTGTCAGTCTGGCCCTGATGAGGTTCAGCGTGGCTTGCGGAGTGGAGGCATTGCTGCTGTCAGTCAGGCCCTTTGGACCGAAGTAAGAAGGAAAGAACTACGATTTCTGCCATGTCAGGGGACATGGGAATATCCACAATCAAGCATTGATTTTGCTAACAGATTTTTAGGACTTACCTCCTTTATTTAAATTCAGACATTTATAAGTCATCGAGTTTTCTGGTCTAATGTAAAAAATTCATTATAACTGTTTCAAGTAAGATAAGGCTCTGACAGTTGAGTTACTGTAGTTCTGGTCCTTGAAAAAGAAACGTTAAGTACCTTTTTTGTCCTCAGAAGAGAACTTTAAAAATTGAGTGATTGTATTTAAGATGCATTGGGCAGAAATGTTTCTAGTTTTACAGACCCCTTAGGTGATAAGGCCTGGACGTGGGGAGCCTTGGAGTTGAGGTGGACGGAGCCACTGGGAGAGAGTGAAATATGGGGAGGACCAGGATTTTGGGGAGGCATTGGTGGAGCCAGTGAAAACCTCGGTAGTCAAGATAAGTAATAGCTTGATGCAGCGTTTAAAAAAGAAAAAACAAAAAAAAACCTTAATGCAAAAAATCCATGGTGAACAAGATACTAAAATTTTAAATAAAGATAAGAGCAGTATTTTTCATTTTTCCTTTAGCCTTATGTGTTAGCTAATGTGCAGCATTGCTCCTTATTCTGTCTTTATTTCTACTTAGAGTTTAATTTGCTCTTATTTTTCTTACCTCTTTAGACAGTTGATGTTTTTACCTTTTAAATAGAAGCACTTGAAGTTTGAAATGTCCCTCTAAATACTCTCAGCTGTGTCCCAAAGATTTTGATGTTCTAGTTTTATTATCACTGTGTTCTGAACATTTTCTGATTTCTTTTTTGATTTGTTATTTGATGGGCGTGTTACTTAGAAAGGATTGCTTTCTTGGGAAATAGTGGGGACTTCGCTAGGTACTGTATCTTTAAAATAGTTACTTTTTATGTTCACTTATTATTTTGAACAGAAATATAGATGGCACAATATTCAAATGGGCAGGCAGGGAACCCTAACCCTCCCCCTCTTTAACCCGATTTCTGCTGAATTCTGTCTGGAAGAGTCACTGTTCATAATTGTGTAAATGTCTGTGGGTGATCTGTGCATATAACAGGAAGCACATATGTGCATGTATTTTTCCTTTACAATGAAATACCACAGTCTACATACTCTTCTATACCTTTTTATTATTTGAAATATATATCTTGGGGTTCCTGGTGGCTCAGTCCTTTGAGCGTCTGACTCTAGATTTTGGCTCAGGTCATGATCTTAAGGTCGTGCGATCGAGCCTTGTGTAGGGCTCTGCTCTGGGCAAAGAGCGTGCTTGGGATTCTCTCTCTCCCTCTGCCCCCAACCCCTAGCTTGCATGTGCTCTCGCTTGCTCTCAAAAAAATTTTTATATAGACAGGTATATATCTTGAAAATGTATGCATTTTAGGACTGGGAGTTACAGTTTTCTTTTATACTATGTGGACTTTTTTCATTGATGAGTGTTTTCCAGTGTCAGTGAAGAATTTTCAGTGAGTATCTTTTTCCAAACTTTATTTACTCATTTCTTTTCTATTGACATGTAGGCTGTTCCTAGTTTTTTAGTTTTGTGAATGAACCTATGATTCATTTAAGCCTCAAACTGCCTTAAACCTTAAAGGGGATTACTGGAGGTTTCTTGGACCAGTCTGACGGAAGCTGGATCTATGGGTGCAGTGACTTAAGTGCTTGTCTTCTTGTGGGCTCTGAACTCCTTAGGGGCCAGACCTCTGTCCGTATTGTCTTCCAATCCCTGATGCTTAACTCGTTGCACCAACACAGAAGATGTGGAACAGTGCCCTAGGCACGCAGCACTCTCAAAGCCCTTGATGCTTGTAATACTTAATTCTCATAACAACTGTTTGTAACTTTATTTAACTGATGAGAAAACCAAGTTCTAGAGAACAGTTTTTTAAGAAAGTGCCCAGAGTCCTATATCTAGTATGTTGCCACGTGGGGATTCAGGGAGTACTTACCAATAAGCTGAATGGACAACACTGGACTTTCAGGTTGAAGGTGGTGGAAAGATGAATGAGTTTGAGCTTTGGGGTCATTGATTTTACAAGGTCCGATCTTAACTCCAAGTCCTTTATCTCTGTCAGCCTCAGCTCCCTCTTTCTTGAAAATAATGTTGTTAACCTTGAAAATAAAACTGCCAGTCATTTTACCAGCGAAAATGGGTTTATTTGGGAACAGCAAAGAATTGCAAAGGCAGGCAAGCAAGCAGGGAGGCAGCACAAAGGAGAGGACTGCTCTTTTATAGAGGAAAGGTGGGGAGTTGGGAGGGAGGAGGAACCTTCCTCCTGCTGGGTTAGTCAAGTGGTATCCGCCTGCAAGGTGCACCTCTCCTTGTTGGGCCTGCAGTGGGGGAGGAGTGGGGAGGTGAGAGCTACCCCTGCTGGCCTCCAGACTCCATCCTAAGTGGGGCCTCCTGTTATTAATCTTCACGACGTATTGGTAATGACCTCAGAGTTTATTAAGGAGTTAACTTTTCCTCGTAGTATTGGACTAGTGTCCTGTCTTTACTCAAGGACCGGTGGTTGTCATTCCCTTTTGCTGCTGCTTGCGCTTTGGGCAAGTTCCTAGCGTCTCAAGGCTTTTTTCCCTCATCTACAAAAGTAGACATAATTATATTCGCCAGCTTGTTGTAAAATAAGCAAGAGACGCTCCATTAAAGTGGTTTTAGCATTCTTTGAATTTTTATTGTGGTAAACAAAAAACAACATAATTTATCCTCTTAACCATTTTTGTACAGTCGTGTTACATATATTTACATTGTTGGGAACCAGATGGCTGGCACTTTTTATCTTGCACACTGAAGCTCTGTCCCCATTGTTTTCTGAGGTGATAGCACCCTGGGTCACACCATTTTATATTCCCACCCATGGTGCACAAGGGTTCCGGCTTCTCAGTGTCCTGGCTAACGCTTGTTATTTCCTATTTCCCATTTAAAAAAAAAAAGAAGAAGTAATCATCCTGATAGGTGTGAGGTTATTTATAACATTTTTTAATGATAAAAATTTTAGGGAGAATTGGAAAAATGACTTTAAATTTCTTGCTAAATCGGAATAGTATCTGTTGATACCAGTGTGAGAAAACCAAAAGCATAGAGGAGGGCCTTTGAGCAAGAGGACCCACGACTGTGTATCTGTGTTTGGGAAGAAAAGTCGCCTTCTTCAGGGCTCTCCTTAGGATACAGCTGGGGGAGGACTGGACCCCTACGATGCTGCTGATCCTTCCTGAAAATGGGCAGTGTAGGTGGTAGAAGGGACCTGCTCGCCAGCAGGGCCCCCTGCCACCCACGGGCCTTCCCGTGTGGCTGTGTGGGTGTCACCGCACAGCCGATATCCCGCAAGCCACCACTGTTTTCTCAGCCGCAGTCCCAACAGGGCACTCTGCTGTTTGCTCGGTCAGGTGAGCGATCACACTGGGGGTAAACTGGATTTACTGGGTAAAATAAGAATTTACGGTGACAAAATGATAAAGTAAGTTGGCTGTATATTGATGTTCACTAAAACAGGAGTTGCAAAGTTTATTCGAATGGTGTTAACATTCAAATAAATAATGGCTTGTTTTTCAGTATTTGTTACTTGGTCAGTATACGCCAAGAAACCCCACTCTGTTTTATAACACGTACAGTTAGGGTGACAATTTTGGTCAGTTTCTGGCCCCGTGCTGTGTTATGCCTCTACTAGTATATTTGAAAAACTCAAGTGGCGTCGTCTTTGAGATTTCAGGAGCCTTTTTTGGTGGCAAATAACCTCCCAGCAGTTTCTAAACCTAGAATTAGCTTTCATCTCCTCTTTGGCAGAACACATGAGAAATGGCCATTAGTGTCTGTGAAAATACTCTAGTTGAGTATTGTCTAAATTGATAAGAAGTTCAGAATTTTCTGCCTCTTGCGGTTGCAGTTGCCCTTCTATTTTATGTATCTTATTTTGCTTAATTCATTGCTACGTGTATTTCCTGGTGATTGTGGTGCATCTCCCCGGTCCCCGCTCCATGTCCAGCATGTACTGTGTTGGCTTGTATCCGCAGTCGGGGGATCGCGGACTCGGGAGGACTGTCATGGGAGCCGCAGAATTTAGTGAGTTGGAGTGCTGCATGGGGATGAGAGCAGCCTGTCTGTCTCATATTCTTTCTGTGATTCAGTCATCCTTTGTAAGCCGAGGGAGGCCTGTTTCCTGGTTCTCTGGAAGCCTTTGCAGCCTCCGGAGGTGGTGTCGTTACCGGTGGTGGCTTGAGTGTGTGCTCTGGCAGGTGTCCCAGTGCTGGGGCCAGCTCTGCCGCCGACCAGTTAGCTGTGACGTCAGGCACGTTGCTTCATTTCTCGGTTCCTCGGTGTGTCCGCCTGTCAGGTGTGCCTTGTGAACTTGCTGGTTGTTGGAATTATTGATTGAAAAAATAGGTGAAGTCCTGCAGTGGGTTAGCGAAGGAGCACACGCTGGAGGCTGACTGCTGGAGCGCGATGTCCAGCTCGGCTCTGCAGGAGGTCTGTGACCTCAGACAAGTTACCTAGCGCCCCATGCTTCTGTTTGTCATCTCTTACACGGGGGTAGTAGAATCTACCTCATCAAGTTGGTTATTAATACCTGAGTCCATATGTTTAAAGTATCTAGGATAGGGCTTGGCACAGAGTAAGCATTAACTTGGCATCCCCATTGTATCATTATCATTATCTTTTCTTTGTCATTAGTGTTGCTATTATGCTATTTGCTGACTGCCACGTAGTCCCTACTCACGTGATAGGTATTGTCATTGTCCTTGTGGAAGTTCAGGATGGCGAAACGAGTCTTTCCTTGTCTCACAGATGGAACCGGGGTTCCTTTGTATCTTCCAGTTGCAAATTTAGTGCCTTCCTCAACTTCCCCAGAGTTCCTTCAGAGTAACAGAAGGGAGGAGGTATAGTAATTGTTAGAAACTCTGCAAGAACGGCGAATAACACCGTCCCCTTTTGGAGTATGTTGTATTTTGATACCTATTATCTGTTTGTCTTTGGAATATGCTTATATCCATTCTTATGATTAAATTTCTTTAGTCCTTATCAAGTCTTAATTTTTGTTGATAGATTAAAATTTTCAGAAAAGTTACTTCTGTTTTGTGGTGGAAACAGGCACAAAGACATAGGAATGATAACTCTGTGAATCGTAATAGAATTAAGTTTGGGATAGCACACCCAGCTTTTGGAAGTCAGGGTGTATTGTAGTGATCAGCTGCTAATTGGAGCTATCGTAGTCTAATAGTGTTGATTTTACTTAGATCTAGAACTCTTGATTAAAGCAAACATAAAAGAAGTAAGAGAGGTAAATTTTGAATTCTGTATGTGTAATATGAATTCCAGTTTTCTTTCACATTCCTCCTGTTAGCTGACTTGGAAGCATTGACTAGGGCTTTCCTCTTCCCAGAAGTACTGCCCTCAAGTATTAAGGCCAGCAAATAAAAGCATACAACTGTATGAGAAATGTGCGAGTCAGACTTGGATTTGTGTGATTTGCTTTTGGTGATATTTATAAGCAGCTTTTTTTTTTTTTTTTTTTAAAGATTTTATTTATTTGAGGGAGAGAGAGAAAGTAAGCACAAGTTGGGGGCAGGGGCAGAGGGAGAGGGAGAAGCAGGCTCCCCTGACATGGGACTCGATCCCAGGACCCTGAGATCATGACCTGAGCTGAAGGCAGATGCTTAACTGACTGAGCCACCTAGGCGCCCCTCCCCCACCTTTTAAAAGATTTTATTTATTTGCGCGAGAGAAGCAGTTTTTTCCTTAATCATTCTTTCCGGTGACTTTCTCACCTAAGACCAGGTTTCTGTAGGGAAGCTGTAGTGGACAGTACTGCACAGTGTATGAAGGGCTTTGGATTCCCTTTTCTCTCCCTCATCTTGCTCATCACCTTGTTTGCTGGCCTTCTAATGATTTCTGTCTAATCTTGCACAGTATTGTCACTTTTGTCATCCTGAAATTTGAAGTGGAGGTTCTCATGGGAGTACCAGAATACTACAGTTGTGTGATTTATTTTTTATGTGGGATGGGGAGAGGTGGTGTGCATGGTCTTCCTAGATTTTGTGTCAGTTTTTCTTTTCCAATTTTTATATTCTTGAAAAAGCAACATTTTCATATGGTTTACTTCTACTTATTCGGTGAATACTTACCAAGCACCTGAGCTGAGTGGGGTCTCGGAGGTAAAGCCGTGCCCAAGACTGAGGCAGGCCATGCTGCCACTGAGCTTAGTGCCAAGTCCTGACATCTAGAACGTCTAGATGCTTTTTTTGTGACCACGGCCTCTAAAAGAGAAGAGAAATTCCCTCTGTCCTCTCCTTGTTGCCTGTAGGTGACTGATGGATGTGTGGGATGTGGCCTGTACCTCTTCCTGGTCACTTCAGTAAGAAGGCCTGGAAGACAGTATGTGCAGAACAGATCAGATTCTTTCCTATTGTGGAGATGGGGTTGTAGTGGGGGCAGCTGGACAGCAAACGAACGTACTGTGTCAGTCAGTCCCGTGGTATTTGAGAAGGTGTAAGTGCCGTGGGAAATGAAGCAGGGTAAGGGCATGGGGCAGGCAGTATAAAGGTGGGCACGGGCCTGGTGTGGGCAGAGGACAGCAGGGAGGTCAGTGTGCAGTGTGTGGAAGGCCACGAAACAGGAGCCAGGCCGTGGCGAGACAGAGGGTGTAGGTGCGAGGGGAGCCACCTGTACAGGGCCTTGCGGACCATGCTGAGTATGTAGTTTGCACTGCTTCTGGCAGAATTGGGGAGCTGTCGGTGAGTTTTAGCGGAGTGAAATGGTGTGACGGGCGTCACGCAGGGAACTGGTTGGGAACAGAGTATAGGGCAGTGAGGCCTGTAGCCGCGGCCTGGTGGCACATGGCAACAGCTGGGCTGGTGGTGGCAGCGGACGTAGGGGCATGTGCACGGTCCAGATTGGGGTCCAAGCAAATCGTAGTCTCTTTCTTGTAAGTTTTAATGAGTTTACCTGTGAGGGAGGACTTCCCAGAGTTGCTTTTAACTATACTGATACGATAAAGAGTTTTTTAAAGAAACTAGAACTTTTTAAGGAATGATGGCCTTTATGTTAGTGCGTGAGTTTCTTATTCGGAGCGCATAAAGGGACTGCTCACCGTTTTCACTTAGGCCACCATTAATGTAGGCCTTTCCCGCTCTTTTCAAGACCTCACCGGCTCGAGAATCTAAGAGCCTCATTGGTCTTTCCTGTTTATCGAGAAGCAAACAGGAGTGGTGCCGTCCCAGAGTGACGTGTCCTCGTGTAATTTCTCAGCCCTTTGGCCGTAGGCCCGCGCCCCACTGCCTGAACCACACTCTCCTCTTCGCTGCACGCGGGGAACGAGCTGCTGTGTGTCGGGAGTGACGTGCGGCGGTTTTCTCTGTGACAGCGCCCAGCGCCCTAGCTTCTCCTCGGTGTGGCGGAGCCCCGTCCTCTCCTGCCCGCCCGCTCTTCTCAGTGGCCCGAGTGCTTCTCGGCTCTTCCGGGCTGCTGCTTCCGGCGGGGCTCTGCTTGGTGGCCTGGAGGGGTCTTGGCCTCTTTCGTCTTGTCATCTTTTGTATCCTCAGAACTCTGCACATGCGGAGGTGATATTTGGATATTGAGATAAATATAAATTAGCTCGAGGGGTGGGAGAGAAAGCTGCCGCCCACTGGTTACTTTGCAGTCAGAGAGTTGGCTTCTCCTCTCTGTCACCTAAAGAGCTCCCACGTCTGTCCTCTCGTCACCTCCTCTACTGCTGTGGAGGCTCCAGCCGCCGTGCCACTTGCTTGCACCAAGCCCTCTCTCTCCCGTGCAGGTGGTGCCGTGGCATTCATTCAGTCTGGCTCAGAAACCTTTTCTGGGTGTGTGCGTACAGGAAGACCTCTGGCTTCTTGGATGACAGGTGGGCTCTGCGAAGCCGTGTCTCTTCCTAGCTAAACGACTCCATCTTTAACTCCTCTTTCAAAGATGTGACAGCACTGGGGTGCCTTCGGCTCAGGGCGTGATCCTGGCGTTACGGGATCGAGCCCCACATCAGGCTCCTCTGCTATGAGCCTGCTTCTTCCTCTCCCACTCCCCCTGCTTGTGTTCCCCCTCTCGCTGGCTGTCTCTATCTCTGTCAGATAAATAAATAAAATCTTAAAAAAAAAAAAAAAAGATGTGACAGCACCGATGTTCCTCAGAAGACGTGAAAATTGGGTGTGTAAAATATCGTTGGCAACTAGTAAAGGTAGCTTCTGTTTTTTAAAGTCTTGAGTCGTAAGTTCCAAGAGAGACTCCGAGTTTGCCTTTGTGGTTGGCATGTCTGTTACTTGATGGTTCAGATTAAACCCGAAGCCATTCTCAGGGGCCTGGGTCAGATACCAGACTTGCTGCTGTGGCGTGCTTGGATTCCTCCTATGATGAGAGTAGGCCTTTGTGTCCCGAGTGTCCTCAGTAATGGTGATCTTTCTGCTTGTTTCTTCTGTTTCTTTCCTAGCTTGCTTGCCTGTGTTTTTCTGGAGCCCCTTTTCTTCCCAGTGTTGCCTGGGGTCAGAGTTCCTTCTGGTGAATGATATGTTTTCACTGGGGGCATCTAGGAGGTTATTTGAGCTCTGACTGCTATTAGGAGGCTGAATGTAACGCCTGGAGACAAAGCCATCATCGAGAGTAGTATGTCAGAAATGAAACTAGCTGTCCTGGGGCATCACTGGACACAGATAGGCCTCTTGTTCCCCTAGCCTTTTTCAGCTCTTGTTTTCACAAGTTAGTGAATTCATAAAACCCTGGTCGTGGTCACAGTTAAGCAGAGGACTCGATTTTTTCTTCGTTAATGGGATTTGCTACGGACAGAATTACCCGCGTAGTAGGAGAGCTGAACTGTCTATGTCTTGAATGTGTATCACATGTGCTCAGACAACAGAGGCTGTAGGAGCCCAGTTTCTTACTGTCTTACTGCCAGAGTGGAGTGTGTTTAAATAGCTACATTTTAGAGATGACCCAGACTATCTCTCAGTTTGAATGGAAAAAGTGTAAGTAGCTTTACATTTTTTTGAAAAAAACTTACTCGTACAGATTGTTAGAGTGTTTTTCTGTCTTCCTTCTTCAGTATGAGTTTCCTACTCACTCATGTTTTGAAATTAAGAAATTGGGCATCTTGTATTCCTCAATATTCCCTAAGCTAGTTTTAAAAGAATCTCGCAACTTCAAATTCTTGTTCCTGTGTGTTTTCTAAATACTTTTATAAATTTGCAGACTTAAAACTATCGATCTGAAAAAACCTTTACCTTGGAAATATCTGGGTTCCTATAGACATAGTTTCTACAGATTTGTTTTTAATGTTGATCAAGATGTTTTCCCCTGCATTATTCATTTTTCATCAAGACAATTACCTTAAGTCTTAAGGTCAGAATTAGGCTGGAAAAAGGCCAAAGGCATGAGTTTGAAAACAAAAATAGTCGGAGGAGCCATCTACAGACATGATCTGGGTCAGACTTGATTTGCAGCTTACTCAATTTTAGAATCGCCTGTTGGTTTTGTGAGCAGAGGTCTGCCAGATGAATTGAGCAGAAGGGTGGGATTAGCATATTAATCGGGTGCTGGCTACTGGCCTTCTTTTTCTCCTCCCTCTTTCCCCTCCCTCCCTCTCTCCTTCCCTGAATGAATCTAGGAACACAGGCCCCTGGGGTCACATTACTGGCTGGTTTCCTTCTGCTCTGGAGCTTAATCTAGCCAGGATGGTCTGTGTTTCAGATCGCAGAAGCAGAAGATTCTGTAACTGAGAGGCATTCTTCAGGCTGCCGGAAAAAATTACAGAAGGAGCACCTCCCAAATTTTGCTTCAAGCTCTGAGAAAAGGAGCACACAGGGGAAGCTTAGTGTGGCTGTGGATGGAAGCGAACGCTGTGGGAGCGATGAAAGGGGACTTGGTGCGCGGACGCCTGGTCTGATCTTGAGGCCTGAGTTTATGTTGCTGGAACTGGCGGGCCAAGAGGCCCTGAGACCAGCAGGTGCCGTCTGTATGGGGAAGAGCGGCTGTAGTCCCATTTCCGATGTGTTGGGCTAAAGGTATAGGTAACTTAAAAATCTGTTTGGTTTAAATTTTATTCAGATTCATGCTTTTGCATTAAAAAGGTGGATAAGAGTTTTTCAGACCTTATTTCAAATAGATTTACAACGAAATTTAAGGAAAAATGGAAATTGATGTACTACAGGTTTGCAGCTCTTGGCATAAAACCAACTAGATAGCTTTTAGAAGTAAATAAAAATATTTTTATCAAAGTGCATTTTAAGTAAGTTATCTTTTCTGTTCTGTGTCTCTTATAGTTTTATGTTTTATTTCGTGTGTTTTAATTAAGGCACCCATATCCGTTCTGTGATGTGGAAGTACGAGGCTAATTTTAACTTCAATAGGATTGGAGGGAAAAAGTGATGTGGTTTTTCTTTTTTCAAAAGTTGGTTCTCTTTACTCACTGTAAAGATTGTGCATTTAATTTGCAATTCCATATTATCGTAAGGTGGTCTTATCACTAAGGGTCAGTAATACTTGGATAAACATTTTCCAGTTTAATGTTTTTAGGGTTTTTATTTGTATAAAAATATAAAATACAGCATTTTCATTGTAACATTCAAGACAGTATTTGGGAAGCATGTTTAGAAGTTAAAAATGCCATGTAATCCATGTATGAATAAGACCAAATAATTTATCTGCTTCTCTTAAAGTATTAGTGAATATTATTCCCGGGGGATGAAGTCCGTAATAAAGAATTTAATACAGATACTGGTATTTTAAAGAGTATATTCAAGTATCACGTTAACCTACTCAGGAAAGACTTTTACAAGGAAGAAACCTGCGCTGGGTGAAGACCTGAAGTATTATAGTAGACCTTCAGGCTGATTCGGTTCAGTGTTTAGCTTGGAACTTTCAGAGCCGCCAGGATGTGGGGGTGCTCGCGCCCGCCAGACCACGGTTTAGATCGCTGTCAGATCGCGTCTCATTTACCAAGTTGTCGGCATCATCTAGTCATTCTTGTCTAGGCTTTTAAACATTTCCCCTTCCTTCCTTCCCTTCTCTTCCCTTCCCTTCCTTCCCTTCCTTTCCTTCTTTTCCTTCTTTTCCTTCCTTTCTTTGCTTTCTTTCTTGCTTTTTAGGTAATCTCTACACCCATCGTGGGGCTTGAACTCACTAACCCCAAGATCAGGAGAGTCGCCGACTGAGCCAGCGCCACTTTTAAACATTTCTAAAACATGTGACGTCAGACCTCAGATGTCAGACCAAACAAAACGCCTGTCACTTTATTACCTAATTAAGTATTTAGAGTAAAGATTTTGCTGAGTTAAATTCAAATTGTTGAATTTTAAAGGGCTTTGGGTATGGAAACTTCTGAAAACTGTAATTTCTCACCTGAGGACTGCACAGTATAATTGAGCATGACCAGTAACGAGTGCTCAGAGGCAGAGAGCTCTTTACTATTCTTGTTGAAGATTTTGGTCTCTCCCAGACTTGTTGGGACCTGTATGCACAATGCTGCCTCCGTGGTGTGACAGTCCTCTGTTAGCCCTGATCCTTAGCAATAAGGCTCTGATTTCACTAAGTCTAGGCTAGATTCATGTCTATGAATCCAGTAGCAATGGATATTAAATAGTTGGCTACTGGGTTTTTAAGAAATTCAAGGTGACTTTAGAAATATGAGCTTCAGAAGGAAAGAGAGACTGAGGTGCTTTTGCTCATCCCAAAGCAATTGATAGAAGCAGCTTATTTCCCAGTATGTTTACTGACTGGCAGAGCTCGTGAGGAGAGGCGTTTTTCACTGAGACGTCATTTCGATAGCGGTCAGGGTTGGGTAGGAGAGCAGAACCACGTGTATGAAAGAGGGGAAGAGGTAGGGACAGCATCAGGCTTAGATCATTGCATTTGCAGGCTGGAGCAGGCCGTCACCTCTGACGCATGGTCTTGTTTCTGGATTGTGCAAGAGGAGTTTTCTGACAACACTAAGGAGGTTGTCACCCTGTCCCCTTCTCAGGGCTGAGTACACCATCTCCCCAGGGGCACGCAGTGCTTATTGCTGTATTGGGATCAAGTGCCATTTAAAAAGTCCAGTCTCATTAAGTGTATGAGTTTCATGAGTCATTGAGTTTTATGGCTTCACAGGTAGGTGAAGCTGGTTACTCCCACCTAGTGAGATGGCCTTTGTCAGGAGCTAGGGAATTACAAAACAACTAACATGTATATAATGCCGAAAGCACTCTGACAAGCTGATTTTATCCCCACGGGAGTCCTACGCTGTAGGAACCATTGATGGCCCTATTTCTGAGATTGAAATTGAGGCAGAGAGTGCTTAAAAAAAACTTGTCCAAGGCCCTATAGCTTCTAGACTTTAGCCAGGCAGTCTGCTCTGGACGTTTTTGCCCTCAACCTTTGCTATTGCCTTTCAGCTAAATAGGGAGAAATAATTGTCAACAAGAGGTTTTAGCTGGACAAAGGAGAGGGAGAGGGTAGCTTTTGGTGTGGTTTATAGATTATTTTCTGGATAAAATGTAAAAATAATAGGAACGGTTTATTGGCTCTTGCTTGGTGGTAAAGGAGAATGAGAAATTAAAGATTTCTTTAAAAATTCAGGAGTGGGGGAGCCTGGGTGACTAACTCTACTAAGCGTCTGCCTTGGATTCAGGTCATGATCTCAGGGTCCTGGGATCCAGCCCTGCATCAGGCTCCCTGCTCAGCGGGGAGCCTGGTACTCTCTCTCCCTCCTCCTCTCCCCCAGCTTGTGTTCTTTCTCTCTCTCAAGTAAATTAAAAAAAAAAAAAAAAAAATTCAGGAATGACCCCAGCTCTGTAAAGGTATCTGCTGGTTGTTTCTCTGTGGTTAGTTTGAATGTACTTCTCTGGGGTTCGTGATGATAGTAAGGCAGTGTGCTGGTGTGTCTGTGCCCAATGCTGAAAATCACCACCCCAGAGGCAGTTTGAGGCCTGAGCTCGGTTGTTCAGCACTTGTCCCCCGTCTCTACTCACCACGAGTGCTATTTGAGGGAACTGCAATGAGCTCCTTCACAGGAAAATTGGCAGTTTGACGTTCAGTGCCACTCACTCCCATCATTTCTCACCTGACTACTTATCTTCCCACTCTTGCATTCCCAGGGTGATGCTTAGTTTTTTCTGGTTTTGATTTATTCGCCCTTGTCTCTGAGGCCTTTGTGTGGTTCAGATTTGAGTTGGGAGGCCAGATAGGAGTTCTGCCCACATCTCTGACTGACTGTGTTACCTTGGGCAGGTCACGGGAGATCTAGAACCCGTGGTTTCTTTATCTTCATTGCACCTGCGCCATGTACCTCACAGGGTTATGGGTGAGGGCCAAAAAAAAAAAAAGAAATTCCTGAAAGTGTCTTTTGAAGTATAAATGTATAGCATTATTAATGTTCCCAACCTCCCCAAGTTTCTTTGTCTACTCCCTGCTTTGATGCCATGCATAAGCTTTGGTCATGGTACCTTTTGCATTACTTGTTTACCTCTGTACCCTCAAAGGCCCTGTGTCTTACTGTCTTTGAATTTCCTAGCACTTGGCTCAAGGCACGTTGGAATGGGTACTGGCTCAGTAATGTTCAAATGAATGAGTAAAGAATGTCTGTCTAAGGGATGTTTCTGGTCATAGTTGTTTTTGTCGTTGTTCATCGTTTTTTCTGAATGAAGACTTCCTCCTTGTCTCTATGCTTCTTGAAGTTAGCCTTGTTAAAAATCTGCCCTTTCTTACTTTCTTGTGTTCCCTTTTGCAGGATGTTAAATTCCAGTATCTGTGGCCTCCTTCTTCAAGGGCTAGGCTTACTTTTAAATATTCATCTGATGAGTCTTGCTTTTAAACAATCAGATAAACAATCAGATAAATCAGTTCTTCCAGCTATTGACTTAGAGATAGAAAATATTTAATATTTATTGTTTGTGTATTCATTTAACAAATACGCCTTGAGTACCTTTTGGGTACCAAGCTCTGTTCCTGGGGCTAGGAACAGAGCAGTGAACAAATTGGATGAGATTCCTGGCCTTATGCAGCCTCCGGTCTAGTGGCGTGTCAGTCAGTGAAGAAGGAAATGAATACATAAGAGAATTTCAACGAATCTTAAGAGCTGTAGGAGGGAATCACGTGAAGAGGGCTTCTAGACCAGTGAGCAGTCGTCATATTTATAAATAAAACTGAATATGTTACCGATGTCGTGCTCTTAGTTTCCCTTTGTATCGGGTTACCTGAAAGGTATCTAATGGTGTTGATGGTGAGTACTTGAAGCTCTAGCCCATCCATGCCTCATCCACAAGAAAGATACAGAATGGCTGAGGAGGAAGGTGGCTATTCCCTGGACTTTTGGTTTCATGAGAGCACCTCAGTCTGTATGAGTGCTCCTCAACCTTGACTAGAACCCTCTTTGTTCAGGTAGCTCTTTTTGAGTATCTCTGATGGACCAAGGGGGACCCAGGAAAGATAAGGGAGTCATCGATCACCCAGTAACTTCGCTGTGCCATCTTGCTGTGTGTCAGTGCACCCACATCCTCAGTGCCAGGGAAACTGCTTGCTTATGGCATTGTGTGTCCACATTCGTTCTCCACATTGTTTACAATGTGCTCTGGATTATAAAGAAACAGTACAAATAAAATATGCCCAAGCCAACACCAGAGTATTTCATTAAGTACATAAGGACTTCCTAAAAAAATTTACTTTTACATGAGTAATTAAAGAGGAATAGACTTCTTCTGACAAAAATTTTTAACAGAAACTGGTAATAGTGACTTCCCCCCACCAAGAAAGAAACTAGGAGGGTAGGGCACAGAATTTGGGATCACAAATTAGCAAATGTTACAAATATAGCAAATAACAGGAAAATCATTCTCTTCCTGGACTAAGGCCTGTTAGGCCACCTCCTAAGTAAATATGTCTTTAATCTGTTCACTTTCTATTTAGTCCAGGTCACCTCTGCTGTCACCTGCATGGCCAGCATGCCTCCCTCTCCTCTTGATCCCCTTGTCTACTGTCCACGCAGCAACTAGGGTGATCTTTTAAAACACAACCATGCCACCAGCAGCCTCACGTGCTTGAAATTCACACCTGGTGTCACCCTTTGCCTGTTTGCTAAGCTTCGGCCATACTGCCCTTCTTTAACTATCACTGTCCTGAGCACCCCACCCTCCTTCAAAGCTCAGGGCCTTTGCATATGCTGCCCCCTCCACCTAGGACGCTCTCTGCCTCACTGAAGCAGGCTTCTCCTTTAGATCTCAGCTGAAATGTTTCTTCCTTGGAGAGAACTTCCCTGATTCCTCAATCCAAGTCTATCTTTAATTAATTATTCTCTCTCGCAGAACTCTGTTGTTTTCCTTCATGGCATGTATTCCAATTTGGTGTATCTGTATTTATTATCTGTCTTCTGCATTAGATTGTGAGGGCTATGGGGGCAGACGTCTTTACTGTGTTGTTTACAGCTGAAATACCAGAGCCACTTATTAGCACATAATCATTTAGTACATATTTGTTACGTGAATTAATGAATGAACAAACTGCTTGGGAACTTGAGTTCAGGACTTTATATCTGCCTTACGCATACTGTAAACCTGCTATGGTTCCGTTCCTCACTCCATCGGTGAAGATTTTGCTGTATCTCTCCTTAAACATCGCAGTTGGAAAATGCTCCCATTATTCATGTGCTCCACAGATCTTACCAGCATGTTACTGATTTCTATGCCCAAGTAACTGATAAAAACACTGTACCTAACAAAGCCAAAAATGAAACATCAGGTCACAGACTGACGTCTCTCTAGGTTGAGAGCTGAATATCTCACTTCTGATCCCGGAGTTGATACTCCTTTGTGTCTTACTCTTCGCCAAATCAAGAGAACCTATGAAGTTTGTCACACAGCCACATTGTCCACTGTGCCACCACCACGCTCAGCTCTCGATGTTCTCTAAACCTAGAGCCCTCTCACACACCGCATCGTGGCCTTCTGTAGCACGGATTCTCGGGGAGCTCCACTCAAGCTGCTGGAAATCACTGCTGCTCCTGTTAAGTGTACACATCTCCTGTTATCCCTTTACTGCGCTAAGGTAGCTAGTAGTGAAAATGAGCAGGGGAAACTATAGGTTTCACTTTGTTAGGATTTTTATTTGCTCCTGTCTCATCTCTTTTAGATTCACTCTAATATCTTGCAAGTCGTATCATTCAAATAAATATTTACTGAGCATCTGCTGTGGACCATGCACTATTTGAATCCCCATAGATTTAGGGCGATCAACACAAACCCCCTCAGTCCTGTATAGCTACAGTATGATCAGGCGCACAGAGAATTAAAAAAAATCATATCTAAAAACTGATGGAACATTATCTGATTTCAGTATCCTATTTCTTAAGTTGCTTTAAAATACCAATCTCATTAGGGTGCCTGGGTGGCTCAGTTGGCTGGGTGTCTGGTTCAGGTCATGATCTTGAGGTCCTGGGATTGAGCCCCATGTCAGATTCCCTGCTCAGCGGGGAGCCTACTTCTCCCTCTCCCTTTGCTCTTTGCCCCTGCTCGCGCTCTCTCTCTCTCAAATAAATAAAAAATCTTAAAAAAAAAATCAATCTCATCAAAACTTACACATCAGACTGGTTTTGTTCATATAAAGCTTTCATCTCCTCCAAAACTTGCCTGAGTCCATCCTCCTAGAACATACAAAATGATATTGATACACGTCCATTAATTCCACCAAGTCTGTAGCAATGTCTAATCTACTCTATGTTTATCTTTGATTCATATATCTTATCAAAAAGCAGTACCTGTGGGAATGCCTAGAACAAGTGTTGGTGAGGATGAGGAGAAAGTGGAACCCTCATACATTGTAGGGAGGAATATAAAATGGTGCAGCCCTATGAGAAACAGTCTGATGGTTCCTCAAAACGTTTAACATAGAATTACCATATTATCCAGCAATCCCACTTGTAGGTATATACTCAAAAGACTTGAAAACATATGTTCATTCAAAAACTGTGTATAAATGTTCAGAGCAGCATTCTTTATGGCAACCCCGAAGTAAAAACACCCAAACATCCATCAGCTGATGAACTAATAAACCAAATATGGCATATCCGTTCAATGGAATATTATTGGGGCATAAAAAGGAATGTAGTCCTGCATGCGTCAACATGGATGACCTTTGGAAACATTATTCTAAGTGAAATAAGCCAGACACAAAAGGATAACTATTGTGTGATTCCACTTACCCGAAATATCTAAAATAGGCAAATTCGTGAAGACAGAAAGTAGATTAGATGTTACCAGGGGCGGGGGGAAGAGGGAAATGGGGAGCTATTGCTTAATGGTTACAGAGTTTCTGTTTCAGTTGATGAAAAAGTTTTGGACAGAGGAGTGATGGCCGCACAATGATGTGAATGTAATTGAGGGCACTGAAGTGCACACTTAAAATTGGCTAAAATGGCAGCTTTTATGTTATATTTTACCACAATAAAAAATAGAGGAAACAAGCAATAAAAGGAATGAATTACTGACAACGTAAGCAATCAACATACTGATGAAGGATATTCTCAAGTACACTGTACTCAGCAAAAGAAGTCCGATACAAAGGAGTACATACTGTACGATCCCTACTGGCCCTTCCCAGAAAAAGTATGCAACTCCTGGCACCCTGAATCCAGACACCTCCCCGCAAAAAAAGACAACTATAATCTGTAGTCGCGGAGAGTACATCAGGGCTTGCCTACGGCTACAGAGAGTAGGTAGCTACAAAAGGGGAAAAGGGAACCCTTGGGGTGACAGAATCCTTGACTGCGGCACTAGTTATAAGGATGTATAAATTCGTAAAAAACTAAAAAAATCTGCTAAATTTGTATTTTGTTGTATATAAATTATATCTCAATAAAATTAACCAAAAAAACCCACCACTCCTTTAGAAGCAATAAAGCATGACAAAAGTATGTAAATAACTTTAACGAAAACAGATCTTAAAAAATTACTACAAGGGTAGTAGTGATACCTAGTCCTGGGATCAAGTCCCCCATCAGGCTTCTTGCTCAGCGGGTGTCTGTTTCCCCCTCTCCCCCTGCCCCTCCCCCTGCTTCTGTGTATGCTCTCTCTCTCAAATAAATAAATAAAATCTTAAAAAAAATCACTACAAAAAATGAACACTTTGGTTTGCAACAACAGAAGGACCAAAGGTGTTTCTCTACTATCCACCTTGGGGCAAATTTTTTAAAAAATTTCCTTTCGAAGGATAAAAATATTAAAATTCTGAAGTTCATAGATATTACACAGTAGGTCTGTCAGCAATCCAAAGATAAGTGACCCAACTACTTTTAGGGCCAACATACATGTAGCAAAAACATTTTGGCGCTATTGGTATAACTACAAAATCAAGAACTTAACCCTCTTCAAACATAAGAAAATACGTAATTCCCAATGAAAAACGTAAGCATGTCTTCTATCTTCCCTTTCATCAAGTAGTTAAACAGAGATCATGGAAAAGTCTGATTTATTAGAATTCAGTTAAATATTCCTATTATCAGCAAATACTATTTTAAGGAATAGCTGAAACTCCTGTATGATTCATAGATCTGCAGGTATACAAAAGACATGTGTGAAATAATTTTATAAAAATACACACATGGGGGCACCTGGGTGGCTCAGGCGGTGAAGTGTCTGCCTTCAGCTCAGGTCAATCCCGGAGTCCCAGGATTGAGTCCCACACTGGGCTCCCTGCTCAGTGGGGAGTCTGTTTCTCCTTCACCCTCTGCCCCTCCTCCCTACTTGTGTTTTCTTTCTCAAATGAATAAAATCCTAAAAATAAAAACACACACACACACACATATGCTGGGGCCCCTGGGTGTCTCAGTTGGTTAAGTGTCTGCCTTTGGCTCAGGTCATGATATTAGGGTCCTGGGATCAAGCCCCATGTTGGGCTCCCAATTCAGTGGGAGTCTGCTTCTCTCTCTCCCTCTCCCTCTGCCCCTACCCTCTGCTCGTGTTCTCTATCAAATGAATAAAATCTTTTTAAAAAATTAAAAAAAGATAATACACACATGCTTTCAGATTTAGATTTATCTATAGTAAAAATAGTACTGTTTTGTGTTCCCACCTCAGGCTGGGAGCCCAAGATAATTTTTCTAAAACCTCACTTAAACTATTAGCAGTTCTGCATATAGAAAGTGGACAATTATTTCAATTTGCTGAATACAGCACCTAACCTTGAGGTCGTGGAATGAACAAGGCAGAGTCCCTCCTCTAGACCCAGTGACTATCATCTTCCTGGGAACAATGATTCTTGAAAGGTCCTGTGGGTCATGGGCCTATCAGCCCTCACATCAATCAGATAGATTGGCCTGTCCCCGCTTGGCTGTGTCAGAGACTGGCCAACCTCCTCAGGCCGAGTCTTCCAGGCCGCTGAGTCACCTGAGCAGACGGGTTTGTTAGTGGAAGGTGCCTGTGCGGCAAAAAGCTGCAAAAGGTGCTCTGCCAAACTAAAACCTAGAAAAAGGAGTGATTTTATAACTTTTAAGTTTGCCTCTGAACCCCCCAAAAGTGGTAACTTAAGATTTGAGTGAAACAGAGAGCTGCATGGACTGAAGGTCTGAAGAGCCAGTCATAAGGCCGGGGCGGCCAGCTCCTGCTGGACGAGTCTGTGTCTCTTTGGGCTTGTCTCCTCATATGTTACATAACCTCCAAAGTGCCTGGTTGTCTGAGTGCAGCGTGGGGTCGTATTTTAGAGCCTGCGTGCCTTGGCATTCTGGCATCTCTGCTGCCCGTCCCACCACTGTCTCCTAACTTTTTAAATGAAGTAACTGTTCTGAAAGAACAACAGACAGGAAATCTAGGAAATCTGTGTTCAAGGTGAGGCTTTGCTCCAATATGCTGTAAGTTCAGACAAGTCCCTGAAGTTGATCTATAATTTCTTTTGGCTCAGTCTCATTTGCAAAATGACCTAACTGTTCGACCAGCCACTCTCTAATGTTCAAAACAAAACTCACCTTTCCCCAAACACTCTTCCTCCTGATCTCTGATGCTGTATCTGAGAGAGAATCCCCTCAAGATCCTCTGTGATTCCTCCTTCATTCATTACCCATCCCACCTCCACCCCTGTTCTAACAGTTACAAGTCCTGTTTGCCTCATCTCTGAAACCCAGACACTGATTTCTGGGCCCAGCGACCAGACATAGTTTGGACCATACGCAGCTCTCACAGTAGGTCTGTCAAAGAGCGATCATAAGCACCCCTGCCACTGTTCTTTCTTATCTCCAATCTATTCCATGTAGTGCTGCCATCACCACCCTCAAAACGTAAAAAACTGTCCTGTCACTTCCCTGTCTAAAATCCTTTACCAGCTTCCAAATGCCTTATACATGAATACACAACTCTCCTAGGCCTAGAACCCACCTTTGTAGCCTCTGCACACACATCAGTCCCCCCTTCCTATGTGACCATGAGTCTCTGCACGGCTGTATCCTTCAGCTGCATTGCCTATCTTCCTTCTCAGAGTGGGGACCTCATCCTTCCAGGCGTGGCCCCAACGCCCCCTCCTCTACCCCAGCTCCTACCAGCATTTCTCCTTATGCTCCTGTGTACACCTCTCTAGTGTCCTCACACTGCATTCTAATACTCACATTTCGTGCCCCTCTACCAGCAGAACATGCCCGGTATCCACGCAATGGCTGCCCTGTGTTAGGGAAAGTAGTCAAGGATGGAATTTAAAGTGCAAGTTTGAAACCAGACTGCCATGGTTTAAATCCTAGTTTCACTTCCCACTGGCTATGGCCAAGATACTTAATCTCCCCAAGCCTCTGGATACATGGCTGGAAGAAATGGTTTAAATCTCAAAGTGTTCTTATAAGAACAACGGATAACATAGGCCACGTGCTTAGCACCCTTTTGAGGTAGTAAGAGAAAAATAAGAATAATGGTAATAAGTAGTAGTGAGTAAGGGACAGGCAGGGCTAGGTAGGGAGAGAGAGGTAGGGGGCTACGGGATCAAGCTCATACAAATCTCAAAAATTCAGAGATATAAGGAAACCAGAGCTAAGGGAACAAACCAGACCATCCTGTCCCAGGTGTGGGAGCTGGGGTCTTATTATGACAGCTACGTGTGACCAACAAAGAATTACAGGACGCTAAAAAGGAAGCAAGCCACTGACGATGTTATCACTAGTCCTTACTCAAGGGTGCTATCAACAGAGAAGTAAAAAAGATTTAAGTTCCCTGGTTAGCTTTCTATAAAAGACCAACCCTAAAAGCCCACAAGGGTAAACCTGTCAGGACCCCTCCCCCTCCTGAGAGCTTCTTCTGTTTCATCACTTACTGAACCTCTATCGGTTTACTCTCCTTTGTCTGAGAGATTCAGTCTTCGACTAGGTGAGACAAGAACCTCGCTGGTCTCCCACTTCAATAGCAGCGGCAGTGGTAGACAGAAAATTAATAGCGAAGACTGACGTCGCTGCTACTTGTATGTCAGGCATTGTCCAGAGAAGCTGACATATATATATACCACTCCTAGGGCCCTCGCGACAGGAAGAGTTGAGTACTATTATTATACTCTTTCCCATTTCTGCAGAAGAAACGGACAGCACAGAGAGTCTGAGTAACTGCCCCGAGGTCACAAGTAGGCTCCATGCCCAAAATGGGGCTTGAACTCAGGACCCTAAGATCAAGAGTTGCAGGTTCTGACCACTAAGCCAGTCAGGCACCCCAACCACTGAACAGATAACTTATCCAAGGTTACTCAGCTTCTAAAGTGGCAGACTTTGTATGTAAGCTTTCAACCCCACAGAAGCTCCTTTGATTTTAGAAGAGTTATTTTAAAACATTTGGAAAATAGCTCTAATGGTGAAGTCTACAAAGGGGGGAAAATACCCAGATTCACACGAATTCACACAGCCATAATTTACCTATATGATTATGGAAATTTTCATAACCATAGAGAATCAAAGGTGGAAATTACTGCTATAGAAACAATTTGTTTTACTTGGTTACCTTTTAAAAAGCAACATTTCTAAAAAGAAAATAGGACTGCATTCTAGCTAACCCCAGAAACTATGTTCCTCTTTTGCAAATAAAGATACAATAGCTGTGTAATCTGAATTGAGTGACATTTCCTTTTCAGCTCTACAGTCAGGGATAATTTAGCTAAGTTTTATTAAATACACAGATCTATAGTGGACTGTGCTACAGAACTGTATTCCAAAAATCACCAGTATCCACAACCTTCCTCATATACCTTTTTAATTTCAGAATCTCGGCCTGAGCTTCATTTCCTTACCTGTACAATGGGGCCAACAGTACACACTTCTAAGGGGCTGTGGTGATTGATTACTCTTTAAGCAAATATTCATGAAGTGCTTACTCTATACTGCATATTGTTCTAGACACTGAAAATAAAGTAGTGAACAAAGTACTTGTTCTCAAGTCTACGTTCCAGCGTGGGATACAGATATACTGATGATAAATATATTAGTGAAAAGTGCTAAGGAGAATAAGCCAAGGCAGGTCAATAGAGTGATGATGAGAGGACCTGAGGGTTTTGTTGGTGTTCAGAGAAGGCACAGACCTGCAGTGTGGAGCGAGTAAGGCATGTGGAAACGGGGCCATAGGTTGGGTAGAGAATTACGGGCAGCAGGAATGTAAGTACAAAGGCCCCAAGGAGGGGAATGGGTGGCTCACACACGTGCCACCCACACCTCTCCTTGGGGTCCCCGCATCAGCAAGGAGGCAGTGACACTGGAGCAGAGTAAGGGAGGGAGACCCTGGTGGCTGACATCAGAGTGAGGACTGGAGGCCATGTCAGGTAGGACCCTTGTAAGCCCTCTCACAAGTTTTCTGTTTTATTTTCAGTGAGATGGGAAACCATACAGGTGTTTTGAGCAAACAAGTGACAGGATTGGAGCTACGTCTTTAAAAAGAACTTTCCGACGGCTGAGTTAAGTAGACAAAAGTTGGCAATGGTGGAGGCAGGAGACCACTTATGCTATTAAAATAATCCAGATTCTTCAGTGATCTGCACACCCGACCTAGGACTGGCACCTGCAAACCCAGATCAAGAGTCCTGTGCTCCACCAGCCAGGCGCACCTCCACCAGCGACTACTAACTGCTTTACACAAATCTAAAGTCATATACAGATTTTAAGAAGTTTTTTTCCAAGTGGAGATGTTTTGACCTGGAAGTTTCATTGAAGAAAGGTGACTGTGATCTTGCTGCCCTAGGCCAGAGTTTTCTGCACAGCCGTATTTCCTCTGACCCTCTAAGGAGGCATGGAAATCTGCCAGGGAACAAAGCCACACAGACAACCTCCTCACGTTAAACCCAACCCCCTGACAAGGGGTGGTGAAAGGCCAACCAGGCAGAGCAGCCTGAACAGCCGAGCAGCAGGCCCCTCCCCCAGAAGACAGACCGGAAGAACAGGAGCTGTTCAAGAAGCTGCTGCCCCATCAGTGCCTGGACTCCGTCTGGTCCAAGCGCAATAAGCCTGGCAATGAGCACCTGGCACCCACAGTCCGGGCCACTGTCGCCCAGTTCAACGGTGTGGCCAAGTGTGTCATCACCACCTGCCTTGGCAACCCAAGCATGACAGCCCGGGACAGGGCCATGGTGGTGGAGCACTGGATCAAGGTGGCCAAGGCCTGTCAAATCCTGCAGAACTACTACTCCCTGAATGCCATCGTCTCGGCTCTGCAGACTGTCTCAATATACCACCTCAAGAAGACATGGGAGAAAGTTTCCAGGAGCAACCATCTAATAAATCTGCCACCCTGGTGATGGCCCTCCGGAGAGCCTAGAAGAAGAGGCTGCAGAAGAAAGGTGTTGTCCCCTAACTTGGCACTTTCCTCACTGAACTGGTGATGCTGGATATTGCAATGGAGGACTATCTGGAGGTGGGTGAGCCTGAGGATTGTGGGGGAGGGACCAGAATCCGGAGGTTTGGGAGCAGAGCGCCCCTGTACTGAGCCCTGAGCTCTCAGGACTCGGCAAACCTCCCCTCATGACAGCCTCACGGCTACCCTGTGAGCCTGGGGGCTGTTGCCCATCTCAGGGATGAGCGAGGTGAGGCTGCAGTTAGGCCACGGCTCCCGGTGCCGAAGACTGGTGAAGCAGCAGAGCTTCCTGAAGGCAGGGCTGCATTAGGTCTGTCTGACTGGACCTCAGCCTCCCCCGGTGAGTTTGCCCGTGGAGGGAGAATGAAGTCAGGACCCTCCACGTCAGCAAGCACCTCAGTAGCCGCAGCAGCCCCTTCCTGCCTGAGGCTTCGGCCTCCCCCACTGTCTTCCGAGAGGGTGGTGCTGCAGGGTCCCGACCTGTAGCCAGTCCATCTGCCCCATGTCCTCCTTTCTCTGGACCCCAGAGCCTGGCCTACATCCCAGGCCCGCTATCTGTGTATGCACGGCCCCCTCATGGGTCCTGGCCATGGTGCAGCATGAGAAGGGATGGGAATCAAGTGCTCCTAAGAACCAGGGGCCTCATTCTGATGGACTTTGTCTGCTTTCCAGGGGAATGAGATCAACGACCACAAAAGAAATAAGAATGCAGTGCAAGACCCATCCCATTAGGAGATGGGGACAGACGCATGGCATCCAGGAGAACTTCCCGGAGGAGAGGCTACTGATATTCACCTCTGAGAA
->XM_012612283.2 PREDICTED: Gossypium raimondii prefoldin subunit 5 (LOC105786035), transcript variant X1, mRNA 
-AATAATAGGAACATAAACAAACCACACAATTTGAAAGAATTCAAAACCAAACAAACAAATAAATAAAATAACGAAACTAAACAAATAAAATAACAACCCAACATTGAGCAGGCATCCACTTTCCCTTTCCATGGGCAATCAGCAACACCATGGAATCCAAAACGGCAACCTATGTTCCTAGCCAACATCATACCGTTCATCTCCCCTGATCTCAACCGAAACCCCCCAAACATTGTCGAACACTCAAAGAATTTAGCAACCCATCACCACCTCAAAAGTAACCCACCGGTCTTCGTACCCCCACCCTAGATAGTAGTAGCCCTCAATACCCTTCCCCCCTTCAAACCCCATTAAAGTTTCTTGCGATGCCATCAGAGAACATCTCCACCATTTCTTCCCCCAACTGTCATTCGCGCCGATCGTTGTCCATCGCATCCCTCGCAAAGTCCAACACACACCCTTCCAGATAAGTGCTCCCACCTCTCATCAACCCCTCTGTTGATAGTATATGTGCAACTCTATTCGCATCCCTGGGAACATGTCTAAATGAGCATCTTGTGAAGCCTTCTATTTTTTTCTTTGCATCGTATATATAAGCCCCTATAACCGGCCCATCTTCATTGCAGGACCTCATCTTTTTTATCACTGACAAGGCGTCCCCTTCTACCATCACCTATTGAATCCCTAAATCTATCCCCAAACTTACTGCCTGAAGACATGCAAGGGCCTCTGCTGCAAAACTCGTAGGGAAGAAAATGTCGGTTCCTCTCACTGCTTCCCTTTATGTTCCTGGCACACTCGATGATGCCGACAAAGTTCTTGCCGATATCCGCACCGGATACTTCGTTGAGAAAACAATGGATGAAGGCAGAAATTATTGCGAGCGTAAGATCAACTTAGTGAAATCCAATTTCGATCTACTTAATGAGGTTCTTTCCAGCAACTCGAGCAACCGAATTAAGAAAAGATATTTTCAAAATATGACAAAAGGAGACTGAATATGACTTCTGGGAACGATACAAGAAGTTATGTGCAATCTGCCTACAACACGACCTAACTGAACAATCATTTCTTCAATACTTCTATGACGGGTTACTTTGTATGAAAATGAAGATAATTGATGTCACCAATAGAGGGGCACCTGTTGGCATGACTCCTCAAAGAATAAGGGAATTAAT
->XR_008246896.1 PREDICTED: Vigna angularis uncharacterized LOC128195426 (LOC128195426), ncRNA 
-TTCAGTGGAATGAAGGTTTCATTCATGCATGATGTTGTTTGTGGATGGTTTTGCTTATGTATGAAATGTCTCCCAAGTGCATTTTGTTGTGTTACTGATTTGTATACTTGTTGTTTGCTTAATCTTACATTGTTGTTGTAATTTTTTTCGATTGGTAGTCATGGACCGCGTTGGCCTTGCTGTGAAAAAAAACAAGCCACCTCAAAATGAGAGTGGTGAACCTAGTTGGCCTTGCTGTGAAAAAACTTGAACCCAATTACCCAGTTCATTCGGCTTTGGTACGAGTTATGTTGGTGAAGCCAGGGTCCTAGAAAATGTATTTTTATGTGACACGAATGTTAAGAAATTGTTCCCAGATTACTTAGAAGTAGCTGAAACGAGGGAAAACAAACAAGGCACCCCAAAATGAGAGTGGTGGACGTAGTTGGCCTTGGTGTGCAAAAATTGGAACCCAGGAAGAACTACAACAAGTTAGGGAGCAATATGTTTGTCAATGGATTTTGGATGTGGACAACGTGCGGAGGAATCAAGTGTTGGAAGATTTAGGCATTTTGTAGAATGTTGGAGATTATTGATGAAAGAAAACTTGTTACTTTTCATATTTATGTATTGGTTGGACATCAAATCTGATTTCAGAAATTGTTGAGAAATATATTTGGCAGTTGAAATTCA
->XM_017185738.1 PREDICTED: Drosophila ficusphila calphotin (LOC108088083), mRNA 
-CAACGAGTAGTCGGTCGCTGTGAAGAACTATTTTACTGTTCGATGTCTACTGACCATGAAAGGCTGACCATGAAAATTTGCGTTCACTAATCACCGGATAAGTGAAAAGCTCCGCAAAAGGGCAAACGAGTTTAACCGTGAGAGAGGCCTGAAACTAGAAGGACATGGAACCTGCAGCGGCACCAGCACCTGCTTCTGCCCCAGTGGCAACGCCTGTGGCCCATGCAGCAGCAGCTCCTCCTGTGCAAGTTGCTAGCCCCGTGGCAGTGGCTCCTGCAGCACCGTCGCCGGTCGTTGCAACACCAATTCCTGCTGCTCCCCCCACTGCGAGTGTTCAGACAGTTACTGCTCCTCCTGCTGCTGCTCCCCCTCCTGCTGCTCCGGTTGCTGCTGCTCCTGCCCCGGTTGCTGCCACTCCCGTTGCTGCTGCTCCAACCCCGGTTGCTGCCACTGCAGTTCCTGCTGCCCCCGCTCCGGTTGCTGCCACTCCTGTCGCTGCTCCTGCAGCTGCATCTCCTGCTGTTGCAACTCCCGTCGCTCCAGTGGCGCCACCTGTTGTTGCAGCTCCCGTCGCTCCAGTGGCCACTCCTATTGCAGCAACAGCAGCTCCTGCTGCAGTGGCGTCAGAGCCTCCGGCTCCTGTAACTCCTGTGATCGCTGCTCCTCCTGTTGCAGTTGCTCCTGTGATCGCAACACCACCTGCTGCGGTTGCTGCGATTCCGGTGGCAGTTGTTGAGACACCAGTCGCTGTTGCTCCTGTGATCGCAACACTACCCGTTCCTGAGACTCCAGTTGCTGTTGCTCCTGTTATCGCTGCATCACCGGTTCTAGTCGCTGAAACACCAGTTAGTGTTGCTCCCGTGATCGCTACACCACCAGTTGCTGCGACTCCAGTTGCTGTTGCTGCCGAACCTGTTGCTGTCGCAGAGACTCCAGTTCCTGCGACTCCTGTTGCTGTTGCTCCAGTCATAGCTGCATCACCAGTTGCAACCCCGGTGGCAGTTGTCGAAACACCGGTAGCTGTTGCTCCTGTAATCGCTGCGACGCCAGTTGATGTTGCTCCGGTCATCGCTGCGTCACCAGTTGTTGTTGCGGAAGCTACTGTGGCTCCTGCTGCTGCTCCTGAGATCGCAACCCCACCTGTTGCTGTTTCTGAAACTCCGGTTGCTGTTTCACAGTCTGAAGCGCCTCCTGTTGCTGCAACACCGACACCTGCACCAGAAGCCCCTGCCCCGATTGCACCAACTGTGGAATCTCCAGTTATTGCAGCCCCTGCAGCAGATATTGCTCCTGTCGCTGCTCCAGTTATCGTCGACACTCCTGTTGTCGTGGCCGCACCAACACCTGCAGCAGCAGAAGCGGCTGTCATTGCACCACCAGCTGTTGTGGAGATCGCAGTTGCTGCTCCTGTGGCTGTCACACCGGAAGTTGCTGTTCCTGAGACTCCTGCTATCGAAGCTGCCACTGTTGCACCAGAACCAGTTGCTGTTGCACCACCAGAAGCTGAACCAGCTCCCGCTGCACCAGCGGCTGTTGCAATTGAGAGTGCTCAGCCAGCTACAGTTCCAGAACCAGTTCCTCCAGAGCCAGCAGCTGCAACCGTTTCCGAGCCAGTTCCTCCAGAGCCAATTGCTACACCAGTTCCCGAACCAGTTCCTCCAGAGCCAGCTGCCACAACAGTGGAAGCTCCAGCTCCAGTTCCGGAAACTCCTATAGTCTCTGTGCCATCGGTTGAAACACCTGCAGCTATACCAGACACACCATCCCCTGCACCAATTCCACAAGTTTCAGCCGCAGTTCCAGAGCCGATACCCACACCAGAACCAATCGTTGTCACTCCTGTGGATCCTTTACCAGTGGAGACTCCAGCTGCGAGCCAGGACCCACCAATTGCCAAAGAGGAACCACCAGCAGAAGCACCAGTTTCTGTGGCAGCAGAGATCCCACCAGATCCACCAGTTGTTAATGAAGAACCAACAGTTGCTCCTGTGACAGCAGAAGTTCCGCCGGAAACTGTTACAGAGGTTTCCGCTCCGGCCGAGGATGCTGTTCCGATCGCAGCTCCTACAACGACATTGGAAGCAGATACTACTACAATCGCAGAAGCTTCACCTGCGTCTGAACTTGCAACACCTGAAGTTGAAGCCGTTGCTGCGGCCGTCGCCGATCCCGTCGCACCTGCACCAATTCCGGAACCAGCCGCGCCGATCCCCGAACCAACGGTTCCTGAACCAACCGTTGCAGCTGCTGAACCAGAACCAGAAAAAGCGGAAGTCAGTGAGCAAACTGTTCCAGCAGCGGAAGAGATTACTGTATCTGAAGTAACAGAGACGGCTACAAAACCTGTAGAGGATATAGTTCAAGAGAGTACCAATGTAATTGACGAAGCAACTCCAACCACAACTGAGTCCGCAGTTATAGTTTCTGGAGAAGTATTGGAAAAACCTCCAGCAGAAGAAGTGGTTGCAGTAGAGTCTGGTCCTGAGGTTGTGGCCTCAGTAGTAGAAACTATTGAAGCTCCAGCTGCAGTAGAAACCACCGAAACTTCGCCAGAACCAGTGATTTCAGAAACACCTGTTGTTGCAGCTGAAGAGCCAACTGCAGAATCAGTAGAAACTATAACCAGTGGTGCGGCAGGTACTTCTGAAGAAAAACCAACAGAAGAGGTTCCCGCAGATCCTAGTTCCGTTCCCGTGGCAAAGATAACGCCCCTGCTGAGGGACCTTCAGACCACCGATGTTTCGCTGTTGGCCATCGCGGCCACTTTGGATGCAATTGGAGAAAAACTTAAGGACCAAAAGGCCAGAAACCAGCAGGTGATGGACAGACTCTGCGAGATCGAGAAAATTCTTGGACCACCTAAATCAAATTAGCTTAAGCTGAAGGAATAATTCATGGTAATGTTAAACTAAAATATCAGTCGAAAATATAAAAATTAACATTGAAATAAACTTATCAGTTTAAATTTCA
->XM_043518673.1 PREDICTED: Dermochelys coriacea RNA-binding protein 14-like (LOC119858569), transcript variant X5, mRNA 
-GCTAGGGCGGGTCTCGCGGATTGTGACGGATGCAAAACAAAGGTTACAGGCGGTTGGGGCTCAAGTGCGCCCGCGCAACGACGTTGCTAGGAGAAGAGCGGAGGCGCGGATACAGAGGCAGGAGTGCGCAAGACAACAGTAGCACGCAGGCGCGGCATTAGCCGAGGGTCTCTCTTCGCAGGCGCAGTTGCTCGTAGGCGGTGGCAGGTAGCGCGCTGCGCAGGCGTGTCGACGGCTGGGTGGTTCCTTCCTCTTTCCTTCCTATCTGAGCGTTCGGAGGGTGTGAGGTGCTGCCGCCATTTTGTCAGGAGTCCCGGTGCCAGCTCGGCCGCGGCCATGCGTCCTGGAGTGAAGCTGTTCGTGGGGAACGTGCCCGAGGAGGCCACGGCCGAGGAGCTGGGCGAACTGTTCACGGGCGCGGTAGGCCCGGTGCTCGGCGTGGCCCTCATGAAGCAGTTCGCCTTCGTGCACCTGCGGGATGAGGCGGCCGCTGTCCGCGCCATCTCCCAGCTCAACGGGCACCAGCTGCATGGCCGCCGCATCGTGGTGGAGCCGTCCCGCCCGCGGCCCACCAACACCTGCAAGATCTTCGTGGGTAACGTTTCGGCGGCCTGCACCAGTGGAGAGCTGCGTGCGCTCTTCCAGCAGTACGGGCCCGTGGTGGAGTGCGACGTGGTGAAAGGAGACACAATCATGGAACAGGGGTTGGTACTCCTTTCCATTGCACCTGCAGAGCTGTTTCAGGTGATATGGACCTGCCACCAGATGCAACATGGGTGGTTGATAACAGTCCAATATGGTGTAATCTGCACAGCCAACTCAAGTGTGTTGAGATGTTTGCTGACTTCTTGAGAGACTTTGAGATTTATTCTTCAACTTTTTTTAGCTGCCTAGATCTGAGCAAGTCATTGTGATTCGTATTGCACTACTCTATTTGGACTAGGGATGTGGGAAATTCTTCATCAGTTGGAGTCTCTATGTTGAAATT
->AY571475.1 Uncultured bacterium clone RsaHf359 16S ribosomal RNA gene, partial sequence 
-ACCTTACCTGGGTTTGACATGGTAGTGAATGGTGCAGAGATGTATCAGTCCCGCAAGGGACGCTATCACAGGTGCTGCATGGCTGTCGTCAGCTCGTGCCGTGAGGTGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTACTGCCAGTTACTAACAGGTAACGCTGAGGACTCTGGCGGAACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTATGTCCAGGGCTACACACGTGCTACAATGGACGGTACAACGTGACGCGAAACCGTGAGGTCATAGCGAAGCACAAAAAGCCGTCCGTAGTTCGGATTGAAGTCTGAAACCCGACTTCATGAAGTTGGAATCGCTAGTAATCGCGCATCAGCATGGCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATCCGAGTTGGAGGTACCCAAAGCCGGTAGCGTAACCGCAAGGAGCGCGCTGTCTAAGGTAAATTTAGTGAGGAGGGTGAAGTCGTAACAAGGTAACCGTA
->XM_017212262.2 PREDICTED: Drosophila eugracilis peripheral-type benzodiazepine receptor-associated protein 1 (LOC108105593), transcript variant X5, mRNA 
-ATGGGGTTAACAGAGAGAACGGGGCTCTGTTAGTGGTTAACAGGGTAAAGTAATAGTAAATCGTAACTAACAGCCCCAGAGCATGAACTTACCCACTTGCAACCCCAAAGGAGCCCGTGAGCGGGAGAAAATTACCCGTTTTTCAGTGTCATTTCACAGAAAAATCGATTCCCCGCACACTGGGTACTGGGCATTGGGTTCTGGGTTCTCTGGGCCACTCTGCTCTGGCACACTGAGCACCGAGCTCTGGCAGTTGGGTAGAAATCAGAGTACAAACCAGCAGCGCGACCGAGATGACCCACTTTTCGGTTTTCGCACTGAGACCCAACTGCTACCCACAGAAAGTGGACAACTAGGCGGAGTTTTTTTCTATATAAGTAGCAGTTTAAACGATCGCGTTTTTCGGATAATTATGTACAGCCTACGTAGCCTAGTGTAAACTCTATGCATTTATGTGAATTTCCCAGCGCAAACGTGGAAGACGAAAACAGGCGACCTGAAAAAGCAGCAGCAGCAGCAGCAGCAGCGAGCAAGAAGCAGAAGCACAAGCAGCAAAAAAGTCGTCCGAGGGGCAGCCACAGCATGCCGTACGAGTCGATGCACCATCATCAGTCGGCGGCCGCTGCCGTGGCCGCTGGCACAGCCCCCAACGGAATGCTGGACGCCCTCAGTCTGCAGCTGCGCGATGCGGAAATGCGGCGCACAGAGATCGAGCGGGCGCATCAGGAAACCCTGGCACAAATACGAAATCTAAGCGGAAGCGCACGTCCCGATGCCGAGGCGGTTGAGAATCTGCAGTCGAGAGCCCGGGAACTGGAAAAGAAGGTTGCGCTGGAAAATGTGCGCTGCGAGGAGCTGCAAATCGAACTGACCTCGGCTCTGAAGGCCAAACAGGCGTCCCGCTCGGTCTGCTCTGGAATGGTCGGCGTGTCCTCCGGAGGCGGAGCCACCATTCCTACATCAGCCAGCAGCTCCACCGTCACTTGGGCACCGACAATCAGTCACCAGGACCAAGGCTCCGAGATTGATATCATAATGGCAAAGATTGAGCAGGATAATCGCGTGCTGGCCGAGCTGGAGCAGCCTCGCACCTCGGCCAGCGCCAGCATGTCAGCATTGCCGCCCAGTTCCATGTTGAGCACGGTAAATAGCGAATTTAGAACCATATCAAAGAGTGAACTCGAAGAAGAACTGAACCGTTATAAAAGGGCCGTTCTTGGCGGAAGTGGCGGAGGTGGTGGCGTTTCAGCTCTCTCCTCCGGCTATTCAAGCCTGCCGCAGTCGTTGGCCTCTACGCTGCCCAATGGCGGGGCAAGCACCAGCCTAAGCGGTACCAGCCTTGGCTCGCACAGCGTGGCCGCTGCTGCTGCCGTTGCCTCTGCTGGATCGGGGGGTGTGACTGGGGGTGGTGGAACGGGAGGTTTATCATCCATATCGGCCCTGGTGCCCAACTCAATCAGCGGCATATCCTCGAGTCTAAGCAGCCATGCCATACAATCGATGCAGTACGGAACCGGACAAACGTCCGTGGAGAAGCTGCTGAGCGGAACTAGTGGAATCACTGGGATTCCACCTCTGCCGGTAAATATTCACACGATGAAGGCTATGCCAACGGCATTAAGTCAGCGCGGAACAATACAGCTGTACAATTTGCAGAGCACAACCATGCCCCTCCTGTCACTCAACTCGCATAACCTGCCGCCCGCCGGCTCGACCAGCTACTCGGCCCTGGGCGCCGGCGGCGGCACCTCGCTGACGCATCCAACCAATCTGGCCAATCTTGGCCTGCTGGACACTGGCGCCCTCTTGGGTGCCACCGGTCTGAGCGGTTTGGGCGTGGGACCCGGTGCCGGTGGCATTACCGGTGCCACATCACTATACGGTTTGAGCGGCGGCGGAGGTGCCAGTGGTCTGGGCAGCTCCTATGGTCCGCCCTTCCTGGACGTCGCCTCGAGCGCCTCGTATCCATTCACTGCGGCAGCCCTGAGACAGGCTTCCAAAATGAAGATGCTAGACGAGATCGATATACCGTTGACGCGGTATAACCGCAGCTCGCCCTGCTCACCCATACCGCCCAGCAATTGGGGACTGGACGAGTTCACCGACGGCCTCAGTGTCTCCATGATGCACAACCGCGGCGGCCTGGCACTGGGTGCCCTTGACTTGGACACTCGCAATCATGGGTTAAATGGAGCCAGTGAACCGCAGGTGGATATGCTGGATATTCCTGGAAAGGGGCGCTGCTGTGTGTTCATAGCCCGTTTTCCATATGATCCGCCAGATGTTCATAATGAATTCCTTTCCATGCCTTGCAGGGAGGCTGAGGGCGAGCTCTCCCTGTGCGCCGGCGACTATCTGCTGGTGTGGACCAGCGGGGAGCCACAAGGTGGCTACCTGGATGCCGAACTACTGGACGGACGACGCGGCCTTGTTCCGGCCTCTTTTGTGCAGCGTTTAGTAGGCGACGACCTCCTGGAGTTCCATCAGGCGGTGCTGTCGACGCTGCGCGATGCCGAGGACGGATCGATGCAGTGCGACACCACATCGCTACCCTCCTTGCCGCCGCACAACCCATTGCTCACACACACCCACGAGGACCTGGCACGTTTGAGTGAGACGCACACCGATCTGGAGCACGACCAGGACGACATTAGCGACAATGTTCCAGCACCCAAGCACTTGACGCTGGAACGGCAGCTGAACAAGAGCGTGCTCATTGGCTGGTCACCGCCGGAGCCAGTGGGCTACAACCTCATCGACAGCTACCACGTCTACGTGGACGGCGTGCTCAAGGTCACCGTGAAGGCCAACGAACGCACACGAGCGCTTATCGAGGGCGTTGACTCCACGCGGCCGCATCGCATCAGCGTGCGGAGCGTGACTCAAAACCGACAGACCTCGAGGGATGCCGCCTGCACGATGATCATTGGGCGGGATACCGCCCACCTGGGCCCCTCGGCGGTGCGCGCTTCGCACATAACGTGTTCCTCGGCGGTCATCTCATGGCTGCCGGCCAACTCCAATCACCAGCATGTGGTGTGTGTGAACAATGTGGAGGTGCGCACCGTCAAGCCGGGCATGTACAGGCACACGATCACGGGCTTGGCGCCGAGCACCCAATACCGGGTGACCGTGCGTGCCAAGCACCTGCGGGCCGTGGGCCAACATGCCGCGAACGTGGGCCAAACAGGTGTAGCCGGCAGACCTGGTCAGGAAGAGGCGCCCGGAGCGTACGCTGACTTCCGTACCCTGACCAAGGGACTGCCCGATCCGCCACAGGAGATTCAACTAGAGGCCGGCCCGCAGGATGGTACCATTCTGGTGACATGGCAGCCGGTTAACAGGCCCACCTCGACGGGGCCTGTAACCGGCTATGCTGTGTATGCCGATGGTAAAAAGGTCACCGATATCAACTCGCCCACCGGTGACCATGCCCTCATCGACATTGGCAAACTGGGTGTCTTTAATCCACGCGCCGTCACCATTCGCACCAAATCCCGCGACTCCCAGTCGGCAGACAGTGCGCCCATCTTGATACCAAATACCGTGCGAAATGCCGTGGCCCGAAGGGTGCCTAACCAAATGGGCATGGGTCCACAGTTGCCGCAGGGACCGCATGGGATGCAGGTGCAGCAGCAGATGGGTGGAATGCCTGGACTGCCGGGTCAACAAGGTCAGAATATGATGGGTCAGCAGGATCATGGCCAGTACGATCCCAATCAGATGCAGCAGCAGCAGCAGGGCATGCAACCGCAGCCGGGTCAGCCGGGTCATCAGGGCTATCAACCAGGGGCACCAGGAGCGCAGCGGGGCATGGTCCCGATTCCGGGCAGGGCGCAGGGACCACAGCAACAGCAGCAGCAACAGCCCTACGGACCCCAGGGTTCCATGGGTGGGCCACGCTTTCGAGGACCAGTTCCGGGCCAGCTTAATATGCAGGGCCAGCAAATGCAGGGTCAAATGCAGGGTCAGATGCAAGGTCAGATGGCGGGTCAAATGCCTGGACAGATGCCTGGACAGATGTCTGGTCAAATGCCTGGTCAAATGCCTGGACAGATGCCCGGACAAATGCCCGGACAAATGCCCGGACAAATGCCCGGACAAATGCCTGGCCAGATGATGGGACCACGAGGACCGCTCAATCAGCAGCAGCAACAACAGCAGCAGCAGCAGATGCAGCAGGGCCAACAGATGATGCCAGGCCAACAGCCTGGACAACAGCAGACACAACCCGGACAGCCGGGTCAGGCCGGCCAAATGCCCGGGGCCCAGAAGAAACCCCGCTATTTCGTGGCCATGTTTGACTATGACCCATCCACGATGAGTCCCAATCCCGATGGCTGCGACGAAGAGCTGCCCTTCCAGGAGGGCGATACGATCAAGGTATTTGGTGATAAGGATGCCGATGGCTTCTACTGGGGCGAACTGCGTGGTCGCAGGGGATATGTACCGCACAACATGGTCTCGGAGGTGGAGGACACTACTGCCTCTTTGACAGCCGGCGGACAGATGCCCGGCCAGATGGGCCAGGGTCAGGGTGTCGGCGTGGGTGGTACTGCCCAGGTGATGCCCGGCCAGGGAGCTCCGCAGCAGAGCATGCGCAACGTAAGCCGCGACCGCTGGGGCGACATCTATGCCAATATGCCGGTGAAGCGGATGATCGCGCTCTACGACTACGATCCCCAGGAGTTGAGTCCCAATGTGGATGCCGAGCAAGTGGAATTGTGTTTCAAGACGGGCGAAATCATACTCGTTTACGGTGATATGGATGAAGACGGTTTCTACATGGGCGAACTGGACGGCGTGCGCGGCCTGGTGCCGTCGAACTTCCTGGCCGATGCGCCCGATCAGTACAACAACCAGATGGGTCCGGGCGGTGTGGCCGGCAGAGGTGGTCTCAGCCAGCGGGGCAGGGGTCAGGGGCCAGGAGCGAGGGGTCCACCGCCCCCGCCACGTGACAACATGATGCCCGGAATGGGCGGTCGCGGCCAACCGGGCAAAAATGCTCGCCCTGCTTCCCCTACACTGTTAGACAACACGGGCCATCCTGCCCCCGATCACCAAACGCAGGGGATGATCGGTCGCGTTGGTAATGTCGGCCTGCAGCAGCAGCAGCAGCAACAGCAGCAGCAGCAGCAACTCCAACAGCAGCAGCAGCCGTATGGTCAGCAACAGACGCAGATGGGACAGCAGCAGCAGCAACAACAGCAAATGGGACAACCTGGAATGATGGGTCAGCAGATGGGTCAGCCGATGGGTCAGCAGATGGGCCAGCAGATGGGACAGATGGGTCAAATGGGTCAGATGGGTCAACAGCAGCAACAGCAGCAACCGCCGGTAACGACACAGGCGCAAACGGGTGGCCTCTTCTCCGGTGCGACTAGCCTGCTCTCTGGTGCTACCTCGGCTGCCACCGGTGGTCTATTTGGGTCGAAGCAACCGCCCAAGACGGATCCAATGCAACCACAAGGTGGTGTGCAGCCAGCGCAGCAACAAGCAAATGCCTTCGGTGCCCAGCAGCCCGGCATGGGTATGCAGCAGGGGGGAATGCAGCAGGGGATGCAGCAGGGGATGCAGCAGGGTATGCAACAGGGGATGCAACAGGGGATGCAACAACCGGGCATGCAACCCGGTATGCAACAGGGTATGCAACCCGGTATGCAACAGCAGCAGCCACAGCAACAACAAGTGCCACCGCAAGCCCAGGCTCCGCCACAAGGACCGGGCGCCGGTCTGCTGGGCGGCCTTAAGGGTATCGCGGCAGCGGCGCCCGGCGGCGATGTCCTATCGAAAGGCAAAGACCTCTTCGGAAAATTCGGGTTCGGCTTTGGCAAATAACCCCGGTCATTCTATAGGGTCCTGTTATATTATTCGTAGATTAGACTTATTATTACTATTATGATTATGATTATTGCTATTGATTACGGATTACTAAGCTAATATATAAAGAAAAAAAAAAACACAGACGATGATGATTAGATCGAGGAGGACAGACAAACCAATGCTAAAGTTAAAAGAAAAACCCATACTTTTAGGCCCAGGCTGTGGGCCAATGTGTGTATGTTGTTGTTGTTGTTGTTGATATGAATATGATATGATATGACTAATAGTACTAATGGTAATATTTTTTATTAATTAAATTGATAGAAATATTATGAGTGACCGACAGACAACAGCAGCATCGGCCTAACAGCTGGGCCAAAAAAAACCAAAAACAACAAAAAGCCACAAGCCCAGATAAATTGTTGTAAAATTATTTAACAAATTGCCTGCCGGTTTAGGTGACTGCAACTCGATAAAAGATTCCACTAACCCATTTAAAGGATAAAGCTCTATATAATGCATAAACCAACACACACACACACACTGAGACACATACAGATGCAATACACACTCACATAGATACTGAGAACACAGATATATTATACAAAAAAAAAAAAGAAAAACCAATACAAATACAAAAGTAAGGGAGGAGAAATATATTATATACATACATTATATTTACAATTATTTGTTAACGCACATTGTTAAATTTGCTACTGTTGCTGACCAGTTTATAAATAAAAACCAAACCGGATGGTAAGGAGGAGAAGAGAAAAGGAGTATAGAGGAGAGAAGATAAAGCAAACACATAAGGTAAACTAAAACCAAAAAAAAACATAAACATAAACATACATATATTATATGTATATATTTCAAATATATTGAAAACTAAATTGAGATACACTATAAAACTTACATTTATAAATCAAAAAACAAAAACAAAAACACAACCGAATGTTGAGCAATGTCAGGCAGGCGAAATGATGAGGCCGAACCAAAAAACAAAAAACCAAAAAAAAAAAACAAAAATATAAATAATGAAGAAGAAGACGATACATACATTAAAGTAAAATAAATAAATCGATATGGTACATATTTACATATATTCGCATATACTAAATACGATTTCGCATTCAAAAGCCAACCTCCAATCGGGCGCATTTCCAAGACAAGGCGACCTTGACTTCCAGTCCAGCACAAGAAGCTAACTTTAATCCCTTGAACATCCCCACCCCCCATGCCTTCTTTTCAATCCAGTGATAGCCGAAGCCAAAATTTCTATCTCTTAATTCCTAGTAAAAACTTTCCCCCCTTTTCTCACGACTGCTCGACTCAAAAACTTCTCTTTATTCTATGCAACCGAAAGAAATTTTGTTCAGTGTTTGATGTCCATAGAAGCCATATGCGATAAAATATCAGTGTAACTTAAAGCAAACCAAAGACCAAGAGAGAGATCTACTCCTACATACATATATATATATATATATATATATATATATATGGGATACCCAACAAAATGGCAAATACAAAGCAAATATAATGTACTAAGCACAAGATCGTAGCATTAGACCCTGGAGACATGTTCACTAAATTCAGCAAAAAGGAGACTTTTCCACAACCTTCTTTAGCCACTTAAGCCGCCGCCCCTATTGCTTTTCTTACCAACTTTCTATCGCTATCTAACCCTAACTTTTACCTAACCAAAAGTACACATACCTTTTCGATTGTTATTTTAAATACTACCAATTAACAGATAGTTAGTTACTCGCCTATGCCGCATACTTACGACTACTTCTGTTCTCCTCTCGTGGAAACTTTATGCTTTATTATCCGATACGATCCGATCCGAGAGAGAGAATGAAAATTTGCAGATAGTCAAGGTGTTTCCTAATGTTTGAAAATTGCTTTGACTCAGCCCTCATGATACACACTCAGCATAACACAGACAAATACATTGCGTACCTCTTGCTTTACGAAAATACAAAATACATTCAAGAAATGGAAAGTATAAAGATAACAAAAACCAAAAAAAAACAATTATATTAATGACAAAATTTACCAAACAAATATATTAAACAAGGCATATTTAAAGAGCGCATAGAGAGTTGCATATGTACATGTGCTTGGCCGGCAAACAAGACAACATAATTGTGAGCAAATGATTACTTTAGACACACACACTTACCACAACTGATACATAGTTACACTGCAAAATGCAAATTGCAAATTGCAAACTGCAATACCGAACACTGTAAATTGTAAACTGGCAAAAACAAAAAACATATAGTAGAGAAGGGCTGTTATAGCCAGAAAATGTTGATCGAGAATGACTTACCGAAATCGAAACAAGCGTTAACTTTTCCCACGTAAACGATTTAAATCTAACAATCAAATCAAGTCACTGTATTATTCAGCCACATCGGATAGACAATTACAATCTACAAGCCTAACTTCGGCAACCACCGAAGCCGTGATGCCTACGTAAACCGGAAGATATATCATATTCGAATTTACAAGGGCACAGCGGAAATACACACACAAATACAAATACAAACAGCAGACAAACACACTTACACACACACTCTCTCTATAATCATTTACTAGACACCTACCTATACAAGTATACAAGAACAGTTTATTTCCTCGGAAACAAAGCGAACAATATAGAATAAATGAAATTAAATTCCCATTAAACACACACACTGGCAAAAAAAAAAATGATAATGGCAAAAAAACGAGTACTATGCAATATGAAATGGATAAAACAAAAACCAAAAAAACAAAAAAAATACAAATGAAAACCAACTAAATTGTTATACTGTATTATTATACTTTTTCTATAAATTATAATTTCCTTATTGAACGACAAAAAAGCGAAAAAAATAATAATTAAACAACAATTTCAAAGAAAAAAAAATCAAAAACGCAGCATTTCAATTGCCTTAATGAGGCGTTTCTTCAATTTCAGTGATATTACTCATACGACACGTA
->XR_003431942.1 PREDICTED: Lagenorhynchus obliquidens AVL9 cell migration associated (AVL9), transcript variant X2, misc_RNA 
-CGGAAGCGGATGAGGGAAGCTCGGCTGCGGCCCGGGGGGGGCGGTGCAGAGCTGCAGGAGCCTCGGCCTCCTCCTCGGTCCCTGCGAGGCTCTCATGCGACGCCCTCGCTGACACCTGAAATCCACTGCTCGCCTCCTCCTGGGGGTCACGGGGTTGCTCGGCTTGCCGCCCTCGGCGGTTGCAGTCATCGTCTTGCGGGCCTGCGGCGGTCGCCCATGGAGAAAAACGGGCGCGGCGGCGATAGCGCCCCCCGTGGGCCCGTATTGCACATCGCGGTGGTCGGCTTTCATCACAAGAAGGGCTGCCAGGTTGAATTCTCTTACCCGCCCCTGATTCCAGGAGATGGACATGACAGTCACACTTTACCTGAAGAATGGAAGTATTTGCCCTTCCTTGCCTTACCAGATGGCGCACACAACTACCAAGAAGATACTGTGTTTTTTCACTTGCCACCCAGAAATGGAAATGGAGCCACTGTATATGGTATCTCTTGCTATCGACAAATTGAAGCCAAGGCATTGAAGGTACGGCAAGCAGATATCACCAGAGAGACCGTTCAGAAAAGTGTCTGTGTTCTAAGCAAGCTGCCTCTCTATGGCTTACTTCAAGCAAAACTTCAACTCATTACGCATGCATATTTTGAAGAGAAGGATTTTTCCCAAATTTCCATTCTAAAGGAGCTCTATGAACATATGAATAGTTCCCTGGGAGGAACTTCATTAGAAGGATCCCAGGTATATCTTGGTTTATCTCCTCGAGATCTTGTGCTTCATTTTCGACACAAGGTCCTAATCCTGTTTAAACTAATTCTTCTTGAAAAGAAGGTTCTCTTTTATATTTCTCCAGTGAATAAATTGGTGGGTGCCCTGATGACAGTGTTATCCCTTTTTCCAGGCATGATTGAACATGGTCTCAGTGATAGTTCTCAATATAGACCCCGAAAGAGTATGTCTGAAGATGTTGGGCTTCAAGAAAGTAATCCCACTGAAGATGAGTTTGTTTCTATGCCTGCTCCTGACATTTCAAATACCAACTTGGAAACTGTTGAGAAAATCATGATGAGAAACCATGGAAGAGATGCTGCCATGAAGACTGAAGAGCCTTTTTTCCAGGTAGATGATGACAGCAGTGAAGGACAGGAACCCAATGACAGCAATCAATATTTGAAACCTCCTTCTCGCCCATCTCCAGAGTCTTCAGAAAGTGACTGGGAGACCTTGGATCCTAGTGTCTTAGAGGACTCCTCCTTGAAAGAAAGAGAACAGGTGGGATCAGAACAGACAAACTCATTTCTAAAGGACTCTTTGCCCTCAGACAGTCCTCCGATTACTGTACAACCTCAAGCTAACACAGGCCAGGTAGTCCTGATACCAGGGATAATTTCTGGTTTGGAAGAGGACCAGTATGGCATGCCCCTGGCCATCTTCACAAAGGGATATCTGTGTTTGCCTTATATGGCATTGCAGCAGCACCATCTTCTCTCTGATGTCACCATTCGAGGATTTGTTGCTGGAGCTACTAACATCCTTTTTCGACAACAGAAACACCTCAGTGATGCCATTGTGGAAGTAGAAGAAGCTCTGATCCAGATCCATGATCCAGAACTCAGGAAGCTGCTTAACCCAACCACTGCAGACCTAAGGTTCGCAGATTACCTAGTGAGGCATGTGACCGAGAACCGAGATGATGTCTTCCTGGATGGCACGGGCTGGGAGGGAGGTGACGAATGGATTCGAGCCCAGTTTGCAGTCTACATCCATGCACTGCTGGCCGCCACGCTGCAGTTAGATAATGAAAAGATCTTATCAGACTATGGGACGACCTTTGTTACAGCATGGAAGAACACTCACAACTACAGGGTCTGGAACAGCAACAAGCATCCAGCACTTGCAGAAATAAATCCAAACCATCCTTTCCAAGGCCAGTATTCAGTGTCAGACATGAAGTTAAGATTCTCACATTCTGTTCAAAACAGTGAACGTGGCAAAAAACTTGGAAACGTCATGGTCACAACGAGTCGGAATGTTGTGCAAACAGGAAAAGCTGTTGGCCAGTCAGTTGGAGGAGCTTTTTCCAGTGCAAAGACAGCCATGTCTTCATGGCTTTCTACTTTCACCAGTTCCACTCCACAGAGTCTCACTGAGCTGCCTGACGGGAAACCCTGAGCGGAGCAAGCCACCCAGAAGCTGCTGTCGCTTTCTTAGGTTTAAGCATCCCCTGTCTGTCTGCTGCTCCCAGACTGTTCCTCTTCATCGACCACAGGTCCACAGCAGGGACCAATAGGTCGAACTGTTTACAGGGACGGTTGCCCTCTGTGTAAATGAATGTCACGGGATGCTGAAAAGACGAAACCACAAGCGTAGCAGGGACGGCTTCCCAGTGGACTTGGCCTGTTTTTCTAGAAGTACCCTTCATGTTGTCAGTGTGGTTTCTGGCCTGCTTCACAGTTGGAGAGAAGGGCCAGCTTCGTTTATTAGGAAACCAGCGGAACTAAAGGACTCATTGCTCGTTTTTTTTTTTTTACTCTCTCATTTTGAAAATACTTGTGGTGCTTCAGTTTGTGAGGTGGTGACCCTCGCAGCAAGAATGTTTAGTGCCTGGGGCTGCACAAAGTACCACCAAACGGAGTTTGGTCGTGCAGTAACATCTTGTCACATGCTCACGGACAGAAATCCCCAGGGGACTAGGATATTGCCCCAAGCAACCCATTTTTCCATCCGTACTGGTGAGCTTCAGAATAACCTTGACATTTCCACTGAGGACTCCTAGCACATTTTCACATATGTATTTCCATGTACCATGGTTTCCTTATAGCTGTTTTGCAAAACAGCTTCACAGAAGAAGGAGACAAATTTCTTTGTTCCCAGGAATGTGCGCTGCCTTGAGTACAGGGTTAAATTTAAGGTACCAGTGTTCTTACAACGTGGACTGTTGCTGCCTGGAGCTGACAAGGTGACTCGGGCAGTAGAGCTCGACACCGCCAACATCTCCCTTTTCCGAGGACCTGTTCCAGCTGCACTTCAGGCTCTGCCGTGGTGAGGGGATGGTCCCCCATTGTCTCCCAGGTCAGAGCTGCCTTCTCTTCATTCTGATAGAATGGGAGTTGCAATGATCAAACCTGGCAACATCTGGAAAGAGCAGGATTATAGAGGCAGTTTCTTCCAAGGAACCACACTTTGTGAAGGGCTCATCTCCTCCTGTGGTAATCACAGGCTTAGGGAACCGCTCTGCAGCAGGACTGATCTGTCCAAGTTCACAATCGACAAATCCCCAGCGGAGCTTCCAGTCGCGTGACCGACAGCCAACTCCAGTCGAGGCAGCTAAGGTCTAGTCATCCAGCGCAGGTCCTGTGCAAAACTTTGCCTCAGCATGAGTTTTTGAAGACAGAGGAGGGAACCCAATTTTTTTTTACTTTGAAGGGCTGATGTTCTCCAAGTCTAGCAATCACATAAATGTCCGGTGTGTCCGGAACTGTCCTGGGCAGCCACAAGCCCTAAGGACTTTTAGCACCGAAGCAGAGACTCACACTGGCCTCCAGAGATCCAAGATGTGCACATCTTTGGCTACTTGCCCTGGGAAGTCACTTTCAGAACTAACCCATGTCCCTCACACTGCATTTTAAACCCTACCTTCTTCCCATCAAGTATTTGAGTGCCTACTGTGTACACACACAGTACATGCCACCCACATAGCAGGGGGAGAATGGATGGTTACCATAGTGGGTAAAGAGGCTGGGTCAAAGGTCAGCCCAGTGTGTTTGAGCAGGTGGCCAGCTCCTTTTTGGCAGGGGTGAGTAGATGTTTCTTCCCCTGAAGGCTAAGTGATAGTTTTAGGAGTGAGGTGGGTTTAGATACAAAGGGCTCCAGGACCTAGGAGAACAACATAGGCAAAGACTGGGAAGCAGTGAATGTTCTTTGGTGTGACTGGAACCTAAATGGCAAGGGGGGATGGGCAAGAGATGAGGCTGTAAGATAAGGCCAGGTTTGGAAAAAGAGATACCTGTCAGCCTGGCAGAGGGGGGGTGGACTTGATCTAAAAGGGCAGGGGAGAACCTTAAAGGGCTCTCCAAGGGCAAGTGGCAGGTTGGGTGCTGCATTTGAGAAAGTTCATTCTGGGTTGGGCACCACTGCATTTGCATGGCCATTAGCTCTAGTGATGTCTCTCTGAACTCAGCCATCACCGCCTTCCTTTTCCTCAAGGGCCCAATCTCTTAGCTTTGTACCAACTTTAAATCCCATTTGCCCCAAACAATGGGCCCCAGAACAAAACTCCTATGGACCCAGCCCTCAGTCAAAAACCAGTCACCCTGATGTCACCCTAAGAACTGTTTTCCTTTGATTTCTCCAGCCGTTAGACTAGCGGGGGTGGGGGGGTGGGGGCTTGTGAACGAGGAGCGGCTCTAAAGTGATTGTGGGCGGTGCCGGGAGAGCCCGGAGGACACTTAAGCATCTGCTGAGGTTACTCTTTTTGGCAAAGGGGAGACCCAAGAGACCCGTGCCGCCACCACCATGTTGATAAACCTGGGCGAAACTCACTGTTTCTTCCTAAAGTTTACAAGCAGGAAGGGAATGCTTCGTATGTTCTAAAAGTCCATCTGCAGTTAACATCCGGACTTTCATTTATATTCGATCTAATCCATGGAATTTTTATTCTGATCAGCGTTACCAGATGAGCCATGTGCACTGAGGAATGATTAGCCCAAAGTAGGACAGAAGAGAATCTGAAAAGTAGCCTTTCCACCTGCCCCCTGGCTCTGCCCTAGAAAACAGTCAGTCAGCAGCACTTCCTAGAAACCACGGAGACAGAAGTTACGCTGCACCGTCTTCAGCTGCAGGAATCCTGAATTGGTTCTTTGTACAAGATCATCCATGAAACGCCAAAGCCTCAGTGCCCTCGATAGATCATTCACTCCCACTAAATGCCTTAGAAATGGAAATTCCAGAGGAACTTGACCACCTGCTATATAGATGTCATTATCGGGAGTTACAACGGTTCCAACCTTATGTAAATCAGCTGGTGGGCTGCATAGCTTGTAAACTTTTTCTGCTTGGGGGCTGTAACAGACAGAAGA
->AB179100.1 Macaca fascicularis testis cDNA clone: QtsA-12801, similar to human tetratricopeptide repeat domain 3 (TTC3), mRNA, RefSeq: NM_003316.2 
-CAGATGTAAAGTCTACACCAGTGTCAGATTCATCTTCAGCACCAGCTTCTGAAGATGTGAAACCCAAACCTGTGTCTGCAAATTCTCCTGAGCCAGCGTGTGAAGATGTGAGGGCCAAACCAGTAGCCGACAATTCTTCTAGACAAGTTTCTGAGGAAGGGAAACCCAAAGGGGCCTCTTCCAATTCTCCCACACCAGGCTCTGAGGATGCAAATTACAAGCGATTCTCCTCTAATTCCCCCAGACCGGTTCTTGAGGATGTGAAACCAACTTACTGGGCTCAATCCCATTTGTTCACAGGATACTGTACGTATCTTCCTTTCCAGAGATTTGATATCACCCAGACACCGGCAGCATACATAAACGTGTTACCAGGTTGGCCCCAGTACACCAGCATATATACACCCTTGGCCAGCCTTTCTCCTGAATATCAGCTACCAAGATCAGTACCAGTGGTGCCGTCTTTTGTAGCCAATGACAGAGCAGATAAAAATGCCGCTGCCTATTTTGAGGGTCATCATTTGAATGCTGAGAATGCTGTTGGTCACCAGATTGCCTCTGAAACACAGATCCTTGAAGACTCTTCGGGAATATCTGTAAAGTCACACTGCAGCACAGGGGATGCTCATACAGTCCTGAGTGAGTCTAACAGAAATGATGGGCACTGTGGAAATTCTAACAACAAATGTGAAGTAATTCCAGAAAGCATCAGTGCAGTAACAAACATTCCACACGTGCAGATGGTTGCCATACAGGTATCTTGGAACATAATACACCAAGAAGTCAATACTGAGCCATATAATCCTTTTGAGGAACAACAAGGGGAAATTTCACGGATTGAAAAGGAGCACCAGGTATTACAAGAGCAACTTAAAGAAGCATATGAAAATTATGAGCAGATGAAACTTAAGGGCTTAGAAGAGACCAGGGACCTGGAAGAAAAGTTGAAAAGGCACTTAGAAGAAAACAAGATCTCAAAGACGGAATTAGATTGGTTCCTTCAAGATTTGGAAAGAGAAATTAAAAAATGGCAGCAGGAAAAAAAAGAAATCCAAGAAAGACTAAAATCACTGAAGAAGAAAATTAAAAAAGTTTCAAATGCCAGTGAAATGTATACCCAGAAAAATGATGGAAAGGAAAAGGAACATGAATTACATCTGGATCAGTCCCTTGAAATCAGCAACACACTTACAAATGAGAAAATGAAAATAGAAGAGTGTATAAAGAAAGGAAAAGAGGATTATGAAGAGAGTCATCAGAGAGCTGTGGCTGCAGAGGTATCCGTACTTGAAAACTGGAAGGAGAGTGAAGTGTATAAGCTACAGATCATGGAGTCACAAGCAGAAGCCTATCTGAAGAAGCTGGAGCTGATTAGCTGTGATCCTGCAGCATATCCTGACATGGAGTCTGATATATGTTCATGGGAACTGTTTCTTTCTAATGTTACAAAAGAAATTGAGAAAGCAAAGTCTCAGTTTGAAGAACAAATTAAGGCAATTAAAAATGGTTCTCGTCTCAGTGAACTTTCTAAAGTGCAGATTTCCGAGCTTTCATTTCCTGCCTATAACACGATCTTTGCCTGGGCTGTTCCCAGCCTGGAACACCGTCCCCGCTCTGCATCCTGCCTTCCCCTGAAACCCCATCAGAGGCTGCCCTCTTTTGGCCTCCCACTGTGGCCCTTCTCTCACATGCATTAGATCTCAGCCTGGCCTTGAATGTCTCTTTCCCGCCAGTACCTTGCACAGTAAACATCCAAACTTACTGTGAATTCATCTGAAAAAAAAAAAAAAAATTAAGTATGGAAAAAGTGTGACCACCCTGAACTGAGTAAAATATTCTGTTGAGATCCAGTTTTTTTCTCTCCATTGAATGTGCAGTTTTAGTTAGAATTACACTAAAGGGCGGCCGGGCGCAGTGGCTCAAGCCTGTAATCCCAGCACTTTGGGAGGCCGAGACGGGTGGATCACGAGGTCAGGAGATCGAGACCATCCTGGCTAACACAGTGAAACCCCGTCTCTACTAAAAAATACAAAAAAACTAGCCGGGTGAGTTGGCGGGCGCCTGTAGTCCCAGCTATTCGGGGGGCTGAGGCAGGAGAATGGCGTAAACCCGGGAGGCGGAGCTTGTAGTGAACTGAGATCCGGCCACTGCACTCCAGCCCGGGTGACAGAGCGAGACTCCGTCTCAAAAAAAAAAAAAAAAAA
->XM_018370368.1 Pneumocystis carinii B80 hypothetical protein (T552_01802), mRNA 
-CTTATTTTGCTTAAAACTAAATACATCTGGACACTTTTCTATCTTAATGGATGATATTTTGGATATTACAGTTCAATTTTCAGGAGGGTTACAGACCCTATTTGGTAACAAAAATACTCATCATATTCAAATATTACTATCCGATCCTGCTTTAAAAGGTAACCCTCCTAACATTGCTTATTTGATACAATTTTTATCTGAAAACCTCATGAATGATGCTCGAAAAAACTTTTTCATTAAAGATGATACTGTACGTCCTGGTATTCTTGTTCTTATAAATAATGAAGATTGGGAATTAAATGATGAAAAGTATTATATACTTCAACCTAAAGATGAAATTACTTTTATCAGCACATTACATGGAGGATAATTATAAATAAATAAATAAATATCTCTTGAAAATTATTTTATTA
->XM_028690088.1 Plasmodium gonderi protein phosphatase 2C domain containing protein (PGO_140940), partial mRNA 
-ATGGGTAATTGTATGTCCATTATTAGTTATTCCAAATTCAAATTAAAAAAAAAAAAATTGGAGGATTCGGATGTGCATTCAAACCCAGATTACGAGAGCGCAACTGATAGCAATATCCGTGATAAAGATGAAAAAAACAGAAAAGGAAAAGACTTAAAGCATAATCCAAATTTAAACAATTCCAATTGCGATAAAAAAAGTTTTAATGTCATCCATGAACATGATACAAATTCCATATATTCAAGCAATCCTGGTAACTTTGATCAAAATGAGAAAGATGAACAAAAGCAGCCTGTTTCCAATGAGGACATTGGTTACCTACGAAGGGAAGAATCGGATCATCATATGATAATCCAGAAAAACAAAAAGAAGAACAAAAATAGTAACAATGTGATAGGAAATGACGAGATGAATCAAAACGAGGGAAACCAAAACGAGGTGAACCAAAACGAGGTGAACCCAAATGAAGTGAACCCAAATGAAGTGAACCCAAATGAAGTGAACCGAAACCAGGTAAACCAAAGCGAAGTAGACAGAACCAAGGTGACAAAAAAAACGAAAAAAGAAAAAAGCGAATCCAAATCTAATATAAATGGAAAAGTAAAACGGAGCACGTCCAAAGACAAAAATACAAAAGACATAATTCCCAATAGTACGCATAACGACAGAGATAATTCAAAATCAAACGAAACACATGATTATAAAGGAGATGTGTTTTCAAATAAGAATTCCTCATTTAATAGCGAATCAGTTAATAGCAAGGATTTGCAAAAAAGAAACAAAAGAGAGAACTTACTGAACATAAAATACAGCAATATGATATTAAATGATATAAGAGATGTAGACATTATTGTCGTTTTTTTATTTAGTCTTTTCCTTTATTTTAATGCCAATAATATAGTAGACATGTTGGATAGAAATAAAAAGGATAGATATTCTCTTAGGAATTCATTGAATATAAATCATGATATCATAAAATTCCCAACGTTTCCCAAAGAAATTATTGACAGTTTTTTGAAAAATGATTTTACTTTATTAAAAAAATATATAAAAAATAAATGTAATAAGTTGAAGAAGAAGTATAAAAGTACATATTTAAAAAAAGTCACAATAAGTAACGAAAAGGGTGAAAAAGTAGAAGCAGGAGAACAGAATCAAATCGGAAAAACAAATCAAAAGGATGAAAAAAACACAAAAAAGAAAAGTTTTAAATACGAATTAAAAGAAAAAAAAGAAAAATGCACTTTTTCAAAAATTATTGAATCTGTTGATAGAAATGAATGGATTCATAGAGACATAACCGAAATACCATGTGATCAAAATTTGCCAGATCTGAAAATTACTTTTATAGTTATGGGGGCATATTGCTTTTACCAAAAAAACATGAAACCATTTCAAGATAAAAATACTTTTTTTTACAAATCCCCATCATATGCTTGTGATGCAGAAATTTCTGTTGCATGTAAAAAAGGAAGAAAATTAGATTTCCCAAATCAGGATGATTTTACAATTATACAAACTAATGAATGGATTTTAATTATGGTATTTGATGGACATGGGCCATCTGGTCATGACATCAGTAATTTTGTACATGTAGTACTCCCTTTACTTTTTTCATACAATATTGAAAGAATATTTGAAAACCCTGTTCGAACAATGAAAACATTATTTTATATGATAAACTGCTACTTAGTTAATTATTCCTACTGTATAAATAATAATATAAATCCAATTAACATAAATTTTATTGATTATAATTTAAGTGGAACAACATGTACAATCATACTCTACAATTTTCTAACAAAAAAAATTTATTCTGCCCACACAGGGGATAGTAGAGCTGTTATGGGAAAACAAAATGAAAAAACAAACACATTTAGAGCTTATAATATTACTGAAGATCACAAACCATCTTTAAAATTAGAAAGAGAACGAATTGTTGCATTTGGTGGAGAAGTGAAAAAATTGCAAGGAGATGTTTCATACCGAGTTTTTGTTAAAAATGAAATGTACCCCGGATTAGCCATGAGTAGAGCTATAGGTGACATTACTTCGTCTTTCATTGGTGTTACTTGTGAACCTACCATAAAAATATTTGACAAATCTGATGAAGACAAGTTCATTATTGTTGCAACAGATGGTATCTGGGAATTTATAAGTAGTGAGGAATGCGTTCAGATGGTTTCTCGAAAGAGGAAGAAGAAGGTGCACGTTGCCATGGAAGAAATTATCAAGGAATCTTGGAGAAGGTGGGAACGAATTGACACCGTCGATGATATGACACTGGTTATTTTATATTTCTAA
->XM_024490585.1 Echinococcus granulosus hypothetical protein (EGR_01336), partial mRNA 
-ATGCATGGAGCGCTTCAGATGCTGCATCGTGAGGACGATATTTATGGCGGTTTTCCTTCAGCCGTCCTCCTCGCTCCCTCTACTCTTACAAATGGTAGAAAGCTGCCCATTATCGCAACCTCCAGTGAAGGCACACCAATCGGCTACATAATTACGCCTAATCCTACCAATGCTGATTCAAAATTTGTCGCTAATGAGACAACGGTCCAAAAGCAACAAATAGGATCTGATGATGCTTCTTCCAGCTCTACCGGTCACGTAAAATCCACCTGCAATGGTCTTCTGTACCGACTACCTGATGGAGGCTATGCAAAGGTGGAAAAGAATTACATGACAATCAACCCCAAGCTCTATCAGCAAAGCATATATCGAAAGCTCCATGTTCATGAAGAATGGAACGGACCTATCACCCAAGCAAATAATGCTCAGGAGGATAATCACGGCATTAAGAAAAAGGTTGTTGTGGCCCATGAATCGTCGCCTGTTTTGGAGGGAGGAACGGGCCACGAGGAAACTGACGTCGACACACCACAATGA
->XR_004086260.1 PREDICTED: Quercus lobata vacuolar sorting protein 3-like (LOC115966022), transcript variant X5, misc_RNA 
-ATTTTTGAACTTTGCTCTGTACGTAGGGTCCAAGGAAACTGATGAAAAGGCTGATGAGGTTCTAAAGTAGGATATTTTGGATTGTTGGACGCCAGAAAATCACTATGGATGGACTGAATCTAAGTGTTAAACATTTCTAAATTTAGACCATCTATAGTGATTTTCTAGAGTCCAATAATCCAAGATATCCAACTTTAGAACCTCATCAGCCTTTTCATCAGTTTCCTTAGACCCTACCTCTGAGGTCCACGAAAATGGAGGTGTATCATAAGAAGTCGGGTAGGTGTATTCAATCGATAAGTTTTGGTGGGGAAGGAGTTGGAGCTAGCGTTATTGCTGATGAGGAAGTTGGGAGTGGGAAACTTGTTGCTGTTGGAACACCCAACAAGGTTATTTGCTATCGTAAATTACCTTCTGAAGAACAAATCAAAGACGTTTTGAGAAAGAAGAACTTTAAAGAAGCCATTGCCTTGGTGGAGGAACTTGAGTGTGATGCTGAATTGTCAAAGGATATGCTCTCCTTTGTTCATGCTCAAGTGGGGTTTCTATTGCTGTTTAACCTGCATTTTGAGGAAGCAGTAAATCACTTTTTGCTGTCAGAGACAATGCAGCCTTCTGAAAGATAAAGGTACCTCCAGTGGTTGATTGAAGATCAGGACTGTGATGATACTCAATTCCATACATTATATGCTCTATCACTTGCCAAATCAGCAATTGAAGCCTTTCAAACTGAAAATACTTATCAAAACAGTGACATTGGAAGGGTAGATGAGACAGTAATTTCTGATAATAGAATGAACTCGATCTTTGAAAGTCCTCTTCGAGAAAGACTGCAGATATTTTTGTCGTCTTCAGACTTGTATGATCCAGAGGAAGTTCTTTACTTGATCGAAGGATCGGAGTTATGGTTGGAAAAGATCGTTTACTGCCTAATGATTTGCATCATTTCTTTCAAACTGTTGTTAGGCAATTCTTTACAGTAAACTGGGTCAAGAGGGATTAGTGCTCCAAATTTTGGCATTAATCAGCACTGAAGAAAATGAAGATGAAGTGACTGAAAATGAAGAAAATTCGGGTTCTGCTTCTACTTCTGCCAGTACTGAAGAAAGTATTGAACTTTCACCAGCAAGAGCAAGACCTCAAAGGGTGAACCGTGCACAAACAAGACTCATGTGTTCATTTCTCCAAGCAAGTTGAGGGTGAAGCTCATAGGGCCTCACCATCTTAGAAAGAAGGATGGATCAAACAGTAACTCTTCTAGACACAATTTGGTTTGCTGAGGAAGGTAGTGCATAAGCCATGGTTCTTGACAGCATTCTATCTTCTCCTCATCGTAGGTCACCATCATTCAGGAAGCAATTCTCGCGGGATGATTCATTAAGCTGGCCAACACTCCTTCAAAGGCACCGCTTCCTCTTAATAGCTCTAATTCTCCTAGCTTTCCTATGCACTATGTATCTTTATTTTGCTGTCACTTTAGGTGCTTCTGGATCATGTTCTGATTTAAAGGGTGCTCAGAAAGCGTCAGGTTTGGATGCAAAAGCTTCTGTGGGCAATGGAAAATTGAAATTCCTTTGACATGTAGATGATAATTATAGTTGGAAAGCATTTCCGTCCTTGGTTCTTTTCGATTCTAAGGAGATTGAATTTAACCATACTTTTAAAATTGCAATAGGTTGTTTGCTGTTTTTGAACTCAATTGTCCTGAATCTTATATATGAGAAATGTAACAAAATTTTCATTTGGAGACTATATAGCAAAAATTTGATTTGGA
->XM_033023418.1 PREDICTED: Amblyraja radiata transmembrane protein FAM155A-like (LOC116974698), mRNA 
-AACTCCCGTGCCGTCTCCTGTTCAGTGCATGCTCCGAATTGATGAAAAGCCGCAGTTTCAGATGTATACTGCAGTAAGGAGACTGCACCGCAGCAGGATTGTGCTCAGCAACGGGCGGCTGTAAAAGGAACTAGTCTGGCACTAAATGCGCACGGCGGCACACGATACAATACTATTACACCTTTCGCCTCTTGTCCCATTGCTTTAGGCAGCGGCCGGGGATACATCTCACGCCAGAATGTGAACTGGACGATCGCCGCGAACACCGAAGACAGGATCCAAAGTGCCACTTTTTGGTGCACGGTTCGAAACTTCGCTCGAGGATTTGTTGTTGTTGTTGTGAAAATAGCGAAGGGCAGCTGATATTTGTGCGTGGCTGTGGCTGTGCCGCCGCAGACACGGCTGGGACGCGCCTGGTGCACAAGTGGATGATGCAGCGCCGGTGTGTGGCAGCGCTGGAGATGTGAGTCTCCCCTTCTCTCCCCTCAGCTCAATGTGCCAGGATGGAGCGATCTCGGTGCTGGGATGACGCAAACCACCGTCCTCAACCGCAACCCTCACCCCCCGCCCAAAAATAATAATAAGAGGTGTTTCTGGGCGAAGATGGCCGCAACTTCCACCCAACATGATGAACGCTGCGTTGCTCCAAACGCCAGGGCCAGCGACGTTTCGTCGGCATCAGGAGAAATAGTTCAACTTTTCTCTGCTTGCATCTGGTGAATTTGTTGGCGCCGATGTTGGCAGGGTCGGATGTGTGAGGCTGGTGTGATGTGAATCTGCAGAGAGTGGGCAGGGGAGAGAGGAGCTCGCTCGCCGTCGCCAGGAGCAGGCTTTCCCCCCGGAGTGCCATGGATAAGTCTGGTGTGACTCTCCTTGCTGCTCCTACGGATTGGATGGCAACAGTTGACCACCCGTACATGCAACCCAAGTGAACGCTCAACAGAATAGCAACGCGGCTGATCTAGCAAGACAAACCCGGTCAATGTATATCGAGGCAAAGGTCCGTTCGCCGCGGAGCCAGCCCGAGCCGCACTTGTCCACAATATGACCAGAGGCGCCTGGATGTGTCGCCGGCAAGACAACGGATTACAAATCTGGTATGTCCCCCGCCAGAACGACAAACCCTGCACGGATTCAGAGCGGGCCCAGAAATGGCGACTGTCTTTAGCATCTCTGTTGTTTTTTACCGTCCTGCTATCTGATTACTTGTGGCTGTGTGCGGATGCGAATCTCACCAGAAGCAGAGACCAGGAGCGGAGCACTTCAGCCGAGCCGACGGGGGGGAACCGCTCACTGTCCCCACTGTTCCTCAGCGCTGATCAGCCTAGGAGCACCGCCAGCAGTGACAAACGTGCTATTTTTCTAGGTAATACCACTAGCAGACCCATCTGCCAACTGGAACCGTGTCGCCCATATTATGTGTGTGAGCAGTGTGTAAGTATTGAAGATGCAGAGACTGTGTGCGGGAGCGCCGGCGAGGATGCGTCCAATGGGTCTCCGCCGCTGTCCTTCAACAATTTCCACCTTTCCTTTTGTGAATCCTACACCCTTTCTGAACTGTTCGCCGGGATGTCGAGACCAGAGGGCTCCAATTGCGATCTGAGCCTTGTGCTGGACGGCGACGCCACCGTCTGCATTCAGTGCGTTGAGATTTATCAACGTTTGGACCAACATGCCCAAGAGAAATACGAGGAGTTCCAGAGCTTGTTTCAGAAGTATTTACAGTGGGGAGATTACTCTGTGAAAAGTTGCATCGATGACTGCAAGGGACAGATGGTGCAAGGTGCCAGCAAGTTCACGAATTGCACATATGAATGTGTTTGCAGAAGTTCGGAGACTGCTGACACTTTTAAGGAACGGTAG
->XM_033152434.1 PREDICTED: Lacerta agilis small nuclear RNA activating complex polypeptide 2 (SNAPC2), transcript variant X3, mRNA 
-AGCGACGGCTTTTCACTAACTAGGCGGCGTTGCGTTTGAGGTGAGGACTACCGGAAGATAACGAGCAGCGTTGTGTCGCCTTAGAAGCCAGGAACGGGTGGCTAGAGCGCCATGAAGCCGCCTTCCAGGCAGCGTTCAGCCCCTGCTCGCTACAGGATGGCCCCCACGAGCCAGGCTTGGACGGACCCAGAAAAGCGACGCCTTCTTCGGGCCTTGAGAGCTCACGGCCAGGGTCCGTTGCGGCCCGAGCTGTTGAAGGAGTACCTGCCTTCGAGGGATGAAGAAGAGATCATGGCATTTGTGGAGCACCTGAAAGAGCGTGTAGCAAAGGAAGCGGTCAAGGAACAATATCAGTATCGCCAGCGTAAACAGAAGGATGCTCCTATTCCAGCACCTATTGAGGTTTGGACAATTGCATCTACTGAGCCACTCACCTTGCTCCATTCCGTGCCTCCAAAGTCAGTGGTGACAAAGAATTCTCAATGTTCATCCCAAAATCTTCATAGTGAGAGTAGGAAATCCAACGAAGAATCTCATGAACCAACTGTATCATCCAGTGTAGAGGAAATAGCCCCTGCAGAAAACAGTGGGTTCCATGTGGACTTTGAAAAGATCTACAAGTACCTTTCTGTGATCTCACGTGGCTGTAAGGCACCTGAACTCCCACCAGGTGAGTCAGCTGTGGTCCTTGATTTGCTACTGTCACTGCCAGAAGAGCTGGGCTTTCTGGACTATAAGAAGCTGAAGAGTCACATGCACAAATGTTATACAGAGTTGAACACCCACTACACAGGTGAAAGAAGCAGAATGAAAGAGGGCAACCAGCCTGTAAACAATAATGGAGAGCTATTCCTGCATGTGCAGCCAGCTACTAGTGGCTTACCACAACAGGAGAGTAGTAGTTCTCCTACCACTTCCCAAGATGATGCAACTTCTGCCTCTGCCATGGACTGGAAGACTCTGGGTATCTGCCCTTTGAATTCATTCTTGATTCCTTTGGATATCCTTGCACGTAAAGAAGAAATCTTTGACTGAGGGAACTGGATTCTGTGCTGCCCAGTAATGAACTATGTGCTCTCATAACATGTGAGGGAAGACTAAACAAGCTTGCCGAGCCTACCTTAGCCATGCTCCCCCATCATAGCATGGAGTTTAAGCAGCCTGACCTGCTCTTTTACACCTTGGCTCATGAGTATGATACTTGTTTTGTATTAATACTATATGTACACTGATGTCTGGTCTTACTACTCCATGACAGCTGCTAGATCTTATTTAGCCAGTTGCTATGTAGCAGCTCATAGATGGCCTTGAGTGTTAATCTTGACCTTGGTCTACAGATCATTATGGTTAGTAAAATAAGTGATGTTAGATATCATTCCTAAGTCACAGAATAGTCAAATTATTTTGTAATAACTTATTTTTAAATATATATA
->XM_011762108.2 PREDICTED: Macaca nemestrina family with sequence similarity 192 member A (FAM192A), transcript variant X3, mRNA 
-GGGACTCTATTGTGGCGGTGAGGAACAGGAAGCCCTGAAGGGTCAAAAGGAATACAAAAGCAAAGGCTATTTTCTTTTTTTTTTTTCTTCTTTCATTCGTTCCTTCCTGTTTCTTTCTTTCTTCCTCTCATTTTTGTTTTTCTTTTTTAAGAGCGAGCGGCTCTGCGGTGGCGGTTTGGGGTAGGCGCCGCCGAGGTGAGGGCGTCTCGCCTCCCGCGCGCCGGTAGAATAAACAGCCATTGGACTCTTCAAAGAAATACGCTGTCTGCATCAAGTACTGCTTTTGCAGATTGGTTGTTTCATTATGGATGGAGGGGATGATGGTAACCTTGTTATCAAAAAGAGGTTTGTGTCTGAGGCAGAACTAGATGAACGGCGCAAAAGGAGGCAAGAAGAATGGGAGAAAGTTCGAAAACCTGAAGATCCAGAAGAATGTCCAGAGGAGGTTTATGACCCTCGCTCTCTGTATGAAAGACTACAGGAACAGAAGGACAGGAAGCAGCAGGAGTATGAGGAACAGTTCAAATTCAAAAACATGGTAAGAGGCTTAGATGAAGATGAGACCAACTTCCTTGATGAGGTTTCTCGACAGCAGGAACTAATAGAAAAGCAACGAAGAGAAGAAGAACTGAAAGAACTGAAGGAATACAGAAATAACCTCAAGAAGGTTGGAATTTCTCAAGAGAACAAGAAGGAAGTGGAAAAGAAACTGACTGTGAAGCCCATAGAAACCAAGAACAAGTTCTCCCAGGCAAAGCTGTTGGCAGGAGCTGTGAAGCATAAGAGCTCAGAGAGTGGCCACAGTGTGAAAAGACTGAAACCAGACCCTGAGCCAGATGACAAGAATCAAGAGCCCTCATCCTGCAAGTCTCTCGGAAACACTTCCCTGAGTGGCCCCTCCATCCACTGCCCCTCTGCTGCAGTCTGTATCGGCATCCTCCCGGGCCTGGGCGCCTACTCTGGGAGCAGCGACTCCGAGTCCAGCTCAGACAGCGAAGGCACCATCAATGCCACCGGAAAGATTGTCTCCTCCATCTTCCGAACCAACACTTTCCTCGAGGCCCCCTAGTTTCTCTGTCCTTAACAGGGAGCTCCTCCCCAAGGGTAGATTGGACCGTTCATGCTGCCTTCGGGCATTACGTCTCAAAAAAAAAACTCCTTTGCCTGCATCCTGTGCACAACATGACACTTTTAACCAATCCAATCTAAAAATGTGCCAGAATCCACCTGTGGCCCGAATTGTGTTTGGTTTCTCTTTCTACTGCAGTGCACATGAGCAAACCTATCCCGCTGCCACTTTCCTCACTGATACTGGGAGGAGGGCAAGGCCCAGCTGAAGTTCCACTAAAAATGCCCTAGGAGAATAGGCACCGGCTGGCTTGCCAAAGGGTTTGGGTTTTATTGCTTTCTGTTTTTTTCTTTTCCTGACAGCACAAAGAAGTAAGGGCAGATATAAGTAAGAAGTAAGGTGTTATTTAAACATTCTATTGTAGGTGAACGTGTTGTTTGGTTCTACTGCATTGTGGAGCATGCGGGGGAAGAGAACTGACCCAGGTGATGAAATGGAGCCCTTCCCTGGAACTAACCAGTCCTTGATGTTGTGTGACTAAGTAAAGATGATAAACCCCATCTGCTGGGGGTGTCACTTCACACTCGGCATGCATTGTGAAAGCTTTCCATACCCTTGGCCATTCTCTCTCCCCTCTTTATCCAACCCCGTTTATGCAGGAAGGGACTGCTAACAAGAAAGCTTCCATCTCAGACCTTTTCTCTGCCTGGAAAATTATTTTATGTTTGTTTTTGAAATAAAGGATTTAGTTTAAGATTCTAAA
->XM_030051840.1 PREDICTED: Myripristis murdjan protein DDI1 homolog 2-like (LOC115359395), transcript variant X2, mRNA 
-ACATGTCGAAAACATCCTGAAATGCGGCACTAGCACTGGTAGTTGATGTTAGTTGTTGAGATAAGAGAGGAAACTGTCCGAGCAGACCTGGACTTAGTGAGTGTAAACCAAGGCGTTGTGTTCAGGGGGGCAACACCAGTTTCCCTTTAATGAGAGTTTCACCAGAGACCGTCTTCACACCGGGTCACACTAGCTGTTTAGCTCAGCGGGAGAAGGAACTCCAGCAACGGCGCTTGTGTTGCAGCGGGCTCGTCAACTGATCCTCCCCGAAAACAGCGATGCTGGTCACCGTGTTCTGCGCGCCGAGGGACCGCCCGGAAACCACTTTCGCCCTCGACGTGTCTCCGGAGCTGGAGCTGAGAGACTTCGTAGCACTTTGTGAACTAGAATCAGGGATCCCGGCGGGAGAGATCCAGATCTCATATGTAGAGCAGCCCCTAAAAGACCCCACTCGTGCCTTGGGGAACTACGGCGTGAAGGATGGAGATGTGGTGGTTCTCAGACAAGCAGACAGAAAGCCACCACCACCAACTCAGCCAGCCTTCCCAGGACTGCCCCATATAGACTTTCGCTCCATCACAGTCCCAGGCACGTCTTCTTCGACCAGTCAGCAAGCTGCCACAAGGCAGCAGCGTCAGGCCCCACAGCAGCAGCAGCAGCAACAGCAGCAGCAGCAGCAGCACACCGCACAACCTTCTACGCCAATGGCCTTCCGTGGCTCTGGCTCCTCTCCACAGGGGCTGGATGACCCTGCCTTACTCCAGCAGATGCTGTTATCCAATCCACATGAGCTTTCACTCCTCAAGGAGCGCAACCCACCACTGGCTGAGGCCCTACTCAGCGGAGACTTAGAGCGTTTCACCAAAGTGTTGCTGGAGCAACAACAGGATCGGGCACGAAGGGAGCAAGAAAGGATCAGACTCCTGACTGCTGATCCGTTTGATTTGGAAGCCCAGGCGAAGATTGAGGAGGACATCAGGCAGCACAATGTGGAAGAAAATATGACCATTGCAATGGAGGAGGCTCCAGAAAGTTTTGGACAGGTGGTTATGCTCTACATCAACTGCAAAGTAAATGGGCACCCTGTGAAAGCTTTTGTTGACTCAGGAGCTCAGATGACAATAATGAGCCAAGCGTGCGCTGAGCGCTGTAACATCATGCGTCTAGTGGACCGACGCTGGGCAGGGATTGCAAAGGGTGTAGGCACCCAGAAGATCATTGGCAGAGTTCATTTGGCTCAGGTCCAGATCGAGGGGGACTTCCTACCTTGTTCTTTCTCCATCTTGGAGGACCAGCCGATGGACATGCTTCTTGGACTTGATATGCTGAAGAGACACCAGTGCTCTATTGACCTGAAGAGGAGTGTGCTGCTGATTGGCACCACAGGCACTGAAACTCGCTTTCTACCTGAGGCAGAGCTGCCAGAGTGTGCCCGGCTGGCATACGGGGCAGAGGGTCGTGAGGATGCCCGCCCAGATGAAATAGCTGACAGAGAACTGGCAGAAGCACTTCAGAGATCCATACAGGAAAGCGGACAGCACTGATGCATTTGGAGACAGCTGGAGAGGGCCCTACCAACCAGACACTGCAGATGGACAAACTACCTCACCAAAATCCCCACCATTCCCATTACCCATACCCTTAGACCAAATGTCTTCATCAACCTCCCCTTCCCAAAGACC
->XM_042461403.1 PREDICTED: Sceloporus undulatus damage specific DNA binding protein 2 (DDB2), transcript variant X4, mRNA 
-GGAGGCTGATGGTCCTGGCCACTACCCTTGGCTCCCTCCCTCCTCCTCCTCCTCCAGCCGAGAATCAGGGCCCTGGAAATAGCACTGAATTGAAAACCGTTTGAAAGGTTTTAAAACGTAATAGATAAGATGAAAAGTACAGCACCACTCCTCCTCAGTTAAAAAAAAGTTGAAGCAGATGAACCCGGATTCCTAAAGGCAGGCGTGAAACCTCGCAAGAAGACTCATCATAGCACCCTTGAGGCTCTGGGTGGTGCTGTGCAGGCATACCAGATCCAGAGCCCAGAAGACAGGAAGGAAAACGAAAGACAGAGACTTGGCCAAGAGTTTGTGTTGTGTCCTGTTAAGTGTGTAAAAAACAACGAAGACAAGCTCCACATGCTCTAGGATGATAATCTACCAGCTGAAGCCAGTCATTTTTGGTTTTCATTCCAATCGCCATTGTTCAAGATACAGTGTTTTAATATAATGCATCCTGGGAAGGATTCAAAGGACAAGAAACATCTGAGGATATCTGATAGTGCATCACAAAAAGAAGCAAAATCAAATGGAAAAAGAAAGCGAGACTGTGAAGACCTAGAAAATGAGCCACAAGCAAAAAAAATACATCTGAGGAAAGCTCCCAAATGTCTGGACAAAACCGGGCAATCTTTCAATTGCTCCATGATCCGAAACAGAGGGGTATTCGTCCATCAGCTGGAAATGCAGAAAAATATTGTCCATTACATTTATCAGAACATGCTGGGAAGCACAATCAAGACACAGCTCAGAAAGTGTCTACAGGTGCCCTTTGTACGTTCTCTCTATTCATACCGCCTCTTCCGAACAGCAAGTCCTTTCGATAGAAGAATTACATGCTTGGAATGGCATCCAACATACCCTAGCACAGTTGCTGTGGGCTCCAAAGGTGGAGACATCATTCTGTGGGACTATGAAGTGCTAAACAAAACCTGCTTCATAAAAGGAATGGGAGCTGGAGGGGCCATCACAGGAATGAAGTTTAACCCTTTTAATCCTTGTCAGCTGTACACATCATCAATTGCTGGAACTACTGCCCTGCAGGATTTTAATGGAAATACAGTCCAGGTCTTCACCAGTACCAACGACTGGGATTTCTGGTACTGCAGTGTTGATGTATCTCCAACACGTCAGTCGGTGGTGACAGGTGATAATGTGGGCAATGTCATCCTGCTTAGTACTGAGGGTAAAAAGATATGGAACCTGAAACTGCACAAAAAGAAAGTTACTCACGTGGAGTTTAATTCTCACTGTGATTGGCTCCTGGCTACAGCGTCAGTGGATCAGACAGTTAAAATCTGGGATCTAAGAAACATAAAGGACAAATCAAGCTGTCTTCATATACTTCCACATGACAAACCTGTCAATGCAGCTTATTTCAGCCCAACCGATGGTGCTAAGCTACTGACTACTGATCAGCACAGTGAAATCCGGATTTATTCATCTTCTGATTGGTCCAAACCACAGCATTTGATCTCACATCCTCATCGCCAGTTTCAGCACCTTACGCCTATCAAGGCAACATGGCATCCTCGTTATGATCTCATTGTGGCTGGTCGTTACCCAGACCCTCTTTTCCCAGGATACACAGCAGATGAACTGAGAACAATCGACATATTTGATGGAAACAGTGGGGAGATGGTGTGCCAGTTACATGATTCAAATGCATCGGGCATTATCTCGCTCAATAAGTTTAACCCTATGGGAGACACACTGGCCTCTGGAATGGGCTTTAATATTCTTATTTGGAGCCGTGAGGAGATGGTGACCAAAAAGCAGGAGCATCTCATGCAAGCTATGACAGAGGAGGGAATTGGACACAGGAGCTTATCTCGACAAGGAGGTAGAAGGCAGAGACAGTCAAACCCAGGAACAAGCAAATCTAAAGCTAAACTACTCAGTCTTGAATTAGAGAGCTCTAAAACTCAGGCCAAAGAACACAAATTGCAAGAGAAAAAGAAAAGAAAGCATCCAAAGGACTAATCAGGCAAGCTTTTCTGTAATGCTGGTTAAAAACAGCCGGTGCAGACACAGTGGGCTGAAATGGCTTCAGAGGTGGCATGCCCATTACTCTCACCCAGCTTCTCCAGATCATAAAAACTGAGTTGTCAAAACAAGGCATCCTTTATTAAAGGCAATAATGGATAAATGTTCACTTGAATTTAAGTGAGCTGAAAGAAGCACCATATTTGTGCATAGCTGCTGATTTTTAATTGCCTAGGACATTGTACAGAGCAGCGATCTGGAGTATCCTGGCAGTTAAGATTGTATTTTCAGAACATTATTATTATTAAGTTTTATTTATATAGTGCTGTAAATTTACACAGCGCTGTACATACAGTCTTTTTAATTAGACGGTTCCCTGCCCTCAGGCTTACAATCTAAAAAGACATGACACA
->XM_022360255.2 PREDICTED: Drosophila obscura nurim homolog (LOC111069978), mRNA 
-CCAGCGATATTTTCAATTGCGTCCGTCCAAGCAGTCAAAAAAATATTTATTTTGCAATTAATTTATAGTGTTTTTTTTTTTGTGTAAATCATGGCCAGTTTTGCCAAGGTTTTGCTGCTCCTGAGCTCGCTGGCCACTTTCGTGTATACCTTTTTCGTGGTTGGCAAGCTGGTGCTGTTCCTCTCCACACCTCGCTCGATTTCGAAGGCACACACGTGGATTTTCAATTTGCTGGACAACAAGTCCCGGCTGGAGACCGCCTATGGGCCCATTGTGTTCGACACACTCTACCTGATAGGATTCATCTTCCAGCACAGCTTCCTTAAGTCAGCGCTGGTGAAGAATTTATTGGGCAAATTGGGCTTGGCTGCAGCCGAGCGCACTATTTATAGTTTGACATCATCGCTTTGTTTACATTATCTGCTGAAGAACTGGCTGCCAGCCCAGTCGATTGTCTTGTGGCAAATTGATGTGGACGAGAGTGCTCCACTCTGGTGGACTTTTGTGGTCACACATGGCCTTGGCTGGGCCGTCATCTTTGGCGGCTGCCTTATAATGGATCTGCCCGAGCTGTTGGGCGTCAAGCAGGTCTACTATGACCTTAAAGAGTATGGGGAGCCCATTGCCTACAAGTCGAGCGAGCTGCGTCATCTGTACTCTCATGTGCGTCATCCGTCCTTTGTGGGTCTCTCCTTGATCCTGTTTGCCACGAATGTCATGAGCCTGGATCGCCTGCTGCTGGCCTCGCTGCTCACCGTCTACATGTACGTGGCCTGGTCCACTGACGATAGGGACGTGGCCTACCAGAAGCAACAACTGCAGTGCAAGAAACACGAGCTGAAGGCTCAGTAAATCGAATTCTTCTCATTTAGCTCTAGTTCCTATTTAAGCTGAACGTATAACACATTAAAGACTAACTCATCCTAACAATGGA
->XM_017911197.1 PREDICTED: Eufriesea mexicana RING finger protein nhl-1 (LOC108555529), transcript variant X6, mRNA 
-AGGCGGAGGAACAGAGCGGCGAAGTAGCTGGCCAGAAATAACTAATAAGACATTCACTCTAAGACGGGCGGCCAACCGGCCCGGACAAACGCGCTGTCACAGCGCCGGATATTGGTGAACGACGAGTGCGACCACTTGGGGCCCCCATAGAGAGGGCCCCCAACCGGAAGAGGCCGCCGCAAGGCGGTCGATCTATCAGGCATGGAGCAGTTCGAGCAACTGCTAACGTGCGCGATATGCCTGGACCGATACAGGAACCCGAAGCTACTGCCATGCCAGCACAGCTTCTGCATGGAACCGTGCATGGATGGCCTCGTTGACTACGTGCGTCGACAAGTGAAATGTCCAGAATGCCGCGCGGAACATCGCATCCCCTACCAGGGTGTGCAGGCCTTCCCGACCAACGTGACCCTGCAGCGATTCCTGGAATTGCACATCGAGATCACCGGGGAGCTGCCGGACCCGACCAGCGGCCAGACAATGGAACGTTGCGGCGTCTGTTCGGAAAAAAGCTACTGCTCCCTCTGCGTCCACTGTGAGAAGAAGTGCTGTCCCGAATGCAAGGACGCTCACATGGACATCCTCAGGCGCGAAATTACGCGTATCAATTCCCAGATTCGCAGGGGACTGCACAGGTTGCAGGACGCGCTGGCTTTGGTGGAGAAAAACACGTTGGGTCTGCAAACAAACTGCGCCTCGGTCGCGGAAGAGGTGGACGAGATTTATCGGAGGCTGAGCAAGGCTTTGAAAGACCGTACGGAACATCTGCGTAACGAGGTCGATCGATACCTGAGCACCGAGCTCAGAGGGTTGATTCAGCTCAAAGAGAATCTCGAATTGGAAATCGCGAATATCCAGAGCAACTGCGATTTGGCGGAGGCTCACATCAATGAAAACGTGCCATGGGACGATTCGGAACTCCTCGACACAAAAGAGCTCTTCCTGCGTACGGTGGAATTCATCAGGAACTTCGAGTACGAGGCCGGGGATTACAGTCGGCGAGTGCGTTTCGTGATGGCACACGATCCGAACCAGCTGGTCCTCCATGTAGCAGGTTACGGCGAACTGAATATTAAGCCAGAAACCGGAAGCGGAGGATTGCTCGGTAGCTCGAGCAGTCTAGCACCTCCCGGAGGATCACCGGGCCTCATGAGAAGCAAAAGCGACCATCGTCTGGCCTCGCAGTACCGGCAGCAAGAGGAAGAGCGACTGGCGAGAAATCGATACGTGCCCGAATACGAGTACGACGCGCCAGAGTACGAAGTACCGAGGAACAAATCGAGGTACAGAAGTCGATTCATGCGACATCGGGACGGAGACGATTCCGATGGCGACTCGAGGTCGACCGTTCGGTTCACGTCCACGCCGCAGGAATCCTCGGGACTTCGTGAACGTGTTCTGGACACAGAAGACGCGGCACGTGGGCCACTTTCCGGGATTTTTCGACTCACCGACTCGCCGCGTATCATGAAGAAGCTTCAAGAATACGAGAGAGCCGGGAAAAGGAAGAAGGAGGAACCGGCGATACACCCTGCTCAACAACCTCAACCACCGAAACAACCTCAGGTACAAGTGAGAAAAGTGCCGACAGCGATGGCGAGGCAGACCAGCGAGGACGACGAGATTTCTAGGATTAAAAAGCAGAACAAAACAGCGGCCACACCTGCGACCGAAACGGTGGAAGAACGACAACCGGCGCCAACACCTGCACCTGTACATCCACCTCCGAGGGAGACACCCTCCGAACGAGAACCGGAGGAACCCGCGCGGAGACCGATGCCCGCGAGGAGAACTTCGACGGATACCCACACTCCTGCGACGAGAAGCGCTTCATCAGACTCGAGCACGGGCTCCGAGAGCTCGGGAGGATCAGGAATCCGCAGCACCGGTGCACCATTCACCGCCGAGGAAATGAAGCAGAAGTACTTGTCGAGGGCACCGGCGTCGAACGCAACATCCACGACCTCGTCGCCGCACAGCGGGACGCCACCGACTGCCAAAGACACCACCGCCAACGCCACCCCCGCGTCCCGATCCTTCCAGAGCCGTTTTTTAGGCACAGGTAACCGCGCAGCCCCACCACCGCCCACGCAACCCCCAGCGGCGCGAGAAGAGACCGCCGTAAAGAAGAAGGAGGAAGAGGAGGAGGAGGACGAGGAAACGAGTAGCTCGTCGGAAGAGACGGAATCCGAGACCGAGGAGGAATCGGAAACCGATGCTCATCCAGCGGGCACGACCACGTCCACGACGCCCTCTACCCCGGCTCAGGATCGTCAGAGGAGCGAGTCCGCGATGGCGAGGACAGACATAGGGCCTCTGCTCGCTAGGAGCGCGGAGGCGAGACGCGGCAGCAAGGAAAACTCACCTACGACCAGGTATTCGTCGCCGAGAGGAAGTCCCGCGCATTCGGTGACGAGCCCGACAGCGACGACGACGACGACGACAACGAGCGGCGCCGCGACGTTGACAACGCCGGCCGGCTACACCAGCAGGTTCCTAAACAAGAGCAGGAGCCAGGCGGCGATGATGGCGAGCCGGGAACGGGAACGGGAGCGCGAAAGAGAACGAGAACGCGAACGGGAGCGAGAAAGGGAACGCGAAAGAGAAAGAGAACGGGAGAGAGAACGCGAGCGAGACATGGACACGGAGGTCGATTCGCCCCTGTCGACGAGGTCACGGTATGCCGCGTTGAAGGAAAGAAGACAACGCCTGGCCCGGTCCAGAAGCTCGCACAACTTCGGCGGCGATGACCTCGACCTAGACGAGGAGCCACCCTCTCCGACTACCCAGTCGCCGAACGCTTACTTGGCAGCCAAGTACGGAGCCGGCTCTGAACTGGCCAGAAGTCGGAGTACTCATGCTCTAAAGTCGAGAGAACCGAGTCCAGAACGAGACAGAGTAGGTACCGAGAAGGATGGCGCCGCCTTGAGTTCCTGGGCGCGGTACTTGAAGAACAAGTACGGCAATCGTACCACCAAAGACAAGGAGCCTTCGTCCTCTGCCTCGACGATTCCGTCATCGAGTGGTAGCGCAACCTCGAGGAGGTTATCCCTCGGACTACCTCTCAGGCACGGTGGTCAAACATCCTTCGAATCCTCTGACGACGACCAAAAAAACCCGTCAGGCTCCCCCACGTCCCCTACAGCAGCTCCCGTTATACCCGCGGCAGCAGGTTCCTCCACTAGTAATGGCCGGAGGAGTCACTACTTGCTGAAGCGGCGGCAGCTGTTTAAGTTCGGGATGCGGGGGAGCGAAGCCGGATGCTTTACCTGGCCGAGAGGCCTCGCGGTTGGCCCTGACAATTTCATCGTCGTGGCTGACAGCTCTAACCATCGTGTTCAAGTATTCGACTGTAATGGGAACTTCCTGAAGGAGTTCGGAACGTATGGCAGCGGTGAGGGTGAATTCGATTGCCTCGCCGGGGTGGCCGTGAACAGGATCGGACAGTACATCATCGCGGATCGTTACAACCACAGAATTCAGGTTCTCGATCCTTCCGGTCGTTTTCTGAGAGCCTTCGGCTCCCAAGGGACCGCCGACGGTCGGTTTAATTATCCTTGGGGAATCACCACGGATGCTCTTGGATTTATTTATGTGTGCGATAAAGAGAACCATCGCGTACAGGTGTTTCAATCGGACGGCACGTTCGTGGGCAAATTCGGTAGCTGCGGAAGCGGACGTGGCCAGCTGGAACATCCTCATTACATCGCGGTGAGCAACACGAACCGCGTGATCGTGAGCGACAGCAACAATCATCGTATCCAGATATTCGACGTGAACGGCCGCGTGCTGACCTTCTTCGGATCCGAGGGCTCCGACGAGGGTCAGTTCAAGTTCCCAAGGGGTGTCGCTGTGGACGATCAAGGCTACATCATCGTCGCCGACTCCGGCAACAACAGGATACAGATATTCAGCCCTGAGGGGACGTTCCTCAAGTGCTTTGGCGGATGGGGTAGCGGTGACGGTGAATTCAAGGGCCTAGAGGGTGTCGCTGTCACGTCGGGCGGTAACATCGTCGTCTGCGATCGCGAGAATCACCGTGTTCAAGTGTTCTGATTTCGTTCCGCTTCGTTTCGTTTTATTCTCTCTTATTCTCCTGTGATTCGTCGACCAAACTCAAACGCGTCGAGCGATCTCAGAGGAGGCTCGCATTTCGACGAAAATCGATGCAGTATTTCTCGCGATGCTTTCGATTCTGGTTTTCTTTTTCTGCCTAATTGGGAGGAGAAATAACTTTCGACGGAGAAGGGTTTCCACGAATCGACGATGGGCGAGACGTCGCGTTAATAACCGCTTGCTTGCGTTAGAAATTAACATGTAGCTGTTTTGTGCTGAGCTAATCTTTTCATTCGGAAGCCCTTTCATGAGAAATGTTAAATAACGTAAGATATTCTGGACGATTGGTTGGAAATTTCGTAACATATATTCTACGTATATACATAGGTTTATATATAACATAGTTACCTTCGCTGTTTATGCATCTCACCGAGACGAATCGATAATGGAACTGAAAAGATACCCTTGGACGTCGGTTAATTGCAGATTGCAGCTTAAAAAATGAAAAAAGAGAGCAAAAATATCGTTTATCTGTTCTTCTCTCTCGTCTTACCCCCTTTCTCTCATTCTACCATCTTCCCCGTACGCACGTCATACTCGCGTAACTTAATTTAATTTATACTCGAAGTGACAACAATACAGTTTGTACCGTTTGTATGCTTTAAATAAATTGTTGCGGAAGTAATAAAGGAGAAACGAAAAAGAAAAAAAAAAAAAAGAAAAGAAAAAAGATATGAAAAAAGGACGACACGCGTTTTATTCGCTTCGACGCACCCCCGAACCCGCGTT
->XM_042027756.1 PREDICTED: Corvus kubaryi hydrocephalus-inducing protein-like (LOC121664448), mRNA 
-ATGGTCTTCAACCTCCGTATTCCTGAGGACGGCTCGGGAGAGCTCAGTGTTTGCAGCTTCGATCAAGTGACCCTGTGTTCCAACACCGTGATGGAGTGCTACCAGTATATCCTGGTGGACGTGGAGGGTATTGGCGAGGGAGTGTTGGCACTGACCGTCATGGGCAGATGCATCGTTCCTAAGCTGACAGCGTACCCCTACATCCTGTGCTACGATGAGTGCCATCCGAAGGAGCCGTACGAGAGGAAGTTCCTCGTTGTGAATAACAGCCACATTCCTGGCTGCTACGGGCTTATTGCCCAGGTTTGGCATCACATCCGCCTCCTCCTCGCGGAGGAGATTATTAGCGGGGAAAAAAGGGTTTGGTTTGCTGGTTTCTATTCAATCTTAAAGATCTGCTGAGAACAAGATCCTACCGGAATGTAAAGTTTAGGGTGCAGTTTAACCTCCTGAGG
->XM_036088610.1 PREDICTED: Halichoerus grypus CD300 molecule like family member f (CD300LF), mRNA 
-TTTTTTTTTAGGTTAGGGCTGGAATGGAGGCCCTGCGCCATGCACGGGCACTGCACCATACCCCCTGGTTCCCCAACACCCTGCCTCCACCTTGTGGGAAGTGGCCAAAGGAGGAAGTTCAAGGGTGGGGAAAGCAGAAGGTTGGAAGATGCCGGAGCTAGGTCGGAGTTGACTGGCTCCATCAAGGGGGGCTTGTGTGAAGAGAGAATGAACCTGCTGCTGCTCTTCCTCCTCTTCCAGCGTGCAGGCTCATCTGCCCTCGTAGCAGTGTCCAATGCAGTGAGTGGCCCAGTGCGGGGCTCACTGACCGTGCAGTGTCGCTATGAACCTGGGTGGGAGACCTACAGTAAGTGGTGGTGTCGAGGAGCTGAGTGGAGACGCTGCCGTATCCTCGTTCGAACTGATGGATCAGAGCGGGACAAGAAGGCTGACCGAGTGTCCATCAAGGACAATCACAAATTGCGCACATTCACTGTGACCATGGAGGAGCTCAGGTGGAACAATGCAGACACTTACTGGTGTGGGATTGAGAGAACTGGACCTGACCTTGGGGTTGAAGTTAAAGTGACCATTGACCCAGCACCAGCTACAATATCAACCACCACCACCTCAACCACCATGTCCGCAGCACCAGCAGAGACCAAAGGCCCCCCGACTGTGAGCCACCACTCCAATGGCAGCGCTAACTCCATGAAGCTCAGCATCCTGATTCCCCTCATCTTGGCTGTGTTGCTGCTTCTCCTGGTGACGGCCTCACTCTTGGCCTTGAGAAAGATGAAGCAGCAGAAGAGAGCTGCTGGGATATCCCCAGAGCAGGTGGTCCAGCCCCCAGAGGGGGACCTCTGCTATGCAAACCTGGCTCTGGAGCCAACCAGCACCTCCCACAACTCCTCCCAGAAGAAGGCCTGTACAAAGTCCTCCTCCTCTGCCCTGGATAATCAGCAGGAAGTGGAATATGTCACCATGGCCGCCCTTCCGAAGGAGGACATTTCCTACGTGGCTCTGTCTTGGGAGCCTTTGAATGAGGAGTCAACCTATTACAACATGAACTACCATGTTGCCCACGTTCCCAGCAGGAGCCACGAGGAATCCATGGAATACAGCAGCATTAGGAGATCTTAGCCTGAGCTCCAGGCTCCCCTCTTGAACCCCACATGAGGCCTGTGAGCATGTTCCTGCCCTGTCTGCTTTCTGCCCCCATTCACTTCACGAGGACCAACCAGGGACTGAAGCCTCGGCCTTGTCTCAGGGGGCTTTCGGGAGGTAGATAGGGGTCTCTCTACATCTCTTTTTCTCCCATACAGCTTAAGAGGGGTTGGGGATATGCTCTGGAGTTGCTGAGGGAGTAATAATGATAATGATAATAATAATAATTAACCTTTATTTATTGCTTAACATGTGTGGTGGGCTGAATAATGGCCCCCAAAGTTCTCTGTGTCCCAATCCCCAGAACCTGTGAATATGGCAAAAGGAGCCACGTGGATGTATGAAGTTGAGGGTTTTGAGATGAGGAGAGTATTCTGGATTCTCCATGTGGGCCCTAAATATAATCACAAGGGTCCTTGTAAGAAGGAGGCAAGAAGGTCATAAGAGGAGAAGGCAGCCGATGACAGAGGCAGAGGTTGGAGTGATGTGGCCAGAAAAGGCAAGCAATGGATTGTCCCCTGGAGCCTCTAGAAGGAACCAGCCCTGCCAACACCCTGACTTTAGTCCAGTGAAACAGATTTTGTCCTTCTGGCCTCCAGAATTATAGGAGAATAAATTGATGTTGTGTTAATGAATTCA
->XM_028783841.1 PREDICTED: Grammomys surdaster transmembrane serine protease 13 (Tmprss13), transcript variant X3, mRNA 
-ATGGACAGAGGCAGCCACCGGAATGCTTCTCCAGCAAGGACACCTCCAGCAAGGACATCTCCAGCAAGGACATCTCCAGCAAGGACACCTCCTCAGGCTTCTCCAGCAAGGACACCTCCTCAGGCTTCTCCAGCAAGGACACCTTCTCAGGCTTCTCCAGCAAGGACACCTCCTCAGACACCTCCTCAGGCTTCTCCAGCCCAAGCGTCTCCAGTCCGGGCATCTGCAACCAGGGCACCACCTTCCAGGTCACTGTCAGGCAGGTCTTCATCTGCCAGGTCAGCCTCCACGACATCCTCCCCAACGAGAGTGTACCTTGTTAGAGCAACACCAGTGGCGGCTGTCCCCATCCGGGCATCTCCTGCCAGGTCAGCACCAGCCACCAGGGCCACCAGGGCCACCAGGGAGAGCCCAGGTCTCAGTTTCCCCAAGTTCTCCTGGCAGGAGACCCAGAGACAGCTGCCACTCATCGGGTGTGTCCTCCTTCTCATCAGCCTGGTGATCTCACTCATCCTTCTCTTCTACTTCTGGCGAGGCCACACCGGGATCAAGTACAAAGAGCCATTGGAGAGTTGCCCTAACCACGCGGTTCGCTGTGACGGAGTGGTAGATTGCAAAATGAAGAGTGATGAGCTGGGCTGTGTCAGGTTCGACTGGGACAAATCCCTCCTGAAAGTCTACTCTGGGTCTTCTGGTGAGTGGCTTCCTGTCTGCAGCAGCAGCTGGAACGACACGGACTCCAAGAGGACCTGCCAGCAGCTGGGCTTTGACAGTGCTTACCGAACGACTGAGGTGGCCCACAGGGACGTCACCAGCAGCTTCTTACTCGCTGAATACAACTCCACCATCCAGGAAAGCCTCTACAGGTCGGAATGTCCTTCCCAGCGGTATGTCTCCCTCCAGTGTTCCCACTGTGGTCTGAGAGCTATGACCGGGCGGATCGTGGGAGGGGCTCTGACCTCAGAGAGCAAGTGGCCCTGGCAAGTTAGCCTACACTTCGGCACCACCCACATCTGCGGGGGCACACTCATCGATGCCCAGTGGGTGCTCACCGCTGCCCACTGTTTCTTTGTGACCCGGGAGAAGATTCTGGAGGGGTGGAAGGTATACGCAGGCACCAGCAACTTGCACCAGCTGCCTGAGGCTGCCTCAATCTCCCAGATCATCATTAACAGCAACTACACGGATGAACAGGATGACTATGACATCGCTCTCATAAGGCTGTCCAAGCCCTTGACCCTGTCAGCTCACATCCACCCTGCCTGCCTCCCTATGCATGGTCAGACCTTCAGCCTCAATGAGACCTGCTGGATCACGGGCTTCGGCAAAACCAAAGAAACAGATGAGAAGACATCTCCCTTCCTCCGAGAGGTTCAGGTCAACCTCATTGACTTCAAGAAATGCAATGACTACTCAGTCTATGACAGTTACCTTACCCCAAGGATGATGTGTGCAGGGGATCTTCGAGGAGGGAGGGACTCCTGCCAGGGAGACAGTGGAGGACCTCTCGTCTGTGAGCAGAACAATCGCTGGTACCTGGCAGGTGTCACCAGCTGGGGCACAGGCTGTGGCCAGAAAAACAAGCCTGGTGTGTACACCAAAGTGACAGAAGTACTTCCCTGGATTTATAGAAAGATGGAGAGTGAGGTACGCTTCCGGAAATCTTAACCATGCCCTTCTCACTTTGGTGATTGCTATGAAGATTCTGGCTAAAGGGACAGGCC
->AY335457.1 Uncultured Sphingomonadaceae bacterium clone B101/6 16S ribosomal RNA gene, partial sequence 
-CGTAACGCGTGGGAATCTGCCTTTAGGTTCGGAATAACTCCTCGAAAGGGGTGCTAATACCGGATGATGTCTTCGGACCAAAGATTTATCGCCTTTAGATGGGCCCGCGTTGGATTAGCTTGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCCATAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAAGCCTGATCCAGCAATGCCGCGTGAGTGATGAAGCCTTAGGGTTGTAA
->XR_002992789.1 PREDICTED: Selaginella moellendorffii uncharacterized LOC112347534 (LOC112347534), ncRNA 
-GTGGCTCATAGGACGATGATTTGGAGTTGGATACAAAGTGACAATCAATGTGTTGGTGGTGGAATGGCTGTTGCTGTTCTTGCAGCTCCACTGTGCTCTGTCGTCTCTCGGAGACACTGCTGCCCTTTCTACTGCTCTGAGAGCCAGCACAGACGAACAAGGACTTCATTCTCCCCGCCCAGCCTGTAAAAGCTAAAGTTTGATCACAAAAACCATGCCACGAGTTTAATCAAAGACGAGTACATTGTGTTGGAGTGCTTCGCTCAAAGAAGATCTACTCGCGGTGTAAGCATAGAAGTGAAAGTACTTTGCGGACAAACTTAAACATCCTTTCAATCCATAGCTTTGCTTCTCAGGTGGAAGAAGTATAGAAGCTATTGGAGATCAAAAGTTCTTTACGGACACACTTAAAAAATTCTAACGAGAAGCTCCTCTCTTTGATTTGTGCTCTA
->FJ727014.1 Uncultured bacterium clone A72h_1235 16S ribosomal RNA gene, partial sequence 
-TTTGATGGCGACCGGCGCACGGGTGAGTAACACGTATCCAACCTGCCGATGACTCGGGGATAGCCTTTCGAAAGAAAGATTAATACCCGATGGCATAATAGAACCGCATGGTTTGATTATTAAAGAATTTCGGTTATCGATGGGGATGCGTTCCATTAGGCAGTTGGTGGGGTAACGGCCCACCAAACCTTCGATGGATAGGGGTTCTGAGAGGAAGGTCCCCCACATTGGAACTGAGACACGGTCCAAACTCCTACGGGAGGCAGCATG
->KY281550.1 Uncultured bacterium clone CP_Otu6690 16S ribosomal RNA gene, partial sequence 
-TACGGAGGATGCAAGCGTTATCCGGATTCATTGGGTTTAAAGGGTGCGTAGGCGGAATGGTAAGTCAGGGGTGAAAGTTTGCGGCTCAACCGTAAAATTGCCTTTGATACTGTCATTCTTGAGTACATACGAGGTAGGCGGAATGTGGCGTGTAGCGGTGAAATGCTTAGATATGCCACAGAACACCGATTGCGAAGGCAGCTTACTAGACTGTAACTGACGCTGATGCACGAAAGCGTGGGGATCGAACAGG
->XM_017287255.2 PREDICTED: Drosophila miranda peripheral plasma membrane protein CASK (LOC108156021), transcript variant X3, mRNA 
-GTTAAGTCCGCGGTCACACTGGGTTCGTGTTTTTAGCAAAATTAGTGAGAAATAACAAATTAATTAAAGAATTAAGCGTTTCTATGTGTTGACGTCAACCCAGGCGCGATCTATGAATGCCGCTGCTGTGTAAAGTACTCCGTCGCTGAGGGGCAGGGCACACAAAATTTCGGTGCGAGGCTGCGAACAGGGCCACGAAATGTATCTTTAACATCAGCACCAACCAGCGAGGAAACGAAAAACAACAACAACTACCATAAGAAGAACAACCCACAAAGAGCCAAATTTTTAGTTAGTTTTTTTGTGTTTGCTTTTGGAGGGCAGTAGGCGAACAGGGCCAAAAAACATTGGACACGGAGTAACACGTACATCTAGGACCCAAAACCAAACCCGGAGCAGCCAGGGACAGGGGACAGGGGACAGGGGACCGTCCCACTCATCAATATTCGAAAAAGCAATTGAGACGCGAACCATCAGCAGGCATCAGCATCAATTCATCAATTATTCAAAATGACCGAAGACGAAATTCTCTTTGACGATGTCTACGAGCTGTGCGAGGTCATTGGCAAAGGACCCTTCTCCATTGTGCGACGATGTATACATAGGGAGTCCAGCCAGCAGTTTGCTGTTAAAATCGTTGATGTGGCCAAGTTCACAGCGAGTCCAGGACTGAGCACAGCGGATCTGAAGCGCGAGGCCACAATATGTCATATGCTGAAGCATCCACACATTGTCGAGCTGCTGGAGACCTACAGCTCCGAGGGCATGCTCTACATGGTGTTCGAGTTCATGGAAGGCTCCGACCTGTGCTTCGAGGTTGTGCGTCGCGCCGTTGCCGGTTTTGTCTACAGTGAGGCGGTGGCTTGCCATTACATGCGGCAGATACTGGAGGCGCTACGATATTGCCATGAGAACGATATACTGCACAGGGACGTGCGTCCCGCCTGTGCCCTGCTCGCCACCGTGGACAACTCGGCGCCAGTGAAGCTTGGTGGCTTCGGTTCGGCCATCCAGCTGCCGGGCACGAGGGAAACCATAGAAACACACGGACGCGTGGGCTGTCCGCACTATATGGCGCCGGAGGTTGTCACCAGGCGGCTGTACGGCAAGGGCTGCGATGTCTGGGGCGCTGGTGTAATGCTGCATGTCCTACTATCCGGCAGATTGCCCTTTCTGGGCTCCGGGGTGCGACTGCAGCAGTCGATAGCGCGTGGCAGGCTCTCGTTTGAGGCGCCTGAATGGAAATCAATTTCGGCTAATGCTAAGGATCTAGTCATGAAAATGCTGGCGGCCAATCCACATCACAGACTTTCCATCACCGAGGTGCTCGACCATCCGTGGATACGAGATCGGGACAAGCTACAGCGAACACATCTCGCAGAAACGGTGGAGGAATTGAAGCGCTACAATGCTCGGCGCAAGCTCAAGGGTGCCGTTCAGGCCATTGCCGGCGGCACCACCATGGATCCCGTTTATGTCACCGATGCGGACATGCCCATTGCTGGTGCACCCGACGAATGGGCCGACGAGGAGGCGGGCATCGAAGCGGTCCAGCGTATTCTGGACTGCCTGGACGATATCTATTCGCTGCAGGACGCGCATGTGGACGCGGATGTGATGCGGGATATGCTGCGGGACAGTCGCCTGCATCAGTTGCTGCAGCTCTTTGATCGCATCACCTCGACGGTTGTCACCAGCAACGGCCGGGCGCCGGCCGCAGAGGCGGTCACCCGCAGTCGGGATGTCCTGGAGTCGCTCTCGTCGACGGCCGGCAGTTCGGTGGCCAATAAGTATGCCAAGGATGAACTAATGCTGCTGCTGGCCGCCCCACACATGCAGGCCCTGCTCCATAGCCACGATGTGGTGGCCCGCGATGTGTACGGCGAGGAGGCGCTGCGCGTTACCCCGCCACCGATGGTGCCCTACCTCAATGGCGACGAGATGGACAATGTGGAGGGCGGCGAGCTGCAGCATGTGACCCGAGTGCGGCTGGTGCAGTTCCAAAAGAACACGGACGAGCCGATGGGCATAACGCTGAAGATGACCGAGGATGGGCGCTGCATTGTGGCAAGGATTATGCACGGGGGTATGATACATCGACAGGCAACGCTGCATGTGGGCGACGAGATACGGGAGATCAATGGCCAGCCGGTGCAGCATCAGTCGGTGGGCCAATTGCAACGAATGCTGCGCGAGGCACGCGGTTCTGTTACCTTCAAGATAGTTCCTTCGTACCGTAGCGCTCCGCCACCCTGCGAGCTTTTCAGGATCAGACCCGCTCCGGTGCTTATTTTCGTGCGCGCACAATTTGATTATAATCCGCTGGATGATGAGCTTATACCCTGCGCCCAGGCGGGCATATCATTCCAAGTGGGCGACATACTTCAGATCATTAGCAAGGACGATCATCACTGGTGGCAGGCGAGACTGGACACGGTTGGCGGCTCGGCGGGCTTGATACCATCGCCGGAGCTGCAGGAGTGGCGCATTGCCTGCCAGACGGTCGACAAGACCAAGCAGGAGCAGGGAGAACCGGGTGCTGGATGTTCCGCTCACGCAGATGGGTGTGATGGATCAGCAGTAAACTGTTCGATATTCGGGCGCAAGAAGAAGCAGTGTCGCGACAAGTACTTGGCCAAGCATAATGCCATATTCGATAATCTAGATGTGGTCACATACGAGGAGGTTGTCAAGGTGCCAGTTGGTGATCCGAACTTTCAGCGCAAAACGTTGGTGCTACTGGGAGCCCATGGCGTGGGCAGGCGGCATATTAAGAACACCTTGATATCCAAGTATCCCGATAAGTACGCCTATCCCATACCACATACAACGAGACCTGCCAAGCCCGAGGAGGAGAGTGGACGCAGCTATTACTTTGTCTCGCACGACGAAATGATGGCGGATATCGCCGCCAATGAGTACTTGGAATATGGTACGCACGAGGATGCGATGTATGGCACCAAGCTGGACACTATCCGACGCATACACACAGACGGCAAGATGGCCATATTGGATGTGGAGCCGCAGGCACTGAAGATACTACGCACAGCCGAATTCACGCCCTATGTGGTCTTCATAGCGGCCCCCTCGCTGCAGAATATCGCCGATTACGATGGCAGCCTGGAGCGTCTGGCAAAGGAATCGGAAATGCTGCGTCAAATGTATGGCCATTTCTTTGATATGACGATTGTGAACAACGACATTAGCGATACGATTTCCGCGCTGGAAACGGCCATCGACCGGGTGCACACCACTCCCCAATGGGTGCCAGTCTCGTGGCTCTACTGACAAGACAGTGAACTGGAATGCCCCGATTGCCTCGAGGGTTGCGATTGCGAGTGGGATGCATATACACAGGCCTCCAATGTGGCGCTCTACTGAGTGCAATACCACAGTTACATCACACCTACTATACACCACAAACACCATTTAAGTATTACCAAGGCACAAAAATATACAACACAGCAACAGCAATAGTAGCAAAAGCAAAAGCAAAAGCAACCGAAACAGAAACAGAAAGACATGAAGACAGAATGCGCTTGGCGCCGAGATATATGTAGGTATGAGGATACAGGAGAGGGTATTGTGGGTAACTGCGGTCGCAACGTAAACACAAAATGTTAATTGTAAAACGAGCTGTATTTTGCCTTATACTTTGTTAAATCCTAAGTGATTAATTTTACATTGTATTTGCCATTCCAATGGGCTGCCCTCAAACAGGCAGCCTGTGTCATTATGTTTATTGTATTTATGATTGTTTGTTCTGTTAAAGTTTTTGTTTGTACCCGTTCTCGTACTCGTACTAGTATTTATTTTGTTTCTTTCTGTCAGACAGCATTAAACGCTTATGTTAATCTTGCACTTGTTAGTGTCTAAGTTAACTAAAACACAAACCGAAATCGAAACAGAAACAGAAACCGCAACTAAAAAACACTCTAAATTGTTTTAATCAAAGATTATTTCCATAAACACATACGAAAAAAAAAAAAATAAAAAACACACCCAAAAAAATGAAGAAATAGAAATCCGAAGAATGTTTGAAGAAAACGAGTTAGTAAATTATAGCAACAAAAAACTACGTAATTAGTTATAATTAAACATAACAGCAAACCAGAATAAAAACCAACAAGAAGAGAAGTTCAGGAAAACGTTAAAAACAATATGAGATGAGAGCAATTTCAAGTGTTTCAAGCCCAAAAAAAAGTATAAAAAAGCAAATTAATTACATATGGAAGAGCAAATGGGGACAAGCGATCGTAAAGTGTACGTTTTAAATGCAATAAACATTAACAAAAGGACCCGTATAACATCACTTACACACGAAACAAACAAACAAAAAAATACACTAAAATATTACCAAGAAAGAAAACAAAAAAAAACCAAATTGTTGACGTTTAAATAAATTCAATGGGAAATGATTAATAATGCAATCATAAACGAGTTAATAATAATAAGAAGCAGGCGCGTTTAAATCAAGCAAAAGCAATTAAAGGACAAAACATTAAACCAACAAAAAAAACATAGAGTGAGCACAAAAACAACAAAAAGAAAACACATACTAACAGCAATTACAGCAAAGAAGTAAATCAAATAAGAATTAAACTATTTAGAGGCCAATGAGAACTGGTGGAAGAGTGCGCAAGGGGCACAACAGGACACGTATAAATATAGAAAGACACGCAGGAAAAAGAGAATGAATGAATGAAAGAAATGATTAGTACAGAAAATATGTGGTGTATGCAGAACATACAGACATATATAGGTATATTTTTCGAACAACTCAAAACTCAGGTTGGATACATTGAAAATCAGTCAAGTTCAATAAGATAAATATAGCGGAGCGCTTCCTTTTAACCCACAGCCAAAAAAAAAGCAAAACGAAAACCTTAACAAAACCCAATCGAAGTTTACAATGGATTAAACAGAATCGAATCGAAATGAATTGCAGTTTACCCACAAGCCACAAGTTACCACCCTAGCAGCAGCAGCTTCTGCAGAAATCTTTTCTAAATGCTTTACAAGTACAAAACATGTCTTTAGCAATCAGATTTTTAGCCCCAAAAAACCCCAGGCTCGCGCTCATTAGCTTTCTCCTCTTGCTCTCACCGAAGCTTATCCTGCTCCCGTTTGATTGGCAAAATCTTATCCAGGCTTGGGCTTGATTGCGCTTCTCCAGAGCAGGACCTAAGCTGAATCTAGACCTAACACTAAGGAGTGCACATGCAATCACAACAAAGAAACAAAAACTGGTTAGAATTGGAAAATGTGGTTGAACAAGCAAAAACCACTTACGATTAATATTAGACTAAAAAAAAACATTTGACATTTGACTTTGTAATTCCTACCACCTACAACCCTCCAGCCCCACAAGCACCTCACTCCTCACTCCATTTAAGCCAGAGCTTAGTTCAAGCCTAACCACAGAACCCACATCGATTTCCACACACACACACACAAATGAACTACCAGAACAATTCTATGGTTTCAAAACGGTTGAACAATTTTTGCATAGAGAATTATTGTTGAACGCTGGGCTATGACTTTTTGGTTCGGAGCGTATGACAGAACAGACAGGCAGCAGGCAATGCAAATCATAGAAGTATCCCAATGAAAAACCTACCCGAAACTGAAGAACTAAACTACCTACCCACAACCAGATACAAAATAAAAGAAAAAACCGCAAAAAAAACAAGCAGCCGAGTGGCCAAATTAACTAAGTATTTTACCCTAAAAAAAAGAAAAAGTCAAAGAACAACCGGAAGTGGAAGTGTATGTATATGTTGCAGCTATCCCCCTCCCCCCCAACCTAGGCAGGGTGTGCCAGATAAAAAAAAGTCTAAGGAAAATTGCTCAAATCAAAAATCAAGTATTTTATGGTATAAAAACCGTGAGGAATGATCAGGATTAGAATGAAGGGGAAGTCGCGTGTAAGAGTTGGACATTCCAAGAATGAGCTAGAATTTCGAAGGGATTCGTTTCTTATTTTTAACTGATCCTTTTTTCTTAGCTGATGCGAGCAAATTGTAGCTGTACACTAAGAATAATTTCACACTAAGATTAAGCGAAAATTTATTGTTGATATTACATAAAAAAAAGAAAAGAAATGGAAAACGGATATTGGAAAAAAACCAGAAGACTCATTGAAGCAAGCCAAATGGATTAGAATTTTTCTCTAATTTGATAAGTGGTAGACGATGATGAAGGAGCTAAGGATAATGAAGATGGTGACGAGTTGATAATGCTTATGATCTCCAAAAGTCAATATGTGTAGGATTGACACGATTTGAGCAAATTGAGTGAATTGTTATTAAAATAATAAATGAAATGAGTGGCTCAATGGATCGATATCGATCCATTGATGCTGAAATAGGTCAAGACGTTAGAAAATATCATTTAAAGTAAATGATACAAATGTCATAATATATACATAGTTTAAAATGAAAATAATAATAACAAAATCAGAAGAAAAATGGGAAAAAATGGGAATAATGCGAATTAAAAACAGAAACAGAAAAAAAGAAAAACAAAAACAACCAGTAAACACTGAAATACCGAATTTTAAATACATAAGTTTTGAATCATGCATGCCGCAAAGACAAAGAAAACCCAACACAGAAAAAGAAATTAATAAAAAGAA
->XM_006681305.1 Batrachochytrium dendrobatidis JAM81 uncharacterized protein (BATDEDRAFT_27075), partial mRNA 
-ATGCAAGTTTGCAACACTCGCTTGACTCGTTTGGCTCGGATTCTGGTTGATATTTACGATATCGATGCAAAGTTACATTCCAGAATGAACGTGCATAATCTGATGTGGTCAATCGTTTGGTTTCATTGTTATCGGTCATTGACACCAGTGATTGCATTGATTGCAAATAGTAGTCCAAGACTGACAAGTGTGTCTGAATTGATGACAGATGATACAGTCTATCCAACAAAAAGTAATACATTGATCGTGTCTGTGTGGCCAAGTGTAGATAGGTCAATAGGAGTAAAAGTATTTCCCACTGGGGTTGTAAAAGAGCCGCCAACAGATGCAAGTACCAAAAAAAGTGCCTTGAGTTGGGGCAACAACAGACTTGACTCTTACGACACTGACCAACTCTCACTCTCGTTGACTGATGGTGGAAAAGCTTTGCAACCATACGGCCCAGTTCCAGCATCAGTTAAAGAGAGTAAGATTTGGTCAGTGTCGTAA
->XR_006867874.1 PREDICTED: Ischnura elegans uncharacterized LOC124171616 (LOC124171616), ncRNA 
-TCCCTAAATCCGCCAATGGTTATTAATCTCCTTTATATTGCCTCAAAATAACTACGAAGTTGAGTCGTTGCAACCCGCCATTTTAATTGCATCATAGGTAAATGGCCGGTTATGTAGTAGCATAGGCGGAACATCAAACGGGTGCCGGTTTTTCCTTTTTGTAATTGATTAATTTGGGATATGTGCGGTTTTTCTGCAACTAACTGTTCTAATAACTGCAGGAATGAGTTCCGTGTTTTTTCCGTAACCTTAAGAAAAAGGCGACATGACTACAAATGTGCCGGAGGAATCATTGGCAACGAACACCATATTCCACAATTTGTGAGATTCATGCCTGTTGCATCATGCTTTGCTGAATTGATGGCCAAATAATGGAACGACTCCTATGACGTCAAGAGACAATTTTTTCATTGCATGTCCAAATAACCTAAGCAGCAGAAGCATCCAGTAATCTTGTACTGCTCTGGTATTTTGGTGTCACCATCTATTTTGCTTGAGGAGAGAATTTATCTGGAGCAGTGTAATTCGGATTATCTACTGATGAGCTTCTCATGAGTGTTTGACGTTCTACACAGCTAGTTATGAGAAAGTCACACCTGTTAGTGTCTACTGTGATTGTTATTTTTATAGAAGAGTAATTTTTTACTTGATTACCTCTGAAATTTCCCATTATTAAATGTAGTAATTCAAAGTTATGGTTACAATGTTGTGTCCTTTCCATCAAATTTTAT
->XM_008649455.4 PREDICTED: Zea mays evolutionarily conserved C-terminal region 5 (LOC100502368), transcript variant X2, mRNA 
-AGAAATCCCATCGTACGCGACTTCGTATTGGTAAAAGCCTTTGAGTTTGATACCCATGACATCTCTAATCGCTCTCATCAAATCACGATTCACATAAAAAAGGTGTGGGAGCCCGATCCGATCGCCAGATCCGCCGGCCTGTGCGCCGACTCGGGCGTCCTTCCACAGATCCTCTTCCTTCTATCGTAGGCTCGCCCTCGCCGCTCGCTGGAGCGGAGGTCTCTCCCTGCAGCCCATACTCCTTGATTCATTCTATTGCCTCGCCGCCGGCTCTATGGATAAGCAGGAGCCAGTAGCCAATGGTGAACAAACGATAGGTCTTGCTGAGAAGCCGAAGGAGCTGCCTGTTGCCAGTAAGGATGAGAAAGCAACTGTGCCCCCGATTTTAGTTGATTCAAATGCTTTCAATCTACCAAGTGAAGGCCAAACCCAAGCTGGCACATCTAACATGGATGGGGGCCATAATGGTGCACACAACTTTTATGCTTCTCAGGCACAACCATTCTATTACCAAGGCTCCGGTTCTGAAAACCCTACACAAGCATGGGATACATATCCTCCCTACATGAGTGTTGAAGGATTGGAAGTGGGTCCACCAGTTGTATACAATGAGGACCCCTCATTGATGTTCCATGGTGGCTATGGTTACGACCCATATTATTCTCCTATTGCAACACCTGTACCAAATGCTGTTAGTGGAGGTGGTCAGCTCTACTCCCCTCAGCAGTTCTTCTCGGCTCCTTACTACCAGCAGTCAGTACCACCTGACATGCAATATTTAAGCTCTCCTACTCCAATATCACAGGGTGATACAATAATGCCGATTGACCCAACACAAGGAGCTTTTATCGCTGATACCCTGAGTCCAAACAGCTTCCTGTTTGGCCCAAGACCTGAATGGTTCAGATCTTCAGAAGGAACTGGGTCATTTCCATCACCTGCAGCTTCACCTCAACCTTCTAGGGGTGTTCCAGGGTCCTATGACCAAAACAACTTTCCAATGGCTTCAAGAATGTCATCACCTCACCAGAAGCCCTTCTATGGTTTGAGATCCACAACTGACTCCTATGGAAGGGGTTTTTCTCATGGTGGAATGTTCCCACAGGCCAGTAATTATGGGGGATCCGTCACCAGCTTTGGCCTTAATGGTAGAAGTTTGATCTCAACCGAGAAAGGGCGCAGGAGGGGAAGGGGCAATGCACTTATTTGCAGCTGCAATGGTCCTCTTGACTTTCTTAATGAGCAAAGTCGGGGTCCACGTGCAACTAAGCCTAAGAAGCAACCAGAGGTTGACAGTAAGGATGAGGTGCCTACTACAGGAGTTGGTCGTGAGTTATACAACAAGCCTGACTTTGTTATGGAGTACACGAATGCGAGGTTTTTCATCATAAAATCGTACAGCGAAGATAATGTGCACAAGAGTGTCAAATATGGTGTTTGGGCTAGCACCACAAATGGAAACAAGAAACTGGACTCAGCCTATCGCGAAGCTAAGGAGAAAGGAGAGCACTGTCCCATTTTCCTGTTATTTTCGGTGAATGCCAGTGCACAATTCTGTGGTGTTGCTGAGATGATTGGACCAGTGGACTTTGAGAAAAGTGTGGATTACTGGCAGCAAGATAAGTGGACTGGTCAATTCCCTGTGAAGTGGCACATAGTGAAGGATGTTCCCAATAATCTTTTCCGACATATAATTCTTGAAAACAACGACAATAAACCTGTAACAAACAGCAGAGATACACAGGAGGTGAAACTAGAGCAAGGAATGGAGATGCTGAAGATCTTTAAGAACCATGATGATGATGCATCAATCCTTGACGACTTTGAGTTTTACGAGGAGCGTGAGAAAGCGCTGCAGGAAAATAAGGCACGCCTGCATCAGCAACATCTACCCAGTTCTATTGTTATTGAGCCCAAGAAACCCTTGACTGCACCCAGTGACCTCGTGGGCCATATCACCAAGAGTTTTGCTGAGGCTGTGCGGCTTGGTGAGGCCAAGACTGTAAGCCATTTGACTGAGAAGGTTTCTGGGGGTGATCCGTCTATTCCTGTGAAGCATGTTGAAGTTAAGCAGAGTGGTTTATCTTAGGAACTCTTGATCGATGTGAATGAACTGTACCAAAAATTCACCCATACGCTTCCTGATCAAAATGTCGGGAATGCATATGCAGATGGATGATGATGAAACCCAAGACATCGGCAAAAGCATGCATGCACACTAGGGTAGGTCTTTGCCAACCTTGGAAGCATAGTTTCTTGAATAGTTTCTCTCTTTTTTTCTTCTTTCTTCCTAGTATTTTCTCCCCTTCTCTTCGCATCATATGATGATTCCTTAGTGTCTAGCCTCAAGGAGAGTTGCTGTTTTTGTGTAAGCCTCTGTAAGTTTCCTGTTCCATCACATATGAGTAAGGCCTTTTTGTTTCTTTTTATTTAAGTAAAAGATCCATCTTTTATGTACTGTCGTGGCAGTTTTATTATACTATGTCTGAACAAGGCCTATTCACTATGTAAGCAAAACATAAACGCTATCCAGGTGACCTGGTTGTGATGACTACAGTAATAAGTAACTGAATAATTTTTTATGTT
->XM_312219.5 Anopheles gambiae str. PEST AGAP002709-RA (AgaP_AGAP002709), partial mRNA 
-ATGGATTATAATTATGATACCGACGAAGCGTGGTACGCGGCCAGCCTGGGCGCCGGGCCCTGTACCGACGTGTCAACGCTGAGCGTGGCGCCGCTCTGCTCTAGTCTGAATCGGTACGGCACGCTGCCGAGCACGGTGCCGATGCCGACGCTGTACGCTTCCGAGGGCCAGCGCAAGCCGAAGCTTTCCATCATCGAGCTCGTGCTGTACAACATGGCCTCGATGCTGGCCAGCATTGCTTCCGGGTACGATGTGCGTGTGTCGAACGTAACGCCGCTCCATCCGCGGCTACACCCGGGACCGTTGCAATCGTACGAATCGTACTCCCAGCCCGTGAGTCCGTACCACCACCATCGGCACCAGCTGCCGCCAATGGTAGACCCACATGCGCTGCAGCTCGAAGGTATGGTACGGTTGGACGGGATGCCGCCATCTTTAACAACCGCGCCACACACGGTGGACAACGCTCTGAGCCAGGAGGCGTACGAGGAGGAGCTGGCTCACCAAGCTCAGGATGATAGACTTTACGCACAACACAGCACACCGTACCAGGAGACGCCGGAGAGACAGCGGCCGAGGAAGGTGCATACTCAATCGACCAGCCCAAGACAAGACGAGCGGGCGCTGAAGTACACGGACTCACCGCAACACTATCTACCATCGACGATGTCGACGACGAGCGGGCTCGGCTCGAACTACACGCCCTCGGGACCCAGCTCGTCCTTCAGCGTGGGAGCGGGAACGCAACCGCCAACGCCTTCGCCCCGCCGAAAGTCTAGCGCCGCGTCGTTCATGGATTTTGGCGATCTGCCGGAAGAGCGCGAAAGTAGAGCGGGCCTCTACATACCGGGCGAGTACGACGGGTACACGCAGCACAATCCAATCTTTAACGCGGGTACGCGCGGTGCCACTAGTAGCTACATCGGATCCCATTATTTCCCCTACCGGCCGGCGATAAACTTTGCGTTCGAGCGGGAAACGAAATCGTACGGCGGGGAACCGGTGTACGAAGACCATCACTACGACAGTGCCTCGTACCATGATTACGCGTACGAAGGTCCCGCCGGGGGACCGTCGGGAACGGCCAGCGCTAGAGCAACGGGTACGCGCGTCCCAACGATGGGCATCAGTGCGGCGGGCCATCGCCGGACGCACTCCAGCATTTCCAGCACGCTGCACAGTAGCAACGTTAACCAAGGGTTTCACATGGAGGGCGAAGAGATGGACGGTGCCGGAACACGCCTGATTGATGACGTGACGTACAAGCTGGGCGATCTCTACCTGCCCGGGGGCGGTACGGATGCGGCTAGCCGCTTACCGGCACCGAGCACCGCGAAGCTGCACGAATCTCCCCTGCCTGCTGCCTTTCATGCGTCGAGCCGAATGCATCAGTACGAGAACGTGCCCAACTTCTTCCGGCGGCAATCGAGCCTGCAGCAGGCGCACTACTCCCCCAGCAGTGCGCACAGTGGACATCTGTCCGGCGATTTTATGTCCGGTGGTGCAATCCCGGAGCCGGAGGAGCGTCCGTACACGGTGCTGGGGCTGACGGAGCACGGTGCCGACGGTGGATTGCTGTCCAGCAGCTTAAGACCCCAAACGAAGCTGCGCTCCAGCATGAAGAAGTACACGCACTCACATCCGACGCATCAGCAGGCCACCGCGTCAGCTGGCGGGCAGGGTAAGTACGGGGCGGGCTACGGTATGCACGGGACGACCAGCGCCACGAACCAAACACCGCCCGACAGTCTCACCAGCGACGACAGCTCGTACCTGAGCGCGAAGGACAACTCGTCCTCGATTTCCTCGCAAAGCCGGGTGCGCTTTACGCCGGAAATTGTGCTCGACGTGGACTCGCCGCTCCAGTCGCCGACGTGCTACACGGGCGGAGCTGCTGCGGCGGCTGCCCCGTCCGGCCATGGCTTAAAGGACAGACGCAGCTCCTCCTCCGGCAGCACGATGCTAACGGCAACGCCCGGTTCGGGCACGTCCTCGACGTCGATTTCGGGCCGGCGGTCGAATGCCTGCGACACGAGCCAATCCTAG
->XM_025275219.3 PREDICTED: Bubalus bubalis NPR3 like, GATOR1 complex subunit (NPRL3), transcript variant X9, mRNA 
-TTGCCTCATACAGTCGCGAAGTCTCGCGAGCCTCTTGCGAGTGTGGGGTGTGGGACGGGCCCGTGGGCTCGGTGGGTCTGGCTCCGCTCGGCCCCCCCGCCTCCAGCCGGTCCTCCTCAGGGCGGTGGGTCCCGGGTCCTCAGCTCTCCCCCGGGCAGCTCCTCCTCAGAGCCCCACCCGCCCCTCGCCCCCGACCCGTCCTCCTCAGGGCGCTGGGTCCCGGGTCCCGGCCCCTCCCCGGCCCGACGTCCTCGGGGCCCCCACCCAGGCCCCGGGCCGACCCCTCCCCGGGCTCCCGGCAGGATGGGGGACAACACCAGCCCCATCAGCGTGATTCTGGTGAGCTCGGGGAGCCGGGGCAATAAGCTGCTGTTCAGGTACCCTTTCCAGAGGAGCCAGGAGCATTCGGCGTCCCAGACGAGTAAGCCTCGTAGCAGATACGCTGTCAACAGTGCCGGAGAGCATGCTGAAGACCAGGATGGGGACCCCAGGTTTTCAGATGTCATTCTGGCAACAATTTTGGCAACCAAGTCTGAAATGTGTGGCCAGAAGTTTGAACTGAAGATCGACAACGTGCGGTTTGTTGGGCACCCGACGCTGCTGCAGCACACGCTGGGCCAGGTCTCCAAAACTGACCCGTCCCCGAAGAGGGAGGCTCCCACCATGATTCTTTTCAATGTGGTGTTTGCACTGAGGGCCCACGCGGACCCGTCGGTGATCAGCTGTCTGCACACCCTCTCCCGCCGCATCGCCACCGTGCTGCAGCATGAGGAGCGCCGCTGCCAGTACCTCACGCGGGAGGCCAAGCTGATCCTGGCGCTGCAGGACGAGGTGTCCGCCACGGCTGACGCAAATGATGGGCCTCAGTCCCCATTCCACCACATCCTGCCCAAGTGCAAGCTGGCCAGGGACCTCAAGGACGCTTATGACAGCTTGTGCACGTCTGGGGTGGTGCGGCTCCACGTCAACAGCTGGCTGGAGGTGAGCTTCTGCCTGCCCCACAAGATCCATTACGCGGCCAGCAGCCTCATCCCGCCAGAGGCCATCGAGCGCAGCCTGAAGGCTATCCGCCCGTACCATGCCCTGCTGCTGCTCAGCGATGAGAAGTCCCTGCTGGGTGAGCTCCCGCTTGACTGCTCCCCAGCCCTGGTACGCGTGATCAAGACCACGTCCGCTGTGAAGAACCTGCAGCAGCTGGCCCAGGACGCAGACCTGGCTTTGCTGCAGGTTTTCCAGCTTGCGGCCCACCTGGTGTACTGGGGCAAGGCCATCATCATCTACCCGCTGTGTGAAAACAACGTCTACATGCTGTCTCCCAACGCCAGCGTGTGTCTGTATTCCCCGCTTGCCGAGCAGTTCTCACGCCAGTTTCCATCTCACGACCTGCCGTCTGTCCTTGCCAAGTTCTCCTTGCCTGTCTCCTTGTCAGAATTCAGGAACCCCCTGGCCCCCCCTGTTCAGGAGACGCAGCTCATCCAGATGGTGGTGTGGATGCTGCAGCGCCGGCTCCTGGTGCAGCTGCACACCTACGTCTGCCTGATGGCCTCGCCCAGCGAGGACGAGCCCCGCACCCGCGAGGACGACGCGCCCCTGGCCACCAGGGTGGGCGGCCGCAGCCTCAGCACGCCCAATGCCCTCAGCTTTGGCTCCCCAAGTAGGACTTCCTGCCCCTGGGCATCTGTCTGGAGGGGGCCAGCAGCGATGACATGACCCTCACCAGCCCCAGCATGGACAACTCCAGCGCTGAGCTGCTCC
->XM_017686507.2 PREDICTED: Pygocentrus nattereri complement C1q-like protein 3 (LOC108413828), transcript variant X2, mRNA 
-AGCAGGCAGAGAGAAAGCAGCTGACCTCCTCAGTGGTCTCCTGTGACAGCAGACGTTGAAGATGTTTGGGCTGGAGGTGTTTCTCCTGATCTTCCTGTGGAGCACACAGGCTCAGGACGTGCTGACCCCCAGTGTGGACATTATCAGGGAACTGGACAAGCTCAGAGCTCTGGAGCGAAGAATGAAGGCCATGGAGGCTGAAATGGCTGAGCTGAAGATGATGAACGAAGGACTTTCCAGGAGCCTGGGGATCATTACGAAGACCATCACAGATCAGCCCAAAGTGGCGTTCTCCGCTACGCTGTCCAACCTGCAAGATGGTTTTAAGTTCCTGGGCCCGTTCCAGAACACGGTCACCCTGGTGTACGAGAATGCCTTCACAAACATTGGCTATGCCTACGATCCACAAACAGGAATCTTCACGGCTCCCCTGGGGGGAGTGTATTATTTCAGCTTTTCACTCTTCCACCCGGTCGGACCTGGTCCTCAGGCCAAGACCGGGGCGTCCTTGGTGAAAAACGGGGTGCTGGTGGTGGCTGCCACAGATAACGCCCCGGGGGCGGATTCTGAGGACACTTCTGGAAACTCCGCCTCCATCCGGCTGGAGGAAGGAGATCAGGTGTACGTGCAGCTTTGGGAGAAGCACAGGGTCTACACAGACGGAAACAAGCGCAACACCTTCAGTGGGCATCTGCTCTTCCCAGTGTGAATCTCACCTCACTTGGCTGTGGACGCCTTCAGCTGATGCTCTAATGCTGGGCGCCTAAAGTTGTAGCGTTGTAGTTCAGGTTAATTCAAATGTACTATTAGTAGAGCTTCTATGAAATAAAACAGTATGACTTCAGTTTACTTCTTATGTACTACACCGCTTCCAAAAAAGCTGTGACGTTCTGCAGAATGTAAATAAAAACAGGATGGTCTGCAAA
->XM_029369271.1 Trypanosoma conorhini pre-rRNA-processing protein TSR3 (Tco025E_02343), partial mRNA 
-ATGGGAAAGCCAAAAGGCCACCCCAACAGAGAGGTGGGGCAGCGCAGCAGGAAAAGTGCGCCCCGAGGTGGACCTCGCGGCCATGCGCCGTGCAACAACCCTTGTAGTGTGCCGCTGGCGATGTGGGACTTTGAGCAGTGCGACCCCGACGCCTGCTCGGGTCGGCGCTTGTATCGGCACAATGCATTGCGCCTTTTAAAGCTGCGGGAACCCTTTCATGGGGTCGTTCTCACACCAACAGCCACAGAGGTTGTGAGCCCTGCCGATGCGGACCTCGTTGCCCGCTCCGGTGCCGCAGTGGTGGACTGTTCGTGGAAGCAACTGCATGCGGTGCCGTGGCGGCAGATGAAGATGGGTGCCCCACGTCTGTTGCCGCTTTTAATGGCCGCAAATCCCGTCAACTACGGTCGGCCGTCAAAGCTGAACTGTGCCGAGGCACTGGCAGGGGCTCTCGCCGTTGTTGGCCGCATGGAGGACGCGAGGTCCGTCTTGTCGTACTTTTCCTGGGGAGAAAGTTTTTTTGACGTTAATGCGGAGCTCTTGGAGGGCTACAGCGGGTGCGCCAACGCGGCAGACGTGGTGGCTTTTCAGGAGCAGTACGTGGCAACTGAGGTGAGCAAAAGTGCGGCACGGCGGGAGATTGACTTGAATAGTATGGATCTGATGGATGCGGGTCCGCTAAACCTTAAACGAGGCAAACTAAGGAGTCGGCATACATGGCAGAAAGACGATGACAACGAGGAAGAGGAAGAGGAAGAGGAAGAAGGGGAGGAGGAAGAGGAAGAGGAAGAAGAGGAAGAAATAAAAAAGGATGCTGAAAAAAAGGAGGTTCAGTTAGGGAAATTGGAGACGTCAGGTGATGGGGGGAGTCTGCGTTCTTAG
->XM_037232021.1 PREDICTED: Pollicipes pollicipes tyrosine-protein phosphatase 99A-like (LOC119108450), mRNA 
-GGCGGGCGCGTGGTGTGTATGCGCGCCGGGCCCAGCGACTGCGGCAGGGGCACGTACACCAGAACCACCCTGCGCGGTTGGTAGATGAGCCGGCTCCAGGAGGTAGACGTGCGGCCGGTCGGGTAGACACGTTTTGAGCGTGTCTGCGGTGTTTAATCACTACTGTGAGTGACGAAGACTTTCTGTGTGACAGTCGTGCCATCTGGTGTCACACCAGTCAGAACCATGTTGAGAAGACGGGCTTTGGCAGTGACAGTCGTGCTCCTCGTTCAAGGCTGCTGCGGGGCGTTCGACACGCTCTTCTCGAGATCTAAAGCGAGCGTCATCCTGCCCTGCGACGGCATGACCGACCTTGACCCAGCCCAGGTCACCGAACTTGCCTGGCTCTGCTACGGCTGCATGGAGAGCATGATCGTGTCGGTGGACGCGGCGATCGAGACGAGGCTGCTGGAGTTCGTGGACGGCACGGCCACCGTGTTCCACAACCACGGCCGCATCAGCCTCCTGCCCGACACGCTCTCGCTCAAGTACGACCCGGTCGAAGTGAAGGACAGCGGCGAGTACCACTGCCAGGTCAACGGCCGCGAGCCCATCTCCGGCCTAATCAAGCTCGTCGTGCAGGATGTTCCTTCGGCACCCGGAAGGCCTCTCATCACCAACTTCACGTCTCGGTCAGTGTTTTTATCCTGGACTCCGGGCAGCAAGCAGAACAACAGCCCCATCAGACACTACATCATCCACGTCAAAACTGGCGAACATGGCGAGTGGAGCCAGCAGCCCATCTCCACGCCAGATAACCAGACATCGTTCGTGGTGGCAGACCTGCAGCCGTTCACCGCCTACAGCTTCAGGGTGACAGCCGTCAACGGCATCGGCGCCTCGCCAGACGGCATCGCCTCCTACCCCATCATCACGCTGAGAGAAGCCCCAGCCGGGAAGCCGGCGATCCTGGCGGCGCATAATACAAGCTCCACTTCGGTCCGGGTCCGCTGGAGGCCGCTGTCCAAGGAGGAGCTGCGTGGAGAGTTTCAGTTCTACAGGATCACTTACCGGGAGCGGAGCAACGTCAGCAGCCGGATTCGAGAGCTTCGGATCAAGGATGAACGTGTTCAGAGCCACACCATCTCCGGGCTCCGTCCGTACACGCAGTACATCATCTCGATACAAGTGGAGAACCCGGCTGGCCTGGGTCCCAGCTCCACGGTCGTGGTCACCACGGACGAAGGAGTTCCCGAAGCGCCACGGCAAGTGTCTGTCGTGAACGTGACAGATACCACGGTCACCATCTCGTGGCTGGCTCCGAATCGCCCCAACGGCCTGATCGAGGGTTACCGTATCTACTTCACTACCGGCAACTTCACCAATGCCACTTGGCTCAAGCTGCCCGTGGATGACATGCAGTACACGCTGAAGAATCTAGAGCCCTTCTCCAACTACTCGATCGCGGTGAAGGCGTTCACGCGGAGCGTGGAGGGCCGCGAGTCGGCGGCGCTGGCCGTCACCACCGACGTGTCGGCGCCGGCCGCACCGCGGCTGACCTCGCTGGCATGTCAGCCGGACGCGGCCCTGCTGCTCGCCTGGCGACCGCCGGGCCGCGTCCGGGGCCGCATCGACTTCTACGTGGTCGGCTACCGGACCGGCCAGGCGACGGCGCTCACGGAGCTGCAGGTCACCGCCGACTCGGCAGAGCAGGAAAGCATGCTGCGCTTTCCTGCTGGCGCTGCTGGCCCTGGCCATCTGGAGGTGAGGTCACTGCTGGCCCTGGCCATCTGGAGGCGGTACTTCCAGTCGTCCTACTACTACAGCCTGGATGAGCCGGTGACGGCACGCGCGCCCGTGACCTCTGACCCGGGCTGGGAGCTGGACGGTCCGAACGGTTCGGCCGGCCCGATCCCTGCCGATGCCTTCCCGGTGCACGTGGCCAGCCTACACGCCGATTCGGACATCGGATTCTGCAAAGAGTATGATGAGGTGCTGGCGCACACAATGAAGTTGGAACTCTCTTCGAACGTGTCACAGACCGAGGAAAACAAGCAGAAAAATAGATACCAGAACATTGATGCCTACGACCACACCCTGGTGCCCCTGAGGCCCCTTCCGGGCCAGCGGCGGGGAGACTACATCAACGCCAACTACATCGACGGCTTTCTCGTGCGCAACCAGTACATCGGCGCCCAGGGCCCGCTGACCGGCACTTTTGCGGCCTTCTGGCGGCTCATCTGGGAGCAACGCATCCAGATCGTGGTCATGATCACTAACCTGGTGGAGCGGAACAGGAAAAAGTGTGACATGTACTGGCCGAAGGAGGGCACTCAAGTGTATGGAGTTATACAAGTGGAGCTTTTGGACCAGAAGGAGCTGTCGACCTATACGATAAGAAAAATGCTCATCAAACATACAAGGCACAAGAAGAAGAAGGGCGTGTGCAGTGAAAGGATCATATACCAGTACCACTACACCAGCTGGCCGGACCACGGCGTACCAGACCACCCGCTTCCGATCCTCAGCTTCGTCAGAAAATCGGCCGCTGCGAACGGCGCCGGCGCGGGACCCATTCTGGTCCACTGCAGTGCCGGGGTCGGAAGGACGGGCACCTACATCGTCCTCGACGCCATGATGCAGATGATGAAGCTCCGGGGCGCCATCAACGTGTTCGGCTTCCTCAAGTACATCCGCACGCAGCGCAACTTCCTGGTGCAGACTGAGGACCAGTACATATTCGTGCACGACGCGCTGTTAGAGGCCCTGGAGGCGGGCGAGACGGATGTGCGAGCCACGCGGCTCACCGAGTACCTGCACCAGCTGCGCTCCTACGACCCGAACCAGTACCCCCGCTACACGCTGGACCGCCAGTACCAGCTGGTGACATCATACCGGCCGACGGAGAATGACCTGGCAGGGGCCTTGGCTCCGTGCAACCAGGCGCGAAACCGGAGCGCCCAGTTTGTGCCGTTGGACCGGTGGCGGGTCCACCTCTCTCCCCGGCCGGGCGTCGAAGGCAGCGACTATATCAACGCCACTCCCCTGATAGGTTACGAGAAGCTGTGCGAGTTCATCATCACTCAGCACCCGCTGCCGCACACGGTGGACGACTTCTGGCGAATGGTGTGGGAGCAGAACGTGCAGACCGTGGTCGTCCTCTCGCCCATCGACGACCAGCATTACCCGCGCTTCTGGCCGTCGCCGGACGATGACATCGACGGCGACAGCTTTCGGGTGCGGTTCGTCGACGAGCCGGCGTCGGCGGCGTACGCCACCGTCGACCTGGTGCTGCAGTCGGCGCAGGACGACTACCAGGTCACGGTGCGCGTCATCTCGTGCGCCGCGTGGCCGCACGGTGCCGCCGCCTCGCCGCACCACCTGGTGGACGCCGTGCAGCAAGCCACGCTCCAGTACCAGAACGGACCGGCGGTGGTGGTGGACAGGTTCGGTGGAACTGAGGCGGCCACCTTCTGCTGCCTGACCACGCTGTCCAAGCAGCTGGTGAACGAGAACTCCCTAGACGTGTACCTGTACTCCAAGCTGTACCACATGAGGCGTCCAGGAGTCTGGCAGACCCAGGACGATTTCACCATGCTGTACCACGCCATGGAGGGATTGGTCCGCCCAATACTGCCCCACTCTCCCAGCAGCCAATCAGAAGCCGAAGCCCTTCTGCGTCCACCCAGCCTGCGCACGAGCACTATGAGGGTACCTCCCGACGGAAGAGAGTGCTATGTGCCTGCAGAGTGTGTCTGACGTTCTGTCAGAGACCGTACGTGACTGTCACAGCAGAGGGTGCTCCGAGCCCGCCGAGTGCCTCTGACTCTGTCAGAAGCCGTGCTCCGTTTTGAACTGCAGGGGGAACCACGCA
->XR_005812777.1 PREDICTED: Oryza brachyantha uncharacterized LOC107305249 (LOC107305249), ncRNA 
-GGAACTCACTAAAACCGCTCGCCGTTCGCTTCTACACCTGACAACCCCCGCCGTGCCTCTATCGACCCTCCCTCCTCCGCCTCGAGCCTCCGCCGCCGCTCAGCAGTTGCGGACCTCTCTCTCTCTCTCCCCGGTGCGAACCGGCCGTCACCGTCGGGAAGGATGGGGTGCGTGCCATGCCGGCACTCACCATCTCAGCATCCTAAGAACCGCAGTTTTGGGAGCTGGCCGAGTTCTTTCGGTATGTCACCAGAAAATTGGCAGCCAACAACGCTCCTGACATGCACAAGAAAAAGCTTTCAAGGTTACTCAAGGATCCAATGGTCGATGGAAGTGGACCGCTCAAGTTGTTGTAAGATAAGTCCCTGCAGATGATCTTAATAGATTTATCACAACCAAACAAGGTAAAAACTTTCACAGGTAGATTCAGCAACATTAAGGAAGAGTCCATGTTGCAGCTCTTGTTTATAACACTCAAAAGCTTTCTGTAAAATTGACAAACTTGTAGTACATACAGGTACTGTAGTTCTGACAATGACTGTACATCTCCTGAAAGTGACCCAGACAATCCAAAACTTGACAGCCTACTGTAAACCACAAGAAAAAAGACATCATTTAAATGAACATAGAAGAAACAGCATCTTGATTTAATGAAATATGTGTGTGTGTGAGAGAGAGAGAGAGAGTTGATTCAGATAAAATGGTTCTAACATCGAGGTGACACGATTCTGGATGCAGGATACTCCTGGCCATTTTTGTCCACAAGGATCATTTCCAACCCAATCCGATAGCTTGGACATGGCGTTATCCCAGGAAGCTGCTATGCCTTTGAGGGCAGAGGCTGTAAGGCAATGAGAGTGAAGAAACATCATCATGCAACAAAAGCTAGTTTTTACAGCAAATTAACTGGAAAACACAAGGAGGCTGATGAAACACTTACTATCTTGTGGATCTGTATCTGCTGATATGATGAGAGCACGGTGAATAATGATCAGGGAGACTAGCAGATGGATGATCCTCCAAGAAGTTGGAGGATGCGCCATGGTGAACTTTATTTCAGGTTGCTGAGAAGCCCTTTCTTGTGTTACCAACTCTCCACTACTCAATTCTGAGCACTTGCAGTGACATGATGTTATGAAGGCTGAATATGCACATCAATTGTGAACTGGTCAATGGAATCAGTCAAGAATGTGGCTTTCATCTCCTCTCAATGGATTGCCTTTTCAAATTCATCCAATTAATGGTGAAGTCCCAGATTTTAAAAACCAAGAGAGAGCTCACAATGGGAGTCAACGGTGAGCTATTGGTTGGCAGGGAGCATGAAGTTCTCTCCTATGAAATAGGATCCGAATGATTCAAATTATTTTTACCATGTTTGAAGTATCATTCCAATTGAATATAAAATAATTGCTGCTCCTTCTAAGACACTTGAATGTTTATTGCATGCATATTATGTTTTGTTGAATAGTGTAGATTTTAGTTGTCGTATATTCATGGTGGGATTGACTTTAGAAAACTATTGGGACCATTTTGTTGTGTACATGTGCTGAATCTGAGGTTTATTCGAATGATTTGCTAAGAAATGGTCTGGTTTGAACACAAAACATCTGATATTTCTAGACATAT
->XM_034077493.1 PREDICTED: Pseudochaenichthys georgianus non-SMC condensin II complex, subunit G2 (ncapg2), partial mRNA 
-CGCGGGCTCTTATGGCAGACTGTCGTTCTGCGGCTGTCGGATCACAGCATTATTAATACAAAGGAATATTGGTGTTGTTTCACGTCTTTTGGAGAACCACAAACATGTCGAAGCGAGAGGCTTTTCTAGAGTCCTGCTGTACGGAGAATGTGGACGATTTCCTCCGCTTTATTCAGCTTAATCGGAACAAGACGGAGCCCTTCGATGTGGAGGAAGTTCTGCAGGAGATGAACAGAGACCAGAGGCAGACGCTGTGGGGGAAACTGTCCTCTCTCCTCCAGGACGTCCTGCAGGAGGAAAGGAGAGAGGAAGGGAGTGAGGAAAGGAGAGAGGAGGCCATGGAGGTGGAGGCAGCTGCAGACCCCAGTCACGTGAGGTCTGTCGTGGACGGTGTGACTCTGGTTGCTGCCGAGTCCCTAAAGGTCCTGCAGGACGGAGAAACCTACAGTTCTCTTCTGGAGATCATCCACAGGCTGCATGATATGTTGGAGCTGCAGCCGGTCTCCGAGGCTCCGCTGCAGCTCCAGATCCTCAGACTTTGTGACGCCTGGTGGAAGAAGGATCTGAAGGAGAAGGAAACGTTCGGTCGCAGCGCTATGATCATCGCTCTGACGAGGAGCTTCGACCTGAAGAAACCGGGCACAGAGATCCAGAGGGTGTGGAGTCTCCGGGAGGTTCTCCTGGGTCTGGATTACACGTCGGAAGACAACAAGCAGATGATGGATCTGCTGCTGAAGTGCTTCCAGCGCCCGGCCTTCCTCAGGAACGACGATGGAAAACGCTTCCTGGTGTTTCTCTTCAGCTGGAACATCAACTTCATCTCGGTCATTCACGGCACCATCAAGAACCAGCTGGAGTTCTTTAGCATGATGGTAACGGCTCACATCGCTGAGATCTACTTCAGAGCCTGGAAGAAAGCCGGCGGTGATTTCCTGGAGAAGATCGAGAGCTCCTGCGTTCAGGATCTAATGCAGAACGCCATCTTCCTCCACAGATCCTCTCCTGTGTACGCCAAAGTCCGAAAGATCGTGAGCTACTTCCACTCGAGGAAAGGCTGTGAGAAAGTGGACAAGATGCTCTCCAATCTCTACAAGCCCATTCTGTGGAAAGCTCTAAGTGCGCCAAACTTCGAGGTGCGAGCGAACGCCACGCTGCTTTTCACCGAAGCTTTCCCGGTGCTTGACGTGGAAACCGGCAACAAGAGCACGGACGAGGCCATTCAGAAGCAGCTGGACACGGTCATGGTGCTTCTGGACGATCCTCACCCCACAGTTCGCTCTAACGCCATCTTAGGAGTGTGTAAGATCCTGGCTAAATACTGGGAGGTGCTTCCTGCCGCCATCATCACCGACTTCCTGAAGAAGCTTGTGATGGAGCTGGCGTTCGATTCGAGCTCTCCTGACGTCCGCTGCTCCGTCTTCAAGTGTCTCATCATCGTGCTGGACAACAGCCTCAGCCATCCCATCCTGGAGAAGCTGCTCCCGACTCTGAAATACAGTTTGCACGACAACTCGGAGAAAGTCCGCATCGCTTTCCTCGACATGCTCATTAAAGTGAAGGCTGTGCGAGCTGCTAAGTTCTGGTCCGTGTGCAGCATGGATCATCTTCTCGCTCGCCTCGCCATCGACTCGTTATCCGCGTCGAAGCGCATCGTGGATCTACTTTTCAAGTCCTTCTTCCCCGTGAACGAGTCGGATAAGGAGTGGTGCAGCCGCTGCATCACGCTCATCCAGATGAACCCCGCCGCCGCCAGGAAGTTCTACACACACACACACAAACACACCGCGCCCACCAACATCATAAAGCTGATGTTGGCGATTCGCCGCGTTCTGAACTCTTGCCTCCAGGCCCAAGGTGACCTGTCTGAGATCAACGACACCAACAAGGAGAACAGCGCA
->XM_013920937.2 PREDICTED: Limulus polyphemus tyrosine-protein kinase Abl-like (LOC106461142), mRNA 
-AGCGGCCCCTATGGACGGCGTAGAGGCTTGCTTTGAGAGTGTTCGGTCATTCGTTTCAGAGGTTTTTCAATATGGCTACTAATGAAATTGTTAGTGATTAAATTATTGATAGTCACAACTTGCTAACATGCTTGTACTTTTTATAATTGGCATATTTACGTAGTTTATCAATAATGCTATTAAAGGTCTCCTAAATAAAAGTTATGTTCTGAAAATATACTGCATAGTAAGGATCCCGAATAGCCTGAAGGTCGTTTTGACGTTAGGCTATGGGAGCCCAGCAGGGCAAGGAAAACCGTGGAAGTGGATCTTCGGTTGGCAGTGGACATGGTGGAAAGACTGGGAAGAGCTTTAAAAATAGATCTAAGGACTCTAGATTATCATCAGTTTCTGGAAATATATTTACAGAACACAATGAAGCCCTGATGCAAAGCAGGCCTTTGCCAGATATTCCTGACTTTGGAGATCATATTAGCAACTTATCCATCCCTAATGATGGGTCATCCCGGTGGATGTCCAAGGAGAATCTCCTGGCTCCTGAAGACTCTGATCCCCAATTGTTTGTAGCACTCTATGATTTCCAATCTGGTGGAGATAACCAACTTTCTCTCAAGAAAGGGGACCAAGTACGAGTGCTATCATACAATAGAACAGGTGAGTGGTGTGAGGCACAGTCACGTTCAGGTCAAGTTGGTTGGGTCCCTAGCAACTACATCACTCCTGTCAACAGTTTGGAGAAACACTCCTGGTACCATGGGCCCATCTCTAGAAATGCAGCAGAGTACCTACTAAGCAGTGGGATCAATGGGAGTTTTTTAGTCAGAGAAAGTGAAAGTATTCCTGGTCAAAGGTCAATATCTCTCCGTCATGATGGACGAGTATACCACTATCGAATTAATGAAGATGGCGAGGGTAAAGTGTATGTGACGTCTGAATGTCGATTCAATACTTTGGCTGAACTTGTCCATCATCACTCCATGCATGCCGATGGTTTGATCACCATGTTACTCTATCCAGCTCCTAAGAGAAACAAGCCTGCTGTATTTGCTCTTAGTCCAGAACCAGATGAATGGGAAGTGGACAGGACTGGTATTGTCATGAAACACAAACTTGGAGGAGGACAGTACGGAGACGTTTATGAAGCTGTCTGGAAGAGGCATAACATGACAGTAGCTGTTAAAACACTGAAAGAAGATACAATGGCCTTAAAGGATTTTCTAGAGGAAGCAGCTATTATGAAAGAAATGAAACATCCAAACTTGGTCCAGCTAATTGGTGTTTGTACAAGAGAACCACCATTTTACATAATCACAGAGTTCATGCCCCATGGAAACTTGCTGGATTTTCTCAGGAACGCCGTTCGCGATGATATCACGGCCGTGGTGCTAATGTACATGGCTACACAGATAGCTTCAGCAATGGCTTATCTAGAATCCCGTAGTTTCATACATAGGGACCTAGCAGCAAGAAATTGTTTGGTGGGAGAAAATCATCTCGTAAAAGTTGCTGATTTTGGTCTAGCTCGACTGATGAGAGATGACACTTATACTGCACATGCTGGGGCCAAGTTTCCAATTAAGTGGACTGCTCCTGAAGGCCTTGCTTATAATAAGTTTTCTACCAAGTCTGATGTTTGGGCTTTTGGCATCTTACTGTGGGAGCTGGCCACATATGGAATGTCTCCTTACCCTGGGGTTGAGCTAACAGACGTTTATCATATGCTGGAGACTGGCTACCGAATGGAGTGCCCACCGGGATGTCCACCAAAGGTTTATGAACTAATGAGACAGTGCTGGTTGTGGGAGCCTCTTGATAGGCCTACTTTTAAAGATGCTCACCACACTTTAGAAACTATGTTCCAGAATTCAAGCATAACAGAAGAAGTGGAGAAGCAGCTAGAAAGGCAGACTCCTGCACCGTACAGGTCCTATGGAGAGAGTTCGCCAAATATTTTTCAGCGTGATGAAGAAGGAGATTATCCACTAACTGAACAAGGTTGTCATAGTGGAGGTTCAACCAAACACCAGACCATTATCTCCACTAGATCTACTTTGGTTCAACTTCGAAGACATGGCCCTCGAAGTAAACAGGCACCTGTACCACCAAAGAGGACCAGCACTTTTCGGGATAGTGTCTATCAAGACAAAATGTATGGAACAATCGGACAGGAAACTAATAAAAATATTCTCAATAATGGTGGTGAGAGAGCCTTTGAGACTAGTAACAGGAAAGCTCAGGAGATGAACAGCAATGAAGAAGGGGAATGTGAAATAAGAGAGAGAACTCCTGATACTGAGGAATCTGATACTCATACAGCAGCTTCAGTTGCTAGTGTTCCAGCAATGTCGCTAAACCAGCAACATTCTCAGCAAAAATTGAAAAAAGCAAGGACCTACCCTCCTAATATTCAGCAACATAATAATACAAAAGAAAACAGTTCTTCAAATAAAGCAAGAGAACCCAAGAAAGTACAAGTTGCAGCTCTAGAAGTTCAAAATGTGAAACGAGCCATTAATCGATATGGGACACTTCCCAAGGGAGCAAGAATTGGTGCATATTTAGATTCACTCAGGGAGCATGGTCTCCATACTGGAGCTAAGTATCCTGAGCCTGTTGTTGAAAGTGAACCACAAGCTTTTAGTGACATAGGATGGGAAAGTGCAGCTTTAGATCCACTTTCCCAGAAACAGAATTTTAGCAACATAAATAATACTCATAAAGGAGAAACTGGAAGCCATTTCTCTTCTAGATATCCTCCTCCAAGTCGGCATAGACACGAATATGATGGGGTTCATCATTCACCTCATGCCTTTCTACAAAGGCAAAAGTCAGATCTCACGTACTCCAAGAACAATGACACATTTGAAACAGGATCTATTCCAGACTCTAGACACCTTAGTTCAAAGCCTATTCCATCTCCTAGACTTCCTAGAAGTCAGAGGGTGGATCGAAAATCCTCTCGTGATGGAAGAATTGAAGGACCACCTTGCATACCCCAGGAGATAAGAAATATTCACGATGTTGGTACTAACAGTGCTTCAAATGCTGGTGGTGAAACCAGTTTTCGAGATTATTCTGGTAGTAGTTACCCCCGGAATAATATTATTTCAGAATCCAGAAATGTTGATTCTCAGTCATTCTCATCTCCTTTTAGTTCTAATGTCTTTCGAAGGACACTCACTAAAAGACCAAAAGAAAGACCTCCAAGTCCTCCAAAGAGCCCACTTGTAAAAAGTGGTTCAATTGATGATCAGTTAGGATGGAAACCTGAGAGGATTTTTGATCAGAGTCCATCAGAAAGTGCACACACTGTGACTCCACTAACTTGGAGTGCTAGTGTAGACAGCCCACTTCCTCCTGGAAAAGTCAAAGTCCCATCGGGGAGTCCAAAGTCATCATGGAATATTGTATCTCCCCCTCCACCACCTCCTTGCCCAGAAGGTTTTCCTCCTCCTCCTGATTTTGTAAAAGATTCTCTGGAATCTTGCTCTGAACAGCAGACTGTGATTGAAGTTAAAGCTCCTTTAGTTGCCAAGGCATCACATAATAATCAAACTGCCAAGAACCCAGCAGCTCAGCTAGTCTCAGAACTCTTTGAGAGTCTTAAAATGAAAGCCAGAAGAAGAGCTGTAGAGATGGGAGATGCTTCTTCTCAAACCACTGAAGAAGTAGGAAGCTCTGCAGAAATATCAAAAGATCAGTCAGCTGTTGCACTGTCTCCTAAAAAGCAAATTCCTTCTGTAGACTTACCTGTAAAATCTGAATCTGTAAATTGCTCTAAGTTAGGCTATCAACAAGGAAATGAGCTTTCCAAAAGAATCAGCTCAATATTTGAAGCCAGCTCAAATAGGGAAAAAACAACTGGAGAATCACAGTCACAGTTTTATGTGCCCAGCAATAGACTCAAAAAGAAGACTCAAGATAATATAGAAAAAAGTGTCAGTGGAGATCTTGGCCAAAAAAATTTAGTTATACCAAAACTCAAAAGCAAACCTCCTGATAGAGATTTGGTAGAAATCTGCCAACCAGATAGATGTGAAGAAGAAGAAAGAAGACATAGTTGTGGAAGTATAACAAGTTTGAAGAAAATCTGGGAGAAAGAGAGCTCAAAACAGGAGTCGGAGCTAAATGCTGATGGTTCATGCATTGACAGTCCAAAAGTTGTGGCACGTCGACCAGAATCACTGAAAATAGAAAGAACACAGACTTTGGAGCTTGGAGATGATACTTTTAAAAGTGGAAACTATGAAACTGAACCTGTACAGAAAGCATCGCCAACCTATGTTAAAGAAAGTACTACGTCAAAAGCATTGTCTCAAGCATCATTAATAGGTGAACAAACAGAAGAACTAACTAATCAAGAAGATCAACAGAGTCATTTAAAAACTTCCCCTCAAAATAAAGAAACAGGAGGACAGTTATCCCCAGCGATTCCTAAACCAGCAGTTCCATTGAAACCACCAGTAAAAGGATCTCGAGCTGTTTTGCCTCCAGGTACCAGACCCTCTAAAACAAGTAATAAGCCCCAGGTTTTTCCTCGAGGAGGTATAGGGGGGTCTCCATCATCGCAGGCTGATGACGAAACACACGATAGCATAAGCAGCAAAGAAACTATATTGGAAATTTCTACAGCACTTGAAAATAGTATTCAGTTACTGAAAACAGCTACATCTCTAAGCAGTGGAAACGTAATGCAGCTGTCGGATAAAGTGCAACTTTTTCGAACTTCTTGTGGCAACTATGCAGAAAGTATCCCTCCACATGGGAGATTTCGCTTTCGAGAATTGTTAACAAAGTTAGAACGACAGGGTGAACAGTTGCGCACATGTAGCAGTAATAACAGTGCGTTCAGTTCCAGACTTTTTGAAGAATTACAAAACACGGTGAGGGACTTGGTAAATATGGTCCAGAGGTGAGCAGTGTGGTCAATATGTATAAAAACGTATATCAACTCTCATTTATATATCATGATATGTGTATGATTAGTTTCTTGATTTACTCATGAATTCCAGCATAAGAAAGTGGGATACATGGTCATCTAGTCGTAACTTTTGCTCATTAGTGAAATGGTGGTGAGAAAAGCTGACAAACTTACTTATAGTTACTACAACTTCAGCTGAGAACTGTCGTATGTACGCTTTAAATTTGTGATTTACACATTGTCCATGAGAACCAGCCTAAAAGATCTCTACTACGTGAATTAGATCCCTTAAAGTGCTTTTGAGAATGGAGTTCAACTAATACTTGTCATGTTAACACAGGTGTCATTTTTATCCTTAGAAAATAGTATTGTAAAGATATATTGATAATCCAGGAGAAGTGTAAGATACAAAATGTCGGGTATTTAATAAAAGTAGAGAGCAAAGCTATACAATTATTCATTCAGGGTTTGGTACAATATTACTCTTTATTCTCAAAGAAAATTAGATGTGTGTGTGTGTGTTGAGTCAGTCATGGTTCCTTTCATCTGTGAACAGTTGTTAACATAGTGTCACAAACAAATATATTTTGTAGTTTAAAAATTGATGTGTGTCGTTGTCCCCCCCCCCCTCCAAGGTAAATTTGTGGTTTGGACACACTTGCCTCGCAATGAGACAGTTAAGTGCATATTTCTAGGCTAAAGCTACATTGAATCCCATTTAACTTTCATTGTGAGTTAATGCTGGTCATAAGGTAAACTCTGTTGTACGTTTTATGGTTAAGAGTATTTAAGAATTGAATGTTTACTAATGTGGCTCTATCAGATCCAGCCCATTGTTGTTTTTGCCCTTATAAACAAATATGTGGATGTATTATATCTGTGTATTTAACTTAACCTTGTGCTACAGTGTCTGTACTAGTTTTTGTGACAGGGGTTAGTGGATGAATTCCTAATATGTATAGCAACATTTGCATTTCCTTTCATAATAAAGAAAATTCAGGTTTCGAAATTTTATCTCACTCAATTCAAATTATCTTAACTTTGTGGGTGGGAATACAAATTCTCATAGGGTTGGCAGTACAGGTGGAGTCGTCCAGTTAGAACTTTGAGCCATATTACTTACTTCCATTGGCTTTACGTAATGATAATAGGACATTGAGGGCACTTTCTATTTGATGCCTATCCTTTACCTTTGTCTTGGGGGGAGATTTCAGCTTATATATGTCATAGCACCTTTTTTATGCACAGTTCGCCCTTTAATTTCTCTTTTGACCTGTATTTGACCTGTACATATTTCGTGGTTTCTTTTACTGCAATATAAAATGTGAAGCCAGAATTAAGTTTAGTGTGAGTATGGTTTTATATGTATATTACAGGAAATATTTTGTGTTTTTTTGTTGGTTCTTTTGTAAGTTTCAAATAATTTTAACTTCAAGCAGTAGACAGGCCCATTTAAGAGAAATTGTACTTAGTATGAGAAGATTTCTTGGGAAAATAGATGAATTTTTTTTTTAATATTTATTGATAGGAACCTGTAGAAAACTGTTTATATGAGCCACTGTTTTGCTCTGAAGACTTCACTGGGACCGAAAACCGTTGTGTGTCTCGGAACTTTACATATCCTTTTAGCCCTGAGCAAAATGATGTTATGACTTTCTCATGTCTGTGTTCTTTATTTAGGCCTAATGAAACTGTAATGGCAAAATGTTGGCTTAAGTAAACTCTATCGTCTGGAGTAATAAGCCCTATTTCATTTATCCTAGAAGTTGGAAATTCGTCAGTCTGCTCCAAAAATCTTCATTGTAATGTTTTCATTAGTGGTAAAAATTTAACTGTTGAACTATCATTCACACCAAAAGTGTTTCAGAAACGCGTGTTATGTAGTTCTGTGTCACAAACACGTGCTATGCAGTACCAATATTTTGAAAATTAAAAGTGCTCTCTATCAGTGAAGTCGTGAACTTTTGATCAGTATATATATATATGTGTGTAAAGAGTGTGTTAAACGTTCATAAGTAACAGTTATGAGGAAATTGGATACAGTGATTATGGCGACTTGTTTATCTGTTCGTTATATTGTTGCTTGCTCATTAAATAATCCCTTTTTTTTAGTTCGCTTTTGTCTGCGACCAGTGTATGCAAACTTGTACACATTATTAATCACCTTGTTAAAACTTTTTCTCTGTTTTTTTTGTATTTTTTTATATCAAGTCTGTTAAAAGCGATTCATCTCTGTAACTTTGGCTAGATGGTGTTGCGTGCGTTTATTATGAGTGAATGTAACATCATCTAACTTTCTCTGTAATATGATAAGACAAACTGCCACAAAAGTATCGTAATTCAAAAATCAAGCCTTGTTTATTGGATGGAAGTTTTGAAAAAATGTCTTTGTCTAAAAACGAACATACGCATTGGACTGTTTGATACGTGAAAATGACGCTGAAGAAACGAGTCGTATTTATGAGTGATTGCCTAAGTTAACATTAAACATGGATTATGTTATAGCAGATATGTAACTAAATTTGTATTTTAATGTCAGAAAGCATGTGAATTTTTGGTGTATTTTAACTGTATATCATGGAAGGTTGTTTGTGAAATGTAGAGATAGGTTTGTTCTCTGTGCCTTGACCTGTAGGCGTGTCTTGTACCGATGTTCAGCACTATAATTATCGGCATTCTTTCCTCTTTCAGTACTTTCCCAAAGCGACTAATCAAGACTCGGTAAAATGGCAATAATCCACACTTGGAATATGTTGTAGGAACGTGAAGGTTAAGCGTGTGATTGTATATAGAGAGAGCAAACTTCCTTCTCAAAACGGTCTTCAATAAACTCTTCTTGAGAACATATCAGTTCTTATGTTGCTTCAACAATCCCTAATGCTAGCGAAAGGTATTTTGCCTACTTAATACATTTCTCCACTGTTAATGTGTTGCCATTATTTTAGTTCACCTTAGTTTCGTTCTATAAGATACCGTTTATAAAGCTTTAGACAGCTTATCCTATTTCTTGCATCGTATACAAGAGAAAGTTTGAGGCCTGGAGCTTTTGTTATTTTACAGGTATTTAATTATATTAATCAAGGACCAATGTTTTAAAAACGTGGTTTTAGGTTGAAATGTTTGTGCTCAGGATTGTACTCTCTTGGTGATCTGAAGGTGTCTTGTTGTAAAGCAGTCTTTGCGTTGAGTTTTTTACATTTAATCCTAACTCGTAATGTTTATAATTGATTAAATTGAAACAGAAAAGGCTATTATTTAATCGTTTTTAGATGAATGAGAATCACTGACTCTATTGATAACAAAGTAGCGGTGTCAATTTCGTATGAAAGATTCGTATTTTTGAAATTAAAATGGGTCATAGTAACACACTTCATAAACCTTACATTTTACCAGTGTGTTTGAGTTAAGAACAAATGACTACTAGACCTAGAATTACCTGTTAAGTGTGTTGCACATTCGCGTATCTAAAACTATTTTATGTGTATTGGAGTTTTCTCTTGTGTTTGTCTGTGTGCATAACAGTATTTCTTTTAACCCTTACTCAAATCCTTGGCAGATTGGTGTTTTTTTTAAGTATTTATTCTGTATGTAAACATAATTGAAACGTTATTTTACGATTTATGATATTCAGGTTCCATAACCCACGCTTTCGGTCGTCTTTTAGAATATTCGTGAAATTTACGATAATTGTAGTGGTTGTACTATTTTATATTTCGTGTAAATATATTGTCTTTTATCTTTTCTTCCTACTTCTCATCTCGCGTGTTTTGATCAGGGGTAGAAACTAATTATACTACTTCTACATTTCATTCTAATGTGTGCTACTGTGTAAACATTTCTTCAAAACACGCTGTCATGACTTGTCACATGTCTATACTTGAAGACCATTTCGTGTATGTAAGAACGCGGTTCCCACCCTACCGGTAGCACTTTTAATCGTGAAACTCCACAAACTGGAAAAAGAAAAATAGTTCTCTGCACCACCAGAGAACTACATAAAACTACAAGTCCAACACGAGTATATCGCAATGGATACTACTAAATAAACAGGAAAAAAAGTTTTTTTTATTGAAAGTACAGTGTGTGAATGATAAATCATAAATCATTAAGACAGTCTAATACTTTTGTTGTAGGTAGCTTAAGTATATAAATAAATAAATATATATATATATATATATATATAGCTATGTAGCTGACTAATTTAATGTAACATACCTTTATGAAACAAATTGAACATTTGTATATAGTTGAAGTGTCTAATATACTAATCAGTAAATGTTTCTTATGGATGCCTAATTTTGACTCGCGCTGTAAATTGTAGATTTTTCTAAGTATTAGTTCCCATCAGCGTAATAATTTAAGATTAAATCAAATGAGAAGTTAAGTTACAACGAATTGATTTTGTTTCAGCACCACGAAAGTGTTTCTTATTTATAAATTTCTTTTGCGTAAAAAAATGAATGGCTTGTATTGGACTTTTTTTAAACGTCTGGTATGGATTTTTTTTTATTTAGTCCTCTTTGAACAGAATAGATAATGCTTGATATAAATACGTCATATCAAAGTAAGAGATTGAACACTTCCGTAATACTTAGGCAGCATAACGTCGACCACCATGTTTGTTTATCTTTCTGAACACAAATGGAATTCCACCGTTATCACAATAGACTGTTTGTTTCAAAGTATGTTCATTTCAAGAAGTAACTGTGATTGTTTTATTTTTATTTTTTTGTTAACTATCGTTGCTCATATTAGACAGCAGATATTAAATAGTTGTGAATAAAATATACGACACCAGTTTG
->HQ716622.1 Uncultured bacterium clone T2WK15F91 16S ribosomal RNA gene, partial sequence 
-GTTTGATTATGGCTCAGGATGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGGAGTTAATAGTGAATGAGGCTTCGGCCAAAGGAGCTATTAACTTAGTGGCGGACGGGTGAGTAACGCGTGAGCAACCTGCCTTTCAGAGGGGGATAACATTTGGAAACAGACGCTAATACCGCATAAGATCACAGTACCGCATGATAGAGTGATCAAAGGAGCAATCCGCTGAAAGATGGGCTCGCGTCCGATTAGATAGTTGGTGAGGTAACGGCTCACCAAGTCGACGATCGGTAGCCGGACTGAGAGGTTGAACGGCCACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCAACGCCGCGTGAGGGAAGACGGTTTTCGGATTGTAAACCTCTGTTTTCGGTGACGAACGAAATGACGGTAACCGAGTAGGAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTACTGGGTGTAAAGGGAGCGCAGGCGGGATAGCAAGTCAGCTGTGAAAACTATGGGCTTAACCCATAAACTGCAGTTGAAACTGTTATTCTTGAGTGGAGTAGAGGCAAGCGGAATTCCGAGTGTAGCGGTGAAATGCGTAGATATTCGGAGGAACACCAGTGGCGAAGGCGGCTTGCTGGGCTCTAACTGACGCTGAGGCTCGAAAGTGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACACTGTAAACGATGATTGCTAGGTGTGGGGGGTCTGACCCCCTCCGTGCCGGAGTTAACGCAATAAGCAATCCACCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCAGTGGATTATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCAACTAACGAGATAGAGATATGTTAGGTGCCCTACGGGGAAAGTTGAGAGAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTGCCATTAGTTGCTACGCAAGAGCACTCTAATGGGACCGCTACCGACAAGGTGGAGGAAGGTGGGGACGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTAATACAATGGTCATAAACAGAGGGAAGCAAGGCCGCGAGGCGGAGCAAATCCCCAAAAATGATCTCAGTTCGGATCGCAGGCTGCAACCCGCCTGCGTGAAGTTGGAATTGCTAGTAATCGCAGATCAGCATGCTGCGGTGAATACGTTCCCGGGTCTTGTACACACCGCCCGTCACACCATGGGAGTTTGTAACACCCGAAGTCTGTTGTCTAACCGCAAGGAGGGCGCAGCCGAAG
->XM_041020936.1 Aureobasidium melanogenum CBS 110374 alpha/beta-hydrolase (M437DRAFT_44633), partial mRNA 
-ACTTTGAGACATATATACCATAAAGGCTCTCATCAGTATCCGCATCTCTTACGGAAAGTCGATATCAACAAGGACACACTGCTTGAGTACGAGAACGAAGCTGGGACAACCATTCTTAGACCAGCTTGGGATGCGTTTTCTGTGCAGTCGGATACGTTGATGATACAGCGCCTTGCTGATCGCAGACAACATGTCGTTGACGGCTTATTAGAGCATGGAGCTACCTTCGGTGAAGCCAAAGCTCTCGATGCAGAAGCCTGGACTCTAGACGAGGTCTCCAGCCCTGATGTGACCGATAAGAAGACAGTCCTAAGCTTCGCCCACATGGCGGCAAACGCCTACGTCTCCATCCCTCGTAAAGGCGACTGGATCGACATTGGCGGCGGCTTCAACTATACCGAAGATTTCGGCTGGGAGTCCGATGGGCTCCGCGGCCACATCTTCGCCGACACGCACAACAAAACCGTCGTAGTCGGGTTGAAAGGCACGTCCCTCTGGTTCTTCGATCCTCCAGAGACAACAAACAACGACAGAGTAAACGACAACCTATTTGGAAGTTGTTGTTGCGGGCAAGGAGGCCAATATGCATGGAAAAGAGTTTGCGAATGCCAGACTGATGCAAAGACTTGCAATGCTACTTGTTTGGTGAGTAGTTTGAGGAAAAAGAGTAGTTATTATCATGCTGCGAGGGCGCTATATCATAACGTGACGGCTTTGTATCCGAACGCTGATGTTTGGCTTACTGGACACTCGTTAGGAGGTGTGGTATCCTCTCTTCTTGGTGCTACTTATGGTCTACCAACTCTGACTTTCGAGACTTTTCCTGATGCACTTGCTGCTCATCGATTAGGTCTGCCAACACCACCAGGTCACCAGATTGGTCAATCTGGTAGACAACATTATACCGGCACGTTTCATTTCGGTCATACTGCAGACCCGATATATGTCGGAAACTGCAATTCGTATGACTCGTCTTGCACGCTTGCGGGATATGCTTTCCAGAGCAAATGCCACACAGGGTTCAATTGCACATACGATACAGTTGGTGATAAGGGTTGGAGGGTCTCAATCGGCACACACAGAATCAGCAGCGTCATCAAAGATGTCCTAGAAGCTTATGACACGGTCCCGGTATGCACACAAGATGTTGGTTGCAAGGACTGCTCTGAATGGTCGTTCTTTGAGGGCAATGGGACAAAGACGACGACCAGCTCAACAAAGACTGCTTCTTCGACGGAACTCACTACTACCACGACTACGACTTGCCGCACTCCTGGCTGGTGGGGTTGTCGGGATGAGTCTACTACTACGAAGACAACATCGACGTCGACGAGTGTCTCTAGCTCAACGTGTTTGACGCCAGGCTGGTGGGGCTGCAAAGATGCTTCTACGACAACAAGCTCTTCATCGTCTCATAGCGCTGAGATGAGATCGACTGCCACGCCGATACCATGA
->XM_012484966.2 PREDICTED: Apis florea spindle and kinetochore-associated protein 1 (LOC100864548), transcript variant X2, mRNA 
-AACTTATTGATAAGAACGCCATTTGTAAACGATATCGAATGAATTAAATTCAAAGTTTACAAACGGCGCCAGGAATGACCGTTATTTGTAATGCTATGTAAAAATGCAATTAAAGAAGAATTCCTTAAAATGCGCATAGTACTTTCACAAATGTGTAATGGTATTGAACAGATAAGGAAAAAATTAGTTGATATGAGAAAACAAAATAATCAATGTAGAGAATTATTGTCATTCATTGAAACTTTGGATAAAAGAATCATTCATATGGAAAAAAATATTCCACATGAATTAATTCGTGACTATAATGAAATTGAAAATTCTTTATCAATGAAAAGTATATGCAAGAAAGAGCTTATACAAAAATCACCTATAATAATAAGAAATAAGAATGTAGAAAAAGAAAAGACTCCAATAAAAGATTGTAAAAAAATATTATTTAACGAACTTGAAGTTTGTCCTACGATATCTTTGATAAGTGAAGATGAGTTCAATAAAGTTCCAAAATATATTATTGGAAGACAATCTTTAGAAACTGTAAATGATTTCATAAATACTATTAATCACATTTTAAAAACAAAATATACATTTTTATCATTGGGAAAAGCTCATGCAAGAAAGCAAGGAGATTTAAATCTTTATTTGCACTATAAAAAACAAGAATTAGATTTATGTAATGATTCTGAATACATATATTTCTTTACTGGTGAAGATTATGAAAAACAAATGAAGTCTAAATTAAATAAAATAAAATTAAATCTAATAACAGTTTTACGACATTGCAAAAGATTAAGAGAACATAGGATAAAAAACGACTTGCGATATGTAATATTAACAAAAAAATAATTGCTTAAGTTTTAAATTAAGTAATAAAATAAAAAGATTGCATAATAAATTGTTTCATTGTACAAAGAAGTTAAACATATAATTTTATATATTTTTTTTATAAGTTTTATAATAATTTAAATGATACATATTTTTATGTGTAATCAATACTATTGTAAAATATATTTCTATTATTCCAT
->XM_047672130.1 PREDICTED: Vanessa atalanta protein claret segregational-like (LOC125064848), mRNA 
-ATCACGAACAAGCGTAAATATTCGAATTTTAAATTATTGCGTCCGTTTACTAATCTGACAAACGAAACAATTGTTCGTGTTTCAAGTGAATGTTGTTTTAATGTAATATTTAAATAAATAAATAAGATGTCTCGCATTCCGAAATTTCCTTCTACTGCTACAAAAGAGAATAAACCCACATTTACAAATGGGCGTAATACAACGCGAACATTAGGCATTGGGCTCAGTGACGCTGATAAAAAAAGCTTACTATTAAATCATACAAAACCAATGCGAAGTACAACATCCGCCAACACTGTAGCTGCGCCCCGCCTTAAAAGATCAGCTACAGCACCTTCCTCCGCTACGGTACCTAATAAAACAACTAAAGTCGAAAAAAAGACGACTACTGTAGCACCTAGGATTGCTCCTTATGATTACAAAGCCAGATTCAATGACTTGGTGGAAAAACATAAAGCCATGAAAAGTGAATTGAATGATTTAAGGGACAAACATTTGGAAGTATCAGACGAATATGAAAAAGTTAAAGAAACAGTTGAAGGAAGTATTACTGAAAGAGATACATTGAAGGATAAATTATTAAACACTCTCAAAGACTTGAGACAGAAGTCTAATGAATATGAAAGCCTAAAGCTGGATTATGAAATACAGAAACGGGAGAATGAGGAATTAAATAATAAAAGTAAACTTTTAGATGACGTAACTAAAAGCTTGAAGTTAAAAATAATGGAATTTGATAAACTTAAAACAGAATTTGATGATTTGACTCGACGTCATAAAAGTCTTAATGAAGAAACTGAGGCTTTAAGGGTTTTGACTGATCACCTTAAGAAAATATCTGTAGAATATGACAAATTGCAATTAGATTATAAGGATGCAGTTTCCACAATAACAAAAAATAAAACAGACTCTGAGGCTTTGCAAAATATTTTAGCGACTATGTATAGAGATCAAAGAGTTTTACGGAACACAGTGCAAGATTTAAAAGGTAATATTAGGGTCTACTGTAGAGTACGACCTCCACTTGAGTCAGAAGCATCCAAGCCTTTGTACAATCTTAATGTCCTTGATGCATGTTCTATAGAAGTTGAAAAGATTGAACTTCTGAATTCTGCAAGAAAAGGAAAATCACAACATTCTTTCTCATTTGATGGGATATTTACACCACACTCCTCTCAAGAGGATGTCTTTGCTGAAGTGTCTCCAATGGTACAATCTGCACTAGATGGTTATAATGTGTGTATTTTTGCATATGGTCAAACTGGCTCTGGAAAAACTTATACCATGGAAGGTGGTTGTGGAGTTGAACAGTATGGTATTATACCACGAGCAATAAATATGATATTCACATGTATGGAAGATCTTAAAAGAATGGGATGGGAATTGACAATTAAAGCATCCTTTTTAGAAATTTACAATGAAATAATTTATGATTTGTTAAACTCAAGTAAGGAACAAGAAAGTCATGACATAAAGATGGTTAATTCGAAAGGCACAGATTTGTATGTATCCAACTTGAAAGAAGAAGAAGTGAAGAGCTCTCATGATTTCATCAGATTGTTGATATTTGCTCAACGTAACAGACAAACTGCGGCTACATTGAACAACGAGAGGAGCTCCAGATCTCATTCAGTTGCACAAATTAAAATAGCAGCTATTAATGAAAAGCGTAAGGAAAAATTTACTAGTAATTTAAATTTGGTGGACTTAGCTGGATCTGAGAGTGGGAAAACCACTCAAAGAATGGATGAAACAAAACACATTAACAGATCACTTTCGGAACTTTCAAAGGTGATATTATCTCTACAGACTAATCAGTCCCATATCCCATACAGAAATTCTAAGCTTACACATTTACTAATGCCAAGTCTAGGTGGCAATTCAAAAACTCTTATGTTGGTTAATGTTAATCAATTTGATGAAAGTTTCAATGAGACTCTTAACTCCTTAAGATTTGCCACAAAAGTTAACAGCTGCCGAACTGTAAAAGCCAAGAAAAATATAACAATGGTTGACTCATTATAATTTTTACATTGACAATATTTTGCTTTAGAATGTAGTACACATGAACACCTATAGTTATACCATCTACTGTGAATTGAATATTATCAGTATTCTGCTTTAACATACATATTTGTATTGAATACTATTAATAAGTGGTATAACTAAATGTGCTTTACTATTTTGTTTTATAGTTAATTTTTACATGTAGTACTAACTTCCCACTGAATATTCCACCGATAAATGTTTTTACTGTTGTTCTATAGTATTTTGAAATATTGTGGGATTTTAGATAATCAAGAGCTCTTATAGTTTTAATTATTCAAATGACCTTAAATAGCTATTACAAAATAACAAGTCTCATTATTTTTATACAAAAGTTTTAGAAGCATTTTTTTGGATTTGTTACTATAAATGTGGAATTCGATATATTATTAAATAAAATAAATAGTGTGAAAGTTCATATACATTCTAAAGAATGTGAGTTGATATTGAAATATTTTGAAGTATTGTGTTAACTGAACTAAAATAATGACAGATTAATTTACTTACTGTTTATATAAATACTATGGCAATAAAATAATATAATTTTACAAATTGTCATAATTTGAATTTGATCCTTTTAAGGCAGGTCTTTGAGTACCATATACAGGTGAAGTTCTAACAATTGACTCACTTTAAATTCCTACTTATAAAATGCCTAATTGACTTATTTAGGAAATTATTATTGTTATTTTTTTACAAATTGGCAGGTTGAATTTGACATTTTAAAGTTTAATTTATTGGGTAGATCAAAGAATATCATATCTGCTTTTATGAAATATCTATTAGGTATGTTTATTACTACTTTTCATTTATATCCTATTCAATTCAATTGAATTGTATTTCTAAAAACACATTATCTTGAAGTAATCTGTTCAGTAAGGTGTTATTTTTAATTTT
->XM_025561023.1 PREDICTED: Sipha flava GTP-binding protein 2 (LOC112688017), mRNA 
-GCTAGTTTTTTCGCGTCCGAAACGGTGCCCGATCGTTGCGAACGTCCCGAAATTGAATTTTATGTTTGTTCGCGATCCGTCAGCGTTTGGGGCCATTCGAGTGTTTTTCGTACCGACGCGGAAAAGCGGAAGCGACGGGAAAAACACCTGTTCGACGACCTTGAAAACCAACATCGTTAGTCATCGATTATTATTGTTTCGTTTCCCGTTGCGGGTCTCCGTCCCGCGATAATGCCTTGATAACGCTTGCCGCTATCTTATCCGCCGCTACTACGACGAGACTTCACTGACCTTTGGCTCTCGTTTTGTTTATAAATATAAGCCCGTCGCCGTACGTTGTTGCCGCCGTCGGCACTCCTCCGTGTCGCTTGGCATCGGTCGCCAACAGATCAACAGCTGTGACCCATCTGTCGAATGATCGTTTCAAGAATCCCGACGATTATCACCGCGCATCGTATACGGCCGTCGACGCTCAACGACGATGGATTCGTTCCTGGACCTGTTCGATCCGGGCACCAGCCCTCCGTCTAATTGCGACGTATGGCCAGCGGAGGACAATGACGATGTCACCGCAAGGCTACCGCCGGAGCCTCAGATGGGCAATGTCGAGTACAAACTGAAGCTGATCAATCCGTCCAAGTTGCGCTTTGAACATCTGGTCACGCAGCTGAAATGGCGGCTCAGAGAGGGTCACGGCGAAGCCATTTATGAAATCGGCGTTGAAGACACAGGCATGCTGACCGGCTTGTCTGCTGAGGATATGAAATCTAGTCTAATCACCTTGGATGAAATGGCCCGTAAATTAGGTGCTACTACGTCGGTGCTGCGAGAGAGATCAGTAAAAAAAGACAAAATGGTTGCTGAAGTTCTAGTTCGAAAGGTTCCAGATGACCAAGAATGTATAGAAGTGATGGTTGCTGTATTAGGAGGTGCTGATGCTGGCAAGTCAACTCTTCTTGGTGTATTAGCACATGGTGAATTTGATAATGGTCGTGGTAGTGCTCGATTAAATGTTTTAAGACATTTACATGAACTACGATCTGGTCGAACTTCTTCCATATCTCATGAGATTCTTGGTTTTGATACTGAGGGAGATGTTATCAACTATCAAAAAGCCCGTACAGCCGAAGAAATTCGAGATCGCTCATCAAAGCTGATCACATTCCTCGATTTAGCTGGACATAAAAAATATCTTAAAACTACTGTAGCTGGTTTGAGCGGTTACTGTCCGCATCATGTTATGTTGGTTGTGAGTAGTCCAGCTGTAACTGTTTCTAGTCCTACTCAATTGGATATGACCAAAGAGCATATGGATTTGGCATTAGCACTTAGACTTCCATTTTGCATTGTTGTTACAAAAACTGATATCACTCCAGCAGATAACACAATTAAATGGTTGGAGTCTATATTGAAATCCATTGGATGCAGAAAAGTTCCTTTTGTTGTTAAATCTGATGATGATGTTTTAACAGCGAGCTCTGCACAGCCAACTCAAAATGTTGTGCCTATATTTACCATTTCTAGTGTTACTGGTGAAGATTTAGACTTACTCACAAAATTTTTATATGTTTTACCACCAAGTATTAGTATAAAAGATAAAGAAAGATTGGAGCAGGAGTGCTGTCAGTTTCAAATAGATGAGATTTTTAAAGTACCTGATATTGGTACAATTGTTGGTGGTGTACTTGTCCAAGGTGTTGTTAATATTGGTACAGAACTAGTTATAGGCCCCTTTGATAATGGAACATTTGTTCCAGTAACTGTGCAATCTATACATAGGAATAAAGCTCCACGTCGAGTTGTAAAAGCAACTCAAAGTGCTTCGTTGAGTTTGGAACAAAGTATTCCTGGATTACGTAATGGAATGGTGCTCTTGGGATCGGGTGTGAATCATAGTGCTTGCATATTCTTCCAAGCTAGAATTGTTGTACTATATCATGCAACATCTATTCATAATGGATTCCAAACCACTGTACATATTGGAAACATACGGCAAACTGCGGCTATTGTTGCTATCATGGAATGTGATAAACGAGGTATGCATACTAATGACACAGCATCAGTAATATTTAAATTTGCACGTCATCCAGAATATGTCACTGAAGGTATGCGGTTATTGTTCAGAGAAGGACAGACTAAAGGAATTGGAATTGTTACTCAAGTATTTGCTTTGCAAGTAGTTGCTGGATAGATAACATTGTTTTTATTGACTTACAACTTTTATTTATATAACCAATAGAGGTAAAATGTACACAGTTACATAATTTAAACTTATAAAAATCACTTTATACACATAAGAATATATATATATATAT
->XM_036413688.2 PREDICTED: Pipistrellus kuhlii TATA-box binding protein associated factor 8 (TAF8), transcript variant X2, mRNA 
-AGAAGCATCACCTGGAGAGGTGAACAACACGTGGTCTCGGCCCCTCCCGCAGACAGCGAGGCACTGATCCTGGGCGGGACCTAGCCAGGTGTTGCTAACAGTCACGTTTGGGGCGCTCCAGGGGGGATGCTCTTTATGAGAAACGATTTCAGGGGGAAAGAGGTGTGCAAGCGAGGACGCATTTCCCGGGCCAATTCCGAGGGTCACAGCAACCCGTCGCTCAGTGTGGGTCACGTGCCCAGGGTCATCAGAACCCCCCATCCCCCGCCTCGGCAGGGCTTTGGAAAACCCAGAGGTGCGAGCGCCGCCTCGCCCCGCCCCTCCCCGCCGGGCGACTACAAATCCCATCCTGCCCTGCGCTCGCGCACGTTACGCCAGAGCAAGATGGCCGACACGACGGCCTCTGCGGGGGCTGGCAGCTCCGGAATGAGATCAGGAAGTAAACAGTCCACTAACCCTGCTGACAATTACCATCTGGCCCGGAGGCGAACCCTGCAAGTGGTTGTGAGCTCCTTGCTGACGGAGGCCGGGTTTGAGAGTGCTGAGAAAGCATCCGTGGAAACACTGACAGAGATGCTTCAGAGCTACATTTCAGAAATTGGGAGGAGTGCCAAGTCTTACTGTGAGCACACAGCCAGGACCCAGCCCACGCTGTCAGACATTGTGGTCACTCTTGTCGAGATGGGTTTCAACGTGGACACTCTCCCTGCTTATGCAAAGCGGTCTCAGAGGATGGTCATTACTGCCCCTCCAGTGACCAATCAGCCGGTGACTCCCAAGGCTCTCACTGCAGGGCAGAATCGACCCCACCCGCCGCACATCCCCAGCCATTTTCCTGAGTTCCCCGACCCGCACACCTACATCAAAACTCCGACGTACCGCGAGCCTGTGTCTGACTACCAGGTCCTGCGGGAGAAGGCTGCATCCCAAAGACGTGACGTGGAGCGGGCGCTCACCCGCTTTATGGCCAAGACGGGCGAGACCCAGAGTCTGTTCAAAGACGACGTCAGCACGTTTCCACTGATTGCTGCCAGACCCTTCACCATCCCCTACCTGACAGCTCTTCTTCCGTCTGAACTGGAGATGCAGCAAATGGAAGAGACGGATTCCTCGGAGCAGGAAGAGCAGACAGACACAGAGAACCTCCCTCTTCATATCAGCACGGATGACTCTGGAGCCGAGAAGGAGAACACCTCTGTCCTGCAGCAGAACTCCTTGTCCGGGAGCCGGAGCGGGGAGGAGAGCCTCATCGATAACCCCTACCTGCGCCCCGTGAAGAAGCCCAAGATCCGCAGGAAGAAGCTGGACTGGGGCATAGGAGCAGCTGGTGACGACCTCATTCATTATCACAGGACCTCATTCCTTTGACCTGAGAGACCAGGGAAGGCAGCAGAAAGAAGGGGCTGTGCCTTCTCTGCTTACTCCAGAAGGACTGTTCACCTCGTTTCTGTTTCAGGCTATCCCGGTCCCTCTTATTGACTCACAGACAATGTGTAGCATCAGTTTATCACTTGCTTTGCCTTGGTGGGAACCTCATTCTTATTTCTCTTCTCACCTGGGCGCCGAGTGCCCTGCTGAGATGACGGAAGGTGACTTTGCCTTCCCACATGGCACTCCTTGACCTGGGCCGGCAGGAGTCGGGAGGGGTGAGCAGGCATGTCACGTGGAGGAGGGTGGTGCATCACAGCACACCAGCTCTCTCATCGCATTTGGTGAACTCTTCCTTCAAGGCAGCGCCCTCTCTGGGGGATTGGTATTTATCGTCCCTCTGTGGAATGTGTGCTTTGGGCCACTGAGTCCTGCCCCGTCCAGGAAAAGAGCTTTCTCTGACAAGAGCCTCTGCAGGATCTATTCTGCTGTGACTTGCTGGAGGAATCCGACCTTAAAGAGCAGGAAAGGGATTGGGGGGGAACGGGGGAGAACTTGAGGGCTGGATGGCCTGTTTGCTGGGAGCCGGGAGCCCGGGGCGTCTGCTGGAAGCCGGCACAGAAGGGCGCCGTGCGTGGAAGCCAGTGGGCCAGGCCACGGAGCTCTCCCAGAAGGTCTGAGTCTGTTCAGCCGCTTTGCATCCTGGGGAGAGATTTCATCCTGCCTGAACCTACAGATCAAAACAAGTGTTTAAGGAAGATGCTGGACAAGCTGATACCCTTTGGCTGGTCTCTGAAAGAAGAGATT
->XM_042281434.1 PREDICTED: Peromyscus maniculatus bairdii phospholipid scramblase 1-like (LOC102915703), transcript variant X4, mRNA 
-TTTGAAACTGTTAACAAATACAAAATCAAGGACAAGCTTGGTCAGAAAGTTTACTACGCAGTCGAAGAGTCCAATTGCTGTGCACGCAATTGCTGTGGGGACTGCAGGTCTTTCTCTATGAGGATTCTTGATAACTCAGATGGAAGTCCAAGCTCCTCCTGGTGTGACAATAGGTTACGTTGTTCAGAACTGGCACCCATGTGTTCCAAAGTTTACAGTTCAAAATGAGAAGAAGCAGGATGTTCTCAAAATTGTCGGTCCATGTATCATATGCAGCCTTGGAGGAAACATTGATTTTAAGATCAAGTCTCTTGATGAAAAAATTGTGGTTGGTAGGATTTCCAAGCGCTGGTCTGGTTTTCTGAAGGAGTTACTGACAGATGTGGACAATTTTGGGATCCAGTTCCCGATAGACCTTGATGTAAAGATAAAGGCTGTGATGCTTGGAGCTTGCTTCCTCATAGACTTCATGTTTTTTGAAAGCAGGCCAAATCAGAAATGAACACTATTATATTCATGAATTGATGAACGAGTCCTCAGAATATGTGAAGCTGGAACACTGATTGAGAATAAAAGGCAACATAGTGATTTCTTTCATTGAAATCACTCATCTCTCCTTGAATTAAACTAGGATGTACATAA
->XM_019798545.2 PREDICTED: Ailuropoda melanoleuca pleckstrin homology domain containing A6 (PLEKHA6), transcript variant X5, mRNA 
-TCCCCCCACCCCTGCGGGCGGGCGGACAGTGGGGGCCGCTGGGCAGGAAGCCCTCCCCCCTCCCCCGCGGCCCGGGGGGCCCGGAGCGAGCGGGGCTTCTGGACGCCGAGATGGCCGATGAGATTGACTGGCTCGACTTGCCCGGCCGGTGGGCCTACGGCGTTGACCGCGGTGGGAGAGTCTTCTTCATCAATGATGAGGAAAAGTCAACCAGCTGGGTGCACCCTAGCACGGACTCCCCCATCCAGAGTGGACACTCCTCCAGCCCAGAATTGCCCAATGGCTGGGAGATGGATTCTACCCAGGAAGGAGCTGTGTATTTCATCAACCACAATGAAAGACGGAATACATTTCTACACCCAGTGACTGGCCAGGTCCCAGAAGAAAACAAAAAATTTAACTTGAAAACATCGGCCTTGGACATGTCCAATAAAGCAGGTGGGAAACAACCGGCTATCACCAACAGTGACGTACCCAACCACAACATGGTGTCTGAGGTCCCCCCAGAGCGGCCCAGCGTCCGGGCAACCCGAACGTCCCGCAAGGCCATCGCCTTTGGGAAGCGCTCACACTCCATGAAGCGAAATCTCAATGCACCTGTCACCAAGGCGGGCTGGCTCTTCAAACAGGCCAGCTCCGGGGTTAAGCAGTGGAACAAGCGCTGGTTCGTCCTGGTCGACCGCTGCCTCTTCTACTATAAAGATGAAAAGGAGGAGAGCATCCTGGGTAGCATCCCCCTCCTGAGCTTCCGGGTGGCCGCGGTGCAGCCTTCGGACAACATCAGCCGAAAACACACCTTTAAGGTGACTGCGTGCTGGGTGGATGAGGCCGGGGCCAGTTCCACGCACTGCCTCTCCCCACAGGCCGAGCATGCCGGGGTCCGCACCTACTTCTTCAGCGCCGAGAGCCCCGAGGAGCAGGAGGCCTGGATCCAGGCCATGGGGGAGGCTGCCCGAGTACAGATCCCCCCAGCCCAGAAGTCCGTGCCCCAAGCTGTGCGTCACAGCCACGAGAAGCCAGACTCTGAGAACATCCCACCTAGCAAACACCACCAACAGCCAACCCACAACAGCCTCCCGAAGCCCGAGCCCGAGGCCAAGACTCGAGGGGAGGGTGATGGCCGGGGCTGCGAGAAGGCCGAGAGGAAGCCCGAGAGGCCCGAAGTCAAGAGCGAGCCTCTGGTGAAAGCCAACGGCATTCAAGCTGGACCGGAACCAGCCTCGGAGCCCGGCAGCCCTTACCCCGAGGGCCCAAGGGTCCCAGGGGGGGGCGATCGGCCCGCTCAGCCCAACGGCTGGCAGTGTAGCTCCCCAAGCCGACCAGCAAGCACAGCTTTCCCGCCTCAGGACTCAGAGAGCGGAGGACACCAGCGGAGCTTCCCCCCACGTGCCAACCCCGACAAAATCGCCCAGCGCAAGAGCTCCATGAACCAGCTTCAGCAGTGGGTGAACCTGCGCCGAGGGGTGCCGCCACCTGACGACCTTCGGAGTCCCTCTAGGTTCTACCCCGTGTCCCGCAGGGTCCCTGAGTATTACGGCCCCTACTCCTCCCAGTACCCAGACGATTACCAGTACTACCCCCCAGGGGTGCGGCCCGACAGCGTCTGCTCGATGCCTGCCTATGATCGGATCAGCCCACCCTGGGCGCTGGAGGACAAGCGCCACTCTTTCCGCAATGGAGGCGGCCCTGCCTTCCAGCTGCGGGAGTGGAAGGAGCCCCCAGGCTATGGGCGGCAGGATGGCACCGTCTGGCTCCCCGGCCCCTCCCCCTCCCGGCAGCCAGTCTATTATGATGAGATGGACGCCACCTCCGGCTCCCTGCGCCGCCTGTCCTTGCAGCCCCGCTCCCACTCTGTGCCCCGCTCGCCCAGCCAGGGCTCCTACAGCCGTGCCCGCATTTACTCCCCCGTCCGCTCACCCAGTGCCCGCTTTGAGCGCCTGCCACCTCGCAGCGAGGACATCTATGCCGACCCTGCTGCCTATGTGATGAGGCGATCCATCAGCTCCCCCAAGTATGATTACCTGGGAGACAGGCGACCAGTCCCTGCAGGACTGTTCCCCTACAACTACCCACCATCCCCCACGGTCCACGATAAGATGGATGAACTTTTAGATCTTCAGTTGCAAAGAAACCTAGAGTATTTGGATCAGCAGATGAGTGAGAGCGAGACTCTCATCAGTATGGTGAACCGCATGGTGGAGAACTCCTCCCCCAGGGCCCAGATCTTCATGCAAGTCCCTCCGTACCCAGAAGTGTTCCGGGACGGTCTCCACACCTACAAGTTAAACGAGCAAGACACAGATAAGCTGCTGGGAAAATTGTGTGAGCAGAACAAGGTGGTGAGGGAGCAGGACCGGCTGGTGCAGCAGCTCCGAGCTGAGAAGGAGAGCCTGGAAAGTGCCTTGATGGGGACCCACCAGGAGCTGGAGATGTTTGGAAACCAGCCCGCCTACCCGGAGAAGCTGCTGCACAAGAAAGAGTCCCTACAGAACCAGCTCATCAACATCCGGGTGGAGCTGTCTCAGGCGAGCACGGCCCTGGCGAACAGCACCGTAGAGTATGAGAGCCTTGAGTCAGAGGTGTCTGCCCTGCATGATGACCTCTGGGAGCAGCTCAATTTGGATGTCCAGAATGAGGTGCTCAACCGGCAAATCCAGAAGGAGATCTGGAGGATCCAGGATGTGATGGAGGGGCTGAGGAAGAATAACCCATCCCGGGGCACAGACACGGCCAAGCACAGAGGAGGACTTGGCCCCACGACCACCTACAGCTCCAACAGCCCCGCCAGCCCTCTCAGCTCCGCCAGTCTCACCAGCCCACTAAGCCCCTTTTCACTGGTATCCGGCTCACAGGGGTCCCCCACCAAGCCTGGGTCCAGTGAGGAGCCCGGTCCGCCGCGGCCCCCCCTCCCCAAAGCCTACGTACCCCTGGAGTCTCCTCCAAACGTGCCGCCGCTCCCTAGCGAGAGCCGCTTCTGGCCCTACCCCAGCTCCCCTTCCTGGCACCGCGGGGGCGAGCCAGCCAGGGGTCAGCCCAAGGCAAGCCATGAGCAGAGCAAGAAAGACACCCCCCAGACGTCACCCCTGGACACTGCTAGAGACATCAGCCTTGTGCCCACCAGGCAAGAGGTGGAGGCAGAGAAGCAGGCAGCTCTCAACAAAGTTGGCGTTGTGCCTCCTCGGACAAAGTCGCCCGCTGATGAAGAGCTAACTCCGTCGAGAGTGGTGAGGAGGAGTGCCAATGGGCTTACCAATGGACTGTCCTCCCGGCAGGAGCGCCCCAAGAGTGCCGTGTTCCCCGGCGAGGGCAAGGTCAAGATGAGCGTGGAGGAGCAGATTGACCGCATGCGGAGGCACCAGAGCGGCTCTATGAAGGAGAAGCGGAGGAGCCTGCAGCTCCCGGCCAGTCCGGCCCCCGACCCCGCTACCCGGCCTGCCTACAAAGTGGTGCGCCGGCACCGTAGCATCCACGAGGTGGACATCTCCAACCTGGAGGCAGCCCTGCGGGCAGAGGAGCCCGGGGGGCAGGCCTATGAGACGCCGAGAGAGGAGATTGCCCGGCTCCGCAAAATGGAGCTGGAGCCCCAGCGCTACGACGTGGACATCAATAAGGAGCTCTCCACGCCCGACAAAGTCCTCATCCCCGAACGGTACATTGACCTGGAGCCCGATACCCCCCTGAGCCCCGAGGAGCTGAAGGAGAAGCAGAAGAAGGTGGAGAGGATCAAGACGCTCCTCGCCAAGTCCAGTATGCAGAACGTGGTGCCTGTCGGCGAGGGGGACCTTGTGGACGTGCCCCAGGACTCAGAGAGCCAGCTTCAGGAGCAGGAGAAGCGGATTGAAATCTCCTGTACCCTGGCGACCGAGGCCTCCCGCAGGGGCCGCATGCTGTCTGTGCAAGCCCTGGCCGAGGCCAACGCTGCGAAGCTTCACAGAGCCACGTTCTGAAGGCCTCCTTCGCCCCCTGAGGTCGCAGTTCCCCACCCTGGCCCCCTGCCCCTGCGCTCCCATGGGCATGCTGCAGGGAGCCAGGCTGGGGGCCGGGGGTGCTGCCAGGACGTTACCTCCGTGTCCACATGCCCACCACGCCCGGCCCTGAAGCCCTCGCTGCTCAGATGGCGACCCTAGGCCGGGGCCTTAGATGGTGGGCAGACAGCAGCCCACATCCCAGGGGCTAGGCCTGGCCCTGGCTGGTGGTGTGACGGCCCTACTGGAACATTCCCAGATGAAGAGGATGCCCTGGTGGGGAAGACGCTCTGGGCTCTCTTAGGTTAGGAGGAGGGTGAGGAGAAGATGGACACTCGGCCTCTTCCGGCCCCTCCTGACACCGAGGACGGCACCTGCCATCAGGTCCTTCCCCCATCGACCCCACCCTGCTGCCCCAGCTGCACCCGGGGCTTTGACATGTCTCTGCTTATGGGTGTTCCTTTGGGGTCCAGTGGAGACTGACCACCCTGCTTGAGCCAAAGACAAGATGACAGGAGCTGGGGAGAGGCACCTCAGCTCCCGGAGGGGACAGTGCTGGCTGTGGGTAGAGAGCGGCACGCAGGTCTGCGCAGCGTCTGAGGACAGGTTGAGAAGGGGGAGAAGAGAGAAAGGGAGAGATGCAGGCAAGTGGGAGGACAGGGGAGCGGCAGGACTCCTTTGCAAGTAAGAGGGTGAGGCGGAGGTGGAAAGGGGCTGTGAGAGGGATGGGTTTCCCCGGGAGGGAACCTTAGCTTAGTGCCAAGTACAGTCCAGACTGTCAGCCCTGCTCCTGCACCGGGTACCCCCGATCCGCGGGCCTGCCCACACACTGGCTCCAGGAGGACCCACCAGCGAGCACATGGTGACCGTCGCTGCAGCCATGGGGACGAAGGTGTGGGGATGCGGGTGTGGGCAAGTAGGTGGGAAGGTGGCCCTTTCTGGGTCTGGGCCTGGTGTCTGCCTCCCCCACCTCGGCTCAGGGGCAGAGAGAGGGACCTGTGTCATGTAGGGTGTTGTCAGCCTTGGGGCCTTTCCTAACCATGTTCGGGACATTTTCTTGTCCCCCTTCTCCCTGGAATGTGCTGTGAGCCAGCTGAGAGAGTGCCCCGGAGAGGAAACACAGCCTTAATCTGGGAGGCTAGATTCTAGGGCCCCATCCCGCGTCCCAGGCATCCCCAAGGAGGACCAGGTGAGGCTGTACGGAAGGACCCCCTTCTGGTCTGGCTCTCTCACCATCTGCCTACCCGGGGAGGCCAGTGAAGGAGACACAGAAGCAAAGCTCACTTTTCCTCCTTGCCTCTCATCTGGGGGGGACGGTAGCCAGGGAGGAGGGAGGGGAGAGAGTGAAGCTGGACACACCGGGGCCCCTAGGCCTTCTCTTTGCCAGAGTTGCTGCCGGGAGACTTCAGCCTCCAGTGGCCCCAAGAACAACTACTTTATCTTCCAGCACTTCTCCACTCCTTCACAGCTGGGCCAGTGAGTGGTTCATATGCAAGTAAAGATGGCAGTTCATTCAACAAATATTTATCGAGCACCTTTTACGTACCAGGCACTGTTCTAGGTGCTTAGGGTATTCTCGTGCTTCTGAGGGCTTGCAGACTGGGGAATTCCTCTTCCCTTTTAGCAGACGTTTGGAACATGGCTACACTTCCCGTCTGTAGCATCACTCAAGCACCCTGTCCCTGTTTCCCCCCCCCACCAGACTGGCAGGTGGGATTGGCCCTCTCCCTCTTTCCAACACCTTTCTCCATCCTCGAGAAATGGCTCTTTCGGGGCCTCCATGCCTTTCCCCTTTGTCTCCCCTTTGTTTTAAGTGATGTTTGTAGACGTACGTGGAAAATACCAAGGGTTAAGGTCTGCATCTCTGCCACGTCTCGCTCTCATCTCATAAAGCTGGCTCTTTATGTTGCTTTACATGCCTTAATATATGTTTTATGAAGATTATACATATTATAGATATATACATAATATATATATTTGTTTGGACGTCTGATCCTTTCCCAGAACTCCTGCCCAGGCCCATTTTCCCTCCTTTACTTTCCACACCATTCCTAGCATGTGTCGGCCACACCCCACGCCTTTTGATCCAAAGAAGGGGAGAGGACGGTCTTATTTTAAGACAGATCTATTTTACGCTTTTGTTACAAAAGCAAATCTATTTTCAAAATGTGCAATGTCTGAATGGAATCAGCAAGTAATACGAGGAGATTGGGCGGCTGCCTCTAGGTCCAACCCTGTGTCCTTCCCTCTCCCCGCCCCCCCGCAGCTTCCTCCTCCCATCCCCCAGTCTGCAAAGGGCTGGTCCCCAGAGCTCACCCAGAGAGCATCTTACCAGGGCGGGACGTTCTCTTAGAAGTCCTGGTCTAAGGATTTGATTACACTGTCAACTCTTGACGGCCCTCTAGGGTTACGGGATGTGAATCCTCTCGAAGGAAATGTTTATAGCTGTGTGCACAAAAATACACCCCTGCGGGCAACCCGCCCCCCAAGTGTACTCCTGGACCACCTCCCGTCACCAATCTGCTGGAAAGGGCAAACAATTTAATGACAGCCTATGCCAAGTGGCACCAAGAACTCCACTCCCTGACGGAGCCAGGATACAGTACAAAGGCCAAAGGAAATGGTTTGGGACCACAGGTCCTTCAGCACAGACACATTTGAGTTCCTTGGACTTCTCACACTCCTTGATCCCTTTCTGGTCTGGGTCACATCTACAACATCTGTCTCCCTCTGTTACCCTTCCTCGGGGGGCTGTTGTTAAGGGGGACGGTTGCTCAGTCTGGCATCCAGACTGCACAGTCAGCTTCTGGGCTGAAGCGGGTCCCACGGATGAGGTGACATCTCAGCCTTGCCCAAGAAGCCCCTAGGACTGTCCTCTGGCGGGCTGCCACCGGGACGCTGAACTCCGCCAGCTCAGCCTTGCAAACTGCTTAGCAGCTGACGTAGTAGGCAAGGGGCTCTTGCCTCACAAGGATCTGGGCAGAATGGAAGTCTTTTGTCCAGATCTGAAATCAAGGGTTTGGGACTGTCACAGAGCTCCTGGCCAGCACTTGAAACCTGACCTCCCAACTTTGACATGTACTGGCGTCCTGTTCCCAGCCTAGAGCGTCTTGTTATGAAAGAATGGGGCCCAGATGGAGGCCCAGGGCTAAGTGACCCAGCGGGGACAGCCCTGGTTGCTATTCTGGGGCCTTGCCAATTAGCACATTACCTCCCTGATCAATAACCAAGAGGCTGTAATCAAATACGGCTACTGTCACTTTAAAGATTTTTCTGAGGTCGCAAGCTGTGCTCACTTGCTCTCCTGCCTTGGTGAGAGGCATGTTCTTGGGGCAGGGCTGACCATAGCAAGACGGAATCGATTCCTTTCCCCTTTAGGCACCCCCTACCTGGCAGCTCTTAAAACTAAGGAAAATACAAAATATACATATATATACATATATCTATTTATGCACATACTGGGGCCAATTTGATCTGCTAGTATTAGACAATAAACCATACAAGGAAATGTATGATCTCAGTGTCTTTATTTAGTATAAAAGTGACCTTAAAAGAAAAGTTAAGGTTAGCTGAACAGAGGGCATCTCTATTGGGGGACCAAACATCTGTAGCCACCCCATAGCATCTTTTTAGCCAACAAGCCCCTACCCAGGAGGGGCATCCTGACTGATAGGTGAGCGCCTGCTTCCCCACTCCCCAGCATTCTTTTCAGATATAGTAGGTACTGAAGAACCCCAGTGAGCTCTGCATTTGTATCTTGCAAGTTTGTATAAACCCGATGCAGGAAATAAAATGAA
->XM_053554548.1 PREDICTED: Nycticebus coucang SH3 and cysteine rich domain 3 (LOC128560913), transcript variant X2, mRNA 
-CCTGTCATTTCAGCTCTGACACCAAGGCAAGAGGCTAGGAGGTCTACAAATATCGTCTAGGTAGCTGGTGTGAGTACAGAGGGTACTGGGGGGGCTTAGCCCCCAAGGAAGAGGACCAATCCTTACCCAGCACCACCATCAAGGCCCCAGGGCCTCCCACTTACTTCCTTCCACAGACTGTGGACTGACTTAGGGAATCCCAAATCTGCAGCGACTGAAGCAGTTATTCAGGAAGGGGTCTACGGGGACAAAGGAGATGGAGATTCCCTCAGAACCCCAGGCCAATGGGGAGGCAGTGGGAGCTGGGGGTGGGCCCATCTATTACATCTATGAGGAAGAGGAGGAAGAAGAAGAGGAAGAGGAACCACCCTCAGAACCTCCTAAGCTTGTCAACGATAAGCCTCACAAATTCAAAGATCACTTCTTCAAAAAGCCAAAGTTCTGTGATGTCTGTGCCCGGATGATTGTTCTCAACAACAAATTTGGGCTTCGCTGTAAGAACTGCAAAACCAACATCCATGAACATTGTCAGTCCTATGTGGAGATGCAGAGATGTTTCGGCAAGATTCCCCCTGGTTTCCGTCGGGCCTATAGCTCGCCACTCTACAGCAATCAGCAGTACGCTTGTGTCAAAGATCTCTCTACTGCCAATCGCAATGACCCTGTGTTTGAAACTCTGCGTACTGGGGTGGTCATGGCAAACAAGGAACGGAAGAAGGGGCAGGCAGATAAAAAAAATCCTCTAGCAGCCATGATGGAGGAGGAGCCAGAATCTGCCAGACCAGAAGGCAGCAAACCCCAGAATGGAAACCCTGAAGGAGATAAGAAGGCTGAGAAGAAGACACTTGATGACAAACACAAGCAGCCTGGCTTCCAGCAGTCTCATTATTTTGTGGCTCTCTATCGCTTCAAAGCCCTGGAGAAGGACGATCTGGATTTTCCGCCCGGAGAGAAGATCACAGTCATTGATGACTCCAATGAGGAGTGGTGGCGGGGGAAAATCGGGGAGAAGGTTGGATTTTTCCCTCCCAATTTTATCATTCGGGTCCGGGCCGGAGAACGCGTGCACCGCGTAACGAGATCCTTCGTGGGGAACCGCGAGATAGGACAGATCACACTCAAGAAAGATCAGATCGTGGTGCAGAAAGGAGACGAAGCCGGCGGCTACGTCAAGGTCTACACCGGCCGCAAGGTGGGGCTGTTCCCCGTGGACTTCCTGGAGGAGATTTAGGCGCTCGCCTGCTGGCGGGAGACACCCACGCCCCCATTCTGGGCGGGCCCAGTGGAGCTTGGGGAGGCAAGGGCAACAGCAACTGGACTGCCGGGTAGGCAGGGGCGGGAAGGCCCGCAAGAGCCTGACGGCTTCTGCGTAGGGGCTGGTTTCCGCCCCTTCCTGACCTAGGGCCTGGGGCCCTGACGCCCAGAGCAGCCGCACAGGCCTCGGACCTAGCCTTCGAGAGCTAGAAAAAGAAAATATCTCACTGGGGGTGGAGGGACGGAGGCACTAACTGTCGAATGTTTCGAATTCACTAAAGTTTTGACAAAAGTTAGAAAAGTTA
->XM_027475688.1 PREDICTED: Abrus precatorius basic 7S globulin (LOC113846927), mRNA 
-AATAAAAATGGTGACATATCCCCGCCCACACAGATGAAGATAGAAGATAAGCACACACAGTGACACGCTTGCCATAAAAAAAGGTAAAAGACTTAGAAGAGAGTGAGCAAGAACCTAGACGCAATTTCATTCTTCTTCAGCAGCAAAACGTACGACCCTCCCAACAACCCTTCTCTTCTCCCATGGCTTCCTTTCCTCTCCTCTTCTCCTTTCTCTTCCTGTCCCTCGTTCATGCTCAATCTTCACTTTCTTTCCACATCCCAGTCACCAAGGACGGTTCAACCCTCCAATACTTGACCACCCTCTCTTACGGAACCCCTCTTGTACCCACCAAACTCGTGCTTGATCTGGGAGGCCCTTTTCTCTGGCTTCATTGTGCATCGAGAAACACCCCTTCATCTTCCACTCTCACTACTCCTCACCGTTCAATTCAGTGCCTCACTGCAAAAACCCACAAACCCGATGACTCATCCTCCTCCTCTTCGTTTCTCTCTAGCCCCGTGGACGAGGACCAGTACCAACCATGCCAAGTTCTCCCAGAAAACAGCATCACAGGCACAGTGGCCACAGAAGGAGAGCTTGTAGAAGACCTCATGGCAGTACAATCATCTCACTTAGAAATCATTCACCAAGTTAGCTTCACCTGTTCCCCCACCAGCATGCTCTTAAACGGCTTAGCAAAGGGTGCTAGAGGCATGGTTGGTCTTGGTAGGTCTCGCAGTTCCCTTCCCTCTCAGGTTTTCGATTCCTTCAGCACACACAGGAAAATCACTCTCTGCCTCTCATCATCAAAAGGGGTTGTCCTCTTCGGCGACATGGCCTATTACGAGTCTTCTCCAGCCGTAACTGAGAGTCTTAAGTCTCTTACATTCACACCCCTTGTTACCAATTTCCCATCTCAGGAATACTTCATCAACGTTAATTCAATCAAAATCAACGGCAAGAGGTTGTCGTTGGACACGTCATCACAGTCCCTCGAGCAAGAGAACAGTGGTGGGGCTCTTACTTTGTTGAGCTCAATTGTACCCTACACCACCATGCAGAGCTCGATCTATGCTACTTTCAAGGCAACTTTTTTGGACGCTGCTGTGGCTTTGAACATGACCATAGTGGCTTCCGTGGCACCCTTTGAGCTTTGCTTTGAGGGCTCGCACGTGGGGGCAAGTGTGCCGGCGATTGAGCTGGTGCTGCAGAGTGAGATGGTGAAGTGGAGCATACATGGGAGAAACTCCATGGTTAGGGTAAGCAGCGAGGTTGTGTGTTTGGGGTTCTTGGATGGAGGTGTCAACCCAAGAAATCCCATCATCATTGGGGGGTATCAATTGGAGGAAGTAATAGTACAGTTTGATTTAGCTACTTCCATGGTGGGGTTTAGTTCTTCCCTTTACACTAAGAACACTGGCTGTTCCCATTTTAGATTCGGTTCCATGCTTGCAGACTCAGTTTGACTATTCGTTATAACTTCGATTATAGTACTGATTATTAAATTTTCTTCTTCAAACTATGTTTCTGAACTTTCTCAATTTTGTACGAGCTTGATTTTTGTGAAGCTTTTTTTGTTTATTTTTTTGGGGGGGGGGGTTTACTATTTAGCTGTACTAATCGAGGCTGATGAGATATTATGATCTTGTATTTTGATGGGACTTCTGCGTCAATTTGAGTTTTATGATATTGGAATACTAGTCGACTTTCAAGATGCTCGATTGAATTGCGAAACCTGAAAAATATCACTGAAAGATTCGTTTCCTTTCCTCCCTCTGTTTGATAAGAAGTGCATCCCACTGGGGAATTTGGACAGTGCCGAAGGAATAATCCTTTATGTACTGCAAAAGAAAAGGGTATGCTCACATAATTTGTTATGTATTTCTTTTTTTCGTTTATTACATCAAGATCTT
->XM_023724909.1 PREDICTED: Trichechus manatus latirostris CKLF like MARVEL transmembrane domain containing 5 (LOC101347816), transcript variant X5, mRNA 
-GGTTTCTTGGACCTTCCTGCTTCTGTCTGCTTCCTCATCCTGCCAGGTTTCAGTTTCCCTTCCAGGCTGCTGGTGGTGGTGTGGGGGGCTGTGCCTGGTGGGTCCCATGGAGATGCTTGGTGCTCGGGACCGCCTGGACTGGCCCCCCGAGGAGGGGACGGCTGCAGGGCTCCAGGCCTTCGCTGTGGACAAGAACTTCCTCTCCTCCCTCAGAGGCATCCTACTGGAAACCGAGCTGGACTTCCTCCGCTGTGTCAGTGCTATCGTCATCTTCCTGGTGATCTCCATCGCTGCTGTGACCTCCCGGGATGGAGCTGCCATTGCTGCTTTTGTTTTTGGCATCATCCTGGTTTCTGTCTTTGCCTATGATATCTTCAAGATCTACCAGACTGAGATGGCACCCAGGGCTACCGAGGCTCTTGGCCCGCAGCTTGTTGACCTGGGACTCAGCGATATCTGCCCGCTCCTCTGCCTCATCCAGCTCGTGCTGCACCTTGCGGAACTTGGAAAGGCATTCCTGGATGGCGAGAATGGTTAAGCACTTGGTTGTTAACTGAAAGGTTGGTGGTTTGAGTTCATCCACAGGCACCTTGGAAGAAAGACCTGGTGAACTACTTCCCAAAAACCAGCCATTGAAAACCCTATGGAGCACAGTTCTACTCTGACACACAAGTTGGAATTGATTTGACAGCAACTGGTTTGGTTTGGTATTTCGTTTTTAACAACAAGCTATGCTTTTAGGATATTCTTTGTTTTGCACTTCTTTTCCTTTTTCTATGAAAATGGGTATGTTCTAGACATTGCAGCTAAAATGACTCAGCTTTGAAGAAAGATTCCAAACAGCAAAGTTCTACTCCTGAACTCTTTAGTAACACGTTTATATGGGAACTATTCCGAGGAAAATGGAAACAACTTTTTTTTACTAGGGCAATATTCTTGAAATGATTGTAGTTGTAGAAAGAATGTATGTTGGGTAAGGAAGAGGGGACCAGGTCAGTGGATGGTGTCATCCCACATATATGTGCTAGATTATGGAACAAAACTCCACAGGGTAGTGCAATAGTTGGTCACAAAAACCCATTGCAGAATATAATTGAAGGGACCATGGTCTCAGGGAACATCTAGCTCAACTGGCATAACACAGTTTATAAAGACAATGTTCTACATTCTACCTTGGTGAATAGCATCT
->XM_006974484.3 PREDICTED: Peromyscus maniculatus bairdii ArfGAP with coiled-coil, ankyrin repeat and PH domains 2 (Acap2), transcript variant X7, mRNA 
-TGGCCGCGGCTGTCACTCCGGGGCGTTTTCCCCGGCCGGCTCTCAGCTGGGGCGGAGGAAGAGGCGGCCTGGGCCTGCCGAGCCGTTGCAGTCTCCGCGGCTGCTATGCCCAGGGTGCGCGGCGCCCTCCGCAGCTCCGCGCAGCGCTAGAGGCGGCCGAGCGCTCGCCGACGCCGCCCGGATCCCCGGTGCCTCCGCTCTCCCGCTCCCGCAGCTCCCGCGGCTCCTCCGGCGTCGCCTGCGAGGCCAGGCAGAGGCAAGATGAAGATGACGGTGGATTTCGAGGAGTGTCTGAAGGACTCGCCCCGCTTCAGGGCTGCCTTGGAAGAAGTAGAGGGAGATGTGGCAGAGCTGGAACTAAAACTCGATAAGCTCGTGAAGCTTTGTATCGCAATGATCGATACCGGCAAAGCCTTTTGTGTGGCAAATAAACAGTTCATGAATGGGATCCGAGACCTGGCACAGTATTCTAGTAATGACGCGGTGGTTGAGACAAGTTTGACCAAGTTTTCTGACAGTCTTCAAGAAATGATAAATTTTCACACAATCCTGTTCGACCAAACGCAGAGATCAATTAAGGCACAGCTTCAGAACTTCGTTAAAGAAGATCTTAGAAAATTCAAAGATGCCAAGAAACAATTTGAAAAAGTCAGCGAAGAAAAGGAAAACGCACTAGTGAAAAACGCCCAAGTTCAAAGGAACAAGCAGCATGAAGTGGAAGAGGCCACAAACATCCTCACGGCCACGAGGAAGTGCTTCCGGCACATAGCCCTGGACTACGTCCTTCAGATTAATGTGCTTCAATCAAAGAGGAGATCAGAAATCCTGAAATCAATGCTGTCCTTCATGTATGCACATCTGGCCTTCTTCCATCAAGGGTATGACCTGTTCAGTGAGCTTGGGCCCTACATGAAAGACCTTGGAGCACAGTTGGATCGACTGGTTGTGGATGCAGCAAAGGAGAAAAGAGAGATGGAGCAGAAACACTCTACTATCCAGCAGAAGGACTTCTCCAGTGATGATTCCAAGCTAGAGTATAATGTAGACGCAGCGAATGGCATTGTCATGGAAGGGTATCTCTTCAAGCGGGCCAGCAATGCCTTCAAAACGTGGAACAGGAAAAAGCCCGATCATATCAGACGCTGGTTCTCCATACAGAACAACCAGTTGGTTTACCAGAAAAAGTTCAAGGACAGCCCCACTGTGGTGGTGGAGGACCTCAGGCTCTGCACCGTGAAGCATTGCGAGGACATAGAGCGGCGCTTCTGCTTCGAGGTCGTCTCTCCAACCAAAAGTTGTATGCTCCAGGCCGATTCGGAAAAGCTTCGCCAGGCCTGGATTAAGGCAGTTCAGACCAGCATTGCCACCGCCTACAGAGAGAAGGGCGATGAGGCCGAGAAGCTGGATAAAAAGTCATCTCCATCAACAGGAAGCCTAGATTCTGGAAATGAGTCAAAAGAGAAGTTACTGAAAGGAGAAAGCGCACTGCAGCGTGTCCAGTGTATCCCTGGCAACAGCAGCTGTTGTGACTGTGGTCTGGCAGACCCACGGTGGGCCAGCATCAACTTGGGCATTACCTTGTGTATTGAGTGCTCTGGGATTCATCGGAGTCTTGGGGTTCATTTTTCGAAAGTACGATCTTTAACTTTAGACACTTGGGAGCCTGAGCTTTTAAAGCTTATGTGTGAATTGGGAAATGATGTTATAAATCGTGTTTATGAAGCTAAACTGGACAAAATGGGAATAAAGAAACCACAGCCAGGACAAAGACAGGAGAAAGAGGCATACATCAGAGCAAAATATGTGGAGAGGAAATTTGTGGATAAATACTCCATGGCATCATCACCTTCTGAGCAGGAGAAAAGGGTTATCTCCAAAAGCTGCGAGGAGCAGAGGCTGAGCCAAGTCAGAGCATCTGTCCACACCGCAGTCAAAAGTAACGACAGTGGGATCCAGCAAGGCTCTGATGATGGACGGGAGTCTCTACCTTCCACCGTGTCAGCCAATAGCTTGTATGAGCCTGAAGGAGAAAGGCAAGAGTCTTCTGTGTTTCTGGACTCGAAACATCTTAATCCAGGACTTCAGCTTTATAGGGCTTCATATGAGAAAAACCTTCCCAAAATGGCTGAGGCTCTGGCTCATGGTGCAGATGTGAACTGGGCTAATTCAGATGAGGACCAAGCGACAGCACTCATCCAGGCTGTTCTGGGGGGCTCTTTGGTGACGTGTGAGTTCCTCTTACAGAATGGTGCTAATGTGAACCAAAGAGACGTCCAAGGGCGGGGCCCGCTGCACCATGCCACTGTCTTAGGACACACAGGGCAGGTATGTTTATTCCTGAAGCGAGGTGCCAATCAACACGCCACTGATGAGGAGGGGAAGGACCCCTTGAGTATTGCTGTGGAAGCAGCCAATGCCGACATAGTGACCTTGTTACGTTTAGCAAGAATGAATGAAGAAATGCGGGAATCAGAAGGACTTTATGGACAGCCAGGTGATGAAACTTACCAGGACATCTTTCGTGATTTTTCTCAAATGGCATCAAATAATCCAGAGAAACTCAATCGTTTCCAGCAAGATTCACAGAAGTTCTGAGCCTTTTAAGAGGGGAAACTATGAAATTTGGTGAATTCCTAATGTGTACAACCAAAATCTCACCCCCCCCCTTTTTTTTTTACTGCTTTAATTCTGCTTGATTTTGGTGGACATTGAATTGTTTGGAAAAAATGGTACCCATTCATTGGTATTTTTGAAAATGAAAACAGATCTTTCATAATTGGGAAAGGGAGAAATCCACTATAGTTCTTCTTTTATTTAAGAAGAAAAAAGCCTATTAATGGGTTGTGCTTTTATATAAAGTTGTATCCAGAGCTGGACCATCCTCTCTTAAGTTCTGAGATGCTACACTGTTAGGCCCCTGCACCCTTTGCCATGGGTGGTACACGGTTCCCCCAGGAACATTGAGTCACTATGCCTGCGTCAGGTGGGAACCAGTTTTCTTACCTGTATCAAGGATGTTTCTTTCCTATAGCTTCCCTGATAGATGCATGTGTGTTTTCTGGTAGCTTCGCTGTGGTACCCACGGTATGTGATGTAATTGCGAGGACTAGTGAGGGTGTTCCTCATTTGCTCGGACAGGCCATCGCACTTGCGGACTTGACAGACATGGCTGCTGCACAGTGGACCACACATTAGTCTTTAGACTCATTTCATCTTACGGTGCAGAGGAGCGCTTCCTTTTTCTTCTGTCAATCTCCACAAGACTCCCAGCTTGCTTTTTATTGTTGGATTGGTTTCCTAAAACCTTGACAGATCATCAGTGCAATAAAACGATTTCAGAGGTTGACTATTACAAAATTGGGCTTTCATCAAAACAGGGTGATTTCAAAGATAATGTAGGGCATTTTTATATTTGGAATTTATCCATTTATATATATATATATATATATAAAATTTATATATATATAAAATTTACTGTTACTCCTGGTGGAAGATGTAAGGAAAAAAAAGCTAATTTTTTTCTGTTTATATTAAAATTTACCAGCAATAAATTCCTTTTATTTTTTTCTACATTTATCTTATTTACTATACAACAGTATACATTCTTTTAAATTGTATCCTGTATATAGCTTTAGAATTAAGTAAAATATGTCATTGACCTTTGAGTTCCAAAATTATGAATATGTGATACAGTTTGGTGAGATTCCATCTCTGATTGACATGTCTTGTCAGAGTATGGAATGAATAAGTAATTACCTTATGGGTCATTTCCAGTACTGTTGATGACGTTCAGTCTTTTAGAAATTATTTGTAAGATACTCAGCTTCACAGAAACATTTTTAAATGTATATAAAATTATAGTTAATTAAATAAAAATTTTTAACATTTTCCCCACAGTATGTAGAGCCTTACTTTGATTGAATATAAAATCAGAATCTAAGCAGAAATCATATGGAAATAAATTCACAGCACAGATAAAGGCCCTGTCGTTCAGTCAGATTGCAAGCATGCAAAGCTTAGTAAGTCCCCACACATTAGGGATACAGAGCTATTGTGATTTGTTTCCAGGGAAGTGCAAACTTCCACAGGATGAGAGGAATTTTGTCTCTCCTGTCTCACCTCAAGCTTGCAGACCATCTGGCCTTGTAGGTATTTTGTTAAAGACAGAAGTCTAACTTTAACTGGCGTGTGTTGTAAAATTTATTGTCCTAAAACATGTTGAGGGAGGACCAGGCTACAGAAGGGCAGAAAGTCCGCCATGTTTCCCTCTGCTGGGCTCATTCTCGGTGACTGCTGGAGCGCCCCCCCCCCCTTGTCTGGAGGTGCTGACGGGCTTCCCTGCGGTCCAGCTGCCAGGAGACTGTCCCCCGGGCCTGCCTGCCTCCCCACCTCGTGTCAGAAGTTCTTGGTGTGGTGGTCAGTAGTGTCTGCTGCCCTTTAATGGCTAGTGTTTTTGAAATAAGCCTTAAAGATTCAGTGTATTTGAAATGCCTTAAAGGTTATTGTGGTTCTGAGTATCGTTAGAAAAAGCTACACCTTTTCGTATTGCATGGAGGCTGGCAATGCAAGAATATATTTCTACAGCTTAATTTCCTCAACGTGCTGAGAAATTGAATAGCAGAAAGGAATGGAATAGAGCAAGGCTTTAAATTCATAGTTACAAAGTAGCTTGGCTTTTAGATGAGTTTTGCTATAATAGCTTATGTGGCCTGTTGTGACGCCTTCTGTGCATTAGGAGAGAGGAGTATACGCAATGCCAGTTGCACACTCAGGCTGCTCTTTCTGATTGCTCTGTTTTCTCTCCAGGACAGACATGCTGAAAATAGTGTGATTCTTTATTATTAGTCTGTTCACTCTTTTTCATGCTCTCAGTAATGTCAAAATTGTATTACTGCCAAGAGAAGAATAGGGGTGCTATGAAGATTCAGAAAATGCAGGCGTAACATGGGCATAGATAAAGGTGATTGAGTAGCCGTTCACCAGGCCTCATTGCAACACTTACATGTTTAAGATTTCCAAGATTTCCAATTTATTTTTATTCATTTTTAAAAGTTTCCAGCATTCCAGTGTGCTTGACTAATTGATGCTGGTGTTTGCTGTAGTGGAGTGAACTTTGGTGTTACTGCCCCCAAAGTAATCCAGCTTGCAACTTGTACTTTAGAACGTCATAGGTGCATTTTTGGGGAAAAAAATTATACATTCACATTTTAGAGAATTTAAGTTTGTGATCATGTTAGCAGTATTTAAAAATAAAAATTCCTGCATATTAGATATGATCATAAACCAAGTTGTTTTATTTAAAACTAAACTCGCTACCCACTTGGAATAATTGAACATTCCTAGACCACTCATTCTCAAATTTTTTTGTGTGGTTGCATTTTGACCATGGCTAGAATTTTTTAAAATGAAATCTTATGTCCATAATAACTTCAGTTTATATCCTTCTTGGATCCAGGGCTCCTCACAAGTGAAAGGATGAAACAAAGGGAAACTCTAAAAGCTCCCCTCGTGTGTGTTTCATGACTTAGAGTGTTCTTCACACTACCTTTCCTCACCTGCTGCTTACAGGACTCCTAGATCCTAACCACGAGCATCAGCCTCGTCCGTCCGTGTCTCCATCCGAGCCCACTCCTCTCGTTTTACAGAGAGCGTCACTTCCTTTGCTAGTTGGAGGCCGAGCTGACCCAGGTCTGCCATAGCTTCGAAGCACTTGTATCATGGAAGGATTTGAAATCGCCGTAATGTAAAGCAGCAGCTTTCCCTGTGTTTGATAAGAAACTCCAAATACTCTGGAGAACCTCATGATGAAGTTTGAGGGACTAGATTGGGATTTGAAAGCATCAAATTGTAGAAAAGTCTCCAGATTTTACAATAGCAAACATTAATAAAAGCAAAGTATTATAAAGTTAAACTCACCATTTATTAACTTTTTGATGTTTTCAAATGAAACATAACCATGGAAGGGACTTGGATTCAGTTTGGCTGAGTCCTAACACCTAGAAGGATGATTTTTGTGGGCGTCTTTTCCTGTTTACATAGAGGGGGATCATGTGGACAAAGAGAGATGGAATGAAATACAAATTTTCTTTGCATTGCTGTTCTCACTATCTTATTTTCTAGATTTTTCTCATTCTCCAGTTTTATTTTGGGTTATTAATTTTTAACAGGGAAAGCTTGCTGCAGTATCAAGGTTGTTAGCACCATTTAATACGAAGGCTAAAGGTTAACTTTTGGAAATGACCAGCTCCTTTTTAAATATCTGTTTACGTGCGCTTTGTGATATTTCTGGATCATTCCGGTCATAAAGACTGATCACGTGTACTATTTCTTGCTACCTGTGAAAAGGGTTTTAAGAATGTATAACCAACACTCCATTAGTTTTTATTAGTGTGTAGAAGATTTGTATCTAATTCATGAATGTAGTTTTACTGTAGTTTGTCATTGTAAATGGAGCAAAGTACATTATCTTTATAGTTCTTCTAAAATGTACATTATGTAAGAATTGTAAATATACTTGATTACTTTGTATGCTGAAAATTTACAATAATAAGTCAATAAAAATATCTCACTTCTGGCACA
->XM_038145225.1 PREDICTED: Motacilla alba alba chromosome 9 C2orf72 homolog (C9H2orf72), transcript variant X3, mRNA 
-TCTCGCCCCGCTGCCCCGGGGTGTTGCTCTTCGCGGGGCCGGGGCTGGTGCAGGGTGGCGGGGCGGGTGCGGGCCAGTGGGCGGTGCGGAGCCGGGGCCGGGGAACATGCGGATGCAGGCCGGACAGGGAGCACGGCGGGGGATGGCGGCGGCAGACCTGCAGGAGCTCCGGGCGCTGGTGGAGCGGGCGGGCGGGCGGCGGGCGGTACTGCTGGTGGCCGAGGTGGCGGAGGGGGCCCCGGCGGCGCCCGCGCTGGCCGCCTTCGCCCGCGACCTCCTGGACGACGAGGCGCCGCGCGCAGCGTGCCCGGGGCCGGCGCCGGTGCCGGGGTGCCGGGAGAGGCGGTCGCCAGGCGCCGGGCGCCGGGCGCTGGGAGCGCGGCTGCTGCTGGTGCTGTGCGGCGGCGGGGCGGCGCGGGACCGCGGGGCGCGTACTCGCCTGCGGGAGATGGTGCGGGACGTGCGCGGCCGCCTTCCCGCGGGACCGCCGCCCGCCGTCGTGGGCGTCCTGCTGCCCGGCGGGGACGGAGAGGACGCGGCGGTGCTGGACGCCGCGCTGCGGCGGCACTTCCCGGCGCCCGGCACGGTGCAGGCGGCCCGGTACAACCCGGGCAGCCCAGGCGACTGCCGAGCCGCAGCCTGCCGCGCCCTGCGGGCTGCCCTGCAGCACCCCGCAGAAGACATGAAAGACAGGGAGAGGTGGAGGCTGCCATCCTTCCTGCAGTGCATTTCTTGGAACCAGGGGAGCTGGAGAAAAGATTACAAAGTGAAAGCTGAAAACAACATTCATGAAGGTCTGCCTTGACCTCTCTCTGCTCCCTGCAGATGACCTGCAGGACCCTGAGGAAGAAGTGGCTCTGGCCAGCCTTTCCCCCAGTGGAAACTGTGAAGAAGCTGCTGAAGGCACAGGCACCTAGAGCTGCTGGGCATCCAACACAGTCCACATCCCAGACCTGCCCAGTGGATTTGGAGCAATGGGAGGAGGAGCTGGTGCAGGCCCTCTCCTCCAAGGACCCACAGCTCCAGGGAAAAGCTGCTTGGCTGAACTTGTCAGGGTATTTTTAGCTGCCACCAACACAGAGGGTCTGTGCCAGAGAGCCATTCCCTGCTGCCCCGGGGCACTTGGAGCTGCTGCTGGACACTGGGCTTCTGAGAAGCCCTTTGGGGATGTACCCCACATCCCGGGCAATATGACATTGGGACTTTGAGTGTGAAATGCAGCCACCTGTTTGAAGAATGAGAAATGTTTTCAACTTCTGAGCAAAGTTCCCTGCTGAGGTTGCTGGGACCGGCCTCCCTGGCAGACTGATTCTGCTGCCTTGTTTTCCTACTTTATTGGTGCTTGGAATTTCCCACCCTCTTTGCCGTTAAAAACCAAACCAAACCAAACCAGAACAAAACAAAACAAAAAAACAAACAAAAAAACCCCCACAAAAGAACCCACAAAAAACCCCCAACGAAGTAATACAGCAGCTTGGAGACTGCAGTAGGACTAAATGTGAGTGCCGGGATCTACCAGCTACTGAAAAGGCATGAATGTAACAGTGTAACAAGAAGAATGCAGTAACAGCCCAGCTTGAGTGGCAAGAATAACATGAAAGATACTGATAGTACTGGCATCTGGACCAGAGTGGGGTTCGGGAGCGGGATCTGTCCCTCTGGCTTGTCCCGGTGCTCATAGGCTAACTGAGGGATGCCTGGGTTGGAGGGGTGGCGGGTGGGCTCTAAGGTGTGGCTGCTGCTAGATGGGGCTACAGGAGAGAGCCATCTTACCTGGGAGATCTCCACAGGCATGGTGGCACAGTTTGGAGGTGGCCTGCAGCACAACAAGAGGTGGCTGTTTCATAAATAAACATAAAAATATAAAAAAATATATTTAAGTAGTTCCAAAGGGTTGCCGGTAGCCTGTGGGGCAACACAACTAACCAGAAATCATTGGTTTACAAGGAATATTACTTTAATGTTAAAAATATATTTTTAATTCTTTATGCAACATCAAAGAGGTCTAGTTTTATTTTGAGCACAAGCCTGGCTTTCCTTTAGGAGTTTCCTCCAGCTCAGATCAGAAATTTCAACCTGCCTGCCTCTACTTTGGGTGAATTGCCAAAGTGCATCCTCTGTGCATGTCTGTCCTCTCTCTGGCTCCTTCTTCCCCACTGGCAGCAGAAGTGTCTGGAGTCCTGCCAGCTCTGGCCAGCACTCTACCCCAGCAGTTTGCCTTTGGCATCCCTCTAGCTCTTACCTGGAGCAGGGGATGCTGCTCTGCAGAGAGGGCACTGACCCGCTCTCCTTCCAGCCTCCAGGATTTCTGGAGAAATGACCTGTGGAAAACACAAATGTAACCAAGTGGCTCGCTGTGGGTGGCTGTGTCACTGGCCCAAATGTCAGCACTGAGCACTCAGTGCATCTTGGTGAGATTAAGGCTCCCTCCTGCTCCATCCCTGCATGGCCCAGGTGGCTGTGCAGGTCTGTATTTCCCAGCAAAGCCCTTGGTTAGGTGGGTCAAGCAGGACTCACCAGCAGGAATCTTTATTTTCTTGCAGCATTTAGCCTTTGCTGCTAAGCATTCTCCAATGAAGAGGTGATCCAAGAGCACAGACTGGCAGTTAAACCTCCCTTAGTGCTGCAAATCCACTGGATTTATTTACTGGTAATTTTGAGGTAAATCATGCAAGTTTATCCCTGCAAGAGACTGCTGGAAGTGGATGAACTGCCTGGGCCTTAGGCAGTGTGAGTGAGAATATATTTGACCAAAAGTATTGTTTTTCTTTCACTGAGGAATAAAAGTGACTTGAATTACTTTTTTTTTTTCCCTTTTCTCTTTTCACTATCTGTGCACTTGGAGGTGTAAGCAGATAGTTTTACGTGTTTAATTAATTGAATAATTTAAGGGCACTATCACATGCTTGTAAAATAAAGACACTTTCCAAATTGGAATGTGCTTATTTGTTTGCCATGGTGTTATCCTTGAAGCAGCATTATGTATAGCTTAACTCATATTTATCTTGGCTTGAGAAAAATGGATATTGGGATGGAATGGAAGTGACCCCAGTGTTTGAAATGCAGAAGATCAGAACTGAGTGCAGTCCAGGTGGAGCAATGGAGAAGGCTGGACATCTTCCCAGTTGTCCAAGAGCAGGGCAGTCCCTCTTGGCATTGTGGGTCGGAGTTTGATAAGCTTTCATTAGTAACTTTCATTAATAACTTTCACTAACTGATACCATTATGCATCCTCAAGGAATTCAATATATACCCTTCATAGGGTATTTCTTCCTAGTCAGTAGCATCAAGGAGAAATGAATGCTGCCGAGGTCTGGGCACTTCAGTCTCTTGTTGCTCATCGTTGCTCCTGAGCTGGACTTTCCCTGGTGCAAATCCACCACCCTGGGTATCCCATCCGTCTTGTGCCGCAGAGGCGGCCGGCACGTGTTAAACCCATGGGATAAAATCGCTGATCCTTGCCCTGCCCTGGGACACGCTATGCCCCTACAGATGCCCACCCCCTGCGGGCGGCCTGTGCCGGCGGGGGAAGCAGCCGCTTCTCTGGGCACGGCACAAACGCGGGCACCGGCGGGGTCACTCGTGGGGAGCTCACAGCCGCGGTCCCGCTCGCGCCGGCAGCGGTGTGGGGTCTGCGGGCGCGGGAGCCCGCGGGGGCAGCGGGGGAGCCCCGGGAGGCCGCGGGGGAGCCCCGGGAGGCCGCGGGGGAGCCGGGCAG
->XM_030524043.1 PREDICTED: Scaptodrosophila lebanonensis synaptic vesicle glycoprotein 2C-like (LOC115628070), transcript variant X7, mRNA 
-ATAGTTCAATTATTGAATGTGTTGTACATATTTAAAAGTGCTTAAAAATATAGAAAAACTATGTTCTGAAAAAACACCTCTTTCAAGTAGTAAAAAGTGGAAAGAGAGAAATCATTCTAAATGGGTGTAATATATAGTGTACAACCAGAATTGTGATATAGTGCCTTAATGATAAAAAGCATTGACATTCAACTTGGAAGTTTGCGATGTTTCAAGGCATGCATATGTCTTGACTTTTTGGAGGATTTAGGAAGCGACTATGAAGATGCACTTCTACAAGCTGAATTTGGAAAATTTCATTTTCTTTTACTTACGATATGTGGTCTTATATACCTAAACACAGCAATAGGAATAACTATAATATCATTTGTTCTTCCCACTGCAACTTGCGATTTTGATATGACGTCTAAAGATAAAGGCTGGCTATCTGCTTCTCCAATGCTGGGAATGCTGATAGGATCATATTTTTGGGGATGTCTCGCAGATACAAAAGGTCGACGCATTGTATTAATTGTAACTCTCTTAGCAGACGGTATATGTGGATTGGTATCATCACTTGCACCTTATTACCTCATATTCCTGTTTATTCGTTTTGCGAATGGTTTCAATGTGGCTGGAACAATGGGCATTGTGTTTCCTTACTTGGGAGAGTTTCAACCAACGAAGTACAGAGAAAAAATTTTATGCTGGATGGAGCTTTTTTGGACATTTGGAATCATTTTACTTCCAGGAATCGCGTGGAGTGTAATTCCATTGCAAATAAATCTCCAATTTAGTGTTTTTACTTACCACAGTTGGAATCTCTTTGTTGCAATATGCGCAATACCCAGTATTTTGCTGGGTCTTTGGCTTTTTTCATTTCCGGAAAGCCCAAAATTTCTATTAGAGCATGGGGAAACAGACAAAGCGCTGGATATTCTCGTTTGCATGTTTATACAGAACACTGGACGTAAACGTGATGACTACCCTGTAAGACAAGCAAAAACTCTAAATAAGCTAATGTAAGAGTCTACGTGGCCCAGACCGTTCTAATAAGAAAAATGGCGAAAAGGGAATTCCTAACCTTCGATTTAGAAGACCGAATGAGTTAAAGATATTAATATCGGAAATTTGGACACAAACTAAAACGCTTTCC
->XM_040248511.1 PREDICTED: Oryx dammah pre-mRNA processing factor 18 (PRPF18), transcript variant X3, mRNA 
-TTGCAAAAAAAGAAGAGGAAGCATATTTTGAAAGATGTGGCTACAAGCCTATAAATGAGAAGCCACCTGGAGAGAGCAAGGATCAAATAACCCTGTAAGATGATTTTCTCAAAGAGGAGAAGCAAGCTGATTGTTTCCAAGAAGAAAGTAAAAATCTTGGAGTCTAGGGAGAAAATACAGCCAAAAGATGAAGACCAGAAACCATTAACTTCATCGAATCCAGTATTAGAACTTGAACTGGCAGAGGAAAAATTACCCATGACTCTTTCTAGGCAAGAGGTTATCAGAAGATTGAGAGAAAGAGGAGAACCAATCAGACTATTTGGAGAAACAGATTATGATGCTTTTCAACGTTTAAGAAAAATAGAGATCCTCACACCGGAGGTTAACAAGGGATTGAGGAATGATCTGAAAGCAGCTTTGGATAAGATTGATCAGCAGTACCTCAATGAACTTGTGGGTGGCCAAGAGCCTGGAGAAGAAGACACCCAGAATGATTTGAAAGTTCACGAAGAGAACACCACAATTGAAGAATTAGAGGCTCTGGGAGAGTCTTTAGGAAAAGGTGATGATCATAAAGACATGGACATCATTACCAAATTCCTTAAGTTTCTTCTTGGTGTTTGGGCTAAAGAGCTGAATGCCAGAGAGGATTATGTGAAGCGCAGTGTGCAGGGTAAACTGAACAGTGCTACTCAGAAACAGACTGAGTCCTATCTCAGACCCCTTTTCAGAAAGCTACGGAAGAGGAATCTTCCTGCTGATATTAAAGAATCCATAACAGATATTATTAAATTCATGTTGCAGAGGGAATACGTGAAGGCTAACGATGCCTATCTTCAGATGGCCATTGGAAACGCCCCTTGGCCCATTGGTGTTACTATGGTTGGCATCCATGCCAGAACTGGCAGGGAAAAGATTTTTTCCAAGCACGTTGCACATGTTTTAAATGATGAGACGCAGCGGAAATATATTCAGGGACTGAAGAGGTTAATGACCATTTGCCAGAAGCACTTTCCTACAGATCCATCAAAATGTGTGGAGTACAATGCACTATGAGATCTGTGTGCGGTGTGTAAATATCAAGAGAAACTTAAGGAAGCCTGTCACGGACTTCTGGAATTACCACCAGTTGCAATGAGGGAAGAAGAAAAAAGGAGTTTGTGGTCTCTGAGTTCTACCTAATGCAGCTCTTGGTTTTAAGAACGTGTGTTGGCTCTCATGTCACATCTGACTACAGAGTGATTTTTGTGTCTTACTTTTTAAGTAGTCAAAAAATTAAGTACTAAAGACTTTCCCCAGTAATTTAAATGTGTAAATTTAAAACAGTCACAGGACACGGTTTAAAATAACTTTTCCCCTCTAGACCTAAAAGTTGAAATGAGAGGATTAAAGAGGAACATTTGAGGATGGACTTAATGATTTCTATAAAATATGGTAATTTTCATGTTGCCTTTTATGTTGTGTTTATAGAGAAATATTTTTATATTTTTCAACAAAAATATGGAACTATTTAGTGAAACTTGATCATCCTTAAATGTTGCTTGACTTTTGCCACCTTGCAATATATTTGAATGTAAATGTTTTTACTATTGTCTATCTTGCATTTTAAAGCTTTTATCCTTTAAAGATA
->XM_027406478.2 PREDICTED: Cricetulus griseus probable global transcription activator SNF2L2 (LOC100770307), transcript variant X12, mRNA 
-GGGCGGAGCCCGAGTTTAGGAAGAGGAGGGGACGGCTGTCATCAATGAAGTCATATTCATAATCTAGTCCTCGCTCCCTCTGTTGCTGTACTCTGGGTGACTCAGAGAGGGAAGATTCAGCCAGCACACTGCTCGCGAGCAAGTTTAGTGATACTCTGCTGACTGGCAGAGCCAGGAGAAGTAGATGTCCACACCCACAGACCCAGCTGCAATGCCCCATCCTGGGCCTTCCCCGGGGCCTGGACCCTCTCCTGGACCAATTCTGGGGCCCAGTCCAGGACCAGGACCATCCCCAGGTTCGGTCCACAGCATGATGGGGCCCAGTCCTGGACCGCCCAGTGTCTCACATCCTATGTCAACAATGGGCTCTGCAGACTTTCCACAGGAAGCCATACACCAGATGCATAAGCCCATGGACGGGATACATGACAAGGGAATTATAGACGATGCCCACTGTGGATCCATGAAGGGCGCCAGCATGCGCCCACCACACCCGGGAATGGGCCCTCCACAGAGCCCAATGGATCAGCACAGCCAAGGTTATATGTCACCACATCCTTCTCCTTTGGGAGCCCCAGAGCACGTCTCCAGCCCTATATCTGGAGGAGGCCCAACCCCACCCCAGATGCCACCGAGCCAGCCAGGGCCACTCATCCCAGGAGATCTGCAGGCCATGAACCAGCCTAACAGAGGTCCTTCGCCTTTCAGTCCTGTCCAGCTGCATCAGCTTCGAGCTCAGATTTTAGCTTACAAAATGTTGGCCAGGGGCCAGCCCCTCCCTGAAACCCTGCAGCTTGCAGTCCAGGGGAAAAGGACCTTGCCTGGCATGCAACAGCAACAGCAGCAGCAGCAGCAGCAGCAACAGCAACAGCAGCCCCAGCAGCCTCAGCAGCAGCCCCAGCAGCCTCAGCAGCAGGCGCAGCCACAACCGCAGCAGCAGCAGCCTGCCCTTGTTAGCTACAACAGACCATCTGGCCCTGGGCAAGAGATGCTGATGAGTGGCCAAAGCACCCCACAGAAGCTGTCAGCACCGGCACCCAGCGGCCGGCCGTCGCCCGCACCCCCAGCCGCTGCCCAGCCCACCGCCACAGCTGTGCCCGGGCCCTCGGTGCAGCAGCCTGCCCCAGGGCAGCCGTCTCCGGTCCTGCAGCTGCAACAGAAGCAGAGCCGTATCAGCCCAATCCAGAAACCGCAAGGCCTCGACCCCGTGGAGATCCTGCAGGAGCGAGAGTACAGACTGCAGGCTCGCATAGCTCATAGGATACAAGAACTGGAAAGTCTGCCTGGCTCTTTGCCACCAGATTTACGAACCAAAGCAACTGTGGAACTGAAAGCACTTCGGTTACTCAATTTCCAGCGTCAGCTGAGACAGGAGGTGGTGGCCTGCATGCGGAGGGATACCACCCTGGAGACGGCCCTCAACTCCAAAGCATACAAGCGGAGCAAGCGCCAGACCCTTCGAGAGGCGCGCATGACGGAGAAACTGGAGAAGCAGCAGAAGATAGAACAGGAGAGGAAACGGAGGCAGAAGCACCAGGAATACCTGAACAGTATTTTGCAACATGCAAAAGATTTTAAGGAGTATCACCGGTCTGTGGCTGGGAAGATCCAGAAGCTGTCCAAAGCAGTGGCGACTTGGCATGCTAACACTGAAAGGGAGCAAAAGAAGGAAACAGAGCGGATCGAGAAGGAGAGAATGCGGAGGCTGATGGCTGAAGATGAGGAGGGCTACAGGAAACTCATTGACCAAAAGAAAGACAGACGCTTAGCATACCTTTTGCAGCAGACCGATGAGTATGTGGCCAATCTGACCAACCTGGTTTGGGAGCACAAGCAGGCCCAAGCTGCCAAAGAGAAGAAGAAGAGGAGGAGGAGGAGAAAGAAGGCTGAAGAGAATGCAGAGGGAGGGGAGTCTGCCCTGGGACCCGATGGAGAGCCCATTGATGAAAGCAGCCAGATGAGTGACCTGCCCGTCAAAGTGACGCACACAGAAACTGGCAAGGTCCTCTTTGGTCCTGAAGCACCCAAAGCAAGTCAGTTGGATGCCTGGCTGGAGATGAATCCTGGGTATGAAGTTGCTCCCAGATCTGACAGCGAAGAGAGTGACTCTGATTATGAGGAAGAGGATGAAGAAGAAGAGTCCAGTAGGCAGGAAACGGAGGAGAAGATACTGCTGGATCCAAACAGTGAAGAAGTTTCCGAAAAGGACGCCAAGCAGATCATTGAGACTGCGAAACAGGATGTGGACGATGAATACAGCATGCAGTACAGTGCCAGAGGGTCGCAGTCCTACTACACGGTGGCCCATGCCATCTCCGAGAGGGTAGAGAAGCAGTCTGCCCTCCTCATTAATGGGACCCTAAAGCATTACCAGCTCCAGGGCCTGGAATGGATGGTTTCCCTGTATAATAACAATTTGAATGGAATCTTAGCTGATGAAATGGGGCTAGGCAAGACCATCCAGACCATTGCACTCATCACATATCTGATGGAGCACAAAAGACTCAATGGCCCCTATCTCATCATTGTTCCCCTCTCGACTCTGTCTAACTGGACATATGAATTTGACAAATGGGCTCCTTCTGTGGTGAAAATTTCTTACAAGGGTACCCCTGCCATGCGACGCTCCCTTGTTCCCCAGCTACGGAGTGGCAAATTCAATGTCCTCCTGACTACTTATGAATACATTATAAAAGACAAGCACATTCTTGCAAAGATTCGGTGGAAATACATGATTGTGGATGAAGGCCACCGAATGAAGAATCACCATTGCAAGCTGACTCAGGTCTTGAACACACACTATGTCGCCCCCAGAAGGATCCTTTTGACTGGGACCCCGCTACAGAATAAGCTCCCTGAACTCTGGGCCCTCCTCAACTTCCTTCTCCCTACAATCTTCAAGAGTTGCAGCACATTTGAGCAGTGGTTTAATGCTCCATTTGCCATGACTGGCGAAAGGGTGGACTTAAATGAAGAAGAAACTATCTTGATCATCAGGCGTCTGCACAAGGTGTTGAGACCCTTTTTACTGAGGAGACTGAAGAAAGAGGTTGAATCCCAGCTTCCAGAAAAGGTTGAGTATGTGATCAAGTGCGACATGTCAGCTCTGCAGAAGATTCTGTATCGTCATATGCAGGCCAAGGGGATCCTCCTCACTGACGGTTCTGAAAAAGATAAGAAGGGGAAAGGAGGTGCCAAGACGCTTATGAACACTATCATGCAGCTGAGAAAAATTTGCAACCACCCATATATGTTCCAGCACATTGAGGAATCCTTTGCTGAACACCTGGGCTATTCAAATGGGGTCATCAATGGGGCTGAGCTGTATCGGGCCTCAGGAAAGTTTGAGCTACTTGATCGTATTCTGCCCAAATTGAGAGCAACTAACCACCGCGTGCTGCTTTTCTGCCAGATGACGTCTCTCATGACCATCATGGAGGATTACTTTGCTTTTCGGAACTTCCTTTACCTGCGCCTTGATGGCACCACCAAGTCTGAAGATCGGGCTGCTTTGCTGAAGAAATTCAATGAACCTGGGTCCCAGTATTTCATTTTCTTGCTGAGTACACGAGCTGGGGGCCTGGGCTTAAATCTTCAGGCTGCGGACACAGTGGTCATCTTTGACAGCGACTGGAATCCTCATCAGGATCTGCAGGCCCAAGATCGAGCTCACCGCATTGGCCAACAGAATGAAGTCCGGGTTCTGAGGCTCTGCACTGTCAACAGTGTGGAGGAAAAGATTCTCGCAGCTGCAAAGTACAAGCTGAATGTGGACCAGAAGGTTATCCAGGCGGGCATGTTTGATCAGAAGTCCTCCAGCCACGAGCGGAGAGCATTCCTGCAGGCCATATTGGAGCATGAAGAGGAGAATGAGGAAGAAGATGAAGTACCAGACGACGAGACCCTGAACCAGATGATTGCTCGCCGGGAAGAAGAGTTTGATCTTTTTATGCGCATGGACATGGACCGGAGGAGGGAGGATGCCAGAAACCCAAAGCGCAAGCCTCGCCTGATGGAGGAAGATGAGCTGCCCTCCTGGATTATTAAGGATGACGCGGAAGTGGAAAGGCTTACCTGTGAAGAAGAGGAGGAGAAGATATTTGGTAGGGGTTCTCGCCAGCGCCGGGATGTGGACTACAGCGACGCCCTCACCGAGAAGCAGTGGCTCCGGGCCATCGAAGACGGCAATTTGGAAGAAATGGAGGAGGAAGTACGGCTCAAGAAGAGAAAAAGACGAAGAAATGTGGAGAAAGATCCTGTGAAGGAGGATGTGGAAAAGGCGAAGAAAAGAAGAGGCCGCCCTCCAGCTGAGAAACTGTCACCAAACCCCCCCAAACTAACCAAGCAGATGAACGCCATCATCGATACTGTGATAAACTACAAAGATAGTTCAGGGCGACAGCTCAGTGAAGTCTTCATTCAGTTACCTTCCAGGAAAGAGTTACCAGAATACTATGAATTAATTAGGAAGCCAGTGGATTTCAAAAAGATAAAGGAAAGAATTCGTAATCACAAGTACCGGAGCCTGGGTGACCTGGAGAAAGATGTCATGCTTCTCTGTCACAATGCACAGACATTCAACTTGGAGGGATCCCAGATCTATGAAGACTCCATTGTCCTACAGTCAGTATTTAAGAGTGCTCGGCAGAAAATCGCCAAAGAAGAGGAGAGTGAGGAAGAAAGCAATGAAGAGGAGGAGGAAGATGATGAAGAGGAGTCTGAGTCAGAGGGTAAGACCCTGCATCTGGCCCCTTCCACCTATCGGGCTATTTCCACAGCCAAATCTGTGAAGGTGAAAATCAAACTCAATAAAAAAGAAGAGAAAGGCCGGGACACAGGGAAAGGCAAGAAAAGGCCAAACCGAGGCAAAGCCAAACCTGTTGTGAGCGATTTTGACAGTGACGAGGAACAGGATGAGAACGAACAGTCAGAGGCAAGTGGGACTGATGATGAGTGAGCAGTGTGGACTTGATCTGACTGTGGCAGAACTGAACACTTTCTCCCCCTTTCTCCCTTCACCCCCAGTGAGTTCATTTGCCCTTTGGGCACTGGGTTATTCCTCCGTCCTCATTGTCATCTAGAGCTAGCTTTAGGATAGTGCCAGACAAACATATGATATCATGGTGTAAAAAAAACAAAACATGCATCTACACACACACACACACACACACACACACACACACACACGAATATTTGTAACATATTGTGACCAAATGGGCCTCAAAGATTCAAAGATTAAAAACAAACAAAAGCTTTTGATGGAAAAGACGTGGGTGGATAGTATATTTCTACAGGTGGGTCAAATTTGGTAGCCGTTTGATGTGCTTGCTTCCATCATCTATCCTGATGAGGAGATTTTTATCTTCTACAGCGCTGATGACCGGGAGAAGCCATTAAAAGCCACTGGTTATTTTATTTTTCATCAGGCAATTTTCAAAATTTTCATTTGTTCGGTATTGTTTTCTTGTTTGTTTGTTTTTTACACTGTGGTACATATAAGCAACTTTACTAGGTGACAGATGTACAGTAGTTAGAAATCACCTACATATACATTTTTCCATTTTATGCTCTATGATCTGAAGAACAAACAAAAAAAAAGCTTTTTGACTTGTATAAGATTTATGTCTACTGTAAACATTGCGGAATTTTTTTTTCCCTTTGGCTCTTGTTTTATTGACGCTATTGACTATTACAGTGTCTAGAGTGTCCCGATGGCTTCTTTTGTCCACCTGAGCTCCTGTGTTACCAATGGGTATGGTCTCCTTCTCCCTAAAGTGTACTTAATCTTTGCTTTCTTTGCACAATGTCTTTGGTTGCAAGTCATAAGCCTGAGGCAAATAAAATTCCAGTAATTTCGAAGGATGTGGTGTTGGTACTTTCCTAATAAACCGATAACTTACCTTGA
->XM_016163448.2 PREDICTED: Rousettus aegyptiacus junctional sarcoplasmic reticulum protein 1 (JSRP1), transcript variant X3, mRNA 
-AAATATCGAGCCTCTTACCACATTCATTGTCATTTTCAAGCCTGGCCACTTCTGCTAAGTTATTCTTGGGAACAAAAAGTCTTGAGCCAGCAGCAAGGAAAAAGAGAAGTCAACAAGGGCATGCGTCAAACAGCCCAGGGCAGAAGCAGCCCAGCAAGGGCTTCCAGCCCTGCCGTGAGGCCACAAATCCACGGGCACATCTGCTGGCGGGTGATAAAGTGCCAGTGGCCTTGTGACAGCTCCCCGAAGACTCACAGGCCCCAAGGATGTGAGGGCGTGGCCGGATAAACAGGGCTTATCTCACACCGGAGGCCGTTTTTTTGTTTTTTTTTGTTTTTTTAACCCAACTTATATATTTTTTATCTTTTATGCTTCTCAATAGACTTTTCAATACTTTGTGATAGTTCAAATGCTTTGGCGAAGGTTTCGTTACGGAAAAAAGGGAGGCGTGGCGGGCTGGGTCTGAGCGCTGCGGCCCTGCAATCCGCTTCCTGCCTCACCTCGCCCGCGCCTCTGGGGTCGCCAGGTTTCGTCTTCGTTGCGACAGCATTTCTGTTGCCGGATGGAAGAGTGACGGGTGCTCTTGGAGGACACTAAGTGGATGTGGGTGTATCCTCGCCAGATCTTTTCTCTGTGTATGTCTTTTAGCATCTGTGGTCAGACTCCGTGTGCGTGTGAATAGCCAGACACACAGTGCCCCACGGCGTGCGCCTCCCTCCACATGACAAGTCCAGAACAAGCACGTCCCCAGACAGGAAGTGGGGGCCACCGTCCATCCCGTCCGCCAGGCCCAGCAAGGCGGCTGTGGACCCCGCAGCAGCCCGAGTCTGGACCCAGGCTTCTCAGACATCTCCATGACAACCAGGGCCCTGGAGGAGCTGGATGGAGGCCTGGGCAGCTGCCAAGCGGTGACACCCAGGCTGGCCGACTCCAGCAGCTGGCCCCACATGCTGTTGCTGGCGAGGCAGGTGCCCCTGCACCTGTCCCTGAGCCATGGGCCCCACCTAGTTCATCCCCCCAAAAGCCAGCACCGCACTTGTCGAAGCCCGTGGCCCGGGCACCCCCATCGGTGCCCCCTGCGCCCCAGGTGGAGGCAGAGGAGAGGCCCGAGGTGCCCGCGGCGGCTGCGTGGAAGGACGAAGGGGAGTCTGGGGAGGCCGCCGAGGAGCAGCGCGCACCCCTGGCCCACGGAGGGCCCAAGGAGAGGCCGCGGAAAGAGAGTCCGCGGAAGGAGAAGTCCCGAAAGGAGGAGAGACCGCGGAGGGCGGAGAAACCGCGGAGGGCGGAGAAGCCGGGGGCTGCCAGGGAGCCCCCGGGAGCCCGCCCCCGGCGCTGGGAGGCCCGCGAAGGGGGCCGCCGGCCCTGGGTGCAGGAGTCCCGAGACCCTGAGCACAGGAAAAGGCAGGCCTGGGCCTCTTTGCGGCGCCCCAGCGAGGAAGACCGGCCTCCGGGCCGCCAGAAGCACCGCGCCGGCAAGGGGCGGGACTGAGCCGCGCCAGGGGCTCGCGCTGGAGCCCCAGGCCTTCCCGGCGGGCCCCGGGTCCAGCCAAATAAAGAG
->KR839926.1 Uncultured bacterium clone OTU_8642 16S ribosomal RNA gene, partial sequence 
-TACGTAGGGGGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCGTGTAGGCGGCCACACAGGTCCGTTGTGAAAACTCGAGGCTCAACCTCGAGACGCCGATGGAAACCGTGTGGCTAGAGTCCGGAAGAGGAGTGTGGAATTCCCGGTGTAGCGGTGAAATGCGCAGATATCGGGAAGAACACCTATGGCGAAGGCAGCACTCTGGGACGGTACTGACGCTGAGACGCGAAAGCGTGGGGAGCGAACAGG
->XM_032296798.1 PREDICTED: Sapajus apella PTPRF interacting protein alpha 2 (PPFIA2), transcript variant X20, mRNA 
-TAATTACATTGATATTTATGATGTTCTATAGGAGTTCAGAAAAGTGGAAAATATTTAGTACATTTTGTTTGATAGTACTCCTAGTATATAGAGTCTTACTGAGTTGTATGCAATTGCCTCTCAATGTCCTAGCCAGCTGTAACAGCTGTAATATACTTTGATCTATAAATTATAAAATAACTATCTACTTTAAAAAAAAAAAGGCTTTGTAAAAAAAATCGCATCTTGTTGAAAAGTCTGGGAATGACTAAAAGATTTAGAAAGATGCAGAATCAAGAGCGATAAAACAGCAATTTGTTACTAAATAGAGCTTTAAACAGTATATGAAACATACTTCAGGTTAGTCAGAAGAGGTCCTCTGAATTACACTGTGCATGCTTCCCTGAAATGAAACTGTATGTTATTGGTTAACCAGGATATTTAGCATAATCACTCTGCTAGACTGTGGTGGAGGGAGGTGATTATCACTGAGAACAGATGGGCAGGTCCACAGCACTGCCAGATTCTGCACAAGCTCCATTTATCGTTGGTTCTTGCTTTTTTCCTTCTGTGTTTTAAATTTTTTTAAAAAACATTGTATGTTCTAAAGAACTAGCTTCACAAAAGGCTGGTGGCTGATGATCTTTCAGCTAAGATTTCAAATGTAGAAGAAAGATTTAAAATGCTGTCACTGTGTATCTAAGAAGGATGGGGCAGATTTCATTTTACCCTGTAGTCTCCCTCAATGCATGCACGGATTTATCTGTACGCTAAGCTCTCTGCTCTGCATCTGTAGCTCCTTGTGGATTATATTGTCTCTGTGATCAGAAATGATTTTCTCGGATATGAACACCGTTTCTGGCTCCCCTAAAGTGCATCCTCCTAATGGGACCCGGTTTTACACTTTTCAAGAATTTGCTGCACTGACAAAAGAATTAAATGCCTGCAGGGAACAACTTCTAGAAAAGGAAGAAGAAATCTCTGAACTTAAAGCTGAAAGAAACAACACAAGACTATTACTGGAGCATTTGGAGTGCCTTGTGTCACGACATGAAAGGTCATTAAGAATGACGGTGGTAAAACGGCAAGCCCAGTCTCCCTCAGGAGTATCCAGCGAAGTGGAAGTTCTCAAGGCACTGAAATCTTTGTTTGAGCATCACAAGGCCTTGGATGAAAAGGTAAGGGAGCGACTGAGGGTTTCTTTAGAAAGAGTCTCTGCACTGGAAGAAGAACTAGCTGCTGCTAATCAGGAGATTGTTGCCTTGCGTGAACAAAATGTTCATATACAAAGAAAAATGGCATCAAGCGAGGGATCCACAGAGTCAGAACATCTTGAAGGGATGGAACCTGGCCAGAAAATCCACGAGAAGCGTTTGTCCAATGGTTCTATAGACTCAACTGATGACACTAGTCAAATAGTTGAACTACAAGAATTACTTGAAAAGCAAAACTATGAAATGGCCCAGATGAAAGAACGTTTAGCAGCCCTTTCTTCCCGGGTGGGAGAGGTGGAACAGGAAGCAGAGACAGCAAGAAAGGATCTCATTAAAACAGAAGAAATGAACACCAAGTATCAAAGGGACATTAGGGAGGCCATGGCACAAAAAGAAGATATGGAAGAAAGAATTACAACCCTTGAAAAGCGTTACCTCAGTGCTCAGAGAGAATCTACCTCCATACATGACATGAATGATAAACTAGAAAATGAGTTAGCAAATAAAGAAGCTATCCTACGGCAGATGGAAGAGAAAAACAGACAGTTACAAGAACGTCTTGAGCTAGCTGAACAAAAGTTGCAGCAGACCATGAGAAAGGCTGAAACATTGCCTGAAGTAGAGGCTGAACTGGCTCAGAGAATTGCAGCCTTAACAAAGGCTGAAGAGAGACATGGAAATATTGAAGAACGTATGAGACATCTAGAGGGTCAACTTGAAGAGAAAAATCAAGAACTTCAAAGAGCTAGGCAAAGAGAGAAAATGAATGAGGAGCATAACAAGAGATTATCGGATACTGTTGATAGACTTTTGACTGAATCCAATGAACGCCTACAACTACACTTAAAGGAAAGAATGGCGGCTCTAGAAGAAAAGAATGTTTTAATTCAAGAATCAGAAACTTTCAGAAAAAATCTTGAAGAATCTTTACATGATAAGGAAAGATTGGCAGAAGAAGTTGAAAAGCTGAGATCTGAACTTGACCAACTGAAAATGAGAACTGGCTCTTTAATTGAACCCACAATATCAAGAACTCACCTAGACACCTCAGCTGAGTTGCGGTATTCAGTGGGATCCCTTGTGGACAGCCAGTCTGATTACAGAACAACTAAAGTAATAAGAAGACCAAGGAGAGGCCGCATGGGTGTGCGAAGAGATGAGCCAAAGGTGAAATCTCTTGGGGATCATGAGTGGAATAGAACTCAACAGATTGGAGTACTAAGCAGCCACCCTTTTGAGAGTGACACTGAAATGTCTGATATTGATGATGATGACAGAGAAACAATTTTTAGCTCAATGGATCTTCTGTCTCCAAGTGGTCATTCTGATGCCCAGACTCTAGCCATGATGCTTCAGGAACAATTGGATGCCATTAACAAAGAAATCAGACTAATTCAGGAAGAAAAAGAATCTACAGAGTTGCGTGCTGAAGAAATTGAGAATAGAGTGGCTAGTGTGAGCCTGGAAGGTCTGAATTTGGCGAGGGTCCACCCAGGTACCTCCATCACTGCCTCTGTTACAGCTTCATCGCTGGCCAGTTCATCTCCCCCCAGTGGACACTCAACGCCAAAGCTCACCCCTCGAAGCCCTGCCAGGGAAATGGATCGGATGGGAGTTATGACACTGCCAAGTGATCTAAGGAAACATCGGAGAAAGATTGCAGTTGTGGAAGAAGATGGTCGAGAGGATAAAGCAACAATTAAATGTGAAACTTCTCCTCCTCCTACCCCTAGAGCCATCAGAATGACTCATACTCTCCCTTCTTCCTACCACAATGATGCTCGAAGTAGTTTATCTGTCTCTCTTGAGCCAGAAAGCCTTGGGCTAGGCAGTGCCAATAGCAGTCAAGACTCTCTTCACAAAGCCCCCAAGAAGAAAGGAATCAAGTCTTCAATAGGACGTTTGTTTGGTAAAAAAGAAAAAGCTCGACTTGGGCAGCTCCGAGGCTTTATGGAGACTGAAGCTGCAGCTCAGGAGTCCCTGGGGTTAGGCAAACTCGGAACTCAAGCTGAGAAGGATCGAAGACTGAAGAAAAACACATCTGGGCATGAACTTCTTGAAGAAGCTCGGAGAAAGGGGTTACCTTTTGCCCAGTGGGATGGGCCGACTGTGGTTGCATGGCTAGAGCTTTGGTTGGGAATGCCTGCATGGTACGTGGCAGCCTGCCGAGCCAACGTGAAGAGTGGGGCCATCATGTCTGCTTTATCTGACACTGAGATCCAGAGAGAAATTGGAATCAGCAATCCACTGCATCGCTTAAAGCTCCGATTAGCAATCCAGGAGATGGTTTCCCTAACAAGTCCTTCAGCTCCTCCAACATCTCGAACTCCTTCAGGCAACGTTTGGGTGACTCATGAAGAAATGGAAAATCTTGCAGCTCCAGCAAAAACGAAAGAATCTGAGGAAGGAAGCTGGGCCCAGTGTCCGGTTTTTCTACAGACCCTGGCTTATGGAGATATGAACCACGAATGGATTGGAAATGAATGGCTTCCCAGCCTGGGGTTACCTCAGTACAGAAGTTACTTTATGGAATGCTTGGTAGATGCAAGAATGTTAGATCACCTAACAAAAAAAGATCTCCGTGTCCATTTAAAAATGGTGGATAGTTTCCATCGAACAAGTTTACAATATGGAATTATGTGCTTAAAGAGGTTGAATTATGACAGAAAAGAACTAGAAAGAAGACGGGAAGCAAGCCAACATGAAATAAAAGATGTGTTGGTGTGGAGCAATGACCGAGTTATTCGCTGGATACAAGCAATTGGACTTCGAGAATATGCAAATAATATACTTGAGAGCGGTGTGCATGGCTCACTTATAGCCCTGGACGAAAACTTTGACTACAGCAGCTTAGCTTTATTGTTACAGATTCCAACACAGAATACCCAGGCAAGGCAGATTCTTGAAAGAGAATACAATAACCTCTTGGCCCTGGGAACTGAAAGGCGACTGGATGAAAGTGATGACAAGAACTTCAGACGTGGATCAACCTGGAGAAGGCAGTTTCCTCCTCGTGAAGTACATGGAATCAGCATGATGCCTGGGTCTTCAGAAACATTACCAGCTGGATTTAGGTTAACCACAACATCTGGACAGTCAAGAAAAATGACAACAGATGTTGCTTCATCAAGACTGCAGAGGTTAGACAACTCCACTGTTCGCACATACTCATGTTGACAAGCCACTCAAAGGAGGCAGCACTGACCTGCTATGTCGTCTTTTCAGTCTACTCTACCTAAAGTGCACTACCATCTAAGAAGACAAGCAGTGAAAATATTTGTGAAAACTGAATTCTAAGAAACTAATGATGTCATGATTTATTAAAAGCTGAAAAAAATGTGATTTTGGGGGGAGTCAGATGTTACATTTGATTAGTTTACTACAATTGTAATAAAATGCTTAAGTCATTTGAATAATAAACATCATCTACATCATAAACTCTGTACAACAGATGCTTTTATGAAATGAAGCCACTTGTTTTTCATGTTTTATTGTAATATACTAGGCATTTATGTATTACTGTGCATTTCTTTTTAAATGTGTAAGTCTTATGTAAATGGATATAAATATGATTTTTTAAAAAATAAAATATATGGTTCATGGAGTCTCGAGTACAAACATTTGACAATTCTAAGTACTGTTTGTATTTTACCATTCCACCATTTTTACAGTTTTTGAATTGTTAACAGTCAAATCAATGTTTCCTTGAAGCATGTTCCATGCTTCAACATGTTTCTCCTTCAAGTCTGTCAATACTTACTTACTTACTTAAAGCTGAACAACCTGCCTCTGATCATGTAAAAAAGAATGATTTAACCTGGAACTGGAGCCAAAAAATAGAGCTTTAAAGGCAATCAGGGATGTCCTATATCTTTAGAAATAGCACTGTGATGGCTCGATCTCCTTTTCAATACAAAACAAAGCCAACCTGTTTACAAGGGTCAAAAGCAATTATTTAAAAATTTATATTAAAAAACCATTATCTTCTCTTGTTACCTGTGGACCAAGAAAAAAAAAAAAAAAAAAAAAACTTCTTTACTAGAACCACATGTTCATTTAAGTATCTTGAACTGCCAGCCAGTACTGGACAGCGAAATGTCAACCGCCGCAGAGTCTGAGGCTCATTTCCACGAGAAAACAAAACCCAAGAAACCCTTCCCTTTTGTCAATGGAACAGGGCATTAGCCAAACTCATGTCTAATGTTATAAGCTTTCAGCCAAGATGGCCTTGTTGCGACTTCCCTGAAGTCAGTTTATCAGAGGAAATAAATGAAAGACAGAACAATTAACACATATAGTGTATAAAATTATGGAAGAGTAATCTCTTTCCCTGTGGCTTTATTTGGTGGTGTTACTGTTGTTTATTCTTTGTTTATATGGGAGATTCAAAGTAAAACCTATTTACTAATACCATTTATCTAACTGCGGATTTTCTGCTGCTTGATCTTATTAAGCGCAAGACCTGTCATTAGTAATTTTTTTTGTATTTTAATTTGCTATGTTTGCACGTACATTACATTTGTTTCGATGTCTATTTTTGTTTAACAGATTCAGTCAAAAGGTAATGGTAACAGAAACCCTTTCCATTGTCAATAATAAAAAAAATACTTCCA
->XM_021543360.1 PREDICTED: Lonchura striata domestica calpain 7 (CAPN7), transcript variant X2, mRNA 
-CGAAAGTTTGTCAGGCTTCGGAGGAGCCGCGTTCTTCGGGGCGAGTTGCGAAACGCCTTTTCCCTGCGTCCTGGTTTTAGGAAGCTGCACAAGCCTTGATTTATGCTGGGATGGCTGGGTCCAACTTGGAAAATATTCAAGAAAAGATAAATGAGTACTTGGAGAGAGTTCAAGCTCTCCATTCAGCAGTTCAATCACAGAAGACAGACCCTCTGAAGTCAAAACAACAGTTGGACTTGGAGCGTGCTCACTTCCTAGTTACACAGGCTTTTGATGAAGATGATAAAGGCAATGCAGAAGAAGCTATAGAGTTGTACACAGAAGCAGTGGAACTCTGTTTGAAAACAGCTACTGAAACCTCAGAAGCCAGCCTCCAGTCCAAACTGAAACAACTGGCTCGACAAGCACTGGATAGAGCAGAAGCACTGAAGGAATCTATGTCAAAGTCATCACAGAAAGAAAAGTCAACTGCAGCCAAACCAAATCAGCCAGTCAGAACGTTCTTTCCACTGGGACCTGATTTTTCTTTAAATGATAAACCACAGACAATCAGAGCAGTACAAGCTAGTGAATCTCAAGGTCAGAGATACACTGCAGAGGAGATTGAAGTACTCAGGAAGACTTCAAAGATTAATGGCATTGAATATGTACCTTTCATGAGTGTTGATCTGAGGGAACGTTTTGCCTTCCCTATGCCTTTTTCTGATAAGTGTGGGAAGCTACCATTATCCCCCAAACAGAAAGCAATGTTTGCCAAGTGGGTGCGACCAGATGACATAACAAATAACCCTACAATGATCTATACTGTATCAAGTTTCAGCATAAAGCAGACAATAGTGTCAGACTGTTCTTTTGTGGCATCACTAGCTATCAGTGCAGCATATGAAAGAAGATACAACAAAAAACTGATCACGAGTATAATTTACCCTCAGAATAAGAAAGGAGAACCAGAATATAATCCATGTGGTAAATACATGGTGAAGCTTCATATCAATGGTGTTCCTAGAAAGGTAATCATAGATGACCAGTTACCTGTTGATCATAGTGGGGAACTTCTCTGCTCTTACTCCAATAATAAGAATGAATTATGGGTGTCACTAATAGAAAAGGCTTACATGAAGGTCATGGGAGGATATGATTTTCCTGGATCAAATTCTAATATTGATCTCCATGCACTGACAGGTTGGATACCTGAAAGAATTGCTATGCACTCTGACAATCAAGCCTTCAATAAAGATAGCACTTTCAGAATGCTTTATCAGAGATTTCACAAGGGAGATGTCCTTATCACAACAGCAACAGGGGTGATGTCTGAAGAGGAAGGAGAGAAGTGGGGTTTAGTTCCAACCCATGCATATGCAGTCTTGGATATAAGAGAATATAAGGGACTTCGATTTCTTCAGCTAAAAAATCCCTGGAGCCACTTGCGTTGGAAGGGACGATACAGTGAAAATGACACAAGAAACTGGACCCCAGATTTACAAAAATACTTGAACTTTGATCCCAGAACAGCTCAGAAAATAGACAATGGCATTTTCTGGATTTCCTGGGAGGACCTGTGCCAGTACTATGATGTTATTTATTTGAGTTGGAACCCAAGTCTTTTTAAAGAATCTACATGTATTCACAGTACGTGGGATGCAAAGCAGGGCCCGGTGAAGGACGCCTACAGCCTGGCCAACAACCCTCAGTACAAGCTGGAGGTGCAGTGTCCACAGGGTGGTGCTGCCGTCTGGGTCCTGCTCAGCAGGCACATCACTGACAAGGATGACTTCGCACACAATCGGGAATTCATTACAATGGTTGTATACAAGACTGATGGTAAAAAAGTTTACTATCCAGCTGATCCTCCTCCTTATATTGATGGTATTCGGATTAACAGTCCTCATTATCTGACCAAGATAAAGCTGACCTCTCCAGGTTCCCATACATTCACCTTAGTGGTGTCCCAGTATGAGAAACAAAACACCATCCATTACACCATCAGGGTGTATTCCTTGTGCAAGTTCACCTTTTCCAAGATTCCTACGCCTTACACCGTTTCCAAACGGGTTAATGGACAGTGGAAAGGTCACAGTGCTGGAGGATGTGGAAACTTCAGAGACACCTACAAAAATAACCCCATTTATCAATTCCAGCTAGACAAGAATGGACCATTGCTAATTGAACTACGGGGGCCAAGGCAATACAGTGTTGGCTTTGAACTTGTCACCGTCTCAACAGTGGGAGATCCTGGTTCCTATGGCTTTCAGAAAAAAAGCAGTGGTGACTACAGGTGTGGATTTTGCTACTTGGAGGTGGAGAACACATTTGCTGGAGTTTACAACATTATCCCCACCACATTCCTGCCTCAACAAGAAGGGCCTTTTTTCTTAGATTTTAACAGTACTACTCCTCTTAAGGTGTCACAGCTGCAGTGAGGAGACAGAACTGTGTAGTGTTGTTTAAGGAGATGGTTTTGATCTGTCCAGCAGCCTGAGAACAGGTGAAGAACCCTTACTACACATGCACAAAAGAAAATTACATCCTGATTTATAGCCAAAAGCATGGAATCACAGATTGCCAGTTAATTATGGCAGGGAGTTGGCTGTGGGTTTGCTGCTGTGGTCTAGGAGTGAGCACTGTTCAACAGGCTTGGGAATAGGCTAAAATGCATATATTCAAATGAACCAGCAGAACTCACTCAATTTATTGCAGTTTTTCCACACTTTGAATCAAAGTCTACTGAGTTACAAGAAAAACTAGCATTGAAATTCTCTCCTCCCCACATACAAGGTATAGGAGCTAAAGATTCTATTCTTAAAAGTAAACATGTAAGAAAAAATATTCTTGTGTATTCTGCTTATTCAGTCTCAGGACCAAATAGCTTTTATTACACATTTGTGCTGCTATCTGTAATGTTTTCAGCACTGAACGGGTTCTCAAATCTAAATGTAAATGTACTACTGCTGAGTCAAGAGTATTCCATGTGTCATCTTATCTGGAATATGTATATAGGAATAAAGGAAAAAGAAGGTTCCAGCTTTAGCTATTTCTAAAAGCAAAGCAAGTGCTTTGCTTATGTTATGTGTACCTTGAGAGCTGTTACTTCATATCTGTATGACTTTAGCACATAATACAGCATGAGGTTCTGTGGCTTTCTTCCTGCTATCTGCCAGACCTAGGTTGATCCTGAGGAGCAGGAAAGACAGGAGATCATCCAGCAGTAGTGATCAGGCAGTGCAGCACAGCCTTCTATGAGCAGCTGTGAAAGGTTTTCATCTGAAGATCCCCTGTATGATTCACTGTATCCACTGAGGGTAGTCTCAGTTACTGGTGCAGGGAGATGGGGAACTGCCCACCATCAGCAGCTCAGCAAAGAAATGTTTTATTTTCATCACTTTTGTAAGTATGTGTCATGTAGGGAAGGATCATTTAAATCTCTCTCCCAATACACCACAGCTTCAAGGAAGGCACTTGCTGATTCAATTATACAAGACATCTTTGAAAATATACTTTTTTCCTTTTAAAATGACACCAGTGAAGGAATTGAGCACAAGGCCAGTGTCATCAATAGAAGCAGGGTCACAGTTCTTAAGAAAATAGTGGAGGTGGGATTAATGCAGAACAAGTTATTTTTTTAGAAGTTCCCCCTGTATGTGTTCTTCCTCTAGATCTGTATAAATTGTATCTGAAGTGAATTCAAGATGAGCAGCTTTTATTTAATACCAACTGCCTGACAGATCCCAAAATTGATTAAATTTTGTCATTTTTACAAAATTTACAGTATTTCACAGCTGAGGGAGAGGGTGTTTTTAAAACAGCCATGGGAATTTTGCTGCCATTCACATTGGTTTGGCAGTTTTCCAAGCAAAAAGGTAGCATTTAAATCTTGCTTTAGATTACAGGTGTCACTTAGCCACTGGGAAACTGAACATACATTCTACAATAGCACCAGAAATAGCTGTGGGCTAAAGTTATTCCCACAGAAATCTGCTATTAGTCCTCTCCTCTCCTTTTGTTTCATTTCCTTCATCAGACAGCTGCTTAACAAGTATCTGGCTCTGAAAGGGCAGGGATAGCTCCTGCCTTGGAAAACACATGCCTTGCTGACTGCAGTTCTCTCAGAGACCATCTGGGCTAGGGAATTCATGACAAGTTTGTCACAGAGTGACTTACCTTCTTTTGCAGGGAAGTCTCTGATGTTTAGTGCAATAAATCAACAGAAGGAACAGCATGGTTGCAAGCTGAGAAGAAAACAGATTAGGTTCTTTGTGGTTATGCTTGGCTTTTGGAGTATGTGCCAAGGACTGCTTCATCCATAAAATATGAAAATTTCATTCAACGCCCATTTTCCCTACAGATTTCTGTTAAGTTTTTAGCCGAGGCTAAACCAGAGTAGCAGGAGAGTCCTCCATCTTATCACCTCTAAAGTTGGAGGTAGTGGGGAAGTATGAACCGAGTATCTTTTTGGCAGTACAAAAGGCAGATGCCAGAAGTGCCAGCTTTCAGCAGCAATTTCTTGCACATTCTCTGCTGTTTGAGATCAAGCTGGTAGACTTGCCTACAGGAAAATCTGTTGTTGTTCTTCAGTAGTTGGTTCCTACTCGGAAGGAAGGAGTTTTCCTTTCTCTTTCCCCCTGAGCACAAGTTAGTGCCAAAGCTTATGCTGCATGAAATGAGCAGAAGGCTCAGCTTCCATACTGTGCTGAACTTAAACTGAACTGAACTAAAAAGTAAGAAATGTACTCACTTTCCTAATGCCAGGCAAAAACATTAAGGCCAAAGGATCCTGTCCCCACCAGGATATGCCAATATTTCTTACGCATTCAGAACAGTCAGTGGATTGGGCTTATCCCCATTAGTGCATAGGACTTAAGCTTACTGTCAATCTTATATATATAAAGCAAATTCTATTCAAATATTGCATCTGGATAGGCTACTAGAATGCCATCACTGTGCACTTCCCTTCAGATACAGGACAGAACACTCAGGTGAAGTATTTCAGAGGTACTACAAAATATCCATATAAATTGCAACCTAGGGATTCTGGTTATGGCAAATTTATTTTACAACGAAATTTTCTTGTCCTTTTTTCTTAAGAAAAAGCATTGATATAAGCATTAGGATTTGCTTTAATATTTTCTGTCAAATATATACTTTTATATATTTTCCACAAGTAAGTCTAGAAAAATTATTGCAAAGTGAACTGATCCTTAGATTTTAACACAAACTCAGACCACTAAGTTAATATTTTCTTTTCCCTGTACTGTTTAGCACTTTTTGAACCATACGAGAGAGAACGTAGTTTGTTCTGTTAGGAAGACACAAGTTAGCCCTTGGTTGATCCAATCTCTCCGTTCTCAAAGATGCAGTGAGACATTGTACCATGGATGAATGGTATCAACACCTGCCCCAGACTGTGAGTCTGAGTTCAGTCCTAGTCTCCTGCTGCAAGCTTCATGTAACTATTTTGTACAGTAATTATGCATTTAACCACACAATGTCTGCAGCCTTTGAACAGCCACCTATTTAGATCTAAGTGTGTGTACATACAGTAGAGGTTTTCATTGCTTTATCTAAAAGGACATTGAAATCGTTTGATAATACCAAAGAGAAGTAGAACTCCTAGGTTAATACTGGCTTTATACATTCTCACATCAGGGCAGATGAAGCAATCATGTATACTTTGATACACCAGAGGCTTATTTTTATACCCATGAAGGCAGCTACCATCATGTTACACTTCAGAATCCACGAAGAGCTTAAGTAAAAACTAACTGGAGAAAGCTTGTTCCCTTACTTGTACTACATAGCAATGTGTGTTCATTTAAGTCTGTCATATTTATGATTATGGCTTTTATGAAGTTTAAAATAAAATGAGTTTTCCATTAATTTATTAGACA
->XM_017957302.2 PREDICTED: Papio anubis enhancer of zeste 2 polycomb repressive complex 2 subunit (EZH2), transcript variant X5, mRNA 
-TGCTTGATTGGGTTGGGGGGGCCAAATAAAAGCGATGGCGATTGGACTGCCGCGTTTGGCGCTCGGTCCGGTCGCGTCCGACACCCGGTGGGACACAGAAGGCAGTGGAGCCCCGGCGGCGGCGGCGGCGCGCGGGGGCGACGCGCGGGAACAGCGCGAGCCGGCGCGCGGGACGAAGAATAATCATGGGCCAGACTGGGAAGAAATCTGAGAAGGGACCAGTTTGTTGGCGGAAGCGTGTAAAATCAGAGTACATGCGACTGAGACAGCTCAAGAGGTTCAGACGAGCTGATGAAGTAAAGAGTATGTTTAGTTCCAATCGTCAGAAAATTTTGGAAAGAACGGAAATCTTAAACCAAGAATGGAAACAGCGAAGGATACAGCCTGTGCACATCCTGACTTCTGTGAGCTCATTGCGCGGGACTAGGGAGTGTTCGGTGACCAGTGACTTGGATTTTCCAACACAAGTCATCCCATTAAAGACTCTGAATGCAGTTGCTTCAGTACCCATAATGTATTCTTGGTCTCCCCTACAGCAGAATTTTATGGTGGAAGATGAAACTGTTTTACATAACATTCCGTATATGGGAGATGAAGTTTTAGACCAGGATGGTACTTTCATTGAAGAACTAATAAAAAATTATGATGGAAAAGTACACGGGGATAGAGAATGTGGGTTTATAAATGATGAAATTTTTGTGGAGTTGGTCAATGCCCTTGGTCAATATAATGATGATGATGATGATGATGATGGAGACGATCCTGAAGAAAGAGAAGAAAAACAGAAAGATCTGGAGGATCACCGAGATGATAAAGAAAGCCGCCCACCTCGGAAATTTCCTTCTGATAAAATTTTTGAAGCCATTTCCTCGATGTTTCCAGATAAGGGCACAGCAGAAGAACTAAAGGAAAAATATAAAGAACTCACCGAACAGCAGCTCCCAGGCGCACTTCCTCCTGAATGTACCCCCAACATAGATGGACCAAACGCTAAATCTGTTCAGAGAGAGCAAAGCTTACACTCCTTTCATACGCTTTTCTGTAGGCGATGTTTTAAATATGACTGCTTCCTACATCCTTTTCATGCAACACCCAACACTTATAAGCGGAAGAACACAGAAACAGCTTTAGACAACAAACCTTGTGGACCACAGTGTTACCAGCATTTGGAGGGAGCAAAGGAGTTCGCTGCTGCTCTCACTGCTGAGCGGATAAAGACCCCACCAAAACGCCCAGGAGGCCGCAGAAGAGGACGGCTTCCCAATAACAGTAGCAGGCCCAGCACCCCCACCATTAATGTGCTGGAATCAAAGGATACAGACAGTGATAGGGAAGCAGGGACTGAAACGGGGGGAGAGAACAATGATAAAGAAGAAGAAGAGAAGAAAGACGAAACTTCGAGCTCCTCTGAAGCAAATTCTCGGTGTCAAACACCAATAAAGATGAAGCCAAATATTGAACCTCCTGAGAATGTGGAGTGGAGTGGTGCTGAAGCCTCAATGTTTAGAGTCCTCATTGGCACTTACTATGACAATTTCTGTGCCATTGCTAGGTTAATTGGGACCAAAACATGTAGACAGGTGTATGAGTTTAGAGTCAAAGAATCTAGCATCATAGCTCCAGCTCCTGCTGAGGATGTGGACACTCCTCCAAGGAAAAAGAAGAGGAAACACCGGTTGTGGGCTGCACACTGCCGAAAGATACAGCTGAAAAAGGACGGCTCCTCTAACCATGTTTACAACTATCAACCCTGTGATCATCCACGGCAGCCTTGTGACAGTTCGTGCCCTTGTGTGATAGCACAAAATTTTTGTGAAAAGTTTTGTCAATGTAGTTCAGAGTGTCAAAACCGCTTTCCGGGATGCCGCTGCAAAGCACAGTGCAACACCAAGCAGTGCCCGTGCTACCTGGCCGTCCGAGAGTGTGACCCTGACCTCTGTCTTACTTGTGGAGCCGCTGACCATTGGGACAGTAAAAATGTGTCCTGCAAGAACTGCAGTATTCAGCGGGGCTCCAAAAAGCATCTATTGCTGGCACCATCTGATGTGGCAGGCTGGGGGATTTTTATCAAAGATCCTGTGCAGAAAAATGAATTCATCTCAGAATACTGTGGAGAGATTATTTCTCAAGATGAAGCTGACAGAAGAGGCAAAGTATATGATAAATACATGTGCAGCTTTCTGTTCAACTTGAACAATGATTTTGTGGTGGATGCAACCCGCAAGGGTAACAAAATTCGTTTTGCAAATCATTCGGTAAATCCAAACTGCTATGCAAAAGTTATGATGGTTAACGGCGATCACAGGATAGGTATTTTTGCCAAGAGAGCCATCCAGACTGGTGAAGAGCTGTTTTTTGATTACAGATACAGCCAGGCTGATGCCCTGAAGTATGTCGGCATCGAAAGAGAAATGGAAATCCCTTGACATCTGCTACCTCCTCCCCCTCCTCTCTGAAACAGCTGCCTTAGCTTCAGGAACCTCGAGTACTGTGGGCAATTTAGAAAAAGAAAATGCAGTTTGAAATTCTAAATTTGCAAAGTACTGTAAGAATAATTTATAGTAATGAGTTTAAAAATCAACTTTTTATTGCCTTCTCACCAGCTGCAAAGTGTTTTGTACCAGTGAATTTTTGCAATAATGCAGTATGGTACATTTTTCAACTTTGAATAAAGAATACTTGAACTTGTC
->XM_028016850.1 PREDICTED: Xiphophorus couchianus intraflagellar transport 27 (ift27), transcript variant X1, mRNA 
-ACCACAGGGAACGGTTGCTAGGAAACGAGCTTTGTCCATTTTTGCCGAGGCGAATGGAAGATTAAAGCTGCTAGCAGGAATGCTATTTAATTTATTAACAGACACTTACAATATTTCTCACGAGGTTTCGAATGTACGCCGAATAATGGTGAAGTTGAGGGCAAGATGTCTGCTTCTCGGGGATGCTGCAGTGGGGAAAAGTTCTCTTTTTCACATCTTCTACAATGATGGATCTCTGTTCCAGAAGAACTATAGCTTGACAACGGGAGTGGAGCTGGTGATGAAATGTATCAACATTCCAGAGACCAACGACTCCGTGGAGCTCTATATCTTAGACTCGGCGGGGAAGGAGACGCTAGCGGAGGGCTGCGAGAAAATGGTCAGAAGCTGCTCTGGATTCTTCTGTTTTCATTTGCATGAAACTAATCAGTGGGGGGAGCCATCTTTGCTGTGTCTGGTGTTCGATTTGACCAGTGAGCAGTCTTTTGCTAACTGCGCATGTTGGATGGAAAGAGTCCAAGCACACTGCAAAGGCCTCCGTGTGCCAGGTGTTCTCGTGGGAAACAAGTCGGATCTGTCAGCTAGAAGGGAAGTACAGGCGTCCGTGGCCGAGGAGTGGGCCCAAAGCAAGGGACTGGAGTACCACGAGACATCAGCTAAAGAGATGGTCAACTGTGATGCCCCCCTCCTCAGTTTAGCACAGTCCTTCTATTCTCTCTACCAGGAGCAGCGTGAGATCATGCAGAACCTCGGGCCCGGCTAGACTCCTCTTCCTTCACCACAGAGCTCACAGCCGTTTGAGACGAACCACTGCGAAGGAATTGCTTTAGGAGAATAGGATTTTCTGGCAAGGATACTGAAAGGCTTTCTGATTGTTTTTGTTTTAAATAAAGGACTAAATAAGGAGCAA
->XM_015847342.1 Paracoccidioides lutzii Pb01 hypothetical protein (PAAG_11752), partial mRNA 
-ATGCAAGGACCAGAATATGTTTTAGATGAGCGGACGGAGCAATTGTTAACCCAGGGGACCAAGGGCGGATATGAGAATGGGTTCACATTTAGAAAGTTGCGGCTGGAAATCTCCTTTATTCGCAATCACCCATGGATGAAACGTCTCACTCCTTTTCCCTTTGGCCCACAACAGATGCTCAAAAATCAATTATGGGGAGTGTCTCCGCTATCATTTTCTCGTCCACAGACAGAGGAGGTCCCTTTGGATCAGAAGGCTCAAAATAATAGTGGATCCCAATCCCGCATCTTGGAACAGCGTGCCCGAAGGGTCAAAGCACTTGCTATCGCTTGTGGCGCTGGAGATGGCTGA
->XM_018786474.1 Plasmodium gaboni hypothetical protein partial mRNA 
-ATGATTTTTAAAAGGTTCTTCCATAAGTATCCTGGAGGAAGTAAAATAAAATGTTATATAGAAAAACGAAAGAAAAAGAAATTAAATATAAGTTTATTTCATCAACCTCTATATTCTAAGAATTCGAAAAATTTTATTGATTGGAGATATAGTACTCCTAAGTCAGGGTATGAATATATGTATATATATGGAGAGAACACTATTGAAATAACGAATTTACCGAATAACAAAACTAATGAATATATTCAAGAACGTCTAAGAAAAAGTTTAAATAAATATGGAAGATTAAAAATTATCAGATGCTTAAGTCATAGGAATGATCCATATATAAATAATAATATTTGTTATGCTACATTTTATAATAGAAAAGATATGTATAAATGTATACGTAATATTAATATAAGACTTCCAATATCTTTACAGTATAAAATATTAAAATTTAAAAGTTTACTTTCCAATAAATGTAATGATTATAATTATTTTTTTAAACAAGACCATTATAATTACAGTGCTATAAATATAGCTTTGAATTTGTTTAAATATTTAGAATATAATAATTGTAGTATGAATATAAAGGATATCTACAAGCATGTATTTGAATATTCGTTTTATCCTCATAAAATTATTTCTTCAGGAATATCAGTTTATAAAATATTTAAAAACTGGACAAATTTTATATATTTTTTTGATAACTTATTTCATATTGTAAAAAAAGATGATGATATTTTTATTACAGCCAAAATTCTTAATGATCAAAATTTATCTATTTATTTAAACAACAAATTAATTGAATTAAAAAAAAAAACGGAACAGAGTAATTCCGTGTATTGGAGGGAGCACTCTTTACAATTACCCGAAGAAATTGAAAATAGAATAAATAACGATCGTCCAAAAAAGTTAAAAGAGGAACTGCAACTTTTGTCCAAGACAAAAGATTTTTACAAGATTCATGACGAACGACACTTATTTAAACTGAAATTAAACAAGGAGCGAAAAGAAAAAAAAAAGATGTTAAAAAAAAATAAGCAACAAGAAAAGGAAGAAAAGGAAAAGGAAAAACAACTTAAGAAGGAAATGTACTGA
->XM_046923823.1 PREDICTED: Gallus gallus integral membrane protein 2C (ITM2C), transcript variant X1, mRNA 
-GGCAGTGAATGCGCTCGGCTGCAGATGAGCACTGTAACTTTCCATGGAAACTGCTGCATTGATTCTCTGCCTTTGGCTGCAGGAGGAGCAGGCTCCCGTGGTGCAGGGCCGCAGGTCATCGCTCAGCGGGGTGTGCTACCTGACCATGGGTCTCCTTGTGCTGCTCCTCGGCTTGGTCTTTGCATCAATGTATGTCTACAGATACTTCTTCATCACGCAGCTTCCCCGTGAGAGCGTGTTTCATTGCGGCGTCCTTTATGAAGACTCGCTGTATTCACCGTTCAAAGGGCAGCTGGAACTGCACGAAGATGTCAAGATTTACATCGAGGAGAACTACGAGCAAATCAATGTCCCGGTGCCCCAGTTTGGAGGGAGCGACCCTGCAGATATCATCCATGATTTCCAGCGAGGTCTAACAGCTTATCATGACATAACGCTGGATAAATGCTACGTCATTGAGCTGAACACCACTATCGTGATGCCTCCACGCAACCTCTGGGAGCTGCTGGTTAATGTGAAGAAAGGGACGTACCTGCCTCAGACATACATCATCCAGGAGGAGATGATTGCGACCGAGCACGTCAGCGACATGGAGCAGCTCGGCTCCTTCATCTACCGCCTGTGCAGCGGCAAGGAGACCTACAGGCTGAAGCGGAGGAGCACCAGGAGACGTATCAGTCGACGTGAGGCTGGGGACTGCCACCGTATTCGTCACTTTGAAAACACTTTTGTGGTTGAAACTGTTATCTGCAAAAAATCATGAAGCCCCTGTCCAGCTGTAACCTTCCGTGGCTTTGCTTGCACACACATGCTCTCAGCCCTCTTTTTAGACTTGGTAATCTGTCTTACTTTTTTTACGCCCTCTCCTGCTTGTGCAGCTCTAAAGCCTTGGGTCTGTCGTGGCCTCGCAGTTGATTCTCTTCTCTTTTCTCCTTACTGAGATGTTTTGCTGGGCTTAAATTTATGCAGCGGTCACAGATGGCCTTGGAGTGGATGCAGCCTCTTCCACCCCACAGGGTGGGGATCTGTTTTGGGAGCAGGTTTTGGGTAGAAGGGACGACCAAGAAATAGGATGCTGGAAATGGGCGCTCTTCTCATGTCTGAGCAGTTTCCTGCTGGCGCTGTTGTGAGGCTGGGGCAGAAGGTGTACTACAGGAGGAGAATTACCATTCTGATGCTGATGTAACGACCAGAATATGTCATCAGATGGACTTAGAATTAGATGCGAGGTTACAAACAGGGTGATTTGGAAAGCTCAGCAGGAGAGTTTCTGCCCACGCTGAACTGTGGTGCTCACAGTTTGTTGTCCCAATGAAGGCCAAGTTTTTGAACAGTGAAAGCAGCCCATATGCATTGTTTCTGTGTCTAGCTCCTGGCTGATTTGGAGTGGCATACCTGGAACCAGCCAGGCTACCCTCCCTCAGCCTTCAAAATAACAAGCAAGTGGTATCTGCTTGGGGCTCCTGAGCTCATCTGCTACGGCTTTGCCTGAGTAAATAGAGGTGAGCCGTCAATACATGCTGCCAAAGCTCAGCTGATGTCCCATCCTATGGGCTGCTGATGAAGCTGGATGCTTTATTTCAGCTCACCTCTCCAGGCCAGCTCCTCCTGCCTGGAAGATGAGTTATGTGAGTTATGTTCACATAGATCTGTCTTTCTGAGTTGTCAGGATCCCATCTGTGTGTGGATGGGTGCCATGCCAGCATGCAAAGCGGTATCAGCAGCAGGATCAGTAGTTACTGGCATCTGCAGAAACAGGGTGGTTTTTTTTGTTGTTGTTGTTGTTTGTTTGGGGTTTTTTGAGAGCATATTTCCACAGAACTCCTCTGAAGAAAGCCATTTTGATCATAACTCCTGTAGCCCAGCTGTGTGTTGTGTCATCTGTAGGCACCGCTAGAGAGCAGGTGTCGATGCAAGGCAAGATTCAGTGCATCAATATACTGCAGAGAAATTGTATGAACAAAATTGTGTTTCTATTGATCATCAGAAAGAAAAATTGCAGGGTACTTAAACATTCTTCCCTCTGTTCCATAAATATAGTAAAAACTAATGAGGTTCTTAAAATGCAGGCAGTTTTTTGGCTTGAAAGAACAGCTTGGCACATTCTTGTTAATTGGTTTTCAGCAAATCTGGACTTGTTCATCTGTTGAAATGAGCTTGTTGTTTCGGGAAGAGAAAGGATAAAGTAAATGCAAGAACAATCATTAACTCAGCAGGACCAAAAAAATTAATGTATTTGAGAGTCAAACTTCTATTAGTAATACTGTGAGCTAATTATATGAAAACAAAACAGAACCTTAAAATGATCGCATAACGCAGTAGCAATTAGTATGTCCTTAGAAGCTGAGGTTCTTATTTTTTTATATAAAAATAGAGTCAACCATAAACATTAGATTTTAATAGGTAGAGGAGGAGGTGCTGATCACCTGCTTTTTAAGGTGGATGTGAAATGTGAGATTGCATGTGTTTCGTGCAGACCAGTGAGGAAAGTTTCCCACTGCCAGAGGAGTATTTGCTTTTATAGTACAGCTGTGTTTTTCCACTACAACTTGCTATTAGTCCTAACCTTTCATTGCAAAGTGAATGATGAGAGTCAGAGAATCGGTTTGCTTGGTGGAAGTAGCACAAACTGGTAAATTTATGCCCTGCATTTCTCTCTGTTTCCAGGATCCTAAGCCTGCACTCAGGTGAGCGCTCAGACCTTTCCCCTTCCCTCTGATGCTGCATGAATTAACTGGTCATTGAATATGCTAACTCTGTGCAACCCCGCAGCTGTAAGGACAAGCCCTGATTCTTTAAGGTGAACTAACATGGTCGCTGTTTCATAGGGTGAGAATGCAGTTGTCTAGAAAGAAAACACAAAATGCTTTGTATATTTTGTCTGGTAGAACCTTTACCTCTTAGGAAACATTCATGGGATAATAAAATCTTTTACCTCTGATA
->XM_008488083.3 PREDICTED: Diaphorina citri protein rogdi-like (LOC103523006), mRNA 
-GCACGATGAAGTTCGAACAGTACCAGGCCGAGAACTCAATACCATGGCTGAATGAGGTGCTCGTGCTGTTCACCGTGGCACTTCAACTGTGCCAGCAACTCAAGGATAAGATCAACGTGTTTGCCCAATACAAGGACTTCATCGTGTCACCTAATCTCTCCACACCTAGTGCTACCTAGTGGTAATTATGTAGATTAAGAAAGTGTGTACAGGGTGGTCCCATTGATGAGAGAGGGTTCACTGCAGATCATGGTTCACACAGTATATTATTATTGCACAA
->XR_001166349.3 PREDICTED: Fundulus heteroclitus uncharacterized LOC105928738 (LOC105928738), ncRNA 
-CGTGTCTTGCACGTCGTCGCGAACGTTCGCTTGCTTCCGGCTTCCGTAGTCACTTCTGTGGCCACCAGGGGGGAAAATGACGGCGTGGAAGATGTGCGGTAAGCAGATGCATAGCTTTACCCTCGTGGGAACTACAGAAGCCGACGTCACGTAACTGCGCTTCGCTGAACGGCTGTTGTTACGAAGAAGCAGGGGATGATCGTCCGGTAAGGGCCTTCCAACGCCAGAGGAGGAGCAGGACAGATGTGCTTCCGAACGCATTTCAGTTTGACTGGGAGTCGTATGAAAATGCAGCGGAGCTTTTTGTCCCCATTGGTAAGGTTGGTTAACGGAGGTTAAAGAATATTAAATATATTGAGGAATTGAAAAAATAACGGGGATAAAACCTCGCGTCTACCTGAACGCAGCTTTACTTATTTCTCTTTTGTTCAAGCATCAAATGTTAGCTTCAGATGGAAAATAAATGTGACAATATGGGGGAATTCCCCCTAAGTGTGGACACTTTAAAAATGTGTGTGTTTAAAGACACATTTCCTTATTATAAGAGGAGCCGTGTGAAATCCCCAAGTTGTCTTCAGCACGTAGCAAGTCGCTTTCGGTTTTATCTGTTTATGATGACTTCCTTGTCATCGTCTCTTTGATGAAACAGCCATTTACTTTAGCGCTAGCGGCTAGTCCAAGTGGGCCCTAGGTCAGTATGTTCTGGGAAATCAATCCAATATCAGAAATATCCTAATGGTTCATGTGAATTCTACTTCATGAACACAGCTGTCAGATTTACACTAGAGGGTTATTTCTAGAGAACCGTATGGTTACAGCAGATAAAATTAGAAATGGACACAGGAACAATTTTCTCAGTAAATGTATTTCTAATACTTCTATTGAGGCCACCAGTAAATATTAAACCTTGTGATATTTATTTGCACATAATGGCTGGAATATTTTCTAAATACTAACAAGCCTTTGGCTGGTTTCTTGGCTTTCAATGCCTTTTGGTACATCCTTTTCTCATCCACCCTTCCACTTTATTACACATGACTCGAATTTATAGACTAATTTGCTTTGATTTCTGCATATGTGAGGATTACTTTGTGTGTTGCTAATATCCGTTGTGAATTTCATCTCAGTAGAAAGTAGGGGCATCCCGATACTGATTTTTTTTTTTTTCAGACCGAGCACGAGTACTTTAGTTCAGATACTTGCTGATTGCAAGTGCTGATACTGAGTATACTGATATAGCTTTATTTGATCATAATCAACTGGATTTTGGTCTTTTTGGTATAAGCATACAACGTGGCTCTATACCTTTAAAGACAATGTGCATATATATTTGAGAGTGGATATGTTTTAACGTAGTAGAAGACCGTTTTGGAACTTTGGGATTTTAGCGCTTAAGCAGATCAGCTTTAACACTGGAAGAGTTATGTACTACAGGCAAGGCATGTTCATAACCTCTAACAGAACGTGACAAACCTGAGCTACCCCTTTAAGGTCGCTCCATGAATGATAATATTTAAGTTGGTGGAACCTTCACAGGTGTTAGCTAAACGTTTTGCTTTTTAAACCCTTTCCAGAAAATAATCTGTGGATGTTTAAATAGATCCTATGTTACTCCTCCTGAGGAACCTGCCTGCAGCCTACACCCAGCTCCATGCCTTTGAGTTAAGTCCGTGGCAGATATAGTTAAGCCCAAAATGATTTACAGCCCTAGAAGACTTATGTTAGTATTTTTAAAATATTACTTTTAAACGAGTTTCTTCTGGCAGGAAGTAATAGCAACGTTCTTGAGCGACTCGTCCTTAGTGCTGGCTTTAATCTGGTAGAGAATCAGCGGAAGCAGCTAAAGATTAGGGTGATTGCTTGGAGGCCTTTCAACCTTGGAGGCTTGGTGCTAATCACCAACAAAAAAATCTTTGAAATATGAGTGGAAAAATACAAAAAGATGGTCAGCAATTTTAGGACAGGTTGAATTGCTGTGATGCCAATGAAGATTAGACCTTGGGCTATTGAGAAGGATGTGCACATTTGGCATAATATTTTGAATAAAATGTAAAACAAGAATGAATTGAAGCCTTCCATTTACATTTTTCAGTATATTTTGGGAGATGCCGCTCTCATTTTTTATCAGAAACAAATGCAAATGATTTAAAATCAAAATCGTCCAGGGGTCGGAATAATTTAGGTTTAACTCTTATTGTCTGTAAAAGTGCTGAAAGCCTGAGTTCTTTTAAATCAAGATTAAAAACACATTTGTTTAGGATTGCCTTCGACTGTTCTAGTTAAACTGTTTCACTGAAATATAATT
->XM_024809453.1 [Candida] sorbophila hypothetical protein (B9G98_02896), partial mRNA 
-ATGGATCAACCATCTTTTACTATGGCCGAGCGGCTGTATAAAAAGGCGTACTCTGCTTCGTTCTGGAGCCAGAACGATTCTAAACACGGGTTTGACTCAGAGACCACGACTATTGTGCCGCATCTTGCCGATGCGCCCTTGTCTTTGAGACAGAAGGCACACATTTTGCTAGGGGTTTGCAAAATCATCTCGTCAAATGGGCGAATACTGAGTATAGAGGTTATACGGACCTGGAAATCGATGAACATTGTCAAATCTAAACCTAAAACAGACCCGCTACTGCTACCTGCTCGAAGGTCTCGCTCCCACACTCTCCCAGAGAACCCGCTCATCAACTTAGAGCTGGAAAAGGACTGGCCACCTTATAAACTGCCCAAACTCGCCTACACCCAGACACCGTCGCATTCCATCAGCGATTCTATTCGGTTAACAGACTTCCCCTTGGACCAAACCGAGTCCGACTACTCTTCTGTCACAGAAAGTATGCTTTCATACCAGAGTGATTTATTTGGTAACGCGAATCAGGTCTTGTTTGATCTGACGGAACATTCCGATACTCCTTTCAACCAAGTAACGCCAATTGCTTCGCCAGTTACGTTCAGTGAACCAGTCTACCCCGATGAACCGATCGAGCCTTTAGATTTCAGCGAACCGGATGAAACAGAGGACCCTACAGAAGCAAGACAAGATCCCTCAAGGAAATCTAAAGTGACTATTCAAAAAGAGATATTTTATTCCCAAGATAAACTAAATGAGTGGTTTGATGGCTATGATGAGTTCTGCAAAAATGCCTCTCGGCCATCGAAGAAAATAACATTTGAACGATTGTTTTGGGGTCGAGAAACTTGGTCTGCTAGGCATAATCGAAAACGCAGAGAGGCTGAGCTGCTGAAGAAAAACAAAGCAGCACCACCGGCCATGCCGACACCAGACCTGATAACACCAGACCAGAGCTCTGATGCGGATGAATCCCCTCATCTAGACGCTTTCGACAACCAATTTGATATAATGGATGATGCAGACAACAGTGATATTGAATTTGATGAGACACCGGGAAGTCCAATGCTGGAACTTCGAAAGGGGGAGTTTGAACACACCCTGGATACAGTGGGTCTTCTTCCTGAATCGTGGGATGAATTACCGCCACACCCACGTATCTCTGGGAGCTTTCAAAGAGACCAAAACGAACTTCAGGGTTTCTTACAACAGTTGACTGGCCAAGATGCGTTGATGGCTGGCCGAGTCACAGAAGAGGACGATGTGGCAATATTGGAAAAAGTAAACACCCTTGGTGGGAAATGTCTGTTTGATCAAGTCCACACAGCAACTCGTCTGAGTAAAGGGCATGCGTTTTTCTCGGTTTTGCGACTCGCTCAACAAGGCAAACTATCGCTGAACCAACCAGACGTGTTCGGAAAAATAACGATCCAGTCCTCATTTAGACCGCATTAA
->XM_044046427.1 PREDICTED: Solea senegalensis ret proto-oncogene receptor tyrosine kinase (ret), transcript variant X1, mRNA 
-TGATACTGAGGAGGACTTCATCTCTCTGTGTCTGCCCAGACAGAGAACCGCGCACTCGGGACGCACACTGGTTTATACATCGCCCTTTTTTGACTCTTGTGGCTTGATTTTTTTTTTTTAACTATTTAAAGATTTTTTGTATTCTTTTTGCCAAAGGAACTTTTTTGAAGTCACGTTTCATTCACAAACCTTTACTTATGGTGCGCGAAAATGGGGTTAAGTTCTGGTTTCTCTCGTGGAAACATCGCCGTGTTGATGCTGCTGCTGCTGCTGCTTGAAGGAGTGACAGGGTTGTACTTTCCTCAGAAGGAGTACATTGAGACGGTATACGTGGGCCAGCCTGCAGGTACACCGATCCTCCAGGTCCACGCTATGCTGGACAACGACTCCGAGCGGCCGCATTTCTACCTGTGCTGGAGCGCGCTCAAACGTCCACCCCACAACTCCTGGTTCCACATGGACATTAACACTGGAATATTGTCCTTAAACAAAACCCTTGAGGAGAGCGACTTCACCTTCCCAAATCAACATTCGTGGTCAGTGAAGAAGTTGGTCCTTCATGCCACAGTCTTACCCAACGTCTCCAGGAAACCTCACTGCATGAACAAAAACGCCCCTCGGATCACTCTGGACTTTGTCAACGCCACATTGCCACAGTGTGCTCAGACAGATATGAAGGAACTGTGCTTCCCCCACAGAGACACCGCCAACCCTCACATAATGGAGAACAGGTTCCCCGGGGCCATCAGGCAACTCCGACGTCTTACCAGACTCAACGTTTGTCCTAACTACACCATCTCTTATAATGTGGAATCAGAGACCCCAGCGCCATTTGCTGTGAACGACAACTCCACAGAGTTGGTGGTGACCGCTCCATTAGACCGCGAGGAGAGCGAATGCTACAGACTCCTGCTGGTCTGTACAGTCCGAACAGAAACAGTCATCACCAAGGTGGAGACTTCCCTGGACGTGTTTGTTATGGACGAGGATGATAACGCACCATATGTAAATGGAACAGACGCAACAGATATTATCATCAGCTTCAATCGTACAAAGGGTGGCTCCTTTGGAACCTTGTTTGTCTTTGACAGGGATTTAACCCCCATTTTTCACATTGACAAGAGTCACAGTAAGTACAGGGGGACCTTGCTCAACAGTGATGCATGGATAAATAAAACGTTTGACATAAAAGGCACCTTCAGTGAAAAGAAAGCTGCTCATGGAGGCATTCGAGAGACCATTCACGACTACCAGCTTGTCCTGAAGAGGAACCTGTATGTGAATGAGAATCGCTCCGTGCAGCTGGACTACCTGGTCAATGACACAACCTACCCTGGTGTGGAGGGAACAGTGTTGCTGCACTTCAACATCACCATCTTACCAGTGCACATCCGCTTCGCAAACGTCACACACACGTTCACACTGACACGTAGAGCTTCCGTTTATGCTCAGGTTGGCAGAGTGTGCGTGGAAAACTGCCAGCAGTTTGATGGCTTCAGTGTCACGTACCGCCTCGAGGTGCCAGATAGGAACGCATCTGCTGACTTGCAGTTCTGCTATGGAGCCATTAGCATTACCCAGTCTCCTGGCGAGATGTGGGGACTGCTCTATGTGAACGACTCGGAGGCTTTGCGCAAGCCCGAGTGCCAGGACCTGCAGTACTTTGTTGTCGCCCAGGAGGAGCACACAAAGCAGGAGGCCACCACACAGATCCACATCCAACTGGATAGTGAAGTAAACAAAGGCAGCCAGGAGAGCCAGCAGTTCCTGTCCTGTGCCGAAAACAGGCGACGGGGAGACTGTGAGTCTGTCCGAGGCCTGGGGGCAACCACAGGGAGCTGTCAGTGGAGGCAAGGCACAGAGAAAGGAATATCTGAATATTACTCAACCTGCTCGCCTGATCTGCGGACGTGCCCAGATAGCTTTTGTGATGCAGTGGAAAGCAAAGACCCATTAATATGCCCACAAGACTGTACAAAGGAGACCGTAATTGGAGGTCATGAACGAGGTTTAGGGAACGGGATTAAAGCTGGATATGGAACCTGCTACTGCTACTCTGAGAGATGCTTCTGTGAGAAGGAAGATATTGAGGAGGCGATATGTGATGACATGTGCAAGACCATCATCGCCACGTCTCTGCTGCTCTCCTTTGTCGCCTCCATCCTCCTGTCCTCATACTTCATTCACCGGTATCACAAGAACTCGCCGAAACCACCGATAGCCTCTGCAGAAATGACGTTCCGTCGGCCAGCTCAGGCTTATCCCATCAGCTTCCCTGCAAACAACTTACGCCGGGGCTCACAGGACTCTATTGAGCCTGATACCTTTAAAATCCCTGAAGATCCAAAGTGGGAGTTTCCTCGTAAAAACCTTGTACTTGGCAAGACTTTAGGAGAAGGAGAGTTTGGAAAAGTTGTCAAGGCTACAGCTTTCCGGCTGAAAGGAAAAGCAGGTTACACCACTGTGGCTGTGAAAATGCTTAAAGAGAACGCCTCACACAGTGAGCTGCGTGACCTGCTGTCGGAATTCACTTTACTGAAGCAAGTCAACCATCCGCATGTTATAAAGATGTATGGAGCATGCAGCCAGGAAGGACCATTGTATCTGATTGTGGAGTACGCCAAATATGGGTCGCTCCGCAACTTCCTGCGCGAGAGTCGGAAAGTTGGCCCGAGCTACATGGGCAGGGACGCCAACCGAAACTCCAGCTACCTGGAGAACCCAGATGACAGGGCGCTCACCATGGGCGACCTGATCTCCTTTGCATGGCAGATCTCCAGAGGCATGCAGTACCTGGCTGAAATGAAGCTCGTTCACAGGGACCTTGCAGCACGAAACGTCCTCGTCGCTGAGGGAAGGAAGATGAAGATCTCAGACTTTGGCCTCTCCAGAGACGTGTATGAAGAGGACTCGTATGTTAAGAGGAGCAAGGGCCGTATTCCTGTTAAATGGATGGCAATAGAGTCCTTGTTTGATCACATATACACAACCCAAAGTGATGTCTGGTCCTTTGGTGTGCTGCTGTGGGAAATAGTGACACTGGGAGGAAATCCATACCCAGGCATCGCTCCTGAACGCCTCTTTAACCTCCTCAAAACTGGCTACAGAATGGAAAGACCAGAGAACTGCTCAGAGGAAATGTATAACCTCATGCTTCGGTGCTGGAAACAAGAACCAGACAAGAGGCAGACATTCTCAGACATCAGCAAAGAGCTCGAAAAGATGATGGTGAAAAGTCGGGATTACCTGGACCTTGCAGCTTCCACGCCTGCCGATGCTCTGCTGTACGATGACGCCCTCTCTGAAGAGGACACTCCACTAGTGGACTGTAATAACGCCCCTCTCCCTCGAACCCTCCCTTCCACATGGATTGAAAACAAGCTCTATGGCATGTCATACCCGAACTGGCCTGAGAAGAGCCCGGTACCGCTCAACAGACATGATGCCACTAATCCAGTCTTTACAAGATATGCCAATGATAGTGTTTATGCAAACTGGATGGCTTTGCCTTCACCCGCAAAAGCTGTGGACAAGCTTGATAGCTAAAGACAAACCGACACTGTAGAAAAGATGACTAATTGGTAGATGTATATATTTCTATAAGACTGTATATATATACGATCTGATGCTAAAGTTGGTTCCCTTTTATTTCTGTTGCATGGGTTGCATTCAAGGTTTAAAGCTGAGGTGTTTTGGCTACTAAAACTGGCTGGATCAACGTAGACCATGCTTCATTCTGCTCTTCAGTATGTTAATTATTACCTCATGGGTCATGTTGGCCAAGTTGTATCACTGCATGACTAGTGTACCAGATTGTATGTCAGTGTCAATGTCTTTAAGTGCCTGTGCCGCTTCTACAATACCCTCCAATTGTTAATGTGCGACCGTGAAGATCTTGTTCCAGCCCAGGAATTAAAGGGGACGTCTTTACCATCACTGTTGTAGACAGCTGGGATTGAGTGGACAGAAAATGCTGAACTTGTTCTGCAAATGTAAAGTTTCTACTGTGGAGAATCCAGCTCCTCGAAATGTCAAAGGCCCATTTTGTGTTTCTCCCACAAGATTTTTCAAAGCTGTTGTTGCCAAAGAAAAAAGTAACACAGACATGTTCAGTGAACGAGTTCATATTCTTTTTTTTCTGTTTTCTGTTGCTTTTTTTTACATGACAAATATCAACTAGAGAGTGTTACTGCAGTGTGAGGACATGAGATTTAATGTAGATCGTGACAATGTTCTTTCGTCAGACTATGGTTCACTTTTTTTTGATTCACTGTAATTGCAATCTTTGTGGAAAAACCGTACGGTGATGTAAAGTAAGGAGTGTTATCATTGTCCTGTTATTATTTGATTATGTTACCATTAATAATAAACATTCAAAATGTGCAGTTTGTCTAAAGACGGATAAGTTTCTGTATGATAGCTTTTTTCACAATTGAAA
->XM_029888545.1 Pyricularia pennisetigena uncharacterized protein (PpBr36_01358), partial mRNA 
-ATGGAATCGTCGCTGAAGTGCAACACGCTTCTGTGCAGGACAGAGCTGAAGGACGAAGCTGTCGTCACCAGCTGCCTTCATGTTTTCTGTATTGATTGCGCTTCTCGCGCCAACTTGATCACTCCAGGCGCGGAGCATCTTCGCCAGTGTCCCGCATGCCGTTCGCCCTTGCCGGGTCCAGATCACGCAGTCCATGTCAATCTAAGACCTTCTGATGACTACAAAGGCAGCATTTTACGTGGATTAAGTCCGGTCGCTGTGATTGACTGTGCCAGTGCTGCCTTGAACTTTTGGGAGTATCAGATGGCCCAGGAGATCGTCTATCATGCCTACTTTGAGCAAACATTGACAGACAAATACTCACAATCGAGAGCCGAGCTGGACAAGATTACAGGAGAAGCAAATGGCCAGATAGGAATGCTGTCTGACAAGCTATCCGCGGTCACACTAGAACGTGACTCTGTGCGCCGAAAGAACGATGAGCTGATCGTCATGCTAAAAGAAAAGAACAAAAAGCTCATGCAAGTCCAGGAGCTATACGACAAGCTGAAACGCAAGGCTATGCTAGGTTCACTGCAAGACGGTGCCTCAGAGGCGGTTGATACAACCTTGGATCGAGTTGCAGCTGTTGGTGCCACGCCTGTAGCCGCAGATCGATACCAGCGGCTGGGGTTTTACCAACAACAGGCCGGCGACGTTAGACCTCATGGAGGTTTACAACCAAGAACAGGAAACACGTGGGACCAGCAGTTTAGACGCGATCGCATTGCAGCAACGCCAGAGCACAGAAACCATTCAAACAACACCGCTGGAATTAGACTTTCGAATATACCGGGCTTAGTTGTTGGCGGCGCGCCTCTGCTCAACCAGGACCGCCGTCACGGCTTGAGGTCAGAGCATCAGCACCTAAACGGTGTCCACGGTAACTCTGGGTATGGCGGTGCCAGTACCAACAACGGCCTTGGGCTGAACACAAGTGGTACAACTGGTGCTCTCCCGGGCGGAGCTGTTGGACTCTCATCCGCACAGAAACCAAGCTGTATGGACTCTCAGGATCCTTTTTCGATCATACTTAGAGCTGACTTTGGATATCTTCTCCAGTAA
->XM_033983629.1 PREDICTED: Periophthalmus magnuspinnatus butyrophilin subfamily 2 member A1-like (LOC117386288), mRNA 
-GAGGCGCTGTCAGAGTCTGATCCTGAGATCCGTGGACTTTGCACTGCACTTAACTGAAGGAATTTGACCTCAAACAAAACAGAGTTTCACTATGGGTGTGGAGATGCTCTCTGTGTTTTTACTCATGCAGACTCACTTTTGCTGGGGTCAGAACACACTGGTCGTTCCCTCTCAGCCAATCATAGCGCCCGTTGGTAGTGATGTCACTCTGCCCTGTCAGTTGGACCCTGTTAAAGACCTCAGGGACATGGTGGTGGAGTGGTCACGGCACGACCTGACGCCGCGCTACATCCACATCCGCCGGGACGGTCTGGACTTCCTCATAGACCAGAACTCCCTGTACCTGGGCCGCACCTCTGTGTCCGAGAGCCGACTGCAGCAGGGGGACATGTCCCTGAGTCTGACCCGAGTCAGGGCCAGTGACAGGGGCAAGTACAGATGCTACATCCCCCTGGTTAACGTCAAAGCAGAGGTCACTCTGATGGTCGTGTCCGTGGCCCCTCCCTCGATGAGCCTGATCAAAGAGCGCTCGGGGTCTCCCGTGCTGAGGTGTGAGTCCAGGGGCTGGTACCCGGAGCCGGAGCTGGAGTGGCTGGACTCAGAGGGGACGGTTCTGCTCAGGACTGAGGCTCAGAGAGGAGCGAGCGAGGAGCTGTTCAGTGTGAGCAGCAGACTGAGTGTGGAGCAGAGGCTCGGCAACACGTTCACCTGCAGAGTGAGTCAACAGGAGAGCGGCCAGAGCAGAGAGGCCCAGCTCAGCATCACAGATGAATTCCTGGAGGCCTGTCCCTCGTGCTCTGTGGCCTGGGTCCTCTTTAGTTTGCTGCTGTGTCTCGTTGCTGCTGCTGTTGCCTTTGCCGTGTGGAAGTTTCAAATCAACAAAACCAAGACTATGGAGAACAAACTTAAAGACTGTGAAGAAGGTGTGCCAATGATGAGGGAAAAAGAAGATGAGAAAATCCACAGAGGAGACGACAAACACAGAGGAGACGACAAACTGACTGAATACAAGGAGCAATTAGAGAAGATTAAAGAAGAGCAGACGTCTGCTGCACAGTTGAGTGAGGAACTAACAGGAACAAAGATGTTTCTAATGAAACTAAAAGAAAAACTAAACCAATGTAAGTATCAACTCAGCACTGACATGAAGGAGAAGGAGAAGACAAAGTATGACTCTAAGAAAGAGGAGAAAATTAAGAAAATGCAGCAGCAAATGGAGGAGTTTAAGAGCATTATTAAAGATGTTGACACAGAAATGTCTAAAATTGAGAAGCTTCTTTCAAAAACCAGTGAGAAGAAAGGGAAGCTGGATGAAGACGTCAGGCGTTTCACAAAACTGGTGCAACAACAGGAGGCAACAGAAAAGAAGAAACAGGAGGAGAAGAAACAGGAAACCAGGAATGAGGCTCATGATGACACCAGTGGAGGAGAGAATATGAACCCCAGTCCTCAAAAACCAGTAAACCCTCAGGAGCAGACAGAGGAGCTGCAGGCACAGGGGACGGAACCGGAACAAACAGACACAAATACAGAGCACTACTGAGAGAGAAGAAAAGTAAGTGGTACAGCATACCAAACAAAAAATGTAAAAATCAATAATCCATCAAAATAACTAAGTTTATTATTGACTACACGCACACGCACACACACACATTCATAATAGACAAGTGTCTTGCCTAAGGACACAACATTCTGTCACTTCTGTCCCGCTGTGGCTCCTGGTATCACACGTCGTCTCATCCAAACACTGACCAGGCCCCTGTTTATCTTCTGACGTCTGAGGAGATCAGGTTTTGACAAAGAGGTTTGGTCAAGTCAATAAACTTCATTATAATTTACAATATAAATAATATCTGAATAAAACACTGAAATACAGGTTTGAAGTCAGTGATAAATATTTACATTTGTCAGACTAATTGTGCTGTTTTCATCTCAGTGAAAATGTGTCTGAATGTGACAGTTCTGTTCATCAGTGTTTTACTCTGTTTATGTGGTGTCTATGACTGTGACATTATCCTCAAAGTTTGAACTGAACACAAAAATACAAACGTGACAGAGCGGATGAAGAGAAGTAATATTTTTTGTAGGACATGGCAAATAAGCAACTTTTATATCTTATTTTGTAACACTAATCCAAGAAATATGACTAGTTTTATACACTTAAGTTTGTGTTTGTTTACTGCTTGTTACTGTGGATAAAGTTTAATGGTTTGGTTCTTGTCATTCCATTCAACTAAACTAAACTTTTTAAAACGAAAAACTATGAATTATTTTTTTTATGTATTTGAAATGACTGTTTAACTGTGAAAAAATGTGCAATTGTGCCATCTGTTGGTGTTGAAAAGTAACTACATGTCTAAATAC
->KJ347058.1 Uncultured bacterium clone Evans.12.9_05674 16S ribosomal RNA gene, partial sequence 
-TACGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGTAGGCGGCCATGTAAGTCAGAAGTGAAAGCCCGGGGCTCAACCCCGGGACTGCTCTTGAGACTGTGTGGCTGGAGTGTCGGAGGGGTAAGTGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCTTACTGGACGATCACTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGG
->XM_027695588.1 PREDICTED: Neopelma chrysocephalum KIAA1217 ortholog (KIAA1217), transcript variant X7, mRNA 
-CTCCTAAATCGCCTTTATCTAGAAAAGAAGATTTTAACAGCCGATCACGAAAAATTAGGCTAGGTGAAAAGATTTTGAGAGCTGGCAGCGAAGGAAATCTGGTTAAACAGCATCAGCAGGAGCAGGTGGAAATCACAGAAGGGCTTGTGCCACGGAGGGCTCCTTTCCTGAAAGACCAGGCAAAAACCAGTTTGCATGTAACATCACTAGACGATGCAGAATGTCTCCGATCTAAAGAGCTCCTTTCGACCCCGAACAGTCACACCTCTTCTAATTCAAAGTCCACCCGCAACATCCCTCGAAGACATACAGTAGGTGGCCCTCGCAGTTCCAAAGAAATACTGGGAATGCAAACCTCAGAAATGGACAGGAAGAGAGAGGCTTTTCTTGAGCATCTGAAACAGAAATATCCCCACCATGCTACAGCAATAATGGGACACCAGGAGAGACTGAGAGATCAGACAAGAAGCCCAAAGCTGTCCCAGAGCCCACAGCCCAATTTGGGTGACCAGACAGAACACCTCTCTGAAGCATCTGCGGATTCCTTAGAGGCCATGTCTGAGGGTGATTCTCCAACCCCCTTTTCGAGGGGCAGCCGCACGCGGGCAAGTCTTCCAGTTGTGCGGTCAGCAAACCAGACAAAGGAAAGATCACTGGGTGTATTATATCTTCAGTATGGAGATGAAACAAAGCAGTTGCGGATGCCGAATGAAATCACAAGCACAGACACAATTCGTGCCCTTTTTGTAAGTGCCTTCCCCCAGCAGCTGACAATGAAAATGCTGGAATCGCCGAGTGTCGCCATTTACATCAAGGATGAGAGCAGAAACATATACTATGAATTGTGCGATGTGAGGAATATTCAAGACCGATCTTTCCTTAAAGTTTACAACAAAGATCCTGCACACGCATTTAATCACACTTCCAGAGCTGTAAATGGAGATATAAGGATGCAGAGGGAAATTGCTTATACAGGACGAGATGGCCCAAGTGGTTCCCGCCCTGGATCTGCCACGCACCCTCTGCATGCGATGCCCAGCTCTCCACCCTCCACCCCAGTGCCCCACTCCATGCCTCCCTCTCCGTCCAGGATTCCCTATGGTGGGGGCCGGCCCATGGGTGTGCCAGGCAATGCCACCATCCCCAGGGACCGTCTCTCCAGCATGCCAGCCTCGCGCTCCATATCGCCCAGCCCAAGCGCCATTTTGGAGAGACGGGACGTGAAGCCAGATGAGGACATGAGCAGCAAAAACCTTACCCTGATCCGAAATGAAGGTCTGTACGGTGACCCCTACTTGTTTCACGAGGGGAGGATGAGTGTGGCTGCACCGCACTCCGGACACCCCCTCGATGTCCCCGATCACATTGTAGCCTACCATCGCAGTGCCATGAGGTCATCAAGCACTTACTGCAACCCTTCAATGCAGCCTGAAATGCTGGAGCAGTCCTTGTACAGACAAAAGTCACGGAGGTACACGGAGAGCCATTTGCCCACTCTCGGCTCTAAAACACCTCCTGCCTCGCCCCACAGGGTGGCTGACATGAGAATGGTCGATATTCATCCTCACCATGGGACTCACATTCCCCACCACACCATCCAGCCTGACAGGTCTTCCCCCAGCCGCCAGTCCTTCAAAAAGGAGCCAGGACCGCCTGTGTTTGTGGATGCGAAAGCACGGAGTGCTGTTGGCCTCCCGGGCATGGCCGAGGCAATGCCCTCTCCAGCTGACAAGCAGGCTTTTGGCTATGGGTCACCTACCATGCCCAAGGACAAGGAGACAAGTGAGAAGATGATGTTGAAAATTGTGTCCAGCAAGAGCAGCGTTGACACTGCAGGTGTTTCTAACATGTCTGGGGGGAAGAATGCACTGGCAACTGTGGAGTCAGCTGTCGTCCATCACCCTGCTGGAGCCCTATCAATGCAAGTCAGCCTGCATGGTATGAAACGCAACGTGTCAGACCTGCGGCTGCAGCTGCATCAGATGAAGCAGCTACAGCTGCAGAACCAGGAGATGCTGAGGGCAATGGTGAAGAAAGCAGAGCTGGAGATCAATGGCAAAATGATTGAAACAGTAAAGAGGCTTGAAGATCCTGTGCAGCGACAGCGCAACCTGGTGGAACAAGAAAGGCAGAAATACCTCAACGAGGAAGAAAAGATTGTAAAGAAGTTATGTGAGCTGGAGGCATTTGTTGAAGACCTGAAGAAGGATTCTGCTGCTTCCAACAAGACAGTTACACTGAAAGATGTTGAAGATGGAGCCTTTCTTTTACGTCAAGTGGGAGAAGCTGTTGCTACTCTAAAAGGAGAGTTCCCAACACTGCAGAATAAAATGCGTGCGATCCTCCGAATTGAGGTAGAAGCTGTGAGGTTCCTAAAGGAAGAGCCACACAAGCTAGACAGCTTGCTGAAACGTGTGCGCAGCATGACCGATATCCTTACCATACTCAGGAGACATGTTACAGAAGGACTGCTGAGGGGTGTGGATCCATCCCAAGCCGTGCAATCCTCAGCTATGGAAAAGTCCACTGCAGCTGACACTCTGAAAAACCAGGAGGAGCACAAGTCTGCCCAAGGACATGCACAGCAGAATCTCACAGCAGTCACATCAGAATCCCAGGTGTCATCAGTGAAGTCAGAAGTCATCCCCTTCTCAACAATGACTGTCCATCACGTGCAGAGCTCGCCAGTTGTCATCCATCAGTCTCAGCACTCATCAGCCCTGGTCAACCATGCCCAGGGCTCACCCACTGCAGGCACTCACAGCGAAGGTGTGCCAGGTCATCTCTCAGCCACCCCGCCAGCCCCCCTGCAAGAGCCCACAACAGGATCCCAGCCCACACAAGCCACACCAGCACCACAGGTCTCTGTCAATGGCACCACCATGCAAAGTCTTTTCATTGAGGAAATTCACAGTGCAAGTACCAGAAACCGAGCTGTATCAATTGAGAAAGCTGAAAAGAAGTGGGAAGAAAAAAGACAGAACCTTGATCACTATAATGGAAAGGAATTTGAAAAGCTCTTGGAAGAGGCCCAGGCCAATATAATGAAGTCAATTCCTAACCTGGAGATGCCTCCCCAGCCAGCAGCCCTGCCTAAAGGGGATGCAGCAGAAAAGCTAGAAGTCTCAGAAGAACTTCCTGATGGAGAACAGGATAATGACAAGCTGACCAAGTCTCCACCTCCTCCACCTCCACGGCGCAGTTACCTGCCAGGGTCAGGACTAACCACGACGAGATCGGGAGATGTTGTCTATACAGCCAGAAAAGAGGCTGCTGCTGTCAAGGAATGCAGTGAGGATGCTGGGCAAATAGCACAATCCAAAGCCCCTAAAGAGGATCAGGCATTGTCTCGGAGCACAGGACATGCTATAGCATCAGCTGCAAAAGATGAAGAGGAAGAGGAAGGGGATAAAATAATGGCTGAATTACAGGCTTTCCAGAAGTGCTCTTTTATGGATGTAAACTCAAACAGTCATGCTGAACAGTCCAGAAATGATACACATGTTAAAGACATAAGGCCTGGGACTTTAATGCATCACAAGGAAAAGAAGGTGTATGGGGCTACAACAGGATCTCCCACAGATAGTGATCATCCTAAAGAGAAGAGGGAAGGGAAAACTGAAGAAGAATTGGGTTCTGATTCATCCAGTACAGCTGACAGTAAAATTGGCTTTTCAATGAATGACAGTCCTACATTTAGCAAGGGTTTGTTTGTAGACAGTACAGACTATTCTAACAAAAACCTTCAGAATAAGAGCACAAACCTGTCTGGTGTCAGTTTGCCAGAGGATGACAGACGAAGAGGGGCTCAAGATATTTTAGGATCCCATATTCCAGCTGTTGAAACTGGAAAACAAAAGCCAAACTACAAACTCTCAAGAGATGCTCACCAGGGCCTGCCACAGGGTGAAGTCTTGCAGAGCACAGGCAAGCACATCCCTATCAGCAGCGTTGCCCCTCTCGTGAGGCAAAGCCAGGAGGCCACAGGGCCTCAACCTGCCTTGCAGGAGCAAGAAGGTTCTGCAGTGAACTACAATCAGGTTGTGCTAAGACCCAAAGTGTCCAGAAGTAATAGTGTGAACAGCATTGAAGAGACAGACTCTCCAGCCACCTCTCCAAGTGAAGATGGCCCACCCACAGAAAACATCGCCTTCATGATTACCAAAACAGCTGTGCAGGTCCTCTCAAGTGGAGAAGTTCACGATATAGTCAGCCGGAAAGGAGGAGATGTGCAAACAGTGAACATCGATGCGAGGAAGGACGTAGCATCAGAAAAGGGTATCCCAGAGAACACAGACAGCGAAGAGCCAGTGGTGTGTCTGGACAAAAAACCTGTCATCATCATTTTTGATGAACCAATGGATATCAGGTCAGCATATAAGCGGCTTTCTACAATTTTTGAGGAATGTGATGAGGAGTTGGAAAAAATGATGACAGATGAAAAGATAGAAGAGGAAGAGGAGGAGGAAGACAATGAAGCACATGATGTCTCTGAGAGCCAGAAGGAAGAGTCACCAGTAGTTAATGACAGAAAAGCAACTGCAGAGCATTCAGCAGCTCACAGTCTCCAGGAGCCGTACCTGTTTAACCTTCAGTCTGACTCTGCAGAAAGCAGACCTCCTGCAGAAGAGGAAAGCACAAAGACAAATTTGAACAAATACCGTCAGATCTATGGGCTAAACACAGAAGCAAACTCAGACTCTGCCGATCAGTTTGGAAGCAGGCAGGATTCTAAGAAAAAATTTAAGTTTAAATTCCCTAAAAAGCAGCTGGCTGCTCTGACGCAGGCGATACGGACAGGGACCAAGACTGGGAAGAAGACCTTACAGGTTGTGGTCTATGAAGAAGAGGAGGAAGATGGGACCCTGAAGCAGCACAAGGAAGCGAAGAGATTTGAAATCACTAGGTCTCAGCCTGAGGAGAGTGACAAAAGTCCTTCTGGGAAGCAAGAGGGACCCTCCGGAGCTGCAGCGCCCCTATCTAGGACTGATGAAATTCGACAGAGCACATACAGGACACTAGACAGCCTTGAGCAGACTATAAAGCAGCTGGAAAACACCATCAGTGAAATGAGTCCAAAACCTATCCCTGAAAACACATACACCTCTGAGGGAAGTACTGTCCCCTTCTCTGCCCAGATAGTAGCAGAGACCCCATCCCGAGAGCGTGTAGTGCTGGATGAGAACCTTGCTGGTGTAGAGCCCCCTGCGTCCATCCCAGCCACTTCACGTAAGGGCTCCAGCGCTGCCTCCCAGACAAGCCGGATGCCAGTCCCCATGACTTCAAAAACTAGACAAGGAAGCATGGAGAAATCCGGCAAACAGCACAAGCTGCAGGATCCACGCCAATACAGACAGGCTAATGGAAGTGCTAAGAAAGCTGGTGGGGACTGTAAGGCTACTTCCCCTACCCTACCTGCTTCTAAGATCCCAGCCTTTTCTCCCACTTCTGGGAAAAGCAGCTCAGCACCTGCTTCTAGCGGTGACAGCTCTAACTCTCTTAATCCACCTACTAAAACCTCCATTCCTTCCTCCAACCTTCTTGGTCCTCAGTCAGGTCGCATAACTTACTCTACCTCCCTCATCCCCTCTGTCTCTAACGGCTCCTCCAAGTTTCAGAGCCCCACTTACCCAGGGAAAGGTCACCATCTCTCCTTCTCACTACAGACTCAAAATGGCCGGCCACCCCCTCCTTCCTCCTCTACCTCCCCCCCCTCCTCTCTGTCCCCCCCTTCACTGAACCAAGGTATGAAGAGCATCAGGACAATCCACACACCTAGTTTCAACAGCTACAAGGCACAGAATGGAAATGCCAGCAAGTCCACCCCATCCACGGTCAAGGAGCCATCCTAAAGGCTAAGCACGGCACACCTGCCAGGTCACCAAGGCTTTTTGTTCATTTTCTGCAGCCAATATTTTAACCAGGGAATGTAACCATTTAACTGTATTGCTGGAGGCTTAATACTAATCACGTGCTAAATACTGAATTACTACACTAGATTAGAGTGAAGCTTTTTGGAAAACTGTTGCTGTTGTACTGATAAAAGAGCATTTTCTTCCTATAGGCAGCACCTCTTACAAAAAGTGTGAAGGTGTGTGAGTGAACTTGACTGCGCGTGCACAGCGGTGTACTGAGCATGGGGAATTGTATGGTTAAAAATTTAGTAAGTTGTTTTGTATAAAGCTATTTTTCATTATGGGGTCTAGAAGTGAACAGAGATATACTAAAGTGTGATTATATTCAATTGTAAAACTGAAACTAAAATATTTTTCTTTTATTTTGGTGTTATTTAGCTTTGTTACAGATTTCTATTTTTGTCAACAAATGTCATGGTTCCTTTCGAGATCTTTTTGCCAAAACATTTTGATACTATTGTAATGTACATTTGAAAGTAGTATGCTGGACAGTAAACCTCTACACAAGAAACAAAACAAGACTGGTCTTATGTGTGTATGAGGCAACTCAAACTATTGCACTGCCATTCAGATTATATTTAAGAATTTGCCAGCCAAGAAAAAAATAAATTGTTTTACACATATAGATAGTTGCTGATTACTTTTTTTCTTAGCTAAATCCACCCTTTTTCCTTCAGTTTTATTTTACTGAGACCTGGTAGCCCATTAATGCATTGCATTGTGGATTTTAAAATGTACACTTCAGTACTGTTCTGTATACTGGCAAACTTTTGTACATATCTATAAATATCTATAAATAAAGAAATACTGTATGTGGCTGGGCA
->XM_001989357.2 PREDICTED: Drosophila grimshawi DNA-directed RNA polymerase II subunit RPB11 (LOC6562570), mRNA 
-CCATGAAATTGCTTGTGAACACAAGCCAAATATAGAAGAAATATTTCGCAAACAGTTTTAAACTTTTTATATTGACTTTTTCATTATCGATATGTAAAGAGGGCTTCATAACTAGACAGCACATTGATATAAATACCACAAACATCGCGTACATGCGATAGATCGACTGTGCAGTGTTGTTAAGCATGTGCGCACTTCAAGCGTTTAACAGCACATACTCAGCGCATTATTTTCGTGTCTGCAGTTGATTTTCACAAACAATTGCAATTTTATAAAACATAAATAAATAAGTAAATTAAAACAGCAAAATGAATGCACCGCCCACATTTGAATCGTTTCTGCTGTATGAGGGCGAGAAAAAAATAATCAAGGAATTGGATACGAAGGTGACAAATGCGGCGATATTCACCATCAACAAGGAAGATCACACGCTGGGCAACATGATTCGCAACCAATTGTTAAAAGATCCAAATGTTCTGTTTGCCGGCTACAAAGTGCCGCATCCGCTGGAACATAAATTCGTGATTCGCATTCAGACAACGGCCGATTATTCACCACAGGAAGCATTCATGAATGCCATCACTGATCTGCTGGCGGAACTATCGCTCTTCGAGGAGCGATTTAAGGATGCTATTAAGGAGAAAAAGGAGGGCGGCGATTAGTTTTACACATTTTTATTTTCGACAAGAAATTTACGAAACAATAGAAATATATATATTTTCACTAATTTGTATAAATAAATAAAAGTAATATATGCTATTAGTGAAATGTAATAGTTTCTCAGCTGAGGTAAAAGAAAAAAACAGA
->XM_027211675.1 PREDICTED: Coffea arabica probable tocopherol O-methyltransferase, chloroplastic (LOC113693095), mRNA 
-AGTGCCACATTGTTCCCTCTCCCTCTCTCTCGTTCTTCTCACAAGTTGTCTTGCGTGCTGCTTTGCTTCTCAGGACACGTTGAAGCTTTTGTTCTTTGCTAGCTAGGATTGTGCGGTACAACCAACAATAATGGAGGGGGAGAAGACGGATACCGAGGGAAAGGTGGAGACAGAGAAGATGAACAAGGAATTTGCGATGACATATGATGTCCACTCTAAAATGTTAGAGGATCTAGTTGGGGATCACTTCCATTTGGGCTTCTATGACTCTAGCTCCGTTATCCCTGGTTCTGATGTCAATTCTGCTCAGACTCGCATGATCGAGGCGGCCCTCCGTTTTGCCTCTGTATCAGAGGATCCATCTAAGAAACCAAGAAACATACTTGATGTTGGATGCGGTATTGGTGGCAGCACCAGGTACCTAGCAAGCAAATATGGTTCTCAATGTAAAGGCATCACCCTTAGCCCTTTTGAGGCTGAAAGAGCTCGTGTTCTAACTGCTGCCCAAGGATTAGAAAGCCAGGTCTGTATTGAAAGATTTGCAAGAAGTTATCAATTGTTAAATCACCCTTTATGCAAGTGCACAATGAGTAAAAATTTTCATTCTTCCATTTCTTAA
->XM_018222954.1 Mollisia scopiformis ARM repeat-containing protein (LY89DRAFT_786121), mRNA 
-CTCTAAACTGCGACCAAGGAGCCCACGAACGCGAAATAAGGCGCCAGGACTGCTTGGTCATGACAATATTCTCGATTCTACAATATGACTGAGGTGGAGGTCAACGGGATAGCGGCGGGCGTGGTGGACCTAGATCTCAAAACATCACTCTCTTCTTCATCAACTTCAAGGCGGATCAATACCCTCGCAATCTTGCAGGAGAGGCTCTCAAAGAATGAAATCAGCCCGAAATTATTCCCCCCTCTTCTACAGCTGTTATTTGACACGCATGCATACTATCGCGACCGCCCCTCTCGTCGAGCTGTTGAGCAATGTCTAAGACTTGCTTTTCGCTCAGGCTGTGCTCCTCCAGCATTAGCGGGCTTCATCAAGAATCTAGAGGCCGAGTCTTTGAAGCTAGGGATCGCCCCCAGCAATGCTTTTGTTCTGGTAGAATGGTGTAGCATGCTTCTGCAGGTGCTGACTGGAACCGACTACTGGGATATCTGGGGCTTCCAAGTTCTCGAGAGCCATGCTCGATTGCTGGAATTGTGTGTTGGAGAGTCTCCGCGGGACAACATTAGACAAACCGCACTGCGCGTCACATGGCGAGGACTCCGGGAGGCATTCTCTATACCCGAGAAGAGGCAAAATGTGATGAAAGGAGCTATCCAGAAACTTGCGTCAAAAGGTGCTCAGTCATCTGCGAAGAATGCTATCATGCTTGGAGCTATCGCTGGAACATGTGCGAGGAATTTCCAGAAAGAGTCCACGAAATCGTCAGAGATGAAAGAATGTCTCACGAACAAGAAATCCGAATACTACGCATTCTACATTCGAGAAATCATTGGTTCGCGGACTCTTGTACCAAGCCACATATCGAATGCTTTACATGACTTCTTTGCTTCGTTCGCAACAAAGGAGGACATAGAGAGGGAGATTGTTCCTGCTCTGGAAAAAGCTCTGCTTCGTGCACCGGAGATAGTGCTCAATGATCTCGTTACGCCACTGTTTCGTTCCCTTCCTGATACGATAGATCTTACAAGTATTCTTAAGAACAACCTTCTCAAACCTCTGCTTTCCAATATCAAGTCAAGCAATGCTACTATTCGCTTAGGAGCGCTTTCGGCACTTCGTGCTGCGGCTCCCAAGTGTCACGAGGTGAATGTTATTGCTGAGGTTGCAGAAGAGATTGTTACCCCTCTCAAAGCTGGAAAATTGCCTTCCGCTGATCAGAGAGCTAACCATGCCGAGATGCTTGCTCTACTCCCTGTCACAGAGACAACAGCTACCAAGATTGGTTCAGCTATTACCGCCGTTGTCGGCAAAGAAGCAAACGAGGCAGCGCTTACATCGGAGACATCAGCCCTCCTGCATTATGTAAGTTGGGCAATACAGCATGGAATGGATCTGGATAAGCAAATGACAGATGCTTTCACCAAAGGGATCTCGGATAAAAAGGTACCTTTCAAGAGTCTTTGGACCGGACGACTGGGTGAACTGTTCTGGGCCACGGATGATCATGAGATTTTGCGAGGCAAATTAGCTAAACTCGCTGAATGCACAATCTCACCTCTTATGGATATCTGGCAGGAAGTCACGGCGAACCCTTTGGCTGCAGCACAGTCTGGTCTCGTCGCCAGCGCTTTTGTGCTTACTGCTATTGCCTTTACGAAGCTACCACATGTTTCGAATAGCAAGGTTGATACGGCTCTGAAGAAAGCTCAGATAGGAAGACAAGCCTTGGTTATGGAGCCAAAACCTTCCTTCCTGTTGAACCCACGCATTTATGGGAAGCTTACAAGTGAGGAGGATTTCATCTGGCTTCTTCGAGCTCTTGCATCCACTGCACAAGATGTCGTTACGTCTGATACAGTTTCACCTAGCTCTATTGCCTGGTCTCAAGCCGTAATATTCTGCATATGCTCTTCAACCGTCAAGCCGAGTGTTAGAAAGAATGCTTCCGAAACCTTGACTAAGCTCTACCTCAATTATCCTTTAGCAATTGTCAAAGTTATCGTGTCGGGACTTTGGAGGTGGCGAGACTCCATCGAATCAGGCGACAAGGATAGTGCTGCTGTGTTGTCTAAAACAGAGAACAGCAATATTCACCATGTTATTCGAGCCATCTGTCTATCCCCAGCAGAAGTCACTCAGCTTGGTGGTCAAGTCGAAATGTCTGTCCGGATGGAGCAGATGATTTTACTGTTGGTTCTATCTCGACAGGAATTGTTACCGCGAGTGAGCTGGATCCAGCTGTGTCTCAAAGTTGAGGTAGATCCTGGCAACCTTGCCAGGAAATCTGGAGATGCTCTGGTTCAGCAGATACTTGATTGCACTAGATTTGACGAAAAAGCGACCTTCCAAAGATCCGACAATGTCAAGATCGCTGCTTTCCAAGCAGCAGCAGAACTTGCCTTTGTGGCCCCCGATGCAATGACCCCTAGAATTGTAGAGCTTCTTGAAAATGATCTGGACTCAACTCAATTGACTAACATCGGCCCAACAGAGGCGGCTATCTTCAGAACAGAAGAAGGCACGGCTTTTGTCGATGTGCTCGCGTCCAAGTCCCAAAGCTATGTTCCCAACAAAAATACAAAAGATTACGACACTTTGAAGTGGGAAGAAGAGTTACGAGCTCAGCTCGCACAGAAGAAAGGACAACAGAAGAAACTCACTTCCGAAGAAACTGCCAAGGTTAATGCTCAGTTGAAAAAGGAGTCTGCTATTCGTCTGCAGATTCGCCACCTTCAAGCAAAGCTCCTCCGTGGGTTTGGTATCATCAACAGCCTAGCCACAGGACCGCCTACTGAAGCAGGTCTTTGGATGGGGCCGGCTGTCAAGGCATTAGTGGAGGTAATTAAGGCTGGTGCTGGGCTCATCACAGGCAATGCAGCTCCCGATGCGTACATTGCCTGCGCAGAACGACTTCCGAGCCGCGTTGGTGCTCTGAGGCCATTCATAGGTATCGCGACATTGAGAGCTTTAAATGTACCACACCTTCCAGAGCATCTAGAGGAAGAGCCTCTAGGTGCGTTGATTACCAGAGTCCTTTATCGACTTCGCTTCTCTGGAGAACAACGACCTTTCGATACAGTCTCCTTGATCTACATTCTCCCTCTTGTCTTTCTCGTCCTGCGCGAGAAAGGCTTTGGAGAGTCTGATGACGCTGAAGCTCAGATTGTCTTAGCTTTAGAATTCTTATCTTACCATACAGATGCCTGCTCTGACGAGCTGGTACCACGCGAGGAGATCTTGTCTGTGCTAATATCATCGATGCAAAACTATAATCAGCATTACAAGATGATCAAAGATTGTCTGGCAGATCTTTGCCGTTGTATTGCGCCGAACATAACTGAGATCGAGCTGTCAATCCTTGCCCGCGGAGCAATTGTCCCGCAAGTTTCGGTTCGTTCCTCAGTCCTACAATCAATTAGTGCTGAGATCGATATGAGTGATGTAGACTTCTCTGACGAGATATGGCTCGCTTGTCATGACGACGTGGAAGAGAATGTCGAGCTTGGAAAAGAAATTTGGGAAGAGAGCGAATTTACAGTCTCCGAAGATGCTCCCTTCAGGATGCTGCCTTATCTCGAGATTGTGGACAAGCAATTGAGACGAGCGGCGGCAAGATCGTTAGCGGCAGCTGTGAAATTACGGCCATCAACATTTCAAGATGTGTTAGAACGCTTGAAGTCGACATATCAAGAGCTTGCAAAGCCCCGTGTGCCCCAGCTCGACGAATACGGCATGCCCAAAAAGATGGATCTGTCGGATCCCTGGGAGGCTAGAAACGGTATAGCTCTTGCGTTCAAAGAGCTAGCTCCCATTTTCGAGATTAGCCTACTTATTGCATTCTTGCAATTTCTGATTGAAGCTGGTCCTCTTGGCGACAGAAACCCAAATGTGAGAGAAGAAATGGTAGAAGCAGCTACCAGTATTATCGCACTTCACGGCAAAGACAAGGTGGAGGAACTAATGAAAACCTTCGAACAAACTCTTGAAGCTCCAGACAAAGGCTCCGAATTCGCGGATCGAGTCAATGAAGCTGTCATCATCATGTACGGAGCTCTCGCTCGACATTTGAAGGCGGGAGATCCACGAGTTCCTAAGGTAGTGGAGAGGCTGCTAGAGACTCTGAGTACACCTTCTGAAGCAGTGCAATACGCTGTTGCTGAATGCTTGCCGCCACTGGTACGTGCGTCGAAAGAGCAGAATCCAGAGTACATCAGGCATGTTCTCGATCGCTTGTTCAATTCCAAGAAATACGCTGCTCGTCGCGGTGCCGCCTATGGACTTGCAGGTATTGTTCATGGCATTGGTATACTAGCTCTGAGAGAATATCGTATCATGTCAACGTTGAAAGGTGGGATTGAGAACAAGAAGGATGTCAATCATCGTGAGGGTGCATTGTTGGCATATGAATTATTCTCAACGATTCTAGGGCGAAACTTTGAGCCTTACGTTATTTTAATCGTACCCCAGCTCCTTTCCAGCTTTGGAGACGCCAGTGCGGATGTACGTGAGGGTTGCTTAGCAGCCGCAAAGGCCTGTTTTGCAAGTTTGAGCTCATACGGTGTCAAGCGAATATTGCCTACGCTCTTGGAGGGCCTTGATGACCAACAATGGAGAAGTAAGAAGGGAGCATGCGACCTTCTGGGTGCTATGGCCTACCTTGATCCTCAACAATTAGCCCAGAGCTTACCTGAGATCATTCCACCATTGACTGGGGTACTCAACGACAGTCACAAAGAAGTTCGACTTGGCGCAAATCGAAGTCTGAAACGCTTTGGTGAAGTCATCAGCAATCCCGAGATCAAAGGCCTTGTGGACGTACTGCTTAAGGCTCTTAGCGATCCTACAAAGTACACAGACGATGCTTTGGACTCTCTCATAAAGGTACAATTCGTTCACTACCTGGATGCACCATCACTTGCACTTGTAGTTCGCATTCTAGAACGTGGACTAGGGGATCGCTCGGCGACCAAGAGGAAATCATCTCAGGTCATTGGCAGTCTGGCCCATTTGACGGAGCGAAAGGATTTGATCTCGCATCTGCCAATTTTGGTCGCTGGTCTCAAAGTTGCTGTGGTTGATCCTGTGCCCACCACACGTGCAACTGCCTCGAAAGCCCTTGGCTCACTGATCGAGAAGCTTGGCGAAGATGCTCTACCTGATCTTATCCCAGGATTGATGCAAACACTGAAATCAGATACTGGTGCTGGTGACCGACTCGGATCTGCTCAAGCTCTGAGCGAGGTCCTTGCTGGTCTCGGTACCAGTCGCTTGGAAGAAACACTGCCCACAATCTTGCAAAATGTTGCTTCCTCAAAGCCTTCTGTCCGAGAAGGTTTCATGTCACTCTTCATCTTCTTGCCTGTTTGCTTCGGCAACAGCTTCGCAAACTATCTCAGCAAAATCATTCCACCAATTCTAAGTGGTCTGGCTGATGAGATCGAGTCCATTCGTGACACCTCCCTCCGAGCTGGACGTCTTCTTGTCAAGAACTTCGCAACTAGAGCTATCGATCTCTTGTTACCCGAGCTGGAACGAGGTCTTGCTGATGACAGCTACAGAATTCGTCTTAGCTCTGTGGAATTGGTGGGCGATTTGTTGTTCAACCTCACAGGCATCAACGCCGGTACCGAGCAAGATGAGGTAGAAGAAGGTGCCCAGGAAGCAGGAGCCTCGTTACTGGAAGTCCTTGGAGAAGAGAAGAGAAACAAGGTCCTCTCGTCTCTTTACATTTGTCGTTGCGATACGTCTGGCTTGGTTCGTACCGCCGCAGTCAATGTTTGGAAGGCTCTTGTGGCCAGCCCAAGAACTCTTAAGGAGCTTATCCCAACATTGACCCAACTTATCATTCGCAGACTAGGAAGTTCCAATATGGAGCAGAAAGTTATTGCGGGCAACGCACTCGGCGAGTTGATTCGAAAAGCTGGCGACGGAGTCCTATCCAGCTTGCTTCCTACACTAGAGGAAGGTCTGCAAACATCGACAGATACCGATGCCAAGCAAGGTATCTGCATTGCTCTTCGAGAACTAATCTCATCTGCTTCTCCTGAAGCTCTGGAGGATCACGAGAAGACTTTGATATCAGTAGTCCGAACCGCTCTTATCGATTCCGACGAGGAAGTCCGAGAAGCTGCCGCAGAAGCTTTTGACTCTTTGCAGCAGATTCTTGGCAAGAGAGCTGTCGATCAAGTGCTACCCTATCTTCTTAACCTGTTACGCACAGATGAAGACGCAGACAACGCTCTATCTGCCCTCTTAACGCTACTTACCGAGACAACAAGATCAAACATCATCTTGCCTAACTTGATCCCAACCCTCACGACCTCTCCAATTTCGTCTTTCAACGCCAAAGCTTTAGCATCCCTATCCACTGTCGCTGGCTCTGCCATGACCCGAAGATTGCCTACGATATTGAATGCGTTAATGTCCAACATCATCTCCTGCAATGACGAGGGCTTACTCGAAGATCTCAACACATCATTCGACACCGTGATCCTTTCGATTGATGAATTTGATGGTCTGAACACGGCTATGAGTGTATTGCTTGGGCTCTCGAAGCACGATGACCACCGCATAAGAGCAGCTACTGATCATCATCTCGCAAAGTTCTTCGCTGCGGCCACTGTGGACTACTCTCGCTATAACCAAGATATCGTAAGAGCTTTACTTATATCTTTCGATGACCGGGATCCGGACGTAGTTCTAGCCGCCTGGACCGCGTTGAGCGAATTCACTAAACACATAAAGAAAGAAGAGATGGAAGCTCTTGTGTACTCCACACGACAAATCTTACAACATGTTGGAGTTGCTGGATCAAATCTGCCAGGCTTCAATTTGCCTAAGGGCATCAATGCCATCCTACCTATATTTTTACAAGGTCTCATGAATGGCACCGCAGAGCAGAGAACACAAAGTGCTCTTGCCATCTCGGACATTGTAGATCGTACAAGTGGGGATGCTTTGAAGCCATTTGTCACTCAGATAACTGGACCGTTGATCAGAGTGGTATCCGAACGCTCAGTCGACGTAAAAGCAGCGATTCTGTTGACTTTGAACAATCTCCTCGAGAAGATTCCTACATTCTTGAAACCCTTCTTACCTCAACTTCAGAGGACTTTCGCCAAATCCCTGGCAGATACATCAAGTGAAGTTTTGAGAACTCGAGCAGCCAAGGCACTAGGCACGTTGATCACACTCACTCCTCGAATAGATCCACTCATTGCTGAGTTGGTCACTGGATCAAGGACTTCTGATTCAGGTGTTCGTAACGCCATGCTGAAGGCCCTCTACGAAGTCATCAGTAAGGCAGGAGCGAACATGAGTGAGGCATCTCGAAGCGCTGTTCTTACTCTTATCGACACTGACCCAGAGGATAATGATGTTTCTATGGCAATCACAAATGCTAAGTTACTTGGAGCTCTGATTAAGGTTGTCCCCTCGGAGAGTGCTGTTGCCCTCATCAAGAACAGAGTCTTACCAAGTCACTTCACTCAGTCCTCTGTACTGGCTCTGAACGCTGTGCTGCTAGAATCCCCAGCGACTTTAACGGAGACTGCCTTCGCCGATAGCTTACCACAAAGCATCTGTGAAGGCATGCAAAACAAGAACAACTTCATTTCTGACAACTGCGTCCTCGCGGCCGGAAAATACCTTCTATCCGACTCACGCAGCAGTGACTATGAGACGATCAAGCCAATATTCGAGACACTTGCCACATTGATAGGACCTGGACAGTCGGCTGACACTCGACGTCTAGCTTTGGTGGTGGTGCGAACTGTGTGCAGACATCACATGGAGCTCGCTCGTCCTCATCTTCCACTACTCGCACTTCCCGTCTTTGCTAGTGTTCGAGATACCATCATTCCTATCAAGCTGGCGGCAGAAGCAGCATTTATGGCGCTATTCAATGTCGTAGATGAGGAGAGCAAAGTATTCGACAAGTATCTTGCATCTCAAGATCTAGCTGCCAACCAAAAGCGGAGCATGCAGGATTACTTTAAGCGTGTTGCATTGAGGCTGGGAAATACTGCACGAGAGAGGAAAGAGGCAGAAGGTGGACAGGGCGGCTTGGGACTCTCTCAAGATGAAGTTGATGATGAAAAGGAGATAGCTTCGGTAGGAAGAGTCGACCTTGGAGAGGGAGCTTTTGATGAGTGATGAGTTACGAAAAGGCATGGGAGGTGGTCAAAAAGCGTGCATTGTATTTGGAGGGATCGTTTTTAGACGAATGAATTCTTGCG
->XM_047966548.1 Annulohypoxylon maeteangense uncharacterized protein (GGS22DRAFT_23129), mRNA 
-CCTGAATCACGGTCATTTTACATCATCTACATAGTCTACAAATCGTAACCATATTCCGCAGACTCAGTCAATTGTTTTCTTAACGAAATAAATATGGCCGATCAACCTCGTCGGCGTCGGAACCGCCCCGATAGCAAACAGATGTGGGATGAATCCGACCGTCGCAACCGCAACGAGCCCAACGCGCGCGACAAACGAGACGACCGCGGCCGGGATCGAGACGAACCACCCCGCGAACGAGAACGAGACCGCCGCTATAGATCCAGATCCCGATCTCCTCGACGAGACCGACGGGACAAGAACCGCGACCGTCGAGACAGGGACCGCAACCTTGATAGGGGTAGACCACGTGAGAACGACGAAGCGCGGCCTAGAGCAGACGAGCGTCGCGAGAAGAATAAGAATAAAGGAGATCGTCATCGCGATAGAGATGAGCCTGCTCCAAAGGGTCCGGCTCGAGATCGAAGTCCCCGACGCTCTGCATCGCCAGCTCGAAGCCCGGCTGGGAAGGTAGATCGCAACACGCACAACAACTCACCACTCCCAACGCGACCAAGACCCGGCGGAAAAGCTGAATCAGGGTTGGGATCCTCGCTTCAGTTTAAGGTTGGAGGAAAACATGACGACGATGCGAACCGTGGAGGGAAGAGTGCGGCGGGAGGCAAATTCTACGATGCCAGAGGTTCTACTGATGAGGCTGAGGACCGAAGACGACGAACCGAGACGCCAAATTCCGACCGCGGGGATGCCATGGACGAGGATGTCGACGAAGAGGATGTTGTTGTCGAGGATGACGGACTAAGTGCCATGCAAGCAATGATGGGATTCGGCGGTTTCGGTACCACAAAGGGAGCCCATATACCAGGCAATAATGCCGGCGCAGTGAGGAAGGAGAAGAAGACCGAGTACCGACAGTACATGAACCGTATCGGTGGTTTTAATCGCCCGCTGAGTCCATCGCGGTAATCGTAATACCTACCTACTGTTTTTTTATTGCTTTTTTTGATACACTACGAATCAGACTATGGAGAAGATGAGTTTCCTTGAAAGGGGCGTAGGGAATACACGGACCAGAGGTTAGGTGCTCTTAATTTGATGATCATTATAATCCTTGTTG
->KF726604.1 Pseudopachylus alticola voucher MZUSP:59952 16S ribosomal RNA gene, partial sequence; mitochondrial 
-GCATAATCATTAGTTTTTTAATTGGGAGCTGGAATGAAAGATAGAGACTGAAAAGATAGTTTTTTTTAATTAGTTTGAATTTAAATTTAAAGTAAAAATGCTTTATTTATTTCTTGGGACGAGAAGACCCTAGAAGCTATAAATTATAAAATAATTTTTTATTGGGGCAATAGTTAAAGAAATTAATTTTTAATTTTGGTTTATGGAAAAAAAAAGTTACTCTAGGGATAACAGCGTTATATAATTAGTGAGTTCTTATTGAGAATTATGGTTGCGACC
->XM_033398930.1 PREDICTED: Drosophila miranda uncharacterized LOC117194359 (LOC117194359), transcript variant X1, mRNA 
-CCAACGCATGAGCAACATCTCGCTGTCCTCCGGCACGGACTCCGTGGGCCACATGGATCGCGGCAGCAGCTCCAGTCTCGCTAGCAGCGCCACCGTAGGCACCAACACCATCACCAGCGGCATTTCCAAGGAGTGCGCCAATTACCCCGTCGGCAGTCAGTCGGCCCGTCCATACGTCCAACTGCCGGGCATACACATTTCCAACCCTCCCCAGTACGGGCCAGGGAATATGCAGGAAATAGACGCTGGCAAAATGGCGCACAACGGCAAGGCACTCACAGGGCGCTACAATGCCACGCCCACCTATGGCTTCGACAACGAGCAGAACTACTGCCTGAATTCCCAACAGTTGCACAACTTCGAGCTCGAGAACCACACACCGCCGGCATGTCCCGGCTCTGGACCCATTGCCATGACGAACGGCACCATCCAGTTGCGCCTCCGCGATGGCGTGCGCATTGACATGACTCTGGACAAGGCGGTGCGCGTGCTCAATCAGCGCAGCATGGTGGCAAATGCTCTATCACGCAACTGCAGCAACTCGGCTTTGATCCACCCCAATGGACGCATCTTGCAGAGCGGCGCTAAAGTCGAAATAGTCACCTACGACGGCATGAAGGGCAATAACTTTGTTCGCTATGCCAAGATGTGGTACAAGGTGTGAGCAGTGTTCTATGA
->JF368683.1 Uncultured soil bacterium clone GO0VNXF07IAPWG 16S ribosomal RNA gene, partial sequence 
-AGATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGCAGCACGGGTACTTGTACCTGGTGGCGAGCGGCGGACGGGTGAGTAATGCCTAGGAATCTGCCTGGTAGTGGGGGATAACGCTCGGAAACGGACGCTAATACCGCATACGTCCTACGGGAGAAAGCAGGGGACCTTCGGGCCTTGCGCGTATCGAGATGAGTCCTAGGTCGGATTAGCTTAGGTTGGTGAGGTAATGGCTCGACCGAAGGCGACGATCCGTAA
->XM_052578998.1 PREDICTED: Carassius gibelio triosephosphate isomerase 1b (LOC127975165), transcript variant X1, mRNA 
-CCTCGCTGTCTCTTCAACCGGGGGCTGTCTGTCATTTCTACTGTTTTTTTTTTCTCTGTATTTTCTGGTGAACGCAACACGTTTCAGTCATGACTGGCAGGAAATTTTTCGTCGGAGGCAACTGGAAAATGAACGGAGACAAAAAGAGCATAGAAGAGCTCGCCAATACACTGAATAACGCCAAACTCAACGCAGACACCGATGTTGTGTGTGGTGCTCCATCCATCTATCTGGACTACGCCAGGTCCAAGCTGAATCCTAACATTGATGTGGCTGCACAGAACTGCTACAAGGTTGCAAAGGGAGCGTTTACTGGAGAGATCAGCCCTGCGATGATTAAGGACTGTGGAGTTAAATGGGTTATTCTGGGACACTCTGAGAGACGCCATGTTTTTGGAGAGAGTGATGAGTTGATTGGGCAGAAGGTCGCTCATGCTCTTGAGAACGGTTTGGGTGTGATCGCCTGCATCGGTGAGAAGCTGGATGAGAGGGAGGCCGGAATCACAGAGAAAGTTGTTTTTGGCCAGACAAAGTTCATCGCAGATAACGTGAAGGACTGGAGCAAAGTGGTCCTTGCTTATGAGCCTGTGTGGGCCATTGGCACTGGTAAAACCGCATCACCCCAGCAGGCTCAGGAGGTGCATGACAAGCTCAGGCAGTGGATGAAGGCCAATGTCTCAGAAGCTGTTGCCAACTCGGTCAGGATCATTTATGGAGGATCCGTCACTGGAGGGACCTGCAAGGAGCTTGCTTCTCAGAAAGATGTGGATGGCTTCCTGGTCGGTGGCGCTTCCTTGAAAGCAGAGTTTATTGACATTATTAATGCAAAAGCATAAGGAGATAAAGCCACCATCTACCTAAAGCCTAAGGCTTAGGTCTGTTCCCAAACACTGCTCTTCTTTAGAAAGTGTTGTTGTGGTTTTGTTGCTGTCGCTTCATTTTTTTTTATATTACAAAGGGACAGATTGCCACACACTGAACACTCAGCTGAGTGTGTTATTGGCCCTCCAACTAGTTTAGTGAACTACATGACTGTAATGAGAACCATCACGGGGCTTAGAGCCCACACCTTTACTTGAATAATATTAACCAACATTCTCATGTATACAGTGTCAAAAATCTAGGATTAAGTCAATCAACCTCAGTGTCGTTTTAATTCAAGCGAAAGTACTTTCCATGAATGTGGTTGTCCTGATGTTTTCCTGTCCCTCAAAGAGTGTTTCTCTGAGTGACCTATCCTGAAGGTGCTCACATGAAACCAATATGTTTTGGTATAAAGGATAAGACAAAAAATATTCTAATAAATGTTTCAGAATCATAGACTTAA
->XM_007110546.3 PREDICTED: Physeter catodon golgi transport 1A (GOLT1A), transcript variant X1, mRNA 
-TGTGAGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGAGCGTGTGTGTGTCTGTCTAGGGGGAGTTAATGATTTACCAGAGGCTCATTTCACAGCTTACCAAGGGTCAGCTTCCCTTGGGCATGTACAAGTTCGACCTTCTGGGCTCCTCACCCCTTGCCAGCTTCCACCTGGAAGGTCCCCCAGGCAGCCCGCAGCATGATCTCCATCACCGAATGGCAGAAGATTGGTGTGGGCACCACCGGCTTCGGCATCTTCTTTATCCTCTTTGGAATGCTCCTGTACTTTGATTCGGTGCTCCTGGCCTTCGGAAACCTGCTGTTCCTCACCGGCCTCTCCCTCATCATCGGCCTGAGGAAGACGTTGTCCTTCTTCTTCCAGAGGCACAAGCTCAAGGGGACCAGCTTCTTCCTGGGGGGCGTGGTCATTGTGCTCCTGCGCTGGCCCCTCCTGGGCATGTTCCTGGAAACCTATGGCTTCTTTAACCTCTTCAAGGACTTTTTCTCTGTCGCCTTTGGCTTCTTGGGCAATACCTCCAACATCCCCTTCCTGAGCATGCTGTTCCGGAGGCTTCAAGGCACCAGCTCAATGGTCTGAACAGCAGAGATAAGCTGCTTGAACTTGGATCATTGGTTGAAGGGGCTGGAAAGGAAATGGGGGCCACCCCCTTAGGCCCCCACCCCACACTGACTCATCTCCCCATCATACCCGGACCTCTCCAAGTCCAGAAGGAAGGATGGAGCCGAGTGACTGACCTCAAATCCCCAAGTCAACGCAAGAAGCTATCAGGACAGTTGGGAGCAGAGATCCAGGTCCCACGGATATTGAACGGGGATCACACCCCACCCTGTATTTATCAGAGGAAAAGCAAAGATTAAATCCCCAAGCTGGGGCTTCCCTGGTGGCGCAGTGGTTGAGAATCCACCTGCCAATGCGGGGGACATGGGTTCGAGCCC
->XM_009871050.1 PREDICTED: Apaloderma vittatum myosin VC (MYO5C), partial mRNA 
-TACAATAGGGTTTGGATCCCTGATAATGATGAAGTTTGGCAGTCTGCGGAAATCACGAAAAACTACAAGGCTGGAGACCGTTTTCTCCATGTGCAATTAGAAGATGGAACTGAACTGAATTACCCTGTTGATCCAGCTGCCTTGCCACCCCTACGAAATCCTGACATACTCGTTGGCGAAAATGATCTCACCGCGCTTAGTTATCTCCATGAACCAGCTGTTCTACACAATCTTAAAGTTCGTTTTATGGAATCTAAGCTTATCTACACCTATAGTGGAATAATTTTGGTTGCAATAAACCCCTATAAACAGTTGCCGATATATGGAGATGCTATTATCCATGCATATAGTGGGCAAAACATGGGGGACATGGATCCACATATATTTGCTGTGGCGGAAGAAGCATACAAGCAAATGGCAAGAAATAACAAAAATCAGTCTATTATAGTCAGTGGAGAATCAGGAGCTGGAAAGACTGTGTCTGCAAGATACACTATGAGGTACTTTGCCACTGTGAGTAAGTCAAGCAGCAATGCACATGTGGAGGATAAAGTGTTGGCATCCAATCCAATAACTGAGGCTGTCGGCAACGCAAAAACCACACGGAATGATAATAGCAGTCGATTTGGAAAATACACTGAGATCAGTTTTGATCGGAGTTACCAAATCATTGGAGCTAATATGAGAACATACCTGCTTGAAAAATCCAGAGTTGTCTTTCAGTCAGAGAATGAGAGAAACTATCATATATTTTATCAGTTGTGTGCATCTGCTATGCAACCTGAATTTAAGCATCTTAAATTAGGAAGTGCAGAAGAATTTAACTACACAAGAATGGGTGGCAGCCCAGTAATAGAAGGAGTTGATGACAGAGCAAATATGGTGGAGACTCAGAAGACATTTGCCTTGCTGGGTCTGAAGGGGGATTTTCAGATGGATGTTTTCAAAATGCTGGCAGCAATCTTACACTTGGGCAATGTGGAAATAACAGCTGTTGGAGATGAAAGATCATCCATCAGTCTGGAAGATAAACATCTCAATATATTCTGTGAACTCCTGGATTTAAAACGTGACAAAATGGCACAGTGGTTGTGCCACCGAAAGATTGTCACTACCTCCGAGACTGTAATAAAGCCAATGACAAGAGCTCAGGCTGTTAATGCAAGGGATGCCCTGGCGAAGAAGATCTATTCACATTTATTTGACTTCATTGTGGAAAGAATTAACCAAGCTTTGCAGTTCCCTGGCAAACAACATACTTTCATTGGTGTTTTGGACATTTATGGCTTTGAAACATTTGATGTGAACAGTTTTGAACAGTTTTGCATCAATTATGCCAATGAAAAGCTGCAGCAGCAGTTCAACCTGCATGTCTTTAAACTTGAACAAGAGGAATACATGAAGGAAGATATCCCATGGACTTTAATAGACTTTTATGACAACCAGCCTGTCATTGACCTTATTGAAGCTAAAATGGGAATTTTAGAACTTCTGGATGAAGAGTGCTTGTTACCTCATGGAACAGATGAAAACTGGCTTCAGAAGCTCTATAATAATTTTGTGAATAAAAACACACTCTTTGAAAAGCCGAGGATGTCGAACATGTCTTTCATCATTCAACACTTTGCTGATAAGGTGGAATATAAAAGTGAAGGATTTCTGGAAAAAAACAGAGATACAGTACATGAAGTATTGATTGAAATCTTGAAGGAGAGCAAGTTTCATCTGTGTGCAAATTTTTTTCAAGACAATCCAGTGTCCGTTTCACCTTTCAGTTCAACTATAAACATCAAATCTGCAAGACCTGTTCTCAAGCCACCCAACAAACACCTCCGGATGACAGTTGGCAGTAAGTTCCGGAGCTCTTTGTCTTTGCTTATGGTGACTCTTAATGCAACAACCCCTCACTACGTACGATGCATAAAGCCGAATGATGAGAAGTTGCCTTTTGAGTTTGATTCGAGAAGAGTTGTTCAGCAACTGCGAGCGTGTGGTGTTCTGGAAACTATTCGAATTAGTGCACAGAGCTACCCATCCAGGTGGACTTACATTGAGTTTTTCAGCCGTTACAGCATTCTTATGACACAGCAGGAGCTCTCCATAAATGATAAGAAGCAGATTTGCAAGACTGTTTTGCAGCGGCTAATCCAGGATCATAACCAGTATCAGTTTGGGAGAACAAAAATTTTCTTCCGAGCAGGGCAGGTTGCTTACTTAGAAAAACTGCGATCAGACAAACTGAGATACGCATGCATCACGATCCAAAAGAGCATTCGAGGCTGGCTGCAGCGGAAGAAATTTCTTCGCATAAAACAAGCAGCTGTTATAATCCAGCAGTATTTCCGAGGGCAGCGGACTGTGCGGCAAGCTATAACTGCAAGAACTCTGAAGCAAACGTGGGCAGCTATAATTATTCAGAAATACTGTCGAGGTTACTTGGTCCGTAGACTTTGCCAGCTCATCCATGTGGCTGCTGTAACAATTCAAGCTTATACAAGAGGATTTCTAGCAAGAAAAAAATACCGGAAGATGCTTGAAGAACACAAGGCTGTGATCCTCCAGAAATACGCCCGTGCATGGCTTGCCAGGCGCAGATTTCAGAATATTCGTCGGTTTGTATTGAATATCCAGCTTTCATACAGAGTTCAGCAGCTGCAGAAGAAGATAGAAGAGCAGAGTAGAGAAAATCATGGTTTGCTGGAACGATTGACCAGCCTGGCTTCGACTCACGTGAATGACATGGAAATAATACAGAAACTCGAATTAGATCTTGAAAAGGCAACTGCTCAAAAGAGAACGTATGAAGAGAAAGGGAAAAAATATAAAGAGGACAGTGAACAGAAAATCCTAAAACTCGAGAATGAGAATAAAGAATTACAACAACAGAAAGAGACCTTGGAAATAAAGCTCCAAGAGAAAACTGAGGAAATGAAAGAGAAAATGGATGATCTCACAAGGCAACTGTTCAGTGATGTACAAAAAGAAGAAAACCAGAGAATGATACTTGAGAAAAATTTCCAAAATCAGAAGCAGGACTATGAAAAGGAAATCGAAATGCTCAAGGGAGAAATTAAAATTCTGAAAGAAGAAAAAACTCGGCTACAACATCAAATTCAGCAAGAAATTGTCATTCAGGACAGCTTGAAAATGGAAGTAGGACAACTTACAAAACAAGCACAGAAAATACCTGAGTTGCAAAAGGAAATTGAACTGCTGCAGACACAAAAATTGGATATTGAAAAGCAGGCCCAGTCACAGAAGCGAGAACTGAGGGAAAAGATGTCAGAAGTTACAAAACAGCTTCTTGAAAGTTATGATTTTGAAGATGTAAGAAGCAGACTCTCCACAGAGGATTTGGAACACTTAAATGAGGATGGGGAACTGTGGTTTGCTTATGAGGGCTTGAAAAAAGCTACAAGAGTATTGGAAAGTCATTTTCAGTCTCAGAAAGAAATATATGAAAATGAGATCGAAGGCTTGAACTTAAAAGTTGAACATCTTAGCCAAGAAATTAATCATCTACAGAAGTTATTTCGAGAGGAAAATGACATAAAGGATGGCATTCGATTGGAAGTTAGCAGGCTAACTTCAGAAAACCTGGTGATCCCAGATCTTAAGCAGCAAGTTTCTGAACTTGAAAATCAAAAATTAGATCTTGAAAACCGTCTTCAAGAGCAAACTGTAAAGTTGAAAGGTAAAGTAACAAATGATGTAGATATAAAAGAAAAAGAGAGACTGAAAGTCACAACCCAAGAAATTAAGGGGCTGAGCAATGGTCTAATGCAAGATGAAACCCAGGATGAAGTACAAAGCAAGATGAAGCAAGAGACAACTCGACTTACTGTGGAAAACATGGATCTTGAAGAAAAACTAGACATGAAAGACAGAATAATAAAAAAATTGGAGGATCAAATCAAAACTCTTACCAAGACTATTGAAAAAGGAAATGAAGCTCATATGCCACCTTTGTCCAGAGAGTACATTGGAATGATGGAGTACAAAAAAGAGGATGAAGAAAGGATCATCCAAAATCTGATCCTCGATTTAAAGCCACGTGGAGTTGTAGTTAATATGATACCTGGCCTTCCAGCTCACATCCTCTTCATGTGTGTGAGGTATGCAGATTATCTGAACGATGCTGACATGCTGAAATCTTTCATGAATGTAACCATTGATGGTATCAAACAAGTTGTTAAGGAACATTCAGAAGACTTTGAGATGTTGTCCTTTTGGCTTTCCAATACATTTTATTTTCTTAACTGTTTGAAGCAGTACAGTGGGGAAGAGGAATTTATGAAGTGTAACACGCCACGTCAGAATAAGAACTGTTTGAAGCATTTTGATCTCTCAGAATACAGACAAATTCTTAGTGATTTGGCCATTCATATCTATCACCAGTTCATTACTGTAATGGAGAACAACATTCAGCCCATGATCGTACCAGGCATGCTGGAATATGAAAGTCTTCAGGGAATTTCTGGCTTGAAACCTACAGGGTTCCGTAAACGGTCTTCTAGCATAGATGACACGGACACCTATACAATGACCTCTATCCTGCAACAGCTCAGCTATTTTTATAGCACCATGTGCCAGAATGGCTTGGACTCTGAGCTGCTGAAGCAGACAGTGAAGCAGCTTTTCTTTCTGATTGGAGCTGTCACCCTCAATAGCCTCTTCCTCCGCAAGGACATGTGCTCATGTAGAAAAGGAATGCAGATAAGATGTAATATCAGCTACTTGGAGGAATGGCTTAAGGACAAGAATCTTCAAAGTAGTAATGCCAAAGAAACTTTGGAGCCGCTATCTCAAGCAGCCTGGCTTCTGCAGGTCAAAAAGATCACAGATGAGGATGCCAAGGAAATATGTGAACACTGCACGTCTCTTTCTGCTGTGCAGATAGTTAAGATCCTCAACTCGTACACTCCAATAGACGATTTTGAGAAAAGAGTGACTCCATCGTTTGTTCGTAAAGTCCAGGCTATGCTAAACAATCGTGAGGATGTTCCACAGCTGATGCTTGATACCAAATATGTCTTTCAAGTGACGTTTCCTTTCACCCCCTCTCCACATGCCTTGGAAATGATACAAGTCCCCAGCAGCTTCAAACTTGGCTTTCTCACAAGGATTTAA
->XM_020048109.3 PREDICTED: Esox lucius basic helix-loop-helix and HMG box domain-containing protein 1 (LOC105026992), transcript variant X2, mRNA 
-CCGCAGCTTGGTAATAGACTGGTTGTTAGTTATTGCACACATGTAGCATTTCTATGTAGCTAGCTAGTACTCTTAGCTAATTTATATTTTGCTGGCTTATCTGCTCGCTCTCGCTGTCACAATTGGCTACTAAGCGGTTTTACAGGTGTGGGTGAATTTTGAAGTGGTCTATTGTCCAGCCTAACTGCATGTTTGATCCCGATGAAAGATTTGAGCCATGGCACCTGGATCCAAAGGCAGAGACGGAACTCGAAAGAAAAGAAGGAGACTCTGGTCCACATGCTGCGCTATTTTGACTTCCTTCAGAGTAAAATACAGACCTTGCAGAGGTGCTTGCCCCCTGAAAGCATCCCCAAGCAGGAACCTGACACAGGATCTGAGAGTGAAGAGAACACCCCCTCTGAGCCCTGTACACCCTCTCATATTCTAAAGGCTAAGCGCAAGTATGTCTGCAACCGTTCCCATAAGAGACTACCTGCCTCCAGCTCAGAGGTGAAAGCAGAGCTTCAGGGGAAAAGAAGAAGATTGTGCACTGCAGATGTCAGTAGACAGAAAGCTGACCCAAAGGAGGAGGATGTGCCTGTCCCTATGTGGGGTGTGCATTTTGATTGGTCAGAGTGCCATTCCAGTGATAGTTATGGGGATTGGCATGTGCGTGAAAGTGACTCCCAACCAAGCTCCCTGGATTCGGGCTTCAGCTTCAATCAGTTGCTTCCCCTGAGCACCCCTTTGGAGGGGTGCAGTGGGACTCTGAGGACTCCATCCACTCTTCAGGGAGGCCACTGCTCTGCCTGTGAGGACGGCAGTGAAAGCAGCCCAAGGAGCGGTGTCCTCCATACCCCAACTACTCCAGTTACTGGGCCAGGGTCACTTTTCCTGAAGGATCACATGGTTGGGGTCATCCCGTCCACAGGAGGCCGATGGAAACCCTTCCTGAGCCCTGCTGCTACACCAAAACGGCCCATCTTTCTGCCGTTTGGAACTGAGGACAGTCTGAACTTGGGCGAGAGTCTGAACCTTAGTCCGTCTCTCCTCACATCACCTGGCCGGGGCCTCAGCCAGTGCCTGCTACCTGAGGGACCGGAGGAGCTCCATGTGCTGTTTGAGGATGTTTGGGTCACCCCTAAAATGACCCAGGCCAAAGTGTCCCACCTATCCTACCATGACCCCACTGACACGCTGTCAGATGGAGAAGCTGTGGTGAGGCATAGCGGTGGAGGGTGGTTGTCCTCCCACAGTGAGGGGGAGGAGGAGGACGTCACCTGGACCCCCAAGCAACAACAAGTCTCTCTGAAGTCCAAGACCAGTGGGACAAGACGCCACCGCAGAACCAACGCCTCCACCAGGGGGCACCCTCTCCTCCCTCCCAACCTGAAGAAGAAGTGTATTAACGGCTTCATCATGTTCTGCCGCATCAACAGGAAGACCTACCTACGCACCCACCCAGGCACGCCATCCACCGTGGTCACCAAGGAGCTGGCCAGCCTGTGGCACGACATGCCCAAGCAGGAGAGGCGTGTGTACTGTCTGAAGGCTCGTCGCTTCAGCCGTCAGCAGAACCGTAACGTGAAGCCTCAGCCGGCGGAGGGGGAGGAAGAGGACTTTGTGCCCAGTCCACTCCACATGCTGCTGGCGCAGAGAGACCTGAGGGCTTCAGCCAGAGGAGACTCCTAGAGCAGTTCCCTTCACACACACTGGCCCTTCGCCAACCATATGCATGGGATGGATATTGATATAGATGTCCATATTAAAATCAACAACTTCTCTTTTTAAGTCACTTACTGTACTAGTTAATTATGGAGTTGTTTAGAGATTTATCTGAAATGCAGACACACTTTGTGTGTGTGTCTGGCACGTCACATTTTAACTGTTACTGTTTACTGCTTCAAGTTGTTTCTAGACAATGTTCAGACTTGGTTTTACAGATATCATTGAGGAGCCTTTTAGACAGGGTTTATTGACAGAAGTCTTTCTGTGGGTTATAATGCCAAGGCATTGTTTTGCTATTCATGTCAACCTGACGTTGAATTCACCAGTCTATTTATGATCATAATGCAAAGGACCAAATAAATGACAGTATGTGGCTGACAGCTTTATTTATTACCTATTTATACTCAGAATATATTCATATGTGGGGAATGTTAATGTGTCTGTGTGAAGTCCTTCTGTACAGGACAGATGAGAACCAAAGTCTTACCGTTTGGAGTTATTCACACTGGTTGGTTGATGTTTTTATGCGGTGTGAAAATGTTTTGATGTTTCGTGAATAAAAGTTATTACTACTTAGTAGTGGGTTATTTGAGACACATCAAATAGTTTGTTTA
->XM_034078853.1 PREDICTED: Pseudochaenichthys georgianus glutamate receptor interacting protein 1 (grip1), partial mRNA 
-GACGGGCGCGATCCACGTTGGGGATCGCATCCTGGCGATCAACAGCAGCAGCCTGAAGGGGAAGCCTCTGAGCGAAGCCATCAGTCTGCTGCAGCAGGCCGGAGAGACGGTCACGCTGAAGATCAAGAAGCAGGGCGACCTGGCGAGCCCTAAGTCCTGTTTGATTGGTTCAGGCATGGGGGCGGGGCTTGTGAGGGAACACCAGGACGGCGTTGACGATCCGGTCATCGTGGTTACGCCGCTGTCGGGTCAGCGAGCGTTCAGCACCCTGCCGTCGGTGGACAGCGCCGTGGAGTCCTGGGACGGATCCAACGTGGACAGCTTCACCCCCCCGGCTCCTCCCTTTCAGTCGTCTCCGTACAATTTCCACGACTGGCGCAACGCAAAGACGACAAACAGCCAATCATCTTCCTGCGCTCGCCAGAGAGCCAATCAGCTGTCAGACCTCGGCCTCAGCGACGACGAGTGGGACCGCCCACCAATGGGAGGAGCCTATAATCTGCCCAGCGGTTTGATCACCGACTGCAGGTTCAGCGTGGGTCATGATGGGACGGAACCGGATCAGGAAGAGAACTTCTGGTCTCAGGCTTTAGAGGATCTGGAGACATGCGGACAGAGCGGCATCCTCCGAGAGCTGGAGGCTACCATCATGTCCGGTTCCACGCTCAGTCTGAACCACGACCCGACCCCTCTGCGCAGCACTCTGGGACGCCAGGCCAGCTTCCAGGAGCGAAGCAACTCCAAGCCATCGGTAAACTCTCGGTCCAACACCTTGCCCTCTGACCCCACGCGCCGAGCCTTCGCCATGAGGAAGATGAGGCAGGAAGTCAACGAGATCCTAAACCAGAACCCCGTGGAGCTCCACAAGCTGACTCTAGAAAAAGCCACAGATCTGGAAGATTTTGGGTTCAGTGTTTCTGACGGCATGTTGGACCGCGGCGTCTACGTGAACAACATCCGACCGGGAGGACCAGCAGAGGGCGGCGGCCTCCGAGCTTACGATCGGATACTACAGATTAACCACGTTCGGACTCGGGACTTCGACTGCTGCCTCGTGGTTCCTCTGATCGCCGAGTCTCCGAACCACCTGGAGCTCGTCATCAGCCGAAACCCGACTTCCTCGTCCACCACGCTGTTGACCAATCACACTGACGGCATCTACAACAGCGGCCACTCCCCTCAGCCAATCGGCAGCGACCTCGGACCTTTGGAGCTCTCCATTGGCCAGTTGGAGGACGGCGGTCCAATCAAGTGGAGCCAACCGGGGGACATGTTGGTGGCGGGCCTTGGGATGGGTCAGGTCAATAATAATTCCGTATAGCAGACAAACAATGGATTCAATTAACCAGATTGGACTGGAGAGGCCGACCAAACAGCAAAATGACTGGTTTTGACCAGTCCAAACTGGTTTAGAGTACCCTATGGTGCTACACACACCCTCTGGATGACCTTTGAACTGTTGAGGCAGCCTGAAAGCACACTGATGGACCGGAGCAACTCCTCACCTTTTCACAAGAACCAGTTCTGCATACTGGTCCTTTATTACTGGAGTCACTGGAACTATAACTACTGATCCTACTGGAACCACTATGAGAGAGCTACTGGTCTGACTGGTCCGACATTAATGGGTACTCGAGTCATGGATGCTGATTCTTCTAAAGCCAATGGTTTTACTGGTTTTAGATTAATGGTTACTGGTCCAACTGAAGCCAGAGCCACAGCCAATTAATGGTCCTACTGGCCAAGACACATCGGCTCTGGTCTTATGGTGAGTTCACACCAAATGCAGAGCTGATGCACTTTGGGTAAACTGGCAAAAGATGGGAAGGCAATTGGTTTGAACTCGGCATAAGTGGGAACAAAACCAATCTGAAGCCAAATTGATTGGTCTTTTTGGTCTAGAAGACTCGGGTTCTGGTCTGAGTGGTGACAGCATCACGAGTACTGGTTCAACTGGTCCAAGACATGGTTGTTATGGTCAAAGAATCATGTGTACCACCAAGCAAGATCCATGACTACTGTGGAACTGGGTCTTCTGGGCCATCTGGTCTTACTAGAATCAGAACCATGGCTCTAATGGCTGTACTGGCCAAGGACCACAGCAGCACAAAGACTGATGGGAACCAGAACCTGCTGACGGACACACGGGTTGCCATGTAGACGAGGGACGCCCCGATCTAGAGCCAATCCAAACCATACTGATTACTGACTGGTTTCTGGTCTTACAGGTTCATTTATGTCGACGGTATAGGTATACATATCTATATTCGGCGCAGTGTGTTGGGTTTAGGCGCACAATTAAAACTAGTGATGGTTAAATACAAGTCTGAAAATGGTCAAATGCAAGTATAATATTGACAAAGTTGGTTTAAAGATAAGGACTAAGGACGTGGATGGTGTTAGGTGGGGTTTAGGTGTAGTTCAGTTTGTTCTAATACAGGGCTGTCAAACTCAATTTCATCACGGGCCACATCAGCATTATGGTTGAACTCAAAGGGCCGGTTGTAACTTTAAGACTATATAAAAATACATATATAAATATTTTATATATTTAAAATAATGTATTATATTACTTTATTGCCTCTGCTTTGGATTATTAAAAAGCTTCATAGATAACTACGTCTGAAAGAAGAAGTCTAGGGCAAATAAGTGCAAGTCTCTTCA
->XM_046869510.1 PREDICTED: Silurus meridionalis nucleolar protein 9 (nol9), transcript variant X4, mRNA 
-GTATATTAAGAACATGAAATAATTCGTTTTAAACCCCGGGATATTTCGTATTGTCCATCCCCTTGTTCGTTCCATACCGCTTTTGGAGCATACGCTAGACAACGGGCTGTGTTTAGATTTTTTATAATATTTTAACAACATGGTCGTTTTTGTCTCACTTTAGTGTAGGAGCGTTTGCAAAGCATAAAAGGGGGTTAACGTTTGTCTTCGTTTGAGGGTTAATATTATTGTTAACGTTGACGTTAAAGAACTGCAGGACTGCTCACATGGAGAGATCCTAGCTGTGAATTCCTGTTTATGGCTGCAGATTCTTGAATATTTTTATCAGCTAGCCATTTAAAGAGGTGGTTTTTCACACCATGAGCCAGTGCCAATGAAAGTTCACAAGCCACAACCATGAAGGTGCATAAAGTCTCCTCTCGCTCCAAACATGAGAATCGAAATGCTACGAAACGCCACTCCAAAAACAAGTGGCGCACTCACGGGAAGAAGAACCAGCACGTGGACCCTTCTGGCCAGAATCCCAGGCCTTCGACGGCAAAGTTTGAGAATGAGCTGGTTAACAGACAGAAGCCCAAGGTGAAGCGCTTACAGAAGGCTTACACCAAGGCTGCAACTGTGACGTCCAAAGACAAATGTTCATCTCAGGCTAAAGGCAAGGCTCTGTCTGCACCCTGTCCTCACGTCCACACCAACGGGGGTACTGAGCTGGAGACGGAGAGCGACTCGGAGGACTCCCAGGTCTGGAGGTCTTACGCCAAGAGCGTTCTTCAGAACGGTGCCGAGAAAGAAGGAGAAGGGAACTCGGTTTTAAATCAGTCTGAGGAAGTGGAGGTGTTGGAATACCACGCGCAGTATGAACGCTCCCAGAACCACACAGTGTTAGTACTGAAGCAAGGCCAGTCCCTATGTTTCCGAGGAACGTGCCTGCTGATGTGCCTGAGCGGTCGTGTGGAAGTGATGGGCTTTACAATCGAGCAAGGCCAGCAGCCGTATCCGCTCTTCTCCCCATCGTCCCACTGTCCGCTCACCATCAAGGCCATGGTCGAGTGCACATCCTCAGCCAAAAGCAGGAGGGAAACTCGATTAGAGGCCAAAGCCATCGTCCGCAAGTACCTCCTGCCAGGCGGCGCCGTTGCCGAGGCTCGTACGAGACTGCTGAGCGAGGTGGATGCAGATTCATGCGTGGTGCTGCTTCAGCCGCTGGACACGCCCCTCACACGCTTCCTCTCCAGCTTCGGCAGCTCCTTCAGCCATCTCTTCGACCTCAGCTCGAAGGAGCTGCACTCCCAGGCTGCCGTGTATAACCCAGCTCTCTCTGCCGTGGGCGTGACGGCGCTGCAGGGCCCCTGTGCACGTGGTCTGGTGGCATCAAACAGCTATAAAGAGGCGCTCAGTCGCCTGCTCAGTGCATGGGAAGGGGATTTTGATCGCTGTCCCATTATTCTCGTCTGCGGGGCCAAAAACTCTGGCAAGTCGACTTTCAACAGGCATCTCATCAACAGCCTGCTTAACCACACTGCAAGCGTGGAGTATCTGGAGTGTGATCTTGGCCAGACGGAGTTCACGCCTCCCGGGTGTCTCTCTTTAATCACTGTGACCGAGCCACTGTTAGGCCCTCCATTCACACACCAACGAGAGCCAGAGCACATGGTGTTTTACGGCCAAGCAGAATGCCAGTCCGATCTAGACCGCTACCTGGACTCACTCAAGACCCTGTGGAGACACTACAGCGGAGAAAACCCGGTCATTATTAACACCATGGGATGGGTTAAAGGGCATGGCTTCCAGGTGCTGGTCGACCTCATTCGCTTATTCTCCGTCACCCATGTGGTGCAGCTGAGCTACGGTGACACGCCCCAGTGCCATACTCTCAACCCCGACTTCCTGCGCTCTGCCCAAGGCTGGCACACTCATCCACCGGCGCAGTCTGCCCTCGCGGAGGAACCGGCCAATCAGCTCTCGGCACGGGGTCACCTCCTCCTCAGCATCCACTCGGAGTTCGAAGGAGCCGGGACATCCGGGGAAATGCGTCATCAGCGCAGTAACGAGCTGCGTGAGCTGGCATTGCTGGGATACTTCAGCCAGCTACAGTCTGCAGAACCCGGCCCTATCTGCCCCCTGCACTGCTTCACCCCCTACCAGGTGCCCCACTCGGCTATCGCTCTCGGAGTCACTCACTGTGACGTGGCACCCAACCACATCCTGTACGCCGCTAACGCCGGTTTAGTGGCTCTCTGCTGTCTGAGTGAAAAAGTGGCAGGAAGAGGTGGACCTGTGCTACTGCCTCAAACGCCCATCTGTCAGTGCGTAGGCTTAGGTGTCCTCCGAGGGGTGGATATGGCCCGAGGGCTCTACTTTCTAGTCACCCCAGTGCCTCCGGCGACCCTGAGGCAGGTCAACTGCCTGCTGCTCGGGGAGATCACACTGCCGAAAATCCTGCTCACTGTCCAGCATGGTGTTGAGACGGAGCTTCCTTACGTCACCACAGATTACAGCTTTGAGATCACGGGCGCAGGAAAAGTCCACGTTTTCAAAGGGCTCGCGAGGTCCGGTTTCGTCAAAACTAAAACAAATAACTAAGCTCTCTTATACGGATTTCACTTTCAGCGAACGATGTTTGTATCCCTGTACTTGTTTTTTAGACCAAATAAAGAGGCTTCAGCTGCCACCGAATGTA
->XR_003057350.2 PREDICTED: Ziziphus jujuba var. spinosa uncharacterized LOC107427618 (LOC107427618), transcript variant X2, misc_RNA 
-GTAACTTGCAAGCAAAATAGGGCTGGTTATATATATTACACTTTGCTTACCTCTCTTTGAGATGGTCTTAGGCTTGAAGCGAGACCATTTCTAAGCAAATTAAAACTACGTCATCCCTTGGCGTGTTTGTAGTTTGAATGTTCATTTTTTAGTGTTTTTTGGCTTCCAAGAATTCTCACATACCCATATGAAAAAGCACATAAAACCCCCTTCATAAATAGATGAATAAGAAACTATATATAATTCCAGAGATCAAATTTTCTTGGCTTAACATTATTATTTATATTTTTTTCTTATTGGTGAATTCAAGAAATTAAAGATCAATTATGTGGCAGATACGATCTTGGGCTTCTTACAAATTCCGAAGTATGCTTGAGTTAATTCGTCCCGGTATATCTGCTTTCTCATCCTCCATGAATACTGTCTATCACAGAAACTCTAATTCATCAGGTATGCCGATGGCTAAGTTTGGATATGGTTTTCCAAAGCACCAAGGACTGCAGTTGTTCGGCAACACCACCGGTAGCAAAACTTTGACAACATTTGGTACCAACATGGTAAAGGATGGCAATAAGGAGCAAGTTCCACCACCAGTGCCTCCTAAGAACAACATTCTTTATTGGGCAAGATGGGTTTTGGGCTCTATATTAACATTGCTGCTGCCATTTTGGAAGCAATATTGGGGAAAACTACAAAGAATAGAAGGAAAGGTAGAAATGGTTGCTGAAGAGGTGGAAAGTGTGGCAGAGGTGGTGGAAAAGGTAGCAATTAAAGCAGAGAAAGTGTCATCAGAGGCTGCAAATGTACTTCCAGATAATGGAAAACTGAAGGAAACAGCTTTGATTGTAGAACACATTTCAAAAAAAGCAGCCCAAGATGCTCAACTAACTCTGGATATCATTCACAAGGTTTATATATATTTTCCAAACCAATTAATTCTAATTAATTTTGACAAGTAATTCTATGGTATTCCAGGAATACATACCCTCAAACTCATAATAGAATGGACTCCACGTATGTTTACGAGTGTGGATGCATTAAAGCATGACTTCGAAGAATTGGAGACTTTAGTTGAGCCTGTTGTCGATAAGATTGTGGTAAATCATGAATCTGATGGAAAGTAATTAATTTGGGTATTGATCATAATATCATTTTTTTCCTTGTAATGTATTTTCATAATTTGGGCAACCGCATTTTGCCCATGTGAATCGTACAACTTTTGCGCTTTGTTCTTTCTA
->XM_010349232.1 PREDICTED: Saimiri boliviensis boliviensis guanylyl cyclase domain containing 1 (GUCD1), transcript variant X2, mRNA 
-GGATTGGGCGAGGGGGCGGGGCCACCCGACGCAGAAGCGGCAAATGGCCAGGGCGGGCTTAAATTGGGAGGCTGGGGGCATCTAGAATCAAAGTTTGGGGCGGGGCTTCTAGAAGGGGCGGGGCCTCCAGATTCGAGACCTGGAACGACCGGGGCGGGTCTCGGGGCGGCCCAGCCGCCGCCTCCAGTTCTCCCCACCGCAGCGGCGCCGGCGGCGGTGGCGGCGGAGGAACTCGATACGCACCGACCGTCCTCCCGTCCTAGCCGAAGCGGAAGCTGTAGCCCGCTCTGGGCCGGGGCCATGGGCGCCCCGCGCCGCCCGGGTCATGAGGACGGAGGCGGAGGCAGCGGGGCCGCCGCTCGAGCCCGGGGACTTTGTGCAACTGCCTGTGCCCATCATCCAGCAGCTCTACCACTGGGACTGTGGCCTGGCCTGCTCCAGGATGGTTCTTCGGTACCTGGGCCAGCTGGACGACAGTGAGTTTGAGAGAGCCCTGCAGGAGCTGCAGCTGACCAGGAGCATCTGGACCATTGACCTGGCCTACCTGATGCACCACTTTGGCGTGAGGCACCGCTTCTGTACCCAGACCCTGGGCGTCGACAAGGGCTACAAGAACCAGTCCTTCTACAGGAAGCACTTTGACACAGAGGAGACCCGGGTCAATCAGCTGTTTGCACAAGCCAAGGCCTGCAAGGTGCTGGTGGAGAAATGCACGGTGAGCGTGCAGGACATCCAGGCGCACCTGGCTCAGGGCCATGTAGCCATCGTGCTGGTGAACTCGGGGGTGCTGCACTGTGACCTGTGCTCCAGCCCTGTCAAGTACTGCTGCTTCGCCCCTAGTGGCCACCGCTGCTTCTGCCGCACTCCTGACTACCAGGGCCACTTCATCGTTCTGCGTGGCTATAACCGAGCCACTGGCTGCATCTTCTACAACAATCCAGCCTACGCCGACCGAATGTGCAGCACCAGCATCAGTAACTTTGAGGAGGCCAGAACCAGCTATGGCACAGATGAGGACATCCTCTTTGTCTACTTGGACAGCTGACACCAGGAGCCTGGTGTGCCCAGGCCCTCGGACCCCATCCCCACCCCAGCTGGGCCCACTCAGGATGCCCTGGCCCAGGCCTGGGGCTGCTGGGGCTGGAATGTGGAACTGCAGCCTCAGCCCATCTGGCAGGGCCCCGGGAACTCTGGGAGACTGTGGCACAGCTGCTTTGTCTGCCAGTGCCCTGTGTTGTCATGTCGGTCACCCCAAGCACTTGCTGGCTGCTGGAAGCATCCCCCAAGACCCCAAGCCTGACTCCAGCTGTACCCACAGAAAGTCCAGCTCCAACAGTGCCCTTGTTGCCTTTGAGCCAGACCCAAGGCAAGGGAGAGGCTTTGTCTCCCCACAGACCGCAGGACTGGGCCTGGAGAGAGAAGTCGCTTGACAGATGCCACTTGTCAGGATAGTATGTGAGTGTCTGGAGACAGCATAGCTGACCCCAACCCCCCCAGCACTGAGGACCCCTCCAGGCTCTTCTCTCCTGGAAGTGCTGAAGATGCCTCTGTGCCCCATGGTTGATGACACCACCACTTCCTGCCTACCCATGGGCCCAAGTTTCTGTGGCTGGTTTCAGAGCATCTGGTCCCTGCCACCCAGCATAGACACACCTCACAGCTGCTTTGCCATGCAGAGCCCTGGCCCCTGGGGACTCTTAAGCCCCCCACAGTCCTCCAGGTCCTCCAGCTCTGTCAGATGGAGGGGTCTCGGGTGTGACCTGGGCCTGGATCCCACTGGTAGGCCTGATGGCTGGCAGCAGTGTGTGCTCTGGAAATAAACAGCAGCTCTAACCCCAGAGGGATCCCTGCACCCAGGAGGCCTCCCAACAGCAGCCTAAATCCTCACAGTGGGGTCTGCCCTGAGATGGGGACCCCCTAGTACTTTAAGGTTGCCTGCTAGGGCCTGTGCTCCAAAGCAACGGGCAGGGGCAGCCTGCAGCTGCCCACCCAGCCTGGTCTTCACACCAGGTTGCACAGGATACTGGGTCTCTTCTATCTTGATGGAGAAGAGGGGTTCCTGCCCAGGATCATACAACACAGCAAATAGCATAGAGCTCTTCCTTCGGTTTTGGTTTTTTTCTTTTTTTTTTTTTTTCCTGGTTGGGATCAGGGGTTGTTTCTTTGAGATTTAAGTTTTCATTTTTGAGGGGTAATGACCTTTAAGTAAAACAGTAATAGCAAGAGTGAAGGTACTTTGGAACCACCAATACCTCTGCACAGGGCAGTTAGCCAGCTCAAGTTCTTTTTTAAAGAAAGGGACTTGGCTGGTGGTTTGAGTACCCACCCCTTCACTTCACAGACAAGGCAGTTGGCCCAGTCTGGGGAGTCTGCCCAGGACAGTGGTGGGGCTGGGCCTTAAACCCCAGTCTATACCTAAAAAACTAAGGGAAATGGATCATTCTCAAAGGGGCAACAGTGACACCATCCCTGCACTCCTGGGTCCTGGTCTTACAGTGCCCAAGGCATGGCATGGTGGCAGCTGGACCCTCCCCCATCAGGTGGCTCTGGTGGTAGAGGTGGGCTCTTTTTAGGAGGGTGCTCGGACCACACAGCCAAATTGCTCCTCAACCCTAGACAAAGCCTTGACCAAGAGGGAGGTGCTGTTAGCTGGGCAGCCCTTCTGGGTTTCAGAGACTCGTGTGGGCTCCAGTCTGGTCTCATCTCCATTGCCTTAATGACAGGTGGCCCAGGAGTACCCATGCACAGCAGCTGTGGGGTGTGGGCATCTTCAGATGTTCTGGTAAAATTGTGAGATTAGCTGTATGAAGGAAACCAGTGGGAGGAAAGGAAGTTTTCAGGATGGCAAGATTTGATTCAGACACAGTGCACATGCTACTAGGGCTGTCACTGGGCAGTGGCCTTCATGGAGAGTGGTACCAGCACCTCAGTCCATCCAGGATATTTAGAAACACTCAGTCTCTGGTCCCAGAGGATGGCTTCTCAGGGCATGCCACAAGTTAAAGTCACCTGCCTGGAAGATGAATGAGAAAGCTGTCCATTCTCAAGACCCATCTGCCTAGGGAGGGTCACAGAGGCAGGATGTAAGCCACACTGTATTGCATTCTTGCATAAGTCATGAAAATGGGGCCAGAGAGGGAGCCTGGACATCAGGGACTTCTGCCCACAGCACATGGCACCCACAGCTGCCCAGCCTGTCTACATGCTGGGGCCCAGCACAGCCCCTGAAGCCACATGGGACAGTGGGCTTTGTTCACTATAGCCACAGGGGGATGAAAGGGATCTTTTACATTGCAGAGATTTTATATATATTTTGTTTGTAATGAGCCATTCTCAATAAATTCTCGCTGCAAAA
->XM_053281253.1 PREDICTED: Hemicordylus capensis transmembrane and coiled-coil domains 4 (LOC128338576), mRNA 
-TCCCTCCCGCGGCTGCCGGCCTAGTCGCCTTTTTCTGAGCCTCGGACTGGAGTGAGCGCTGAGCCGGCCCAGAGTGAAGGCAAGGCGGGGGCCGGTCGGAGCCTCGATGCGGCCCCTTTCTCCCTCGAGGACGGGCAGAGGCCGGTGAAGATGGCTGCCGGTCACCACCAGCGCTGGAGGCCTTGGAGAAGGGGGCCGATAGGAGAGCCGGAAACGGAGGAGCCGTCTGCACACGTCGGCCGGCAGCTGGGCGAACCGGGGAAGTTTGCCTACGCCGCTCTTTGTGCTGTATCCTTGGCATCGCTGTTTCCAGAGCAAGCCGAAAGCTCGTATCGGACGGGATTCGTCGAGAGCCTGGTGCGGTGGCTAGACCTCCCGGAAGGCGTCTTGCCTGCGATGCAGGCCTTTGCCGGCGGCTTGGGAGGCGAAGGGACAGACACCTTTGCTCAGATCCTCTTGAAGGACCCCGTCCTGAAAGACAACTCTGACATCATCACCCAAGATCTCGTGGCCTTTTCCCTCAAAGATGGCTACTATGATGCCCGAGCAAGAGTGCTCCTCTCTCACGTCACCTGGCTTTTAAGAATCCCGTTGACTGAGCTGGAGGCCTCGGAGGAACGACTTCTTGAATGCTTGAAAGATGAAGAAGAAGAAGAATCTGCAACGGCGGAGGCATCGCGGAAGAGGAAAGAGAAGAAGAAGAAGCTAAAGCGGTACTTGCTGATCGGTTTGGCGACTATTGGAGGAGGGACGGTGATCGGTCTGACGGGAGGCCTCGCCGCCCCTCTGGTGGCGGCCGGAGCCGCGACCGTCATCGGAAGTGCCGGAGCGGCCGCCCTGGGCTCGACAGCTGGGATCGCTGTCATGGCGTCGCTCTTTGGAGCAGCGGGAGCCGGTCTCACCGGTTACAAGATGAAGAAGCGTGTGGGAGCCATTGAAGAGTTTGAGTTTCTCCCGCTAACTGAGGGGAAGCAACTCCACATCACCATCGCGATCACTGGTTGGCTTTCTACGGGCAAATATGGGAGTTTCACGGCCCCGTGGAATAGCCTGCTGCAGTCGAAAGAGCAGTACTGCTTAGCCTGGGAGTCCAAGTACCTGGTGGAGCTTGGAAACACCCTCGACGCCTTGCTGAACGGGCTGGTGAATGTGGTGGCCCAGGAGGCCCTGAAGTACACGGTATTGTCGGGGATCGTCACCGCCCTGACCTGGCCTGCTTCACTGCTCACAGTCGCCAGCGTGATCGATAACCCCTGGGGTGTGTGTCTTCATCGCTCGGCCGAAGTCGGGAAGCACTTGGCGCAGATTCTGCTCAAGCGGCAACAGGGCAAACGGCCTGTTACGCTGGTTGGATTTAGTCTTGGTGCCAGGGTCATCTACTTCTGCCTCCAGGAAATGGCCAAGGAAGAAGATTGCAAAGGGATCATTGAAGATGTGGTTCTGTTGGGGGCACCCGTGGAAGGAGAAGCCAAGCACTGGAAACCGTTTACCAAGGTCGTTTCGGGCAAGATCATCAACGGCTACTGTAGGGGAGACTGGCTGCTGGGCTTTGTGTACCGGACGTCCTCCGTCCAACTCCACGTTGCCGGACTTCAGCCAGTTGACCTGGACGACCGGAGGATGATCAACGTGGATCTCTCCTCTGTCGTCAGCGGCCACCTGGACTACATGAAGCAGATGGACACGATCCTGAAGGCCGTGGGCCTCAAAACCAAGCAGTGCCGTCTGGAAGAGAGGGGAGATCTCACCCTCCTCTCCGCTGAGCCCAAGGAAAGCCAGGAGGAGGCCCCATGTGTAGACACTCGGGAAGAGCAAAACCTGCTGGGAGGAGGAGAAAGTGGCAGCCATGACGGCGGCAGTGATGACTGCTGGTCATGGGAGCCAGTGCCCAGCCGCGGATCGTGCCCAAGGGAACCTCCAGAGGGGGCAGATTCTGAGCCGAGCAGTCTCCTCGATGCCGAAAGGGACCCACAACTTCCTGGCTTGGAAGACCCCTTCCCCACCAGCTCCTCAGGAATAACTGGCCACTGCGACCGCTCTGCAAGCCCTCTTTCTCCAACCGTCCGATAATGCACGAGGTGGCAGGGCATGATGGTGGTTGTAGTACTTGCACAGAGTCTGCCATAAATCTCCCACGGGGCTGGCGCCTCTTAGTGCTTGATGGTGGCGAGACCGATCGTGCAGGATTGGGCCAAAGGACTTATTTTTGTAAAAAAAGTATTTCTCCCCCCACAAAACCATGAATTGGGTACCACTGAAAATCTCGCGAGCATGACGGAGGTGCCCGTCCCTTTTATTCTTTTCTGTGGCTTCTGTTAATAGGAGATGCTAGTCCTGGAAGCCAGCAGTTAGTAACTACTGTTCTTCCTCCATGAGCATATCTGGGCCTTTAAAAAGGCCGTCTAAGTTACTTGTATATTGCATTAATTCCTTCTTATGTGATTTCCTCAGTTGATTTCCCCTTAAGTTCTGATATAAACAGAGAGGGGAGAAGGGTATCCTGCTTCCGAATATGGAGGTTCTGTTCTATACTGTCAGTTTTTCAGAACTGTTAGTTACCTAACTAACATATTGACTGTTTTATGTCAGTGTATGTAGCCTAGGGCTGTCTGCTCTGGCTGGCAGACAGGGTCAGATCATTGGCCCATCTAGTTCAGTGTAGCCTACCCTGACGGGCAGACCCTCTTGAGGGTCAGGGGCCTCTTTGAACTGGAGAGGGAACCTGGGAGCTTCTGCATGCAAAGTGTGTGCTCTCCCCACACTCACAGATCTATTACCCATCGCCATATCTTGTGGCAAAGAGTTCCTAAGATTTCCTAAGAACTCTTGTGGCAAAGAGTTCCTAAGATTTAAGTTCAGAGTGAGAAGGGAGAGAGCTTGCAGGAGACTTAACAAGGTCTGTGTAACCGAAAAAGACACACCCCTATTTATTTACAAATTCACAGGGTTCTGTACGTGGCAGAAAGGTGGGATATAAAATGCAACAAAGCTTTGCTTGGCTTATGGGGCCAAACCAAATAATGCATGTGAAGTATCCTTGCGTACTAAGGAAAGTCCTGTAGTCCTGATCCAGAACTTGATTCCGATCCATCGGTAGATCTCGTAGCTAGACCTCCAATCAGAACTCTGTTTCCCCAGCCCCCCGTATGGCAGATCTAGCCTTGCCATTGGACCCAATTTCCATTTGCAACCCACTTGTTGTCATTTCATCCTTCGGGTCTACCTGGAATGCAAGGCGGGACCATGGCAGCTTGGGCAGGATTCCTGTGAAGCTTTGTTAAAAGCAATTCCAGTTTCTGTGAACTGCGAGCGGAAGGTGGGCTTCCGGTCCGCTACTGTTTAAGAAAAATATTTATTTTGTCAGGAACACTGAAAGGTTGGGCATTAAGAGGATTTGCAGGAGAGATGTGTGGGTGTGCCTGCTGGGAAATAAAGCAATTGTATTAAT
->XM_029611915.1 PREDICTED: Rhinatrema bivittatum neurofibromin 1 (NF1), transcript variant X2, mRNA 
-ACTTCCGGTGTGGTGTCATGGCGTCTTCGCTGTGATGGCTGAGGAGAGGCTGCGATAACAGGGGAGGGGGGGAAGCGAGAAGAAGGGGAAGAGGGAATTAAAATAATAAGAATAACCACCCCCTCCTCCAAGCAAGCCAAAAAATAAGAGCCCTTCCAAAAACAGCAAAATAAAAAGCAACGTAGTCGCGGAGGTGGGGGGTGAAAACCTCCCACCCCTTTCTTCCCCTCCCCCGAGGGAAAGAAGGTACTTTTAAACAATATCTAAACATATATATTATATATATATGTAATATAGGAAGGTCGAATCCAGGCGGCCCCGGGGGTGTTTCCACTCCCCTGCCCGGGCTCTCCCCGGGCTGAGATGGCGGCGCACAAACCGGTGGAATGGATCCAGGCCGTCGTGAATCGGTTCGATGAGCAGCTTCCAATAAAAGCGGGACAGCAGACCACGCACACCAAAGTCAGCATGGAGCACAATAAGGAATGCCTCATTAACATTTCCAAGTACAAGTTTTCTCTGGTCATAAGTGGACTCACAAATATCTTAAAAAATGTAAACAACATGAGAATATTTGGAGAAACTGCTGAGAAGAATCTCTACCTGTCCCAGCTGATTATATTGGATACTCTGGAAAAATGTCTTGCAGGGCAACCGAAGGACAGCATGCGGCTAGATGAGACGATGCTGGTGAAACAGCTTCTCCCCGAGATCTGCCACTTTATCTACACCTACCGTGAGGGAAACCAGCACGCAGCCGAACTCCGCAACTCCGCCTCTGGCGTCCTTTTCTCTCTCAGCTCCAATAACTTCAATGCTGTCTTCAGCCGCATTTCTACCAGATTACAGGAACTGACCGTGTGCTCGGAAGAGAACGTTGACATTCATGATATTGAACTGATGCAGTATATCAACGTGGACTGTGCAAAGTTAAAACGATTGTTACAGGAGGCAGCGTTTAAATTTAAATCTCTCAAGAAAGTTGCTCAGCTGGGAGTTATAAACAGTCTGGAAAAAGCATTTTGGAACTGGGTAGAAAATTATCCAGATGAATTTACAAAGCTGTATCAGAGACCACAGGCTGATATGGCGGATTGCTCAGAGAAGTTGTTTGACCAGGTGGACAGCTTTGCTGAAAGCACGAAACGCAAAGCGGCGGTTTGGCCCCTTCAGATCATTCTCCTCGTCTTGTGTCCTGAAATCATACAAGAAATCTCCAAAGATGTGGTGGAGGACAGCAAAATGAACAAGAAGTTGTTTCTGGAAAACCTTAGAAAGGCATTAGCTGTGCATGGTGGAAGCAGACAGCTGACTGACAGTGCTGTCATTGCCAGTGTTAAGCTCTGCAAAGCATCCACCTACATCAACTGGGAAGATCACTCCGTCATTTTCCACCTTGTACAGTCCGTTGTGATAGATCTAAAGAATTTGCTATTCAATCCAAGCAAACCTTTTTCCAGAGGTGCCAGCAATCAGAATGCCGATGTGGATCTAATGATCGACTGTTTGGTTTCCTGCTTTCGCATTAATCCTCACAATAACCAGCATTTTAAGATCTGCTTAGCACAGAACTCCCCATCACCATTTCATTATGTGCTTGTGAATTCTCTACACAGAATCATTACAAATTCGGCCCTGGACTGGTGGCCCAAGATCGATACTGTGTACTGTCACTCAGGAGAGCTCCGCAGCATGTTTGCAGAAACCCTTAAAAGTGCCATGCAAGTCTGTGGCACGCATACCACCACCCGCCTGACTCAGAGTCTTCCATTCAAAGACAAAAGAACAAATCGTAAATTTAAAGACAAACCTACAGACTTGGAAACCAGACTTGGAAACCAGAAGTACCTGTTGCTGTCCATGGTGAAGTTGATTCATGGAGATCCAAAGCTTTTGCTTTATAACCCAGGCAAGGTAGGACATGACACCCAAAACAGCACTACTGAGTTAATTACCGGACTTATGCAGCTTGTACCACAGTCCAACATGCCAGAAATAGCACAAGAAGCCATGGAGGCCTTGTTAGTCCTTCATCAGCCAGAAAGCATTGAGCTGTGGAATCCAGAGGCACCAGTAGAAACGTTTTGGGAAATTAGTTCAAAAATGCTTTATTATATCTGCAAGACATTAATTGGTGCCAACATGCTGAACAGCACAGAAATTCTCAAGTGGCTGCGAGAGATTTTTATTTGCAGAAACAAATTTCTGCTCAAGAACAAGAGCGCCACAGCGGGCAGCAGCATTCCAATCTGTCGCCAGGCACAGGCCAAGTTAGAGGTTGCTCTCTACATGTTCCTGTGGAGTCCTGACATCGAGGCTGTCCTTGTTGCCATGTCCTGCTTCCGTCACCTCTGCGAAGAAGCGGATATCCGGTGTGGGGTCGACGAAGTGTCTGTGCATAATTTTTTGCCAAACTACAACACTTTCATGGAGTTTGCATCTGTCAGCAACATGATGTCAACAGGGCGAGCAGCTCTTCAGAAGAGAGTGATGGCATTATTGAGGCGCATAGAACATCCAACAGCTGGAAACACAGAGGCTTGGGAAGATACACATACGAAATGGGAGGTGGCTACCAAACACATTCTTAACTACCCGAAAACAAAATTGGAGGATGGCCAATGCACTGAAAGTCTTCACAAAACCATCGTGAAGAGGCGAATGTCTCATGTTAGCGGAGGTGGGTCAATAGATTTGTCTGACACGGACTCTCTGCAGGAATGGATCAACATGACAGGCTTCCTATGTGCTCTGGGCGGTGTCTGCCTGCAACATCGCAGCAGCGCAGGCTTGGCCACGTACAGCCCGCCCATGGGACCCATCAGCGAACGCAAGGGCTCCATGATCTCCATGGTGTCCACCGAAGGCAACACAGAGACACCCGTCAGCAAATTTTTGGATAGGCTGCTTTCCTTGATGGTGTGCAACCATGAAAAAGTGGGAATTCAGATTCGGTCGAACATTAAAGATCTGGTGGGCTTGGAACTGAGCCCTGCGCTTTATCCCATGCTATTTAACAAAATGAAGAATAATATCAGCAAATTCTTTGACTTACAAGGACAGGTTTTGCTGACTGACACCAATACGCAGTTTGTAGAGCAGACCATAGCTATATTGAAGAATTTGCTTGATAATCCTACAGAGGGCAGTTCTGAGCACCTGGGACAAGCTAGCATTGAGACCATGATGCTGAATCTAGTTCGATATGTTCGTGTGCTTGGAAATTTAGTGCATGCCATCCAGATAAAGACAAAACTCTGCCAGCTCGTAGAAGTGATGATGGAAAGGCGAGACGATCTTTCCTTCTGCCAAGAAATGAAATTTCGGAATAAGATGGTGGAATATTTAACAGACTGGGTTATGGGAACGTCTAACCAAGCAGCGGATGAGGATGTAAAATGCCTAACCAGAGACTTGGACCAGGCCAGCATGGAAGCAGTAGTCTCTCTCCTTGCTGGTTTACCTCTGCAACCTGAAGAAGGAGATGGAGTAGAGCTGATGGAAGCCAAGTCCCAGTTATTCCTCAAGTATTTTACTCTCTTTATGAATCTTCTAAATGACTGCAGCGAAGTTGAAGATGATGGTACTCAGACTGGTGGAAGGAAACGAGGGATGTCTCGGAGGCTAGCTTCCCTGCGACACTGTACTGTTCTTGCTATGTCAAATTTACTGAATGCTAATGTGGACAGTGGTCTCATGCACTCAATAGGTTTGGGCTATCACAAGGATTTGCAGACAAGAGCCACATTTATGGAAGTCCTTACCAAAATCCTCCAGCAGGGGACTGAGTTTGACACCCTGGCAGAAACTGTGCTTGCGGATCGTTTTGAGAGATTGGTAGAATTGGTCACTATGATGGGCGACCAAGGAGAACTGCCCATCGCCATGGCTCTAGCCAATGTGGTGCCTTGTTCACAGTGGGATGAGCTAGCCCGTGTCCTTGTGACCCTTTTTGATTCACGACATCTGCTTTACCAGCTTCTCTGGAACATGTTTTCAAAGGAGGTTGAACTGGCAGACTCCATGCAGACCCTTTTCCGGGGAAACAGCTTGGCCAGTAAAATAATGACTTTCTGCTTTAAGGTGTATGGTGCTACATATCTGCAAAAGTTGCTGGAGCCTCTGCTCAGGGCCATTATCACATCACCTGAGTGGCAGCACGTCAGCTTCGAAGTGGATTCCACAAGGCTGGATGGGATGGAAAGTCTGGATGAAAACCAGCGCTGGCTGCTGCAGATGACAGAGAAATTCTTCCATTCAATAATTACTTCCTCTTCAGAGTTTCCTCCCCAGCTGCGAAGTGTCTGCCACTGTCTGTACCAGGCAACTTGCCACTCTCTTCTGAGTAAAGCTTCCGTAAAAGAAAAAAAGGAAAACAAAAAATCAGTTGTCAGCCAGCGATTCCCCCAGAACAGCATTGGGGCAGTCGGCAGCGCCATGTTCCTCAGGTTCATTAACCCTGCAATCGTCTCTCCATACGAAGCAGGAATCTTGGACAAAAAGCCACCACCTAGAATTGAACGGGGCCTAAAGTTGATGTCAAAGATCCTTCAGAGTATTGCCAATCACGTCCTGTTTACAAAAGAAGAACACATGCGCCCTTTTAATGACTTTGTGAAAAGTAACTTTGATGCAGCTCGAAGGTTTTTCTTTGACATTGCTTCGGATTGCCCAGCTAGTGATACAGTCAATCATAGCCTGTCCTTTATCAGCGATGGTAATGTGCTGGCTTTGCATAGGTTGCTTTGGAACAATCAGGAGAAAATTGGCCAGTATCTCTCTAGCAACAGGGACCATAAAGCAGTGGGCAGGAGACCTTTTGACAAGATGGCAACTCTGCTCGCATACCTGGGACCTCCAGAACACAAACCTGTAGCAGACACACACTGGTCCAGCCTAAATCTCACCAGTTCCAAATTTGAGGAATTCATGACCAGGCACCAGGTACATGAAAAAGAGGAGTTTAAGGCGTTAAAAACTCTCAATATCTTCTATCAAGCAGGGACATCAAAAGCTGGAAATCCGGTATTCTATTATATTGCCAGGCGATTCAAGACTGGCCAGATAAATGGGGACTTGCTAATATACCACGTGTTGCTGACTTTGAAGCCATACTACGCCAAGCCATATGAGATTGTAGTGGACCTCACCCACGCTGGGCCCAGCAATCGCTTTAAGACTGACTTCCTTTCCAAGTGGTTTGTCGTTTTCCCTGGGTTTGCATATGAAAATGTGACAGCAGTTTACATCTACAACTGTAACTCTTGGGTGCGGGAGTACACAAAGTATCACGAGAGACTGCTCACCGGCTTGAAAGGCAGCAAGAGACTAATTTTCATTGACCCCTCGGGGAAGTTGGCAGAGCACATTGAGCATGACAAGCAGAAACTACCAGCTGCCACTCTAGCTTTGGAGGAAGACTTGAAGGTGTTTCATAATGCTCTCAAACTGGCGCACAAAGACACCAAAGTTTCTATTAAGGTTGGTTCCACAGCAGTTCAGGTGACATCTGCTGAGCGGACAAGAGTCCTGGGTCAGTCAGTTTTTCTGAATGATATTTACTATGCCTCCGAGATTGAGGAGATCTGCCTCGTGGATGAGAACCAGTTCACGCTAACCATTGCCAACCAGGGAACACCTCTGACTTTCATGCATCAGGAGTGTGAAGCCATCGTCCAGTCTATCATTCACATAAGGACTCGATGGGAGTTGTCACAGCCCGATTCCATTCCACAACATACTAAAATCCGTCCAAAAGATGTGCCTGGAACATTGCTCAACATTGCATTGCTTAACCTAGGAAGCTCAGATCCAAGTTTAAGGTCTGCTGCCTATAATCTTCTGTGTGCCTTAACATGTACCTTTAATTTAAAGATTGAAGGCCAGTTACTGGAGACTTCAGGTCTGTGTATCCCTGCCAACAACACCTTGTTCATTGTCTCCATAAGTAAGACTTTGGCAGCTAATGAGCCCCATCTCACCTTAGAGTTTTTGGAAGAGTGCATTTCCGGATTCAGCAAATCCAGCATTGAACTAAAGCACCTTTGCCTGGAGTACATGACCCCCTGGTTACTAAATCTGGTGCGCTTCTGTAAACTCACCGATGATGCCAAACGGCAGCGAGTCAGCGCTATTCTGGATAAGCTGATAACCATGACAATCAATGAAAAGCAGATGTATCCTTCCATTCAGGCAAAGATATGGGGAAGTCTTGGACAGATCACAGATTTGCTGGATGTGGTTCTGGACAGTTTCATTAAAACCAGTGCCACAGGTGGTTTGGGATCCATAAAGGCTGAAGTTATGGCAGACACAGCTGTAGCTCTGGCTTCAGGCAATGTGAAATTAGTCTCAAGCAAGGTGATTGGAAGAATGTGCAAAATAATTGATAAGACCTGTCTGTCGCCTACACCTACATTAGAACAGCACCTGATGTGGGATGATATTGCCATCCTGGCCCGGTACATGCTAATGCTGTCCTTCAACAATTCACTGGATGTGGCAGCGCACCTTCCCTACCTCTTCCATGTTGTCACTTTATTGGTGGCCACAGGTCCTCTGTCTCTGAGAGCTTCCACCCATGGCCTGGTCATCAATATAATTCATTCCCTGTGTACCTGCTCACAGTTGAACTTCAGCGAGGAGACCAAGCAAGTTTTGAGACTCAGTCTGACGGAGTTCTCATTGCCCAAATTCTATTTGCTGTTTGGAATTAGTAAAGTGAAGTCAGCCGCTGTCATAGCCTTCCGATCCAGCTACAGGGATAGGTCGTTCTCTCCTGGCTCCTACGAGAGAGAAACGTTTGCTTTGACGTCGCTGGAGACGGTCACAGAAGCTCTGCTGGAGATAATGGAGGCTTGTATGAGAGATATTCCAGCATGCAAGTGGCTAGACCAATGGACAGAGCTAGCACAAAAGTTTGCATTTCAGTATAATCCATCCCTGCAGCCCAGGGCGCTAGTAGTCTTTGGCTGTATCAGTAAACGAGTGTCACATGGGCAGATAAAACAGATCATCCGCATCCTTAGTAAGGGACTGGAGAGCTGTCTTAAAGGCCCTGATAATTATAACAGTCAGGTTTTAATAGAAGCCACAGTTATAGCTTTAACCAAACTACAGCCACTTCTGAATAAGGACTCCTCTATGCACAAAGCCCTCTTCTGGGTGGCTATGGCGGTGCTGCAGCTGGACGAAGTGAATCTGTATTCCGCAGGCACAGCCCTCCTCGAACAAAACCTACACACATTAGATAGCCTTCATGTGTTCAATGACAAGAGCCCTGAAGAAGTATTCATGGAAATCAGGAGGCCCCTGGAATGGCACTGCAAGCAAATGGATCATTTCGTCGGGCTCAATTTCAACTCCAACTTTAATTTTGCACTAGTAGGACACCTTCTGAAAGGTTACAGGCATCCTTCTCCTACCACAGTAGCACGGACGGTCCGCATTCTACACACATTGCTGGCGCTAGTTCACAAACACAGGAATTGTGACAAGTTTGAGGTGAATACCCAGAGTGTGGCTTATTTGGCAGCTTTACTCACAGTGTCTGAAGAGGTCAGAAGTCGCTGCAGCCTAAAGCACAGGAAATCTCTCTTATTGGCAGATGTTTCACTGGAAAATGTTCCTATGGATACATATCCCATGCATCACAGTGACCCAAGCTACAGGACATTGAAGGAAAACCAGCCGTGGTCCTCCCCAAAGGGTTCAGGCATCCATCTTGCTGCAAATTACCCAACAGTGGGGCAGATTAGTCCCCGAACCCGAAAATCTATGAGTCTGGATATGGGGCAGCCATCACAGGCTAACACTAAAAAGCTTCTAGACTGCTGCTGTAACTCTGTTAAGTTTTGGCTAGGCGTGGCTGAAAACGGGATATTTGTTCCAGTCCACTTTCCTGGTACAAGGAAAAGCTTTGATCATTTGATATCGGACACCAAGGCTCCAAAAAGACAAGAGATTGAGTCTGGGATCACTACACCTCCCAAAATGAGAAGAGTTGCAGAGAGTGACTACGAAATGGAAACCCAGAGAATAGCATCGCCCCAACAGCACCCTCACCTGCGCAAAGTCTCAGTGTCCGAGTCCAATGTGCTTCTGGATGAAGAGGTCCTAACAGACCCCAAAATCCAAGCTCTGCTGCTTACCGTCCTTGCTACACTGGTAAAGTACACTACAGACGAATTTGACCAGCGAATTCTTTATGAGTACTTAGCAGAAGCGAGCGTGGTCTTCCCTAAAGTTTTTCCTGTCGTGCACAATCTGTTGGACTCCAAGATTAATACCCTTTTGTCACTGTGCCAAGATCCAAATTTACTGAATCCAATTCATGGGATTGTACAGAGTGTGGTTTACCATGAAGAGTCCCCGCCCCCATACCAGCCATCCTACTTACAAAGTTTTGGTTTTAACGGTTTATGGAGGTTTGCTGGGCCATTTTCAAAGCAAACACAAATTCCAGAAGATGCTGAACTCATTGTAAAGTTTCTGGATGCCTTGATCGACATGTATTTGCCTGGAATAGATGAGGAAACCAGCGAGGAGTCCCTCCTGACTCCCACATCTCCTTACCCTCCTGCCGTGCAGAGCCAGCTCAGTATTACTGCCAACCTGAACCTTTCCAATTCCATGACCTCGCTTGCCACCTCCCAGCATTCCCCAGCTTCTCTGCCTTGCTCTAAATCAGCAGTTTTCATGCAGCCCCTCGCTCATCAAGGAATCGACAAAGAGAACGTGGAACTCTCACCCACGACGGGACACAGTAACAGTGGCAGGACGCGTCATGGATCTGCGAGCCAGGTGCAGAAGCAGCGGAGTGCTGGCAGCTTCAAACGGCATATCATTAAAAAGATTGTGTGATGTTTGCATGGGGGAGAGGGGTTTTAGAGAGAAAAAGCATACAAGAAACCAAGAAAAAGACTTCTGCTTGTGAGCTTCTCACCAGTGACCCCTACCAGTCAGGATGCTGCACTTAACTTTTAATGTCACCGTACAGTCAGCCATGTTGCCAAAAGAACAACTCTTTGATGTATTGCCTGAATTAACATAGTTTAATGCCTCCTTCAGGTTTCTTCTGTTTCTCTTTGTTCTTTTCATTTTAAAGCAGTGTTCCAGAACCATTGTAGAAAAATTGTTCGTAGATCCCAAGGTTCCAGAATGAAGAACTTTGCAGCTAAAGAAAGCACTGAATCTGCTTCAGTACCTAAACTACAGAAGCCATTTTTTTTTTATTTTTTTTTTTTAGAGATGGTTCTCTGGCTTTTTCTTCCTTGCCTTGCTTTTTTAATTTTGTTTTTGTTTATAAAAAGGAAAGTGTTAATGCTGAATTATTTTTGCACACTTTTCAAAATGGAAAAAACAATAGAGGGATAAATCCTGTTCTTAATGGAAACCCCTTTTAGACTTTTTAGTAGTCCTCTTTTATTTCTTTTTTCTTTTTTACCTGGAAATGAATCTGTAAAAGTTGCAATTGTTCAACTGTGGGCCTAACTAACCAGAGATTGTGCACCTTTAAATAATGTAACTACTTTATCATTTATGGTGGAATTCATGGGAATATAAAACTCTGGCATCAACAAAATCAGCATTTACTCCTTGATACCTGTCAGTTTCTCTAGTGTTCATTTATATAAGGCAAAACTGTTTGTCCCCCTGTTTTTATTGTCTGTAACATTTTAATGGAAAATTGCAGGGTTTTTTGAAAGAGTGAGGGGTTCCAATTTTCAGTGTTAGTTGCTGAGCTGTTTCTCTTCCTGAGTTTGTAGATAATGGTTAGGGTTAAGTCTCAACGTACCCTGCTGCCAGAATGGAATGGTTTGTTAATGCAGGTGTAGAGAATTCAAGTAATTTTTTTCCAGCAATTTCTGAAAACTTCTCTGTGAAGACCTGTTATGACAGCCTCCTGAAGGGAGATGGTAGTTTAAATTTTCTATCTGTGTTTTCCTGGGGGTTCCCCTCAAAACAAAAATAACTACTGGGAGAATTTAGTTCAAAATAACTAATCCCCCTAAATTAATTATTTAATAAGCTTGAAAGCAAGGAGCAAAATACTGATTTTATCATGCCTCTGTTCATGTGTTCTGAATGTAGATGCACCTGCCTGAAGCAATGCTGCGCAATCTTGTTTTTTTTTAAGCAAACTAATCTGTTTTAACCAATTTATATCTGCACTAAAACACATTAGAAGGCGAGAACTGACATCTGTGGTGACACTTTGAATAGAAAAGACATTTGAGACTATTTGTTCATCCAATGTCGTCCTGGGTTTTTTTTTTGTTTGTTTTGGTGCCCCTTAAGTTTAATAGATTCTTCCCCCGGGGACATTGCAAGCAGAATAAATACAGGATTAGGCAATGTGGGAGTTAGAAGCATTACGTCCATGCAGCTCAGCCCAAAAATCAACGCATGTATTATGCCCACATAAATGCAAGATGGAACGGTACATGACCGGAGCGGGCTTAACAAAAAATCCGCTTCATGATGTCAAGCTCTCCCAGTCAAGAATTCTGGCAGTACAGTTTGTCTTATCGCCAGACTTTCCAATCAACATCCACTTATGCTGTAGAATAATCAGAAATTCTAAGAATCACTTTAGAAACATTTTGGGGGTTTATAATTAAACTGAAAACCACATTCTATCACTGTGAAAGCCGTGTCAACCTAGCATAGTATAATGGCAGTGGATGACTGTCCTGGTATACTGCTGTTAAGGTTAATATGTACTATGGAATAGGGCAAGTGGTTAAAATGCTATAATGGACGAAAATGTAAACATTCTGATCATGGAGATAAATACACGTTTGACAGCTATGAGTCAAGGTCATGTTATTTAGGTGCTCATTTTTAGATTGACTGTATTTACTGCTTTAACAACATCTATTCATGGCCCCAGTATAGTACTAAAATTACAAAAAGCTTTAAAAAAAAAAAAAAAAAAAAAAAAAGTATATTGTTAGTGTATTTCAGTAAATCAAATTCCACAGCTAAATTACTAGAAAAAAGGTACAATAAAGTGTTCAGATTGTATTTCTATAGCACATAACACACTTATTCAGACACAGTAATCAGTTTAACATTTATGAATGTAAAAAAATGCCTTTATTTTATTGTCACAAACAAATAACTTAATTTCTTTTTAATTTGTTTACAGTCCTGGAAAAACTATGAACAGAAACATAATATGCAAATATAGTTTGCCAAAATAAGTTTTAAAAAACAAACAAAAAACCCCGTAGTATTAGTTGTGGCTATTTTGAAGTAGCTGACATGTTCAAAATATTGAAGGTTTGTGCAATTAACCAAACTTTTTGTTTTTTATTATTATTATTATTATTACTGTTATTGATAATGTAGAAGTTGCAAAATAGAAATAATTAAAATGCTACAAAATGTATGAAGGGTATTAAAAGGTGAATGAAGTTAGGAATAGAGCAGGGACCCAGTGGCAGGTGCTATACCCATTAGTTTATTTTCCCCAGTCCTGAGATTTCACATGTGAAAACCTACTGTACTGTACACGAGATTCTACTGTAGATTGAATCAAAATTTATTGAAAACATGTACCAGTTTAGCTCGTAAGTGATTGCGTACCAAACTGTATTTTCTCTTTTTTAAAATTTTCATTTCAAATTGAGCAGGAAAGAAAGCAGGGGGAGAAAATGTAATAGATGCCTTGATCTGATTTTTCAAAACACTACAATTTTCTGAAACTGTTGCAAGATTGGATTTCTTTAGTAACCTATTCAAATCATTGACTCTTTCCATTGTGATTCTTAGTGTTAAAAGTGCACGTTGCTTAATCATAGGCTGAGTTGCACAAAAAAATGTCAATTTGGAATGTACACCCTCCACCCTTCCTCCCCCCTCTATGAAATTTAAAAAATATCAGACAACTAAAATTGCTTCTCACTATTGGAATCCAAAAAAATGACCAGGAAATGTTTCACTTGTCCTAACAAAACTTGTACAAAACAAAATGCACACAGCATAACTAACATTTACTTAAAAAAAAAAAAAAGCAAATGAACATGTCCATTACTGGTACCTGAGATCT
->XR_005095104.1 PREDICTED: Pollicipes pollicipes uncharacterized LOC119106218 (LOC119106218), ncRNA 
-AAGAAATGAACTTCAACTGCCTGATCTGTGGAACCAGATGCAAGCTTCACAAGAGCCAGCTTAGTTCCAGGCTGGGAGAGTGGCAACAGGAGTGGTCCTCCAAGGAAGCTGATCAGGGACTCGTTTGGATACTGGATCTGGATCTGAACTGCTTGGACGAGGAGCAGTGCCTGTGTCCAAAGTGCTCACAACTCTTGCGTGATCTTCGGAGCTATGAAGCTAAGGTCACCGAAATCCGAACTGAGCTCATTCAGAGACATGAGGGTTGCATGCATACAGACACTCCAGGATCTGTAGACATCACTGTCACAGAAGCGTCTGTGAGGCATAAGCCGAACTCGGCGAGGCCAGAGCCGGAGCTGGAGCTAGAGCCAGAACCAGATCCAGAGCCGGAGCCAGAGCCAGATCCGGAGCCAGAACCAGAGCCAGAGCCAGCGCCCTGCCTGCGGCGAAGCTCTCGTCGTTGTGGACGACCGCCGGCGCCGGG
->XM_024031699.1 PREDICTED: Quercus suber uncharacterized LOC111999568 (LOC111999568), partial mRNA 
-AGTGCAGACCTGCGTTGGAAGCCACCTGACTTGGGTGTCTATAAAGTCAACTTTGATGGGGCTTTATTTATGGATCAGAGGTGTGCTGGTTTAGGGGTGGTTGTTAGGGATTCAGCTGGGCTTGTTATTGCTGCTTTAAGCCAGAGAGTGAGGCTGCCAGGATCGGTTGATGTGGTGGAGGCCTTGGCAGCTCGTAGGGCAATGTGTTTTGCTCAGGAACTTAGCCTTCATCATGTGGTGATTGAAGGGGACTCTTTGCGAGTTATTCAAGCCATTAACAACACTAGGCCAGTGCAGACTTTGTATGGACACATTATTGACGAAATTAGACTTTTATCTTCGTCAGCTAATTGTAGTTTTTCGCATTTTAATCGGAATGGCAATAAGTTAGCTCATGCCCTTGCTAGACGAGCAATTTTATCTGCTGATACTGATGTGTGGATAGAAGAACTTCTATAG
->XR_001602060.1 PREDICTED: Miniopterus natalensis uncharacterized LOC107525510 (LOC107525510), ncRNA 
-TCACGGGCAGCGGGAGTAAAACCGCGGGCGCTGGAAGGGGCAGAGTGGTGAGGGCTTCTGAAGGCGCAGCCGCGCTCCCCGCGGCCCGGCTGAGCGTCCACCAGGAGCTCGCGCCAGGCCTTCCCGGCTGGGCCGGCCGAGGGCAGCCAGAGCTGTGTGATGACCCGGTTCCAGCTCACACCGCCTCGTGCGCCCGGTGTCGGTGACTGAGCAGCTGCCACAGGGCTTCCCAGTTCTGGAGGCTGGAAGTCCAAGATCAAGTGTTGGCAGAGTTGGTCTCTGCTCACTCTAGCGAAGGTTAGCCACCCTGTCATGAGGACATTCAGCACCCCCTTGAGAAGTCCATGTGTGCCAATGTCCATGTGTGCCAACGTCCACGTGGAAAGGAGCTAATTCACCAGCAACAACTTTCCAGCCAGCTGCAGCTCCAATAAAGGCGAAACCACCGGCCACCCTCCCTCTGGATCTGAATGCTTTCAAGGAACTATTTATTGAGACTGAGCAAGGACTACTTTCTCTGGTTTTCAAATATGTTTAACACACCAATCAATGTGGCACCTTGTTAATCATTTCACTCAACCAATCCTCATCGAGCACCGAAATACACAGAGCACAATCCCCAACAGTGAGGTTCAAGGTGGTGAAACCCCATCACTGCCATAGGAGCTTCCTGCCCAGTGGATTCGAATTACAGAATACAATATAATCAGGTAATAATCACCAAAAACATCAGGTCTAGTTTTACTCATTTACCAAAGGCGTGAGAAAGCTGGGTGTGCCCTGGGA
->KP885581.1 Homo sapiens isolate SLS040 tRNA-Pro (trnP) gene and control region, partial sequence; mitochondrial 
-ATTCTAATTTAAACTATTCTCTGTTCTTTCATGGGGAAGCAGATTTGGGTACCACCCAAGTATTGACTCACCCATCAACAACCGCTATGTATTTCGTACATTACTGCCAGCCACCATGAATATTGTACGGTACCATAAATACTTGACCACCTGTAGTACATAAAAACCCAATCCACATCAAAACCCCCCCCCCATGCTTACAAGCAAGTACAGCAATCAACCTTCAACTATCACACATCAACTGCAACTCCAAAGCCACCCCTCACCCACTAGGATACCAACAAACCTACCCACCCTTAACAGTACATAGCACATAAAGCCATTTACCGTACATAGCACATTACAGTCAAATCCCTTCTCGTCCCCATGGATGACCCCCCTCAGATAGGGGTCCCTTGACCACCATCCTCCGTGAAATCAATATCCCGCACAAGAGTGCTACTCTCCTCGCTCCGGGCCCATAACACTTGGGGGTAGCTAAAGTGAACTGTATCCGACATCTGGTTCCTACTTCAGGGCCATAAAGCCTAAATAGCCCAC
->XR_003958643.2 PREDICTED: Taeniopygia guttata SFT2 domain containing 2 (SFT2D2), transcript variant X1, misc_RNA 
-GTGGGCGCGGTGGTTGCCGGGGCTGGTAGTCCCTGGGGAGGGCAGGGCATTCCGGCCGGCCGGGCGGGGTGCGGAGCCATGGACAAGCTGAAGCGGGTGCTGAGCGGCCGCGACGCGGAGGAGCCGAGCGGCCTGGCCGAGGTTATCGATGCGACTTCCTTAGGTTGGGGCACCCGAGTGAAAGGTTTCATTGCGTGTTTTGCGATCGGATGTCTGTGCTCGATCTTGGGTAGTTGTCTGCTATGGATACCAAAGAAAGGGCTGGTATTCTTTGCGGTGTTTTATACCCTGGGGAATATTGCATCCATTGGGAGCACCATGTTTCTTATGGGACCAATGAAACAATTGAAGCGGATGTTTGAGCCCACACGTTTGATTGCTACTATTGTTATGCTATTGTGCCTCATACTAACACTGTGTTCTGCTTTCTGGTGGCGTAAGGCAGGACTCGCGCTGCTTTTCTGCATCTTACAGTTTTTTGCCATGGCATGGTACAGCATTTCCTTCATACCATATGCGAGGTTGGAAAGATGGAAAGATGTGTCAGTGGTGAACTCTGCCTTCTGCTACATACAACATAAATTGCTCTTAGGCTGAACTCTTAGAGTTGAAACAACCTTCCCCATGCTGAGAATAGTAATTGGGCTGTTCCCACTAACCAACTACAGCTCCTTCAGTTAGAGTCTGCACCAGCATGAATGCAATTTCCATGCATTGTTTCAGTCTGGAAATGAAACAATTTTCATTAATGG
->KJ543947.1 Bacterium AM0179 16S ribosomal RNA gene, partial sequence 
-TACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGACGAAAGTCTGACCGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAACTCTGTTGGTAGAGAAGAACGTTGGTGAGAGTGGAAAGCTCATCAAGTGACGGTAACTACCCAGAAAGGGACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTCCCGAGCGTTGTCCGGATTTATTGGGCGTAAAGCGAGCGCAGGTGGTTTATTAAGTCTGGTGTAAAAGGCAGTGGCTCAACCATTGTATGCATTGGAAACTGGTAGACTTGAGTGCAGGAGAGGAGAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAGGAACACCGGTGGCGAAAGCGGCTCTCTGGCCTGTAACTGACACTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAGATGTAGGGAGCTATAAGTTCTCTGTATCGCAGCTAACGCAATAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATACTCGTGCTATTCCTAGAGATAGGAAGTTCCTTCGGGACACGGGATACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTATTGTTAGTTGCCATCATTAAGTTGGGCACTCTAACGAGACTGCCGGTGATAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGATGGTACAACGAGTCGCGAGACAGTGATGTTTAGCTAATCTCTTAAAACCATTCTCAGTTCGGATTGTAGGCTGCAACTCGCCTACATGAAGTCGGAATCGCTAGTAATCGCGGATCAGCACGCCGCGGTGAATACGTTCCCGGG
->XM_007779277.1 Coniosporium apollinis CBS 100218 hypothetical protein partial mRNA 
-ATGTCGGGAATCAAATCCGCCGCTGCCGTAGGACTTACTCTCCTTGCCAATCTTGTTTTGGCCCAAGAAGTTATCATCAACGGTGTAGTCCAACAAGATGTCTTCTTCTACGGTCAGAGTCCACCGGTCTATCCATCACCTGATGCTGAGGGTGACGGCCGCTGGGGCGACGCCTTGTCAAGCGCTCGGGCGATCGTTGCTCAAATGACACTTGAGGAAAAGGTGAACATCACCGGAGGGTTCTCTAACACCACGAATGGATGCGGTGGAAACATCCCGGCCATCGAACGCCTGAACTTTCCTGGAATGTGCTTGCAGGATGGCCCGAATGGTGTGAGAGAGACTGATTTCGTCAATGGCTACGCTGTGGGCATTCACGTTGGTGCAAGCTGGAATCGGAATCTGACTTACGCGCGCGGTTCTGCGATCGGTGGCGAATTCAGAAGGAAAGGTGCCACAATCGCCTTAGGCCCTATGGTCGGACCGTTGGGAAGGATTGCTCTTGGTGGTCGCAACTGGGAGGGATTCAGCAACGATCCCTACATCAGCGGTATCCTTGCTGCTGAAACAGTTAGGGGAATCCAAGACAGAGGCGTAATTGCTTCCACCAAGCACTTTGTTGGAAACGAGCAAGAGCTTCTGCGAAACCCCCGCCCAGATCTCAGCAACCGCAACAAGACTATTGAAACTTCGTCTTCGAACATGGACGATGCGACGATGCACGAACTATACATGTGGCCTTTCGCGGACGCTGTACACGCTGGTACAGGCAGCATTATGTGCGCATACCAGCGCCTTAATAACAGTTATAGCTGCCACAATAGCAAAGCTCTGAACGGTCTTCTAAAGACCGAGTTAGGCTTTCCAGGTTTCGTGCTGAGCGACTGGGGTGCTCAACACACTGGCATTGCCAGCGCATTGGGCGGTCTCGACATGGTCATGCCTTTTGGATTCCGCTTCTGGGGCCCCAATCTCACTGAAGCAGTCCGGAATGGCTCGGTTCCAGAGTCCCAAATCAACAACATGGCAACGAGAATCATGGCAGCATGGTACTTTGTGGGCCAGGACAGTCCAGACACGCCTCCTTTAGCAGTTGGCATGGCACGCAGCCACTTGCGTCCTCACACTGTGGTCGATGCCCGAGATCCCGCGGACGACGCCGTCAACCTCCAGGGAGCTATTGAGGGCCATGTCCTTGTCAAGAACATCGACAACGCCCTACCTCTACGAAATCTCAGCATGATGTCAATCTTTGGCTACGATGCCAAGAACCCTAACTACAACAGTCCGGCAGAAGGATTCAGTGCTTGGTCCCTGGGTCTCCAATCCCAGAATTACCGCTCTATAACCGGAGGCGGCTCAGGAGCTATTACCCCTTGGTATATTGACGCACCGTTCGAGGCCCTGTCCCGACGCACACGTGCAGACAGAACCGCCCTGTTTTGGGATTTTGACACCAACGGAGCGAACAGCACGATTGACACCAACAGCGAGGCCTGTCTCGTGTTTATAAATTCAGCCGCTTCTGAAGGTGTTGATCGGCCATCCCTACGCGACGACTTCTCGGATGCATTGGTAGAGAACATTGCCTCCTCTTGCAACAACACAATTGTTGTGATCCATAACGCTGGCGTCCGTCTAGTTGACCGTTGGATCGACCATCCTAACGTCACAGCACTCATCTTCGCTCAACTGCCGGGTCAAAACTCAGGCGAGGCGATCACGCAGATTCTCTATGGCGACGTTTCCCCCAGCGGCAAGCTTACTTACTCTATACCACGGAACGAATCTGACTACGGGTCGCTACTGGCACCCGTCAATTACACTGGCTGGGACCGCTACTTCCCGCAGGACAACTTCACAGAAGGTGTCTACATCGACTATCGCGCTTTTGATGCAGCAGGCATTGAGCCCAGGTATGAGTTTGGCTTTGGCCTCACCTACACAACCTTCGAGTACTCTGATCTCAATATTCAAGTTACAAGCGATGGGAACCTCTCGGAATACCCTGTTGGGCCAGTAATTCCCGGAGGGGAGGCGGACTTATGGGACAACCTAGCCACCGTGACAGCGGAGGTCACCAATACCGGCGATGTAGAGGCGGCCGAGGTGGCCCAGCTGTACCTTGGGATTCCAGTTGCCGGCCAGCCTGTTAGGCAGCTGCGGGGCTTTGACAAGGTGATGATCGCGCCGGGTGAGACGAGACACGTTCAGTTTGATCTGAGACGGCGCGACTTAAGCGTGTGGGATACTGGTGCGCAACAGTGGAGACTTACCCTCGGAACCGAATATCGTGTTTGGGTGGGAGCGAGCTCCAGGATTCTGCCACTGAATGGAACCATGGTCTTGTAA
->XM_034834249.1 PREDICTED: Vitis riparia plasmodesmata-located protein 2 (LOC117917828), transcript variant X2, mRNA 
-GAAACCCAAAAACAAAAATCACCCAAAAAAAGGTTGGAACCCCACAACGCTCCTGAGCTTTTCTCAACCAGAATCCATCACCCTTGCCTTGATTTCAACCAAAACCCATTTCTAGAGACCACCAAACCCTGCAAAAACCATTCATGCTCTGAACGATTTCATGTTTCCTAGATGGGTTTGCCGCCAAAACCCCTGTCTCTCCTCTCCCTCTCTCTGACTTTCCTCACAATTCTTGGCTTCTTCCCATCTGCCAAACCCTCCACAGATTTCACAAACTTGGTGTATAAAGGCTGTGCCGACCAAAAATTCCAAGACCCATCAGGGGTTTACTCCAAAACCCTCAAACCCCTGTTTGATTCTCTGGTTTCACAGTCCTCCACAAAGAATTTCTCCACAGCCACCTCTGGTGAGGGCCAATCTTCCATCACAGGGCTGTACCAATGTAGAGGTGATCTCTCCAATTCCCAATGCTACACCTGTGTGGGAAAACTCCCAGGCCTCTGCACCAAGCTCTGTGGCAAAGCTATAGCCGCCAGAGTTCAACTCAGTGGGTGCTACATGAGGTATGAGCTTGCTGGGTTCAAGCAGGTCACTGCAACTGAGCTTCTGTACAAGGTGTGTGGATCAACTCAGGCAAGTCAGAGTGGGTTTGAAGAGAAGAGAGACACTACTTTTGGGATGATGGAGAAGGGAGTTGAAGGTGGGGATGGATTCTACACTGGGACATATGAGTCTGTGTATGTGTTGGGGCAGTGTGAGGGGGACATGGGAGGTAGTGATTGTGGAGATTGTGTGAACACTGCAGTTGAGAGAGTCAAAACCGAGTGTGGTGACTCAATTTCCGGGCAGATTTATTTGCACAAATGCTACATCAGCTATAGTTACTATCCAACAGGGGTGCCCAGCCAATCTTCAGCAGAATCAGGTCAGAGTACAGAGAAGACAGTAGCACTTGTTGTGGGAGGGGTAGCAGCTCTAGGGTTTGGAATTGCTTGTTTGATGTTTGTTAGAACAGCTTTCAAGAAACATCATAGTAATTACTGAAAATTTTGAGATATGGGTCTAGAAGATGCCACTGTTTTCTGTAGTGGGTCTCCTCTTTTCTTTGATAAAGAGGGTGGGAAGAGGGTGGTAAAGTTAGGTGAAGTATTCATTGAATCATTGGGAGTGTTGTAAATGGGAAAGGAGAGAGGGTGGGAAGAGATGTTTTTTCTCTCCTTACTTCACACTTAGACTCTACTAGTATTTTGTCATTTTCCATTTTCCTTGTGCATTACATTCCCACACATGAAATTGATACATATGATTCAAAGTATTTTGCTTTCCAATGAAGTTTCCCACTTTATCACTTTATCA
->LN615563.1 Uncultured Glomus partial 18S rRNA gene, isolate ACyCA VTX00247, clone GAMF284 
-AGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAATTTCGGGGTTAGTAGGTTGGTCATGCCTCTGGTATGTACTGGTCTCACTGATTCCTCCTTCCTGACGAGCCTTAATGCCATTAATTTGGTGTTTCGGGAAATTTGGACCGTTACTTTGAAAAAATTAGAGTGTTTAAAGCAGGCTCACGCTTGAATACATTAGCATGGAATAACGAAATAGGACGTTTGATTTTATTTTGTTGGTTTCTAGGATCGACGTAATGATTAATAGGGATAGTTGGGGGCATTAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATTGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGATGATGTTAATTTTTTAATGACTCATTCGGCACCTTA
->XM_026558135.1 PREDICTED: Papaver somniferum 60S acidic ribosomal protein P0-like (LOC113309662), mRNA 
-TGCTCATCACTTTCTCTCTCAACCAACTCTTTCTCTCTCCTCTCTGAAATAGTGAAAAAAAAATCTTTACAGTTTTTTCGTCATGGAAGAGTAATCTCTAGGCAAACCTTCGGGTGATTAACGGGTCAAGAGCTGCAAGGAGCGGATCTGAATGTTTTCGGATTGAAAAAGTGGTGATGAAATTTTAGGATTTTTTAATCTTGTTTTTCACTTTTCTTGCTTTGTTCTTAATCCTCTCTTCTTTCCGGGTTTGAGAAATACAAGCTATGGTTCCAATTGACACAGGTATTCCCTTGGATTGTTGTTCTTTTTGGGTTTTGTATTGATTCTTCTCACTTCGGGTAAGTGAAATACAAGTTGTGGTTCCAATCGAGGACCGTGGCTCCTTTTTATGATCTTGATTGAATCTTTTCTTCCTTTCTTTGGGTTTTTGGGGGTACTGTTGTATTAGGTACAACAACAACAGGGGATCTAAGATTTCTCTTTCAAATTTCTTTTGTGTTCTGATTAGATTTGCCACTGCATATAATTATCAAGCTGTTTTTCTCATTCCTCCCCTTTTAGGTTGTTCTCGGTATGGTAGTGATAAAAAAAAAACGAGGATATAGAGGGTTGAATCTACCTTTGGTCTGATTCTCTTAAGCTTGCAATTATTCTTTTTTTTTCTTTCATGTGTAACTGGATTGTAGACCAATTAAGTAGTTGTCGGTATCCCAATTGAGATTGGGTATGTGGATTCGAATTTTGCAATCTAATTTCCTTTGCCGTAAATACCAATGTTGATTGGGTCTGTTTATTTTTGTTGCCTCTAAGCTGTTTGGTGAAAGTCCTGAACTGTCTTTCTCCTGTATTTGGCCTCTCTTGCATCCTATCTTGAATGATTCATTCTAAAATTTTAGGTTTCTTACATCAGTTTGGTCAAATTTTCGTTTTGAAAACTACTTTCAATCTTTAACCTTTGCCTTAAAATTAGTATAAATTTATCAGTTAAATTTTCTTTGGTGTTGTTAAACACTTGGGTTGACAATTTTGTCCCAAAAGTGGTAGGTATCTTAAAATAAGTAATTCACAACTATTATTACCTGTTCAGGTGTATGTGCAGATGTTCGTGTTAATTTTTAAAAGTCATCTCCGTTAGGTGTGCTTTATGAACCAAGTGTATGTGCATTGGGTTTTAAAGGAATCGTGTTTAATTTCGAAATTTTCTGATCTTAAAAGTGCTTTCATAGTTCTTAGATGAATAATAGGGCCTAGCACTTCGGAAAAGGCGAAGTCACTTATTAAAAAACAATTTCTTCATTTTTATGCACTTTCACTTATAGTAGTGGTTTCTTTTTAAGATGATTAAGAGTTCTGTTATGTCTTTTATTAGAAAATTTTAGAAAATGGTTTTGATCATTCGTTTGGGTTAATTTTAAAAATCCATGTTGGTCTAAACATATTCAAGAAATCTAAGGAGTTAATATTGGTAGGATCAAAGTCGTTGTTCTTACTAAGTAAATTGTTAAAAGTAAAATTGATAGGTTAATTTTTGGGAGGCTCGTTGATCTGTTTCTGGTTATAAGATGGTTTTAAGGGTATTCACATATAGTTTCTTGGAAGATTAAGGACTAGGATATGATTAATGAGAATTATCTAGCGATAAGGTGTTTCCATCTCTAGTCAATTTTGTTCTATGTATTGTTAAACTTTCGAGGCATGTCTTCGCCTTTGCTTGATTATTTTCCATTAAGAACCAGTGGTAGCCCCATTGTTTTAGTACCCTTATCTCTGCGTCTTTACAAATTAATTTGAGTAAAATCATCATCACTTTTTTGCGAGTCATAAAATCATATCTAAACCTCCGCTCCTCTGTCCCGATAAAACCCAAAGGTAAGCTGACGTCATCTCTTGATTTCTCTCCTTCTTTTATCTCCCGTCTTAACCTTCTTTTATTTCGTCGTATCTTCTTATATTCAAGATATTTTGTGTATGTTTCTGGTAATTCAATTTGAAGTTATTTCTACTGTTTCAACAAACAAGATTTTACAGCAGGAATACAGGTAGCAAAAGCTTGAGGGATTTTTCCACTCAAGCTTTTGACTTACATCTTTTTTTTTAAGATAGTCTTTTGTTTTATCTTGAGTTACGTTTTTACAGAATTCTTATAATCTATTGCATACATGATTAAATCTTAGTTGTTGCTTTAATTCCTAAAACATATTTAGCTTGTTTTTTAGCTTAGGATTATAAGCTGAGGTTTCAATACTTTTTCCTCAACATTCCCTGATGTTTTTAAAACCCCTGGTTATCTTAAAATCAAGCATATCATTAGTTTATATTATGTTTTCACTCATAATTTGTTGTTGTTATATTATATTATTTTGTTTTCTAATACAGAACTTGCTAATGAAAATATTGGCCTGGAACACACAAGGGTGTGGTAAAAAAAAACTAGGCAACAGCTAAACCACTTAGTAAATACTAAAAAAAACAGATGTTCTTTTTTTTATCTGAAACCCAATCTCAAAGGTGCTTAATGAAGCATGTGCTTAATTTTTCCCAAACACCCACATTGTTGACCCAGATGGAATCGCTGGGGGCTAGCAATTGCTTGGGTAGATGGTTTTCATTTTGAAGTGGTTCAATGGAACCTTAACATGATTAATATCATTGTTAAAAACAATTTTCATTCAAATGAATGGCTTCTAACTTGTTTTTATGGTTCTCCGAAGAATGAATTTAAACTAGAAATAATGGGTTACTTAGAGAATATTGCTAATCAAATTAATATGATTTCAGTGTCATGGTTAGTAATAGGAGACCTGAACATTATCTTCAACAGTGATGAAAAAGAAGGATGTCTTCCTTTCAATAGGAAAAAACTGGAACCAATCTTAAATTTAATCCAAAGAACTGGATTAGAGGATATAGGTTTCCGAGGTAATATTTTTACCTGGAATAACAAAAGAGAAGGGCATGCAAACATTAAGCAAAGGCTTGATAGGGGCTTAGCTAATGCAGAGTGGATTCTTGAATTCACAGATGCAACTGCAGAGTGGATTCTTGAATTCACAGATGCAACTCTTGAAAATTTGGTGGAAATAGGATCTGATCATAGTCATATCTGTCTTAATCTCATCTCTTGTAGTTTACATTTAGTTCCAACTTTTAAGTTCTATGACACCTGGCTAAAAGAACCTTCTTGTATAAAGGTTATAAGACAATCCTGGAAATGTTTTTCTGATTCTCCGGCTTTGAAATAATTTGGGAGAAAATTTGAAATTTTGGAAAAAAAAATATGTTTAGAAAGCCAAATAAAAAAATTAAGCATATAATCAAACGAATTGAGAATCTCTCGGCTAAAACATCTCAGGGGAGTATTAGTGAGCTAATAAACTAAAAAACTTTGGAATTAGAGGCTTTGTACGACACTCAAGAAGAAATAGCTAAACAACAATCTAGGAACAACACAATTTCCTAAGGAGAAAGAAACACAAAAATTTCATGTCACAACTTTAAAAAGAAGAAATAGGAACAATATAGATTGCATTCAGGATAGAGATGATAAAGTCGTTACTTCTAGACATGAAATTGAAGATGTTCTCACATCTTACTTTTCTGATCTTTTTTCTGAAAACTCTGTTAATACAGAGGATGAAATTTTTAAACATATTATGTAACACCCCAATTTTCGGGCCCGGATCCTGCTCTGATACCAAACTGTAACACCCCGAATCCTTCCCGGATCCCATGCCTGAAAATCGGGGTGTTACATATTAAGCCTTGCATCTCTTTGGAAGAAAATATAGCTCTAACTGCTATCCTAACTTCAGAAGAAATTTGCGATGTAGTGAAAAAGCTTAAGTCTAATAAAGCACCTGGGCCCAATGGCTTCACAGTGAGCTTCTTCAAACAAAACTGGGAAACTGTAGGAACACAATTGATAACAGTAGTACAAGATTTTTTTCAAAACTAAACAACTACATGTGGATCTAAATAAGACTTTCTTGTTTTTAATTCCAAAAATTAAAAATCCCAAATCCCTTTCAGATTTTAGGTCAATTGGACTTTGTAACACTCTTTACAAAGTCATAGCTAAATTAATGGCTAACAGGTTCAAAATATCTTTAGGAAAAATCATTTCCCCCTTCAATCTGCCTTCCTCTCTTCTAGACAAATCTCAGACAATATTATTGTTGCTCATGAGATTGTCCATTCAATGAAGAAAAGTAAAAAGAAAACAGGAAACATAGGAGCAAAAATTGACATGTCTAATGCATTTGATAGAGTTAATTGAAACTTCTTGATAAAAACTCTAGAGGCCTTTGGTTTCTCTAGCCATTAGAGTGAATTGATTTATCAATGTATCTCTACTTCTTCCATATTTATTTTACTAAATGGGAACCCCTGTAAGGAGTTTAAACCAACTAGGGGAATAAGACAGGGGGATCCTTTATCTCCATATTTATTCATCCTATGTATGGAGGTTCTTTCTAGACTCCTCTGTCATTTGGAATCTGTGAAACAGGTAATAGGTATCAAACTCATCCCAAAATCAACACTTATTTTTCATTTATTCTTTGCAGATGACCTTTTGCTTTTCACTAGAGCTGATTTAGGCAGCTGTAAAAATCTTCTGGAAGCTATTAATCTTTTTAGTAAAGCCTCTAGGCAAGTAATAAATTTTTCAAAATCTGGTCTGTTTTTTTAGTAAAAAAGTTCATAATAAACACCAAGGTATTATTTCTAGGTTAATGAAAATCAAAAAAATAAATATCAAAGACACCCATTTAGGAGTACCTTTATTCATAGATAGATCAAAACTTAAGTTCTTTGATAGCATTATAGAAAAAATGGAACAGAGAGTTAAGAACTGGCTAGCAAAAATCTTATCCCAACCAAGTTAGATTGTTCTAAATAAATCTGTTCTTTCTTGTATGCTAATTTTTAGCATGGGATGTTTTGTTTTGCCTAAAAAAAATACCAAAAGAATGAATGATATTCAGACAGATTTCTGGTGGGGAAAACATACTAATTCCAAAGGTATTTACATAAAATCTTTTGATTTCTTATGTAAACCAATTGACCAAGGGGGTTTAGGTTTTAAAGAGGATAACAAAGTGAATCAGGCTATGATTAGCAGGATATCCTGGAGATTGGTGAGTAATCCTGATAATTTATGGGATCAAATTTTAAAAAGAAAATACTTTAAAAAACAGGAGCTCTTCAATCCAAAAAGAAATCAACAACTTGTTAGATTTGGAAATGCATTTTACAAGGTATTGAGCATATCAAAAAGTATAGTGTTTGGGATGTAGGAAATGGATTCCCTATATATTTGATGATAAATGGTTACCAAACATGGAACAAACTCTAGCTAGTTTTGTCCCTAGAAACTCTAATATAACACTTGTGTCTGATTTGATAAATCATGACACAAAAAAGTGGAATGATTCTTTGTTACTTTCAACTTTTGATAGATCTTTGGTCAGTGAAATAATGAACATAAGATTATACACACAAAGTGATGAAAAACTGAAAAAAGATAAATTGAGATGGTTACTTGCTAGAAACGGTGAATTTTCTGTTAAATCTTTATATGCAAAGTTACTGAATCCATCTAACACCATCCCTGACTAAACAAAGAAGTTTTGGAAAGGATTGTGGAGCATTAATACTTCGCAGAGAATCAAAATGTTTATTTGGAAATGACTGCAAGATGCATTACCTACTAAACAAAAGTTAAAATCAGTGGACAACAAATGCATTTTCTGTAAGACTGAGGTGGAATATACTTTTCATCTGTTCTTTGACTGTGACTATGCTAAAGCTGTGTGGAATCTACAACCAATGGAAGTTCAGAGAGTACCTCACAACTTAGTTTCTCTTAATACTTCTTTCTTGCATAAATATAATGGATGGTTAGCAGGAGATTCGAATTCCATCTCAATGGCACTAGCTGCAACAAAGTGTTGGTTTATTTGGAAAGAAAGGTGTCTGAGGATATTTGAAGATAAATCTATAACACCAATTCAGTTATCACTAGATATATCAAGACACTGTGAGTACTGGCATCCAATGACTTTGAACAGTTTGAATTAAACACAAGACAGAACTATCAAACCAAAACCACAATGGACCTTCCCAATCACAAATACTTTCAAACTAAATTGTGATGCTTCTTGGTTGTCTGAAAAAAAATATAGGCTTTGGTTTTGTTCTTCATAATTGGACAGGAACCTTCAAGGGGGCAGAATCAGGCATCTTCAGGTCTTCCACTGCGGAAGAAGCAGAAGCTATAGTTCTCCTTCAAGCAGCTAAATGGGCTAAAATACATAACATACAACATCTGGTCGTAGAAGGAGATAACAGGGCAACAATTAAGTATTTACAGGGAAAGGAATCAACTATCCAATGGCAAAGCATTGTAATACTAGATGAAGTTAAGAAGCTAGTAGAACAAATGGTATCTTTTTTGGGTTTCCGGTACGTAGACAGGTGAGCAAACAAAGTGGCAGACCAGTTGGCAAAGAAAGGAAGAAAAGGTAACATTGCAATTTCTTGGTTAGACCAAGCTCCCTTTATTTTGATTCCAACAATTTCTTTTGACATGGTCAAAGCTTATGAATCTTGTAATATAAGTACAAACCTTGTATCAATTCAAAAGAAGGTTAATCTTACATATTCAGTCATCAACAAGACAACTCTATCTGAGTTCGCTCCTTATGAGACTGAATCAAATGCTTAGCCTTCTTTGTTTCCAGTAATATATTTCTATTTTCAAAAGAAAGGAAGTCGTTGCTCCTCAGTCTCCCTTCGGGCAGGAGCGGAAGCACAACCATGCTTCCCCTGGCTGGAGCCACCCACAAAGGCCCAAAACACATTTCTTTGTGTCTAATTCATGTTGGACCACAAAAACAGTAGGAACAGTATGGTCAAGCTCAGGGTGAAAATATGGTCAAGCCTGGCTGCCTGGGGTAAGGAAGGTTTCTGGTTCTGCCACTGCCTCCAGCTCTAGTTTAGGTTCATCGGCACATCAAGTTAGATTCATCGGCACATTAAGAAAGGTAACTTAGCTGGTGCCGCGTTGGAATTGGTGCGCCTTTTGTTTTTTGACGCCGCAAAGGAAAGTATTTAGGAATTCTGTTTCTAGAAAGAGGGTATATATGGAAATCGCACAATGAGATATTCAATGCATCTCGCATTATAAATAGAACAATAGAGTAAACCCCGTTACTTGCATAACACACGTAAAGATTATTTTAGGGTTTCATTAGGGTTTCAAAGCAGCAGCTCAAAACATGGCACCCAAACCTTCCAAGGCTGAGAAGAAGATCGCTTATGATAAGAAACTCTGCAAGTTTCTTGATGAATATGGTCAGATCTTAGTTGTTGCTGCAGACAATGTTGGATCGAACCAGTTACAAAACATCAGGAAAGGTTTGCGTGGCGATTCAGTTGTTTTGATGGGAAAAAACACTATGATGAAGAGAACTGTTCGTCTTCATGCTGAGAAAACTGGAAACAATGATTTCCTTAACCTCATTCCTCTTCTTGTGGGAAACGTTGGGTTGATCTTTACTAAAGGAGATTTGAAGGAAGTTAGTGAAGAAGTCAGCAAATATAAGGTTGGAGCCCCTGCTCGTGTTGGACTTGTTGCTCCTATCGATGTTATTGTACCACCAGGCAACACAGGATTGGATCCATCACAAACATCCTTTTTCCAGGTTCTCAACATTCCAACCAAGATTAACAAGGGAACCGTCGAAATTACAATCCCAGTTGAGCTTATCAAGAAAGGTGACAAAGTGGGTTCTTCCGAAGCTGCCTTGCTATCAAAGCTAGGCATAAGGCCGTTTTCTTATGGTCTCGCTGTACTCTCGGTGTATGACAATGGTTCAGTCTTTAACCCAGAGGTGCTTGACCTTACTGATGACGATCTAGTTGAGAAGTTTTATGCCGGTGTATCGATGGTTACTTCACTCTCATTGGCTCTCTCGTACCCTACCCTTGCTGCTGTACCTCACATGTTTGTCAATGGATACAAGAATGTTCTTTCTGTCGCTGTTGCCAGTGAATACTCCTTCTCTTATGCTGATAAAGTGAAAGAATACTTGAAGGATCCAAGCAAGTTTGCAGTTGCAGCTGCTCCAGTTGCTGCGGCTGCTGCTTCTGGTGGTGCACCAGCTGCTGCTTCAAAGGCAGAAGAGAAGAAGCCAGAGCCTGAAGAAGAGTCTGATGAGGATATTGGGGGGCTGTTTGGTGACGACGATTGAGAAACTGTTCCCTGATGATTTTTCCTGCTTGCATTTGCATCTTATTATCTTTAAACTCATCTTTAGTGTTTATACAGTTTGTTAGAACTATCACCCATAATCAGTGTTTTGTTGATATATTGCCATTTTATTGGGTGCGGTTGTTTTTCACTCGTATGGTAGGAGAAATAAAATCATTTTGGAACTCAGAAATCTGTGTGTGTGTTTTGTTCTACCTTTTCTTGTGTTCAATGTGAGTATTATTCGAAGGGAGTACAAGTTTTTACA
->XM_034856521.1 PREDICTED: Etheostoma cragini testis associated actin remodelling kinase 1 (tesk1), transcript variant X2, mRNA 
-TAATAGGCCGCAGCGTCACTGAGGCAGCTCTGTGCGCACTGGAAACCCGGAATTCAATTGGTGGAACCAGGAGGGAAGCCCCGGCCTTTTCTACTGCAGAAGGAGCAGTTTGAAAGAAACCGTGAGAGAGACGCCGCTGCCAAGACAGCAGCAGGAGCAGTCTGCGCAGTTTAGAAAACGGCACAGCCTAATCTGCTGCACGGCATGATGGACTTTACCAAAACTGCGTACTGACTCTGCAAGATGCAACGCTGCAGCTTCGTAGTTCGTTAGACACAGATAGAAACAAGCCCGTTCCGGACGTGTGCAGGAATTTGACAGAGGAATTAGGCCTAACCGGTCGCTGACCACAGCTGCGACATTTGGTTTTCCCACTGAGAGTTTATCACTCCTCCCCTCCGTAGAGCCCTGCTCTGTGGCCTTGTAGCGGACATGGGAAATGTAAACAGTGGTCGGGCTGGATTTTAAACTACGCACACGTCATACGTCCTCCTCTCGCCTCCACCTCCTTCTCCTCCCGGGGCGCCTGAGATGGAGATGGAGACGGAGAGGGTCGAGCAGGGAGAGGCAGAGCTGCCCATGCACAGCGTCCACGGAACCAACCGGATCAGACCGTCCTCTTACCGGGCACTGCGCAGCGCCGTGTCCAGCCTGGCCCGTCTAGATGACTTCAACTGCGAGAAGATCGGCGCTGGGTTCTTCTCTGAGGTGTTCAAGGTGCAGCATCGAGTGTCGGGCCAGGTAATGGCTCTGAAGATGAACATCCTGGCCAGCAACAGAGCCAACATGCTCAGGGAGGTCCAGCTCATGAACCGACTGGCGCACCCCAACATACTCAGGTTCATAGGAGTGTGTGTCCACGAGGGACAGCTCCACGCCCTCACAGAGTACATTAACGGTGGCAACTTGGAGCAGCTGTTGGGGAGTGACGTGTACCTGTCGTGGAGTGTGCGGATGATCCTGGCCCTGGACATCGCCCGGGGACTGCAGTACCTGCACAGCAAGGGCATCTTCCACAGGGACCTCACCTCCAAGAACTGCCTGGTGCGCTGGGAGGGCTGTGTGTGCTCAGCCGTGGTTGGAGACTTTGGCCTGGCGGAGAAAATACCAGATTACAGTGAGGAGGAACAGGAGCCTCTGGCGGTCGTCGGCTCTCCCTACTGGATGGCCCCGGAGGTGCTCAGAGGAGAGGTGTATAATGAGAAGGTGGATGTGTTTGCATACGGGATTATCTTGTGTGAGATCATTGCGAGGATACAGGCCGACCCCGACATCCTACCACGCACTGAGGACTTTGGTTTGGATGTGGACACCTTTCAACAGATGGTGGGAGATTGTCCTCCTGACTTCCTGGAACTGGCCATTGCCTGCTGTAATATGAATTCAAAGCTCCGTCCATCCTTCTCCCAAATTGTGGTAGAGCTGGAGAGGAGACAGGCTGAAAGGAAACAGAAGGATGAACCATCAGTCAAAGCCGTTTCTCCAGTCATTGGTCCTCTACGAAGACGATCCCTCTGCCTCCTGTCAGATCCTCGACTCTCCCGTAGCAAATCCGACATGCTCCACCCCCCAAACATGTCCCCCTCTGTTACTACGGCAATTCCTGCTCGGGTCAACCCCTTCTCTCAGAGGGAGGACCTTAAGGGAGGCAAGATCAAGCTGTTCGACACTCCCAGCAAGTCTGTCATCTCCCTTACCTTCACCCTGCCTCCTCCACCTGACTGCGATGACCCCTCTGTCTCCGAGTCTGACAGCAGTGAGGTACCAAGGAGACACAGGCGCTGCCACTCGCTGCCTTGTACGCCTCCTCCGCACCTCACATCAGCGCCGAACACAATCCTTACAGAGCAGGAGTCCATGTCCAAGATGGACACTGTAAATGGAGAGACAAACCGAGTGAGTGAAGAGGAGAGATTGTTAGAAGAGATGGCAACTATGGAAGGGAATGGAACTGATTCAGGCCTTCCTCTTTCCATTGAGCCCCTGTCGCTGGACCAAGAGAGGGAGGAGGAGGAGGACAACGAGGAAGAGGAGCCCATGGACTGTACCAGCTCCCCAGACACACAAGACAGCACATCATCTCCTTATTCCAAACTCTCCTTTCCTCCGTCCGACTCCTCAACTCCCATCCAACCCTCCACTCCTCCCTTCTCAAATGGCTGGGGGTCAGCAATCTCCAACGGGCCTCCTTGCCTACCTCCCCTCTCTCATTTGGACAACAACAACGTGGTCATCGGTCGACCCTTGGGATGGAGCGCCGCCACCACCACCACCAGTGCTCCCACAGCAAGAACCACCAACAACAACGGCTACCACTTCCCTTCCAGCGACCCCGCTGGATCGTCCCCATTTGGCTCTGGCAGCGGACATTCTCTGGACCAGGAAGAAGTCATCTCCTGTCCCGGCTGCTGCATTGCCGGCCTTCGCTTTCCTTCGATGTGTCCCCGAGCTCCACCGCGCAGAAACCCCTACAAGAACTTGAACGGGGACCATGCAGCTTCACGTGGGCTGCTTGGTCCGGGACCCAAGGGTCTGCCGCCCTCCCCTACCACCACCACCAACCTGGAGCCAGGACTTGCCTTGCCGGAGGCACAGACATGAACCCCAGCAAACTGAAAAGATTTGTGTAAACTCTGCACCAAAAGCTCATCCCTGGAAATTAAGTGGGTCTTGGAAGAATTTGCACAGATTTTAACTCAGCAATACCCTGATTTTTTTTTTTTTTTTTTTTTCAGACAATCTTTTTGGTGCAAATCAGTTTACTAAAACACACTCCAGGTTGACTTTTTCCGTGAAAGCTGTAGGACAAGGTGCTGGTGACTTGTTGCACGTCGCCCTCTGCTGGGCTGAGGGCGACATGCTACGTCAAGAACTGTTAAGCATGGAAACACTCCAGTTTGGGGTCCATTTGGTTTGATCCTCTAAATGTGCATATGTAAAGATTCTTATGACTGATAATATTGATGATGATGCTCAAATGAGGAATGTTAAGCTTAGTTAAGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTTCTGTTTTTTGTTGCTGTGTGATCTCTAATGGCCCTTCTGGTCGCCTGGTTAAGCACTTCAACTGTATTACTGAAACTATTGATGTTATTATTTTTGGGAATGAATGGTCAAAGACCTGTATAAGAGATGTACAGATTCATATTATTTAAAGGATGCATTGAATAAAAAAGATAGAAT
->XR_001760135.2 PREDICTED: Cynoglossus semilaevis uncharacterized LOC107988670 (LOC107988670), transcript variant X2, ncRNA 
-AAAACTCCCCCGCTCTTTGGGGGCATGTCCAAAAGGTGCAGCCCACTTCTCCTGTGTGACTGGGGGGTGTTTCAAGAATCTGTTAAATGCAGAGAATGTTTGGAATTTCTCTTACAGAAAAGTAGAGAATTGAAAAATACATTTAAATAGAGACCTGGACTTCTGGCAGGACAGTCAGGCAGATGAACTCCAACATGATTTTGTCATTTGTACAGAATTATGCTGTAAATGATCCGGGTAAAAATCCTAGATCTGGAGTTCTAGAATGAATGTTTTTAAGCCATCGATTGTACATTGTTAACATGATGCAGCCCTACCTCGACACAGATGATTGATCACTCAGTTGATCAACTGTTTTTTGGGCAAAACGGACTGTTATCAACGTCACATTTGTGTGCACTAACGACTGTATTTGTTTTTTGCAGCACTGATGTACGGCTTCCTCGTTGGGTAACGCACACTCTCAGGGAGGCGTTCTCCAGGTAGGCAGACTGCGTTTAAGCAACAATGATTTTCTAAAGTATTCCACACCCTGTGCCTATGAGCTTGAAGGTTATACTCATTCAGCAGCAATGTTTTTCCCTTTTACTACAACAACATAGATTTCCCCAGACTCCCTGGATCGTTTCACAACAATATTAACTCTTGTTGGTGACAGACCTGATTTTTCTCCAACCTTTTTCTAACAAACACTTTTTTTATCTCTAAATAAATTTCTGAAGTCGAACATAAAGTTCCAAAACATTTTTACTTAAGGCCGAGTCTTGAGCAACTAGTCAAACTAATAAGGTGATTACTGAATGTTATTATTATGACATTTTTAATCCCTTAAAACAACTTTTGGGAGTTTGTTGCAGTCTTTTGGTTCTTCATTTGTTTATGTTAAATAGACAGAATTATGATGGTCAGTGGTCAGTTTTTTTGATTTGAGGGTTTCGTGCACTTTAAGAAGTGTACCAACTTTCTGGAAATAGGATTTGTATTGTATTCAACAGTCACACAAACAACCAAATGACTGTCCTCTTCATTTGCACTGTTGGCTGTTGTAGGTTTGGGCTCATGCCACATGAAGAGCTGTTACATCCATGAGCGGTAGAAAAGGGCGAAGTTTCCTCCCAGATCCAATCCAACAAGTGGCCAGGCCTAAATGTCAACCCGGGGGTCCTCAACCTGCGGCTCCACTACCACATAAGATAGAGATCGGCTCCTCTCGTACCTTGCTCTCTGGGACGCCAGCTCCGACAACCAGCACCAGACCACAGCCACTATTACAATCATTCCTATGAAGGGGATGGAGAGAACAGGGTGCTCAGATGGATGGATGAATCTCTGAGGAGGGAAAAAGAACAAACACACGGGACGTGGAGATGAAGGGAACAGATGAACTGATGGATTAAAACTGGAGACTTCACGGACAGTCGGAGAACACGGACATGAGCAGAGGCACGGGCAGACAGTTTGACAAAACGCTGAGAGACATTCACAACAGGGCTGTTGTAGACGAAACACATTCCAGGGCATCACTGTCACACAGAGGCTTGGACACAGACACAGTCAGGCAAGGATTCACCACTTCAGGCCACACAATAATTTCTGATATGTGCTGACAGGTCCTGTCAGTTCATATCAAACACACACACATATATATATATACTGTATATATATTCTCCTCACAATGAGAGACATATAAAGAGGTGCTCGACACACAGGAGATACAGCAGGTGTGATGTCGGGTGTTGTTATGTGTTAGTTGAGGACATGAGCAGAAACAAAGCTGGAAATAGCCAAAAGTTTAGCAAATTTCTTTTTCAGTCCTAATGATTGTAGCTACTTAAAACCTCAGTGGTGTATCTTTTAGATAACTTTTTTTTTTT
->FJ579386.1 Uncultured Methanobacteriaceae archaeon clone KR-H08-A02 16S ribosomal RNA gene, partial sequence 
-GCTCAGTAACACGTGGATAACCTACCCTTAGGACCGGGATAACCCTGGGAAACTGGGGCTAATACTGGATAGATGATTTTTCCTGGAATGGTTTTTTGTTTAAATGTTTTTTCGCCTAAGGATGGGTCTGCGGCAGATTAGGTAGTTGGTTAGGTAATGGCTTACCAAGCCTATGATCTGTACGGGTTGTGAGAGCAAGAGCCCGGAGATGGAACCTGAGACAAGGTTCCAGGCCCTACGGGGCGCAGCAGGCGCGAAACCTCCGCAATGTGAGAAATCGCGACGGGGGGATCCCAAGTGCCATTCTTAACGGGATGGCTTTTCTTAAGTGTAAAAAGCTTTTGGAATAAGAGCTGGGCAAGACCGGTGCCAGCCGCCGCGGTAACACCGGCAGCTCTAGTGGTAGCTGTTTTTATTGGGCCTAAAGCGTTCGTAGCCGGTTTGATAAGTCACTGGTGAAATCCTGTAGCTTAACTGTGGGAATTGCTGGTGATACTGTTGAACTTGAGGTCGGGAGAGGTTAGCGGTACTCCCAGGGTAGAGGTGAAATTCTGTAATCCTGGGAGGACCACCTGTGGCGAAGGCGGCTAACTGGAACGAACCTGACGGTGAGGGACGAAAGCTAGGGGCGCGAACCGGATTAGATACTCGGGTAGTCCTAGCCGTAAACGATGCGGACTTGGTGTTGGGATGGCTTTGAGCCGCTCCGGTGCCGAAGGGAAGCTGTTAAGTCCGCCGCCTGGGAAGTACGGTCGCAAGACTGAAACTTAAAGGAATTGGCGGGGGAGCAC
->XM_007564720.2 PREDICTED: Poecilia formosa hexokinase-2-like (LOC103146708), transcript variant X3, mRNA 
-AGAAGATGATAAGCGGGCTGTACATGGGGGAGCTGGTGCGTCTCATCTTGGTGAAGATGGCCAGAAAGCAGCTGCTGTTCCAGGGACAGACCACGCCACAGCTTCTTACCTCTGGATGCTTCAGCACCAACTACATCTACGCCATTGAGAGCGACAAAGATGAAGAAGGCCTGGCTAGCGCCGAGAAGGCGCTCCGCAGCCTGGGCCTGGACCCGTCTGCTGAAGACTGCGCCGCCACTAGGAGGATTTGCCAGATCGTTTCAACCCGGGCTGCACATCTGTGCGCCTCTACCCTGGCGGCGGTGATGCGACAGATCCGGGACAACAAAGCGGCCGAAAAGCTGCGCATCACCATCGGAGTGGACGGCTCAGTCTACAAGGGTCATCCAGAATTTTCCAGGAAGCTCAACAAAATGGTGCGGCGCCTCGTGCCAGACTGCGACGTGCGCTTCCTGCAGTCGCAGCACGGCAGCGGGAAAGGCGCGGCCATGGTGACGGCGGTGGCCTACCGACTCGCCACCCAGCACGCCGAGCGGCAGCGCGTCCTCGACACCCTGCGGCTGAGCCGCGAGCAGCTGCTGGAGGTGAAGCGGAGGCTGACGGAGGAGATGGCACGGGGTCTGTCCAAGCAGACGCACGACCAGACCAGCGTCAAGATGCTGCCGACGTACGTCAGGTCCACCCCGGACGGAACAGAACAAGGAGATTTCTTGGCTTTGGATCTTGGTGGGTCCAGTTTCCGTGTTCTTCTCGTTCGGCTGAAAAATGAGAAGAAGCAGAAAGTGGATATGCACCAGAAGATCTACAGTATCGATCAGGACACGCTGCAGGGCACGGGGGAGGAGCTCTTCAACTACATTGTGTACTGCATTGCTGACTTCCTGGACTACAGGGGGATGAGTGGAGCGTCCTTACCTCTGGGGTTCACGTTCTCTTTCCCATGTGATCAAACCAAACTGGAAGAGGGAATCCTTCTGAAGTGGACGAAGGGCTTCAAAGCCAGCGGCTGTGAGGGGAAAGACGTCGTGAAGCTGCTGAAGGAGGCGGTCCAGCGCAAGCAGGACTTCGACACTGACATCATGGCAGTGATCAGCGACACGGTGGGGACCATGATGACCTGCGGCTTTGACGACCGTCACTGTGAAATTGGCCTTATAGTGGGAACGGGCACTAATGCGTGTTACATGGAGCAGATGAGGAACCTCCAGCTGATGGACGGCGATGAGGGGCAGATGTGTGTGAACACAGAGTGGGGAGCGTTTGGAGACGACGGCGCCCTGGAAGACCTGCGCACCGACATCGACCGGGAAATCGACGCTGGCTCGCTGAACCCTGGCAAGCAGCTGTTTGAGAAGATGATAAGCGGGCTGTACATGGGGGAGCTGGTGCGTCTCATCTTGGTGAAGATGGCCAGAAAGCAGCTGCTGTTCCAGGGACAGACCACGCCACAGCTTCTTACCTCTGGATGCTTCAGCACCAACTACATCTACGCCATTGAGAGCGACAAAGATGAAGAAGGCCTGGCTAGCGCCGAGAAGGCGCTCCGCAGCCTGGGCCTGGACCCGTCTGCTGAAGACTGCGCCGCCACTAGGAGGATTTGCCAGATCGTTTCAACCCGGGCTGCACACCTGTGCGCCTCTACCCTGGCGGCGGTGATGCGACAGATCCGGGACAACAAAGCGGCCGAAAAGCTGCGCATCACCATCGGAGTGGACGGCTCAGTCTACAAGGGTCATCCAGAATTTTCCAGGAAGCTCAACAAAATGGTGCGGCGCCTCGTGCCAGACTGCGACGTGCGCTTCCTGCAGTCGCAGCACGGCAGCGGGAAAGGCGCGGCCATGGTGACGGCGGTGGCCTACCGACTCGCCACCCAGCACGCCGAGCGGCAGCGCGTCCTCGACACCCTGCGGCTGAGCCGCGAGCAGCTGCTGGAGGTGAAGCGGAGGCTGACGGAGGAGATGGCACGGGGTCTGTCCAAGCAGACGCACGACCAGACCAGCGTCAAGATGCTGCCGACGTACGTCAGGTCCACCCCGGACGGAACAGAACAAGGAGATTTCTTGGCTTTGGATCTTGGCGGGTCCAGTTTCCGTGTTCTTCTCGTTCGGCTGAAAAATGAGAAGAAGCAGAAAGTGGATATGCACCAGAAGATCTACAGTATCGATCAGGACACGCTGCAGGGCACGGGGGAGGAGCTCTTCAACCACATTGTGTACTGCATTGCTGACTTCCTGGACTACAGGGGGATGAGTGGAGCGTCCTTACCTCTGGGGTTCACGTTCTCTTTCCCATGTGATCAAACCAAGCTGAATGAGGGAATCCTTCTGAAGTGGACGAAGGGCTTCAAAGCCAGCGGCTGTGAGGGGAAAGACGTCGTGAAGCTGCTGAAGGAGGCGGTCCAGCGCAAGCAGAAATTCGACCTAAGCTTTGTGGCGGTGGTGAACGACACAGTGGGCACCATGATGACCTGTGCCTATCAGGACCCCAAATGTGAGCTGGGCCTTATTGTAGGCACAGGGACCAACGCCTGCTACATGGAGGAAATGCACAACATCGAAACGGTGGAGGGAAATGAAGGCCGCATGTGTGTCAACGTGGAGTGGGGAGCATTCGGCGAAAACGGTGAACTGGACGACTTTTGCACAGAGTTTGATTATGCTGTCGACGAAGCCTCCAACTACCCTGGGAAGCAGAGATATGAGAAGATGATCAGTGGGATGTACCTGGGAGAGATAGTGAGGCATGTGCTGATGGATTTCACCACCAAGGGTCTGCTGTTCAGGGGCAAACTGTCGGAGCGCCTGAAGACCAGGGGCATCTTTGAGACCAAGTTCCTGTCACAGATTGAAAGCGACCGGCTGGCCATGCGTCAGGTCCGCTCCATCCTGCAGCACCTGGGCCTCACCGGCTCCACGTGTGACGACAGCGTCCTGGTGAAGGAGGTGTGCAGCGTCGTGGGTCGCCGCGCGGCGCAGCTCTGTGGCGCCGGTTTGGCCGCTCTCGTTGACAAGATCCGGCAGAACCGCAACCTGAACCAAATGTCCATCACTGTGGGAGTGGACGGTACCCTTTATAAGACCCATCCTCATTTCTCGAGGATCATGCAGGAGACCCTGCAGGACCTGGCCCCGCAGTGCGAGGTGACGTTCCTCAAGTCGGAGGACGGCAGCGGGAAAGGAGCGGCGCTCATCACGGCCGTGGCCTGCAGGTTGAAGAGCGAGCAGTCGCTGTGAAACCTGCGAAAACTTCTCCCTGTGGGTCAACACGCGCACTGTGTTCAGTCGGTTGTCATTCTTTTTTCGACGTGAGCGCGTTCACACGAGAGTGTCCGCTTAACGGCGCGAGGCGAAGCTGTGACGGAGGTTCGGTCGGGCGCGAACTGAGCTCAGAAATCACAGTTCTGCTGGTAATGAACCTGCACCTTCAGTGAGACCCGACTGTTACGAGCTCGTTGCTTTTCGTTTTTACACTCTGTCGTTGTCTTTTACTTTTATATTAGTTCTGTTTTTAAGTCAAGTCTGTGAAAAATAAAACTTTTTAGCACATTTACTGTCTGGCAAGTTTAGAAAAGCACATTCCTGAACCAAAGAGAAGCAAACCAGTACATTCAGCAGGTAAATGAAGCAATAGTTTCTTTCCTTTTTTTACATTTTATTTAAGTTTTAAAGCAATTTTACTTTGTTACAGGAAACTTCAGAAAAAATGCAATATTGTGATGAAATGTTTTTAAAATGTAAACACTAGTCCATGCATCAGAAACATAAAGATGTTTTAGAAATTGCAGAGGCTCCGTATAACTGGAGGTATAAATAATTCAAACTGTGTAGTTCTGATTGCAGCAAGCTTATTATGATGTGCTGTGAAAAATATCAACTCCAAATAAAGTGAGAAATCACCAGGGTCTATTTTTTTTATTATTATTTATCAATAAAACCAAGATTACTCCAACTTGGACTCATTTTATTACTGGGGTGTTGAGAATAAAGAGGACAATCTGCACCTCCATAATTGGACCAATCAGTTTAATTTGTAGTTTTTCTCACAAAGCATATTTTCATTGGCTTTTTTTTTTTTTTTTTACAAAATCATTACCTTACAATGGAAAACTACCCTGAATACACATAATCAGACAGCTCTGAAAATACTGTAACATGTGATCTTCATTTTCACTGTTTTTCATCCAACCAAACCCAATAAATCTTACTTGGCTATGTTGTT
->EU380792.1 Rickettsia sp. GDM18 16S ribosomal RNA gene, partial sequence 
-GCTTAACACATGCAAGTCGAACGGACTAATTGGGGCTTGCTCCAATTAGTTAGTGGCAGACGGGTGAGTAACACGTGGGAATCTACCCATCAGTACGGAATAACTTTTAGAAATAAAAGCTAATACCGTATATTCTCTGCGGAGGAAAGATTTATTGCTGATGGATGAGCCCGCGTCAGATTAGGTAGTTGGTGAGGTAATGGCTCACCAAGCCGACGATCTGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCAATACCGAGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTTAGCAAGGAAGATAATGACGTTACTTGCAGAAAAAGCCCCGGCTAACTCCGTGCCAGCAGCCGCGGTAAGACGGAGGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGAGTGCGTAGGCGGTTTAGTAAGTTGGAAGTGAAAGCCCGGGGCTTAACCTCGGAATTGCTTTCAAAACTACTAATCTAGAGTGTAGTAGGGGATGATGGAATTCCTAGTGTAGAGGTGAAATTCTTAGATATTAGGAGGAACACCGGTGGCGAAGGCGATCATCTGGGCTACAACTGACGCTGATGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAGATATCGGAAGATTCTCTTTCGGTTTCGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGGTCGCAAGATTAAAACTCAAAGGAATTGACGGGGGCTCGCACAAGCGGTGGAGCATGCGGTTTAATTCGATGTTACGCGAAAAACCTTACCAACCCTTGACATG
->XM_045299987.1 PREDICTED: Echinops telfairi calcium voltage-gated channel subunit alpha1 G (CACNA1G), transcript variant X9, mRNA 
-TCGAGCGCATCAGCATGCTGGTCATCCTGCTCAACTGTGTGACCCTGGGCATGTTCCGGCCGTGTGAGGACATCGCCTGTGACTCGCAGCGCTGCCAGATCCTGCAGGCCTTTGATGACTTCATCTTCGCCTTCTTCGCTGTGGAGATGGTGGTGAAGATGGTGGCCTTGGGCATCTTTGGGAAAAAGTGTTACCTGGGGGACACTTGGAACCGGCTTGACTTTTTCATTGTCATCGCAGGGATGCTGGAGTACTCACTGGACCTGCAGAACGTCAGCTTCTCCGCTGTCAGGACCGTCCGTGTGCTGCGGCCACTCAGGGCCATTAACCGGGTGCCTAGCATGCGCATTCTGGTCACGCTGCTGCTGGACACGCTGCCCATGCTGGGCAACGTCCTGCTGCTCTGCTTCTTCGTCTTCTTCATCTTCGGCATCGTGGGTGTCCAGCTCTGGGCCGGCCTGCTACGCAACCGGTGCTTCCTGCCCGAGAATTTCAGCCTCCCCCTGAGCGTGGACCTGGAGCGCTATTACCAGACTGAGAATGAAGATGAGAGCCCCTTCATCTGCTCCCAGCCTCGCGAGAACGGCATGCGGTCCTGCCGGAGCGTGCCCACGCTGCGTGGGGAGGGGGGCGGCGGCCCACCATGCGGCCTGGACTACGAGGCCTACAACAGCTCCAGCAATACCACTTGTGTCAACTGGAACCAGTATTACACCAACTGCTCCGCCGGGGAGCACAACCCCTTCAAGGGGGCCATCAACTTCGACAACATCGGCTACGCCTGGATCGCCATCTTCCAGGTCATCACGCTGGAGGGCTGGGTGGACATCATGTACTTTGTGATGGATGCTCACTCCTTCTACAACTTCATCTACTTCATCCTCCTCATCATCGTGGGCTCCTTCTTCATGATCAACCTGTGCCTGGTGGTGATCGCCACGCAGTTCTCAGAGACCAAGCAGCGGGAGAGCCAGCTGATGCGTGAGCAGCGGGTGCGCTTCCTGTCCAATGCCAGCACCCTGGCCAGCTTCTCGGAGCCCGGCAGCTGCTACGAGGAGCTGCTCAAGTACCTGGTGTACATCCTGCGCAAAGGTGCCCGCAGGCTGGCCCAGGTCTCCCGGGCGGCAGGCGTGCGGGCCGGGCTTCTGAGCAGCCCAGTGGCCCACGGGGGTCAGGAAACGCAGGCCAGTGGCAGCTGTTCTCGCTCCCACCGCCGTCCATCAGTCCACCACCTAGTGCACCACCACCACCACCATCACCATCACTACCACCTGGGCAACGGGACGCTGAGGGGCCCCCGGTCCAACCCGGAGATCCAGGACAGGGAAGCCAGCGGGTCCCACCGCCTCATGCTGCCACCGCCCTCCACACCCACCCTGTCTGCGGGCCCTCCGGGGGGCACAGAGTCTGTGCACAGCTTCTACCACGCCGACTGTCACCTGGAGCCGGTGCACTGCCAGGCACCCCCTCCCAGGTCACCATCGGAGGCGTCAGCCAGGACGAGGGGCAGTGGGAAGGTGTACCCCACCGTGCACACCAGCTCGCCGCCAGAGGTGCCAAAGGAGAAGGCGCTGGTCGAGGTGGCTCCCCATGCTGGGCCGGCCACCCTCACCAGCCTCAACATCCCCCCAGGGCCCTACAGCTCCATGCACAAGCTGCTGGAGACGCAGAGCACAGGTGCCTGCCAAAGCTCCTGCAAGATCTCCAGCCCGTGTCTGAAGGCAGACAGCGGGGCCTGTGGCCCAGACAGCTGCCCCTACTGTGCCCGGGCAGGGGAGGTGGAGCTTGCCGACCGAGAGGTGCCGGACTCTGACAGTGAGGCGGTTTATGAGTTCACGCAGGATGCTCAGCATGGTGACCCCCGGGACCCTCGACGCAGCCTGGGGCTGGCTGTAGGGCCCAGCTCTGTGCTGGCCTTCTGGAGACTGATCTGCGACACCTTCCGGAAGATCGTGGACAGCAAGTACTTTGGCAGGGGCATCATGATTGCTATCCTGGTCAACACGCTCAGCATGGGCATTGAGTACCACGAGCAGCCTGAGGAGCTCACCAATGCCCTGGAGATCAGCAACATCGTCTTTACCAGCCTCTTTGCCCTGGAGATGCTGCTGAAGCTGCTGGTGTACGGGCCCTTTGGCTACATCAAGAATCCCTACAACATCTTTGACGGGGTCATTGTTGTCATCAGCGTGTGGGAGATCGTGGGCCAGCAGGGGGGTGGCCTGTCGGTGCTGCGGACCTTCCGCCTTATGCGGGTGCTGAAGCTGGTGCGCTTCCTGCCGGCGCTGCAGCGGCAGCTCGTGGTGCTCATGAAGACCATGGACAACGTGGCCACCTTCTGCATGCTGCTCATGCTCTTCATCTTCATCTTCAGCATCCTGGGCATGCACCTGTTCGGCTGCAAATTTGCTTCTGAGCGGGACGGGGACACGCTGCCAGACCGGAAGAATTTTGACTCCCTGCTCTGGGCCATCGTCACAGTCTTCCAGATCCTGACCCAGGAGGACTGGAACAAGGTCCTCTACAATGGGATGGCCTCCACATCCTCCTGGGCCGCCCTTTACTTCATCGCCCTCATGACCTTTGGCAACTACGTGCTCTTCAACCTGCTGGTGGCCATCCTGGTGGAGGGCTTCCAGGCGGAGGAAATCAGCAAACGGGAAGATGCGAGTGGACAGTTGAGCTGTATTCAGCTGCCTGTCGACTCCCAGGGGGGAGATGCCACCAAGTCCGAGTCCGAGCCTGATTTCTTCTCGCCCAGCCTGGACGGCGATGGGGACAGGAAGAAACGCTGGGCCTTGGTGTCCCTAGGAGAGCACCCGGAGCTGCAGAGGAGCCTACTCCCTCCTCTGATCATCCACACGGCCGCCACCCCCATGTCACTGCCCAAGAGCTCCAGCACGGGCCTGGGGGAGCAACTGGGCCCCGCCTCCCGCCGCACCAGCAGCTGCTGGTCTGCAGAGCCTGGGGCAGCCCATGAGATGAAGTCACCGCCGAGCGCCCGCAGCTCCCCACACAGCCCCTGGAGTGCCGCCAGCAGCTGGGCCAGCAGGCGTTCCAGTCGAAACAGCCTGGGCCGTGCCCCCAGCCTGAAACGCAGGAGCCCTAGTGGGGAGCGGCGGTCCCTGTTGTCTGGCAAGGGCCGGGAGAGCCAGGATGAGGACAGCTCGGAAGAGGAGCGGGCCAGCCGGGTGGGCAGTGCCCGGCACCCTGGGGGCTCCCTGGAGCAGGAAGCCAAGGGATCTTTCGACCTGCCGGATACCCTGCAGGTGCCCGGGCTGCACCGCACGGCCAGCGGCCGCAGCTCGGCCTCGGAGCACCAGGACTGCAATGGCAGGTCGACCCCAGGGCGCCTGGCCCGGGCCTCACACCCAGACGAGCCTCCACTAGATGGGGATGACGCTGATGACGAGGGCAACCTGAGCAAAGGGGAACGGATGCGGGCGTGGATCCGAGCCCGGCTCCCTTCCTGCTGCCGTGAGCGGGACGCCTGGTCAGCCTACATCTTCCCTCCACAGTCAAAATTCCGTCTCCTGTGCCACCGGATCATCACCCACAAGATGTTTGACCATGTCGTCCTCGTCATCATCTTCCTCAACTGCATCACCATCGCCATGGAGCGCCCCAAAATCGACCCCCACAGTGCCGAACGCATCTTCCTGACTCTCTCTAATTACATCTTCACCGCCGTCTTCCTGGCCGAGATGACAGTGAAGGTGGTGGCGCTGGGCTGGTGCTTCGGGGAGCAGGCGTACCTGCGCAGCAGCTGGAACGTGCTGGACGGGCTGCTGGTGCTCATCTCCGTCATCGACATCCTGGTGTCCATGGTCTCCAACAGTGGCACCAAGATCCTGGGCATGCTGCGGGTGCTGCGTCTGCTGCGCACCCTGCGCCCACTCAGGGTTATCAGCCGGGCGCAGGGGCTGAAACTGGTGGTGGAGACGCTGATGTCCTCCCTGAAGCCCATCGGCAACATCGTGGTCATCTGCTGTGCCTTCTTCATCATTTTTGGCATCCTAGGGGTGCAGCTCTTCAAAGGGAAGTTCTTCGTGTGCCAGGGCGAGGACACCAGGAACATCACCAACAAGTCCGACTGTGCCGAGGCCAGTTACCGGTGGGTCCGGCACAAGTACAACTTCGACAACCTCGGCCAGGCCCTGATGTCGCTGTTCGTGCTGGCTTCCAAGGACGGCTGGGTGGACATCATGTATGATGGGCTGGATGCTGTGGGCGTGGACCAGCAGCCCATCATGAACCACAACCCCTGGATGCTGCTCTACTTCATTTCCTTCCTGCTCATCGTGGCCTTCTTTGTGCTGAACATGTTCGTGGGTGTGGTGGTGGAGAACTTCCACAAGTGCCGGCAGCACCAGGAGGTGGAGGAGGCGCGGCGGCGGGAGGAGAAGCGGCTGCGGAGACTGGAGAAGAGGAGAAGGAATCTAATGCTGGACGGGGTAATTGCTTCCGGCCGCTCAGCCAGCGCGGCACCAGAAGCCCAGTGCAAGCCCTACTACTCGGACTACTCCCGCTTCCGGCTGCTCGTCCACCACCTGTGCACCACCCACTACCTGGACCTCTTCATCACAGGCGTCATTGGCCTGAATGTGGTCACCATGGCTATGGAGCACTACCAGCAGCCCCAGGTCCTGGACGAGGCTCTGAAGATCTGCAATTACATCTTCACCGTCGTCTTTGTCTTGGAGTCGGTGTTCAAGCTCGTGGCCTTTGGCTTCCGCCGCTTCTTCCAAGACAGGTGGAACCAGCTGGACCTGGCTATCGTGCTGCTGTCCATCATGGGCATCACGCTGGAGGAGATCGAGGTCAATGCCTCGCTGCCCATCAACCCCACCATCATCCGCATCATGAGGGTCCTGCGTATCGCCCGAGTGCTGAAGCTGCTGAAGATGGCTGTGGGCATGCGGGCGCTGCTGGACACGGTGATGCAGGCCCTGCCCCAGGTGGGGAACCTGGGACTTCTCTTCATGTTGTTGTTTTTCATCTTTGCAGCTCTGGGCGTGGAGCTCTTTGGAGACCTGGAGTGTGATGAGACACACCCGTGTGAGGGTCTGGGCCGGCATGCCACCTTCCGGAACTTCGGCATGGCCTTCCTGACCCTCTTCCGCGTCTCCACTGGCGACAACTGGAACGGCATCATGAAGGACACCCTGCGAGACTGCGACCAGGAGTCCACCTGCTACAACACGGTCATCTCCCCCATCTACTTCGTGTCCTTCGTGCTGACCGCCCAGTTCGTGCTGGTCAACGTGGTGATCGCCGTCCTGATGAAGCACCTGGAGGAGAGCAACAAGGAGGCCAAGGAGGAGGCCGAGCTGGAGGCCGAGCTGGAGCTGAAGACACTCAGCCCACAGCCCCACTCGCCGCTGGGCAGCCCCTTCCTCTGGCCTGGGGTCGAGGGCTCCGACAGCCCCAAGCTGGGGCCCCTGCACCCTGCAGCCCACTCCAGGGCAGCCTCCCGCTTCTCCCTCGATCACCCCACGATGGAGTCCCAGGCTACTGAGGTGCCGGTCACCCTGGGACCAGACCTGCTGACCGTCCGAAAGTCTGGGGTCAGCCGCACGCACTCCCTGCCCAACGACAGCTACATGTGCCGGGATGGGAGCACTACTGCGGAGTCCCCTGGGCGCAGGCCCTGGGGCCTCCCCAAAGCTCAGTCAGGCTCCATCTTGTCTGTGCACTCCCAGCCTGCGGGGTCCAGCTACATCCTGCAGCTGTCGAGAGATGGGGCCCATCTGCTACATCCCCATAGCGTACCCCCCTGGGGCGCCATCCCCAAACTTCCCCCACCGGCCCGCTCCCCGTTGGCTCAACGGCCACTCAGGCGCCAGGCAGCAATAAGGACTGACTCCCTGGATGTGCAGGGCCTGGGCAGCAGGGAAGACCTGCTGTCAGAGGTGAGTGGGCCCTCCCCGCCGCTGGCCCGGGCCGCCTCTTTCTGGGGCCAGACAAGCATCCTGTTGCAGCAGCAAGCCCAAGCCTGCAGCCAGATCTCGAAGCACACACCACCTCTAGTCCCCCATCCAGGCCCAGAGCCCACCCGGGCCAGGGTCCCCCGAGAAACCAGCAGCAGCTTGGAGCTGGACACGGAGCTGAGCTGGCTTTCCGGGGACCTCCTGCCAGCGGGCAGCCAGGAGGAGCCCCCCTCACTTCGGGACCTGAAGAAGTGCTACAGCGTGGAGACCCAGAGCTGCCGCCACCTGCCGGCCTCCTGGTTGGACGAGCAGAGGAGGCACTCTATAGCCGTCAGCTGTCTGGACAGCGGCTCCCAGCCCCACCTGGGCCCCAGCCCCACCAGCTTTGGGGCCCAGCCTCTTGGGGCACCAGGGAGCCGGCCCAAGAAAAAACTCAGCCCACCCAGTATCTCCATAGACCCTCCAGAGGGCCAGGGCTCTCGGCCCCCACCCAGCCCTGGCGTCTGTCTCCGGCGTAGGGCTCCGTCCACCGACCCCAAGGACCCCTCGGCCTCGGGCCCCCCCGACAGCATGGCTGCCTCGCCCCCCACAAAGAAAGACGTGCTGAGTCTCTCTGGTTTAGCCTCTGACCCAACAGACCCGGACCCCTGAGTCCTGCGCCCACTCTCCCTTCCTCCACTGGGGGCCAAGTCCTAGCTCCCCCTCCTGGGCTGGTGCCCTGAAAATGTCCACACAGACACGGAGGCGCCCCTCCTCGCCTCAGTGATGCTGGGCCACGCCACACAGGAGTTCCACCCTGGGCCGCCGAGCCAGGGCACAGAGAGGCCCCATGCCGCCGAGGTTCCCGACACCAGGACTTGCTGGGAGAAAGCAATACGTTTGTGCAGAATCTCTATGTATATTCTATTTTATTAAATTAATTGAATCTA
->XM_020899216.1 PREDICTED: Odocoileus virginianus texanus LCA5, lebercilin (LCA5), transcript variant X2, mRNA 
-GCGGAGAGAAGGCAAGGCGGCGGGCGCCGCGTCGGCGCTGAGGAGGGGCCGGAGCGGGTTGGAGAGGAAAAAAGTGTATCTTCTGGTTGCTATTGTGAATTGTGGACTAAAGGTACATAGAGAAAACGGATTGCACAGACTTGAATATTATCCCCAGGATCTGAAGACTCAAAATTGCTCTTCAGGCTTATTTTGGATTTTTCTGAGAAGACTCTGTGAAATTATGTGAATAGAGACTATTTTTCAAAGCCATGGGGGAAAGAGAAAGAAGTCCAGTTACTGATCGAGAAAGTAAGACAAGCAGACCCTATTACTCTTACTGTTCATCTGAATTTGGAACTACTCCACAGTCTTCTGGCCGGTCGTCGCTGGTGCATCCCTCCCCACCTGCAAGTGTTAAGGAAAAACATCCTAAGAAACAAATTTCAGATAGCCAAGTGCATCATCACGCCCCTAGGAAACCAAGCCCTAAGGGTTCACCAAACAGAAAGAGAGTCAGAGCAGGATTTCGCTCCCAGAGCCTCAATAGGGAGCCCCTTCGGAAAGATCCTGATCTTGTTACAAAACGGGTTCTTTCTGCAAGACTGCTAAAAATCAATGAATTGCAGAATGAAGTAACTGAACTCCAGGTCAAGATAGCCGAGCTGCTAAAAGAAAATAAGGCTTTGAAAAGGCTTCAGTACAGGCAGGAGAAAGCCCTGAATAAGTTTGAAGACACAGAAAATGAAATCTCACAACTTATTGCTCGTCATAACAATGAGATTACAGCACTCAAAGACCGCTTAAGAAAATCTCAAGAGAAAGAACGGGCAACTGAAAAAAGGGTGAGAGAGACAGAAGGTGAACTGCTTAGGACAAAAGTTTCCTTACAGAAACTGAAAACGATCTCTGAAGCTAAACACCTACCTGAACGAGATGATTTAGCAAAGAAACTCTCTTCTGCAGAGTTAAAATTAGATGACACTGAGAGAAGAATTAAGGAATTATCAAGAAACCTTGAGCTAAGTAGTAACAGTTTCCAACGACAGTTGCTTGCTGAAAGGAAAAGGACATGTGAGGCTCATGATGAAAATAAACTTCTTCAAAAAGAACTACAAGGACTATATGACAAATTAAAGGAAAAGGAGAGAGAACTGGACATAAAAAACATATATTCTAATCGTCTGCCAAAGACTTCTCCAAAGAAAGAAAAAGAATTTACATCAAGAAAAAATGCTGCATGCCAGAGTGATTTTACAAACCAGTGTACAAAAGGAGTACAAACCAGTGAAGACTTCAAGCTGGAGGACTATCCTATAACACCACAGACAGTTATGTGTTATGAAAACAAAAGGGAAGAACCCGAACGTCTTTCTTTGGATCTGGAATCTCAAAAGAGAGATAATCTTGGAGAAGCTGGGATTCTAAACCCAACTGTGGAAAGAGAAGACAAATTTGCTAAAGATCAAGGACTCCATGTTGTGAAACAGGATGTTGAGAAGCTGGATAATGGGTGGGAAAGAGAAGAACTTGCTAAAAAGCCAAAGGAAAAGACATCTTTGTTGGAGAGAGAAGGAAAGCCAGTGTTGGAAACTGGAAGATATCAAGTGGAAATGCACCAAGTTCAGAAAATTGATAAACTGGAAGAAGAGGAAGAAGAAAGGCTAAAAGAAATGCTACTTGCTAAACTGAATGAAATCAACAGAGAACAAGACTCTCAGAATGTAAAATATCCTTCTCTGCCATTGCTTCCTGACGTGAAGCCAAAACTGCATTCCCCAGAGAGAAACCCCAGAACACACACGTCCTCTGGATCCTCAGAGAGATTATTTAACGGGCATTATTTGCAAGACCTCAGTCTTTCAACAACGAAAGGAGATGGTCAGAATCCAGGCCATACTCGAAGCCCAGCCTCTCCAGATGAGCTTGTGTTTGGTAGCTATGTGCCTTCATTTGCAAAAACATCAGCGAGGTCAAATCCACTTAGCCAAAAAAGTGACCTTTTGGGTTTCTCAGGAAATAATACAGAGAAATTTAGTAAAGACAGTGTAGATTCAATTACCAGACAAGAAAGAAAAGCCACCCTGATGGAACAGCTGTTTGGTACCAGTGGTGGCAGCAGCCTTTCCTCTAAAAGCAGTGACCCAAATTCTCTGGCTGTCACTAAAGAAGACTGTGACCCTCTAAATTATCTCCCTGGGGATAAAAACAGCTGGGGTAGGGAACATAGTGATGATGATGACTTTTTCCTCAGCGAAGGAAGAAGTTTTAATCCAAGTAGACACCGATTAAGACATGCAAACAGTAAACCAGCAGTAAAAGTAGTTGATTCTGTAGAAGATGAAATTGAAGAAGTAGTGCTGAGATGACTGACTAGAATGTTTTTTTCCAATTGTAATTATTAGGATATTTTAATACAGTATTTATTATGAACATTTAGACTTTCTAATATTAAAAAGTCATCATTAACGGATAATTTTTAGTATATAAATACAGTGAAAAGTAGCTGATACCACTAGTAGCTACACACATGTAGCTAGTTTGCTAATAAGGAAGGAGGCTCTTTTGAATGAAACCAGAAATAGAGATGTATCTTACTTTCTTTGTGCAAATAAAGATGTATCTCACTTCCTTTTTGCAAATAGGTTTTACCTCTTGAATCAACTCTATGAGGAGTTTTACTCCATTGGCATACACATTCATTTTCTGTGTTATCCCTATTATTTTTGGTCTTATCCTCACTGAGCTAAGTACAGTTTTCCCGCTGATGGTTGTGTGGAAATGGAGAGATGCTGTAGGGAGCTGGTGCTACTAGGAACCTCTCCACTGTGACTAGGAGTGAAGGGGGTCCCTTTCTTATATGCCAAGACTGAGCTACTCTTAAGTGGAAACAGTGACAACGTGAGAATTTCCCATTCTTCTGGAAGTAACCACAGTTAAATGGTACTGATTTCGCAGTGACAGAGTCTGATTATATCACTTACCTACAGCTGTGCTAACTCATTAGGCTGAATTCCGAAGACGTCTTTCTGTTGGCATGAACAGTGCCCTCCCTGTCCTGGCTTCCAGAGGTTCCAGTGCAGTGTAATCGGTAATTCCTCTCCTTGAACTCCTAATGCTATCTGTATCTCAGTGACTGGTTGTGAGAGGTCATACCAAATGCACAGAATGGAAGAAATTTCACCCCACTAGAGCAGGATTTTCAACTCAATTATGATTCCAGAGTAACATAACTTGGAAATTTTAATATGTACTTTAAGATTTGAACTTACTGTCAAACCAAAGAGACAATGATCACATGATACCATTGGACTTAAGCGGACTAGTTTTAAAGCAGCCTTGGTGAAAAGTGTTTTACAGATGGAGCTCCTCCCTTGCTGAGTAGGGTGGAAGATGTTCTGTTGAAAAGTGTTAGTTTTTTTGCTGTTTCATAGCTCACTTCAGCTCCAGAGAGGAGTCAGGGACCTTGGATTATGCTGGGCATGAGTGGTCTCTAAGAAGCAGAAATATGCCAGTGGCCTAGGAGAAAACTCAGTGCAAATGAAGAGTGGTGGGAACAGTGTATCAGGGCAAGAATAAGTGGTGATTGGCACTTGTTCTGAAATGAACTGTTGTTTTCTAGAATTTGCTACATATTTGTTCATAGTAGGATTTCTGATGCCAGGCATACATACTGATCAGGGGATTCGAGTTACTATCTTGAGTTCTTATAAATGCTAATTATTGAATATAATTTCATAATTATCTGACAAGACTTACTGGTTAGGTCTCTAATTACAAGATGTACTACCTACATCTTCTAAATTGTGTTCCTGTTACCTACTAGGAACCGAATCTCTCAAAAGTGCTAAACTATATCAAATTTTTTTATAAAGAGATTTTTGGATTGATATAAATAAGCATTTACTATGTTGTAAGTCATTCTAATATATGTAAACCACAATATTTTTGTAATGCAGTTCTTGATAAAATATTATATATTAATTTTTTTCATAGCTGCTAATTTTTCAGCCAAAAGTATTCTCATTTTTAGGCTGTTTTTGTATTAAAGGTTTTTTTCTTTCAAAAGTCCTTTAGTAAAGTTTTAAATTCAGATCATTTTAATTAGTCTCTTTTTTCTACTTGATGTTTTCCAATCTTTTTAAACAGATGTAATAACACAGAATTGTTAAAATTAAATCTAAAATTAAGTTATAGACTTGAAGCATTATGGAGTTAAGCATTAAAATTGGAGACTAAAATGTACAGAACAAGTTATTCTTTATGAACAAACCTTAATGGATAACTTTTTTTTCTAAATGTCAAGTTAAATTTATCTGTACTCCAAACTATTACTAATAAAAATTTAAAATA
->XM_045922658.1 PREDICTED: Maniola jurtina cleavage and polyadenylation specificity factor subunit 6 (LOC123876410), transcript variant X5, mRNA 
-GGTCACACTGGTACTACACTTTTCTTCAATTCGCAAAATGGCGGATGGAGGCGTGGATATAGATTTGTACGCCGACGATATTGAATCTGATTTTAATAGACAGGATGACTTTGGAGGTGAAAATGTCGATTTGTACGACGACGTGATCGCAGCCCCGTCGAAGCCCGAAGACGGCGACGGGCCACCCAACTCCGGACCGCCGCAGCATCAGCATCCACCGGAGGAAACCAACGGTTCAGTTCCGTACCACCACAACACCGTATCAAGCCACGGCCATCATGGCCGCCGCTTCCAACTTTACATCGGCAACCTCACCTGGTGGGCGACTGATCAAGACATAGCTAACGCGGTCGCCGATATCGGCGTAACGGACTTTCAAGACGTGAAGTTCTTCGAGAACAGGGCAAATGGACAGTCGAAAGGATTCTGCGTCATATCGCTGGGTTCCGACCAATCCACCAGGATGGTCCTCGATCGACTGTCCAAGAAGGAGATTCACGGTCAGCATCCCGTTGTGACGCTGCCAACTAAACAGGCGTTGAATCAGTTTGAGAGTCAGTCGAAGACAAGGTCAACACCGCCCGGACCCAACAACCCCGGTATGAGAGGTCCTCACCCTGGGGGCATGCCTGGCCCACACCCTGGAGAATTCTTTGGTGGCGGACCAAATGGACCGGGACCAAATGGCCCACGCATGATGATGCCTGGGCCAGGCCCCCATCATCAGCTTCGTGGGCCCCCACCCGGACCCCATGGCCCCCCACCGCACCACATGCAGCAGCACCAAGGCCCCCCACCGCACCATATGCCGCCTCATCAGGGCCCGCCCCCGCACCAGGGGCCCCCACAACACAGGCCACCGATGCAGTTCCAAGGGCCGCCGCAGATGCAACGCGCCCCCGGAGGCCCTCCAGGAGGCCCGCGAGGGGGCCCTGACTGGCCCAGGCCCCACCACATGCAGGCCCCAGCTCCACAATACGGACCCCCGCAACACCAAATGCCGCACCAAATGCCCCCGCCGTCACCGCATGGGCCGCCCGGGCAAGGCATGCCGCCGCCTCACCATCAGATGCCGCCGCACCAGCAGGGCCCGCCCAGGGGACCCGCGCCGATGCCGCAACATCCAGGCGGGGCTCCAGCGCCGCACGTGAACCCGGCGTTCTTCAACCAGCAGCCGCCCGTGCAGCCCGCGCCCGCAGTGCAGCCGCCGCCGCAGCCCGCGCCGCCCGGACCAGGCGCGCCCTACGGCCACCCGGCGCACGGAGGCCCGCCGCCCGCACAGGGCCCGCCGCCCGGCGCGCGCCAGCCGTACGGAAGACCACCTGCAAGCTACCCCGGCGGTGCCGAGGCGCGGCCCGCGCACCACCCTTCGCCGCTGGGCCCGCACGCGCCCCCGCACGCGGCGCACCCCACGCACCCCGCGCACCCGCCGCACCCCGTCATCAGTGAGGCGGAGTTCGAGGAGGTGATGGGCCGCAACCGCACCGTGTCGTCCAGCGCCATCGCGCGCGCCGTCAGCGACGCGGCCGCGGGCGAGTACGCGTCCGCTATCGAGACGCTGGTCACCGCCATCTCGCTCATCAAGCAGAGCAAGGTGGCACATGATGACAGATGCAAGATTCTCATCTCCTCACTCCAAGACACATTGCACGGCGTAGAGACCAAGTCGTACGGGGGAGAGAGACGGCGGTCGCGGTCGAGGGAGAGGGATGCGCGCGTGCACCACCGCGCGCCGCGTCGCAGGGAGCGTTCCGCGTCGCGCTACAGGGACAGGTCGCGTGACAGGGAAGAGCGAGACAGGTATTACAGGGACTATCGTGAGAGGGAACGCGACCGCTCAAGGTCCAGGGACCGCGAGCGTGCAGAGCACTACAACAGGGGACACAGCCGGACGGAAGAGAGGCCTCGCAAGTCGCCCGTAGAGCCAGCGGTGGAGAGTGGCGCCGGAGATACAAGCACGAGCAAAAGTCGTACAGCGGCGACGCCCTACTACGACGAGCGGTACCGCGAACGCCGCGAACGCGACCCTCCCACCGCGGACCGCGAGCGCGACCGCGAACGCGACCACCGCCGGGACGCTAGGCATTAAATGACTAATAAACTAAAACTAGACCATACCATAGTCTAAATAAAGTACAGTACTACCACTTTCAGAAGTAACGCTGATGTACATTCAAAGGCCGTAATTTGTTTAGCACCTTAATGATCATATTCGCGTGGCAAGGTTATGCACATGCGTTAGGTGTGTGTAGCGTGTTTATAGAAAAAAGCCATAAGTGCGACAGGTTTTTGATGCAATAGTTTCGCGGAATTGCTACTCGAATTCTGAGGCCGACCGTACCTACGCAGATATTATATTATATATTATGTATGTGACATTGCCATTACGGGATAGTGGGAGCAAAATTCTATTTTGTTATTCTGGGACTTTGAACTTTCTCTCTTCTGATTGGTCCACAAACATTCGTATGTCTTGTTTTTGCTCATAGGTAGTGATGTAAAATAGTGCCACTCGGGGCCAAAATTTTATGTTTAAGGGCGACGTATATCAATTCCTCTCTCATAACCCCATGTTGATTCCACAGTTTGTATGTGCGTGGAAAAAAGGATCTGGCACAACGGGCGGTCGAAGTCACCAGGCACCCAGGTGGTTAGGGTGAA
->XM_034343108.1 PREDICTED: Prunus dulcis protein DECREASED SIZE EXCLUSION LIMIT 1 (LOC117614330), transcript variant X3, mRNA 
-CACCCTCACACCACTAGTACTCTGATACAAGTCTGTCTACATCTACATCCTCTCTCTGTGTGTCTGATGAGAGAGCACAAAAAGTTGAAAATTATTCTTCTATCTGACTATTTTCCCCTTGCACGGGTTATCATCGTCTTCCGCGAAAAACAGGGTTTCTCCAAACTCTTTCAGTCTCTCGCCGTCTCTGAATCGGTTTGTGTGTTGACCAGAGGACGAAGTCAATTTTAAGTTCGTTCTTCTGTCTTGACTAGTCCAATGGAACGTTGGTTTAGTACAATCTGTAATAGCACCTCCTCTTGAATAAGTCGTAAGAATAACACGAAGAAACCCCTTTCAACCCCGTCGGGTCGTGTACTCAGCACCTCCCTCTAGTGCTATAGCGGCAGTCTGTGACTCTGTCTGTGACTGCCGCATTGCTTATTGAAGAAGCAGGTCCAATGAGCAAACAGAGACTGCCACCGGACCCAGTGGCTGTGCTGAGAGGTCACCGCGCCTCTGTCATGGACCTCTGTTTTCATCCATCCCAACCTCTCCTATGCACCGGTTCCGCAGACGGCGAGTTGCGGATTTGGGACACTATCCAGCATCGGACTATATTATCAGCAGGGGTGCATAATGCTGCACAGGGGATTGCTTCTGTTGCTTGTAGTTCTTCAATTGGAGCCAATAAAGTGATCAGCCAGGGTAGGGATGGAACAGTGAAGTGTTGGGATATTGAAGATGGAGGTCTGTCCAGGACACCTTCTGTTACAATCAAGACAAACTCTTACCACTTTTGTAAACTTTCCTTGGTGAAGAGACCTCATTCTAGTTCTAAGCGAGTTTACGGGACTACGCATAATGACAGTGATGAAACAAGGGTTACGGAGAATGCTGATACGGATGCTCTAGACAATAGCAGAGAAAAGTTTCAAGAGTATCTGCCTGAGCAGTCCAGCACCTTTGAAGAAAATACTCAAGTTGAGGGATCTAAATGTGTCGCTGTAGCAGGGGAGCAGCCTTCTGAGGTTGAGATTTGGGATCTTAATACTGCAGAAAGGTTTGCACGGCTACCTCAAAGCTGCGTTGCTGGTTTCTCAGGTATATCTACCACAGAGAGAGGAATGTGCATGGCGGTTCAAGCATTCTCACCATCCGAATCACAGGGATTCCTAAATGTCTTGGTGGGTTATGAGGATGGTTCCATGCTTTGGTGGGATATTAGAAATCCTGGGGTTCCATTGACCTCTGTCAAGTTTCATTCAGAGCCAGTTCTAAGTCTATGCGTTGATGGGTCATGCAATGGTGGTGTCTCAGGAGCCGCAGATGACAAAGTTGTGCTGTACAGTTTGGATCATTCCATGGGTACATGTGTGATCAAGAAAGAAATTAGTTTGGAACGACCTGGCATATCGAGCACTTCTATTCGACCTGATGGTAAAATTTTTGCAACAGCTGGCTGGGACCACAGAGTGAGAGTATATAACTATTGCAAAGGCAATGCTCTGGCGATATTGAAGTATCACCATGCAACGTGTAATGCTGTTTCTTATTCACCCGATTGCAAGCTAATGGCATCTGCATCAGAAGATACGACAGTGGCACTGTGGGAACTTTATCCTCCTCGAACTTGAAATGATATGGTAGTCCTGAAGTGGAAATGAGTTTGTGTTCCCTATAATGTAATAAAAGAGCATCAATAATCAATATCATTACCGTTTGTGTGCATAAGGTTAGATTAAATTCATTTAAATTATGGATTATTGCTTCTTTAGGAAAAAGATAAGATGTTAGACCTTCAATTTAGCAATAAGAGAAGATGTTACTCGCCTACAAGAACCGTGTGCTGGGATGAAATATGTGTTCTCCTTGTGTAATTTTCAGTTGTTTCAGACAAAGCCTAAGAAAAAATCGACATTTTGGACTGTTATGTAATTTGATGGCTGCCTGCAGGTTTGTAATTGAAAAACAGAACCAAACTCGCAGGCTTTCAGACGCAAAAGAGAGGGCCAAGTCGCGTTGATTTGATTTGGACATTTAGTTTGGTGGCCAGCCTCCAATCCAATGGTATCGAATAGAGGTGCCACATTCTTAGCCTCTGATCTACAAAGCAATGATTGGCTTGGCTATGCCGGGGATTATTGCTTCAAAGCTCCCAATTTGATCTCTCTTACTTTGCACTAGAAAAAGATGACCCGTTGTTGACTTTATCAATTACTCTTGAAATATTTTTCAATATAGCAGCCGGGGAAAGAAGTTGCACCTA
->XM_035481792.1 Colletotrichum scovillei uncharacterized protein (HER10_EVM0012396), partial mRNA 
-CGGAAATTTAGATCATTGTAAAAACTGTTCGTTGAGTTGTTCTCGGGCGTTTTTTTCTTTTCTTTAAATAGCGTACAAGTCTCGCAACTCAAAGCGTCGGGCGCTCTTCCGTTGATCAATCGGAACGTGGCCAGAGACCAGACGATGTCGAGGGACGGGAACCCCGCAATTAGTTCATAAATCCTGTTCAGCCGCGGGCTAATTCCGATGAGCATTGCACACTCATTCGCAGACGACCCATATCACGATTATCGGGGCCATGGGATTTCGACAGCATGTCAGAGGGGAAGGTTCAAAGAGGTGCTGCTGAGTCTACTGGGGAAGTGCCCGCAAAGCAGCTCAAGGGCTGCGCCAACTGTGAGCGTCGTCGAATTCGCTGCGATCGACGGCGACCCCATTGCGCCAAGTGTGACAAGAAAAGACTTTCATGCCCTGGCTATGACCGCCGACTTCGATGGGTGGAAGGGGTTGCCGCGAGGGGACATCTGCGGGGTCGAACGGTCCCGACGAGGCCGTCTTCTGAAGATAAGGCCGCATTTCGAGAAGAGGACTCGAAAGACATCTTCACCGAAAGTCCACAGCTACACAAAATAAAAGACTTCACGACTTCGGTCGTCATTCTCAATGCGCCAACCGCCCAAGCAAGTCAAGCTTGCGAGTACCCCGACTCCCTGACAAGGGTGTTCATGGACTATTACAGACGGAACTTAGCCGGTCTGATGGTATGGATGGACTCAGACCAAAACCATTACCGTACACAGGTTGTTCCTCTGGCCGCGAATCAACCAGCGATCGGCTTCGCCATCATGGCTTTCGCGGCTCAACACGGCGCCATGGCGTTGCCTGATGAATCTATCGCTGAGACTGCTCGCGATAGGTGCTTGCACCTGATACAAACCCGCGCTCAGGATATGACGGCACGGCTTATCGAGGGCGATGACTTGGACAATCATGGTGACTTGGCTGATGCGGAATGGATGCTGGCCTCGATTCTCATCATGTGCAACTACGAGAATGCCCGTCGCCGCCTTCAAATCGCCGATGATCACAGGCGCGCGGCAAGGACGATTGTCAACCTTTTCAAAAGCCAGAAGTCAATCAACAACCGAGATCTGTTTGCGTTCTTGCGAAACCAACTAGCTATAGATGATGTACTGGCAGCTACGACATCGTGCGACCTGCCTCTCATTCGGAGCGCCGTCACGCCAGCACCTGGCTCAGATTATCTCCTCTTTTCGAGATATCTGACTTTTTTGCACCGTGTCACGCTCATTTCGGCAGATGCTGTTGATTCTTATCCTTCAATCTCGCGCTTACGCAGCGGCCTCACGGTGCCTCTCATCCAATCCGAGTTTGAGCAGGCAAGAGGCGCCACGCTGATGGCAGCCGGACGACTCGGACTGGCAGGATCAAGCATGTCTCGTGACTTCATACGCTTAGTCGAGGTTTATCATAACGCGGGGTTGCTTTACTCGTTAAGATGCCTCGACTACGCCATCGAGCACGCCTCGGAGCGCCTTGTGGCCGCTGCTAGTCTGTTCGACCAACTGACCGAATTGGAAGACCTAGCTGCTTTCGTTCAGAATCTAGCCTGGCCGACGTTCATTGCCGGTACCGAATGCCATGGAGATCGGCATCGACAAGATATCATTGCGGGTTTGCTCACGGCAATTCATGAGGGCACGCGCTTCAGTTATTACTTGGACGCGGTGAACTTTCTCAAGGAGTTTTGGGCCGGAGAAGACAACGACTGGCGTCCTCTCGCTCGCATGAGAGAAGCCATAGGGCAGCGAGTCCTTGTGGTATGA
->XM_006964907.1 Trichoderma reesei QM6a uncharacterized protein (TRIREDRAFT_61223), partial mRNA 
-ATGGAGACGTACCACGGCTATGTACGGACTCCAGCTGATGCCATCAAACTGTTCGAAGCCTGTCGGCTAGGCCATCTGCCTCGGGTCCAGAGGCGACTCTCTGAAAAGGAGAGGCAGTCTATCAGATCCGGCTCAGTCTTTGTGTGGGACGAGCGCGAAGCAGGCATGCGGCGATGGACGGACGGCAAGTCTTGGAGTGCTAGCAGAGTGTCGGGCAGCTTCCTGACGTACCGCGAAATGGAGGGCAAGCGAGGAGGCGGCTTTGGAGGAAGCAGACGGGGCAACGGCAAGACGCCCGAATCTGGGCGCGGTAGCGACGAGGACCATGACGACGGCGAGCCGGAAGGATACCGATACAAGGCCGACGGCCTTATGAAGCAGTCGTTCAGCATCACCACGTCGACCGGCCAGCACCTCCACCTCATCTCGTACTACTCTCGGCCTCAGCCGGGGCAGCCCGAGCTGCCTCAGCCGACCAACGATCCGATGCTGCGATCCATCATCCCGATGAAGGGCATGTACCCGGAGTCCAGCATGGGCGAGACGAACCAGACGCCTGCACTGACGAGGGCGCCGATGCTGCAGCAGCCGCCTTACATGATTGCTCCTCAGCATCAGCACCACCACCCTCCTCACCCGGCGCATCATCAACCGCCGTTTGCGAGCCATTACCAGCCCGGGTATGGCTGGCCTCCGTCGCCAGTCGCGACCCCTCCGTACAGCCATTACACCTATAGCCATCCTCCTCCCGTCCACCATCTGCCTCATCCGTATGCCCCCCAAGGTCCGCCGCCGCCTCACCACGGCTATGCACCGCCTCCGCCTCCTCCGCCGCATCACTACCAACAACATGGCGCGCCTAGTCCCTACGACCGGCCTTCATTACCGCCTCTGCAAAACACGCCAAAGCCGGCCCCTCTGCCTCCGTACCATGGCCCGCAGCATTCCCAAGGACCGACGCCGCCCCGTGGCCACGAGTCTCCCCACCAGCCAACCTTGCAGGCTGCCGCGCAAGCCGCCATGGGCGATTCACGGACCCCGCCCGAGAAGAAGCCTCAGGGGCCTCTTCCAGCTCTGGGGACTGTTGCCAACGGGCCTCTTGTCTCTGCCCACAGCGGACTGCACACTCCTCCCACACGGACGCTGAGCCCGAGTCCGCCTCAAAGTTCCCATGTGGAGACGCATACTAGCACCAGCACCAGCAACAAAGCAAGCCTGTCCGCGCTGCTGCACCCCACGACGTCTTCCTCCACAGAGGCCGGTGCAAACGGCAGCGCTCACAGCAGCCCAAGGACGGCCAGTATCACCATGGCTGAAAAGGGAGGCGCCAGCGAAGACGCGCGAGCCCTGCGGATGCTTGACCGCAAGTTTTGCATCTAG
->XM_032861574.1 PREDICTED: Lontra canadensis endothelin 1 (EDN1), mRNA 
-TCAGACGGCGGGCGTCTGCCTCTGAAGTTAGCAGTGATTTCCTTTAGAGCCTGGCCTTATCTCCGGCCGCACGTTGCCTGTTGGTGACTAATAACACAATAACATTGTCTGGGGCTGGAATAAAGTTGGAGCTGTTTACCCCCACTCTATAGGGGTTCAATATAAAAAGGCGGCGGAGAGCTGTCCAAGTCAGACGCGCTTCTGCAGCGGCGCTGGGGCGAGCGCGCACAGGGTCCTCGGTCCGCGCTGCTGTCCCCGCACGCCACCGCCGCGTGCGCCCGCAGACCGCTCCCACTGCCGGCCCTCCTGGCAGAAACTTCTTTTTTCTCTCCGTTAAAGAGCACTTAGGCTGAAGGCTCACTTTGAGATCTGAATAACCAGAAGAGCTTTGAGGGACCCGAAGCTATTATTTTTCTTCGTTTTCCTTTGGGTTCAGTTGGCAGGGGAGGACTTTGATCCCCACTCCCTCCCCCCTTTTTTTTTCAGAATGGATTATTTCCCCATGATTTTCTCTCTGCTGTTTGTGGCTTTCCAAGGAGCTCCAGAAGCAGCGGTCCTGGGCGCGGAGCTCAGCACGGGCTTGGACAGCGGAGGGGAGAAGCCCGCCCCCAGTGCACCCTGGCGGGCCCGCCGGTCCAAGCGCTGCTCCTGCTCCTCCCTGATGGATAAAGAGTGCGTCTACTTCTGCCACCTCGACATCATCTGGGTCAACACTCCCGAGCACATTGTTCCCTATGGACTCGGAAGCCCTTCTAGGTCCAAACGATCCTTAAAGGATTTATTTACCACAAAGGCAACAGACCACAGGAAGAGATGTCAGTGTGCCAGCCAAAAAGACAAGAAGTGCTGGACTTTTTGCCAAGTGGGAAAAGAATTCAGGGACCAAGATGGTATGGAGAAGAGCTGGAATGACCCTAAGAAAGGCAAAGACTGTTTTGGGCTTGGAGAAAAGTGTGTTCATCAGCAGCTGGTGGCAGGAAGAAAAATGAAAAGGTTGGACGCCATCAGCAACCGCATCAAAACAGCTTTTCGTGTTGCAAAGCTGAAGGCGGGGATCTACACAGAGAGGCAAGTGACTCACAACCGAGCACACTGATGGCAGGTCACCAGGGCCCATGGCTGGCCCGCCCGAAAGCCTTCTCCTCCGAGGAGGGAACCCTGTGGCTGATTCTGCACTCTCTCCCCATGGCTGGGATCAGAGCAACAGCATCCTCCCTGCTTTGACCGACCATTTCTTGCTCCAACTGGCAATGGACCAGTGCCCTCGCTCTAAACATTCCAGGGAAGGTTAAGGAGTCCCCCAATCCATCTTCATTTGCCTCCATTGGTGATAACTGCTTTCGTCTCTCCTCGTTTGGGGTGACAAGAGACTACTCAGAAGGCAGAGAGACACACAGTGACTTGTGATTTCGGGTGTCACCATCCAGAGGGAGGACAGGAGATTCCACACATGGTGGAATTTCTGAAGAGGGTCCGAAGGGAGTGTTTGTGTCTCACTCAGGCGCCTGGCACATTTCAGGGAGAAACTCCAAAGTCCATGCAAAGATTTTCTAAGGAATGCACAAATTAAAAACACTCTCGAAGGACACTCAAGTTAAAAAAAAAGAAAGAAAGAAAGAAAGAAAAAGACTTTTTTTTCTTTTTAAATTCACAAAATGCAAAACTAAAAGATACTGCTACTACTGTAAATCAGGATGGGTTTGATGAATCTGAGTCTACCTCACCTCTATTGCACTCTGGTAGAAGTACTCCCCCCCGCCAAAAAAAGAAGTACTTCCCCACCATTAACTATATCCCCCCC
->XM_030076989.1 PREDICTED: Myripristis murdjan Ras and Rab interactor 1 (rin1), mRNA 
-ATGCAGGAGGTGGGCTGCTCCCAGCAAGGCTCCCAGAGGGCCTTCAGCGTCTTGGACCGTCTGCTCCTCACACACCCCGTCTGGCTGCAGCTGTCACTCAACCAAGACTCCGCCCTCTACATCCTGCTGAGAGAGCCGGTCGGGACGTTCTTGGTGCGTAAATGCAGCTCCACTCAGAGAAAGGTGCTGTGTTTGAGAGTGACAGCGGACCGAAGTGCCTCCTCTGTGAAGGAGTGCTTCATCTGTGAGGAGGACTCCACTTTTGCCTTGGAGAGCTCTGCGCTCAGCTTCCCTGATTTGTGTCGATTGGTGGCCTTCTACTGTATCAGCAGGGATGTGTTGCCGTTCCCGTTGCAGCTACCGGATGCCATCGCTAAAGCCACGTCCCACAGGCAGCTGGAGGCCATCTCACATATGGGACAAGAGTTTTGGAGCCCGCCCACTGCCTCAGAGATGCTGAACGGACCAGTGGACCAGTTGGCATCGACCAGTCAGGACCAGGCGGCGCTGACCCAGGACCTGTGCAACCTGATGGCCCGAGGCAGATACAGCAAACTGTGCTTCATAAACCCCCTCTTCATGCAACTGGAGCAGCCACAACATTCAAACCACGGTGCCTCCAGTAAACGGCACCGCTTAAAACGCAGCATGAGGCTCCGGCTCTCCAACGAATGCTCCATGAATCTGTCTCTGGAGGGCGTCGGCTCCTTCTCGCCTCCCTCCTCCTTGGAGGTGCCCGGCGGTGGAGAGAGGCTGCAGAAGGCCAGTCCTAACCCACAGAGAAGAGTTCATCCCGGGGCAGGGGTCTTGAGGCGAACCCCTGCTGTTTCCCCCGGCTCTGCAGAGGAAGATGACATCATGTCGACCTTTGTACCCCAGGTAAGAACCAAGGCTGGCGTGGACGAACCTACAAGGCCCCAGCATGGTGTCCGAGCGGAGGAGCCGAGCATCGAGGTGGCCGTGCTGGCCTTGGAGAGCCGTCCCGCTCCCTCCCTGGTCGAGCTGGACAGCAACAGCTCCTTCAGCAGCATGGACGACTCGGATTCAGATTCAGAAACTATGAGTCAGCCGCGAACGCAAGCCCACCAGCGCCCGCCCCTCGTGCGCTCGCGATGCCGCGGCGGGCTTCACCGCATGAGCGCGGCGTTTGTGTGCTTCTTCGCGCCGGAGAAGCGCCTGACGCGGCTGGTGGAGGAGCTGTCCCGGGACAGGCGCTCGATGTTTGGGGCCATGGTTCAGGACTTCATCGCGCAGCAGATAGAAGTGCTGAAAAAGCTGGATCCCTCTTCATCCTCTTCCTCTCCATGCGTGACCTCGGTGGAGCTGCTGCAGGGCCTGCGTCTCTTTCTGTCCCAGGCTAAGTGCTGCTTGTTGGACAGCGGAGAGTTGGAGCCTCCCATTGAAACTCTGGTGCCTGAGAATGAGAAAGACCTGGCGCTGGAGCGGGCCATGTTCACCTGTGTGCTCCGGCCGCTCAAGTCCCTGCTGGACCAAGCCCTGGTCATGCTGCACATTCAGGATGGCTCCAACCAGCGCCTCAGCAAGAGCCTGCTGCAGCTGAAGGGGGACAGGGCCATGGAGCATCTGGGGGTGCAGACGGGCGTCCCGGACAGCCGTGACGTGGAGAGGGTGAAGCAGAAGCTGATAATGATGCAGAGGACGTACTCACCTATTGATAAGGTGCTGCTGCTGCTGCAAGTGTGCAAGTGCGTCCAGAAGGCCATGGGGTCCTTACACGGCCAGCCGGTGAGCTGGGAGGACTTCCTGCCTTCGCTGTCGTATGTGATGGTGGAGTGTAACCGGCCCCACATCCTGATAGACGTGGAGTACATGATGGAGCTGCTGGAGCCCTCCTGGCTCTGCGGAGAGGGTGGCTACTACCTGACCAGCGTCTACGCCAGCCTGCGTCTGATCCAGAGCCTGGAGGGAGACCAGCCGCCCCCCGCCGGTCTGACCCAGGAGGCCCAGGAGGCGCTGAGGGAGTGGGGCTGCAGACGGAACCGAGAGGCCCAGAGACACAAGGAGAACCAGCAGACTCAGAGGTACGTTCGGATACTGTTCCAGGACGGGGAGCGAAGTGCGGTGCGGACGTTGCAGTGGAGAGCCGGGGAGACCAGCCAGGCCCTGGCACAGCTGTGTGCCGACACCTTCGGCGTGTCGGACCCCCAGCAATACACCCTGTACTGGCGCAGCGGCGGTGAGATGAGGGCGCTGCCGCCCCAGGCCCAGCCACAGGACCTGGCCAGCCACAGCGAGGGCGGCCCCTCGCTGTCCTACCTGAGGACCGACCACGACTTCAGCAAGATGCGGCGGCTGACCAGAGGCGGCGCTGTGGACCTGAGCGAGTCGGTGTGTGAGGAGTGAGTGGGAGGGATGGAGGAAGGAAGGAAGG
->XM_013321598.1 PREDICTED: Papilio xuthus rab11 family-interacting protein 2 (LOC106124683), mRNA 
-TGATGCGACTGAACGGTGAACGGACTTAACAAACAAATGGTGACGGGTGACGGTCTATGATTATTGACTGCGACAGCTCATCGTTTGTATAACAGTAGTTTTTTTGTACATTCCATCAACAAAAATATTGCTTTATTATTACTATTTCTTTTAATAAAATGTGGGATCCGACACATGTGCAAGTAACAGTCCAAAGAGCCCGTGGATTATTAATTAAAGGTAAAAACGGTACTAATAACTGTTTTGTTACTATTGCCCTCGGTAAAGAAAAGTTTCAAACTTCCGTGAAACACAAAGCTACTGAGAACGTCGAATGGTTAGAAGAATGTGAACTACGTATTCCATCTCACGGCAACACTGCTGAAATCGTTTTGAAAGTTTACGACGAGGATTTTGTAAAGGATCACTTACTAGGTCAAGTATCGATTCCGTTAAAAGACCTCGATGTCTATGAACGTCCAAGAAATCGCTGGTATACATTGCAAGGTAAAACTGGGAAAGAAAGTGATAAAAAAAGAGGCGAGCTTGAAGTTAAAATAGGTTTTACAGTAAAAGAAGGAAGCCTGACAGATCTTAGCAAAAAGGAAAAACATAAATCATCTTTGTCAAGTATTGCTCAGAATGTAGGCGGAAGCCTTATGAGTATCGGAAGCATTGAAAAACGTAAAGGTATCAAGAAATTCGCTAAGAATCTTGGTTCCAAAATTAATCTGACAAAGAAAGATAAGAAAAGTGATACTTTATCACTTGATGGCAGTGTGGGGAATCTCAAAACTCCGACTTTGCTGACGCCCGACCATTCAACACCAAAAAGATTGTCAGGGGAAGCAGACCCTGGTGTAATTAGTGAAGATGAAGATGAATTTGCTTTTGATGATCTGTCCCATAAAAGTTCTGGGAGTTCACTCAATGTCCACACACTACCAAGAGGGCATAAATATACTCCATCGCCAGTTAATGCTTCCCTTGAAAACCTAGGAGGTGGAGAATTCTTAAGAAGATCAACAAGCAGTAACTTAGCAGTACCTGATAAGTTAGCACCTCAAAAACCTGTCCGCTTGAGTTTAGACACATTCACAGCTCCGCAGCTGCCTGCTCAAGTGATAGATAAAAATGATGAGTGGTCCCAAAAACTTTATTCCCGTCCAAAATCCAATAGCCAGAGTACTATTGACAGAGAAAAGTCATCAAGTCTAGAAAGAAATAAGAAACTGGATAGTCCCAGTTCTCTGAAAGAAAAGCCTAGCCCAAAGTTCTTTAAAAAGTTTGGTAACAATAACAAACCAAAGAAATTGTTAGAGGAGCGAATTATTGTTGGTGAAGAGAACATTGTTGAAGAAGATGCTATCAATCCAGCCTTTAATAACATTCCTAAGACGGTCTTGCAACAGTTTGATGGAAAGACAAGAGAAGATTTAATTGTCATGATCTACAACATGCAAAAAGATGCAGAAGCTGAAAAGAAGAAGAATAAAGATTTAGAAAATTATTTAGATGAATTGTTGCTTCGAGTTATGGAAACAACACCAAGAATCTTACAAAACCCATACACAAGAAACAACAGTATGCATATGAGAAACAAGTGAATTTAAAACTTTCTGAAATCAATATTTACAATGTCAGGAGTGAATTATATTAATATGATAATCACTGTTTTGAAAATTTTACAGAATTGAGTCCATCCAAAGTAAAATTATTAATGCAAAGATTGTGTCATAGTGGATTAGTATGTCTAAATATGGTATAATTTAAAATTAATAAAAATTTAAATGGATGCCTTGAGAACTGTGGCACAGTATTATAAAATAAACTTAGGTAAGTACTTGTCAGTTCAGTTATGAGATTTCTAGTTATAAACATGTTACATTATTTCTCATTATTTATTATGCAGGTGAAATTAAAATGTACTTCCTTATGTTCATTAATTGCTAGTAAGATTTCTTCAACCTAGTGCCTTATAAATTTTACTAAATCTGTGATAAAAGCAAATTTGATTTGATACAGAAATATATTGCTTATTTGATAAATTACTATGAGAATTATGAAACTATTAGCTACTAAATATTTCAAACATACTCAATTTATACATAATATGTCTATGTTATTAACTCATCTATATATCTATATTTTTATATCATTAAAAGCAAACATGCTAACACATCACCTATTGTTATGTGACCACTTTAACCTTGGTGCCAAATTTTGTTGTTTGAAAATTGTGGATAATTTTACTACCAAATCAAGATTTTTATTTTTGTATTATCTGATATGATATGGAATGTATTCATTTGTAAATCTACAATCTACAAGTTTTACAACCCTAAAATATAGTAACTTTTTGCTTCTATGGAAATATTATTAATCCCATGGGTGCGGAGTTATTTGAGAATATATTTGCATGTGGAACGGAATAACTTTTGATTGCTTGGAGTATTATGTAAAGGCAGTACATTTAATTTAAGAATGTTATTTATAAAATATTAAAAGTTTAATTTTTGGTTTGACGTCTTAAACACGTCATCCGTTCTTAGGGGGGAAAAGCAAATGACGTAAATGTAATGAAACAAAAAGAAAAGCAAACTGGAAACCATATGTGTGTCACAATTATTAATATCTAAATATAGAAAACTATTAGTTGATTTGTGAAATACTATTATTGCATTGCATATATTTTATGAATGTATATATACTTTATCATTTTTATAACTACAGTGAACCTTTGCTAAATAAGTTTTGGGCAGTATTGAAGTATTTAGGTGACTCTTTCAATTTGTCTGGGCGAATTACAAACAGACGACATTCACAATCGATCAGTTACATAAATATGAGTGGGTGAATCATGTGTTTAGTGATTCACTTATAATGAAAACTCTTAACGAGTCATGTAATAAACCATAGACATACCGGTTTAAAAGAGTTGACCATTATTATTGTTTATATAACTTTTTTACAAAAAATGTAGCTATTTCATAGACAAAACTGAGTTTCAAATTACTTCATAATATGTGCAATATGAATTAGCTCATAAGTAATTATACATCTCATTTATTAATGAAAGGCAATTTAGGTGTAATACATATCAAGGTCCAAGTTGTTATGTCTGAAACATGGAGAAAAAGTTCATATTACTTTGGTACTAGATGAACAAGCCTTTATTTACTTAAATTTATATTAGTGTTATTATTCTTATGTAGTTGTGTTATTTCAGTGCAGTCAGCAAAAAACATCGATGATTTTTAATCTTCCTTCACTTACACTTATGTTCACCAATACACACAGCTGAGCACTGGGCTCTCTGACCTTTTTAAGACTTGGACTGCAGTGAGAATCACACAACTATTATATTTATGGTTGCATATTGAACAATGTAACCTTGATTATATTCTCCACTGAGTGAGTTGATAAATTGTAATTTTAGAAATAGGATACTATAAGCCTTACTTGTAATTCAAAGATTTGTTTAGTGTTTATTTATTTTTTATTTCATTTAAATACTAAAATTGATTTTATTTACTTCCTTTACCATTTTTCATTAACCATCAATTGTTTGATTTTGAACTTATTTTTTATTAACAATTAAACTACTAACTCTTAAATTATTTAGTTCATGTATCTAATAGTTAAGAGTAAAGTATGTTTATATTCATTGATT
->XM_031377017.1 PREDICTED: Mastomys coucha olfactory receptor 2A12-like (LOC116095757), mRNA 
-ATGAGGATGTTTTCAGGACAGAACCAAAGTTGGGTTTCTGAGTTCATCCTGCTTGGTTTCTCCAGTGACCCCATGACCAACAGCATCCTCTTCATTGTCTTCCTTCTCATCTACCTGAGCTCAGTCCTGGCCATGAGTCTGCCATATTGTGGGCCCAATAGGGTCAACCATTACTTCTGTGAAGGTCCTTCAGTGCATAGCCTGGCTTGCATAGATACCCACCTCATTGAGATGGTGGATTTTGTATTGAGTGTTTTTGTGGTTGTCATTCCCATTTCCCTCATTGTGGCTTCCTACATTCATATTGCCAAGGCAATTCTCAAGATCAAGTCCACCCAGGGCCGCTGCAAGGCTTTCTCTACCTGTGCCTCCCACCTGACTGTGGTCACATTCTTCTATGCTCCAGCCACTTACATCTACATGAGGCCCAACTCCAGCTACTCTCCTGAGCGAGACAAGCAGATCTCACTCTTTTACAATGCCTTCACAGCCTTGCTCAACCCTGTGGTCTACAGTCTGAGAAACAAGGACATCAAGAGGGCATTTCTCAAGGTGATGGGACATGGTAGGCTGGACCAGTGA
->XM_021109787.1 PREDICTED: Arachis ipaensis putative amidohydrolase YtcJ (LOC107613187), transcript variant X3, mRNA 
-AACTTATAACAGACATTTAGTTTCCGATCATTGGAGATGCTTTAACTCACCTCTTCTCAACATAGTTCCCCCATTTCTCTTCCACTTCCTCTCCCGCTGTCGTTTGTCAGCGCCGCCAGAAACGACTCTTTAGCCCTCCTCGACGTCGTTCCTCTGGTTGAGCTTCGTGCTGCCGTTTCATTCACTGTGTCTGTTATTTGAAATTTTTTACGTCGTTGATGCTGCTGTTCCGAATAACATTAGCACATCAAGACGTGAATTTCATGATTTGCTGAGGCTATTTTAGGAAATTGCTACAGTACTCCTGGATATTACATTGGGACAGAAGAGTGCCCAATGAACTCTTTTCTGAAGCTGCTCTCCATTCCCATAGCTCTCCTCTCCATTCTTTCTTTCTCCTTTCTTCACCCAACTCATTTCTTGGGTTGGAAGGCACTAATGTCGTCTCAGCAAGTGGCAGATTTGGTTGTGAGGAATGGGGTGATATATACAGGTGATGATTCTCTCCCGTTTGCAGAATCCATGGCAGTGGCCAACGGGAGGGTTGTCCGTGTTGGAAACCATTCCTATGTGCAGGAGTTGGCCAGCTATGGAACTGAAGTGTTGGATCTTGGTGGGAAAGTTGTGGTTCCGGGGTTTATTGATTCCCATGTGCATTTCATACCTGGTGGATTGCAGATGATGCAGGTGGATCTGACAGGTGTGAATAATAAGGATGAGTTTATCAGAAGGATCAAAGATGCAGTACAAAGTACAAAACGAGGTTCTTGGATTTTGGGTGGAGGATGGAACAATGATTTATGGGGAGGAGATCTGCCAGCTGCATCTTGGATTGACGATTTCACTCCTTACAATCCCGTATGGCTATCAAGAACAGATGGTCACATGGGCTTGGCTAACTCAGTGGCACTAATGTTGTGCGGCGTGACAAACTTAACAGCTGATCCGAGTGAAGGGACTATAAAGAGGACTCCAGATGGAGAACCTACTGGATTGCTGATCGAATCTGCAATGTCACTTGTTATGTCGCAGATTCCAGAGGATTCAGTAGATAATAGGAGGGAGGCACTGCTTAGAGCAAGCAATCTTGCCCTGGAAAGGGGTGTGACAACAGTTGTTGATATGGGAAGATATTATTCAGGGACTTCAGCAAATCTTTCTTGGGAGGATTTTACAGATGTTTATCAATGGGCTAATTCTATGTCAAAAATGAAAGTTAGAGTGTGTTTATTTTTTCCAATGGAGACATGGTCACGTTTAGTGGATGTGATCAACAAGATGGGTTATGCCTTGAGCGAATGGGTGTACATTGGTGGTGTCAAAGCTTTTGCTGATGGCTCATTGGGTTCCAATAGTGCATTGTTTTATGAGCCGTATGTTGACGATCCAAACAATTATGGCCAACAACTTATAGAGTCCGAAGCTCTTTTCAACATGGCTTTGGAGTCAGATTTATCTGGTCTGCAGATTGCAATCCATGCTATAGGGGACAAAGCAAATGACCTGATCTTGGACACATATGGCTCAGTTGCCTCTACAAATGGACCGAGAGATCGAAGATTTAGGGTAATATGGTTACTATTGAGCATGCTCAGCATCTGGCTATGGGAACTCCACACCGATTTGGCAAACAATGGGTTATTGCTTCTATGCAGGTATACCATTTCCGCTGCTCGGGCAAGCTTCCTTGACAATGATCTGGGATCCTTATCTCCAGGGAAACTTGCAGATTTTGTCATACTAACCACTCATTCCTGGGAAGAGTTTGCTGAAAGTGCATCTGCATCTATTGCCGCGACATATATTTCCGGTGTGAGAGCATATCCTTGAAGGTATTCCATAATCTATTTCAAGTTTTACAATCAAATTTGCATCAGATGTGCAGAAGGAAAGAAGTGTTGTAGCGCCAGTCCTCTGAAAGGTTTTAAATACAGTCATCTTATTTTTTATTTTTTTAGGAAGATTAATACATACGCATGAGAATGTGAACATTATTTTAATTCCATATTGGTGTATTAATTATTTCATATTTGTTCTTGTCATGTGAGTTTTTCTATATTTCTTTTATACGACTAATACTAGGCGTACACCAAAATCAACTATAAAATCAGCCATTGTATTTTTATACG
->XM_010548157.1 PREDICTED: Tarenaya hassleriana uncharacterized LOC104818540 (LOC104818540), mRNA 
-ATGGGAAGAAAAAGTTCGAGAGGTGATAGCGTTGCCGAACGGTTCTTCAAATGCGCTGAAGCTTATACGTTGAACGAATTTGAAGACCTGTTTAATGATATAAAGGACAGGTATCCCAAAGTTGCGGAGTATATGCAGAAAGAAGAACTTGATCCCGAGAAATGGGCAAGGTGTAAATTTAAGCGTCAAAGGTACAATTTATTGACAACAAATGCAGAGGAATCAATAAATTCTGTAATGAAGAAGGCCAAAAGGTTTCCGATGCTGGGCCTTCTGGATATGTGTGTCTCCAAGACCGTGGAATGGTTCAATAGATATAGAGTTGAAGCAGGATGTGCCGATGATTCACAAAAAATGACACCGCATGTTGACAAAGTGCGCCATAAGAGGTATGAGACTGCATGTACGTATGAAGTCATTGTGCTAAACACTGTTACAGAGGAGTTTGAAGTGATGGGTGAAAAGGGTAGAAAACACTTTGTTAGCATTGAATGTAGAACGTGCAGTTGTAGGGTGTTTGATATCGATAAGATCCCATGCAGCCATGCAATTGCAGCACTTCATAAGGTTGGTAAAGCGAATGTTATACTAGACTTATGTTCTCCATACTATACACGGGAGGCATGGCGTCTTGCCTATCAGGAAACCGTGTATCCGGTCCCCGATTGCTGTGAATGGATTATCAATGACCCGGATGTTACAAATCTTGTGGAAATGCCTCCTATCATGGATGAGAAACGATAA
->XM_032257218.1 PREDICTED: Sapajus apella replication termination factor 2 (RTF2), mRNA 
-AGCGGTTTGCGTCACTGCGGTGCGCCGGAAGTGGCTGCAGATTCCGTCAGTAATCCCGGAAGTGGCTTCTTTAGGGTTTTGCTGCTGGCTGTGACTCCTGTTCTGCGATGGGTTGCGACGGGGGAACTATCCCCAAGAGGCATGAACTGGTAAAGGGGCCCAAGAAGGTTGAGAAGGTTGACAAAGATGCTGAATTAGTGGCCCAATGGAACTATTGCACTCTAAGTCAGGAAATATTGAGACGACCAATAGTTGCCTGTGAACTTGGCAGACTTTATAACAAAGATGCCGTCATTGAGTTTCTCTTGGACAAATCTGCAGAAAAGGCTCTTGGGAAGGCAGCATCTCACATTAAAAGTATTAAGAATGTGACAGAGCTGAAGCTTTCTGATAATCCCGCCTGGGAAGGGGATAAAGGAAACACTAAAGGTGACAAGCATGATGACCTCCAGCGGGCACGTTTCATCTGCCCCGTTGTGGGCCTGGAGATGAATGGCCGACACAGGTTCTGCTTCCTTCGGTGCTGTGGCTGTGTGTTTTCTGAGAGAGCCTTGAAAGAGATAAAAGCGGAAGTTTGCCACACGTGTGGGGCTGCCTTTCAGGAGGATGATGTCATCGTGCTCAATGGCACCAAGGAGGATGTGGATGTGCTGAAAACCAGGATGGAGGAGAGAAGGCTGAGAGCGAAGCTGGAAAAGAAAACAAAGAAACCCAAGGCAGCAGAGTCTATTTCAAAACCAGATGTCAGTGAAGAAGTCCCAGGGCCATCAAAAGTTAAGACAGGGAAGCCTGAAGAAGCCAGCCTTGATTCTAGAGAGAAGAAAACCAACTTGGCTCCCAGAAACACAGCAACAAATGAGAGCTCTTCTGGAAAAGCTGGGAAGCCTATGTGTGGAGCCACAAAGAGGTCCATCGCTGACAGTGAAGAATCCGAGGCCTACAAGTCTCTCTTCACCACTCACAGCTCTGCCAAGCGCTCCAAGGAGGAGTCCGCCCACTGGGTCACCCACACGTCCTACTGCTTCTGAAACCCACCCGGCCACTGCTCCTGCCCCAGAAGGCTGTCTGGTTTCCACCTAGGCGGGTCGCTGTGCACGCTGCTGTGTGTTCTTTCTGTACATCATAAAGCTGACCTGGCCAGCCTTGGAACTGGTGTGGCCACTCTTGTTGTGAGGTGCGTGTGTTCCAGGGGGGACATAGGACGGGCTGCACCGTGCCTGAGGTCTTGCTTGCTTCCACCTGCAGGTACGCTTGGTCGTTTCTATGGCCAGGAAGCCCTGCAGGCCGCACTTTTTATGCTTCCAGTAACGAGAGATCCCGGAGTCTTCACGAGAGCAGAGTTGGCACATATTAACTAAAATTATGATTTTGCTACCAGCAATAAATTAAGTAGGCCAAGTGAAACTGGGCTTTAGAAAGGGTGGATTTCAAATACACTGTGCCCACTAGAAGCTTTGAAGGGCCTCATCCCTCTGCTCCATCCCTGGGAGGAGTCCGGATCCTTGTTGGTCTAGCTAAGTACTATTAGGGGAGTCTGCCCCTAGCTCATCATTTGAAGACAGCAGAGTCTCAGTTGGGCACCAGTGATTGGGTTCAGAAATAAAGTTGGTCTGCCTCTTCTC
->MG651402.1 Priestia aryabhattai strain FJAT-46583 16S ribosomal RNA gene, partial sequence 
-TGCAGTCGAGCGAACTGATTAGAAGCTTGCTTCTATGACGTTAGCGGCGGACGGGTGAGTAACACGTGGGCAACCTGCCTGTAAGACTGGGATAACTTCGGGAAACCGAAGCTAATACCGGATAGGATCTTCTCCTTCATGGGAGATGATTGAAAGATGGTTTCGGCTATCACTTACAGATGGGCCCGCGGTGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCAACGATGCATAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGCTTTCGGGTCGTAAAACTCTGTTGTTAGGGAAGAACAAGTACGAGAGTAACTGCTCGTACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGGGAACTTGAGTGCAGAAGAGAAAAGCGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGGCTTTTTGGTCTGTAACTGACGCTGAGGC
->XR_007238697.1 PREDICTED: Ziziphus jujuba var. spinosa serine/threonine-protein kinase ATG1t-like (LOC125420078), transcript variant X3, misc_RNA 
-AAAAATAAATGGAACGCGTAAGTCAATCCTGTTGTAACCTGCGAGGTTGTTGATGGAAGAAGGGGAAAATGGAAGAAGATGGAACAACTCTCTGCAACTGCGACGGCATTAGAGTGGGAGACTATATTCTAGAATCAAAGCTTGGAGAAGGCTCTTTCTCTGTAGTTTGGAAGGCCCAGCACAGTCTCACTGGCCAACAAGTGGCTCTGAAGCAGGTCTATCTTTCAAAGCTCAATAGGCACCTCAGAAGCTGCTTGAACTGCGAGCTTACCTTCTTGTCCTCTGTTAACCGCCCCAACATAATTCGTCTCTTCCATGTCTTCCAGGCCAATAGTCCCCATCCTCCGGGAAAAAGTTGCATCTTCCTGGTCCTGGAATTTTGTGCTGGTGGGAACCTAGCTTCTTATATCAATCAGCACGGGAGAGTTCAAGAACAAATCGTTGGAAGATTTATGCAGCAGCTTGGGGCTGCTTTAGAATTACTTCACTCTCACCACATCATTCACAGAGACTTAAAACCAGAGGTAACATCCGTACTATCAGGGGCACTGAGGTTCATTTCTTCAATGCTTTTTGGAAGCTTGTTTTGGGAGTTTTTACAATTAAACAAGTACTTACACCAAGTGCCAACCTTCAGTTTGAAGATTTTAGAGCGCAAAGTTTGGAAAAATCTAAGGATTTTTAACAATTTCATGATGAAGCTTTGGTAAAATTTCGAGCTAAAAAGAAAAAAGCCTACCAAGAAGAAAAGAAGCAAAAGGGTCGTGCAACTTTATTCTAGGCACTAAGGCTAATTTCTTCAATACTTTTTCAAAGATTGTTTTGGGAGTTTTTACAGCTAAACAATTACTTGCATTCAGGGTTGTTGAGCTTCAATGTGTAAAAGATGGAGTAATTTGGGTTTATGGTAAAAGAATTAAACAATCTTTTGAGGAGAAGAGCTTAAGCATCCAATTCTTTCATCACTTAGCTTTATCTAGCGAGAGAGGTAAAACCAAGCTCTTATTAGGATGCAACCCAAATGTCTCTTACAATTTCTCTTTATTTTTAAGTTTAAGTTTTTATTTTTGAAATTTAAAGTTTGAGTTTGATCATTTTAGTTGTTTTCATAATTAGTAGAATTTATATTTTTGAATTCCATCTTGTTTGACTAATTTGGGTTTATGGTAAAAGAATGAAGCAATGTTTTGGAGGAGAAGAGCTTAAGGATCCAACTTTTTCATCATTTGGCTTTGCCTAGCCAGAGAGGTCAAACGAAGCATTTCTTGAGAGGCAACCCAAGTGTTTCTTACCATTTCTCTCTATTTTAAGTTTTTGTTTTTGAAATTTGAAATTTGAGTTTGATCATTTTAGTTGTTTTCATAATTAGTAGCATTTATATTTTTGAATTTCATCTTTTTGGCTAGTAAATTGGGAGTTTAAAACCTCAAATTTAGATGATTAAGTTGGTCAATCAAGAAGTATTCAAGAATGGCACAAAGTTAATGACCAAGGTGATCTAAATGGGGGTCATCTCACTCATCCCCGGAGAAACAACCTGGATGGGGC
->XM_053020070.1 PREDICTED: Gossypium arboreum probable pre-mRNA-splicing factor ATP-dependent RNA helicase DEAH9 (LOC108487114), transcript variant X2, mRNA 
-TATTTGGGCTTAGAAACCCTAAACCGAAGCGAGAGCGAAGCTAAATAAAAAGCCCGTTTAGTTACATTACTGAATTTTGATTCAATTTCCCTCGAATCGGGAAAAGTAAAACTGAGCTTAAAATTATGGCGCAGTTCTGGAAACCGGGAACCGAGAAGCCCCGCCTCCTCGAGGACGAGGATGGCGGTGTTATTTTCTTGTCATCTTCTTACTCTTCATCTTCTTCTGGATATGGGTATGTGAGCATTGAGAAGCAAAGACAGAGGCTTCCAGTTTATAAGTATAGAACTGCTATTCTTTATTTAGTGGAGTCTCACGCTACTACCATTGTTGTTGGTGAAACGGGTAGTGGTAAAACCACTCAAATTCCACAGTTTTTAAAAGAAGCTGGTTGGGCTGATGGTGGGCGTGTTATAGCTTGCACGCAACCAAGACGACTAGCTGTGCAGGCAGTTGCTTCAAGGGTAGCTGAGGAGATGGGGGTCAAACTTGGAGAAGAAGTTGGTTACACAATCCGGTTTGAAGATATCTCTAGTCCAGATCTTACTAGGATCAAATTTCTCACAGATGGAGTCTTACTTAGAGAAATGATGGATGATCCTCTTTTGACTAAGTACAGTGTCGTTATGGTGGATGAGGCGCATGAAAGATCCATTTCAACAGACATTGTACTTGGTCTTCTGAAAAAGATCCAGAAACGTCGACCGGAGCTGCGACTGATTATATCTTCTGCTACGATTGAAGCGAAATCAATGTCTAATTTCTTCCTGTCCAGTAAAAGGCGCCAAGCATTGGAAGGTGAGGAGCTTAGACCTAGGTTGGAGCCTGCTATCTTATCCGTTGAGGGTAGAGGGTTTAATGTGCAAATTCATTATGTGGAAGACCCTGTACGAGACTATGTTCAGGCTGCTGTTTCAACAGTGCTATTGATTAATGACAAGGAACCACCAGGTGATATTTTAGTATTTCTTACTGGTCAAGATGATATTGATGCTGCTATTAAGTTGCTTACTGAAGAAGCTCGAAGCAATGGGAAAAATTCCTCAGGGTTGATTATTTTGCCTTTATACTCTGGACTTACACGTGCAGAACAGGATTTGATATTTTCTCCAACTCCTAAAGGCAAGAGAAAAGTAGTGATATCAACAAATATAGCAGAGACATCATTGACTTTAGAGGGTATTGTCTATGTTGTTGATAGTGGCTTCTCAAAACAACGATTCTACAATCCGATCTCGGATATAGAAAATCTTGTGGTGGCACCCATATCCAAGGCATCTGCTAGACAAAGGGCTGGTCGAGCTGGTAGACTTAGACCTGGGAAGTGTTACAGATTGTATACAGAAGAGTATTTTCTCAATGAAATGTCTATTCAAGGAATTCCTGAGATCCAAAGGTCAAATCTTGTTTCTTGTGTGATTCAGTTAAAAGCATTAGGCATTGATAACATTCTGGGCTTTGACTGGCCGGCATCTCCATCTCCTGAATCAATGATCCGAGCACTTGAAGTACTTTATTCACTTGGAGTCCTTGATGATGATGCTAAACTTACTTCACCAGTTGGTTTTCAAGTTGCAGAAATTCCACTGGAACCAATGATCGCAAAAATTATTTTATCTTCAAATGAGCTTGGGTGTTCTGATGAAATCATAACTATTGCTGCTGTTCTCTCTATCCAGTCTATCTGGTTTTCTGCTCGAGGAGCACAAAAGGAACTGGATGAAGCCAAATTGAGATTTGCTGCTGCTGAGGGTGACCATGTTACTTTCCTGAATATTTACAAAGGGTTTCTCCAGTCTGGCAAATCTTCAAAGTGGTGTCACAAGAACTTCATAAACTACCATGCCATGGTGTGTATTTTTATTTGGGCATTTTTGAGAATTTAAGATACTGTCCAGTTTCACTCTGTTACCTGTCTTCAAGTACAAGAACATTAAAAAGGTAATGGAAATTCGGGAACTACTCAGAAGAATAGTGCTGAGGTTGGGCATAGTCTTGAAATCTTGCGAAACAGATATGCAG
->XM_020956221.1 PREDICTED: Drosophila serrata CTD nuclear envelope phosphatase 1 homolog (LOC110186899), mRNA 
-AAGCCCTGGCGATCATTGTCAGTTTTTCAAATTCTGTAAACTTGTAGAAAAATAATTAAACTCTTTTCAAAAAACCTCACTAAATTAGTTTTGAGATTATTTAAGATTCTTAATGGTATTAAGTTAATTGGTTTCAAATTTAATCATAAGCTGGTTGAAATCTTAATAAAACCATGACTGGCGACTCGTTTATGTTTTTCTCATATGGACTGATTACTTTGGCCCTGCTGCTGGCGATCATTTGCCTGTTTTTGCCCAGGGTGGACAGGTTCATCAAGTTGTCAGCGGGCAGGATATACAAGATCTATGCAGAGTACACTCCTATAGGATACATGATCGATGATTCCTTGACTCCTGTTTCCCGACGCCGTCTGCAGCGGGTGGCTAAGAAGACACTGGTGTTGGACATGGACGAGACCCTGATCACGGCCTGGATTCAGCGACAGGACAAACGTCGGCAGTCACCACCCAACGTTCCCCACGACTTTAAGTTCGTGCTTTCGGATTCCAAATATAAGGGCAAGGTCTATGTTTATAAGCGTCCCCATGTAGATCACTTCTTGAACTGCGTATCCAGATGGTATGACCTGGTGGTTTTCACCTGTGGAACGGAGCATTACGCAGCACCTATTCTCGATTTCCTTGATAATGGCCGTGGGATTTTAACCAAGAGGTTTTACCGTCACAACACCATCGATGTCGCTGGCCTAAAGGCCAAATATATATCGCTGTGTTCGCCTGACATGGCAAATGTCCTGCTGCTAGACAATTCCAATACAGAATGCAGCTTCAATGTGGGAAACTGCATCCCAATCCCATCGTATAAGATTGGGAAAAAGGACGAAGCCCTTCTCGACCTCCTGCCATTTCTGGACGCCCTGCGCTTTACAAGAGACGTGAGATCGGTTCTGGGAAAATGCACTCGCTTCGAGTGCCTTACCACGCTTCTGGAGAGTCTCGGCAATTACGATTAA
->XM_046865945.1 PREDICTED: Silurus meridionalis translocase of inner mitochondrial membrane 29 (timm29), mRNA 
-TGAATGGGACCTGCACCCTACGTAGCGCCCAGTATGTCCACTAGATGGCGATTTGGCTTCCGTCCCGGACGCACGCTGTGACTGAGACGCTAACATGGCGGCCTTGAGGAGGTGCTGCTCCAGTGTAGCTGCTGCTGCTGTCAAGAGCAAGGGGACGAGATGGGAGAGACTGTGGGACAGCCGTGCAGGTGTGTGGTGCCGCAGTCTTCTGAATGATTACAAGGAGGCGTGCCGTGAAATATTTGTTGGAGCATATGAGCGCCCTTTGAAAGCCAGCCTTTACGCGGCTTTGCTCGGAGGCACCTACGCCTGTTGCTACACCAACCCGGATGAAACTTCCTTCCAGGCACGGATACTAGAGACCTCCAACCAGCTCGCCCTCCTCTCTCCGTGGATCCGTAGCGGCACGTCTGACGGGCACGTGCAGAGCTTGGCCAAGCTGCGCAACGAGGGCCGTTTGCGACACATCAGCCTGGGTATCATCTCATTGGCATACGAGGCCGACTACGACCCTGAGTCCAGCCTGTACGAGGCAAGGTGCTCTGCGCTTTACGTACCCTGGGCACAGTTGCGAGAGCGGGTGCTGGACGTAGGCTTTGCAGGCCGTTGGTGGGTGTTGAAAAAAAAAATGGAGAACTATGATATAAATGAGGAGGAGTTCAAGTATCTTCCGCCTGTCCTGCTGGCCACAGCCCCGCCTACGGTACAGGAGACCGAGAGAAACGAAAGACTGCACCAGGAGTCCTTGAAGGCACTGGTGATTGAGGGAGAAGAATAGATGGGGGAGGGTAGCAGGTGAAGGAGAAGAGAGCAGTACACAACAGAACATTTGGTAATGTGAACAGTTCCTGATTGAGACCTGTGGACATGTCCTGTATGGTCAAATAATTTGATGTATAATGGCCTAAGAGGACGTTTCTGAAATATTTATTGTGGTGAAACATAATGCTGTTTATCCGTTTGTCTTGTGAGAAAATGAATCTTTGGAATCTTTGA
->XM_039776918.1 PREDICTED: Perca fluviatilis serine-rich and transmembrane domain-containing protein 1 (LOC120543720), mRNA 
-AGGGAGGGCAGAGACAGAGGAAGTCACAGAGGGAATGAGATTAGAGCGAGCACTACTCCCTCTCTTCTCTTCTCTCTCTTCTTTTCTCTTCACCACTTCAGTAAAAAAACCCATAATTCATTAGTTACAGCCTCTCAATTAGAGACCTTGTGTATGTGTGTTTCCTTTTGTATGTGAGCCCATTCATAGAGAGAATCCACATCTGACAGTGTCTACTCCAGCTGTAGTGCATGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTTTGTGTGTGTGTGTGTGTGTGTCAACCTGAATGACAGAAAGAGAGAGGGAGAGGGAGCGGACAGGCTCATAGGGAAGATCTCAGCAGGGGCAACAGATCTGGATTTGCTCGGCTGAAAACACCAAACACAACAGGATGGATTTCTGCACGACGTGAACGCGACCGAGGAACACCCGCATCACACATTAAAAAAGCCAGGATGTCAGGAATGGACGCGCTGTTGGTGGACCGTAATGAGACTGAAATCTCTCCAATAGACAATGGGACCTTCCTCCGTTTCTCCCCAACCTCTGCTTCCACATCTGCGGCTGCCTCGTCACCAGGACGTCCGGGCAACGTTTATGTTTACGTGTGGCTTTTTTTCGGCCTGCTGGTATTCCTCCTGACGCTGCTCATCATCTCCCTCCACAGGCTGAAAAACATCATCTCCTCCTCCTCGTCTGTTCCCGACTGCAGCAGCGAGGGAGGGAGCTCCTTCACCAACATGGAAATCTGTAGCATCTCGTCCCAGAGGTCCACCATCTCCTCACTGTCCACCTAAGGGAGATGGGATGGAGCACATACAGACACATAGACATACAGTATATGTCCATGTGCTTACATGGTAAGCATGCACACACACAAAGCCCATGGAGGTCCAGTGCCTTCTCACTGTGACATACAAATACAAAAACACTTTTTCAGCCACAAAGAAGCGGACAGCATGGCATTATAGTACATTCCGTGCATGTATATTCTATTTCCGGTGGTCCAGTGAGTCAGGTATGTCCATGCGATTTGCATAGGCACAGGTGAAATATAGCTCACAATGTGATGAAGAGGTATTGAGGGTTGAGACTGACTGAACCCCTTTGAGCCTTATTTCAACGACAAAGACAGATGAACCTGAGAAACTGCTCTTCCTCAGCAGGAAAAAGCATTGGAACTATTGTCTTTCTTCACTGTTTTTGTAAAGGTAATTTATTGTACTGTACTTGTCATATTTACTGTGGAACAAATAATATTGCTTTATAGTGCGTACAGCATGTCTCATAATGTCTGTAGACTACAGTACATTGCCAAATCAGAATTACAATAATATTTAAGACCATACATTGTACAGAAATGCATGCTTGTGTCTCAGTTGTTCAGTAAGGCTTTGGGAACTTTTTTTTTTTTTTTTTACCACTTGGCAAATTTCTGTATGATGCCCCTGGGGAAAGGACAAGACATACTGCTGTGGATGTAAAGGTGAGAAAGAAATGAGGGCTGTCTCTTGGACTCTTGACAGACAGTCTGACTGCAGCTATAGACCAGGTCAAAACTGGCATAAACAACAAGATGAAATTCTGGTCCTGAAAGACAGTTGCAGTCTCCATAGTGACTGATGCTCTGAGAGCTCTGTGCAGCTGTCAGCCTTGTCTGTATTCCAAGTATAACTACAATAATGGTTGTTTTGGCTCAACATACATCATTTTTGTTTTAATACCGTAAAATGTTTCTTTGACATGGCAACAAAAATACACACTCGAAACAAATTATTAGAAAAAGATTCATTCATCTTTGTCACACTTTGCCATAAAATTCAATATGAACTGATGGCTTGTAGAGCAGCGATGACGGCTACGAGGCCACGGACAATACAAGGAGTCATATCTGTCAGTGTTCTTATCAACAAATCCTAATTTTTTTCAGTTGATGGTACTGTGTCAGCCAAACTCTTTGGTTCCCCAATCACAGTGTTGACTATTGGTTCATTATCTCAGCTGTTGACAAACATGTATGGTTATTATGTCTAGAACCTGTTTGGTTTAAAGTACAAAAGATGTTTTAAATAATAGCTAAATGTTGGTTTTCAAGTTAACCAGGAAGTAAACTCTTTGTTTTAGCCTGGTGATGTTAAAAGAATAACCCCCTGATTGAACCCCCTGACTGTGTTTTGTTATATTAAAGCTCACATTTTCAGTTCTAGTCCTGCAAACACAAATCATTCAGTGAAAGTAGATTCAATTATTTTCCTTGCATGATTTACTGTACTGGATGTAACTGCAAAGCTGACTTTTGTCCCTGGATTAAATGAATGCAACTAAGGATTCCATCCTCTCTTACACATTGTACATATTCTCTTTTTTCATGCTTGTAAGGGATGTGTTCCTACTTGTATCTCTATTTGATTACTGGGTCTGCTGCATAAGGTGCTTTAATATCCTGTTAACGGAAACTCCCAGCACCATGAGCCCAACAAGTCTACAGCAACTTGTGACGCATGCAATTAACCAAACTCACACCTGAAACTTTACACAGTTTATCTTTAAGAAGCTCCACAGGAGAGGCTTTGAGTTACATGACTTGCTTAAGGGAACTTGAGTTCTTTCATTGATTCGATTTAAGCAGGAGACAATGCAGGACCAGATCCTACAGATGGAAAAAACATACAGCTAGTGCTGGAAATAGAAACTGGACACGTTGTTAAACTAACGCTGCTCTGTACGTCTTAGGTCTGTGTTCTTAGGAGGTGCTGCAGAGAATGACGGACAGTAACAGACTGAAATGTGTTTCTTGAAATCATCTGAAGAAGACTGGTGTCTAGTGAATGCAACAATAACACACCCTTGTGTGTTAAAAAGGAACCTTTTAGTGAAAAAGCATATTTGACCAATAAAAAGTAAAGTCATCAAA
->XR_006253100.1 PREDICTED: Puntigrus tetrazona uncharacterized LOC122362386 (LOC122362386), transcript variant X1, ncRNA 
-GTGTGTGAGAGAGAGAGAGTAAGAGTCCTATCATGCCTGTGTGCTGAAGGTAAGGGTTATTCCAGTCAAGCACTGAAGTCACTGAGGGGCTTGTACATGTCGGTTCTTGTCAGACGCAGCAGCTTTTTCTATCTCTCTTTCTCCCTTTCTTCCCCTATTCTTCCTGCCGGCCCGCTTTTCTTTTCTTTCTGTCTTTGTCTCTTTCCATCTTTCCTCTCCCTTTGAGTCCTGCTCCAGTAGACCTGCAGGTTTTAATGGCTCTGTGAAACAGTATAAAAGCAGCGGGTGCATTGAGTCATTTTAGCCTGAGGACTCAGACTGACTCTGTTTGTCTTTCTGTTGCAGCTGTCACTCTGCAGCCCTCCACATTCACAGCTTCACTTAAACGCCAAAATAGAGAGATAAAATGGTCGTGGTCATTTTATTGTGCATGGAATAGCCCTCGCCTGCATCCTCGTATCAATCAGTTAAATGAGGTGCTCAGACAGGAGCACAGCATGGCAGTAATAATGGAGTAGATTCTAGAGTTGATGGCCATAAGACAAGCTGAGAGCTCACTGTGCTATGGTCAGCTACATCATTAAACACACGCATGCACTCAGCTCCGAACGCATCTAATTTGACAAAATTGCTAGAATAATAATGAATGATGTTTGCTAGACACGTCTTATCACATCATATCCTTCCTAGTATACAATTTGGTGAGGTCGGTGCAGTCAGTACTGGACTGGTGAACTTTTCCCCTTCATGAAAGCACACAGAAAGTACTTAAATTGTGAAACTTGTGATTCATTAGCCACTATAGGCCTTAGTCTGAGAATGGCCATATTTAATTTTTGACAGCAATGAACAGGAGGCTGAGGGTTAGTACATCGTGTTCAGTGGATTGTACTGTTTAACAATATACCAACTGTTCGGCTGACAAAACAACTTTCCAAAAGACAGAGACTCCAGTTTTAGTTTTAGTTGTGAACGTAATCTAGGAGCTTTGAACAGATTGTAATCTCCCACATTTCATCCTGGGAAAATTCAATATGGCATCTGCCCTGATTAAAGTGTACATGTAAATAACTAGAAATGCAGTAAATTTGGTAAGCTGGTTAGCTGTTTTGAGCTGGTCAGCAGGCTGGTTTTAGTCGGGTTTTGCCACATTTCCCAAATCATGCCAGGCTGGTCTTAGCTGGGAGACCAGCTTGAACGACCAGCTAAAACCAGCCTAGCCTGCTGGGAGACTAGCTCAAACCAGCCACTTCTAGCTTAAACCAGCTAAGACCGGCCAACCAGCCTTTCTTTTCTTCTTCAGCAGGGCTACCACTTCACAATAACAAGCTGCATAACTGACTGTTTCTTAAACGTTGGCTGTGACCGCCTTGCACAATCAAAATAAAAATGGAAGTGCCCATTCTTACTTTAAAAATAAGGACACACTCAGACATGTTTGGGTCAACTCTGGAATGTAGTGTCGCCTTAAATTGAACATTTAAACATGTTGTTGTTTTTTCAAACCGTGCAGTAGTATGTGACATTTTCTATTTGAAAGGAATGACATTTAAAAGAAATGTGTTGCCACTGGCTTTAGCATTTCAAGAAATATGTTCAAGAAACAAAATAATATTTTAACCATTTATCAGAATTTAAAAAGGAACAAAAGGCGATTTTGTTCTTGTTTTCTCAAACTGTCTAAAGTAGATGTATTAATTAATCGTCAACTCGTGAAAATAATCACGAAAACCACCAGTGACCATTTCGCTATTAAAATGAGTAAAGTGAAATGGCGGCGTCCATAATGCTGGATGGTGTTTTCACGGTTGATCCCACTTCAGTCGAGTCTAATAAGGCTTAAACGCAGGAACGCAGAACTTCGGACACCACATTTTTTTGGAGTAACTCCTCTAGAAGACGGACCGGATCCAAAACCTCCGAATAACACACGGTTCCTATCTCCGTCTATATCCAGCACCCCAGACCAGATGCTTCACAATTACCCACAATTCCCCTGGAATTGTTCCTGCCTCATTGAGTCTTCAGCCAAAGTCAGGCAACTGCAACTAGTCAAAACACACACATACACACACACTACAGGGCACAGCCTGATGTGACCGCCTCTCCCCACCCCATCTGTCAGGATGACGTCAACTCTCTTCCGTCAGACAGGTGGTATCACCTAAGACCCCCCAGCTCTGCCACTCGACACAAAGTCATCCATCACCACAGCAACAGCTCCTGTCATTGCCTGGGAAGCGAGGGACTGCTAGGGCAGATGGGAAGAGAGGCAGCCCAACTGGTCTTCCAGCATCAGGTGGTCTGGGAATGATAAAGAGAGACTGAAAGAGAAAGAGGGCATCTTCCTTTGACACCAAGAAGTTTAAAATGGGGAAAAAATAACTTTCTTTTTGACACACAGACAGTAATGACAGGTGTGTCCGTGACTGGAGCTCCCAGCTGGAAACTCCAGAAAGAAATGTCCAAAGCCTCCTCAAAAATAGTCCGAGCTGACCCTTTTTGTGCAAAACCTCTGGCCCACAACATGGACAACCCGGAGATGAAGGGTAAGAGTTAGATGTGCTTCCTAGGAAGGTTTTGACTGTGCGTGACTGGTGTTGGCTGTAAATGCATGGAAATGTTTCATCACAGGTCAGTGGCATCTTTTCTGCAAGACAGCAGTACCGTATGAATGCAAGTGACCTGAAGGAAAAATTTCAAATCTTTCAGAGTTTCCGTTGACATACTGGAGACATTTAAAGAGAGAACACTTATCAAGCTGTATTCAGGCATAGAGAATGCGTCCCACATCTTAACGACACAATGATGAAACAAAAGAGCATATTCAGTACATGTCTGATTGCACTAAAATGCCATAAAGAGAGACAAGGCATCTTTTGTTCAATTCTGTCAGGCATCAAAATGTCTGGTCCATTGCTTAGCTAAATATAGAATAAAGGAGGGCAGTTATAACACTTCTTACTGCAGTGGATATTTCTAAAGGAAGGTTTATTTTATTGAGTCTTTGTGTTGAATTATGTTGCATTGACACACACAGTCTTTTGAACATTTCCACAATTATCACCCAAATGACAAAAGTTTGTGAATATGTGTAGAGCGAATGAGAGAGAGAGAAAACTATACTATAATTGCAGAACTTTTGTATAATTGCGTACCTTAGTAGTATAAACATATATGGCTAGGTTCGTATATATTTGGACACTATACAATTTTAAACATTTCAGTTCTGTATGCCACCAGAATATAATTATAAAATAAATTAATAATAAAATATTAATAATAAGGAAAACATCAATATGAAACTGAAGTGCAGACATCAAGCTGTGATTGGAGGGGTTAAACAGAAATATAAGATGTTTGGGAATTACAACCATTTTTATACACAGCCCCCCCATTTTCTGGGGCTTAAATGGAATTGGACAAGTAAATAAATAAAATATATAAAATGTTAATTTTTAATATTTTGTTGAGAATCCTTTTCAGGCAATGACTTCCTTAAGCCTTGTTTGTTTGTGGGTCTTTTCTGCCTTTAGTTTTAACTTCATGGAAATGGATGGAAATCAGGAGATTGACTTGACAATTACAGAATACTCCACTTTTTTTTTTTTTTACCTTTAAAAGCTCCTGGGTTGCTTTTGCAGTATGTTTTGGGTCATCATCCGTTTGTACTATGAACTGCTGTCCAATCAGCTTTGCTCCGTTTGACTGAATCCGGGCAGAGAGTATATTCCATGCATGCTCACGCCATCACACTACTCCACCATTAACAGATTATATTTTATGCTTTGAATTGTGAGCTGTATCAGAGTGTATACTACAATTGCACTCCTGTCGGCAACAATACATTTGCATATTCGAGTTTTGTACTATTTAATCTGCTTCATGATTCAGGGTTTGTGTAGCTCAGTTCGTAGTGAGTTGTGCTATAAGATGAGATGCAATCATGCGAACATGGGTTTGAACCAAGAGAATGTGTGGCCTCATAAAAGGTATATGTCCTTAATTTATGGTTTTACACAATTTTTTGTAACTGGTAGGTTTGGGGGTGGGGCCAGGTGTGGTCATTGGAATGAATTACACCTAGTAAAATCTGTTTTAATCACTGTGACTTTGGTGTAAAAAGTTCACACACTGCATTTAAACAAAACAGGCATTTTGACTAGTAAGGACAGTCATATAAGTCATTTCATGATGACAGATACAACACAACACTTTTACTTTTTACGCCTGCTACAAGGACGCTTAACTTTTAAACATTAAAAAAAGGTCTTAATAAGGTACTTCCACAAACAGGCTCGTAATTGAAATATATTTTGGTCAACAGATAAAATAATAAAAACTGTACCTGTGTACAAATATGCATTGACCTAAATGTATAATTAAGAGTGCAGCTTGTTATGAATTTCTATCAAACTTATTACCGTTGTTAATTGAATTTTCTTTCAAATTTGGGATTAAAAATCACTAAGTACACTCCTCAGAAAATAGTCGTCTTTTAATAGGCACAAGAAGTGATAATTACAAATTCTAAAACTTTTTTTTTTTCAGTGTTTGTTTGTTTGTTTTAAGAACTTGAAACCTGCAGCACCAACATGCTTCCCATGAGGTAATAAAAGAATGTTTTATTTGAAGCCTTTTTATGTGTAGATCAAACCACACCATTAAAGCACGGCTTTTTTGCCTGTATGTTTCATCTCGGGTTTACACATCAACAAAGCACTAATTAGCAGATGACAATCACATCAGTCCTGTTGTCACCAGTTTAAATGACACTGACAAACATTAGGGACCAGATTATATGCTTTAAACAAACACCACTTCTGTTATTGTAATGACTTCAGAATATAATAATTGCATGCTCCCAAAAGCTACACCAAATGGCACTTTGCAAATCTGCTGGGACATTTCTATGGGTAAATTCCAGGCTCTCTGATAACCATGTAATGAAATGTCTAATGTAAGATTTACTGTAAGTTCTTATTTCTAACAACAAAAATAATATAAAAATAGCTATATTGTGATTATCAATCTAGTAATTATTCTTAAGAAATGGTGGGGGAAGATGTAA
->XM_001704125.1 Giardia intestinalis Myotubularin-like protein (GL50803_008210), partial mRNA 
-ATGGTGCTTCTTGACGGGGAATTTATCGTCTTTCAACCGTTCTTAGCTGCTACATCCATACCATCTTACACAGAAGGAAATCTATGGCTTGATCCTTCCGAATACGCAACTGCCACAACCAACTTGCCTCCTTCAAACGGGCACCTTCTGGTTGCAGGACAGCTGTATCTGAATATTGTGCTGACGAACTACCGCATGTTGCTCTTTAGAGCAATTAGTCCAACGGAATTTACTCCCTTTGCAAGTATACCCCATTTTATGGTCGTTTCTATTTCTAAGATTGGAGGAAAGAAGTCACGCGACGCCTATGGTGTGCTAATTAGCCTCATTACACCTCTACAGTTTGCCGTCTTTTTGCCTCGACATAACAAACAGCGCACTATCTTTATCGGTACGCTACTAAAGTACGCATCACCCAGGCTCACTCTGACACACCTGTTTCCTTGCTTTTCTCTTTTCACGTCTCCTAAGGCAGAGAAAGGCTGGTTTATATACGATCCATTTGCAGAGTACTGTAGGCAAGGCGTGGGGACGCCGCGTTTAGATCTAGAGAAATTCATGAAGCCCTTTGATCTATCGGTGGTCAAGCGGCCACTAGGGACGCTTGGAATCAAGGCCTCAGATGTCAAAGACGGCATGTACCGCATTGTGACCGGAAACCCAAAGCTCATGGTGTGTATTCACGAGTATGAAGAAATGAGAAAGGAAAAGGAGCGGGCGCTCCCTTGTAATCCTGGACACGTTCCCTTTTGGTCGCTCACCGACGCAAACTTTGATTACTCAGTTTGTAACACTTATCCTTTCTTACTAGCAGTTCCTAGTCGTTACTCAGGAGAGAACAATCTTGACGCACTTCAGCTCGTTGCTGGGAATCGTTCTCATAGGAGACTCCCAGTGTTGGCGTGGAAGGACAAGGATGACCGCTACGGGGTCATTCTGCGTTCCTCTCAACCCTATAACCCAACAAAGAAAAGCGATAGCAAATTTGTGGCTGATAGAGCATACCTGCAACACATATGGCAACACTACGGCGCCCTGCATAAGAAGGAGAAGCTCTTAGTGATTGATGCTCGGACAAGAGCTAACATGCAGATGAACCAGTTTGTTGGTAGGGGAACGGAGGGGTATCCCTTTGTGCATGTGGAGTTTCTTGATATACCAGGATGTCAATACATTCAACAGAGGCATATTGCAGACTGTGCATTGTTTGCCTCCACACAAGATAATTTTCAATATCATCGCTTGGGGCGCGTCGGTGGCATTACTGAGGTACTCGGAGTTGATCCGCGTAACTACATATTGCAGGACACAGAGTGGATGAAGGTAGATGAAGTACAGACGACAAGGAGTCAGCAAGATTTCGTGGCAGATAATCAGCCACCTGCTGAACTTGTTAGTAGGGATAGAATCAGGGAGGATGGCGTTGATCATGAAAGCTCCGAATGTGATATCTCAGGGGTAGAGCAGCTATCTCCAAGTATAGACTTTAACACGATTGCAGTACCGCAATATGTCGGTAATGAAAATGTTGACCATAGCTGTCAGGCGGGCTCCTCCGTTGTTATGATTAGGACAAAATGGACTAGCACACGTCAGCTTGAAGAAGTACACAGACTTGTCATTGCAGGAGCCGTTTCTATATGCGAAAACATCATTCGAGGAACTGTGGTTCTTGTTCACTGTTCGGATGGCTGGGACAGGACCGCCCAGTTAGTCGCTCTTGCGATGCTTATGCTTGACCCCTATTATCGATCTATGAATGGCTTCTTTGTCTTAATAGAAAAGGAGTGGTGCTCGTTTGGACACAGGTTTTCTTCACGGTGCGGAATTCTACAAGTTAGCAATCAGGACCAGGAATCTCTTGAAGACGCTGATAGAGGAGACCTCTCATCGAGTCTATGCAGCCCTGTCTTCCTCCAATTTCTGGAGCTCGTCTACTACCTTTTGAGCGCATATCCGTCAGAGTTTGAGTTCACCGAAGAGGTTCTCAAGTACCTTGCCTATCACACCTATAGTGCTCGATTTGGGACCTTTATCGGCGACTGTGAGCTAGATAGGCTCTTGTGCCAGCTTCCTATACGGACCGCCAGCATATGGGATCATCTGTTGGCATGTAAAGATCACTATACAAACAAAGGGTACTCGCCAGAGTCTATTCTGAAGAAAAATGGATGGGTGTATCTCAAGCTCAATTGCAACAGACAGCTTCCTGCTTGGCCAGGCTATTGGGAGCAGCACATACCTAAGCCTTAA
->XM_022698119.2 PREDICTED: Brassica napus long chain acyl-CoA synthetase 1-like (LOC106386204), transcript variant X3, mRNA 
-GGTTTGTACTTTGGTATTGTTAGGTTGACCGGGCTGGTCGCAATAAATGCCATTGTACCAATTACTCATAATAACAAAACTATGCAACTTATGTGTATATATAACAAAATTCAAGTACGGAGTACGCAGTCAGATTAATCAATGAAACTTTAGTATCTGTTTTCGCAACGATTATATATATTGTTCACAAATAATTCAATTTTATGAACATGCAAAATACGATAAAGACCCTCATTTTTAAACCAAGTTATTTCCTTTAATGATCTTTACCTATTTCACGTTTTTGTACCTAAAATTTTGAACCATTCGTCAGCTACGTCGGCGTTGGCTTCATTGTATATCTATCTCATTTATCCATCATTTCCGGTTTTTCTATCTAATACATTTCTTTAACATAAAGAAAATAGCTTCAGAGAGTTTCTCTTCAAAAAACGGAAAACAAAGAGAGAATGAAGTTTTTCGCGGCGAAGCTGGAAGAAGGAGTTAAAGGAGGAAACGGGAAGCCGTCGGTAGGTCCGGTGTACCGGAATCTTTTGTCGGAAAAAGGTTTTCCGCCTATGGATTCTGATATCACCACTGCTTGGGACGTTTTCAGTAAATCAGTGGAAAAATTCCCTTACAACAAGGTGCTTGGATGGCGTCGAATCGTCGATGAGAAGGTTGGACCGTATATGTGGAAAACTTACAAGGAAGCATACGGAGAAGTTCTGCAGATTGGTTCTGCAATACGTGCTCTGGGAGCTGAGCCTGGGTGTCGAGTGGGGATCTATGGAGTTAATTGTCCTCAGTGGATAATAGCAATGGAGATGACACATGAAGATGTGTATCTTTCCTTCTTGCCGTTGGCTCATATTCTTGACCGTATGAATGAGGAATACTTCTTTCGCAAAGGGGCTTCGGTTGGCTATTACCATGGAGATTTGAATGTGTTACGCGATGACATTCAAGAATTGAAACCAACTTATTTAGCTGGAGTTCCAAGAGTGTTTGAGAGAATTCACGAGGGAATTCAAAAGGCTCTTCAGGAACTTAATCCTAGAAGGAGATTTATCTTCAATGCTCTCTACCAACACAAGCTTTCATGGTTGAATCGTGGATACTCTCATAGTAAAGCTTCGCCCATGGCTGATTTCATAGCTTTCAGAAAGATTAGAGACAAATTGGGAGGTCGAATCAGGTTGCTAGTATCTGGAGGAGCACCATTGAGCTGTGAGATTGAAGAGTTCCTTAGAGTTACTTGTTGTTGCTTTGTCGTCCAAGGGTACGGTCTAACGGAGACTCTTGGAGGAACGGCTTTGGGTTTCCCGGACGAGATGTGTATGCTAGGGACAGTTGGTATTCCGGCCGTTTACAACGAGATACGACTTGAGGAGGTGGCTGAAATGGGCTACGACCCACTCGGGGAAATTCAGGCAGGCGAGATCTGTATAAGAGGAACATGTTTATTTTCTGGTTATTACAAGAACCCTGAACTTACTCAAGAAGTCATGAAAAACGGATGGTTCCATACAGGAGATATAGGTGAGATTCACCCAAATAGAGTACTCAAGATAATTGATCGCAAAAAGAATCTTATCAAACTCTCTCAAGGAGAGTACGTTGCTCTTGAGAACTTGGAAAACATCTACGGTCAAAACTCTGTTGTCCAAGATATATGGGTTTATGGAGATAGCTTCAAATCAATGCTTGTAGCAGTGATTGTTCCAAATCCTGAAACCGTGAACCGGTGGGCTAAAGATCTCGGCTTTACTAAGCCATTCGAAGAACTATGCTCTCTCTCGGAATTACATGATGAACACATCATTTTAGAACTGAAGTCCACGGCAGAGAAAAACAAGCTAAGAAAGTTCGAGTATATAAAAGCAGTGACAGTGGAGACAAAACCTTTTGACGTTGAGAGAGACTTAGTGACTGCGACCCTCAAGAATCGAAGGAACAATCTTCTCAAGTATTATCAGTCCGCCAACGTTCCGTTATACAGGTACAAGTCGACGAAATGTACCGAAAATTGTCGTTGAAGAAAATGTGAAAGTGTTGCATGACCATCGATGTGTGTGTTATTATTGGTAACTATGTTATGTACGTATGTGTCAATCATTGATTAAAAAAGCCTTATGCGTTCTGTAATGTTTTAATTCTAAGCTATGTTGAATAACCATTGACATCATTAATTATTATTTTTTCTTTTGTTAA
->XM_040148298.1 PREDICTED: Xiphias gladius tensin 1b (tns1b), transcript variant X3, mRNA 
-GAGGCAGAGTGAGCACAGAGGAGAGGCTGTCAGGATCCAATTTAGGTTTAGAGGAGAGACACAGGAGGAGAAAGCAAGTCAGACAGTGAGGAAAAGGGAGAAACAGGAGCCCGAGGTGAAAGAAAGTGTTTATGTTCAGGATAGTCATGGCTCTGCAACGTTGGGAAACTCTTCTCCTGCCTGGATTAGACTTAAGGAAGACCAGTGGTCTGTAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCATCATCACCAACACTCCTGTCCGTCAACATGCCGTCTGTCTCTCTCAGCCTGCCAGCAGCTCTGGCTGGACCTGCACGCACCTGGGTCTGCCTGTCCTGCATGTTCTGGCCAGAGGAGTTGGAGGCTCTTCATTCCCATACGTTCCGGGTGAAGACTTTCAAGAAGGCCAAGCACTGCAGCGTTTGTAAACAGACCATCATCCAGGACGGACTCGTCTGCCGAGTGTGCCGAATACCTTGCCACAAGAAATGTGAAGTCAAGGTGTCTTCATCTTGTGTTCCAGCAACAAACTATGAGCTGGCCCCAAGCGGTGACCTCCCTCTCAAACATGTAGACACCATGGGCTCAACAAAATCGTCAAAGAGCATGGAGTCACGGCGCAGACCATCAAGGAGTGTGAGTTTGCTGCAGGCTCTGGAAGAGAGCTACGAGTTGGACCTGATCTATATCACAGAGAGAATCATCTCCGTCTCCTTCCCCAGCAGTGTGGATGAGCAGAGTTATGCTGCTAACCTGCAGGAGGTCGCCTCCATGCTGCGCTCCAAACACGGTCACAACTACCTGCTCTTCAACCTCAGTGAGAAGCGTTATGACATCAGCCAACTTAATCCAAAGGTCTTGGACTTTGGCTGGCCTGACCACCATGCTCCAGCCCTGGACAAAATCTGCAGCATCTGCAAGGCCATGGACACTTGGCTGAGTGCGGACAGCCACAATGTGGTGGTTATACACAACAAGGGCAACCGGGGCAGAACGGGAGTGGTGGTGGCGGCCTACATGCATTACAGCAATATATCTGCCAGCGCTGACCAGGCTCTGGACAGGTTTGCCATGAAGCGCTTCTATGAAGACAAAGTGCTTCCTGTGGGCCAGCCATCACAGAAAAGATATGTAGAGTACTTCAGTGGCTTGCTCTCTGGACACATCAAGATCAACAACAAACCCTTGTTCCTTCATCATGTTATCATGCATGGCATCCCAAACTTCGAGTCTAAAGGGGGTTGTCGTCCTTTTCTCAAAATCTACCAGGCCATGCAGCCCGTCTACACATCTGGGATCTATAATGTTCAGGGCGACAGCCAGACGAGCATCTGCATAACCATTGAACCTGGTCTTCTTCTGAAAGGGGACATCCTGCTGAAGTGCTACCACAAGCGCTACCGTAGCCCGTGCCGAGATGTGATATTCCGGGTGCAGTTTCACACCTGTGCCGTTCATGACCTGGGGATCATCTTCGGGAAGGATGAGCTTGATGAGACATTCAAAGATGAAAGGTTTCCAGAATATGGAAAAGTAGAGTTTATTTTCTCGTTTGGGCCAGAGAAAATACATGGTCAAGGTGTGGACCACCTGGAAAACGGGCCGAGCGTCTCGGTTGACTACAACACACAGGATCCCCTGATCCGCTGGGACTCGTATGAAAACTTCAATCAGAACTGTGAGGACACCACAGATGAAGTCATCCATACCCAAGGACCCCTGGACGGCAGCCTCTACGCCAAAGTTCGCAAAAAGGAGTCTGTTGAAGGAACAGTCACAGCAAATGGCCTGCCACCCACTGCTGTTGAACATGCCCTACCTGCGGTTGACCATGCCTTATCAGTAAGCAGCGACTCAGGAAACTCTACTGCCTCCATCAAAACTGACCGAACTGATGAAGCAGCAGCAGTCCCTCAGGTTTCCAGAGTGAGCCAGACACACGTTCCTGTGGTTGAGGAGTCACCATCAGTCCATCACCAAGCCCCACCTGCGCAACAACCAATTAGTCCCCAAGAGAAACAGGAGCTGGAGCAGCTGCTGAGTGGCTTGGAGGGGCCCATGCACCAACAGGGCTACCTGTCCACCCCAACATCAGCTGTTGGAGGGATGCTTCACCTGGTGCCTGCTCAGGTCCATGTCAATGGGCACACTAGCATTGACCGTGAAACAGACATTTTAGACGATGAGCTACCTACCAGTCAAGAGGGCAATAGTGTGGACAGTCTAGGAACATTCTCCTCCACAGATGGTAGGGCTACACCAGCTGATCTGTACTACCAGACTGAGTCCCTTGTCAATGGCCAGGACCATGTGCCATATCTAGAGCGCAGCGTCCCCGAAAAGCCTCTGGAAACCGTCCAGCCACATGTTGGCATATCTGACAAACCTGTCACTTTGACCCAAAGTGATTTAGCCAAATCATCTGGTACTTACATGGCCACCCAGAATGGCAGTCTGTACCGTTCTCAGTCATTTGGTGCAGAACCAAAATCTATGCCACAAGCTCCAACCCGCACCACCAGTAGCAGGGATGCCGTCCAGCGTGGTCTTAACGTTTGGCAGCAGTTTGGTGTACCTGATGAGCCAGTAACTGAAGGGTTCACTTTTAGTCCACCTCCTTCTGTAGCAGTGATGCCCAGCCACCACAGTCTCCCACAGTTCCCTCATCGCCACAGCACCTCCCAGCAAGAAATTGAGCAATCTATTGAAACCCTTAATCTCCTCATGTTGGACCTGGAACCAGGGTGTTCGCTGGTGCCAAAGTCCCAAAGTGCTCCACTGCGGGAAAACAGTGTTGTAGTGACCACCCAGCCGTCCTTTTCCCAGAGCCAAACCAGGCCCACCTACCAGGGTGATGCCGCCATTCATACCCACTTTTCGGGTCCCATGTCCAGCCTGGCAAGCCACTCGTCAACAGCTCAGATGTCACCTGGGAAGCCTAGAACACCAGAGCCTGCACCTGCCCAGGGATCTCTGAGTTACAGCTCTGAAACCTCTGGAACTAGTCCTCCCTCACAAGACTCCCTTCCTGTAGCAGGCCACGTCCAGCTGAAGCCCATCAACACCTACCCTCCAAGCACACTGTCCCATTCTGCAGACATCTCTGAGGCCCAGAGAAGCCCTAGTGCTGCGTCAGCATCACTCCAGCCAAGGGACAGTGAGCCCGATGAAGTCTTCAATGTTGAAGGTCTGGTGGCTCAAAGAGTGGCTGAATACTCGGCTCGTGCCCAAAGTGTCATCCCCAGCATGACCTCTTCTCAGTCTGAGCACCGCCGTTCTCACTCCCTCCCGGGTGTCCAGGCCCGTGCAGTGTCCTTGGATGAGCCTGCAACTCTGCCTCGCCATCGCATCGTCAGTGACGGCCATTATCAAAATGGCCCTGACGACAGTCCCTCACCTGATATCCTAGTTCGTTCCCCCATTCGATGCGTTTCTCCAGAGTTTGCCAATGCCATAGCGATGAACCCCGGAGGACGGCCTAAGGAGAGAAATATGCACAGCTACCGGGAGGCCTTTGAGGAAATGGAAGGAGTCCCCATTAATCCTACACCCACAGTTGGTGGTGAGGTGTTTCCCCAAACCCCTGCCTTCCCCATCTCGCCGCAAACCCCTTACTTCAACCTGTGTCGGTCCCCTCCTGGTCTTGCCAAGACTCCGCTGTCAGCCCTGGGATTGAAGCCCCACAACCCAGCAGAAATCCTCCTGAATCAAACAGGCTCAGATGATGAGAGCAGTGAGGGTGAGGAAGCACCAAGAAGCTATGTTGAGTCTGTGGCGAGGTCGGCAGTAGCAGGTGGAGAGCAGCCCACATCACCTCTGAGCCTTAGCCCACTGGGAGAGACTACAAGCCAGCAGAGAGGTCCAAGTCAATCGACCCACACACTGAACCCACCTTTGTCCAGCAGCAGTCCCTTCCAGAGCTCACAGGGTGAACACCCCTCAGCACACTGCAATGTTAGCACTCCGTCCCAACCCACTACTGATTCGAGCTTCCGCTCCCAGGCTACAGAGAGTGCCTACCCCACTCCAACCCCCTCATGTCCAGCCGTGAATACTCCCACCTCTTCCTACCTGGATTCCAGCTCTCCAGCCTCTTCCTACCTTGGCACTACTACCCCCACACTGTCCTACCTTGGCCCCAACAACCTCCTGGGAAACTATGTTGCCTCAGATCCAAGCCTGTCCACCTCAGAACCCTCCCAGACCACACTCAGCCATGGAAGTCCCCATGCACAGCACTGGACCAACACCCTTAGCTCCACTCATAGTCCTGTCCTCCAGCAGCGCTCGAGTGCTAATCAGGATGGCTCCATCATGGGTCAACAAACATCAACAGCTAATGGCTTTGATGTGGGCATGCCAGGCCTCATGACAGGTGGCAGTCCCATCCTCGGTCATCGTCTGTCTCAGGGAGCTCAGAATAGCCCAGTCCTCAGCAGACAGGCCTCTTTGGGACAGGGGTCTCAGCGGAGCCCTGTCTTCAGCAGACAGCCGTCCCTGGGTCAGCCCATACAGAGCAGCCCTGTGCTCAGCCGACAGCCATCTATCACACACCCCCAAGGAAGTCCGGTTTTGGGCCGTCACCCATCTGTGTCACAGGTGTCCCAGAGAAGCCCCAGTTTGGACCGTCACCCCATGCACAGCGGTTACACCACCCCAGATGAGAGACATGGGAACCTGTCGAGACAGAGCAGCTCTTCGGGCTACCAGGGGCCACCCACTCCCTCCTTCCCCATCTCGCCTGCAGGCTACCAGGATGGGGGGATGATGGGGACGGGTGTAGGGTTCAGGCAGGGTAGCCCAGCCCCTGGTCTCCAGCCCCAGCTTCCAGAGAAGAGGCGCATGTCTAGCGACGACAGACCAAACGGAGCTCTGTCCTATGGCACGCTAAACGGAAAAATAATGTCCCCAGTGAGTGGAGGAAGCACTCCCAGCTACTTCCACACCCTCTCAGACTTCTCCAAGTTCAATATGCCCGACGAAAGCCCTGAGAGCAGGCTGAATGTCAAGTTCGTCCAAGACACGTCCAAGTTCTGGTACAAGCCAGACATTTCCAGGGAACAAGCTATTAGCCTGCTGAGAGAGAGGGAACCTGGAGCCTTTGTTATTCGGGACAGTCACTCGTTCAGGGGGGCGTACGGCTTGGCTATGAAGGTGGCCTCTCCCCCGCCCTCCGTGCATCAGAACAAGAAAGGTGACATCGCCAATGAGCTGGTGAGGCACTTCCTGATCGAGAGCAGCCCGAAAGGAGTGAAGCTGAAGGGTTGTCCAAACGAGCCTTACTTTGGCTGCCTGTCTGCTTTGGTCTACCAACATGCTATCACACCATTGGCCCTGCCCTGCAAGCTGCTCATCCCTACCACAGATCTCATTGAGGAAGCACCAGAGGTCGCAACAACAAATCCACTGGCTGAGAGGCTGAAACAAGGAGCAGTGCAGAGGGCCCCTGCTGATTCCCATGCATGCAACGTGCTCTACATCAACTCAGTAGAGATGGAGTCCCTGACGGGCCCTCAGGCTGTTGCCAAGGCCATATCTGAGACACTGGCTGCCGCCTCTCCACCTACAGCCACCATTGTGCACTTCAAGGTGTCTTCACAAGGCATCACGCTGACTGACAACCAGAGGAAGCTTTTCTTCCGACGCCACTACCCCGGCAACACTGTCACGTTCTGCGATATTGACCCTCAGGACAGAAAGTGGAACAAGCCTGAGGGAGGCACAGCCAAGCTGTTTGGGTTTGTGGCGCGTAAGCAGGGAAGCACAACCGACAACGTCAGCCACCTCTTCGCTGAGATGGATCCCGACCAGCCTGCCAGCGCCATCGTCAACTTCGTCTTGAAGATGATCGCCTCGCAGAAACAATGAGAGCTGTCAGCAAACCCTGGCGCTTTTTTTTAATGCCTTTGGTTATTTTCTTTCCTTTTAACCACAGACACTTTCTGTTTTGGAAAATTTGCGTTTGACGCACCACCTTGTTTTTCCTGCTCTTTTACATTTAGGCAATTGTGTAGCTGTGTGTGTTTGTGTATGTAAGCGAATGAAAGAGAGCAAGACAGAGTGTGTGTGTGCGTGTGTGGTGTGTTCGTGCGTATGCGGCTTGCATTCATGTGCTTTTCTTCTTGGATGGACTCCAGAATGGACCAGAGGAAGTGCAGGATGGGGAAGTGGCTGTGTGTGACAATGGGATGGGAGGTGATTTTAATCTCCCTGGCAGGGTAACTCATGGACAGGAAGAGGGAATGAAATTGTGTGTGCAAATGTTATTTTTTTAGCAATTGTTTCATTTTTATTTTTTTAAAGAAGAAGTGAAGTTGTGTGATGTAAAAGTGGGTTGTATATCTATCAGGCTTTTGACTGGTCAACCAAAGATTTTAAAAAAGTTGTCAGGGCGTGTATAGTGTGCCATTGTCAGAGGGTCAGAAGTATTTTGTAAAACAAATATGGCTGCTTAATCAAAAATACTGAACTGTTTCTTTCTGTATGTACTGGTCAATTCTGCATCTTGCAAACAATGTTTTCGGACATTTTTGCAGCTGGTGAGGTCTATGTAAATATTCTAGATTGCTTTATGAGTAGGACTGTTCTAGATGACATTTGGTGCCTGACTTTTTTTCTAATGCAGAGCTTTTTAAGAAAAAAGAAGAAGATCAATCTCACCCAGGCTGTCTTAAATATGCAAATAGCCAAACTTTGAAATAAGGTTGTTCTCCCAAATTCCACAGGTCCTTCCCTGTTCGACGTAGTAGCGTAGCTAAAGATGCAACTGATGTAATTCCTCTGAAGTGCAGCTAGAGTCTGACAAAATCGGCTAAACCTGTTTTTCGTGAATTTGCTGTATCCAAGTGAGCATCAGTAAGAAGGCCACTGAATCCTCAACAATCACGTCTCGGGATTCTGTTGGTCAGACAAGCTTCCTGTCTGCCACCATCCTCTGTTCAGTCTGCACAGCACATAGCCACACTATTTTGCTCATGATTGAAGGGCCAAGGGTTGTTTTATGGGGACAATCTTAATAGAGAAGTGTTGTCCTGCTATACTGCTCTTCAGTTTTCTGTGTTGAAAGTTTCCGTCAATAGAAAGAAGCTCTTTGCGTCAGCCGGCCAAAACTGTTAACACTCACACCCTACCCAAAAGTAAGCTATACATATAAATAAACATATATAGATATATATAAAAACTTCCAAACAGTGACTTAAGATATTTATTTTTTTGCTTTGTTGCTGTATCTTATCTTGTATACATGTATTATAAAGCATACACCAAGATTACTGAACGCGTGAAGAAAAAAAATGCTTTTTATTTTGGCTAAAGTCAAGAGCATTGACATATATAAGGTGTAAAGTGTGTGCATTTAAAAGTGTATCACTGTTGTTTTTGAATGTTTTTATTTCACATTATTACTTCCTTTTGTTAACCTTTTGTTTTCTTGGGGAGGCTTTTTGTTGTTTTTTTGTTGTTTTTTTTTTTTAAGAGAGGGGAAATATTTTGTATGACAGATTGTTGTTACTGAAGTCCAAATTGGAGTTATCCTAAAGTGATGCCAACAAAATTGTTTTATTAACTTAAACCTGCCTAGAAAATACGTTGTCCAATTTAAGCACTTAAATGTTGAGCTATTCTCATTGTGTTTCTACAGAAAGACGAGATATGGACGTTGACAGACCCATTTCATATCATCACTGCATGTGTGGGGGGAAGACTTGCTAGTTCCTCAATCCCCACAGCCTGGGACTGATCCTTGTACATGGAACATTATTAAGTTCAGTCAGTAGCTGCTGCCCTCATGTGGTGTGGAACGCTCATTACAAAGGAACCACTTTTATTCTAATACAGTGTTTTAGCTGTGATTACGGCAGGTCAAAGGGTAAATGTTTGAGTTAAATTTGATCACTGAGAAAATGAACTAAAACTACGTTAATTTAAATGCTGATTCTTATGCTAACTTTCTTAGAAAATTTGTTTTTTGTTTGCATTTCAAAGTCCCATTCAAGGATTGAGTGTGTCGAGATCACATCTCCTTTCTTTACGCCTGATACACTAGGATCAGTTGGCAGCATGATGTAAAATAATTAGATAAGGGTTAGTTTTTTGGGCCTACATTGACTCAAATGTACTCCTTCAAAAATATAAAAAAAATAAGAAATACAGCACTTACAGGACTTTTATATCTGACTAGAATATTCCATTATTTATTAGCAGGCTCCTGCACGCTCAAGTCAGCTTGCCACCTTAGTGCTGCTGACTGTAATGTGTACACAGTATCCTCAAGTCTTACACGACCAGTCTTTTCAGAAAGATGCCCATAGTTAGTTATCATCAGGTTTTGATTATCATGTGACGACTGTGTCTTGACTCTGCTTATGAGACAAAACAATCTATATTTTTGCCTACAAAATGCTTGTTGAGAGGACTCCCTCTTCTTCAAACTGAATGTTAGCCATTTGTTTGCCAAGATGGAAACTCCAGTGGCATCTGCCCACTTTGACAGATCAGTCTGGACTGTAGAATGTGTGTGAATGAGCTACTATGTCTGTACAGAGCTTTGTCATTTTTGATTTGCTACATTGTATGGCTTTTACTATTTCTGATGGAAAAAAAACACATTAAAAAGCAGTACAAATCAAAA
->XM_044234934.1 PREDICTED: Neovison vison P2Y receptor family member 8 (P2RY8), mRNA 
-GCCAGGATGGATATGAACATGACCCGGCCGGACAACGCCACCATCGTGATGCTGCGCGACCCGACCATCGCGGTGGTCCTGCCCGTCGTGTACTCGCTGGTGGCGCTGGTCAGCATCCCGGGCAACCTCTTCTCCCTGTGGGTCCTGTGCTGCCACATCGGGCCCAAGTCCCCGTCGGTCATCTTCATGATCAACCTGAGCGTCACGGACCTGATGCTGGCCAGCGTGCTCCCTTTCCAGATCTACTACCACTGCAACGGGAACCACTGGGTGTTCGGGGAGCTGCTGTGCAACGTGGTCACCGTGGCCTTCTACGCCAACATGTACTCGTCCATCCTCACCATGACGTGCATCAGCGTGGAGCGCTTTCTGGGCGTCGTGTACCCGCTGGCCTCGGCGCGCTGGCGCCGGCGCCGCTACGCCGTGGCCGCCTGCGCCTGCGTCTGGCTGCTGCTGCTGGCCGCGCTGTCCCCGCTGGCGCGCACCGACCTCACCTACACCGTGGAGGCGCTGGGCATCGTCACCTGCTTCGACGTGCTCAAGTCCACCATGCTGCCCAGCGTGGCCATGTGGGCCATCTTCCTCTTCACGCTGTTCATTGTGCTGTTCTTCATCCCCTTCGTGGTCACCGTGGCCTGCTACACGGCCACCATCCTGACGCTGCTGCGCGCCTCGGACCCGCACGGCCGCGGCCAGCGGCGCCGCGCCGTGAGCCTGGCCGTCGTGGTGCTGCTGGCCTTCGTCACCTGCTTCGCGCCCAACAACTTCGTCCTGCTGGTGCACATGGTCAGCCGCCTGTTCCTGGGCCGCAGCTACTACCACGTGTACAAGCTCACGCTCTGCCTCAGCTGCGTGAACAACTGCCTGGACCCCTTCGTGTACTATTTCGCGTCCCGCGAGTTCCAGCTGCGGCTGCGGCGCTATCTGGGCTACGGGCGGCTGCAGGCCTGCGGCCGGGACGCGCGCAGGGATCCCCTGTTCTCTGCCCGGACGCTGTCGGCGCGCTCCATGTCCAGCGGCCACGGCGACGGGCTGGACGGCCCCAGCCGGCCCTGCCTGCAGAGGCAGGAGAGCGTGTTCTGA
->XM_006814478.1 PREDICTED: Saccoglossus kowalevskii uncharacterized LOC102803486 (LOC102803486), mRNA 
-ATGATATCAGATAACGCGTCTACATATCTGTCTGCTGCTAATGAAATTAAACGATTATTGGATTCCCCTGAAATTCAAACCTATCTTACGAACAGACGCGTGCAATGGTCATTCATACCCAAACGAGCACCGTGGTTCGAGGGTTTTTGGGAGCGTTTGATTGGCCTCGCCAAAACTGCTATAAAGAAAGTCTTGGGTCGTTCATTCGTAACATACGACGAACTCAATACTATCATAACTGAAATCGAATCTACTCTAAACGACCGTCCCCTGACGTATGTGTCTACGGACATTGACGACGCAACCCCGCTCACTCCGTCACATTTATTAATTGGTCGCTTGGTTACGCCACTTCCGCATTTCGTCGTGGACGACGATGAATTATCTGACCCGACATTTGGAAACCGACTAGATCTCGAGAAACGCCACGCTCATATATGTAAATTACTAGAACAATTTTGGAAACGTTGGACTAGCGAATACCTCACGTCTTTGCGAGAACGACACAACAATACGGTTGGTGCAACGGACAATACAATTAAGGTCGGTGATGTTGTGTTAATGCATAGTGATATCGCTCGTCGTGTAAATTGGCGTTTAGCCACCGTTCAAAGATTAAATGTCGGAAATGATGGACTTGCACGTTCTGCTGAACTCAAGACTACCAGTGGATTTACAAACAGACCGATTACGAAACTATATCCCTTAGAAGCATGTGGGAACAACGCGCCCACGCTATCTATCGAAAAATCTCTTGCTGTGAAGTCTGTTCTACCCGGAATTAATGAAACTGTTACTCGCTGTCCACCCAGAACAGCCGCGACTATAGCCCGACTACGCATTCAGGACATGAACGATATGTGA
->XM_026561538.1 PREDICTED: Papaver somniferum uncharacterized LOC113312801 (LOC113312801), mRNA 
-ATGTTACACCATAAGTGTACTAATGGGTTGAGTAACAAAGCTTTTGACGAGTATTGTACTATATTACAGTCCACGAAAGCTTTTCTAGATAGCAGTATCCCTAAGAATTACTATGAAGCAAAAAAACAAATTCGAGATCTTGGTGTGGAATGTATTAAAATAGATGTATGCCCAAATGATTGTATGTTATATTGGAAGGATAATCGTGATAAGGAAAGGTGCGACGCCTGTGGTGAGTCTAGATGGATATCAGGTACTTGTCAATCTGGAGAAAAAGAAGCAAGTGGAAAACAGAAAGTCAAGAGAAAAGTTGCCAGGGTTTTGAGATGGTTTCCGTTAATACCACGGCTTCAAAGGTATTATATGGACCCTAAAACCGCAGAGGATATGATATGGCATGATAAAGAGCGTACCAAAGATGGTGTTTTAAGGCATCCGGCAGACTCGCAATGTTGGAAAACCTTGGACGAAAAGCATCGGGTATTTGGTTCAGAACGTCGCAATGTTAGACTCGGGTTGGCAAGTGATGGGTTCAATTCTTTTGGTGTTATGGGTACTGGTCACAGTACATGGCCAGTCTTTGTTACTTCTTATAATTTGTCACCAGAGAAGTGTATGAAGCAACCCTATTTTATCATGTTTCTGCTTATTCCTGGGCCTAAGGGTCCTGGGAATAATATTGATGTATACTTACAGCCACTAATCGGAGAGCTAAAGGAATTGTGGGAAATGGGAATTGAGACGTATGATGCTTATTCCAAGCAGAACTTCCAAATGCGTGCAACTCTCTTATGGACTATTAATGACTTTCCAGCATATACCAACCTGTCAGGATGGAGGCACCGGAGATTCTTACCTATTGGTCATCCGTTACGAAGAAACCTGAGCTCTTTTAATGGCCGCAGAGAACATGATAGTGCACCAAAACCTTTAAGCGGTGAGGATGTTCTTCGGCAGTTCCGTGGTTATCATCAAATCACTTTTGGCAAGGAAGAACATGCTGTGTGTGGGGAGAAAAGAAGGAGGGATGACAATGAGCTGCCTTATAATTGGAAGAAGATAAGCATTTTCTTCGAACTACCTTACTGGAAAGATCTTCTCTTACGACACAATATTGATGTGATGCATACCGAGAAGAACAACAGTGAGAGTTGGATAGGGACACTGTTGAACATAGAAGGTAAGACAAAAGATAACTTGAACGCTCGGGAAGATTTGAAAGTAGTGGGTATACGTGGACCACTTCACCCTGAAGCTTTGGGGAACAACAAATTCTACCTTCCTCCAGCAAAGTATACCTTGTCTTTGGCGGAGAGGAGGAAGATTTGTCAATTCTTGCGTGACATAAAGGTACCCGATAGTTATTCATCGAATATTTCGCGGCACGTTCAGGTACAAGAATGCAAGATTCCCGGGCTAAAGAGTCATGACTGGCATGTTCTCATGCAACAACTTTTTCTTGTTGCGGTGCGTGGTATCTTACACGATGACGTGACTAGAGTTTTAGTTGAGTTTTCTGATTTTTATACTCAATTATGCTCCAAGACATTGAGAATCGAAGATTTGGAGGCGCTTAAAAAAATGTATCTCACTTTGTGCAAAATGGAGATGATATTCCCTCCTTCGTTTTTCGATATTATGACACACTTGCCTGTTCATATAGCAAGAGAAGCTATAATTGCTGGACCTGTTCATTACCGGTGGATGTATCCAATCGAACGGTACTTGTACACCTTGAAAAAGTATGTGCGAAATAAAAGTCAACCTGAGGGATCGATTGCACAAGGGTATCTTGCTGATGAATGTCTGACATTTTTCTCCAGATACTTGAGTGCTGAGATTAATACAAAGTTCAACCAGATAGGGAGAAATAGTGATGGTGATGGTGCGACGACATCTAGTCATGAATCGCCTATCTTTGAAGACGCATGTCGTTCTTTAGGGAAACCAATTTTCCGAACTTTATCTGACAATGAGTGGGAGGAAGCCCGAATGTATGTGTTGAGTAATTGTGATGAAATTCTTCCGTTCATCGAGTAA
->LC340153.1 Symphorichthys spilurus mitochondrial gene for 12S rRNA, partial sequence, specimen_voucher: KAUM:I:93808 
-CACCGCGGTTATACGAGAGACCCAAGTTGTTTAACAACGGCGTAAAGAGTGGTTAAGATCTAAACTTATATTAAAGCCGAACGCCTTCAGAGCTGTTATACGCATCCGAAGGTATGAAGTCCAACCACGAAAGTGGCTTTATAACATCTGAACCCACGAAAGCTACGGCA
->MF223903.1 Uncultured bacterium clone denovo5551_560_46813 16S ribosomal RNA gene, partial sequence 
-TTTTTCCTACGGGGCGCAGCAGTGAGGAATATTGGTCAATGGGCGGGAGCCTGAACCAGCCACGCCGCGTGAGGGAAGAAGGTACAGCGTATCGTAAACCTCTTTTGTCAGGGAACAAAGGCGGGGACTAGTCCCCGGATGAGGGTACCTGAAGAAAAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATGCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGTGCGCAGGCGGCCTGGTAAGTCAGCGGTAAAAGCCCGGGGCGCAACCCCGGCTAGCCGTTGAAACTGG
->XM_024271454.2 PREDICTED: Oryzias melastigma visual system homeobox 2 (vsx2), transcript variant X2, mRNA 
-TCCAAGCATGCTGAATATCCTCCTCATCCTCGTTCCCTGCAAAATGCAATAGGAGAGGGAGTAACTGCATCCATGATCCACTGGAATCCTGAATCCTTGCAGCTGATTGGCTGCTGCGGGCTGCCTCTTGTTGGGATGGACCTGTTGGATAAAAGGAGAATTTTCTAAAGGACTATGTGATACAGAGGATGTTGTGCGGGGGACAGTCCAGTTAGACGCTTTTTTTTCAGAAGAAAAACAAACAAACCATAACGTCATGACGGGGAAACAGGGCGCCGCGCTGTCGGAAAGTTTAGAGAAAACCTCTCTGGTCGTGAACGGCGGGAGCCTCCAGCCCAAAAGCAGCAACCCTCCACCCAGATGCACCGGCTTTGGCATCCAGGAGATTCTGGGGCTGAACAAGGAGCCGGCCAGCGCGCCGAGGAGCCCTCTGAGCGCGCTGCCGGCCGGGGCGCACCTGATCGCGGCGCGGTCGGTGCTGGGACCCGCCGGCGTGGGTGTCGGGATGGGATTAATCGGCCCCGCCGGGATTCCGTCGTTCTACAGCCAACCCGCCTTTCTGGAGACGGTGCTGGCGGACGGACACGACATGCGCCTGCAGCCGCACAACAGGTCTGCGAGGCCGCTGGACGCCAGCCAGTCCGTCAGCTCAGATTCCGAAGATTTATCTTCCAGTGAACGGAAACTTTCCAAATCATCAGTAAATCAAAGCAAGAAACGCAAGAAAAGACGCCATCGAACCATTTTTACATCATACCAACTGGAGGAACTGGAAAAGGCCTTTAACGAAGCGCACTACCCGGATGTTTACGCGCGAGAGATGCTGGCTATGAAAACAGAGCTGCCTGAAGACAGAATACAGGTCTGGTTTCAGAACCGCAGAGCCAAGTGGAGGAAGAGGGAGAAGTGCTGGGGCCGCAGCACAGTCATGGCGGAGTACGGCCTGTACGGAGCCATGGTGAGGCATTCCATCCCTCTGCCAGAGTCCATCCTCAAGTCTGCCAAGGATGGCATCATGGAGTCCTGTGCTCCCTGGCTGCTCGGGATGCATAAAAAGTCCATGGAAGCAGCAACTCTCCCGGCAACAGCAAAGTGCGATGCCCCCCAGCAAGCAAGCACACAAAGGCCGGAGGACGTTGAGGCAGAGGAGAAGAGGTCGGACGGCAAGTCCAGCATATCTAAAGAGGAAATGAGGGAGAACAGCATCGCTGCACTCAGGGCCAAAGCACAGGAGCACAGTGCCAAAGTGCTGGGGACAGTTTCTCATGACAAACTGCTGGAAGGCAAACAGGAGAAACAGGCGGTTGGGGAGAAGGTCAGTGACCCACCGAGCCCGTCAGAGGAGCAGAAAAGTCCCTAAAGAAACACATTTTGTGAATACTGTGGACCGACAGCTGTCGAAGCAAAAACAGACTCAATGATCTCCACTAAAGATATATAGCCCGCATCCAGACCGCTCTGAAGGAGAACTTTGATGATTCTTCTGCTGCACAGAAGTTGAAATTCGCACTTTTTCTGGTTTGCTTCTGAAACCCACTCTTGTCTGCAGTAGAGGAGACTGAATAAAAGTAGGAAATGATGTACAGAAATGAGACAATTAAAGGTTGAATCAATGGATCAGCTTAAGCACATACAGGAGGAGGAATTAGAAATTAAAGTGTGCAAAAATATGTTCCATTTCACATTTATTCTAAACCTGCTTGTACAATAAATGTGACATTTTAGAGGAGACCCATCCCACTGACAGTAAGAAAGTCAATGTTGTCTTACATGCCGCTGTATAAAAGTGATTTACAACGAAGGCACAACTTTTAAAGAACATTTTCTTCTTGTCTTAAAATGTCTGTGTTTTAATTTTAAATATGTAGAGGTCAAATTTCAAAGCATA
->XM_039993337.1 PREDICTED: Panicum virgatum casein kinase 1-like protein HD16 (LOC120708211), mRNA 
-ACGGGAAGGCTTCAAAAAGCCAGCACTCCTCCTCTCCCTTCCAGACAGCCAGCCAGCCAGCCACAGCGCAGCGGTGTGTGTCTGCGGGAGAGACCAAACACCAACCTCCCACCATCCCGACCCATCCCTCCCCGCATCCCCACCTCGCCGCCGCCGCCGCTGCCGCCCGCACGGTCTCTTCTCCCGAGATTCGTTGGCGATTGGAAGTGCATGGGGAGAAAGGATGCCAGAGTTGCGTAGTGGAGTCCGGCAATCTCGGTTGAGGGCAAAGAAGGTTCAGGATCTCGTGGCACAGGACCCTACGGACAACTTGGTTGCTGCAGCACCTACGGTGGCAGGAAGGCGTGGTAGAGGAAGGGGTGGTAGGGGTGGAGGGAGAGGAGCAGCACGGGGAAGGGGAGGAAGAGGGCGAGGTGTTCCGGTGATTGACTTGGACCCCGACCAACCTTGTGGGGTTTTTCCAGGAGCTGCTCTGGGTGGTCGTGCTGCAGGTAGGGCACAGCCCATTGAGGAATTTGCTGATAGGGCTTTGAAGATGGATGGTGGGAGTGCTGAGAAGATTGCTGGCGGTGAAGATGATGGGACTGTAACCCCTGTCCCAGAGAAGGTTCAAGTAGGTCATTCTCCGCAATACAAGGTAGAGCGGAAGTTGGGCAAAGGTGGTTTTGGTCAAGTTTATGTTGGCAGAAGGATTTCTGGAGGAACAGAGCGTACCGGACCTGAAGCTTACGAGGTTGCTTTGAAATTTGAGCACCGCAACAGTAAGGGTTGCAATTATGGCCCTCCATATGAGTGGCAAGTTTATAGTGCTCTGAACGGTTGCTATGGTGTACCTTGGGTTCATTACAAAGGCCGGCAAGGGGATTACTATGTTCTGGTGATGGATATTCTAGGACCTAGCCTTTGGGATGTCTGGAATTCATTTGGGCAGACGATGACAGCTAATATGGTCGCTTGCATAGCTGTAGAAGCAATTTCTATACTTGAGAAACTCCATGCAAAAGGGTTTGTTCATGGAGATGTTAAACCTGAGAATTTTCTACTTGGCCAACCTGGATCACCTGATGAGAAAAAACTTTTTTTAATTGATCTTGGATTAGCATCTAGATGGAAGGAAGGAGGACCATCTGGGCAACATGTTGAATATGATCAGAAGCCAGATATTTTCAGAGGTACAATAAGATATGCTAGTGTCCATGCCCATTTAGGACGTACTGGTAGCAGAAGGGATGATCTGGAATCATTAGCATATACGTTGATATTTCTTCTCAGAGGGAGGTTACCGTGGCAAGGCTATCAGGGTGAGAACAAGAGTTTTCTTGTTTGCAAGAAGAAAATGGCTACGTCTCCAGATCTACTATGCTGTTTTTGCCCACCTCCATTCAAACTCTTCCTGGAGTCCGTGACAAATATGAGATTTGATGAAGAACCAAATTACTCGAAGCTTATTTCCCTTTTCGATGAATTGATTGAGCCCCAGCATTTGAGGCCTATTAGAATTGATGGTGCATTAAAGGCTGGACAAAAACGTGGAAGATTGCTTGTAAATCTAGAAGAAGATGAGCAACCGAAGAAGAAAGTTAGACTTGGGAGCCCAGCAAACCAGTGGATTTCAGTTTATAACGCTAGAAGGCCCATGAAGCAGAGATACCATTACAATGTAGCAGATGCCAGACTTCATCAACACGTAGAGAAGGGTAATGAAGATGGATTGTTCATTAGTTCAGTCGCATCTTCAGCAAACCTTTGGGCCCTCATTATGGACGCAGGAACTGGTTTCACATCTCAGGTTTATGAACTTTCACCCATATTCCTTCATAAGGATTGGATTATGGAGCAGTGGGAAAATAACTACTACATCAGTGCCATAGCCGGTGCAACGAACGGTAGTTCCTTGGTGGTCATGTCAAAAGGAACTCCATACACTCAACAGTCTTACAAAGTTAGTGAATCATTCCCCTACAAATGGATCAACAAGAAATGGAAAGAAGGTTTTCATGTTACATCAATGACAACTGCAGGAAGCCGCTGGGGTGTAGTTATGTCGAGGAACTCTGGATATTCTGAACAGGTAGTAGAATTGGATTTTCTTTATCCTAGTGAAGGTATCCACCGACGATGGGAAAACGGGTATAGAATAACTTCTACAGCAGCCACTGGTGATCAAGCTGCTTTTATATTGAGTATACCCAAAAGAAAGTTGATGGACGAGACACAAGAAACCCTTAGAACATCAGCTTTTCCAAGCAACCATGTGAAGGAGAAATGGGCCAAAAATCTTTACATTGCTTCAATATGCTATGGCCGGACAGTGTCATGAGGCTTGCTCGGCACTTCATCCCAAATCGGGAGAGAACATATTCAGATGAGTAGATATCAGAAAAATCAGCAATTTTTGTTGCTGGTCTCTGTTACTCTGTATGTGTAGGTAAACTGGTCAAGATGAACCACCTTACCATGGCCAGAGTAGGAGCTCAAGAAAGAAAAGGAAGGTAGGTGGAAAGCAAGCAGCCAATAAGCAGGCGTGGAGGATGTACCCGGCTAGTGGCGGTGCAGACGCCGATGGTGTCAACTGTTTTGCATCAGCGTGTTTTGCACTTTTGCTTCGCTCCTGACTGCTGTGCAAGAGTAGACAGCTTGTAGCCTCCGTTCGGAGGCAAGTCAATCTGAGAACCCATTGTGTATAGCGTATCATGTCATTGCATTTTGTTTAGTGGAAGCCAAGTTCCACGTTTCTGGAACTCAGGAAATGCTAAGTTATTGTGTGAGGAGAACAAGTGTACTGATAAAATTCGGTGTATCGATTCCATTATTTGATAATTCTCATTGCAGTAATTAATGCAATAATGTTGCATGACT
->XM_003142805.1 Loa loa hypothetical protein partial mRNA 
-ATGCTGAATGATACAGAAAATGAAGAAATTAAGGAAGATGGAAATGTTGAATTAATCATAGAGATTGATGAGAAGAAAATTGATTACTGTAGATATGATGTCGTAAATGTGATATACTATTTATCAGTGGCAGATTCCAATAATTATACAATTATTTGCATCAACCTGCTTAGTTACGGTAAAAGTCGTTCTCTAGACCGACAACACGAAGTAAATCGATGTATGAGGAATGTATCTTTTTGTGTGGAGCTTATGCAGGGGGAAGATCCTCGAACAGCAATACATATTGCTAGACAAGGAAAACAGCTCGTCAACGGTGTGATTTTGTTGGCCATAGCTGCTTTCATTGATCTACGTGGAACACGCGTTTTCCGTGGTGTAACTTTGATCAAAACATTGAATTTCTCGGAAATTGGAAACAAATTAGTGGGAAGACTAGATTGGCATTTGCCGATAAAAATGCGTACATAA
->XM_050796503.1 PREDICTED: Macaca thibetana thibetana RPGR interacting protein 1 (LOC126958262), transcript variant X8, mRNA 
-AGTAGGACTCAAAAGTTCCAAGGCAGTTGGTAAATGACAGTTATGAATAAAGCAAGGGGCAGAAAAAAACATGTAGGGGAATGAATGAGGAACTAGGTCCAGGAGATGCTGAACCTGGATAATAAAGACGTCATATCACACACCTTGGGGTATCCATCTGAGAGCTTGCTTTCTGTTGTCAGCATGCTGGACAGCAGTAGTCAGCCCCACTGGAGCAACGAGCTCATAGCAGAACAGCTGCAGCAGCAAGTCTCTCAGCTGCAGGATCAGCTGGATGCTGAGCTGGAGGAGAAAAGAAAAGTTTTACTTGATCTGTCCAGGGAGAAAGCCCAAAATGAGGATCTGAAGCTTGAAGTCACCAACATACTTCAGAAGCATAAACAGGAAGTAGAGCTCCTCCAAAAGGCAGCCACAATTTCCCAACCTCCTGACAGCCAATCTGAAGCAGCCACTCACCCAGCTGTGTTCCAAGACAATACTCAGATCCAGCCAAGTGAACCCAACAACGAAGAAGAAAAGAAACTGTCCCAGGTGCTAAATGAGTTGCAAGTATCACATGCAGAGACCACATTGGAACTAGAAAAGACCAGGGACATGCTTATTCTGCAGCGCAAAATCAACGTGTGTTATCAGGAGGAACTGGAGGCAATGATGACAAAAGCTGACAATGATAATAGAGATCACAAAGAAAAGCTGGAGAGGTTGACTCGATTACTAGACCTCAAGAATAACCGTATCAAGCAGCTGGAAGGTATTTTAAGAAGCCATGACCTTCCAACATCTGAACAGCTCAAAGATGTTGCTTATGGTACCCGACAGTTGTCATTATGTTTGGAAACACTGCCAGCCCATGGAGATGAGGATAAAGTGGATATTTCTCTGCTGCATCAGGGTGAGAATCTTTTTGAACTGCACATCCACCAGGCCTTCCTGACATCTGCCGCCCTAGCTCAAGCTGGAGATACCCAACCTACCACTTTCTGCACCTATTCCTTCTATGACTTTGAAACCCACTGTACCCCGTTATCTGTGGGGCCACAGCCCCTCTATGACTTCACCTCTCAGTATGTGATGGAGACAGATTCCCTTTTCTTACACTACCTTCAAGAGGCTTCAGCCCGGCTTGATCTACACCAGGCTGTGGCCAGTGAACACAACACTCTTGCTGCAGGATGGATTTGCTTTGACAGGGTGCTAGAGACTGTGGAGAAAGTCCATGGCTTGGCCACACTGATTGGAGCTGGTGGAGAAGAGTTCGGGGTTCTAGAGTACTGGATGAGGCTGCGTTTCCCCATAAAACCCAGCCTACAGGCATGCAATAAACGAAAGAAAGCCCAGGTCTACCTGTCAACCAATGTGCTTGGAGGCCGGAAGGCCCAGGAAGATGAGTTCAGATTGGAGTCTTGGGAACCTCAGAACGAGCTGCAGATTGAAATCACCAAGTGCTGTGGCCTCCGGAGTCGATGGCTGGGAACTCAACCCAGTCCATATGCTGTGTACCGCTTCTTCACCTTTTCTGACCATGACACTGCCATCATTCCAGCTAGTAACAACCCCTACTTTAGAGACCAGGCTCGATTCCCGGTGCTTGTGACCTCTGACCTGGACCAATATCTGAGACGGGAGGCCCTGTCTATACATGTTTTTGATGATGAAGACTTAGAGCCTGGCTCATATCTTGGCCGAGCCCAAGTGCCTTTACTGCCTCTTGCAAAAAATGAATCTATCAAAGGTGATTTTAACCTCACTGACCCTGCAGAGAAACCCAACGGGTCTATTCAAGTGCAACTGGATTGGAAGTTTCCCTACATACCCCCTGAGAGTTTCCTGAAACCAGAAGCTCAGACTAAGGGGAAGGATACCAAGGACAGTTCAAAGATCTCATCTGAAGAGGAAAAGGCTTCATTTCCTTCCCAGGACCAGATGGTACCTCCTGGGGTTCCCGTTGAAGCTGGTCAGTATCAAGCAAGGAGAAAATCTCCTCATAGGGGAGAAAGAAAGGAAAAGGAGCACCAGGTTGTGAGCTACTCAAGAAGAAAACATGGCAAAAGAATAGGCGTTCAAGGGAAGAATAGAATGGAGTATCTTAGCCTTAACGTCTTAAATGGAAATACACCAGAGCAGGTGAATTACACTGAGTGGAAGTTCTCAGAGGCTTACAGCTCCATAGGTGATGGCTTTAAAAATGAGCCAGAGGAAGAGGAAATGACATTATCCCATTCAGCACTGAAACAGAAGGAACCTCTACATCCTGTAAATGATAAAGAATCCTCTGAACAAGGTTCAGAAGTCAGTGAAGCACAAACTACAGATAGTGATGACGTCATAGTGCCACCCATGTCTCAGAAATATAAGGCAGATTCAGAGAAGATGTGCATTGAAATTGTCTCCCTGGCCTTCTACCCAGAGGCAGAAGTAATGTCTGATGAGAACATAAAACAGGTGTACGTGGAGTACAAATTCTACGACCTACCCTTGTCGGAGACAGAGACTCCAGTATCCCTAAGGAAGCCTAGGGCAGGAGAAGAAATCTACTTTCACTTTAGCAAGGTAATAGACCTGAACCCACAGGAGCAGCAAGACCGAAGGCAGTTTCTGTTCGACGTGCTGACTGGACAAGATCCTGATCAAGGACATTTAAAGTTTACAGTGGTAAGTGATCCTCTGGATGAAGAAAAGAAAGAATGTGAAGAAGTAGGATATGCGTATCTTAAACTGTGGCAGATCCTGGAGTCAGGAAGAGATATTCTAGAGCAAGAGCTAGACATTGTTAGCCCTGAAGATCTGGCTACCCCAATAGGAAGGCTGAAGGTTTCCCTTCAAGCAGCTGCTGTCCTCCATGCTATTTACAAGGAGATGACTGAAGATTTGTTTTCATGAAGGAACAAGTGCTATTCCAATCTAAAAGTCTCTGAGGGAACCACAGTAAAAAGTCTTATAAAGTTAACTTGCTATAACATGAA
->XM_032861595.1 PREDICTED: Lontra canadensis mitochondrial calcium uniporter regulator 1 (MCUR1), transcript variant X2, mRNA 
-CGCAGCTGCTGGTGTGGACTCGGGCCGGCGCGCCGCGCGAGCGGGATGAGCGCGCGCCCGGGCCTGTGACCGCCGTGGCGATGGACTGCGGCTTCGTCGCGGGCGGGAGATCGAAGCGCCCGCCGGGCCGCCGGCGGCTTGTGCTCTTCCTGCCTTCAGGCGGCTGCGGAAGCCCGGGCGGCCGCGGCGTCCCGGCGCGCTACTGCCTGTCAGCGCTGTCCGTGGGTCTGGGGGCGCTGAAGCCTCGCGCCCCGGCGGCCCCCCGCGGCGCGTCACGTGCCTCCCCGCTGCTCCTCCTCCTGCTTGTGCCCTCCCCGCGCCTGGCCACCGTCGCCCAGCGCCGGCCCCTAGCGGACCGGGAGCGCTCGCGCCTGGGGCCCTCTGTCCCCGCGGCTAGCCGCGGCGGCGCGGGAAGGTGCCTGCGGGGCCTCGCCCCGGGCGTCGCCTGGGCCGCCGGCGCCCTCCACCTGTGCCGCGGCCGAGTGGCCGCCATCACTTCGTCCAGGAGAGAGCTAAGCCTCTCGGCTGGGAGCCTGCAGTTGGAGCACAGGAGAGATCTGGAGCACAAAAGGCGAGATTTCACCTCTTGTGGGAACAAGAAGCTCTACTTTGACACCCACGCCTTAGTGTGTTTACTGGAAGAAAATGGCTTCACCACCCAGCAAGCAGAAATCACTATCTCTGCATTGGTCAAGATCACGGACGCCAACATGGATATCGTCTACAAGGATATGGTCACCAAAATGCAGCAGGAGATCACTGTTCAGCAAATAATGTCTCAGATTGCCAATGTGAAAAAGGATATGATTATTTTGGAGAAGAGCGAATTTTCGGCTCTCAGAGCAGAAAATGAGAAGATAAACGTGGAGCTACATCGATTAAAACAACAAATAATGGATGAAGTGGTCAAAGTCCGAACAGATACCAAGTTAGACTTCAATCTAGAAAAGAGCAGAGTGAAGGAATTGTACTCGTTGAATGAAAGGAAGCTGCTGGAAATGAGGACAGAAATGGTGGCATTGCATGCCCAGCAAGATCGGGCTGTCACCCAGACAGACAGGAAGATAGACACTGAGGTCGCTGGCCTCAAAACCATGCTGGAGTCACACAAGCTTGATAATATTAAATATTTAGCAGGATCTGTATTTACGTGCCTAACAGTAGCTCTGGGATTTTATCGCCTATGGATATAATAAAGTGTCTATTTAAAGA
->XM_032539735.1 PREDICTED: Etheostoma spectabile DNL-type zinc finger (dnlz), mRNA 
-CACGAGATTTGACGTCATCGGTCCGCGACACACACCATGTTGATGAAATCGTTAGTAACGTATACATCTACGCGTGTATGTCCTTCAAAACCTCACCTGTCGTGTTGGTTTTACAGACGTGTTTTGATATTTTACCTCCGGCCGATTCTTTGAGGACGATGTTGGCGGTTAACCGGTTGTTTCGCTGTTCTCGCGGTCGTTCAGCGCCGTCTGGACTCTGCGTTGTGCTCCACTGCCGTCGTCCAGGACCACCGACGACCACAGCCAGGTCGGGGCTTCTCTCCTCACAGGACCAGCGTGGTTGTCATACTTTGTTACCTGCAGACAGACGTGAAGCTCATCTTAGCGGTTATAGGGAGTTCTCAACCTGCCAGAGTATCAGAAGTGACGCTATTGGACAGATCCAGTCAAAACATTATCGACTCGTTTACACATGCAAGGTTTGCTCTACCAGGTCCACACAGAAAATATCCAAGCTGGCTTATCACAAAGGTGTTGTGATTGTGACATGTCCAGGGTGTAAGAATCACCATATCATCGCTGATAACCTCAACTGGTTTTCGGACCTGGAAGGGAAGAGAAATATTGAGGAAATCCTTGCTGCCAAAGGAGAGACTGTAAAGAGGATTGAAGGAAGTTCCGCTTTGGAGATTGTGGTGGATGAATCTATCAAAGAAAAGTCACAACATGGTGAAGACACAGAGAAATCAGACAATGAGCCAGAAAAACAGTAATGCTGTGTTCATACTGTATATGTATTTTGTAAGATGTTTATATTGAAATCCATAATAAAAACAAATATTTATATATAAATAAATGTCTTTATGAATTCTAAGCAAGGAAAAAGGGAACTGATCAAGATAGCTTTTAATATCAGGAATAGAATAGATGGAACTATAAATCCAGCTAACTGATAAA
->XM_027304875.1 PREDICTED: Coffea eugenioides probable LRR receptor-like serine/threonine-protein kinase At4g37250 (LOC113761756), mRNA 
-CCTTTTAGCCTTGTCTTCGTCCCCCGTCTCTCCTTACCATCTCTCAAACTGACTCCATTTACAATATCTCCTTAGTTTTGGTCCTTATATTTTTGGTCACCAAAACAACATCTGTGAAGTTGGTTACCGTCTCAATCGTTCTTATTTTCTCCACTTCTTCTTGCTTATGAATAGCAATGACCATCTCGGACTTCTATGAGCGCCTAATACCAAGAAACCAATGAGCAGCTGGTTTAGAATGAGAAGTTTTTTTCACATACTTTGGTGCTTTTCCACCCTGTTTTTGCGTCTTTTGCTTCCTTCTCTGGCTCTGAACGTAGATGGAACGCTCTTGCTTTCCTTCAAATACTCCATTCTCAATGACCCTTTGTCAGTGCTTGATAACTGGAACTATGATGACGAGACGCCGTGTTTATGGACTGGTGTGACGTGCGCGCAAGTTGAAACGCCCTTTGGCACGCCGGCTATGTTTCGAGTCATAAGCTTAGTTCTTCCGAACTCTAAGCTCTTGGGTTCAATTCCTGAAGATTTGGGATACATCCAACACCTCCGTACTCTTGATCTCTCTGGCAATTTCTTGAATGGGACCCTTCCCAATTCGCTGTTCAATGCTTCAGAGCTCCAAGTGCTGTCGCTGTCCAGCAATGCAATAACTGGCGGGCTACCGGGGTTCAGCGGAGGAGGACTGAAGAATCTCAAGCTCCTCAATCTCTCTGACAATGCTTTAGCTGGAAATCTCCCTCCGAATTTACCGTCTCTGCAGGAGTTAACTGTGGTTTCTCTGAAAAGAAACTTCTTTTCGGGTACTATTCCAAATGGGTTTCTGTACGTTGAAGTACTAGATTTGTCTTCGAATTTGCTGACTGGATCACTACCACTTGAATTTGGTGGAGAAAGATTAAGGTACTTAAATCTTTCTACCAACAAGCTCTCTGGCCCGGTATCTCCAGAATTTGCGAAGAAAATCCCAGCAAATGCAACTATTAATCTCTCATTCAACAACCTCACTGGAGAAATCCCTGAATCAATGGCATTATCTAACCAGCAAACAGAGTCCTTCAGGGGAAACATGGACCTCTGTGGCAAACCGCTCAAGAAACTTTGTACTGTTCCTTCAAGTTTATCGGCACCACCCAATATATCCACAACAAATTCCTCTGCTCCGGCAATTGCGGCCATACCACAGACAATCGACTCGACCCCCCTGCCAAGCTCACCGGGAGCAGCAGCAAATGCAGCCCAAAATCAAGGACAACACAGGCTAAAACCAGGAACGATAGCTGGAATTGCAATTGGAGATTTAGCTGGCATTGGAGTCCTTGCAATTATCTGTTTGTATGTCTACCAACTAAGGAAGCGAAGAGCAGATGAAGGAAGCAAAGAGATTCCACTTCCAGTAGCAGTAGATAAACAGCAGAAAGATAACGTCAAAGATTCACAGCTCTCAACAGCGAAGGAGACAACTTCAAGAAGCCTGCCCTCTTGGTCGTGCCTAACTATAAGAAATGGTGAAGAAACATCAGAGGCTACCGCCTCGGACTGCGATGATGAAAACAAGAACATGGACATTGGACATCAAATAGATCAGTATCATGAGAAGGAGCGGAGCACTAAGTACAAGAGCGAAAGGTCACTTGTGATGGTTGATGGAGAAACTGAACTTGATATCGAGACTTTATTGAAGGCTTCTGCATATATACTGGGGTCTAGTGCTGCTGCAAGCATAGTTTACAAAGCTGTACTTGAGGACGGTTCTGCATTTGCTGTTAGAAGGATTGGAGAGAGCGGTTTTGAGAGGTTCAAAGACTTTGAGAGTCAAGTTAAAGCTATCGCAAAGCTGCGCCATCCAAACTTGGTTCTGCTCAGAGGGTTCTACTGGGGAGACGATGAGAAGCTTGTCATCTATGATTACATCTCCAACGGCAGTTTAGCTAATGCCGGTTACAGAAAGGTTGGCTCATCACCTTACCATATGCCCTTTCAAGTCCGGCTAAAGGTAGCAAAAGGAGTTGCTAGAGGACTAGCATACGTCCATGAAAAGAGACATGTGCATGGCAACATCAAGCCTAGCAACATTCTTTTGACGCCAGAAATGGAGCCAATAATCAGCGATTTTGGGCTTCATTCGCTTCTACATGGCAAAAATAGCTACAAAACAGATGCCTTTTCATCTCGGCATTTCGGTAGCATGAGAAGCAGTACTAGTACTGCTACTGCTGCTACATCATCTTCTCGCGATGGGCTGCACGACCACTCTATCAATGGCAGCCCTTGCATTGCACCTGCAGGCTTCATGGGTTGCACATCACCTTATCACGCCCCAGAGTCGCTCAATAACCTGAAGCCTAATCCCAAGTGGGACGTTTACTCCTTTGGAATTCTACTGCTCGAGCTTTTAACGGGCAAAGTGTTTTCAGACCGGGAATTGGGCCAGTGGACCGCCGGCCTGCTGATGGAAGACAAGAACCGGGTGTTACGGTTGGCTGATGTGGCAATTAGAGGAGACGTGGCAAACAGGGAGGATGCCATGCTGGAATGCTTTAAGCTAGGCTTTAGTTGTGCTTCATTAAACCCGCAAAAGAGACCTTCCATGAAAGATGCGCTTCAAGTTCTTGATAGAATCCAGACTTCTCCTTCGTACTAATCATGGTGCTGGGCAAAAGCTTAAATATAGTGGAGAAAAAAGAGAAAGAGAAAGAGAAAAAGGGGCGATCGCCTTTGGTCTTTTTGACTTGGAAGAATGTCTGGCGGGAGGAATGCTTTTGTTGATAACTCGTACAAGTGTTGCAAAGTTTGACTGATGATGAATGAAATTGGTATTTGTGTAAGACAGAATTCCGACGGTCTATCATATGATATGGTGCATTTTATCTTTACTTTGTTGTTAAGAAAGTGAGCACCATAATGAGAACTTGCTTGTCTTGATAAGCGTTTGACATGCTCAGAGAAGCAGAGTAATTGCTCACTAAAGGAAAGGAGATTACAAGGAAGAATCAAGGAGCTGCAATATGAA
->XM_019217988.1 PREDICTED: Vitis vinifera uncharacterized LOC104878060 (LOC104878060), transcript variant X2, mRNA 
-CTTTAGTCTTGAGACTTTCCTCTCTTTCACCACTTTTTCTTCTCCTCTTCTCTTTTATGTACCTTATTGTCGTCACAATCTCACCTTCTCGTTCCAAACAAATTTTTTCCCCTGCTAGCTTAGAAAGTGAAAGAAACTGGAGGTAGGAAGACGAGGCTTATGGTGGCGTCTCCCCGAAGTGGAATCTAGGGCGCGGCGGAAGCCATAGGCTTGAAAGAAGGGGAAGTGAAAGGCGGAGGACTTTCGAGTTTTATTGGCCGAGAGGCTAGGGCACGGTGTGATTTGGTTCGATCTCGGTGTGGAAGCTCGGGGAATCAGCTTATTGCGTAGTGGTTTTGTGGTTGTGGGATTTTGGAAACCTTAGATTTGGGTCAGGGTTGTGTGGTTGGCTGATTAAGCTAGGGGCGGGGCTGCCCTTGCGATTGACTGGGTTTTCATGCTGTCAAAACCACTGCCTTGGGATCGGAAGGACTTCTTCAAGGAGAGGAGAGGAAGCACGAGAGGTTGGAGTCTTTAAGTTTGCTGCAAGATAGAGGACTCGCATCAGGGTTCTTGGGAGTTTGCTCGCCGGAATCGGCAGACTTGCGCCGTCCTACAGAAGCACGAGAGGTCTGAGTCTTTAGGTTTGCTGCAAGATAGAGGGACTCGCATCAGGTTCTTGGGAGTTTGCTCGCCGGGATCGGTAGACTTTCGCCCCCCTACAGGGACACTTTTCTTTGCCATGAGCAATGTTGGTGAGGTGGGTAAATATCAATACACTTGAATATGATTGTCACATCATTTGGGGGCTTTTGACTCTGGAAGATTTCTGATTAATGTCATTAAATTTTTTCTTTTTCTTTTGAAACAATATGCCCCTTGAAGACTTGCTTTGAATAAATAAGATTTTAACTTGTTTAGCATTGTCTATTGTTGTCTTATTGTATTAGAGAGAAGAAAAAATTACACCTTGATTCCATTATTCTCCTTTTCAATTCTATCTAGTTTATCATCTTTGAAAACTTGAAGACCTTCTACTTCTAGCTTTATCTTGCAGAAGGACAATGATTCCTGATCTATCTGAATGAGGTTTAACACCAAGAACCAGATCAGGCCTTGGACAACTCAGATGGAAATTAAATCTTGGATAAAGCGTCCCTGTGAGTGTACCATTGCCCATGATATATCACTGGAAAATGTTTCAAGAATGCATGAGCTTTCAGAAGCCTTCCATGCTATTTCCTTAAGACACACATGCCTCTTGTCTATCTTGGAGCAGTTTAGTAAACTGAGTTCTAGGGCCGGTGAACTCAACTTACAGGTGGAAGCTGAGAGATCTTATCATCAAACTGTACTTGCTACTTTAGAGAAACTATTCGATGAGATGATTATGGAGAAGAAACGAAATGAGTCTTCATCTCAGCCAATAACTATGGAGAAAGATGTTTGCGTTCCTACCACATCCAAGGATGCAAATTCAAATGGATTTGACGATCATGGACATGCAAATCAAAATGGTTCATACTTTATTGCAAAAGTTATACACCCATTTGATGCTTAAGCAGATGGAGAGCTCGGTCTTTCTGTTGATGATTATGTTGTCGTTCGCCAGGTACCACCTGCCTCTATTGCAAATCCATCTAGCAATAAGAGGAATGTTTGAGACCTTTTAACAGCTTATTGGAACTTTCAATGTTTTGTATTTC
->XM_024297971.1 PREDICTED: Oryzias melastigma barrier-to-autointegration factor (LOC112162223), mRNA 
-TGACTCCTCTTTCATACAAACGATCTCAACGCTCTGCCTCGTGACGTCACAAGAGGAGCGTCAACCGCCCCAGCAGCGTCCGGGTTCGGTTTAAAGTGTCCGGGGCAGAGAGCAGCGCTGACGCCTCTCAGGTGGTCACGTTCCAGTCGCCATGTCGACCACGTCGCAGAAGCACCGGGACTTTGTCGGCGAGCCTATGGGAGACAAACCTGTGATGGCGCTGTCGGGTATCGGAGACACGCTGGGGAAGAAGCTGGAGGAGCAAGGCTTTGATAAGGCCTCCGTGGTTCTGGGTCAGTTCTTGCTGCTGAAGAAGGACACAGAGATGTTCACTGACTGGCTGAAGGACGCCACCGGCGCCAACTCTCGCCAGGCCGGATCGTGCGCTCAGTGCCTGAAGGAGTGGTGCGACGCCTTCCTCTGAGACCCCGCCCCCTTTCCTGCTCCACCTGGTTCTGCTTCTGTTCTGCTCTCCGTCAGAACTGGTGTTCTCTGGATTTCTGTGAGAGAGCTCGCGGCGGCGACGCGTGTTTTATACCAATGTTTGCAGTTCACATGAATAAAAGGTTTGAATGTTTGAA
->XM_006985027.3 PREDICTED: Peromyscus maniculatus bairdii WT1 interacting protein (LOC102927739), partial mRNA 
-GCAGAGCGGCGGCTGGAGGCGCTCACGCGGGAGCTGGAGCGCGCGCTCGAGGCGCGCACGGCGCGAGACTACTTCGGCATTTGTATCAAGTGTGGGCTTGGCATCTACGGAGCGAGGCAGGCGTGCCAGGCCATGGGGAGCCTGTATCACACCGACTGCTTCGTCTGTGACTCCTGCGGGAGACGACTCCGCGGGAAGGCCTTCTATAACGTGGGTGAGAAAGTGTACTGCCAGGAGGACTTCCTGTACTCCGGGTTCCAGCAAACAGCTGACAAGTGTAGCGTGTGTGGACACCTTATCATGGAGATGATCCTGCAGGCCCTTGGCAAGTCCTACCACCCCGGTTGCTTCCGCTGCTCAGTGTGCAACGAGTGCCTGGATGGGGTCCCCTTCACCGTGGACGTGGAGAGCAACATCTACTGCGTTAGAGACTACCACACGGTGTTTGCACCAAAATGTGCTTCCTGTGCCCGCCCCATCCTCCCTGCGCAGGGCTGTGAGACAACCATTCGCGTGGTGTCCATGGACAGAGACTACCATGTGGAGTGTTACCACTGTGAGGACTGCGGGCTCCAGCTGAGCGGGGAGGAGGGACGCCGCTGCTACCCCCTGGAGGGGCATCTGCTCTGCCGCCGGTGCCACCTGAGGCGCCTGGGACCCGGCCCGCTCCCCTCGCCGGCTGTGCACGTGACTGAGCTCTGAGAAGCAGCCATCAGGAGAGACGGGGTGACCCACACCCCCCTCTCACCCCCTCCACCGAGCTGCTGTCCCTTACGCAGGGGCCGGACCCCTGCGACAAATAATCGATTTCTATTTATTCACCGTCCGTGCCTCAAGCTACTCCCCTGCTGGGTTCCAGGACACCCGCACCCTGCAGCCTCGGGACAGGCCCAGCTCCTCTGCCCAGCTCCTCTGCCTGACCTCGGCTCCCAGAGGGGCAGGGCTTGGAGGGCCTTGGTGCCATGGGGGAAGGGTGCCTTGTTTGTGTGTGATCACAGCCAGGGGGCAGTGACAACCTGGGAACACCGCGGTTTGGCCTTGATGGGTGTTTTCAGCCACAGTCCTCCACCTCTCGGGATCCAGTCTGGGCCGGTGCTTTTCCAGCATCAGTCTCAGAAGACCCTGAGCGAATTCAAAGGCAGAGAGAAAGCCCACGAGAGCTCCCAGCAGACCCCGGGAGCATCTGCGCGCACTGTATCAGGCTCCACCACAAAACTATGTGATTTGACTTAAATTAAGTTCCCCCCAAGGAGGATGTTGACATTTTCTTGAAAAGAATATAGTTTTCTTCTAAAAACTTGGA
->XR_005799689.1 PREDICTED: Rosa chinensis OVARIAN TUMOR DOMAIN-containing deubiquitinating enzyme 12-like (LOC112165159), transcript variant X19, misc_RNA 
-TAATTGTGTCCCATAGACCGAGTCACATCTCGACCTAATTGCAAAGTGGAAGACAAAACCTCTCGACCCTCTCAGTCATCTTCTTCACCACTTTCTCTTCCCCTTCTTATCCAAAATGAAAATCTTGTGCCCTCCTCACTGCTAATCCAAACCACTAATTCAATTCCTCAAGTTCCTTTCAATTTTTCGAAATCCATACCAAATCCGAGCGTCCTGACCTTGAGAAGCAGCAGCAGCGTGACGGAGGCGCCGAGGCGGTTACCTTAATTCCTAATTCTTCTTGCGTTGAGACAGGGGTTGAGTCTAGCCATCTGCGTTTCGACTTGTTCTGGGGAATCTCGAGCCTCTCATCGTCACTGTCGAAGACCTCGATGTATAGCAACAGATTTATTCCATGCCAATCGTCGTCCAGGCTCCACCAGTTTGGGCTGAACGACAAGGCGTTGCCGGTGAAATATAGTGGATTCAGAGAAGGCCAGTAGTCCTCTCCAGTCATTGTGTTTCTTCGCTCTCTTTCTCTCTCTAAATTTCCAAATTTGATTCTCACACTCTCTCTCTCAAAACCCTAACCCCCATTCTCTAGACCACAAGACTTCCGCTTCTCATTGCCGCTCGCCGTCGACCTGCCACGGCGTCGTTTCGGCTTCGTGTCGCATTATCGGTATTTCTCGGCGTTGTCGGTGATAGCCGGACGGAAGAAGGAGGGAGAGTGGGGGTTTTGGCTTTATGGGACTTGTACGACGGCGTTGGTGATTGGTCTTTGTTTTGATCAACATTCTGGCGTTTTGGCTCTCCGGAGAAGAGCTATTGGGGTATCGAAGGCTCTGTGGGAAAAGAGGTTTGTTGAGTGAAACTGCGAAGATGCTTCAAGGCTTTCCAAAGAGCAAAACATGAGCATGAGGCATTAAAGAGGCAGCTTGAAACTTATTTCCAGCTCAAGAAAGCAACCACAATCTCCTAAAAGCTGAGCTGAGAGGTACACACCAAGATTGAAATGGGGGAAAGGAATTGTATTAAAGATTTCATCTTTAGTAATTTTACTAATATCCCATCAGCTAAACTGAGTTTCAGGGATGTGTGAGCTGTTTTTTTAGTTGGGTAGTATGAATGGAAGCTATAGCAATGCAAATGTGAGCTCAAGCTCGAGTTTGAATAGCAGCTCTCATGATACCGAGGATGACCTGACCATTGCAACTGTTTTGGCAGAAGAGGAAAAGCAGAAAAATGATGGCAAGCTGGGGAAAAGACTCTCCCACTTAGATTTGATTCCGCACACTCTCAGGGTGAATGGGGAGATACCTGACGTGAATGATGCTACTCAAGACCATAAGAGGCTTTCAGAAAGTGTAAAAGTTGGAGCAGCTCAAGTCAAGTACGCTCAAAGAGATCATTCTGAAAAAGAAGTTAAAACTGGAGGACAAGCTGCTGGATGCTCCACCCGACACATTAGGTGCTGCTGTCTTGGCACTACACTATGCAAGTATGAGAGAACTTTAGTGGCAAAATTTCTCTCAATCACATTTGATTGTATCAACTTTTGCTATCTTTCAATGTAATTAGGTAGAATGCAGTAGTCATTAAACTAGCTAGAATGCCTTTTGTACGGTATGGATACAAGAATGTATATATGATTGACAAATGCTAGCTCCTTTGGTACATTAGATGGTTGAATTAGAATATTTCAATGCCTAAATCTTATATTAAGCATTATTTTTGTGCAAA
->XM_031791253.1 PREDICTED: Oncorhynchus kisutch protein-tyrosine sulfotransferase 1-like (LOC109884214), transcript variant X2, mRNA 
-AGACTCTAGTAAAGTAAGGGTGACGCGTTTGCAGCGATACAATTGAAAAGAAAGCAGTAACAAGTAATCTTGTGTGTCGGATCAGTGGAACAACAAGGGAGCAAATTGAACGGATGGAATTTACGAGTAACGGTGTTCACCTATGAGATAAGCAGCTTGATCAACTCTCTCCCGCGGTGGATCCTCTACATTTAGGCCTGATGGAGCTGGGCACGCGACAAGCGTTGACCACCGGGGAACACACAACACGCTCTGCCCCCCATCGCCGACCTTGAAAGGAGGGACACTCCGCTACTCCCAACCTTCCCTCCTCTTCCACTACCTCCTCTGGTACAACTCCCCCCTTCCTCCCTCCCTCCCTCCTCCCCGGTTCTGAAATGGTGATGGTGATGATGATGAAGCTGAAGCAGAACCTGCTGGTGGCCTGTCTGGTCATCAGCTCAGTCACAGTCTTCTACTTGGGTCGTCACGCCATGGAGTGTCACCACCGCATCGAGGAGCGCAGCAGCCAGCCTGGGGACCAAGGGGTTCTGGGGGGCCTTCAGGGGTCAAGAGGGTTGCTCCTGGGGGGTTCTTTGAGCTCCTCCACCATCCTGCGGGGCTCTGGTCCCGGGGGCCATAACCTCTCCGCTCCATTCGTCTACAACAAAGACATGCCTCTAGTATTCATTGGAGGGGTTCCCAGGAGTGGGACCACATTGATGAGAGCCATGCTGGACGCTCACCCCGAGGTTCGTTGTGGAGAGGAGACCAGGGTTATTCCACGTATCCTGGCCATGAAACAGATGTGGTCGCGGTCTGGGAGGGAGAAGATGCGTCTGGACGAGGCCGGGGTGACAGACGAGGTCCTGGACGCCGCCATGCAGGCCTTCCTCCTGGAGATCATCGTGAAGCACGGCGAGCCCGCCAACTTCCTCTGTAACAAGGACCCCTTCGCTCTGAAGTCCCTCTCCTACCTGGCTAAGATCTTCCCGCACGCCAAGTTCGTGCTCATGATCCGGGACGGACGCGCCTCGGTCCATTCGATGATCTCGCGTAAGGTGACGATCGCTGGCTTTGACCTGGGCAGCTACAGAGACTGCCTGACCAAGTGGAACAGGGCCATAGAGACCATGTACACTCAGTGCCTGGATGCCTCAGACAAGTGCCTGCCAGTGCATTATGAACAGCTGGTGCTCCATCCAGAGAAGTGGATGAGGACGCTGCTCAAATTCCTGGACATTCCCTGGAACGAGGCGGTGCTTCACCATGAAGAACTCATAGGGAAAGCAGGAGGTGTTTCCCTCTCCAAGGTGGAGAGGTCTACAGACCAGGTGATCAAGCCGGTCAACGTGGAGGCCTTATCCAAGTGGGTGGGCAAGATCCCTGTGGACGTACTGCGGGACATGCCCGTCATCGCCCCCATGTTGTCCCGTCTGGGGTACGACCCCCACGCCAACCCTCCCAACTACGGCCGGCCAGACCCCAAGGTCCTTGACAACACCAGGAGGCTTCAGAAGACTCCAGAGAAAACAAACCCCAGTTAGGAGGAGCAACCAACATGCCACACAGACAAGACGGGGCACCGATGGACAAACATCCAATACAACACCACTTTTTGGGGACCTCAGTACTCTTCCATGGACACACACACACAAACACATACGCTATATATACAAAAGTATGTGGACATTACTTCCAATTAGTGGATTCGGCTATTTCAGCCACACCCGTTGCTGACAGATGTATAAAATCGAGCACACTGCCGTGCAATCTCCATAGACAAACATTTGCAGTAGAATGGCCCCGAACTGAAGAGCTCAGTGACTTACAACGTGGCACTGTTATAGGATGCCACCTTTCTGCCCTGCTAGAGCTGCCCCGGTCAACTGTAAGTGCTGTTATTATGAAGTGGAAACGTCTTGGAGGAATCAACGTCAAAGCCACGAAATGGTAGGCCACACGAAGTCACAGAACTGGACCGCCGAGTGCTGAAGCGCGTAGAAATCGTTGCAAACACTCACTCACGAGCCCCTGGAAGTAACTTCAGCACAATAACTGTTCGTCAGGGGAGCTACATGAAACGGGTTTCCGTGGCAGAGCAGCCGCACACAAGCCTAAGATCACCATGCGTAATGCCAAGCGTCGGCTGTAGTGGTGTAAAGGTTGCCGCCATTGGACTCTGGAGCAGTGGACCAACTCCATATTAATGCCCGTGATTTTGGAATGAGATGTTCTACGAGCAGGTGTCCACATACTTTTGGTCATAGTGTATAACATCATGACTGGATATAACCGTATTCCACACTGGCTTTGTGGAGAAACTCTCTTGGCCTTTTGATGTTCGTACTGTAAACAAATGATGCATTTGTCACAAAATGGTGACCAGAGAATGTCTATGTTACTATCTTTCTTGTCGAGGGTTGCAACATTTCCCCAATTTCCTAGATTTTCCAAAAAAATCCCAGTTGGGAGATTCCTGAGATCCTACAACCAGGATTTCTGGAAAAACATGGAAATATTTAGAAAGTTACCAGAATTTTTAAAAACAATTCTCGTGACACCAAATGTTTTTTTCTTCTTTTAAATGATTTCTCCTGTAAATATAAATATATAAATCTGTGATTCTGTTGTAAGAAAATACAGTGGACTTAAACATCAAAAAAAGTGAATAATGTATTTATGGATGACATTTTGCTTTTTGAAGATGCAATATCTATTTTAATGTTTGTTTTTCATGCCTTTCTATAGTGCGATTCCATGGGTACGGATGTACAAGATCTGTTTTTAAGTATTGACAGTGATAAAAGATGGCATTTTGTAAA
->XM_031379489.1 PREDICTED: Mastomys coucha kinesin family member 1B (Kif1b), transcript variant X9, mRNA 
-ATGTCGGGAGCCTCAGTGAAGGTAGCTGTCCGAGTGAGGCCCTTCAATTCTCGAGAGACCAGCAAGGAGTCCAAGTGCATCATTCAGATGCAAGGCAACTCGACCAGTATTATTAATCCAAAGAACCCAAAGGAAGCACCAAAGTCCTTCAGCTTTGACTACTCCTACTGGTCGCACACCTCGCCTGAAGATCCCTGTTTTGCATCACAGAATCGTGTGTACAATGACATTGGAAAGGAAATGCTCTTACATGCCTTCGAAGGATATAATGTCTGTATCTTTGCCTATGGGCAGACTGGTGCTGGGAAATCCTACACGATGATGGGGAAACAAGAAGAGAGCCAAGCTGGAATCATCCCACAGTTGTGTGAAGAACTTTTTGAGAAGATCAATGACAACTGTAATGAAGAGATGTCTTACTCTGTAGAGGTGAGCTACATGGAAATTTACTGTGAGAGAGTACGAGATTTACTGAATCCCAAAAACAAGGGTAATTTGCGTGTGCGTGAACACCCGCTGCTTGGACCCTATGTGGAGGATCTGTCCAAGCTGGCAGTCACTTCCTACACTGACATTGCTGACCTCATGGATGCTGGGAACAAAGCCAGGACGGTGGCAGCTACCAACATGAACGAGACAAGCAGCCGTTCCCACGCCGTGTTCACCATTGTCTTTACCCAGAAGAAGCAGGATCCTGAGACGAACCTTTCTACTGAGAAGGTCAGTAAAATCAGCTTGGTGGATCTAGCAGGAAGTGAACGAGCTGATTCAACTGGTGCCAAAGGAACAAGATTAAAGGAAGGTGCAAATATTAATAAGTCTCTTACAACTTTGGGCAAAGTCATTTCGGCCTTGGCAGAGGTGGATAACTGCACAAGCAAGAGTAAGAAGAAGAAGAAGACTGACTTTATTCCCTACAGGGACTCTGTGCTCACTTGGCTCCTTCGAGAAAACCTAGGTGGCAACTCCCGAACTGCAATGGTTGCTGCTCTGAGCCCAGCAGACATCAACTACGATGAAACGCTGAGCACGCTGAGATATGCAGATCGTGCAAAACAAATTAAATGCAATGCTGTTATCAACGAGGACCCGAATGCCAAGCTGGTTCGTGAGCTGAAGGAGGAAGTGACCCGACTGAAGGACCTTCTTCGTGCTCAGGGGCTGGGAGATATTATTGATACATCCATGGGGTCCCTTACTTCATCTCCATCTTCATGCTCACTTAATAGTCAGGTGGGCTTAACATCTGTGACCAGTATTCAAGAGAGGATCATGTCTACACCTGGAGGGGAGGAAGCCATTGAACGTCTGAAGGAGTCAGAGAAGATCATTGCTGAGTTGAATGAAACCTGGGAAGAGAAACTTCGTAAAACAGAGGCCATCAGAATGGAGAGAGAAGCCTTGTTGGCTGAGATGGGAGTTGCCATACGGGAAGATGGGGGAACACTTGGTGTTTTCTCCCCTAAAAAGACTCCACATCTTGTTAACCTCAATGAAGACCCACTGATGTCGGAGTGTTTGCTTTATTATATCAAGGATGGAATTACAAGGGTTGGCCAAGCAGATGCTGAGCGGCGCCAGGACATAGTGCTGAGTGGGGCCCACATTAAAGAAGAGCATTGTATCTTTCGGAGTGAGAGGAACAACACTGGTGAAGTTATTGTGACCTTAGAGCCCTGTGAACGCTCGGAAACATATGTGAATGGCAAGAGGGTGGCCCATCCTGTTCAGCTGCGCTCAGGGAACCGTATCATCATGGGTAAAAACCATGTTTTTCGTTTTAACCACCCTGAACAAGCACGAGCAGAGCGGGAGAAGACTCCCTCTGCCGAGACCCCCTCTGAGCCCGTGGACTGGACATTTGCTCAGAGAGAGCTTCTCGAGAAACAGGGAATTGATATGAAACAGGAGATGGAAAAGAGGCTTCAGGAAATGGAGATCCTTTACAAAAAGGAGAAGGAGGAAGCTGACCTTCTTCTGGAGCAGCAGAGACTGGACTATGAGAGTAAATTGGAGGCCCTGCAGAGGCAGGTTGAGACTCGATCTCTCGCTGCAGAGACAACGGAAGAAGAGGAGGAGGAGGAGGAAGTTCCTTGGACACAGCATGAATTTGAGTTGGCCCAGTGGGCGTTCCGGAAATGGAAGTCTCACCAGTTTACTTCATTAAGGGACTTACTCTGGGGCAATGCCGTGTACCTGAAGGAAGCCAATGCCATCAGTGTGGAACTAAAGAAAAAGGTGCAGTTCCAGTTTGTTCTGCTGACTGACACACTGTACTCCCCTTTGCCTCCTGAATTACTTCCCACGGAGATGGAGAAAACTCACGAGGACAGACCTTTCCCTCGGACAGTGGTGGCGGTGGAAGTCCAGGATCTGAAGAATGGAGCAACACATTATTGGTCTTTGGACAAACTCAAACAGAGACTGGATCTGATGCGAGAGATGTATGACAGAGCAGGAGAGGTGACCTCCAGTGCCCAAGATGACAGTGAGACGACCATGACCGGCAGCGATCCGTTCTATGATCGGTTCCATTGGTTCAAACTTGTGGGAAGGGCATTCGTGTACTTGAGCAACCTGCTGTATCCGGTGCCCCTGATTCACAGGGTGGCCATTGTCAGTGAGAAGGGGGAAGTCCGGGGATTCCTTCGTGTGGCTGTGCAGGCCATTGCAGCCGATGAAGAAGCTCCTGATTATGGCTCTGGAATTCGACAGTCGGGAACAGCTAAAATATCTTTTGATAATGAATACTTTAATCAGAGTGATTTCTCTTCAGCTGCAATGACTCGTTCTGGTCTGTCCTTGGAGGAGCTGAGGATTGTGGAAGGTCAGGGCCAGAGTTCTGAAGTCATCAGTCCTCCAGAAGAAGTCAGTCGAATGAATGACTTGGATTTGAAGTCAGGCACTTTGCTGGATGGGAAGATGGTGATGGAAGGGTTTTCTGAAGAGATTGGTAACCACCTGAAACTGGGCAGTGCCTTCACCTTCCGGGTCACGGTGCTGCAGGCCAACGGAATCCTCCCAGAGTATGCAGACATCTTCTGTCAGTTCAACTTTTTGCATCGACATGATGAAGCATTCTCCACTGAACCCCTCAAGAACAATGGAAGAGGAAGTCCCCTGGGCTTTTACCATGTACAGAATATTGCGGTGGAGGTCACCGAGTCATTTGTGGACTACATCAAAACCAAGCCCATCGTATTCGAGGTCTTTGGACATTACCAGCAGCACCCACTTCATCTGCAAGGACAAGATCTTAATAGTCCACCTCAGCCATCTCGAAGATTCTTCCCCCCACCCATGCCACTCTCCAAACCAGTTCCAGCTACTAAGTTAAACACCATGAACAAAACCACCCTTGGGCAAAGCATGAGCAAGTACGACCTTCTGGTTTGGTTTGAGATCAGTGAACTGGAGCCTACTGGAGAATATATTCCAGCTGTGGTTGACCATACAGCAGGCTTGCCCTGCCAGGGGACATTTTTGCTGCACCAGGGCATCCAGCGACGGATCACAGTGACTATCATCCATGAGAAGGGCAGTGAGCTCCACTGGAAAGATGTTCGTGAACTGGTGGTAGGTCGGATTAGGAACAAGCCTGAGGTAGATGAAGCTGCAGCTGATGCGATCCTTTCCCTAAACATCATCTCCGCTAAGTCCCTCAAGTCTTCCCACAGCTCCAGCAGGACCTTCTACCGTTTCGAGGCTGTATGGGACAGCTCCCTACATAACTCCCTCCTCCTCAACCGAGTGACCCCCTATGGAGAAAAGATCTACATGACCTTATCTGCTTATCTGGAGTTGGATCATTGCATCCAGCCAGCCGTCATCACTAAGGATGTGTGCATGGTCTTCTATTCTCGAGATGCCAAGATCTCACCACCACGTTCTCTGCGAAACCTCTTTGGTAGTGGCTACTCAAAGTCGCCAGACTCCAACCGAGTAACTGGAATCTATGAGCTGAGCTTATGCAAAATGGCAGACACTGGGAGCCCAGGCATGCAGAGGCGGAGGAGAAAGGTCTTGGATACCTCCGTGGCGTACGTGCGGGGGGAGGAGAACCTAGCGGGCTGGAGGCCTCGTGGAGATAGCCTCATTTTGGAACACCAGTGGGAGCTGGAGAAGCTGGAGCAGCTGCACGAGGTGGAAAAAACTCGCCACTTCTTGCTGCTTCGGGAGAGACTTGGTGATAGCATACCCAAGTCTCTGAGTGACTCGTTGTCTCCCAGCCTCAGCAGTGGGACCCTTAGCACCTCAACCAGCATCTCTTCTCAGATCTCAACCACCACCTTTGAAAGCGCCATCACACCGAGCGAGAGCAGTGGCTATGACTCAGCTGATGTTGAAAGCCTGGTAGACCGAGAGAAAGAGCTGGCTACAAAGTGCCTGCAGCTTCTCACCCACACTTTCAACAGAGAATTCAGCCAGGTACACGGCAGCATCAGTGACTGTAAGTTGTCTGACATCTCTCCAATTGGACGGGACCCATCTGTGTCCAGTTTCAGCAGTTCCACCCTCACACCCTCCTCCACATGCCCCTCTCTGGTGGACTCCAGGAGCAGTTCTGTGGATCAGAAGACCCCAGAAGCCAACTCTCGGGCCTCCAGTCCTTGCCAAGAATTTGAACAGTTTCAGATTGTCCCAACTATGGAGACACCCTATTTGGCCCGAGCAGGAAAGAATGAATTTCTCAATCTTGTTCCAGACATTGAAGAAGTCAGAGCAGGCTCAGTGGTATCTAAGAAAGGATACCTGCATTTCAAAGAGCCGCTTTCCTGTAACTGGGCTAAACATTTCGTTGTGGTTCGTCGCCCTTACGTCTTCATCTATAACAGTGACAAAGACCCAGTAGAGCGTGGCATTATTAACCTGTCTACAGCACAGGTGGAGTACAGCGAGGACCAGCAGGCCATGGTGAAGACACCTAATACTTTTGCTGTATGCACAAAGCACCGTGGGGTCCTTCTGCAAGCTCTCAATGACAAAGACGTGAATGACTGGTTATATGCCTTTAACCCACTTCTGGCTGGCACAATAAGGTCAAAACTCTCTCGAAGATGCCCGAGCCAGCCAAAGTACTAAGCGGTTCTTCTGAGCCTTGCTCACCTGTGACAGATAAAGAAAGTGTTACCTCTCATTCTCTCTCTTTGTGATTCTTGACGGTTATTCTTGTATGTAATCCTGTGGCTTAATGACTTTTCCCTCCCTCGTCATCCCGCACTTCTCTAGTTCTCCTGTTCCCTCTCTCCATGGCTCTGTACTCTTCTTATTCTTGTGCTAAGACTTGTAGCATGTGGCCTAACAAAGGGGAACAAAACCACTACACATTCATATACACTCACACCCACGCACCCTGAGGGGATCCAGCACATCTCCAAATGATTTTCCTGTGTACGTTAGCTTCCTTTTGGATGATGGGTCCCCTTCATGGTCACTGTCCCCCTGTTGTTTCTGTATGGCTCTGGTTTTCAGGGTAACTTCTCTGTCTCTCTTTTTTCCCTCCTTTGTTTATGATAATCTACTTTTTTCTGGGTGGTTTAGATACTAAGGGAGGAGACGTTTGGTATTGTCAGCCAGGAGAAAAAAACTTGCTTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTGTCTCTCTTTGTGTGTGTGTGTGTGTCTGTGTCCATGTTTCTCTCTCTGTCTCCGTCTCTCTCAATGTCTCTGTCTTTGTCTCTCTCTTTGGTTGCTAATCCATGTATTTCCATTCAGGGAAAGCACTGTGGGAAGCTCAGAATTGGGATTTTAAATTCTCTGTCTAAATCAGGGCGCAGAGCATGGGCTTATAGAGAGGAAGATGCAGAAGGGCCTTTGTGATCAGCCTGCAGCAGAGGCTGCTGCAGTAGACTGCTGGAGCTCCTCACAGCCGGGTCCTGCAAATGTCTCCTCCCTGGGAAGGAAGCTTTTGTCTAGGAGTTCCCCAGCCCTATTCTCAGCATTACTGTTTAGAATTACGAGATGTCATGAACAGATTTCCCACAAGAGGGATTGGGGAATGTTTGACTTTCTAGTGATAGACTGGACCATTGTTGCTTTGAGAGTGCTGAGTGCAGCTTGTGATTGTTGTAGCTCCCTTTGATCAAAGACTTGTAGCTTCAGCATAAATCTTGAGGTCTCCATCTAAATCCAGTGGCCATTTTCAATGTATGAAATATGAGCAAACATGGCATTGTTTTTTAGATGCCAGAACTGGCCGGTCCTTACCACCACTCCAAACAAATCACAAGATATTTAGGGTTGAAAAAGATTGTGGATTGTGACATGCCTCCTGTGTGACATGCCCCTGACCCCACTATCCCCATGTGGTTTGGAAATACTCCCTTAGGAAGAATTCACTGCTCCCAGTTTCTGTGGCTTCTAACAAACCAGGTCTCTGGATTCAAGAAGTTATCATAGAAAATAACACTCTCCCTCCACCAGCTAGTCAGTGTTGGGGACTGAGTAGGGCACAGAATGCCCGCTGGAGCTACTTGAGTTGTGTGCCAGCGACTTGAGGCTCATTCACACTGCTGTGTCCTGGCTTCGCCAGCCTGCTTCAGTGCCACTCATGCACCCAGGAAGGCATCTGCTCACCTCCACTCTACAAAGGCTCCTGGCTACCTGAGGGTAGAGAAGGAATGGATTGCCTTCTGTTGGGAGCTCATCTCCACTGCAGAGCAGCCACCAGGGAGGCGAGCGAGCATGCAGCCCCTTGCTGCTGACCTCTCGGCAGGGCTTCTCTCGGAAGAACTGGTCTCCAGCTCCTTTTGTTACAGCTGCCTTGCAAAGAAAGGGAAAGTGGACATGGAGAAAAGAAAGGGCAGAAATCAGACTGTTCTTATCTAAAAGATGATCAACTCCAGTAGACTTGTAAAACTTTCTTTCTCTCCTTAAAGTATAGGTTACTAACTGTAATGTTACTTGTTTTCTAAGCATATATATGAGATTTTTAATGTAGTTAGAAGTCTCTGTTGTCTGATGGACACAACATGTCCTTCTGGTGTATACTCAAATTCAGCAGGCTCTGTCTATGCTTGTAGACAGTTTCCTGGACCGGAACTAAATATAATTTCAGGGAAACAAAGATCAAAGGTCGCTTTTAAACTGAGTCACTGATGTTGCTGCTGTTAGAAAGGTAGATGGAAGGATCCGCGTCTGTGCGAGGTGAGAAGCCTGAGGGAGGGTGAAGTGTGCGGTACACTAAACCCTGCGATGACTTGTGTTTTCTTTTAACTCAAACAAAACTGGTTTAGAAAGTCTTTGCTTTGCAAATATCAAATATTAGCATGAGCCAAACTGGACTGCCCCTTCATCAGAGGCGCCCCCCCATAAGGAGGCCTCATTAGGAAGCCAGGGAAAGGAAGGTTGGAGCTTGGGCACGTGTGCTGCTACCTGCCATCATTGGGGCCCCCCCTGACTGTAAGGCCCATGGTCAGATCAGAATCAGAGCATTTGGGGGCTTTACTTTCTGTTTCCAGACAAGGTCACCTCTGCTTCGAAGCTCTGCAAGAGAAAAGGTTTTATGGCAGGACCTGTTCATGAGATTTTTGTGGTTGCCATAGTAGCAGGAAAGTTAAGACAACTAACCTTAAAGAAACTTTTTTTTGGGGGGTGGGGGGTCTGAGACAGGGTTTCTCTGTGTAGCCCTGGCTGTCCTGGAACTCACTCTGTAGACCAGGCTGGCCTTGATCTCAGAAATCCGCCTGCCTCTGCCTCCCAAGCGCTGGGATTAAAGGTATGTGTCACCACCACCTGGCAAGAAACTATTTTTAAGGTAATTTTAAAAAAAATTTCAAAGCACTCCTTTAAACAAAAAACCTACAAGGAAAACATACAGATTACAGAAAAGTGAGTGCTGGTTGAAATGAATTAGCCTCCCCCTTCCTTCTTTATCCTCCTTCCTCCCAAGCAGATATCACTCCTAACTGTCCCCCACGCCAGTGCTCAGGCCCAGCCTGCTTCTGGGGCTCTACCCTGGGAGTCAGCCAGCTCTCAGCCCCAGACTGTCAGGGACCAGGCAGTCCCTGCACAAGGCTAGGCAGGAGCACAGGCCAGACTGCTTCTGAGCAGGCCCCTGATCTCCATCCATAAATGAGGCGAGCTAAAGCTTCCTCAGCTAGGAAACCTTTCCTCCCCTTCAGCTATATGGAATGTATATATCTATTAAATTTTTATCTTGTTTTGATGAAAGGATGAATGGTTGTGAAAGGTATTTGGGGTCTAAAACCATGATTTTTTCCTGGCACATATTTCAAAGCATAGACTTTGTTACCTGCTGCTTCTTGTCTAATTTACAGGGATATTTAATTTTGTAAGGTATTTGTATATTTATACAGCTGTAATGAATTGCACATTGGACTGGAAGGGGAAGGCTCTGCCCTGTGTGGCTCCTACTGGAACTCTTGCATTTTCCTCTTGGGCGCTGTGCTTTGGCCCATCTGAACAAAATCAGGGGTGTGTGGTTTGTTTAGCGTGGGTCCATCATTTTCATTTGGGTTCCTTTTGGAAAATGTAATCTTTAACTTGCTCTGTGAGAAGAAAAGAATAATTGTGTTGCTGCTCTTGGAAGGTCTGCTGAGTGCATTTGAGTGAACTCTGGCGCTGTGTACTGCAGCCATCCACCATGACCTGTGATCCACCAAGAGTGAGTAAGACCACGACCATGGAGCAAGTCAGAGATTGTCAGGCGAGAGATTATTGCTGTTACTGTTCAAAAGGCCATTTATGAAGTAGATATTTGAGCTCTTTAAAAAAAAAATCTTAAGAGAGCCCCTAATTACTTAAAGAAAAAAAGAAATTTAAAGAGTTAATACAGAACTGGTATTAAAAACTTGCAGGCAGAGGTTAGAGCACTTGGCAATTTTACGTGATGCCTTTGGTTCAATCCCGGTGCTGCAGATCAGACAGAAAGCCAGGAGGCAGAGAGCTGCGCAGACAGAAAGTCTGTTATATGTTGTCATGTCTTTAATTGATTCTTTTCATGCTGTGTATTCTGGCATCAGTTCACCTAAGGGACCCACCAGCCTCCTCATGTTTAAGCATTGTCGTAGACTTTGTGGCTCTAACATACTTGTCTGTTGAGAGTGGCGTCTCTTGTCACCATCCCCATGCTATAACAGAACCCATGAAGCATAAGTGGCCTTTTTGAACCAAGACTTTGCAAACTGATCTCTCCCCAGGGAAGGAGTTGAGCACAAGCAACAATGTACATTATTAATTTTGGATTTCATTTTCATGTTTTATTTTGTAAATATCTAATGTTTGGAGCTTGAGTATACAAAATGTAAATACAGTTCTCGTATTTGTACTAATCCTGATTCTTTTGCTGTATAGCCCTAGCTGTGTAATGCAGACATTATCTGACTGTGTATGGTAACCTTGCATCACAGAACTGCTAGTGAACGAGCTAAAACAATAAAGGTACAACCAGTGCA
->XM_039680831.1 PREDICTED: Pimephales promelas family with sequence similarity 49 member A, like (fam49al), transcript variant X3, mRNA 
-AGATGAGCAGCTGCTAGGCAGGACTGTCTTGAAAGCAGAGAGACAGTGAGAGAGACCATTTGGTGCCTGAACGCGAGCGAGGGAGGGGGCGAGAGAGACGCACACACTCAGCGTGAGCCTCTGGTTTAAGTAGACACTAACCGTGCGTTTAGGGAAACCCACAGTCTCAGCTCCCTGGGATACAGGAGTTTCTGGCCCTGCTCTTTTTCCCCTTTTCATTCTTTTATTTTACTCCCTCCATCTTTTCTCTTCTTCCCTTTGCCTACGGAAAGCGCTGGACCACTGTTTTCTCCCTGAAACACGCCAAGCCGGTAGTGGAGGCTGATGCTGTGATACACTGCAGGAGAAACATACAGGCTCTCATTTGATGCAGTGAAGTGCTCTGTGAGGAAAATCGCAAGCAAAGGTTTGCCGGCCATGGGGAACCTCATTAAAGTCCTTGGCAAGGATTTAGAGAACTGTCCTCATTTTTTCCTGGATTTTGAAAATGCTCAGCCCACAGAGGCCGAGACAGCCGTGTATAACCAGGTTAGTGCTGTTCTGGAAGAGGCCCATGGGATACTGGCAGAACTACAGTCTTACAATGGAGCAGGACAAGAAATAAGAGAGGCCATTCAGAACCCCAATGACCTCCAGTTGCAGGAGAAAGCCTGGAATGCAGTCTGCCCTCTGGTGGCCAAGCTCAAGAGATTTTATGAATTTTCTCTCAGGCTAGAGAACGCCCTGCGGAGTCTATTGGAGGCCCTAACAAGCCCACCCTACGCTCCCATGCAGCATCTGGAGAGAGAGCAGGCCCTCGCCAAACAGTTCGCAGAAATCCTGCACTTCACTCTCAGCTTTGATGAGCTTAAAATGACAAATCCAGCCATACAGAATGACTTCAGCTACTATAGGAGGACCATCAGCAGGAATCGTCTGAACAACCAGCAGTTAGAAGCTGAGAATGAAGTAAATAATGAAATGGCCAATCGGATGTCGCTCTTCTACGCTGAAGCCACACCCATGCTCAAAACCCTGAGCAATGCCACGACTAAGTTTGTGTCGGAGAATAAGACTTTGCCAATCGAGGACACCACAGATTGCCTGAGCACTATGGCCTGTGTGTGCCGTGTCATGCTGGAGACTCCGGAGTACCGGTGCCGTTTCACTAACACAGACACCATGCTGTTCTGCATGCGTGTGATGGTGGGCGTCATCATCCTTTATGACCACGTTCATCCAGTGGGTGCCTTTGCCAAGACCTCCAAGATTGATATGAAGGGCTGCATCAAGGTGTTGAAAGAGCAGCCTTCAAACAGCGTGGAGGGACTGTTGAATGCACTGAGGTATACCACAAGACATTTAAATGATGACAGCACCTCAAAACAAATCAGGGCTCTGCTTCAATGAGAGCAGGAGGAGAGGGAGGAGGACCCACAGAGACAGGGACTGTCAGAGAACAAGCGATGGTGGCTGGCAGTCCTCTGAAACCTGTTTGTTTACAAGAGCAACTTGATCTCAAATGAAATAAGATATTCTAGAAAAGAAAAAGGAATACGAAAATAAATATATATATAGAGAGAGAGATTGTTGATGGTTCATCACCGTGTGTCATTTTATAAAAGCAGGAAAAATAGAGATATATATGTATATTAAAATTCATTACTTAAAACTACCTGGGTGTGGATATAAAAGTCTTTCAAAAACATATTAAATATTTAAGAATTGAATTTAAAAGCGGTAGTTAAAACCACCAACAAAACTGGTTCATATTCCAAGTTCCGCCTGAGAGTATTTTTGCACACTTGAAAAGGAATCCCACCTCACAGGAAAGACATTAACATGGCTTGAAACTGTATAATTCAGATCCCTTTTCACGCGTTTTTAGACTTGATTTGATTTGCAACGCCTCGTTATTCCCGTATGTGCTTCGTCCAATGCATTCTGGGAATTAAAACCGGAGTCCTTGGCATTTCAAGTCTGTTGAAGGATAAATGTAAAGATCACATACTTGAGACGCATCTCTGCTGACATCGCCAGAAATCAAACTATAATCCTCTAGCTGTATATACTCGGAAAGCACAGGATAGTTTTGTAAAGAAATGAAGCGTTTTGTTAGACTTCTTCACTAGTGCTGTACAGCAATACTCTATACCACCAATGTGACAAACCCGTTCATTTGAAATGCCTTCATACCAATGTATGAGACGCCGGATAATGCTAACAGTTCATCTGTGGAGTTGTACATATCATCAGACGAACAATCCTTTAAAAGTTACGTTTTTGCTCTTGTAAAGTTGACGTTCAAACGGAGCGAGTAAGCCATGAAACTGTAATTCAGACGCAAACACACATTCTGCCCTGTGCCATAGCTGCTTCCTGTACCACTGCGTCAGAGTGACGTATAACAAACATCATTCGTAGAAACCAAAACACACCATTGAGAACAACACAGCGATGTGGATTTGCTTTCCTCTGTATCCAAAAGCAAATCATTGCCAAATGGGACTGCAACTTTGCCTTTCAGATAAATAGAAGTGAGACGTTTGGTCATGAACACAATCTCAAAACAACAGGCTTGAAGGTGCAAAACACTTGACTTGGTGTAAATAAGAGGATTTTTACTAAACAAACGTTCCATCGAGACTCTTTGTTAGAATTACAGATGCATATTAAAAAAAAAAAA
->KC305230.1 Stachybotrys sp. HGUP 0107 internal transcribed spacer 1, partial sequence; 5.8S ribosomal RNA gene and internal transcribed spacer 2, complete sequence; and 28S ribosomal RNA gene, partial sequence 
-TCGTTGCTTCGGCGGGAACGCCCCGGCGCCCTGCGCCCGGATCCAGGCGCCCGCCGGAGACCCCAAACTCTTGTGTTTTTTTCAGTATTCTCTGAGTGGCAAACGCAAAAATAAATCAAAACTTTTAACAACGGATCTCTTGGCTCTGGCATCGATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCGTTAGCATTCTAGCGGGCATGCCTGTCCGAGCGTCATTTCAACCCTCAGGGTCCCCGTTCCGGCGGGGAACCTGGTGTTGGGGATCGGCCCGCCCCGTGCGGCGCCGTCCCCCAAATTCAGTGGCGGTCTCGCTGCAGCCTCCCCTGCGTAGTAGTTACAACCTCGCATCGGAGCTCAGCGCGGCCACGCCGTAAAACCCCCGACTTTCTGAACGTTGACCTCGGATCAGGTAGGAATACCCGCTGAACTTAAGCATATCAAT
->XM_052206935.1 PREDICTED: Mytilus californianus uncharacterized LOC127702642 (LOC127702642), transcript variant X2, mRNA 
-AGGTTAATAGATGTAGTATTTAAGCGTATATCAGAGCAACGTTACCCAACATACCACATACGAAAAAAAAAAAAAAAAAGGGATAGCATGCTTAACAAATTACAAGTATTCGTATGTTTTCTGATTGTCAATTATATATTTTGCGAAGACACCGATGATTGCAAGGATGAAATATGTAGGAAGTCGTTAGCAATGCCACTATTGAACAATCTGAAAGCACCTCTTGTTGCCAATTTGGATATAACTCAGTTTAACAAGCAGCTACGAGGGTACATTACAGAACAGATCAAGCAATGAGTAGAGCAGGCAAAGAAAGAAATAAGGGGCGAAATGGTAGAACTCGTCGACACATTCGAAGACGCTCATGTAAACGTTACACAAGACCTTAGCAAAGATTTGAACGAAATCAGGCGTCAACAAATGCAAATGGAAGATCGTGCAACTAAAGAAAATGAAATATCGGGTAATTTTACGTTTGAAATTATCGATGGAATGAAGAATATAGAACGACATCAGAAAGATATTCTGACAGATGTGGAGCAGTTGAAACGTTATAAAGAATCAGTAATTACAGCAAATGAAGAAAAAAACAATTTCACAGCAGAAGTCAAAGATACACTAAAGAATTTAAATCAACAACTGAATGAAACTCATGATGAAATTCATCACTTGAAAAGTTTTCATGCATCTTTAAACTCCAAAATTAATTCAGCCGACAAGAGGATATCTGCAAATGAAGAAAAAGTACCAATTGTCAACGAAAAATTACGTAATTTAAAAGGAGAGCTAACTTCAATTCGATCGGACATTAATAGTGTAGAAAGTCGTCAGAAATCATTGTCCTCTGACATCAGCAGTGCTTTCAGTCGTCTTACAGCAAATGAGAAAAGAGTTGGTTTTACTGCTTGCGTTAGTAAAGATGATGGATCAACCATATCAGCAGGTCATCCAATACCATTTACCACTGTTACATCTAGTTATAATGTTGATATGTCAAGCGTTAAAAGCAATGGAAAGTTCACCGTTAAAATAAGTGGTTTATATTTTATATCGGCATCAATAAGAAGTAAAACAGACCATGGATTCTTTGCAATATATGATGATTCGTACTTTTTAGCTTATGGATACACAGCTGAGCATGACGGTAAAGATACATATGATCACAGTGGTACAGTAGATGCGGTGCGATATTTTAATTACGGTGATATCCTAGCAGTAAAGCCGTGGAAAACTATGGACATTGGTGCTTGGTCTTGTCTGACTTTTGTCAAAATAAAATAGAAACAAATTATAATTAATATCTGACATTTTGTATTTTTGCGCAATAAGATATCACAATTGAACATTATATTTTGAAACAATACTATAAAGGAACTGTTCTAATTATTGGAAGTACTAAGTACGTACAACAAAAGGTGTTTCTACTCACAACTTGACATTCTGTATTGTCACCAATTGGAAGTTTTCATGTTTTGTTTTAACAATTATCGCTTTCAAATAGTCAATTAGCTTATAGTAATTCTAATGTTCAATTATTTATTATTTCTTCATTTATGAATAACAAAATAATAAACTGATATGATATTTCAAAAA
->XM_050245764.1 PREDICTED: Anopheles aquasalis tyrosine-protein kinase Fer (LOC126581837), transcript variant X1, mRNA 
-GCGCGTGGTTGTGTGAAGCTGCGGTGCGTGAGCTTTCTTTTGCTTGTTTGTTCTGTGTTGTGTTGTTCTCCGTGCATCGCGGTGATCGTGCAGCGTGATTTGTGTGCGTGTGCACGTGTGTTCAGTGCGCCTCCTCCACGCCGTGATTACAGAGGTACGCCTTTACCTGCGCTACGTGTTTGCTCCTTGCTAGTTTACAACAGGAAGGAGAAAGAAAAGATCAAAGTGTCGGTGCGTTGTGCGTATGCTTATGCTTGAAATACGAAGATAAATACAACCGCCTGCTGCGTGTGTGCTTTTTCGGTGTGGCGGTTTGTTGGTGGCACCTGCAATAATCGCACGTTTTATCAATTCGATAGTGTTGGGTTAAGGATAAGATACAACATATCGCGCAAATCATCAATATCAATCCCTACCTACTGACTTGGTGGATAGTGTCGTTCCTCCATTTTCCAAAATGTAACGGATATTACTACATAAGACCGGAACGAAACGGCTACGAATTAACGCATTGAAAAAGTGAAATCCTAGTGCTAGAAACGGATTCAAAATTGCTTCAACAAATTAGAATATCCCTTTTGCATTTGTATCGCTTAATTGCTGTGTTTTTGTGTTACTAAAGTAGTGTTAGTAGTGTATGGCGATTCGCCAGGGGATGGCTGCGTGTAGTGTCGTGTAGTGTCTAACGCGCGAAGCGTTAGAAGTGGAGTGAACAATAGAGCCAAGAGAAGAGGTCAATCAAGTGCATAGTGCCTTTTTTGTTTTTTTGGTTGATTTTTTTTTCCTGCGCGAGAGGAAACCAATTCTCTCAGTAGGCAGTGGCAAAGCAACGGGGGGAAACCATCATGGGCTTCTCGTCTGCGCTGCAAGGCCGAGCGGCACACGACGCGCTGCTCAACCGGCAGGAAGCGGAGCTGAAGCTGCTGGAAACCATGAAACGGTGTCTGGCACAGAAGGCAAAGTGTGACCGGGAGTATGCCGTCTCGTTGGCGGCCGTCACCCAGCAAGGATTGAAAATCGATCGCACCGATGATCTGCAAGGAAGCCACATTATGCGTGCTTGGCGGGGTTTTATGGAAGAACTCGAGCACACTGCCAAACAGATTCGCTCCAATGCCGAGCAGCTGGAAACGGTTTGTCACGAGAAGCTGGCCAGCCTCTACCAGGAGAAACGCCGGGTCCGCAAGCAGTACCAGGAAGAGCACACCAAAATTGCCACTCAGTTCAGTCATCTCACAGAAGACGTCGCACGGAAGAAAAGCGAATATCAGAAGCATTTAGACTACTACAAACTGCTGCGAGGTCGATTCGAGGAACATATCAAATCTGGTCGGTCTGGGCGAAAGCTGGACGATGTCATCGACAAGTATCAAAAAGCCTGCCGGAAGCTGCACCAGGCCCACAACGAGTACGTTCTGCTCATCAGCGAGGCGGTCGAGGTGGAGAAAGATTTTCGAACAACGCTACTGCCCGGCCTTCTCGAACACCAGCAGACGCTCCAGGAAGGATTCATCCAGGCATGGAGCAATCTGCTGTCAGAAATTGCAAAACTCAGTGACACCACATCGGAAAAGTACGTGGAAATACAGCGACGCATTGATACGAGTATATCGAGCATCAACTCGACGGAGGAGTATCGCGAGTTTACGGATAAGCACAAAACATCACCGACCACGCCGGTCGTCTTCCAGTTCGACGAAAGCCTCGTCGAAGACAGTCTCGGTAAACTCCAAGCGAACACGTTGACCGTCGACAACCTGACGGTGGATTGGTTACGCGGTCGCCAGGTGGAACTCGAAGGTACGATTAAGGATCTGCAAGAACGACAAGCCAAGCTGCTCGCCGAACCGAACGGAACCGGTACACTGGCCACTAGCAGCTCACCCGCTTCCAGCAGCCCGGTCAGTACACCGGGAACAAAGCCATCCACACCGATTCTCAACGGTACCGGAAACAGCAACGGGGCATCAGGCAAGGACTCTCAGCAGATTGCGGCCAATAAATCATCAAAGGAGTTGAACAACCTGCGGTGCCAGGAACGCCAAACCATGAAGCTGGTCGAGATGATACGAACAGCACTGAACGAGGTCGGATGCGAAGAGCTACCTTCCGGATGTGACGACATCGCGGTAGAGCACCTTATCGAGAACAAAAAGTCTGTCAGTCAGGATCTATCGCTGGACTCGCAACATAACAATCCATCGCAGGCGGGAGGATTTTTCACACTGCGCACGGGTAACGGTGGCAGTGGTGGTGGTGGTGGTGGTGGTGGAGGTGGTGGTGTGATGTCAATGTTAATAGATCAGTTGCGACGCAAATCAGGGCCTCCGGGAGCGGCGACTAGTGGTGGTACTGGTGGTAAGGCGGCACCCCGATCGGTGGGTACCACTCCAGCTCAAACACCCAAACCAGGACATCGCGCGACAGCAGCGAGCACGGTAAATAGTGTTTCTAGTCCCGCTACTATTACGTGTGAGCGTGTGCAAGCTTCTTTGGATGGCTTTCCGCCGCACGCTACTAACCACTACCAGCAACAACAGCAGGAACAGCCGCAGCTGCGACCGTTAGCTCCCTGTTCATCAGCAAGCTTGTACGCTGAGCTCCGTTCCGTTAATCCAGAGATCGATGATGAGCAATCCTTTCCATACCCCGAAAACCGCATTTCAAACGTTTACGTAGACATGGAAGCGTATCTTGGGATGCGGGAGCTCAGCCCCGATGAGAACAGCAGCGAACATGCATGTGCATCGTACACTAATATCAACAGCGACCATCTTCCTTCCCTCCGCCATGAACAAAGTTCAACCGCACACAACTCGCAAAGCAGTCCAATGGGCGATCTCCCTAATTCACGCACCCCCATGCTAGGGGACGATGATGGCGAAAGGCGAAAGTATCGTCGACTACGAACCATGGGCGATCGTATCGATGATGAGGATGATGATGCCGATACTGCTGAGGAGTTGAACGATTCGAAAAACAATTTACTACGCGAAGAGAGCTACGATGGTGGGGATCAACTAGATGAAGGGCCGACGGAATCGGAAACAAAGTATCTGACGATGAGGAAACGTTCATCGCCCCGCGCTGATACGACGACCCGCTGGAAGTCCTCCATCGAGCAGCACCTGGATGTGATAGATGCGCTGAACATCAAGCTGGACGAACATCAACGCCTCTCGGCCCGCCTTTCTGAGGATTACGAATACATACGGGTGCAGACACTGCGCCGTGAAGCGGAGCTGATAGCAGCAGCAGCAGCGGCAACAGCAGCATCTTCAACATCCTCTACCGCTGTACCGCAGCGTGCAGCAGCAGGAGGGACACCGTTCGAAAAAGCAAATAGCTTCCGCGAGAAGATCAAACGGCGCATCCGAGGAGCAAAGAGCTCGCAACTTAGTGAACCGGTAGAACCGGAAACACCGGATAAGGTGGCGAATGTGGTTGAAAGTTTTTCCGGCCGATTGCGCACACGCATTGCTTCACAGCGGCAGTTTCGGTTGATGAAGGAAACGGACTCGGCCAGTCCTTCCACCGATCGTGGTTCGATCACCACAAATGGCGGCGCCTCTAACTCGGCGGGTGGACGCCAGAAGAAAAAGAAGCGTAAGTCGTCCAAAGCGCACCGTGCCTTCAAGCAGCAGCAGCAGCAGCAGCAGCAACGAAGTGGTCTAAAACGGGATACCGAGAGTGAGCAAGAGGTGTATGACCAACCGCAGCAGCTGCTCCACCCGGCAAATACCTTCTCCGAGGATGAGCTGTTAGTAGACGAGCCACCAAGAGTCGGTTCACCGGAGCAGATGGTTAAACCGAGTGGCCAAAAGTTCTCGCAAACCGTACGCGCCACGTGGCGGGAACTGTTGCACTCGACGAACAAGGTCAAGGATTCGTCAATTAATCTCACCAACCAGCAGCAGCAGCACGATCGTATGGAAGAAAAGTTAGATCTTATCCCCAATCAGGACCGTCCCGGGTTGCTAGCAATACGGTTTACCTTTTCGGACACTGAGACACCCGAACATCACGGAAGCCGCCAGCTCGATGCAACATCATCAACAACAGGCGAAGGAGGAGAGTATTGTGTACCATTGCTTTTATCGCAATCGAGTGACGATACGAAGGCTCCTCAAATTCTCTCTTCCGGCGATAGCAGCCACCCGGCTGGTAGTAACAGCACCACCAGCAAGCTGGCTATGAACCTGAAAATCAATCTGAAGGAAAGGCTCACCAAATTGGTACACAAAAGGGCACTGATGATGGGTGGTGGAGGGACAGTGCCAGGTAAAAGCAATCTTCTGCCGCTCCATCAACCATCGGGCGAAATATGTAGGTCCTGCTCCAAACGTATCGTTCGCCCGGGAACCATACACCCGAGCCAGACGGTGTTGGATTTTGTAAAAGAATTTCCTGGCCTCGATATCTGCAACGGTGGCCACGATGAGGACGACGAAAACGACGATTGCGATGGCGACGGTGACAACAAGAAGGCAGACACCGCCCGTCCAGGCCGTGCAACCGAATCGGAAATGATCAATCTCGAGTATGAGGATATCGATGTGATAACGATTAAGTCCCACAAACTAACTGACCATTGTGAGGGTGGTGATGATGATAATGATGATGATGGTATGACGCTGTCCACAAACCGGCCACTGCATGAGGAAGAATGGTTCCACGGTGTGCTGCCGCGGGAAGAGGTGGTGCGGTTGCTAAGAAACGAAGGTGACTTCCTGGTGCGCGAGACGACGCGAAACGATGAAAGCCAAACCGTACTCAGTGTCTGTTGGAACGGTCACAAACACTTTATCGTGCAGACGACGGCGGAAGGCCACTACCGTTTCGAAGGACCGGCATTCCCCAGCATACAGGAGCTGATCGTGCACCAGTACCAGTCGGAGCTGCCGGTGACGGGCCGGTCAGGTGCGGTGCTGCGTAAGCCAGTGTTGCGCGAACGCTGGGAGCTGAGCAACGATGACGTGATACTGCTGGACAAGATTGGCCGGGGCAATTTCGGCGATGTGTACAAGGCGAAGCTGAAATCCTCCAAAAACACGCTGGTCGCGGTGAAAACCTGCCGCATGACGCTACCGGAGGAGCAGAAGCGCAAGTTTCTGCAGGAGGGACGCATCTTGAAGCAGTACGATCATCCCAACATCGTCAAGCTGATCGGTATCTGCGTGCAGAAGCAACCGATCATGATCGTGATGGAGCTGGTGGCCGGCGGATCGTTGCTGATGTTTTTGCGCAAAAATGCAACCACCTTGGGCCAGCGCCAGATGATGGGTATGTGCCGAGATGCGGCCGCCGGGATGCGCTACCTGGAGTCGAAAAACTGCATCCACCGTGATCTCGCGGCTCGAAACTGTTTAATCGGGAGCGAGAACATCGTGAAGATTTCTGACTTTGGAATGTCCAGGGAGGAGGAAGAGTATATCGTATCTGGCGGTATGAAGCAGATTCCAATCAAGTGGACTGCCCCGGAGGCGCTTAACTTTGGAAAGTACACCTCGCTGTGTGACGTCTGGTCGTACGGGATCCTGGTGTGGGAGATCTTTAGCCGTGGCGATACGCCCTACTCAGGAATGAGCAACTCGATGGCTCGCGAGCGAATAGACGAAGGCTACCGGATGCCATCGCCGGAGGGTGCTCCACCGGAGATGTACCGGCTCATGCTCAAGTGCTGGTCGTACGAGCCCGAAAGCCGGCCACACTTTGACGAAATCTATACCGTGGTCGATGCCCTGATTCTATGCACCAAGGACTGACCGGAT
->XM_009229646.1 Gaeumannomyces tritici R3-111a-1 hypothetical protein partial mRNA 
-ATGGAATGGAAAACTCAATATCTTGACGACACCGGAGGAAACTCTGAGATGAGGGGGTCGGGCTGCGACATTTACAGCCTGGCCGAGGGTGAGGGAAGAAGAGGGGAGGGGGGGGACGTGACGGGATACCAGAAGCGGCTCGCACCATGCACAGCACCCCGCCGCCGGCCTCGAGGACAGCACAGTCTGACCAGAGTGCCGAAAGCGATTACTGTAGATGGAAATGCAACAGAGGCGGACATGAGACGTGTCGCCGTCGGACAAGAGTTCAGACGAAGTCGCCTCAACATCATGGAGAGCCGACATAAGTATCTGCACGTGAGCATTAGCCATGGGAGGCGCTCCGGCTGA
->XM_014964222.1 PREDICTED: Calidris pugnax CCR4-NOT transcription complex subunit 4 (CNOT4), transcript variant X8, mRNA 
-ACCTTCAAGTGCTGACCTTCTTGGTCTATTAAGTTATTATAAACTTTTGCTGCTCTGCGAACATATAAAGATGTCTCGCAGCCCTGATGCTAAGGAAGACCCTGTGGAATGTCCCCTTTGCATGGAGCCTCTGGAAATTGATGACATCAACTTCTTCCCTTGCACCTGTGGCTACCAAATCTGCCGTTTCTGTTGGCATCGTATCCGTACTGATGAGAATGGACTTTGTCCTGCTTGCAGAAAGCCATATCCAGAAGATCCAGCAGTGTACAAACCACTCTCCCAGGAAGAGCTGCAAAGGATAAAAAATGAAAAGAAACAGAAACAAAATGAGAGGAAACAGAAGATATCAGAGAATCGCAAACATTTGGCCAGTGTACGGGTTGTACAGAAGAACCTTGTCTTCGTGGTAGGACTGTCTCAGCGCTTAGCAGATCCAGAGGTTTTGAAACGACCAGAATATTTTGGGAAGTTTGGTAAAATACATAAAGTTGTCATTAATAACAGCACATCATATGCAGGCTCACAGGGTCCAAGTGCCAGTGCATATGTAACCTACATCCGGTCAGAAGATGCTCTTAGAGCCATACAGTGCGTCAATAATGTGGTGGTAGACGGCAGAACACTTAAGGCATCGTTAGGTACAACAAAATACTGCAGTTATTTTCTAAAAAATATGCAGTGTCCAAAACCAGACTGCATGTATCTACATGAACTGGGAGATGAAGCAGCCAGTTTCACAAAAGAAGAAATGCAGGCGGGCAAGCACCAGGAATACGAACAGAAACTACTGCAAGAATTATACAAACTAAACCCCAATTTTCTCCAATTATCTACGGGTACAGTTGACAAGAACAAGAACAAAGTGACAGCACTGCAGAGCCCTATCGACAAACCTTCAGATTCCCTCAGTATAGGAAATGGTGACAGCTCCCAGCAGATAACAAACAGTGACACACCTTCACCACCGCCTGGTTTAACAAAACCCAATCCAGTCATACCCATCAGTTCATCTAATCACAGTGCACGGTCTCCTTTTGAAGGGGCTGTAACAGAATCACAGTCGCTCTTTTCTGACAACTTTCGGCACCCTAACCCCATCCCTAGTGGGCTTCCTCCATTCCCCAGCTCTCCACAGACTTCAAATGACTGGCCCACAGCACCAGAACCACAGAGCCTCTTCACATCAGAAACTATACCAGTATCCTCCTCCACAGACTGGCAAGCGGCTTTTGGGTTTGGTTCCTCCAAACAGCAAGAGGACGACTTAGGGTTTGACCCCTTTGACATCACCCGCAAAGCCTTAGCAGACCTGATTGAGAAGGAACTGTCAGTCCAAGACCAACCTTCCCTCTCGCCCACATCTCTTCAGAACCCTACCCCACACACTACAGCTGCCAAAGGGCCAGGCTCTGGATTCCTGCATCCTGCTGCACCCGCAAATGCCAACTCTCTCAGTAGCACCTTTCCAGTCATGCCACAGAGGTTCCCACAGTTTCAACAACATCGAGCAGTTTACAACTCCTTCAGTTTTCCAGGCCAAGCAGCTCGCTATCCTTGGATGGCCTTCCCACGCAATAGCATCATGCACTTGAACCACACAGCAAATCCCACCTCAAATAGTAATTTCTTGGACTTGAATCTTCCACCACAACACAGCACAGGTCTTGGAGGGATCCCTATATCAGGTATCCCAGCCTCCACAGGAAACAGTTTAGACACCCTTCAAGATGACAATCCTCCACATTGGCTAAAATCTCTTCAGGCCCTCACAGAGGTGGACGGCCCCAGTGCAGCACCATCACAGACGCACCACAGTAACCCCTTCGGCACACAGATCCCTCTGCACAGAGCCAGTTGGAATCCCTACTCTCCTCCTTCAAACCCCACCAGCTTCCATTCCCCACCCCCAGGCTTTCAGACAGCCTTCAGACCCCCCAGTAAAACCCCCACAGATCTACTACAGAGCTCAGCGCTGGATCGTCATTAGGAAAGGAGGAAAAAGAAGAGGAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAGAAAAAAAAGAAAAAGAAAACCCAAAACGTTAGAAATGCAGGAAGTGTCCCACCCTGACTCCTCCCCATGCCCACCTACTGTTCCCTGTCATATCTTTCTTTCTGAAGAATCCAGTTCCTGATCAAACCTCCCCCCCAAATGCAATGCCATCACAGGGTCGTGACCGTATCTTTTTGTTAAGTTTCTGCTGAGCCAGTGTTTGAAATACACTGTTTGAAATATTTTCTAACCGTTCTAAGGAAAAAAAAAAAGAGAGAGAGAAATCAAAATGCAGTCTCAATGCTTAAGGAGAATATTACTGTCTTATGTCTTTTGCACATGAGTATTTCTGCCTAGTGGAAAAGTGTCAATCTGCAGTAGGGGAAAAATTGCAATGCAGAATCAAATGCAGAAACATGAAAAAGGTATTTAATTTAAATGAATTTACTGAACATGTGGGGCAAGCAGTGGCCTAGCATTTATTTTGCATTCAGTGTGGCACTACACAGGGAAATTGCTATGTTTTTTTTTTTTAAGGGGGATTTTGTGTCAGAGTTTGACATGAAGTGTGTTGAAAGACAAAAAACACTTATAGCTACGAGTAAGTGGCATGTTGCTAAAGAGTGATTTAAAGAGGGGAGAATAAGATTTTTCTTTAATTTTGGCTTTAGATTTAAAGTAAACTTTAATGTTTTAAAAGTATTCACAGATTTAATACCTAGCGTATACATAATATAATTATAAGCAGCTGAAACACGAGTGATATTTACTTCAGTCTTTCTGTCTCCTCTGTCAGTCTCTCTTTCTTTTTTTTTAAAAAAACAAAGATTCACCTGATTAGGGCACTCTGGGATAGCACTGCATTGGGGCCACATGATCACCATCAGGAGCAACCTCTGACCTCCTCTGCCTGCAGCTTTTACTTAACCCTGTAGTTTCTGGACGTTTGTGCAGTATTGAAAAGACAGGAAAAAAGAAACAGATAAATAAACATGGTTATAACCTGACTCTAAAACTAAAACCAAGGAAATGTACCTCTTTCTTCAGAATTAAAACTAAAATCTTAAATAAAACAGAAAACTTGATGATGA
->XR_005915111.1 PREDICTED: Gossypium hirsutum xylose isomerase-like (LOC107963207), transcript variant X1, misc_RNA 
-ATTTTGCAGGGTTTAGTTTGATACTTTGAGTGATATCAGTAAAGAAGAGTATGGCAAGGAAGATTTCATATATATTTCTTTGTATGAATGTGATCCCCCTTTTAGCGGCTGCTGCATCACAAGCTTGCTCTGCTCAATCTGATGCAAAATGTTCTCAAACCGGTGAATGGAATGGGGAATTTTTCCCTGGAATTCCCAAAATCAAGTATGAGGGTCCTTATACCAAGAATAAATTTGCATATAAATGGTATAATGCAGAAGAGGTGATTCTTGGGAAGAAAATGAAGGACTGGTTGAGATTCAGTGTGGCATTTTGGCATACATTCCGTGGAACTGGTGTTGATCCTTTCGGTGCACCTACGAAATTTTGGCCATGGGAAGATGGTACCAATTCCATTGCTATGGCAAAAAGAAGAATGAGAGCCAACTTTGAATTCATAAACAAGCTTGGTGTTGACAGGTGGTGTTTCCATGACCGGGACATTGCTCCCGAGGGCAAAACACTTCAGGAAACTAATTCAAACTTGGATGAAGTGGTGAAACTTGCTAAAACACTTCAGGGAAACAATATCCGTCCACTGTGGGGTACGGCTCAACTATTTATGCATCCTCGTTACATGCATGGTGCTGCTACAAGCTCTGAATTGGGTGTATATGTATATGCTGCAGCTCAAGTCAAGAAAGCCATGGAGGTGACACACTATCTAGGGGGAGAAAACTATGTGTTTTGGGGTGGTCGTGAAGGTTATCAAACACTATTGAACACAGACATGGAATTTGAACTTGATCATATGGCAAAATTTCTTGAAGCTGCGGCTGCCTACAAGAGGAAGATTGGATTCACCGGAACTCTACTGATTGAACCTAAGCCTCAAGAACCTACAAAACATCAATATGATTGGGATGCTGCAACAACAACTAATTTCTTGCGAAAATATGGGTTGATCGGGGATTTCAAACTTAACATTGAGTGCAACCATGCCACACTCTCTGGTCACAGTTGCCATCATGATGTTGAGACTGCAAGAATCAATGGATTGCTAGGAAATATTGATGCAAACTCTGGCGATGCTCAGACAGGTTGGGATACAGATCAGTTCTTGACAGATACTCGAGAGGCAACTATGATCATGCTAAGTGTGATTAAAAATGGACACTGAGCTTCTTATCGTTTGACCCAACAGACCTTTGGTGTTCGATGAGAATTTATTTATCATATTTGGTTCACTTTTGTTTATGACAGGGATGCAAAATTACGGAGAGAGAGCACAGATGTTGAGGACTTGTTCATTGCTCATATTGTTGGTGTTGACACCATTTTTTTTGATGAAAAACGGTGGCGACTTCCGTTTTTTTCGAAATCATTTATTAAAAACAACCACTTTTGGAGGTGATCCGATCACACCTCATCAAAAAGGATCGGTGGCGACTCCCGTTTTCGTTTTCATTTTTCAAAACCCAAGTTGATCCCGTTTTTCATCCAAAAAAAATGGTATCAACAGTTGGAATGGACACCTTAGCCCGTGGACTCCGATATGCTGCCAAGTTGATTCAGGTAATACCAATACGAACATAAAACAAATACATATATGTAAAATACTTTAAACATGATTATGACACGATAAATTACATGAATACGATATAGATACATGATATTAATGAACTTGATGATTATATAGGATGGTTCTTTGGCTAAGCTTAGTCATAAACGATATTCAAGCTTCTATAATGAACTCGGTGCCCTCATTGAGGCTGGTAAAGCTGATTTTGAAATGCTTGAGAAGAAAGCAATGGAATGGGGCGAACCTACGGTTGCTTCAGCCAAGCAGGAACTTGCGGAAATGATCTTCAACTCTGTGCTATAAGAGGGACCTTGGCTAGCAATGTCTTTTGCAATTTAGCATTAGGAGTAATTGATGATGTTCAATAAGTACAGTTTATGTAATTTTCATTTTTTTTTTTAGAAATCTTTTGTACCTAAATTTCACTCTCTCTTTTTTAATTTGGTATTTAATTTTTTTATGTCCAATTTGGTAGA
->XM_033267273.1 PREDICTED: Anneissia japonica uncharacterized LOC117121888 (LOC117121888), transcript variant X1, mRNA 
-CAGGCGCTGACATTGTTATTAACAAACCTACTTGGTACTTTGTAGATTTTTTATTTATTTGTGCTCGGAAAATTACGAGAACCTGGGATGCAATTTTTTTGTTATGACCCACCCTTTCTACTGAAAATGAATTCCCTAAGATTATTTTACACCATCATTATGTTTGTGGCAGTCAAAGAAGTAGAGTGTGAGGTGAAAACAATATATTTTTGTCCTGAACAGAGTGCAACAATATATTGCAATGTTACCAGTGATTTCACCAAATTATATTGGAAAAACTCTACAGATTATGTTGTAGCATCACAGACTGTTAATAATTGCAAAATTACCAAAAAAAGTCCAAATAAAACATACTCCTCATCTGACCGATTTGAAGTCCAAGGATTATCATTGAAAATAGCATTTCCAAAGGATGGTGAACAATTCTATTGTGATGTTGTATCGAGGAAAAAAGAAATAAAACAGCATTTTACTCTAGACGAGTACAGTGAACCTTATCCTGATGATGTGTGCAGTTCACCAAAAGACACTAACAAAACAAAAAGCAGGCAGTTAAGAAGCGGTGGAACCAACAAAATTACCCGGGAAATCAATGAAACAAACTTTGTATGCATAAATGGAAGAACTGTTTTAAAATGTGATAACGGGCAACACGATAGGCCTATCGCAGAGTACTGGGAAGATAGATATGGCAAATTGATTGTGTCTAATGTGGATGGGAGACTATCAAATACGTCCGATGCCAGATATGTATTTAACCATATGAATTCCACATTGTTAGTCCAAAATCTATCAGAATGGGATCATCTATTTGTTTGCAAAACTGTCTACAAAAATGAAGATATCATAAAATGTTTCAATTTACAGGAATATGGTACACCAAAAGACAGCTTTTTTGAGGGATTTGAAAACAATAAATGTGAAGTAGATGCAAATGAAAATGGCCAGGTCATTGTACCATTCACGGTGGCTTGTTTCAGTCCAGTGAATGCAGTAACTGTAGTTTGTGAACTGAATGGAGAGTGTAATGATACAAACCCGCAGTATAATGTAACCGATGACGGGAAATTTAATTCACAAATTTGTATAGATAGGAAAATCGAAGTGAATAAAAATTTGACATGCACATTGACTGGTCCTGCTATGTGTAACCATTCTCAAGAATTTGTTTGTCACTTCAAGTTCAAGGAAAACAGTTCAAGCAGTATCAGAAATTTAGTTATTGCTATTTTGTGTCCTATTGTGGGTCTTCTTGTGATTGTATTTGTGTACTTACGTTGTTGTCAAAAAGAGGAAGAGGAACATAGCAAATCACAAGTTAAGATGCCATCTGAGATTCCCCCCATCCAATACATCACAAGCTCCGACCAAGTAACAATAACTGCACCTCAGGAGGTCACTTAATTGAGGCATGTCGTGGTGAAATGGTTAAGTTGTCGCACAGACCAGTACTGAGTAAATGAGCTATAAAAAATGGGAGCTCAAAAAATTTCCTGAAAATCCAAATTTGTTTTCCACTATTATGGATCAACAGTTTAATGTCTTATTAATCATGTCCCAAAGTATTAGTTCTGGAAAAGTTCATCAAATTGTTTATTTAACGTTATTTTGATATTTAATTGTATTTAACAATGCACAAATAACTTCAGAAGGCAATACTGTACTCAAAATTATGTTTATCTTGGCTATAAGAGTGCTGTACATTCACTTACCAATAACTTGGGCTTGAAATTTCCAATTTTAATGAATGACCCCCCGTTTTAAAGATTCCTCTTTTGTCTTTCATCTTTTGTGATCTGTTGGGCTTTGTCCCCTCCCTTGTCGTTATTTTAAGGACGTGACCCTAGAGAGTTTCATTTATATTTTCCTTTTATTATTTTTGTAACATGTTCTTGTTGGTTCTGAATAAAACTGATTATATATATATACTCAGGTATCTTAAAATATGGATATTTTAGAGGAGTCTTGAATTGGTGGGTGCATTGTACTATCTTCACTCCTTTAATCCCGACATGTCTTCAACATGGGGATTTCTAATTGTCAACATGGTCTTGTCAAATTGATCCTGCATAACTTCTCCTTGGCTGTGTTCTCCACCACAGGACACAGAATCTTGATGAGAGGGAACCAGCTCCTCATATTGATGTCATTTTCATTGATTGGAGAGGTGTATTTTATCTAATTTGATATGCTTCTTTCTAAAATGTGCAATTCAATGCTATTAACTTTTCGTTTTATATTTAATCTAACTTTTAGTAGATTTTTAACTGTTAACTTAATTCAATCTTATATATATTTTATCTACACTTTTTAATGTTTTAAAACCATTAAAAAGTAATCGTTTAATGTGCAATGTATAAATGCCAAGGTCAACTTTTTAATTATGATGCAATATATTATTACTATTACTAAAACTCTATACGGCTATGTTTGCTCTATGCTCTATGTTATAATGTAACAATACCTTAGAATAACTCTGTACAATATTTATATTCTTCTAACTTTTATGAGCTTTGTCAGTTGTGGAGACTGCATACACTTTTTAATGTTACATATTCTTCATCAATACCTCCACACCAAAGTTCATCGTCGTAATTTTGTTACCGTCAATCCCGCGTTTCCGATCTCTGTATTTGTTATGATATCACTAAGATTGATATAATCAAATTTTCTCCATTTCTATCATATTGATAGTGGACTAGAATTACTGTTGTTGGTTTTACTAACATGTTTAAGGGCAAATTTAGACAACACTGGGTTGAAATTTTTCATATTTAGTGTTATTATTGTACTTTGTATACTAGGCTCCTAAGCCTCAACTAGTGGAGTAAATATGCTCAAACAAACTGACACCATTCAAATAATTTAATTCTCGAACTCTAAATAATATGGTAATAAAGAGGGCTTAATTCCCACGTTTGCCATCATTACTATGTTTGCCATTCATCACTACAACTGAAATCAACAATAAATTCACCACAAATAGATGAGATAGTAAAAAATGATTATGTCTGATTCTATTTAATTTGTTATTAATAATAAGCCTGAAAAAATGAAAAGAGAGAAAGTATATATTGTAGTTTAAAATGTCAACTGTTCATAGTAGGGCCTATCAAATAGGGCCTAGGCTTAAATTAAATGACCAATCAGAACGTGTTATTTTTTTTTTCTTGTATTGCATTTTACGAGAAGTACCAATACTGAGTATGATGGTATGGCTACATGATGAATATGTAACATTAAAAAGTGTATGCAGTCTCCACAACCAAGTTCGTCATCGTAATTTTTGTTACCGTCAATCCCACGTTTCCAATCTTTGTATTTGTTATAATATCACTACGATAGAAATAATCAAATTTTCTCCATTTCTATCATATTTACAGTGGACTAGAATTACTGTCGTTGGTTTTACTAACATGTTTA
->XM_004993437.1 Salpingoeca rosetta uncharacterized protein (PTSG_12341), partial mRNA 
-ATGTCGCGGTTTGTGGTGGCGCTGCGGCCGTGTGGACAGCTGCGTGAGCGGCTCACAGAGCCCTTGGAGCTGAGTGCTGGAGTGCACATCCTGGGGCGAAGCCCACAAACCAAAGTGAAGCAGCAGTTGTGCAGCCGACGCCAGATTGAGCTGGATGTCGACACCGCCCGCGGCACCGTCACCCTCAAGCAGCAGCTTGGCCCAAACGCATGCTCTGTGAATGGACAAACCATCAGCCGAGGGAACAGTGTGGCGGTTTCGCGAGGCGCCCGCATCTCCATGTTGGCAGACAGTCCAGACGAGACCACGTTCACCCTGGACATCCACGAGTACGCGCCCTGTGGCATGACAACGCCCGAATCAACGCCGCTAACCCAGTTTGACACGTCAGCGTCCAGCACCGCGTCTTCTGTACGACCTGACGCGACTAGTTTTGACACAAAGCCAAGCGCACATGCCCCAGCCATCACCATCAATCTCACAAGCAACACTGGCGCCGCCACAATCACCATCACCAACAATATCACTGCTGCAGACGATGCTGATTCATCGCGCTTGACGACACCAGGCGGTGACGCCGTTACTGAAGAAGACACTGGACAGCCCAAGCAGCGCAGCGACAAGCAGCAGCGACGTGTCACCAGCGAGTGTGTGGACCACTGGGCAAATGCGCTGACGGAGTTGGTGCGTCACCCGGAGCGCCATGCTGATGACATTGTCTACGAGACCGTCGACACGCTCGTCATCAACGACAAGTACCCAAAGGCGCGGTACCACTTTCTTGTGCTGCCCAAACGCGTGATCACGGATCTGACGTGCCTCACCCGACATGACCGCCACCTCATCCAGAGACTGCAGGAGACAGCCATGACCTTTGGCAAGATGATTCAGGAGGACAAGCCAGGCGTCAAGTTTCATACGGGGTTTCACGCCGTTCCCAGCATGAATCAAGTGCACCTTCACTTGATTTCGCAGGATTTCGACTCTGTGTCCCTCAAGAACAAGAAGCACTGGAACTCGTTCAACACGCCGTATTTCGTTCCTGCTCGCAAGGTGTATGAGATGCTGAAGAATGAGGGCCGAATCCACTTTGATGAAGCAAAGTACAAGGAGTATTTGAAGAAGCCGCTGGTGTGCCACCGGTGTCGCCAGGAGATGCGCAACATGCCCACCCTCAAGCGGCACCTTAAGGAGCACCTCACCAACCCCTAG
->XM_046397594.1 PREDICTED: Scatophagus argus UbiA prenyltransferase domain containing 1 (ubiad1), transcript variant X2, mRNA 
-TGCACGATGTTGCACTTCTGGAAGAGGAAATGGCGCCCGTCAGGTGCAGCAGGATTTACAGTGGCCAACCAGTCAAGTCCCCTCGTAGTTGACACGTAAGCCACCTAACTGCCTCTCGCTGCATCAGGCTCATCGGACACAGAAGTATGATTTTAAGTAGTGAGAAACCCAGTTTGTGTCGGATGGTGAAGACGTAACGGAGCGCTGCTGGTACTGCAGACCCCTTGCATCGGAATGGCCAAAGAGCAGAAACAAAGCAGGGCAGAAACATTTGTGCTGGCTGGATCTAATGGTCACAATGGCCAGCAGTGGCAGACTGGTATGAATAACTTGGTCACTCACTCTCCTGGCACTAACCACAAGTCGAGGATGGCTCGCGTTGCCTCGGACATGAGGCAAAAGTGTGCGGCCTATGTGCTAGCACTGAGACCGTGGAGCTTCAGTACCTCGCTGACGCCGGTGGCCCTTGGCAGCGCTTTGGCATACAAACTGGATGGCTCTGTGGACTTGGTCATCCTGATGGTGTGCGCTGTGGCTGTTCTTGTTGTCCATGGGGCAGGAAACCTTGTAAACACGTACTATGACTTCTCCAAAGGGATAGACCACAAGAAGAGTGACGATAGGACTCTTGTGGATGAAATCTTGGCACCGCAGGATGTTGTTATGTTCGGAGCATTGTTATATTCTTTAGGCTGCTTGTGTGCCACTCTGCTCTACTTCCTGTCAACACTTAGACTGGAACACCTAGCCCTTATTTACTTTGGGGGACTCTCCAGCTCTTTTTTATACACTGGAGGCATCGGCCTCAAGTATGTGGCCCTAGGAGACTTGGTAATCCTCATTACCTTCGGTCCTCTGGCAGTCATGTTTGCCCACGCTGTGCAGGTTGGCTACCTGTCAGTGCTGCCGCTGGTCTATGCCGTCCCACTGGCCCTCAACACGGAAGCCATCCTCCATAGCAACAACACCAGAGACATGGACTCTGACAAGCAGGCAGGGATTGTCACCCTGGCCATCCTCATAGGCCCCACACTGTCCTACGTCCTCTATAACCTCCTGCTTTTCGTCCCCTACGTGCTCTTCTGCATCCTCGCCACACGTTACACCATCAGCATGGCGCTCCCTCTGCTCACGCTGCCCATGGCCTTCCCACTGGAGAAGCAGTTCCGCAGCCGACGCTATGCCAAGATACCCCAAAAGACGGCCAAGCTCAACCTCCTTATGGGACTTTTCTACGTGTTTGGGATCATTCTGGCACCTCCTGGCAGCTTGCCGTTACTGTGATTAATTAGCTTTGATATTTCAAATTTTGTTGTTTTAATACAGACTAGTTTATGCACCTCTTTGTATTTGTACAACGCTGAGGGCTTTTCAAAGGCTTTAATTTATTGTCTAATTTATACATTGAACAGAGATCTAGTTTAGGTCCTGCTCTGTCACACTGAAGGCATAATCAGATGTATTTTTTCAGTATTAAGCCTGCTGTAATGTGTTGGTGCAAGTAAGAAGTGTTGGTGTCATTTTGTAGAGGTAGGCAGCATTTTTATCATACAAGGACAGACAGTAAACCTACAGTTGCCATATTTGCTGTTCTTAAAAACACAATACTACAATGT
->XM_045050371.1 PREDICTED: Felis catus zinc finger protein X-linked (ZFX), transcript variant X5, mRNA 
-CTCGGGTTGTTCCGCTTCCAACTACCACATTCAGAGTTGGCTATCAAGTGGACGGATTGCTAGACTCTTACGTTGATATTCACACTTACGTATCTTTTTGTCCTGTATCTTTTTGGCCTCCATTGGTTAAGGGGAGCACATTCTTATTCCCTTCGTTAAAAACCTGGTTCCCTCATAACCAACACTCCTATTCTTGTCTTTGACAGCAGCGGTCTCAAAACGTCAGTGTCCTCTTCAGTTAATCTCTTGCCCATTTCCAGCACTGAGTCCTATTATTTCTCCCTTGCTTACATCTCTTCCTTCTACTTTCTGCCACATGGACAGGCTCCGTCATCTCATTCTTAGTTTGCGGTAACTTTTATTTTCCTTACCCTTAGTCTCTTTTGTCTAGCCCAGCAGTTAAAACACTCATCATAAGATAACATGTGGATTGTGTCATTTCTCCATTTTCCGTTCATGACCCAGCAGTTTTTCAGAACACTTCCCATACATTCCCATTTGATCATCACAACAGTCCTGTGAGGAGCTGATGCTACACACATGGATGGTGATCAAATTGTTGTGGAAGTACAAGAGACTGTTTTTGTTTCAGATGTTGTGGATTCAGACATAACTGTGCATAACTTTGTTCCTGATGACCCAGACTCTGTTGTTATCCAAGATGTTATTGAGGATGTTGTTATAGAAGATGTTCACTGCCCCGATATCATGGAAGAAGCAGATGTATCTGAAACGGTCATCATTCCAGAGCAAGTGCTGGACTCAGATGTAACCGAAGAAGTTTCTTTAGCACATTGCACGGTCCCAGATGATGTTTTGGCTTCCGACATTACTTCAGCCTCAATGTCTATGCCAGAACATGTCTTGACGAGTGAATCCATACATGTGTCTGATGTTGGACATGTTGAACATGTCGTTCATGACAGTGTAGTAGAAGCAGAAATTGTCACCGATCCTCTGACAACGGATGTCGTTTCAGAAGAAGTACTGGTAGCAGATTGTGGCTCTGAAGCAGTCATAGATGCCAATGGGATCCCTGTGGACCAGCAAGATGATGACAAAAGCAACTGTGAGGACTACCTTATGATTTCCTTGGATGATGCTGGCAAAATAGAACACGATGGTTCCTCTGGAATGACCATGGATGCAGAGTCGGAAATCGATCCTTGTAAAGTGGATGGCACTTGCCCTGAAGTCATCAAGGTGTACATTTTTAAAGCCGACCCTGGAGAGGATGACTTAGGTGGCACCGTAGACATTGTGGAGAGTGAACCTGAGAATGACCACGGAGTTGAATTACTTGATCAGAATAGCAGTATTCGTGTGCCAAGGGAAAAGATGGTTTATATGACTGTCAACGACTCTCAGCAAGAAGACGAAGATTTAAATGTTGCTGAAATCGCTGATGAAGTTTATATGGAGGTGATCGTGGGAGAGGAGGACGCTGCTGCCGCGGCGGCCGCCGCCGTGCACGAGCAGCAGATGGACGACAACGAAATCAAGACCTTCATGCCAATAGCGTGGGCGGCAGCTTACGGTAATAATTCTGATGGAATTGAAACCCGGAATGGCACTGCAAGTGCCCTCTTGCACATAGATGAGTCTGCTGGGCTCGGCAGACTGGCTAAACAAAAACCAAAGAAAAGGAGAAGACCTGATTCCAGGCAGTACCAAACAGCAATAATTATTGGCCCTGATGGACATCCCTTGACTGTCTATCCCTGCATGATTTGTGGGAAAAAATTTAAGTCCAGAGGTTTTTTGAAAAGGCACATGAAAAACCATCCCGAACACCTTACCAAGAAGAAGTACCGCTGTACTGACTGTGATTACACTACCAACAAGAAGATAAGTTTACACAACCACCTGGAGAGCCACAAGCTGACCAGCAAGGCCGAGAAGGCCATCGAATGCGATGAGTGTGGGAAGCATTTCTCTCACGCTGGGGCTTTGTTTACTCACAAAATGGTGCATAAGGAGAAAGGAGCCAACAAAATGCACAAGTGTAAATTCTGTGAATACGAGACAGCTGAACAAGGCTTATTGAATCGCCACCTTTTGGCGGTCCACAGCAAGAACTTTCCTCATATTTGTGTGGAGTGCGGTAAAGGTTTTCGTCACCCGTCAGAGCTCAAGAAGCACATGCGAATCCATACTGGGGAGAAGCCGTACCAGTGCCAGTACTGCGAGTATAGGTCTGCAGACTCTTCTAACTTGAAAACGCATGTAAAAACTAAGCATAGTAAAGAGATGCCATTCAAGTGTGACATCTGTCTTCTGACTTTCTCAGATACCAAAGAGGTGCAGCAACATGCTCTTATCCACCAAGAAAGCAAAACACACCAGTGTTTGCACTGTGACCACAAGAGTTCGAACTCGAGCGACTTGAAACGACACATAATTTCAGTCCATACGAAGGACTACCCCCACAAGTGTGACATGTGTGATAAAGGCTTTCACAGGCCTTCTGAACTCAAGAAACACGTGGCTGCCCACAAGGGTAAAAAAATGCACCAGTGTAGACATTGTGACTTTAAGATTGCAGATCCGTTTGTTCTAAGTCGCCATATTCTCTCAGTTCACACAAAAGATCTTCCGTTTCGGTGTAAGAGATGTAGAAAGGGATTTAGGCAACAGAACGAGCTTAAAAAGCATATGAAGACACACAGTGGCAGGAAAGTGTACCAGTGTGAGTACTGTGAGTATAGCACTACAGACGCCTCGGGCTTTAAACGGCACGTTATCTCCATTCATACGAAAGACTATCCTCACCGTTGTGAGTACTGCAAGAAGGGGTTCCGACGACCTTCAGAAAAGAACCAGCACATAATGCGACATCATAAGGAGGTTGGCCTGCCCTGATAGTCCTTCTACAGACATTTATGGAGATGTTGGCCTTGAAGCAGAAATCTCATTTTAAAGCCAGTCAGTCTCGTTCACATACAATACTGTATATTGATTTATGCTGTGTACAAATAGAATTATTGCTTCTAGTTGAGTTTTGTTGTTTTTTTTTTTTTTTTTTTTTTTTACATTTTGTTTAATAGTGTGTTCTGAATTCTATTCAGTTTGTTTAATAAATGGGGGAAAGCAGCAACAAATAAGTTGCTTTTAATAAAGTAATCCTTGATGCTATACTGGATTTTTCTATCTTACAAGTTTTATATTTATTTAAATATTTACCTTGCTTACCTTGATGGTACTCTTCTAAGACCATTTAACTTAAAGTTAAGGTAACTTTAGATTGGTAACTCTGAAAGTATTCGTGTTGACTCATTTTTTTTTTTTTTTTCCCCATGAATTTCTCACAATAAAATTGTCAGAGACATCTACTAACATAAACGGGAGATTTTACAGTCAGGTCTAATTATCCTAACATGGAAGTCCTTGACTTGTCTTGCTTGCTCTTCTCAGACCACATGACAGTGAAAGTTTCCATTTGAGCTTTTGCCACCCGGGCATCGCTGAGGAAAGAACAGTGGCTGGGTTCGTCTTTACTTTTCATTTCGTTGAGCAGACAAGCTGTACTTTTTGCAGGGAGGGGGGGGTGGGGGGGGGGCTTTCTTTGGTGTATTTACATCTTTTGTCAGCATAGCAGACTTCTAGAAAACTTCCTTGACAAATTTTGCTTGGTCATGTTGTATTTTGATTATTCCGTCTGTGCTGCTTTGTCTCGGAATGGTTGTGTGTTACAAATGAGATTATCGAGGACTGCATTTTGGAATCTCCTTGAGGTAATTCGTGGCTCGTAGGATCTTTTGCGACTTTATATATGTAAATGTACCCTGAATTATATATATGCACATATATAGAGAACATGTATCTGTGTGTATTGTTTATTTTACATATTTATACACACAACCCCAGTAGTAGTTGTTTAAGATCTATAATGAAAAGTATTAAATTTACAATAACACGAAAGATGCAGGGATGCATGAGAGAGCATTTTGTAAATCATGCTCTTCAGAGAGACTACTCAGGTGAAGAATTAGAAGGAAAATAAGGACACTAGTATTTTTAAAGAGTTAAAGGTATTTTCTTTTAAATATCTTTGGTAATTGAAAAATAGACGTTACGATGTTTCTAGATAGAATGTTTTCATACAACTTCAGCTCCATGCCTTTATATTTTTCTGAAAAGCTAATGAGCATCCAGGCAGAACTCCCTCCGTTCTCTCAGAGAAACTCTTGAGGGAACTCTGTGTCTGTCACCCAGTGAAGGGGGATTAAGGAAGCCACAGCTCCGTGTCCCAGAGATTGGGTGCTAATGATGACTTCCGCTTGGCAGGTCCAGCCTGCTCTGTTATGTCTTAGTTACAGTTAGCAAACTTTAAAAACCTGAACACCCAAATTGGCTTTGGTTAGAAGATAAAGGTGTGTTTAAGTGCATGAGGAAAATCTGAGGCCTTATTTGGAACATCCCCAAGTCTTTCACGGTTTCGTTTTTCTTTGAGAGTTGGTATTTTTTAAACAGTTCTGAATCAGTTCAGAAACGCATACACTGAAGTCAGTTACTTAGAATTGGATCATGCGAAGATGGGTCTTGGAAAATGGAAAACAGTTTTTGGGGTCCTTTAGATGGGATGTCAGCATGTGAGTATCCGGCACGTTGTAGGAGATTTAGTAAGGACTTTTCTTCCCACCTGATAGCTGCCTTGCCACTTCATGATGGTGCTCCTTCCCCTTTGTGCTGTTCGGGTTTAACCTTTCATCTTTCTCTTTGCCATTGATACTTGTATTCAAGAATTCTATTTATAGGGTTAGAAATCTAAATATTTGGTGTTTGGCAAGCCTCTGAAGTGCTAGATTGATTTCATCCACTTGGAAATCAAGTGCTTTAGGCTGGTATGAACTCCAGCCTGAATGCCAGTTAAAGCCAAGGCATGGGCCTATCCCAGCGGGAGCTCCTGTGCTCTCTTGGCCCCATAAACATTCTTTTTTTTTTTTTTTTTTTTTTTTTAAGCGTAACTTACAATTGTGTGATTCATTGCCCTGCAGTACTATTCTTGAAAGCTCTGTCTGTTTTTTTGTGAGAACCTTTAAAATCTCCCTTAATTTCTTTTTCCCAGAAGTCATGTAAAAGAAAACACTTAAGTGAAAGTGGAAAGTTATTAACTTTAAAACATGCTGTAAAATTAGTACAGAAAATATAAAGAATTGGTCATTTAACTATATTTTTTTAAATAAACTGAAAGATAAAGAACACAACACTGTACACACTTTATATTTCTCTTACATAGTCTGGAATCATACACAGCTATTTTCTTTTTAAAGCACAATATTGAAACCTTTAAAAGGTATTTAAGGGTTTGGTCAAGTGAATATGATAAGATGTATTTGTCTGTATAAAGAGAAAATGAACTTGTAGTCACTGTTATGTACTGACATTAGTTACAACCTAGTTTTAATTCTTAAAACAATTTTGATTAGCAAAGCTAAAAAAAATGGATGTTTCAGTTAAATGTTTTAAAGAGGTACAGATTTTTACAAGGACATAATATAAGTTATTGTTCTGTAGAAATATCCTATTAAATATTGTATGTCCCTCCCTCTGTACACTTTGTAAAAAAAGTAAAATACATAAAAAGAAAATCATATAGGGATGTGTGACATTATTGTAATTGTGTACTTGAGAATAACGTGCAAAAATAAAAATCAGAATATTTTCCTGTTAATGGATGTTTAGTCTATTTGATACCAGTACTAAGTTAATGCTTTTTCTTAAGGAAAAAAATGTACAGTTTTTGTAAACCTAATAAACATCAAAAGCAGTGGATTA
->XM_008507523.1 PREDICTED: Equus przewalskii developmentally-regulated GTP-binding protein 1-like (LOC103540855), partial mRNA 
-ATGAAAGATGAAGAGTCATGGACTCTGACAGGCATGACATGGAGAACGGCCCAAGGTGTGGTCCCACCAAGCACTAGGGGTCTTCAGGTCCCCTCCCCGAGAAGCCTGATGACCTACCTCAAGGGCATGACTGGACCTGGCCACCAATCTAGGGCAGGGTGGGGAGACAGAAGCTGTTCTGTCCACCTAAGCTCCTCTCAGCCCACCCTTCGTGGCCCCCAGCTCTGTCAGCTGCACCCTGGCAATCGGATAAAACTGGCTTCCCTCCAGGATGGGGACGGAGGGTGGTTGGCTGAGAGGGAGAGGACTACTCCGCTCTGTCTCTTGCGAGGAGTAGGACGTACGCACCTGCGCACTGCAGTAGCGCCTGGTGGTCGTTGGCCGGTCCACTGGTGGGTGAGCCTCCAGGGACTCACCGCTGTCAGCAGCACCTTAGCCAAGATCCTGAAGATCGAAGCCAAGATGGCTCGGACTCAAAAGAACAAAGCCACAGCACATTACCTCGGGNCGGTTAAGGCTAGCTTTGCTAAGCTTGGCAGAGAACTCATTACTCCAAAAGGTGGTTGTGGTGGTGGGCCAGGAGAGGGTTTTGATATGGCCAAGACAGGTGACACTAGAACTGGGTTTGTGGCTTTTCCATTTATGGGGAAGGCAACACTGTTCAGTAAGCTGGCAAGGGTATATTCCGAGATGGCAGCCTATGAGTTCACTACTCTGACATCTGTGCCTGGCATCATCAGATACAAAGGTGCCAAGATCCAACTCCTGGATCTCCCAGGTACCGTAAAGGGTGCCAAGGATGGGAAAGGTAGAGGCCATCAAGTCATTACAGTGCTGCAAACGTATAACTTGATCCTGATTGTTTTGGATGTCCTGAAACCCTTGAGACATAAAAAAGTAATTGAAAATGAGTTGGAAGTCTTCGGCATTTGCTTGAACAGCAAACTCCCTAACACTGGCTTTAAGAAGAAAGATAAGGGAGGGGCTGGCCCCGGAGGCATTTATCTCATGGCCACTTGCCCTCAGAGTGAGGTGGATGCTGAAACCGTGAGGAGCATTCTGACTGAATACAAAATTCATAATGCTGATGTCACTCTGCTTAGCAATGCCACAGCGGATGACTTCACTGATGTGGTAGGAAGAAGCAGAGTTTATATCCCCTGTATCTATGTGTTAAATAAGATTGATGAGATTTCCGTTAAGGAATTGGATATCATTTATAAGGTGCCTCACTGTGTAGCCATCTCTGCCCATCACTGCTGGAATTTTGATGACTTGTTGGAAAAGATCTGGGCCTATCTGAAACTAGTGAGGATTTACATTAGACCCAAAGGCCAGCTGCCAGATCACAGATCCCCAGTGGTGGTGCATTACCCCAGGACCATGGTGGAGGATTTCTGCTTGAAGATTCACAAAAACCTTATCAAAGAGTTTAAATACACTCCAGTCTGGGGGCTTGCTGTGAAACACAATCCTCAAAAAGTGGGTAAAGACCATACGCTGGAGGACGTCATTCAGGTTGTGAAGTGGAACCTTTCCATTTCCCCATCTGCCAGGCCAAGCACAGCAGCTTTCCCGGTGATCACCCTACTCCAATCCCCTTCTGGCTTTGGCAGCCTCTTGATCAAGATTCAGGGGAGGGAGATGGAGACACTCAAAGTGGAACTTCACTTGTATTATCTTGGTGTCATCTTGTATATTGAACTGCATAAAGGACATGACAGGAAAAAAAGAAAAAATAATGACCACATTCGCTTAGTTGCTCTGCGATTCTCCATGACTACACCAACAGTTGGGACTATGAAAATACAGGGCCCACAGCTGATGCTCCATAAGAGAGATCTTGGATACCTGATGCTTCAAGCCCA
->XM_052662140.1 PREDICTED: Budorcas taxicolor EH domain binding protein 1 like 1 (LOC128068878), transcript variant X12, mRNA 
-AAACGGCGCGCTCGCCGCTCAGCGCTCCAGCGACCCGACGCGCCCCAGACGACCCCGCCGAGGCGGCCAGATCATCGGCGGGCCCTGCGGCGGCCGCGGCGGAAAGAGCGGCCCCGGATCCCGCGCCTCGGACCCCTCCGCACGGACGGGGCGGGCGGCGCGGATAGGATCCTGGAGGCCATGGGGACCTGGGCCGGGCCAGCGGTCGCGGACTAGCGGGAGTCCCGGGTCTGAGGAGCGGGCGGCGGAGGCGGCGGGGCCATGACCTCAGTGTGGAAGCGCTTGCAGCGCGTGGGCAAGCGGGCCGCCAAATTCCAGTTTGTGGCCTGTTACCACGAGCTGGTGGTGGAGTGCACCAAGAAATGGCAACCGGATAAGCTGGTGGTAGTGTGGACCCGGCGGAACCGACGCATCTGCTCCAAGGCCCATAGCTGGCAGCCGGGCATCCAGAACCCATACCGGGGCACCGTGGTGTGGATGGTACCTGAGAATGTGGACATCTCTGTAACCCTGTACCGGGACCCCCATGTGGATCAGTATGAGGCCAAAGAGTGGACGTTCATCATTGAGAATGAGTCCAAGGGGCAGCGGAAGGTGCTGGCCACGGCCGAGGTGGACCTGGCCCGCCACGCAGGGCCCGTGCCAACCCAGGTCCCGCTGCGGCTGCGGCTGAAGCCCAAGTCAGTGAAGGTGGTACAGGCCGAGCTAAGCCTCACTCTGTCCGGGGTGCTGCTGCGGGAGGGCCGTGCCACGGATGATGACATGCAGAGCCTTGCGAGCCTCATGAGCATGAAACCTAGTGACGTGGGCAACTTGGATGACTTTGCCGAGAGCGACGAGGAGGAGGCCAATGGTCCAGGAGCCCTGGAGGCACGGGCACGTGTCCCCCAGCCAGGCCCAGGCAGTGCCCTGAGGCTGGGGCATTTCCCAGAGACCCCTCGGGAGCTGAAGACACTTTGTGAGGAGGAGGAAGAGGGCCGACTGCGGCCTTGGCAGGCAGCTGCCAGCCCTTCTAGTGCTGAGGATACCAGCCCAGCCCCTGTGAGTGCCCCTGCACCCCCAGCTAGGGCCTCCCGGGGCCAGGGCTCAGAACCAGCTACTGTAGCAGGGGGCCAGGTAGGGCTCAAGGCCCCAAGGCCCCCTGGAACCCTGCCAGAGACAAGGTCCCCAAGACAGCCAGGCCAGGACGTGGCCCCCACTCCAGCCCCTCGGCTCCAGAAAGGCTCTGATGCCCCCTGGCCCCCAGTCCACCAAGGAGAGGATGAGGCCCCCAAAGCCTCCAGGGCTCCCCCAGCAGGAGTGGATTCTGCTGTGGAGACCCAGGCTCGGGCAAGCCCTCAGGAAGGGACAGAGGCCCAGGGAGCTGGGCTGGGCCCAGGCATTGAGAACAGAGACTCCAGCAACTCTTTGGAAGGGCAGAAACCCAAGGTTGAGGAGGGGCCCGCTGGAGACAGGGCAGAGGCTAGTGGGGTGGATACTGGGCATGGGCCAGGAGTCAGAGAGGTGAACAGTCAGAGGTCAGTGGTCAGACCTGGGGAGGTTGAAGAGAGTTTAGAGATCGGTCACGTGGATGCGGAGCAGAGGTCAAAGGTGAAACCTGTGGACACTAAGGGACCAGAGGCCACAGAAGTGACATCTGAGGCAAGATTCAAGGGGACTCCCGAGGCTCCTCCAAGGGGCTCTCAGGGGAGAATAGGGGTCAAGACCAGGGATGAAGCTCCCACAGTCTTGAGCCCAACGCCAGCAGAGCCTGCGGGGCATTCCAGGCATCTTGGTGACCAGGCGGCCAGGGCTGCTGCAGGCCAGGAGAGAGAGTGTGCAGAGGTGAGGGGCAGAGCCCCTGGTGTTGGGGGGACAGGCCTGGAACAGGGGCCCTCTGCTGGAGCACCAAGCGCTGGGCCCCAGGTGAGCTGGTACGAGGGGCCCCCAACAGCAGCTGAACAAGGGGTGATGTCCAGGGATCTGAGGACCTGGGAAGTAGAAACTGGGGATTCGAGGGTCCTGGGGACAGAGCCTGGGGTGGCAGAGTCAGAGTTATCGGGGACCCAGGAGATCTCAGGGTCCCCAGAGATAGTGTCTGAGGCAGCAGAAGCGAAGACCTTGGGGACCCAGGAGACAGAGGCAGTGAGATCGGGGGTCCTGGAGTCAGAGACTGCTGAGATGGCAGAGTCTGAGGATCTAGGGATCCAGAAAACAGGGACAAGCATTTCAGGGGCCTCAGGGACAGAGGGTGGGACGGCAGAGTGTAAGGCACTGGGGATCCAGGAAACAGAGGCTGGGGGCTCAGGAGTTCTGGGGACAGAGACTGGGGTGTCGGAAACTGAGATGTTAGGGACCCAGGAGATATCTGGGTGCTCAGGGATACAGAGAAAGGAAGCTGAGACAGCAGAGTCTGAAATACTTGGGGCCCAGGACACAGAAGTGGGGTGTTCAGGGGTCTCAGAGATAGAATCCAAGATAACAGGGAGCCAGGAGACAGAGGTAGGGAGTTCAGGGGTCCCAGGGACAGAGACTGAGGTAGCAGAAGCTGAGATACTGGAGATCCAGGAGATTGAAGCTGGGGGTTCAGGGCCCCCAGAGATGGACACTGAGACCCTGAGGACCCGGGAGACAGAGGTGGGGGGCTCAGGGGCCCCACAGATGGACACTGAGACCCTGAGGACCCGGGAGACAGAGGTGGGGGGCTCAGGGGCCCCAGAGATGGACACTGAGACCCTGAGGACCCGGGAGACAGAGGTGGGGGGCTCAGGGGCCCCACAGATGGACACTGAGACCCTGAGGACCCGGGAGACAGAGGTGGGGGGCTCAGGGGCCCCACAGATGGACACTGAGACCCTGAGGACCTGGGAGACAGAGGTGAGGAGCTCAGGGTTCTCAGGGTCAGAGGCTGGAATGGCAGAGGGTGAGGGACTAGGGAATCAACAGACAGAAACTACAGTTTTAGAGGCGGAGAAGGGAAAGGCTCGGACTTCCGGGGTCCAGGAGGCAGAGACTGGACTTGGGGAGACCCTCAAGTATGAGGCTTTAGGGGTCCCAGTCGTAAAGCATGAAGTTTCAGAATCCCAGGGAACAGAGGCAGAAACTACAGTTTCAAGGGGCCAGGAGGCGGAGATTGGGATTTGGGGGGTTTCAGAGGCCAAGTCTGGGGTTTGGGGGGCCAAGGAAGCAGAGGTGGAAGTTTCAGGGGCTTCAGAAAACCCATCTGGTATTTTTGAGGCCCAGGAAGCAGAGGCTGGGGTCTCAGGAGCCGAGAAGGGAAAAGAAGCTGAGGGAAACCTCCCAGAGGCCAGCCTGATGGAGGTGCAGGTGGCCAGTGGGGCAGGGGCTGAGGTGTCCAGGCCCTCCGGGGCCTCTTCCCCAGAGGAGCCTGAAGAGGACAGGAGGCTGCCGGGCAGCCAGGCACCACCTGCCCAGGTCAGCTTCAGCCAGTCCCTGTTGGAGTGGTGCCAGGAAGTCACTGCAGGCTACCGCGGTGTGCGCATCACCAACTTCACCACGTCCTGGCGCAATGGTTTGGCCTTCTGTGCCATCCTGCACCGATTCTACCCAGACAAGATAGACTTTGCCTCCCTTGACCCCCTGAACATCAAACAGAACAACAAGCAGGCCTTCGATGGCTTCGCGGCCCTGGGCGTGTCGCGGCTGCTGGAGCCGGCGGACATGGTGCTGCTGTCGGTGCCCGACAAGCTGATCGTCATGACCTACCTGTGCCAGATCCGCGCCTTCTGCACGGGGCAGGAGCTGCAGCTGGTGCAGCTGGAGGGCGGTGGCGGCGCGGGCACGTACCGCGTGGCCAGCGCCCAGCCGAGCCCCCCCGACGACCTGGACACCGGGGGCCTGGCGCAGCGGCTGCGTGAGCACCGGGCCGAGGCGCCCCAGCAGCCCCAGGAGGCCGCGACCCGCGTGGACGCGGCGGCCCCCGAGGCGGCCTCCAAGGACCGCGGGGCCGCAGCCGCCCAGGAGGCGCGCTCCGCCGAGGCCCCGGCCGACGGTCCCGGAGCCCGGGCGTCCGTGCCCCCAGCAGAGGGGCTGGTGAACGGGGTGGGGGCGCCGGGCGCCGCGGGCGGCGTGAGGCTGCGGCGGCCGTCGGTTAACGCGGAGGCCGGGCCGGTGCCCCCGCCCCGCGCGCACGGCTCCTTCTCGCACGTGCGCGACGCAGACCTGTTGAAGAAGAGGCGCTCGCGACTCCGGAACAGCAGCTCCTTCTCCGGGGACGAGCCCGACTCCGGAGCGGCGGGAGCGGCGGCGGAAGGCACGAGCCCTGACCCCAGCCCTGCCCCTGGCCTTCCCGCAGCCTCAGCCCCACAGCAGCCCGCTGGTGGGACTCCTCCGGCGGAAGAACCGCCCCCAAGCCCAGGGGAGGATGCTGGGCTGCAACGGTTCCAGGACACAAGTCAGTACGTGTGCGCGGAGCTTCAGGCCTTGGAACAGGAACAGAGGCAGATAGATGGGCGGGCAGCCGAGGTGGAGAAGCAGCTAAGGACCCTCATGGAGTCAGGTACCGACAGGCTGCAGGAGGAGGTACTGATCCAGGAGTGGTTCACTCTGGTCAACAAGAAGAACGCTCTCATCCGGAGGCAGGACCAGCTGCAGCTGCTCATCGAAGAGCAGGACTTGGAGCGGAGATTTGAGCTGCTGAGCCGGGAGCTACGGGCGATGCTGGCCATTGAAGACTGGCTGAAAACGGCTGCGCAGCAGCGCCGAGAGCAACTCCTGCTGGAGGAGCTGGTGTCGCTGGTGAACCAGAGAGACGAGCTGGTCCGGAACCTGGACCAGAAGGAGCGGACCGCCCTGGAGGAGGATGAGCGCCTGGAGCGCGGCCTGGAGCAGCGGCGCCGCAAGCTGAGCCGGCAGCTGAGCCGGCGTGAACGCTGCGTGCTGAGCTGAGGCCACGCGGGCCCAGAAGCCTTCGCCCCTCCCGGTCCGCAGCCTTTCTCGCCGCCGCGCCGGATCGCCGCTTTGGCCCTGCGCTCGGGAGGACCGGACCCTCCCTGGTGCCGCGCGCGACCAGTAGGGGCCGCCGTGACCCTTTACCGGGAAAGGAAGCGCAGCCTTTCGGGCCCCGACGGACGAGGGCGGCTGGCTGGGCGGCCGCGCCGTCCGGGCCGTATTTATTAGTCCGTGTGAGTGAGTGTGCGTGTGTGTTCGTGGTGGACTGAGGGTCCCAACCGTGCCCACCCAGAGCCCGTACCCAATGGCCGGACCCCGCTGGCGAGCTCCAGGGGTGGGAGGGACGGATGGTGAACTGCCGCGCTCAACACCCCGCCCCCTTCCTGTTCCTAGCGAGCAATAAAGTTGGAAAAGGCCACGCCAACGCGCCTGGGCTTTCTCAGGGTGACCCGGGCTTTCAATAGACGGAAGGGGGTGGGGCCTTGGCCGATACGGCGGTCTGCGATCCTCACGGGGACTGTGCAGGAATGGGGAGGTTTTCAGATGCCAGCCGAGGCAGGACCAGAGGCCTGACCTCTGCCTTTAAAGGATGATGGGGTTTGGGTTGTTGATGGCTGTAGGGAAGTCCCGTTTCGAAAGAAGAGACGAGAACA
->AY338304.1 Uncultured bacterium clone BREC_93 16S ribosomal RNA gene, partial sequence 
-TGAGCGGCGGACGGGTGAGTAACGCGTGGGTAACCTGCCTCATACAGGGGAATAACAGTTAGAAATGGCTGCTAATGCCGCATAAGCGCACAGGACCGCATGGTCTGGTGTGAAAAACTGAGGTGGTATGAGATGGGCCCGCGTCTGATTAGGTAGTTGGCGGGGTAACGGCCCACCAAGCCGACGATCAGTAGCCGACCTGAGAGGGTGACCGGCCACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGAGGAAACTCTGATGCAGCGACGCCGCGTGAAGGAAGAAGTATCTCGGTATGTAAACTTCTATCAGCAGGGAAGAAAATGACGGTACCTGATTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGTAGACGGACGGGCAAGTCTGATGTGAAAGCCCGGGGCTTAACCCCGGGACTGCATTGGAAACTGTCCATCTTGAGTGCCGGAGAGGTAAGCGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCTTACTGGACGGTAACTGACGTTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAATACTA
->XM_053628787.1 PREDICTED: Ictalurus furcatus calcium/calmodulin-dependent protein kinase (CaM kinase) II delta 1 (LOC128609903), transcript variant X2, mRNA 
-GAAGAGGCGAAAGCGGATCATTTACGTCTGAGCAGCCGCAGGAGCAGATCGACGCTCTCAACTTCACTCAAGCGCGAGCCATCTGCAGAACACAGACACAACACACCTGCGCGAGCGGAGAGCTGACAGACTGGACTTTTTCTTCTCTCCGCAGCATTTAGGCGTTTACTTTCATTCTGTGAAGCACAGCTGAGGAAGCGAGGCATTAGACTTGATTGCTGTTCAGATTTGTCCTGGCTGTCTTTCTCGGCATGGCTGCGACCACCTGTACCAGGTTCACCGACGAATATCAGCTCTATGAAGAACTGGGCAAAGGAGCCTTCTCAGTGGTGAGACGATGTATGAAAATCTCCACTGGACAGGAGTACGCTGCCAAAATTATCAACACCAAGAAGCTGTCTGCCAGGGATCACCAGAAGCTGGAACGTGAAGCTCGCATTTGCCGTCTGCTTAAACACCCCAACATTGTGAGACTCCATGACAGCATATCTGAAGAGGGATTCCACTACCTCGTCTTTGATTTAGTCACAGGAGGGGAGCTGTTTGAAGATATTGTGGCCAGAGAGTATTATAGTGAAGCTGATGCCAGTCATTGCATTCAGCAGATCCTTGAGGCCGTTCTCCACTGCCACCAGATGGGAGTGGTCCATCGCGACCTGAAGCCTGAGAACCTGCTTTTAGCCAGCAAACTTAAGGGAGCTGCAGTGAAACTGGCTGACTTTGGCTTGGCCATTGAAGTGCAGGGAGACCAGCAAGCATGGTTCGGATTTGCTGGCACTCCTGGTTACTTGTCTCCTGAGGTGTTAAGGAAGGAACCCTATGGGAAGCCAGTTGATATGTGGGCTTGTGGTGTGATTCTCTACATCTTGCTGGTGGGCTATCCTCCATTCTGGGATGAGGATCAACATAGACTTTATCAGCAGATTAAGGCTGGTGCCTACGATTTTCCTTCTCCTGAGTGGGACACAGTGACCCCAGAGGCCAAAGATCTGATCAATAAGATGCTGACAATCAACCCTGCCAAACGCATTACTGCTGCAGAGGCCCTCAAACACCCATGGATCTGTCAACGCTCTACAGTGGCCTCTATGATGCACAGACAGGAGACTGTGGAATGCCTGAAGAAGTTTAACGCCAGGAGAAAGCTAAAGGGAGCAATCCTGACCACGATGCTTGCCACAAAGACCTTCTCAAAAGGGAATCCATATAAGAAGCCTGATAGTGTTAAGATCAACAACAAAGGCAACGTAGTCACCAGCCCTAAAGAGGCAGTCCCCTCTCCTGCTCTGGAGCCTCAAACTACTGTTATCCACAATCCGACTGACGGAAGCAAGGTAGAATCCTCCGAGAGTGCCAACACCACCATCGAAGATGAGGATGTGAAAGCACGGAAGCAGGAGATTATAAAAGTGACCGAGCAGCTGATCGAGGCCATCAACAATGGAGATTTTGAAGCTTATACCAAGATCTGTGACCCTGGACTGACCTCTTTTGAACCTGAGGCTTTGGGGAACCTGGTGGAGGGAACAGACTTCCACAGGTTCTACTTTGAAAACTCTCTCTCAAAGAGCCACAGGCGTACCGTCCACACCATCTTGCTGAATCCTCACGTGCACCTGCTGGGAGAAGACGCTGCCTGCATAGCTTACATCAGACTCACCCAGTACATCGATGCTAACAGCATGCCTCGCACCATGCAGTCAGAGGAGACTCGGGTGTGGCATCGCCGTGACGGCAAGTGGCAGAATATTCATTTCCACCGCTCAGGCTCGCCAACCGTGCCCACCAATTAACGTGGTGTCCTGACCAGCGCAGTTCAGTGTAAAGGACTTAATGTCAGATGGCCACTGAGTGTCTGCTTTATTCAAACCCCACCTTTACAACTTCTCCACCCTGTCAGTCTTGTTTACATATCGTCACTGCTGGACTTTAGCCTACACACAGGTGGGGAATTAATATCATTTTGTATTAGGATGTGTGTATGCGTGCGACTTGCACGCTCTCCTCATAAACCATTGATGTTAAAGACTTATGTATACATATTTTTTTTTTCCCTTTTTATAATTTAATGTTCTATTTTCTATGGTGTGAAAGTAGGGCGTCACACTTGCTGATATATCTTTGGGTGTGTGGGTACATCAGGAAAAGAAATGCTTGATCTCTGTACACAGTCAGATACAAAGTCAAACAGTACATAGACGAATCTGGGCGCACGTGTGACATGTTCATATTAGAGTGATTAGTAATCTAGGCACAATATCCGTCACTGATCTTGAGGATATGATTAGCAGCAAATCAAAGCCAATTCAGTCTTGTTTCAGTGCTTTTCTATTTTAAGTGCAATACAGCTGAAAAAAATTCATTATGAATCTGACAAATGAGCTCGCTTTTGTTTTTTTGGTGAAGTTTTTGTGAAGTTGTGTGAAGTGCTATTCCTGCTTTATCTTTTAGAGAATTGACAGTTGACCGTGATCTTAGTTCTGCGAGCTTTGTTCGGTTTTAGGTTGCTATGGCCTAATGGGTTTAGCAACACTAATGTGCAAAACTGACAAAGGAAGCACATTTAGCCTACAGTTCGCTATTTTATTCTGATGTTTTCCACAGCATCACATGAACACAGTAGAAAAAGTGTAAAAATTTCAATTAAAGAATGTACTTTATCAATCAACACGAATAATTGGTAAACCAAACTATTTTATTTTATTCAGTTGTTGTGAGAGTTTTATGCTTCTGTTTTCATTTTTATATTGTTTACTAACATTTGATGGGGGTATTCTTTGGAAAGAAAAAAAAACGAGTTTTCTCTATTTTTCACACCTTCCTTAATTAATTAGCATTAGCTGTTATGTATTGCATGAAACATCTTTTATCAACTTTTATGTACTTTTATGTACTTCATGTTTATGATCTTGTGATGGTTCCCTTCTCAAGGGTGAAGTAGAATAAATGGTTTATGCTTTGTATTCCATACTGTCCATTTAAACCGAAAAAGAGATGAGTAGTTAGTGCAGTTTGAAAATGATTTATATTTGCAAAAACTATTACGATTATCAATGCAAAATCCAAAAAAAAAAAAAAAAAAGAAAAATAGGAAAATTTGAAATGGGAAACATTTGACAGATTAATATAAAAGATGATTTATTTGTAGCACAGTTGATATTTGATTTAAATAAAGCTTGCCTTTGTTTACTCAAACTTTGTTTAAGATCGACTGTAATGCTTCATAACATCAGTTTGTGGAAAGCATTGGGAGGAAACCTGAATTTGGGACTGATTATTAATCAGTCTGATTATTAATGATTGTTTAATTTGGATTCAGTGTCTGAAATGCTATCAGCGGTTTGAGACTTAAAGATTATCAGTTGTTATCTAGTTCCATTTTATTTGCTTTGCATTTAAAATTTTTTGTTATTTTTGTTACTTTTTTTTTATTCTAGTCCAGTTCCCTTTGTACTTTTTATTGCTGTAACTAGATGAAAATCCCCAATCCCACAAACCTGTACACTAAACAGAAGTACAAATACTCGAGCAGTTAAAAAGGACACGATAAAGCAAATAAATAAACTGTGAAAACATCCTCTTTTTTTCTCGGTTAATACATATTCATTTTGAGATTAAGAAAATTAAGGAATTTAAATAGTTTGTATATGTGGATACAGAGAACAACATATTACTGTGCACAGAAAAACATATTACCAACCCAATGCATGAATAAAATATTTCTGCCTATTTTTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTGTTAATCTTAAATTGGGTTTAAAAGTTAAGTTTAATGGAAAACTATTAGCCATTTTGTGGTTTCTGTACATAAAAAAGGTTGGGGTTTTTTCCTCCTTTGTTTTTTTGTAAAAACTTTTTACAAAGAAAGTGTCCCATGTTAAATAAAAAAGCCCCAGGCACCAGCA
->XR_003317481.3 PREDICTED: Ursus arctos uncharacterized LOC113259124 (LOC113259124), transcript variant X3, ncRNA 
-GGGCCATCTGCAGAGCCCTCTATTGGACGAGCCATGCTGAGGGATCCCTCTGGGAACCAACCAAAGGCGTCAATCTGGAGCCGAAGAGGCGTTATCGCCCGGCGGACCAGTTTTGGAGGTCAAAGCTCCGCGGGGCGCAGCTAGTGGCGGAGCGAGCTGTGAAGGGAGGGTCTTCCACTTGTCGCCAGCGTGAACTCTGGTGCCCCGTGAGTGTTCGGAATGAACCCCCAACTCCGGACCCTCAAATCCGCCCACGCCCAGGCGTGCTTGTCTCTGCTTCGACTTTGTCATGTAACACTTTCTCCTTTTTTCCCCTGGGATCCTTTTGGTCCCTCCCCGTCTCTTCGCGCTCGGAAAGCCGAATTTCGCTGATGCTCTCAGCTTAGAGGAAAAAATTTTGTGCGGAATTCAGTCCTTCCTTCTGTTAGGCAGCAGTCGTTGGATGGGAGGGACTAAAAATCACTTGGTGCCCTGACAAGATTTGTTACTGTTGCTAAAATCGTCAACTCTAATGCTTTAAGGGAGATAACTTCCTGCAAATCCAGAACTTTCGGATTACTTCCGAGCTTAAAGAGCACGCCACATGAAGATGAAGGCAGAGATTGGGTTGATGCTTCTCCAAGCCAAGGAAGTCCAAGATGGCCAGCATACTCTCAGAAGCTATGGGAAAAGCCTGAAACAGATCTTTCCCTCACAGCCATCAGAAGAAACCATTCATGCTGATACCACGATCATGGATTCTAGGCTCCAAAACTGAGCTGCTTACAGAGTGTTATTAAATATGTGGATACATTTCGGGCACCTGACTGGCTGTTGGAATAGCATGAGACTCTTGATCTTGGGGTCATGAATTCAAGCCCCACACCAGAGGGAAAATACAGACGTCCATTAACTTCAATCCCTGGAGTCAGAATTCAACTTGAGACATATGGATGGGAGCTATGCTCCATTTGTGGGATGGGAAGAAACCAGTTCCCCTTTTCTAGCCTCACATCTGTTTGGATTGTATCTTAGTAGGCAATAATGAGAAGGCTGCCTAGGGCTGACTCAACCATAAATATTAGAATTAGGAGAAGTATTAGAATTGCGAAGCCATGTTTTTTTGTGAATGGTGCTCCCTATTCTTTGATTAAGAGCTTAAACCTCATTCACACTCATGACTTACAGGCTGAGCCAGCAGGAAGGTGGACACTAACTCTAATCTCCTAGGAATGAGGAATGAAAAACCAAGACAAGCAGACACTGTAAAATTGTTTTTGTTTTTTTAATGCAGGTCAAATATCCTGAAACATACATGTATTTTGATAGTCTTCTAATGCCACTTTAGTTCAAATATTAAAGTAACACACACGAGCTAAGAGAATTCAATATTGTTCCAAGGCACTTACTGAATCTCCATGACTAGATGAAAACAAGGACAATTAAGATGAACAATTAGTATATAATATAAAAATAACTTTTTGCTTACAATTTACAAAATGTATTATTATTACAATCTTTGATCTCTGATAACCTGCAATGCTGGCTGCATGAATCCAGCAATTTTAAAATTCAGAAACTATTTTCTAAAACTTCAGGGCAAATAATTTACAAATAAGGTACACAAAGATTTAGACCATGCAGAAATTTCTTACATCTTCTGTTAATAATATTTTATGACTGCAACTTTATCAAATTATATACCTACTTGCCCTGTACATATACAAAATAATGCATACATGATAAAACATTAGCAAAAGAGTAGTCCTTAAATTCAATTTATCATAAAAGTATTACTATATTAACATGTCTACAAGCAGCGTGTAACAGGTTAAGAGACATTAAGGCAATAATACTTGAAGTTACAAAATAAACCAATGTAATACTTTCCTAAGTGTAGTATAAGGCAGGTAGATGGTCCAAGCAAAAAAATACTAAGGTAACAATCTACACTGCTGTTAGTCCCACATTTTTAAGATGGAATACTATAAATCTGGCTTTCAGTGGCACTTGAATTTTCCAGTATAATTTAAAGTGTCTTTTAGCTCCCTGAATCATGTCCATTCTGAAGGTGGATCTCTTGGTCCTTTGGGTTTTCCACAGCGATTACGAAAACCTGTAATCAAAAGACCAGAGTAATTGGTCAGTGTTCAGAAATGTATTTTAATGTACTAGAAACTCTTAATTTGCTTTGGGTAGTTCATTTAAGAACCTAAATAAATCAGCACAAAGTATGGTAAACTCTGCCTTCAGGAAAGCCTGAAATGATGGCAAATAACCGTTTCTCATTCTTGCCAGCACTAACTACATAACTAAAGTTTTAAAATTATTTAGTAAACAAATTACCAATATCTGTGGCCTCTGTTGGACTTTCTGATATTTGATCTTTCTTGTTACTGAAAAGAGGCGGACATTCTGTACAAGTCTCTGTGTGAATACCTCCTGCTGGATGATCTAAAATGCAAAATAAAGCCATTGTTAACCACC
->XM_011504069.1 PREDICTED: Ceratosolen solmsi marchali transmembrane protease serine 3-like (LOC105365808), mRNA 
-TTTTCAATTTAAATTTTTGCTCTTCAGATACTATGAAAATTATTTTCAAAACATTAATTGCACTTCTACTGGTGCAAGTCAGTTATGTAAATTCGTGGGATCATCTCAGGCACGCCAGTCCTGGTCAGTTTCCACATCAAGCAGTATTGGTATGGATCGGAGCATTACCATTTCCTCCATTTCACTTATGTGGTGGTGCAATCTTGAACGAATTCTGGATTTTAAGTTCAGCGTACTGCGTTGTTGATATATTACATTTAAATAACGTACGTATCAAGGTTGGTAGTCACAATATTTCTTTAGATGACGAGCACGTACGAAACGTTGAGGTGGCAAAGATTATCGTTCATGAAAAATATACTAGGTGA
->XM_048344465.1 PREDICTED: Perognathus longimembris pacificus LRR binding FLII interacting protein 1 (Lrrfip1), transcript variant X23, mRNA 
-GACGGCCCCGCGGCGGCGGCGGCGGACGGCGGCGGACATGGGCACCCAGGGCTCGGGGCGCAGGCGGCTCCCCAACCGGGAGCGGCTCACGGCCGAGGACGACGCGCTCAATCAGATCGCGCGCGAGGCGGAGGCCAGGCTCGCAGCGAAGCGTGCGGCGCGGGCGGAGGCGCGGGAGATCCGCATGAGGGAGCTGGAGCGGCAGCAGAAGGAGGTTGAAGAGAGACCAGAAAAGGATTTTACGGAGAAGGGGTCTCGCAACATGCCGGGCTTGTCTGCGGCCACGCTGGCCTCGCTGGGCGGGACTTCCTCCCGGAGGGGAAGCGGAGACACCTCCATCTCCATGGACACCGAGGCTTCTATTAGGGAGATTAAGGACTCCCTAGCAGAAGTGGAAGAGAAGTATAAGAAGGCCATGGTGTCCAACGCCCAGCTAGACAACGAGAAGACCAACTTCATGTACCAGGTGGACACGCTGAAAGACACGCTGCTGGAGCTCGAGGAGCAGCTGGCCGAGTCCCAGCGGCTCTACGAGGAGAAAAGCAAGGAGTTGGAGCGGGAGAAGCACGCGCACAGTGTCCTGCAGTTCCAGTTCGCCGAGGTGAAGGAGGCGCTGAGGCAGAGGGAGGACATGCTGGAGAAACACGGAATAATCCTAAATTCAGAAACAGCTACCAATGGAGAGACTTCGGACACACTAAATAACGTCGGATACCAAGGCCCGACTAAGATGACAAAAGAAGAGTTAAACGCCCTCCAGTCAGCCGGCGACGGGACACTGGATATTAGGTTGAAAAAGCTCGTGGATGAGAGAGAGTACTTATTGGAACAGATTAAGAAACTCAAAGCGCAGCTGGAGGGGAAACAGAAGAACAACAAGCTAGACAATCTGCGATCTGAAGATGAGGTCTTGGAAAACGGGACAGATGTGCACGTCATGGATCTACAAAGGGATGCCAACAGACAGATCAGCGACCTCAAATTTAAACTTGCAAAGTCAGAGCAAGAGATAACTGCATTAGAACAAAACGTAATAAGGTTAGAGAGCCAGGTATCGCGTTATAAGACAGCTGCTGAAAGTGCAGAAAAAATAGAAGACGAACTTAAGGCAGAAAAGCGGAAACTCCAAAGAGAGCTTCGCTCCGCATTGGATAAAACGGAAGAGCTTGAGGTGAGCAATGGCCACCTAGTGAAGCGTCTGGAAAAGATGAAAGCGAACAGGAGTGCACTTTTGTCCCAGCAGTAAGCACCAGCCTGCGGGGCAGCTGCGCGTGTGTGTGTGGCCCCTGGGCTTTTCCCTGTCCTATGAGAGCGCCGCTTCCCCTATGCCTCCGCAATGCCTCCGCGGAACGCTAGGGGGAGCCCCTGGCCCTTCCCACCCGGGCCACATCCACTCCAGAGAAGCCCGCAGCCGCCGGGGCGGCCTGGTCTGCAGCCGCCTTCTCCAGGCTGGGCCGGCTCTCAGAACCTCCAGGTTTCTTTGTAAGCACACTGGGCCTCGTGGAAGCTCGGCGTCTCCGTGGCACAGCTCGGGCCGACCGAGGCCAAGATGAACGTGGAACATGAGTTGTCTTTTCATGTGTCTTGCTGAAGGTTAAGGGGAAATGTTACCGTGTGGGGACTCCTCCAGGGCAGAACTACAATTTGAGTGACTTCCGTAGTATCTCTTAGTCTATGCTTTTCATACACGAAACACTGTGGAACCACAAGCCATTACCAAGCGAAACTCTCACTGCGAACAAGAGGATGGTCTAGGCGTAAAAGTGACCTTAAGAAAACTCTTTACAGGCAACAAATGAAGCTTTTCTAAGGGATTTTTTGCATCTGTTCAGTCATGAGAATACTTTTTTCCAGGGTAATTAGGCAATAGCTTCTCTGAAAAATGACAGCTTTTCATTTGCATTATATTTGGAATTGAAGTTGTTAACTTCTTTTAAAGAATGTACTATTAGGAAAATAAAATATGAAATGTTAAAAGACTTGAGCAATGTGGTTTTTATTTTTTTC
->XM_005356914.2 PREDICTED: Microtus ochrogaster leucine rich repeat containing 71 (Lrrc71), transcript variant X2, mRNA 
-CAGTTGCTGGCCAACTGGGTCTGGTGAGTGGCGATCCTCAGGGCGAGGCCCACAGAGTCCTGTCTCATCTTGCCTCTCACTCAAGGAGTCCAGAGCCACCAGAATGTCAAATGAGCCGAGTGCCACGGGGACCTCACCTAGGACACCTCGTCCTGGGGCCCAAAAGTCATCCGGTGCGGTAACCAAGAAGGGGGAGCGGGCTGCTAAGGAGAAGCCAGCAACTGCCCTGCCTCCAGTGGGTGAGGAGGAGCCAAAAAATCCCGAGGAATACCAGTGCTCGGGGATCCTGGAGACAGACTTCGCAGAGCTCTGCGCACGGTCAGGCTACACGGACTTTCCCAAAGTCGTCACCCGGCCACGGCCCCATCAGAACTTTGTCCCTTCTGCCTCCATGTCAGAAAAACCCACCCAAGACGACCAGCGGCTGTCGGCATCCTGTAGCCAGAACAGCCTGGAGAGCAAATACGTGTTCTTTCGGCCCACCATTCAGGTGGAGATGGAGCCAGAGGACAGCAAGGCAGTGAAAGAGATCTACATCCGAGGTTGGAAAGTTGAGGATCGGATTCTGGGTATCCTCTCCAAATGTCTACCCTCCCTCAGCCAGCTGCAAGCCATCAACTTGTGGAAGGTGGGGCTGACGGATAAGACCCTGACCACGTTCATCGCCCTTTTGCCTCTCTGTTCCTCCACACTCAGGAAGGTATCTCTGGAAGGGAACCCACTGCCGGAGCAGTCCTATTACAAGCTCATGGGACTGGACAGCACGATCGCTCACTTGTCTCTGAGGAACAACAACATCGATGACCATGGGGCGCAGCTCCTAGGCCAGGCACTGTCCACACTGCACAACAGCAACAGGACCCTTGTTTCACTGAATCTGGGATTCAACCACATTGGAGATGAGGGCGCAGGCTACATTGCGGATGGCCTGAGGCTGAATCGCTCTCTCCTCTGGTTGTCCCTGGCACACAATCGTATTCAAGACAAAGGAGCACTGAAGCTGGCCGAGGTCCTGCGCCCCTTTGAGCTGACCCACAGGGAGGTGGTGGAGAGGAGGCGCCTGCTGCTGGAGAAAGGATCGCAGGAGCGGTCACGATCGCCTTCCTCCTCCCGACATGGGGACTCCAAAACAGAGCGTGAGAAGTCTCAGACAATGGGGATCAGCAGTGTTGCTTTGGCAGACAAGCCAGAAAAGATGCAGACAGTGAAAACACCCAAGGGCCTGGGCAAGAAAAAGGAGAAGTCAGGGGAAGTTGTAAAGAAGGAGGAGAAGTCAGGCTCCGGGCAGTCACCCACACAAGGAACCCCTAAGAAAGAAGATGCCACAAAGGCAGGCAAGGGGAAGGTCACCATCCCCGAGCAGAAGATGAGCAAGGGAAAAGGGCCCAAGACGGGGAGCAAAGAGAAGCGCAGCATCCTCCTGGAGTCTGAGCTGGTTGTCGAAGCTACAGAGATGGTCAACCCTCTCCTGGAGCCTGTGGAGCACCGAGATGGGAAAGTTTTCATGCCTGGGAACAAGGTCCTTTTGCACCTCAACCTCCTCCGAAACCGAATTACAGAAGTGGGGTTGGAAGGTTTCCTTACTGCCGTGCAATACCAGGTTCAGGTCTCCAAGCCCAAGAGTTCATCCAAGGGTCCCTTGGGGCTGCTGTGGCTATCCCTGGCGAAAAACTGCTTTGACCCACAGTGTCCAACATACACCATGATTCAGGAACTGATGCTGCCAAGGGACCCTGTGAAGGCCAAGGTCAGGGAGGAGGAGGCCACAGCTACCTAGGCTTCCCATGGGAGACACCTTGGACCATTATCAGCCTATTGCTGTGCTATTCTTTGAAAATCACTTCAGAACTGTTGGGAACATTTGGGCTCCTGAGTCTGTTCATATTGCCTGGTTAGGCATGGCAGAGTGGTGGCCTGAATCACACGGTATCTGTTGGGGGGATGAACTGAGCTCCTGGCTCCACCTCCCGAGTGCCCCAGCAGCATCCCCCAGCCCCTCTCTGCCAGCATGCACACAGCTGATGATGGAACTAGGACCCATCCCCCAGCATCCTTGCTGCTTATCTCCAACCCATGTGTTTGCCTGGCTTGTGAGACAAATGCACTCTGGAGAGGGTACTGTAGCCATATTTGCATAGCAAAGGCCAAACATTAGACATGGCAGGTGAGCAACCTGAAATCATGGACATCCAGAGTTGGGACTGCCAGGCTGCCTCTAAATTCTGGAGAGCCCATGCTAACCTACAGGGAATCTCCAACCTCTTTCATCTCTTGGCCCTCCGCACTGGCTGCTGAGTGGCTCCAGGGACATCTTTCTCCATTGCTCTGAGTCC
->XM_030788246.1 PREDICTED: Chanos chanos meiotic nuclear divisions 1 (mnd1), mRNA 
-ATGGGCGGACAGTCTAAGAAGAAAGGATTGAGTTTGGAGGAGAAGAGGAGTCGCATGATGGAGATATTTTTTGAGACTAAGGACGTGTTTCAGCTGAAGGACATTGAGAAAATTGCCCCCAAAGCCAAAGGGATCACGCCCATGTCGGTGAAGGACGTCCTCCAGAGTCTAGTGGACGACAACATGGTGGACTCAGAAAGAGTGGGAACCTCCAACTATTACTGGGCATTTCCCAGTAAAGCTCTCCATGCCCGTAAACGCAGACTGGAAGAACTGGAGAAGCAGCATTTGGAAGGGAAGCAGAAGAAAGCCAGTCTACAGCAGGCCGTGGACAAAGCCAAAGTGGGACGCCAAGAAACGGAGGAGAGGAGTGCTCTGAGGCAGGAGTTGCAGACCCTGAGGGAGCAGCGGGACCAGCTCAGGGAGGAGGTGGAGAAATACAGGGAGTGTGACCCTGAGGTGGTGGAGGAGATCCGCAGAGCCAATGTGACTGCCAAGGAGGCTGTCTCACGGTGGACAGACAACGTCTTTGCCATCAAGTCTTGGGCCAAGAGAAAGTTTGGATTTGAGGACGCACGGCTGGACAAGGCCTTCGGAATACCGGAGGACTTTGACTACATGGACTGA
->XM_051990939.1 PREDICTED: Antechinus flavipes zinc finger protein 665-like (LOC127557627), mRNA 
-ATGAAGTACTACCCACCTGCCCCTCCCATCGCCTTGCCCACCAGACGCCCCTTCCCTCTCCGAGAACACCCGCCCTCTCCGAAAACACCCGCCCTCCCTGGGCACACCCGCCTTCTCCGCATCCCCCTCTTAGGCGCCATCATGCTTGCAGTAACCAACGACACAAGAGTCAGCCGCTGGGAGAGGGCAATCATATGCCCACCCACCTCCCCCGGCACGCTCACCCTCCTCTGCTCTCCTGGTCTCCTGCAGCTTTTCTCCCCCTCTTCTGGCGAACCCGTCTCTTCTGTTGCCCTTGGTTACGACCCTGGTGCCCACACACTGCCCCTCACCCACATTCCCCCTCCGCGCCATACCTGGGCAGCCCCTCGACCAAGCAGCGAAGGAGTCGAGCTCCACGCCCGCTCGCTGTCCGTGTCTCTGGGATCAGGGGCTGCGAAAGCTTCCGGTCTAGCCAAGGAGGACAACATAGGGGGAGATAGGTACAAGGAGTGCGGTGACACTTATGGACTCTGGAAGGGCAAGGTGGCCCGCCTGAGCAGTGGGGATGATCAGGGGGACATGAGGGAAGGTGAAGTTGTGGAGGGCACAGGGCAGTGGAGCAGGAGAGTTCCTCGTGACCAACTAGTGAGGCCCCGCCTTTGCAAGCGCAGCCCTGGCCACCTCCTGGAAGAATCCTTTGTGGCTCGCAGTGGGATCGCATCTCTGGCTGGCCCAGCCCGGGGCCCAGCCAAGAGCGAGCCTACGTCCTGCCTCGCCTCCCTTCCCGTAGCCCCAGGGGCCGCCCGCCTCCCCCAGCCCACTCCTCTGTCTTCCTCCTCTCTGCTCTCCAGTTTAGCCTTTAGGATGTCCAAGCCTGGCCCAAGAGAGAAGCTTGGAGCCAAGGGAATGGCCCCTGAGACTCAGAGGACTCCATCCCAGAAATGTGTGACATTCAAGGATGTTGCTGTGTTCTTCAGCCGGGAGGAATGGTGCTCCCTGAACTCTTCACAGCAGAAGCTGTACAAGGAGGTCATGCTGGAGATCTCTCAGAACCTGCTCTCTCTGGATGGAAAGAATAGACCTAAAACCCAGAAGTCTACTCCAAAGCTGAATAGTTCCTGTGACTTTCATTTGAGAAAAATCAAGGGTAGTGAAAATAACTCAGAGAAGAAGCAAGGCAACTTGAAGAGTCATTCCAAAAAATTAAATATTATCATCAGGAAAACTCCTCAAGAAAAAAAAGATGATGACCATAATAAGTCTGAGAGTAGTTTTACTCCACAGTCGACCAATGAGGGTAATCAACTTGAGGGGAAGCCAGATCTTACTAAAGATCAGAAAAATCCAAGTGTCAAAAAGCCTTACAAATGTAATGAATGTGGGAAGACTTTCAGTCGAATCTCATACTTTAATGGACACAAGAGGATTCATAATCCAGATAGATTTTACGTTTGTAATCATTGTGGGAAAAAGTTCTCAAGACCCTACAAACTTGCCGTACACCAAAGGGTACATACTGGAGAGAAGCCTTATAAGTGTAACAAATGTGGGAAGTCCTTCTCCCAGACCTCATCCCTTACTCTGCATCAGAAGATTCATAGTGGGGAGAAGCCTCATAAATGTAACGAATGTGGGAATACCTTCAGCCAGCGCTCAACACTCACTGCACATCAGAAAAGACATACTGGAGAGAAGCCCTATGAGTGTGGTCAGTGTGGGAAGGCTTTCAGCCGGAGCTCGAGTCTTAGTGTCCATAAAAGGAGCCACACCGGGGAGAAGCCCTATGAATGTACCGAGTGTGGAAAGGCCTTCAGCCAAACCTCATCCCTTATTGTGCACAAGAAGATTCATACTGGAGAGAAGCCCTATAAATGCAACGAATGTCAGATGGCCTTCAGGGAAAGCTCAGCCCTTCATGTACACAAGAGGTTACATACTGGCGAGAAGCCCTATCAGTGTAATTACTGTGGAAAAGCCTTCAGTCAATCCTGCAGCCTTGCTGTACATAAGAGAATACACACAGGAGAAAAGCCTTATAAATGCAATGAGTGTGGGAAGGCCTTCTGTGAGAGCTCATCTCTCAGTACACATCGGAAAATTCACACCGGAGAAAAACCCTACAAATGCAAGGAATGTGGGAAGTCTTATTGCCAAAGCTCGACGCTCAGTGCTCATCAGAAGACTCACACCGGGGAGAAATCTCACAAATGTCATCAGTGTACAAAAACTTTTGTAAAGCCCTCCCAACTTGTAGCCCATCAGAGAATTCATACTGGAGAGAGACCCTATAAATGTGACGAGTGTGGCAAGACCTTCGGCCACACTAAAACCCTTCATGCCCACCGGAAGATTCATGCTGAGGAAAAACTTTATAAATGTGATCAGTGTGAAAAGTCCTTCCAGTGCAGTTCCTACCTGGCTGTGCACAAGAAGATTCATACTGGGGAGAAACCTCATCAGTGCAACGAGTGTGGAAAAACTTTTAGACAAAACATATCTCTTATAGTACATCAGAGGATTCATACTGGAGAGAAACCCTATAAATGTAATCAGTGTGAAAAGTCCTTTCACGGCAGCTCGTATCTGGCTATCCACAAGAAGATTCATACTGGAGAGAGACCTCACTCGTGTAATCAGTGTGGAAAGGCTTTCAGAACCCACTTGAACCTCGTTGTGCACCAGAGGATTCATACTGGAGAGAAACCTTATCAGTGTAATGAATGTGGGAAGTTCTTCACCCAGAGCTCCAATCTTGCCGTACATCAGAAAAGCCACACTGGAACCAAATCTTCTAAATCTAATTAACGTATGAATCACGGACTTGATGACACAGAAAATTCATGTGAATGTAATTTTTTTCTCCTCTTCTATCAGTGAAGAAAGGAGGAAAAAGCAGATGGGACTTTATATTTCCTGTAATTTTATGTAAAGATATATAGGAAGGGACAAGGGGAGAGAGCACAAGATGATCTGTACTTTTAACAGGACAAAGGAGGGTTGAACACATGCACACACACACAACTTTATCGTAGGAATAAATCAGACTCAAATCAATAAGCAGGGATGAGGAGTAGGGTTAATGTGGAGAATAATGGGGAGGGAATTATCAAAAGCACAATGAATGTTCACTTGAGGGAAGTGAACACTGAAGGGGATATTAAAAGTTAAAAAAGAAATCAAAGAAATGATACAAAGAGGACCCCATTATTTGGATAATGAGTAGGTAATGCAGTGGAGACAGTGTGAAGTCTGGAGCTGGAAAGATCTGAGTTAAAAAATGGCCTTAGATACTTAATAGCTGGATTACTCAGAGCAAATCACTGAATTACTTACCATCTGCCTCTATTTCCTCATATGTAAAATGGGATTAATAATAACACCTCTTTTTCAGGGTCGTTTTGAAGATCAAATGAGTTAATATTTGAAGTGATTTCTAGATCTTAAAGTATTTTATAAATGCTAGCTCTTAAGAATATCTGATAGGATAGTATTGTATCATAAGAACTGATGACAAGGACAGGTTCAGAGAAACTTGGGAAAACTTGTAACTGAGGCAGAGTAGTGAGCAGTACCAGGAAAACAATTTATGCAATAGCAGTATTATTTTTTTAAAATTTTAATAGCTTTTTATTTACAAGTTATATTCATGGCTAATTTTACAGCATCGACAATTGCCAACCTTTTGTTCCAATTTTTCCCTTCCTTCCCCCACCCCTTCCCCTAGATGATAGGATGACCAATACATGTTAAATATATTAAAGTATAAATTAAATACAAAATAAGTA
->XR_004154822.1 PREDICTED: Punica granatum luc7-like protein 3 (LOC116196428), transcript variant X3, misc_RNA 
-CAGTAAGTACAGTTGATCGCCCCTCCACCTCCACCGTCGTCAAAGGGATTTCTTGCTTCCCCCTCCCACTCCGAACCCTAGAAAGTAGAGGAGCTCTTCCCCTCACCCACCATCGCAGCTTCCTGCTATTCCATTTGAGGGAAAAACCTATTGTTCCCAGCTGAATTATCCATCTGTTCCGAGCTCTTACACTACGCGATAGCGAAATCTTATCCATAAGCCATGGACGCGCAGCGAGCTTTGTTGGACGAGCTCATGGGCTCAGCTCGTAACTTGACGGAGGAAGAGAAGAGGGGATACAAGGAAATCAGATGGGACGATAAGGAGGTCTGTGCATTCTATATGGTCCGGTTTTGCCCTCACGATCTCTTCATCAATACTCGAAGCGACCTCGGTCCGTGCCCAAGAATCCATGATTTGAAGCTGAAAGAAAGTTTTGAGAACTCTCCAAAGCATGACGCCTATGTGCCAAAATTTGAAGCTGAACTCGCGCAGTTCTGTGAGAAACTGGTGATGGACTTGGATAGAAGAGTTAGGCGCGGGCGGGAGCGTCTTGCGCAAGATGCTGAACCTGTGCCACCTCCTCCTCTTTCTGCTGAAAAATCTGAACAACTATCAGTGCTCGAGGAGAAAATCAAAAACCTGCTGGAGCAGGTGGAAGCCCTTGGTGAATCTGGAAAAGTAGATGAAGCTGAAGCACTCATGAGAAAGGTGGAGATGCTTAATACTGAAAAGACTGCTTTGACACAACCTACCCAAAATGAGAAGGTTCTGATGCTTACACAGGAGAAGAAGATGGCTCTTTGTGAGATATGTGGCTCGTTTCTGGTGGCTAATGATGCAGCAGAGCGGGTTCAGTCTCATATCACAGGGAAGCAGCATGTAGGTTATGGCATGGTTAGGGATTTCATAGCAGAGTACAAGGAAGCTAAGGAGAAGAGAAGGGAGGAGGAAAGACAAGCAAGGGAAAAAGAAGCTGAGGAGCGGAGGAAGCAGAGAGACAAGGAACATGATAATCAGAGAAGAAGTGAATCAAGAGACAAGGATAGATCCCATGATAAGGAGACAGACAGGGACAGGGAGCGAGACCGCTACCGGGAACATGATCGCTACCGTGAAAGGTCACGAGATCTCAATGGTAGAAGTGGTCGGGATGGAGGGAGGGGGATGGATTGGAGATCTAGGAATGGAAGAGATGGAGGCAGGGACAGGTACCGGGACAGGAGCAGGTCTCGATCCCCTGGTAGACATGGATACTGAAGGTCATCACAAAGTCCAGTTCACTAATATTATGGATCTTGTAGACAGATGAAGATCTGGACTTGTTGAGATTTCTTGAAAATATGTGATCTTCAAGGGTTGAGGTAGGTATTACCTTGGCGCTAGTCTGTTAATTTTACTATGCGGGTTTGGATTTTGTTTTTGGACCAGATTCATTGTCTCTGAAAGGCCCCTTTCAGAGTCTTAGCCTTTGCCTGAGCATGAATCTCAGCTGCTCTGATGTCCCAAGCATATTAGAGTTAATATTCTTGGAAGAAACATGCCTGGGCTTCAAGGAGATGCATTTGGAGTTGGGTTTTATGATGATCATTCTTAAGGCAAAAGACAGAGCACTGCCCTTATTCACGTTCAGTGTCTGGGGATCTGGTTATTGGGCTGGTTTAGCATGGATGAGAAAGAGTGATATATTTTGCTGGCTTTTTGCTGTCGGCTTAGAAACAGAACTTTATTTAGCTGATGTGCCATTCCATGATCAAGAAAAGTGGTAGCATTTCCACTAATGTCAAGGTATAAACTCGTGTCTCTATTACGCAGTGTTTTCAACTATGCAGGAAGAGAATGGTATCGTGGTGTATTATAGACTCGTAGATGGTGGAAGGGGAGTGAGGAGTAGTTCTTGCTGGGCGTTGGCAGACTTAATTTACTCTTCGGTTCCTAGCTGTCTGTAATGAATGAAACTGTAGGAGGGTGATTAAATCTAGAAAAGTCTCCATTTATGGTGGTGGCTTTTACAATCTGTTCTGCCCATTGGCTTGAGACTTGTTCGGTTGTTCCTGAACTTTCTAATGATTGTACTTGTGGTGTGAATGGTCCAACAAGCAGGCAATTCTGGACATTATACACTTTACCGGCTTTGAAGGGTATTCCGAACTCAA
->KX758048.1 Babesia microti Trx1 mRNA, complete cds 
-AAAAAGTATTGACAATGGTGAAAGAAGTACAAACTACTGCTGAATTCAAGACTCTAATTTCTGAAAATGCCATCGTTGTTGTGGATTTTTACGCAACATGGTGTGGACCTTGCATGAGTTTTGCCCCCAAATTTGAAGCCCTTAGTGCTGAGTTCCCCAACATCTTATTCATAAAAGTGAATGTGGATCAAAATTCGGAACTACAAGCACTATATTCCATCACTAGTATTCCGTCATTCAAAATTTTCAAAGACGGGGCTGTTGTAGATTCGTGCACTGGAGCTAATGATGCGATTTTGAGGAGCACTATCAAGAAGCACGTCTAGCAGTTATATGCAATGGGGACTAATACCTCTGGGTATCACCTAGCCCTGGGACTTCTGGGTTTGTCCATAATTTTATTCAATTTAAAAAAAAAAAAAAAAAAAAAAA
->XM_027775713.1 PREDICTED: Tupaia chinensis melanoma-associated antigen B4 (LOC102498282), mRNA 
-CGTTGGGGGTGAGGTGTCTGTGGAGGAGGTGCAGCCTCAGGCCGTTGCCGGAGGCGTCTGATCCGTGTCTTATCAGTTCTGAAGACTGTACACAAGTGGAGCCGAATAAGGACAAGCTGAATTGTTCTGCTTGGCTTTTAGGTGCCTGCCTTGTCAGCCCTCCAGCTGTCCCTGGAAAGACACCATGCCTCGCGGTCAGAAGAGTAAGATCCGTGCCCGGGAGAAACGCCAACAGGCCCGTGGCATGACCCAGAGCCCCAGGGTCCCTCAGATCACCGCAGAAGGGGAAGAAGAGTCTTCCCCGTCCGCCTCTCCTGCCTGTGGAGGACGCAGCTCTCCTTGCAGCTCTCCTGCTGCCTGCTCTCCCCCAGAGTCTCAGGGAGACCCACCCACTAGCTCCCCTGATGCAGGTGCCTCAGGCACAAAATCTGATGTAGGGGCCCAGAGCCTGGAGGAGGCAAGTCCAATAACCTCTCAGGCAGCANTTTGCTGCCCTATGGTCATGCAGAATAAGCAGCACTTCCCTGAGATTTTGAGGAGAGCCTCAGAGCGCATGGAGCTGATCTTTGGCCTAGAGTTGAAGGAAGTTGACCCTGTCAGTCACTCCTATGCTCTTGTGAGCAAGCTAGGCCTCTCCAACGAGGGAAGCGTGAGTGGTGACAAGGGGCTACCCAAGACCGGTCTCCTGATGACGCTCCTGGGTGTGATTTTCATGAGGGGTAATCGTGCCACTGAGGAGGAGATGTGGGAATTCCTGAATATGTTGGGCTTATATGCTGGGAGGAGCCACTTAATATTTGGGGAACCCCACAAGCTCATCACCGAAGATTTAGTGCGGGAAAAGTACCTGGTGTACCAGCAGGTGCCCAACAGTGACCCTCCATGCCATGTGTTCCTGTGGGGTCCCCGGGCCTATGCTGAAACCAGTAAGATGAAAGTCCTGGAGGTTTTGGCTAAGATCAGTGACACAGTCCCTAGTTCCTTCCCTTATCTGTATGAAGAGGCTCTGAGAGAGGAGGCAGTGAGGGCAGGAGGGAGATTTGCAGGCAGGATTGGCACTGTGGTCCAGGTCAGGCCAGGTCCTAGGGCCATGTCCCACTGCTCTACCCACATCTAG
->XM_046141267.1 Boeremia exigua Molybdopterin synthase sulfur carrier subunit (C7974DRAFT_388246), mRNA 
-CAGACACACACAATTGATGGTAAGCATCAACCATTTTCTTCGCACTCAACCCCCCTGTCTTGTGATGTTTTCCAATAGCATGTATTATCCGACTGTCGCTTCGGTGACGGCCTGCGGAACACCTTTTTTGGCTGATCAGAAAATTTGCTCACCCTTGTTGCACACTGTTCCTAGGACACAAAAGCTAACAAGGTCCAGTCATTGTTGCTGTCATGGTAGCCTCAAACCCTCCAGCGGGGCACTTTACCATCTTGTACTTTGCGGCCGCCTCGACCTATACAGGCAAGACCACGGAGCATCTGCCCGCACCCCTCCGGGTGCGCAACCTGTTTGCACAGCTCGATGCCGCATATCCTGGCTTCGGACTGAAGGTGTTGAGCAGCTGTGCTGTGACTGTTAATCTCGAGTATGTTGATCTAGACGATAGTGATGCTCTCGATGTGGATGCCGAGATAAAAGCAGGCGACGAGGTTGCTATCATACCGCCTGTAAGCTCAGGCTAGGGCCAGCAGTGCTGCAACGGAGTGGGTGCAATGTGGACCGAGGATCGCATGCCTGCTGTCTGGTTGAATGGGTCACGTGAGGAGGCCGGCCGCGGCTGCTGTTGACCTCACCGCACGAGGACTACGATTAGCGAGTAGCGACCGAGGACGGACGGTGGCTGGACAGTAGAGAATGTTAGCTCGCGTGTTAATTGTGATTGTGCCTCAACGTTCTCGCGTCACGCGTCACGCATCACGTAGCACGCTCTCACGTTGCAAAGTAAATGGCGGACTATGAATGAGCCGGACATCCTACTACGCGACAGTAACGTGGGGAGAATGCACAAAAACTCTACAGAATATTTTTTTGTCTACAATATAAGTAGTTCTTATACAAAGTTTAGCTTTTAGTATTGTGATAGCTACAAGTTCTATATGAAAGTTAGTGAGCTCTGCTTATCCACCGTTTTTTCTGAAACTTG
->JX990552.1 Uncultured thaumarchaeote clone H7_Parch519F_24 m 16S ribosomal RNA gene, partial sequence 
-CAGCCGCCGCGGTAATACCAGCACCCCGAGTGGTCGGGACGATTATTGGGCCTAAAGCATCCGTAGCCGGTCCTGCAAGTCCTCCGTTAAATCCACCCGCTCAACGGTTGGGCCGCGGGGGATACTACAGGGCTAGGAGGCGGGAGAGGCAAGCGGTACTCGACGGGTAGGGGTAAAATCCACTGATCCATTGAAGACCACCAGTGGCGAAGGCGGCTTGCCAGAACGCGCTCGACGGTGAGGGATGAAAGCTGGGGGAGCAAACCGGATTAGATACCCGGGTAGTCCCAGCTGTAAACGATGCAGACTCGGTGATGGGCTGGCCTTGTGCCAACCCAGTGCCGCAGGGAAGCCGTTAAGTCTGCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTTAAAGGAATTGGCGGGGGAGCAC
->XM_020038344.1 PREDICTED: Musca domestica GATA zinc finger domain-containing protein 4-like (LOC109613490), partial mRNA 
-GTGGAGACACGTGCCTATCCCGAATTAAGCGGTCAGCAGCGTGACACAGCCACACCCCTGTGGATTATCATATTGGCCATAATTGGAGGCCTGCTGCTGCTGGCGCTCTTCACCTATGCCATGTGGAAGTGTGGTTTCTTCAAGCGCCGAAGACCGGATCCAACGCTTAGCGGAAATTTGGAGAAAATGAACGAAGAGAAGCCATTCTTAAATTCATCACAGAAAAATAATCCTCGCGGTTTCTAACAAGAAGGAACAGTTGGGTGGGATTTAATGCAGCAACAGAAATTGAGACCGGAAACGGTTGAGCCACCCAAAAATTGCTGTAGCAAAACAACAAAGAAGGATAGCGATACTTATGATTTTTGGCAAACATTTCAACAAGAGAATAATAACAATAACAACAACAACCACAATACATCTAACAATATCTATCAGCAATTGGGTGCCCATAATAGTAAATCAATAAATGAAATTAATTTGGCCGAGGTACGTAATGCCCTGGACCGGCGAACAATTGCAATGGCGAGCAATAATCAAACAACAACAACAACGGGCAATAATCATAATCACAATAGCAATAACTCAGGAATACAACCGATGGGCGGTAGTGCTGAAATAATATTCACCTCCAATTTTCAATCATCCCCCTCGCCCAACAATCCTCATGGTGGCAATACATCAATGTCCACCGGCAATAATGTGGGTAGCAGCAATGAAAATCTTCTAGATATCTATAATGGAAATGGGAAATTTGCAAACTCCCCCAGTGATCTATATAAACAAGCGCCAGCCATATCGGCTAATGGTGCTTTGGTACCACCACCCTACAGAGATCCACCGCCACCACGTAATAGTCCTTTACAACAGCCAGCAATTAATGCGAATGCTTCAAATGCCCTCTATTCAAATCAACCACCACCACAACAACAACAG
->XM_019441788.1 PREDICTED: Panthera pardus solute carrier family 51 beta subunit (SLC51B), transcript variant X2, mRNA 
-CTACTCTGTGGAATTCCTCCTCTCTGGGTCACTTGCCTTGCCTCCCCCAACACTTAGCCCTCCAAAGGTCTTGTTTTACTGCTTCTTGTAGGGAATTTACATAAGACCATGACCTTCACTGTGAGAAAGCACAGGCTATAAAAGGCCAGGCTTGGCTCCCAGCTCTGTGGTTAAATATTGATAATAGCAGGAAACAGAGGCCTGGGGCGGGTATACCACATATCCCCCTGCAGTAATGGAACACCCAGACTGAGGGTCTTCCCCAGCCCATTGCCTGGGCTGGAAAGACAGTCCACATGTTTTCTCTTTACTTCAGATCAACATATAGGAAGGAAAGTATGGAGCTGCTGGCTCTTGCAGATCGTGAAAGCCAGGCGGAGCCTGTTTGTCATCTAAGGCCACTCATTCAAGAGGTCATTCACCCTGGAGTGACAGAGGAGGTTCCAGGCCTGGGCGTGTGCTAAGGGCAGAGCTACCAGCTGGGCCCCACTGCCACAGGCTCTACAGCACTGTTCCCCCAGGTGACGGCTGTGACGGGTGCTCAGGCACAGAGACCATCCAGTGCTCCGGTAAGGGGAGGACATAGAAACCAACGCTGCTCCCAGCAGCAGATCAAGGCAGGCCCAGGAAGTCAGATCCCAGGTCTTTAATTTTGGTGTCTCAGTTTGCTGTTTGTTAGATGTGCACCTCGTCTTCCTTTTCTTCATCAGTAGCTAGTTTCCCTGACATCATCCACTGAACAATTCCTCCTTTACCTACTGGGGTCTTCAGGGCTTTGCTCAAGGGCCAGAACCTAGGAGCCCAGGCGGGCAGCTCGGGAGCAAAGGGGCCTAAGGATTTCATTGTCAGAAACGTATCCCAACCGTGAACAGGGGCATGGACCACAATGACGGTGTCATCCAAGCTCCAGCTGGCACCGTGGTGCCTCAGGAACTGCTGGAAGAAATGCTTTGGTTTTTTCGGGTAGAAGATGCATCTCCTTGGAATTATTCCATCTTTGCCCTGGTGGGTGTGGTGATTGTGATAAGCATCGTCCTCCTGAGAAAGAGCATCCAGGCAAACAGAAATCAAAAGACACTGAGGAAAAACAAACTGGAAACAACAACTCTGGAAGTCCAAGACTTGGCTGAGGCCGGAGCCAGAGAGGACAACAATCTGAACATGCTAAGAGAGACTTTGCTCTCAGAAAAGCAAAATTTGGCCCAGGTGGAAACTGAGTTAAAAGGGAGAAAGGTGCCACTGGTTCTCCTTCCAGACCCACAAGAATCCGAGAGCTAGAAGGGGTCCAGAGCACCGCCCCATGTTGTCAGCAGATTCAGTGAATGAACTGCAATCAAAATATTGTTATGAAAAAAAAAACCCTCCCTTTTTATTAAAATGCATCTGAAGTGGGCATTTGGAAATGCAGTTTGTTCCAATGGGGGTGGTTCAACACAAGGGGCTTGGAGCAAAA
->AY749834.1 Labidiosticta vallisi 16S ribosomal RNA gene, partial sequence; mitochondrial 
-TGCAAAGGTAGCATAATCATTAGTCTTTTAATAGGAGGCTGGAATGAAAGGTTTAACGAAGTACTAACTGTCTCATTTTTATATTAGAATTTAATTTTTAAGTGAAAAAGCTTAAATTTTGTTGGAAGACGAGAAGACCCTATAGAGCTTTATAACCAGTTTTCAAAATATTTTTAGTTAAATATTTTATTTTTATTAAATGGGTTATTTTGTTGGGGTGACAAAAATATATAATTAACTCTTATTATTCTATTGACCATAAATTTATGATTATTGGATCCAATAATATTGATCGTTAGTCTAAGTTACCTTAGGGATAACAGCGTAATCTTCCCTCAGAGTTCAAATTTACGGGANGGCTTGCGACCTCGATGTTGGATTAAGATAATAGTTGGGTGTAGAAGCTTGATTAATAGGTCTGTTCGACCTTTAAATTCTTA
->KR841045.1 Uncultured Stella sp. clone OTU_9761 16S ribosomal RNA gene, partial sequence 
-TACGAAGGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCGCGCAGGCGGCCTTTGAAGTCGGGCGTGAAAGCCCCGGGCTCAACCCGGGAATGGCGCTCGATACTCTTGGGCTCGAGTTCGGGAGAGGAGGGTGGAATTCCCAGTGTAGAGGTGAAATTCGTAGATATTGGGAAGAACACCGGTGGCGAAGGCGGCTCTCTGGACCGATACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGG
->XM_050429574.1 PREDICTED: Quercus robur uncharacterized LOC126725075 (LOC126725075), transcript variant X1, mRNA 
-AAAAAAAAAAAAATCCCTTACGCCGTTGCCATTGTCTCCACACTGCAAAGTTTCAACACTTTGTCTCCACAAGTTGCTGTTTTGTGACCTCAATTGTGGCTGAGCCATAGCTGGACTTGACAAGCATGCCCAATGGTAGTATCTCTCTCTGTTGGTCTGTTTTGGCCCTTTTGGGTTTCCCGTTTCTGTGGTTAGTTTAGGATTTTATGTTTATTTGTTTATTGACTACTTTATTGATATTTGTGATATATTGATATATTTTATTATGTTTATTATATTTACAAGTGGTTAGTAGCTATCATCATTTATAATTTACAATTTGTATTTTATTTTTTAAATTTCATAATGGTGGCGCCGGCTTGTTATGGTTTATTTGATAAAATTGTTTGAGTATTTGTATATATATAATTATATTTGAACAAGTAGCAGTCTAATTATTTTATAGATACGAATTTACACCTTAGTTGCTTGGTTTTGTCTGACTGCACATAATGAAAGTACTAAAAAAACACTTTAGAATCAATTATAAATTGTCAGAAAGTCTTATAGTTCAGTAAATATTTGTTGGTGTTTTCAATACAGTCTAAAGCTCAAATCTTTCGTCCCCAACTATTGAATTGCCAAATTATAAAGAATTAATTATTAATTATTTTGGTATAGCACCCAAAAACATAAGCCAAAACTTTAGAGTTAATTTAATTTCTGAAATAAAACTTTTTTTTAGTTATGAAACTTTTTTCATACTTAGCTTGGCCCTCCCCAGGAAAAATTTATGGCTCAGCCATTGCCTAGTTGACTACATCCCAACAAGACTTAGGATTATTGAAGGGGTAGCAGATCATCACTTAGATGATCTCTGCTTTCCAATTAGACTATGCAACAAAAACACACTAGGAGCCCCTATTGTAGTCCCATTGCAACAATCTGTCCCAGGTAGACAAACTATTGTTGAACACAAGCCAGCCAATAACCGCATGCTTGCACACAACTAAAGGAAACTAGACTATTTCCCAATATGGAGTTTCTTGCTTCTTCAATCTAACTGCATTCCAGTCTTCAGTAGAATCAAATTTTCTTGATTAGGATGGCAACCACAGAAGCCGAAGAACTTTACCACCAACTTCAACCAAGCTTATCAGGCCTTGATGTACATTTTCAGATTTTAATTTAAAAAAAAATAATAAAAAAATAAAAAAATAAAAACTGTGAAATAGACTCTTTCTATTTCAAATGAAACCAAGAGAATCTTGTGATGATGTGGGTGTGTTTTTAGTAAGTGATGTTCATAACAGAATGGAATGGAGTCCATAAGGAAAGTGGTATTATGTACTCAACCAGGGACAAACAAGGACGTGTGAGTAAAATTGGTACAAGAGCACATTTCTAGGAGGAGAGAAATTTGAGTAAAGCTTCAAAGCTATCACTGAATCAAAAATGGGATAAACAAATATTTAATATTGATTTAAGCTAAAAATGGGATTGAGATAAAATAGATAATTTTTAAGCAGCTGGGGTTTTTTTTCAACAGGTTTTCTTAATGTATGGGGTTAATTTTACATTTCAGAGAACTCAAATGGCCTATTCATAAACCCACAAAAATTCCTAACCTTTATCTAAAACTTGGTCTGGAGTTTGAAATTGCTATTAAATATTTGTCTTTTTAACTAATTTGTCAAGTTTTTGGAAATTGCAGTTTGTGTTCTACTTTAGCTTATTATCCATTTTTCATCGCATTATGGCCTTTGTTATTGCAAGGGATTGTTCTAATTGCTCTGTTATAATTTCCAACTACTGAGTGGGTCAAGGGGAAGCAATTGGAAGAAGCTATAACCATTAAGAACACTTGCAGAAATGGCCAAAAAGGGCAAAGACACTCATAATAAAATAATGAAATATGAGATGGAAAGAGCACAAAGAATCAAGCAAAATCAAGAGAAAATAAATGCTTTGGGATTGAAGCATCTGTCAACTTTTTTGCCTAAATATGCAAATGTGGGAAGAAAGAGAGTAAGTGCTCAGGTAGATGACGACGATTGTGTACCAACTATTGGTGATGATGAGTTATCTAGTTCTTTACATAATGAGATGGCACCAAGATGTAGCACTCATTCACGCCGTGAGGAATTTACCCCAACAGTCCAGCATAAGGGCCCATTATTGAGACTACTTTGCAATGGAGATTCTGAGATGGCTCATTATAGGCGTGAGGAATCTACCCCAGCAGTCTAGCATATCGGCCCATCATCGAGCACACATCTTGGTAGAGATTCTCTTGTCGAAATTTCTACTAATGTAGAGGCACAGCTTGTGGGCACACCGTCTACCACAGATACATCGACTAGTAGACGTGCCCGTGGCATGACTCGTGGATTAAGGGTACGAGGACTTGTTGAGAAACATAGGAAGCTACCGGTCCTCATTGCCCCAGAGTTTTGTGCTCCTGTTGGTGAACATGCAGGGAAATTTGCTAGCCAAATTGGTGTACAAGTGCGTACGAACTTGTCCACTATGAATGCTTATAGTTGGAAGAATATTGATAGCGGTGAAAAAGAGGCGATCATTCAAAATGTGGCGGATCAATTTGATATACAAGGAGAATCTGTACTTGTCAACAAATCTCTAAATACAAAGTGTGGTAAATTATTGAGCAGCCACTACTACAAGTTGTTTACAAAATATAAAAAACTTGTAAAGGATGAAGGAAGCACATATGCAAGAAACCACCCACCAAAAAATGTCACACGAGAAAAATGGATTGAACTAATTGATGGAAAGTGGAGTGATGAAGATTGGCCGGCAATTAATACTTCGAAAATTTTAATTACAAGTGAAAAAGTCTCAACAAGAAATGCTAGAAACAGAAATAAAGAGGGAATGCTTGACAAACACATTCATAGATGTGGAAACAAGTCACTTGCAATTAGAGTGGATGAGGCAAGACGGAAAAATGGAGGTCATATTCCTAAGCTGGCACAAGTCTACTATGATACTCACTTCAATTTAAAGACAAAACAGTGGGTACACCATGATTGCGAACATACATATCAAGAGATGTTGAGAGTACAAGATGAGCATTGTAGCACTCTTGAAGCACAACCTTTGACCGAAGAGGAGATATCTATGATGGTTCTTAAGTCGAGATCTGGCTATGTAAAGGGACTTGGCATGAGGCCTTCCTCGTCTCTTAGGACTCTTGCCTCATCTTCCTCAACTCCGTATACTCAACAACTCGAAGGTCGAGTAGAAGAGTTCCAGGATGCAAACTACAAGCTGGAGGGCCGAGTAGAAGAGCTCCAAGATGCAAACTTCAGGCCAGAGGAGAAGATGGATTGCATCATACAATATTTGAGGAGCAAGGGCGACAATGACATTTGTGGTAGTGGGGGGAGCTCATCTACTAACTAGAACACACCTTGATATGGGATTGGTGACAGAAAGATAGCTTTTGTGGGACTACTTGAACTCAAATAATTTTTTGTAAAATTTGGAAGTTAAGACATCATTTGTATATAAATGGTTGTAACTTTGTGAACATCTTTATTACGTTTTTAGATTGTATGGATGTATTTTTTATGGATTTGGTTAGAAATGAATGGATTTTTATTTATTTTTTT
->XM_035972485.1 PREDICTED: Aplysia californica uncharacterized LOC101852208 (LOC101852208), transcript variant X5, mRNA 
-GCATGAGGAGTGAATTTTACTTTTAGTTTTAGTGAATTTAGTCGCTATTCCTCTTGACAAACTTGTTTTACAGTGATATAGTTCAATAAACATTAGGTCGTGCACTTGACTGTATGTTACATGAAAGGATAAAAAAGTAACTAGAAATCTTCCCCCTTTCTGTCCTGAAAAAAAAAAGCTCTTCACTCCCATTCTATTTTCCCTTTAACAACAATTAATTAATAAACTCAAGCCAGCCCAAGCGGATTTCTTGTTTCGTAAAATTATACTAACCCTAATCATACATTTTTAGAGAATTAACAAATAGTTACTTCCATTTCTAAAGAGCAGTTTGGGTATTAATGCGCTCTCTTGGATACCAACAAAACAAGTGACTTAAAATAAGAAAAATAGATATGGTGTCAACGTTTTAAATATTGATATCGACTTATTTTATTACTAATAAGATCCATTTTGGATCGAGAAATGAACATATTATATTGTATTTTATTAAATTTCTTGGAACTATTTATGTCCTTCTGAAAGGCGCAGTACCACATTGTTTATGATGAAGTAAAGTGGCGCCTTTCATTTTTTTTCCTATTGACTAAACGGTGAAAGCAATATCGAGTTTTTATAATGTATAGGGTCTTTTGATAGTCAAACAAATGTGCCAAGGATGTCTTCGAACGAAGTTGTAAAGACCGTTGCCAAAAAGTTGAAATACTACTTTGAGATCAAGCGTCTAGAGGATGGCTTTGATTTATCAGATGTGCACCAACCCCAACTGGATCACCCTCCTTTGAAAGCGCGTCCAGCACTTCAGTATGAGGGCCTCCATGACCGTGCCCTCAAGCACTACTTCAGCCAGCCTGAGGTGCGCGTGCAGCTCACACAGATGCACGGGCCAAATGGAAGGGGCACATTGCATGGGCGGAGGGAGCAACAAGTTCGCAAGATGCTGGACAACTACATGAAACATTACTCCTTCCAGGAAGAGTTTCTGAATGCCTCCCCAAGAAAACGTCCGGCCAGCCCAAAGAAGAACACACTGCCCAGCTGCTACTACTACCACACACCCAAGGGCTGTAAGATGAACACCAAAGCCACTGGAGTCCTCCATAGAGCCAAAAAACCGAAAAATCTGATTGGAGGCTGGCCTACCCTGAGGTCTGTCCCAGACCAGCACATCTCCAGAGGGGAGGCCACCAGGCTGGTCAACTCAGCCACCAAGATTCTTGTGGCCTCAGCCTATGATGACTCCTACATCGATAAACCCAGAGCCACTTCAGCCCAATCTCGGCCAAGATCACCAACTCCATCCCAGAGCACAGCAACAACCACGTCAGCGACAACTGCCACAAGCACGTCCACCGATGATCACCCACCCGTGCGGCCGCAGTCAGCCAAGTACCGATCACGCACAGTCATCAATGTGCCACAGCGCAGGGCCCAGGAGGAAGTGGCTGTGATCAGGGCTACTCAGACGGCGGCTGATTTTGACGTGGGAACCAAGCATGATCGGCAGCTGCTGGAGAAATATGACAAGCTGGAGGAGGAGGTCGATGATGGAGCATGGTGTGAGTACCAGGTCTATGTCTGCACGGGCACGCGTATTGGCTCCAGCACAAAGGCACCCATCAAGCTGACAATGTACGGGGAGAAGGGCAGAACAAAGGAGTTCATTCTCAATGACTCCAAACGCCACAAAATCCCATTCCAGAAAGGGAAGGAAGATCTTTTCATGCTGGCGGCGCATCACATTGGTAGGATCAGGAGAATACAGATTGGCCACGACAGGCCTGAGCTAAGCTATGCATGGTATCTGGAAGGGGTCACTGTCTACGACATGCATGCAAGGAGGATTTTCCAGTTCCCCTGTGAACAGTGGCTTTCTGGACAGGCCGGGGATAAGAAGACATACCGTATGCTTCAAGTTGATCGTGAGAGAGAGTTTATTGATGCACTGGGGGATGAAGCTGGCTTGGAGAAGTCCACGAGAAAACACAGATACTCTGCAGAGCCAGAATCATCGACACCCAGTGAGGCGTTCCGGTACCAGCCGAAAGGAGAGGACAATGTGAGCACACGGGTGCGACCGGGCGATGACTACAGCGACACCGACAGCTCTGACAGCTCTAGCTCCGGCCGCTCACAGGACGCCGAAGTTCCTGTCAATGAGCATGGCTCTACGCCACGGCAGAAGAAAAAGGTGGCTAAGGACGACTACGAGGAGAAGACACGGGCTGGGACTGTGATAACGCTCCATTCTGCCACTGACTCCCAGCAAGTGGACGAGATCTTCATGGAGCCCAAGGGACGAGCCGCTAATGCCAAGTCTGGCTCTGATTTTCTAGAGGGATATAAGACAGCACTATCTGCATCAGAAGCTGAGAAGAAGAGAGGGCTTGAGCGAGAAAGAGAGATGGAGCGAGCATTGCTCCAGGGCAAGAGTATTCACGAGGCAGTGCGGGATGGGGATGTGGACAGAGTCAAGGATCTGCTGCACCATTTCCCTGAGATGAGAGATTTTAAAGACGAGAGCAGCTGGACACCTTTGCACCTCGCAGCTGCCAGAGGAAACATCGAACTTTTGAGATGGCTACTGACCAGTGAGGCGGACATCAATGCAGAGACGTCCACAGGCTACAACGCTATGCACATTGCTGCCATGAATGGCCATGTCAGCTCCATGATGTTGCTTCAGGCGATGGGATCCTCCATATTTGGCTTGACAGCAGAGAAACAGTCGGCTCTGCACTTGTCTGCTAAGAGTGGTCATCTGGAGTGTGTCAAGTGGCTTGTGGCCAACCGTGCCTCTCTGCCAGCTGAGGATGCCTTCGGTCGCACGGCTCTCAAGTTGGCCGAGGAGTTCCGTCACGATGCCTGTGCTGACTTCCTGCGCATCTGCCTCCGGGAGCTTGCCAACCCCCGCAGCACGTTTGCCATGATGCAGGGACAGAGGTTGAGCCAGAGTGGCCTCCCTCCTATTGAAGAGGACACAGGCTCTGCCTCCAGCAGCTCACAGTGGAAGGACGATGTGAAGGGACACTCAGCCTCAGAGGATAGTGAGAATGAAAAGAAGAGCCAGAGAAAGTCCAAGGCTGAAGAAAAAGAGCTGGAGGAAAAACGGAAACTGTACAAGGAGCAGCACGAGCTGATGGAGGACAGAGGGTTGTCTTTCCTTGATAGCATCAGACAGGACGCAAGCAAGGCATAAAGCAGGAAAGCAGGAGTGAAGGAATGGAGGAGAGAAGGA
->XM_048336008.1 PREDICTED: Perognathus longimembris pacificus SH3 domain containing kinase binding protein 1 (Sh3kbp1), transcript variant X4, mRNA 
-TTTCGTAATTTCCACTCACGGAGAGCAGGAAACCCGGTGCAACCGGGCGCAGCGGGCCGCGATGCAGCAGCAGCAGCAGGAGTCGCCCCAGGGCAGCAGCGGTAGCAGCAGCAGCAGCAGCAGCAGCAGCAACAGCAGCAGCGGGCGGCGCTGAACCCCCCACCGCCGCCACTGAGGAAGAAGCCCGCCCAGTCGCCGCCGCGTCCTGACGCCCGCACCCGGATCCCCGCGCCCCGATCCCGGCGCCCAGAACCTCACGCCCGCCTCCGCCAACTTTCAAGCTGCCTCGGCGGCCCGACCCGGCTCGGCGCCAATGGTGGAGGCTATAGTGGAGTTTGATTACCAGGCCCAGCACGATGATGAGCTGACAATCAGCGTGGGTGAGGTCATCACCAACATCAGGAAAGAGGATGGAGGCTGGTGGGAGGGACAGATCAACGGCAGGAGAGGTTTGTTCCCTGACAACTTTGTAAGAGAAATAAAGAAGGATGTGAAGAAAGACCCTCTCACCAGCAAAGCTCCGGAAAAGCCCATACACGATGTGTCCAGTGGAAATCCTTTGCTGTCTTCTGAAACAGTTCTAAGAACCAATAAGCGAGGTGAACGACGGAGGCGCCGATGCCAGGTGGCATTCAGCTACCTGCCCCAGAATGATGATGAGCTTGAGCTGAAAGTCGGGGACATCATAGAGGTGGTAGGAGAGGTAGAGGAAGGATGGTGGGAAGGTGTTCTGAATGGGAAGACTGGAATGTTTCCTTCCAACTTCATCAAGGAGCTGTCAGGGGAGTCGGATGAGCTCGGCATTTCCCAGGATGAGCAGCTTTCCAAGTCAAGCTTAAGGGAAACAACTGGCTCCGAGAGTGATGGGGGTGATTCGAGCAGTACCAAGTCCGAAGGTGCCAACGGATCAATGGCAACTGCAGCCATCCAGCCCAAAAAAGTGAAGGGAGTGGGCTTTGGAGATATTTTCAAAGACAAGCCAATCAAACTGAGACCAAGATCAATTGAAGTAGAAAATGACTTTCTGCCAGTGGAAAAGACTATTGGGAAGAAGTTACCTCCACCTGTGGCAACTCTAGACCCATCAAAATCAGAGATGGATAGCAAGACTAAGACCAAGGATTACTGCAAAGTAATATTTCCATATGAGGCCCAGAATGATGATGAATTGACAATCAAAGAAGGAGATATACTGACTCTCATCAATAAGGACTGCATTGATGCAGGCTGGTGGGAAGGAGAGCTCAATGGTAGACGAGGCGTGTTTCCTGATAACTTCGTGAAGTTGCTTCCAGCAGACTTTGACAAGGAGGGGAGTAGGCCCAAGAAACCACCTCCTCCATCCGCTCCTGTCATCAAACAAGGGGCAGGTACCACTGAAAGAAAACATGAAATGAAAAAGATACCTCCTGAAAGACCAGAAACCCTTCCAAATAGAACAGAAGACAAAGAAAGACCAGAGAGAGAGCCAAAACTGGATTTGCAGAAGCCCTCGGTTCCTGCCATCCCACCAAAAAAACCTCGACCACCTAAGAGCAATTCCCTTAGCAGACCGAGCGCGCTGCCTCCGAAAAGGCCGGAGCGACCAGTGGGTCCGCTGACCCACACCAGGGGTGACTGTCCCAAGATTGATTTGGTGGGAAGTACTCTGTCTGGAATTCTGGACAAGGATCTCTCTGACCGCGGCAATGACATTGACCTAGAAGGTTTTGACTCTGTAGTGTCATCTACTGAGAAACTGAGTCACCCTACCACAAGCCGACCAAAAGCTACCGGAAGACGCCCTCCATCTCAGTCGCTCACCTCTCCAGGAACCATGGCAGCAGGCAGTGGCCCAGCCTCGCTGACTTCACTGGCTTCAGTCCCCCTGTCATCTTCTATGGGAGCACCCGGACACCGAGCCAATTCCCCATCTCTGTTCAGCATGGAAGGAAAACCAAAGATGGAGCCGATAGCCAGCAGCCAGGCGGCTGTGGAGGAACTCCGGACACAGGTCCGCGAGCTGAGGAGCATCATTGAGACCATGAAGGATCAGCAGAAACGGGAGATTAAGCAGCTACTGTCCGAGTTGGATGAAGAGAAGAAAATCCGCCTTCGTTTGCAGATGGAAGTGAATGACATAAAGAAAGCTCTTCAATTCAAAGTGAATACTTGATAATTGAGATTTTGCATTTTTCATCATGAGTCCAAGACTCAAAATTTTCTGCCCCAGCCAAAATGAATCCTGTGCCAAAAGGTTACAGATTTGCCATCACATGTCCCTGTTTAAAAGATTAGCACAAAAAGTCTTGATAGCACAACACAAATTCCATCCAAGAGGAGAATCTTCCCCATGGTTTAGGCCTGGGTCTGGCACTGGTTGTGACTTAGAGCAAATTGTGCTAAAAAGGCTTTTCTACCTTGAGATCTCATGTGAAACGAAAACTCAGGCAGTTTAGTCCATAGTGGTACTATTTTGATGATCTTTTCCATTAATGAAATGTAATTTCAGATTATTCTTTACAAGCTTTATAATTTTATGATTTTTTTAACCGTGTTTTGTCACAGAAGCCCCTAGCGTTTGTATTACACCTAGTCAGAAGCGAGAGTCTTGGTCTTTTTGCTTCAGGCAGAAAGCTGCCTGGCTTTATGTTCCCTTTAGGATTCTATTTACATATGCAATTTTAGGTCCAACCCTCCCTTCCCCTGCCAGCAGACCCACCCCCTAAGAGAAATTTAGCTTATATATGATGGTATATTTACAAAAAGAGAGAGAGAGAAAAAAAAATCTGGTATTTGCAATGATCTGTGCCTTCTTTTTACCACCCTCTTGATTGGAGTTTTTGTGATGCAGCTACCATGATTCAACAAATCAAAAAGAAAGAAATGAAAATCTACCACTTCTCCAAGTCCACTAGAGGCCGCTGTGTTCGCAGTTTCTCTCACCCTAGCCAAAGGTCCTAAGAGGAGACAACTGAGATGTCAGGCGTGTGCTGGATCAGACCACCTGTGACTTCTCAGTTTCTCCTACTTTGAGGTTGTTCATGAAATGAAAAATGGCATCCCTGCTTGATTTTTTTTTTTCATCAGCCAAGTGAAATCCCTGCTTCCTGTCCTTTGGCGCCTTTTTTTTTTTTTTTCCGTGAACAGCATATGCATTATTAAAGCAAAGCTAAATAAAAGTTCAAATGCAAATGAAAACAAGGGGGGGAAAGTTGTATTATTTCCTGCACTGGGTAATCCATGTGTGTTATTGTTTAAAACTGTATTCACACAATGTCATTTTGCCTTGCTCACTTGTAACCCCCCTTCCTCGGGTCCAAACGAATGGGACGAGGGTCTTGTTGAAGTGCAGCCAATGGATCTTTCTTGCATTCATGGAATTGCTTTTTTTTTTTTTTTCCTTTCTGAGGGAATTGATGTTTGCTTGTCTGATTTAATCTTTGTAGCACTTGGAACAGTTCAGCCTTAGATTATGTAACTGTTTTTCCTCATCCTCTGCTGAAAAACTATGGGGCATACCTTACTGCAAGATTGTTCAGGGGTTAGAGGTGGAGGGGCTGGTCCCTTAATGGCCCCAACAATGTCTGATGTGTTTCTAAGCAGCTGCTTTGTCTATTTCTTGCATTTTATAGTGAAAACTACTCAAAAAAATGTCATAGATTTGCACAACTATGAAGAATGAGAAATGATGTCACTAAAGGAATGATGCAAAAAAAAATCACATTATTCATCCTTGAAAATAGAACAAGTGTCTCTTTCCTTTCTCTTCCTCTCTCCCTCCCCTTTGCCTTGCTCTTGCCTGCATACTCCTTTCTTTCCTGAGAGTATTTACAGAGCCCAACGCCCTAGTCTTCCTTGGTGGGGACACAGTTAAGGGAAGGGAGTGTGTAAGGAGCCAGGCACCTTTTGCTCCGAGTGTGGCTATATGTACGGCTTGTGCAGCAGCCTTGGCCTCAGTGTGCATGGGGCTGGGAACAGCAAGTTTCTAAGGGCAGCACAAAACATTCCTGTCCCCCTTGAACTGTTCTAAGCATTTCTGCATTACACTTGAAGCCTTCAGAGATTTCCCACCACCTAATAGAACAATGAAGATTGGATTCTTTGGTGTTTGAATTTCTCATTTCTACATCAAGAAAATCCCAACTGATATAGCTTTATCAAAAGTGCATACAGAGTAAGATTGTGGACAAGGAAACGGCAAGGTGGAGGTATCCTCGGTGGGGCATTGGCAACCTGGAATGTGTAGGGCTGATGTCAGCGCCTCAATAGAGGCCATTGGCTTTCTTCATTTAAAGAGGGGAGAAGTAAGTGATTGTAAAAAGAAGTTGCCATTTTCCAGCCTCCTTATTGTCCCTCGGGCTAATCAGCAAAGAGGATTCTGCATCATGGGACTGGGTGAGCCTCTGCTTGAACGGCTACCATCTTTACTCTTGTCCATATGAATCCATCAAGGAAAGCTTG
->XM_001582328.2 Trichomonas vaginalis G3 uncharacterized protein (TVAG_2v0998720), partial mRNA 
-ATGAGTGAACTCGCTGTAGACGCACCAAAGGTTGTTGAAGCTTTCAATGGCGGCCTCACATGGCTCAACAGAAAATCAAACTCCCTCCAGAAGTTCCAACTTGACAAGATTTTAAGCGCTAAGGAAGAAGCAAACGGCGAGCTTATTATCGAGAGCAACCTCAAGATGTTCAACAAGGATCACCACTTCAGATTCGTTATCGATACATCCTTGGCACCAACAAGCCCAGAATACTTGAAGGACTTCAAGCAATTATCTCCATAA
->XM_018438955.1 Phycomyces blakesleeanus NRRL 1555(-) hypothetical protein partial mRNA 
-GCAAAAACTCCCCCCCTCTTTTTTTTTTTTTTTCTTCGTACTATTTTTTTTTTTCATTTATTATTTTTTATTTATTTTTAAATACTAAATGAATGTACCAGAACAACAGCTCCATGATGACCTTGTCAAGGACTGGATTCTTTCAAGTCGTAATGAAATCGATGCGTCCTTCATGGCTCACGTTTTATTAATGACAACAAAAAGCTCGACAGGGTTATCAGATCTTGTCAAGTTTCTCTCAAATTATTGGAAGGATGAAATTCACCGAGGAAAATGTGTCGAATTACTTACCCAGGTCACAACTCATAGTCGTTCCTCTCTTGATTATGAGACAGTCGAGGTGTTGATGTCATTCTCATGCGACCGTTTAAATGACTCTACATCAGTTCTCCGTCTTCTTGATCTAGTTGATGTCCTATGCTCAACACCTCATTTCGATGGCCATTACGCTGTCATGTTATGTCAATCAATCTTTCGACACATTGGCCAGAAAAAACAACCTCAGGGAACTCGCCACAAGATATTCTCACTACTCAACAAGCTTCTTCAGACTTACACTTCCGATCTACAACGTGCAAGAGTGAACTTTATTGGTAGCTTCGTAGCTTTTATGGATGGTGAAAAGGATCCACGTAATCTTGTGATTGCATTTGAAATTGTTCGATTCATCATTGAAAAATTTGACATTTCACAGCATGTTGAAGATTTATTTGACGTGCTCTTTTGCTATTTCCCAATAAGTTTTAACGCCCCGATTAATGACCCGTTCAGTATCACCACCGAAGACCTGAAGGACAGCCTCAGACGTTGCTTGGCTGCCACACCTTATTTTGCAAACTATGCTACTCCTTTACTAGCAGAAAAACTATTGAATACGACTGGAAGTGCCAAGAAAGATGCCATGGAAACAATTGGCCTTTGCGCTCCCGCGTACGGTGCACACGCTCTCTTACCACACGCAAAAGATATATTCGATGCCCTCGTAAACGAAGTCTATCATGCAACCGAGACCTCAATGGAGGCCACAGCTCTCAAGACCATTCATAATGTTGTGGCTACTCTAGGAACTGGTGTCAGCATAGCCAACATCAGAGATCCTGTAGAGAAAACCATTGATGCCTTACTATCCCAATGCGTCGAGAAACTTAACGAACCCGAACTCAAATATGCAAAAGCTGCAGCATTGATTCTACGTTCTGCCGCCTCTGCATCAGATCCTGCTTGTACATCTGTAGTACATACGACCTTCCCTATCCTTCACAATATGTTTAAAGATGCCAATTCTCTCAGTCGACAGCTCGCTGTTCTTGATATCTTTATCGAGATTCTATTTGCAAGTAAGAGTCTTTATGGCTCAATCGAGGATATTGGATTTGATCGAGATTTCCAGACCCCTTTGCTTTCTTACAAGAAACCGCTGTTGGATATCTTTATCACATCTTTGAATATTCGTTCTGATGAAGGACGTGTCTGTCGAATGTCTGCCTTGAAAGGAATTCGCCAAATGGTTGTTATGAAGCAATTCTTGTCGGCAGAAGAGATGGAGAAACTTGTATTGCATCTCACCCAGTTGATTCCAGACACAGACGGTGAATTAAGAGCGCTTGTTCTCTCTTCCCTTTCTGTATTAGCAAAGTTGAGTCTCCCTGCACTCTCCAAATACACCTTCCCACTCCTGTGGAGACTACTTCCAGGACACCAGAAACCAGACAACAGCAACTACCATAGTACCCTTGAAGCCGTCGAATACTTGACGATCAACCCCACCATTTTCAACACCATCGTTGCCTCTTCTCTATTGGACAAATTTGATAAGTCCTGCCGTCTATCTGACCAGTCGCGAGACTACGTTTCCGCGTTGGCTAAAACTATGCTCAATTTATTTCAAACTATGGCCCCAAAAGACCCAAAAACTATGCAACTAGGACAACGTATTTTTTTCCCTCACATTATGTCAGAGTGTATCAAATCTACTCTTCACTATCCAGGTTCATGGCTACTCGATACCCAACTTGTCGATATATTGTCGCTCTTTGTGGCTGGAGTCGTAAAGAACTCCAATTCAAGTCATCAAACAGCACTGACTGCAATTGCGTTCCGTCTTTTTGTTAATGGTGATCTGACAGCTGTTAACCTTCAATCTACAAGTGATCCTACCCTTCGTCTCTTTCCTTTATCAACCGTTGTTCTTCCTATCCCATCTTATAGTGAATTCATCCAAGGACTTGTCCAGGCTGCGTTAAATACTCCATGTAGTGCCAAGAGTCTAGCGTTGACAAAATCCTTTGCCTCAATTGTAAACAAGTGGGGAAATGAAAGTGTAATGTCTTGTGTGGACAATATTATTCCTACCTATCTTATTCCTGCCTTGGAATCCTCGGATATCAAAGTAAAGAAGGCTGGGTTATTGCTTCTAACATGGTTGGCCAAGGCACTCGTTATTCAAGGACATGCTTTGGGTTTCCAGATACTTGACATTATTGCAAACCAATGCCAATTACCTGATGTGGGGCGCGAGGCTGCAAATCATTTTTCTACTATCCTTCAAGACGACGAACTTATGCTCAACAAAAAATCCTATGCAAATGTTTCTATTCTTTACAGACAACGCGTCTTCAACTACTTGGCCCCAAAACTCATCGAGACAGCAAATATATCTTCTGCAGACTCCAAAATCAATTACTTTACCGCACTCTCTTGTTTGCTCGTGAACGTACCTGATTCTGTAGTTGCTAGTGAATCATCAAAGCTTATTACCTCTATCAATGCCTCCCTTTTATTGTCTGACTCCAACCTCTCCTTGTCTATGATCAAAGTAACACGCGTCATTATTGCCACTTCTCCAGAAAAGATCGAACACGCCACATCACCCACTATCGATGGACTGCTACACTCGGCTGATCCTGCTCACAACCTCTCCTTGCCCGTTCGAATCGAATCTATCCAATGTCTAAAGGATATCCCAGATAAATTTAAGCCAACAACCCTATCGCCACATGCACCCATTGTAGTCAAGCGACTTTGCAGATCCTTGGATGACAAGAAGCGGCTTGTTCGTAAATATGCCGTTGACTGCAGAGAAAGATGCTCGCTTTTACGGTATCTTCTCGGAGCATTTTCTCAGCCACTTTGCATTAAAAGATATATCAATAATAGAATGACAAGCCTTCTGTTTTACGATTGTATTACCTTAAAACTCGAGATTTTATGTGTCGGTGATCCTACATAA
->XM_023978471.2 PREDICTED: Salvelinus alpinus phosphatidylinositol glycan anchor biosynthesis class Q (pigq), mRNA 
-CTGTCTGTCTGTCTGTCTGTGTGTCTGTGTCTAGCTCCGCCTTGTGGTAGTGATGGTCCAGGGAGTGGTCCATCTCAGTGTTGACTTCATCAACTCCTTCCCTCTGTTCGCCATGGGCCTCCGACTCTTCAGATCCTACAGACTGGCAGAGGGGGTGAAGTTCAGAGTGCTCTGTGAGGAACCAGGAACACCTCTACACCTCATGATGGATATTAACCCTCTGAAGGTGAGCAGTGTGGTTCAGACCTACAGGACCCCCACCTACAGCTGCTACCCTAAAGACTCCTGGCTGGCCCTCTGCAAGAAGCTGTTCCTGGGAGAACTCATCTACCCCTGGAGACACAAGACTACCAAGATAGACTAGGACCAGGGGGGAGAGACAAAGGGGA
->XR_002711448.1 PREDICTED: Cucurbita moschata uncharacterized LOC111448527 (LOC111448527), ncRNA 
-ACCAAATACATTGATCGAATGGCGCCTTCTTCCTCTAGTGCCGCCGAAGCATCGTGAAATTCTCCCCTCCTTCCTCCTGTAATGCCGCAGGATCGTGAATTCATTCTCTGTCTCCTTCACTGACTCTTCGACGAGCTGACGATTCGAGTTGTAAGAAATCCGCTTCGAGCCGTAGTCCTAGTCCTTTACGAATTTGGAAATCATTGAAACTTATCATTCAGACTAGCATTGTTGATTGAAAATCCGAGTCGCAGAGGATAATCCAAAAGCCTTGTTTAGTGCACCGATGAACAAATGTTCGACGCATTAAGGCTATTACAGACAGGATTTTAGTAAATAGACAGGATTGTATTAAGCACTGTCTTTTTTCTATGACGGAGATGTGATGATCTTTACTCCAAATGGACTTCCACAAGTATACAACGTTCTTCGGACATCGTTACGAGCGTTAATTGAGATTGTTCGTTATGAAGGATTAGGAAAGGAGGGAAAGAAGATGCAGGAGAAGAAGATGGAAGTAAGAGGAATGGTGAGTTACAACCCGAATGAGCGAGAGTTGACCAGGCTGAGAATCATCATTTATTATTGATGTGACTCGAAAGTCGAAGACTGAATTATAAGGAAATTCACTCGATGATTATTACTCAGTAAGCAGGTAAGTCTTCTATTCTTTTGTTATATAATCTGTTGCATCCGCTACCATCTACATTTCTCGTTATGATTAATCATCATTACTCAGTTTTTGTTGGATGAAATTTGTTGTTTGCTGT
->XM_041901937.2 PREDICTED: Coregonus clupeaformis protein lin-28 homolog A-like (LOC121585613), mRNA 
-GGAAAATACACTATTTTCCAAAGAGGGATTACCGAAAAACGTGCACCGATAAACCAGAGTTTATTGCCTGATTCTTCTGGAGTTGTATGAGGCCCAGGAACCCCCCAAACCATGGCAGAAGGGGGCTGTGCAAAGACCGAAGAGGAGGAAACCACGGGCTCCGAGGAGGATCTGGGTTCGTCTCGTGGCAGCGGCGTGTGTAAATGGTTCAACGTCCGGATGGGTTTCGGGTTCCTGTCCATGACCAACCGAGATATGACACCGCTGGAGGAGACTGTCGATGTATTCGTTCATCAGAGCAAGCTGCACATGGAGGGCTTCCGTAGCCTGAAGGAGGGCGAGGCGGTGGAGTTTACCTTCAAGAAGTCGTCTAAAGGCCTAGAGTCTGTTATGGTGACGGGGCCAGGGGGAGCACAGTGTGTGGGCTGTGAGAAGACACCCAAGGGGCAACAGAAACGACGCTCCAAGGGGGACAGATGCTACAACTGTGGAGGACCTGACCACCATGCCAAAGAATGCCAGCTACCTCCTCAGCCCAAGAAGTGTCATTTCTGCCAGAGCATCAGCCACATGGTGGCCAACTGTCCAATCAAAGCACAGCAGTCCTTCCCTGGCTCTCAGGGAATAGCATCATCATTGAGGGATGAGAAAGAGGAGCAGAGCCACGCCCCCTTGCTCCAGAGGGAGAGCACTGAATGATCCATTCAGGGATTCAGCCAATCACAAGGTTTCATTGTAATGCTGCTTTTGGAACTACATCAGGCTGTCTTTATTCATCGAACTAACAGCAAGAAAATGGTAAATTTATTGATGCGATAGTTGAGATTGAGAGTTAGCTCTGTGTTTTAATGCACAGAGAGACACATCTATCCACCTTCTTTGCAACTCAAATACTTTAAAGTAATTCCTTTTCTGTCTATGAAGTTATTATTTCTGCATTAGATACTGAAATAATCTAAACTCACTGTGTTTACAAACTGCAATAAGCCTTGTATTGTCAGTTTTTACCACTGTACGTAT
->JN498124.1 Uncultured organism clone SBYZ_7200 16S ribosomal RNA gene, partial sequence 
-GTTAGCTTTGGCTATATGGATCAAAGGTGGCCTCTGCATGCAAGCTACTGTNTGGGGATGAGCCCGCGTACCATTAGCTTGTTGGTGGGGTAAAGGCCCACCAAGGCGACGATGGTTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGGAACACGGTCCAGACTCCTACTGGAGGCAGCAGTGAGGAATTTTGCGCAATGGGGGTAACCCTGACGCAGCAACGCCGCGTGAGTGATGAAGGCCTTCGGGTCGTAAAGCTCTGTCAAGTGGGAAGAACCCATTCCGGCACAACAAGCCGGGGTGCTGACGGTACCAATGAAGGAAGCACCGGATAACTCCGTGCCAGCAGACGCGGTAATACGGAGGGTGCGAGCGTTATTCGGAATTACTGGGCGTAAAGGGCGCGTAGGCGGCCGATTAAGTCAGATGTGAAATCCCGGGGCTTACCCCCGGGAAGTGCATTTGATACTGAACGGCTTGAGTATGGGAGAGGGAAGTGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCGGTGGCGAAGGCGACCTCCTGGACCAAATACTGACGCTGAGGCGCGAAGGCGTGGGGATCAAGCAGGATTAGATACCCTGGTAGTCCACGCAGTAAACGGTGATCACTAGGTGTAGCGGGTATTGACCCCTGCTGTTCCGGAGTTAACGCATTAAGTGATCCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGACGCAACGCGAAGAACCTTACCTGGATTTGACATCTCGGGAATCCCGCGGAAACGCGGGAGTGCCCTTCGGGGAGCCCGAAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTATCTTCAGTTACCAGCGAGTAAAGTCGGGGACTCTGGAGATACTGCCCCGGTCAACGGGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCTTTATGTCCAGGGCTACACACGTGCTACAATGGGCTGTACAGAGGGAAGCGATCTCGCGAGGGTGAGCCAATCCCAAAAAGCAGTCCTCAGTTCGGATTGGAGTCTGCAACTCGACTCCATGAAGCTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGCGCTACGTTCCCGGGCCTCGACACACCGCCCGTCACACCATGAGAGTTGGCTGTACCAGAAGTCGTCGG
->GU967443.1 Rosa rugosa putative MYB transcription factor (MYB4) mRNA, complete cds 
-ACTTTGTATAACCAGCCTCTTTCTTTCTTTCATTCACTCTCCCTTCCTCACAAACACATAACACACTACGGGAGCAGCCATGGCTGGTGTTGCAGACAGTGAGTACACAAGTCCTAATGAAGAAGAGAATGAGATGAGAAAAGGGCCATGGACGCTTGACGAAGACACCCTGCTCATACATTACATTGCCAACCACGGCGAAGGACATTGGAATGCCTTAGCAAAATGTGCAGGATTGAAGAGGACAGGAAAAAGCTGCAGATTAAGATGGTTGAATTATTTGAAACCTGACATCAAGCGTGGGAACCTCACTCCACAAGAACAACTCTTGATCCTTGAACTCCATGCCAAGTGGGGTAACAGGTGGTCGAAAATAGCACAACATTTGCCAGGAAGAACAGACAATGAGATTAAGAACTACTGGAGAACAAGGGTGCAAAAACAAGCGCGCCAACTTAATATTGAGTCTAATAGCAAGAGGTTTCTTGATGCGGTTCGATGTTTCTGGATGCCGACTTTGCGTCAGAAGATGGAGCAAACTTCTTCACTTAGTTTAGACCCACCTTCTTCTTCTTCTTCTCATTCTAATTACTTGACTTCTCAGATCTCTATAGCTCCTTCTCTGTCGACGTCTCCTCAAACTTGCTCGGTTCCTTCTTCTCCACCAAGCAAAGTGGTCTCACACGTATCTGATTATTCCCCAATTGGAACTTCAAGCCCAAGTCATAATAGTCTTTCCTCGGATTCTCTTATTTCACAGCTGCCTCAAATTACAGAACAACCAGCAAGTTCATCCTATGCCTTTGAAGCTCTAAATGACAATTATTATGTGGACTATGACATGGAGGGTTTTAGCCTTGACCCTGTTTCAGAAATGGCAACTTTTGACACTTCACAGTTTGATTGCCAGATGGCAGAAAGCGATTGGATACCAAGCAATTACATGACTGACACTTTATGGAACATGCAGGGGATGTGACAATTTGGGGAAAGATACAAGATCAGATGGGGCATCAACGACTAGAATTCATAATTCATATTAGGAGTCTAAGGGTGTGTTGTAATCTGAGTGACCCTTTCATCTATAGGAACCTTTAGTTATATA
->XR_007259806.1 PREDICTED: Pyrus x bretschneideri uncharacterized LOC103929507 (LOC103929507), transcript variant X5, ncRNA 
-CATTCTTTTCCCTCATTGGTACCCATCCTTTTCGATCTCTATCTCGCAGAAGCCTTTCTTCCTTGTGAAAGTGTTGCTCATCGTGGAAGGAGAGAAGGATGAAAAATGGGGCTCTTCCATTTGCTTCCAGAACAGATTTCTCAAGCTCTCTCACTTAAGCCGCGAACTCCTGGCCTCCGTAAGAAGAAAAGCTTGGCTCCCGTTCTGATTTGAGGAGATTTTAAACCCATAAAAGCTTGGGTTTCCAGCTTTGAAGAAGAAGATAACTTCTTTCACTGCAAGGACTTTAGACCTCTGATCTTCTGGCCTTCACGCAATCTAGATCTTCACCGTCAATCTCACTTGGGCTCTGCATTTTGTGAAGACAACTTCGTCGCTAAGATTAAAATAGAGATTGTAGTGAGCAAAGACCGGGAACCCAGAAGAGTCCCGAATTCAGTTTCCACTCTGACTGAAGATGGAACTTGGTGCTATTAAGCTATCATCCTCAGCTTCAGAATTCAGGCCTTGTCCATGTAAGGAGTTGCAAAACACCAACCAATGATATGAACATGGTAGGGTCTTGAAGCAATTCACCATTGTAAGGAGCAAGTTTAGAAGCACATGAAGGCGATGCACATGGTTTGGAATCTAGCATGTTGGCTTTTGTTAGGAGATCCTCGACATACTTGGTTTGAACCAAGAAGAGCGTGTCTGCCGATGAGCTTGAATACCAAGAAAAAAGTGCAATGGACCAAGATTCTTCATAGCAAACTGAGTACTGAGCTTGTTGATAAAAAATTCACAATGAGAAGAAGAGTTACCTATAATCAGAATATCATCAGCATAAACAAGTATAAAAGTGAGTGAGTGATCAACCTTGATAAAGAGTGAAGGATCTGCTATAGAGGAACGGAATCTGAGAGCTACAAGACTACGATAGAGCTCCTCATACCAAGCTTGCGGGGTTGTTTGAAACCATATATAGACTTGTGAAGCTTGCACACAAAATGAGGTCTGGGAGGATCTATGAAGTGTGCCATGAAGGAAGGCATTGGAGACATCCAATCGAGTAATCTGCCAATTGAATTGGATAGCTAGAGATAAAACGAGTCTAATAGTTGTTGATTTAGCGACTGGACTGAATGTTTCATGGTAGTCAATACCATGTTGTTGAAGAAACCCTTTAGCAACAAGTCGTGCTTTATATCGA
->XM_014803901.1 Moesziomyces antarcticus ANTH-domain-containing protein partial mRNA 
-ATGGCGCGCTTCGACGACCACATGCCCACGCGGCCCGTCGACCGCGACAAGGCCGAGTCCGAGCTCTCGATCCACATCAAGAAGGCCACCAGCACCGAAGAGACCGCTCCCAAGCAGAAGCACGTCCGCAAGTGCATCGTCTACACCTGGGACTACCGCACCTCCCAATCCATCTGGACCGGCCTCCGCGTCCAGCCCATCCTCAGCGATGAGGTGCAGACCTTCAAGGCGCTTATCCTCGTCCACAAGGTCCTCCAGGAGGGTCACCAAGTCGTGCTCAAGGAGGCCCAGGCTCAGATCGGATGGTTCGAGACTTGCGCCCGCACCGTCGGCGCCGACAGCATGCGCGGCTACGGAGCCCTCATCCGCGCCTACGTCAACTTCATCCTCGCCAAGCTCCGCTTCCACCGCCACCACAAGGAGTTCAACGGCCTCTTCGAATACGAAGAGTACATCTCCCTCAAGAACATCGACAACCCCGACGAAGGCTACGAGACCATCATGGACCTCATGAACCTCCAGGACCAGATCGACCAGTTCCAGAAGCTCGTCTTTGCCCACTTCCGCGGCTCCGCCAACAACGAGTGCCGCATCTCCGCTCTCGTCCCCCTCGTCAAGGAGAGCTACGGCATCTACAAATTCCTCACCTCCATGCTTCGCGCCATGCACCGTCGCACCGACGCCAGCGACGCTCTTCAACCCCTTCGCGAGCGCTACGACTCGCAGCACCATTCACTCCGCAAGTTCTACTACGAATGCGCCAACCTCAAATACCTCACCTCCCTCATCAACGTCCCCAAGCTCAACCACGAGCCCCCCAACCTCTTTGAACTCCCCGAAGAGGGTCCCTACCTCCCGCCTCGACAGACGCCCAAGGCGCCAACGCCGGACCCCGGTCCATCCCAGGCAGAGATCGACGAGCAGGCGCGCTTGCTCAAGCAGTACGAAGACAAGCAGGCCTCACTCAAGGCGCAGGAGGAAGCAGAGAGGCAACGACAAGCCGACCTCGCCGCAAAGCAGCAGCGCGACTTTGAGGAACAGCAGCGTCAGCAGGCCGAACAGCAGCGCCTCGCACAAGAGCAGCTCATGCGTGCACAGATGGACCAGATGCAGGGCGGTCGTCTCGCCGAGCTCGAGCGCGAGGTCTTAGCCATGCGCGGACAGTACGAGCGCGACCAGCTCATGCTCGAGCAGTACGACCGTCGTGTAAAGGCGCTCGAAACCGAGCTCGCCAACATCGGCCAGAACTTTGGCGCCCAGATGCAGGGCAAGGACGACCTCATCAAGCAGCTCCAGGATCAGGTCACTCTCTGGCGCAACAAGTACGAGGCGCTCGCCAAGCTCTACTCTCAGCTGCGTACCGAGCATCTCGAGATGCTCGGCAAGTACAAGCAGATGCAGATCAAGGCTGGAAGCGCGCAGGAGGCCGTCGACAAGATGGAGCGTATGGAGCGCGACGTCAAGGCCAAGAACCTCGAACTCGCCGACATGATCCGCGAGCGCGACCGCGCCCGCTTCGACCTCGACCGCATCAAGGCCAGTCAGAAGGAGGAGTTCGACCGACTCAAGCGCGACCTCATGTTTGCCAACGAGCGTGCAGAGGATGCGACGCGCGCCAAGAGCTCCGAGCTCTCGGGCATGATGTCCACGCTCAACCGCCAGATCGCCGAGCTCGAGGACTCGCTGCGCGAGAAGCGCATGGAGCTCGACGCTCGCGACGCCGAGCTGGCACGCATCCGCGACGAGAAGGATGCCGAGCTCGCCATCATGCAGGAGGGTATGGACGCCACCATCAAGCAGCTCACCGACATGCAGCTCAACCAGGGCGAGAGCGACCAGGCGGTCAATGCACAGATCGACACGCTCATCCTCGACAACTCCAAGAAGCTCAACGCCATCATCGACTCCATCCTCCAGGCGTGCGTCGACAAGGTGGACGATGCGCTCTACGAGCTCGAGTCGCCCTCGGCCTCGGGCAACACCACCGCCACGCCCGAGTACGTGCTCTCGATGATCGAAAAGGGCACCACCTCCACCAACGAGTTTGCCACCGTCTTTTCGCTCTACCTCTCCGGCGAGGTGGGCGGCGAGCACGTCGAGGTCATCAAACGCGCCAATCAGCTCGCCCAGACCATCAGCGACACGCTCACCAGCACCAAGGGCATCACAAGGTTGGCGCAGAACGACGATGCTGCCGACAAGCTCATCGGCACCGGTCGCGAGACGGGCAACGTGCTGCTGCGATTCTTCAGCAACCTGCAGTCGTACCGTCTGGCCGGCGTCGCACCTGCCCAGCGCCGCGATGTGGTGGCACGCCAGAACATGGAGGCGCGCGCCGCGTTTGGCAACCTCAACAGCGTGGTCGAGACCATGGTCAAAGCGGGCAACACCATGCTTGCCAACGCCAACGGCGACATTGGCGACATTGTGGAGCGCGAGATGATGAATGCTGCGAGCGCCATCGATGCTGCGACGGCCAAGCTGCAGGCGCTGCTGTCGAGGCCGAGGGACCACAACAAGTACTCGGCGGTGGATCTGCAGGTGCACGACGCCATCCTCGAGGCTTCGCTCGCCATCACACGCGCGATCGCCGGCCTCATCAAGGCGGCGACCGAGTCGCAGCAGGAGATCGTGGCCAAGGGACGAGGCTCGTCGACCAACCAGCAATTCTACAAGAAGAACAACCGCTGGACCGAGGGCCTCATCTCGGCGGCACGTGCGGTGGCGTTTGCGACGACCATGCTCATCGAGGCGGCCGACGGCGTCATCATGGGCACGCACTCGCTCGAGCAGCTCATTGTCGCATCCAACGAGGTGTCGGCTGCGACGGCGCAGGTGGTGGCCGCGTCGCGTGTCAAGGCCGAGTTCATGTCCAAGACGCAGGACCGGCTCGAGCGGGCGGCCAAGGCGGTCACGGACGCGTGCCGTGCGCTCGTCAAGCAGGTCAAGACCATCACCGACAGGCAGAGCAACGGTGCAGCCGACTTTGACTACTCGCAGATGGCCGTGCACGAGTTTAAGGTCAAGGAGATGGAGCAGCAGGTCGAGGTGCTCAAGCTCGAGAAGGAGCTCACCCAGGCACGCCGCGTGCTCGGTGCGATGCGCAGGGCGGGCTACCACGCGACCGAAGACGACTAG
->XR_001875487.1 PREDICTED: Lepidothrix coronata uncharacterized LOC108499283 (LOC108499283), transcript variant X2, ncRNA 
-TATGGGCTTTCTGAAAAGGTAACTGTTGTAGAACTGCTCCGCTTCTATCCGGGTAAATCCGGGGCAATGATGGTCCTCGATGACGGCTGGAGAGTGAAATAAGGGCGAACATTCTGTGTTGTTACTTGAACTAAGATGGAACAAGAAAAGTTGAGCCCTGTGAAATGCTGTTTGCAGTTTGTCTTGGAACCTACAGAAAAAGGTATGTAATTCAGCATCCTGGACATAAGCAGGAAGGTAAGTCATCCAATGAAAAACACTCCTTAAAATGTATCAAAACATCAGGTAAAGGAAAAACAGTGATGTGGCTTTTGTCACATGAGGTGTGTCTGTACAGCAGTGACCACAGCTCAGCAATGCTACCTTGTTTATGTTTGACCTAGGTAGCTGGCAAGAGATCTCTACAAGCAAATATTTTAGTAGAAGTAAAAAGTTAAGAGTGTTTTTCAGCTGTTTTTGACCTGGCTCTGTCTTAAACTGTGAGGCTTCCCCCGTGATCAGCACGGTGACTGTGCTGCCTGGGCTAATGAGCCTGTTTGTGGAGGGGTAAAGCAATGCCAAGCTGCAGTCAGAGACATACATGTCATATGCTGTGTCCTGGCCAGGTGTGGACCTCAAAGCTCTGAGCTGTGCAGGCACTGGACTTATACTGCAGTTTCAATTACAAAAATCTGTGAGTGGACACTTGGTAACTGGTGAACTACCTAATAAATAATAGAAGAGTTTAAGGATCACTTTGATAAAACTGTATGAAAACCAGCATTAATCTTAGATGGGTTTCTGAACTTCAGAAAATGCAGTCTGTATCTTGCCAGTTGCTAGTAGGTGCTGGAAGTTTTTTCCTGTCTGGCTCAACAACTGTATGAACTGTTTAGCCAAAATCACCGTAGAAGTCTCTGTTATAGATAGTGGCAAGATGATGAATCTGCAAGATTTCCAAAGACATTGCCTGAAATTTTGTTTTACTGTTGTTGCCTTGGACCTGACCCAGTTAACCACGAGCATTGGGAAATGCTCATCCCATACACTCAACTATTTAGACACGAGAAAGAGGTTTATATGAATTAGAAGTATGACAGAGTTTTGATTAAGTCAGATATTTGTGGAAGTCTCAGGTTTTTTTCATAGTGTGAGTTGGTGGCCTGTAAAAGTTCAGCCTTTAAGGATTTTCCTTTTAATTACCTTTTCAGAATGAAAGATGGAAGAATTTTCACTTTTCTGGCCTTTTCCTGATGACAGTGGCTTTGACTGGGGGCCCTGATCTCCCAAACACTGATTGTCTTATGTTTCTCAATTCTGAAAACCTTCAAGCATACAGTCAGGTATCCTGCCAGCAGCTCTGCAGCAGTCAATGCTTTTGCAATACCGGGCTCTGCTCATTTCAAAACTGTGAAGCAATCCAGCTTAGCAGTCAGCAGAGTGTAAAACTGAATAGTAGGAAGCATCGGAGAGCACCTACTCCAGTTTCAAGCAGAAGAAAGCCTTAAAACTTCAAGGATCAGAATGCTGGGGCATCTCCACTGACAGGTATCTTTCAGGAGCTGCCTTATCCTGTACCTGTCATAAAGCCAAAGTAGGAGCAACTGTTCATTCTAAGATGCATAAATCAGCTTTCCGAGATGATGCTCTAAGGAGAGCGCTGAAGAGCTCTGAAGAGCTTGAAGCTGGCAGGTACTGGGTGGCACACCTGAACTGCTCCTGGCTGCCCTGGAACATCCCACTGAAGATAACATTTATGGAAATGCAAGGAAAAGAATTGCTCCACCTTGCAGGTACAAAACAAGATGCCACGTTCCTCACAGCGGCCAGAGTTGGCATGGATGAACAGCTCTCCCAGAGGGACCTGCTTCCCTGTGGGAAGATGCTGCCCAGGACAGTAACATTTCTGCTACTAGAGCTGAGGGGAAAGGTCATATTTGGGACCTGATGTTAGGTCAGAATTGGAGCTGGAACTTTGCATACATTTTTTTTTCCCCCAAAATGGTCCTGTACTCTACTCTCTCAGCCTTGTCCTCAGCTAACGTGTTGCAGTATTGCTTAGGGGTGAGCTGTGCTGATGCCACTGCTGTACTCTTGCTGGTTTGGAGCATGGGGTCTGCCTGGCCAGGTCTGGGAGGAGCTGGGAAGATGGACTGGCTTGCAGTGCTGTTTGAAAGCAGCACAGACCCCTTTCCTAGCAGAATGTTTAATGGAATCTGCTTCCTTGAAACCAAAATGAGGCAACAGCTGTGATTGCAGCAAGCTGTAACATCTCATTACTGGATGGAGGCACGTCCTGTTACAAGTGGTGGTGCTGCAAAACCTCAGCAAAAGAACCTACTGAGACCTGCCTGGCTGGGGGCTGTGAACTCCCCTGAGGCCTCAAGAAGAAGCTTGGAATGTGGTGCCAGCACAACAGCAGACAGTGAGAGAAACTGAGGCAAGCACCTCGAAGATAAGTAATAAATGATAATTGTTATTTCCTATTATTCATCTGAATCTCTACTCCTGAGAATTTGAGTTAAATCCTAAATTTTCCTTTATTTTTAAGCAGATCATCCAGCAAGTTAAAAAACAGCAACACAAGGAGGTCCTAAGATAGGGTTTGCTCCAGTTTTCCTGCTGAGCATCTGTTTAGGAATTGCTGCTAAAAAAAGTCAGAGGGGATGGTAGTTGCTGTGCTGTCACATGGGCTGATACAGAGCAGAATCTGCTTAGCATTCTTGAAGGGAAATTATCCAGTGCTGTAACTCACAATTTATAATTGGTTGCATATTAATATCTAAAAAAGGCAATAAAATCCACTGTGTGTTTAAAAAAAATAGTAAGTAGGAGTATTACAAGCTGAGCAGTGAAAATCTGGAAGACTTCTTGGCTAGAGCAAGGCTGTGTGCAGTGCTGTTTCTCCCTTAATTACAAGCAATTTTAAATCATCTCCTTCCTTCAAAGAGGGATTTTGTTCAGGGTGTGTGTTAATTTTAATCTTGCTAACGTGATACTCTCTTGGAACCTCTCCCTTGTGTCATAACAGTGAGATGTGCTGCCTCTTTTGTCCCTGCCCTTTGGGAAATGCAGTTACTGCTGCTCATTGCCTCAACCCTGCCGTCGTGACTATCAGTGTACCTCCCTTGAAAGGAGAAGAAAACAAAACCCAACAGCAGCATTGCTTTTTCCCCCCCAGAGGTTCACTTTTATTTGTACTATTTAAGCTAGACTGTGCAAGTACTTCATGAAAATCAGGGATTTAAAATGTATGGTACTGTATTATGCTGTATTATTGTGGAAAGCTTGTTATTCAGCACACTAATTATTTCTGAGTCACTATATTTATGAAATGGCATGTAATAACTACTTCACCACCACGCAAAGTAAACAGTATAAAAGCAGGCATTTTATGATTTTGACATTTTAGTGTATAAACATATTCCTGAATCTCCTGGGGGGCTACTGGAAATCAGATAATGTTTTTATGACTTTTAAAAAATGACATTGAATTTCACAGTCTGTAACGCTCCATATATATGGTTAATGTTGCATATTTTATTACAGCCTCAGTGGCTTATGTTACAAGTGTCAGCTGCAAAGAGAAAATGTACAAAGGCGGGTTTGTGGAACTGTGGGGGAAACAACATCGTAAAACCTTGCAATGCACACATCAAAGCCCTTGGACAAGCTGTAATGGCAGGTCCTGGGCCATGCTGGGACACCAGAATACACCCTCTGCTTTTTTTCGTGTCAGGATGGATTACAAAGCCCTCGCTGAAGGAGGGTTTCTGCCCACACTTGTCACTAGAGGATAACTAAGTTTGGGGTTTTGTCAAGCCCTGTGTGAATGACCCGTTAACTCCAGAGGAACTGGGACGCCTTGAGTGACACTCTGCGAGCTGGACTGCACTGAGACTTCTGCATTTCAGGAATGTGACTCCTGTCCTTGACCTCGTCTGCAGATAAATACAACATGCCCCGTAGTGCTGAGTGGTTTGGGAAGAATGTCAGCCAGACAAGAGAGGGGAGATAATGGAAAGACAGGCTAGGATAGGAACTGGGCTGTCTGATTCTGCAATGTGGGAATCGCCTTTTCTCAGCTGCCAGTGTCAAAGTCAAGCTTGCATTGCACAAATAAAATGGGGTATTCCACACACACACCTGCACCCTTTCAATTCTCACTGATATTTAGCAGAGGGAATATTCAAAACATTATTCCCTCCAATACAGAATGGCTGTTGGGTGTTACCAGATCACGTAAAAAGACATCTGAGTGGAGTTTTTCCAGCAACAAACAAGAAACAAAGGGAGGATTAAAAAAATGTTTTGCTACGTATACTGTTATGATTTTTTTTGGTGAATATATATAAAAAATTAATGTTGGGATGTGAAGAAACAAAGAAAAAGAGCAGGCAAGTGTGCTACCATAAAATGTAGCATGACTTGGTACAGAACTGAATGTTACAGGGTCAAGCATCAGGTAGGGACATGTGTTGGGGACTAGGATGGTACTTACACTTATTACTGAGGTCAGTGCATATTTTCCACTACCTTATTTATGGGATCAAAGGTTTGATGGGATCTAGAAATCCAAACACATTTAAAACGTGGCAGATGTGGGTAACCTCAAGTACACAGCCCATCGCCTCAGAAAGAGGAATGTTCTTGCAAATTTGACATAATCCAATTAGTTGATTCCCTCAGTGACATTTCTGCAGGCTCATGTACAGAGGGACAAGGAAAGGGAGATTTATGACAGCTATTCCTAGCAAAGGTCATTTCTTTATTAGTGAACAACCTGTCCTTAGTCATGCTGATGATGAGGCGTTGAAGGATAAGGGAGAGGCTGTGTAGCTTTAAAACTTGACAGGGAATAACAGCAATAGAGCATAGATCATCTCTCTACTTGGACCAGGAGGACTGAAATCTCCCACCATCAGGCCAAAGCCAGAGAGCAGGAGGCAAAATCCAGGAAAAAAATAATACATGGGGATTTCTGTGGAGATTGTGAAGGAGTTTGGATGGTTCAGTGTCAGCACAGCAGGGGGGAAAGAGGAGCCACAGAGCATGAGTATGTTTTTGGATAGGATAAGTGTCCTTGGTGGAACCAGCTGCTTATAAAGAACCTGGTCTGGTTGCTCTGGGGAATCCCTGGTCAGCACTGCCAACTTCCCAGTTTGAGCAGCTCTCAGCATCCTGTTCCATGCCATTTCCAGAACAACACAGATGAGAGCATGCTCAAATATCTACAAATACACTTCCTTGGCTGTCCTTCCATAGGCAAGGAAAGCACCAGATTTGACAGGAATATGGTTTCAGTAGATTGTGACATACACATTATGTATTTTTAAACAATAAACCAGTATCTACCTATTCAAGTGACTATTTTTCCTGCTTGCAGAAGAGAAGGTATTTGACACTGTACATA
->XM_039434265.1 PREDICTED: Nilaparvata lugens aminopeptidase N (LOC111044204), transcript variant X4, mRNA 
-GTCTCTGCTATTTTTAACCGTATTCAGCTGAATTAGTCGCTAGCTTGGAATCAATTAAACATGGGTGCTCAAACTTTTGTCCCTCGTTCAAATTTCTTCAAATCCTGACTATAATTATTAGATTGTCACGTGTGACAACTTACAGTTTAAATTTTAATTTGATTTAATTTTGATAAGTTCAATTTCCAGAATTGTTGTTATTATTGGGATTCATTTTTAATCAAGTAAGCGTTCAGTCATAATAGTTCCTAAAATGGGGTATTTTATGACGTCATTGATAGTATCTCTCTTGCCCTACACAATGAATTTGGCTGATTCGAAAATGCTAACTGGATCTCCTATAGCATTTCAAAGATCGACTCATTTCAATAACCAAAGACTACCTCTTACCATCTTTCCAATACATTATAGATTAAATTTGTCAGTGCCATTGATAGATAACAATTTCACCGTAACTGGGGACGAATGGGTTTTTTTGAATTGTACAGTAACTACAAGGGAAGTTGTATTCAATGTGAAAAACATTGACATCGATAAGGCTAAGACCAGGCTTTATGATTCTTTTGGTGGATCGTTCGTTCGAATTATAGAACAAAGATATGAAAGTAGCCGAGAAATGTTTGTGATAAGAACGGCAACTCCATTGATTTCTAGACGTCAGTATGAGTTGGGACTTCAGTTCTCCTATGTTCTCAATGATGAGCTGATGGGATTCTATCGAAGCAGCTATATTGATCATGCTACTGGAGAGAAACACTGGATAGCAACCACCCAATTCTCTCCCACGGCAGCCAGGCGGGCTTTTCCTTGTTGGGACGAACCATCATTCAAAGCCTACTTTTCCATAAGTATTGCTCATCACAACAAATACCATACTTTATCCAATATGCCTATCAGCAATTCAATACCGGCCCCTGGAATGAACAATGATTGGATCCAAGATGTTTTCAAAACGACATTACCGATGTCAACATACCTTGTGGCTTTCATTGTTTCTGACTTTGTTCCTTACAAAACAGTCATCGATAACAGCTCAGGTTGGAAGTTCACACTATGGTCAAGAAAAGACATTCTATCACAGACTGAGTATGCCGCCGAAATGGGACCCAAATTGCTTAGTTTTCTGGAAGAATATTTCTCCATAAAATTCCCTCTTCCGAAACAAGATGTGGTTGCCATTCCCGATTTCGGTTTCAGCGCGATGGAGAATTGGGGACTTATCACATTCAGGGAAACATCCCTTCTATATAAGCCCGGTAAGACAAGTGAGAAGAGCAAACTGGACATAGCGTTTGTGTTCGGTCACGAGTTGGCTCACCAGTGGTTTGGCAACCTGGTCACCCCTGCCTGGTGGAACGATCTCTGGCTAAAAGAAGGATTCGCTACTTTCATTGGATACACGGCGATAAATCATATGGAGCCATCATGGAAAGTGCTGGATCAATTTCTTCTGCAACAAGTGCTGGGATCGATGAAAATCGACTCACTCAACGCAACACATGAAATTGAAGTTGAAGTGGAGGAGCCCAAAGACATTGTGCAGATCTTCGACAACATTTCATACATGAAAGGCGCCTCGATAATCAACATGATGAGCCAGTTTCTGGGTGAGCGGGTGTTCCGCGCGGGTCTCAAGCGCTACCTGACCGAGCACGCCTACTCGAATGCATGCCAGGACCAGCTATGGCGAGCGGTCACGGTCGAGGCTGCCTCGAGTCTGCCTCAGGGTGTCGACGTCAAGCAGATCATGGACACTTGGACCCTGCTGCCTGGCTTCCCTGTCGTCACGGTGCACAGGGATTATGAACAGGGAACGGCTAGTGTCACACAGGAGCGATATTTCGTGCTGAATGAATTCACCAGTGAAGATAAGTGGTGGGTACCTGTTTCATACACCACACAAAGTGAAATGGACTTCAACAACACCCAGCCAAAAATTTGGTTAGAACCATCCAAACCGACTAAGAAAATTACAAATATTGATCCTGATGACTGGCTGCTGATAAATTTAAAACACACTGGCTACTATAAGGTGAACTACGATGAAGAAAACTGGCGTAGATTGCAGGAATCGTATCTGAAAATGCCAGAAACGATTAGAGCTCAGCTGTTGTCAGATGTGTTTAGTTTGGCAGCCACCGGAAGGACCAACTACTCGACTGCCCTGGGCTTCAGTCTGCATTTGCCCCGAGATAATTCCTATTTTCCCTGGTCGATTGCTTCCGAAAAATTGTCGTTTATCGGAAAACTCATGCGGGATACGGATGCTTCTGACGATTTGAAGAAATACATGTTGCATTTGGTGGTGAATACCAACAAAGAGCTCACTTTCTTCCCAAAAACTCCAATTACTGGTTATTTGAACCTATTGCTTCAATTGAATTTAGTTGGAGTGGCGGCGGACAGTGATCACCAAAAATTGGTTCATGAAGCGAAACAATTTTTAAATGATGAGATTCTCGGTAAAAACGTCAGTATAATGGCGGATTTCAAAACCAAGGCATATTGTACGGCAATCAAACATGGTGGCTATGAAGAGTGGAATTTTCTATGGAAAAAATATCATGAGACAAATATTGCCTCAGATAGAGTGGTCATTCTCATGGCATTGGGATGTAGTAAAAATAGCACCATCCTTTCAAGGTATTTGAACAGAATCCTAGATCCAGACAGTGAGATAAGAAAACAAGACGGGGCGTTTTTATTTGAAGTTGTAGCCAATAAGAATCCAGTCCTGGCTTTCGATTTTCTCAAAAAGCGGTGGGAGAATCTCCAGTCATATTTTGGACTGGGATTCAGACAAATGGCAAAAATAATTGAGTCTCTTGGCACGCACTTGAATATGGAGCAGCAACTGATAGAGCTGGAAAAACTGCGATCAGACCACATGCAAAGCCTTGGGTCCACAAGCAACAGTTTCAAACAAACCATCGAAAGAGTGAAGTTCAACATACAATGGATGAACAACCATTACGAGTCTGTTACAACTTGGCTGAAAGAAATGCTACCAAAATTGAAAAAGACGTGATAAAGTGTTCCTTCCTCTCAGCTATGATCAATACTGGAGTATTATTAGTTTAAGGGAATAAATGTGTCGAAAACTTGAAGATTCAAATCGTTGAAGGCTTATCTAGCTTTTAACATTATCAAGACTATCTCCTATCAGACATTTTTCATGTCAAATAATAATATTTCAAATTTAGAACTTTTAAGCTAGTACACTCTTGAGGAGAATGTTAACAAGTTTTTTATTTTTTCAACAATAATCTACGTTTTCACTTATTGACGTTTCACTTATACACGAATTAATGAAAAGTTTGCATTGGAACAGCATGAGAAACTCCAATTTCTCCAGCAGTTTCAGTACAAAAATTTTATTGAACCGAGTGCTTTGAATATTTTCTGTAAAATTTAAAAGTTTAACTTGTATGTAAGAAATCTACAAAGCTCTAGTGAAGAAGTGCCATTGTTTGAAAGGTGCTATTATTATAGTCAATATTATTGCAAAGTCAGTTCTGACTTAATTGTGCTAAAGTAAGATTAAAAGTTGTGTGTTCTCATAAGTTATTGAGGAAATCTTTTTTTTCTGAATAGAGTATGCAAAAATATAGTCATTATTCGA
->XM_028248081.1 PREDICTED: Camellia sinensis pentatricopeptide repeat-containing protein At2g13600-like (LOC114302958), mRNA 
-ATGGGGTGTGCTAGCAGGTCCGATGTGAAAGAAATAGCCGATTACATGACACTTCTTGAGGGATGGATTTATGAGCACTTTCGTGGATTCCAACCACACTTGAATATGAATTACACTCGAGACATGCCACATGTTTACCGTTGGACTTCTCGGAGAGAGTCTGGTGAAGAGAGACAGTTGCAGGCTTTTCGAGAGGAGCTTGATAGGTTAGGGTATTTGGAACCCATACTAGAGTTGCAGAGATGTCCATCCGTGTCACCCAGCTATGTTCTATCACGGTTGCCTAAAGTGTTTGGAAGAAATCTTGTCCCAGATGATGCAGTTGATTATATTGCTTCTGAGAATAACATTGCAGAATTTTTTAAAGTGGATAGCACTATGTTTGTGCCTCTTTTGACTGTATGCACAGAGCTCTTTTTGCTCAAAGTCGGAAGACAAGTCCATGGCTTTCTTATTGCTTTCTCTAGCTGTCATTGTAATAATTATTCATTGGATGATGGCGATGCAATTATTGGAAGCGCTTTGATCAATATGTACAGCAAGTGCGGTAGCATTGGTGAAGCTCGAAAAGTTTTTGATGCTTGGCTGCCTGCCCAACTTGTGGCTCTTTGGAATTCGATGATATCAGGTTATATGTATAATGGTTTAGTTGAAGATGCTAGGACACTGTGGGAAGAAATGTCAGAGAAAAATGTCATTTCATGGACGAGCATGTTATCTGGGTATGTACAGAACGATATGCCACGAGAAAGTTTAGATTTACTAGCTAAAATGTATTCTAACGGGGATGGATCTAGAGTAGAAGGGAACTGCTTCACTTTTGTAGCGGGTCTTGAAGCATGTAGCTATTTAACAAACTTAGAAATGGGAAAACAAATCCATGCAAAGCTCATGAGGACATTAACTAGAGCTGATACCAATAATGTGGTTGTTGGAACGGCTTTGGTGGATATGTATTCTAAAGCCGGCTATTTGTCCTATGCACAAACTGTTTTTGATTTGATGGTGGAGAGAAATGTAGTTGCATGGACATCTATCATTATGGGGTATGCAGTTCATGGGTTTGGTTTTCGAGCCCTTGATTATTTCCAGCAGATGATGGAAATGGGCGTGGAACCAAATGAGGTGACATTTGTGTCTGTCTTAACTGTTTGCAGCCATTGTGGTTTGGTGGTTGAGGGGTTACAATACTTTAAACTGATGAAGGAGAAGTATAGATTAATTCCAAGGGAAGATCATTACACATGTTTGGTTGATATGTTGGGACGCGCTGGAAGGCTTGAGGAAGCATGGAATTTGCTGGAAGAAATTGATGTTGGAGAAATGAGTTCTAGAGGTACCATTTGGGCCGCAATGCTTGGGGCATGTCAATTGCATGGGAATGTGGAAATGGGAAGGAGGGCAGCTAAGAAGATGTTAGAGACAAAGAAACAAATTTTGACGACTCATATTGCACTTTCTAATGTTTATGCCGGGGCAGGGATGTGGAATGAAGCGTATAGAGTGAGAGAAAATTGGAGCAAAGAAGGTGATGTTAATGGGGAGCCAGGTCTTAGCCACATCTGCACAAACCTTGTGGTTTCTTGA
->JX292766.1 Haloferax sp. SSIN2 16S ribosomal RNA gene, partial sequence 
-CGCAAGTGCGATAAGGGGACCCCAAGTGCGAGGGCATATAGTCCTCGCTTTTCACGACTGTAAGGCGGTCGTGGAATAAGAGCTGGGCAAGACCGGTGCCAGCCGCCGCGGTAATACCGGCAGCTCAAGTGATGACCGATATTATTGGGCCTAAAGCGTCCGTAGCCGGCCACGAAGGTTCATCGGGAAATCCGCCAGCTCAACTGGCGGGCGTCCGGTGAAAACCACGTGGCTTGGGACCGGAAGGCTCGAGGGGTACGTCCGGGGTAGGAGTGAAATCCCGTAATCCTGGACGGACCACCGATGGCGAAAGCACCTCGAGAAGACGGATCCGACGGTGAGGGACGAAAGCTAGGGTCTCGAACCGGATTAGATACCCGGGTAGTCCTAGCTGTAAACAATGCTCGCTAGGTGTGACACAGGCTACGAGCCTGTGTTGTGCCGTAGGGAAGCCGAGAAGCGAGCCGCCTGGGAAGTACGCCCGC
->XR_004551154.1 PREDICTED: Pseudochaenichthys georgianus uncharacterized LOC117439437 (LOC117439437), transcript variant X1, ncRNA 
-GTTTGGTGATGTTGTGTGTGAATTCCAAAAACAATGTGACAACAATAATGGAGTTTCCATGCACTAATGGATACTGATTCAACAAGCTCCGTCCATATAAACTGATGGTGAACAGAAAGTCTGCAGTCAGCTCCTTCACCACAAGAGGAGAGAGACAACAATGATTTCCATGCAGCCGGCGGAAGAGAGAGAGGGAGAGAAGAAAGCCACCAGCGGGTTCCCGGTCCAGAAGATCCAAAAGGTCCAGAAGATCCAGAAGAGCCAGAAAGCCACCAGCGGGTTCCCGGTCCAGAAGATCCAGAAGATCCAGAAGAGCCAGTGTGCTGGACCGACTTGTTTGACTGTGACAATCCCAGTGGCTCAGGGGACTGGGAGCTTTTGAAGGACCTGAGGAAAGAAAACCCAGGAAAGATCTGTGAAAACCCTCTGTACATAAAGGTTGTTATCACTGACACGATGACCCCAGCCATCTCCACAGGGCAGACCTTCTATATCTTCAATCCGACTCAGGGATTTGTTTTCCGCAACAAGGACCAGAGTGAGGGCATGTGCCGTGACTACAAAGTTCGCTTTGGGTGCCCGTGCAAGAATTAAGCTGCAACTCCACAGCAAACATCCAACAAGAATATGAAGCTTTGATTGCTTTAAAATGTTGTCCTTTTCACTTTACCTTTCTATTTTATATCTTACTTTGCCTGATGGAAGAAGTTCAATGGACCTTTTTTACGGCAGACATGTTGACTTGTAGCAGGAACAGGACCATGAAGCCTCATCAGTTGATTAAAACTGAGCTTTATATCGGAGTATGTTTTACGCCTGTACGTTTACCAACATGTCTTCCGAGTTAAGATGCATCATGTCATGTGCTTTCTCAAAAAAACCTTTTTCTAGTGATCATGAAATCATTGTCTAATGTAGGAAATA
->NR_045871.1 Mus musculus RIKEN cDNA 4930428O21 gene (4930428O21Rik), long non-coding RNA 
-ACAGCAAGAGCTTCACTGCTGCAAACCAAGTATGGCTCCCACTGTCACCCAGCACTTGGGAGGCTGAGGAGAGCCCACGGATTTGGCAAGTCTGGATAGCCAGCTTGTCCCTGGGATCCTCTGCTCCTCCCGCCTGAGATCTAGCACGGCAAGTGGACTGCCACATCTGCCTGTGGACCTCCACCACATCTGCCTGTGGACCACCACCACATCTGCCTGTGGACCACCACATCTGCCTGTGGACTACTACATCTTCCTATGGACCTCCACCACATCTGCCTGTGGACCACCACATCTGCCTGTGGACCACCACCACATCTGCCTGTGGACCACTACATCTGCCTATGGACCTCCACCACATCTGCCTGTGGACCACTACATCTGTCTGGATTTTATTGCATGGTGATGCTCTCGGCTTGGGAGTGAATCACAGCAAGAAAGCCCTGCATCGTAGGTAGCTCTCCTCGGTACATTCCTGACTCTCTTTGGCCAAAGGATGGAAATCTCTGAAGATAATGACTCTTCTGTGACTTCTCTCTTCCTACTTACTTCTGTTGGGTTGAGTTCCCTTGTGGCCTGCTGATTGGCCCTGGCAATGTACCTGTTAGTGGTGGAGGGCAGTTTGGAGAGTTACTTCCACTAAGTTGATAAATGCCCTCCCCCACAACGGTTTTCTAGACTCCAGTCACAATCAACACCTTCTTTCCAAATTCCCCAACCACATTGTTCAGGAAGCAGAAGCATCTAGAAGCCACAGGGAACTGTTGGACTCAACCTGTAGAAAACTGGATGGAGGTTAGCTAGCCCTCCCTCCCGGGAGCTCCGACCTACTCCAGGGTGAAGAAAGCGAACTTGTATTGTGTAAATTGTACCCAGCACTGTCTCAGGAAGTACCGTAGCTTCCTGATTGTGAATGCAGATAATAAAGTGTAAGGCCGTAGCGGCTAAGGACGAAAGCCACCAACCCACCAAAATGTAGAAAATGACATTTCTAAGCCTCAGGTGCAGGAGAGTCACTATAATGGTTAGGAGGCCTCAGGCAAGGAATTGGTTTCCTGTCTTAAGCAAAGATCACTGGGAGCTTTGAGAATGGCAGGGAAGGGTTGGGAGACCTCTCCGCTGGTCTCACACAACCGTTGGGTTTCCAGGGAGTCAGGACTGCTACTTGCCACTTCCGCTCCCCTATTTTCTAAGAGAAATTATGAAACAGAACTTGATAAAGAAAAAGTAAATTTATTTACAGCTGGAAAAAACTGGGGAGAAAGAACCTAGTTTCTTTCCTCAGTGTCTATGGTTAGGATTTTTCAAAACCCCTAAGACACAGGCCAGAATATTGCAGATTTACCTCTGACAGTTAGGCTGGTCTTGATCTAGGGGCAGAGTGACTCAGCCCTGGGTTGCCCGTACTCCCGGCAGGCTGCCTGGTGCTGCTTCTGCCTCCTTCATACACACAAGCATACATGCACATGTATGTATTATATACACAAACACATATGAACATATATGTATTATACATATAAGCATACATGCACATGTATGTATTATACACACCAACATATATTAACATATATGTATTATACACACACGCACACATATGTATTATACACACAAACATACATGCGCATATTTGTATTACACATACATGGTTATTAGACATTTGAAATATGAAGAGTGTGAGGAGCTGGTTTTAAAATTTTAAAATGAAAATTTATCATTTTAAAATAAAAAAATTATTTTGAG
->XR_004558147.1 PREDICTED: Thalassophryne amazonica uncharacterized LOC117501971 (LOC117501971), ncRNA 
-CCCTGAGCCTGGTTCTGCTGGAGGTTTCTTCCTCATAGACAGTTTTTCCTTACCACTGTCGCCTGTGTGCTTGTGCCAGGTGTTGGTAAGGTTAGACCTTTTTTGTGTAAATCGCCTTGAGGAAATTTTGTTGTGATTTGGTGCTATAAAAATGAAA
->XM_018405618.1 Kwoniella dejecticola CBS 10117 hypothetical protein partial mRNA 
-ATGGCACCTGTAAAACCGGTGAATGGCAGTGACAAGCAAGTGAAGAAGAAGCGGACTTTCTTCGCGTCGAAATTAGCCATACCAATCCCTCCAGCAAGTGCGACGGAAAAGGGCAAACAAAAGGCAGTAGTGGTGTCTACAAAGACGGTACTTAGTGCTTTGGATGGATTGGAATCTGTGTCTAGATCAACACCTATCAGTAACGGTAACAGGAGGGATCAAGAGAAACGCCCCACTGCAACTCACACTCCATCTCGCGCGCAGACCGTAACATCGAAGCTAGTACAAGATCCCAAGATCTACACGAGGAGAAACAAACCGAAGGTTCAAGCCACAATCACCCGGAGCTCAGAGGTCGGTGGGAATGTCAAGAATGGCGTAGATGGTAAAATCAAAGTGAAGAGTGAGCCTTCAAGCTCGGTATCAGCTTCGTCTAGTAGGCTCGTGAACCGGAAGAAGGATGTCATCAATGACACGGGAAGGGTTGCGAGTGCTATTGAGCCGCAATCGAGTTCATCGTCCTCGTTTGTTGTGGGGAAGCATAAACACCTCAACGTGAAAACGAAAACCAAGTCGAACTCAAAAGTGGGTCCCAGTGCTAAAGCCAAGATCATTACCATCAAATCATCTTCGTCTCGCAGAATACCACATACCACCCTCAAATCCTCTTCCAAAACCAAGAGCGCAAAGACGACCACGCGTTCATCTGGCTCTGCGAAGACTTCAAATAAAGCTACACAGGTGCGGGCGATCCTGTCGAGGCGAATCATCAGAACTTATGAAGCCAAGTCTCAAACCAAAAGCGAACCCAGTCAAATAAAAGGAGGAATCTCTAGTGGGAGTCCAGAAAAGCAGGAGAAAGGGAAAGAGAAAGAGAAAGAGGGCAAACCGTTGAAAAAGGATTACATGTCAGCTGGATTCTATTGCCAAGATCCCCATCCTTCGTCTTCAAAGCAATTACACAACAAGATCTTAGCTATCCGTTCGGCGGAGAACAAAGCCTCAAAGTTGTTAGATGCAAAGGCAAAGGCAAAAGCAAAGGCTACTCCGACCATAGTGCGCCAAACGAGAAATAACGTCAAATCACATTCGAGCGAAAGTCAGAGTGCGAGTGCGAGTACGAGTACGTATACGAGTACAGCTCAATCCAGTAAGAAGTCAGTCGATCAGGAGAGACCGAGTTTCCCGCCGTTACCGTACGATCATGGCTACGACCTGTTCTTCAAGCAGGAGCACGAGTTCGTGTTGCCGTACCATATCATGAAGGAGAAAGAGGATGGAAAGCTGGTGGCGAAGAAGAAACCTACTCAATTTACGAAGATACGAGGGAACATATACCCCGAACGACCAAAAGTCATGACTGATTTCCATGCGATATGCAAATGCTCGCCGGAATCGAAATGCGCCGATCAATGTATAAATAAGTTGATGAGTTATTTATGTGGGAAAGAATGTCCTGCAGGAGATGAGTGCACGAATAAGACTTTGACTAAGAGGAAGGCGGCGGCCTATAAAGTGGCTGATACCGGGACAAGGGGTTTCGGGATCATACTGCTGGAAGACGTCAAAGAAGGGGATTTCGTAATGGATTACAGAGGAGAGGTGATATCGATAGACCTTTTCATGGACCGCATACAGGATGAGTATAAGGGCACGAAGAATTTCTATGCGCTAGCGTATGATCAAGATGAAGTGATTGATGCGGGGATGAAAGGGAATGATGCTAGATTCATCAATCACGGCTGCGCGCCCAATTTGGAAGTACGGAAATATCAGACCGCCGGGGATGGGTGGGACGAATTTGAGGTGGGCATGTGGGCTATTAAGGATATCAAAGCGGGAGAAGAGCTGTTTTACGACTACAACTTCGAGTCATTCGGAGTTGCCGCTCAGTCCGACGAACTACGCACGAAATGTCATTGTGGAGCGCCCAATTGCGTCGGGTTCTTAGGTAGAAAGGCAGGAGAGAAGTCGGCGAAAGAACTTGCAGCGGAATTAGCTAGGAATGCCAAGATCCTGCAAGGAAAGAAGGCGTCCATCAAGAAGCTTAAAAGTAAATTAGCGGAAAAAGCTCAAGCTGAATCTCGAAACGCGGCGAAGCTGGGTACGACGGTATTGGGTTTGGAAGATACCCCATCTATCATTTCTAATGCCGATACAATCACTACCACTTCTATCAAGACGCCTTCTCAAATATCGCCTTCTCGACCGCAGATTAATGCAAGGATGCCTTCGTCTTCCCCACTTTCCGAGCTGGATCCCGTCGAAGCCGAAAGCCAAACCAAAGGTTTGCCTAAGGACAAAAAGAGGAAGAACGAGATTTTAGCCACAACGGAAGCGGAGACTAAGAAGAAAAGAAGGAAATCTGAACCTTTACCAATACCCAAGAAAGCGACTAGCAAACCGCGCAAATCTGAGCCTTCCGCAACAAGTGCATCGACATTGAATTCGGCAGTGCGAATCAAGAGTGTGGGTAAAAAGGCAAGGAAGTCAGAACCGATCCCTACGTCTACCGTGAAGAGAGATGAGGATGAGAGCGAGGATGAGGCAGAGAAGAAACCATTCAATAATCCTCGAATCTGTATGGATGCCGTCCGAGAGGCTGCTCGAATCAAGAAGGCCGAAGTCGTGAAAGCTAGGAGGGGGGCGCCTAAGGGATGGACAATCGTTTTACCGGGACATGAACCGCCACCTAGGGCCGCACCGCTCGTCGTGTCGACTAGGAAACCGCCCAGAGATAGGTCGAGCTTGGGGTGA
->GU637646.1 Uncultured bacterium clone RW2302 16S ribosomal RNA gene, partial sequence 
-ATTGAACGCTGGCGGCATGCCTTACACATGCAAGTCGAACGGTAACAGGCCGCAAGGTGCTGACGAGTGGCGAACGGGTGAGTAATACATCGGAACGTGCCCGATCGTGGGGGATAACGGAGCGAAAGCTGCGCTAATACCGCATACGATCTGAGGATGAAAGCGGGGGACCGTAAGGCCTCGCGCGATCGGAGCGGCCGATGTCAGATTAGGTAGTTGGTGGGGTAAAGGCTCACCAAGCCGACGATCTGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGAATTTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGCAGGAAGAAGG
->XM_023804680.1 PREDICTED: Paramormyrops kingsleyae potassium voltage-gated channel subfamily H member 2-like (LOC111840147), transcript variant X3, mRNA 
-AAGGCCAGAGTCGCAAGTTCATCATCGCCAATGCGCGTGTGGAAAACTGCGCCATCATCTTCTGCAGCGATGGTTTCTGTGCCCTGTGCGGCTACACGCGCTCGGAGGTCATGCAGAAGCCGTGCACCTGCGACTTCCTGTACGGCCCACACACCAAGCGGCTGGCCGTCGCACAGATGGCCCAGGCGCTGCTTGGCTCAGAGGAGCGGAAGGTGGAGATCGCCCTCTACAGGAAAGACGGCGTGTGCTTCCTCTGCACGGTGGATGTGGTCCCGGTGAAGAACGAGGATGGCATGGTGATCATGTTCATCCTGAATTTCGAGGTCATGAGCGAGGAGAAGCGCAGCGAGTCCAGCCGAGAGCTCAACCACAAGCTGTCCATCCCTTGGCTCTCCGCAGGCCGCTCTCGTGGCTTCAGGGTACGCCTCCCGCTCCTGCGCTCCCTGGCCAACAGCAGGCAGTCCCTCCAGGACGACCCCGAGGCAGCTTGTGTGCCAAGGGCCTCCCACCCCAGCCGGGACTCCCTGATGCTGGACGAGCTCATCTCCCTGCCCGAGCCGGCGGGCCGGAGGGCACTGCTGGAGAGCCAGCCCCCAACACCACCACCGCCACCGGCTGCCGACTTCCCCGTGCATCCACACCACCTCGACCCAGACGCTTCCGTGTCCAACTGCAGCCTGACTCAAAGCCGCTCGCGGGAGAGCTTCCACAGCATGCGGCGCGCCTCCTCCGTTGACGACATCGAGGCCATGAGGCCCGAGTGGGAGCGCAAGGTCCGCTCTGGTAGCACAGGCGCAGTGAACAACAAATCAAACATCCTCAACTCTACCTCGGACTCGGACCTCATGCGCTACCGGACCATCAGCAAGATTCCACAGATCACCCTCAACTTTGTGGAGTGCAAGCCGGACCCCCTTATTGCCCTACCTCCTGGGGACAAGGACATCATCGCTCCCTGCAAGCTAATCGACCGCACGCACCACGTCACAGAGAAGGTTACCCAGGTGCTATCACTGGGTGCCGATGTCCTCCCTGAGTACAAACTCCAGGCTCCCCGCATCCACAAGTGGACCGTCCTGCACTATAGCCCCTTCAAGGCGGTGTGGGACTGGTTAATCCTGCTGCTGGTGATTTACACGGCCATCCTGACTCCCTACTCTGCCGCTTTCCTGCTGAGCGACCAGGATAACGTGGCCATGGAGAGCTGCATCTACACCTGCACTCCGCTTAGCATGGTGGACCTCATCGTAGACATCATGTTCATCATCGACATCCTCATCAACTTCCGCACCACCTACGTCAACATTAATGACGAGGTGGTGAGCCACCCCGTCCGCATCGCAGTGCACTACTTCAAGGGCTGGTTCCTCATCGACATGGTGGCGGCCATTCCCTTTGACCTTCTCATATACCGCAATGGGGAGGAGACGACCACTCTGATTGGCCTGCTGAAGACTGCCCGCCTACTGCGGCTGGTGCGGGTGGCTCGCAAACTGGACCGGTACTCGGAGTATGGTGCGGCGGTGCTCTTCCTGCTCATGTGCACCTTTGCCCTTATCGCCCATTGGCTGGCCTGCATCTGGTACGCCATCGGCAGCGTGGAGCGCAACGGCTCCATTGGCTGGCTGCACTCTCTGGCCGACCAGCTGGGGAAGCCCTACAATGAGACCATCCAGGGCTCGGGCCCGTCCATCAAGGATAAGTACGTCACAGCACTCTACTTCACCTTCAGCAGTCTCACCAGCGTGGGCTTCGGCAACGTGTCGCCCAACACCAACTCGGAGAAGATCTTCTCCATCTGCGTCATGCTCATCGGCTCCCTGATGTACGCCAGCATCTTCGGCAACGTGTCGGCCATCATCCAGCGGCTGTACTCGGGCACGGCGCGCTACCACACGCAGATGCTGCGGGTTCGGGAGTTCATCCGCTTCCACCAGATCCCCAACCCCCTGCGCCAGCGCCTGGAGGAGTACTTTCAGCACGCCTGGTCCTACACCAACGGCATCGACATGAACGCGGTGCTGAAGGGCTTCCCCGAGTGCCTGCAGGCCGACATCTGCCTGCACCTGAACCGCACACTGCTGCAGAACTGCAAGGCCTTCAAGGGCTCCTCCAAGGGCTGCCTGCGCGCCCTGGCCATGCGCTTCAAGACCACGCACGCCCCGCCCGGCGACACATTGGTGCATGCCGGCGACGTGCTCACCGCCCTCTACTTCATCTCCCGCGGCTCCATCGAGATCCTGCGCGAGGACGTGGTGGTGGCCATCTTGGGTAAAAATGATATCTTTGGTGAACCCATCAACCTCTACGCACGTCCTGGGAAGTCAAAGGCAGATGTGAGGGCACTGACCTACTGCGACCTGCACAAGATCCACCGTGAGGACGTTCTGGAGGTGCTGGACATGTACCCTGAGTTCTCTGATCACTTCTGGAGTAATCTGGAGATCACCTTTGACCTGCGCGACACTAACATGATTCCCGGCTCTCCGAGCAGCGACGAGTCGGACTGCATCGGCTTCAACCGGCTGCGCAGACGGAAGCTGTCCTTCCGGCGCAGGACCGAAAAAGATGACGAGAAAGCAGGTGAGATAAAGAAGTCTCAGAGGCCAGTCCGCCGGGCAAGAAAGCAGACTGTCAGCAACCAGACAGAGGGCTGTAAGGTAGAGTGGGAGGGGCCACGCAGTTCCGTGTCTTCTCACTCCAGTGGGGAAGAGGGGGAGGAGTTACTTCTCACCTGCCCCGCCCCTCCCTCCGCCCTCCTGGAGTTGCCAAGGGAACTGGGGACACACGTCAACGTGAGCAACGCTCCGGAGGTGGACGGGGATCCTAAGACTGGCAGCACCTGCAATGCGCTCTCTGGTGCGTTTTCCGGAGTGTCAAACATCTTCAGCTTCTGGGGTGACAGTCGCGGCCGGCAGTACCAGGAACTGCCCCGGTCCGGTCCGGCCTCCTCTCCCACATCGGCCACGCCGACCCACGGCATGGCCCGCTGGCAGCGGAGCCAGGTGGAGAACCGTCTAGAGCTGCTGCAGAAACAGCTGCACAGGCTAGAGATACGCATGTCCACCGACATCAGCACCATCATGCAGCTGCTGCAAAGGCAAATGGTCCTGGTGCCCCCTGCCTACAGTACGGTGACGTCCCCCCCTCAGCCCTCGCCCTGCTCCGGCCCCGGGGAGAGGCTGGTCCAGCCGGTCCCCCCACTGGAGCCCGACACCCTGCAGTCGCTCTCACAGATCCTGGTCTCCCAGAGCTCTGAGGGACCCTCTGCCAGGTTATGCGAGTCCCAGAATAGTACGGTGGAGCCTCAACCCCCGGGTTCCCTAGGAACCAGGAACCAGGAGGCAGGGCTCTCTGGCCTGGCCGGTCCCCAGTACTGGCTGGACGGGGTGACGGGGACCTCCGCGATGGACCCCGAGGCACAGCGGAGGCTGTCGCTGCCGGGGCAGCAGGTGGTTCTGGATTCACGGACGCCGCAGAGGCACATCTCTGACCCGGGGAGCTAGGTCCTCCTTGGAGCATCTCATCCAGGTCTTCCCTGTAGTCCCTCCACGCCGAGGAGGAGACCACCAGTGCTCACCACTTCCTACTCGTATTTCCATCAGCTGTGGGAGTTTCCTAGGGTGCTTCCCACCTACCTTGCACAACACTACCCCACTTACCCCTCTTCTTGGCTGACTTGAGGAACCACTGGAGATTAGAGTTTAGACCCATCCATCTCCAGCTCATTGTCCTTCACAGCAGGTCAAGACACTGCAAAGCGTGTAGTGAAGCGAAAGGCTACACTGGATGGACTTTCCCTTTACTGCTGAGACTGGCGTTGGAACAGTGAGACAAACGTGCACAGCGTAGGCACTCAGCCCACCTCTCGTCCACGTTGCTTCCTGACATTGTTAGTGAACTTCTGCGTTAGCTGGCCTAACAGATGTGTGGCTGCTGCCCCCTGGAGTCCATTTCCCAAAGCGCATCCACCAGATGGAATGTGGTTTCTAACTGTTGCTGTAGGGGAGTGGGGTGTTCAAAGCCATTAATTACTGGTGAACATATCACATTCTTAAAATAAACCTTGTACAGATTTTGAATGACAGAATCCTCGAACCATATGCAAACTCAGCAAGAGAAATGTTAAATTATTACAGGAGTGTGTCGATTTTCAGTCCAAAGGTTTGCTGAAGTTTGCTAAGGCCTGTGGATCGCAATTCGTCCGCGTGGTGATCTGCTGGATCCTACTACAGCAATATAATATATAGAGAAAGAGTTCTTGCTCATGAAGACTGTAGTTTTCTGTTAATCACCTTCCATGTCTTCTTGATCCATTCTCTTGGGCGGGTGGTCCTTCTCCCTACCTCCTTCTGGAGATAGTCTTCAGAGTGGCATAGAAGAACTCCTCTGGTGTTCATCTTGGTGAGTGGATGGCAGGTTGTACTTTGAAAGATGGTTGATTGTAATGTACTGCGTTGCACAATGAAATGAAGGTATGTATTGTATGTTTTTTATTTCTTGGGTGTTGTATCTTCTTCAGTAATCAACACGTATTCTTCTGTCGCAAAGAAAAATATCAGAATTTCTCTTCTGATGGAAGAATATGCACTGGATTTTTGACAGTCTTGTGGATCCTTTCCCAAATCCATTTCTGTGTAGTGAAAACATGGCAAAGCAGCTTTTAATTGGACTTAATCCTCACCAGAGATTCCATTTGGTCGAGTTACACACCTCAGTTTGTAATGAACTGTAACAAGGTAAAATTTGAGCTGTCAATCTACTGTATGACCACATATTTGCCAAACCCCAAAATCTATTGGAATTATGAATATTTTTTCCTGTGTATTAGTATGTATTTTTACAAAGTTCCTTACCCAGACTGAACATGAGTCTGAAAATTCACAGCTTGTCCATTATAAAAATAAGCATTGATTTGCATTACTAGTCCTGGGCATTGATATTAACATTCAGTCCAAAGCTGGGCTGTCGAATTCCAGTCCTGACAGGCAGCAGGTTTTTGTTACAGAAGAGATTTTATTAATTAACAATTCATCGATCCTCCCCATCTATGCCAGGCAGCATAGGGCAGATGCCAGGGGTACAGCCTCGATGGATAATCACACTCTGTGGGTGATGTGAAGGTGACACAGAAGTATCAGGTGACAGGGCTGCCTAATAATTTTACAGCAACTGATTTCCTAATTTAGAAAAAATAAAATAAACACGGTTCAAAAACCAGCATCTTGGTTTACAAACTAAACACATTGCTTGTAGACCCACTGCAGTTTAATTTGAATGTGTCTGTGATTTCATTTGACCCTTTGGTCAACAGTAAAGTTGATTATAGTAAATTTACGGTAAAGTAGTTTACACAATTGAAACTGAACAGTAAACCTCTATTGGAACTTAAACCAGAGTACCCTGCAATTCCGTCCAGGACTTAAGTTTCACAGCCCCTTGCAGCAATTCCAAATGCCTTGCCAGTCCCAAAGTAGAGTTTAACTGTTTATTTTCAAATGAGCATATTTTGTGTTTTTAAAGACTTTAACCAGACCTTTACAGCCATTATTAGCATAACCTGTTAATCCCATGAAGCTGATTCAGTTATTCTTGGCAGGTATGAATTTTAGTGTTGAAAGACGATGGGGGTGAGGTATTAGTGACCCCCAGTGATATAGTATTGCACAGTGGACATGTGTAAAGTGTAAGCCAAGTGTTTCTCCCATGTCTGAGGGTCACATGGACTTCTGAGGCACTGTATAACATGATTTACCAATTAACAGAAACCTCAGTCCTCAAATTGTGTTTTAACCTGTGTATATGTACTTAATGTAAAGACATTAATACTGCTTTAGTCTGTAAGAAAAAAAAACATTTAAGCACATGACAGTAACACCACTGGAGTTTTCTATCCCTGATGCCAAACTGAGGGATGATTTCACTTTCCACTTCAACCTTCACGCAGTACTGTAAGATGTCCACTGTTATCCTGTGAATCAGATTGTCTTGTTTCCTCTGATTCAGGTCCATTTCCTTTCTGTACTGCTCTGATACTTGCCCTATTGTTGGCAAACCGCTTACAACTGTAAGTCTCAGCTTAATTTCTGTCATAACCTCGGACCTGTATCATAAAACAGGATTTCTTGGTTAGCTCGATGACTTGTCAGATTTAAGGTAGTCTGGGCTAAATGTATGTGAACAAAGATAAAGTCCATTTAAACTGGGCTACCTCAAATCTGACAGGCTATCCAGTTCAGCAAGAAATCCACCTTCATACAGGCCCCTGCTGTAAAAGTAGCTTTGTTCTGAAGTATCCTCACACGAGGATGTTTTGCTTCCTCAATTCATTCAACTGGTTCGCTCAGGCATTTGAAAACCGTACTGGCTGTCACCTTAACAAACAAAACCTAGGAGCTGTAACGCAAAAAGCAGGATTTCTTGCTTAGCTAGATGACTTGTCGGATGTACCCCGGTTTAAATCGACTTTATCTGTGTTCACTTACATTTAGCCCAGACCACCTTAAATCTGACAAGTTGTCCGGCTAAGCAAGAAATCCAGCTTCGTGATACCAGCCCGCAGTCTTCATCTTAGTACAGGTATCTGCAACAAATCACCTGTAACATAATTCTTACACTGCCTCCTACAAAGGCACACTGCACCCTTTAACGTCTGGAAGATTGTCATTTAAACCTGATGCCTCTCAGTAGACGAGACTGTTTTCATATCGACGGATGTTTCTGATATAGGTCTGGCATTTGTAGATACTCTGACAAATATTTTTCCCTAAAGTAAGTCTACACTAGATTTTTTATTGCCTCTTCCCTGTATATGAGAATCTTGTAATTGAATCAGCCTTGGCACTCTTGTAGCCAGCACTATGCAGAAACTGTCATATCCGTGGCATGCTCCAGAATGCAAACTGTAGAAGCGTTTGTCCAGTTTTTAATAATCATATTCATGATTATATTAATATTAATAATAACGGTGATGGTGCCGATCAAAATAATGAAGATGAAAAAAAATAAATAAACGTTGTGCACATTTTATTTGCATGCTGCACTGAAAATGGAGGGACGAGATTAGCTCTGGGCCACTGGTTTCTGGATCGCCTGATCGGCACGCGTTAAGATGCTGTGTCAGAAAGCAGTAAATGCATACTAACATGCCAGAAGGAGACCTGAAGAAGAACAGTGAGCCCAACACCTCAAGGAGAATTAATTCTATAGCCATGTTTATATCAAGCACCAGTGAATTGGAGGAAATAAGCTATGGGGTCTTGACTGTGTGATGGTACCATAAACGGATGAAATGTCCAACTTTTCCTTCAATAAACCTCTTTGAAAGCAA
->XM_035091360.1 PREDICTED: Chelonus insularis ras-related protein Rab6 (LOC118071888), transcript variant X2, mRNA 
-CGTCACTTCCCAGTCAAACGTGGCGGCCGCGACAGGAGAACGAAGGAGTGGCTGTACGATCTGTCAAGTTGCTCAGTTTTCATTGTGTATTTAATGTTTTTTTTCGTAACTGGATTAATAATTGTGTAATTACAAGTAGATCCAGTAGTATTATTAATAAAACTCATTAGAAACATGTCGTCGTCGGGTGATTTTGGTAACCCGTTGAGAAAATTCAAGCTTGTGTTCCTAGGTGAACAAAGTGTTGGGAAGACTTCTCTTATTACACGTTTTATGTATGACAGCTTCGACAATACTTATCAGGCTACAATAGGGATAGATTTCCTGAGTAAAACCATGTATCTGGAAGATAGAACTGTTAGACTGCAGTTATGGGATACAGCTGGTCAAGAGAGATTCCGTTCTCTAATTCCAAGTTATATTAGAGATTCTACCGTTGCTGTCGTTGTTTACGATATTACTAATGCTAATTCATTTCACCAAACATCAAAATGGATTGATGATGTACGAACGGAGAGAGGCAGTGATGTTATTATTATGCTTGTTGGTAATAAGACGGATTTGAGTGATAAACGACAAGTTTCAACTGAAGATGGAGAGCGTAAAGCTAAAGAATTAAATGTGATGTTTATTGAGACTAGTGCTAAGGCAGGATACAATGTCAAACAGCTATTCAGAAGAGTTGCTGCAGCATTGCCTGGTATGGACTCCACAGAAAATAAACCTCCAGAAGACATGCAAGAAGTAGTTCTCAAGGATACACCAATTGAACTCAAAGCGTCGGAGAGCAATTGTTTATGCTAAATCAAGATAAGTCATAATAGACAGACTTACATTTCTACACTCCATAGACACGAATTAAACAAAATTATAAACAAGATTCGTCGTCAATTGGTGCGCTAACGATCTTGACAGATCACAATTGTAACAATAATTTTTACCCACATATTAAACAGTGCGATTTTTTAAGAGTGGTGCACATATCCAATATTTTGTATAAATTGCTCATTAATTTTTATTTCCGGGAATCATTCGTTTTTATCAGCATTTACAAATGATGAGATCAATTCTTTGTACTCATTTTTATCGCTTTATCCATGCTATTCATCGTGACAGCCACGGCACTAATAATTATACATTAATCATTTATACAAAAGCAACGATTAACTATTTTCAAATTATAAAATTCTTATTGATCACTTTCGTTATCAATTTATATACATTTTCATATTTACAACAAAA
->XR_006035448.1 PREDICTED: Aricia agestis torso-like protein (LOC121725853), transcript variant X2, misc_RNA 
-GTCAGTTGTGCCGCGGGGCGCGTGTTGTCGCGATGTTTCTGTCGCGTCGTGCTGTCGTGTTGCTGTCGCTGTGTTGTGTTTGTTGTGACGAGGACCTGGGATACACTCTGACCATCGGCAATGCTATTGACGTGTTTGCCAACTACGGTGACCTGTCCCAGGTGACGCAGGTGGTGTCAGCAGACTACGATGACAACGAGGGCTCGGAACCCTTCAGGGAGAAGAACATCAGACTGTTTGAGAACATCAGCAGCCGCCAGACGCCGGGGGATTCCCACTTCGACATGAACATACAGCTGTGCGAGACCTTCGATGACTTATTGGCAGTGTACTTCAAGAACTTCAAAATAGAAGGTACAGACAAACCATGGAAGGCTTTCTTAGGAGATTGGATACTGGACGAGATCATGCGGACTTTCGGTATCGAGTACGACGCGCGGCCTGACAACTGCTGCTACGTGCTCGTGAAGTTGACCAAGGTCCACACTGCGGTGCAGGTAGAGTCAATGGAACGAGTCCGCGTGCGGGAGTACGTACAGCGCGCGGTGAACAGCCTCAACGTGAGCGACGGCGTCGCGATCAGACAGTTCATGAAGAGCTACGGCACGCACTACATCGAGTCCTTCGCGACCGGCAACTTTATATACCAGGTGTTTAAGTACAAGCGGTCTGGGTACAACCGTCTGAAGGCGTACATCAGGCTGCGGGAGAAACACCAGATCAACTCCGACAGTCTCAGGTTCTACTTCTCCTCGTACTTCCTCAAGCAAGTCGGAGATATCCGAATAGCAAGCGGCAACAAAGTAATAGAGGAGTGGGCGCGAGACAATCTCAGAGACAGCCAGTATCTTTTCTCACGACCGAGTCTACTCCGACTGCACTTCAACCCAATACTGGCGTTCAAACTCAACGAAATGCTGGACAACGGAGCGCTCCTATCGTTGAGTTTGAGAACACTCAAACCGCTATTCAAAGACGAATACAAAGGAAGGGTATTTGCGGAGTACGTGGAAAACGATATGAGGCTATGGGAAATCAATGCTTAGATTTGAAATTTTGTAGAAAGAATGACATGGAGTTAATTTTCAAGATGCAGGTACGGTTAAATAGTCAATACTTATGACGAGAGTATGAAAGAAATACAATGGTGAGAATTATAATAATAGATTTTAAATTTTTAATGTTGGTGAAATATTTACTTAAGTTCACCAATAGATGGCGTAACGTTCATATAGAATTAAAAAGT
->XM_009873997.1 PREDICTED: Apaloderma vittatum cytoskeleton-associated protein 4 (CKAP4), mRNA 
-ATGGGGGTTGCGGTCAGTTCGGTGCGTTCCCTTCAAGCAACTTTTGGAGAATTTGAATCCATGATGAAAATTGCTCAGCAGAAGCAGGAGGTTACTGAGAGGGCTGTTAAACAAGGGGAGAGTGAAATAAACCGGATCAGTGAAGTGCTTCAGAAGCTGCAAAATGAAATTTTGAAAGACTTGTCTGATGGCATCCACATGGTGAAGGATGCAAGGGAACGAGATTTCACGTCTCTGGAAAATACAGTGGAAGAGAGACTAACAGAACTAACCAAGTCTATAAATGATAACATTGCTGTATTCACAGAAGTCCAGCAGAGGAGCCAAGATGAAATCAACAATATGAAAGCAAAGGTTGATTCACTAGAAGAAGCAGATGTGTATAAACAGGAAATTAAGGTGCTAAAAGATGCTTTTGCTGAGATGCAAGCATCCATGAAAACCAAAGAAAAGGACATAGAGACCTTGAAGAGTACAATAGACTCCATGGAGTCTGATGTGTACACTGAAGTGAAAGAGCTAGTCAACCTCAAACAAGAACACGAGAAATTCAAAGAGGCGGCGGACACTGAACACCTTTCGTTGAAAGCTTTACAAGAGAAAGTTCTGAGAGCTGAGGATTCTATCATGCAGCTCCCTGGTGACATTAAAAGACTTGATGAAGACTTACTGCAAGTTAAAGCTGACCTTAACAAATGGGAGGAAAATGAACTCTTCAGAAAAGCACTAGAAACTTTCGGAAAGAGCAGTGAAGGGCTGGAATCTCGATTGAGGCACATAGAAGACAGCTTGGAATCTCTAACATCTGTTGCTGCTCAAAACAGTGAAAAGATGCAATCCTTCCTTTCTAAGGAGGCAGAGTACGAGAATAAGCTCACTACCTTAGAACAAAGCGTTACTGCTCTTCAGGGAGTCTTCAATATGGACGTAACTTCAGTCACAGACACTTTGAAAAATCTCGGTGAATCGCAGACCTCACTGTACAATGACGTGGAAAACTTGAGGAAAAGCATCAGTGACCTGCCATCCTCTGGTGTTCTTCAGGATGTCCAGAAGCAAATTAGTACTTTGCTGGATCAAGGAAATCTTCAGACAGATCAAGCACATTCTCAAGGTTATCTTGACAAATTTTCTTCTGTGGAGGGCTCTGTAGATGAACTGAGATCTTCTGTCAGCCAGGTTGATTCCGATTTGAAAATGATAAGAACTGCAGTGGATAGTTTAGTCTCCTACTCGGTGAAAATTGAAAATAACGAGAACAACTTGGAGTCTGTGAAGAGCTCAGTAGACGACTTGAGGAATGATCTGGAAAGGTTGTTTGTGAAAGTAGAAAAAATACATGAAAAAGTTTAG
->XM_014296803.1 Sphaeroforma arctica JP610 hypothetical protein partial mRNA 
-ATGGGTCAGAGAACGTCAACGCAGGTAGATAAGCTAGCTAAAGCATTCAAGAAAGGGTTAAATAGTAAGTTACCTGAAGCTCAGAATACAACCCTCGAGGCGTTATTGAAGGACATGCCAGAAGTTCACGATAGACTTATGACATTGTTTAGTGAAAGTAATGCTGTATCAGCAGCATCAGCAAAACGCACTTCGACGGGCGAACAAGAGTTCAATGATGATGAGCAAGGTCAAGAGACTGATATTGAGGGAGAAGACGAATCTCCCTTACAACGTGACATGGATACAGAAGAACTGATAAGGAGAAGTGTTAACGATGGGTCAGAGAACGTCAACGCAGCATCAGCAAAACGCACTTCGACGGGCGAACAAGAGTTCAATGATGATGAGCAAGGTCAAGAGACTGATATTGAGGGAGAAGACGAATCTCCCTTACAACGTGACATGGATACAGAAGAACTTGAAGTTCACTATTGGGTTGTACAAGATCACAATCTAAAACATGTTAGTGAACGACCTACTCTACGAGATGCCCAAGAAGAAGGGATTGATCATCCCAGACTCAGGGCGATAATACGTAAAAACTACAACTCCTGTAGGATTGCGAATATAATCAGATCAAGCGTTATGGATTCGCGCCACTAA
->XM_018329607.1 Xylona heveae TC161 zf-DHHC-domain-containing protein partial mRNA 
-TCAAAAAGGCACACTTGGTCTCAAACATCACGCTTTGCATCAAAGGCCAACACTTCTTTGGGGGGTGTCACCACCGGAAGCGAGATAGGGACAGAGTCAAGGAGACCTCAAAGTTCGGCGAGTAAAACGCATGTGCCATCGCTTGCTTCACATGCTTTCTTCCGTCCACTGAGCTCGCAGAGGCTTCAAGCTCAGCGAGGGCGTCCTTCGCCAGCCACCTTCGTTCCAGCTAAAGAAAATGTGCCTTTAAAAGACGCAGACTCTGAGATAGCGCATGAATTGGATTCAAAGATTAATCAGAAAAGGAACTCCGCTGTCCTTCTTGATAGTGAAAAAGCGCAGCCACCGTCAAGGGGTACTGAGTGCACCGAGTTCCATGGGCAGGAAATGATCACAGGCGAAGTTAGCCCTGCTGCTAATCGCACAGGCACAAGCACTGCCGGCAGTGCGCATCCTTTGACCCAAGCTTCTCTGGCACCCAATGAGCCGACCGGGACGGTCTTTCGAAGAGGCTCCGCCTTTTCGTCACCTCTCGAGAAAGATCAAGGCTCGTTTCGCTCAAATTTCCTTTTACCAAGTCAGAATTTAGAGCTTCGAGATAATCAAATCATCGGTCGAGAAAAGCTAGCTTCTGCAGATTCTTCGCCACAACTTGGGCCCTACGAGACAAATAATCACGTGAGGAGAGATTCGGAGCGCAATTATCAATATTTTCCTGGAAACACTGTCTTCTGCTTTGGCGGGAGGCTTCAAAATACCAAAGATCGACCAGTTAACATCGTCACTTTCGTCTTGGTCATTCTGCCCTCGGCTCTTTTCTTTGGTTTCTCTGCTCCATGGCTCTGGCTGCATGTCTCGCCCGCGATACCAATTTTGTTTGCGTACCTCTTCCTCATATGTGTTTCCTCCTTCACTCATGCCTCTGTTACCGACCCTGGGATACTACCGCGAAAAACCCAACCATTTCCTCCTGCGAATGATGCAGACGATCCTCTTACCCTTGGGTCGCCAACGACTGACTGGACTCTGATTAAGTCAGCTGCGTCGCCCACCTCTGCCATGGAGGTTCCAACAAAATACTGCAAGACTTGCAACATTTGGAGACCTCCTCGGGGACATCATTGTCGAGTTTGCGACAACTGCGTGGAAACGCAAGATCATCATTGCGTGTGGCTCAATAACTGCATTGGTCGCCGAAACTACCGATTTTTTATATCCTTTGTGGCTTCCTGCACGTGTTTAGGTCTCTTTTTACTCGGCGCCAGCCTTGCTCATATTCTTCTATACGAATCCAGAGAGAGCATCTCATTTCGGGACTCAATCAGTCATCTGCGAGTCCCCTTTGCTATGGTTCTATACGGAGCCCTAGCGACGCCTTATCCCGCATCTCTTTGGGGTTATCACTTATTCCTGATGGCACGAGGCGAGACAACAAGAGAATATTTGAATTCTCACAAATTTTTGAAGAAGGACAGGCATCGTCCATTTACGCAGGGCAATATTCTGAGAAACTGGTTAGCGGTCGTCAATCGGCCGAGGCCCCCAACCTACATACGATTCAAGGAAAAACACGAGGCCGGTGACCAAAGGTTTAATCTTCGGAGA
->AB364225.1 Uncultured bacterium DNA, ribosomal RNA intergenic spacer, clone: Amplicon22-5 
-CCGGAAGGTGCGGCTGGATCACCTCCTTTCTAAGGACGAAAAGCGGAAGCGCCGCGTTCGGCTCTCGAAGCCAAATGTTCTTCACCCGGAGGGGTGCTGGCACCCCGAGGGGGAAGGTTATTTGGCAGAAGAGAGCCAGGCGCTGGAGCTAGACAAGACGAAAAGTGGAGGCCGCAATGGCCAACTGTCGATACACAGCGCTTCTGTTTCGTTCAGTTTTGAGGGAACGAGTCATGTTCTCTCAATGACAAAAATCGTTCCTTGAAAACTAGATAACCGGAAAAGCGGAGGCGAGTGTTTCGCCGCGATGGGCAAATGTTCTTCGCCTGCAAGGGTGCTTGCACCCGGAAGGCGAAGGTTATTTGCCCCCGAGCGGCGGCGAGCCGACGCTAGACAATAAGGAAGAAGCCGAGAGCGCTGTAGGTTAAGCTAGAAAGGGCGCAC
->XR_002421788.1 PREDICTED: Columba livia uncharacterized LOC110363588 (LOC110363588), transcript variant X2, ncRNA 
-CTGCTCTGGGGATGTTCTTTGTGCCCTTCGTGATGTGCTGCTGGGAGATTGTGATGTCAGTGGATGTCGAGATGATTTTCCCAGCTATCATCCCACTGCACATTGGACTTCTTCCCCAGGATCTGCAGCACCTTTCTGTGAGACATCACGCTTGATGAATATTGACATGGAAATAATGACTGCCCATTGCTACAGTGCCACTTGTGTTATCTGTTGGAACTAAAGCCTTCACTTCTTAATAAAAATAAACTTATAAAATC
->XM_031706046.1 PREDICTED: Actinia tenebrosa lysosome membrane protein 2-like (LOC116297758), mRNA 
-CACCTGATTGAGTTTGAAGGCCATTCAAGGTTCGGCATCTGGTGAAGTAAAAACTGAAGGACTGGAATCTTAGCTAGCAAGCTTCATTCAGCCATATTTTAAACTTTMCACCACATAAAAGCTGCATTTCTCCATCAATAATGGAAGAGAAATCAGAAAAACAAACAAGCTGTATTTACGGGGGAAAGAAGATTGCAGTTCTTTTGACTATTGGAGTGCTGCTAATATTGGTTGCCGTCACTTGTTATCCTCTGATCGATTCTTTGATTCAGAACAAGATCGATTCAACTCTGGCGTTGAAGCCTGGCTCAGATAGCTTCAAACAGTGGAGGGCACCAAAAGTTTCGATTTAYCTTCAGTTTTTTATTTTCCATGTTGTTAATTATGAAGAAGCATCGCTTGGTTTACCTCCTTATGTTGTGCAAAAAGGACCTTACTCGTACAAGGAGTACAGACGAAAGGACAACATTACTTGGCACGATGAGAACTCTACTGTGTCTTACAATGAGAGGCAGTGGTTTGTGTTCGACCCAGATACCTCTTGTGCAAAATGTGATCCTGTTAGAGATGTTATAGTAAACGTGAATATTCCCTTAATCGCGATTGCTAATCTAGTGAAGAACTTCCCAGATTTCTTASGCTGGAAAGAGCTGTTATCTTTGATATTGGGCAATTTCAATGAAACGCTTTTCGAAAATAGAACAGTACAGGAACTTTTGTGGGGATACGATGATCCTTTTCTTGCAGAATACGCTAAGTTGAGGAAAAAGCTCMATCTCACTAGTATTCTTCCAGATGTCGATCCTCTCATAGCTTTGCAAAAGAATGATACTTATTCAGGATTCACAAMAGTCCACACTGGAGTGAAAGATATAAACTTGATAACTAAATGGACGGAATGGAAGGGAAAACCAGATGTGGGTGTATGGAACACGACCTACGCCAACATGCTAAATGGCAGCGATGGTACTCAGTTTCCTCCGCAACAGTCAACTGATAGTACACTCTATGTTTTCGTAACTCAGCTTTGCCGTTCATTATACTTGACATATAATAAACAAATAGCAATTCACGGAATTGATACTTTGCAGTTCACGACTCCAAAAGAGCTTTACTTAAATGCCTCAATGAATCCAAAAAACAAGGCATTTTGTACAAAGGAGTGTTACCCAACTGGAATATTAGACATTGGTGTGTGTCAGGATGCACCCATAACAATCCCATTGTTTGTGTCTGCACCACATTTTTATCTTGGAGATAAGTCTCTCACAAATAATGTGAAAGGTCTCTCTCCGAATGAAAAAGACCATGGAACATTCCTGGACGTTGAGCCACACCTTGGTGTACCGCTTAAAAGCAGCAAGCGACTCCAGATCAATGCTCTCATTGAACCAGTCGACGACATTAAACAAACTCAGAACCTTCACAAGTTATTCCTTCCTGTCATGTTTATTAATGAGACAGCCACCATTGATAATAGTCAGGCGCAAATGATCAAAGACAAAGTGTTGATGCCATTCACAGTTGTTCATGGTGTGGAGATAGGACTGGTTGTTCTTGGGGGCGTGCTTTGTTTGGCAGGATTGATTTTATTGGTGCTTTTGATTGACAGAAATAGGAAACTCAAACAGGTGAAAAACATACTATCAAACCCTGATGAAAACTCACCTCTTGTAGTCAGCACTTAGTAACATCATCTAGATTATGATCTTTTAGTTTAATATTATTAAAAGATCATWTCTATATTTAAAAAATGTCAAAAAGGCTAAGCTGAG
->XM_028718607.1 PREDICTED: Podarcis muralis ubiquitin specific peptidase 4 (USP4), transcript variant X3, mRNA
XM_028718608.1 PREDICTED: Podarcis muralis ubiquitin specific peptidase 4 (USP4), transcript variant X4, mRNA 
-AGAAGGAGGGATTCCCTGCCTCCCTGCCCTTTCACTTCAGCGGAAAGCGGCCCCTTCTTCCTCAGCGTCAAAACACCGCGCTCGGCCCGGCGCTCCCTGCCCTCCGAACGCCCGGAGGCGTCGCCGCGCCTGCGCAGTGCCGTTCTGTGCGCGCGGCGGCGGCGGCGGCTGGGCGAGGAAGGATATCCGCAGTTGGGGACGGCCGGCCGGGCGAAAGCGCTTGCAGTACTGTCATGGCGGCAGCCGAAGTAGGGTTAGACGGCGGGGGAGGCGGCGGCGCCGGCCTGAGGCCGGACGCCGGGACGCAGCGGGCGGAACTTATGCCGCTGCTGGGGACGGCGCTGCGGCCGGGAGAGTCGTGGTTCCTAATTGACAGCCGGTGGTTCAAGCAGTGGAAGAAATACGTGGGCTTTGACAGTTGGGACTTGTACAACGTTGGAGAACCTAATCTCTTCCCGGGACCCATTGATAACTCGGGGCTTTTTGCAGACTCAGAAGCTCAGACTTTGAAAGAACATCTCATTGATGAGTTGGATTATGTGTTGGTTCCTACTGAAGCCTGGAACAAATTAGTAAATTGGTATGGTTGTATAGAGGGACAGAAACCAATAGTGAGGAAGGTTGTGGAGTATGGCCTGTTTGTGAAGCACTGTAAAGTAGAAGTTTATCTTTTGGAGCTGAAGCTGTGTCAGAACAGTGATCCTGCTAATCTTACGAGCTCTTATTTCAGCAAAGCAGACACTGTTGCTACTATTGAAAATGAAATGCGAAAGCAATTTAATATTCCTGACGGAAAAGAAATTAGACTGTGGAGCAGATACATGAGTAATACTTATGAGCAGCTAAGCAAACTCGACAGTACTATACAAGATGCGGGGCTCTATCAGGGACAGGTAGTGTTAATAGAAGTGAAGAATGAAGATGGTACGTGGCCCAGGCAATCTCAGACAAAAGGTTCTAGCTTTTCCTGCAACTCCTACAACAACAGGGAGAGCCCTCCTCAGTCACAGCCTGGTCTCTGTGGGCTCAGTAACCTAGGAAATACATGCTTCATGAATTCAGCTTTACAGTGTTTGAGTAACACCCCTCCACTGACTGACTATTTCTTGGAAGATGAGTATGAACCTGAAATAAATCAGGAGAATCCTCTGGGAATGAGAGGAGAAATTGCAGAAGCATATGCAGAACTCATCAAACAGATGTGGTCTGGGAGAAATTCTCACGTGGCCCCCCGCATGTTCAAAACCCAGGTTGGCCGCTTTGCTCCTCAGTTTTCAGGGTACCAGCAACAAGATTCCCAAGAGCTCCTGGCCTTTCTTTTAGATGGTTTACATGAGGATCTAAACAGAGTAAAAAAGAAACCTTACTTGGAGTTGAAGGATGCTAATGGCAGGCCTGATTCGGTGGTAGCAAAAGAAGCTTGGGAGAATCATCGATTGCGTAATAACTCTATAATTGTAGATATTTTCCATGGTCTCTTCAAATCCACATTGGTCTGCCCCAAATGTTCTAAAGTTTCCGTGACTTTTGACCCTTTTTGCTACTTAACCCTTCCATTGCCCTTGAAGAAAGATCGAACCATGGAGGTTTTCTTGGTTTTTGCAGATCCACAGCGCAAACCTACTCAGTACAAGGTAATTGTGCCAATGATGGGGGCTGTATCTGACCTGTGTGATGCACTCTCAAAATTCTCCGGGGTTCCTGCAGAAAACATGGTGGTGACAGATGTTTATAATCACCGATTCCACAAAATTTTCCAGATGGATGAAGGCTTAAGTCAGATTATGCCAAAGGACAACATCTTTGTATACGAAGTTTGTAAGTCAACGGAAGATGGTGCTGAATGCATCACTCTTTCAGTTTACTTCAGAGAAAAGAAAGCAAGACAATCCAGTGCTGCTCCGGGGACTGTTCTCTATGGGCAACCACTACTCATAGCTATACCCAAACACAAGCTTACTCTAGATCACTTGTACAATGTTATATTGGAGCGGATTAGTCGCTATGTTAAAGTTTCCTTAAAAGAAGAATGTTCTGAAGGATGTCCAGATAGTGAGAATTGCAATGGCTCCAGTAATGTGTCTGAAGGTGATGTTGAAGAAATGGAACATCAGAATGGAGAGGAAGACAGTAAGGAGAAAATATCAGAAACAGATGCCTGCAAATCAGAGGACTGCATCCAGGATGACCTGGAAAAGGAAGGCCTGCATCACAGAAGGCATCTCTTTAGCTTCAGTCTTGTGAACTCTTATGGAACATCAGAAATAAACTCCCTTAATACAGATGGGAAAATCCTCAAGTTGAGTTCTCATGCAACTCTTGCTATTGATTGGGATTCTGACACCCGAAAGTTGCTTTTTGATGAACATGAGGCACAGGCATTTGAAAAACACAACAGTATGTTTCAGCCACAGAAGAAGAAAACTACCGTAGCTCTGAAAGACTGCATAGAACTGTTCACTACTATGGAAACACTTGGTGAACATGATCCATGGTACTGTCCCAATTGCAAGAAACATCAACAAGCCACTAAGAAATTTGATCTCTGGTCACTTCCACGTATTTTAGTAGTACATTTAAAACGCTTCTCATATAACAGATACTGGAGGGATAAGCTTGACACTGTGGTTGAATTCCCTATCAGGGATTTGAACATGTCTGAGTTCGTTTGTGACCCAGCAGCAAGCCCATATGTGTATGACCTCATTGCTGTTTCCAATCACTATGGAGGCATGGGTGTTGGCCACTATACTGCATATGCTAAGAATAAAGTGAATGGCAAATGGTACTACTTTGATGATAGCAGTGTGTCTCCAGCATCCGAAGAGCAAATAGTGACAAAAGCGGCATATGTCCTCTTCTACCAACGTAGAGATGGCATGCTCAAGGGAAACCCCGCTCCTTGCATAAGCACTGAGCTGAAATCTGAGGAATGTGATGGCATGGATACCAACTGAACCTATGTGGTGGGGTTTAAACAAGTCATATTGCTAATTTTAAAAAGCATCCAAGAACTGATTTTTGTAAGAATCAAACAGGAGTTTCAGTACAGAAGGACTCAATGAGCAGTAACTATGGATAGCATAGGGAAGCAATAAGATGTCAAGGACTTGGGTATATCATAGCCAAAGAGCTTTTAAACAAATAGTTATTCAATAAAGTGTTATCTAAATCTGACTGTGTAGTCTGGCAGAAACTGTGTGGAAGCAGGAGCTTATGCTGTATGACTGGAGCAATGCATGAAAGTGCGAAACAACATTTGACTGTAAGTAGAATTCTGGTTTGAGCTCTATGCATTGCAGAAGATGCCTGAGTGCTTGTGTTTCCAGAGTAAAAGAGAAGTGAACATTTGGCACAAGTTCCAATCTCGCACAGCACATTTTGGCACTATGTTGCTGTCAGTCCCTTGCTGACATGGCATGGTGAGCTTGTGTGTGCTTTTAAGAAAAAGAGAAAATTGCATATTTGTTCTGGCTCATTGTGTCCCATACAGGAGTCACAATCCCCACATTTTCTTGTTCCGTTCTAATAAAACAATTATTTAGGATCCGTCCCAAAGATTAACTTTCCCCCACCCCCAGCCTTTCCAGCAGCAGTATTCATGGGGCCTATTCTTCACACCAACTCACATGGAGCCTTATATGCTCCTGATCTAGTTGGTAACTTACATATTGTGCAATCACAAGGCTTCTTTATTCAAGTGTCTCATTGGGGAGCTAAAATAACTTTCCCTGGTAGTTTTTTTAAATTCCGCTGTCAACTGTCTTCTATTTCTGTGCACTTTCAGCCACACCAGGAAAAGTTCAGAGTCCATCTCTTGAAGGCTGCATAGGAATCAGTGTCCAGTGGAATATGTCCTTTTGGGTGGTCTCAGACACGACACACTATTTTTCTTTTTAGCCATTTTATTTCTCTTTTTGTAATCTTTTGCTATCCTCATACCTCCTTAGTATTTTTTCCTCATTGGCTGAGAGATGGCAAGAGTAAATGTTGTTTGACTTCTTCCTACCCACAGCCTCCTCCTCCACGGAGGATGATAGACAAGAACCTTCTAGGAAAGGAGCTTTCAGGTAACACCGTGGAATTCCCATGCACACTGCTATGACACCTTAAGACATTTCCCATTTAGTGTCATGGCTTTGAAACTATCTTGGCACCTGTGTAAAGGTGTTTCACTTTTGTGCTCTGAACACATTCCCACGGATTCCCTTCAGCAAACTAAGAAGTATTCCTCTCCCAGACTGCTTCTGTGCTGATCTTTATCGGCATGACGTCAGGCAAGTGGTAGCCAGTGGTATCGTCAGGCCACACCATTTTAGCAGAACTGATTAAAAGTGATCGTGTTCTTTTTAACTTACAGAGCAGAAGAGTCCTCATTGCTGTCAGCTGCATTTTCCTCACTATTTTCCAGTGATTACTATTGCGTTCTCCAGGATAGTCCTTTTAAACACTGAAATTTGAGCTGTTTGGTTCAGTTGCTAATGCTTCCAGGTTCTTTAATTGATTTGAGGTCTTGTCTCAACTGGATATTATTTTCCTGCACACTTGGGTTGGTGGGTGGGGTTAGGGCTGGAATTATTTAAAGGCTAAGTTCAAACTGTAGCATTGCACTGTTTTGTTTTTTCCTGTTTTTCTGGGTTATATTTTCTTTGGAATGTAACATTTGGACCGATAAGGAAACAGATATTTAAAAGCAAAGAGCAATTTAATGTAACCATATGTATTTCTGTTCCATACTGTTGCAGCAAACTTTTCACTGCTCTGTATGGTCAGATAGTGTGCACATTTGTGTTTGGGTGATTTTTGGGCTCCTGAACTAAATTTCTTCTAAATGCTGTAAAGATGGTATTAGGAACCTGGATTTGCCTCTGACCAGGCTGGATCCTAGCTGGTGTGTACATTCTGTATAGTGTCAAAATCTGTTTTTAGACTAGCACTTTGTAAGTGACTGGCTTTACTGTATAAAAGGAAAAAAAATTAAAAAGAAGTGGATTGCA
->XM_029695648.1 PREDICTED: Salmo trutta inaD-like protein (LOC115151590), transcript variant X3, mRNA 
-CCTCCCTTCTCTCTCCTCTCTACGTTTGTTCTCTGTAGATTCTCACCATATTTCAGTATGCCTGCTCAGCCTTGCTCAAGGCAGCGCTGCCAACCAACACCACGAGGTTGACAACGGACAAACACACACACAAACACACACACTGGCGCATGGGGATGTTAAACTCAGGATTGCTGGGAGAGTGAAGCATGGACCATGCTGCCAGAGCGGATCAGGTTGCGTTACGGGGAGCTGCGCGGGGAGCTGCTGTGTGTGGAGCTGGACAGGGAGCGCCAGGGCCTGGGTCTGAGCCTGGCGGGGAACAAGGACCGCTCCTGCCTCAGCATCTTCGTGGTAGGCATCAGCCCTGGGGGCCCCGCCGCCAAGGACGGACGCATCCGCATAGGGGACGAGCTGCTGGAGATCAACAACCAGGTCCTGTATGGCCGCAGCCACCTGAATGCCTCGGCCATCATCAAGAGCACCTCGTCCAAGGTCAAGATCACCCTGATCAGGAATGAAGATGCTATCAACCAGATGGCCGTTCCCCCCTTTCCAAACCCTCCTGCTGTCCTCTCCTCCACTGAAACCCATCCCCCCAAACCAGCAGCAGTAGCATCCCCGGGCCCCACAGAGAAGTCTCAAACCCCAGAGAGCCTGGCCCTCAGCAGGGGACCCCTGGAGGCCTCCATCTCCATCAGCGAGGTGAAGTCCAGTGTTGGGTCCAGTGGGAGCACAGCTACAGAGCTTGTTTCCAGAGAAGCAACACTCAAGATCCTCCGAGAGACTTCCTCAAAGAAGGCCTCAGAGAACGAGGCTGAGTCTTCAGAGAGCGTGACTGTGCCGGCTGCCAAGGCCCCCCTGGAGCAGACTGCTCTCCTGTCCAAAACCTGTCGGCTGTCCTGTAAGCTGCCTGTGGTGAGCTCTGTGAAAGGGGGGCTGGTGCCCACCCCTGCCTCTTCCCTGCCTTCCTCCTGCACCAGCCCAGACTTTGAGTACTGCAACAAAGACCCAGCCACGTGCCCTATCGTTCCAGGCCAGGAGATAATCATAGAGATCGCCAAGGGTCGCTCTGGCCTGGGTCTCAGCATCGTAGGGGGAAAAGACACCCAGCTGGATGCCATAGTGATCCATGAGGTATATGAGGAGGGGGCGGCGGCACGCGATGGACGACTCTGGGCTGGAGATCAGATCCTGGAGGTAAATGGTGTGGACCTGCGTAACGTGGCCCATGAGGACGCCATCACAGCCCTAAGGCAGACCCCGGCCAAGGTGTGTCTTAAGGTTCTGCGGGACGAGGCGAGGTACCGCGACCAGGAGAACCTAGATGTGTTCAGTGTGGAACTGCAGAAAAAGGCCGGCCGTGGCCTGGGCCTCAGTATCGTCGGCAAGAGGAACGGCACAGGGGTGTTCATCTCGGACGTGGTGAAAGGAGGCGCCGCCGAGCTGGATGGCCGGCTGATGCAGGGGGACCAGATTATCTCTGTCAACGGAGATGACATGAGGTCTGCCTCGCAAGAGACGGTAGCTGCCATTCTCAAGTGTGCCAGGGGGGTGGTACTCCTAGAGCTGGGCCGACTGAAGGCTGCCTCCTGGATCTCTTCCAGACGTACCTCCCAGGAAAGCCAGCAGATGAGTCACGTGAGTGCCAACAGCACTATCGTCACGCCCCACCCCCCGCTAAACTCCACCCCTTCCACCTCTCAGCTCCTCAATAACGTCAGGAAGCCAATGACGGTGGGCATGACATCATCACAGAGCGCAGAAACAGGGATGCGCACTGTGGAGATCACAAGGGGTCCTACTGATGCGCTGGGGATCAGTATAGCTGGGGGGAAGGACAGTCCTCTGGGGGATATCCCCATCTTCCTGGCCATGATACAGGCCAACGGGGTGGCAGCCAAGACGCACCGGCTCAAGGTGGGTGATAGGATCGTGAGTATCAACTCCCAGTCTCTGGAAGGCCTGTCCCATGGGGATGTAGTCACCATGCTGAAGAATGCCTACGGCAGCATCATTCTGAAGGTGATTGCTGACACTAACATCAGTGCTATAGCCAGTCAGGTGGAGAGTATGTCGACTAGCAGCAGCCCCGAGACACAGCCAGGGGAACCAGAAGCCCCCAAGCCCAAGAGTATCTGCCTGGAGAAGGGTTCTGACGGCCTGGGCTTCAGCATCGTAGGAGGCTTCGGAAGCCCTCATGGAGACCTGCCAATCTACATCAAGACTGTCTTCAGCAAGGGGGCAGCAGCGGTGGACGGGCGTCTGAAGAGGGGTGACCAGATCTTGTCTGTGAATGGAGAGAGTCTGGAAGGGACCACACACGAGCTGGCTGTGGCCATACTGAAGAGACAGAAAGGGGCCGTCACCCTGGATGTGCTGTCCTAGCTCACACACTCTCTACCCCTTCAACTCTCTACCCCTTCAACTCTCTACCCCTTCAACTCTCTACCCCTTCAACTCTCTACCCCTTCAACTCTCTACCCCTTCAACTCTCTACCCCTTCAACTCTCTACCCCTTCAA
->XM_046072427.1 PREDICTED: Micropterus dolomieu transcription factor ETV6-like (LOC123985072), transcript variant X4, mRNA 
-TAACAGCATAGGTTTCAGGTTTGCAGCCAGTGTTTTGGAGCAGGGAGGACGTGGCCCAGTGGCTGCGATGGGCCGAGAAGGAGTTTGCCCTGCGGCCAATCACCAGCGGCTCCTTCCAGATGAACGGCAAAGCTCTGCTGCTGCTCACCAAAGAGGACTTCCGCTACCGATCCCCTCACTCCGGGGACGTCTTGTATGAGCTGCTGCAGCACATCCTGAAGCAGAGGAAGCCCCATGTGTTTTACCCGTCTGCCTACTTCCCTGGGAACTCCTTCCACTCGCTGCCTGAAAGCGCTGTGCAGCACCTGAAGCTTGAAGAAACGGTACGGCGGGCACCACGTGGTACGGAGCCACTCCCCCAGCATCCACCAACCATTGAGCTGCGGCACCGCTCCCGCTCCCCCCATCATCCAACCACCAGACGATCCCCTCCGGAGCCAAACCACCCCCGCCAAGCCAATGAGGACCCCCTCCAGACCTTCTCCCAGCTGCCCGACAGCAACCACCACCTGCCCGAGGAAATGTACCCTCTGTCGGTGTCTCCGGCTGCACCCAACGGCCGCTGTGCGACGCCCCGGGAAGCCCCATGTCCGGGCAGCCCTGGGGGCCAGGAGGCGGGCCCTCCTCGCGTCATCCAGCTCATGCCCAGCGCCATCATGAACCCCCTGCTCCTCAGCCCGAGCAGGAGCGGCGGGGGTGCCGCCATGGACTTCAGGCACAGCCGTGGCGGACCCCCCTCTCAGGTGACGCTCGAGAACGGGCGCGAGGGGAAGGTCCACGCCCACCACCATCAAATATCACTCTCCCAGCAGCAGCAGCAGCAGCAGCAGCACCACCTACTGCAGCAGCAGGAGGAGGTGCTTTACCGGAACCAGGTCATCATGCCCGTGTCTCCTCCAGAGGAGCAACAAATACCCATCGGACGGATAGCAGACTGCAGGCTGCTCTGGGACTATGTCTACCAACTCCTGTCAGACAGCAGGTACGAAAACTACATCCGCTGGGAGGATCCAGAGAGCAAAGTCTTCCGCATCATGGACCCCAATGGCCTGGCCAGGTTGTGGGGAAACCACAAGAACAGGACCAATATGACCTACGAGAAGATGTCACGAGCACTGAGACACTACTACAAACTGAACATTATCCGGAAAGAGCCTGGACAAAGACTTCTATTCAGGTTTATGAAAACTCCCGATGAGATAATGAACGGGCAGACGGACCGGCTGGAGCACCTGGAGTCCGACACAGACGAACAAATCTACATCAAAGAGGAATGCTGAGGAAATCTTGGGGGAGGGGATGAGTCCATGAACTACTTACTACTTACTACTACTACAGCCGCTGATGCCTTTCAGAAGCAGCCTGAACAATCGTTGTTGAATCTGGAGCACGTGGATGTGCGCTTGTATCAGTCCCACACAGATGGATGTGAAATGTGGTCTCCCGTAAGATTGCCTTAGGATGACGTTTTCCTGAAGTAAACAGATTTTCCTGATGGAGCGAGCTGAGAGCACTTTCTAAGTGTTCCCTTTTTATTTCTGAATGAACTGCAAAAAAAAAATCACTTTGTGCTTAAGTCACTTTTATGATTTTTATTATTTTTTTGTCCCCTCACATGCATTATACAATGGAATTTTGCTGTTTGTAAAAAGAAAATCGCGTGTGTGTGTGCGTGTGTGTGACAGGAATGTTTTCACCATGGAATAAACATTTTTTGATCAAACTGTA
->MG257935.1 Paenisporosarcina sp. strain SC-Apr-C3 16S ribosomal RNA gene, partial sequence 
-GCCTAATACATGCAAGTCGAGCGGAATGAAGAAGAAGCTTGCTTCTTCTGATTTTAGCGGCGGACGGGTGAGTAACACGTGGGCAACCTACCTTGTAGATTGGGATAACTCCGGGAAACCGGGGCTAATACCGAATAATCCATTTTGCTTCATGGCGAAATGTTAAAAGGCGGCTTCGGCTGTCACTGCAAGATGGGCCCGCGGCGTATTAGCTAGTTGGTAGGGTAACGGCCTACCAAGGCGACGATACGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCACAATGGACGAAAGTCTGATGGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAACTCTGTTGTAAGGGAAGAACACGTACGAGAGTAACTGCTCGTACCTTGACGGTACCTTATTAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTCCTTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGAGGACTTGAGTACAGAAGAGGAAAGCGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGG
->XR_003604399.1 PREDICTED: Vigna unguiculata uncharacterized LOC114183599 (LOC114183599), transcript variant X4, ncRNA 
-GTAATACCTTTTCACACATTTTTCCAAAATTTTCCTATTCTAACTTTTTTTACTTAAAATTGAAAACCTAAACACCTTCTCCCTCATAGAAAACCTAAACACCTTCTCCCTCAATCAGTCGCATCTCTAGCTTTGTCGCTCACTCTTTCACTCATGATTCTAGCTCAGTTGCCCACTCCGTCACGTGTCACTCTATTACTCCGTCGTAGGCAGCCCTATCATTCGTCGGAGTTGTTCGCAACTTTTAGGAGCTTCCACTTCCGATTGTTTTCCTAACATTTCACTTTCGATTTGCTTGCACTCATGATCATGGCAGGAAACATGTCTGATCCAAGTGGGAGCAAGGGTGCAAATATTTTCATTGTATCTTCTTCCTTGTTTTGAAAAAATTATGGAAAACGCCCTTACATTACCATGATTTTTCTACAAAACTTCTGTTAATAAGGATAGTTCTGAGAAGTTAGAAGGGACATTCTCATTGTCAATTATGCCTGATCGGTTTGTATTTTACTTGGAAGGACATGCTCCTAGAGTTGACCTGCCCATAAGATCAGTAGAGATAAGCTGGTCCACTCCAAATAATAATGTTATAAAAGACTCCAATGGTGGCAACCTTGTTGATATGGAGCCTAGGATGCACAGTTTTGGAAATGGCTACAACTAAACCTCATTGGAGTCAGCATGAAAGGGTTAGTAATTTATGTATGTCAATATATTGGAAGTTTTAGCTAGCTTTTTTATATTTTGTTTCCC
->XM_043838092.1 PREDICTED: Telopea speciosissima uncharacterized LOC122644689 (LOC122644689), transcript variant X2, mRNA 
-TCTTCTTAGCTCTTTTTGGAGTCTGTAAAGTTGAGGCATGGGAGTAAAGGTTGCCGCGACCTGTTTACAATGGTCGCAGCCAGTAGCTTCACACTCTCCTTCATCGGCTCAGACGCTAGCCTCTGCAATTTCATCTCCTTCGACGAAAAAACAGAGAGGAGGCGATCGAGTTCTTGTATGCCGATTCGTCCATAAATTGGCTTTCTTGGGAACGTCATCGACGAAGCTTTTGAGATCTCGATCTTGCGATAATCTGAAGTCTAGAGGCCAATTCCTCAGGCGAGCTTGCAGCGCCAACTTAGATGGATACCCTGACGAAGAGTTCACGGAAAATACTCGGGAATTAGCACAGAGGTTCGATCTTTTAAGCGATGGTGATGAAGAACAGAACAATAATTACGACGCGGAGGATGTAGAATTGGATAATTCTGCTGTTGATTCCGGGGAAAAACAAGGCGAGAGCAGCAGCAGGAACATCGACAATTGCAGCACAAATTCGGTACGAATATCCAGTTCTTTTCAGCCACCGAAGCTGGAGTGTGTGCAGCCTCCATGGCTTCATGTCAAGCCGGAACCACCAGACTGGCCAGGAAGGGATGAGATTGATCAGGCGAGTATAGAACGAAAGGCAAATAGCGTGGACCTTCCCTTATCTCTTAGAATGATAAAGAAGAAGATGCAATGGCAAGAAGGTTTCAGACAAGCAGGGGAATCTGCCTACTGCTCGATGAAGAAGGCCTTCTCGTCGATGGTGTTTATCATTCGTGAGCTTCAATGCTACACGTTGCATATGCGAGAGATTCTCTTCTACGAAGACCTCCAAGGTATCCTGGCACGAGTACAGATGGAGATGCACGCCTCATTTGTTTGGCTTTTCCAACAGGTCTTCTCACACACGCCCACTCTAATGGTCTACGTGATGATCCTTCTTGCCAATTTCACCGTGTATTCGATGGGAAACAACGCAGCAATCGCAGCTCCGCCACCGGCGTCGGCTGCCACGGAGATCGTATCGGTGAATGAAAACCAACCCAAGAGTTTTGATTCTTCTTCGGTAATGAACACGTTTTCAGTTTCGTCTTCGACCGGGAAAACGGCCTTCGTGGGAGGACACAATGGCGGCGGCGGTGGAAAGTTCCGGCGTGTGATGAGTGGGACTGAGGGAGATGGACCTTCCGATAGTTCGTCATCGTCATGGAACTATCAGTCTCTGTCTCATCAGGTATCGTCGTTTGGGAACCCCAACCCCACGACGACGGAGGGAGCAGAGTCGGAGTCGGCATCGGTGGTAGAGGCAAATCCGGATGGTTTTGTTGGAGGAGTAAGGAGCGAGGAAGAAATGAAACTGTGGAATTCGATGGTGGATGAAGCTATGAGAATGCAATCGGAGGTGAGGGACGAGTCTCTCGATATCCACACGATAACAAATTTCGTTTCTCCGATAAAGGCAAACATTGAAGAGGAGGACCAATCTGATTACTTGAGGACGGAGCTTCTGTATAAGACGGCCGTGTCTCAAGAGCCCAACAACCCTTTGCTACTTGCGAATTACGCGCAGTTCCTATACGTCGTCTTACACGATCATGACAGAGCGGAGGATTACTTCAAGAGGGCAATAGAGGTGGGGAAGAAAGGAGGAGGAGGAGGAGATGCAGAGGCGTGGAGTAAATATGCAACATTCCTGTGGCTGGTGAAGAAGGATATAGAGGCGGCTGAGGAGACATATTTAGAGGCGCTAGCGGCGGAGCCAGGGAACACGTACTACGCCGCTACCTACGCTCATTTCTTGTGGAACACTGGTGGAGAGGACACTTGTTATCCTCTCGACTCCCCCGACAACGACTTCGACAATATGGTTTAACAAGAAATAGG
->AY015863.1 Lepidium latifolium chloroplast tRNA-Leu (trnL) gene, intron sequence 
-TTKAKCCTTGGTATGGAAACCTACTAAGTKATAACTTTYAAATTCAGAGAAACCCTGGAATTAACAATGGGCAATCCTGAGCCAAATCCTGGTTTACGCGAACAAACCGGAGTTTAAAAACGAGAAAAAAGGGATAGGTGCAGAGACTCAATGGAAGCTATTCTAACAAATGGAGTTCACTACCTTGTGTTGATATTGTGTTGATAAAGGAATCCTTCGATCGAAACTTCAAATCAAAAAGGATGAAGGAGAAAAACCTATATTTAGACAATATAGGTAACACAAAAGATCTCAAAAATGACGACCTGAATCTCGATTTCTATTTATTTATAAACAAAATAGGAATGTTGTGAATCAATTCGAAGTTTAAGAAAAAATCAACTATTCAGTGATCAAATGATTCACTTCATAGTCTGATAGATCCTTGGTGGAACTTATTAATTGGACGAGAATAAAGATAGAGTCCCATTCTACATGTCAATACTGACAACAATGAAATTTATAGTAAGATVAAAATCCG
->XM_014048373.1 Monoraphidium neglectum hypothetical protein mRNA 
-ATGGAGGCAGCCTTGCGACAGCTGCTGTCATGCGTCGACAGCGGCCGCCGCGACGCCGCCAGCGCGGCGCTCGTGAGGCTGCAGCACGCGTGCCGCGCAGCCGCAGAAACTGGCTGCGCCGCGGCGGTTGAGGTGCCCGGCGAGCGCTCCTTGGACCGACTGCTGCGGCACCTGTCCTTGGCCGGCGGCAGCGCGCGGGCGACCAAAGCGGACTTCAACACATCCCTGACCGCCAACCGGGCGCTCCTGATCCTGCTGAACGTGCGAGCAGTGGCGGACGCCTTTCTGACGGAGGGTCGCGTGGCCGCCCTGGTCGACACACTCGAGGCGCTCGATGGCGGCGAGGAGGGCGGCAGCGGCGGCCGCGAGGGCATCTCGGAATTGCGGCTGTGGCTGCTGACCGCGAATCTGGCAGCCGCGGCGCTGCACTTAGGTCTTCAACGCAACGGGCCCACGGGTGGCGACGTCGACGGCGGCGGCGGCCCCATCAACCCCGCGCAGCTCGCCCTGGCTGGAGTCATTGCGCGGCCGGCTGCCGTGCGCGTGCTTGTGCGGGCGGCGCACACGCAGCTGTCATCAGAGCTGTCTGCAGGGGACCTTCTATCGCCGCTTGAGCAGGCATTCTTGGCTGCAGCTTTCTTGCGAGAGCGGGCTACGCCAGCCCCCCACGACACGCCGTCAGGGCCCTCGTCCTGCGCCGCTGACCTGTTTGCCGCAGCGCGCGCGGCGTGGCAGGGCGCCGACGCCAATTGGCTCTGCGAGGCGCTGCCGCCGCTGCTGGCGATGCGACTGGAGGAGGCCAGGCAGCGGCAAGGGACAGGGCCCGGCGGAGAGGCGCTTGAGCCGCACGCTGCTCTGTTCGTGGCCTTGCACTTGTGCGCCGTGGTCGGTCCCCTGAGCAGGGCCCTGTCTTTGCACGCGGCCGCCATGCGCGCGGTCGCAGCGTGCATTTGTCGGAGCGGAGACATCCGCCTGGCCAGGTCATCGTTGGTCATCCTGACCGGCGCGCTCGACGCCTGGCCCTGGGGCCACGAGGGCGCCGGCACAGCGCTCGCGGCTTGCTGCCAACCCGACACTCTCGGGGAGCTGCTGCGCACAGCCGCCCTTCGCGGCACCCGCGGCGGCAGCGGGGTGGCGGCCGGCACGCCGGCGAACCAGGAGATGTTTCCGACTGTAACGGATGGTGGTTGTGCAGCGCAGCTGCTGGCATCGATCGCGGCCCACGAGGCGCTGTCCACGCGGCCATCCAGCATTGCTGCAGTGCCAGCGACCGCGGCTGCGGCGGTGGCGAGCCTGCGCAATTGGCTAGAAGTGGACGGCGCGCAGATGGCTTATGGCAACATGCCGCGACTCCATCAAGTCTGTGTGATGGTGCTCAGCGTTGTTGCTGGCGGCGGCGCCGATGGCGACGCATGGGCGGCCACGTTGTTGCGCCTCGGAGCGCGGCAGCTGCTGATGCGCGCCGCGGCCGAGCTAGGGCCAAGGGCACCCGAGTGGTCGGCGGCCGCATCAGCAGCACTTTACGCCGTCACACACGCAGCGCACGCATCACATCAGCAGCAGCAGCAGCAGCCTGCACAAGGCGGCACCACCAGCGGGCTTGAGGAAGGTGAGGAGGAGCAGGGCGCTGTCGCCGCCTTGGTGGATGCTGGGGTTTACGCGGTCCCGCAACTGCTCTTGCTGGCGGCCCTGCGTCCCGGCTGGCGGTCCTGGCTGATCCAGGAGCCAGACATACTGGAGCTGCTGTCGGCCGTGGCGGCTGCCCCTGACCAGGGCGAGTACAGCCACAAGGCCCTCCGCACCCTCTGCCTGCTGGCTGCGGGCGCGGCGCCGTCGGAGCGCCTGCCAAACTTTGCGCGGGCTGTGCTGGAGGTGTGCAATGAGCGGCCGGCGGACGTGTGGGCCGGAGTCCCTGAGCTGGACAGCGATGGCGGGGCCGTGGAGGAGGTGTTGGGGTGCCTTGCGGGCTGCCATGAGGCAGGCAGCAGTGTGGGTGAGCGCGCTGCCCTGGCTCTGACCCAGCTGAGGATCGGCAAGCTTGGGTTGGTGCAGCCCCCATCGCAACAGCAGCAGCAGCAGCAGGAGGAGGAGGAGCAAGACGTGCAGCAGCAACAGCAGCAGCACCAGCCGCGGCCACAGCCGCAACAGCACCAGCAGGAGGACAAGCCAAGCATGCAGCAGGCGCCAAACACAGGACATGCAGGGGCTATGAGAACGGCGCGCCCACATAGTGCATGCGCTGTCTGCGGCAGGACGGCGCGAGAAGGCGCCAAACTGCGGCGCTGTGCCGGCTGTGGCCGTGTCACGGGGACGCGGTACTGCAGCCAGGAGTGCTGCAGGACGGACTGGGTGGTGAGGGGGCACCGCGCGGTGTGCGAGGCGGCGCGGCGGGGCCAGGAGCCGTGA
->XM_031652239.1 PREDICTED: Papio anubis mab-21 like 3 (MAB21L3), transcript variant X1, mRNA 
-TGCAGATATTCTTTAGTATTTAAAAATGAGCAAATAAACAAAATGAGGCAAATAAATGAAGAAAATGAGTTTCTGAGGCACTGCTTAAGTGACCATAAATCAGACACATATTTTTATGGTGGGCAAATTGATGAAGATACTTTTAGTAGGCGATTTATATTCATAACAAATACATATTGAAATAATGTCACTACTGTATCAGAATTAAGAAACAGCCTCGCATTAGGACTTCTCCGTACAAATTCTTTATCATTGGTTCTTAAATTGGAAAAGTACCTATAAATGATTACATTTTTTAACTAAATAAAATGCAGATATTTTGGCTTCTTGTGAATTTAATAAAGAATCATAAAACATAGGCCTTTTTTTTGTTCTCCCAGAATGTCTCAAAAGCTACAGTAGTAGCTTTGACAAGTTGGGCAAATGCAGAACCTGCTAATGAGTTAAGTAATATGTGGACAGGGGTTGTAGCAAAGTTGTAGACTGATGGACACAAAAGTTAACTATCCAAATACTTCTAGAATGAGGAAAATGCAAAGACAGTGCATTGTGGAAAATCCATCAATGTAGAATATCAAAGGAGAAAGAGCTTATGATTACCTCAATAGAAAAATAAACATTATTTGACAACATTCAACATACATTCAAAATAAAAGCTATTAGTAGAGTAGGAATAAAAGGATGCTTCCTTAATAAAATAAGAGATACTATAGTAGATATGGTAAATTGGCACACAGCATCTCTTCACCTTCCTGGTACCTTGGCCTTTAGCCTTTTTTTTTTTATCATAACCCACAGTAAGAAATGTGTTTTATATATTCATCCTGTCATACTTCCCCACTTACAAATATATATGTACATATAAAATATCTATGAATCATAAAAATGTGTATATTTTATGCAATAATACTTAATCTTGCTAGGTACACTAATAACTTATGTTCTATTTCACTTTTTAAAATGCCATTTATGACTCAATAAATGGATATCATGACCCGCTAATAGGTTCCAACCCATAGTTTGAAATCCACTGTTCTACTCTATCTTCTTGTACTACAGAAGCTTTGAAGCTAAAATGTACATTTTCTGAATTTCTTGCAGATAAGTTTACCCTTTGCAGCCAGGTGAAGTTTTGTTTCCTTCAATCAGATACAAATGGAACTTGGAAGGTAGAAGCAAGGTGGAGGCCATACTTTTGATGAGTCTGCATTTTTCTTCACAGTGGTGGAGCCATTTGGTTTTTTTGAGGCAGTATCAGCCAGAGATGTTGTCAGTTGAGCAATAAGATCTTAAGATGTTTTGATAAACCTGGAGTAATACTTCTAGTATTCAAATGGAAAAGCAAAGATCCAAAAATATTCAAGACAACTCTGATAAAGAAGAGCACACAGAAGCTCTGAAGTCAGACTACGAAATGAGTCCTAAGGGGCCTGAATGAAGATGTCAGCAGAGCTGGTTTCTGGATTCCTTTTCTGCAATAAAAGAGGAATGCCTGTAATCTGCCTTCTCCTCCCACTTTTCTGAAGAATCCCTGGAGCAAAATTGGGGAGGAGGCCGTAGCCTCCTTGTGGGAGGAGTTGGAGAGACTACATGATAAAACAACTTTCTGACCCTAGACAAAAGACCTTCTCTCTTCTGTTTTTGGAATCGTTTTGGAAGGATGACAGATGGATTTTCACAATTTGGAAATAAAAACATGAGTGAAGGGTTCAGAAGGCAAGTCTCTGGTCCATTACACACTTCCAGAAAAATTTAGTACCCAGAGACTCACATTACTGGGAGTGCTGTTTACTCACAAGTGTTGCACTCCATTGAGAAAAAAAAAAAAAACCAGGAAGTTGCTGTTCTACTCAGGACTGACCAAGAAGCCATGAAATCCCTTACTGTGGGAGGCTTAGAAGATTGCCTACTGAATAAGGTGGACTTGAGGCGCCAGCAGATTTCCCAGGCTATGGAGGAGGTGCAGAAAGTCGTTCATCATTTGACCACAAACATCAGCAACCAAGACATTAGATTTCAAACTGTGCCTTACTCTGACACATACAATGAAAATATTAAGGTTTTGGCCCCCAGTCAGTTCCTTGTCACAGTCCCAATAAAAGGCCTGGCTGGCTACAGGGAGGCCAGGGAGCAGCGCTGGAGGTACTACACCCTGCAGGGCACCAGGCTGCCCTGCCCGTTGCGGGACCCTGAGGGTCTGCAGCAGTGGCTGGAGGTGGAACAGTTTATGAAGAGCCTGTGGCAGTGGCATGAGACAGACGTGAACATCGACGGAGACATTGTGCCCGCTAAGGTCCTCCTGGTGTTCCGGAAGCTGGTGGAAAACGCAATTAGAACCTGTCACCTCTCAGGTAAGGTCAGCATGCTAGGAAACCGCTCTGCAGTTTGGATTGCTGTGGAAACATCTGCATATCAGGTGGAATTGGAGCTGGCCCCCGCGGTGGAGATCCCCACCACCTGGTCCGAGAAAGCCCGGTGGCCTCGATGTCTGCAGCGCTGGCCTTCCCAAGAGAGAGTGGAGTGCATCAAGTCGTTTGGGTTTAACTTGTTGCCCTGTTCAAATTATCACTGGCAGCTGAGCTTCCTCCGTGCTGAGCAGGTGTTGCTAGAACAGCTGGATGAGGATGGGGGCTGCCGTAGGAAGTGTTTTCAGGTCATGAGGCAGCTGAAGGAGGACGTGTGGTGCCCAGGGAACAGGCCGGTCATCACGTCCCACCATCTGCAGACGGTGCTCTTTTGGACCTGCGAGAAATATCCCCACTTTAAAGACTGGAAGGTCTTCAGCAAAGCGTTTCTGCGCCTGGTGAGGAAATTGCACAAGTGTGTGAGCCAGCACTTCCTGAAACACTATTTCGTCCGGAACAGCAACCTCTTTCAGTGCACCAACCCGATCGAACTGGACGCTGTGGCCCAAAAACTGGCCACCTTCCTGAAGAAGCCCCAGATCAGCCCGCCCTGATGGCTGCCCCAGCCTGGGAGGCTCTTGGACATTTTATTCTGGCTTAACCTTGTTCTTTGGATGGTTCCTAAGTCAGGTGCCAGGATCCTGCCTAGGAGAAAGGCCATGAATGGCAGCGGAAATTACATCAAACCAGTAACACTTCAGCAGGGAGGGAGGAAACTGTGCCCCAGGCTGTCTGGCCCAGGCCTCCCTGGAGCCCAGCAAGCATTTCCACCCTAGCTACCTCTCCTGGAGACGGCTCTCATCAGGCTGCCTCAGGCACAGATTTGGAACTGGTGACAGTTCTGAACTTAGTTTCCCTTGTTCAGGCTCTGATCGCCTCACAGTGAAGATGGAGACGGAACCCCTGGAAGACATGAGCCTGCTGGCCAATACTGTGCCCAGCCCACCGATCATGGGTGCATTCTCCTGCCATTTGTAAAATGGGAATGTTAACGTGCCTACCTCTGAGCAGGGCTGTGTGTCTATGAGACTGTGCTGGCGCCTTTTCAAGGGGAAGACATTGGATCAACACAAAGTGTTCCTGGTTGGTTGAGCAGCTGGTGTTTGCATCCTGGATCGGTACCCACAGCACTGACGCAAAATTGCACCTGTTGAGTTAGCGAGCCTGTGCTTCCTTGCTGCCCTCCAGCTTCCTTAGCATGTGGGTCAGTGGCTCCTGAGGTTCTGTCTGCTTCTCTGGTATTCTCTAAGCAGGGACGGGAGTGGTTTTGATGACAAGTTTAAGTCAAAGATGAAAGCACAGCTGTTGGCCTGATCCCAACCGCAGCCCTCTCTTTGCTTCCCAGGCCATAGGCCATGGATGGAACTTCCTTATATATTTATGTAAATAACCTAGTACCATGATCTGCATGGAGTGACCTTAGGTGTCTGTCACCACTCATTGTGTTCCTTTGCTCACTTCATTCACTCACTCACTCATTGACAAATAATGCTCATTAGGCACCGGGAACACAGCAAAGAGCAAAGTGGATGAGGACCTCCCCCTGGGGATGCCGCCTAATGGTGGAGACAAGAAATGAACAACGGATAAACATGCACAGTTATTACAGATGGAAGCAAATGCTCCGAAGGAAATAAACAGAATGTTGAAGTAGAGTCCACAGAAGGGTCCCCAAAGGATGAAAATGCAAATAGCTGAAGGGGAAGGAAAAGTGACCAAAGGCAGGCCTGGCAGAGCTGGCATGAGTCAGAGCACCTGGCCTTGTAAAGCCAGGAAGGAATCAGTATTTTATTCTAAGATCAAAGGTGTGACATTTGGCCTCTGCAGAAGCGGAGGAGTATCACCATCTGACTGCATTTTAAACAATTGTTCTGGTAACTGCATGAAGAAGGTCTGGGGACTCACACGTGAGCCAGGAGCTCTTGAGCCACCCATTTGGAATTTCACAGAGGCCCACAAGGCAGCATATTCTGTGTAGCACAACTGATCAGGATTTCTAGGAGTTCTCGGTGAGATCAATGGTTTTTTTCTGGCGTTTACGTAATGCTTCTCAACTCAAGGGGCTCCTTTATTACTTTGGAATGTTTTTGCCCAAATATCTATACCAAAGATAAATTTCTAAAACATGAGCTACTGGTTTTGTTTTGATGAAAATTCACATTTGAAAATAAAAATGATTATTTTTCAAAAGTACTGTAACCAAATGGTGGGGTCCCTAGGCTATCGCATAACAAATAATGATTTTTAAAATATTGAAAACAAGTATTTCCAAACCAACAATGAGTTTACAATTTTTGAAAACATAAAGGCCTGGTGCAGTGGCTCATGCCTGTAACCCCAGCTCTGTGGGAGGCTGAGACAGGAGGGTCACTTGAGACCA
->XM_033668712.1 Dothidotthia symphoricarpi CBS 119687 RTA1-domain-containing protein (P153DRAFT_369234), mRNA 
-GATATCGACCATGAACATGAGACTCCGGAAAAGGTAAGATAGACGAATGCGAATGTAGAAACAACCAATGCGAGATTGTCAGACTTTGTCTACTCCATCGTTGGAATGTATTTAAGATGCTTTCTCACCTCCTTACTTTCCATGCACAGCTTCTCTTCCTGACGACGTACTGTATCCACTACTTCTACACTTGATCTTTAGTGTTTCATACACTCTCCACCGTTCCTAGTCTTTGGTACTATTCAAGCTGCAAGATGGCCAATCCTCCCAGCAGCAAATATTTTGACTGGAAGATGTACCGTTACGTCCCGTCCCTTGTCGGCGCAATAATTGCTATGATCATCTTCCTTATAATGGCTCTATTGCATTTCTGGCAGTTCCTAAAGCTTCGGAACTATATTGTCATCTTTGTGGTCATAGGAGCTATGTGCGAGGTTGGAGGGTTTGCAGCTCGAATTGGATCCCACTACGACAACGAAGAATGGGCAGCATACATCATTCAGGGTGTTCTACTCCTCGTTGGACCCCTATTCTATGCCGCGACAACTTATATGATGCTCGGAAGAACCATCCTACTCGCTGGGGGAGAAGATGTCTCTCTCATCAAACCAAAATGGTACACTCGCATCTTTGTCGCAGCAGATGTTAGCACTCTCATCATTCAAGGCCTTGGTGCCAGCATCATGGGCACCATGAAATTGAATCTCGCAATCGCAGGCGAGAAAGTAGTCATCGCTGGTCTCGCTCTCCAAGTCTTCACCTTCGTTGTCTTCCTCGTCGCGTCCGTCGATTTCCAGATCCGCATGAATCGCAAAGTCAACAACTACACGGCCACCGAAGATCTCTCGAACAACTGGAGAAAGATGCTTTGGATTTTGTATAGCGTCAGCACGCTCATTCTCTTCCGCTGTACTCTTCGCTTGATCGAGTATGCTATGGGTAACTCCGGCTATCTGATCGCGCATGAGTGGGCGCTGTATGCATTTGATGCTGTACCGATGTTCTTGGTGTTGATGCTGCTGCTGGTTCTGCAGCCGTCAAAGTATGTCCCGCAAAGTGACAGCAAGAAAGAGCACGGGAGTGATGAGGAGGTGGGAGTCGCGCAGAGTCAGTGACAGATCTATGCATGTTATGCTTATGCAAACTTTTAATATTGCTAGGGAAAAGGGTATTCTCATATTTCCTCAGTAGGAGTT
->XR_003329731.1 PREDICTED: Papaver somniferum uncharacterized LOC113287130 (LOC113287130), transcript variant X3, ncRNA 
-GCGAGAAGATAAAACCAGACATTCTCCCTCAAACCCCAAAAAGGAGGTTCCCCTACTACCAAAATCACCAGAGACTAATCTCTTCTTCTCGTCGTCTCTTGGATTGTGTATGCATTCATACTTATAAAGATGCTATTGAGGAGCATCAAACATTTATAGTAAGCAAGATTAATTTTGAAGAACACCGCCTACCTGCAGGTGGTTAAGGATCACAGTAATCATTGTTTGAGTCGTCAATTCGTGTTTGACGATGAGAGTGAAAAAGCTAATGCTGGCGCATTTACCAATTTGGAAGCGCTCAACTTTTTACGAGCTAGAGGAGCCTCAACAGATCCTACGAGTAGTTTCTCCTGTTTCTCCTTTTGAGTACCAGGTTTATGATTATTTGGTCAAAATTGCTGCTTATAGTCAAAGTACAAACACAAGAGAGTATCAATGAGTTCTTGAAGAGCTGTGAGAAATACAAACTTGCAAAAGCGGAGAAGCTCAACATCATTAAAACATTAGGCCGTCAACTCAAGAGGAAATTGACCCGGTATGTTTACTTTCAAAATCCCCTTTCAGTTCTTATTATATGTTTATTATTAATCATTGTTAGACACTCTTCTTTACGTATTAGCGTCCATAAATGACATCGTGCTTGTTTTGGTTTTCCTTTGTATTGACTAAATAAGGCATTTCAGAATTCTCTTGTGCATGCTGTAATTGTCAGGCTTAGTATAGACAGGAATAAATGAATAGAAATTCTTATGATCTGTCTACAGTTTTAACTGTTTCAAGATTCACTATCTCAGGAATTGGTGTGCAGACACTTCCACGCCTCCCAAATGTGTTTAAAATCTTGTTCCTTTATGCTTTAAAGTTAGTGTATCATCTAAATCTTTGTTAACCAATTTTAGATTTATGAACTCTTCTTGACGACCTCACCAGTCCCTGGGGTCTATATATTGTTTGAAATATGACCTAGTAGGCATGATTGTCTGAACCCTTACTTTTATCAAAATTGGCAATAAACGAGAGATCTTAAGATTCATCAATCTGGTAGCGAGACAACATAGATGATTGCCTCTCAATTGCGGAATCATAATTGTTCAGCATGTGTAGGCTAAATATGTTATACCTTCTGATTATATTAGATACCTTAAAACTTCCCACTTCCTAGATTCTTCTGCTTTTTAGCGTCTTTGAATTTATAGGCTCTGGCAAGATGTTTTCCATTGAGCAGATTATTGAAGAGTGTCAGAAATGCTTGGGAGATGAAGAAGTTGAAGAGTTGGTGGAGCTGATATCAAATTTATTTTGTCCACCACTCTGAAGGTACAGATGAGGGTAAAGGAATTCTTGATGGTTTCTGAATGGAAGGTAAAGATGATGTCAAAGGAGCTCCAGATGAGGAAGATACAGAAGGATTTTTTGACGGCTTTCTACTGAAAGATATAGATGCGGGTATAGAACTATAAATCTCTATCAACTTTATGGGAACTCTAAACGATCAACCAACTGCTATCTTTCTCAACCTTTTCATGTCATCTGTCTTGGTATTAAGAGGCAGAAATCTTTGTGAATTGAGACCTGAATTAACTGAACTTGTGCAAAAATATTCTATTCTTCATGTGAGCAGTTTCAGTCCAATTATGAGACCTGAATTAACTTGTGCAAAAATATTCTATTCTTCATAGGGAGGAATGTTTACATTCTGACGACAATGGATCAGAATGGTCAAGGACGCAAGAGCGGTGAACAGGATAAACTTTGGGAATTTGTTGATCCCATTGATAATCTTTTTCAAATCCCATCCGGAGTCATTCAGGTGTTACCTGACTTGCCCATGATTTGGGAGAATAATGTTCTTGTTCAAGGCATGTGGAGCAGCGAATGAAACCTAGAATGGATGCATGCAATTCATGATTTCCTTAAACCCTACAAACCCCTTCTCAACTCTCACGTCATCTATTTCTTCACTGATAAACTTTGGAAATGCATGTTGATCAACAACGTCTTCATCATGACCCCATTGCAAATGTTTCTTCAAATTTTGAATCTGAGCTTGGGGTATGGATGCAGTTGAATTCAATCTTGTGTAGG
->XM_053220790.1 PREDICTED: Acinonyx jubatus zona pellucida like domain containing 1 (LOC106972235), transcript variant X3, mRNA 
-GAGACAGAGAGACAGAGAGAGCGTGAGCCGGGGAGGGGCAGAGAGAGAGGGAAACAGAATCCAAAGCAGGCTCCAGGGTCCCAGCTGTCAGCACAGAACCCGATGCATGGCTTGAACTCACAGACGAGATCGTGACCTGAGTGGAAGTCGGACGCTTAACAGACTGAGCCACTCAGATGCCCCTTATATTTCATTTTCTTAATGATGTCTTTTTTTTTTTTATAGTGAATGGTGTCTTTTGAAGTGCAAAGCTTTTAAGGTTTTATGAAGTCCAATTTATCAATATTTTCTTTTATGGATAGTGCTTTTGATATCATACTAAGAAATCTTTGTTTTCCTTAACCCAGGTCATAAAGATTCTCTCCTATGTTTTCTTCTACAAGTTGTATAGTTTTAATTCTTTACTATTTTGAAGGAGAGATAGAGAGACAGAGTGTGAGCAGGGGAGGGGCAGAGAGGGGGCAGAGATAGAGAGGGAGATACAGAATCCGAAGCAGGCTCCACACTCTGAGCTGTCAGCACAAAGCCTGGCCCCAGGCTCGAACTCATGGGCTGCAAGATCATGACCTGAGCCGAAGTCAGACACTTAACAGACTGAGCCACCCAAGCACCCCTTAATGCTTACATTTGGTAAGGGATTTTTGGTCTATGATTCACGTGGAGTTAATTTTTGTGTATGGTGTAAAGTAAGCGTCTAAATCCTTTTCCTTATGGGTATCTAGTTGTCTCAGCAGCATATGTTGAAAAGATGGCTCGTGTAATTGTTGACTCTGCTTTTACTACATTTGTGTCTTTAAAGAAAAGCTGAAGTAAGTAGGGCATAGAGAATTAATGTATTAATGAAGATGAAGAGATTCTTCTGTGTTGAGGTTTTAAGCACTTACATTAGATAAGGAACATCTGGTTGATGTTTTAAAGAATAACTCGAACCATAATTTCATTTCGTTTCCTTCGTCTCCCCCATTCCCTCCCCAGCTCTCCACTGAACATCTGCTTCTCTTATGTGAGGGGAAGTGAAAGATTTAGGTCAGGCATAAACACAAACTATCTTTACTGTATTGTTCCCTTTTAAGACCAAAATACCCACCCTGCCGGGCCAGTTTAGCACTACATTACCCTATATCAACAGATCTACTGCAATTTTTGGAAGCTGGCTTTCCCCAGGAAACAGAACTGCTATTGTTACTTCTCGGTGTTATGTAATAAATCTGGTGGGTCACTTTCAAGGATGTGAACAGGAATCGAGAAACACTGTCCTTCAAATATCACTTTTCTTTATGTTAGCTTTATTGATGAATTTCTCACAAGAAGTATCTTAAGAGACATCACTAGTGTTGTGAGCCCTCCGCATCCAGATCTCACATGTATCTATGGTGCTGGCTAGAGGTAACCCCAAATAAAAACAGTTTCCGTTGACTTCTGGCTTCACTGATGCAAGATAGCAAGACCTTGGGGAAGTCTATCTCCCCAAAATACCATCCATTTTGCTATCTTAAATCTTTGCAAAGAACAGGATGATTACATTTTCCTCTCTGGGAATTTACTGAGTTCCTCTGTTTTATGGCACTGACCTAGCAGCTCTAATTGGGGCACTCTTCTACCCGTGGCTTTGCTAAAAATCCCTCACAATCAGGACTGCAGTGTAATAATAATAATAATAATAATATAATGCAATAGCTCATATGTGTATAGCACTTATTATGCACCAGACCTTCTTTTCTTGCCTTACATATATTAACTCATTTAACTGTTCCCTGGAGGCGTACATTAAAGCTGGCATTGCTGGAGGGTAATGAGTATAGAAGCAATTTAGTGTTTGGAGTATGATAAACTTCCATAAAATAGAAGGAAAGCCTTGAGATGATGCCTCAGGGATAAAATTGAACAGCCTGGTCCTTTTTGGGGTCTCATAATTTTTTCAGCTGTAGAACTCATTTGAGGGAAAAGTAACAGGTAGGAAACATTGGTTTTCATCACCTCGCTTTGGTTAGACATATGCTTTGGATATTCTTCCTCAAGCACCTTCAGAATCCCCATCCACTTCCATGTCTAGGCACTCACTTCAGTAGCCTGGCTCTGGGCCACTCTAGGGCTATCCAGCCTTCTCATTGTGAGGCTGGGTCCCTGTTGGTGCTTTCCTGTCCTGTGTTTCATTGTGGGAGCCGTTTGCTGGGAAGGGGCAGTTTCACCAACAAGGAGGAGGTCTTTTAAAATTCTAGCTCACTGTTGATCAGAACCAGGAATTTCCCTTAGTTTAAGATTTAGTTAGTAGACAGGGGCTCCTGGGTGGCTCTGTTGGCTGAGTGTTCGACTCTTGATCTCAGCTCAGGTCTTAATCTCACAATTTAGTTAGTACACAAACATTCTGGCTTTCTCTAAGTTTTTAGCCAGTTTTTTACATTTTAGTAGAAGATTCAGGAACACGTTTCTTGGGAGGAAAGAAAAGAAGAGGAGAGATTCTGGGGGCATAGCAAGGGGGAACAAAGAAGGGAAGAAAAGTTGGAGAGCCTCTGTGTACCTCAAAATTTTGCCGAGGGCCTTGCCTTGACAGTGGGGTGCAGATAGGTCCTTCATTGCTGTCCCCCAAATCTCACCAGCACTGTAACAGTGGCCTTCTATGAGTTGTGCACTCACCTTTGTCATCTGACACAGGGGAATGACTCAAATGGTTGGAACGTTCAGACAGGTAAGAAAGGAGACAGGTTATTACAGATGGGGGTGGGGAACTTGTTTTGGACAGGTAGTTCCTGGTGGCATCAGGGAAAACATGCCTTAGGTGGCTCTCTCTGACTGATACATTGACTGATCCTGCTAAGTCAGGAACATGACCAAGATGGCCTTATTTTCCTCAGCTTGACTAAACTTTAGACAGGTTTCTTAGTGACAATAGGTCACTGACCTCCCTTGTCTTAGAGCATTTACTTTAGAAAACTTACAATTGTAAATTCTTTATTTGCCCATCTGAGATGTAAATCTTTTCCTAGCCTCTTGCCCCTTTTACAACTGAGAACCATCTGTTTCAGAGACCTGGGAGACATCTTTTGAAATATTATCATCAAGAAAGGTAGCATCCAGGTCTCCCAGTTTCTGTAGGAGGGTAGGAACCTAGACTGGTGTCAGCAAACACAGATGGCCTAATCACATTGACCAAACTAATGTCCTCCAGTACTTTTCAACTAGCTAACCTCGGCCCTTAGAAACCTTCCTGCTTTTTTTTGTTTCTAGGGAAGTTAAGTTCTCTCTCCCCTTGAAGAAGACTTGAATTATGTCTTCTTCTTTTTCAGCCAAACTCTGTTCTGTGAAATTTTTCTTTGACATACAGACACTTGTGCAATATTTTATCTAAACTGACTCTCAGTGTGTTTGGAAAGCCATTAACCAAGAAGACAGGATAACTTTATCATGGTGCACTGTTTTCTGGACTCATTATTGGGGGTCTGACACCCACAGCATTTCATATGCTATTAATCACCTCCTCCAATAAACCCAAAACCCAAACCAGAATGCTTCTCATATTTCTTTGCCATAAGATACCTTATATATACACACGTATGAAAAGTATACATGCACAATGTTATATAGACAGACACACACAATTAGTAATAGCTATCATTTTTTTGTAGGTCTACTGTGTACTTTGTATACATACACATAGTACTTCATACATATTTCCTCATTTGATCCTTACATCATTTCTATGAATCAGGTATCATTTATCTCAAGATGAGGAAGCCAAGGCTGAGAGAGTGAAGTGACTACTTCAAATTGCTGTCAGAAGTGGGATTTGAACCCAGTCAATCAGTCTACAAATCATGATATCAGGTTTCCAATTGTCTTTCAAAGATTCACTGAGCTACCTTGTTAGGATTCTGGTCCAGAGGGAAACCTGTATTTCCAGAAGGAATTAAGGAAGAACTTCTGTCACTGTCCCTTCATCCCTCCTCCCAGAAGCATTATAGAAGATTTTACTATTCCTTAGAGAACTTCATCTCAAAGTGTGTCCCAACTCTCACCTGTCACCTGTAATTTCTGCTTTGGGGTCTAGCCCCAAATCTTGAGGAAGACATTTTTTTTTCCAGTTAATTCATTTTTGAGAGAGAGACAGAGTGTGAGCAGGGGAGGGGCAGAGAGAGAGGAAGACACGGAATCGGAAGCAGGCTCCAGGCTCTGAGCTGTCAGCACAGAGCCCCACATGGGGCTCAAACCCAAGAACCACGAGATCATGCTCTGAGCCCAAGTCATCCGCTTAACTGACTGAGGCACCCATATGCCCCTTGAGGCAGCCATTCTGATCTTCATTTCAGGGTTGCTCTGACAAGGATAGTTGGGGATCTGCCCTGGTGCTTCCAGCACAGAGGATATATTCCTTCAGTGGACAGAGAAGATGGTAGCAACTTCCTCTCTGAGTCACGCATATTGTCTGTCATTCTGTCAACCATCTGTCCTATTAGCCACGCTTGGGTGATGAATAGAAAGAACTCAACGTACTGTGAGGTTACTAGGTTACAGCTTGTGACATCAGAATGCACAATGAACAGAGCATTAGAAAGTAGACAGCAATGGTTTCTACTTATTTCAAAATATCCATGATGCCAGAGAAATACATCCCTGTTAAAAAAACCTAGGTCTTTGTAGCTCCCTTTCCTTCTTTGACATGGAATGAAAGAGATGTTTCCAGAACTGGTCAACTTCAGTAACTTTTATATCAGAGTCTGTGCTTAAAAGTATCACAAACAAAACTTCAGAACAATCACACTACCTAGAAAAAGTATTTCTAGGACTCTGAGATGGTCCTTGCCCTGAGGAAGGTGGCAAGTCTTGTGTTTACTATGGGGCCTACCCCCTCTCCTATGGAACACAGTGAGGTTTTATTCTGTGAAAGCTGTGGGAAGCTCACCGTAGGTTGTGTACCTGAGCCACTTAGATTCAAGGCAGCAGTGGTGAGGTCACTAAAGTGACCTTCTCCTTTCTCCCAGATGGAGGGGCTCCTTCTCATGAGGACTCTAACACATACAGCTCTACACATACATAAAAACTTCACTTCCATTTATTACTGGATAGATTTTTTTCAGTGTTGATGAGATGTTTTGTAGAAATCAACATATACTGTCCACATAAGGAAAGTTTAAATGATTTAAAATATGTTTCCTAATTATAAGCACTTGTGGGAAATTTGGAAAGTACAGAAAAGAAAAAAAAATTACAATTGCATCAACCCGGAAGCAACCATCACTAACAGGTTTTTTTGTTTTCCTTTTGGTCTTTAATTTTGTAGCTCTGTTTTTGTTTGTTTTTTTCTTTTTCTTTATTATTATTTATTTTTGAGAGAGAGAGAGAGAGAGAGAGAGACAGACAGACTGTGTGTGTTTGGGGGGCGGGGGGAGAGGGAGACACAGAATCGAAGCAGGCTCCAGGATCCCAGCTGTCAGCACAGAGCCCCATGTGAGGCTCAAACTCACCAATCGCGAGACCATGACCTGAACCGCGAGATCATGATCTGAGCCGAAGTCTGCGGCGCTTAACAGACTGAGCCACTCAGGCGCCCGTTGGTTTGTTGTTTTCAAGTGAAGACGCTCCTGCCCAAAAGGAACTTACAACTTTAAGGGCAACACAAATGAGAAAAATGAAGACAAAATAAGACTGAAAACCAGAGAACATGATGATAATGATGATGGGCTCACTGATTTCTCCAAAGTGTCTCTGAGACACATACTGCCTGGAATCAGTCACTTCCTGCCTTGTCTGCCACCCATTGTGTAGCCACAAAGAATGTGTGTTCTGTCAGCAGCTATAAAAGTACAGATCTGGGTGCTGATCAAGAATGTGAAGTGAGGCCTGAGAAAATGCAGAACTGAGTTGAAAGAAATGCAGAGTCATTAGCGTCTTAAGCCAATCATCACCCTAAAATGGTTTGAAGGGAGATATGGTAAACCCAAATCACTGTTTTAACTATAATGAAAGGTCAACCCAGCAATGGAAAGCAATGGACACATTTTATTTCCAAATGGTGATGCTGATCCATTTCAGTGTCTTCCTTCTGGGACAATGCAGTGAGAGCCAGTTGTCACTCAACACAAAGGTGTCTGTATTGTAGCTGCAAAAGAGGGTTATGGGATGGAGTGCCTGATAAGTTCCTCTAGATTGAGCTGTCAGCTGTGACCTCTCTGAGGAGGTGATCTAAGCTGCAATCTGAAAGGCAAGAAGGAGTCAGTGTGTGAAAATCTGTGAAAAAGTAACATCTGGCATAGAGATCTTAAGATTACATGGAGTATTTGCTTCCTGATCCTTCTTAATCTCTCTAGCCTGCATTTCTGAAAACTTGGGGAAGGCATACAAGCTTTGAAAAGACGGAAAATTTCTTAGCATAAATATCAGTAAAACAACTCTTTCCTATGGGATTTTGATGTCTCACTGAAGTAGCAATTAAAACTGGACTCTTTTGAAGTTGTTTATTCCAAGAATGCACCTTCTTGATTTTAAGGATGAAAAGATAGGAGCTGGAAGCAAACTGGATTCTGCTTCTCCAAACCTGAGCATATGTAAAAGAAAGCCTTTGCCCAGCAGAATTAGCAGATGGTCTAAATCCCCTTGGAGTACATGGGCTCAGTTCAACACTGATTTGGGATTATTCATTCAAAGTCCTTGGTCTTCTGGAACTTTAATAAGGCTTTCCCTCATCAGGCTGACGATGGCTCACTTCACACATAACCACTCAAGACTTCTGTGCAGCATAAAATAGAAGATCAAAAGCAGGGTTGAATCTTTTTTGAAAGAGTTTGGTAACACCAGGCATTTGAACACTCAGTCACATGCAGCAGAACCAGGCACATGGAGAACAGCTGATTCCACGAAACCAAGGGCTTGGGTTTTGCAATGGAACGAATATGGTTGCTGTTGCTTCTAACAAGTAGAGTGCTTCTGGGGTCTGCTCAGTTTAATGGCTACAACTGTGACGCCAACCTCCACAGTAGATTTCCTGCTGAAAGAGACATCAATGTCTATTGTGGGGTGCAGGCCATTACAATGAAGATTAATTTTTGCACAGTACTTTTCTCGGGTTATTCTGAAACAGATCTGGCACTGAACGGAAGGCATGGGGATTCCCACTGCAGGGGGTTCATCAATAACAACACCTTTCCCGCGGTGGTCATTTTCATCATCAATCTCAGCACCTTGGAGGGCTGTGGAAACAACTTAGTGGTATCCACAATTCCTGGAGTCAGTGCTTATGGGAATTCAACTTCAGTACAAATAGGAAATATTTCGGGATACATTGATACTCCAGACCCACCAACAATCATCAGCTATCTACCTGGGCTTCTTTACAAATTTAGTTGTAGTTATCCATTGGAATACCTGGTTAATAATACCCAGCTTGCCTCATCCTCAGCTGCTATTTCTGTGAGAGAGAACAATGGTACATTTGTCAGCACTTTGAACCTGCTCCTTTATAATGATTCAACCTACAGTCAGCAGTTAATTATCCCAAGTATAGGATTACCTTTGAAAACCAAAGTGTTTGCAGCTGTACAAGCCACTAATCTGGATGGCAGATGGAATGTCTTAATGGATTATTGCTACACAACCCCATCAGGGAACCCAAATGATGACGTTAGATATGATCTCTTCCTTAGCTGCGACAAAGATCCTCAGACCACTGTCATTGAAAATGGCAGAAGCCAGCAAGGCCGGTTTTCCTTTGAAGTGTTCCGATTTGTGAAACACAAGAATCAGAAAATGTCCACCGTCTTCCTGCACTGTGTTACCAAGCTCTGCAGAGCTGATGACTGCCCCTTCCTTATGCCAATTTGCGGCCACAGAGAAAGGAGGGATGCAGGGAAGAGGACCACTTGGAGCCCCCAGAGCACGTCTGGAAATGCAGTCCTCTCTGCTGGTCCCATCATTACTCGGAGTGATGAGACTCCAACCAACAATTCACAGCTTGGTTCTCCAAGGGAACCTCCCTTCCAGCTGAATGCCATCACCAGTGCACTGATATCAGGAATGGTCATCCTGGGAGTGATGAGCTTTTCCCTTCTCCTGTGCTCACTGGCCCTTCTATACAGGAAGGCACCCACCAGTTTGGTGTTGAATGGCATAAGAAACCCAGTCTTTGACTGACTTTAACAGGTCCCTTCTCTCAGGAGGACTCACTGACTATACCCTGTGTTACTGCAGTCAGTGTTTTCATCCAAATTGAATGCCAGCCAGCATTTGATATTTGTAGGTTTGATAGATTTCACAGTGTAGTTCGTCAGCATGATGATAGTGAAAGAATTTGGGTGGTATTGTTCTCGTCGCGTAAGTATGTGGTCAGCCCTATTTGTATGGCACCAATGGGTAGAATGACAACAAGCCAACCATATTCAGGACTCAGATCTTACAAGATCAGTCATATTTCATTTTATTTCAATTTTCTTTTGATAATTGGTTGTTATAGAGATAAAAGGTGGGCATAGAAAAAATATACATTTGTTGCATTTTTCCCCCTAAGCATTTATATCCAATGTGCTGGCATTTAGATTGTTTATGTGGTCCTAAATTGAAAGTTACTTTTTTATTTGT
->XM_019449735.1 PREDICTED: Panthera pardus microtubule associated protein RP/EB family member 3 (MAPRE3), transcript variant X4, mRNA 
-TTGCAGATTTTCCAGACAGCTGGGGTATGGCCGTCAATGTGTACTCCACGTCCGTGACCAGTGAAAATCTGAGTCGCCATGATATGCTGGCATGGGTCAATGACTCCCTGCACCTCAACTATACCAAGATAGAACAGCTCTGTTCAGGGGCAGCCTATTGCCAGTTCATGGACATGCTCTTCCCCGGCTGTGTGCACTTGAGGAAGGTGAAGTTCCAGGCCAAACTAGAGCACGAATACATCCACAACTTCAAGGTGCTGCAAGCAGCTTTCAAGAAGATGGGTGTTGACAAAATAATTCCCGTAGAGAAATTAGTGAAAGGAAAATTCCAAGATAATTTTGAGTTTATTCAGTGGTTTAAGAAATTCTTTGACGCAAACTATGACGGAAAGGATTACAACCCTCTGCTGGCGCGGCAGGGCCAGGACGTAGCGCCCCCTCCTAACCCAGGTGATCAGATCTTCAACAAATCCAAGAAACTCATTGGCACAGCAGTTCCACAGAGGACGTCCCCCACAGGCCCCAAAAACATGCAGACCTCTGGCCGGCTGAGCAATGTGGCCCCACCCTGCATCCTCCGGAAGAACCCCCCATCAGCCCGGAATGGCGGCCATGAGACCGATGCCCAGATTCTCGAACTCAATCAGCAGCTATTGGATTTGAAGCTGACGGTGGATGGGCTGGAGAAGGAGCGTGACTTCTACTTCAGCAAACTTCGAGACATCGAGCTCATCTGCCAGGAACACGAAAGTGAGAACAGCCCTGTTATCTCAGGCATCATAGGCATTCTCTATGCCACCGAGGAAGGATTTGCACCCCCTGAGGACGATGAGATTGAGGAACACCAACAGGAAGACCAAGACGAGTACTGAGGGCGGCCCCAGCCCTGGCTGACTGCACGGCTGCCGTGCCTCCCCGCCCTGCTCCTGCCCCACATTATAATCCTTTCCTTACAGC
->XM_044229603.1 PREDICTED: Neovison vison NOVA alternative splicing regulator 1 (NOVA1), transcript variant X2, mRNA 
-GAAAAGAAAAGAAAGAAAGAAAGAAAGAAAAGAAAAAAAAAGAAAGAAAAGAAAGAAAAAAAAAAGCCAAAACAAAAGGGAGAACCTTCTCCCCGTAGCAGCGGCAGGAACTGCAAACATGATGGCGGCAGCTCCCATCCAGCAGAACGGGACCCACACTGGGGTTCCCATAGACCTGGACCCGCCGGACTCGCGGAAAAGGCCGCTGGAAGCCCCCCCTGAAGCCGGCAGCACCAAGAGGACCAATACGGGCGAAGACGGCCAGTATTTTCTAAAGGTTCTCATACCTAGTTATGCTGCTGGATCTATAATTGGGAAGGGAGGACAGACAATTGTTCAGTTGCAAAAAGAAACTGGAGCCACCATCAAGCTGTCTAAGTCCAAAGATTTTTACCCAGGTACTACTGAAAGAGTATGCTTGATCCAGGGAACAGTTGAAGCACTGAATGCAGTTCATGGATTCATTGCAGAAAAAATTCGAGAAATGCCCCAAAATGTGGCCAAGACAGAACCAGTCAGTATTCTACAACCCCAAACCACCGTTAATCCAGATCGCATCAAACAAACATTGCCATCTTCCCCAACTACCACCAAGTCCTCTCCATCTGATCCCATGACCACCTCCAGAGCTAATCAGGTTAGACTATTTCCACAGGTCAGAGTGGCAGACTGTAACTACAGTAGTGGGTCTATAATAATTTCCCCCTGAAAATTGAAGGACAGTCGCAAAGAGAAGTC
->XR_007719743.1 PREDICTED: Macaca thibetana thibetana uncharacterized LOC126937484 (LOC126937484), transcript variant X3, ncRNA 
-CCCTGCTTGCAGTTCCCCCTTCTGTAGGGCCCCCATGCTCCTGTCCCACCCCCTCTACTCGGCGTCCGGGTGCTGGGTCGAGACGTGTGTGGGTGTTGGGAGGTGGATATCTCTTTTCCGAGCCGTAGGCGTCACCCCTACGCCCAGGCCCAGGCCCAGTGCTGGATCCTGCACTTTCCCAACCTCCCCCTCCCAAGTTACAAGGTTGCCCTCTGTTCCCCTCCCGAGCGCAGGTGACGAGCTGCTGAGACAGTGTCTGATTCACCGACAGCTGAACCAGCTACTGGTACTTGGGGAGACAGAGTCTTGCTATGTTTCCCAAGCAAATTTCAAACTCTGACCTGAAGTCGTCTTCCCACCTCAGCCTCCCAAAGTGTTGGGATTATAGGTGTGAGCCACTGCAACTGGCCCAGAACTGGAGTATTTATCCACCCAATCCTTGAACAAACCAGCAGACCAATTCAGAGTCCATTTCAGTGGTGCAGGTGAGAGGTATTAGAGACCTGGACAAGGTGGTGGCAGATGAAGATGGAGAGAACAGAGATAGGATCTCACTGTGTTGCCCAGGCTGACCTCCTGCCTTATACACCACCTCACCAAGCTTAACAGGGTGAAAATATAGGAGATGACGATCCATTCCTGGGTGGACGGCCAGCGTTCCATCTTCACTAACACGATATAGTTGAAGAGCATCAGGTATCCGATATACGCCAGCTGTAAGGAAATACAATACAGTGGTCTGGCTGTTCAGGCCCAGGAGCCTCAGCGTCAGCCACGGCCACTGCACAGCAGCACAAAACAAGGCCCAGTGACATGCACATTCTTCCAGAACCTCTGCATTTTAGTACCCACTTCACACCTTGAATTTGAATCCTCTCCAGCCGGATACCTGAAATAGGCTCTCAACACAAGCAGGGTCGAGGAGCCAGCTGGACCCCTGCCTGCTTTCTTCTCGGACCAGAAGAGGACCCAACCTACTCCTAGAGAAACTTGCTACAATGCAGAAGTGAGGTTACATGGAAATGAGGTGTGTCCTACCTTTCAGAAACTTGGGAGAGTAGGACACACCATTTTTGGAAATCTGGTGAGAAATACTCTTACAGAGAAAAACACAGCCCCAAGTAAAGTACATGGGACCTTCAATCTGAAACTGAATTGTATTGTTAGGCATGTCTGGTGATTCAAAAGACTGGCATACCTCATTTCCGATCACTTCCTCGAGGCCTGGGCTTTGTCGATACGTGAAGATGAATTTTGGAGAATCATGAAAACACAACTGAACGGATCTGGGGGATCCAGTCTGATGGGTTTACTGAGGCCAACTCAGCCATGCAGAAGAGTGCTGGACACACAGGCCCCACCCCCCAAAGAGGCAGCCTCCCAACAAGCTGCCAATGACATAAGCAAAGCAGCGTGTCTCAAGCATCTCTAATCACAAGTTTCGCCTGGGAAGCTAGTTAAACTAACACAGCCTCTTAGGCTCCTTCATGAAGATTTGATTCCATGGGTCTATGATGGGGCTAGAAATTCGCATTTCTAACAAAACGCCCTTGTCATCATGGAAGTTTTAGAAATGTTGATACTATTACGTCTACTGATTTCTGCTCTCAGCAGTCTGTAAACTTTTTCTGCAAATGGCCAACTGGTTAACAACTTTTAAGGCTTTGTAGACCTGATAGTCTCTCTCTGTCTCTCACTACTCATTAACTCGATGTGGTAGTACAAAAGCAGGCAGCCTACTGGTAATGTTAAATGAGGTTTAGCCTAAAGCTGCCTCCTTACATATTTTAAGTTCGGCCTAAAGTTTTCTCTGTACATTGTGAACTATAACAAATGAAGGTGTAACAAGACCAATCACTGAATTTCAGTCAATCAAATGTAGCCAACTGCTCAAAATGTGTTCAAATAAGGTAAATGCTGAGCTGTAACCAATCCAGCTGTTTGTGTACGTCACTTCCGTTTTCTGTCCATAATTCTTCCACCACGTGGCCCTGCTGGAGTCTCTGAGCCTCCTCTGGCTTGGAAGGCTGTCCCATTCACGAATTGTTCATTGCTCAGTTAAATTCCTTTAACAGAAATTAAGAGTCTGCCTGTGCTCCAATTCTTTATGGACACTACAATTTGAATATATGTCTCAAGTATTCCTTTTTAAATTTTATTTTGACCCTTTAAAAATGTAAAAACCATTCTTAGTTTGCAGGCCACAGTCATAGGCCATGGGTTGAATTTGGCCCGAGAGCTGTAGTTTGCCAAGCGTTGTTCTAAGCTAACAGTTGGGGTATCATAATATTAAAGGAAGGACAGACCTGGGTGTAAAATAGCTCCAAAAATATTATCTTAGGCTGGGTGCAGTGGCTATTGCCTATAATCCCAGTACTTTGGGAGGCTGACGCAGGCCCATAGATC
->XM_032774723.1 PREDICTED: Chelonoidis abingdonii docking protein 5 (DOK5), transcript variant X4, mRNA 
-GTCAGCTGATGCAGAAGGGTCCTCTAGCCTCTTCCCCCCTCTCCTGAGTGGATTAAAACTCTGGCCGCTGAGTTTCTGGGTCAGGAGGATTATTCCAAGTGATGTGAATCATTTCAGCTACCGACTGGATTCAACTTGGGCTAGCGGCTCCTCCCCACAAAAAGGATGGCTGCCAATTTTAATGACATAGTGAAGCAAGGGTATGTAAAGATTAGGAGCAGACGTTTAGGTATTTATCAGAGATGCTGGTTAGTTTTCAAGAAAGCTTCAAGCAAAGGGCCAAAACGACTGGAGAAGTTTTCAGATGAGCGTGCTGCCTATTTTAGGTGCTATCACAAGGTCACGGAACTCAATAATGTGAAGAATATATTACGACTGCCAAAAAACACGAAGAAACATGCTGTAGGCATTTATTTTAATGATGACACATCCAAAACCTTTGCTTGTGAATCAGAACTCGAGGCGGATGAGTGGTGCAAAGTGCTGCAGATGGAATGCCTAGGAACTCAGATTAATGACATAAGCCTTGGAGAGCCTGACTTGTTGGCATCTGGTGTAGAAAGGGAGCAGAGTGAGAGATTCAATGTGTATTTAATGCCATCCCCTAATTTAGAGGTGCATGGGGAATGTACCTTGCAGATAACATTTGAGCATATCTGTCTTTGGGATATCCAGAATCCCAGAGTAAAACTCATCTCTTGGCCATTAAGTGCCCTCCGGCGATATGGACGAGACCCAGCTTGGTTTACATTTGAAGCAGGGAGGATGTGTGACACTGGGGAAGGACTATTCATCTTTCAGACAAGAGATGGGGAGGCGATCTATCAGAAGGTTCACTCAGCTGCTTTGGCCATAGCAGAACAACATGAGCGCTTATTGCAGAGTGTGAAAAATTCAGTGCTTCAAATGAAAATGAGCGAGCGAGCCGTCTCCCTCAACACCATAGTGCCCCTGCCTCGGAGTGCCTACTGGCAGCACATTACACGGCAACACAGTATGGGCCAGCTCTATGGCCTACAAGATGTTTCAAGCCCCCTGAAGCTTCATCGAACAGACACTTTCCCCACTTACAGATCAGAGCATTGATAAGACTGTAAAGGATTTGAAAACTCTCTCTGTCTTGTGACAGCTTGGCCCAGCGGATAATAATGATGACAGCAAGCAAACAAAGTTGGAAATGCAGAAAAAGTCGGCTTGGATTGAATTAAGTCCTTGAATATATATATTTTTTTTTAACCTTGGCAAGAAAGGAATGTATTCTGTAGGTATTTAAAAAAATGCCAAACCAACTATCACACAGTTATTTAATATTTTACACCGGGAGGGGACAGAAATCAGCCCCTAAATGTTACTGAATGTTTTTATATGATAGATATATGTTGCAAATATATGAATTTGTCTTATGATGTGGGGTACTGTGATACCACTTAGTCTGTTTCAGCAGTGTTTGTGTTGACGTCAGCTGTGCCAGCAATCTCATGGTTCCTGTTTGCTGTAACTCATACCCTTTAGTTGTTAACATTATTGATTAAGACTAATCTTTGACTATAGTACTGATGGCCAGTTTTAAGCAGGAATTGTATCTGTTTTTCTTGTGTGAAGTCTCCTTGAGTCCTGATAGACTTTTAAAAGG
->KF434600.1 Uncultured bacterium clone SNGUT_M7 16S ribosomal RNA gene, partial sequence 
-CCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGCGGGGAGGAAGGCGGTGAGGTTAATAACCTCATCGATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTCTGTCAAGTCGGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTCGAAACTGGCAGGCTAGAGTCTTGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACAAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTTAGATAACCCTGGTAGTCCACGCCGTAAACGGATGTCGATTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAATCGACCGCCTGGGGAGTACGGCCGCAAGGGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCACAGAACTTTCCAGAGATGGATTGGTGCCTTCGGGAACTGTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTTCAGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGACCAGGGCTACACACGTGCTACAATGGCATATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCA
->XM_052950715.1 PREDICTED: Mya arenaria nephrin-like (LOC128235928), mRNA 
-ATGAGGGAACAACAGATTGTTGGTATCACCACGGTGACGTTATCTCCCGGCACCGATCCTATCAACGTGATAGAGAATACACAAACGACACTGCAGTGCCGAACATCGGGCGGGTTACCGGCAGCCTCGGTCAGATGGTTCATCCAGGGGTCAGGGCAGGTGCAAGACGTAACGTCGCTCTCCGCGAACACGTACCAAGAGGAGGACAACCTTAACGTGACGCTTAGCACACTTAACTACACCCCGTTAACAGCTGACCAGAATGGCCAGATATACTGTTCAGCAAACAATATGGGAGTGAGGAGAAATTCCACAAAGCTTTATATAAATGTATTTTACGGACCTGATAGACCGCTGTGCAAAACAAACAACTTCAACATAACTTCAGTATTGAAGGTCATTATTAGTACCACATTCACCATCTCCTGCACAGTTGACAGTAATCCAGCGCCATATTCGTGGCAGTGGTCACCTTCTGGAGGGAGCAGTCAACAGTTAGGCTTCACAAACATACAGAGGATACAGGGCGGAGAGTACACACTTCAGGTTTTGAACAGAATGGCTGTCACTGGGAGTAACAGTTTAGTCGATGGCAGTAACGCGACGTCTTTTACAGTGGATGTTTTGTTTCCCCCTGCTGTGCCAACATTACGCATGAGCGGTAAAGAGGTTATGGGTACGGTCAAGGTCATCGAAGGTAACAGCAAGACGTTCAACTGCAGCACAGAGAGTAACCCGACCAGTAGCTACAGCTGGACGTACCCACGAGGCTCAAGTTCTAACAACATCTTGCAAGTGAGCGACTTCCAGCCAGGCTCCTACGACGGCGATTACACGTGTCAAGTTCAGAACAGAATGGAGCCATCGTTTGGCAATTCAAAGGAGAATGTATCCCTGAAAACTATATCTGTCGATGTTTTGTATGGCCCGAAAACGGGGAATTTGCCGAACGCAAGTAAAGTTCGCGGGGAAAACCTTGTTTACCAGTGTTTGTACATACCTGGCAACCCTCCAACTGTTGACTTTGAGTGGACGAAATCCGGAACAGAGGTCTCCTGGGTCAAACAGAACACACAGAATTTGACCATTCTAAACCTGCAGCGCTCTGACGAGGCCAGTTACACGTGCAAGGTGTCCAGTGTTCTCCAGCCGACGTTGACATTAGCGACGACCACACAGTATGATACTGCAACATTTTTTCTAGATATTCTTTATGGGGCGGAAAATTTGCTGTTGCAACTCAACAACGTTTCCCAATCGTCTGTACAAATTGATGAACATTCATCAAACCATATGCGATGTTCGCTAGAAAGTGATCCCGGCTCGAATATGGCCCTTACAAAAGACGGTAAAACGATAATTGCACGATCTGGAGTACATCAACTCACACATGGAATACAGGCTGAATGTTCGGACGCAGGAGTGTATACGTGCTCAGGATACAACCAGTACGGAGCAGCAGATAACGCGTCAGTGCAGTTATTTGTAAAATGTTCCGCGAGGCGACCCACTGGGGTGGAGGTACAGCTTAATTTCACCGCACGCAAACATGAAAATGCAACATTAGTCTACAAAATAGTCGCCTACCCTGTGCCCAAGCCCCAAGAGTTTGTTTGGACGCGCTGTACGAATCGCACTTCTTGTGAACTTGTGCCGGATGAAATGAACAAATTTGAAATTTACACAGAGGGTCTATCAAGTAAATTAACGATTCTGGACGTTCAGATTGAAGATTACAGACTATACCAATTGTTAGTGTATAATGGAGTTGGTGATACACTAGTCGAATGGTTACACCTCAGACCCATCGGAAAATCGGATTCGCCAATGGACTTCCACGTTATTCAAGATACAATACGCGAAACAAGTGCTGTATTGACCTGGATTGCCGGATTTGACAACGGGTCTCCTCAGGAATTTCACATCTCCTATGGAAAGGTTGCTGATGACACTGGATATATTACACAAAATGTAAAACATGACAACAGAGTCGAGATGAATTACACAGTTGTAAATTTAAAACCTGGAACCGAATACTTTGTCTCACTAATTTCGGCAAACGAGGAGGGTTCTTCTGCACCGGTGAACGTTACATTTTTAACTCTAAAACGTATTAATGATCAAACTCAGACTAGTCCAAATACTGGTCCTGTTTTTGGAGGGGCAGTTGGCGGAACTGTTGGTGCAATAGTGGCAATAGTTGTCGTCGTTATCATTCTCAGGCGGAACTACGCACTAAATTGCAACGTAACCTGGACAAAGAGAGGTGAACCTTCCGAGCATTCCATATCCGGAAAAGACAACCCCGGATATAACGCAGCCGAGACGTACGAGGTCGTTTCCAGGACAACGGATACATCGGCATACAATGATCTAAAAAATGATGACAGCGGAGCCGATAACTCGCACGTGTATACGTCGTTGGAGGAGTCAAAGGCACCTGTTTACTACGAAAATGTAAAGAAAGATGATCCCATATACAACAATACTGCGCTGCAGAATCCGGTGCAAACAGTGCTTTAAATGTACACATCCATACAACAATGTGAAGATATGGCATTTTACAATGTCATTTACTTACCCAGTGAAATATCGAATACTAAACCAGCACTATATCAACGAAGTATGGATTGCATAATATTTGTTATCAAAATGTTTCATACTTCATAAAATTATATTGATT
->XR_003276401.1 PREDICTED: Carassius auratus uncharacterized LOC113048120 (LOC113048120), ncRNA 
-TTTTGAACAATTCTTGAGAGAGAAAAAAAACAGTGATTCTTTTACGTCCTGACGCAATAACGTCCGTACGTCTTTGCCTTGCGTGCTTTAAAATATTCCGATAAAGCCATATTAGGTTTTTGTAAAACCATGTCATTTAGGATACGCGTTAATAAAATTATCAAACAATCGTCGTAAATACATTTATTTTGTAACATTACTGCTCTTTGGCCACTAATGTAACTTTTAGCGCGGTAAAAATAAATAAATAAATAACAATAATAATTGTAAGCACGAGCTTTTGATTCGGGAACAGCTTGGACCGATTAGTGGAGCCAGGAAATGATCAGACTGGTTTTGGGAACCGCGTTAAGTGATTCAATGAGAAGATTAACCTCAAAAGAAACCACGCTTTCAATCGCGGGAATTTCTACAAACGCTGGAATCTCCCCCTTCACACGGAGGGATTTTATATGATGTCATGACGCGGGAAGGCAAAACGCACACATCCACTGACACAGCTGTAATACATTCCCACGCAAGCGAGACCACCATCCCGCCTGAAAAGCCTGGACATCCGTAGTGAAACATGTCTGGAATCGGCTTTCTGAAGATCTACTTCATTGGAACCGCGGTTTCTTTTCTGGTGGCTCTGTTTGGACTGGTTGATTCAGTCGGGGGTCTGATGTATCCTCAAGCCCCAGACTGGGCAGACGACAGCTGGACAGAGAAGCATCCGACCGTGTCTCCATCACAGACTGCTGCTGCCAGCAACACCAAGCGCAACGGATCGACATGATCTTCTCCGCTACCGTGGCTCGAGAGTCTAGCCTCGGGAATAATAGCCTCGGTTTACTGACCTACTAAAGCCTACTGTGGAACTACAATCTTCTACAATTTTCACTACTGCGGTCTGTGTCGTGTGAAATATGAGACATGAACACAATGGCTTGTGAGGTGCCAGCTCTTCACACTCGTTACGTTTTTACTTTGTTATTCTGGTTTCTGCAAAAACTTTAAATGAAAAAAGGGAAAAATTCTTCCGGAGAGGTTGAAAGCATAAAAATACTACAAATATGCAACATGAATTTGCTGGGCTGCCTTGGAATATTGAAATCCCTCTGTGGTCGATTGTTTTTGTAATGGGTTTTAAGTAGTTTTTGTAATGTTTGTTCCTTTTTTATATGCCGTTTATATGAAGATAAATGTAACACTCAGAATGTAAACATATGTGTAAGATGCTGTTTACCATGAGCAACTGTGGCATTAGGCAGCAAAAAGTGCACTCCCAATATGGCTAAAGGGTGTCTAAAAGATATCAGCTAGATATCTTTCAAATAGATAAGTTGGGTTATGTTACTGAAATTCACTGTTTTGTATTGAACTGAATACAATGTATACAGTTGCATTGTACATCACTAAAGCAGCCTGTTTTTGTGCTCTAAAAAGTTGTCAATTTTAATTAGAAAAATTTCCATTTGCTAAACTTTCAAATTACTTATTTCTAGTCATATTTTTGCTAAACTTTGTGTGTTGTGAACTTGTGATCATAACTGTTTATTGTGAAATGTTGTTAATGGTGTGGATTTTCCATTGAAATACTCTCGTCTTTACCTTTTACATGTCTTTGAAAAGCTGTAAATTGCAAATTGGCAGCTTTGGAAAAAAAAAAAACCTGTCATAGATGATTAAACAACATTACTATA
->XM_017265421.2 PREDICTED: Drosophila elegans E3 ubiquitin-protein ligase Ufd4 (LOC108141837), mRNA 
-ATAATCAATTTTCGAGCTGCTGGACTGGATATTTGTGTGAATAAAAATAGTGTGGTGTATTGAGTAATTGTAGAAAAGCTTTAAAAAAGCAGCTTTAAAAAAGCAAGCACCAGCAAAATATTCAATATAATGCAAAAAAGATTTGGTTAAGCATAAATCAAATTTCGATTTGCGATGGGCGATGTCGATCCCGAGACGCTGCTGGAATGGTTGTCCATGGGACAAGGAGATGAGCGGGATATGCAACTGATTGCGCTGGAGCAGCTTTGTATGCTGCTCCTGATGTCTGATAATGTAGATCGTTGCTTCGAAAGCTGTCCTCCTCGAACATTTTTGCCGGCGCTATGCAAGATATTCCTAGACGAACTGGCACCTGAAAATGTACTCGAGGTCACTGCGCGAGCCATCACCTATTACCTGGATGTGTCGGCGGAGTGCACCAGGCGCATCGTTTCGATTGATGGAGCCATCAAAGCCATATGCAACCATCTTGTGGTTACGGATTTGTCATCGCGAACATCTCGCGATCTGGCCGAGCAATGTATCAAAGTGCTTGAACTGATTTGCACCCGAGAAGCGGGCGCCGTCTTTGAGGGCGGTGGCCTCAACTGCGTCCTGTCCTTTATTAGGGACTGCGGATCGCAAGTTCACAAGGACACCCTACATTCGGCCATGTCCGTTGTATCCAGGCTCTGCACCAAGGTGGAGCCCAACACGCCGTGCATTCAGAACTGCGTCGAGAGTCTGAGCACTCTGCTGCAACACGAGGATGCCATGGTATCCGATGGCGCTTTGAAGTGCTTTGCCTCCGTGGCCGACCGATTCACACGAAAGTGGGTTGATCCAGCGCCGCTGGCAGAGTACGGTTTGACCACTGAGTTGCTCAAGCGCCTCAAGAGTGTCGGCGGAAACACACACTCTTCGCTGTCTGCGGCAGGAGCCCAGCCGACTAGCTCTAGCCAACCCGCTGCGGCCACAAACTCGGATGCAATCAATGAAAACGTAGCGGGCAATGCAACCATTTCCAGCAGCACCAAGGTCAAGGCATCCGATGTGGCCGCATCGCCACAGTCGATATCGACTACAATTTCCTTGCTGTCGACACTTTGCCGCGGATCTCCTTCCATCACCCATGATATTCTGCGTTCCCAGTTGGCTGACGCCCTCGAAAGAGCCTTGCAGGGCGATGAGCGATGCGTGCTGGACTGCATGCGATTCGCAGATCTCTTGCTTTTACTTTTGTTCGAGGGGCGCCAGGCCTTGAACCGAGGAAGTAACAATCCCAATCAGGGACAATTGGCGCCACGACCCAGGCGCAACAACACCAACACCGATCGCACGCATCGCCAGCTTATCGACTGCATACGATCGAAGGACTCGGAGGCGCTTCGCGAGGCCATCGAATCTGGGGGCATAGACGTCAACTGTATGGACGATGTGGGTCAAACCCTTCTCAACTGGGCTTCAGCCTTTGGCACACTGGAAATGGTGGAATATTTGTGTGAGAAGGGAGCGGATGTCAACAAGGGCCAGCGGAGTTCTTCCCTTCACTACGCCGCATGCTTTGGTCGACCGGCCATTGCGAAAATCCTGCTTAAATTCGGAGCCTATCCGGACCTGCGCGATGAGGATGGTAAAACACCATTAGATAAGGCACGCGAAAGATTGGACGATGGACATCGGGAAGTGGCAGCTATTTTGCAGTCACCGGGAGAGTGGATGTCTCCCGATCACTCGCTGCTCAACAAGGACGGAAAAAAGTATACGTTGATGGAGCCCAGGGGTGATCCTGAAATGGCGCCCATTTACCTCAAGGTACTGCTGCCCATATTCTGTCGGACCTTCTTGGGCTCCATGTTGGGCAGTGTGCGACGGGCCAGTTTGGCCCTGATAAAGAAGATTGTACAATATGCGTACCCAACGGTGCTCCAAAGTCTCAGTGAAACCAGTTTTAGCGAAGATGAGCCGTCAACATCGAGCCAAAATGGTGGTAACCTACTTATCGAAGTGGTCGCTAGTGTCCTAGACAACGAGGATGACGACGACGGGCACTTAATTGTTTTAAATATTATTGAGGAAATTATGTGTAAGACACAAGAGGAATTTCTCGACCACTTTGCAAGACTAGGAGTGTTTGCTAAAGTTCAAAACCTGATGGACAATGATGCAGAGGAATTGTATGTGCAATTATCAGGAAACCCCGATGAACCAGCTGTCGTGCAGAGATCATCGACCAGTGTTGTAGTCTCCCCAAGATCAACTTCAGATGATCCTATGGAGGACGCAAAGGAGATATTGCAAGGAAAGCCTTATCACTGGCGAGAGTGGAGCATTTGCAGGGGTCGAGATTGCTTGTACGTCTGGTCGGACTCGGTGGCTCTAGAGCTTTCCAACGGCTCTAACGGGTGGTTCCGTTTCATAATCGATGGAAAGCTAGCAACGATGTACTCCAGTGGAAGTCCAGAAAACGGAAATGACAGTTCTGAAAATCGAGGAGAGTTTCTTGAGAAGCTTATGCGTGCACGTTCCTGCGTAATTCCAGGAGTTGTATCCCAGCCCATTTTGCCCACTGCAAGTGCTCTACGATTGGTTGTTGGTAACTGGGTCCTGCAGTCGCATAAAACAAATCAACTTCAAATTCACAACACCGAAGGCCATCAGGTAACCGTGTTACAGGACGATTTGCCTGGCTTTATCTTTGAAAGCAACCGTGGAACGAAGCATACCTTCACGGCTGAAACTGTCTTGGGTCCCGATTTTGCCTCCGGTTGGTCAACGGCTAAAAAGAAACGCAACAAGTCCAAGACCGAGGGTCAAAAGTCTCAAGTTCGCAACTTATCCCGCGAAATTTACAACAAGTACTTCAAGTCTGCCCAAACGATTCCTCGCGGAGCGGTGGCAATACTTACGGACATTGTGAAGCAAATTGAATTATCCTTTGAGGAGCAGCACATGGCACCAAATGGAAACTGGGAGACAACACTCTCGGACGCCCTAATGAAGCTGTCTCAATTGATCCATGAAGATGGTGTCGTGAGCGCCTACGAAATGCACTCGTCGGGATTGGTGCAAGCGTTAGTGGCCGTTTTGTCGGTTAACCATTGGGAAAATAATTCACCTCGATGCAAACGAAATAAAATGCAAAAACAACGAGTTTCCGTATTCAAGAAATGCATACTGGAGGATAACGTTGAATCCGCAACGAATAAGCCGCGAACTAAGAGCACTGCAAGTATTTTAATACAGAAACTTGTATCGGTTCTGGAGAGCACAGAGAAGCTACCAGTGTACTTGTATGACACTCCATGCACTGGTTACAGCTTGCAAATTCTGCAGAAACGACTTCGCTTCCGTTTGGAGCGAGCAGAATGCGAGAGCACTTTATTCGACCGATCCGGTCGAACTCTAAAAATGGAACCTTTGGCCACAATTGGACAACTATCCAAGTATCTGCTGAAAATGGTGGCCAAACAATGGTACGACCTCGATCGGTCCACATATTTTTATTTGAAAAAAATACGCGAACATCGGACCGGCACTGTGTTTACGCACTTATTTGACTTTGACGAAGAGGGTTTGTTGTTCTACATTGGCTCTAATGCAAAGACTTGCGATTGGGTCAACCCAGCGCAATATGGACTTGTGCAAGTGACCAGCTCGGAGGGGAAGACCTTGCCATATGGCAAACTGGAGGATATTCTGTCTCGCGACAGCATCTCACTCAATTGTCACACCAAGGACAACAAGAAGGCCTGGTTTGCCATCGACTTGGGCGTGTATATAATACCCACTGCGTACACGCTTCGTCATGCGCGCGGTTATGGAAGGTCGGCTCTGAGGAACTGGCTTCTCCAGGGATCAAAGGATGGCCTAAGTTGGACAACCCTCAGCTCACACGTGGATGACAAGAGTCTCGTGGAGCCCGGTAGCACAGCGACTTGGCCCATAACGTGTGCAGCTGACGACTCGGTTAGATATAGGCACATCAGAATCCAGCAAAATGGACGCAATGCATCTGGCCAGACCCATTATTTGAGTTTGAGTGGATTCGAGATCTATGGTCGCGTCGTCGGAGTTGCCGACGACATTGGCAAGAGCGTCAAGGAGGCTGAGGCAAAAATTAGGCGCGAGAGGCGACAAATAAGAGCTCAGCTCAAGCATATGACTACCGGTGCTCGAGTAATTCGAGGCGTCGACTGGCGGTGGGAGGATCAGGATGGTTGTGCCGAGGGCACAATAACCGGTGAAATTCACAACGGCTGGATCGATGTGAAGTGGGACCACGGCGTACGCAACTCGTATCGCATGGGAGCCGAAGGGAAGTACGACTTAAAGATGGCCGATTGCGAATATCTTTCCGTATTCGAAGGAAACCAGTCGATGGTTACTGTGAACGCGGCTGCAAAAATAAACGATAAATCAAACACGCTCACCTCGCGCAAATCAAGTTCAACTCCATCCCTGCCCGAAGCCACTGAAAAGAATCAAAACGCTGAAGGTGCGTCCAATCAAACCGTTTCGGCTGATAACTTGGCCTGGAAACAGGCGGTGGAGACGATTGCAGAGAACGTGTTTGCTTCGGCAAAGACACAGATTATCTCAAATCAACTGGCTATGAACACGTCATCCTCTCGGGAAGTTCGAACCAAGCACAAGGAGTCGGCTGCCAACCAAATGCATAAGGATAACATAAGTGGACCGTCGCCATTGAGTCGCGAGCTGGAGCACATATCGGACTTGTCGGCCATCAACAACTCGATGCCGGCAATTAACTCAAATATTGTTTCCGATCTAGCTACCATTTCGGAGAACCTATCCCTAGCTGAATTGTCCAAAGAAAACATATGCAGTGTCCTTTCGCCTTCATATAAGCCCGCTGAGGCTGTTGCTGCGAGTCAAAGCTCAAGCCTTCCCGATGTACAGAGTTCGTCTCCGTCTCCGCGAGAGAGTGATATAAAGAACATATCCAACATTGAAGAGAACAATAAGATGAATGCAAACAACACGGTGAATAAGATATCAAAGGATCTGCTTGTGAATCTCCGAACATCGAACATTGCAGGCTGTCAACCGGTGACACAACTTTCGACCGAAGCCCTCGAAATGATCGACAAGATGCGTGATGGCGTGGATATGATACGGAATAACTCCAACAACATTCTTTCCACAGACACTTTCCCCATGCCGCCATGCACAAACATGGGAGTCGGAGTTAAAAAGACACCCAAGGCTCAGGCGCTGATAAATCCCGAAAATGCGAATCAAAAACAAATCATAGTTGCAACAGAAGAATATCCCAGCAAGAGTTCAAAGAAACCCAGTGTAACGTTGAAGCCAACACAGCAGCCAAATGCCGTGCTTTCGATCGTGGACATCAAAGATCCGCAAATTTCATCCGAAAGCGTTTCGGTGCCCAGCCAGATGAGTATAAGTGTTCCTAATCTGACAACAACTTCAGCATCTGAGGTTCCCTCCACCTCAGAGGTGGCTACCCACACGGGTCTGCTGGAGACATTTGCGGCAATCGCTCGTCGACGCACCTCGCAGGGCACCAACATACAGGATAATCAGATCATGAATGCGGAAGTGAATGTGAACGAGCACGGGGATCAGAACGCATCGGGCTCATTCCTCGGCCACTCGGTAACCAGTTTGGTTAAGCTGGCATTGTCCAGTAATTTCCATTCTGGACTGCTCAGCACCGCCCAGAGTTATCCGAGTTTATCGTCGAATAATAGTGAAAACATAGCCCCATCAAACCCGTCAAATACGTCGACGGGACAGCAATCGGCATCCACCATAAATCATACACTTACAATGAGTCTTACATCCACGTCGAGTGACAGCGAACAAGTGTCACTGGAAGACTTTTTAGAGAGTTGCCGAGCTCCGGCTTTGCTGGGCGACTTGGACGATGAGGACGACATGGATGAGGACAACGACGAGGAGGAGAACGAAGACGAGTACGAAGAGGTGGGCAACACTCTGCTCCAAGTGATGGTCTCCCGGAACTTGCTCACCTTCATGGACGATGAGGGTTTGGAGAACAGACTGGTGGGTGTTACGAAGCGCAAGTCCTGGGACGATGAGTTCGTCCTAAAGAGACAGTTCTCCGCGTTGATACCTGCATTCGATCCGCGACCGGGTCGCACGAATGTTAACCAGACTTCGGATTTGGAAATTTCCCCCATTGGCGTTGAGTTACCCAAGCCCCAACAGAGCGGCCAGGAGACTATTGAACAGCCGATGCTGGGTCTAAAACTACGTGGTCCGGGAATTGGCGGAATTCCCGAAGTTGAAATTGACCTGAACAACACAGACTGGACCATATTCAGAGCCGTGCAGGAATTGCTGCAGTGCAGTCAGTTGAACAAGCTGGACAAGTTCCGAAAGATATGGGAGCCCACATACACGATTGTGTACAGGGAGGTGCCGCCTGAAGCGCCAGAAAGCACTGGCGTGGACTCGGAGGAGTTTGCCCAAACACCGGATGTGTCGTCAAAGAGTGGCGCCTCCACTTTGTCCCCCAACTCACCCATGCACATCGGATTTAACGTAGCCGATAATAACCTGTGCTCCGTGGACGATGTGCTTGAGCTGCTCACTCAAATCAATGGTCTCAATCAATCGGAAATCGATTCGGATGGCAAGGAACTTGGTGTTTCCGTGTTGTCCGAAGATCTCTTTATCAGCAAGAAAATAACTAACAAACTGCAGCAGCAAATCCAGGATCCACTAGTGCTGTCCAGCAACGCGCTGCCCAATTGGTGCGAAAACCTAAACCAATCTTGCCCCTTCCTGTTCCCATTCGAGACCAGGCAGTTGTACTTCAACTGCACATCCTTTGGAGCCTCTCGCAGCATAGTATGTCTGCAATCGCAGAGAGATGTGACTGTGGAAAGGCAGAGGATTCCCATCATGAGTCCGCGCCGGGATGATCACGAATTCCGCATCGGTCGTCTTAAGCACGAACGCGTTAAGGTGCCTCGAAACGAGAATCTACTTCAGTGGGCAATGCAGGTTATGAAGACGCACTGCAACCGAAAGTCCGTGTTGGAGGTGGAGTTCTTGGACGAGGAGGGAACTGGTTTGGGTCCTACACTGGAGTTTTACGCCTTGGTGGCTGCCGAAATTCAACGCGCCGACCTGTGTATGTGGCTGTGTGACGACGATTTGGGCGAGGACATCGACAACTCATCGGAGAATACGCAAGGCAATTCGAAACCCGTAGGGTATTACGTAAATCGCAGAGAACACGGAATTTTCCCAGCACCTCTGCCGCAAAATACCGAAACATGTGAGAAAGTACTAAAATACTTCTGGTTTTTCGGTGTTTTTGTGGCAAAAGTATTGCAGGATATGCGTTTAGTGGACATACCCTTATCAACATCATTTCTTCAATTGCTTTGCCACAACAAGGTGCTGTCACGTAATCTCCAAAAAGTTATTTCGGATAGACGAAATGGCGATCTCTCTGTCGTGTCAGAAGAATCGGACATAGTAGAAACCTGCACTAAGCTATTGCGCACTGATTGCAATAAGACCAATGCATTTGGGGGAATTCTTTCCTTAGAAAACTTAAAAGAAATAGATCCAACTCGTTATCAATTCCTACAAGAAATGCAAAACCTCTTATTGCGAAAGCAGTCAATTGAGTTTGACGACACCATAGACGCCGAGAAGAAAGAAGAACTAATAAACGAGCTTAAGCTGCACACCCAAAACGGCTTAGAGGTATCCCTTGAAGACTTGGCCCTTACGTTCACGTATCTGCCAAGTTCCTCGGTCTATGGATACACCCAGGCCGAACTGCTGCCAAATGGGGCGTCAGTGAATGTCACCATCAACAACCTGGAAGCGTATTGTGAACTGCTTATGAACTTCATCCTGCAGGACGGAATCGCTCAACAAATGAAGGCTTTCAGTGATGGGTTCAACGAAGTGTTCCCCCTCAAAAAGTTGGCTGCCTTTACGCCCTCAGAGGCCCGAATGATGATTTGTGGCGAGCAGTTCCCCCATTGGAGCCGAGAAGACATTATTTCATATACTGAACCAAAACTTGGTTACAACAAAGACAGTCCTGGGTTCCAACGCTTTGTAAATGTTTTACTAAGCATGTCGGGCGACGAAAGGAAAGCCTTCCTTCAATTCACAACTGGTTGCAGTAGCCTGCCGCCGGGAGGACTTGCAAACTTACATCCCCGACTGACAGTTGTTCGAAAGGTAGATGCTGGCGTCGGAAGCTATCCATCCGTGAACACGTGCGTTCACTACTTAAAGCTTCCGGACTATCCAACTGAAGAGATCATGAAGGAGCGCTTGTTAACAGCAACTAAAGAAAAGGGGTTTCATTTAAATTAAACAATTTATTGTACTCGATATTCAAGTTAATAAAATTTGAACCTTTTGTTATTTAAAGCGTACTTGTTGTGTAACGTAATAAGCGATACTGTAAATATTTCAACTGTTCAAACCCAATCTTTATATATAAGTTTAGATTTATTGCTTACACCTAAAGTCTCGGCCTATTGTTTCAAATTTAATTTAACCATTAAAATGGTAGCCACTGCAAA
->XM_004521695.3 PREDICTED: Ceratitis capitata heat shock factor-binding protein 1 (LOC101452289), mRNA 
-ATTGTCATTTTCTGTTAAAATTTTGTTGTGTCTGGTTTCCAAAAGCGGAAAGTGTGCAAGATATATTATTTTTATACTTTTATAAAAAAGTTAACACAAACAATTTAGAACTAATTTTAATCGAAAATAAACCACAAACATGGCGGATATAAAGAATGATATTGATAGCGATTTGGATCAGAACTATTCGCTAAGTAGTAATGCGGATCCAAAAAATATGCAGGAATTGACAATTTATGTACAAAACCTGCTACAAAATGTTCAAGATAAATTCCAGACAATGTCGGACCAAATTATCACACGTATTGATGACATGGGCAACAGAATAGATGATTTGGAAAAAAGTATTGCAGATCTGATGAATCAAGCAGGTGTTGAAGGGCCAGAGAAGTAAAACGAAGCGGTTCGCGTAAAAACCTCATATTTTCCCATGAAGCATACTTATAAATATCGCTCATAAATGCAATAATCTTAACAAAATTAAGACATTTATTTAAATTCCTAAACAAAAATACATAATATGTAAGTGCACACATACACACAGCGACATGTACGTCATGTTAAACACAAAAGCGCACGAAAATGCAACCTTAAATGCTGATAAGAAGAATAATTGGCTCAAATGTGACACAAAATGTTTAATTAAGTTACAAACAATACTTATTTTAATTAAGTGAATTTTAAATATATAATGATTAAGGAATCATTTTTGAACATATTTTAAAGTTTTTTTTTTTTTTGTTATTTATATGTAAACAATAACCAAATGTGGGAGAAAAAGAAGTTCTTTGATATATGTGAATTTCTTATTAATTATTGTAATAATTATTAAATATTAATTATTTTTCTTAGTTTCCATACACTATGCATAATTCGGTATAATAAATGAATTAGTAATTTTAAATCAAAACATGAAAAA
->XR_004389653.1 PREDICTED: Rattus rattus uncharacterized LOC116914019 (LOC116914019), transcript variant X1, ncRNA 
-TTTTCTCTCCTGGGAGCGGGCCGAGGGGCGGGGGAGGGGCCACCGCTCCGCCTTCTTCTTTTCGCAATGTTGACGCAATCTATAAATAGTGGAACAAAAGGACCAACTTCCTCGGAGCTTTGCTGAAACTGCACAAAAAATCGAGCTGGGGGGTTCCCTGGTCCCCGATGTTGGGGCGGGGAGCTCGGCGCCGAAGGAGGGGGCGGCGCAGACCGGCCTAGGGGGACACCTGGCCGAGCGCAGTCGCCGCTCCGCTCGAGCCCTGCGCTCCAGTGCCCCCACTGGCTGGAGAGCTCGCCCAGACCCGGGGTCTTCCACCGTCTCTGACAGATTTTAACCTTTAGAAGAGAGCCAGTTGTGGAAAACAACCAGTTTTTTGATCGAATACCCACGTAATACATTGGAATATGATAGGAGATTAAGGTTTAACAATGATAAAATGAAGATATTACTAAAACAGCCCTCTAAGTAGCCCAACAATTATTATTTTTGCTAGAGATGAGAACCAGAACCATACAAGGTCCAAGACGAGCACTTTCTCTGTGCATATGGATGTCCTAGAAGTTGTGGCATAATGGTATTAATATGCTAGACGTACTGAATTGAA
->XR_003957782.3 PREDICTED: Taeniopygia guttata uncharacterized LOC115492501 (LOC115492501), ncRNA 
-CGTGTCCGCCCCCAGCCCCGTGTCCGCCCCCAGCCCCGTGTCCGCCATCCGTCTGTCCGTGCGCTCAGACTGAGCCCGCAGCGCCCGGGGGAAAGCAGCGGCCGCCTCCCCGCTCCTCCCGCGCGTCCGCCGGCGCCCGCTCGGACTGGCCACGCACGGCAACACGAGATGGTGGGAGGAGAAGCTCCTTACTTCAAGGAAACGAGGCCATGGTCAGAGGCAAATTCTCCAGGGGCTGCAGAGCCCTGTGAGCACAGGGTGACCCCGCACTGGGAGCAGCAGCTGGGGGTTTCTGCACATGGGGAAGGGAATTCCCAGAGCACTCGAGCCTCAACACGGACAAATATTCTGCAGTCTCCAGCAACAATTGGCTTTGGGATTTACGCTGTTGCAGCTCTTCTGGCTGTGAGGATGACCTGAAAATGTGAAGCAAGTGCATCAGCTCTTTCCAATGGCTGTGGCAGCACCAGGGTTTGGGTTTTTTGGTTGGCACAGGAAAATGAGCTGTGAGCAGCATCTGTGCCAGGGAGGAAAGTGCCCCTGGAGCTGGGGCTGAGAACCCGGGGTCGATGTGAGCACCTGTGGGTGGGAAGGAAGCTGGCAGAGCGCTGAGTTTGCTTTTCCTGCAGGCTCGCGCTCTGATGCGGCACAACGGGCCCCCGCAGCTGCAGGAGCCCGGGCGCCTGTCGGCTCTGCTGCGGGACTGCCTCGAGTGCAGCCTGGAGCCGGACGAGGAGCGGCGCTGCTCTGCCCAGGAGCTGCTGCAGCACCCATTTTTATCATCAGCCAAGCCTCTCTCCAGCCTGACCCCTCTGATCACCGCAGCAAAGCAACTGAGGGAGCAGCGGAGGAGATGAAGCACTTGAAAACAGCTGTTAGTTACAGTAGTTAGTGAGGACAACTAGTTAGTGATGGTAGTTGGCAGTGCTAGTTGGTTATGTTGGTTAGGACACCCTGTTTGTTACAGTTCTTATGACAGCCTGTTTGGCATGGCAGTTTTTTGAATAAAAACTCTGTTAAACCACAACTCCCTTGGCGTGTCCCTTCCTCCTCCCTCTGTGACTCAGCTGCCCGGAGCAATGTGAGGGGAGAGCGGGCCCAGCCTCGCCCAGAGCTGAGCCCCAGCAGAGCCCTGGCAGAGCCCAGAGCAGCCGGGGCATCTGCAGAGTCAGCCTGGGAGGAGGCGCTCGGAGCCTTCTCGGCTGCACCGACTCTTGGGTACAAACTGCGTGTGCTGGAAAATGCCCCCGGCTCGGCCAGAGGGCAGAAGGGGCCCGGGGAAGGCCCCAGTGCTCCCTGCAAGGGAAACACCTGCCCTGGGTTTGTTATAAAGGACTATGTAGTTGTGGCTTTTGCTGTGATGTCTTGGCTTCTGCAACTTATTCTTAATCGCAACGATTTAGATACAGTACAGCTTGTAATCACTTTTAACTGCTTTTGCTGTAGTATAATTTGTCAGCTTTTTGTGGTCAATGCCCTGGCCCCTGTGTAGCTCATATCCTCAGAACATCATTCATGGATGATAGTTTAGTTTGTGCACAGTGTGAAAAACATACATGATAGTTTTGGCTTTTACAAAATATTGAAGTGGATGCCATGTGTTGTGCATTAGAATGTTAACTTTTGCAGAAGTAGCTGTAGTTGTGAAATAATAACTAATGCTTTTCTTTTTGTAACTAACTGACAATAATAACTCAGAGATATTTGTGAAACAGCCAATGTTGATTTAAAGTACTTGTGGAAGTAGCTAAGACCGTCTGCATGGCCAGATAACGTTTAAGGAACGGGTGTGATGAGGACCCTGCCGCTGACCCTTCGACTGTCAGTAACTGTCGCCTGCTGATGTGGAAACCCAGGGCACCGGGAATATTTCTCTGTCTGCTCTGGGGTGTCCTGACCCCCAGGGGAGCACTGACTTTGACCCTCATTCATGGAGAAAACTTCCAAAGCTTCAAAGTAAGCTAGAAACCACAAAAGTGTGAAATAGATTGTAGAGATTGCAGAGAGTAGTGGAGTATGTCATATGGGTGAAAAATTTAGGTTTTAGAATTTTTAGTATGTTATAGATGGGTTCAAGATGGAGGATATAGGGTGTTGTCTTGAGTTCCCTTCTTCTTTCTTCTTCTTCTTCTCTTTCTTTTTGGGTTTATGTGGTATCCTGTAATTGGGTAGAATAATCTGCATTGTGGGTCTTTAGGGGTCAGTTACTGGGTTAGAAAGAAAACTAATTTAGGTGTCACTTCTTAATTGGGTAGCTTAGTTTTTGATTAGACTTACAAGGCCTTGTAACAAGAGATTGTTGGCCATTTTTGTGCTGTTTTCCTGCACGCAGAGTCTGGTGCAGACAGTGTGCTGAAGTTTTGATAAGAATAAACAGAAGCTGAAGACCGAAAAAGTCCAATGCAGCTCTGGTTCCTGACACAGAACTGCTCCAGGAGGGTCCCCCTGCCAGGGGAGCCGCCAGGGAGTTGCCCAACTTGGGGCCTGCAAACTCCCAGCTGAATCGGGGATCAGGGGGCTGTTGTGAGGAAGTGACACACAACCCTCAAAACAACAATCCATGATTCCTGCACGGACTCTAGAAAGGCGGGTTGGGGGTCAAACCAAAAGAGTTCCTGGAAGAAGTAAATGAGTTCAAAGAAATGTTTGAATGTGTATAATCTTTATGAATATGTTTTTGGACAATACAATGGAAAAAGTAGATAAGAAGAGTTGCTATGGCTAACCAGTGTGCCTCTGGCCATTGCCAAGCACCCAGCGCTGTTATTGATTTGTCTCTAATTATCCCTTCTTAAAGTTTTAAAAATCGTCTTGCTCATTTTGCCCCTCTTTGGCTTCTTCTCCAGGAGCAGAGGGAGCCGGGGCAGAGACCGCTGTTCCTTCTGCCATCTGCGGCAAGAGAGAAGCATGAGGGACAGGCCGTTACCTCTCATTTATAACCTCGTTCCTCCTCGGATCCACAAATACCACTTCCAAGGAGAAATCAGCAACTCTGTTAGCGATGGGATTCTAAGTGACTCTGACCAGATTAAAGTGGGTTAACTCAACAGAACTCTATTTGATGAACTCTATGAATTTGATAGTCCTCCCTGGCTGCTATCAGCAAGCAGCGGTGCCTCTGCACAATGCAGCTTTTAGCTCTTGAAAACTCTGAAATGGAAAAGTCAGAGATAGCCAGCACGGACTTTGTTATTGCTGCAGCAGACAAGGAAAACTCAAACTGGATCAGAATCCCATGCAGTGCACGAAAAGGGCAGGAAAGGTTGCGCAGACGCCTCTTTGCTTGCTGGAAAGAGAGAAAATGAGCGGGGCTTCTCCTCCTAGCAAACCAACAAACCACAAGTCGGAAGTGTCCCCTCCTCAGGTGGCTAAAGCACTTGGATGCAGTGAGGGCATGTCTGGCAGGGAAACAGCCCTGGTGGTGAGCACTGCCATGTATGGATCCATGGATCTGAAGGTCCCTCACAAGCCTCCCGTTGTCCAGGCTAAAGCTCCCTCAGCACCTCCTCCTTGGCCTTGCGCTCCACAGCCTTCCCCAGCTCCCGTGTCCTTCTCTGCACACGCTCCAGCCCCTCGAGGACTTTCTGCTTCAGAGGGGCCCACAAGTGGACACAGCACTCCCAGCCATGGCCGCAGCGCTGCCCAGCCCAGGGGGACGGTCACTGCCCTGCTCCTGCTGCCCCACTGCTGCTGACACAGGCCAGGGCATCCTTGGCCTTCTTGGCCACCTGGCCACACACTGGCCCACCTTCAGCTGCTCTTGACCGGCACCCCTGCGTCCTTTTGGCCCACGCAGCTCCCCCACCACAAAGTTGCCCGCTTGACTTCAAATAGAGCATCCCCAGTTCCAAGATGTCCTTCCTCTTCTCAGCAACACAAGACAGCAGTCAAGGACTTGCAGCTTCCCCCCCACCCTAGGCACTAATGCCATTCCCAAAGCTGCAGGCTGTGTGCAGCTGTCCCTGCAGGATGGCCCCAGGGCAGAGCCCAGCCGGGCTCCCCCTGCAGCCCCTGAAGCTTGGGGCAGGCAGTGGTCCCAGAGCTGAGGTTCACGGGGAGCACCCGCAGCTGTGCCTCGCACTCTGTTGCCGTGTCACCGTGCAGGCTGGCTTGTACGGGGTGAATGTACCAGCCCTGGTTTGACTGACAGGGGCCTGGCCCATCACAGCTCTCCCAAGGCTGCAGGCATTCCCCAGGCCAGAATCTGAAGGGGCACAGAGATCAGACCAGTGAAATCATCCAGACTGGGTTTTTCAAAGGCCCTTTAGAAGGAAGGGCTTGAGAATAAACGTGCTCTGTTTGCCACAGGAA
->KP156844.1 Uncultured bacterium clone garden_soil_51834 16S ribosomal RNA gene, partial sequence 
-AGTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGCAGCGCGGGGGCAACCCTGGCGGCGAGCGGCGGACGGGTGAGGAATACATCGGAATCTACCCAGTCGTGGGGGATAACGTAGGGAAACTTACGCTAATACCGCATACGACCTGAGGGTGAAAGCAGGGGACCGCAAGGCCTTGCGCGATTGGATGAGCCGATGTCCGATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCGACGATCGGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGCCTTTGGGTTGTAAAGCACTTTTGTTCGGGAAGAAATCTTCCGACCTAATACGTCGGGAGGATGACGGTACCGAAAGAATAAGCACCGGCTAACTTCGTGCCAGCAGCCGAC
->XM_050191817.1 PREDICTED: Dermacentor andersoni protein FAM136A-like (LOC126544480), mRNA 
-AAGCTGCCGGGCGCTGGCGGCTGCATGGGCGGCTGGCGCAAACACGAGGCGATTGTTGGTCTGCTTGGTTTCCTTCCTGTAAAAGGAGGTATTATACTAGTACTGGGAATACTACTGTAAGTGTTGAGCCGAACAACGCGATACAATGGCCGAAGGAGCTGCTCTGCGTGTACAAACTGCCGTAGACAACATGGTCAAGGAACTCGACAACTCTTATCTCCGCAAAATATTGGGCAATGTGCACAGGTGTGCAGTTAAGTGTTGTGACAATTCCAGCTTGTCAATGGATGGTGCTCGCACGTGCATCATGAACTGCTCTGAACCTCTTAACAAAGCCCAGAGTAAAGTCGAAGGTGAACTTGGAAACTTTCAGGAACGCATACGAATGTGTGTTATGCAGTGCGAGAATGACGTGCGGGACCAGATGAGCTCAACGTTAACAGAAGCAGAAGCCTCCAAGTTGAAAGGCCAATATGAGTCGTGTGTTGTGACGTGTGCGGACAAACATATTGCTCTTTTGCCACAGATGCAGCGAAGAATGAAAGAGTTGTTAAGTCAACTTTAGAGGCCAGTGTACACTGTTGTGTACATAGTTCGTACCGATCCTTGTATTTCTAGGATGAGTTAACATGCCATGTAGCTCCGCTCGTTGCCTTCTACCATAAATGTTTGATGAAAGGAC
->XM_014783154.1 PREDICTED: Ceratotherium simum simum ATPase, class VI, type 11B (LOC101400597), transcript variant X4, mRNA 
-GTGGGCGACATTGTTCGAGTAGCCAAAGATGAAATTTTCCCTGCAGATTTGGTGCTTCTGTCCTCAGATCGACTTGATGGTTCTTGTCACGTTACAACTGCTAGTTTGGATGGAGAAACTAACCTGAAGACACATGTGGCCGTTCCAGAAACAGCAGTATTACAAACAGTTGCCAGTTTGGACACTCTTGAAGCTGTGATAGAATGTCACCAACCAGAAGCAGATTTGTACAGATTCACAGGTCAGATGATGATAACTCAACAATTGGAAGAAATTTTAAGTTATTCCTTCTCGTTTTATATCTCCTTAATGGAGAGAAATTCAAACACCAAGAAGACCTGTGCTCCAAGAAGTGTACAATACCTCTGGGGCCAGAGAGTCTCTTGCTTCGTGGAGCCAGATTAAAAAATACAAAAGAAATTTTTGGTGTTGCTGTATACACTGGAATGGAAACTAAGATGGCATTAAATTATAAGAGCAAGTCACAGAAACGATCTGCGGTAGAAAAGTCAATGAACACATTTTTGATCATTTACCTCATAATCCTTATTGCTGAAGCCATCATCAGTACTATCTTGAAATATTCATGGCAAGCTGAAGAAAAATGGGATGAACCTTGGTATAACCAAAAAACAGAACATCAAAGAAATAGTAGTAAGATTCTGAGATTTATTTCAGACTTCCTTGCTTTTTTGGTACTCTACAATTTCATCATTCCAATTTCATTATATGTGACAGTAGAAATGCAGAAATTTCTTGGATCATTTTTTATTGGCTGGGATCTTGATCTCTATCATGAAGAATCAGATCAGAAAGCACAAGTCAATACTTCTGATCTGAATGAAGAGCTTGGACAGGTGGAGTATGTGTTTACAGATAAAACTGGTACACTGACGGAAAATGAGATGCAGTTTCGGGAATGTTCAATTAATGGCATAAAGTACCAAGAAAGCAATGGTAGACTTGTATCTGAAGGACCAACACCAGACTCTTCAGAAGGACCCTTTTATCGTAATAGTTTATCCCATCTTAACAACTTATCCCATCTTACAACCAGTTCCTCTTTTGGAACCAGTCTTGAAAATGAAATTGAACTAATTAAAAAACATGATCTCTTCTTTAAAGCAGTCAGTCTCTGTCACACTGTACAGATTAGCAATGTTCAGACTGATGGCATTGGTGATGGTCCCTGGCAATCCAGCCTTGCACCCTCCCAGTTAGAGTACTACGCATCTTCACCAGATGAAAAGGCTCTAGTGGAAGCTGCTGCAAGAATTGGCATCGTGTTTATTGGCAATTCTGAAGACACTATGGAAGTTAAAACACTTGGAAAACTGGAACGGTACAAACTGCTTCATGTTCTGGAATTTGATTCAGATCGTAGGAGAATGAGTGTTATTGTTCAGGCACCTTCAGGTGAGAAGTTTTTATTTGCTAAAGGAGCTGAATCATCAGTTCTCCCTAAATGTATAGGTGGGGAAATAGAAACAACCAGAATTCACGTAGATGAATTTGCTTTGAAAGGGCTAAGAACTCTATGTATAGCCTATAGACAATTGACATCTAAAGAGTATGAGGACATAGACAGACGCCTCTTTGAAGCCAGGACTGCCTTGCAGCAACGGGAAGAGAAATTGGCAGATGTCTTCCAGTTCATAGAGAAAGATCTGGTATTACTTGGAGCTACAGCAGTAGAAGACAGACTACAAGATAAAGTTCCAGAAACTATCGAAGCATTGAGAATGGCTGGTATCAAAGTATGGGTACTTACTGGCGATAAACACGAAACAGCTGTTAGTGTGAGTTTATCATGTGGACATTTTCACAGAACCATGAACATTCTTGAACTTACAAACCAGAAATCAGACAGCGAATGTGCTGAACAATTGAGGCAGCTTGCCAGAAGAATTGAAGAGGATCATGTGATTCAGCATGGGCTGGTGGTGGATGGAACCAGCCTGTCTCTTGCACTCAGGGAGCATGAAAAACTATTTATGGATGTTTGCAGAAATTGTTCAGCTGTATTGTGCTGTCGTATGGCACCGCTGCAGAAAGCCAAAGTAATAAGACTGATAAAAATCTCACCTGAGAAACCTATAACATTGGCTGTTGGTGATGGTGCTAATGATGTAAGCATGATACAAGAAGCACATGTTGGCATAGGAATCATGGGTAAAGAAGGAAGACAAGCTGCAAGAAACAGTGACTATGCAATAGCTAGATTTAAATTCCTCTCAAAATTGCTTTTTGTTCATGGTCATTTTTATTATATTAGAATAGCTACCCTTGTACAGTATTTTTTTTATAAGAATGTGTGCTTTATCACACCCCAATTTTTATATCAGTTCTACTGTTTGTTTTCTCAACAAACACTGTATGACAGCGTGTACCTGACTTTATACAATATTTGTTTTACTTCCCTACCTATTCTGGTATATAGTCTATTGGAACAGCATATTGACCCTCACATATTACAGAACAAGCCCACCCTTTATCGAGACATTAGTAAAAACCGTCAACTAAGCATTAAAACATTTCTTTATTGGACCATCCTGGGTTTCAGTCATGCCTTTATTTTCTTTTTTGGATCCTGTTTTCTGATGGGGAAAGATATATCTCTGCTTGGAAATGGCCAGATGTTTGGAAACTGGACATTTGGCACCTTGGTCTTCACAGTCATGGTTATTACAGTCACAGTAAAGATGGCTTTGGAAACTCATTTTTGGACTTGGATCAACCATTTTGTTACCTGGGGATCTATTATATTCTATTTTGTATTTTCTTTCTTTTATGGGGGGATTCTCTGGCCATTTTTGGGCTCCCAGAATATGTACTTTGTATTTATCCAGCTCCTATCAAGTGGTTCTGCTTGGTTTGCCATAATCCTCATGGTTGTGACATGTCTGTTTCTTGATATTGTGAAGAAAGTATTTGACCGACAACTCCATCCTACAAATACTGAAAAGGCCCAGCTTATTAAAACAAATTCAAGTGTCAAGTGCTTGGACTCCATGTGCTGTTTCTCAGAAGGAGAAGCAACGTGCGCATCTGTTGGAAGAATGCTGGAACGAGTAATAGGAAGATGTAGTCCAACCCATGTCAGCAGATTATGGAGTGCATCGGATCCTTTCTATACCAACGACAGGAGCATCTTGACTCTCTCCACAATGGAATCATCCACTTGTTAAAGTGGCAGTAGTACTTTGTGGGAGCCATTTCAACTCCTTTCCTAAAATTCAGTGTGATCATCCTGGTAATGGCCATACTGGCTCTTCAGATTTACTTTCTGAAATCTCTGGAGTAGTTCATACCCACTCAGAGTTATAATGGCAAACAAACAAAAAGCATTAACGGGAACCCCTCTCAACTCCCTTATGTTAAACTTTGTGAATAAAGAGACATTTTGCATCT
->XM_027489590.1 PREDICTED: Abrus precatorius vicilin-like seed storage protein At2g28490 (LOC113857560), mRNA 
-ATGGGAAACATAGCTACCCTTTTGCTCTTGCTCTTTGTTTTTTGCCATGGAGTGGCCATAGCAGAAAGTCCTTCAAGTTCATCAACCAAATTGTTCTTGATGCAAAACTCCAAGAGAGTGGTTAAGACTGATGCAGGGGAAATGCGAGTTATGAAAAGCTATGGTGGTAGGATTTTGGATAGGCACATGCAAATTGGTTTCATCTCTATGGAACCAATGTCCTTGTTCATTCCTCAGTACCTTGACTCCAATTTGATCATCTTCATCCGAAGAGGGGAAGCAAAATTGGGATTCATATATGATGATAAACTAGCGGAAAGGAGATTGAAGACAGGAGATGTGTATATAATTCCAGCAGGTTCAGCATTCTATTTGGTGAATTTAGGGGCGGGTCAGAGACTTCACATCATTTGCAGCATTAACCCCTCTTCAAACTTAGGAGTAGATACCTTTCAGTCCTTCTATATTGGCGGAGGAGCCAATGCACCCTCAGTGCTTTATGGATTCGAGTCTGTGATCCTTGAAGCTGCATTTAATGAATCAAGAACCGTGCTAAGGAAAATCTTCACCAAGGAACTAGATGGGCCAATTGTGTACGTGACTGATACACATGCACCTAGATTATGGACTAAATTCCTTCAACTGAAAAAAGAAGACAAAGTGCAACACCTGAAGAAAATTGTGCAAGACCAAGAAGAAGAAGAAGAGGAGGAAGAGAAGGAAACAAGTTGGTCATGGAGGAAGTTCATGGAAACTATACTTGGTAATGTGAATGAGAAGATAGAGAACAAACACACTGCTGGTTCTCCTGACTCTTACAACCTCCATGACAAAAAACCTGATTTCAGAAATGCTTATGGTTGGAGCAAGACACTTGATGGAGCCGAGTATCCTCCACTCAGAAAAGCTGACATTGGCATTTTTCACGTCAACCTCACCGCGGGATCCATGATGGCACCCCATTTGAATCCAAGAGCAACAGAGTATGGCATAGTGCTGAGGGGTTATGGTAGAATTCAAATACTATTTCCAAATGGAAGCAACGCGATGAACACCGAAATCAAAGTAGGGGACGTGTTTGTTGTACCAAGATACTTCCCCTTCTGCCAAATAGCATCAAGGAATGGACCCTTAGAGTTCTTTGGGTTCTCAACCTCTGCCAGGAAGAACAAGCCACAGTTTCTAGCTGGAGCTGTGTCCCTTGTTACGACCATGATGGGGCCTGAGCTCGCAGCTGCTTTCGGGGTGAGCGAGGACACGATGCGGCGCACTGTCGACGCTCAACACGAGGCTGTAATACTGCCATCAACATGGGCTGCACCACCGGAAGATCCAGGGAAAATGGAAGAAGAGAAGGTACACATGCAGCCAAAGGCTATTAGAAGCTTTGCTAAGGATATAGTTATGGATGTTTTTTAA
->XM_036746150.1 PREDICTED: Trichosurus vulpecula N-6 adenine-specific DNA methyltransferase 1 (N6AMT1), mRNA 
-ATGGCCCAGGGGGGCTGGGCCCCGCCACGTTTTGCCACTCCATTGCACCGACACGTGGGACGGGGTGCTTTCCGGGAGGTATACGAACCTGCCGAAGACACGTTCTTGTTGCTGGATGCACTGGAGGCAGGGGCCGCGGAGCTCGCGGGAGTAGAGATATGCCTTGAAATAGGATCAGGATCTGGCATCGTATCTGCATTCCTGGCTTCAGTTATTGGCCCTCGGGCTTTGTATATGTGTACTGATATCAACCCCAAAGCAGCCGACTGTACCTTGGAGACAGCACTGTGTAACAAAGTTGACATTCAGCCAGTAATTACAGATTTGGCCGAGGGCTTGCTACCGAGGTTACTCAGCAAAGTCGATCTTCTGATATTTAACCCACCCTATGTAGTAACACCTTCTGAAGAGGTAGGAAGTCATGGAATAGAGGCAGCTTGGGCTGGTGGCAGAAATGGCCGAGAAGTCATGGACAGATTCTTCCCTTTGGTTGCAGATCTACTATCACCAGGAGGATTTTTCTATTTAGTTACCATTAAAGAAAACAATCCAGATGAAATTATGGAAACAATGAAGAAATATGGTTTACAAGGCAAAATTGTACTTTCCAGACAAGCAGGACAAGAAATTCTTTCAGTCCTAAAATTCACCAAGTTCTAATATACGTAATGTGAAATGTTCAGTCACTAGTATACTTTTAAAGCCAAAGCTATTCCAAGAGCCAGGTAAAAATGTGAATTGTAATTTTTTAAGTGTTGAGAACAATTTAGGCAAACTAAGTTAAAAATCAGTGCTTTTCAAAATGTAATCTGTGGCTTTTCAAGAAAAGTCTCTCTGGGCTTTAAGCTAAGTCAGAGTGGTTTATTGAACAGTGTTCATAAACATTAATAAAAATGTTATGTCATAGCAAATGTCACTGTCACTAAGTAATGAGAGAAGGGTTTGACCTATATGTTTATTGTTCAGTCATGTTCAGCTCTTTATGTCCCCATGGACCATAGCACGCCAGACCCTTCTATCCATTATCTCCTGAAGTCTGTCCATGCTCTTTCTTTTTTTTGCTTCCATTACAATATCTATCCATCTCATCCTCTGCTATCCCCTTTACCTTTTGCTTTCAGTCTTTCTCAATATCAGCCTTTCTTCCAATGAGTCCTGTCTTCTCATTATGTAGCCAAGGTATTTCAGCTTCAGCTTCAGTATTTGACCTTCCAATGAGTAGTCTGAATTAATTTCTTTAAGTACTGACTGATTTGATCTCCTTGCTGTCCAAGGGACTCTCAGAAGTCTTCTCCAGCAGAATTTGAAAGTGTCGATTCTGCAGTGCTTAGCTTTACATATAGTACACTCTCACAGCCATATATTGCTAGTGGAAAACCTGTAGCTTTGATTATATGGACCTCTGTCAGCAAGGTCATGTTTCTTTTTTTTAGTATGCCATCCATGCTTGCCATAGCTTTCCTTCCCAGGAGCAAATCTCTTTTAATTTAATAGCTGCAATGATCTTTGAACCCAAGAATATAATCTGACATTTTCCATTTCTTCTCCTCCTATTTGCCAGGAGGTGATGAGACCAATTGCCAAGATCTTCATAGTTTGGGTTTGGTTTTTTGATGTTTTTAAGCTTCAAGCCAGTTTTTACATTCTCTTCTGTTTTCACCCTCATCAAGAGGCCTCCTTATTCCTCTTCACTTTCTGCCATCAGAGTGATATCATCTGCATGTCGAGATTGTTGGTATGTCTCCCAGAAACTTTACTCCTGGCTTTTGATTCATCCAGCCTGGCATTTCATATGCTATTCTCTGCATACGTTAAATAAATAAGATGACAATATATAGCTTTGTCATACTCATTTTCCTTTCTTAAGCCAATCAGTTGTTCCATGTTCAGTTCTAACTGTTGCTTCTTGGCCCACATTCAAGTTCCTCAGGAAACAAGGAAGGTGATCTGATGCTTCCGTCTCTTTGAAGACTTGTCCCATTTTGTTGTGATCCACACAGTGACAGACTTTAGTGTAGTCGGTGAAGCAGAAATAGATGCTTTTCTGGAACTCCCTTGCTTTCTCCATAATACAGCAAGTGTTGGTAATTTGGTCCCTGGTTCCCTGCCTCTCTGAAAACCAGCCTGCTCTTTCAGTAATTGTCAGTTTACATATTGTTGAAGCCCAGCTTGAAGAATCTTAACTTGTAACATTGCTGAAGGGTGAAATGAGCACAGTTGTTCAGTTGCTGGAACATTCTTTGATCTCGTTCTTCAGGATTTGTATGTGAACTGATCTTTTCCAATCCAGTGGCCACTATTGAGTTTTCCAAATTTGCTGCCATATTGAGTACAGCACTTTTAACATCATAATTAGGATTTTAAATAGCTCAGATAGAATTTCCTCCCCTCCACGAGCCTTCTTGTTAGTAATGCTTCCTAAGGCCCACTTGACTTTATTCTCCAGGATGTGTGACTCTAGATCAGCAACCACACCATTGTAGTTATTGGTGATATTAAGATCTTTCATATATAGTTCTTCTGAATGTTCTTGCCAGATCTTCTCAAGTCCCTACCATTTTTTGTTTTTTATCATGCCTATTTTTGAAGGAAACATTCCTTTGATATCTCTAATTTTCTTGAAGAGATCTCTTTGTCATTCTAGTGTATTCTTCTGTTTCTTTACATTGCTCATTTAAAAAAAAAACCTTTCAGGGCAGCTAGGTGGCGCAGTGAGCAGAGCACCAGCCCTGGAATCAGGAGGACCTGAATTCAAATGCAGCCTCAGACACTTGACACATGTACTAGGTGTGTGACCTTAGGCAAGTCATTTAACCCCAATTGCCCTGCCCCCCCCAAAACACCTTTCTCCCTGTTATCCTCTGGAATAATGCATTCAGTTGGATATATCTTTACCTTTCTCCTTTATACCTTTCACTTTCCCTCTTTCCTCAGCTATTTGTAAAGTCTCATCAGACATTTTGCTTTCTTGTTCTTTTTCTTTGGATTATTTTTTATTGCTCCTTCCTGTACAGTATTGCAAACCTCTATCCATAGTTCTTCAGGTACTCTATTCACCAGATCTAATCCTTTAAATTTATTCATCACTTGTATTTCATATTCATAAGGGATGTTATTTAGGGCATATACCTATACAGTCTGATGGTTTTCCCTACTTTCTTTAATTTACATGGGAATTTTTCAGTAAGAAGCTCATGATCTGAGCCACAGTCAGCTCTGGCTCATTTTAACTAACTGGATGGGACTTCTCCACCTTTGGCTGCAAAAAGTATGTAACCAGTCTGATTTTGATATTGACCATCTTATCTTGTGATGTCCATGTGCAGAATCACTTTGTGAGTTGTTGGGAGTTTTTGCTATGACCAGTGAGTTATTTTGACAACTCTATTAGTCTCTACCTTGCTTCATTTTGTACTCCAAGGCCAAACTTACCTGTTATACCAGTTATCTTTTGATTTCCTGCTTTAGCATTCCAGTCCCCTGTGATGAATGTGATATGGTTTTTTGGTGTTACTTCTAGATGTTGTAGTTCTTCATAGAACTGATAACTTTGGCCTCTTCAACATTAGTGGTTGGAGCATAGACTTCTATTGCTGTTCAGTCACACATACAAATGTACTTTCATTAGAAAAATAATTTTTAAATCTCAGCAGAAAATATTTTCTCTCTCCTGAAAGAAATCACTTCCTTTTAGAATTTTATTGTGGGTTTTCCTACATGGTTCTTTTAAGGGATGAGTGATAGGGTAGGGATAGGGATAGGGTCTAGACCTTTGATTTCAATGTAATAGAGAACTCCAGAATGAGGAAATTCTGTGAATGCAGGGTAGCACCATCTTCTTAAGTTTAGAAATCTTAAGAGAGTTGCCTAGAGCATTGAAAGGTTAAGTGATTTTTCCAGGATCACAGAGCCAGTATATCCAGCTGGATTTGAATCCAGTTCACTGTACTACACTGGCTCTCATTTGATCAATATGAATTATAAAAAAATGTTTTGTGAATGCCAAATCATGATTTCAGAGGACCAAAAAGAAAGCACATTACCACCCATATCCTGCCAGAAAGGTGATGGACTTAAAAGGGGTTTTTTGTTGTTGGTTTTTTATTATTTTTATCATTAGCAATTTGTTGGGGACTGGGGGGTGGTAGCTAATTGGAAAAAATACTAAAATTTAGTTTTAAAAAATATTTTGCAACAAGCATGTATACTTTCTAAAATGGGCAGCATAAGATTGATGGCATTTCATGCCACCGATATGACAAAAGGGGACCTAATATCCACATATCGTATTGAAAGTAATTTGTTCCCACACCAAGAACATTTGGGTTTTAGTTCTTTGGACTTTGGTTAATAGACTTTTAGTATCATGAGATTTAAATGTTCTTGTATTTATTGTTGAAACTTTTGGGTTATTTGTATAAACCCTTTAACACAATTATACAAATGTTATTCTTGACCAGAAAAATACTTTTTGTCTTTACAGAATGAGAGGATACACTATCAAATGTTGGTCTAAAAATAAAACTGCTATATTGCTATTAAAGCCTTGAAAAGTAGGTATTCCATTCATTACATAAATGAACTGTGAAAAGTGAATCCCAGAAAGTTATTTTAAAAATTCCTTTGACTTCTGAGGTCAAACACAAAATTAGTAAAGATTCTGGGAGAATTCTTCCCCTAAATATAATTTTCAAACTACTATAAAGTTGTGGTTGTAAAAGTGCTATATGTTATATATGGTTTATTACCAGTGTATGACATTTTTGATCTTGAACTTAAGTAACTATGACAAGGTGAGACTGATTTATGCCATTGTACAAAGTAGTACTTCACTAACACCTGAAGACTGCTTATGCACTTTGATTTTTTTTTTAAGTTTTAGCTAATTTATGCTGCTATAAGTTGACAAAATTATTAGGCTCTTAAATTTTATTTTTCCTACCTTGATCCCAGTTTTTGGTAGGTAAGAGAAAACTTGACAATAAAATTGGAGGTCACATTGTA
->XM_015642795.3 PREDICTED: Parus major Rho GTPase activating protein 17 (ARHGAP17), transcript variant X8, mRNA 
-CGGGGGCGGCCGGGGCACAGCGGCGGGGCCCGGGCAGGCCGGGGCAGCGGCCGCCGCCATGAAGAAGCAGTTCAACCGCATGAAGCAGCTGGCCAACCAGACCGTGGGCAGGGCTGAGAGAACAGAGGTACTCAGTGAAGACCTGTTGCAGATCGAGAGGCGCCTGGACACGGTGAGGTCCGTGTGCCACCTGGCCCAGAAGAGACTGATCTCCTGTCTGCAGGGCCAGCATGGCACAGACCCTGACAAGAGACACAAAAAACTTCCTCTAACAGCTCTGGCTCAAAACATGCAGGAAGGATCCATCCAGCTGAGTGATGAAACTCTGCTGGGGAAAATGCTGGATACCTGTGGGGATGCAGAGAGTAAACTGGCAATGGAGCTCTCCCAGCATGAAGTACAGATTGAGAGAGAAGTTATAGACCCACTGTGCCTGCTGACAGAGACAGAGATCCCAAATATCCAGAAGCAGAGGAAGCAGCTTGCAAAGCTAGTGCTGGACTGGGATTCTGCAAGGGGAAGATACAACCAAGCCCACAAGACTTCAGGAACAAATTTCCAAGTGCACCCTTCAAAAATAGAATCTCTTAAGGAGGAGATGGATGAAGCTGGAAATAAAGTAGAGCAGTGCAAGGATCAGCTGGCTGCAGACATGTACAGCTTTGTGTCCAAGGAGGGGGAGTACGCCCGCTGCTTTGTCACGTTATTAGAAGCACAAGCAGATTACCATAGAAAAGCATTAGCAGTCATAGAAAAGGTCCTACCCGAAATTCAAGCCCATCAAGACAAATGGACTGAAAAACCAGCTTTTGGAACTGCCCTGGAAGAGCATCTGAAGCGCAGCGGGCGGGAAATCGCAGTTCCTATCGAAGCCTGTGTCATGATGCTCCTGGAAACGGGGATGAGAGAGGAGGGCTTGTTCAGAATTGCTGCTGGAGCCTCCAAGTTAAAAAAGCTGAAAGCTGCCCTGGACTGTTCCACCTCCCAGCTGGATGAGTTTTACTCAGATCCCCACGCTGTCGCAGGTGCCTTGAAATCCTATTTGCGGGAGCTGCCAGAGCCTCTCATGACCTACAGCCTGTATGAGGAGTGGACACAAGCTGCAAATATTCAGGACCAGGATAAGAAGCTGCAAGAGTTATGGAGGATTTGTAACAGATTACCTGAGCATTACCGTGTTAACTTCAGGTATTTAATCAAATTTTTAGCCAAGCTTGCCCAGAACAGTGACGTTAACAAAATGACACCGAGCAACATCGCCATAGTCTTGGGCCCCAACCTGTTGTGGGCAAAGAATGAAGGATCCCTGGCTGAAATGGCAGCAGCCACTTCAGTGCACGTGGTAGCAGTTATTGAGCCCATTATTCAGCATGCAGACTGGTTCTTCCCTGGAGATGAAGATTTCAACGTGTCTGGGGCGTTTGTGGCAGTTCCTGCTGTTAATTCCAATCACTTGTCACACACTGGGAATGACTATGAATGTGGGACCCTGGAGAGGAAGAGGCCTCTGAGCATGACTGTGATGGAAGGGGATTTGCTGAAGAAGGAGAGTACCTCAAAATCCAAGGACAGCACATCTTCAGCCACTCCTCCACCGGTGAGGAACGGCAGCCAGGCAGGCCCTGCCCCGGGCCAGGCAGTGCCCAGCACGTCCCAGCTCTCTGTCACCCAGCCCCAGAACGCTGCTGGTCCCAGTCCCCACGCCCTGAGGAGAGCTGTCAAGAAGCCAGCACCAGCCCCCCCCAAACCAGCCAACCCCCCTCCGGGGCAGCCAGGAAGCCAAAGCTCTTCCCCAGCTGCTCAGCCACCTTCTGTCTCTCCCAAACCACCAGCCAGAAGCTCCTCTCCTCCTGCTCAACACGCAAACCAAGGAGCAGCCCAGACCTCCTCCCCTTGCCAGGTTTCTGCACCTCGGAGATACTCCAGCAGCGTGTCCCCAATCCAAGCCCCCAGCCACCCACCCCCGCAGCCCCCAGCACAGGCAACTCCTCCCCTGCAGCCCAAGGGCAGCAGCCAGGGCTCTGTGGAGCAGGGGGCAGAGCAGAGCCCCTCGCTGTCCCAGCCGCAGACCCCCACTCCCCCGGGCAGCCCCCCGGCCGTGCCCCCCGAGCCCTGCCAGGCTCCCTGCGGACCTCAGAGCGGCTCCCTGCCCCGGCCACGGCCCGTGCCCAAGCCCAGGAACAGACCCAGTGTCCCCCCTCCTCCTCACCCTCCCTCGCAGCTGCCTGCAGACGGGACGGCTGCAAACCCTGCTCAAACGGCGTCCAAAATAGTCACAGACTCTAATTCCAGTATTCCAGAGCCACCTCCAAACCCTCCTCCAGAGCTTCCTGCAGAGCCGGCGGGCAGAGAGCTGCACAACCACGTCCTGCTGGCCATCGACAATGACACGGAGAGCACGGCGCTGTGAGCGCTCCCTCCCCGCGCTCCTCTCCTCAGACCTCACAGGGAAAAGCTTCTTCTGGCAACGTGGCACAACGGTGTGGAGCTGGGGCTGCAGCCTGCTGGGCACAGGGATCTCCAGGATGGCCGAGGTTGGAGAAGACCTCGCAGAAAATCCAGCCCAGCCTTTGGCCCAGCTCCGGTTTCGCCCTCAGAAGAAGTTTAATGATCTGGGTCTGGACAACGGTTTTCAAACTCTTGGATGGAAGGAATGAATTCCTGCAGGAACTCGCCTAGGAAGCGTGGTCAGTGCTGATACAGGTGGTATTAGCAGAGATTCCAGAAGAATAAGAAGCAGAACATTAGTTATTTAAAGTGCATGTCTGTATTAGGGGAATAATCCTTCCCATGGCACGGTTAGAGGTTATTTGTAGTTCTTAGCCCGTACCAGGAGCTGCCTCCCAAGGGCCATTCCCTCTCGGATTTGCTGCAGATTCCCCCCAAGCCATGAAGCAAACCCTGCCCCAGTGCTGGTGGTGACTGCTGGTTCTCAGTCACCCTGTGGAACTGTGGATGCATCCCGTGCCTTGAAGGACTGTCGTGCTGTAGGAGGATCTTCCTGTCTCTTTAATCATTTCATTGCTACTTAGGATCAGTACTTACCCTGATTTCATAGTTATTTGTATTAACCTGCTTTGTTCATGTGCAACTGGCAACTGTTTCACGAGGAAACCGTGGAAATGGGGTTTGTGCTTTTGTTGAAAACGGTTGAATTTTGAAAGAACTTTGAAACAGCTGTTAGGATTCAGCAGTTGAGTGAACATTTATAAAATTAAAGATTGGTTTTTGTCAACTTAA
->XM_039807938.1 PREDICTED: Perca fluviatilis tubulin, gamma complex associated protein 6 (tubgcp6), mRNA 
-TTTTGTCGAAGCCCCGCGGTAGATTGTGAATCAAGCGACTAGAGAGCAATTAGCTAGCTAGCGACAACATCTAATATGCTGGAACAAGAAACCTTTCAATAATAAAAATACATTTTGAAGCAGTGTAGGGGACCCATCTACTGGGTTTCACATGCTTGGTACACACAAGCTAGTTAAGCAGGACAGCTAACGTTAGCGTTAGCTGGCTAGGTGATCCGTGGGGGCTTGCTAATAACAAACGTTAGCATGCACTGGAAGGAACCTTTTGGGGTGGATGCAAGATTGAAACTGTCTGAATCAACGAAAAATACACCATCTCGAAGGCTGAGGTAACAGTGCCACCATGTACTCGAGCCTAAACAACCCAATGAAGTCCAGCTGCAACAGCAGCAGCATCACTGAGCTGCTGGGTGCCCTGTGTGACTGCAGCCTGTCTGGGGTGTCATGGAAACGCCGTGCCCTGGGTGGAGTTTCAAGAGAAGGTTTCCGCAGAGCTCTCAAAAAACGTGCCTACGGTGCCCTGCTGTCTAAGCTATTTCAAGATGACACCAAAGGGTCTGCCTCAGGACTGAGTGCCACAGCCAATACACCGCCCAAAAACAAAGTTTTGATGATATGTTTTGACTTGCGGGTGGCAGGGTGCCGAGAGGAAGCAGAGCGTTTGGAGGAGCAGCTGGGGATGCTGTTGGATGGAGCATCCTCTGGCCTAAAGGAAGTAGACGCTGTCCTTGAGCTCTTGGTACATCTAGCTGGTTCGGCACCTCCACCCCCTACCTCTTTCATTAGGGACTATATGAGACGAGAGAGGCCTGTACTGCGGAGGCCTCAACCCTGGGGCTACCAGAGCGAGGAGCTTCAGAGGCTAGAGGCCCGGGCATGGAGTCTAGTGTGTGGGGAGGAATGGGGGACTTTAGAGAGTTTGTGTGGAACTCAGAAGTTGATGGATGCTCCTCCAGGCACAGGACTGCTGGCTCTGAGAACTAAATTAGAAGTGGAAGAAAGATTTGAGAGGGAGACCAGGATGACACTGTTTGGAGCACTGCAGCACACTCGCACCTCAGACATAGACATAAGACTGGACCTGCCTCCTGTTCCCAGTAATATTGATGTAACTGGGCTGGCTATACGGGTCCCCCCATGTATAGATCAGTCTGAGGATGAAGGTTTCCAGTCAGCTTCCAACATGACCCCAGACTCTCAGTCAGAGACCAGCCCCATACCAGACGTTGATATATGGGAGGCTCTTCGCACATTTGAGCCTGGAAGACGTCGCTGCTGGGAGTCTGTTGGCTGCCCACCAGGGAAAAGCGAGTCACTCTATCTAACAGAGGGAGGCAGGGAGGCCTTTGACCAGCTCTATCGTCTGTGGGAGGGGGAGATGAGGGTGGTCAGCACTGCTACACCTTCTCCTCTCCTCCCGCTGCCCCTGGACTCTCAGGCACTACTGGTATTTGACCTCCTCAACGTCTTGATCGGGGTGGCATCCACGACCTTCCCTCTCAACCAGAGTGTTCAGTTTGATGTCAGACCTGGTGTGTGCGTGTCCGGAGCCTCTCCAGAGAGTGTGTCTCGTCTCTTGGGGGAGCTGGCCCAGTACGGCACCCACTACTTGAGGCTTAGTCGCTTTTCTCTGCCGAGTGCTGGAAAAAAAGGCCTAGTCTTTCAGGCTTTTACAGGTGGTCTGCGGAAGTATCTGCATTACTACAGGGCTTGCGTTCTCAGCACTCCACCCACCCTCAGCCTGTTGACTATTGGCTTCCTCTTCCGCAAAGTGGGCCGCCAACTAAGGTACCTGTCAGAACTGTGCTGCGTAGATGGGCCTTTGGGTGCAGGCCAGGCTACCTTCCCTGTGGGTGTTAAACTGCTGTCCTACCTGTACAATGAAGCACAGAATAACTGCAGCAACGAGAACTGCGCGGTCCTCCTGTCGCTGCTGAAGAGCAGCTGTGAACCTTATACACGGTTTGTGTCTGACTGGGTGTATAGCGGCGTGTTTCGGGATGTTTATGGAGAATTCATGATCCAGGTTAATGAGGACTATCTCGTCTTCAGAGACAAACACTTCTGGGTCCAAGGCTACACTCTGATCTCAAAGGATGTGGAGGATTGTGTGCCCATCTTCCTGAGAGACATTGCCAACGACGTGTATGTCTGTGGAAAGACCATCAACCTCCTTAAGATCTGCTGCCCGCAGCACTACATCTGCTGGTCGGAGCTGCCGGTGCCTCGCATTGCTGTCACCTTCTCCCTCCGGGAGGTGGAGGACATCGAGAGGGACTGTGCTGTGTACCGCGGACGCATGGAGCGGGTTGCTAAGCACAGCGCCATCAGCAGGGAGGAGCAAGCCCAGCGAGCAGAGCAGGCACGCCAGGAGCTGATCAATCAGGTCAGAGAGTCAGCGGCCAAAACCCTGGAGAGCATCCGCGGGCGCCAGGTGTCACAACGTCTGGCTGAGGAGGCCAAGAAGAAGGAGCGTTTTGAGGAGCTGAAACAGCACCTGGAGCAGGAGCAAGAGTGGCGAAGCGTAGCCACAAAGAAGCAGGAGGAGGATGACTTCAGCTTTGCCAGAGAGCTGAGGGACAGAGAAAAAAGACTACAAGCCCTCGAGGAGCAACTGGAGCAGAGAGCCAGGAAGGAGCTGATAGCTCAGTACAGCCGTCTGTCAGAGGATGCAGCTCGCAGAGAGAGACGGGCCATGTGGCGGGTGCAGCGAATGAGACTTGATGAACCCCGGGCTCAGTTCTTCATGCATGACAGGCAGCAGACTCAGGCAATGCTAGAGAAATATCCTTTAGGCCAGAAGAGACCTCCCATCAAAGTGTTTCCACCTGTTACCTCAGCACAACAGACTGCACTACAACCAACACTGGAATCTCCCACTCAGCATCTGTCTGAGCAGCAGCCAGCGGAGACTCAAGAATCTGATGGTGTATCACCTGACCCATCTTCACCTACCCTCACCCACCTTACAGTTAACCTCGCACTCATCTCTGAGAACGTTGACGTCAATGATTTTCTTCCTAAGTCACCAAATCCTAACAGTCAGCAGGTAGACATCGCCCTACAGGAGATTGGCTCTGACCTACCTGAAGTGTGTCCTACAGCACAGCTAGTAGACTATGACTTCAGTGCCCCCTTTAGTCCACTTGAAGGTATCACAGGTCAAGCCTCAGTCCAGCCCCAACCTCGCTGGGGACCTGCAATCCAGCCTGACTTGATCCAAAACCATCCCTCTTTTTCTCACATCCTCATAGGAGAGAACATGTCTCAAGTCCAGGATTGTCTCCCCAAAGCTAGCCCCTTTGGCCAACCCTCCAAATCCAGCTTTACGCTAGGCCAGTACACCCCAGAGGAGCTTCAGAATACATCTAAAGCAAGCATTTATGGACATCCCTCTCAAGCCTCAGTGCAGTTAGTAGATGGGAGTGGCTCTATGACTGACAACAAGCAGGCGGAAATTGCATCTGTGATCATTGAAATGGGGAATTTAGAAAGTAAAGAGGCAAATAAAGACAATGATGTGCTTGATGCAGCTTTGTCCACCACACCAGAAGAAAGTGGCAAGGGTAATTGTCGTTACAAAGCAGTGACAAGTCTTTCTGACTGTGGTGGGATTGAGCCACCTGATGCAAATCCTAACCCAAGCACTCAAGACCGCAGCTCAGATGCTCAAGATAAAGCTGGTGATAATAATTATTTGCCAAATGTTCATCTCCCCAGTGCTCGCCTTAAAGCTGGAGAGCTGGTTTTAGATGTCGTTGCCCAGCATTCTTTACCTAGAGTCCATGGGCATTCCTCTGATGCTCGCGTAAAGGTTGGACAACTTGTATCAGAGGTAACTGCTCCTCTTCCATCCCCTAACGTCCACGGTTATGCCTCAGATTCCCATATCAAAATTGGAGAACATATTTTGGAAGTTGATGCTTCTCTACCTTCCTCCAGTCTTCACAGTCAATCTTCTGATGCTCACATTAAAGTTGGGGAAAATGTTTCAGATATAGTTGCCCCTCTGCCCTTTCCAAACGTTCATGGTCACAGTTCAGATGCCCACATTAAAGTTGGAGAAAATATCTCAGATGTTGTCGTGCCACTTCCTGCTCCCAACATCCACGGTCACTCCTCTGATGCTAATATAAAAGTGGGCGAGTTTCTGTCTAACATACCTGAAGCAAGGCCTCGTGAGAGTAAACATGGGCATGCCTCAGACTGCATGCTTCAATCAGGCTGTGTGGTGTCTGGAACTGAACCCGCCTTGTCTGTTCTACCTGGAAGCTCTTATGGTCACTCCTCAGACTCAGGGTTAGGTGGTGGATGTGTAGTTTCAGGAGAAGAACCCAAACGTTCTCCTCTACCTGGCAGTGCTTATGGTCATTCTTCAGACTCAGGGTTAGGTGGTGGATGTGTAGTTTCAGGAGATGAACCCAAACGTTGTCCTCTACCTGGCAGTGCTTATGGTCATTCTTCAGACTCAGGATTGGGAGGTGGATGTGTAGTTTCAGGAGACGGACCCAAACGTTGTCCTCTACCTGGCAGTGCCTATGGTCATTCTTCAGACTCAAATTTAGGCGTTGGATGTGTTGTGTCCAAAACTGAACCACTTCCATCACAACTACCCGGCAGCACCTACGGCCACTCCTCTGATTCAACCCTGGGGGTGGGTTGTGTGGTGTTGGGGACAGAGCCACAAGCCTCTGCACTACCAGGCAGCACCTATGGCCACTCATCAGATTCTTCACTCGCAGTTGGGTGTGTGGTGAAGGGCAAAGGCAGCTTAAATCAGCAGAAGACAGACGACAATGAAGATGGCAGAGGTTCTAAGTCGGACAGCCCTGGTGAGCAGCTGGTTGAGTTCATGGGGTCCTGGGCAGCAGGCTTCGGTTTGTCCCCTGGAGAAAAGTCTGAGCAGGAATATCTCTTGGCTTTGTGTGCTCAGTACGAGGTGGAAAAATACGAAGACTGCTACAACCTAATGGCTTCGTCCCCAGAGTGTCAGCTGCTGAAGCAGGTAACTCGGGGACCCTGGGGCCTTCCTATGGACCACACACTCCGCAGAGCCACAGACACCACTGTTGTCCAACTCAGCGAGATGGTTTCTCTGCCAGTTCTGATAAAACAGGCCGTCACTACCCCACTGATCACACATGTGTCATTGGTGAACAAGGCGGTGGTGGACTACTTCTTTGTGGAGTTGGGGGTGGAGAGACACTTTGAGGCACTGCGCCACTTCCTGCTGATGGAGGATGGCGAGTTTGCACAGTCCCTCAGCGATCTGCTCTTTGAAAAGCTGGGCAGTGGCCAGACTCCCGGTGAGCTGCTGACCCCCCTGGTCCTGAACTCCATCCTCAGTAAGGCCCTGCAGTACAGCTTGCATGGGGACACCCCCTTAGCAGGTAACTTTACCTTCGCCCTGCGCTTCCTCCCGGAGACCTTCCACCCACACGCCCCCGATTCTCTCAACTGTCTGGAGCTCCGCTACAAGCATGAGTGGCAGCTTAATCGCATCATCACGTACTGCGCCGAAAACAAGTACAACCGTCTGTTCTCGTTCCTGCTGCAGCTCAAACACATGGTGTGGAGCCTCCGTGAGGTCTGGTTCCACCTCAAGAGAACAGCGCTGGTGAAAGGTGCAGGTCGCTCGGTGCAGTTTCGGCAGCTGCAGCTATACAGACACGAAATGCAGCATTTTGTCAAGGTGATCCAGGGATACATCGCCAACCAGATCCTGCAAGTGTCCTGGAGCGAGTTCACAGCCAAGCTGGCCACTGCCAACGACCTGGACGCCATTCACCGTACACATGCAGACTACCTCAACAGAGCCATCTTCAGGGGTTTGCTGACAGAGAAGGCAGCTCCGGTCATGAACATCATCCACAGCATCTTCAGCCTGATCCTCAAGTTTCGGGCCCAGCTGATCGCACAGCCCTGGGGCAGCCAGCAGGGGGAGGCAGTGCACCCAAGCTTTATTGCCATGCAGCAGTCGTACAACACCTTCAAGTATTACTCTCACTTCCTTTTCAAAGTGGTGACCAAGCTGGTGAACCGAGGCTACCAGCCTCATCTAGAGGATTTCCTTCTTCGCATCAACTTCAACAACTACTACAAAGACTCCTGAGCTGTGTACTGGTGTGTATGTTGTACATGAGCTTAGTGTGAGTACTTGACATAATACAGGCCATTTGTTAGATACTTGCAATGCACTGTTTACATCTTAGAGTCCCCTGTATCTGTCTATAAGACAGATAATCAGAAATATATAATACAATAAATGTTAGTGTCGAAAATACATTAAGAAACCCACCTGTACTTTATATTAGGCCATGAATTTGAAATTTAAATTGTATGCAATTATGCAAAGTTTATGCAATCCATGTGCAGGATTTAATTAATGGCTAAAACTGTATGCTGCCAAAGTTTGTAATTAAGGTGAAGCTGATGCCTACTGTAATGTCTCACGATTACGTGTGCCTCCAGCTATGTAGATTTTAAGTGCATATAAATGAAGTGTCAATTGCATGTAAATACAATTGTTAAATAAATGCGCTATGTTCCTGTGT
->XM_050218304.1 PREDICTED: Anopheles maculipalpis sensory neuron membrane protein 2 (LOC126561926), transcript variant X2, mRNA 
-GAGTGTGGGTGAGTGGGTGCAGTGAACGGTGTCACGGTGCTGCCAGGCGACGGCGATCCTCCAAACCACCAAGATGGTGCAATGCACTCTGATCTGGGCCGGCATCGGTGTGATGATGGCCGTATCCGGCGCACTGCTCGGTTGGGTCGTTTTTCCTCGCGCCGTGCACGAGAAAGTGATAGAGGCTACGGAACTACGTCAAGGGACGGATCAATACAAGCGATGGGAAGCATTGCCACAGCCGTTAGATTTTAAAGTGTACATATTCAACGTCACTAATCCGTACGAAGTGATGCAAGGACGACGGCCGAAGGTGGTTGAAGTTGGACCATACGTTTATTTCCAATATCGCCAGAAGGATAATATACGGTTTAGTCGAGATCGGTCCAAGGTGCATTACAGTCAGCAGCAGATGTATGTCTTCGATCCCGAATCGTCCTATCCACTGACGGAAAACGATGATCTTACAGTGTTAAACATGCACATGAATTCCATACTGCAAATAGCCGAGGATGAAACGTACGACAGTTTGCGACTGATCAATGCCGAGCTGAACCGTATCTTTGGCCGACCGGACACAATGTTCCTGCGGACGACACCGAAACAGTTTCTCTTCGACGGTGTACCGTTCTGCGTGAATGTGATCGGCATTGCGAAAGCAATCTGCAAGGAGATCGAGAAGCGTAACACCAAAACCATTCGCACCATGCCGGATGGAAGTTTACGGTTTTCGTTCTTTAGCCACAAAAACATGACAGATGATGGTATGTTTACGATCAACACGGGAATTAAGGATCCGTCGCGGACGCAAATGATTGAACAGTGGAATGGCCGAACAACGCTCGAGGTGTGGAACAATCGGAGCAGTGGATTGCCCTCTGCCTGCAACAAGATCCGGGGTACTGATGGGTCCGGCTATCCACCGTTCCGAACCGGTGTCGAACGAATGACGATCTTCAGCACCGATATCTGCCGCACGGTGGACATTAAGCTAACCGGGGCATCATCGTACGAAGGCATCCCCGCACTGCGGTACGAGATCGACGGTAACTTCCTGCATGAAATAGGACCCGAGTACGGCAACGAGTGTTACTGCGTGAACAAGATCCCGAAGTCGATCGTTAAAAGCAATGGCTGCCTGTACAAGGGCGCACTGGATCTTTCCAACTGTTTCGATGCACCGGTGGTTCTGACGCTTCCTCATATGCTGGGTGTAGCCGAGGAATATACAGCACTGATTGACGGCATGGACCCTGAGCCGGACCGGCACCAGATCTTTGTGGATGTAGAACCGTACACCGGCACACCCTTGACCGGTGGGAAAAGGGTACAGTTCAACATGTTCCTGCGACGGATCGACGCCATCAAGCTGACCGATCGGTTGCAGCCGACCCTCTTCCCGGTCATCTGGATCGACGAAGGTATCGCACTGAACGAGGACATGGTGAAACTGATCGATGACAGCCTAATGAAAGTGCTCAGCCTGCTAGACATTGTGCAGTGGGTACTGATCGGTGTAGGGCTCCTGCTAGCCATCCTGATGCCGATCGTCTTCTTCGTCAAACGCTGTCGTGGCAACGATAGCCGTACGGTTAGTCCTGCCGTAACGGCTACCACGAGTGCGGCCAGCCTATCGATGGCGACGGGCGTTACCGGCGAGCGGAACAAATGACCTTCGCTGACAATGCTAAGTCTGGACTGATGAACTGCTAGCACCAACTAGCGATCAACATTTAGAAGGTGCCAATGAG
->MK538674.1 Uncultured bacterium clone OTU_1300 16S ribosomal RNA gene, partial sequence 
-GGGCCCGCACAAGCGGTGGAGCATGTGGTTCAATTCGAAGCAACGCGAAGAACCTTACCAGCCCTTGACATCCCGGTCGCGAGCACCAGAGATGGAGCTCTTCAGTTCGGCTGGACCGGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGCCCTTAGTTGCCATCATTTAGTTGGGCACTCTAAGGGGACTGCCGGTGATAAGCCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTACGGGCTGGGCTACACACGTGCTACAATGGCGGTGACAGAGGGATGCAAAGGAGCAATCCTTCGCAAATCTCAAAAAGCCGTCTCAGTTCGGATTGTGCTCTGCAACTCGAGCACATGAAGTTGGAATCGCTAGTAATCGCAGATCAGCACGCTGCGGTGAATACGTTCCCGGGCCTT
->XM_023646352.1 PREDICTED: Equus caballus chromosome 7 C19orf24 homolog (C7H19orf24), transcript variant X1, mRNA 
-GCACTCGTCCCTGCCGGGCCCTGGCCGTCTCGGCGGAGTGACCGGGCAGCCTCATCGGTGTTGCGGGGCCGAGCCTGCTTCCCGGGCGGGCTGGTGGCCTCCTCGCTGGTCTTGGGGTGCAGCTGTCTTGGGGCCGAGCGGGTCCCCTCAACTCCCCCGGGGTGGGGGCGGCGCAGCGGGCGCAGGGCCCTGTCGGTGTGGTCAGCGCGGTCAGGACGGCGAGGGCCCCGCGTCTGCCGGCGGTCCGGTCTGCTGGTCCTGGCTCTGCGGGCGCCGATGCCGTGGCCTCGTGGACGGCGCGGGCCACGGCACGGCCGCCCTGCTGGCCCACCGGCCCCCGGGCTGCACGGGCTGCGGGAGGGCCCACCGGCCGAGAACAGCGAGTCGGGGCCCGGACCGGAGGGAGCCCAGGCTCGGCCCCAGCCGTCCTGCGTGGCGTGGCCTCGTCCGTGCGGGTCCTTGGGCGGCGACCCTGTGGCGCGCCCAGCTGCCGTGACCCGGTCTGGCCCAGGGCAACTGAGGCCTGGCGCGGCGGGCCCGCGGGGCCGGGGCGCGGGGAGACGCCCCGGGAGCGGCCGGGGGCGGGCGTTTCCGGAGTCGGGCCCCGCCCCCGCGGGCCATTGGCTGGCGCCGGTGAGTGACAGCGCGGCGAGGGCGGGGCAGCCTCCGCTTCCGGCGGGCCATGGGGCCGCGCGTGCTGCCGCCGCCGCTGCTGCTGCTGTTGCTGCCGGCGATTCTGCTGCCGGCGTTGCTGTGCGGGGCCCAGGGGACCACGCCCAGGTCGTCGCACCCCGCGTACGCCACGCTCTTGCCGTCGCCCGCCGTGACGAACGGGAGCCAGCCGGGCGCGCCGCACAACGGCACGCACCCGCGCTCGCCGGCCGCGCCGGGCTCGCCGCTGCTGCGCTCCTTCTACGTGCTCACGGGCCTCAGCGGCCTGGTCGCGCTCTACTTCCTCATCCGGGCGTTCAGGTTGAAGAAGCCGCAGCGGCGGAGGTATGGCCTGCTGGCCAACACCGAGGAGTCCGCGGAGATGGCCTCGCTGGACAGCGACGAGGAGACGGTGTTTGAAAGCAGGAATCTGACATGGTGGCGTTTCCAGCGGCCCTGGGGGAAGGACAAGACGCGGGGTCACCCCCAGTGCCTGGCGCAGTCGCTGATTCTTTTGTTGGCCTGGCTGCACCGCGACAGCTCGTGTGGGACCTGCCCAGCCTCCCTGAAGACGCTTCAGCCCCCGCCTGCACAGGACCACCCGAGATGGCCGGTAGAAGCCAGAGAGGCTCTGGCAGCCCCTCCCAGGACTCAGGCCGCCTGGCCGGACTGTGGCTTGTGCTGCTTGCTCTTTGCTGTGGGGACGTGGCTGGCCTGAGCCGAGGCCTGGGGGGCAGGGGGGCTGAAGGCCTGTCTGGGAGCACCTTCCCCCTGGGCTGGGGACAATAAAGGAGTGGTGGCTCTGTC
->XM_035641279.2 PREDICTED: Scophthalmus maximus zinc-binding protein A33-like (LOC118314697), mRNA 
-TGGAGCTGGAATATTTTTCCTATAACCTCACTTTACAGGAACACTTCAACCTCACCATGGCAGCAATGAATTCGCCCCGGGAGGAGGACTTACTTTGTCCCCAGTGCTGCGAGATCTACCGACTCCCTGTTCTTTTGAAATGTGGCCACAATGTTTGCAGAGTTTGTTTACAGAAATTCTGGGAATTGAAAGGATGTCGAGAATGCCCAGTGTGTCGCACTGTGGCTGAGCCCGGGAGGCCTCCTATCAATCTGCCACTAAAGATAGCTGCAGATGAATATCAACTGCGACGGAGCAGCAGGAATCGAGACCTTTGTTTTCTTCACGGTGAGAAGCTGACACTTTTTTGTCAGAACGACGAAGAGCCCGTCTGTGTCGTCTGCCACACATCCAAACAGCATAAGGTGCACGAGTGCTGCCCAGTAGAGGAGGCTGCCCAACAGAAGAAGACAGAGATTTCAACCATGCTGGAGTCCCTGAGGAAAAAGCTCAGAACCCTGAACAAGACCGAGGAGCACTGGAAGGAAACAAAAACCTATTTACAGACCCAAGCTCGTCAAAATGAAGAAGGGATAAAGGAGGAGTTTCGGAAGCTGCACCTGTTCCTCCAGGAGGAGGAGAACGCGAGACTAGAGGTTCTCAAACAGGAAGAGGAAATCAAGACCCAGGTGATGTGTGAGAAGCTGGACAACATCCAGGAGCAGATCACAACCCTCTCCTCCACCGTCAGTGATACGGTGGCCACGCTCACAGCGAAGGATTTGACCTTTTTACAGGACTACAAGAAGACAAAGAAAAGGGTCAAATGCAACGTTCGAGAACCGGAGTGCATCAGAGACATCCTGATAAACCCTGCAAAGCATCTGGGATCGCTTAAGTTTGGAATTTGGAAGAGTATGGCCAAAATGGTCAAATATGTCCCCATCACTCTGGATCCAAACACAGCCCACTCCAACCTGGAGTTCTCTGAAGAGCTGACCTGCGTGCAGTACAGCAGGAAGCAGCTCCTGCCCGACAACCCCGAGCGCTGCACCAGCCGTCTGTGTGCGCTGGGAGCGACCGGCTTCACATCTGGAAAGCACAGCTGGACAGTACACGTGGGCCAAAGCAGAGACTGGTACATCGGAGCGGTCCGAGAGTCTATCAAGAGGAAGAGCGCCGTCTTCCTCAACCCTGCCGAGGGCTTCTGGGTGATCGGCCTGTGCGGCGGAGACTCGTTCTGGGCTCAGACGTCGCCTCGCACCAAGCTGGTGTTGAAGCAGAAGCCCGAGAGGATCACTGTGGAGCTGGACTGTGACAAGGGAAAGGTGGTGTTCACCAACGCTCAGGATTCGACGACAATACACACATTCAGAGACAGATTCACAGAGAGGATCTTCCCCTACGTCTCCACCGGATTGTACGGGGAGGGGAAACTCTCCAGCCCATTGACGATCTGCCCTCTGACCGTAACACTGGAAGTAAAATAGACTCACACAGCAGATGAAGAGACACCGTTTTAAATTAGATGTGCGCGTTTTAACTTTTGACTGACATAAAAAATAATGATAAAGCCATGATTCACACATGAAATTCAGCAGCCAACTGAACGATACCATACTTTATTGTATGACTTATGTACAATTTATTAAACAAGACTATAAACACTTTCAA
->XM_041090641.1 PREDICTED: Gossypium hirsutum uncharacterized protein At4g17910-like (LOC107939771), transcript variant X6, mRNA 
-ATAAAAAAAAAGAGTAAAGCCCATCAAAATCCCTAAAAGCTCGTTCCCATGTCTTGCCACAACAATGGTAAAGCCTAACCCATTTATAATCGTCGAGTCCACCAGGTTTTCGGCTTTTGACCCATCCAAGGTGAAAAATATTGTTTGGCTAAAAGCTCTGATCTCCTGTAATAAATTCACAACTGCGTTTTCAAACTCTTCGTCAATGGATTCCTTCCCAAGATCTTTGAATCCCAACAAGCACCTCAGAGAACAATTCGTGAGCAATTTGCCTGGATCTTCCATGCTTGAAGTCTCTGCGCTTTTGAATAATGTAGCTCTTCTAATGCTTTTGCGGCACACTTTCTGCTCTCAAACAGTGAATGATGCTTGTAGGAGTTTAAAGTCTTACCTAGCCTCAGTAGCTTTGGATTATGTCTTCCTTGTTCTACCCACACTTTTAATTTTCACTGTTCTAGCAGAGTGGGTATACATATGCTTGATTGGGTTATTGTTATTGCTGGTCTTCTTTACTGCAGTCAAAAGAACTTACTCTTTGCCTTACATGGAAGGACCTAATGCTTCAAGGGCAAGCATATCATCTTATAGGGTTGTTACGATGTTTATCACATGCTTGTGTATCTTGGCTGTTGACTTCAGAATATATCCTAGAGAATATGCTAAGACAGAGACTTACGGGGCTAGCTTGATGGACCTTGGAGTTGGCTCCTTTGTGCTAATGAATGCTGTTACTTCACGGCAAGCACGAAACATCAAATCATCAATGAGTTGGTGGAAGGCAGCCTTTAAATCTACAACTCCGCTACTACTGTTAGGATTTGCTAGACTTGCTTCTACATTGAGTCTAGACTATCAGGTACATGTGGGGGAATATGGAGTCAACTGGAATTTCTTTTTCACACTTGCTGGTGTATCTATCCTTACATCCATTTTAAATGTTCCCGCAGAATATTCTGGAATTCTTGGTTCAGTAATTTTAGTTGGGTACCAAAGTTGGTTGACTAATGGGCTAAATGTTTATCTTCTTTCTAATGAAAGGGGTACGGATGTCATAAGCAGAAACAAGGAGGGAATTTTTAGCTTATTTGGATACTGGGGTATGTATCTTGTTGGTGTTCAGGTCAGCTACTATCTCTTCTTTGAAAATCATACTACCAAGCAGAGAAGCAAGCATGAAACACGAATCAGAATCTGCCTTCTTACTATTATGTTTTGTGCAACCTGGCTTATGTTACTTGGGTGGTGGCTCAAAATCTACAGGTATCTGAAGATTGACTATCAACCATGACACTGCTAGGAATTTTTGGGTTCGAATTACCATGTTTGTTCTCTATTAGCCTCTCAAGAAAAGTTCACTCAGAAACTTTGTTATACAAATTGAACCCTTGCCTGTGTACCTTGTTTGGTTGTCTTTGGTTATTTTGCTTGTATTTGGATATTAAGAGACGGAGCAACATAGGTTTTTGGTATACTTGATGAACATAGATGCAATTACTTACACAAGATAATCGAAATGCTTGTTGGTGTTTCAA
->XM_015948335.1 PREDICTED: Nothobranchius furzeri homeobox containing 1 (hmbox1), transcript variant X1, mRNA 
-TGTAGATCCATCGGCTCCCTGTCGCTCTCGTTGCTGGGATTTGTAGTCTTTGTGTCGAAGAGCGCCGCCGCGTGTCGGGGGCTTCGGTGGGAGTGAAACTACAGTTCCCTCTGAGCTGCTCGGAGGTGTTAGTTGTCAGTATGGCTGTTGTCAGACAGACAAAGCAGAGAGGCAAATAATTCGCCTCTGATTAGAAATCCTTGGAAGAGGGTCGCGCGGGGCACCGCCATCAGATTCGCGTCGTTGCTCGGCTGCGGCAGACCGCGCAGCTGCTCTCCGCTCTAGTTTTAAAGTTAGATGGTTACGTGGACGTCTGGAGCCGAGCAGGATGTCTGACTTCAGCGAGGAGCCGCGCTTCACCATCGAGCAGATTGATCTGCTGCAGCGGCTGCGGCGCACCGGCATGACCAAGCAGGAGATCCTGCATGCGCTCGACACTCTGGACCGGCTGGACCGGGAGCACGGCGACAAGTTTGGCCGCCGCACCTCTTCTTCCTCCTCCTCCTCCTCCTACCTAGTAGGCGGGGCAAACAGCTGCACCAACAACTCTGCCTCCAACACAACCGCCACGTTCAACAATAACACCGCTGCCTCGGCAACCACCACCTCTTCTGCATCGTGTAACGGTAGCAACAGCGGCGAAGGCGGCACCGCGGATCAGTCCGTTGCCGCCGCCGCCTCTTCCACGGCCTCTAAAATCTCTACAGCCACGCAAACTCAGTTTAGTACTGGAGGGGGACTTTCTCCGTCTCCCAGCTATGACACCTCCCCCCCTCCAGGGCCGCCGCCGCCCTCCGCCATCCTGCCGTCACCGGTGTCTCTGGTGGCGCTGTCTCAGAACGGCCGTGACAGCCTGGCTGCCACGCCCAACGGGAAGCTGTCCCCTCCTCGGTATCCGGTGAACAGCGCCGCAGCGTCCCGAGCGTTCGGGTTTGAAGCTGCAGAAGAAGACCTGGACATCGACGATAAGGTGGAGGAGCTGATGAGAAGGGACAGCAGTCTGGTGAAAGAAGAGATCAAAGCTTTCTTGGGGAACAGGAGGATTTCTCAGGCTGTGGTGGCACAAGTGACTGGCATCAGTCAGAGCAGGATCTCCCACTGGCTGCTGCAGCACGGCTCCGACCTGAGCGAGCAGAAGAAGAGAGCCTTCTACCGCTGGTACATCCTGGAGAAAACCACCCCAGGTGCGACTCTGAACATGCGTCCGGCTCCGCTGCCTCTGGAGGAGATGGAGTGGAGGCAAACCCCGCCGCCCCTCAGCACGGCTCCCGGAACCTTCCGGCTGCGGCGCGGGAGCCGCTTCACGTGGAGGAAGGAGTGTCTGGCTGTGATGGAGAGCTACTTTAATGACAACCAGTACCCAGATGAGGCCAAAAGGGAGGAGATAGCAAACGCCTGCAACGCCGTTATCCAGAAACCAGGGAAGAAGCTGTCGGACCTGGAGCGGGTCACCTCTCTGAAGGTCTACAACTGGTTTGCTAACCGGCGCAAAGAGATCAAGAGACGGGCCAACATTGAAGCCACAATCCTGGAAAGTCATGGGATTGACGTCCAGAGTCCGGGGGCACACTCCAACAGCGATGACATCGACGGGAACGACTTCTCAGAGCAGGCCTGTGACCTGCCGTACTTTGACAAGAGACCTCTGAGCCGACCGTTTGGCCTTTACCGCCTGGAGCCCACCTCACCCACACAGGATGACGGCGCCGCTCACAGCGAGCACCAGGACCCCATCTCTCTGGCTGTGGAGATGGCTGCAGTCAACCACACCATCCTGGCCCTGTCCAGGACCGGGGGGGTCCCCAACGACATCAAGACCGAGTCCCTGGAGGACGAATGAACTGGAGCAGGATGCAGCCGGGGACAGAGGAGACGACGGTGGATTTAAAAAAGAGACCAAAATAATCCTACTTAGTAAAGCTGC
->XM_031476826.1 PREDICTED: Photinus pyralis uncharacterized LOC116163007 (LOC116163007), mRNA 
-ATGGATGAATTTTGTTCAGCAGAGAAAATACTCACTGCAGAACAGCAATACTGTGAGGATTATTTCAATCAAACTACTAAACGTGATTCTTCTGGAAGGTTTATTGTTAAAATACCTTTCAAACCTACTTTAAACAAATTGGGCGACTCTTATGACACTGCTTTAAATAGATTTTATGCCTTGGAGAGAAGGTTAAACAACAATCTGGAATTAAAACTTTCATATTCTAACTTTCTTAATGAATACATTACCTTAAATCACATGACAAAAATTGAGAGAGATAATCAGGTAGCCTTCTACATGCCACACCATTGCGTTCTCCGAGAAACAAGTGAAACAACTCGTCTCAGAGTGGTGTTCGATGGGTCATGCAAGCTTACGAATGGACTGTCCATTAACGATGTTCAATGGGTAGGCCCAAAGTTGCAAAATGAAGTAGTTTCAATTATTGCTCGATTTAGACTTTATTCTTATGTTTTAACTGGGGACATTACAAAAATGTATCGCCAGATTCAAATACATCCTGAACACAAAAAATATCAAAGAATTTTATGGAGGGAAAATGAAAGTGACGAATTATCAGTATATCAGTTAAACACTGTTACATACGGTACGGCGGCGTCTGCGCCATATTTGGCCATTAGATGTTTGATTCAAACTGCACTAGACAATGAAAAAGAATTTGGTTTAGAAGCTCAAATAATTAAGGAAGACTTTTACGTCGATGGCCTTATAACAGGGTCCGACAATCTACAGACATTAATGAGAATGACTATTAAACGAAATATACAACAAATTCTATTTACTGCAGGGTTTTCTTTGCAAAAATTTAAAAGTAATGTCAAGGAACTTAGGGATGATACTGATAATAAATCATTAAAACTGTCTGATAATCAAAATAAAGCATTAGGGGTAGGCTGGAACCCGAAACAAGATTCATTTTTTTACTGTTTTAATTCTTCTGAAATACCAGGACAAATTACCAAACGCACAATTTTGGCAACTACTGCACAAATGTATGATCCTCTTGGTTTACTGGCTCCAATAATCATTACTGCAAAATTGATGGTCCAAGAATTATGGCAAATTAAATTAACATGGGACGAATCAGTTCCTGCTTATTTGCATACAAAATGGTTGACGTTCAAAAACAAATTACATTATATCAATGAAATAATCATTCCGAGACAAGTTCTCATATCCGATTATAAGGTAGTTGAATTACATGCATTTTCGGACGCATCTCAAAGGGCATTTGGAGCGTGTCTTTATCTAAGGTCTATCGATGGTTATGGTAGAGTAAAGGTAGCACTTTTAGCCGCAAAATGTAGGGTAGCGCCATTAATAAATGTCAAATTACCGCGACTTGAGTTGAGTGGAGCAGTTTTGGCAGCTCAATTAACCGATAAATTTAAAAATATATTACGAATAGACATAAACAAACAATATTATTGGTGTGATTCCATGATTGTACTGGCGTGGCTAAAAAATAATCCAAATAAATGGCAAACCTATGTTGCCAATCGTGTTGCTGAAATACAGAGATTTAGTAACCCGGAAAATTGA
->XR_005729805.1 PREDICTED: Ictidomys tridecemlineatus uncharacterized LOC120886716 (LOC120886716), transcript variant X8, ncRNA 
-GACTGGGCTGGATAGCCTGGAGGAGGGCCAGCTGGGAAAGGCATGATTACTGTCCTCAAACACCTAGAAGAGCATCGCATGCGGCCCCGGGGGAAGGGGCTGTTAGGGGGAAGCAGACGACTGCTCCTATAAAAAAGGGACTTTGAAGAGGTGGAGCTGGCCAAAGATGGAAGAGGGGCCTAGAAGACGGCCAGCAAGGCAGGACACAAGCACAGTGGATGCTGGAAGGGGACTCAAGCCCCCACAGACAACTGCTGCCAACAAGCAGAAAAGGAGAATGTTTATGCAGCCTAGTCACAAGGGAAATGACATGAGGACATGAGGACCTCAGACGGCAAAATCAAGGCTTCAACACCTTTGGGGAATCCACAGCACAAGAGCCCCTATTTAAGTTCAACCCCAGAATGAGATCAGCTGACACTTGTTCACTCCTCCCTGCGCCCAGGAAATACTTGGTTATGTGTTACTGACTGAAGATTTGGAGTCCCTGTTTCCCATGTTCACTCAGCATCTGACTTGGGCTCCCTGGGCCTCAATTCCTCCATCTATAAAATGAAAGTGATAAAGTGATACTGGCTTACCACGAGAACTATCTAAAGCTCCTGTGAGAGTTCCTGAACAGTCAGGTCTGTGCCAGCATCACTCCTCCAAAAAGCCTTCCTACAGTCTCCCCAGGACCCTCTGTGGCTCCTCACTGGGCTAGCACCCGTGTTTAGGTGACCCACAGCTCCCTGTCCATCACTGTGTGTTTATACCTATTTAATGTTCCTGCATCTGCCTTTAGACCCTGAGCTTCCTGAAGGCAGGGACCATGTGGTTCACATTTCTAACTCCATCCCCGGACCAGAAGAGGCACCAGGTTCAACAATGCAGGAGCTTCTCAGGCAATGTTTTAAATACAATAATGATGGGAAAGCAACCTCTAAAAAGTCTACTGTTCTTTGAAAGACTGACCAGCAAGGAATACTAAACCTACTGAGGACTCCAAGCTGGATGGAAATCAATCTTATTCTCTACTCTCACTGGCTCCCGGAACAGCACCTGGTACTCTAGGAAACTGCCCACACGAGTGATGACCCTCTAGAGACAAACCCCAGCTCTCGGTGCCCAGCAGACCGGCCTTGGACGATCCTCTCCAGCTGATCTTGCTTATCTTGACTCCTGGACAGCCTGCCCCTTGTCTCCCCTTAAAATTTCTGTCTACTTGAGCCTGCTCTGCTTGGATATCCTGAAGGTCATCTCGTCCCTAAAGTCTGCCTTGACTCCCTCCATATTCCCATCACAGTCCTATCCTCTAAACAGCCCATCTAGTCCACCTACATCTTTCCAGGCACGGGATGCAGGCAGGCTTTAGCTACTTTTAAGTCTTCTCTCCCCAGGATGTCAGTAATAGCAGCAGCTGACCCTTAATGCCTCCTCCCTACCATGTACACCTTTCTTCCTGCTAAGACTATAGTCAGGATATCACCACTTCTGTTTGCAAGTGAGGAAACCGAGAGGTTAGCACCTAGTCCAGTCTCACAGCTCTAGTGGCAGCCTGGGGTCTGAACCCCAGCATTCTGACCCTGAACTATGCTCTAACTACAGGTCTGTATGACTTCTGGGGTGTGGGCTTCTCATTGTGCCTAGCTCAGCCACACCCATGTAGGCTTAATAAACGCTATTCTTTTGCATTCCAAGGAA
->XM_021191354.2 PREDICTED: Mus pahari transmembrane protein 140 (Tmem140), mRNA 
-ACGCCAGTGTGGGTCATGTGTTCCCGTGAGCAACAAGAAGTTGTTTACACTCTTCATTTCTGAAAAGTCATAAGACACAGGCAAGTTAAAGAACGAAAGTGAAATCAGCTGGTAGTGACATCAGTCAGCACAAATGTACCAAAGTTCAGAGAGCTGTTTACTTGAACGCGGCTGCCTGCGAGTGCGGACAGAGCCCAGGAGCTCTGAGCTGTCTGCTTGCAGCTTCTCTCCTCTGCCCTGCTTGCTGGAGCCTGACTTTAAAAAGCAGCTCAGGAGAGGATCGACTCCCGGACAGACAGACGCTGATTTCCTGTGTCACCTTTTGATGAGTGTTCCTGGGCTCTGGCGCTGGTTTTCGCCTCCCTGCAACAGCAGAAGATATGGCTCTCTCCAGGCTGTGGCGGAACAACCACCTGCCCTTCGTGGGCATCATGATCCTCTTGGCCGCCGCCCTGTCCCTGATGTTCTACGCCCTCCTCTGGAAGGCTGGCAACCTCGCTGACCTACCTAACCTGAGAATCGGCTTCTACAACTTCTGTCTGTGGAAGGAGGACATTGGCTCCCTAGAGTGTTACAACTTCCCTGAGCTGGAGATGCTGGGCATTCCTCAGGTTGGCCTAGCCCTGGCCAGGCTTGGCGTGTATGGAGCCCTGGTCCTCACAATCTTCGTCCCTCTGCCTCTCCTCCTTGCCCAGTACAACAGAGATGAGGGAGAGTGGCGGCTGGCCATGGGCTTCCTGGCGGCATCCTCGCTTCTGTTGGCCTGCGGACTGAGCCTCTTCCTCTCCTTCGTGTGGAAGTGGCTCAGGCTCTCCTTCCTGGGGCCTGCCTTGCCAGCTCTGTGCCTAGCCCAGCTGTTACTCATCTTCTTACTTGTGGCCACGGTTAGGTTCCCGCCACGGGACAAGGAGGACAAGAACCAGTGGGAGAGGTGTTAGTCCGGTCTTACACAGGCTTATTATGGGATTGCAAGGGTTTGGTTCCAACTGTGCTCCAAGAAGGGGCCAGAGGACCTGTGGCTGGGTGGGTCCTCTCAACCACCCTGTATCATAACCAATGTTGATCTCCAGCACAGCAGCGGGAACCACCCACTGTGCAGACGGCTGTGGTGTCAAGGAAGCCAGAGGCGGCTTGGAGGGCTAGGGTACCTGCAGTTTCTTAGGGTACCACGTAGCTCATTAGCAGAGGGGTTCCTATAGCCCCAGGCAGGTGGGAGTCGTCAGAGGCCAAACTTCCAAGCTATCTTGGCAAAGTGTCAAACTAGAACTCTGTGACGGTTATGGCAACAAATGGAACAGTTAGGGAAAAAACAAAACAAAACAAAAACTGCTTTAACACCGAGTCCTGACAGCACAAAGAGAAGCCTCACTGACTTTTCAGGGTCCCCTGAATGGGTCCCTGGACCTGACAGCAAACGGTAATCAGCTGTTAAACCATTCTTGTGACCCAGGGGATGCAGACACAAAATGTGTCAAAGCCTGGAAGGTGAACAGGACTGAATAGTCGTCACAAACACACAACGCGTCCCCTCACCTTACCCAGAACTGGAAAGGCAGAAGCATGGTCTTTATTATGCATTGTGGCATCCTTATATATTTTGTTCAGTGTCTATGTATCAGAAAACCTACGTGCCAACGAGTTCTTCATTCTGTGCTCATCAGAAGCCAAAGTGAGTATAAAGA
->XM_051505439.1 Emericellopsis cladophorae uncharacterized protein (J7T54_008404), partial mRNA 
-ATGCCTTCTGCCCCTGCTCTCGGCGCCCTGGGCGTGACCTTTACGGCCATGCGCGTCATGGAGGGCATTGCGCTCCTCACCATCATCGGCCTGTCTGCCAACTTTATCAGTGACGCCGTCAACGCCGGCTACGTTGCGCCTCCTCCGCTGGTCGGCACTCTTGTCGTGTCCTGTCTGGCCACCCTGTACATTGCCATCAGCTACATCCTGTACTACGACTCGATGCTGCCCATGCTCATCGCCACGGGCGCCGACGCGGCGGTCCTCATCATGGTGATTGTCGTGGCGGTGCTGCTCGGCAAGCCCGTCAGCTACCTCCAGTGCGAGTCGTACCCGTCCAAGGGCAACACGGCCAACTTTATCCACTCTGTCTACAGCAACGTCAAAAAGACCAACTCCAACGTCTTCCTCTGGGTGGACCCGGACAAGACGGCCTGCTACGAGGTCAAGGCCGTCTGGGGCCTGAGCACCGCCCTGTGCATCATGTTTGCCATGTCTGCCATTGTCTCCGGCGTGGGGGGACAGGCTTCTGGTCCGAACGTGCTGCGAAAGGGCCGGAGTCTGGGCACCACGGCGGTGACGGGGCCACAGGAGCGCAAGCTCGCATCGCAGGGATCCGTGGCGTCGTCGTCGTCGTCTTCTGGCGGGTCCAACGTCCACGAGTCCTTGCCCCTGCCTGTTCCTGTTCCCGTTCACCGGGCCTCCCCGCCTCCCACGGCTTCTGAGCGACCGTCACGGTTTGGAGAGGTGGCCCGCCCCGTGGAGAGCCTGCCTCGGCTTCAGATCCCACCGCCACCGCCCATCCCGGAGGATCCTTCTCCTTCTCCTTCTCCCCAGCCGCCGCCAAAGAGTCCGCTGAGCCCGCTGCTGGCGAGGGCTCGGTCGAAGAGAAGGACCATCATGTCTAGGGTGGAGGGCTGGTGGGATCTGGGGTTGCTGGACAGACGGCAAACACTGTTTGGCAAGAGGGGTTGA
->GQ040491.1 Uncultured bacterium clone nbw955c02c1 16S ribosomal RNA gene, partial sequence 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACAGACGAGGAGCTTGCTCCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATATTGAACCGCATGGTTCAATAGTGAAAGACGGTTTTGCTGTCACTTATAGATGGATCCGCGCCGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACAAATGTGTAAGTAACTATGCACGTCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGCGCGCGTAGGCGGTTTTTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGAAAACTTGAGTGCAGAAGAGGAAAGTGGAATTCCATGTGTAGCGGTGAAATGCGCAGAGATATGGAGGAACACCAGTGGCGAAGGCGACTGTCTGGTCTGTAACTGACGCTGATGTGCGAAAGCGTGGGGATCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAAATCTTGACATCCTCTGACCCCTCTAGAGATAGAGTTTTCCCCTTCGGGGGACAGAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTAAGCTTAGTTGCCATCATTAAGTTGGGCACTCTAAGTTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGATTTGGGCTACACACGTGCTACAATGGACAATACAAAGGGCAGCGAAACCGCGAGGTCAAGCAAATCCCATAAAGTTGTTCTCAGTTCGGATTGTAGTCTGCAACTCGACTATATGAAGCTGGAATCGCTAGTAATCGTAGATCAGCATGCTACGGTGAATACGTTCCCGGGTCT
->FJ241711.1 Uncultured bacterium clone E53LV6Q02JNG4U 16S ribosomal RNA gene, partial sequence 
-TGCGTAGGCGGCGCGGTAAGTCGGGTGTGAAATCCCTCGGCTCAACCGAGGAACTGCGCCCAAAACTACCGTGCTCGAGGAAGATAGAGGTGAGCGGAACTTAGGGTGGAGCGGTGAAATGCGTTGATATCCTAAGGAACACCGGTGGCGAAAGCGGCTCACTGGATCTTTTCTGACGCTGAGGCACGAAAGCTAGGGTAGCGAACG
->XM_033909212.1 Saccharomyces paradoxus Par32 (SPAR_D00700), partial mRNA 
-ATGGCTACGTTCAACCCCCATAACGAGATGGAGAACCAGGCACGTGTACAGGAGTACAAGGTTTCCACCGGCAGAGGCGGAGCCGGCAACATCCATAAGTCTATGTCCAAGCCGTCTCCCGTACTTCTTCCTTTGAAATCCAACTCAAAGCCAGCAGCAAACAACAACAACAATGGGAGCACACAGGAAAAGGTTCCGCGTTTTGCAATTGGCAGGGGCGGTGCTGGCAATATCTTTCATGATCCGCACCTGACGAGATCCGCCCAACAACTAGACTCCAACGATAATATCAACTATAACGATGTGATTGATGACATTGACGATTATATCTCCCCTATAACTTCAGATATGGTCGATGAAGATGGGCCAAACGCGGTGACAAACACCAGGTCTCGTATCAGCGCGACAAGGAGCCACCAATCTTTGCACGCTTCCACTTCGTCTCCCAACAACAAGGCCCCAATTGTCGTTGGTAGAGGCGGGGCAGGAAACATTTTCTTTAACAAAAAGAAGGTATCCAGCAATGGTGGAAACGAAGAGGACGAGATACGAGGCGGTAATGTTGAGGATGAGGATACGATCAATGCAAACGAGGACAATTTGTTCGTGGTGACTTCGAACGGCAATGCATTGGCGGCAATAAAGTCTACATCCAAGAAACCCAAAAATAAGCACAAGGGCAAAAGCGTGCCGGAAAAATTTGCCATTGGAAGAGGCGGCGCTGGGAACATAATTTCGCCCAAGTCGAGCAGGAACACTATAAACCACAACTCAAACGATGATGATGAGGATGAAGTTAATCTGAAAGACGACAATAGTAAAGAAAAGAAGAAGAAGAAGAAGAAAAAGAAATCGGGGTTTTTCAATTCTTTGAAAACTATGTTTAATTGA
->XM_008090460.1 Glarea lozoyensis ATCC 20868 hypothetical protein mRNA 
-ATGACCGGCACTCGATTGTTTGACAGTTCCTTACCCGTTGGGAACAGGTCTGTCGTGGTCAGAGAGCACTACACACTTGAACGCTGCAATGGCTGCTTTGACTCTGATGTACACCGCTGGGGTCAATTCGAGCATTCAGCCCGTGGTGGACAACTCCTTTGA
->XR_006437666.1 PREDICTED: Triticum aestivum uncharacterized LOC123078769 (LOC123078769), transcript variant X30, ncRNA 
-AAGGACCAGCGATGGAAACCCTAGACTATCGTTTCCCCAGTCCCGCCGCCGCACGCTCTCCCTCTCGCGTGCTCATTCTCCCACCTCTCCACCTCCAAGCCCCTGCTTCCGCACGTCATTCTTCTCCCATCCTCGCGTCGCCGGTCTGGAGGCTAGAGCTTGTGGCCGACGCCTCCGCTCGCCATTTGCCACGCCTCCGGATCTGAACTCGCCCGCGGTGGCAGCGATTGGTGGATGAGAGCCGAGTCCTGAACGGGAAGCAGCGCCTGTCCCTGTCCCACTGCCGTTGGAGAGGCAAGGATGGTATCGGCCGTGCCGCAGCAGCTCGGCGGCTGCCACTTCTTCACATCCCCATCGAGTCGGCGAGTCGCCCTCTGTCGGGCCCACGGAATCGGCTCCCATGACTACACGTTCTTCCTCGGCCTGTTGTAAACCATGGTTCTTCTCAAGCGCGGGCTAAGGTGGCACCATGGCTCGTGCCAAGGAGGCAGCAGCGACCTGCAAACCCTGCAACCAGCAGTAACACGACATGCTGATATTTCTTCAGGGCGTGGCTGGACTCCCCTCCCAGGATCTCACTCCACCACGGGGCCTTCCTGCTGTGAGCCTCTCTGGACGGGAGCTACAACGCCCGTCCCCATCTCACCTTAGGCAAGATATGTGTAGAATTTGGAAAGGACTTGCGAGCTAGGAAAATTTGGGAAAGGACGTTGGGAAGATAACTAGGTTTTCAGTGTGGAGGAACATGACAATTTGAACCAACTAAGATGCAAGGGCATGCTTCACATGGATTCAGACACAATTTTTTTTGGGAATAGATGGTTTTACTAGCCGATGGCATCAGAGGAGCAGCTGCAAGCGCCGAGTGAGGAATTTTCCTTTTGCTCGCATGTGTCTTGTGGTCACTTGAAACAGAGCACTACCTCTGCTTGCAAGTGTCAGAACTACAGGTTTTTGGCTGAACATTCAATTGTGGCAAAATTTTATTGATCCTCATGATTTTGAGATCTAGTGTGCCTTGTTAGTTTGGAATCAGAAGATGCATGCATGCTGCAACCTTCCTGCTTATCAATTAAGTTCTCTGCATCCTAAACTCGCTGACCTGGTATGATCCGTGTGATTAAGAGATGTTTCACCTTTTCTCCATAACAATTCTACAATGCCCCACAAGAGGGATCCACCACGCCGGTGGACTTCACTTGCCACTCCGGGAAGGGTTTTCACATTCCATTTCCATCCATCAGCTTTTCAGTTCTTGTTAGTTTTCACATTTACATTTCACCATATCGGGGATTTAGAGGGCAGCACTTCTTTCTTGGTTATATTAATCAGCCGCATTGTTTTGTGATTACAGAGAAGAAATGACTTCAACCAGGGCAAATTGATAGGGAGGATAGATTACGGCGAACTGTCTATGTCCCAAACATTGATCAACATGATGCTAAATAGAAGCTTGCTCAGGTTTTCTCAACTTGTGGCCAAACCCTACTCAAGCATCTACACCCTCTTCAGCGACCGACGCCCTGTCTGATGGAAACGAGAGACGGGCGGTCGCTCTGCTTGAAAAGAGAGACAAACGGTCTCTGAGCGAGGGAGGGGCGGAGGTTCGTCTTTGCCGGCCGTATGACATTCCTGGTTGCTGGTGGAGGTGCAGGGCGCTCACCTGATTTAGGGAAGGCACCGTGGCTGTTCGGTGAAGCGGGTTGATGAAGCTGATGTGCTTTGTTCCTAAAAACAATGCATCATCAGTTCCTGGAAGAGTTCAGTACATGCACGTGTATATGTTTCTCTGATGCTCTCCTGTCGCGTTCTTACTCCGGCAGCAGAATCTCAAGCAACTATGGTTCTCGGACTAGGTGGCCCCTCTATCTTCATTTTTATTCTCCAGTACGATCACTTCTTTGACCCAACAATTCCGTTGTGCTATTTTCTTTCCAATCTCAGAATTGTACAGTTGGTTTTCATCCTAGTTCTTCAGGCAAAATTTGAAGTTTTGCTCCCATTTTTGGTTTGAGGAAATTTAACTTGCAAAGCTACCGCCAGGTGAATTAATTAGGTCCCATGGGTTTGGATACCTCATCTCTTCACTGACTGCATCTCTTCATGTTTCCAGATTGTGCATTGGTCTAGAAATACATACTTAACTCGGTAATGTGGACTTCACTACTGTGGTACACTGTAAATGGCAAGCTTTTACATGAAGCACTTTTGGTGATCCTAAGGATTTGCTACAGAAAAGTATAATATGATATTGAGTTTCATTCTCTTCCTTTCTGCATTTCCTTGAATATTGTGCGTTCAATTAGCTCAACCGGATAGCAAGAAATGTCAAGGGTTAGCTCTTCTGAACATATTCCTCATGGTAGAAATGGCTGGTATACATGCCGACACGCCCATCCGTGTGTTCAAGACTGGCTGATTCACACCATGGCTGATGTGTACACACAAGCTAACCAAAAGGAGCAGAAAAGGGGTGCACACAACATGTCTGCTCGTTAATAACAAGTCAGGAGGGGGCTATCCAAGGACGAGAAAGCTGGGAAGCTCGCATTGCAGCTTTGGCTTAAGCTGTGAGCACTTTTTCGTCAGAGAAGCTGTAGTTTGATGTTTTGGCCAAGCAATGGGCTGTTGTACCACAATGGTGTTCCTAATTGTTGGCTCTTCCATATAGAAGCTCTGAAACAAAATGAGATGGCCTCAAATTAAGGACAGTTAAACCAGCTGCTCCGAGAGGGGATGTTGAGGATAACGACAATGACGAGCAAGTCGGTGTTTGTGAAGCTTCGCCTGAGCCATTCCAGCTCTTCCAGAGGCACAAGGAGAGCCTAAAGTCAGGGTACGTTCAATCGAGGACACTTGATTCTCCAAGAATTTGTTGAGGATAACAATGGCAACGAGCAAGTCGGCATTTGCGAAGCTTCATCAGAGCCATTCCAGCTCTTCCAGAGGCACAAGGAGAGCCTAAAGTCAGGGTACGTTCAATCGAGTACACTTGCTTCTCCAAGAATTTGTATAATCATTAGAAGTCCAAAGAATGAGTCAAGCCAAAGATATGAAAATGGAACACATTTGCGCTCCTACGAGAAGAAGGTCGCGCAACTGAGGATTCAGGACGCCAACAGTGCGGAGCTGTTCGCCATTGAGAGGACCAGGGCTGCCATCAGGGACATCTGGACCAAGTTCAACATCTCCCTTGCCTCCGTCAACGCCGGCGACCGACTCTACAAGCGTCTAGCTGTGCTTTATGACATGATGAATGCTGCCATCGCTTGCTTTTGAGCACCTACAAGTTACCCTGTTGCATGTAATCTCTAAGACTGCCACTCATCAGGCTTGCATGCGCCTGTTAATACCAGGGCTATAACAACACTTTTATGTGTATATACTCAGTTCTGCTTCC
->LN810097.1 Uncultured bacterium partial 16S rRNA gene, clone HWB-4 
-CGGACGGGTGAGTAATGCGTAGGAAGCTACCCGATAGAGGGGGATACCAGTTGGAAACGACTGTTAATACCGCATAATGTCTACGGACCAAAGTGTGGGACCTTCGGGCCACATGCTATCGGATGCGCCTACGTGGGATTAGCTAGTTGGTGAGGTAATGGCTCACCAAGGCGACGATCCCTAGCTGGTTTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGTAGGGAGGAAGCGTTGAGTGTTAATAGTACTCAGCGTTGACGTTACCTACAGAAGAAGCACCGGCTAACTCTGTGCCA
->XM_029018326.1 Cryptosporidium ubiquitum uncharacterized protein (cubi_01314), partial mRNA 
-ATGGAAAACGAAGCAGAAGAAAATTTCTCAAAAATGATTAAAGCTGTAAATCCACTTTCTAATGATCAAAAGGTATTTTTGGATTTGGGACAAGAAGGTAAGGCCATTCCAATTGATGCTACAAACACAGGTATTTATGAGTATAATATTACAAAACCAATTACAATCACCAAAAGTGGTTCTTATGTTGAGGATGACGATTCATGTTTAACAACTACTATAACTACTAACGAACTTTGTGATTCAAATAGTGTTCTCTCTGTTGCTGGAGCGAATAACTCAGAAGATATACAAACAGAAGACTCAAAAACAGATGTTCTGGCAAATAAAGATTCTAAAGAAAAACTAGAAGAGCAATCTGCTTTTGATATTCATCCTATTAATATTGACACAGGAGCTGAGGAATTGGTACAATCCGCACAAAGTACCTCTAAATCAGGTCGTCGTTCATCAGCAAATCATGAAGTTGGTTCAAGGCAACTGAAATACAATCAAATTGGAGTATATTGGAAAGATAAAGAAAGCAGAGTTTATGCTAGGTTTACATGGGCCACTAGAAAGTATTCTAAAAGCTTTTATGTGGGCCCCAATAAGCCATATGCTACTGTTAGGGATGCAGAAAAGGCTGCTATCAGATTTTTGTTGATTAATAGTCCATTACATAGAAGAAGCCACTTAAAACATTTTAGATTTTCAGAAAGTGATGAAGAAGGAGAAGAGCCTTATGTTGGTTCTCAAGCACTTAAGGAGGCAAGAAGGACCAAAGGAATCATGTTACATTTCCCTGCTCCTGAAAGTGATGATGAGGTTTGGTCTCATTATAACACTTCCAATATCAATCCTGCAACCTTGTATGGTGAGATTATTAAGAAAATGGATAATAGTGAAGGAAATGCCGCTGGAATAACTAGCCCAATTACATCTGCCAGAGAGTATGTTACAGCTAAGCATAAGCAGAATACCAATACAAACCAAAATGAATCCAAATTTTCCGCTTCCCTTCCAGTAAATTCTACAATTGGAGAAAATGTCTCTTCTGATGACTTATTTTTGGCATTAATGGCAAACCAAATTGAATCCGATAGACTAGTAGAGAGGCAGACTACGGGAACATATATGAACCCATCAGCCAGTTCAACTACTGTTTCCTCTAAGAGATTTAAACCAAATTCCAAAACAGAAACTCTTGATTCTTCTGAATTAAACTTTTTCCCCACGAATTCGAATCAACTTGGATCGGCATTTATGGATCAAAGCTCTTCAACTACCTCCACTAATCCTTTTGTTGGTATGGATTATAATACTTTGGTCGCTTTACAACATGCTCAAATGGCAAATTATTATTTGCAACAGCAAGTGGCATATGCAGCTGCTGCTAATCTTGCAATATCATCAAATACTAGTGGGAACTATGCTAATGCTGCAATACGTACAAACCCATTCATAATTCCACAATATTGCTTGGCACCTGTTACTGGATTAGAATCCAATAAATCTGAAGAATCAGAAGTTGATAAACTCCAAGGTGTTACTTTAAATGTTGGTGGTCTTAAAGGTTCTACTCAGTCTAATGCTTCTAACTCTGTTAAAAACATTGCAGAATCTACACTAGATCAGTATGGTGCAATAATGCCAGGACAAGAAACAAAGGCAATGCCTTCTTCGAATATTACTATTTGTGGTACAAACATTCCAAGTAATTACCATACGGATTATATGGCTGTTATGGCTGCTGCATATTCAGGTTGGTATTCGCCTTATGGATACACTATGCCTTTTATGGGATCATACACCCCAATGATGCCTTCGATTATTCCGAATCCAAATGTATTGGGAAGTCAATTTCATAATAATATAAGTCTATCTACAAATACAACTAATGCAGGTCAGGTTCAATCAAGCAGTGTTAATAATGCTGTTCGATTGCAAAAACAGGTAAATAATAATGTTAATTCCATTGAATCTCTGGTGAACACTCGGGTAGAAAAGGAATTACAATCACAAGGTACTTCAGAACAGGAAAATAAACAAGTACCCTAA
->XM_027495983.1 PREDICTED: Abrus precatorius uncharacterized LOC113862782 (LOC113862782), transcript variant X4, mRNA 
-TGCAATTGTACCTTCCCTATGTGAACAGTGATTTCTCCACAACAACCCTTTTTCTCATTCTTCCCAGTGTTTAGCTTTCTCAATTCAGTTGGTGCTGAATGGAAGGTATATTCTTTCTAGTTTGGAATCCTTTCAACTTTGTCTGAAGAATGTTTCAGAATCCTTCTCCAGATTAACATTTTGAGATGGTGTTATATGAGCATTCAGATGTTTTTCAATGGGGTCTTAATATTCTTGACGGTGACCCTGCTTATAGTCCTGGATACTATGGCAACATAATTCAACATGATAATGGTGACATCTATAATGGACACTACTTTCATAGCCATTATGGTAATGAATGTAACCATGTAGAGAATGATGAGATCATTGCCCGCACACTTCAAGAAGAGTTTTCACAGCTGGAGATTGCTGAATCTTCAGGATATTTACAGGCAGGTGAAGAGCAGTTCCATGTTTCTGAGACTGAGCCTGCATATGATTGGCATAACTCTTCAATGGTGAACTATTGTTCAGGAGGAGTTGGTGATGAAGAACCATCTAGCTCATGTTCAAGTCCTTGTGAAAAAGAGGAATATTCATTAGAGCTAACTGACAGTTATCCACTTGATGATGAAGTAGGGAGGAGATTGAGTCAAATGATACCAATTCCTCATGTTCCAAAAATTAATGGAGAAATTCCTTCAATCGATGAAGCAACTTCAGATCATCAAAGGCTTCTGGATAGATTGCAGTTATATGACTTTGTGGAGCACAAGGTACAAGGTGATGGTAATTGTCAGTTCCGTGCTTTATCTGATCAATTGTATCATGCACCTGATCACCACAAGTTTGTGAGACGACAAATTGTCAATCAGCTCCAATCGAATCCAGACATATATGATGGATATGTTCCCATGGAATATGATGACTACTTGGAGAAGATGTCTAAGAGTGGAGAATGGGGTGATCACGTCACTCTTCAAGCAGCTGCAGATTCATATGGTGTGAGAATATTTGTGATGACTTCTTTCAAGGACACCTGTTGCATAGAGATTCTTCCTCATTTTGAGAAGCCAAAAGGAGTAATTTTCTTGAGTTTTTGGGCAGAGGTGCATTACAACTCCATTTATCCCCAAGGAGATATACCTTCAAGTGAGTCGAGAAAGAAGAAAAGGTGGTGGAACTTTGGGAGCAAACATTAACTACACCCCTTTTTAACACATTTTTCCATGTTCAGGAATGAATTTATATCCCCATGTTTTTAGCCGGTCA
->XM_035510062.1 Lasiodiplodia theobromae Gaba permease (LTHEOB_1369), partial mRNA 
-ATGGCGCGCTCCTCTACCGAGCTAGATGTGCTGCCCGCCGTCTCTTCCGGGAAAGAGTATCACAACATGTCCTCACGCGAGCTGTCTGCCGGCACCGACGATGATCTCCATGAACAGAAGGGCATTACTCGCCATGACCAAGCCGATATGTCGAGAATGGGCAAGGTTCAGGAGCTGAGGAGAAATTATCGCCCGCTGTCCGCCATTGCTTTCACAGTAATTCTCCAGGGCACGTGGGAAGTGCTGATGACTGCGACAACCCAAGGTTTGGTTGATGGCGGTTTGGCTGGCCTGATCTGGAGCTATGTGTGGACCTTTGCTGGCTTTAGCTTTGTTATGGCTTCACTGGCTGAGATGGCTTCCATGGCCCCTACTTCCGGAGGTCAATACCATTGGGTCTCTGAATTTGCGCCTGCAAAGTATCAGCGCTTCCTGAGCTATTTTACGGGATGGATGTCGACCATGTCATGGCAGGCCGGAACCGCGTCCGGCCCATTCCTTGTCGGCACGCTGATTCAGGGCTGTGCTATCGTTGCTTATCCTGACTACTCTCCGACGAATTACCAAGGCACGCTCATGGTTATTGCCGTGGCCATAATCGTCTGGATATTCAACGTCTACGGTGCTCACGCCATGCCCATTCTTCAAAACCTGATGCTCATCGTCCACGTCCTTGGATTCCTCACCATCATTATCGTGCTGTGGGTTTTGTCGCCGCGCAACACTGCTGAGACAGTCTTCACCGTCTTCACCAACGATGGCGGCTGGAACTCCATGGGCCTGAGTTTGATGGTTGGCCAGATTTCAGCCATATATGCTTGTATCTGCTCCGACGCTGCCGCTCATATGTCCGAGGAGATTAAGGATGCCGGTGTCGTCGTTCCCCGTGCCATGGTTTGGTCATACGTCATCAACGGCGGCCTCGGCTTCATCTTCCTCGTGACATACTTGTTTATGATTACCGACGTGGAGGCTGCACTTGAGGACTGGTATCCCCACATCTGGGTCTTCCGCCAGGCCGTCAATGATGCTGGCGTCGTGGGTTTGAACGTGATTCCCACCGTGCTCATCTTCGCCGGCACCGTCTCCTACAACCTGTCCACCTCGCGCCAAACCTGGTCCTTCGCCCGCGACAAGGGCGTCCCGTTCTCCAACTGGATCGCTAAGGTCGACCCGAAGCTGGAAGTCCCCATCAACTCCGTCACCGTCACGACGCTGATCACCATCGCACTGTCGCTCATCAACATCGGCTCCGACGTCGCCTTCAACGCCATCATCTCCCTCAACGTCGTCTCGCTGATGATCACCTACATGACCTCCATCGGTTGCGTCTTGTGGCGCCGCATCTACCACCCGGAGACGCTGCCGACCTGCCGCTGGAGCTTGGGCAAGTGGGGCGTGCCCGTCAACATCTGCGGCTTTCTGTACTCGACTCACGCTTTCTTTTGGTGCTTCTGGCCGAATGCTACGCCCACGGATGCCGAAAACTTCAACTGGGCGTCGGTCATGTTCGTGGCTGTGTTCATTTTGAGCAGTATTTATTATGTCTTTAAGGGCAGGAAGGCGTACGAAGGCCCAGTTGTGTTGACCGAGGGCTGGAAGGGCGAGTGA
->XM_020885145.1 PREDICTED: Odocoileus virginianus texanus zinc finger protein 300 (ZNF300), transcript variant X2, mRNA 
-GGTCAGGTGCAGGCCTGTTCGTATGCTGCTGCCGCCATCTTGGGTTGCAGGGCCTGTGCAGGCTTCTGCTCACCACAGGCGGAATTGGGGTTCAGCATAGCGGTTCTGCACCGGGAGCTGTAATGTGATGGGTTAGGTGCAAGGCCTCTGCAGAGTGTCCTATACAGATAAGCAAGTTGCAAGTTGGAGAGTCCTACATGGCAAGATATTGAGGGTGGCTTCCTTGCAACAATCAGCAAGGACATGAATGCCCTTAGTCCAGCAATCTTTGAGGCATTAAATTCTACCAACAATCATATAATTGAGCTTGGAAATGAATCTTACCCCATTTGAGTCTTCAGATGAGAGACCCCAGCCTGGATCAATACCTTGATTATAGATTTGTAGAACACCTCAAAGCAGAGGATTCAGATAATCCATGTCCAGATTCCTGACCCACAGAAACTGTGAAACAATAGATGTGTGTTGTTTAAAACCACTAAGTTTGGGGCCCAGACAAAAGCTCTGAGTAAACTGAATTCCTCTGCTTGTACGGAACTGACCAATCTAACAAGATGGCGGCTCCCACTGAGCCACATAGCACGGGAGTGGCCATATTGCCTCCTGAACAAAGCCGCCCAGGGTGCAGAGTGGGTAAAACTCCGCTGTACGGAACAGTGCACGCCGGGGAGCCCCGCGCTTTGCTCACCCAGACAGGAAGCGGGAGAATTCACCACTATGGATGTGACAGCTGTCTTGGATTGAGCCGTGATGGGCGTTTCTGGAACTGCAGGAAACATTTATTGAACACCTGCTGGGTGCCTGGAGACTGGTGAATATAGAAACTGCATTTTGCAGCCCATCTGTGAAAATACCCTTCTGATCACCAATTTTGCCTTTTCAAGCATCTGCCATTTTAGAGGAGAGCAGAAAAAGATGAAGTCCCAGGGATTAGTATCTTTCAAGGATGTAGCTGTGGATTTCACCCAGGAGGAGTGGCAGCAACTAGACCCTGCTCAGAAGACCCTGTACAGGGATGTGATGCTGGAGAACTATAGCCACCTGGTCTCAATGGGGCATCCAGTTTCCAAACCAGATGTCATTTCCAAGTTGGAGCAAGGAGAAGATCCATGGATCATTAAAAGAGACATACCAAATTGGATCTGTCCATATGAAGACCAGACAGATGGGCGACTAGACAGGAAGAGTAACCTTGACAACCCCCAATCATGTATTTTGGGGTCTGTTTCCTTACATAATAAGATATTGAAAGGATTCACAAAGGATGGTTCATTATACTCCATTTTAAAAGTCTGTCAAAGTGATGGCCAGTTACAGAGATGTCAGAAAAACAGACTTTCCACAAAAGTAACAGTCATCAACAACAAAACAATGACTGTAGAGTCAGACTACAAATATGAGGCACTGAGGAAAATATTTCAAGAGTGCATAGAGTCAGATGCTTCAAGACAAAGACCCTATAACTATGATGCCTTTAAAAAGAACTTGAAATCTAATATTGACCTACCTAGTTGTAATAAGAACAATTCAAGAAGAAACCTTGAGGAGAGTTCTGGATGTGGAAAATCATTCATCCACAGTGTGGCAAATTCTAACCTTGAGAAGATTCACAATGGAGTAATTCCCTGTAATGATATTGAGCATGGAAACATTTTCGGCAAGAAGCAATCCATTATTCATTATCAGAATGTTGAAACCAAGGAGAAAACCTGTGTGTGTGTTACATGTGGAAAAGCCTTTGCTAAGAAGTCACAGCTCATTGTACATCAACGGATTCATACTGGGAAAAAACCATATGATTGTGGTGCATGTGGGAAAGCCTTCAGTGAGAAGTTTCACCTCATTGTACATCAGAGAACTCATACTGGGGAGAAACCTTATGAATGCTCTGAATGTGGAAAAGCCTTCTCTCAAAAATCATCTCTTATTATACATCAGAGAGTTCATACTGGAGAAAAACCATATGAATGTAGTGAATGTGGAAAAGCCTTCTCCCAGAAATCACCGCTCATTATACATCAGAGAATTCACACTGGAGAGAAACCTTATGAATGTAGAGAGTGTGGTAAGGCCTTCTCCCAGAAGTCACAACTGATTATACATCATAGAGCTCATACTGGAGAGAAGCCCTATGAGTGTACTGAATGCGGGAAAGCCTTCTGTGAGAAGTCCCACCTCATTATACATAAAAGAATTCACACCGGGGAGAAACCCTACAAATGTGCTCAGTGTGAGGAAGCCTTCAGCAGAAAGACAGAACTCATTACACACCAGTTAATTCATACTGGGGAGAAACCTTATGAATGTACTGCTTGTGGGAAGACCTTCTCCCGAAAGTCACAGCTCATTATACATCAGAGAACACATACTGGAGAAAAACCCTATAAATGCAATGAATGTGGAAAAGCCTTCTGTCAGAAATCACATCTCATTGGACATCAGAGGATACACACAGGAGAAAAACCTTATGTTTGTACTGAATGTGGGAAAGCCTTCTCTCAAAAGTCTCACCTCCCAGGTCATCAGAGGATTCATACAGGAGAGAAACCATACATATGTGCTGAATGTGGAAAGGCGTTTTCTCAGAAGTCAGATCTTGTTTTACATCGGAGAATTCACACTGGGGAAAGACCCTATCGATGTGCTGTATGTGGGAAAGCTTTCATCCAGAAATCACAACTCACTGTACATCAGAGAATTCATAGCAGTGGTAAAAATCATAGTGAACTAAAAACACAGACAAGCTTTCAGTATTAGCTCAATGCTTAATACGTAACAGGAACTTGATTAATTTGATAACTTTGTTGAAGCATCTTTATAGAGAAAATTTTACAAGAGAATACATATCTGTAGTGTGGTGATACCTAACTCAGCAGACATGATGGAAAATAATTACATAAATGAAGGCCATTTTCACCATAGCATGTAGAGCTTTTAAAGTTATGAATTGAATGGTTAGTAGAACAAATTATGTATATAGAATGTTGTCAAAGTACATATTCCTTATTATGCCCCATAACAATAAACATTGTGAAATTGCTAATATTAACTTGGCATCATTTTGGTCATATACATTAATTGCCTATAAAGGACATGAAGAATGCTTGATTTAAAAAAATCAATTCCAAGAAACTGCATTAACAAGGAAAGGCTTGGGAGTTCCCTAATAATAGGACTCAACAATTTCACAGC
->HQ038014.1 Uncultured Syntrophus sp. clone F2M5Y2A01B2QEH 16S ribosomal RNA gene, partial sequence 
-GAGGAGGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCGCAACGAGCGCAACCCTTGTCTTTAATTGCCATCATTCAGTTGGGCACTTTAAAGAGACTGCCGGTGTTAAACCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCTTTATGCCCAGGGCTACACACGTGCTACAATGGGTGGTACAAAGAGATGCAATCTCGCAAGAGCAAGCAAACCTCAAAAAGCCATCCTCAGTTCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGCGGATCAGCACGCCGCGGTGAATACGTTCCCGGGCCTT
->XM_048223246.1 PREDICTED: Ursus arctos SEC16 homolog A, endoplasmic reticulum export factor (SEC16A), transcript variant X12, mRNA 
-GGCGGCCGGAGCCGGATGTGCCAAGATGGCTGCTGCGGCTGTCGTGTCTGCGCTCGTCGCCGCAGCCGGGCCGGCTTCCGCCGGCGGCTCCTGAGGGGCTGGCCCAGGGGTCGCGGAGGGGCCGGGCGGGAGTCTCGGCCGCCCTGTGGCGCGCCGTTCAACTTAAGGAACCTATATCCTGCTTCTATCCGTAAGGAGCATCTAATTGTGCAGAAGATCAATCATGCAGCCACCACCCCAGGCAGCCCCATCAGGCGTGGTTGGGCCACCTCCAGCTGGGACTCCTCAGAGCATGTTCTGGTCCAACAGACCGTATAGAAGACAGGCAAATAACAACGCACCGGTGACTCCAATAACTTGCCCACTGCAGCCAGTGACCGATCCGTTTGCTTTTAGTAGACAGGCGCTACAAAATACATCGTTAGGCGGTTCGTCCAAAAGCAGCCCGCCCATTCTGCAAGGCCCGGCCCCACCAGCGTTCCTTCAGCGCCCTGGTCTGCCTGTGCCTCACACAGATGCTGGGGATACCCCCCAAGGACCAGTGTCGCAGCCCAGAGCAGATGGCAGTCTGTTTTCCAGTGTGTTGACCCCTTCAGCACCATCGGAGCCCGAGGTGAACAGGAGTGCTGAGGTTGCTCCCAGCTCAGAACCCGAAGTTCAGACTCTGCCATATTCTCAGTACATTCCAGGAGCGGGTGCTGACAGTTCTCACGGGGGCCATCCGCACACAAATATGCTTGGGCCTGATAGGCTCCTGAGTAGCCAGAACCCGCACGACAGTGCTGCGGCGTTAGCACCATCCCCTTTCTTCCCTCAGCCTCGTCAGCAAATGCCAGGGCAGTGGGGACCCGGGCAGGGAGGCCCACAACCCTCAGGTCAACATTATTGGCCCCGCCCAGAAGGACCTGTTCAGAACGCGGTGCCTCATACCTCCATCGTTTCTCAGTTCCCTGCTCCATCCAACCCGCATCTTGGTCCTGGCCACGAGCAGCTCAGCTCACTGGTGTCTTTGCCAGGACCCTTAGCCAGTGATGGAAGCAATGAGGTGGCCTACCTGCAAAGTGGAAACCATTCAACAAATAATTTTGATCCTGAAAATGCATTCAGGCAAAATTCTAGGGCTGGGAATACTTGGGCGAGCCAGGAGCTCAGGCCAAGTCCAGGAGTGAATAAAGAGCAGTTGCCAGACCTTGCTCTCGTTAATCCCCTCGCTCAGGGAAATAGCCCAGAAAGCCATTTGCACTACCCCCCAGGGGCTGGGACCAGCCGAGCCCTGTCAGAAGTGGACTCGGGGGCTCTCTCCATGTTTTTTCAAGGTGGGGAGACAGAAAATGAGGAGAACCTCTCATCTGAAAAAACAGGCTCTGCTGGTCAGTCTGACTTCGACGGCTTCTCCCCCAGCCCCGCGCTTGGTCATCCTCCTGTACATGTGGGAGCAGGCGGCATTTACCAGGCCCTTCCCAAAGGTTCCAACAGTGAGGCCATGCAGCAGGGAGGACACCCGCAACCTTATTTTTCTCAGTCTGCAGGCCCCCAGCCTGATCGACCCACCACGGCCAGTGCTGCCATTGCTGCGTGGGGCAGTGCAGCAAGTGCGGGGGCGCACGCAGCCAGCAGCTCGCAGTCTGAGAATGTGGAAGACCTAGAATTCATTCAGAATCAAGAAGTTCTGCCAAGTGAGCCCCTGAGTTTGGACCCTTCCTCCCCAAGCGATCAGGTCAGATACGGGCCCCTTCCTGGGCCAGCCGTCCCCAGGCTCGGTGTTGTGGGCCACGCTGGAGGTGGGGGTCCAAATCTCGAGGCCCCGGATTCAACGCCACACCCTGTGCGGTCTGATAGCGTGTCATCCGGTTACAGCAGCAAGAGCCACAGGAATCTTTCGAGTGCAGCCAGGCCCCAAGACGTAGGCACTTTCATTCAGCAAGAAGTTGGAAAACCTGAAGATGAGTCTTCGGGGAGTTTTTTTAAGCAAATTGATTCTTCCCCTGTGGGAGGAGAGGCAAACGAGACCACCGTGAGCCAGAATCACCGCAGCAGCCTGTCCCAGACCTCAACCCCAAGCCCCCCAAAACCCACTGGAATATTTCAGACAAGTGCAAATAGTTCTTTTGAACCAGTGAAATCCCACTTAGTTGGAGTAAAACTCGTCGAGGCCGATCGCGCCAACGTGGTGGGTGAGGTGAGAGGGACCATTGCCCACCAGAAGCAGCGCAGACCCGCTGCTGCCCCACCCGACACTTCCCCCGGCAACCTGGAGCAGCCACCGGACAACATGGAGACCCTGTTCACACTCCAGGCCTGCTCTCCGCCCTTTTCCATACCTGTGGAGCCCGGGTACGGGCTCGTACATGCTGGGGGGCCGCCCTTGGAAACTGTGCCCCTGGCAGCTGAGAAAAGGCCTTTGGCCAGAGCCCAGGGAGCCGTGAAGTGTGAGAGCCCAGTGACAACGTTGTGGGCACAGAACGAGTTGCCAGATTTTGGAGGCAACGTCCTTCTAGCCCCAGCTGCTCCTGCGTTGCACGTGCCTGTGAAACCACAGCCATCCGAAGTGATCCAGCCGCCAGATGAGGGCGCGTCCGCTCTGCAGTCCCAGCAGCCAGGCTCTGGCCTCCCTCTGCACAGTGGGGACAGCATTGGTGCTTCTGAGAACCTCGAGAACCCTCCCAAGATGGGAGAAGAGGAGGCCCTCCCGTCACAGGTGACAAAAGACGCTCAGGAACAGCGTGGCCCAGAGAGAGCCCAGCAGGAGCCAGCACCACCTCCCCCACAAGGGCCCAAAGCAACATGTACAGATCCTTCAAACCCAGGAGGTCCACCCGTGCAGGGACAGCCCCAGAACTCGGTCCCACCACCCACAAGCCCAGCTCCAGCTGACGCAGGTCAGCCACTGCCGCCTCGGCCACCTCGGTCTTCCAGCGCGTCGGTCGTGTCTACCAGCTCGAGCCAGGCAGCCGTGCGGTCAGACCAGCACTGGCTGCAGCCGCCTCCTCCAGACCTGGCATCTTACTACTATTACAGACCCTTGTATGATGGCTACCAGTCCCATTACCCCTCGCCATACCCACCGGAGCCTGGCACGGCCCCCCTCTATTATCAGGACGTCTATGGCCTGTACGAGCCCAGGTACAGGCCCTATGACAGTGCGGCGTCTGCCTATGCTGAGAGCTACCGCTATTCCGAGCCTGAGCGACCCAGCTCCCGAGCAAGTCACTGCTCAGACCGGCCGCCTGCCAGGCAAAGGTACCCTGAAGGTTACTACAGTTCCAGAAGTGGGTGGAGCAGCCAGAGCGACCACTATGCGGATTATTACCCCGGCCAGTACGATTACGCAGACCCAGGTCACTGGGACCAGTACCACTATGGTTCCAGATTCAGGGACCCCCGCGCCTGTGACCGGAGGCATTGGTATGATGCTGAGTACGACGCGTGCAGGAAGGACAGCTGTGCGTACGGTGACAGGCCCGAGAGGTACGACGACCCCTGGAGGTACGACCCTCGCTTCACCGGCAGTTTTGACGATGACCCCGAGCCCCACAGGGACCCGTACGGGGAAGAGGCGGACAGGCGCAGCGTGCACAGCGAGCGCTCGGCCCAGAGCCTGCGCAGCAGCTTCAGCTCCCACTCACGTCAGAGTCAGATTTACAGAAATCACGGCGTGACTGCTGCTCCCTATGAGGCCCCACATCCCCCAGGCTCCTTGCCTGGAGATTACGCCTACGGGGCCTATGGCAGCAATTTTGGCAGTGCCCAGGGCTTCCCAGAGTACGGCTACCCTGCCGAAGCTGGCTGGCCCTCCACGGAGCAAGCTCCGTCAAGACCAACTTCTCCTGAGAAGTTCTCAGTGCCTCACGTCTGTGCCAGGTTCGGGCCTGGGGGTCAGCTCATTAAAGTGATTCCGAACCTGCCTTCGGAAGGACAGCCGGCGCTGGTGGAGATGCACAGCATGGAGACTTTGCTGCAGCACACGCCGGAGCAGGAGGAGCTGCGCTCGTTCCCAGGACCGCTCGGCAAAGATGACACCCATAAAGTGGATGTTATTAATTTTGCACAGAACAAAGCTACAAAATGTTTGCAGAACGAAAATTTAATTGACAAAGAGTCTGCAAGTCTCCTTTGGAATTTCATTGTTCTCTTGTGCAGACAGAATGGGACCGTGGTGGGAACAGACCTCGCAGAGCTTTTGTTACGAGACCACAAAACCGCGTGGCTTCCTGGGAAGTCACCCAACGAGGCCAACCTGATTGATTTTACTAACGAGGCTGTGGAGCAAGTGGAGGAAGAGGAGTCCGGGGAAGCCCAGCTCTCATTTCTGACTGACAGCCAAGCAGCTAGCAGCAGTGCTCTTGAAAAGGAGACGGAGAGGTTCCGGGAGCTGCTGCTGTACGGCCGCAAGAAGGATGCTTTAGAGTCTGCGATGAAAAACGCCTTATGGGGTCATGCTCTGTTACTTGCAAGTAAGATGGACAGCCGGACACACGCCCGCGTCATGACCAGGTTCGCCAACAGTCTTCCGATCAACGACCCTTTGCAGACAGTGTACCAGCTGATGTCGGGGCGGATGCCTGCTGCGTCCACGTGTTGCGGAGATGAGAAGTGGGGAGATTGGAGGCCACATCTTGCTATGGTTTTGTCCAACCTGAGCAGCAACGTGGATGTGGAGTCCAGGGCAATGGCCACCATGGGTGACACTCTGGCTTCGAAAGGTCTCCTAGATGCTGCGCACTTCTGCTACCTCATGGCCCAGGTCGGACTGGGGGTTTATACAAAGAAAACCACAAAACTTGTCTTAATTGGATCAAACCACAGTTTGCCGTTTTTAAAGTTTGCCACCAATGAAGCTATTCAGAGGACAGAAGCCTACGAGTATGCCCAGTCTCTCGGGGCACAGACCTGCTCCTTCCCCAGTTTCCAGGTGTTCAAGTTCATCTACTCCTGCCGCCTGGCCGAAATGGGGCTGGCCACGCAGGCCTTCCACTACTGCGAGGTGATTGCCAAGAGCATCCTGCTGCAGCCCCACAAGTACTCGCCCGTGCTCATCAGCCAGCTGGTGCAGATCGCGTCCCAGCTGCGCCTCTTCGACCCGCAGCTGAGAGAGAAGCCGGAGGAGGAGGCCTTTGTGGAGCCTGCCTGGTTGGTCCAGCTGCAGAGTGTGGACAAGCAGGTCAAGGAGGGCGCCGCGGTGTGGAGTCGGGGCGGGACCTTCCCCCAGCGCTGTCCCAGCACCCCGAGCTCAGAGGCGGGTCAGTATGACGGGCCAGCACTCTCCCAGCCGGGGGGCCCGGGCACCGGCAATCCGCTGCTGGCACCGCCTGTGCCCAGCGCTGAGCACTTTGGCCAGGGGGTGCGGCTGCTGCCTTCAGCTCCGCCGACGCTCCCCGACAGCCATCCGGCCCTGCCCGCCAGGGTGCCCTTGTTCCCGGTGCCCTCGCCCCCGGGCCCTGTTGAGCTGGGGCCTGGCTGTGGACCCTCGGGGGCTGCCCTCGGCTTTCCGGAGCCCTCTGGGCCTGACCCCGTGGCTCCGTACGCGGCTCCTGGCCTGCCACCTGGCGCACCATCTCCGCAAGAAAGTGAGCACGCGCCCCAGGAGGCCCGGAGCCAGGACCCAGGGGTGATGCCACCGGAGGTGCTTGGTAGAAACTCGCTTCTGGAGCTGAGAGAAGAGGGTCTTGGCGGAAAATTTGCTGATCTGGGCTCCTCCATGATGTCACAGGACTCCGAGGTCCCCCCGGGGTGGGAATGTGCTGGCTCCAGTGTTCTGCAGCCACCGACGTCCACTCCCGAAGCGAAGAGACCTGCACCAGCAGCCAGGAAAGAGGCCAAGGAGCCCAAGAAGAGTGGCGAGTCCTGGTTCTCTCGTTGGCTCCCTGGGAAGAAAAGGACGGAAGCTTATTTGCCAGACGACAAGAACAAATCGATCGTCTGGGATGAGAAGAAGAACCGATGGGTGGATGTGAACGAGCCAGAGGAGGAGAAGAAGGCTCCGCCCCCACCACCAACCTCGCTCCCCAAGGCTCCACTCACTGCACCCCCCGGTCCTGGAGGGCCCCCGAGGGCCTCTGTGAACATGTTTTCTAGGAAAGCAGCTGGAGCCAGAGCACGCTACGTGGATGTTTTCAACCCGGGGGGGCCCCAGCGGAGTGAGCCGGCTCTCGCTCCAGCAGAGTTCTTTGCTCCTCTTGCCCCGCTCCCGATTCCTGCTCACTTGTTCGGACCAAACACAGACGCAGAGGAAGCTCCGCCTGCAGAGGGGGCTGGCAGGGAAGGGCAGGCGCCCGTGGGGGGTCCGGCCAACCCAGAGCCGGCCTCGGAGCCCCAGGTGTTCAGCTCGGCGGTGGCGCTCCCTGGCCCTGAGCTCCCACCCGCCCGCGAGGACGGCTCCCAGGGCGGAGAGCTGTCGCGCTGTAGCTCAGTGAGCTCGTTATCACGCGAAGTAAGCCGGCACTTTTATCAGGTACCTGTGGCCGGCGGCTCTCACCGGACGCGAGTTGAACTGGGTCGCCTTTGTGTTCCTTCTGAGAGCGCTGTGCTGGCTGGCCGTCGTGCCCTTGTCACTCACGCGGCCCGCTGCCTCCCCGTCCCCCTCACGCCAGAGGATGCAGTGTTCCTTTCTCCCAGGGTCCTCGGGGGGTCGGGAGCCGTCCACGTGCACTGATGCGCACGTGGACCCCAAAAGGTTCCTAGTGAACGAATGCAGTTTGTAATTGTGTTCTTTCCAGATTGGTTTGTCCACACGGCAGCCGTGGGCGTAGCCTCACCGTGTGTGAGTGGGCTTCAGAAGCCCGCCAGGGGCAGGAGGGACTTGTGTTCTCTGACCGAGCGCGAGACGGCGTCGCGTAGGCCCGGCAGAGAGCGGCGGGCGGCTGTCCTTTGGCCAGTCTGGGCGGGAGAAAAAGGAATGCGTCATCTTTTATGTGTATCGTGGCACAGCGTTTCCGTTGGCTCAGTAGAAGGCTTTACGTGACCTTTTTATTTGCGTACTAAAACGCTGGATTTTGTAGCTGGATACTGGAGTCTGAAGTAATCAAAAATGTCTACTAACTGCTTCAAGCCGACGCTAACGGGCCGTCTTGGTGCCGTGCACTCCGCGTTCCTGCATGTTCTGGTTTTAAGGCATTTCTCTCTGCATGCTGCTTCATGTTTTCCCATTTTCCTGTGAACCTTGGCGTAATTAAATCCAGTGTTGCGAGAAGTGTCTGCCAGCTGCTTCCGTGGCTTACTTAGAAGCGCTGTAAACGGTTCCCGGAGACCAGTGTCTGTTCACAAGGGGAGCAAAGCGCTGGGATGGCGCTGTGTTGACGCGTGCTCTCTGTGGT
->XM_012078672.1 PREDICTED: Cercocebus atys galectin-7 (LOC105594508), transcript variant X1, mRNA 
-GTTGCCCTGTCTGGCACTATCGCTGTGGTTGTAGCCGCTGTTGCTTTAGAGACATAGAAGCAGGGATTTCAGCGCAGACATTTCCAGTCCAGGCAGGAGGTTCTTAGCTGGAGAGAAGGGTCTAGAGTTCCCGCTGGGCTTGGCTTCTCAGGACCCAACATGTCTGTGTATAAAATAAGCATGAGACACTCTCCGTGCGCCAGGCAGTGGGAAGGCAGGGCTGGAGGGGCGGTGGCACGAGGAGCCTTCTCTGCTAACGTCCCCCACAAGTCCTTGCTGCCCGAGGGCATCCGCCCTGGCACGGTGCTGAGAATTCGTGGCTTGGTTCCTCCCAATGCCGGCAGGTTCCACGTAAACCTGCTTTGCGGGGAGGAGCAGGACTCCGATGCCGCCCTGCATTTCAACCCCCGGCTGGACACGTCAGAGGTGGTCTTCAACAGCAAGGAGCAAGGCTCCTGGGGCCGCGAGGAGCGCGGGCCTGGCGTTCCTTTCCAGCGCGGGCAGCCCTTCGAGGTGCTCATCATCGCGTCGGACGACGGCTTCAAGGCCGTGGTTGGGGACGCCCAGTACCACCACTTCCGCCACCGCCTGCCGCTGGCGCGCGTGCGCCTGGTGGAGGTGGGCGGGGACGTGCAGCTGGACTCCGTGAAGATCTTCTGAGCAGAAGCCCAGGCGGGCCCGGGGCCTTGGGTGGCAAATAAAGCGTTATCCCGCAGCG
->EU356148.1 Uncultured bacterium clone 053.F4 16S ribosomal RNA gene, partial sequence 
-GAAGGGTGCAAGCGTTACTCGGAATTACTGGGCGTAAAGCGTGCATAGGTGGTGAGTTAAGTCTGTCGTGAAAGCCCCGGGCTCAACCTGGGAATGGCGATGGATACTGGCTCGCTAGAGTGCGGTAGAGGGTGGTGGAATTCCCGGTGTAGCAGTGAAATGCGTAGAGATCGGGAGGAACATCAGTTGCGAAGGCGGCCACCTGGACCAGCACTGACACTGAGGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGCGAACTGGACGTTGGGAGCAACTAGGCTCTCAGTGTCGAAGCTAACGCGTTAAGTTCGCCGCCTGGGGAGTACGGTCGCAAGACTG
->XM_036526509.1 PREDICTED: Megalops cyprinoides Janus kinase and microtubule interacting protein 3 (jakmip3), transcript variant X3, mRNA 
-AATGGTAAAATGCCTGTGTGTGAGGAGACGCGCAGACGGATTCTTTTTAGGATGTGCGCTTTAGCCCACAGCAAATGGTTCTTCACCGGATGCTAGGGGAGCTACACAGCTAAAGCAAGCAGACAGCATTCAGCCTAACTGGATCATGGCTTTAAGGTGGGAGAGAAGATGTAGGTGAGGATTCGCAGGGGGGAAGAGAAGCCTGACACCTCCCATCCTCAGGTTCTTCCTGTGGGGGCGGGCCGGCCCGAGCCGGGATCAGTGCCTCACCATGTCCAAGAGGGGGTCCGGCGGCCGAGCCAAGGGGGAGCGGCCCGATGCTCTAGCCGCCCTGCAGGCGGCGAATGAGGAGCTGAGGGCCAAACTCACAGACATCCAAATCGAATTGCAGCAAGAGAAGACTAAGGTCAGCAAGTTAGAGCGGGAGAAGTCCCAGGAGGTGAGGCAGGAGCAGCACAAGTCGACGGTGGTGGTGACGGAGCTGAAGGCCAAGCTGCACGAGGAGAAGGTGAAGGCCCTGCACTGCGTGCGTGAGACGCTGCTGCGGCAGCACGAGTCCGAGCTGCTGCGGGTCATCAAGATCAAGGACAACGAGATCCAGCGGCTGCAGGCGCTGGTCAACGCCCTCCGCGACGGCTCCACCGACAAGGTCAAGACGGCGCTCTTCGCCGAGGCCAAGGAGGAGGCCAAGCGCGGGTTCGAGAGCGAGAAGAGCAAGATGCAGCAGGAGATCTCCGAGCTGAAGGGCGTCAAGCGGCAGATGGAGGAGGCGCTGACTCTGGCCGTGCAGGCCGACAAGATCAAGGCGGCCGAGATCCGCAGCGTCTACCACCTGCACCAGGAGGAGATCACCCGAATCAAGAGGGAGTGCGAGAGGGAGATCCGCAGACTGATGGATGAGATTAAGGTAAAAGACAGAGCAGTCTGCCTGCTGGAAAAGGAGCTGGGCGTCCAAGCAGGGCACACTCAGAGGCTCCAGCTCCAAAAAGAGGCTCTAGATGAGCAGCTTGTCCAGTTCAGGGAGGCTGAGCGACATCTGGCCAGCCCCAAACGAGAGGCCCCTTATGCAAGTGGTGCAGGAGACGCCTCTGATCATTCAGGAAGCCCTGAACAGCAGCTGGACGAAAAGGACGCGCGGCGCTTCCAACTTAAAATCGCTGAACTGAGCGCCATCATCCGCAAACTGGAGGACCGCAACGCGCTTCTTTCCGAGGAACGCAACGAGCTGCTGAAGCGTCTCCGTGAGGCCGAGAGTCAGTACAAACCTCTGCTGGACAAGAACAAGCGTCTGAGCCGTAAAAACGAGGAGCTGGCCCATGCCTTCAGACGCATGGAGAACAAGCTGAGATTCGTCACCCAGGAGAACATCGAAATGAGAGAGAAGGCGGGAAGCATTCGCCGGCCCAGCTCCCTGAACGACCTGGACCAAACTCAAGAGGAGAGAGAGATCGAGTTCCTCAGGCTGCAGGTGCTCGAACAGCAGAACATCATTGACGATCTGTCAAAGGCGCTTGAGACAGCTGGATATGTGAAGAGTGTAATAGAGCGGGACATGTTGCTGAGGTACCGGCGGCAGAGAAAGAGAGTCATCAAGCCCTGTAAGCCGGTTGTGGAGACGTTCTTCGGGTATGACGAAGAGGCGTCTTTGGATTCAGACGGGTCCTCCATATCCTACCACACGGACAGAACACCCTGCACGCCGGACGACGACCTAGAAGATGGCCTGATCAAAGAGGAGACGGAGCTGAGGTTTCGTCAGCTGACCATGGAATACCAGGCTCTCCAGCGCGCCTACGCACTCCTACAGGAACAAGTCGGGGGGACGTTTGATGCAGAGAGAGAAGTAAAGACAAGAGAACAACTACAGGCAGAACTCATCCGGTACCAAACAAGAATAGAAGACCTCGAGTGCGCTTTGACCCAGCAAGGCCTGGACGTGAAGTGGATCGAGGAGAAGCAGGCCTTGTATCGCCGAAACCAGGAACTTGTGGAAAAGATCAAACAGATGGAGATGGAAGAATCCCGCCTGAAACATGACATTCAGGACGTCAAAGACCAAAACGAGCTTTTAGAATTCCGTATACTAGAACTAGAAGAGCGGGAAAGGAGGTCCCCAGCCGTCAACTTCCACAACATCCAATTCACGGAGGGCATGAGCCCCCTGCAGGTATACTGTGAGGCAGAGGGCGTCACGGACATCATCATCACCGAGCTCATGAAAAAACTGGATATTCTGGGGGATAACGCCAATCTCACCAACGAGGAGCAGGTGGTTGTCATTCACGCGCGGACCGTTTTAACTTTAGCAGAAAAGTGGCTGGAGCAAATAGAGGTCACCAAATCAGCTTTACAGCAGAAAATGCTGGACATTGAGAACGAGAAGGACCTGTTCAGTAAACAGAAGGGGTATTTGGATGAAGAGCTGGACTATAGGAAACAGTCAATGGATCAAGCACATAAGAGGATCCTGGAGCTGGAGGCCATGCTGTTCGACGCGCTGCGGCAGGAGGCCGGGGCCAAGATGTCGGAGCTGCTGTCCGAGGAGGAGCGGGAGACGCTGCGGCGGGCCGTGGAGCAGTGGAAGCGGCAGGTGATGAGCGAGCTGCGAGAGAGGGACGCCCAGATCCTGCGGGAGAGGATGGAGCTGGTCCATCATGCACAGCAGGTTACATCACTGAGATGGCAATCAAGCGGACACCATTGCTTGGAGGGAAAAATGAACACATTTTTGTTACACAGTGCAGTTACACAAATGTTAATGTATTGCAACCTCCTTGTTAGGTTACAAGTTATATGCTGTTTCCCAGCTGAAATGTGTTCAAATATTTACTCACTCTGAACTGAATTCAATAAGGTAGCTGCAAATCACCACCCCCTAGACTGAGATAGAGTGTAGAGCACTCGTGATATATTTGCTGATATTTATGACTCATTTCAGTAGTA
->XM_041210960.1 PREDICTED: Carcharodon carcharias tbl1x receptor 1a (tbl1xr1a), transcript variant X1, mRNA 
-GGGGGGGAAGGGAAGGAACAACAAGAGGAGGCCGCCCAGCAGCCAGGCGGAGGAGGCCAAGTGTGTGCAGATCCCGGTTCTGCAGTGTTGTTAAGTACTGACATCATTACACCCTTTGCTGGACCTGAGATTTCGCACAGTCAGTGTTTGAAGCTACTATACCACATGCCCAGTGATCTAAGGTGACGTGATACAACCATCCTTAATTGGTCCTGAGGGTTCAAAATGTGTTAATAGCCTATTCATGAAAGGCTTACCCTGTAATGACCTCATGGTTTAAGTGGGACTGAAGATGAGTATTAGCAGTGATGAGGTCAACTTTCTGGTATATAGATATTTACAGGAGTCTGGTTTTTCCCATTCAGCGTTCACATTTGGTATAGAGAGTCACATCAGTCAGTCCAATATTAATGGTGCCCTGGTGCCACCAGCAGCTCTCATCTCGATCATACAGAAAGGTTTGCAGTATGTGGAGGCTGAAGTCAGTATCAATGAGGATGGCACACTATTTGATGGGAGGCCCATTGAGTCCCTTTCTTTAATTGACGCTGTAATGCCTGACGTGGTGCAGACAAGACAACAAGCTTATAGAGACAAGTTGCAGCAACAACAAGCAGCAGCAGCTGCTGCTGCTGCTGCAGTTAGTCAACAAGGGTCTACAAAGAATGGGGAGAATACTGCAAATGGAGAGGAGAATGGCGGACACGCAGTTACGAATAATCATACAGATATGATGGAAGTTGATGTAGATGTGGATATTCCATCCAATAAAGCTATGGTATTGCGTGGCCATGAATCAGAGGTTTTCATATGTGCCTGGAATCCAGTCAGTGACCTCTTGGCATCTGGATCGGGAGACTCAACAGCACGGATATGGAATCTTAGTGAAAATAGTAGTGGTGGCCCCACCCAGCTAGTACTTAGACACTGCATAAGGGAAGGAGGACAAGATGTACCAAGCAACAAAGATGTTACATCTTTAGACTGGAATAGTGAAGGCACACTTCTAGCAACAGGTTCGTATGATGGATTTGCAAGAATATGGACAAAAGATGGTAACCTTGCTAGTACGTTGGGTCAACATAAAGGACCGATATTTGCATTAAAATGGAACAAGAAAGGAAATTTTATCCTTAGTGCAGGAGTGGACAAGACAACAATTATTTGGGACGCGCATACCGGAGAGGCCAAACAGCAGTTCCCTTTCCACTCTGCTCCAGCACTAGATGTTGACTGGCAAAGCAACAACACGTTTGCCTCTTGCAGCACAGACATGTGCATCCATGTGTGTAAACTAGGTGCAGATAGGCCCATCAAGACATTCCAGGGACATACGAACGAAGTGAATGCAATCAAGTGGGATCCAACTGGGAATCTACTCGCATCTTGTTCCGATGACATGACCCTAAAGATCTGGAGCATGAAACAAGATACATGTGTTCATGATTTACAAGCGCACAACAAAGAAATCTATACCATCAAGTGGAGTCCAACAGGACCTGGTACTAACAATCCAACCGCCAATCTTATGTTAGCAAGTGCATCATTTGATTCTACTGTACGACTATGGGATGTGGACCGAGGTATCTGTATCCACACTTTGACCAAACACCAGGAACCTGTATACAGTGTAGCGTTCAGCCCAGATGGCAGGTACCTGGCTAGCGGCTCTTTTGACAAGTGTGTTCACATCTGGAATACTCAGACAGGTGCTCTTGTCCATAGCTACAGGGGAACAGGAGGAATCTTTGAAGTGTGTTGGAATGCAGCTGGGGATAAAGTGGGTGCAAGTGCATCAGATGGTTCAGTTTGTGTGTTAGACCTCCGGAAATAGCGCTGCTAGCTGGAAGCCATGGACCGACAATGAATGTGTACATAGCCAAAACGACTGTCCCTGCCCCATGCACTGCTACAGTCTCACTTGAACCATGGCCAGTCCACTACAGCCAAAACAAGTCAGAATGCAAAACCCAGGACAACTGAGCCCTGATGTGAAGAGTACCCTGACTGCTTAATGCTGGAAGCTCCACCCACAAAGAAAAGTCAACCTTTCTTGAAGGTTTAAAACAACTTGAAATAAGACTTGACATGAGACCATATGTGTACCAAAATGGAAAGATAATATCAGAGGACAAAAATATCTTTTATTTTTTTGGTCCAGAGTCTATGTAGAATGAGTTATCTTGTCAGCAGTTCAGCAGATCTGTGTGCAGACATATCAGCTTCTTTCAATCAGCAGCAAATAGTTTGTTCCCTTGTTTTAAACATTGTTTTATCACTTTAGTTTACAGTTGCATGATGTAGGAGAGTGACTGTATCTTGTTTATCTTGTTTTTTTTCCTACTGACACTTAACACACAACTAGAAAAAAACTTTTTTATGGATACTATAAGCAAAATAACAGTGTATTTGGTATGTTTTTGGTACATTTTGTGGCTCAACAAACTAATATGTGGGGAAACATGAAACCGCTCCAAAATTCAACATAAAATTAGTTTCATTATACATCAGTCATAGGTAACAAGCTGTGGTTTACAGGTGATGTGGCTAAAATGTAGTAGTTTCTTAATGGGGACATGATTCTGCCGATTTATGAGAATTAAACAAATGGGCACAAAGAAAGAGAATCGATGCAGGGATGCATCCCATTGCTTTAAGACCATAGTTTGCATATGGTTGGATTGTGCACTATTGATAGAGCAGCTTATAGAATTTTGAAAGATAACTTTTCTGGACAGAGAATTATTACTGTTACTCTACTTATTCTTTGGTAGACCTACAGGCATAAATTTCACAGCAAGGTTCCAGTATTAAGGACTGATGTCTCGTAAGCAATGTTTTTAAAAACCTATCCAGTGCAATGAGATAAACCTCCCTCCCCCTCCCTCTGCCATTGGGCAGAAATCATGCAGGCATATGTTTTATGTTAATGCTAAGATAAGGGTTGACTTTGCTTTAATTTTCTTTCCTTGGTGCTCGTGTATTACACATGGGTTCATCTTGGCTCAGCCCTCTAAAGTACTTGCACTTGCTGTATTGTTCAGTAAAGTACAGGTAGTATAATTGCAATAGCTTTTTTTAGAATAAAAGTATATTCTATAAAGTATAGCATATCTGAGCTTTTAAACCTCAGGGGACCCTTCTTCAGATGATGAAGTGGTTAAACAAATATTTCTGCTACAAGATGCTCAATTACTTTTTCACACGAAGAAATGACGTTTGAGGTTTCAAATCCTTAGATTTAATGCATTGTAAAATGTTAGTCTAAAAAAGGTATTCTTCTATTTCCCATATCCCATGCAACAACAGATCAATGAAATGAAGTTACTGTTGCAAAGGCTTTATACCACCACTTCAAACTTGATCTGTTTTCCAACTCATTAAAAATGCAAGGTTAGTTGCTTTTTTGTTTAAATAGAAACATGAGTAAGAATAATTTCTGCACAAATGTTGGATTTTTTGTCCTTGGAGTAAAGTCTGTTGTTAATCTGAATCTAATCTAATCATTTAGAACTGATTATAGGTAACGTGGTATAATCAAATAGCTGCTATTCCAGATATTCCAGTGTCTGCATCACTGAAGTTGACCAACAAGTTCAGAACAGCTCCTAGATGTTCATTATGGGCTATTTGTCAAGTAGAGTAACAGTTATTAGGCAGCTTTATCACATTTCTAAGAAAAAAAACCATTGGTTATGTTATTTACTAGCCTTTTGTTAAATTGCGTCATATTAAGGTGATGAATGAGATTGGTTTTATCATTCTTCCAAGCTCTGCCCTTTGCAAGTTTGTTGCGAAGTCCAAGTTAAATTAAAAACCCTTGCATTCCCCTCCAATTAAAAAGGACTCATAAAGCATCTGCTACTATATGTTGACCTAAAGAACTAATGCTTGGAAAGGTGAGCCCTAGCCAGTTTTTAAATGAGCAGTTAAAACTTTTCATTTAAATCTTTTAAAAAGTATACATCGATGGCACAACATTTGAGAGCTCACAAATACAGTGGTAAATTTTTAAGAAGCAATTTTTTAAAAAATGAAAACAAGATATAAGTAGCTTTCCAACTGCTGTTTTTTGACCCTGCCAAGGGTAGAGGTGTAAGAGCAATTTTGATTACCTAATTTAATTATCTAACTTCACATTTTGGATTGGAAAATTAAAAAAAAGTTGGCAGTTACCTACACTGGACTTAAGTGACAGTCCAAAAATGGGGTAGCAGTAGAGCCTCTCACCTGAAGGTGAAGATTTATTTGAATGGGAATTTACAGCAGCCAGATATTGTATGGATGGCAACACTTACTTTTCAAAAATAGGTCTGTTCTTACCAATTGTTCTAAGGGCATCCATACTTTAATGATCTGAGGCTCTTATTCACATCTGCTAGAACTTTGGGAAACTCATAACAGCAAGATCATCACAATAAATTATACACACAACATTGTTTGAACTAACTAAAGTCAGACATTATTACACATAACACATTGAGCAAATGCATAACCATTTCCAATAATATGAATTAAAAGCTGCTTCCCTTGCTCAAGTCAATATTGATTGAAGACTCTGATAAAACTGTTGCTCATTTGTTCCATTGCAAGTGCTGTTTTAGGAAGGGCTGCAAATGAAACTAGATAGTTGAAGCAAGTGAAGTATTTAGGTTGGTGAAGACAGCATTAGGTGCATTCAGTGCTCAAGAATGAATAGCATAAAAGGATGATTTCAGGGGCTAGCATTACAGCTCTAGCACTGGATTTACATGTCTGCATCATTTCTACAGTTCTCACAAATTAAGATTTTAAAAATTGTGAACCTGTAAACCAGGCCATGAAAGTTTTTTTCTACTCTTTGAACTCTTTATTGTTCTGTTTTTATTTGTACCTGTTAAAAAGACTGATTTTTGATGTACCATACTGTCCTGGACCATGTAAATATCACCTGATAATGTATTTAGGTTCCACATTACATTAATAATTTTCCCTTTTCCACTCTCCCAACCCTCCTTCCACCACCTCACCTTACAAGTATCACCACCAAGGCACATCTTCTGTTGCAGCTTCCCTTTGCATCGTATTGATCTGACAACCATAATTTGCATCAGATCTGAAAGAGGTCCAGAATAAAATATATTTTGATATTA
->XR_005699604.1 PREDICTED: Hirundo rustica beta 3-glucosyltransferase (B3GLCT), transcript variant X7, misc_RNA 
-GGGGAGGATCATGATGGAGGAGGAACCTTGGGGAGCATGAAGGAGGGTCTCATGAAGCAGGATTTCTGGGGAGAGAATCACTGCTGTGAGCTTTTGCTGTAACTGTAATTTCTGAAGGTGCAGAAGATGAGACTGAACTACCAGTGCTGCAGAAGCCTGGAAAAAGTAATACAATTAGTAAAATAGGCAGAGAATTAAAAGGAATTGTATTTGTCATCCAGAGTCAAAGTAATTCTTTTCATTCCAAGAGAGCAGAAGATCTAAAAAGAGATATTTTGAAACAGGCTGTAGATCTTGGAAAGGAATTGCCTACAGTTCTACTTATTCATCAGATCGACAGGCATGAAGGTGCATGGACAATATTGCCGTTAATGACAGACTTCTCTGTTACCTATGGTAGGAACACCTCATGGATTTTCTTCTGTGAAGAAGATACAAGAATACAAGTAGTAAAACTGCTAGAAACACTCAGAAGATTTGACAAGTCTAAGGAGTGGTTTTTAGGTAAAGCATTATATGATGAAGAATCTACAATAATTCACCATTATGCCTTTGCTGAAAATCCTACAGTCTTTAAATTTCCAGATTTTGCTGCTGGTTGGGCACTTAGCATTCCACTTGTTAACAAGCTTGCAAAGAAGCTGAAGAGTGAACCACTCAAATCAGACTTCACAATAGATTTAAAGCATGAGATTGCCCTGTACATTTGGCAGAAAGGGGAAGGACCACATCTTACTCCAGTGCCTGAGTTCTGTACAGATGATGTGAATTTGTATAAGGTTGATCACTGTGCAACAACATTCAGTAATTTTCTGCCACTTTGTGGAGAGCCAGTGAATAAGGAAGATGTTTTTGTTGCTGTAAAAACGTGTCGAAAATTTCATGGTGACAGAACTTCCAGTGTTGTGCAATAGAGGATAATCTTACTCCAGATTTTGAAAGATTAATGGATGGCAGCTTCAGAGAGCTCTTTTTACCTGTACCAGTTGTAAAGCAGACTTGGGAGAGAGAAGCCGCCCTTATTGAATACTACAGTGATTATGCAGACATCTCCATTCCTACTATAGACTTAGGCATCCCTAACACTGACAGAGGTCACTGTGGCAAAACTTTTGCCATTTTGGAAAGGTTTTTGAATCATACTTCTGCCAGAACACCTTGGTTAGTTGTAGTGGATGATGACACACTGATAAGTATATTCAGACTCCGACAATTGCTCAGCTGCTATGACCCAAACGAACCAGTTTTCCTTGGAGAGCGTTACGGCTATGGCTTGGGAACAGGAGGATACAGCTATATCACTGGTGGAGGAGGGATGGTTTTCAGCAGAACAGCTGTTCAGAAACTACTTGCTAGCAAATGCCGGTGTTACAGCACGGATGCACCCGATGATATGGTCCTTGGGATGTGTTTCAGTGGCTTGGGAATCCCTATAACACACAGTCCACTTTTTCATCAGGCGAGGCCAATGGACTACCCAAAAGACTACCTTTCTCACCAAATTCCAATATCATTTCACAAGCATTGGAATATCGATCCAGTGAAGGTGTATTTCACATGGCTGGCACCAAACACAAAAGAGTCACATAACGACAAAAAAGTTGGATACAGCAGAGAGGATTTATAAGCAGTAGAAGAATGTAAGTGTTAATTACGATTTTACAGCTGAGAGACAGACACTACTGACAATTTTGTTTTCACATTGTTCCTCTGTTCATGACATAAAAAGACAGTGTTTTGTTCCTGTTGGTGGAATCCCTTCAGAGCAACGGAAGAAGGCACTTAATGACTTTTGGATTCTTTTCCTCTGCTTGGTTTCTTTTTAGAATGCTTTTGGGTTTTGTATACCAATGAACTTGACTCACATTTAAGAGTCTTGTACAACCTCACCTGTGTTCTGCTTTGGACTTGGTTCAAAAAGCATCGCTCTCTCAAAAGCTGAATTTATGCATTTGGGAGCTTAATACTGAATAAGTGTAGAACATCTATTAAACATCATCTCTCACTGACTTACAGAAAGTAGTTCTCTAAGAGGCTCTAGAACAGGTTCTTGATAAATCAGAGGACACTTGACTTTTTTTCCGCGTCCAGGAGCTAGATTGTCGGAAGGCTGTGCTCCTTTATGCTCATTTCAGATAGAAATACTGTAGTTTCCTGGAGTAGCAGGACCAGGCATGAAACCACTGTTGTACCTTTTAAGTTTGTTGGCATTTGTGTGGAATGTCGTGTACAAAATGGAAAAAAAGGTTAAGGACGGGGATTTCTTAGGTGGCCACGGGAGGTCACTGTGGCTCCTTCAGAAACCGGAGTCGGTGTACATCAATTTGGCAAATATAAAAGTGACTCTTAAGGATTTTGGAGAACTAACATTTCAGTATTTCTGATGTGTGCATTTCAATAGCATATGAATGCCAGCTTTAAAAAGTTTTGTAGTATCCCTAATTTGTATCATCAAAATAAGTAAATTGATGCCTACAGCATGTGAAGTGTGATTCTTATTTAAAACGTTCTTGAATTTTTTTTTAGTAATTCAGTTTTGTAAAAATGTTTGTACAAAACCTGGCTTTTAGTATGTTCTAAACTAATTTTTATATTGTAAAACTACTTCTTTTAAAATGATGTTGTATGGCACTTGTATGCTGTTATTTAACTTGGCTTGCTATATTGTAACCAAATACAGGGTCTTAAAGCCATACTGCTGAATTAATTTGTGTTTTGGTTTCTTTCAGTAGGTTAAAAATTGATTCCACTCCAAAGAAAAGCAATATTTCCTCTAGAGTTGAAGTAGGGGGAGCCACTGATTCCTGTCTCTGTAATTACCAAACTTGTATAAACATTTGTTTGCAAATGTAGCTTGTGGGTTTCTAAGCATTGAATAGCAAGCACATATTCATAATAGATTCAAATTCTGATTAATCAAGAGCAATCCATGTTATGTCTCTTTTCTTCCCACTACCAGTGCCTTAAACAGTAGACATTTTACTGATACCAGGACTATGTTCTCTGACACCATTGGTGAACTGTTAATTATGTTTACTGTTTAGAACTGTGAAAGCTGAATAAAAGCCTTCTTTAACCTGT
->XM_020777834.1 PREDICTED: Pogona vitticeps XK related 6 (XKR6), mRNA 
-ATCCGAACCATGTACCTGGGGATCCAGAGCCAGAGACAAAAGGAACACCAGCGGCGCTTTTACTGGGCTATGATGTACGAATATGCAGACGTCAACATGCTGCGTCTCTTGGAAACTTTCCTCGAGAGCGCCCCCCAATTGGTGCTACAGCTCTGCATAATGATCCAAAAGAACCGTGCAGAAACCTTACCTTGTGTGTCCTCTGTGGCCTCCCTGATGTCCCTGGCTTGGGTGCTAGCGTCCTATCACAAGCTCCTTCGGGACTCTAGGGATGACAAGAAGAGCATGAGCTACAGAGGGGCCCTTATCCATCTCTTCTGGCGCCTCTTCACCATCTCATCCAGAGTTATCTCTTTTGCCCTCTTTGCTTCCATCTTCCAGCTCTACTTTGGGATTTTTGTCGTGGTCCACTGGTGCGCCATGGCCTTCTGGATCATTCATGGCGGGACGGACTTCTGCATGTCCAAATGGGAGGAGATCCTCTTCAACATGGTGGTAGGGATCGTGTACATCTTCTGCTGGTTTAATGTCAAGGAAGGCAGGACCCGATACCGAATGTTTGCCTATTACACCGTAGTCTTGACAGAGAACGCGGCCTTGACTCTCCTCTGGTATTTTTACAGAGATCCCGACACCACTGACTCCTACGCTGTGCCAGCACTTTGTTGCGTCTTTCTTAGCTTCGCCGCCGGGATCGCGCTGATGCTCTTGTATTACGGCATCCTGCATCCCATGGGCCCGAGAGCTAAGATTTTTGCCAGCTCCTGTTGCGCCGAATTGCTCTGGGGCATACCTTTGCCCCCTGACGTTGAACCTATGGATCCTCAAACGCCCGGGTACAGGGCGGACCAAGTAACGCCCACCAGAGTGGTCACGGAGCAACAGGAGGAACTTACTGCTGACACTTGCTTGCCCGTTTTCCAAGTGAGGGCCATGGTGCCATCGACTCCGTTGGGGAGACCTTACCACCCAGAAGGCCCTCTCATTAAAATAGACATCCCAAGAAAGAGGTACCCGGCTTGGGATGCCCATTTTGTAGACAGGAGGTTGAGAAGGACTATAAACATTCTCCAGTACGTCACCCCCACTGCTGTAGGAATTAGATATAGAGACGGACCTCTCTTGTACGAATTGCTACAGTACGAATCTTCACTTTAAAAGCTCCTTTAAACACAAACCCACATACACAGGAAACAAACACACACACATACACACACACACACACACAAAACTCAACACACGGTCACAGGCAAACAAGCAGCAACAACAAAAAAATTAAGAGAGGGGATTTGGGGTGGGGGGTG
->XM_018564101.1 PREDICTED: Nanorana parkeri transmembrane protein 72 (TMEM72), mRNA 
-CTGGAGTCATGGAATGTACTGAGGAGGTGAGAACAGCAGCATTAACTGGATGTTTGTGGACAGAGCCTGTTGCTTCACGGTCACATACACTTTGGGATTCTTGTTTTCAAAACACTCAGAAGCACAGCTTTCCACCGCGTGAAAGCTTGTGATGTCTGTGATGCTGAAGGTGGTGTCAGTACAGTGTCATTAGCCAGTAGTTACAATGCAGTGCCAGGCAAGCTGGGTGGTATTAGAAGGCATCTGTAGATTCCTGGGGGTGTGTACAGCTGCAGTGCTAATTGGTGTTGGGATTGAAACTCTGCAAAAGGGACAATTTCCAAGTCTGGCCTATTATTTACTGTTTTCATCAGCAGCCGTGTCATTCTGTGAAGGTGTTTTCTTCATACACATGTTTCTCATGCACTGTATAAGATGGCAGTCAGAACCCCGTCTGTATGTATGCTTACGGAAAACAGCACGAATGGGAGGATTTCAGAAGTTCCTTGGGTATGGCATACTGTCAGTGGCCTGCTTCCTTCACCCAGTACTGGTCTGGCATGTCACAATTCCAGGAACCATGTTAATTGTTACTGGGATTGCCTATCTTTTTTTGAGTAAACGAAAGAAGACTAAGAGCAAGGATTGCGTTTTGCAGGCTGAATATTACACAGACCCATCTACCACAGCCATTGCTATGACCAGAGCTGGAGACACAGAGCAAACTTACACTTTCAATGACTCCCTGCGCCAGAAGAGAGAATCTCTACTCACCCATATGAGAAGCATCCTCAAAGTAAAGAAGGACCGCCAACCATCTAAGAAAGACCAAGGTCGCATGGATGCTTCTATAGACTTATGTGCTAAAAAGAAACAGGTTCACTTTGAGGAAAAGGTTATTAAAATCATCCCCTTGGAGGAAGGCATTCTTGAAGACCAGGACAGTGAGTTGGAGGTGACAATTTCAGATACTATTCCCATCATACCCAGTGAGCCCAAACAGGTTTTGAACACCACACCCATGACATCTGGCATTTTTTAAAGG
->XM_025751866.1 PREDICTED: Arachis hypogaea uncharacterized LOC112701064 (LOC112701064), mRNA 
-ATGGCAGATTTTCTAGTAGAAGTAACGGGGAATCCGACCGAAGAAACAAGCACACGGTGGAAGCTCCACGTGGACGGAGCCTCCAACCAGACGTCCGGGGGTGCCGGGATCATCCTGGAAAGCCCGGTTGGAGTCGTATACGAGCAGTCGATCAGGTTCAAATTCCCCATTTCAAACAACCAGGCAGAATATGAAACCCTTATAGGGGGCTTAACCATAGCAGCGGAAGTCGGAGCAACAAGGCTGAAAATATGCAGCGATTCCCAGGTCGTCACCTCCCAGGTCACGGTCCACCACGTGCCAAGAGAAAGGAACACACGGGCAGACCTTCTATCAAAATTGGCCAGCACTAAACCGGGAGAAGGCAACCGATCTCTCATCCAAGGTATGATGAAGGAGCCGGCGGTCACCTTGCATTTGTCAAGGCTGGGCTCTTCATGGCTAGACCCCATCACCAGCTTCCTAGAAAATGGCAAACTCCCTGACAATGAAAAGGACTCCGTGAAACTGAGAAGGGAAGCAGCTAAATATGCAGTCATTCAAGGACAGCTATTCAAGAAAGGGTTCAACCAGCCCCTACTGAAGTGCTTACACCCCGACCAAACGGACTACGTCCTCAGGGAAGTCCATGAAGGCTGCTGCGGACACCACATAGGAGGCAAAGCCCTAGCAAGAAAATTAATTCGAGCCGGATACTATTGGCCGTCAATGATGGCAGACTCCAAGGAGTTCGTCAAAAAATGTGTCAAGTGTCAAGAGAACGCCAATTTCCACAGGGCGCCGGCCTCCGAGTTAAGCCTGTTAACGTCCTCCCGACCATTCTCCCAATGGGGAGTCAATCTCTTGGGGCCCTTCCCAGTGATAACGCGATTCGCGATTCCAGAAGTTGTCATCTCGGACAACGGCACACAGTTTACCGACAAGAAGTTCACGGAATTCCTCACCGGCCTAGGCATAAGACAGAAGTTCTCCTCGGTAGAGCACCCCCAAACAAACGGACAAGTGGAGTCCGCGAACAAGATTATCCTGATAGGGCTCAAGAAGCGATTGGATAATAAAAAGGGTGCTTGGGCCGACGAGCTAGCCTCGGTGCTCTGGTCTTATCGAACAACTGAACAGTCCTCCACCAAGGAAATTCCTTTCCGACTAACATACGGATTAGACGCGGTAATACCCGTGGAAATTGGGGAACCGAGCCCCCGGCTACTTTTGAAAGGAGTAGAGGAAGCCGTGGAGAAGGACCTAATAGATGAAGCCAGAGAAATGGCCCATTTGACGGAGACATCGCTAAAACAAAGAATGGCCCTACGCTACAACACCAAAGTGCTCAAAATAGAATTCGAGCCGAACGATCTCGTCCTAAGGCGTAACGACATCGGCCCACCGACCCCAGGAACAGGCAAGATGGCGGCAAACTGGGAAGGCCCCTATAGAATAAAAAAAGTGATGGGCAAAGGCGCTTTTAAGTTAGAAAGGCTCGATGGCAAGGAAGTCCCAAGAACATGGAACGCGAACAACTTGAGAAGATTCTACTCCTAG
->EU583709.1 Uncultured Tulasnellaceae isolate S2.12h internal transcribed spacer 1, partial sequence; 5.8S ribosomal RNA gene, complete sequence; and internal transcribed spacer 2, partial sequence 
-AACGTCTTGTAATAAATAACGTACAACTATCAACAACGGATCTCTTGGCATCCCACTCGATGAAGGACGCAGCGAATTGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACCTTGCACCTTTTGGTATTCCGAAAGGTATGCCCGGTTGAGTATTATGAACATCTCAATCCTCTGGCTTCTGATCGCAAAGGTCGCACGTTCGGCGAAGTCGTCTGTCGGGACGACGGTAGCTGAAGTGCGACTTGGAAGCCTGTTGGACTTGGACTTGAGCGACACGTCGGTCCTCCACGATCGACCCGCTTGAAATGTATTAGCTGGCGACCCGCCTTACGGTTCCACTCGGCGTAGTAAGTTCTATTCGTCGAGGACGCCTCTTTCGAGGTGGCCGAAAAGCGCGCGATTGAAGCCGCTTCCAGTCGTCTTTGGATGCTTTGAATCTTTAATCTCCACCC
->KC809930.1 Bacillus sp. EK-CH-I9 16S ribosomal RNA gene, partial sequence 
-AGCGGACAGATGGGAGCTTGCTCCCTGAAGTCAGCGGCGGACGGGTGAGTAACACGTGGGCAACCTGCCTGTAAGACTGGGATAACTCCGGGAAACCGGGGCTAATACCGGATAATTCTTTCCCTCACATGAGGGAAAGCTGAAAGATGGTTTCGGCTATCACTTACAGATGGGCCCGCGGCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGANACNCGGCCCANACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCANCGCCGCGNGAGTGATGAAGGTTTTCGGATCGTAAAACTCTGTTGTTAGGGAAGAACAAGTACCGGAGTAACTGCCGGTACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCANCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTTCCTTAAGTCTGATGTGAAAGCCCCCGGCTCANCCGGGGAGGGTCATTGGAAACTGGGGAACTTGAGTGCAGAANAGAAGAGTGGAATTCCACG
->XM_041467909.1 PREDICTED: Pyrgilauda ruficollis lysosomal associated membrane protein 3 (LAMP3), mRNA 
-CTCGGCTCGCTCCGCAGCGGCTCCCGGGGAGAAGCAGAGCCCGCAGCCCGCTGGCCATGGGGAGGAGCGCACGGCAGCTCATCTCGCTGACCCTCGCCTGTGCATTTTCCTCCTGCTTTGCTGAAGTGGCCCTGGGGGTCGAACTGTCTCCAGAAACCACATCCTTCCACCAAATGGCTACTTCTGCTCAGCCACTTTCCCTTTATCATTCTTCACCCCATCAAAGCACTGCAGTTCATTTTACCAGCACAGGCTCTCTTCAAACAACACCCATGGGCCACAGAACAGCTGAGCAGACAACGGAGCAGCTCAAGACAACATCAGCCGCAGGCCAGCACACGGCAGCCCAGGCAGGAGCAGGCACTGTACCCACAGCCCCTGCAGACAGCCCCAGCCCCGGCCGGGCCACCACCCCGGCGATGCCCTCGCTTACAGCGGTGGTCAAGAACACAACCACTGCCCCTGTGTCCTCCACCAGGCATGGCAAGGGACCACGTGTGACCACAGGAACTGTGGCAGTGGCCACCAACACCTCCCTGAAGCACGAGACAGCGAGTACCCCGGGGGCAGCTGCCACCTCCGCCTCGGCAGCCCCCAGCACGCCGAGGGCCGGGCCCAGCACGCGGTCACGGAGACAAACAGCAGCCACTGGTGCTCCAACAGCCACGGCCGTGACCAACACAACAGGCACCCATGCAGGGACACAAACAGCCCCCACATCCCCTGCCAGCACAGTGAGACCCCGTCCCACCCCACAGCCCTCTGCCATCCCCACAGGCACCTACACCGTTTCTGATGGCAACAGGACCTGCGTCAAAGCCGTCATGGGTCTGCAGCTGATGGCCCGAAATACCCAACAGGAGCAGATGGAATATGTGACTGTTAACCCAAATGCGACAAAGATATCTGGAAGCTGTGGGATGGTGCAGTCTGAGCTGAACTTAACTTTTAGTGGAGGATTTGTAAACATCAACTTTGTAAAGCAAGCTCCAAGTTACTCTGTGACTAAAATTGAGAGCAGAATACTGTTATCTTCTGAAGGTATGCTTTACTATGCAGCCCTAAATGAGAAGCTGTTCACAACAAAGCTGGGGAATTCCTTTAAGTGTGCCAGCAGGCAAACCTTCCCCTTGGAGAAGAACTTCCAGATCCTCTTTGTTCATATGCAGCTGCAGGCGTTTGACATTGTGGGTAACCAGTTTGGAAAAGAAGAAGAATGTTTTCTTGATAGAAACGGCAGAGTAGCTCCCATTGCAGTGTGCCTGTGTATCCTGGGATTGTTTGTCATTGTGTTTGCCACCTTCCTGATCTCCAGGAGGAAGCCACAGAGAGGATATGAACGCATCTGAGGTGCCCCTATGCTTCCAAGTGTGTGCAGCAAGCAGAGAAGTCACAGGAGTTTTTGCTTCTGCCTGGCAATCTCTCTGCCCTGAAGCCACATTTTTAAGTGAGATGACACTGTGTGTTTACAGCTAATGAATGTTTCTGGAAGGAGTTCTTTTAAGGTGGGAAGGAGAGAACTCACACCTTCTGCTTTAAGCTATTCTTAGCATCTAATTTAGATGTAGTCCAGAATGAGGAGCCTAAATTCTCTCTGTTGTCAACAAAGGAGGTCATTCAGATCACTTAAGCCAGATTCCTAAAAATAGCTTAAAGCAAGCAGTATCACTATCTCCCAGAAAATGCATCAGGTTTGTTAATGATGGTGTTCAGATTTATCAAAAGACATAAGTCTGACCTTCAGGTGAAAAAACCTCAGGCCCACAGCTACAGACAACCCTGCTAAGTGAGAGCTCACTGAAAGCTTTT
->XM_023176141.1 PREDICTED: Drosophila willistoni uncharacterized LOC6643128 (LOC6643128), transcript variant X4, mRNA 
-TTCATTCACTATGTCCAAGGGACTTTTGGGCCTTTGGCTTCTGCTGGCAGTGCTAAATAGGCTACAGTGTTCGAATGCTTATCAATCTGGTGGCAGCTATTATGATGCTGGCCAGTCCGGGTTATCAGCATCAACGCAATCATCTTATGGCGGCAGTGCCAGAATTCAAGAGCAGCCCATCTATGAGCGCGAATCGGCTTGTCCAGCGGGTTTTACGGGTCTAAAGCCATATCCTCATGATTGCCATCGATTCGTCAATTGTTTCAATGGACGTCCAACCATTCAGACCTGTGCACCGGGCACTCTATTCGACGCCAGAAACTTGCAATGTGATTCACCCAGCAAGGTATCCTGTAACGGAGACATTGCTGAAGCAGCTGCAGCAGCAGTGAATTCCAATCAATCCAGTCGTTCGGCTCGTTTGAGACAAATCAACACTGAACCCAAGTGTCCAGCTGGTGTTAATGGATTGCATCCGCATCCTTTTGATTGCACCAAGTTCCTCAATTGTGCCAATGGTCAAACTTTTGTGCAGAGTTGCGGACCAGGCACAGCATTTAGTGCATCTCTTCTGATCTGTGACTACAAGAACAAGGTGGATTGTGGAGCTGGTATCAGTGGTGGTGTTGCTGCATCAGAGGCCTACGAGAGTCGTCAATCGAAAGCCTACAATGAAGGCAGGGGGGAAAGTGCCGGTGGTAATCGTTGGAGCTCCATGAATATGCAGCGTCCAGCTGGCATTGGCTTCACAAATTACCATCAGCAGCAGCAGCAGCAGCAGGTTGGACAAGTGAATCAGCAATATGGCGGCGAAGCAGGAGGCTGGTCTGGTCATGGCACCTCTTTTACCCATCGTATACCCACACAGAGTGTGCTCTATGTGGAAGGATCCCTACAGCCGAATCGTAATTATCCCAGTTATAAGACTCCATTGGCACCCATGGCTCCTGCCTCTACAGATCATGTGTATTACGCTAATCCAGTTGTGGAAGAGGTCGAAGAGGAGGAGGAGGATCAGCAGCAGCAGCACCATAACCACCACCACCACCAACAACCACAACCACATCAGTCACACTACTCACCCAATAGTTTGTCACGTCAAGACTTTAGTAGAGATTTGGTTGGAGCTGGCCAACAATATCCCAATCATGACTTGCCACCATTGGCTCCTTTAGGCGGACAGCAACCTCTTGATTTAGATTATACACCAGATGCTGGACAGCAATCAGTTGACCTAGACCAAAATCTCACGCCACACAGTCCATCACATGACCAGTTTCCCAGTGAAACACATCAGGAACCTGTAGATTTATATGACCCGCCCGTTAAGGGTTTCCCTACGCCATCCTCTCCGTTGCCTCACCAACCAGTTATAGACGAGTCAAATTTGTATGGAGGCTTGCAACCTCCACCACCACCAGCACCAACTCCAGCAGCACAACCTTCTACCCCATCCACAACACGTTTGCCTACAAATCTTCGTACATTTCCCATCTATCCACCCATGGCCAATGTTAGCTCACCGAAAGAGGTCAGGCCACCACATTATAGTCCTGGCTATGCAGCTGTAGCTCATTCCCATAATACATCTTGGCAAAAGATTCCGCCGCCAACTACTACACCAAAAGCTCATGATCCTTTCATTCCTTCCGAGGATATCGATGATAATTTGGATGAGTTTGGAGAGAGCACAACTAAGAGGCATGATCTTAGTCCGCCTCCTTTTGATCATAAATTTTACAATCCCACATTAAATTCTAGAGCTGCTAAAGCAGATTCCAATTCCGATCCTTCAAATGATCAACGGATTTTCGGTGAGGCTTTGCGTCTAATGCTGCGTCCCTATTTCAATCACAGTGGCAATGCCCCGGAGATTTTAGCCAAACAAACTGAATCAGCCATAGCTACGGTGATAAGCAAGCCACCTACCTCTAGAACTATTGCATCCACATCCACAACAACCACTCCCAGAAATTCCATACGACCCGACGATGATGTTGAACTCATTGTGGCCGGCGAGCAGGAAAGCCTGGACATTGAAACGAACGAATCTGACAGCGACTCTGACTCTGTTGTTCCAGATGCTGAGGAAACGACACACACTGAGCAGACCATAAATCCTACAACCTATGCTTTTGGTGATACACAAAATGATTTTCATCGTGGCACACGCAAGGTGGACATCGATTCAATGACGACCACAACCACCACATCCAGCACAACTACCGCCACAAACAACAAAAACAACAACAACAACAATTGGCATACGCCGCACAATCGTGATTTTCATAGGCGTCATCCAAATTTGCCCGATCCATTTGAGAAGCCGCATTCTCACCATCAGCATCAGCACCACAACAATCACCATTACCATAGTCCCCTCTATCATAGCCAGCATCCCGAATTGCTCAATCCCTTTCGGCAAAATCCCGAACAGAATAGTCCTGACACGACGACTCCTGACATAGTTCATCATCAGCATCATCACCCCGATCAACGTTTGCCCAAATCTTTTGACTCGCCAAAAGATCAAGATGAGGATGAGGATGAGGAATATCTACCCAATCCTAACGCTGAGGAAACAACACCTAAATCTCAATATCAGATATCCATGCGTAGTAATTTCCAGGATAATGACTGCGAATTCGATTGCGGCAATGGCAAGTGCATTAAACAAAAGGAAGTGTGCAACGGAGTGAATAACTGTGGCCCGAATCGCCGGGACGAGAGCCAGTGTCAACATTTGGGCTATCAGGTGCGGTTAACTGGCGGCGAGAACTCTCACATGGGACGCGTTGAAGTTAAGGTCAACGGTCAATGGGGTTACGTGTGTGATGACAAGTTTGGTTTACGGGATGCCGATGTTGTTTGCCGCGAATTGGGCTATAAAATGGGCGCACAAGAAGTGCGTGGCAATTCGTATTATGCCCCACCTGATCGCAACTTCAACTATATGATGGACAAAGTGGAGTGCCAGGGTAATGAGACAATGCTCAAGGATTGCCAATTCAAGGGCTGGGGCATTCACAATTGCGGTGTCGATGAAGTCGTAGGAGTAGTCTGCAAAGTTCCCGTGCTCAAGTGCCCGAACAACTATTGGCTGTGTCACACCTCTAAGGAATGCATCCCACCAGCCTTTGTATGCGATCATACAGAGGATTGTGCCGATAAATCGGACGAGAGTGAAGCAGTTTGTAAGGCTCCCATTGAGTATCGTTTGGAGGGTGGACGCAATCCAAGTGAAGGTCGCCTGGAGGTGAAGTACCATGGTGTCTGGGGTAGTGTTTGTGATGACGATTTCAGTGCAAAGTCAGCGCAAATTGCCTGCAATTCTTTGGGATACTATGGATCAGCCAAAATCGAGAAAAATATCTTTGGTCCTGCAAGTGGACCCATTTGGCTGGATGAGGTCATGTGTCATGGCAATGAAAGTAGCATCGATAAATGCAGTCACTGGAATTGGGGCGAACATAATTGCAATCATACTGAAGATGTAAGTTTACGTTGTACAGCTGGGCCACCACCAACCCGGCAGCAGCGTCAGCAGAGTGTTCGCCTTCACTCAGTGGGTGGTGGCAGCCACAACATCAAGGGAAGCCCATCCGGGCAAATTAGTCATCCCGCCTTTACTTTATCGGACATTGGACTGTGGGAACGTTCCAGCAAGGCTCTACATACGCCACGCCGTTGCGGCATCTTCAAAGATGATCTAACCGATGAGTATGCCCATCCTGAGGAGCGTGTGATTAAGGGTAATATAGCGCGTCGCGGCCGACATCCTTGGCAGGCCACCATACGTACCCGTGGTCGTGGCGGCATCTCAAGTCATTGGTGCGGCGCTGTTGTCATCTCTAAGCGTCATCTTCTGACTGCTGCCCATTGCCTGTACGGTCATCCAAAGGGATCCTACTTTGTGCGTGTCGGTGATCATTATGCCAATATTGCTGAATCCTCTGAAGTGGATTCGTTCATTGAGAACTGGTATACACATGAGAAATTCCGCGATGGTTCACACATGAACAATGACATTGCAGTGATTGTGCTTAAAACTCCGCTTAAATTTAGTGACTATGTCCAGCCAATTTGCTTACCAGAAAAGAATGTGCCTCTTGGCGAGAATCGAACCTGCACCATATCAGGTTGGGGCTCCATTAAGTCCGGTTTGTCCACTCCATCCCAGATTCTTAGATCAGCTCAGTTGCCCATTTTATCTGATGCCACTTGCAAACGCTCAAATGTCTATGGCGATGCAATGACCGATGGAATGTTCTGTGCCGGCTCCATGGATGAGAGTGTAGACGCATGTGAGGGCGATTCTGGTGGTCCACTTGTCTGCTCTGATGAAGATGGCGAAACTCTATATGGCATTATATCATGGGGACAGCATTGCGGTTATCAGAATAGACCGGGAGTTTATGTACGGGTTTGTCACTATATTGACTGGATCTATGAGAAAATCAATCACAGCTTGACGAAATTCTAAAAATCACATTTCGGATTTTTCAAAAAACATTTAGAATTTAGGACTATGAACAAGAATAAAGTCAATTTGCTTAAAATATA
->XM_044890485.1 PREDICTED: Coccinella septempunctata spastin (LOC123307970), transcript variant X2, mRNA 
-CCAGAAGAGGTCCTGTTACAAGTGTTCTGTGCTTGTTACTCTTTGGTCCTACGCTGACATAACACGTCGTTTTCCATTATTTTTTTAAGGATGAATACGAGTTCAATAAACTGAACATTGACTTAAAATGTATATTTGAATTTAGCTCCTTAATGGTTCGAAAAACACAAAGTGGAAAATCCCCTAAAAAATCTAGAAAAGTTGACCCTGAATCAGATAAAGATGTTATGTATATGACTTATGGGGACTCGTCTGTTCATAAAAGGAATCTGTGTATTGTTTCGTTTCCCATTATTTTTCTTTTCAGTATATTGAGAGCATTATTGTACCAAATTTTCGTTATACTTCGATTTCTCTACTGTCGTTCGTCGAGCTATTTAATTAAGCCACGTAAATTGCAGAATGGAAATATAGAAAGTAGTTGTGCTATTGAAGAAATTCAAATGTCACATAATATACAAAAAAATTCAGGTCCTGGTCCAGGGGACCCTCTGCTAGCCAAGCAGAAACATCATCATAGAAGAGCATTTGAGTATATTTCTAGAGCCCTTAAAATAGATGAAGAAAATGAAGGTCAAAAAGAAACTGCCATCGAATTATATAAGAAAGGAATTACAGAACTCGAATTGGGTATTGCGGTACACTGCTGGGGAGGAAGAGGTGAAGTTTGGGAAAGGGCTCAAAGACTCCATGAAAAAATGAAAACTAATTTGTCCATGGCAAAAGATAGACTCCAATTTTTAGCATCTGGGAAGAAATTAACTGTAGCTACTAGAAGACCTGGTAATTCACCTTTGTCTAAAAGCCAGACATTGCCAAGATCAATGGGTTCCCGCACAACACCTGTACAGCCAGTTCGTCCTTTTAATAAGCCAACACAGACTCCACCTGCAATTAAGAAGCAGTTATCTGTTCCTGGAAGTGGATCTCCAGCCAGAAAATTCTTAGCTAGTCAAGGTACCAGTAAGCAAACTTGTCGAGGCAAGTCTCCATCTCAACTGAAAGGAGTAGATCCAAAATTGGCTCAAAGTATTTTGGATGAAATAGTGGAAGGAGGTCCAGCTGTTCAATGGGATGACATAGTGGGTCAAGAAACTGCCAAGCAAGCTCTTCAGGAAATGGTTATTTTACCCTCCCTTCGTCCAGAACTCTTTACAGGACTGAGAACACCCGCAAGGGGGTTACTTCTGTTTGGGCCCCCTGGAAATGGCAAGACTTTATTAGCAAGAGCGGTAGCAACAGAATGTCAAGCAACATTCTTCTCAATAAGTGCCGCAAGTTTAACATCAAAATATGTTGGTGATGGAGAAAAAATGGTTAGAGCGTTATTTGTTATTGCAAGGGAGTTGCAGCCTTCAATAATTTTCATTGATGAAGTTGATTCTTTGCTTTCTGAACGCACCAATAATGAACATGAAGCAAGCAGAAGGTTGAAAACAGAATTCCTTGTTGAGTTTGATGGATTACCATCTAACCAAGAAAGTGAGAAGGTTCTTGTGATGGCCGCAACTAATCGACCTCAAGAACTAGATGAAGCAGCTCTTCGTCGATTTCCCAAAAGGGTTTACGTTACACTACCTGACATGGAAACTAGAATGGAGCTATTAAGAAAATTATTGGCTAAACAAGGTTGTTCTTTTACTCAACAAGAGTTGAAAAGGTTGGCTACACTAACAGAAGGATACTCTGGAAGTGATCTCACTGCACTTGCTAAAGATGCTGCTCTGGGACCTATACGAGAATTGCAACCTGAACAAGTGAAACAGATGGATCCAAGTGCAGTCAGAAGTCTTACGATGAACGACTTCCTGGAATCTTTGAAGCGTATAAGAAAAAGTGTTTCACCTCATAGTTTAGTGGCTTATGAAAAATGGTCATTGCAGTATGGAGATGTCTCTATTTAGAAGTAATACTTTGGTACATTTCAAACTTGTCTTTTATATTATTTGGTCTTGTTTTTTATACTTTGTCTGTGATAATTGATGTAATTGTAAGTGTTTATCATTGCTGCCAAGGATGAGTTTTGAAGGTTATATGGTTTATTCGATACTAAATTATATTCATAGCGATACAACTATGCAAACTGGATATTTTATGTTTGTTAGCTTCTTTAACTATTGAAGCAATACTTGCTATTAATAATTGAATTTCATTACGCTTTTTATTGCTATTATGTAGACTTAGTATCATGGACATTAATATATTCACTTATAACTTACAAAA
->XM_040825979.1 Metarhizium album ARSEF 1941 uncharacterized protein (MAM_07181), partial mRNA 
-ATGTCGCCACGGCCGGCCCGGACGGAACATCATTTAAACGTCGACAAGCCCAGCATCCGAGCTTCGCCTCTTCCGCTTCACACCAAACCCCTCTTCCAACGAGAGGTTCGAGCACAGCCCAGCATGGCACTCCCCAAAGTCCCGACCGCGACCGGCTTGCTGCGGCACAGCACACGCCCGGCGGCCTCGCGGGCCAGCCTGCCTCAGCTTCGACGCAAGGTGACACGAGGTGACGGCGATCTCGGCGGCCCGGGCGGACAGCAGCCCCCGCCGCCCAATCCAGGCGGTCCCGAAGCCGTCAAGAGAAACTGGGTGCCCATCGGCGGCGCGGCTCTCGCTGCTGTCGCAGCGTACGCGTATCTCACCACCCCCAAGGTGGATGTGGACAGGGCCAAGCAGACAGACGCCAGGAACCCGAGCCAGGCGGAATTGCGCGACCTGGCGGCCGGTAGCCAGGCGGCGGAGGAGGTTGTCCAGCAAGTTGCCGACCAGGCGACCAAGACGATGAAGGAGATGAGCGGCAGACGCAAGACGGACCAGGGCAGTTTCCGACACGATTGA
->XM_034374830.1 PREDICTED: Thrips palmi deubiquitinase DESI2 (LOC117639294), mRNA 
-ACACACCGTACAGTGCAGTGCGTCTGCGCGCGCGCTCGAGGGGTGGTGTTGTGTTGAATGAATGTTGACCTGTGTCCAAAATCTTTTGTTGTCGTCAGCATTTTAACTTTTCGCTTTGTTCAAAGAACCGTTTAGGCTTTAGTTTAGGACTTTGGACATCTAAGCCTGTATCTGACTCTTCGTTTGTCGCATGTGTTATCAGCAGGGTTTTCAGCAAGAAGATGTCGTCAGAGCCAGTTATTCTCAATGTTTATGATATGTACTGGACCAATGAGTATACTACTCCTATAGGATTAGGAGTATTCCACTCTGGTATACAAATATATGGCATGGAATATGCTTACGGAGGCCATCCCTATACCTTTTCCGGTGTGTTTGCAATTGCTCCACGTGATGCAGAAGAATTAGGAGACCAATTCCAGTACAGGCAATCAGTTCATGTTGGGTACACAGACTTTACTGAAAAAGAAGTAAAAAAAATAATTCAAGAACTGGGAAAAGACTTCCGTGGGGATCGTTATCATCTTATGAATAAAAACTGTAATCATTTCTCTGGGGCATTAAGTCAGATTCTCTGTGGCCGCGACATTCCCTCATGGGTCAATAGACTGGCATACTTTAGTTCTTGTGTGCCTTTTCTTCAACGGTGCTTGCCGAGAGAATGGCTGACTCCGGCAGCCTTCCAGCAATATAGCACACCAAATGCCCTGCAGCACACACTTAGTGCACGTGATAACAGTCCTGATGGTCCTTCCTCATAACATGAGGCTGCTGGGGCGGATCATGAAACACATCCTCTCTATGAAGATGACACTCAGTCCGTCTCCCAGCTTCCCTTGCTGTACACCCATGATCAGCCAAGTTCATGGCTGGGCAACCCCAAAGAACCACTGCCGTCCAGCTCTAACGTCAGTGATGAAGATTGAATGTACTTCTGTGTTATGCTTAAGTGGGTAACAGGAATGTTCAACATATATTTCTGTGTTATATTAAGTGAAGATGTGATTGGGTTATGAAAAGAGTGCTTCCAGAGGAGTACAAGAAGCACAACATTAAAAACTTTCAAAAACTTGAATCAAAACTTTCCTGTAAGTCATTTGTATAGTATTAAGCCTGTTGTCTCACATTTTTATTCTATTTTCCTGTTTGGTTTGAATGTTTTTAAAGCTTGTGTGGGACTCCTTCGGAAAAAGTGTTTGTGCATGAAGTCTACTATGACCTGATTCCCTTTTTTCTCTGAACCCTGAAATATTATTGGTTAATGGTGAAGCAAGTATTTCCCTGCAAAAATAAAAATTACTTGTTATCTTGTTGTAAGAAATTCTGCACTCTTGTGCAGTTAAGTTTTAAGAAACGATCATTCATCTTATATGGCCCTGTTTTATCATACCTTTGTTGATAACTCCCCCTTTATTACATAACAAAACAATTTTCCTTATGGTTTCTTTCATAAAAAGTGATCAATTTTTTTTTTATAATGTTATACCATGGTGCTTTTTGAAACTGTTGGGAAGATATCTTTGGGATTTTTCCAGACTCTAGGTATCTGATGTCATCATAACTCTTGTTTGACATTCTGTAGAAATATTTCAATTGATGTATCAGCATGTTGTCACTATTTGTATTTGTCAGGAGATGTGTTAATGCTTACTACGTATGAAATTTAGTGTTGTTGAGTCTTTGCTGGCCGCTTTTTATGTGCCACTGTAAAATTATTGCCTTATCCTAGGAATTAAAATTTGCTCTTCAAATTTGACCTCAGATCTCAATTTTTCTTGCCACTTCCTTTTTTAAAAAATTCAAAGTTCACATTTACTATGTCAGTGATTCCTCCCTGTGAAGAGGAATGCTTTGGTTTGAGTCTGTAGTTCTCTCAAATATTTGTATGTATTTAAGTTATTCATGAATCATCATAGCGTGACAGGTGACATTTTGAGACAAGCATTACTGTAGACTCCTTTGAGAGAACCGACTGCTTTTTTATTATTCAATAATCTGAGTGCGAATGAAATAAACCTTGCCTCTGTCTATGAATGAACAAACAGTTATAATTCCACATTACTTGAAGTTTTTGTGATTCTGTATATTTGGTGCTTTATAATCACTAGTTACTTACTGTACAATTGGATTTGATACGGAGGTGGCTATGCCTTGCCTAACTTTGTGTTTCAACATTTTTTGTAAAAAAAATTTGCAATATCAGCACAGTACGTTTGTATTTACTTTACAGGTACAATGTACATAATGTGAATTGTTCTTGTCATGGATCCTTGTATAACTAGTGGCAACCTGAATGTAGAAGGCATAACTGAAGGCAGAGTTCAAGTTTCCAGAATTAAAGTGTTGTATTCAGAGCCAAAAA
->KC066956.1 Uncultured bacterium clone G4RKN2Y13H4BNZ 16S ribosomal RNA gene, partial sequence 
-TACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGTCGTGAGGAAGGTGTTAAGGTTAATAACCTTAGCAATTGACGTTAGCGACAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGGGCACGCAGGCGGTTAATTAGTTGGATGTGAAATCCCCGGGCTTAACCTGGGAATGGCATTCAAGACTGGTTAGCTAGAGTCTTGTAGAGGGGGTAGAATTCCATGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAATACCGGTGGCGAAGGCGGCCCCTGGACAAAGCTGACGCTCATGTGCGAAAGCGTGGGGAGCAAACGAGGGATTAGATA
->HQ143338.1 Uncultured bacterium clone 19-239BM 16S ribosomal RNA gene, partial sequence 
-GCCGTGAAAGTCCGAGGCTCAACCTCGGATCTGCGGTGGGTACGGGCAGACTAGAGTGATGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGATGGCGAAGGCAGGTCTCTGGGCATTTACTGACGCTGAGGAGCGAAAGCATGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCATGCCGTAAACGTTGGGCACTAGGTGTGGGGGACATTCCACGTTTTCCGCGCCGTAGCTAACGCATTAAGTGCCCCCCCTGGGGAGTACGCCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGCGGAGCATGCGGATTAATTCGATGCAACGCGAAGAACCTTACCAAGGCTTGACATGTGCCAGACCGCCTCAGAGATGGGGTTTCCCTTCGGGGCTGGTTCACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGTTCCATGTTGCCAGCACGTAGTGGTGGGGACTCATGGGAGACTGCCGGGGTCAACTCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGTCTTGGGCTTCACGCATGCTACAATGGCCGGTACAATGGGTTGCGATACTGTGAGGTGGAGCTAATCCCTAAAAGCCGGTCTCAGTTCGGATTGGGGTCTGCAACTCGACCCCATGAAGTCGGAGTCGCTAGTAATCGCAGATCAGCAACGCTGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCAAGTCACGAAAGTTGGTAACACCCAAAGCCGATGGCCTAACCACCTTGTGTGGGGGGAGTCGTCGAAGGTGGGACTGGCGATTGGGACTAAGTCGTAACAAGGTAGCCGTA
->KT815871.1 Uncultured eukaryote clone 41c_79369 18S ribosomal RNA gene, partial sequence 
-CAATAGCGTATATTAAAGTTGTTGCGGTTAAAAAGCTCGTAGTTGGATTTCTGTTGAGAGCAGCCGGTCCACCTTTTGGGTGAGTATCTGGATTGGTCTCGGCATCCTCACAACGAATGTTTCTGCGCTTGATTGCGTGGTATAGGCGTTGTGACTTTTACTTTGAGGAAATTAGAGTGTTTCAAGCAGGCGCACGCCTTGAATACATTAGCATGGAATAATAAGATAGGACCTCGGTTCTATTTTGTTGGTTTCTAGAGCTGAGGTAATGATTAATAGGGATAGTTGGGGGCATTCGTATTTAACTGTCAGAGGTGAAATTCTTGGATTTGTTAAGACGGACGTACTGCGAAAGACATTTGTCCAACGGAAGTGTTTTCTATTGTATCAAGAACGAAAGTTAAGGGGTAGTCGAAGATGATTAG
->XM_033019624.1 PREDICTED: Amblyraja radiata GREB1 like retinoic acid receptor coactivator (greb1l), transcript variant X1, mRNA 
-GCGGAATCTAACGCCACATGCGTGAAGGGAAAATACTGCAGGCGGGAGCTGCGACACCGTGCCTTTGATCGTGCTGGTTGCTAATGGGGTCGCTCGCTACATTTGTATTGAGCGCGGTCGATGTCATTTTCTTTCCTCCAATTTCTTTGTGCTTGGACCTTGAGTGGAAGCTAGGTTACTGCAGGACAAGCGTTGAATGTGGAGAGATTTGTGTTTCTTCCATGGCCGGAATAAACTGATTTATACCGACGCCAAATTTAATGTCCTTAATTTGAGTGTGGACCAGTTTATTTTTCATCTTTGGTTATTGCACGTCTGCGAGACAATTGAGCCATTGTTTCTATCATTGAGAGGATTGCTGACCACACAAACTCCGGCATCATTTTACCTCTTGTCAGATAAAAATGAATGCATTTCCAGAAGGGTAACTGACAGAAAGGAGACCATGGGAAATTCATATGCTGGGCAATTGAAATCTGCGCGTTTTGAAGAGGCTCTTCACAATTCAATCGAAGCATCACTTCGTTCCAACAGTATTTCTCCTCAACCAATTTTCTCTCAGCTTTACCTTGAATCCGATAAACCACCTCTGTCCCCTCAAGATGTCAAACCAAAGATAGAGGAACTTAATAAAGAAATTGAAGTGCATCGTTATACGCAGAGTAGCTCTTCTGGATTCCCAGCTATACAAGTTGGCAATGGACTGGATAATGAGGAGGAGGAGGAAGAAGAGGAAATGTCTGAGTCAAACAGCCCACCTATTGCCTACATGCAGAAACATGTTCCAGAGGGATCCTGCACTACTGATGGTTATTGCCAGGCTGGCAAGGACTTGCGCTTGGTATCACTCTCTGCAGAACAAATTGACATTCCACCAGGCTTTGTGTTGGTGGGAGCCAAATCTCCAAATCTTCCTGAGCACATTCTGATCTGTGCAGTTGATAAGCGGTTCCTGCCAGATGACAATGGAAAGAATGCACTTTTAGGTTTCTCGGGAAACTGCATAGGCTGCGGGGAGAAAGGATTTCGGTACTTCACTGAGTTTTCCAATCACATCAACTTAAAGCTGACAACCCAGCCGAAGAAGCAGAAGCACTTAAAATATTACCTCGTCAAAAACTCGCAAGGTGTTTTCTCAAAGGGACCTTTAATTTGCTGGAAAGAATGCCGGACTCGTCAATTGCCCAGCAGTTACTCGTCTGCAGTAACTTCAACCAAGACAGTTACCACAGTCGTTGGATCCACCACATCTTCTCCGAATATTGACACCGTCTCATCTAGTGTTTGCAGTACCACCATTGCCAGCTGTCAGACAGAATCAACATTCAGCCATGGTTCAGCAGCATCTTCTGCCGGCTATTCTGGATGTCAGGACCTGTCCAGGAGTGGAAATGTAGCAAAACCTGTTACAATAGCTGCACAACAACTTGTGAAGCCTCCAACTTCAGCTCCCTGTGCAAATAACCAGCCACCTGGGTCTATGCGAGTTAATGGTAATCCCAATAGTAACGGCAATAGTGGAAAATCCAATGTTTTCAATGCTGCTCGACCTCAACCTCTCTCAACATCATCAAGTCCTGGCTTGGCATCAGGAGAAAATAGCATCATGACAAGCTCTGGACCACCTAAGAAGCGTCATCGTGGCTGGTCACCTGGTTCCCCCATTGCTGCGCCTACAGTAGTCCCTGTTCCAGCTGTGAGACCAGTGATGCGACCTGATGTTATGGCACCCATGCCTGTTCTTCAGACAATGTCACCTGGAGTCTTGCAGCCTCAGGCAATACCTGCAGGGGAGACTGTTATCATCCCAGACAATTTATTAAACAATTCTGGAGTGAGACCTGTTATTCTGATGGGTTATGGTTCTTTGCCATATTTTTATGGCAACGTTGGTGATATTGTAGTGAGTCCCCTACTTGTGAATTGTTACAAATTTCCACAGCCGACATCAGCTGAGCTGGAACAACTGGGAATTTCCAACAGCCAGATACTGTCAGTGGAAAACATGATCCTCTTAACAATACAATATCTGATTCATCTTGGTCCAGACCAAATGCCGCTCAGGGAAGAATTTGAACAGATTATGCTGAAAGCTATACAGGACTCGAGCCTCAAAGACCGATACCTGCAGCTGGGAGCCCCTTGTTCCACTGTGTCTCCAGGGCAGTTACCCTGGCTGGCCCGCCTTGCCGCCAGTGTGTCGAGAGATCTGGTGCAAGTTGTTTTTTCTCAGAATTCTCTAGCAGAGGGCATCTCGGAGACGTTAAGAACATTTGGTGATGTGCATCTTCAACAGAAAGTACCAAACTATGTGGTCGTCATTTGTACGTCAAAGATCAGAGGCAATGAATTTTGTGTGGTGGTTTTAGGTCACTATCAATCCAGAGTTTTAGCCGAGAGTATGCTCACCACCACTGAGTTTCTGAAGGAAATCAGCTACGAACTAATTACAGGAAAAGTCAGTATTTTGGCATCCCATTTCAAAACCTCCCCCTTTGGAGATAACGTAGACAAATTCCTGGATAAATTTCAGCAAAACAGAAACAACAGTGTTGCCATTCCATTCAATGGAAATGTTTCGGAATACATTCCGTCAAATGAAGCGGCAGCAATGACATCAAAGCAAGGAATTGATTCACTTACGGAAGTGTTCCAGATTCATCTACCTCAGCTCACTGTCGCTCGGAATCTGTTGTCTCAGGTTTGCGCCATAGCCGACTCTGGAATGCAAAACCTAGATTTGGGCCGTTTTGCAAACGTTGACTTCATCATTTTAGTTCCTGCATCGGAGGTTCTTTTCCACCAGACTCTGCAACGTATTAGACATTCAGGAGTACTTGTAGATTTGGGGCTTGAGGAAAATAATACAGCCGACCAAAAGGCTGAGAAATATATTATCCGACTAGACCATGACATTCAGAACAAATTTGAGGCTTTCATGAAGAAGGTCAAACAGAATCCATACACACTCTTTGTTCTTATTCATGACAATTCTCATGTTGATCTCACAAGTCTTGTTCCAGGCTCTACAACTCACGGGGAAGCCAGCCAAGGTCTGTCAGATAAGTTTATTAATTCACGTGAGGCACTTGAAGCGTGCAACTTACTTATGTTGCAGGTCAGCTCCTTTCCTTTCACTCTACAGACACAGCAATCCCGTGTTAGCTCAGACAATGAAGTACATTGGCTATTATCCAGCAATCCTGAGGAACTCAGCAACGAAGAGTTGGTATATTTTGGTTTGTCCGATTACAGCAAGTCTTTGCAATGGGGCATAACAAGCCCAATACTGAGATGTGATGAGGCTTTCGAAAGAATGGTGAATACATTGATGGAAAGGTATCCTAGGTTGCACAGTATGGTGATCAGATGCTACCTGCTGATTCAGCAGTATGCTGAAGCCATGATGGCTGTCACATCGATGAACCTGTTGAGGGAGCACACCACCCCCGAGACCCTGAGCATCGTGGATGACTTGATCAGCTGCCCCGGGAAAGACGAGATTGGCCGCGGACACATGCTCCTGATACGGGTCCCATCAGTACAGCTGGCGATGCTTGCCAAGGAGCGGCTCCAGGATGTCCGAGACAAGCTCGGCCTGCAGTATCGGTTTGAAGTCCTTCTGGGCAATCCAGCCGGGGAGCTCAGCGTTGCCAAGCACTTTGTCGCACGGATGAAGGGATGGAGAGGGTGTGAGCAGGATGACTGGACACCACTCACCTATCAGGATCTGGAGGGTCTACCATGTATTGTCATTTTAACTGGTAAAGATCCACTTGGGGAATCATTTCCACGGTCCATGAAGTACTGTGATCTTAGGCTAATTGACTCCAGCTACCTTACACGAACAACCCTTGAGCAAGAGATTGGCCTTGCTTGTGGCTATGTTTCTAAAAGTGCTGTCAGAGAAACCATGGCAATTTTCGAAGGAACGGAGAAGGAGCATGAGAAGTTTCTTACCAGTGAGAATGAATCTGATGAATTACAGATCGATCTAGAGAGACCACAAAGTAACAGCAGTGCAGTCACTGGAACTTCAGGGTCCTTGGCAGAGAATGGTGTGAGCTCATCCAGTGTGCTTGACTCATCACAGAGGCCTGCTTCATCTCTTAGCTTCCAGAATATTGTGAACAGTTCAATTGATGAAGGCACGTCAACACACACTTCACACATCTCGACCACTGTGGGCAGTGAGGGCTGCAAGCAGGAAAATGACTTGGAAGGAAAGGAAACAGCAAGCAGCACAGTTTCAAAATCTTCCTCATCCTCTGGGAATTCTCGGCAATCCATACTGGTCAACAAGGACCTGAGGACTCCACGTCTCATCTTTCCAAGAACTGTAATTTTATCAAAACCAGTGTATCATCTCCTTGGTTCAGCAAGAAATGAGCACCTGTGTTCTGCCTCTTTGTTGCCCCATGCTGATGTGACTTGGACAAGCCCACTGAGATCACTTTTCCACAAGGAATTGAGCAGTGAAGAGCAGTCACTCTACTACAGACAGTGGACATTTCCCAGGCAACATCATGCGGACTATAGCAATAAAAGCGAGGGAAGTTCTGGAAATTTCCACCGACGCCGATTGTTATTGACTGGACCTCCACAGGTTGGAAAGACTGGTGCTTACTTGCAGTTCCTTAGAATTCTTTTTCGCATGCTAATAAGGCTCTTAGAGGTTGATGTATACAATGAAGAAGAAATTAACGAAGACACGAAAGATTCAAATGAGTATGCACAGGGTATTAATGCACAGTGGCCTGATATTGAACTCTTCAGTAAAATGACCTTTGATTACACGGTACATGATCCAAAGTATCGCCATATCAGTGCTGTCTACTCAGCCAAGCTGCCAAAGATTAAGCTAGAAGGTGGTAAAAAACGCAGCCTGATCGAAGGATCAACAAAACGAGAGACAGTCTCGATAATGCTAACTAAATATGCTGCATACAACACATTCCATCATTGTGAGCACTGCCACAACTACATTGACTTCAACCCAGCCACACAGGTGTCTGATTCCACACTACATGCATTTACATTTTCTTCCTCCATGCTGGGAGAGGAAGTTCAGCTTCACTTTATTATTCCAAAGTCAAAGGAGCAGTATTTTATCTTCAGCCAGCAGGGTAAACATCTGGAGAGCATGCGTCTACCTCTTGTCACAGATAAGAATCCAAAATTAGTGAAGAGTCCCATCTTTACACCAACTACAGGACGGCATGAGCATGGTCTTCTGAATCTCTACCATGCCATAGAGGGTGCAAATCACCTTCATATCCTTGTGGTTAAAGAGTTTGAAATGCCACTCTATCGAAAGTACTGGCCCAACTACATTATGTTGGTATTACCAAGCATGTTCAATGGAGCAGGGGTCGGTGCTGCCCACTTTCTAATCAAAGAACTTTCATATCACAACTTGGAGTTGGAAAGAAATCGCCAGGAAGAGATAGGGGTGAAGCGGCAGTGTGTGTGGCCATTTATACTTGTCATGGACGATTCTTGTGTCCTGTGGAATGTCCACAATGTGCAGGAATTGAGCAGTGAAACAAAAGATTCTGCAGTTTCCACAAAGAATGTTTCCTTGAAGTTCGTAATGCAGCACATTGAAGCCACACCAAAGATCACTCATTATGCACTCTGTGGGATTCGAAAGTGGAACAGCAAACTGAACACTAGCAAACTGAGGACAGCATTCTCTCATTGTCACATGCATGACTTTATATTCCTCAATGTCGACCTGACACAAAATGTACAGTATGATCTGAGCAGATATATCTGTGAAGACATTGATTTCAACTTACGGACAAATAGCAGTGGTTTGCTCCTTTGTCGATTCAATCACTTCAGTTTCATGAAGAAATGCATTCAGGTTGGAGGGCACAAAGATTTTGTTATAAAGCCTAAGATTATGGTGATTGAAAGCCTGAATATTATTTCAGCCTCGCAGTACGTCTGTGCTCCAGACAGTGAAAGCACAATGCTGGCTGCACCTGCCCAGTTTCTCCTGGAGAAGTTTCTGCAACACACTAGTTACAAACTCTTTCCTAAAGCTATACACAACAGTAAGAATCCGGTGTTGTCCATTGACTGTTACATGAACCTGGGTCCTGAGATTTCTGTATGCTACGTAAGCTCACGGCCTCACTCAGTTAACATAAAATCCGAGGAGGTATTGTTCAGTGGACTCCTTCTCTACCTCTGCGACTCGTTTGTTGTTGCTGACTTTCTCAAGAAATTCACGTTTCTTAAAGCTGCCACACTCTGTGTGATTTGCCAAGATCGAAGTTCATTACGTCAAACTATCGTACGTCTAGAATTGGAAGACGAATGGCAGTTTCGGCTACGTGACGAGTTTCAGACGGCCAACAGCAGTGACGATAAACCACTTTATTTTTTGACCGGACGACATATTTAAGTTCAGTTCACAAGACAAGAAATAGCAGGTGAGGGTTAACGGGTGCCATAAGTGAGAGCCTGACGGAGCACAATTTATAATTCCAAGCGAAAGGTGAAGTGGCACATGCGCAGAAACAAATATCGGATTTTTTGTTTGGTTACCTGACCACCGTCACTTCATCGAACATCTACATCAGAACAGAGACAGCGTGATCAGTGCATAAGAAGGGTCTATGACCTGCACTCTGTTACTTCTGTAACTCCGGGAGAGAGTTTAGTGTGCGACTTGCAGGGAAACTGGCATTGCACATGGTATGATATATCAACCCTTTCAATGTGGGGAAAAAAAGGCAGTGCGAGCTGCAGAATGTATTTTTTTTTCAGAACCGGTCAAACCTATGATTATTCCAGAATATGTCCAAAATAGACCTGGATCCAAAAAAAAAGGAACTACTGTCAACAAAAAGACTTCACTGAAGGAATGGAACCAAAGCAGTGGAGCATAAAACAATTGATTGTATGTTGAGGTTCTTCAATGTCACCATTCTGACTGTATGTAATTGCAGTTCAGCTCAGGGTTTTGCAAATAGGTGGCAATGGAGAAAGAGTTGTCTGTATTCGTACTAACTATTACCTTATTTTTTGGTGGGTTTTGTAGTGTATGGTTTCATGCTTATTTGGAGTAGTTCTTAACCTGGCATTTTTTTTAAAGCATGTTCTCATATTTTATGGACATTTAAATCTAAACATGATACATGGGGAAATGCAAAATACATGATGCTTTCAGTGGGACTATTGTTGAAATTTTTAATGGCACGCAACTTATCCAGAATCTTTTTCCTACCGTTGACAATACAGGCTTTTGTTAATTTTTAATTTCACATAATCTAATTGTTTGACTTCTCTCTTGCATTGTCTATAAAACCATTTATCACACGCAGTTACATGCTTGTACTTACACTTCTTATTTTCATACAAATGATTACCATAGTGCATTGAATCAGATTTTGAAAAGTAAAATGCGCAGCCTTGATTCTCAAAGACATCAATATCTTTTCAATGTTAACATGGTAAAGATTAATAATGGACGATGGAGACCATATGATTTTTGGTTTCCTTTTTTGTATGATATATGAAAAGAGTAAATGTGCACAAATATCACACATCCAATGGTTCCCTGCTTTGTGCCTGTAATGTTATTTTTTTATTTACTTGTTTTAAGGAGATAATCTGAGGGGGATAAACAAATGTCACATTTGTTTCAGTTATTATTCTTTATTACTGTGCCATTTCATAACATTTTTGGCCAGTTTTGTATACATCTACAGCTATCCGCTTGCAAGGGATGGATTGATATACTCTCATGGGCAACTAAATAAAAATGTAGAAAGATAGCAATTGTATAATGATGTGAAATTTCAGCTGCTCTTTTGCTACCACTCTTCCCCGGTCAACAGCAATATTAAAATCACAACGTAAATTGGTCTAGCGATCTTTCCAAAACAAAAGTGATGATTTGGCCTGCAAGTACAAGTTAGAAATTCCATATTGACAAATAGGGAAGGAACAAAATAAATCATCCAGTTTTGATGACAGTTTTCAGTTGTAATTTAAGTGTAAACGTAATGTTAAGCAGGCAGCAGCAATGTGGGGGTGCTCTGGTATCAAATGTAATCATGGGAATTGCAAATGAATGAGCAAGTGTTTGTTTGCCTTCTCACTAATAATCACTTATCAACGATAACTATTACTGTAAATATTGCTAATTAAAAATGAACAAGATTTA
->XM_053163347.1 Puccinia triticina uncharacterized protein (PtA15_15A169), partial mRNA 
-ATGCCTTTTACACCGAAAATCGAAAAGGACGCTGGAAGACTTCAAGAGTGGAACTTCCACCATCGACGATCAGGTTCGATGGATTCTTCAAAAATCGCGCAAAAAACTTTCGAGCTTGAAAACCATATTCAGCCTTTGGAACAGGATAAGATATTCAAATACAACGCGGAGGAACAAAAGACGATCCAGAAAGAAGCGAAATGGAGGAAAGATCCTCACTACTTTAAGAAAGTGAAAGTCTCTGGTGTCGCTTTGATCAAGATGGTTATGCATGCTCGATCAGGAGGGCAATACGAAATCATGGGGCTCATGCAGGGCAAGATCGATGGAGACACTTTCGTCGTAATGGACTCATTTGCTTTGCCTGTTCAAGGGACAGAGACTCGAGTCAATGCGGCTAGTGAAGCCAACGAGTACATGGTCGATTTCCTCGAAAGTTCAAAAAATGTTGGCCGACTGGAGAATGTCGTGGGATGGTATCACTCTCACCCGGGTTATGGTTGTTGGCTATCGGGAATCGATGTCAGCACTCAGCTGACAAACCAAACTTACACAGACCCATTTGTCGCGATCGTCATCGACCCCAATCGCACAATTTCAGCCGGGAGAGTCGACATTGGCGCCTTCCGCACCTTCCCTGAAGGATATACCCCTCCATCACTGGGAAAGAGCAAGGACGACGAATACCAATCGATTCCATTGTCGAAGATTGAAGACTTCGGCGCCCATGCCAACTCTTATTACGCCTTGGAAATCGAACACTTCAAATCTAGTTCAGACTCGAAAATATTGGACCTCTTGTGGGAGAAGTATTGGGTCATGACTCTGAGTCAAAACACATGGCTTTCAAATCGAGTATACACGACAAGCCAAATTCAAGAAATGACCGACAAACTCACCAAATCAAGTAGCTCGCTAACAAACAGCAAGCGAAACACGCTAAAAACGTTGATACCCACTCACTTGCGAACTGCGATCGAGAATGAGAACGGTCATATCGGCAGTAACAACCATCCGGAAAACTCGACTCAAAATAACAATAACAATCAGCTGTTCCATGACGTCTTGAAAGATGTCGAGAAGTTAGAATGCGAGAACCTATGCGGCATGTTTGGTCAGATTATCAAAAATGTCTTGTTTAATAACAATTCTCATAACTGCCAACTTGAGTTCCCCATGTAA
->HQ319463.1 Uncultured bacterium clone RMAM0533 16S ribosomal RNA gene, partial sequence 
-GAGTTTGATCCTGGCTCAGGATGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAGCGGAGGTTTAAAGCGGAAGTTTTCGGATGGAAGCAATAAACCTTAGCGGCGGACGGGTGAGTAACGCGTGGGTAACCTGCCTCATACAGGGGGATAACAGTTAGAAATGACTGCTAAAACCGCATAAGCGCACATTGTCGAGTGACAGAGTGTGAAAAACTCCGGTGGTATGAGATGGACCCGCGTCTGATTAGCTAGTTGGTGAGGTAACGGCCCACCAAGGCGACGATCAGTAGCCGGCCTGAGAGGGCGACCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGAGTGAAGAAGTATTTCGGTATGTAAAGCTCTATCAGCAGGGAAGAAGAAAGACGGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATC
->XM_029801181.1 PREDICTED: Octopus sinensis homeobox protein rough-like (LOC115231097), partial mRNA 
-TTCAAAGACGGAAAAGGAAAGAGAACCGTCCCCGACGTCAGCGTACGACATTCACCAGTGAGCAGACACTGAAGTTAGAACTGGAGTATAACCGAACTGAATATATCACACGACCTCGGCGATTCGAATTGGCTGAGATGTTGAACTTGACAGAAACCCAGATCAAGATCTGGTTCCAGAACCGAAGAGCGAAAGACAAACGGATCGAAAAGGCACAAATGGATCAGCAGATGAGCCTATCTAATTTCCAAAGAAGACAAGTTGTTGGAGTTCGGCCCGATCTCTACAGCGCTGCTATTAATTTTGTTCTCTGTCCAGAATTGTGTTGTGGACAAGGGTTAGAATGCTTAGAATACTGGAACTGCCGCATTGCTGTGCCCGCACCTGCAATTCTAGCATTCCGTTCAGCCTTCTGCTTCCCATCACAAGAGAACGG
->XM_043204581.1 Ogataea angusta uncharacterized protein (KL928_003939), partial mRNA 
-ATGGTCCAAATCCCCAGATCGTACGCGGAACTGAAGCAGAAGGTTCCAAACATTGGAATCATTTTTGCCGCAATAGCTTCGTGGTTTTCGTTTAGTTTACTTATCTCGCTTTACAACAAATGGATGTTTTCAGATCCTACTTTGAACTTCAAGTTCCCCGTGATAATTACAGCCTGTCACCAATTCGTGTTATTTTGGCTCAGCTGTTTGACGCTCACCTTTTGGCCCAAGTTCAGACTGAACTATGTCGATCCTTCCAAAGGCATTGCGTCCTCCGAAAATCTCAGCTACTTTATCAACCCTAAAGTGTACATTACCAAGATCTTGCCGTGTGCGCTGGCTTCCGCCGGTGATATTGGCTTGGGCAACTCTTCTTTGAAGTATATCACCATCTCGCTATACACCATGCTCAAGTCCTCTGCAGTGCTCATCTTCACGCTCTTCTGGGGTTTCCTTCTCAGACTGGAGAAAGTTACGTTGAAGCTTTGTCTGATTACGTTCATCATGACTGGTTCGGTCATGATGATGGTGTACGGACAGGGAGAGACCTCGGCTGAGACCAGTCCTTCCGCTGTTGAGGAGGAGGCTGGAGAAATGAAGCTCAGATTCGTCAAGCACCTCGTGAAAAGAGCAGCTTCTCTGTACCTCGGTGTCAGAGACGAGGAGCAGGAATCCGACGACTTGGTTTCCTCGTCCTCCTTCACAGGTTCTACGGCCAAAGCTTCTGCTGCCCTGGACACACTCACCGCATCCTCCATCATCATTGGCTGCATCCTGGTTCTGCTTGCATCTTGCATGTCTGGGCTTAGATGGGCTTTGACTCAAATTGTCTTGCGTGGCAACAGATACACCAAAAACCCAATTTTGACCATCTTCTATCTGAGTCCCGCCATGTGCGTCTCGCTGATTGTCATGGGCTCGCAGGTCGAAGGCTTAGGCAACTTTCTAGGATCGCAGGTCTGGGAGACGTATGGTATTTTGGGAACCTGTTTGCTGCTTTTGTTCCCAGGTTTCCTGGCCTTTTGCATGACCCTGTCTCAATTCATCATTCTGCAGTACGCTCCGTTGCTCACGCTCTCTATTGCCGGTATTGTCAGAGAGCTCATTACTATATTCCTCGGATGGCTGATCTTCGGCGACCACCTGAACGCGATCAATATGCTGGGTATATTGATCACCTTGGGAGACATTGCATGGTACAATCTCTACAGACTGGAGCAATCTTCGGCCAAGCCGGCTTCTGCTGCGTCTTCTGAGGACACAGAGAGGTTTGTCACCGAGGAGCACGAGCTTGAGTCTATCGACAGACGCAAGTGA
->XM_004287821.2 PREDICTED: Fragaria vesca subsp. vesca putative F-box protein PP2-B12 (LOC101291663), transcript variant X1, mRNA 
-AAATATTTTGTGAATTTCTGAGATTCATCAGAAAAGTTAGGATGCTTTCTCACCAAGAAAGTGAAAAGAAGTATATATACACAGCTTCATGATTGATTCCTCTACAGAAGGCTGAAGCAGTGTTGTTCTTTCACAAGGACCTCTAGAATTGTGTATATTCTTGTCTGATACTTTAGGTTTTTCTCATCATTCAAGTTGTCTTGTAGAGGTGTATAACTATATATACAGTAAGATGAATGCAAGAGAAATGTTTGTCAAAATAGCAGAAGCATTTGTGGAGTTGTACAATTATGTTAGAGGGCCTATGGTGCCGCAAGCAATTCAGTTAAGGGATGCAGTAGTGAAGATTCATGAAAGCTTGGCTGGTCAAATTGCAGACTCAGAATTGATAAGTAGTGTTATCGAATGGTTTAATACGTTTCATAACATTTATGTCGCACTAGGATTGGTTGGTTTGGTGATCTCCTTTGTTCTAGGATTGCTTTGGAAAGTTTTAGCTGTGGTAGTTTCTGCTTTAGGTGTATGGATTTCCTATTTGATTTGGAGAGACCATAATTGGCACAAGCTGTTCCTGACAGACGAAAAAGGATTAGCATTTTTTGCAAGTACTTGGCTTGGGTTATTGCTACTCTACCGAGCACAAGGTCTGCTTGGCAAAGTTTGTCTTTTGGGAATAGAAACCCTAGTAATATGGGTGATGCAGTATTCCATGTCGACGACGACGAATATGGAAATCCCTTGGGATGATTCTAATATCCATGAAATTATCTCCCGAGCTGTTCCACCGGTGCCCCATTATTCTTCTCCGCATGACCTCTACCGCAGTCTCTGCGCTTCCCCCATCTTCCTTGACGATGGCTACTTGAGTTTGGCGTATGATCGGGCGACTGGTAAGAAATGCTGGATGATGGGAGCCAGGCTTTTACTTATTGATTTGGCAGAAATTCCAGACTACTGGAACTGGATATCTCTGCCTGAATCCAGGTTTTCCCAAGTGGCTGAGCTCAGATTTGTACGTCGTCTTAAGATCAAGGGATCCATTTCTACCTATATGTTGTCACCAAGAACAACCTATGTAGCTTACTTTGTATACAAGTTTTCAAATACATCTCGATCTGGTTTTCATGAAAGGCCTGTTAGCTTGCGTGTAGTTCGTGTTGTTAATACTCAACGCCAAGTTGTGGCGCATCATAATCGTGTGTTCCTGATAGGAGAGATGGCTTCACAAGCTCGAACGAGAAGTGATGGATGGATGGAGATTGAGTTCGGTGAAATCTCCTACATTGATGATAGTGCTACTATAGAGTGTATACTAGAGGGATCTGAAAGTTTTGAGGGAAAAAGAAGTCTCATTGTGGAAGGTATTGAGCTCAGGCCTAGATAGAGGAAATTTATCTCTCTGTATATATATAATGGATCTTTGATCTTTAGCAAATCTTCTTGATGGCATGGTTGATGGAGATCCAAGCTCACAGTTTACTATATATATTGGTTATGGACGTGGTTTATGGACGTGATCTTGCTAGCTTCCAGCCTTCCAGGCTGGTTTACCT
->XR_008327014.1 PREDICTED: Panonychus citri uncharacterized LOC128397849 (LOC128397849), ncRNA 
-AATTACTGGATCATCTTTGATTTGTCATCTAATAGTCAATGGAATTGTAACTTTGTTAATTGTTAGTTCTTAGAATAGATTCAATTAAAATCGATGACATCAATCAGCAACAATTTATCAATCGTTGTAACAATTAACCTTAATGCGAAAAGTGAAAAACAAATCTAATCAAAGTAAATTGTTTACAATTAGAAAAAGAAATCAAATTAATTGTAAACATACCTACGTGATGAGATGCAAATCTAATTGTTAACAATTAGTCTGGGAAAATTACTTATCATTAGAAATTAAATTTGTCTGATCAACAATTAGTCAAATATGATAACAAGGATCACAATTAAACTTAATTGTTACGGAAAAACCTTCAACAGATTCTAATTATAATGTAACTATATTTACTCATTATAAAGAAAGTTAATTATAATGTCGATACATTTGCAATTAAATTTGACAAATCAATCAATTAATTACACATTTATGATGATTATGATTAATAATTAATGAGAAAATGATTAACTTTTGATTAGATTAACAAGAAGGAAATTATTTTAATTGTGTTTACCAGAAACGGTATCAATAGTAATTAGAATTACTTTGTTTACCATTTAGCTTTAACATAGAGAGAAATTGATTAGTAGTTTATCAACAATTAATTTAATCGTAATAATCAATTGATTAGTAGAAGAGAAATCAACGAAAATAGACAGAGAAATAGACAGAGAACAAGAAAAAGAGAGACGATCAAGTGAGTGAGAGAAAAATATAAAAATCATTTTCTCTTCAACGAATCAAGTGAATGTCACATTTTCCTTGGAGACTTTGAGTTTGCTAATTGATTTGATTTTTTGATTAATTGTCTTCATCTTTAAGAATTAATTACTCTTTGATTGTTGTTCTTTGAAGGTGTTGAGTTAATTTGGATTCGTTTTAATTGTGATAATCAATGACAACCATTAAAGATCAACATCAAATGCCTAATCCCAAATGGATCATCTTTTGTTGCTAATCTGTAAAGTGGTCAACACATTTTGTGACTATAAGTGTCTTAATTGTTCAAGTGATTTATTGTTAATAAGAACGTTTAAATTGACTAAAAGATGCCAGTTTACGCTGCTATCAGTCGATCAAGGAAACGAAGTCAGGAACGGAAACTGTCCCTTAGTTCCTGTTCCTCTGAGTCTTCATCTATTTCCTCAAGTGAAATTGATATAAAGGTGGATCAGAATGTGATCTTTGTGGATTATCACTTAAATCGGTCAAACAACATTACATTTGTGGACATAATTTTCACATCGATTGTATTTGGAGATACAAAAGATTAGCCCCCAGTAACCATGAGTATTGTCCAGTTTGTGGTATTCATCATCCACCAAAAACAATTAGAAATTACTAATTATCATCCTCATCACCATCATCATCGTTGGGTCATCAATATTTATCCACATCTCATACTTGCGACAATTTAAATCTAATTGTTTGCCTCTTGCTCTCTGTCTCTCATTATCCATCAAAAATCATTGTAATTATTTAATCGATCATAACAAAGTCACAGATCATGATTAATACCAATCAATACGAATATAAAATACAACTAAATCAATCAAAACAGCTCAAAACAATTAAATTGTAATCGAAACAAAAAACACGCTGATTAAACAAGTGTATCTTTGTATTATAATCATCACAATCAAAAATCAAA
->NM_001096323.1 Xenopus laevis zinc finger DHHC-type containing 1 L homeolog (zdhhc1.L), mRNA
BC106577.1 Xenopus laevis hypothetical protein MGC131347, mRNA (cDNA clone MGC:131347 IMAGE:7766144), complete cds 
-CAGCAGATTCCGTAAGGATCATCCCTTCCCTTCCTCTCTGATTTCTACTCTGCTTCTTAGTTCAGACTGCGCCCGTTGTATATTCATAGCCTCATTCCATCAACCGCAAAGAGACATGGGCATTTGGAAAAAGCTACTTTGTATACAGGGTTGGAAGCAAACAACATGAGCTGACTTTCCTGTCAAGGTTCAAGACAAAGTCTTCCTATGCTGAACACATTTAGAAGCCATCTTAAAATACATGAATTATTAGTTCTGGTACTGTCAGATGGGCATTCAAAAAGATGTCAGTCTGCAAGAAGCAGTCTGCTATGAATGTGCCCGATAAAGAGAGAGGGGAAGTCATTTCAGATCCACCTCAACATTCAAGAAAAAATGGCTGGAGTTGGCCCCTGCACCTGCTGCAGCTTGTTGCCTGGTCCACTTTTCTCTTCTTTGCTGTTATAGGACTTGGGATCTTGGTCCCTCTTTTACCACAGCATTGGTTGGCAGCTGGTTACATTTGTACTGGAGTCATGTTTACTTTCCACTGTGTTGTCCACTTTCTGGCTGTTACCATTGATCCTGCTGATGACAATGTGCAGGCCAAAGGTTCTCTTGGGCCTCTACCAGCATTTGATCGCAACAAGCACACTCATGTAATTGAAAACATGCATTGTTATATCTGTGAGGTGGATGTGTAAGTAAAAGATGACCCTTCATGTTGTAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
->XM_051729581.1 Alternaria postmessia uncharacterized protein (J4E82_003292), partial mRNA 
-ATGGATGAGGAAAATGTTGCCAACTTCTGCGGCATCACGTCCTGCAGCCCAGAGCAGGCTGCTCAGTACTTGCGCCTAACAGATGGCAACTTGGAGCAGGCCATACAACTCTTCTTCGACTCTCCTGGACTTGCCGATGCTCCTGCTGCGCCATCACAGCCCTCAGCAGCCGCCTCCGCACAGAATCCCATCAATATCGACTCCGATGATGACATGGACTTTGATCCCGCACCACAAGGCAACGCGCCGTCCACACGGGCACAACCAGGCGTGGAAGACGATGAAGCCATGGCACGGAGGTTACAAGAAGAGATGTATGGCGGCGGCGGCGGCGCCGCCGGTGGCGCTGGCAATGATGAGATTCGCGCGCCCATAGAACGAAGAGTGGAAACACTTGTTGGCCCAGGCTCAAACTGGGGGCCTGCCGATGACGAAGAAGATCTTGATGCTATGGTCCAGGAGCAGCTTGCTCGTCGGCGGACAGGCCGCGCCGGTATCTTCAACCAGCACACAACCCATACCAATGTCTGGGATAACACGACCGATTCGAGCACCCGGCGACGCGAGCTTGCGACCGCGACTGGCGGTGCTTCAGAGCAGTCTTCTAAGATGAACATGCTCGCAGAGCTATTCCGACCACCGTTTGAGATCATGTACCAAGGATCGTGGGAAAAGGCGCGAGATATGGGCAAGGACGAAGAAAAGTGGCTGCTTGTCAACATCCAAGACCCGGCAATCTTCGACTGCCAGCGCCTTAACAGGGATATCTGGAAGAATGACGATATCAAGGCAACTGTGCGAGAGAACTTCATCTTCATGCAGTATGCAAAGGATGATCAGCGTGGACAGCAGTACATGAACTACTACTTCCACGCCCGTGACAGTTCTGACGCCTACCCCCACATCGCCATCGTTGACCCACGAACAGGCGAGCAAGTCAAGGTCTGGTCGGGACCACCGATACCCGAACCAGTTGAGTTCCATGCTCAGCTTCATGAGTTCCTCGACCGTTACAGCCTCAATGTCAATGCGAAGAACCCTGTAGCGAAGCGGAAGTCTGAGTCTAAGAAGAAGGATGTCGGTCGCATGACAGAAGAGGAGATGCTGGAGATGGCGCTACAAAACAGCATGGATAACGGCAAGGGGCCGAAGGACGATGACCCAGATGCTCTCACCAAGTCTACAGACAACATCAAGGGCAAGGGCAAGGCCGAAGAAGTCGCTTCTGAGCCGCCAGCTGAGCCCGAGGCAGCTCCTTCGAATCCTGTCTTCGCTGCCATCTCCGCACATGCTCCTCATACCGAGCCTACCGTTACTGATCCCAAGGTCACGACTCGCATCCAGTTCCGTGGCCCGTCAGGCCGTCCGATTGTGCGCCGCTTCAACCTTACAGACCCTGTTCGCCGTGTCTACGAATGGATCAAGTCCGACGTGCCCTGGGAAGGCAAGCAAGGAGCTGAGTTCGATCTGGCGTTCATGGGCAAGAACCTCCTCGACCACGTCGACGACACGGTCGAAGCCGCCGGACTCAAGGGTGCCAGTGTTATGGTAGAGTTCTTGGATAATGAGTAG
->XM_006724281.5 PREDICTED: Homo sapiens eukaryotic translation initiation factor 4E nuclear import factor 1 (EIF4ENIF1), transcript variant X2, mRNA 
-AGGGGCGCGAGGCCCGCAAGGCGGCCGGCGGGTAGCCGGCGGGCTGGCTGGCGGGGACCGAGCCGCCGGGCCGGGGAGGACGGCTGCGGGCCTGCGCTAGCTCCAGCTTGAAGCGCCCGGGCCGGGAGATTCGGCCTCCCTCCTCCCTGCGGCCGGCCGCCCCTCAGTGAGTACGGTCTCCGCCCTTCCTCCGAAGGAGGCCGCTGGGCCCGGGCCTGCGTGAGGGGCTGCGGGTTGGGGTCGCGGCCCGGGGAAGCCAAGTTTCGGAGCTGAAGCCGGTGCTCGCCCTTTCCTTGCCATCGGCGCCCCTGACATGGCCACAGGTGCGGCTGGCCTGGCGAGGGGCGCTCGGGCCCCGTCCCCAGTCCCTGATCGCCGGATAACAAGGGGCAGCTGGCGCCGTCCATTGGTGCAGAGCATTGTAGACCAAGGAGCCATGGATAGGAGAAGTATGGGTGAAACAGAAAGTGGAGATGCTTTCCTTGACCTGAAGAAGCCTCCTGCCTCCAAATGCCCCCATCGCTATACAAAAGAAGAACTCTTGGATATAAAAGAACTCCCCCATTCCAAACAGAGGCCTTCATGCCTTTCTGAAAAATATGACAGTGATGGTGTCTGGGACCCTGAGAAGTGGCATGCCTCTCTCTACCCAGCTTCAGGGCGGAGCTCACCAGTGGAAAGTCTGAAGAAAGAGTTGGATACAGACCGGCCTTCCCTGGTGCGCAGGATAGTAGATCCACGAGAGCGTGTGAAAGAAGATGACTTAGATGTTGTTCTCAGCCCTCAGAGACGGAGCTTTGGAGGGGGCTGCCACGTGACAGCCGCTGTTAGCTCCCGGCGCTCAGGAAGTCCATTAGAGAAAGATAGTGATGGGCTTCGTCTGCTTGGTGGACGTAGGATTGGCAGTGGGAGGATAATCTCTGCCCGGACCTTTGAGAAGGATCACCGTCTTAGCGATAAGGACCTGCGGGACTTGAGAGACAGAGACCGAGAGAGGGACTTCAAGGACAAGCGTTTCAGGAGAGAGTTTGGAGATAGTAAGCGTGTCTTTGGTGAGCGTAGAAGAAATGATTCTTACACAGAAGAAGAACCAGAGTGGTTCTCTGCTGGACCCACAAGTCAGTCTGAAACCATCGAACTGACTGGCTTTGATGATAAGATACTAGAAGAAGATCACAAAGGGAGAAAAAGAACAAGGCGACGGACAGCCTCTGTGAAGGAAGGTATAGTAGAGTGCAATGGAGGAGTGGCCGAAGAGGATGAAGTGGAGGTCATCCTTGCACAGGAGCCTGCGGCTGATCAGGAAGTGCCAAGGGATGCTGTCTTGCCTGAGCAGTCCCCAGGAGACTTTGACTTTAATGAGTTCTTTAACCTTGATAAGGTGCCATGCTTGGCTTCGATGATAGAAGATGTTTTGGGAGAAGGGTCAGTCTCTGCCAGTCGGTTCAGTAGGTGGTTCTCTAACCCGAGCAGATCAGGAAGCCGATCCAGCAGTCTTGGGTCAACACCACATGAAGAGCTAGAGAGACTTGCAGGTCTGGAGCAAGCCATCCTCTCTCCTGGACAGAACTCGGGGAATTACTTTGCTCCTATACCATTGGAAGACCATGCTGAAAATAAAGTGGATATTTTAGAAATGCTACAGAAAGCCAAAGTGGATTTGAAACCTCTTCTTTCCAGCCTTTCTGCAAATAAAGAAAAACTTAAAGAAAGCTCACATTCAGGGGTTGTGCTTTCAGTGGAGGAGGTAGAAGCAGGTCTGAAGGGCTTGAAGGTTGACCAGCAAGTGAAGAATTCAACTCCCTTCATGGCAGAACACCTAGAAGAGACCTTGAGTGCCGTAACCAACAATCGACAACTGAAGAAAGACGGAGACATGACTGCGTTCAACAAGCTAGTGAGCACAATGAAGGCAAGTGGGACTTTGCCTTCTCAGCCCAAAGTCAGCCGAAACCTTGAAAGCCATTTGATGTCCCCTGCTGAGATTCCAGGCCAGCCTGTCCCTAAGAACATCCTGCAGGAACTTCTGGGTCAACCAGTTCAGAGACCTGCTTCTTCCAATCTTCTGAGTGGCCTTATGGGGAGCTTGGAGCCTACAACATCTTTACTGGGCCAAAGAGCACCCTCTCCTCCCTTGTCACAGGTGTTTCAAACTCGAGCAGCCTCAGCTGACTACCTTCGCCCAAGAATACCATCACCAATTGGTTTCACACCAGGACCACAGCAGCTACTCGGAGATCCATTCCAAGGCATGCGCAAACCCATGAGCCCCATCACAGCCCAGCAGATGAGCCAGCTGGAGTTGCAACAGGCAGCTTTAGAAGGGCTGGCCTTGCCACATGACCTTGCTGTACAGGCAGCAAACTTCTACCAGCCTGGTTTTGGCAAACCACAGGTGGACAGAACCAGAGATGGATTCAGAAACAGGCAACAGCGAGTGACCAAGTCACCAGCACCCGTGCATCGAGGGAATTCCTCTTCCCCTGCCCCTGCTGCCTCCATCACAAGCATGCTTTCTCCTTCCTTTACCCCTACCTCAGTGATTCGTAAGATGTACGAGAGCAAAGAGAAAAGCAAGGAGGAGCCAGCATCTGGAAAAGCAGCTCTTGGTGACAGTAAAGAGGATACTCAGAAGGCCAGTGAAGAAAACCTCCTGTCATCCAGCTCTGTACCCAGTGCCGATCGAGACTCTTCTCCCACTACAAATTCCAAACTGTCAGCATTACAGAGGTCTTCGTGTTCCACCCCACTGTCCCAGGCCAACCGTTACACCAAAGAACAAGATTATCGACCTAAAGCAACTGGGAGAAAAACACCCACCTTGGCATCCCCAGTTCCTACAACACCTTTTCTCCGCCCTGTCCACCAAGTTCCCCTTGTCCCCCATGTCCCTATGGTTAGGCCTGCTCACCAGCTTCACCCAGGGTTGGTACAGAGGATGCTGGCCCAGGGAGTACATCCACAGCATCTTCCAAGTTTGCTCCAAACTGGTGTGCTTCCTCCTGGGATGGACTTGAGTCATTTACAGGGAATATCTGGCCCCATCCTGGGTCAGCCCTTTTACCCTTTACCTGCTGCTAGTCACCCTCTCTTAAACCCTCGTCCTGGAACACCTCTGCATCTGGCAATGGTGCAACAGCAGCTACAGCGCTCAGTTCTGCATCCTCCAGGCTCTGGTTCCCATGCAGCAGCTGTCAGCGTTCAGACAACCCCTCAGAACGTGCCCAGCCGGTCAGGCCTGCCCCACATGCACTCCCAGCTGGAGCATCGCCCCAGCCAGAGGAGCAGCTCCCCTGTGGGCCTTGCCAAATGGTTTGGCTCAGATGTGCTACAGCAACCCCTGCCCTCCATGCCCGCCAAAGTTATCAGTGTAGATGAATTGGAATACCGACAGTGAGCAGGGCAGGCAGACTCAACTAAGCCCGGACCTGTGGTGGCACACTGGGCAGGACCCTGCTTCATCTCGGGTTGGTTTATGGGCTTTTACTTTGGAGCACTCTGTGTGAAGCTGTTTGGTGGAACCCATGCATCTGGTGTGGTCCGCATTATGATGGAAGGATCTTAACCAGTCGAGTGGAGTGTACATTGTCTGAATACAGGATGCACAATGTTGTCAATCCTGGAAATGGTCTTTCTTTTTTGTAAGATATGTGAATGAAGTGTTGGTGTCCTCACCAAGAGGTGGCACCTAAGGGTTCTGAGGAAATAAATGTATAGACCCTTATGTACAGACCTGTGTATAAACAACTTTTGTATATACATATAGGATAGCTTTTTTGAACTATACAGCTGTACATAAAAGTAGCTGATATTAGTTAGGCCTGTGTCAACAGTTTGGATTTTTTTCACTTGTACATTTGGGATTTTCTTTTGGTTGATTAAAATTGCATATGCTAAGTGTGTGAATGAA
->XM_003017089.1 Trichophyton benhamiae CBS 112371 phosphotransferase enzyme family protein (ARB_04011), partial mRNA 
-ATGGTTTCCGTGAGACCGCGACTATTTCTAAGGGGTCTCAAGCACAGAATCCCGGAAGAGCATAGTACAACAGACCTTTTCAACTATACCACGGGGCGATGGCTTTGGAGAGAGAAGGAGCAGCTACTTGAACGATACCGGAGATTCAATGTACGAGAGCTACAGGCCATAACTGCACATACACTGGGCTCTCAAGCATGTGTTTCAATGTCCAAAATTGGAGAAGGCAATTTCAACAAAGTCTTCCGACTTGTAATGGATGACGGAGCAGTGGCAATAGCTCGAATCCCCCATCCAAATGCTGGTCCGCCTCGGTATACGACTATGTCGGAGGTTGCTACTATGGAATTTGCAAGATCAATGCTTAAAATACCAGTTCCTAAAGTGTTAGCATGGTCTTCATCTTCTGATAACTCTATAGGTGCAGAGTATATCATTATGGAAGAGGCTAAAGGCACCCAGCTCTCTCAAACATGGGATGAAATGAAATTACATGATAGGAGTGAAATAATCAATGATATTGTTTCCATAGAGCAGAAACTTCTCTCCGTGACCTTTGGCTTGTATGGGTCACTATATTTTTCCAAAGACGCTTTCCCTGGCTGTCAGCCGGCAGATATCAGTGGTGACGTCGCACAAGGGATTGAGGATGAGGTTAGAAAGCAATTCGTCATCGGCCCTACGACTCGCCGGGAGTTTTGGGAAAAGGAGCGAGCACTGATGGATCTGGACCGAGGACCTTGGAAATCTGCTAGTGGATATGTGGAGTCCATAGCCCATCGCGAGACCGCTTGGATTTCCCAGTATGCACGGAGGGATTCCATCATATCTGGCTACCCCAGGGGCAAAGGAAGTCAAAAATCACCCCAGGACCACCTCGGCTTATTGGAGAAATACCTATCTGTTGTTTCGAGGCTCCTTCCCGATGATACCGAGCTTGTTCGCCCAGCACTCTGGCATCCTGACATCCACGATGGCAATATATTTGTCCAGGATGGGAGGATTTCCAGCATTATTGACTGGCAGTCTGTCTGGATTGCACCTTTGCTTCTCCAGGCCAGAACCCCTCGACTGATCGATTACCATGGAGAGATCCAGTTGAGACTTCCCGAAGACTTTAAAACGCTGCCCGAAGAAGAGAGGGATCGCGTCAGAGACCAGGTCCAACGGTCTATCCAGGTATACCTTTATGAGGACCGGACGGCAAGAGTCAACCCTCTTCTTGACAGGGCAATTAGGAAACCCCATGGGAAAACATTGGCTCAGCTCGTGAGCTTTGCTGGAAACTCATGGGATGACCACATCGTACCCCTGAGGGACACTCTGATTGACGTTGAAAGGTATATAGCAAATTGGTCATGA
->XR_008008321.1 PREDICTED: Arachis duranensis uncharacterized LOC127746577 (LOC127746577), ncRNA 
-TCTTATACGTAATCCTTTTCGTGAGCGATTGTCTCTACTCTCTCTCTCTCTCTGGAATAAAGTAAATACGGTATGTTATACAAAAACTGTCAACACTATATATAGATTATAACTAACTTGTCTCACAAAACTTCCAATAATTTCTCTCTCTCTTTCTCTCTAAAGCTCTCTCCCTCTCTGAATGTTTGAGTTGCAGGTGCTTATTAAAAACATGGCTTGGTGTTTAAAACAACGCGTGTTGCTCCCTGTTATGGTGGTGTTATTGTTGTTGGGAACAAGTCCTTCCATAGCAGAGCTTCAGAAGCTGAAACACACTCCAACAAAAGCAGATCAACCTCTGAACATTCTGGTGGTCGGAGACTGGGGAAGAAAAGGAACCTATAACCAGTCCTTGGTCGCTTATCAGCCCAGAATAGGCTGAGCTAATAGGTCCAAGAGGCAGTTCTAATTGGGTTGGTTGGCTATCATGCTGTCCCAAGGTATGGATTTTATTTTTTGGAATAAAAAAAATTGTTGGGACACATTTCTCAAGAAACGTAAGGTTTACTA
->XR_003114846.1 PREDICTED: Melanaphis sacchari uncharacterized LOC112597600 (LOC112597600), ncRNA 
-ATTTCTCGGGCTTGTTCCACGGCGTCATCTTTCTGACTCTTCGTCTGTCACAAACAAATTTGTTCCTGAATAGAGCTGAACTCTCTGTTCCGCTCCGAATTTCTCGCCTTTGATTTGTCGTTAGCCCGATTATGAGGGCTAAGTGGCGTAAGAAGCGTATGCGTAGGTTGAAGCGCAAGAGGAGGAAGATGCGTGCAAGGTCCAAGTAAACCTCGTGGCCTGCACAAGACAATATTATCATGTTTTGGTAAACATTAAACGATATTGAAACTTTTATATTAAATCATCTAAACAGTAATAAACTCTTTCTGTTCAACTTATAAAA
->JX816942.1 Uncultured bacterium clone HC1::G9RA0RH03HINL4 16S ribosomal RNA gene, partial sequence 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAGCGGTAAGGCCCTTTCGGGGGTACACGAGCGGCGAACGGGTGAGTAACACGTGGGCGACCTACCTTCAGCTCTGGGATAAGCCTGGGAAACTGGGTCTAATACCGGATAGGACCGCATGTCGCATGGTGTGTGGTGGAAAGTTTGTTCTTAATTGGACACTTCGGCTGGGGATGGGCCCGCGGCCTATCAGCTTGTCGGTGGGGTGATGGCCTACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGCGACCGGCCACACTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGGCGGAAGCCTGACGCAGCGACGCCGCGTGGGGA
->XM_053359157.1 PREDICTED: Podarcis raffonei calpain 7 (LOC128398277), transcript variant X5, mRNA 
-AAGATTGCGCTCCTATCTCTCTCCAGCGAGAGGTGGAGGGGAGGGAGGAGCGTTCTCCCGTATTGCGCAGGCGCATCGCGACGGCGACGCCTCCGCCACAGGGGCTGCCGGGAAGTCCCTTCCTGAGCGGGAGGCCATAGGCGGAGACGTCGGGGGGCTGCCGTGACGTCAGCGAATAAGGAAAGGAGCGCGCTGAGGCGTCTGCTGCCCGGACCCGGCCATGGAAGCGGCGGAGCTGGAGCAGGAGGCGGTGAAGTTCGCGCAGATGGCGGTGCAGCGGGACCAGCGGGGCCACTATCACGAAGCGGCCTTTTACTACAAGGAAGCTGCACAGTCTTTGATTTATGCTGCAATGGCAGGATCAGTCTTGGAAAATATTCCAGAGAAAATAAGTGAATATTTGGAAAGAGTTCAAGCCTTGTACTCAGCAGTGCAAAGAGTCGACCCCTTGAAGTCGAAGCAGCAGCTGGACTTGGAGCGGGCCCGTTTCCTGGTTACGCAGGCTTTTGACGAAGACGAGAAAGGCAACAGCGAGGAAGCGATAGAGCTGTACACGGAAGCCGTGGAACTCTGCCTGAAAACGGCCAATGAAACTTCAGAAACAGCTCTCCAGGCAAAACTGAAGCAGCTGGCTCGGCAGGCACTGGACAGAGCTGAAGCGCTGAAGGATTCAAAGCCATCTCAGAAAGACAAGCCGGTCCCAGCGAAACCAAATCAGCAAGCCCGGACTTACTTTCCATTAGGGCCTGATTTTTCCTTGAACGATAAGCCACAGGCAGTCAGAGCTGTGCAGGCCAGTGAACCTCAAGGTCAGCGATACACCGCAGAGGAGATTGAGGTGCTCAGGAAGACGTCAAAGATCAATGGCATTGAGTACGTCCCTTTCATGAGCGTTGACCTCAGAGAGCGTTTCGCTTTTCCAGTACCTTTCTCAGATAGATGTGGCAAGCTGCCGTTGTCTCCCAAGCAGAAAGCAATGTTTTCCCGCTGGGTGCGTCCCGATGAGATAACAAACAGCCCCACCATGATCTACACAGTGTCGAGCTTCAGCATAAAACAGACAATCGTGTCAGATTGTTCCTTCGTAGCTTCTCTTGCTATCAGTGCGGCATACGAAAGACGATACAACAAGAAGCTGATTACCAGCATTATTTATCCGCAGAATAAAAAAGGAGAGCCGGAATATAATCCGTGTGGAAAATACATGGTTAAGCTGCATATCAATGGGGTTCCTCGGAAGGTGATAATCGATGACTTCCTACCAGTGGATCACAGCGGAGAACTTCTCTGCTCTTACTCCAACAATAAAAGCGAACTCTGGGTTTCCTTGATAGAGAAAGCTTACATGAAGGTCATGGGAGGTTATGATTTTCCAGGATCAAATTCTAATATTGATCTCCATGCGTTGACTGGCTGGATACCTGAAAGGATTGCCATGCACTCAGGCAACCAATCGTTCGACAAAGACAGTTCCTTCAGGATGCTTTACCAAAGATTTCGCAAAGGGGACGTGCTCATTACAACGGCGACGGGAGTGATGACTGAGGAGGAAGGAGAAAGGTGGGGTTTAGTACCAACCCATGCCTACGCTGTTTTGGATATCAGAGAATACAAGGGGCTTCGATTCCTCCAGCTGAAAAATCCCTGGAGCCACCTCCGCTGGAAGGGAAGATACAGTGAAAATGATATGAAGAACTGGACCCCGGAACTTCAGAAATACTTGAATTTTGATCCCAGAACGGCCCAGAAAATAGACAACGGGATTTTCTGGATTGCCTGGGAAGATCTGTGCAAGTATTACGATGTTATATACTTGAGCTGGAACCCAAGTCTTTTTAAAGAATCAACATGCATTCACAGTACCTGGGATGCAAAGCAGGGTCCTGTGAAAGATGCATACAGCCTAGCTAACAACCCACAGTACAAACTGGAGGTTCAGTGCCCACAAGGTGGGGCTGCCGTTTGGATCCTGCTCAGCAGACACATTACGGACAAGGATGACTTTGCTCACAACCGGGAGTTCATCACAATGGTGGTATACAAAACAGATGGGAAAAAGGTTTACTATCCTGCCGACCCTCCTCCGTATATCGACGGGATTCGAATCAACAGCCCCCACTATCTCACCAAGATCAAGCTGACCTCTCCGGGAACCCATACGTTTACTCTGGTGGTTTCTCAGTACGAAAAGCAGAACACAATTCACTACACGCTCAGGGTGTATTCAGTGTGCAAGTTTAATTTCTGCAAGATCCCGACACCGTATACCATATCCAAACGGGTAAATGGGCAGTGGAAAGGTCAAAGCGCTGGCGGGTGTGGGAATTTCAGAGAGACCGCCAAGAACAATCCTATTTACCAGTTCCAGTTGGACAAGACCGGCCCCCTCCTCATTGAGCTACGAGGACCAAGGCAATACAGTGTTGGCTTTGAAGTGGTGACCGTCTCTACAGTGGGAGAGCAAGGCTTTCAGAAGAAAAACAGCGGCGATTACAGTGAGCCTGAGGCCAGGGACTGTCTGGGAGAAATATATATTTAAATGGCTGAAATGCTTTTTAATTCTGCAACTTGGATGCTCAAGGGAAGAGTCTACGGTGCACACAATAATATTAAATCCAGAGCTTTGGGTGGTTTTCTTTTTACTATTTATCACTGTGCCACAAATGGGACAAACAATTGTACCCCTTCGCTCTGACTTCCAAGCTTGAATCTTGCCATGTATCAGAGAAAAAAAGAAAACACACACGACAACTGTTTAGTTTT
->AY736006.1 Aedes aegypti inositol-1 monophosphatase mRNA, complete cds 
-GGGGAGTATTATTCAACTCGTAAAGTCATTCAGTCCAGTTTTTCTAATCATTATTTGAAACATCCGAAGCTCCCTCGATAATTGAAAGCAAATAGCCGAAATGTCGCTCGATTTGGACGAATGTTACGAGCATGTCCTCGGATTGGTAGAACAAGCTGGACAGATTATCGCATCGAGGAATTATGGGGAGAAAACGGTGGTGGAAAAGTCCAGCAACATTGATTTGTTAACCGAAACAGATCAGCAAGTCGAGCGACTTCTGATGGATGGTATAACTGAGAAATATCCCGATCACAAGTTCATTGGTGAGGAAGAAACCAGTGCCGGGAAGAAGGCAGAGCTGTCCGATAACCCTACCTGGATTATCGATCCAGTGGATGGCACCATGAATTTCGTTCACAGTTTTCCCCATTCATGCATTTCGATTGCGTTGCTGGTCAATAAGCAAGCCGAAATTGGAATCATCTACAATCCGATGCTGAACCAGAAATTTACGGCTCGCCGAGGCAAGGGCGCATTCATGAATGAGAAAGCGATTCGGGTTTCGGGAGAAACTCGACTGGAGCATGCTTTGGCAACGACCGAGTTCGGCACTAGTCGTGACGAGGAGAGGACGGCTATCGTTTTGGAGAACATTGGGAAACTGATTCGAGTTGTTCACGGGATGCGAAGCTTGGGATCTGCTGCCCTAAACATGGCCATGGTTTGCCCTGGGGTGGAGCTGATTTTCAACTATGAAGTGCGGGTATCCACGCCCTGGGGATATTGCCTGCGGGGGGAATTTGATTTGTCCCGGGAAAGCAGGCCGGGTGTCTGTCTGGATCCAGCTTGGAGGACCTCCTGGATCTGATGTTCTCCCCCCCGGGTGGCTGTGTGCCAGTTTCGCCAGAGCTTTGGCCGGAATAAAGGTGGTTCCATTTGGGTTGAACGCCAGTACTTTTCCGCCAGCCCAGAAGACTTAGGAAAAAGTTCCCCCGAATGGGTTGGGATAAAGGATTT
->BC169882.1 Xenopus laevis signal transduction regulatory protein SAP-2, mRNA (cDNA clone MGC:196609 IMAGE:9041516), complete cds
BC170158.1 Xenopus laevis signal transduction regulatory protein SAP-2, mRNA (cDNA clone MGC:196885 IMAGE:9093539), complete cds 
-TCTGCGGTGTTGCCTGTTTTAGATTTCATGACTCAAATGCTTTAGATAATCATGATGGAAATTATTTCCACTTTATTTTTTCCTATTATTGTTGTAGTCCTGGCAAGAGTCATTTCACTTCAGCCTACGAGTGTCTATTCGTGTGCTTGTGGGATGGTTTAGTAATTAACACGTTTATGTCTCCACCTGTGGGATCCTGTCTCGTCTTTGCTGCATTTACTTTTGAAGAGTTTAAAGGCAGCTTCTTCCTCTCCAGCTTGTCTAGAGGTGCATCTGCCATTGCCACTCTTTCATCACACTGTTCTGCCCGCAATGGAGAAGGTATCCGTTTATCATGGGAACATAAGCCGTGAGATGGGCGAGAAGCTCCTGAGTGATGCCGGGAAAGATGGGAGTTACTTGCTACGGGATAGCGAGACCATGCCGGGAATGTATTGCCTCTGTGTTCTGCACAAAAATTTGGTCTATACATACAGAGTTCATCAGACATCAACTGGTTCCTGGACTGCTGAGGCTGCACCTGGCGTTACAAGAAGGCTGTTCCGGAAGGTGCAAAATTTGATTTCTGCATATGAAAAACCAAACCAGGGAATTGCAACACATCTGCAGCACCCAGTGGAGAGGACGGTGACAAAAATTGTTTAAGGGTGATTAATGGATGGATGCTTAAACAAATGAGTCATTTGCAGATCAATTCATTCGACGCTGCCTTGAAGAGAG
->XM_040760640.1 Sporothrix brasiliensis 5110 uncharacterized protein (SPBR_02337), partial mRNA 
-ATGACTCCTCGCCAACCACAGAGCGACAGTGGTCGTGCCTGTACGTCAATTGTCACAGAGTACCACCGCAAAAAGCCGAATCAGGAAGCGCCGTTTTTGATCGAGGTCGAATACTTGAACTCTGCCGGCATAAAGGCCCACTTACAAGAGCTGCTTTGGAACTATCGCCGCATCTACCGTCCGGATATTGACCCAGAGGCATTGGGTGATGCCGAATACAAGCGACTCGAGGCTACATCCAGCACGGCGTGGTCGACTCTACAGACAGCGTTCCGCCATGAACGTGGCTTTAGTTCCTCGTTTGCCCTGAACATGGACGACGGTTCCGACGAGCGCATCCTGGAACAGCTTGTCACATGGGCGGGCCGCATTGAATGGCCACGCGGAAGTGACGAGGGCTTCTGGACAACTACGGCCCTCTCCGTGGACGAGTGTTGTGATGCTACGCGGCCATTCATGGAGGATAAGTTCTGGCCGTTTACCAATCTTATCAGGATATTTCTCAGTGCACGTGTGCTCGACTCCGGTATCATCCTAGCCGACCTCCCCGGACTCCAGGACGTCAACCTGGCTCGAGTCCGTGCGGCCCACGAATACGTTCTGCAATGTGACAGCATTCTTGTCGTGGGCCGCATTGCGCGGGCAATCTCTGATCAGTCTTTGCGGTCATCACTCTACACGTCCCTTGCAAGTCACGCCCCAAACGAGTGGCAGGAACAAGGCGCAGCCCGCCTAAACATCGCCGTTGCACTTTCGCATGCGGAAGACATTAATGTTCGATCTGCACGGCGTGAGATCCAAGACCCAGAAATCAAGGCCAAACTGGATCGCCTCGACATCGAGATAAACAATGCACAAGCCGCAGGTTCCCTTCGAACGGAACAAAATATGAAACTCATGCGAAAGCGACTGTTGGTCGAGGAGAGAAACAAGAACGTCACGAAAGGCTTGCAGGATGCTTATGCCTCCAAGATGATCAACCAAAACAGGCAGTTGCCCGTTTTCTGTATTTCCAACAAGTGGTACGAAAAGTTTACGGCCATTGGAAACACAGAGCTCGTGCGGGAAAGTCAGATTCCCGCCCTCCGACGACACTGCCAAGCCATCGCAGCGGATGCCCTACTGGGCGAAGCAAGGCACTACTTACGAACAAGTCTTCCCTCTCTCGTCACCTCGCTCGACCTCTGGGTCACAAATTCCATTGCCACGCAGGCTCTGCAGGGAGACGGCCGACACGACCGATCTGATCCCTCCGTAGATCGCGTCCGCCAAGTGGTCCGCGGAATCGACGACGAAAATTTGCTAGGCCCGGAAAGTGACTGGGTCGACAACGTCGAAAGTTGTTTCAACGAGGAAATAATGGAATTTTTCGCCAATAGGGGTGACATATGGAAGGATCAAGCTGTCAACGAAAGCAACAAGTGGACTGTAAAGTCAGGTCCTAACTACTGGCATCAAACCCATTACAATTCATGGTGTCTTCATGATGGCGATTGGAGCACACCAAAGAAGCCACATGTCAACTGGAATGCCGAGTTGATCTGGAAGATGCGGACCGAGCTCGAGCTGCAGTGGGACATTTTCGAAGAGCAAACGCATGACGAGTTCAAGGCCGTACACGAGAACCTTGGTGCAAGCCTCGTTGAGCTGAAGGACGCTATTGGGTCTGCAACTAGCGTCCCAGGGCGTGAAGGACTGGTGCGCTTGATCAACTTCAGCTTGCACGAGTTCAAGCACTCCCTGGACCAAAGAGAGCGACGCTTCCTCGTGACGCTGAGGGCTACGCGCAGCAAGACCAGTGAAGCCACATGCGCGTCGTATATTGTCGAGCACATGCTTCCGGCATACCGCGACGCGTCGCTGGAGTTTGGGACCGGACGGCGTATCAGGCAGGAGACGATCATCGGCTCAAAGGTAAGCAGAGGTGACATATTTCTCAGCATGGGCAGTGCATTGGCGCGTGATATCCAAAGTCTTCTCCGACACACAGAGGAGGAGATCGAGCGCGCCATAGAATCGATGGCTGAACACATTCTGCGGAATGTCAAAATGGCATTTGGGGCCGATGAGACTCCTCACACGTCTGTGCCATCAGCTGCCCTGCGGAATGCCGAATACAACGAGCGCCTGCAGCACTTTTCGAGTATGGTCTCTGTCTGGAGAGAACAGTACTCGCTTTTGTTTGCGAGCGAAGATGGGGCGTTGGACTCTCTGTTGTGA
->XM_027854401.1 PREDICTED: Vombatus ursinus myo-inositol oxygenase (MIOX), transcript variant X2, mRNA 
-CTCAGACAGATCACACACAAGCCACGGGTGACACTCTACACACCCCCTTCCCATCCTGTTCACTGCTAGGCCTGTGGTCAAGATGAAGGTTTTAATGGGTCCAGATCCTTCTCAGATTTATCGGCCTGATGGGGGCAAAAATAAAGAGGACTTCCGAAACTACACTTCAGGACCCCTCCTGGATCGAGTCTACACCACCTACAAGCTCATGCACACGCACCAGACCGTGGACTTTGTCAGGAGGAAGCACGAGGAGTTTGGTGCATTCTCCTACAAAAAGATGAGTGTGATGGAGGCCGTGGAGCTGCTGGACGGGCTGGTGGATGAGTCTGACCCCGACGTGGACTTTCCCAATTCATTCCATGCATTTCAGACGGCTGAGGGCATCCGGAAGGCTCACCCTGACAAGGACTGGTTCCACCTCGTGGGGTTGCTGCATGATCTGGGGAAGATCCTTGTCATGGCTGGGGAGCCTCAGGATAATCCTGACACCAAGGACCCTCGATACTGCACTGATTATGGAATGTATGAGCCCCACTGTGGCCTGGAGAACGTACTGATGTCCTGGGGCCATGATGAGTACATGTATCGAATGATGAAGTTCAACAAATTCTCCCTGCCTCCGGAGGCCTTCTACATGATCCGTTTCCATTCCTTCTACCCTTGGCACACCGGTGGCGACTATCGGCACCTCTGCTGCCCCCATGACCTCAGCATGCTGCCCTGGGTGCAAGAATTCAACAAGTTTGATCTCTACACCAAGTCAGAGGACCTGCCAGATGTGTCCATGCTTCGGCCATACTACCAGGGCCTCATTGACAAGTATTGCCCCGGGGTCCTTTGCTGGTAACGGCCTCTGCTCTGGTCTGAGCCAGCTTCTTGGCCCTCATACAGCCGGTCAGACTCACTTGCCTCACCAGGGGCAGCCAGCCCCCTCCCTTGTACACACCAACCTGTCCACAGGCCCCTTTCTCCCCCTTCCTATGAGCTGGGGATTATCAGCCCAGAGACCACCCCGAGCCACTGGCCACCCCCTTAGCTGACCTCTCCATCCCACTAGCAGCAGCATCCATGTCTTCATTATCTCCATACCTCATTGCCAACTCCATCCCCGTTACATCATCATTGCCAGTCAGCAGGTGCCCATCACTTTCCTGCTTACCATTCTCACCATCATTTGCAGCCGTCTGCACCACATGCTCTGGGGGTCCCTGGGCACTGCTCATCTCTCCAACCACACCCGCAGATTCTTAACACTCCTGCCGAGAAATAAAGACCGTACAGAACCCTG
->XM_044147674.1 PREDICTED: Aphidius gifuensis vesicular integral-membrane protein VIP36 (LOC122849090), transcript variant X1, mRNA 
-TAGGTTGCTTACGCAGCTCACTTTTTTATCATTATCATGTCATAAATATTAAATATCCATTATATCATTTACCTATTGTGATGTGTCGTTTTACACGAGCTAATCAGCGCTCATTTTTCCATTCGTGACTTGGCAAGATAATTATCGACCTGTGGCCCAATAAATTTGATTAAAAAAATCTTCAAAAATTCATTCAGATCTATAAACAACTAATTTGATTGCGTTTGAGTGGTTTGAAATAAAATTTTGATCACAACCGGTCAAACCATCAAGAGGTGCTTGTTAAATTGATATCAAGATGCATTCATGGTTGTTGTGTGTTGTGATTATTGGATCTGTCAATGCAGAATGGAACACCAAAGATTTTATGAAAAGAGAACACTCTCTTGGCAAGCCATATCAAGGTATGGGAATGTCAGTACCATACTGGGATTTTATGGGCACCACAGTGGTCACAAATGACTACATAAGGCTAACAAGCGATATTCAAAGTCAACAAGGATCACTCTGGAACTCTGTGCCATGTAACCTCAGAAATTGGGAAGCCCATATACATTTTAAAACTCACGGTAAAGGACGTGATTTATTTGGTGATGGTTTTGCAATATGGTATGCATCGGAAAAAATGATGCCAGGTCCTGTTTTTGGTTATAAAGATTATTTTAAAGGTCTTGCTATTATTCTTGATACATATAGTAATCACAATGGCCCACACAATCATCAACATCCATACATATCGGCCATGATTAACAACGGCACATTACATTATGATCATGACAGAGATGGTACACATACTCAGTTGGATGGTTGTGAAGCCAAATTCAGAAATCTTGATCATGATACGTATCTGTCCATCAGATACGAGGGAGACACCTTGACCGTTTCAACTGATATTGAAAATAAAAAGGCTTTCAAAGAATGCTTTTCAGTAAAAGGAATTCAACTACCAACACATTACTACTTTGGTATTACTGCCACAACTGGTGATTTATCGGATAATCATGATATTTTGTCATTTAGATTATATGAACTGGACACACCAGTCGATCCGAATGATATCCAGGATCGTTCCGCAATCGTTCCATCAGCAACATACTTTGATTCTCCACGAGAACACATCGATGATCCAAAGCCATCGTCTATGAGTGGATTTAAGATATTCTTCTTAATGCTTGTTAGTGCAATTGCACTCGTCGCCCTGGTCGTCGTAAGCATTATGGTTTATCAAAAACACCAAGAAAACAGTCGGAAACGTTTCTACTAATAGAAAAAAAATAATAATAGATATTAAGAATCTTCCAAGACGTTATTAGAATAATTCAAGAATCAAAACATTGTACACAATTACATATTTCATAATTTTTTT
->XM_025922904.1 PREDICTED: Puma concolor solute carrier family 30 member 8 (SLC30A8), transcript variant X2, mRNA 
-ATGGAGTTTCTTGAAAGAACTTATCTTGTGAATGACAAAGCCACTAAGATGTATGCCTTCACCCTAGACAGCGTGGAACTCCAGCAGAAATCCTTGAATAAAAATCAATGTCCTGGAGAGAAGCCAGAGGAGCTGGACTCAGGAGCCATCTATCACTGCCACAGCAACTCCAAGGCCACAGAGAACAGAGCAAACGAGCAAGTCTATGCCAAGTGGAAACTCTGTGCTGCTTCAGGAATATGCTTCGTTTTCATGATTGCAGAGGCCGTGGGTGGGCACATTGCTGGGAGTCTTGCTGTCGTCACAGATGCTGCCCACCTCTTAATTGACCTGACCAGTTTCCTGCTCAGTCTCTTCTCCTTGTGGTTGTCATCAAAGCCCCCTTCGAAGCAGCTGACGTTTGGATGGCACCGGGCAGAGATCCTTGGTGCCCTGCTGTCCATCCTGTGCGTCTGGGTGGTGACGGCTGTGTTGGTGTACCTGGCATGTGAGCGCCTGCTGTACCCTGATTACCAGATCCAGGCGACTGTGATGATCATCATTTCAGGCTGTGCGGTGGCAGCCAATATTATACTAAGTGTGATTCTGCACCAGAGACATGCTGGACACAATCACAAGGAAGTGCAAGCCAATGCCAGTGTCAGAGCAGCCTTTGTGCATGCCCTCGGAGATCTATTTCAGAGCATCAGTGTGTTAACCAGTGCACTTATTATCTACTTTAAGCCAGACTATAAAATGGCTGACCCAATCTGCACATTCGTCTTTTCCATCCTGGTTTTGGCCAGCACCATCACTGTCTTAAAGGACTTCTCCATCTTACTCATGGAAGGTGTGCCAAAGAACCTGAACTACGATGATGTGAAAGAGCTCATCTTAGCGGTGGATGGAGTGGTGTCTGTGCACAGCTTGCACATCTGGTCTCTAGCAATGAACCAAGTGATTCTCTCGGCTCATGTTGCTGCAGCAGCCAGCCGGGACAGCCAGGTTGTTCGAAGAGATATTGTAAAAGTCCTCAACGATAGCTTTACTGTGCACTCACTCACCATTCAGATGGAATCTCCAGCTGACCAGGACCCTGACTGTTTTTTCTGTGAAGAACCCCGGGACTAG
->XM_025582792.1 Aspergillus brunneoviolaceus CBS 621.78 hypothetical protein (BO95DRAFT_367563), partial mRNA 
-ATGCTCGGTCGACTATTGAATACTGCAGCGGCCACTCTCAATCCGACGGCATACTCCGCGAAGAACCCCCAGCCACTGGAATCGGTCACAGAGGAGGAACATACATCGGGCTTGCTTTATCCTGACGTTAGCCTTCTTCGCCGCTCCAACTCACACGCGTACCCCCTTCATACCGCTTTCAATTCCCCGAATACCTCGACGGCCGGTGGATATGATGATCGTGGTGGCGGCGTCGAATTGGACCACCTGAAGGATTTCCGTGTGATAATCGCCCAGAACGCGCTGGGAGACCGGGATGCCTGCGTGTTACTGGATACCCGGGCCACGCCGCAGGGACAAGGCTCACATGGTCTGGGCTTGGAGCCACAGGTGTTTGAAAATACTGGTACCCGCCATGCCCGCACGCTCTCCACGTTGACTCGCGGCCCGCGGCGGGGTTATCTGCCTCAGTCATCGGTCGTGGAATCAAGCCCGCTGTCTGCGGCCGCAGAGACACGGCGATCCCCGCCCATGTCTTCTGGCGCGTTCATGAGGGCACGGGTTCGTAGCTCTACGCTGGCGCCAGGTGGGAACTTCACCGAAGGTGGCCATTCCCGGGGCACGACGGATGCGAACGATTCCGGGTTGCTGAACTGCATCTTCGGGAGCAGTGCTTTCAGCTACAAGGGTTCCTCCACCAAGATGCATATCATTTCCGCCGATGATGAACCGAGTCAAACCTCGCCAGCCTCGCCGGCGGCACGTAGCTCTCTATCACGAGCATATACTACAGGAAGTTCTACGACGTTTGGCGGTTCTGATCGTGGTAATGAGTCTAAACCGCCTGCCAAGGTCACTATCCTGTTGACAAGGATGTTCAGTGTGCATCTGCCCGAAGGCGGAGATGATGACTCCTCTCCGGACAGGCCTGACTTGTCATCTTCAGTCTCCCACGACGCTCTCCCGAGCCCAGGGTTTCCCTTCCCGGATGTCTCGAAGCGCAAGAAGATCAAGGAGAAGAAAACTCCCATGTATGCGGTCGCTATCACAATCCAGATCCCGCTCTTATCCCGAAATGGTGGGCGGCCGGTTTCTCGGTTTGCGCAAGGTCCAGACTCTCCCAAGCCAGGGCTTTCGTGCTCATTGGACTCGGACTACCGTTGGCGTGGAGGCTTCTTCGAGGACAGTCTGTCCCATGCATCCCCTCCTGCAAGTTTGGATGAGCGTATTGATCTGCTGGTTGATCATTGGGACATCATCAACCGGACGTTGTCCCATTTGGAGAGGCTGTCTCGGAACGAGATCCTGTTCTTACTCAAGAAAGTAGACGCCTCGGCAGGGCCGCATCCGAAACCCGCCAAACCTCCAAACATGCAAAGGACGAATCAGACTTTTGTTCATCTGCCGGTCAATGTTTTGTCCATCAATTCCAAACTCCGCGACGAAGCCATCCGCAGCACTCGTCGCATTAGCACGGCTCTGCAGATGCCGTACGTTGTCACAGGCCAGAGCCGCTGGGGCGTCTGGCGTGAAGAAGGGCGGTCGATAATCCGTAGCCTCGGAGACAAAGACCACAGTTTCTTTTTCCTGGTCTTGGTTACTGCCTTCTTGGGAAACCATACGGAGTGGCTCAATGCTGTGGGCCCGGAGTGGTACCGTCGGCGGCACTACCTACAACAGAAGGCTCAGCAAGACGCCGACCCGATGCTGGCGAATCGCACCGTGATCATCTCACCGGATAAGATGACTGCCAGAAGACTGATTTTCTTGCTGGCGGCGTTTTTGCCGCCCAAACAGCGCTTCGAGCCCCTGCCGTCTCCGATTCGCCCTGGCACTGCGGCGTCGACTCGTGCTGTCTCCCAGAGCCCGCCTAATGTTCCTATCCTACGACAGGAGGCATTGCGGAGGGTGATGGAACGACGGTCTCGTGCGCAGCGCCTCAACCTCAATGAGAGAGAGCAGCACCAGCGTTCTGTGAGTGCTTCATCGAATGAGACGGCCCATCGTTCGGCGGAAGAACCCGAGCCCATGATTCCGCCTGATTTTGGTGCGAAGCGCAGGGGCTCAGATGCCCGCTCGATCCGAGCCTTAGGGGTTCCTATCCATACTAGAGACATGCGTCCGAGGAATACCAGTGCAGCCACCACCTCGACCACTACTCCGAGTAGTACCGTCCCCGTCCCGCACTTCGCCTCGCAGAGCCGGTCTGAGCGGATGGGATCGGATCCAAGTGTGGCTGAAGGACGTGACAGCCTGGCGTCGGAAACTCTTCTAAAGAATTTGCGGCGGTCCGAAACCTCGGCAACCTGTGCCAATGGCCAGATGCCTCCCGCGAGTGGCCGCTGGGGCACATTGTTCTCTGGCTTATGGAGCTCTCGTCAGGAGTCATCAGACGCTGGTGACGCCCCTGCGCCATCTGAAGCGCGCAAGCGATCGGTATCTGCTTATACGAACCCAGCCAGAAGGAACCCTCCGACACTTGCCCAGATGGTCAAAGAAGCATCAGAGGAACCCATGCCGGCGGCACCCAAAGCTACTACGAGCGGCAACATCTCTATCCCTCCGGCGACAAACAGTCATATCTCATTCGAGGAGGACGCACCGGATTTCTCGTCGACCACGGACCAGACCAGGGAGTCATCCTTGAGGATGGCCGTTCGTGGAGATGACGGCGTGGTGGATGTGGACCTGCCGCTCCCAGGGTTCCTGTCGCTTTCGTCGTCTGGGGACTCCACGCTGGCTTCTCCCAAGAAGACCCGCACCTCGGTTACTAGTATGGATGCAATGGCATCTACGCAGAGCAGTGTCTCCGGGTTCCACGGCAGTCTCAAGGACAATGATGGACCTAACACCAACGTCGCTGGCTGGCTGCGAACTTTCCATGACGATTTTCTCCTGCAGGCCGTGAGACCATACGCTTCGCTGGAAGCCGATATCAAGCGCGCCATGCAAGCCGAGCCTACACCAAGCCAAGCTCTGTGTCTCAACGCTGATGGTTCCGAACGATGGGTGGATGTTGCGACCACCGTGATTGCGGATGTCCGGAACTTCACCGTGAAGCGACTGCGACTGAGACGTAAACTTGTGGGACATGGGTCGTCGCGCAAGGCGTATACGCCGTCTTTCCCGTCGCAGCCCGGCACTCCGCGGTACGTGTCCAACGGGTCTGTCTCGGCCTCGCAGCTCACCAGCTTCTTCTCGCACGCCACTGGGTCGAGCAAGACATCGAACAATTCCTCCATGGACGATTTCTATCCTACCGAGGTTGAAGAACGGTTCGTGGAAGAGCCCGTGATGGATCTGGATGGCACTCTTGTCGATGCTCTTGAACGGGTGCTTGCACAGAGTGGACCGTCGTCCATGGTGCACTCTCGCGCGCCGTCGCCATCCCGTGGTCGTCGCGGAGAGGATAAGCAGGCATCGGATGCCCCCGTGCCCACACGGGAAGAAATCCGACCTGTCGAGGTGCCTCGGACTGAGTGTCGCAAGCTGGTCCTCGGGGCGCTGGAAGAGGTGGTGCGCAGTGTGACGGCGGAGCATTGCCGCGAGGATGTTGACGGGGAGCTCGGCCTAGCAGATCGCGAGCGCAAGCGTACGTTGGCCGGGGCGGATAATACGCTGCGCGAGGGAGTTCGCAAGTGGCTTCTCGATGTTGAGGAGGCGTGGTAG
->XM_046049963.1 PREDICTED: Micropterus dolomieu ArfGAP with GTPase domain, ankyrin repeat and PH domain 1 (agap1), transcript variant X1, mRNA 
-GCGGAGGAGGGAATGGGACCGAGCCCAGCGTCGCTGTCAGGGAGGGTAAAGCTATCGGAGCAGAGGAGGGGAGGGCAGGCCCGGGTCCAGGGCTGTAAATCCAGGGACATTTGAATCACAATTGAATCCGGTCTGAGGTGAAAGAGGCTCGGCTGGCTGGCTGGCTGCGCTGCGCTGCGGGGGATGTGCGCACACAATGGGAGACGACGCGCTGGCTCCGTCCGGGACGCGGCGGCAGAATAAAATTCACCTCTCTGTTTGTTTGTAATGGAGACGCGGACACCGGAGCAGGATCCAGAGACGTCAGCGGGACACACGGCGGAGGACTCCCGGGGGTAAGGACTTGTGTGAAAGTGTTTCTTCATGCCGGGACGGAGCGCTGCTGCGAGCCCGGAGAGAGGAGCTTGGGACGCGCCTGCTGCCTGTTTGTCTCGTTTGCTGCCAGTTTAAATTCCGCTGGGATGAACACGGAATGTATTTCCTGCGTCAAAGTCCGCGCTGTTTGCACATCTGGATAAGGGGAGAGTCGGTTATTGCCCCGTAGCGTCCCCCCCCCGGTGCGGTTGAACCCGTTTGTGGAGAAACGTTTCAAGTCAATTGACCACTTCCATGTTTTAGACCCTCAGACTGCAGAGCTCAGTGTGAGCAAAACAACAGAAACCCTCTTTTTAGTTTAATAAAGACATCATAAAGGAGACGACAGGATCATTTGAGTGATTTTTCTAATGCAATAAAGCCTCGTTAGAGTTTCTGTTGGCTGCTGCAGACTTTAGATCAGAGCTGAAGAGGAGCTCTTTCATCAGGGATGTACCTTCTGGACAGTAACTGCACTGAAAGGATGGAGAGGGGCACGCCTCAGAGGAAAACTGTCTACCGCATCTCGCTCACCTTGGTGAAGAGGGAGAGTTTAGATGGTGAGGATGAAGGCTCAGGCCCCCGGCGGGCGGAGAACCCCAAGGTGGGCACCATCCGGCGGGAGAGCTCGGTGGAGATCCAGCGTGGCGGCCTGCTGGAGCAGCTGAAGGAGGTGGAGGACGAGTCGGACGACTTGTCGTCGTCCCGGGGCTACATGAGGAACTTCAGGACGTTCAGCACGGGGCAGCTGGAGCTGGGGAGGCTGAAAATCTCCAGGAAACAGCAGCTACAGAAAGAGCCGAAGCAGAAGGCCTCCAGCCCGGTGGCAGAGCACGCCGCGGAGGCCCCTGAGAAGATGTCGGCACAGAGTCAGGAGCACACTCGGGGGGAGAGCAGAGAGCAGGAAGCGGAGGACTCAGACAGACTTAAAGAGGAAATCTGCTCTGAAACTCACAAACAAACAGACGCTGCCGTGGAGACGAGCGGCGTGAAGAAGAAGAAGAGGCTGGTGAAGGCTCAGAGCATGGAGGAGAGGAGCTCCGACCCTCCTCTGAACGGTGATGGGTCTCACTCCAAGAGCAACGGCAAAGCAGCCAAAGCTCCCTCCCCTGAGACGCCCCCTCTGAAGCGGCCGCCCGGCCTGCTGCGCCGCAGCTTCAGCTTCAGACACTGGAGCGGCGGCGAGCTGCTGCGTCTGCGAGCGCTCTCCAAAGACAAACACCACAGCAGCTCCAGCTGCATCGGGCGTGACGCCGGGCCGGGCGGCGGCGAGAAGGAAGCGGAGGCTCCTGTCGCGCTCCCGGCTTCCCGCCTCGCCGACCCCACCAGAGTGAAGAGCAGGACTCTGGAGGTCGGCGCCGTCCTGAACAAGACGGACTCCATGTCTGAGCTGAGCCGCTGGGAGAGAGCGCGGGGCAACAAGAACCGGACGCTGGACAACAGCGACCTGCAGCGGCTGGCGGCTGAGAGGGACGGGTCAGGAGGGGGGTTCCTGCTGAGGGGAGGGGGAGGTCGCTCCAGCGAGAGGCGTCTGGTTCGCTTCTTCAGCGGGATCTTCTCCAGGAGGGACGGGGCAGCCACCTCGACCCCGGTGGGAAGCCCCAGCAGCCTCCCGCGGAGCAAGAGGAGGGTTCTGTCCCAGTCCAGCACCGAGAGCATGAACGGAGGAAGCTCTGAAGATGCGTTTGTGAACAGTCAGGAGTGGACGCTGAGTCGATCGGTACCAGAGCTGAAAGTGGGCATTGTGGGTAACCTGGCCAGTGGTAAGTCGGCGCTGGTCCACAGGTACCTGACAGGAACGTACGTCCAGGAAGAGTCCCCTGAAGGCGGACGCTTTAAGAAGGAGATCGTGGTCGACGGTCAGAGTCACCTGCTGCTCATCAGGGATGAAGGGGGCCCCCCGGAGGCTCAGTTTGCGTTGTGGGTCGACGCCGTGATCTTCGTCTTCAGTCTGGAGGATGAGATCAGCTTCCAGACCGTTTATCACTACTTCAGCCGCCTCGCCAACTACAGGAACACCGCCGACCTGCCGCTGGTCCTGGTCGGCACGCAAGACGCCATCAGCTCAGCCAACCCGAGGGTGATCGACGACAGCCGAGCCAGAAAGCTCTCCAACGACCTCAAACGCTGCACCTACTACGAAACCTGCGCCACCTACGGCCTCAACGTGGAGCGGGTCTTCCAGGACGTCGCCCAGAAGATCGTGGCTACCAGGAAGAAGCAGCAGTTGTCCATCGGGCCGTGCAAGTCGCTCCCCAACTCGCCGAGTCACACGTCCGTCTGCGCCACACAAGTGTCAGCCGTCCACATCAGCCAGACGAGTAACGGCGGCGGCAGTTTGAGCGACTACTCGTCGTCGGTGCCGTCCACGCCCAGCACTAGCCAGAAGGAGCTCCGCATCGACGTGCCGCAGACCACCAACACGCCAACGCCCGTCCGAAAGCAGTCCAAACGCCGCTCCAACCTCTTCACCTCGAGGAAGGCGAGCGAGTCGGACAAGGACAAGAAAGGCCTGGAGGCTCGAGCCGACAGCATCGGCAGCGGGCGAGCCATCCCCATCAAACAGGGCATGCTGCTGAAGAGAAGCGGTAAATCCCTCAACAAGGAGTGGAAGAAGAAGTACGTGACGCTGTGTGACAACGGACTGCTCACCTACCACCCCAGCCTGCATGACTACATGCAGAACGTCCACGGTAAGGAGATCGACCTGCTGAGGACCACGGTGAAGGTCCCGGGGAAGAGGCCGCCTCGCGCCGTGTCCACCTGCGCGCCCGTGCAGAGTCCCAAAACCAACGGCCTGACGAAGGACATGAGCAGCATGCAGCTCGGACAGACTCCAGGTTCGGTGAGCAGCAGCTCGTCGGTGTCTCAGATGGCGAGCGGCGTCAGCTTGGTGTCCTTTAACAGCCGAGGTCTGGAGGGGATGCACCAGCGCTCCTACTCCGTCTCCAGCGCCGACCAGTGGACCGACGCCACCGTCATCGCCAACTCCGGAGTCAGCACGGATACCGGCCTCGGAGACTCGGTCTGCTCCAGTCCCAGTATCTCCAGCACCACCAGTCCGAAGATGGAGCCGCCGCCATCGCCGCACGCCAACCGCAAGAAGCACCGGCGGAAGAAGAGCACCAGCAACTTCAAAGCCGACGGCCTCTCTGGTACTGCGGAAGAACAAGAGGAGAACTTTGAGTTCACCATCGTGTCGTTGACGGGGCAGACGTGGCATTTCGAAGCCACTTCGTACGAGGAGCGAGACGCCTGGGTGCAGGTCATCGAGAGCCAGATCCTGGCCAGCCTGCAGTCCTGTGAGAGCAGCAAGAACAAGTCTCGTCTGACCAGCCAGACGGAGGCCATGGCTCTGCAGTCCATCAGGAGTATTCGAGGAAACGGCCGCTGTGCCGACTGTGAAGCCCAGAACCCGGACTGGGCGAGTCTGAACCTCGGGGCCCTGATCTGCATCGAGTGCTCGGGCATCCACAGGAACCTGGGCACCCACCTCTCCAGGGTTCGCTCTCTGGACCTGGACGAGTGGCCGCTGGAGCTCATCAAGGTCATGTCGGCCATCGGCAACGAGCTCGCCAACAGCGTGTGGGAGGCCAACGCGCAGGGACGCCTCAAACCTGGGCCGGACGCCAGCAGGGAGGAGAGGGAGCGCTGGATCCGGGCGAAATACGAGCAGCGTCTGTTCCTGGCGTCGCTGCCCGGCACCGACCTGTCTCTGGGCCAGCAGCTGCTGAGGGCGACGGCCGAGGAGGACCTTCGCTCCGTCGTCCTGCTGCTCGCCCACGGGTCACGACAGCAGGTCAACGAGACCTGCGGAGAAGGAGACGGACGCAACTCGCTGCACCTGGCCAGCCGCAAGGGCAACGTGGTCATCACGCAGCTCCTCATCTGGTACGGCGTGGATCTGATGGCGAGGGACACCCACGGCAACAGTGCGATGGCATACGCTCGGCAGGCCAACAGTCAGGAGTGCGTGGACACGCTGACTCAGTACGGCTGCCCCGACGAGCGGTTCCCGCTCATGGCCACGCCCAACCTGTCGCGCCGCAACATCAACCGCAACAACAGCTGCAGCAGCGCCGGGAGCGCCGCGCTCATATGACGAGGGCATGTCACCGTCTGACTCTTTATGACAAACAAACAAACAAACGCCGATTTGGGAGAATCCTGACCGTTTATTTTGGGAACCACTACCTGTTGCGACTCTAAGCCCCGCCCACCTCACCTGAGAGCCACCACTGCCGCTGTCGGCTCGTTAAGACTGATTAGAGCTTATCACGGGTCAGTGGTGGCGCTGTTTGTTTGGGAGAACCCTCAACGGGTGGGGAAACCCTAAAACACGGTGGGAAATGTGGTCCACAGTCGCCGATGGCTCATCAGAGCTCTTTGGGAAATAATCACGTGACTTATGACAGCCAATGACGGCCAGTCTGAAAGCTCTAGGGAAATCATACCTCATCACACAGCTATACTTTAACGCTACGCGACCAGCTCCCGCGCAACCTCGCCACGCATCATCCGGCCAATCAAAATCTGTCTAGCCAAAACATATGGTCACAACATAAGGAAGCAAACTGTGAGACAAAAATATCAGGAGGGGGGGGGGGCGGTCTTCATAGCATGCTCACACACAGGAAGCCATCTGAACTGCACATCATCTTCATCATCTTCACCAGTCGAGGACTCCTCTCTGTTGGATCCCTGCAGCTTTTCTCCTCCTCCCACCTGTACTTTTTATTATTTTATGAATTATGTGAACCCTCCTGCCTTTACACCTTCTTTTTTTTTTAAATGTGAACAATATCTCGATGTAAAACTTTAAGAGGAAAAAAAAAGATATCAGATCTTAGAGGTGAAAAAGAAGTGTGGTAGATCGCATGTCCTAGACACTTTTTGCTATTTTAATTTAAGGATTTTTTTTTTCCTTCTCCTGGATTGTGTATATTGTATCTCGATGTGCATTGCTGGACCAATCGTTTAATAATGTCAACACGGTAAGGGGATTTATTTAGTTTGTTTCCGGGTGTATAAAGTCGTTAAGTGTACAGAAGCTCTTGCCAGGCTCAGGGACCGGAGACTCTTGATCATGAACACCCCATCGTCTTTTCCCAGAGTCCTTAACCCAGCGTTCAGAGCGTTTCATTTGTTTTCACTTCACTCAGCTCAGAATCTAACAAAATTTATACTAACGTTATAAGGGAATAATACTTTCTAGATCGTTCCTCAGCTATTCTTGAGCTGGACGATATGATTTAAGATCCATGTCATGATGTATTGTCACATTTCTTCCTTGAACAATAATAAATATAACGATTTGTATGTTTTGGGGTTACAAATAATAATGTTTTTCAGTCATCAAACAATCTGCTGATTATTTTCTTTAGTTTTCCCCATAAAATGTCGGAAGATCTTCTAGTTCGTCTTTTTGTTAGACCGCCAGCCCAAAACCCAAGACCCCAGAAACTAAATATGTACTAAACTGTTCTTGTTCTTCTTCACATGTTGGATTTTTAATACTTTTCTGAACTGAGTGAACTGTGAGCATCTTAAACCCGAGCCTGATTTTACATCCTGGTCAAATAACATTTCATTTAAAGTGTCCCTGAAGTGAATTTAATTGTTTTAACTTGTAAAAAAGAAAAAATGGAATAGACAAGGAAGCAGCTAAGAAACTAACGGAGCGAAAAGGGAATTGATCTGCTTCTCCTTGTTCAGGTGTTTTTGTTAAATCTGTGAGTTCAGTTCACAGAATCTGCTGTCAGCTCAGACACATCACGGTGGTGATGAGAGGGAGGAAACTTTTTTCTTTGTTTCATTTCAGCTGGTAGAAAACTTTTCCTTTTAACAGGCGTAAACGCTCAGTAGAATGAAAAGAGTCAGTGAACGTAACACAAGTTCAAAGTTTCATGGCCACAAAATAGTGTTTCTGTGTATAAAAATCCGTTTGTAATGCTAGAGAGCCAACGCCCTCCAGTCCTGTCCCGTCCAATCAAACAGTCTCCCCGATCTGCTCAGCGAATCACTAAGAAGGGCTTCTTCTTCTCTGGTCTTGTTGTAAATAAACTTCTCTTTCTCTGTCACTCTCTCTCTTTTAACGGTGACGCCATGTAAATTAGAGAGCACAGGAAGTACTTACTGGATGTCGGGTTGCAGAGTGGAAGTGAAATATTAGAATGTGTGTTTGTTTGGGGGGGAAAAACGATATCAGCATGGACTGAATGTTGCGTGTTTTGGCTCAGTGTTGCGCTGATCCATCCAAGGCAGGAAGTTAAACTTTTGCGGCTCACTAGGCGTCTGAACCAATGGTTCCCAACCTGGAAATGTTTGCAGAACTACGATTCCAGTCCGAAGGGTCGCAAGAAGGTTTACAGGATGAGAAATAAAAAAATTTAACATTTACATGGTACAAAGAGGGCTAGAGTCAAGGCGACTAAAGGCCAGTCCAAGACTATTCCAAGTCTGCGCAGTTTTCAGAACGAATCAAGACCGTGTCCAAATGCAAAAAGTGTTCTGTTGAGACAAAGTCCTAGTGTGGTCAAGGTTGAGTCCAGATGTCTGAAATGTGGTCAAGACAAAGAATAAATGGACTTCAGTCCAAATGCGGTCTATTGTTCTGTCGAGACCAAGTCCCAATGTGGTCAAGGTTGGGTCCAGACGGCCGACATGTGGTCAAGAATGAGTCGACCCGACACCAAATATGGTCACGGTTTGAGACGAGACCAAGTCCCAATGTAGTCAAATTTGGGTCCAGGCGGCAGACATGTCGTCAAGAAAAGATCAACTTGAGTCCAAATTAATCAAGTTTGGGTCAATACCATGAGGCCTAAGAAAGCAAACTATTGAAACCAAAACAGTGCCAACTGGGTATTCGCCATACTGTTGTCTCACTTACAGTACAGTCATTTGGAAAATAAGCTTTACCTGGACTTTATTGGCCGAAGCTGGTGGCTGTGCCTGAGACAGAAGTCCACGATGAAACTGGACTCTAGTAAAGTCCACAAACATGCCTACAGTCTTTGCTTGCTTTCCTTTTGCTTAGTCATCCTAGTCATAACTCCTGCAATGATGAGCGGGGATGAAGTCAGTGGCGTGGACTACTGATGCAAACACGGTTCTGTTTACATCGGGTGTTGGCGTACGTAGATGTGAGAACTCGCGTAGTCGGTGGATACAGTCCACATGGTCATAGCTTTTGGACTAAACCCTTGGAATTTAAGTCGTTGGACATTCAAAGCTACTTAGATGCATAAAGGATGGTAAGGTTGGGATCCACTGGTCTAAAGATGCGCTGGTAATTTTAAGCCGTCACACAAGATTGTAAAGAAACACACCTTTCTCACCCTGATGACGACGACGTAGATTTGACTGAGCGTTGATTTCTTTCGTCGACTGAACGCTAATCGATCGTCGGGATAAAAAGCTGCTTAACCTCGACATTTGTGTGTGATGATTTTCACCTTCAACACTATGCTGAGCATCACCTGCTCGTCTCTTAGTCTTTGCTCTCTCTGCTGTTTTCGTGCTCAAATTGTAACGTAAAGGTTGAGAAGCAGCTCTCAAACCGACTGTGTATCCAAGCAATATTCATAAACTCATCAGTCACCGTCACATGGTGACTTCACACGCTGACGTTGCTGCAATATTCCCGTTAAACCACAAACACACTCATGTTTGTAGACTTGTAAGAAACAGTGAAAAGATGAAGTCATCATGAACTGAAAATATTTTCTCCTTCTGCCTTTTTGTTTTAAACGTCTGCCTTTACGTTCCTAATTTCGTCCGACCTTGTAATTGTACGTGCCACGCCCGTTTGCCCTCCCAGTCATCTCAAAGATGGCATTTTATCTTGCATAAATACTAAACCAAGGGGTTTGACCGCAACTTGTGTTTTCAAACTGTTTATTTTATGTTTATATCCGACTCTGTCCTAACTCTACCCATGACAGCAGGACAGGGCAAAGACGTCCTTTTATTTATGACAGAAATGCACTAAATCTGATTCAGTCTGTCTTAAGCTCAACACTTGCCACTACAGCTTTCTTTTATTCTCATATTGGCACTAACTGACGTTTGCTTATTTCTCTAAGCGGTGGCGGCTTCTGGCGGTGTCCTCTGACCTGATTGGTGCTCTCATTTTAACGGCATCTAAATTCTGAGCAACTTGGGAATCCAGAATCCATTTATTTAAGTTCACATGAGGGGAGAAAGCTCAGTAAAATCTGCTTTTAAATGACTATAGGCACCAAAATAATCCGTTGCAGGGTCAATGATAGCGCTGACCGCTAGCGGTGAACAAGCTAGCAACAAGTGTTTTCATTCTAAGGCTAAACCAAGCATGAAAAGTTGGGAAATGTCTAGATTATAGAAACATTGTGTTGGACAAGTCCGCAAAGTCAGTTTATTTAAGTTGTATGGCGCAGGAGAAGTTCTGTAAGGTTCTAACGTTAACCCTTGTTGCAGCTAGTGGTGAGCACTTTAGCATGGCAGCATTGTTTCAGCTTGCAAGCAGTTTCTACTACTACCAGTAAAAATCAAAATCAAGCTGCAGTTATCTAAACACGGCTAATGGAGAGAAGCAGGGCTGTGTACGGCCCAAGTCTGTTTATTTAATCTCAGAATAAACTCTGTAATGGCTGCTTTTAACTGTTTGAATCATCTATCGCTGAAGCTAACTGTAGCTAGCGGTAAACAAACCAGCATGGGCAGCATTGTTTCGGCTTGCAAGCAAACTATAAATGACTTAAAATTGGAAAATGTTTAGAGAATGGAAATGTCTTGTGAATCTCCAGCCCCAGCTAATGATCAGTTAGCTAAACCCAGCTAATGAAAACTGCTTGACACCGACTCTTTTCAGAACAGTTTTGTTTGTTTGTTAATGCATTAGCTGACACTTGAATCCAAAATCTGATGATTTAATCCCATTGCAGCAAAGAAAGCTCAGTAATATCTATTTGTAGTCACAGAAACTGCTGAGTCTGATCTGAAGCTAATTGCCGCTAGCGCTGAATACGTTAGCATGGTTATTTTCAACTTTATCTAAGCGAACTTTACTACCCGTCTTTCTTATTCTTAAAACTAAACATGAACAGTTGGAACATGTTTAGAGACTAGAAACATCCTGTGAATCTCCAGTTGCAGCTAGCAATCAGCTAGTTAATCTCCGCTAACGGAGCGAGGCGAGGCGCAATATATTCTCTAGTGGCGTTAGCACAGATATAACAAGATTCACGCTGCAAACAAGTGAAGCTGCCTGCTTGTAAATGAATCACGTCTGCTTTGAAAGATCCGGTGAACGAAGAAACCGCGCTAATATTGCAGCTCTGCGCCACCTCACCTGTACATAGACTTCAAACTAAAAAACGACTCAGTATGATCAACGTTTGGTTTGTCTGGTTGTGTTATCTCTTGTAGCCTTTACCCCTAAGCTCCACCCACCAGGGCTGTCCTCCACATTATTTATAAACGAACCCCGTGAGGAAGACTCCGCCCCCTCAAACCTACGTTTTTGTATATTTTTCTCCGACTTCTCCACTTTTATTATAATTGTTATAATTTCATCCAGATGCATTATTGTTCTTATTGTCATTGTTATTCTAATTATTATTATTATTGTTATTGACTTTTTGTTGGCTGTACAGTACCGTTGTTGAAAAATTTTACTTAATACAGAGTCTTCTACTGTAATGTGTCTCTTTTCAATAAAGACAAGAATAATGCTTCTTAATATAA
->XR_002412069.1 PREDICTED: Columba livia uncharacterized LOC110358026 (LOC110358026), transcript variant X1, ncRNA 
-GGAGGTGTAGGGGCTTACCATACTGTTCATGACAAGATTGAAAAGTATCTGAATGAGATCCAGAACAGCCAGCACACTGCACTGAGTTGCCAAAACTGAGTATATATATATCACAGAACCACGTTGAATTAGTCAGTGGGAACACTGAGGACTTGAGTGCTGAGAGCGACCTCCAGGCACCTTTGCCTGTGACAGATCAGGACTGTGGCCACATATTCCTCCTTGCCACGCTGGTCTGGCTGACTCAGGGAGACATTTACACCAATAGTTGATCCACTCACCTGTGATATTTTCAGCTGATTGACTCAACTGACATGCAGCATATTGTCCTCGAGGAATGACAGCTCAGGAATGCACGAGCCTTGTTCTCCTCCTGCAGCACATCTTCCCCGGTCAGCTGTGTCCCACCTCCAGCCTCACCTCTGCAGCAGCTCCTCTGGTGAGTCCAGCGTGATGGGGACTGACTGTATCATGGGCACATAATGGAAAATTAAGGCAGAAATAAGACTACGAGCACAGGATTACGAGCTCCCTAAGGTGGACACGAAGATTTACAAAGACAATATGTCATTTGGATTTTTCTGATAGAAACGTTTAACAAAAGAATATTCTTTCTAATGGCAATTTTCAATGAGATCCCACTTTCCTGTGGGGGTCTTGTGTGTAAAATTTTTACTATTTCCTTGATATTATTTAGCTTTGCAGCTAATCCATTATACAAAAGGAAATAAGAAAAGAGGGTAAGAAATGCCTTCTTCTGCAATGACATGGTTCTATGTTGATTTTTACATTCCAGGTAGGATAGCTACATAAGGACAGACAGG
->XM_006834443.1 PREDICTED: Chrysochloris asiatica PDZ and LIM domain 3 (PDLIM3), transcript variant X3, mRNA 
-ATGCCCCAGAACGTGATCCTGCCGGGTCCAGCGCCCTGGGGATTTAGACTCTCAGGAGGTATAGACTTCAACCAGCCGTTGATCATCACCAGGATTACTCCAGGAAGCAAGGCTGAGGCTGCCCACCTGTGTCCTGGAGATGTCATCCTGGCAATTGACGGCTATGATACAGAATCCATGACTCATGCAGACGCGCAGGACAGGATTAAAGCAGCGGCACACCAGCTGTGTCTCAAAATTGACAGGGCGGAAACTCGCTTATGGTCACCACAGGTATCTGAAGATGGGAAAGCTCATCCTTTCAAAGTCAACTTAGAGTCAGAACCACAGGATGTGAACTACTTTGAACACAAGCACAATATTCGGCCCAAACCTTTCATAATCCCAAGCCGAAGCAGTGACCCGGTAGCCTCGGTGCCCCCACAGTCAGATGTGTACCGGATGCTCCACGACAGTCGGGATGAGCCTACTCAGCCTCGCCAATCAGGCTCCTTTCGAGTGCTCCAGGAGTTAGTTAACGATGGCCCTGATGACCGTCCTGCTGGAACTCGCAGTGTGAGGGCTCCAGTTACAAAAGTCCATGGCAGTGCTGGTGGCGCACCAAAGATGCCGTTCTGTGACAAATGTGGCAGTGGCATTGTTGGTGCTGTTGTGAAGGCACGGGATAAGTTCCGGCACCCGGAATGCTTCGTGTGTGCTGACTGCAACCTCAACCTCAAACAAAAGGGCTACTTCTTCTTAGAGGGAGAGCTGTACTGCGAAACTCACGCACGAGCCCGCACGAGGCCTCCAGAGGGCTATGACACAGTTACTCTCTATCCTAAAGCTTAA
->XM_020957015.1 PREDICTED: Drosophila serrata uncharacterized LOC110187620 (LOC110187620), transcript variant X4, mRNA 
-CTATTCAAAAGTGAAATTCTAACATTTTTATTCAAACAAAATTTTAAGTTGAAAATAGCAAAAAATGCGTGGTATTCTTGGCTGCTTGCTAACTTACCGCATGGAACCGCGTCTTTTGCAGATATCACGTTGTTTCAGCTACCATGCTCCGCATTTCCGTCCGCGTAGTGTGCTCGGTGCCAACAAGCTTTTCGAGCTAGCCAGCTCCACTTCCCCCGGTTGCCAGGCGACAAAGATTACAATATCGACGAGTTCCGGTCAAATTCGGGTACAGAGGTACTCGCAGACGACCTCCAATGTCTTTAACATCACCGAAAATGTGGACATGCTGCGCAAGCGGATTAGCTTTACTGGTGCACCCAACACTACTGCTCAGATCCTGCCCATTGGATTAATCACACCAGAAGCTGGTGGCGAGAAGGACCTTAAGATCGTGATTGTTCCTTTAAACTTGGCTGGCATGGATGCCAACGCCCTGAAGGAGACGCTTGAGGCCATTAACCAACTGCGCATGTACGCGCACCATATCGAGGCCTTTTCCAGCAGTATGGTCGACGACTACAATGCCTTGAATGAGGCCTTCCAGGAGGTTGAAGCGAAGAAGGAACAAGAAGCAAAACCGGAGGTTACCGCCGAAGATAATGCAGTCTGGGAGGACTTTGCCACACCCGATGCCACAGCCGATGCCGTGGCCACTCCAGCGGTCGATCTGCCCCTTCAGACCGACACGCCATTGCAGCGCCAGGAGGCGGTTAGCTTCCTAATTGATACCTTGACTAATGCCACTCCAGCAGCTGCCCCCCCGCCGCTGAAGACCACCAAAACTATATCGGCCGTGGCTCAGCCCAATCCGGAACCACCTAGCCCAGCCTCGACCATGGAAACCGACCTTCAAGCAGCTATTCAGGGGGGCGATGCCATTGATGAGGTTCAAGTGGATGTTCCACAGGACCTAAGTGATCGCCTCAACTGTATGGCCGTCTCCTCCATGGAGCTCTCATTCGAGATGGACATGACCAACCTGCGCGAAGCCCTGTCCAACAAAGACGCCAATGCTGTTAGCAACCAAGATCCCATGATTTGCATGCATACCAAAGTGGAAATGGAGAAGCCTACAGAGGGAAAACAAACTGTTCCGCTCAGGTTCAATGGCTTGATTTCGGGACTTGTGGAGCTCGATGCCCAAAAGCTGAATTTGACGGACGAGCAGATGACCGGCTTTAACGATAGCCTCACCGCGTTGGCGGCCAACCTGTGCAGCACAGCCTTGGATAAAGGCTTCTCCAAGGACATCAATCTAACGTTAAAAGCGGATGACACCACCATGAGCCTAGCGCCTAGTGCCGAACTGAAGATTGCTGATCAGCCTCAGGCGAATTTTGCGCTTCCTTTGGAAGTGCCGGTGCCGACTGATAAAGATGGGTGCAAGCATCCACCTGTAAAGCCGAAGCGGAAGTGTCCTGGCAAGTGTCCTCTAATTGATGATCCCTGCAAGGAGAATCCCTGCAAGCGACCCGCCGAAAAGCAGAAGCCGCCTAAGAAAGCTGAGAGTACCACGGAGATCATAGCTTTTGCCAAGGACCCCTGTGAGAAAAAGGATCCATGTGCCAAGGACGACAAGGATGCCAAGAAGGACCCATGTGCCAAGGAAGGAGGCAAGGATGGCAAAGATGGCAAAGATGGCAAAGATGGCAAAGACGGCAAGGGTGGCAAAGATGGCAAAGACGGTAAGGGTGGAAAAAATGGAAAGAATGGGAAGGGTGGCAAAAATGGCAAGAACGGCAAGAAAGACCCTTGTGCCAAGTTCAAGAAGGATGGCAAAAGTGGCAGCAAGTTTTCGACTTTCGCCGCACATCATAAACCCAACAAGCGCTACCTATCCACGGCACTGAATCAGGTTTTTAAAGAGACTGGATCACATTCAAGTCCTAAGGGTCCACGTTTCCTTGTCCACTCGACACTTCTGCGTCGTCACTATCGTGGCACCGTTCCAAAGGCCCCAGAATCTGACCTCAAACAACGAATGGTGCACAAGGCTAGTCCTCCTGCCCGCTTTACCATACACTCGACCATTCTGCGTCGAACCTATTCAAAAAAAAAGAAGTCTGGTAGCGGCAAGTGCTCTAAATTGCAGACCAAGTTTCCTACAAGTAGGGGCAAGGATATCAAGGAGCGCACGGGTATTCGCGACGACTGCTTCAAAGATGACGCTGACAGCTGCCCCTTAAAGACCTGTAGCGGCAAGTGCTCCAAGGTCAAGTTCCCCAAGAAGAAGTGTGACCGCAGTAACAAGGACAAAAAAGAGTAGACAGGCTGTTGGGCCAGGGTGCTCCAGTTCAGCTGCCATCGCAGCAACGATCATTCAGCAC
->XM_019302128.1 PREDICTED: Ipomoea nil putative late blight resistance protein homolog R1C-3 (LOC109154305), transcript variant X2, mRNA 
-GTTTCATTAAGCTACAAGTACTTACCTTGTGATTTGAAGGATTGCTTTCGTTATTTTGGTGTGTTTCCAGAAGACAATGACATACCTGTTAAGAAATTAATCAACTTATGGGTTGCAGAGGGATTTATAAAGCCACATGACAATATGAGTTTGGAAGAAGTGGGAGAGAGTTACTTGCATGATCTCATTAATAGAAGTCTTGTTCAAAGTAATGAGCTAAGTATTGACGGCAAAGTTAAATCATGTAGCATTCATGATCAAGTGCACAAGGTTTGTGTGAGAGAAGCAATAGAGTGGAATGATTTGTGCATTATCAATGACAATCATGCTCCAAACGCTTGTTGTTGGTTAAGCTGTCAAACAAGTCATTGGCCAATCACTCGAGCGAGTTACGAGAATTGCGGTCCTGATGAAATCCATTCTGTTCTCTGCTTTGGTAAAGATGTAAACCATTCAAAATGCAGGTTTGTATACCCATCTTTGAAATTGCTAAGAGTATTGGATTTATCATTAGTTAAATGGTCAAGAGGCATGCCTAGAGAAATAACAGACTTGGTTCATTTGAGATACTTGGCTTTAAGTACCATTGGTTCTCTTTACCAGTTTCGATTTTTCAAGCTTAAGAATTTGGTAACTCTCATAGTTACTTCATGGATGGAAAAATGTCCTTTGCAACTGCCATGTGATATTTTGGATTTGCCACAATTGAGGCATTTGCATGTTGACAAGAGATGTTCACAATATCTCCGTAGCTTAGTAAAAAAAAAACTACAAACTCTTTATTGGTTGAAGGTTGCTAACTCTGATCAAAGCCCAAACTTCGAAATGGTTCCAAACCTAAGGGAACTTGGGATTTACATTGAAGGCCAACTGGCGCCTAGATATCTAGGGAGCCTTGTGCATTTACATCTACTTGAGAAGTTGAAGTTTGAAGTAGGAAGAGTTGAGCGCTTTTATCTACCAATTGGTTTTCCGCCAAACCTAAAGAAGTTGACACTTCGTTATACTTATCTTCCATGGAAAGAGATGGACACAATTGGCAAGTTGCCACACCTTGAGGTGCTTAAACTAAAAGATTTCGCATTCTATGGCTCAAAGTGGGAACCATCAAAGCAGGGCTTTTTGGAATTAAAGGCACTTCTCATTTCACGTTCAAATCTCAAATATTGGAATGCAAATTCTAATCATTTCCCAGTTTTGGAGCGCTTGGTCTTAAGATATTGTTGGGAATTGAAACAAGTTCCAATTAATTTTGCAAATATTGGAACACTGAAGTTAATTGTGTTAGAAAGTTGTTATTCTTCTCTTGTGAGTTCTGCAATGCAGATTTCCTCTGCAAAGAAGTTATTGTTTGAGGGAACGACAAATTGTCCACTTCGTGTTCGTGAAGTTAGAACTAAGGTTGAATTGCCAAATAATGAAAGCTCTGAAGAAGAAAGTTGTGGAAAACTTTGAAGAAGAAAGTGTGAA
->EU813087.1 Uncultured bacterium clone DP1_95 16S ribosomal RNA gene, partial sequence
EU813284.1 Uncultured bacterium clone DP3_43 16S ribosomal RNA gene, partial sequence 
-ATTAGATACCCTGGTAGTCCGCACGGTAAACGATGGATGCCCGCCGTCGGCATATGATGTCGGCGGCCAAGCGAAAGCGTTAAGCATCCCACCTGGGGAGTACGCCGGCAACGGTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGAGGAACATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCCGGGCTTGAACTGCAGGAGAACGATTCAGAGATGATGAGGCCCTTCGGGGCTCCTGTGGAGGTGCTGCATGGTTGTCGTCAGCTCGTGCCGTGAGGTGTCGGCTTAAGTGCCATAACGAGCGCAACCCCTCTCGCCAGTTGCCATCGGGTGATGCCGGGCACTCTGGCGACACTGCCGCCGCAAGGTGTGAGGAAGGTGGGGATGACGTCAAATCAGCACGGCCCTTACGTCCGGGGCTACACACGTGTTACAATGGGGCATACAGAGAGTTGGCCATGCGCAAGTATGGCCGGATCAAGAAAGTGCCCCTCAGTTCGGACTGGGGTCTGCAACCCGACCCCACGAAGCTGGATTCGCTAGTAATCGCGCATCAGCCATGGCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCAAGCCATGAAAGCCGGGGGCGCCTGAAGTCCGTGACCGCGAGGGTCGGCCTAGGGTGAAACCGGTGATTGGGGCTAAGTCGTAACAAGGTAAC
->XM_043073989.1 Brugia malayi Uncharacterized protein (Bma-cdh-5), partial mRNA 
-ATGATGATAACAACATTTGCGCTACAAACGATTCAAAACAATATCAAAATCTCTTCTTTACATTCGCCAACATTAAAGGCTTCATCGCATGAAGGTTATATACCGGAGTCAGCACAAATGGGTACCGCGGTTCGAGTTTCTCCTTCTGCATTTTCAGATTCACTTCAAATAGACATTTATGATGATGACCTGAAACCTGGAATGTCTCCAGTCAGTTATGAATATATATTAACAGGACTAGGCTCGTCCATATTTGCTGTTGACCAGAGAGGTTATGTCTACTTAAATGTACCATATATTGATGCTGATCCTCCGAATCCATCAACATATCAGCTTCATATAGAAGCTCGAGAAGTAAACACGACCCCAACTCGTAGTAGTGAACCAATATCAGTAATAATACACGTTATGGATATCAACGATAATCCACCCCGCTTCAGTTCCTCTATTTATACTGCCAATGTCAGTGCTAATGGTACTATTGATCGCCCTGTCATAAAGATTCATGCAACGGACAATGATACTGGCAAAAATGCACAAATAAGTTACCATTTGGTGTCAATAAGTGATGGAGCGTACAATAATTTTTGGTATGACAGTAAAGCGCATCAATTAAATGCTGTTGGAAACTTGAAAGCTGGTGAACGATATGAAGTTATACTGAGAGCAACTGATGGTGGCGGCCTCTCAAATCAAGCATTAATAATTGTTTATTCTGTACCTGATAATTTTCCAAAAGTAACAATGCTTGACCAGAAAAAGGAATCATTCGGACGGAACCAGATAGCCGGTCTATCTAATTTTTTAGTGGCCAAGTCATCGATTACATCTACATCTGAAAGTATTGATTCACCTGAAATGATCCAAACTTACGTTATTGAAATAAGCGAAGCAATTCCACCTTACTCCATTATCATTACACTTGGGGATGATTCAACGAAGGAACAAGTATATCACACGATCACCGGTGGTAACGAAGATAACAAATTTGCTGTCAGAAACGAAATTGGGGCTTTAATTACGGTGAAGTCGTTTGATAGAGAAGAAACGTCACTTTACACTTTAGAAATCGAAACACGCTCTTTAAAGCTAAATCAACACTTGCATTGGACGATTGTCCAGGTTGTTATAGCGGATATCAACGATAATGCACCAATATTCACTGATCCGCAGCCAGTGAGGTTGCGTGTTAATAAAAGTGGTGTAGTCAATTTTGCCCCAAATACGTATTTGGGGCAAGTGAACGTAGAAGATCCAGATGACGGTGATAACGGACATGTGGGACTCAGAATAGCATCTCCTATGAATAAATTGTTTTCAATAAATGACAGCGGTGCTGTTATGGTAAATGGTGATATGTTAAGTGGACATTTTGGTGAGCATCGAATGACTGTTATTGCCACTGATCACGGTGATCCACCTCTTGAAACTCGAGTCAATCTAATCATCAATATTGAAAATACCGCACAAAGTGTGCTATCAAATTCCATTCAGTTATCAAAAGAATCGAATAGTTTGGAACGTACGAATTTGATGCTGAATAGTACTGGTTCTGTGCAAAATGTACAATTCACATTCGATTCCTTTATACCAGCAACCATGCAAACAGCAGCAGAAAATCCAACACTGCGACTTGCGCCTGTGTTCGAGCTGTCTGAGATTGAAGTTATTGTAGAAGAAAATCAAGCAGACATTGAACTCGTCAAGCTTCATGCTTATTATATGGATGGTAAACCTGGAAGCATCACATATATCATGCTTGCAGGAGATTCATCTCTTTTTAATGTAAACAGTTTCACCGGATCGCTCCTTTTGCTGCGCCCGTTAGATGTGGAAAAAGAAATGTCTTATGAAATTCAAGTTGGTACTGCCGAGGCGACTGTTTTGTTCACCGAGCAAAATTTCCCATATACGGCCTTGGTTCATGTGAATGTTGTAGATGTCAATGACTGGATACCAAACTTTGAGCTTGATAGCTACCAATTTAAAGTGAATGCAGATGCCAAACTCGGCACAGCTATTGGCCAGATTGTGGCATACGATCAAGATAGAACCGCACCGAATAACGAGATTCGTTATCGGATCAAAGAAAGGGACACTAATGAATCATACGTCAATGTAGATCCCAAAAGCGGTTTACTAACTGTCGAGAAAAACCTTCGTCTACTTGCAAATAAAAAAATTTCGTTAAATATAGAAGCAGCAGATGACGGTACGCCGAAACGGTCTAACGAAACGCTTGTTTCAATTGATGTTGAACCTGTAGAAACTATCACTACCATTTTAACAAGAATGCCATCAACGTCTGATGCAATGTTTTCTAACAATAAATTGCAGTTCTCGCAACGGAATTACTTCACTTCTATATCGGAATCGATTCGTTCGCCACATCTGTTACTTGTTTTACCAGTACTGAACAAGTCAGCAAATGAGCGTTTCACAACTTGTTCAATCATTTCTGGTGATTACGGAGGAATCTTTAGCATTTCGACTAACTCCGAAGGTAACTGCGACCTTCGAATGCATGCGTTACTGGACCGAGAAACAGTGGACTCCTATCAATTAAACGTAAGCGTAAAAACAGAACAACAAGTAGACCATGCAATTGTCCATGTAACTGTTCTTGATACATACGATAATGGTCCGAAATTCATTTATAATAACGATGAATACAATGGATATTTTGCAGCTTTGTCCACTGATGCCTCTTCATTTGCATTTCTCACCACCGTGCAGACTAAGAATGTCGGTTTAAAAAACAACAGTGTTATTGTATATTCGTTGGATTCGTTTTCAATGGACTCGAAATACTTTATGGTTGATTTGAGCGGAAAAATCCAGACAAAAATGAGTGCATCACAAATGATGAAAGATAGTCAGAAAAATTATTTTAATTTCCGAGTGATCGCTTGTGACTCTTCTTATACTGTAAAGAAACTGTGTTCCAAAGCGGAGATATTCGTGAATATAATCAGTAATTCAAACCGATTCATTCTATCAGTTCTCAATACCGAACCACATCATCTCATAATTGCTAAAAGGGAGATTGCAAAAATATTGCGAGAATTCACTGGTCCTTGTAAACTACTTCTCTTGGAAAGTATAGAAGGCCGAACTAATATAAAGAAGCAGAAACACGTCGACATGCGCTGGTATGCTATAAATCCAACAACAAAAAGGAGTTGCGAATTTGATGAGTACAGCAAACTTTTCGATAATTCAACGATAAGAATGGTTGCTGAAAAACTAAAACAACGACTTATTATTGGTGAAATCCGTATTAACTTAAAAAATGTGTTTAGCGAAAATGCGTTGTTTTTAACAAATTTCAAAACGGTTTCTGCTGCAATAATTGTACTAGCAGTGGCCATAACAGTTGGAGCACTCCTTGGGATATGCGTAATATGTTTGTACTACATGCGTCATCGGGTGAAACGACATTCAAAACATGAATATCCAAACATTAATCAAATTCCAAAATTTGATGCCATATTTCTACCCAATCCACCAACCGGAAACACCCATGATATGCTTTATGAATCTCAAATGCTCGAAATGCCAATGGGAGAGGAAAACAGTATGCTCAAACCAGTAGGAAAGATAAACGGAATATCCGCTGCTGCATACGGTTCCAACAGCTACGATTTGGATCTAAAGCAGAGTTATCAGAATTATGCTCAAAACGCATTGTCTGATAAAAAAATTTTCGTTGAAGAAAAAATGTTTTCGGTCAGTGAACGAAGCGGGCTACATCCGCAAAAGAACAAGAATTGTGCATTCACAGCAACAAGATTCCCAGTGCAAAACTTTTTCTAA
->XM_040515260.1 PREDICTED: Rosa chinensis uncharacterized LOC121051827 (LOC121051827), transcript variant X7, mRNA 
-GTTATGAGTCATCTAATTCTTTCTCAATCTCAGGTGCTATGCCTCCTAGACGCCGGACTCGTGGGGAGACCCCTCCCATTCCAGGAGATGAGAATACTCCTGGAGGAATAGCGGAAGCTTTGGGACGTATTGTGCAGCAGTTGACTGCAGCGCTTCCGGGCTCCAGAACCGACTTTACCATGGAGCGAGCGAAGAGGCATGGAGCTTATAGCTTCTCCCATGCTCCTGATGCTATGGATGCCCAGAATTGGTTGAACAAAATGGAGAAGGTCTTCACTCAAATCCATTGCCCAGAGGATCGAAAAGTGGGTTTAGCAGTGGATTTTCTTGATGGTGTGGCTTTTGATTGGTGGGCTTTTACTAGCAGGGATTTAGAGAATGATGGCCCAATCACTTGGGAACAGTTCAAAGAACATTTTACTGAGAGATATTATGGTACAGCTATCCGTGACAGGATGAAGTATGAGTTCTTGCATCTACAGAAAGGGGACATGACCGTGACAGAGTTTGAGCAGCGGTTCACCCAGCTAGCCCAGTTTGTGCCTGATCTGGTTGCCACTGAGAGGGAGCGGATCTATAGGTTTGTTGATGGATTGGGGGGTAAGTATTGTGAGCAGTTGACAGGAGTGCCATTTAGTGATTATGCTGAGGTAGTTAATGCTGCTCTGCGACTTGAGACTATGTATATGTCTGGTGTCCGACCTCGAGATGTGGGTGGCCCCAGTCAGGGTCCATCCAAGAAGGCTGCTTCTACCTCTAGGACAGGATCTTCAGCAGGTTTAGGGTTGTCCACTTTTAGGGGAGATTCTGACGAATTTTTCCGAAAAGTGGGCCCCGCAGGTCCATTTTGGAGTTAGGAGGGTAATTCCGGGGTGGGTCCTGACAATATGTTACTTTATGCAATGGAGATCATCTCTTCTATATATGCTGAACCTGCATCTGGAAATACCAAACTTGGCACTGTCATGGACAAAAGCATTTGCGAAGATGTGTCAACTTTAAATGTTTGGGGGCATAACTAAGTTCTTTCCTCTTTAAGTATGCTGCAGTCTGCATGCACTATACTAGGATAGACCAGGTGTACCCTCAATCCCCGGAATAGAACGATCCCTACTTACTTAT
->XM_048494676.1 PREDICTED: Sphaerodactylus townsendi CD200 receptor 1 (CD200R1), transcript variant X3, mRNA 
-GGAAAGTTAGGGATGTGAACAGGAAAACTGAGATGCCAACTGGACAGAAGTAGACTGGTTGAAAAGATGTTCATCATAAGAGTGGCTAGATGTCTGCCATAATGGATGTAATGGTGAGAGAACTATGTGAGCCATGAAATCTGACGTTCATTTTGTTATGAAAGCCACAAGTGCCAGAATTCTGCTTGCTGTCATAGTAATTATGATACCAGTTGGGTCATTCCCAGCAACAGGCTCCATTCAAAACAGGTCTGCACAGTATCTTTCCAACCATTCAGCTAGCACAGTGACAGTGACCAAGACTGCAACTCAGCTGGCAGAAGAAAAATCGAGTCTATCTGCAGTGGTTGGTTCATCACTCACACTGAAGTGTCCCTGGCAATGGCAAAGAACCTTGTTAACTGTATGGAATGTGAAATTTATAAATGGGACAAATTGTCATTTATCCTACAAAAGTGACCGAAACCTGTCTGTTACAAACTGCAATGAGAACGTTAACTGGTTATCGAGACCCGATCAAGAATATGCTCTTCTTATAAAGCCTGTGCAGATTTTCAATGAAGGATTTTATAAGTGTTCTAGTTCAATTGATAAGGGCACTTTCATTCATGAATATGCTCTAACTGTGCTAGTGCCTCCTCAGGTGCACCTGACCCATGACTACAATGGAACTGCTGTGTGTACGGCAGCTGCAGGAAAACCAGCTGCCCAGATCTCATGGGGCCAGAAAGGGGATTTTATCACAGTGAATGAAACTTTGCCTAATGGCACCAAGACCGTCATAAGCAAATATAAGATCACCAGTGCTGAAGAGAACAATTTAACTTGCTACATTTCCCATCCAGCTTGGACGAACTCACAAGTCTTAAGTTTCCTGTCAGGCACAAGAAAGTCAATACATCTAAAAGTCCAGAAACAATTTCAAGAGGCAGCATTCAGGAGAATGAGATGGAACCCTATGCCACCTTTGTGCAAATGGAAAATGTGATCTACGATACAACGTTTGACACCTCAATGGGCAAACACTTCCCACCCGGGCTTTCACCTTCCACATAAGTTTCAATATGACTCTAGCTTTCTGTGCAAAGGAGACAGAGAAACACAGCATAATAGGAAGAGGAAAGACAGCTGTTGCCTTTTAAAAATGACCTACCAAAAAACGTGGTCAAATGTT
->XM_046460927.1 PREDICTED: Marmota monax MIA SH3 domain ER export factor 2 (Mia2), transcript variant X18, mRNA 
-AAGGGTACAGGATGTATTAGAATCTGAAATCTTTCTCCAGGATATGAGGTGCTTAGAAGAACTTTATTTACATCTAAGGTTATCTTAACATGAGCCATTTAAGGAATGGAATTGAATGATCTGGAGGAAGAGGTTGTGGAAGCATTGCCTGAAGATATGAGACCAGGCCCTAATCCTTATGGCCTTCCGTGGGAGTTGGTGATTTGTGCAGCTATTGGATTTTTAGCTATTTTCTTGTTTTTGTGGAGAAGTTTTAAATCTGTTAGAAGCCGGCTTTACATGGGAAGAGAAAAAAAGCTTGCTCTAAAACTTTCTGGACTAATTAAAGAAAAATGTGAACTACTTGAAAAAATTAGCCTTGTTCAAAAAGAGTATGAAGGCTTAGAGTCATCTTTAAAGGATACCAGTTTTGAGAAGGAGTCAACAGAAGCACAAAGTTTGGAGGCAACATATGAAAAGCTGGATAGGTCCAAGTCTAAACTTGAGGATGAAATACTCTTTCTAGAAAAAGAGCTAAAAGAAGAGAAATCTAAACATTCTGAACAGGATGAATTGATGGCAGATATATCAAAAAGGATACAGTCCCTAGAAGATGAATCAAAATCTCTCAAATCACAAATAGCTGAAGCTAAAACAACCTTGAAAATATTTCAAATGAATGAAGAACGACTTAAGGTAGCAATGAAAGAGGCTTTGAATGAAAATTCCCAACTTCAGGAAGGTCAGAAACAGCTTTTGCAAGAAGCTGAAGTGTGGAAAGAACAAGTGAGTGACCTTAATAAACAGAAAATTACATTTGAAGAATCTAAAGTACATGCAGAACAAGTTCTAAATGATAAAGAAAATCACATTAAGTCTCTGATTGAATGCTTGCTAAAGATGGAAGACTGGGGTGCTGTGCTTGGAGAAGACCTAACAGATGATGGTAACTTGGAATTGGAAATGAACAGTGAATCAGAAGTTGGTGCTTACTTAGATAATCAGCCAAAAGGAGCTTTGAAGAAAGTGGTTTATGCTGCTAAGTTAAATGCCTCCTTAAAAACCTTAGAAGTAGAAAGAAATCAAATTTATACTCAATTATCTGAAGTAGATAAAACAAAGGAAGACCTTACAGAACATATTAAAAATCTTCAGACTGAGCAAGCATCTTTGCAGTCAGAATATACACAGTTTGAAAGTGAGAATCAGAAGCTTCAGCAGAAACTTAAAGTAATGACTGAACTATATCAAGAACATGAAATGAAACTCCACAGGAAATTAACAGTAGAGGAAAATTACCGGTTAGAGAAAGAGGAGAAGCTTTCCAAAGTGGATGAAAAGATCAGCCGTGCAGCTGAAGAACTGGAGACCTATAGAAAGCGAGCCAAAGATCTTGAGGAAGAATTGGAGAGAACCATTCATTCTTATCAGGGGCAGATTATTTCCCATGAGAAAAAAGCACATGATAATTGGTTGGCAGCTCGGGCAGCTGAAAGAAACCTTAATGATTTAAGGAAAGAAAATGCTCACAACAGACAAAAATTAACTGAAACAGAGTTTAAGTTTGAACTTTTAGAAAAAGATCCTTATGCACTTGATGTTCCAAATACAACATTTGGCAGAGGCTCAAGAGGCCCAAAGAATCCTCTGGATCATCAGATTAGCAATGAAAGGGGAGAATCAAGCCATGATAGGTTAACTGATCCTCATAGAGCACCTTCTGACACTGGGTCCTTGTCACCTCCATGGGAACAGGATCGTAGGATGATGATCCCTCCACCAGGTCAACCATATTCTGATCCACCTCTTCCTCCACAAAGGCAAGATAGATATTATTCTAATTCTGGTAGATTATCTGGACCAGCAGAACTCAGAAGTTTTAATATGCCTTCTTTGGGTAAAGTGGATGGGCCTATGTCTTTAGAAATGGAATCCAGTACAAATGATACCAAAGATGATCTTGATAATTCAAATGTGCCTGATTCATCTCTGCCTGCTGAAAACCAAGCAACTGGCTCTCGCTTTGGTTTTTCACCTCTTCCTCCAATCCGAGGTCCATTGTTTCCAGTGGACCCAAGGAGTCACTTCATGAGAAGAGGACCTTCTTTTCCTCCACCTCCTCCACCTCCAGGAAACATGTATGGAGCATCTAGAGATTATTTTCTACCTGGCCCACCACCCCCTCCATTCCCAATGAGAAATGCTTATTCACCGAGGGGTTTTCCTCATTATCTTCCCCCAAGAGCTGGATATTTCCCCTCACCCCCACATTCTGAAAGTAGAAGTGAGTTCCCTTCAGGGTTGATTCCGCCTTCAAATGAGCCTGCTACTGAACATCCAGAACCACAACAAGAAACCTGACAATATTTTTGATCTCTCTTCAAAATGGCAAAAGACAGAAGATTAAATATTCTTGAACCACAGCAGTGATGCTTTTATAATTGGAACACTTCATGCTAGCATTTCCCAGACGTTATTTGGAACCCTGGTCTTGTGAAGTATTTCTTTTCTTCTTCCATTACCATCCCCACCTTAGAGAAAAAGGGTAGAAAGAAAGATTGGGTAAATCTTGGGTAAAATAAATGCTTTGCGTAAAATATTAAGTGAAATGAGAACTGTAGAAACATGATTACATTAAAGTTTGTTTGCTGTGGTCTAAA
->XM_053649385.1 PREDICTED: Ictalurus furcatus tubulin cofactor a (LOC128622690), mRNA 
-TCCATTACACGTTGGGCAGTCGGGCATTTTGGAAGTTTAGGGAAGCTTGTATTTCAGCTGCTGTGTTTGTGCGTACTTACGACTCTGCACTTACCACACTTCTCAGAAATCATCTTTATTATGGCGGATCCAAGAATACGCCAGATAAAAATAAAGACTGGAGTCGTGAAACGGCTCGCTAAGGAAGAGGTGTTATACATAAAGGAGGCAAAACAGCAAGAGGAGAAAATTGAACGCCTGAAAGCAGAGGCAGGGGACGAGTATGTCATCAGGAAACAGATGGAGGTGTTGCAGGAGTCAAGAATGATGATTCCAGACTGTCACCGCCGTTTAGCCATGGCTCATGCTGATCTGCAGCAGCTGTTGGAAATGGAGGTGGATGTTGAAGAATCGGAGGAATACAAGGAGGCCAGAAGTGTTTTAGACTCTGTCAAACTGGAGGGATGATGTAAACACACATGCGCAACAAGTGTCCATTCCATTATTCAGGACTTCTTAAAAATGTTGATTCGGAAATAAGTCTGGTCATCGTCTCATTGTTGTATTGATTTGTAACACTACGAATAGTGTGCCTCTGCGTTCTCTGTTGATTGTTCACAAAACTAAATAAACAATCTTATTATTCAA
->MT512057.1 Pythium aphanidermatum strain Sala1 internal transcribed spacer 1, partial sequence; 5.8S ribosomal RNA gene and internal transcribed spacer 2, complete sequence; and large subunit ribosomal RNA gene, partial sequence 
-ACCATAAAAACTTTCCACGTGAACCGTTGAAATCATGTTCTGTGCTCTCTTTCGGGAGGGCTGAACGAAGGTGGGCTGCTTAATTGTAGTCTGCCGATGTATTTTTCAAACCCATTTACCTAATACTGATCTATACTCCAAAAACGAAAGTTTATGGTTTTAATCTATAACAACTTTCAGCAGTGGATGTCTAGGCTCGCACATCGATGAAGAACGCTGCGAACTGCGATACGTAATGCGAATTGCAGAATTCAGTGAGTCATCGAAATTTTGAACGCACATTGCACTTTCGGGTTATGCCTGGAAGTATGCCTGTATCAGTGTCCGTACATCAAACTTGCCTTTCTTTTTCTGTGTAGTCAGGGAGAGAGATGGCAGAATGTGAGGTGTCTCGCTGGCTCCCTTTTCGGAGGAGAAGACGCGAGTCCCTTTAAATGTACGTTCGCTCTTTCTTGTGTCTAAGATGAAGTGTGATTCTCGAATCGCGGTGATCTGTTTGGATCGCTTTGCGCATTTGGGCGACTTCGGTTAGGACATTAAAGGAAGCAACCTCTATTGGCGGTATGTTAGGCTTCGGCCCGACGTTGCAGCTGACAGAGTGTGGTTTTCTGTTCTTTCCTTGAGGTGTACCTGAATTGTGTGAGGCAATGGTCTGGGCAAATGGTTGCTGTGTAGTAGGGTTTTGCTGCTCTTGGACGCCCTGTTTTCGGATAGGGTAAAGGAGGCAACACCAATTTGGGACTGTTTGCAATTTATTGTGAACAACTTTCTAATTGGACCTGATATCAGGTAAGATTACCCGCTGAACTT
->XR_007174521.1 PREDICTED: Salvia hispanica uncharacterized LOC125211483 (LOC125211483), ncRNA 
-AGGCTGCACAACACACAAGTATCATCAACAGTTAGTCAGGCGGGAGAATTACATATATGTTCCATCAAGAGAGTTTGACAAAATGAAATACTGGGGGAAGAAGGAGCATTTCAAACCAGCTGTGACTATGAAGCCATACATTGTTGGACGATATACTCAAATCACAAGAACACAGAAATATCTAGGATATCTTATAGCTACCCATATCATATCATATTTTGTACAGATATCTAATAAGATTAGGATTATGTCGCACTTGTAACCCCAAATATCCATCAGCACCCAAATATCTAGGCTTAATGCGTCTGTCAATTGTTCATCATCAATATATAGTCCATGTCCCAAAAAAGGAGAAAATATACGTTAGCAGAATTGCAGAGATAGAGTTGTTTGTCACATCTATAACACACAATCACATATTCACATAAAAAATCTAAAACAAACTCAGAAAACCTACTTCAAAATGGAACTACACATACTTAACAATTCAACATAAACTTCACCAGAGAATAATCCTATACATTTTCTCACAAGTACTACTTGATAGAAAA
->XM_021335350.2 PREDICTED: Helicoverpa armigera UTP--glucose-1-phosphate uridylyltransferase (LOC110376763), transcript variant X1, mRNA 
-TCATGCGAGCGTGACGTGTGCGCGGAATTTTAAAACAACATTTTTAAAAGACGTTTTTTTTAAATAATTTTAAGTGTTTTTTTTTGGTTAAATAATGGATAGTGAGGCTGAACAGTGTCGGTCATGGGTACGTGATATGTTAAGAAATAAAAATGGGAGTATCCGCAGTCACCAGAGAACTCCCTCAGGTTCAAGGGACTTCAAAGAGGCGACCAAGCGCGATGCTCTCACCCGGCTGGAGGTCGAACTGGAGAGACTCCTGGCTTCAGTCCACGAGACCAGAAGACCACTCGTTGAAAAGGAGTTCAGGGGTTTCAAGAACTTGTTCAGCAGATTTTTGGCGGAACAGGGTCCATCAGTAACATGGGAGAAAATCCAGAAACTCCCAGAGGGTGCTGTCATAGACTACTCGTCACTCACCACCCCCACCACAGACAATGTTCACCACATGCTAGACAAGCTTGTGGTGGTCAAGCTCAATGGTGGTCTGGGAACCTCTATGGGTTGTAAGGGTCCTAAGTCTGTGATACAAGTCAGAAATGATTTGACCTTCTTGGATCTTACTGTACAGCAGATTGAGCACCTAAACAAAACGTACAAATGCAACGTGCCCCTAGTTCTAATGAACTCGTTCAATACCGACGAGGACACGCAGAAGGTCATCCGCAAGTACCAGGGCCTGAAGCTGGAGATCCACACCTTCAACCAGTCCTGCCACCCGAGGGTCAATAGGGAGTCACTGCTGCCGGTGCCCAGGCATGCTGACGTACAGGCTGACATTGAGTCATGGTACCCACCCGGTCACGGAGACTTCTACGAATCATTCTACAACTCAGGTCTTCTACAGAAATTCATCAAAGAAGGCAGGACTTATTGCTTCATCAGCAACATTGACAACTTAGGAGCCACCGTTGACCTGAACATTTTGAACCTACTCCTCAATCCTGATCCCGTGAAGACCGTCTCCGAATTCGTTATGGAAGTCACTGATAAGACCAGGGCCGACGTTAAGGGAGGTACCTTAATACAATACGAGGATAAACTAAGATTGCTTGAAATTGCTCAAGTACCAAAAGAGCATGTTGATGACTTCAAATCTGTTAGCCAGTTCAAATTCTTCAACACAAATAACTTATGGGCGAAATTGGATGCTATTCAGAGGGTGGTCGAACAAGGTTCTTTAAATATGGAGATTATTGTGAACAACAAGCATTTAGCTGATGGTCTCAACGTTATACAGTTAGAGACAGCAGTCGGAGCCGCAATGAAGTGCTTTGAAGGAGGCATAGGAGTAAACGTGCCTAGATCTCGATTCTTACCTGTTAAAAAGACCTCGGATCTTTTACTAGTGATGTCCAACTTGTATAGTTTGTCCCACGGATCTCTAGTGATGTCTCCACAAAGGATGTTCCCATCGACACCTTTAGTGAAGTTAGGGGATAACCACTTTGCGAAGGTTAAGGAGTTCCTGAACAGATTTGCTACGATACCTGACCTGATTGAGTTGGATCATTTGACGGTGTCCGGAGATGTGACTTTCGGCAGAGGAGTGTCTTTGAAGGGAACAGTAATAATAATAGCCAACCACGGAGACAGGATCGACATACCTTCAGGAGCTCTGCTTGAGAACAAGATCGTCTCCGGCAACCTTCGTATCCTCGACCATTAAGCAACAACTATTTAGCTAATATACCTTTACTAAAGGTGGATTTCAATACCCTTATCCATCCGTTGATTTTATGACGGATACGTTATTGGAATTTAAAGTAAATTGTAATACTTTTAGGTCTAGATTTGTTGAAATGGAACTTCTTTGAACATGGTGAGGAGTAAATTTGTACTACGTTTTTGTTTGTATAATAACATGATATGGTTATGCTCCGAAGTGTTATAAGTTTTTTTGTTACTAAAAGTTGTTATAAATTAAAATATATTTTTTGTGGATACTATAAAAATGAAGATTGAGTGAAAAGTTAGGGTTTAAAAGAATGAAGTTGAAAACTTTGTGGTTTTTAAAGAAGTTCCATTTCATTTGCGTCTAAAGAGGTGCGCGTTCTTTTTTATACGTCTATGTATTTGTCTATTACATGTGCATTAGTTGCCCATAGACTAAGTAGTTCCATATTCAAACAAAACAAGAGTTAAACTTACGAAATTGCTTAAATTGAGGATTACCTATGTATCATGAATTATATGGTTGTTTTTTGGTTTTAATTGGTATAATTATTGAAATTGAGATTTAAAGCGTTTGAAAACTTATTATAAACATATTTATTAGGTCGATTTTTAATATAATTGTAAAGTTTTCTATTTATTCACTTTTTATATTTAAACTTTTGCTATAAAAGTAGAGATAATAGCACAATTATATAGCATTGAAATTTTAGAATTTAATATTATGTAATTGCTAATATTGTGTTGTACTAAGATATTTCTTAGTAACAATTTATTTATAAACCAGAATACTTTTTTTTACAAGAAATATGTTTTATGATCACAAAAAAATTTAAGATTTGAGTATCTAATCTTTATTTATTGATTTATATTTAATAAAACGTATTTTTCTACACTTTTAATATGGGTTTTTAAAACCTTTGATTTTTTTATGAGCCAAGTTGCCAATTGTTGTTGCTTTATTAATTATTTATTGCCAAAGTGAAAAATTAATATATTGGGTTTATTGTCTGCTAAAAATTGTTTTTAGGTATATTACTCTTTTATTACTTTTATACTACTTACCAGTTAATATCATAAATATGGTTTGAAGAATATGAAAAAGAAAAAATATTTTTCATCATATTATTATACTTAAATATGGCCGATTTATTACACTTATTTCCAAAATATGCGACTTGTATTTGTAAAATAGATTTTTATAATTACTCCTAATAGTGATTAAGTTCATTACATTCATAGATTTCAGTCAAATATGTATTTTAGAAGAGAAATCATAATTCATACAATAAAATTGTTCTTTAAAAAAAATGAGCAATTTTATTACTCTGTTAATGAGTGTAAAGTGGCACCTTACAAAAAAATACTTATCGAATCGTAAAAAATATGATTCAGTTATATCGATAAAATATCTGTCGAGAGTGACATCACTAGGAAGGTTACTCAGTGAAGAATAAATACTGTACTATTAAGTAGTTTTAATCTAAGCAAGTTAGTGCCATTAGCTAAGTAGGTAAAACTGTTGTAATAAATATTATTATGTTTTCATTTCAA
->XM_021074111.1 PREDICTED: Sus scrofa fibrosin like 1 (FBRSL1), transcript variant X15, mRNA 
-TGCCGCCGCCACCGTCGCCTCACGAGCCCAGGCTCCTCAGCTCCGGTCCGCGCCGCGCCCGCCCGCTCGCTGGGCCTCTTCCCAGCCTTTGCCCGCCGCCAGTCGCCCATGGGGCGTGCCCGCGGGTCCGCGGCCGAGAGCCGCTGAGCGCTGGCCGTCACGCTGATGTGCGCGGCTGCTCGCGCCCGGGAGCCCAGGCCGCGCCGGGCCCGGGGCTGAGGCCACCCTCGCGGCATGTCCGGCCCGGCCCGCCGCCCGCCGCCGCCCAGGGCCCGAGTCCGCGCGGTCCGCACCGAGCCCGGCGGTGCCGCGTAGCACAGCGGCAGCGGAGCGGGAGCCCGACGGCACGGCCGCAAGGTCACCGCGCGCCATGGAGGCCAAGGTCCGTCAGAGCCGGCGCTCACGCGCGCAGCGGGACCGCGGCCGGCGCCGGGAGGCGGCCCGCGAAGCCCGCGACCAGAGCGCGTCGTCGGGTGACGAGCCAGAGCCCGGGCCGGGCAAGGAGAACACGGGCCTGCCCCGCGCACCCCCACCCCGCGCCGCCGCCGCGCGCCCCCCGCGCCGCCGCCGTCGTGAGTCCAGCTCGCAGGAGGAAGAGGTCATCGACGGCTTCGCCATCGCCAGCTTCAGCACGCTAGAGGCCTTGGAGAAGGACATGGCCCTGAAGCCACATGAGCGGAAGGAGAAGTGGGAACGTCGCCTCGTCAAGAAACCTCGCGAGTCAGAAAACTGCCCGACTGCAGAGCCGAGTGAGAACGGGCGGCCCCTGGAGGCAGGCAGCTCTGAGCAGGACCTGGAGCCCACCTGTGACCGAGGGAAGAAGAAGGTCCCATTGCAGCCCACCAAGCAGATGAAGGTCGCGGTGTCCAGAGGGGGCGACCACAACAGTGACGGCGACAGCTTCCGAGAAGCCAGCAGCTCCCGGAGGAGCAGTTCCCGGGACCAGCTCAGTGACAGCTCGGCGCAGGCGGTCTCAGGCAGAGGTTACTCCTGCGACAGCGAGAGCGACGGGGATGACAAGGCATCTGTGGGCTCTGAGAAGCTTTTTGCCCCAGCAGCGGATAAAGGGCCCACGTTGGGCGAGAAGTCCGAGGCCAAGGCCGGGGCAGCACCCAAGGTCTCCGGTCTGGAGCGCAGCCGCGAGCTGAGCACCGAGCCGCCCTTCCTGCCCCCTGTGCGCAGTCCTGTGCCCGCCCTGCCCTCCGGTGCCCCGGCCAGCCCACTGGTTAAGAAGGAAGCCCCGGCCCTGCCCCGCCTCGCCCCACAGCCGCCTCCTGCGCCCCCGCAGCCCCGGGCCCCGCTCCCGACGCACGTGCCTCTACCCCCGGGCGCCTTCCCCGGCCACGGCCACGGCCACGGCCCAGCAGCGCACAACGGCCTGCACAGCCTCAGCAGGAGCAGCAGCGCCAGCAGCGGCGCCAGCCTGGGGCTCGCGAAGCACGCGTCCCTGTCGCCTCACGGGCCGGGCCCCCACCTCTCTACCTCACACTTGGCGCTCCGCTCGCAGGCCCAGCACCAGCACCACGCGGCGGCCATGTTCGCCGCGCCCCCGACACTGCCCCCGCCCCCGGCGCTGCCGGCCAACAGCCTGGTCATCCCAGGACACCCCGCCGATCACGAGCTGCTCAGTTTGACAAGTTCACACCCAAGCTGGACAGCCCCTACTTCCGACATTCCAACAAACCCCCGGACTGAGGATGTGGTGGGAGGCCAGGCCTCCCGCCCAGGAGGCGGTGTGCAGGGCCCCACAGGCAGGGTGAGGCGGGCACAGGCGCCTGGGGTCTCACGCCCTGTCTCTCTCTCCCCTCAGACTTCAAACCCACTCGAGGTAACGGGCCGGGCCAGCGCTGTTCACACCCTCCTGCAGAAAGCCCCAGGGGTGTCCGACACGTACCGGACAACAGTCAGGAAGCCCGGGAAGTGGTGTGCGGTACACGTGCAAATTGCCTGGCAGATATTCCACCATCAGCAGAAGATCAAGATGCAGCTGGACCCCCACAAGCTGGACGTGGGCACCAAGCTGGACTTGTTCAGCAGACCCCCTGCCCCAGGCATATTCGCTGGCTTCCACTACCCGCAGGACCTGGCCCGGCCCCTCTTCTCCAGCTCGGGTGCCGCCCATCCCACTACCAACCCGTTTGGACCCTCAGCCCATCCTGGCAGCTTCCTGCCCACTGGTCACTTGACAGACCCCTTCAGCAGATCAAGCACCTTCGGGGGCCTGGGGAGCTTGGGCAGCAACGCCTTTGGAGGCCTGGGCAGCCATGCGCTGACTCCCACAGGCGGTATCTTTGCCCCCAAGGAGGGCCCCACGCTGCACGGCCTGACCAGCCCCCATGAGGCCTGGAACCGGCTGCACCGGGCGCCTCCCTCCTTCCCCACGCCACCCCCGTGGCCCAAGCCCATAGACACGGAGCGGGTCTCAGCCCTGACCAACCACGACCGAGAGCCGGACAAGGGCAAGGAGGAGCGGGAGCGGTGTCTTATCGCTCCCAGGGACCTCCTGGAGAAGACGCGCCTGCTGAGCCGGGCCTCGCCCGCAGCCCCCTTAGGCCACCCGGGCGGCAGCCTCCTGCTCCGCGGCCAGGGCGAACCGGGCCGGCCCGGAGTCCCCGCCGAGCGCGAGGCCGAGCCCCGCGTCAAGGAGAGCCGCTCCCCAGCCAAGGAGGAGGGCGCCAAGCTGGCCGTGCGCCCGCCATCTCCTCTCAGCAAGGCGGCCCTGGGGGACAGTCTGCGCCTGGCTGGCCTCCTGGGGAAGCCGCCCGAGGCGCCGGCCGAGCGGCCCCAGAGCGACGTGAAGGTCAAGGAGGAGCGCGGGGAGGACGGCGACGCGCCCCCACAGCTCGCTCCGGGCCCCGCGAGCCGCGAGCGCCTGGCCTTCGCGTGGGAGCCGCTGCGCGACGCATACCGCGGCCTGGAGCCGCCCCGCCGCGGCCCGCCCGGCCCCGGCGCCCTCTTCGAGCCCCCCGAGCGCCCCTACCGCGACCGCGAGCCGCACGACTACAGCCCCGAGCGCCTGCGGGAGGCGCGCCGCGACGAGCTGGAGCGCGCGCGGCCCCCGCACCTGCCCGCCGGCCCTGCCCTGGACGGCGCGGCGCTTCTGCCCGCGCTGGGCGCCCTGCACTACCCGCGCCTCGCTCCCGCCGCCGCCGCCGCGCTGCACAACGGGCTCCTGGCGAGGCCCCCGCCCGCCGCCGCCGCCGCCGCCCTTGGCGCACCGCCCCCGCTGGTGGCCGCGGGCGGGCCCCCCACGCCTCCCGGGCCGCCGCGGAGCAGGACTACGCCGCTCGGGGCCCGCGCGCCCGGGGAGGCCCGCGACTACTCCCCGTCCCGCAACCCCCAGGAGGTGGAGGCGCGGTAGTCCCCGCGGGGCCGCGCCCGCCGCATGTACAGAGGCCCCTCCACGAAAGCACTGCTGTCAACTTTTTTAACTGTACGTTGTTTCTAGAACCTAAGCACAGTTCCATCGGTCCTGGGGTGACGCCCGCTCCTCCACCTGCAGCCTGCGGAGCCAGGGATTTCAGACACGGTTTTGCCAGGAGTGATCTTTTGCTTTCCAAGCTCGACATTAGGCAATTGGAGAAAAACTTCAAGTTTGTACCTTTTTTCCCACAGGTGATAAGCGTTTTTAACAGATTTGTATTTTTTTCAATTTTGTGCTCTTTGGACGTTTAAAAGAAAGACTTTTGCTTTTTTATTTTTAGTTTGGATTTGCAATTTAATGGCCTCAGATCCCTCTCCAGAGCCCCAGGGGTTTTTTTTGTCTTATTTATGAAGAAAAAACAAAAAACAAAAAAACGGTCATTTTGTCCAACGCACTGTGAGGCCCCCACTCAGGCCCGGCCCTGGCCCTCCCTTGGTACTTGGAACAGAAGTTACAGATATATATTAAGATAATTAATAATGTACAAAACTTTTTTTGCCTTATTATGCAGAAGTGTAAAAGGGTTTCCTTTTTGGTTTGTTTTTTTTAAAAAAACAAATGAAACCGTGTACATAGTCTGTTAATATAAATATATGATGTTATTAAATTCTTAACCTAGGTAGACTTTATAAAAATCGTTTCTAGAAATTCCTCTGGTTATTTGTTTAACACGGTCACAAAAAAAAAAAATTCACTGGCTGTCAGTTGGAAACGCCCTCAGATGGTTGACTGCAGCAGCATCCTTCAACTATGCAAGCGCTCGGGACGGCCCGGGCCTGGGGGACCACGGCGCGCTCCCTGGAGTGTCTGCCCTGGTGCTTTCTGTGCAGTGTTCACAGAATCACACCAGACAAGACTGGGGAGGTGAGGAGTCCAAAGGCTGATTACAAGGGGAAGAGTAGCTGTCTCCTCCGCGGAGCCACCGGCAGACATGGTCTCATGTTCTCCCACCGGCCAAGGCCTTGGCGTTACTTCCTTTGGGTTCTGGTTTGCTTTCATGACCCCGTGAACGTCACTGTGCCCTGTCATCAGTGTTCCCTGTTTCCTGACGTCCATACCTGTGTCCTCAGCGTTTGAACCTCAGTTCACCCATCTCTAGCCATTTGCTTTGTTTGGTTCTGTATTTCCAACCCCACGTTTCCACTGTAGGCTCCGGTTATTTTAAATATTTTCACATCAACCAATGAAGATAAATACAGCCTTGATTTTGGATGAAAA
->XM_006877835.1 PREDICTED: Chrysochloris asiatica histone-lysine N-methyltransferase PRDM9-like (LOC102837583), partial mRNA 
-GCACTGTGCTCTTGGGCTGGAACTGTCAGAACCTGTGGGTGATGCTGACAGCATGAAGCTCACCAAGAGCCATGGAGGAGAGTATGGGGAGGACACCCACGATTGTGAGGAGTGTCAGAACTTTTTCACCGACACCTGTGCAACTCATGGGGCCACAGCGCTTTTAAAGGGCAGTGCCATGGATACAGAGCACCCCCGTCACTCAGCTCTCACACTGAATCCCGGGCTAAGGACTGGACTTGGAGTACACAGTGAGGCATCTGAGCCGCTGCTGGGCCTAGACTTTGGCCCCTACGATGGTCAGCTGACAGAAGATGAGGAGGCAGCCAATAGTGGCTACTCTAGGCTGAAATTCCTCCATCAACAAGTGCAGCACACCCATCCCTCTCAGTCCTCTCCAAGAACTCCTGCGGAAAAACACCTTCACCTAGAGCACCGCCATCCAGGGGATGGGAAGGAGCCGCATTCTGAGCAACTCGCCAGGAATGACAGAGCAGAAGGTCTAGAGATGGGAGATGGGCCCAAAGCCATGTTTGAAAGGACAAGACAGGGGGGCATTTTAAAGACCTTCTCTAGTCTACCCAAAGACCAAATGGGGAGTTCTAGGGAGGCTAACAGAATGACGCAGACAGACCCATGCTCAGGCCAGAGAGTGAATGCTGCGGACACAGGCAAATTATTGCCGGGGAAAGGAATCCCAAGAATTGCAAAAGTTACATGTAGAGAGTGTGGGCAAGGCTTTAGTGCTAAGTCAAGCCTTATCACACACCTGAGGACTCACACAGGGGAGAAGCCCTATGTCTGCAGGGAGTGTGGGCAAGGCTTTAGCCAGAAATCAATCCTCATTAGACACCAGAGGACACACACAGGGGAGAAGCCCTATGACTGCAAGGAGTGTGGACGAAGCTTTAGCCGGAAATCACACCTAATAAAACACCAAAGGGCACACACAGGGGAGAAGCCCTATGTCTGTAGAGAGTGTGGACGAGGCTTTAGCCAGAAATCAGTGCTTATCACACATCACAGGACACACTCTGGGGAGAAGCCCTATGTCTGCAAGGAGTGTGGGCGAGGCTTTAGCCAGAAATCAAACCTTATTAAACACCAGAGGACACACTCAGGAGAAAAGCCCTATGTCTGCAGGGAGTGTGGACGAGGCTTTAGCCAGAAATCAGACCTCATTAAACACCAGAGGACACACTCAGGAGAGAAGCCCTATGTCTGCAGGGAGTGTGGGCGAGGCTTTAGTCAGAAGTCAGACCTCATTACACACCAGAGGACACACTCAGGGGAGAAGCCCTATGTCTGCAGGGAGTGTGGGCGAGGCTTTAGCCGGAAGTCACACCTTGTCACACACCAGAGGACACACTCAGGGGAGAAGCCCTATGTCTGCAAGGAGTGTGGGCGAAGCTTTAGCCGTAAGTCAGACCTCATTAAACACCAGAGGACACACTCAGGGGAGAAGCCCTATGTCTGCAGGGAGTGTGAGCGAAGCTTTATTCAGAAGTCACACCTCATTAGACACCAGAAGACACACTCAGGAGACAAACCCTATGTCTGCAAAGAGTGTGGGCGAGGCGTTAGCCAAAAGTCAGACCTCATTACACACCAGAGGACACACTCAGGGGAGAAGCCCTTTGTCTGCATAGAGTGTAAACGAGGCTTTAGCCAAAAGTCAGATCTTATGAAACACCAGAGGACACACTCAGGGGAGAAACCCTATGTCTGCAAGGAATGCGGGCGAGGCTTTAGCCAGAAGTCAGACCTCATTAGACACCAAAGGACACATTCTGGAATGAAACCCCATGTCTGCAAGGAGTGTGGGAGAGGATTTAGCCAGAAGTCAGACCTCGTTAAACACCAGAAGACACACTCAGGGGAGAAGTCCTATATCTGCAGGGAATGTGGGCGAGACTTTGGTGATAAGTCACACCTCATTGGACACAGGAGAAGAAAATACTGCCAACACACACTGCCATCTCCCCAGCTTTGA
->XR_001644210.1 PREDICTED: Nicotiana tabacum uncharacterized LOC107768680 (LOC107768680), transcript variant X6, ncRNA 
-CCGGCAAAAAAAATGACTGGCCACTAAAAGCAGCTAATTCAAAAGAAATTTTAGTATTTTATCTTACCCTCACCTAATATTCCCTCCAATTTCTCAAAATAACAAAATGAAATTTGAAAAATTTGGGAATACATCACAAAGACTCAACCTATCTAACCGCTGCTGAAACCATTACCGCCACTGCAATTGATTTCTATCTCATCGCCGGCAACCAATTCCAGTTGCTAAGGTGATTTTCTTATATCTAGGGTTGGAGTAGTTCCCCTTCATTATTTTTTGAGAAAATCAAATGGCCGCTCCACCTGCTCTAGCCCATCACGACTACAGATTAGCTCATCAAGCTCCTTTTGATTAGCAATAGCAGTATACTTTTTATCCAGGACATTAGTTAACGTTGTTGGTTTAATATCGTTGTGATATTATTGACTACCTCTACTATTTGATTGAACAAGGAAGGAAGATTACAATAAAATAAGACCCTTGAGGCTTGAGCTATCATGGGCAGATGTATCTAGAATTTCAGACAGAAAGATTTCTCGCTAGCAAGCACAATTACAAAAATGTCTCCAAAAAAAGGTGATATATTGTGATGTTCAGAGATATAGCATGTGAAAGTTCATGTGATCAAGAGTTGGGAGAATCTGTCCGATGTAATTTATTATCGAGCTTATAGCTACTTGATAAAATAACTAATTAGATGCGAAATATTATTGGATTCAAATAATTTAGCATTTTTATGTTGTTTGCACTCTCAAATTATGGATTTAATGAAGTGCATTGAGCTGTTTGAAGTGAATTAATATTATTA
->XM_026966869.1 PREDICTED: Rhopalosiphum maidis uncharacterized protein PF13_0277-like (LOC113560796), transcript variant X2, mRNA 
-TTAGTGTTCGTATTGCTTTTCCATCACCGATATTATACCGATCGTTTGTGCGTAAACCGGGTTTTTTATCGGTGACAAATCAGTTTCGTTGTCAATACGGCCATGTATATGCACTTTTTCCGGACAGGTCGCCTTGCAATTGTGTCGTATTAGATACGTCCGTCGTGCATATTATTATTAGTATATGAATGTGCTTAAAGTTTAAACGTGACATAATATTATATAATATGTAGTATTATTGTCAATCAGTGACCGATATGATAATGTGCTTGTGACCCGTCTTGGTTATCGGTACGGTAATATCGTCTTGGTACGGTTTTATTTTTAGTGGTTGCGACCCCCCTTCAATTCGTTTTTCAACTACTTAAGTAAATCTGAATATTATGTTTTTTTATATAATTGCCGGTGAAGTAGATTATTCTTGTATTTATATTTCTAAGAGAAATTTATTTTTCAATTATTAATAAGACATATTGAACTAATATTTGACAAAACACAACGAAAAATATATTATTAACTCGTATCGGTGTTAGCCGGATAGATGGAATTGTAAACGACAAAAAAATAACTATCGATGTGTATATATTAAATATTAAAAAATATAATAGACATTATGTAAAGGACGATCGAAAAAACATGAATAAATACCAACAACCAGCAATGAATATGGATATAAAAAAATAATATATGATATCATATTAACCATGTCAGTGAGCAATATAATTCAAATTATTCTTGCAATTAAAATGGAAAACTGTCGGGCACATTGAATACTGCTCGATGAAATGAGGACGGATAAAAATGGATATCTATTATACAGAAGAAGACAAAACTACCAAATTAATGACAACACGGCCAATCCAAGTCAGATCGATGATGAAAATAATAACCCAGATGAAGATATTCAAGGCGACCGCAATCTTATTACATCAAATGTTAATAACCCAACAGGAAATAACAGATTAATAAAAAATGATCTTATAAAAAACGTTTTTAATAGGATGAATTCGAATGGAAAAAAACCTTCTCAAATAGAATCAAGTAGAGCAGATGCTGTTGAAGATCAACAACTAGAAGAAGAAATAGAAAACGATCCAACTAAAATGTCACTCGGTTTAGATTCTGAACTAGAAATCGCTGAAGACACTGACCTAGAAGAAGCAGACGATAAAAATATTGAAAAACCAAAACCAAAACCAAAAAAAAAAAAAAAGAAGAAGAAGAAGTCGAATTCGAAGAAGAAAAGTAAGAAACAAAAACAAAAAAAAACTGAAGATGATGAAACTAAATTAATTGAAATTGATAATAATGGAAATCAATTTAATTATTTTGACCATGAAGAAAAAGATATACGTGAATCAGATAATATTAAAGATCAGCAACAAGAACTTGATAAAGAAAACGATCCAACTAAAATTCTACTCGGCTTAAGCACTGAAAGAGAAGCTGAACTAGATAAGGAAAAAACAGAAAAAAATTTACAAAAAGAAGAAACTAATTTAAAATCAGCTGAATCCAAAGTCACTGGAAGTGATAATATAGAGTCAACGATAGAACAAACATCCAAATCATCCGATCCTGAGAATATTAAAGATCAGCAACAAGAACTTGATAAAGAAAACGATCCAACTAAAATTCTACTCGGCTTAAGTACTGAAAGAGAAGCTGAACTAGATAAGGAAAAAACAGAAAAAAATTTACAAAAAGAAGAAACTAATTTAAAATCAGCTGAATCCAAAGTCACTGGAAGTGATAATATAGAGTCAACGATAGAACAAACATCCAAATCATCCGATCCTGAGAAAAATCCCATCGAAAATATTAAAGAAGATACAACAAAAAATACAATTACGGAAGTTGATCAAAAAGACTTAACAGTATCTTCACTGGAGAATGTTGAAATCGTAAAAATTAAAAAAAAGGATAATGCAACCAGCGAAGCAATAAGAAAAGAAAAGAAAAAAACGACATTTAGAGAATTCACACATTCAGAAGGAAATGCACGCATATATTGTACATTTTTGGGAGACTTGTTAAAAATGTACAACAAAGTAAAAAAACGTTTTGTTGGACACTTTTGTCATGCAATTGTTGTTGGCACTCCAATTATCTTAAAACAAAATCAAGTACACTTAAGCAGTAACATGAAAAGTCACCTGAATAAAATAGAACCACATAAACAAGAAAGTCTTCTTATCGTCATCATGAAATATTCAAGCTATAAAGATTGGAAACATGCGTTAAAAAAATCTAACATCAAACACTTAATTACAAATATAATGCATACGGTCAAAACTTATAAAATCGATGGAATACAATTTTCAAATTTACAACCAATAGCGGGGAAAGATCCAGACAATTCAGTGGATACACACACGATGAATAATCTATTAAAATTCTTTGAAAAACTACTAAATACTGCAAAACATAATCATAATTATGATTTAAAAATTGGCATAACCATTCATTTGAACAGTCAGTGGATCACATCAAGTTTTACTTCATTCGCTGAATTAAATAAACTAGTCACTTGGTATACATACGAAACAATTTCCATGGTAACATGTTCACCAGAATACAAAGATACAGGCACTTCTCCATTAGAAGGAGACGTGAGCTTGATGAATGCATATAATACATTAACGGATACCAATATTGAAATGTCAAAAGTAGTAGTTGGCATACAATTATTTCCAAATAAAGTTAATAAATTAGAACCATTTACATATGAAGAGTTATGTTCAACACCAAAGAACACTTGGAACGAATGGTGTGCTGCATACCCTGAAAAACTTCGGTTAAAGGGTATATTTTTACGGAACAATGAAATCGGAGGCGTCCAACTATTTTACATGCACTCAGACGATTACAGGTCAACATGCGGCTGTTATTCTTTCCCGTTGACTCGAGCACTTCTTCGTGGCTTGATTAACACTCAGACGGAAGAACAGTGTAATTTTATTACGGCACACAACTAAATAGAAAATACCCGCAATAAAATCAAGAACCATTATAATAATATTAGTATCGTTTTCCTCATTAGTGCATTATTAGTAATTATTTTTTAGGCACTTGGAGTATGAACATTTTAATATTTTATATATCATTACTAAATGAATGTATTCTATAACAAACGCGGGTTCGTATACGACACATTCGTTCATTTTAATTAGCTAAACATATTGTTGTATAATTATTTTTTTAACACGCATAAAATACTGAATATATTTTATTAATTTAGTTTTTTTTTTATTATTCTTGCATTTTATTTTATCTTATAACACAGAACAAGATACTTAACTCCTATAAGTTGTATGAGTATAGACTGTAAGTATTTACTATATTTATTCGTACCCATAGTAACTATGTTAATATCACGACCTCGAGAGTTTATAATCATCATATTCACTCCTTTATTTTAATAAACCAAAATTTAAATAGTATAAAGTACAGTGGACGCCGCTTATAAGACTTACTTTGGGACCAACACAAAGTGAGTCTTATAACCGAATGAATCTAAC
->XM_048102724.1 PREDICTED: Salvia hispanica GDSL esterase/lipase 6 (LOC125204156), transcript variant X2, mRNA 
-AAGTTTTATTTAATAAATAGGAGTTTCAAATGAAGAAGAAAACTACAAATTGGTGTTGAACAGTTGAAGAAGAGTTGGCATAAAACAATATGGTGATCGAAGCCATGCATGCATTTAGTTAGTGTTGCTATGTCGTCTTCCTCGTTTTCCCGACATAACACCTCTCTCTCTATATATGTGCAAAATTCACAACAACTTTACTCAACTAATTGATTAATTTAATTTCTACAAAATCACTGGTAAAAATGGAGACACGGTTGCTGCTCGTCTCCGTCATTCTATTTCTTCTAGCAGCTTCCGCCATCGGATCTAAAATTCCGGCAATTTTCATATTTGGGGACTCGCTCTTGGACGCCGGAAACAACCCCTACATCCCAAATTGCACCGTTCAGGCGGATTTCCCGCCCTATGGATCCAGCTTCTTCGGCCGCCCCACCGGAAGATTCACCAACGGCAGAACCGTCGCCGACTTCATCTCTGAGTATTTAGGCATTCCACTGCAAAAGCCATACATGGAGGTGATGAACGGAACGGAAAAGAAATTTCCGGCCAACGGAATCAATTTCGCCAGCGCCGGCAGCGGAGTTCTTCCGTCCACCAATACAATTTCTGGAGTGACAGCAATCCAAGTCCAATTGCAACAATTCAAATCACTAGTCCAAAAAAATCAAATAGACAGAAAAGTCGTAAAAGATTCCTTGTTCTTGATAGAATCAGGATCGAACGACATATTCAGCTACTTTGATCCATCAACCTCAACACCCGAGGCCTATATACAAACCATGCTCGGACAAATCCACAACTTCGTCGATAACATCGTTAGCCTAGGGGCCCGCTGTGTCGCCTTGTTCGGACTAGGCCCGGTCGGCTGCGCCCCGGCTAGGTCCAATCTGCCCGGTGCCCCCCTCGGAAAATGCTACGACAAGTTGAATAAAATGGTCATGAAATACAACATGGGGTTGCAGAATTTGGTGAACGTTTTGCCTCGCACCCATCCCGGCACCATCGCTGTTTTTGGACGTGTTTATGAAACTATCCAAACCTATCGAGCACATCCTACGCGTTATGGGTTTGTGGATGTGGAGAACGCTTGTTGTGGATCTGGGAAACTAGGAGGACAGGTGCAATGCGGGAAGGTGGGCTACAAATTGTGTAAGAATCCAAATGAATACTTGTTTTGGGATTACTTTCATCCATCGGAACGGACTTGTGAGCTCATTAGCAAGGCCTTGTGGGCGGGCGGCCCGACTTCTATTATGCCCTTCAATCTCAAGCGGCTTGCCAATATGCCTGTCGCCTAATTGTTTAGGGTTCATATTTCATTGTTATCGTCATCTAAACGGTTTATGTTATACCGAAATGTTATTGGATTTTAGTTAA
->XM_042583618.1 PREDICTED: Zingiber officinale exportin-4-like (LOC122024892), transcript variant X3, mRNA 
-CCTTACTCAGGTGTTCTTTTCATTTCCAGGAAGGCGCACACACAGGGGGAAGGCGGCTTGAAGGGCTACCAGGCCCTCCGATCGCTTCCCTTTTCCGCACAATTTTATCTGCCGACTTTGAGAAAGCTCGCAGCTCACTCCCGTTCCTGCATCCCCATCTCCTTTTGATCGTCTCTTCCTCGTCGCTCCTAATCCGACACACACAGTACCCTAGAGAATAGAATCGGACGAGATTGAGTTGAAAAACAAGAGGCAATGCAGGGGTTCCCAGGATCAGTTCCGGATTTGTCCCAGCTTCGGTCCACCATGATTGCAGTTGAACAGGCTTGCTCCATGATCCAGATGCACATGAATCCAACTGAAGCAGAGAAAATTATTGTTTCACTGCGGCAATCCTCAATGCCATTCCAGGCATGCCGATTCATACTTGAAAATTCTGAATTGCCAGCTGCAAAATTTCAAGCTGCTGGAGCAATTGGTGATGCTGCAATTAGAGAGTGGGGAATGCTTACAGATGAGAATAAGAAAAACTTAATAGTATTCTGTCTACACTATGTTATGGAGCATGCAAGTGCTTCTGATGCTTACGTCCGATTAAAGGTGTCTGCAGTTGCAGCTCAACTGTTAAAACGAGGATGGTTTGATTTTGTTGATGCTGAAAAGATTTGTATTCTCTTAGAGGTGAAGCAAGCCATTCTAGGACCTCATACATCAGATGTGCAATTTGCAGGGATTAATTTCCTTGAGTCCTTGGTATCTGAATTTTCACCTGCAACTTTGACTCCGATGGGCCTTCCTAAAGATTTTCACACCCAATGTCATTTGTCAATGGAATCTAATTATCTGAAGGAGTTCTATTGTTGGGTTCAATCTGCTGCGTTTAATGTGACTGAAAAGATAGTGAGCTCATATGCAAGCATATCTGATGAGAAAGCATGCTCTGCAGCACTGCGGTTTATGTTTCAGGTTTTGAACTGGAACTTCCAAAATAGTTCCATTTCATGGGATACCTCCAGAAATAAATCAAATTTAGTAACATACGGTATCAGACATGATGTGGTTCAGTTGAAAAAGTTTGAACGGTCATTGGTTGAGCCAGGACCCTCATGGCATGGTGCTATATTATCAAGCGGACAAACTCTTTGGCTTTTGAACTTGTATGCAACAGTTCGCCAGCAGCATTTATCTGATATTTTGTGGTTTGATTCTCCCTTATCAGTCTCTGCCAGGCAGCTAGTAGTGCAGTTATGCTCTTTGTCAGGGACTATATTTCCTTCCGACAATGGGGAAACACATATTAAGCACCTAGTGCAGATTCTGTCAGCTGTTATTGATTGGATTGAGCCGCCTAACATAGTCTCAGGAGCATTACGTGGGGGGCGAAGTGAAAGTGAGATGATTGATGGTTTTCATGTATTACTTTCCATGGCAACCATGACTACAACTGTGCTTTTTGATAATCTTCTTAGGTCTTTAAGACCTTTTGGTACAATTCAATTATTGTCTGCCTTGACTAGTGAAATTGTTAAAACTCATGTGAGAAGAACTGATGTTGATCAAACATGGACATCAGAGGCTCTTGATATTCTCTTGGAGATATGGACCCTCATTCTTGGGAGAAATGACAATGAAAGAAAGGTTTCACCTGAAAACATATCATCATTATCGAATTTATTCAAAGCTATTGTGGAGTCGCATCTTAATGCTGCTGCCCAATCTGCATTTGAAGATGATAGTGATGCTGAGTATTTTCATGTCTCTGTATCAAAACGAGATGAAACTTTGTATGCATATGCTCTTATTGCACGAGCTGCAGTTGAAACCAATATTTCCTTTCTTATGAAACTGTTTGCAGAACGTTGTGCTCTTCTCAGTCAGAATAATGAAAGTTGTGATCCTACACAAACCTTAGAAGAACTCTACTGGCTTCTATTGATTACTGGTCACGTGCTCACTGATTCAGATTCCAGAAGCAATACAAGACGGGTTTGCTGATGTATCAGATGAATCACAGCATCCAGTGGTTGTTTTTTCCTGGTCAATACTAAGTTTTGCTAGGCAAAG
->KM122633.1 Uncultured bacterium clone LNH_9_9_11_Pumice.146514 16S ribosomal RNA gene, partial sequence 
-CCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGGGGAGGAAGGGAGTAAAGTTAATACCTTTGCTCATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCTGATACTGGCAAGCTTGAGTCTCGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACGAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGACTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAGCGACCGCCTGGGGATACGGCCGCAAGGTTAAAACNCAAATGAAATTGACGG
->KF304776.1 Cystobacter minus strain Cbm6 small RNA Pxr-2, complete sequence 
-AAGTGAGGCTGAAGGAGGTTCCCCCCCACCGCCTTCAGCACTTCCGGTGAGCTTCCTAAGAAGAACCCGAGGCCCGGTCCCTTTCTGAGGTGACCGGGCCTCCTTCTTTT
->XR_007867290.1 PREDICTED: Lolium perenne uncharacterized LOC127325588 (LOC127325588), transcript variant X4, ncRNA 
-TCCGGATCCCGTCCCCTCTCCGCGTCCAGACCTCGATTAATTTCGTCATGCGCATGGTCCTGCCCCGTACGTGCAGGTAAGCGGAAGCAGATCAGGGACGGCCTGTCCCCGCTCGACGACCACGCAAAAGGGCTCGTCCACTCCGGCCTCGACCAGGAGGAGCTCTTCCGCCCACCAAATTAAAGGTCACTTTATCCTTTATATGGAGCTCATGACTACAGCCATCAAATGTCTCAGTCTGCTCCTCAAGCGGAACCTTATGGTGACAATCTTCCACACATCGATCCCTGGGGCCTACCGAAGCTGAGAAGAAAGAGATGGCGCCACGGTGGCTCTTGGCGACTTCTGGTGACATTGGCCGGCTTGGAGGCTTGATGGGAGAGCTGCAGGTCTAGCTGCTCTGTCCCAAGTTTCACCTCGGTGAGCTCGACTCATAAAGATCGATGGGTTTAAGCTGGATAGACGGTGGTGGTTATTGTTGCAAGAAATAGAAAAGAAGACCTTATCAGTGCACCCCATGCCCATGATTATTCATTGCTGCTGCTTCACCACACACCCAAGAGGAGCAGGTTCGGGAGAAAGAAAGGGACCCAAAATAGAAACAAGAAAGGGAAAAGAGAAGAGATGGGGATTCTGCGAAACTTCCTCGAGCTCGCCATCAATTCATGTCTCGTGCTGCCATGGTAACCTTATAGTTAGTCCTTTGATTACAGATTGGTGGATGTGTTGGTAGAATTTACCCGGTTGGTTTAGCTTTACGACAGTATATTGTTTACCCGATTCCGGCGAATGGTTTGGAAAGGGGAGCAAAAACAGTACAGTTGAACATGCAGTTTTCTGTATAGTGAGTTATCATCTTTTTTTATATTAAATCAAATACGTTTTCAACATAACAATCGAAGAAGTTGTCTTGTAGGTACCAAAACTTATATTGGTTTACAGATTTAGTTTTCTCTATTAATTTGTACTAAATGACTTAATAGTTTGCCCAGTGTGGACATATTTGCCATCAAAGCTGAGATTTGGTGCTTATGTGTGCTTTTTGAAACATGTGCTTTTGAAGTTCTAGGCTTCCAGCTGCAACTTTCAGAGTACACCTGGGTAAATCATTAACGATACATCACTCATTTTGCATCAGCTTTCACAAAAAATAAACTTATTTGGATTCTTAGAAACATGATACTGTTTTCTGAAGTGTAAGCCACCACCAGGTTTCTTTATGTCTCGCTTCAGAGTTCGGGCTTGAAGGTTTAGCTAGTGACTGCAATCTGGTTATATACTCTCTTATGACGAGTTAACGTCAGTTTTGAAGGTCAAACTGTGTTGATCTGAAGCTTTCTGGATGTATACATATTAGCTTGAGCACGCTGATTTTGAGGAGTAGCCTGCTTTTGCTATGTTTGTAGTCTTCTAGTGAGAATTGACTTGAGCTTCTCTCGTGTGCTTTTTTGTGTCTAGGAGTGCTATTCTGTACATCCAGAATTGTCATTGATATATAGTTTCTTTGCAAATACCTTATGTGTTGGATTTCTCTTGAGGATCTTCTCCTATGCTTTTTAAAAAAAAAATTATTTGTTGTTCATTCATCTGGGAGTTATCTTAGGTATTGATGAGGATGGGTTGGAATGTGGGATCATGGAACATTATTTTCCATTGGTTTTGACTTTTTTCTCATTGATGAAAAGGTTTATTACACAAATGCATGGTCTTGTTGCTGTCGTCTTAGAGCTTATACTCATGTTCCTGATTCTTGTATATACCCAATTTGGGTCTTTCACTGTTAATTATATGATAGTATTGATCTGGCATTTTAGTTGATAAACATGTAATTGCCACCACTTATGCTTATTAGGACAGCAGCTAGATTTAGTGGTTTTGGTTAAAATATTTACTTGCTCTGCTTTAGTGGTTATGGCTAAATATTGACTTGCTCTGTTTGAGTGACGAAAAAGTTCGGACAAACTCCGTTTTGTTTTTATAATCTGCTTGGTGTTACTTGGGAGGGAAACGGGAAGGAAGCCGTTGAGCACCTTACCAAGGCGATCCTAGTGAACCTCAACAACCATGTATGGTACAAAGAGGTCAGTCACAATAGCAGCAATGCTTGCAGAGCTTACTGACTTGAAAATGTCGCTACTCTTTGTATGTGGAGCTGTCCCCCGAGGAGCTGGATGCAGAGTGAATGAACTTCTCGATCTCGACATGTGGAAGAAGGCAGTAGTTGATAGAGGATATGTACAATGTCACCCATGATCCTCGCAGAGGATCCATCCATGGTGGCATGATCAGGATGGTGTGAGTGAAGCTTTGAAGGCCAGTTCTCTACCGATGTGCGTAGCATATGTGCTATCCCTTGTGACTTCCTTTTTTTGTAATTGCTTCACAGACCTGGAGTTGTAATAGTGTCACATCTGTCTTTGTTGCTTATTTACGTTTGGACTTGTGATCTGAGTTGGATGATGTGGGGTTTTGGATGTCAATCTGTGCTGTTGTGATACATATGAAATTTGGACTGTTGATTATTTCA
->XM_025161730.1 PREDICTED: Tetranychus urticae CXXC-type zinc finger protein 1-like (LOC107366317), mRNA 
-AAAAGTAAAAAACTTTGTTAGTGAAAAGTTTTTACCATTTTTTTAATATCACTCTCAATGTGATCAATTAATAGATGTCCTATCAAGCCCTGGTGGACAAGCTAGTTTCAATGGTCAAATTTTTGGCCTTGGTTTGGACTTAGTGCTAGTATTGGTGCCCGAACTACTAGCACCGGATCATCTGGTGCCTCAGCCTCTGGTAGAGCTGCAGTTAAGGCCGTTGTCTAAGTGAAGACTCAAAGGGCTTAAAATGGTTTTCTGTGGTGAAAAATATCTGTGATCGTCAAGTTTCAAGGGAAAAGGGTAGAGGAGAATCACTGGACTGTATTAATCGTTTAAGCTGTAAAATAATGATTTGCTTGTATCAAAATTTAAATATCTCAATGTTTTTTCACTATGAAATCAGGTTCAAGCGTATGAGCAAATAGTGATGAATTATTAACAGCTAAAGTAATTTTACCATATTAATTATCGAAATATAATTACTGTCATAGGTTTAAAATTTTCTGGTTTACCTAACAGACCTACCTTTAGCTAAGAAACACCTACTTAACCGTGAAATAGACCATTGGTTACTCTCACTACGTCTAACTTACAAGAAACTAATTACTTGTTAACGAGATGTTAACTTGTTGACTGTGTTTAAAATAAACAATAAACTTTTATTAAAATGAGTGAAGACATTGCTTATTGTATTTGTCGCTCTTCAGATATAAGTCGATTTATGATTTGTTGTGATAATTGCGATGAATGGTATCATGGAGATTGTATTTCTATGACTAAGGAACGCGCTTTTACCTTTTTAAAATTTTACTGCAGTAAGTGTCGTGATCGTGATCCATCCTTGAAAAATCAACTTGTTAAAGAATCTAAAAAATATGTGGTATACACAATATCCTCTTCTGAAGTGACCAGCAAATAGGGAACAGTTCGGAAAAAGAGCCCATCACCTCAGAGGTCTAATAAAGTGGCTCGTTATGAAGATGATGCAGCACCTGAGAAGAGGAATTATGAAGATAAAGACGACGATGATAAAGATGAAACTTCAATAGATAAGAATAATTCATGTGAAAAAAATAATGAAAAAAGTGAACTCAAATCTAGATCAAGCCGAAAAGAAGCAAACACAACACCAGCTGACAACGAACGGACCAATGAAAAAACACATAAAGACAGAGAGGAAGAAATCTCCGAGATTGATGATGGTTTGGGTCAATTTTTTCAATGGATGTTTGAATATGAATTTTTATCGTGGCGTAGTCTTGTACTTTAAGTATAGAAGATCTTAATTGCCCGTGTTGGATAATCTGGTGTTTTTAAACCAGGTAAAACTGAAGGCGAATCCTAAATCTTCACCACTACTATTACAGTATTTCCTTGAATTTTTTGCTTTTTTCAAGTGCTGACATCTATGTCAACTACAGGGGGGAATAATTCAATTTTACAGTTAGTCTATTCTAACGATTCCCCCTTAAGGGAAAAGGGTAGAGGGGAATCACTGGACTGCATAAATTGTTTAAATTGTAAAATAATGATTTGCTTGAATCAAAATATAAATATCAATCAATGTTTTTTCACTATAAAATTAGGTTCAGGCGTAAGAGCAAATGTTGATGAATTATTAACAGCTAAAGTAATTTTATCATATTAATTATCGAAATATAAATACTGTCAGAGGTTTACCTAATAGACTCTTAAAATAGAATAGAATGATCTTTAGCTAAGAAACACCTTCTTGACCGTGAAATAGACCATAAGTTACTCTCACTACGTCGAACTTATAAGATACAAATTACTTGTTGACTGTGTTTAAAATAAACAATAAACTTTTATTAAAATGAGTGAAGACAATGCTTATTGTATTTGTCGCTCTTCAGATATTAGTCGATTTATGATTTGTTGTGATAATTGCGATGAATGGTATCATGGAGATTGTATTTCTATTACTGAACAACTTGCTAAGACGATGACCAAATTCTACTGCCTTATATGTCGTGATCGTAATCCATCTTTAAAAATTCAATATCACAGTGTAGTCCTAAATACTGTAGCATCTAGTCCTAAACCCACCAGCAAACATGGAACTGTTCGGAAAAAGAGCCCATCACCTCTGAGGTCCAATAAAGTGGCTCGTCATGAAGATGTCACTCCATCTGAGGAAAGGGATTGTAAAGATAAAGACGACGATCATCAAGATGAAACTTTAAGAAATAAGACTGATTCATGTGAAAAAAATAACCAAAAAAGTGAAATCAAATCTAGATCAAGCCGAAGAGAAGCAAACACAACACCAGCTGACAACGAACGGACGAATGAAAAAACACATAGAGAAAGAAAGGAAGAAATCTCCGAGATTGATGATGGTTTGGGTCAATGTTTGCGATGGATGTTTGAATATGAATTTTTATCGTGGCGCAGGCTTATACTTTAAGTATAGAAGATCTTAATTGCCCGTGTTGGATAATCTGGTGTTTTGGAACTGAAGGCGAAACCTGAATCTTCACCACTACTATAAGGACAAGTTAAAATGTTTTGTTGTACTGACTAAATCAACTATTTGCAATTCCCTAACATTAAAATAAAAAAAATTAAATTGTAAGTGAAATTTTGATATCAATAAGAATCAGCTTTAATTGTTCATTTTTGCTGTGAGATGACATGCAATTTAAGTTAAGACCTCAAGAAAAAATATCCAAAAGTAAAATTTTAACAATTTCTGAGAGTTTTATCATAAATGTTCCGAGTTAGATTATGCTCAACTTGAAAAGTGAAAAACCTTTGTCAGTAGAAAGTTTTACCATTTTTTGAATCTCCCTCTCTATGTTATCGAAAAGTAACTGAGTAACCAGTTTTTAAAGTCTGTTTGACTGGTTTCGGTAATTTTACATTTGTTTACAAACTCTGTTTATCTTCAATTTCGGCAGTTTTTATCCTTACGTCAAAGTTTTATTATTTAAATGTTTTTCTTATTAACTTAAGTGATATCAACATGGGTGAAGACACTTCTTACTGTATTTGTCGCTCTTCAGATACAAGTCGTTTTATGATTGGTTGTGATTCTTGTAATGAATGGTATCATGGAGATTGTATTTCTATTACTGAACAGCTTGCTAAGACGATAACCAAGTTCTATTGCCTCATGTGTCGTGATGCTAATCCATCCTTAAAAATTCAATATCACAAAGATTCTGGCTCTAAATCAACTAGCAAACAGGGGACTGTTCGAAAAAAGAAACAACCAACTTCTAAGTCCAATAAAACGGCTCGTTTTGAAGATGATGCCTCACCAGAGAAGATGGATTTTGAGGATGAAAACGATGAAGAGTTTGATGACGATGATGATGGAGATGAAACTTTCAGAATTGAGAATGAATTATCTGAAAAAAATAATCGAAAAAGTAAACCAAAATCTAGACCTAGCCGAAAGAAAACAAATACAACATCATCTGACAACAAACGTGGAAGTAAAAAAACACATAGACAAAGAGAAAGAGAAAGAGATGTCTACGAAGTTGATGATGGTTTAAGGCAATGTTATGGTCCTGGATGTATCAATATAGCTCGTCGAGGCTCCAAATACTGCAGTGATAATTGTGGTATCAAATTAGCAACCAACAGGATAATAGAAATTTTACCTGAACGTATAAGGTTTTGGCAAAGTACACCATCAAGTGCTGATGTTTTCAGTAATCGAGAATTAGATGCAATTCGAACAGAAGGAGAAACAGCCAAAAGGCTTCTTGAAGAACTGGACGGTAAACAAAAAGAACTAGAAGCTATGATTGCCGAGGCCAAGAAACTACCACCAATCTCAGAAGATGAAGTAGACGAAGAGACTGGAGATGAGCTGATGACTTACTGTGTAACCTGTGGACATGAAGTTGCATCGAGAACTGCTTTGAGACACATGGAAAGATGTTTT
->XM_043408227.1 PREDICTED: Colletes gigas uncharacterized LOC122404294 (LOC122404294), mRNA 
-ATGCATATGATAACAAGACAAAGGCTTGGTCGCCCGAGAGGACCAAATGCTAACCGCCCTAGGGAAGTGGTTCATGATTCCGCTTCTCCGACATCAGAAGTGAGATATCCTCGGCTACAAAGCGAGTCAGATGCAAATTGCGAACATCAGCCGCATGAAAATGTGCCCATTCAAGACAGCGCGTATACGATGCCGCAGTCGGCTGCATATGCAGCGCGGCTTATGGCCATGCTCACCTTGCGATGGCAGAGTTTCTCTACAGAGCAGATTGCTGTAGCAATGGTTCTGGCGCACACGGCTCAATTTGATAGACGACTCCAGAGATTAGCCTTTACCACAGAAATCAATTCAAGGGACAAGCTACACCGTGCAACTGGTCACTATGCTTCCAAGTGTCACCAAGTAGCTGGCAAGGGTAGCGGCGGTGCTAGCAGCAGCAGAGATTTTAACAATGCAGTTACGTCAAATACGGTTCAGCGACGGGTTGATGTTTGTCAGATAGGTAACCCTAGTGGAAAACTGGTCTGCAATGATCAGATAGCTAGATTAGGAGGTGCTCGGTGGTACTCCAGTTTTGATATGTTGAGCGATTATCACCAGATCCCTGAGGAAGCCAATTCTATTGAGAAAACGGCCTTCGTTACTCCTGAAGGTCAATGGGAATATTTGACCATGCCATTTGGGTTAAAGAATGCTAGTTCGGTCTACCAGCGAGCTATTGTAAAAGCCCTCAGAGATATGGCATTTAGCTTCGTTTTATGA
->MZ269370.1 Colletotrichum fructicola isolate 25640 internal transcribed spacer 1, partial sequence; 5.8S ribosomal RNA gene and internal transcribed spacer 2, complete sequence; and large subunit ribosomal RNA gene, partial sequence 
-GAGTTTACGCTCTATAACCCTTTGTGAACATACCTATAACTGTTGCTTCGGCGGGTAGGGTCTCCGCGACCCTCCCGGCCTCCCGCCTCCGGGCGGGTCGGCGCCCGCCGGAGGATAACCAAACTCTGATTTAACGACGTTTCTTCTGAGTGGTACAAGCAAATAATCAAAACTTTTAACAACGGATCTCTTGGTTCTGGCATCGATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCGCCAGCATTCTGGCGGGCATGCCTGTTCGAGCGTCATTTCAACCCTCAAGCTCTGCTTGGTGTTGGGGCCCTACAGCTGATGTAGGCCCTCAAAGGTAGTGGCGGACCCTCCCGGAGCCTCCTTTGCGTAGTAACTTTACGTCTCGCACTGGGATCCGGAGGGACTCTTGCCGTAAAACCCCCCAATTTTCCAAAGGTTGACCTCGGATCAGGTAGGAATACCCGCTGAA
->XM_036071201.1 PREDICTED: Halichoerus grypus sequestosome 1 (SQSTM1), transcript variant X2, mRNA 
-CCCGCCGCCGCCGCGGCCCGGCTCCGTCTCCTGCTCTCCGACCGGTAGCGATGGCGTCGCTCACCGTGAAGGCCTATCTTCTGGGCAAGGAGGACGCGGCCCGCGAGATCCGCCGCTTCAGCTTCTGCTTCAGCCCCGAGGCCGAGGCGGAGGCCGAGGCGGAGGCCGCGGCCGGGCCCGGGCCCTGCGAGCGGCTGCTGAGCCGGGTGGCCGCCCTGTTCCCGGTGCTGCGGCCCGGCGGCTTCCAGACGTACTACCGCGATGAGGATGGAGACTTGGTGGCCTTTTCCAGTGACGAGGAACTGACCATGGCAATGTCCTATGTGAAGGATGACCTCGTCCGTATTTACATTAAAGGTCTGGAGGGCAGGGCCAGGGGCCCGCTGACTGAAAGCCCCCCAGTCGTGACGAGCGGTTCGTGTGGGGTCCCACCTGCAGAGAAGAAGGAGTGTCGGCGGGACCACCGCCCCCCGTGTGCTCAGGAGGTGCCCCGCGGCCTGGTGCACCCCGGCGTGATCTGTGACGGGTGCAATGGGCCCGTGGTGGGGACCCGCTACAAGTGCAGCGTGTGCCCGGACTACGACCTGTGCTCCGCCTGCGAGGGGAAGGGCCTGCACCGTGAGCACAGCAAGCTCGTGTTCCCCGGCCCCTTCGGGCCCTTCTCCGAGGGCGTCGCTCACAGCCGCTGGCTCCGGAAGCTGAAACACGGGCACTTCGTGTGGCCCGGCTGGGAGATGGGCCCCCCAGGGCACTGGAGCCCGCGTCCTCCCCGGGCAGGGGACGCCCGCCCCGGCTCCGCAGCCGAATCAGCTGCTGGTCCGTCGGAGGATCCCAGTGTGAATTTCCTCAAGAACGTAGGGGAGAGTGTGGCGGCCGCCCTGAGCCCTCTGGGCATCGAGGTGGATATCGACGTGGAGCACGGCGGGAAGAGGAGCCGCCTCGCCCCTGTCTCTCCAGGCAGCTCCGGCACCGAGGAGAAGTGCGGCTCCCAGCCGAGCAGCTGCTCTTCGGACCCCGGCAAGCCGGACGCGGACCCGGAGGGCGCGGCGCGGTCCCTGGCGGAGCAGATGGACAAGGTGGCCCTGGAGTCGGTGCCACCGGAGGAGCAGATGGAGTCGGATAACTGCTCGGGGGCAGACGAAGACTGGACTCACTTGTCTTCCAAAGAAGTGGACCCGTCCACGGGGGAACTCCAGTCTCTACAGATGCCCGAATCCGAAGGGCCGGGCTCTCTCGACTCTTCTCAGGAAGGGCCCACGGGACTGAAGGAAGCTGCGTTGTACCCCCATCTGCCACCAGAAGCTGACCCCCGGCTCATCGAGTCCCTCTCCCAGATGCTGTCCATGGGCTTCTCTGACGAAGGCGGCTGGCTCACCAGGCTCCTGCAGACCAAGAACTACGACATCGGGGCGGCGCTGGACACCATCCAGTATTCGAAGCACCCGTTGTGACGGCTTCTGCCCCCTTGTCCCACCCCCTTCTTGTCTCCTAGTTGTGTTGAGCTAGTGTAGAACAGCAGGGCCTCTCTAAGGGCCAGTTTCTCTGCATTCTTCTTCCAGAATCTGGGGGGCGGGGATGCACCAAGCCATCCAGGGCAGTGGAACAAGTGACGGGGGGGGGGCCCCGTGTGTGGCTGCCCATGTCGGAGAAGCGTCTGCTGGCTTCCAGGGGCGGACGCGGGGCCCAGTGGTGTTCTCCTGCCCTCCCCCCACCAGGATCACACCAGCAGTCCAGAATGTCTTGCCTAATGGCCTTTTTTTTTTTTAATGACTAATAGTAGGCTGACA
->XM_050309850.1 PREDICTED: Myiozetetes cayanensis ring finger protein 111 (LOC126636998), transcript variant X10, mRNA 
-GCAGGCTCACCCGTGTCTAGGCCTTCCTTAAATCTTTCCATGTCTGAATGGACTCCTGAATGTAATATAGTCTATACTCCAGAAGCGGATATGAAGAGTGAAGTTCCTTCTGATGCACCAAAGAGCCAGGAGAGTCTGAAGGGGATCCTCTTGAACCCTGAGCCTATTGGGGCGGCCAAAAGCTTCAGTGCAGAAGTTGAGATGATTGCCAGTAAAGTAGGGAATGAGTTCTCCCACTTATGTGGTGACTCTCAAAAGCAGAAGGACATGAATGGCAACCATACAGACCAAGAAAAAAGTATTGTGCGAAAAAAACGCAAGAGCCAGCAGGCTGGTCCTTCCTACGCTCAGAACTGTCCTGATAAGGAAAACAAAGGAATCTTGGGATTGAGGCAGCATCTAGGAACACAGAGTGAGGACAATGACTCTTCTTTTAGTGACTGTATCTCTTCACCTTCTTCTAGCTTACACTTTGGAGACTCTGACACAGTAACATCTGATGAAGAGAAGGATGCTCCTGTCAGACACCCTCAGGCAGTGCTGAATCCTGTGAGCAGAACTCACAGTGCCCGGTCACACAAGTGGCCTCGCACTGAGGCAGACTCTGTGCCCGGATTACTCATGAAAAGGCCCTGTTTTCACAACAGCTCTTTAAGAAGGCTCCCATATAGGAAAAGAGTTGTGAAAACAGGCTCATCCCAGCGGACACAGAACCAAAAAGAGCGGATTTTAATGCAGAGGAAAAAGCGGGAGGTGCTGGCTCGCAGGAAGTACGCACTGCTGCCCAGCTCCAGCAGCTCCAGCGAGAACGATCTCAGTAGTGAATCTTCCTCCAGTTCATCTACTGAAGGGGAGGAAGACTTATTTGTGTCACCTGGTGAAAACCACCAGAACACTACAGCTGTTCCTTCAGGAAGCATTGATGAAGATGTTGTGGTGATTGAAGCATCCTCCACTCCCCAGGTCACTGCTAATGAAGAAATAAATGTTACCTCAACAGACAGTGAAGTGGAGATTGTCACAGTTGGTGAAAACTACAGGTCTCGTTCTGCACTTGGACACACAAGATCCCACTGGGGCCAGAGCTCTGGCTCTCACGCTCCACGACCTCCGGAGCAGCGGAACCGCAGCAGGATCTCCACGGTCATCCAGCCCCTGAGGCAGAATGCGGCTGAAGTTGTGGACCTCACGGTGGATGAGGATGAGCCAACAGTTGTGCCAAGCACATCAGCTCGAGTGGAGCCGCAGGTCGTGAGTTCTGCTTCCAGTAACAGTTCCAGTACCTCTACCTCAGAGCAGGCCTCTGATGCAGCTCCCACCATCTCCACCAGCCAGCCCTCTGCAGCTCCAGAGACGACTCCCAGTCTTCCCAGTGGCAGCACTGCTGGTACTTCAGCTGGAGATGACATAAGAAGAACTTCATCTAATACAACACTGGAAACTGGCCCTCCGGCCATGCCAAGGTTACCGTCGTGCTGCCCTCAGCATTCTCCTTGTGGAGGACCTTCACAGACTCATCATGCCTTGGGGCACCCACATACGAGCTGCTTTCAGCAGCATGGCCACCACTTCCAGCATCACCACCACCACCACCACAACCCTCACCCGGCTGTCCCGCTCTCCCCTTCGTTCAGTGACTCCAGCTGCCCTGTGGAAAGGCCTCCCCCGGTGCCTGCCCCGTGTGGAGCAAGCAGCAGTTCTGGCACCACTTACCATGATCAGCAGGCACTGCCAGTAGACTTAAGCAGCAGTGGTATAAGAAGTCATGGAAGTGGTGCTTTTCATGGAACATCTGCCTTTGATCCTTGCTGTCCTGGTTCTTCATCCCGAGCGACGATCTATGGGCACCAGGCTGGGGCTGGGCCGAGCCAGTCCCTGACAATAGATGGATACGGATCAAGCATCGTTGCTCAGCCACAGCCCCAACCTCCTCCTCAGGCATCGCTCTCCTCCTGTCGCCATTACATGCATTCTCCTTTACCTGATGTTTTCATTGCAGATGCTTCCTTGACCAGACCACTTCACCATCAAGCTTCTGCATGCCCTCACTCTCATGGAAATCCCCCTCCACAGCCACAACCTCCACCTCAAGTAGATTATGTTATCCCTCATCCAGTGCATCCCTTCCATCCTTCAATCTCCTCTCATGCATCTTCTCATCCTGTTCCACCTCCACCACCGACTCATCCTTTAGCCAGTGCAGCTGCTCCAATCCCACAGCATCTTCCTGCAACACACCAGCCTATATCCCATCACATCCCTGCAACAGCACCTCCAGCACAGAGGCTACATCCTCATGAAGTGATCCAGAGGATGGAGGTCCAGAGAAGAAGGATGATGCAACACCCAACACGTGCTCATGAGCGACCTCCTCCACATCCTCACAGAATGCATCCCAATTATGGGCATGGGCATCACATTCATGTGCCTCAGACTATGTCTTCCCATCCTCGACAAGCTCCAGAGAGATCTGCCTGGGAACTAGGAATTGAAGCTGGTGTGACTGCAGCTACTTACCCTCCAGGGCCTTTGCATCCTCACTTGGCCCACTACCACGCACCTCCTCGACTGCATCATTTGCAAATAGGGGCACTCCCTCTAATGGAGCTGATTCACTTGGAGGAACGATTAGGCAACGTGAATCGTGGAGCAACACAGGGAACTATAGAAAGATGCACATATCCACATAAATACAAAAAGAGGAAACTGCACTGCAAACAAGATGCGGAGGAAGGAACAGAAGAAGACACAGAGGAAAAGTGTACCATCTGTTTGTCTATCTTGGAGGAAGGTGAAGATGTCAGGCGCCTTCCGTGTATGCACCTTTTCCACCAAGTCTGTGTAGATCAGTGGTTGATTACTAACAAGAAGTGCCCCATTTGCAGAGTGGACATTGAGGCTCAGCTGCCCAGTGAAAGTTGACACTGCTTTCCAGAACTCTTGTCCTCCCGCTCGCTCCCTCTCATCCCTCCTGGTACTGCAGTCAACCAAAGATGGCATGACTTACCTGCGCAGATGTGGAACATTGAACCTTAGAGTGCTGGCTCTGCTACATGGTACAACTAATGCTAGACCTACAGTTTATTGTAGAAGACAGTTGAGTTTCAGTGTATTTATAATTTTTTTAAAATTTTTTTAGGTTTTACTTTTTTTTCTTTAAATTCATTACTGTATTTTTGCATGGTTCCTTGTATTGCATTTGTTTGCACATATTATGGGCTTTGTGACCCCAAACTTGCAGGCAAGATTAGCTGCTTTAGTAAGTAGAATTGTGTGGTCTCTTTTTTTTTGGTTTGTTTTATGTAGTATCAAGCTTTGAAAGTATGATTTCACTCATTACTAACCTCGAATTCCTTAATTTAATCAATCATATTTTAGTTTAAATGTATAAAGATCATCTAGAAAAGGATAATATTATGTATTGAGACATTCCTTAATTAGGAAAAAATGGCTGCTGTATATTTACAATATCAGTTCTGAGTCAAATAACATCCTTAATACTGGGAACAGAATATGGACTATATTCAGTTTGACTGATACATATAGCATACTCATCACCAGAGTTTTTGTCTGATCAGATTTTTGTGTTTGTTTTAAAAATTTCAGCACAATGCAGATATATTTGAATGTCAATATTAAACATTTAGACTGCTGTTCAGATTGTATTTATCATTTTCTTCTATGTCTAGAAATTTGAATCCCTAACTTAAATATATGCTGCTGTGAAACAGCTCTAGTGAACACTAAATGTTGATTTCAGTTAGCTGGATTGTAGATACTTGCAGATTGAAAGACTTATTAGGGAAATGGAAAAAGAGCTTAGAATCTGTTTGGTCTTCTGCTAACTTAAGTTGAAGTATCTGCGCACATTGAGAGTTGGTTTGTTTTTTTTTTTGTTGTTTTGGTTTGGTTTTGGGTTGGGTTTTTTTGGTGGGTTTTTTTTGAGGGGAGGGGTTGTTTGTTTTTTTTTTTCTTTTTGTTGTTGTTGCTGTTTGGGTTTTGTTGTTGGTTTGTGGGTTTTTTTTTAATATAAAACCATTCAGTAAGGACTTTAAGCTACAGGGTTTTTGTTTGGGTTTATATACATGCATTCATAGAATTTCTAAGGATTCCAGGCGTGTCTTGGGATTTTTATTAGATTTAAAGTTAATAAAGTTAGCTAAATCCACTTGTCTCTTGTTTTTATTTTTCATTAGTAAATTAAAAGCCTGTAAATTTCTGTAGAAACTGAGACACAAATTATGTGGTTACCTAGTTTTTGCCTTGATCATAGGTTCCCTCTTTATAAATTACCAACAGTCCATCACTGATTGAAGTATTTTCTATAGTTAAGATTTGCTGCATAATATAGTATATAGAATTAATAATGTACTAACATTTTGCCTTTGGAGGAGGTTTTAATCCACATCAGGATTCAAGTTGCTTCAACATTCTTTCACATATAATAGATTATAGTTTATTTAAATGTGCTCAACATTGCAAAATGCAAATGTGCAAAAACATTGGGACAGTATTACTGTCACTTTGGAAAAGATGTTCCTCGGGGATCATAGATAAATATGTCAATTAGCTTGCATTAAGCCACCTGCTTTGTAAGTGAATTGAATAATAAATACCTTCAGTTTCTCTTGTCTTTGTCTTTCATAATCAGATGATATGTACAATGGTTTACAGTAAATCTAGAAGATGAACTGTTATGTTTACACTAAAAAATGATCCATTTATAAATATTACCTTATCTAATTTGATGCCTGTTTCTGTCTGGTTCAAGCAGCTTCCTTTTTATTATTTTTTTTTTTTTTTTTGTCAACAAACTTAACACCTCTGGCACTGAGGCTTTTAGTGGAGAGAATTTTTATTCCAGTATGTATGTGATAAATGGACCTTCTCAAGCTTCCTTGTGTTGCTAGAACTGAACTTAAAACCACTTTGTGCTTGTAAATGGGGGATGAGGGAGAGAGGCAGCCCAGGATCTGACTGCTCCTGTGGGTTTCTGCTAAAGCTTTTGGACATGGTGGCTGTAGGAAATTCAAAGACTGGAGTTGGAGCTTCATTGCTAAAAATGAATAAAAGTAGCTGGAAGGACTGACCAGACACTTTGCTTTCCCATGACTGAAAAGAAGGGAAGTTAGTTGACTGCTAATGTTTGAAGACTGATATTCACTGCTAAAAGGTTCCAAGAAGGTACTTGAGAGACATGGGACAAAAAAACCCAGGGCCTCTAAAATAATAGACCCTGGGGTAGAATCTCTTTTGGCTTTGTTACTGGACAAAGAAGCACAGATTTGGGGGATTTTTTTTTTTAATTTTTTATTTTGTTTTTAGGAAATATTTTATGGGTCTGATTTGAGTGCGTGGTACTAGAGGTATTTTAGTGGTCCATGATTTGATTTATTAGAGCTACTGATACTGTCTTGCTTTTAAATGTATGCATAACATTGTAATGTGATGTTGAACACTTTTGTCAGGAATCACGGTATTCTGATCTTAATGCTATTGCAGGGGCTAAAAAGCTGCAGCTTACTTCTGTTCCGGAAGGTTGTGACTTAACCGTAATTTAAGAGAAGGAGAAAGATTAGGCTTTTCATTTTGAAAATTTCCACCACTTACTGTGCTTTATATGCTTAGATGCATTGCCTTAAGTTTTCTGCAGCATCTTTGACTTTGAAGATAAGATTCTCAACAGTATGCATCAAATTACTTTTCATATGAAACTCCATTGTCAAAAGAAATCCTTTTGTATGCAATAAATAAAATGTTAGACTGGTATCATTCAAAA
->XM_033409705.2 PREDICTED: Orcinus orca olfactory receptor 2J3-like (LOC105748649), mRNA 
-TTCAACATTCCCTATCCAGTTCCTCTGTTGCATGTAAGTTCATGAACCAGCATTAAGTTCTAAGCAAAGGATAATCAGGCTTCAAAATTCTGACTGTGGTGTTTCCAGCAAGTAGTGTTAAGCAATGAGAAAATTCAGTAACACTTTTCATCACTCTGATGGCTTTGTTCTGGTGGGCTTCTCTGAATGGCCCAAACTAGAAATGGTTCTTTTTCTGGCCATCTCTGTTTTCTACATAATGACCCTCCTTGGGAATTTAGCCATCATTATCTTGTCATGCCTTGATGCCAGGCTCCACACCCCCATGTATTTCTTTCTGTCTAATCTCTCTTTTTTGGACCTTTGCTGTACTACTTCCCCTGTCCCCCAAATGCTGGTCAACATCCAAAGCCACTGGAGAAATATCAGCTACCTAGGATGCATAGCTTAACTTTTCATATTCCTTAGTTTAGGATCCACTGAATGTGTACTTCTTTCAGTAATGGCCTTTGGTCGTTATGTAGCTATCTGCCAGCCTCTCCATTACACAGTTATCATGCACTCTTGGCTATGCCAACAACTGGCAGCAGTGGCTTGGGTAACAGGTTTCAGCAACTCTTTGGTGCAAATAGTGTTGACCTTCTTGTTACCTCACTGTGGTCCATATCAGGTGGAGAATTTCTTCTGTGAGGTACCTGCCATGCTTCAATTATCATGTGTTGATACATGGATCAATGAAGTGGAGATGTATGCTGCTGTAGTGGTCATAAAAGTCTCTTAAAATTTTGATTATAAGGAATTTCACTTATTCAACAAATATTTGAGTGCCTAATTGTGTGCCAGGCACTGTTCTAGGCACTTTGGATTTATCAGTGGACCAACAAAGAACTTTGCACCATGGAACTTACATTTTGGTTTGGGAGAAATCAATGATAAGCAATAGATACTAAATATCATGTTAGAAGATGGTAAGTGCTCTGGAAAGGAAAAATGTGGAGTATGGTAAGAAGATGGGGATTGTGGGGCAGGAGGCATACATTGCAAGTTTAAATAGAGTGGTAAGAGTAGGACTCACCGTAGCTGTGGCATTTGAGCGAAGACTTGAAGGTGAGAGGAGACAATGCAGATATTTGGGGTAAAAATGTTCCAGGCAGAGGGATCAGCCAGTGCAAAGGCCCAGGGATAGGAGTGTGTTTGGCTTGTCCGAGAGATAGGAAAGAGGCCAATGAGAATGGAATGGAGTGTGTGAGAAGAGAATATCAGAGAGATTACACAGGGACCTGATTGGTTAGGGCAGGGGTTGGCAATTTTTTTCTATACAGGGCCAGATAGTAAATATTTTAGGCTTTGCAGGCCATATGGTCTCTGTCACGACTACTCAATTCTGCCTTTGTAGCACAAAGGTGGCCATAGACGATACTTAAAGCTTTACTGGAATATAGCCATGCTCATTTGCTTATTTATGGACTCTAAATTTATTTTATATGTCATAAAATATTCTTTTTCTTTTGTTTTCCACCATTTAAAAAATGTAAAAACCATTTTTAGCTCCCATTCTTAGCTCATGGGCCACATAAAAACAGGTATCTGGCTGCATTTGGTCTGTGGGCCATAGTTTGCAAGCCCATGGTGAAGGGTTTCCAGGGCCCTTATAAGATCTTTTGTTTTGGGACTTCCCTGGCGGTCCAGTGGTTAAAACTCCGCGCTTCCAATGCAGAGGGCACTGGTTCGATCCCTGGTCAGAGAACTAAGATCCCAGATGCCACGTGGCGTGGCCAAAAGATTTTTTTTTTAAAAAAAGATCTTTTGTTTTTACTCAGAGTTTAAAGGGGGAGCCATTAGCAGGTTTTGAGCAGATAAGTAAAATGATTTGATTTATATTTTTAAGGGATCACTCTATGGAATGATGTCTAAGATTTGCTTCAAAATAATCTGGAGGGCAGGGTACTATGGGGGTTAAAGATGAATCAAGATGGGTCATACATTAATAATTATTGAGTCTGTATAATGGGTATATAGGGTTTAATATAGTATTCTCTATGCTATTATGTAGGGTTTTCCATACTAGAAGGTTAAAACAAAAATAGGCACTCTGGCTGCTTATTTGGAGCAGACTGTGAGGAGGGAAGGTTAGGAATGAGAAAAGCAATTAGGAGGCTATTACGGTAATCCTTGAGAGATGGCAGTGGTGGCTTTGTCTGGAGTGGTAGCCCTGGAGGTGGTGAAAAGTGGTTGGGTTCCAGGGCTTCCCTGGTGGCGCAGTGGTTGAGAGTCCGCCTGCCGATGCAGGGGACACGGGTTCGTGGCCCGGTCCGGGAAGATCCCACATGCCGCGGAGCGGCTGGGCCCGTGAGCCATGGCCGCTGAGCCTGCGCGTCCGGAGCCTGTGCTCCGCGGCGGGAGAGGCCACAGCGGTGAGAGGCCCGCGTACCGAAAAAAAAAAAAAAAAAAAAAAGTGGTTGGGTTCTGGATGAATATTGAAAGTAGAGCCAAGAGGATTAACTGTGTATCGGGTATGAGGTGTGAGAGAAAGATAGGAGTTGGGGAGGCTTCCAGGTTTTGGCCTGAACAGGGAGAAGGGTAAAGTTGCCATAAACTGAATGGAAAAATCTGCAAGTAGAAGAGATGTGGGCGGAAAGATCATCATGAGTTCAGTTTTAAACATTTAAGTTTGAGATGTCTACCAGATATCCTAGTGGAAATATTAAACCGACAGTTGTCTATGCGAGTTTGGAGTTTGGGAGGAAGTTTTGGACTGAAGACATAAATTTGGGAGTCATTGTCATGTAGGTATCTTTAGCTTGGACTGGGTAAGATCACTGAGTGAGGGAGTGTAGATAGAGAGGAGAACAGTACCAAGCACTGGGCCTTGCAGCATTCCAGTGTTAAGTAGTCAGGAGAGTAGGGAGAGATAGCAGAGGAGACTGAGAAGTCACCAGGGAGACAGGAGGAAAACCAAGAGAGCATAGTAGCCTAGAAATCAAGGAAAGAAAGCGTTTCAAGGAGAGGGGAAAGATCAGTGATGTAAAAATACTGCTTGAGTAAGACGAGGACAACAAATTGACCCCTGAATTTAGCAATGTGATTATTGGTAATCTGGATGAGCAGTTTAGGTGGAGTGATGATGGCAAAAGCTACATTGCCAAGGGTCAGGGCAAAGAAATGGAGTAAGAACAGTCCGGAAAAGTGAGGGAAAGAAGTCCGCTCTTTAAGATGGAAGAAATAACAAGTATGTACAGTCAGCCCTCTGTATCCGCAGGTTCTGCATCTGAAGATTCAACCAATTGCAGATTGAAAATATTTGGAAAAAAATTCCAGAAAGTTCCCAAAAGCAAAACTTGAATTTGCCTTGCACAGGCAACTATTACATAGCATTTGCGTTGTATTAGGTTTTATAAATAATCTAGAGATGATTTAAAGTACGGGAGGATGCACGAAGGTTACATGCAAATACTATGCCATTTTATATAAGGGATTTGAGCATCTGTGGATTTTGGTATCCACAGGAAGTCTGGAGCCAATCCCCTGAGGATACTGAGAGACTATTGTATGTATACTTGTTAACATATAGAACATAACAGTATGCATGCAAAGAGAGTGACCCATGAAGAGGAAA
->XM_042525726.1 PREDICTED: Zingiber officinale uncharacterized LOC121974587 (LOC121974587), transcript variant X1, mRNA 
-TTGATCAACGTTTGACGAATTAGAGAGTTGAGGCCTCTTTTGTTTTGAATTTAAAGGAAATGGCGTCGTCTTCCAAGAGATCTGGCAGACCGGTGCTCCCTTTTCGGAGATCTGTCTCTCCGGCTGGCGGCTTCGCCTCCTCGTCAGCCAGCCTCTCTGCTCCCTTCTTGCATCACCGATCGGCCTCCCCTACCCGCGTCCACCTGGCCGGTGCTGGGTCTTCCGGATCTTCCTCCGTTCGCTTCTCCCTCAACCGATCTGCCTCCCCCGGACGCTCCATCGCTGCGTCCGACAGCCGATCATCTCCCGCCCCGGCCCGGCGCACCTGCCTCTGCTCTCCTTCCACTCACCCTGGATCCTTCCGCTGCCACCTCCACAAGGGCCTCAACGGCGGCGGATCCGCGGCCGCTTCCTCGCCGTCGAACAGGCTCAATGCGCGGAGGTCCGCGATGGCGAACTCGCTGGTCCGGATCGGGGCCGTGGAGGGCGAGTGGGTGAAGCGCGCGCTCTCGGCGCTCATCCGTCCCTCCTCCCACCAACAGCGTCGGCGGGGAGCCTTCCAACCCCGCCCTAGCCGCCTCTCTCGGATGTCCAACGCTGCCGATCCTAAATCTCCGTCGTCCGATCCACCGATCTAGAATCAGTAATGGGAGTAACGTTCCCTCGCTCCGTTACGTTCCCGTTGGGCTTCAAGTTTGGATTGCGTCGCCGTCAAGTTCTCATCGTTCGCCGGTACGTTCCGTCATCTGCGAGGGAATTGCCTCAGGAAGCTACTTGATTCAGTGACTCGGCCACTGGTGAGATGAATCGTAAGAATTATTTATTTAAATCATTTCGATAAATAGATAAAGGACATAAAATATGATGACTAGGTCTCAATTAAAACTATAATATTAAATCACTTTAGTATTAGAACCATTCACTTAACACAATAATCATGTAATGATTTTGAAATTCTATCAACGAATTTTAGAAAATAGAATAACTTCAAAGTTCAGAAGATAAAGTGAAAGTTTGGTAGAGGAAAACATTAGGTGAGGACAATGGACAAGTCCATGTGGAAGCCATAATTGTGGTGGGAAAATTGTTAGTGGAACTGAACCACCAAGAACCTAATTCACCTTCAAATTATTTCAACATCAAACGCATATTTAAAAACTACAAAAGTGAAACAAATAAAGAAACGTTGGGTGGGTTAGTTGGATTAGCTAAGCATCACCATTTAATATAGCACGCATATTTTACCATTACATTATTTTATTTATCATTTTAAATTTTAGTCTATAAAGGTGACGCAACAAAATTTAACATGTTATTTTTTTATCCTTTTAATTAAGAATAATGTACCTAAAAGTAACATATTGGATGTTATATTAATAAATATATCATTTTATTGTTTTCAAAGGGTCATCCCTTAGTGACAAGTGGGAATAATCACAATAGTTGAAATCATAAGGAGAACTTGTGATGGTGGAGATTGGATCTAGATGGTGAGGAAGAAGCTCCACCAGATTTTGTGATGACAAAAAGGACAGTTTGGATAATGTCTATCAACATAATATAAGCATTCCCTTTCAAATTAATTAATTATAGATATTGTTCTTATTAAAGAGTCACGGAACCAAGGTTATCATCTTGAAATATTGGTTAGTGGCTAGCAGGATCTTGTGTATCCCATGGGCTTTGACTGGAACAGTTGGCCACAGTTTATTATTAAAATTTGGGAAACCTAAAGATTTTTTCTTTTTTTTGTAAAATTTTACAAAAGAAGTATTAGAGGGAGATATAATTAATTACAATGATGAATTTATAAATTATTAAAACAATTAGAAAATGTATACCGGCCAAATTAATTAACACAACATTATGTGTATTCATCTGTTCCTTGTTTATCAAAGACAAAATTAATACAAAAGTGCGATTTGAAATAGTATTTTAGTTGGGTAAGTGTGTAGTGGGAATTGTCCCGCTTGCTATGGGTATTCAGATTATGGGGAGATCGTAGAGAAAAGAAAGAGAGAAAGGGAAGATGAGAAGTAAAACAATTTTAAAAGAAAGCGAAAATAATGATAATTCTTGCTTTTGTTCTCTTTGTCAACTCATTTTTCCATCCCATGGGCATTGCAGTTGGAAAATTTGCTACAAAGGAGGTTTATATTATATATTTCTGTGAAAGTCTCATTTATAGATAGTTATTGGATCAAAGTATAGTTAAAGAAAAAAAAACTTAATTACTAATTAATTAATATCCAAGATCTATTCTGCTCATATAAAAGAGTTATTCAAAAGATCGTACTGTAAAAGTTTCTTCCAGACTATTTGTTTCCCGATCCACTGATTACAATCATATCAAGTAGTAGCTGTGGGCAACTATAGCAATGGTTAGTGGTCGTTTTTTTTCCTGGTTTTTGATGGATGAATTTTAGAAAAAAGAAGAAATGTTGACCAATGTAACTGATGAACGAGCCACTCTCTAGAAGAGTGACAGATAAGAATCAAGCGAGGTTGAAAGGAAAATTTTGACCGGAACAAAAGAGGCTGCAATTGTCAAATTTACTTCTAAGAAGTCCTTTTAAAGTGGTCATTAATCCGAGCATCAAGTTTAAGACATTGTTTTTAGAGAAAGATGTTGGGCGTGGAAGCAAAGGCGACGGCACTGACATGGAAGATGATAGAAGTCAATTATGGCACAGGACTTTGTAAGAATCCATCTTCTCATTCTAGAAGAAAAAGGATATTTTTCACCGGCGCCTGTTTGATTTCCCGTACAGATAGTTAGGCGTAGGGTCGATCGTATGGGATAGTTATGACCGTTTGCAGAAAAAGAAAAAAGAACATTTTTCCTATTTATAAAGTGGTATTTCGAAATAGATGATAAACAATCGAAGATGATAAGAAGGATTTTAGGCAA
->XM_039010113.1 PREDICTED: Salvelinus namaycush gamma-aminobutyric acid receptor subunit delta-like (LOC120060710), mRNA 
-ATGGACATGATAACTTTCATGTTGGCGAGCCTTGCCCTCCTGAATATCAGGGACAACATTTTCACCAGGGCCATGCTGAGTGACATTGGGGACTATATAGGTTCAGACATACAAATTTCCTGGTTGCCTAATCTGGATGAGTTAATGAAGGGCTATGCGCGAAATTTTCGCCCTGGGATAGGAGGCTCACCCGTGAATGTTGCCATGGCTATTGAAGTAGCCAGTATTGACCACATCTCTGAAGCCAACATGGAGTACACCATGACCATTTTCCTGCGTCAGAGCTGGCGGGACGACCGCCTGTCCTACAACCACACCAACAAGACCCTGGGACTTGATAGCCGCTTCGTGGATAAACTCTGGCTGCCCGACACCTTCATTGTCAACGCCAAGTCTGCCTGGTTCCATGACGTCACCGTGGAGAACAAGCTGATTCGCCTGCAGCCTGATGGGGTCATCCTTTACAGCAGCCGGATCACCTCGACTGTGGCGTGTGACATGGACCTGACCAAATACCCCATGGATGAGCAGGAGTGTATGCTGGACCTAGAAAGCTATGGCTACTCCTCAGAGGACATTGTGTACCACTGGTCTGAGAGTCAGATACATATCCACGGACTGGACAAACTGGAGCTCTCCCAGTTCACCATCATCGACTACAAATTTGTCACGGAGACGATGAACTTCAAATCCGCCGGACGTTTCCCGCGGCTCAGCCTTCGCTTCCAGCTGAGACGAAACCGAGGCGTCTACATCATCCAGTCCTACATGCCCTCCATCCTACTGGTTGCCATGTCCTGGGTGTCCTTCTGGATCAGCCAAACAGCAGTCCCGGCTCGGGTATCCCTGGGGATCACCACTGTGCTCACCATGACGACTCTGATGGTGAGCGCCCGCTCATCTCTCCCTCGAGCCTCAGCCATCAAAGCGCTGGATGTCTATTTCTGGATCTGCTACGTGTTTGTGTTCGCCGCGCTCATCGAGTATGCCTTTGCTCACTACAACGCCGACTACAGGCTCAAAGAGAAGGCCAAGAGCAAGGCCAACAAGATGAGCTCCGAGTCAGTCGTAAAGAATGGGAAACAGGCCATGGTGCTCTTCTCCCTGTCCGTGGCTGGAATGAACCAGGGCCTGATGGTGTCCAGCCGCCGTCCGCAGCGCTCCGGCGCCGAGACCGCCGAGGAGGAGGACGTGGAGCACAGGAGGGGGCGGGGGACCACAGCGTCAGAGGAGAGAGAAGAGGATAAGAAGTGCTGTAGTTGTTGTTCCAAGTGTTGTTGCGCTTGCAAGCCCCTCCAAGCTGATACCATAGATGTCTACGCCAGGGCCGTGTTCCCTGCCACCTTCGCCATCGTCAATGTGATCTACTGGGTGGCGTACACCATGTGA
->XM_010916034.2 PREDICTED: Elaeis guineensis potassium transporter 7 (LOC105039769), transcript variant X2, mRNA 
-TTCTCCCTGCTTCGCCATCTATGGGCTTTCGAGAAAACTGTCCTAAAATCTCACGGTTTTTCTCAGCTTTCTCCATCAGGTCGATCTCTCCTCGATCTAAGCTTCGTCGGTTTGCGGCCGATTCCTTTCCACTTTCCATCGGAAGTTCCTTTGTTCTTCATCTATGTCGTAAAAAGTTCCAATTTTAGATCAATTCTGGTTGAGTTCTCCATGGCGGAAAGCTCGGGGAGGGCGAATGGGTGGTTGGCGAAGATGGATTCCTCCGAATCGAGGTGGGTCTCTCAAGGTGAGGAATATTCTAGCGAGGAAGAGGAAGAAGAGGAAGAGTTGGTTCGCCGGGCTGTTTTCGAGTCGGAGGAAGAGGACAGCGGGACCCGGAGGTTGATTAGGACCGCCCCCCGGCTCGATTCCTTCGATGTCGAGGCGCTCGACGTCCCCGGAGTTCAGAGGAATGAGGTCGAGGAACTTGACTTGCGCAAGAACTTCATACTTGCTCTTCAGACTCTTGGTATTGTGTTTGGGGATGTGGGAACGAGTCCATTGTATACTTTTGATGTTATGCTTCATCAATCACCAGTTCGTGTGAAGGAGGATGTCATCGGAGCGCTGTCTTTAGTTCTATATACTTTGATTCTGATACCGCTGGTGAAGTATGTGTTGGTGGTCATTTGGGGCAATGACGATGGTGAAGGTGGCACATTTGCTTTGTATTCATTGATATGTAGACATGCAAAGGTAAGTCTTCTACCAAACCAATTGCGTTCTGATACCCACATATCAAGTTTCCGCCTCAAGGTTCCATCACCGGAGCTAGAGAGGTCTCTAAAAGTTAAGGAGCATCTTGAGTCTTCATTGATGCTGAAGAAACTGCTTCTTATTTTGGTGCTTTTTGGCACTTCCATGGTCATAGCGGATGGAGTTGTCACCCCAGCAATGTCAGTATTGTCAGCTGTGGGTGGTCTGAAGGTTGGAATAGCTAGCTTTGAAAAAGATGAAGCGGTGATGATTTCAGTTGCATTTCTTGTAATCTTGTTCAGTGTACAGAAGTATGGAACCAGCAAAGTGGGGCTTGCAGTTGGCCCTGCTTTACTTGTATGGCTTTGCTCCCTAGGGGGCATTGGAGTTTACAACCTTATAAAATATGGTGTAACAGTTTTGAGGGCATTCAATCCTGTCCACATCTATTATTATTTTGAGAGGAATTTAACTCAGGCTTGGTTATCTCTTGGTGGTTGTCTTCTGTGTGCAACAGGTTCTGAGGCAATGTTTGCAGATCTTTGCTATTTCTCTGTAAGATCTGTTCAGCTAACTTTTGTGTTTTTGGTTCTGCCCTGCCTTCTGTTGGGATACCTTGGCCAAGCTGCTTTCCTCATGGAAAATGTAACTACATCTGAGCAGGTCTTCTTTTCGTCTATCCCAAGCACTGCAGAGCTTGGAATAATGATGATGACAACAATTCTAGTAACCATCATTATGCTTCTAATATGGCAGATTAACATTTTCATCGTGCTTTTCTTTGTCATATTCTTTTTGGGGGTGGAATTAGTTTTCTTCACTTCTGTTTTGGGTAGTGTGGAGGCTGGAAGCTGGGTTTTATTGATTTTTGCAGCAATATTGTTTATGATAATGTACATATGGAATTATGGGAGCAAGCTAAAGTATGAATCTGAAGTTAAACAGAAGCTTTCAATGAATCTGATGATGGAGTTGGGCTGCAACCTTGGGACCATTAGAGCCCCTGGTGTTGGCTTAGTTTACAATGAGTTAGTGAAAGGAATTCCAGCAATATTTGGACACTTTCTGACCACCCTTCCAGCAATCCACTCTATGATCATATTAGTGTGCATAAAATATGTGCCGGTTCCTGTAGTTCCTCAGAGTGAAAGGTTTCTTTTCCGGCGTGTCTGCCCAAAGAGCTATCACATGTTCCGTTGCATTGCTAGGTACGGCTACAAGGATGTAAGGAAAGAGCAGCACCAAATATTTGAACAGCTACTTCTTGAGAGTCTTGAAAAGTTCATACATCGAGAAGCCCAAGAACGCTTATTAGAGAGTGATGGAGATAGTGATTCAGATGCGGAAGAAGCGGCATCACGTTCAAGAATTCTTATAGCACCAAATGGCAGTATGTATTCCTTTGATGTCCCTCTCTTGGCTGCTTACAACAGTACTGAGAAGCCAAGCCCGGAAGCAAGCACTTCATCTCATGAGGCTCGAGATGAAGCCATGCCAGATGCTAGGCAGAGTCTTGAGCAGGAGCTTTCATTCATAAACAAGGCTAAAGAGTCAGGAGTTGTCTACCTCCTTGGCCATGGTGATATTAGGGCCCGAAAGGACTCTTGGTTTTTCAAGAAACTGGTCATAAATTACTTCTATGCTTTTTTGAAAAAGAACTGCAGGAGAGCGATAACAACATTGACTGTTCCCCACACAAATTTAATGCAAGTTGGCATGACTTACATGGTTTAG
->XM_035180460.2 PREDICTED: Hippoglossus stenolepis sperm associated antigen 9a (spag9a), transcript variant X14, mRNA 
-CCAGGCGCCTGTGAACGCAGCATTTGACGAGGAAGAGGAGGAAATCCACGTAGCTCGTCTCGCGTCGCGGGGTCCGGTCGTGTTGTGTCCTCGATGTGTCGGCCCGTGTAAAGAAACGCTGCTTTTCTACTCGGCGGATAAAGGCGTCCATAGTGGCGGGGTGACGCGGGGCTGCCCACACCGGTGCTGTTTGCTGAAAGCGGGGGAGAGGACAGCGGGGAAAATGGAGCTGGAAGACGGAGTCGTGTACCAGGACGACCCGGGGACGTCCGCGATGATGTCGGAGCGGGTGTCGGGCCTGGCCAACTCCATCTACCGCGAGTTCGAGCGGCTCATCGGGAAGTACGACGAGGACGTGGTGAAGGAGCTGATGCCGCTGGTGGTGGCCGTGCTGGAGAACCTGGACTCGGTGTTCGCGGAGAACCAGGAGCACGAAGTGGAGCTGGAGCTGCTGAAGGAGGACAACGAGCAGCTCATCACCCAGTACGAGCGGGAGAAGGCGCTGAGGAAGCACGCGGAGGAGAAGTTCATTGAGTTTGAGGACACTCACGAACAGGAGAAGAAGGACCTGCAGAACCATGTGGACAGAATGGAATCGCACTCCCGACAACTGGAGCTCAAGATCAAGAACTATGCAGACCAGATCGGCAGGTTGGAAGAACGAGAGCTGGAGATCAAGAAGGAATACAACTCCCTCTATCAGAGACACTCAGAGATGATCCATAATTATATGGAGCATGTAGAGAGGATCAAAATGCAGCAGATTAACGAGACTTTGGAATCGAGCGCGGTCGGCCGAGTCAGGAGAGAACGGCCTCTTTCTTTGGGGATTTTCCCCTCGCCTGGTGGGGCATCTCTACTCATCCCAGACCCGCAGGCCAAAGCGGAGACGCCGGGCACAGACCGCTGGAGGTTCACTGACTCAACACAACCACGGTCCAACACTAGCCTCAAGCAGTTGGACTATGTCGACCCCCCAAGGGACAGGGAGGGTAAGAGTGCGCAGGACTCTACTTGGGGAAATTCACTGGCAGACGACTGCAAGGATGAGCTGTCGGACTTCACCGGCTCCAAGTCGGCCACACCAATGTCCACGACCGCCTCTGACATGGAGAGGGAAAATGGGAACAGTAAGAGCACTGAGGTGCAGGCGGCTCCAGGGACCAGATCCATATCAGTGGGTTTGCCTGAAAACAAAGACAGCTCAGACGTGCAGGACATCATTGAGTCCACCCCTGAACTGGACATGGATCTCGCTGGATACAAGCTCTGCAGTACTCCTACCAAAGGCATTGAGAACATGGCCTTCGACCGCAATACAGACTCTCTGTTTGAGGAGCTGTCATCTGCGGGCACTGGGATAATAGGGGATGTGGATGAAGGGGCAGATCTGCTGGTGGAGTACTCTGACCTTAGTTTGATTGGTATGGGCCGGGAAGTTGAAAATCTCATTCAGGAGAATTCACAACTGCTTGAGACAAAGAACGCCCTGAACGTGGTGAATAAAGACTTAATATTGAAGGTGGACGAGTTGACCTGTGAGAAGGAGATGTTGCAGGGAGAAATGGATGCTGTGATGCAGGCCAAGGCCAAGCTGGAGGACAAGAACAAAGACCTGGAGGAGGAACTCAAAAAAGTGCGAGTGGAGATGGAGGAAGTGAAACACAAAACTAAAGATGAAGAAGATAATGATGTACCTACAGCCCAGAGGAAGCGTTTCACCAGAGTGGAAATGGCCCGAGTGCTGATGGAGAGAAACCAGTACAAGGAGAGACTGATGGAGCTACAGGAAGCGGTGCGGTGGACAGAGATGATCAGGGCCTCGAGGGAAAATCCAACACTAACAGAAAAGAAGAAGTCCAGCATCTGGCAGTTCATTGGCTTCAGCAGACTGTTTAGCTCCTCCTCCAGTCCCCCCGCTGGGAAGAAGGTGGAGTCCCAGTCCAACGTGAAGTACAACGCCCCGGGCGGCATGGTGAAGAGGAGCAGCACCTTCTCCCAGTTCCCCACAGAGAAGTCCAAGACCTTTGACTTCCTCAATGAAGAAAAGGACCAGTGTAGTTCACCATCGCGTAAAGAGCAGAAACGAGCCCAGTACAGACAGGTCAAGGCCCACATGCAGAAGGAGGATGGACGAGTCACTGCGCACGGCTGGAGCCTGCCCAGCAAATACAAGGTGGCAAATGGTGGACAGGTGGAGAACAAAGTGAACTTACCTGTACCGGTGTACTTGAGACCTCTCGATCAGAAAGATGCTTCTATGAAGCTGTGGTGTGCTGCAGGGGTCAACCTGTGTGGGGGGGGGATATCAGAGCTCACGAAGCAGACGAAGGGTTCTCAGAGTAGCCTGGACCAGCTGGAGCAAGAGAATAAGGATCAGGAGAAAGTGGAGCAGGAGAAGGAGCTGATACTTCAGGATGAGACGTCCAGTCGGGTGTGGGTGTGTACCAGCACCCACTCCTCCACCAAGGTTATGGTGCTGGATGCAAGTCAGCCATCTGACCTACTTGACAGCTTCTATGCCTGCAACACCCACGTCGTCTGCATTGCCAGTGTGCCTGGGGTGTTGGAGTCAGATTTTTCGACAGGTGAGGAGGTACCACAGGACGTGGACGCTAACCAGGGTGATGTGGTGTCACTGGCCGGCAGTGTGGCCAGTGTGGGGTCTACAGGCAGCGATGGAGCCATGGCAGCAGAAGGGACCACCGCAATCCCACAGATAGCCAGCTCAGTTGAGCTGTCCAGAGAGTCGAGTCCAGCAGAAGATGGGATTCCTCCGGCGGAGGAGGCAACAGAAGCAACAGAAGCTAACGCTGGTGTGGGTGAAGAGGGAGAGGAGGACCAGGGGGCAGAACACAACCAGCCGGGAATCTACACAGAGCATGTGTTCACCGACCCGCTGGGGGTGGGACCCACTGACTCCTCGCCTACTGACGCACAGAGGGGCACCGGGCAGGATGGAGTGGATTCCTTGCCTCCAGACTCGGACCCGTCGGAGGGGGATGTCCTGAGGATGAGCAGCGCCCTCCCCACCATGTGGCTCGGAGCTCAGAATGGATGTCTGTATGTCCACTCGTCCGTGGCACGATGGAGGAAGTGTCTGCACGCCATCAAGCTCAAAGACTCCATCCTCAGCATAGTGCATGTTAAAGGGAGAGTCCTGGTAGCGTTGGCTGATGGGACATTAGCAATTTTCCACAGAAGCATTACAGACGGACAGTGGGACCTAACCAACTATCACCTGTTGGATCTGGGCCGGCCCCACCACTCTATCCGCTGTATGACCGTAGTCCATGACAAGGTGTGGTGCGGCTACAGGAACAAGATCTACATTGTCCAGCCCAAGGCCATGAGGATAGAGCAGAAGTCCTTTGACGCTCATCCTCGCAAGGAGAGCCAGGTGCGGCAGCTGGCCTGGGTTGGAGACGGTATCTGGGTGTCCATCCGACTGGATTCCACCCTTCGCTTGTTCCACGCCCACACCTACCAGCACCTCCAGGATGTGGACATCGAGCCCTACGTCAGCAAAATGCTTGGTACTGGTAAACTGGGCTTCTCCTTCGTGAGAATCACAGCTCTTGTGGTGTCCTGCAGTCGTCTGTGGGTGGGGACAGGAAACGGTGTCATCATCTCCATCCCGTTGTCTGAAGCCAACAAGACAACGGGAATAGTGCCAAATCGGCCCGGCAGCGCTGTACGGGTTTACGGTGATGACGGTTTAGACTGTGCCATGCCAGGCAGCTTTGTGCCATACTGCTCCATGGCCCACGCCCAGCTGTGTTTCCATGGACACCGAGATGCTGTCAAGTTTTTTGTCACCGTGCCAGGTCAGGCAATGCCTCCTCCATGTAGCGCAGATTCAGGCTCCGATGAGCCCCCGTCTGAATCCTCTGACACAGCGACCTCCGAGCCCAAAACACACCTGGTCATGAGTGGAGGTGAAGGCTACATCGACTTCAGAATGGGTGATGAAGGTGGCGAGTCGGACGGTTTATCAGAGCCGACAGCCGACCAGCAGTCGGCACCAACCAAGGCTGAGCAGAGCCACCTCATCGTCTGGCAGGTCACAACTTCTAATGATTGAAAAAAAAACAACTGACATACTGTTGTCAGGGCCTCCCTCCAATCCTTGCATGTCCTCCTCTAAGTTTTACATTTGATATTACTGATTGTTCTTAATGCCTGAGTAGTTGACTACTTTGTAAAAAAACAAAAACAATTATTTTTAGTCCATGTTTTGTACAGTTTATTGTTTATGAATTTGAAAAAAGTGAGGATTATGTCGGTTTAAGGAAAACGTCCACGGTCCGAGTGTTTCCTTCTGCCGGGGCGCATGTTGGAAAAGCAGGTGCACGCAGGAAAAAGTTCAAGTCAGTTCAGGAGAAGGTGCGAGATACTGTAAGTGTGATCGTTTGTTTCTAAAACGTCAAAAACGGGTTTAGATGTGAAGGACAAAAAGGAAAAAGTACTTGAAGGATTCAGGAGAAGTCGTTGAAAAGGGACCAGGGAGTTTTCATTTGAATGAAATATATTTTATGTTACACACATAAGACTTTTACATTTGTAAACCACATGTGAGAATGGAGTCATGAATTCTATCCTGTGTTAAGCATTTTTTTTTATTATCCATACTATTCGGGCTGGGTGTGTAAATGTGACACCTACAGGTCAGAATACATTCATGCAGACAGGCTGATACTGGTCGGTCTGCTAAGTAGAAAACCAGTTTTCACAAACAAGCAATCCACAAACAAACATTTCCTCTAAACTAAATGTACTTTTATTGAGTAAAAGCTGTACGATAAAACATTATCTTAGAGGTCTTATTTAATTAAAGGAAACCGAGCCGCAGGATTATGTTTAGGAATGTTAATCATATCAAAGCAGTTAGGGTACTGTAAGGTTTCCTGTGAATAGAGGACCCAGCTTACTGTACTGTAGGTTAGCATTAACCGGAATGAAGGGAATCCTGTATCCTTGTGTGTGTGTGTGTGTGTTCGCCTTCTCGGCCATTTTACGGCTCAACCCTCATCTATTTGCGCGAGAAGAATCCACCCGTGCTTCCTGTTTGCTTCCGCTCATCGGCACTTTAAGATGTTAGATGTTATTCGCGTGACATTTGGAAGAACACTCGTGGTGATGCACACTGCACTGCCATGTGCTACATTTATTTATTTATTCGGTTTAAAATAACAGGAACAATGCTCATTAATAAACATTTTTGTAAAAGGGAACATAACGGACAAATCTTTATAGGGAGGTGACACCCCAGTAACCAAAGGACGAAAGAAGATGCACCGTGAAACTATTTGTTTTTTGGTTTTTTTCCATCTTTTAAACGTCTCATGAGTAATAATTTGAAGGTTTTAAATGTATGTTTTGTTGAAAAATAGGCTTGAATAAGGGAATTGGACTAAAAGTAACATTTCCGTGTGGCACCTTCTAACGGACATGCACACAGCACTAAAGAGTGTCTCTCCTGATTGCCTCATCATTCCTTGTTTTGTTGTTAAAAATACATTTTGAGGCCTGGAAGGCAAATTTTGTCATTATTTTTCTGTTGCTTTGGGCATCGTGCGTGTTTTGTATTCATCTGTGAGACACTTTCATTAAGTGAAGACTATTTTGTTGAAATAACCGAAGGATTCCAATATTGAGCAAGTGTTTTAATTTGTTTTTATATCTGAAAACTTGGACCACTGTTGGTCTTCAGTCTATTTCAAAATATTAACTTTATATTGTGCTTTATTTTTCTGCCATTCCAGTATTTATTTCCTTTGTTATGGAGCCTATCTGGGTTCAGAATGTAACTTTCTACATAAGTATAATAGGAGGCTATTGTAAACGGAATAGTCCAATGCGTTTACACGATTGTTAATAATGGCTAAATAAAAGAAATCAATGTTA
->XM_041364600.1 Suillus fuscotomentosus uncharacterized protein (F5891DRAFT_1130999), partial mRNA 
-ATGCACCCCTCAGAATTAGATGCTAGGATTAGAGTGCTCCCACCCTGCTTTGAGGTTTGCCATTTCCAGAATGGTTGGACTGTGCTCTCTCAGATCTCTGGTAGAGAGAGGAAAGAGATGGTGTGCATCTTATTGGGATGCTTAGTGGGAAAAGTTCCTCGACAGGTCATACTTGCATACCGCTCCTTACTGGACTTCATCTATTTAGCTCAGTACCCCACTCACGATGATCAAACCCTAAGCTATCTTCAAGATGCTTTGGACATGTTTCACAAGCATAAGGGGGTGCTTATTGAACTGGGCGTAAGGGACCACTTCAATATTCCAAAAATACACAGCCTCACCCACTATATCAACTCTATACGCCTATTTGGTGCCATGGACAATTACAATACAGAGGCATTTGAGCGCCTTCACATTGATTTTGCTAAGGACGCCTGGAGGGCAACTAATAAAAGGGAGGAGTGCCCTCAAATGACTTCATTGGAGATGACTCAGCTTCCATTTGACAAGCTTGACATATACCATGGTTTCAAGTTTGTTTTGGAGGAACTAGGGGAGGATGAAGTTGACAGTAGTAGACAAACTGACTGGATAAAGGCCTGTCCAAAGACTCATGGTTCCCATGGTCAGAAACACTTTGATACAGTTGTGGCCATGAGGACGGATGAGTGCCAAGCTACTGGGGTTCAAGGCAAAATCGGGCGACTTAGGTTATTGTTCAAGCTACCCCAACAATGGTATACTATGCTCAAAAATGTGCCAGAGAAAGAACACTGTATGTATGAGGTGAAGAAGATGCCACTAAGGAGCGGTAATGTAGTACCAGCAGATATCATTCCTATCAGCACCATATGTCAGACTTGTCAGCTAATTCCTTGTTTTGGTACTGCTGATGTTTCCAGAGAATGGAGATCAGAAAATGTACTGGATCTCTGTGACAGGTTCTTATTAAATAATTGGTCCACCAAGTATGCATACAAAACACTGTATTAG
->XM_041096011.1 PREDICTED: Gossypium hirsutum uncharacterized LOC107900440 (LOC107900440), transcript variant X1, mRNA 
-ATCTTCAATTGTCATCAGTTCCGTCACACCCCAATTCTCACAGTCAAACACTTGGAACCTTCTTTCATACCCCACTGCCATTTTCCCTTTCATTTTTAACCGTAATTTTTCCATTTCCTCCTCACTCAACTTTCAATCCTTCTTCTTTGTACATAAAAGAATTCGCAAAATCAAAAAAAAAAAATTGAAGAAAGAAAGGAGATGGGTTTTTCAAAGGAAGAGAAATCGAGAAGAATTTGGAGGGTATTGAAAACAGTGTTTTTCTTGATAACAATGGCGATTTCGTTCCTCGTATTTTCTGCGCCGGTTTTTCTCGTTCTAGCCGATGCTCTTTTGCCTTCCGCTTTGCTCTCTGCTTCGCTTTCTCCTTCTTATTTATCACTCCAATCCCTTTCTTCCCATTTCGATAACTATGATTTTAGATCTTCTCTCATAGATATTCCCCTCATATCCATCATCAGATCAGCTGTTATAATCGTTGTTTACAGTTTTTGTGATGGGCCAAAACTTTCGAGGGGACCATACCTGGGAATCACAATGATTTGTTCGATTTCATCGTTGGTTTTTGTTTCGATAAAAGCTTCGTTTGTGTTCGGTTCGAGAATTCCTAAAGAAGGGACATATGTTACAGCCATGGAAACCGCTCTTTTCATTTCTTCATTGGCTTTGGCAATTGCACACATGACTGTGGCTTATAGGACAAGTTGCAGAGAAAGAAGAAAGCTCCTTGTCTACAAAATTGACATTGAAGCTATTTCAGCTTGCAAGAATGGGTTTCCAAGGTATCATAAGATTCTCCAACAAGAAAGGGTGAAGTAAATGCAATATTACCAACACTGAACGATTTTCCTCTCCAAGAAACCTACCCTGTTCTTGGCTCATCACATTCTTCTTTCTCACATTTCAGATTTAACCAAAACCAATCAGTCACTTGAAAATCAAAGTGTTAACAAGCAGATCACAGCCAGCAGATACAGACATACATACATACATACATACATACATACATACATATATATATTATATTTCGAGGAAATGATCGAACATGCAATGATTTTGAGTGTACAGTTTGTATTACATCTGTAAATATTAATTTAAAAACAAAGGAAGAAATGGGCCAAAGGTCTTTTCCATACCCCAATTTTTTTTTGAAATATTTGAAAAATATTTATTTTAGTTATTATTTTGGCCGAACGATTTAGGTTAATTATTTTTGGTTCGAATAAAAATATTAAGGTTAAAATATGTTTTAACTCTATATGCTCTATTTTTAAGAATTTCGTCTATCTGTCCCTTGCCGATTTCAATTTAATTAGTCTAACCAACTGATTTGATCCAGTTCAAGTTTTTATGTTTTTTTTTATAATCTTTATAAGATTATATTAATTTTAGTACTTTTTATGATTTTTATAGAATTTTAATATGTTTTTTAATTTCAAATATTTTAAATTTGTTTTATTAATTTTATAAAAATATTTTAGAATTTATTAGAATTTTATATTTTTATATTTTTTATATCAATTTTCATAATTTTTATTTTTTATATTTAATATTTTTTAATTATTTTTATTGGAAAAATATTAGATTAAACTAGAAGCTGCCATCTGTCAACATCTAATTAGTCCGCCAATTTATTTTGACAGTCAACATGGTTAATGATAAAAATTGTTAATGTAGGAGCTTAATTGATTATTTTAGTTAATGATAGAGGCTAAATTGAATATGAATTTAATACATGGGCTTAATTTATCTTTTTTGCAGCTTTTTAAATATATAAGTCACATAATTTAAAAACAACAAAGGTTGTGACATAAATCCTATATATAAACATAGTAACTTGAATTTGACTATTTTTTTTGGACTAAAATAATATAAACCTAGACTTGCTTAAGATATTAGAGTATAGGAGGAAGGGTTGTATGAAACTGTGATTCCATGTCATTCTTTATCTCTTTCCATTCTCTTATTATAAAGAGATAAAAATGATATGAAATTACAGTTTCATACAATCCCACCAAATTAAAGAAAAAAAATGAATAAATAAATAAAATTCATTTTTTTATGATTCGATAAAGGAATCAAAATTCAAAGTTTTTGTGTGTTTGTTCTTCAGCTTTGTGCAATGAGAAATTTGGTGAATTTCATTTAAATAAATAGAATTTAGATGCCAACATTTGGGGAATTTTTACAAGTTGGAAATAAGGATCAAAACAATGCCCACTGCATCTCTATTACCTGAACAACATTTTTATCCCTCACTTTCAAATCCAGGTAAAATAGTGATCGTAACCCCAACTTTGGAAATGATTACACCTCCACTCCATCTTCTTTACAATGGCTAAGATGCCCAGATTTAACGCCGACGCTGCAGATTGATCGGAAATCGCTTTTGGGTTCGGGTTGTGGGGAAGAAAACTAGCTTATCTTCTTCAGCAGGTACCCAACTGTATCAGAAATATAAACTCAGAATGCAACAAGCTTCTATTTTTTAACTCAAGTTCTAAATAAAACTCGGTTTGATTACCTGAACTGAGTTACAAGGTGGTGTAAGAAGACTGAGATTTCTACTCTAGCAAGCTCATATCCAGGGCACAATCGAGGCCCTCCTCCGAACGGCGTGTAAAAATTCCCGGAACAGCTCGTCCCCAAGTTATTATTCTGTTCAATTTCATCCAACACTTCTTTGTAACTTTCGTCGTGTACCATGAACTATAATGTTGCGTTACATCTTATACTTAAATTTACCTTCCATCTCCATGGATTGAAAGTGCGAGCATCTTTAAAGTGATCATGATCAAGATGTACAGCACGAAACGATGCAAAAACCTTCCAACCCTTTGGAATTGTGTAACCTGGTCGAGTTGAGTTACCAGTAAGCACACAAAAAATGAGTCTAACAGGTTTCGGATTCGAATTCTAACA
->XR_004848542.1 PREDICTED: Amphiprion ocellaris uncharacterized LOC111577915 (LOC111577915), ncRNA 
-ATGGCTGCACAGTAAATGTGTTTGATGCTGCCAGCTGAGCTGCAGATGGATGTTCATTTTTGTTTCTGTCTTGTGTTTCAGTAACAGCTGTAGCTATTGCAGCAGGCGCTGGTGGAGCAGTGGTCTCTGCTCCGTTTGTTCTGGGAGCCATAGGTTTCACCTCAGCTGGAATAGCAGCAGGTTCCTACGCTGCAGGCATGATGTCCACTGCTGCTATTGCTAATGGAGGAGGAGTTGCAGCAGGGAGTCTGGTGGCTGTTTTGCAGTCAGCAGGAATGGCTGGTCTGTCTGGGACTGCTACTGCAGCCGTGGCCAGTGCTGGAGGAACGGTGGGATTTTTGGCTACTCTCATCTGAGATGAAGCTGGAAATCATGAAGGAATAATACATACGAGACAATGTATTTGCTTTTGTAAATTAGAAACAAATGCCAACAATATCAGTGAAGTCGAACTTTATCTGTCAGTAAAGTAAAACTTGACTGAAATCTGTGGGCAAAAAATGTTTCTGTGTTTTTACAAAGCACATTTATATTGTCAAATTGTCCAAAATAAAGAATAACAATGAAGGAA
->XM_034416225.1 PREDICTED: Pantherophis guttatus spondin 2 (SPON2), mRNA 
-AAAACCAACCACTGCCCCGCTTGGACTAAAGGGACTTTTGCAGGCATAAATAGCAAGATTTCCTCTCTTCCCCTTGCAGATTTTCCAGCTGGGAGACAAAGCAAGTTCTTCTCCTAACAACCTCACAGCCACCGGAACACCCGAAATGGGAAACTCACTACCTGTGTCTGGTTCTGACAAGACAATCGCAGCACTGCTGGTTGCACTCTTGAGTTGCGTGGATTGTGTTCCCCTCGAGGGAGAGACCCTGTGTGGTGCAGAGGAACCAACCACCTACAGCATTGTCTTCACGGGGAAATGGAGCCAAACAGCTTTTCCAAAGCAGTACCCGCTCTACAGACCCCCAGCGCAGTGGTCCTCCCTCCTAGGTGTGGCCCACAACTCGGACTACGTCATGTGGAAGGCCAGCGGCTATGCCAGCAACGGCATGCGTGAGTTGGTGGAGAAGGGGGAGCCCTGGATGCTGATGAAGGAAATTGAAGCAGCTGGAGAGAAAATGCAAAGCGTTTATGGAATCTTCTCCGCTTCTCCTGTGGTTACCGGAACAGGACAGACCTCAACTCTCTTTGAAGTTGACCCGGGTCATCCCTTAGTATCCCTTGCAGTACGAATCGTGCCCAGCCCTGACTGGTTTGTGGGGATTGAGAATTTTAATTTGTGCGACAAAAATGGCTGGAAGCGCCACGTCTCCATAGATTTATTTCCATATGATGCTGGAACGGATAGCGGCTTTACGTTTTCCGCACCCAACTTCGCCACGATCCCTCGCGATACGATCACGGAAATCACCTGTTCCTCCCCAAGTCATCCTGCCAACTCATTTTATTACCCCAAGCTTAAGACTCTGCCGCCGATTGCCCGGGTGACCATGGCAAAACTCAAAAGAAAGAAATTGGGCTTTCTCATCTCTCAACCAAACGTCACAACCACCCATAACGAAGTGGAGGATTCAGTCTCGGAAACACCTTTGGATTGTGAGACCTCTCTGTGGTCTTCGTGGGGCCTTTGCCGTGGCACCTGTGGAAATTTAGGAACGAAAAGACGGACTCGGTACATACTACTTCAGCCAGCCAATCATGGGACCCCCTGTCCAGATCTGAGCGAAGAAACACACTGCGAACCAGATAATTGTGTCTGAGATAATTTCTTTGGACCATCGTTTACCTCGTGTAATTTGGGGGATATTTAAGGTATCTCTGCGTTGATATTTTTTATAGCTCATGAGCTGTCCATCTATCCATCTATCCATCCATCCATCCACCAATCCAATAGATAGATCTACTTAAGGGATCTGAGCTTTCTACACGTTTATTGTGAACTCCTACAGTGCCACCTAGCGGTCAGAAATAGTAGTAATAGTAGTAAACTCGAATAGTAAACTTAGTGTTACCAACATCTGCACGGAGAAAAGAGGCAGGCGAGAATCTTTTCATTTCTGCTACTTCTGGAATGTATTTAATGCATCTGAGGAATAATGAGCTAGTTTCTACTGACTTACGAAATGCTGGAGAATTAAATGTATAAGTTTTGAGGGAGAATCAACTTGAAGGAAAAAGAAAACCAAGTTTTTCTCAAGAGTACGAGAAAAAAGCCGAGATTTATTTGGGTGTGTGTGTGTAATTCTAAAAATTTTAAGCTGTTGTTTGAAAACTCTTGGGCTGGCTATGGTGAAAGTTGGCAAGTTTTATCTTTTATGCAGATTTCTATGAATTTTGTCCTGTTCTGTAAAGAGCTAAGAAGGCCTAAAAGGAGAACTGTAATAATAATTTGCTAAAAAGTTTGTGTACCAAGGCGTAGAGTATATACGTCCTTTACTTACAGTGTTCTATATTTCTGGATTTTTTTTTTCTAATTAAAAACAAACATTTTCCCTCCGGTTAAATAATA
->XM_047217565.1 PREDICTED: Lolium rigidum uncharacterized LOC124682972 (LOC124682972), mRNA 
-CACACGCCTAAGTGCCATTGATGGCCACGAAAGCCTGGAGCGGCTCCACCCGCTTCAGATCTCCGGCCAGCGCCGTCTGGTTCCTAGCGGCCGCCATCCTCATCCTCATCTTCCTCCTTCAGCGCCGCCCGCCCATGGACCCTTACGCTACCCCAACCCCTCGGACCTCCGTGTCGTCCCGGCGCGCCGAGCTGTACGGCAGGATGGCGCGGGATCTCGACGAGCGCGGCGCCGCGTTCTTGGAGGGCGGCGAGACGTCGCAGTCGCTCACGCTCTCGGACCTCTTCGACGTCAGAGACAGCGCCGTCGTGCCCAGACTCAAGGCCGCCGACCCACCGGTGCGCGCGAACGTGCTCTACCTGGACCCAGAGTTCGCGGCCGTCATATCGAAGGCTGTGAAGGAAGTATTTCTTCCTTATTTTGACAAAGTTATCTGGTTCCAAAATTCCAGTATGTATCACTTCAGTATGTTTCATGCCTCCCATCACCTGGAGCCAATCTTAGCATCCAAGGCCGAGATTGAAGCCGAAGTCGATGCTGTAAAAAGAGTTACTAAGGCTATTTGTCCCATTCAAATTGTCTTGGATCAAGTGGTCTTGACATCAACTGGAGTTCTTCTTGGCCTGTGGCAGGTTGAATCTGGTACTGATCCTGCCGACATCCGCTCAAAATTGAGAGAGGCTCTCCCTCGAGCACCTCAAAAGCAATTGTATGACCCTGTTCTGCTTCACACCTCCTTTGCACGAATTTTGGGACCTCCTAAGCTTCCACAAGAGGAGAATACGACATCTTTTGATCACATCAAATTCTTCCATGACCTCGTTGCACAAGTTAACGGGAAGATCCGTGGGTTCCAGGCGAAGGTAGCGGAGCTGTGGTATGTAGAAGAGTACGACGTCCTCGCACTAGCGCTGAATGGAAAGATGAAAGTTCGGAGGCTCAACCTTGGCTGCAATGAAGAATAGAGCAACTGACGGAGGACAAAGAGAACACCACGGGGATATTAATCCATCGCGTCCAAGCATTATTATGCAACGCTTGGAATGCTTTCGTGATTCGAACATCACATCCATGGCAACCTTTTGTTCTGCGAAGATTGGGACCAGGCAGCGCCGAGGAAATAGCAGCTGGGTGCCCCCAATAGAGAAGTAGAGATCGAATGTAATTGCTTTCACACCACAGTATTTGAGTACTGGTGATTCGTGAATATGTGGATGAAAATCAAACCTGTATTTGTAACACCTCTCCTGTTACTCAGAAAAACTTCCAACTTA
->XM_017403287.1 PREDICTED: Daucus carota subsp. sativus GBF-interacting protein 1-like (LOC108227900), transcript variant X2, mRNA 
-AATAACAGTGAATGGGCTGGTCTAGTGAGCATCAGGAGGTAATTTGGTTTTCAAAACCCTTGTTTGCGTCCCATAACTCTTTTTGAGCCGTTCTCAACTATTATATATAAACACACACAATCACTCAAAACCCATTTGAAATCGAATGCAACTCGCTCTTCTATTGGCTCTGTTAAACCCTGTTTTGATATTGGATTACTATCCCAACTGGGTTGTTTTCAAGTATCTCAAAGATGGTGTCTTCTTCCTCAACTTCAAGAATTGATGGGGGCCCTCAAATACTGTCTGCTGGCGTGAGAAAAACAATCCAATCCATAAAAGAAATCGTGGGTAATCACTCTGATGCTGAAATTTATTCCACCCTTAAAGAGACTAATATGGATCCTAATGAAACTGCCCAGAAATTGCTCAATCAAGGTCCCCTTTTTTTTCTTGATCCATTTCACGAGGTCAAAAGAAAAAGAGACAAGAGGAAAGAGGTTACAATGAACGTGGGGCATACTGCATCACAACAGAAAAAGCACAGTGAATCATTAAATCAAGGGAGCAAACACACTGCACATTCTGATCACAGTGTCAGTGGCAAAGGAATTATCCGGAATTCTTTGCCGGATGCAAAGGCTAGCAGAGAGTTCCGTGTTGTGAGGGACAATAGGACTAATCATAAGCCAAGCAGCAAGATAAAGCCTCCCTTGCAAAGCCAAATATCTTCAAATGAACTAGAAGTCCCGAAGTTTGCCAATAAGAGCTTGAACGTGACTTCTAATGAGCAGAAACAGACAGTTGTGCGTCATCTAACTAAATCTTCAAATGGAACGACTGAGACACAGCCTAGGCAGCCAAGGGTTGTTCAGATTAATAATAAGAAAGAATCATTGGAGGATAATCGATCCGCAGTTATAAAGCCTGTTACACAGATTCAAACTAAGAGCACAAATGATTCCCATCTATCTGCAACTTTATCTAACAACTCTGTGGCAGGGGTATACTCTTCATCTTCTGATCCTGTACATGTACCTTCTCCTGATTCCAGACCAGCTGCTAACATTGGAGCAATTAAGCGTGAAGTTGGGGCTGTTGGTGTACGTCGTCTGTCTACAGAAGTTTCTCCCAAAGGTTCATCACCACAATCTAATTCTTTTCCTAATACACATTTGGGACGTGATGGTCCGTCAAGAGATTCATATCGATCTTCTGCTTCCCTGTCTAAAAGCAGCCATCCTAGTCAAGCTCCTGTTAATGACTCGACTTTGAAGAATATTCCAGTCAATAGGCCATCTGTTAATAATCAGCAGGTTAACAGACAGCATCAATCTGGTGGTCATCAAAAAGTTTCTTCACATTCTAACAAGGAGTGGAAACCTAAATCAACCCAAAAACAAAGCACCGGTCCTGGAGTTATTGGAACACCATCAAAATCTGCTTCCCCTCCTGCTGATGCCTTAAAGAATTTGGAAACAGAATCAACTCAGTTGCCATCACATGTAGACATCTCGGACAATGAGAATGTAATTATAGCTCCACATATACGAGTCTCCGCAACTGACAGGTTTCGAGTGACTTTTGGCAGTGTGGGTACAGAGTTTGAACCTTCCAGAAACCCGGGGTTCGAAGCAGTAAAAGTTGCAGAGGAGCCTTTGATTGATCCTTCAGGAAGTGTATCAGTTGCTACTCCTGACTCTTCTGGTGATGAATCTTCTGGAAGTAAGCAAGAAGACTTGAGAGATGAAAATGTTCGCAATTCTGGTAGCAGTTCCCCTGCGTCTGCAGCAGTATCTGAACAGCAATTGACCAGTAGGATAGAATCATCAGGTCCTCAGGATATAGACAAGGGGGCAGAGGTTGAATTGGTGCGTAATAACAGTCAGTCTCACACTCCATCTCAGTCACAACCACACCAGGATCCTTCCCAGTTACCAATATTTTCTTCATATGATCCCCAGAGTATGTATGACATTCCGTATTTTCGATCATCAGTCGATGAAACTGCAAGGGTGCAAAGTCTGCAGTTTCCTCAGGAGGCTATAAGCTCACATACAGTAAATAACATCCCATCATCTACGGTAGCCATGGTGCAACAGCCGCAGTTGGCGCAGATGTACCCGCAAGTTCATCTTTCTCATTATGCTAATATGATGCCATATCGTCAATTCCTCTCTCCAGTTTATGTTCCACCAATGGCTGTGCCAGCAGGCTATACTAGTAACCCTTCCTATCCTCATCCATCAAGCGGCAACAGTTACTTGCTGATGCCCGGAGGTAGCTCCCATCTGCCTGGAAGTGGGGTCAAGTATGGAATCCAGCAGTTCAAACCAGTCCCCACCGGCAGTCCAACTGGGTTTGGCAACTTCACTAATCCAAATGGTTATCCTATCAATGCTCCTACTGTTAGTGCGACAGGACTTGAAGACTCGTCTAGGCTGAAGTACAAAGATGTGAATCTTTATGTTCCAAATCCACAGGCTGAGACCTCTGAGATATGGATGAATCCGAGGGACCTACCTACTATGCAATCAGGTTCATACTACAATATGACTGGACAAACACCTCATGCTGCATACTTGCCATCCCATACCAGTCACGCCTCGTTTAATGCAGCAGCACAATCTTCTCACATTCAATTTCCAGGCATGTACCATACTCCACAACCTGCTGGAATCCCCAGTCAGCATCATCCTGCTGTGGGCGGTAATGTTGGAGTTGGATTGGCTGCAGGCGGGCCAGCAGCCCAAGTTAATGCCTTTCAGCAACCTCAGCTGGGCCACATGAATTGGACAGGGAACTTCTGAAGGCCTTTCTAATCCTTGAGAATTTTATTAAAAGGGATTGGAGCTGATTATCTGTGGAAGTCCTCTCCTCTCTTTGCCCCTTTTCTCCTCAAAACAAAACTTAATCTACAAATCAATACATTGAGTTGTGTTCAGTCCTTGCTGGTTTATATCTGTGATTCAGGGGACGGTATGTCAACCTTTATATGGTTGTATGCAAGTTTATTAGGATTAGAGCAGGCTTTCGTTTATAAGTTCGGCCCTATGTTTTTATAGCCCGACTGAAAATATATCTCCAAATGGTTTAATTGTTTTGGAGGTTTATCAGGTCAGGGCAGGCTCTTGGTTTATAAGTCTGCCCTCATTTTTTCAGCAGTCTGTTTTTTCTGATAAATAATCTCAAAATATATCAGTCAGCCCAAATTGGGACATGTAGTTCTAGCATTTACATAACAATGCATTATTTTTTTTGTGTGAACCAAAGTGTCTGTGCAGGAATTCTGTAGTGTAGTATGACTTATGTTTTGAGATAAATGAATCATACTTTGTAATCCCAGTTTCTGAATTATTGGAAAAATAACACTTTTGATGACA
->XM_006679287.1 Batrachochytrium dendrobatidis JAM81 uncharacterized protein (BATDEDRAFT_11902), partial mRNA 
-AGACATTTGACTGGAAAAACACATGTTGCCGGCAGTGATGGTGATAATCAGTTTGCTACTTACATCAAGGAGAGATGGGAAGCTGCTGGTCTTCCCATGACCCATATCGATTCGTACTATCCATTGCTCAACTACCCCATCTCTCGCTCGCTTACTTTATTGGAGCCATTTCGATACGATGCAGTGCTGAGAGAACCAGCTATTGCCGAGGACACTACAAGTGGGGATCCAGATGCTGTTCCTACCTTTCTAGGCTACTCTCCTTCTGGAAACGTCACTGCAGAGCTAGTGTATGCCAATTTTGGTGGTATAGAAGACTTTGCTATGCTAGCTAAAAACGGCATTGATGTCAAGGGGAAAATTGTTTTGGTCAGATATGGTGGTGCGTTTCGTGGTTTAAAGGTTCGAGCTGCTGAGCTCTCTGGAGCTGCTGCTGTTTTGATCTTTTCGGATCCTGCCCAGGATGGTTACAAAATGGGTGCTACGTATCCTGACGGACCGTGGAGACCACCTCATGGTGTACAAAGAGGTTCTATCCAGTATCCAACATTTTACCCTGGTGACCCACTTACGCCTTTTATTGCTGCGACAAAAGATGCTCCTCGTATTCCAATTGAGGAAGCACCCATTCCCAAGATTCCTGCAATTCCAATTAGCTACGCTGATGCTGCCCCTTTTTTGAAAGCTCTTGTCGGTCACGGAATTCTTGCCAGAACCTTATCTCTCAATTGGCAAGGAGGTCTTGACATGGATTATTGGACAGGACCTGCTGCAAAAGTAAATATGTATGTCAACAATGATTTCAAAATCAAACCTATTTGGAATGTTTTGTCCATCATTGAGGGTAAACACGAACCCGACCAAGCCATTATTCTTGGCGGACATAGTGATGCATGGGTATATGGCTCAGTTGATCCATCTTCATCCAATTCCGTGATTGTTGAAACTGGTGTTGCACTTGGTAAAATGTACAAGTCTGGCTGGCGACCCGATCGCACCATCATTCTTGCAAGCTGGGATGGTGAAGAATACGGTTTATTAGGCTCTACCGAATGGGTTGAGGATCATGTCGAAGTACTAAATAGAACTGCGATCGCGTACATTAATCTTGATATGGGTGCTTATGGACCACACTTTCATGCTGCTGCTAGTCCTTCTCTCGCTAATCTTATCCGTGATGTAACCAAGGGCGTAAAAGATCCCAACTCGGGAAAAATGGATACACCTCAAGGTCGTGTTCCACGTATTAGCCCACTTGGATTTGGATCTGATTATGTTGCATTTTTGCAATTTGTTGGTGTTGCTGCTATGGATATTAAATTTGAAGGCGACTATGGTGTGTATCACTCCAACTATGATAGTTTTCATTGGATGGAAAAGTTTGGAGATCCCACTTGGGAATATCACAAGACACTTGCTAGTATTGTTGGTCGCATTGTTCTTTCGCTTGCACACGATGAAATTCTTCCATTTGACTATGCCCCTTATAGTTATGAGTTGACTCGATATGCTACAGATGTAAGCACTGCGCTCCAGACTGCTGAATTTCCTATCGAATGGGCAAGTAGTTTGCACGAAGCCATCCAACTTTTTTCAAAAGCAGTAAATAAGTTGAACAAGGCTATTGACGGATTGTCTGATATTGAAACCAAGACGAATGCTGAGCAAATGGATGAGCCCAAGCTTGTTGTTCAAGGAAACGACAACAACGAAATAATGATGATTACATCTTTTGATGCAGACTTGTCAGCATCCAAGAAACACAAAAAACGACCCAATGCCAAGAAGCTTAACAAGATTCTTGGATTTGGGGAGCGCGCCTTTATCAATAAGGATGGCATTCCTGGTCGACCATGGTACAAACATGTTGTTTATGCACCAGGAGAGTGGTCTGGATATGGTGCAGAGATGTTTCCTGCAATTCATGAAGCCATTCGTGCGCATAATGAAACTCGAGTGCTAAATGCGATCGCAGTTGCTTCGCATCAAATTCAACAAGCTGCAGAGATGCTTTCTCCTTGA
->XM_023773343.1 Ramularia collo-cygni uncharacterized protein (RCC_08091), partial mRNA 
-ATGGCGCAAGGTCCAGCCAAGAAGCCAAAGGCACCAGCCGTAAAAACCACGCAGCGCAAGCAGACCGGAAACCGTGTAATCAAACCGAAAAAGGCCGTCCTGATCAAGCAGAATACGATGAAGAAGGCGCATTCCAGTGGTCTGGCAGCCCTGACCGAGAAGTCTCTGGCCAATAAAGCGGGACATTTGGAGCTTTTGAAGGGCGGCAAGAGGGAGAAGCGGGTCGCGATGAAGGAGGCGGCAGAGAAACTAGCGAAGAAGAAGTGA
->XM_001417720.1 Ostreococcus lucimarinus CCE9901 predicted protein partial mRNA 
-ATGCTGGACGTGTCGTGCGGACCGGGGCTGATACTCGACCTCTTGGCGCGCCATTCGGCGCGCTCGGGGAAGTGGGAGCGCGTGGTTGGTTTAGATTTTTCTCGAGAGATGGTGACACTGGCGCGCGAGGCGTGCGGCGAGCGCGCGACGGTGGTGGTGGCGGACGCGTGCGATTTGCCGTTCGCCGATGGCGCATTCGACGTCTTGCATTCGAGCGCGGGGGCGCATTGTTGGGGCGATTTGAACAGCCGTGGCGTTCCCGAGTCGGCTTTTCGCGAAATGTATCGAGTTTTAAAACCGACGGGGGAGATACTGGTATCGACTGTCGTCCTGCTGAAGCCGACGACGGTTGAGGAGGAGTACTCGCGAACGCCGAACACGCCATTTTTCGACGAACGCGCGGTGTGCCGGATGATTCAAGACGCTGGGTTTCGCGATGTTGAAGTTATAGCAAAGGATAAGTGTTTCGTGGCCGTCAAGGCTGTTAAGTGA
->XM_048826826.1 PREDICTED: Caretta caretta laminin subunit beta 3 (LAMB3), mRNA 
-GCACCCACCCCACAGGAACTTCCTTCCTCAGGTGAGGCTGCATTTAAAAGCAGAGAGTGAAAGGAGACAGCCCATGAGGACTCAGGTGAGAATTCGTATCAGCTGCTCAATAACGGAGGAAGAGGAAAGAAAAGTCTAGCCCCTGAACCAGGTGAGTCCTCAGAAGTATGGAATCTCCCCCCCGGCCCATTGTATGGACATGTTTCATTCTCCTGGCTTTGCCACGACTCCTGGATGCACAGGGCTCCTGTTCCTATGGTGCCTGCTACCCACCTGCGGGAGACCTGCTGGTAGGAAGAATCCATCACTTGAAAGCCTCGTCGACATGTGGCCTTGTGAAGCCTGAGACCTACTGCACATCGTATGAGGAATGGAGGATGAAATGCTGCCGATGCGATTCCCGACTGCCTCATGCTTACAACAGTCACCGGGCGGAGAACATGCTTTCCTCCAAAGGACACATGCGCTGGTGGCAGTCCCAGAATGATGTGAACCAGGTCTCCTTGCAGCTGGATCTCGACAAAAAGTTCCAGCTCAGCAGCATCTTGCTGGACTTCAGGGCGCCTCTGCCCGTGGGGATGCTTATTGAGCGCTCCACCGACTTTGGCGAGACCTGGACGATCTATCAGTACCTGGCCTCTGACTGCGCCGCTACCTTTCCACGGATCCCCCAAGGCTCCCCCCAGAGCTGGCAGGACGTGCGCTGTCAGGAACTGCAGAGCCACCAGGGGCACCCTCTGCACGGGGGGAAGGTCAAATTCAACCCCCTTGACCTGGCATCCGGCATCACCACATCTCACAGCCAAAGCATCAGTCACCTGGGAGAATTCACCAACCTGAGAGTTAACTTTACCCAGCTACCTCGCCTCCCACAGCAGGGCTACCGCTCACCCAGTGCCTTCTATGCTGTGACCGAAATGCAAGTGCAGGGAAGCTGCTTCTGCCATGGACACGCAGACCGCTGTACTCCCTCCAGAGACCCCAATGCCGTGATGCAGGTTCACGGACACTGTGTGTGTCAGCACAACACGGCCGGCCCACACTGTGATCGCTGTGCAGCTTTCTACAATGACCAGCCTTGGAGGCCGGCAGAGGACCGCAACCCCAATGAATGCCGGAGGTGCAATTGCAACGGTCACTCGGAGACGTGCCATTTTGACCCAGCTGCGTACCAAGCCAGCGGTGGGGTGAGTGGAGGTGTGTGCGACGACTGTCAGCACAACACAGCGGGGAGGAACTGCGAAAGCTGCCAGGCCTACTTTTTCCGCAACCAGCGGCAAGATGTCACCCATCCGGAAGCCTGTCTGCCTTGTGAGTGTGACCCGGACGGCACGGTGCCTGGGTCCAGCTGTGACCCTCTGACCGGACGCTGCGTTTGCAAGGAGAACGTGCAAGGGGACCGCTGCCATCTCTGCAAGCCTGGGTTCACCCAGCTCACCAATGCCAACCCTCTGGGATGCCACAAATGTGCCTGCAGCATCCTGGGGACCCGCCAGGACGCACCCTGCGACGACGAAACAGGGAGGTGCTTCTGCCTGCCCAACGTGATGGGAGCCAATTGCGATCAGTGCTCTGCCAATCACTGGAAGATTGCCAGCGGCCAAGGCTGTCAGCCGTGCAACTGCGACCCTCGCAACTCCTTCAGCCCACAGTGTAACCAGTTCACAGGGCAGTGTCAGTGCCGGGAAGGCTTCGTGGGGCGTACCTGCTCCGCTGCCCAGCTGCGGGTTTGTCCAGATGGGTCCTATGGTGACGTCAGGACAGGATGCAGAGAGTGTGACTGCAATTTCCAGGGCACGGAGGGGATGGGGTGTGACAAGACCACAGGCAGCTGTCTCTGCCGCCCTGGCTTTACCGGGCCTCGCTGCGACCAGTGCCAGCGGGGTTTCTGCAGCAACTACCCCCATTGCGAGACGTGCCACCCCTGCTTCCAGGCCTACGACAGCGACATTCGCCGGTTCGGCCTGCGCCAAGTCAGCCTGAGAAACTCCACCTCACGACTGCAGCTGGGAACAGGGGGCGCTGGCTTCAGCACTCGTGTCTTGGAAGCAGAAGGCAATGTTCAGCAGATTCAGGGGATCCTCGGCAACCCCCTAGTGACGCAGCAGGGCCTGGGTCAGGTGTCCAGCATGCTCACTGCAATCAGACAGCAGGTCCAGGGCATAAATCCTGACCTACCCTTTGTGAATGACACCTTCTCTCTAGCCAATGATCTTGAAGCCCTGGACAAGAGCCTGCTTTTCGTTAATGGGCAGTACCAGATTAAGAAGACCCAGTTTGAAGCCAGCCGCCACACAGACCTTTCAGGAGCCTTCAAGACTGTCAGCTCTGCGTACCAGAGCTCCACCAACGCCAGCTACCGCATAACGGGCACTTCCAGCCTGCTGGCTCAATCCAGAGAGAACCGGAGAATGACTGAGGGGCTGGAAAGCAGCTTTACAGACCACCCCTCCAGGCTGGAGGCCCTCCAGGGCGAGATGGCCTCCTCCCCCAACTTGACACCAACTATAAATAAGATTTGCAGTGGCGTCAGATCCAAGGCCTGCACCCCTGGGCACTGTGACGGGGAGCTGTGTCCACAGGACAGCACAACGGGGTGCGGAACGGGCCTCAGCTGCAGAGGGATCATTCCACTGTCAAGTGGCGCAGTCAGAACTGCTGAGAAGACCACCAGAGAGCTCGATGGCATAAAGACTCAGCTCCAGCGGACCATGCAGATGATCAGGGCAGCAGAAACGGCTGCAAACCAAATCCAAAGCAATGCACGACGTCTCGGGGACCAAGTGAGTGTAACCAGGACCCAGATAGAAGGAGACGTCCGACGCATCCAGCAATTCATCCAGCAAGTCCGCAACTTCCTGTCAGACCCAGCCACCGACCCTGCCACCATCCAGGAGGTCAGCGACTATGTGCTCTCGCTCCGCCTCCCAACGGACACTGCTGCCGTCCTGAGGAAAATGACTGAGATCCGAAACCTGGCTGCTAAGCTGCAGTGTCCTGAGAGCATCCTCACCCAAACAGCTGGTGATATCGCTAAGGCCAAGAGGCTTCAGCAAGAGGCTGAACAGGCAAGGAACCGAGCAAATGCTGTAGAGGGCAACGTGGAAGAAGTGGTGGAGAATTTGAGACAAGCAAACACAGTGCTCCAGGAAGCCCAGGATGCTATTAGTGGCTCCAGCTATTCCCTTCGGCTCATCCAACTCCGCATTGATGAGATCCAGGCTGTCCTTGGTCCAACGGAGAAGAGTATGAGAGACATTACTGATCAGCTGGACAACTTCACCGAGAGAATCAGCCAACTGCGGCACAGGGCGGAGCAGAATCAGTTGCAGGCCACCGATGCTCAGCAGAGAGCAAAAGAAGCCATTGAGCAAGCAAGGAGCACTCAGCAGGGATTTGAACGGGTAAAACAAAAATACGATGAGCTAAAGAGGCGGATGGGACAGAGTTCGACACTGGGAGTGCAGGGCAGCAGGATCCAAAGTATCGACAGGGAGGCAAAAGCGCTCTTTGAAGAAACCTGGGCTATGATGCTCAGGATGGAAAGTATAGAAATGGAAATTCAGAAAAGCAACAATGCATTAATCATCAAGTCAGCCAGCCTTGCAGGCCTGGAGGAGCAAGTGGAAAAGATCAGCAGTCATATCCATGAAAGAATCGCCTACTACACCGGTTGCTAATCAATCAATGAGCTGCTGGGACTCCATCTTGCCCTGTAATTGCAGAGTCTGCCTTCTGTTCAAACACTGACTGGGGTAGTTAGCCCCCTCTCATAGAATTTTCTTGTTCTCACACTTAGTGTCTTTGGTAACAGAACTGCTGTAGCTTTAGAAAATGCTAGCATGGAGCCCAAAAGGACAAAAATGCCTCTGGAGAGAATGAATGTTATATGGCCTGGCTGAAGCAACCCTGGGAGGCTCTAGGAAAGGGGGAAGATATAACTAATGAAAAAAGCCTTTTGGAAGGAGTTATTTCTGTATGAGGTTTGTTAATGTGACCGGGGATGTTTGTTTTAGCACCTGGATTTTACCTTTTGAATGACAAAGACCAGAGTTGAGGTTTAACTTTTCTGGTACAGTGCATTTAGTTCTTCTAAGGGAGTCATAAGAGGAGTAGAACTAAGGCTACAGATAAATATAGGACCAGATAACTGAATAAGCCCTATTTATACAAACGTAAGAGCAGTTGTGCTCTCAGGTGGAGTTAGATACTATCCAGTTGGACTTAGACAATATGTTGCAAACTGAAGCCTGTAGGGAAC
->XM_019557682.1 PREDICTED: Lupinus angustifolius nucleolin 1-like (LOC109325361), transcript variant X10, mRNA 
-GTCGCATATAAAATCATTGTTATCAGCCGTAGCCTCATTCTCTTCCTAGCTTCTCAAAACCCTAAACCCCTTTCTTTCGTTGATTCATTCCTCTCTATTCGATGGCCAAGTCCAGCAAGAAATCCGCTTCCAAAGCTGATGCTGCTCCAGCTGCAGCAGTTCCACCTTCCAAGTCTGCCAAAAAGAGCAAGAGGCAGCCAGAAGATGAAATTGAGAAGCAGGTGAGTGCTAAGAAGCAGAAGGTAGAGGTGGTTGCCCAGAAGCAAAAGAAGGAAGCAAAGCTGCAAAAGGTTAAGAAGGAAAGTAGTTCAGATGATTCATCATCAGAATCTGAAGATGAGAAACCTGCTGCAAAGGTTGTTGTTCCTTCAAAAAAGCAACCAGCTGCTGAGAAACCAAAGGTGCAGAAGAAGGAAAGTAGTTCTGATGATTCCTCTTCAGAGTCAGAAGATGAGAAACCTGCAGCAAAGAAAAGCAAGCCAGCACCCCCTTCTAGCTCTTCTGATGAATCATCTGATGAGGATGAAGCTCCAAAATCCAAGGTGGCTGCTGTTAAGAAGGGCTCTGCTCCCGCAAAGAAGAATGTGCAGCCTAGTGAGAGCTCTGAGTCATCTGAGTCTGACTCCGACGACAGTTCTGATGAGGACAATGCAACTAAACCTTCCAAGAAATTGCCTGCCGCTGCTGCTAAGAAATTGCCTGCCGCTGCTGATAAGAAATTGCCTGCTAAGAAGGCTGAATCAGACTCATCCTCTGACAGTAGTTCAGATGAAGATGATAAAAATGCTGGCAAGTCGGTGCCTGTTTCTAAGCAGCCCACAAAGAAGTCAAAAAGTAGTTCTGATGAGAGTGATTCAGATGATGAAGAGAAGAATGCTAAAGCTTCTAATGGTAACAAGAAACCCACACCTGTTGTGAAGGTGGTGAAAACTGAGTCCAGTGATAGCTCATCAGACGATGAGGTAAAGATGGATGTTGATGAGGATGATAGTAGCTCTGATGAAAGTGATGAGAAGCCTCGAAAGAAAAAGCCTGTAAAAGACTCAAAAGAAAGCTCTGATGATAGTTCAGAGAGTTCAGATGATTCAGAGGATGAAGATGACAAGAACAATTCCAAAACTCCCCAGAAAAGTGTTAAGGATGTGGAGATGGTTGATGCCTCATCTGGAAAGAAAACTCCTAATACCCCGGTAACACCGAAAGGAGAATATGGTGGATCAAAGACACTATATGTAGGCAACCTGTCATATAGTGTGCAGCGGTCTGATGTGGAAAATTTCTTCCAAGATTGTGGAGAAGTTGTCGATGTTCGCCTTGCAATAGATGATGATGGGAGATTTAAGGGCTTTGGACATGTTGAATTTGCAACATCAGAGGCAGCCCAAAAGGCGCTTGAGTTGCGTGACCAAGAACTGTTGAACCGTCCTGTCCGGCTTGATTTAGCTCGTGAAAGGGGTGCATATACTCCCAACAGTGGGCCTAACAGCGGTAACTGGAACAACTCATCCCAGACTGGTGGAAGAGGCCAGTCTCAGACATTATTTGTGAGGGGTTTTGATAGATCCCTTGGAGAAGATGAGTTAAGGTCTAGCCTGGAGGAGCATTTTGGTACATGCGGGCAGGTTACAAGGATATCTGTGCCAAAAGATTATGATTCTGGTGAAATTAAGGGGTTTGCTTACTTGGACTTCAAAGATGGTGAAGGCTTTAGCAAAGCTCTAGAACTCCATGAATCTGAACTCGGAGGTTATACATTATCAGTTGATGAAGCCAAACCTAGAGACAGTCAAAGCTCTGGTGGTAGAGGTGCAGGTAGGAGTGGTGGTGGCCGCTTTGGTGGTGGAAGAGGTGGTCGATTTGATGGAAGAGGCAGTGGTGGACGATTCGGCAGCGGTGGTGGTGGTCGATTTGGTGGTGGTGGCCGATTTGGTGGTGGGCGTGGTCGTGGAGGACCAAGCAGACCAAGCTTTGCCCCAGAAGGGAAGAAGACCACTTTTGCTGATGAGGATTAGAGTGTCTGGAATCTGAAGTTTACTATTTTATTATGTGCTTTTAATTTCAGTTTTTTGCTCCAGTTTTGGTATTTGTTTGTATGAATTGGTAGAAATCAAGTGTATTTGGGATTTTCAGACAATGTCTTATGGATTTGTAGTTCTGCTACCTATCCAAACCATGTATGCAGTTTGTTAGGTAAAGACATATTCAGAAATATATATTTATTATATATTTAA
->XM_039356821.1 PREDICTED: Crotalus tigris PTPRF interacting protein alpha 1 (PPFIA1), transcript variant X7, mRNA 
-GAGTTTGCAGCACTTACTAAAGAGCTCAATGTATGCAGAGAGCAACTCCTTGAAAGGGAAGAGGAAATTGCAGAATTGAAAGCAGAAAGAAACAATACAAGAGTCAGTTCATCTTCTGTTACTACTAGAACATTTGGAATGCCTTGTCTCCCGGCATGAAAGATCTTTAAGAATGACCGTAGTAAAAAGACAAGCTCAATCGCCAGCTGGTGTTTCTAGTGAAGTTGAAGTTCTCAAAGCACTAAAGTCTCTATTTGAACATCACAAAGCCCTTGATGAAAAGGTAAGAGAAAGGTTACGAGTAGCACTTGAACGATGTAGTTTGTTGGAGGAAGAACTAGGTACTACACATAAAGAGTTAATGATTTTAAAAGAACAAAACAATCAGAAAAGAACACAAGCTGATGGAATGCCTGATATTAATCATGATCAGGAGAATATACCTAGCACTAATGGGAAGAGATCTTCCATTGGCTCTTTGAATCATGATGAAGATCTTGCTAAAGTAATAGAACTTCAAGATATCATAGAAAAGCAAACTAAAGAACAGTCACAAATGAAAGAAAGAATTACTGCCCTTTCTAATAGAGTAGCAGAACTGGAAGAAGATCTTGATACTGCTAGAAAAGATCTAATCAAATCTGAGGAAATGAACACCAAGTTGCAAAGAGACGTACGAGAGGCAATGGCTCAGAAGGAAGATATGGAAGAAAGAATTACAACTCTTGAAAAACGCTACCTCGCTGCACAACGTGAAGCTACATCTGTGCATGATCTTAATGATAAACTTGAAAATGAAATTGCTAACAAAGATTCATTGCATCGACAGAGTGAAGACAAGAATAGGCAGTTACAAGAACGATTGGAACTGGCTGAACAAAAATTGCAGCAAACTCTGAGAAAAGCTGAAACTCTGCCAGAAGTAGAGGCTGAATTGGCTCAGAGAGTTGCTGCACTTAGTAAGGCTGAAGAAAGACACGGAAACATTGAAGAACGATTGAGACAAATGGAAACACAGCTAGAAGAAAAAAATCAAGAACTATTAAGGGCCCGTCAAAGAGAAAAGATGAATGAAGAACATAATAAACGTTTATCTGATACAGTTGATAAACTTTTATCTGAATCTAATGAAAGACTTCAGCTTCACCTTAAAGAAAGAATGGCAGCTCTGGAAGATAAAAATTCCCTTCTCCGTGAAATTGAAAGTACCAAGAAACAAGTGGAGGAGCTTCAAAATGAAAAGGATCAGTTGGTAGTAAACGTTGAAGCAATAAGGGCTGAAAATGACCAGTTGAGGATCAGAGGCCCTGCTCTTCATCATAGTAGGCCACATTTAGGTAGTGTACCAGATTTTAGATATCCACTGGCACCTTCAGTTATAGCAGACAATCAGACAGATTCCTACAGCACCTCAGTTCTACGACGTCCACAGAAAGGACGCTTAGCAGCTCTGCGAGATGAGCCTTCAAGGGTTCAGACTCTTAATGAGCAAGATTGGGAACGTGCACAACAAGCAAGTGTATTGGCAAATGTTGCACAAGCCTTTGAGAGTGATGCTGATATCTCAGATGGTGAAGAGGACAGAGAAACTATATTCAGCTCAGTTGATCTCTTGTCACCTAGTGGTCAGGCAGATGCCCAGACCTTAGCCATGATGCTTCAGGAGCAATTGGATGCCATCAATAAAGAAATTAGATTGATCCAAGAAGAAAAGGAAAACACTGAGCAAAGAGCAGAGGAGATAGAAAGTCGTGTTGATAGTGGGAATTTAGACAATCCTGGTCGATTCCGATCAATGAACTCTATCCCACCTCCCTTTCCTAGTGGAAACCTTTCTGGTTCCTCTCCACCAGGAAGTGGGCTTTCTACTCCTCGAAGAATGCCACACAGTCCTGCTCGAGAAGTGGACAGACTAGGAATTATGACATTACCTAGTGATTTAAGGAAACACCATAGAAAGTCTCCAGTTTCTAGAGAAGAAGTTAGAGATGACAAGGCTACAATAAAATGTGAGACCTCACCACCTTCTTCACCTCGATCACTGCATTTGGATAAATCTTATAAAGGAGCTTTGCATACAATGAGCCAGGAAGATATAAGAGATCTTCGAAATTCTACAGGCTCTCAAGATGGACAGATAAGCAATCCCAGTAGCAGTAATAGCAGTCAAGATTCTCTCCACAAAGCTCCTAAAAAGAAGGGGATCAAATCCTCAATTGGCCGCCTATTTGGTAAGAAAGAAAAAGGTCGATCTGGACAGATGAATAAAGAGATCCTGGGACAAGTTAGTGTATTAGAAGCAGAAAGTTCAACTCAAGATGGTTTGGGGCTTGGAAAACTTGGAGGACAAGCAGAAAAGAATAGAAAACTGCAAAAAAAGCATGAACTTCTTGAAGAAGCTCGGAGGCAGGGTCTGCCTTTTGCTCAATGGGATGGCCCCACAGTGGTTGTCTGGCTAGAGTTATGGGTTGGGATGCCAGCTTGGTATGTGGCTGCTTGCCGTGCAAATGTGAAAAGTGGTGCTATAATGTCAGCCTTATCGGATACTGAAATACAGCGTGAAATTGGAATCAGTAATCCTTTACATAGGTTAAAACTGAGACTTGCCATACAAGAAATTATGTCACTAACGAGTCCATCGGCTCCTCCTACATCAAGAACGACTACAGGAAATGTCTGGGTAACGCACGAAGAAATGGAAAATCTTACATCTACACCACAAACGGAAGATGAGGAAGGAAGCTGGGCTCAGACTTTAGCCTATGGTGATATGAACCACGAATGGATTGGCAATGAATGGCTTCCTAGTTTGGGGCTTCCTCAGTATCGCAGTTATTTTATGGAATGTTTAGTTGATGCTAGAATGTTGGACCATTTAACTAAAAAAGATCTTCGTGGTCAACTTAAAATGGTAGACAGTTTTCACAGAAATAGCTTCCAGTGTGGCATTATGTCTCTCCGAAGATTAAATTATGACCGAAAAGAACTTGAAAGAAGAAGAGAAGGAAGCCTGAATGAAATTAAAGATGTCCTTGTTTGGAGCAATGACAGGATGATTCACTGGGTGGTATCAATTGGCCTTAAAGAATATGCAAATAATCTTATAGAAAGTGGAGTTCATGGTGCACTTCTGGCCTTAGATGAAACTTTTGATCACAATGCATTAGCTCTGTCTTTACAAATACCCACTCAGAATACACAGGCTCGTGCTGTCTTGGAAAGGGAATTTAATAATCTTCTTGTGATGGGTACAGACAGAAAGTTTGAAGAGGATGATGATAAAAGCTTTAGACGTGCACCGTCATGGAGGAAGAAGTTCAGACCAAAGGACATAAGGGGTTTAGCTGCTGGATCAGCAGAGACCCTCCCTGCAAATTTTAGAGTTACCACTTCAATGTCTTCACCTTCTATGCAACCAAAGAAGATGCAGATTGATGGCAATGTATCAGCAACACAAAGATTGGATTCTGCTACAGTAAGAACTTATTCATGTTAAAGACTTTCGTTGTTTATCCCCACTATTTCTACAGATGAACTGAACCATTTTGAACCCAATGACCACATTTTGGAAACAGCTGAAATCTTTAATCTGTTAATACTTGTTAAATCAACACTTTGAAATATTTTATTACAGAGTTTTTAATTAGCAGGTGAATTTGTGAGTACTATAAAAAGTATTTTAGATTAAATGTTTCTTATGTGGGTGTATGTGTGTCCCATTACTTAATTTTCTATTAAAATTGTCAATCAAGTTATTACTTTATGTTAATTTTAGTATTTTCATCTGAATGTACTGTAATGCTTGTATGTATCTGTCCCTGTAAGCAATATAGGGCTTTATTGTAAATTATGCAGTTATTGTAATTACCAATAATGAATTTAATAAAGTGAAGGTGAATTTTTTTTTACAATCTTTGTAAAGACATCATGACACCAAGCAATATCAATATATATATATTGCTGTTTGAAAAATGCTAGCTAGCTCTAAAAATTGAAATAATTCCTTTTTTTCAGAGAGGCATATGTTTATTAACAAAACAGGCATGGTACCTGATTCCATTTCCGTTAGAAACTGTACCTTTTAAACTTTTAACATTTGATTATTTAGTGTGTATTCTTATTTAAGGCTTTTGTTTAGTATAATTTGCTTTATATTCATAAATGTGGGAATTTGTAGAACATTATGAAACATATGAGACCTAATGAGGTCATTTATAACTACTTTTTGTGGCTGTATTTGTACAGTCTATGTTCATTGATTGAGCATAAGCAAGCCATAAGCGGAAATATTTTCTGTTAAGCAAGAATAGTTACTACATATTTTCTGTTAAGCAAGAATAGTTACTACATAAGAGTACTTGACAGGCAACATGGAGTGCTCCCTTTCTGGGTTTTGATGTGAAAATGTTTGTGAAAAGATATCAATGCAGTTCTTTTAATGGACCAATCATGATGCACTGCTGCCTCATGACAAAGATGTTAAGAGCATAACATATGGAGGCATGTGGTAGTGCAACTATTAAAAAGGCCTTACTTTTCTTATGTCATCTTTTAGATATATTTATAAGCTTGTTTTTAAATCCAGGCAGATTTTTTAGTTGTTAATAGTTTGAGTCATTGCAAACAGTATAAGTAGAAAATGCATCATTCATTTTTAAATAGCATCTTATGAAGCCAGCAAGGAGGAGATTCAGATCATGGTGCATTATTTATTATACAATAATATACATGGCATGTCTTTTTTCTGTATTTGGTTTTGGCTCTTTTTAAATTGTACAACTTGAATTCATTGTTACTATTTTTTCTATTAACCTTATGTGTACTTTGAATAATGTAACAAATTATGTACAGTCTAAGTACTTTGAACTATTTTTATCACAGTATTATTTATTGCTTTCAATAAATTTCTGAAGCATTTTTCCACTGCCAATAAAATGTTACTATCTTGTGATGAGGCTTGAGATGTTTTAAAATGGTAATTCAGATATTAATGCAAATGAAATATCTTGTGACGTATTAATGCTTCCTTTGGCAAAGACAGTTTTATAAGATCCTTTTCACTTTAGAAATCACACTCTGTATATTATATGTAAGATATACTATTACTATATAAACTTATCAAAATGATTTGTGCAAAAAATTTAAATTCTGAATGTTAATACATTCAAAGAAGATATATTCCAAGGAATGATTGTATGCATTAAATCTACCAGATCTCAGGTCCATAAATCCAGATAAGACTATCAGATAGCAGCAAAGAAATGTGGAAGACTCAATTTTTTTTACTGCTCAGTATTGATTATATGCATGCATATCTTAATCTGAATTTTAGATACTAAGACTAAGGAATTTAATCTTCATTGTGATTATACTGAAGCTATATATAAAATGATCAAACAGA
->XR_002477788.1 PREDICTED: Aotus nancymaae transcription initiation factor TFIID subunit 9-like (LOC110567331), misc_RNA 
-ATTACGGTTCTTCTTTTTCCAAGTGAATATCTTTTTCCTTCTGTTCTTTAAATTATAATGTAATACATGATCACAAGAGACAAATCAGAAAATACAAGGAAGCAGAAATAAAGAAATCAACTTCATTTGCACTCAAGGAAAAGAAACTGTCATCTCTCAATGCAGGTCCTTCAGTATCCCTTTATTCTGTTCATTCATTGATGTAAAAAGGATTTGTGAGTTACCGATGTGCCAGGTGCTATGCAGGTGTTACACATAAACTCATCAAAATACAGTTCCTTCCCTAAAACAGATCAACCAAGTGGAGGCAGAGAACTGAATAAACAATTATACCTAAAGTTTTCCTACATATACAGCTATCTATATATGTAGATACAGTCTTTGCAAAAATTAGAATATATCATGAATGCTATTAACCTAATTTTGGGCCTAATACATCAGAAAAAAATTTTCCTGTCAATAGATTCAATCCTTGCTCATAGCCATTACTGGAGGTAATAAAGAGAAAAAAAAAATAGATTCAATCCAGAACAACAAAACAAACTCTAGAGCTAAACCTAATAAGAATCATAGTCGGGGGAGCAGTTGCAGCGAGGACCATGTTGCTTCCGGACATCCTGCTCACCGGTACACCAGGGGGTTGTAAAAACCACACTAGGCAAAGAACTTGCGTCAAAATCAGGACTGAAATACATTAATGTGGGTGATTTAGCTCGAGAAGTCTGATCATAGGATATCATGGAGTCTGGCAAGATGGCTTCTCCCAAGAGCATGCCGAAAGATGCACAGATGATGGCACAAATCCTGAAGGATATGGGGATTACAGAGTATGAGCCAAGAGTTATAAATCAGATGTTGGAGTTTGCCTTCCGATATGTGACCACAATTCTAGATGATGCAAAAATTTATTCAAGCCATGCTAAGAAAGCTACCGTTGATGCAGATGATGTGCGATTGGCAATCCAGTGCCGCGCTGACCAGTCTTTTACCTCTCCTCCCCCAAAGAGATTTTTTTATTAGATATCGCAAGGCAAAGAAATCAAACGCCTTTGCCATTAATCAAGCCATATTCAGGTCCTAGGTTGCCACCTGATAGGTATTGCTTAACAGCTCCAAACTATAGGCTGAAATCTTTACAGAAAAAGGCATCAACTTCTGCGGGAAGAATAACAGTCCCGGGGTTAAGTGTTGGTTCAGTTACTAGCAGACCAAGTACTCCCACACTAGGCTCACCAACCCCACAGACCATGTCTGTTTCAACTAAAGGTGGGGACTCCCATGTCCCTCACGGGACAAAAGGTTTACAGTACAGATGCCCACTTCGCAGTCTCCGCTGTAAAAGCTTCAATTCCTGCAACTTCAGCAGTTCAGAATGTTCTCATTAAATCCATCATTAATTGGGTCCAAAAACAATTCTTATTACCACTAATATGGTGTCATCACAAAGTACTGCCAATGAATCATCAAATGCATTGAAAAGAAAACATGAAGAAGATGATGATGACGACGACTATGATAATTTGTAATCTAGCTTTGCTGCATGTAACGTGTACTTGATCTTGAATTTATTATACTGATATTAAACATGCATGCTGGATGTTTTCAAGTTGTGTTTTAGAAAACTTTAATAATATTTAATGAGTAAATACAATTACCATACTTTTCAATTTAAATGAAGGTTCAGCCTTAAAAGTGTAAGAAAAATAAAGTTGTCATTCATTAAAAAAAAAAAAAAAAAA
->XM_035574191.2 PREDICTED: Spodoptera frugiperda proline-rich protein 36-like (LOC118262654), mRNA 
-GTTGGACAGGCAGCGGCGCGCCACCAACATCCGCGCCGTGTCGAGGCGAGAGAGCAGCCACAGTCAGTCCGGCGCCGACAACCGCCACGCGAACACGTATTCTCCAAATAATGGCCGCCGCCCACACGCACCCGGCCCCCGCGCCCTCAGACCGTCGCTCAGAGGGCCGTGCCGGTTCCCGCCGTATATTCCCACCACAATTTAAGCTGCAAGTTCTCGAAGCGTACAGGCGTGACGCTCAATGTCGCGGAAATCAACGAGCTACAGCAAGAAAATTCGGAATACATCGTCGTCAAATCCAAAAGTGGCTTCAAGCGGAACCTGCACTTCGAGCAGCACTTCTGAGGCGAGCGCCGCAACCAGCGCCGTCGCCACCGCCTTACGCAGCTGGATCTCCAGAGAGCGCACGGCTGCCTTCGCCGCCACCAGTGACAGTAGCCACACCGGTGCAAGTGCCCACACCTTTACCAGTACCAGTGCCCGTTCCTGTGCCTATGCAAATTTCTGAGCCCATCGACCTGTCAGTACGTCGACCTACACCACCACCTGCGCCTCAACCGGCCTATGTGCCACCTACGGCACCTTGTCCGACACGCAAGCCTTTCAAACTATTCCGGCCGTATCTACTTGAAGACGAAGAAGAAAAGCGACCATCGCTGGCATCGCTGCCTGTGTCTAGCGGCGTTCATGTGTCAGCGTTTGTACCGGTGCAAAGCGCGGCGGGTTGCGCGCTCGCTGCGTGCTCCGCCCCGCGATGGTGCTCACCTATTCCCTCCTTCCCGGCTCCACTCAGATGAGAGTGTGCCGTCGGAGCCCTGCTCCGTAACTCCTGTGATCTAGTCGCTGACGCCCGCCTGGCGCCGCCTGGGGCGTAGCCCTTTATCATCGTGCCTTAATGTTCACGCCGCCATAGTGCATTATGCCGTCATCACCCGATGACAGATATTTTGTGTATAAAGTTTAAGATTGTATTTTTATATGTGGGGTTTATGAAGCTTACCTACATTTATAAAGAATATAAATATTATAACGTCTATTATTATTATTATTGAATAAATAAAGAGGATTGTTTACTAAAA
->HQ100547.1 Uncultured Brachymonas sp. clone F5OHPNU07HZVCK 16S ribosomal RNA gene, partial sequence 
-TGGATGATGTGGTTAATTCGATGCAACGCGAAAACTTACCACCTTGACATGGCAGGAATCCCGAGGAGATTTGGGAGTGCTCGAAAGAGAACCTGCACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGCCATTAGTTGCTACGAAAGGGCACTCTAATGGGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTACATCCCGGGCTACACACGTGCTACAATGGCAGGTACAGAGGGCTGCGAAGCCGCGAGGTGGAGCGAATCCCAGAAAACCTGTCTCAGTCCGGATTGAAGTCTGCAACTCGACTTCATGAAGGCGGAATCGCTAGTAACCGCGAATCAGCAGGTCGCGGTGAATACGTTCCCGGGCCTT
->XM_030296100.1 PREDICTED: Lynx canadensis ADP-ribosylation factor 2 (LOC115501167), transcript variant X3, mRNA 
-GCCCCCGCGCCAGTCGCCATTTTGCAGAGGGGAGCCGAAATCCGAAAGGCAGTGGTGTGGGTAACGGTGCCCTGTGCGGCGGCAGGTAACAGAATTCAGTCACAATGGGGAACGTTTTTGAAAAACTGTTTAAAAGTCTATTTGGGAAAAAAGAGATGCGGATTCTTATGGTGGGTTTGGATGCGGCTGGAAAAACCACCATCTTGTATAAATTGAAACTGGGAGAGATTGTGACTACCATCCCTACAATAGGTTTCAATGTGGAAACGGTAGAATATAAAAATATCAGCTTCACAGTCTGGGATGTTGGTGGCCAGGACAAAATCAGACCTTTGTGGCGACATTATTTCCAGAACACCCAAGGTCTGATTTTCGTGGTTGACAGTAATGACAGAGAGCGGGTCAATGAGGCCCGAGAAGAACTAACCAGAATGTTGGCAGAAGATGAGCTCAGAGATGCAGTTTTATTGGTGTTTGTAAATAAACAGGATCTTCCGAATGCTATGAACGCAGCGGAGATAACAGACAAGCTCGGCTTACATTCCCTCCGCCAGAGAAACTGGTACATTCAGGCCACTTGTGCCACCAGTGGAGATGGGCTTTACGAAGGCCTGGACTGGCTCTCCAACCAGCTCAAAAACCAGAAGTGATCGGAAGCGATCCCTTCCCCGTGTGATGGAGGTCGTCAGATAGTACACACAAACTGATGATACGCCGTGGAGATGAATTTTTTTTTCCCTTTGAAAGTTTCGATATTCTTCTCACCTTTTTTGGTAGCAGCTTTATTGAGACAT
->XM_052553176.1 PREDICTED: Carassius gibelio lipopolysaccharide-induced TNF factor (LOC127953842), transcript variant X2, mRNA 
-TCAGATTGTCTCAGATAAAAGCACCCATCAAGGCCATGGCAAGCGCACCCCCGCTGGAGTCATCCACTCTTGTGGGACACCCTCCTCCTCCCTCGTATGAGGAGGCACTGGGATCAAACCCGCAGTACCCACCAATGCCCTACGCTCCTGCTCCTGCTCCAGACATGAAGACATCTGTGCCTCCGTATCCAGCACAACCCTACTGTCCCATGTATCCACCACCACCAGCTCAACAAGGTCAACCCATCACCAGTCCTGTTGTATCTGTGCAGACCGTGTATGTTCAGCCTGGGCTGGTGTTTGGGAGTGTCCCGGTGCAGGCACATTGCCCAGTGTGCTCACTGAATGTGATAACTCGCCTGGAGTATACATCAGGAGCATTAGCTTGGCTCTCTTGTGCAGGCCTGGCCATCTTCGGTTGTATCTACGGCTGCTGCCTGATTCCCTTCTGCGTGGACAGCCTGAAGGATGTGATACACCACTGTCCGAACTGCAGCAGCGTTTTAGGAGTCCACAAGAGAATCTGAAGCAGCTGCAGAACATATGAATGAGTTGTGTAACATACCACTCTGTGTTTATAATGGGGAAACGTTACAGTCAATTCATCTTTTTAGCAAGAGTTAATTCAATATCTGTTGCACCGACACACACATATTCAAATGTATGCGCGCACGCGCGCACACGCACACACACACACACACATATCTTAACATACTTGTCTATTCAATTTAAAAACTGTTATTTGACCAAAAACGAACTCTTTTTTTTTTTTATAATTGTATCACAATTGTGAAGGAATCTTTATAACATTAGATTTACGTATAAACAGTGCAATTATTCTCAATTATATTTTCTGTAATCAAACTGATGTAGGGAAATATTATACAAATAAATATGTATATGCTTTTCACACTTAAA
->XM_030451652.1 PREDICTED: Calypte anna neurexin 3 (NRXN3), transcript variant X4, mRNA 
-ATGGGCTTCACTCTGCACTCCATTTACTTCACCTTGAAGGTGAGTTTGCTGCTGGGCTCATTGCTGGGTCTCTGTTTGGGTCTGGAGTTCATGGGAATTCCCAATCAGTGGGCCCGCTACCTCCGCTGGGATGCCAGCAGTAGGAGTGAACTCAGCTTCCAATTCAAGACCAACGTCTCTGCTGGGCTGCTCCTCTACTTTGATGATGGTGGTGTCTGTGACTTCCTCTGTCTGTCCCTTGTTGATGGGCGCATCCAGCTCCAGTTCAGCGTGGACTGTGCAGAGACTACAGTTATCACAGACAAGCAGGTCAACGACAGCAACTGGCACTTCCTGATGGTCAGCCGCAATCACCTTCGGACAGTGCTGGTACTGGATGGTGAAGCCAAGCCAGGTGAGGTGCGTCCACAACGCCAGTATATGAACATTGTCAGTGACCTTTTTGTTGGTGGAGTCCCACTGGACATCCGTCCTGCTGCCTTGACTCTTGATGGTGTTCTGAGTGAGCCTCCATTTCAAGGATTTATCCTGGATCTGAAATATGGCAACTCTGAGCCGCAGCTCCTGGGCAGTCAAGGGGTGCGACTGGAAATGGAAGGGCGATGCTCAGAAAACCCCTGTGAAAATGGTGGCACATGCTTCCTCCTGGATGGTGAGCCACACTGCGACTGCTCAGCCACTGGATATGCTGGCAAACTGTGTTCTGAAGATGTCAATCTTATTCCAGGACTCTCACACCTGATGATGGGTGAACAAGGTAGAAGTAAAGCACGAGATGAGAACATGGCCACTTTCCGTGGTTCCGAATACCTTTGCTACGACTTGTCACAAAACCCCATCCAGAGCAGCAGCGATGAGATCACTCTCTCCTTCAAGACCTGGCAGCGCAACGGGCTCATTCTGCACACCGGCAAGTCGGCCGATTATGTCAACCTGGCCCTGAAGGATGGCGCCGTCTCGTTGGTCATTAACCTGGGATCTGGGGCCTTCGAGGCCATCGTGGAGCCAGTCAATGGCAAGTTCAATGACAACGCATGGCATGACGTTAAGGTGACACGCAACCTGCGGCAGGTGACAATCTCTGTGGATGGCATCCTTACCACCACGGGCTACACGCAAGAGGACTACACCATGCTGGGCTCAGATGACTTCTTTTACGTGGGAGGGAGCCCCAGTACAGCTGATTTACCTGGCTCTCCAGTAAGCAACAACTTCATGGGCTGCCTCAAAGAGGTTGTTTATAAGAATAATGACATTCGTCTGGAGCTGTCTCGCTTGGCACGGATTGGCGATACTAAGATGAAGATCTACGGGGAAGTGAAGTTTGTATGTGAGAATGTGGCTACACTGGATCCCATCAGCTTTGAGACACCTGAGGCATATATTAGTCTTCCTAAATGGAATACCAAACGGATGGGTTCCATCTCATTTGATTTCCGAACCACTGAACCCAATGGACTGATCCTTTTCACCCATGGCAAGCCTCAGGAGAGGAAAGATGCCAGGAGCCAGAAAAATACCAAGGTAGACTTCTTTGCAGTTGAGCTTCTAGATGGGAACCTCTACTTGCTGCTGGACATGGGCTCAGGGACGATTAAGGTTAAGGCCACTCAGAAGAAAGCCAATGATGGGGAGTGGTATCATGTGGATATTCAACGAGATGGAAGATCAGGTACTATATCTGTGAACAGCAGGCGCACCCCGTTCACCGCTAGTGGGGAGAGCGAGATCCTTGATCTGGAAGGTGATATGTACCTTGGGGGGCTGCCTGAGAACCGGGCAGGACTCATCCTTCCCACCGAGCTCTGGACAGCAATGCTGAACTATGGCTACGTCGGCTGTATCCGAGACTTGTTCATTGATGGCCGAAGCAAGAACATCCGCCAGCTGGCAGAGGCACAGAACGCTGCAGGAGTCAAATCCTCCTGCTCCCGCCTGAGCACCAAGCAGTGCGACAGCTACCCCTGTAAGAACAACGCCGTCTGCAAGGACGGGTGGAACCGCTTCATCTGTGACTGCACGGGCACCGGCTATTGGGGCAGGACATGTGAGCGAGAGGCTTCTATCTTGAGCTATGATGGCAGCATGTACATGAAGATCATCATGCCTATGGTCATGCATACAGAAGCAGAAGATGTGTCCTTTCGTTTCATGTCCCAGCGTGCTTATGGTCTGTTGATGGCAACCACCTCGCGAGACTCTGCTGACACCCTGCGCCTGGAGCTGGATGGAGGCCGTGTCAAACTTATGGTCAATTTAGACTGTATCAGGATAAACTGTAACGCCAGCAAGGGACCTGAAACACTTTATGCTGGGCAGAAACTCAACGACAACGAGTGGCACACTGTGCGGGTGGTACGGCGAGGAAAGAGCCTCAAGCTTATGGTGGATGATGATGTTGCTGAGGGTACGATGGTTGGTGATCACACTCGCTTGGAGTTCCACAACATCGAGACAGGGATAATGACAGAGAAACGATACATCTCTGTCATCCCCTCCAGCTTCATTGGCCACCTCCAGAGCCTCATGTTCAATGGGATGCTCTACATTGACCTCTGCAAGAATGGTGACATTGACTATTGTGAGCTGAAGGCACGCTTCGGTCTCCGCAACATCATAGCTGATCCTGTGACGTTCAAGACCAAGAGCAGCTACCTGAGCTTGGCCACTTTGCAGGCTTATACATCCATGCATCTCTTCTTTCAGTTCAAGACCACCTCAGCTGATGGTTTCATCCTCTTTAACAGTGGTGATGGCAATGACTTTATTGCAGTTGAACTAGTCAAGGGGTATATACACTATGTGTTTGACCTTGGAAATGGACCTAATGTTATCAAAGGCAACAGTGATCGTCCTCTTCATGACAACCAATGGCACAATGTTGTCATCACCAGAGACAACAGTAACACCCACAGTCTAAAAGTGGACACTAAGGTGGTCACTCAGGTTATCAATGGTGCCAAAAATCTGGATCTTAAAGGTGATCTCTACATTGCTGGTCTAGCTCAAGGCATGTATACCAACCTCCCAAAGCTAGTGGCCTCACGTGATGGATTTCAGGGCTGTTTAGCATCTGTGGACTTGAATGGGCGTCTTCCTGATCTGATCAACGACGCTCTGCACCGCAGTGGGCAGATTGAACGTGGATGTGAAGGACCAAGCACTACCTGCCAAGAAGATTCCTGTGCAAATCAGGGCATCTGTAATCAGCAATGGGAAGGCTTCACCTGTGACTGCTCCATGACTTCATATTCTGGGAGCCAGTGTAATGACCCTGGTGCCACATATATATTTGGGAAGAGTGGAGGTCTCATCCTGTACACCTGGCCAGCTAATGACAGACCGAGCACAAGGACAGACCGGCTTGCTGTGGGCTTCAGCACTACAGTGAAGGATGGCATCCTGGTTCGGATTGACAGTGCCCCTGGGCTTGGTGATTTTCTGCAGCTGCACATAGAGCAAGGCAAGATTGGTGTAGTCTTCAATATTGGCACAGTGGACATCTCTATTAAAGAGGAAAGCACACCTGTAAATGATGGCAAATACCACGTGGTACGTTTTACCAGGAATGGTGGCAATGCCACACTGCAGGTTGACAGCTGGCCAGTGAATGAACATTACCCAACAGGCAACACTGATAGTGAACGGTTCCAAATGGTTAAACAGAAAATCCCCTTCAAATATAACCGGCCCGTAGAGGAGTGGCTGCAGGAAAAAGGACGACAGCTAACGATCTTCAACACCCAGGCCCAAATTGCCATAGGAGGAAAGGACAGAGGGCGTCTCTTCCAAGGCCAACTCTCCGGTCTCTATTACAATGGCTTGAAAGTGCTGAACATGGCAGCGGAGAACAACCCCAACATTAAAATCAACGGCAGCGTCCGACTCGTTGGGGAAGTCCCTTCCATCTTGGGAACAACACCCACGACCTCTGTACCACCAGAAATGTCTACTACGGTCATGGAAACCACAACTACGATGGCCACGACTACAACCCGAAAAAATCGTTCACCACCCAGCATCCAGCCTACAACAGATGACATAGTTTCATCAGCTGAATGTTCCAGTGATGATGAAGATTTCATTGACTGTGAGCCCAGTACAGCAAACCCCACAGAGCCGGGAATCAGACGGGTTCCGGGGGCCTCAGAGGTGGTCCGCGAGTCGAGCAGCACAACGGGGATGGTCGTCGGCATTGTGGCTGCTGCCGCCCTCTGCATCCTCATCCTCCTGTATGCCATGTACAAGTACAGGAACAGGGACGAGGGGTCCTATCAGGTGGACGAGACACGGAACTACATCAGCAACTCAGCCCAGAGCAACGGCACACTCGTGAAGGAGAAGCAGCAGAGCTCAAAGAGCGGCCACAAGAAGCAGAAAAACAAGGACAAAGAGTATTATGTGTAAAAAAAAAAAAAAAAAAAAAAAAAAAAAGAATATTTATATATAAATATATAAATACTTAATGAGATTTAACTGAAATAGCAGAAACATTGCAGCGAACAAGATTGGGAGATCTATCGTTTGTGGGAAAAAGTATTGGGAAAAAAAAATTCAGCAGTGACTGTTAATGTCTCAGTCATCGCTTGGAGTCAGCAAACTGCCCTAATGTATTATAAAGCACACTTAGAGTTCTGGAGATGGCGCGCACAGCTCTGCCCTGATAGTGAACTTGGACGTCTCCAAATCTCCTCCTCCGCTGAACTTTCTGCAAAGGTAGAAGACATCATGGCTTACTTGTTTCATACCTCCAAGTGAGTCTTTAACAATGTTCGTGATCCCTGACTGTATCAATAATTTTTCGGTTTACTTATTTAAAAAAAAAAAAAAA
->LR784286.1 Phallusia mammillata mRNA for cytochrome P450 10-like (Cyp11b1-001 gene) 
-GAGCAGATGAAATACCCACCATCAAGAAAGTGGCACCACAACCATTTAATTCAATTCCCACCCCAAGCACCTCTGCTCAAGTGAAGACCCTCCTAAAACTGTTAAGAAAAGATTTTAACATGGTAGAGCACATGTCCAAAAGACACCAGGAACTTGGACCAGTATACAAGGAGAACATTTTACCTGGAATTGCCGATGTAACTGTGTCTTGTTGTTCACCTGCTGACACAGAGGCTATGTTACGCTGTGATGGTAAATATCCTGTCCGTCCCCAACTTGGGCCACTGGAAAGTATTAGAAAAGAATTAAAATTGTACAAAGGCATTTCTGAGGCCAGTGGTGAAGAGTGGTACAAAGTGAGAAGTGTAGTGAACAACCATTTTCTACGAAATCGATCAGTGTGGTCATATGGAGAAAAGCATTTAAAGGTTTCTCGGGACTTTATGGAGTACATTGCCAAAAATTTGGATTCCAATAATGAGGTGCCTGATTTTGAAAATGCCCTAAAATATTGGTCTTTGGAAGCAGCAGGTGTATTCAGCCTAGACACAAGACTTGGTTTGTTTGACGATGAAGTGAATGAGACATCACTGGAATTAATTAAGGCAATGGATTTGTTTTTTGAAAACCTTTGCAAGCTAGTGTTTGGTGTTCAATTTTGGAAAACTTTTGAAACATTTACATACAAGGATTTAAAGAATTGTCAAAAGGAAATTTACAATGCGGTTTCTCTTCATCGGCAAGCAGTACAGCACAGCAGTAATGGAAAGGAAACAAATCAGCTCCAATCCTTTCTCAACAGCAGCCTGCTCACTGACAAATATGGTGATGGTAGACTTTCTATCTGGTGGAATAGAAACCACAGCAATGAGTTCAATTTTTCCTTTGTATCTCCTTGCAATACACCCTGAAAAACAGGATATTTTACGTCAAGAAATCAAAAAATACATTGGTGATTTTAGTATTGACAGTGGAAAGGTGCTTGCTGAAATGCCATACCTAAATGCTGTACTCAGGGAAACTCAACGTATTTTTCCTTTTGCACCTTTCTACAGTCGAAAATTCAAGAATGGCATTGTTCTTTCAAACTATCAAGTTCCCCCAGACCAACTGGTTATTAGCTCAGCAAATGTTGTCAACAACAAAGACCCTGCATACTTTCACGAACCAGATTTATTTAAACCTGAACGATGGCTTGATCCTGCACAAAGAAAAAAGGCAGCATTTGCTACTGTAGGGTCGTTCGGGGCCGGTGCCAGAAAATGTCCTGGTAGGAAGTTTGCACTCCAAGAAATCCATTCTCTTATTCCACTCATATTAAGTCAGTACCGTATTGAATACCACTATAAACCAATTAGAGCCAAATTGCGACTTTTGAGCTATCCATCTGAGAAGCCAAGATTTACTTTTATACCCTTGGATGAGTAAGATCGA
->XM_047789995.1 PREDICTED: Phacochoerus africanus uncharacterized LOC125132573 (LOC125132573), transcript variant X1, mRNA 
-GGGATTGAACCCGGGCCATACCAGTGACCCAGGCCGCTGTGGTGACAGTGCCGGATCCTTAACCCACACGCCACAAGGGAACTCCCCGACTCTTCTCTACCACCTCCTTTTCTGTCTCCATTCCCATCTTCCCATCATCTCTGGGTCAGTAGCTCTCTTTCTGTCCCTGTCTCTCACTCACTGTCTCTCACCCCTTCTTTTATCTATTTCTTTCTCATTCATCAACGTTCTTTCCACACCCCTGTCCTTTTTGCTAAGTATTTCCCTGTGGGTCCCTCCTCCGCCCACCCCCATACCCAGGTGGAAGTTTTCAGCCAAATCAAAGGCAGGCAGGCCAGAAGAAGCCGAAAGGGACTCCTTCAGCACATACCGGGAGGGAGGCCGAGCGGGGGGATGTCTGGAAATCGTTACCCACCCCCTCACCACCCCCATCCGCCGCCGCCGAGGTGGGCTGAACTGGCAGAGGGAGGAGGTGGCCCAGAGCACTGGGACCCTATAGAAAAGGGGGATGTTTCTGGTGGATTCCCTGATGTTCTGGGTGACTCCGCCCTTCCTCACACTCTCTTCCTTTATTTCTGGGTCTCTGTCTCCCCTATCCTTGGGGGGGGGGGGTTCTCTGTATCTCAAACTCTCTATACTCTGAGTTTCTATTTTTCCCTGCCCTCCCCCCTTCCTGCTGTCCTCTTCCTCTAGCCACCCCCCCCCACCCCGTCTCGCTTTTTCTCTGAGTTTTTGTGCCTCTTTTGAGGTCTCTACTCATTCGTCTCTCAAAGTCCCAGTCCCTCAGTGCCTGGATCTCTTTCTCACTAGAGTGAGATCTAGCCATCCACATGCCTGCAGGCCCTGCAATTGGCTAGGCTCCGTGTGGGCGGGTTCTGTCACCCCGGGCAACGGCAACAACAAGCCGGCTTGTCCTAGGCTCTGGGGCGGGGCTGGGACCATGGCGGGTCGGACCCTAGCTCTGCGCTATGGTCCTCCGCAGTCCCCCGTCTCCGAGACCGAGGTGTCTGGATCCTGGCCCAACTGGCATCTCACCAGCAGTGGCGTCGCCCACCACTTCATCCCGCCTGTGCCCTTTCCCCCGCCCACTGTGCAGTGCACGGTCACAGAGCCCCTGCCCCCGGCCCCAAAACAGGATTTGCATATCTGGGCTTTCGACGAGGTCATCAGCAGATGGGAGACAACCTCGGGCTCAGCTTACACGCCCAAGACCCTCGGCGGGCCATACGCGCAGCCGAAGGCCCCAGAACCTGCGGACCCCACGCGGGCTGTGGGGATCAAGGATTTGGGGGAAAAACTCAGACACCAGGGCTGGCGCCTCCCTCGGATCACAAAGCACCAGTGCAGTGAGGCCAGGGCGCAGTACACCGGCTGGCCCGGCCTGGACGGGCCTACAACCTTCCATATCGGGCCCCAGCCCCCAGAGCTTGCGGACCACCACCGCGGGGGCCCTTCCCAGGCTCTCATCCCCTGGACGAAGAACCCCGAGCTGAGCGGCCGGCCTTTCGCAGCATCTGATCAGGGCATCCTGGACTGCCATCAGCTCTATATGACCACTTCCGCTCGGGACTTCCGAACCTACTCGAAGAAGGAGTTGTCAGGATACCCTCGCAAGGACTCGCTGACCTACTGGAGCTTCAAGGAGACGCCCCAGGCCTGGGGCCACGGCCCAAAGCAGCCGTCCTATCCGTATTCCTCTTGGCCACCCGGGCCGCCGAAAACCCGCGTGCCCCGCGCCCGCCCAGTGATGCCCGCCGTGCCGCACCGCGGGGCGCAGTCTCTGGCTCAGGAATCCTACGGCCCCCCGCTGCACCCACTCCGCCGGCTCGACCGTTTCTGCCCGCTGAAGCTCCCTTGGGGAGGCCCCCACTGCAAGCCCGTGTCAGGCATTTACACCGTGCCGCAAGCCTACGGCACCGAGAACTCCAACTACGGCAGCTTGAAGCCGGCGCTCGTCTGAGCGGGCGGGGCCGGC
->XM_035987257.1 PREDICTED: Helianthus annuus cysteine protease RD19A-like (LOC110876098), mRNA 
-TTTCTCACCACGTTAATGGCAGTTTGCAGATTACGAGTCTCTCATACGCTCCGACTTTCCTCTCACACAATCGTTGCAGCGGTTGTGTCTTTCTCTCTCATACGCTCCCCTAACTTCTCCCACTATAAAACTATCACCAATAACATCCTCTCCATTATACACCTTCATCTTCTCGAATTTTCTCTGATCTTCTCTCCCCTAATAAACCCAAATCAATAAACGGGTTTGTGTTTTCATGGTTCGCATTGCTGAAATTGGGATTCTAGGATTGAGATCTCGTCTCCGGTTTCCGGACGATGCTAGAAAAGCTCCGATTCTTCCAACGACTGATCTGCCGGAGGATTTTGATTGGAGAGATCATGGTGCAGTTACTGATGTCAAGGATCAGGGTTCGTATGGGTCGTGTTGGTCATTTAGTACGACTGCGGCGTTAGAAGGTGCAAATTTCATTGCTACAGGGAAGCTTCAAAGCCTTAGTGAACAACAACTTGATGATTGTGTCCATGAGGATTTCGGTGAAGGGTATAGGGGGAAACAGGTGGTGTTGGAGAATTTGAGGCAGCTTTGTGTTCACAGATTTGCTAATGAGACCAACAGGTGGTGTTAAAACACTACTACCCCAACTTGGGGATCGGAGTTGTTGTTACCTTTGTGGGATTTGTTTTTAAAGGGCATGATGGTCTTTTCAGCATTTATGTTCATAGTTCCGGTTTGTCTTCCAATTGGACAGAGCCAGAAGAGTCGGTTTTTTTTATGGCCGGAGAATTCCCAGCAAGGATGTCGAATGGGGGAAAGTAACCATGGTTGAAGCGGAGCGTCGGCTACTAGCTAACGCGCTACTCGATTTTTGAAACCAACGATTCGTTCTCCTCTCGGAGTCATGCATTCCGCTATTTAATTTCTCGACGATATACTCTTATTTAATCAACTCTAAACATAGTTATTTCGAGTCCTATGATTTGGCAGGACCAGTTGGCCGAGGGCGGTACAACTGGAAAATGCACCCGACGGTTAAATTTCATGAATGGCGAAAAGGGTCACAATGGTTTGAAATGAGCCGTGAGCTAGCAATTGAGGTGATATCTGACAAGACTTATTTTCCGGTCTTTATAGACTATTACAATGGTTCATGTTATGCAGACGAGCACTACTTGCCTACGTTTGGTACACTTAAATATGGGGAAATGAATTCAAACCAGACTTTGACTGACGATGTTCTCCTACAAACATGCAAAGTTCAACTTGGTGATTCATAAATAACCCCCCCCCCCCCCCCCGCCCAATAAATATAATCTACGTTTGGTTGTCATTGATAGTTTTTTTTAAATACTTTTGTAAACATGTAACATTGATAGATCTCATTTATCTTCATTTAATGGTTTTAGCAATT
->XM_040865634.1 Pseudomassariella vexata uncharacterized protein (BCR38DRAFT_77744), mRNA 
-CTGGGGCCCTTGGCAAGGGCTGGAGTGCCACTCGGAGATTTCCATGAGGCTGGGAGAGACCCTGAAAAACGCGAACGCGCTCGAGAACCTGGCCAATCATGGCAGACTGTCCCACCAAAAAAGCTATTCCCTTTTCGATTTGCCATCTGAATCGCACTTTTACATGCTCAACTATCTCCCACATCACGCCCCGGTGAGCTGAACAGCATGGCAACCCAAGACGCTGCGGGTATTCCTCTCACGCATGCCGCGGATGGAGTGGGCTACAAGCTGTTGGAGCTACCCTCGGAACTGCTGGCTCTTCTCGAATCCGAAAACCCCCCTGTGTTGACCTTAGAGTCGTCCACAACCTCAGCTGTCCTCAAACACGGTAGCCAGACTTGGTCTCTTCGGCAGAAGAACACATCCAATGCCCTCATGCTCCTGTCCCCTTGTGAGACTGCGGCGTCGTCTTCAGATATTCCTCAAGCCGGACTCAAGATTATATCCACAGTCCATGACATGGTGGAGCTTACCACCGAAGGCGCGTCCGGCGCTGCTCCTGTTGCCAGGGGAAAGTGGCATGAGATGTTTGCTCGAGGCAGGTGACAGACAAGAGAGAATATGGGCAAGTCAAGTACCGGTTTTTTCTTCAAATGGTAATTTGAATAAGTCTTGGTGCTGGTGTGCTTAATGGCAATGATCTTTTGCTGCTCAAGATTGTTCATGGATGAGCATGGATGG
->XM_013015936.1 PREDICTED: Dipodomys ordii single-stranded DNA binding protein 2 (Ssbp2), transcript variant X1, mRNA 
-TGTTCCCGGGGAGGCTGTGATGGGTTGACAGGTGCGTGACAGTGGGAGCTGCTCTCGGCACAAGCATGTACGGCAAAGGCAAGAGTAACAGCAGCGCCGTCCCGTCCGACAGCCAGGCCCGGGAGAAGTTAGCACTCTATGTATATGAATATCTGCTCCATGTAGGAGCTCAGAAATCGGCCCAAACATTTTTGTCAGAGATAAGATGGGAAAAAAACATCACATTGGGGGAACCACCGGGATTCTTACATTCTTGGTGGTGTGTATTTTGGGATCTCTACTGTGCAGCTCCAGAGAGACGGGAAACATGTGAACACTCAAGCGAAGCAAAAGCCTTCCATGATTATAGTGCTGCAGCAGCTCCCAGTCCAGTGCTAGGAAACATTCCCCCAGGAGATGGCATGCCAGTAGGTCCTGTACCACCAGGGTTCTTTCAGCCTTTTATGTCACCTCGTTACCCTGGAGGTCCACGGCCCCCACTGAGGATACCTAATCAGGCACTTGGAGGTGTCCCAGGAAGTCAGCCATTACTCCCCAGTGGAATGGACCCAACACGACAACAAGGACATCCAAATATGGGTGGCCCAATGCAGAGAATGACTCCTCCAAGAGGAATGGTGCCCTTAGGACCACAGAACTATGGAGGTGCAATGAGACCCCCACTGAATGCTTTAGGTGGCCCTGGAATGCCTGGAATGAACATGGGTCCAGGTGGCGGTAGACCCTGGCCAAACCCAACAAATGCCAATTCAATACCATACTCTTCAGCATCTCCTGGGAATTATGTAGGTCCTCCAGGAGGTGGAGGGCCACCAGGAACACCTATCATGCCTAGTCCAGCAGATTCAACCAACTCTGGAGACAACATGTATACTTTAATGAATGCAGTACCTCCTGGACCGAACAGACCTAATTTTCCAATGGGTCCTGGGTCAGATGGCCCCATGGGTGGCTTAGGAGGAATGGAGTCACATCACATGAATGGCTCTTTAGGCTCAGGAGATATGGACAGTATTTCCAAGAATTCTCCCAATAATATGAGCCTGAGTAATCAACCTGGCACTCCAAGGGATGATGGCGAAATGGGGGGAAATTTCTTAAATCCTTTTCAGAGTGAGAGTTACTCCCCTAGCATGACAATGAGTGTGTGATCCTTTACGCGTCTCCTCATGAAAACCACAGTGAGTCAGCCCTTCACAGAACTACTACGGAAGAAAATTATTCATCACAGTGTACAGTAAAGGAATCTCAGTCACACCAAACCAACCTTTTTATTTCCTGCTCTCTCCCCTATTTTGTGAAGAAAGCGGGTCCAAACGTGATTCAAACAACTGTACGGAGTGGCACATTAGAATTGCCCTAATCTGAACTGCAAATAATTATCTGTGTATGTATATGTGTGGGAAGGAGATTGTATCGTATATGTGGATGTTATATGGACATATACGCATACATGCATTGACCCACAGGACATTGTAAAATATTATCACATGACATCTTAAGTAGAAATAGGTAGGGACTTTTATTCCATCCTTTTTTTCACGTTTACATTTTAATTATTAAAAGTTGCTCCTGTCCCCTCCCTGAACTATTTTGTGCTGTGTATATCACTGCTTTATATAAGTTATTTTTTAAGGTGAACTCAGATGTTATGGTTTTGTAAATGTCTGCAATCATGGATAGGAATAAAATCGCTTATTTGAGAGCTTTCATTAAATTGTGTCTGATGCAAGTTATCCTGTGAATCCTAAAGTGTACTGTCTCAAGTAATGGAAGAAAGTATGCCTTTATCCTTATGTCAAATCAAACAATTTCTTGGTTACCTTGAGTGAAAAGTATTTTTGTATTTTTTTTTGTTTGAGAAAAACACTTCAGATCAACAAAAGCTTAACTGGGGCTTCAACAGTATATTTCTGCAATAACTACTTTAAATGGAATTCTTGATTTGTTTGTCTTAGATGATACAAAAATCATTAATTAGCTCAAATTACCTAGATCACAGCAATAAAGTGACAGGGGTTGTCAT
->XR_006051903.1 PREDICTED: Salvia splendens uncharacterized LOC121807657 (LOC121807657), transcript variant X48, ncRNA 
-AATTAAAATTGCCTAGAAACCCTAAATTAAATTAAAAATATCCCTCTCCATCTCCCTTCCCAACGGCATCTCCATCTCCATATCTCAATTGGCAGAAATGACTCGTGTTTTCCCCACACCAAGAGTCATAGCCCTCGCAGATTTCACGCCGCCGGCCTGCTTGCCCGGAGAAGAAAGCCGAGGACTTGGCTGTCTCGGAGTTTGGTCCCCGCCGCGGCTGCTACTCGCCATCATCAGACGCCGTCGTCTCCTGCAGCAGGTCGCTGGTCCGGATTCGTGGGCAGCGTCACGTGGCTGCTGACTCGCGGCCTTGCCGCCGCTGCCAACTGCGCGAACCCATCGCCGTCCGCCCTCCCATCGTTTGATCCAGCTGAGCAAAGTGGTGACTTATCAAGATCCATGGGCATCCCAACTTTCAATCGAACTATGGCCTTCCTGAAATCCACACATATAGACTACAATGCCACGGGCTTATACTGGTGTTGGGAAATGAAGCTTTGGAAATCATAGAATATGCTTTTTCAAAAGATAGGTTGTGAAGACTTTTGACTTCAGCCTCACTGGTGCCTCTTCAAGATCTTGTAAATATGTCATGGATACTATGATGCAGACTTTTAAGAACAAGAGGCTTGCTTATGCAGTTAAAGAGAGTACTCTTGATAGTCTCATCATGGAACTATTGCTCCGGCTTTTGGATGATAGTAATCCCCAATGGATGATGGAAGTCAACTTTTAAGAGCTTTGAATGTTCTGATGTTAAAGATTCTGGATAACGTAGAATGTATTTCATCATTTCCTGTGCTTATATATCTGTCAAGACCTGGATCCATCAAGATGGCCATCTCCATCAAATGATCTCTTGAAATCAGGAACCAGAAGTTCTCTGATTTGGTTGTTAAATGTTTGATCATGCTCACAAAGGTTAAGGAGCCAAAACCAGAAGCTGTTCCTTAGGCTGTGGGTTCAGTACCCACTTAAGAGTGTAGCTGATGCACCTCAGGACCTTATCGATCCAGTTGATATATTAAAGCCTTTGGAGAAGTCTGGATTTTAGGAAGCGGTTAAAGCTTCAAAATGGTGGGAGAGGAAAGAGGCTGTTGCTGAACTAGCCGAACTTGCTTCAACCAAAAAGATTTCTCTTGGAGATTTTTCAGAAAGTTTGTCATACATTAAAGAAGGTTATCACGAATGTAAAGGTTACTGAAGGAAGGAAAAAAAGGAAAAAAAAAAGAAAACACATTGTTGTTGCAGCTGAAGCTATTCAAGCTCTGGGCAACCTTGGCATGAGAACCCTTCCTAAAAAAAGAAAAAAAAAAGAAAAAAAAGGAAAAAAAATGAAAAAAATAATTGCTGATGTATTTAAAGCTATTCAAGCACTGGGCAACTGTGCTAGAGATCCGAGAGCCCATTTTTCGGCCAATTGTTGCTTCTTATTTGCCTGTAAACCGCACCTCAGGACCTTATCGATCCAGTTGATATATTAAAGCCTCCTTTTTATAAGTTTGGATTTTGGGAAGCGGTGAAAGCTTCAAAATGGCATGAGAGGAAAGAAGCTGTTGCTGAACTAACCGAACTTGCTTCCACCAAAAAGATTTCTCTTGGAGATTTTTTCAGAAAGTTTGTAATACATTAAAGAAGGTTATCACGAATGTAAAGGTTACTGAAGGAAGGAAAAAAAGGAAAAAAAAAAGAAAAAAACATTGTTGTTGCAGCTGAAGCTATTCCAGCGCTCGGCAACCTTCCTAAGGGCATGAGAACCCTTCCTAAAAAAAGAAAAAAAAAGAAAAAAAGGAAAGTAAATGAAAAAAAGCAAAAAAAGGAAAAAAAGGAAAAAATAATTGCTGATGCATTTAAAGCTATTCAAGCACTGGGCAACTTTGCTGGGGATCCGAGAGCCCATTTTTCGGCCAGTTGTCGCTTCTTATTTGCCTGTAAACCGCACCTCAGGACCTTGTCGATCCAGTTGATATATTAAAGCCTCCTTAGGAGAAGTCTGGATTTTGGGAAGCGGTGATAGCTTCAAAATTGCGTGAGAGGAAAGAAGCTGTTGCTGAACTAACCGAACTTGCTTCCACCAAAAAGATTTCTCTTGGAGATTTTTTCAGAAAGTTTGTCATACATTAAAGAAGGTTATCAGGAATGTAAATGTTACTGAAGGAAGGAAAAAAAGGAAAAAACATTGTTGTCGCAGCTGAAGCTATTCAAGCGCTGGGCAACCTTCCTAAGGGACTGAGAACCCTTCTAAAAAAAAGAGAAAAAAGGAAAAAAAGGAAAAAAAGAAAAAAAGTAAAAAAAGGGAAAAAGAGAAAAAAAATAATTGCTACTGCGTATAAAGCTATTCAAGCATTGGGCAACGTTGCTAGACTTTTCAGAACAAGAGCCTTGCTTATGCAGTTAAGGAGTGTACTCTGATAGTCTCATCAATGAACTGTTTCTCTGGCTTTTGCATGATAGGCTTCCGGAGATGGATGATAGACGTCAAATTTTAACTGCTTTGAATGTTCTGATGTTAAAGATTCTGGATAACGCATAATATACGTCATCATTTCCTGTGCCTATAAATCTGTTAAGTCCTCTGGATCAATCAAGATGTCCATCTTCAGATCAGAAACTTAAAACCTAAAGTTCTCTGATTTGGTTTTTAACTGTTTGATCATGCTCTAAAGGAATCTGCAACTCCAAAGAAGGTTGTTAAAGTAACTTAACTGGTGGCATAGATGGACTTCCACGTGAAGATATAAGTGAAAAGGTCACCCCCACTTTGTTAAAAGGCTTATAGAGTTCTGATTGGAAGGTCCACTTGGAATCTATTGAAAATGTAACCAAAATTCTGGAAGAGGAGAACTGGAATTGGAAATCTATTTGGAGCTCTATAAGGGCGTCTACACGACAGTTCTAAAATTTGATAATTGCTACTTTGTCCACAGTTGGTGCTCTTCGGACTACAATGGGACATCCGGTTGAGAAGTCAAGCTAGCTCCTGTGAAGGCTTGATCATTTACACGAATGTAGCTCGTGCAAGGGATTCTTTCAGATTTTTCTGATGTCTTGAAATGCCTTGGTGACAACAAAAAGCATATGCATGAGTGTACATCTAGTACCTTAGATACTTGGCTTGAGTGTATATCTGGCCAATGTTGTCAAGTCACCACGTAGCCAAAGGTCGAGGTTCTAGGTTTTGTGGGAACCCAATTTATGTGCATCACTGATTCTGACCAACCATCTTAAGCTTTAATGAATTGAAGCTGCCTTTGTAAATGCTCCTCAGGACCTTATCGATCCAGTTTATATATTAAAGCCTTTGGAGAAGGCTGGATATTGGGAAGCGGTGAAAGCTTCAAAATGGTGGGAGAGGAAAGAGGCTGAACTAGCCGAACTTGCTTCAACCAAAAAGATTTCTCTTGGAGATTTTTTCAGAAAGTTTGTCATACATTAAAGAAGGTAATCACGAATGTAAATGTTACAGATGGAAAAAAAAGAAAAAAAACATTGTTGTTGCAGCTGAAGCTATTCAAGCGCTGGGCAACCTTGGCATGAGAACCCTTCCTTAAAAAAGAAAAAAAAAAGAAAAAAATGAAAAAAATAATTGCTGACGTATTTAAACCTATTCAAGCACTGGGCAACTGTGCTAGGGATCCGAGAGCCCATTTTTCGGCCAGTTGCTGCTTCTTATTTGCCTGTAAACCGCACCTCAAGACCTTATCGATCCAGTTGATATATTAAAGCCTCCTTAGGATAAGTCTGTATTTTGGGAAGCGGTGAAAGCTTCAAAATGGCATGAGAGGAAAGAAGCTGTTGCTGAACTAACCGAACTTGCTTCCACCAAAAAGATTTCTCTTGGAGATTTTTTCAGAAAGTTTGTCATACATTAAAGAAGGTTATCACGAATGTAAAGGTTGCTGAAGGAAGGAAAAAAAGGAAAAAAAAAGAAAAATACATTGTTGTTGCAGCTGTAGCTATTCAAGCGCAGGGCAACCTTCCTAAGGGTTGAGAACCCTTCCTAAAAAAAGAAAAAAAAAAGAAAAAAGGAAAGAAAATGAAAAAAACAAAAAAGGAAAAAAAGGAAAAAATAATTGCTGATGCATTTAAAGCTATTCAAGCACTGGGCAACTTTGCTGGGGATCCGAGAGCCCATTTTTCGGCCAGTTGTCGCTTCTTATTTGCCTGTAAACCGATGTCTTCCCTATCAGCACCTCAGGACCTTGTCGATCCAGTTGATATATTAAAGCCTCCTTAGGAGAAGTCTGGATTTTGGTAAGCGGTGATAGCTTCAAAATGGCGTGAGAGAAAAGAAGCTGTTGCTGAACTAACCGAACTTGCTTCCACCAAAAAGATTTCTCTTGGAGATTTTTTCAGAAAGTTTGTCATACATTAAAGAAGGTTATCACCAATGTAAAGGTTACTGAAGGAAGGAAAAAAAGGAAAAAAAAAAGAAAAATACATTGTTGTTGCAGCTGAAGCTATTCAAGCGCAGGGCAACCTTCCTAAGGGTTGAGAACCCTTCCTAAAAAAAGAAAAAAAAAAAAAAAAAGGAAAGAAAATGAAAAAAACAAAAAAGGAAAAAAAGGAAAAAATAATTGCTGATGCATTTAAAGCTATTCAAGCACTGGGCAACTTTGCTGGGGATCCGAGAGCCCATTTTTCGGCCAGTTGTCGCTTCTTATTTGCCTGTAAACCGATGTCTTCCCTATCAGCACCTCAGGACCTTGTCGATCCAGTTGATATATTAAAGCCTCCTTGGGAGAAGTCTGGATTTTGGGAAGCGGTGATAGCTTCAAAATGGCGTGAGAGAAAAGAAGCTGTTGCTGAACTAACCGAACTTGCTTCCACCAAAAAGATTTCTCTTGGAGATTTTTTCAGAAAGTTTGTCATACATTAAAGAAGGTTATCAGGAATGTAAATGTTACTGAAAGAAGGAAAAAAAAGGAAAAAAAACATTGTTGTCGCAGCTGAAGCTATTCAAGCGCTGGGAAACCTTCCTAAGGGCCTGAGAAACCTTCTAAAAAAAGAGAAAAAAGGAATAAAAGGATAAAAAGAAAAAAAGTAAAAAAAGGGAAAAAGAGAAAAAAAATAATTGCTACAGCGTATAAAGCTATTCAAGCATTGGGCAACGTTGCTAGACTTTTCAGAACAAGAGCCTTGCTTATGCAGTTAAGGAGTGTACTCTGATAGTCTCATCAATGAACTATTTCTCTGGCTTTTGGATGATAGGCTTCCGGAGATGGATGATGGACGTCAAATTTTAACTGCTTTGAATGTTCTGATGTTAAAGATTCTGGATAACGCATAATATACGTCATCATTTCCTGTGTCTATAAATATGTTAAGACCTCTGGATCCATCAAGATGTCCATCTTCAGATCAGAAACCTAAAACCTAAAGTTCTCTGATTTGGTTTTTAACTGTTTGATCATGCTCTAAAGGAATCTGCAACTCCAAAGAAGGTTGTTAAAGTAACTTAACTGGTGGCATAGATGGACTTCCACGTGAAGATATAAGTGAAAAGGTCACCCCCACTTTGTTAAAAGGCTTATAGAGTTCTGATTGGAAGGTCCACTTGGAATCTATTGAAAATGTAACCAAAATTCTGGAAGAGGAGAACTGGAATTGGAAATCTATTTGGAGCTCTATAAGGGCGTCTACACGACAGTTCTAAAATTTGATAATTGCTACTTTGTCCACAGTTGGTGCTCTTCGGACTACAATGGGACATCCGGTTGAGAAGTCAAGCTAGGGGATTTTTTCAGATTTTTCAAATGTCTTGAAAAGCCTTGGTGACAACAAAAAGCATATGCATGAGTGTACATTGAGTACCTTAGATAATTGGCTTGAGTGTACATCTGGCCAATG
->XM_013088457.2 PREDICTED: Aplysia californica ubiquitin carboxyl-terminal hydrolase 5 (LOC101848919), mRNA 
-GAAGTAATTCTGTTGTACCGCTTCTCTCAGTTTCAACATGGAGTCCGGTCTGTCCGAACTAGCTAAGCGATTGCCCGGTATCAAAGCCCCTATAGGGGGTGAGAAAGTCTACAAGGATGAGTGTGCATACTCATTTGACAATCCGGAGAGCCCTGATGGTTTGTATGTTTGCATGAATTCCTTTCTTGGAATTGGAAAACGTCACCTACAGCAATACTATGAGAAAACTGGGAATGGGGTATTCTTGCACATCAGACGTTTAAGAAAAGAGGTGCCCAAAGATGAGACGGCTGAGGAGGAAAAGCCAACCAAGATGGCCATCGGAGTGGAAGGTGGCTTCCAAACAGATGAGAAAAGATTTGAGTTTGAGGAGAAAACGTCCATCACCATCTTGCCCCAGTGGCACGAGATCGCCTTCCCCAACCCACAGATCCCTGATCAGGCCCAGCTGTCAGCCACCATGATTATGATGGCAGAGGATGCAGCCAAACAGGAGGAGGCCGCGGCCATGGCGGGAACGTGGGAGGGGGAAAAACTGAGGGTGTCGAAACACGCGGAGAACCTGCTTCAGCTGCCAGTGGAGAAGAAGATCCCCCCGTCGGGCTGGAAGTGTGAAAAGTGTGATCTGACCTGTAACCTCTGGCTCAACCTGACGGACGGCTCCATCCTATGTGGCCGGAAGTTCTTCGATGGTTCGGGGGGCAACAACCACGCGCTGGAACATTACCGGGAGGTGGGCTACCCTCTGGCCGTCAAACTGGGCACCATCACGGGCACAACTGCAGATGTGTTCTCCTATGAAGAGGACGATATGGTGGAGGACCCATACCTGGCCAAACACTTGGCGCACTTCGGTATCAACATGGCCGCGCTGGAGAAGACAGACAAGACCATGACGGAACTGGAGATTGACATCAACCAGAAGATCGGGGAGTGGGATGTGATTCAGGAGGCCGGCAGCGTGCTCACCCCAGTCTACGGGCCTGGCTACACGGGCATGCGTAACCTAGGCAACAGCTGTTACATGAACTCGGTCATGCAGGTCCTCTTTACGCTGCCAGACTTTCAGAAACGGTACTTCAGTAACTGTGGACAGATTGTGTCCAACGCCCCCCAGAATCCTGTCTCTGACTTCAACACACAGATGACCAAGCTGGCAGATGGTCTCCTCTCTGGTGTATATTCCCAATCAGTAGATACCAAAGAGGCTTCAGAAGGGGATGCCAAGTACATTCCACCCCCCAGCGGAATCCGCCCTCAGATGTTCAAGACGTTGGTGGGCAAAGGTCACCCGGAGTTCTCCACCAAGAGACAGCAAGACGCGCAAGAGTACTTCCTACACATGGTCTCCGTTATACAGAAAAACAGCCGGGGCGGCGCGAATCCTTGTGAGTCGTTCCGGTTTGAGGTGGAAGAACGCGTTGCTTGTTCCTCCTCCCAGAGGGTTCGCTACACTCGCAGAGAGGACTTCTGTCTATCCCTGCCCGTGCCCATGGAGGCTGTGTCCAATAAAGAGGAAGTAAGGAAATACAACGAGTCCAAAGCTGCTGGGGCAACCATTGTTGACCCAAAGAGCATTGTGCGTCCAGTGATCGCGTTCTCCGAGTGTGTTCGAGCGTTCACAGAGGCAGAGACGGTGGAAGATTTCTACAGTTCTGCCATACAGGGCAAGACCACAGCTCTCAAAACGACGCGTCTTTCATCGTTTCCTGATTACCTGATGGTGCAGTTGAGGAAGTACACCGTCGGCGATGATTGGGTGCCGCGGAAACTGGATGTGTCGATCCAGGCTCCAGATGTACTTGACCTTTCCTCCCTGAGAGGTCGCGGTCTGCAGGCTGGGGAGGAAGAGCTGCCCCCAGGGGATTCCCCGCCAGAAGCCCCGGTGGAGATCCAGGAAGGCACGGTGACCCAGCTGGTGGACATGGGGTTCCCACGCGAGGCGTGTCGCAAAGCCGTGTACTTCACCAACAACACAGGCGTGGAGGCAGCCATGAACTGGGTCATGGAACATATGGACGACCCAGATTTTGCTGCTCCCTTTAACCCTGCCCCTGCGGGCGGAGGTGTGAAGGGAGGCGCGTTCGAGCCCAATCCAGAGGGACTGGCCATCCTCGTGTCCATGGGCTTCTCCTCAGAGCAGGCAACAGTGGCCCTCAAAGCAACCAGCAACAATGCGGAGCGAGCCGTAGACTGGATCTTCAGCCACCCGGACGAGCTGAGTCAGCCCATGGAGACGGAGGAGGCCAGCGCCCCGGTCACTGCCGCTAACTTTAAAGATGGGTCAGAGAAGTACCGACTGGTGGCCTTCATCAGCCACATGGGCACGTGCACCAGCGTGGGTCACTACGTGTGTCACATCCTGAAGGAAGGTCGCTGGGTCATCTACAACGACGAGAAGGTGGCACTGTCGGAGCAGCCGCCCAAGGACCTGGCCTATCTCTACCTGTACCAGCGCATGTAGGACATTGAGGGGGGGAGGTGAGAGTGTGTGAGGGAGGAGGACATTGAGGGGGAGAGGTGAGAGTGTGAGGGAG
->EF220307.1 Uncultured alpha proteobacterium clone FB-2_C04 16S ribosomal RNA gene, partial sequence 
-AGGGTACGGGAGAGGTGAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGTTACCGACGCTCAGGCGCGACAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGGATGCTAGCCGCTGGTAAGCATGCTTATCAGTGGCGCAGCTAACGCATTAAGCGTCCCGCCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGACGCAACGCGCAGAACCTTACCAGGGTTTGACATCCCGCGCTAAACTCAGAGATGGGTGGTCCCCGCAAGGGGCGCGGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCTCCTTTAGTTGCCATCATTTAGTTGGGCACTCTAAAGGGACCGCCGGCGACAAGCCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTACACCCTGGGCTACACACGTGCTACAATGGCGGTGACAGTGGGCAGCGACCACGCGAGTGGATGCGAATCCCAAAAAACCGTCCCAGTTCAGATTGCACTCTGCAACTCGAGTGCATGAAGGTGGAATCGCTAGTAATCGCAGAACAGCAGGCTGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTTGGTTCTACCTGAAGACGGTGCGCTAACCGCAAGGAGGCAGCCGGCCACGGTAGGGTCAGCGACTGGGGTGAAGTCGTAACAAGGTACCAATCCCGCGG
->KU308505.1 Uncultured Alphaproteobacteria bacterium clone 0107 16S ribosomal RNA gene, partial sequence 
-AATGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGAGATCTTCGGATCTAGTGGCGCACGGGTGAGTAACGCGTGGGAACCTACCTTTTAGTACGGGACAACGTTTGGAAACGAACGCTAATACCGTATACGCCCTCCGGGGAAAGGCTTGCCGCTAAAAGAGGGGCCCGCGTCTGATTAGCTTGTTGGTAAGGTAATGGCTTACCAAGG
->FQ227369.1 Rattus norvegicus TL0AEA13YJ12 mRNA sequence 
-CAAAATAGTTAAGATGTAGATCTCCTCTTTTACTGAAGTAATTTATAATTTCTGGCTTTTGGACTGACTGTCAGCCATCAAAGGTTTGAAATTAGACTTAGTTAAATGGTTCTTACCGTTGGAGCTCCCTGGCCTCCTAACCCAATTAATGAGCTCCGTGTTCACATAGATGATAGAGGACCAGTTGCTGAGGACACTGCTGTAGCGCATGCAGCAGCACCACATTAAGAGTCACATGGAGACAACATCACTAAATAGATACGAATCTTACGTAGAAATAAAGGGCAAGTGAGTCGAGCCCAGTGTCTGTTTTAACAGAAATGATCTGCTCTGCAGTAGTGGTATAGGTCTTTAATCTTAGCACTTGAGAGGCGGATTCAGGTGGACAGCCATGGCTACACAGAGAAACCCTGTCTCAGGAATGGAAAAAGTCAAACATCAAGGATGTTTCATGTGATTTTGGTATGTATTCAATTTTGGAACTCTCTTCTGGTGGTGTAACATACAGAGTTGACTTGGTTTTTTATTTTTGTTTTCTTGAAGAAAACAGGGTTTATCTGTGTAGCTCTGGCTGGCTTCTATCTATTGGATTAAAGGTGTTTCCACCTCTGTTCGACATCAGTTTGGTTTTAGGATGAGGCATATTAACATAATGTTTCACTGGGCTTTTTCGTTCCAATGGGAAATTAATAAAAACCTGTGGATAAGGGTTGGGGATTTAGCTCAGTGGTAGAGCGCTTGCCTAGGAAGTGCAAGGCCCTGGGTTCGGTCCCCAGCTTTGAAAAAAAAAAAAAAAACCTGTGGATAAGCAGCACAAGTCAGATTTGAGTAGTTTAAATATGACAAAAAGGACGCAAGACGGGTTGGACATAGTTAGGAATGAGAGATGGATATTTTAAAATGTTAGGAAATTCTCAAGGAATAAAATTACTTTAAAATTACTGATAACAATCAGACATTCTTTAGTATGATTCTCCTTTGATACTGTAAGCAAGCACAGAAGTTTAAGAAATAACATAAGGGGCTGGAGAGATGGCTCAGCAGTTAAGAGCACCCGACTGCTCTTCCAGAGGTCCTGAGTTCAAGTCCCAGCAACCGCATGGTGGCTCAACAACCATCTGTAAAGAGATCCAATGTCCTCTTCTGGTGTATCTGAAGATAGCTACAGTGTACTTATATATAATAAATGAATAAATCTTTTAAAAAAAAAAAAAAAAAAA
->JX483172.1 Uncultured prokaryote clone Cluster11712 16S ribosomal RNA gene, partial sequence 
-CGTCAAATCATCATGCCCTTTATGACCTGGGCTACACACGTAATACAATGGCGCTTAACAACGGGAGGCAAAATCGCGAGATGGAGCAAAACCCCAAAAAGCGTCTCAGTTCGGATCGCAGGCTGCAACCCGCCTGCGTGAAGTCGGAATTGCTAGTAATCGCGGATCAGCACGCCGCGGTGAATACGTTCCCGGGCCTT
->XM_030995465.1 PREDICTED: Strongylocentrotus purpuratus uncharacterized LOC105441690 (LOC105441690), transcript variant X2, mRNA 
-ATAGCAATGGCTGTCGACGGCCTGGCGATTCAAACTATTTGGATGAACGTAGCTGCATTTTGTTCCCTGAGTGATCTTGGAAGATTACAGTCAACATGCAAATATCTCAACGCGATTCTTTCATGCAATTCAGTTTGCTGTGGCGCAGGGCCGAGTCCTCGCGGCACATCCGTTTGCGCTCGGCGTTGTCTACAGTAGTTCCTCTTCGCAGACTGAAGGCGTGTGATGCAAGGTTCCTGGATGCTGCAACAGATCACATGCTGCTTGGTGGCATAGCTCAGAAAGATAACAGTTTTGCTGAACTCTGGCCTTTCCTGGAGTCTGAGAAGAAGGCCTTCTACAACCATCGAATCGCGATGCTACTGAGGAAGGGGCGGAAGGGGAGAGAGAAATGCTTCTCACAGGTCTCAGGGTTGGAGTGTGGCATGCCGCTGCAGTTCTGCTCTCTGAACCTGCTGGGAAGCGGATGGAAAGTGCGGAAGAGGGTTCTGCAAGCCCTTGAGGACACCACCAATGCTGCCATCAAGATCGGTGGAATCAAGAACTCTGAGCTGAGGTGTAGCCTGCAGGAGTTATTCCGTCCAGGATTGATCAGAGACTTCTCTCAAGAAGCGGAGCCGATCTGTCTCCGAACCCCCATCAATATGATTCCAAAAGACCTGGAAATAGTCAAGGACCTCTTCTTTCGTGTCCTGGGATACACTTGCATCTTACCGTTCAACGTAGCATCCCATGTCAGCGACAACGCCAGAGCAGAGACATGCCTCATTATAGAGAGCTACGTCCATCACACTGTCATCACACCCATCATCGATGGCATTCTGTGCTCAGACCTGGTGAGATGCAAACCCATCGGCTTTGCTCATGTCCTGGATTATCTGGTTCTAAGTTTGGTAGTGAAGAACCCAAACCTCAGTAAGATCAGAGCGCCATCCCTCATGCTGAACACGAATCCTGAACGCATGACCCTTGCCCTTTCACCTGCTCGTGACCTAATGGCTGCCGTCCGTCCAGAAAACCCTTCAGAGTATGCCTACAATTCACAGCTTGGTGTTTTGCAGTCAGGTACTGCACTTCAGCTCAAAGAGAGCATCCTATGCGTCTTCCAAGGAATCGACTCGTGTAAGCGCTCAGAGTTCCTAGTCCTTCTGGCAACCGAGTACATGTACAAGTGCCTTGACCTTGTCTCCATGGTAACCGAACTCCTCGGCCAGTTTGACCTTCTCAACGTGCGGCGATTGGTGAGTCGCATCTTCTTCGTCGGGGAGAACACGCGGATCGGTAGCTTCCGGGAGAGGTTCGAGAGGGACCTGCGGGTGAGTCTCAACCGGTTGGGGGCGGTGTTCGGAGGAGAGTTTGCCAGGCAGCAGCGATGGCCGATACACTGCGTACACGCAGAGGTGGAGGACAGACCAAACTGTCTGTTTTCTGATACCTTCACCACCATGGACTATATCCTTCAAGGCCCTGATTTCTTCTGAATCTCCCTTTATTTCTTTTTTAATTATTTATTTGGTACTTTCAAGAAATATAACAATAAAACAATATAATCATGGTGTTTACAAAATTAGAATGACAACAATTATACAAATACAACTGTTTGTAGCAATATTCTAAGTGCAAAAGATGGCAGCCAGGGAAAAACAGAGCAAACTTAATTACTGTAACCGTAATGGTCTCTTTGCCAAACCAACTGATGCACTCAGATGGTGCCTCCTCCCCAATGAACACCCTATACAAAGGGTAGTTAATATGAGGATATGCAATTGACAACCATGAACAATACTTTCCAAATCACAATTTCTGCAGGATCTTCCTTTCAATGCACCCATTTGAGGCTTGCCTCTAAGGAACATGCATGTCTACATCCTATATAAAGAAAAGTCAGCAGAATCTGCAGTTTTACAAAATAGCACATATCTTTCAGGACCCTAATTTCTTTTAGGTCTCAAGGAACATGGATGTTTTGTCCTATCCAGCTGATAGAAGGGCTAATGTGCAATTTACCGTCATCAATATATTCAAGGCCCAAATTTCTTTTGAATCTCTCTTTCAGTTCATTCATTTGAGCCTTGTTCCATAGGAACATGGAACATTTTTTTTATTATCTAAAATCCAAAGGATAGTTGAATAATTCAATTTACCTTCATGGGCTATATCTTTTAAGGTCCTAAACCTTTCCCAGCATTCATTCACCTATTCATCCACCCTTCCTTCCATCCATCTGTTAGTATCATATCCTTAATACCGGAGTTACATACTAGTTATATTTAAGAGGCCTAAATAACAAGATGTTACACAAAGGTTCTTCATTTACTGCATGTATTTCACTTTTACAAGTCTGCCACAAGGTAGCGCCATTTCACTATCAATATTGGGATATATTAATAATCTCATTACACCTTTCCTTCTTTAAAGAAGCATGTCATTATATAAACTAAAATAATACCAACAATGTTGCTCAGAATTAAGCAGTACTGAAACATTTGAGTATCTTATATAAACTTTCAAAACCTGTTCTTTGTATTGTAAATATGTACATGTATGTGTGTATTCCTAAAAAACCAGCTCACACATTTTGGATATAATAACAAGTGATTCAATTATCACTGAGGTATAAAGCTACTGAAGCGACTTCAACAAACTTATATTTAAAACTTAATATACACAGCAACTCCACAGATGAACTTCCTTAATTCTTACTTACTATTAAGCTGTTCTTTGTTCAGTTGAGTTTCTAATCTTTTAGATATGCTGGCTGTTTTGTCTGCCACTGACTTCTGCAGAATTGATCCGAGTTCTGCCCGGAGTTGTCACTACTCGATGTCGTGTTTGTTGGTGATGTGGTTGGAGATGTGTTTTGAGGATAGTCCGTTACGGAAGATTGTTGATCCACAACCAAGTCACTATTATCGTTGAACTGTTCATTTGATTTTCGATGTTCAGTTCTGATGGAGTACGACCGAATACCGACTTTCTTGAGTACAATGGCACTTTCCCAGGCCCTGGCATCCTTTTTCGGCTTGACTATTACGGTATCTCCAACTTTGAGTTCAAGCAGATCTTTGGCACTGCGGTTATAGTATTGTGCCTGCTTTTCGCGATTCTTCTCTTTTCGTTCATCAATGTCTGTTTGCAGCTATACGAGGGTCCATTGTCAGCTAGGACCGTTTCCGGGATTCGTCAAATTCCTCTGCAATCTAGTTATCACAGCTGGCGCATCCTTCTTCCCGGTCCCAGTAATCCGAAAAATAGTCCACTGTACATAGATAGTCATGGCCATCTAGCGCGAAAATGTCACATCCATTTTCTGCCATGGACGCGTTGGTAATTCATGGTGTATGAGGGTTTCCTTCCTTTGTGATGAAGCATATATGTTGCATGCTTCACACCACGATAAGTAGTCTTTCATGTCGGATGTCATATTCGGCCAATAGACACATTCCCTCGCTCTTTGTAGTGTGTTCTCGAGGCCTGTGTGACTGGCATGTAGTTTCTTGCGAATTTCACCTCTCATGTCCGTGAGGATGACACATCTCAGTACTTTGAACATGATACCGTTCGCGCTTGTTCGTGACGAATGCTGAAGAACGGTTTTGCCTCTGACGTACAAGCCTGGCTAGTGCTCGGCCATCCTGAAGCAATATAGTCCATCACTGCTTTCAGGGCTGTATCGCGTGCGGTAGATTGGCAGATCTCTTGTTGCGATATCTGAGATACGGGAATTGCATCAATAAGGTGAATACACTCGACCTCTTCTTCAATGCCTGATCTTTGAGGTCACTAGTTTTATTTCTGAAAAACTTGTTTTAATCGATTTAAAGATATTGGGTATTGTCGTAGTACGTGATGAGACAGTAAAGGAAGCCCAAGAGACATTTGTTAGTGTAACTGGTGCTTTATTTAAAAAACGTTAATTCTCGGTGTCCACACACAGAAATGAAATGTCTACAGCAAATAACCCACTGAAGCCCCCAACTACAGTCCGGCATCCTCAAGGAAAGAAGGAAGACACCATGCAGCCATCAATCTACTCAGCAACACAAACTGCAAGTCCTCTTGCCCTCATAAAGACTGCCAAACAGTTGAACTAAAACGTTCACCAAAAGTAACTGCAAGTTTCTCTAGCACAGGCACAGCCAAAACATGCACTCTACCCTTGAACGTGACAAAATGTGCTTCAATACAAACATGTGTGTTAAGACATTAACGTGGGCGGTGTATTACAAAATCAATTACCCATCCGCGAAACCATGTGTAACATGTGTAGTGAACTAATTTGCATAATCCACCTGATCTTGATAGCAACTTCCACACAATCCTCAATTGGTACTTCAATGTCACGAACACCTCTTGGTACGCTCGAAAAAGGAAGACCGGGCTAGATTTCCGCTTTGTTGTATAAACCCAACAATATGCCAGTTGAGTAAATTTATTCAACCTGTAAGTAGAATAAAGATAAACATCTTCAGTATACATCACGCAAAATATATATGTATGCATTTACTCTGTTCATGCATAATTAAAAGCGTTAAATTGCAATCATTGGCGGATGCTGATCTGGGCCCCTGAATCTAGGAGCACATTTCCTTCTCTCTTTAGCTGGTCTGTTCAAGTAAACCTAGCATGGCTTCCATCCCTCTTACATGGGCTACTCCCACTGCATTGTTGTCCATACTGGGGTGTAAAAGCGGATGATGGAAGAACTTGCACGGTTGCCCTTTTTATGTCTCTGGACACTGTCTCCTTTTCTTACAAGTAGCCATCCGATGCTCTGTACCGGCTTGCCTTAAACAGCTATAACAAGCTCGGCTGCTCTTCACCAACTCCAATCTCTCTGCTGTAGACTTATCAAGGAAAGTTTTGCATTGATCAGTCCAGTGCCATCCTTACTCTTGCAGATCCAGCAGCGATAATCTTGCTGTCTTTCCTCAACTGTTGTGACCTGATTAACAGCGGATCTGGACTTGGAGGTTGAATCATTCCTCACTGGAGCAGATGATCCTTGAGGATTCTCTCCTCCCTGCATAAGACTTTCTCCTTGGCCACTCCTCCCAAATGATCGACTAAGGACGGGCCTTTGCAGCATCTTTCAGCTGGTAGTGCCGACAATAACTATCGAAGTTGTCCAGCCACCCCTGCAGAGACAGATCACCAGCAACCTGTGGAGAACCCTTAAACTTGCCCACCTTAACTGGTGGTGGCGCCTTCTGTACATTAAGTCCTTGCAGAACACTGATTAGTGTCTCTAATATCTGCACCACTGATACGGCCATCGTTACAAAGGCTGTAAAGGTACTAGTGGGACAAAACAGATAAGTTACAAGTTACTATACTAAAAGTACATAATAATAATACAAAACAAACAAAATACAATGATAAACAATTACATATCAGACATAACAAAAATTACAAATAAACCTACAAATTA
->AK346643.1 Sus scrofa mRNA, clone:MLN010029B10, expressed in mesenteric lymph nodes 
-TAGCTGAGACACTGCCATGTTTCTCATGTACTTAGAGAAAATTCACAAGGTTTTATTTTATTTCTTAGGTTTTGCAAATATACATATAGGGAAAAATGAAAATATAGAAAAATGTGAAACGTAACCAATTCTGTCTATATGGTGGGATGGGTTTTTTTTTTTTTTTTCAGAAACTAAGTTTACTGACAGGATTTTACTTTAATTTTAGTAAATATGACTAATTTAGAGGCGTTAATCCCTTATGAGGTCTTGGGATTCCTAAGTCATTGTGTTGGAAACTGTCTGGGAAAGACAAATAGTTAAGATACGTAACTAGGATCTCATGTTTTGGATTTGTACTGAATGACGTCAGAAGGAATGTGGTAACTGTAGTCTCTCCATATTTGAAGCCTGTCAGAAAAAGGAGAAATTATAGAATTTTGTTCATTCGTTTTAAATTTCAGGAGGCAGTGTCGGTCACTGGAACGGAGGACAGTGGTGAAGGCAGGTGTAAGTGAGGGAAGGAGGATGAGGAATGCCGTGAGTGGAAGGAGGCAGCCTGGCGTGGAGGTAGATTTTAGCTCATGTGAAGCGAGATTGCTTGCTGACCGGTACAGAATTATCCAAGGATTAAACTACTTGATGAAGTCATGAGCCTTTCCATCTCTACAATGGTTTTCTCTTTAAAATATAGGTTGCCGAAGGATCTAAAAATGTACGGCTAGGTTCCCTCATTGGGTTGCTAGTTGAAGAAGGAGAAGATTGGAAACATGTTGAAATTCCCAAAGACGTAGGTCCTCCGTCACCAGTTTCAAAACCATCAGTGCCTCCTCCCCCCTCACCACAACCACAGATTTCTACCCCTGTCAAAAAGGAACACACACCGGGAAAACTGCAGTGAGTATACTTACTTGAATGATGTTAAAAAAAAAAAAAAAAAAA
->XM_010884186.4 PREDICTED: Esox lucius IQ motif and ubiquitin domain containing (iqub), transcript variant X3, mRNA 
-GGGTGGGGGCGTATGAAAACGTTACGCCAGTGCTTCTTAGATCACATGGATGTTACCATGGGAGCGCCCAAACACTTGCAGCATTGAATCAAGTGAATGGTACTGTATGCATGCGGCACCAAAGACACGAGCTAACGTTAACGTTAGCCAGTTACCCATGTCCGAACATGATGCAGAAACTTCGGGGATCAAAACTGATGAGCAAAATGAAAAAGAAGACCCTTTGTACCACAGATTAACCGAAATAAGTGAGTCTCAGTTAGAAAGCAACGCGACAGAAGAACCACCTACAGATGTAAGTCTTACGTTACATTTACAAGATAGCGATGCTGGGGGAAAGATTGAAACACAAAATGTGATGATGGAGGAAGAGGTATGCAAGTCAACCTTTTTGACTGAGAATGGGAACTCGGTGGAGGCTACAGCTCCAGCAGACCCTCTGGAGGATAACAGGCAACAAGGAGCATTACCAAAGAAAGAGTCCTTCCCAAATGCTGTTGGGAACTCAACAGCCACTGTGAAGATCATGCTGATGCCAGAGGGACACATGATGACAATGGCCTTTGCCATTGGGCTCTCCATCAAAGAGTTGAAGTGTAACTTCTCAAATGAGCTAAAAGTACCAACAGAAGTCATACAAATATCTCTGAGTGGCAGAGTGATAGAGGACCACAGAAACCTGATAGAGCTGGGAGTGCAGCCTCATAGCACCGTCCAGTTGGAGATGACCTCCTCTGACCCTGACAACCACCCCATCCGTCCTATGAAGCCCCGGCAGGACTACAACATGCCTGACGTCCTCACTGTCCGAGTCCAGACAGACTCGGAGACAGACACATTCCAGGACGTTGTGGTCGAGGTTGAGAGGGTCACCCACAGGAAGGCTTTTCTGGGGGGCTACAGGCACAAGGCCACAGGGACGGAGTACCACCACGCTGCTGTACAGACTATAGCCAAGAAAAAACCAGACGGGGGGGTGGAGACTTTCAGCCGCGACACACAGACTGTGACGGTGAAGAGCCAGTCCCAGCAGTGCACCAACAGCACATCCACCCAGATGACCAGGATCGGCTGCTACGTATCCAACATGGAGGACAAGCTCATCTCCCCTGGGGCCTACGTCACCGCCGCCCAGTACCACGCCAAGAGACTGAGAGCTGTGATCACTCTGCAGACGCACACGCGGCGCTGGCAGGCAAAGCGGATGACTGACCAGCTGAGGGCCGACAGGGATCTGCGTCTGGCCTGGATGGAGCGAGATGGGTGTAGGAAGAGGAGGGAGAAAGAGGAGCAGATCAAGGCTGAGTACAACAGGAGGATGAACCCAGAGAGCAGGGATGACTTTGCACTGCTCTACAGCGCCCTGGAAAAGTGGAAGAAAGAGGAGTTGGAGCGAATCAATGCCACACTGGAAGGTGCTGAGAGGAAGGCTGCTCTGTGTGCGCTACTGGAACAGGAAACGCAGCTAATTGCATCCATTGGACGCCACCGAATAGCTGCTGGGGAGAGGAATTACCACAAGGCCGTTCAGGCCTTCCTTGAAAAGTGTGCTGCCCCTAAGAGGTGGTGTGCATTTGATGGGAAGATGACCCAAATGGAAACCCAGTACACCATCAGAGCCAAGAAGCTGAAAGAGCTGTACACCAGCATCAACCTGCACTACTTCAACCACGAGGAGAGGCTGGACGTGCTGCTAACACTTAAACACACCGTCAAGGAGCATGACTGCAAACTTACCCAGGACATTGTGGAGTTGATTGACAGAGAAGCAGACCTGCTGTTGAGGGGGGTGAAGAAGTCCAATCTGGAGGGGCTAAGGAAGAGAATTTCCACCCTCTTCCTCCAGTACATCAAAAGCCCTACCTTTAACCCTGAGGCGGCCAAACTACTGAAGGTCCCCCAGGACCCAGCTCAGCTGAGGAAAAACATCTACTTCTGCCGTAGCTGTTGCCGCCATTTGCAGTCCACTGACTTTACCCTGACGGTCAATGCCCGCCTAGTGGGCCAGTGCCAAAGCTGTTCGGAGCTGGACAGCGAGGCCCGCGGCCGCGAGAACCTCTCCCACTACAAAACCATCCTCAGCAGGCTCCGCAAGTCAGAGGCCCAGAGGGACAAGGAGGCCAAGATTACCTTCCTGCTTCAGGAGCAGGATCTGAAGTACCTGGTAGATGTAGTGTGGGGGGCCCAGTCAGCACTCAGTGCGTGGAACGACATGCACGACCTGGTGATGGTGAGATGGGAGCGCATGTGGGAGTGGAGTCCCTGGAACTGCATTCTGCTCACCAAGGAAGAAGCTCCTGTTCATGACAAAGTGGAGGACAATGAGAAGGCCTACGGAGTGGTGTTTATTCAGAATGTCAAACAAAAACACACGCTGGCAAAGAAGTACTTCTCCCAGATTCCAGTCATGGCCAAATACCTCCAGGACGTGCACTCACAACAGGCCGCCCACGGAAACTTCTTGGTCGCCAAGCCCATCAACACGTTGACAGCCAAGGCCCTGCCTACAATTCCACAAGCCACTGGTGGAGAGGCTACCCAGTGAAGGCCTCCTTATCCACCTGCCTGCCTAACTGTCTGTCTCCCTCTTTCTCTATTCCTCATACTCTGTTGAATGTCAAATAAAAATAGTATTCTTGAGAGGTATTGAACTGGGTAGAAATGCAATTTTGAAATGGATGTGTAATAATTTTGTGATAAACGTGAAGATATTAAATGTAAAATA
->XM_003665021.1 Thermothelomyces thermophilus ATCC 42464 uncharacterized protein (MYCTH_54167), partial mRNA 
-ATGGCCTCATCAGCTGCCGCTCATGGCTCCCGGCGTCCACCCACGAGACCAATAATCTCCGCAGACCGGAACCACCACCGCATCATCCAACTCGACGACTTCTCCTCTCACATCGCAAGTGCAGAACAACAACCACCGCCAGCAGGACCAGTATCGGCAGCAGCCAAATCCTCCTTCAAACACCTCTTCACATTCACCCCCGCACGGCACATACCCTTGGTCGCCCTCTCGTTCACCACCGCCGCCCTCGTCGCCGCCGGCCGCACTGCCTACGCCGTCCTCCTCGGCCGCATCTTCGACGTCGTCACCCGCTTCGGCACCGGCCTGCTCTCGCCCGCCGACTTCCTCGCCCAGATCTCCCAGTGGGCCGTCTGGTTGTGCGTCCTAGGCGCCGGCATGTGGGTCGTTTCGACCGTCGACGCCGCCGCCTGGGTCGTCGGCGGGGAGCTCAGGGCGCGGACGGCGAGGCGGGAGGTGTTTTGGCGGTTCCTGATGGGCAAGGAGGTGGGTTGGTTCGAGGCGCGGGAGGAAGGGGTTGGCGGGTTGACGGCCAGTGTTGCGACGCAAACGAGGGAACTGCAGACGGCCACATCCCAGACGCTTGGCTACATTGTCTGCGACGTGTTTGTGTTCGCCGCCTGCCTCGTCGTCGCGTTCGTCTACTCGTACAAGCTGACGCTTGTCATGCTGGCGACTGGTGTCCCCTCGGCCCTGATACTCTGGCGCATCAGCAGGTTCCTCGACCCGGCGATCGAGGCGCAGAAGAGAGAGCTCGCGCAGGCCGCTAAGTACGTCACCGCCGCCTCCACCGCCATAGACCTCGTCAAGGTGTACAACGCGGCCGACCACGAGGCGTTCAACTTCACTTCGGCAATCCGGAGGTCGGCGAGGTATTACTCGCGCCAAGCGATGTGCAACTGCGGGCAGATGGGCTACGTCAAGTTATGGATGATCACGTTGTTCGTGCTGGGCTTTTCATTTGCCGTCGTTCAAGTCAAAAATGGCGAGCTTAGTCCGGGCGATGCGTTGACCACCTTCTATGCCGCCCTTATCGCGTTCCAGTCGATCGAGATGCTCGGACCGCACTGGCTCGTATTGGCGAAGGGCATGGCCGCAGGACAGCTGCTTCGAGGACTGGTGGATGAGAGCGGCAGTGGTCAACTCGAGAGAACTGCTGGCTGTCTAAAGCCCTCTGGGTGTCGGGGAATCATCGAGATGAACAATGTTAGCTTTGCGTATCCGTCAAACTTTGCCAGGGCAGTCATACGGCCATCGAATCTTCGTTTCGAGCCTGGACGGCTCACCTTTGTCATTGGCAGAAGCGGCTCTGGTAAGAGCACCCTCGGCAGTCTCCTCGTGCGGTTCTACGAACCCCTCACCGGACAGATCATGCTGGATGACAACCCCATCACGGCATTCGATCTCAACTGGCTTCGACAAAACGTTACGCTTATCCAGCAATCCAGTTCGATCTTTGGTGACAGCTTCTTCAAAAACGTCGCCCTTGGCGCCATGGAACCAGACAATGTCCCCCTCGACGCCGTGCAAAGCGCTTGCTCCATGGCCCTCCTCCAGTCCACCATTTCCAGCCTACCCAACGGACTCGACACCACGATCGGTCCAGGCGGCTACGGCTTGAGTGGTGGACAGAGGCAGCGTCTAGCTCTTGCCCGAGCCAAATTACGCGATCCACCCGTTTTGATTCTTGACGAGATCACCAGCGGACTCGACCCCGTGAGCCGAAATCTGATCATGGAAGGCATTCGCGCGTGGAGAAAGGACAAGACAACAATCATCGTCACTCACGAGGTCGGCGACATTAAGGACGATGAGTATGTCTATGTCCTTGCAGATGGATCGGTGGCTCAAGAGGGTCTCAAGCGTGAGGTTGCCAAGGATGAGAGCGGCCTCTTTGCCTCGTTCGTTGCCTCTGCCGAGACTGCCTGTTCCGGCACTGACAGCGAGACTGAGAGCGAGACTGAGAGTGAATCCGATTCCTCTGACGACGGTCCTCTCCAGGAGTCCCAATATGCTAGGTCGCCCCGAGGTGCGCTCATCAGCAACCAAAGAATGCCTGTGGGCCTGTTCCAGCGCATCTCGCTAGGACCCCGAGCAACCATCGCACAGGAGTCCATCTGCCGATCCATCACTCACAAGATGGCCACGGATGATGAGCCTGTGACTGTCAACATCAGCCGCCCCTCTAGTATCCGGATCATAGCGCAGCAAGGATTAGCAGCTCAAAGAAGTAGGACTCTGAATGCACGCCAGGCTTTGCGGACCGATCTGGACCCGGAGCTCCAAGTGTCTCTCGACTCACTAGACCGTTTCTTTCTCGAGCACCTTGCCAAGCCCAGGGGCCGCGAGAGCCCATCTAAGGGGACCCAACTACCTTCACTCGCGGCCATTTTGAAGACTGTCTGGCCGACGCTGGACAGGACGGGCAAGGCTCAACTGATCGCTGGTATTGCTCTGTGTCTGGTTGTCGCAGGCAGCAACCCCGTCTTCTCCTTCTTCTTTGCCAATCTTATCGGACAATTCTGGAACATGGAGGGCCAAGAGAGCTCAGTCCCCAAGTGGGCTGGCCTCCTTGCCGCCATTGCTGCTATCGATGCGAGCGCTACCTTCTTTGGCTACTTCCTCATGGAACAAGTGGCCCAGAAATGGGTCAATAATCTGCGCGCAGAGGCGATCAAGCGCATCCTTAGACAGCCCAAATCGTGGTTCGACAGGGCAAACCATTCCCCGGCTCGCATCACCCAGTGCCTCGACCGCAACGCCGAGGAGATGCGCAAGCTTGCCGGCATGTTCGTGCCCCTCCTTTTGACCATCTCCACCATGATGCTCTCCTCGCTCATTTGGGCGCTGGTTGTCCGGTGGGACTTGACATTGGTGACGCTCGCCGGCGTGCCCGTGGTCATCGCAGCGGCGCGCGCCAACTCGCTGACGAGCGACAAGTGGGAGGCCGCCTGCGATCAAGCTGCTGCCGCGACCAACGCCATCTTCAGTGAGGCCTTGGCCAACATCAGAGTCGTGCGCGCCCTGACACTGGAGCGCTACTTTAGCAACAAATTCAGCCGCTCCGCAGCTGCCACCTACCATCTCGGGGTGAAGCGTGCAGGCTTCATCGGGTTCTTCTACGGCTTGCACCAGTCCATCGTCTTCTTCCTGACCGCTCTCGTCTTCTTCTACGGTGCCAAGATACTCGGCGAAGAGGGTACCACCGTGACCGACGTCGTCAGGGTCATCAACCTCTTGCTCTTCTCGCTCGGCACCGCGGTTGCCATGCTGGGCAACGTCCCGCAGATCGCCGCCGCCAAGGCCACGGCGGTGCAGATGCTCTACTACGCCAACCTATCGCACGCCGCGAGCCACGAGTCTCGAGGCGAAAGGCGGCTCTTCACCCCGCTCCCCGTCCGCATGACGAACCTGCGATTCGCCTACCCCAGCGCGCCCCAGACCCAGGTCCTGCGCAACATCAACCTGCAGTTCGACGCCGGTACGTGCACAGCCATCGTGGGCGCCTCGGGCTGCGGCAAATCCACCATCGTGAGTCTACTCTTGCGGCTATACGACCCGCTGCAAGAAGAGACGGACCCGGCACGCGCAGCGCACCGAAGCGAATCCGGAGCCCCCATCTCCCCGACCCCGGAATCCCCTAGCACTCCCCGATGCCAACGCTCCTCCCCCTTCCCCTCTGCCACCGCCACCACCAACACCACCACCAACACCCCACCCCTGACCTACGCCTCTGTCCCCTCCTCCCACGTCCACACCCCTTCTCTGCGCGCCCGCATCGCCTACGTGCCGCAGACCCCGGTCCTCTTCCCAGGCACGGTGCGCGCCAACCTGACCTACGGGCTGCACGAGGGGTCGCCGCTGCGGGCGGAGGCCAACGTCGTCCTCGCCGCGCAGCAGGCCGGCATCCACCCGTTCGTCGCCTCGCTGCCGCAGGGGTACGACACGCCCCTCGGCGGCGACGGCGGCGGCGGCATTGGCGGCGGCATTGGCGGCGGGGGGCCGGCCGCCGTGTCGGGCGGGCAGGCGCAGCGGCTGTGCATCGCGCGCGCCCTCGCCCGCCGCCCGCGCCTGCTCGTGCTCGACGAGCCCACCAGCGCGCTGGACGCCGAGGCGGCCGCCGAGGTGAGGCGGCTCCTGCGCCGCCTGGTGGAGGGCGGGGGCATGGCGGTCGTCGTGGTGACGCACAGCAAGGAGATGATGCGGATGGCGGACCGGGTGGTGATGATTGAGGGAGGGGTCGTGGCGGAGCAGGGCGGGTACGACGAGCTGATGACGGCCCCGGGAGGCAAGTTCCGGGCGCTGGTCGAGGGCGGGGTCTGGACTGCCGGCGAGGGCGGTTATGCTGAGGAGATGGAAGGGAAGGGGAAGGGGAAGGGGAAGAGAAAGAAGAAGAAGGAGAAGAAGGAGAAGAGGGGTGCTGCCGGGTGGAGGGACGTGGAGAGGTCGAGGGAGGAAGCGCTTAGGCGACTGGAGGGTAAGTCGGACTAA
->HM739632.1 Uncultured bacterium clone GB7N87002DK33B small subunit ribosomal RNA gene, partial sequence 
-AGAATCAACGCTGGCGGCGTGCCTAACACATGCAAGTCGCACGAGAAAGGGGCTTCGGCCCTGAGTAAAGTGGCGCACGGGTGAGTAACACGTGACTAACCTACCCTCGAGTGGGGAATAACCTAGAGAAATCTGGGCTAATACCGCATAACACTTACGAGTCAAAGCAGCAATGCGCTTGAGGAGGGGGTCGCGGCAGATTAGTTAGTTGGCAGGGTAATGGCCTACCAAGACAATGATCTGTATCCGGCCTGAGAGGGCGCACGGACACACTGGAACTGAAACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGCGCAATGGGGGAAACCCTGACGCAGCAACGCCGCGTGGAGGATGAAGTCCCTTGGGACGTAAACTCCTTTCGATCGGGACGATAATGACGGTACCGGAAGAAGAAGTCCCGGCTAACTTCGACGCCAGCAGCCGC
->XM_026799137.1 PREDICTED: Zonotrichia albicollis erythroblast NAD(P)(+)--arginine ADP-ribosyltransferase-like (LOC106630292), mRNA 
-ATGGCCATCAAGGTGGTGCCCCTGGACGTGGCCTGGGACTCCTTTGATGACCAGTACCAGGGCTGTGGCCCTGCCCTGAATGCAAAGTGGTCATCCCTCTACAACTCCAAGTCCCAGAAGAATCGTCCCTTTGCCTGGGGCCGTGGCTCTCATGGCCTACACATCCTGTACATGTACGGGGACTTCAATGCAGTCGTGTGCGCTGCCGGGCGCTCCCGCCAGGAATACCAGAACAACTTGTGCTTCAAAACGCTGCATTTCCTACTGACCCAGGCCCTGGTGACGCTGAGGCAGGGTCAGAACAGGCAGTGTCACCATGTGTTCTGGGGCATGCGTGATGTTCATTTCCAGGCATGGCAAGGCCAGAGCATCCGGTTTGGTCAATTCACATCGATGTGGCTGCGTAAAGAGATTGCTCTGCACTTTGGGACAGACACAATTTTCGAGGTGCACACGTGCCATGGCGTGGACATCCAGTGGTTCTCCATGTATCCAGGGGAGGAGGAGGTGCTGATCCCACCATATGAGACCTTTGAGGTCACCAAAGTCACCCAGAATGGGAAGAGGACATGGATCAGTCTCCGTTCTGCTGGGACTTTCAGCAAATATAACTGCGAGTGGCACTGA
->XM_047886733.1 Psilocybe cubensis uncharacterized protein (JR316_0000919), partial mRNA 
-ATGTCGCTCGCTCGTCTCATTCCAAGGGCTACCACCGTCTCTCGCATTGTCCGAACTGCCCCAACTCTCCAAACCAGATGGGTGCCCCGCGCCATGTACTCTGCTGGCGGTCCCTTGTCCAAGGACGTCATCACATCCCGCGTTCTCGAGACATTGAAGGGATACGAGAAAATTGACCCGGCCAAGTTGACCACGTCCGCATCTTTCCACAAAGACTTGGGGCTCGACAGCTTGGATGCAGTGGAAGTGATGATGGCAGTTGAAGAGGAGTTCTCAATCGAGATCCCTGACGCTGAGGCTGACGAAATTACAACGGTCCAACAAGCCATCGACTATATCGCAAAATCTCCTGACGCTATTCTGGAGTCTCTTGACTTGAGAGATGATCGATGTGACGCGAGTTCCGTCAAATCATCTGCTTTAGCGGTCGCATGA
->XM_023773741.1 Ramularia collo-cygni uncharacterized protein (RCC_08491), partial mRNA 
-ATGGCGGCCCCCGAAAAGACTCCCACATCCCCAGATGCCCACCGCGCGCTTCCAGACAAGAAAGCCGTGGAAGCGGCTGGCGAGCTTCTAATCAAAGACGAAAAGGGCAACGAGATTGCCTTTAAATCGCTCTACTCCGACAAGCCTGCCGATGAGAGACAACTCATTGTTTTCGTTCGACACTTTTTCTGCGGCTCCTGTGAACTCTACGCCCAAGCACTCGCACGGGATCTCCCCGTAGAGGCACTGGCAGCCAACAAAATCACACTCACAATCATCGGATGCGGAGAGCCCATTTGCATCGCTGATTGGCGAAAGCGAACGGGATGTCCTTATCCCCCCCACACGGAGCCCAAGCACCGACTACAAGACACATTGGGCCCCCCCAACCCCCCCAGAGCCATGCCCGATAAATTCCCCGAGTACCACTCCAAAAGCCTGTTCCAAGTAATCAAAGATTCCACATGGCATGCACTCTCCTCCGGACCTAAAAAGGCCTTGTCAGGCGGTCCCGCATCGCAGCAAGGAGGCGAGTGGCTTTTCCAGAATGGAGAGGTTAAATTCGTGCACCGTATGAGGAACTCGGCCGATCACGTCGACACCAAAGAGCTGAAAATGGTTCTTGAAATCAACGAGTAA
->XM_048709217.1 PREDICTED: Triticum urartu serine/threonine-protein kinase Nek3-like (LOC125545316), mRNA 
-TTACGAAAAAAGACCTACAACAAAAAATCACACGACTCGCACGCACGAGCGAGTGCCCTCCAGAGTGCGCTCGAGCGAGGCCTCCAGATCGCTTCGCCGCCGCCCTCGCACTCCCATCAGGCGACTCGCAATCCAGTCCTTCGTTACAACCCTCGCGCTCGCATCAAGGATCGAGGCCTCCAATGGCCGCCGCCGATCCCTTCGACGGCGCCGAACCACTTGAGGAGCCGCCGCCGATCCCCTTGAGGAGCCGTTCACCGATCCCCTTCAGGAGCTGGCGCTGATCCACGCCGCTGCCACCTATGCAGAACCCCAGGGCAGGGCGCTAGGAACCACCGACAAGAGCATACTCGCCCTCGTGGCCAGGGTCTCCGCGGTCGGCATCGGCGTCGGCGTCGTCTACGGCTCCATCAGGCTCGACATCCTCAAGGCTTGCTCAGAGGATAGTGCAAGGAGATGTCCCACAAGCACTGACAAATTGTCGACTAATTACCAATTGACATGGGTGCTTTGATTGCCGGTGCAAAATATCGAGGAGAATTTGAGGATAGGCTTAAAGAAGACGCAGATTCTGATGGACAGCTTGTCAGAGATGGCAAAGCTGTTCTATGCAGGGTACGCCTCTGAGCTAGCCGATGCGTACTGTATCCAGTGTTCTGTTGCATCCGGTGCGACCTCAAAGAATACCTTCTTCTACCTGGGCGTTGAGCGCCTCAGGGACGACGAGGTGCAGCGCCTGGGGCGGAAGCAGTTCAACTACACGATGATGAATTTTTGCAGAGAAGTTCAGTTGCTTTGCGTATGGATTTACCAACAGTTCTTTTGTGCAGTTGACACAATGGGCCATATGATTCTTGGCAGGGAAGAAGCTATTTGGGCTGAATCAGACGAGGTGCTGGAGCAGATTGGGAAGGGCTCCTTTGGCTCTGCGCTCCTAGTGAGGCACAAGGTTGAGAGGAAGAGGTATGTCTTGAAGAAGATCCGGCTCGCCTGTCAGACCGTCAGGTGCCGGCGATCTGCGCACCAAGAGATGGAGCTCATCGTCGCAAAAGTAAGGAGCCCTTACATCGTGGAATACAAAGATTCTTGGGTGGAGAAGGTGGGGTGCTATGTGTGCATCATGATTGGTTACTGCGGGGGAGGGGACATGCTAGAGGCCATTAAGAAGGCTAACGGCAACCATTTCTCGGAGGAGAAACTCTGTGTGTGGCTTGTGCAGCTCCTGATGGCGCTTGATTACTTGCATGCCAATCATATCCTTCATCGAGATGTCAAGTGTTCAAATATATTTCTTCCAAAGGACCAAAATATACGGATCGGCGATTTTGGGCTGGCTAAAGTGTTTACTTCTGATGATTTAGCTTTGTCGGTTGTAGGAACTCCCAGTTACATGTGCCCTGAACTTCTTCCTGACATTCCATATGGCTCCAAGTCCGACGTATGGTCGTTAGGATGCTGCATCTATGAGATGACTGCGCTGAAGCATGCATTCAAAGCATTTGATATGCAGACACTGATAAACAAGATTAACAAGTCTGTTGTCGCCCCTCTACCGACTATATATTCTGGCGCATTGTAA
->XM_027425389.2 PREDICTED: Cricetulus griseus phosphate cytidylyltransferase 2, ethanolamine (Pcyt2), transcript variant X10, mRNA 
-GCGTCGGGGGCGGGGCCGAGGCAGTGCGAGTCGCGGGAGCAGCCCCGGGCTTGCGGGGCCTGTGGTGCCATGATCCGGAACGGGCACGGGGAGGCCGGCGCGGCTGGGCGCAGGGGCCCGGTGGGCCAGCGCGCCGTGCGGGTGTGGTGCGATGGCTGCTATGACATGGTGCATTATGGTCACTCCAATCAGCTTCGCCAGGCACGTGCCATGGGGGACTACCTCATCGTGGGTGTGCACACTGATGATGACATCACGTTGACAGTAGATGGCCGAGATACCTACGAGGAAGTGAAGCAGGCTGGGAGGTACAGAGAGTGCAAACGCACCCAGGGTGTGTCCACCACAGACCTCGTGGGTCGAATGCTGCTAGTGACCAAGGCCCACCATAGCAGCCAGGAGATGTCCTCGGAGTATCGGGAATATGCTGACAGTTTTGGCAAGTGCCCCGGGGGGCAGAACCCCTGGACAGGGGTGTCCCAGTTTCTACAGACATCCCAGAAGATCATCCAGTTTGCTTCTGGGAAGGAGCCCCAGCCTGGGGAGACAGTCATCTACGTGGCCGGTGCCTTTGACCTGTTCCACATTGGGCACGTGGACTTCCTAGAGGAGGTGTACAAGCTGGCCAAGAGGCCCTACATCATCGCCGGCCTACACTTTGACCAGGAAGTAAACCGATACAAGGGCAAGAACTACCCCATCATGAACCTGCATGAGCGGACTCTGAGCGTGCTGGCTTGCCGGTATGTTTCAGAAGTGGTGATTGGGGCGCCATACTCGGTCACAGCAGAGCTCCTGGGTCACTTCAAGGTGGACCTCGTATGTCATGGGAAGACAGAAATTGTACCTGACAGGGATGGCTCTGACCCTTACCAGGAGCCCAAGAGGAGAGGAATCTTCCGGCAGATCGACAGTGGCAGCAACCTCACTACAGACCTGATCGTGCAAAGGATCATCAAGAACAGGTTGGAGTATGAAGCTCGGAATCAGAAGAAAGAAGCCAAGGAATTGGCCTTTCTGGAGGCCATGAGGCAGCAGGAGGCACAGCCTGCAGGGGACACTGCCTAGCTTCTGACCTGGAGGATGTTACTCAAGCCCTCGCCCTGTGCCCACCTCTTCTCGCCCCGCCCTGCCCTGCTGCTGTGTCTTGGTGTCAGCTCACACAATTCCAGAGGAAGCTGCCTTGCTGGAGGGTGAGCTGCCCAGAGAGGGTGGCTCACACAGTGAAGCAGCCCAGTGGACAGGATAAGCAGAGGGCACCTGTGACTGGAGGAGTATTGCTATGTGTCCTTGGCATCCACAGTTCCAACTGCCACTGCCCTAGTCTTGTCTGGGACACACCCCTCCCGCCTGACTGGAAGCTGCCCACCCAGCTTTGGTGAAAAGGTTCAGAGGTTCAGAGGGATGACTTTGGGGACCTCTTGTCCTGGGTCACCCTGCAAGTGGGTACCCTCTACTTTGGGGCACGTTCTAGCACCCCATTCCTGATTCCTAGAAGACGCACTTGCCCCGGTGGCTGGGCCAGCTTGACTGTTCTCTGCACAGACTTCTGGTCCTCATTTTGTACCTCAGTGGCTGCTGTAAATCTTTTTGGCACAACTGAATAAATCCTGGTGGGAAGTGCTCTGTGGGCTCCAAGCCCCCGAAGAAGCAGGAAA
->XR_002678113.1 PREDICTED: Setaria italica uncharacterized LOC111257591 (LOC111257591), transcript variant X4, ncRNA 
-CCGCACGCCCCCCGCCGTCTGGACGCCTCCCGTCGCTCTCGCTTGGGCCACCGCCGCCGCCAGCTCTTTCATGTCCGCCGCCGCCTCGTCCTAGTCCTCGTCCTCCTCCCTCCTTTCCAGTTCGCTGCCACCACCGCCGCCGCCGCTAGCCCTTTCCAGTCCGCCACCTCCTCCTCCTTGTCCTCCTCCTCCTCCCTCCTTTCCAGTTTGTGCCGAGCGGACTCTGCACCGCGGTGAGCTGTGCCGGATCCTCGCGGAGCTCTTCCCAAAGTACCCGATTCAGACGAGCGCAGACGGTGAGGACCAGGAGGAAATAGGTGCTGTTCTAGACCTGTAGGGCAGTTGGTGTGTCCTGACAAAAGTTAAACTACCTTGAGGTATATGATATGTTCCTATTAACATCTAAACTAGGGATCTGCACATAGAAATGAAAATAACTTGATTGGTTTGGAATACTCGATCATCATAGATAATGAAGTGAAACACGGAAATAATGGAATGTAATCTATTTTTCATTGTCTTGCTTCGTGTATGTCTCCTCGGCATCGGTAGCTTTGTATCCTGGACTTCCCTTCACTTTGTTCCAGGCATAGTTAACCAATGTGACAGCTAGCTTGAGCCTGAAATTAGTCATATCCTTCTGCACATAACAAATACAAATGCCTGTTAGCCTTAATGTAAGATGGGCATAGATTGGGTTGCTGAATTTATGTTGTTCAACTTACCTGTGTGAATAAGGAAGATAATTTGTTTCCGGTCCAAAGCTCCATGAATTTAACCGTGAATAGTCCACACGATGCACTGCGAGTTTATTTGTATTTACACAAGTTAGGAAGAACTAATTATGGGAACCCGAGTATATTGACAGGTGTTGATGTGCTTGTACTTGTCAGTCTGGATTGTCTTTTTGATGCATTCAATGACTGGCCATTCTTTGACTTGGGTGTCCTTCCACCTATGTTCTTTGATCAATTGCAGGTCTACAAGGCGTGTCATACGGTTCTGCAACCCTTGCAACTGAGTTCAATAGAATCATCAGTGGTTGAGGCTTGCCTATATGTGTCTCCATCGCCTGAAGCACGACATTTCTAGGTTCTACCACTGCCCTTGATTCCTGCAAGTTAGCAACGGCTGCAAATTATGGTAGTCGAGCTCGGAACTGAATGAAGGCAAGTGGTGGTATATGGAGCATTTCTCTTATTGATCCAAACAATGAGAATATCCAATAACACTTGGAACAATTCTCAGCTTGCAGAATACAATTGATCGCTACCTGAACCACACCAAAGGCACACCTACAAATGAAAAAGTTCACGAACCAGGTGTAGAGATGAGATTGAACTTACTGGATTGAATGGGAGAGATGTAATTGGATCAATTAGCGCAGGTGGTGCATGCTCCTTCTGTTGCGCAGGTGGTGTATGGTCCTGCTCTTGTGTGTCAGGATTGATGGGTGGCACCGAAGAAGTAGCTCCGTCCACATCCATGGTGGCTGAGTTGTCTGATGTGAAGCAAGATGGTAAACTGCCGCTGCCTGCTGCCTTCCTGCCGCTGCAGCTGCCAAGTTTGTTGTTCATGTGAGTCCGTGTGAAGCAAGATTGTTTTTATTATCTAACGTCAAGTGTTAGTTTAAATTAGGTGCTATGATATCCAAACGTGTAGAGTTTGTTTAAATTAGGCCTCACGTGAAGAGTTTGTTTAAATTAGGCCTCACGTGAAGAGTTTGTAAGCTAATACATGCCTCCAACGACGGGATAGCACAGTTTCCAACTAACGTTTTTCTGTCAATGCTTTCCAAGCAAATTACTGATACCTTGTCAATGCGACGGGATACTCTAA
->XM_050703260.1 PREDICTED: Spodoptera frugiperda RNA binding protein fox-1 homolog 3 (LOC118266813), transcript variant X21, mRNA 
-TCTAACCAATGCCCAGCATTGACTACTATTCTTAAATAAAAAATGTTGTTATTATGGCTTGGTTAGGTTGTGACCGAAAAGTTAAAATCATCTGTAATTTTGTGTAAAAGCAACGGCAACATTGTTTGTCACGTTTCGTCCGCCGAATCATGCCGACTGTATCTCCTATCCTTGTCTTTCTCACGGTGATCCGCACGGGCGAGGCGACTCGGTGAGTAGCCACGCGTGCTCGTACCCGTCCGTTGTTGCACATCGACATTAACCGCTTTCAGTGCTAGAGCGCGTTCCTCCGCGCTATACTCACATAACCTAAAAGTTAAACAATCCTGATAATTTTAGTACTATTCATTGTAAAACCATTAAATACTCATGATTACCTCGAATTTATAAGTTAGTGTTGTGGAAGTTTACGCCCAGCGAAAGGGCGTACGTGGAGTGTATTTTTGTGCAACACAAAGTAAATACAAACGGCAAGCTGTGGGGTTCAGGGGCCTTTTTTTTGCCGCCGCAGGGGATGTACTATCCTGTGAGTAACGGCAATGTCATCGATACAGGAACACCAACCTTGCTGCATATGGTGGGGACGGGTATGGCGACCCCGTTCCCGGCGGCGGCGGCGGCTGCGGCAGCCGCGGCACAGTTCGCAGCTAACGGCGACGCACTCGCCGGCGTGAAGGCTGAGGCTGCCGGTCCGACAGCTCCACCTCAACCCCCGCTCGTTAAGAGCGAAGGCCCGCCACCGCCCGCGCCTCTACCGCCCGCCAATTTCTCCCCTCAACCGCCTCCTCAACAAACACACACACAAAATTCAGTAGAAAATCAAAACAACAATAACAATACGCAAAGCGAAGGCGAAGCAAATGAAGAGAGCACACCAGTAAGTGTGGCGGCGGCGGTGGTGGCGCAGCAAGCCGCGGCCGTAGTGGCGCAGCAAGCGGCGGCGGCGCACGCGGCGGCCGCGGCCGTCAGCGCTGCCGTCGCTGCCGGCAATGTTAACGCTACCGGCACTCCTGAAAAACCGACACTCGTACCCGTCTCACAAGCGTCACAACCTAAACGATTACACGTCTCCAATATACCCTTCAGATTTAGGGACCCAGATCTTAGAAATATGTTTGGGCAATATGGCACGATTCTCGATGTAGAAATTATCTTCAACGAACGTGGTTCCAAGGGATTCGGTTTTGTAACATTCGCAAATAGTGGTGATGCGGAGCGAGCACGAGAGCGTCTTCACGGCACCGTGGTTGAGGGCAGAAAGATAGAGGTTAATAATGCGACAGCGAGAGTGCAGACAAAGAAACCTCCGACAGTTCCCAACGTGTGTGTCCAGTGGCCGGAAGGTGAGAACCTTCATTACGATTTTGCGCTGCGCCGCGAGCCGCGCGCCGCGCCGCACGCCGCCGCCGCCCCCGCCCCGCACGCCCCGCCCCAGCACGCGCTGTCGCACGCCGTGCTCAACCGCGCCGCCGCCTACGCCTCGCAGATGCACGCCTACGCGCCTGTATATTACGACCCGTTCTTAGCAGCCGCGGCGACGGCTGACTCCAACTACAGACTCCAGGCGGCAGCTGCAGCAGCAGCGGCAGCGGCGCCCCTGCTGAAGTCTCCGCTTACTTCGCCGCCGTCAGCGCCGCGCCCGCGCCCGCGCTCGCGCCGCTCGCTGCCACGTACGGCAGAGAATATGCAGATCCATATTTAGGCCATGGAATCGGACCAGTATCAGGATATGGGACTGCAGTGTACAGAAGTGGCTACAACAGATTTGCGCCATACTAGAAAGCCAGTGGATGGATACGATTGAACTCGAATACCTTCGTCACCTTCACCTTAACATGACAATGAACTCTCTTTGTAAACGTACAAACATAAATCATAAATTTAAGGATCAATAATAAACGCTAGCAGACTACCGTGTAAGTATCTAAGCTTGGGTAGCAAACTAACGAAGTAACGAGCGAGCGTGGAGTCGTGCAGTCGTCGAGTCGTCGAGTCGTCGGCGTCCACAACTTATGAAATACCAAAGTCATTAAAATTTCTAACAGAATACTTTATAAGTTGAACTTAATGTAAATTATTGTGTACCTAATGCTATACAAGTGCGAGCAGCTAAAGTGATTGCTTTCGTTCTATTTAGATATTCTAGGAGTTACTATAATTTTAACAGAAGTGAATTCATCTTACGATCATACGTACCGTACTGTCTAGTGTAGATGTTACACTTTGTTCATCGTGGACAATAGAAGAAATATTTACTATATTGTAATGATATATTTAGTGAGCTTTGCACTTGCATATCATAAAATTGTAAATACTTGTTTGGAAACATTTAATTCGGTCTTGATATTTTATTTTTAAATTCAAAATTGCCAAATGGTGTTTCCTGAATACATTTTCAGCGATCTTATTCTAAATAATAATATACTCGTTAACGTTAAATGGTCTCCATTTTTAATTATTAAATAGAATAAATTCGATTTGTAAACGCGAATTAGTTGGCGTTGCGGTTTATACCTAATATATCAATTTTAGTAAAATCGCCGTTATTATCTTGTAGACATGTATGTACGCAGAGACAATAGAAATCTCAAATCAACTATTTTGGAGTAAATACGTTATTTGGTGCGATATCAATGTGGTGCCATTTATTTGGTTGTTATTTTTACATCGTATTATATATTTTCTAAAGTTACCTTGTACTCTATACAGTTTATGTGACCTAGTTGTAGGCTGTCCCTCGGAGAACGCGACCAACGTCTCGGGTGTGCAATGCTCTGCCTCGCGTCGCTCCGCTTGAAGCGTGTCTCTTGAACTTTTGGCAGTGAACGCGAGGAGAGCACTTGTATACGTGTGTTGTTAGTCGGTAGAACTAATATGGCGTCGTTTCGGTTTGTACATTTCGCTTGAAGCTTACGTTGTCGACAGTCCCCGTTCCTTCCGTCAGCGCTGTGTCGCAGTCTGAGCCAGGCGTTTTCTCGTGTTCCTGGTTACTTGTAAATCGGTTGCTAGTTTATAAATAAGCTAATGTTTTACAGAGTGTAGGCGAAACGCTTTAGCTGTAGTCTATAAGGAAGAAGGGAACTCCGTCGAGTTCTTACATATCATTGAGATTTTCTCCTTGTATGTAGTTACGTTTATTCAATAATTATTCTATTGTCTTTTAACGATGTCTTATTTTTACAATGCTATTTAATATTTTTGTCTGGCGTACGGACTTTCATTTTTATAGAACAAACACGCATACGGGTCCAACCCTTTTAGAAGTTGTAAATTTTAGATCTAACATTTGCATTAGGATTTTAAAGTATTGTAACATCTATGAATTCGCTCAACGTTTATACCAAAGCACAAAAACCCATCGATTCATACGTATTCGGAGAAGTGTTTCATGACATTAACCCCTTTTCGATAGATTTAATAGTCTTTCAATGAGAAAAACTTGGGAAATCTATAAGTCGTGGTGTAGATAGATGATAACTAGAACAAAACTACAGACTTTATTTTTTACTTCATTTGTTGAAAGTTTTCATTAATCCTAAGTAATTTTTTTCTAAGGACATATCTACATGTTTGCCATCTAGAGTAGTTTAATCTTAACGTAGTTCAATGACTATATACATACATAAAATATAGATCTGAATTAAATCATAGTTGATTGTCAATCTTCTCATGTTATTGTAAATTCCTAAGGAATATAGTACACATTGTGTTACAGATGTGTCTGTATGAGAGGTTGCGTCGACGTCGACGTATTAGAGCTTTGTCAGTTTATTTTTCAAACCTTTACGTAGCAAGTAGAGATAGAGTACCGAATACGTTGGGCTGGTGCAGGGGCGCATGGCTCTCGTCACTGCTCGGTGTCGTCTGATGATGATAGCTTTAATTAATTAAAGGTGTTAAGGTGATGTTCTCACCCAGTTGTGTCATCTTGTAACCACAATTAGAATAACTAACTCAAGTAGCATTTCCATGACATTATTATTATTATTTGTCTTGCAGAATTCTAGTCTTCGCGCACAATCTTTTATTAAAATAATAAATAAATAGTAAAGGTGCTTACTCGTAAAGGTTTCATGTGATATTTACGGAATTAGTTGTCGAATCTTTGTCTCGATTTTTATTCTATTATTTCCGTACGATATGTAATAAGCAGTTCGTGTCATATTTTCCTTTTACTGATTATTTTTATAATTATTACTCTCGCCTTTTAGTGCCACTGGCTTTTATATAATAAGTTATATTTACTTTATCGTACGTTATTGTAGTCTCGTTGCAGCTTCGAACAATATTTTGTGCTTTACTGCTGAATACTCATGCGTGGATGCGTTATTTTAAGTAATTCTTAGGTTTGTAGGAATTGTCTGATTAATGCAAGATTTTGTATCTGAGTACAGAAACAAGTACATGTGATTCTATTTGATGATTTTATTGTTTAGTTTTAGTATTTTGTATCAATTAAAGTCACAAATATTTGTGAGTGTTATATTTTTAAATCATCATATTTTATAACAAGTTAACAGGACTTTATTTGGAAATACAATAATTACTTACGAACTTTGATATTAAAAATTCGATCAAATTCTGACCAAATCTCGTCTTGTTTACTTGGAATTTTAAAATGTACCTACATAATTTTTGATTATGTTATCTTTATAGTCTTTATGTATGATTTTAATGATAATTAAATAAATCACAAAAGCAAAATACCTAAGTTTTGTATAAAGTTACATAATATAAGCCAAATTGTTGTTACTTGGAGAATAATCAGAATTTAAATTACATATCTGACAAAATGGTTAGTGTGCTACAATAAGATTGAAAAAAAAATAACATCAAGAACAATGTATTATAAATATTATAATCATTAAATTAAGGATATGTATTTTGTAACGCAGTTTGTTTCTCAGTTTTTATGAGATGTTAAATTAAAGTTTCATACTACTCTTGTTTCATGCTGTGCACAACTTATACGATCGTCGGCTTCGATATTGTATTCATTAGATAAAGCGAATTGTTATATTGTGCATAATAAATCATATCAGTAGTGGTGTTAGCTAGTTGCGAGCCGGCGGCAGCGTCCACTGTACATAGGTATACTTAGTGTTACCGGCGGCCGTATTACTGTGCCCTCGGGTCATATTGTTAAAGTAGCCAGAGTTGATAAGTATCACTTGTTCGTCAATTGCACTCGTCAAAGCTGTTCAGTTGGTGTTGTAGGTTATTCAGATATTAGCGGGGTTATTGTTAGCTCCTGCGTGGCAAACTCGCAACTTGTGGCCGTGCATGACACTCATTTTATTGCACGACATCGCCACACGGCACGTCTACAAATTGCTGGTTTGTTTGCGATTAACCCCAAAACATTTAGATGGTGTAACGCATACTGACTATGGGATCGATTAGTTGCTGGTCTACTATCCGGAACGTAAATAAGTTTAACGTTCTAAGATCCATATTATCACTGTTAACTTAATTATAGCTATCGTTTGTAATTACTATTTGTTATGCATTACTTTTGAAGTTGCTTGTAGTGATCAAAGCAGTCAGTATGCGTTGCAGCTGCATTGTGGGCTAGTATGCGCGTGCGCATAGTTTCCGAGCTAGTCTCGAGCACACTTGCAGCCGGCCAGTATTTGAAATACTATTACAATACCGTGCTCAATTCCTGTATCTGTACATTGTAAGTATAATGTTGACAAAATGTTTTTGAAGTTTAATGTAAACTACATACAATAGGTTTGTTACATAATGAATGTCTTCCGTTTGGCACATTTTATAGATATACCTACTTTGCACATTTTATTAAAGCACGGATCTACATAGGAATACTAGTTCAATATTATTTAACAGAGATATTTTCAAGCCAAGTGCACAGCGAGCCCCTCATATACAATTTGTGATACCTAAAGTGAAATACGATTTTCCTTTTTTTTTGTGTGGCAATTTTTAATGGATTGCAAAGCTGATTTTCTCTTTTGAATTGTAAATATTTTTTTCTAATGAAAAATATTAAATGAAGTGAATCATTTTAAAGCCTTTGGCATTGTGTACTCATTTACGTTATAAATAAATTATAGTATAAAA
->XM_050906876.1 PREDICTED: Gymnogyps californianus immunoglobulin lambda-1 light chain-like (LOC127022987), mRNA 
-ATCGCGCCATGGCCTGGGCCCCTCTCCTCCTCGCGGTGCTCGCCCACAGCTCAGGTTCCCTGGTCCAGGCAGCGGTGACTCAGCCGGCCTCGGTGTCAGCGAACCCGGGACAAACCGTCCAGATCACCTGCTCCGGAAGCAGCTATGGTGTTGGCTGGTACCAGCAGAAGGTTCCTGGCAGTGCCCCTGTCACTGTGATCTACAACAACGACAAGAGACCCTCGGGCATCCCTTCACGATTCTCCGGGTCCAAGTCCGGCTCCACTGGCACATTAACCATCACTGGAGTCCAAGCCGAGGACGAGGCTGTCTATTTCTGTGGTGGCTACGACAGCAGCATGTGTGGTGTATTCGGGGCCGGGACCATGTTGACCGTCCTAGATCAGCCCAAGGTCTCCCCCACCGTCCACCTCTTCCCACCATCCTCCGATGAGCTCTCGGCACAGGGCAAAGCCACCCTGGTGTGTCTGCTGGGAGACTTCTACCCCGGCGCCGTGCAGGTGGCCTGGACGGCCGATGGCCGTACCCTCAGCAGTGGCATCGAGACTGGCCAGCCCCAGCGGCAGACCAACAGCAAGTACATGGCCAGCAGCTACCTGACGCTGAGTGCCGCCGAATGGAAGAGCCACGAGACCTACACCTGCAAGGTCACGCACGAGGCCGGCAACGTGGATAAGAGCCTGAATAGATCCCAGTGTTCCTAACCCTGCTGGGACCTCCCCGCACCCGGCAGCCCCTTGCCGGCCCCTTGCCGGCGCCCTCCCTCTTCCCCGCTGCTGGGGGCAGCGGCTCCCCCCCCACCGCAGATGTCTCTCCCCATGTCCCCCTGTCCCCTGCTCCTGTCCCCCCGCCCTGAGTGTCACACGAATAAACACCGACACTGAACTAG
->JF646645.1 Uncultured bacterium clone GDIC2IK01BM6IP 16S ribosomal RNA gene, partial sequence 
-GATCCTGGCTCAGGATGAACGCTAGCTACAGGCTAACACATGCAAGTCGAGGGGCATCATGTTGGTGCTGCAACCAATGATGGCGACCGGCGCACGGGTGAGTAACGCGTATCCAACCTTCCCCTTAGTAGGGGATAGCCCGGCGAAAGTCGGATTAATACTCTATGTTCTTCAATGCGGACATCTAAGTTGAAGCAAAGATTTATCGCTAAGGGATGGGGATGCGTCTGATTAGGTTGCAGGCGGGGTAACGGCCCACCTGGCCTACGATCAGTAGGGGTTCTGAGAGGAAGGTCCCCCACACTGGTACTGAGACACGGACCAGACTCCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGGCGCGAGCCTGAACCAGCCAAGTAGCGTGCAAGGACGACTGCCCTATGGGTTGTAAACTGCTTTTATCAGGGAATAAAGTGAGGCACGCGTGCCTTTTTGTATGTACCTGATGAATAAGGACCGGCTAATTCCGTGCCAGCAGCGGC
->GU634984.1 Uncultured bacterium clone HF9475 16S ribosomal RNA gene, partial sequence 
-ATTGAACGCTGGCGGCATGCTTTACACATGCAAGTCGAACGGCAGCACAGGGAGCTTGCTCCCGGGTGGCGAGTGGCGCACGGGGTGAGTAATACATCGGAACGTGTCCTGTTGTGGGGGATAACTGCTCGAAAGGGTGGCTAATACCGCATGAGACCTGAGGGTGAAAGCGGGGGATCGCAAGACCTCGCGCAATTGGAGCGGCCGATGCCCGATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCGACGATCGGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGGACAATGGGGGCAACCCTGATCCAGCCATGCCGCGTCGCAGGGATGAAGGCC
->MG192940.1 Homo sapiens isolate HD19_NN14_F4 T cell receptor beta mRNA, partial cds 
-GTTGTCTCCAGATCCAAGACAGAGAATTTCCCCCTCACTCTGGAGTCAGCTACCCGCTCCCAGACATCTGTGTATTTCTGCGCCAGTGGGAGAGGACAGGGGATCTACGAGCAGTACTTCGGGCCGGGCACCAGGCTCACGGTCACAG
->NM_001252006.1 Homo sapiens poly(A) polymerase alpha (PAPOLA), transcript variant 2, mRNA 
-AGTTCTAGAACGTTGCTGTGGTAGCGCTCGGGCGCCATGTTAGGACGAAGGGGAAGGAGGAGAAGCGCTTAAAGCGGCGGGAGCGGTGCGGGAGAGGGGTTGGACCCAGGGCTGAGGCAGGCCCCCCCCTCCCTCCCGCCTCAGTGGATCATGCCCAGGGCGGCAGCGGCGGCGGTTGCGGGGGGGAAGTGACTGGGCGGTGCCGGCGCCGGAGACGATGCCGTTTCCAGTTACAACACAGGGATCACAACAAACACAACCGCCACAGAAGCACTATGGCATTACTTCTCCTATCAGCTTAGCAGCCCCCAAGGAGACTGACTGCGTACTTACACAGAAACTAATTGAGACATTGAAACCCTTTGGGGTTTTTGAAGAGGAAGAGGAACTGCAGCGCAGGATTTTAATTTTGGGAAAACTAAATAACCTGGTAAAAGAGTGGATACGAGAAATCAGTGAAAGCAAGAATCTTCCACAATCTGTAATTGAAAATGTTGGAGGAAAAATTTTTACATTTGGATCTTACAGATTAGGAGTGCATACAAAAGGTGCTGATATTGATGCGTTGTGTGTTGCACCAAGACATGTTGATCGAAGTGACTTTTTCACCTCATTCTATGATAAGTTGAAATTACAGGAAGAAGTAAAAGATTTAAGAGCTGTTGAAGAGGCATTCGTACCAGTTATTAAACTCTGTTTTGATGGGATAGAGATTGATATTTTGTTTGCAAGATTAGCACTGCAGACAATTCCTGAAGATTTGGATCTACGAGATGACAGTCTGCTAAAAAATTTAGATATAAGATGTATAAGAAGTCTTAACGGTTGCAGGGTAACCGATGAAATTTTACATCTAGTACCAAACATTGACAACTTCAGGTTAACTCTGAGAGCTATCAAACTATGGGCCAAACGCCACAACATCTATTCCAATATATTAGGTTTCCTCGGTGGTGTTTCCTGGGCTATGCTAGTAGCAAGAACTTGCCAGCTTTATCCAAATGCAATAGCATCAACTCTTGTACATAAATTTTTCTTGGTATTTTCTAAATGGTATGTGTTTAGATTATATTAAAATAAAATTGATTGTAGACACTGAAGTTTAGTCTTATTTCTATGACATTTCTCAGCTTGGTTTCAGATTCAAATTTTAGTTCATGATGTAGTCATGTAGGCAGCCTTGGAGATCACATTGTGTATAAAATGGCAAACTGAAACTATTTTTTTTCCCTAGTTTGGCCAGGATAGTAAGGCAGATTCTATTTGTACTTCCTTGCATAAACTTACCCTCTGAATAAACTCTGAATTTTAGCAGCTAAGATCCAATTTATTGATAGGTTGGGAAATCAGTTACTATACTTTTGGATAAAACTTGTACACACTACCTCTTTCACTCTTTTAATTCTCTATCTATAGGCCATTAGTTTCTTGTGATTGTTTTTTTTTTCTTTTTGCTTTCAGCATTTATTTGGCCTAATATTAAAGATACGAATTTTCATAAGAAGCTTTTAAAGAATAAATTAACATTAAGTGCTTCGGGACAAAAAAGGAATTTGAGATTAGTCATTAACCCAGATTTTTTTAAGTTTCTTCGTTTCATTTCCACATATGTCAACTATGATTTAAGAAAAAGTAGAATAAAAGATTACTGCCATTTTATATTAATTGCCTTGGCCCAAAAGGTGAGGGTTCTTGGTTTTTAATCAAATTAAGATAAATCGTCCATTCCTGTTCTTATGAACTCCTGCTCCTCCCTCTGCAAAAGAGATGTTCTTTTCTAGTAATTTTATAAAAATTAGTTATTTGAGACAATTTAGAGCTGTGTTCAACTGGAGGAAAAATAAAAAAAATTTAGAACCATGCCACACTTTTCAGTACACATTCTGGCTGTTTTGGGATTTAGTAGCACTTATAATCAGGTGTGATAAGATTAAAGAATGTCAGAATTTCTTTTTTTTTTTTTTTTTTTTTTGTTTGAGACGGAGTCTCACTCTGTCACCCAGGCTGGAGTGCAGTGGCACGATCTTGGCTCACTGCAAGCTCTGCCTCCTGGATTCATGCTATTCTCCTGCCTTAGTCTCCTGAGTAGCTGGGACTACAAGCGCCTGCCACCACGCCTGGCTAATTTTTGTATTTTTAGTAGAGACGAGGTTTCACTGTGTTAGCCAGGATGGTCTCGATCTCCTGACCTCATAATCCGCCCGCCTCGGCCTCCCATAGTGCTGGGATTACAGGCGTGAGCCACCGCGTCCGGCTGTCAGAATTTCTTTTAATGCTACACATATATAAGCAAATAATGTTTTTAAGAAGCTAACCTTGATGTTAAGAGTGGCAGGTGTTCTCCAGTTTTTACCTCTTTCATATGGGACCAAAGTAGCTAGTTTATGGAACACATATGAAAATGTGGTTATGCCACCAAGTTTTACTACTACACTTGTCTTACCACTTTTAAGTCATGAATTCTATAATTATTCATACCCCTTTGCCTGTGATCAGAAGTAACTTTTAAAATTATCACTTGACTTTGGATGGAACTAGTATAAAGGCAGGAATTTTGTCTTTCAGTGGAGATTTATTCTGTTCAAGGTTGAAGTGGACACATCATTATCTTGGGATGGTACTTCTTTATTTAAATAGTCCTTTAAAGTTCTTTGAGTGGCAGAGAACGTTTTTGGTTTCAGTCTGAGAAGGCTACCAAATGGTTTAAGTTCATTTCATAGTTAGGAGAAAAAGATTTTGAGTAGTCTAATGTCGTCAGAAAGGATTAAAACGTTGTATGTACCAAGAAGGCAGAATGAAGAAGGATCACGTTCACAAATGCTGTATGTTTAACAAAATACGTTTAGATGGTAATATCCAATAGTCTTATCAAGTGCTACAATCTTTTTAAACAGGGAATGGCCAAATCCAGTGCTATTGAAACAGCCTGAAGAATGCAATCTTAATTTGCCTGTATGGGACCCAAGGGTTAGTGTATTATTTTTTCCCCTACCAATTCACACTGTGCAATAACAAGTAAAAATCATCTGCATAAACTCCAGGGAGACTTCCAGCCTTTTACTTATGAATGGTCATGTCCGTATTACACTTTCTTTTAGATAACCTCAACTATAATTGTCCTCAACTATAATTGATGTGAGAAGCATAATTATGTACCCTGTAAACCACATTTAATTGTACATAGTTTTTAATACAGATTTTACTAACATTTTAATTTATTCTATATAGAACTACCTTGTAAGTCAAAGTTGTGTGGGCATTTGTGCTTTAAAAAAAATAAAAGGATACTAAAAATCCCTGTATTTTTTATTTTATCTAAGTATTATGCTAAAGTTGGGTTGTTATAGGAAAGCTGTTACTTAATGTTTACATGTGGCATATAACTTCTAAGCATTTTCACTTTAATTACCATGATGTAATTGTAAAAAAAATTGGTTTAGATATTTTAGAGATTATAAAAACATGGTTGGGCTAAAGAAGACCTTCCATTCTGTTTCTTGGGAAGTTACAACATTTACCGCTTACTCATTTTAAATGTTAACAACATGCACTTTATAAACTGATAAAAGAAATTTAGGTTTGAATAAGATTTCCTAAGTTTATGAAATCCTTTTTTTCTAAATTATTACAATATCAAAAATTTTAAATTCTGTTGAATTACATCAAGCTATGCATTTTCAGGTTTTCCGAACCTCAAGGCATTTACTTTTAGAGGATGTGAATTTACAACTTACTTTGTGGAAATGTGCCACTTACTGATATACAGATTTAAAATTAACAGTATATCATTTCATTATCTCCTAACATATCAACATGGATAATGTAGTTTCACCGCGTGTTAATAAGCTTGAACTCCTTAATAGTTTCAGGGTATATTAAGAACTTAAGTTTCTATCTTGTTGAAAATTAGCTTACAAAACATTGTAGCATGACATGTCTCTAAAGGTAATTGTATGTGCATCCCCATTTCTGTTGTTGAATAAAGAAAAACTAAACATCAAAAAAAAAAAAAA
->XM_018797717.1 Schistosoma mansoni hypothetical protein partial mRNA 
-ATGGGTTGTGGTGCAAGTGGATTGAAAGATTGTAAATCAGAAGTAGCTCAATCGACAGATGACAGTCATTCCAATAATGCAGAAATAGAAGTTGAAGAACATAAAGAAACAGACACAAATCATACAGTTCCTGAATTATCAAGTGAACAATTGGATCCTGTATCGAACGATAGACTACATGATGAATCTAAAGAAGAAATTCCACAAAATCAAGAAATTCCAGAAGTTTCAGTGATTACTGAAGAAAAACCAGATGTAGATTTGGCAAATGATGCGGGACAACCTGAAGAATCCAATACAAATGAAGGAAATACATCAGAAAGCTAA
->XM_040902855.1 Laetiporus sulphureus 93-53 uncharacterized protein (LAESUDRAFT_536661), mRNA 
-GCAATCGGAAGATCACGCCTCACGAATGACCCGACCGTCTCATCGACGGTACTTGACTGACCTCTCCGCGCTGAGTGCGTCAATGCCGAATCATCGAACGCGCCGCCTCGTACCGAAACCAGACCGCGCGTCGGGGCCACGCCGCTGCGATAGAAGACGAAGACGTGCCTTGCGCTCACCGCTGATGCAAACGGACCGCGGCGTGGACCGTGATTTGACGCGATGCACAGCAGATGCTGGGAAACGGTTGACACGGTGAGCATTGCACTTCCCTACACACCTGCTACTAGATTCTTCGCGCGTACATGTCGACTAGGGCGGTCTCTACGCTCAATCGCCCTGTTCGCGTTGAGAATGCTGTCGACCTCGTTAGATGTGTGGATGACCAGAGCGTACCGAGACGCAGGCGAGATGTTGACTACGCGGATACTACAAATGACGAGGCGCACGACGAGAGACGGCCAAGACCGATTGCAACCGTCATTCGCGCTCACCCGCATCGCACTCGGGCTGGACATGCCCTCGTGCGCTCGTCGCCGTCCTGCTGTCCGTGGCTTTGGACTGCGAAGCAAGACAGCATGATCAAACAAGTGCGCAAGAGAAACGGGGGGATGGCCTACCGCATGCCAAAGCCATCATTTCACGCAGTCTCCTTCGCCAGAACACGCGCAGGACTGGCGCTTTCACGACAGGGCTTGAGGCTCGTGCCACTATCCAGCGACCGGTCGGAGATCACACCTGACGTCTCAGAAATACCCGCATCCGATGCTGTCTGATGCAACTGGGCTATTCCGGCGCACTTCAAGCGATATTCGAGCAACAGAAGCTGCGACGGTTGACTCGCAGGCCGCAGAGGCCGACCATGACCTGCCGCAGACGGTAGACCGACCTAGGAGAGCATCTCGCGTTTCGCGTGTGGTATAGAGG
->XR_002312254.1 PREDICTED: Odocoileus virginianus texanus uncharacterized LOC110131716 (LOC110131716), transcript variant X2, ncRNA 
-GGACGGCCCACCGCGGCCCTGCCCAGCTTCCAGCCACAAGGTCTCTGGCTGATGAGTAGGCGGTGGTGACACCCTGATGGCCCAGAGGCCGGAGCCCACTCAGTCACCCGGTCTGTGCACGGGCCTGTGTGTGTCCCTCCCCACAGGAGGGCTCGCAAATTAAGGGACTCCGGCTGGAGGAGGGCTGAAGGGGAGCCCTGTGCTTCTGTTTGTCGAGACTTTGCCCATACCATCGCAGCTCCAGCCCAGCTCTGTGGGAACAGCCTGTAATAAAAATAGAAATTATTGCTAATCAGGAAAATCCTCCCAGCCCAGCCATGCTCTTCAGCTACAAAACACCTCTGTTTTCTGGTATTAACCTTCTCTACTGCTACCCTCCAGTGTTTGCAGCCTCTATTCTGTAAGCAGGGAAACTGAGGTCCAGAGAGGCGAAGCAACGAGCTGAAAGCTACTGTGAGGGGCAGAGATGAAGCCAAGGTAAGGTCATTGCCAGATCTGTTCTAGTGGGAGGTTGCAGAGAAGTCACTGAGGGCTTCCTGGAGGAGGTGGCAAGAAATCTAAAGGAAGGAGGACTCAGATCAGGAGATAAAAAAGGTGAGGACAATTCTGGCAGAGAGAAACATGTGAAGCTTGAAGTTGGGGATATTTCAGCCACATTCGTTCGTTCCACAAACGCATTGACATCTGCTGTGTGCCATGTCCTCTGCAGGAGGCTGGGGACACACAGAGGACAAGCCAGATCGGGCTCCTCCCTAGTGGGGAGCCCACCTACATAATCGTCCCAAGGGACCGGCAGCAGTGGGAGCTCCAAGAGGGTGCCTGACTCAGCTTGGGGCATCAGGGGGAGTCTGGGGAGGGTTCTTAGAAGAGGAGGGAACACAGAGCTATGACCAGGAAGGTGAAGAGACCACAGTCAGATAAAGGCATTCTAGCTAGAGAAACAGGATGTGCAAAGGCCCTGAGACAAAAGTGTGTCTGGTCTGCTGGACAGATTGATCTCAGGGTAGAGAGATCTTGGGGCTCAGGAGAACGGGTACCAGGTGGTCCAGGGCTTGGGCTGTCTCCTGAGGGCAATGGGGAACCGCAGAGCATGCGTGAGGAGTGGTGGGTCTAGAGGGGGCGCTGAACAGAAGGAGCCAATCCCAACCTGGGCACTTCTAGTGAAGCCTGTCCCCTGATGCCTGTGGCAGGGCCGTGAGCTCACCTCCTGTTTCCCTTGGCATTCGGCACCCCTGGGGGCCGCTCCTGGCTGGTGCTGGGGTTCTTGGGAAAACCACGGCTCCAGGAGGGCCTCTGGGCTTGCGTGTGCCTCATGCAGCTAGGACAAGGGCACATGGAAGCCAAGCCCCTGCCACAGGCTTGGCATGGGGCTAGAAGTGTGGACACACATGGCCTTGTTCATGGCTGGGCCATGAGGAGTTGTGAAGAAGAACATTCTAGGCAGAGGGAATGGCGAAGGCGGCAGTCCTGAGGATGTCCCAGTCTGCGGATCAGACAACAGAGGCCTGGAGCCAGGCACTCTGGTTTCATGTTCCTGCTTTCTGGATCCCATTAGCTCTGAAATCCCACTTCTAGGCAGCAGCCCCCTCCACCCTTGCACACCTTGGCAGCCTCTCATTACACACTTACTCACTCTGGGTGAACTTCCAGCCCTTGTACCTGCTGTTCCCCACCATCCCAAATACCTTCCTCCTTCCTCCAAGATCTGGCTCTGATGCCCCCTCCTTCAGGAAGCCCTCCCTGCTCTTCTTGGGCAGGGCTTAGGGGCTGTGCGACATTCCCCTAAGATGCCAGAATATTTCTGGCAGAGACAGGATGACCTCACCCGGGGGACTGGGGATGTCTGTGTTTTGTTCTGTTCCCCTTTCCCGGGTCCCCCCTGGGCCTGCAGAGAGCCCTGCCCCGATGAGTGTCACATGGTTCTTAGTTCTTATAATTCATGTACCATCGTTACTATTAATAATAGTAACCCCTGCTACCGCTGTGCTTTATGACAGACTCAGGAGCCGCATGGCCTGGGTTCAAGTGTCAGCTGGGCATAGCCTCACTGTGTGACCTAAGGCAAGTTGCTTGACCTCTCTGTGTCTCAATCGCCTCACCTAGAAAGTGGGAGTGATCACTGCTGAGAGGACTGGATGAGCTCAGCGTCTACCTCCAGTGTTAGCCTCATTATACAATATGGAACTTATACACGATGTCGGTTATACCTCAGGCCGTTTTTACTCACATTTTCCTCAGAGAGGGAATGAGACAGCTCAAGGTCACACAGCCAGGATTAGACCTGGAGAAGGCAGGACCCCTGAGGCCTTCACACCACCCCTCTCTGCCCTTGGCCACAGATTGCAGGGGAGAAACGCTAACCCAGGCCCCTCATTAGCTGTGAAGACTGCTGCCTGGGACCTCCTGGCCTGAGCCCTTGGCTGGCGCCCCAGCCAGCCCCCCTTCCCACCACGCTAGACCCAGCGGTTCCAGGAGCCTGGCCAGACTCGGGCAGAGGGGCTGGTGCCTGTGTGATGAGGCCTCGGAGCCCTCCCTGGCAGAGTTCTGCTGGGCCAGGAGACATGTGGGCGCCCCCCGCTTGCCCAGCCGCCTCTCCTGTGAATCCAGAGGGAAAGTATGTCGGGAAGGCAGCCGCCCTGCCCTGGGCGGGCCCAGCCACAGGCTCAGGGTCTGGGGAATTCATTAGAGCAGCGAGGGAGGCCACTTAGCCACTGCTGGATCTGCGGCTGAGGAGCCTGACCCAGCCTGCCTTGGACGGCCCGGCTGGACCCTGCTCTCCAGAAGGACCAAGCAGTGGGGTGAGGGGCAGTGGGGCAGAAAGGGTGCCATCCGGGCACTGGAATCTGGCAGAACCCCCCGACTTGCTCTGTGAGTTCTGGCAAGCCCTGACTCTTTCCCCATCCTTCATTTGCTCTGACTGTGTCGTCATTTGCCTCAGGCTCTCCAAAAGGTATGATAAAGAAGAAAATAACAATAAATATAATGGCTACAATTTTATTGAGCAAGTGCCAAATGCTCGAAAACTTGCCACATCACTTTTGTGGGTTTTCCCTTTTTGTCCCCTCTCCTCACGGCGCCACGGGGCAGGAACTGACCATCATGGGAGACAGCAGGAGACTGCCAGGAAGTCTTGGTCTCTGGCACCAGGAGCCTGAGTTTCATATCCCACCTCTGCTGTGCAGCTTCAGACAAGTTGCTTAACATCTCTGTGCCTCTTTTCTTTTTTTCTTTTTTATGGGGTAGGGGAGGGTACCTTCAAAGGTAGATTTACTTTTAATAATAATGTAGATTTTTGCTTCTCCAGTTTAGAGAATGGACTGCAGAGTTGCCTCAGGGGAGAAAGGACTTCACTAGGAACCAGCTGGAATTTAATGATGTGGCATTCAATGGGCATTGACTTCTGAGAATGGTTTTACATCACTATTATCTTCAGAATTTTCCAGGGATAACTGTGGCTGGACAAATGACCACTTTACTTTTTCCTCCTCTCCTCTCACATTTAATGAGAGTTTTGTAGGTAACAGTAAAACAAACCAGTGTCTGTGTTGCAATAAGAGAGACTGCCTACGGGCTCACTATAGAAGTTTTCTTCTCTCCCTCAGTCTGTCTGTGTTTCTCTCTGTCTAATGAAGTGAAACATGAAAACGTCTAAAGTTGTTTGCAGTTTATCAGCAGCACTAAAAACCCAAGTGAAACGAGGACGATGAGAGCCCCAACCTCTGAGGCTCATCATAAAGCCCGAATACATTAATTCGTGAAAACTACACTCGGCACTTTTTTTTTAGAGATGGGACGATGGTGGTCTGAGCCTCTGCGCCTGGCGGTAGGTGACCTTGGAGGTGGACAAGTGCATACCAGCTGCGGCAGGAGCCCCGGAGTCAGGGAGACCACTCTGCCAGGGAATGTTAGTGTTGAGACCTGAACAGACAGGAAGTTCCCGTGAATCCAGGCATCCCAGGACCACAGAACAGGACGTACAGAACAGGGGGTCACAGAACCAAGGTCACAGCGCTGCGTCACGGCACTGTGAGTTAATGGAACCGTGGAACCGCAGCATGCTCCAGCCGTGGCACTGTGGGATCCTAGGGCCACGGGACCACAGTGCCAGAAGCCCACAGACTCAGGGGATGTGGCCACTATCAACAGGAGCTCAGAACCGTGGGATGGCAGAAGCCACAGAATCCTAGGGGGCCTGAGACACAGCACCCAGAAATCCCACTTGGGAGGTGCCATAAGATGGAGTCTCAGAACTGAGCCCATCAGAAACACCGTCTCAGCTCCACCTTCACCTGTTGGCTGGCCAGCGAGTCTCTCAGAGGCCACGGGAGCTCGGAGGCACTCTCTCTCCATCCCTGGGGCAGCCACCGGAGAGAAGGACCATGCTGTCATCAAGGCCTGGAGCCAGCCAGCCGCCAAACACTCAGCGAGTCCCCTGTTGCCAGGGCCAAGTGAGGCTGTCCGGGTGCCGAGAAACAGTGCCAGCCTCCGGCCAGGCGCGCCGGGACGCCGAGTGCTCAGCAGCAAGTGGAAAAAGAATCAACGGGTTCCTTCTACATCCACATCCTCTTAAAAGCCAACAGAAACATGACTCGGAGGGGAGGTTGTACCCTGGCTGCATTGCCTCCGGATGGCGGCAACGGGAAGCAGCCCCCCAGCACTGCCTCCGCCCACGCCAGGAGTCACAGCCCGGCTCAGGTTGCACCAGACACATCCGCGTACTAATGAACTCTCCAGGGACTGTTCACCCAGCAGACCTGACACCTGATGCTCAGAATAACCAATCTGTTTTGGAGAGGGGAGACTGAGGCCCAGAAGTGAAGACTCCTGGCCCAGATCACGAGGGTGAGAGCTGAGACCCAAACCCAAGCATGATGGATGCTAAGAGTGAGCTTGCCACCACCCAAACGGGCTTGCTCTCGGGCTTCCCCAGCCCCATCCTGTTTCTAAATGTGATCCAGCATGGAAGGTGGGAGGCTGGGCTTCGGCAATTCCTTCCCTTTGCCGAACCCAGATCCTCTTGTTCACGGGGCTGCCATGGGGACGAAACATGATCGTGGTGAGTGCTCACTGGAACCTGGTATTGCTGTCATGAAAGGACTT
->XR_005956344.1 PREDICTED: Pyrgilauda ruficollis uncharacterized LOC121361499 (LOC121361499), ncRNA 
-CGCCTCAGGCCGGGATATGCCTGGATGGGGCAGTCCTGGGATGTTGGGGGCTTATCCTGGAGATCGTCTGGTCACAGCGCCCGCTGCCAGGGGAGTAGTTCTGCTGGTTGCTGCCATGCTCCACAGGAGGAACTCAAAGCTCTGGCTAGGATTTTTTTGCAGAATTCTACAGTCATTGCATCCTGGTGGAGAACGCAGGGATTCCTGTTACACTGCTAGCACATAGAAAAATTCCTGGAGGAATGCCACAGGTTGCTGCTCTGCATCTGCTCAGAGAATCAACTGTGCCCAAAGCCATCAATTTCCCCCAGCAGTTCAATGCACAGGAAAACTACCTGGAACTTGTATGTTGCAGTAAGTCATTGAGAACTTGGGGGTTTGTGTTCATCCTAACACAGACATGTGATGGCAGCTGTGAAAATAAGTGCAGTTCCCCGGAGGCAAAGCAGTGCTATGTTTGTGCTGCAGCAGCCTGGGCCAGAGGAAGGTGAGAGAAACCACAGTGGGACAGGTGAGGCACCAAAAATGCCTTTATCTTACCTGTGGCCTTTTGGACAAACTCCAGTTGTATCAACCCACAGCATCAGACAAAGCTGCTTTTAAGAACACTGATGCAAAAATGAGATCTTGGGTGATCATTTCTGGTTCAAGTAGCGGTTTATATATTTATTATAATTATACACAACCTTGACAATCTGTATTGCCATTCAAAAATAAATCCAAGTCTTGTCAA
->XM_003890613.1 Puccinia graminis f. sp. tritici CRL 75-36-700-3 hypothetical protein (PGTG_20695), mRNA 
-ATGGCGCAGCCATCAAGTCCGTTGCTCCACATGCGGCCTCCAAACAGCATATCTCTGCCCACATCTTTCTTAAACATTTTTCTTTCTTTAAGCAGTGACGCCACCTCCCTCAACAACACAAGCAAACTTGCTCTTGGAGCAAGCTCCCACTCTAGTCACCATGATGATTCTGGCGAAACCGTCCTACCTCAGCCCGTGATTTATATCATCATCGCAGGGATCGCTTTAGCAGTGATATTGGCGGGATTTGCGATGTGGTCATGTGTTCAAAAGCGCAACAGACGTCGTAGCCGAAAGGCATCATTCTCGATGTCCCAAGCTTCTGAAAAAGAATGGGGCACCACTCGCGAGATGGCTGGCGGCATGGAGAGCGTTTACCGGCACTCCGTCATCACCTATGACGCCAAGGCTCAACCCAAGCTGCTCTATGAAGACTTGGATTTCGGTCCAATGGTCACCTCGCAACTTCCAAGTCAAAAAGAACTGAATCAATACAAGAAAGATACCATCGTGTGTCTAACCGACGTCTATGGAAGTACCAAAGGATGGGACGGCTCAGAATTTGACTATATGTTAAACTCGCCAAATCAATTCCCACCTGCGAGAAGCAGTCCCGATCTCTTATCCTCGCTTCCCAAAGCACTTTTAACTGGGAACCATACGGGTCGACAACCGGCTGTCCCGGGGTTTCGCCCATACCGGTCACCATCCGGCCAATTGATGGTCAAGCCGTTCTCTTCGACCAAAATGAGCCCCGCTGAAGCCTCTAACGAGCTGCAAAAGATCATCAACGCGCATGCCAACCTTGAGAACTTCGATGACTTGTTCGACCACGGCGAAAGCTTCGATTCTTCCAACCTCACAAACTCCTTTGATGGCACTCCAATCCATTCAAACCCTGAACATTTCCCTATCCTCTTAGGTAGCTTCCCTGCTGCCCGTAAACTCTCCTCTTCCTTCTTACCCGGCGCTGATAAAAGCTTGCCCAAAGAAATCGTCCAACTTCCCCTTCCCCGGTATAACTTCAAGCAAACCACTGCTTGA
->XM_051686607.1 PREDICTED: Myxocyprinus asiaticus autophagy related 9B (LOC127434116), transcript variant X2, mRNA 
-CGTCGAGCGATGTTTGTTGTGATTTCTGTTATTGTTGTGAAGCGCAAAGGCGAAGATCATCGTTAGTCGGATGGATCTATGGTGAACATCATAGAGAGGTAGAATGTAAAACACGATGGCTGATTTTGAAACGTATCAGGAGTATCAGCGTATAGAAGACTATGATGAAGACTCACCCCAAGGAGAGGAAGACTTACTTATTCATGTGCCAGAGGGTAGAGGAGACCCATGGCATCATATCAAGAACCTCGACAATTTCTTCACAAGAATCTATCATTTCCATCAGAAGAATGGATTTGCCTGCATGGTGTTGTCAGAGTTTTTTGAACTTGTGCAATTCCTGTTTGTGGTCACGTTTACAACTTTCCTCTTCAACTGTGTGGAATATGATGTTCTCTTTGCCAACCGAGCGGTCAACCACACGGGCCAGAGTCTCGGTCCCCTTGACAGAAACAAGGTCACCCTTCCTGATGCTATTTTACCCAGGGAGCAGTGTACTGAGAGGATTGAAGGCAACAGCTGGATCATATTTCTCTTGATAATGGCAGCCATTTTTTGGGTCTATCGGCTCGTGAAGGTGATCTGCAATGTCCTCAGCTACTGGGAGATCCGGCAGTTTTATATTAAAGCACTCAAAATACAGATGGACGAGTTGTGTAACTTCTCATGGCAAGAAGTTCAAGGCCGTTTGATTCACCTGCAGCGTGAGCAGCCCATGTGCGTCCAAAAAAGGGAACTCTCCGAACTGGACATCTACCACCGCATCCTACGCTTTAAAAACTACACCGTCGCCATGATCAACAAGTCTCTGCTGCCCGTCAGACTGCGCGTGCCCTTTTTCGGAGACATGATTTTCCTCACGCAGGGCCTAAAGTACAACTTTGAACTTATTCTTTTTTGGGGCCCCCTCTCGCTTTTTCAGAACAAATGGAGTTTACATCCCAAGTACAAACGAGCTGCGAACCGCCAAGAGCTTTCGAAACAGCTCAGCCGTGTTATATTGCTAACTGGCATGGTCAATCTTCTGCTTTGCCCATTCGTGGTGGTGTGGCAGGTGTTGTATGCGTTTTTTAGCTATGCCGAAGTCATCAAACGGGAGCCAGGCAGTTTGGGTGCGCGCCGCTGGTCGCTGTACGGCCGTCTTTACCTGCGACACTTTAATGAGCTGGATCATGAGTTGCAAGGCAGGCTGGGTCGCGGATACAAGCCGGCCGCTAAGTACATGAACGCCTTTGTTTCTCCCCTGTTGACGGTGCTGGCGAAGAATGTGGCTTTCTTCTCCGGCTCAGTGCTGGCTGTGCTGATTTTGTTGACAGTGTATGACGAGGACGTATTGACGGTGCAACACATCCTGACGGCCATCACTGTGCTGGGCGTGGTCATCACGGTCTCCAGGTCATTTATTCCAGATGAACATATGGTGTGGTATCCTGAACAGCTGCTGCAGTGTGTCCTGGCCCATATTCACTACATGCCGGATCACTGGAAGGGCAATGGCAACAAGAGCGAGACTCGCGACGAGATGGCACAGCTTTTCCAGTACAAAGCGGTCTTTATCTTGGAGGAGCTCCTCAGCCCCATAATTACCCCGTTCATCCTCATCTTCTCCCTAAGGAACAAGTCTCTAGAAATCATCGACTTCTTCCGTAACTTCACAGTAGACGTTGCAGGAGTAGGTGACATATGCTCATTCGCTCAGATGGACATCAGACGGCATGGCAACCCACAGTGGATGTCCGAGGGTCAGACGGAAGCTTCGGTGTACCAACAGGCTGAAAACGGCAAGACAGAGCTGTCTCTGATGCATTTCACCATCAAAAACCCTCACTGGCAGCCGCCGCAGGAGAGCTCTGTGTTCATCAGTCACCTGAAGGAGAAGGTTCAACAGGATGCACAGACAGGACCATCTCCTCAGCTGCTGCTGTCTGAAGCACCTCTTTGTACCTCACTACTGTCTAATGAGTCTGCCACTGGTCCTGATAACCTGTTAGCCAGCGTGTTGGCTCACCCCGTACTGACTGCATCCGGACTGCCTGGATGGAATCATCGTTTTATCCCACAGAACAGCGCAGCCTCAGCAGCCGCCAGCGTTCTGGCGTCCCTGTCTTCATCCCAGCAGCCCCATGCTGGGCGTTCACGTTCACACACTCTCCTACCCTCCAGACAGCATCAAGATGGCCCTATGTACTACAGTGAGCACACTGTGGGCGACAGGCCTGCACCCCTGAGTCTTCTCTTTACTGTTGCACATGAAACTGGTGTTGAGCGGGTAGAATTCAATGAAGCTGTCAGCTGAGGACATCATGTCCGCAAGTGACTCCAAGATGCTCAGCCAGTCCAAATCAGCCCTTGCATCAGAGTTTGCATCTGCTGAGATGAGCCTGCATGCTATATACATGCACGAG
->XM_028933362.1 PREDICTED: Prosopis alba uncharacterized LOC114745209 (LOC114745209), transcript variant X1, mRNA 
-ATCAACGGCCAAGTTCAGGACCTCAATTTCAATTCTCCTCCCACCAATTCCCACTAATTGAAGCCCAACTAAGGCCAATATGGGCGCGGCGGCCGGCGTCGGAGGCTACCCTGTCGGACTGGACGAGTCGTACCGGCCACTTCCGGGGCTTTACTTCGCCTTCTTGTCCATCTGGCTTCTCTCTGCTTGCTCTTGGACTCTTAATACCTACAAAAAGCGCCAGTTTCAGTCAAATAATTTGCAGTGGGCACTAACCTCAGTTCCCTTTATAAAAGTATTGCAGCTCCTGCTGTCCTTTCTCTTCTGGTATTCATGCTTCTATTTTCAGGCATGTTCCTTGTGGATGTCATTTGGGGTGTATGTAACTGGGGTGCTCTTTCAGACTGCTGCCTTTGTCTCCTTCTTGCTCATTGCTCATGGCTACTGTATCATGTGTGAGCATCTTTCTTTAAGTGAACGCCGTACAACTGCTGCACTTGGATGTGTCTTTTACTTAACGCTAGTGGGTTACAAAGCTTGCGTACCATACTTCACGGTTCTTCTGCTACTGAATTATTTCATTTCATTCTATGTTATTTTCCGGCATATATCACAAAACCTATTGTTGTTGCGGGAACAACTGAGTATTGTTGAAAATGAAGATGTTCGGACAATGCATGATGCTCTGTATACGAAGTACATGATGTTCAAGAAATTCCAGGTTGCAATGCAGATAGTAGCTATGGCAGAAACTATGATATACATGAACATGGATGACTCTTCAGAGAATTACTGCCTTCGGTTACTAGTCAGAGAATGGGCACAATTCTGCATTTTTTCATACATTGGGTGGACTTTCAGGTCACAGGACTTGGCGCCACGCTTCTCTGTTATGCCTGCCACCAAGTGTAAAGGCGATACTTTGGTGCCTCCCATCTACAGTATTGAAATGGATGCCGCTACTTTTAAAGATTTCAGTAGTCATGAATGGCACATTGGGGTGCCAACTTCTGCTTGCCGTGATGAAAACTCAGAAGGTGCAGTTCTAGTGATCATTGAACATCCCCACTCACAGAGGCTAAGAACGCCTGATACTTCCTCTTCTCCTATTGTGTCAAATCTCATTTCACAGACATCTTCATACCGAATATAATCAATCAACATTAGCTCTACCATCTAGTCATCTATTGGTTGCCCATGCCTTTTCTCCTGCAATCTGGCATGGGCATGCCAGTACACTCACTGCTTCCGGGTTTAGAAGGTAATTTGAACGTTTCAAGCTGAGAGGAAACAAGAAGAGTAGAAGTATATATTGGGTATAGTCTCCCCTCTTTTTCTTTTTCTTACCAACTCTTTCTTTCTTTGTTTCTTTCCTTTTTTTTTTGCCCTCTTCTTTTTTAAATACTTTACAAACTTTTGCTTTAGAAAATGCCATGAGTTAGTCATGAGCTGAGGGTAGAATAATGAGTGTTATCTTGTTTAGAGGCAACCACAAATATGTATTCTGTACACCATCGAAGCAAATGGTAACTGTATATTGTTCTTCCTTGTACTGTTGTTCTCTCATTGATTATTTCCGACTT
->XM_003035727.3 Schizophyllum commune H4-8 uncharacterized protein (SCHCODRAFT_02607625), mRNA 
-ACCACCATGAGCTCCAGCGACACCCAAGAGCGACGCTGCTGTGCGATCTGCTCCTATCCTGCGCCCAGCCAATGCTCTGGCTGCGGACAGGCGTTTTACTGCTCGAAAGAGCATCAGACACTGGCGTGGTCTAAACACAAGCGTCTATGCAAGATCTATCAGCGCCAGGCTCGAGGGGAGCCCGTCCCTTCCCCAGATTCCTACTGCGGTCTGTGCGGGAAGGAGAACGGGCCGCTCCGTCGGACAGAATGCTGCAACAGAACTATCTGCGACGACTACGGGAACTACACGATGTTCTCGTTCAGCGCCAACAGCTGCTCCCGAAACCATGATCGATATACGCGCTGCTGCTACCATTTCAACGAAGGTCACCCCGGCAGCGACCCTCTGCAGTGCACTAAGTGCTCTACTAGCCACGACGCGGAGAAGGAAGCGTGGTACATGACGAACAATTACAACTTCCAGGAGGACATACTACGGGCCAATCCGGCATCCTTCGCACCAAAGCACTGCACCGGGTGCGGCAGGCAGGTCAAGCAGAATGCCGAAGCCGTTTCGTATGGGCCAAGTGGTCTGCAGTGTGGCCGATGCACGGAGAGGATGGCTCCTTCTGTGCTGCCTCAAGATACTTACCAGTTTGACTCTTGAAAGGTAGCGACGTACGCGCCAATGTAATACCCTGATCTATGTTTGTGACCAAGAGGTTCATATCATCAGAGTCGACGCAACGAAGTGCGCTCGTTGTAAGTAATCATTTCAAGAATGTTGCAGCGCATACTGTATATTCGCGAGCGCGGGAACAGGTAGAGTTCATGAAAATCCTATCTCAAGTACTGGAAACATGTACTACGGCGCTGGATCTCCTTGTCGTCATCACAGTCCGATGTACTTATGTGTGTAATGGGCCCTTTCCCTTCAC
->XM_019346602.2 PREDICTED: Oreochromis niloticus filamin-C (LOC100698591), transcript variant X4, mRNA 
-CTTTTTAATCGACTCAACCCACTAGAATCATCACTGTGGACATTTTTTGTGTATAAAGACTATTTATATGTGTTTCTGTACAGCCAGGCTGATGTTCAACACAGCTGGGATAAAACCAGCAGCTCTTATAAAGCTCTAACTGCACACATCTGTATGTGATTATTGCAGAGCTGATCTTGGGCTTCACTCTGGGTCAAGTTCAGCTTGTTTCACGTAGAAGCAGACCGTGCTCAGCAGGGGGCGCTGCTGTTTACGTCAGTAAATCTCTTCAGTTTGTTTTATTCTTCAAAAAACTTGTATTAAACGCAGCATGAAATTTTTCTTCCTCTCTCGCTTGCTCCAGTTTGCCGCGCCTCCATTTGCCTCCATTTGGCAGCCAATGGAATTGCAGGAAGCAGCAGCACCTCATTCAGTTAACTGTAAACACCCAACCTCCATTGTAGTTACCATTAATTGTCATTAATCATTATCACAGAGTCTATTGTATTTTCAGATCTGATATGTATTTCCAAACTGAAGTAAACTTCGATGTTGTTTATTTCTGCTTTGTTATTTAAATGTCACGCAGTGATTTGATTGGCTGCCTGATGGTGATGTCATGTCCCTCCTCAGGGTGTCTCTCCAGGTTTGAGGACTAAAAATACCCGGAGGTGTCAGAGCGGCTGTGGAGCCCCGGGTCCGGCTGTCGGGGTGGGGTAGGTGGGGGTGTCCTGGTTGGGGTATCCAGCGTGTCTCCACCCCCTGCTCCGCGCCCGACCAATGATCTGCGGTCTCGGTGTCCTGCGGCTCGGAGGATGCCCGGGTCGCAGTAGTATATGGTCATGGCAGGGGCATTCCTGGAAGTCCTGCGCAGTGACGCCGAGCCTTTAAACCTCGCTTCACGCTCCCGCAGCTGCACAGCCCCACTCTGTCCACGCCGCCGCCCGTGCGTGACCACAGCCAAGCCAGCCGGAGGACAAAAGCAGACTATTCTTCACTCTTCCTCCTGAGCCTCCTCTTTCTCTGAGAGTGTGAGTCCGCAGGAGTGCCCGCGGGTCTGCATGCGCGCCTCTTTACGCACAGCTCCGTGAAGCTCCCTCCCCGCGCGCTGGGCACTGCCCCTCCGCTTCCACTGCCCCGTTTCTCTTTTTTTTCTGCCTTTCCTTCTCTTCCCACTGCGCTCGGTGCTATAAAAGGCATGTCCATGATGAGCAACAACAGCTACTTGGAGCCCCAGCAGTTCTACCAGAGCACCGCGGACATCGGCGAGGAGGAGGAGGAGGAGGAGATGCCGGCCACCGAGAAGGACCTGGCCGAGGACGCCCCGTGGAAGAAGATCCAGCAGAACACCTTCACCAGGTGGTGCAACGAGCACCTGAAGGTGATCAACAAACGCATCAACGACCTGCAGAAGGACCTGAGCGATGGGCTAAAGTTAATAGGGCTGCTGGAGGTGCTGAGCCAGAAAAAGATGTACCGGAAGTACCACAGCAGACCCAACTTCAGGCAGATGAAGCTGGAGAACGTTTCCGTGGCGCTGGAGTTCCTGGAAAGGGAGCACATCAAGCTGGTCTCCATCGACTCCAAAGCCATCGTGGATGGGAATCTGAAGCTGATCCTGGGTCTGATCTGGACCCTGATCCTCCACTACTCCATCTCCATGCCCATGTGGGAGGATGAGGATGACGAAGACGCCAAGAAACTGACTCCTAAACAGCGTCTGCTGGGCTGGATCCAGAACAAGGTGCCCCAGCTCCCCATCACTAACTTTCACCGAGACTGGAGGGACGGCAAGGCGCTGGGAGCTCTGGTGGACAACTGTGCCCCCGGTCTGTGTCCCGACTGGGAAACATGGGATCCCAGCCAGCCGGTGGAGAACGCCCGGGAAGCCATGCAACAGGCTGACGATTGGCTGGGAGTGCCACAGGTGATTGCTCCTGAGGAGATCGTCGATCCTAACGTGGATGAGCACTCTGTCATGACCTACCTGTCTCAGTTCCCTAAAGCCAAACTGAAGCCCGGTGCCCCCTTGAGGGCCAAATCGCTACACCCCAAGAGGGCTAAGGCCTACGGACCAGGTATCGAGCCTCGAGGTAACATGGTTCTGAAACCAGCAGAGTTCCTGGTGGAGACAGTGGAGGCTGGACTGGGAGAAGTTCTAGTTTATGTGGAGGATCCAGAGGGACACACAGAAGAGGCCCGAGTCATCCCCAACAATGACAAGAACCGAACCTACTCTGTGGTCTACCTGCCCAAAGTGGAGGGGCTTCATAAAGTAAAGGTGTTGTTTGCTGGTCAGGACATCGACAGAAGTCCCTTCATTGTAAATGTTTCAAAAGCCATGGGCGACCCAACCAGAGTCCAGGCCCGCGGGCTGGGACTGCAGCCAATGGGAAATGTGGCCAACAAACCTACATACTTTGATATTTACACTGCAGGAGCGGGTGCTGGAGATGTGGGCGTCATCATTGTGGACTCAAATGGCCGCAGGGATACAGTGGAGATTGTCCTGGAGAACAGAGGCGACAGTGTATTTCGGTGCACCTATGTCCCTGTCCTGGAGGGGCCTCACGTCGTCTGTGTGACTTTTGCTGGGCAGCAGATTCCCAGGAGTCCTTTCACTGTCCACATCTCCGAAGCCTGTAACCCAAACGCCTGCAGAGCATCTGGCAGAGGTTTGCAGCCGAAGGGTCTGAGAGTGAAAGAAGTGGCAGATTTCAGAGTTTACACCAAAGGAGCCGGCAGCGGGGAGCTCAAAGTCACCGTTAAAGGACCAAAGGGCCTGGAGGAGCCGGTGAAGGTGCTTGAGATGGAAAATGGCCTGTATGAGTGTAATTATTACCCCATCATGGCAGGAAAGTACATCGTAACCGTCACTTGGGGCGGACACAGCATCCCTCGCAGCCCATTTGAGGTTTATGTCAGTGAGGAGGCAGGGCTTCAGAAAGTGAGAGCCTGGGGTCCAGGTCTGGAGACCGGTATGGTCGGGAAGAGTGCTGACTTTGTGGTGGAGGCCATTGGAACTGAAGTGGGAACTCTCGGTTTCTCTATCGAGGGGCCCTCCCAGGCTAAGATTGAGTGTGATGATAAAGGCGATGGATCATGTGATGTTCGATACTGGCCGACTGAACCAGGCGACTACGCCGTCCATGTTGTTTGTGATGACGAGGACATCAAGGACAGTCCCTTCATGGCCCACATTCTCCCTGCTGCCAGTGACGTCTTCCCTGAGAAGGTGAAATGTTACGGTCCAGGTCTGGAGCCTTTGGGCTGCATTGTTAACAAACCTGCTGATTTCACCATTGATACCCGTGGAGCTGGCATCGGAGAGCTGAAGCTCTATGCTCAGGATTCAGATGGTTTCCCCATCGACATCCAGATCACAGATAATGGAGACAGCACCTACTTCTGTGTTTACATTCCCACAAAACCCATCAAACACACCATTATCATCACCTGGGGTGAAGTCAACGTCCCTAACAGCCCGTTCAGGGTGACTATTGGAGAGGGCAGCCATCCAGAGAATGTGAAAGTTTATGGTCCAGGTGTGGAGAAGACAGGACTGAAGGCCAACGAGCCGACTTACTTCACTGTGGACTGCAGTGAAGCCGGACAGGGTGATGTCAGCATTGGCATCAAGTGCGCTCCAGGTGTAGTTGGACCTGCCGAGGCCGACATCGACTTTGACATCATCAAGAACGACAATGACACATTCACAGTGAAGTACATGCCTCCAGGTCCCGGACAGTACACCATCATGGTGCTGTTCGCTGATCAGGAAATCCCTATTAGCCCCTTCAGAATAAAGGTGGATCCTTCCCATGATGCAGCCAAAGTCAGGGCAGAGGGACCTGGACTCAACAGGACAGGGGTGGAGGTGGGTAAGCCCACCCACTTCACCATTTATACAAAGGGAGCTGGTAAAGCCAAACCCGAGGTCCACTTCACCGGAGCAGCTAAAGGTGATGCCGTCCGAGACTTTGAGATCATCGACAACCATGACTACTCATACACTGTCCGCTACACGGCGGTGCAGCAGGGGAGCATGTCCATCATTGTGTGTCACGGAGGAGACCCCATCCCAAAAAGCCCATTCACCATCGTTGTGGCCCCCCCACTGGACCTCAACAAGGTCAAAGTTCAGGGACTGAACAACAAAGTAGACGTTGGGAAGGATCAGGAGTTCTCCGTCTGTACTCGAGGTGCTGGAGGTCAGGGCAAACTAGACGTGAAGATCACCTCCCCTTCGCGTCGACCAATCCCCTGCAAGGTGGAGTCGGGGACAGCCAATGAGGTTCATACAGTGAAGTACATTCCTCCCGAGGAAGGACCATACAGAGTGGACATCAGCTACGACGGGAATCCTGTCCCAGGGAGTCCATTCACTATGGAGGGTATCATGCCCCCTGACCCTTCAAAGGTGCGAGCCTATGGTCCAGGCCTTCAGGGTGGTGTGGTAGGCAAACCAGCCCCCTTTGCCATTGACACAAAGGGTGCTGGTACTGGTGGTCTGGGTCTGACAGTGGAGGGGCCGTGTGAGGCCAAGATTGAATGCCAGGACAATGGTGATGGATCCTGCTCTGTGTCCTACCTGCCGACTGAGCCTGGTGAATACGCCATCAACATCCTGTTTGCAGACCAGCACATCCCCGGTTCTCCCTTCAAGGCTGTGGTCCAGTCAGTGTTTGACCCCAGCAAGGTGACAGCCAGCGGCCCCGGGCTGGAGCGAGGCAAGGTCAACGAGGCTGGAACCTTCACGGTGGACTGCTCCAAAGCCGGGGAGGATGAGCTCACCATCGAGATCATCTCTGACTCTGGGGCCAAAGCTGAAGTTCACATTCAGAACAACAGTGATGGGACCTACTCCATCACATATATCCCCCAGTGCCACGGGATGTACACCATCACCATTAAATATGGAGAACACATGGTGCCAAAGTTCCCCATTCGCTTGCAGGTGGACCCAGCTGTTGACACCAGCGGGGTAAAGATCTATGGACCGGGAGTGGAACCCAGAGGCGTCCTGAGGGAAGTAACCACTCATTTCATCGTGGACGCTCGAGCTCACTACAAGAGCGGTGGCAGCCATATCAAAACCTCGATCTCAAATCCGTCGGGCACCAACACAGACGCCTACATCACCGACAAGGGAGATGGGACATACAAAGTCGAGTACACACCCTACGAGGACGGTTTGCATCTGATTGAAGTTCTTTTGGATGACGTCTCGGTGCCGAAGAGTCCGTTCAGGGTGTCCGTGAGCGAGGGTTGTGATCCCAGTCGAGTCCGAGCCTACGGTCCAGGTCTGGAGGAAGGACTGGTGAACAAACCAAACCGATTCACTGTTGAGACCAGAGGTGCTGGCACTGGGGGACTTGGCCTGGCCATTGAGGGTCCATCAGAGGCAAAAATGTCATGTAAGGACAACAAAGATGGCAGCTGCAGTGTGGAGTATATCCCCTTCACGCCTGGAGAATATGATGTCAATATCACCTTTGGAGGCTTACCGATCCCAGGGAGCCCGTTCCGGGTCCCAGTGCGAGAGCTGGTTGATCCCAGTATGGTGAGGTGTTCAGGTCCTGGCCTTGGAAGTGGAGTCCGGGCTCATGTTCCTCAGACTTTTACTGTAGACAGCAGCAAGGCAGGGGTGGCTCCCCTGGCAGTTCAGCTATATGGACCAACAGGTGTAGCTGAGCCCCTCAACATCACAGATAATGGTGATGGCACTCACACGGTCAACTATACTCCTGCAAACGATGGCCCATATACAGTGTGCGTGAAGTATGCCGACCAGGAAGTGCCCCGGAGTCCTTTTAAAATCAAGACATTACCGGCTCATGATGCTAGCAAAGTTCGAGCCAGCGGTCCCGGACTGAATGCATCCGGGGTTCCAGCCAGCCTGCCAGTGGAGTTCACCATTGATGCCAGAGATGCTGGAGAAGGACTGCTCACCGTCCAGATTCTGGGTCCGGACGGCTGCAGTCGCGAGGCTTCATTGTTTGTGGAAGACTGGGGCAGGAGGGTGTGGGAGACTCACATAGTAAAGAAAACCATCCCCTTCAGTATTCTTAGGAGAGGCTCTGATCCAGAGGGAAAACCCAAGAAGGCGACCATTCGAGACAACAGAGATGGGACGTACACAGTGTCCTACGTGCCGGACATGACGGGGCGCTACACCATCACCATCAAATACGGAGGAGATGAGATCCCGTACTCACCTTACCGGATCCACGCCCTGCCCACCGGAGACGCCAGCAAGTGTCTGGTCACAGTGTCAATCGGAGGACACGGACTCGGTTCAGGAATTGGACCAACCATCCAGATCGGAGAGGAAACTGTCATCACCGTGGATGCAAAGGCTGCAGGGAAAGGTAAAGTCACCTGTAAGGTGTCAACGCCGGACGGAGCGGAGCTGGATGTGGATGTAGTGGAGAACGCAGATGGGACGTTCGATATTTATTACACGGCTCCAGAGCCAGGGAAGTACGTCATCACCATCCGCTTCGGAGGGGAACACATTCCCAACAGCCCCTTCCATGTCGTGGCAAGTGATACCATCCCAATAATAGAGGAACCATGTGACAAGCTTCAGTTACAGCAGCCCTACTCTCCCTATGCGGCCTTCTCCCCTCAATGGGCCACCGATGATCCCATCAGCCCTGTGGACGGGCTGGAGCCGATGCTGCGTCCCTTCAGTCTGGTCATTCCCTTTACGGTGCAGAAAGGAGAGATCACAGGTGAAGTCCGCATGCCTTCCGGCCGAACAGCCCAACCTAACATCACCGACAACAAGGACGGGACAGTTACTGTGAAGTACTCGCCAACTGAACGAGGCCTCCATGAGATGGACATCAAATACGATGGCAACCACATCCCAGGAAGTCCACTCCAGTTCTATGTTGATGCTATTAACAGTGGTCATGTGACAGCATACGGTCCCGGCCTGAGCCACGGCACCATGAACCGACCAGCCACTTTCACTATAGTTACAAAAGATGCTGGAGAAGGAGGTTTGTCTCTGGCGGTTGAAGGTCCATCCAAAGCTGAGATCAGCTGTAAAGACAACAAGGACGGGACGTGCACAGTGTCCTACCTGCCCACGGCACCTGGAGACTACAACATCATCGTCAAGTTTGATGACAAACACATCCCTGGCAGCCCCTTTACCGCCAAGATTACCGGTGACGACTCTATGAGAACATCCCAGCTTAACGTTGGCACGGCAACAGATGTTTCCTTAAAGATTATGGAGACAGACCTGAGCAGCCTGACCGCGACGATCAGAGCTCCGTCAGGAAACGAGGAGCCCTGCCTGCTGAAGAGGCTGCCCAACAGACATATCGGAATATCCTTCACACCAAAGGAAGTTGGTGAACACGTGGTCAGCGTGAAGAAGAACGGGAAGCATGTGACCAATAGTCCGTTTAAGATCATGGTGGGTCAGTCGGAGATTGGAGATGCCAGCAAGGTGAAGGTTTACGGTCAGGGGCTGGTGGAGGGACACACGTTCGAGGTGGCCGAGTTCATTGTGGACACGAGGAATGCAGGTTATGGAGGTCTGGGTCTGTCCATCGAGGGTCCCAGTAAGGTGGACATCAACTGTGAGGACGTGGAGGACGGGACATGTAAAGTCACCTACTGTCCCACAGAACCAGGAAACTACATCATCAACATCAAGTTCGCCGACCAGCATGTGCCAGGAAGTCCGTTCACGGTGAAGGTGTTTGGTGAAGGTCGGATGAAAGAGAGCATCACCCGGAAACGTCAGGCACCCTCCATTGCCACCGTGGGCAGCACGTGTGACCTCAACCTCAAAATACCAGGAAACTGGTTTCAGATGGTTTCAGCTCAGGAGCGTTTGACCCGGACATTCACCCGCAGCAGCCACACCTACACCCGGACCGAGCGGACAGAGATCAGCAAAACCCGAGCCGGAGAGACCAAGAGGGAGGTGCGGGTGGAGGAGAGCACGCAGGTCGGAGGAGATCCCTTTAGAGACGTATTCGGAGATTTTCTAGGGCGAGAGAGTCTTAGCGGCTTCGGCGGGATGCCGACTGGCAGCCGACAGCCGCTGCAGAACGGTGAGGCAGCTAACCAGGAGATGACGGCTCAAGTGACGAGTCCTGGAGGAAAGACAGAGGACGCAGAGATCATTAAAGGAGAGGACAGCACCTACAGCGTCCGCTTCATCCCTCAGGAGATGGGACCTCACACTGTCAACGTCAAATACCGGGGCCAGCACGTCCCTGGGAGCCCCTTCCAGTTCACTGTGGGGCCCCTGGGAGAGGGAGGGGCCCACAAGGTCAGAGCAGGAGGCACTGGACTGGACCGCGGAGTGGCAGGAATCCCAGCGGAGTTCAGTATCTGGACCAGAGAGGCTGGTGCTGGAGGTCTCTCAATTGCTGTAGAAGGACCCAGCAAGGCTGAGATAACATTTGAAGACAGGAAAGACGGATCCTGTGGAGTCACCTACGTAGTGCAGGAACCTGGTGATTATGAGGTCTCCATTAAATTCAATGATGAACATATCCCAGACTCCCCCTTTACCGTCCCCATCGCCTCACTGTCAGACGACGCTCGCCGCCTCACCATCACCAGCCTGCAGGAGATGGGTCTGAAGGTGGGTCAGGAGGCCTCCTTTGCAGTGCAGCTCAATGGAGCAAGAGGGCTGATTGATGCCAAGATCCACACGCCATCAGGAGCCACAGAAGAGTGTTACATCACTGAGCTGGACAGTGATCAGCATGCTATCAGGTTCATCCCAAAGGAGAATGGAGTTCATTCTATAGATGTTCGTTTTAACGGCAGCCATGTGCCCGGCAGTCCCTTCAAGATCCGAGTAGGAGAACCGGGTCAGGTCGGAGATCCAGGAATGGTGTCTGCATTTGGACCAGGTCTCGAGGGAGGAACCACAGGCGTGGCATCAGAGTTTATTGTCAATACTTGTAACGCCGGCTCAGGAGCACTGTCCGTGACAATTGATGGCCCATCAAAGGTTAAGATGGACTGTCAGGAGTCTCCTGAGGGGTATAAGGTCTCCTACACACCTATGGCTCCTGGAAGCTACCTGATCTCCATCAAGTATGGAGGACCCCAGCACATTGTAGGCAGCCCCTTCAAGGCCAAAGTATCAGGACCTCGTCTGTCAGGTGGCCACAGTTTGCATGAGACGTCGTCTGTTCTCGTGGAGACCGTCAGCAAGTCGGTAGCAATGGGCAGCCCCTTTGCCTCTTTGCCTAAATTTTCCTCAGATGCCAGTAAAGTCATCTCCAGAGGCGCTGGCCTTTCGAAGGCCTTCATTGGTCAGAAGAACACCTTCACAGTCGACTGCAGTAAAGCAGGCACAAACATGTTGATGGTCGGTGTCCACGGGCCGAAGACACCCTGCGAGGAAGTGTACGTCAAACACATGGGCAACAGGATGTACAATGTCACGTATACTGTTAAAGAGCAGGGCAGCTACATCCTCATTGTGAAGTGGGGAGATGAGAACGTCCCTGGCAGTCCGTTCCATGTCACCGTCCCTTAAAACTGAACTCTTCACTGTCTCCAGCCTCTTCAACATCTGCAATGCACTGACGATTTTTCACTTACTGTTTTCTGCTAAATACGAACATCAGAGCACAGCTTCAGTAACCACAGGTTGTTCGTCGAGGCTTTTCTTCTGTCAGTTGCTCTTTTAAACATCGTCCCATTTAACTTCAAGAAAAGAGAATTTAAAGAGTTCAAACTGACAACAGCCCACACGCCTCAGAATTTGACCTGTTTTCATGCGTCCTTTATTTGAGAAGATTTGTTTCCTGCCAACATGTGGATAACTATGCAGGTGTAAACATCTGGTTCATAGCAGCTAAAAACAAACGTGCAGGATGCAAACATTAAGACTGGATTTAAATGTGATCTGCAATATCTGGACTAGTTTATTTTCTTGATGACAGGTTTTCTGTTAGTATTTCTGAAGATATGCAGCACTCAAAGAGGTCCAGAGGTGTCTGAGAAGGTCACCATGAAGGGGAGACTGCATACATTTCCATCTTTTTTGTGTGTGTCCAGTTCCCTGAAATTTTTCATCACATCTCATATTGTGTACAGTATGTGCATTAATTCACAAACACAATCTCATATTTAGTGAAAAATTCAAGCCGCAAGTTGCTCTTTTGCTCCCACAAACCAAACAATTCAGACAACTTAGCTTAAACAGAAGAAACAGTTTTATCTTCAGTGAGGAAAAAAGTGCTTCAGAGTCCCTTGTTTCTTATCTCCATCTGTAAAAACCGGAAACGATAAACTTTCTCTAAGAATCCTTATTTCTTACTGATGCTCATCCAATAAACACTAACACTTCTGACCCTCGGACTGTCTGCACTCCAGCCGTGGTGACTATCATCCAAAAATCTGATTGGTCAGTAGATGGTGATCTCTTATCTGCAACATAACCTGGAGCAGCTTTGATCTGTAGCATCAGTTACCATGGTGACATACCACCTTCATAACCCTGAAAAGACAGAGTTAAACCCGAAGTTAGCTTGATAACTACAGATCCCTAAAAGCATTCATGTTTTCTCATGGATGAGTTAAATGTCTTTCAAAGATATTAGTGTCACATAGTTGGAATAAATCTCTGAGTGAAAGATGGTGTTTAGTTAGCCTCAGCAGGTCTCCCTTTCCTCAGGATTCAGTTTCAGGTGAGCGAGAGACTATCTTCCCTCCAGGTTGAATCAGATGCACTCGGCAGGTCTCTGTATGTCAGGGTTTGTCCCAATTGCTCATGTGGTGTGGGCCCAGCTGTGGGATGTGGAATGATCAAGATGAGCTGTGCTGTGAGATTAACAAACTTTTCTGTTTTTATTTATTCTGCAGCATTTTTCTCTCCTTTGATTTTCTTTGACAGAAAATGGTCTTACTGTTGAGAGAAGCAGGTGATAATGGATTTTTTTTTTTTTACCACAGGAAGGAAGTGCAGTGGAGTTTCCTTTGTGAATGTTGGAAAAACAGCAGCAGATATTAGAGTGACATTTTATAGTGATTTTATATGTATGAGTGAAGCAAAGTTTAAGTGTTTGATATGTTAACCTTCTGTATTGCAACACTGTGCAGGCATAATAAAAGTTTATCTGTGAAATCTCCA
->XM_002992450.2 PREDICTED: Selaginella moellendorffii UV-stimulated scaffold protein A homolog (LOC9662154), mRNA 
-ATGGCGGGGCGATTGAGCGATCTCATCCTCGCGGCCACGAATTCCCCGGGCAAGGAGCTGGAGGAGCCGCTGCTCAAGGCGATCAAGGCGCTGGTGCGCGCCTCAGATGACAATGTCAAGGCGGCGGCAGACCTTCTCATGGACCGGCTAGGGAAGAATCACTCCCAGGTCAGGCTTCTCGCTCTGCTGCTCATCGATCAGCTCTTTACGCGATCGAAGCTGTTTCGCGGCCAGATCGTGGCGGTGCTCGAGAAATTTATGGTTCTCTGCCTAGGGCACCGCACCGACCAGCCGCTCCCAGCTCCCGCGGATCGAGCGGCGCTGCTCAAGGCTAAGGCGCTGGAAATCGTGGAGAGATGGAACGAGACGTTTGGGCCTCACTACAAGGAGCTCCAGCTTGGCTACGAATACTTGAAGTTCACGCTACGTCTCGACTTTCCGGGTGTTCGAGAGGCCGCGAATCGAGCCGAGGAAGAAAAGAATGCCAGGGACAGGCGCACGCAAGATCTTCTCCGGTGCCGGCTGCTCCAACTCACGGAGAATTTCCCTGGCTTGAGGAGAGATCTCGAGTCGACGATGAGTCAGCTGGAAGAATGCTTTGCCATCTTGAGCGAGGAGGAGGAGGTGGTCCAGGACGAGGATGGATTTTTGGAGGTGGACAAAGATGAAGAGGACAGTAATGAGGTGTTTGGGATCCAAAGCTTGCGGTCCATGCGTGATCAAGAGGAATTGATGGTCACGGAATCTCGCGACAACGGGGCCATTTTCGACATGGCCCGGGATTTGCTCAAGTTGGTGACAACAAGACATCTTCCAGCAGCGCAGGAATGGCTGTCGGTTTTGATGCGAGTCGACCCGGAAGATCGACAAAGCCGGGATGCTCTCATGAAGGAGGTGATCGACTTGAGGAACCGCCTGGTGGTCTTAAAGGATAAGTGTCAGGAGCTCGGGATTGTCGAGGTGGCCAAATCCAAAACCACCACTGACGACGATGTGGAATGGGAAGAAGAAGAGATATTTGACAGGAGCAAGCTGGATGGTCCACGACACAAACTAGAGCAAGAACGAGAACGAGAACGAGAACGGGAACAAGGTGGCGAAATAAAAAAGAGTTCCTCACCTCAGGCTACAGCAACAGGAACGGCTTCGTCATCTAACGCAACCATGTCCGAGCTTAAGCAGAAGCTGTTTGAGGAGGCTCCCGTGCTGCCGTGGGGATCGTTTCTCGACGCCTGGGGCTCCGACGCTGCGGTTCCTGCAAACAACAGGGGACTGGTTCTCGACAACCACTGGGGAAGAGTGGATCCGGACGCTCTCATCTCTACCGAGAAGATGGCGGAGATGCAAGTGAGAGCATCGTACTACCAGCCTTTAAAGTCGGAGTTACGTCCTTGCTCGGCACCGCTGAGGAATGGAGGCCTTTGCCAGAGACGAGATCTCCGAAAGTGCCCGCTTCATGGCACAATAATTCCGCGGGACGATAGAGGCAATCCTCTCGAGGAGAAAAGGGCTGTCGAAGCCAAGGGGAAGGAGAAGGCGGCGGTCAGTCCGGCAGCTTTGGCTGCTCAAGCCGTAAGGAACGTGAGAGGCAGGGATGAAGCCAAAAGGAAACAGAATAAACGTTTGCGACAGTCTCAAGCCAGGACAGACAGACAACACAACGAGGCCGTGCTGAGAACTGCCGCGCTTGCTCACGACACGCAGACGATTGAAGCAGGCCTAGAGAGGAAAAGCCTGGATGAAGAAACGCCAAAGAAACGAAAAGGTGGTCTCAGCGCTATGCTCCGTAAGAAGGAGACTCCAAAAGACAGAATTGCCAGGAGACTGCTGCGCGGCCGGGCAGTGGACGCTATGGTCGGCAGCATAGCTCGAGACGAGGATGCCAAGTACAGGGAGTCTTTCCCAAATCAGTGGTGATTCCACTCGGAAGCTGGCGCCGCTGATTCCCGCTTTAAGCAGTCCTTTTGCTGGCAGTCTGGGACGAGCTTTACAACTGGACATCATCAAAGCAAAGCCGAGCCGAGGAAAAGAAAAGAACGAGTCATCCGCAGCTCGAAAAGAGAGTTAAATTGTTCGAAGGAAGAAGACGAAAATCGAAGCAGCCTGTCTTTATAGA
->MF497935.1 Uncultured bacterium clone Ant5 16S ribosomal RNA gene, partial sequence 
-AGTGGCGGACGGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACTGGAAACGGTAGCTAATACCGCATAACGTCGCAAGACCAAAGAGGGGGACCTTCGGGCCTCTTGCCATCAGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAACGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGGGGAGGAAGGGAGTAAAGTTAATACCTTTGCTCATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCTGATACTGGCAAG
->XM_053485329.1 PREDICTED: Clarias gariepinus hook microtubule-tethering protein 3 (LOC128512176), transcript variant X3, mRNA 
-GCTGTAGCTGTGGCTTCGCCGGTGGAGCGGGTTGCGTGTGTCTCCACGTATTTGTTCATCAGAAGACGGATTTTATTGTTTTATATTGAAAGGTGCGATAAGGGAACATAACCGGAACGTGTTAAAACGTGTTTAAATTACTCGGGGATATATTGTGATATTTGTTTCGTTTGATCAAATCGTTCCTAGTGATTTTTTAGAGGTGCTCTCTCTGTTTGTTTGTGTGTGTGTGTGTGTGTGTGTGTGTGTCTGGGTAAAGTCACGGGCGGATTAAAAGCGAGCTGCGATGAGCACTTTGGACGCAGTGGATCGGGTCGAGCTGTGTGAGAGTCTCCTAACATGGATCCAGACGTTTGGCGTGGAGGCGCCGTGCAAAACCGTGGAGGACCTGACGAGTGGCGTGGTCATGGCGCAGGTTCTGCAGAAAATAGACGTGGTGTACTTCAGCGACAGCTGGCTGAGCCGTATCAAGCCCGAAGTGGGGGATAACTGGAGGTTAAAGATCAGTAACCTGAAGAAAATATTAAAAGGCATCCTGGATTACAACCATGAGATCCTGGGGCAGCAGATTAACGACTTCACTCTGCCCGATGTGAATCTGATCGGGGAGCACGCAGACGCAGCAGAGCTCGGCCGCATGCTGCAGCTCATCCTCGGCTGCGCGGTCAACTGCGAACAGAAACAAGAGTACATCCAGACCATCATGATGATGGAGGAGTCCGTGCAGCACGTCGTCATGACGGCCATTCAGGAGCTCATGAGCAAAGAGACGCCAGTTTCAGCCGGGAGCGACTCCTACGCCGACCTGGACAGACAGCTGAAGAAGACGGCGGAGGACCTGAACGATGCTCTGGCTTCCAAAGAGGAGATCGCTCAGCGCTGCCACGAGCTGGACATGCAGGTGGCGGCCCTGCAGGAGGAGAAGAGCAGCCTGCTTGCCGAGAACCAGGTCCTGATGGAGCGCCTTAACCAGTCCGACTCCATCGAGGACCTGAACAGCCCGGCAGGAAGGAGGCACCTCCAGCTCCAGGCACAGCTGGAGCAGCTGCAGGAGGAGACGTTCAGGCTCGAAGCGGCCAAAGACGACTACCGCATCCGCTGTGAGGAGCTGGAGAAGGAGCTCCTAGAGGTCAAAGGTCAGAACGAGGAGCTAACGTCTCTGGCTGACGAAGCCCAGTCACTCAAAGACGAAATGGACGTCCTGAGACACTCGTCTGATAAGGTGGCGAAATTGGAGGCGCAGGTGGAGTCGTATAAGAAGAAGCTGGAGGATCTGGGGGATCTGCGGCGGCAGGTGAAGCTGCTGGAGGAGAAGAACACCAGCTACATGCAGAACACCGTCAGCCTGGAGGAGGAGCTACGCAAAGCTAACACGGCCCGCGCACAGCTGGAGACCTACAAGAGACAGGTGGTCGAGCTCCAGAACCGTTTGTCCGAGGAATCCAAGAAGGCCGACAAGCTGGAGTTTGAGAGCAAGCGACTGAAGGAGAAGGTGGATTCACTCCAGAAGGAGAAAGACCGGATGAGGACGGAGCGCGACTCTCTGAAGGAGACGATCGAGGAGCTGCGGTGTGTTCAGGCCCAGGAGGGTCAGCTCACCTCAGGTCTGGTTCCACTGGGCAGCAGCGAGGCTGGTTCACTAGCGGCACAAATTGTGACCCCAGAGATCAGGGAGAGGTTTATTCGACTGCAGCACGAGAACAAGATGCTGAAGCTGAATCAGGAAGGATCTGACAACGAGCAGATCGCACTCCTGAAGAGTCTGCTGGAGGACGCAAACGCCAGGAAGAACGAGCTGGAGTCGGAGAACAGGTTGGCGAATCAGAGGCTCATGGCCGGTCAGAGTCAGGTGGAGGAGCTGCAGAAGAGTTTACAGGAGCAGGACTCGAAAGCAGACGACTCGGTTCTGCTGAAGAGGAAGTGCGAGGAACACTTAGAGAAATTGAGAGACGCGTCCAACGAGCTGCAGAAGAAGAGCGCCATCATCGAGGAACTGGAGCCCAAATATCACGCTGGTACTCAGAGGATTGAGGAACTGGAGGAGGCTCTGAAGAAGAAAGACGACGAGATGAAGCAGATGGAGGAGAGATATAAGAAATATCTGGAGAAAGCAAAGAGTGTCATTCGGACTTTGGACCCGAAACAGAACCAGGGTTCAGCTCCTGAGGTTCAGGCCCTGAAAAACCAGCTACAGGAGAAGGAGAGAATGCTGCACTCTTTAGAGAAAGAGTACGACAAGGCGAAGTCTCAGCGAGACCACGAGGAGAAGCTGATTGTATCCGCCTGGTACAACATGGGCATGGCTCTCCAGAAGAAAGCAGCGGAGGAGCGTTTAGCCAGCACGGGTTCGGGTCAGTCGTTTCTGGCGCGTCAGAGGCAGGCCACCAGCACACGGCGCTCGTATCCGGGCCACGTGCAGCCCGCCACAGCCAGTGATGTAAAGGCATGAGGTCGAGGCGGCGCGGCTGCATGACGGCGCTCCTTGCATGACCGATTTTGCTCTTGAATAACACCTCAACCAACACTAACACCTCTCGCTTTCTTCCGTCCCCCGGTCCCGCCGTTCCGTCTGCATGCATACGCTGCGTGTGTGAACGTCCGCTGTGTCCCAGCATGCAGCAGTCTGTGGGCGGGGCTTGAAGGTTACCGGAGAGTGACGTAATAATGATGATAATAATAAGTGTTGCGCTGTATTAATACGACAGTCTCTTAGGTCAGCATTTTGTTATTAACTCTTGTCTTCTTTTTCATATTTATTATCACTTTTTTGTTTCCTTTTTTATTTGAATGCAGTGTTATTTTAATTTCATGACCCGCGTGAGCAAACGGTGAGCCTCTGCACGGCACGGCTTCACTTTATTTATTAAATGTTTATTTTCCCAGAGCTCACAGCGCCACCGCTTGGCGGAAACCACGCACGAGAATTACGTTACATTACGTTTCTGTTTTTTCTTTCTGACAGGGAACAGTATTAGGAGGTCGAAAAGAACAGAAAAAAAAGAAACAAGGTCAATAAGGAGCTTAGAAGTAAAATATAAAGTATTTAAGTCCTGGGTGTGCGTATCAGAGACCTGGCAACAGGACAGAAACCACACCTCGTACCAGGGCTCTTTGTTTTTGTTTTTTTTCATAAATGATTCTATAATATTCGTTTATTAAACATTTATTAACCATCAGATCTGATTGAACAAAATGTTTTGTTAAAAAAGTTAACTATGCCAGGGTTTAGGCTGCTTTCACAGGGTTTTATTTCCCTCCCAAAGAATTATGGTTTAAAATAAGGTGATTTTTTTTTTTTTTTTATCATTATTTTTTTTTTTTTTATAAAAAGAAAAAAAAAGTCCTTTCAAAAGTATGTTTAAATTAAAATAAATGAATGAATGAATAAATAAATAAATACATATATATTGTTTTTTTGACCAATCTGATTGCAGTTGAGCAACTAAATCACGCACAAATTGTTGGTTTCAAATGAGCTTTATTAATAAAATATAGTGTAGTAATATTTAGAGATTTGTCACATTTTAAATGTATTTTTATTATTATTATTATTATTATTATTTATTTTGAGTAATTAGATGCAAATCAGAGGTCCAGACAAGAAAGAAAAATTACACGAGTGTGGGAAAAAATGCATAAGTGAAAATAATGTGAACTATATGAAGCTTTATGATGCTAAAAATAATGAAAATATATAACTCTTTTTTTTTTTATAATTATTATTATTATTGAGCCAATTAGCGGAAATCTGGGACGTCCCACTTCTTTCTCCCACCAAAAAAAAAAAATACTACAAAAGCAAATAACTTGTTTGTTTTTTTTACAAATAATTACTGCTTATCATGTTCAATCTAAATGAATCTTTCGTCGATTACTAGTTACCATGCGTTTATATAAATTAGCTAGCTGATACTAGCAGAGGTTTATAAAATCGTTGTTATGGTTAACGTAATATGACCAGCCTGAAAAAACAAAACAAAAATGAAAGCAGCCTAAAATATCTAGGCATAAAAACCAGTAAGCTGAACCACAGTTGGCTCGATCACAAACCATCGAGTGCTTTTGCGTTGTTACATTTTACACAAGGACACAGAGAGACGACCGAATGACATCATCAGGTCTCTAGGTCTCTAACATGTGCGTCTGCGATACTAAAATATCGTTTCCGCATCCGCTAAGAGGCGTGTCCTGTTTTATTATTATCTATTTACTTTTTTTTTTTACCTCGGATTGATTGATTGATTGATTGATGACTCTGTGGACTAACACACTAAACCGTGTGCTGTTTATTAGCCCTTAAACTTCAAAGTCTTCTGCTGCTTCTTTTCTTCATCACGTCATGACGTCCATTCTTACGCGCCATTTTGTACTGTTTAACGACTTTTTGTTTGAATCTATATTTAGCTTAAGTACATTTGTAAGGGTGTTTGTAAGTCGAGGAACGCACAACGCGTGGACTAGACAACAGTGTTAGCCTATTTAATATGAAATTTACAAAGAAACGTTCACGATAAGAACCGTCCATTAGGAGAGGACCTGCTCTGATCGGACACCTCAAAAGAAAAAAGAAAAAAAAAGAAAAATGACAATGACATTTTGGTTTTTCGAGTATTATTATGGTTGATGTGTTTTTTATGCATAGAAAGATGTTACGTTTAAGTCAAAGTAGCAAATAATCTTTCCATTTGCCAAGTTTTATATTGCTTGTGTACAGTATGTACAGACGCTCTGTGTAAGGAAGAGAAGGAAATTCCTGCTCATTAGTTTGTATAATTATATATATTACCAAAAAAAGAAATTCATCAAGAAGGTGATTGATTTTAGTTTAATTATGTGTTGCGACTCGACGGGAAAATGTGCTTCCTTTGCTGCAAAACTGTACAGTTGGTAATCAAGTTGTAAATAAAGCTTGTATAAAATTCTGA
->XM_052168617.1 PREDICTED: Apodemus sylvaticus canopy FGF signaling regulator 4 (LOC127673070), mRNA 
-TTTTAAAGCTTGCTGCCCGCTGCACCTAAATTTAAAGGGCCCGCTGACTTCCAGAAGTTGGTCTGAAGGCAAACGGTGGTTGTATGGGTGGACTGCGTTTTGTCATGGGACCTGTGCGGCTGGAAATACTGCTTTTCATCCTGGCAGCGTACGGTGCTTGGACTGGGGCGACGAAAGAGGAGGAAGATGACACAGAACGTTTGCCCAGCAAATGTGAAGTGTGTAAGCTGCTGAGCATGGAGCTACAGGAAGAGTTGAGTCGAACTGGTCGATCCCGGGAGGTGCTGGAGCTGGGTCAGGTGCTAGACACGGGCAAGAGGAAGAGACACGTGCCTTACAGCCTCTCTGAGACAAGGCTGGAGGAGGCTTTGGAGAATTTGTGTGAGCGGATCCTGGATTACAATGTTCATGCTGAACGCAAGGGCTCACTGAGATACGCCAAGGGTCAAAGTCAGACTATGGCCACCCTGAAAGGCCTGGTACAGAAGGGAGTGAAAGTGGATCTGGGAATCCCTTTGGAGCTCTGGGACGAACCCAGTGTGGAGGTCACGTTCCTCAAGAAGCAGTGTGAGACGATGCTGGAGGAGTTTGAAGATGTTGTAGGAGACTGGTACTTCCACCATCAGGAGCAGCCGCTCCAGCATTTTCTCTGCGAACGTCACGTGCTTCCAGCCTCTGAAACTGCTTGTCTACAGGAAACTTGGACTGGAAAGGAGAAGATCAGTGATGAGCAGGAGGAAGCAGATGAAGAGGAGGAGGAGGAGGAAGAAGAAGAGATAACCAAGACTCCAGGCAGTCCCAAGCATGACCCAGAAGATCTTTGACCCTTACTTTTGAACCCCAAGGATGGGTCATGGAGAGTTGTCTAAAGTCTTCAGCTCTCCCTTCCCCATCCGTAGGCTGTAACTGTCCTTCTCGTATGATCCTGGGGACCCAGAATGGCCACAGGAAAGGAGGAGAAGGGGGGAGAAGCGGAAGCAAGTTTTGCCTTCAGAGATGAGTCACGTGCGGCCACTCAGTGGACCAAGTGTGTGGTGACAGCACTGAAACCTTTCTCTCCCTTTTACTGGCCCTCGCCTGCACCAATTGGTCAGTGGTGTTATGACCTGTGGGAAGGTCACTTTGCTTTTTAAAGGCTCTATTTTAAACCCTTTCAAGAGGTCAGAGAAGAGCTAGAGCTCAGTTGGTAGAGTGCTTGCCTCTTCCGGGCAACGATGGGAGTTGGACCTGATGTGGTGGCACACCCCTGTAATCTGCAGCGCTTGAGAAGTGAAGGCTGGAATATCAGAATACCATCCAGCTACATGGCAGGCAGCTCAGGACCAACCAGAGCTACGTGAGACCCTGTCTCAAAGTAAGAAGCCAAGAAGGGACCCTCAACCAATACGCACTGCGAACACGAGGCTGTGTACCATTAATCTGTCAACAAGAGCAGGACTCTGGGAGCGAGTGCAGTAATACTGGGGTTAGGTGGGGTAGACATGTGGCCTATTTCCTATTTCACAGGTGCCATATTTTCTATATTGCTATTAAACCTTTTATATGTACATCA
->XM_024925133.1 Trichoderma harzianum CBS 226.95 glycoside hydrolase family 78 protein (M431DRAFT_99295), partial mRNA 
-ATGGGTCATTCGGTGTCTCCAGTCTTGGTTCTTCCACCGACTTTTGAGCAGCATCACAATGGGTTTGGAGTTCAATGTGTGCACCCAAGGCTTTCATGGAGGTTTTCATGCTCGAAAGAGCAAATACGCAATTGGAAACAGACTGCATACGATATCGCAATTTCCTCCAATAGCACAGAGCCTGGCCAAGTCTTTCACGTAGAGAGCGAAGACAACGTTCTAGTACCGTGGCCGAACTCAGAGCCACTCAACTCACGAGCGCGCCGGTTTGTGCGCGTCAGGTGCTATGGCAAATACTCTCTATTCGATGGGCGCGATAATGATTCCGACCATGAGTCCGTGACCGAATGGTCTGCATCGTCTCTTTTGGAAATTGCATTGCTGAGAAACAGCGATTGGAAGGGGAGTATGATCACAGTGTCGGAGCCGTGGCCTCTGGGTCCGGACCTTTCAGCCCGCCCCCTGTGCTTTCACAAGCGGTTTCATCTTTCCCTAAAAGACGGGATGATTGACAGGGGCCGGCTATATGCCACGAGCTATGGCGTGTACAGCGTGCGGATCAATGGCAGAAAAGTCGGCGACCACTGTTTGGCCCCGGGTTTCCAAAGCTACCATAAGAGACTGCATTACCAGATTTACGATATTAAAGATCTTTTGGTAACGCCTGGGTGGAACAAGATCGAGATAGACGTGGCCGCCGGCTGGTTTGCCTCTGCCACCAGTTGGGCCAGGAAACGATTCACCTACGGCCAGAAACTCGGTGTCCTACTTCAGCTAGAGATTTGGGCTGCAGACTCTTCCTTGCCGATTTTGGTGAACACCGACGCGAGCTGGAGCGTCTCCAACACGCCTTTGGTTAGCAGTGAAATACTGGATGGTGAAATCTTTGACCAAAGTCTGAGTGTGGGCTCAAAGCTGGACGACGCTTTCTCGGTCCGAGAGTCGCCTCTTGCAGTGAGCCGGCTCATCTCTCCGGAAGCCCCGCCAGTAAGGGTGGTGGAGAGGCTGGAAGCAAAAGACATATTCAAGTCGCGGTCCGGAAGCGCTGTCATTGTGGACTTTGGACAAAATATCGCCGGTCGTATTTGCGTTAAACAAGTGCAGAAACCTGCTGGCTCTAGAATCACGTTTCGCCATGCCGAAGTCATCCAAGACGGGGAGATTATGTGTCGTCCCTTGCGAACAGCAAAAGCCAGGGACATTATAATATGCGATGGCCGAGAACTCCTTGACTGGCATCCGCAACACACGTTCCACGGCTTTAGATATGTCGAGATTGCGGGATGGAGCCCTGATGACAAGAACTGCCCTCTCACCAAAGCATGCATTGTCGCCGAGGTGATGCATACTGACATGCTGCGTACGGGTTGGTTTTCATGCTCCAACGATGATGTCAATCGACTACATGAGAATGCTCTCTGTAGCATCAAGAGCAACTTTTTGAGTGTGCCCACAGAGTGCCCATCAAGAGATGAGCGCTTTGGTTGGACGGGAGACCTGAACATCATTGCACCTACTGCCAACTTCTTGTATGACACGGCTGGCATGTTGGGAAACTGGTTGCAGGATCTGTACCTCGATCAGATGGAGGGGACCGAATACTGGCGCCAAGGCGTGGTGCCCTTGTTCATTCCCAATTTTTTACTAAGAAATGGCGACGGGGGCCACGGGTGGGATCCGATGCCAAATGGCGTTTGGGGTGACGCTGCAGTTATGGTTCCCTGGGGCCTGTATCGTATGTCTTGTGATGTTAGTTTCCTCTCGAGGCAGTATGATAGCATGGTTAAGTACCTGGAAAATGGCGTGACTCGAGGTCAGGATGGACTCTGGGATCCTGAGCAGTGGCAGTTTGGCGACTGGTTAGACCCAAGAGCGCCCCAGAACGATTCCGGCAGAGGGACCACGGATGGCACATTTGTCGCCGATTGTTTCCTCATTGCTTCCACTCAGATCGCTGGGAAGGTAGCCGCGAAGCTAGCCAAACCGGTTGACTCCTCTCGCTTCAGAGACGCTGCACTGCGCCTAGTTCATGCGTGGCGGGACAAGTATTTGACCGCGGCTGGTCTCGTGGTTCCAGATACTGCAACGGCTCTTTCGCTCGCCTTGTCGTTTGATCTTTTGCCAGAATGTGGAGACAACTCAATAAAGGCACAGGCGGCCGCTCGTCTGTTCCGACTGGTACGTCTTAATGACTTTAAGCTTACCACAGGATTTGTGGGCAGTGCATTTCTTTCTCGGGCACTCACCCAGTCCGGTGGCGTCGAACTAGCCTACGCTATGCTGTTCCAGAAGAAATGTCCTTCGTATCTGTATCCCATTACGATGGGAGCCACCACGACGTGGGAGCGCTGGGACAGCATGCTCCCTGATGGGACTGTTAATCCCGGTTCAATGACAAGCTTCAATCATCATGCTCTCGGGAGCATCGCAAATTGGATGCACGCTGATGTAGGCGGACTCGAGGCGATTGAGCCCGGCTGGAAAGTATTCAGAGTGAAGCCGCAGCCCAATAAGGAGCTGAGCTGGGCGGATACCGCATTCGAATCAAGGTACGGCCGGATTGAGCTGAGATGGACCTTAAAGGGAGACCTTTTCCGCATGAGATTACGGGTGCCTCCAAACTCTACCGCCGTCGTCAGCCTTCCCAGTGACGGCCGAGAATCTGAGGTGGGGAAGCGGGAAGCTAAAGAGCAAAGATTTGGGTCGGGAGAATACGACTTAAGGTGTCAATTTGTACAAACACAGTGGCCACCAAAGGCACTGCTTCCACCATGGGGAAGAGCAGAGTTCTAG
->XM_036290224.1 PREDICTED: Monomorium pharaonis uncharacterized LOC118646716 (LOC118646716), transcript variant X3, mRNA 
-TGGACATTTTCATATAAGAAGTAATCTCGCAGTTGCGCTGCGTCCGACTACAGCTATCGAACGTATCGGATACGTTCCGTGTAATCGTGTAACAGAGTGAAGATAACGAAAGGGAAAGCGGAGAAAACAAAGAGGATTTTGCACGATATCGCCGCGCCGTTTTTATCCGACCAGTAAAGTGAGCGGATCGAATTGTTCACAAGACCGTTTAAGATCATTTGGGATCTAGCGTGATATATGCGCCGATAACTAGGATTCGATAACGAGCATTTTACGCTCGTGTATAAAGAAAGAAAGAAAAAATAATCGTTCTTTTATCATCGAGGTGTGGCAAAGAGTCGCGTGCTGGGCAGAATTATACCCGTTCGATTCCCTGTGCCGGCGATTTGAAACAAAGTTTAGATCTGTTACTGCCTCTGTTGTAAGGAACAAAATAAGCAACATCCGCTCGATCTCCCGGAGATAAAAGGCATCGGGCGAACAGGAAAGGCAAGGGGAGAAAAAAATGGCAGAAAACGAGAAAATCGTGTCGGACGAACGATTGTATGATTATTTGCGTACGTATGCGAAAAGCATCCAATTGAGATCCCCGAAATTTCACGTAATCGAAAGCAATAAAGGCGATAGTTACATTAGTGTCGTTTATCGCGTCACGATCGAGGGAATCGAGGAATGGAACGAGGCCAAGAAACTCGAGCTCGTTCTCAAAACCACGCGGAACTACGGCATCGACAATATTTTGACCAGCGGCAGGGTCACAGAGCTATTCCAACGCGAGGCATCTTTCTATCAGGACGTGTTGCCTATTTTCAAAGAGACTATGAAGGACCACGGCGGAATGCACGACCGCTTCCCCATTTTATACGACGTCAACGATGAATCCGGAAAAGAGATACTGCTGTTAGAAAATCTAACGCCCCAAGGTTTCGTGATGTCAAAGTCAAAAATTATGGATTACCCGCATCTCAAGTTAGTGATGCGATGTCTAGGTGAATTTCATGCGTATAGCTTCATTACGAAAGCGGCAAATCCGACGGCTTTTGAGAAAATGAGGCAAATGAAAGAACACATATTTCTAGAAGTAGTAAATAGTGGCGAACAATTAGAGGCTAACGAGAGAATGAAAAAATTGGGAAAAATGCTTTTTTACATCGTGCTTAAAGCTTTAGCAAACGAAGACAAACATTATTCCGAAAGGTACCAACGATTCATGGAGAATATGCCGCAAAATATGTTTGCCGCAACTAATGGAAAAGAAGCTGAACCATACGCCGTTGTAAACCACGGTGATTGTTGGACTAACAACATGCTCTTCAAATACGACCAAGAGAAAAATCCGTGCGACTTGCGTTTCTTAGATTTTCAGTTATGCCGTTATGCATCTCCCGTTTTAGATCTAGTTCATATACTCTTCTGCTGCTGCACGCAAGAAACAAGGAGTAAATGTTTTGATCAGATAATTAAAGACGTATATTACAAAACACTATCTGACACTATAAAGAAGGCCGGTTACGATCCTAATGTACTCTTTTCTTACGAGATATTATTACAACATTTTACCAAATTCGGGAAACACGCAGCGGGAATTGCTACTTTCACTGTACATTATTATACTACTAATGACGTAGACTTCACAAGTGTATATGACACTAATAGGCTCGAAGAAAGAATAGAAAAAGATAGCTTTTACAGAAATATGTTAATAGAGACCTTTAAAGATATTATTGATAGAAATTATATTTAAATTACTACTTTCACAATAACATCGACATATTGTGATACCAAAAGAAAAAAAAGGACTCTTGTAGTTAAAACAAAATGCTTTATATTAAACTTAGACACCAATGTAGCTAATTACATATATTCATACAAGCCTACCGCATCAGGTTAAGAGAATTTCGTTATGACTTATCGTGAATGACTTATTCACATAAATATAATTTATAAAAATTGTATATTTTATGTTTCTGAACAGTTAGAAATATCGGACATTTTATTGTCACTTTTATCAAATAAAAATTTATTAAAATTACTAAATTTTTCTTTATAAATACTTCATTTTGGTCACTAAAAACAATAAGGTGCAATAATTCTTTACACTAAAGTGCCTAAAAATTAACGATGAACAATTTCATTCGGAGAAAGACAAAAATTGTATAAGAGATATATTTTTAAAAAAATGTACAGTCTCAAATATACAAAATAAAGGTAATCTATTACATTGTTTGATAATGAAAGGAATACTAGTTTAATAGTAATGTATCTTAGCTCTTAGTAATAAAGTCTTCTTGGATTATTTTGAAAGAAATTTGTAATAATAAACCAGATAATATTTTCTACTTAA
->XM_017386452.1 PREDICTED: Daucus carota subsp. sativus histone acetyltransferase MCC1-like (LOC108214453), transcript variant X4, mRNA 
-GAAGGTTTGTTGGTTATTTTTTAATTTTCTTAAAAATTCTTTATAGTACTCCCGAGAAGAAAAAGAAGCCCGGTTGCTTTGTTTTGGCGAGGGAAGATTGAAGAACCAAAAAACAAGAGCTGCATCGAATTCTGCATATACACAACAGATTCATCTACTCGACATCTTTCAAGTTGTTAGATCAAACATCAATCGGATTCATGAGCAATCCTTACATTTCCCCCAAATTCAGGTTACTAATTAGTACAAATTCACTTCATCTCTGAATTTCAATCGCATCGATGGTGAACCTGTATAAACCGCCTTGTGCTAGTATCTTTTATAGGCCTATTAGGCCCTCTGATTTGCAGCTTCTCGAGAAACTCCATGCCGATCTTTTTCCTATCAGATATGAGTCGGAATTCTACTTGAATGTTGTTCATGGTCGTGATATTGTCTCCTGGGGCGCTGTTGATCGGAATCGCTCGGATGGTCTAAGTGATCAGCTTATTGGATTTGTCACTGCCAGACTTGTTATGGCAAAAGGAAGTGATGTGGAAGATATACTCAGATTCGAAACGTCAGAAGCAAACCAGACTCTAGTTTATATTTTGACACTTGGAGTGGTGGAATCTTATAGAAATTTTGGCATTGCCACTTCATTAATCAAAGAGGTTATCAAGTATGCTTCAAACATTACAATGTGCCAAGCAGTTTACCTACATGTGATTTCCTACAATAATTCTGCCATCCATCTTTACGAGAAAATGTCCTTTCAGTGTGTACGGAGATTGCACGCTTTCTATTTCATCAACGGGCAGCATTATGATTCATACCTGTTCATATATTATGTAAATGGTGGTCGATCTCCTTGCTCGCCATTAGAACTTGCGACGATTTTCATTGCTTACATAAGGTGTGGATTTAAAGCAGCTGCATCAAAGTTATGGAGGAAGAAAGATAAGAAGGTACCTGTGTGGATGAAGTGTAAAGAAAGCAGTGGCCTACTACCAACAACGCAAAACAAGAGAATCCTCACAAGTCACAACTGAGGTTATTGTGTCAGATTGTTTTAACTTATAATGATCTTTTCACTGCTGTAACACAAGATCAAATCCCGATAGTCAATTGTATCTTGTTCTTGGAAGTTTGTTTCTTTTATTTATTTGATCAACTTCATAGTAGCCTTGACCATGCTCTTATGTTGCAAGTGTATGTAGTTGTTCCTCCTTTTCCCAGAGTTGGACACTTAAATTTCTATCTAGACAGCAAAGCTCAACAGTAGATTTTTATTCTTCAGTTCCATTGTCTCCGCCACCCTCTTTGCAATCCCTAGTGAGTGAACTAAGAAAATGGTATTTAGTGTTGCCCCCCCTTCTTTCTGTGCTCCACTTTCTTTAATAATCACAGCAAGGTAGATAAATATATCAGATCGGTAAAATAATTTCATATATTTGGCCCTATGGTACAATAGTGAAGCATTTTTTCTTGACTCGTTCCATAAGCATGACTATACCATTGTGCATTATGTTTGTATTAGTAAAGATATCTTTATCTGACTGATTCTGCATAGATTTCTGTATATAGAATATAGAATGCGAGAGGTTGATTCCATATGAAGTACGCTTGTTTTCATATTTCCTGGAATGTTAAATTGAATAAATCAATTTTGGATACTTTATGCCCACAACTAAACAGGAACACCCGTGAAAAAAAAAAGGATTTTGTGAAATTCATTTATGAAAGAAAATTGAAAAAATGGACAGATTTAGTTCTTTTCAGTTGGTACTTGTTCTCTCCCTTAAACCGAGCCTTGATCGTTTGTCTTTGAGCGCATTTGTTGGTAATATTGAAAAGCCTGTCCTACCACAATTGTCCTATACTTGCTGGTAAAATTAATTTGTCAATCCTATGGTTTGGAAATATGAATGAGCAGCAAAAGTCTTGCCTGAAGTTCTTTATTAGGGTATTCTGTTAGAGCCATGAGTGGCTGATTGGTGGCTTATGTAGAGACTAGAGAGAGATACTAGCTCGTGGTGACCAAGAAGTTAAAGAGCATTCCAATTTTCAATGGATGAAAGTGACCGTGCTCAAGGAAACAAAAGAGGCCGCTCAAACAACTCTTTGGAATATTCATTTTGAAAGATACGGCAAGGCAAAGCTGCCTGTGCTGAAAGCAAAAGTGTGGCTGTAATTGCTATGGACGAAGGAACAGAATGGAAGAAAGCATGAAATGCTTTGTGCATAATTTTGATGGTGAGCAGCTGGTAATTGTGGAGGTTGACTTATTGGATGAGTTTTAAAGGGACTGTGCACGCCTTTTTCTTCAGGAGGAGTAGGTAATGTCCGGATTATTAGTACCTTTACCACCAAAGAAGATAGTTGAGAACTTGAGATTATATGGTGATTCATTTTGTGGCAGCATTAGCCGAGACTGTAACAGATCCACAACGTTTAGGATTTTCTTTTAGACTGATGATCAATGCGGGGAAGTTCTGACTTGAAACTCGGGCACAGGCTTCCATGCTCGTGATATTTATGAATGATATCATTATTCATTTTTGATTTACAACTGTTGTTATTATA
->XM_052334290.1 PREDICTED: Diospyros lotus succinate dehydrogenase assembly factor 1, mitochondrial (LOC127799971), transcript variant X1, mRNA 
-ATGCCCACGGAGAGAACACACGAGAGTGAAGATTTGGAGGGAAGAAGAGTCCTGCACCGCCCGGTGAGCCCCTCCGTCGCTGCCGCTCACCTCCGTCGCCGGTCTCATCTCCATCGCCGGCGAACAGTTTAGTACCGCCACTGCCGACTGCCACCGCCACCGCCCCTGCAAACAGCCAAACACAGGATTGCTTTATTTTGTGGAGTTGCGGAGAAATTATCTTCAGTATTTGTGCTGTGTTAGGGTTCACAGAAGAAGCAAAATAGATACGCAGTATTCCCCAAGCTGCATACAAGCAGAACCGTTCATCTACAACAATACAATACACTGTGCACCATCATATGGTTAAGCAAACATCAGGGGCATTATTTGAAGGGAATTCAGGCTGCGGAACACCAGGGGACAAATCAACTTCTGCCCTAATTTCCAGATCCCCGTTTCCTTCTTTTGGCTGAGCAAACAGCAGGGGAAAAATCGAGAATGGCTCGAAGGGAATTCAGGCCGCTGAATACCATCTCTGAATTCCAATGGTTTGTGTCGTTCTTCGCATTCTGCAGTGGCATTGATTTATTCTGGTTGGTGGCTCCTTGATCTCCTGTGAACTCCAGAGCTTTCAGTGGAAGGCAAAGAAATACAAGAGAGATTGCAATCAGGAGTCAAGAAGTGAACAAGATGCAATGGGAGGTTCTAGTGGGCCAAAGCTTTCTGGAATGCAGAAGCAAGTGCTTGGTCTATACAGAGGGTTTTTGCGAGCAGCGCGTGCCAAATCCCCTGAAGATCGATCCCGAATTGAATCAATCGTGTCAGCTGAGTTCCGTCGCAATTCGAAAATAGTAGACCGCAAGAATTTCACCTACATCGAGTACTTGCTTCGGCTTGGTAAGAAACAGCTTGAGCAGCTTCAGAGCCCGGATACCATTGGATTGTCACACTTGAATGTAGAACTCTCCCACACTAAGAAGTCCTAATCCCACACTAAGAACTCTTGTACCTTACCTTAGGATGTATCCTAAAGTTTTGTCATCCTCTGGTCTCTGACCGAATGTTTTTTTGATTACTCAAAACTCATGCTTCTCCAACTCCAAAATTCAAAATAAATGTTTTATATGAGAGCTGCAA
->XM_028897914.1 PREDICTED: Prosopis alba SWR1-complex protein 4 (LOC114713302), transcript variant X2, mRNA 
-CCAAAAAAAAAAAAAATCCCCACCCGGTGTTTTGTTTCACCATTTCCGACGTTCTTCGTCGTCTCTTCCTCCCTCCTCTTCCTCTTCGTCGGCAGCTGTCCCACGTCGGCCGTCTTCGTTGAACTTCGCTGGCTTTCATTACTCTCCTCTCTTCCGCTGCTCCGTCTAAGTGCCTCCCGTTGATATACTCCAAGTTCACCAGCTAGGAAAAATATTGAGAAGACCTCAGTTCCTGAAACTGAAGACTGAATTCTTGAATCGAAGTATTGGAAAAAGCCAAAATTTTGACAAGATTTAGAAACCCTGTTTTACATTTATGAGATGTGCTTTTTTAATTTATGTTTTTTTGGTTGTACATAAATAAGGTGGATTAGCTTGGCCCTAGATTTCCTCTGAAACTCCCATGGATGCCAAGGACATCCTTGGTTTGCCCAAAACCTCCTTGCCAATTCAAGAGAAAAAGTCTAGGCCCCAAAAAGATTCACAGAGAAAACCAGATGGCATTTCACGGGAGGTATATGCACTCACTGGTGGTTTGGCGCCTCTTATGCCTGCAATTGATTCGTCTCAATTAAAGAAAAGGCCTCCATCTGACGAGAAGATCACTTGGCAGTGGCTTCCTTTCGCCAATTCTGCTCGTAAAGATAATCTTCAACTATACCATTGGGTCCGAGTTGTGAATGGTCTTCCACCCACTGGGGACTATTCTTTTGCCAAGTATAACAAGTCTGTAGACATTATCAAATACACAGATGAGGAGTATGAGAAGTATCTGACGAATCCAATGTGGACCAAGGAGGAGACGGATCAACTCTTTGACTTGTGCGAGAGGTTTGATCTTCGGTTCATTGTGATAGCTGACAGGTTCCCATCATCACGAACTGTAGAGGAATTGAAAGACCGATACTACAGTGTATCTCGGACTCTGTTAATTGCTAGGGCTCAATCTTCCGGGGATGTTGCAATGCATCCTTTAGTTAAGGAACCATACAATGTTTCACAAGAGGTTGAGCGGAAACGAGCACTGTCTATGTACCTCTCTCAAACAAAGCAACAAGAGCGAAAAGATCAAGAGGTTCTTGCTGAGGCAAAAAGAATAACTGAATCACGCATGCCTGCTAAGGTTGCTGAAGAGTCTGAGGCTGCTGCTGCATCAAATGCTGGTGCGGAAGAGAGAGCTGTCTCCGGTGATCCTCCATCAAGTGTTCAGCTTCCATCAACGGTTGTTCCATCCACAACAGCAGATAATGCAGCCACTCTTGCTTCCCTTCGCATGCTTCGTGTGTATCTAAGAACATATGCACTTGAGCAAATGGTCCAAGCTGCAAGCTCATCTGCTGGACTACGGACCATCAAACGGGTGGAACAAACACTACAAGAACTTGGGGTTAATTTAAAACCAAGGGTTCCAACCAAAGCTGTTTGTGCAGAACATCTTGAATTAAGAAAAGAAATACTAACTCTGCTCAATCTTCAGAAGCAGCTGCAGTATAAGGAGGCAGAAGGTCGTGATGGTTCATACACTGAAACACCTGGCACACCGAAGGATAGGACATTTATTCCAGATTCTATGAGTTTTGGAGGTGAGAGGATTGGTAAGAGGGACCAGAAACGCAAGGCGCCTGGGAGGATATCAGAAGCTCCATCATCACCGGCTCAGTCTAAAAGGCCTAGAAAACTGAAGGCATCTGATCTATAGTCCGGTGGTGTAATGGGAGAATATAGAGTTACAGAATTCTGCTAACGAGGATGAGGAATGCAGGGTAAAGTAGGTGTAAGCTCATGGCCCAGAAATTCAGAATTTCCAACTGAAGTACTTTGTTTCCTTTTGGGCTGTTGCCGGTCACAGTATCTAGCGTAAGATGGAGCACAAATAGTGATGGAAATTCTGGGTTCTTCTAACTTTTAGGTACCTCGTGAGCTTAACTTTATTTTTATGCTGGCAAAGCTTTGTACGGTTGTTAGGTTTTTCTGACCAAATTGTCATTGAGAATTTTTATGTAAATAAGCATTCAGGTGAGGATTGTTCGAACAAATATAGGGCCTCTAAAAAACATGTATTTGTGCCTCGTGAATGGATTCATATCCTAAACTTCTTCAACTAATCGAAGGCTGATATTTGAATGAAA
->XM_012572725.4 PREDICTED: Taeniopygia guttata EPH receptor A7 (EPHA7), transcript variant X1, mRNA 
-CGGGCTGCAGTCGGGGCTGGCGGGCGGCCGGCCCGGTGCGGGAGCCGGGCAGCGGCGCGGAGGCGGAGGAGAAGGAGGCGAAAGAGAAAGGCAGCCTGGAGGGAGGGAGCGCCGAGCCACAGACTAGCACAGCAAATTCTCCACCGTCCTCTAGCACCCACCAAGCGGCGGCAGTGGCAGTATCTAGGAATAGAGAGCTAGAAATATAAAATCACCCCGCTCCTGCACCATGGCTTTCCAAAGTAGGCTCCCTTCTTGGATTATTTTGTGCTCCGTCTGGCTGTTCCGCTTTGCACACACGGGGGAGGCACAGGCTGCAAAAGAAGTAATACTGCTGGACTCTAAAGCACAACAGACAGAGTTGGAATGGATTTCCTCTCCTCCCAATGGGTGGGAAGAAATTAGTGGACTGGATGAAAACTACACTCCTATACGAACATACCAGGTATGCCAGGTGATGGAATCAAACCAAAACAACTGGCTTCGGACTAACTGGATTGCAAAAAGCAATGCACAAAGGATTTTTGTAGAACTGAAATTCACTCTGAGGGATTGTAACAGTCTTCCTGGAGTTCTGGGGACTTGTAAAGAAACCTTTAACTTGTATTATTATGAAACAGACTACGACACTGGCAGGAATATCCGAGAAAACCAATATGTAAAAATAGACACTATTGCAGCAGATGAAAGCTTTACCCAGGGTGATCTTGGGGAGAGAAAAATGAAACTTAACACAGAGGTGAGAGAAATTGGACCTTTGTCCAAAAAAGGATTCTATCTTGCGTTTCAGGACGTAGGGGCCTGCATTGCTTTGGTCTCTGTCAAAGTCTACTACAAGAAGTGCTGGTCCATCATTGAGAACTTAGCTATTTTTCCTGACACAGTGACTGGCTCAGAGTTTTCCTCTTTAGTTGAAGTGCGAGGAACTTGTGTCAGCAGCGCGGAGGAGGAGGCGGAGAACTCGCCAAAGATGCACTGTAGCGCGGAGGGAGAATGGTTAGTGCCTATTGGAAAATGTATCTGCAAAGCAGGATACCAGCAGAAAGGAGACACGTGTGAACCTTGTGGCCGTGGGTTCTACAAATCCTCCTCACAAGATCTGCAGTGCTCCCGCTGCCCTACTCACAGCTTCTCTGACAAGGAAGGATCTTCCAGATGCGACTGTGAAGATAGCTATTATAGAGCACCTTCTGATCCACCATATGTCGCGTGCACAAGACCTCCATCTGCACCACAGAACCTAATTTTCAATATCAACCAGACTACCGTGAGTTTGGAGTGGAGTCCTCCTGCTGACAATGGGGGAAGAAGTGATGTGACCTACCGCATTTTGTGCAAGAGGTGCAGCTGGGAGCAGGGCGAGTGTGTTCCCTGTGGGAGTAACATTGGATATATGCCCCAGCAAACTGGATTAGTAGATAACTATGTCACTGTCATGGACCTGCTAGCTCACGCTAACTACACGTTTGAAGTTGAAGCTGTGAATGGGGTTTCTGACTTGAGTCGTTCCCAGAGGCTTTTTGCAGCTGTCAGTATTACCACTGGCCAAGCAGCTCCCTCGCAAGTTAGTGGCGTAATGAAAGAAAGAGTGCTGCAGAGGAGCGTGGAGCTTTCCTGGCAGGAACCAGAACATCCCAATGGAGTCATTACTGAATATGAAATCAAATATTATGAGAAAGATCAAAGGGAGAGGACCTATTCAACAGTGAAAACCAAGTCCACTTCAGCTTCTATTAATAACCTAAAGCCGGGAACAGTGTATGTTTTCCAGATTCGTGCTTTTACTGCTGCTGGTTATGGAAATTACAGCCCCAGACTGGATGTTGCCACACTGGAAGAAGCCACAGCCACAGCTGTTTCCAGTGAACAGAATCCTGTTATTATCATAGCTGTGGTTGCTGTGGCAGGAACTATCATCCTGGTCTTCATGGTGTTTGGATTCATCATCGGACGAAGGCATTGTGGCTATAGCAAGGCAGATCAAGAAGGGGATGAAGAACTTTACTTTCATTTTAAATTTCCAGGCACCAAAACCTACATTGACCCTGAAACCTACGAGGACCCAAATAGAGCTGTCCATCAATTCGCCAAGGAGCTAGATGCCTCTTGTATTAAAATTGAGCGTGTGATTGGCGCAGGAGAGTTTGGTGAAGTGTGCAGTGGGCGTCTAAAGCTTCCTGGCAAGAGAGATGTTGCAGTAGCCATAAAAACTCTGAAAGTTGGCTACACTGAAAAGCAGAGGAGAGATTTTCTGTGTGAAGCAAGCATCATGGGGCAGTTTGACCATCCCAATGTGGTTCACCTAGAAGGAGTTGTTACCAGAGGGAAACCAGTCATGATCGTAATAGAATACATGGAGAATGGGGCCTTAGATGCATTTCTTAGGAAACATGATGGGCAATTTACTGTCATTCAGCTAGTGGGGATGTTGAGAGGAATTGCTGCTGGAATGAGATATTTGGCCGATATGGGATATGTACACAGGGATCTTGCAGCACGCAATATTCTTGTCAACAGCAACCTTGTTTGTAAAGTATCAGACTTTGGCCTTTCCAGAGTTATAGAAGATGATCCAGAGGCTGTCTACACTACAACCGGTGGAAAAATTCCAGTGAGATGGACAGCTCCAGAGGCCATTCAGTACCGCAAATTTACCTCAGCCAGTGATGTGTGGAGTTACGGAATAGTTATGTGGGAAGTAATGTCTTATGGAGAACGGCCTTACTGGGACATGTCAAATCAAGATGTTATAAAAGCAATTGAAGAAGGCTATCGTTTGCCAGCGCCCATGGATTGCCCAGCAGGACTGCACCAGCTGATGCTGGATTGTTGGCAGAAGGAACGCGGTGAAAGGCCAAAGTTTGAACAGATAGTTGGCATTCTGGACAAAATGATTAGAAATCCAAACAGCTTGAAAACCCCACTGGGAACCTGTAGCAGACCAATTAGCCCTCTTCTGGACCAGAACACTCCCGATTTTACCACTTTCTGCTCCGTAGGCGAATGGTTACAAGCTATTAAGATGGAAAGATATAAGGATAATTTCACAGCAGCAGGCTACAACTCTCTTGAATCAGTTGCCAGGATGACTATTGAAATCAAAAACATGCCAGGTGCTTTGCAAAACAGAGAACAAGAAAAATCCCTTTCCAGAAGAGATGACAGCCTGAATAGAAATGGCATAATGGCAGGAGACAAAGGAAGCAGAAAGGGGAAGCAAAACAAGAGTTATAACCATAAGATCATGAGATTGGTTTGGAGGCACAGTGAACGCTATGAGGCATTTTTTTAAAGCCCATAAGGACTGTAGTTGGGATTAGAGAATGGAAATATAGAAAAGAAGCATGGAAAGGAATGGAGAAGAAGGGAGGAACAGACTGGCAACAGGAGGAAGAGTAAACAGAGGTGTATGGGAGAGGCCAGAACACACATCTGACAAACTGAGGATTATGACTAATGACAAGAATGAAAGACCACATCTGAAGAGCATGATGATTTCAGGAGGATGGCGAAGCAGGACATGGCGATGCTGCTAGGGAGAGAAGAGCCAGCAAAGCTGCCCTGGAAGCCTGCCCTGGAAGCTCCTCACACTAACATAACCCTGCTTCCCCATCTTCTTTCTCGCTCCCCTCTTATACATAAAATATGTATATAGAAGAGCAAAGGAGAAGGAGAAGCAGCTAAATAAACTTTTCCAAAGATCGTGCTGGGGAAGAAGTTTAAGCTGGGATGATACAGATTTGCTCCTCCTGATTATGCTCATGGTAGCGAGAGGAAGAGAGCATTCTGTTAGTCATATTCCTGCAGATGAATCTATATGAGTCTTTGCCTCTGGTTACAAATAGGCCTTGTTGAGAAATAGTCAACAAAATTATAATACTCCAGCCAATCTGGGACATTTTAAAATGTCCTTTCATTCTAGAACAGAAATAAATTACACCACTGACAGTGAAATGGAAAGAGGAAAGAAGAATATTTTAACAGTTTTGGTTTTTTTTTTAATGCTGAAAATAATCATTTTAGTATTATGGAAAAAAAATATAAGGGGGATTTTTCTCATTGTGAAAAAAATAAAGCTTTTAATGAAATTTCTGATAAAATTGGGAATTATTTTAATTATGTAGGACTGGTTTTTCTGTTGGGTTTTTTTTTTTTAGAAAATTGGTATTTTTAGAAGGAAACAGGAAAATTGCTGTGTTCATTCTGTCAGACATTTTAAAATACCCTGATTTCCAAGGTAAGAATTCTTCAGGAGTAAGAAAGCTGAAAAGTGGCCAGTCTAATCTCTTCCTCACTTCCTTCTCCTCTGCTTCTGTGATCAGACGTGTCTAATGATAGTCTGCAGATAGCAAAACCAGTTTCTATGTCTCCCTGAGAAAAGGCATTTTGCCAACTTTAAGAATCTTTAACTGGATCTACTTACAGGAAGTCACTGTTTTGCTGCAGACTATGTGTCCACTTAAATCCCCCTCAAAGCTCTTCCATTTTGCCTGGAAAGGTTTATCAGAAAGCATGCTGGAAAGGCTCAGATCTTTCCATCTCCAGTGAAACTGTTTCTGAACATACTTATAGCTTAGCAGATGTACTGGTATGACAGTTGAGAGACTACTGCTGTTAATGAAGTATTCTATTACCTTGGCATATATAGACACTTTTCACTTGGTACTTCTAACTGCAAAGTATTGATGTTTAGGCTATTATAAGTACTTGTGCGTTATATTTTTTTGGTAAGTTTTAGAGGACAGAACTGCGTAAATATTTCTTCTCTTCAGGGTAAAACAGTTTTCATGAGTCTTGAAATGTTTACATTCATCTTGAATGTACACCAGAGTGATATCAAGTTTGTTGTTGTGACACCTTATCAATATGATGCCCATTTTTAGTTTCTTCTAGCAGTGGAATGATTTAAGTATTGTCTCATGGAGACAACGGCCTTGTTTAAGAATGGTGACTCTGGATAAGATTCAAATAATTTGTCTGAGTGAAGAGGAGGCAACTGAAAGTCATCGCTGAAATATTACCAAAAATCCTTAACTGGTTGGATTTGTCCATCACTTGCTTGAAGATTTTGGTAAATGGTGGTTTACTAGGTTCCCAAATGCCAGCAATGGCCAAGCACTTTCTTTTAATTTTCTTCAATTTGGACTTTGCTTAAGTTAATTAAGCTTTTGTCATCTCAGGGTTCCATTTTAGCAATGAGGTTTACAAGACCTTCTCTGTCAATGTAAAATCTTCCTATACTTAAGAACATATGACATACGGAGAGTAAACTCAATGCTCAGCAGTGCTTGAAGAATGATTCCCACCTCAGTAATTTCTCTCCATTTTTATCAAAATAATACTGGATTTAAATCCTATAGCCATGGTATCAATTTACCAAAATCTTCTCTGCCTAAATTATTCTTCAATTAAATGTAGCTCAAAGTTTTATTACAATCCACCTATCATTTAAAAAATGGGATTGCAAAGTAGTTTCATAGTATCACCCCATAATACAGATTTTTTGCATATTATTTTTACATATTTGAAAGAACTCCATTACTCAGTTGCATATAACTTTTTGCAATAAGAGGCACAACGTAAAGCAATATCAAAACACAGGTAGTATTTCTACTAATTTTATTTAGCCAAGCTCCAGATTTTGCATAATTTTGCCACTGCTTCTGGCATGATAGCAGATATGGAGGTTATCCATGCCTGCCTACCTTTTGGTGCTGAGATAGGATTCATCTGTGTGGCACCTTACCACCCTCCGCTACCAAAAAAAAAAAAAAAAAAACCAACCAAAAAAACCAACAAAAAACAAAAATTCCACTGGGAAATTTGGCATAACCTCTGGGAAATTCAGTTTGACCTACCTTCTGGGTTCAGCAACTGAACCGGATGCATGATTTGGGAAGGGATTTAATACCAGCTACCTCAGTAGCCACAAGGTGTTACGGGAAAACGACTGAAAAAATCCAAACTATTATAATGTATCCTGAGACGGAAGGACAGCATGGTCATTTGCCTATATATTTATTTCTAACCTTGCCTACACTTTTCCTCAGAATCCTTCCCTGATATTGTCTGTCAGCTCTTTCAAGAAGACACTTGGTTGTGCATAAAGTAGGAATGGCTGCACTGACTCAAGCCACGAGCCCACATAGTTGTGTGTACCTGACTGTGTGCCTTGGTAGGGGTACAGTCTTGTTATAAGGCCTCCACTGATCCCTACAGATTAGGGAAACCTTCAGCTGTTGACTTCCAGACATCTTCAGGGCTCTATATCCAATATGTACAGTTCAAATGCTTCCCAAATCAGGGTGGTGCACTATGATGAGTAGTCTGAATTTGTCCTATATTCTGTGAATTTACTTCTTTCTTCTGTCAATCTTCTCTCTCTGTCTTGCCCTTCTTTCTCCTGAAGTAGAATGACCAGGGTTGCATGAATTATTCAAAATAAGAGTGTATGATGTATTTATACAGTGATATAGCGATACAGTGTATTTATACTGTGATATATATATATATATATATATATGTTTTCTATTTTGTTTACCGTTTCTTTCTTAATCATCCAAATATCCTGTTTCACATTTTTACTTGATACTGGGTGCTTGACTTGATGTTTTCAGAGAGATGTCTGATGTTATTCCTTATTTTTCCTTCTCAAGCAATAGTTACTTTGTAGTCCCTGCCTGTGTGTGTATAGTTAGACTTATTTACCCCTTGTTCAGTTCTTTCTGTTTTATCAGATTTCATCACTCCTTCATGGCCAAGGGCATTGAAAATTGTGAAATCATTTTGCAGTCCTTTCCAGACAGTTCCTTACTGATTTAACTTACAAAAAACATTTTGTATCAAACTTTCTCATCTGACAGTTCTTAGATATCACGTTTCCCTTTACTACTAATAAAAGTACTTTTGCTTAAA
->XM_033125297.1 PREDICTED: Rhinolophus ferrumequinum 5'-nucleotidase, cytosolic IB (LOC117033240), transcript variant X2, mRNA 
-ATGAGTCAAACATCTCTGAAACAGAAGAAGAAGAATGAATCTGGAACAAAATACCCAAGAGACAGTCTAGAAGCAGAGAAAAAAAGGGAGTCTGAGAAATCAGGAGTTCGTCTGAACACTCAGATGACGCATGCAGTCACACCGAATCACTCGCTGAGACGTTGCCCCATGCATGGTCACCCGCCGTGTAGAAACTGCCTTAGTGCAGCTGAGGGAACAGTCCTTCTTGGTCCCTGCCGCATAATACACATTTATATTCACATGTGCCTGTTGTGGGAGCAGGGCCGGCAGAACAGCATGATCAGGGGATCACAAGAATTATCATTGCCAAAGACAGATTCTCGTGGGTACATCGTGCGAAGTGAGTGGTCCCGAACTTCACGGAGCCCATCCAACAAAGCCCCATCAGTAGACGAGAACAGAAGCAAGTCTGCCAATCTTAAGGTCCCCAGTAGCTCCACCACGTCCCGCACTTCATCTGCCTCCCCCAGCCAGCAGGACTCTCAGCAGGAACTGTCCACGCAGCCCTTCCCGCCCACCCCACCCGTGCCACCCACACCACCAGCGCCTACAGACTCCTTCCCTCCCACACCCCCGGAGCCCCAGCCCCAGTCCGTGTCCCAGCACAGCAGCAAGATGCATGAGAACACTGACACCTGGCCACATGGCATTCCGCGGGAGATGCGGGACCCCCGGGACCCCAGGGACCCCCGGGATCCCCGGGAGATGCAGCAGCGAGAATATCCCCGTACACCCCCCACTGAATGGAAGCCCTATGCCCAGCGCAAGGCGCACTACTCCTCCCAGCTGGACCGCGACTGTATGTCTGACCTGCCCCGGCAGCGGGAGGAAGAGGACGACAATGAAGAAGCCTATTGGTCATCCGTGAGGACACTGTATGAGAAGACCCCAAGCTGCTCGCGACCCCGGCCGCCCAAACCCAAGCACGCCATCACCATCTCTGTGTCATCCCGAATTCTCTTCAACATGATGGACGGCAGGAAAATCTACGAGGAAGAGGGTCTGGAAAAGTACATGGAGTATCAGCTCACCAACGAGAACGTTATCCTGACTCCAGGACCCGCATTCCGCTTTGTCAAGGCTCTGCAGCATGTCAATGCTAGACTCCGAGATCTGTATCCTGAAGAACAGGACTTATTTGATATTGTACTGATGACTAATAACCATGCCCAAGTGGGAGTGCGGCTTATAAACAGCGTCAATCACTATGGCTTACTAATTGACCGCTTCTGTATGACTGGTGGAAAAAGCCCTGTTGGCTATTTGAAGACCTATCTTACCAACTTGTATCTTTCGGCGGATTCTGAAAAAGTCCACGAAGCAATTCAAGAAGGGATCGCCTCTGCAACAATGTTTGATGGAGGCAAAGACATGGCTTACTGTGACACACAGCTCCGTTTGGCTTTTGATGGAGACGCTGCCATCTTCTCAGAAGACTGCGAACATCCTACCAAAGACCACGGGATGGACAAATTCTTTCAACAGGAAACACAACATGAGAATAAATGCACGGCTCAGGGTGCCTTGAAAGGCTTTCTGGAAGAATTAGGCAGACTGCAAAAGAAGTTCTATGCCAAAGACCAACGGTTATGTTGCCCCATCAGAACTTACCTGGTTACAGCCAGGAGTGCAGCCAGTTCAGGTGCCCGAGTGCTGAAAACCCTTCGCTGCTGGGGTCTAGAGATAGACGAAGCTCTTTTCCTTGCTGGAGCCCCCAAAGGGCCCATCTTAGTGAAAATACGGCCCCACATCTTCTTTGATGACCGCATGTTCCAAAGTGAAGGCGCACAGAAATTTGGCACAGTCGCAGCTTATGTACCTTATGGCGTTAATCAAAAAATGAACAATTAG
->XM_037725972.2 PREDICTED: Dermacentor silvarum acetylcholinesterase (LOC119465175), mRNA 
-TGCTGGTGAAACACGCAGTGTCGCAGGAATCCCGGCTACCACTAGCGCATTGTCGGTTGTACTGGCCCAGAGCGTTTTTTATCTGGATAGCCGCTCGGGTCCCGGAATCGATATTAGAGGACGAGGCTAAATCCTCAACGACCATAGAAATGGCGACCAGAGCAGCCCTCCTGGCGGCCATTTTTCTCGCCGTCATGCTCATTGCCATGGCCGACGATGCATTCGTCAAGAAGCAGACCACGGAAGGCATGGTTCGCGGCAACGTGATCCGCGCCCTGGGCAAGACTGTCGAAGAGTACCGCGGCATTCCGTTCGCCGAGCCACCTGTAGGAAAGCTCCGGTTTCGGCCTCCAGTTCCAAAAAGACCTTGGGAGGGCACCATGGATGCAACCGCTGGAAACACAGCCTGTCCTCAGGTGCTGGTGGAAGGAATCCCGCTAGGCAACCTGAGCTTCACAGAGGACTGCCTCCAGCTGAACGTATGGGTCCCAGAGGTCGCGATTACCCCAGGTTCGCGTCGGCCTGTACTTGTGTGGATCCACGGAGGAGCCTTCACCTTAGGCAGCGCGAATATGGCGAACAGTAGCGGCGTCTTCCTCGCCGCGCTGGGCGATGTAGTCGTCGTGTCCGTGAATTACCGTCTTGGCATCCTGGGCTTCATGAACGCGAACTCTCCTGAGGCGCCAGGCAATGTTGGCCTCCTGGATCAGAACATGGCTCTGAAGTGGGTGCAGCGGAACATCGGACATTTCGGAGGTGACCCCGAGCGAGTGACGTTGCTCGGGGAGAGCGCAGGCTCAATGAGCGTGCACGCGCAAATTATGTCGCCATTAAGCGAAGGCCTCTTCAAGAGGGCAGTTTTGATGAGCGGTACCATGTATAGCTTAGACACGTGGGACACAGTTCCGGAAAGCATGGTCAAGGCAGACAAGGTCGCTAACGCTGTTGGCTGCTCCAACGGTAGAACCATCGAGCTGTCATCTAATGCGGAAGAAATCGTGGACTGCATGAGAAACAAATCCGCTGATGAGCTCGTCATGGCTTCTAAGGAGGTGACGGTACCAAAGCTGGCCCCATTTGCGCCTACTTATCACAACGAGTTCCTTCCCCGAAATCCATTCTTGGCCCTGAAGCGTGGTTTCTTCTCATCTGTGGACGTCTTAGCTGGCGTAACTTCAGACGAAGGAGCTGCGTTTCTCCTGTTCCCGTTGGTTCACGAGCTTTTGGTGGAAGACATTCGAGGTTCGCCACCAGAGGAGCTTATTAGGTCTCTTCGCAGCGCATTATGGCGAGTGCTTAAAGATGACATACCGAATACATTAGAAATGTACACCGAGGAAGCACCAAAGGACGATAACAACGCACTGAGACGCCAATACATCGACTACGTGTCCGACAGATTGTTCAACTGCCCTCTGCAGTTCTTCGCGGAAAATCACAGCCGAAGGGGCAACAAGGTTTTCACGTATGTGTTCGCCGACAAGCCGGAGATGTTTCCACTGCCTGGGTGGATGGGAATGCCCCACGGCATCGACGTAGCCTTCATGTTTGGTCACCTCTACGCAGCAAATCCTGATTCGCCAGATGGTCGCATCTCTGAGGTCTTTATTAGACTGCTGGCCAGCTTCAGCGAAAACGGGATTCCCGAACTTCCCAACAATGAGACGTGGCCACAATACAGCAAGGACTTGCCAAGCACAATCGTTATGAAGAACGGCCTATTTAACGAGACACAGGGATTCCGCTCAAGCTACTGTGAACGCTGGAGGCCTTTGTATTAAATGTGTCACTCCACAA
->HQ089085.1 Uncultured Arthrobacter sp. clone F5OHPNU07H9DXX 16S ribosomal RNA gene, partial sequence 
-GCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGTCCTATGTTGCCAGCGGGTCATGCCGGGGACTCATGGGAGACTGCCGGGGTCAACTCGGAGGAAGGTGGGATGACGTCAAATCATCATGCCCCTTATGTCTTGGGCTTCACGCATGCTACAATGGTCGGTACAGAGGGTTGCCAACCCGCGAGGGGAAGCTAATCCCACAAAGCCGATCGTAGTCCGGATCGCAGTCTGCAACTCGACTGCGTGAAGTCGGAATCGCTAGTAATCGTGGATCAGCATGTCACGGTGAATACGTTCCCGGGTCTT
->XM_026579881.1 PREDICTED: Papaver somniferum tRNA-specific adenosine deaminase TAD3-like (LOC113333371), transcript variant X2, mRNA 
-CCAAAATATTGCGATGAAGAAGTGGGAAATCCTTCACATCCCAGACAAGATTCCGTTTAAACTTGATGAACAACCCACGATCGACGTCTTTGCTTCAGTTATAGAGCCAAAGCTTACCGATACTCTTGAAGTTAAATAAAGTTGCACCAATGGAGATTTATCGACATATTAAGAGGGTGTGGAAGAAGAAATCCGCGGAAGGAGGGGATTTTCAGTTAATACTGATTTTATGTCTTGTTGGTGAGAATAGGAATGAGTTGGAGAGTATACCTGATGATGTACTTGAGTTGATAAATGCCCACCAGTTGAATCCATATATTACAAAGGTCCATAGGTATGCCGCGATATCAAAAGAAGAATGGAGAGAACAATGCAGACTTTGGCCAACATCTTATCATCCGCCAACCTACAATATTGAGGGCATTACAGGATTTAATGAGGAGGATTCAGAATCAATATTCCACTTCATGAAGATGGCTCTTGAACTAGCGAAAGTGGGCCATTGCACCGATGAGGTAGTCAATGCAGCAGTTATAGTAGATCCTTCAACTAGGCAGGTGATTGTTAGGGGCAATGATCAAACATGTCAGCCAAGTACATCCACAGTGAGTAATACCAGCTTCGAATGTGGTTCCGTTGAACAAAAGGGTTTTGCTACTTCCCATCAATCCGATGCAGATGCTGTAGCAATCAAGGAGACTCTGTTTTCCATCTCCAGTTTTGCAGTTGCTGAAAATAAAGAATCATATACTGGCGTTTCTTGTCTATATCCTTGGAATTGGACTGAGCAAAACTCTATTGCTGGAAACACATATTCCTGGCATCCTCTGCAGCATGCAGCTCTTGTTGCCATTGAACATGCTTCCTCTAGGGATAGGCGCCTATTTCCTGGGCCGGTGGATCCTGAAGATCAATCTATCAATCAAGTGGATCACACAATCTCTTCTCCCAATAGCTCACCAGCCAAAAGACAGAAATTTGATTTGACAAAAGATGTCAAGGTTCTGAAAGCTTGCTCTAATGGTGATTCTCATTCTGAAAGGGGTGAAAGGCCTTACTTGTGCACTGGTTGTGACATTTTTGTCGCTTGGGAGCCCTGTACGATGTGTGCAATGGCACTTGTTCATCAAAGAATTCGGCGAATATTTTATGCTTTTCCGAACCCTAACTGTGGTGCACTAGGCAGTGTTTACAGACTACAAGGAGAGAAAAGCTTGAATCATCACTATGCTGTTTTTAGGGTTCTATTACCGGAGGAATCCTTGGAAACATGACATGGAAACCACATCTCGATGATGTCCAACAAATGTTAATCTAATGTTGTTCTACCATACAGTTTTTCCAAACGAAGGATGGTAAAGCTGAAGTTTATTGGAACACCCTTATGTCTGCAAGTGAAGGTTTTGATAGAGAGGTGCTTGGAACTTGCCATTATTTATTTTTCTTTGTTTTGATGTAAACTTATGTTGTGTTGTGCTATTATATAAACATCAATGTTCATAGTTTTTCAGAATACACCGTTGTAACTGTGACCGTTAATGCTTA
->XM_020573339.1 Polysphondylium pallidum PN500 hypothetical protein partial mRNA 
-ATGAATAAATCTATAATATTGTTTTTATCTTTTCTAATAAATATAATTGTTGTTGTTAATGGCCAATGGCATATTGAATTCGAATATTCAGCTGCTGGATGTGGTGGAGTTCTGAATAGAGCCTCATCATTTTTGAATAATATGTGTTATAATTACGATAATGGTGGTCCATATTCACATAGATACATTGTATCTGGATCTACAACACTCCGTCAAATATTCAGTAGTACTGACTGTTCAGGAGCTCCAACTACACAAGCTACTTTCGCTGGAAATACATGTTATGATAATTTAATGAAATATGCAATAGTAAATGAACCTGCTATTTCGCCAGGTGGTTGGATTTCATTAGAACGTACTCCTGGAAATGCTTTATCTGGTTGTGGAGTTTATGAAAGTGAAAGACATATTTTTAGATTGGCTACTTGTGTCAAGACCTATGATCTTCCTAATTTTCCTTTCAATACTTATTTTAGTAGTGGTTCGGTTGGCCATGTTTACAATTTAGTGTGTCCCAATACTCTTTTCAACTTCCAACCGTGTAGTAGTGATCCCCAAAGAATTACATCAATATTAACACCAACCATTTCCTATTCAATAACCAATCCAACTCTTATCAATTCCAATACAATTCTTTTAAATCCTTTTACCAGCAACTTTAAATATACATACAAATTCCTTACTGAATATTTTAACCCCAACACCGGAAGTTTTGTCGTTGCATGCAATCAATATTCATCACTGGCATGTCAATTCTCTGTTCCAGCTGGAATTCCTTACACCTATGTTAGAGTTAGAGCTAACGGTGATGAATCATTAACTGCTGCTCCTATTTATACATCACCTAATTTTAATTTACCAATGCCACCTGTTATGAATGCAATTAATTCAATCATTACCACTACAAAATCTGTACAATTTTCATATTCTGCTACCAATTCCCCAACTTCCTATACTGTCAATGTGAATAGTGTTCCTCGTCCTGAATGTTCTGGTTTAACTACTTGTAAAATAAGTGGATTGACACCAGGTTCTCCCTATTCTATTTCTGTCTCTGCTACAAATGGTTATGGAACATCAACTCCTGTTTCTGCACCCGCTGGTAATCTTTATGCCAGTATCAAAATTCAAACGATAACTGCAACTCCATCTGCTGGTCAAATAGTGGTAGACTATACTTCTTTAAATGGTATCCCAGGTCAAACCACTTACACAACCACATTAAATAATTATCCAGGTGGTTGCACAGGTATTTACACACTCCGATGTATAATTAGTAATCTACCAGCACAATTTTCTACAACTGTAACTGTAGTTGCTACTAACGATGGTGATTCAAATAGCGATGTAAGAAGTATTGACTTTTTGGCACCAGCCATGAATCCAATTGTAATGTCCTCAGTCAAAACAAAATCTATTACTTTCACATACTCAGCATCGAGAACACCTACTTCTTATACTGTTTTGGTTAATAATATTGCACACCCAGAATGCTCGGCAACCACTACTTGTATAGTCAGTGGCTTAACATCTGGTTCCCTCTTTTCAATTTCCATAACTGCTACCAATGTAGCCGGTACCTCTCCTGCCACACAAACTAGTGGAACTTTATATCCAGATGTTGTTGCTCCAACTGTAACATTAACTCCATCAACTAGTACCATAGTTGTTGACTATGAGTCTTTGGGTGGTATAACTGGTCAAACTCTATACACTACAAAACTTGATAATACACCAGTATCTACTTGTACCAATATTGCTGCTTTAAGATGTACTATTACCGGACTTCCAGGTCAATTTGCAAATGACGTGACTGTTGTAGCAATTAATGATGGTCTTTCACAACAAACCACTCAAAGAGTTGAGTTCTTAGCACCTGTTGTTAATCCAATTACAATAGTTGAAAAGAAAACCAAGTCTATTACCTTCTCCTATTCTGCTTCTCGTTCACCAACTTCATATGATGTCAGTGTAAATGGACTTTCCAATCCACAATGCTCTTCGAAAACCACCTGCACATTTACTGGTTTAACAGCAGGTTCATCATATACTATTCAAGTAACTGCTACTAATGGTGCTGGTATTTCTCTACCAATTACATCAACAGGAATTCTTTATCCATCAGTTGATAATTTATTCTTGATGTCTACACCAACTTGGAATAGAATGTTAGTGGAATACAATTCAACAGGTGGTTTCCCAAATAACACTGTTTATACTACACAAATCGATGGAGTCAATGTACCTGGTTGTATTCAAATTGCTTCATTGGAATGCCAAATCAATGGTTTAAAGGCACAATATTCACATAATATTACCGTTTTGGCTTTCAATGATGGTGATACCATTCAATCATCTTTAAATGTTACTTTTAATGATATGGTTCCTATTACATCATCTCAATTTATTCATGTTGAATCAACTCAAAATACAATCAATGTCAAATGGAGTGCTTCAACTGGAGGTGTACCTGGTTTAACTGTCTATGATTTGTCTTTATCAATTGATAATTCATCATGGATAGTAGAGTTTAAAAATATTACCATCACTGAAGCTACCATTTCAGACTTAATTCCATCGGTCAACTATTACTTAAGAGTATCAGTGAAGAATTCAGATAATCCACCAATTCATACCTATACTAATACTCAAACCTTGGGACTTGGAGCAGAGGATTGTAAATGTACCAATGGTATCTGTGATGCCAGTTTTAAATTCTGTTTATGCAATGCTGGCTGGACAGGTTCACGATGCGAATTTAAGCACGATGTCGTTGAAGGTGAGATGAAACCACCAACTATAACACCAAACCCCACTAGACCTGAGGTAATTATCGACAATGGTGATTCCCAATACACTTTCAAAATAAGTACAATCATTGAAAGAAGTGAACTATTAGAAGAGATCTCTAGAATGGACCTTTCAAGCTTGAACTGGGATCTCCAATCAAATCTTAGTACTATTATTAAACATCCCAATAGTTTAATGAATGTTTCAATGAACCAATGGATTTACTCGGCTAAAATCCAGAAAGCCGAAGATTTAATTATCAAGTTCACTCAAATCAACCCGATATCCAATGAATCAACTCCTACCTTCCCAATGGAATTTGCTGGTGAATCGTTCAATTTGACAATTGGTTCACTTAAATATCAAATTGAAGTTAAGAAATGGGATTTTACAACCAAACTTAACCACTTGGAAATTCAATCGACTGTTGAATCTAAACTTGATGACTGTGTTAACCCAGAATCTCAATTTTCAGATGGTACCGGAATTTCAGATATTGCAATTCGTCAACCTTCTGGTTATTTCTTATTTGGCAGAGTCTCCAAGAGAATTCTTCTTGATAAAATCCCTAGAATGTCTACCATTAAATATAATCAAGTAAATGTTTCAACTGCCACTATTTCAACATTGGTTAGCCATTTCCAAGATAGTTTGGTTGTAGATCCAGATTTCTCTGTACTTTTAGATCTAGATAGAAAATCAGATGTTAAGTGTGGTGGAGAAAAGAAAACCAATGCTGCTGTTATTGCAGGATCCGTCGTTGGTGCAGTTGTTGGAGTAAGTTTAATCACAGCCAGTGTAATCTTAATCAAGAAAAAGAAGATTGCACAGAGATACAATAATTATTTGACTCAAAAGTTGAAACCAAAGATGATGGCAGACAAAAACAACAATTTGATGTACCTCTTAACCGATCTAGGTGTCTCTAATTCACTATAG
->XM_030616062.1 PREDICTED: Syzygium oleosum uncharacterized protein At1g24485-like (LOC115689878), mRNA 
-ATGGCAGTCCAGATGTTCTTGTTGATGCTTCTCTTCATTGAAGTATCTCTTTCTCAAGCATCACTGTTGAGAATTGATTGTGGGTCTCAAACTGGGTATGAGGCCAAAGATGGCAGCTACTGGAGCACCGACGATGAATTTGTCAAGGTCGGCAACGACATGCCGATCTCAGCCGGTAGTTTCTCCAAGTGGACCCAACTCAACACTCTTCGAGTCTTCACAAAAGAGAAAAAAGTTTGCTACAAATTGCCTGCGCAACCGTCGGTCCGATACATGAGCAGAGCGACATTTTATTACGGCAACTACGACGGCCTTTCGAAACCACCAACTTTTGACTTGGAGTTTGACGAGAATAATAGGAAAACTGTTGTCACCTCAAATACAGATCCGCAAATTTATGAATTGATTTACACATCGGGTGCGGACGACATTAAGGTGTGCTTGATTCGAACATCGGATGCTCAGTTCCCATTCATCAATGCGCTGGAATTGTGGCCATTAGATGATAATATGTACGATGGTATGACCCGAGACATGGCTTGGCTCAGCAATTACCGCTACGACTATGGTGCAGTGGCGGACACTGTCGATGATTGGATTTTAGGGTACCCTACTGATTCGGCCAACAGAATATGGGTGCCAACAACTCCATCCGACCTGAATCAGACGAAAGCCTCCGCAACTTACTTCTACGACAACGGCGATAACAACGTGCCCAACGTTGTCATGTCCCAAATGGTCGAGGCGCCAAATTTAACGTACCCAATCAGCTTAAGCTTCAGCATCAACGACGGGATCAATCTAGTTCACTACGTGACCGCGTATTTCACCGAGACCCATTCACTAAACGAGAACGAAAGCAGGTCGTTCGAATTCAACGCGAACAACAAGTTCGTCTCGACCATGAACCCGAGGTACGAGTACTGCACGTCGGTGTGGGCATTCGTGCAGTCGAACGGTACTCTAAATGTTCAGCTGCGCGCAAGCGGGAATTCGACGCTGCCTCCTTTGATCAGCGCCATTGAAGTGTACACGGGCCAAGCCGTACATTATCCTAAGACAAGTAAGTGGAAGGAAGTCGGCGGCGGCGGCGGCGGCGTGCTCTTTCTCATTTTGATTGGCTGTGGGTACTATTTGTGCTCTAAATCGAGGAACGACGGTAGACCAAACGGCGGTGGACCAAACAACGGTGTTATAGAAGAAGCCCCACCTCGGCGCCGTTTTTGGTGGAGAAGAACTCGCTACGTTGAGGAGGAGGTTGTTGAAGCTCACGCGTAG
->XM_031145784.1 Lachnellula hyalina Eukaryotic translation initiation factor (SPBC4B4.04), partial mRNA 
-ATGGCAGAGCCTACGCAGTTTGCATACAGGACACAGAAGACGGTGGGCATCGTGGATGCAGCGCCCGTCTATGAGCCCTTGAGCGGGTTCCAGAGACCGGATGTTGCCTCTCGCTGCTGCACGTACTCGCCGTGCGGGCGGTACTTTGCCTGGGTCAGTAACGAGGCAGTCACTGTAGTCGATGCCTCCGTCGGACACGTCATCACCACTCTCTCCATACCCAACGTGTACGAATTGGGTTTCTCGCCGCGGGGCTCATATCTCATCACATGGGAGCGGCCGTCCAAGGATGAGAATGGGGATGCCGTGAAGAATCTAAAGGTCTGGCGCACGGTGGAGGACATTGCAGAGGGCGCGGAGAAGCAGGTTGTAGGGCGGTTCGTGCAGAAGTCGCAAACGGGGTGGAACTTGCAGTACACTTTCGATGAGAAGTACTGCGCCCGCGCTGTCACCAATGAGGTGCAGTTCTACGAGAGTGACAACTTGGGGTCGGTCTGGAACAAGCTGCGCGCCGAGGGCGTTACAGATTTTGCTATTTCACCTGGCAACAACCAAGCTGTTGCCGTCTTCATCCCAGAGCGCAAAGGTCAACCTGCTACCGTCAAGGTTTTCAACGTCCCTCAATTCGCCAGCCCGGTTTCACAAAAGAATTTCTTTAAGGGCGACAAGGTCACGTTGAAGTGGAACCAGCTGGGTACAACCCTTATTGTTCTTGCACAAACCGAAGTCGACAAGACGGGCAAGAGTTATTACGGAGAAACTACACTATATGTGCTGAGTGCAAATGGTGGATTTGATTCGAGAATTACTCTGGACAAGGAAGGCCCAATTCATGATGTATCGTGGTCCCCTAATTCGAAAGAGTTTGGAGTGGTCTACGGATACATGCCAGCCAAGACAACCATCTTCAACCAAAGAGCTGTTGCAACGCATACGTTCGATCTCAGGCCCAGAAACACAATCTTGTTTTCCCCCACCGGTCGATTTGTTTTGGTTGCTGGTTTTGGTAACCTTGCAGGGCAGATGGATATCTATGATCTCGAAAAGGATTACAAGAAGATCTGCACTATCGAGGGTGGCAATCCAAGTGTCTGCGAGTGGAGTCCAGACAGCAAATTCATCCTGACTGCCACTACTAGTCCCCGTCTTCGTGTTGAAAATGGAGTTCGGTTGTGGCATGTTGGAGGAGGTATTATGTACAATGAAGATATGGTGGAGTTGTATCACGTTACCTGGAGACCTCAATCACTGGACAAGCTTACGGCTGGGGATCCTTTGCATCCAGTCCCGACTCCTCATGCATCGGCTCTAGCGTATCTAGGTACTGTCAAGACGCCTTCCAAGCCTGCGGGCGCTTACCGGCCACCTGGAGCTCGCGGAACCTTAACACCATCGCATTACAAGCGTGAAGACGAAGGAGGGGCCGCACATGTTGTTAGTAACGGCACTCAGCTGGTAGGATCCAACGGATTTGGCAGAGGTAAACGACAAATCCCGGGAGCGGAAGCAGTGGAAAATCTGCCACCTGGAGCGGATCCTAGCAAACCAGTCCCAGGAGGTGCCGAGGGAGATGAGAATCTCTCCAAAGCAGCTTTAAAGAATAAGAAGAAGCGAGAAGCAAAGAAAGCCAAGGAGGCAGAAGCCAAGGCCCAGGGCCTAGTCCCTTCGCCCGATGGAGGAAATGCCGCTCCCCCCGATGTCCGCAGCCCTGAACGCAGAGATAGGCGCGACCATCAACGTAGCCGATCCAAGGGAAACCAAGACATACGCACCCCATCTCAGCAACGATTCCGCAGCAATACCCAGCAAGGCAAACAGCCACAGTATCGTCAGCAGAACGGCGGAGCTCCCACGGGAAATATGAACAACCTCTCTATCAATTCCACCCCACAGCCGCCAAAGCCGGTGCCTGCGCCTGAGCTCTCTGTCACATCACCTAATGGTGGCAGCCCAGATGCGAAGAAATTACGAGGACTGCAGAAGAAGATCCGCGCGATTGAGGATTTGGAAATGAGGCTCGCAGGAGGTGAGAAGTTGGAAGATACTCAGCTTAAAAAGATTGGCACGAAGTCTCAGGTGCAGGGAGAGCTTTTTGCTTTGGACCGTGAAAGTTAG
->XR_007275131.1 PREDICTED: Beta vulgaris subsp. vulgaris uncharacterized LOC125498264 (LOC125498264), ncRNA 
-AAGATGATCTCGGGGGTCGTCCTGGGAGCATTGTGCAGAATTATGCAACAAAGGGTGGTTCCGAATTTTTTTTCATAGTGAACATACAGGTCCCTGGATAAAAAACGTACAATTTAGCACTGTACTATATGACGAGTAATCTGGAAGATGCACCTCTGCTGCAGAATTTCGTTGACAGAGACGATGCTTACAGAAATTCAAGGTTCAAACTTATTCTATACATATCTAAGGTCGGTAACATTCTGGTCTGAGGCTTGGGAATTATGCTATCTTGTCCCTCTTATGAAATCGATAGCTCGTATTGAGCATGCATTGGAATGCTTTAAAGGATTATTTCCTGGACATACAATATGTTTTCCAACTGCCTTCTCATATTTGAAGTTGCAATCACACAAATTTATTGGCCAACATTAAA
->XM_022542561.1 Aspergillus glaucus CBS 516.65 hypothetical protein (ASPGLDRAFT_163897), mRNA 
-CCGAGCTACATGCTGGGAAGTTTGGAGCAACTCCCTCTGGAACTCATTAACATGGTGCTTATACAGCTCGAAATACAGTCACTGACAGACTTCCAACGCGTCAATAAACGAGCTATGCAAGTAGTAGACTCGATTCCACAATACAAAAAGATCATCCTCCATGCCCCTGCCTCAATCCGGGGGAGCCTCAGCATCAGCACTGGCAGTTTGTTTTCTTGTCAGGAACTGTACGAGAAGCTCTGTACGGCGGAGTGCGACAGCTGCGGTGACTTGGGTGGATACCTGTACTTGGTTACATGCCGCCGCATTTGTTTTCTCTGCTTCACCAAGAAGACCGAGTACCTCCCACTACTACAGGCGGACACGATACGGAAGTTTAGACTTCGCCGTGAGGATATAGCAACTTTACCTTCTATGAATAGTGTCCCCGGCCGCTATTCACCACGAGAGATCAAATGCCGTACTCAGCTTACCTTAATCGATCATGACGCTGCGCGACAAGCTGGAATTACTGTGCACGGGAACATCAATGCAATGGAGCAATATGCCTTGGAAATGACATCTAAAAAACTGGAGCAATACCAGTCTCGAAAATCAATACACATAGCAGATTGCCCGAATCTGCGTCGACCCAGATCTGAAGACATTTTTGATGGGCATTCACCTAATCTCAAACGCTTCTTGGGAATTATCCGTGCGCCATTTCTTAATGCTCGTACAGGGTCTCTGGAATGGGTCTTCCATTGTGCCGCATGCAAACCCCATCATTATAACAGACCGCTCCATTGGCGCCGAAGGTATACAAGGAAGAGTTTCGAAGATCATATTAGGGAGTGTGGAGAGATTATACATGGGAAGCACAACCAACGCGTGAGATGAAAAGAATAAGCAATGAGGATACGAAATATAATGGAAGGCAATTGCCCTGTGTCAGGTGATAGAAGATAACCGTCGGTAGAAATAAAAGAAACCAAC
->XM_031654791.1 PREDICTED: Papio anubis FA complementation group C (FANCC), transcript variant X2, mRNA 
-GCACCGCTCACACGTGTGCGCGCGCAGCCCCGCCGCCGAGCCACCGCGGGAAAATTCCAAAACCCTCAAAACAAAAAGCCAATCCGAGGCAAAGCCAAATTTTCAAGCCACAGGTCCCGGGCGGTGGCTTCCTTTCCGCCGCTGCCCAAACTGCTGAAGCAGCTCCCGCGAGGACCACCCGATTTAATGTGTGCCCAGCATTTCCTTCAGTGCTGGACAGGCTGCTGTGAAGGGACATCACCTTTTCCCTTTTTCCAAGATGGCTCAAGAGTCAGTAGATCTTTCTTGTGATTATCAGTTTTGGATGCAGAAGCTTTCTGTGTGGGATCAGGCTTCCACTTTGGGAACCCAGCAAGACACCTGTGTTCACCTGGCTCGGTTCCAGGAGTTCCTGAGGAAGATGTATGAAGCCTTGAAAGAGATGGATTCTAATACAATTTTTGAAAGATTCCCCACAATTGATCAACTGTTGGCAAAAGCTTGTTGGAATCCTTTTATTTTAGCATACGATGAAAGCCAAAAAATTCTAATATGGTGCTTATGTTGTCTAATTAACAAAGAACCACAGAATTCTAGACAATCAAAACTTAACTCCTGGGTACAGGGTGTATTATCTCATATACTTTCAGCACTCAGATTTGATAAAGAAGTTGCTCTTTTCACTCAGGGTCTTGGATATGCCCCTATAGATTACTATCCCGGTCTGCTTAAAAATATGGTTTTATCATTAGCGTCTGAACTCAGAGAGAATCATCTTAATGGATTTAACACTCAAAGGCGTGCTTTATCATCATTCTCTTACCACCAAGATGGTTTTAGATCTAAAATTCATGTGTTTTTGAGTCCATCATCTAAGTTGTTAACAAAAAGACACATTTACCGTGAGTTAATGACTCCCGAGCGATTGGCGTCCCTGTCACGAGTCTGTGTCCCACTTATTACCCTGCCAGATGTTGACCCCCTGGTGGAGGCTTTGCTCGTCTGTCACGGACATGAACCTCAGGAAATCCTCCAGCCAGAGTTCTTTGAGGCTGTAAACGAGGCCATTTTGCTGAAGAAGATTTCTCTCCCCATGTCGGCTGTAGTCTGCCTCTGGCTTCGGCACCTTCCCAGCCTTGAAAAAGCAATGCTGCATCTTTTTGAAAAGCTAATCTCCAGTGAGAGAAATTGTCTGCGAAGGATCGAATGCTTTATAAAAGATTCATCGCTGCCTCAAGCAGCCTGCCACCCTGCCATATTCCGGGTTGTTGATGAGATGTTCAGGTGTGCACTCCTGGAAACCGATGGGGCCCCGGAAATCATAGCCACTATTCAAGTGTTTATGCAGTGCTTCCTAGAAGCTCTGGAGAAAGAAAACAAGCAGCTGCGGTTTGCACTCAAGACCTACTTTCCTTATACTTCTCCATCTCTTGCCATGGTGCTGCTGCAAGACCCTCAAGATGTCCCTCGGGGATGCTGGCTGCAGACACTGAAGCACATTTCCGAACTGCTCAGAGAAGCGGTTGAAGACCAGACTCATGGGTCCCGCGGAGGTCCCTTGGAGAGCTGGTTCCTGTTCATTCACTTCGGAGGATGGGCTGAGATGGTGGCTGAGCAGCTCCTGAGGTCCGCAGCCGAACCCCCCGCAGCCCTGCTGTGGCTCTTGGCCTTTTACTACAGCCCCCATGATGGGAGGCAGCAGAGAGCACAGACCATGGTCCAGGTGAAGGCTGTGCTGGGCCACCTCCTGGCGATGTCCAGAAGCAGCAGCCTCTCAGCCCGGGACCTGCAGACAGCAGCAGGACAGGACACAGAAACAGACCCCAGAGCTCCTGCACAACAGCTCATCAGGCACCTTCTCCTCAACTTCGTGCTCTGGGCTCCTGGAGGCCACACGATCGCCCGGGATGTCATCACCCTGATGGCTCACACTGCCGAGATAACTCACGAGATCATTGGCTTTCTTGACCAGACCTTGTACAGATGGGATCGTCTCGGCATTGAAAGCCCTAGATCAGGAAAACTGGCCCGAGAGCTCCTTAAAGAGCTGCGAACTCAAGTCTAGAAGGCACGCAGGCCGTGTGGGTGCCCAGCATGAGGGATCAGGCTCGCCAGGGTCACAGGACAGATGATGACCTATGGCCACGCATTTGTGGAGTAAGTAAGTGCCCTCTTTGGGCTGTGAGAATGAGCCATACACGTCTTGGGAAGATCTGCTAGTATCTATTTTAAAAAATGCAGAGCCAGGTCCCTCAGCCCAGACTCAGTTGGACATGTTCACCAATGACTTGAGTGAGCCTTCAGCGCTCCTGGTGCCCGCCCGGCCAGACTGTCAGCTAGAGAATTACTAAAGCAAAGGCTTGGGTGGGAGAACAGGTTTCTAGTTTTTACCCAAGTCTAGATGCACATCTATTATTTAAAGATTCAAAGCCTTAGAACCAAGAATTTGGTGATGAACCATTGAAGAATTTAGAGAGAACTCAGCTCTTTTTAGACTCTCTTCAGGAGTCAGGGATCTGGGATACAGCCACGCTGTCGTGCTGTACGGAGAAATCTCCACGGGGAGTCAGCGTCCCTCAGGCTTCCCTTGCGTCTCCCTGGACCTGCCCGATAGACCACAGGAGCAGACAGAGCACACCCAAGCCTGCGTCTCCTGCACACGCTTTCCACTCTATTTGCTAAACGCTGACTGCCACCAAAGAGCTCCTGGGACATGAGAGGGGCCGGCAGGTGAAGGTGGAGGACGTGTTGCAGAAACATTCAAAGGCAGGATTCGTATCAGTTAGTTCTCTTGTTAAACGGAGATGGGAATTGGAAATTCCTGATAAAGAACTGACGTGGCTGGGCGCGGTGGCTCACACCTGTGATCCCAGCACTTTGGGAGGCCGAGGCAGGGGGATCCCTCCAGCCCAGGAGCTCCAGACTGGCCTGGACAACATGGCGAAACTCCATCTCTACTAAAAATACAAAAATTATTGGGGTGCCGTGGTGGGCACCTATAATCCCAGCTATTGGGGAGGCTGAGGCATGAGGATCCCTTGAACCCGGGAGGCAGGAGTTGTAGTGAGCCGAGATCATGCCATTGCACTCCAGCCTGGGCAACAGAGTGAGACCTGTCTTTAAAAAAAAAAAAGGCATTGTTGGTGTAATCTCAAAGTTAACGTTTATTTCACGTCAGCAGAGGATGCTTTTTCCTGTCAGAGACATTCTGGAATTGTACCGATTGTACATTCTTTTGTGCCTATTCTGTTTGTCAAGTGAGTCAAGACTTGCTTTTGTCCATTTTGATGTACGTGTGTTAGTCGGAGTCTTGGCTCCGTTTTGAGGCATGAGCAAAGTTTCACTGGATTAGAGGTTAACCTTTAGGGAAATTCCTTTTCTTGGTATGTGGCAATGCTAATAAAGCCACCTGAAGATCTGGAAAATTCCAGGAACTTTTCACCTGAGCTTTTCTTCTGAGAAATGCTGCAGTCAGAAGGGTGTGCTGGTAAAATATTTTGGTGGCAGCTGCCATCGTGATCATTGCTTTCATATAAGACGCTCTGTGCCATCATGATCCTTACCCTCATAAAACAAACACACTTCGTCAGAGGCGTCGGGGTTGAAAAAGGAGCTGCTTCACTGGAGTTGAGGGCCTCTCTCCTGTTCTGACTTTGAGCCAGAACTTGTGGCTGGCCCTGGAAGCTGACTCCACTGTGGACACGGTGGCAGCAGGGAGCCCCTAGAGGGAGGGTCACTGGGACCAGGCCTTCTGTCATCAAGGGGATTCTGGGACAGTCCCTCACCCTGTCCTGTGGTCCTGTTCACGGGGCTGGCCTTTCCCTCCTCCCCGGCCAGGCCTCTGACCATGCCCCTTCCGTCTTCTCCACTGGGGACTGGTGAAGCTGGGCGTCTGGAAGACTTCCTGGCCTGGAAGCCCTGAGCTCGGCCTGTCTGTAGAATCTCCCAGTTCCTTCACAGCTGCCGAGTCCTCTTGTGGGCGCGGTGGAAGCGGCTTTCCGGGCAGCCAGGGGTTCCCGGATAGGACTGTCCCTCTGGGGATGTGGCACCGAAGTGCCTGCTGGCTTCATGTGGCCCTTTGCCCTTTCCCGGCCTGAGAGACGCTCAAAGGTGGAGAGCCAGGGGAGCCACCCCTCGGCTGGTCCCTCCACCTCTGGGACAGGTGGCAGCCGGGCAGGTGAGGGCATGTGAGGGCCGCGGCTTCGCTCCTAAGCCCACGTCCTCCTCCTGTTGCCATCGATTTTTGGCAAAGTCTGGGCAGGTGCCACCGGGAAGGAATGGCGTCCGAGATGCTGGGCACGGCATGGTGCGGCCGAGGGGGCCTTGACATCGCTGGCGGGGCCTGGGCACAGGGGCAGCCACAGGGAGGCAGGGATGCCAAGGCCTGGAGCCACCGTGGAAGGAACTGCTCGAGGTCTGCAGAGGTGCCACAGGGCCCAGAATCTGACCTTACCTGACCTCTTCTAGACTCTCCCTGATAGTTTTTGATGAAGCATGTTGGTAAAACCACTACCCTCAGAGAAAGCCAAAAATACAGATGAGGCGGAGCTCGCCCCTCCAACCTGGCTGTTACTCACCTGGACTCCACGACATCTGTGGAATTCGTAAGCTCTTTAAAATCTGTAACTTGTTGTCTATTTTTTCATTCTAAATAAAACTTCAATTTGCACCTAA
->XM_047252959.1 PREDICTED: Schistocerca piceifrons cuticle protein 79-like (LOC124777512), mRNA 
-CGTTTCGCTTGGTGAGAATCTGGATGGTATATAAGGAAACGGCTGCGCTAAGAACTCTGTCAGTCATTCGTTGCCCATCTACCACCATCGCAAGAGCAACAATGAGGATCACGGTGTGCGCAGTTTTGCTGGCGGTGTGCTGCCTTTCTGCCGCGGAAGAGAAAGCGCGTGCCAAGACGGAGAAGCGAGGCCTGCTGGGGCTCGGCTATGGTGGCTTCGGCGGCGGCTACGGGGGCGGGTACGGCTACGGAGGCGGCTACGGGGGCGGGTACGGCTACGGTGGCGGGTACGGCTTTGGGGGCGGCTATGGGGAGGTCAAGGCCGTCACCATCACCAAGGAGGTGCCGGTGCCGGTACCGCAGCCGTACCCGGTGCCGGTGGAGAGGAGCGTGCCGTACCCGGTCAGCGTGCCCGTGAAGGTGCCCGTGGACAGGCCGTACCCCGTGCACGTGCCGCAGCCGTACCCCGTGCCCGTGGAGAAGCCGGTGCCGTTCCCCGTGAGCGTGCCCGAGGCCGTGCCCGTGGCCGTACCTCACCCCGTGCTCGTCAAGCAGCCCGTGCCCGTCGTCGTCAAGGACGTCGGCTTCGGCGGAGGCTACGGGGGATTCGGAGGCGGGTACTCCAGCTTCGGTGGCTTCGGGGGTTACCACCACTAAACGTCATCCGTGCCGTCGCAGCCACTCATCTGACAGCCATCTTCACAGCAGGACTGCCCAACCACCTATTTCCATTCGTATGTTTCCATTTTGTTAGATCGAGATCTCTATGTACCAAAAATTTGCAGATTACTGTTGATTTCAATAAAATATTGCAATAAAATT
->XM_046236555.1 Lentinula edodes uncharacterized protein (C8R40DRAFT_884233), mRNA 
-GGAACTTTCAAGTTATCAGACCTTCGATCTCGGTCCGTGATTACAGACAGATACATTCCAACCCCAATTTTCACTGCTTTTGTCTTATCACAACATTCATGAGTGGTGTTCAAAAGACTGCCATCGTCACTGGTGCCTCTTCAGGCATTGGACGATACACTGCTATTGCCCTCCTGAATGAGGGATGGAACGTTGTTGTCACTGCTCGGAGATTAGAGGCCCTTCAAGAAACACAGGAAATGTCTTCAAATGCTGAAAGCTGTCTTTGCGTGGCTGGTGATATTACCGATGAAACCTTTGCGATAAATCTCTTCGAGCAGGCAATTGCTAAATTTGGGCGACTGGATCTTTTGTTCAATAATGCTGGAATATCGTCCGCCCAGGTTCCAATTGAAGATGTCTCCTTCGACACGTTCCAAAATGTTCTGAACATCAACTTGGTAGCGCCTTTTATCTGCACTCGGGAAGCAGTCAAAAAATTTAAAGCTCAAACTCCCCCTGGAGGTCGCATCATCAATAATGGTTCCTTGTCAGCCCATGTACCGCGTCCGCACTCTTATGCATATACGATGTCAAAGCATGCGATGAACGGTCTCACCAAGTGTACTTCTCTCGACGGACGCGCATTTAACATTGCCTGTACCCAAATCGATATAGGAAATGCGGCTACAGATATGGGAGGACGGCATGGATTAGGTGCATTACAGCCAGACGGACGCATAATTCAAGAAGGCGTGCTTAATGTCCAACATGTCGCCAGCACGATCGTGCATATAGCCAGTCTTCCGCCTGATGTTACTGTTCTCCACGTCAACATCATGCCCACCAACGTCCCATATGTTGGACGAGGTTAATAGAGTCGAAGCGTAGGATTCAATATCATTCCGACTTATACAGAGTTTTCCTTCTATTTCCCCTTACAAGGTTCATATAAGTACATAGGCCTCGTGAAATAATTTGTCCGTATCCGACAAGCCTCTGATTA
->XM_053458426.1 PREDICTED: Spea bombifrons corin, serine peptidase (LOC128482252), mRNA 
-TGTTCATCTTCAGCACGTGGAAGCTGAGTGGAGCCGCGATCCCTGCGAGGGGAGAATGTGAGCGAGGAATCGCGCAGGGAAAGTGTTTGGGAGAGAGCCGGGCATGTCAGCCCACTGAGCATGCTATCAATGCAACAGTTTGCTTCCCTGCCTCCGGAAGACAGCTACCGGCCGGTCATCTGCGCTGACAGGGTCTTTGGAGCAGATGAAGATAATATGGGGGATGGCTGTTCTCAGAAGCCGGCATCTGCCAAGTACCTCCGTCTCTTGCTGCTAATACTCATCCCATGCATCTGCGCTTTCATTCTTTTGCTGGTTGTTCTGCTCACATTTGTTGGTGTGATAGACAGACACTGTTTTGACTTTAATAGGAGTGATCCGCTAACCAGCAGTATTGGAATCGGATCTCCTGACATTCCATTCATAAAGATGGATGACAATGCATCAGAAGGGACATTAATGAAAGGCTGGGAACCCCATCCCGCACTCTGGAATACTTCTGCTGTTGTAGCTGACCAAAGCTCTACCAACTTTAGTGAAATAAAAGACACTCCCCAGCAGGATCCCTTATACCCCTTTCCTTATACCACAGTAGATTATAAACGCTCAAGAAATAACGTGACACTGACCAAAGAGCATGACGCCAACCTATTGGAAAGCACGGGCGTTTGGACCACGCCATTGCTGAGTGACGCCACCATGTCTCCGACTGTGGAACCAATTGGGCCTCAATTTGTAGTCAGGGAAGATGCCTGTGTGAACATCTCATACAGCCAATGCCAAATGCTGCCATACAATAACACCGTCTCAAAATCAGTGTATTCGTTCGTCAAGAGCATTGAAATGGAAATGTTTCTCAAGTTCTTCAGCTATCTCAACCGCCTCAGCTGCTATCAGCACATCATGCTTTTTGGCTGCAGCCTGGCTCTCCCGGAATGCATCAGTCATGGCGATGACAGTTATACTCTCCTGCCGTGCAGATCATTCTGTGAGGCTGCGCAAGAAGGTTGTGAACCAGTGCTTGAGATGGTGAATTCTTCCTGGCCAGAGTTCCTGAGATGCTCCCAGTTTCGGAACAAAACAGACAATAACAACACAAGCCGAGTGTGTTATTCTCCGCAGCAAGAGAAAGGAAAGCAATCGCTTTGTGGAGAACATGACAGCTTTCTGTGTAACAATGGAATCTGCATACCTAGACAGTTGATGTGCAATGGATACAATGACTGTGATGACTGGAGCGACGAGGTACATTGCAACTGCAGTGATCATCAGTTCCGGTGCAATACAGGGAAATGCCTTAACCACAGCCTTGTATGTGATGGGTACGATGACTGTGGAGATCTAAGTGACGAGCAGAGTTGTGATTGTAATCCATTACATAGCTACCAGTGTGGAGATGGACGATGCATAACTTTAAGATGGGTCTGTGATGGTGACCATGACTGTGTAGACAAGTCTGATGAAGTCAACTGCTCATGTCATAGTCAGGGTCTCACCGAGTGCAGGAATGGGCAGTGCATTCCTAGTGCCTTCCGCTGTGATGGAGACAGTGATTGTAAAGATGGCAGCGATGAGGAGAACTGCACTGTAAGTAAGGGACAGGTATGCCAAGAAGGAGATCCAAAGTGTATTTCTCAAGCCTGTTCAGGAGCATGTGCCAATGATCCCAACTGTGGAACGCCTCACAACAAGACAAACTGCAGTCAGTGTGAACCAATAACCTTAGAGCTGTGTATGAACCTACCCTACAACTATACCCATTTCCCAAACTATCTTGGTCACAGAACTCAGAAAGAGGCTTCCATAAGCTGGGAATCATCTCTGTTCCCAGCCCTTGTTCAAACAAATTGTTACAAATATCTCATGTATTTTGCATGTACCATTCTAGTACCAAAGTGCGAACCGGAGACCAGTCAGCGGATACCACCATGCAGGTCACTTTGTAAACATGCCAAAGAGCGATGTGAATCTGTGCTTGGTATTGTGGGATTACAGTGGCCAGAGGATACAGACTGTACCCAGTTCCCAGATGAAAAATTAGACAACCAAACATGCCTTATGCCTGATGAGGATGTAGAAGAATGCTCCCCTAGCCATTTCAAGTGCCGTTCTGGACGCTGCATCTTGGCTTCCAGAAGATGTGATGGAGAAGCAGATTGTGAAGATGATAGTGATGAGGAAAATTGTGGATGTACTGAGAGAGGTCTTTGGGAATGCCCAGTGAACAAGATGTGCATCAAACATTCAATGATATGTGATGGATTCCCAGATTGTCCTGATGAACTGGAAGAGAAGAATTGCTCATCCTGCACAAACGATGAGTTAGAATGTGCCAACCATGAGTGTGTATCTCGTGATCGCTGGTGTGATGGCGTGGTGGATTGCAAAGACAGCTCAGATGAATGGAACTGCGTTACTCTGTCTAAAGGTGTGAGGTCCCTCCTAACCATTCACAGGTCTGCATCTGACCATCACGTATGTGCCGATGCTTGGGATGATGAGCTTACTCACTGGGTCTGCAAGCAGATGGGTTTAGGCGGCCCATCAGTGGCAGAATTTGCCCAAGAAGCTGATCATTTGGAACATAATAAAATGCTGCATCTAATTAAAGACTGGAAAAAGAAAAATGGATCTACATTTCACGAGCTGCTCATGAAAGGGCAGACTTGTGAAAGCAGAGCTAAAGTATCTCTGACATGTACCAGAGAAGATTGTGGACATCGTCCAGCCGCCCGAATGAGCAAGAGAATTCTTGGTGGCAGGACGAGCCGACCAGGACGTTGGCCTTGGCAGTGTTCTCTCCAGAGTGATCCCAGTGGACACATCTGCGGCTGTGTTCTCATTGGGAAAAAATGGGTGTTAACGGTAGCTCACTGCTTCGAAGGAAGAGAAAATGCTGCCGTATGGAAGGTTGTATTTGGTATAAACAACTTGGATCACCCATCTGATTTCATGCAGACTCGCCTTGTGAAGACTATTATTCTCCATCCACGGTATAACAGAGCAGTGGTGGACTACGACATTAGTATTGTGGAACTGGATGAGGACATTGTGGAGACTAGCTATGTGAGGCCAGTTTGCCTCCCAACTAAGGGCCAGTTGGTCGAACCAGATACGTATTGTTACATCACTGGATGGGGACATATGGGCAACAAAATGCCATTTAAGTTGCAAGAGGGAGAAGTTCGGATTATTTCCTTGGAACGCTGTCAGTCTTATTTTGACTTGAAAACCATAACATCCAGGATGCTGTGTGCTGGGTATGAGTCCGGGACAATAGATTCCTGCATGGGAGATAGTGGCGGTCCCCTTGTCTGTGAACAAGAAGGAGGACAGTGGACGTTATATGGACTGACTTCTTGGGGATCTGTATGTTTTTCCAAAGTTATGGGACCTGGAGTTTATAGCAATGTTTCCCACTTTATTGACTGGATTGAAAGACAGATATACATTCACAGCTTCTTAATCAACTAAAGACGTATATATATATGAATAAAATACACATATTTAAAGGCAAACAGCAAAAATTGCCTTAACCACCAAGGAGGTTTTAATGAGTGGAAATCCTTGCCCTGGGTATTAATGAAAATGATATCTATATATTTTTGTTCTAAACGTTAGGTGTTTTAGTCTAAAGCTTTTTGACTTTTTGTACATATCTGTTCACGGTTATGTTTTGCTGTGTAATCATTTCTTAATGAACACAGACTTTCAAAAAAATGTAACATTTGTTGTTTGTTTTATATGCGGGCATTGAGTGGGTGATACCGGGCTTGGGTTTGCCAGGAGTCATTTACAGGGACTGACAATTGTAAATTACCACACATGGGACAGGTTACATTTGTAGCATAATACACTAAATTCTGATTTCAGCTACCGAGACAGGTAGGTAAAGCTCACGTTAGCTTTGAGATGTCTTAAATACCAATAGAGATGCCAGTTCATTAACTTTACTGGATATTAAGCTTACGGACTACAATGGTCCCTGTAATGTTTCCATAGACTTCAAAACATCACAGTCTGACCGCCTAGTTTATTCACCCATGTTTGATTGCTCAGGTTTAGAGGGGTTACACATGCATTTACTATAATGAACATGTAATTTGGTAACAACAGACCCCACAATGCAGTCTACAGATCAACTGTTACTACTACATGATGATTGTTTCTTTAATAAAA
->XM_051514774.1 Durotheca rogersii uncharacterized protein (GGS23DRAFT_536457), mRNA 
-CAGCTAGGCACGTGAAGTCTGCCTCTCTTTTAAACCCACGACGAAACGCCAATTCTCCCTTCGCACCCGCCGTCTTGGCTCCTCGGGCCCCGCAGTGCAGCGTCAACGAACACTCAGCCAAATCGTTCCTCCCACCCCGCCATCGCCATGGGTGAGCCAGTCAAGACCCCCGTGGTCGCGGAGGCCCATCTGGTCGACACCTACCATCCCCCCCACAAGATGCTTGAGAAGCATCCAAGCAAACCTCATCTGAATGGCCTCGAAGATTACCAGCGGCTGTACAAGGAGTCCATCACCGAGCCGGAGAAGTTCTTTGCGAGAAATGCTAGGGAGCTGTTAACTTGGCAGCGGGACTTCCAGACCGTCCGAACCGGGACTCTGACCGACGGGAATGTTGCATGGTTCGTTGAGGGCCAGCTCAATGCCTCCTACAATCTCGTCGACCGGCACGCCTTCAAGGACCCGAACAAGGTCGCCGTTATCTACGAGGGCGACGAGCCTAACCAAGGCCGAAATCTGACCTACGGCGAGCTCCTTCGCGAGGTAAGCCGGGTCGCCTATGTCTTGAAGAAGATGGGCGTCCGAAAGGGCGATACCGTCGCGATTTACCTACCCATGATTCCGGAGGCCATTGTCGCTCTCCTGGCCATTAGCCGTATCGGCGCTATCCACTCCGTCGTCTTCGCCGGCTTCTCCGCCGATTCCCTGCGCGACCGTGTCATCGATGCTCAATCCAAGGTCGTCATCACCACGGACGAGGGGAAGCGAGGTGGCAAGTTGATCGGCACCAAGAAGATCGTGGACGACGCGCTCAAGCAATGCCCCGATGTCACCGGCGTGCTCGTCTTCAAGCGCACTGGCGCCGACATCCCCTGGACGCCGGGTCGCGACCTGTGGTGGCACGAGGAGGTCGAGAAGTGGCCGACATACATTGCGCCCGAAGTCATGAACTCCGAGGATCCCCTCTTCCTGCTGTATACCTCGGGCTCGACCGGGAAACCCAAGGGCGTTATGCACACTACCGGCGGATACCTGCTCGGCGCCGCGCTAACCGGTAAATACGTGTTCGACATTCACGACGGAGATCGGTACTTCTGCGGCGGCGATGTCGGCTGGATTACCGGCCACACGTACGTCGTCTACGCGCCCCTTCTCCTAGGCATATCCACGGTGGTCTTTGAGGGCACTCCGGCCTACCCGAACTTTTCACGTTACTGGGAGATCATTGCGAAGCACGAGGTCACGCAGTTCTACGTGGCGCCGACGGCGTTACGGTTGTTGAAACGCGCCGGCGACGACTTCGTCAATGCCGACATGCCGAAGCTGAGGGTTTTGGGATCGGTGGGTGAGCCTATCGCCGCCGAGGTTTGGAAGTGGTATTTTGAAGTTGTTGGCAAGGAGGAATCGCAGATTGTCGACACGTACTGGCAAACCGAGACTGGCTCGAACGTAATAACGCCCCTGGCCGGCGTAACCCCCACGAAGCCGGGCAGTGCCTCGCTGCCTTTCTTCGGAATAGAACCAGCCATCATCGACCCCATTTCCGGCGAGGAAATCTACGGAAATGACGTTGAAGGTGTGCTGGCGTTTAAGCAGCCGTGGCCTAGCATGGCTCGGACTGTCTGGGGTGCCCACAGGAGATATTTAGATACATACCTGAATGTGTATCCGGGCTACTACTTTACCGGCGACGGAGCTGGCCGTGATCACGAAGGATTCTATTGGATCCGAGGGCGAGTCGATGATGTCGTCAACGTTAGCGGGCATCGTCTGTCGACTGCCGAGATTGAGGCGGCCCTCATCGAGCACCATTCGGTAGCCGAAGCCGCCGTCGTCGGCGTCACCGACGAGTTGACCGGCCAAGCCGTCAACGCGTTCGTGGCCATCAAGAACGGGAACGAAGCCTCGGACGCCTTGAGGAAGGAATTCATTCTGCAAGTGCGGAAGAGCATCGGACCGTTTGCCGCCCCCAAGGCGGTGTACATCGTACCCGACTTGCCAAAGACCCGGAGCGGAAAGATTATGCGCCGTATCTTGAGGAAGATTCTGGCCGGCGAGGAGGACCAGCTCGGTGACGTATCAACGTTATCGGACCCGTCGGTGGTTGAGAAGATTATTGCTACCGTTCACGAAGCTCGGAAGAAGTAATGGTTGGATACGGATATAAGTGGGTAGGTAGGCGGCTCGATTGGAGAACACCTGACAGGGCCTTGGATCGCAAATGCGGGGAAGGGTCCCAAGACATCGGATAAGTTGGAGAATTATGAGTATAGTATGCTATTTGACGGCAACATTGTGGTTTGGCACAGCCACAGAGCGGAGGAAGACGGTACGCCACCGGCTCAGCAGCTAGTGGCGCGCGCCCTTTGGTGTGGAGGCTTTGAGGAATCGCTCGGCCAAGGGTGGGATAGTTGCGCTGATATGGACGGCGTGTTTTTTATTGATTTGTCAGCTTTAGAGCCACCTTATATCAGCTTGATTGTACATTCCTATAACGCGGCGGCTTTAACGCCGAGGGTGATCAAACAGGTCGTGGTTTGCCGTTGGT
->XM_037547025.1 PREDICTED: Pygocentrus nattereri leucine rich repeat transmembrane neuronal 4 like 1 (lrrtm4l1), transcript variant X2, mRNA 
-AAAGGAGCCAGTGCATCCTGGTGGTGCATGGTGCAATCATTGCATTGCTGTCCCAAACCCTTGGAGGAGAACGACAGGCTCTCTGAAGCTCAGGTGTGGGTGGCAGGAAATTTAAGGTGCTATGGTTTGTGCTACGAGATTAGCATGCCTCCTCCCTCTCCTTGTCTCCACTCTTCTGTTGCTCTGCTCTGGGGAGAAAACATGTCCCTACAACTGCCGCTGTGAGGGTAAAATCGTCCATTGCGATTCAGCGTCTTTCATGGATGTGCCAGAGAACATTTCAGTAACTTGCCAAGGTTTGTCCCTGCGCAACAATGACCTGCACACAATGCTCCCATACCAGTTTGCCCACCTTAACCAGCTCCTCTGGCTGTATCTGGATCACAATCAGATCTCATTTGTAGACAGTCGTGCTTTCCAGGGCATACGACGGCTTAAGGAGTTGATCCTGAGCACCAACAGGATTTCACAACTCCATAATTCCACCTTTCATGGAGTGCCTAATCTCCGCAGCCTGGACCTCTCCTACAACAAACTTCAGGAACTGCAACCGGGTCAGTTCCATGGTCTTCGCAAACTCCAGAATCTGCACCTACGCTCCAACGGGCTCACAACAATTCCTGTCCGGGCATTTATTGAGTGCAGAAGCTTGGAGTTTCTTGACCTAGGGTATAACCGACTACGTGTCCTCACACGCACTGCATTTCTGGGTTTGTCTAGGCTGATGGAGCTGCATCTGGAACACAATCAGTTCTCTCGGATCAACTTCTTTCTCTTTCCACGCCTCGCAAACCTGCGTGGTCTGTATCTCCAGTGGAATCGTATTCGGGCAGTGAACCAAGGCCTCCCATGGATTTGGTATACCCTGCAGAAGCTTGACCTGTCTGGCAATGAGATCCAGACTCTGGATCCTGTTGTATTTCAATGCCTACCAAACCTACAGGTTCTTAACTTGGAGTCTAACAAGTTAGCCAATGTATCTCATGAGACTGTAGCAGCCTGGATTTCCCTGACTACAATCAGCCTTGCAGGAAACATGTGGGACTGTGGGCCAGGCATTTGCCCTCTTGTTGCCTGGCTAAGGAATTTCCGAGGAACTAAAGATACAAGCATCATTTGCAGCAGCCCCAAAAATCTTCAAGGGGAAAAGGTTATGGAGGCAACAAGAAATTACATAGACTGTGAAGATTTCGAAATCATTCCACAAACACCATTTCCTCACCACACTCTGGAACCAACTATGGAAACTACTTCTGCACCACCCTTACCTCCCACTACTCCCCCACCACCCCTGCCTCCACCTGCCTCTGAGGCACCCATCCCACCACCCCTAGCTCAACCCCTTCCTCATCCTACTATCTACAACCTTGCTGAGACTCATCCTAGAAACAGCCCTCCACAGACACCTCCACCTTCCAACAGCCTGCTCGTCACTCCATCCCCAGAACAAGAGAACTTGGCATTCCATAAAGTTGTGGTGGGGGCTGTGGTGCTTTTCTTCTCAACATCACTCGTCTTGACAGTGATCTATGTGTCCTGCAGACGGTACCCTGGTGCCACCAGGTTGTTGCAACAGCGTTCAGTCATGGGACGAAAGCGCCGGAAAAAGAGTCCCGAGCCAGAGCAGAACCTGAGCTCCCAACTGCAGGAATATTACATGAGCTACAATCCTGCCGCCACACCAGAAGCCATGGATGTGCTGGCCAATGGGACTGGTACTTGCACCTGTACCATTTCCGGCTCCAGGGAATGCGAGAATGAATACACGTGTCCCAGGCCACTCCCTGGAGCCTGGATCGGCGACATCCCCACCATTCACTAGGAATGTTTTCTCCACCAATGAGATTTCAATAGGCAACAGGGTTCCAGCCTACAGCCTCTGCATCCATCACTCTACGGCCTACGCTGCCATTTTTTTTCTTTTCCCTGTCATTTATGGAACGTTATCCACCATGGACATGTGAAGGGACATCTAAAAAGACAGCAGGAACGCCTCCATCACGCATTTTACTAACACGCACGTCACACTTCTTCAAGACGCCTCACTTTATCCACTCTCTTTTTTGCCTAGACAGCTCTTTCTCTAGATCTAAGCCTGACTAGGCCTTTGGTCGAGTTGAACATACAGGAACAGGATGAACTATTCTATTCTACGAACAAAGCCACTGTAACAGCAATGAGAGTGCATGGGAAGATATCTCCTGGACTTTAAGGAATATCCTCAGCATCAGAGCGTATGGATTTTCCATATGACAAAACATCATCCATCAGACAACCATTGACTGCCAGTCAACTGATACATTAAGCCTATTGCTGGACTTAACTTATTTGGTCACACTTTATGTGAGGGCTACCTACATATGGACCTTATAACACACTGATAAGCATTGAATAACATGTTTATAAAGTAATGTTTGAGTATTTATAAACAGCTGATATGAGTAATCACAGAATGTGTAGGCACTGTGTTGACATAAGAGGTCTTAAACCAATATAATGGATGTTTTTTTTTCATTTGTATCATTCCCACATAATGGATCTTAAATGCCAAGACCACTGTTTATGAGTTTTAAATATTTCTTCTTGAAGTCCAATTGTACAATTTCTATAAAGGAAAACCAGTATGGCTGCAGATACTAACTCCTTAAAGTAGAATTTTTCATTCAAATAAAATAGCATAATAAATCAAAGTGCTTTTACTCATAGTAAACTGCATTTAAGCAAGCAAGCAAAGTTTATTTATATAAAGCTTTTTACAACAGATGTTGTCACAAAGCAGCTTTACAGAGCAATCAGTATTATAGAAAGAAAAGAAAAGAAAATCCGGGACCAAGCCCCCATGAG
->XM_023033177.1 PREDICTED: Olea europaea var. sylvestris ferredoxin, root R-B2 (LOC111404360), mRNA 
-ATGAACATAGGATTTGAGAGAGATTTGTGTTTGCTGTTTGAGATTTGGATCAACGATGGTGGTGGTTCGCGGTGGCGGCGAGTGGTGATGGAAAGGAACGGATCCTACATCCATGCTTACAAGGTACTAATTGAATATGAAGGTAAAACAACTGAACTAGAGGTTGAGCCAGACGAGACAATTCTGTCGAAGACACTGGAAAGTGATTTGCCAGTGCCATATGACTGTNAATGCATGACATGCCCGGCTCAANGAATGGACGACCAAAGTGATGGGATGCTTAGTGAGGATGTTGAGGAGAGAGGTTATGCTTTATTGTGTNATTGTCACATTAGAATCATACCCGAGGAAGAATTGCTCTCTCTGCAGCTAGTTACTTCCAATGACTAATAAATCTGTTGGTTGTTAAAATTTTCAGTTTTGAGGCACTGCTAATTGTTACTGTTTTTCTGCATTAAATCTATAAGAGGAATGTGCAAAGTGAGATTCTGAAGGCAAAGGTTAACGATACCTTGTATTTACTTGCTGGAATTTCTATTGTTTGAAGAATATTTAGGCTTCCACGTTTAGATTTCTCTAAAAGCGTTCTCTCTGACAACCAAGAATGATAAAATCATTCGCATTCAGTCTAAAATTTAAGCACAAGAAGATTTAGTTGGAAACACCTGCTACCATTAAACAAAGTTCTTCATAGATAAAAGTAGCAAAATAGGACATGTATTGAATAAATGCATTGTGCGTGGCTGGTATCTATCTATTATTACGGGTTCAATACTACTTCTCAGAGTTGAATGTAGACATATAAGGTCATATAACAAATTTTGGAAGTATGGTCAAATGTTAATGAACAGTAATTCATCCATGCGTGTATAACAGTAATTGGACACAATGTGAGTTCAGAGGTGACTAACAATTAAAAAGTAGACACTTCTCCATATCCATGTGGAAGTATGCTAACAAAGCATTCAACACTTATGTTCAGTGAATAAATATGATCGTATCAAAAATGTACTCACTGACTCCATTTGATGTTGATGCAGACAGCAAGCACTTCAGAGTAGCTCCCGCAAGTGATAAATAAACTCGGTCTTCTTCAAAATTTAGATCCTAGGACATTATCAGAGCCCATAAATCCAGTATAGCATATGGCTAACCACATTTTGTATCTCAATGAAGGCCATAACACGCAGTATTACTGCTGAGTTCTCAGGGCAAGGCTCTGGATTTTCTCTGCTCAAGTTTCAACTTCACATCAATTCCATTTATCAATTATGGACTTGAGTACAATCTGAAGCTTCCCTTCCAATTTCTCCCCTTTCCTTGGAGTATAAACCACATTATGGATATCATCAGCCAAGGCCCTCTGAGCCAACAATTCCCCAACCGCAGCACAAGCATTTCTATTCTTAGTCGAACCCATGGCCTTGGAAATAGAATGCACCACAACCAGAGGTTTGCTAGAATTTCAGATCAAAAGAATGCTCTTTCATTCAATATTCATTGAGACTCGTTTGTTGACAGCCTATTGCACAGCATTGTGTTTGAACCTTGTGAAAAGCGAGGAAACTCATCTAATCCTTACTTCCCCATCTGTTTCTCTGGATCTTGAACAGGTTTCCTAGGTAATCCCCAGCTCCGTAGATTGTTCTTTTGCACAGGGCCAATTCTTGGTATTCCTTCACTTTCCCCTTCATATAAAAAATTACAGTATCCGAAACCAAAAGTTCATGATGCATATTTCTCTTAACTGGTGGTTTTCTGGTCACGACGGTTACAGTTAAAGTTCCATTAAAGAGCATTTCCACATGGTAGAACCTTCTCAAGGAATATAAGGTTTTCAATAGGCTGATCTTGAAGCTGCCCAGTCAACACAATTAAAAGCAGAGTACACAGCACGTGCAACAAACCCAGCCGTTCTTTGCTTACAATGGTAAGTACCTCATTATAGATTCTTTGGTCGACTATAAATGCTTCACAGCCTTGTTAAATATTTGGATTTTTATACTTGGTTCTAGCTACCAGAAAAAGGACTTCGAAACGAAGACTTTAATATTATTGGTCGCATCATAATACGCATAATATGAGTTTACAATCTCCACCTGAATGTAAATGATTGAAAGGAGAATGCTACCAATCAGGACAAATTTGACCTTAAAGAGGATAAACAAAACTTCTACTTCAGATTCTTTCATA
->XM_017942333.1 PREDICTED: Habropoda laboriosa cyclin-T (LOC108578915), transcript variant X2, mRNA 
-ACAAGTATGAGTTTGGAGTGGAGTTTCCGGTTAGCGTAGTGACGTGAAGTTTTCAACGTGTTGCTGTTGTGCGTTGTGCGCCCGCCGCCACTATCGCGACCGCCGTGAAGTGCGCATCGTTAGTACCGAGTTGTGTGTACATATAAATGGCGGCTGACGAAAAATGGTACTTTACGAAAGAACAGCTTATAAACACGCCGAGCAGAAGATGCGGCATCGACGCGGATAAGGAACTGAGCTACCGACAGCAGGCAGCGAATTTCATTCAGGATATGGGACAGCGGCTCGTGGTGACACAATTATGTATCAACACAGCAATAGTGTACATGCACAGGTTCTATGTATTCCACTCGCTGTCACATTTCCACAGGAACGCAATTGCAGCAGCAGCACTATTTTTAGCAGCAAAAGTAGAAGAACAACCGCGCAAGTTAGAACATGTTATCAAAATGGCACATATGTGTCTCCACAGAGATCAGCCCCCACCTGATGTCAGGTCTGAGCAATACCTTGAACAAGCTCAGGATCTGGTTTTCAATGAAAATGTCCTACTACAAACTTTGGGGTTTGATGTCGCCATTGATCATCCCCACACACATGTTGTTAGGTGTTGTCAACTGGTTAAAGCGAGCAAGGACTTAGCCCAGACTTCATACTTCATGGCATCTAACAGTTTGCATTTGACAACCATGTGTCTGCAGTACAAGCCAACCGTAGTTGCCTGTTTTTGCATACATCTTGCGTGCAAATGGTCCAACTGGGAGATACCACAAAGTACTGAAGGGAAGCACTGGTTCTGGTACGTCGATAAAAGCGTAACGTCTGAACTTTTACAAGAGCTTACAGCAGAATTCCTCCATATATTTGATAAGTGCCCGTCAAGATTGAAACGAAAAATAATGAGCATATCCGCCAATCAAAGTCCAAGCATTAATCATCCTAGTTTACCGAATTCACCCTTTGATGCGGAACCTCGCAAGGTACAATCTCCTGCGACGACGGCCGACGGTGGACCTACATTCCATTCGAATCGACCTCATCAGATGGAGAAGCAAGAAGAGAAGAAGCAAATTGCACCAGCATCCTCAAGACCCCCTGTCGATTATCGGGAGTATAGAGAGAAGAAGGAACGCGAGCGTTTGGAAAGGGAAAAGGCGTCGGTTACAACGACAGTTGCCCAGAGTCATGTGTCAGATATTAATAAGCATCATTCGCATCACCACAAACTCGTATCTAGTACAAATGTGCTAAACAAACATCCACTGCCCCCTGGACAGAAGGCGCTTCACCACAATCATCACCACAGACCAGATATAAAGGTTGGACAACCAGTACCTCAGAGGCACTCAAGTAGCGCTCAAGCTAGGGAACCAAATCGCGATCCCAATAGGCAGAGGTTACAAAGAGAGTACAATTCGAATACTGGTACAAGTAGCAGTAGTAGTAGTAGTGCTCTTCATTCTCATAGTCACGCGGTATCGAAGGAGTCAAGTTTGGATAATTCATTGACGGATTCCGCCACTCACAGATCGGATGTCGGAGCATTGCAAGAGCCAACGTCCCATGGAAGTATACAGGAGAAACTTAGTAATAATAACCATAGTGTGCACAGATTAAGTGCAGTAGAAAGCAAATACCAGGGTCATGACAAACGAATGTATGATCCGAGGCATAAACCTGTTGAACATAGGAAAGATAGTGAACAAAAGCCATACAAATATCCCGATCCAACAAGAGAATATCGACAAAAAAAGTCTGATACGTTAGAGCAGAGGTGTGAAGAGGTGAGGAAGCTTATCGAGAAGCCATTACCTCCGCCCAAGCCTCCACTCGACGTACCGTACGCTTCGAATACACAGAAGCCACCACATCATACGAAATACAATCAATCGGAGAAACTACAGGCTAGCAGTGGCGCAGTTTCTACCGACGTGAAACTTCCCACTGGCCAGAGTTCGTTTTCACAGGAAAAATCACCAACCAGTTCCAGTTCGACCTCGTTGCTTACACAGAAGTCGTTAACCTCGAAGACGGTGTCCAGTCAGCACACAGCTCACGGTGTGTCCCAAATAATAAAGGATACGATTAAAAATGGTAGTTCTCAGTCGTCGAGTTTGTCATCTTTGAACAATCTCGACGATCAAAAAACTGAAAAGCGACCACGGCACGATGACATAGAGAAAAATTCGTCTGACATGCAGCAAAGTGTGTTACAGACACCTCCTAACAAGCCGAAATCGCTATTCAGTCCAGAGAAAGTACCAACGCCTCGCGAATCTCATTCGCAGAGGCCTAAGACTAAGCAAAAGACGCCGCCTTCGGCTGCAAAAGTTCCTAAACAAGAACGCGTACCAGATACGTCGATAGGCTTTAATTTAGTATCGCCGTTCGCGAGCCCGCCAGGCTTGCAACAGCAAGAAACACAAACAGTTAAACGATTGGCCAGTGATGTTTCCACAACATCCTCTCACAAAAGGCATCGTACAGGCAGCACCACCACCGAAGTAGGACAACAGGTTCAAAAAGTGAAAATAGACGATACTTCGAGTTTCGAGGCTGCTAAGATGCTCGGTAGGGTACCAGAACTGATACAACCTATCAGAGATAATCCATCGGCAAATGGTAGAGCCACTCAGATCGCGAACGACATGAAACCACCGGAACTCATCAGACCGTTCGACTCTGAGCCAACGATATCACGCTTCGGTACAGTGTCTACACAGCAACAAGTTTCGTCGAATCAACAAGGTCTGACCAATGGTCTGGACAACAATTTAGTGAAGCAAGATTCTCAGGAGTTTCTAATTAAGAAGGAGCCTACGTACAAGACGGACTTGTCAATGAAAGTAGAACACTCCCAAGCTAAAGGCGAATATTTGTCGCCAATGAAATCCGCTCAAAGTATAAGTGCTCTGCTTCAAGAGCCTTTAGCACCAATGCCATCGTTGTTGCAGAACATGCAGCAATTTAGTCAAATACCGTCGCAGCAAGTTCACCAGGATCAATTCCAGCAACAGCAGTTACAACAGCTTCAGCAACAGCAATCATCGCAACAACAACACCAGCCATCTATATCACACTCGATGCTACTCACACATCAAGAACCCGTTCAAACTCAATGCATGTCTTTGTCATCGGTCAGCGAGCCTGTTATAGCGTCGACCGTTGACATAAGCGCTCTCTCTATTCCCATACAGACCAGTACAGAATCCATACTATCTGTACCAACGTCGACAACCATAACCGTTCCACCTCCCGCAGAAGAAAAGAGATCGGAGCATCACAAGAGCGAGAAGAAGAAGAAGAAAGAGAAGCATAAACACAAGGACAAGGATAAGAGCAAAGAGAAGCACAAGCACAAGCATAAAGACAAGGACAAGGAGAAGCACCGGGAAAAGGACAAAGAGAAGGGCGATGAGACTGTACCTGCGGTACCTATTAAAATCACTATTCCTAAGGACAAATTGAATCTGAGCACAGAATCGACAAGTAGCACCGGCGGAAGTACAATTCCACCGGATAAGAACAAATCACCCCAGAATACAAGCATCAAGATCATTATCCCGAAGGAACGGTTAAAAGGTACCGACAGTGTGTCAAGTTCACCGGCTCAGTCGATGGTCCAGGCACCGTTGAAGATCAAAATCCGTACGGATGGAATCTCAAGGAGTTCAGGTGCTCCGTCGACGACGAGCAGTACGAGCAGTAGCATCGTGCCGGAGTTCACGAACGAGAGTCGTAAACGTGACCGTTCGGAGATAAAGGAGAGCCCAACTACCAGTGTTCCACCAACGAAGAAGCAATCGCAGGTCTCGTCGGCGGGTTACGGACAGCATCGGCCTGGAGAACGGCAGAACGGCAGACACTATAGTTCAGGCAGCAATAACAAGGAGAAACACACGTCTAGCCACCACAAAAGTTCCAGCAAGCTATCGCAGTCACAGCAGTCTCACACGTCGTAG
->XR_004353595.1 PREDICTED: Danaus plexippus plexippus uncharacterized LOC116771400 (LOC116771400), transcript variant X1, ncRNA 
-TCCTCAATACCCTCACCGGGTAATGCACGGCTCTCAATTAAACTCTAATTTGTTAATAATTAATACATAATGTTTATTGGGCATACTAAAATCTGCTCTAGACATGCAATATAGACAATTATAGGGGAGCGGTAGACTGGCCACATCTCAAATTCTGAACGTACTCCGCTCACATGGACTGCATCGTAATATTGACCCGCGTTACACGCACTGGAATTCGTCCTCATTTACCGCCCACTTGGAATTATTGAGGCGAGAAATGGATGATGTCTCTAACTTGAAAATATCAAAGTTAGAAGAGTCAAAAGACGGGTTGCCGAAACCAGAAACGATTGAAGATTTTGAAAGAACGAGCAATTGGAGTCCTGAAATAATTAATTTATAAAAGAAAAATTTTGCTTCCTTCGAATATTTTTGATTACTTTTAAGAACTTGATGAAATACACACAGAGATGGAATTCATAACGAATTTCCTTATTATAAGAGCTTTTATTTAGTTTCCAAAGCAAAATACACTTTTCAACATACTATGCAGATAACTGGCTATTGAAATAAACATTCAGTTCGCGAGCATACATTGTAGTTCAAACAAGCGACATATGG
->XM_004253934.1 Entamoeba invadens IP1 hypothetical protein (EIN_093680) mRNA, complete cds 
-ATGATGAGAATCAAAGATGCATTGATCAATACTGGAGGAAACACATCAAATATAAATAAAATGATTGAAGATGTTAATATTGCTCTTCAAGCAATATCCATTGAATTAACAATTCAACAACCTGCAATAAATGAGCCACACTTTGTTTCACAACAAATCTGTGAACAAAATCCAAACATCATGATAAACACTTACAACGATAATGGTATCAATGATGAGCACAACGATTCATCTTATCCAGATAGAACAGCACAACCCAACACTGCTACGCCCCCTATGATAGACACAACACAAACACCAATAGGTGTTGTTGATCAAACACCATTTGATCTTGAAACAAACTTAGATAAGAAACAGACCACTTTTGGTGATATCATGGGTCATTATGACCTTGTTTATGGAAACGATCCAATTGATGGCAGCCTGGAAACTGAGCACAGTGGAGGCGAAGATGAAGCTCATGAAAATGAAGAATATGAAGGAAGTGAATGCAATGAATGTAACGAAATAGAAGACACACGAGTCCATGAAATAATGAGTCAAGCATCCGGGATATGGCAACAGTTGTCTTCTTCGCTTATTAAGTCACACGCATCAAAAAAACCTCCCGGAAAATATCGAGGTTGCAGATGA
->XM_004439747.2 PREDICTED: Ceratotherium simum simum succinate dehydrogenase complex assembly factor 1 (LOC101397205), mRNA 
-CGGATAGCCGGAGGCGGGAGGCGGGAGGCGGGAGGCGGAGGCGGGGGCGCGCGGGGCGGAAGTGCCTGCTGCCTGGCTGCTGGCGTCTGGCGCCGGGCGGCCGCGCCGCGGTTGGTGGGGCCTGCGCTGCGTGCGACCGCGGCCCCGCCGGCACCATGAGCCGGCCCAGCCGGCTGCAGAGGCAGGTCCTGAGCCTGTACCGCGAGCTGCTGCGCGCCGGGCGCGGGAAGCCGGGCGCCGAGGCGCGGGTGCGGGCCGAGTTCCGGCAGCACGCCTGCCTGCCGCGCTCCGACGTCCTGCGCATCGAGTACCTGTACCGCCGCGGGCGGCGCCAGCTCCAGCTGCTGCGCTCCGGCCACGCCACGGCCCTGGGTGCCTTCGTGCGCCCGCGGGGCCCGACCGAGGAGCCCCGCGGCGCGGGGGCCCCGGGGACCCCGCCTGAAGATGGTGACGGCCCGAGAAGCCCGCCCGACGGCATGGGGTCACCAGAGACCTCGCGCGATGGACGGTGACAGGCAGAAGAGCTCACTCGATGGTGCAGGGAAGACGGGGGGCCAGCCTAACTGCGTGGGGGGACCAGGGAGCCCGCCTGATGAAAGGCGAGAGGTCTTGAGAGACTAGCTCGATGG
->XM_013238176.1 PREDICTED: Biomphalaria glabrata uncharacterized LOC106077421 (LOC106077421), partial mRNA 
-AGAAATTCTATATTTGGTCAACATGCTTCTAATTAATTCTTCAATATGCTTATTATTGATACTTCTTCTGCTTATGTTTTTGTACAATTCCTAAGGAAGAAAGAAACTGATACAAGGCTTCAGAATGGATACGCTTCATTTGACAACAGTGGGAAGACAACTGACAGTGTCAAACTATCAACTGGAGAAAAAACACCCTTACTGAACAGAAGATCCAATGTAAGGACATCATTAGCCGACGAAACTGCCAGAACTAGTGCTAGTGAGAAAGAAAAGGATAATGAGGACCATCTAGTTCAAGCTTCATTATTTAAGGTGTTGGTGAAGACTTATGGGATAGAATTACTTAATGCTCAAGTCTGCAAGTTTGTTTATGACTTGCTTCAATTTGTTAGCCCTCTGTTACTTAG
->XM_016498712.1 PREDICTED: Sinocyclocheilus anshuiensis protein FAM150B-like (LOC107697862), transcript variant X1, mRNA 
-GTCTGAGAGCCCCAATAAATTGACGAGAATCGACGGCGAATGTCTCGAGGCGTTGAAGACGCGCGCGCACAGCGTCCTCAGGAGCTTTGACTGGAGTTTTCTCAAGTCTCGGAAACATCAGAAGGAAGTCTGACCACTATAACTTCCCACGCTTGAGCACATTAAAGAACGATTCGCTTTAAAGGGTAGCGCTCTCTCTCTTTCCCAGCGCGTTCTGCGAGCCTCGCGTGGGGTTAAATAGGCACCGGACGCTCAGTCGCCTCAGGCTGTGTCGACTGAGGGAAAGAAACGCGGCGACACAAGCGCCCTCAGACTGCGTGATCCAGGACTTGGGCAGTTCGGGAGCGATGCGCGCGCTGCGGGCTCCGGTTCTAGTAATGGGGCTCGTCATGTTAATCTGCACTACTGCACAAAGCGACGCCAGCGCGAACAAGGTCGAGAAAACGTTCAGACGGATAACGGACATCATGAGACTGGCGGAAAACAGCGTTGACGACGCGAGCGTGCCAAAGGACACTCATCGTCTCAAAACGGAAACCGGGGAAACAATTTTAAAAATCTTTCCCAGAGACCTCAGAAAGAAAGAGAAGGTTATCAAAGTCTTAACAGGTCCTCTTTATTTCAGTCCAAAATGCAGGAAGGACGTCTACAGGCTTTATCATAACACCAGAGACTGCACCATCCCTGCATACTACAAAAGGTGCGCACGACTCTTGACGCGACTGGCAGGGAGTCCGAGATGTCAAGAGGGTTAACTGTACCAGATTCAGAGAGGACACATGCACTTAAAGCTTTTATGACTGAGAACACATTCTAGGATTAGATAACTTATCCAAGCTATTACAGATAAACCTGCGTGTCTTAGCAAATAGGATGTGATTTAAGCATGTAAACAAACTTAAGTCAGTGCTTTACATTTCATGGTGGGTTTTTCCCCCCCCAAAGACCACTTCAGAGGAAGCACATGTAACAAAACCTGTTTCCCAATTTTTCACAGATGCATCCAAGTGCACACATGTATGCGAACACAGCCAAGTCTGAAACAGCACTAAACTTCACTTCCTTTATCAAGCAGGTTGAAGCCAAACCAGAGTGACCCAAGGAAAAAAAAAAACAGCAGTCAAAGTGCCTTTGGACAAGAGAAGAGAATTTAAACCAACACACAACAATCCACATAATCAGCACATCTCGTCCAGAACACTGCTCTGCCTCTCTGGAGAATAGATGTGGGAAAGTATTGACAGAGAAGTAAACGGACACGGAATAATGGGATGCACTTGCCCAAGGACAGTCTGATGGACTCAACATGGAGCCAATGTTAAAACACAGGACGACAGAGAAAGAAAACAGAAAACGTATCTGGCATAGTGCGTTCTGAACCTGTCTGCCAAAAAAGAAAACCATTTTTCCATCGTTTCATCATGAAAAAGGGATAGCCATGGTTTTGCGTTTCGATATCAGATTATCGAGACTCGTCATTGCTGATGTTTCGCACGACATGCCTCGATGGGGTTACAATTCAGAGCCACGATGACAAATTGAGTTAGTTCGCGGCAACGAGAGAGCTTTGCTTTTCTCGGTGCTAGAACTGAAAATCATTAATTGCATGAACGTTTCCTTTTGCTTCTGTTTGCCAGCAGACAGGTAGATTTTTGCAGTAAATCTGTGACCAAAAGCTTTTAGTTTTTGTGTGAGACTATGAGTGTATGACTGTGGAATATATTCAATATATTTTGATATGTAAATGTTGTACAAATGAGACTTAAAAATCCCTATAACAAAACATATAAGCA
->XM_010619662.2 PREDICTED: Fukomys damarensis sorting nexin 31 (Snx31), partial mRNA 
-GCGCTGGGGGGTCGCTACGTGCTGTACTCCGTGTACTTGGACGGGCTCCTCTTCTGCAGGGTGCGCTACAGCCAGCTGCACCGTTGGAACCAGCAGCTCAGGCGGGTCTTTGGAAGCTGCCTGCCGCCCTTCCCACCGAAGTACTATCTGGCAATGACCACATCTATGGCAGAGGAGAGGAGGGCCCAGTTGGAACAGTATTTGCAAAACGTAACTGCAGACCCAAATGCCTTGAGGAGTGATGTCTTCATTGAGTTTCTACAGCTGGCACAGCTGAACACGTTTAACATCTCTGCTGAAAAAGCTTCTCTAGATATATTTCTGCCCAATGGAAGAAGTGTTAATATAGAAATTCTGACATCAGATACTGCTGAAAGAGTCCTAGAGGTGGTGTCACGCAAACTCGGACTGAGTTGGGAGCTCTTGGGCTACTTCGGCCTCTTTCTCATTCGGTTTTACAAGGAGGGCAGCCTGTCTGTTGTGAAAAAGTTGGCAGATTTTGAACTCCCTTATGTTAGCCTTCGAAGTTCTGAAGAGGAAAACTGTAAGGTTGGACTCCGGAAGTGGTACATGGACCCAGCCCTCGACTCTGTGCTGATGGGCTGCAGAGCGGCCGTGGAATTGCTCTACATGCAGGCAATGCAGGACATTGAGAAAGAATGGATCAAGCCCACACAGGGACAGAGGCAGGAATTAGAGGCTCTTCAGAAAGAAAACAATCAAACCAAGTTCCTGGAGCTGTGCCGGGAGGTGCAGTGCTATGGATACATGCAGCTGGATCCTTGCCGCTGTGATTCCCCAGAGCCAGGCTGTGGGGCTGTGCTCTCTGTTGGCAAAGATGAGATCTGCTGCTGCGTGACCCTGCCTGACAGCCGGACACAGGATGTCATCCTCCAGATGAGCAGCGTGAAGTGCTGGCAGGTCACTTTCCTTGGGACTCTGCTGGATATGGATGGGCCCCAGCGAACTCTCAACCAGAACTTAGAACTCAGATTTCAATACAGTGAAGATAATCACTGGCAGTGGTTTATCATTTACACCAAACAGGCATTTTTGCTGAGTAGCTGCTTGAAAAAGATGATCTCAGAAAAGATGGCAAAGCAAGCTGCTGAGAATACAGAAATGCAGATGGAAGTTCCGGGAACAAGAAAAAGTAAAACATGGCACATTCAGCAAAGCAAGCAAAAGAAGCATTCTAGTTTTCTATCAAGAAAACACAAGATCAAGAGAGCTGAAGGTGTCTGTGTGTTTGGAACCATAAAGGAAGAAGATCTTTGAAGAAAAGTCTCACCTTTGAAATGTCCCCTAAGACATCTCAAGATGGTGAAAGAGCTCGGTGGTGGGGGGTGGGCTTCCTGCTGTCAGGAAATAATTGACTTCTTCCTGTGTCTTCTAATGTTAAGATAGACTCTAGTCGTCAGGACTACCACAGCATTCTATGTACATTTCAAGAGTAAAAAATGTAAGAACTAAAGTTATAGAATTTGTTTTTACCAGCTCATCAATCACAAATTGCTGAATCAATTAAACAAATACGAACTTCACTCTCTTCCCCCCAAGAATCCATTCTTCTCTGGCTTCATGAAGTCCTCTGAATGGTCCCGTATTACGTAATGAAAGTCTTGCTCCAAAATGTTACCAGCGTTTTGGGCTCAAGTTCTAAAGACATGATTCATTAGCTAAGGAAAGCTGGGCTCTATCTAGGAAGTGGAATCACTGGGGAAGAAACCCAGACTTCTCCGACCTGTCCGCAGAGCTGCGTCAAGGAGGCGTGCAGTGCCGACTTGTTTCCTTACCTAGGTCGGAGGTACCATATGGGCAACCTCAGGGTCATATGCTGTTTTGAACATTTCTATTTGGGAAAGCAACACTGCCTTGTACTTGACATAAAATGCCTTTTAGGTCC
->XM_017738153.1 PREDICTED: Corvus brachyrhynchos solute carrier family 23 member 1 (SLC23A1), partial mRNA 
-GCCACCGCCCGGCCGGTGACTAAAGTCCTTCCCACGGCCATAAAACCCCCCCGAGCAGGGCCATCGCCGCCGGGGACGCGTCGCCGGAACATGGGGACCCGCTCAGGAGACCTGGCTCAGCCCCAGAATGGGAACGTGGCTCTGGCCCCCGCTGGCTCCCCGCAGACCCCTGGGAAGGAGCTGCCTGCGGCGGGCAGGCAGGACCACGGGGCGGGCACCAGGCCCCCCCGGCCGGAGATGGACATGCTCTACAGGATCGAGGATGTGCCCCCCTGGTACCTCTGCATCCTGCTCGGCTTCCAGCACTACCTGACCTGCTTCAGCGGCACCATCGCCGTCCCCTTCCTGCTGGCCGAGAGCCTGTGCGTGGGCAAGGACCAGCTCACCGTCAGCTACCTCATCGGCACCATCTTCACCTGCGTGGGCATCACCACCCTCATCCACACCACCGTGGGCATCAGGCTGCCCCTCTTCCAGGCGAGCGCGCTGGCTTTCCTTGTCCCCGCCAAGTCCATCCTGGCCCTGGAGAAGTGGCGATGCCCATCTGAAGAGCAGATCTACGGCAACTGGTCACTGCCCCTCAACACGTCCCACATCTGGCAGCCCCGCATGCGAGAGATCCAGGGGGCCATCATAGTGTCCAGCCTGGTGGAAGTGGTCATCGGGCTGCTGGGGCTCCCCGGGGCACTGCTCAGCTACATCGGGCCGCTGACCGTCACCCCCACCGTGTCCCTCATCGGACTCTCCGTCTTCCAGGCGGCTGGAGACCGGGCTGGCTCCCACTGGGGCATCTCTGTGCTAACCATCTTCCTGATTGTCCTGTTTGCCCAGTACCTGCGGCAGGTCGCCATCTGCCTGCCCGGCTACCGGCGGGGCCACGGCTTTGTCCTGCTCCGCATTCAGATCTTCAAGATGTTCCCGATCATCCTGGCCATCATGGTGGTGTGGCTCATCTGCTACGTGCTGACCCGCACCGGAGTCTTCCCCAGCCAGCCCGGGGAGTACGGGTACAAGGCCAGGACGGACGCCCGGGGCGAGATCCTGTCCGTGGCGCCCTGGTTCCGCGTCCCCTACCCCTGCCAGTGGGGGTTGCCCACGGTGACCTCAGCAGCCGTGCTGGGCATGTTCAGTGCCACACTGGCGGGCATCATCGAGTCCATCGGGGACTATTACTCCTGTGCCCGGCTGGCAGGAGCGCCCCCGCCCCCTGTGCACGCCATCAACAGGGGCATTTTCACCGAGGGCATCTCCTGCATCATCGCGGGGCTGTTGGGAACCGGCAACGGCTCCACGTCCTCCAGCCCCAACATCGGCGTCCTGGGCATCACCAAGGTACCGGGGCCGGGGAGGGTCCCGGCTCGGCCG
->XM_007330897.1 Agaricus bisporus var. burnettii JB137-S8 hypothetical protein (AGABI1DRAFT_85928), mRNA 
-CAACGATCGATTTGCTCATCGACACTGACATCCTCAAGACATGGCCCCCGCGAACACCAAGAAAAAGACTGGCGGCAAGACTCGCTCTGCGCTGCAAGACGTCGTCACCCGCGAATACACTGTCCACCTCCATAAACGCGTGCATGGCCGTTCCTTCAAAAAGCGTGCTCCTTGGGCCGTCAAATCCGTTGTCGACTTTGCTCAAAAAGCTATGGGCACGGCCGACGTTCGTCTCGACCCGAAGCTCAACCAGGCTGTTTGGGCCCAGGGAATCAAGTCTGTTCCTCACCGGATACGTGTAAAGCTCGAGCGAAAACGTAATGATGATGAAAACGCAAAGGAGAAACTCTACACCTACGTCTCCCATGTTCCCGTGGAATCTTTCAAGGGTCTTCAAACGACGGTCGTCGATGCAGAGTAAAAGCTTAGTTATATAGGTTCTGCCGGTCTTCTATTCGTGTTGTCGCCTTGCACCTCATGCCAGTCACATATGCATGTTCTACGTCCCCCATATGCCATGCCACCCAGGTTTTTAAAATCAAGGAACAAAAACAAAACAAACCTTTTCACATGGGTGCTTCGTGTCAATGTCATAATTCTGCGTGCAACACGCTGCCTACTTCTTTCCGGCCGTAATTCAGAAAAA
->XM_027301384.1 PREDICTED: Coffea eugenioides uncharacterized LOC113758607 (LOC113758607), mRNA 
-ATGGCCATCAGGCAGAGGCCCGACGAGTCCCTAAGGAATTTCATGACCCGTTTCAATACGGAGAGCTTGCAGATCAGAGACAAGGACGAAAAAGTGGTCATGGCTGCCTTCATGAATGGGCTCAGGGTGGAAGACCTCTTCTACAAGTTGGCCGAGCAGCCTCCTGAAAATCTGGAGGAGCTCCTGAAGAGGGCGCACGCGGCCGCCAATGCTGAGGAGGCGGCCTGCCTGAAGAAGGAATCAGATCGGGAGCTCGGCGATCGGAGAGGACGGACAAACCCCCCCGAGAACAAAAAGGGTCTGGCCAAGACGAACGTATTTGACCGGCTCTCAAAGGAAAAGGCCCCTGCTCCGACACCGCTCCCAGAGAAAAGCTACACCCCCCTGACTCGGCCCAGGGCCCAGATCCTGGCCGTCATGGAGGCAGAGGGCCTGGGAGGTCGGCCACCTAAGATGGGAACACCTCGGAACAAAAGAAATCAGGACCGGTACTGTGCCTTCCACCGTGATGTCGGGTATAATACGGAGGGGTGCTGGGCCCTGCAAAGGGAGATTGAGGATTTGATCCAGCGCGGCTTCCTGGGACGTTTCGTTCAGCAAGGTCGGCTAGGTCGGGAGCTAGGTCGGACCTACCGTGGAGACAGGGACGAGGGCTAG
->XM_036118028.1 PREDICTED: Halichoerus grypus purine nucleoside phosphorylase (LOC118551879), mRNA 
-GATTAAGTTGTTAGCCCAGCCTTGGGCAGTTGAATCTGGGTGTGTCACCATGGAGATAGGGGCCGGCTTGCGTGTTCGGCTGCCATTGGCTGGGGACGCCGGGCTGGGATAGAAGCCAGCCGCGAGTAACTGTGCAGACACTGTGCACAGCGCTCCCGGCGAGTACAGCTCAGCGCGGCGCTGCTCAGCGGACCGGATCCCAGAGGCCAAGGGCGGGCTCCTCGAGAGGGCGGAGGCGGCACCATGGAGAAGAGATTTGCGTATGATGATTATCAGAAAACGAGTGAATGGCTTCTGTGCCACACCAAGCACCGACCTCAAGTGGCAATCATCTGTGGCTCTGGGTTAGGAAATCTGGCCGATAAATTAACTGACAGCCAGAGCTTTGACTACAGCGAGATTCCAAACTTTCCCCGAAGTACAGTGCCTGGTCATGCTGGTCGACTGGTGTTTGGGTTCCTGAATGGCAGGGCCTGTGTGATGATGCAGGGCAGGTTCCACATGTATGAAGGCTACTCGATCTGGAAGGTGACATTCCCGGTGAGGGTTTTCTTCCTTATGGGCGTGGACACCCTAGTGGTCACCAATGCTGCTGGAGGACTCAACCCTGAGTTTGAGGTCGGAGATATCATGCTCATCCGTGATCACATCAACTTACCTGGCTTCAGTGGTGTGAACCCTCTCATAGGGCTCAATGACGAAAGGTTTGGACTTCGTTTTCCTGCCATGTCCGATGCCTATGACCGGGATATGCGGCAGAAGGCTCACAGGGCCTGGAAAGAGATGGGGGAGCAGAGGGAGCTGAAGGAAGGCACCTATGTGATGGTGGCAGGCCCGTCTTTTGAGACTGTGGCTGAATCTTGGCTGCTTCAGAAGCTGGGGGCAGATGCTGTTGGCATGAGCACAGTACCAGAAGTTATAGTTGCGAGGCACTGTGGCCTTCGAGTCTTTGGCTTCTCCCTCATCACTAACAAGGTCGTCTTGGATTATGAAGCCCAGGAGAAGGCCAATCATGAGGAAGTACTAGAGGCTGGGAGACAAGCAGCAAAAAAACTGGAACGCTTTGTCTCTATTCTTATGACCAGTATTCCACCCCCTGCCAAAGCCAGCTAACCAGCCCTGGAGCGGTCTGGCCTCTCCATAATGGGATCCAAGTAGCTAGCTACTACATACTTCGGCCCCTTGCTGGTGTCACGTGCCTCTGCCCTTCAGTAGGAGGAGAAGAGAGAGGAAGATCCCTATCCTTCACCTCCCCCATTTCTCCCACCAGACCCTTCTGCACTGGCTCTTTTGCTCAGTTATCTCAAAGCAGTTATCATCTCCTTCCCCCTCTCCCCGCCCCCTCCCCCGGCCAAGAGCTGGAACCCAAGCCCTGCTGTGTCTATGCCCTGGGTGTGACTTGGCTGTTGAACTTGGCACGGTAGCTACTGCTGTCCTTTTGCTGTAACGCTTTCACATTCCTGGGGACTCGGTTCTGCCTCCTCCAAAGCACTAGAGCCCACACGGGGGCTGGCCCAGTCCAATACCCCTTGGAGTTTTGTATTACCCTATTTTAAGAATAAAAAGAAAGATGAAATAATATATTTTTTGTGCAGTTTGGGATGAGGGTAGGGGCACAGGCCGAGTTTGGCATGAAAGACTGAGATCCCATGTCTTGTGTGACTATCTGCTTCTGAGACAAGCAGCTAAGAACTGATGAGGTGGTGTGTGAATGCACGGAAGGAGGAAAGATACAGATGTTAGAAGATAAAGAAAGAAGGGCTAACGACTGGCACAAGAGGGCCCCTTTCCTCAGACCAGTCTTGCCTCGGTCCTTTGCCTTCCGATTGTTTCACGCCCTGTCTGTACTCTCATGAGTATCTGAACTGCTTCGCTGGTCTCGGCTGTCCCACAGTTGCTATTTTCTTCCTAAGGCCTGATGATATTTCCTGTTGGTTTCTTTCTTCTCCCCTACTCTAACTTCTGCCGTAATTAACGGCACCCCTACATTCCTTCTCTGCATTCTGGCAATGCAGTGGCGAATACCTCTTTCTCTACTACAGTCACCCCGCTGCAGATTAGAGTCCTGCCAGGCCCAGGCAGACCTGTGAAGTTGGCTCATGCTTCGCTTCTCTTTGAGCCCCTCCTTCCGTCCTATTGCTTCATTTCTGGGTTCTAATCTTTCTCTTCACTTTTGCTTGATCAGAACCCGTCTGTGACACAGCATCCAGGCATTGCCCTTTGCTGGCTTGCTGCACTGTTCTATGCACTTATCAATTTGCATGCAGCTGGCCCGTGTGTCGCAAAACCACGCTACTCTCCCAGACCCCTTTGCCTTTTGAGAAAAGATCAAGTTGGATGAGCCACTAATAGTAGTGATATGTCAGTTGTCCATTGAAAACTTTTAAAAACCTCTGAAATCATCTTTTGTTTGATAACTGACCTACCTACCTGAGTCCAGCACAAAGAAAAAGCGTTCTGGAGTGGCCCTGTCCCCACTCTCTATCTCGTCAGTTCTTTGTACCTCCAGCAGCTCTAAAACCCTCCCTGGATCTTTAGGCGCTCTGCTAGCATTTGCCATGTGTCCATGAGAGCTGGTTTAGAGGGAAGTACTGTGTGTCCTTCAGATTATATGGACTCCAACTTGTTCGTTTAA
->XR_007407767.1 PREDICTED: Canis lupus dingo uncharacterized LOC112644623 (LOC112644623), transcript variant X13, ncRNA 
-ATTATGACACACTGTTACCATGGAGACCAGAAGCTACTCAGCTCCTGCGTGGGTTGATTTTCCCCCTTTCTAACCAGCTGTTATTCCATCAGAGTAAAAGATTTTTACCAGGGTTTTTATGTTCATTGACCAATTTGGTCCTGTAAGACAAGCAGTCTTGGCCTTACTATTCCAGCAGCAAAAAGAGCACTGAGGCACAGAGGGATTTGTTCAAGGTCATACAAATAATGTTCTAAAAATGATATACTGAGAAGCACTTCCAGAAAGATGCAGTAAGGATCTCAAAAAATGCATTCCTCCAGAAAAACAAGAACACTGGCAAAAATTATAGAAATCAACTTTTTCAGAACTCTGAAAATCAACTAACAGCTTGTCACAATTTAAAGAGCATTTATTCAATAGAAACTTGTTGCAAGATAGCTGGAGGTTGCTCACTATCTGGGCTCCATGAAGGAAAGATGTGGGGAGAAGAGACCTTGATCCTAACACTTGGAACTGCCAGCAATCACTCACTTATACATCTCTTGCTGTTTGTGAAAGGTCACGATCTCGGGGTCATGAAATTAAGGATTAGTAACCTTAATTCCATTTGCAACTTTAATTCACATTTGCCATGTTACATAATATATTCACAGATTCTGGGACTTAGAACTTGGACATCTTAGAGTGGCGGACACAGAGTGGCCAGAGCTAGAGTAGCCATCTTGGACAATCAGGTGAATTTGACAATGGAAATCATGCCAAGTGAGCCACAAAAAAGAAGAATCTTATTGTATTTTCCTTGAGAGAGAAATAAACTTCTATTTATTTTTAAAGATGAAGAAAATGCCTTTCTGGGATACATTTCGGCAATCTTCTGAAGAAATAAAAACTAGATGACATAATGATCAAAACAAGGAAACAAACATGGCCCAGATGCTGTGATAAATGTGTGGGATTCATCCTATATTCTTGTAGGAACATTTGTCATGGCCAACTCTAATTTAAGACCAAGAAATGCTTTCAGCTGCTTTTATCCAGTTGCTAAATCAAATAACAGTATCAGAAAGAAATTCGAGGAATTTTGAGATGACTGCAGAGCTGTTATGTAATAAAAATCCCAGTAACGA
->XM_029005051.1 Plasmodium malariae 40S ribosomal protein S18, putative (PmUG01_09035500), partial mRNA 
-ATGTCTTTACAAATAATCGATAACAACGATTTTCAGCATATTTTAAGAATTTTGAATACGAATGTTGATGGTAAAGAAAAAGTAACCATTGCCTTAACTGCTATTAAAGGTATTGGAAAGAGAATGGCTAGCGTAATATGCAGGCAGGCAAATGTTAACCCAACAAAAAGAGCAGGGGAATTAACAGCAGAAGAAATTAACAACATTGTTCACATTATGAATGCCCCCTCTCAATTCAAAATTCCAGACTGGTTTTTGAATAGAAGGAAAGATGTAAAAGACGGAAAGAATTTACATGTTATAGCAAATCAGCTAGATTCCTATTTACGTGAAGATTTAGAAAGAATGAAAAAAATTAGATTACACAGAGGTTTACGTCACCACTGGGGATTAAGAGTGCGCGGTCAGCACACCAAAACAACGGGAAGAAGGGGAAGAACTGTTGGTGTATCCAAAAAGAAAGGAGCGTAA
->XM_007952246.2 PREDICTED: Orycteropus afer afer chromodomain helicase DNA binding protein 3 (CHD3), mRNA 
-ATGGAGTGGGGGGACATCAAGGAAGAACCAAACCCAGGCCTTCTGACAGAGACATCTGAGGAGAAAGCCAGGGACCTAACCCTGCTGAAAGCAGGTCAGAGTGTGCTGAAGGAGCCACACACTATGATCTTGCAGGCAAGAAGTGAAAATGACCAGCTCAGGCTTTCTTTTCCTCTAAGGCTATGTTGCGATGACAGGAGGCTTGATAAGGATGACATTCGGCTGCTGCCTTCAGCTTTGGGTGTGAAGAAGAGAAAACGAGGACCCAAGAAACAGAAGGAGAATAAGCCAGGAAAACCCAGAAAACGCAAGAAGCTTGATAGTGAGGAAGAATTTGGCTCTGAGCGGGATGAGTATCGGGAGAAGTCAGAGAGTGGTGGCAGTGAGTATGGAACTGGACCAGGTCGGAAACGGAGACGGAAGCACCGAGAAAAAAAGGAGAAGAAGACAAAGCGGCGGAAAAAAGGGGAGGGAGATGGGGGACAAAAGCAGGTAGAACAGAAGTCATCAGCAACTCTACTTCTGACCTGGGGCCTTGAGGACGTGGAGCATGTATTCTCTGAGGAGGATTACCACACACTCACCAACTACAAAGCCTTTAGCCAGTTCATGAGGCCCCTAATTGCTAAGAAAAATCCTAAGATCCCAATGTCTAAGATGATGACCATCCTTGGGGCCAAGTGGAGAGAGTTCAGCGCCAACAACCCCTTCAAGGGGTCAGCAGCTGCTGTGGCAGCGGCCGCAGCAGCGGCAGCAGCAGCTGTAGCTGAGCAGGTGTCAGCTGCCGTCTCATCAGCCACCCCCATGGCACCTTCCGGACCCCCCACCCTTCCACCACCCCCTACTGCTGATATCCAGCCCCCACCTATCCGAAGAGCCAAAACCAAAGAGGGCAAAGGTCCAGGCCATAAGAGGCGGAGTAAGAGCCCCCGCGTGCCTGATGGACGTAAGAAGCTCCGGGGAAAGAAGATGGCACCTCTCAAAATTAAACTAGGGCTGCTGGGTGGCAAGAGGAAGAAGGGAGGCTCGTATGTCTTACAGAGTGATGAGGGCCCCGAGCCAGAGGCTGAGGAATCAGACCTGGACAGTGGCAGTGTCCATAGTGCCTCAGGTCGACCTGATGGGCCTGTCCGCACCAAGAAACTAAAGAGAGGGCGGCCAGGAAGGAAGAAGAAGAAGGTCCTGGGCTGCCCCGCAGTGGCCGGGGAGGAGGAGGTTGATGGCTACGAGACGGATCATCAGGATTACTGTGAGGTGTGCCAGCAGGGTGGGGAAATTATTCTGTGCGACACCTGCCCTCGTGCCTACCACCTCGTCTGCCTTGATCCTGAGCTTGACCGGGCTCCTGAGGGCAAATGGAGCTGCCCTCACTGTGAGAAGGAGGGGGTACAGTGGGAGGCCAAGGAGGAGGAAGAAGAATATGAAGAGGAAGGAGAGGAAGAAGGGGAAAAGGAGGAGGAAGATGATCACATGGAGTACTGCCGTGTTTGCAAAGATGGGGGGGAGCTCCTCTGCTGTGACGCTTGCATCTCTTCTTATCATATACATTGTCTAAACCCTCCCCTGCCTGACATCCCCAATGGGGAATGGCTGTGTCCCCGTTGCACATGCCCTGTGCTGAAGGGCCGTGTGCAGAAGATCCTGCATTGGCGGTGGGGGGAGCCACCTGTGACAGTGCTAGCCCCCCAGCAGGCAGATGGAAATCCAGATGTCCCAGCCCCTCGCCCTCTTCAGGGCAGATCGGAGCGAGAATTCTTTGTCAAGTGGGTAGGCCTGTCCTACTGGCACTGCTCCTGGGCCAAGGAGCTTCAGCTGGAAATCTTCCACTTGGTAATGTATCGAAACTACCAACGGAAGAATGACATGGATGAGCCCCCACCCCTGGATTATGGCTCTGGTGAGGATGATGGGAAGAGTGACAAGCGCAAGGTGAAAGATCCCCACTATGCTGAGATGGAGGAGAAGTACTATCGCTTTGGTATCAAGCCAGAGTGGATGACAGTCCACCGCATCATCAACCACAGTGTGGACAAAAAGGGGAATTACCACTATTTAGTGAAATGGAGGGACTTACCATATGACCAGTCCACATGGGAGGAAGATGAAATGAACATCCCTGAATATGAAGACCATAAGCAGAGCTACTGGAGACATCGAGAACTAATTATGGGGGAGGATCCCGCCCAGCCCCGCAAGTATAAGAAGAAGAAGAAGGAACTACAGACCGATGGGCCTCCCAGTTCTCCTACTAATGATCCTACAGTGAAATATGAGACTCAGCCACGGTTTATCACAGCCACTGGTGGTACACTGCATATGTATCAGCTGGAAGGATTGAACTGGCTACGCTTCTCATGGGCCCAGGGCACGGACACCATTCTGGCTGATGAGATGGGGCTGGGCAAGACCATACAAACCATCGTCTTCCTCTACTCACTCTATAAGGAGGGCCACACGAAAGGTCCCTTCCTGGTGAGTGCCCCACTCTCCACCATCATTAACTGGGAGCGGGAGTTCCAAATGTGGGCACCCAAATTCTATGTGGTGACATACACGGGTGACAAGGACAGCCGGGCCATCATTCGTGAGAATGAGTTTTCCTTTGAGGATAATGCCATTAAAGGTGGCAAGAAAGCTTTTAAGATGAAGAGGGAGGCACAGGTGAAGTTCCATGTTCTCCTGACTTCATATGAGCTGATCACCATTGATCAGGCAGCGCTGGGCTCCATCCGCTGGGCCTGCCTTGTGGTGGATGAGGCCCATCGGCTCAAGAACAACCAATCCAAGTTTTTCAGGGTCCTCAATGGCTATAAGATAGATCATAAGTTACTGCTCACAGGAACCCCATTGCAGAATAATCTGGAGGAGCTCTTCCATCTGCTGAACTTCCTCACCCCTGAAAGGTTTAACAACCTGGAGGGCTTCTTGGAGGAGTTTGCTGACATATCCAAAGAAGACCAAATTAAGAAGCTGCATGATTTGCTGGGGCCACACATGCTGCGGAGGCTTAAGGCTGATGTCTTTAAGAACATGCCAGCCAAGACGGAGCTCATTGTTCGAGTCGAGCTGAGTCCCATGCAGAAGAAATACTACAAGTACATCCTGACTCGAAATTTTGAGGCCTTGAATTCACGAGGTGGTGGGAACCAAGTGTCGCTGCTTAACATCATGATGGATCTCAAGAAGTGCTGCAACCATCCATACCTCTTTCCTGTGGCTGCTATGGAGTCTCCAAAACTCCCTAGTGGGGCTTATGAGGGTGGAGCACTTATTAAGGCATCTGGGAAGCTTATGCTACTGCAGAAGATGTTGCGGAAACTGAAGGAGCAAGGACACAGAGTGCTTATCTTCTCACAGATGACCAAAATGTTAGACTTGCTAGAGGACTTCTTAGACTATGAAGGCTACAAGTATGAGCGCATTGATGGTGGCATCACTGGTGCATTGAGACAGGAGGCCATTGATCGGTTCAATGCTCCTGGAGCCCAACAATTCTGCTTCCTCCTGTCCACCCGCGCTGGGGGCCTGGGCATCAATCTGGCCACTGCTGACACTGTCATCATCTTTGATTCTGACTGGAATCCTCATAATGACATCCAGGCCTTCAGCCGGGCCCATCGGATTGGCCAAGCCAACAAAGTGATGATTTACCGGTTTGTGACTCGTGCATCAGTGGAAGAGCGAATCACACAAGTGGCCAAGAGGAAGATGATGCTGACACATCTGGTGGTGCGGCCTGGACTAGGCTCCAAGGCAGGCTCCATGTCCAAGCAGGAGCTGGATGACATCCTTAAATTTGGCACTGAGGAACTGTTCAAGGATGAAAATGAGGGAGAGAACAAGGAGGAGGACAGCAGTGTGATCCACTATGACAATGAGGCAATTGCTCGGCTCTTGGACCGGAACCAAGATGCAACTGAGGACACTGATGTGCAGAACATGAATGAGTATCTCAGCTCCTTTAAGGTGGCACAGTATGTTGTGCGGGAAGAAGACAAGATTGAGGAAATCGAGCGGGAGATCATCAAGCAGGAGGAGAATGTGGATCCTGACTACTGGGAGAAGTTGCTGAGGCATCACTATGAACAGCAGCAAGAGGACCTGGCCAGGAACCTCGGCAAGGGCAAGCGTGTTCGGAAGCAAGTTAATTACAATGATGCTGCTCAGGAGGATCAAGATAACCAGTCAGAATACTCAGTAGGATCAGAGGAAGAAGATGAAGACTTTGATGAACGTCCTGAAGGGCGTCGTCAGTCAAAGAGGCAACTCCGGAATGAAAAGGATAAGCCACTGCCTCCACTGCTGGCTCGAGTTGGGGGCAATATTGAGGTGTTGGGGTTCAATACTCGTCAGCGGAAGGCTTTCCTGAATGCTGTGATGCGCTGGGGGATGCCACCTCAGGATGCCTTCACCACTCAGTGGCTGGTGCGGGACCTGAGGGGCAAGACTGAAAAAGAGTTTAAGGCCTATGTGTCTTTGTTCATGCGCCATCTCTGTGAACCTGGGGCTGATGGCTCTGAAACTTTTGCCGATGGGGTCCCTCGAGAGGGACTGAGTCGCCAGCAAGTGTTGACCCGCATTGGAGTCATGTCTCTTGTGAAGAAAAAGGTACAGGAATTTGAGCACATCAATGGGCGCTGGTCAATGCCTGAGCTGATGCCTGATCCCAGTGCCGACTCGAAACGCTCATCTAGAGCCTCCTCTCCTACCAAAACATCTCCCACCACTCCTGAGGCTTCCACTACAAACAGTCCTTGCACCTCTAAACCTGCTACTCCAGCTCCAAGTGAGAAAGGAGATGGAATAAGGACACCTCTTGAGAAGGATGAAGCTGAAAACCAGGAGGAGAAGCCAGAAAAGGATAGCAAAATTGGAGAAAAGATGGAGACAGAGCCCGACGCCCCCAGCCCAGTCCCTTCACTTGGGGAGCGGCTGGAGCCAAGGAAAATTGCTCTAGAGGATGAGGTGCCAGGGGTACCTGGAGAGATGGAGACTGAACCTGGGTACCGGGGGGACAGAGAGAAGTCAGCCACAGAGTCGACGCCAGGAGAGAGGGGGGAGGAGAAGCCATTGGATGGACAGGAGCACAGGGAGAGGCCGGAGGGGGAAACGGGGGATTTGGGCAAGAGAGAAGATATAAAGGGGGACCGGGAGCTTCGACCAGGGCCACCTCGAGATGAGCCACGATCCAATGGGCGACGTGAGGAGAAAGCAGAGAAGCCACGGTTCATGTTTAATATTGCAGATGGTGGTTTCACAGAGCTTCACACACTGTGGCAGAATGAGGAACGAGCAGCTATCTCCTCTGGGAAACTCAATGAGATCTGGCATAGAAGACATGACTATTGGCTTCTGGCTGGGATTGTCCTCCATGGTTATGCACGGTGGCAGGACATCCAGAATGATGCTCAGTTTGCCATTATCAATGAGCCATTTAAAACTGAAGCCAATAAAGGAAACTTTCTGGAGATGAAAAATAAATTTCTAGCCCGAAGGTTCAAGCTCCTGGAGCAGGCGCTGGTGATCGAGGAGCAGCTGCGGCGGGCGGCCTACCTGAACCTGTCACAGGAGCCGGCGCACCCCGCCATGGCCCTCCACGCCCGCTTCGCCGAGGCCGAGTGCCTGGCCGAGAGCCACCAGCACCTCTCCAAGGAGTCGCTGGCGGGGAACAAGCCGGCCAACGCCGTCCTGCACAAGGTTCTGAACCAGCTGGAGGAGTTGCTGAGCGACATGAAGGCAGACGTGACCCGCCTGCCAGCCACGCTGTCCCGAATACCTCCCATCGCAGCCCGCCTTCAGATGTCCGAGCGCAGCATCCTCAGCCGGCTGGCCAGCAAGGGCACAGAGCCTCACCCCACACCGGCCTTCCCTCCGGGTCCGTATGCCACACCTCCGGGGTACGGGGCAGCCTTCAGCGCCGCACCCGTAGGGGCCCTGGCCGTCGCAGGCGCCAATTACAGTCAGATGCCAGCAGGGTCCTTCATCACAGCCACCACCAACGGCCCTCCAGTGCTGGTGAAGAAGGAGAAGGAAATGGTGGGGGCAGTGGTGTCAGACGGGCTGGATCGGAAGGAGCCCCGAGCCGGGGAGGTGATCTGTATAGACGACTGA
->XM_031808598.1 PREDICTED: Oncorhynchus kisutch rap1 GTPase-activating protein 1-like (LOC109896808), transcript variant X3, mRNA 
-ATGAGGATCTTTACAGTCAGGCACATGCTCACACAGATATAGTACATACAGACCTATACAAACCCATGCATTCTAATGGGCATGCAGACCTGTTAAGAGACCTGAGACGCAGCAGTTCTTGTCTTGTATTTAGGGGCAGTAGAATACAGAGTGTAAAGTGACAGTAGTAGTTAGACCTCTGACACTCCTCTGGTCAATATACACACAGAAACAAATATACCCATACTCTGTTTTTGGAGTCGGAGTTTTGGAGTTATGAGTGACTTCAGGATGACTAAGAGTGGCCATGTGTTCCTCAGTCCTTCGGTTATTACATGGGGCCAGAGGAGACGACACAGTGATACATCAGACCTATTTGCAAAGATCGAGAGGATGCAGGGCAGCAGAATGGACGAGCAGAGATGCACCTTCCCTCCACCCCTCAAAACAGAGGAGGACTATATCCCTTACCCCAGCGTTCACGAGGTCCTGGGTCGTAGGAGCCCCTTCCCCCTAATCCTGCTGCCTCAGTTCGGAGGCTACTGGATCGAGGGGACCAATCACAAACCCAGTGCCACACCTGAGCCTGAGCAGAGGCCCTGTGCGTCCTCCCACATCAAGCTGGAGACCAACAGCATGGCCAAGATCTACAGGAAACAGTTCATGGGCAAGGAACACTTTAATTACTACTCCATGGACATCGGCCTGGGCCACCTGGTCTTCTCCATGAAGTATGATGTCATCGGGGACCAGGAGCATCTCTGCTTGCTGCTAAGGACCAAATTAAAAACTCACCATGATGTGATTCCTATCTCCTGCCTGACTGAGTTCCCCAACGTGGTCCAGATGGCCAAGCTGGTGTTTGAAGAGGTAAATGTGGACAGATTTTACCCAGTCCTCTACCCAAAGGCTTCAAGGCTCATTGTCACCTTTGATGAGCATGTCATCAGCAACAATTTCAAGTTTGGAGTCATTTATCAGAAGTTTGGCCAGACCACCGAGGAGGAGCTATTTGGGAACAGCGACGAGAGTCCTGCTTTTGTAGAGTTCTTGGAGTTTCTGGGGGACAAGATTGAGCTCCATGACTTTAAAGGGTTCAGAGGAGGACTGGACGTCACCCACGGCCAGACAGGAACAGAGTCTGTCTACACGAACTTTCACAACAAGGAGATCATGTTCCACGTGTCCACCAAGCTGCCATATACAGAGGGAGACTCTCAGCAGTTGCAGAGGAAGAGGCACATAGGCAACGACATCGTGGCCATCTTGTTTCAGGAGGAAAACACACCCTTTGTGCCAGACATGATAGCCTCCAACTTCCTGCATGCCTATGTGGTGGTGCAAGTGGAGAATGCCTGCTCAGACAATGTCACATACAAGGTGTCTGTGACAGCGAGAGATGATGTGCCTTTCTTTGGACCCGCTCTACCGGACCCGGCCATCTTTAAAAAGGGGCATGAGTTCCATGAGTTCCTGTTCACTAAGCTGATCAATGCGGAATATGCCTGTTACAAGGCTGAGAAGTTTGCAAAACTGGAGGAGCGCACGCGGTCGGCCCTGTTGGAGACCCTGTATGAGGAGCTACACATTAACAGCCAGTCCATGATGGGCCTGGGAGGGGACGAGGACAAACTGGAGAATGGGGCTGGGGGGGGAGGGGGCTTCTTTGAGTCCTTTAAGCGGGTGATCCGCAGCAGAAGCCAGTCTATGGATGCCATGGGCCTCAGTAACAAGAAGCCACACACTGTCTCCACTAGTCTCAGTAGCAGCTTTACCGAGACCCCCAAAACCCCAGGGATATCTCTGATCATTCCTGGGAAGAGCCCCACCAGGAAGAAGTCTGGGCCCTTCAGTGCCAGACGGAGCAGCGCCATCGGGATCGAGAACATCCAGGAGGTGCAGGAGAGGAGTCGGGAAGTGTCCCCCAGCACACAGAGGACTCCAGACAGTGGACACATCTCCCAGGACCCCAAATCAGAGAACTCATCTAATCAGAGCTCACCAGAGATGCCCACAACAAAGAACAGTTTGGCCATGTGTTGCAGGGCCCCTTCTATCCCTGAGGCCCAGGATCTGTCCCGCTCCTCGTCCAATGCCAGCAGCTTCGCCAGCGTGGTGGAGGAACACGATAACGAGGGCATCGAAGAGTACGACACGGGACTGGAGAGCCTGTCCTTTTCTGGAACACCACACAAGAGAGACTCATTTGCGTACGTGTCCTGGGTAGAGGATAGTTTGAGCAGTACTAGTGCCACCAGCCAGGGCAGCTCTCCAGCACCTGCACGGTCCCGGCAGCCTGAGGGGGGCAAAGGGGAAGAGCTCAAAAAGGCGGAGAGCCGAGACAAGACAGAGCGGTCACAGGATAAGTCATCATCGAACTGTTAGCCTCACCTCATTGATCAGTACATGGATGTCCATTAGCAGCATTCCCATAAGAGGCACCCCCTGCAGGAGATGAAGCAAGCGCACGTGTGTTCCACCACAGATGCAGAGGAGGAGCAGAGCTAGTCGCTGGGACAGACAGCTAGACCTGGTGTAAACTAGTCCAGTCTGAACAGCCAGGTCCATGGACATGCACTTACAGCCTTCCCTCATCCCAACTCTTTGTGGCTGACTCCCAGCATGCTTAGAGGGGTGAAGGAGAGGATCAGCCCACACCCATTCCCAAAATGAGTGCCACTCACACAGTATCGCTTCTGGCTGTTGTCTGTTGGCTCGCTTAGCCTGCATATATTTCTGCTCCATGAGCTCTGTGAAGCCTAAATCTGTTCATGTGGTAACTCATAGTATACTCTCCCTTGTCCTCTCTATGGCATTGTTTTTGTTTTGGTTCGAAGGTGGAGGGAGGGGAGGATCTTAAGCATTAGACAGATTGGTGTTGCAGGAGATCCGTTGATCATGCATTAGGGGAAGTTTTCTGTTAGGCTAAAGAGGAATGCATGAGGAGGATAAGAGGGTGTTGTCCTGTTGTCATTGTTGGAAGAACTGACATTATTGCTCCCATCAACCTCACGTCCCACCATGATACTGTACATTTGTTATTCTTGGTGTCCCGGATCCTTTGATGTCACACCAAGCCTTGTGTTTTATTAATGGTCAATTAAGAGTGTAATGGTGGATGTTGACTAGAAACTTTTAGTAAAATGTTACATGTTTTTGGTAGAAGGTACTTTTATCATCATGCTGCTGCTGGTTTTGATTCCATTATTCATTTCCCCTGACAAACTGTACAATTACAGTTCACAGTTTATGAATGGACAATACTTTACTGACTCCATAATTATAGTCAACGTATTTCAGGCCATTTAAAGGGGTAATTTGCAGTTCAAACAACAACAAAGTCTTTACCCCGCCACTTTTTCGATAACCAGCTGAGTGATGGGGTTGGCGAAAAGTAACCACTCTCAAATTCCTAGACAGAGCTATGGATGCAAGGACTGACCATCCAGGATAGCAAAATTATACTTTTAACCATGTTGAGGCTATATAGTGTTTGTTTACAGTTACCTTGTTTACTAACTAATGAGTAAAACACATTTTGGGTTTTGATGGGGTACGACAGTTGAACTAAGCGCATGAAGCATTTATAAGTAATATTCTTCAAGAATCAATGGGTATATATAATTAATTTAAATGTAAAAAAAAGCTATGTAGCAATCGTAGATTGCCCCTATAAACTGAGGAAAAAAACATGAAGTATTGAATTACCGATAAGGTCTAGTGTTCAAACTAAATTACTCATCAGTCTTCACTGTCCCATACTGTAGATAGTACCACACAGTCAGACATTCCTCCAAGGTGACCTAACCAAAGCACACAGCCTCCAAAGCCAAGCTATTGTCCAGTGACTACTGTCTTCAGTTTATTTTTTAAAACCTCTAGTTTGTTTTAAAGTATGTGTTTGGATGTGTATGCATGGTGAATGGTGTAAATCTGCTTGCAAAACCATGTCAACTGTACAGTACCATACTGGAAAAAGATTGTTTCTTCAAACCAGTCCAACTTCTCTAGAAAAGCAGACAGTCATTATTTCTATAAATCAGTTTCGATAGAGAAATATGGCGATACAAGTGTAGATGTGGAAACTGGCACTACATTTTCAATTAATTGTTTTTTTTATTTTTATTTTTTTTAATCTGACTTGGTTTTTAAAAATAATTACACTGTGACAAGTTTTGAAGTGGCCTTTTTAATGATTGTGTTAATTAAGCTGCTTTGTAGGAGGGTATCCCCCTTCATATAAGGAATCTATCCCATGGTGGATATCGCCACTGGATTGAATGTAAAACTAAACAGATATATGTATTCATTTGTAGACATCTGCTCTCAATGAATGGAACCTTTGTATCTTGTTGTAATGTTTTACATTTTCCCTCATCTCAGATTTATATAATGAAAAGACCTGATATGAAGGCATAGTTTCCATTACTTTTTATTTAAATTAAATGAACAAAAGCTAACATGGAATTTAGTTGCACTTTGTCAGTTGTGGCATTAATGCATAAACCTTTTACACTCCTTTGGAAATCTTTCAGTTGAATCTAAAGGATCTCTGTAAGTAAGGAACACTACATCAAAATACAGTAAGTTTGACAAGTATTTATTATTAAACACCATTCTAAAGATTATGATTCAACAAAAAACTATTAATTGAAATTGTGATTGGAAAGATGAGAAAGTAACCTTTCATCAGCTTAAGAGAGCCTTTGGAGTCCGTGTGTATTCCAGGCACTGAAACTCTAAATATATCAAACACAATTTTCATCTCAAAGCTTAAAATAAATGTATTAAAACTCACGAGTCTTCAGAAATGCTTGAATAGTTGGATCACACCCTCTGGTGGCTCTAGATTATACTTACACATTTCTCTGTGGTCCTGTTCATCTGTACCTGTGTTTGTACATGTAAATGCAAGACACTTGGATTGAGCACCCAGCCAATCCAAACAACAGATTCTGCCTACAATGTGCTTAATTCAGATGATTGTATTTCTGTTCTCGTTGATATTCCGCTCAAGCCCTTGTTTAAGTTGGAAAGTCTTGTATATAAATATAGCTTTTCATCCTTTTGTAAAAAAAAAAAAAGGCAAATACATGTTTAATAAAGACAAAGGGGTAA
->DQ727116.1 Mus musculus piRNA piR-142438, complete sequence 
-TGGCAACAGTATTGCTCTGGCTCCA
->XR_005158834.1 PREDICTED: Triticum dicoccoides uncharacterized LOC119328068 (LOC119328068), transcript variant X2, ncRNA 
-CTGCGTTCAGCGCTGCCATCCTGTCTAGTGCGCTCCCCTGACCGGCGCCATGAGAGCGGCTGCGCCGGTGGCTCTCGTGGACAGCGCGTGCATCAGTAACGTCGCAAAGTTCTTCCTCGCGAACAGCATCGCAGCACCGGTCGGAGCGGCGGCCATCCGTCGTCCCCCTCTGCGTTGTGCTACGCCGTCTCCGCTGAAGCTGCAATCTCCTCGGACGACCGCGTTATTGAGCGGATTTTCCTCATCCAGCAGCGCTGGCGACTCGTATCCATCTACCAAAGAAATGAGCAGCATCTTATCCATTCACTATGCTTCTTTTTTTCCTTTTACCCAGCGTTTGTACGAACAGGGAAACCCTCAAACGACAAAGACCAGCAGGATAGGAAGGGTGACAATGAGATGGCAGGCGCTGGAAATGTTTCTGATGTGGATCTTGCTAGGAAAATGTTAGATACTGCAAGAGGTAATAATGGAAAAGAGCAAAGGCAACACTGCGGAGATATCAAGAATCCTTTCCGCGGAAAAGAGAAAGAGTGGAATTAATTTGACAAGTCACTCAGTGAAATGTTTAACCATCTTGGAGCATTTACCTAGCTGTGCTTGACACCAGGGGCAAAGGCTGCCCCTTTTTCTTGTTCAAGGGTGGCGCGGCGAACACAGATGCAACATCGGCGAGAGTCGTTGGGGACACTGATATTTACCCAGGTTTGGGCCGCATGGTAACGGCTTGGATGTTCGCGACTTGTTCATGGGAGCCCACGACTTGGGCGTTCCTGGGAAGAATGCGGATGTCTTGATATCTCCTTATACCTTATTGTTGGTGCGGAAGCCGAGGGTCACGAAGGTAGCACCTCTCGATGACCTGCCTGGATGTCTGTGCTTCACTTGTATCTCCAGGGAGGAGCCTTGGATGATTCTTGGATATGCTGATGCCTAGGTGATCTCCCGGCAAGGAGCCACTGTGTGCCGCACGCATGAGGGTTTGTGGGTACCCGATACCCGCGACACCGACAACCTAACTGCATTCTGTTTTGGGTATGAAACTGTCAATCGTCTGTCATATAGCAGTAGTATTTGCATCCTTCTGAGGTGGGTCTCTGTGGTTTTAGGAGTACTAAATTTTTAGTTAGATACGTGCTGGTATCTTGTAGATTTGGCTGGTCTTCCTGTTGCTTAATTATCCCCCTTAATTCAGTCCCGGGACTCCCTGCACCGGCTTGGTCTTGGAGCTGCCTCCATTATGTAAATTGTGTATACAGAACCATGAAAGTGCCAAGGAGACTCGGAAATTCCACTTGAGAAGATGAGATAA
->XM_024744316.1 PREDICTED: Neophocaena asiaeorientalis asiaeorientalis ataxin 2 like (ATXN2L), transcript variant X4, mRNA 
-ATGTTGAAGCCTCAGCCGCCACAACAGACCTCCCAGCCCCAGCAGCCGCCCCCCACGCAACAGGCCGTGGCCCGCCGGCCTCCCGGGGGCACCAGCCCTCCCAACGGCGGCCTCCCGGGGCCCCTGGCCTCCACCTCGGCTCCCCCAGGGCCTCCCGCCGCTGCCTCCCCCTGCTTGGGGCCTGCAGCCGCTGCCGGGAGCGGGCTCCGCCGGGGAGCTGAGAGCATCTTGGCGCCGCCGCCGCAGCAGCAACATCAGGAGAGGCCAGGGGCAGCGGCCATCGGCAGCGCCAGGGGACAAAGCACAGGAAAGGGACCCCCACAGTCACCGGTGTTTGAGGGTGTCTACAACAATTCCAGAATGCTGCATTTCCTTACAGCTGTTGTGGGCTCCACTTGTGATGTAAAGGTAAAGAATGGTACCACCTATGAAGGTATCTTCAAGACACTGAGCTCAAAGTTTGAACTGGCAGTAGACGCTGTGCACCGGAAAGCATCGGAGCCAGCAGGTGGTCCTCGTCGGGAAGACATTGTGGACACCATGGTGTTTAAGCCAAGTGATGTCATGCTTGTCCACTTCCGAAATGTTGACTTCAATTATGCTACTAAAGACAAGTTCACTGATTCAGCCATTGCCATGAACTCGAAAGTGAATGGGGAGCACAAGGAGAAGGTGCTTCAGCGCTGGGAGGGGGGCGACAGCAACAGCGATGACTACGACCTGGAGTCTGACATGTCCAATGGATGGGACCCCAATGAAATGTTCAAGTTCAATGAGGAGAACTACGGCATAAAGACCACCTATGACAGCAGTCTCTCTTCTTACACGGTGCCCTTAGAGAAGGACAACTCAGAAGAATTTCGTCAGCGGGAGCTGCGTGCAGCCCAGTTGGCTCGAGAGATTGAATCGAGCCCCCAGTACCGCCTGCGGATCGCCATGGAGAACGATGACGGGCGCACCGAGGAGGAGAAGCACAGTGCAGTTCAGCGACAGGGTTCAGGGCGAGAGAGCCCCAGCTTGGCATCTAGGGAGGGAAAGTATATCCCTCTACCCCAACGAGTTCGGGAAGGTCCCCGGGGAGGAGTTCGATGCAGTAGTTCTCGGGGTGGCCGGCCTGGCCTTAGCTCTTTGCCACCTCGTGGCCCTCACCATCTTGACAATAGCAGCCCTGGCCCAGGTTCTGAGACACGCGGTATCAATGGAGGCCCTTCCCGCATGTCCCCTAAGGCACAGCGGCCTCTGAGAGGTGCCAAGACTCTGTCTTCCCCCAGCAGCAGGCCTTCTGGAGAAGCTTCTGTTCCACCTCCTCCTGCAGTAGGCCGGATGTACCCCCCGCGCTCTCCCAAGTCAGCTGCCCCTGCCCCAATCTCAGCTTCCTGTCCTGAGCCTCCCATCGGCTCAGCAGTACCGACCTCTTCAGCTTCCATCCCCGTGACATCATCAGTTGGGGATCCTGGAGTAGGCTCCATTTCCCCAGCTTCTCCAAAGATCTCACTGGCACCCACAGATGTAAAAGAACTCCCAGCCAAGGAACCTGGGAGAACGCTGGAGTCCCAGGAGCTGTCCCGGATAGCAGGGAAAGTCCCTGGCCTTCAGAATGAGCAGAAACGCTTTCAACTGGAAGAACTGAGAAAATTTGGGGCCCAGTTTAAGCTTCAGCCCAGTAGCTCCCCTGAGACCAGCCTGGATCCTTTTCCTCCCCGGATCCTAAAGGAGGAGGCCAAAGGGAAGGAGAAGGAGGTTGATGGTCTTTTGGCTTCAGAGCCCATGGGGTCCCCTGTTTCCTCCAAGACAGAATCCATATCGGATAAGGAGGACAAACCACCCCTGCCACCAGCAGGAGGCGCCGAAGGGCCGGATCAGCCCCCACCACCTTGCCCAAGCCAAACCAGTAGCCCCCCAGTGGGCCTCATCAAGGGAGATGACAAGGATGAGGGCCCTGTTGCTGAACAAGTGAAGAAGTCAACATTGAACCCTAATGCCAAGGAGTTCAATCCCACTAAGCCGCTGCTGTCTGTGAATAAATCCACCAGTACTCCAACTTCTCCTGGGCCCCGGACTCATTCAACTCCCTCCATCCCGGTGCTGACAGCAGGCCAGAGTGGGCTATATAGCCCCCAGTACATTTCCTACATACCTCAGATCCACATGGGACCAGCTGTTCAGGCACCTCAGATGTATCCATATCCTGTGTCCAACTCAGTGCCTGGACAGCAGGGCAAGTACCGGGGAGCAAAAGGCTCCCTGCCCCCCCAGCGCTCGGACCAACACCAGCCAGCCTCAGCCCCTCCGATGATGCAGGCCGCCGCCGCCGCTGGCCCCCCTCTGGTGGCTGCCACACCTTATTCTTCCTACATCCCCTACAATCCACAGCAGTTCCCAGGCCAGCCCGCCATGATGCAGCCCATGGCCCACTACCCCTCGCAGCCGGTGTTTGCCCCCATGCTTCAAAGCAACCCACGCATGCTGACGTCGGGGAGCCATCCCCAGGCCATTGTGTCATCCTCCACCCCTCAGTACCCTTCTGCAGAGCAGCCCACCCCCCAAGCCCTTTATGCCACTGTTCACCAGTCCTATCCACACCATGCCACGCAGCTCCATGCCCACCAGCCGCAGCCGGCCACCACGCCTACTGGGAGCCAGCCGCAGTCCCAGCATGCAGCCCCCAGTCCCGTCCAGCACCAGGCGGGGCAGGCCCCACACCTGGGCAGTGGACAGCCACAGCAGAACCTGTACCACCCAGGGGCCCTGACAGGCACGCCGCCTTCTCTGCCGCCGGGACCTTCTGCGCAGTCCCCTCAGAGCAGCTTCCCCCAGCCAGCCGCTGTGTATGCTATCCATGCCCACCAGCAGCTGCCCCACGGCTTCACCAACATGGCCCATGTTACCCAGGCCCATGTCCAAACTGGAATCACAGCAGCCCCGCCCCCTCACCCTGGGGCTCCCCACCCGCCCCAGGTGATGCTGCTGCACCCACCCCAGAGCCATGGGGGCCCCCCCCAAGGCGCGGTGCCCCAGAGTGGGGTGCCTGCACTCTCAGCTTCCACACCCTCACCCTATCCCTACATCGGACACCCCCAAGGTGAGCAGCCTGGCCAGGCGCCTGGATTTCCAGGAGGAGCCGATGACAGGATTCCTCCCCTTCCACCCCCCGGGGAACTGAAGATTGTCCTGGCCGCGACCTGAGACCTCCATGAGTGGAGGGAAGAGTGACCTATGTCTCTTCCCCCAGCAGCTCGGACCAGTCCCAGCCCCCCAATCCCCCTTTCCCCCCGGGGGCGGGGGGAGCTGGGGAATTCCTGCCAAGCACCTTGAATGGGAAGGGGGGCCTCAAAGTGGGCAGGGCCGGGGTCCAGC
->XM_034818856.1 PREDICTED: Vitis riparia uncharacterized LOC117905960 (LOC117905960), mRNA 
-GAGGGGAGAGGGAGAAGAGGTTAAATAATGAATGGGTTCTGAGGAATTGCTACCTTCTTCACCACTTTACTGTTTCTTTCAACCACGCTCTCCTGCCTTTCTTGAACCAGTCTTTGGTCCACGCATGCCTCTCTCTGCAGCCGTCTCTCTTCTCCTTATTTAGCTTTCCTTCTTAATTCCTTCTTTCCTTATATTGGATTTTTTTTTTTGTTGACATAGAGAAATCCAAAAGGAAAAACAGAAAAGCATCGGGTCATTTGGGGAGAAGGGATGTTGGGATGGAAGCATATCACGGTGGCTGCGGTGGCGGCCGGAATACTGACTGTGCTTCTGATCGTGTTATTTTGGCGATGGTGTTGTAGTAAAGGACATAAGGATTTTGTTGATGCTTCCAGGAATAAACATCAGAGCTTGCAAGCTGGGATTGCGAAACTCCACCATGTTAGCCTTCCTCCATATCACCATGATCTAGACAGCAAGAGAAAGGCGAATTACTATGTTTTTCGACGTGGGGTTTCATCCAGACCTTTGTTTAATTGGGCGCATCATCCATCGCTCGTCACGGATGCGGTTGAAAATGGGTGGTCTCGATTCGGTTTCACGAGCTACATGTCGTCTCCCTCGATGAGATCATCGCTGTTGGGATTATGCGCAGTGGGGGAACATGGGAAAGAAACGGGGGCGGAGATTAGCTGGGAAGTGTCTCAGGGATCGGCTGATTTCATGCAGAAGATCAGATTGAATTCTGGGTTAAAGAAGATGAATATGAGCAGTCCTTCCATGGCTGCTGCATCTGTAATTAGAACAGCTTTGCCACTGCCAGGCCCTCCCTTGGGGAATTCCTCGTTCCCGCAAGAAGCCTACTTCGAAATCACAATATTGTTTTCCGGTGAAGGTGATCCTGAGTCTGTTGGCCGGGTTAAGGAAGGTGAGAGAACGAAGCTCATCCATGAGAATTCCAATGCTAAAGCCAATTCAGAATCTATAATCCATCTTGAAGAAATGAAACTCGGCTCTAAGGACGACGGCAAAGGTGAAGTCGTAATGCTATCGGTGGGGCTCACCGCCGGAGGCTCTCTTCCTTTGAAACTTCCTGGCAGCTACCCGGGATCAATTGGATTTAACTCCAATGGCTCTGTCTATCTTGACGGAATTAAACTTGTATTCGAATCGGAGAAGGAAGAATGGGAAAGGGCAGACAAGGTTATTGGTTGCGGATTTGATCCTAGCCAGAAGAAGGTGTTCTTCACAATAGATTCAGAACTAGTTCATGTAGTCCATTGCAAGTCAGAGGAATTTGGGAGTCCCCTTTATCCAACCCTCGGGGCAAACACAGACGTGGAAGTTCTGGTTAATTTTGGACAAAGTATGTTCAGCTACGCACCCGCCAATGCACAAAGAACTCCGAACCCTTGCTTTATCGGCCCCCTTGTGAATTCCCCCGCTGCTGCTCTGGGGTATGAAGACAGCAGGGAGCTTTTCTCAATGGGGAGAATAGACTCCCAGTGGCTCAACAGATGCACAACCAAAAGCAGCCACAACAATGGCAGTAAAGCATTAGATTTCGATGAGGATTCTGAAGCTGATTTATTTGAAATAGTCTTGGACAGAAGTGGCCGATCACCACACGCAGTATTGTAGAAACAAACTATAAATATCACTAGGATTTGTTGCATATATGCCGCCCACATGCATTTGCTGAATGCAAAATTTTCATACATTCACAAGCCTCTTTTAGGGTTTCACCTTCGCTTCTCCTATTACATATACCAACAGGTTCTTCAGGAACTGCTGATACATTTTTTTCATCACCCCTGTAACTAGAATTTTCATTTATTTTCCCTCTGTATATATCATGACTAATGTTCCTCCTCCTGGTTGAGTGATACCAATGTTCTTTCAGTTC
->MF368550.1 Uncultured bacterium clone New.OTU5316_1 16S ribosomal RNA gene, partial sequence 
-TACAGAGGTGGCGAGCGTTGTTCGGATTTACTGGGCGTAAAGGGCGCGTAGGCGGCGAAGTGTGTGAGGTGTGAAATCCATGGGCTCAACCCATGAAGTGCGCCTCAAACTGCTTCGCTCGAGTTCGGGAGGGGAGATCGGAATTCAGGGTGTAGCGGTGAAATGCGTTGATATCCTGTGGAACACCGGTGGCGAAGGCGGATCTCTGGACCGATCCCGACGCTGAGGCGCGAAAGTGGGGGGAGCAAACAGG
->XM_050853872.1 PREDICTED: Eriocheir sinensis uncharacterized LOC126994540 (LOC126994540), transcript variant X10, mRNA 
-ACACACACACACACACACACACACACACACACACACACACACACACACACACACAACACAGATGCTATGAAGTTCGTACCAAAATACAGACCGAGGGAGAGGGCTAAAAAGGACTGGTTTAATACAAGATGTACAGAGGCAAAAGAAAAGATACAAAGCTTGGTCAAGATTGAAAAGAAACAGAAATCAATGAAACAAAGAAGAGGAGAAACGATACGAAAAGGATATCGTGGAAAAGTATAAAGAACAACCTAAATTATTTCATAGATTTATAAGTGGAAGAATTAAACCAAGAGAAACAATTGAAAGACTGACTGAAGAGAATGAAGAGATTGACGCTCCCAAAGGCAGGGCGGAAGTACTTAACAAAAAACTCCAGGAAGTGTTTACCAAAGAATCAATATTTAATGAACCACAAGAAAACAACTTAGATGTATATATGGAAGAGCTCAAAATAGATAGAGAGGAGATAATAAAACTATTTGGGGAATTGGGAGAAGGGAAGGCCATGGGACCAAATGGAGTTTCAGGTTTTATGCTTAAAGAATGCAGAAATGAGCTAGTTAGCCTGATATATGACATAATTACGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATAATTAGGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATAATTACGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATCATTACGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATAATTAGGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATCATTACGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATAATTAGGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATAATTACGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATCATTACGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATAATTACGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATAATTACGTGCTCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATAATTACGTGCCCAATTAAAAGAAATGAGCTAGTTAGCCTGATATATGACATCATTACGTGCCCAATTAAAACGGGCACAGTGCCTAGGGAGTGGAAGAGGCCAGGAGTGGAACTTATATACAAAAGTGGAAGAGAGGATGAACCCCTTAATTTACAGACCAGTGTCTCTGACCAGTGCGCAAAATATGTGAGAAATTAATAAAAGAACAATGTGTGAGATTTCTAGAAGAACATAATCTAATCACAAACAATCACTATGGGCTTAGGAGAGGCCGCTCATGTGTGACAAACTTGCCGAGCCTTTACTCAAGAGTGACGGACAAATTACAGGAAAGAGACGGATGGGTGGATTGCATTTACCTAGACTTAATGAAGGCATTTGACGAAGTTCTGTGGAAACTAGAAAATAGAGGAGGATTGAGAGGGAAGATGACGTGCTGGATGGAAAGCTACTTAAGAGGATGAGAGATGAGACCCGTGGTTAAGGGCGCTAGATCGGAATGGAGGGCTGTGGACAGTGGAGTGCCCCAGGGGTCGGTTTTGGCCTAGTCCTAGTCTATATTACTGACATGCCGGAGGGAATAAACAGCTACATGAGCCTGTTTGCAGATGAAGCCAAACTGCAAAGACAGACAAGAAACAGTGAAGCCTGCAAGAAGACCTAGACAAGATTTGGAAATGCAGTCAGAAATGGGAGATGAAATTCAACGTGAGGAAATGTCATGTTATGGAAATGGACATGGACTTATAAAATGGGAGATGGGGAGATATTAAAGAAAGTATATGAAGAGAGAGAGAGACCTGGGGGTAACAGTGAAAGATTATATGCAACCAGAAAGTCATATAAATCAGATCTTTGGTGATACGTTTAACATGGTGAGGAATATAGGCATAGCATTCCACTACATGGACAAAGAACACGGGAGCTTAGGGTCAAAGGAGCTGCCTCGTATAGGCCTACCGACCTCTTGCAGACTCCTGCGTTCGTATGTTCTTAAGAAATGATGGAAAACTTAATAACTACTATGATCAGACCTAAGCTAGAATGCGCGGAAACAGTGTTGTCTCCACATACGAAGAAACACAAATATATATGCTATTGAGTAGAATGGAAGTAGATAACGAGAAATTCCCACTAAGAGACGAACCTTCCAGCAGGAATAGTAGAGGACACAGTAAAAGGTTGAGGAAGGGAAGATGCTTGAGAGACATAAAGAAATATAGCTTCCCACAAAGAAATATAGAGGCTTGGAACAGACTAAGTGAGGATGTAGTATCAGCGAACTACTACTACTACTACTACTACTACTACTA
->XR_005515939.1 PREDICTED: Hibiscus syriacus uncharacterized LOC120120851 (LOC120120851), ncRNA 
-GATCTAATAGGTAAGAGAGAGCTTTCTTCAGTCCACCCATGGGTAGCGATGGGATTTAATTAGCTGCCGACTCATTCACCCAAATACTGAGTTAAAATGGACCGGCCTGCAAATAGTTACTCAGTAAATGAGTGAATGATGCGGGAGACAAATTGAATCCTAATCTTCCTGTGCTTGGACTGAAGGGAGCTCCTTCTGCTGTTATTTTATCAACACCTAAACTACTTTCATCCATGTTTTTCACGACGACCACTACCTTTATATATAGTAATAATTTGTGGCTGAGATATCAATGTAGGAATAATGATCGCTTTATTAGCTTGTTTGTTTGTTCTTCATTGACATTTATATAGATTATCTCAACTTCTTAATGGCGGTGCGTTCTCATTGTTTGACTACTACGAAAGGAAAGTTTCGTTTTTCGCTCCAGGAGGAAAATTTTGCAGCTGTTTCTGGAGTCTAGGGCTGAGGGTTTTACTGTGAAGCTGCTGTTGCAGTTTCTTGTTTAAAGCTCCACC
->XM_049955181.1 PREDICTED: Schistocerca nitens uncharacterized LOC126253663 (LOC126253663), mRNA 
-GTTTTGTTGAAGTATAATAATGAGTAAAAGTAAAGTTATTAGAAACCCTCTGAAGGCTTTTAAGAAAAGGAGAAATGTTGGAAAGCCAAAGGTATGTGTTATTACTGTAAACAATAAAGACGATGAAAATGCCCAACATAGCTTGTGTCCCAAAGAAGAAGACAGTTGGTGTAAATATAACAAAGGATTGCTAACTGGTGAAGTGTACACTCATAAGCATAGTCTGCCTCATGCAATAATGGAGGTGATAAAACCTATTTTCAGAGACTTAGCAGCACCTGAACTGTTGAAAAAGTGTATTCACGGAAAAACTCAAAACCCCAATGAAAGTGTAAATAGTGTTATATGGTCGAGAATCCCCAAGACTGTATTTGTTGGAATAGAAACACTTCACTTTGGTGTGTATGATGCTGTTGCGACTTTCAATGATGGCAACATTGTAAGGTGCAAGGTATTTAGAAATATGGGAATGAAGATAGGTTCTAACATGGTACGAGCAATGCTTGCTTTAGACAAGGAACGCCTTCGGGCTGCAGACAGGGCTGTAAAGAGTCTAGAAATACAAGCAAGAGTAAACAGGAGGAGGAACAAGAGGAAGCTGGAGGAGGAGTTTGCAGAGGATGAAGATAATCCATCCTATGGACCTGGAATGCACTAAAAAGTTAATCCAATCTTTGTCGCTCGATTCCCAAAACTTTTATTTTCTCATACTAATTACATGTTTTCTAAGGATCTTCCAAACATATT
->XM_028358397.1 PREDICTED: Glycine soja membrane-anchored ubiquitin-fold protein 2-like (LOC114396422), transcript variant X3, mRNA 
-ATTATTATTGCTTTGCAAAACACTAACCAACCAAAACAAAGGGAAAAAAAAAGTATCCACTTTCCCTTCTTCTTCTTCCATTTGGGTTTTCTCAAAAGTGAAAAGCAAATTCCGTGACTTCCACAATCACCACTCGGATCAAACTCTTGAGTGATAGACTTTGAATGAAATCTTGTTTTTCATTAACGAGATTCAATTGAAGTGAAGTGATTATTCACTGGAAAACTTATTTTTCATAGTATTGGAGGTACAACTGAAGCTGTTAGATTTGTTTTAACTACACGAGTTCGTTGGATATTTGAGCATGGCTGGGAATCAAGATCAGTTTGAGATCAAGTTTCGGTTGACTGATGGTTCTGATATTGGCCCCAAAAGTTTTCCTGCAGCTACTAGTATTGCAACATTAAAAGAGAGTGTTCTCGCTCAGTGGCCAAAAGACAAGGAGAATGGCCCAAAGACCATAAAAGATGTGAAGTTAATTAACGCAGGAAAAATTTTGGAGAACAACAGAACAGTTGGGGAATGCCAGAGTCCGTTATGTGATACCCCTGATACTGTTACAACAATGCATGTGGTTGTGCAACATCCTGCTACGGAGAAAGAGAAGAAAGCGGCAAACAAAGCAACACAGAACAAATGCATGTGCGTTATTTTATAGCATCCAGATTGAATAGCAGATGTCATCTGTCTTAGTTGATTAGGGACAGTTCATTTTACATAACCTGCGTCGTCAAATATTTCAACATACACAAATTATTTGGTTGCATGCCCCATTCATACTACAGTCAAGGAGTACTGGACTATTTTCTTTATAAAAATGGAGTACTTGACTTGGTGAAGATTGTGAAGCTTGTAGTTCCCTGATTCCTCTGCGGCACTAAATTTCTTGCACAATTTCATAGGAGATGTTCTTCTTCTGGTTTCAACATGTATTAGGTGTTGCCTCATCAGACACTTGGTATAATTGTTGATTGAAATGAACTCTACTAGTTTGCCATCTTACCCCCTCATATATTTTACAATTCTTCTCTTTCGTGTATCTGATTCAACATACTTAATCCAGACATGTATGCGTTGAGTATTTGAATGTGTTTCAATTTTCTGGTTGTTTATATGGTACCATTGCTACCCACTCTTGTATAGCAGCTATGGCAATAGTGATTTAACAACATCTCTCACAAAATGGAGATTTGATGCTTGAA
->XM_017886251.1 PREDICTED: Rhinopithecus bieti MAS related GPR family member E (MRGPRE), mRNA 
-AAGGCTGCAGGGAGGGTCGGGGTTTCTCTTGCTGTCCACACCTGGGCAAGAGCTGAGCGGAAGAGAAGGGGTCCTCAGAGAGACGCCTTCCTCACCAGCCCCATTCCAGCCGGACACCATGTGACTCGGAGGAGCTGGTGGACACTGAACAGGAGCGGCCCAGAGGCTCTGGGGACTGGAGCCCGCGGCTGCAGCCAGGACAGATCCAAGGCCCAGGGTCAGAGCAGGCAGGGCTCGGTCGCGCCTCTGCCCCAAACGGGGCATCAGCAGAAAGAGCGAGCAGCAGCAGCACCCTCTGGCCCCCCACCCTACGATGGAGTCCAGAGAAGCTGGAGAGCAGGCAGGGGCTGCCGACGGCGCCCGGGAGGATGTGGCCTTCAACCTCATCATCCTGTCCCTCACTGAGGGGCTCGGCCTCGGTGGGCTGCTGGGGAACGGGGCGGTCCTCTGGCTGCTCAGCTCCAATGTCTACAGAAACCCCTTCGCCATCTACCTCCTGGACGTGGCCTGCGCAGACCTCATCTTCCTTGGCTGCCACATGGTGGCCATCATCCCCGACTTGCTGCAAGGCCGGCTGGACTTCCCGGGCTTCGTGCAGACCAGCCTGGCAACTCTGCGCTTCTTCTGCTACATCGTGGGCCTGAGTCTCCTGGTGGCCGTCAGCGTGGAGCAGTGCCTGGCCGCCCTCTTCCCGGCCTGGTACTCGTGCCGCCGCCCACGCCACCTGACCACCTGCGTGTGTGCCCTCACCTGGGCCTGTTGCCTGCTGCTGCACCTGCTGCTCAGCGGTGCCTGCACCCAGTTCTTCGGGGAGCCCAGCCGCCACCTGTGCCGGACACTGTGGCTGGTAGCAGCGGTGCTGCTGGCTGTGCTGTGTTGCACCATGTGTGGGGCCAGCCTTATGCTGCTGCTGCAAGTGGAGCGAGGCCCCCAGCGGCCCCCACCCCGGGGCTTCCCCACGCTCATCCTCCTGGCCGTCCTCCTCTTCCTCTTCTGCGGCCTGCCCTTCGGCATCTACTGGCTGTCCCGGAACCTGCTCTGGCACATCCCCCACTACTTCTACCACTTCAGCTTCCTCATGGCCGCCGTGTACTGCGCAGCTAAGCCCGTCGTCTATTTCTGCCTGGGCAGTGCCCAGGGCCGCAGGCTGCCCCTCCAGCTGGTCCTCCAGCGAGCACTGGGAGACGAGGCTGAGCTGGGGGCCGTCAGGGAGACCTCCCGCCGGGGCCTGGTGGACATAGCAGCCTGAGACCTGGGGGCCTCGACCCCAGCTGCAGCCCCCATGAGGCAGGAGGGTGACTTGGGGAAGGTGGTGGGGTCAGAGGCTGGGGCCAGCTGGACCTGGAGGAGGCCTTGATGGGTGGCCCAGTCATGTGCTGCCAAATCTGTGACCATCAGTCCGGAGCACGAGGCTCCCCTGGGAGGCAGCTGGAAAGGCGAGGTCTCCACATGCCCAGTCAGGTGGGCTGGGTCTCTGGGGAGAAGGCCCAGGAATGTGCATTTTTGGGAAACCTCCCCAATGGTTCATGCACTGGCACCCAAGCGCTGCTGCTGCTACCCATTCCGTGCTCAGCTGCAGTGAGGAGACCCCGGAAAGGAAGGAAGCAAGGCCAGACGCCAGGTGAGGGGCAGGTCCAGGCCCTCCCGCAGCCCACCTCCCCTCCCACTCCAGCTTCCCCAGTGCTGCAGGGGCACCCACAGAGAACACAGCCATTCCCTCAGCTCGCCATGTCCGCTCTGTGGAAGCTAAATTGACCCTAAAATTGAAGACTGCCCAAAACTTGACCCCCTCCCCCGACGAACTGTGTCCAAAGCAGCCAGCAGCCTTTTTGTCCTGGGTCCGTTACGTTGTCGTGAGTTTTCAGCAGGAAAATGTGGTGATACCGCAAAGCCACTCATTCTATCGGCATAAGGGTGTGCATTGATCAAAAGCTGTACCCCCAACCCCAGCACAGATGCTGTGAGGAAAAGCAGGGGCTGAGGCTTCTAGAAGGCTGTGGAGCTGTCCTTGGTCATCAGGCCGTTGCTCAAGGCCATGCCACCCAGACCTGGACGATGCAACCCTCACTCGGAGCTTCAGAAAAGCCGGCCCCGTGGGTGACCCTGGATATTACAGGATGCTCCCTGGGCAGGTGGAGAGGCTCCTTACAGCCCTACCCAGCAGCCTGTGGCCCTGTCTCCCCACAGGACCCAGGCCTTCAGCAACCGGAAAGCTTCTTCCCACCGGCCCTATCTAAGGCAGTTCACCCGCCTCTGTCCTGAGCAGTCCCGCTCCAGAGGATCCCTCTAAGGAAGGAACCCAGGCTTCACCCCTCAACAGGTTTCGCGCTTCCCCTGAGTGCCGGGCCTGGCTGCCATCCAGGAGCATGTGCCAGGGGGTGCCAGAGCGGGGGCTTTGGAGCCCACAGCCTGGGCTGAGCCCTGCTAGCCACCCCACTGTGCTGCCAAGGCCATCTCTGAACATCCCTGTGCCTCTGCTTGCTCGTCTGTAAAATATGAGAACCCAGTTCTTTGAGTCTTTGAGGCCTGTCCAGCCTGTTGTGAGCCCGAGAGAAATGTCTGTCGATTCTACTGCCACCAATGCCGCCATCCAAGTCCACAGTACAATTCTTAGCCACAGACTAAGG
->XM_051693489.1 PREDICTED: Myxocyprinus asiaticus WW domain-containing transcription regulator protein 1-like (LOC127438147), transcript variant X3, mRNA 
-AAAGTCCGTCAGTGGACGCAGGAAAGTTGGGGAGCGGAGGAGGAATATTTCTGGAGAAATTCATATGAGGAACATTATGACATCAACTTTTTAAGCTTTATGACAACTTTTTAAAGACTTTAAAAAAAACTTTTTAGAAGGCCAAAACAACTTTTACCAAAGAAAGAAAAAACAGGCCTAACCAAAGAGGTTCAGGATTTTCATCGCCTATTTTTAATCGAATCTTTTTATTAGTAGGATTTGTTTTATTTGTTTGTATATCTAACAATATGAGCGGTAACCCTCTCCAGCCGTTGCCGGGCCAGCAGGTGATCCATGTCGCCAAAGACCTTGACACGGATCTGGAGGCTCTTTTTAACTCGGTCATGAACCCAAAGCCTAGCTCCTGGAGGAACAAACATCTGCCCGAGTCGTTCTTTAAGGAGCCGGACTCGGGCTCTCACTCCCGGCAGTCTAGCACGGACTCGGGCAGCCACCCGCCGCGGCTCCAGGCGCAGCACGTCCGTTCGCACTCGTCTCCGGCGTCCCTGCAGCTGTCGTCGGGCGCGCTGAGCGCTGCGACCCCCGGGCGTCATCACACTCATATCCGACACCAGTCGTTCGATGTGGCCGAAGAGCTGCCGCTGCCGCCGGGCTGGGAGATGGCCTGCACTCCCAACGGACAGAAGTACTTTCTCAACCACCTTGAGAAGATCACCACATGGCATGACCCCAGGAAGAGCATGACCCCGTCGGTGACCCAAATGAGTCTGCACAATCAAGCGTCTAACAGTGCTAACATACAGCAGCGCTCCATGGCCCTGTCTCAACCCAATCTCGTGTTAAATCAGCAGGCGCATCCACAGCACCTGCAGCAGCAGCATCAACAGCAGCAGGTGCAGGCGCAGACGCTTGGCTCGCAGCAGCAGCAGAACTCTCAGGCCAGCATGTTGAACATGAGCGCACAGCAGCACCAGCAGAAGATGCGACTGCAGCGCATACAGATGGAACGAGAGCGCATTCAGAGGAGACAGGAAGAGCTCATAAGACAGGAGGTGGCGCTCCGGCAGCTGCCCATGGACTCTGATAATATGGCATCTGTGGCACCAGCCATCAGCTCTCCGGCCATGACACAGGGCAACATGCCCAACAACAGCACAGATCCCTTCCTCAACAGTGGGCCATACCACTCTCGAGAGCAGAGCACAGACAGTGGACTCGGACTGGGCTGCTACAGCATCCCCACCACCCCTGAAGACTTCCTTAACAACATGGAGGAGATGGACACAGGTGAGAACATGGTGCCGGTCAGTGTGAATGTACCGCAACAGAGTCGTTTCCCAGACTTTCTGGATTCCATGCCCGGCACCAATGTGGACCTGGGCACCCTGGAGGGCGCTGACCTCATGCCCATCCTGAACGACGTGGAGTCAGTCCTGAACAAGAGCGAACCCTTCCTCACCTGGCTCTAGACTCAAACAGGACACTATAGACTTTTATATATACGTACATATATATATTATATATACACAATCAGCCTCCTCCTGTAGTTTCACTTTGTAGACATCAGTTTTGTTTCCACACACTACTCTGAATTTCCTTTTCTTTTGCTGAGTCAAAGAACAATATTTACCAAAGTGTTTAGCCTGCGAACAAATATGCGAGTACGCGTCAGTAATAGCCGTAGTGTAGAAAGACTAATGTGTTTGTTTTGTAACTGAAATTGGATAGATTTGATTATGTTCAAAATTATCACATGAACACATCCTTTCCACAGCAGACATGCCTGGATAGTGTCCTAACAGTGGCTGTCAATCAATCTGCCCAATCATGTTTAACAGTGAAACATTCAAGAAAATGTTCAGGTAACATTTTACTCCAAAATCAAAAGAAACAAATAAGAAATGTTATTTTGCATAAAGAAAATGAAGGACATTTTAGGACCATCAAGTTTTTTTTTTTGTTTTTTTTTGCATTGTGACATTTTCATGACAATTAAGCATATTTCCCCCCCCCCCAAATTATTTTTAACCGCAATGCGAAAAATCTCATTCTAATTACCGTAATGTGAAAACATAATGAGGTATTAAACTTGTAAAGTATTTTTGTACATTATGGTAGCATTTGGTCTACTGCCTTTATGCTGATTTTTTTTTTTTGTTTGTTTAAATAATTTTATTTAGGGCTTTCAATTTAATGCACTAATTCAGTGCGATTAATTATATAAATAATAATGTGTTAAAGTAATATGGACACTGGCTACCACCAGTTCGCTAGTTCGAATCCAGGGCATGCTGAGTGACTCCAGCCAGGTCTCCTGAGCAACCAAACTGGCCCGGTTGCTAGGGAGGGTAGAGTCACATGGGGTAACCTCCTCGTGGTCACTATATTGTGGTTCGCTCTCGGTGAGGCGCGTGGTGAGTTGAGCGTGGATGCCGCGGTGGATGGCGTGAAGCCTCCACACACGCTATGTCTCCGTGGCAACGCACTCAACAAGCCACGTGATAAGATGTGTGGGTTGATGGTCTCAGACGCAGAGGCAGCTGGGATTCATTCTCCGCCACCAGATTGAGGCCACTACGCGACCATGAGGACTTAAGGCACATTGGGAATTGGGCATTCCAAATTGGGAGAAAAAAAAAAGAAAAAAGTAATGCAATTAATCATGTCTTGAGAAATTCAAGCTTGAAGTACCACCTGTTTTCTCCAGAGGGCAGTAAACGAAACTTCAGCTGTATAGGTAACACGAAGCTTATACAGACAACAAACCAACCCTTCAGCAGACAGCACAACACGAGGACACATTCTTGCATTCAAAACACAACTTGATGGAGTGCAAATCTGAACTTGGGGATCTCAAGAAGTGTTTTTCTAAGTATTAAACTACTTTTAACTTGACACAGTGACCTAAAAACGGTATGATTATGATGCGACGGAACCAAAGTGAGACGCTCCAAAAGCGTCCATCTGACGCAGGTGAACATTGATGCGTTCTTAGACAAGCCCTCATAATAAATCTCGGACTAATTGAAAAATTCAATTACAAAATGAATTGCTGTGAACTGTAGGACAATGATAGGCTTATATTCAATAATATGCAAATAAACAATACACACATTCTAAAGCCATATATATATATA
->KU122020.1 Uncultured bacterium clone 26372 16S ribosomal RNA gene, partial sequence 
-TACAGAGGGTGCAAGCGTCAATCGGAATTACTGGGCGTAAAGCGTGCGTAGGTGGATACCTAAGTCGAATGTGAAATCCCCGGGCTTAACCTGGGATCTGCATCCGATACTGGGTATCTGGAGTATGGTAGAGGAAAGTGGAATTCCCGGTGTAGCGGTGAAATGCGTAGATATCGGGAGGAACATCAGTGGCGAAGGCGACTTTCTGGACCAATACTGACACTGAGGCACGAAAGCGTGGGGAGCAAACAGG
->XM_050382592.1 PREDICTED: Mercurialis annua probable xyloglucan galactosyltransferase GT14 (LOC126688031), mRNA 
-GGAAAGTTGACAAGATTCCTTGAAATGTCACAAAACCTTCCATTTTTATTTTTTCTCTCAGATTTATTTCCACCATTCACTAACTTAATTATACACTCTCTTTCACCAACTACTTAACCCTATTACTTCTCTCAAATACTACTCCATTAGCAGCCACCATTTTTGTTCATTATTTCCACTAAACTAAGCTACTATACACAATGCTAGAGAAACAATCCACAAAACGGCAGATGGAAAAATCTGGTTTAGAGCATAATAGATCAGTCTGGTTTGTCGTTTTGATCATTCTGATACCTTTCTTCTTCTTCTTTCTTTATGCTTTTGATTATTTATCTTTATTTGCTAACATATCCAATCAAAAATACGAGAAAAATTCTGATGAATCTTGTTCGGGTCGTTATATATATGTTCACGATCTTCCTCCACGGTTCAACGATGATATTCTTGAAAATTGCAGTACCATTAACAGATTTGTTAACATGTGTCCTTTTCTGAAAAACTCAGGTTTTGGTGTTCAGGTTGTTGGAGACTATCCTGACGGGGTCGATTTAGGACAGAACTGGTTTGCAACTAATCAATTTTCTTTAGAGGTTATATTCCGTACTAGAATGAATTATTATGATTGTCTGACGAATGATTCTTCTTTAGCTTCTGCCATTTTTGTACCGTATTATGGCGGACTCGACGTGGTTCGATACCTGTGGGATTATAATGCTACAAGAGATTATTTAGGTGTTGATCTTGTCAATTGGCTAACTCAAAAGCCTGAATGGAATAAAATGTTTGGTAGAGACCATTTTTTTGTTGCCGGAAGAATTTCTTGGGATTTTCGACGCCTGAACGATCAGAATGACGGTTGGGGAAGTAAACTCATGTCGTTACCTGAATCTATGAATATGACAATGTTGTCAATAGAATCAACTGCGTGGAGTAACGAGTTTTCAATACCATATCCGACTCATTTCCACCCGTCAAGCGACGCTGAAGTGATCGAATGGCAAAACCGAATGAGAAAGCAGAAGCGGAACTATTTGTTTAGTTTTGCAGGCGCTCCAAGGCCTGATCAGAAAGATTCTATCCGTGGACAGATAATCGAGCAATGTTTAGCTTCAACAGGGTTATGCAAGTTGCTCAATTGCAGTTCGGGGAACACATGTGATAATCCTGTCGAGGTGATTAAGGTATTTCAGGATTCTGTTTTCTGTCTGCAGCCTCCAGGGGATTCATACACAAGACGATCAACTTTCGACTCGATTGTTGCAGGATGTATTCCAGTTTTCTCCCATCCGGGATCCGCTTACGCACAATACGAATGGTATTTACCGAATAACTATTCTAAATATTCCGTGTTCATACCGGTGGATTTAGTAATAAATGGAAGTGTCAGCATTAACGAGACTCTGATCAAGGTTTCTGATGATGAAATTGTGCAAATGAGAGAAGAGGTCATAAAGCTGATACCAAAGATTATATATGCAAATCCTAAGTCAAAATTAGAGAGTACTGAAGATGCATTTGACATTGCAATTAAAGGAGTTCTTGAAAGAGTTGAAAAAGTGAGAAGCAAGATTGATGAGGGAAAGGATCCAGCCGTTGGATTTGCAGAACCAAATTGGAAGCTCAGATTTTCAAGAATGGGTCTACAACAAAATTGGACTCATTTCTTCACGTAAATGAAAATGTTGAAACAGAAAATGGTAAAATTAGTACAGTTTTATAAATATAAATTTTGGAAAGTTATTTTGAAATCATAAATGCAAAAATGTAGGACTTAATAAATTTTTGTGAAATTATAGCTTCTGAAAAGTAATGTATATTAGTGTGGTTAATTAGAGGTTCTAGCATTTGCATAATAGCATTTCTTCTGTTCACAATTCTCTATGTGATTAGATGATATAAGTTTTGGTGGAAATTTTGCAGTCCACCAATTTATA
->XM_022914722.1 PREDICTED: Durio zibethinus uncharacterized LOC111313871 (LOC111313871), transcript variant X2, mRNA 
-TCCATTTAAGATGCAGATAGTATGTTTTCCAATTTTCAGAGTGATACCTTACTGTATTGATGATTCGAAGCCAAAAATTTGCAGTCCAAGAATCTCAACTCACCATTTCACATTTCACTGTAATGAATTTTTACAGGCAGACTCCAAGCTTGGTCTCTTCAGCATCAAGATTCCCTTTCAACCAACTTTGTTAGAAGACTAATTCCTCAAATGGTCACTATCCATTCATGAATTTTAAATTCCAAGGTGACGTTTGCTCTATAATTGAATTCATTTCCTGGGTTGTTTTCATTTCGGAAAATCATATGAGATTTCAACTACATTTCAGTCCATCCTTGGGCCGGTTGATTAAGGTAAAAAACTTGAGCCAGAGTCCCAAACTCGACTAATCATAGCACAACACGTGTTAGTATTGAAGAATTTTTAATAAAAAAATAACAATTGAATTAAGTTTCAGGTTCATTATTGCGGTTCTGCAGATAAAAATTTTGGCAACTCTTCTACCTCTGGAGTTTCCCTGTTATCCAGCATTGCTGTTGTCATAGTCGGCATATCTTTATTAATTACAAGTGCTTTTAATTTCTTATCAGCCAAGATTTGGACTTGCAACTGCAACAAGAAATATTCTAGTTTGGCTTGACAAATCTTTGAATGCGGAAGAGTGGAGATGAGACAAGTTACTATGGGTTGTAGCAACAAAGACCAGGTGGTTTCACATGCAGGATTTAAGGACATGATGGAAAGTGAAATCAATGAATCCCCTTTTGCATCCATACCGAAACCACCTATACAAAGTAGCAGACCAAGTAGCATGGTTGTTAAGAAAGCACATACTGTGATTCCAGCTCATATTGTTGCTGAGGCTATATCAACACTCCTTGGTCTTGATCTCAGATGGTCAGGACCCATCACACAAACAGAAAGAGAATATGTTGAACAGTATGTATTGGCAAAATACCCAGAGTATGCAGGGCAAGTTGAAATAGAACATATTGACCTCTCTAGTCTTTGTATCAATGAAGAGTCGTGTGAGCCTGCAATTGATGATAAAAAGAAATCACCTAGAAGAGAGTCCTCCACACCTTCCTTTGGAAGCAATCTTCCCGACCTGGACAGGATTCAATTGGAGGCATCGAGACTGCTCGACATCCTCACCAAGAAATCTTCCTTTCCTGGAAGTTTCATTTCAATTCCTGAAATTCAAGCTCGAAACAAAGTTTTGAAGCATTGCGGATTACCAGATAATGACTATCTTGTTCTGTTCACTCCAAACTACAAGGATGCGATGATGCTAGTTGGAGAAAGCTACCCTTTTTTCCGAGGGAACTTCTACATGACCATCATTGGTGAAGAAATGGATTACGTACGAGAGTTTGCCAGTTACAAGGAAGCAAAAGTGATCTTGGCCCGTGAATCTTGGTTGGATTTGAGAATCAAGGGATCACAACTTAGCCAGTACTTCAGGAGGAAGTGTAAGCACAGTCCAAAGGGTTTGTTCTCTTATCCAGCTGATGTAAAGGGGATGCGTTATTCCATGCATTGGATTTCAGAAGCTCACAGGAATTCATGGCACGTTCTGCTTGATGCAACTGCCTTGGTTGTTGGACAGGATCGATTGAACCTTGCACTTCATCGACCCGACTTTGTTCTTTGTAGTCTGGAGAATACGCACGCTGATCAACCATCAAGGATAACTTGCCTTCTGGTCAGGAAGAAATCCTTTGAAACTACAACATCTTCATCTCATGTCACCGAGTGAAAAGTGGGATTAGCTTTTGTGAATACGCTATATGTTTAAATTATTGAACCCAAATTTATGCCAATATATTTTGGAAGTAGGAAACTTCGAACAAATATAATTAGTTACATTTATACAATTGTGGCAAGTTTCTAAAGTTGTTTACAAGGATTCTTAAATCTTAACCTCAGCTGGTTCCTTTAAAGCTGGGGTTTCGTTGCTTCAAGCTACCAATTCGAAAAAAGAAAGCCTTTCAAGCCAACAGAAAAGGAAAAATTACATAAAGAGTTGAGTTTCTTTTTAACTTGGAAATTTGGTATACTTGAAAATTCTATTACTTGGAGAAGGCATGTTTCCACTTTATCAGGTCAAGGTGTATTTTCATACATTAATCAAGTTATTTAGGTGAAAAACTAGAAAAATTCAATGTCCAACGCATTAAAAGCATGGAGTCCAAGTGTCAGAACTAAGGACAATCATCTTTAGGGTAATGAAAAATTCATGGTTTTTTCAAAGTGGACCATGACATTTTTCATGCAAGTCTGGTAGGGTGGAGATGGTTTAAGGTTTAGGCCCATCACTGTTTCAAAAAGCCATGTCAAAAGTCTTCGCTCCCATCCTCCATGTTTTTCAAGTTTACTTGTTTCTGGATTTGCAAGTCACAATCTTCAAGCGATCAATTCAATCAAACAATTCCTCCATTGTTACTCGGTTTCTGGCTTAGCAATTTGTCACCTTTACCTTCATGTTAAATAGTCATAGTGAGCTCCAGCCTTTGGTGAAACTTACTATGGATATTTGGTTTGTGATTTTGGGTTCTGGGCTGGCAAGGCAAAATGATTTTCCATTTGGTTCCTTCAAAGAAA
->XM_005089107.3 PREDICTED: Aplysia californica serine/threonine-protein phosphatase 6 regulatory ankyrin repeat subunit A (LOC101861246), mRNA 
-GCGCAAGTTCACCGTCAAAGTGATAATTTTTTTTATTGGATCTGCCATTTTCTCCATTATAGATTTTTTTCTTCAGGGTAAGTTATGTGTGTAGATTATTGCTATATCCATAAGTGGCGACCTCTTACAGCCTGGCTGGTGTATTAAAATGGAGCCCAAACATTGGGCCCGGTAACCCGGCCTGGCACCCGCCACGACTGGACGCACAATAAGGCACACAATATACCCTCTAGATTGTAAGGCGAGCCGGGCGATCACGGGAGTTGGGGGTGTCAATACTGCCACAGAGGCGGCGTGCACACACCGCTACACCACAACGACCCCAGAACGAAACCCTGACCAGGTGAACAAAGGCGGACATAAAAAGATCGCCCGGTTTGCTTCTCAACTCGATCGATTTCAGGCTGACTGAAAAAAAAATTCCGATACGTTCAGTTGTAATTCTACATGCAAATCTTTGTGTGGTGGGATCAAATCAGAGCGGAGAGGCTCTTCGGATACTCGGCTTTGTTGTGTATTTGCTGGTTGACTGAATTCTGATAGCCATTAGCTTTGAGCGATCGAGTCGCCCCACTCCTGGTAGCTGTGTGTAGTGCAGTCTAAGCAACACAGTGCTCGCCTGGACGTACGTAAGCCTACAGTGAGAACACCGGTCCAAAGACAGGATTATTTGATCTGTGCAGACGGATAGTGCCGGATTAGTGAGATTGCACTCCTGCAGGATTGCTCCAGCCAGCGACTGTGCCCTCTTGTGGCTATGGAGATCTAAAGAGGACAAGCCTTACAGTGCCGGACCGTACAATACAATAGTGAGACAAACCCTTGCTGAGTTGGATACTTTTGGATTCTGTGTTGGTTGAATTTAGGTGGTCTCACATTCTTTTGATATACTACAAAACCCAGGAATCTTGAACTTACCAAAGATGTTGGTCTCATCTTTGATTTGCGACACCACACGACGATGAAAGACAGAGTCGCTGGTCAGACCTGTGTCCACATCATCTAGGCAGCCCCACAAGACGACTTTGCGCTGGCCACCACAGCCCGTGGGTTTGTAAGAAAACTTTAGGATAACATAATGGAGAAAATAGCCCTGCCACCCCCGCCGTCCAAGAGACTGGTGAAGACAGCGCTACATCAAGCAGTGTTAGATGAGCGCTTACATCAGGTTCGGCTTCTTGTGGACAAACATGGAGTTGGCATTGACACCAAGGACGTCCATGGCAGAACGCCTTTGATGCTTTCCTGTATCATAGACAACCATGAGTTAGGATACAGAATGGCGTACATATTACTAAAAGCAGGAGCGTACTTGAACCTTCGGGACGGAATGGGTCGGACAGCGCTCAGTTATGCCTGCATGAACGGCAGGGAAAGCTGTGTGGCTGTGTTGCTGAAGGAAGACGTGCTGGACATTAATGAACCAGATAATGACGGCAACACGCCACTACACCACGCCTCTACCTGCGGCAATCCTCGCATTGTGGACATGTTGGCCAAGGCATTTCATAAGTTCGGCCTGAACGCTGACAAGAGAAATAACTTGGGCTACACAGCTCTACTGCTGGCCTGTAAGAGCGGCCACTACGTGAGCGCACATCTGCTGTTGACCGTGGCCAAGGCATCCCCCGCTCTGAGAGATGGAGAATTTCACCTCAACGCCACTGAATGGGCACAGAGAAGTCATCAGATCCAGGCAAGGTTAACAGATCGGTCATTCTTAGCCTCAGCCCCTGCCGCCACTCCGCGGCCCCTCGCTGCGCTGTCGTTTGAGCGTGAAGACAGCATGTACCAGAGACCCTGGGTGCCCATCTGTCGCCTGTACCGAGTGCCCAACCCTCACTTCTCGGCGGACAACTTCAAGCTGCCAGACATCCTTCTTCCTCCACCGGGCATCAGGAGTGAGCTCTTCTTGGATGGGCTGGATGCCCGCCAGATATTGCTGAACGAGATCGAGCTGTCAGAAAGTAAGACCCGACCTGTCTCCACGAAGGCGACATTGTCGAAGTGGAGCCATCCTCCAACAGCCAAGCTAAGGAACATCTCTCAGAGGAATGCCCCGTCCTCTGCTTCCGTGCCCGACATGGTGACGATGTTCAAGATGTACTGCGAGCAGTACCAGCCAGACTGGCGCACGATGAACAAACAGAGGCGGAAGACGATGGCCGTGGGTGGGCAAGGCATGACGTCCAACAACAGCAACCACTCCTTCTCCGACATAGCCGGGGCCGCCCATGGAGAGGGCGTGGAGATGCCTAGTTGATTACGTGTTGACTGATTTATTGAGGGCTGTGTCGTTGTGAACTGTGACATCTTTTTTTTTTTCAATCTTAGTCTCTGATGAGACGATTGATTATAACTATCGGACAAAACGTTGGTCAGCTGTTCAGAAATACTAAGCTCAAATTTCGTTTGCTTTTGTATAAAAATTTTATTTTTTTTAAAGTAAAGTACAGCAGCTTTACTGGAACTGATTGCATGAGCTCAAGAAGCACAATTTTGTCGAAATTCAAATTCTGTATGTCAGAAAGCAAAATTTAAAAAAAAGAAATGAAAAA
->XR_006395823.1 PREDICTED: Acropora millepora uncharacterized LOC114972299 (LOC114972299), ncRNA 
-TCTAAGAAGTGCATATTCTTTATAAAAAAATCAATGAAAGGAATATAACATAGTTCAAGTGCGCTTTCCGTTTCCGTACGTAAATTGTCAAGATTGCAAAGGACCGAGAGTAACTTGAAAACTGTACACGGCAAAGTCTCTGTATAGAAGTCTTAACCAAGTTGAACTCATGATTAAATTGGAACCAGCGCCTCTGAGAATACCCGATTGTTTGGATCTGCGAAGTCGATTCATCCGCAAATTGTCCTCTGTTTCAGGGGAGAGGAAGCCTAGCCAATGAGTAATTGATAACATTGCCGACTACACGATCGTACAAACGCTTCTCTTATGGCCAGACCAGCTTTATGGAAGTCGCCCGCTCTATGGAATGTTTGTTCGACATATAGCGTTCAGTCGAACAATTTCATCATTGACTCGGTTTTCCTTACCGATCGAGTTTAATTTGCAGCATATCAACGATGAGTCACGTTCACATGACGTAGTAGACATTGCATAATACGGCCTCATATGGACTCACGAGTTGGCAGGCGTCCACTCACCCACCCATAATCCTATTCTTGAGGTTTGTTTGTATTTTGACACAACTTTAGTCCTCTCTGACAAGCATGAAATCAAGACACAAGATACTGAAATAGATATTGAACTCATTTCAAGCTGACATCTTTTATTTGCTTAGGCTGTTATATAAATTAAAAGTTTACTGGTTTTATTCTTATAACATTATATAAAGATCAGCATAGTAGATCATGA
->XM_002951530.1 Volvox carteri f. nagariensis hypothetical protein, mRNA 
-ATGCCCGCAACTGACGATCGCGCGGCGGACACCTCCTGGCTCCACGTCAGCAACACCATCGTGTACTTCCTCGCGTTCTGTATCAACGTCCTTGTCAACTCGGGTGCCGTATTTCGTACTGTACGTTCAGTTGACCGGCAGTTCGGACCCGTACTCACACCTGCCGGATGGTCGTACTACATCCGAGATCTGACGCTTTTCTTATGGGGTCTAGGAGTGACGTGTCAGAGCTTGGTGGAGCACAAGGGCTGGAAAGACGGACTCGTGGCGTGCATTGGCTACTCCTGTTTTCCCCCCCCCCCAACTCCCCGCCCGCGCCACCCCCGCCGCCTACTGACCCGGGTGGCAGTGCTGGTTCCGGAGCTGCAGAGGGAACTGCTGGCGGCGGGGTTTCGGGGTGTGCCCCCCCTGGCCTACCTAATCTACGTGTACCCAACTTCCCTGGCGTGTGGCTGGCTGCTGGTGCACCAATGCCATGTCACCGCGCTGGCAACTGGCCTGGTGACGAGCTCGCATCAGGCGGCGCTCAACGTTGGTTGTGTGACGTTGGTGCTGGCGACTGCATTGGCGCTCCTGCTGCTGGTTCGCCTCCGCGACGTGGTGTTTGGACTTGCCTTTACCTGGGGCTGCGTGGCGGTGTGGGTGGCTGGGTTCACCACCCAGGAGGATTACCGCCCGGACCAGCTGGTGGCCTTCTTCTGCGGCCTGGTCATGGGAATGTTGACGTACTGCGTAGCGGCAGGGCCGCAGGTCAGGATGGCGTGGGGGGGATGGACGGCGGCGGTGACGGCGCCGGCAGCGGCTCTGCCGCCGCCACCGCCGCCGCCGGCACCGGCAGCGGCTCCGCCGTCGCCTTTGGCTGCTACTGGTGGTATGACATCCGGAGCAATACCAGCAACGAACAACTAA
->XM_041800643.1 PREDICTED: Cheilinus undulatus beta,beta-carotene 9',10'-oxygenase-like (LOC121518372), mRNA 
-TTGCTGGTTAAATTATGGTCCATCTGGAAGCAGATGCAGACAGAAGAAGCTGTGTCCATCCATTACGACGTCGTCCATGGCTCCGGTGAAGTTCGACAGCTCAGATGCCGCCGTTCCTATTGAAAATGGGCCAGCCAAGGCATGTATCACCTCTGTACTGAAGGGTCTGGAAATGATCGCCCCTCTGGTCCGCTCTATGGAGGAGACCCCTGTGCCCATCCCCACTGAAGTACATGGGACCATCCCCTCCTGGATCAATGGAAACCTTCTCCGCAACGGCCCTGGGAAGTTTGAGTTTGGGAACACACACTACAACCACTGGTTTGATGGCATGGCCATGCTGCACAAGTTCAAGATCGAAGAAGGCCAGGTGACGTACATGAGTCGATTTTTACAAAGTGATGCCTATAAGAAGAACAGTGAGAGGGACCGCATTGTGATGTCAGAGTTTGGCACCCTCGCCATGCCAGACCCCTGCAAGAACTTCTTCCAGCGCTTTCTATCTCGTTTTGAGATGATTGAGGCCACTGACAATGCAAGTGTGAGCTTTGTGAAATACAAAGGTGACTACTATGTCAGCACAGAGACCAATTTCATGCACAGAGTGAATCCTGAGAACCTGGAAACATTGGAAAAGGTAGACTGGAGCAAGTTCATTGCGGTAAATGGAGCCACTGCCCACCCACATGTTGATCCTGACGGTACCACCTACAACATGGGAAACTCGTACGGAAGCAAAGGGGCCTTATACAACATCATCAGAGTACCCCCAGAGAAGAAAGAGTCCACAGACACCCTGCAGGGAGCCAAAGTACTCTGCTCTATTGTGCCTGCAGACAAGGCGCACCCCTCCTATTACCACAGCTTTGCCATGTCTGAGAACTATGTGGTGTTCATCGAGCAGCCGATAAAGATGGACCTGCTGAAAATAGTCACATGCAAGCTGAGAGGGAAGGCCTTGAGTGAGGGCATCTACTGGGATCCAAAGCTGCAGACTGTCTTCCATCTTGTTGACAAGCGCACTGGCGAGGTCAGCTCAGTGAAGTACCACACCAAAGCCATCTCAGTCTTCCACCAAATCAACGCCCACGAGGAAGGTGGGTTCTTGTTGCTCGATATGTGCTGCTCTGACGATGGTCAAGCAATCAACAACTACCTGATCCAGAACCTACGCAAGTCAGGAGATGCTTTGGATGAGGTGTACAACACTCTGTGCCGGGCTTTCCCTCGCCGTTTCGTTCTTCCTCTTAATGTGACCAATGAAACCCCATTAGACCAAAACCTGAACACTCGACCCATGAGCATGGCAACCTGTGTCAAAATCGGCAAAGACAAGGTGTTCTGTCAACATGAGGATCTACATGGAGAGGACCTGCAGGAGTATGGTGGACTTGAGTTCCCACAGATCAACTACAGCAACTACAACACAAAGCCATACCGCTATTTCTACGGTTGTGGCTTCAGACACCTGGTGGGCGATTCTCTGCTCAAGATGGACCTGAAGGACAAGTCGCTCAAGGTGTGGTATCAGAAGGGTTTCTACCCATCAGAGCCGGTGTTTGTCCCATCACCAGATGCTGTGGAGGAGGACGAGGGTGTTATCCTGTCTGTGGTTCTCACCCCCTCACAGGATAAAGGAACATTCCTCCTGGTTTTGGATGCTAAAACATTTGAAGAGCTGGGCAGAGCCAATGTGCCGGTGAACATGGCTTATGGCTTCCACGGCACATTTAACGCCTGTGAATGAATGATGTGATGTGTTACTGATGTTGACTATAACATGAAGAATACCAGTGCAGTGTCAACCATTATAACCACTATAATCCAGATGGTACTGACTCACAGCTCTACATGTTAAAGACAGATCTTCTGTTACTGAACAAATGCTCTTTTTCATTGGTTTCTGGTTTGAAATCAGACCCAAATGTGATGGTATTGATCAGTCCAATCATATTCAGGCAAACTGAAGATGAGTATTATAAATACATTCCTTTGGCATTAATTGTGCTGTCGTTATTCGCAACAGAGTGTTATGACCTCTTATTCTGCTGCCTTAATCCTGGTCATTGCAGGTTGTAGCATGTTTCAACCTTTAGGTCACTGAAGTGCCAAATGCTTTTCTTTTGTACTTCTTTTTTAATTGAGCAATACATTTTTGAGCTTGCATGAAATTTTGAACTTTTGTAAACTCTTCTTGGCATTAAATTTACTATTATATGAA
->XM_003028818.1 Schizophyllum commune H4-8 Mg2+ transporter protein (SCHCODRAFT_01102597), partial mRNA 
-ATGCCAGGAAACGTCGAGACCGTGTCCGGTCATTTCAAGAAGTCCGATCTAAGCGCCGAGCATGGCCTCAATATACGAGATCTCCGCAAGATTGATTCTCGAATACCCAACCTCGTCCCCACTATCCTGGTCCGCAAAGAGTCCATTCTAGTCAACATCCTCCACCTCCGTGCCCTCATCAAAGCCGATGCCGTCGTCCTCTTCGATACGTATGGCTCTGTCGACTCCAGGCTACACTCCACTTTCCTCTACCACTTGCAGCACAACCTCCGCAGCAAGGCCACCGGCCTCCCCTACGAATTCCGCGCCCTTGAGTCCATCCTGCTCTCCTGTCTGAGCGCCCTCGAAGTCGAGATGGTCTTCATTCGCAACCTCGTCGGCACCCTACTCGCCGAGCTCGAGGACGACATCGATCACGACCGGTTCAAGCGCTTGCTGTACTACTCGCGTCGGCTGGACAGCTTCCAGAATCGGGCGAAGTTGGTGCAAGACTGTTTAGACGAGCTGCTCGACACGGACGAGGACCTGGCGGCCATGTACCTGACGGACAAGAAAAACAATGCGGAGCGGCCGGATGAGGACCACGAGGAGATCGAGTTCATCCTGGAGTCCTTCTCGAAGCAGGTGGAGGAGATCGTGAATGAGGCGCAGAGTATGCAGAGCAACGTCCAATCCACCCAAGAGATTGTCGAGCTCATCCTGGATTCCAATCGGAACGCGCTCTTGACGCTTGACCTCAAGGTCTCCATCGCCACCCTCGGCATCGGCATCGGCACGCTCATTGCAGGCCTCTTCGGCATGAACCTGCGCACAGGCTGGGAAGACGACGCGCACGCCTTCTGGGTCATGTCGGGCGTCTCGGGCGTTGTCGCGATCATGGTGGCGTGGAGGGGATTCAGAATACTTCGCAAGATCAGGAAAGTCGGCCTGTCGAGCACGCATAGCCCACGGCAAAGGAGGCGACCCTTTTTGCCTCTGCCTTTAGGGCGCGAGCGAATCGGCGACGGCTGGCCATAG
->XR_007359457.1 PREDICTED: Ostrea edulis uncharacterized LOC125645827 (LOC125645827), ncRNA 
-ACACCCGCTGTGAGTCCTGTATCTTGATCATTTAAACAGAGTTAAATGGTTAAGTAATATAGATAGTGGCAAAATAACAGGTGTTCTTTTCATTGATCTTAGTAAAGCCTTTGACACTGTAAACCACCAGGTATTGTTACACAAGCTTTTATCATTTAGTATTTGTCAAAATTCTTTTAAATGGTTTCAGTCTTATCTTAGCGGAAGATCACAATGTGTTAGATGGAAAGGTGTTTTGTCAGATGAAAAAGATGTTACAATAGGAGTGTCTCAGGGGTCCATATTAAGTCCATTGTTCTTCATTTTATTTGTTAACGATTATCCTAAATGCCTAAAGCACTCAAATGTCTCTATATATGCAGATGATACATCTCAGGATGTTTCACATCAATCTATTGATGTTATTGAGCAAAGGTTACATGATGATCTTTTAAACTCTATGAAATGGGTGAAAAGTAATAAACTTACGATGAATTTAGAGAAAACACAATGTATGTTGATTGGCACTGCACAAAAACGCTCAAAGTGTAGAAAAATGTGTATTAAATTAGGAAATATTGTTTTAGATACTGTTAAAAGGGCCAAACTTCTTGGTGTACAAATAGATGAATGTCTAACCTGAAAAGGGCAGCCAGAATTATATTGAAGGTGAAAGTAACTCAGACTTCTACAGCTGATATTTTTAGTGTTCTTGAATGGATGCCTGTTCATGATTATGTTGTATATAGAAAACTAGTGCTTGATTTTAAGGTTCTTAATGACATGACACCAGAATATATGAGAGTTTTTAGTTTTGTCAGCCAAGTTAGTTTCAGAACAACAAGAAGTAGCGATAGTGGCATTTTATATTTACCAAAAGTTTGAACTGAATATTATAAATGGTCTTTTAAGGTATCCTCCACAATTTTATGGAATGAGTTGCCCGAGTCTGTCAGAAGCTGTGGTTCTATTACATCTTTTAAATCAGCATATTTGCAGCATTATTACTCAAATAAGTGATATATAGATATGATGTATATGTTTATTTTTCCCCAGTGATATGGTGTGTATATTGTATGTATATATTTCATATTATGTTATCTATTTTTCTATTCTTTCATTTATCTGTCTGTCAATATGTCTTATACAGGACCACAATGCAAACTAGTCATTTGTACTAATTGTGCTATCCTGTCTAAATAAAAGAATTTATTTAT
->XM_011701982.1 PREDICTED: Wasmannia auropunctata histone demethylase UTY-like (LOC105457365), transcript variant X2, mRNA 
-AGACAATAAGAAAAATTACTATTATCTTCTTTACTTTTCTTACTGAGGAAATAATCCTCCTCATTTATCCGATTTTTTGGGGTGTTCCGCGCTAAAAATAGTTTCAAATCTTGTCATACGTGAAATCTGCATAAAATTTTGTAAGAATTTTATTTCATATCTCCGTTTCGTATTTGCATAGTCATGTCTTAGATAGGGAATTATTTCGAGCATTTATGGCATAATAATAATATAAAAATATTGCCGGGCAAGTGATATGATTATTTGGGGAATAAGGAACGACGCTATGTCCGATGATTATTGTTTATCTGTAGTAGCAAAAAATTTCTAACAGGATATTTAAACCAAATAGCTTTAGTGTGTGTGGGGGGGGGGAGGCCGTTTATATTATTGAACCTATGTCCTTTGTATCCGCATCACTTTACCTTCAAATCCAATATCAAATGTGTTAGCAAGAACAGTCGCAGTTCGTTAGTGGTTGTGAGAACAATAGAGAATTTTAACTAGTATACACGTATTTCTTATCTTGCAAAGAGTCTGTATTTCCTGCTTTTTATAATTTTAATTTAATTATCCATCCAGACGGCAGTTGAAAGAGAAAATAAATCTCAATGAACGCCTCAGAGATTATCAAGCTGTGCAAAGAGCCGATCAACCAACGATTAACGGAAGAGCAATTGTCGCCGCCGGTACCGAGCTATCACGTGAACAGCAGAACGGATGCATTCCATCCGAAGCTGCAGAGAACCTGCCTGGATTGTCCCGTTGCCGTGATACGCAATCTCACGGCAACGCTCGAGATCAATCTGGACCTTTATTCGACTAAGACTCTGGTTGAGACACGGCCAAATACGAAAATCGACATACGCGAGCAGAGAAGATACGCTTTTGATGAGAATTGGGACGAGGAGAGGAGAAAGAAGAACTGGGCGTGCACCAGTAAAATGAGTTACATGACGATCAGCAAGTACGCGAAATATCAAACCGACAGGCTTCTCGAGGAAGATCAAACTCTACTCGAGGAAAATCGAAATCCCAACTTGTCTACTTTCGACGGGCCCGACAAAGTGACCGAACGCAACAAGACGGTGAAATTCGCTACGAATGTGGACCTATCGAAGCCATGCTGGAAACCGCAGTTGAACGAATTAACGAAGTTACCATCCTTGTTCAAGGTGGAATGTGCCGACAATATGCTTAGCTACATGTGCCGCGATCTCCTAGGGATGAATACCGTACAGTTATACATGAAGGTACCCGGCTGCAGAACGACCGGTCATCAAGAGAATAACAATTTCTGCTCCGTCAACATTAACATCGGACCGGGTGACTGCGAATGGTTCGCGGCGCCGCACGAGTACTGGGGCGTGATAAATTCACTCTGCGAGCGAAACGGCGTCGATTATCTGCGTGATCCCTGGTGGCCGCCGAACCTGGATGTTCTGCGCGAGAATAACGTCCCGGTGTACCGATTCGTTCAGAAACCGGGCGATATCGTGTGGGTGAACGTCGGCTGCGTGCATTGGGTGCACGCGATCGGCTGCTGCAATAACATCGCGTGGAACGTCGGCCCGTTCACCGTCAAACAATATCAGACAGCGATAGAACGTTACGAGTGGAACAAGCTGCGGCAGTACCTGTCGATCGTGCCGATGGTGGAGCTTTCGTGGAACCTGGCGCGCAAAGCTAAAGTGTCGAATCAGCTGTTGTATCAGCTGATCAAAAACTGCCTGTCGAACACGATGAAACAAAATTATTTGACGCTGGAGTTAATAGAGAGCAAGGGTCTGACAGTGAAAAAATACGCTGACGAGTGCGAAAACGATGAGACGGCTTATTGTGAAGACTGCGCTGCTGAGATATTCAATATAATAATCTGCAAGCGCAAGAGCAAGAAGACGAAGACACATCTGGTATATTGCCTGGACTGCGCGCTGAAGCAGTCTACTTCGCTGGAAAATTTTGTCTTTTTGGAGAAATGTTGTATGGAAAATTTGATGAACATTTACGATAAATTCGTATGCTACTAATTATCGGTGCTATCATCACCATTTCCTTATTATCAGCGTTGATACTTTGATGTCGCAGGTCGCAGACACAAACAGCTAATCTTATTGGTATAGCGATATTAGATATATGAGCATCTCCTTCCTACGAATATTCTTGTCGAAACATATTACAGTAGCGAGAATAAGCATCTTTTTTTGTGGAATTATCGAATTTCATTCTTCTTTTATACACTTAATTTTAAGACTGAAAAACTCATCGAACGTCTGTATTGTGAATTTAGAGTCAAACAAGGTTCCTAATCATGAACATTAAAATTATGTGCACTCTAT
->XR_007367990.1 PREDICTED: Ostrea edulis endochitinase-like (LOC125669718), transcript variant X4, misc_RNA 
-TACGTGTGTTTAAGTAGCACAGTCGAGCAGCACAAAGCGGAGTCCCGAGTAATGTGTGGCGTGCTCCTCTGCTTAGAAGAAGGAACTGTTATATTCACATTTGATGTCAATACACTAATCTGTCGAACTTACAAAGAGGAAGATTTTATCGGATGCCTCTTTCAAGCTTGTTCGACCTGTAAAACATACGGATATAATGAGTTGGAAACCACCACCGCCGCCAATGCTGGTACCACAACAGTACAAACAACCCAAGATACAGGACAACAAGGTTCTATAACAACAGTACAGACGACCCAAGACCCAGGACAAGAAGAGTGTCTCAGTCATTGTGAATTTCGTTGAAAAACAAAATATTTTATCTTTTATTCGAATCAACTGTATCCTGCACAGGTCTTCATGGAGCACTCCTTCCTCATCCTACCGACTGTTCTAAATTCTTCGAATGTGTGTACACGAATGCCGTACCACGTGTTTGTGCCGTCAGCCTTCATTTCGATGTCAACCGCAATTTGTGTGACTACCCAGCTAATGTTGACTGTCAGTCGTAAAGCAGATTTCAAAATTAATTCTCCACGCAGGACAATATCATTGTTATGCTATTAGCACATGTAGAGTTATAAGTGAATCTTCGCATTTCAAGATAATTAATATCATGGTGTTTGGCGTGTAACAAATAATTAATGATTAATTAAAACGGAGAGGATTTATATAGGCAGTGCCTGCTGCCCAATCCTATTATGAATTATCATAATAAAACAATATTTAAATCAAATTAATTATTTGTT
->XM_024808092.1 [Candida] sorbophila hypothetical protein (B9G98_01534), partial mRNA 
-ATGAAGCTTTCACTCTGGACTTTGGCCGTCGCACTCCCCCTTGCTTGTGCCCAAAACAACAACAACAATGAAGATCACAATAATCACCATTCGGAAGTGAATGGTAATAACAACGACCAAAGCCAAGACCATAACCGCACCCGTGACTATAACAACTCACATGATCACAGTCACACTAACGATAACGACCAGGGTCATAACCGTACTCGTGATTACAACAACTCACATGACAATAACCACACCGACAATGACCAGGATCACGACCAGGACCATAATCGTACCCGTGACTACAACAACTCGCACCATAACGAGCACACCCGAACCAATAGTGCAGTATCTACAGGCACTTCGGCCAACGGAGGTAAGCCCTCTCCTATCGGTGCTGGTGTTGGTAGTGCTGCTGAGAGTACCAAAACTGATATCAAAACATCTACCGTGACTACAAGTTCTACTAAGATCGCTTCCACCACTGCCTCTGCCAGTCACAGTAGTACTACCAGTTCCGCTAGCTCTTCCAGTGTGTTATCCACTTCCAGCTCGACCAGCTCCACCTCTTCGTCTTCTAATGCTGGAATGGCCGTGGTCGTAGGCGGGTCTACTATTTTCGGTGCCGCCCTTTGTGCTATAGCTATTTTGTAG
->XM_028677370.1 Plasmodium relictum conserved Plasmodium protein, unknown function (PRELSG_1111000), partial mRNA 
-ATGGATAACAGATATAAAGATGGAGAAAGTAATACTAATAATTTGGAAGAAAATGATGTGAATAATTTTGTTTTAAAAAATAAAAATGACATAGAAAGCAAATCAGAAAAGCAATTAAATGTGAATGAAAATTTAAGTATGTATAATTCTTATTATCAAAATGTACTGAATATTAATTATAAAACAATAAATAATGAAAAAAGGGATATAAAAAACGAGCAGAATGTGCAAATTAAAAAGTTAAATGATATTAATATAGAAAGTAACTATAATATGAATTCTGCTACTATTGGTAGTAAAAATACATTAAGTAAAAATAATAATAACATTAATGGTTTGTTTAATGATTTTAGAAAGAATAAAAATAATTTTTTCAATTCAGAATCTAATTATCTTGAGGAAAAAACAGATACAAATAATTTTGATGAAGAAATTAAAACTAATTCAAAGGATAATATGGAATGTATGTTATTTAATAAACTTAATCATAACACAAATAATAAAATTAGTTCTGATGAAAATAAAAATTTAAATAATATTTATTCAAATACGAACTTCTTAAGTGATACTTATAATAATGATTCTAATAATGATGTAAATAATTGTAACTATAATTATATTAATAACGATAACAGCAATAATATGAGTTGTAACATAAATAATATGAATAAAAATAGAAATAATATATATGATAACTTAAATAAATCAATTAATGTTAATGTTTCAAATAAAAACATTAATAAGTTTTGTAGCACAAATAATAACAATAACAATTATAATAATAATAATAATAGTATTTATAATAATGCAAATATTGTAAGTAATTCAAATAATAACTCTTTTAAAACTTATAATCCAAAAAAAAAGACGAAAAATATAAATAATTTTTTAAATATTGATGTAAATGCAAATTCAGAAAAAAATTCTTCCATTATTAAAAAAAATTGCTATATAAAAAATTATCTAAATCTAGAAGGTAATATAAAAGGTAGAACTGATATTGAGAATTTTAATTATATTAAAGAAAATAAGAAAAGTGTAACAAATAGCATAAGATATAATGATAAAGAAAATAATAATTCTATTTTAGAAAATAAGAATAGTACGAATGTAATTTTAAACACATGTATGAACAAAGTTAATAATTATAATGAAGAAAATATATTACAACTGAATATTAGCAATGAAGATTGCTTTAAATCATCGAAAAATTCAAAAAATAATGATTTAAATAATGATGTAGGTAAAACTTATATTACTATAAAAGAAAATTGCAATAAATCAGAAAAAAAAGAAAATTGTTTTAGTAAGGTAAATAGCAATAACTTTCATAATAATGATATATATGGAAATGACTATTATAATAATTGTAATAGTAACATTTTTACTTCTCCACATGAAAAAAATGAAAAACTACATAATAATTTAAGTTATGAAAAAAAGTATATGAATAATAATTTTTTGAACGATAGATATTTAAATTATATGGAAAGCGATTATAATGATAATTCATTTGATATATGTGAAATGAAGAATATAAAAAAGAATGACGAAACTAAAATTGAAAATAAGGAAGAATTAAAAGATTTTTCAAATGACTATTTATTATTTAAAAATAATGAAAATTCTTTTAATTATGATATCAACGATTATGTTTTACTGAATAAAAATTTTAAAAATTATAATGCATCAGGTGAAAGTAATGCAAAAGAAATGAAGACAGATTGTATGACAACTGATAGTACTATATATACGAATAATATTCTTAATCTACATAAAAATATAGAAGAAGAGAATGATGAAATCTATCAGAATTATAATTATTATGAAAATGATAATATTAATATAATGCAAAAAGAAATTGATGAGGAAAGTTTAAATAAAAAAATAAATATAGGTAGTAGGGAGAGTATTTTAAATGTAAATAGTTTTGAGAAAAATTATGATTTTGAAGAAAATTCACATATGTACAAGCATTTAAATTTTTCTGATAATTTAAATATGAACAAAAATTTATCATTTTTAAATTTTGATGATACACTTAATGAATGGAGGCGTAAGCAAAATAATGATAATTTTTTGAAAAAGGAAAATAATAACATGAACACATGTTCATTTTTTGAGAAATTAACTTTAAATGAAAATGAAAGCTTGGAAAATGGAAGAGAAAATAATGTTTCTATTTCAATGTATGATATGCAAGAAAATATAAATGAAAAAAATTGTTTTAAATGCACTATTGAAAACAGTGATCAATGCGATGATCGTATGAAGAAAAACATGCATAATATTATTATGCATAAGAATAACCTCAATAGGAATATAAATTTTGATGTTAGTGATTTTTGTAGAAATGCTAATAATATAAGCAATGATAATATAAATGCCAGCAATAATGATAATAGTTTATGTGATAAAAATATAAATAAATATGTTGATAATAATTATTTGAATAACCATGAATATAATAATAATAACAATAATTATAATCATGATAACGATGTAAATATCTCAAATAACGAAAATTCAATTAAAAATAATTCAAGTAATGCTAACAGTAATAATAATTTAAATAATAATACAGATAACATAAATTCAAATGGAAATGATCGTAATTCCTTTTTTATGAAAGAAAATGATTTTCCATATTTAAAATATAAAAATGAATATACCAAAAAATATATAGATGAAAATAATTTAATGTTTCACAATGAATTTGACACTTTCGATATAAAAGATAAGAAAAAGGGTTGTGAAAAAATGAAAAAGAATAATTATGATATGAAATGGATTAATAGTAATTTATCACCTAATAATAAAAATGAAATAAACAATGAAGTTATTTCCAATGTTAATAGTGGAGATTGTAATAATTATTATTTGATTTTAAATAATAAAGGGATATGTTATGATACTAATAGAAGTGATTTTCCAAATGATTGTGAGGAAAAGTTTGATGATAAAAAGAAGAAAAATAAACATAATTTAAATTATTGTAATATGAATAATAATAGTAGTAACAATAACATCAATGATAATAATAAGAATATTAATAATAACAATAACAACCAAAATAATAATAATATTAACAATAACAATAATAATAATAATAGCAATAATAATAATAATAGTAATAATAACGATAATAACAATAATAGTAATGATAATAATAATAATAAAAATGTTAATAATAACAATAACAACAATAATAATAGCAGTAATAATGATAATAGTAATAATAACGATAATAACAATAATAATAATGATAACGTTAATATGAGTAATAATAATAATATTAATATGAGTAATAGTAATAACAATGATAATAGTAACAATAACATTAATATAAATAATAATAATAATAATGATAATAGCATTAATAATAATAGTAGAAAAAAAAATGTAGAAATTGAAAATAATTTATATATGAATGACTTTAATATTGATCTACTGAGTTATAAAAATATTAAATTTGACAATTTTTCATATAAGGGTGATCTTATAAGTAATGAAAAATCTCCAAACAACTATTTAAAATTTTCTTCTAGTAATTTATTTAACAATGATTATAATGATTGTGAGAAAAATGCTTTTGGAAATGATGTATTTAATATTAAGGATAAGGAAAATAACAATTATGTTAATTATTCGAAACTAATGAATAAAGATAATAATTCAATTAGTAGATACTGTGATAACTCAAAGGAAGAAAATAATTTAAATATATGTTCTAGTGTGCTTAATGGAAATAATAATGATAAAATTAATTTGAAGTCTTCTAGATTTTTAAAAAGTAGCATTAATAATAATTCTTATTATTCAAATAACGAAAAAAAGGAAACTTATTGTTTGCCAATAACAAATAATATATTAGAACTTAATAAAAACATAAATTTAATAACAAATGAAAAAGAAAAAGAAATCATTGATCCAGTTTTTTGTTTAAGTAAAAAAAGTTTTAAAAATAATTATTCTATGAATACAGAAAAATGTAGCAGCATTCATAATAATTTGAATGATATAAAGAATGATGAAATAATGTTTAATATTAATAACAAATACAATATGTATAACATAAATAATGAAAATAATATATACCATATAGATAATGAAGATAATATGTATAACTTGAATGATGAAAATGATATATATGATATGGATAATGAACAAAACATGTATGACAATATAGAAAATATGCACCCTACAGAAAATAACTGTGCGTATAATAAACTTAATAACTTAGAAAAAAATAATAAGAATTTATATCTTATGGAAAATGATTATATGTATAATAACATAGATAATGATATATACAATGATATGAATAACTTACAAAGTAATGAAAATATATGTGATAATAGAAATAACATAGAAAATAATTCAGATGTGTGTGGTAATATCGGAGAACATGGCAATGCATGTAACATGAATAGTATTGAAAACAATATGGATTTTATATTAGGTGAAAATGAGGAAGTGGAAAAAGAATCAAAAGGAAACGTGAATAATGATAAAATAAATGAACTTCAAAACATTATAAATAGTTTAAAATTTAAAAATAGACAATTGGAAAAGGAATTAACTGATATAAAGAATATGTATTTAAAAAAGAAGCAGTGTTTAATATTAAATAGTCTAAGTAATAAAAATGATGATATTAACAGTTATTCAACTTTTAAGGACGATACCAATAATTCTGACTGTGAAAGTGCAGTTCAATCAAGTAAATATATACAGAATTTTTTAAATGATAAAGAGAAGTATAATTATGATACAAAAATATCTATTCAAAAATTTCATTTAGCTTATACTAATAATTCAATTGGAAAATTAAAAATAGCAGCGCAAAGAGATATTAGTGGATCTTTTATGGGACCTAAAGGAATACATGTAAAAACAATAAAATCTTCTTTACATATTTCTGTTTATAAAAGTGCAAAAGATGTATGGTTTCCTGGATTTGCTGATAGTCATGTTTTTTTATTAAAAGGAAATATATTTGGAATTTTAAGAGCATGCCAGTTATTATATCATTATGTAAAATCGAAAATGTCTTCTTCGAAATGCTGCATTTACCTAGTTGCTCCATTTGAATGCGTGCAAAAATTATTAGCTGATGGTTGTAAGAGAATGGCTATTATAAAAGAAGAATGTGGAGCTGATGTAAGATTAGGAAATTTATATGTACAAGTTCATGAAGGTTTTACTGAAAGATTAATGGAAATAAGAGGAAACGAAGTTAGTGTTGATTGTGCTTTGGAAAAACTAGTTATTTTTATGCAATCATGTTTTTCTGTACAGTCATATGATTATGAACTGTTAAAATATCCATGTCGCTCAGTATTAAATTTACAATAA
->HM928366.1 Uncultured Pseudomonas sp. clone GG5QJA201B0DXG 16S ribosomal RNA gene, partial sequence 
-AGAGATGGATTGGTGCCTTCCGGGGACGTCTGACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCGTAACGAGCGCAACCCTTGTCCTTAGTTACCAGCACGTTATGGTGGGCACTCTAAGGAGACTGCCGGTGCAAACCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGGCCTGGGCTACACACGTGCTACAATGGTCGGTACAAAGGGTTGCCAAGCCGCGAGGTGGAGCTAATCCCATAAAACCGATCGTAGTCCGGATCGCAGTCTGCAACTCGACTGCGTGAAGTCGGAATCGCTAGTAATCGTGAATCAGAATGTCACGGTGAATACGTTCCCGGGCCTT
->XM_012845165.1 PREDICTED: Setaria italica wall-associated receptor kinase 5 (LOC105914170), mRNA 
-ATGGGAAGCTACAAATGCACGAACCAGCAGCACCAGCATCAAGCCATAGAAAGTATCATAACAAATTATACGCTTTCAGGTTTAAGCATCATTATAGGAGTTGGTAGCGCAGCAGGCTTTATACTTTTGGTTGTCATTATTGTCTTTATCACTCAAAGGTTTAAGCAGATGAGGGCAATGAAGCTAAAACAAAGAAACTTTGAGCAAAATCGTGGACAACTGTTACAACAGTTGATATCCCAAAGGACAGACATTGCGGAAAGGATGATCATAACATTGGATGAGCTTGCAAAGGCAACAAATAACTTTGACCCAGCCCGTGAGCTTGGTGGTGGAGGGCATGGTACTGTCTGCAAAGGGATTTTGTCGGACCTACATGTCGTAGCTATCAAGAAGTCAAATATAACAGTCCAAAAAGAAATAGATGAGTTCATAAATGAGGTCGCCATCCTCTCACAAATAAACCATAGGAATGTGGTAAAACTGTTTGGATGTTGCCTAGAAACTGAGGTGCCATTGTTGGTTTACGAGTTTATTTCCAATGGAACCCTTTATCACCATCTTCATATTTCAAGATCACTAGCATGGAACAACAGGTTAAGAATCGCAACTGAAACTGCTAATGCAATTGCCTATCTTCACTCATCAGTTTCAATCCCAATCATCCATAGAGATATCAAATCCAGTAACGTGCTCCTTGATGATACGTTGACATCAAAGGTGTCGGACTTTGGAGCTTCAAGGTACATTCCACTTGATAGAAGAGGGTTAACCACAGTTGTTCAGGGGATTATAGGATACTTGGATCCTATGTACTTTTACACAGGCCGCCTTACAGATAAAAGTGATGTTTATAGCTTTGGTGTTCTTCTTGTGGAATTGCTCGCTATAAAGAAACCATCATATTTGTCCTCTAACGGTGATGGTCTTATTGCCCATTTTTCTCGCATTAACTTACATGATGATGGCAACCTGGACCAAATACTAGATCCTCAAGTTATGGATGAGGGAGGCAAAGAAGTCGAAGAAGTGATTAAACTTGCAGTGTCATGCGTACGATTAAGGGCTGAGGACCGGCCAACCATGAGACAAGTGGACCTTACACTAGAAGGCCTTTTGTCATCTGAGAATCATGAGGAGAATAATACATTGGCAGAGGGATTTGAGGATATTGGTAATATGCAGATGGATTTTCCGTCGATTGATGAGGGGCAAAGCACGGGGGAGTCTAGTAAATGGCACAGTTTGGGACAGGATCCCTTGATGTTTTCTGGTTCTCGGTAG
->XM_031547130.1 PREDICTED: Punica granatum sister chromatid cohesion protein SCC4 (LOC116212494), transcript variant X1, mRNA 
-TTCCCCGAGTCCCCCATACACAAGAAGGAAGGGGGAAAAGAAGACGAGAGAAGAGAAGAGAAAAGAAAAGAAACTCTGGTCCTTGTTGCTGTTCTCAGTCTTCGCTCCTCAGGGTTGAGGGAGACGGTCGGTAAGGGACAACAAATCCGGTAAAGGACCTCCCCAGCAGTTGCAGAAAAGAGGTGAGACTTGCGGCAAGATAGTCCGGAGCACGAGGGCGTTGATCTGATTTAGAGTAGTCAGTGCAGCAGTTGGAGTAGGCTTGGTGCGGTGGGAGAGAGAGAGAGGAGAAATGAGAAGCTAAGCAGAAAATGGAAGAGGTGGCGGAGGGACTTTGGTCACTGGCGGATCACGAAGAGAAGAAGGGGGAAATCGGCAGGGCCATTAAGTGTTTGGAGGCGATATGCCAGAGCACGGTGTCGTTCCTGCCCATCATAGAGGTGAAGACGCGACTCCGCATCGCAACCCTGCTCCTCAAGCACACCCACAACGTGAATCAGGCCAAGTCTCACCTGGAGCGCTCCCACCTCCTCCTCAAGTCCATCCCTTCCTGCTTCGACCTCAAGTGTAGGGCCTTCAGCCTCCTCAGCCAGTGTTACCATCTCGTGGGCGCCATTTCTTCGCAGAAGCACATCCTGACCCGCGCACTCGACCTCATTGCTTCTGCTGCTGCCGCTGCCGCCGACCAGCTGGAAGTGAAGCTATGGGCTTGCAACTTCTACTCGCAGCTTGCCAATGCTCTCATAATTGAGGGCGACTATCAGAGCTCGATATCTGCGCTAGAGCATGGACGACTCTCTGCCACTGAGCTGCGCTATCCGGAGCTGGAGATGTTCTTCGTGACATCCACTCTTCATGTGCACCTGATGCAATGGGAGGACGAGAATGTGATTGCAAGTGCTGTCAGTAAATGCGATGAGGCCTGGGCCTCCATTCATCCTGAGAGAAGACCACAATGCCTTGGTTTGTTTTTCTACAATGAGCTGCTGCACATCTTCTATCGCCTGCGCATCTGTGACTACAAGAATGCTGCCCAGCATATCGACAGATTGGATGCGTCAATGAAGAATGAGTTGCAGCAGAGGCAGGAGCTTATGGAGGAACTCCAAGCTTTGAACCAGAGTCTCTCTAGCTCTGATCTGAGCCCCAGAGATAAATTGGCTCTGTCTGGAAAACAATCTCAGCTTCTAGAGCAGTTGAGAACAATGGCTGGTCAAGATTCTTTTGCACCAGGTAATAGTGGAACTGTCAAACAAGCATGGGGTGAGGGGCTTGAGTTGGCGCCATCCCCTATAAATGGAGAGTGGCTCCCTAGGAATGCTGTGTATGCACTTGTTGATCTTATGGTTGCCACTTTGGGACGTCCAAAAGGACTTTTTAAAGAATGCAGCAAAAGGATTCAATCTGGAATGCTTATCGTCCAAGAGGAGCTGATGAAGCTCGGTATAACAGACAATCTCAAAGAGGTGGATTTGCAACACTCTGCTATCTGGATGGCTGGTGTTTATCTAATGCTTCTTATGCAGTTCCTAGAAAACAAAGTGGCGGTGGAGCTTACACGATCTGAATTTGTTGGAGCACAAGAGGCTTTGGTGGAAATGAGAAAATGGTTCACTCGCTTTCCAACTATATTGCAGGCTTGTGAGAGCATTATTGAGATGCTTAGAGGTCAATATGCGCATTCTGTTGGCTGTTATAGTGAAGCTGCCTTTCATTACATTGAAGCAGCAAAGCTAACAGAGAGCAAATCTACGCGAGCAATCAGCCAGGTTTATGCAGCCATCTCTTACATTTGTATTGGTGATGCTGACTCATCTTCACTGGCACTTGATTTAATTGGGCCTATCTATAGAACAATAGATTCCTTTGTTGGAGTTCGCGAGAAGACTTGCATCCTTTTTGCTTATGGACTTTTGTTGATGAAACAACATGATCTACAGGAAGCAAGGAATCGGTTGGCCAGGGGCCTGCAGATGACACATGCACATCTGGGGAATCTTCAACTTGTTGCACAATATTTGACTATTCTGGGAAGTTTAGCACTTGCCTTGCATGATACAGTGCAAGCCAGAGAAATCTTAAGATCTGCCCTTACCTTAGCAAAGAAGTTGTATGATATTCCAACACAGATTTGGGTATTGTCTGTCCTAACAGCCCTGTATCAAGAAGTAGGGGAAAAAGGAAATGAAATGGAGAATGCTGAATACCATAGGAAAAAGGCGGGTGATCTGCAGAAGAGACTTGCTGATGCTCATTCATCTATCCACCATATTGAACTGGTCGACAAAGTGAAAGTTGAAGCTATGCAATTCCAAGACCTTGATATGAAGCGTCTTCTTGGTGGTCCATCCATGAGGGCAAATCTTGACATTCCTGAATCTGTTGGTCTATCGGCTCCAGCCCCTAATACATATACTTCGAGGCTGGTGGACTTGGACTTGGATACAGGAAGACGCACAAAAAGAAAATATTAGTTGGAACTCTACTTTCTTTTCCTTCCACCTATATGGTGGAATGTTCATGGTCAAACTACATACGATATCAGCACTATCAACAACAATTTACCATGTTGTAATTCATGTAGGTATAGATAGATGTAATATCTAATTTGTGTATATGTAAATCTGCGAAACATGTTACTGGAATAGGCATTACAAGGTTCTTGGTTTCCGGTGCTAGGCTCTGCTAGCCGTATTGTTTTCAGTAACCTGACACGATTAGCGATCACAGTAAGTAGTTCAGTTTGA
->XM_051656078.1 PREDICTED: Myxocyprinus asiaticus protein unc-13 homolog C-like (LOC127416634), mRNA 
-TCCTCCAAGGGCTTCTCGTACTCTCTCTCAGCACACACACTTCCTGTGCATCCAGACAAGGAGCTTTCACCCGTTCCAGACACACTGTCTGCTGCCCAGCGTAGTGCTACGAATTTTGTCTGGAAGAGACAGGCAAAGAGGAGGGATATTACCCAGGATCTCTCCATGATTTGCAACAGCATGTGCCTGCCGAACAAGACTTCAGCCCAAGGTTGATCCGAGCACAACCGCTGCAGCACGAAACTAGGGAGAGATGGATCATATAGAGGGGAGGACATGGAACTGAGTCTGACATCTAGAGGCTTGTGAAAGGATGCTCGGTGCTCCACAACAGGACATTTAAGAGTTTAGTTGACTGTTCTGGAGCTCCGGTGCTGTAGTAAATGGATTTGGTGTGCTGTAGGAGTAGGCTGTGATTGAGAGATATGAAATTTCTTCAGAAGTGCGCATAGCATGTGCAATGATTTTTGCTTGGCACAATTGTCTCTGAGGACATCAACTCTTCTCTAGACCCTCTTATACCACAGAGTTAACTTTCAAAACTAGTAAGCTTTTGCGTGCTTCCTGTTAAGCACCTCTGGATCAAAGACCAGTTTTGCTTTGCCGCATCTAGAGTGCAAAACTGCTGAAATATCGCCATCCATGGTTTCTGCTCATTTCAAGAAGCTATCGTCTTACATTGTAAAGATTTGCAAAGGAATGTTTACAAAGAAACTGGCAAATACCTCAAAGAAGAAAGAAAGCAGCGACAACAAAAAAGAGCCGAAAACCTTCCCAGAACTGCATGCACGGAACCCAACGTTCTCAACTACATTGAAAAGCACAGTCAAAAAAATATCCAAATGCTCATCAACACGCAATATATCTCTTGAAGAGGAGGATGGAAAAAACGACTGTTCCTCTCTCTCTCCGACATTTAGTTATCGTGTAGCAATTGCCAATGGACTACTCAAAAATGACCTCTTACTAAACAATAATGAATTTCATGAGGTCTTGTCAGTTGACAGCGATTACTCAGACTGTCTAAACGAGACCAAACTTGTCCATAGATTCGATGAACAAAAAGCTTATACAATGCCAGTAAGAAGGAATAGGAAGAGCTTGATTAGTCTAGCACCCTCAGACGGCAGCTCAGAGGGAGAGCGGGGAGAGCGCAGCAGTCTCCACACCCTTCGATTAGGTGCTCTGAAAAAGTTGAGGAAATGGAAGAAGAGCCAAGAATGTGTGTCCTCAGATTCAGAGGCAAGCAACTGGAGAAAGACTCTTGGCATCAGGAGCAAATCTCTGGACAGGGCTGGACGGCAACAGAAAACCACTACCCTGGAGCCAGGGTCCAGCTCAACAGGGTGTATCAGTCAGACTCAGGATGTGATGGAGATGATCTTCAAAGAACTTCAGGGAATCAGTCAGATTGAGTCTGAGCTCTCAGAACTGCGAGGGCATGTTAACGCCCTCAAAAGCTCCATCGACGAGATCTCCAGCAGTGTAGAGGTGGTACAGAGTGAAATCGAGCAGCTGCGTTCGGGATTCGTACAGTCCAGACGTGAGACTCGAGACATCCACGATTACATCAGACAGATTAGCCAACATACCAACAAAGCTACTCTAAGATTTCTAAATGTGCCTGAGGAGAAGTTTGAAAAAACCGAAGAGCTTATTTATCAGATTCTGAAAGAGAAAATGGGTTTCACTGATGCACGCAAGACATTTAAAATTGAACTTGCCCATCGACTAGGGCAACAAAGAGAATGTTACAATGCTAAACCTCGACCAATTGTAGTTATATTTTCAAGCCCACAAGATAGAAATTTAGTTTTGAAAAAATGTTATAAGCTAAAAGGGACTGGCATATCAATATCAACTGATAGTCTAGCACATGATTCAAAAGAAAGGAAGGACAAGGCAATGGCCTCCTCGCAGACATATGAAAGCATGGATATCAAGGTTTCAGCCAAAGATAAGGCTGAAAGTGATGAATGGGACTCCATGGAAAGTGACAAAGAGCTAGATGAATTAAATAAGAACAAATATGCAATTGTGTCCAAACCACCTCAAAAAAGTAAATCGGACAAGAAAAAGTCTCACAATCACCGACGGTTGGCTGATGACACTGCATATTCTGTGCACTATGCAGATAATATAGCCTACGATGACCCTGACAAGCAAAGCAAGTCTTACTACTCTGACCTAACACCTGGGTGGCAGTCTCAGAGTGATTATTCTACTCCCAAACTCAGTCGGTCTGAATCGGACTGTTCTAAACTTTGCCAGTCTTATTCAGAGGACTTCTCAGAGAGTCAGTACTTCAACAGAGTCAACGGCTGCTCCCTGCTCTCCTCCTCGGATCAGGAGCTTTGGCAAAGGAAGCAAGAAGACATGGCATCCTCCTGGTATGCTAGTCCTCCCAGTCAAACTCTGAGCCAAGAACGACCTTATGTGGAACATAATGAAGTTGACACCACAGAGACTATTGACAGTGGTGTAAGTAATGGTATTGTTTGCATATCAGGGGACAGGAGCCATTACAGTGGCTCTCAGCTGTCTCTACAGGGTGACCTCTCACCATGGAAAGATTGGCATCACCTCGAACAAGGTGCTGATTCAGGTTTGGATGCTTCAATTGAACAGAACATAATCTCAGAGATCACTAGCCCCTTCGACCCTGCAGCTAACCCAGGTTTCCCTGAGAAAATTACAAAATGCCTTGAGGTTGATTTACAGTTTGAAGGTGAGACCTTCTTGACACTAGATAGCACTCCTGAGACAGGCCAAGACCAAGATATAGATACAGAACCTGAACTTGTTCTAGAACCCGATCCAGAGCCAGAGCTAGAGCCAGAACAAGTACCCAGGCCAGGACCTGAACCAGAGCCAGAGGTTGTAATTGAACCCATATCAAAACCAGTACCAACACCTGTGGCCGAACCACAACCAGAAAAGAAGCCGAAAACCAAGAAAGCCCGTACTAAGCCTGAATCAGCTCCTCAAACTCTGCAACGACAAGATGTCAATGTGAACCACCTCCAACAGAACCAGAAATCTTCATCCATGTACCGCAGTCAGAGTGAGATCGGTAATGAGAAAGTGGAGGAAGTCCCTAAATCCTGGAGTAGTAGGCTCAGCATAGACCTCAGCGAGAAAACCTTCAGCTTTGGATTCGGATCCACCCTGCAAAGAGCCAAGTCAGCTTTGGATTTTGTCTGGAATAAAGGTTCCCAGAGCACTAGTGCTCCAGTCGAAGAAACAAGCAACACCTCATTCATGGGCAGGCTCAGAACCTCGTCCCAGTCCACTGAAAATAGTTCCAGCACAACCATTGACTCTGATGTTTACACAGAACCTTTCTATTACAAGGCAGAGGAGGAAGAACAAGCCAGTGAACAACCTGTGGACAATGAGACACATTATGTTGAGGTAATGGAACAAGTGCTGGCGAATCTCGAGAACCGAACGAATACCAACGAGGCTGAGGAACAGTACCAAGAAGAGGAATATGATGTCTCGCAAGAATACGACATCTCACAAGAGGGTAATCCTGTCCTAGAATACGACTGCAGCCTTGATGAGCAAGATGATGAGGAATACAGTGAGGCGTATGACGACAATCCCATGACTGAAGACACGGCGGAGTATGAAGGGAGTTTGGTGGAGTATGTTGAAGTAACTGAGGAACAGGAAGAAGAATCTGAGGAACAGGAAGAGGAAATAGAGCAGACAAAGGAAGGTCAAGATACAACGGGAACAAAGGTAGCAGCTGAGGTAAAAAAGACAGTAGAACAAGAGGATGAGAATAAAAATGTTACAGAGGTTCCTGTGGAGCCAGCACCACCCAAAAAAAGGATACGGCCCACCTTCAAAGAGGCAGCTCTGAGAGCTTACAGGAAGCAGATGGCAGAGCTAGAACAGCAAATCCTGGCGGGAGACAGCACAGCTCTGGATACAGAGGGTTGTGCAAATATTCTGGATCAAGCCAAACTGGGGCTGAACGGTGGTGGAGTTGGCAGTATACTTTATGGCATTGACAGCATGCCAGATTTACGCCGCAAGAGGACCATGCCTATTGTCCGAGACCTGGCTTTGACCTTGGCTGCTCGAAAGGCAGGCATTGCGTTTGGCCTCGTGAACAGATCAACTCTAAACAATGAGGAGCTGAAACTGCATGTGCTGAGAAAGACCCTGCAGGCCTTGATCTATCCCATCTCCTCCACGACACCCCATAATTTTGAGGTGTGGACGGCAACTGCGCCCACCTACTGTCACGAGTGTGAAGGGCTGCTGTGGGGCATCGCCCGGCAGGGCATGCGCTGCACGGAATGTGGGGTGAAATGCCACGAGAAATGCCAAGACCTTCTGAATGCAGACTGTCTTCAACGTGCGGTGGAGAAGAGCTCAAAACACGGAGCAGAGGACAAAACCCAAAACATCATTATGGCAATGAAGGAACGGATGAAGATCAGAGAAAAGAACCGACCTGAGGTGTTCGAGTTGATCCAGGAGATGTTTCAGCTCTCAAAGGAAGATTTGACCACCCATCTGAAAACAGCCAAACAGGCAGTGTTGGAGGGGACATCCAAATGGTCTGCCAAGATTACCATCACAGTGTTGTGCGCTCAAGGTTTACAAGCCAAGGACAAGACAGGCTCCAGTGACCCTTATGTCACAGTACAAGTTGGAAAGACTAAACGCAGGACCAAAACTGTTTTTGGCAATCTCAACCCCATCTGGGATGAAAAGTTCTTCTTCGAGTGCCATAATGCCACAGATCGTATAAAGGTCCGCGTATGGGATGAAGATGATGACATAAAATCTAGAGTGAAGCAGCACTTTAAGAAGGAATCTGATGACTTCCTGGGTCAAACCATCATCGAGGTGCGGATGCTAAGTGGAGAGATGGACGTTTGGTACAATCTTGAGAAAAGAACAGATAAGTCGATGGTGTCGGGGGCCATCCGACTAAAGATCAGCGTTGAGATGAAAGGAGAGGAGAAGGTGGCTCCACCACACGGGCAGTACACATGTTTACACGAGAATCTCTTCCATTATCTGACGGAGGTGAAAAACAATGGAGTGGTTAAGATTCCAGAGGTCAAAGGTGACGATGCGTGGAAGGTTTATTTTGATGACGTGTCTCAGGAGATCGTAGATGAGTTTGCGATGCGTTTTGGTGTGGAGTCCATCTACCAGGCCATGACTCATTTCTCATGTCTCTCATCGAAGTACATGTGTCCCGGTGTTCCCGCAGTGATGAGTAACCTGCTTGCCAACATAAATGCTTATTTCGCTCACACTACCACGGCAACCACCAACATCTCCGCCTCCGATCGATTCGCTGCATCCAACTTTGGGAGAGAGAAGTTTGTTAAACTCTTGGATCAGCTGCACAACTCTTTGAGGATCGATCTCTCCAAGTATCGAGATAACTTCCCAGCAGGAAATCCAGAGAGACTCCAAGACCTGAAATCAACCGTCGACCTGCTAACGAGCATCACCTTTTTCAGGATGAAGGTGCAGGAGCTGCAGAATCCTCCCAGAGCCAGTATGGTTGTAAAAGACTGCGTGAAAGCATGTCTGGACTCCACTTACAAGTACATCTTTGACAACTGCCATGAGCTTTACAACCAACTTCTGGACCAGGCTAAGAAGCAGGATTTACCACGAGAGGAACAGGGCCCGTCCATCAAGAACCTGGATTTCTGGCCCAAACTGATCACGCTGATGGTGTCTGTTATAGATGAGGACAGAACAGCTTACACACCCATTATTAACCAGTTCCCTCAAGAATTGAACATGGGTAAAATTAGTGCTGAAATCATGTGGAACCTCTTCGCTATGGATATGAAGTACGCAATGGAGGAACACAACAAGCATTGTCTATGCAAGAGCACAGAATATATGAATTTGCACTTCAAAGTCAAATGGTTCCACAACGAGTATGTTCGAGACCTGCCAGCCTTTAAAGGAATTCCTCCGGAATATTCCCTGTGGTTTGAGCCGTTTGTTATTCAGTGGTTGGATGAAAATGAAGATGTAGCCATGGATTTCCTTAATGGAGCTCTGGAGAGAGATAAAAAAGATGGGTTCCAGCAAACATCAGAACATGCTCTCTTCTCCTGCTCGGTGGTGGATGTTTTCACACAGTTGAATCAAAGCTTTGAGATCATAAAGAAGCTAGAATGTCCAAATCCACAAGCCCTCGCTCACTTCATGCACAGATTCGCAAAGACCATAAATAAAGTCCTTCTCCAGTATGCGGCGATCATCTCGAAAGACTTCACCAACCATCTGAGCAAGGAGAAAGTGGCCTGTATCCTCCTGAACAACATTCAACAGCTCAGAGTCCAACTGGAGAAGATGTTTGAGTCTATGGGCGGAAAACAGCTGGACGCTGAAGCCAGTGATCTACTGAAAGAACTGCAGAATAAACTGAACACAGTGCTGGACGAGCTCAGCGGGGTCTTCGGCTCCAGTTTTAAGCCGGTCATTGAGGACTGCATCAAACAAATGAACCAGGAGCTTGTGCAGATAAAAGGAAATGCTGGAAACAAGAGCAACGCAGCCATGGACGCAGAAATTGCCCTGCGACCACTCATGGACCTCCTGGACAAGAACTTGATTCTGTTTGCTAAGATCTGCGAGAAGACGGTTCTCAAACGTGTTCTGAAGGAGCTGTGGAAAATCGTCCTCAACACCATTGAGCGACAGATCGTTCTGCCTCCGCTGTCAGATCAGACACAAGGAGCTCAGATGATCTTCAGTGCTGCCAAGGACTTGGGTCAACTCTCCAAGCTTAAGGAGCATGTGATTAGGGAGGAAGCTCGGAGTCTGAGCCCTCGGCAGTGTGCTGCCATGGATTTAGTGCTGCCAACCATCAAGCAATATTTCCATGCGGGGGGAAACGGTTTGAAGAAGAATTTCCTGGAAAAGAGTCCTGATCTGAAGTCCCTGAAATACGCCCTCAGCCTTTACACTCAACCCACAGATGCCTTGATCAAGAAATATATATGCACCCAGACCTCTCAAGGTCTGTCAACGTCTGGATCCATTGGTGAGGTCACTGTCCAGGTGGACCTGATCTCACACCCTGGTACTGGAGAACACAAAGTCAGTGTGAAAGTTGTAGGTGTGAACAACATAAACTGGCAGACGAATGTCATGTTCCGGCCATTTGTGGAGATCAACGCCATCGGACCACACCTAGCTGACAAGAAACGCAAGTTTAGCACCAAAACCAGGAATAACAACTGGTCTCCAAAATACAACGAATCATTCCAGTACGTGCTGAGTAACGAGCATGGCCCAGAGGCCTACGAGCTTCACATCTCCGTGAAGGACTACTGCTTCGCCCGAGAGGACCGTATCATCGGAATGACGGTTCTGCAGCTCAGAGAACTGGCTGAAAAAGGCAGTTTGAATGCAAGCTATCCACTCGTCAAGAACATAACCATGGACGAAACCGGTCTGACCATCATGAGAATACTCTCACAAAGGACCAACGACGAAGTGGCCAAAGAGTTTGTACGTCTTAAATCGGACACACGGTCAGCCGAGGAGGTGTCGTAAAAATAATCGCAGGGGGAAAAGAGCGGGGAAAAAAGCGGCAAGAAACAGAGTGAAATCCCAACAGCGCAAGATGGTTGTGTTTGTTTTTGTGCATGTGTGTGTAAAACATCTGTTGGAATGTTCATTTTAAACTACAAGTACGTACAAAAGTGTTTACCTACCGTATGCTCTATCAAATATTATATGCTACGAAGTTATGTTCAAGAGACGTTGAATACAGTTTTGTATGACGATTAGTCTTTTTGAACAGATAGTTAATTTGTTCAGATAAAGTGCCAAAACAGATGACAGAAAACAGAGGGAAAAAAAAACAATAGACACATAAACCCATATGAATTCTCGACGAAGTCTTTCTAAATTTGCTCGATCTTTTGTCCAGTGTTTATCATCCTCTCTTTAAGTGTGTAGCGGTTTTGTTTGTCTTTTCATTCTCACCCTACTTTTTCCGTTTTTGTTGCCTCGCCCTTTCCATCTTTCACAAAGGCACTTGGTGGTGCATGTGTTGTTTCCTTGGTGACGTCTCTCCCATGTGTTCACAGTGACTGTGGGCGTCAGGTCGAACCCTTTCCCCTCTAATGTTTTGTATTTTGAGCCGACTTTAAAAAGAGACCATTTTTTTAAATGGCGATGACTGCTACGAATCTCTTCATAAGTGTTTGTAATTTTATAGCTGTTGACAACGATGAAACCCACCTTCCGTCTTGCCGGTATAGGCAGAATGGGTGGAATTTTTTTTTTTTTTTTTTTTTCATATTTCTTGTTCATTTACATACTTTTTTTTTTTTTTTTTTTTTTTTTAAACATAGGCTTCCAGCCTTTCTGAATAATCACTGTGAACATGGGCTCTGGAAGGCAAGCGTACATCAGTTTTGCTGACTGTTTGATATCATCTTTTAATTTTTTCAAACAACTTTGATTCAAAAAATAAATAAATAAAAAAATGGCAGTTATATATAAAAAAAACTTTCATACAAAAGCAATCCATGATCTGTATGAAAATCAGTATATACTATGTACACGTGTTACATATGTACATGAATTATGTTTTTAGTTTTGCTAAATCATATCTGATTGTTTATGGGCCGGTTCTGAATTTAATTTGGGATGATCTTTGTGAAGTTGTTTTATCTGATATGAAATTTGTAAATGTTGCTTTACAAAAAAAGGTAAATCAATCGCCGTCATTTCATTTATTTTTGTTTACAGAGGAAAAAGTTTAACATTTGGTATTTATGCAACATTCCTATGTATTGCACTGATGGCAAATTGTATGTCATGTAAATATATTTAGTGAGATATTGTAATGAAAGTCTCGTTGTATTGCATTTTAATCAAGGAAAGCAACCTTTTCACACATTACACTTTTATAGTATGTATTAGTGTTGGATGTAATGCAATTACAAAATAATTAGTTACTATAATCTAATTACATTTTTAGTCAAAAAAGTTATGTAACATTACATTTAAAATTGTTTTAATCATATTACAGTTGCTAAATTTCAATTAAGTTCTAAAGACATTACTTAGGTAACACATATTGCTAAAAACATTTACACGGAATGAATTTAAAGGAATATTCTGGGTTCACTACAAGTGAAAGGTGCACTTAGTAACCTTTGTCTTTGTGTCTTTGTCTTGGACTTACACTGACACCTAGTGGTGTGGATGCAGCATCGTTTAAAATCAGTAGTTTTCAGTTTCAGATGCCATTGTAGAAATTTAGTATTCACAGTCAGCCATGATTACTTTAATCAATGAGTGAAAGTGTCATATTACAGGATGGTTACTGAGATTAAGCGAGTAGCATTCGGCTGGTCATGTGATACTAACATGGCAGCCCCCATGTGCGGACCCTCTCCATGTAGAATAAAACAGCTTTTATAAGCTTACTGATATAACTTGAGTCTCCATTTTAATGTGAGTGGTCATGATTTCCTACATATATTGCACAATTACAATTCATGTCTTTAGGAATTAAACTTTTTAATGAGGAAAAAATTACTGAGTGCACCTTTAAGCTCAATCAACAGCATTTGTAGCATA
->XR_003260173.1 PREDICTED: Dromaius novaehollandiae ADAM metallopeptidase with thrombospondin type 1 motif 6 (ADAMTS6), transcript variant X8, misc_RNA 
-CGAGGCTGCCAAGGCTCCCTGCTGCCGCCGCGCTCGGCTTGGCCGGGGGCCGGCAGCGAGAGGAGGTCTGGGGCTACTTCAACCAAACTTTCCTGAGTCCTTCCTGCTCTGCCTGCCTGTCTTCCCTTTCCCCCTTTCTCTCGCTCGCTCGCTCTCTCTCTCGCTCCCCCCCCTTCCTCCCCCCCAACTCAGATGATATTCACATGGTATTTTGCACAGAGGAGGCTGTTCAAGAGGAGGGCACCCACCCCCACCCCAATATAAGCCTGTTTTTCCTTCCTTCCTTCCCCCCCTTTTTTGTTGGAAAGACAAAATGTGCAGGGTGATAGGTTGGGTGAATTGATGGCATCCCTCCTCCTGCCAAGTCAGTCCGTTTTCTAAAACCCCCTTTTAGGAAGGCTAGAGAATTTTATTCTGTTGGAGAATATAACCCTGATGGTTGCTTGCACAGAGGGGAAAAGCAGAGAGGAATACGGGAATCGTCCTGTGCAATCTCTATTGTTTGAAACTTACTTTATATCAGAAATTGAAGATGAAAACGGGAAAGAAATGGAGAAAATTCACTAACTGCCAAGTCTAACGTCTTACAGATAACTTAAGGAATTTTACAAATGCTTATTTTTGCGTTGAGAAAATGACTGCTGATATAGAAGAAAGTATAGGTTGTTGGAAAAGAATACCTGTCAAAAAGTGGAACGTCCAATAGTTAATTTGGGAGTAATATAAATGTACTTGTTATGGTGCGATTCTGGAGTGGAGTTAACTCTATAGCACACAGGTAGCCCTCCAAGGAGAAGAAAAAAAAGCTTTCAGTTTTTCTAAATTATGGAAGTTTTTTGGAAGACGTGGACATGGATTTTGAGCCTAGTCGTTGTTTCATCGGAATTTCACAGTGACAGCAGGCTTTTGTATAGTTCTCAAGAGGAATTCCTGTCTTACCTTGAACACTACCAGCTAACAATCCCAATAAGGGTTGATCAGAATGGAGCCTTCCTCAGCTTTACTGTGAAAAATGCTAAACCCTCAAGGAGGAGGAGGAGCACAGACCCTTATGATCAAGAACTGGCAGCATCTAAATTATTTTTTAAACTTTCTGCCTATGGCAAGCACTTTCATTTAAACCTGACTCTCAACACAGATTTGGTATCCAGACATTTTACAGTAGAATACTGGGGGAAAGATGGACCTCAATGGAAGCACGATTTTTTAGACCACTGTCATTACACAGGATATTTGCAAGACCAACATAGTACAACTAAAGTGGCCTTAAGCAACTGCAATGGTCTGCATGGAGTTATTGCTACAGAAGATGAAGATTATTTTATAGAGCCTTTGAGGAATGTAACAAAAAATTCCAGTAACTTCAGTTATGAAAATGGTCATCCTCACGTTATTTACAAAAAGTCTACCATGCGCCAGCAGCATCTCTATGATCATGGTCGCTGTGGAGTCTCAGAAGACCTCACAAGAAGCAGTAAGCCTTGGTGGATGAGTGATGCATCTGCTTTTCCAACTTCACTTCCAGTCAATGACACATTAAGTAGTCACAGTCGGCAGAAGAGATCAGTAAGCCTTGAACGGTTTGTGGAGACGCTGGTAGTAGCAGACAAAATGATGGTGGGATACCACGGTCGCAAAGACATTGAGCATTACATTTTGAGTGTAATGAATATTGTTGCCAAACTTTATCGTGATTCCAGTCTAGGAAACGTTGTGAATATTATAGTGACTCGTTTAATTGTCCTCACTGAAGATCAGCCAAACTTGGAGATAAACCACCATGCAGACAAGTCCCTCGATAGCTTCTGTAAGTGGCAGAAATCCATTCTCTCCCACCAAAGTGATGGAAACACCATTCCAGAAAATGGGATTGCCCACCATGATAATGCGGTTCTTATTACTAGGTACGATATCTGCACTTACAAAAACAAGCCTTGCGGAACACTGGGCTTGGCCTCTGTGGCTGGAATGTGTGAGCCTGAAAGGAGCTGCAGCATTAATGAAGACATTGGCCTAGGTTCAGCTTTTACCATTGCACATGAGATTGGTCACAATTTTGGTATGAATCATGATGGAATTGGAAATTCCTGTGGGACCAAAGGTCATGAAGCAGCAAAGCTAATGGCAGCTCATATTACAGCAAACACCAACCCTTTCTCTTGGTCAGCCTGCAGTCGGGATTACATCACCAGTTTTTTGGATTCAGGCCGTGGTACTTGCCTTGATAATGAGCCTCCCAAGCGTGACTTTCTTTATCCAGCTGTGGCCCCAGGTCAGGTGTATGATGCTGATGAACAGTGTCGCTTCCAGTATGGAGCAACATCCCGCCAATGTAAATATGGGGAAGTGTGTAGAGAGCTCTGGTGCCTCAGCAAAAGTAACCGCTGTGTTACCAACAGCATTCCAGCAGCTGAAGGTACTCTTTGCCAAACAGGGAGCATAGAAAAGGGGTGGTGTTATCAGGGAGAGTGCGTACCTTTTGGCACTTGGCCCCAGAGCATAGATGGGGGTTGGGGTCCATGGTCAATATGGGGAGAGTGCAGCAGGACCTGCGGGGGAGGAGTCTCCTCGTCTATAAGACACTGTGACAGTCCAGCGCCTTCAGGAGGAGGAAAATATTGCCTTGGAGAAAGGAAACGGTATCGCTCCTGTAATACTGATCCGTGTCCTTCAGGGGCCCGCGATTTTCGAGAAAAACAATGTGCAGACTTTGATAATATGCCTTTCCGAGGAAAGTACTATAACTGGAAACCCTACACTGGAGGTGGGGTTAAACCATGTGCATTAAACTGCTTGGCTGAAGGTTATAATTTTTACACTGAACGTGCTCCTGCAGTAATAGATGGGACTCAGTGCAATGCTGATTCACTGGATATCTGTATAAATGGAGAATGCAAGCATGTAGGTTGTGATAACATTTTGGGGTCTGATGCAAAGGAAGATAGATGTCGTGTTTGTGGAGGAGATGGGAGTACATGTGAAGCCATTGAAGGTTTCTTCAATGATTCATTGCCCAGAGGAGGCTATATGGAAGTGATTCAAATTCCAAGAGGTTCTGTGCACATTGAAATAAAAGAAGTGGCAATGTCGAAGAACTACATTGCTTTAAAATCTGAAGAGGATGACTACTATATTAATGGTGCCTGGACTATTGACTGGCCAAGAAAGTTTGATGTTGCTGGAACAGCTTTCCATTACAAGAGACCAACAGATGAACCTGAGTCTTTGGAAGCCCTAGGCCCTACATCAGAAAATCTCATAGTCATGATTCTGCTACAGGAACAAAATTTGGGTATAAGGTATAAATTCAATGTTCCCATCTCTCGCACTGGCAGTGGAGACAATGAAGTTGGCTTTGCATGGAATCATCTGCCTTGGTCAGAATGTTCTGCCACTTGTGCTGGAGTGGCCACCAATGCAATTCTTTACCTCTGGCTGGGAGAGCAGGACAGTTGGCTTCCTTCAAAGCCAACACCATTGCTGCTGCATGGACTGGTGTGCAGAAACAAGAGGTGGTGTGTAAAAGGCTGGATGACAACTCCATTGTGCAGAACAATTACTGTGATCCAGACAGTAAGCCTCCAGAAAACCAAAGAGCCTGCAACACTGAGCCTTGTCCACCTGAATGGTTTATAGGAGATTGGTCAGAATGCAGTAAGACCTGTGATGGAGGAGTGCGTTCACGAACAGTTCTCTGTATCAGAAAGATTGGACCTTCTGAGGAAGAGACACTGGAAAATACCAACTGTCTAACGCACCGGCCTATTGAAAAGGAGCCCTGTAACAATCAGTCCTGTCCCCCCCAGTGGGTTGCTTTGGACTGGTCAGAATGCACGCCAAAGTGTGGTCCAGGATTTAAGCACCGAATTGTTCTGTGCAAAAGCAGCGATCTTCTAAAAACTTTTCCAGCTGCTCAATGCCAAGAAGAAAGCAAACCTCCAGTCCGCATCCGCTGTAGTTTAGGTCGATGTCCTCCTCCTCGCTGGGTTACTGGAGACTGGGGACAGTGTTCTGCACAGTGTGGTCTTGGGCAACAGATGCGAACAGTACAGTGCCTCTCATATACCGGACAAGCATCCAGTGAGTGTCCAGAAACACTTAGACCTCCATCAATGCAACAGTGTGAAAGCAAATGTGACAGTACTCCCATTTCCAACACAGAAG
->XM_009065832.1 Lottia gigantea hypothetical protein partial mRNA 
-TTTCACCAATGGTTTTCTAATTTCCATGGTTATGCCAGTATTATAGTGTGTATATTTGGCATCAGCACCAATATATTCAATATATCTGTTTTAACACGAAAAGATATGAGAACTCCTACCAACATCTTGCTGACGTGGTTAGCTGTGGCTGACATTTTAACGATGGTGCCATACATTCCGTTTGCCATTCACTTTTATTGTCCGAATACATCACCATTCGAGACTCCTGAGAAATACACGTATAATTGGATACTTTATATGATCTTCGTAGTCAATAGTGCCGCTACAACTCACACTATTTCTAATTGGTTGGGTGTTTCATTATCAGTGTTCCGCTTTATGCAGATGAGATCAACGAGTCGAGGCGTTCTAGCCAAACAACGTCGCTTAAAACATGTGAAGGTAATAACCGTGGTTGTGTACATTTTCTCAATCATTGTTCTAATTCCCAACTATCTGACTAACAAAATCCAATCAGTTCAAGGCCCGCGTAATACGACCATATATGGATTAAAAGACATGACACCGAAAGATCCCAGCACCGACAAAATGGCTTTGATAAATACTTTACTTTATGCAGTGGTGGCTAAAATTGTACCGTGCCTTTTAATGTCTATATTTAGTGTGTCTTTAGTATATACAATACATTACAAAAATCGACATCGCATGCGCAGGCTTGTGGCTGCTGGGAAAAAATCGAGGGCCATCTCTAAACAAACAACTACAACCCGAATGTTACTAGTTGTTATAGTCTTGTTTCTTATTACCGAACTTCCACAAGGCATTCTTATTCTCGTTACAGCTGCCATCCCTCAGTTTCATAACAACGTATATAACCTTCTGGGTGATCTAATGGATTTTATTGCCTTATTAAATAACGCAATCAATTTTGTGCTTTATTGTAGTATGAGCCAGCAATTTCGCTCCCGGTTCATTGAAATGTAC
->KU027247.1 Uncultured microorganism clone SZY.L801.1_Tag26405 16S ribosomal RNA gene, partial sequence 
-CAGCCGCCGCGGTAATACGTAGGGGGCGAGCGTTACCCGGATTCACTGGGCGTAAAGCGGGTGTAGGCGGCTCGGTAAGTCGGGTGTGAAATCCCACAGCTCAACTGTGGAATTGCGCCCGAAACTGCTGAGCTTGGGGCCGGTAGAGGGAGACGGAACTGCCGGTGTAGGGGTGAAATCCGGAGATATCGGCAGGAACGCCGGTGGGGAAGCCGGTCTCCTGGGCCGCGCCCGACGCTGAGACCCGAAAGCTAGGGGAGCAAACCGGATTAGATACCCGGGTAGTCCTAGCCGTAAACGATGCCCACTAGGTGTGGGGGATTAATTCCTCCGTGCTGGAGCTAACGCGTTAAGTGGGCCGCCTGGGGAGTACGCCCGCAAGGGTGAAACTTAAAGGAATTGGCGGG
->XM_042244958.1 PREDICTED: Ovis aries caspase 8 (CASP8), transcript variant X4, mRNA 
-AAAAGTAAACTTCTTCCTGGAGGCGTTTCCAACCCCACCTCCTGTCTCCCCCTCCCGCTTGCCTCATTTCCAGGGATTTATCTCCAGCTGGGTTTTAAGAACGAGCCTCAGTAATACGAAGTGTGAAGTTAGGCAGTGTGGGGTCTTGTCGTCGAGAGTTTGGTGGCTGGGATGTTGCCAGGACTGTGTGGAGCAGGTCCCAGTCCATGGTGAGGGCCCTGGGATTTTATTTTTCCTTTGATGTACTGAGAGAAGAGGCCCGTGAAGTGGCTGCTGCTGTGAAGGTTCCAGGATTCGCCTCTGGTAACAACTACATTCTCCTAACACTTGAAAAGCATGGATCTCACCCAATGTCTCTATAAAATTGGAGAGCAGCTGGGCAGTGACGACCTGGCTGCCCTCAAGTTCCTAAGCCGGGACCACATCCCATATAGGAAGCAGGAACCCATTAAGGATGCCTTGATGCTATTCCAGAGGCTCCAAGAAAAGAGAATGTTGGAGGAAAGCAATCTGTCCTTCTTGAAGGAGCTGCTTTTCCAAGTGAATAGACTGGATCTGCTGCTTAACTACTTGGACACCAGCGAGGAAGAGATGAAGAGGGAGCTTCAGATACCTGGCAGGGCCCAGATCTCTGCCTACAGGATCCTGCTTTTCCAGATTTCAGAAGATGTGAACAAAGTGGAATTGAAGGACTTTAAGTTTTTTTTGAGCCAGGAGATTGCCAAATGTAAGCTGGATGATGACATGACTTTGCTTGATATTTTCGTGGAGATGGAGAAGAGGACCATCCTAGGGGAAAATAACTTGGACACCCTGAAAAGAATCTGTGAGCAGGTCAACAAGAGCTTGCTGAAGAAAATCTATGATTATGAAGAATTAAGAAAAGATATGTCACAATCGCTTCCAGAGGAGGGCTCCTCTGAGATGCTGGCCATGTCAGACTCTCCAGGAGAACAGGGCAGTGAGTTGCAGACATCCGACACAGTTTACCGAATGACAAGCAAACCTCGGGGATACTGTTTGATCTTTAACAATTATGATTTTAGCATAGCACGGGAGCAGGTGCCCGAACTTCACAGCCTTAAGGATAGGAATGGAACACACTTGGATGCAGAGGCTTTGGACAAGACCTTTCGTGAACTTCATTTTGAGATAGTGCACTACAGAGACCAAACAGCAAAGGGAATCTGTGAGGTTCTGAAATCCTACCAGAAGAAGGACCACAAAACCAAAGACTGCTTCATCTGCTGCATCCTTACCCATGGAAACAAGGGCACCATCTATGGCTCCGATGGGCAAGAAGCCCCCATCTATGAGCTGACCTCCTACTTCACTGGATCAAAATGCCCTTCCCTTGTCGGCAAACCCAAAATCTTTTTTATTCAGGCTTGTCAAGGGGATAAGTACCAGAGAGGAATAGCTGTTGAGACCGACTCAGAACAGAGGGAAGCCTATTTAGAAGCGGATTCGTCACCTCAGAAGAGATATATCCCAGATGAGGCTGACTTTCTGCTGGGGATGGCCACTGTGAACAACTGTGTTTCCTACCGAAGCATCGTGAAGGGGACCTGGTATATCCAATCGCTTTGTCAGAACCTGAGAGAAAGATGTCCTAGGGGTGAAGACATTCTGACCATCCTAACCAAGGTGAACTTCGAAGTAAGCAAAAAGGATGACAAGCAAAACATGGGCAAACAGATGCCGCAACCTACTTTCACACTGCGAAAAAAACTCTTCTTTCCTCTTAATTGATGCTATTGTTTAGTTGTATAACTAGACAATAGTTATGCAACTGAACAATAGTTAAAATGCTGCTACTTTATTCTCTTTCTTCTTCTTTTTATTTTCAAATAGCTGGCATATCATGAGAGTCAGGACAACATAATTTTTATGCAAATTCAAGCCTAAATCTCTGGCTTTGTAGACAATAACAGTCATAGCTGTGGTCTTGATTTCAATTGTATTTTTAATTTGATGAAAAGGTTTAAAAATGAACTAAAATAAACACAAAAAACACAGTAAGTTTAAAAGAAATATCAAAGATCATGGAGGGAGATTTTTGTGATCTGACCTAGCTGAAAAATCCCCTCGACTATTGAGGTTCAGGGTATAAAGTTCCCACATCCAGCCTGATTGCTACTGATGTGTATGATAAGCTGTCCTGGAAACATGTGACCCTCCTCTCCTTAGCCATGAGCAGACTCTGATTTTCAGTGGTGAAAACCACCACTCTTTAGACTTCAGTTTCAAAAGCTTAGAGATTATTTTCCTTTTTTAAAAGAATTATTCATAAATGCGGCATTCAACATACTTTTAAGAGAAATGATGTTAATATTAACTCGTTTTATACTTCCAGTAGATCTTTTCCCAAGCTGTCCTTTATACTAATTTGCAATATTTTGTAAAATAAAAAAATTTTAAAATTCATATATTAAAGATTTTAAAAATACCAAATGATTTTGTTTTTTAAAGACTCTTTCCAAACTGAAAAGTTTTTATATACATGCTTCTGCAGTGCTGAACATGATTTGCTTTTTTACTAAAAATGCAGTATGCCTTTTATATGTTTGCTCTTTCTTTATATGTTCAATTCACTTTAAATCTTTAGTAATTAATAATTAGTAATGTAATAAATATTTTTAACAGAATAAAATATAATTTTATCATA
->XM_012896071.1 Acytostelium subglobosum LB1 hypothetical protein partial mRNA 
-ATGGACCCTCAACAACCTACACAACAACAACAACAACAGAATGGTGGTGGCGGTGGTGATACATTGTCAGCAGCAGTGGCAGAGTTGGATAAGCTAGAGTCATTGTTGGCCAGTGGTTATCTGTCACGTCCATTCTCTGTGGATGTGTCAAAACAACAGCAACAGACGAACAAGTCGACGACGAACGAACCAGCAGCAAAGCAGACACCTGCACCTACACAAGCAGCTCCTTCAAAGCAACAACAGCAGACTTCATTGCAGACTGCACAGCTTACACAATTGCTTCAATCACAAGTGCAGGCACATCAACATCAACAAGCAGCAGCAGCAGCAGCAGCAACAGCACAGGTACCACCTGCAGCAGCAGTAGCAGCAGCAGCACAAGCTCCACCTGCTGCTGTGACTCAGCCACAACCTCAAGCGCCACAGCCACAGGCTACAATTCAGATTGCAACTCAGGCTCAGGTGGCCCCAACACAATCGCAACAACCTCAGACGCCACAGCCACAGGCAGCCAAGCCACAGGCCACTCAGGTTCAGGTGGCCCCAACACAAGAGTCACAGCCACAGGCAGCCAAGCCACATCCCACCCAGACACCAGCACCCCAGACACAGGCTCCTAAGCCACAGGCCATCCAACCTCAGGCTTCACAAACACAAGCACCTCAGCCTCAGGTGCCACAACCACAGGCTGCACCGGCACAGGTGACTCAGTCGTCTGTGACACCTAAGCCTCAGGCTGCTCCTGCTACACAACCCCAGCCACAACAAACTAAACAGGCAGCTCAGCAACAGAAGAAACAGGCGCAACCAAAACAGAATGATGTCAAGGACACATCACAGGTTCCGAAGACACAGCCTCAACCTCAACCTCAGGCGCAAGCTACTCCACAGGTAGCACAGCCTCAGACACAACCTCAGTCACAGCCCCAAACAAAGCCTCAGACTAAGCCTCAGAATAAGACTCAGACCAAGCCTCAAGCACAAACAAAGCCACAATCTCAAACTCAGCCACAGACGACACAGCCTCAGCCACAGGCTCAGGCTCAGCCACAGACAACACAACCCCAACCTCAGGCTCAGCAACAGACGACACCACCTCAAACACCACCTCAGGACAATTTGGAAGAAGATGTACAACGATATGATGATGACGATAACAACAACAACAACAACAATAGCAAGGAGTTGGAACTTTTGCAAGAGTTGGAAGAGATGGAAGCAGAAGTAATGATGCTGAGGCGAAAGGAATATCTCTCAATGTCAGGCGACATGAAACGCAACGAATCACTGCTGTTCCTCGAGCGCAAGGGTTTGGTCAAGGAGATCAGTGCCAAGTTCCAGACACCCGACACAGCCTCCTTCACCAAGTTCAATCCCAACACACATCTCTCCATCAAGGAGAGAATCCTGCACTTGAAGCGAGAGAATGAGCGCAGGAGCAAAGAGGTCGAGGCCATCAGACGAGAGACTGTCATCCAGCTCGCAGACGAGGACGAGACATCGACGATGGACTCGCCAACAAGCAGTCTTAGGGAGAGAATATACAAGTCTGTGTCCGAGCCACTCGCGCCACAGGACCCAAAGAAGACATCGCCAGCCGATGGCCACAAGTCGACACAGGTGGCCACCTCAAAGTCCCGCGCTGCTGACCCCGTGTCACCATTGCTGTTGTCAACAACATCAACACCAGTCACCAAGCCCAGCGGCAAGGGTAGCAAGATCATCATTCGTAGACGAAGGAATGCTGCGGCAGCAGCGTCCCATGATCAGATGAGCATGATGGCGCTCACACATTATCTCAACATCCCGCCCAACCCTGCCAAGCCACCAATCACATCCAACACAGCCAGCCTAACACAGCCGACCAAGGACTTTATCAAGACGCTAGTGTCGCTGTCCGACACTGGCAATGATATCATCCTGGACACTTCGCTGCCCACGCCCAACAGCTCACCGGACGCAGGCACCGCTCCCGATATTCAGTACACGCAACTGCGTACCCGCGCCATGAAGGCAGCTTTCAACGTGCTCTTCACACTGCCCAATCAAACATCGGTGATCATGCCATGTCAGAACACTGACACTATCGAGGCCATCAAGGAAAGGCTTGTGCAGTACATGTTGAAGGCATTTTGTACTACTACTACTACCACCCCGGCCACATCAGATGCGGCCAATGGCGAATCATCAGAGACAGACGAGTCGGCCTCCAATCCCGCCACACCACCCTCCCCTCCCATCAAGATCATGCCCGAGAACTATGTAATTGTTGACTACTTCAACAAGCCTCTCGAGAAGTCAATGACCTTGACCAAGAGCGAATATATAATGCACAGGAGATCACGTGGATTGCAGCCAAAGCTGAAGTTGGTTGAGAAGGTCAACTTCTACGACGCCGATCCTTCAACGGAACTCAGTGAACAGTCATACGAGATCATCAAACAGATTATACCCAATGTCAAGAGTTGGCATGGAGAAGAAGTGGACTACTTCAGACGCATCGCTGCACGTCTGCGTTACGAACTGTTGCCACACATCAAGGGAACTGTTCACTCATCGCTCACTGAACGTCTGTCCCCACTGCCACTTCCAACGCCTCCCAACAACAACAAGTTCCTCGTCTCCATCTTCCTTCCCATCCTCCAAGTCACCAGAACTGTTGAGATTGAGATTAACGAGATAGCAGATGATGTAATCGCAAGGATATTCAATAGGAACTATGCCAAGCATTTGCCACCACAGGTTAGTGCAGGAGACTTCATTCTCAAGGTGATGGGACGATCAGAGTACATTCATGGCACACACAAGATAACTGTCTACGAGTACATCCGATCATGTCTGGTACAGAGCAAGAAGATACAACTCGTCTACGTTCAAAGACCAACCATTGAGATGGACATTGCACCATTCAAGCCAAGATTCAATCTATCCAAAGAGTTGCCAATCAAACATGAGGTTGGAGCACTGTCTCATCGCGCACTGCCTTGGGATCATATGAATCACATCTCTGTTCGAGACATCAAGCGACCATTTAGGATCAAGGTGGGCGGCGCCTACAACATCCCAACGAGCTATCTGAGCAAGGAGGACGAGAGCATATCGGTGATCGTGTCAATCTCTTTGTATCATGGTGTCGAGTGCATATCGACCTCGTCCACCAAGCTTCAGAACATACTCCCGCCATCATTCTATGCCACGCCACCCGCATCGCTCAACGCCACGTGGAATGAGAACGTGACCTTCTCCAACTTGGACTATGCCAACCTGCCAATGGAAACACGTCTCTGCATTAGTCTTTACGCGAGCACTTCGTTCAAGACTCCCACATCGCCCACTGCCGCCTCATCCAACACCGAGCTCGACCAACAGCGCAAGGAGTCCTTCCCGATCGGATGGGTCAACGTCATGCTCTGTGACTACAAGTCGCAACTGCGCACGGGCCCAATGACCCTGCATCTGTGGCCGGATGATGTGGCCAATCCCCTGGCGCCCTGCTCCAGCAATCGCCAGAGCGGTGTCGCGCTGTTCATCGAGTTTGAGCAGTTTGCGCTGCCGGTGGTGTTCCCCTCGTGCAACAACCGCGTTACAAGCACCCGTCCCCACACCATCAACCCCAAGGACATGGTTGAGTTCTTTGAATCGATCATCAAGCTCGACCCGCTCAGCGACCTACCCAAGGAGAAGTACCAGCATCTGTGGGCGTTGCGACACTACGCCACCCAGTATCCTCAGCTACTACCGCGTCTCATGCTCAGTGTACCCTGGACACAGCCATCGGCTGTGGACGAGATCCACGCACTGATCGACAAGTGGGCCATCCTGAATCCCTACGATGCACTGGAACTCCTGGATGCCAAACACGTCGATCGCAAGGTGCGCGAGTACGCCGTGCGCTGTCTCGAGTCGCTCTCTGAGGAGGGCCTGCAAGATATCCTGTTGCAGTTGGTCCAGGTGCTCAAATGCGAACCCTACCACGACTCCCCATTGGCACGCTTCCTCCTTCGTCGCTCTATACTCAACCGCACGACAGGACATCACTTCTTCTGGTATCTCAAGTCCGACTTGCACGTCACCAACATTGCCGAGCGCTTTGGACTCTTGCTAGAGTCCTACCTCCTCGCTTGTGGCACGCACCGCAATGAGATACAGCGACAGATACAGGTCATCGACAGCCTGACCGAGGTGGCCAGGAAGATCAAGTCGCTGAAGGATCAAGATCGTCGCGAGACACTAATGCGCGACCTCGAGCGCATCGAGTGGCCCAAGCGCTTCCAGATCACACTGAATCCTAAGTTCGAGTCGAATGGTCTCATCATCCAAAAGTCCAAGTACATGGACTCCAAGAAGCTGCCGCTGCGGCTCTCATTCACAAACATCGACATGGATGCCGAGCCAATCGATGTGATATTCAAGGTGGGCGATGATCTGCGCCAGGACATGCTCACACTCCAGATGATCCGTCTGATGGACAAGCTCTGGCAGAAGGAGGGTCTGGATCTCAAGCTGTCGCCATACGGTTGCATTGCCACGGGTGATATGATTGGAATGATCGAGGTGGTGCTCAACTCTGAGACCACGGCCAAGATCCAAAAGAGTGCTGGTGGTGCCACTGCCGCCTTCAAGCTGGATCCACTCGCCAACTGGCTACTCAATCACAACAAGACCGAACAAGAGTATCAAAAGGCTGTGGACACATTCATTCTCTCCTGCGCTGGCTACTGTGTTGCCACCTATGTATTGGGCATTGGAGATCGTCACAATGACAATCTGATGTGCACAAAGCTTGGTAGACTATTCCACATTGACTTTGGACACTTCTTGGGCAACTACAAGAAGAAGTTTGGATTCAAACGAGAGAGAGCACCATTTGTATTCACGCCAGACTTTTGTTATGTGATGGGAGGCAAGGAGAGCCCCAAGTTTGCCCAGTTTGTAAACTACTGCTGCACGGCCTACAACATATTGCGTCGTCACGCCAAGTTGTTCATGAACCTCTTTGCAATGATGGTGTCCACTGGCATACCAGAGTTGCAATCGATGGAGGATCTCAACTACCTTCGCGAATCATTCTCACTGGAGCTCACAGACGACAAGGCCAGGGAGAAGTTCACATCACTCATACATGAGTCATTGACAACAAAGACCACACAGCTAAACAACGCAATACACATTCTGGCGCATTAA
->XM_013042216.1 Blastocystis hominis mRNA 
-GGAGAACACCGCTCCTCAGACACGCGAAGAAATGTTGGCCGCTCTGAAGAAACAGATTGAATATTACTTCTCTAAAGAAAATCTATCGAAAGACTCTTATCTCCTTTCCCTCATGGATGATTCTGGCTATGTTCCTTTAAAGACAATTTCGCGTTTTCACAAGGTCCTTTCTCTTAGCAGCAATATTGACGATATTATGGAAGCCCTAAAGAGCTCTGAGAACGTCGTGGTGGACGAAGTTAGCAAACAAATCAAGCCTGCGATTACTTTTGAACGTAAAACAGTCATTCTGCGTGACGTCCCGGCCGAGGTTACCGAGGAAGAGGTCCGCGCCTTGTTCGACGGAATGGGCGTTGTCGAAAGTGCCACTAAAGAGTTTGAAGGCACGTGGTTCGTCGTGATGGAGTCGGAGGCGGCCGCCGTCGCGGCGCTGGAGCTGCTTCGCCAGCGTTCTCTCCACGACCAGCCCGTGAAAGCTCGTCTGAAGAACGAGTCGTACCTGAAGAACCTCGTGAAGATGCTGACGACCTCCGAGGACGGCATTCCCGCCGAATATCTCCCGGTGGACCAGTCGTACTTCATGAACTTCGGCGGCCAGCCCCTTCTGGACTTCCAGCAGAGCCAAATGTTCGGCCAGAACTTCGCCGTCCAGGCGCCGGCGACCGGCGTGCCCGCCGAGAAGCGCGGCCGGAAGGGCCGGAAGGAGTTCAAGCATCGCGAGCGTCGTCCGCGAGCCGTTTCGAAGCCGAAAGTGGTGCCTGCGCTGCAGAGCGCGGAGATTTTCCCGCCGCTGGTGCCGACGACCGCTCCGGTGGTGGGGTCGATCGACGTGAAGTACTCGTACAAGGAGATCTGCGACATCGTGAAGGGCGTGAAGGATCTGTCGTGCCCGCCGATCGCGTCGGCAGGCGTGGAGTCGGCGCTGGTGGAGACGGCCAACCAGGAGTTGGTGCAGAAGGGACGAACGTTCAGTATCGACCAGGCGCTGCAGCGAGGATGTCCGCGAACGATGTCGGTGGACAGCATCGACTACACGTCCATGCTGCAGGGAGAGATGGACGAGGCGGTCGCGGAGTCGGCTCGCAAGGCGCGGCGCGAGAAGAAGCGCGCGATGAAGATGGGCGAGCGAGGCGAGGCGCATGCTCGCAGCTACCGCAACATTCTCAAGAATTCCCCGCCCGTGGGTGAGGCGGTCGCTCCTTCGACGAAGCCTGCCGCTGTGCAGACAGTGAGTGGAGCCAATGCGGCTAATGCGGCTAATGCGGCTAATGTGGCTAATGCGACTAATGCTGCCAGCACTACCACTGGTGCCAATGCTGTGAGTCCTGTAAGTGGCACGAACGGAGCGGAGGGAAAGAAGGAAGGGAAGCAGCATACAAAGAAGTCGCAGAAAAAGGCGGCAGAAAAGAAGGCAGCGGAGAAGAAAGCAGCGGAGAAGGTGAAGAATGAGGAGGACGGATGGAAGACGATTACGGAGAAGAAGCATTAGAGACACTCATTGTTTATTCTTTTAATGTGTGGAAGAGTT
->XM_001589778.1 Sclerotinia sclerotiorum 1980 UF-70 hypothetical protein partial mRNA 
-ATGAGTAATCTCCTCTGGAAATATTACCTCGAAGATGACGTCGATAAATTTCGACGCCTACTGGCAAATACTGCCTATTCATCGCAGCATACACTGAAAAGTCATGGTGGAGGAGGGCCGGCATTCTCCAGCAGCTTTGGGAACAAAATAGGGAGTTCAGGCGGATTTGGAACATCACCAAAGACTTTCGGCAAGAACCGCAAAACACCCGGTCCAGCTGGAAACTCAAATGGGAATAAAGGACAGGGAAATGCGATCAGCAAGGCAGAATTGAATAGCAGAGATTATGCTGGGTTAACTGTCTTACACCGAGCTGCATCTTCGACATCTACGAATGCAATAATCTTTGCGACCTCTCTTATCGAACATCCTTCCATCGACCTCTATATACAAGATACGGAAAGTGGGTGGACAGCGTTGCATAGGGCTTTATATTTCGGCAACGTCACAATTGCTCGAGCAATTATCGAGCGAGACTCGAAGGATCGCGCCGCTGGAAATACAGGAGCTAAGCCGGACTCTTCGGTTATCAAGGTCAAGGATAGGGAGGGAAACACCCCATTTGATGTATACAATGCAACTATCGCAAGGCGATCTCTGCTAGACCGAGGAGAGCAGGGAGTACCTCACCGTTCAGATGATGATTCTGATGAGGAGTTATTCGATTCACCGTCGAGCGAATCGTCAAAGTTCAAAAGTATCGATGGTGACGAACTTTATGCATTTGGTAGTAACAAGAACTTTTCATTGGGTTTCGGTGATCAGGATGATCGTCAGTATCCGGAGAAGATAACGCTTAAACGTCCTGACCATTTACTCTTTCGATTTTATCAAGAATACTTGGACTCTGTCTATGATCATAACCCTATTGGAAACCCAAAAATGCCCAAGACAGTATCTGAACTTCCTTCCATGATTCAAAATAAGCCCATCATCATACAAGATGTTGCTCTGTCCAAACTTAGTAGCGCTGTATTAACTACGGATCCGGAATCAAACCTTTACATGTGTGGCTTTGGCCCTGGAGGTAGATTAGGCATGGGGGATGAAACCACTCGTTTCAATTACGTGCCAGTAGATCAAGGCGGTTTGGCAGGAAAGAAGGTCGTAACTGTTGCTTTAGGTCAAAATCATACGCTTGCAGTCTCGTCGGAAGGAGAGATTTTCAGTTGGGGTACAAATACTTGGGGTCAATTAGGCTACAATCTACCTCGACCTGCGCTGAAGGATGAAGAACCACTTTGTACAACCCCGCGCCAGATATTTGGACCTCTGAAAAGAGAAATCATTATTGGCATAGCTGCATCTGCTATTCATTCAGTGGCCCACACGTCTACCTCATTGTTTTGCTGGGGAAAGAATGAGGGACAATTGGGTCTTATGGACTCTGACTCACGATCTTTGGAAGCTCAACCAATACCTCGCAGAGTTGCCGCATCTTTATTCAAGTCATCAATTGTAAAAGTTTCGGCCATTAGTGGTGCAACTATATGCCTCTTGGCAAACCATACAGTCTGTGTTTTCACGAATTATGGTTACAACATGGTCAAGTTTCCGTTGTATGAGGGCTTCACAAACTATCATTTACAAAGTACCTCGCTCACGACTCGATATGACTCAGAGTCAAATAATATCACTACTATTGAGTCTGGCGGAGATACAATTGCGGCTATATCTGGTAGAGGTGACTTGTTTACCTTCAATGTAAGGAAAATTGATACAAAAGTTGCGGCGGCTTCTACAACGAATCCCTCCAAAATTAAAGATGCTTTATCACAGCCGCAGCGAGTCTGGTCACTTCGCAAGGGTAATTGGGATGGAATAAAATCTGTTGGTGTCGCCGAGAATGGGTCCGTGATAGTTTGTACTCAGGCTGGAGCGGTTTGGCGACGCATCAAAAGAGCTAAGAATAAGGATGCTTTCACTGGGATCAGTGGTTACGACCGGAAGGATTTCAAATTTCAGCGGATCCCGGGACTTACTAAAGTAGCTGCTGTCAGAAGCAATCCTTTTGGTGTGTTTGCGGCCATCCGTAAGGACTGTGATGTGACCAGGACTCAAGTTGCAGTTGAAGATAAGACATTGTGGGATGATATTGCACCTTTGCTAAGTATCCGAGATCTTGTAGCTTCGGAGCATCCAGTAGAACAGGCGGGAAGTCTAGTAAACCCTCGCCTGGCAAATTTGGACATCGAATATGGCCCTGTCCTCGCGGCACTGATCATGTCTCCGGACATCGAGGAAGATGTCCAAGGCTTGCTCATGGGAGTGGATTCTGAGAGTGGTGGTTATGATGTTGAGATATGTTCCAGTACATCTGACATCGCAATACCTGTCCATGGCTTTATGCTGGCAGCTAGATCATCTGTCTTGAGATCACTTCTTGCCGACTCTCATGCCAACGGAACCACTTCACTGTCTAATATCCTCAACATTGAAAATAGTACGGGTGGTAAAAAGAGAATTATCTTTAACGGCATAGATTTTATCACCCTTGTCAATTTCGCTATCTTTCTCTACATTGACAAAATTGCTGATGTTTGGGCCTTCGCGAATTATCTCCCGAATATGGCCTTCAGACTGAGGCAGGTTAGGATTGAAATCATGAAGCTTGGTTCTCATTTAAATATTCCCTACCTAACTCAACCTGGACTTGTCAGAAGGCCCTCAGACAAATTGAACTCTGACATGGACAACGCTATTACAGACGAGAAATTCTTCGATAATTGTGATGCTATTGTTGAGTTGGATGGAGGAGAGATGCCTATTCACAGTGTGCTTGCATGTCAAAGATGTCCTTTCTTCGATGGTCTATTTAATGGTCGATCGGGAGGTCAATGGCTTGCTGGTAGACGCGCAAAAATCACAGATCCGATCAGCATCGATTTGAAGCATATTTCGCCTGATACCTTCGAACTGGTATTGCGTTATATATATGCGGATGTTGGACCTGAGCTTTTTGATGATATCGTCTCCACTAATATTGATGAGTTCTCGGAAATAGTTATGGACGTCATGAGTGTTGCGAATGAGTTGATGATTGATAGATTGTCTCAGATCTGTCAACAAGTGTTGGGTCGTTTTGTCAATACTCGAAACGTATGCAATATCATCAATGCCGTGGCACCTTGCTCAATCACCGAACTTAAAGACGCCGGCCTTGAGTATATGTGCTTGCAGCTGGAGTCAATGCTTGAGAATCGTTTACTTGATGATCTTGATGAGGACCTTCTCCTTGAATTAGATGAAGTCGTGCGTGACAATCAATTGAATTGTCTTCCATTCGCCAAAAGTGGACGAGCTGATCTAGATTTGCACGAGAAATATCCTGAATTGGCGGGGGACATTGATGAGGAAAGACGTCGCAGACTTGGAGATATGATCTTCCGTGCTCATCTAAGAGATGATGATAATCGAATATCTTCATCTTTCAAGGCACGTATGGGGAGTCTTGATGATTATTTACCCTCTCCAAGTAATGATAAAGCTAGGAGGAAATCAAGGGTGGTCAAGAACGAACCATTTAGCCCAAGTGTACGTCCTAAGGATGCAGCGGCTGATTTCATGTTTGATATGGATGACGATGAAGAGCCTGGTAGTCCACCTGAACTGAACTTGACTAACGACCTAACTTCTGCTTCCCCTGGTGGTCCAGTAACTCCAAGGTTCCCTACAACTGGTTCGACGCCTAAGGTTTTCGAGTCAGGATCTCCTACGGACTTTCGAAATTCTGTCGGATTAGGAATCAATCACAATCCAGACACCCCTCAAACTGGAAATAAAACTTGGTCTTCTCCTAATCTTTTAGTCAAGCTGGACATGAAAGATATTATGGCCCAAGCATCAACGAACCGTACTTCGAATTTATCAATGAGTCTCTCAGCTCAAAAGGCCAAGGATGAAGCGAATGCCAAATCATCTACCCCAAAACTTTCACAGAAAGAACGTAAGAAGCAACAGGCAGCTCTTCAACAAGCAATTGCACAAACTCCTGTGAACAAGGGTAAAGACAAGGCATCTTCTCCTTGGCAAATTGCAGGTGTGGGTTCAAAAACGAACCTCAAGGATATTCTTGATAAGGATAACAAATCTTCACCATCATCCTTAGCACCAAACCCAACAACCTCACCAGCTATCTCACCTTCAAGTACTACTTCAACTATACGTCGAGTCACGGCGCCAGATACTCGATTTGCTGGTCAAAAAAGGAATGATAATAACAGCATCACGAAAGCACAAAGATCTTCACCTGGTCCATCAAGGCCAAGCTTGTTAACACCAAGCAAATCGTCTCCACTTATTCCTCATTCGAAATCATATACAGCGCCAGCAGCGAAAGCCGAACCGTCACTACAGTTATCCATGGCTGATATCATAGGAATGCAACAAAGAGAGCAAGAAGTGATTAAAGAAGCAGTTGCAAAGCGAAGTCTTCAAGAAATTCAAGAAGAACAAGCATTCCAAGAATGGTGGGATCAAGAGAGTAAAAGGGCTCAAGAGGAAGAAGCTTTGAGGGCAAAGGCTTCTACTGGAGTTAGTAGAGGTGGTGGTAAGTCTGGTGGTGGTAGAGGAAAGGGTGGACCGAGAGGGAGAGGTGGAAGGGGAAGAGGTGGTGGGGAATCTGTTAGGGGTGGTGGTGGCGGAGGAAGGGGAAGAGGAAAATCTCAGGAAAAAAGTACTGGCGCGAATTAA
->XM_051905607.1 PREDICTED: Ctenopharyngodon idella intraflagellar transport 88 homolog (LOC127518647), transcript variant X2, mRNA 
-ATAATTCGTTGGATTTTATCCCAGACGTTTATACGTATATTTAGAAATGTAATGTTAAAAGACAATATATAAAGACACGAACATAATCAATGTAATATCGAAACATTGTAAAATCTCTCTTGTGTGCCTAATGGCAACCCCTCTTTGTATCCTAGCAACCGATGTGTTGCTCAGCTTAGTTAGCGAGCTGTAGGTGCTGCTAGGCTACAGACACTATTTTTCGGAATATTTCAGCTTAATACGGCCATTAATTTGCATTTTTCTTAGATGGAGAACGTGCATCTTGTTCCAGAGGAAGAGGAGGATGATTTGTATACAGGCTACAATGATTACAATCCGACTTTTGACTCAGAGGACCTTCACAACGATGTGGGCTTTCAGCAGGCTGTCAGGACAAGTCATGGCAGAAGACCACCAATGACTGCAAAATATCCTGGCACTGCTATTGGAGGGCGACCGATTGGAACAGCTTATGGGTCTCGGATTCCTGTTGGCACTGCAATGGGAAGGCCTATGACTGGAGCTGTTCAGGACGGTGCGGCTCGTCCCATGACTGCAGTGCGGGCAGCAGGATACTCTTCATCTATAGCTAGAGGCTCGGTGTTTGATCCACTGGGACAAGCAAAAGGACCAGCCCCTCCATTAGAGAGACAGAACGAAGACACGCCAGAGGAAAAGATAAAGATCCTGGAAAAGAAGGTGAATGATTTGATAGAGGAGAGCTGTCTCGCTCATGCTCGTGGGGATCTTCAGCTGTCTCTAGAGAAAGCCAAAGAGGCGGGCAGGAAGGAAAGGGCTCTGGTGAGACAGAGAGAACAAACAGGCACTGCAGACCACATCAATCTGGATCTGACCTACTCTGTGTTGTTTAATTTAGCAAACCAATATGCCAATAATGACATGTACACTGAGGCCTTGAACACATACCAAGTCATTGTGAAGAACAAAATGTTCAATAATGCTGGACGATTGAAAGTTAACATGGCAAATATCTATTTCAAGCAAAAGAATTACACAAAAGCAATCAAATTTTACCGCATGGCTTTGGATCAGATCTCAAATGCCCACAATGCAATGAGGATCAAGATCATGCAGAACATTGGTGTTGTGTTCATACATATGGGCCAGTACTCAGATGCCATCACATCCTTTGAGTACATCATGAGTGAGAGTCCCAACATAAAGACAGGCTTCAACCTCATCCTGTGCTACTATGCCATCGGAGACCGTGAAAGGATGAAGAAAGCTTTTCAGAAGCTCATTTGTGTGCCCCTCGATATTGATGATGAAGACAAGTATATCCCTGCAAATGATGACTCTCATGCAAACATGGTGATTGAGGCTATAAAGAATGATAAGCTTCACCAAATGGAAAGGGAGAGGAAAGCATTAGCAGAAAAATACATTATGACCTCAGCCAAGCTTATTGCTCCAGCCATTGAGTCGTCATTTGCAGCTGGGTTTGACTGGTGTGTGGACATGGTGAAGGGTTCACAATATGTGGAGCTTGCAAATGACTTGGAGATCAATAAAGCTATTACATACTTAAGACAGAGGGACTTCAAACAGGCAGTGGAGACGCTAAAGATGTTTGAGAAGAAGGACAGTCGGGTAAAAAGTGCCGCTGCCACTAATCTATCTTTTCTCTACTTTTTGGAAAAAGATTATGACCAGGCTGACCGCTATGCTGAGCTGGCCATGAGCGCTGACCGCTATAACCCTGCTGCCCTCATTAACAAAGGCAACACAGTGTTTGTGAAAGAGGACTATGAGAAAGCAGCAGAGTTTTACAAGGAGGCTCTTCGTAATGACTCGTCCTGTACTGAAGCCCTCTATAACTTAGGTTTGACCTATAAGAGGCTGGGTAGGCTGGAGGAAGCCCTGGACTGCTTCCTCAAACTGCACGCTATCCTCAGAAACAGTGCTCAGGTCATGTACCAGCTGGCTAATCTATATGAGATGTTGGAAGACCCTCATCAGGCCATTGAGTGGCTGATGCAGCTCACCAGTGTGACCCCCACAGATGCCCAGGTGCTGGCCAAACTGGGAGACCTCTATGACAATGAAGGAGACAAATCTCAGGCCTTCCAGTACTATTATGAGTCGTACAGGTATTTTCCCTCAAACATTAGTGTGATTGAATGGTTGGGAGCATATTACATTGACACCCAGTTCTGTGAGAAAGCTATTCAGTACTTTGAGAGAGCTACCCTCATTCAACCAACACAGGTCAAGTGGCAGCTGATGGTGGCTAGCTGTTACAGGAGAAGTGGGAATTATCAGAAGGCACTTGAGACCTATAAGGACATTCATCGGAAATTTCCTGAAAATGTTGAATGTCTACGCTTCCTGGTCAGGCTGTGCACTGATATGGGACTAAAAGAGGTGCAGGATTATGCCACCAAACTGAAGAAAGTTGAAAAAATGAAGGAGATCAGAGAGCAGAGGGTGAGATCTGGGAGAGAGAGCAGTGCTCGAGGTCGCAGGGAAGGCAGCGCTGGCAGTGACAGTGGACAAAGCAACCATGGCACCAGCGCCAAGGGTGAGAGGCTTAGCGTTAAACTGAAAACTCTTCCCGGGTCCAATGAACCGTATGAGGCCAGCACTCAGCAGGAAATAGATGCTTCTTATGTCGATCCATTGGGGCCTCAAATGCAGAGACCAAAAACAGCAGCGAGGAAACGCACAGAGGAAGATGAGTTTGCTGATGAAGAGCTGGGAGATGACTTACTGCCTGAGTGACGTGTGCAACAGAGATCAGTTCAGAGGAAAGTCTGATATATGTCCAGACACTACATTTCTTTGAATTTCAAGCTCAACCAATAGCACTGTAGATTAAAAATACTTCATTGTTACTTCATTAAATTCTTCATTATGCTTTACTATATTTTATAATAGCAATGTATTGTACTTGCATTTAGGGAAAAATGAATTCTGTGCAATAATTTTTTCTTTCTTTCTGTATGACAGCATAAGACCTAGATAACATAAAGCTGAAATATAGTTGTTTTGTGTGAAATATTAAAGCCCAGTTTTATAGA
->XM_045586159.1 PREDICTED: Pipistrellus kuhlii protein SLFN14 (LOC118726237), transcript variant X2, mRNA 
-AAAAATAGAGCTTTGAAATGAAATTGACCAGGATAGGAGGTGCTTGTATGATGTATGGAAATGACACGCAATCCCTTAGAGGTGAGCAGTGTAACTGGCTCTCATTTGAAAACGCCTGAATCTTCCCTTACTACCTAATTCACTCCAGAAGCCAAACTGCAGCCTTCGAATCTGCCCTGTCATAGGCTTTTCTTGAGTCCTTATCAGTCTTCCTCAGTGGGTCAATGTTATGAAGTCTGGGAGAGTCTGGCAGGGCTCCTGCTCCTCCCAGGCTGATATCAAAGAGCCACAGGACTGTGACAGAAAGCAAACATTCAGACCAAAGCCAGATGTGGAACTGAAACAACAAGAAGAGAAGCAAACGTATCAGCACACAGGGGCTGCTGAGATGGAAAGTCTCCAGACCAGTACGGAAATGCTCTATCCTGAGATAATTGTGGACGTGGGCACAGTGACTTTTGGAGAAGAGAACAGGAAGAACATGACCAATAATCAGTTGAAAAGGAATGAGAATTCTAAAATCATCCAAGCCGCCTGTGCACTGCTAAATTCTGGAGGGGGTGTGATCAAAGCGAAGATTGATGATAAAACCTACAGCTACCGGTGCCACGGGCTGGGTCAGGATCTGGAGACTTCTTTTCAAAAGCTCCTTCCTTCAGGTTCACAGAAATACCTTGACTACATGCAGCAGGGGCACAATCTCTTGATTTTCGTGAAGTCATGGAGCCCAGATGTTTTCAGCCTCCCCTTAAGGATCTGTAGCTTGCGTTCCAATTTATATCAGAGAGATGTGACTTCTGCTATAAACCTGAGTGCTAGCAGTGCCCTAGAACTTCTCAGACAGAAGCAGTATAGAGCCCAGAGAGGAAGACCCAGGGTGAAGGAGCGGCATCCTCAGAAGGTTCTTGACAGACACATTCAGGAAGAGGAAGATATGAGGCTGTCTGCTTCGGAATTTCTTAAAAAGGACAAACTCATGTATAAAGAGAAACTCAACTTTACTGAGTCGACACATGTTGAGTTGAAAAGGTTCACCACCAAAAAGATTGTCCCTAGGATTAAAGAAATGTTGCCCCATTACATTTCTGCGTTTGCCAACACTCAGGGGGGATACTTAATTATCGGGGTAGATGATAAGAGCAAAGAAGTGTTTGGATGTAAGAGAGAAAAAGTGAACCCCGACTTATTAAAAAAGGAAATAGAAAACTGCATAGAAAAACTGCCTACATTCCACTTCTGCCATGAAAAGCCGAAGGTGAATTTCACTACCAAAATCTTGGATGTATACCAAAAGGATGTCCTGTATGGTTATGTCTGTATTGTTCAGGTGGAGCCTTTCTGCTGTGTGGTATTCACAGAGGCCCCAGATTCGTGGATCATGAGGGACAATTTGGTCACAAGGCTGACAGCAGAGGACTGGGTGGCTATGATGCTGGATATTCCATCAGTGACACAGGAAGAGATACTATTTAAACCAGAATCCCTCTGTAAGACATTGTTCTCAGATCATAAAGAACTGGAGGAATTCATGAAGATGCAGATACGTCCTATCTCGCAGGGGATTGTGGTATTTTCTCGAAGCTGGGCTAATGATATTGGCTTAAGGAAAGAACAGAACGTCTTGTGTGATGCTCTCCTGATAGCGGTGAACAGCCCCCTGGTACTTTATACAATCTTGATACACCCCGGTGGGACCGAAGGGCCTGAATATGCCCGGAACACTGCTCGTCAGTTAAAGCAGAAACTGGGAACTGTTGGTGGTTACACAGGGAGAGTGTGTGTCATTCCGAGACTGCTGCACCTGCCCGGCACACAGTCTAGACCCTGTGGGACCCCTGTGCACTACCCTCAATCCTACCTGCTTGCTAACGAGGAGGAAATGGAAGACTTGTTGCAGGCCCTTGTCGTGGTGGTCTTGCTGTGCTCTCGTTCCCTTCTGAGTGACCGGCTGGGCTGTGAATTTTTCAACTTGCTCATAGAGGAGCAATGTGAGTTGCTGTCAGAGAGCCTTCAGGAGACGCGAGAATTGTTCATCCACTGCTTCCCAGGAAGCAGGAAGACAGCCCTAGCCATAAAGATCATGGAGAAAATCAAGGACCTATTCCACTGCAAACCAAGAGAGATCCTCTACGTTTGCGAACATGACTCCTTAAAGGATTATGTGGCCCAACAAACCACCTGCCAGGCCGTGACCCGGAAAACCTTCATGCAAGGGGAGTTCCTAAAGATTAAACACATAGTGATGGATGAGACCGAGAATTTCTGCAGTGTGTATGGTGATTGGTACAAGAAGGCTAAGGGTATCACCCATCCAGAGGGGAGGGGAGCTGGAAGGAAAAACCTTCACCATGGGGTTCTCTGGCTCTTTCTGGACCCCTTCCAAGTCCGTCATGCTGATGTCAACGGCCTCCCCCCTCCATCTGCTCAGTTTCCTCGGAAAACAATCACTAAAGGGATCCACTGTTCTCTGGAAATAGCAATGGTCATGAAACAAGAAATGAGGAAGATCAAAGAAAATCCTCCCTCCAACATGTTTCTGGACACACTGGCACTCTTCAGGGAAGCTGCCTACGAGGCAGCAATGTGTGCCCAGGCTCTTCCTGGGGTGTGTGAAACGGAGACCAACCTGACAATAGAACAAATCGCAAAGTACGTGGCAGAAAGATGTCACCACCTGTTCCAGTGTGGCTATCTGCCCAAAGATATAGCAATTCTGTGCAGGAGAGGGGAGGACAGAGGACGCTACGAGCTTGCACTGCTAAAAGCAATGGAATTAATTGAGACCCGCAGAGCCGCAGAAGTTGTGTTCAGCCAGGCCTCTGGTGTTTTGGGCAGTCACATCATTTTAGACAGCATTCAGCAGTTTTCAGGCCTAGAGAGGAATATTGTGTTTGGGCTTAGTCCAGAATGCACTCCTTCAGAGGAAACGCATAAGCTCTCCTTCGCCTCAAGAGCCATTAAACACCTCTACCTGCTTTATGAAAAGAGAACAGCCTTCTGAAAACCATTTCAAACAAAACAGGAAGCCAAAGGAGCAGAGTCCCTTCTCCTAGGCAGGCTGCAGGTACTCCTTTTCACATATTACAAATGGGAAGATCAAGGCACAATCAGTATGGCA
->XM_047948956.1 Puccinia striiformis f. sp. tritici uncharacterized protein (Pst134EA_017638), partial mRNA 
-ATGTACCCTACAGCCGAAGATGCGGTGCCGTCAGCGATCAGCCGCGGGTCTATTAATTGTGTGTCGACTGACATGCGAGTATCAGAAGATGTTCGCCCGGGTCGGCTAGCCGAAGCTCAACGGGAGATCAGCGGCTTTCCCGAATCAGTTCCACTGCCACGGCCAGCCAACCAAGATGCGATTGATTGGTCCAGGAACATTGACCCAAGGATCACAGGGCTCAAGGAACTCAGGAGAGAAGAGCTGAACAGTGTTACTGCACATTTAGAACAGCTCGATCAATATGTCCAGGCTCAAGCTGAAGCCACGACGGATGCTATCACCAGAGACCCTCAAACTCTGGTTGGCCCTTGGTTTCAAGTCACGCCTGCTCGTCCAGGTCCACAAAGATCGAGTAGACTTGCAGAATTATTCACCAGAAGATCCAGTAAAAAAGCTGAACTAGATGATGGGTTAAGAGAGATCATCATGACCGACGTGATCCCGGTTTGA
->XM_046909055.1 PREDICTED: Gallus gallus pleckstrin homology like domain family B member 2 (PHLDB2), transcript variant X26, mRNA 
-AGAGAGACTGACTTCTCTGGCTACTCATTCACAGAAAAGTTGTGCAGCTCAACAGCAATGGGCTTGAATTAAAAGCCTCAGGGAAATTCATAATGCACAGCCTGATAGTTTTCCCCCTCGCATGCATTTCAGAATGGTGCTTGCTTCTAATCTGGAGAATGCCCTTTCAGTACCTGCTGGCAAGTCACGCCACTTTAATTTCAGATTCCAGTAAGATTATGGCAGAGTATAACCACACACAAAACCAGATGGAATTACAAAATGCTAGTTTGGGAAAGGGTTCTGTGGTGAATTCCCTTGAAAACGGTCTCCAGGATATTATGGAAAACCTCAACACGAAGAAATATTCATCAAGTCTCAAATTTAAAACAAACGGGGACTGCGCCGGTTCTTACTTAACCCTTTCACAGCCTATGATGGCTAAACCCAGTCCTTCCACTAGTGTTAAAAATATACACTCTGTTACCAAAATTCAAGGAGGCAAGCTTTTCCCTTGTGAAAGTCCGTATCTTCCAGATAAAAGCTTCTCTGTAAAGCATTTGAGTTCCCTGTCGGGCACATCTCCATCCCTCAGTGGGTACAACTTAGGAAGGACAGACTTTGATATTCATGCCAACAGAGAAAATGAAAAAGCTCTTGGACACGCAGATAAGTTTTACTACTCTAAGTATAGCCAGAAAAACAAATCGTATGACAATGTCTACTTGCCAGGAATGCTGGACACAAAGAAGATCTCAGGCTCTCTTCTTACAATGTGGAACGGCAGCTCAGGGAGCGAGCTGATGCTTTCCCCTGTTAGCAATTCAGGGGCAGCCAGCATGCCTTCTAGTCCAAAGCAAGGTCGGAGGATGAATATTGAAGATGGCCTGGCCCTTCATGCAAAGCCAGTTAAACACAAGGATGTGATGATGGAGACTCTGGCCTCACGCCCTAGGAAATACTCTGGTGGATCTCTGAGTCATATGGGAATGTACAGTCGTTCCCTACCCAGGCTTCATAAATCAACAGAAAGCCAGTTGATGCCATTAAGTTTGCCCCCAAGAAACTCCTTGGGTAATACTAAAAGGAAAAAACTTGGAGAAAAGGATCTACCTCAGAATGCTTTAGATGCTGATAATTACCTGAATTTTTCTTCGTGCAGCTCAGGGGTTTTACCACATGCAAATTCGTTCTCTGGGAATAATCCCTATGTTAGTTCAACTCTTAGCGTTCCTGCAAGCCCTCGAATTGCTAAAAAAATGCTTCTAGCATCTTCTTCCTCGTATATTCCTGATGATTTTGATAGACTTGGACTCTCAGGAACGAGTCCCAGTAGTTCGTTCTCCCCTGTGGATTTTGACAGATCATTCTCTATCAGAAGAAACCTCTCCACCAGTTCCATGGAATTCGATGATACAGACTTGGAAAGTTACAGGCAGACACCAAACTCACTGCAGACCTCTGTGAGAGAGCGTAAGAACAGCATCAGCTCCATTTCAGGGAGAGAAGACCTCATGGACTATCACAGGAGGCAGAGGGAAGAGCGGCTGCGGGAGCAGGAGATGGAACGCTTGGAGCGACAGCGGCTGGAGACGATCCTCAATCTGTGTGCAGAATACTCCAAGTCTGACAGTGACCCTGCCGCAACTACAACAGTTGCTGATGTTCAAAAGATTAACAAAGAACTTGAAAAACTTCAGCTATCAGATGAGGACTCAGTGTTTGAAGACTCGCAGATGAATCTAGAAACGAGGTTTAGGAACCACCTGAAATCGTCTGCGAGTGATTCGGATTTCTCAGAGCCAAGTAACCACAGTCGGAGCACTGCTTCTTTCCTTTCCTCCCGGGGGCTGAGAGCCGACGAGCACTTCACTGACAACATGAAGCCTGCACCTTTAGCTGCCCCTGGCTTCCTGAAGGATTCCACTGAGTCTTCGTATCTAAGCATCACGCCAAAGATACCAGAATGCACAAGTGATGATCAAAGAGGACAGGAGCTCACTCGGCTAGAAGAGGAACGCATAGTAATATTAAATAACTTGGAAGAGCTTGAACAGAAGATCAAAGATTTAAATGACCAGATGGATGAATCCTCAAGAGAGCTGGATATGGAATGTGCCCTTTTGGATGGGGAACAGAAATCTGAAACAACAGAGCTGCTGAAAGAGAAGGAAATACTGGATCATCTAAACAGAAAAATAGCTGAGCTGGAGAGGAATGTTATTGGTGAAAAGGCAAAGGATGCTGATCTACTGGACATAGAAAGCAAACACTTTGAAGACTTGGAGTTTCAGCAGCTTGAACATGAAAGCAGGTTAGATGAAGAGAAAGAAAATCTGACACAACAGCTCCTGCGTGAAGTAGCTGAATATCAGCGCAGCATTGTCAGTAGAAAGGAAAAGATTTCTGCTCTGAAAAAGCAAGCTAATCATATTGTCCAACAAGCACAAAGAGAACAAGATCATTTTGTAAAAGAGAAAAATAACCTAATAATGATGCTGCAGAGGGAAAAAGAGAATCTCTGTAATCTGGAGAAGAAATATTCCTCACTCTCTGGAGGAAAGGGATTTCCTGTCAGTCCCAATAGTCTAAAAGAGGGCTATATCAGTGTAAGTGAAATTAGTGAGCTGTATGGCAATTCCACGAATATATCCCCTTCCACTCAGCCCCCCACAGATGCTGACGCAGGTACCACTGAGCCTTCCACGGCTGTGCTGACGAGCCAGCCACAAAATAAAGAGCATTTCAGAAATCTGGAAGAGCGAAAGAAACAGCACAGGGAATGCATGTACATGAGTGATACTTTGCCTCGCAAGAAAACAACTCCAACTGTGTCACCACACTTCAATAGTTCTACTCTTGGACGAAGCATTACATCTAAAGGGCATTTACCATTAGGACAGAGCAACAGCTGTGGCAGTGTACTTCCTCACTGCCTGGCAACCATGACCAAAGAGTCAGAATCAAGAAGGATGCACAAAGGGTATAACCATCAACGTATATGTGAAAACCAAAGGCAGAAATCTCCTGAATTCTACAGCAGAACAGCATCCGAATCCAACGTGTATTTGAATAGCTTCCATTACCCAGATCGTAGCTACAAGGACCATGCCTTTGATACATTAAGCTTAGACAGTTCTGACAGTATGGAGACAAGCATATCAGCATGCTCACCAGATAACATTTCCAGCGCTAGCACATCAAATGTCGCAAGAATAGAAGAGATGGAGAGACTTCTGAAACAAGCACATGCTGAAAAGACTAGGCTGCTTGAGTCCAGGGAACGGGAGATGGAAGCTAAAAAGCGAGCTCTGGAAGAAGAGAAACGCCGTAGAGAACAACTGGAAAAAAGACTGGAAGAAGAAACTAGCCAAAGGCAAAAACTAATTGAAAAGGAAGTGAAGATACGAGAGAAACAAAGAGCACAGGCTCGTCCATTGACTCGCTATTTGCCCATTAGAAAGGAAGACTTTGATCTACGAAGTCATATTGAAACAGCTGGTCACAACATAGAGACCTGTTACCACGTCTCCCTCACAGAGAAGACCTGCCGAGGCTTTCTGATTAAGATGGGAGGAAAAATTAAAACATGGAAAAAACGATGGTTTGTTTTTGACAGAAACAAGAGAACTTTTACGTATTACGCAGACAAACACGAAACTAAATTAAAAGGTGTAATTTATTTTCAAGCTATTGAGGAAGTCTATTACGATCATCTGAAGAATGCATACAAGAGTCCCAACCCACTACTTACTTTCAGTGTTAAGACACACGACCGAATATACTATATGGTCGCTCCTACACCGGAAGCCATGAGGATATGGATGGATGTTATTGTTACAGGCGCGGAAGGCTACACCCACTTCATGTTATAACAAAATGGGCCAATAGGGCATACTGCAATAATGTTAACATATGAAGTTAGCCATATATAGTAAAATCTGAAAAGCCACATAAAATACCAGTGAACACTCTGAAATATCCTCCTTATGATGTGCAGCCAAAGCCTCAGAACGGAAGGGTTTTCTAAATGCATTGAAAAGGGGGACTTGCTACTTATTTTAGTTGATCTTTGTAGAGACAAAAGAGCTAAAGCTGTTGAGAAAGTCATAGTGCTCCAAAACAAATCAACTGGCCACTTATGTGACAACATCTGGATTCAACAATAATTTTGTACCAGTTCTCTTAAACAGAGAATGTCTTCATCACCAGTTTATGAATGCGTGTGCTCTCATCAGTATGCAAAAATTCTAGTAGAGGAACAAAAAGGTGTAATAGCATATATTTTAATATGCAGCATTTGACATTTATAGACGATTAGGTGACTTTTAAAAACTTTTAGTCGAGTATTTTATAAAACTATGAATTAAAAAGCTGCCCTAAGGTACACACAGTTCTTGCCTTAGTAAAGTATTACAACAGAGCCAAAGAGTTATGTGACTCCCTTATTGTAATATTTCAGATTGTTAGCTGTATTTAACTTCCTGTAAGGGGACAGTGCCAAAACTCTTCATGACTTGTAAAGTAATTAAGTTTTTACAAAACTATGTTAAACCACCCAGTGATACTGACTGTCAGTTTAAAGTCTGTATCTATGAAGCTCAACAAGAAAAGGACAGCTTTATAAAGACGGATTTATCCACAAGGATATGAAATGGAAGCGTGGGTTAACTTTGTCATTAGGAGGGCTTTTGCAGTCTTCCATGCTGAATGGATTGAGCTGATTCTGGACCCTGCAGCGATTTTATGTAGTCAGGTCCCACCTGATGTGGTTCTGATCTTTCTCTGTGCCAAACGAACACTTTGCTGAAACCTCAGATGTTGGTCTCCATGAAGCAAGCACTGAAGTATCTACCTATCTAAATTCTTTGAAGCAATGTTTTTAGCCAAGGAGACTTTTTAAAAGTGTATCTACTCAGAATAATGCTATCAGAATAAAAATAGAAAAGCAAGCGCTAAGGGTTTACACTGAGCAGTGTATGGATAAAAAGCGTGAAAACTTTAAGTATCAGGGATTGAGATTCCTAAAACAACAAAAATAAGGAGGATACAGTGGTCTCCTATTTAAAAATCACTTACAAATTCCAAATCCTTGAGAAATATTGCAAAGCTTAAGTGAATTGAACTTCAAGAAAGTCTCTTATTCTTTGACTTTAATGAGGTTCTATTTCAGTCATCAATACTTGTGCTATGTAATTTGTTTGTGTAATAAGAGAAAGCACATTAGACATTTTTCTCGATGAAAAGCTAATGGCTTTTGATGAAGCAAGTGAAAAACTGAAAGCAAAACAAGTTTGCTGGCAAAATAATTTTGTTGTACTGTTTCAACCCTGTATCTGTTAAGAAGGGGATGCGTTCTTCCTTGTGTGGTATACACAGGCGATATGGTTGCTCTAGCATGACATTTGTCAGTTTTGACTTGAATCATGAAAGAAGGGACAGTTATCACAAGGTAACTGTTATCATCATGTGCAGATCACAGCTTATAATCCAACGATTTAAAAACACTATCAGAATAAATTGCTTTGGTATATGTAATTATTATTTTTTCCCTGACGTATCTTGATTTTACTTCTTAGCATAGTTATAAAGGTTTTCTAATCATGATTTTTGTATCCTGCATGATGCAATGAAGGCATTTCAATAAACGTTTTTAAAAACA
->XM_010693631.3 PREDICTED: Beta vulgaris subsp. vulgaris 110 kDa U5 small nuclear ribonucleoprotein component CLO (LOC104905180), transcript variant X2, mRNA 
-AAATAATTAAATAAAACAATATTGAAGAGAAAAGGCAAAAAAAAAAAAAAAAAAACTCTCCACCAAAAACAAATATTTGTACCACCTTAACCTTAACAGCTTAACTTGAGTGTTGAGTCCATCTAAAACCCCAAATAACCCCATTTCACTTTACTCCCAAAATTCTCTCTCCTCCATTTCATCTTTCTCTCCTCTTTCCGCCATGGATGATAGCTTATATGACGAGTTCGGCAACTACATAGGTCCCGAGATCGACTCCGACCAAGACAATAATTCAGACACCGACATTCCTTCCGACGATGACGCCGACAAACGTCCTTCCGACGACGACAACACTCCTTCCGCCGCCGCCGGTCCCACCAACGGTTGGATGACAACCTTAAACGACAACAACGATGACGACATCGAAATGTTCGACAACCAGGTTGTTCTCGCCGAAGACAAGAAGTACTATCCTACTGCTGATGAAGTGTACGGTGAAGATGTTGAAACCCTAGTTGAAGATGAAGATGAACTTCATCTTGAACAAGCTATTATTAAGCCTGTTAAAACCCTAAAATTTGAAGTTGGTGTTAAAGATTCGTCTACTTATGTTTCTACTCAGTTTATGCTTGGTCTTATGTCTAACCCTAATTTAGTAAGGAATGTTGCACTTGTTGGGAATCTTCATCATGGGAAGACGCTTTTTATGGATATGCTTGTTGAACAGACTCATCATATTTCTACTTTTGATCCTAAGAACGAGAGGCATATGAGGTACACGGATACAAGAGTTGATGAGCAGGAGAGGAGAATTTCTATCAAATCAGTGCCAATGTCACTTGTTCTTGAGGACAGTAACTCCAAATCATATTTGATTAATATTATGGATTCACCGGGTCACGTAAATTTCTCGGATGAGATGAGTGCTGCTCTTCGGCTTGCTGATGGGGCTGTCCTGGTTGTTGATGCGGCTGAAGGTGTCATGGTTAACACTGAAAGGGCCATTCGACATGCAATTCAAGAACGCCTTCCTATTGTTGTTGTTATTAATAAGGTGGATAGACTGATTACAGAACTAAAACTGCCTCCTAAAGATGCTTATCATAAGTTGCGCCACACCTTAGAAATCATCAACAACCTTGTAAGTGCTGCCTCTTCAACTGCTGGCAATGTTCAGAGTATTGATCCGGCAGCTGGTAACGTTTGTTTTGCCAGTGCAACAGCTGGATGGTCATTCACTTTGCAATCATTTGCAAAACTCTATGTTAAACTGCATGGGGTAGCATTTGATGCAAATAAGTTTGCTTCTCGTCTTTGGGGGGACATGTATTACCATCCAGACAGCAGAACTTTTAAGAGGAAACCTCCTGTGTCTGGTGGGGAAAGATCTTTTGTTCAATTTATCTTAGAACCTCTGTATAAGATATACAGTCAAGTCATTGGTGAGCACAGAAAGAGTGTCGAGGGCACACTGGCAGAACTTGGGGTTACACTTCCGAATGCAGCTTACAGGTTAAATGTTCGGCCCCTGTTAAGACTTGCTTGCAGCTCAGTTTTTGGTACAGCAACAGGCTTCACTGATATGCTAGTTCATCACGTTCCTTGTGGCAAAGAAGCTGCATCAAGGAAGGTTGATCACATATATACTGGTCCAAAAGACTCGGAGATCTACAAGTCCATGGAAATTTGTGATTCATCGGGGCCAGTTATGGTTAATATCACCAAACTCTATCCAAAAGCAGATTGCAGTGTTTTTGATGCTTTTGGTAGAGTTTACAGTGGTGTGCTCCAAACGGGACAAACTGTTCGTGTGTTGGGAGAAGGATACTCACCTGAAGACGAGGAAGATATGACAGTGAAAGAGGTCACGAAGTTGTGGGTCTATCAAGCTCGTTATAGGATACCTATAAGCAAAGCTCCACCAGGTTCATGGGTTCTCATTGAAGGTGTCGATGCCTCTATCATGAAGACTGCTACACTTTGTAATGCTGATTTTGATGAGGATGTCTATATATTGCGTCCTCTCCAGTTCAATACACTTTCAGTGGTGAAAACTGCTACTGAGCCTCTTAATCCTAGTGAATTACCAAAAATGGTTGAGGGGCTTAGAAAAATCAGCAAGAGCTATCCTCTTGCTATCACCAAAGTTGAAGAATCTGGGGAGCACACAATCTTGGGCACTGGGGAATTATACCTTGATTCTATCATGAAGGACCTGAGAGAGCTTTATTCCGAAGTAGAAGTGAAGGTAGCAGATCCAGTTGTCTCATTTTGTGAAACGGTGGTAGAATCTTCATCAATGAAGTGTTTCGCTGAAACTCCAAACAAGAAGAATAAGATAACTATGATTGCAGAGCCATTGGAGAGAGGTCTTGCAGAGGACATCGAGAATGGTGTTGTGAGCATTGATTGGCCTCGAAAGAAACTGGGAGATTTCTTCCAAACAAAGTATGATTGGGATTTGCTTGCTGCACGTTCTATATGGGCTTTTGGTCCTGATAAGCAGGGACCTAATATACTGTTAGATGACACACTTCCCAGTGAAGTTGACAAGAACTTACTGAATGCTGTGAAAGATTCTATTGTTCAAGGCTTTCAATGGGGTGCTCGGGAAGGTCCCCTCTGTGATGAACCAATCAGAAACGTGAAGTTTAAGATAGTTGATGCTAGGATTGCTCCTGAGCCACTACATCGGGGAACTGGACAAATCATCCCCACTGCCCGACGTGTGGCTTATTCAGCTTTCCTTATGGCTACCCCTCGTCTTATGGAGCCAGTCTATTATGTGGAGATACAAACACCAATTGATTGTGTTTCCGCCATCTACACGGTTTTATCTCGGAGACGTGGCCATGTGACTGCTGATGTTCCACAACCAGGGACCCCGGCGTATATAGTGAAGGCATTTTTACCTGTGATAGAGTCGTTTGGATTTGAGACAGATTTAAGGTATCACACTCAAGGGCAGGCCTTCTGCCTCTCTGTATTTGATCATTGGGCTATCGTCCCAGGAGATCCACTGGACAAGAGCATAGTCCTACGGCCTCTTGAACCTGCCCCAATACAGCACCTGGCACGGGAGTTTATGGTGAAAACAAGGCGTAGAAAGGGTATGAGTGAGGACGTGAGCATCAATAAATTCTTTGATGAGGCCATGGTTGTCGAGTTGGCTCAACAGGCCGCAGATCTTCATCTACAAATGATATGAAGGATGTAGATAGATACTTTTGGGGGTTTTGAGATATACACCTGACCGTTCTGAATGTAGTTTCAATCAGTTACCCCAAATTCTTTATCACTTCATTGAAGCTGAGATGCTGCCATCAATTATATCATTCTTTCGCGAGTTTCAAAATTCA
->XM_037769526.1 PREDICTED: Sebastes umbrosus plectin-like (LOC119488165), transcript variant X1, mRNA 
-GTCTGGGAGGAACCGGGACCGAGAGGTGGACGGAGAGAGACTGCCTGCTTGCTGTAGTCTCAGAGTCGCTTTGGCTGCAGCCGAGTCGGTGTCACAATGAGTATGTACGGGTCTCAGAAGGCCCTGAACATGGGCCGCAGGAACGGGTCCAAAGGAGACTTGAGCGGGATGCAGCAGTACGCACGGAGCGAGGTGGTGCACATGGGAGGCGGTAACGGATACGAACCTTACCTGGACGGATACAACACCTACAACTTCTCAAAGTCCTCTGGAGGCGGCATGGGAGAAATGTCGAGCAGCATGATGAGACAAATGTCGAGCGGTATGGGAGGCGGCATGATGAGACAAATGTCGAGCGGCGGCATGATGAGAGAAATGTCGAGCGGCATGGGAGGCGGCGGAACGATGACCAGGATGTCGAGCGGTGGAGGAGGCGGCGGAATGGGAGAAATGTCCAGCAGCATGATGAGAGAAGTGTCGAGCGGCATGGGAGGCGGCATGATGACCAGTGTGGATGGCGGCATGATGAGCGGCATGGGAGGCGGCATGAGTGGCTCCAGCACCATCCACCAGAGGGCTATGATCCTGCAGGCCCAGTGCCAGGAGTACCTGAAGAAAGCCGAATACGCCCTTCAGTCTGGCGGCGCCTCCGGTGACGCGGAGCGCTACATGTCAATGGCTAAAGAGACCATTGAGCAGCTGAAGGGCTACGCGATGGACCTGAGACAAATGGGACAGCCCAATGACAACGTAGTCAGGACTTTGGAGATATGTAAAGACCAGCTGAAGGGGGTCCACATGGTCATGACCGGCAGCCTGAACAGGAGGAGGAGCACCAGAGGGAGCTCCGGAGGCTGGGAGGAGCCTCCGAGGAGCTTCCAAGACGCTATGGGCTGGATTGCACAGCAAAAGCGTCTGATTGAAACTGCTTCATGGGGAGACGATCCTGCTGCCATCGAGCAGCAGCTCATCAACCACTCGAACTTTCACAGCTCCATCCAGAGGAGCGTCGAGGTGGAGCGAGCCAGAGATGAGCTGATGAAGAAAGGAGACAAGGGAAATCTTCACGCTCTGGATCAGGAGTGGGACAGTCTGCAGCAAATGTCATTTGGTCGGACCGAGCAGCTGCAGAACCTCAAGCGGATCATTCAGGATATGTCCAAAGAGATCATGTGGGTGAACGACAGGGAGGAGGAGGAGCTGATGTTTGACTGGGGAGACAAGAACATTGACCAGTACATCCCACGGAAACAGGAGAGCTACTCGAAACTGATGAGTGCCCTGGAGGAAAAAGAGAAGGACCTGAATAAACTGAAAGCCAGAGTGGACGGCCTCCTGAAGCTCAACCACCCAGCTTCAGACAAGATCGAGGCTTACAGGGACACTCTGCAGACTCAGTGGAGTTGGCTCCTTCAAATCACCAAGTGCATTGATGTTCATCTGAAGGAGAATGCAGCTTACAACCAGTTCTTCAAAGAGGCCAATGAGACGTACAGCGGCCTGCAGAAGGAACATGAGACGGTCCGGATGAAATTCGCTTGTGACAAGAACACTTCACTGGAGGACCTGATGGAGCTCCTTCAGGGACTAGAGAGGGAGAAGGAGAATATAATGGAAAACAAGAGGCAGGTTCATCATCTGGTCAACAAGTCCAGGACCATTGTGAGACTGAAACCCAGAAACCCTGAAGAGAAGAGCAGCACCCCCGTCATCGTCAAAGCTCTGTGTGACTACAAACAAGACCAGAAGGTGATCTGTAAGGAGAATGAGGCGATCCTAAAGGACAACAGTCAACGCAGTAAGTGGGACGTTACCGGCCCGGGAGGACTGGATATGTTGGTGCCCTCCGTGTGCCTGATCGTACCACCTCCCAACCCACTCGGCATCAGTATGGCCAACAAGAACGAGCAGTACTATGAGGCCATCCTGTCAATCTGGAGTCAGTTGTACATCAATGTTAAGAGTCTCATCGCCTGGCAGTACTGCCTCATTGATATCAGGAAAATCAACTCCCTCACCGTGACCATGCTGTCCCGCATGCGTCCCGAGGAATACCGCCAACTCATCAAGAGCCTGGAGTCTCGCTACGAGGAGTTCAAAATGACCAGCCACGGCTCCCAGATGTTTGCTGACGAGGACAAGAAGATGATTGAGAACCAGGTCACCGGAGCCCAGACCCACTATGACCAGATCGTGGTGGAGCTGCCTACTTACATTGCTCAACAGGAACACATAGAAGTACAGCAAGCGTCCGGCCAGCAATACCAACAGCAGCTGATCCTAGTACAGCAAGCGTCCAACCAGCAACACCAACAGCAGCTGATTCTATTACAGCAGCAGCAGCAACAACAAGCTGCCGCCGAAGCCGAGGCCAGGAGGCTCGAAGAGGAGGCCAGGTGGCGCGAAGAGGAGGCCAGGAGGCTCGAAGAGGAGACCAGGAGGCGCGAAGCGGAGGCCAGGAGGCTCGAAGAAGAGACCAGGAGGCGCGAAGCGGAGACCAGGAGGCTCGAAGAAGAAAGACGAAGAGCGGAGCTGAAAAGAGCAAAGAAAACGGAAGTGAAGTTGGTGAAGAAGGTGAAGGTGGTCACTTCTTCTGCTGCCCCTCCTGTCTCCTCCCACTCCTTCTCCTCCTCCTCCACCTCCACCTCCTCATCCTCATCCTCCCGCAGCTTAACTGAGCTGCATGCGCTCAGACTCAGGCTGGAGGCCTCCGAGGGCACGCTGAGTCAGCACGTTCACATCTGCCTCGGAGACGACTGGATGCACGACTGTGGCCTCAAGATATCTGAGCTAGAGATGCTTCTGCGTAATGTCGACTCGATGCGTGAGGAGCACTTGCGTCTGAGGGAGCATATCTTGAAGGAGCTGGAGGGCATGAATGATTCAGATAAAGCCCAGTTCCTCCGCAACGAGGTTGAAGTCATCAACCAGAGGCTGGGTAGTCTGGAGAGCAGCTCATCAGCTTACCTGGACCGGCTGAAGGCTCTAAGGGACATGCTGGAGAGTGTGGAACAAGCCGAAGACATAGTGAAAGTCCACGAGGCGAGACTGGTGGAGAAAGAGACCACCTCTCTGTCGCCCAACGAAGTGGAGGAATACATGTTGACCCTGAAGAATGTTAAAGCGGAGCTGGATCTGAAGAGGGGTATTCTGGCCACCATGGAGACGGAGCTAGCCAAGGCCAACCACTGGAGCGGCCAGCTGGGCGGGCCCTTCCAGAGGTGTGACATGATGCTGTCCAAATACTCTGAGCAGGTGGTTCTGCTGTCAGACCGCTGGAGACGACTCCTAGGGCAGATTGACACCAGAGTCCAGGATTTGCAGTCGTACCAGCCTCAGCTGGAGCACTACAAGCAAACCAGCACCTCCCTTATTGACTGGATTGATGCCACACGGACAAAACAAGACACCCTGCAGGCCACCAAGATAGAGAGCATCCAAACACTGATGGACCAAATTAACAACCAGAAGGCCCTGAACTCTGAAATCAAATCGAGGAGGGAGACAGTAGAGAGCGTGCTGAGGGACAATGAGGCCTGTGTGATTTCTATCAAGGATTATGAAACGGACCTGGCCTCTTACACCTCTGGTTTAGAGACGTTGCTCAACATCCCCATCAAAAGGACAATGCTGAAGTCGCCGTCGATGGACCTAAATTTGGAAGCTACACAACTGCAAACCCGTTACATGGAGTTGCTCACACATTCTGGTGACTACTACAAATTCCTGGGAGAGCTGCTAAAAAACATGGAGGAGCTCAAGATTCGTAACACCAGGATTGACCTGTTAGAGGAAGAACTTCGCCTGCTGAGGGAGGGCATGCGAGACCGCGACTCCAAGAATAAATCTCTAGAAGAGTCTGTTTCCCGTTATGAGCTGGAGTTGTCCGACTCGCGGGACAAGCTGCTGTCGATTGAGGAGGTGAAGCAAACCGCTACGCTGCAGTGCAGTGCCACTATGGACAGCCTGGACAGCACTCAGAGCCAGCTGGCAGACCTCAACGATGAGGTGACACGTCTCAACTACTTGCTTGAGGAAGAGAAGAGGAAGAGGAGGCTGGCAGAGGAGCGCTACACTACGCAGCAGGAGGAGTACGAGCTGGTGCTGAGGAAGAGGCAGAAGGAGCTGGACACGGTCAGCTGGTCCAAGGTGGAGATTGAGAAGAGTGTGACAAACAAGGATCACGAGATTGAACAGCTGCGGCGGCAGCTGGCTGAGGAGGCGGCGAGGATCAGGGAGCTACAGAAGGAGATGTCAAAGGTAAGGAGCCAATGCAGTATGGAGATCAATAACTTAAAGCTCAGCTACGAATCCCAGATCCACGTCAGCTGCACAGACATGCAGAGGCTGGCAGCCCAGAGGGAGGAGGATACCGTTGATGTCCAGCTGCGGTATGACAGGATGGAGGCAGAGAGGAGGAATCTGGAGGAGGAGCTCAGGAAGCTCAGGATGTCTCTGAGCCAGGCTGAGGAACAAAGGAACAGGGCAGAAGAAGAAGCTCACAGTCAGCGTGCTGTCATCACAGAGGAAGGGCGCAGGAGGAGAGAACTGGAGAGTCAGGTGGAGGTGCTGATTAGGCAGAGAGACGAGGAACGCAGCCAGTATGCAGAGGAGCTGGCTGAAGTCATGAAGAGGCTGCAGGAGAAGAGTGACGAGCTGGCCTACATTACACACAGCCTGGAGGAAGAGACCCGCAGGAGGAGAACTATAGAGGAAGGGCAGGATGTGTTCGAACAGACTCTGGCCCAGCTGCAGGTGAAGCTAACCAGTTCATCAGTGGCTGCAACCCAGCTGGGGGAGTGCGAGGAAGAGCTCCAGAAGATACGTATGGAGCTTGAGAGGGAGAGCAGGGAGCGAAGCAGAGTAGAGCAGAACATGAGCAGGCTACAGAGTCGCATGAAGGACCTTCAGGATGTGAGAGGTGGGCTGGAGAGCCAAGTGGAGAATCTGAGGAGGGCCAACCAAGAGGAAGTGTCCAGAAGAAGGCAGGTAGAAACAGAGCTGGAAAACACCACCAAGGCCATGACTGAGTACATCAGCACCGTTACCACTCTAAGCCAGAGCCAAGAGCACGCCAGCATGTCAGAAAAGAGAGGTGAAGAAGAGCGCCTTAGGTTGCAGGAGGAGCTGGAGAGAAGCTCGAGACAAAACAAGACCTCTGCAGAGCGCATGACTCAGCTGAGCGCCGAGCTGAAGGCCCTGCAGCAACAGCTCCTCCAGGAGCAGGCAGGAGGCAAAGAGGCAAACCTCAGGAATGAGGGCCTTTACAGAACTATAGAGGAGAAGAGTAAGGCCCTGAATGAGCGCTCTGGTGAGCTTCAAAGGCTGAAGGAGATGGCAGAAAGCCAGACCAAAGAAAGGCTGAGGCTGGAGGAGGAACTAAGCGCAGCACGACATGATAAAGCGGAACTCCTGAGATCCAAACAGGGAAGTGATGATGAGCTCTCCTCCCAGATTACAGCCCTGCAACTGCAGCTTCAAGCCAGTGAGCGCAGCAATGTAGATTACCGCAACCTGGCCTCAGAGCTCTCCTCGGAGAGGGAGAAACTCAAGCTGGAGACTGAGAAAATACAAAAGCAGGCCACCGAGACAACCACCATGATGCAATCCATTCAGTCCCAGTACAATGAGATTGTGAATGAGAGAGATGCTCTTTTGCTGAGACTGCAATTGTCAGATAAGGACAAAGATCGCTACCAAAGGCTAGAGGACGAACTCAGTCGCATTAAATTGTCCCAAGACTCTGAGCTTCGCAGTAAGCAACGTATACAGGATGAGAACGAGAGGGCGAAGAGGGATTCAGATTACTGGAAGGACCAGTTTGATAGTAAGCAGGTCCTGATCAGGCAATATGAAACAGACAAGGAACGTCTGGAGAGGGAAAAGAACTCTCTGAAAAGTGAGCTAGAGAGGCTGATGAGGGATCTGAGGGAGCTTGATGAGACATATAAAATCAGGCTGTCAGATATGCAGAAAGAACTGCGAGAGGTGGCTGTTGTCAGAAAAACCATGGAAACTGAGCTGATGAGAGTTAGAGAGCCCCCAACCTTGGATCCTTCCACTTTGGTCTTTGATGGAGTCCGTAAGCCAGTCACAGCAAACCAGTTGGTTGACTGTGGTGTTTTGGACAAACCAACACTTAGCCAGCTTGTGAAGGGGCATAAGACTGTGCCTGATGTCTCTGTCGACAAAAAAGTCAGTCTCAAAGGGACAGGCCCAATAGCCGGGGTGGTAATTCAAGGTCCGAAAGGTCCAGGGTCTTTTACAGGCCCCTTATGCAAAATGACTTTCACCGAAGCAAAGAAAGAGAATCTGCTACCACCAGATAGCGTAGACCTACTACTGGATGCTCAGGCTGCCACAGGCCACATAATTGACCCAAGAACTAATAGGAAGTTGACAGTTGAAGAGGCATGTGATCAAGGTGTGGTTGATGAAGAGGACAGAGAGAGGTTGTTGGCAGCAGAAGCTGCAGCTGTAGGATATTGTGGTCCTGGCACAAACAAACCCCTTTCAGTATTTCAGGCTATGACGAAAGGACTGATTGACAAGAACACAACACTGCGTCTGCTACAAGCCCAGGAGTCTGTGGGGGGCATCCTAGATCCCATACTCAGTGTGTTCCTTCCTAAAGACACAGCCATTGAGCGTAACCTAATTAATGATGACATATATCATGCTCTGAGTCGGAGGCCTGAGCTCTACCTGGACCCCGAAAGTGAAGATGGTGTAACCTATATGTCAATGAAGAGGAAATGTAAGGTAGAGCCACACACAGGCCTTCTGCTTCTTCCGATCCCTGAGAAGGTAGACCCCTCCAAAATTGTCTTTGATGGTGTTCGGAAACCTGTCACAGCCAAGCAGCTCCTTGATTGTGGTGTCCTGGACAAGCCAACATTTAAAGATCTAGAAAAGGGGAAGAAAAATGTCCCAGAGGTGTCTGTAGACAAACATGTTAATCTGAAGGGGACTGGACCCATTGCTGGGGTGGTAGTCGGACGTGAAGGAAAAATGTCTTTCTCAGAAGCCAAGAAACGGATGCTCTTGCCCCCAGATAGTGCAGATTTGCTACTGGAAGCCCAGGCTGCCACAGGTCACATCATTGACCCCAGAAACAATCAGAAGCTGACAGTAGATGAGGCATGTGACAGAGGAGTGGTGGATATTAAGGATCGAGACAGATTATTGGAAGCTGAAGCTGCTGCTGTGGGATACAAGGATTTTAGTGCAGCCAAGCCTCTCTCAGTGTTTGAGGCCATGAAGAAGGAACTAATTGACAGGAAGACTGGGCTACGCCTGCTGCAGGCCCAGGAGTCTGTGGGAGGTATTCTAGATCCCAATCTCAGTGTGTTCCTTCCCAAAAATACAGCTATTAAGCGCAACCTTTTGGATGAAAACCTCCGTCAAGCTCTAAACCAGAGTCCTGAGTGTTACTGTGACCCAGAAACTGAGCGTGATGCCAGCTATGGAGCATTGAAGAAAAGATGCAAGACAGAGCCTCACACAGGTCTGCTACTTTTGCCAATCACTGAGAAGCTAGACCCTTCCAAACTGATCTTTGATGGTGTTCGTAAGCCAGTAACAGCACAGCAGTTGCTTGATTGTGGGGTCCTGGACAAACCAACATTTAACCAACTAATGAAGGGAGAGAAAACTGTCCCACAGGTGTCTGTGGATAAGAAGGTCTTTCTAAAGGGGACAGGATCGATTTCTGGCGTGGCAGCTGGACCTTTAGGGAAAATGTCTTTCTCAGAGGCCAAAAAACAGATGCTCATGCCTGCGGAAAGTGCCGATTTGCTACTGGATGCTCAGGCTGCCACAGGACACATCATTGACCCCACAACCAATCAGAAGCTAACAGTAGAGGAGGCATGTGCCAGAAGAGTGGTGGAAAATAGGGATCGAGATAGACTCCTGGCAGCAGAAGCCGCTGCTGTGGGTTACCGGGACCCAAGCACAGCTAAGCCTCTTTCAGTGTTTGAGGCAATGAAAAAGGGATTAATTGACAGGAAGACTGGGCTACGGCTGCTGCAGGCCCAGGAGTCTGCCGGGGGCATTCTAGATCCCAATCTCAGTGTTTTCCTCCCCAAAGACACAGCTATAAAGCGCAACCTTTTGGATGAGGACCTCCGTCAAGCTCTAAACCAGAGTCCTGGGTGCTACATTGACCCAGACACTGAACGTGATACCAGCTATGGGGCTTTAAAGAAGAGAAGCAAAACAGAGTCTCACACAGGCCTGATACTTCTGCCAATCAATGAGAGGAAAGACCCTTCCAAACTGATCTTTGATGGTGTTCGTAAGCCAGTAACAGCACAGCAGTTGTTTGAATGTGGAGTCCTTGACAAGCCAACATTTGACCAATTAGTGAAAGGCGAGAAAACTGTCCCAGCAGTGTCTACGGAAAAGACAGTCTATCTAAAGGGGACTGGACCCATTGCTGGGGTAGTAGTCGGACGTGAAGGAAAAATGTCTTTCTCAGAAGCCAAGAAACGGATGCTCTTGCCCCCAGATAGTGCAGATTTGCTACTAGAAGCCCAGGCTGCCACAGGCCACATCCTTGACCCTGAAGCTAATCAGAAGCTGACAGTAGAGGACGCATGTGCCAAAGGAGTAGTGGACATTAGGGATCGAGACAGATTATTGGCAGCAGAGGCTGCTGCTGTTGGCTTCAAGGATCCTAGCGGAGCCAAGCCTCTCTCAGTGTTTGAGGCCATGAAGAAGGGACTCATTGAAAGGAAGACTGGGCTACGCCTGCTGCAGGCTCAGGAGTCTGTGGGAGGTATTCTAGATCCCAATCTCAGTGTGTTCCTCCCCAAAGACACAGCTGTAAAGCGCAACCTTTTGGATGAGGAACTTTGTCATGCTCTAAACCAGAGTCCTGAGTGTTACGTTGATCCAGACACCGAGCGTGATACCAGCTATGTGACTTTAAAGAGGAGAAGTAAAACTGAGTCTCACACAGGCCTCATACTTCTTCCAATCCCTGAGAAGGTAGACCCCTCCAAACTTGTCTTTGATGGTGTTCGGAAACCTGTCACAGCCAAGCAGCTCCTTGATTGTGGTGTCCTGGACAAGCCAACATTTAAAGATCTAGAAAAGGGGAAGAAAAATGTCCCAGAGGTGTCTGTAGACAAAAATGTTAATCTGAAGGGAACTGGGCCTATTGCTGGGGTTGTAGCTGGGAGTCAAGGCAAGATGTCTTTGTCAGAAGCCAAGAAAAAGGCACTCCTACCTGAAGATATTGCAGATTTGCTACTGGAAGCCCAGGCTGCCACAGGTCACATCATCGACCCCAAAAACAATCAGAAGCTGACAGTAGATGAGGCATGTGCCAGAGGAGTGGTGGATATTAAGGATCGAGACAGATTATTGGAAGCTGAAGCTGCTGCTGTGGGATACAAGGATTTTAGTGCAGCCAAGCCTCTCTCAGTGTTTGAGGCCATGAAGAAGGAACTAATTGACAGGAAGACTGGGCTACGCCTGCTGCAGGCCCAGGAGTCTGTGGGAGGTATTCTAGATCCCAATCTCAGTGTGTTCCTTCCCAAAGATACAGCTATTAAGCGCAACCTTTTGGATGAAAACCTCCGTCAAGCTCTAAACCAGAGTCCTGAGTGTTATCGTGACCCAGAAACTGAGCGTGATGCCAGCTATGGGGCATTGAAGAAAAGATGCAAGACAGAGCCTCACACAGGTCTGCTACTTTTGCCAATCACTGAGAAGCTAGACCCTTCCAAACTGATCTTTGATGGTGTTCGTAAGCCAGTAACAGCACAGCAGTTGCTTGATTGTGGGGTCCTGGACAAACCAACATTTAACCAACTAATGAAGGGAGAGAAAACTGTCCCACAGGTGTCTGTGGATAAGAAGGTCTTTCTAAAGGGGACAGGATCGATTTCTGGCGTGGCAGCTGGACCTTTAGGGAAAATGTCTTTATCAGAGGCCAAGAAACAGATGCTCATGCCTGCGGAAAGTGCCGATTTGCTACTGGATGCTCAGGCTGCCACAGGACACATCATTGACCCCACAACCAATCAGAAGCTAACAGTAGAGGAGGCATGTGCCAAAAGAGTGGTGGAAAATAGGGATCGAGATAGACTACTGGCAGCAGAAGCCGCTGCTGTGGGTTACCGGGACCCAAGCACAGCTAAGCCTCTTTCAGTGTTTGAGGCAATGAAAAAGGGATTAATTGACAGGAAGACTGGGCTACGGCTGCTGCAGGCCCAGGAGTCTGCCGGGGGCATTCTAGATCCCAATCTCAGTGTTTTCCTCCCCAAAGACACAGCTATAAAGCGCAACCTTTTGGATGAGGACCTCCGTCAAGCTCTAAACCAGAGTCCTGGGTGCTACATTGACCCAGACACTGAACGTGATACCAGCTATGGGGCTTTAAAGAAGAGAAGCAAAACAGAGTCTCACACAGGCCTGATACTTCTGCCAATCAATGAGAGGAAAGACCCTTCCAAACTGATCTTTGATGGTGTTCGTAAGCCAGTAACAGCACAGCAGTTGTTTGAATGTGGAGTCCTTGACAAGCCAACATTTGACCAATTAGTGAAAGGCGAGAAAACTGTCCCAGCAGTGTCTACGGAAAAGACAGTCTATCTAAAGGGGACTGGACCCATTGCTGGGGTAGTAGTCGGACGTGAAGGAAAAATGTCTTTCTCAGAAGCCAAGAAACGGATGCTCTTGCCCCCGGATAGTGTAGATTTGCTACTAGAAGCCCAGGCTGCCACAGGCCACATCGTTGACCCTGAAGCTAATCAGAAGCTGACAGTAGAGGACGCATGTGCCAGAGGAGTAGTGGACATTAGGGATCGAGACAGATTATTGGCAGCAGAGGCTGCTGCTGTTGGCTTCAAGGATCCTAGCGGAGCCAAGCCTCTCTCAGTGTTTGAGGCCATGAAGAAGGGACTAATTGACAGGAAGACTGGGCTACGCCTGCTGCAGGCTCAGGAGTCTATGGGAGGTATTCTAGATCCCAATCTCAGTGTGTTCCTCCCCAAAGACACAGCTGTAAAGCGCAACCTTTTGGATGAGGAACTTTGTCATGCTCTAAACCAGAGTCCTGAGTGTTACATTGACCCAGACACCGAGCGTGATACCAGCTATGGGACTTTAAAGAGGAGAAGTAAAACTGAATCTCACACAGGCCTCATACTTCTGCCAATCACTGAGAAGAAAGACCCCTCCAAACTGATGTTTGATGGAATCCGCAAGCCAGTCTCAGCACAGCAGTTGTTTGAATGTGGAGTCCTTGACAAGCCAACATTTGAAGATCTAGAAAAGGGGAAGAAAAATGTCCCAGAGGTGTCTGTAGACAAAAATGTTAATCTGAAGGGAACTGGGCCTATTGCTGGGGTCGTAGCTGGGAGTCAAGGCAAAATGTCTTTGTCAGAAGCCAAGAAAAAGGCACTCCTGCCTGAAGATATTGCAGATTTGCTACTGGAAGCCCAGGCTGCCACAGGTCACATCATTGACCCCAGAAACAATCAGAAGCTGACAGTAGATGAGGCATGTGCCAGAGGAGTGGTGGATATTAAGGATCGAGACAGATTATTGGAAGCTGAAGCTGCTGCTGTGGGATACAAGGATCCTAGCGGAGCCAAGCCTCTCTCAGTGTTTGAGGCCATGAAGAAGGAACTAATTGACAGGAAGACTGGGCTACGCCTGCTGCAGGCCCAGGAGTCTGTGGGAGGTATTCTAGATCCCAATCTCAGTGTGTTCCTTCCCAAAGATACAGCTATTAAGCGCAACCTTTTGGATGAAAACCTCCGTCAAGCTCTAAACCAGAGTCCTGAGTGTTACCGTGACCCAGAAACTGAGCGTGATGCCAGCTATGGGGCATTGAAGAAAAGATGCAAGACAGAGCCTCACACAGGTCTGCTACTTTTGCCAATCACTGAGAAGCTAGACCCTTCCAAACTGATCTTTGATGGTGTTCGTAAGCCAGTAACAGCACAGCAGTTGCTTGATTGTGGGGTCCTGGACAAACCAACATTTAACCAACTAATGAAGGGAGAGAAAACTGTCCCACAGGTGTCTGTGGATAAGAAGGTCTTTCTAAAGGGGACAGGATTGATTTCTGGCGTGGCAGCTGGACCTTTAGGGAAAATGTCTTTATCAGAGGCCAAGAAACAGATGCTCATGCCTGCGGAAAGTGCCGATTTGCTACTGGATGCTCAGGCTGCCACAGGACACATCATTGACCCTACAACCAATCAGAAGCTAACAGTAGAGGAGGCATGTGCCAGAAGAGTGGTGGAAAATAGGGATCGAGATAGACTCCTGGCAGCAGAAGCCGCTGCTGTGGGTTACCGGGACCCAAGCACAGCTAAGCCTCTTTCAGTGTTTGAGGCAATGAAAAAGGGATTAATTGACAGGAAGACTGGGCTACGCCTGCTGCAGGCCCAGGAGTCTGCCGGGGGCATTCTAGATCCCAATCTCAGTGTTTTCCTCCCCAAAGACACGGCTATAAAGCGTAACCTTTTGGATGAGGACCTCCGTCAAGCTCTAAACCAGAGTCCTGGGTGCTACATTGACCCAGACACTGAGCGTGATACCAGCTATGGGGCTTTAAAGAAGAGAAGCAAAACAGAGTCTCACACAGGCCTGATACTTCTGCCAATCACTGAGAAGGAAGACCCTTCCAATCTGATGTTTGATGGAATCCGTAAGCCAGTCTCAGCACAGCAGCTGTTTGAATGTGGAGTCCTTGACAAGCCAACATTTAAAGATCTAGAAAAGGGGAAGAAAAATGTCCCAGAGGTGTCTGTAGACAAAAATGTTAATCTGAAGGGAACTGGGCCTATTGCTGGGATCGTAGCTGGGAGTCAAGGCAAAATGTCTTTGTCAGAAGCCAAGAAAAAGGCACTCCTGCCTGAAGATATTGCAGATTTGCTACTGGAAGCCCAGGCTGCCACAGGTCACATCATTGACCCCAGAAACAATCAGAAGCTGACAGTAGATGAGGCATGTGCCAGAGGAGTGGTGGATATTAAGGATCGAGACAGATTATTGGAAGCTGAAGCTGCTGCTGTGGGATACAAGGATCCTAGCGGAGCCAAGCCTCTCTCAGTGTTTGAGGCCATGAAGAAGGAACTAATTGACAGGAAGACTGGGCTACGCCTGCTGCAGGCCCAGGAGTCTGTGGGAGGTATTCTAGATCCCAATCTCAGTGTGTTCCTTCCCAAAGATACAGCTATTAAGCGCAACCTTTTGGATGAAAACCTCCGTCAAGCTCTAAACCAGAGTCCTGAGTGTTATCGTGACCCAGAAACTGAGCGTGATGCCAGCTATGGGGCATTGAAGAAAAGATGCAAGACAGAGCCTCACACAGGTCTGCTACTTTTGCCAATCACTGAGAAGCTAGACCCTTCCAAACTGATCTTTGATGGTGTTCGTAAGCCAGTAACAGCACAGCAGTTGCTTGATTGTGGGGTCCTGGACAAACCAACATTTAACCAACTAATGAAGGGAGAGAAAACTGTCCCACAGGTGTCTGTGGATAAGAAGGTCTTTCTAAAGGGGACAGGATTGATTTCTGGCGTGGCAGCTGGACCTTTAGGGAAAATGTCTTTATCAGAGGCCAAGAAACAGATGCTCATGCCTGCGGAAAGTGCCGATTTGCTACTGGATGCTCAGGCTGCCACAGGACACATCATTGATCCCACAACCAATCAGAAGCTAACAGTAGAGGAGGCATGTGCCAGAAGAATGGTGGAAAATAGGGATCGAGATAGACTCCTGGCAGCAGAAGCCGCTGCTGTGGGTTACCGGGACCCAAGCACAGCTAAGCCTCTTTCAGTGTTTGAGGCAATGAAAAAGGGATTAATTGACAGGAAGACTGGGCTACGCCTGCTGCAGGCCCAGGAGTCTGCCGGGGGCATTCTAGATCCCAATCTCAGTGTTTTCCTCCCCAAAGACACGGCTATAAAGCGCAACCTTTTGGATGAGGACCTCCGTCAAGCTCTAAACCAGAGTCCTGGGTGCTACATTGACCCAGACACTGAACGTGATACCAGCTATGGGGCTTTAAAGAAGAGAAGCAAAACAGAGTCTCACACAGGCCTGATACTTCTGCCAATCAATGAGAGGAAAGACCCTTCCAAACTGATCTTTGATGGTGTTCGTAAGCCAGTAACAGCACAGCAGTTGTTTGAATGTGGAGTCCTTGACAAGCCAACATTTGACCAACTAATGAAGGGAGAGAAAACTGTCCCACAGGTGTCTGTGGATAAGAAGGTCTTTCTAAAGGGGACAGGATCAATTTCTGGCGTGGCAGCTGGACCTTTAGGGAAAATGTCTTTATCAGAGGCCAAGAAACAGATGCTCATGCCTGCGGAAAGTGCCGATTTGCTACTGGATGCTCAGGCTGCCACAGGACACATCATTGACCCCACAACCAATCAGAAGCTAACAATAGAGGAGGCATGTGCCAGAGGAGTAGTGGACATTAGGGATCGAGACAGATTATTGGCAGCAGAGGCTGCTGCTGTTGGCTTTAAGGATCCTAGCGGAGCCAAGCCTCTCTCAGTGTTTGAGGCCATGAAAAAGGGACTAATTGACAGGAAGACTGGGCTACGCTTGCTGCAGGCCCAGGAGTCTGTGGGAGGTATTCTAGATCCCAATCTCAGTGTGTTCCTCCCCAAAGACACAGCTGTAAAGCGCAACCTTTTGGATGAGGAACTTTGTCATGCTCTAAACCAGAGTCCTGAGTGTTACATTGACCCAGACACCGAGCGTGATACCAGCTATGTGACTTTAAAGAAAAGAGGTAAAACTGAGTCTCAAACAGGCCTGATACTTCTGCCAATCACTGAGAAGAAAGACCCTTCCAGACTGATGTTTGATGGAATCCGCAAGCCAGTCTCAGCACTGCAGTTGTTTGAATGCGGAGTGCTTGATAAGCCAACACTTAATCAGCTAGTGAAAGGGGAGAAAACTGTCCCAGCCGTGTCTATGGAAAAGATGGTATATCTACAGGGGACTGGACCCATTGCTGGGGTGGTAGCTGGACGTGAAGGAAAAATGTCTTTCTCAGAAGCCAAGAAACAGATGCTCCTGCCCTCAAATAGCGCATATTTGCTACTAGAAGCCCAGGCTGCCACAGGCTACATCATTGACCCTAAAACTAATCAGAAGCTGACCGTAGAGGAGGCATGTGCCAGAGGAGTGGTGGACATTAGGGATCGAGACAGATTGTTGGTAGCAGAGGCTGCTGCTGTTGGCTTTAAGGATCCTCGCGGAGCCAAGCCTCTGTCAGTGTTTGAGGCCATGAAAAAGGGACTAATCGACAGGAAGACTGTGCTACGCCTGCTGCAGGCCCAGGAGTCTGTGGGAGGTATTGTAGATCCCAATCTTAGCGTGTTCCTCCCCAAAGATACAGCTATAAAGCGCAACCTTTTGGATGAGGACCTCCGTCAAGCTCTTAACCAGGGTCCTGAGTGTTACGTTGACCCAGAAACTGAAAATGATGCCAGCTATGGGGCTTTGCAGGAAAGATGCAAGACAGAGCCTCAAGCAAGCCTGAAACTTTTGCCAGTCTCTGAGAAGAAAGACCCTTCCAAACTACTCTTTGATGGTGTCCGTAAGACTGTCACAGCACAACAGTTGCTTGATTGTGGGGTCCTGGACAAACCAACATTTAACAAACTAATGAAGGGAGAGAAAACGGTCCCAGATGTGTCCGTGGATAAAAAGGTCTTTCTGAAGGGGACAGGGTCAATTGCTGGTGTTGCAGCTGGACCTTTAGGGAAAATGTCTTTTACAGAAGCCAAGAAACAGAAAATTATGTCCTCGGACAGCGCTGACATGCTACTGGAAGCTCAGGCAGCCACTGGCAACATCATTGACCCCAGAACTAATGAGAGATTGACTGTAAAGGCAGCATGTGCCAAAGGAGTAGTGGATAAGGAGGATGAATCAAAGTTGTTCGCAGCTGAAGCTGCTGCTATAGGTTACAGAGACCCAAATACAGGCAAGCTCCTGTCGGCAGGCCAGGCCATGAAGAAGGGATTGATTGACAAGGACACAGCTCTACGTATACTTCAGGCTCAAGAGTCTGTAGGGGGTATTTTAGACCCTGCCCTCAGTGTATTCCTACCCAAAGACATTGCAAAGGATAGGGATCTCATAGATGAGGACCTATACCGGGGCCTGAATCAATATCCTGAGTGTTATTTGGACCCAGACACCCAACAAGCAACTACCTATGTATCTCTGAAGAAAAAATGCAAAGCAGATCCAAAAACAGGTCTTTTGCTTCTCCCTGAACCTAAAAAGCCAATAACTGTACAGGGGCTCAGGGGTCAGGTGCCAGTCAGAGATCTAGTGGATGCAAACCTATTAGACCGGTCAGATATGGACCAACTGAGAGAGGGCAGATTGACGAGCCAGGACATTGAAGACCGCCTGCACTCCTACCTGAGAGGTTCCACCTGCATAGCAGGAGTTTATGATGAGGCCAGTGATAAGGTGATGCCCATCTATCAGGCCATGAAAGATGGACTGCTGCAATCTGGGACCACACTGGAACTGCTTGAGGCCCAGGCTGCCTCAGGTTTTATAGTTGATCCTGTCAACAACCATTACCTGACAGTTAGTGATGCTTACAATAAAAGACTGTTTGGGCCAGAGTTTAAGGACCATCTGCTATCAGCAGAGAGGGCTGTGACTGGTTACAAACTGCCTGGTACAGACAAGATTATTTCCCTCTTTCAGGCCATAGAGAGAGGTCTAGTGGAGAAAGGTCATGGCATCCGTCTACTCGAGGCTCAGATTGCCAGCGGTGGTATCATTGATCCTGAACACAGCCATCGGATTGACGTGAACGTAGCCTACAAGAGAGGTTACTTTGATGAAGAAATGAACAAGGCCCTGACTGATCAGAATGTTGATACCAAGGGTTTCTTTGACCCCAACACAGAGGAAACCCTAGCTTATCTGGAGCTTAAGAATCGCTGTATCACAGATAAGAAGACTGGCCTCATCCTGTTGCCTATCACTGACAAGAAAAGTCAAGAATCGACTTCGAAGAACACTCTGAGAAAGAGGAGAGTGGTAATTGTAGACCCGGAGACTAATAAAGAGATGACAGTACGTGTAGCATATGACAAGGGGTATATTGACTACGACACCTTTGTGGAGCTGTCCGAGCAGGAGTGTGAGTGGGAAGAGATCACTATCACTGCTCCAGATGGTTCCATCCGCTTTGTTATCATTGACAGGAAGACTGGAAGACAGTATGACATTAGCGAGCTGCTTGAAATGCGAGTAATCAACCAATCAGATGTAGATAATTACCGATCACGTACCATCACCCTTACTCAATTTGCAGATATCATCAGCAACAAGACCAAATATGGGTCATCCTCATTATCATCATCATCATCAGCTTCAAGATCATCAGCAGCCGGAGGTACATCTTCAGTGACATCATCATCAACTTCAAGAACATCAGCATCCCCGGGTACATCTTCAGTGATATCATCATCAACTTCAAGAACATCAGCATCACCGGGTACATCTTCAGTGACATCTTCATCAACTTTAAGAACATCAGCAGCCTCAGTTCCATCGTCAGTGACATCATCATTGTCATCATCAGTCCTGTCAAGACCCTTATCATCTTCTCTCTCAAAGATGACCACAACAAGAACTTCCACTGTCACAGAGCGAAGCACCTCAACCTGCAGTGTACCTCGAGACTCAACTGACTCCCGTAGGAATATATCCAGCATATCTGTCACTCTGTCCTCTCCTATTGAAGTAATAGATGAACAGGAACCTGTGGGTGCCGTCTTTGACACAGACTGTATCGAGAAGATATCCATCACAGAGGCTCTAGATCGTGGTCTGGTGGATTCCATCACTGCCCAGAGACTGCTGGAGGCTCAGGCTTGCACTGGAGGAATAATCAATCCCACAAATGGCCATAGGCTCAGCATCCATGAGGCCACCCGCCTGGGCATAATAAGTGACAACATGGGCCCAAAGCTCAAGCCTGCCCAGAAAGCCTTCTTTGGCTTTGAGGATGTAAAAAACAAGAAGAAGTTATCTGTTCCTCAGGCCATGAAGGAGAGGTGGCTGCCATATGAGGCAGGGCAGAGGTTCCTAGAGTTCCAGTATGTAACAGGAGGGATTTATGACCCAGAAATGTGCTGTAGAAGAACCATAGATGAGGCTGTGGAAATGAAGTGGCTGGATTCGAGAGACGCCGAGAGGCTCCAAAACGTCAGAGACCACACAAAGAACCTGACGTGCCCCAAGAGCAAACTTAGGATCTCTTACAAGCAGGCTCTGGATAATTGTCTGGTGGAGGAAAGCAATGGGTTGAAAATGCTCCAGGCATCATCTGTGTCTTCCAGAGGGATCAGCAGTCCTTACAATGTCTCCTCTGCCCCAGGGTCCACCACCGGCTCCAGGAGTGGCTCACGACGAAGCTCCCGCAGGAGCAGTGTGGACCTTGGATCCCCCTCCTCCTCAGGAACTTATCACCACAGTGTTTCTAGCTTCACCACCTACTCTGCATCCTCCAAATAAATCAAGAAAATGATCTGCACATTCATGCTCTTTTCTTGCAAATGATTCCTTTTGTTAAAAATATACCGATTGTTCAGAAAATAACTTGTGTGTGTCGTATATGAGGAGAAAAAAAAAATTAAGATAATGTTCTTAAACTTTTTGCATAGTTTTAGATTTCTGCTTTGGTGTTGCTATGCTTTTAAAATGCTATAGTTCAAATGTTCGAGAAAATTAACACTTCCAAGATATTTTTTGTGGAAATGAACTAAAGTATTAATGGCAGCCATCTTATGGTATTTGGAATGAAAATAATGAGGATGTTAATATAATTTTTGGTGCCCCTAAAATAGGCTTAGAAATGATTACCATATTTTTGCATACAAAAAATAAGTTTTTCAAAATCTTCATGAAATGTAATTTCTTTTTAAGCTTTGCATTGGTCACATAAGGGTGCTATGTTTACATTTATTTGTCATCTGAAATACATGTTTTGTGAGGGGAGGGATACAAGGTTTGGTTACATATATTGGTTTAACTATTTGTTTTCTACTGAATCAGTTGTTAACTGTTGTTCTTTTGCTCTTTAGTGCTTCCGGTTTTGTAACAGTTTCTCAATATCTCCAAATAAAAGCGGTTGAGTCTTTAGCTCA
->KJ343209.1 Uncultured bacterium clone Evans.12.9_01824 16S ribosomal RNA gene, partial sequence 
-TACGTAGGTGGCAAGCGTTATCCGGATTTATTGGGCGTAAAGAGAACGCAGGCGGTCTTTTAAGTCTGATGTGAAAGCCTTCGGCTTAACCGGAGTAGTGCATTGGAAACTGGGAGACTTGAGTGCAGAAGAGGAGAGTGGAACTCCATGTGTAGCGGTGAAATGCGTAGATATAAGGAAGAACACCAGTGGCGAAAGCGGCTCTCTGGTCTGTAACTGACGCTGAGGTTCGAAAGCGTGGGTAGCAAACAGG
->XM_018460662.1 PREDICTED: Trachymyrmex zeteki zinc finger protein 830 (LOC108730757), mRNA 
-GTTGCGTTCAGAATCATCATCCGAGTGTGCACCAAGATGTTGTTTTATCCTTATGTAAGGTAGATAACAAGGGTAAAACGACATCTGAGTGCATCTGGACGACAATTCTGAACACTGCCCAGCACTGCACTGTAGCCAATAGCTTCGATGGTACGAAGCACGGAGCATAGAAGCGCGATCAAAACATAAGTAACTGAACATAACCTACAAATCATTCGTTGTACGTAGTGATTTAACGAGTGAAAATTGGTGAAAATGTCCTTAAAAAGGAAACTGACGCAGGACGATCTGCGTAAAGCAATGAGTGAACACAAGAAGAAGTTCGGAACCATTAAAAAGATCGACTCACCGTTGGCAAAATATACAGATTCAGGACAGCTTATGTGCATTTTATGTAAGTCAGTGGTACGGAGTGAAACAATTTGGCCTGTTCATTTAAATTCCAAGGTGCACAAGGATAATGTTGCGTTAGCGAAAAAGACTAAACTAGAAACAGAAAGTACTATAAATGTATCTAATGTTCAAACATTCAAAAGGCCTCCGTCTCCATCAAACAATTCCCCAAATAAAAAGATAAAAGGAATATTGAAAAACTCTAGCCAGCCAGTGGTACAGGTCAAGTCAAATTTACCAGCAGATTTTTTTGATGATAATTCAGAGCAAGTTAACAATCCGTCTGTTCTAACGCAAAAATTAGAGAGCAAAGAGAAAGATCCCATAGTCAATACTACAGATGTACAACATGCCAAAGAAGAAGAAAAAGAGAAAGAAAAAGAAAAAGTAAAGGATATGAATCAAGCTGTTCTTCCAGAAGGATTTTTTGATGACCCAGTGATGGATGCTAAGGTTCGTAATGTTGAATACAAAGATCCTATTGAAGAAGAATGGGAGAAATTTCAAAAAGAAATTAAGGAAGAAACTGCGCAATCTGCACAAATTATAGCTGACGATCAGGAGGAAGCAACAACGGAAAGACAATTAGATGAAATTGAGGAACAAATTAGGCATTGGTCTAGGGTAATGGATCTCGCAAAACGTATGGAACAAGTGCAGGGTACCGATAGAAAACAGGAAAATATCGATAATGATGTATCAAGTGGTGACGAAGCCGAGTTCGACGAGTTTCTTGACTGGCGAGCAAAGAATTCGTATAAATGAAAGATTTTATATATCTAACAATTTTGTAA
->XM_003538860.4 PREDICTED: Glycine max probable serine/threonine-protein kinase PIX13 (LOC100777578), mRNA 
-CGAAAACGACCCATGTTATGTAGCTAGCACTTGTGTTGTGTCTTTTCTCATTCCTCATCCTCAACCTTACGCAGCAGCCATTCTTGTAGAATTCATTTTCTCGAAATTGGTTAATTAAGTTAATTAACACTAAACACTAAACATGGGTCTTTGCTTTGCTTCCCTCGCTACCCACCAAACACCCTCCAATAATTCCCCTCACTATTCAGGTTCAGCGCGTGAGATGGGAATTACTGAAAGCACTAGTGTTAATGGAGGAAGCAGTAGCATTAATAGCAATAACATGGTGTTTCCGAGTGTGGAAACGCGGAACTTGAAGCAGTTCAATTTCGCGGATCTGAAAGCAGCAACCAAGAGTTTCAAGTCGGATGCATTGCTTGGTGAAGGAGGTTTTGGCAAAGTTTACAAAGGATGGTTGCATGAGAAGACACTGACACCCACCAAAGCTGGATCTGGAATGGTGGTTGCTGTTAAGAAGTTGAACTCAGAAAGTTTGCAGGGCTTTCGTGAGTGGCAGTCAGAAATCAATTTCTTAGGAAGGATTTCTCACCCAAACCTGGTCAAGCTATTGGGTTACTGTTGTGACGATATCGAATTTCTCCTTGTGTACGAGTTCATGCCAAAGGGAAGCTTGGAGAATCATCTCTTTAGAAGAAATACTAACAGTGAACCACTCTCTTGGGACACCCGAATCAAAATAGCTATTGGTGCTGCACGGGGCTTGGCTTTCTTACACACCTCAGAAAAGCAAATCATATACAGAGATTTCAAAGCCTCCAATATACTACTTGATGAGGATTATAATGCAAAAATTTCAGATTTTGGCTTGGCAAAATTAGGCCCTTCTGGGGAAGATTCACACGTGAGTACCAGGATCATGGGAACATATGGCTATGCTGCTCCAGAATACATTGCAACAGGTCACCTTTATGTAAAGAGTGATGTTTATGGTTTTGGTGTAGTGCTGCTTGAAATGCTGACAGGGTTAAGGGCACTTGACAAAAACCGCCCCATAGAGCAGCAGAATCTGATTGAATGGGCTAAGCCTTCTCTCTCTGATAAAAGAAAGTTGAAAAGCATCATGGATGAGAGGATAGAGGGTCAGTATTCAACCAAGGCAGCATTAAAATCAGCACATCTTATTCTAAAATGCCTTCAATGTGACCGTAAGAAACGTCCTCACATGAAAGATGTTCTTGACACATTGGAACACATCGAAGCTATCAAGGACAGAACGAAGTAATCCAAGAAACATTGTACTAAGTTTGCAACTATGTGCAATTTCCAATAGCCAATTTATCATCCTTATGTGTTGAATATGACAAGGAGCTCCAACATGTGTAGGCTGTAGCTAGCATACTAGTCACAGTTCAAGTTCAGTGTAACTACTAACTAACTTGGCTTACAGTTATTATAGGTAGTTAGACCTGTTACTGCATGAGTGTGTTTGTGGCTGTATTTGAGTAGTCGTACCTCTCTCATTCTAGCTTTGTTCCCTTGTCAATAAAAATGTGTAGCTCCTACTTGTATCATCATCTTTTCATTTAATTCAATAAAATGAGTTACTTGAA
->XM_039254146.1 PREDICTED: Hyaena hyaena mitogen-activated protein kinase 15 (MAPK15), transcript variant X3, mRNA 
-GTGCTGCGGGCGTCTGGAGGCCCCCGGGCGCCCACTCGCCGGCATGTGCGCTGCAGACGTGGACCATCACGTAGCCCAGCGATACTTGCTCAAGCGGCGGCTGGGGAAGGGGGCCTACGGCATTGTGTGGAAGGCAGTGGATAGGAGGACCGGCGAGGTCGTGGCCATCAAGAAAATCTTCGATGCCTTTAGGGATAAGACGGACGCCCAGAGAACCTTCCGGGAGATCATGTTGCTCCAGGAACTTGGGGACCATCCCAACATCATCCGCCTCCTGGAGGTGATCCGGGCGGAGAACGACAGGGACATTTACCTGGTGTTTGAGTCTATGGACACTGACCTGAACGCCGTCATCCGTAAGGGCAGGCTGCTGAAGGACATCCACAAGCGCTTCATCATCTACCAGCTCCTGCGGGCCACCAAGTTCATCCACTCGGGAGGCGTCATCCATCGGGACCAGAAGCCGTCCAACATTCTCCTGGATGCCAGCTGCTTGGTGAAGCTCTGTGACTTTGGTCTCGCCCGCTCCCTCGGCGGCATCCCTGAGGGGCCTGAGGGCCCGGCCCTGACAGATTACGTGGCCACACGCTGGTACCGGGCTCCAGAGGTGCTGCTGTCCTCGAGCTGGTACACCCCTGGGGTGGACATGTGGAGTCTGGGCTGCGTCCTGGGGGAAATGCTTCGGGGGAGGCCCCTGTTCCCGGGCACATCCACACTGCACCAGCTGGAGCTGATCCTGGACACCATCCCGCCTCCATCCAAGGAGGACCTCCTGGCTCTTGGCTCAAGCTACAGCGCCTCAGTCCTGCCCCGCCCGGGGCCCCGGCCACGGCAGACGCTGGACGCCCTCCTGCCGCCAGACACCCCCCCGGAGGCCCTGGATCTCCTCAAGGGACTCCTGGTATTTGCCCCGGACAAGCGGCTTAGCGCCGCGCAGGCGCTGCAGCACCCCTACGTGCAGAGGTTCCACTGCCCCGCCCGCGAGTGGACAATGGATTCGGCCGTGCGGATCCCGGTGCTGGAAGGAGCTCAGCTCTCAGCCCCTGAGTACCGCAGCCGCGTCTATCAGGTGAAGTCCAGCGTGAAGGGGGCGGCGCCCTCCCTGGCCTCGCAGGCTGCCGCCCTGGGGGCCGTCCAGGCCCTGATCCGGAGCGACTGGAACCCGGGCCGTGGGGCGACGGCGGCCGGAACGCGACAGGTCCCTCGCGGGCTTCCGGCGGATGCCCGGCCCGAGCCCCGGCCCGGCCGGCGGATGTTCGGCGCCCCGGCCTGGCAGGGGGCCCAGGGCGCCGCGAGGGCCGCGCTGGGGGGCTATTCTCAAGCTTACGGAACCATCTGCCATTCGGCGCTCGGCCGCCTGCCCCTGCTCCCCGGGCCCCGCGCGTGAGCCGCCCGCCAGCCTCCAGTCCGGCTCCTGTACTCAGCCCGCGCCCCTCGCCCAGCTCTGGATTC
->XM_016250992.1 PREDICTED: Sinocyclocheilus grahami solute carrier family 7 member 2 (slc7a2), transcript variant X3, mRNA 
-GGTTGAATAGGAAAATTAGCATTGCCTCCCTCTGTGTGAAGTGTCTCTCCTCCTCTTTGGCCAGACCAGCCCTCCTCGTGGGGGGCAGGGCAAGTTAAAGCAAACCAGAACAGAGTAAAGTAGGCAGTAAAACTAATGCGGTTGTGGGCTGACATGTCATTTGAGCTTGAGGAAGGAAGGGGCAAACTTTGGAAGGACTGAGCCTGTGAGCTTTTTAAAGAAATCAGTGGAGATCCCTGAGAGGTGTGTGTGTGTGTGTGTGTGTGTTTGCATGAAACCGTAAGACATTACGTCCATAAGGCAATTCTACAGCTGCCAGTCTCTCATCAGGTGTTTGTGGTAACAGGAAGAATGCTGGAACATTGCCTCGCATTTGGTCGCTCCCTTGTGAGGAGGAAGAATGTGGACCAGGACTGTCTGGAAGAGTCCAAGCTGTGCCGCTGCCTCTCCACTGTTGATCTGATTGCCCTCGGGGTGGGAAGTACACTTGGGGCTGGTGTCTATGTGCTCGCTGGGGAGGTGGCCAAAGGCAGTTCTGGCCCCAGCATTGTGGTGTCCTTCCTCATCGCTGCTCTGGCATCTGTGATGGCTGGCCTGTGTTATGCCGAGTTTGGTGCACGGGTACCCAAGACGGGCTCAGCCTATCTGTACAGCTATGTGACCGTGGGGGAGCTCTGGGCCTTCATCACAGGGTGGAACCTAATTCTGTCATACGTCATAGGGACGTCTAGTGTGGCGCGTGCCTGGAGTGGGACGTTTGATGAGCTTATAGGGGGCCACATTGAAAAGTTCTGCAAAATGTACTTCAAAATGAGTTTGCCTGGCCTAGCAGAGTACCCTGATTTTTTTGCTGTCTGCCTGATCTTACTACTGGCAGGCCTTCTCTCCTTTGGGGTGAAAGAATCAGCTTGGGTCAACAAAATCTTCACAGCTGTAAACGTGCTTGTGCTGATGTTTGTTATCATCTCTGGGTTCGTCAAAGGAGACTCGCTCAATTGGAATATATCTGAGGAATCTCTCATAAACGTTACCATTTGCAAAAGGAATCTCTCACACACTGCTAATGTCACTAGTGATTACGGAGCAGGGGGATTTTTGCCTTATGGCTTTAGTGGGACACTGGCTGGTGCCGCCACCTGCTTTTATGCCTTTGTGGGATTTGACTGCATTGCAACCACAGGTGAGGAGGTGAAAAATCCCCAGAGGGCCATTCCCATTGGGATAGTTATTTCCCTGCTGGTCTGCTTTCTCGCCTACTTTGGTGTTTCAGCGGCCCTCACCCTCATGATGCCCTACTACCTGCTGGATGAGAGGAGTCCCCTGCCTTTGGCTTTTGAATATGTGGGCTGGGGGCCTGCGAAATATGTTGTAGCAGCAGGATCGCTCTGTGCTTTATCAACCAGCCTGTTGGGTTCTATGTTCCCTCTTCCACGCATTCTGTTTGCCATGGCACGAGATGGCGTGCTATTCAGATTTCTTTCCAAAGTGAGTAAGCGTCAGTCGCCAGTGGCTGCCACTATGGCAGCGGGCACTACTGCGGCTATCATGGCTTTCCTGTTTGACTTGAAAGCGCTGGTGGACATGATGTCTATTGGAACCTTGCTGGCATACTCTTTGGTGGCTGCTTGTGTTCTAATCCTTAGGTATCAGCCGGATGCTGCGTTTGAGAGGTCTAGGATCAATGAAGGCAAGGAAGAGGTTGGTGAGTCTGAACTGACGGAGTCTGAGTCTCACCTGAACATGCTGAAGGATGGAAGAGTAACCCTGCGCTCTCTGCTCAACCCTCCACTGCTGCCCACTGAACAGACCTCCACTGCCGTCAACATGTCTGTTATAATCATGGTGTTTGCTGTGTGTGTTATTGGCGCACTCAACACATATTACGGACAGGCCATTATTGCTATGGAGCCTTGGGCCCTGGGGGTCTTAGGTGCATCTTTGTTCATCTTCATCATGTGCATCCTTCTGGTTTGCAGACAACCTCAGACGAGGAAGAAAGTTTCCTTCATGGTTCCTCTGTTGCCCTTTCTACCCATCTTGAGTATATTTGTCAACGTGTATCTCATGGTTCAGCTCAGCGGCGACACGTGGATCCGTTTCTCCATCTGGATGGCTATAGGATTCTTCATCTATTTTGGATATGGAATGTGGCATAGTGATGAACGTAAGAGACATCTACAGAACTGTGGTGTTGCGATGGAGAAAAAGACACTGACAGGAAATGAAGGCACTGTGGAATATGTGACGCACATAGAGAAGACTAGCCCATGTTAAAGAACAGCAGATAAAACTA
->CU677742.1 Synthetic construct Homo sapiens gateway clone IMAGE:100017471 3' read PBXIP1 mRNA 
-GTACAAGAAAGTTGGGCAGCCCCGGTGGTGGTGGTGGTGGCTATGGCTGTGCCCCTCCCTGGGCCCCGCAGCTCTTGGGCTCTGTGAGTGCTTGTCCTTCTTCCCTGACCTCTTCTTCAGTGCTTTGTCTCCAAAGAAGTGGCTGAAGATGAAGTCCTCAAAGTCATCTACTTCATCATCATCACCTGTCTGTTGCACAGCCACCTCCTCCAAGCTGTCCTCCAGGGCATCCACAAAATCCCGGAAGCGGAGGCGGTCATGACGGAAGATGCCATCCTCACCAAAGAAAGCAGGTGAGAGGGGTAGCTCCTTGGTCAGCTGCCCAGCCCAGGGCAGCCGTGCCAAGTATGTTCTTAGCAGAGAGGCCAGCTCCTGTTGCCGCACTGGGGCTAGCTCTGTGCCAAAGAAAGTCAGGCCCTCCTGCCGGGCACACTCGTCCACACCTGAGCAGCCCTGGGGTGCCCGGTACTTGGGCCTCAACAGCTCTGCCCAGGATGGCAGGGGGTCATGGCTGTCCTTAGTCCCTTCCCTCCACCGAGGTTGCTTCTGCTTTTCTCCAGAGGAGTGGAAGCTACCACTTTTTCCTTGGGGGGTCCCTTCGGGCCCTGTCGCTTGCCCTCTTTCTTGCTCCCCCGACTCCTCCACCCTTGGCCTGCCCCTCCTTCCACCTTCCTGCTGGCCTCCTGTCCTTCTGGACCTCCCCCAGTCTTCTTTCTTTTCCCGGCCAAATTCTTCTTTTTTATGTTTCCGGTTTTAACCTTTCGGGTTTTTTGGCCCTCCCCCCATTTTTCTTTCCCCTCCCTCCCTAAAATTCGGAAGGGGAATTTTGGGGCCAGCCTTTAGGGTTTTGGAAAAAACCCGGGGTCTCGGCCCCGTTTCCCCGAGCCTGAATTATTGGGGCAAATTTGGGGCCCACTCTACACACCCAAAAAAAATGGGGCCCCCGGGGGGGATCTCGAAATCCCTTCCAAAATCTGGTGAAAACCCACGGCGGCTGCGGCCCTTTAATATTTGCATAAAGCGGGGCCCACCCACCAGGGTTCTTCTCTTTAGAAAGGAATG
->XR_001314002.1 PREDICTED: Thamnophis sirtalis uncharacterized LOC106555578 (LOC106555578), ncRNA 
-GGACCTGCTGGGGGAGAAGGAGAATCTGGACAAAGAGGCGACCTTGGTGAAGCAGGTTTGCCAGGCCCTAAAGGATCTGATGGCAATCTTGGTGAACCTGGCTCACGTGGGCCCGAGGGAATCCGTGGCATGCCTGGCATAGAAGGATTCCGTGGGCCTCCTGGCCCCCGTGGTTTGCAAGGGGAAC
->XM_050835981.1 PREDICTED: Eriocheir sinensis PEST proteolytic signal-containing nuclear protein-like (LOC126983306), transcript variant X5, mRNA 
-GCCCCCTGGGTCCCCATGGAGACGTCACTGGAGGACCAGAGGCTGCCTGCCCCCAAGCGGCCAGTGGAGGAGGAGGGGGAAGGGGAGGGGGAGGAGGAGCCTAAGAAAAAGATTAGTTTTGGGCTGAGCAGCAAACCTCAGGGCAAAAGTGGCCTCCCTGTCAAGAAGCCAATTGGTGGCATCTCCATCAAGCTGGGCCAGTCACAGGCAGCTGCACAGGCAGCTGGTGGTGCCTCCATCCTGAAGCCCAAGGTGGGTGCAGCAGCAGCAGTGTTCAGCACTGGAGATGAGGACGATGAAGATGAAGAAGAGGAGATGCCACCTGAGGCAAAGATGAGGATGAAGAACATTGGGAGGGACACCCCAACCTCAGCTGGCCCTAACAGTTTTGGCAAGACTAGGATGGGCTTCTGTGACTCAAAAAAGATCTACGAAAAGCAACTTAAGGAGGTGCAGGACAAAACTAACAAAGTAGTGCCAGACAGCGTGTAGGCAAGGTGACAGCCACTGCTGGCTGAAGCCCTGCACCTCACTTGGCCTGTAGCAGGGCAGGAGTGTGCCTGGCCTAGGCTGGCCTGTGCTAGGCTGGAGACTTGTTGGTTATTTGGACATCCCTCCTTTAGGCCTTAAGGTGTAGTAGTGCAGCCTGTCATCATCAGTTGTGTGTATAAATTGTAGCATAAAGCTCCAGGCTCGGGGTTGTAGCTGACTCACAGCACTGGTTGACATCTCGGGGGTTTGAGTGTGTGTGTGTGTGTGTAAACATTTGCTTGTATGTGTGTGTGGTGCATGCATGGTGGTTTTGGCTCTGCACCGGGAGAGTTTGGTTGTGTTAGAATGGGCTGTGTTTGCCAAGCAAGGAGTAGTGCTTTCCTCAGACAGGGACACACTGGTGTGGCCAGCAGTGTAGTGCTCCCCTCACTACTATGTACTGAGGCAGGACACACGGGAAACACCGGTGTTTATTTCAGCTTCTCGCAAGTACTGTGGTGTGCATAGAGTATTTCAGTTTCAACTGTTTCAGGCATGTACTTCATATTTCTTTGAGCGAACTTGTGGATGTTACTGACAGGGATTAACTCTATTAAACTCGACCATAGGCAGTGGTATGTGTCTAGAAGGAGTGAGGGATTGCCGACTTTTATAATTTGCCTGTGTACTTCAGGACATATACCAGTGATTAGGATTCAGGTTTTAGATTTTATCATGCATGCAAGCCAAGGAAAACTTGAGACTACATCTTCAACATCTTATAAAGGAGTATTGTGTCGACCTGTATGGATACTTTAGAAGCAGAGCAACGAGTAAGTGAAGATTTCAGCAGTTTATGTGATGAATGACTTTTATCATTATTACTATTCTGTGTGATAGTGCAGTTTGTGTATCTAACAACCTCATCCTACTGAGGGTCTCTGCGTACCCTCAGCAGCTGCATCACTGCAGAATTTATTGCCTGTCAGTCATTCCCTTGCCGTAGCGAAGGATGATGGCTGACTGGCTTGCCATCCATCTGGGGGCAGCATGGCTGAGTAATACATAGCATTTGTCTGCTTCATTTAGAAATTCTGTATAATGTTCTACATAGATGCATTTTCTGCTATCACCCAGAATGAGCCATTGTGACATTGATATCGAAACTGTAATATGTGTATAAAATATGTAGGGTGTTCTTAAGACTTTTGCACTCACAATGCATTTGGCTATGTTTATAACTACACATTTTGAGGATGTCCAGCTATAGACACAAACATGAGGCATCCACAGGAATCCTTGTAGGTGTGAATGATGTCTTGATTAAGGGAAGGCCAGAAAGGTAAGGTTCAAAAGTTATATTACAATTCATTACAGTAACATCAAAAAATATAAATACAGATTAGTCCTTGACTATACATCTGTCTAGTTTGGCAGTAAAGAAAAAGGCATTGGAAGCAGAGGACATCAACAACCCTCATACGGTATCAATCTTCAGTATTGTTTAAAATTGTAATACAAACATTAATTCCTCTTGCCTACTTTGTGGGTGCCTCATTGCTGGTTACAAGTAATCCTTCAGAGGTCTCATTTAATCCCTCAAAGGTGCCCTCCCAGCCAGTGTTTGCCGGCAGCACACAGAGCAGGGTGGCGGACACTTGGCCCCTCTTGGTGTTGCTGGCACTTGTAAATGTCCCAGCAGCAGTATTTCTAAATTGTTTGGGTTTGTTGTGTTGTAGCTGAAGTGTCCTCTGTTGGATGATACCACATATTCTTGCCATTCAGTTTTGTTTGTCTCTGCTATATGTGGCTGTTATTCATTTTATTTAGTCTGTCTGTGTAATTTAATTTGAAGTATGTGTGGTTGAGAGGTCATTCTACAATGTATCCATTTGTAATTTGTCATTCATCTCTACGGTCTGATGGATGGTTTTACGACTGTACAGAACCATGCAGTATTTCAAGGTTTCTTTCTGTTCAGTATTTGCCATTACTGTTGATTGTTTCTATTTGACCAAATCTGAAGTGGAAGTGGTGTACAAGATTTTAATTGACATACAGGTTGTCCACTTTCTTGAGCAAGTTGCATTTGTTCAGGACACCACCTGAGCTTTTTGTGTATTTTTACCTGAATGTTATTTAAGGGAAGTTACTCTCTGTATTCCTGGTGTTTCGGCTTCTTTGCCAACATCCACAGTCCATTCCTCTCAAGGTGACTTTGAATGTTTATCCTTATTGTTCTCATTAAGATTCACTAAACTGCCAGATGTAGGCTATCTGAGGCATCTGCTAAGTCCATGTATCATTATTACAAACTAACAGGGAGCATACGCCAGGGGGTGCATTTGCTTCACCCCGGCGGTCCCTCTGAGTGAACCCTCATGCAGTTACCTTTCCCATTCTAAGCCACTCCTGGCAGGATTGATCAAATTGCCCCACCCATGAGTTATGAGGATATAGGTTTTTTTTTATATAAAAGTTTGGTGTTCATTCAGAACAACATTGTTGTTCAGTTTTCTTCTGTCATAGCACTAGTGTTAATAATTGTGCCCATATTTTCTGTATTTTCTTATGGCTGTTCTGCTGTACCATTCCATGAAAGACAGCAGCTGCCAAGGAACAAGAGACTACCAAACAAATGAGCTGCACTAGATCACAGTAACAGCAGCACAGAGTAGCTGGCCAATGCAGGGTGCACCATCGCAGCTTCGCCAGGACCCCTTGGGGTCTTCATGACTCAGGTGACGGAAGCAGTGCATCCTGCCTGTGCTGCCCTGCGTCTTGTGTCCTGTGGTCTATACTCCAAACAACAACGTTCAGTCACTTGCGATGCCATACCAAACCTCTTCTTTCAACAAATAAAATTTCCCAAGATTTGTTAAAA
->KP395388.1 Uncultured bacterium clone MISEQ01_89_000000000-A647M_1_1111_13864_15148 16S ribosomal RNA gene, partial sequence 
-AAGGAATATTGGTCAATGGACGCAAGTCTGAACCAGCCATGCCGCGTGAAGGATGAAGGTCCTCTGGATTGTAAACTTCTTTTATCTTGGACGAAAACGGGATTTTTATCTCAATTGACGGTACCAGAGGAATAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAAGACAGAGGGTGCAAACGTTGTTCGGAATTACTGGGCGTAAAGCGCGTGTAGGCGGTCGTGCAAGTCGGGTGTGAAAGCCCAGGGCTCAACCCTGGAAGTGCATTCGATACTGCATGGCTAGAGTCCCGGAGAGGATGGTGGAACTCTAGGTGTAGAGGTGAAATTCGTAGATATCGAGAAGAACACCGGTGGCGAAGGCGGCCATCTGGACGGTGACTGACGCTGAGACGCGAAAGCGTGGGGAGCAAACA
->XM_013051197.2 PREDICTED: Mustela putorius furo actin binding LIM protein family member 3 (ABLIM3), transcript variant X7, mRNA 
-GTGGCGGCAGCGAGCGGCCGCGCCCCCCGCGCTGCCACCCCGCGAGCCCGCATCATGGATGTCGAGCTCTCCTATTTCGCTTTGCTCGCCTTGGAATTCGAGACTCCAGACGAGGACCAGGATTCATGAGCCGGTCGCAGGGGCCCAGGCAGGGGCCTCTGGCTCCCGACGCCGGCCGAAAGGTGATGAGTGAGGTCGGAAGATCGCAAGATTTAAAAAGCAACCGGGTCCTCCGTATCGAATGAAAGACCCAGTGCAAAGGCATCACCATGAACACGAGCATTCCTTATCAACAGAATCCTTACAATCCCCGAGGCAGCTCCAATGTCATCCAGTGCTACCGCTGTGGAGACACCTGCAAAGGAGAAGTGGTCCGTGTCCACAACAACCACTTTCACATCAGATGCTTCACCTGCCAAGTATGTGGCTGCGGCCTGGCCCAGTCGGGCTTCTTCTTCAAGAACCAGGAGTACATCTGCACCCAGGACTACCAGCAGCTCTACGGCACCCGCTGCGACAGCTGTAGGGACTTCATCACCGGCGAGGTCATCTCCGCCCTGGGCCGCACCTACCATCCCAAGTGCTTCGTGTGCAGCTTGTGCAGGAAGCCTTTCCCCATTGGAGACAAGGTGACCTTCAGCGGGAAGGAATGCGTGTGTCAAACATGCTCCCAGTCCATGACCAGCAGTAAGCCCATCAAGATCCGTGGACCAAGCCACTGCGCTGGGTGCAAAGAGGAGATCAAGCATGGCCAGTCACTCCTGGCGCTGGACAAGCAATGGCACGTCAGCTGCTTCAAGTGCCAGACCTGCGGCGTGATCCTTACCGGGGAGTACATCAGCAAGGATGGCGTTCCGTACTGCGAGTCCGACTACCATTCCCAGTTTGGCATCAAATGCGAGACTTGTGACCGGTACATCAGCGGCAGGGTCTTGGAGGCAGGAGGGAAGCACTACCACCCTACGTGTGCCCGGTGTGTCCGCTGCCACCAGATGTTCACGGAAGGCGAGGAGATGTACCTCACAGGTTCTGAGGTTTGGCACCCCATCTGCAAACAGGCAGCCCGGGCAGAGAAGAAGTTAAAGCATAGGCGGACGTCCGAAACTTCCATCTCACCCCCCGGATCCAGCATTGGGTCACCCAACCGAGTCATCTGCGACATCTACGAGAACCTGGACCTCCGACAGAGAAGGGCCTCCAGCCCAGGATACATCGACTCTCCCACCTACAGCCGGCAGGGCATGTCCCCCACCTTTTCCCGCTCGCCTCACCACTACTACCGCTCCGGTGATCTGTCAATAGCAACCAAGAGCAAAACGAGTGAAGACGTCAGCCAGGCCTCCAAGTACAGTCCAGCCTACTCCCCGGACCCCTACTATGCTGCAGAGTCCGAGTACTGGACCTACCATGGGTCCCCCAAAGCGGCCCGAGCCAGAAGGTTCTCATCTGGAGGAGAGGAGGAGGACTTTGACCGCAGCATGCACAAGCTCCAGAGCGGAATCGGCCGCCTCATTCTGAAGGAGGAAATGAAGGCCCGGTCCAGCTCCTACGCGGATCCCTGGACCCCACCCCGGAGCTCCACCAGCAGCCGGGAGGCCCTGCACACGGCTGGCTATGAGATGTCCCTCAATGGCTCCCCTCGATCCCACTACCTTGCTGACAGCGACCCCCTCATCTCCAAATCCGCCTCCCTGCCTGCCTACCGAAGGAACGGGCTGCACAGGACACCCAGCGCAGACCTCTTCCATTATGACAGCATGAACGCCGTCAACTGGGGCATGCGAGAGTACAAGATCTACCCTTATGAACTGCTGCTGGTGACCACGAGAGGAAGAAATCGGCTGCCCAAGGATGTGGACCGGACGCGTTTAGAGCGCCACCTGTCGCAGGAGGAGTTCTACCAGGTCTTCGGCATGACCATCTCGGAGTTTGACCGGCTGGCCCTCTGGAAGAGGAATGAACTGAAGAAGCAAGCCCGGCTGTTCTAGGCAGAGGCTCTATAAATATATATGCATTTATATAAAGATACATGTAAAATCTCTATACTGAAGCTCGGTATAATCCTCTCTTGTGTAATGGGACACACTGCCAGCCATGAGACTTGCTTTTCTGTACTGTCAGGCAAGCCCACGTCATCGAGATATTTTTATGCTCCTTACTTTCTCTTTTCTAAGTGCTCTGGGGTTCGGGAAGGGATTTGAGGAGACTCCCATCCTTTTACTGGGGATCCTTTTTATACTGAAACATCTGTCCTAACCTGAGTCCCCCAAGGTCCAACTCTCTTTCCTAAAGGAGGTGCCTGAAGAAGTCTCTCTTCTCTCTGCTTCTCGGCTCTCTCCCCAGTCTCCAGGGTGGATGCTGACCAGGCAGTTTCCACACCTTACTGGCCCCAGAGGGGCCCTCCCACGGGAAGATCCACAGTGATCTCCCAAAGTCACCGAGCACCATGGAGAGCCCGTGAAGAATTCTCCCATCTCCCCCATTTAGGAGTTCGGTGCCCTCTGGGGGTGATGCCCTTAGCTGTGTGGGCCTTGGATCTACTCACTACAGCAGCAAATGAAGTGGTTCGGGCCTGGGCCTCTCTGCAGCTTCTCAGTCCTCCTCCTCCTGCCCTTGGCCCTAACTTCAACCCAAGTCACATGGTAGGAGGAGAAAAGTCATTTCCCTTCCCTCCAACACCTCCAACTGGTCCCTTTGCCTGGCCCCGATGTGGAGATGAGAGGGAAAGCGTGGGAGCCGGCCACAGGAGCCGGAGCAGGGCACCTGTTGGAACTGGAGCTGCAGGACCTTTTGCAACCCTCCTCTCACCCTCACTGCCCCCAGCACCTCCTAACCCTTCCCCCCTTCAGAGGAGAGGCCCATTATTACGCCTTACTACGATCTATGTGCCTGACAACTCAACACACCACAGGGCTAACTTTCCCATCACAGTTCCAACAGAACAGCTAGACAACCTCTAACTCCCCTCCAAACATAATACAGGCCATGTCCCAAAGAAAGCCGCCTGGTCTACATCTGCAGGCCCCTGGGCTAGAAGGGCAACCGAAGCTGTCCCTCACCAGTCAGTCATTGGCTCCCACTGCAAAGTTGGCCATGTTTCCTAGGGGAAGCCTTTGGAAGAATGGCTGCTTATGGAATTCCAAAATGAAGCATTTGCCAACAGTGCGCATGACCACCCTGGATTTCCCCAGCGGCTGCCTTTCCTGCCCTCTGGCCTTCTTGAACAGCGATGAAAGCTTGACTTTAACTTCTCTCCTCCCTTCCCCCAAACCTTTGAACCCCGGCCCCCAGTTGGCTATGTGTGGTGGGGTCTGTTCCTCCCTGGAGATGCCTTGATGTAGATCATGTTGAGGTCACGGAGGGAAGACGAAGAAGTGGAAATAACCATTATGACTCTCAAGAGGCTGGTGTCGTGACCTGGCAAATAGAGAACTGACTCCAATCCAGCGAACCCTCACTGAGCCCCTGCTAACGCTGAGCACCTGCTGTATCCTGAGCACCGAGGGGGGAGGGAGGTGGGGACACTGAGATGATCAGCACGGGATCTGGACTGGGGGGCACGCCTGCTAGCACTGGGTGTCGTCGGACATGGACTCGCATGTGATGGACGTAAGGCAGGAAGTGATGGAGATGGCATGAGAACGTGTTTGTGGGATTACCGAGAGGGCAGATGCAAGTTGGTGCAGACCAAGGAACTTTCTGGAAGAGATTGCATTTGAGCGACATTCAGGAAGGATCTCTGTAAACTGAGAGGAGACTGTAACTTGAAAGGGTGACAGGGTGAGGGGTCAGAAGGGGGTCTAATATTCTCTCACTTAAAACATCAACCCTCTCTGCAACTCTCCTTTTGGCCAGTGTCTTTCAACTGTCCTGACCCTTTAGAAATGTCCCCAGCCAGACGCAATCATTGAAACTGCCTCATTATCACCGGTTGAGAACTTGGCAAGATGAAGGGCTTTTGTTATTGTTGTTGGGTATTTTTGTTTCCCATAAAAGCACATAATTCCAACCCA
->XM_039549112.1 PREDICTED: Corvus cornix cornix chromosome 2 C8orf34 homolog (C2H8orf34), transcript variant X3, mRNA 
-TCAACGGGCGCCGGCGGCCGTGGAGCTGACAGGAGCCCGCGGCTATCGGCCTCGGCAGCGGCGCTGTGGCGAGCACGGCAGCGCCCGTCACCACGGCGCTGCTTGGCACAGAAACACAGACAGAGACGGACTGACAGACACACGCAGCGCGGAGCGGCGCGGGCTCGGGGGCCGCCTTTGCAGCTCCTCTCCTCCCTGCACCATGCTCCGCTCTAGGCAGCGCCCGCCCGCTGCTCCCTAAGGGCAGCCAGCCCCGCGCCCAGCTAAGCGGGCGACTGGCACCCGGCTCTCTCCCCCCCGCCCCCAGTTACCTGAGTTAGCTCCGTCCCGGGGACTTTCGCAGCGCCTCCGCCCTCTCCCGCTGTGGCAGCCCTTGTGCGGCGGGGGAGTGAGCCGCCCGCAGCCGGAGGGACTGCAGCCGCCGCCGGGGGAGACGAGCTCAAGCCCCCGCCCCCGGAGCTCTTCATGGCGTCTCATCAGCAGACAAGGATCCAAGCCTACCTGGAGAAGAATAAGATCGGTCCCCTCTTCGAGGAGTTGATGACCAAGCTGATAACAGAGACACCTGACCAGCCAATCCCATTTCTAATTGATCATCTTCAGTCCAAGCAGGGGAACCGCAGTCAGCTTCAGAGAACATTGTCTGGCTCTGCTGCCCTGTGGGCAGAGAGTGAAACATCAGAAAATAAAGGAACAAGAAGAGATTTTAGAAGTTATGATAAGCCTTGGCAGGTAAATGCAAAAAAGCCTAAAAAGTCAAAGAGCGACCTTGCTGTGTCCAACATTTCTCCACCATCACCGGAGTCCAAGTCATTGCCAAGGTCAATAGAGCATCCTAAATGGGATTGGAAGACAAAACCGGAGAACCATGATTTTGATGAACTAAATCATATTCTTCAAGAGAGCAAAAAGCTTGGAAAAGCCCTTGAGAATCTGTCTCGCAGCATTGCTATTTCTGATGAACTTGATAAGGACACAGCAGGTTTCAACACCCCCCTTCTCAGACCTCGTGTGATTGGAGAATGGATTGGCCGTGAAGAGAATGATGCAGATCCTCTGGCTGCTGAGATGTTGCAGCCACCAATACCAAGAAATAAAAATGAGCAGTGGGACAGTGAGGATAGCAGCAGTCCTGGAGGAAGCTTAAAAATGGAGCCAAAGACCAAAGGATTAAAACATCAACAGCAGCAACATAAGAAACTGCTGGCTGCCATGCTTTCTCAGGACTCCTTTGATTCTGCTCAAAGCACAGCTCCATCTGTAACCGAAGAAGACATTGACAATGAAGATGATGCAATGGAACTACTGGAGGATCTTGATGATCTCAGAATGGAAGGAGTAACAAGTGTGGTATCCTCTGGGAGCAAATTCAATCAAACTCGAAGTGCTCATATGGCTGAGCCTCAAGCAAAGGTCACATTGAATATATGTGCAAGATGTGCCAGATTGCAAGGGGATAATTTGGCAGAAAGGCCAGAAGATGTCTCCATGGTATCTCAGACATCTGAGCCAGCAGTGTCAGACTCTGATGCTCAAGTACCTGGGGTTGAAACACTCACAGAAGATATTGATGAATTTCAGAGTGCCTCTCAAGTGGCAGCATCTTCTCAGACAGTTTGGACCTTGGATGCCATGACTGTCAGACCTGGAGGTTCCCCAAGGCAGAAACTCCTAAAGGACTCCTTAGCAGCAAAAGAACTTCAGACCATGGAAAAACACCTAGCTGACATTGAGAAGGACCTCGCACTGTGGGAAGAAGCAAGGCTTTCAAGAAGCCCTGGTGTCCAGCATCCCAGTGTGGTTACCTCTGACCATCCAGGCACTCTTCAGGCTGCGCAGGGCCAAACCCCCAGGCCTCAGGTGCCAACTCCGATGGGGAAGAACATTCAGCTCCAAGGAAGCAAATCACCACCGCTGCCCACTAACAGCAGAACACAGGTCTCCAGTGTCACAAGCAGTAGACCTTCAACGCCTGCTGCACAAACCAACAGGCCATCAACTCCAGGGAGCAGACCTATGACCCCAAATAGCTTGTTGTCACGGCCTCTTACCCCTAGCAACCAAGGAAATAGGGAAGGCATTATTAGTATTCAAAGAAGCAGATCTTTGTCATCTAAGAGCCAAATGGGGAGGACCCTCAGTGCCGCTTCAGGGCTTTCTGTGCAAGATGAATTCTTACAACAGTTTCAACTTGCTCATCAACCTTGGATATTGCCAAGTGACACAGAAAGTGAAGGAGTGGAAGCTGACCAAGACAAATGTAAGTATATATGTAAGGACCAGATAATACATCAAAAACCGTCAACTTAACTTCTATTTTCCATATATTCAAATACTGTGGAGATGTCATGCCTGCTCACAGGAGCTTTTCTCACAAGTACCAATTACTTATTTGTCTGAGGGCTAGACCTTACAGGATTGATTTGCAGAAGCTTTCCTGCAGTCACTGAGCAATGACAAAATGATCACAGACCACACTTTACTTAATCTAAGTGAAACAATTTGTCCTGATGTGTTAAAGTAGCTATTCCAGAGAAGTAACCTGAACTTGAAATAGGCAGTCTGTTTAATAAATCTGTATTCACCAGCAAAAAAAAAAACAAACCCTAAAAAACTTCAGATCTGAAAAGCAGAGCCTCCCTTCTTAGGCCTGTCACTCTATTGTCTCTGTTTTGCTTGCATTCTTTTTAATTCATCTGTATTAATAAAAAAGTTCTTAATCATACAAGTAATCCTTAATATCCTACACTCTTTGAAGTATTTTTGTAATCATGGAAGTGAAGGTCAGCAGGATCAGAGCCTAAATGACAGAACAAGTAACTACAAGTAACAGGCTATAAATTGCAGTTCTTTCAAACTGTAGCAAGTTCCCCCTGCCTACAACATACCTGTAAATGATCTTACTGTTTCACATTTTCTTTAATTCACAGTAATTTTGTGATCTGCAAGGGTGAATATGCAAACTGTTTCCTAACAGATTTTAGGTGATACACTTGAAAAGAACAGATTATTTAATCAGCATGTTTAGAAAATTCAGTACTGGTTTAAACATGAAGAGTTAACATATGAAAAACACATTTTCTTTACAGAAGGGAACAATTCTATAAGGGATTAAGGATTCATAATAAACATGCCAGATAAACAGAATGTATTTTTACATTATGCTAGTTAAAAGAATTGTTTTCTACTCATACATCAGTTTCACAAATTCATACATAGCCCAGAGTTTGACTGAAATTTAAATTTATGCAGTGAGGTTCTGAAGAGCATGTGCCAGGTCTTTTTGAGCACTAGTAAAATGTTAAAATGAGATTGTGTGCATCCAGCTGATTTTAGTCCAAAGCCAGTAATATGACTTCCACCAGAGCCTTTCAGTTATCTTTGGACTGAAGCTCCCCTTAGGAGGCTCAAGAGATACCCTGTCACCTGCCTTTTATGTGCATGCAATTTTTCCTCTGTATTTTCTGTAATGAATTTACAGTCCTACAAACATTGGTTGGATTGGCTGTGCACACACAGACTGATGCCAATTATGTGACCAGGGAGACTGATGCTCCGGGACATATCAGGTACACAGCATGGTTTCTTATAGCTGCTGTACTTGAATTGTGTGGGTGTGAGGACTTGTGAGCACCTAAAATCCTGTACTGTAGTATTCCAAGAATCCTGGTAGGTCACTGTCACTGCCCAGAAAACAAAGTGTTAAGTTAAAAAAGTATGTTGTTAAGGTCAATGTCCAAATCCCTCTTGAACAGTGACAGACTTGAGGTAGTGACCATCTCCCTCAGATGCCTGTTCCAGTCTTTCATCCTCTCAGTAAAGGAATGCTCCCTAATGTCTAGTCTGAATCTCCCCTGGCACAGCTTTGAGCCATTGCCATATGTTCTGTCACTGAATACCAGGGAGAAGATATCAGTGCCTCTCTCTCCACATGCCCTCCTCTGGAAGCTGTGGACAGCAAGGTTGCTCCTCAGCTTCATTTTCTGCAAACTAGACAAGCCCAAAGTCCTTAGCTGCCCCTCACAGGTCATTCCTTCCAGCCCTCTCACCAGCTTTGTTGCCCTTATCTGGACACATTCAAGGACCTTCACATCCTTTTTAAATTATGGTGCCCAGAAGTGCACACAGTGCTCCAGGTGAGGCTGCACCAATGCTGAATACAGTGGGATAATCACCTTCTTGAGGAGCTGGTGGTGCTGCGTTTGATGTACCCCAGCATGGGGTTTGCCCTGTTGGCTTCCAGGACACGCTGCTGACTCTTGCTGTGCCTGCTGCCAGCCAGCACCCCCAGATCCCTTTCTGCAGAGAGGCTCTCCAGCCACT
->XR_008192058.1 PREDICTED: Gossypium raimondii uncharacterized LOC128035582 (LOC128035582), ncRNA 
-TACATAATAGATATATATACAGTTTTTCCCTACCCTACCCGTCATCCTCTTTTCTCTTTATCCTCTCCCTCAATTTTCCTTCTTTTCCCTTCACCGTGTCTCCCATCTACCCTTTCTTCTTGCCACCCTATTGTTTAAGCTTTGATTTTTGTTTTTCCACCTACCTTGCTGATCGTTTTACCCTCCTTAATTAGCCTTATTTGCTACCCTAAGTCACCTTAAAGCCGCCCCTATCAGTCTCTTTTATTGCTCAATTGTCGCCCCTCTCCATTGTTGAAGTAGTGCCACTCTAAGAATTCATCTTTATGGCTGACAAAGATTCCCTCTTGTCTCGCCCTGTTCTGCATTTTTCTGTCGCCGTTTGTGGTGTTGCCGCCCTTTAAGACACCACCAGTTTGGACAGTCGTTCCCTTTTCAGTTACCACCCTTATATCAGTGTGCTTTTCGAGTTATTCTTTATTTATATCTGGTCTAAACGTTCTAAGTTGGCAAAGTAACCTAGGTGATCAATGGCTAACTCAGATCTCGGTAACGAGTAGTGCAAAATGTAGATTTGTGTGAGATCTCGCACTGTTTCGTTTTGTTGTTAAGTGATGCTATGGTCGAATACCCTAAGGCTTGGATATGGAATTTCGTTGCGGATTTTTGGGTATTTAATGTGATTTAGGTGCTGATTTGAACATCCCGGATCAACAATAAAACCAGATTTCATCCATGCCCTCGTTTCGTAGCAAATCAGTGCAAGTTGTTCAATCGAATTGAACCTAAAATTTTTGGCATGTAGCACTGATTTGGCCGATCCATTAAAGGGTGTTTCAAGGCTGGTTTTAATGGTAGTTAATGTGGTAGTTATTGTTATTTGGTGTTAGGTTCGATTAAGGAGTTAAATTTGGAACACAAACTTTTTCAGCTTAGTGCTGCGGATTTTTGATAATAAGGTGGGTTCTAACTTGTTAAAAAGTGCTAAAATTATGCTTTTAATGATTAAA
->XR_004466254.1 PREDICTED: Bombus vancouverensis nearcticus uncharacterized LOC117166512 (LOC117166512), ncRNA 
-CCGTTTTTCATTATAATTACGATTATAATATATTCGTTTTAATTATAATTATGCTGTATTGTTGCGATATCAACGTACTACGTTGCGCTTTAAATTAAAACTTCTTTCTGTTAAAAAAAAGCATCGTTCCAAGTCGACTTCTTTTGTTCTTTCGCGGGATTCTTAGGCAAGCCGTCGCAGCCACGCTGCAGTTTACTAACCGAGCGTATATGCATGGATTTACCGACATAATCCAATAATATCGTAGGTTGCAGACACAAGATCGCGCTGCGTAATAAGTCTGGAAATTCTCATGGTACTCCGTATGAAAGCCCAGCGACTGTGGCCGTAATCTGCAACATTGCAGAATGCACAACTGCAGTGGAATAGCCTACAATTATAGAAAATCAAGCCGTAGGATTTATCAACACAGCCTTCACCAAATTATATCTGATTTATGCAGATTCGCAGAACATTTTACAGAGTCTAAAAATCTACTCCCTTAAAGCCGCGATAAATCAACACAATTTAAACAT
->XM_049312721.1 Wardomyces moseri uncharacterized protein (JN550_001527), partial mRNA 
-ATGTCTAAAAATGGAGACATCAGAGGGTTCTTCGCCAAGGGAGCGCCGTCCAGGGCTCCTCCCCCGAAGGCATCGTCTGCTAGCAGCGTATTGCCTGCCTCCCCGCCGGCGGCCGAGCGGGCCCATCAGCCAACACCTACACCTTCGTCACAGCTGTCGATAGATCTCCCGTCGTCGCCTTTCACACCACAGAAGCAGCCCGTCAAGACACCTCTGACAAGGGATGACGAGATCAGGGGCTCAGACGACGAAGACGATGACTCGGATAGTTCTCTCGAGTCGCTCGGGGAGCTCCTGGGACGTAGATCTGGCCCGGCCACATACCAGAGGCCTACGGCGTTGACGACTACTCCCAAGGCCAAGAGGATTGCACCCAACAGCTTTCACCGGTCTCCTCTGACGCTGCAGCAGCAGCCTACTCACAAGTTCGACCTCAAGTCTCTCATCAAGCATGCGAGACAGGACGATGCTACCGAGCAGAGTGCTCGACGAGCTGACGAGCTCAGGGTGAAGGCGGACCAAGAGGAGCTCGAAGCTGGGCGTGATATGGCCGACAAAGCCAGGGACGTTTTTGGCGGCGAGGATGGGGAGAAGGGCGACAAGCTGGCCAGGGCTATTGACCGCACAGTAGGCGACGAGTCTAGACCGCGCTGCTATTTCTTCGCTCTGGAGGATGAAGCAGCCGCCGCAGGCGCTGGTCCCAGGCGGCCGTTCCCCAAAAAGGCAGCCAAGGTCAAACCGTGGACCTTGTTGCAGGATAGCAAGACCCGAGACCAGATGTTCATACGCGGGATGGTCAGCGCTGTGGCTGCAAAAGGGAAGGAGCTGCCAGACGAAATCTACCGGTGGATCCTCGACGAGATATGTATCGAGGAGAACCTTCAGCTGCGGAACCAGTATATCAGGTCGGCCGCGCTGTGTTGTGATGACACACGGCGTCTGGTTGACGAGAGGCAGCTCTATAAGATGCTGGAGAAGATAGGGGGCCAGAAGCATGAAACCTCGAAGCAGAAGTTCGAGCTATCGCCTGGGCTGCAGGACCCCTATTCGAGGAGAGACTGGTCTCCTCTTCGTCATTTCTTGCAACTACTGGCGGAGATGGCGCCCAATCTGACATCAAAAAATGCAACGAGCGCAGTGCAACTGCTTTTACGCTTAAGCCTCGACCCTGTGGTCGACAGGGCGCCGGGCGTTCGTGCCGAATACGCCAAAGCCATGGTCGCTCTAGAGTCGGCTCTACCTGCTCCAGAGGACCAGTGGGATACATGTTGCAAGAAGATATGCAATTATCTCCATCAAGGTGTAGACCAAGTGACGCAACGCCACATTGCCACCGTGATGCTGCCGACCTCTACGCCTCGACTGGCTGACTTGCAGCGTAGGCTGGCGACAGTAGCCCTCTTCGACGACCCGGGCCTGGGCGCCATACATCCCGACGAGTCCGTCACCATGCAGGACCTCTTCGCCCGCCTCGGGGCCAAGAATTTCCGCGTAAGACACTCGACCGACTTTGACGAGCTCAACGCGCTCCTCTCGCTGTTCGACATGGTGCTGGACCGCGGCTCGCAGTTCGGCCGGGCCTACCTGTCGACGACGCCTCTGCCGGCCCCCACGCCTCAGCCCAGGCTCGCACCGGCGCTGCCAACCCCGGCCTCGTCCACGTCAACCACGACGGCGGCGAGCACGGCCACGACGCCGTCGCCGCGGTCGGAGGCCGAGGCGGCGGCCCTGTTCGACGCCGACGTCGACCGGCTGCGCGCCCACCTCAAGGCGCTGCACGACAAGATCGCCGACAACAGCCTCGTGTCCAGCAAGGTGGCCAAGGCGTCGCTCGACGGCATGATGAAGCGGCTGGCGTTCACGGTGCGCAGCCGGCCGCCGCCCAAGAGCAGCATCTTCGACGAGGCCATCTACGGGAGGGAGAAGGAGGACGCGCATCTGCCGCGGCAGCGGGATTTCATGAAGAAGTGGAGCGCGGCGTCGAAGGGTGGCGGCGTAAAGAAGGATGAAGCTGACGATAACGAGGGCGCCGCCTGA
->KY685464.1 Uncultured Glomus clone M01338:4:000000000-A3V74:1:1101:10809:13957 18S ribosomal RNA gene, partial sequence 
-CTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAATTTCGGGATCAATACGTCGGTCGTGCTTCGGTACGTACTGGCGTCATTGATTTCTCCCTTCTGACGAACCATGATGTCATTAACTTGGTGTCATGGGAAATCAGGACTGTTACTTTGAAAAAATTAGAGTGTTTAAAGCAGGCTCGCGCTTGAATACATTAGCATGGAATAATGAAATAGGACGTTCGATCCTATTTTGTTGGTTTCTAGGATTGACGTAATGATTAATAGGGATAGTTGGGGGCATTAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACC
->XM_032084393.1 Aspergillus pseudonomiae uncharacterized protein (BDV37DRAFT_269601), partial mRNA 
-ATGTCAAGCCTTGTCATCGGGACTGCGCCGGAGGGTCTGGACTTGTCCGAGGATAGAATCGCTCAGAATGACGCCACTGTTGGTGTTGTCATGGGAATTGCCACAATTTTTGTGGGTTTGCGATTCTGGGCGCGAACGACTAATAAGAGTGCCAATTTAGCATATGATGACTGGTTTGTCTTGGTAGCATTGATCATCTTCGCTTATGTTATTCTGTATGCCACGACAGTGCCTATGGTCAAATTGTCCGTGCTTCTTCTCTATCGCCGGATTTTCCGCCTCACCTGGACGTTGTATTTCTGTGCATTTCTCTCCATCGGATATACTATCTCAGTTGTTACTACCATCTCGCTGGCTTGCGTCCCCTCATCTTTCTTCTGGACTCAATGGGTATATCCTTTGAGTGGAGGCCACTGTCGGATCAACCTCTATCAATTCTATTTGTGGAACGGTGTGGCCAACTTGTTCACCGATGTCATCATTTTATGCCTGCCCATGCCGATCGTCTGGGGCCTGCAGATGCCCAAGGCGCAGAAATGGGCCATTAGCGGTATCTTCCTGCTCGGTGGATTTGTCTGCGTGGCCACGATTGTCCGCATCTCCGCCATCACGAAAATGAAAGATTCCGTCGACATCACCTGGGTAATCGGCGACGCCATGATCTGGTCCAACGTCGAGCCCTGCATCGGTATTGTCAGCGCGTGCCTACCGACTCTGCGGCCCCTCCTGCGCCAAATTCCCCAGCTAAGAGTCTGGGGGCTTTTCGGCAGCAGTGGACTCTCGGGCAATTACAAGATGACCGGCGACGGCACTTCCGGCACGGGACAGCAGGATACCGGCAACCGATCGGCATATCGGTCCTCGACTGGTAAGAAGCAGCGATTCTGGCCAGAAGATGACGAAATCTACCTGACTACCGACGTAGGACGTGCTGCCAGAGAGGAAGGCGTCATCCCGTCCAACGGCTCCGCTGCCTCCAGCCAGGAACCCATCGCTATGCAGATCAGGGTGAAGCAGAACTTCGATTGGAGGGAGGACCACCCATGA
->XM_048215029.1 PREDICTED: Ursus arctos zinc finger and BTB domain containing 20 (ZBTB20), transcript variant X11, mRNA 
-GCACCCAATGTGGGCCTTCTGCCGAAGAAGTAGGGGCGGGGGGAAGTTTAGGAGTTGAGGAAAGAAGATTAAAGAGCGCGAGGAGGAATCTTTTGGAGGATGTGCTACATCCAAATGAGGAGAAACTGAGAAGGAAAGAGGAAGACAGAGGATTCAGGAAATAGATGATGATAATGAGTCACACAAAAAGAAGTATTAAGGATTGCCTTTTAAGACTCTGAAGACTGAAGAGTGCCTGATAAATTGCACGTCTGTCTGTGCCCCCTAGCTGCACAGACTGCCTGAAGTTACATTTAGAGACTGAAATCACTGCACCTTAAAAACAAAAGATTGAGCTGCACTGCATTCCTAATGTATCGCCATCACTAACTGGATATTCCTCACAACTTTGCTGTCCGAGGTAAGGAAAAAGAGTCCAGAGAGCCCATGCCCCCTGGGTCTCATCCTGTGAGGCACTGTCGAAACCAGAGTAGAACTCAGGCCTCAGCTGCCGTTCCAGAGCTCTTTCTATAAGTTCCGTGACCATCAGTCTGTGGCCTGACCCTTCTCTTTATATGCAGCCGCTCTCTGTCCCCTGCCCCAATGAACATCTGCACTGCGCCCAAGCCTTGGAGTGATTTACCTGAAGAGTGACACCATTTCTTTGGAAACTACTATGAGGAAACTGAAGCCCAGAGAGGTGAAGTGAGGTGCCCAAGGCCACACAGCAAGTTAGAGGCACAGCTAGTACCATAGCTCAAGTCTCCTGACTCCCAGTCCAGTGCTCCTCCCATTACTCCACGGGTCCTGTGTCTAAGCTTCCTGACAAATGCTAGAACGGAAGAAACCCAAGACAGCTGAAAACCAGAAGGCATCTGAGGAGAATGAGATTACTCAGCCGGGTGGATCCAGCGCCAAGCCGGGCCTTCCCTGCCTGAACTTTGAAGCTGTTTTGTCTCCAGACCCAGCCCTCATCCACTCAACACATTCACTGACAAACTCTCACGCTCACACCGGGTCATCTGATTGTGACATCAGTTGCAAGGGGATGACCGAGCGCATTCACAGCATCAACCTTCACAACTTCAGCAATTCCGTGCTCGAGACCCTCAACGAGCAGCGCAACCGTGGCCACTTCTGTGACGTGACGGTGCGCATCCACGGGAGCATGCTGCGCGCACACCGCTGCGTGCTGGCGGCCGGCAGCCCCTTCTTCCAGGACAAGCTGCTGCTGGGCTACAGCGACATCGAGATCCCGTCCGTGGTGTCGGTGCAGTCGGTGCAAAAGCTCATTGACTTCATGTACAGCGGCGTGCTGCGCGTCTCGCAGTCGGAAGCCCTGCAGATCCTCACGGCCGCCAGCATCCTGCAGATCAAAACAGTCATCGATGAGTGCACGCGCATTGTGTCGCAGAACGTGGGCGATGTGTTCCCGGGGATCCAGGACTCGGGCCAGGACACGCCACGGGGCACTCCCGAGTCAGGCACATCGGGCCAGAGCAGCGACACCGAGTCGGGCTACCTGCAGAGCCACCCGCAGCACAGCGTGGACAGGATCTACTCGGCGCTCTACGCATGCTCCATGCAGAACGGCAGCGGGGAGCGCTCCTTCTACAGCGGTGCGGTGGTCAGCCACCACGAGACTGCACTCGGCCTGCCCCGTGACCACCACATGGAAGACCCCAGCTGGATCACGCGCATCCACGAGCGCTCGCAGCAGATGGAGCGCTACCTGTCCACCACCCCCGAGACCACGCACTGCCGCAAGCAGCCCCGGCCTGTGCGCATCCAGACCCTGGTGGGCAACATCCACATTAAGCAGGAGATGGAGGACGATTACGACTACTATGGGCAGCAAAGGGTGCAGATCCTGGAGCGCAACGAATCCGAGGAGTGCACGGAAGACACCGACCAGGCGGAGGGCACTGAGAGTGAGCCCAAGGGCGAAAGCTTCGACTCGGGCGTCAGTTCCTCCATAGGCACCGAGCCTGACTCGGTGGAGCAGCAGTTCGGGCCCGGGGCGGCGCGGGATGGCCAGGCCGAACCTGCCCAAGCCGAGCAGACCGCAGAAGCGCCTGCCGAGGGCGGCCCACAGCCGCACCAGCTAGAGACAGGTGCCTCCTCCCCGGAAAGAAGCAACGAGGTGGAGATGGACAACACGGTCATCACTGTCAGCAACAGCTCCGACAAGAGCGTCCTGCAGCAGCCTTCGGTGAACACGTCCATCGGGCAGCCATTGCCAAGTACCCAGCTCTACTTACGCCAGACAGAAACCCTCACCAGCAACTTGAGGATGCCTCTGACCTTGACCAGCAACACACAGGTCATTGGCACAGCCGGCAACACCTACCTGCCGGCCCTCTTCACCACCCAGCCCGCGGGCAGTGGCCCCAAGCCTTTCCTCTTCAGCCTGCCACAGCCCCTGGCAGGCCAGCAGACCCAGTTTGTGACAGTGTCCCAGCCTGGCCTGTCAACCTTTACTGCACAGCTGCCAGCGCCACAGCCCCTGGCCCCATCCGCAGGCCACAGCACAGCCAGTGGGCAGGGCGAAAAAAAGCCTTACGAGTGCACTCTCTGCAACAAGACTTTCACCGCCAAACAGAACTACGTCAAGCACATGTTCGTACACACAGGTGAGAAGCCCCACCAATGCAGCATCTGTTGGCGCTCCTTCTCCTTGAAAGATTACCTTATCAAGCACATGGTGACGCACACGGGAGTGAGGGCGTACCAGTGCAGCATCTGCAACAAGCGCTTCACCCAGAAGAGCTCGCTCAACGTGCACATGCGCCTCCACCGCGGGGAGAAGTCCTACGAGTGCTACATCTGCAAAAAGAAGTTCTCCCACAAGACCCTCCTGGAGCGGCACGTGGCCCTGCACAGTGCCAGCAACGGGACCCCTCCCGCGGGTACACCCCCAGGTGCCCGCGCTGGCCCCCCAGGGGTGGTGGCCTGCACGGAGGGGACCACTTACGTCTGCTCCGTCTGTCCAGCAAAGTTTGACCAAATCGAGCAGTTCAACGACCACATGAGGATGCATGTGTCTGACGGATAAGTAGTACCTTTCTCTCTTTCTTATGAACAAAAACGACAGAAAAGAAACAAACAAACAAAAGCTATGGCACTAGAATTTAAGAAATGTTTTGGTTTCGTTTTTACTTTGTTTTTGTTTTTGTTTCGTTTCATTTTGTACTACATGAAGAACTGTTTTTGCCTGCTGGTACATTACATTTCCGGAGGCTCGGGTGAATGATAGTTTTCCCAGCCTCCCTCGGATGGTGGCCTTAAGGCCTGGTAGTGCTTCAAGAGGTCCACTGGTTGGATCTCTAGCTACTGGCCTCTAAATACAACCCTTCTTTACAAAAAACAAAAAACAAAAAAAAACAAAAAAAAAAATCTTAAAAAAAAGTAAAAAAAAAAATTTTTTTTTCACTTGTGAAGAGCACTACAAAAATATATAACAAAATCTAAAAGGCCTACTGTCTTTAAGTACACCGCTTGCAGTGTTTCAGTGGACATTTTCACAATTCTGGCCGCTTGGACTTCACAGTAACCAGTTAAAACTGTGGAATATCACTTCTGGTTGAAAACCCAGAGGAAAGGCCCTGCTGTTTTCCACCTACCACATTTTCTGATTTCATAAAAGGGCTGGGGGGGTTGGGAAGGGGCAGTGGGTCCGGTGGTGTGGGGAAGGCGAATGGCAGGCTTCTCCCCCAGATTTCTGCTCGCGTCCACACACCCTGGCCCACCTCCTCCGTGTCTCCCCCTTTCAGCAGAAGCCAGGAAGACTTGGACAAGCATCAAGCAACAGTGGCTATCGTATTTATTCAGTGTCTTCGCTGAGCCACAGCCTCAGCACAATCAAGAGGGACTTTCATGAAGGGCAGGAATGCAGATAAAACAAAGATATCAGAGGTTTGCACCTACGTTTCTAGGTACAAGAGAAGGATTATTTCCCACAATCTTTGCAAAAAACAAAAACAAAAAAAAAGTGTCAGGATATATTCTTGTGGAAGAGAAAAAGAAAGAGAAATGGAGGGTGGGGGGTATAATAAAAAGTTCTTGAGGCTTTTTTAATTCAAAATTTTATAGAGGGGCAAAAGTGACGTTTACCAGATAGAATGCTGATTTTTTTAATATATTTACAACAGTATTTGTGTAAAAAAAAAACAAAAAAAAGTGAGATTGTTAAAAGTAATTTTCTTTCGTTTTGATTTTGCGTACACTGCCACCAATCCCTTCTCTTATTTTATTTCACACACATATATATATTTTTTGGTAAGTCAAGACTGTTAAGGTTAGCGATACTGCTTCCAGATAGAAAGAATAAAAGGCAATTAAAGTTATATTTGAAAGAGAGGAAGGATATTTTCTTCATATTTTTTTTATTTTTTCTTAATTTTTATTATTTTAAGTATTGCCTGGGTTGATGAGGGCCTCTGTGGCCAGCCCATCCCTGCTGTAATTTGAACTGCTGCTTTGTATTTTGATATGTAGTTCTTTGACTTTTAGCAAGCTTAAGTTGCTCCACTGACTTTTTTTTTTCTTCCAACTGATCCATCTAGAATTCTGTTCTTTTTCATGGGAGGACTTTATCTTTCAGAAACAGATTTCCTGCTTCTCTAAAAGTTCACTGAGGTCTTATGATTCTAGAATGTCTCTTGACTTGACTTCTTTTCTTGAATGAAACACTAGTAGTCTAGAGGTCGTGACAAATGGGTTTTCCTTCTGTGGTCAGCCAGGAGGAGGAGTTCATGCCTCCTCACCCTTCACAGCTGCAGAGAGCAGAAGCCTGGTACAGATCAGGATGCTTGATGCCAAAATTACTCTCCTCCTTTCAGATATCACCTTCTGACTATTTCCACCGTGGTTGAGAGGGCTAATGAGATGATCCTCCTTCAGAGGATGTAGTAACCCTTGCTTTTTGGAAAGATTTTAAGGAAATTAACAAAAATTTCTCAGATACCAACATCCATCATTCAAAAGGCCACCAGTTCATTGCATCATCCTGGATGCCACTCTCTCTTCCTAGTTGGGATTTCTCTCCTCGGTCCTGATCAAAGTATTGTAATAGGGATTTTTCCATTATAGACAGTGTCCTGAAGGGATTCCGACTCAATTATGAGAATTCTTACACTTAACAAAAACTCCAAAGGTGATTTTATTGCTGGGCATATTTTAACACTCTTAAAGGGGAAGAGTAAATCTTTAAACAAAGCAGAAACACCAAACTGTAATTTTAAAAAAGAAGCAAAGACAGAATTTTAGTTTCAAAATTACTTTGCATTTTAATTTTCCTGTCAGCAACTTATTTGCAAAAACTGTGCATCAAATGAGGAGACATCTTCCAAGGGAAGAAACTCTATAATGACTAAATTGGTTTTACTCATATATTTTAGATATTGGTTAACTTGGATCTTTTCCATACGTTCTTGGTGATGTTTAGTAGGGTTAGTGCAACTGGAGTACATGTGGGTTTTATTTGGTCCTCCGGTCCTCAATTCGGTAAATATTTTACTAGAAGTTTAATGTAGACTTGGATGGTTAACTGATTATTGGGTGTCACTCATCGTGATTTCTAAAAGGAGTCATATCAAGAACGGTGTGTCCAAAATTGACCTGTTTTAGAAGTTAGTGGGAAACAGCTTCAAAACTAAGAAAAAGTCCATTTTTCTCTTGCTGATTTTGCTTTTTAAAATAGCAGTGTGGAAGACTTTAATATTTCCACTTACTACCAACAGAGGGAGCGTTACTTAATTAACCACGTCCTGGGATTGTTTTGATATCTTGAAAAACAAGTCATTCAACCCAATATATAAAAAAGAAAAAATTAACATTAAGGAAAAAAGTTGTTCAATCTAGAGGGATAAATGACATAAACTCTCTCAGCATACTATACAAATGAGCTAAAAGACACTTAAAAATATTTTCAATTATTTGACAGTAGCTGATTTAAGATAGTGTCCTTATTCCAACCTTCGCAAAGTAAGCAGAATTTATAGTACCTCTAAAAAAATTGATCTTGGGTGCCATTTTGGGCCCCATTTAGCTATCTGCTTCTCAAATCAGAGGGAAACCCGTTTGCCTTAATGTTGATTTGCCATGTGAAAAGTGAAGCAGTTGGGTTAAAACGAAATCCATATTTTGTTATAGAACATACAGAGGGAAAAAATTCCAGTTGGGTTTGAAGCACTAATATTCATCCTTTCCCTTCAAATGAAGTATCTCTTTTTAAAAAATGTTGGAGAACTCCCAGAGAATTCGTGGTGAGGTGATGCAGTCATTATAACCACATGGACTCTCCAGGTTTGCATAGCAGTAGACTTTTTCCTACCGTATGTCTATTCCTCTCAAACACTCATAGTCTAAAATAGTTGACAGACTTGTACTCTGGAGAGAGGGAGAAGCTAGACTGCAGTGGAAGGTCTAATCTGGGGAGCAGTGAACTTGCTGTGGGGTTATTACAATATGTTCTGACCTCCTTAAAGGGCAACTTTCCCCACGGATCTAAACCAGACTGGACCGATTTCTAAAGGATAGAGATGCTTTTAGATTGCCAATCCTTACTTTTAAATTAAATAATTACCAACATCTTAGGAAATGGGGAAACATATTTTGCTTCAGGAATAGAGGATGAACATGAATCCTTTTATTTTTTAGTTTCAAATCCAACAATCTTCTTACATTTAGAACTTCATGCTAGGATGCTATGAGTGCTAAAAAAAATTTTTTTTTCAGTAGTCAGAGGAAAAAATAGATAAAATGGAAGCAAATGTTCCAGATTTAAGACCTCTTAGGATGAATACAGGGAACAAGAACTAGTTTGGAAAAGAACTTTTTTTTAGTAATTTATGATTTAAAAGTGGATTAGCTGAACAAGGGAAAGGAAAAAAGTCAAAGGGGAATATTTATGTCCAGACATTTAGATACAGTGTAAGAAAAATGAAATTTCCCAGCTCTGAAAACATTGGTAGCATCTCAGCATGGAAGGTAACTTTCCCCCTATTACTATAATAAATGCAAATATTTATACTAAAAAAACAAAAAAACAGAACCCAAGTGGTAAAATATGGCCCTCAAAAAGAAAGGAATTGGAACAGATGGATCTGATACAAATCTACACATGGGAAAAGATTAAGAAACAAGCCAGGCAAAGATAATTTGAAATGAAAGTCTTGATAGCAAAACGGTTTTTACTATATATTTTAATTGAGTTGTAAACTTCAGCTCCTGACAATAGTTTATAGACTTTTTCCTGCCCAAACTCCTAACTCTCTGAAACTGTTTGTGCCATGAGTAAGTGTGGTGGATAACTTCCTTCTCGTGTTCCAGCTTTAGTCCGTTCCTTCTTCATAGGCATTTTGGAGGTCACGGTAGCTCCCAGCCTTAGAAGAAAAGACTTGGATTTGCTTTGTTGAAAAGTCATGGGTTTTATTTTGTATCATCCCAATATTCTTTAAGGACCAAGAAAACCCTTTAACCCATGAATAGTTAGAATTTGTGCATTCTGATAGGAGAAGAACAAGATTTCCTCTGGGCGTGTGTGTTGCAAGTAAGTCCTAATGCCTTGACCTACGTGTACCTCCATCATATAAGCACGCCAACAGTGTGTGGCCAGCCCATACGTACCCCAAATCTGTTTTCCCTCAGCAGTTCCATCAAATGAATCGTGCCCCTTATAAAATCCCTCAGGTCCCTGACAGAACATAATAAAGGTTCATGTCGCTTCCTCCATGTGCTTCCTCCATAATGCTCCCAACACCTGTTGCCCCTAGGAAAGGGGGCAGTGAGCTAGATCTGGCTGGGATTCACACCCAACATGCCCATTCAGGAGCCCTCCTCTGCTGTTATGGAAGATGTTATTTAATTAGCTGAGGCTGGGAGCAGAGGGTACGTGATTCTGCAGCAAAGTTATCAGATAACCAAATCAGATCTGCCTCTGCTATGCAGAAAGAAACAAAATGAAGGTACAATGTAAGAGCAGACACAACCTGAGATGCCCTTGGGATTTGGGAGAAGGGAGGGTGCCCTTTCTGTTGTGACCTGACTCTTAAAAGAAATCTCCTGAAAGAATTCTTTAATTTAGTAATGAGTTGAAGTCCAGGGTAATGGAAGCCCTGGGGAAGAGAACAAAAGGACTGCAAAGTGTATTCAGCACCCAATAATGCGAAACCAAAAAACATCCAATCACAACACTAGGAAGTTTGGCAAAAAGTATTTAGAGAAATCTCTGGGCTTTCCATGGGTAGTAGGGTCGACAGACTTTCTTTTGAGTGATTTCTGGCTCTGAGAAACCTCTTTACTCACTAGAAAAGAACTTTCTTTAAATGGCCAATTTTATCCCCCAGAAAAAGAAATTTAAAAAAAATAAAATAAAAATAGGACACTAAAGACAGAACCATGTGACCCGGTAACAAACAAAAGGAAGGGTGCACTAGAATTTCAATAGAGTCCCTAATTCCATAGAAAAAGCAAGGCAACCCAACGCCTCTCCATCTGCAGTGCTTGAAGAGAGTGCTTGCGCCGACCCCGCCCCCCGGGGCTTTCTGGGGCTCCACATAACTTCCCCATTGGGTTGGCGGCAGCCCCTTTCTCTTCTTGTTGACATGAAGGAAAGGACTGTTCTCTTAGGTGCCCAGGAAATAGATTGCATGGGGCAAACTTTCAAAAGCTATCTCTACCCTGGTGCTCCGGCAGCATATGGTGAGAAGAAAAGGGACACAGAAGAGCCCTTGCTCTTGAGTGAGAATATTCTCGTATCCCCAAGGGCTCTCCGTGTGGAGTTGCCATTTCTAAGACCGTTTAAACCTCCACAAGAGGAAAAGTTGTGGTGACTCAGTGTTCATATAAACACAAAACGTGGAAATTGCTAACCCAAAGCATCGTTTCTAGCGCTAGGGATTAAGCTGATTAACCTAACCAAAATTCCCCCAAAGATTTGTCTAAGTCTCCGAATACATTTTTTCCCCTTGAACCCCGAATCCACAGTGGTCAGCGGTGTACATTGACAGATCCCAGACAATGGTTTGGAACACCAGGGTTTATTTCCAGTTCTTTTCAGGATGAAGACGTAGAGGATGAGGGTTGTACCACACGGGTTCTTTTTCAGAACTGTGTATTTCACTGAAAAAGCGGTACAAATGCCCCGGGTTGAAGCAAGTGACTGCAACCCCTGGATTCTGGTGGTTCCTCAGGCCCAGCCTAGTGCTCCATAAACTGAAACCCTTCGGACTAAAATCTGATCTGAAGTGACCTCAGTTGAGGGATTTTCACCAGACACCACTTACAGTGTAGAATTATTGCCTTAAATCAGAAAGCCCAGGGAAGAGAACAGAGGACAGAGGGGTCGGAAGGGTGTGAAGACATAGACATTTCTTGTTTTTAATGGTTGCATCGTCATCAGAATGAGCGCTCTTCATGATTGAAGATGATGGAAACAGTGGCTTTGCAGGGACGCATCACACTTGTCCGGAACTGATGGTTCTTGGGAAGTGGTTGCTCTTTTTTCATATCCTATTTCAGTGACAGAGGTCTGGGCTGGGTGTAAAATAGGCATCATCTTAGTCAAAGAGCAAATCCCATAAGACATGGTCACAGGTGCCTGGGATGTCAGTTTTCTTCATTTCCTTCATAGGGAGAACAGTCTCTACAAAAGCTTTCTTTCTCTGTACGGTATATATTTCTAAACTCGGTTTTCCTCACTTTTCATAAGCATCTGCTTTATCTGGTGGTTCTTTGTTTAAGTGCAAACTCACGACTTTCAAATCTTCAAGGAAGGAGCATAATCTGCAGATCATAGAGGAAATCTAGCCACGTTTGCAGGAGTCCTGGCTTTTGAGATACTTAATTAGGGTAGAAAAAGTTGCTACTAGCCCTCTTTCAAATTCAGGGCTTTCCTTGGTTCAGATGCCTCCATGAGATTCTGATACACCTAGAATAGAAAAAAAAAAAAAATTAACCCCATCAGAGACATCTGTTTCTACTCCTGTTACAACAGAAGTTTGTTATTGCCCAGCAAAATCATTGTAATTTATATGTAGATTCCAGCAATGAAAAGGACCTAACCCAGCTACTATGTCACAGCTGCTGTGCAGAATGTCCGTAAATGAGCACACGTTCTGCACGTACACACGCAGGGTGAGGTGCTCTCAGTACAGAGCTGTTCCACGCTCGTATTGCCCAGGGACAAGATAGATTCTGGAACTTGAAATAGTCCGGGCTCTCACAGATCTCCTCTCTGCTTCTGCTCTGCCTTCTTTGGGTGCACCGGTGCCGTCCGTTCTCTGTGATGAGGTTCTGGGGCATTCTGAAGGAGCTCAACCAGCAGTAATTTCTATGTACCTGTTTCATGAGAAACTTGACTATGCCATGTGGAGGAGGGCGCTCTTAATGAACTCCGCACTTGCACTGGATTGACTGGCGTGCGTGGACGTGTGGTTTGCGTGTGTACGTGTAGTCTGGGAGTGTGTGTGCCTGTCAGAGGAAGCACACACAGGCCCAGGTCCTGGTGCGTAGATGCAGTTGCCTCTGCCTACCGTTGTGCTCCAGACTTGTGGCTCCCTTCCCGGGAAGCAGTCACCTGCCCACTCTGTTGCTTTTCAGAGTGTTTCAGAGTTGGGAGAAACAAAGGCAGCTTGTTGGATCCACAGCAATCCTACGGTGACAGGCTGTTTTCCTCCAGAAGAAGGTAGAACAGAAGTACTCAAGTGGCGAGCAGACACAGAGAGCAGCAGTCTGGGGCACCTCTCCGGGTCTTCTGGGAGGGAGGAACACCGAGGCCAGGGAGGCAAGACCCGCACAAACTGTGATCTGAGCCGTCCATGGCTGAAAGGCCTCCATTGCTCTCCTCTGTGCAGCCCAGCGTGTGCCCACAAACACTGCTCGGCTGTTAAGTCTCACTCCCAAACGGAAGCTTCCTGACCCTGCCTGTATCTGCAGGACGTCATCCTAATTCCAAACTGTGTCTCCGGAAACCAACGTGGCCTTTGCCCAAGTCTTTCCAGGAGTGGGTTGTTTACCATGTCTAGCAAACCAGTAGACTCTCGGGGGAATCATTTTTGGTAATCTCTAAGAGTTGATGGCTCTGGCCCATCTCACACATTAAAGTAGAACGCCATTCTTGCACACTATTCTGAACAAATGGACCTGGCTCTCGTAGCTGACCTTAGAGAACGGCCTGGAAACAGTCGGATTCAGTTTGCTCCCTCCCATGCCCTTCTTTTAGTAGGTGGCTTATTATTTTTTTTGTGACATGTAGATGATTTCTGCTAATTTACAGAATTCAGAGGACGTTTTCTTTCCTCTTCTACTTTGGTGACTTTTCCCCTACCCCATTAAGTAAGGCTACTTACAGTTAGAATCTTTTCATTGTTATTATTTTTTAAAATGTATATTGTCTTTCTATATCCAAAAGAAGTCTGTGACTGTAACCATAGGTATTTCTTTTTACTGGAAAAAAAAAATGAGGTTTTTTTTGTTGTTTTTAATTCACAGTACTAGTGACTCTGTGAAAGAACGTGAGTTACATTTAGGTATGCTTACTTAAGTACAGTACACTACGTTGCAGTATTTCTGAAAGCTAGAACATACACATTATATATAACAACTCTATATTGAAATATATATTACATTATATTCATTTTAACTTTTGAATCCGCCTATGATCATGAGTTGATTGACATATTATTTCTTCGCATTTATCACCCATCACCAACCTGCTGCAGTTAATCTGGTGCATTTAATAATAATCACGACTGCTCTAGTTTGCTTTTTATATTATCAGCTTCAGTATTGTCTTTACAGGATTTTAGAATTTTTTTAAGCTCAGACTTAGCAAATGTAGGAAAGTGAAAACATTTTTTTAAGAAAACTTTGTTTTTTTCAGTGTGGCCGATACAAAGAGGTTCATATTCGAAGTGGTCTTGTTTAGCTGACCCTCTCAATATCTGAAGAACAAAAGAAGTGCATATGAATGTATCTGTGATTTTCCCTTTGAGGACTGTCACTGTCTATATTTGCTTTAGAAAATATGACCAAGGGGCTGCTTAACCTCCGTATGATCTGACCAACAGTTACAGGCTGCCGTTCAAAGGGCTGCTCATAAGGGAATGAAATGCCTAGCGTCCCAACTGGATTTCCAAACCTTGATTTCCATACTGCTTCTTTACGGACTACTGTTTGTTTTCAGTGTGCTTTACGATTATTTTACCTAGTCTTCAATGCTCCCCTGGAGGCAGCTTGACAATATAACATTCATTTTCCTAGGAGATTTTCTTTCTTAAATAAAACCAGAATTTGAGGAACGTTTTCATGACAGAGGCCGATAGAAATAGAACCGAGAAATAGCTCATTTTTTAGCCCACAGAATCCATAAAATGGTGGCTCTTGGGTGTCTGGCCCTCCGTATCGCCATTCGTCTGTGAAAGTGGGGATTTGGTGCCTTTCTTCTCCAGCCAGGTCATCATGGAAACTTCAGGAATGAGGCATCCTGTCTTCCTAGCAAGAAATATTTTCTAAGTAGTATTTTCAGATAAAGAGCTTCTTCGGCTTCTCTTAGCTACTCAACCCAGTGCCTGGAAAACTCCACTGTTGGGTAAACTTTACATCCATCCTGGAGACCTAGAGCCGGATTCATTCTCTCAGTTCTCCATTCAGGACAAAATGACAGCAGTTTTTGATACTCAGTATGAAAGCCCTTCCCATACTGGACCAATAGTAAAGCCTCTCAGTATGACTATAACACCAATTCCTTCCTTTCGTCTCTCCTAATAGATTTTTATTTCCAAATCCCATCCCATTCTGCTGTGCTCCCCCAACCGCAGCCCTGAAACAAGTCTTTCCCAACCTCCCCTTATTCAAGCTCCCAGCAGTGCCCCCCACTTGTGAAGCCTGGCAGACCTACTTCAGCCTACTTCAAAAGGGCAACATTGAGTCTAGTAGCAAAATTATGAATCTGTTTCTCCATGGTTTTCAACTAAATATATTTCTACAGGACGGACATAATTGTGATTTGGGAGTCAGTGAGGCTGCTCCTTTTCCGGTGATCACATAATACCCAAACTGTATCAGTTTCATTATTTTCCTCTTTCCTTTTCCTAACCACGTTCTTTTATTTCTTGTTTCTCTTTAGGACTACTTTAAATTACCTTTTCTTCTCCTCATCACCTGAGGAACTCGAGTAATTATGACCCCTGAGTGCTCATTTCCCTCCTTTCCCCCCACCCCCTTCCCGAATGTCCTTCTCTAAGTTTTATGCAGTTAAAGAGCATTGACAGGAGTCAGCTCATCAACTTGAGACTCGTAGGCAGAGTGAAGAAGAAGAATGTCTTCACTGTACCTTCAAATTTTAGAAGTTATCAATATTCTTTTGAGAGTGGGAGGACCTGAGTCACAGTTTTAAATGTCAGCTGTACTAGTGAGGTCATTAATTCCTTTCACCTTCACATTTGGCCAAAGGTAAAGAAAAAAAATATACTTTCTGGGTTTTTTTTCTTTAAATATCACAGCGTTCAAATTTCTGATATGAGTAGACCATTTCTGAGAGGAAAAAAAAATCATCAATGTTGGCTGTTTCAAGTCCTGCTAATATTTAGCCAGATGACATATTTACCCCATACTAGATTTACAGAAATCTGAAGAAAGAGGTAACATTGTAAGATAATTTTGATAACTGCTCAAGCCTTAGTAAACTCTTTCAAAACAAGTAAAGCCACTTCCACTGAAGTAGGAGGAAACAATTAGGAAGAATTTTTTCATTTGTTATCTTTTTGAAAAACAAATAATTGTTGATTGATTTGGAACTTCAAGCAGTAATTTACTGAGGGATGAAAAGATCCGTAAAGTGTCTAAAGTGTCTATTTTACAAACAGTTTTTTTTAGATATATATATATATATATATATACATATATATATGTATATATATATATATATCTGACTGGATACTTGAAGGGCCATGTAATGTACTCCCCAGTACCTAAACACTCAGCATATAATTTAGTCATCATGCTAGATCTCCTTTCAGTGAGTCATAATTGTCTGGTTGGCAAAATGTTGCCCAAAAGACTGATACTGTTCTGGATCTGTCCGTTACAGAATGTTCATAATGTAATACCCGCTTTCCTCACTTCCAGTCCATGACTCTTGCCATGCTCCTACAGTGCCTCTTGGCTCTCAGGAAGACAAATTCTGCGGCATTTAGAGTACTACCTGGTTCTGAGTGCACAGACATGCGCTGTTTTATTTCTTGCTTTACCCACTGACAAACAGAATCAACATGTAGTATCAGAAATGTATTCCTAACGTGACGAGAGGCTTGACCCATCTCTCCTGCCTTAATTAAACCAATTTATAACATCAACTCACACCACAGAAAGCAATGAAATAAAGAGAGAGTTCAGAACCTTCCTGAGTTACACATCTAGTAGGACCCCAGCGTTTCTTCAAGCCAGTATTTATGTTGCCTACGGTGGCGATCTTCACTTGGCACGTTTTCCCCGTCAATCCCATCTTCCTCTCCTCCTTTGTCCGTTCTCCCTCTATCTCTTCTGTAGAAGGACTCTTCATCTAAAGTACTCTTCTCCCCAGGCTTTGGCTTCTGAAACAGTAGAAGACTCTCTTTTAAATCCTAATGACTAATGTTTAAGGTGTAATGTGGCGTAGGAGAGGATTCAGTTCTGCCACGTCCCGTTTGGTCCAGTTAATCGCAAGGATTTCTCCAGGATGCCTCTTTGACATTGTTCCTTCTGGTTCCCCGAGAAGAGCTCTAACCCTGAGACCAGGATTTCTCCCCACAACCTCTGCATTAGTCTAGGTTAATGTGCAAATCCTGCTAGCATTCTAGAGACTCCAGGATGTGACTCTCTTATTGCTTAGGAGCCCCCTGCTTTTCGAAACTGACATCTGTCAGGAGCAGCAAGAGCCCTACCAGTCACTAATGCAGCAACACGATGGTCAGAAACATTATAGTACATAATAGGGAGGATAGGAAGAGATTTCATTCTTCTTTTCCCCCATAAAAAACTTGCTTCCCCGCCCCACCACCACCATGCATTTCAGAAAGCCTGCATCTCATTTTACAGATATGTAGTTTTAGGATTCGCAAATATAGCTTAGGAAATGTTCTGAGATTGAAGCTGGTAGCGAACCAGTTTATTTTCTGCACTGGACTTTAGGACAAGTGTGCACAGATACAATTCCTTCAAAGAAAGTGAAACTGATATAGTAAAGCAAAGGGATAATACTTTGACACATTAAAACAGTTGTTTGCTCTCTGTAAACCTTGACTTAGGCATAATTATTATTTTTAGAAACCTGAAACTGGAGGAATGTGTATTTTAGTAAAGTTTGTTGTCAGTTTATTTGTTTCCCTTTATCTCTTTCTTCTCGAGATAGTGAAAGATTTTGATTCTTTAATTTGATACTGTCCCTGGCCATAGGTATCAGTCAAATAATGCCCACCCTTACCATACGCTTTTCCTTTTAGAATGAGAGCCTTCCTTCCTGCCATTAAAGAGTCTTTTCTCCTTGAAAACCTTATCTTCCTTTACAGTTAGCATGAGAGAGCTTTGAGGAGAGGGATTCTCTCTGCACTTTGAGGGTAGAATCGTTAAAATAAAAACTATTTCTTGAGATAAACCCCATTTACCCAAACTAACAGGTCTGAGGCCAAAGAATGGGAATTGATTGCAGATGAAGGTCTTGTATTTTACACTACAAATCTTTATTGCCTCCTCCAGTTTTTGGAGTAAGGCTGGGAATAACTGAATGAAAATCTGCTTTGGATGTTTCTTACTAATATCTAATGCAGAATACCCAGAAAAGACAAAGAAAGGGTGCTGCTTAAATGCACAATCAGTCCATAGATTTCTATAATTATTCAGATTTCTCTTCTACTCATTTCAAAAATATGTGTCCATGAGGTCTTCACTAGAGAAACATCCGCTTCTCCATTGTTCCTCATCTCCCCCACCTGGCACTGGAGGGGAGAGTCACAAGGGAGACCGGTGCCGCATCGCCAGCCCTCCACCCATCTGTACCCCACCACCACCACAAGATAAGGAAAAACCAAATTAGAAACTTTTTTTGAAAAAAAAAAAAAGGGAAATTGTAGTGCTTCATTTGAAAGAATACTGTTTTTAACTCAATTTACAGATAGCCTGACAACCTTTTTATAACCTGTCTTTTGTGCTATAATTTGCATTTTTAGCTCAATCTTTAAAATAATTGCAATTTCAATTAAGTGAACAGAGGAAAAGCAAAGAGGGGAGACAGGGCAATGTGATGGGGCTAAATCTGATACAGTTCTGGATTCATAAGGCCAGTTCTCAGGGTTACCAGGGAAAGCTAACACCACTCACCCTTACCATTCTTGCCCATCCTTACTATTAGAGTCTTAAAAGTTGGTCAGAAAACCTCACTTCCTTATGATTGAAGACTTTTCTTATTACTGTCAAACCCACATTGAGAGAAATGGTACAAACCCCTGACGGCACCTCTGCCTGAGCTTCCTCCAGGGCGCGTGCGGAGAGATGCCGGGAACCGAAGTGTGGGCTCAAATTTGATACAAGACTCAGACATGGTCTCAAGTGCTTTGTGTATGTTCACTGCCAAGGGGTTCGTTGAAAAATAAGGCCAGTTTCTCTGCTCCTGCTGTCCTTGGGACAAACTTTGACTTGGAACCCTCTCTACAATAGATTCGTAGGAGAAAATTCTCAAAAGCATCGTCAGCAGTTCAGCTCCTTCCTTAATCCCATTGAGTTGAACCTCAGTTTTCCTGAGGAGCCCTACTGAGGTAGAAATCAAAGGTAACTTCCGTATATTGAATGAAAATTGGCTTTTTGCCCTATTTGTTGAAAGGATTGTGGTTTTCAGGAAAAATGAAAGCAGAATTTCTTAGTAATCCTCATCATGGCACACAAAGGCAAGAAGCTGATAGGCTAGAGAAAAACCTATGATGAACTTTTATGTTTTTAAGCAATCTGACTGTGCTGACCCCACTATGCCAAACGCCTTTGTTTCTACAATCTGTTCTCAACTATGGATTGATTCTCCTGAGACTTCCAGCACGCGTGTGTCGTTTGAGCAGACACACAGGTTTCCATTTGGAGAATGGAGACCCAGACAAGCCAAAAGCATCAACTCTCACGAGTATCAAATACAAATCATTTCTCCAGAATCACTCAGTTCTGCCGTATCCCAAACCAATTCCAGACTAATCTTAAGTGAGAAGTAAGCTCCATAAGATATCCTACTATGAATGTTTTTTCTTACAGAATAATACAAGAAGAGGTACAAAGCAGATTCTTAATTTGGGTGTAATTATAATTCACTTTTATATTTAATAGTTGTACTGTTTGTGTGAGTGTGTCGTTGAGCTATTAGTACCAATTTTCAATCTGTCATCCTGAGAGGGGCCTTGAGAATTTCTGCAATTTCTGCATATGTGTGTGTAGATCTGTATTTATGTGTTGTCAGAAAAACAAAATGAACGGGGGAAGAACGAGGGGAGGGAGAAGGTGGTCAATGTGAAGAAGGGACTGCTCCTAGTGTCCCTATTTCTGTTAGGTCAGGTGGCTGCTGCCAGAAGCCCTCCAGGAAGAGTTGATTGCACTATTCTAAAATAAGAGCCCAGCACTGTTAAATTTAGAACCATGTTTTGGGAAACAGGAAAGTTTTATCTTTTTCTGTACCCATTCTCTTTAGCATCAGAGCCGTTTGACATGATGAAAACCATTCAGTAAAAACCACTACTGACCTTTGCATTAAATAGCTGTTTTCCTCTTCTAAATACTAGCCCTGGTTTCAACTCATCTACTTCCCTTTATTTTCTGCCTATTGATTTTAACATTTTACAGAAGAATACAGAGGCGCATGCTAGTTGTTCCTCTCCTTTGAGCTGAAACAAACAGGGGCAACAAGAAATGACTCACTGAAGAGTGAGGTCAAGACTGAATTTCCCACTTGTGTGGCACTGGTAACCTTTAGCAAGAACTGTTTAGGGTTGACCTTGGGTCTATATTAGGGCTTTTTTTGGGGGGGGGTTGTTTTGTTTTTTTGTTTTGGGTTTTGTTTTGGTTTTTTTTTTTTGCACTAAATATGACTGCACTGCATTGCACTACTGAAATGTATTTACTTGTGCTGGGAGAGAGTGTGTGAGGTATGGGGGAGAAAGAGGCAGTTATGAAACAGGAAGCATCACAAAAACGGAGAATTCTTTCCGCCGTGCTTGGTCTTAGCAGGGTTGGTGAGAATCTGTGGAATCTGCTAACTCTTGATCAGGCCCAGAAACTGCCATGCTGATAGGATCTGTTGTCTTATGGTCAAAAAGCTGGGCTGGTACAGTAAATTGGAGATGTTTAAGGAAAAGTTTGCCCAGTGTTGTCTCCAACTATGCTTCTGGTAAGAGTTGCAATGGGTGAGGGAGCCAGCCGAGGTGAGGTTGAAGCCTTCACCTTGGCCTCCACCACAAAACCCCTTGCTGACCCACATTCCAGTGTGGCAGAGGGCGGTGGCGTGTCCTGCTTTCAAAACAAAACAAAACAAAAAACAAAAAGACAGCCTTGTCTGTATTGGAGACATCCTTTCAGCCTGCGCATGCTTTTCTATCCCTGGGTGAGACCTAGATGAGCCTAACCAAAGAGGAAGGCCGTGCACGGGGTTAAATCCTTTAAGATGGCAGTAAGGGAACAGTGCAATAAACACTGAAAACCAGTGAGGTGAAGGGTTTATTTTGAAACAAGGTAGGCCAACTTTGAAACTGAAGGAAGGGTTGGAGAATTGATCAGAACCTACTTACTAGCTGCTCCATCGTAGACTATCCTTTATTAAGCAGAAGACCTTAACAGTGCCTAAAAGTTTAGTTTGGAAGTTGCTGAACTTTTTCAATTTTTTATTGGATTTCTTTTTATTGCCTTTTCAAACCTGAGAAGTAATTAGCGTGTGACAGCTCTTCAGTGACTATTAATAAAAGAATCTTGCACCACAGGAAAAACAATCAATTGTGTAGGGCACAATAACACCAGAGTGGAGATGCTGAAGAGCTCTCCCAGAATCCAAGGCGACAGCTTGGAAGATTCTGGTTCTGTGAGAAAGGGTCACAACACATATACATGGGTAATGTTGAATTTCTCTGAACACTATCACATGTGGGGACATCAATTTGGAAAACTGTCAGTTGAGGTCTCTTTCCTAAGATTACAATATTGATACTTCTCTCTCTCTCCTTCTCTCTCTCTCTCTCCTCCTTAGCATCCATCCAAGTCTACTATTACAAGGTAAAAAATTTGTAAGGGAACTGTCAGCCTTGTGAGTCAGAAAAAAACACCACTTAGGGCTTTCAGAACTAACGTAAGCAATCCCTTAAGCACTCAAAGCATTATCTCAGTTTTAAATAGGAAACTCTAAATTCAGAGCTATTAACAGGTACTTAGAGATGTGTATTGCGTAAGCACTAAGACGGTATTGACTGCACCAAACCAAAGGTATAGAAAGAAATAATTGACCTTTTAAGATACATTCACATTAACTGTCCTAGGATACTTCTCTTGAGGCTTTGGGGAAACAACTTCTTTTGTGAAACTTGCATACCCATTCCAGTTTTGTCACCAAAGATTTTAATCACCAGAGCCTAATCTCCTCTCTCCCAGATAAAAATAATATGACAGGCTCAAGGGGTATGCTTTGGTGGTCAAGGGATGACACTTTGGTTTTCACTGTATTCACGGTGATATTTACAGGACACTCGTTATTAGAGGAGCTACCGAACTGTCTTCATGACTTAGGGTTTGGCCAGAGGTTTAAAGAGATAGGTGAAAAATAAACAATAGTACCTTGACACTGTAAACTAGTCTTTAATAGAGTCATGACCTGAAGACTGATGGAGAGAAAGAAACTTCCAGGGAAGAGAGTGAGCTAAATCACATAGAACTAAACAAGGATCGTTGGTGAAATGTGGGGCAGTGTAAACAACAGAGCGGATCGCTGCTCTTTGTGGCCAGACCCACAGCAACGGCCGGGGGCGAGTCAGACAACTGGCAAGTGAATTCAAGTATTGAAACAGCCGCGCTCTGGGTTTCGCTGTGGTTGGCGGAGCCCATGGCAAGGACAGTGCTGAGGCTGCCCTGTTGTGATAGTGCCTTTCTTGTAGCAAGTACTCGGTGAATAATTTGTTCAGTTAGGCTTTTCTGGACCATTACCCCCAGTCTTCTGAGGAGGTCTGAAGGGATAGTGTTCACTTAGGATGAAGGGACAGGATATTGCTCCTGGGATGATGTGATTTGATGATATTTGCACTAGATTCTAAACTCTACTTTAAACTGGAGCAACTGAATAGAGAAAAACCAAGGATGGTTCAATGTTAAAAGAAACCAAAAGCAGTATTTTCTAACTGATGCCTCTTCTTTTTCTTCTCCTTACTCTTGTTCTTCTCCTTCTTCTTCTTTTCCCTGGAAGGGAACTTCATACCTGCTGATTACCAAGCTCAACTCGAACCAATTCTTTTCCTTCCTATTTTTTCCCCACACTGAACCTTCAGTGTGAATTCGCCATCAGGTAGGCATGGTTAGTGTAAAGGGCGTCTGTCATTACAACTTTGCACCCGTCCTCTGCGTCATCAAGGGCATGAGGCAGTGGGGGGGGGGGGGGACGGCGAGGCTCCTCCAGAGCCACCAGCCCTTAGGACGGGTGAAAAGCAGAGATTTCCTATGGAGAGCTGAGCTGACACATATTTGTCCAGAGGACATTGGAGCCTGTAATTAATCCCAACGAATGCTTAGAAAGAGAAGGAAACCCACGTGTTGAAGAAAAACAAGGAAGGTGGTGCCCACAGTTTGCCTGTTTCCCCTCTCTCTCCTCTTTCCCACCTCACCCCCCTGTCCTCTCTCAGAATTGTATTTCATCTTTGTATTTATGTTACCAGAAGAATTATTTGGTTCCTTGGTTTTTCTCTTTATCAGTGGTCTGGGAACTCTTCCAAAATCAGAAACAGGTACCATCAGTGGCTCCCCTGTAGCCTACCAGTTTCTCAAATGCTGTCCACCTGGTCTTGACCCAGTCAACTAAGATAACTCGGAAGCTTTGGCTGGCTCAACCACCTGTCACTTTATTTTCATTTTGTTTTCATTTCCATTTGAATTCTGAGTGATCTTATGGGAAGGTGGAAATCACAGAAAAGGTTTAGAGGCTGCAATTCTAGGGCATAGCTTGTCAAGAGTTTGTATTATCCAAAATATAGCTTTCTACGCCTGTTTTTCTGTTGAATCTGTTGCCCTGATTATAATTTCTATTATATTTGCGGTTATTTTTATAAGAATAGAGTCCATTTGCTATGTCTATTTGAGTACTTTTTTTCTATTTTCCCCACATGGATGCAGTACCAACCTGTTAATGAAATATCTTTTTATTATATTATTAATATGTAATTCTACTGTAGACCAAAAATATAAAAACAAATTTGCTCATTTTAAAGATATAAAGAACTAGTGAGTTAAAGATGAAGAGTTGAAGGAAAGACAGAAGAGCAGTGGTTAACTATGTTGAGTTAGAAATCTAAGAGTAGCCTTACCTATTTTTAACCAGTGCTTGCCAGTCATACCATAGTTGGGATTATATAGTCTTGGCTCCTTCATGCTTATGTTCTATAATTTTTGTTTGTCTGTTTTTCTTTGATGTAATTGAGGTTGCACATCATGCTATTTTTGGCGATGCCTGATTTTATTATATTGTACTTTTATCAGTCATTTCCTTTAGAAGGATGGGGGGAAAAGTTTTATTTCTTTTTTTTTTTAATTTAAAATTTGTTTAATGCACTGGAAATAAAATTGGACACATTTCACTGTTCAAAAATTCAAAACCAAAACAGAACAAAAACCACAAAGAAAAAACCAGCAACCAAATAAGCAACAGAAAAAAAAAAAAGCTATGAAAAAACCACCTATTCCTACCGAATACACATATAAAATCTATCTCACACAAAAGAGAAATATCATCAAACAAGAAATATAAGTCCTAGAAGTTACAATGCTGGAAAGAAGACAGCTGGGCTCAGTGGGGATGGGAGACATGGGGCATTCCTTTGAGATCTGAGATCTCGCCCTGGTTCCAGTGACTGCCAAAGGGGTTAAATGTGGGAGAGGCAACTATGGAGGAAATAAACCCAGCATTTCTGGAACTATCACCGTTTTATCCTATGCTTGGGCTCCATTGGGGGTGCGGGGGGAAGATGTGCTATGGTTGAGAAGGTGGCTTGTATGGAGGTATGGGTACAGTCCACAGCCGCACGCAGTTCAGGTCTCTGTCCACCAACTACCTCACGTGTTTCTTTTCTCCGTGAGGATTTCAGCGGACGGGCCCGAAACATGGGAGAGACCGTTCATGACTCGTTAGAACATCAGCCAATGCTAAAGAACCTCTTGACTGCAAGCTCACCCCCTTCTTCAGCATTCCCGGTACCAGCAGAGCCAGTCAACCCGTACAAACGCACAGTGAGAGGGAGACAGAATTTGCGTAGCGGAGCGGCTGTATCATTTGTTTAACGTTTGCTGGGTTTTTCTGGTTTGGTTCTGTTTTGGAGTCGGGGTGGGAGTGGATGTAAGTACACAATCCTAATACAGTAATTGTTTTGCATCTTCCATGTTTTATGCAAAAACAGACATTTAAATCAATAACTAATTGTGCCCTAGACTGAAAGTTAATGTTTAGGAGAGGAAAAAAATTGTTGGAATTTTTTCTACATTTTTTTGTGAAGAATCTTTTTTGGAAAGGAAGGATACATATTTTTGTTGTGTAATATTTTCTATTTTTGAATGCATTTTATTGGTACAAGACTGTTTTTTTGGTGAAGACATTATTTAAAAAAAAAAAGAAAAAAACTAATCGAAAAGTTTGCCCTTAAGGATATGCTGCAGTTTTGAGGTTAAAAAAAAAAAAATAACTGATTCAAGATGCGTGTTAAAAGTTGGGATTATATTGTTGTTTTTTGTAATTGTTACAAGAAGAAGTTTGTACCCACTGCTGTTTATTTTGTTTCAGATGAGTAAGTAAAGGGATTGTTCTTGTTTTATTCTTTTTTTAGAGAAAAAAAGCTATTTATGAAATGTCAAAAACACTGGACTGTGAGTTTAAGTGTGGAAGCATTTTACCACCCTGTGTCTTCGACCAATTATGGGAAACCCCTTTTCTCTTCCCCCCCGCCTTAGCCTTGCCAAATGAGAAAAAAATAGAACAGCTCTCAGATGATGCACACCACTGAAGCCCTGCTTTAATTTTTACGGTTCAAAAAGTCAGAAAACCAAAGTTCAATTTGTTTCTGAAACCCCACTGTCCGTGGCCCTTTTTTGTAGGACACAGCCAGTCGGCTCTGCCTCTCCGTCTTGGATCATTGCCTTCTTCAGGACAGGGGGCCAGCTGTGACACAAAGAGAAGCAGAAAGGTGGTGAGCCTGAGGGTTGAGGTCTCCTGGAGCAGATGTGAGTGGGACTTCAGCCTCTCAGCGGGCAACCAGGCTTCCCCGGCCTGTGGCCAGGCTGCCCCACTGCCGGAGGAGGAGAGAGGCTGCCCACGCCTCCACCCTCCGCTTCTAAGGCCCTTCTGTTACCGTCGCTCTCCAGAATGGCTTTGCCTTTCTCAGCAGCCCGCATTCCACGGACGGGCTGGGGGGAGGAAGGATCCAGTTGAAAGAAATGGGGAAGGTAGGACAAGGGACCCTCTAGCATGAGGGATCTTGTCCGCCTCAGCTTTGATTCTGTGGATCGTCCACCCATCTGCTCACTGTGAAGACGGAGAGGCAGAGTGCCCTACGGCTGTTCAATAGCTTTCTGTATTTTTTCAACATTGAAAAAATAATTTTTAAAAACTGTGATTTTTTTTTTAAATCATTTGGCTGGAGGGAAGGGAAAAGGGAAACACCAAAAGCTGTAACATGATTAACTGGAGATATTTAACTGGGGGCACTTTCTAGACCAAGACAAACGAATTCCGTTCTGGACCCTAAAGCAGCCAAATCTTGAGACTGTCAATGACAGAAAGCTGAAGAGAGGCCTCCATTTCCTCCTTTCTCCTTTCTTCTCTCTGTCTCAAAATTCTCTCTCGTTCTCCTTTTCCAACTTCCCTTGGACTACTGACCCAATGGCCCTTGGACTCCCATTTCATGCGTGTGTGCACACGTGCGCGCACACACACACACTTGCAAAATACCATTTTTCTTAAGGATTGTGGGACCGAATAAAATCATGTGCCTTCATTTTTTCCTTTTATAGTTAGATGAACCTCTTCCTTTTTACAGTGCTTAAAAAAAATAGGGGAGGTTGAAGTGTTAGTGGGACTTGGGCATCGCTTGCGAAGTAATTTTCATTTAACACATTCCCCCTAAATATGAACACAGACACGTCAGCCCCTTCAGGATGCTCTTTGGCCATTTAGAGCATTACCTAACCAGATATGTGACAGCCTGAACCCATTTGACTTTAGAGCAATTCCTGACAATTCTCTTTCATACACTTCTTTCATTTTTACCACAAATGAGGTGAGCAATGGCAAGCAGCCTTGTTCTCCGGATCTGGTGCTTTTGCGTGTGGCATGGGGTGGGCCTGGGGGTGGGGGAGTGGGTGTGTTTCGATAAAGGGTGCATTCCTATAGATCTCTGGTGCTGAAGGGCCTCGAGTTCCTTCCAGAGACTGCATTTGACACACTTTAAGTACACACAAGTGAATGGTATCACATGCAATATTTTAATGGAGCAATGGGAGAGGCTCTTTGAAACGGGGTTTTGCATCTTTTTGTAACATTTTGATTTCTCTGGTGCCTTATTCCTACTTGATGCTGGCACTCACATACCCACAGGGAACGGACACAGAAGTCAGCCTGGGGAGTGGGGACCCTCGAGCAGAGCGATGCTCGAGTGTGTGGGCGCGGGGGGCGTTGGGAGGTTGGTGTCAGTTGGCTGGGAAGGGACTAGATGGCATCTCTTAGCCGAAGCCAAGCAGGAACTGCACAAACCCACACAAAGTGAACAATTCCGACCTGCAAACACACCGCAAACCCACCCTTCCTCATCTGAGCTTTCCTTCCTTCTTCCTCTTTGATCTCCGCCTTCTCGCAAAGGTGCTGCTGCTGCTGCTGCTAGGTGCCCGGAGTCCAGAATGCCCAGTAATCACTCAGGCACAAGCCTGGCACTGCCACGTCAGCCCCCGGCACGACCAAACCCAGGTTTCTCTTGCTCGGGGCTGAGAACTGTCAGATTTTTCTCATCAAAAATGTTTTCCAAGGAATCAGTGGATTACAGTCATTCTGCATTGAAAATGCACTTTAAAAAATAAATAAAAGCTCCAGACTGTTTAAAATGTACAGAGGGAGCAGGGGAAAGATAAACATGTGCTAGTGTCTGAACCCAGTTCAGTTTATCTCCAGTTGAAACAATATACACTATATTATGTATAAATGTATACACACTTCCTATATATATCCACATATATATAGTGTATATATTATACATGTATAGGTGTGTATATGTGCATATATACACACATGCACATAACAAATCCAGATGCTCATTACAGATGCTACACAAACAGCAGCAGAGGAAACAAGGTTGGACTCTTGCAACAGATCACAAAAAATAAAAACAGCCACTTGCAGTGATTTTGGTTACTTCTGTATGTTCACAA
->XM_008328421.3 PREDICTED: Cynoglossus semilaevis SLAIN motif family member 1 (slain1), mRNA 
-AGTGTTTTTTCCGTGTTTTCACCCAGAATATTCTTTTTAAATTGTCTCAGTACCATATAAATGTTCTTTTGTAAGGTTTTTACAAATACTTTATCACTGTATATATTATGGTTCAACGAGTGGTCGCTCAAATCTTAAAGTAGTCTTTTTTTTGTCTATCTCAAAGACAAATCTCATTTTAACGTCACTTTTACGAACATTATATTCATAATAATATTAATGTTGTGGCTGAATACAAAGACCAGCCTTTAAATGGTCGACCAGTACACTGGATTATTTTTGGTGTTTTTCTCCAAAAGAGGAGGTGCACACAGTCTTCTTTGTCACTTCGGTACGCGTGTGCATTTGGAGCGTAAACACTTCCTCAGCAGAGGAATGATGGGAAGTTCGGCTGACCAATCAGAGAGAGGCTGAGCAGTCACACCAGCAGCAGCAGCGGCGGCAGCATCAGTGTGTGAGTGTGTGTTAGGGTGAGTGTGTGTCGGTGAGGGGGGGGTAAAATCTGGACAGCCGCTCTGTTGTTGTGAATAGTTCCCTCTGCAGGCGGACACACACAGGGCCGCCGTGCGTCCTCCTCTGTTTGTGAGCCTCCCGTCGTCTCCATGTGCTTGTTACCTGATGGAAGCGGAGGTGCTGAGTCCCAGGCCGATGATGGCAGATGTCAACGGCAACAATAAGATGACCAACGCGGAGTTGGAGGTGCTGAAGCTGCAGGAGCTGGTGCGAAAATTGGAGAAGCAAAATGAACAATTGCGCACCAGGGCCAACGCTGTAAACAATTGCTCTTCCGGCGGCCCTCACCCTCACCCTCTCCCTCACCATCTCCACAATCAGCAGCAGCAGCATCTCCATCACATACATCCAGATGATGACTGTCTGAGTGGCACTTTCCCCAGTAAATATAACATATCCAGTCCTATTCGGTCCCTTTCGTCTGCGCTCGAAACCCGGAGTCCGTCAGAGGAGCCGTTCTCTTATTTCCAGCCGAGCTCCGCGTCTCCTGATGCCGCTGAGGAGCAGAGAGGAGCTGCTGCTGTAGGAGCTGCGGACACCACTGTTCTGGATGAGGTTGATATTCTGGACCTGAACGTCGTGCTCCCAGTTGGAGAACCTGATAGCTGGTTGTACGTGAGTAACAAATCCAAACAGCGCTGTGAGAGCATCCTCACTCCTCTGCAGTGGTGCAGGAAGGTTCTGGACCACCCAGGACCAGAGGTGGAGCTGGCCAGGATGACCCTCGGTCACAGACTGGACCAAGCTAAGCGTAGGCGAGGACTCTCCTCCATCCGTCCCTTCAGCTGTATTGAAGGTCTCTCCACCCTCAGCTGTCCTGTCCTGCCTTACACTAAATCTGCTTCACTAACAGAGTCTCCAGCTCCGGTGGCATCACCAGATCAGCCCAGTGCTCCAATCAGAACCAGCAACAGTCTGAGTGAGAGAGCTTCAACCTTCCTATCCAACACCGCCCTCCACAGCTCTGCTCGCAGACATGCAGCCCTCAGCCCTCAGTCTTCCCTGGACAGTGACGCTGGTGTGTCAGACCTGGACAACGAAACCATCTCTATGGGCTACAAACTGCAGGACATGACAGATGTGGAGGTCATGGCTCGACTTCAGGAGGAGAGTCTCAGGCAGGAGTACAATGCCTCTACCTCAAACACAGCCAGCCGTCGCAGCTCCACTCATCTCCAGGCTTTCNNCCGACATTCCCTGAGACGCAGTGCATTAGATCTGGAGGAAGAAGAGGAGGAGGATGAGGGGTACGACCAGCTCCCCCCTCCTCAGCCTGAACTCTTTCCAGCGGGCTCCATGCAGAGGACAGGACTGTCCCACTCTCACACCTTCTCCAGTATCAGAGACTGTAGACGCAGCTTGACCACCTCTCAGTTTTCACTCAGTGGACTCTCCCAGTTCTCTGGTCTCCTCACAGAATCACAGGCTTCTTACAGAAACAGCACAGACAAGCTACGGAAGAGCATGCCCAACCTGCTCCGAACTCCCAGCATGCCCAGTGTTCCCAGTATGCCCTGCCTGGTTTCCCCTGTCAACCCACCCTCCCACGGCCCCTCCTCCCTGCCAACAATACCCTCCCTCCGCAGCAGCCAGAGCTTTGACTCCTCCAGTGGACTTGCACGACTCCAGTCCTCCTCCATTCCTTCTCCAGGAAGCCTCAGCCAGCGAGTCCACAGCGTGACCAACTTCTCTACCGCACCTCGTCACCCTCTGAAAGCAACAGCCTATGTGAGCCCCACGGTGCAGCAGGGTCCCACCAACACTTCTCTGTCCACTTCCACCAGCCTACACTCCATCCCCAGCAGCACTGCACTGCCTCAGCCCCTGAAACCCAGCAGCATTTTGGCTCCGCAGACATTAAAGTCCAACTCTAACCAGCAGCCCTGTGTCCCTCGCAGCTCCCTCCCTCGTCCTGCCTCCTTCGTGGGAACAGGTGGAGCTCTACGTCCAAGCAAACTCACTCCACCAACACGCAGTTTGCTGACCCCTCCAAAGAGCCTGTCTACACTGAGTGCCCTGAGGGACGGCAGCTGGAAAGATGGCTGCTACTAAGTCTTCAGGTTACATATGTAGCCCTGGTTCACTAAGTGGCACGAGTGAGAAATAAATGCTATGAGAGAACCAAATTTAAAGAAGTTCCAGTGGTGCACAGGGTAATGCTGCACAGCAGGAGAGAGAGAGAGTGACTGGTACTGTTTCTTCAAAGCACTTCTTGTTGATTAAGGACTAAGCAAAGACTGTGAAGAGTATGGTTCCAGCAGGCTGGATCTGTACCGACTATCTGCTGAAGAGACCTGGCAATACGTATTCTGTTAATAAGTTGTTTGATGTGAACTGAATCTTATTTGATGTGTATTTTTATTCATTTATAAAAGTTTAATTTGAAATTAAAACTTTTTTCCAGTTGAAATCTTACCATTAATAATCCACAGCTTTTGCACGCGCCTCAATCAGTTTCAATGCAATTTAATTTGACAACATTTATTTTCCCGCCATTTCAGAGCATCTTGTCAGATTTTAAGTCATTTCCTGTGCCTGTGAATTTGCAGTAAACTCCTGTCACTTTGGTTGCTGGACCTCATAGCACTTTTGTTGGAGGATTATAAACAATGTATTAAGAGGAAAAATTATCAGCTTGACTTTAAATTTAGGTAAGATATGACTTAAGTTCAAGTAAGTGTGATTTATAAGTGTGTGGCTTATTTTTCTTTTTCTTTTTATTAATGTTTACAAAAAAATGCTGTGATTTTCAATGTTCTTTATTAATAACATAATCGCTGCAATCATATTGCACACTGAGCCCAGAGGCTCTTGGTGGATGATAAGAAAATAAAGAGGAGGTGAATTTTTAACCAAATAAACACCTTTAAAAA
->XM_048024951.1 Epithele typhae kinase-like protein (BXZ73DRAFT_88453), partial mRNA 
-ATGTTTGACGACAGCGGACCCCCGTCCCCCTCAAACAACCCCCTAGCTCTCGCCCCCGTCGATCACGAATGGCAGCCCATCCTCCATGTCTCTAACCAAACCGTAGCTCGCAACGCTCGATGTCCCTATTGTCACCGTGCTTTTTCTCCCACGCATTCGCGAGGTTTCCACCCCCACGACCAAGACCTGGACGCGGAATACGAGGGGGATGACATAGAGAGGGCAAGTAACCGGGCAGCCAACTACTTCCAGCTCCTCGAGATTGCGAACGAATCCTCGAGACCACCTAGTCCCACGCAAGATTCCTCGCGTAGATCGTCGCCACAGCCGAATGCATTCCGTGCAGAGAACATGGCCGAGGGATACTTTAAGGCCTTCTTCCAGGAGGTGTGTAGGCTCGGCATGGGCGCAAACGGCAGCGTCTACTTGTGTCAGCATGTCCTGGATGAGAACCCTCTGGGGTTGTTTGCCGTCAAGAAGGTTGCTGTTGGACAGTCACATTCTTACCTCTTGAACACACTCAAAGAGGTCCGACTTCTTGAGAAACTTCACCATCCAAACATCGTCACGTATCATCACGCTTGGCTCGAGTCGTCACAGTTCTCGTCCTTTGGACCACGGATTCCAACCTTGCACATCCTTATGCAGTGGGCTGAGGGCGGAAGTCTCGACGACCTCATCGACACGCGCCTTGGACGCCGTGCCCCGAACCTTCCTCACATTAGGACCACCGCTGATGGATCCACTGAACAATATACCAGTCCCCAGCCGACTTCTCCGATAGAGCAAGAAGCCAGCCAACCATACTCACGGAATGCCCGTATACGGGCCTTCAGAGCATTACAGCGAGCCCCTCCTGAAGAACGGGAACGATTACGTCACGAAATGGGTCTCAATGATAGCGGGCAAGCCAAGTCGACGGTAAACCTGAAGCCGGTGCATCTGCTCAGCGCAGAAGAGATACATGAACTATTTAAGGATGTTGTGGGAGGACTCGCGTTCTTACATGAACGATCTATTCTGCACTTAGACCTTAAACCAGGAAACGTTCTGTTGACTTGGGACGAGGGAAAGCTTGTGCCACGAGCGATGTTGTCCGACTTCGGCACTCACAAGACATGCAATACCGGAACCTTGGAGTATTCTGCACCTGAGTCTCTGCCCGAGCCCTCGACAGGGCGGCTTCTCCAGGTGGACTCGAAGGCAGACATGTGGTCTCTCGGCATGATCTTGCACAAGTTGCTATTCTTCCGTCTTCCCTTCCGGCACACCTCCGACAATGATGATCCTAGTCGGCCAAAGGACGGCCAAGAGTATTCGGATGAGCTCGAGGCTGAGATCCTCGCATACAAGGGGTTCAAGTCTTCCGCTTCGCATATGAACACATTCGAGCCCAGACGAATACCCAAAGCTTACCTCCTGTTGCTGGAGACTCTTCTGAACGTCAAACCTTCCGGACGACCTACTTCAGACCGCGTGCTCAGCGTTATCCAAGAGGGTGGGCTTCGCCCGACGAGCCGTCCTCCGCGTAGAAATGGGCAGGCCCCTCCGGGTACACTTGCGCTAGCACGTCCAAGCGCGGCTCTCAACCCAAACCGCCTTCGAGTCAGCCCCGACCGGACCCGTCGGTCGCGCTCGCCGTCGCGCGTCCCTTCCGCCGACAGTCGCTTTGAAGCCAGCTCCGCCAATGTCGAAGAAATCCAAGAACACGACGGCGATTCGGAAGCTCCGACGGACGAGAAGGACAGGCTCCTGCCCATCCCGAAGGGCTACGCATGGACTCTGCCTTGCATCGGCAGCCTGCGCATTCCCCCCGCACTCGCCGCTCAGGCGCAAGCCATCCACCGCTGGCAGCGGCGTGCACGAATACCTGCGCTCGGATGGCGCACGCTGAAGTCCTCTATTCTTGTTGCCAAGGTCGTTTCCCTCACAGGGCCGCACCTGCATCCTAGCACGAGCGTCCATCCCATTCTAGCGGGAGCAGCGCTAATGCTTGCGGTGGTGGATACGTGGTTCGAGAGTATGGAGGCAACACTGGCGTTTGGTGCAGCGCATTTGGCGGTGCTTGCCCTTGGACAATTCACGTCGTGA
->XM_020597508.1 PREDICTED: Monopterus albus apolipoprotein Eb-like (LOC109958668), mRNA 
-ATTTTATCTATGATATTCCAGGTGTGTGATTTCTGGTTATGATGAGAGTGTTTGCAGTAATCCTTGCACTGGCAGTCCTCTCAGGCTGCCATGCAAGAAGTGTGCCTCAGGATGATGGGAGTGACTTTGAAGATACCGTCCAGAAGTTCAAGGATTATTTAACATATCTGAACTCCAAGGTCGATGAGGTGGTGAAAGACATCCAGAGCTCCGAGACCGTCAGAGAACTGGACACCCTGGTCCAGGACAGCATGTCTGAGCTGGCCATGTACAGGGACGACCTGCAGAACAAGCTGGCTCCCTATGCCCAGGAAACTGCAGAGCGCCTGGGCAAAGACCTGCAACTGCTGGCTGGCAGACTCCACAACCAGATGGCTGAGACCCGGGAGCAGCTGGTGCAGTACACCCAGGAGGCGCAGACCATGATGGAGCAGGATGCTGATGACAGCAAGCTCCGGGTCTCCACCTACAGCCAAAAGCTAAACAAACGCCTCAACAAGGACATGGAGGAGATAAAGAAGCATGTTTCTGAGTACCTTGAGGAGCTTCAATCCCGGACCTCAGACAACATGGAGGACGCGAAGTCTCGTTTGCAACCTTATTTTGCTCAGGTGCAAGACAACGCCCAGGCGAAGGTCACCACCCTGAGTGATCTGCTGACGAAGCAGGTAGAGAACATGAAGGAGGAGATTCAGGGGGTGGCTGCGGGCATCAAGGACCAAATTCAGAAAACTGCTGAGGACATGAAGGAACAATTTCTTGAAACTGCTCAGAATATGCAATTCAGCCTGGGGGAGAAGGTGGAGGAGATGCGCATCTGGTTTCAGCCTCTGGTCTCCACGATCAGGGACAACATGTGA
->XM_009083577.1 PREDICTED: Acanthisitta chloris achaete-scute family bHLH transcription factor 3 (ASCL3), mRNA 
-ATGCAGAACCTGATGGATGACAAAAGCTACTGTAACCTCATCTGTGCTGAGACTCAGCGTGTGCAGGTGGCCAGGCCTTTCTGTGCTGACCCACTGGTCACCTTTCACGTGTACCCAGAAACCCCAAACCAGGCCACTTGCTCTGAAGATTTCTCATTCCTTCCTTTCATGTCTGAGCACCTCCTCGCAAAGAACTTCTACAGTGAGCCCTGCAGCTTTCCTTACCAAATGCCCCATGCCAGTTTCCACAGAAATGACTACTCCTATGGGCCAGCTTTCATCAGAAAGAGGAATGAGAGGGAGAGGCAGAGAGTTAAGTGTGTCAATGAAGGCTATGCTAAGCTGAGGCATCACCTGCCGAAGGAATACTTAGAGAAACGGCTCAGCAAAGTAGAGACACTCCGTGCTGCAATAAAATACATTAGGTACCTACAGTCTGTTCTGTACAGTGATTCTGTGATGGCAGGAAAAAGTGTTGTGGAGCCAAGCCAAGCACCCAAAGCAATTAACAAACAAAACCAGTTTTTGAAGACCATCTAA
->XM_017239098.2 PREDICTED: Drosophila bipectinata uncharacterized LOC108123788 (LOC108123788), mRNA 
-CGCCAAAACCAAAACAAAAGCAAAAAACAAATAGAAATACAGCCAAAAAATAAAATATAAGAAAAAAATTAAATAAATGGCTACCGAAGTGGAGCCCGCAAATACGGCGGACAAGTTTTCGGCCAATGCCGAGGAGCTGGAGAGCTATTATCTGATGCTGGAAAACGGCAGCATTCCGGAATTGCAGTGGCAGTTTCCCGGACGGAGACCGCCATCTCCGGACGTTGGCGGCGGCGTCGGATCTGGCGCCACCAACAAGGAACTGGAGCAGACTGTTGGCGAACCTATAGAACAGGAGCCCCAAAAGGCTCAGAACGACTTTGATTTCAGCGACGATGTGGCGCCCACACAGATGCGAGTCAGAAGCCAGACATCTACGCCCAAGTCGGCCAAGAAGAAGACGGCCAACTTTGCTGGCGTTATGGAAACGCTGAAGAAGAAGAATGCCGAGAGCTCCTAGCATATGCTGAAGTTCTGATGTAATCCTAGCAAGGGTACATGGGAGTATATACGATTCTAGGCGAAGTTTCACCTTAAATAGGAAGGGGAATTTTCAAATTTTTAAAGAAATATTTAAAGAAAGATTTAAATATTATTCTATAAAATCAAAGGTCCGATTTTTGAGGGCTTTTTGATGAAGATTATGTTTTAAAGTTTTAAAGTAGATGTTAGTTGTCAAGTTAGGACTATTAACAAATTCTATAATCATTACATTTACAATTTTAAATTTTAAACAAAATAATAGCTAAGTTGTGCAATTTATAATTCTTTTATAAGATTTTGATTGAAATTATAAAACCAAAAATTTAA
->XM_021934158.2 PREDICTED: Papio anubis ZXD family zinc finger C (ZXDC), transcript variant X4, mRNA 
-TCCGAGCCGGACTCTGCGACGGGTCTTGGCGCGGATCGCGTCCCGGGGCAGTGCACGCACACTTGGGCGGGGCGCGGGCCGCGCTGCGTCCGAAGCGGGTCCGACGCCGTCGCTGGGCCCAAGATGGACCTCCCGGCGCTGCTCCCCGCCCCGACCGCGCGCGGAGGGCAACATGGCGGCGGCCCCGGCCCGCTCCGCCGAGCCCCAGCGCCGCCCGGCCCGAGCCCCGCGCGCCGCCGCCTGCTATTGGTGCGGGGCCCCGAAGATGGCGGGCCCGGGGCGCGGCCCGAGGAGGCCTCCGGGCCGAGCCCGCCGCCCGCCGAGGACGACAGCGACGGCGACTCGTTCTTGGTGCTGCTGGAAGTGCCCCACGGCGGCGCCGCCGCCGAGGCTGCCGGATCACAGGAGGCCGAGCCTGGCTCCCGTGCCAACCCGGCGAGCCGCCCGGAGCAGGGCCCCAGCGGCCCGGCAGTCGCCGCCGGCCCTGGCGTAGCCCCGGCGGGCGCCGTCACCATCAGCAGCCAGGATCTGCTGGTGCGCCTCGACCGCGGCGTCCTCGCGCTGTCTGCGCCGCCCGGCCCCGCAGGCGCGGGCACCGCCGCGCCCCGTCGCGCGCCCCAGGCCTCCGGCCCCAGCACGCCCAGCTACCGCTGCCCCGAGCCGCAGTGCGCGCTGGCCTTCGCCAAGAAGCACCAGCTCAAGGTGCACCTGCTCACGCACGGCGGCGGTCAAGGCCGGCGGCCCTTCAAGTGCCCGCTGGAGGGCTGCGGCTGGGCCTTCACAACGTCCTACAAGCTTAAGCGGCACCTGCAGTCGCACGACAAGCTGCGGCCCTTCGGCTGTCCGGTGGGCGGCTGTGGCAAGAAGTTCACTACGGTCTATAACCTCAAGGCGCACATGAAGGGCCACGAGCAGGAGAGCCTGTTCAAGTGCGAGGTGTGCGCCGAGCGCTTCCCCACGCACGCCAAGCTCAGCTCCCACCAGCGCAGCCACTTCGAGCCCGAGCGCCCTTACAAGTGTGACTTTCCCGGCTGTGAGAAGACATTTATCACGGTGAGTGCCCTGTTTTCCCATAACCGAGCCCACTTCAGGGAACAAGAGCTCTTTTCCTGCTCCTTTCCTGGGTGCAGCAAGCAGTATGATAAAGCCTGTCGGCTGAAAATTCACCTGCGGAGCCATACAGGTGAAAGACCATTTATTTGTGACTCTGACAGTTGTGGCTGGACCTTCACCAGCATGTCCAAACTTCTAAGGCACAGAAGGAAACATGATGATGACCGGAGGTTTACCTGCCCTGTCGAAGGCTGTGGGAAATCGTTCACGAGAGCAGAGCATCTGAAAGGCCACAGCATAACCCACCTAGGCACAAAGCCATTCGAGTGTCCTGTGGAAGGATGTTGCGCAAGGTTCTCCGCTCGTAGCAGTCTGTACATTCACTCTAAGAAACACGTGCAGGATGTGGGTGCTCCGAAAAGCCGTTGCCCGGTCTCTACCTGCAACAGACTCTTCACCTCCAAGCACAGCATGAAGGCACACATGGTCAGACAGCACAGCCGGCGCCAAGATCTCTTACCTCAGCTAGAAGCTCCGAGTTCTCTTACTCCTAGCAGTGAACTCAGCAGCCCAGGCCAAAGCGAGCTCACTAACATGGATCTTGCTGCGCTCTTCTCTGACACACCTGCCAATGCTAGTGGTTCTGCAGGTGGGTCGGACGAGGCTCTGAACTCCGGAATCCTGACTATTGACGTCACTTCTGTGAGCTCCTCTCTGGGAGGGAACCTCCCTGCTAGTAATAGCTCCCTAGGGCCAATGGAACCCCTGGTACTGGTGGCCCACAGTGATATTCCCCCGAGCCTGGACAGCCCTCTGGTTCTCGGGACAGCAGCCACGGTTCTGCAGCAGAGCAGCTTCAGTGTGGATGACGTGCAGACTGTGAGTGCAGGAGCATTAGGCTGTCTGGTGGCTCTGCCCATGAAGAACTTGAGTGACGACCCACTGGCTTTGACCTCCAATAGTAACTTAGCAGCACACATCACCACACCGACCTCTTCAAGCACCCCCCAAGAAAATGCCAGTGTCCCGGAACTGCTGGCTCCAATCAAGGTGGAGCCGGACTCGCCTTCTCGCCCAGGAGCAGTTGGGCAGCAGGAAGGAAGCCATGGGCTGCCCCAGTCCACGTTGTCCAGCCCAGCAGAGCAGCACGGTGCCCAGGACACAGAGCTCAGTGCAGGCACTGGCAACTTCTATTTGCTGTGTGGCGTTGGGCTACCTCGCTTCTCTGAGTACAAATGGTGTGTGGTGAATGGGTCCCAGGAAAGTGGGGGCTCAGCAAGAACTGATTACCGAGCCATTCAACTAGCCAAGGAAAAAAAGCAGAGAGGAGCGGGGAGCAATGCAGGATGACCCCTCCGGCGAAGGTGTCCTGCCCTCAACCCGCGGCCCAGCCGCCTTCCTCCCCTTCCTCACTGTGGACCTGCCCGTCTACGTCCTCCAG
->HE815016.2 Uncultured endophytic bacterium partial 16S rRNA gene, clone Dkk4A12.M13-F 
-AACCGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGGGCACTAGGTGTGGGAGGTGTCGACTCCTCCCGTGCCGTCGCTAACGCACTAAGTGCCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCAGCGGAGCATGTGGTTTAATTCGACGCAACGCGAAGGACCTTACCTGGGCTTGACATGTAGGTGACCGCCATAGAAATATGGCCTTCCTTCGGGACACCTTCACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCCGTTCCATGTTGCCATCATTCAGTTGGGGACTCATGGGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGACGACGTCAAGTCATCATGCCCCTTATGTCCAGGGCTACACACGTGCTACATTGGCGCATACAAAGGGCAGCAATACCGTGAGGTGGAGCGAATCCCAGAAAGTGCGCCTCGGTTCGGATTGGAGGCTGAAACTCGCCTCCATGAAGGTGGAGTTGCTAGTAATCGCGGATCAGCAATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAAAGCAGGCAACACCCGAAGCCGGTGGCCTAACCTTTTGGAGGGAGCCGTCGAAGGTGGGGCTCGTGATTGGGGTGAAGTCGTAACAAGGTAACCGTA
->JQ912969.1 Uncultured archaeon clone B22pf 16S ribosomal RNA gene, partial sequence 
-TTCCGGTTGATCCTGCCAGAGGTCACTGCTATCGGGGTTCGATTAAGCCATGCGAGTCGAGGGGGTTCAGACCCTCGGCGGACTGCTCAGTAACACGTGGATAATCTGCCCTATGGTGGAGGATAACCCCGGGAAACTGGGGATAATACTCCACAAGTCAGGAGTACTGGAATGTCTCCTAACTGAAAGTTGCGGCGCCATAGGATGAATCTGCGGCCGATTAGGTAGTTGTTGGGGTAACGGCCCAACAAGCCCGTAATCGGTACGGGTTGTGGGAGCAAGAGCCCGGAGATGGAATCTGAGACACGATTCCAGGCCCTACGGGGCGCAGCAGGCGCGAAAACTTTACAATGCAGGAAACTGTGATAAGGGAACCCCGAGTGCCCGTAAACGCGGGCTGTCCCGGTGTTTAAAACACATCGGAAGAAAGGGCCGGGCAAGACCGGTGCCAGCCGCCGCGGTAATACCGGCGGCTCGAGTGGTGACCACTTTTATTGGGCTTAAAGCGTTCGTAGCTTGATTTTTAAGTCTCTTGGGAAATCTCACGGCTTAACTGTGAGGCGTCTAAGAGATACTGGGAATCTAGGGACCGGGAGAGGTAAGAGGTACTTCAGGGGTAGAAGTGAAATTCTGTAATCCTTGA
->XM_036570612.1 PREDICTED: Colossoma macropomum myosin-10 (LOC118808147), transcript variant X1, mRNA 
-TCCGCTGGGTTCGGTTGAGTAGAAGCGGCTGCAGCAGCGCGGAGGGAGACGAGACTGAGTTTAATATATTTGAAGAACAAAAACTGGATTCTTGTAAAACTGGAAGGCCTGGATTAGAGGTTTATTTCAGCTGCTCACAGTCAAAGGTTTTGCCCTTCGTGGCCTGTCTGTAGTTCCTAATGCCGGAGATGGCTCAGCGGAGCGGTCAGGAGGACCCCGAGCGGTACCTCTTTGTGGACCGGGCGGTGGTCTACAACCCAGCCACCCAGGCTGACTGGACCGCCAAGAGGCTGGTGTGGGTTCCCTCGGAACGACACGGGTTTGAGGCGGCCAGCGTCCGCGAGGAGAGAGGAGAGGAGGTGGTGGTGGAGCTGGCGGAGAATGGCAAAAAGGCTCTGGTCAACAAAGACGACATCCAGAAGATGAACCCACCAAAGTTCAGCAAAGTGGAGGACATGGCGGAGCTGACCTGCCTGAACGAAGCCTCTGTACTGCACAACCTTAAGGACCGATACTACTCCGGCCTCATCTACACTTATTCCGGACTCTTCTGTGTGGTGATAAACCCATACAAAAACCTTCCCATTTACTCGGAGAACATCATTGAGATGTACAGAGGGAAGAAGAGGCACGAAATGCCGCCACACATCTACGCCATTTCCGAATCCGCCTACAGATGCATGCTTCAGGATCGTGAGGACCAGTCTATTCTGTGCACAGGTGAATCCGGAGCTGGAAAAACAGAAAACACCAAAAAAGTGATCCAGTACCTGGCACACGTTGCTTCCTCTCACAAAGGAAGGAAAGATCACAACATTCCACCAGAATCTCCTAAAGCAGTGAAGCTCCAGAGTGGACTCCTGGTCTATGGGGAGCTGGAGAGGCAGCTGCTGCAGGCTAACCCCATTCTGGAGTCCTTCGGAAACGCCAAGACGGTGAAAAATGACAACTCGTCTCGCTTCGGCAAGTTCATCCGCATCAACTTTGATGTCACGGGTTACATTGTGGGGGCCAACATCGAGACCTATCTGCTGGAGAAGTCCAGAGCGATCCGACAGGCCAAAGACGAGAGAACCTTCCACGTCTTCTACCAGCTGCTGGCTGGAGCAGGAGAACATCTGCGCTCCGATCTCCTCCTGGAGGGCTTCAATAACTACCGTTTCCTCTCCAACGGCAACATTCCTATTCCCGGCCAACAGGACAAGGACAACTTCCAGGAGACCATGGAGGCAATGCACATCATGAGCTTCTCACACGATGAGATTTTGTCGATGCTGAAGGTGGTATCAGCTGTGTTGCAGTTTGGAAACATTGTGTTCAAGAAGGAGAGAAATACAGACCAGGCCTCCATGCCTGAGAACACAGCTGCGCAAAAGCTCTGCCATCTGCTGGGGATGAGTGTGATGGAGTTCACCCGCGCCATTCTGACCCCCAGGATCAAAGTGGGCAGAGATTATGTCCAGAAAGCCCAGACGAAAGAGCAGGCTGATTTTGCAGTGGAAGCTCTGGCCAAAGCCACGTACGAGCGGCTCTTCCGCTGGCTCGTCCACCGCATCAACAAAGCTCTGGACCGGACCAAACGGCAGGGAGCGTCCTTCATCGGCATCCTTGACATCGCTGGCTTCGAGATCTTCCAGCTGAACTCGTTCGAGCAGCTATGCATCAACTACACCAACGAGAAGCTCCAGCAGCTCTTCAACCACACCATGTTCATCCTGGAGCAGGAGGAGTACCAGCGCGAGGGCATCGAGTGGAGCTTCATCGATTTCGGCCTCGACCTGCAGCCCTGCATCGACCTCATCGAGAGGCCGGCAAACCCTCCAGGTGTGCTGGCCCTGCTGGACGAGGAGTGCTGGTTCCCCAAAGCTACAGACAAAACGTTTGTGGATAAGCTGGTGCAGGAGCAGGGCTCGCACGCCAAGTTCCAGAAACCGCGGCAACTAAAGGACAAGGCTGACTTCTGCATCATCCACTACGCAGGCAGGGTGGATTATAAAGCGGATGAATGGCTGATGAAGAACATGGATCCTCTGAACGATAACGTGGCCACTCTGCTCCATCAGTCCACTGACAAGTTTGTGGCCGAGCTGTGGAAGGATGTGGACCGCATCGTGGGTTTGGACCAGGTGGCCGGTATGAACGAAACGGCGTTTGGAGCGACGTACAAGACCAAGAAGGGTATGTTCCGGACGGTGGGACAGCTCTACAAGGAATCTCTGACCAAACTGATGGCCACTCTCCGGAACACCAACCCCAACTTTGTCCGCTGCATCATCCCCAACCACGAGAAGAGGGCTGGTAAACTGGAGCCCCATTTGGTTCTGGACCAGCTGAGGTGTAACGGGGTTCTGGAGGGAATCCGTATTTGCAGGCAGGGCTTCCCCAACCGCATCGTCTTCCAGGAGTTCAGACAGAGATATGAGATCCTCACCCCTAACGCCATCCCAAAGGGCTTCATGGATGGGAAGCAGGCCTGTGAGAGGATGATCCAGGCCCTGGAGCTGGACGCTAACCTGTACCGGATTGGTCAGAGTAAGATATTTTTCCGTACCGGAGTTTTGGCACATCTGGAAGAGGAGCGGGACCTGAAGATTACTGACATCATTATCTACTTCCAGGCCGTATGCCGAGGATACCTGGCACGCAAGGCGTTTGCTAAGAAGCAGCAGCAGCTGAGTGCTCTGAAGGTTCTCCAGAGGAACTGTGCGGCGTACCTGAAGCTGCGGCACTGGCAGTGGTGGAGACTTTTCACCAAGGTGAAGCCTCTGCTACAGGTGACCCGTCAAGAGGAGGAGATGCAGGCTAAAGATGAGGAGCTGGTGAAAGTGAAGGAGAGGCAGGTGAAGGTGGAGAACGAACTGGTGGAGATGGAGAGGAAACACCAGCAGCTCCTGGAGGAGAAAAACATCCTGGCGGAGCAGCTTCAGGCTGAGACAGAGCTGTTTGCAGAAGCTGAGGAGATGAGAGCTCGTCTCGTGGCTAAAAAGCAGGAGCTGGAGGAGATTCTGCATGACCTGGAGTCCCGAGTGGAGGAGGAGGAGGAGCGGAACCAGACGCTGCAGAACGAGAAGAAGAAGATGCAGTCACACATACAGGACCTCGAGGAGCAGCTGGATGAGGAAGAAGCCGCGAGGCAAAAGCTCCAGCTGGAGAAAGTGACCGCAGAGGCCAAAATAAAGAAAATGGAGGAAGATCTGCTGCTGCTGGAGGACCAAAACTCCAAATTCCTGAAGGAGAAGAAGCTGCTGGATGAGAGGATCGGCGAGATGACCTCTATGCTGGCCGAAGAAGAGGAGAAGGCCAAGAACCTCGGCAAAGTGAAAAACAAGCAAGAGATGATGATGGTGGACCTTGAAGAGCGTCTGAAGAAGGAGGAGAAGACCAGGCAGGAGTTGGAGAAAGCCAAGCGTAAACTGGACGCCGAAACCACAGACCTGCAAGAGCAGATCGCTGAGCTTCAGGCTCAGATCGACGAGCTGAAAATCCAACTGGCTAAAAAAGAGGAGGAGCTTCAGGCTGTTCTGGCCAGGGGCGATGAGGAAGTGGCCCAGAAGAACAATGCTCTGAAGCAGGTCCGGGAGCTGCAGGCCCAGCTGGCCGAGCTGCAGGAGGATCTGGAGTCGGAGAAGGCTGCTCGGAACAAAGCGGAGAAGCTCAAACGGGACCTCAGCGAGGAGCTGGAGGCGCTGAAGACTGAGCTGGAGGACACACTGGACACCACGGCCGCTCAGCAGGAGCTCAGGACGAAGAGAGAGCAGGAAGTGGCTGAACTGAAGAAGGCGATCGACGAAGAGGCTCGAAACCACGAGTCCCAGATTCAGGAGATGAGGCAGAGACACGGGATGGCGCTGGAGGAGATCTCAGAACAGCTGGAGCAGGCCAAACGGTTTAAGTCTAATCTGGAGAAGAGTAAACAGACTCTGGAGGGCGATAATAAGGAGCTGGCGAGTGAGGTGAAGGTTCTGCAGCAGGCAAAACTGGACTCTGAGCACAAGAGGAAGAAGCTGGAGGCTCAGCTGCAGGAGGTTCTGGCCCGCGTTACTGAAGGAGAGCGGACCAAGGGCGAGCTCGCTGACCGCACTCACAAACTACAGACGGAGCTGGAGAATGTATCTACTCTGCTGGAGGATGCGGAGAAGAAGGGAATAAAGCTGGCTAAGGACGCCTCCAGCCTGGAGAGCCAGCTGCAGGACACACAGGAGCTCCTGCAGGAGGAAACGCGTCAGAAGCTGAACCTGAGCAGCCGAATCCGTCAGCTGGAGGAAGAGAAGAGCGCCCTGCAGGAGCAGCAGGAGGAGGAAGAGGAGGCACGTAGAAACCTGGAGAAACAACTGGCAACCTTGCAGTCTCAGCTGTGCGAGACGAAGAAGAAGCTAGAGGATGACGTCGGAGTTGTGGACGCTCTGGAGGAGGTGAAGCGGAAGCTGCAGAAGGACATGGAGGCCACCAACCAGAGACTGGAGGAAAAGGCCATGGCCTACGATAAGCTGGAGAAGACCAAAACCCGGCTTCAGCAGGAACTGGACGACCTCATGGTGGATCTGGACCACCAGAGACAGATAGTCTCCAACCTGGAGAAGAAGCAGAAGAAATTTGACCAGATGCTGGCGGAGGAGAAGAGCGTATCGGCGCGTTACGCTGAGGAGCGAGACCGAGCAGAGGCCGAAGCGCGGGAGAAAGAGACGAAGGCACTATCGATGGCCCGAGCGCTGGACGAAGCACTGGAGGCTAAAGAGGAGTTCGAGAGGCTGAATAAGCAGCTGAGGGCCGAGATGGAGGATCTGATGAGCTCCAAGGACGACGTGGGAAAAAACGTTCATGAGCTGGAGAAGTCCAAACGTACGCTGGAGCAGCAGGTGGAGGAGATGCGCACTCAGTTGGAGGAACTGGAGGATGAGCTGCAGGCCACAGAGGACGCCAAACTGCGCCTGGAGGTTAACATGCAGGCCATGAAGGCCCAGTTTGAGCGTGACCTGCAGGCCAGAGATGAACAGAATGATGAGAAGAAAAGAATGCTGGTCAAACAGGTGCGTGAGATGGAGGCGGAGCTAGAGGATGAGAGGAAGCAGCGTGCGCTGGCTGTGGCGGCTAAGAAAAAGCTGGAAATGGACCTGAAGGATGTTGAGGCTCAGATTGAGGCAGCTAACAAGGCTCGGGATGAGGCCATCAAACAGCTGCGCAAACTCCAGGCTCAGATGAAGGACTATCAGAGGGAACTGGAGGAGGCTCGAGCCTCTCGAGATGAAATCTTTGCCCAGTCAAAAGAAAACGAGAAGAAGCTCAAGAGTCTTGAGGCAGAGATATTACAGCTGCAGGAGGACCTGGCTGCATCTGAGAGAGCACGGCGTCATGCAGAGCAGGAGAGGGACGAGCTGGCAGACGAAATCTCAAACAGTGCCTCTGGGAAGTCTGCTCTGCTGGATGAGAAGCGCAGGCTGGAGGCTCGAATTGCTCAGCTGGAGGAGGAACTGGAGGAGGAACAGAGCAACATGGAGCTCCTCAATGACCGCTTCCGCAAGACTGCCATGCAGGTGGATACTCTGACCACAGAGCTGACCGGAGAGCGCAGCGCAGCCCAGAAGAGCGAGAACGCCCGGCAGCAGCTGGAGAGACAGAACAAGGAGCTGAAGGCCAAACTGCAGGAGCTAGAGGGATCCATCAAATCTAAATTTAAAGCCAATATCACCGCCCTGGAGGCCAAAATCCTGCAGCTGGAGGAGCAGCTGGAGCAGGAGGCCAAGGAGCGGGCAGCGGCCAATAAGATTGTCCGGCGCACAGAGAAGAAGCTGAAAGAAGTGTTCATGCAGGTGGAGGATGAGCGTCGCCATGCTGACCAGTACAAGGAGCAGATGGAGAAGGCGAACTCTCGCATGAAGCAGCTGAAGCGTCAGCTGGAGGAGGCGGAGGAGGAAGCTCAGCGCGCTAACGCCTCCCGCAGGAAGCTGCAGAGAGAGCTGGATGACGCTACAGAGGCGAGCGAGGGGCTGAGCAGAGAGGTTAACACCCTCAAAAACCGTCTCAGACGCGGAGGCCCGGTCAGTTTCCCCTCGGGTCGCTCTGGCCGCAGGCAGCTGCAGATGGAGGGCGAGTGTTCCGATGACGACGCCGAAAGCAAAGCCAGCGATGTGAACGAGACCCAGCCTGCCCAGCCTGAGTAGTTATAGTGTCCCCCTGTGGTCCTGCAGTGCTATTACACCTTCTACCCCAAAACAGTCAGCACGCCAGAAACCGTAACATGTAACCCAGTTCGTTCTGCTGCTCGCGTGGTGGAGAGCAGGACTGAGGGTCCACACACACACCTCTCTAAACACATTTATACACACATGACTCCTCCACACACCTGCGTTCTGTCTACAAGCCTAAGCTGCAACGAGCATGAGAACGATTCAGTACATACGGTCATTCCCTTCATATTCAGGGAACCTCAACTCTGCCTTACTCAATGCAGCAAAGCTTCAAGGTTGAGTGGAGTTTTGTTCTAATTAGCAATCTGTTGTAATGTTAGCCTTCAGAATAATTGCTTAAGGTGAAAACACTATAGGTACAAGTGCATTTTATATGTTCAGTTTTTTTGTGCACACAGTCATACATGAGCAGCAACTCGAGTCTAGTATAAATAAATAACGATAAAGCCACTGCTTAGCTAAAGCAAGACAGGTCTGGCGTTAGAGTACGATGTGAAATTCCAACGAAGCACAGGTTCTGAGTGTTTTTGGCTGGCGGAAGTATGTGTTAGAGATGCATGGACTTCTGTTTTCTACAAGTAATAGAGAAAAAACACAAAAATGTACATGTAACCGGCCGAACCTGTGGCTGCTTCGAATTGGATTGAAAAGTGAAGAAAAAAACTGTGAAAAAGCTACTGCTTAAGCTTCTGCCCACATTAGACAAACAAAAACACTAAGATGAAAGTACCTTCAGTCATTTCCGTTCATCCTCATTCTATTTGGGACACTTGATTGTTGAAGTATTGGGAGAGATTCCGATAAGTGATGGTATTAGACGTTGACGAAACTGGATGTAAATGCAAGATGCGAAATGCTTTGTAACTGCACATTTACTACAAGCCATACGAGGCAAAACTGGAAAGAAATCCGTACATTTTGGGAGAATGTGCACATCCACAAAAAAAAGAATAATTTTTTTGTGAAGGTTTCTTCGGAAAATATCTCATCAAATGTGTGAACTATTAGCTGCTTTATTAGACACTCCGAGAAGTGCTTTAGTACATGAAGGGAAACCGACAGAAGTGAAGGAATCATTTCGTTCAGTGGGATCATCTCGTTCACTGCTGATTTTGACTGGAACACTAACATCAAAACACATTGATGATTCACAGGCACTTAGTTCGATTTGAATCATAAACCTGAGCCCTTGAGCTTCAGCCCAAAATGTATAGAAGAGCCACTACAGTTCTCAAACACACTATTATTTCTCAGTATCAGTATTATAAAGATGATGGATTAGAAACGATACTCACCTGCTCCAATATTAGTATTTAATAATGTTTCTTTAAAAAGTGCCTTAGTCACTAATTAAGAAAATATCCATGAGTTAAATGCATTGTACATCTATAATGGTGTGTATACAAGTGCAACACTAACATGAAGGCAAAACTGGCAAAACAATATAAGAATAATAAAAAAAACACTACGTAACCCTTTCTGTTTTGTATTTTACTGTGCTTTGAATCATATCCGTTATCTAAGTCTCTCTTCCCTAGTCTTCTAGGTAAGCCATGGGCCAGCTTCAGTGTTATCTGTAGGAGTTGGAACCCTCTGCCTTGGCTGCAGAGGGAGTTGCAGGATTTTATTTGGTTAAAAGCTTTACCCCTCCACGATCTAGTTACTATTATTACAATTATCATTATTATTGCTATTGTTATCACTCTTATTATTGGGCTGGCTGTTGACAACCAGACATTCAACTGCAAATATATCTCTCCTTTTTTTCTTGTATACTGTTACTGTATTTCTAGACAACAGTGATTTTTGTAAAGGAAAAAAAAATAAAACCTTCATTATAG
->XM_017906153.1 PREDICTED: Eufriesea mexicana enoyl-CoA hydratase, mitochondrial (LOC108551834), transcript variant X1, mRNA 
-CATATTGAAAAGAAAATAGCTTTCTCCACTTCATAAACATGCATTGTACTGCTCTGCTAACCTTCACAGCTTTCTTCTCTCTCTCTCTCCCTATATACATTCACCTCTCCCCGCTCTTTTTTAATCGTGTAGTCTGCTAGAATCCAGTCTGGATGATATGAGTCGGAACGAACTCGTTTTATCGTCACTCATCTCATCATTCGTTCTGTTGATTCCATAAGAAAAGTGTTTTTATTGCTATTAAAATCATAAGTTTAAACAGCATTATGGTAACTACACGTATTGGACATATTCTCCTAAACAAGAGTTTACAGATCGATCGAAAATTACCATATTGTGCGTCCAACGTAAAACATTATTGTTGCCAAGTTCAAAATTATGAATTCATCAAAGTCGAATATACTGGCGAAAACAAAAATGTGGCTTTAGTAACACTAAACAGGCCGAAAGCTTTAAATGCTCTATGTGATAAATTAATGATTGAATTGAATGATGCTATATCAAAATTTGATAGAAATGATTCTATCGGTGCCATAGTCGTTACTGGTAGCGAAAAAGCATTTGCAGCCGGAGCTGATATTAAAGAAATGCAGAATAATACTTATGCACAGAATGTGAGAGGAAACTTCCTTGCCGACTGGGACGGTGTTTCCCGAGCATCGAAACCAGTAATTGCTGCTGTAAATGGATATGCTTTAGGTGGAGGTTGCGAATTAGCAATGATGTGTGACATCATCTATGCTGGGGATAAAGCGAAATTTGGTCAACCGGAAATCGCCCTTGGTACCATACCTGGTGCGGGTGGCACACAAAGATTAACGAGGGTAGTTGGTAAGAGCAAAGCGATGGAAATGGTACTAACAGGAAATCAGATCACTGCTGAGGAGGCGGAAAAAAGCGGTCTTGTTAGTAAAGTCTTCCCAGCAGATAGACTTATTGCTGAGGCAATTAAGTCAGCTGAAAAAATTGCCTCCCATTCTCAATTAATCGTTGCCATGGCAAAAGAATCTGTTAATACTGCTTATGAAACTACTTTGAAGGAAGGACTTCACTTTGAAAAAAAGATGTTCCATGGCACATTTGCAACGGATGATAGGAAAGAAGGAATGACAGCGTTTGTTGAAAAAAGACCACCTAAATTCAACAACCACTGAGACCATTAATTCCATTATAGGAGAAGAATAAAAATGATGTAACATTTGTAAAGAAATTTTATTTAATTTTATTTAATTATTTCTTTACGTCTAATATCATAATCCATGATTATGATACATTTACAATTAACGGCTCATACCAGGTAAATATTTCTTAATAATAGCAATTCTAATGCTCTCGTAGAAGCATAGAAATGCCGTTGACATCGTAAAAGGTATCCAAGAATGGTAGGAACAATGGAATTTCACACCGACATCGTTATATAATAAATATCAAACTTTATAATAATGTGTATCTTGCTTGCTATTTGGAAATTTTTTTAATCCTGTTTTCAGATATTCTCGGAGAA
->MH775349.1 Uncultured bacterium clone 2932 16S ribosomal RNA gene, partial sequence 
-TGGGGAATTTTGGACAATGGACGCAAGTCTGATCCAGCCATGCCGCGTGCGGGAAGAAGGCCTTCGGGTTGTAAACCGCTTTTGTCAGGGAAGAAACGAGTTTCTCTAATACAGAGACTTAATGACGGTACCTGAAGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTGATGTAAGACAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCGTTTGTGACTGCATAGCTAGAGTACGGTAGAGGGGGATGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAACACCGATGGCGAAGGCAATCCCCTGGACCTGTACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACA
->XR_003646050.1 PREDICTED: Camellia sinensis protein TPR1-like (LOC114310240), transcript variant X10, misc_RNA 
-TAATCTCTCTGAATCGATCGAATCAACCTTCTTCAGCCCCATTTGATCTAATCTCAGAGCGATTGGTGATTCATCTCCGATCCAATCTCAGAGCGATTGGCAATTTCGATTTTGAGATTTTGAAGCTCCACCGCCTCCACCATCTGCACTGGCGAGGGGAGCGAGCACCATCATCTACTAAGAGCCATGTGCGGCAATTCTGTTTGGCGTTCACTTCAATGTAATTGTAATTTAAAGCTTCAATTTGTTGCTCTCTCTTTCTCTCTCTATCTGTACCCATTTGGCGTTGTCTGTTGCGTCCAAGTCACAGCAACCTCTTGATTTGCCTTTTGGTCTGAAGTTTATTTTGGACGCATTCTTGTGATTTCAACATTTCATTTTATCAAATTTGTCACAATTTCATCCAAAATTATAATCAATATCCTTAAAACAAATATGATCATATAATTGTGGTGATGATCTGACAGAGGTGCGAGTGGATTATGCTCTTCTATGGTCTGTGGATTCGGCTGCATTCAAGGTTCCAAATGCATAAGAACCACGCACTGTGACAAAGGTACTAAGGTAAACCATCCAATCATGCTCCGTAGAACTACTTTTGTGGCTCTGATCTTTGGGACCATAGCCATCTTCTTCATCAGCTCGAGTCTTGTCTTCTAGTATAAGTGGCTCCCTTATCTCTTCTTGCAAGCTGTTCTCACCTTGCTCCAAAAATTAGAGAATTCAAATTTATGGTCAAGAATTTAATGGAGAATGCTAACAAAAGGATTTTGTTCTGTGATGAAAGCCAGGATGCACCACACTATGAAGTCCTTGCCAAGAATATTGTAGATGCTATGCTGGTGGACTGTTTGTTGTGTACTTTGCTCTGCTGCAACAGGTAGCAGCATAAGAGATATTCAGTTGATTGCATGACCTTTCATCCTCTATATTTGATCCTCGCTGTCAACTTTTGCTTATGCATATCTCAGTGACTATTTTTTTGAAGTGATTCACTTATTCTTTTGAACAGGTTCCTCTTACTAATGAATTCATTACTAATGGTGCTCCTCTTGCCAGGTTACATATCCAACATCTCGTCAACATGCCACTTGGTCCTTGGATGACTTGCCAAGAACAGTAGCTTGTACCATGCATCAAGGATCTGCTGTTAACAGCATGGATTTTCATCCTTCTCATCACACATTGCTTCTTGTTGGTTTTGCTACTGGTGAAATAACGCTCTGGGAAGTGGGGATGCGATATAAATTGGTTTCAAAGCCATTCAAGATATGGGACATGGCAAATTGTTATATGCTGCTTCAGGTTCCTTTTCTTCCTTTTCTTTCCTTGTTGCTTGTTATCTTAGCATTCTATGATGTGATATATACCTATGATATGAGATATCTATGGAGGTTGTAAACAGCATGTACAAATTAATTGTGACCAGATTATTTCTTGTTTGATTTGGGGACATTTATAATACTAATCTTCAACTA
->XM_016745472.1 Penicillium expansum Zinc finger, DPH-type (PEX2_082020), partial mRNA 
-ATGGCCGACGACGGACTGAACATCTACGACGAGATCGAGATCGAGGATATGACCTTCGACCCGAATATCCAGATCTATACATACCCTTGCCCATGTGGCGACCGATTCGAGATCGCAATCGACGATCTGCGCGACGGAGAAGAGATCGCCGTGTGTCCGAGTTGCAGTCTGATGATCCGGGTTATCTTCGACTTGGTATGTTTCCCTATCGTCCAACCAGACGCCGATCTTCCTAAAGCCGATGCGCAGAGTACGAGTGGCGTGGCTGTTCAGGCTTGA
->XM_047872644.1 PREDICTED: Prionailurus viverrinus adenylate kinase 4 (LOC125173463), transcript variant X6, mRNA 
-TGGTGCGGCTTAACCGCGCCCCAGGAGGGTGCCGAGGCTCGCCGGGAGGAGGGTGGGAGGTGCATGCTTCTCCTCTCCTCGCCTGGACTCCTCTTGCCTTGGGGAAAAGCCTGTAACCACCCAGCTGAGGGAGAACCAGACAGCTGAAAACCCCGAGCTTCCCTCTCGCCCTGCTTCCTTAAGGATAAGCCCTCCCAGCCCACGCGTCCCCGGGGAACTGGGGCGTCCCCCCGCTCTCGCCGCCCACCTGTGGGAGTCCGGTCCCGCTGCGCTCTGGGGAACCTGTGGCGCCGCGGGGCCCCCAGCCGCGCACTGTTCCTGCCCCTCTGCGTCACCCTGGGCCTCCGGGCAGAGCCCTGGTGGCTTTGAAAGGCCTGTCTGTCCGCTGCCGCCTTCTAAGAAGTTGGTGATATGGCAAAGCAGTACATAGAGAAAGGTCTTTTGGTTCCAGATCATGTGATCACACGCCTAATGATGTCGGAGTTGGAGAATAGGCGCGGCCAGCACTGGCTACTAGATGGTTTTCCTAGGACATTAGTACAGGCTGAAGCCCTGGACAGAATCTGCGAGCTGGATCTAGTGATCACTTTGAACATTCCATTTGAAACACTCAAAGACCGTCTCAGCCGACGTTGGATTCACCCTCCCAGTGGAAGGGTGTATAACCTGGACTTCAATCCACCTCATGTGCATGGGATTGATGACATTACTGGTGAACCATTAGTCCAGCAGGAGGATGATAAACCTGAAGCAGTTGCTGCCCGGCTAAGACAGTACAAGGATGTGGCAAAGCCAGTCATTGAATTATACAAGAGCCGAGGAGTGCTTCACCAATTTTCTGGGACGGAGACTAACAAAATCTGGCCCTATGTTTACACGCTTTTCTCAAACAAGATCACACCTATTCAGTCCAAAGAAGCATACTGAGCCCGCCCAATGAAGAACCAGGAAGATGTCATTCATTCAGTTGTATGTGTAGTATTGGTGCCGTGTCCAAATTAGAAGCTAGCGGGGATAGCTTGCAGCGTCTTTTCTAGTCTAAATGGTGAACTGAAATGAAAACAAATGAGGAGAAAGAGTTAATGAAGAGGCTCTTCTCTGCCTTTCTGATGAAGGGTCACCCACACATGTCTAGGATGTCTCTGCATGTCTCAAGCCCTTCACAAGAAAGCAAGTACAGGCTGGATTTCAAAGGGTGTATAACCCAAACTCTAGCTGATTTCTGACCATCACATTGTTGCCATAGTAGCCTTTTAACATGTGATGGTGTTGGCCTCTGGTTCTCCCTGCCCCCCAAAGGCTATTGAACCACAGCACCAGGTGGCCTGAGAATGCCAAGGGCAGTAGCCCCGGCCTTGTCCCAAGTTCTCTGGTATGTGCCCTTCCTGGTGACCGTGCGATTGAAGCCAGTTGCTCTGTGGTCACTTCTCTGGCCTTGAGTGACTGTCCACAATTAGCTTTTCTGTTCAGAGTGATACCTTTTTCTGCCTCCATGCTCTGTAGAGTCTCTCCTTTTTCAGACATCCTGGAATGAAAGGATTTCGCTTCTAGTATTTTTATTAGACTGTATTTTGGTACATCTGTTTTCTCTCTTCCTAGACTATGAAGTAATAGATAGTTACTGCTTTTATCTCTCTCAGATTCCTTTCTAAGAGCCGAGAGTGAGGGGAGGGTGTCCAGATGCTTCTTGCAGCAGGAACTGAGCTCTGCAGAGGGTCTACTTATGCTGCTGGGCTGACCCTCATGGGTTGACACTGCTCTTTTCTTTTATCATGAAAAAATAAAATCCTCAAAGTCTTTGGGAGTCTTCAGAAAAATGGGAGATACTACATACATGTTAAAGAATCATATCTTGTGTATAGAAGTAATAAGACCATATGGAATTACTGCACTAAAAGAATAGTTTAGCTTTTTATTCAAGACAAAAAAAATGTATTTTGAAATGCTGCTAAATATTGATGCTGACAGTGTTTTTCTCCTGGGAGTGACCCAAACATATTATAAATAGTTGGTAAAGGGAATGGAGCCTGTGTGTTGAGGAAAATGTTGCACTAGCTGTGCCCAGACTGAGTATGACAGCTTTGTGATTATGGGAAAACAAATTCTTAATTTTTTTTTCTTTCTATTCCAAAGATGCTTTCTGTGGGGTGGCCATTAAGTCTAGAAATATAGATGATACAATTTTGTCATTCTTTGTAATGTAATATCAATAAACCATTTATTAAAGATTTGCCTGGTTTCCAGACTTGGTGGCCACCTAATGTAATTCTGGCTCTCCTCTGGGAAGGACAATGAAATTTATTCCTGTTGCCTTAAAAATAAATACCCCTCTTCATGCATCGTGATTGTCCCCAAGGAGGGTTCTTTGCTATTCCTGAGAGTGACTTCTAACTCCTCATACTGAAGAGAAGGGGGGGGGGGGGGGCGGGGAGCCTATTTCAGCACGCCTCTGGTGTTGCAATGCATTGTTTATTTTCTGAAGATGTCCTGGAGAATCTCCAGTCAATTCCCTGGCAGATGTGTTCTGTATGGTAATCGTTGCATCTTCCTTACAAATACTGCCCCACTCTTGACAGTTCCTCTCCTCTATACCTTCGTGAGAATGTTCTTTGACTACCTTAGTGGAAACATAGACTGGTCTCCTCCTCATTCTCTGAATCACCATGTTACTTTTTGGGTGTATGCAATGGAGGTGCCCAGTTCAGGTCTGTGAAACATCAGTGCATGATATGGACTTCTAGTGCTTTAGAAGAGCCGTGTTTGAATGCCGGTTGGTGGGGACAGGGTGAAAATCAGACCTGTAGGTAAAGCTCAGGTTTCCTGGGGAACCAGGTACGGAGAAAACAAACCTGATATGAAGAAAGTTGCACAATTTAGACTAGTACTGCCATGGAGACAATTTCTAAAAACTAGGAAAAGTAGAGAGTTAAGGTTGTTTTATGGGTAATTCAAGAGAGGAATGTGTGTGTCCTTTTGTAAGTGGAAAAATCTACATGACTCTTCCTTTACTTCTCTTTTTGTTTAACAGACTCCCTTTGGAGTTTTTGAGAGAGTTATGGGAAATGGCTGGTCCCTGGTGCCATACTCTAGTTCTCAATCCTTCCCTCCTCTCCTCCAGCAGAATAGATAGTTATAGTCAGTGTGGGAGCCTCTCAGTGTCTCAACAGCATTTGCTGTTTCTGTGCTTGGTGAGGGCCCTGTGCTTGGTGAGACCAATAAAAAAGACAAACACCTTTTCCATGCGTCTTTGAAAGATGATACTTATTTCATGTTCAGTGGCCTAAAAAGTCTATTTCAGATTTTCTTCAACAAGCTCTCTAGCATTTTCTCCAGTAATTTTGTAAAAAATTAAAATTCTCTTGAAAATATTTTGATAAAAGCTAAAGGGACATCTTTTCTTGGTTTTTCTTCTACTGCCACAGATACGGTTCCTTCACAGTTCTGCAAAGAGAGTAATTTGGGTGTCTATAAGATTCCTACCGGTCCACATATTCTGTGATTTAGCCAGTTGTGAATTAATTTTGCTTTTCATTGTCTGAACAGGCTTCCCACTTACTTAGAACTTGGAGACATTGCTGTGTTTAATATCCTTTAACACTAAGGCAGACATAAAATAAGTATCATTTACTGAAGGCCTTTGGGCGATAGGTAAAGTTCTAGGACCTTAGCAAACACTCATTTAATCTTTCAAGCATCCTTTGAGATAGGCATGAAGCCATGTTTATGAACAAGGAAGACAAGGGTCAGAGATGTGAAGCATCTTGCCCAGGCTCTTGCTGCCAACAGACAGTCCAGCCAGGACTCACACCCAGGTTTTCCTGATTCTGCAGCCTGAGTTTGCTCCTGGATGTTAACTATCTGTGTCCTGTCCCAACCAACCTAGGGTGCTGAGCCTGCTTGATTTTGCTCGTATTTCCAAGTGGCCTCATCAAAAGTAGCAGAAGTGACATTCAGCTCTATATGGGACTGTTCTCCCCCTCCCCGCTTTGCTTAAGCAAAGGGAGCTGCTAGAGGAAGATCTGAGCCTTTGATCTTCTTTCCTAACTTCTCACTTATAAAATGAAAGGCTGTTGAAATAGGCTGGGCTTGGGTCCAGGCTAATCTGTGGAGGGGTCAGGTTCCTTCATGTTCCTCACCTACCTAGGCTTTTGGTATCCATGGTATTGTACCCCTAAGAGACCTTAACACTTCAGCCGCCTTCAACTATAGGGCTCCCTGTAGATCTGGGCTTCTGGGAGTTAGATGCTACTCACTTTTCTTCCCTGATACCAGGAGAAATTACTCCCTTACTCCCACCCCCAAATAAGGCCCTGATGATAAACATCCTTCCTGAAGTGCTGGCAGGTGATGGAGCCCCCAGCATACCATCTTGCCTATGTCACATTGCGTATTAACATGATCCTGAATGCTACATTCACACCTTTGCGTGCCATCTGATGTGGCACTGCTTGTCATGCACAATTCTGGTGGAAACCAGGGGAGATTGGTTTCCTGTGTTATCCGCCCTGCCCAGGGTCACTCCCCACCACCCTCCAGCAGCCAAGCTCAGATGAGCTCCAGCTTTACCCAGGGTGTGCCCCTCCCTTTGGTAGGGAAGGAAAAAGGTAATAACAGCCAATGGATAAAAGGGATTCTTGGAAAGAGCTACTGCTGTGGCTTCGCCCACCTACCACTTAAAAATGTTGAGACAGGATGGTTTTAGATAGATGGGTGCCTGTGCAAAACCATAAATAGGACTGTTAGAAAATTTAGTTCACTAAACTGATTTCAGTATTTGACTTTAGCTGTTTAGCAGTTTAAACAGCTTACCAGCCTGCTGGGGGTCCTGCTTAGGTCATAAAGACCACAAATTTCAAATATGTTAAGACATATGCATTCCTAGTAGTTCCTGTTTATTGGTACTTAATGCTAAGTGCATTATGTGCATTGTCTAATTAAATCTGCAGTAGTTACCCTAACGTAATAGATGTTTTAGTTATCTAGCCTCTGTGTAAAAACTGCAATCATTCTGTTCACTTAAGTTTGTATTTTCATGTATCTATAGGGATTAATCAAGAAATCCAAAAGGGCCTTTTTTTGTACCTTTTCCTCCTTTGAGTTCCCCATTCTAATTAATAGGTAAAGCAGTGTTATTTGATTGTACTTGGAATCTTTGCTTTTGGCACTCTGGTGCTGAGGCAAGAAGTGGGCACTCAGTGGGTCTTGGTGGTAGTTGCACACTGTATATACAGAGAGCATATATCTCATCTGCACTCTGCTGAGTTACAGGATCTCGGGAGACATTCATATCTACCTGATGAATTTCATTTATTACCTTTCATTTAAAACACAGTATCTTTTTTTGCTGCATTTAATTTTGCCAGAGAGGCAATTCATAAGGCCAAGTTGTGTTCTTAGTATGAATTGCTTTCTATTTCCCTTGCATTTTTAGTAACTCCCTGGTCTATTTGGTGTCTCAAAAGGAGAACCTAGCAATGCAGCCTGTTTTTTTTGTTTGTTTGTTTCGTTTTGTTTTGTTTTTTTTTTTTAATACGGGAGTGTGGTCTAGTCATAAGTTATCATCCCTTTCCACATATAACTGATCCAGTCTGGTTTCTAGATGAAGAGTGTGCAAGAGCCAGATGTTGGGAAACCCATGAAGCCGTATTTCAACTATGAAGAAAAATATACTTCCTGCATCTGTTGAGATATACTATAATTACAGTTGTTCATAAATGCCATACCTTATCTTTCTTTTAACAAATTGCACAATTCTTGCCAAAATAAATGCCATTATTCTGTATGCTTCAGGGAAATTCCCCCAATTTGATCAGTGAGCATATGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTAGGGAGAGGGAGGGAGAGATGGTGAAACATTTCCAAGGGGACAAGAGCCCTTGGATGGCATGGATGTGCATTCCTTCCGGGTAATAATTACGCTATTCCAGGAAACAGCATGTGTCTTCCTGGAAATAAAGATTTCCTGTCTGTAACTTTTGTAAGTTACACCAAGTGCACCTTGTGATTCTCCCTGGGGTTGGTGTGTGTCTAATTCCATTTCATAAAACCTTTCTTCATTTTAAAGCTTTGGCTGTGAAGTCAGAAATGTGCTAAATAAAAACAAACTGTTTTGTATTTAATTTAGAGAAGGGTAAAGGGAAGAAAAAAAAAAAAACTCAGTCTTTATGTAAGCTCCAAGGTGTTAGGGCTTAGAGGGTTTTTCTAGTTTTATGAGAATTTGTACTACTGATTTTTATATATTCCTGTTTTTGAGATGAACAGATCTCTGGGGAAATTGTTGCATTACAATGGCGTTTCACTGTGACCCCTCTCAAGCTCAAATCTGTTCTCTTAAGCCAATGACAACTTGTCACTTCGGTTTACTGTCCTGTGAAAAGTCAGCTCCAGTTTCCCAGAAGTTGTGTGTTTATGATGAGTCAGTGCTTTTCTTCAGTGAAAGTTGTCAGCCTTCTTGATTTGGGTGTATGTGCTTAATTCAGAGTATCTAAACCTGTAGTCTAATCTGTACATGCTCTCCTAACTGTTAATTGTTATTGACTATTTTGATTATCTTGCTTGAAGATTGATTCCTACTTTTTAATTTGATAGAAATAAAGTTTTTTTTTCCTGCTTATAACTA
->XM_032280742.1 PREDICTED: Sapajus apella ubiquitin specific peptidase 32 (USP32), transcript variant X1, mRNA 
-GGCTGGCGGGAGGGGGCGGGGGAGGGAAGAGGGCGTGAGGAGGGAGGAGAGAGAAGGGCGGAGTAGGAGGGAGGGAAAGGGGGGCGGGGTGGAAGCGGGTCACGTGATCCACCATGGAGGCGGTGGCGGCGACCGGGAGGAGCCGCCGGGGCAGAAGCCGCACTTGTTAGTGTGGGGGGAGGTGGGGGTGGGGGACGCCGACACCGTCACCCAGGGACGCCGAGGAGAAGGCGGGAGGGGGGTGGGGGCGAGATCAGGCTCCGACCCCCGGCCGAGGGGATGTGGGGAGCATGGGCGCCAAGGAGTCACGGATCGGATTCCTCAGCTACGAGGAGGCGCTGAGGAGAGTTACAGATGTAGAGCTAAAACGACTGAAGGATGCCTTCAAGAGGACCTGTGGACTCTCATATTACATGGGCCAGCACTGCTTCATCCGAGAAGTGCTTGGGGATGGAGTGCCTCCAAAAGTCGCTGAGGTGATTTACTGTTCTTTTGGTGGAACATCCAAAGGGCTGCACTTCAATAATTTAATAGTTGGACTTGTCCTCCTTACAAGAGGCAAAGATGAAGAGAAAGCAAAATACATTTTTAGTCTTTTTTCAAGTGAATCTGGGAACTATGTTATACGGGAAGAAATGGAAAGAATGCTCCATGTGGTGGATGGTAAAGTCCCAGATACGCTCAGGAAGTGTTTCTCAGAGGGTGAAAAGGTAAACTATGAAAAGTTTAGAAATTGGCTTTTTCTAAACAAAGATGCTTTTACCTTCTCTCGATGGCTTCTATCTGGAGGTGTGTATGTTACCCTCACTGATGATAGTGATACTCCTACTTTCTACCAAACTCTGGCTGGAGTCACACATTTGGAGGAATCAGACATCATTGATCTGGAGAAACGCTATTGGTTATTGAAGGCTCAATCCCGGACTGGACGATTTGATTTAGAGACATTTGGCCCATTGGTTTCACCACCTATTCGTCCATCTCTAAGTGAAGGTTTGTTTAATGCTTTTGATGAAAATCGTGACAATCACATAGATTTTAAGGAGATATCCTGTGGCTTATCAGCCTGTTGCAGGGGACCCCTGGCTGAAAGACAAAAATTTTGCTTCAAGGTATTTGATGTTGACCGTGATGGAGTTCTCTCCAGGGCTGAACTGAGAGACATGGTGGTTGCACTTTTAGAAGTCTGGAAGGACAACCGTACTGATGATATTCCTGAATTGCATATGGATCTCTCTGAAATTGTAGAAGGCATATTGAATACGCATGACACCACAAAGATGGGCCATCTTACTCTGGAAGACTATCAGATCTGGAGTGTGAAAAATGTTCTTGCCAATGAATTTTTGAACCTCCTTTTCCAGGTGTGTCACATAGTTTTGGGGCTAAGACCAGCTACTCCAGAAGAAGAAGGACAAATTATTAGAGGATGGTTAGAACGAGAGAGCAGGTATGGTCTGCAACCAGGACACAACTGGTTTATCATCTCTATGCAGTGGTGGCAACAGTGGAAAGAATATGTCAAATACGATGCCAACCCTGTGGTAATTGAGCCATCATCTGTTTTGAACGGAGGAAAATATTCATTTGGAACAGCAGTACATCCTATGGAGCAGGTTGAAGATAGAATTGGAGGCAACCTCAGTTATGTGAATTCTACAGAAGAGAAGTTTTCAGACAACATTTCTACTGCATCTGAAGCCTCAGAAACTGCTGGCAGCGGCTTTCTGTATTCTGCCACACCAGGGGCAGATGTTTGCTTTGCTCGACAACATAACACTTCTGACAATAACAACCAGTGTTTACTGGGAGCCAATGGAAATATTTTGTTGCACCTTAACCCTCAGAAACCAGGGGCTATTGATAACCAGCCATTAGTAACTCAAGAACCAGTAAAGGCTACATCATTAACACTAGAAGGAGGACGCTTAAAACGAACTCCACAGCTGATTCATGGAAGAGATTATGAAATGGTTCCAGAACCTGTGTGGAGAGCACTTTATCATTGGTACGGAGCAAACCTGGCTCTACCTAGACCAGTAATCAAGAACAGCAAGACAGACATCCCAGAGCTGGAATTATTTCCCCGCTATCTTCTCTTCCTGAGACAGCAGCCTGCCACTCGGACACAGCAGTCTAACATCTGGGTGAATATGGGTATGATGAGCCTGAGAATGTTTCCTCAGCATTTACCGAGAGGAAATGTACCTTCTCCGAATGCACCTTTAAAGCGAGTATTAGCCTATACAGGCTGTTTTAGTCGAATGCAGACCATCAAGGAAATTCACGAATATCTGTCTCAAAGACTGCGCATTAAAGAGGAAGATATGCGCCTGTGGCTGTACAACAGTGAGAACTACCTTACTCTTCTGGATGATGAGGATCATAGATTGGAATATTTGAAAATCCAGGATGAACAACACTTGGTAATTGAAGTTCGCAACAAAGATATGAGTTGGCCTGAGGAGATGTCTTTTATAGCAAATAGTAGTAAAATAGATAGACACAAGGTTCCCACAGAAAAGGGAGCCACAGGTCTAAGCAACCTGGGAAACACATGCTTCATGAACTCAAGCATCCAGTGTGTTAGTAACACACAGCCACTGACACAGTATTTTATCTCAGGGAGACATCTTTATGAACTCAACAGGACAAATCCCATTGGTATGAAGGGGCATATGGCTAAATGCTATGGTGATTTAGTACAGGAACTTTGGAGTGGAACTCAGAAGAATGTTGCCCCATTAAAGCTTCGGTGGACCATAGCAAAATATGCACCCAGGTTTAATGGGTTCCAGCAACAAGACTCCCAAGAACTTCTGGCTTTTCTCTTGGATGGTCTTCATGAAGATCTCAACCGAGTCCATGAAAAGCCATATGTGGAACTAAAGGACAGTGATGGCCGACCAGACTGGGAAGTAGCTGCAGAGGCCTGGGACAACCATCTAAGAAGAAATAGATCAATTGTTGTGGATTTGTTCCATGGGCAGCTAAGATCTCAAGTCAAATGCAAGACGTGTGGGCACATAAGTGTCCGATTTGACCCTTTCAATTTTTTGTCTTTGCCACTACCAATGGACAGTTATATGCACTTAGAAATAACAGTAATTAAGTTAGATGGTACTACTCCTGTACGGTATGGACTAAGACTGAATATGGATGAAAAGTACACAGGTTTAAAAAAACAGCTGAGCGATCTCTGTGGACTTAATTCAGAGCAAATCCTTCTAGCAGAAGTACATGGTTCCAACATAAAGAACTTTCCTCAGGACAACCAAAAAGTGCGACTCTCAGTGAGTGGATTTTTGTGTGCATTTGAAATTCCTGTCCCTGCATCTCCAATTTCAGCTTCTAGTCCAACACAGACAGATTTCTCCTCTTCGCCATCTACAAATGGAATGTTCACCCTAACTACCAACGGGGACCTGCCCCGACCACTATTCATCCCCAATGGAATGCCAAACACTGTTGTGCCATGTGGAACTGAGAAGAACTTTACAAACGGGATGGTTAATGGTCATATGCCATCTCTTCCTGACAGCCCCTTTGCAGGATACATCATTGCAGTCCACCGAAAAATGATGAGGACAGAACTGTATTTCCTGTCGTCTCAGAAGAACCGCCCCAGCCTCTTTGGAATGCCATTGATTGTTCCATGTACTGTGCATACCCGGAAGAAAGACCTATATGATGCGGTTTGGATTCAAGTATCCCGGTTAGCCAGCCCACTCCCACCTCAGGAAGCTAGTAATCATGCCCAGGATTGTGATGACAGTATGGGCTATCAGTATCCATTTACTCTACGAGTCGTGCAGAAAGATGGGAACTCCTGTGCTTGGTGCCCATGGTATAGATTTTGCAGAGGCTGTAAAATTGATTGTGGGGAAGACAGAGCTTTCATTGGAAATGCCTATATTGCTGTGGATTGGGACCCCACAGCCCTTCACCTTCGCTATCAAACGTCCCAGGAAAGGGTTGTAGATGAGCATGAGAGTGTGGAGCAGAGTCGGAGAGCACAAGCCGAGCCCATCAATCTGGACAGCTGTCTCCGTGCTTTCACCAATGAGGAAGAGCTAGGGGAAAATGAAATGTACTACTGTTCCAAGTGTAAGACCCACTGTTTGGCAACCAAGAAGCTGGATCTCTGGAGGCTTCCACCCATCCTGATAATTCATCTTAAGCGATTTCAATTTGTAAATGGTCGATGGATAAAATCACAGAAAATTGTCAAATTTCCTCGGGAAAGTTTTGACCCGAGTGCTTTTTTGGTACCAAGAGATCCAGCGCTCTGCCAGCGTAAACCACTCACACCCCAGGGAGACGAGCTCTCCGAGACCAGGGTTCTGGCAAGAGAGGTGAAGAAAGTGGAAGCGCAGAGTTCGGCCGGGGAAGAGGATGTGCTCCTGAGCAAAAGCCCATCCTCACTTAGCGCCAACATTATCAGCAGCCCAAAAGGTTCTCCTTCTTCAACAAGAAAAAGTGGAACCAGCTGTCCCTCCAGCAAAAACAGCAGCCCTAATAGCAGCCCACGGACTCTGGGGAGGAGCAAAGGGAGGCTCCGGCTGCCCCAGATTGGCAGCAAAAATAAACTGTCAAGTAGTAAGGAGAACTTGGATGCCAGCAAAGAGAATGGGGCTGGGCAGATCTGTGAGCTGGCTGACGCCTTGAGCCGAGGGCATATGCTGGGGGGCAGCCAACCAGAGCTGGTCACTCCTCAGGACCATGAGGTAGCTTTGGCCAATGGATTCCTTTATGAGCATGAAGCATGTGGCAACGGCTACAGCAATGGTCAGCTTGGAAACCACAGTGAAGAAGACAGCACTGATGACCAAAGAGAAGACACTCGTATTAAACCTATTTATAATCTATATGCAATTTCGTGCCATTCAGGAATTCTGGGTGGGGGCCATTATGTCACTTATGCCAAAAACCCAAACTGCAAGTGGTACTGTTACAATGACAGCAGCTGTAAGGAACTTCACCCTGATGAAATTGACACCGACTCTGCCTACATTCTTTTCTATGAGCAGCAGGGGATAGACTATGCACAATTTCTGCCAAAGATTGATGGCAAAAAGATGGCAGACACAAGCAGTATGGATGAAGACTTTGAGTCTGATTATAAAAAGTACTGTGTGTTACAGTAAAGCTACCACTCTGGCTGCTAGACAGCTTGGTGGTGAGGGAGATGACTCCTTGTAGCTGACATTTGGCAGAAGCGTCACTGAAAGGCAAGCTAAATGTAGTTATTTTATCCTGTGACCCTGAAGCACAAAATAAAAATTCTAATTAAAATAGTTAACTTTAAGAGTAGTAATAATTTTATTTTGAAGTCTCATACAAGCTCTCCGACAGAGAACTTTCAGGCAGATCCCACCATTAGCCTGTAAACAAAGGGTTTGGCACCAGCCACCTGGGACCAAATAAGAATTCAACTGTGCTTGTCCAGATGTGAACAAATATGTAGTGAGTATAGAGTTTACCAGTAATCATAACAAATATTAAAGATTTCCTTGGAGTCAAAGTAAAAAACAAAAAATTATAATGTTGTCTAGGGACGACATGATATGCTACCTCCTTTTTCCTGAAGTTTTATTCCATTATATTGACAAGATGGAGAAAGCAAGATCATGAAGGTGTGCAAATGATTCTTATGGCATGGATGATGATTTTTTGATTTATTTTTTAAATTGTTTCCCTACTCTGTCTTTCTTGTTTTTTGTTTTTGTCATTGTGTTTGAGTTTGAGACACAACCAGTCATTGGTGGCAGGGGCATATAGTGGTTAGTCTGAAAGGGAGGCTTTCTTAAGAGCTATGTGCCTTCCACCCAGAGCCTTGTGGGAGACCCAGTAAAAAGGAAAAGCATCCTGGGAAATCCAGCTACCATGGCCCTCCCAATGGAGGCATCTTACATTTAGGATACTTCAAGTATCCTCAGAAATGTATTCTGCACCCCCGGCCCCACCCATGCTGAGGGAGGGGATGTTTGCCAATATTTGCATCATCTTCACATGCACATGTTGCAACAAGAGCTTCTGGGAAGGTAAGCAGCATTGGAGCTAGATCAAGTTTCACAATTAGTGGTTCTTTTCCGTGTTTGTTTTGCACTTTAAAAAGGAGAGAACACATGCAAATGAATCTGCTTGTGTGTATTTGATGGCTCTAAGGGCTATAAATTAAAACAAAACACATCCCAGACATTGGGATTTCATAGATTTATTTAAGGAAGTTGGTAGTTTTAGGAAGTCAACTTTAGTTTTGCTTTATTTGCATGTCCACTAATTTTTTTATTTTGATATTTGTCTTTTTAAAAAAATTTGCAGTAGTTATTAAAAGTTATGTTTCTTTGCTTACTTCATTTTTTTCTCCAATTATTCAAGACTGGAACAAACATAAATATTATTTATTTCAGGTAGCATTTTTTTTCTGTGTAGTTTTTTAATATATATTTGAAGGAAATGTTTCATCTTGTTTTTGGTCTTTGTTTATTCATTTAGACCCTGCAAGTTGATTCTCATTAATTGTCAGATTCCACTACCCTTTCTTCCTCAGAGGTAGTAATTACCAATGTAACTAAGCATTTGTATTCTGATATCTGAGGCCAGTAACTATTAATATCTAGTTCTTTTCAGAGCATTTGGAATGGTTACCTTAAATGACTACCTAAATTGAAATCCTTTTCAGAAAAAATATAATTACAAGTAGAAAGGAGTGGCCTAAATTGTATAATGTAATAAAGTCAGACAAAATGCATACTTTATAGTTTCAGATTTTCAGTATATAAAATGTGTCCATTCCTACCTGGACATGTCCCATTAAAAAGTGGAAGATTTTAAATAATTTCTTTACAGATGTTTTATTTAAGCAGGTAGCACAATCTACTAATGTTGTTTGATCTGTGTTTGTTATACTGGTTGTAATTAATTTTTTTAATTCACGAACTAGCAGAAAGTTTATTAAATTAACTATTAACTACATTCACCTTGTAAATTACTGTATAAAACTTGTTGACAATGCACTGACTTTAGAAAGATGTTAATGTACATAAATAGAGTGTAAATAAAATAGTGTTGATGTACTGAAATATGAACTGTATAAAAAGTATTGGTAATTGTATATGGGGTGTACCTGTTTATCTGTAACTATTATCCAAACAAATTAAATACTGTGGATGCCTCTATGTGCTGTTTTGCCTCATACAAGTAAACACAGAAAGTCAAATTCTTCAA
->HQ846933.1 Monilinia fructicola isolate HAG7 internal transcribed spacer 1, partial sequence; 5.8S ribosomal RNA gene, complete sequence; and internal transcribed spacer 2, partial sequence 
-CCTCCCACCCTTGGGTATTATTACTTTGTTGCTTTGGCGAGCTGCCTTCGGGCCTTGTATGCTCGCCAGAGGATAATTAAACTCTTTTTATTAATGTCGTCTGAGTACTATATAATAGTTAAAACTTTCAACAACGGATCTCTTGGTTCTGGCATCGATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCCTTGGTATTCCGGGGGGCATGCCTGTTCGAGCGTCATTTCAACCCTCAAGCACAGCTTGGTATTGAGTCTATGTCAGTAATGGCAGGCTCTAAAATCAGTGGCGGCGCCGCTGGGTCCTGAACGTAGTAATATCTCTCGTTACAGGTTCTCAGTGTGCTTCTGCCAAAACCCAAATTTTCT
->XM_035415524.1 PREDICTED: Anguilla anguilla abl interactor 1-like (LOC118226150), transcript variant X7, mRNA 
-TCAGTTTTTTTGTATGTAGCTGGTGAAAGGTCGCTGTGGTGAAATCGAGGCCAGGAATCCCACAATACTAGGCGAAGGAGCTCCTTTTCGGGGCTGAGCTTGTGGTTTTAATCAAAGGGAAGGCGAAGAAGCGATGCAGAGACATGTAAGATGGCAGAGTTACAAATGTTGTTAGAAGAGGAAATTCCAGCCGGCAAAAGAGCCCTGGTAGAGAGCTACCAGAACCTCACGAGGGTTGCGGACTATTGTGAAAGCAATTATGTTCAGGCCCAGGACAAGCGGAAAGCTCTGGAAGAGACCAAAGCCTACACCACCCAGTCTCTGGCTAGCGTGGCCTACCAGATCAATGCCTTAGCCAACAACGTGCTACAGCTGCTGGACATCCAGGCATCCCAGCTGAGGAGAATGGAGTCCTCCATCAACCACATCTCCCAGACTGTGGACATCCACAAGGAGAAGGTTGCCAGGCGAGAGATTGGAATTCTGACCACAAACAAGAACACCTCGAGGACCCATAAAATCATCGCCCCCGCCAACATGGAGAGGCCGGTGAGGTACATCCGGAAGCCCGTAGACTACACGGTGCTGGACGACGTGGGCCACGGAGTCAAGTGGCTGAAAGCTAAGCAGGGGAACAACCAGCCGGCCAGAGGAGGGACGCTATCGAGGACCAATCCGCCGACGCAGAAGCCCCCCAGCCCGCCCATGTCCGGGCGTGGCACTCTCGGACGCAACACACCATACAAAACCCTGGAACCCGTTAAGCCTCCTGTCCTGCCCAACGACTACATGACCAGCCCCGCCCGCCTGGGCAGCCAGCACAGCCCTGGGCGCACAGCCTCCCTCAGCCAGAGGCCCAGAACTCACAGTGGAAGCAGCGGGGGCAGCGGCAGTCGTGAGAACAGCGGCAGCAGCAGCGGCGTTGGCATTCCACTAGCGGTGCCTACGCCTTCTCCACCCACTATGGCACCAGCAGTGGCCCCAGGGCCCGGTCCAGGCCCGATTCCCATGTCCCAGTTTGGCACGCTGTCTCGGCAGATCTCCAGGCACAATTCCACCACCTCCTCAGTCTCCACGGTTTCGGCCACGGGGACGTACAGGCGGGCCCCCTCCGTCACGTCCCAGTTCTCAGTCCAGCAGCCGCACATTAACGGCGGCCCCCAGGTGTACCCCCAGAACTCAATCGCCGACACCCCCAGCCTCCCGCCCCCTCCTCCCCCGGACGATGTCCCGATGTTCGACGAATCCCCGCCGCCACCCCCTCCACCGCCGGTGGACTACGAGGACGAGGATGCGGCCGTCGTGCACTACAACGACCCCTATGCGGACGGCGACCCTCAATGGGCCCCCAAGACGTACACTGAAAAAGTGGTGGCCATATACGACTACAGCAAGGACAAGGACGATGAGCTGTCTTTTATGGAGGGGGCAATCATCTACATCATCAAGAAGAACGACGACGGCTGGTTCGAGGGGGTCTGCAACGGCGTTACTGGCCTCTTCCCTGGAAACTACGTGGAGTCCATCATGCACTATGCTGACTAAAGACACCCCTTTTTTCTTCAGTCATCCCAAGACCATTATAAAAAAAGCATAACACTGGTCTACAAAAGCATATGTATAAGTGCATTAGAAAATGACCGAATGTTTGTTCCTTATTGAATTGCAAATAAAATAAATTCTATTTAGTTTTTTTGGTGGGAAGATTGTGGGATATAATGTATTACTTTGATGAGGTCCAATGGCTTGGTTGATCACATGCTCATGTCTGTCAGTTGTCCTGTCAGTTAATTGTATATAATGTTGAGGGCTGCAATTGGGTTGTTGGTAGTGTTACTGTTAATATTGATAAATGTCCTGAGCAGTGGATGCCACAAGTGAACATGTTAAAGTAGGGATTATGTTTTATAATGAGTCCGGTTATAAATTGTGCCATTTTCCCCCCTACCTTATCTTCCTCAGAAGACACAAGACCAATTTAATGCATTTTGGATCCTGAATGCAAACTTAACTGCTTGCCAGAATTGCAGACTTTTTTTTAGAACAGTGTTTCCTGGCTACTCGTAATTCCTGAAATGTACTTATCTTGCCGTGAAGCATGCACACAAAAGAACTGTAACATATACTTTATTTCCATTATGCTTCCAGTATGGTGTAATATTTACAGTGAGCACTCAAAATTAGTTTTTTTAAATGAAATGTCTGAAGCGGTTGTTTAAAGTCGTATTCTTTTTTCTGAAATGCTCTAATTTGTATTTAAAACATTTGATATGATTACATTTACATTAATAATTTCTACATTGAGTTATATATGTAAAACAAGGCTGTTTTGTTGGTAAGGTGTCTCAGAAGTCTGGAACCCTTGCCATTTGCTTGATACAGGTGTTGAAATGGTTTAAATTTCCAATCATTTATAGTTACAAAAGCAAAACCTCAAGTCATTAAAATTTCTGTGGAGAAAATACATGGTTCTAAAAACTTCAGTTAATTGGATGTTCTGTGTTTTAGTGTTAATGAGCTCTATCAAACATGGATATTTTAGATGTGGCCAAAATGTGCTCAGTTGGGTTATAACTGTTTCTCATCTGTCACCTAAAAAGCCATATGAATATTCCATTTTTAAAAATTGTAATGAAAACCAATACAACATATTCCTCTTCCTGAGAGGAAAAACAAGGGAGTTGCCATCCTGTCAAAGTATTGGTTTACTATTTTTAAAAATTTAATTACTCCATTAATTGTCTAGGTTCATAACTCAGGTCTAGTAATCTCCTTTGTTATTAAACAATCACTACAACAGAGCAAGGCAATGCCATCTTTTCATCTCTTAGTTTTGTACATTTTCTGTATTTTATAATGTATGAACATAAGTTTGAACCTTACCACTAAACCTGCTTTAAAAGGAAGTCACTCCTTCAAGTTTCACCTCTTCTTGAAAAATCCATTAGGTTGAAACTGACTGCTTACAGTATATTAATCACCAATGTGTGTTTCAGGATATTATCGCCAATTCCTTGATTCTTCAGTGTACGCTTTGGTATATTAAATGTGGAAAATTGCTAAATTCTTGCTTTCCTTTGGGAAGAACCCAAAACTTCTCTTCCAACCATAATTTGTATATATAAAAATGTTAATGAAATTTATGTACAGCTTTTTTATATAATAAATCATTCTCCTATATA
->XM_017904422.1 PREDICTED: Eufriesea mexicana facilitated trehalose transporter Tret1 (LOC108550645), transcript variant X4, mRNA 
-ATTAAAAATCGAAGCAAGAAAAAATGGCGACATCCAAAACTCAGATAAATCATCTTTAGTGGAGTCAACATTACTTCCAAAAACCCAGTCAGTTAACCAGTTGGAAGATGGAAGACCTGAGCTTGCAACCAACAGTGGATACAGCGATGATGGAAATGGTCGAAATGTTAGTGGAAGTGTCATCAAACAAGTTCTGGCAGCAATAGTAGCGCAACTTGGGACCATTAACACTGGTATGACTTTTGGTTTTTCTGCCATTGCACTACCACAACTTCAGGAACAAAATAGCACCATTCCTATCGTCGAGGGATCATCCGAAGAATCATGGATCGCGAGTATGTCTTCCATTGGAACTCCCATTGGTTGTTTAGTGTCTGGATATATGATGGACGTACTTGGAAGAAAACGATCTCTCATTATTACTGAGATTCCAGCATTACTTGGATGGATATTAATTGCATTAGCAACTGATATTCGTATGATATATGCTGGAAGATTCTTCGTTGGACTTGGATCGGGTATGGTAGGCGCTCCAGCACGCGTCTATACTGGAGAAGTAACACAACCCCATCTACGAGGAATGTTGACTGCTTTTGCAAGTATTGGAGTCAGCACTGGTGTTCTGATCGAGTATGCATTAGGAAGCGCACTTACATGGAACGTCTGCGCAGCTATTAGTGGAATTATACCTCTTGCCGCTCTGCTGTTAATGTTTCTCTTTCCTGAGACACCTTCATACCTCATATCTCGTAGTAGACCTGAAAAGGCACGAAAAGCGTTACGACAATTTCGCGGTAGTACATATAATATTAATCAGGAAATGGAAACACTTATTAATTTTTCAAATAAGAATAATATTAAGCGTTTAACAGGATTCCGTGAGATAATTAGCGCCCTTTTAAAGCCTAATGCTGTCAAACCTTTTACTGTCCTATTCTTGTACTTCTTAATATACCAATGGTCAGGTACAAATGTCATAACTTTTTATGCTGTTGAAATTTTTAAAGATTCAGGAGCAACGTTAAATAAGTACTTAGCTGCAGTAATTCTCGGAATAGTAAGATTAATATCAACGGTTGCCGCTTGTATCTTGTGTAGAAAGTGTGGCCGAAGGCCCCTTACAATGATTTCTTCCATCGGTTGTGGACTTTCCATGGTAGGATTAGGTGGATATATGTGGCTGAAAAATAACTGGGATGCAAATAATTTTACACCTGTTGCTACTTGGTTCCCTGTCTTTTGTATATTTGCATATACTGTAACTTGCACACTTGGTTTTCTTGTTATTCCTTGGGTAATGATAGGCGAGGTATATCCAATACAAGTACGCGGTATTATTGGAGGTTTAACTACAATGGCAGCCCACTCTTTTATTTTTACAGTAGTTAAAACGTATCCGTTCCTAGCTAACGCACTTACTCGGCACGGTACTTTCATCCTTTATGGTTGTATATCTTTATTCGGCACGATATATTTTTATCTATGTCTTCCCGAAACTAAGGGTAAAACTCTTCAAGAAATAGAAGATTACTTTTCTGGTAGAAACAATAACTTAAGAACCGGAAGTATAGGTAAACATAAGCCAAAGGTATTAGAAGTAAAAAAGGGTCACATATTGCCTTGAATAACTCATACAGTGAACATCTTAATAAAATTAAATTAATAAATCTGTCTTCCATTGAACAAAT
->XM_001378120.4 PREDICTED: Monodelphis domestica inhibin beta C (INHBC), mRNA 
-ACCCTGCTTTGTACTTTAGCTACTTATCAGTTGGCAGAGTCTGCCAAGTTCTAGTGTTGGTCTTGTCCTTCTCAAGCCAGATGTGCGGCCACCATCTCTCCCAAGGTAAAGAATCATGCCAGCTGGACACACACCTTTGGTGTGGACTCTAGCATTTAAAACTCAAGTGGCATAGTGGCTGAAGCCCTGAGCCCCAGATTTAAGGTGTTTCTTCTTCCAGAGGAAGACCCAGCTGAAAATGGTCTCTACTCTGCTCCTGAGTCTCCTGCTCTTGATTCCAGCTGCAGCAGGGACCGAATGGATTGATGGTCAATGTCCAGCATGTGGGGTGCCTGGTTCAGATCCTGAGAGACAGAGGGAAATACTGCTCAATCTGGCAAAGCAAAATATCCTGGATAAACTGCACTTAACTCAACGCCCGACACTGATCCAGCCTGTGTCCAAAGCCACCCTGAGAACTGCACTTCGACGCCTCCACGGTCTCCAAGGAGGAAGGATTGTGCCTGGTAGCACTTTAGGGGGTTCTGGGACTGGAGTTGAGGAACAGGAGTATGAGATCATCAGTTTTGCTGAGACAGGCTACTCTACCACCAACAGGACGGTGCTGGATTTCCAACTCTCCCCAGATCAAAGCAGTGGTAGCTTGGAGGTCCTCCAAGCCAGGCTGGGTTTTTTCTTGAAGATTCCTCCCAATGGCACATGGACTATGCACGTGAGGGTCCTGGGGCCTGGGCCCCGGGACACCAACCTCACTTTGACCACCCAACACCAGCTAGAGGTAGATGCCAGTGGCTGGCACCAGTTCCTCCTGGGGCCAGAGGCCCAGGCTGCTTATGGTCAAGGGCATCTGACCCTAGAATTGGAGGCCAAAGGCTGGGGAGCCCAGGGCCCAGTTTTCTTGGAAAAGGATGCCCATCAGCCCTTTATAGTAGCTCAGGTGAGAATAGGAGAAAAGCACCGGATTCATCGTCGAGGCATCGAGTGCCAAGGTGGGTCTCAGATGTGTTGTCGACAAGAGTTCTTTGTAGATTTCCGGGAGATTGGCTGGAATGACTGGATCATTCAACCTGAAGGTTATGCTATGAACTTCTGTACAGGGCAGTGCCCACTACATGTGGCAGGCATGCCAGGAATCGCTGCCTCTTTCCACACTGCTGTGCTTAACTTGCTCAAGGCTAATGGGGCCCCAGGAACAACTGGAGGAGGCTCCTGCTGTGTGCCTACTGCCCGCCGCCCTTTGTCCCTTCTCTACTATGACCGCGACAGCAACATTGTCAAGACTGACATCCCAGATATGGTGGTGGAGGCCTGTGGCTGCAGTTAATGTGTATAAAAGGGAAGGAGGACACGCAGAAGAGGACATTCACTTAGAGATTCCCTTCTCATCTCAGGCAGGTTGTTCACAAATTCTTCCACAACCCATAATGGGGAACCAAGGCATTTCTGGAAATCCTTCCACTCTCCCTCTGGACATTCTATTGAAGCATCTGGTAGCAGGGTAGACAGAGAGCACTGGACCTCAGCAAGACCGAGTTCAAAGTTGGCTTCAGTATGACCTGGAGCAAATCACTTGTCTTTATAGTCTCCTCAGCTATAAAATGGGAACAATAATAGTACCTATCTCACAGGATGGTTGCATGAATGAAATGAGATGTTTGTAAAAAAGTACCATAGTACTTGGTGCATAGCA
->XM_017900195.1 PREDICTED: Eufriesea mexicana UPF0769 protein C21orf59 homolog (LOC108547609), mRNA 
-ATGGTCCGGATGCACGTGAAGAGAGGCGAGGAGAGCCAGTTTCTGTACGACACACACGTGGAGGCTCGGGTTGAAGACATTATATACGGCATTACTATTATTTACAACGGCCGGCTGAAGATCTCGAGAATATGTTATGAAATCGAGGAGCTGGCCAAGCACGGCACCATGCTGCCCCATAACATCATGGGCCTCACCGACGAGCAGGTAGAGGAGCTGAAGCTCAAGGACGAGTGGGGCGAGAAGTGCGTACCGATGGGCGGATGGACCTTTAACAAGGACGTTATCGGCCGCAGAAACGGCAGACAGCCTAACGCGAAGATGCAGGAGGTCTTGAACAAAACGATCGGGGAGGCACGAGCTATGGTTTCAAAGAAATTGATACAAGAGGAAAAACTGGTGACGCAGAAAACTGTGCAAGATGCACTGGATATACTGAGGGGGGCCGTAACGATTGTGTATCCGATGGGACTTCCGCCTCACGATACGATCCGACAGGAATTCGAAAACACCGAGGATCTGAGTGGCACTCAGGCATCTCTCGAAGTTATCGACGTACAACTGGCGCAACTTTGGTTCTCGGGAAAGGAAATGTTACCGGGAAGAAAATTAAAAGATTATTTGGGGATGAACGAGAAAACCAAGATTATCGTGAAGCTGCAGAAAAGAGGAGCCGGAAGACCTGCTCGTGAACCTCTGATGTCAGAGGACGAAAGGAAAGAACTAATGCTGCATGCATATAAACGACAAGAACAACTCAAGATTTCTATCGTGGATAGTGATATTATGTTAACACAAGCGGGTAAAATCAGTTTTCTGATAATTCTCTCAATTTTTCTTCGGTTATGCAGTGCCATGTGGAGAATATTGTGGTGCCTGGGTAAACCATATAAAGCTTAG
->XM_007934287.1 Pseudocercospora fijiensis CIRAD86 uncharacterized protein (MYCFIDRAFT_46883), partial mRNA 
-ATGGCCGCGCCTGCACAAAATGGCCCTGTGCCCGCGGGCGCCCCTGCAAAAGCGACAGAAGCGCAACTCATCACTGCCTTTGACAACTCAATATGGTATCTACTTGACCTATGGCAACCGCTATCCATCGCAGTGGATAATGGCTGGGGCGGAGGGAATTCTTCAGACAAGCGCGACTGGTTCGCCGGCGCAGTTTCCGATTTCTTGAATCAACCGCAGTATATCAATCCTGCTCCGGGTGCTGTGCTCACCTTCGCCGACATGCAAGAAGATCTCGAAGTTTTCCTCCTACAAATCATGCAGGACGAGTTTGACTGCAACATCGAAGACGAATCGGAAGTGGAGCTTGCGAACGGCATCCTCAGAGTGCGAAAAGCCATGACTGAGACCTTAAGCACGGCTGCGGCGGACGAGGTGAAACAGAGATGGGAGAATCGAGGAAGCAAAAAGCATGAAAAGATTGTGGTTCAGGAAACGAACCAGGAAGTTGGCGACGACGAAGAGTGGGATGGTTTTGATGAGGACGAGGATATGGACGAGGCGCCACAGCTCCTGCAAGCGCCTGCACAGCCGCGAGAAAAGCCTATACCTGAGGTTGACGAGGACGGATTCACAAAAGTCCCGAGCAAGAAAAAGAGATGA
->XM_007491848.2 PREDICTED: Monodelphis domestica cytochrome c oxidase subunit 6B1 (LOC100013297), transcript variant X1, mRNA 
-CGTTCCAGGCCTACGCTTCCGCTTCCGGTCTCGGACCCTTAGTGCTGAGGGTCACATTGAATCTGCGGTGCCCGCGGGATTAGCAGCGGAGACAACTACAGTGACAGCGGTAGGAGCGGCCTCAGTCCAGGAGCCACCATGTCTGATGATATCAAGGCCAAGATCCGAAACTACCGCACTGCGCCCTTTGACAGCCGCTTCCCCAATCAGAACCAGACCCGCAACTGCTGGCAGAACTACCTGGACTTTCACCGTTGTGAGAAGGCCATGACTGAGAGAGGCGGTGATGTGTCTGTCTGCCAGTGGTACAAACGTGTCTACAAGTCCCTCTGTCCCTTGTCCTGGGTCAGTAATTGGGATGATCGCAGAGCAGAAGAAACCTTCCCTGGAAAGATCTGAGCGACTTCCTTTTCCTCCCTTCTCCCCGACCCCAATGTCTGGGGCTGGATCCCTTCTTCCCTCAGCGTGGGGGGAATGTGATCTGTGGCTACCCCTGCCCTGAGGGGCCTGAATCATGTTAAAATAAACTGTTGGAATC
->XM_024666474.1 PREDICTED: Selaginella moellendorffii aquaporin NIP1-1-like (LOC112343293), mRNA 
-CCCTGCGCCGCGCGCCTCTATACTCTCCCAAAGTCTCCACAATTTATGGCCGCTTATAAAAGCTTGCACGACTTCTCTGCCTCCTCGCGCACAACCATCTCTCCTCTCCCCAATTCCTCGCCTGATCGAATGTGATCGCTTCTTGGGCTGTGCTGCGACGACCTTCCTGACCCGATCCATGGCAGCAGCGGCGGCAGGGATGAGCGATTTCCAGCTCAACGAGATCCGGGTCACGCCAGCGCCCTCCATCGCTCTCCCCGCGAATGGCCACCAGATTCATCACCAGGCCTCGCCTCCCGCGGCCTCTAGGGGATGCATTCCAGTCGCCATCGTGCCCAAATCCACGCTCTTCCAGAAGATTGGCGCGGAAGTGATCAGCACATTCATCCTCGTCTTCGCGGGATGTGGCGCCGCGATGGTGGACGCCAAGTACAAGGATTCGATCACCCACTTGGGCGTCTCGGCGGCGTTTGGGCTCGTGGTGATGATCATGGTCTACGCCGTCGGCCACATCTCTGGAGCTCACATGAATCCGGCCGTGACTCTGGCGTTTGCGACCGTGCGCCATTTCCCCTGGAAGCAAGTTCCTGCCTACATCGGCGCACAGGTCACTGCCGCGATCACTGCCGCGTTTGCGCTGCGGCTGATCATCAGCCCCGTGGCTAACATCGGTGCCACAATTCCCGCTGGAAGCGATCTCCAGTCCTTCTATCTGGAAGCGATCATCACCTACATTCTCATGTTCGTCGTCTCCGCCGTCGCCACCGACACTCGAGCGATTGGAGAATTGGCAGGCCTCGCAATCGGTGCTACAGTGGGCTTGAATGCCATCTTCGCCGGGCCGATTTCGGGCGCGTCAATGAATCCAGCACGAAGCTTGGGCCCCGCGATCGCCGCGAACAACTACAGTGGATTGTGGGTTTACATTGTCGGCCCGACAGTCGGCGCGCTGGCGGGTGCGTGTTCTTACAACATGATCCGGTTGCCCGTGAAGCCGGACGAGCTCCCCAGGGCCGCTAGCTTCAAGAGATAGAACAAGGCTGTAAAAAGAATAGCAGCTTTTAGGTGACCACCTAAGTGATAACTCAAGTAAAAAAATAACTAGTTAGCCGTGTCTCGGTTA
->FQ756522.1 16S rRNA amplicon fragment from a soil sample (ferralsol, Madagascar) resulting from a 16 days laboratory incubation experiment in the presence of 13C-enriched wheat-straw and a tropical peregrine endogeic earthworm, Pontoscolex corethrurus: Light-DNA fraction (DNA-SIP technique) 
-TAGCCTTGCGGCCGTACTCCCCAGGCGGGGCACTTAATGCGTTAGCTACGGCACGGAACCCGTCGATAAGGCCCCACACCTAGTGCCCAACGTTTACGGCGTGGACTACCAGGGTATCTAATCCTGTTCGCTCCCCACGCTTTCGCTCATCAGCGTCAGTACCGGCCCAGACCACCGCCTTCGCCACCGGTGTTCCTCCTGATATCTGCGCATTTCACCGCTACACCAGGAATTCCGTGGTCCCCTACCGGACTCCAGCCATAGAAGTATCGAGTGGCCGCTCCAGGTTGAGCCTGGAGGTTTCACACCCGACTTTCCAAGCCGCCTACGAGCTCTTTACGCCCAATGAATCCGGACAACGCTC
->XM_047971315.1 Xylaria bambusicola Gar1/Naf1 RNA binding region-domain-containing protein (F5B22DRAFT_384725), mRNA 
-TCTTTTTGCGATACTCGAAGAGACAACTTGACATTGAAATACTACAAAGCTATATATACACCCCATGATCTTCTCAATTGTTCTCACCAGGTTTCTATGGTAGCTGCATCTCGCCCTGTCTACTTACTTAGGTTGGTATTCGGTGAGTTTGCTGTCTGGTATCAGTACCAGATCTACAAGAATCCATCGCCACAAGCAGCCTATCCGTGAAAGCAATAATCCCAGAATCAACACCTACATCACCAACACCGTCATGTCTGACGTCAAAATTCCTGGACTTGGCAACTTGCAACCCGCCGCGGATACAGAGAGTGGCAATGTCCAGCCTACTGCGGTGCCTGCGGTGCCGGCAGACGAAATGGCGGTTGATAATCCACCAAGTCCACCATCACTCACGTCGGGACTCGAAGCCCTCCTTGGTGGCCTAGACCCTCTACCAGAGCCAGTGCCCGCTTCATCAGAACAAAGTAAAGATACCACTGGTGCTCTACCGGAAACAAACAACACAGCTGTATCAGAGACTGAAAATCCAGCGCAAGCCAGCGCCTCCCAAGAAGCTGGTAATGATAACGTGCAAGAAGAGCATCCAGAGTGGGAAGTGGACTCATCTCCCTACGAGTCATCTTCCGACTCTAGCAGCTCGGATGACTCTGATGAGGACTCTGACGATGAGAAAGACTATAAGATTCTTGGGCCCGAGGAGACCGCCCGTATACTCATGGAAATGGATGGTGGGTCTGACGACGAAGGTGATGGCAAGGGAAAAGGTAGCAGTTCTGGTATGGTACGAACCAAAAATGAGCTCCCTGAAGCCATCGTCCCGCGACCCGAAGTTGAGATCAAACCTGAGATGGAGATAGTTGAGCTGGGTTCGATTGAGCATTTCGTTGGCAACACCGCTGTCATCAAAGCAAATACCGACGGAGAGTACCAAGTCCTCGACACAGGATCTGTGCTTTGTCTTGCAGACCGAACCGTGATAGCTGCCGTGGCGGATGTCATCGCGGCGGTGCGGGAGCCTCGGTATACCGCTGGCTTCCAAAACGAAGAAGAGATCAAGTCTTTCGGATTAGAGACTGGAACCAAGATCTTCTACCCACCTGCACTAGCAAGTCTTGGGTTCACAGAGATGCTCAAAGCCAACAAGGGCACAGATGCAAGTAACTGGCACGACGAGGAGGTCGCTGAAGACGAAATCGAATTCTCGGATGATGAGAAGGAGGCAGAGCACAAGCGCCAATTGAAAGCCAAAAAGCGAGGGGCACGTGGTGGTCGAGAGGGTGCGGCGAGTCGAGGAGGACGTAACGATGCTATTCCTGCGGGTGCCTCCATGGCCTCGGCTGAATTGAAGTACGATGATAATGACGATGATGACGGCCCTTACCGACCGCTAGCTCGTCCAGTAGGATTTGGGCAAAACCAAGCCTCCCATGGAAGCAGTGAGCCTCCGAGTGGCTTCTCTGGCCATTCCGGTGGTCATTGGGGAAATCGAGGCGACTTTAGAGGCAGAGGGAGCCGTGGCCGGGGCGGACGTGGCAATCGTGGTGGCAATGTGCGTGGCGGATATTCACTACCACCAAGACCACAAGGTCAAGACGGCCAGGGAGCGCAAAGTTACCACCAACAACAACCACCTGCGCAACAGTACAGTCTACCTCCTATGGTGATGGGTGGTCAACCCTTTACAAGCTTAAGTCCTCCTCAACCCAACGCTCAGCAACCACATGGACCTGCCAACCAGCAGTTTCCCTTCCCCTGGCCACAAAATGCTCAACCAGGCTTTTATCCTCCTCCACCACCTCAATTCACAGGCCAGTCTGGTGCAAATGGGATGTATTTACCGCCCAATTTCTTGACAGCTCTACAAAATCAGATGCAAGCCCAACAAAATCAACAAAACAACCAGTGGCCCGGTCCACATGGCCAACACAACACTAACTCATGGCCTGGACAAGGAGGCCACGGGTAAAAATTTAGCATGTCGTTTGCTTGTGCTGGGGAAATCGGCACGTGGATTATAGGCAATAGGTTGTGGCATGGATCTAACATTTTAGGCGCATATACTCTGGCCAGCTGTGATGGCGAAAGTAAGGACAGGGCTGCCCAGCATGGACCTTGTTCAAAATAACGATGATGACTACCGTACTCTTGGTAGCACGTACGGCTCATTTGCTCGCTAACTGGCTATTGGCCTGAACTGACAGAGAAGAGAACGTCCCTCGGCTGAACTGTCGATCGCGCCTTATCTACATACTTTGTACGTGTGGTTGTGACTAAAAGTCGAGTCGCCCCGTTTCCGTACGATAATATATATTATATGCTCCCTAAAATATGATTATATTTGATGCCACTCTTGTTCTCAGGGAGGCTGACATGCTGTTATTTTGCTGCGTCTTGATGCGACTGGTG
->XM_014964001.1 PREDICTED: Calidris pugnax family with sequence similarity 19 (chemokine (C-C motif)-like), member A2 (FAM19A2), transcript variant X1, mRNA 
-TTTTTTTTTTTTTTTTTCCCCCACTCAAATACTCTGAGACCGTGCACGAGAAACACTTCAAGTGGTCCCTCCCTTCCTACTTCCTTCACCCTTCCTCCAGCGTCTCTTTACCGGATTCCTGGTGTATTCCAAGGGAGAGGCGGGGGGAGAGGCGGCGGAGGGCTGCCTGCCCCAGCCCGGCCCAGCCGAGGGGAGCCGAGCCGAGGCGGGCGCGGTGCCGCTCCATGCCCCCGGGCGCTGGCGGGGCGCGGGCCGTCTGCCGGCGATGCCCGGGCGGTGAGGCTGGAGCTGGAGCCGGAGCTCCCTCCCGACGGGAGGCGGCCGATCCCTAGGTGTTTCCAGGAGGAAGCGGGGCTGCAGGATGAATAAGAGATACTTACAGAAAGCAACAAAAGGAAAACTGCTAATAATAATATTTGTTGTAACTTTGTGGGGGAAATTAGCATCTGGGGCAAATCATCATAAAGCTCACCATGTTAAAACTGGGACCTGTGAAGTGGTGGCACTCCACAGATGTTGCAATAAGAACAAGATAGAAGAAAGATCACAAACAGTGAAGTGCTCCTGTTTCCCTGGGCAGGTGGCGGGTACCACCCGGGCAGCTCCTTCTTGTGTTGATGCTTCAATAGTGGAGCAGAAATGGTGGTGCCACATGCAACCATGTCTTGAAGGAGAGGAATGTAAAGTTCTTCCAGATCGTAAGGGATGGAGCTGTTCCTCTGGGAATAAAGTAAAAACAACGAGGGTAGGTATAATACCAACTTTACATGTTACCAACAGGTAA
->XM_012986102.1 PREDICTED: Erythranthe guttatus probable polyamine oxidase 4 (LOC105961838), mRNA 
-AAAAATCCCGAATTTACCCCTAGCCGAACAGAAAAATATCATGCACAAACAACAAACCGCGTACCCCTACGTCTCCTCTTTAAGTTAATCCGGACAACCAGCCTTTTTTCTTCTGCCTAACAAACAAATTTCTAGAGAGAGAGAGAGAGACAGACGGTGGTAGAGAGAGAGAGAGAGAGAAAGTAGGGGGAGAGCCAATCTATGCAACCGAGGACGAAGAATTCATCGGTTGGTGTAATTGAATCTTCTGGTTGTTGCCGTGAATGCAGCTCCTGCAATTGTTGCTATTATGATTATTATGAGCTTGTTTGACGATAACCTCCGCTGCGCTTCCAGTCTCAGCCGCCTCATTGCCGGACTTTTGCTTTTCCTCCTCTTTCATTCTTCCCAATTGATTTCTAATTTTCCGATTCCTATACACCCGTAATTTTTCGTTTTTTTTTTTTTGAAAAATTGTTGTTGGTAAGATCAGATTTGGTTCTCCATCAATTTTCATTCCCAGTTAGGGTTCTCTGAATTTGTTTGTGAGAGAGAGAGGTAGAGATAGAGAGAGAGATAGGTATTTTCAGTTGTCGATTAATGGAAGTCAAATATGGCGACGATTCGATCTCCGGCGAGTTTTTTGATGGCATTTACGGCTCCCTTGTAGAGAGGCCACACAATGCACTGCCTTCTGTCATCGTCATCGGTGGAGGAATATCAGGGATTGCAGCTGCACGCATGCTGCGTAATGCATCTTTTAAGGTGATCGTGATGGAGTCGCAAGATAGAATTGGTGGGCGCATTCACACCGATTACTCATTTGGTTGCCCAGTTGACATGGGAGCTTCCTGGTTGCATGGTGTCTGCAATGAGAATCCTTTGTCTCACGTGATACGTCGTTTGGGGCTCACGTTGTATCGTACAAGTGGTGATGACTCCATTCTGTATGACCACGACTTGGAAAGTTATGCACTCTTTGACATAAATGGACATCAAGTTCCCAAGAAAATGGTTATTGAAGTTGGAGTTGCATTTCAGAAAATCCTTGACGAGACGGATAAAGTGAGGGATGAACAAACCGACGACATATCTGTGAAGGAAGCAATATCAATCGTGCTGGATAGATATCCAGATTTAAGACAAGAAGGCGTCGCATGTGAAGTGTTGCAGTGGTACATTTGTAGAATGGAGGCTTGGTTTGCTGCTGATGCAGACATGATATCTCTGAAAGCGTGGGACCAGGAGAGAGTTCTTTCTGGTGGTCATGGGCTTATGGTGCAAGGGTACGATCCAGTCATAAAGGCCCTCTCAAGAGATATTGATATTCGCTTAAATCACCGAGTTGTAAAAATTGTGAACGGGTATAAGAAGGTGGTAGTAACACTTGAAGATGGGAGAAACTTCGTTGCAGATGCTGCTATTGTCACAGTGCCATTGGGAATTCTAAAATCCAACTTGATTGAGTTCGAGCCTAAGTTGCCAGAGTGGAAGCAGTCTGCAATATCAGATCTTGGTGTGGGAAATGAGAATAAAATTGCCTTAAAATTTGATAATGTTTTTTGGCCAAATGTGGAATATTTGGGCGTGGTTGCGAAAACGTCTTATTCGTGTGGCTATTTTCTTAATCTCCACAAGGCTACAGGCAATCCCGTCCTTGTCTATATGGCAGCTGGAGCACTTGCGGATGACCTTGAGAAGCTATCAGATGAAGCTGCTGTCGGTTTTGTAATGTCACAGCTTAAGCAAATGTTTCCTGATGCAACTAACCCTGTGCAGTACCTTGTATCACATTGGGGAACAGATCCAAACATTTTGGGATGCTATTCGTACGATGCTGTGGGGAATACAGAGGATATATACGACAGGCTTCGTGCACCAGTGGGGAATCTTTTCTTTGGAGGTGAAGCTGTAAGCGTTGATCATCAAGGATCGGTACACGGCGCGTATTCTGCTGGAATAATGGCTGCTGAAAACTGTCAAATGCATCTTATGCAGAGGCTCGGGGGTCTGGAAAGAGTTTCTGTCGTTGCCTGTCGGGAGGATCTTGTCGAGGCTAACGTTCCTCTTCAGATATCGAGATTATAAGTTATTTGTAATGCCAAGGAAATAAAGATAGTGCAACTTGGTTTTAGGACCGGCAAATGTGTGAACAAAGTTTTCCTTTTTTTTTTTTTTTTTGCCTTTTCTTCAAGCAGTGTGGAAACTACATTGTTCCTTTTAACTTTTGTTAGAAGTGATGCTTTGGTAGTTGATGAGTGGTAGCGCCTTTTTAAGAACTCAATTACTACAAGCAGAACAATGTTATTGGTACTTTGTTTTCAGACCA
->XM_030648245.1 PREDICTED: Cannabis sativa haloacid dehalogenase-like hydrolase domain-containing protein 3 (LOC115719273), mRNA 
-GCATGAAAAAGGGGTTAAAAAAAAGAATCAAAAGGGTACGTTAGAGCGGTTTTAGGCCATAGTTTTTCTCCGCCTTTGTTTTGGTGTTCTTTAAAGACTTAGGTTCAGCTGCCCTCTACAATCTACATCTACTTCCTTCCTCCGAAGCCAAACTCGGTTAATGTGGGGAATAACACCATTGCTCTTACCCATATACCAAAGCTATTCAACCACCACACACACACACAAAGAGAGATATCATTGGAGCTGTTGAAGGAGGTTGTTAGAATTAAAGTGTGTCACTTTATGATTTGACCATTTCTTCATAACAAGAGTTAGATAGTCTCATCAATTATCATACTTATAGAAAACTTATTACAGTAATTCTATAATGTCAATTTTGTCAAAATTACGATGTATTACGGTGGATGTAACTGGTACATTGATGGCTTACAAGGGAGAGTTAGGAGACTACTATTGCATGGCAGCCAAATCTGTTGGTCTGCCTTGCCCTGACTATAAACGGGTACATGAGGGCTTCAAACATGCATATAAAGACATGGCTCAAAAGTATCCATGTTTTGGATATGCTGCCAAAATGCCCAACATTGTGTGGTGGAAAACTTGTGTAAGAGACTCATTTATCAGGGCCGGTTATGACTACGATGAAGAGACATTTGAAAAGGTGTTTAGACGCATATATGCTTCATTTGGTTCTTCCGCCCCTTACACCATCTTTCCAGACTCCCAACCATTTTTAAGATGGGTCCGTGAGCAGGGTCTTCAGGTTGGCATTATTAGCAATGCAGAATACCGGTATAAAGAAGTGATTCTTCCAGCATTGGGCCTGAACGAGGGATCTGACTGGGACTTTGGTGTATTTTCTGGTCTCGAAGGCGTTGAGAAACCGGATCCAAGGATTTACGAAATTGCCCTTGAGAGGGCTGGAAATCTTCCTCCAGAACAAGTACTGCATATCGGTGACAGTATGCGGAAAGATTATGTGCCAGCAAAGAGTGTAGGAATGCATGCATTATTGTTGGATCGATTTAAGACAACTGATGCCGAAGAATGGAGGAAATCTGGCGCAATTGTGCTCCCTGATTTGATGGGAGCAAAAGAATGGCTTCTTTCAGACAAGTCATGAAGAAGAAGCATGATTGGATTTTTCTCTCCCCCTTGAAAGGAAAGATTGGTTAGTGGCTAGCAGAGATTGTTTTCTCACAAAGTGAGGCTTCACTCTAATCTATATGTACACAAGTTAGAAAAGTTTGATGAATGAGAAAATGAAACCTGCTAGATTATGAAAATGACTCTAATAATTAAATAGAAATAAAATACAGGATAGGGGAAGAGTTGCACCATTTGCGTTTTTATTTTATTGAGTAATTTTTAAATATAAATATAGTTGAACAATGATGGGTCAAATTATAAACAAAAGTGTGAAGCAGACACTTTTATTAA
->XM_012066938.1 PREDICTED: Cercocebus atys POU class 3 homeobox 2 (POU3F2), mRNA 
-GGGGGGAGCGCCGAGCTAGTCAGAGAGTGAGCGAGAGCGAGAAGGAGGGAGAGGAGGAGAAAGAGAGCGAGGGCGGGCAGGCGGGAGGCGGCGGCGGCGGCAGCAGCAGCAGTAATAGCAGGAGCAGCAACAGAAGGCGTCGGAGCGGGCGTCGGAGCTGCCCGCTGTGGGAGAGAGAGGAGAAAGAGCTAGCGAGGAGAGGGAGCCCGAGGCGAAAAAGTAACTGTCAAATGCGCGGCTCCTTTAACCGGAGCGCTCAGTCCGGCTCCGAGAGTCATGGCGACCGCAGCGTCTAACCACTACAGCCTGCTCACCTCCAGCGCCTCCATCGTGCACGCCGAGCCGCCCGGCGGCATGCAGCAGGGCGCGGGGGGCTACCGCGAAGCGCAGAGCCTGGTGCAGGGCGACTACGGCGCGCTGCAGAGCAACGGACACCCGCTCAGCCACGCTCACCAGTGGATCACCGCGCTGTCCCACGGCGGCGGCGGCGGGGGCGGCGGCGGCGGCGGGGGGGGCGGGGGCGGCGGCGGGGGCGGTGGCGACGGCTCCCCGTGGTCCACCAGCCCCCTGGGCCAGCCGGACATCAAGCCCTCGGTGGTGGTGCAGCAGGGCGGCCGCGGCGACGAGCTGCACGGGCCAGGCGCCCTGCAGCAGCAGCACCAGCAGCAGCAACAGCAACAGCAGCAGCAACAGCAGCAACAGCAGCAGCAGCAGCAGCAACAGCGGCCGCCGCATCTGGTGCACCACGCCGCTAACCACCACCCGGGGCCCGGGGCATGGCGGAGCGCGGCGGCTACAGCGCACCTCCCACCCTCCATGGGAGCGTCCAACGGCGGCTTGCTCTACTCGCAGCCCAGCTTCACGGTGAACGGCATGCTGGGTGCCGGCGGGCAGCCGGCTGGGCTGCACCACCACGGCCTGCGGGACGCGCACGATGAGCCACACCATGCCGACCACCACCCCCACCCGCACTCGCACCCGCACCAGCAGCCGCCGCCCCCGCCGCCCCCGCAGGGTCCGCCTGGCCACCCAGGCGCGCACCACGACCCGCACTCGGACGAGGACACGCCGACCTCGGACGACCTGGAGCAGTTCGCCAAGCAGTTCAAGCAGCGGCGGATCAAACTGGGATTTACCCAAGCGGACGTGGGGCTGGCTCTGGGCACTCTGTATGGCAACGTGTTCTCGCAGACCACCATCTGTAGGTTTGAGGCCCTGCAGCTGAGCTTCAAGAATATGTGCAAGCTGAAGCCTTTGTTGAACAAGTGGTTGGAGGAGGCGGACTCGTCCTCGGGCAGCCCCACGAGCATAGACAAGATCGCAGCGCAAGGGCGCAAGCGGAAAAAGCGGACCTCCATCGAGGTGAGCGTCAAGGGGGCTCTGGAGAGCCATTTCCTCAAATGCCCCAAGCCCTCGGCCCAGGAGATCACCTCCCTCGCGGACAGCTTACAGCTGGAGAAGGAGGTGGTGAGAGTTTGGTTTTGTAACAGGAGACAGAAAGAGAAAAGGATGACCCCTCCCGGAGGGACTCTGCCGGGCGCCGAGGATGTGTACGGGGGGAGTAGGGACACGCCACCACACCACGGGGTGCAGACGCCCGTCCAGTGAACTCGAGCGGGGGGAGGGGCAGAGCGCGGGGCTCCCCCTCCCCTTCGGTCCTTGGCCCTTTCCCGGCCCTCTTGTTCCCTCTCTAACTTCTGATTGTTCTTTTATTTTTAATTATTATTTCCCCGTCCCTTAAAAAGAAAAAAAAAATAAGGAAAAAGGAAAGCAACTAAGACACTGGACTATCCTTTAAAGGTAGCAGGTGTAATGATGTGTTTTGACCTTTGCAGACGAGTAACCAGGCAATGGAGTGGAGTGTCTCCTGGAGAGAGTGAGGAGAGTGTGTGATAGATAGAAAGAGAGAGAGAGATAGAGAGATGGCAAGCACTGAGATAAATACCTGGCAAAACTAAATAAATTACCAAAAAGGAAAAAAATATCCACCAAACCATGATAAACACAAGACGCAGCTTCCTGATGCTTGGAGTTGGCACATGCTGCTGTGTTTATTTGATGTGGATTCCCATCAGGAAAGAGGAAAAAATACACACGTTCTTTGATATAGGCAAAATTTAACCACATAAATTTGCACTGCAAGAAAATTGAAGTTTACATGAACAAATTCATGAACATATTTTCTCTTTCTCCCCACCGTTAATTTGGGAATTGCCGTTTTGGGGGATTTTGTTTTGCTTTGCTTTATTCATCGGAGAGAGTTGAAGCCAGCTCTTGGCCTCTCTCCATTTCTAATGTTCTTGTGTTGCCCCTTATTCGTACTGTTTGTGAACTTTGGTTACCTTCAGATTCCCCTTACAAGGGTGTAACATCTATTTGTTCCTCTTACCAAAGCAAAACGATTGGCTTCATACAAAATAGACAATTCTCTGCTTTCAGGAAATGTGCGTGGTCTACCCGCTTTATCCAAGGCAAGAATCCAGTTTGCAATATAAAAATAAGCATTGGTTGTTGTTACGAGCCACAAAGTAAACTTCATTTTCAGGCAGTGTTTCTGGGGGAGGTTATGGAGGGAAGAAAAAGAAAAATCGATAGTGAGTGACTGATTGCTTCATTTTATCAGGCGGGCCCATTGTGAAAGAGCTCAGAGGAAATGTGGAGGTTAAATATATTTCCAGAGTTGTCCAGCAGAAAGAAAGTGGCACTTTGAAGAGAACTAGGGAAGTATATATCTTCAGATATCCCTATATAGTTCTCTACCTTCAGTTTTAGTAACAATTATGAAGAATTCTTTATGCTGACAGCAGCAGTTAAACTTTGTTTCTCTAATAAGCTTTTTTTTTTTTTAACATAAAAAAGGACCCACGAACTTAATAGTGTATGCATAAGGCTGTGTTTTTTAGCACATAAATACCCACAGCATACACAGACGATCTCCACGCAGTAGACAGGTTTTGTCTTCACTAGCTCATTTGTTTATCAAGTCATATTTAGGGTCCCACGCCCTCTTTTCCTGTAATTTATTGCAGAATATACCACTTTGACTTGGACAGCTTTCTCCCCCCTCTTTCACTAAGGAAGGCAAATGAAGGGGGAAAAAAATGCCATTTTCAATCCTTCCTTTCTCCCCTTTGTTAATAGTTTTAAGTGCATTTTTGACCTTATCTTGATGGAAAACGGTTAACTCCAAACACAAAAGACTCTACTGGAAAGTGTAGGTGAAAAAACTTGTAACTGTATTGAAAATAAATACCATTAAACTGTGATCAGTTAAAATTTAAAAGAAAAATCAGCACAAAAGGGCGCTAAAAGGGAAAACACTTTTTATTAATCTTAAAAGTTTGGGGTTTTTTTTTCCAGTTAGGTATTAGATAAATTTTTATTTTAAAAAATGAAAGTCTCACTACCATAAAATTATGGTTCAGCATCAGATTAGCATTGCACTCATTAGTCTTTAAGGTTTTAGGAAATATGCTTTATATTGTCTTTTCAAACACCTGTGATTGTTTCATTTTCAATGTTTTTGCAAGATAAATGGTGACTTATAATGGGCATATTTATTTGCCTGTATTTCATTTCCCCCAATGAATGTCACAAGGAGATGGGCACGGAGCTGCTTCGGGTACATCACGCTGCTCGTTCCTGAGGTATGGGGACTGGCCTTTAGTGAAGCTATCCAGAGCAGGGCAAATAGCCACTGGTGAAGGGAGGAAATGAATTTTCAGATACTTATTACCAAGTAGGTAAGGTCAGAAGCTGGAGTTCAGAGGATGTATCTACAGCTTCTCTGACTCTTATAGGTTTACTAAGATGAAAGTTACCACTGAACCTTACCACTATGTATATATGTTTAATATCTGTCTTTTGAAATGCAGAAATAGTTTAAATGTTTCTTTGTCTATTTTTCTTTTTTTTAATGCTACCCAGGGAAATATTTTCATATCATTTTTAAGTGGCCTGCCTCAATGTATATTTATTTCTTTTGAAGCAAAAAGGTTCTGGAAACTGTTTTTCTGTAGCTTTAAATGAATAGGTGAGCAAAATCTATATGGGATGTAATTTTTTTGTTCAGTCTCTTAAAAAATACTTTGTTTTTGGTACATTTGGTTGTGCTTGTGGGGAAAATAAAAACGCAGAGATCCTTATATATTTATGTTAAAGTAATATTTTATTATCTACATAAAACAGAAATGCACAATACCTTCATAGTTTGTTCTAATTATTGAAATATCTTTATTTTATTTTTAAAGATAGTGCCATCAAGTTTTAAGGGGGGAAAACCCTAGACCTTAAATTGACTGAGTTGAGTTGTGTGTAAAACACTTCCCTTCCTTTATACTTCATAAAGTTTTGGAATAAATTTTATGCATATACCGCCAGATTTCATGTTCATAACTTTCAGAGGCTTTTTTTTTTTAAATGGAGACTACTGGTCTAATTCACTTTTCTTTGCAAAAACTATTAGTCCCAAATCTTTCAGCCACTATGCCTGTAGCATTAAATAGAAATGGTCATTGGGTTTGAGCTTCAATTTGTTGAGATGTTTGTCCCCTTTAAATATGTGCAGATATGCCTGCATCTTCTTTCCAGGTTAACTGTACTTTATTCAATTGTGCAGTTTTGGAGAACATCAGTGGAACTAGGTGGACTTTAATCTCTACCCACAGGTCCTCATATAATTTGGGATCTACAGAAAGGCAGGATTTAGGAGATTATTATTTTTAATAATTTACAAGTATCTCTTAACAAAGAATAACCCTGATAGTATGCTATTGTATGTTTACTAAATAATTAGAAGTAGATCCTATACATTATTCCTGTTTGGTTTGCATAAAAAGATGAATTTTACAATGGTTT
->XM_053552187.1 PREDICTED: Mercenaria mercenaria high affinity cGMP-specific 3',5'-cyclic phosphodiesterase 9A-like (LOC123560979), transcript variant X1, mRNA 
-GACAGAACGCCAGAAGAGTGTTTCCTAATGCGCATGCGTGTGGTTGCGTGAGAAACGTATGTGTTGTGGAAACGCCACTTTCTCTTAGATTCGCCAGCGCGCTTTAAAGTGGACGACATTAACTTGTGATTTTTTGTGTGTCTGAGATTGACAGTGTTTGGGTTTCAGCTAAGTGCGTCTACATTTATATGAATCCAAACAGATATCAGACATTTTATCGATCAAGCTTTTGTAGCCATCGCTGTTGTCTGACTATTTATATCTTCTCGAGCGCTGATAAAACTGAGGATGCAAAAGTTTTGTTTGCTTATTAATATATCGTAATTTCATTCAGTCATTGTACAATGTGGACTTCATAGTGCTTTCTTTGGAGTGGTTAGACGAGAACTAAGATGGGAAACGCTTCGTCAATAGATTCGTCTGTGGTCGTTTATCTAGAAGTTAGTGGAAAACAAGAAAAGATTGTATTCAGCAAACACTGTAGTTCCAGGGATATACATGACCTCGTGGCACAAGCAGCCGGATGTAGCAAGTATTGTATATTGACCCTTAAAGATCCAAATGGTGCCCATATTTCCATGTCTCCCACGATGCCAAGCAACACGCCCAGTGCGCCTTACAAGGTTCAAGTATCACAACCTACGTCAAATCAAGGCGATAGTGAGGTGCTTACACAACTTATGACGCATGTGGCAGATCAGTTCAACAAAGCTTTCAAAGTGGAGGAAATGAGATCGGAAATTTCAACCAGACTTACAGCACTGGAAAGGAAACTGGAAATGGAGGGACTGAAAGCTGTTGAAATTGAAAAGTGCAAAAAGGACATTTCGGAAATCAAGGATCAGATCTGGACAGCACAAAAGAAGTTTGTGGACTTCAACAGAATGAGACCCTTATTGTACGGTAGTAACACTCACGATCATTTTTATAGTTCGCTGAGTGATGAACGGAAGATCTGCCTTAAAAGGGATATTCCCTCATATCCGAAGTATACTTTGTCTCAGGAAACGATAGATTACTTAAAGCAGCCAACATTTGATATTTGGCATTGGGAACCAAATGAGATGTTGAGTCTACTAGAACATATGTACCACGAGCTTGGCCTTGTGAAGGAATTCAGTATCAATCCGATTACACTGAAAAGATGGCTGCTATGTGTCCAAGAAAATTACCGGAACAATCCGTTTCATAACTTCCGTCATTGCTTCTGTGTCACACAAATGATGTATGGGATGATTCATTTATGCAAACTCTGGGATTACATGACGAGGGAGGAAATCGGGATACTCCTGACAGCAAGCGTTTGTCATGATTTAGACCATCCTGGATACAATAATACCTACCAGATAAACGCACGGACGGAGCTTGCTATTCGGTATAATGACATATCACCCCTAGAAAATCACCACTGTGCTGTGTCTTTTCAAATTCTGTGTAATCCGGAGACAAACATTTTTGCTAACTTAGACAAGGACGGCTTCAAACGTGTGCGAGCAGGTATAACACAACTTATATTAGCAACAGATATGGCAAGACATAGTGAAATCATAGAGTCGTTCAAATCTAAACTGGAAGGCAAATTTGACTTCAAGAGCAAAGAACAGCTAGACACTTTGAAGATGGTTTTAATCAAATGTTGTGATATATCAAATGAGGTCCGTCCTATGGAAGTTTCTGAGCCTTGGGTAGACTGCCTGTTAGAGGAATACTTTAATCAGTCTGATCGTGAAAAAATGGAAGGATTACCAGTGGCGCCTTTTATGGACAGAGATAAAGTAACTAAACCAACAGCACAGATAGGTTTCATCAAATTTGTTCTCATACCAATGTTTGAAACAGTCTCAAAGCTGTTTCCGCAGATAGATGAGACAATGGTACAGCCATTAAGATTAGCACGTGATAGATATGAAGGAATGAAGGAGCAGACAACTCCTCCTAATCCAAAATCTCAAAAAGATCAGGCTGCGAAGAAAGACGGAGAGTGATGCCGTGTTGTATATATATACTGGCACCTGTTGCTAAGTTAACATATCATCTCTGTGTTAAAATGTTACGAAGACCTGTAAAATAGACTCTAGTAGAATAATATCTTAACATTGTGGAAAACTATGTTTGTAGGATTTGAAAGCTTTGATAACATTATAACGGTTGCATATATTCAGGTCAAGTTTACAGGCAACAACAAAAATGTTGGGCCTTTCTCATGAAAAAAAATCTGGTGAAAAAGAAAATACTGGGTGAGTTTTGAAAAAAAAAGACTTACTCTTAAAGTGATATTGTTTTACATAAACAAACATCGAATTAAGGGTAACTTATCGTGTTGATGTATTTAATTCCTGTACATGTATGTGATTACATTGTTCAGTGTCTTGGTAAGGACTTTTAATGTTCAAATTTAAACAGCAAATTGCGTTATGTAGCAATGAGCTTGAAAGTATTTGTTCATACAGTTCAGACAGATACGGAGCTAGTGCTTGGTGACAATAGCTTTAATATAATGTTATTATTTGTGCATACAGTTTAGATAGACAAGGTGGCAATAGTTTGAACAGCATGTATGTACAGTTATAACTCGCTGTCTCGAATTCCAAGGGATCGAGCGTTTTAGCTCGAGATAACCGAAATACGACTTAAAATGATATTTTATACACGCGTTTTACCTCGAGATAACCGAAATACGATTTAAAAGGATATTTGATACACGCGTTTTACCTCGAGATAACCGAAATACAACTTAAAATGATATTTGAAACATGCGTTTTACCTCGAGATAACAGAAATACGACTTAAAATGATATTTTGTACACGCGTTTTACCTCGAGATAACCGGAATACGACTTAAAATGATATTTTGTACACGCGTTTTACCTCGAGATAACCGAAATACGACTCAAAATGATATTTTGCACACGCGTTTTACCTCGAGATAACCGGGATACGACTCAAAATGATATTTTGTACACGCGTTTTACCTCGAGATAACCGAAATACGACTCAAAATGATATTTTATACGGTGACAATAGGTTAAATGTTGTGGACCCGTAATGACATTCGGCAATTTCCGTACGATTACGAAACTTGTATGCTAGTTCGGCACCTTACGGCTGTAACATCAAATTGCTTTTTTCATAATCAAATCCTTGAGACGTCTGGTGGTGGTTGATTTTTAGCAGATTTACTTTCTGTTTTCTTGCAACTATTATGCACCTCAACAGCTAAAATAAAACGGAGAATACCTGAATTTACATTTTCTGTATTACAAATATCATGTCACCTGTACACAAACTAATTTTATACAACAAAAACAGGAAACAAAGAACATTTTTATGCAAATCATTTTCATTACATTTACTTATAAATATCTCACTTATTAGTAATATACTTTTGATCTATTTCTGACACTCTATTTTGTAACAAAACAAATATCCAACTATTAAAATACTTGTATAGGAAACGAACATAAACGTGCTTCGAATCTAAGATGAATTCTACGTGACCTCACATGAATCCAGAATTAACCCGCTTGAATTCAGTGATGTAACCATAGGCTTGAAAACCTTATCATCAATAGATCTTGTATAATCTAGCCGGTCAATGTGAATGGAGACAGGTTAAATTAGACTGCTTGATCATTGATAGTTCATCCGCAATATTCATGAATGGAACTATTTGGTGTAGCGCACGAACATCTTTTTGATGTGATTAGGAATGAAATAAAGATCCTGTGATTGTCAGAAATACACTTATAACTTTGATAGCGGGTAAACCCGCCCCACCCCACAAAAAACGGAGAAAGTCGAAAGTGCTTACGGAAAATACGTAAACGAACTGAAAATGCGATTGTCGTTACGGGTCCACGAAAAAGTAAGAACAGAATCGCTTGCAGCAATGAGTGCAGCAAACGCAACACACGCGGATTACATAAGAATGGACACTGTAGTAAAATTGCAACAGAAGTTTATGTATTTGTATTTACAGTATACAAGGTTCTTAGAGTTTGTTATTGCGTTTGAGTATAATGTAAGTTTTATATCTGCAGTTTAGAAAAAATGAAGTTTTACATTAGAAATCAAGGAAATGTTGTAGATCTATACTAGAAAATATTCACTGAGTATAGCGATAAGCATTTTACTAACATTTGCCTATAAATCGTTTGGTTATACCAAACTTCTCAATGAAACAATACATTACAGTTTCTTCAATCTCTCTCTTTAGTTATTATACAATATGTATTAATAGCGGAAACGTGATATTTTTATATTATTTTTTTTTTACATTTGAGACGCTTTTTAAAAAAAAAATATGTCACAGAGATAATGGTATACGAGCTTTTCTGTTCAAAAAAGCATGTGTTGCAATTACAAAAATTGTGTCACTGTTCACTATACATATTTAATTTCATTAAGGTGTCGGCTATATCAAAAATATTTTTACAGCGTAGGGAGTTCTTAAAATGTTTTATGTGACATTTTTACGAACACACATTATTGATCAATAGCGAGATTTATTTCAAGATTTCATAATAAAAAAACATAATGATAATAAAAAAATATATTTGGGGAAATGTTTTATGATAAATGGCACTGTATATGTTGAACTTACTTGTGTAACAGTTGTTTGATCTGTCGGTTATTTGTTCTGAAATATTGTCTTGCGTCGAAATGTGAATAAACAACGGTTTCTTCATA
->XM_050728021.1 PREDICTED: Bombus affinis sodium-dependent transporter bedraggled (LOC126919204), transcript variant X1, mRNA 
-TTTTATTGTTTAATAAATAATTGATTAAATAACAAAAATTTACAAGAAGAAGTGAAATCGTTTATCAACGTTTGCAATGTTATATCTTTTGAGAACAGCTATACTGAAAATACTAAGATCTTAATTTTGTGATCCTTTGTGAAAATTTACATAAAATTTACAAGATATGAAAAATATTCAATATTTTACTTTACAAGACTTCAATCATAATTATTTTTAAACTTGATTTATTAAATTATATGTATTTAGTATTTAGTAAATAAAAAAATAGAAAAACAACAAATATGATAAAAAAAACGTTACGTGCTAAATCTTAAAATCATGTAGCTGTTTTTATGAATATGTAGTTGGCCTTCAAACATTGATAGCTATTACACGTTGTTTGTATGTAATAGAGGATATCATTAGTGTACTAGCTTAACCATATTTATAAGAAAAATGAAACTACTCTTACACAAACGACAAAACGAGTAGATCATTTGTCATCATTTTGTCAGTTTATTTATTTTTTATTATTAACTATTGATTGTACACTTTATTATTGATATTTTATCGAGGAGAATCAAATAAATATTGTACAACAAGTATTACAGGCTATATAGATGTATCTATATATAAAAGCAAGTATCACACAAACACACACATAGAAGAACATATTAATTATATGTTTCATGTAAAATAAAATTTCTTCATAGAAAAATAATATTGTGCAAGTACGTGAATAAGGAAAATGAATTAGATTATTTGGCTATAGTATTGTTTTTAGGATATTGATTAGTTTGAAACTCTATAAAAGCATTCTGAAGTTGTTGTCCTGGTTCATGATTCACGAATGAGTTATATAGAGCCGTAGCCAGCTGAGAAGGTCCGGTTACTGGTTACCTGTTACCTGGACAAGTGTGCTGGCAACGGGCTTGTCCTAAAGTATCGACCGTGACAGTCGTTCCAGTCGATTCCAGTCACAGCTTTTAGATCGATAGTTTTCCGACAATATCGATCGATAGCTTCCTTTTGACTTTTCCAATCATGCATCCATTATTAAAATATATAGAAGTGTAAAAATTGTTAAAAACGTTAAAAAGTACAAAAATTGTTACAATTTATTCTTTCTGTTACTAGTATTTCTCTACGAGTTTTGTAAAGGGACATTCGTCGTTCGGAAGAGTAATATTGCAGAAATGTTTCTGTGTTCTTCCCTTCCCGAGTACTAAAGGACATGAATCAATTAATGAATGAATCATATTTTTTACCAACTCTGATATGATGTACGTAATCAAATTTTTAATTTATATCGGTTATCAATTCTTACTTACTTCTTCACCTACTAGGTAATATCAGATAATAATTTGAACTATTATCAGTTGACAATAGATGCTAATGGATGATAATTGATACGACAATCGAATCGTTTTAGATGAAATGTTACTAAATAATAATAAAACTTAATGAATTTGTGTCAATAATACTTTTGATTGATATTGTATGCGTATTTTGGTAGGTATGAGGAATGATTCATATGTTTATTTCTCCATTTTTATCACAATCACGTTAGTATTGTGGTAGTAGGATTAGTTTATAAATAATCGGAGTTCGCAAATTGTCTTTAGCATTACATCGTTAATGATTCCTAATAATATAACACCGTGGTTGAAGCTGCAACTTATTTTCCTTAACGACCCGGCATTCATACGTGTTTCTTTATACCGTAAGGTTAAACATCCATTTCAATCAGTTATTGTTTTAAATCATGTCAGCTATATGGATATTTCATAACGTTGTTCAATATTTCCAAAATAGTGAGTCTGTCGTAGCATGTTCTACGGTTTACACAAAGAACTAAAGAAAGTAATTTGTGTGATAAATTTCTACGTGAAAGAGCGGTTTTAGAATCAGTTTTCACCGCATCGAGATAAGATGACGATATATATGTACTTAGTTTCCAAGTGAAGCGAACGTAGGAGAGGTTTAGACATTTCAAACGAAAAAGTATCGGTCTACTTTGTTCAAGGGATTAAGTTAGCCTGATCGTAGAAATTTAAACATTTAAAACAATGCATAGGATTGTTACCCTACTACAGATAAACGTTCATTTTCTCGTTGCAGTAGTTAACCATTACAGAATGACTTCGAGCGAAGATGGTGATTTGATCGATCTTGGAAACGATAGTTGTGTACCACGAGTATCGATTCAAGAATCATCGCCTGACGAGCAAGAACATCTTCTCGATGTGTGCCTACCGAAGTTAGAACAAGCATTGTCATTAACCAGGAAGCAAGAACAAGTACAATGCATAAATGACAACGGTGATGTATTAGTCACGTTAGGTCACGATCAAGTGGTACCGATTCGTAAAAGAATCGATGTCGTTTCATCCGATACGATAAAAAGGGTTCGTGACATTACCAGGAACTTAGAACCAGTTATAAGAAAGACTTGTTCCGACATTAATGAGGAGCATCAAGACACGGTTGATTATGGAAGTTCATCGGATAACAAAGACGGACATTATTCTAGTGAAAAGCTCGAAGACGATACGTTCGAGGCACAGGAGATCAATGATGCTTTCAATTTTCTCACAGAACACGATGACAACGATGATCCAGCCGAAGCGAAATGTAACCGTTATGACCAAGTTATAAATTCACATGGACTGATCCTATTAACCTCTCGTACCATAAAAAACGAAGATTTATTGAATTACCATGGTAAAAGTGCTTCACAAGCGCTAAACTGCTGGAAAGCAGACACAGATTTAAATGATTCAGGTTTTGAATTATGTTCGGGCAACCCGTCTGAAAGTATTTCGAGGAAACCTAGATCTGATCCTGTTGATTATGAACTTGGAGCGAGTAGCATTAATGTGGTTGAAAATCATTCCGAAGAACAAACGTTTGTACGAACAGCTAAAAGAAGATCATTTCAGCATATACATCGTAAATCTTGGACGGAAGGAACTACACTCAAAAATGCAACACAGGATACATTCTCTCGGTTCGATAGGTCAACTAGTTTAAGAGGATATAATTACGCGTCATCAACTTCCAATGGCATTCATCGGCAATCCAGTTTTATTTCGAGTTGTTCAACGGAGGAAGGATTGGAAACGAATGGAGAGGATCAAGAGGACGGATGTTCAGAATGTTCGGAAGTAGATTGGTCGTGGTTAGAGGAAGTAGAATGTCCGCGGGCTACGGAGTCGTTAGCACCCGGTGTGGTTGACGCGGTTCAGGAGAACCCCGAAGGAGGGAATGTATCCCCCACCAGTGAAAACGCAAGACGCAGGCGCGGTCGCGAGCATCGTGCTACCGAGGCGGGCTGCAGTGCCGCGATGTCTGTCTCCGGGACAGTAAAGTCCCTAGTGGTCGGTGGTTCGCGATGGTTAACTTCCGATCCGCCGTCCGACTGTAACGGCAATAATCAAGATGAAAATATACGTTGCAACGCGAGCAACGAAACCATCGATCGCGAAACACGTGACAATCCTACGCTTGTCAATTCTTGGGTACGGGCTTCGATGAGACGTTTGCGTCACCTGAGATTACCGGAAGAAACTGAACGACAACGAAACATTGATTTGAATAGTTGCCACGGAACTGTCGTATCCGCGCCAAATTCTTTGCCAGATATCGCTTTAATCGCTCCAGAGATATTAGCTGCCCAAACAAACGGTACTTCCGGCACCCTCCTTAGGCCATCCAGCGCTCCTGTAAGAAACTCGAATAATTCAAATGTAGTGCCATCGCGGAGAGGCGGAAGACAATTTAGAGCAAGTCGATCGCAAAGAACGCGAAGTCGCGACATTACTTCCAGGCAAAGCAGCGTTTTATCGTCGACTACGGGCAGTGATACAACTGCTTCAGGAATCACGACATGCTCCAGCTCTTTTGGCGGTGTTTCTACGAGTCCACCTTCTAGCACGGCGACAAGTCCGCAACGCATCGCTTCCAGACGAATATGTGACAGACAGAGAGACGTTGATAGAGATGAGGATAGAGGAGAGGATGAGGATGAGGATGCTAATCCATTGGGAAAATGGCCACATGCTCTTAGTCCAGCCTTGGCGTGTCTTAGTTGCACCCTTGGTCTTTTTAATATAAGTAGATTTTCTATTCTTAGTGTACAATTCGGAGCAAATTTCATTGTACAGTTCCTGATTTTATCTTTGGTATTGGGTATTCCACTTTTGACGTTGCACGTGTGTCTCGGTCAAAGATTGGCGGCTGGATCCGTGGATATGTGGAAGATTTCACCCCTCTTTCAGGGCGTTGGTATAGCTCTCCTAATTGCACAAGCATTCATCGGTATCTACAGTATCGTTGGTGTATCCTGGATGTTCGTCTACTTTAGAGATTCGTTTATAACGAAGCAGGATAAGTACCGATGGGCAGAACCGTTTTCCTTGTACAGAGAAGATAAACCTACACAGAATAATAGTAATTTGCATAAATTATATGAGACAGTACCAGATTATTTTAGCGGAGTTGTCTTGCAAAGAAATCATTTAAATGAATCAGATCCCGGTATCGTAACGTTAAAGTTTCAAGTGGCTTTCAATTTAGCTGTTGTATGGATGATCGTGTTCGTATCATTAAGCAAAGGTTTGAGATCTTATGGCAAAGTAGTATATGTTTTTACGTTGGTGCCTGTATTTGGTACACTAGTTCTTTGTACGAAATTACTTGGCCTCACGCCACCAGGCTCTGTACATCAACTTTTTCCTGCCACTGTGTGGACTGAGTTTTTCATTAATGGCAAATCGTGGGTAGCAGCATCCATCGAGGTTTTCCTCACTTGGGGATTACTTGGTGCAGCTGCTATGCAGATAGCTGCTCATAATAAGCACAAACATCTATTACAACGAGACACGAGTCTAGTAATCGTGTTAACCCTCGCAGTTCTACTTCTCGCAGCTTTTCTGGCAAATACTTGCGTGCAAGTTTTGCGACATCATGGATATATTTACATACCTAGCTCATTTGAAAGAATATCATCGTATATGTTTATGCGACCTGTGAACCAGCCGGCACCACCGGGATATAGCAGTACACCAGAAAGATTTATGGCACATGCGTCGTTTATTGTTGGAGAACGTGTAACTCGACCCGGTGCAGACTTTAGTGTTGAATCTGGTTATCAAGCCTTGAGATTTTCGACTGAATTGGTTCCTGCAACGTTAGCGTTACTAGGCACTGAACAAGTGTCACCATTCTGGGCAGTTCTTTTCTATTTTATTCTTATCCTATTTGGAATAGCTCAACAGCTAGCAATATGGCATTGTGTAATAACTGGTATTATGGCAATTAATGCAAAAATGATGAAGTTATGGGAAACTACTATTACATTCTTCAGTTGTGCTTGTGCTTATATACTAGGCTTACCCATGGCTACCGAGTTGGGCATACACGTCGTATATTATCTAGACTACACAATTGGTGGTACGTGGTGGATAATGATCTTATACTTGGTGCAAGTTGGTGCTGTATTCGCAGTGCGCGGACGTCCACATAGTGGTGAAGCGGTAGTAGCCGAATTGTTTCCTCCAACTGGTCGATGTCTCAGACACTGGGCTGGTCCTCTTCTTTCATTCACGTGGAACGTTATACTGCCTGTTATTCTTATGGTACTTAGCATTACGGTATTTAAAAATGCTGGATTTCGAGAACTTTATTCTTACCGACGTACCGCTAGAGAGTACTGGACAGTTTGGGCAAAACAACTCGGAGCTACGATTCAATTAGTACCAATATTGACGATACCGGCAGTGGCGATTATACAAACATGTCGATACTTGAACAACGGTCCACCCGATATTTTTGATAACAATCAAGTGGAAGTTAATATAAATCACTGCGAACAATGTAATGGTAGAATTCAATTATTGTATCGACCATCTTTGGAGCCTGATGACCCACGAGATGCACAAACACATACTGGAAACGATATGAGTACCAGCATTCACGGCAATGGTATCGTACATACAACGACAGAAGTACCATTTGAAGATCCACCACCAAAATATACACCTCCTCCGAGTTACACTACAGCAACGGGAGCGAGAATAGCAAAGATGTTGCGGCAAAGTTTTCGAAGAAGTGTTCGTCGAATAGCGAATGTGCTCGGTGAGAGCAGTACTCCGAGACAGAGACCGGCGCTACAACCTCCACCTCCTGATTACGCCACTGTACTTGTAGAAATGAATCAAAGTAGGCAAACCCCAGATGTAACAATTCATATAACTGAAGCAAGAAACGAAAACATCAATTCAAACACTCAAAGTAATGCTACCGAAAGACATAGACCTAATACGATAGATAGATCAACAAGAATTGGTGTGGTAGAACGCTCGATAGAAAGAACGCATTCGACGCTCGAAAGACCTCGTCGACCTTGTATGACTTCATCGAGCAGTTCGAATTTAACTGCAGCCGATGTGGCTAATTTACTTCGTAGTAGCATTAGGAGAGGGACTTCGCGAACTCAACAGTCCCTGCGTAGGAGTTTCTGCCACGACGAATCAACGGTAGCAGCGTCCGTTGAAAATCTAGTCGAGGCTGCAGCGCCGATAGGTGAAGAATCCTTGGTCCTTCCAAAGGACGTGTCTCTAGTCTCTAATGAACAGGCTAACAATAATAGCGACGATAAAAAGACTGCCGAAGAAACGGATGATTCCGTTTCTGTGATATAGACTATATCTTTCTTTTGAGCATATAAGAAGAATAATCTGATGGTTATTTAATTTCTGCTGCATAGTGTTACGGTGATTTATTCCTTGTTTAACTTGTATTCAATATTCATTTTCACAAGCTATTCTACGAAAGATAAACAAGTTGCTGATGATTTCATCGATCAATGATCGAAAAAATAATTTTATCTCTCAGACTGAATTCAGTATTTTCTAATCTTGTCACACTTGACAAATAAGTGCATAATCTCATCACTTTAATTACCGTGACAATTGTATAACGCGCAAATGAAAATTGGATAGCTATAAGCAGTGAAACATATAATAAACTCCTTTTCTTACTTACTACGATAGACATCGATTTTATATTGTATATGTTGAACTTTATTGAGGTTCAATTTGCTTTCAATCAGTCTATTTTAGCATTTTGGCATTTTCAATCGAGACTGTGTAACTAAAATATTTATGTAATATATACTACTGTAACATTTTAGTAGTTTTATGATATTAGTGTACATACTATTTTAACGAATCATAAATTCGCTTATTAAGCATTTTCTTCATTAA
->XM_027781123.1 PREDICTED: Falco peregrinus polycystin 1, transient receptor potential channel interacting (PKD1), mRNA 
-ATGAATATTTTTGTCAAAGGATACATCAAACTTAGTAATACATTTGTCATGTCTGTAATTACTCTAGATACACTGCAGAATGTTGAACGAAAACTGAAAATTGTGTTTTCTTTCTCTAGGGATCTTTCCAATAACAAGATCAGTGGTTTAGATGTTCAGATATTCAAAAGCCTGACTTCTCTGGCAAAACTAGATATAAGCCACAACAAGATTTCTACATTAGAAGATGGAATATTTGATAATTTATTTAATTTAAGTGAAATAAACTTAAGTTGGAATCCATTTGTTTGTGACTGCAAACTTTCCTGGTTGCCCCATTGGGTGGAAGACAGACAAGTGAAAGTTATTCAGGCATCAGATACGAGATGCGCCCACCCCCCTGAGGTGGCAAACCTTTCCCTCTTTGATGTCTTGTTCGTCAATGCTACTTGCGGAGCTCAATACATAACGTGTCTGACAAGCAACCACACAGAAGGGACTGAATTTGTCATCCTCTTCACATCTGTTCACCCTGGGAACCTCACTGAGGAGACTTGCAGTGCCCTCTGTTATGCTGAAGATCAGGAATATGGAGGTTTCAGCACCCAGGAGCAGTGTTTGTGTGGTACTGCCCATGAAACAAACTCTTCCTACGGTTGTTTGCCATTTTGCACTGAGCATTTGTCCGGGCAGGCCTGTGGTGGCCCATCACTCGTCCCCTCTCCCTTCCAGGCACAGCTATCTGTGTCTTTCACAGGACTCCAGCCCCGGTACAGCCTACGCCAGGCCGTGCTCTTCAATGTCAGTATTCCCATTGCTGTCAGCACTTTACTGTGGGAATTTGGGGACCAGACAGAGGTTCTCAACACCACTGGAAATACAGCTGTCCACATGTATGCCTTACCTGGCCAGTACAATGTCACTGCCACCATCTCTGTGGGCACCAAGGTCTTATACGTGCAGGCAGAAATTGAGGTGGTGGCTTCACCCCAACAGTTAGAACTGCAGTGTCCTTCCTTGGTCAAGACTAATGAGAGCCTGGACATACGGATCCGCAACAGAGGTGGCACAGGCCTTGCAGTGTCGTACAGTATCACCGCAGAGGCTGGGGAGCTGGGCAGAGCCGTTCACCCCCTGTGTCCCCCTGATGGCTTGGTTTTCCCGGGCAATAACCACTGCTATCAGCTGGTGGTGGAGAAGGCTGAGTGGCTGGAGGCCCAGCAGCACTGCCAGGAGCATGGCAATGGAGAGCTGGCTTTTGTGAGCAGCCCTGAGATCCAGAGCTTCTTGGTTGCTCATGTCATCAGGAGCCTCGATGTCTGGATTGGGTTCAATGATTTTGCAAGCACTGGAGCACAGCAAAGAGGTGAAGGATTTAACCTGGAGAGCTGTCAGAACTGGCTGCCAGGAGAACCACATCCATCAAATGCTGACCACTGTGTCCGGATGGGCCCAACAGGCCAGTGTAACACAGACCTGTGCATGGCCAAGCATAGCTACGTCTGCGAGTACAAGCCAAAAGGAGTTCTCTTAAATGCCAAAAACTTCTTTGTGGGAGACCCTGTGTCAGACACACATGAGGCTGTGAAAAATGTGACAGAAGATGCGCTGTCAGCTCCATGGCAAGCTGTGGAGGTGATGGTGTTCCCTGAGCTGGCATTCAGGCACGAGGGATATTTGACTGCCCTGGAGTTTGTAACACAGGAACTGCATCAGCCCGTTCAAGTGAGGTTCCAGGTGCATAGACCGATAGATGGAGAAGACTACCAGGAGGAAAAAAATGCTACAGAACCATTCTACACTTCTCAGGATGATGGGAACTGGACACTATTTGAATGTCCTCCTGGTTTCCAGTGGTGTCATTTGACTAATTTGTGCTCATCGCTAAACAACTGCTGCAACGCAACTGAGTGTGCCAACAGTTCTCTTGCCAGCAGCTCTACCCCCGTTTCCCTTCAGCACAGTGAAAGCCAGCTCAGCTATGAACTCATCGAGGAGTTTCTCTTTACAATACCAGCTGGCCCTTCTTCCCGGTATCTGGTCACGTTCAGAAAAGAAAATATATTTGTCAGGTCTGAGGATGTCTTCAGTATCCAGCACAATGCAGGCTTGGGCTTACTCCTCCAGTGCCAACCAAGTACCACATCCCCTTACAGAACCAACGTCTTAAGCATAAACTCTTCGGAGTCGGCACTTGGCTTGTCTGACGGCTTCATCGGTGCCACCTGGATGAACAACACTGTTTGTTCTCTCCGAGTTTGGTACGCTGAGGAGCAGCTGGTCCCGGTGATCAGCTCCCACAACACGGGGCTGGAGCATCCAGGTCGCTACACGGTCAGAGCCAGCGTGGACAACGGGGTCTTCAGCACCAATCTGTCCTGCAGTTTCTGGGTGGCTTCCCAGGTGTCAGGCCTGCGTGTCATCCACCCCGCTCCTCAGGGCGGCAGGGTCTACCTACCATCCAACCACACTACCCTGGTCATCAAACTCTCCTCAGGGGTGAATGCAACAGCTAGCTGGCTGGGAGACAACCGCACCTTCCCCTTCGAGGGGTCCTGCCCAGCGGCTGTGGCCCTGCTGACAGCAGACTGTGCCAGGGAGACCAATGACACCTGGTTTGCAGTGGTCAGCCTGAGCGGCCTCAGGGAGGGGATGAGCACCCACACGCTGGTTGCAGAGAACACTGTGAGCTCGCAGAACATCACTGTCACAGTGAAAGTGGAGGAGCCTATCCGTGGGCTGCGGGCCACCCCTGACCCTGAGAGCAGAGTCCTGCTAAATACACGAGTGAGCTACATCCCTGTGATGGAAGCTGGGTCAGATGTGACTTTCCGATGGACAGTAGATGATAAGCCATCTTTCACTTTTTACAATGTTGTCTTCAATGTTATCTACCAAAGCCCAGCTGTGTACAAGCTTTCGCTCACCGCCTCCAACCACGTCAGTAACTTTACGGTCAATTACAATGTCACGGTGGAGATGATGAATAAGATGAAGAACCTGACTGTGTTGGGTGTCCTGCCGGTCCTCCCGCAGAACAGCACCGTGGAGCTTACAGCAAGAGTTCAGGTTGATTCAGCTGTGGATGCTCTTTTCCTGTGGGATTTTGGAGATGGTGTCCAGAAGACATACCTGTTCCAACCTCCCTACAACAAGTCTTTCCTTGTTCCTGATCCCAGTGTGCATGAGGTTGTAATTGAGCACAATGTTTCACACGTCTATCAAGACCCAGGAGAGTATGCCTTGGTGGTTGTCGTGTCAAACCAGTTTGAGAACCTCACCCACTTGACCCCAGTTCACATCCACAGTTACCTGACTGATGTGAAGATGGAAGCAGAGGAGGATGTTTTAGTTGTGAACTGTCCGGTCACCTTCAGAGCTGATCCATTGCCATCTCCTTATGGCGTCGTGTACACCTGGGACTTCGGGGATGGGTCCTTGCTGTTCACAGAGAGCCAGTCTACAGTGACATACAGCTACCCCAGAAGAGGGGTGTACAACATCACTGTGACTGCCAACAATACCATAAGCAGCGTGGAGACAGTTGAGCACTACCAAGTGTTTGAAGAGATAACTGGGCTTCATGTTTCTGCAGATGAGGCAGCAGAGCTGGGAGCATCTGTGACCCTTAATGCTTCCGTGCAGACGGGGGACAGCATCACCTGGATATTCGATATGGGGGACGGGACGGTGCTGAGGACTCAAGTGCCAGTGGTAGAACACGTGTATGTAAAGGACATCAACTGCACTGTGAATGTGACAGCTGTGAATCCTGTGAACTCTGTCTCCCAAACTGTGCCCGTTAGGATATTTGTCCTGGAAGTACTCAAAATAGAGCCTACTTCTTGCATCCTTGAGCACCCGGACGTGCAGCTGACTGCATATGTGACAGGAAATCCTGATGAATACATCTTTGATTGGACTTTTGGAGATGGCTCGTCCAATGTCACAATCAGTGGGGACCCTGTGGTGATGCACAACTTCACCCGCAGTGGGACATTCCCCCTCTCCCTGACTCTCTCAAGCAGGTTTAACAAGGCTCACTATTTCACCAGCGTCTGTGTGGAGCCAGAGATTGTCAATGTCACACTTCTCCCTTCCAAGCAGTTTGTGAGGCTTGGTGAAGAGAGCAGCTTCCAGGTCAGTGCCGTGCCTCTCTACCAGTACCGCTACCGCTGGGATTTCGGGACCAATGAGTCCACTAGATCGAGTGGGACTGAAGTGACCTACACCTACAAGAACACAGGGGTCTTCCTGGTCACAGTGACTGTCTCCAACAATGTCTCTTTCAACAACGACACAGCGTTTGTGGAAGTCCAGGAACCGGTTGGGGTAGCAAAGATTGAATATAACGGGACAAGTGTTTTGGAGCTGAACCAGATCTACCTGTTCTCTGCCAGCATGAATGGAACCAAAGTGAGTTACTGTTGGGACTTTGGAGATGGCACTACCCAGCCCGGGCAAATCGCTGCCCACTCCTACAACAACACGGGCCATTACACTATTAGTGTGGTGGGCCGGAATGATGTGAGCTTTAATGAGACCGTCATTGATGTCACAGTGAAACGGCGGCTCCAGGGGCTGACCATCAATGCCAGCAGGACAGTGGTGCCGTTAAATGGTTCAGTGAGTTTTGTAGCCACACTTGTAGCTGGCAGTGCCATCCGCTACTCGTGGATCCTCTGTGATCGGTGCACTCCTATCCAAGGCTCGTCCACAATTTCCTACACTTTCCGGTCCGTGGGCACATTCAATGTCATTGTGACAGCAGAGAACAAGATCAGTTCGTTGCAGGACAGCATCTATGTCTACGTCCTGGAACAGATTGAGGGCCTGCAGGTGGCTAGCAGTGACCTGGTAGAGGACATCTATTTCCCAACGAACAAAACACTCCATTTGCAGGCAGTGGTGAGAGAGGGAACAAACATCTCTTACAGCTGGGTAGCCCAAAGGGATGGCAATGCTGTGCAGACCTTCACTGGGAAAACCTTCTCCTTGGTTGTCCTAGAAGCTGGAAACTACACTGTCTATCTGAAAGCCACTAATATGCTGGGATGTGCAACTGCTAACAGGACACTGGAGTTCATTGAAAGCATTGGTCTTTTAAAGCCTTGTGCCTTCCCCAACCCAGTTGCTATTAATGCCTCTGTTAACATAAGTACCACCATAACCAGTGGCACTGGCATCACATACATTTGGTACCTAGAGGATGGCTTCTCTCCTGTTACTTCTGAACCCTTTATTATACACTCCTTCCAAAGCCCTGGAGTGATAGAGGTCATCGTTGAAGCAGAAAACAAGCTGAATTCAACCAATGCAACAATTCCTATCTGTGTAGAGGAGGTCATAGAGGGGCTGAGTATAGGGACTGCAGAACTGGACTGTAGATACGTCTCATCCGGCTCCACAGTGGTCTTTGAGGGGGAGCTGCAGAAAGGGACTGAAGTGACATGGCTTTGGGAGGTGCCAAATGGAACGCTGACTGGCCAGTCTGTGGCAGTCATGTTCCCCACAGCAGGGTTTTATACAGTCTATCTGAATGCATCAAATGACATCAGCTGGGCTCTGGCCAGCAGGAANNNNNNNNNNNNNNNNNNNNNNATCTCAGTGCTGGACAGGATTCAAGGACTGGAAGTTCTTGCTAGCAAGAAGGTGGTGGAGCCAGGGGAACAGGTCACCTTTGTGATCAGGATGTTGTCAGGTACCTCTGTGAGTTACTTGGTGAGCATAAGTGGGGACTACTCTGTGGTGCTCAATGGGTCCAGGTACACGCATGAGTTCACCAAGAGTGGTGATTACTTGGTAACTGTGACAGTGCAGAACCAAATCAGCATCGCACATGCCCAAGTGCTCATCTCTGTCCTGGAGGCCATCCGTGATGTCAGGCTCCTGAACTGCTGTGAGGAAGGCATACCCACAGGCACGGAGAAGAGCTTCCATGCCCAGGTGGGGAGTGGCTCCCGTGTGGCATTCTCATGGCAGTTCTCCCTGTGGAAAGAGAAAGGACGATCTGTGGTCACTGTGGCAGGAGAGAGTGTTTCCTACACTCCAGAAGCTGCAGGGCTGCTTGAGATTCACCTCAATGCCTTCAATGACTTGGGAGGTATCAATATCACCAGAACCATCCAAGTCCAAGACCCAATAGTCCAAGTCTCCCTCACTGCCTCCAATGCCTTTGTCAACAGGACAGCACTGTTTGAAGCAGCACTGGTGCCCAGCAGCAGGAGTGTTGAGTTCTTGTGGACCTTTGGGGATGGCTCTTCCACTCAAATGACCAGGGTTGCAGTGGCCAACTATTCTTACGTGAGCCCTGGGGATTACCTGGTGGAGGTGAATGCCACCAATCTCATCAGCTTCTTCATAGCCCACCTCACTGTCACTGTCAAAGTCCTGGAGTGTGAGGAGCCAGAGGTGGAGTTAGCCTTGCCCCCTCAAGTAGTCATGAAGCGGTCCCAGAGGAACTACCTAGAGGCACAGATTGACCTCCGAGGATGCATCAAGTACCAGACAGAGCACCTGTGGGAGATCTACCAAGCACCCAGCTGCATGAACTTGGATGACTCCAGCAGGATCCGTCTGCCAAATGTTGATGTGAACAGGCCCCAGCTAGTTATACCAAAGCTTGCCCTGGAAGTTGGGAATTACTGCTTCATTTTTATTGTCTCCTTTGGAGACACCCCACTGTCCAAAAGCATCTTTGCCAATGTGACTGTGATACCGAGTAAGCTGGTCCCAATCATTGATGGGGGGTCATACCGTGTATGGTCCAACACTCAGGACTTAATCTTGGATGGGGAGAAGTCCTATGACCCAAACTTGGATGACGGTGAACAGACTCCGTTGTTATACGATTGGTCTTGTACATTCTCCTCCAAGAGCTCGGCTGCAGGGTGCTCTCTGAATTTCAGTGCCAAGGAAGGAATTGTCACAATTTCCAAAGCTCTGTTAGAAGCAGATGTGGAGTATACGTTCGACCTCACCGTCAGGAAGGAGGGTATGAGTCCTGAGGCAACAAATCAAACCGTATTCATCAAGAGGGGAGGAGTCCCTATCGTTTCCCTGGAGTGCGTTTCCTGCAAGGCTCAGTCTGTCTATGAAGTTAGCAAGAGCTCCTACGTCTACCTGGAGGGGACCTGCCAGAACTGTCACAATGACTCCAAGCTTGGGAGATGGGCAGCACACAGCTTTAAAAACAAGTCTCTCATCCTGGACAAAAAAACTACCTCCACTGGCGACACAGGCATGAACCTGGTCTTGAGGCAAGGGGCACTGAAGGATGGGGAGGGATATACTTTTACCCTTCACATCACAGACCTCACAACCGGGGAGGAAGGATTCGCCTCAATCGATCTGCTCCCCAACCAGCCACCTGTTGGAGGGTCCTGCCAGCTGTCTCCGGAAGGACCCCTCAGGGCACTGATGGCAAAGGTGCACTTTGAGTGTGCAGGCTGGCGAGACACAGAGGACGCGGAGGGCCCGCTGGTGTACATCCTGCTGGCGTCTCGCCACAGGGCTGGGCACTACCACGAGTTCTGCGTGTACAAGGGCAGCCGTGCAGAGCACAGCGCCTTCCTGCCCCCGGGCTTCCATGAGAGCGGCTTTATGGTGTCTGTGGCGGTCCTTGTTCAGGACCAGCTGGGAGCCACCGTGGTAGCCGTTAACAGCTCCATGGAAATCGGCTTACCTGAGGGGTTCCCCAGCCTCTCCCACTGGCTGTACAATCAAACTGACACGGTGCTCCAGGGCTTAGTGAAACAAGGGGATCCTCAGCAGGTCATTGAGTACTCTCTGGCCCTCATCACCATCTTAAATGAGTACGAGAGGTCCATGCTTCTGGAATCTGAGGCTGGAAATGAATTTGAACTCCGGACCTGGACTCGCAATAACATCACAGAAACCCTGAACTCGTTGAATGTGAACACAGTTGATGACATCCAGCAGATCTCAGCTGCCTTGGCGCAGTGCACGGTGGTGAGCAAGGAACTGGTTTGCAAGTCATGCCTGACAAGGACCTTGAACAAGCTGGAGACCATGATGACCATTCTACAGGGAGAAACGACCCAGGGCACTGTGACACCAACTGGCATCGCTGACAACATCCTCAATATCACAGGTGACCTAATTCACCTTGTCAATACAGTTTCACAAGAGTCCAAGCCCCAGGAGCTGCTTGCTGATTCCCACAATTTGCTGCTAGCTCCCAAAGCCTACAACCTGTCTTCCAGCCTGATGCGCATCCTCATGAAGTCTCGGGTGCTGAATGAAGAGCCTCTTGAGCTGGTGGGAGGAGAAATTAAGGCCACAGGCAAGCGGTCTGATCCCTTTAACTTGCTTTGCTACGAAAACACACCAAACTGCCAGTTCTCCATCCCCCAGGCATTCAACACCACCCTTTCCAACCTGACGGATGTCATTCAAGTCATGTTCCAAGTGGACTCCAATCCTTTCCCTTTTGGTTACATCAGCAACTACACTGTGTCCACAAAGGTCGCCTCCATGGAGTTTCAGACACACAACGGGGTGCAGATCCCCATTGGGAGCCTGGACTCAGAGAAAGCCATCACTGTTATGGTGTCAAACAACACAGATGCTGACAATCTCTCTGCTGGCACTGAAGTCATCGAGGCAAGAACATCTGTGAACTTAATTGTGATTATGGAAAGCAACAACAGAGAAGCAGGGCTGCACTTCCAGCTCACTTACAGAGTCCTGAACGATCGCTACATCGCAAGCGAGCCTGAGCCATTCATTATGGCTTATCTCCATCACGAACCAGAGCCCAACGAGCACAACTGTAGTGCCTCTAAGAAAATCGGCCTGGATGCCCTGGCTGGAAGGGACCACAAGCTCTATACCTTCTTCACTTCACCCAGAACGGATGACACCATCCAGAAATACTACTTCAACATCACGAACCATTTCAGCTGGTCCCCAGTGGAGGTGACTCTGGGGCTGTACACCTCCCTCTGCCAGTACTTCAGTGAGCAGGAGAAACGGTGGAAGACAGAAGGGATCATCCCACTGGAAGAGACCAGGCCAGACCAGGCTGTGTGCTTAACCCAGCACCTCACTGCCTTTGGAGCCAGTCTATTTGTCCCCCCAAACTCTGTCCAGTTCATCTTTCCTGCTCCAGGTCCAGGTCTCAACTACATCGTTCTGCTGACATGTGCCGTCTGCTTTGTGACCTACTCGGTGGCTGCACTGATAGTGCACAAGTTGGACATGATTGACATTAACCGAGTAGGGGTGATACCCTTCTGTGGGAAGAACGGGCTGTACAAATACGAGATCCTGGTGAAAACTGGCTGGGGCAGAGGATCAGGTACCACGGCCCATGTGGGGATCGCCCTGTACGGTGTAGACAGTAAAAGTGGTCACAGACACCTGGATGGAGAAAACGCCTTCCACCGCAACAGCCTCGATGTGTTTCAGATCGCAACAGAACGAAGTCTGGGGAGCATCTGGCGCATCCGCATTTGGCACGACAATAAAGGACTCAGCCCCTCTTGGTACCTGCAGCACGTCATAGTCCGGGACCTGCAGAGCAGCAAGAGCTACTTCTTCCTGGTGAATGACTGGCTGTCGGTGGAGAGTGAAGAGAACGATGGCATGGTGGAGAAGGAGGTTTATGCTGCCAGTGAGACAGAGCTGAGGAGCTTCTCCCGGATCTTCATAGCAGAGCTGCAGCGAGGTTTCTTTGAGAAGCATGTCTGGCTCTCCATGTGGGACCGCCCGCCCCGCAGCCGCTTCACCCGTGTCCAGAGAGCCACCTGCTGCTCCCTCCTCATCTTCCTCTTCCTCTGTGCCAATGCTGTGTGGTACGGCGTGGTGGGGAACGTACACCTCAGCAATGGGGCAGTTTCTAACCTGATCCCTGTTAACGTGGACACAGTGGCTGTTGGTCTGGTGTCCAGCGTGGTGGTCTACCCTCTCTACCTGGTCATTTTATTTCTCTTCCGGATGGCTCGTGGCAAGGTCTCCATCAACCACACCCTGACTCACTCAGACCAGCAGTCCTTGGAGATCGACAACTACCTGGACTCCTCAATCCTTGACAGCTCCTTCCCCACCTTCCCTGGGCTCCAGGCAGAGGCCTTCTCTGAGCAAACCAAAACAGATCTCTTCTTGGAGGACTCCAAAAGCCTCGTGCGGTGGCCCTCTAGCGAGGCCCTGCTCAGCTGGCCAGACCTCCTCAGCGACCCCTCCATCATGGGCAACACCATCCAGAAGCTGAAGAGGGGCCGGGCCAGCCGCCACCTTGGACTCGAGGCCCCATTGGCAACTGAGGAGGACAGCTTGTCGCTTGGTGTTCACCAGGGACAACCTCGATATTTCTCTGCCTCAGATGAGGATCTGATCCGGCAGATCCTGGCAGATGGAGCTAGTGGCATCTCCCACTCCCAGGACCTAGGGCCGTACATGAGGGCTGAAACAGATCTGATCTCAGGCCTGTCCAGCATGTTCGGGGAGAAGGTGGAGACTGTCATGATGCAGAAGCTGAACGACAAAGGCCAGGGCATGGCAGCTCCTCCCAGGGAAGTGAACAGATCCGCCAAGTCGACGTGGACAGTTGCAGATCAAACATTCAGAAAGCGCCTGCTGCCACCCTGGTGCTCCTACCTGGCTCATGGTATCAGTCTCCTCCTCTTTGCCACCTCCACGGGGGTCTCTGTGTGGATCGGGGTGGGCTTTTCCTCCAGCGTAGCCCTCATGTGGCTCATCTCAGGGATATTCAGCTTTCTGGCATCCTTCTTGGTCTGGGAGCCCCTGAAGGTTCTGCTGGAAGCCCTCTATTTCTCACTGGTTGCCAAGCGCTTGCACCCAGAGGAAGATGATACCTTGGTGGAGCATCCGTTTGTTGAGCATGTTTCCGAGAAGATCAGCAAAGTCCGACCACCACAGGGGTTTGCCCTTTTCCAGGCCAAGGAGGAGGCCAGGAAGGTCAAACTGCTACACAGGATGCTGAAGAATTTCCTCATCTACATGATGTTCTTGCTGGTGATCCTGCTCACCAACTACGGAGACGCCTCCCGCAACAGCAGGGCCTACCTTCTGCAGAGCTCCATCAAGCAGCAGTTGGGCAGCAACGAATTCCTCCTCATCAAGAGGTCAGATCAGTTCTGGGTCTGGATGTCGCAGGTCTTCCTCCCTTACCTCTACAACAACCAGTCAGGCCAGGAGAGCTACAGCACCACACTGGGAGCAGCCCGGCTGCGCCAGCTCCGGCTGCAGGAAGCTGAGTGCCAGCACAGTGCCCGGGACATCCTCCATAGCATGGGCCCAGCTGCCAGGAGCAACTGCACCAACTCGCACAGCTTTTCTACTGCTGACTATGCAGCTGGCTGGGAAAGGGCGGCCGTGAATGTGTCAGCTGCGTGGTCCTACTCACCACCTGACCTGACGGGGGTCTGGTACTGGGGTTACATCTCTTTCTACGATAGCAGCGGTTACGTCCAGGAGCTGGGGGCTTCGCTAGAGGAAAGCAGGGCTCAGCTGAATTTCCTTCAGCAGCACACTTGGATCGACAACATGAGTCGGGCAGTCTTTGTGGAGCTGATGCAGTATAACCCTAGCGTGGACCTGCATGCTGCCATCACCCTCCAGCTGGAGTTCCTGGGGGCCGGCCAGGCCATCGCCACGGTCACCATCAGCCCCTTCCCACTGCTGCGGCTCAGCAGGGGTGTCACGCTGCAGCTTCTCATGATGGTCTTCCTCATGATGTTTGTGGTCTACTTTGTGGTGTCTGAGTCGCTGTCCATCAAGAAGGAAGGCAGAGCCTACTTCACCCTGTGGGGCAACTATGGCCAGTGGGTCTTCATCCTCCTCACCACGTGCACCGTGGTGGTGCACCTCAGCCAAGCCACCCTTGCCGACCAGCAGTGGCTCAAGTACCTCAACAACCGCAAGGGTTTCACCAACTTCTACCAGGTGGCCTTTCTCAACACCATCTTCAGCACTTTGGCTGCATCCCTCCTCTTCCTTCTGACTGTGCAGGCTGCCCAGCAGCTGCGTTTTGTCAGGCAGTGGTCTGTGTTTGGGAAAACCCTGCGGAAGTCGGCGAAGGAGCTGGCTGCTGCAGGGCTGGCCTTCGCCGTCCTCATCCTGGCCTACGCTCAGCTCGGCTTCCTGCTCTTCTCCTCCTCCTCGGAGTCCTTCCGCAGCGTTGGCAGCAGCCTCCTGCTGCTGTTTGCCATGCTGCGGGGCAGCGGGACCCTCCGCCCCTGCCTGCCCGAGTCCTCGGGCCTCTACTGCCTGTTCTGCACCAGCTACATCGTCCTGGAGGCGTGGATTGTGCTGAGGCTGTTCACCGTGGTGCTTATCTACAGCTACCGGGAAATGCACTTTGAGCTGTACCGCCCCGCCTTCGAGCCCCAGGACTACGAGATGGTGGAGCTCTTCATGCGCAGGCTGAAAATGTGGATGGGCTTCAGCAAAGCCAAGGAGTTTCGGCACAAGGTGAGGTTCGAAGGGATGGAGCCGCTGCCTTCCCGAGACTCCAGTGACTCCAAATCCTTTCGGGGCCCCACTCCCAGCGCTGCATCTGACAGCTCCTGGGCTTCCACCTCCTCCAGCCAGCTGGACGGGCTGAGCCTCGTGCTGAGCACCCGGGACAGCCTGGAAGTGGACGCTGACATCCAGCGCCTCCTTTCCCTCTTTGAGATGCTGCTTGCCCAATTTGACCGGGTCAACCAGGTGACAGAGGACGTGTACCGCATCGAGCACCAGCTGGAGGGCTCTCAGAGCCGCCGCTCCAGGAGGAGGGGTACCCAGGTGTCCGAGGATGTCCCGAGCAGGTACTGTGCGGGCAGCACAGAGCAGGGGCCCTCGCCTGAGACCCCCTCCAACACGGACCTGCAGCCCCTGCGGGACGCCCCATTGTCCCCCCACTCTGCTGCCGCCCCACCAGGCACCAGGGGCTCTGTGCCCAGCCGGCTCCTTCGAGCTAGCAGAGGCATCGGCATGGCGGCTTCTGTGCTGCCCCCGCACAAACCCTACGCCGCCGTGGCTCCGGCGGTGAAGAAGAAACGGCCTCTCCGGGCCAAGAACAGGGTGCACCCCACTGTCAAGTAACAGGTGGCCTGCTGGGTATCGCGGGGAGCAGTGCCTCGGAGAGCCGGCAGCGCCTGGAAGTGGTTTGCATAGGGCGGGCTGTGCCTGCCCTGCAGACCTGGAGCCTCAGGAGCTGCCGCTTCTGATGGCTCCCGCCGCGGCGGCTGTGCCTGCCGGGGCGCACGGGGCTGCTGCCTGCACCGGGGTGGCACCGCTGCCATCCTCCACGGGCCTGACGTCCCCATCGGGTGTGCTGACCTCTCCGCTGGTGGTGCCCAGCACTGTGGGGGAGGCTGTGCAGGGCACGGTCAGTGTGCAGGAAATGCGTTAGCGTAGGGCAGTATTAAAAAGTTGTCTCTGAAATGGCTCCATCTGCAGACAGCCTGCACATGGTGACTGTCACAAGGACACTTTACTGGGGACTGGCACAGGGTGACCGGTACAAAGCTCACCTCCCTTCCCCACTGGCTGTGCCGGAGGGAAAGGGGGAGAGGAGAGCCCCAGGCCTTGAAGGTTTGAATTGAGTCTTGGATTTTTGTCGACCAGGCACACTGTGGAGGAAAGCTACAGCTTTCGAGAAGATATTTAACCCTTTTTTTTTTTTTTTAAAGCATAAATATATATAGATATAGATAAATGATATCTACACCCAGATCAGTTAATTTCCAGTATTGGCTACTTTTATCCTCCAGAAATTGGTACTATTATTTGTATTTAAAGAAATCCAATATTTAAGACCAATGACATTGGAAGCTGCAGCGAGCTGCCAGCCCTGCTGCCCGGCCAGGTCGGAGGGGATAACAAGCA
->XM_024348560.1 PREDICTED: Pan troglodytes SGT1 homolog, MIS12 kinetochore complex assembly cochaperone (SUGT1), transcript variant X4, mRNA 
-AAAAAGTAATGTATTTCTGTATTTTGTACCTTCTGAATAGGGAAAAACTGAATACCTTGAGTAAAATTACATAGAAAATGTTAATGAGACAAGGAGGTGAATTTTGTGACACAGCTGTATTCATTGAAGAGCTTTAAGAAGGAAGCTAAATGTTAAGCCAAAAGGAAGTTGCTGTTGCTGATGCAAAGAAGTCTCTAGAACTCAATCCAAATAATTCCACTGCTATGCTGAGAAAAGGAATATGTGAATACCATGAAAAAAACTATGCTGCTGCCCTAGAAACTTTTACAGAAGGACAAAAATTAGATAGTGCAGATGCTAATTTCAGTGTCTGGATTAAAAGGTGTCAAGAAGCTCAGAATGGCTCAGAATCTGAGGTGTGGACTCATCAGTCAAAAATCAAGTATGACTGGTATCAAACAGAATCTCAAGTAGTCATTACACTTATGATCAAGAATGTTCAGAAGAATGATGTAAATGTGGAATTTTCAGAAAAAGAGTTGTCTGCTTTGGTTAAACTTCCTTCTGGAGAGGATTACAATTTGAAACTGGAACTTCTTCATCCTATAATACCAGAACAGAGCACGTTTAAAGTACTTTCAACAAAGATTGAAATTAAACTGAAAAAGCCAGAGGCTGTGAGATGGGAAAAGCTAGAGGGGCAAGGAGATGTGCCTACGCCAAAACAATTCGTAGCAGATGTAAAGAACCTATATCCATCATCATCTCCTTATACAAGAAATTGGGATAAATTGGTTGGTGAGATCAAAGAAGAAGAAAAGAATGAGAAGTTGGAGGGAGATGCAGCTTTAAACAGATTATTTCAGCAGATCTATTCAGATGGTTCTGATGAAGTGAAACGTGCCATGAACAAATCCTTTATGGAGTCGGGTGGTACAGTTTTGAGTACCAACTGGTCTGATGTAGGTAAAAGGAAAGTTGAAATCAATCCTCCTGATGATATGGAATGGAAAAAGTACTAAATAAATTAATTTGCTCTCATTGTATTGTGTATATTCACCTAATGCCCATTGTGTATTGATATTGCATTCTTGAATTTTGAACACTGAATATCTTTTTGAAAGATTATACTTCTTTACCTCTTTGTGCTTTAGAAATTATTTTCCTTCAAGTGTTCAAGTCTAATGAAGAATGAAGATAACATTTTATCACTTCTGTCCTTAAAGATTTCAGACATGGTGAAACTGAATAAAGCGTGTCATTTGCTCCTAGATAGATTCATTCTATCTAGTTGTGGGGATGGAGAAATCTTTAATGGTATATTTTTGGTTATTGCCTTATTTTTGATGCAGTATTCTGTCAGTAATTTATTAGACCTGGCAGCTTTGGGTGAGCTTAGATTTTTCACCTTCAGTGTTACATTGTGTTTGCTTTTAAAAACTGCTTTTGAATGGAGTTGTAAATACAATTTTTCTATGAA
->XM_028429604.1 PREDICTED: Parambassis ranga ventral anterior homeobox 2 (vax2), mRNA 
-ATGTTTGATCAGGCCACGACTATGGGCGATGGGAGCCACCGCTGTGGACCCAACCCGCTGTGCCCGGACAGGATGGAGACAAAGTGTCGCGCCGAGATAGGGAGCCGGTCCCCGGTGCAGAGCTCCACCGACACCCCGGGGACATCAGCGTCCACGCCGACGTCCTCCAGCGAAGACGGGCATGACAAACTTTTGGGAGTGGACCCAGACTACTGTCGGAGGATATTAGTAAGAGACGCCAAAGGCACCATCCGAGAGATTGTCCTGCCGAAGGGCCTCGACCTGGACCGGCCCAAGCGCACCCGGACCTCCTTCACGGCGGAGCAGCTGTACCGGCTGGAGCTGGAGTTCCAGCGGTGCCAGTATGTGGTGGGGCGGGAGCGGACGGAGCTGGCCCGGCAGCTGAACCTGTCCGAAACACAGGTCAAGGTGTGGTTCCAAAACCGCCGGACCAAGCAGAAGAAAGACACCACCAAGGACTCAGACAAGCGCTCCTCTTCCACGTCCGAGTCTTTGGCCACCTGCAACATCCTGCGCCTCCTGGAGCAGGGCCGCCTCCTCTCGGGCTCCGCTCCACCTCCCAACCCCCTTCTAGGGCCCCCAGCTCACCCAGCAAATGGTTCGCTTTTGAGTAGCCCGGGCGGGGGCTCCTCCACCTCCCCTGGGATGAGCAGCAGCACTCCTCCCAGCTCTCTACCTGGAGGGACATTCGGGCTGTCGCTGCCCTCACTGGGCGGCACCCCGCCTTCGCCGCGGCTGGGCGTCCCGCCGCCGCACTCCCTCTGCTTCTCCATGCCACTGCTAGGTGGCGCTCATCACGAACTGACATCCGCCTACGGCTGCGGGTCCTCAGCTTTTGAGCCGTACATGCGGCTGGACAGGAAGGACGCAGATCTGGGAGGGAAGAAGACAGTTTCTTAA
->XM_039793275.1 PREDICTED: Perca fluviatilis Rho GTPase activating protein 1 (arhgap1), transcript variant X5, mRNA 
-GGTGTCGACGCAGATTGTTGCTGTTGCTGTCAACCGCACGTCTTGCTAATCAAGTCTACGGCGACTTCAGACGCCACAAAGCCCACTGGGTGACTACAAAGCAACTTTGCAATTACGGACTCTGGCTGCTACTCTGTGAAAGTCCCAGCTTTAAGAGTGTGTGGTAAACATCACTGTGCAGTGTGTCAGTGGGTGTGTGTAGCACCGTTTTGCAGAGTGAGTGATGTCTTCAGAGCTGCTGGTAGATTTGGGTGAAGACCCTGCGACTGCACAGTTAGGACAGCTGAAGCTGACCACGGTAGATGACCAGCAGTGGCCCGCTGATGAGTCTACTCTCAGCAAGTCAGAGACAGATATCTCCCAGTGCTTTGACGCTGGCTCTCCACACCTGCCCTGGGACCATCCGTTCTATGACATCGCCAGGCATCAGATCATTGAAGTGGCGGGTGATGATAACTTTGGAAGGAAGGTGATAGTGTTTAATGCATGCAGGATGCCTCCACAGCACCAACTGGACCATCACAAGCTGCTGATGTATCTTAAAGGAACACTGGATCAGTATGTTGAAAGTGACTACACTCTGATCTATTTCCATCATGGGCTGACCAGTGAAAACAAACCCTCTCTCAGCTGGCTACGAGATGCATACAGAGAGTTTGACAGAAAGTATAAGAAGAACATCAAGGCTCTGTATATCGTCCATCCAACCATGTTCATCAAGACTCTGCTGATCCTCTTCAAACCAATCATCAGTTTTAAGTTTGGCAGGAAGATTAACTATGTGAGTTATCTGAGTGAGCTGGAAGATGTGGTGAAGTGTGAGCAGTTGCTAATTCCTGCCCGTGTCAAAGAGTATGACAACAAGTTAAGAGCTTCCGTTAAACCAACCGTCCAGCCTCCCATGTCTCCTCCTCACAGCCCCCCCCTCCACAGCCAGGTGTTTGGGGTGCCACTTGCATTGCTCAGGCAGAGGAATCCAGATGGTGATCCTGTTCCCGTGGTGATGAGAGATACCATTAGCTTCCTTTGCGAGCAAGGTTTGGAGATTGAAGGGATCTTCAGACGGTCTGCCAATGTGACTCTGGTGAAGGAGGTCCAGCTCAGATACAACTCAGGTGCAACGGTGAATTTCAGGGAGATGGAAGACGTCCACTTGGCTGCTGTGATTCTGAAGACATTCCTGAGGGAACTTCCAGAGCCTCTGCTGACCTACCAGCTCTACAACGACATTGTCAACTTCACTTTATCCAGTGAAAGGCAGGTGGCACTTATGAAGACACTGATAGAGTCGCTGCCAGAAGAAAACTATGCACCACTGCGACACCTCATCACATTCCTGGCAAAGGTATCAGCCAACAATGAAGTGAATAAGATGACCAACAGTAACCTGGCTGTGGTGTTTGGTCCTAACCTGCTCTGGGGACGGGACAACGCCATGTCACTCAGCGCCATTGGGCCAATCAACAACTTCACTAGAATCCTGCTGGACCACCAGCATCTGGTCTTTACCTAAACCCTGCCCCTTTACCCTGCAGTCTCTCTTCCAGTCGGAAACACCCTTTTCCATTAAAACACCATACACTTTAAAAGGATCCCGTGGACCAATTGCATTTAATTTTGTCTCCCACCAGTCTTTACATTCTGATTGGCACATATTGTTGATGACAACAGCAGTGTGGACTGCTACTAGCTTCTGGCCAGCATTTCCATTTGCATGTGACTCTAGTAAAATGGCACATACATTAGACTGCAGACAAATAACCCTCAATAAACAATGTAGGCAGAGAGATTTAACTTTAAAGTGCCAGTTATTCTTGAAAGTCGTGTATTTTTGCAGCTTTGCTTTTTGTCATTTTGATAAGTCAACAGAGCTGCCTCAGTATCCAGTTTTGCAACCAGTGAGTTGGAGGAAATCACAGAATTTGGGGACAGTTTTGTGAAATCAAAATCAGGGAGTGGATCTTCACAATTACTACTACATAACAAAAAACTAGATGATATGAGGTGAAGATCTGTGCCTGTGCAGGTTATTCCAACTTGCAGAAATAGTTAACTCCAGTGATTGTCCTTAAAAAAGTCTGCCGACTCACAGAAGTGAGAATGTAAAAAAAATATACAGAATCGAAGAAGGTGGAGATAACCTGAAATTCAGTCTAGCTCCAAAAACACTGGAACCTTCATTTCCCATAATGCAGCTTATTAGAGTATTTCATCAGACCCTAGCTGCCTGGTTAACTAAGTCTTGTAACGTAAGGCTTTCTGTTATAGATTTGTAGTCCAAACATTACTTTCTCACATTTGACACAGCTCCCCCAGACACAACTGTCAGACTGAATAATGAAGTGAAAGGAAATGGTAGATCAATGTCCTATAATAATAATGCTATAATAAACATAATCAGGGAGTGTATATTTAAGGACATAATTGCACTCAAGTACAATTGATTATGTTGGTTCCAGTGTGAATGCCACTGGCTGAAGTGCAGGCAACCTACAGTTATTTCACATAGTACATTTCATCACCCTATTACACCCAACAACCCTTCAAAAAATCCTGTCCTAATTGCATATATATATATATATATATACACACATACATGTGCTGTGCTGTTGTCAGACTGTCTCTCTGCTGTTTTTTTATGTAGTGACAAAAAAAATAATAAAACTGGCCTCCAGCATTCACATGAATTATCACCCTGCTCTGCATGGTAATACATGATCAGTAATAAGTACAGATAATGAAGCAGTGCAGTTACTGTACAAAACGTATAGGATTCTGATCCCAAACTTAAAGAGGAGCGATAGTGGCCCTGTTCAGACCTGGCATTATAAGTGAACAGCTCTGAGGTTGTTAACTTAGATCATGCGGCAAAAACTGCAGTTCATTTTGAATGGTGATAGTGTGATCACCCGATACGCAACTTAATGCCAGTTCAGAACAGGGCATAAGAGAATGAAGGTCGGATTTTCCATGTCCTTGAAAGTCTCAGGATCATTTACAGTAGTAGTAAACTTGGTACCAAATGTTGTTGACAATCTTTTAAATGCTGTAATTATAGTAACCAGTAGAAAAGGAGCTGTGTGATTCTACCAGCAGATGAGTAAGTGTTTAGAACCCAAAAACAGCTGTGCATGTAGATGAAATAAGTGCTGGTCTAATATACTCTGTAATATCA
->XM_035125527.1 PREDICTED: Zootoca vivipara cadherin 20 (CDH20), mRNA 
-TCTACCTGTAACCTCAGCTGCAGCAGTAAGTGACAGGAGCTCAGAGGAAAGGCCAACATAGTGACATCAGTAAAAGAAAAAGGAAGGAAACTACTGTCCTTAATCTGGCTGGCTTCATATCACTGAAAGACTGCCCTTGGGAGTTTCAGAGGCCTTTCTGTTGGGTGTTTTAAAGGACCCGGCTACAACTTTTGGAAACAATCCTGGTATGGCAACGCGAACTTCGTGTGAAATGGATAGAGCCAGGAAGTGGCTCGGACTCAGTATATCTTTAAGTTGTTGCTTAATGATGAACCTCGTTACGGCTGTGTTATCTGGGAGCAGCAGACCACCCAGCAAAGGCCAAGAAGGCAGCCTCTCGGACAACTTGCTTCTGCATCTGCGAATGAAGAGGAGCTGGGTGTGGAACCAATTCTTCGTTTTGGAAGAATACACTGGAACGGATCCTTTGTATGTGGGAAAGTTGCATTCTGATATGGACAGAGGAGATGGATCCATCAGATATATACTGTCGGGAGAAGGAGCAGGCATTGTTTTTACCATTGATGATGCAACTGGAGATATCCATGCCATTCAGAGGCTGGACCGAGAAGAGAGATCCCAGTATACTCTAAGGGCTCAAGCTTTGGATAGACTGACTGGCAGGCCGATGGAGCCGGAATCTGAATTTATAATCAAAATCCAAGATATCAATGACAATGAGCCCAAGTTCCTGGATGGGCCATATGTTGCTTCGGTACCAGAAATGTCACCAATAGGTACCTCCGTTATCCAAGTGACAGCAACAGATGCTGATGATCCTACCTATGGGAACAGTGCCAGGGTAGTCTACAGCATTCTCCAAGGACAGCCATATTTCTCTGTGGACTCCAGAACAGGCTTGATTAGGACAGCGCTAATGAACATGGATAGAGAAGCAAAAGAATATTATGAAGTGATTATCCAGGCCAAAGATATGGGCGGACAGTTGGGAGGATTAGCTGGGACGACCACAGTCAATATCTCCCTGTCTGATGTCAATGACAACCCACCCAGATTTCCACAGAAACATTATCAGATGAGCGTTCTGGAGTCTGCTCCAGTTAGCTCTACTGTGGGCCGTGTCCTTGCTAAAGATTTGGATGAAGGCATTAATGCTGAAATGAAATACAGTTTTGTGGATGGGGATGGACTGGATGTTTTTGATATTGCCACCGAGTCTAATCGCCAAGTTGGTGTCATTACAGTGAGAAAGCCCTTGAACTTTGAGAGTAAGAAGAGCTACACTTTGAAGGTAGAGGGTGCCAATCCCCACTTAGAAATGCGCTTCCTGAACCTGGGCCCCTTCCGTGACACTGCTACTGTACACATCACCGTTGAGGATGTAGAAGAGCCCCCACTCTTTGAGCCTAGCTTTTATTTTGTGGAAGTCCCTGAAGATGTGGACATTGGGACCACCATACAAATGATTCATGCCAAGGACCCGGATGTGACCAACAACTCCATCAGGTATTCCATTGATCGAAGCAGTGATCCCGGACGCTTCTTTTATGTCGACATTGCAACAGGTGCTCTGATGACTGCAAGACCTCTGGATCGGGAGGACATTCCATGGCACAATATCACCATCCTGGCCGTGGAGCTGAACAACCCCTCGCAGGTTGGCAGTGTTTCTGTCACGATAAGAGTGCTGGATGTGAATGACAACGCTCCAGAATTCTCCAGATTCTACGAGGCTTTTGTATGTGAAAATGCCAAAGCTGGACAGCTGATTCAGACAGTGAGCGCGATTGACCAGGACGACCCACAAGAGGGACAGCACTTCTACTATAGCTTGGCTCCTGAGGCAGCTAACAACCCCAACTTTACTCTAAGGGACAATCAAGACAACACAGCTTGGATTTTAACCAGGAGATCAGGCTTCCGGCAGCATGAGCAGAATATATTTTACCTTCCTATCCTGATAGTTGATAATGGACGTCCCATGCTGAGTAGCACCGGGACAGTAACCATTCACGTTTGCAGCTGCGACGACAAGGGTCTTGTGATGTCCTGCAATGCAGAGGCCTATGTGCTCCCTGTCAGCCTGAGTAGAGGAGCTCTTATTGCCATTCTAGCCTGCATCTTTGTCTTGCTAGTGCTGGTACTGCTGATCTTGTCCATGAGAAGGCACAGGAAGCAGCCGTATATCATTGACGAAGACGAGAACATCCATGAGAACATCGTGCGGTACGACGACGAGGGAGGTGGGGAGGAAGACACAGAGGCCTTTGACATCGCAGCCCTGTGGAACCCGAGGGAGGCTCAAGTGGTGCTGAAGAGCAGGCAGGACATGATGCCGGAAATCGAAAGCCTCTCCAGATACGTTCCTCAAGCCTGCACGATGGACAGCAGTGTTCATAGTTATGTGTTGGCCAAGCTCTACGAAGCCGACATGGACCTCTGGGCACCTCCCTTTGACTCTCTCCAGACGTACATGTTTGAGGGCAACGGCTCCGTGGCAGAGTCGCTCAGTTCCTTGCAGTCTGCGTCTACGGACTCAGAGCAGAGCTACGACTATCTGACGGACTGGGGGCCTCGCTTCAAAAAGCTGGCCGAAATGTACGGTGCCACAGAAGGGAACGGGGCCCTTTGGTAACAAAGAGGCGAAGGCAGAGTACTACTCGGGTACTCGGCACAGCCATCCGAATTTGTACTCAATCAGATATTGAGGACACAGGCGAGGTGGCCTCCTACAAATAGCAATATGGTGCTTGAGGGAGAATGCAGAAGAGGAGTGGAAATAAATAAGAGCTCTCTCTGGATCAGCTTTACTCAGTTACATTAAGCTACATTTGTAAACG
->XR_003975245.1 PREDICTED: Gadus morhua 5S ribosomal RNA (LOC115538338), rRNA 
-GCTTACGGCCATACCACCTTAGGCACGCCCGATCTCGTCTGATCTCGGAAGCTAAGCAGGGTTGGGGCTGGTTAGTACTTGGATGGGTGACCGCCTGGGAATACCAGGTGCTGTAAGCA
->XR_008382064.1 PREDICTED: Nycticebus coucang U6 spliceosomal RNA (LOC128592852), ncRNA 
-GTGCTTGCTTCGGCAGCACATATACTAAAATTGGAATGATACAGAGAAGATTAGCATGGACCCTGTGCAAGGATGACACGCAAATTTGTGAAGCGTTCAGTATTTTT
->XM_035287433.1 PREDICTED: Callithrix jacchus URI1 prefoldin like chaperone (URI1), transcript variant X4, mRNA 
-TCTTTATCAATGTGTCTGTCTCTTTACTGATGCCACTCTGTTTTGATTATGTAGCATTATAGTGTTCCTTAAACTTGGTGGTACAAATGCTCTAATTTGTTCTTTCCAAATTGTTTTGGCTGTTCTACCCCCTTTGCCTTTCCATTTTAGAAACCACTTGTTTATGTTTACAAAAACTCCTGGTGGGATTTTGATTGGAATTACGCTAAATCAATACATCAATTTGGGGAGAATTGACGTCTTAACTAATGTAAGAAAAACAATAGAGGATTTAAGAAAAGTGGTGAAAAATTTTGAATCAAGAGTTGAATTCACAGAAGATTTGCAGAAAATGAGTGATGCTGCAGGTGATATTGTTGATATAAGAGAAGAAATTAAATGTGACTTTGAATTTAAAGCAAAACACCGAGTTGCTCATAAACCACATTCCAAACCAAAAACTTCAGATATTTTTGAAGCAGGTATTGCAAATGATATGAAATCTAAGGATTTGCTTGCTGATAAAGAACTGTGGGCTCGTCTTGAAGAACTAGAGAGACAAGAAGAATTGCTGGGTGAACTTGATAGTAAACCTGATACTGTGACTGTAAATGGAGAAGATACGACATCTTCTGAAGAAGAAAAGGAAGATCACAACACAAATGTGAATGTGATGCATCAAGTAACAGACTCTCATACTCCGGACAGTTGTCATAAGCATGTGGCAAGTTCAGAACCATTTAGTGATCAGTTGAATAGTCAGTTGAACTGTTCAGTGAATGGTTCCAGTTCTTACCACAGTGATGATGATAATGATGACAATGATGACGATGATGATGACGACGACGATGGTGATGATGAGCATGAGGCTTTAGGAGTTGGATATAATTCTATACCAACAATATATTTTTCTCATACTGTTGAACCTAAGAGGGTCCGAATAAATACTGGAAAGAATACCACTTTAAAATTCAGTGAAAAGAAAGAAGAAGCCAAACGTAAACGAAAGAACAGCACTGGCAGCGGCCACTCTGCCCAGGAGCTGCCCACCATCCGGACACCTGCTGACATTTACAGAGCCTTTGTTGATGTTGTGAATGGAGAATACATCCCTCGCAAATCCATCCTGAAGTCTCGAAGTAGAGAGAACAGTGTGTGTAGTGACACCAGTGAAAGCAGCGCTGCTGAATTTGACGATAGGCGGGGCGTTCTGAGGAGTATCAGCTGCGAAGAAGCCACTTGCAGTGACACCAGTGAGAGCATTTTGGAAGAGGAACCACAGGAAAATCATCAAAAGAAACTTTTGCCCTTATCGGGAACACCTGAGGCTTTTTCTGGAACTGTTATAGAAAAAGAATTTGTATCACCTTCCTTAACACCACACCCAGCCATTGCTCATCCTGCGCTACCCACTATTCCAGAACGAAAGGAAGTTCTGTCGGAAGCCTCAGAAGAAACTGGAAAGAGGGTTTCAAAGTTTAAAGCTTCCAGATTGCAGCAGAGAAACTAGGCCCTGTGTAGGAAATGGGAATTTACATCTTAAAACCTAGTTGTTCATTTGTTTAGAATATCGATAGCAAAATAGGTTACGTGTAGTTTGACATAAGGTATCCCGAGTTACTTTGGCAACAAGTTCTTTTACCCTTACCAGCGGTATTTGAAAAAAATCACAGTAACTGTCTGAATACTTTAATATTCGCCTTGTTTTGTTAGTTCTCTGAATACTGTCAACACTTGTCTGAGTTTGCCTTTATGATGCAGTGGCAGCATTTTGAATTACTTTTCGAAGAATACTGTTCATACGCATTGTTTTTGTGTTTCAGACGAAATACAGGCAGTTTTGTGCCAGCTGTGATATTGTGCATACCATATGGACCCTTTTAAAGAAAATTTTTAAATTTCAAAGAGATTCAACAATTATATTACTTGCTTTTACATTTTAAAGGCACTTTAAAAAAGATCTACTTCGCCTGTAGGTTTTGCAGCTAGTGGGCTATTTAAGAAACCTCTCCCCTCTAAATGTCATACTGTAATCTATCAGAAAACTACATGAGTTAATTGTACTCTATGGAAAATTTCTTTGGAAAGATATTTTGTAAAACTTTTTTTTTTTTCCAAGTAAAAATTTTATGAAACTTGGTCTCAAAAATGTTGTGAACTTTATGATTCAAAATTAAGTCTAGATATGTCCTCGATTCATGATATATGCTACATGTATCACACAACAGATCTGCAATTCTTTCACTTCCCTGGACGCTTCTCCCTTAGTTTCTGCAGTTTCATTGGGGTTATGTTTTGGGAGACGAGGAAACGTCTAGATGCTTAAAAACGATTTTAAATAAAAATTCCTTACAGTTGAAA
->XM_003139612.1 Loa loa hypothetical protein partial mRNA 
-ATGCGGTCTTCGACTGTTCCGTTATCAATAGTATTGGTGTGGTGCATCTACTACAAACTGAGTTGTGCAAAACAGTCAGAACTTGCGAATAATATGCAAATTTCTAATGTATTGAGTGAAAACGACGCTCAAAGCACCGAATTTGTTCGCACAGCTTGGAGCGCTGCAACTTATTCGAAACTCAGAATTTACAGAGAGTTTTTAATTATCTTCCTTGATAAAAAATCCATGAGGGTTCTGAGAACGAGTTGCTTCTTGCTGGAATTTTTCAAATTACATGTATGGAAACGTGCTTTCGGTAAAATCGCACTAGACATTACTTTTGGTCGAAATGCACAAATATCTATTTGGTTTGAAATGAAAATTTCTAAGCTTTCCAGTCTGCAATTAATTCTTAGAAAATTGCAAGAAGAATAA
->LC592336.1 Uncultured archaeon gene for 16S rRNA, partial sequence, clone: m5-3 
-GCGAGAAACCTCCGCAATACACGAAAGTGTGACGGGGTTACCCAAAGTGTTCATTAGAACTGTGGTAGGTGAGTAATGTTCCCCACTAGAAAGGAGAGGGCAAGGCTGGTGCCAGCCGCCGCGGTAAAACCAGCTCTTCAAGTGGTCGGGATAATTATTGGGCTTAAAGTGTCCGTAGCCGGTTTAGTAAGTTCCTGGTAAAATCGGGTAGCTTAACTATCTATATGCTAGGAATACTACTATACTAGAGGGCGGGAGAGGTCTGAGGTACTACAGGGGTAGGG
->XR_004309533.1 PREDICTED: Coturnix japonica uncharacterized LOC116654348 (LOC116654348), ncRNA 
-CTTGCTTTTTGCCTTTAGCCTTTCTATGAGTCAGGAGACAGCAGGCTGCTTGCAAGTATAGGCTGGGGCTGGTTTTTTCCCATTTATTTATTTATTTTCCTAGGAAGAATGAAGAGCAAATAATGAGGAGGAAGAATAGATGATGAACCCAAAGATGAGCACGAGTTCCTGGGCTGGTTCTGACCCATCTAAGGGGTCCTGACTCTTAGGATCCTTTGGGGTTGGAGCTCACACATCCTGCTGCTTGTTGATGGAGGAACGATGACCCCATGTGAGTACTGCAGTGCCATACAGCCCTATTTGGGTGCATGGAGAGGCCAATTCGGCTGCAGCAGCAGTGAGAAAGCTGCAAGGTGCTGAGCTCTCTCCTGCCCTGGAGCAGCCCAGGGGATGTGGGGGCAGTCAGTGGCTGTTTTGGGGCTGTGCTGGGTGTGTTTTGGGGCTGTGCTGGCTACAAGCCTCGCTTCTATCTGCAGGCCAGCAGGCAGCATGTGATGCTGTGATGCTCACCAGCTCCAGCCAAGGGGAAAAGCCCCTTCAGCACAGGAGCTGCTGGCAGGGTGCCTGGCTGCACCGTGCCTGGCACCAGCAGTTCGGTGCCCCTCAGTGCAAAGCCTCCATCTGCTCCCCATCCTTCCCCCCCACCATGGGATGGGACTGAAGGTGGCACAGCCCCTGAGCGCTGTGCCTGCCCAGTCCCAAAACGCAATGTCACCAGGGCTCTGGGACAACCCTGCCGTGTTTAAATCCTCTTCCTAGGGGCAGCCGGGGCTGCAGACCCCTCAGGACGGCTACAGAGGCAGCAGCGTATCGCACCTTCAGCCCTCGGGGCTGCGAGCAGTCGGGTTGGAGCTGGAGCTGGCGAGCTCTCAGCACCCTCTGCCGGCTCTGCTGCCCGGCCCCGGCCCCTCCTGCTTGGGATGGAGCCTCTGTGAGCTCTAAGCTGCTGCTCTGCTTTGCTCTGCTCCCATTCTACAGCCCTGAGCCCAATAGGGGCCGTCACCCTCTGCCCTCGCACTGAGTGCTTTGCGCCCTGGGTTGAGCTGATGACTGCAGTGCTTGTGCTGAGGGTACGGGAAGGGGCCCAGCAGCCTCTCGATGTGGCTTTTCTCTGCTGTGAATGATCCCAAATAGCATCTCTGTGCTGTAAGGCAGCCCTGGGCTGACAGCAGTCTGTGCTGATGTACACGTATGGGGTATTCATGGGGCGGAAAAAGGCTGCTGCTCAAACAAGCAAACATTGACTGTCTGGTTTCCCAGCGCTGCCCCCAGCAGCAGCTTTCACATACCCTGCAGACATTCCTGCTGCTGGGCTCCCATCACCGGGCAGGGAGGAACCCCCACACTGCCTGCAGCAGCCCCTCTGACCCAGGAAAGCAAAGGGAAACCAGTTGACGTCGGGATTCTTTTAATGCAACAGCTCTTAAAATGCAACCTTCAAATGATTTTTATAATGGTCAACAATGAGAAACATCTGAGCTTTTCTACCTATGCACCCCAAACCCTTTGGGTGGAGGACTCCCTTGGGCAAAAAGGGTGAGGACAGTGTTCACATGGAGGCCCCCAACAAATGGCAGCACAACCTGGACCTTCCTCTCTCACACTTTACACTCAGGCACAAACCTACAAAGGCATCCAGCCCATCAGCTCCCCTCTTGTAGCACTTCAGACAACAGCTTCAGGCTCCTGGTTCTCTCTGCAGGTTTGTGCCTTCATGCTACGTAAAGCGATTTGAGAATGAATATCTGACTGTTTTCTGCCTTGATAGGATGGTGGTGGAGGAAGCTGATTTCCCATCACCTTGCTTTGTATGATATAATGCTACTTTATGCCTTTGTTCTGCAGAGCAGCAGGTGTTACAGGCTGCCACAGCTCGCCAATTCAAGTAACGTGGGAAATTCTGCTCCAGCCTAAACATCTGTGTAAGAATATCCCCCCACCGCCCCCTCCGCATCGTGCAGTGTTTATATGCTGTAACAGGAGAGCAGGCAATACTTGCTGAAACACATTTAATACCTTCCAGTTGTTAGTCTCAGTTTCTGGTTCTGTGCAGTCAGCACACAGCCCTCGGGCTGCGCGTGCTGCAGAATAGCAATGCTGTTAGAGCTGTGAGTGCCTTTCTCCCATCTAAAATGCTCAGTGGTTTTCTTGTACCATTTACTGGCTCTGCCCTTCCAAGAGGGGAATGGTGAGACTACACACAACGTCCTGTTGGAGGAAGGTGATGCTGTGTCTGCTTTCATCAATGCTGTGAAGAGAAACAGCAGAAAGAACCACGAGGGTCTCCTGAATCTCAGTGCTGTGTGATGCTTTCCTCCCCTTCGTGTCAAGCCTGTATTTTACTACTACCAACTACAGAAAGCTACTTTGGTCTACAGAAATGCTATGCACTTATCTCCAAGTGAATTCTAACCAACCCTTCTTAAGGACAGCAGTTAACAGTAAGTCAGTGGGTTCTTTTGCCTTAGTCTCCAATACGAGTTATAAAACCTGGATTCAGGTTTGGACAGACTGGAGCTCTTTTAGAGTCTGAGCAGCAGCTCTTGCACAACCAAAGGTCACAATTAGAAACTGAGTGTAGAAAGAGTTCCCAGGGGG
->XM_006448447.2 PREDICTED: Citrus clementina protease Do-like 10, mitochondrial (LOC18050602), transcript variant X1, mRNA 
-TCATCAAAAGATTCAAAACCTAACAAAAGCGTTTTCCTTCTGATATTTTTGCCTGCAGCTTTGGATTAAGGCAAAAACCCAAAGCCGAAGGCAAAAAGAAGAAATGCAAATGCTGCTGGGTCCGTCACTGCGTAGTCTACGAAGGCAGCTATGGTCCTCTTCATCCTCTATTTTCTCCAATTACAGTAGTATTAATAGCAGTGGCTTATTAGAAACCTTCTCCAATACATTAAGATTAATTATTTTGCCTTCTACCTCTTCACTCTCCACTATTAGTACTAAAAATTGTAATTTTCACTATTTTTCAACATCAGCAGCAGTAGCTGCTAATTTGAGTACCAAGGAAATTGTTTCTAAAGTTACGCGACGGCGACAACGACGTCGTTTAGCTAAAACCTGCGGAAAGACTACTAATGCTTACGCAGCAATAGAGCTTGCTTTGGATTCTGTTGTGAAAATATTCACAGTTTCAAGCAGCCCTAACTATGGACTTCCCTGGCAGAACAAGTCCCAACGAGAAACCACCGGTTCAGGATTCATTATCCCTGGAAAAAAGATTCTTACAAATGCTCATGTGGTGGCTGATAGTACATTTGTGCTTGTAAGAAAGCATGGTTCTCCAACCAAATACAGAGCCCAAGTTGAAGCTGTGGGTCATGAATGTGACTTGGCTATTCTGATTGTCGAGAGTGATGAATTTTGGGAGGGAATGCATTTCTTAGAGTTAGGAGACATTCCGTTTCTTCAACAAGCTGTCGCTGTTGTTGGATATCCTCAAGGTGGAGACAACATTTCCGTTACGAAAGGTGTTGTTTCGAGGGTTGAACCTACACAATACGTACACGGTGCTACTCAGCTCATGGCAATACAGATTGATGCTGCTATTAATCCTGGCAACAGTGGTGGTCCAGCCATCATGGGCAATAAGGTTGCAGGTGTAGCTTTTCAGAATCTTTCCGGTGCTGAAAATATAGGTTACATTATCCCTGTTCCTGTAATAAAGCATTTTATAACTGGTGTGGTGGAACATGGAAAATATGTTGGATTTTGCTCGCTGGGACTATCATGCCAGACCACTGAGAATGTTCAACTTCGTAACAACTTTGGAATGCGGTCTGAAGTGACTGGGGTACTTGTGAACAAAATTAATCCTCTGTCAGATGCTCACGAAATATTGAAAAAGGATGATATTATTCTTGCATTTGATGGTGTGCCTATAGCAAATGATGGAACAGTTGCTTTTCGTAACAGAGAACGTATAACATTTGATCACTTGGTGTCTATGAAGAAACCCAACGAGAAGTCTTTGGTTAGAGTTTTGAGGGATGGCAAGGAGCATGAATTCAGTATTACACTACGACCTCTGCAATCACTAGTTCCCGTACATCAATTCGATAAGCTTCCTAGCTATTACATATTTGCTGGCCTGGTGTTTACTCCACTTACACAGCCATATCTTCATGAATATGGAGAAGACTGGTATAATACTTCGCCACGTCGTTTGTGCGAACGTGCATTAAGGGAGCTGCCTAAAAAGGCTGGTGAACAACTCGTTATCCTTTCGCAGGTGCTGATGGATGATATAAATGCCGGGTACGAGCGTTTTGCAGACCTACAGGTTAAGAAGGTCAATGGGGTGGAAATTGAAAATTTGAAGCATTTATGTCAGCTAGTGGAAAACTGTAGCACTGAGAACTTGAGGTTTGATTTAGATGATGATAGGGTTGTTGTATTGAACTATGATGTGGCAAAAATTGCCACATCTAAAATTTTGAAGCGTCACAGAATACCTTCTGCTCTGTCCGGTGATCTTAACGGTGAACAGATCTCCGAAATTGAGTTAGCTTCCAGACATAAAGAATGGTCACAAAGTTGAGGGCCCTGAGCCGGCTAATATTAAAATTTTGGTTTCCTAATCCACTTAGCTGCTTTTATTATTTGTCATTTATAATCGGATGTTGAGGTGCAAACACATTTTTGGCCTTTGTGTATTGTAAGCGATTCAGAGTATTAAAACCAAAAAGCGTTCTGTTGTTTGGTAAA
->XM_037730203.1 PREDICTED: Cebus imitator glycosylphosphatidylinositol specific phospholipase D1 (GPLD1), transcript variant X3, mRNA 
-GAGACTTGGTTTCCTGGGTCAGTGACCTGCTTAGAGGGAAGCAGCGGGTCTGCGCCTGGATTTCGGAGTCACGGTGCTGCTGCAGCTCTGAGCATTCCCACGTCGCCAGAGAGCCCGTGGGGAAGGAGAGCATGTCTGCTTTCAGGTTGTGGCCGGGCCTGCTGATCGTGCTGGGTTCTCTCTGCCGTAGAGGTTCATCCTGTGGCATTTCAACGCACGTAGAAATAGGACACAGAGCGCTGGAGTTTCTTCAGCTTCATAAAGGGCGTGTTAACTACAAAGAGCTGTTGCTAGAACACCAGGATGCATATCAGGCTGGAACCGTGTTTCCTGACTGCTTTTACCCTGGCATCTGCAAAGGAGGAAAATTCCATGATGTGTCTGAGAGTACTCACTGGACTCCGTTTCTTAATGCAAGCATTCATTACATCCGAGAGAACTATCCTCTTCCCTGGGAGAAGGACACAGAGAAATTGGTAGCTTTCTTGTTTGGAATTACCTCTCACATGGTGGCAGATGTCAGCTGGCATAGCCTGGGCATTGAACAAGGATTCCTTAGGACCATGGGAGCTATTGATTTTCACGGCTCCTATTCTGAGGCTCACTCGGCTGGTGATTTTGGAGGAGATGTGTTGAGCCAGTTTGAATTTAATTTTAATTACCTTGCACGACGCTGGTATGTGCCAGTCAAAGACTTACTGGGAATTTATGAGAAACTCTATGGTCAGAAAGTCATCACCGAACGTGTAATTGTTGACTGTTCACATATCCAGTTCTTAGAAATGTACGGTGAGATGCTAGCTGTTTCCAAGCTGTATCCCAGTTACTCTACAAAGTCCCCGTTTTTGGTGGAACAATTCCAAGAGTATTTTCTTGGAGGACTGGATGATATGGCGTTTTGGTCCACGAATATTTACAATCTAACAAGCTTCATGTTGGAGAATGGGACCAGTGACTGCAGTCTACCTGAGAACCCTCTATTCATTGCATGTGGCGGCCAGCAAAACCACACCCAAGGCTCGAAAATGCAGAAAAATGATTTTCACAGGAATTTCACTACATCCCTAACTAAGAATACTGAGAGGAATATAAACTATACTGAAAGAGGAGTGTTCTTTAGTGTAGATTCCTGGACCCCGGATTCTGTGTCCTTTATGTACAAGGCGTTGGAAAGGAACATCAGGACCATGTTCGCAGGTGACTCTGAGCTGTCACAGAAGCACGTCTCCAGCCCCTTGGCCTCTTACTACTTGTCGCTTCCTTATGCAAGGCTTGGCTGGGCAATGACCTCAGCTGACCTCAACCAGGATGGGCATGGCGACCTCGTGGTGGGCGCACCAGGGTACAGCCGCCCCGGCCACGTCCATGTCGGGCGCGTGTACCTCCTCTACGGCAGTGGCCTGGGCCTGCCCCCCATCGACCTGGACCTGGACCAGGAGGCGCACGGGATCCTTGAAGGCTTCCAGCCCTCAGGTCGGTTTGGCTCGGCCTTGGCGGTGTTGGACTTTAACCAAGATGGCGTGCCTGACCTGGCTGTGGGCGCTCCCTCCGTGGGCTCCAACCAGCTCACCTACAAAGGTGCCGTGTATGTCTACTTTGGTTCCAAGCAAGGAAGAATGTCTTCTGCCCCTAACATCACCATCTCTTGCCAGGACGTCTACTGTAACTTGGGCTGGACTCTGCTGGCTGCAGATGTGAATGGAGACAGTGAGCCTGATCTGGTGATTGGCTCCCCCTTTGCCCCAGGCAGAGGGAAGCAGAAGGGAATGGTGGCTGCGTTTTATTCCGGCCCCAGCCACAGCGACACAGAAAAACTGAACGTGGAGGCGGCCAACTGGACGGTAAGAGGCGAGGAAGACTTTGCCTGGTTGGGATACTCCCTTCACAGCGTCACCGTGGACAACAGAACCTTGCTGCTGGTGGGGAGCCCCACCTGGAGGAATGCCAGCAGGCTGGGCCATTTGTTACGCATCCGAGATGAGAAAAAGAGCCTTGGGAGGGTGTATGGCTACTTCCCACCAAACAGCGAGAGCTCGTTTACCATTTCTGGAGACAAGGCAATGGGGAAACTGGGTACTTCCCTGTCCAGTGGCCGTGTGCTGATGAACGGGACTCTGACGCAGGTGCTGCTGGTTGGGGCCCCAACACACGATGACGTGTCTAAGATGGCATTCCTGACCATGACCCTGCACCAGGGCGGAGCCACTCGGATGTATGCGCTCACACCCGCTGCACAGCCCCCGCTGCTCAGCACCTTCAGTGGAGACCGCCGCTTCTCTCGATTTGGTGGCGTTCTGCACTTGAGCGACCTGGATAACGATGGCTTAGATGAAATCATCATGGCAGCCCCCCTGAGGATAGCAGATGTAACCTCTGGACTGCTTGGGGGAGAAGATGGCCGAGTTTATGTATATAATGGCAAAGAGACCACCCTTGGTGACGTGACAGGCAAATGCAAATCATGGATAACTCCATGTCCAGAAGAAAAGGCCCAATATGTATTGATTTCTCCCGAAAACCAAGTCGTCATTGCTGCTGGAAGGAGTTCTTTGGGAGCCCGACTCTCTGGGGCACTTCATGTCTACAGCCTTGGCTCAGATTGAAGATTTCCCTGCACCTCTCCACTCTGCCCCCTTCTCTCAAGCTGAATCACATCCATGGTGAGCATTTTGGTGGACAGAGTGGCATATCCAGTGGAGCTATGGTAGATCCT
->XM_003291721.1 Dictyostelium purpureum hypothetical protein, mRNA 
-ATGAATGAGCTATTATCATCTCTAATTAACTTTAGTGTAAAAGAAGAATTAAAAAACAGTAGTAATATTAGTGATAGATTATTATATATAGTTTGGAATAATATATTTTTAAGAAATGAAATTCATAAACATATTTTAAAGTTTATTGAATATAGTGTTGTAGATTTTGAAATATCACAATATGACCAGTTTAAAGATAAATCATATATAACAACACTTAATTGGTTTGGTGATACACTACCTGATAAAAATGAATTTCCACCATTTTTGACAAGTTTATATTTGCCCCATTTTTCTGAAAAGTTAACTCCAACAACTTTACCAAATACAATAACTACACTCACGCTCGGTCATTATTTTAACCAAGTAGTTCTACCCGGCACATTACCAAATAGTCTCACAACACTCACATTCGGTGATGATTTTAACCAAGTAATTCTACCTGACACATTACCAAATAGTCTCACAACACTCACATTCGGTTATAATTTTAACCAAGTAATTCTACCTGACACATTACCAAATAGTCTCACAACACTCACATTTGGTTATAATTTTAACCAAGTAGTTCCACCTGGTACATTACCAAATAGTCTCACAACAATCACATTCGGTCATTTTTTTAACCATATAGTTCCACCTGGCACATTACCAAATAGTCTCACAACACTCACATTCCGTAGTAAATTTAACCAAGTAGTTTTACCCGGCACATTACCAAATAGTCTCACACAACTCACATTCGGTTATTATTTTGACCAAGTAGTTCTACCCGGCACATTACCAAATAGTCTCACAACACTCACATTCGGTCATCGTTTTGACCAAGTAGTTCTACCCGGCACATTACCAAATAATCTCACAACACTCACATTCGATAAAGCTTTTAACCAAGTAGTTCCACCTGGCACATTACCAAATAGTCTCACAACACTCACATTCAGTTATTTTTTTAGACAAGTAGTTTTACCCGGCACATTACCAAATAGTCTCACAACACTCACATTCGGTCATCATTTTAACCAAGTAGTTCTTCCCGGCACATTACCAAATAGTCTCACAACACTCACATTCGGTAATTGTTTTGACCAAGTAGTTCTACCCGGCACATTACCAAATAGTCTCACAACACTCACATTCGATCATCATTTTAACCAAGTAGTTCCACCTGGCGCATTACCAAATAGTCTCACAACACTCACATTCGGTTTTTTTTTTAACCAAGTAGTTTTACCCGGCACATTACCAAATCGTCTCACAACACTCACATTCGGTGGTAAATTTAACCAAGTAGTTCTACCCGACACATTACCAAATAGTCTCACAACACTCAGATTCGGTTATGAATTTAACCAAGTAGTTCCACCCGACACATTTCCAAATAGTCTCACAACACTCACATTCGGTCATCGTTTTAACCAAGTAGTTCTACCCGGCACATTACCAAATAGTCTCACAACACTCACATTCGGTTATGATTTTAACCAAGTAGTTCTACCCGGCACATTTCCAAATAGTCTCACAACACTCACATTCGGTAATGATTTTAACCAAGTAGTTTTACCCGGCACATTACCAAATAGTCTCACAACACTCACATTCGGTTATGATTTTAACCAAGTAGTTCCACCTGGCACATTACCAAATAGTCTCACAACACTCACATTCGGTCATCGTTTTAACCAAGTAGTTCTACCCGGCACATTACCAAATAGTCTCACAACACTCACATTCGGTGATGATTTTAACCAAGTAATTCTACCTGACACATTACCAAATAGTCTCACAACACTCACATTCGATAATGAATTTAACCAAGTAGTTCTTCCCGGCACATTACCAAATAGTCTCACAACACTCACATTCGGTTATTGTTTTAACCAAGTAGTTTTACCCGGCACATTACCAAATAATCTCACAACACTCACATTCGGAACTAAATTTAACCAAGTAGTTCCACCGGGCTCATTACCAAATAGTCTCACAACACTCACATTCGGTCGTGATTTTAACCAAGTAATTCTACCTGGTACATTACCAAATAATCTCACATCAAAACTCTCAAAGATTGTTTAA
->HQ115669.1 Trichoderma koningiopsis isolate NG_05 18S ribosomal RNA gene, partial sequence; internal transcribed spacer 1, 5.8S ribosomal RNA gene, and internal transcribed spacer 2, complete sequence; and 28S ribosomal RNA gene, partial sequence 
-AGGGATCATTACCGAGTTTACAACTCCCAAACCCAATGTGAACCATACCAAACTGTTGCCTCGGCGGGGTCACGCCCCGGGTGCGTCGCAGCCCCGGAACCAGGCGCCCGCCGGAGGGACCAACCAAACTCTTTCTGTAGTCCCCTCGCGGACGTTATTTCTTACAGCTCTGAGCAAAAATTCAAAATGAATCAAAACTTTCAACAACGGATCTCTTGGTTCTGGCATCGATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTCTGAACGCACATTGCGCCCGCCAGTATTCTGGCGGGCATGCCTGTCCGAGCGTCATTTCAACCCTCGAACCCCTCCGGGGGGTCGGCGTTGGGGATCGGGAACCCCTAAGACGGGATCCCGGCCCCGAAATACAGTGGCGGTCTCGCCGCAGCCTCTCCTGCGCAGTAGTTTGCACAACTCGCACCGGGAGCGCGGCGCGTCCACGTCCGTAAAACACCCAACTTCTGAAATGTTGACCTCGGATCAGGTAGGAATACCCGCTGAACTTAA
->XM_026575105.1 PREDICTED: Papaver somniferum aspartic proteinase CDR1-like (LOC113328005), mRNA 
-ATGAGTCGGAAAAATGTTGTTTCTTCTTCCATCAATTTTGTAACAGCAGTTGTTTATGTTTCATTTCTACTAAACTTGGCCACTGCAGTTAAACCAAGAGGGTTTAGCATGAAGATGATTCGCAGCGACTCTAAAAAATCACCTATGCATCTAAGGTATGCTAATTTAACTCAAGAAGAAAGATTTCAAAGACTCGTCGAACAATCCAAAGCTCGAGCGCGTTACTTTGCATCCGCAAGAGCTGCTGCTTATAATAGAAGCATCTCCATGAATCCCGATATTGCACGTATACGTCTAAAATACATGGAGAACAGACACTATTACATCGGTGAGGTAGGTATAGACGGGCTCTGTACGTACAAAGAAGGATACATTTCCGGACCAAAAATATCTGGTCATCTTGCTTATGAAACACTCACTATGAAGTCAAACACCGGTGCCCTTGGAAGTGTTGAAAAAATAGTCATGGGCTGCGGTATTGATCAAAGGAATTTCGGACCATTATTTGGTGTTCCTGAGATTCGTGAAGGCATTGCGGATTCACACACGTATTTAAGATTTGGTTTCGACACAATAATTGAAGAAGGACCTCCTAATGAAATACTTACAACTCCAATAATTCAAGACCCGAACTTCGGGACGCCTTACCATTTGATTCTTAAGGATATCAGTATAGGTAACAGAAGCGTAGGGTTTCAACAAAGTGATTTCGAGCTAAAGCCGGATGGAACTGGTGGGACTATCATAGATTCAGGGGCTCCATTTACCACCATGAGGATGCGCCATTTTGAAAGAGTTGAGCAAGTGCTGGTAGAATATTTTACAGATTCTGGTATTCGTCCTGCTGATCCTGAACCTGGCAGAGATTTCGATACTTGTTTTGATATACCGGTCGATTTCACTGCGTTTCCGGTGATGACATTTCATTTTCAGGATGCGGATTTTGTTATTCAACACTGGTCTGCCTATTACATACAAGAGCGCTTGCTATGTTTTGGTATCATTGGCTTGAATGACGACGATCCAAATGATGTTACTCTTGGAGCTATGCAACAAGCTAATAAAAGGATTTTACACGATCTTCATGCCAAGGTACTCAAGTTTACTGATGAGAGATGCGATGATGATGGTTCGTGA
->XM_050131643.1 PREDICTED: Microtus fortis GEM interacting protein (LOC126494357), transcript variant X3, mRNA 
-ACCGCTCCTTAGCTCTTAACCCAGGGAAGTCCCACTTACTCCTGAGCTACCTGACAGCCGGGGAAGAAATCCTGGCAAGGGAAGGACAGGAAAGGTCTGTGCACCTTGGAGACTCCTGAAGCGCACAGGGCGCACGACTCCTGCCCCAACCCTCCGATTGCCCTGCAGAGCCGGCACCCCGGATGCCTGGGGGGAAGGGGCCCAGGAACGGGAAGTGGCCGCTTCTGCTTATTATACTATGGATGGGGGCAGGGTGTCAGGGCCAGGATCCCTGCAGGGCACCCCGGGCGGGGGTGGGGGCATAAAGCTAGAAAGTGGCGGCAGCAGAATTGTGACTAGGTCTAGGTTATGTTTCCAGCTGTCTTTGTGTGTGTGTGTGTCATTCAGTCCGGTTCCTCATGGTTTCAGCTGTACTCGCGTGTGTTTATGCCGCAGGCTAAGTGCCTGTGCGTCCCACGTGCGGTCCCATCTGTCTGCCCTGGGGTCCATGTGGCTCCATTGTCAAGCCAGGCCTCTACTCCATCACTCATGTGGCAGCTGCATCTGTATTCTTGCTTTGCCTATGGGTCCCTGCCTGTGTGGGTGTCTCTGTGACTGTGAGCAACCGCTTCTCTGATTTTGCCGGGGCCCATCTGTCTGGTCTGAAACAACCCCTCTGAAGCTCACTGTCCCGTCCCACACTAGTCTTAGATCAAAACTCACTTAGGTCTCTGTTTCTATCTCGCTTTCTCCCTCTTCCTTCCATCTCTGCTTGAGAGTGGTTGAGGTGCTTTGCTGCCTCCAAGGGTAGAGGGAGGGAGACAGTGAGTGGTTGGTTCATGTTTTCTTGCACTTCTCTCCCCCCAGAGCTGACCCCAGCTCCTGAGGGCAGGAAGAGGTACAGTGACATCTTCCAGAGCCTGGACAACCTGGAGATATCGTTGGGGAACGTGGCTTTCGACCCCTTGGCTGGAGACCTTGTACTCAGACAGGACCTGGAGCCTGACAAGACTGCCACAGCCGCGGTGAGCAGTGAAGCCAGATGGAGTGATCCCTCCCCAGAGGGTCCCGTACCCCTCACAGAGGAAGAACTAGATTTGCGACTCACTCGGACGAACGGTGGTGTGGATGCTGCCCTGGAGTATGCCAAGGCATGGAGCCGCTATGCCAAGGAGTTGCTGGCCTGGACAGACAAGAGGGCCAACTACGAGCTGGAGTTTGCTAAGAGTGTCATGAAGATCGCTGAGGCCGGCAAGGTGTCCATTCTCCAGCAGAGCCAAATGCCACTCCAGTACATCTACACCTTGTTTCTGGAGCATGACCTCAGCCTGGGAGCCCTGGCCGTGGAAACGCTGGCCCAGCAGAAGAGAGACTACTACCAGCCTTTAGCAGCCAAAAGGATGGAGATTGAGAAGTGGAGAAAGGAATTCAAGGAGCAGTGGCTGAAGGAGCAGAAACGCATGAATGAGGCGGTGCAGGCACTACGGCGCACCCGGCTCCAGTACATTCAACGCAGAGAGGACCTTTGGGCACGTTCCCAGGGGTCCCCTGAGGATCCTCCTCCCCAGGCATCTCCCGGATCCAGCAAGCAGCAGGAGCGCAGACGACGCTCCCGAGAGGAGGCACAGGCCAAGGCACAGGAGGCAGAGGCTTTGTACCAGGCCTGCATCCGAGAGGCCAATACGCGTCAGCAGGATCTGGAAACCACCAAGCGGCGGATAGTGTCACATGTACGCAAACTGGTGTTGCAAGGAGACGAAGTACTTAGGCGGGTGACGCTGGGCCTGTTTGAGCTGCGAGGGGCACAGGCAGAGAGAGGACCTCGAGCCTTCTCAGCTCTGGCTGAGTGCTGTGCGCCCTTTGAGCCTGGCCAGCGCTACCAGGAGTTTGTGCGGGCACTGCAGCCTGAGGCCCCGCCACCGCCGTCTCCCGCCTTCTGCTTCCAGGAGTTCACGCCTGTGCTACACAGTTCCCCTCAGGACACAAAAAAGAAGTTTTTGGGGCCTCCACATGCCAGGCTGGAGGAGGGTTACTCTGAGCCTGGCCCTTGGGAGGATACCAGCTCAGGCAGCCAGGGCCCCACTCCAGTCAGTGATGTGGACAGTGTAGGTGGTGGCAATGAATCCCAGTCCCTGGATTCCCCTACTTCCAGCCCAGGTGCTGCTACTCGGCGGCTTGTGAAGGTGTCGTCTATAAGCACTGAGTCCTCTGATGACTTTGAGGAACGAGACCCTGATCTGGGGGATGGGATGGAGAATGGACTAGGCAGCCCCTTCAGGAAGTGGACACTGTCCACAGCTGCTCAGACCCACCGGCTACGGCGGCTGCGTGGTCCAGCCAAGTGCAGAGAATGTGAAGCCTTCATGGTCAGCGGGACAGAGTGTGAAGAGTGCTTTTTGACCTGTCACAAGCGCTGTCTGGAGACCCTCCTCATCCTTTGTGGACACCGACGGCTTCCAGCCCGGATGCCTCTCTTTGGAGTTGACTTCCTACAACTCCCCAGAGACTTCCCTGAGGAGGTGCCCTTTGTGGTTACCCGGTGCACAGCTGAGATAGAACATCGCGCCCTGGGCCTGCAGGGTATCTATCGGGTCAGTGGGTCTCGAGTGCGTGTGGAACGACTGTGCCAGGCCTTTGAGAATGGCCGAGTGCTGGTTGAACTGTCGGGAAACTCTCCTCATGATATCACCAGTGTCCTCAAGCGATTTCTTCAAGAGCTCACTGATCCCGTGGTCCCCTTCCACCTCTACGACGCCTTCATCTCTCTGGCAAAGACCCTGCATGCAGACCCCGGGGACGACCCTGGAACCCCCAGCCCCAGCCCTGAGATTATCCGCTCGCTGAGGACCCTCTTGGTGCAGCTGCCTCCCTCTAACTACAGCACTGTGCGGCACCTGGTAGCCCATCTGTTCAGGGTGGCTGCTCGTTTTGAAGAAAACAAGATGTCTGCCAACAACTTGGGAATTGTATTTGGGCCTACGCTGCTGCGGCCACCAGATGGACCCAGGGCCCCCGGAGTCAGCCCTGTGGCCTGTCTGCTGGACTCTAGTCACCAGGCTCAGCTTGTTGAATTCCTCATTGTGCACTATGAGCAGATCTTTGGAATGGATGAGCTCCCTCTGGCCTCTGAGCCCCTGACCCAAGATCCTGGCCTGGCTCCCACACTCCTCGAATCCAGTCCTCAGCACCCAGCCCCACTTCTTGCCCAAGACATACAACCCCTGACCATAGCCTCAGACTGCAGCCCAGATCCCAAACTCCACAGTGCCCCGGAGAAGTGTCTGGAGGTCACACCTTCTGAGGTAATTGCAACTCTGCAGAGGGACCAAAGGGAGGAGAAGGAGGTGGAAAACACCAGAGATGGGGCAGGGGAAGGGTCCGGCCACAACCCTGAGGACTTGCTCCTGGGAACACAATCCCGGGGCCACTTCAGTCGCCAGCCAGTGAAGTATTCACGGGGAGGTGTACGGCCAGTCACTCATCAACTGTCCAGCTTGGCTCTGGTAGCTTCCAAACTGTGTGAGGAGACTCCTGTTACTGTTTCAACAGTGCACCGAGGTAGTTTGAGGGGACGAAGCCTGGGCCCTGCTGCTGCCTCCCCTGAAGGCAGTCCCCTGCGCCGAAACCCTCTGCCCAAGCACTTTGAGATCACCCAGGAGACAGCCCGGCTACTCTCCAAGCTGGACACTGAGGCTATGTCCAGTGCTACCTGCTGTGCTGACACTGAGCCTGAGGGGTCTGAGGAACATCTCTGACCACCCACCATCCCAGGAGACTCAGGACTGAGCTGATGACCCCATATGTCTCTCTTCTTGCCCCACCTGGTAACCAGACCAATTTAGTGGGGTGTGGGGAGAGACAGGTTACCAGAGAGTTGGGTAAGGAAGACCACCCATCTTGGGAAGTCCTCACCATCTCCCTGCCAGAGGAGGTTAAAACGGCCAGACAACACAGGTGCACAGGCAAATCAGGATCAATGACTCAGTTGAATCAGTATTCAATGGTCAGTACAGGTCCGAAGATCCTTGGGTTACCCCAGTCACAGCTGTCTGACTACTCTGATCATAAGAGCTCCTGGTTCTACCTGAGTAGGTGGGTGTGGTTTAGCCCTCACCTGCTTTTATATCTTCCTGGGTTTGGTTTGTTTGTTTGTTTGTTTTGAGATGGGCTCTATTGTAGCTCTGGCTGATCTGGAACTCCCTATGTAAACCAGGTTGTCATAGAACTCACAGAAATTCCCTCCTTTTAAGTGCTGGCCAAATCTGGATTCTTATAACCTCTGAATAAAGCCATGTCCTGATTGAATACAA
->MH278833.1 Uncultured bacterium clone DEN-OTU-710745 16S ribosomal RNA gene, partial sequence 
-ACGGAGGATCCAAGCGTTATCCGGAATCATTGGGTTTAAAGGGTCCGTAGGCGGTCTTATAAGTCAGTGGTGAAATCTCCCCGCTCAACGGGGAAACGGCCATTGATACTGTAGGACTTGAATTATTAGGAAGTAACTAGAATATGTAGTGTAGCGGTGAAATGCTTAGAGATTACATGGAATACCAATTGCGAAGGCAGGTTACTACTAATGGATTGACGCTGATGGACGAAAGCGTGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGGATACTAGCTGTTGGGCGCAAGTTCAGTGGCTAAGCGAAAGTGATAAGTATCCCACCTGGGGAGTACGTTCGCAAGAATG
->XM_020557668.1 PREDICTED: Prunus persica putative disease resistance protein RGA3 (LOC18785927), transcript variant X4, mRNA 
-TCTCTTCAATTATTATATCTTTTTACGCCAGCCATATGCGCACCTTCTTGTCTACAAATCCCTCACAACCTTCTCAAAGATACATTGCGTCCTCAATTTTGCTCTACTTTTCTAACCCAAACTAAGCATTCTGCTCTCTGTCTTGAGCAACACTGAAAGAAAATATGGCTGCAGAGTTTCTTACTTTTGGTGCTGAGGGAATTCTGACGAGGGTGGCTTCACTTGCAGAGCAAGAACTCAGTCTTCTCTGGGGATTCAAAGGAGAGCTAACAACTCTACGAGACTCATTATTCAAGTTGGAAGCTATGCTCAGAGATGCACAACATTTACAAGTTCGGGGTGAGAGGGTGGAGATGTGGGTGAAGGATCTGGAAGGCATAGCTCATGAAGCAGATGATGTGTTGGATGAATATGAATATGAACTTCTCCGGCGGAAAGTGGAGATCCAAAATCAGATCAAGAACAAGGTGCTCAACTTCTTTTCACGCCACAATCCCATTGCATTTCGTCGCAAAATGGCACATAAAATTAAAAACATCAATGCATCTTTGGCAAACCTGAAGAATGAGGCAGCTAGTATTGGACTGGTTGATAGGTCAACACTGGTCAATGCAACATCTCATGATATTGGAGGACTTGACAGGGAAACCGTCTCAAACTTTGATCAAGATGAAAAGTACATTGTTGGAAGGAAGGAGGTTGCGTCGGACATAGTTACAACCCTGATCAACTCTGGCAAGAACCAAGACAATTGTCTTTCTGTTATGGCCATTGTGGCGATGGGAGGCTTGGGCAAGACAACTTTGGCTAAATCTGTATATAATGATCCTGAGATAGGTAGACACTTCGATCAAAAAATATGGGTATGTGTATCTACTCCTTTTGAAGTCAAAAAGATTTTAAGCGAGATCTTGGAATGTCTTAAACCAGAGAAAGCTGGGATAAAGGGTAAAGCAACAATATGTGAAAACCTGCAAGAAGATTTGAAAGGGAAGACATATCTTCTCGTGCTTGACGATGTTTGGAACGACGATCGTAGCAAATGGGACGATTTGATGAGTTGCTTGTTGAATGCTACAAGCACTAAAGCAAGCAAAATCCTTGTCACTACTCGCAATGTGAGTGTTTCATCAATTGTACAAACACTTCCTACATGTGTTCTGGGAAAATTATCGGAGGATCAATGCTGGTGCATATTGAAGTATAAAGCGTTTCTAGATGCGAGTGTTGTTTTGACTGAAGATCAAGAGAGAATCGGAAGGGAGATTGCCAAAAAGTGTGCAGGTGTACCATTAGTGGCAAAGGTTTTGGGAAATATGATGCGTTCTCAAGATATTGATGGATGTCGGTCAATTCTAGAAAGTAGAATATGGGATTTACCAGAAGGAGAAGAAAGAATCTTGTCGGTTTTGAAGTTGAGTTTTGATAAATTGAAATCACCATATTTGAAACAATGTTTTGCATATTGCTCAATGTTTGTCAAAGATTTCGAAATTGAAAAGGATGACTTGATCCAACTTTGGATGGCTCAAGGATTGCTTTACCCTTCTCCTCCCAACAGACGTAATCTAGAGATGGAGGATATAGGAAATGAATATTTTAATATTCTATTGAACAACTCTTTCTTTCAAGACGTTGAAAAGGATTGGTATGGTAATATTACAAGTTGCAAAATGCACGACCTTGTGCATGATCTCGCAGAACTTGTGTCAAAAACGAAGAGTAATGACTCCAATGAGACTCGACATATGGCACATATTCCTACCTCAGTGCTACATGGAGTTCCAGAAAGAGGTGCTCATAAATTGCGCTCACTTTTCTTGAATGTTGAAGTTCTTGGTGATATCTTACCAAACTTTAGAGGTTTGCGTGTCTTAAATTTATATCAAACTTATATGAAGGAGTTGCCAATTGCAATTGGAAAGTTGAAACACTTGAGGTATCTGGATGTTTCCTATACAAAGATCAAAGCACTCCCCAAATCCATTGGAAAGCTTTATAATCTACAAACATTAAGAATGAAAGAGGTCGAGCTTGAAGAGTTTCCAAAAGAACTGCAAAATTTGATAAACTTGAGACATATTTATTTTTATCCGTATGGTATGAAATTTCCAGCAAGGATAGGGCGATTGACTAATCTCCGAACATTAAAATATTTCATCGTGGGTAAGGAGACAGGTCGTGGAATAGAGGAGCTGGCTGGCTTAAACTTGTTAAAAGGCAGATTAACTATCTATAATCTAGAGCACGTGAGAGATGGAGAAGAAGCCAAGAAAGCAAAATTAGTGAAGAAGACAAACATAAGCAAGTTAAAGTTTCAGTGGGCAGAGGATAGGTCAAGCATCACCAATGATGAAGAGGTACTAGAAGGCCTTCAACCACACCCTAGTAAACTGGAATTTTTACAATTTTTCAACTTCATGGGTGATAAATGTCCATCATGGATCATGAGTAGTTCGTTTCCTGTATTGAAAAGGTTAAAGATTTACAATGCTAGGAACCTAACTGAATGGCCAGAAAGTGGGATCGTGGTCTTTCCTTGTCTCGAGGAGCTGGTTTTGAGGAATTGTGATAAATTGAGAAGTGCTCCTAGCCATTTCCCATCTCTCAAGACGTTGGAGATAGATTCCATGGGTAGCGGCATGCCAATAGCAAACATAAGCAATAAGCTGACCACTCTTACTTCGCTCGCAATAAGGAACATAAGCGGACTTGTTTCTCTGCCAGAAGGGATGCTTAAAAACAACAAGAATCTTGCATACTTGGAGATAAAAGATTGTCAGGAGCTAACTTGTATTGCTCTTGATGTAGTTGGCTCTTGCGCACTTCTTGAGTCAGTGCGTATTTCCAAGTGTCCTATTCTTGCTTATTTTCCTGATGGGCTACTCACAACATCTCTTAAGAACCTGATTGTGGAAGATTGCGGTAGTCTAGAGTTGATTCCAGTTACACAGCCCCTCTCATCCCTCTGTGAATTAAAGATTACAGGCTGTCAGGAGTTGTCAAGTCTACCGAGTGGGTTAGATTATTATACCTCTCTTCAGGAGTTGGCAATATCAAATTGTGATATGCTAACATCCGCTTTGATTCACAGCCTCCCATCCCTCCGGAAGTTGTCTATATTTCGTTGCAACAGGAGACCAAAGTTTGTTCCAAGTTTACTCGGCTTCACATGCCTTCGTGAATTGAGAATTAAAGATTCCCATGGATTGACAAGTCTGCCAATAGGGCTAGAATCATGTTCTTCTCTTGAGGTGTTGATAATAAGCAAGTTGCCGAATGTAGAATCTATTACAAGTTTAGACAACCTCACAAACCTCCATGAATTGGGGATATTTTCTTGCGATGGATTGAAAAGTCTACCCAATGGGTTAGCAATAACATCCTGCCTCACCCACTTGAAGACATTGGAAATCGGTGGCTTTTGGAAGGAGCTTGATTCATTCCCTGCTTTTCAGGTTACATCACAACTTGAAACATTGAAGTTATGGGGTTGGCCTAAGCTCAAGTCTCTGCCCGAGCAAATTCAACACTTGACTTCTCTAACATGTCTTGAAGTGCAATGCTTTGACGGAATGGAGGCTCTTCCAGAGTGGTTGAGAAACCTTACATCTCTTGAGTACCTGTATATACATCTTTGCAAGAATATGATGTATCTACCTACACTAGAAGCTATGCAATGTCTCACCAAATTAAAACGCATATTCATTTTGGATTGTCCCCTTCTAAAAGAGAGATGCAACAAGGAGAGCGGCTCAGAGTGGCCCAAGATTTCTCATATTCCACAAATATATGTTGACTGGGTACGGTGGCAGCTGCCAAATTCAATATAGTCTGAGAAAGTATCATCTTGAAATGAGAAATAGTTGAAAGTGGGCGAATTGTGGTCGAGAAAATGATTAAACTCAATTGCGTTTTTCCTTGAGACTGGTGTTGGTGTGGAGAGTTGATTGAAGCTATATATGCTACACATCATCACCATTGAAGAAAAGGTGTCCATTCCCTACAGCCTACAGCCTACAGCCTACAGCCTACAGGGTCTGTTGTTATTTGGGCATAATTTGGAGGTGGGTGGCTTTGCCTTACCTGAAGGAACATTTTTTGTAATGGGAGCAAACAGAGTCCAGGTATTCAAAAGCACTCCAATTTCTACAGTGACTGATGGGGGTAAATCCAACACAAGCCACCAACTCAAATGATCACAAAATCAAGACAGAAGTCACAGGCTGCTCAAATTTTGTGTGCCGATCCGAAGCGATTGTAGTTGGAATATTTTGGTAATATCCTTCTATTGATGTCCAGAGAAAACTATAAATTTATTCAAATTTTAGCATGGGTGTCCAAAGATGGATTTTGGGTGCAAGCGTGAGCTCACCAACATTTGAAGCACGAAGCCCAACAGCCCAAGAACCAGCAACTAAGTCCAACTTAGCCTATTGCTCCACTCTACCCCAACACCCCACTTTCTCTTTCCTTTTTTTTTTTTTATAATTTTTTTTAACTGTTGTAAAAGTGGAGTCCCCAAAATGCCCCCAAAATGCCTATAAATAAGGCTCCCTCCCATACTTGTAAATACACAATGAGATTGAGAAAACACACAGAAATAATGTGAAGAACAAACTCTCAATGAATGAGAAATCAGTTTTCTCCAATTTCTCTCTATCCCAATTCTCTCTCCATTTTCTTACTAGATTTATAACACATTATCAGCATGATTTCTCTATCTCTAAATTCAGAGACCCAACCCATCTCACCTTCCTCTGCTCTCTCATCCACACCGCAGCAGAGCTTTTCTTGAAAACCCAGAAACAACATAAATCCTGTCCGTACAGCAACCGAGCCATCTATGGGACACGGTGCTCCAGCTCACCAAGTCCGCTTAGGACAAGAACAGCGACCCGCTCCTCTGGGCGGTTCAGCACAGCAACAGCCTCAACTCGGCCGGCGTGGCCTTGCCCTCCGTCGAGCTCGCGCACCTCCTCGTCTCTCACATCTGCTGGGCCAATCACGTGCCCATCACATGGAAGTTCCTCGAGAAGGCCTTGACCGTCAAGATCGTATTGTGAACCAGCAAAAGAAAATCTTGAGAACCCAGTAAAGTGCGATGGGGGAGCTGGCAAGTCAGAAACATGTTCAGTTCATTGTATTAGTCGAAAAGAAGAAGGATTCTTTTGAGTCCGTGGTGATGGAGCATATAAGAATGAATGGGGCATATTGGGGTTTGACTGCTCTTGATCTTCTTGGGAAGCTGCACGTCAAGATGACTCAGGTGGGTTTGGTGGTAACATTGGGCATGACCCACATGTACTATATACCTTAAGTGCTGTGCAGGTTTTGGCCTTGTTCGACAAGCTTGATGTTCTGGATATTGAAAAGGTTGCGAGTTATACCACACACCAGCCTTCACATGTTTTGGATCAGCGGATGATGATGAGGTTTTCTCCAGTCGGCAAGGACAGAGAATAAAACAGTGTAAATGCAGAGGCAACTTTGACAGACCCCTGATGACGGCCACAATGATGAGCAGCACCCACCGATAAAGAAAAGCAAACCCACCGAAAAAAAAAAAAAATGCTAAAGTGCTGAAGCATCTTTCAATAAGAAAAGCAAACCCACCGAAAGAAAGAATAATAAATAAATATATTTTTAAAATTAAAAAAAAAAAAAAAAAAAAGATCACTCAGCCAAGGGCACTGACCCTAAAGTAAGCGATAAGGTCTCTGCTCCCTTATCTTCTC
->AY964845.1 Eptatretus stoutii clone Es2VLRA.33 variable lymphocyte receptor A (VLRA) mRNA, complete cds 
-TGGTGATAACCTCAAGGTGCTCTTTCAGAGATGATGGGTCCGGTCTTGGCCGCGTGTCTGCTCATCATTTTGTCCACTGCATGGATTTCCCAAGCGAACGGGGCAACCTGCAAAAAAGATGGTGGTGTTTGTACCTGCAACGACCAAACGAAGAACGTTGACTGCTCCAGCAAAGGGCTCACAGCCATTCCCAGCAATATCCCCTTGGAAACTACGCAACTGCATCTAAACCTCAACTCCCTGAGCAAGCTCTCACCCAAGGCGTTTCACAGCCTGAGCAGTTTAACATTCCTCGATTTGAGTTATAATCAACTGCAAGCTCTCCCTGCTGGGGTGTTTGACCAATTGAAGAATCTTGAAACACTATACCTGCTTCAAAACCAGCTCAAGTCTCTCCCACAAGGGATATTTGATAAACTCACCAAGATCACCTACTTGGACCTGGAAGGCAACAAGCTGCAGAGCCTATCACATGGAGTGTTTGACCACCTCACCAAACTCACAATTTTATGGCTGAATACCAACCAGCTGAAGAGTGTTCCTGAAGGAGCTTTTAACTTTCTGGAGAAACTGACACGGCTACAGCTGCAAAGCAACCCCTGGGACTGCACGTGCAACGACATTCTCTACATGGCCAAATGGCTAAAGAAAAAGCAAGACGGGGGTCTTGGGGGTGTCGACACGGCAGGCTGTGAGGAAGGAGGCAAAGCCGTCTTAGAAATCACGGAAGAGGAAGCGGCAGAAGATTGCGTCTATCCAAATACCACAACAGCGATACCGACAACAATTATTACGACACTGGCATCAAGTAATGACGATGATATACCCGAGCTGCCAGTGCCGCAAGAAAACTTTCAGAAATTCTTGGGATACCAAGAGCCAGACCATCTGCCCACCCAACCACAGTGCTTGATGTCCATTTCTGGATACCTCGGCCTCATGATGTTTTTCGTGCTCATTTCTGCTGCCATTTTGTACGTCATCCACTTTCTCAAGAAGGCCTGAACCAGTGTCTCACTTGCC
->XM_028621987.1 Apiotrichum porosum hypothetical protein (EHS24_006566), partial mRNA 
-ATGGCGACCGCTGCCCCGCTTGTCAAGCATGCAGCCTCGCTGCTTCGCCCTGGCCACTCAAACTGTGTGGCCTTTCCTGACATTCACCAACCGGGACTGTCTTTCAGCCTTGTGCCGAGGGCCGCGACTCAGTGGCACGACGAGGACTGGTTCATGGGCGGGCTGAACTACCACCTTGCTGTCACTTTTGATGATGGGGTTTGCTGGCTCGCTCGAATTCGCCAGAAGAATGGCAACCCGCGCAAGCTCCAGTCCCTCGTCTCAGAGTTTGTCACCCTCAAAGCCTTGAACCGCGCCTGCCCCGAGTTTGTTCCCAATGTCTGGATGCCACAGGCGTCACCCTTGGGTCCCCCATTCTTCTTCATGGAGCACTTCAAGGGGTCCAACAGTCGCCACCTGTTCCCCCGATCCGGTGCTCGCCCTGTCGAGTCCCAGACCATCGTTTCCGACATGGCCACCTTTCTCATCCAGCTGAGCTCGCTGGAAATCCGCGGCGACATTGGATCTCTTACTGCCAGCAGCGCGGTCGTCGACGCCGCAACCGACCTCGAGCCAGAGCCAGTTGTTGGGCCCTTTGAACATTGGGACTATTGCATTTCGAACGGACTGACGACGTTGGGGCCGTTCCGCACCAGCCGTGATGCGTGGGTGGCAAAGATCGACGCCGTCGTGCTTGCACTCGAAAGGGGGCTGTTTGCGATCAATGGCGGGCACCTACTGCATGTGTATCTCGTCCATCTGGAAATGCGTGCTCTGGTCAACGCGTGCGAGGAGATGGCTGTGCCGTGCGGTCCCGGCGACGGCGAGCAGCCGACGTTCATCACACATGCCGATTCCAAAAACCACCTGCTTGTCACAGACGACGGCCATCTGCGCGCAGTCATTGATTGGGAAGGTGCGTACACCGCTCCATTTGCCGAGGCGTTCGCTGCTCCGATGGGGTTTTACGATCAGCGCGGCTTCGTTCGGGGCAGTAACGAGCTCTCCACCGAAGAAGTCCTCCTCGCCGACATATTCCAGTCTCGCGGACGCAAAGACATGGCGCAGGCGGTACGCGGTGGGCGCAAGTACCACCGACTTGCGTTTCACCTCGGAACCCTTCAGCCGACTCTGGAGATGGTCAACGCACTCTATGACGCCTTTCTGGGTGAAGAATCGGCAAGTTGTATCAGGTTTGACTCGCTCTTCGAGTGGGAGGCCGCGGCGTTGCACAAGTTCTCACATGTCCCGGGCCTTGAACAGTTGGCAATTCCGCCGGGAGAGGGGGATGTCGCCTACTTGCGCTTCGCAGAGGTCGAGCCAGACGCAAATTGGTGCAAGGTCGTCACTGTGAAGGACGCCTCGTAG
->XM_035908051.1 PREDICTED: Neolamprologus brichardi nuclear GTPase SLIP-GC-like (LOC102787354), mRNA 
-TCTGTGCTAGAGTCCGCTCGTTCACCTCGACAGGATCAGCAATTAAAATTTATCTTTCAGTTTCTATTCTTGGTCATGGATGATTTTGTGCGAAACAAACTGACTGAATGGAAACTAAGTGACTGGATTGATGCATTTGAAGCTCAAGAAATTGATGAGGAAAGTCTGTATCATCTCAATGATCAGGAAATTGATCAATTGATCACAAAAGCTGGACCTAGAGTAAAATTCAAGGAAAAACTAAAGATGTTAAAGGAAGAGCAAAATACAACCCAACCACAAAAAGAAGCAGTCAATACTTCTGGTCAAGATTTTCCATCCATAAGTGAAAGAGGAAAGAGAAAGTCAGATCATCTTCAGAGTGAGACCAGAAAATGGCAACCACCTCTTAAAAAACAATACAACTGTGCAGCAAGATCACAGTCAGAAACAGAAATACTGTCTGATGTCAAAAACATAATGAGATGTGTCAGTGAAGGACTACATGGCCGTGACAAGCTCAGTGCTTTCCTAAAAGATAAAATCAAGAATTTAGAGACAGAAAGGAGACACCTGGTTGGTGTCTTTGGTAAAACTGGGGCTGGAAAGAGCTCTTTAATCAATGCCATCATAAATAAGGAGGGCCTGTTGCCTTCTGGAAGTGTCAGTGCATGTACCTCAGTGATGATAAAGGTGGAGGCTACCAATGGATCAAAGTATGAGGCACACATCGAGTTCATTACAAAAGAGGATTGGGAAGATGAGGTGCAGTCACTAAAACAGGCTCTTGAAGACAATGACGACAACGATGATGATGATGGTGGTAATGATGATTTACTTGATCCTGACGGAAAGTTATCAGCGCTGTATGGAGAAGAGTGGAAAGAAAGATCCACTCACAGCCTCATGGACAACAAATATTTCATAGATATTCCAGAGTTTCGAACATCCAAGATAAAAATTTTGAAAAGTGACTCAGTGGGAGAGGTAGAGGTGAAGTGCAGTGAAAAGAGCATCCTTGGTCGTTCTGTTCGGCCAGTATGCAAACTGCAGTGGGTCCAAAAGAAAATCAAGAATGCAGTGAAGAATGAATTCAAAAAGCGGAAAACGATTACGAATCACTTCAGTGAGCATTGTTTCAAAGTCTTCACAGTGAGCTCCAAAGAGTTCCTCAAAGGGGAGAATGTAAATTCAGATGTCAATGAAATACTGAAACTCAAGGAAATTTTGAAAAATCTGAATGATGCTCATTCAGAGACATTAAACTATGTGTCTGGAGCTCACGGGATTCTGTCTTTGATTCAAGGGGCCAGAAGTGGAGAAGTGGTTGAACAAAAAAATGATGTGTTTGCAATCCTTGAGGGAAACTTGAGCATCCAACTTAATCAAGTCAAAAAAGCAATTGAAGACATTATAAAAGCTTTTGAACAATGCCTAAGTGAGGGAGTTGAAAAATCCAAAAAAGCATGTGAAAAAAAACTGAAGTCCTTCTTATACCCTAGTAAAAAAACAAACAGAGCTTTTCACATGACACTAAAGTCTGCAGTTAGGAATGATGGCATCCAGAAACCAAAAAAAGGAAAACCTAAAAACCTCAACATGATATTAGCGTCTTATTTGACTGAAAGCATTGATGAAAAATTCAGAGATACCTTCCCAAACAACATAAAATGTGGACATTTCAATGGAGCCATCGATGCGTTTTCACTCAGCACTGATTCACTGATTGAAAAGTACAAAGATGTCAAACTGCAACTGACATTTCTCCAGACAGAGGGGGAAAAAATGAAGACAAAGCTCAACAAAACCATCCTCACACAAAAGAAATTAATCTACAACAGTTTGACAGAGACAATCAAGGACAACATGAAAGAATGCTATAAAGAAGCAGCAGCATTTACAGGAAAAGGCACCCTGAAGAACATGAGGGACACTATTGAGAGACATGTGCACTCAAAGATGGACATGTTTGAGGAAGCAAAAAATGTCATGTTGGAGCTCTTGAACGATTTGAAGGAAACTGTCCTGAGGACACTGGAGAAAACCATGAAGGATTCCATTGAACACTCACTTAAGTCGGAGGCCTGCTCACTGCCAGGTAAACAGAATATATAA
->XR_005829514.1 PREDICTED: Falco naumanni ATP binding cassette subfamily B member 11 (ABCB11), transcript variant X13, misc_RNA 
-ATGAAAACATGATGGGAGATGGTTGGGTACTTCACTGCCTAATTGAATAGATCCTTACAATTTGTTCTATAATACATAATTTTTCGCAGCGCAGCCACGGGACTTCCGATTTAAGTAACTAAACATCATGTCTGACCCTGTTGTTCTGCGTAGCATCAAGAGATTGGGAGAGGATAACAATGCTTTTGACTTGGATGGCAAATGTAACAGCTTCAAGAAATCAGAGAATTTCTATACGTATGAAGAACCTTTTGTAGAGAAGAAAACTGAAAAGTCACCAGAAAAGAAAGAAAATACTATTCGTATTGGCTTCTTTCAGCTGTTTCGATTTTCTTCATCTATGGAAATTTTAATGATGGCTGTTGGCAGTTTCTGTGCTATTGTTCATGGAGCAGCCCAGCCAGCTGTGCTACTTGTGTTTGGTGCAATGGCAGACACATTCATTGAATATGACATTGAAATGCAAGAGCTTAAAGACCCACTCAAGATATGTGTAAATAACACCATAGTGTGGATTAATGGTACTATTCATCAGAATGAAAAGAATGCCACAATAAGATGTGGGCTGCTGGACATTGAGCAAGAAATGACCAAGTTTGCAGGTTACTATGCAGGAATTGGTTGTGCTGTACTGGTGTTAGGATACATCCAAATCTGCTTTTGGGTTATGGCTGCAGCTCGTCAGATACAGAAAATGAGGAAAGCTTATTTCAGGAAAGTAATGCGAATGGATATAGGCTGGTTTGACTGTACATCTGTAGGAGAACTGAACACCCGCATTTCTGATGATGTTAACAAAATTAATGAGGCTATTGCTGACCAAGTAGCAATCTTTATCCAGCGCTTAACCACTTTTGTGTGTGGATTCTTACTGGGATTTGTCAGTGGCTGGAAATTGACCTTGGTTATCATTGCAGTCAGCCCTCTGCTTGGGGTTGGAGCAGCTGTCTATGGCTTGGCTGTGGCAAAACTAACAGGCCGAGAACTAAAGGCTTATGCAAAAGCTGGAGCTGTGGCTGATGAAGTGCTCTCATCCATCAGAACAGTGGCTGCTTTTGGTGGGGAGAAGAAAGAAGCTGAAAGATACGATAAGAATCTGGTGTTTGCTCAGCACTGGGGAATTCGAAAAGGAATAATAATGGGATTGTTCACAGGTTATATGTGGCTTATAATTTTCCTGTGTTATGCATTAGCCTTTTGGTATGGTTCTAAACTTGTCCTTGAAGAAGAAGAGTATTCACCTGGAACTCTTCTGCAGGTTTTCTTTGGTGTTTTAGTAGGAGCTTTAAATCTTGGCCAGGCATCTCCCTGTCTGGAAGCCTTTGCCACTGGCCGTGGGGCTGCAGCAAACATATTTGAGACAATAGATAAAAAACCCGCCATTGATTGCATGTCAGAAGATGGCTACAAACTGGATAAAGTACGAGGTGAAATTCAATTTCATAATGTAACATTTCATTACCCCTCCAGACCAGACGTAAAGATTTTGGATAACCTTAATATGGTTATTAAAGCAGGGGAAACAACAGCTTTTGTTGGAGCTAGCGGAGCTGGAAAAAGTACAACAATGCAGCTCATCCAGCGTTTCTATGACCCCACTGATGGCATGATTACCCTGGATGGCCATGACATTCGTTCCCTTAATATCCAGTGGCTACGCTCACAGATTGGTATTGTTGAACAAGAGCCAGTCCTGTTTGCCACCACGATTGCAGAGAACATTCGCTATGGTCGGGATGAGGCTACCATGGAAGACATAATCAAAGCAGCCAAACAGGCCAATGCTTACAATTTCATCATGGACTTGCCACAGCAATTTGACACTCACGTTGGAGAGGGTGGAAGCCAGATGAGTGGAGGTCAAAAACAGAGGATAGCTATTGCTCGAGCTCTTGTACGAAACCCGAAAATCCTGCTGCTGGATATGGCTACATCAGCACTTGATAATGAAAGTGAAGCTACTGTCCAGGAAGCACTTCATAAGGCTCGCCTTGACCGCACCGTAATCTCAATAGCTCACCGCCTGTCAGCCATCAAAGCTGCTGATGTCATCATTGGGTTTGAGCATGGAAGGGCTGTGGAGAGAGGAACTCATGAGGAACTCTTGCAGAGGAAAGGGGTTTATTTCATGTTGGTGACCTTGCAAAGCAAAGGAGACAAAGCACTTAACAGGGAAGACACAGAAACAGCAGAAAATAACATCGTTGAGCCAAATCTTGAGAAAGTCCAGTCATTCGTCAGAGGAAGCTATCGGGCCAGTTTGCGAGCTTCACTTCGACAGCGCTCCAGATCTCAGCTCTCTAACATGGTCCCTGACCCTCCATTATCCATTGCAAGAGATCATGCAGAGTCTATGTATGTTGTGCCTTCTTATGGAGAAGATGATGGACAAGCAAAAAAGGAATCTGTTGCAGTGGAGGAAGATGTCAAACCTGTACCATTTACCAGAATTTTGAAATACAATGCCTCGGAATGGCCGTACATGGTGCTGGGATCTCTGGCGGCAGCTGTGAATGGAGCAGTCAGTCCACTCTATGCTTTGTTATTCAGTCAGATTCTTGGGGAGCTGTTGGGTGTGGGTTTCTGTATTCGCATACAGTGTATTTTAGATGAGACAAGAGGTACCTCACGTGCAGACCTTCTCCATTCTTGACGAGGAAGAACGAAGAACCCAGATCAATGGTGTCTGCCTGCTCTTTGTCTTTGTCGGAATTCTTTCATTTTTCACACAGTTCCTACAGGGATACACCTTTGCCAAGTCTGGAGAGCTGCTTACAAGACGGTTAAGGAAAATTGGTTTCCAGGCTATGCTAGGGCAAGACATTGGTTGGTT
->XM_001628387.3 PREDICTED: Nematostella vectensis peptidyl-prolyl cis-trans isomerase NIMA-interacting 4 (LOC5507809), mRNA 
-GGGGAGTGGAGATTGCCAGCCGTTGCCTGTTGTGTGTGGAACAAGTAAAAGGGTCGTGTGAGGGAAAAGAAACGATGCCCAAAGGCAAGAAATCTGGCGGAGCTGATGGCGGAGGAGGAGGGAAGCAGGATAACAAAGGGAAAGGTGCCAAGGGAGGCAAAGATGATGATGGTGCTAGTAAGGCAAAAAAAGGAGGAACTTCAGTCAAGGTGCGCCATATCCTTTGTGAGAAGCACTCAAAGGCAATGGAAGCCATGGAAAAACTGAAAGCAGGGCAGAAATTCAATGAAGTGGCCACAGCTTATAGTGAAGATAAAGCTCGACAAGGGGGTGACCTCGGTTGGATGACACGCGGTTCCATGGTAGGTCCATTTCAAGAGGCTGCATTTGAGCTACAGACCAGCACTGTTGACAGGCCTGTCTACACAGATCCCCCAGTCAAAACTAAGTTTGGCTATCATATTATTATGGTAGAGGGGAAAAAGTGACCCATGTTGATGGTAATCCCTTTTTTCAAGAAAAGCCAGTTTAACAGAATGCATTGCATTTTTTTATGAAAGTGGTATAGGATGATACTGTTTCTGCGTGCAAGCAATTAATAGCTGTGTCATTTATGCAAATGCAATACACTATGGGGTAGGTCAATGCCTTATGGGGAAGGTTGAGATAGACCAAGTTACCTTACACATTTTCCATTCATTTTGCATTTAGTCTGTGATTGTTTGGAATGAGGACTGTGGGGTTTTTCTTGAACAAAACACAGCTCTTAAAAAGCACTATAATACGCACTGGGAATCAACATAATTCAACACACAGTTTTGGCAACTAACATAAGATTTTAAATCTCATGTTTTCAAATTGATTTTTGATTATTGTTGACAAATGATTTCCATCATCGCATATCTTCCCTATTCTTTAAACACTTTTAGTTGTGCTGAAATATTTTGTGTATATTTAGAACTACGAAACAAAAGAAGGAAATGTAGCACAAACAGCAATGTGTATTTGAATTGCATTATGATTTAATAATAATTTATTGTTAGATAATAATTAATAATAATTTTTTTGTGTAGAAATTCCTTCGTTATAACATTTCTGGAAGTCTGTGCCCTCTGGTGCTTGCACTTCCTACAAAAAACAGGAGGGCAACTGTGATTATTAACTTTCTCTAAAATAGTGTCTGAGTATTTACAGACTCAAAAAAGGGTCCAAGTTCACCATAGTTCTCGCAAAAAACGGGGCATTTTCCCTCTCCCCCCCGGGTTCCTCCCCCTCCGCTTCCCCTACTGCTATCTCAGCTATATCTACAGTTTGCCAACGATTCGCCGCAGGATTTTCCAGCACCTGCGGGTTGTTCAGATGATGTTTGCACGGGCTTGTTAGCCGCAAATGTCACCAGTTCACTTCCGGAGGTACGACGGAAACCTCAACCGTTAAGACAAAAGAATCTACTAGAATCCGATATATTTGACAGGCCATCCGCTCTAAATTACCAATCACACCCTCAAAGAAACTTCCAATAGACACACTGCTTCCAATATTTTGAAATAATTTTCGAGTGTTCCGTTAAAAATCATCGGATATTGTTAGGTAATCGACCGGAAGTAAACTGGTGACAATGCGGCTTTAATACGCACCCTCGCGCGCCAGGGTCCAACTCTCATAACCCGAGGCCAAGGAGGGTCTTATGGTATCAGAGGGGTAGAGCATGGTGCGCAAAATGGTGAATAAGTTCGCCAATAGTTCCTTTATCTTGTTGTCAACCGAAAGATGCCAGCTAAAGTCTGATGTTGGCGCTTTGTGCAAGGGGCTTGGTATAGCAATGATTGTCGTAATAATAGATTAACAAAAGACTTAAATAAAAAAAGAAGAACATCCCAA
->XM_031545768.1 PREDICTED: Punica granatum exocyst complex component EXO84C (LOC116211402), mRNA 
-GCCCTGTCTCCGCCCTTCTTCGCCGGCTCCTGCTCTTCTCGGCCTCCTGGCCGTCGCCGCCTCCTGGCTGAGACCGGCTCCTGCCCCTCTCCTACTCCTCTGCCCATTTGGGTACGGGTCCTCTTTCTTCTTCCCTCTGTGGTTTCGTGATAATTCCCGCCGAGCAAGAAAATTGAGTGAAAAAAAGGCCATCTACTGGGTTTTGAGCTATTAGATGTTCTGCGAGTTGAGCTTTCGCAATCTGGGCTGAGCTGAAATCCATAAATGGGTCCTCTGATCTGAGCAATCAGTAATTGTTGAGTTGAGATTCAGTAGAAACTGACTATACTGAGATCAACTCAGGTTCCCTTCCTCAATGTAGAAGTCAGTCTGTGAAGAAGAAGAAGAAGAAGAAGAAGAAGAAGGAGATTTGAATTGGGAAGTAAAGAAGGGGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAAGATGGAGAGCAGTGAAGAAGACGAGGAGTTCCCTTCAATTGAAACCATCACTCCCCAGCCGAAAGTCAATTCCCTGTTCCAATCTCACACCGAAAAGGGGATTAGGCAGCTTTGTTGTGAGCTATTGGATCTGAAAGATGCAGTGGAAAATTTATGTGGCAACACACAAACTAAGTACTTAGCTTTTTTAAGAATATCAGAAGAAGTGGCGGAGACGAAGCACGAGCTAAGCGAGCTGCAGAAACATATTTCCTCCCAAGGGATACTCGTGCAGGATCTGATGATTGGTGTGTGCTCCCAATTGGACGAATGGAACAAATGCAATCGCAGGGAGCATGAAGGTGAGAAAAAACAGGAGAGCTCTGAAGATAGAGATTCTGTACCTAATGAAACTGAAGACAGCAAGATGATGGTATTAGAGACCATCGATATTCTTTTAGCGGAGCACAGAGTTGAGGAAGCCGTGGAGGCTATAATTGCTGAAGAGAAAAACTCATCAGAACTAAAAGGTTCTTCTGAAGCTTTATCTGCTGAAGCAAATTCATACAGATCGATGTTTCTGGAGAGGAAAGCCATGGTTGAGGAGCAGTTGGTAGAGATTGCAAAGCAACCTCTGATTAGCATGGTGGAACTGAAGAAGGCATTATTGGGTTTGATTAAGATTGGGAAAGGCTCTCCTGCTCATCAATACTTGCTTAAGTGGTATGGGTCCCGCCTCCAGAAGAGCATTGAGGTTTTCCTTCCTTCGTGCTCTCTTTGGCCGAGGACATTTGCCGCCACACTAGCTAAACTCATGTTTTCTGCTATCTTAACGACAACCAGAGAATCTGGTTTGATTTTCGGGGATAATCCGGTTTATACAAACAGAGTTGTTCAGTGGGCAGAGTGGGAGATTGAGTATTTTGTTAGATTGGTTAAGGAAAATGCTCCATCTTCTGAGACTATAAGTGCTTTACATGCAGCAGGCATCTGTGTCCAGGCGAGTCTTAGTTACTGTTCAATGTTGGAATCACAAGGGCTAAAATTGTCCAAGTTGCTTCTTGTGCTCTTAAGGCCTTATATTGAGGAAGTTTTGGAATTGAACTTTAGAAGGGCTCGAAGAACAGTTCTTGATTTGGAAGAAGGCGATGATAACTTGTCTGTGGCACCCCGATTTGTCTCCCCATTGTCTGCTTTTGCTACATCTGACAATGCTCTTATTGACAGTGGACTGAAATTCATGTACATTATCGATGAGATATTGGAACAGCTAACTCCTCTTGCCATTTTTCATTTTGGAGGGAATGTATTGAGTAGAATCTCACAGCTGTTTGATAAGTATGTGGATGCTCTTATCAAGGCCCTTCCGGGTCCCTCTGACGATGACAATCTCACAGAGCTTAAAGAAGTTTTACCCTTCAGAGCTGAAACAGACTCTGAGCAACTTGCATTGTTGGGAATGGCTTATACCATTGCCGATGAACTCTTGCCTGATGCCATTTGGAGCCTGTGGAATACGCACAATGAAACCCAAGAACCAAGAAGTGAACCCAGTGAGAGTACTCCTACTCAAGCTAAGCCGGCAGAGCTAAAAGAGTGGAAGCGCCATCTTCATCACTCATTTGATAAGCTCCGAGATCACTTTTGCCGGCAGTATGTCTTGAGTTTCATCTACTCGAGAGAAGGCAAGACACGACTGAATGCACAGATTTATTTAAGCGGAAACAGGGAGGATTGGGATCCTGATCCCTTGCCATCGCTTCCATTCCAGGCATTGTTTGCAAAGCTACAGCAATTCATGACTGTAGCTGGAGATGTCTTACTAGGCAAAGAAAAAATACAGAAAAATCTGCTTGCAAGGCTGACAGAAACAGTCGTGATGTGGTTGTCTGATGAACAAGAGTTTTGGGGTGTCTTCGAGGATGAATCTTCGGCTATTCAAGCGATGGGTTTGCAGCAGTTGATTCTTGACATGCACTTCACTGTTGAAATAGCCCGGTATGCAGGCTATCCATCCCGGCATGTGCACCAGATTGCATCTGCTATTATTGCTCGTGCTATTAGGACCTTCTCTGCCCGAGGGATAGACCCTCAGAGTTCGCTTCCTGCGGACGAGTGGTTTGTTGAAACTGCAAAATCGGCGATACACATCCTTCTGGGGCCTGGGTCAGATACATCTGAGATAGATGAAGGGCATATCATGCACGATGAGATTCTATCTGATTCAGAAGACTCTGCTTCGTCCCTCTCAACTGAAGAATCCGTCGAATCTTTTGCTTCTGCTAGCATGGGAGAACTTGAGAGTCCAATGTTCACCGATCCCGAGAACTGAGGTACTAATTCGAGTCTTCTGTTATGGTGAGGCCCTTTGGCTGCGGATTGCATTGGGTTCTCTTTTCGGAACGTCGGATGGGCATTTTGTTGGTAGGGAATCTTATTAGCTTCGGCAGAACAGATGATGGATAGCTTAGGTTTTAATGTGCGATGATGGATATGGAAATCAAGAAAGTGTATTTGATTATGAAAACTAGTGTAATTTATGATGTTAAATAAATTAGATAATACTTTCTAACAGGCAGTACACAATTTTTTA
->XM_006508279.3 PREDICTED: Mus musculus anaphase promoting complex C subunit 15 (Anapc15), transcript variant X2, mRNA 
-AGTATATAAAATCTGTCAGTGCTTTCGGGATCGTGGTGGACGCGCCTTTTTTTTTTTCCCCCATCACACGGACCTGGGGGGGCTTTGGTCTAGGGAATGACAGCGTCTAGTTCTGCTGCTGGGCCAGGATCCCTGCCTTGCGTAGGATTTAAGCCCCCATCGAGTGTGTGGCCAAAGTCAAGCTCTACATGTCACTGGGTTTGTGAGCCAGGGCGTTTTAGTTCAGCTTCTTGGTGACCTTCCTGGTCAGCAGCTTCAGCCCACAGAGTTGATTTTGTTCTCTTCCATATGAGGAAACTGAGGCCCAGAGAGGTTAAGTGTATTGGCCAAAATCAAAGAGCTAGTAAGTGATGGAGCCAGGACTCAAACTCAGCTTAGGAGCCATGTCCACCTTGTTCCCGTCACTCTTCCCTCGTGTGACTGAGACACTGTGGTTTAATCTGGACCGACCCTGTGTGGAGGAGACAGAGCTGCAGCAGCAGGAGCAGCAGCATCAGGCCTGGCTCCAAAGCATCGCAGAGAAAGACAACAACCTGGTACCAATTGGCAAGCCGGCCTCAGAGCACTACGATGATGAGGAAGAAGAGGATGATGAAGATGATGAGGACAGTGAAGAGGATTCCGAAGATGATGAGGACATGCAAGACATGGATGAGATGAATGACTATAATGAGTCACCTGATGATGGAGAGGTCAATGAGGAAGTAAGTGCAAAAGACTCGGGATTGTGGGTAGGAGCAGCATGCCCTCCAGGATGCCAGCTGCCTGAGTGGAGCTGCTTCCTTGAATGGGAGTCCCTCATGAAAGAGGCCTGGTCTGAGCAATTCCTGGGATAGCTGAAGAGATCAGCGTTGGGGCGATAGGGGCTGACCATTTGCTCATCGAAGCCTGCCAGCCGGATGACTTTTTCAGCCACTGCTGCTGTACGTGAGTCCCGCTCCACAGTGAGAAGGCGACTTCCAGGGGGCAAGGCTCGCGCAATAAGCAGTGTAGAGTATCCACAGTATGTGCCCAGCTCCAGCACACAAGCAGGGGCCTTCTCTTCCACCAGCCGCATCAGAATCTGACCTATGGGTCAAGATGGCTATTTTAGAAGACATTGAAAACAGGTGTGCCCAGAATCAAACCTGCTGTGCTTTTCTGAATGTGGTGTTTATGTGTGAGGCTGACAGGCTGCTTTCCCCTTTCCCACACCTGTCTCCATCCACCTGGCCAACTTGAAGAGAAGCCTTCCAGTCTCAGTTTAGATGTTTCTTCCTCCAGGAGGACCCAGGCGAAATATCCACCCTACCTTCCAGGTTCCCGAGACATTTTCAGTTTCATGCTCAAATGCACTTCCCCATTGCTGATTGTCTTTGATTTTGGAATTGAATAAATCTCTTAATACTTAGAAGTACTTGTGCTATCTCAGCAGACAGCTATCCTGAGTTGGTTGTGGAAGCCTCTTTGGTAGGGAAGAAAGTCTAGAACAGATAATTACAAACCTCTGAGTTATGGCTATTCCCCTATGTTATGATCTCTTTGAGGCCAGCATTTGTGGCTGGTTACCCTCTGTGATCTCTGCCTCCCTCAGCACCTGGCACAAAAGAGTGGCAATAAATGTCTGCTGGATAACTGAA
->XR_006907879.1 PREDICTED: Neodiprion virginiana uncharacterized LOC124303282 (LOC124303282), transcript variant X1, ncRNA 
-CGATGATTGATAGGAAAATAACCGGAGTGGCCAACCAGCGCAGTAATATTATGTAGATCAGACTTATGGCGGCACTGATACCAAGGATCGATGCAATGGTCCATCTATAAATGACAAAGTCAGCTACAGTCATTGTATAATTGACAAACAGTTCCGGAATTCCGTTTGGAATACAACGACCAGTTACAGAAGTACTGGTCAGATACCACTGAGCACACACGTCGTTTGAAACGTAGGTAGCAAGCTGGTCTGCCGTCGCTGTATCCACTTCAATTCCAGTCTTGCATATCATTGCGGTTCTTAATGCGGTCAAGTTATTTGCCAAAATTGACGAATTCAACTGCCACACAAAATTATCTGTCGGACACTCCGGCACGCATACCTGCGGCGTATCGCATCCTTGGGTCACAGACGTGACCGCTACACATTTTGTCAGATCAAAAAATACCAAATATGGTCTGTCCTCGACATCTTTATGCCTACCGCATATCCTTCCTTCACTATCAGTTGGGTATACTAACGTATCTATATCTCCATAAGTATAAGCTGAAATTATAAAGAATTTTATCAGTGTGTTTCAAAGCTGTCTTTAAACATATATGATCAGGGTGATGTAAAAAAGATGTACTGGTTCCTTGTAGTATACTCGTATTCAAAATTGCGTACCGTAATATCCAATTACCGCCCATCCTACCACAAATGCTGAGAAGATAATCAAGCAAAAGCAATCTGTACATGATCTGCCCTTTAGAGGTCCTCGATATTTTGGATCGAACTGCATCCTATCACCTAAAATTGGTAATTTACATACTTAAATCAATAATAGGCCTTTTATAGTTTAAACATTTATCCAGTTCACAAATTCATTTCAATAGTTTTGGCACTAAGCCATTTTGACAATGTGTTGTGACATTCAAATAATCTTATCAACCACTTATCTCAATAACGAAGTATACATATTATATTGGTAGTGATCTATATTGATCTCTTACCTGGAATGGGAAAGTATCGATAGAGACGGTACTGCTTACATTTTACAATAGAAATTAAAGAAGTTTTTGAGTTACAAGCATAGTGCTCAAAACTATCGCAGAAGTTGCTTGTTGAAAAATTTGAAAACAGTTGTGGATCGTTCGGTTTGGCATAATCCTTTTTTGGTAACTCACACAAAACTCTCTACAGGTACAAGACATTTTTGACACGAGAATTCAAAGCAGTCTGTGACGTGACTCACGTTTCTATACAATGAGACAATAAGCATACGTACCATGTTTGTCGACCATTGTTTGCACTTTGGTTCTTTAAATAGACGTTATCACTCTGACTTTAAGTACTTATATAAAGCCAGTCAACGTTCTAAGAATTTTTTTTACTTGTCCAGTGTTACTTATTAACTTGTTAGGTCTGCATATTATTTTGCCCACTCCGGTTTCATGCTCTTGGTTCAAATTATTAACGAATACTTGGATAGCATATGCTTTCAGTAACACTTCTACTGATAACACATTAATCTGATAAGATGAGATTTGGCAGCGAAGTATGAATCACCGGAAGTAAACAATCTTATCAATTTTTAATTGAGTCTGATAAATTGCAAATTCTTTACAGGATATGCTAACCATATATTGATTGAAAATATGCACAGCAGTAACTTGAATCATACGAAATCTCAGAATTATGTGAGTCGTCGAAATTCTCATTATTTGCACGTTATCGGTTCTAGCTATCCCGAGTTTATAGTTTCCAACTCTGGTCAAGAAACATTTATTTACTGAAAAAGTAGCGCTCGGTGATTTGGAATAGAGTATAAAATAACAAAATAATGGAATCGTTGTTAAGACTATTGAACAGTTCGTTGCGAAATCCAAACATATCAACATCTACACTATCTAGAAGAGTTAATTCATATTTCATGAAACAGGGAATGGGTCGTTTTTTGTTAGACTTATGTACACCTTCAGTGCCGACAGATTTGTTAATTGATTAAAGAAAGATACGCAAACAAAAACAATATGATTGATAGCACTATATGACTTGATAAGAATCAATTTATGTGTACAAGATATGAAGCATAAAAAAAATTCTCCCAAGAGAACATTTCGTGTAATGGCTGTGCCGGAATATCGGTAAGGTCGTCTTAAACTACCGGGTTATTGAATTGATGCAATGACAATATTGCTCTTGCCTGGTATTCATCCCAGATCAAAAACCATTGTGTTTCTAGGATAAAATAAGAATTTACTTGATATCATAACATAGAAACTAAAATCACTAAATATCGAATGATTGGATTTGTAGGGTGGTTCATGGTGTGTTGGCATTCATAAAATAAGGTAAAAACCTGTCCAGAACTCCATGGCTTTTTCCTGGCAATAGCTTATTTGCTGTGCACCTAACTGCTCGATCTTCGTGCATCGTCTTGATTGTCTCCTAAGGGGAAGGAGAGTGAGTAAATTATTAATGAAGTTTCTTCTTTGCTTCGAACTGGTCTCTCATAGTAGGAAGATCAACCTCAGCAACTGCGGATGGCTCAAGGGTGATCAATTCAGGTTGAATTTTGTCCAGAAGTGCTTTCACTTCAGCCTCGCGGCGTTGGCTCTTTGTCTGGAATGGATTACTCTCAAGAGCATCAAAATTGGCTTCGGCACTCCCAGGAACAAGTAGAGATTGAAATCCTTTGGCTGTTGCGATGCCCAACACATCTT
->XM_023859745.2 PREDICTED: Cryptotermes secundus sodium/potassium/calcium exchanger 4 (LOC111868780), transcript variant X2, mRNA 
-TCATCCCTTCCAAAAGTGAAGACACTAAACGGGTTTGACATTGAAGTTGAATTACGAGTTGTCACACCAACAATTTTAATTGTTTGGTTTTGTAATTACTACTGGTTTATGTTGAACGGTTAGATAGACTGCCTGCGCTCTATTATTTAAATTACATGTTGTTTATATATATATATTGTAAGCAATACACGATTACTCCATAAAGTACTTAAAATATCAGCTGATGTGTAAGTTTTAGATAAGGGCTGACTGTATTTACTTCGATTTTCTGATAGCACGTGTGAGTAGTTCTCATGTAGCATCAGGCCGAATAGGATCCCTGAAGGCCTTTCCTCTTGCTAGGCTGCCTATACCAGTTGCCACGATAACCTGCTTGTGTATATAAATAATTATTTCTTCCAGTCAGAGTATGTAGTGGCAAAGTACGTTTAGAGAAGTTGAACGCAGCAAATATAACTATCATTAAAGTTAAAGGAACGAGCTCTAAAGCAAGAAATCGTAACTACTACGTGAAACAGTTTTGTTACTTCTTCGTAAGTGTGATACTAATTTATTCATTTAGGATACGTCACTTTTTAAGTCTGAGTTTTTTTTTTTGTGAATGTTTTAATTTTCTAAAATAGTGACAGTCAGTTCAGTTCCATAAACAGTTTGACAGAATTGTAAGTTCAGAAACAGCATACAGTGTCCTGATGCCAACAAGAATGACAGAACTGAGGTTGATTATAATAGTTGTGTCCATAATTTTGACTGTACAATTTGTGTCAGTGAAATGTACGAATAATACAACCGCTGAAGATGACAGGTCCCATGTGCAAGATTGCATGAACAGTTCTGTCTCAGATTTCCCTGATGATTTGTTTGATTTCAAAGAGAGGAAAAATGGAGCAATCATCGTTCATTTCTTCTTAGCACTCTACTGTTTCACAATAATTGCAGTAGTTTGCAATGACTATTTTCTGCCATCTGTGGACTGCATCTGTACAGAGCTGAACCTTACACAGGATGTGGCTGGAGCAACTTTCATGGCAGTTGCTACATCATCACCAGAACTTTTTGTCAATATCATTGGAACTTTCATTACGGAATCAGATCTTGGAGTGGGGACAGTGGTGGGTTCAGCAGTGTTTAATACACTGGGGGTTGCAGCATGTATTGGTCTTGCAGCTTCTAAGACTATTATTCTTGAATGGTGGCCACTGACACGTGACTGTAGCCTCTACATTGTTACCATTGGAGTTCTGACTGCAGTGACTCTTGATGAGAAAGTAGAGTGGTATGAAGCTCTCATACTATTCCTTATGTATATTACATACTTCCTCATAATGTGGGGAAATGGACACCTTATGAAGTTGGCTAAGAAAATTGAAGTCAAAATTATTGGCAGTAAAACTGTTCTAAATGATCCAGAGAGCTCTACATCAGAGGTTTATTCAAATGTTGGCCCTGGAATATACCGCTGGTATCTTCATGGTGATTTTACTGTCAGTAACAAGATGACTTCAGATGATACAGAAAAATCTCCCAAAAAAGGAAGTCGTCTGATGTGCCCACCAGTAGGGGGCCTACTGGACAAAGTGTGGAATATATTCTTATGGCCAATTTCACTCTTGGTCTTCATCAGTATACCAGACTGTCGAAAAAATCACTTTCGCCATTTATATCCTCTCACATTCATTATGTGCATCGTATGGATAGCTACAGCATCATACTTGAATGCTTGGATGATGACAATTATAGGTAATACATTGGGAGTTCCTGATTCTGTCATGGGCCTTACTATGCTTGCAGCAGGTGGAAGTTTACCTGAAGCATTTTCATCTATCATCATGGCACGGAAGGGTGTGGGAGCCATGGGGATCAGTTCCTCTGTTGGAGCCAATACTCTCAACATTCTTCTCTGTCTTGGTACGCCTTGGTTTATCAAATGCATTGTACAAATCATCCAAACTGGTAATACAAACAGTAGTGCAGTCAACATCATTTCAGAAGGTGTCACCTACAATTGTTTTGCTCTCCTCTCCAGTGTCCTGCTACTTTATGTTGTCATAGCTGTTTTCAAATTCCATCTTGGAAAGCTTCTTGGATTCACATGTCTCGTCACATATTTCATTTTCATCACAGTTTCTGTTCTCATTGAAATGAATGTATTCTTTTATGTTAATAGGCCTTTATGTGCTGAAATATGAAAATAATTACTTTCACA
->XM_002627964.2 Blastomyces gilchristii SLH14081 U3 small nucleolar ribonucleoprotein IMP4 (BDBG_00918), partial mRNA 
-ATGGTCCTTCAGTCAGCAGCCTTGCGTCCTTCAGCAACTAAACCACGGGTCAAAATGATTCGCCGTCAAGCTCGTGAACGGAGAGACTATCTCTACCGAAAAGCTCTCCTCCTCCGCGATGCTTCTATAGCAGAGAAGCGCGCGAAGCTGAAAGCTGCCCTTGCGTCAGGGAAACCGTTAGATCCCTCTGTGGCCAATGATAAAATATTGCGAGAAGATTTCAAATACGATGAATCCTTACCCACATCCTCGAAACCGGGAGACCCTAACTCCAAAGATTCTGACATGCTTGACCTCGATGACGAGTATGCTCTCACATCCGGCATCGTTGACCCTCGACCCCTCATTACAACGTCCCGTTCTCCCTCTGCGCGCCTTAGTACTTTCGCCAAAGAGATGCGTTTACTCATCCCAACTTCGATTCGGATAAATCGGGGAAATCTAGTCATTCCTGATCTTCTAGCAAGCGCCAAGGCGTCCGCACTCTCTGATATGATCCTGCTACACGAGCATCGCGGTACACCCACTGCGATAACCGTGTCTCACCTCCCCTATGGCCCAACGGCCAGTTTCTCGCTACATAATGTCATGCTACGAGCAGATATTCCGAACTCTGCACGAGGAACCGTCTCGGAAAGCTATCCTCACCTAATATTTGAAGGGTTTACCACCAAGCTGGGTGCTCGTGTCGTCCAAATCCTAAAACATATTTTCCCGCCGCGGGAAGCAAATGGGAAGCTCGGGAGTAGGGTTGTCACCTTTAAAAATATAGAAGACAGTATAGAAGTGCGACATCATGTATTCGTTAAGACTGGATACCAATCAGTTGAACTAGCTGAAGTCGGGCCGCGGATGACGATGAGACTATTCCAAATCCGAGGAGGAACGTTGGAGAAGGACTCCGGAGGCGAGGTTGAATGGGCACTCAGTCAATATACCAGGACGAGTAGGAAGAAGGACTATTTGTGA
->XM_031798635.1 PREDICTED: Oncorhynchus kisutch protein FAM180A-like (LOC109879465), transcript variant X1, mRNA 
-CAGACAGAGAGAGAGGGGGGAGGCAGAGATAGGGAAGGGGAGGAGAGAGAAACAGACAGACAGAGTGGTGGAGAGGAAAGGATGAAGCAGTTGCATGTGAAGTGGTTTAGCAGTGCTCCAGTCAGCGTTCTTACCTCATTCTCCTGAGGGTTGTTTGTACACAGCTCTCTCCAGCTGGGGCCTGGCCGGTGACTGATCCACATTCAGATCCCATTGAGACAGACAGACGACAGGGCAGTGTCAGTGTGTGTGCGCTGGGCCGAGAGTCAGCATGATGCATCGGTGGGGTCTACTCATCACTGTGTTCTACTGCCAGCTGTTCCTGGCTGCTGCTCAACACTGGAGGAAAGCCCTTTACCCATCAGCCTTTAGAGTGAAGCGTGGCACACACTCATTGGTCAACCCCACCTTCCAGAACTCTGTGGAAGATGTTAACCTGCTGTTTGAGATCCTGCTGGCAGGCCTGCAGATCGAGGGTGAGGACAAGCCCTTCGTGATCCCAGACAAGGAGCTGGCGTCTCTGAGGAGGGTCCAAAAGCTGGAGGTTATCTGTGAGGACGTCCTGCCCAAGAGACTATCCGAGATCAGACGTCTGACCTCCCACCTGTCCCAGCGCAGAGGTGCCCTAAGCAGGGAGGAATTTGAGCGCACAGTGCTCACTATGGTGTACACTGCCCAGACTCTGGCTCATACCACCTCCCAACACCAGAAGGCGCTGTGGGGAGACGCCCTACTGCAGCTGTTCAGGGCCATTCAAGAAGATCTGACGCCCCTACCCAGAACACCTCAGCACAACTAGTGTTATGGACACGTGGACACATTTTTTTAGATACTGTAATATACTGAACATTTTATACTGTAACACAAGTCACTTTTTGGCAGAAAATTTAAAGGATGTTTTCTATTGAGTTGTATTGTATAATCAAAATGACTGTTCTAATAATGTAATGTGTTTGGTTATGATCAAATGATGATATGATCTAATCATATTGAAAGGAGGATGTGGGAAAAGGAGGGATGTGAACAATATCCTGTTCATGTTCTATCTATCGGATTCCGCCTTGTTCCAAGACTTCAGATGTAAACAAACAAATATTTTATCAGTCACTCTGTCATGATTCATTACAGGTCTTTATCAAATCTTCTGTCATAATCTTCTCAGCTGTTTATCACAATTACATAATCTTTTCCCAGCACAGTCCTGTTGCGAAAAGGTGCTTCATGAAAAAAAGAGTCCCATGAGGTGCAGAAATATTGTATTGAACTGTAACATTGAAGACAGGGGTATCAATTTGCTCAGCTTATTTCTCTGCAATTGATATTATAATAAAATAATGATCAATATATATATATATATATATATAGGTTATGGCCATGTTATGAACCAAGCTAAACACTGAAGAAGATGGTTCAGCTGAAAAGTATGTGTATGCTATCCTGATGCAGTAAAAACATGATTTATATATAATGAAGTAAGCTTTATGCAGCATCTTTTAGACTGCAGACCCATTACAATTTTTTGAGGGCTTATCTGGATTCACAGGTTTTACGCACCAACAATACTTTTTGGAGAGCACTATGGTCCTCTTTTGATATGGCCTTGTTATGATTATGTGCAAATGATTGATATGACTTGAGGATGTTCATTCACATTTGCAAAAACGTGGGTAGGGTTTTGCCTCAGTCCCAAACTGTTTTCATTTTGGAATTAGAGGATTTTAGCTGCTCTAGCCTGCAGGGAGGATGTCAGACTAGATGTGAGACATGGGGCCTCAGGCTTTCTACACATCCCCCAGGTCTACACATTCCCCAGCTCTTCAATGGCTACAAAGAAAGACGAGTGCCTAATGTGTGTCCTGTTGGCGACATAGTCCACCGCTGCTAGAACAGACTTTCCATTGACATACTGTTGCCTACAATGTTTCTCCCTCATCTACAGATGACAGGTTCAGGGTGGCGGCCATTTTGCATGGAAAACTCCTCTCCTTCTCTGTGTCCAGTTGCTATTGTTTCCGGATGGTGATAGAACTGGTCTAGCTCTCCTGGTGGTCACACATCAAGGCACGGGTGAGTCCATGCCCCATGCTCCCGGTAGAGCCCACTAGAGCCCTCATTGATGAGGAACTGCAGATTGTGGTGAAGAACGTTTTTCCCCAAAAAAGAAGATCACCCTTCGTTCACCCTTCGTTCCTGGGAGGCGTTCGGCCATTATGCCAGTGATAAAACGGGGATGGTCAAAGAGTCCAATGGGCTTACTGTGGATCATGAGGCCTGTGTATGGCAGTGAAACATGACCCAGGTTGAGGAAGAAGGATATCCGTACTCCACTGCTGGTTCAGATCTCTGTGTACAGTGGCCACATCAGCCAGGACTACAGTGAGCAGGCTGCTGTAGCCTGTACAGTCGTAGAGCGCTGGTGTTTGGCCCCCGTAGTCCAAAAGATAGACATCTACAAGAACGGAATCCAGGGAACCCTTTTTATACCAGCAGGTCCTGGACCTTTCCCTGCTGAGCTGGAGCTATCTGGGGGAGGAGGGGGTCTGTTTGAGCATCGCTCCTACCTGTTAGCATCCCAAAGCTACGTCTCCTTAGTGCTGCAGTACCCCACGGACGTCTCTACAATGGTTGCCATAGGATGCAAGTACTTTGAGGAATTTGCACAGTTCATTGTGGAAACAGATGCAAGAGGCCTGAAGTGTGTGTGCTCTGGAGTTTGTTGTGAACCTGCCGCCCCTACTTCAGACAGCCTTCACTATGCTGAGACCATCCTCAGGTGGCCAGTGATAGAGGCTATGTTTGGCTTCTCACTGGGATTCCTTATCCCTGACCGTTTACACTGATGTCATTAACATGATTATTCCACACCTTCCTCTTTGAAATTGACTTGTTTGATTGATAACCAGTTAATTAGTGAACGCAAATACTGTAAACAATTATTTTACAGGTGCTCTGTAGGCACACCTCTCTCCTATTTCCCAACATATTTGTTGATAATCCCCCTCTCTTCCAGCCCAGATGTATGGTGAGTATACGTGGCAGCCATGTTTTCCCTTTCAGATTGTCGCTTGTGTCAATAGCTGACAGGTACAACACGTGAGTGTGTTTTAACCTATTCTAAAGCAATGGGAAATGACCTCATTTGGAATGCACTGAAATTATAGTTGTATTTTGCTCAAATTTCTAGAAATATGCACTTTGATGAGAACAATCATTTGATCTGGAGAGACACAATCCAGCCCATCACTGAGAGTGGCCCTAAAGTAGAGGTGATGGTATCTTTCAGACTGCATTGTATGCACACTATACTGTATGTATTTGTACAGTGAGGAACTGACATGTGTGTGAACCTATTTTTTGGCACCATAGGTCAGGAGGTTAAAGTGTCCATTACTGATGGTCATTGGAGAAGCTTACCAGAACTGTGCCACTACAGAATCTGTCCAGGATATGCGCAGTACAGTATGTTGGAGAGGGCAGGGAACCTGTGTCTTACCCTGGGGCTGGTCACCTAATCAAACCTTTCTACACTCCTCACTTCCGCTCCAGCACCTCCAGGGGCAAAGTGATCATGTTGTGGGGAGGGGAGTCCAAATGGAGGAGGATCCTGGAGTTCCTTCAGAAGAACCTGTACCAAAGACAGGACCCCTCTGTCCCCTCAGAGCTGTCAGATCCTCCTGGACTATCTCCATTATTATAGTCATCGCTTCTCCAGCTTCATTATCTGTCAGGGCCCTATTCTTGAAATTAAGTAGAGACAATATTGGTTGGATTTTTTTTTACTCACCAGGTGGCAGCATTGCACAGTCTCTTAAATGACTGGTCTGCTGCTTGTAGTTGTCATAGTAGTCAATGTCCTGACAATTACAAGGAGGAAGAAGAGGAGATGGTCGACATCGGCCTTTCATCAAAGTCCTTATAGGGAAGCCTTTCTGTTTAAAGACCATGGATCAGACCTTGGCTGCTCGGTCACGGTTGAGTTGCGGTCTTCTAGCCAACCTGGTTTGGATTCCAAACTCCTGTGAGGTGACATGAAGTGTTATTGATCTCAGAGTTGAAGAGAATGAACACCGCTGCCTTTAACTCTCATCAACTGCATACTTTTTTCTTTTTTACATGTCACCCATATATTCTCACTCCAGATTCCATTCTGGCAAAGGGGACCGATGGCCTAAACATCTCCATGTGTTGCACATATATTAAACCAATAGCCTGGTCTGGA
->XM_017410869.3 PREDICTED: Kryptolebias marmoratus Yip1 domain family, member 1 (yipf1), mRNA 
-GAAAATATACAGAAACAGGAACGTGGCTTGTTTACATGCTGTCACTTCCTGCTCAAAGCTAACGTAGCTAACTGCAATTATTATAGGTTTTCTCGAAGAATTTGAGCTTGAACTGTTCCCTTTATTTGGCATTAAATTGCCTGCAAGTTTCCTAAAGATCAGTAACATTGTCGTGAGAGTGAATGGCGTCAAACAATGATCCATTTCAGTTTCAAGAATTTGAAGAAGCTGAAAATCTTTTGGAGACCAACAGAGATGCAGTCACCGTAAGCATTGAGGAAGAAGATCAGAAGTCCAAGAGCCAAAGATCTGCTGGTGGCTTTTCTCCAGATTTCACTGATGAGGATCCACTCCGCACCGATGACAAGGCAGAGCTTCTTGGTGGCCAAAAGAAAAGTGCCCCTTTCTGGACGTTTGAATACTACCAAACATTCTTTGATGTTGAGACACACCATGTAAAAGAGAGGATCATCGGGTCGATGCTGCCATGGCCTGGAAAGAACTTCATTCAAGTTTACCTTCGTAAAAATCCTGATCTTTATGGACCATTTTGGATTTGCACCACTCTTGTGTTTGCCATTGCCATCAGTGGAAACTTATCCAGATTCCTCCAGTACTCTGGCAGTTCAAACTACAAATATACCCCAGAGTTTGGAAAAGTGACCATAGCTGCTACAGTAATCTTCAGCTATGCCTGGCTCGTGCCTCTTGGCCTTTGGGGGTTCCTGCTGTGGAGAAACAATAAGATTTTGAACCTGGTCTCATATTCCTTCATGGAAATCGTCTGTGTGTACGGATATTCTCTGTCAATTTACATACCAGCTGTGGTCCTGTGTATTATCTCATACGAGTGGCTCAGGTGGTGCTCCATCGTGGTGGCCCTCTGCCTCTCTGGCTCAGTCTTGGTGATGACTTTCTGGCCCGCGCTCAGAGACGACCACCCCAGAGTCGTCATGGCTGTCGTTTCAGCCATCGTGTTGCTCAATGTGCTGCTGGCTGTTGGTTGCAAGACCTACTTCTTCAGCAGTCCAGAGATTGACTCACAAGTAAAAAGTTCTCCTAAAACAGAGGTTGTCAAACCAACGTCATCGACATGAACGCCTCCTGTTTGAAGCTTCTCCTGTTGCCTTATTGGAGAGAATCGGGTTCCTGTACCAATGAAGTCATGGGCTGACTGGATTTCACCGCACTTGGACATTCCAGCTCGATGCCTCTGAAAAGCCAAGACTGTAAACTTGGTGCGGCAGCATGACGATGAAAATGAAAACTGGTTGCAAGTATGTTACTTCTAACGGGATGGGTTCTAAACAAACTTAAAGTTAATTGGGGTATAGTATTACACAACGCACAATATCTGTTGTGGTGTTGTAGTTTTCAGCTTTCTGTCGCTCATGTAAAATGTTTGGAAAAAAACAACTTTGTGCAATAATAATAGCAGCACCAATGCTTTTTATATGCACATTTGTTTTGCAGTATATTTCTTTAATAGGTAATGGTAAGTCGATTTTATTTACAAACTTAATGTATGATCAATTATAGGCATTGGTAAGAATTTCCAGGATTATTTATCAAGCACCCTGTAAAGGTGATGTGGTGGTATTTTCTTATAGTTAAGTTGCCTCAACTAATGCCAAGAGCTGGTTTAAATAATTTTTCGAATGACTTTGTAAATATTTCATAAATAATTTGTTGTCATTATAACAAACATCTTTAAATAAAGTCTACTGAATTTCATCTCTA
->XM_007381610.1 Punctularia strigosozonata HHB-11173 SS5 hypothetical protein (PUNSTDRAFT_132265), partial mRNA 
-ATGGCTGACGACTCGAAATCGGAGCCTTGCCACTGCATCGAAAAACCCAGACAACGTGGACCTGATGGACGTAAGCTCGGCTTGGATCAGATGATCTTGCTGATGGATCCATGCTTGGGGGCGCACTGGCAAGCAATCAAGGACCGCATTCGCAAGCTGGCGTTCGAAAGGTTGGCTATCGGCCGCGTTTACAATGACCAGCCGTCATTTGCCCATTCGTTATTGGTCTGCCAGGTTGCCGACCAATGGCAATTCCTGTGGGACTACGTGGACCTCTGGCCGCTTCGTCTATACCTTCGGTTTCTTCTCTCTGCGTACGCGGATCCTGATACGCCTACCGGCATCGCCTTGAGGCTCAGGAAAAGTCTTGACGATCATTCTGTGAAGCATGAGACTGCCTCTGCATCTACTGCCTCCACACAAAGTATCAACGATGATGATACTCTTGAGTGGGATGACCCGGAAGAACAACTTAACGATACAACTACACGAACCTCTTCGTAA
->XM_032672596.1 PREDICTED: Danaus plexippus plexippus SAP30-binding protein (LOC116778559), mRNA 
-GTGCAGCGATACATAGTTTCACAGTTGTTGTATTTACACCAAAAACATTAAACAAGAATAACCTTAAATAAGTTATTCTTGTGAGTGAAACATTACAAAAACTGTGCTAGAAAAGTGTAATTTATTCTTATAGTGCGTAAAATAAGCAACATGACTTCGCAAGCGTTAGCCACATTGACCGCGACGTACACAGACTCCGAAGGTGAGGAGGAAATGGAAGATGGAGATCCTACACCTGAGAAATCGGTCACTCATCACACACAGTCAGCTCCAACCAGTCCCAAGAACATCGACGACACCAAACAATCTGCTTCCGCACCAGTTTCTCCAAAACGAAGTTTGGTCTCGTACGTAGACGACACTATCGTATCCGATGACGAACAATTGTCTCCTAACGCGGAAACTCAGGACGATATGAGAAGATTATCGATGGAAACCGACACAGATGAAGCTGTCCCACGATCAGATCCCGACGACTCAGAGGATAGTGTCCTTATACCTCCGGAACCAACAGCCAAATGTCCCAAGGAATTACAAGACAAAATAACAAAATTCTACACAAGAATGGTCAACGAAGGTTACGACATGAACAAAATAATTCAGGATAAAAAGAATTTCAGAAATCCAAGCATATACGAGAAGTTGATACAATTCTGCGACATCAACGAGCTAGACACGAACTACCCACCAGAAATATACGATCCTCTAAAATGGGGCAAGGAATCCTACTACGATGAGCTCGCTAAAGTCCAAAAACTAGAGATGGAGAAACGGGAAAAGGATCGCAAAGAGAAGTCCAAAATAGATTTCATCACCGGAGTGGCAAAGAAGTCGGACAGCGACGATGACAAGAAACGGAAGTCCAAGTGGGACCAAGCGGCGCCCAACGTAGCCAACAAACCCAGCATCAAACAACCGGGGCTCCTCCAGCAACCGCTGACGAGCAACGTCACCGGCACCAAGGGCACTGTGATATCAGCATTCGGTTCCATTGCCAAGAAGCCAAAACTATGAGTTACAGCACAGACGGACATGTTAGTGATGCAAAGAACGACAACAATATAAAGTGTACAATATTAGTTGCAGACATTTTAATACAAAGTTTTGGCTTTTTATAAGTTGTTAAGACTGGTAGATAGTGTATGACAAAGTTAGACTAAAGCATCCATATCATCCTCAACGTGCTCCTCTCCGAACTCTCCCACACTTATGTATATATTAAAACCGTTAAATAATTCTTGTAAAATAAATTATTTGC
->XM_030796770.1 PREDICTED: Nomascus leucogenys intraflagellar transport 22 (IFT22), transcript variant X3, mRNA 
-CAGGCCAACCCTGCAGAACCGCGTCTGCAGCCCGGGCTTTGTGGCTTCTCTCCGACCCCCTCCCAGTAGCAAACGCGCCCGCTTTCCGCCCTGCGCGCCGGAAGTGGCCGAGTCCCGTCGGCCCCTGCGGGCCGCTCGCCGTCGCCATGGAAACGAAAGTGGCCAAGTAGCGCTCCGCCCTGACACGCTGGCTCTGGTGGGCTGCGGCCGGCTACGCCGCGGCGGACAACGATGCTGAAGGCCAAGATCCTCTTCGTGGGGCCTTGCGAGGATCCTAGAATTTGAGAACCCGCACGTTACCAGCAACAACAAAGGCACGAGCTGTGAATTCGAGCTGTGGGACTGTGGTGGCGATGCTAAGTTCGAGTCCTGCTGGCCGGCCCTGATGAAGGATGCTCATGGAGTGGTGATCGTCTTCAATGCTGACATCCCAAGCCACCAGAAGGAAATGGAGATGTGGTATTCCTGCTTTGTCCAACAGCAGTCCTTACAGGACACACAGTGTATGCTAATTGCACACCACAAACCAGGCTCTGGAGATGACAAAGGAAGCCTGTCTTTGTTGCCACCCTTGAACAAGCTGAAGCTGGTGCACTCGAACCTGGAAGATGACCCTGAGGAGATCCGGATGGAATTCATAAAGTATTTAAAAAGCATAATCAACTCCATGTCTGAGAGCAGAGACAGGGAGGAGATGTCAATTATGACCTAGACAGCCTTCACGTGGGACTGCCACAGCCCCAGTGAAATCAGCATGTTTCTCAGTGCAGATCTGAAATCACATCCAGCTCCTGATGTTTTCTTCTCCCTGTGACTGCAGAGGAAGTGTTCCTACGTGCAGGAAGGCACCTGTCACACAGGGCGTTCACTCAGACCATCTGTGCTCTGTCCTGAGTTCAGCTGAGAAAATCCGATTATCGAATTTGGATTTCCTGGCCCCAGAACTTCCCAAAGACCTGTAAAATGGAGGGATTTACCACCTCACATATGTCCAGTTATACAATTTGTGGAGTTGTAACTGTTGCAGCCCAATGATACAACAGTAGTTTAATCCTGTGTATTGGCTTGAATGTGATTTTCATTCCTTGATTCACCCAACGAATACCGACTGGCTGAGCACCTGCTGTGTGTGCACTGCTGTTCTAGCTGCTGACCGTAGACAGCATAAATGAAAAAGACAGAA
->XM_046808004.1 PREDICTED: Homalodisca vitripennis neuropeptide F receptor-like (LOC124356796), mRNA 
-CTACAAGTTGCGCGTCCCGCTCCACCTTCCCGCAGTCGTCCCGCACCCACATCGCGCGTGAACTTTATACTGCTGGAGTATGTGATGTTGTGTATGTGCTGACGTGTCGATCAAACATACTGTGTCCTGAATTGAATGCCTCAAGTTGGTAAAGTATATTCTGAACGCACTAAACCTTCTCGACTCCAGAGTGACGGTGAAACTCCTACGTGGCCGTACAATCTGATGACGCCCTCTGTACATGAGCTGTCCCATGTTCGAATCATGTCTGATGATGGAACTGAACGCCTCAGGCACATTTAACTTCAGCATCCACGAGGCGTTCCAGATCCTGCAAGAACACAAGAGTCGTGACCGCAATGTTGACGGACTTACGGAGGTGATCCTGATCTGCATCTACGGGTTCCTGATGGTATCCGGACTGTCAGCCAACCTGATTGTCAGTTTCGTGGTGGCGCGTCGACCGCAGATGCACACACCGAGGAATCTCTACATCGTGAATTTGACTGTCTCGGATATGACTTTGTGCCTCATCTGCATGCCTTTCACCTTGGTCTCCATCTTGAGCCGCCAGTGGACTCTTGGACTCGCATTGTGCAAGCTGGTGCCGGTCATTCAGGGCACCAACATCATGGTCTCCGTTGGCACCATTACCGTCATAGCCTTGGACAGGTACTTGACGATAGTGCGTGGACAAGAAGGTACCAACAGTAGACGACGGGTAATCACATCCATAGTGATGGTTTGGTTGGTGTCAGCACTAGCCACCCTCCCTGTTGCCTTTTATCAGGTGGTGGAGCCTCTGATGTTCCACCGGGTGGTGCTGTACGAGACGTGTCTGGAGCGATGGCCCTCTCAGCAACTAAAGATATCGTACGCTGCAGCTGTGCTGCTCGTACAGGCCGTCATCCCAGCCCTCGTAGTGTGCGTGGTGCACGCGCGGATTGCATCCTACCTGCACGCACACGCACGCACACAGAAGGATAGGCGGAGAGCCCTGCGGGAAATAAAGAGGAACCGAAGAACTACGCTTCTCCTCTCAGGTGTTGCGATCTTGTTCGCCCTGAGCTGGCTGCCTCTAGGTATCTTCTCTCTGACGGCCGACGTCCTCTACTCAGAGGAGTCCTTCAGCCGTGTGTCCTCACAGGACCTGTACGTGACCTTGGCCGTATGTCACGTGACCGCCATGACCTCCGCTGTGTCCAACCCCGTGGTGTACGGCTGGCTGAACTCCAACATACGCCAGGAGTTGCTGCAGCTGCTGCCCTCGAAGTGTGCCACTGTGTCCGGGATAGAGGAAGCCACCACCAAGACCGCTCTGCCAACCACCACCCACCGGCGGGAAAGTTTCACCATCCTGCTGCAGAACGGGGACCGGCCAGTGCTCACTCAATCGCCCCACACATTGGTCACTGTCTTATAACGGTCCGTGAGGTCCTCATCGCGACTCTGAGATACATCTTCTAAACACCATTCTCTAGATAAACACTATTTTATGTGACAAGGTATGAATGCAATGGGTAGAAAATTGTAAAACAATTACATATCACATAGTAAGACGGATAAATTCCTGGTTTAAATAATATAAGTTTCTTGACCCGTTCCTTACTTCCTAAAATTGTTTACCAGGATTACGATTGTAGATTGTCAATACAATAAATATCCAATTTTTTATACTAAACTCTCGAACACATAGCCTCTAATCGCCCTCAGTATATAAAGCTTCTGGCTTTGGAGATGAGGTCAGTCTTTCTGTCAATAAAAATAAAATTCATAAAACATGGTTTACTAATATTATTATATTCAATTTTATAATGAAAGGAATTTTTCATCGCAACATATATAACTTTTCAAATAAGCTAGATCTAAGTAGAGATACTTTCACACTTTCTGTTTATGGTGGTGTTGACAAACACATGATGAGCGAGTGCCAAGAGAAGATAGGTAACTACTGTCTGTGTTATGTTTGCTTTGCTTAGTGTCAACCTTGACGTATGCTGCATAAATATCTCTTGTGACAGATACCATATAACTAGTTTTAGAAAAGTCTATTTAAACGATTTAATTTTGTAGTAAGAAATGAATTGTTGAAATTATTTGTTGTTTTGATTGGTTTTAAAAATACAAATTGACAAAAATTATTCAAAACCTTGAAGATTTATAATGCTTGTAATATTTATGATCCGGTTTTATTTAATTTGAAAAGTAAGACACCTGTATTGTTTGGTTTTTCGAGAACATACTTAAAGTCCGTTCCTAACGATAAATATTTAAATTCTTGCTCAAACACATTTACAACAGAATTTTGAAGTTCAACTGACTCACATTCAAATGTTATTCCACCCCAAGTACTACGTTATCATAGACATGATACGCGCTTCTTTCCTTATAGAAGTATTGAAAAAAGAGTTTGTTTGGAAGAGTAACATAAACTTTCAAATATAAGTAAGAGTAAAGAGTAGCATGGACATAACTTGATGCTAGATTTACTTGGCGTATTTATAATAAATACGTATAAAGACATAACATCATGATCAGTATCAGTAAGTTCAGCTCTTTGTTTACTTTACTATAATTTTACAAGTATGGGTATGCCACAACACGTGTTGCATAACAAGCTTGACTGAGGTTGTGTGCAAAACTAAGTTTATAACACATGTTCTTCTGGTAGTTATAAAATACGTTAAAATTTATTATGATTTGATCCATTTTGTTTACAAGTTGATTTAGTCTTTGATTTTCTCGTTACTATCACGGTGAGACATAAAACCAATGTATAAGTAATTTTAGTAAGTACCGCTGTGGATTGAAATGCAGCCTCCTTAAAATCGATGTTGCATTTATAAAAATGAAGCTGCTTGCAAAATTCCAAGTTTATAGATTAATTCGTTTTTGAGGCATCGTGCGGACAGAAGGGCCTACATAGATGAAATTTTTCCAGTCCCTCGAGGGATGGTCTTCTCTAACGCTCAGCCATCAACGGACGATTGAAAATATGTATAGACAAACTTGTACGTACGAAAGGACAAAATACTTAAACACACACAAAATCTGTGATTGGATCTACGAGTTAAGAGTATCGAGAGTTATCGAGAACGATGAAACATATCAACACGAATGAGAGAGAACGATGAAATGTATCGATTTGTGGCACATCACGAACATCTCTCTGTATGCTGCAGTACCAAAGTGGGCGTCGAGTTTACTTATCGGTTTGGCAAAATCGTTTAGTTTAGTCAACAACGATGTATTTTCGTAGACTCTGATCACCCACCAAACCGTTCATAGGTTACAAACTGGATGTGATATTTAAAACCTTTTTAAATCTCTTAATATAAACCACTACCGAATTGGGTCACATTATTGGTGCTCAAATATGATTCCTTTGAACTGTGACTATAAAGTAAATGTGGGCGTAGTAGGTGGTTACATATTAGGGCGGTTCTATAGTATTTGTTTTATAAAGCCAGCATTAATACAATTATTTTTTTAGTCTCAGAGATAAAAACTGTAATACATTTTAAAAGTTTTTTCTTATTCCATATATTCCGAAAGTAGCATAAAAATTATATTTAACTACATACCATTGTATAACTATTTAAAGTTCTACTTTCATTACCATTGAGATTTGAAGATGCAACTATATGATCTTACTTAAAATGTGGCAAAATGTGTTATATGACAAGTAAGTATTATTTCATTATTTGTTTATCATTTCAAAAAACGAATGGTCGTTATCTTGTATCGTTTTCTTCAATCGCCTATCGAGCTGGAATCGCCTATCTTACCAGAATTACTATACAGCCGCTTTTATACCTTGAGGGGCATAAATGTTTAGTGCTGTGAGACAAGGGTCAATAAAAGATAATAGCGATATCGTGTTCCTTTTAAGTTCAGTATCATTAAGTAGTTCTTTCGCTAAAAATATCACAATCTGCTCTATCTAGCTTAAATTAAGGAATTAAAAAAATAATTCAGGATAATGCAATAGTATAGTTTTCTTTGTAATAGAATCAAATAATTCGTATAATGACGTCAAAAATAAACAGTTTGGATTCCTGTGATTAAAATTAAATTCTAGTTTTTTCGGTTAAATAATTTCAAAATGTTATTTTTATTTACAGTGGCATTATTTAAAAAAGTATAATTGGTAAAATTCATAATGTAATTTAATAAACAAATTGTATAATGTGTTAATTACTAGTATTAACAATTCGGAGTTTAATAAAGAAAGACTGTTTTAAAGAATAATTGTAAACTTTTTCAAGAAATATTCGTAATACATTTTATTTACATAGTTTCTCGTAGTTCTAGAGTAATATAAATTTTATCCGATGACATCTTAGAGTGGAATTCAGGACTTGGTACGCTACATAAGTTAACAGAGATTGTTACGGATAACTCCTACAGGTGAAATGTAAATGTCACTACCCACTTCTCAAGCAACACCTCTTTGCATCTCATTACTTCTCCGTACACATCTATTTTCGTATGGAATATTAGTATTTTCTGAATAATATTTTCCTGTTCTAATATTCGCTCTTGTTGTTGGCGTGACAGTGCACCCAACCACATTTAAAATTTGATATTTTTATATGTACATTTTATGACTGTACCACTACTTGAGTGTATTGTTAATATGATAAATTAATATAACAATTATAACTTAATATAATGTGCGTATTTATCTTGTAATTTGTTGTAAATACTAAACAACATAAGTGTAATTTAGTTTTAGTGTTGTTCTATGGTTCCTATACAGATTGATTACAAATTGTAACTAACATAATTGTCAAAGGTAAATTATTTCACAGGATAAATGTTTTTTTTACAATGGGTTCGCCAATATAATACTTGTAACGTGAAGCTCTTTTTTACTAATGCTAGCTGTAATCTCATATATTTACATCACAAATTGTATATATATTTAAATATATATATATATATATATATATATATATATATATATATATATAATATATTTTAAATATATGAACATTAATGTAAAATTAGATACAATATAAGTAATACAAAAGATACTTTAACGTATATTTTACAACACATTTTTTAAATAATAACAAACAAAATGAATAAGTCTAGATAGGTTTCCTAAAGGATTTTAACTGGTATCTCATGAATACTGGAACTATTACTACAGACAAAAATTGAAAAACTGTCATATATATACAATTTCACTTATTTGTTAATTTGAAATTATTGCTTGCAAATGTCAGAAATTGTATCTAAAACCATTTATATAAATTGCCAAAATAACAAAACGTTTCTATCATTATAACATAATTTTCTCTTTAAATTGGCAATTATTGAACAGCAACGCCACCTGCTTTTTTGTGATGAATACCAATTGGAATTTACAATTTTAAATTATTGATACAATTTCCCAGTATCTTGTAAATCTTAAAATTCCTTAAGGAAAACTCAATGTTTTCTTTTAATGTTGATTGTAGTATAAGATGATTTTATAATTTATAAACTTTTATTTACTCACTCGCTTAAGAGCTATAGCATATTAATGCTTTAAAAATTGCATATTTTTCCAGATGTAAGCACTATTGTGTAATTAATTTCAAATGAAGCAATAAGGAACACTGCTTTTAGTGAATTAGTAGTGTTGAACGAAAAAAATACACAGCATGACATGCGTATGGTGGATATGAGTATAAATATTAAAAATACAATAAAAATGTGCAATTGTTCGTCGTCTATGACGATAATCAATTATCCTTGGTGTTCCACTAATTTTGGCGATGTATTGATTACACTAAAGTTTTATAACTGATCTTGGCATCATACAGTGATTTAAATTAAGGTGTTAAAATTAGTGAATTTAATTAATAGTTTCTTCCATCGCATATATGCAAAATGTTTTACTCATAATACCAATAAAAAGTGTATTTATTTTTTTAAACTAGTATTGAAGGATCTAATTTAAATAATATATCAATTGAAAATAATTTTATTACGTATGGGGGGCTTCACGCTTTACATGTGTACGTTACCTATGTTTCTTGTGTTGTTTATGGTGATCTATGAATAACCACAACTATTGAGTTATAGCAATCCAAATGTTTGTACACGTGCTGTTGTGAGTAGTGAGCCCAACTCCAACACATGATTACAAACATGATCATGTATACATCAACATTATGCAGCCTCTGTGATTTGTTTGTACGCTTATTGATTAAACTATACCTTTGACACAA
->XM_021555190.2 PREDICTED: Lonchura striata domestica interferon regulatory factor 7 (IRF7), mRNA 
-ATAAAGGATCGGGAAGGAGACGGCCGCCCCCGCGCCAAGGGACGGCACGGCACGGCACGGCACGGCACGGCACGGCACGGCACGGCACGGCACGGCGCGGCGGCTCTGCGGACCGGCACCATGGCAGCACCGGAGAAGGAGGGGGAAGCGCAGAGGCTGCGGTTCGGACAGTGGCTGCTGGACGCCATCAACAGCGGGAGCTACCGGGGGCTGCGCTGGATGGACGCTGCCCACACCACCTTCCGCGTCCCCTGGAAGCACAACGCCAGGAAGGACATCACCAGCACTGACCTGGAGGTCTTCAAGGCCTGGGCAAAGGTCAGTGGGCGGTACGAGGAAGGCTCCGAGGATCCAGCCAAGTGGAAGACCAACTTCCGCTGTGCCCTGAGCAGCACCCACTTGTTCAAGCTGGAACAGGACCATTCCAAGCGTGGTGATGACCCCCACAAGGTTTTCTCCATTGTCTCAGCCACCCTCCAGGACAGCAAGGAGGGACATTCCTGCATCCCCAACCCTGTGGTGGACCAGCAGGCAGCACAACAGCAGCTGCAGCCGGAGATCCACCCCCAAGACATGGCCTCAGCCATTGCTGTCCCAGGAAACACCGACCCCACAGAGCTTCTGGAGCAGCTGCTGCAGCAGTGTGACATCTCTCCCAGCGACCTTGACTCGCTGGCCCCATCCTGGGTGCCTGCAGGTGGTTTCCCTGCCAGAGACACTCCCCACCAGGACATCGTACAACAGCCTCACCAGGACACCCTGCTCCAGCCTCACCAGGACACCCTGCTCCAGCCTTACTCAGACACCAGCCAAAACAGCTGCTTCCCTCCCACATTTCCACAATGGGTGCCCTCGGTGGAGCAGCCCACCTTGGGCACCTACCAACCAATCGGCCTCATGCCACCAGAGGAGACAGGGGCCATGCCACCGCCGTGCCAGCTGACGGAGGGCACGGTCCCCATGCAGTATGTGCCGGGTCGGACGTTGTTCGTGCCCGCCGCCAGCCCCGTGCCACAGCCACGGCTGCTGCTGGATCACACAGATGGCATTGTCTCCATCCTGGATGTCACCATCTACTACCGGGGGAAGGAGTTCCACCACGAGGTGGTTGGGGGCAGCCACTGCCTGCTGACGTACCAGCGCCCCAGCCTGCCGGGGGCCCCGTGCCCCGGGCACGTGGTGAGCTTCCCCAGCCCCGCCAGCCTGGCCGACGGCAAGCAGCGGCGCATCACCGAGGATCTGCTGGGCATCGCGAGGCTGCGGCTGGAGCAACGCGCCTACAAGGTCTTTGCCACCCGCCAGGAGAAGTGCAAGGTGTTCTGGGCCTTGTCCCAGCAGCTCGAGGGGGTTGAGGAGCCCCCATCCAACCTGCTCTGCCGAGACCAGGAAACACCCATCTTTGACTTCCATGAGTTTTGCACAGAGCTGAGGGACTTCCGCAACGGCCAAAGGCGGCGATCTCCCGACTTCACCATCTATCTCTGCTTTGGGCAGGCCTTCTCCAAGGCCAAGCCTAAGGAGTCCAAGCTCATCTTGGTGAAGCTGGTGCCCAAGTTCTGTGAGTACTACTACGAGCAGGTGCTGCAGGAGGGAGCCTCCTCCCTGGACAGCCGCACCATCAGCCTGCAGCTCTCCAACTCCTTCGACCTCATGGAGCTCATTGAGCAGTACAACATGCAGCTGGGCTGAGCCCACCTGCCCCGCTCCCCATGGCCCTGGCACAGGCAGCAGCACCAGTGGGCATCCAGGCTCTGCAAACCAGCACCCCCCAACCCAAGGACAACTTCAGTGACCAGTCCTGGAGCTCACACATTGCTTTTCCTCTCTGTCAGCTTCTAGTGTTGTGTTTTTGTGGAGGGTGGTAATTTACAGATTTATTTTCTTAACTTTTTCAAGCTAAAATACATATATATATGGGATCGTAGTTCTCTCTTGCCTGGAGATGTGCCTCTTCTATCAGTCTGAAATCTTCACCACCCCTTTCTACCCCCAAAACCACGGGGGTCCATGCCCAGCCTTGTCTCAGCAAAGTCCCTGCTGGCAGGGGTGGGCTGGTATCAGAGAGCTTTATTAGCACCTTCTTCTCCTTAAATTTGAGTGGATGAGGTGACTTCCCAGTGTGAAGGGATACATTTATCCATGCATTTATTTCCATGCATTAAGGCTGCAAACATGACTCGCAAGCAGAATGTGTTGAGGACAGCTTGGCTTGGGCTAAACAAAAGTAATTCTTCATTGAGCACTGCCCAGAGTTACTCACTGGAGATGTTCTGGAAAAATAAGGCAGTAAGTACAACACGAAACACCCAGACCACCAGCTCAGAGGTGCAGAGGGGGGTGGTATCTCAGGGAGGAGTGTGGAGACCAGAGGGCTGACTGAAGATGGGGTGTGCCCTCCCCAGGCTGCAAGCAACTGCACCCCCTCCTTTCAGGAGCCTGACCATCACTGTTGGTCCCTGGGCAAGGGGAGGAAGCAGTGTCCTTACCTGCCGAGTGACCTGGATGCTGCTGGGCCCAAAGGTGGTGGTCCCGTAGCTTGTCACGTAATAGTGAGCAGAGGGCTGTGCTGGGGGCTCCTCCAGTGGCCTGGGTACTGTGGGAATGGGACACCCTTAACCCCTCTGCTCCATGAAACCCTCAGCCCTCCTTCCTCTGAGCACAGCTGTGGCACAGACTCGGGACACCGGGCTCACCTTTGGGCAGGAGCAGCTCTGCACCAAAACAATGCCCACACGTCCCGCAAGTTTTAACGTCTTCCTTTGTCCTGTGGAGGAAAAAGCCCAGGAAAGAAGGAGCAGGAGCTGCTCTCAGCGCTCCCCATGGAATATGATGCCGAGGCCATGGAAGAGGCTTGCTCTTCCCACCCTGACCTGAGGGGCAGCTGTTGGTGGACAGCCGCTGCCCTCCCAGGTGCCTGAGCACCTTCAGCTCTTCATGAAACAGGGACATGTGGGCACATGTCCAGAGTGAACATTCTGTGCCTGAGCCCCAGAGTCTCAGCTTCTTCACTTTTCCCTCCATGCTCCAGTTTCCCACACCAGTAAGTGTTAACACCACTTGGGACAAGAGCTGCTATGGTTGGGAGAAGGGCACCGTAGTGCCTGGTGAGTTTCACAACTGATTTCACATGGCTTTTAAAAGCTAACCAGCTGCACCAGCATTGCAGTAGTGGCCACCCAGGTCCCACCCTCACTTGGAGGGCACAGTGTACGTACGTGGCACCTGTGCCATCCATGTCTGGCCAGAGGAACTCTGCGGGACAGCCGGACGTTCGGCAGGGAGCCTTCACACACACATGCAGCCCCGGCCACTCCTCAGCGAGCTTCTGGATGATGAGCACAACTGCCACAAGGAAGTCCCAGGCAAACTGGAACCCTTCCAGGCAAAAGGAGAATGTCTCTTTCTTACAGCCTCCAGCCACAGCAGCCCAGGAGATTCTGTTGTGACCCACACATAATTTCCAGCCCACAGCCTCAGCTGTCAGACCAGCTCCATCCCCAGTTAACCAAACTTCCATACGGAATTTAATGGTATGTTGGAAGAGCTCCCCAATTTGGGTGGCCCTTTTACTTATCAGTGGAAGACCCAGCCTTAGACTGTTCTCTGCTGGAGCCTTCTGGGGAAGGACGACCCATTTGCTTCATGACGAGAATGAAAACTTGGCTTTCCACTTTCATGTGATACCTCTAGAGGAGTCCTGACCAGAATTCGATGGAGAAAGGGAAAACCTTTAAGTGGACTGCTGGTGGACCCAGGCCAGACTAGGACATGTGGCAAAGGCTTCCTGGGACACTTCCCATAGGGCTGGAAGTGGCAGGAGCAGAGCTAAGGCAAGACATGGGGTTGGGAGTAATGAAATATGGATCAGGGATCTTACCTGTCCTTTCTGATGGCTTTCTGCTGCGGAGCTCCAGGTAGCTGTAGGCCCTCTGGTTATTCTCTTTGATCAGCAGGGGTTTGCCATTGCATACAAGCAGGCAGGTCACCTTGGCCACCCAGTGCGTGGAATAGAAGGAGCAAGCTTTCACCAGCAACCTGCAAGGAGATTGTCCATGGCTTTCATCACTTTTCTCCTAGCTTATCCCTAATGCTGGAGAAACTGGATGGACTTGAAAATATGAACCAAGTTGCAGTAAGAACAGACACAAAATGAGGACCTTCCCCTGCTGAAAGCTCAAGTAGCAGGAGCAGCCTCTTAAACCAAGAGATCTTTCCAGAGTTGGCCATTTTGTCCTGGTTTTGTCTGGGATGGAGTTAATTTTCTTCCTAGTAGCTGGTACAATGCTGTGCTTTGGATTTAGGATGCGAATGATGTGGATAACACATCACTGATGTGTTAATTGCTGCTGAGCAGGGCTTACCTCAAGTCAAGGATTTTTCAGGTTCTTAGGCTGCCCTGCCAGTGAGGGGAATGGGAAGGGACAGCTGACCCCAAATGACCAAAGTGTTATCCCATACACAGTAGCATCATGCTCAGCACATAAACCTTGGGGACCATTGCTTGGGAACAGGCTGGGCATGAGTTGGTTAGTGCTGAGCAATTGGTTTTTATTTGTATCACCTGTTCTTCGGTTGTATTTCTCTCTTTGCTGATTTCCTTTTCATTACAATATTATTATTGCTATTACTGTTATTATTATAATTTATTTCAACTATTAAACTGTCCTTATCTCAACCCA
->XM_037981260.1 PREDICTED: Kryptolebias marmoratus origin recognition complex, subunit 1 (orc1), transcript variant X4, mRNA 
-CCCCCACACACACACACACACTGTCTGGTTTTGTTATTTCCTGCTTTGTTGGCGTTCCTGTTTGGTTCTCGATACGTAACACGTCAGAAAGAGCACAGGAACTGATGAAGAGACCCTGGTAGATTTTTCAATCTTTTATTATTAATTTTAAATTAGTGCAAATTCTTTACTCTGACTTTGAAAACAAGCTCCTTTTGTGACTTTATTTTGATTCCTGTTGACTTCAAAACACTTTTTGTTTCACCTTTAATCACTTGCACCATGTTCCCTGAAAGTTTAATAAAGACAGACAGACGGATAAAGAACTACTAACCTGGTTAAAAACCTGTTTTGCTGTGACGCTGTTGCGCTTCACCTTCCGGCCTGCAGGTGGCGCCAGACGCACCAATTAGCAAACCGGAAGTAATCAGCACAAGCAGAAGAAGAAATTTTCCCGCGAAACGCCGTCCCTCTGCCGTCTTCAAACGGCTCCAGTTAGTTTTCTGCGGGTTCTGGTTTGGAAATAAACGCGGATTTTCGATCAGAAGAAGACATTTTTTTTTTAATTTTCCGGGTCAGGTTAGCGAGGACCGGGATGAAATCTTTCGGCAGATTGAGAGTCAGGAGGTTTTATACATGGAGAGGAAATCCTCTGAGTTCCAACAGGAAGCTGCGGACACACGAATATGAGTCTTTGGCCATCAGGGTGGACGGGCTCCCGAGGACCACGGTCATCAGAACGGGTCAGCACATCCTCATTGAGGGCGACGACGACGACAACCCGTTCGCGGCCAAAGTCGTCCGGCTGTTTGGAGACGAGAGCGGGCAGCAGAAGAAGGCCGTGGTTCAGTGGTACGTTCGAGTTTCTGAAGTTCCTCCGAGCAAACTGAAGCTGCTGGGCAGAGACCCTCACCCCCGGGAGATCTTCTTCTACCAGGGAGGCAACTGCGACGACGAGGTCAACGCCGAGTCCATCATCAGACCCGTGCAGGTGAAACACCTGGATGCTGACGCTTCATTCCCCCCCTCTGATGATGGTGATGATGATGAGACGCTCTATGTGAAACTCGCCTGGGACTCGAAGGTCTTCAGGATCCTGGACTCGGCTCTGGTGGCGTCTCCTCCTCGCCATCCCAACCCCTCCCTCCCCCCGTCCCCCCCACGCTCCCCGCCTGCTGCCACCCCGGCCTCCAGGACCTCGAGTCGATGCACCCTGCCCACGCCAGACCCCACTGTGCTGCGCCGAGCCGCGCTGGGGGAAGTGAGACGCAGCCGAGCCGCAGCAAGCGCCGGTAAAAACCCCGCCGCCATGGAGGCGCTTCACTCAGAGACCAAACTGTCTGCGTCAAAATGCCTCAGCGCCAAGAGGAGGCATGGCACGGAGAGGACGCCAGGCGTCCGCAAGAAGCTGCAGCTCTGCAGTCCTGAGAAGACGGTGATGGTCAGAGAGGACGCCCTGACCCAGCTGCTGGACGAGGAGCTGGAGAAGGAGAGGACACTGGCTAAAAGGGTGCCATCCTCCCCCGCTCGGTCCCCCACCCTCACCCACAGACTCACCCCCCTCAGGAGGACCAACAAGAGCCTTGCCGCTCAGGACGCCGTGTCCCTGAAACCGTTCGTCATCACCTGCCGCAAAGTGCCCCTGAGTGAGGTGGAGTCTCCAACACCGACCAGAGACAACTCGAGCAGAGCTGCGACAACTCCTTGCACGAAAGAACCAAAACCTGTCAGAGAACCAGCTCTGGGTGATCTAGCTGAGGAAGAGGCCAAGAACTCCTCGCCGCCCAGGAGCTCCAAGAGGAAGTCGGCTCTGAAGGTGTCGTATCGCATCAGGAAGCAGCTGAACCTCATGGACGGCCAGCAGGACCTGAACTCTGACGAAGATGATGAAGACGAGTTTGTTCCGTCAAAGGAGCTGCAGAGCAGCAGCGAGGAAGAGGAGGCAGAGGTGGTGGTGAAGAAGAGCCGGGTGTCCTCAGCGGGGTCCCGCACGCCTCGTTCCTCGACCCGAACGCCGAGGAAGACTCCGAGGAAGAACGCACCAGGAACGCCGCGGACCCCCCGGAATGCCACGCCCAGCATCCCCAGCAGGTCCCTGCCGGCCAGACGGCCTGCCAACGTTCTGGAAGAGGCCAGAACCAGGCTCCACGTGTCCTCGGTGCCCGAGTCTCTGCCCTGCAGGGAGCAGGAGTTCCAGGACATCTACAGCTTCGTGGAGAGCAAGATCACCGACGGCACCGGGGGGTGCATGTACATCTCAGGTGTGCCGGGAACAGGTAAGACGGCCACGGTGCACGAGGTGATGCGCTGCCTGCAGCACGCCGCCGACACGGACGAGATCCCGCCGTTCCACTTCATAGAGATCAACGGGATGAAGATGACGGATCCTCATCAGGCCTACGTTCAGATCCTGCAGAAACTGACGGGTCAGAAAGCGACGGCCGATCACGCCGCGGCGCTGCTGGAGAAACGATTCAGTAACCCGGCACCAAGGAAGGAAACCACCGTGCTGCTGGTGGACGAACTGGACCTGCTGTGGACGAGGAAGCAGAACGTGATGTACAACCTGTTCAACTGGCCCACATGCCGCCACGCCCGCCTGGTGGTTCTGACCATCGCCAACACCATGGACCTGCCCGAGAGGGTCATGATCAACAGGGTGGCCAGCAGGCTGGGTCTGACCCGGATGTCCTTCCAGCCCTACACCTTCAGGCAGCTGCAGCAGATCATCACGTCACGGCTGAACAAGGTGAAGGCCTTCGAGGAGGACGCGCTACAGCTAGTGTCCAGAAAGGTGAAGCCCGCCCCCTCACCCGTCCCACAGCTCTTGCCCTGTGTCGGATCGCTCAGTTCTCTCCTCCGACAGGTGGCGGCTCTGTCGGGCGACGCTCGGCGGTGTTTGGACATCTGTCGGCGAGCGACAGAGATCTGCGAGCTGTCTGCTGCAGGGCTGGTGGGGATGAGTCACGTGATGGAGGCGCTGGATGAGATGTTCTCCTCAGCTTACATCACTGCCATCAAGTGTGCGTCGACGCAGGAGCAGCTCTTCCTGCGAGCCGTCATCGCTGAGTTTAGACGGCTGGGGTTGGAGGAGGCCACCTTCCAGCAGGTGTTTGTGCAGCACCAGGCTCTGTGTCGGGTGGAGGGTCTGCAGCCCGTCGGCGTGTCGGAGGGCCTGGCCATGTGTCAGCGTCTGGGAGGCTGCAGGCTGCTGCTGCTGGAGTCCAGCCGCCTGGGAGTCCTGCAGAGAGTCCGGCTCAACGTCAGCCAGGACGACGTCCTGTACGCCCTGAAGGCCGACTGACGAAGGAGAGTCAGCTCGGGTCCTGACGGAGGCAGAACACTTTACATACTGAGACCTAATGTGTTTACTGCAGATTTTCTTTTTTTGTTTTGTTTTGTGGGAGACTCTGTGACGTCCCCGGTTTTACCTGGACTGTCAGGTTTTACTGCTCTCATGGTTCTTTTATTGTTGACTTTTATATTTTTATGTTTCACTATTTGAATATAGAATAAAACAGTTTTAATATAAAGAAAATTCCTTTTCCCTCATCCATAAGCTGTGAAGCATTCACACGTTCCTAAGA
->XM_018492714.1 PREDICTED: Trachymyrmex septentrionalis FAD synthase-like (LOC108752090), transcript variant X3, mRNA 
-TGATATTGTCACGAAATTTGAAGATATTACTGAGGATGATAGAAAACTACTAGTAGATCAATATGAATATTTTAGTACAATGGACATTACACTAAAGTATGATAATTGGCGTCGTGATGTGATATTAAAATCAATTCTCCCAGAAGATATTGAAGTTCCTACAGCGTACAGTTTAGTAGGACATATTGTACAGTTGAATTTACGTGATGTACATTTGCCATACAAATCTATTATTGGTCAGATATTTCTCGATAAGACTGCGAATGCACGAACAGTAGTAAATAAAATAGATACAATTAATACATCGTTTCGATATTTTGCTATGGAAATCCTAGCAGGTGAAAGAAATACAATAACATCTGCAAAAGAACATGGTTGTACATATCAGTTTGACTTTGCGCAAGTGTACTGGAATCCACGTTTATCTACTGAACATTCACGAATTATAACATTTATGACCGAAGGTGATATTCTATATGATGTATTTGCAGGAGTAGGACCCTTTGCAATTCCTGCCGCACGTAAAAAAGTCCAAGTATTTGCTAATGACTTAAATCCTGAATCTTACAAATGGCTTCAAAAAAACGCTCTTATTAACAAGAACAATATGTCGCAACAAATACGTCATTTTTATACAGCAAGTTTGATAGTTGTAGGAGATGAAATTTTACGTGGACAAATAATTGATACCAATACATCATATCTGGCACAAAATTTAACTGCTGCTGGAATAAAACTACAGAAAGTTATAATGGTCTCTGATATCGTGGATGATATTGCTAAAGAAATACGCAATACATCAAAGGAGTATTCTGTTGTATTTACATCTGGTGGTGTTGGACCTACTCATGATGATGTAACTTATGAGGCTGTAGCAAAGGCTTTTGAACTAAAACTTGAATTAAATCAGAAATTATTTGATATATACACTCGAATGATTCCTAATCAGGCCGAAATAAAACGACTTGCTATTGTTCCCAATGCATGCAAGATTATCAACATTGATTCAGAGGCTTTTCCAATAATAAATATAAAAAATGTTTACGTGTTACCTGGTTCCCCAAAGTACTTTAAGCCTGCTGCAGATACAATAATTTCTCGTTTGAAAGGAAGCACGCCATTTCACTTTGAACATATAGATATTGCATTGAATGAACTATCAATAGTAAACATTTTAGATAAACAAGCAAAACGATGGGATGGTAAAATAAAAATTGGTAGTTATCCTCAATATGAATTGCAAACATCTTTTACGAGAATCACTTTAGAAGGACCTGAAGAAACAATTGCAGAACGATTGCTAGGATGGAACGTCCCTACTGAGGAACTGATTCATATACCAGAACATTGGCTGATCTATCCTGAACCCAATCCTTCTCTTCACTATTTACTAGCCATTCTATACATAATTTTCACCTTTGTAGCGTTACTCGGAAATGGACTTGTTATCTGGATATTTTGCTCAGCCAAATCGTTAAGAACATCTTCAAATTTGTTTGTGGTGAATTTGGCATTTTGCGATTTCTTCATGATGCTCAAGGCACCGATATTTATATATAATTCCTTTAATACCGGATTTGCTACTGGTCATTTAGGATGTCAAATCTTTGCCTTTATGGGTTCGCTTAGTGGAATTGGAGCTGGTATGACAAATGCTGCTATAGCGTATGACAGATACAGTGTTATAGCTCGACCACTTGATGGGAAACTATCTCGCGGTCAAGTGATACTCTTTATTGTACTTATCTGGGCGTACACAATTCCATGGGCCTTGATGCCAATAATGCATGTCTGGGGTCGATTTGTGCCTGAAGGTTTCTTGACAAGCTGCACTTTCGATTATTTGACAGATAGTCCAGAAATAAAATATTTTGTGGCCACGATATTTACCTTCTCTTATTGTATACCAATGTTACTCATCATATATTATTATAGTCACATTGTCAGCCACGTTATTGATCACGAGAAAGCTCTTCGTGAACAAGCAAAGAAGATGAATGTCGAAAGTTTGAGAAGCAATGTCGGTGCAAATACTCAAACTATGGAAATACGTATAGCTAAGGCTGCAATAACAGTATGCTTCCTCTTTGTTCTCTCGTGGACTCCATACGGAGTTCTCGCGATGATCGGTGCTTTTGGAGATAAGACATTATTAACTCCTGGTATCACAATGATACCGGCATGCACATGTAAATTTGTGGCCTGTTTGGATCCATATGTATATGCCATAAGTCACCCAAGATACAGACTAGAACTGCAAAAACGATTACCATGGTTAGAATTGCAAGAAAAATCTGTGGACACGCAGGGTTCTACATCCGAAGTAGTGAATATGCCATCATCTTAAATCTTGTTTAATTTTATCTTAAACAGTAACTATTTAATTATGAATGATCAATTGCTATAGTCATCATTAAGATTATGTTCTTTATTACTGCAGTAATAAAATGATTGCGTAGTCTATATCAATGTAGTTACAAGTAATTGTAAATATATAAATGTGAATAATGTAAGCTCTTAATAAATACAATATTGTTCAATCTTCCTATTCTTTGTTACGATCATGTTTATTGCTAATGTGTGATACTTCTTATCTGTTACATAAAAGACAATATTGACATCAGGCGTGTAATTGTA
->XR_002250031.1 PREDICTED: Pseudomyrmex gracilis uncharacterized LOC109852741 (LOC109852741), ncRNA 
-CAAAAACATTTTGAACTATTTCGATTTATCCGCGTCGAAAAGTTCGTTCCACGTCGCGACACGACGTATCTCGTGATAAACTTTCGATCGTAAAGTGTATTTTCGCGAAATCGTGCCTCGGATTGTGTAAATTGTATATTTTGTGCTAGTGATATCGTAGTGACAATTCAGAAATATTGGGCAAAATTTTTATCTTTATCACACAGGTCCTCGTTAGAAAACGGTCAACCGTCGATGCAAGAATATAGAACGAGAATGCCCGCATGGAATTCCCTGAATCTCGCAACTATGCACGCGCAATACTGTGAGTGTCACCTATATGCCGGAGAATGCGATTACATTTGTGAAAAAGGAAAACCTCTATTTTCGAGGCCAATACACGCGAGGGGCGTGTAATTCGTCGTGTAAGCACGTC
->XM_050446992.1 PREDICTED: Anthonomus grandis grandis uncharacterized LOC126740808 (LOC126740808), mRNA 
-ACTATTGTTGCTATAAGGGGATTCTACAAAGAATTGTTTATTGTTATAAGATTTAAAAAAAAGCGCACTCTTGCGGCGCGAACTTGTAGTACATTAAAACTGTTGACAGCTGTCAATTAATATTGACAGTTTGTTTTTTCAGTAAAATTTAAAAGCAGTTTCACAATTTCTGTGATTAAAAGTGACGTGTTTTGATCAATTATAAGCCGGGACAATGAGTAAGAGCCACAAAACGAAGCATCACGAAGATCCCAGTCTGATCCCCACTTTTATGAGCGATGAAATGCACGCGGGGGCCAGGAAAATGAAAGCGGGTCCTTCGGCTGTAGCTTCGATGTTATATCCACATGCCGCGACTTCTATTACTACCACAACCGGTGTAAGGAAGAAAGAAGAAGATTTAGCGAATAACGACGAGTTGACCGATGACGACATGGAACGTAAAATGGATGGTACATTACGCAAGGGACCCCCGAAAGAAAACATTCAGGTGGATGGGAAAATTAGCATCCTTACAAAAATTGAAGGTAGGAGAGAAGCCCTCTGTTGCAAATACAACGAGGAGTACGACTATATCGCAGTGGGTTACGCTGACGGGGTGATCGTCATGTACCAAAGTTCCACGGGCGAACCAGTTTTCACTTTAACAGACGCGGACGTGAGGGAGAACAGGGCGCCAGTTACCTCGATCAAGCATCGACCTGTATCGAAAATTTACCCCATTACCAACTGTTACACCGGGACCTATGCGAACGGTTGCGTTAAATGCTGGTCCTACAATTTCAACCAGTGCCTCTATACCATCAGGGAGAAGCGACAAACTTTCGGGATCGCGTATCATCCGCGATTCCCGAAATTCGTTACGTTTGGGGACGATATGAAGGTTTATTTTTATGACGAGGAAACGAAGACGCAGGAGAGGGTGCTATCGTCCAGTGATAATCCTGATACGCACGACGGTCACATGTCCAGGGTATTCGCCGCGTGTTTCCACCCGAAAAACAATTACGAACTTTTAACGGGTGGTTGGGACGATGTCGTTCAGTTTTGGGATCTGAGACAACCGCATGCGGCCAGGCACATTTCGGGGGTTCACATGTGCGGAGAGGGCCTCGATATTAGTCAGAAAGGGACTGAGGTGTTGACTTGCTCCTGGCAAAAAGAGGATCCTTTGCAAGTGTTTGATTATAATACGACCAAAAGGATGTACTGTTTAGAACCGGACATTTATAACACTAAGCTGTATTGCGGTAAATATGCCACCAAAGATTTTGTGGTGTGTGCAGGATCCGATCCGAACCTTATACGTGTGGTGGACTTGCAAACGACTGCAACTTCGGCATTTATAAACCAATTACCGGGAGCCATTTACAGTTTGGATATCGGTCCGACGAAAGCGAAAAAAGAAGCAAAGTTGGAAAAGTACAGCGTTAAAAACGACATAACGAACGTACCGAAAATGGTCTTCGTATCTGGTAAGAGACTTTACCAGATCGATTTTTGTTAATTTAACAACGAATAAAACGCATGTGTTGAAACAAGAAAA
->XM_028067949.1 PREDICTED: Vigna unguiculata protein IQ-DOMAIN 14-like (LOC114181480), transcript variant X1, mRNA 
-CTTATTTATTCATTAAATTTCTTGAAGTTTCGTTGTTCCCTCCTTGCATGTTCCATGGACAAGGTTTTTGTCATATATAGCAGATTTTCACGAGCTTTTGACAGAGTATTTTCTTTTGTTTTGTCTCCTTTCAGATAAAATCATCACATAGTAACATAGTTGAACTGTTTCTTGCAGTGAGGGCAGCAATGGGGAGAGCCACAAGGTGGATGAAGAGTTTGTTTGGGATTTCAAGAGAGAGAGAGAAGAAACAAAACATCATAGAATCTGGTTTTTCTGAGAGTACTAATAATTCAAGAGTTTTGTGTCACAACCCAGGAACTATACCTCCCAACATTTCTCAAGCTGAGGCAGCTTGGTTACAGTCATTCTACACAGAGAAGGACAAAAACAAGCACGCCATTGCGGTTGCTGCGGCCACCGCAGCTGCGGCTGATGCTGCCGTGGCGGCAGCACAGGCCGCCGTGGCAGTTGTTAGACTCACAAGCCAAGGAAGGGGTGGCACCATGTTTGGCGTTGGACCTGAGATATGGGCTGCTATCAAGATTCAAGCAGTGTTCAGAGGATACCTGGCAAGGAAGGCACTGAGGGCATTAAAAGGATTGGTGAAGTTGCAGGCACTTGTCAGAGGGTATTTAGTGAGGAAGCAAGCAACAGCAACACTGCATAGTATGCAGGCTCTTATTAGAGCTCAAGCTAGAGTACGGTCCCACCAATCTCGCAGGCTCATGAGTACGAAGAATGAAGCATTTAGATCTCAAAATAGAGCAAGAAGATCCATGGAGAGGTTTGATGATACTAGGAGTGAGTATGCAGTTCCAATCCACAGTAGACGAGCATCATCGTCTTTTGATGCTACACTTAACATCAACAACAGTGTTGATGGGAGCCCCAAAATAGTGGAAGTAGACACTTTCAGGCCTAAGTCAAGATCAAGAAGGACAATATCAGATTTTGGTGACGAGCCATCACTTCAGGCACTTTCATCTCCCTTCTTTGCAATTTCATATAGAGGTACCCCTACCCCTACCCCTACCCCTACACGTTGGTCCATACCAGATCAAAGGAATTTTCAGGACTCTGAATGGGGGTTAACAGGGGAAGAATGTCGGTTCTCTACAGCACAAAGCACTCCACGCTTCACAAATCCTTGTAGTTGTGACTCAGTTGCACCTATGACACCACAAAGTGGGTGTCCTGATGATAACTTGTTTCTAAGGCAATATGGGAAATTTCCAAACTACATGGCTAGTACTCAGTCTTTTAAGGCCAAGTTGAGGTCTCATAGTGCTCCAAAGCAACGACCTGAACCTAGTCCAAGGAAAAGGCTCTCCCTCAATGAAATGATGGAGTCTAGGAGCAGCTTGAGTGGTGTTAGAATGCAGAGGTCTTGCTCAAAGGCTCAAGAAGTCATTAGTTTCAAGAATGCTGTGATGGGAAAGCTTCAGAAATCCACAGAATCTGTTAGGGAAACAGACAGAAACTATTTCCATCAGAGAGGGTGGTGACATGCTGAACTTGTTAGGACAGATATCTAGCTATCTTTGTTCTTTAAACTGTTAAAGTGTTAATAAAATATATTTCTCCCCCAGTTTGGTAATTTGCAGATACATATAGGTGGTGAGTGTGGGAATGTGAAGACAAAATAGAAGGCAAAGATAGAGAGAGAGAGAGATGCCTCTCATTGTTTTGTGAAAAGTTTGGCTTTGGAATTTTGATATATCATCTCTCTGTAGTCTATTCAAATGCAAGGATTTTAACTT
->XM_043209237.1 PREDICTED: Drosophila ficusphila oxysterol-binding protein-related protein 8 (LOC108093331), transcript variant X2, mRNA 
-AAAAACAGAAAATAACACGAAAGCTTGTTTCGCCTTTTCACTTCCAGCGTCTTCGGCCGCGTCATGAAAATAATACTCGCCGCCTGTTCGATGGGTGGACGGTCGGTTGGGGGAGGGTGGTGACGTCGCCAGCGCTGGTGGATGAGCTCATACGAAAGCGAAAAGAAACAAGTTTAGCTTTTTGGAATACGGACGACTGCAGCCTCAGTTCATTCGAACGCCGAACGCCAGCGACGCCGGACCGTTAAAACGAGAGAGCAAGAGAGCCGCGAAACAAAAAACGAAAACCGAAAAAAGCTATCTATAAAGTCTTTGCAAAAAGCCCAAAATTGTTGTGCAAAAAAGCGAGGAAGGCTGAGACTCTTGAGCGGCTAAAACAAAATCAATAATTGGCCCTGCGTCCAGCGCTATATGTGTGTGTGTGTGCGTGTGAGAGGGGGAGTGTGTACGTGTATTTGTGAGAACGACAATTGGAGCAATGCCTGCTGATTGATACGAAAAAAAGGGGGAAACCAATTACAAAAGAACCACAGAAGCGAAGGATTATAATAACTATTTTGTGCAATAATTAAGTGATCAAAACCATGCAACCCGCAACGCCCGGAACGCCTGTTAATAATGCTCCCTCGACGACTAATTCATCGGCCACCCCTGCCGCTCCCGCCGCCCCTGCTGGCGGGGGGGTTAGCAGCACTCCAATACGCATAAACAGTGCCAAGCAGCACGGGGCGGGGGGCGGTGACTCGCTGGCCCCCTCCACCCCGCACTCCCATTCGATGCCTGGAACGCCGCAACAACAATCGAGCAGTGTGCCCACGGGAAGTCAACTGCTGCATCTCCAGGCGCCGCTGCCCTCGGCTGGGGGAGGCGGGGGAGGATCAGTGACCCCCTCTGGCCTGTCCATGGGCGCCTCGAATCAATCGCTGGGCGTTAGTGTTGGCGCCGCCAGCAGCGTCAGTGGTATCAGCATAACGCCGCCGAATAGCGCCGGATTGCGTCAGTCGACAGTATTCGATTTCAAATTCAAACGGCGACCTTCGCTAAAAGTGCTCATGACCAAACTTCCGTCCACGGACAGTTTGAGTAACAGTCCGGCGCCGTCATCGCCAGGAATCGCCAATTGGGCCTCAGACAATCGGGATGGCAATCTGGCAGATAAGTCTGCTGCTGATGCCGCCAAACTTAATAGGAAGGAGTCCTACAAGGCGCAAAGGAAAAACTACAGGCGGGAGAAAAAGCGAGTGGCCAGTGAGCTGATGAACTCGCTGCAGGATCCTGCGGTTATTGTGCTGGCCGATTGGCTGAAGGTTCGAGGAACCCTAAAATCCTGGACAAAACTCTGGTGTGTTTTGAAACCGGGCCTGTTGCTTATTTACAAGAGCCAAAAGACAAAGAGCAGTCACTGGGTGGGCACGGTGATGCTCACCTCCTGCCAGGTGATCGAGCGTCCCAGTAAAAAGGATGGCTTCTGCTTCAAGCTTTTCCATCCCCTGGAGCAGTCCATTTGGGCACCGAGGGGTCCAGACAAGGAAACCATTGGTGCCGTTGTCCAACCGCTACCAACCGCCTACCTGATCTTCCGAGCTCCCAGCCAGGCGGCCGGCAAGTGCTGGATGGACGCCTTGGAGCTGTCCCTGAGATGTTCGGCCCTCCTGTTGCGTTCCAATAGCAGCACGGGAGCTGCTCCTTCGTCCAGCTACGTGGGTGAACCGCTGCCCGTCTCCCACGAGACGCAATGGTCGGAGGCGGACTACGAGAAGCACTTCAACGATCACGATCTAGACGCAGACAGCCAGAATGAAGCACCCAATGCCGTCATGTCTGGTCTGGAATCAGAATCGGAATCGGATCCGGCTGAGCCGGCGCAGGAAGATGGCGTCGAGCAGCCTTGTGAGGAGACGTCGTATGTGCCCTTCACCGAGGAGGAGTTTGGCGAGCAAGGGGAGCAGGTAGAGGAGTTGGCAGAGGAGAACAAGAGCCTAATTTGGTGCATTGTCAAGCAGGTGCGACCGGGAATGGATCTGAGCAAGGTAGTGCTGCCCACTTTCATCCTGGAGCCGCGTTCATTCCTGGACAAGCTATCAGACTCGTACTACCACGCGGACTTGCTCTCCAAGGCCGTGCAAGAGGATGATGCTTTTACGCGCATGAAGCTTGTCGTGCAATGGTACCTGTCCAGTTTTTACAAGAAGCCCAAGGGCCTGAAGAAGCCCTACAATCCGATTCTGGGCGAGCGATTCCGCTGCTATTGGCAGCACCCCAGCGGCAGCCGGACCTTCTACATCGCGGAACAGGTCTCGCACCATCCGCCCGTCTCGGCGTTCTACGTGACGAACCGCGAGGACGGCTTCAGTATCACCTGCTCCATCCTGGCGAAATCGAAGTTCTACGGCAACAGCACTTCGGCGGTGCTCGAGGGCGCTGCCACGATGACGTTGCTGCCGCGCGGTGAGTGCTATACGGCGACCACGCCTTATGCCCACTGCAAGGGCATACTGATGGGCACGCTCTCCATGGAGCTGGGCGGCAAGATAAACATCGAGTGCGAGAACACCGGTTACAGGACGGAGCTGGAATTCAAGCTGAAGCCGTTCCTCGGCGGCGCCGATGCCACCAATGTGGTCGTGGGCAAGATCAAGCTGGGCAAGGAGACCCTGGCCACCATCAACGGGCACTGGGACAAGGAGTGCCGCGTGAAGGACTCGAAGACGGGGGAGGAGACGTTGCTATTCAAGGTGGACGCCGAGACGCGTTCCAAGCGGCTCACCAGATACCTGGTGCCGCTGGAAGCGCAGGAGCCCAACGAATCGCAACGTATGTGGCAGCACGTCTCCGAGGCGATTGCGCGCGAGGATCAGGTGGCCGCCACCGAGGAGAAGACCGTGCTGGAGGAGCGACAGCGGGCGGAGGCCAAGACGCGGGCCAGCACCGATTCCATTCACATGCCGGAACTCTTCGAGCTGGACAGCTACGGCCAGTGGCTGTACAAGTACGCCGATCTGCGGCCCTGGGACTCGCGCAACGATGTCCGCCAGTACGAGTGCCAGTTCAAGGTGCTCACCCAGACGCGACACAAGTCGGTGCCCATTGTCCACGGCGCCGAGATGATCCATCCCCTGCGCAGCTCCTTGGAGACGCTCTCCCGCACCCAAAGACAAGCAGGACAGGCCATATCGCCGGGCGGCTCCGCGGTGCCCAAGGCCAAGAACAAGAGCCTGGTGTTGGCACCGCGCGATACCAACTCAGACTCCAGCCAGTCGCCGCAGGGAGCGGTCAAGCGCAGCTCCTCCAGCATTAAGCAACTCGCCTTGGCAGTGGACCAGGTGAACCGCGTGCTGGAGGTCCACACCCGGCAGCTGAACGAGATCAGCCAGCGCCTGGAGCGCATGCAGTATTCGCCTCCGGCTAGCAACATGAGCGTGCAATCGCATCATTTGCTGGGCGGCGGCGTTTCGCAATCGACGGTGATCAAGTCGCTGATCTACGCTCTGATCGGGCTGACCTTTAGCCTGATCCTGCGATGGCTGTTCAAGTAGACAGGCGGAGTCCGTCGTTGTTGATGTCATTTCTTTTAGGCCTAAGAAAACTTTTGGTCAACCTATAGATAACAAACATATATATAAACACCCTAGAGTACAGACAACGTATATGCTTTACTGAATTGTACATTTGGTCCTACTCAAATGCCTTCGCACGCTGCCAGAGATTCAAACCCGACCGAGGCGCGTGACCAGAACATCCGTTGTGAGAAAGTCTAATCACGAACTATGTATAAGATTAAGTGTTTGTCGTATGTAAGTCCCAACAATCCAAGTCTCTCCCGCAGACAACGTCCATGTGCAAGTCTCTTCACCATTGTATCCCTCTAAATTCTTTACTCAAGCTAGACCCGTTGGGTAGGTTAGGATGTCGGATATATATATTTAAATATACACATACGTACGAGTAGATGCACCAGATTTCGTAAAAATTCCAATTAAACCGATTATAGTTCGCTTTTCCGTTTCCTTCTATATACTGTTATTGTTAATGACACGACTTAGGGTGGAAAATGAGGATAATATGCTCGAGAGGCTTCCTGCCCTTTAAATCACCACTTATAGACATACCTTAGAGATTTAACGCGAAAAGTGCTTATAATAACTAATTTTAGTATCTCTTATACACAAATTGTTTTTCCTTTTTTTCCCAATACCTGCAAACCTTAAAACTTAATAAACTTCCCTTTTTCAAATCTA
->XM_007369094.1 Dichomitus squalens LYAD-421 SS1 uncharacterized protein (DICSQDRAFT_149347), partial mRNA 
-ATGTCGCTCCAGGTCAACCTCTCAGGCAGGGAGCTCGCCCAGGCGTACCAAGATGTCATCAATGCCCGCGGCATAGATTGGGCGATCTTCACCTACGACAAAGGATCCAACGATCTCAAGGTGCAAGCAACCGGAGATGGAGGTCTCGAGGAGCTTCAGGAGGAGTTCTCGGACGGCCGGATGCAGTACGCCTTTGCTCGCGTCAAAGATCCAAACAGTGAACTCCCTAAGTTCGTGCAGATCAACTGGTGCGGTGACGGTGTGCCCGTCGCGAGGAAGGGTCTCTTCCATACCCATTCAAGTGCTGTCGCCAACTTCCTCCGCGGTACCCATGTTGTTATCAGCGCTCGCAATGAGGCCGACGTAGAGCCATCCTTCATCATGTCCCGTGTCAAGGCTGCGTCCGGAGTCAACTATACGGCTCAGAAAGAAGCACCGCGCAAGTTCGAGCCTATCACCCCCGTTGGTACGAACTATGTCCCTGTAGGCAGACCTGACATGGCCGCCATTCGTCAAGGCCCTGCCAAACCACCACCGGCACCCGCCGCAGCGAAGCCAGCTATCCCAACTGCCGCACGTCCTGTCCCAATGGCTCCCTCGCCTGCTGCAGGATTAGGGAAAGCTCCCGTGGCTAGCAAGGCCCCTGCGGACGCATGGCCGGACGAGTCCAATAGCTTCGCGCCGCCCCCACCTCCGCCTGCTGCTTCACGCCCGACTCCTGCGGCGAGCTTCGCCAAACCTGCCCCTGCAGCTTCTCCAGCAGCAGCGCGGTTCTCTCCCACCGTTACAACTCCAGTTGCCGCTTCAAACGTCCCCACGAAGCCTGCTGAAGAGGACAAGATCGGTCCAGTGGGTACCGCGTATACCCCAATCAAGCTTCAGCCCAAGAAGCTCGTCAATCCGTTCGCCGCGATGGAGGCGAAGAACCAAACTGAAACTACTGCGCCAAGGTCTTCGCCTGCTGGTAGTGCCAAGAAGTTGACTTGGAGCGAGCGCCAGGCCCTCGCGAAAAAGCAACAGGAAGAGGAGGAAGCTCGCGCGAAATCTGCATTCGGCTCTCAGCCTACTCCTCCGCCTACCTCCGCGTTCCGTACTGGTGGGAGTATTCCAGAGCCAGAGGAGGAATTCGAGGCGCCTCCTCCGCCCCCGCCACCTCCCGCGATTGCCAGTGCGAGCCGTCCTATTCCTGTTCCGGAGCCCGAATCTCAAGCAGAGGCTCCTCCGCCACCTCCCCCGCCCCTGCCCCCGCCACCGCCACCGCCCCCTGCTCCTACGGTATATCACGAGCCAGAACCTGCGAGGGAGGCCCCTCCACCCCCACCGCCTCCGCCACCACCTCCACCGCCGCCCGGGCCTGCAGCACCAGTCGCTCCGCCGGCTCCCCCTACACCCGAGCCCCAGCCCCAGCCCCAGTCCGAACACGCTCCAGACGCAACTGCGCATTCGGGTCAAGGCATCTGCGCTATTGTGCAGTATTCATATGAGGCTCTCGAGGATAACGAGATGGACCTCGTCGAGGGCGAGCTCATCGAGCAGATCGAGCAGCTAGATGAAGGATGGTGGTCCGGCGTTGGTGCGAACGGGACGAAGCAGGGCCTCTTTCCGGCGAACTATGTCGAGATCATCGAAGCTCAGGAAGCTCAGGCTGCTACCCCCCCTCCGCCGTCGCCTCCCCCTCCCCCGCCCGCTCCTCCTGCCCCGCCTCCACCTCCCGTTGCTGCCCAGCCGGAGCCGGAGCCCGCGCCCGAGGAAGATCTTGGGTCGTGGGCAATCGCGCTCTACGATTACGAAGCGGGCGAGGATAACGAGATTTCGTTCAAGGAGGGTGATAGAATCACGCATATTGAGGCTGTGTCGGATGACTGGTGGCAAGGTACCGAGCCTAACGGCAATGTCGGCTTGTTCCCCGCGAACTACGTCGAACTTCAAGCTTGA
->XM_039761524.1 PREDICTED: Polypterus senegalus RAB, member of RAS oncogene family-like 2 (rabl2), mRNA 
-TAGAGTGATCTGAATTACGTGCATACATTTTTATACCGCTGAAGATGTGCAATGCTTTTACTGGACATTTTTATATAATTATTTTTTCTTCCCGATTGCTAACATTGGCATATGTGAATGATAAAACAAAAAACGCCGGCTTTTGGTATGGCTATTGCCGGAAGTAGACAGCACAGTGGCGCAGGCAGACGAATAGACAACCTACATTTTCCTGTTGAGGGTCCTTTTTTAGCGTCGGTTGCGTAGAAACTGCTGTTGTAAATTTTTGAAGCACTTTCTCAATAACGAAGTATCGCTCAGGCTACATCGATAATTAACCGAGTCGTGGTTAATAGGAGTCCAGTCAAACGGCGCTGCTTTGTATTTTTGTTCAACTGAACAACTTCTAACTGATAATCTTGTATAAAGAGTCGCGACGGTGGAGCAATTTGGCGAATGATGAATGGAAGGGATTTGGTTATCTCTGATGATTAATTAAAACGGAGCAAAAAGAAAAGCCTAACCGGAGAAGTCGAAGGCGGTAGTGGATGAAGGGGCTGTGTGCCCGTATTTAGTTTACCGTAGATGTTCGCTGCTTGCTCCTAAGGTCGGGATCGCGTTTTTACCTCCGCAAAGCCAAAAGATGGCCGAGAATGCTGCTGGTTTTTCCGATCTGAATCAAGATAAGTATGACAAAGATGAGCTTAAAATCATCTGTTTGGGCGACAGCGCTGTTGGAAAATCAAAGTTGATGGAGAGATTCCTCATGCAAGTGTATCATTCCAAAGACCTGTCTACCTACGCACTCACACTTTACAAATATCCAACAACTGTGGATGGAAAAACTATCTTAGTAGATTTTTGGGATACTGCTGGACAGGAGAAATTTCAGAGTATGCATCCTTCTTACTACCACAAAGCTCATGCCTGCATTATGGTTTTTGACATTCAGAGAAAAATAACCTATAAAAATCTTGGCAACTGGTACAAGGAATTAAGGGAGTATCGCCCAGAAATCCCATGCATATTAGTTGCAAATAAAATCGATGCTGACATGAAGGTAACCCAGAAAAACTTCAGTTTTGCTAAAAAGCACGGACTTCCCTTCTATTTTGTTTCTGCTGCAGATGGCACAAATGTAGTTAAGCTGTTCAGAGATGCAATCAAACTGGCATTATCTTATAAGCTAAATTCCTGTGATTTCATGGATGAAGTCATGCGCGAATTAGAGAACTTTGACATGGACAAGAAAGATGACTACTCAGATAAAGAAGATGACAGTTTAAAGGAAGACAACATCAAAAAGACATGACCTACCCTGGTCTTCATAAAATGATTTGGGTTTTAAGCGGAATAGTATCTTATTTTATTTTCCTGACCGTCTTTGAAAGGAGAATCTGTTTGACTGCTGAAAACACACCAGTGAGAAATATACATTACCTAAAATATCTGACCATGATAAACTCTATTCAAATTCAGATTTGTCCCACCAGAAAAAAAACATTGTACTGTGCAGACTCCTATTGTTCCACTTTATGAATTTGAGTCCTGTCAATTGATTTTGTTGCTTTATTTAAAACTGTGAATATTACTGCCACAGCCAAAAGGT
->XM_051965029.1 PREDICTED: Antechinus flavipes proline rich and Gla domain 4 (LOC127540371), mRNA 
-TGAGCCCGCCGCCAGCACCCCGCAGCCAGCGCTCGCGTCCGGTGCCGGGGCAGCCGTCGCAGCAGCAGGTTTCTCCCGGGAGCGCGGCTGAGCGGTGCCGGCTGGCTGACCCGGAATCAGGAGCCCAGGCGCTCAGCCTCCGCCGACCCCGCTGACTTAGAAAGAAGTCGGGGCAAAATCCGGGATCCACCCCGGGCCTGGGAGAGACCGGACGGCCGCTCCGGAGCATGTGCCAGCTGCTCCAGATGCCAGACTATGTTTAAACTTTTGGTTCTGCTCAGCACTTTGCCTGCTATTACTGTTGCGTTTCCTCCCTGCCTAAGAAGTCCCCAGGAGTCTACACATGCTGGAAAAGACGTCTTTACATCAAAAAAAGAAGCCAGCATCTTCATCCATAGACGTCTCCTCCACAATAGATTTGACTTGGAACTCTTCACTCCTGGAGATCTAGAAAGAGAGTGTCATGAGGAACTGTGCAACTATGAGGAAGCCAGGGAGATCTTTGGGGATGACGACAAAACGATGGCATTTTGGAAGGATTATTCAGTTCGAGGACCAAGCACAAGATCAGATGGTGAGAGAGAGAAGATCGATGTTATGGGACTTCTGACTGGATTAATTGCAGCTGGAGTGTTCTTGGTTATCACTGGATTACTTGGTTATTATTTCTGCATCACCAAGTGCACAAGAAGAAGACAGCCATGTTCCTCAGCTGTCTATGTAAGAACGGGTCGACACCATCCAACTATTATTTTTAGAAGACATGAGGAATCTGCCTTAACCCCGTCACCTCTTCCCCCAGAGGATTCAGGACTGCCTTCTTACGAACAAGCTGTGGCACTGACTGGAAAATATGATGTTCCGCCTCCTCCATATCCTGGGCCAGCAAGAGGGTTTAAGGTGTTTAAAAAGTCTATGTCACTACCTTCTCACTAAATCCAATGTCAATATGAGAAATGGATGTTTATTCAAAGAAGGAGCCATGATTCAGTTCTCCAGTAGCTTAAAAGGCTGGCCATTCCATTCCTGTAAAGGTATTAAGATGCCTGGTCTTTTGCTCCAGATAGTTGGACTTTTACTCTGACATCAGAATAATGAGGGAATCGGTTTCATTTTGTGTGGGTATGTGTATGTAGGTAGGAGGCGAGCCCTGATTTAAATTTAGGAGTATCCAGATCATTAGCCCTAATCAGCTAAATTAGGCAAAAGATTACTAATTACTGAAGGAAAAGCCACATATCCACTATAGCAGAAAGGGTTCTAGATTGATTATGTTGAGAACTGAATTAATGTTAATACAAGACTTTTTTTGTTTCGAGTCATCTTGAGTCAAGATACTATATTTTATCCCTGTTTATTTTAATTCTCCAGCAAAAGAAACCTTGTGAAAAAATTTTAAATCGCATGATGAATCAGTGGTCTTTAAAACATAAAAGGAATCCTAATGCTTATTGTATATAAAATAGCATATGATATTCCGTACAGGTATTTGTACTTAAAAGATTATGTCCAGTTGTACAATGGTGGGAAAATACCTTCATTTTTCTTTTGATTCAATGGCTGCTGCCATTAGAACTTGGGGGTCAGAGGTACAGTGAGACAAAGTTGCAGATTATAGTTCTAATTCTTTCCTATCACCAAAAGTGTTTCTAGAACCTAGAATCTCTAGATTCTGTATGAATCTGCCCGTCCCATGAGGAAATAGATGAATTCCGTCTGTATAATTATATGTTTGGTTCATATGAGATTACTCAGGTTGGAAGTTTTATTCTAGCTTATAACTAATAGTTTAATCAGGAAAGGATAATTTATTTATTCTCTTATTATCTATGTATAGTGGTTAAAGATGTATATGACCCTTTGCATCTCTGGGATATGTTTTCTCAGACATTAAAGCACACTTAAAATGATCACTCAA
->XM_019516974.1 PREDICTED: Gavialis gangeticus B double prime 1, subunit of RNA polymerase III transcription initiation factor IIIB (BDP1), transcript variant X7, mRNA 
-ACAAGTTTGTTCTACATGGTATTTCATGACACTTTTTTAATTGTTTGTAGAAATGAAAGGGTGGGTAGTGCAAGTGATGCTGGAGAAGCCATTAAACCTGCAGATGGACCCTTGCAGAGGAGAAAAAGAATATCCACTCTGCCTAACTTGGCAAAACCCAGAGTTACGGCTCTAACTGCACAACGGTTGGTATCAAAGCCTGCTCAAAAACAAGTACCTCAATCTGTCAGTGGCAACACTTCACGGAAGGAATCCTCTGCATCAGATAAGACCAATAGTGAAAGCTCTCCAAAGTCTCCCAATCTGCCTGAAAAGAAAACACCTGTCCCACAAGTGCCACAGTTTTCCCCACTTAAAAAATCAAGAAGCAAAGAGCCAAATGCCAGTATAATTGCTCATAAAAATGATGAAACTCTGCAGAAGAGCACGCTCTCCCCTCTCAAGGAGAGACCTACCCAAGGAAGATCAAAAGAAGATGAAATGTCGCATGCAAAATCTACTCCAGCAAAAGAAAAAAAAAGGTGCTCAGATCGTGAAAGGATCCTTAAAGCCCAGAAGCTGAGAGAGATGCTCAAAGAAGAGCTGAGGAAAGAAAAACTGAAACATGGGAAATCCAGACAGAAGGTGGCTGAAGGTTTCACTGCAGCAGATCGTTCCAAAATGACCATGAGAGACTTGATATACTTCCTGCCACAAAACAATCCCATGAAGTCTTCACTAATAGACGAAAAAACTTCTGCATCAAGCCAAATGAAAGAATCAGAAGAGAAGAGTGCTCCTGTTCATGAAGATGAAGAGGAAGTTGCTCAGGCAGAGGATGAGGAGGAGAATCACGATGATAAGCTTCTAGTTCCTCGAGTGAAAGTGGCAGAAGATGGCTCAATTATTCTGGATGAAGAAAGTTTAACAGTGGAAGTTTTAAGGACTAAAGGGCCAAGTGTTGTAGAAGACAATGATCCTATTTTTGAGCGTGGCTCTACAACTACCTATTCTAGTTTTAGGAAAAGCTTTTACACCAAGCCATGGTCAAATAAAGAAACTGATATGTTCTTCCTGGCCATCAGCATGGTAGGAACAGACTTCTCCCTGATTGGTCAGCTGTTTCCTCACAGAGCAAGATCAGAAATTAAGAACAAGTTTAAACGTGAGGAAAAAACAAATGGATGGAGGATAGACAAAGCCTTCAAGGAAAAGCGGCCATTTGACTTTGAATTCTTTGCACAGCTGCTTGGGAAAGTTCTAGCAGATGAGGAAAAGAGGAAACAAAAGGTGATTAGAAGTCAAAGATCAAAAGAAAAGAAGCCACAAAAAGCTCGGAAAAAGCAAAAAGTAGCTCACGCTGAGAATGAAAAAGCTGCTAATGAACAAGATCAAGAGGATGTCGGAATTTCTGATGCAGAAACTGAAGTGGATGCTGTGACAGCTGAGAAGGAGAATGAAGAATCTTTGAATGTTTCTGAACCAGCAGAAGGGCAGCTCCTGTCAGAGCCAGGGGTAACCAAAAAGAAAAGAAAACAGAAGAAAAGAAATTCTGAAAAGGAACTTCAGAAACTTGCTGATGCAGAAACAGGAGTTGATGCTGTGACAGCTGAGAGAGACAATGAAGAAACTGTAAATATTTCTGAACCAGTGGACGAACAGATTGCATCTGAGCTAGTGGTACCAAAAAAGAAAAGAAAGCAGAAGAAGAAAAATCTTGAAAAGGAACTTGAAAATCTTTCTGATGTGGAAACAGGAGTTAATACTTTGATAGCTGAAAAAGAGAACGAGGATTCTTTGAATCCTTCTGAGCTGACAGAAGAACAGATCACATCGGAGCCTATGGTAAAAAGGAAAAGAAAAGAAAAGAAGAAGAATTCTGATCAGGGCATGGAGACTCTTGCGAAAGAGACAGCAGTTATTTTGAAACCAGCTAAGGGAGAAAAATCCAGCAGGAAACAAAAAAATACATCTGGCACAAACAGTGATGATTCTACTGAATGCAGGGAGGAACTGGGTATTCATAATGAAGAAATGTTTTGTGAGACTCCTGTTCAAGTGGAGCAAGTCTTCGATTCCTCCTTACAACTGAATGATGAAAATGAGGAAGATAGTGATTTTGATTTACACAGCTTTCAAGATAGTAATAATGTAACAGAAGCAGAACCTGTTGAACCAGAAATCACCAGTGAGTCTCAGGAATGGCAGCTTTCAAAATCTCAAGTTTTGGTTAACAGAAACCAAGGAAGTAGTGATCAAACCACTGAATCAAAGAACAATGAAGTATTTGACTTATGTGAGCCAGGTGACAAGGAGAGTGCAGCAGGAAGAGGCTGTGATACAAAGTCCGAAACAATGGAATCTGAAAAAGCTGTTGCTGGGAAATCAGGAGTGAGAGGACGTTTGCAGAGACCTAAGCCCAACTTAGCAAGAGGATCTGGAAAGAGAGAAGGAGCAGTGCAAGAAAAATCAGAGGTCAGGGCTCCCCCTCCAGAGCTTATGGAAGGAGCAGAAAAGGATTCTGTGGACGATAGTGAAGGCAAGATGTTGGAAGTTGCCAGAGATGAAACCACAGGAAGAGAGAACAAAGACTCGGAGACTGAAGCTCAAGAGACTGAGAAAGTTGTTACTGGAAGGACAGCAGTGAGAGGGCGTCAGCAGAGATTTAAACCTAACCTGGTAGGAGCTTCTGGAAAGAAGAATGAGCCTCTTCAGGCAGAAAGAGAAGATAAAACTCTTCATTCAGAGACTGATGGAAAAACAGAAGAAAAGAATAGTAACCAAGGTAACAAATCTGATGTTCCCAGAGTGGAAACAACAAAAAAAGATGGTAGAGTCTCAGGGACTGAATCTCAGTCTGAAGAAACTGCTCAGTCACAAGAAGATGGCAAACAGAGTGTACTCAAACCAGCACCACTAATGAGGAGTCGAATGCAGAGGCCAAAACCAAATGTGGAGAGGGCAGCTGTGAGACAGGGAACACTGATACTGCAGACAGATCTTGGAAAGGCAAAAACTGATTGTGGTGAAGCAGTGGAGAAAGATTTGATACACTGTGAAGACAAAACAGGCGGTTCACTTCTCACTGCATCTGATGCCATCCAGGCACACTTGGAAGTATTAGAGAAGGAAGCTGCTGCAAATCCTGAGAAGTTGGCTTCCACACATGAAAACCCGCATTCCCTGAAAGAGTCCTTAGAATCTGAGAGCTGTGAACAAGTAAAAACAATTCCTGGAGGTGATTTGAAAACTGGTTCCGATTCTGATACAGGAGATTCAGGTTCTCAAAAACAAGAAAGAAAAGATAAGCCAGCACAACTATTAAGGGGTCAATTTCAAAGGCCAAAGCCTAATTTAGGAAGGTCAGCTGGAAAAAGGGAAGTGTCAGGAGCAGATAAAGATGTATCTGATGACAACACTGATAAAGAAGAAAAAAGTTTGCAGTCTGACTGTGAATGCAGCTTGCTTCCTGACCTAGACAAAACAGCGAAATGTGATGTCCTGCCTTTAGGAAAGAACGACCTTGCTGACTCTCGGGAGGTATCTGTAATACCATTAGTTAATCAGTCCCCAAAGAAGCTGTCAGGATCTGAGAGTGATGAACCCAGCAGATCTTCTCCACCTGCAGATAACGAGGAAATTGCTGCACCTGTTGCTGTAGGGCTTTACAATAAAAATATCCCTCAAGAACAAAGTAAACCAAGCTCTCTTCAACCAGCCCAGTTAGTGAGAGGCAGATTCCAGAGGCCCAGGCCAAATATAGGAAGAGGAGTTGGGAGGAAAGAAACACGACCAATGGAAAAAAATGAATCTGAAGTTGAGCAATCAATACAGCATAAACATGAATCTTCCAGTAGCTCATTGACCACAGTAAAGGGTGAAAATGAAGTCATATGTTCTGAACCTTCAGAAAAATTGTTGGATTGTGAAAAACAGACAGAACAAGAAGAATCTCAAGTGCCCAGTATTTTACAAAATGTGTCAAATGAACAAAGCAGCATTAAAAAATCCAGTTCTCTAGAAAATAAACCAGGTGCCATCAGACCAGCACAGCTTATGAGGCATCGGTTCCGGGGGACTAGACCAAGCATAAGAAGGCTGTCTAGCAAGACAGGAGAACTATCAGCAGAAAAGAATACTGCTCCAGTTGAGAGAGAAGCAGGACAAATGGAAGCGAGTCTTCTGGAACATGAAGATTGTAGTGTTAGTTTTTCTACCAAAGCTGAAGTGGAGACACTGACTGTCCTGGAGGATTTGTCCAGAAAAGATGATCCGGATTTCAGTGCTGTCACGTCTTCTCCGAAAAAAATCATTCGATCAGAAGAAGTTTCTTCCTCTGAGAAATCATTGAAATGCAATAGTCAGAGAAATGAAGTGGGCTGTGTGTCAACAGAAGTTGTGGAAAGCCTTCCAGATAATTCTGAAGGGTCGAGTGATAAATTTACTTCTGAAGAAGAAAGCAAGCCAAGTAAGAGAGAACCTTCACAGTTACGGAAAGGCCATCTACAGAGGCCTAAGCCAAATCTAGTGAAAGCAACTAGAAGGAGAGAAGTGCCAGATGAGGGAGAAAGCACAACTGAGGATAAGTGTGATGCCGGAAATGCAGATGAGGATCTCATTCTGTGTGGGAGTAGCAAATCAGAAAAATTAAATGTTTTAGTGCATGGCTCTGCTAAGTTAGCAGATGCAGCGTCACCTTCAGAGGTTTCAAGAAAAAATATTTCTGAGGAATTGACCCATAAAAGAAGCAGGCAATTCAGAAAATTCCAATCTCTGGAGAGATCGTCAGAGAGTGAAAGTCAAATAGAACAAGATGATTCTCAGCCCTCTGCTGCTGAAGAGAAGACTTCAGACAAGCTGACAAGAAGGCGGCGGAGAAGATCATCCAAACAAATAGCCCTGCCGAAACGAATCTCTGAGCTAAGAGCAGCTACTTCATTTTCATCTGAATTTGAGGCGGATCATTCTGAAAAGGGGAAATGGTGTCGGAAGTTCAAACCAAATGTCACCAGAGGCAGAGGCTCAAAACCTGCTCGCAGCAAGAAATCTGGGAAAGACCATAGGAGTTCCAAGGTAACCTTGGTGACTCTCAGGGCTTCACAGGAAGAGGATGAAGATGAGGCAGATGACTTTGAACCGGATGATGAAGATGAGTGTTTTGCTCCAGAAGAAGTAAATAAAGCTCCAGTGTTTGTTCCTGTAGGTCTTCGATCTCCAAAACCTGTTCCTGTCCAGATTGAGGAAACCATGGAAGAGCTTGAAATTTCTGTGAATGTTCCAGATGTGCCATGTGTCACAACTGCTGAATCTGTGTCTCCTGATTTAAATGTACCTGTCCAAGCTGGGATACAAAGTAGTGAAAATTCGAATATCATACAAATTGTGGGAGTGACTACATATGAAAATCCAGAGACAGACACAGGGGCTAATGATGGAAGTACAGAAGCTGCCATGACCTTACTTGCAATGGGAGATCCAATGTTCCAGTTAAAAATAAGCGCTCAAGGACGGACACAAGTATTGCCTGAGCAAGATGAGCGGGATGTGGCTGATAGCTTTGTAAATCAACCTTATGCAGAGCACAGTGCAGTTCTTAGCGAGCATTCACTTCCTTCACCTGCTGCTAATAACAAACTGGTTCCACTGGAGGATGGAAATAAAATCATTCTAGAGGACCAAAGCACTGGAACGGGAATAGGTGGAGAAGACTATGCCAATGAAAATGCTGGACACAGCAGTGATCATTCTGTCCCTAAAGCTTGTAACACAAGATTGACAAGATGCCTTTTGCCAAGGCCTAAACCAAATGTTGGAATATTGGAAAGAAATGGGGATGCTTGTCAGAAATCTTACAGTCCAGAAATAGTTGTGGAACAATTGGTGCAAGTTGAAAGTGAGGACAAAACTCTAAGTGACAGTGCAGAAGAGGAGGTGGTGGAACAGAAGATCCGATCAAGTGAGAATAGTCCTTCCAGTCCAGATGATACTGCAGCCAGAAGCACAGACCTTGTCAAACAAGGAGACAAAGACGAGAGAACAGAAAAAGAGATGAGAGAAACTTGGGAAGCTCTGGGAGAGGTAAAAGCTCTCATCACATCTCCAGAGACAGAGTCTTGTCAACCTGGGCTGGGGAATGATCCTGGTCAAAGTTTTACATTTGGGTTTCGTGAAGGAACTTCCTGTGATGCTGAGAACAACTTATATGCAGTTGAATTACTTCAGACTGAGGCAAGTGCTCACAAACTTGATCATCAGTCCTTAACCAGCTCAAAGGAGACTTCAGCAGTAAGTGGTTGCGACAATGAATATCAACCAGACCTGGAAGAACAAACATTTATTTTAACTCTGGTGGAAATCCCAACTGACTCTAAAGAATACAGTGATGGGTCTGTTTCACTTGGACATACCTCAGAACCATTGCTGCCAGCCCCAATAATACTCAGTCCAGTCAATACAGATGGGGCAAAAACGGTGGGAAAGCAGAGCATTGGATCCCTGACACCCATAGTTGGTGAAGTTCTTGCTCCATCCTTAGACAACTGTACAGAAATTGAAGGACCACAAAGAACTTTAACAGAGCCATTTCTTAATTTGGAGTCAACGCCTCGGAAAAGGCGTGCTACTGATACTGAAGATAGCAATGTTCCTCCTGCCAAGAGGAGTCCAGCAACTTCAACAGAAGATAAGCTGGAATCTTCAGTTAAATCGATACACGCTCCAACAGAAGTTGCTGGAAAACTTTTGGAAAACTTGAGGTCTTTGAAGAAGAAAAATGTATCTACCTCAGCGTCTTTGTCTACATCTGCAGATTGGCAACTAGAACAAGGAGGCCAACATAAATCTTTGCAGAATGTAGAAACTTTACCACTTGAAGATAAATCAGCATGCAAATATTTAAATGAAGGGGGATCTGGAATATGCCCTGAGATAAAAATAGGAGCCAGTGAGCAAGGACTATCTGTGGAGGTTCATGAACCTGAACAGTCAGGACATGCTGGAACTATAGCAGCCCCATCAAAAACCCTATTAGTCAGGCCTGGGCGAAAACCTCTGGGATTTTTATCCTTAATTTGCAAAAAGAGTAGCCCTGATGTTGGAGAAGACAGTAAAGGGAACAAAGAGAAATTCCAAAAACCTCAAATACCTGCCTCAAAGCGAAGCCTGAAAAGGTCTGCTCCATCCACAGAGGACAAGAGGCAGACTCTAGAGCCATGTTCCCTTCCTTCTACAAGCACATCATTTGCTGAAGGAGAGAATACAGCAGCTACTGTAGTAAAGTTCAGTGCATCTTCAAGGGTTTTAGACTTCAGATCCTAGGTTTGATATCTGGGCTGTGGTTTGGCAGTTGTCTGCAAAGATGTGGACCTGATAGACCCTCTGTCTTGCTGCACAGAAGCAGAGAACTACATCCATGCATCACACCCTCAGAATCTCAGC
->XM_006020837.2 PREDICTED: Alligator sinensis neuronal differentiation 6 (NEUROD6), transcript variant X5, mRNA 
-AGGTTGACAACCCTTAGGACCTTTCATAATATAAATCTTAATACATAAATTCCTATGGAGAGTAATGGGGTTTTAACCTTTGTTCTATTATACGGATTATACTATTCCATATAGAATGTAATAAATGTAATGAATAGTGCAGAACTTGCTCTCTCTAGCATTAGCCTCTTAACTTTTAAAATCTTGGCCACTTCAAAAACGTTTATCTTTAAAAAGAGGCCCAACCTAGATAAAGTACTAATGACCTTCAGCTTCTCATTGCAATAAGAAAATAAAGGTTGTGTGTTAATTGAGCTAAAGTGTCTAAAGTTCATGTACACCTAGACACACACCTGCCCACATGCACACACATGTGCACACACACATGCAATTTTGCTGTCTCCTCCTCTACAAAAAAAAGCCCAACCCGGATTTAAACAAAACTTTGAGAAAACAAAAATAATTGGATTGGGGACGAGAATATTAATGCCAAGCTTGGGCCCAATGTGAATTAAAGCAGATGAGTTATAAACCCTTCAAAAACAGGATTTATAATGGAAATGCTGACAAAGACCCATAACAATAGCAGCTCTGCCAGGGATTACTTTAATACTAAAACCGTATTCAATCTCACTTTTTAAAACAGAGATTACGGAGTCACTAAAAAGCTACAATACGTGACAATAGTAAAAGAAAACTTTAAATATTTTTCTATCTTTGACACTGCATTCTCACTTTAACTCTTGCTAATATATTGCTTGCGCCTGACATTTCACTCCTAAATAAAATAAAAAAGCACAAGGTGGAGTTTACCACAGGCTCCAAAGCAAGGCTTAGCTGAAAGGCTTTGTCAGCTTCATTTAACAGTTTCTTGTCTTGTTGATGAGAGAGACAAAAGGGTTAAGGCAGAAAGAACAGATAGTGCAAGAGAGACAGCTGACCGGGGAAGAGAAAATGACACTAGAAAAACAGAATGAAGAAAGGAGAAGAAAAAGAAGCAGTTGGAAAATGGATATGCAGCTAAATATTTCAAATCTCATCTACATTTTTAAAACAGAAAAGACCTTTTAATTTTTAAGGAAAAGGTTTAAGAGAAGGCAAGACACCTAGAAAGAAAAGTAAGGGGAAATTTTTCCGATTCTCACAAGTTATTAAGAAGGGCTGCACAGGAAGCAATGGGTGAAAAGTGAGTGTATACATCTATCTTGCAAAGCACTCGTTTCTAATGTCAGAACACGTTTATATTCTTGAAGCCTTCTAGTTTTCATCTAATGTCTTTTCTTTTTTTTTCCAGGGATATTACAAAAAGTCACTGATGAAAAGAATTTGAGTTTTTCTTCTATAGACTCCAGCAGGATGCTTTCTTCTATTATTTTGAGATCTGGAATAGCACACAACCCTTTAAACACATGCACACACAAAGATTGCTCACGAAAGTATCACCCAAGTATTATGCCCTCTTACACATAAAGCTAACCCTGTGTAGGTGTGCCCTAGTGCCTTCATTACTTTCTGATTTCTGGTTTCCTTTCACGGCTTTTTTTCTGGGTACCCAGATGCACAGATTGGGACCCTGTTCAATGCAACACAACACTTTAAATAAAGACTGCAATATTAACAACTACGGAGCAGTTGTACCTGCAGGTAGGGATAAAACTGAATGTTGGCATGTCTGACAATATAGACTGACTGCTAAACAGAAGCAGCTCCAGTAGAAATGTACCTACTGTATGTGAAATGCTGGTGCAGATTTTTTTTCTCTCTATCACTCTAACCTTCTGTGTTGATACATGAATGCTGGTACCCACTTACAGGGATGCCAGATGATCAGTGCAGAATGTAGGTCCCAGGAGAAAGGATCACATGGTTTTCTCTGCCTTGTGACGTCACTAGCAGATGGCATGGGTACCAGCTCTGGCAGTTGGCATCAATGTCACTTTTTAGAGATCAATGAGATAGTGCAGATATACACAGATCTAGACTCCAGGAGACGATGCGACATTCAGACTGAAAAGATTTGGAAGGCAAAAAATGAAAACTGATTGTTGAATGAAATAAAAAGCTAAGGTAACGTAAGATTATAGAACCATGTTAACACTACCGTTTGATGAGTCTGTTGTAATGCCAGAATCCCAGATGTGCAGAAAGTTTTCCAGAGAAAGTGAGGACCAAAAGCAAATTAAAAATCCAGAAAGCTTTTCAAAGCAGATTGTACTCCGAGGAAAGAATATCAAAAGGGCCGCTGGTGAAGACACAGAAAAAGAAGAGGAGGAAGAAGACAGAGAGGAGGAGGATGAGAATGGTTTACCTAGAAGGAGGGGCCTTAGGAAAAAAAAGACAAGCAAGATAAGAATGGAGAGGATCAAATTCAGGCGACAAGAAGCCAATGCTAGAGAAAGGAACAGGATGCATGGCCTTAATGATGCTCTGGACAATTTAAGGAAAGTGGTCCCTTGTTATTCTAAAACACAAAAACTGTCTAAAATAGAAACATTGAGATTAGCCAAAAACTATATTTGGGCTCTTTCTGAAATCCTGCGAATTGGCAAGAGACCTGACTTACTCACATTCGTCCAAAACCTGTGCAAAGGTCTGTCCCAGCCAACTACAAACTTGGTGGCGGGGTGCCTGCAGCTGAATGCTAGAAGTTTCTTGATGGGTCAAACCGGTGAAACTGCCCATCACACAAGGTCACCATATTCCAGCTTCTATCCTCCCTACCACAGCCCTGAGCTCAGCACTCCCCCAGGGCATGGAACTCTGGACAACTCCAAGTCTATGAAACCCTACAATTACTGCAGTGCTTATGAGTCCTTCTATGAAAGCACTTCCCCTGAGTGTGCCAGCCCACAGTTTGAAGGTCCCTTAAGTCCTCCCCCAATTAACTATAATGGGATATTTTCCCTGAAGCAAGAAGAAGGCTTGGACTATGGCAAAAATTACAATTATGGCATGCATTACTGTGCAGTGCCACCCAGGGGTCCCCTTGGGCAGAGCTCCATGTTCAGGTTGCCTACAGAGAGTCACTTCCCTTACGACTTACATCTGCGCAGCCAGTCTCTCACCATGCAAGATGAATTAAATGCAGTTTTTCATAATTAATGAGGAAAATGAAAATAAACAGTGGTCATTCACCTCCCCATCTAATTAAGATAAAGCAGATGCTTGTGCACTACGTAATTGGCACAACTCTAGTTAGCGTGTTTACTAGTTTCTAAAGTGTGATTCAACTATTGTGGGAATTTTCTATGTACTAATAAATCTTTTTTCCTATAAGTATTTTTCCTTTTTTTTTTTTGTCTGTAAACACTGTGAGATTCTGTTTCTTACCAGAGAATTTCCCCCACCCCCTGCCTTTTTTTCCCTATTCGCTTGATTTGTTGAACAGTGTGTCTAAACAATATCATTGAAATAAAGGCATACACACTGTATAAAGTCAATGTCTATTTTGATTGTACAATTTGTAATTATACAAATGCATGTTATTACATTCAGATGAATAAAAATAATGTATTTATAATGAGTAGAAATTATATATTATGTATTTAAGAAATGGATTTTAAAAATTCTGAAGAATTTTAAAAATCTATCCCTGAATTGAGATGGGCTTGTGGGTGTAGGGGTTGGGGGACAGCAATATTTAAAGCTATGCAAAAATAAAAAAAATTTTGGAGGATGGGAGGCCTGTAAGATTAAAAAAGAGGTGATCACCACTGACTGTTTGCTGACAGGGGCTAAATAATGTTAGACAATGTTGTCAAAATTTCACATCAGTTATTCTAAACCTAATCATACAACAGTATCAGCACCTTTTTGTATTATTCTGATTTCAGATGTAAAGGTTTGTTATAACAATGTATAACTGTGGTTTCGCACTACATATTTTAAATGCAATTAAACAGAGATGTTTCCACTTTTAAAGTATATCTCTTAGCTGTGA
->KM473888.1 Uncultured bacterium clone 2010ECS-StA#2600 16S ribosomal RNA gene, partial sequence 
-GGACCCGCACAAGTAGTGGAGCATGTGGTTTAATTCGAAGATACGCGCAGAACCTTACCAACACTTGACATGTTCGTCGCGACTTTAAGAGATTAAAGTTTTCGGTTCGGCCGGACGAAACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGTTAAGTCCCGCAACGAGCGCAACCCCTATTACTAGTTGCCAGCACGTTATGGTGGGGACTCTAGTGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTATGTGTAGGGCTACACACGTGCTACAATGGACGGTACAGAGGGTCGCCAACCCGCGAGGGGGAG
->XR_005569779.1 PREDICTED: Styela clava uncharacterized LOC120344705 (LOC120344705), ncRNA 
-GCAAAAGCACTCTTAAAATAGCCCCGAAAATTTTGTAATGGTAAAGTATAGGAAGAATTTTCTGGGGGTTAAAGGCGGGGAAAGGTCCATAGAGAAATTCTCATTCGGCAAGATAGGCAGGAGCCCAAGGGACCCAAGCCTTATGGGACACGGTAATGGACATAACGATCATTTCAATATTATTTTGTTGAACACGGAGTGGACAAAGCGATGGTTTTGGCGTTATTGGACACGTAGTGGACATAACAATCGTTTTGTTGTTCTTTGACACGTTTTGAAGAAATCGCTTTTCTTTTTGATTACTGGATCAATTGCTTCGGTTGCCAATTTTCAGTGGTTAAAGATAGAATTTTTCTCCAGAAGGCTATTATTTTTATTCATTTCAAAATTTTCTGTGGACTTCAAGAGATTCGTTTTTTTTAAGTAATGGCATACTGCCCCTTGCAGTGCCGATACATGGATGCGCCAGCGAGGTGGATCTTCGTCTTTGGGCTTCTACACTTCATCCGAATTCTGAATCTGATAACGGACAAGACAACAACGACTGGAAGGTTAGATTTATAACAACAACTAACTTCACTGGAAGAATCTTGGAGGAGGTGAAGTGGAGGCTTCGTCCGAGCGCTGAGCATCGGCGGGAGTGAAGGAAGATCCTACTTCGTCTACATGTCACAACCAGATCTGCCTAGTTTCACAGCGATCTATGCTTGGACACCGGACCTCGCGGCTCGTGCGAATTGGTGATCACAAGAAAAATAGCGGCACACGTTTTTTATTTCGAACATTTCAGGAAGGCTTTGCTACGCTTGAGCGCCGAAGGATTCGTCATGGTTTTGCTATTGAAGCAAGGGAACAAGCTTCATTCTTGTGTTTTGGTATAATTTGTGAAGGATTTTATTATCATGAACAATTAAAAAGTCCGTTGAGTTAGGAATTTACCACTTTTAAATTCATTTTGGAATTCAAATATGGAGAATTTGAAGAGCTTTATTTCTACGTAGGAAACATCAAGCAAACAGCAAGAATTGGATTGGATTACTTCGTCATTGCAAAACGTTCCACAACATCACAATAAAACATCTTACATCATTCAATTGTTTTACTTGGGCATAACACAAGTGCATCCTGTAGAATTCATCACCGTCTCTCTAATCCAGCGTCTCTTTTTCCGAAAATATACTTGAACCGGGGCCTTAACTTGGACACTTGCTAGACTTAAATTTTCTTGGCGAGTTGCCGGATCTATGCATCCCTTGCAGAGACATTTTGCGCTTAAAATTACCCTCGGGCGTCTGTAAAATGTAATTTGTTTTAAATAAAATAACATTTGATTGTGACTCCTGTATTTGCTATCGGTGATGTTTCACTAATTTAATAAA
->XM_047271736.1 PREDICTED: Hydra vulgaris uncharacterized LOC124808573 (LOC124808573), mRNA 
-ATGTTAAAGTTCCAAACTGAAGATGAAGATGATGACCTACCTATAGTTTCGCAAAAGATTGAAGTTAAAGAAAAAGAGATAGTTCCTAGTTTAACACTGAAGTTAAGCAGAGTAAAAAAACCATTTGAATATGATGATGAGGATGACATACCAAAGTTATGCAAATCCTCAAGTAAACTAAAAAGTTTAAACTTAGATTCTGTGGCATTAAATTCAAGTAAAGTAGTTGATGATGACAATAGGGAAAAGTGTAAATGCATTGATAAGTTAAGGAAAATTGGTGATGATGGAGTTTCGTTTCGAGAGATGACAAATAAACAATTTCAATATGCTTTGTTTATGGACTTGCAGAAAAATTTTCGGCAAATCCAAGAATCACAAGCACAAATCCTTGATAAGCTTAAAATAATTAAACAAAGTGGAGATATTGATTTTGATGTGAATGTTGATGATATTGGTAGAGACCCTATTAATTCGATTGAGCAATTTGATGTAATGGAAAATATTTTAAATACAAGTTCTAATGCAAGAAAACGCAAGGTAAACCATAAAATATAGTAACAAGGTCAGTAATCTTTGCAAACCT
->XR_769696.1 PREDICTED: Tarenaya hassleriana uncharacterized LOC104800274 (LOC104800274), ncRNA 
-GCGGGCGGCGCCTCCTTCTCCTCGCCTTTGCGTCGCCTCGTGGATACCGGAGAATTCAAAGTCCCAGAGAATTTCCGTGTTCCTGGAAAGCCATTGTTGTTTCTCGAGCTTGCGAATCTGATGAATAGAAAAAAGTTCATGTGGATTCGGAATTTCACGGCTCATTCCGAATGTGTTGCACCGAGTGATGGAGGATGTCCCTTGTCCAATTCACCAACTATAATCTACTTGAACTGGACATGTTCATGAAGTGGACTTCGCTGCTGGAGATAGCACGATACCAAGCCCTCTGTTATTGTAATGGATGCTTTAAAATGAATCAAGCACTGAGTGTTTGTGTTTCTGCTCTTTCATCAGATATCCATCTGGTATTGTTGATTTGTTGTTCTTGCAGATTCTTATTTGGACCAGTGTTGTCAAATGGCGGCCATGGCCCCGCCATGGCGGGATGGCCTGGCGGATTTCAAGGTAGACGCCATGGTATTTGTATAGCGTGGCGTGTATGGCGTTTTCGCCATTGCGTGCGCCACATGGGGTTTTCCATTGTGGGTTATGGCGGCCATAGCCCCGCCATGGCGGAATTGCGTATTAAAAGGGAAAGTAAAGTCCAGAAAAAAAAAAAGGAAAACACAAAAATGGGAGATATCGAAGCGTCGGTCGAATAGTTTAAGATTTTGGAAATAGAAAAA
->XM_033481735.1 PREDICTED: Megalopta genalis pericentrin-like (LOC117226934), transcript variant X11, mRNA 
-GGCCTATAGATACAATACCACACTGTACATAGCTATTCGTATTTTTATAAATCGACAACGGTCAAACGTTTATCGAATCGGTGGACGGTTTGAGACACATGCTTTGAAATGTAATGGATGACGATTCTGCCACTGGATGTTATACAATTAATTATTAACATCGTCTATTGTTGGTCGATTATTAAACGATCGTCGATTTGATTTTATTAATGAAATGAGCAAAGTAACGGACGATGATGAACGTAGAAGACGCTCTTTGGAAGCAGGCAGAGAAATGCTGGAGAAATACAAGGCGGAAAGAATTAATAAAGCCAAAGGCCCGGGTCATAGTCAAACAGACGATGCATCGGACGAGGAATCTTTTCGTATCGACAAATCCATTGGACGCAGAGAATCTTACATGCACGAGGGTGTATCGTCGAGGGATGTCACCCAAAGCAGCGTCAGTATGAGCGAAGGAGAAGCCGACGGCGATTTGGAAGGACTCGCCGGGAGGGTAGCTCAATTGGAAGAGATGCTACAAGGAAAAGAAGCCATAGTCGAAGCTTTGCACGCCGAGATAGACCACTTAAGAGCAGAGGCTTCGTCCCCTAATTCTTCGCAGAGTCAAAACAGTAGCATTCATGGCAAAGATATTATATCGTTGTATCATACGAAGTTGCAGGAATTTGAGAAAGCTATAAATAAACGTGATAATTTGATAGAGGAGTTGACATGGTCCCTGCAACAAGCACTATCTGCCAGAGATAATCTTGTTACTCAGTTAAGTTCTTTAAATGCTGTACAAATTCCGGATAAAGGTCGGGCTGGTACTGTAAATAGCGCAAACATGCAGGACAAGATCGACGCCTTGGAAGCTACTCTAAGCAATCAGAGATCGATAATAGAAAAATTGAACGGTCAGCTGATACAGTCTCAAGAACGTGAACGTACATTGGAAATGGAGAGAGAGACTCGAAATGCCGAGATCAGCGACTACAAACTGCAAATAAACAATCTGAATGAACAGATTCGTTTGGGTGCAACTGACAAGAATTTGAATATCGCTGAGACTTTGGAACAGCAAAAGAAATACGAGGCGCGCGTCGATAAAATCAAGCAGGACATGCAACATATTTTAGAAAAATTCACGACCGAGACAAACATAAATACCGCACGACATCAACAGGAATTAAAAGAGGTGGCTGCGAAACACGAAACGGAAATCATGAATATTCAAGAGATGTACGAGGAACGATTGAAACAGTTTAAAGATGAAAATAAAGTACTAGCCGATCGTTTGAACAAAGACTTGCCCGATCTCGAAACCAGGCACGCCAAAGAACTTTCCATATTCCAAGCACAAATGGGCCATTATAAAAAGACCGTTGAGGCTTTGAAGCTCGAATTAGTAAACAGATCGGAGTCACAGCAAACCGCGCAAACCGAACTGAGCCAGTGCAAAGCAAAAGTGAACGAGCTGAAGGTTCAATATGAGAACGCGCATCAAATACAAGAGTTGGAGCATCAAAAAGAAAGAGAAATGCTAGGTGAACAGATCAAGCTGCACAAGTTACAATTGGAAGATATCACGTCGAAATATGTTGCCGCGACCGCGATTCTGGAATCGAAAGAGAGCATCGAACGTTCGTTGGAACAGGCTCTAACGAATGCCGCGACACTAAAAGATGAGAACGATAGTTTGAAGTTCAAATTGGACGACTTGTCGTCGAGATACACCGCGGCTCAGTCGTTGATTGAAAATACTCAAGTGCACGAGCGAACTTTGAGCAATCGAATTTTCGACCTAGAGAAATCGTTGTCCAGACTCAGCGGTATCAACCTTAGCACGTTCAGTGGCCTAAATGAAACAGCTTATCAAAGTTTGGACGAAGTTGCGATTCAATTTCACCTGACGAAACAGAAACTCGAAGAGAAAGCGGAACTAGAAAAGCTTCTGATCGATAAAATTGAGAATCTCGAGGGCGAGGTTCGGAAAACGACGGAGGAGCTCGAGCAAGCAAATCTGGCTAGAAAATCGTACGAGAAGCAACTGAAGGACACAAGGAACATGTGCGACAAGTACAAGTCCGAGCTTAACTCGTTGAAAACTCTTGATACCGATGGCCAGAGTTGCTCGAGAGATTTGTTCGAAAAGACCGAGAAAGACCAACAGGAGATTAAGCAACTGAAAATAAATTTGGAGCAAAAGGAAGCAGAACTCGCGGATTCTCTGAGGCAGGTACAAGACTTGTCGCAGAAATTTCAAAAATCCGATGAGGAATGTCAGCAGCTGAAAAACGGATTGGCCACTGCGTGGGCCCAATGCGCGGAGGTAGAAGAGAAGTTGAATCAAACGTTGGCGTTGAACGAAAGCAAACTCGACTCGTCTGTCCCGATGTCTAGTCACGATAATACTTCGACGATGCGAATAAAATTCAATAGAACCGTAAACGATACTACGACGTTGTCCATCGATGATACGCACGATCAAAGCAGAGACGACAACAGGCTTTTCTACGGCAGGGACGACGACTCGTCGGACACGACCGGTGTCGTGGCATCGTTGCAGGCAAAGCTGGCATCGACTTTGCAGGAAAACGAAAGATTGGCCAAAGAACTGGAACGCTCGCTAGAGGCACAGCTCGATTACAATCGAGTTAAAGAAAAACCGGAACACTACTCGACATCGATGGACAACTCGATCATGGAGAAACATCGTGTCGAGGAGGAGGAGGAGGAGGAGGAGGATGAGGCTCCGTGGCAAGAGCTAAGGACCGCGCATTCGCTGAAAGAATCTGTGAATCAACTCCGAGCGGAGAAAGAATTGTTGAGAAAGGAGATCGATGCGTTGATTTGTGTTCACGATAAGCAAATAAACGCGATAAAAGTCGAAACTGCCTCGGAAATTAGGAAAGTTCAATCGTTGGTATCGGGCGTGAAAGATGGCACAGCGGAGCTACGTGATCTAAAAACGGAATTGGAGATGCGACACGCCAAGGAGATGGAGGAATTGCGGACCTATTTCGAACAGAAATGTCTGCTGATGGAAAAGCAATATTCGGAGGAAATCTTTAGTCAGCAGTCGAAAAAGATGTCCGACAACGACAGCGAGATAGCAGACTTGACGGAAAGCTTGTATTTCGGCGGTGCCGGGGATTGCATGAACGTTTCGAACAATCTCTCCGAACGTAGCTCCAGGGTTGCTTCGCCGTTGGCGTTGGCGTTGGCGGACGAACAATCGAAACACAATACCAACGGTTTGAATAAGTACGAGCTCGAGACAACCGTTAAAGCGTTGCAACAGGAACTGCAAAATAAAATAATAGAAGTGCAGGAAGTAAAACTGCATTATGAAAAGAAGTTGGAGGAACAAAAGATGACATACGAAGGAGAATTGTATGGCAACAGAAGGGAACCAGAGAAACTGGAATTCTTGCGGAACATGGTGACTCGTCATTGTCAAACAGAGTGGGATGCGGGTGCGTTGGAAAACGGTGAATTAACTCAACTGCGAGCGGCCTACCACCATCAGTTGGAAGAACAGATTGCGCTAGCTAAATTGGACATTGTCAATGCGCTTCAAGAACAAATTCAGGCCCTCCTGTCGGTCGAATCGGAGGTCGATGATATTTGGTCGCCAGAGTTGCTAGAGTTACGCGACAAACTGACCGGCAATGCGAAACGCGAGATGCAGTTGCTGAAAGATGCTCATGCAGCGGAAGTGCAACGGCTCAAGGAGGAATACTCGCGCAACGTAGCCAGAATGATAGACCGTCATCAAGAGGAGCTGAATAAGATTCGAGATGGCGTGCCCGTCACCGATTCGAAGAAAGTCTTGGCCCAGCTTGGAAATTCAAATGTTCTTGAAGAGAGGAATAGTTTGTACAAAATCTGTGCTACCCTGAGAACCTTGGTCGAAGAGCTACTAAAATATTTTCTCGTGTGCGAAGAGGAAGTCAACGATACTCTGATCGGCGAAATTTTCAAGAGACAACCGCGCGACGGTGTCGGTAACGAGAGAACGTTGGAGAACACCGAGGACGTTAAAAAGTTGAAGAACGAAGAACATGCTAGTCCAAGTTCGTCGAGATTAAATTCATCCGGTTCGAGGATTCGACGAGTTCACTTTGCACCGCAAACGACAGAAATAATATCCATAATGAACAGCGATAGCGAGACTTGGCAAACAATATTGGGAGAGAAGAACGACATCGTCGAAAAATTGAAAGAGGAATTGAACAGCTGCGTGCAACGTTTGAAGTCCGAAAACGCCGAGATTCTCGCGATTACGAACAGAAAGGACGGGGATTGTGGTCAAGGTGGTCCTTTCCCGAAAGAGGTCGCCTGGATGAATCAAATGAACGAACAGCTCGCTTCCAAGCTGCAGGAAACGGAATCCATGATTTTGAACTACGAACAGGAAACGGAGCAGCTGAAACTTACTGTTCTTGATCTCCAAAGGAAATTGATCAACGTAGAAAACAAGAAAGAGATCATTACCGAAGGTTACGGAGAGAACGACGACGTCGGCGTAGAAATTACCTTGCAAGATTTCACGCATCTACAGGAGAAAGCGAGGCACGTATTGTCGAACGGAGGAGAAGACTGTACGGTCCTGTTGCAACTGATAGAGGAATTGTGTAGACAGAGCGACAAATTGATGGAGGATGCCAGGAGAGAGAAAGAAGACTTGCAGCAACAGGTGGAGGCTCTCGAGTCACAAATGAGGGAAATGTCATCCCTTATGTCCGACACAGAAGCCAGGAAGATCGAGACCGAGAGCGAACTGAAAGCAGCCATCGACAAGATCTGGGTGTTACGAGACATTATTACAGACTTGGAGCAACAGCTACAATCCAAATCGGAAAAAGAGGAGTCTTTGCAGCTTCAAATCGGTCAACTGGAAACTGTGATCGCCGCACAAACCAAGAACCAGCAAGAGTTGGTACAGGAGCTGGACACGGTTAAAATGGGTAGCGAAAGTAAGCAGCTTAACGAGCACATCAATCACTTACAGGAGGAGTTGAGGAAACACAAACTAAGTTCCGAACAGTTTAACGCGAATTCTACCGCTCTGAAACAAATGAAGTCGGAGCTTCGCGAAATGCAGATTCAGTTGGACAAGAGGATCAAAGAATTGGAATCGATACATATGTGTAGCTCCAATTTAAGTCTGAGTCAACCTAGCGAGGACGTGTCGATCAGAGAGCAAATCGACGCGGCACGTTGCCCTACTCCGGACGATCCCAATTCACCGCCAATGTTGCCGTTGGACCAGTTACTCAAGCTCAAGGAGAAGATGTCGAAACACGCGAGAGCCGAGGAGGTTGCGTTCAAGAGAATCAAGGATCTAGAGATGCAGGTGGCTGCATTGAAGAACCAGAACGAAGAGTTGCAAGCGGAGCAGGAGATCTTGCAACAGACCACCTCCGAACAATTGTATCAAATCGAAGCGATGCGCGGCCGTCTGGAACAGCACAAGCAGAATGCGCCCTTCGCGCAGAGGCAAGCGACGTCGCGGCTCGAGTTGCAGCTTCACGAAGCAAATACCAAATTCCAATCGTTGGAGTCCGCCGTAGCGGAGAAGGACTTGGAATTGAGGGACACGCTGAATCAGTTGGACAGAGTCAGCCAACTGTTGCAGGAGAAAGAATCGGAGATCGCGAATGTCGTGCAGGTGGAAAGGTCTACCATCCAGAAGCTGCGCGAACACTTGGAGATCGTCGAGGAGGAGAATAGAATTTTACAAGCGAAAGTCGGCGTTCAAGAACACTCTCAACTCGAACTGCCGCGGCTGATCGACAGCATGCTGGCCGACAAAAACGAGGAAATCGACCACATGAAGGACCAGTTGTCGAAAAAGGACAAACAACTGCAACTCTATTCCTCGTTGAACCTGGACGAGACGCAACTGAGAGAACTGATTCGACAGACCGAACCAAAGAACAGTGCCCGTACGTTGAGCGACATTCTGTCGATTCACTCGGAATGCGAGGAAACGTCGGAGGCCGTTCGTGGAACGAATTTCACTCAAACGTTGCCAAGCGTATCCACTTTGAGAATTCCCACAGCATTCGTTTCGGCCAAAATCATGGACGACACCGCGGCGCTTTCACCTTTGGACAGCACCGCCACCAGTAACACCGGCAAGATCGGACTGCGTGTACCACCGTTGGACCTGGGCTCTCGTTCTCAGAGTTTATCGGCCGCGTCGAACCAACAGTCCTCGGAAATGGATTTGTTGCAGCCCGCTGAACCGACCTCTAGGAACTCGGAGGAGAACGACGGCACACCGATGAACGACAGCGAGAAGAAGAACGAGTATGTAATCGTCGACGATAAAGTCGACGGCAAAGTCGACGACGAGTCGCTTGTTCGTTCGGTGTGCGTCACTCCGCACGTGAAACATGTGGAAACTTCGATCAACGAGTACATCGAGGAAATGGAAAAGTTGGAACATCAGTTGGAGATCGTTCGAGAAGAGTTGCGAACGAAATCCGAAATTTTGGCGAAACGCGAGGCAGATTTGCTGTCGCTGCAAAAACTGTACAACGAGTTGCAGACGGAAGTTAAAGAAGTCGTGGAGACGCTTACCACGGACAAGTGTTTCTATCAGAATCAGTACGAGTTGTCGAAAACGTCCGAAAATAAAATCAAAAAGGATCTTCTGGAGGTGGAGAACGTTTTGAAATTGAAAACCGCAGAGGTCCAAGAGCAAAAATGTAAAATTCAGGTCAACGAGAAGATCATCATGGAGTTGAGTTCGGAGAATGGTAAGCTGAAGGCGGATATCAAGGAGAAGGAGCAACAACACGCGAACAAGTGTGCCTCGTTGTTGCGAGAGAACGCCCACGAGTTGGAGACTATGAGGGGCAGGGTTCTCCGGCAGGACAAACAATTGAACGAACTCAAGACCAAGAACGAGTTGCTCAAACAAGAAATCGTCGAGTGTCAACGAGAGATGACCGAAGGTTTGAACAACAGAGATCAGACTATCAGGCGACTCGAGGAAATGGTACGACGCGTTAGCTTTTCGGAAGCATCCTCGCCTTCGAACGAAAAGGACGAGGAGATCCATCATCTACAGGAATATTTGAAGGAGAAGGACAAAGTTATACGGCAAATGAACGACGACAGCAAGAGTTTGCACAGAGCTTTGGAGACTATACAGAATAAGATGAAGGAGTCCGGTAACGTGGTCGAGCTCAGAAGGAAGCTGAGAGAAGAGCAAAAACTGAATGCCGAGCTGAGGAACGCGATGGATAAGCTGAACAAGGAATTGTCGGATTTAAAGTTGGCCACGCAGCGGTCACAGGAGGACACCGACATCGAGGACATGGTGCAGAGGGAGCTGAATTTGTCGGCGCATCTCGACAGACGGCTGATGAATGCGATCGAAACCGACCAGGAAGATGGTATCTGTAAAGTGGAGAATCAAGTTCAAACCAGAGGGCCTCGTCGGGAGGGCGTTCAAAGGAGCAGCGAATTAAAGCTACAACTGAGTCAGGCGAATAGGATCAACGACGAATTGAAAAAGTTGAAAGACGACTTGGAAATCGAAAGGGGAATGTTAAAGTGTCAGATCGCTGAGTACGAGGGCCGGATCTTCCAACTTAAGTCTGATCTAGCGATGGAGCGCGAACAGGTTGCGAAGCTCAACGAAGAATTATTCGCCGAGAAAAGCTTGATTCGGAGCTTGAAGATCCAAATCGAGAAGGAGCATAGATCGATGGAGTCCGGTCACGTGCAGGACTCGGAGTTGATCGAGTTTCTTCAGAATAAGCTGAAGACATCTCTGGACAACGAGGCGAGGCTGCGCAACGATCTTTCCTTGTTACGACAAGAACACAAAAGCCTAGAGATACAGCTGAGTTTGATGAAGGAACACGTACAGTCCCAACAGTCCCAGAAGTCCGACGAATTGCCGAAACTAGCGGACCTTTTGGAAACTGAGAGGAAAAAGTATTTGTCGGTGATGGAAAGCTTGGAAAAGGAAGAACGTAATAGCGCGGAACTAAAGGATACTTTGAGGAAGCTACAATCGGAGAAGAATCGATTCGAGAAACAGCTGGAGGTGGAAGTGGAGGAGAAAGAGAAATTGATAAGCAGCCTTGCTCTGGTCGAGGGAATCAGGGACCATTTGCAAACAGATCTCGGTCGCACCAAAGAGGAGTTGAAAGCGCGGGAGGAGGAGTGCGAATGGCTCCAGAAGAGAATCAAGACAACGTCCGACGCGGAAATCAAAAGGCAAGAGCAAAGGACCAGTGAACAGAATCAGCTGAAGGGATTGAGGAGGGAGATCAACAATGCCAGAGAGGTGATGGTGGACTTGGAAGCCGACATGAAACAGTTGCGTGAACGCGAGATGAAACTGACCGAAACGGTGGAGAGTCTTCGGGAGAAAGAAACGTATCTGCTTAAGGAATTGTCCGCTGCCAAAGACGAAGAGACAAAGTTGAGGGACACGATCGCCGAGTTGCAACAGGAATTGAGATCGTTCGCAGAAAGGGAACTGGAGTTAGCTAGAGAATTGAAAAACAGGTACGGTGGCGACAAGACCGCCACGCCTACCAAATTGCTGCAGAAGATCAAGGAACTCGGCGACATCAACAAAAAGTATCTAAACGAGAAAAGCATGCTTCAAGAGAAGCTTGTGAAAGCGCTGGAGGATAAGGAGCAACTCGGTCAACGAGTCAAATCGCTCGAATCTCGTTTGAAGAGAGGCATCGAGTCTCGCGATGCGAACGCGGCGATCGGTGGAGATTGCGCGGACAAGTTGCAACACTTCTATGGGAAATATATACGAGCCGATAGCAGACGCAAGGCTTTGACTTACCAGAAACGTTACCTGCTAACCATCGTAAGTGGTTATCAGATCTCCGAGGAGAACACATTGTCCATTCTGGCGCAATTGACTAGCGAACAACGATCCTATACCACAGCAGGCCGTCATAAAAAGTCTCCGCGAGTACGCTTCAAGAGCGCTGCTCTGGTACTCATCAGTATCCATAGAATGAAGTGGCTGATCGTTAGGTGGAGCATCGGCAGAAGAATAGGTGCCCAGACGTTGCTGTGGAACGTGGACCAGTCGTACGTGCCGGTACAGAAACTTGCCATGGATCATTCTCCCCCTGTTCGAGAAAGACCTGTCGCAAACGAGGATGGTAATTTCGACGGATTCGCGCTTGCACAGTATTATCAACGGTTAAAAAACATTCAACAGACATTAGGTTTAGCGATGGCTGAATCTGTAAATTGTCAGATTCATCCCGAATAGTATTATATATTATAAGAGCGTTCGAGTCTTCGACACGCGGGGTAAGGCAAGCATGATAAACGTACCACGAAATCAAGTTGTGTATAATCGCGCGTGGAATTGATTGTCAAACGGGTATTTCAATCTAGGAATATTTTGTTCGGATTTCATCGTTCGCGGGCATGTATTTTTCTTATGGCATGTAAATAGGATTGCAGCATAGTAACTGCAATTGTTGGACACGCGTCAAGCCTTCTCACCGATTACCGCGTTGTGTGCTTTTTAAAGAGTTGCCACTGCAACATTCGACAACCCGAAAAAGAGACTAGAACGTTTAGTGCTAAATAATTGTGCTCATATACCAAGTTTTACCAAAGGTACGATAGACTTTAGTTATAATTGTACTTTGTTAATCCTTTCAAGAGGATGTGAACCAGTGCCTTGTCAACTATGCTACAATATAATAAGTGTCTAGTATTTATTTATTATCGATTATCGAACTGTAAGTTTTTATAATGTGAATAAACTCTATGCAATGGCTTTTTATGAAA
->XR_006348224.1 PREDICTED: Manihot esculenta vacuolar sorting protein 18 (LOC110629926), transcript variant X10, misc_RNA 
-AATGAATATAAGATAGGTTTTTATGGTTTGTATAGAGAAGTTCTAGAATCTCCTAAAATAATAGAAAAATACAAAGAAATAGAAGCCATATGAAATATGAGACAACTCTGGAAAGCTGTGGTCCCCACCAAACTTCTCCTCCAGAAGCTGCTTTCGCACCTCCAGCTTTGGCGCTAGACTCCCCCAACAGCTTCTAGATAATCCTCGCAAAGTCCAGCTTTTACTCGGGCTAGCCGCGCGCTGATTTGCTTTCCTCTCGTGCGCTCCGCAGACCAGCCCGACCAAAATACTCATCCAACGCTTGGCTAAGTTTGCTCTCAAAGACTCGGGCGACAGTACCATCCTGGAGGGTTTCCGAGTGTTTCTAGCCTTCCGAGTTTAGGGGCGTTCACCAGCCCTTCCAAGTGTCTGGGTGTTCACCGGCCCTTCCGAGCTCCTGGGCATTCACCAGCCCTCCCGAGCATCTGGGCTTTTACTAGCCTTGCGACCATCCGGGCATCCTCTGGCCCCACCTAGCTCTGCCGAAGTTCCGAGTGTTTCCTCGCAGACTTCGCTCGCTTGCTCAGCAGGTTGCCTCACCAGCGTCAATTGCTAAAAGTCTCAGTCATCCTACCATCTCTCAAATTCACCCGTAGGCCTGTTGGCTCCCGTTAATACTCCGTAGGCCTATCAAAATATCACTCGATAGCTAGTTTCTCCGAGATGACTTAGCCCATCCTTATGCCGCCTACTCGGCACCAAGATTAGCGCCAACTCCTTCCAAAAGAATATGGATATTTCCGGGGAAAACTGTGGGGGTTTGTAAGTGCAAAATCTTAATTGTGGGTATGGACTACCACATCTCATGCCTGTACTTAAGAGGACCAATGGGCTCCCTTCTATGTATTTCCATGTGGCATGCCTTCCATGAACAATGCTTGATTGCCCATTTGACAAGTCATACCAACAAAACTCAGAGAGATTTTTCTGACAAACTGCCAGTATGGTGAAGTTCAATAACATTGCTTTTCTGTGAAGATGGATGAAAAACAAAAACAGTATGCCTATGATAGTTCGGGGCCCAAACATCTAAGACAAATTTCTTCAGCTCTACGGGATTCGAATATGTAATTGGGCAATAATTGTTGAGCAAAACTAAATACAGTTTATTGGCCCAACCAAGTACAGTTCATATTTGAACTGACTAATTTCTGCAATTCTTTATGAGAAAAAAACAGCATGAAATATGCAGCAGCCTGCTGCAGTCAACATTGTACTTCAATTATTGTACGACTATGCTCTCATGTTCTGCAATCTTCTGGTATATGCACCATAAGAAATCCCATGAAGGGCATAACTAAATAATGAAACAATAAATTGAACTGCAAGCTTAGTACAAGCACATTTGCGTGGCCTAAGATTTACGATGACTTTTGTTTAAGTTTTTTTTATTGTCATCTCTAACTGAGTTGGGTTTTGTATTTAGCTTATCATAAAACTATCCTGCACAGCTTCTTACTCTGCTTTATATCAATGAAACATATCTCTGCGCCATCTTTTAGAATGAACTCCAATTCTGGAAACTCTTACCACCAATCAAATTTTCTTCCTTCGGGTATTTGAATGGATGATGCAGGCTGATTATATACTGGATCTGCAGAAGCAACTTACTTTACTGGGTGAGGGAACTAGGAAAGACTTGAATGGTGGAATAACGTAAGATTCCATTGCTAGCAAAACCCCTGTAGATAAGGTCAGTTCTATGTTCTTCTGAAGCAAAATCTATTATGGTAATATGGAGTAGTTTGTTATAACTCGAGGAAAAAATTTCCTGCATTGCTGTACATTAACTACAGTGGCAGTTTATTACGTCTTTTGTAGTTTGTCTGAGCCTCATCTCTTCTCTGGTGTGTATTTTAAATCCCGTTGGAATTTGCAGCTCGGCTCACAGTTGATGATGCAAATAGCCAGCAATTGCCCATTTCACGGTGAGTTGATGATCAAAATGTTCTCCTTGCCACTACTCTCCCTGGGGAAGCACGGTTGGTAGGTTCATGGGATAAAACCACATAACCTGGGAAACCAGAGGACGCCCTATTTATAGGTGTAATAATATTACCTGTGTGTGATTTCAAAAGCCAGTGTGCGTGTGGGGAGCTTCGATGCCTGTAATGTGGCTCTCTCACCGTCTCGTTTTGAATTGGGTTATGAAGGAGAGCATCCCCATTTCCTTGTAAACCTTTTAAGTTCTTCTTAGGCAGCACCATTAGTTCTCAATAATCATGATTTATCCCTTCTGATTGTTCAAGATTTCTGAAAGCACAAGCAAATATATGAACTTTTATCACT
->XM_029702302.1 PREDICTED: Salmo trutta DNA-binding protein SATB2-like (LOC115155576), transcript variant X3, mRNA 
-TACTCGCTTAGCCTAAGTTGTTTATTTTGCCTAACGTTCTGATCTCCCTCCCCCAGGTCTGATGATCCCAGTATTCTGTGTGGTGGAGCAGGCAGGGCCGGATGGGGGGATGCAGCGTGAGGAGGTGGAGAGGAGCGAGGGCCACAGAGAGGAGCATGCTGAGTTTGTCCTGGTCAGGAAAGACATCCTCTTCAACCAGCTGGTAGAGACGGCCCTGCAGGCCCTGGGGTACTCCCACAACTCTGCTGCTCAGGCCCAGGGCATCATCAAGGTGGGTCATTGGAACCCTCTGCCCATCCACTTCCTATCAGACGCTCCTGAAGCCACGGTGGCTGACATGCTGCTGGACGTCTATCACATGGTCACTCTCCACATACAGCTACAGAGCTTTGCCAAGCTGGAGGATCTTCCGTCAGAGCAGTGGAACCACGCCACGGTGAGGAACGCTCTTAAGGAGCTTCTCAAGGAGATGAACCAAAGCACACTGGCTAAGGAGTGTCCTCTGTCACAGAGTATGATTTCCTCGATAGTAAACAGCTCCTACTATGCCAATGTCTCCACTGCCAAATGCCAGGAGTTTGGACGCTGGTACAAGAAGTATAAGAAAATCAAAGGAGACTATCAGGAGAAGATGTGGCCAGGAAGAGAACATTCTGAAATCAAAGTGGAGAGAGACAGCCTGGCAGACTTCTATGTCCTGGGCCAGCGTCCCCCTCCCCACCTGGCCAGCCTGGTCCAGCTCAGCCACCTCGGAGGGGGTGGAGGTGCTCTCCTCAAGGGTGGGTCCGGGGACCCCCAAAACCCCTCCCAACCCCCCCAACAACAACAACAATCCCAACAACAACACCCCCCCTCGCCCCATGGCCAGCACCACAACAGCCCCCCTCTACGTGGCCAGGTCCCCCCTCCCGGCCCTCCAACCTCCCTCCAACCTCTCCTCGGCCCAGGCGGGCTTCTCTCCCCCCAGCTCAGCCCTCAGCTGGTCCGACAGCAGCTAGCCATGGCTCACCTCATCAACCAGCAGCTAGCTGTTAGCCGCCTGCTAGCCCACCAGCACCCACAGGCCCTCAACCAGCACTTCCTCAACCACCCTCCCATCCCTCGCCCCTCCAAGGCAGGGGCCCCTGGGGACCCTGGGAGCAACCCGTCTGCTGCGGAGGTCTCCATTGATATCTACCAGCACGTCAGGGACGAACTGAAGAGGGCCAGCGTCTCACAGGCTGTGTTCGCCCGCGTGGCCTTCAACAGAACACAGGGCCTGCTGTCGGAGATTCTGCGGAAGGAGGAGGACCCTCGCTCTGCCTCTCAGTCCCTACTGGTCAACCTCAAAGCCATGCAGAACTTCCTCATCCTCCCTGAGGGGGAGAGAGACCGTATTTACCAGGAGGAGCGTGAGCGCAGCATCAACCCCTCTGTCGGCCTGCCCCCTACCCCTACCTCCAGCCCCGGGGGCCCGCGCCTCTCACAGAAGGTGTGGGAGAGAGGTATGGACGAGCAGCTCACTCCTGACGCCTGGGCTGCTATCTGGAAGAACAAGACCAAAGCCACCTCTGTGCCCAAGCCACCAGGCCCCAACCCAGACCTGCCCCTGAAGCTGGAGTCTCTGGTCAACATCACGTCAGGTATCTATGATGAGATCCAGCAGGAGATGAAGAGGGCCAAAGTGTCTCAGGCGCTGTTCGCCAAGGTGGCTGCCAACAAGAGCCAGGGCTGGTTGTGTGAGTTGCTGCGGTGGAAGGAGAACCCTAGCCCAGAGAACCGTACTCTGTGGGAGAACCTGTGTACCATCCGGAGGTTCCTGACCCTGTCCCAGACAGAGAGGGACATGGTGTATGAAGAGGAGTCAAGGCACCACCACAGTGACAGGGTCCACACTGTACTACACCTGCCCCAAGACCCACAGATGTACTGTTTTTCTCACCAGGCGCTGCACAGGCAACCCCCACAGCCCCTGAAGCACCACTCCCCCATGCGCGAGGACCCCGTGCCCGCTCAGGGTAACGACGAAGGGTCACAGAACGTTGAAAGAGGTGGTGGTGGCGGTGGCTGCACGGGCGGTCCAGGAGTCGGTGGTTGCACGGTCGTTAAGAAGCCTCGGTCGCGCACTAAGATCTCTCTAGAAGCCCTGGGCATCCTACAGAGCTTCATCCAGGACGTGGGTCTGTACCCGGACCAGGAAGCCATCCATACCCTGTCAGCCCAGCTGGACCTGCCCAAACACACCATCATCAAGTTCTTCCAGAACCAGCGCTACCATGTCAAGCACCACGGCCGGCTGAAGGAGCTGGGGGAGGGGGCTGGCGGCGTGGACGTCAGCGAATACAGAGACGAGGAGCTCCTCTCCAGCTCAGAGGACCCTGAGTCCAGTGAGGATGGTCACGAGGAGATGTACCCCACTACTGAGAGGGAAGGAGGGGAGAGAGAGGGCAGCACAGCAGGGTCAGCCCCTTCCCTGGCCCTAGCCCCAGGCCAGTCTTCAGGGACCAGCATGGGAGCCATGGAGGAGAGCAAGGACAAGGGGCATTCTCATGGTCTGGGTGAGGGCCGAGCCAGCTCCCTGCCCCCTAGTAGCTCCTCATCCAGTCCCAGAGAACAAGCTGACTTCCAGAGATAGAGACCCAGAGACTAGATGAGACACTGGAAGAGACGGGCGGAGATAGAGAGACACGAGAGACAAAGAGACACGAGAGAGAGAGAGAGAGAGAGACGAGGGGAAGCGAATGGGAACAAGACACTGGGAGAGGGGAAGAGAGGCATAGATGAGACTCACTGACACACAAATATACAGACAGAAGGGATCTTAAGGAGGGCTCGTCAAAGAGGGATTTCAGTGAAAATACAATTTGTTACCTCAGCAACAGGGATATGCCATGAAACAGCAGCCATGTGGAACAGTTAGTATAGTATGTTCACTGAACCAATAGACAGAGAGATAACCAAACATACACATCTCACCCCTGTCCACAAGAAGAACTCGCCACATCAACACCACTCTTGAATTGAGCCAATCCCAAAATTCAGCTTCACTCTGTCCAATGACTACTCTCCCTAATGTCTCAACCGCACCCACATGCTGAGCACTTGTCCTTATTTCGATGCTGGGTCTTGAGTCAGGAACCTAACTGACAGTCATAGACTGAATACTGGGGGCCTGCTCAGACCTCCACCATCCTGTGGTCCCTCAGCTCCAGATCTACAGAACTGGCTGCTGTAGCTGTCCTCCAACTCGTCCCCCTCTCCGCCCCTCCATGACAGGACCATTCTAGTCTTTGGTCTTTGACAGTGTTGGCAGTTTGAGTGGGAGGTTGGATAGTGGATGGGTGTTGGTTGGAGGTAGGAACAGTGGTATGGGGGGAATTCACCAATGATAAACAAATATGGTGTAAGTCCAGAATGGAAGCTTATGGTATTTTTTTGAAGTTGGAATCGCCCCTCCCATCCAGCTCCCGTTGCCAACCCTCAATGGTGCAACAACATCCCTATGCGATGGACCAGACCATCCCTCTAACGCCCTGCCCCCTAACCCCCACTCTAAAGATGGTTCATTCTCTCTGTCACTGTACAGCAGTTATTACACACTAACCTAGTGTGTATGGCCACTGTGGTTTATGAGGACACTGCTAGCTGAACGTATCGTGGTTTAGGACATAAGAGAGGACAGCCTTGTGAGGACAATGAGGACCCAGTGGTGTACAAGGACCCTCAGGATAACAGTTACTCTGGTCTGTCCTCTGTCCCCCCTGCATACCCAACCTCTCCCTGTGTGGAAAGAAACAGGGAGGGGCACAACAGAACGGAGATTCAGCAACCAATCGGGTATCTGCAATCAATCAGTCACTTTATGTGCACTAGCCCACCCCTTCACTCTTCCTCTCTCTGTCCCCATCCCTCGTTCTCTCTCTCTATAATTGGTGCCCACAGTGTCCCCTTCCACCACACCTACCCACATGTAACTTCACCATATTTATTGCTATCTTTATCCATGATTATCATTATCATTATTGTTATGGTTGTTATTGTTGTTATTGCTGTCATAGCTGTTTATTTTTTACTTCTATTTTCATGCTTGTAATATTGGCTTTCCGAGCACCATGGTTGTTTTGGTAACGAGAGACGTTTTTGAGACATGAGGAACACACATTGCCGAACAAAGAGCAGAAGAAAACCAGAAAAGAAGCAGTTACTGTAACGTTTAGCGAGTAGAAATCCTGTCATGCTGTGCTAAGCAACTCACGTGTTCTTCCAAAGAGAGACGGACATTGGCTGAAACGGGAGTGGAATCCAAAAAGTAATGGAAACACAACGAATAAACTGAGCTTTTGCTACAGCTGTTAACAATCTGACATGTTTGGAGCCTTTGGAAAACACAGCAGGCTTGACCTCTGTGTGTTATGTACAAGTGTGTGTACAGTTCAGTACAAATCCTTATCTGAGAGCGGGTACTTATGTCGAAGGATGCATCCCAAAGAGAGCCCTATGAGCCCTGGTCAAAAGAAGTGGACTGTATAAGGTATAGGGTGGCATTTGGGACACAGACAAAGTAACAGAGTAACCATTATTTACCCGTCTGACTCTAGGCAGCTGCTACGTGAATGACCTGTCTTGTACTGTAATTCATGAATTAATCAATCATACAATACATTGTGTTATATCGCTC
->XM_009901592.1 PREDICTED: Picoides pubescens prodynorphin (PDYN), mRNA 
-ATGGCTCGGCAGGCGCTGGCACTGGCACTTTGCCTCTCTCTGGCCGTGATGGCATCCACTGACTGCGTGACCCAGTGCTCCCTCTGCGTGGCACAGACACCCACCCCCGAGACCAGCAGCTGGCCCCTGATGTGCCTGCGGGAATGCCAGGGCTCCTCACCGCCCGGGCCCGAGTGGGAGACCTGCAGGAAGGCACTGGCGCTGCTGGCCCCGCTGGTGGCCCTGGCCGAAGGGACAGAGCCGGCCCCTCGGGAGGCGGAGGAGGAGAAGGCAGAGCCGGAGCTGGGCGCCGGAGGGCGGGGGGAGGCGGCAGCCCCCGAGGACTCCCCGGGGCCGGAGCCGGCAGGAGATGGAGCCGAGGAGCCCACGGGTGGCGGGGCCGGGGGGCAGGAGCTGGCCGAGCTGCACAAGCGCTACGGGGGCTTCATGCGCCGCATCCGGCCCAAGCTCAAGTGGGACAATCAGAAGCGCTACGGAGGCTTCCTGCGGCGCCAGTTCAAGGTGACCACACGCTCGGACGAGGACCCCAGCGCCTACTCAGGGGAGGTCTTGGACCTATAG
->XR_007834401.1 PREDICTED: Phodopus roborovskii U6 spliceosomal RNA (LOC127220836), ncRNA 
-GTGCTTACTTCAGTAGCACATATACTAAAATTAGAATTATACAAAGAAGATTAACTTGGTACATTATCAAGGATTACAGGCAAGTTTGAGAATTGTTCCATATTTTT
->XM_029382818.1 Trypanosoma rangeli nuclear RNA export factor 1/2 (TraAM80_05959), partial mRNA 
-ATGTCGGCACCCTACAAGAAGACGAACACCCACAATGTGCCCTGCTTCTACTTCAAGAGGGGCGCTTGCACGAATCAGCGCTGCCCGTACCTGCATGTGCGTGGGAAGGAGTCAGGCGGTAACGCAGGCGCGGTGAAATTGTCAAGCGTTACCTTGGGCTTACCGGATGCAGCGACAAATTTGCTCTCAACAATGCTGAAGCTGGTCTTTGAGAAACAGCAGCAACGGGTGTATGACGCGTCGTCTGGGATGTTGGACCTGAGCGAGTTGAGGAAGTTTCCAGACCTAAAGGACGTCTCAAACTCCATTAACTTTAATACGCAGAACTTCTGCCGCGCTCTCTGTTCGACGATAAAGTCACTTATTGTCCCACCACCCTCTGCTATGCAGTTAAAGGGAAATGATATCACTTCCCTTTTTCACCTGGCAGGCCAGATGGAAAAGGCGGATTTGCACATGTCGCTTCGGGCTCTTTCGCTAGAGGCAAATAATATTAGGACGATGGATGCACTACAGGAACTTAAAAAGTTCATGAATTTACAGGAGTTGGTGCTTGTGGGTAACCCTGTGGCAAAGCGTGATGACTACCGCATGGAAGTGAAGAAGGCATTGCCGTTTCTCCTTGGACTGGATGGGGAAGGCATCGCGGTTCCGCCACTGTTATTGCCATGGCCACGATTTGCGACTTCCGAGTACACCGACGCGCAGCGGCATGTGCTTCAGTTTGTCCAATGCTCATTGCTGAATCCACTTGAGGCGGGTGAGGTGGAGCGGGTTTCACAGGGCGTGGATGCAGTATCAGATATTTATGCGCAGAAGGCCATTCTCACCATTTCCCTTTCGTCACCGGAGGCTGCAGTAAGTTCGCCGGCGCGAAGCGTAAATGGCTTTTCATTGGCGTCTACGCAGCGCAACGTCATTCGCGAAATTGTTGGTCTCCGGCTAAAACAGACAGAGAGCAATCACAACTTGTTGCATGGCGTGAAGTCAAGTGTTGTGGCGTGCGGGCGTACAAAGGTCTGCTCACAGCTGGAACACTGGTTGTATCCCAAAAATTTTGCGGTTCAACACTTCGTGCACAGCAGTGCAAGCGCCTCGTTTCTGGATAACACGTACCTGTCTGGCCCCGCACCTGTGGCGATGAAGGTGCCGGTGACTGTGGTGACGTTGCATGGCGTGATGACGTGGACCCACCTCAGTCCGCAAAGTCAGAATAACTCTGATCGTGTGGTCATTTATCGCAACTTCACACGAGTACTTACTGTTCAGCAAAACGAGGCGGGCCGTTGGTTGGTGACGAACGATATGGTGTCACTGTACCTATTTTCGGGGAAGACAGCGGGTCTATCCAAGAAGGGAGAAGCTAACGCCGATATTTCAGCTGACGTGAGTGAGTGCCGTATCCTGTTTAGTCCCAGAACCGATCGCAGTCGCGCTGAGTTGCTTGGCAGGAAAAAAGATGTACCAGTGGAAGTGGTTTTAGCACTAAGCCAACATGTGAGCAATGATGCAGAGCTGATGGCGGTGCTCGGCGACATTGGAGGGGTGCCACTGAGCATGTATGAGCACTGCGCTGCACTAACAGGTGAGAATATACTAGAAAGTATTCAAGTTTGCCGCATAGGTAACCGGTTTGGATTGGCCCCACAGGAAGGTTTGGAACTGCTGCGCAGGGTGGGTGGTAATTGGTGTGCTGTAGAGGAGGCAATGGGCACCGCCGTAGGAGTAACAACATCACAGGTAGCATAG
->XM_017771362.2 PREDICTED: Gossypium arboreum uncharacterized LOC108470132 (LOC108470132), transcript variant X1, mRNA 
-CGTTTTCTTCATCGAGACTATTCGTGTATTAACATCAATCAAAGATTTAAAATCATTTCTAGAGTCTTATCTTGGCGCTCTCTCTCACATCACTTTTGCCTTGCTCCGCAGCACGTAGGAAAACTAGAAATTAAGAGAAATTAATACTAAAAACTAATGAAAAAAAATAGCAAATAGCTCTCAATTCAAACCAACAATTTGGACTTTAGATTAATAGAATCAAGATGGAGGATTCTGGAGCAATTCTTTACCAAATTTCATGCCTCAAGGAAATGCTTGATCAGGTTAATGAAGAAATCGAATCCAATATTGAAGTATCGCGGGAGATTGAATCAGAGATGGTCAAGTGTACGGAGTTCGAAGCTGCTCTTACTACTAGAGAATCCCTGCTTACCAAATCGCTATACATTTCTCACTTCGAAATCGATGGCTTGCTCTCCGTCATCGCCGATTCAAGAAATTCGCTTAAATTTTTGGAGGAGGAGTTGAGTTGTCTAACCACGAAACGAGATGAGATGTTAAAGAGGATTGACGATAAACGAGACGGATTTACCAAACAGTGCTTAGAATTTCAAAGGGAGATTGACAAGGGGGATAACAACGAGCTGGTGAATTTGCTGTCAGAGAAAGAGCTTCTTGAGAATGAAATTCATCTCTTGCATAAGAAAAACAATGCTTTGAGAAATTCAATGTCCGCTTTTGTGGAAGAAATTCTTGAAGACCTTTATTCTTCAAATGCAGATTTTGGGTTCACATTACAAGCTCGGGGATCGTCAGCAAAGTTCTTCACACTATCTACGATTTCGGCATTTAAATATTTGAACTCGAACTATGGCATGTATAGGCTAGAAAGTGTTTTTGAAATGTTTGATTTTGGTTTGTATAATAGCCATGGGAAAATGGCTTGATGTTAAATTCAGTCTTGTTAAATTTGGTTGGTGTTCACCTTGGTTATGTAGTTATGAGCCTGGTATGTGTGATGTTGTGCTAGGTACCATGTGATACACAATTGGTTTGCTTATTATGGTAAAATTTAGTTTTATATGATCTTGATTAAAA
->XM_003676498.1 Naumovozyma castellii CBS 4309 hypothetical protein (NCAS0E01160), partial mRNA 
-ATGCCATCTTTTGAAAGTGGTTCAGGTGCTGAAGAAGAAGAAGAAGAAGATTATTTTAATGACTTAGAGGTTGATCTTGGAAGTGAATTAGAGGAGAATGAAGAGGAGTACGAAGCTCTGGACATAACTCCTCAAAGTGGATATGACGATGCCTTCAATGATCTAACTAACGACACAGCTTTTCTAAATGAATTAGTTAAAACTTTTAAACCTTCTACTATGCTAAGTTCTGTCGATATGAACATGGAACCAAAGAAACTTTCGATAGTATATAGAGCGATCGAAAAACTTAAGGCAATGTTTCATTCCCAGTCAACATCATTCATTGAAGTTTTGCCTCATCTGAACGAACTTAGCCATCAGATAAGAAGAGAAATAGACATCCTTTATCAATATTCGAAAAACATATATTCGACAAGATTTACTGAACTTGATACCATAGCAGCTACCCCATATCAGTATGCAAAAGTTACATCATTGATAGAGGGAACTTCTGATGATAAGGCCGGCCAACTTCCGATCAACATCGAAATTGAAGCTAAACTTTCAAAAGAACAAGTCTTGGTGCTACGAATGTCCATGCAAACTTCATTCCTTAAGAATAAACCTTTAGAGAAGAAGGTAAAACATTTGCTTTTAGAGGCGTGTTCTATGATCATACAACTTACGGACTTGCAAAATGTTATCCTGCAATACATTTCTTCTAACGTATCTGATATTGCCCCAAATTTGTGCGTCCTAGTGGGTCCAGAGGTTGCATCACTTTTAATCGCACACACAGGAGGAATACTTCAATTAGCAGAAATACCTAGCTGTAATCTAGCGTCTATTGGGAAAAATAGACATTTATCACACGAACTTCATACCACTCTAAGTGGGGTAAGACAAGAAGGTTACATTTATAGTAGCGAACTAGTTCAAAATCAACCGATTCAAAATCACAAACAAATGTTAAGGATGGTCTGCGCCAAAGTGGCCTTAGCAGCCAGGGTTGATGCGGGTCAAAGGGGTGCTGCTAAAAACGATTTATTGGGACAACGGTGGCGAGAAGAATTAGAGACTAAGATTCAAAAAGTTACAGAGTCGCCCAATATTTCCAATGTGAAACCATTACCTATCCCAGAAGATAAGCCAAAGAAGAAAAGGGCTGGGAGAAAATTTAGAAAGTATAAGCAACAGTTCCAATTATCTCACCTCAGACAATTACAAAATCGAATGGAATTTGGGAAACAGGAACAATCTACAATGGATGCTTTTGGTGAAGAAATTGGCATGGGTATGACGAGTTCATCCATTCAACAATCGATAGGAGGTATCAGAGCTAGCTCACAACGTGTAGATAATTCGGCCAAGATTACCAAAGTGATGAAACGTAGACTTAAAGAGGCAGATTCACAATCAAAAGAATTTGCATCGTCTCTGAATTCAAGAGAATTTTAA
->XM_026930086.3 PREDICTED: Pangasianodon hypophthalmus carbohydrate (chondroitin 4) sulfotransferase 12a (chst12a), mRNA 
-GTGTGTGTGTTGCAGCTTAGATTTTGACGTGTAACTACTATTTAGGACAGCAGACAGGGTTATATATGAATTTAGGACAGTACTTAAACTTCATGGTTATCTGAAGCCGTGTAATGATTACAGCAGTTGCTGAAATCTCGCGAGGTTTCGGAGATCTCGCCTGATCGTGCGAAGAGCGGTCGCACATCATTCCGGAGGAGACGACGACGACGTCTGGGTGGAGGGTCTCGAGATGACTGATGGTGATATGGAGCTTCGGTGAGAATGGAACTCTCCCTGTCCAAACCAGACAAAATGGGCAAGACGAGGCTGTTTCGCATCTTTCTCATTTTAGGCTCTGTCTTCATGATCCTGCTGATCATCATCTACTGGGATGATGTTGGAGCCACCCATTTTTACCTGCACACAACCATATCCGGACCTCATTCTTCCCGCCTCCCACCCGAGAGTCATGCAGCTTCCAAAAACAAAGTTGAGGAGGACAAGGATGGCTCGTTCCTGGCCGACATTGACGCTTTTGTCAACCAGTTCCTGGAAGGCACCTCCGACCCTACGGAGCAAGTGAGAGCTGAAACGCCGCCCGGTGAGACTCACAACCAGTCCTCAGAAAAACCCGAGGAAAGATTCGTCCCCAGGCGCGAGTGGAAGATCCACCTGACCCCGATCGCCACAGAGAAGAAGCAAAGGCAGGACAGCAGGAAGCAGCTGATCCACGATCTTTGCAGCAGCAACAGCAGCTTCGACTTCCCAGGCAAGAACAGGACGTTCGATGACATCCCCAACAAGGAGCTGGACCACTTGATTGTGGACGACCGACACGGGATCATCTACTGCTACGTTCCCAAGGTGGCGTGCACCAACTGGAAGCGCATCATGATCGTGCTGAGCGAGAGCCTGCTGGTGAACGGCGCACCCTACCAGGATCCTCTGGACATCCCCGTCGAGCTCATCCACAACAGCAGCGTGCACTTCACCTTCAACAAGTTCTGGAAGCGCTACGGCAAGTTTTCTCGTCACTTGATGAAAATCAAACTCAAGAAGTATACCAAGTTCCTGTTCATCCGAGACCCTTTCGTGCGGCTCATCTCGGCTTACCGCAACAAGTTTGAGCTGGAGAACGAGGACTTCTACAAAAGATTCGCTGTGATAATGCTGAAAAGATACAGCAACTATGTCGACCCGCCGGCGTCGGTGGTGGACGCTTTCGCTGCTGGAATCCGACCGACTTTTTCAAACTTTATTCAGTATCTGTTAGATCCGAACACCGAGAAAGAAATGCCATTCAACGAGCACTGGAGGCAGATGTACCGCTTGTGCCACCCTTGCCAGATAAATTACGACTTTGTGGGAAAACTGGAGACCTTGGACGAGGACGCTGAGCATTTGTTGCGCATCCTGCGCGTGGACAATGTCGTCCAGTTCCCACCGAGTCGTCACAACAGGACGGTCAGCAGTTGGGAGCAGGACTGGTTCGCCGACATACCTTACGAATCACGCAGACAGTTGTACAAGCTCTACGAGGCTGACTTCAGACTGTTTGGGTATCCTAAACCTGAGAAGCTTTTAAACGAGTGAAATGGGTTTCTGAGTATTTTCTTGCTGTGGGTTATTTAACTGTAGTTCATTTGGTTAATGAGTAAATTTTTTTTTTTTTTGTGGGTCCCCTTTTCTCTGTGAGCATCGCTCCCGTTTGCTTATCACACAAGCATTAGAAAGGGTTGATTAGAGTGAAAACCGATATTACATTCAAATTTTTAAAAGTTTCCTGTATACAGATTTATACTTTTTATCTTCTTTTGAGAACACATCCGTCTGGCACGCAGTACTGTACTGTAAAGTCGGGCGAAGATGTAGGTTTTAATTATTATAGAATATCACAACAACAGTAATAATAATAATAATAATAATAATAATGGCTTATGCCTTTAGTTTTTCATAAAGTATTCTTTTTACTGTCCTCAATTAACCATCATTCATAGTTTCTTTCAATTTGATTTTAAAGAAGTATGCAGCTTGAACATACAACTGCTATGTTCTGCACATTTAGGGCAGTGCACATAGAATATGTAGAATATTTTTGTATATTTGCTATTTTGGAAGAGCGAACTTTTAGCTTTATAAAGGAAAGGATTCACTGCACTCCTGTAGCATTGCAAGATCAAACCATTTTGCTGGCACTCATTAAGCGTAGCTTGTGTGTAGACATCACCTCATTTTTTATTTTTTTTTTCCATAGCATTTGCATTTTTATCACCCACCTCAGGATGCAAACACTTTTTTCAGACCTCATTTAAAATGTATTGAGTGCAAATGGATTTTCAGACGTTTACTTAGGAAAAAAAAGAAGAAAAAACCCGAGCAGTATTGGCTCTAATATGCACTCCACACAAGGTATTTCTGTTATTGCTGTGTGATGAAACAGTGTTTCTGAACATCTTCTGTTTTTTATGAATGTTTAATGTTTAACAGGCGTCAAAAAGACATTTCTTTAAAGCAGGGCAGTGCGGTTGACAGATTGGAGCTCCTGTTAGTTTTCATGGCATCTTTCCTTTCATCATTTGCATTCGTTTCTGCTTTGATTTGAACATCGGTTCCCCTGGCAGCAAGCCGCTCTCGCTTCATTGCTACATCTCTCTTATTGTCAGTGTGCCATGTGTGCCCTTTTTTAAATTTTTATTTATTTTTTTTTTATAAATGTCCATCTCTCAAGAGCTGGTCATGGATTGTGGACAAGTTTTACTTGTTCTGGTAGACTTAGCATTTAGCAAATGATGCCTGGTTTGAGTATTGTTTTGTCTAAATGCAGACTCAGCAGACGTGGAGCGGTCTTAAAGCACAAATATTTGTCCAAGGCCCTTAAACAGTAAACAGTTCACTTTAGGCGCCTGATTTGCTCTCCAGCGTTTCCCAGAATTCTCCATACGTAGTGGACTGTGTTTGCCAGCATCACGTCAGTTGTGCCTTCGTCAGCGGATGTTCGTGGACGTCCGCTTCTCCGTTGGTCCACAACACTTCCAGTCTTTTTGAATTTGTTAATAATGTGCTCGCCGTGTTTCCTTTTAAAGTCCATCTCAACCTTGCGACAGCTTCTGATCCAGCCATGAGAATGATTTCAATACGAGAATGATTTCTCAAGAAGACAATAGTTCTTCTTTTGTCAAAGGCATCTGTAAAGGATATCTGAAAAAAAAAATAATAATATAAACTAAGTATGAAACATTTTGGAAGATATTTTGCAAAAAAAAAACAAAAAAACCTTAATGTACATCCTATGTATGGAGACTTTTGGGATACCATGCAGAGTAAAGTAAGCGTGTCACAAGGACTTGCGAGGGATTTTACGTGGGAAGTTTTCGGTTTTCGGTTGCCGTCACGGTGTTTTTGCGTGTTGCATTTTGCACATGGAACAGTTCTTGTCCTGGATGAGAACGCCGTTTCTGAGAAACAGGAATGTGTTACGGTGAAATGGTGTACAGAGAGCAGGAGCGTTATGAAGCACAGTGTGACTGTAGTAGGTCAGAGGAGGAAGGTTTTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGGAAGCCTAAACCACCATCAGCAGCTGTACTAGAGGAGGCACTGCACCGGGTGCTAGCAGTGCCTTTCTTAAGATAAGATTTAAAAAGTTTACACAAACAAAAATAAATATGTATAATGTACAGGTATTTTTGTAAATGGGTCAAATTTGAGATTTTCTTTCTCACTTGCTAGTTAGATGATGGGAAAACATTTAAAAGTATTAAATTCTGTGTCGTGTAATTTTAATCCTAGGGGTTTTGTTTTAGTTCTGGCTGTATTGGCGAGATCTGTTTAGTTATTTTTCCATCATTTTCACTGTTGTTTATTTTTTTGTCACTCGATTCCCATAGTTTACAAAAAAAAACCAACGTCAATGCAGTTAAATGTCCGCACAGTATTTCCTGATGTTCTTGTGCCACAGTATTCACTGAAACGTTGACATAAATGACAGACACATGCTCGTTCGCTGGCTGATGTGAGATTTATATTAAAAAAAAAATATTCTGAGATGATTCTCCAACATGAAGGTTTTGTGTTTGCATGGAATATGTTCATTTCAAGGGAAATTGCTGTGTTTGCGATTCAAAAGGCGATGTGTATTTCTTAATGTTGCATCAACTGAAAAACATTCTCCAGTGTGCTGATCTGGAATACAGTTTTGTATTTGGCTGGTGTTTTTTGTTTGTTTTTGTTTTTTTAATTTATTACACTTTAAGGACCTTTGTTATGCAACGTCAAAAGAACAAATAAAGCTTAATGCATGGTGCAAAA
->MF557355.1 Uncultured bacterium clone 1686 16S ribosomal RNA gene, partial sequence 
-GTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTCTCTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGGGGACTTGAGTACTGGAGAGGAGAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAGGAACACCAGTGGCGAAGGCGGCTCTCTGGCCAGTAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCC
->XM_012605072.2 PREDICTED: Gossypium raimondii heat stress transcription factor A-4b (LOC105780637), mRNA 
-TGTTGTTACTAAGTCATAAGACTCGTATAATTAATAAACCCACTGTTTCCTATCTCTCTCATCTTCTTCTTCCTCTTGCTTTTTCCCCAAGTTTTTATTTTGGATTGGATTAGAAACTTCCACCCACGTGTTTGGTTTTTTTATTTAACTTCATATTTTTTCCTCAATACCCTTTCTAGATTATTTTCCTGGAAAATTTCCCTTTTTTCTTTTCATAATCCAACCCTGTTTGACAATTTTACATGGGATAAAGGAATATCTACTTTCCTCTGGATTGTTCTTCAAAGGTTTTTAGGGTTTAAAGGTTTACGTGCTTTCAGTGGAAGTGATCCTGGTTTCGATTTAGCTTCTGAAAATATCAATTGTTTTGACTTTTTTGATTTAAAAAGAAAAAGGAAAACGCAGGCATATGCTTGAGTTTGAATGAAATGGAAGGATCGCAGGGAAGTTGTAATGGGCCGCCGCCTTTTCTTACAAAGACATACGAGATGGTGGACGATCCAGTGACTGATTCGTTGGTGTCTTGGAGTGAAACTGGTTATAGTTTCGTTGTATGGAACCCCCCAGATTTCTCAAGAGATTTGCTCCCTAGATATTTCAAGCACAACAACTTCTCAAGCTTTGTCCGTCAGCTCAACACCTATGGGTTCAGAAAGATAGATCCTGATCAATGGGAGTTTGCAAACGAGGAGTTCATAAGAGGGCAGAAACATCTTTTAAAGAACATTTATCGACGCAAGCCAATCCATAGCCATTCCTTGAACCGGCAAGGAAGCTCTAGTGTGCCATTGACTGAGAAAGAGAAGAAGGAATTTGAGCAAGTGATCAAGATGTTGAGTGACGATAAGAACCGGCTTCAGTTACAGTTGCAGGGTCATCAAAAAGAGAACGAGGAATATCGGTGTCAAGTAAGGCTGTTATCGGAGCGTTTTCGGAACATGGAAGATCGACAACGACGAGTGATGGTCTCATTGGCTAGGATTATAGACAAACCCCATGTTCTGTCCCAATTTCATGGCAAAAAGAGAAAGTTATTGAACTGTAACGACTTCAATGATGAATGCAACATACAAGATCTTCACAGTTTGGCTTCTCTGAATGCAAACATGGGATTGGACTTGAAACAGATTGAAGAATTGGAATCATCTATAAGATGTTGGGAAACATTGTTTCTCGAAATCGGAGAAACTATAGGTGAAGAAGTGCGCGATTTCGGGACATCCTTACGGCCTTCTCCGGTTGTTGTTACCGAAATACAGACATCTTCAGGGGACTATGACATGGATGGTGAACTTTACTCACCTTCATCACACCATTGCTCCCCTTATTCAACCGATATTAACTCATCACCTGAGCTGGTAGCCCCTGCTTATCGTCCTATCCATACACCATCATTTCACCATGTCGTAAATCTCAACCCAAAGCCTCCTGGAATTGGCCTAAACTCCCAACATGCTAGTCCACTGGAGACCGATCAGGCCTCAAAGAACCAGGCAGAAGCAGTGGCGACCGGTTATACCGTGCCAGGTAGTGTAAACGATGGCTTCTGGGAAAGGTTTCTAACCGAAGTTCCGGATACATCATCGTATGCACAAGAGATCCAGTCAGTTTAGATTACCTGGCATAGCAGCTTTCTCCAGATTAAAGAATTTAGAGTAGGTTAAGTGATAGAAGTGAGCTATGCTATTAACCATGTATTACTTCTGCCACATACTATGATGTAAGGATATTAGGTTAGAGGACTCTGTATTTTTTGGTTTACGTTTATCTATCTTCTTTCTCTTAGTTATTTTAGCAACAATTTTCACTTTGAATTGAAGGTTATTTTTTTA
->XR_002390227.1 PREDICTED: Heterocephalus glaber uncharacterized LOC110346290 (LOC110346290), ncRNA 
-TTTCAGCTTTCTCCTGCCAGTTACCTCTATCTCAGGCAATATGTTTACACTATTTCTTGGTTTTTTCCATGACTGTTACACTAGGAAATTAGAATTTTCCTCTCTTATGCCCTCTGTACACTCAGCCCCCCCAGGCAGATGTATGATAAGTTGTGGTAAGATCAATATTCAACAGTCACTGTTTCATCTGTGTAAATGTTACTCCATGAGCTGTATTTATCTTCTTGTGCAACTGGGTTGCTGTATGTTAATAATTTTCCTGTGTTTGTTTTGTTTTGAGACAGGGTCTCACTATGTAGTCCTGGCTGGCCTTGAACTCATTATGCTGCTTAGGCTGGCCTTGAACCCTCCGAGATCCTCGTGCCTCGGCCTCCTGAGTGTTGGGATTGCAGGTGTGCACCACCATGTCCGGCCGTCTTGGTTTTCTAAGCATCTCTCTGCTTCATCACTGAGCGCCCATGAGTTGCTTCTCTACTGCTCCAACCCATGCGGGTGTTTCTAAGTCATAAGCCTGAGCTGGAACTTGGGATCCTCCTGCCTCAGCCTCCTAGAGCTGGGATTATAGACCTGCACTACCATGCTAAGCTTTTGGTGCCCTCCCCACCACCACCACCATGGGTCCAACTCAGGACCTTGCACTTGTGAGGTATATCCTGGAAGACTGAAATCACAGAAAATGGGCTGACATTTGCTCTAGGAGCCACGAGTCAGTCTTTCCTGGCGAACAGTTCAGGTGCATTCCACAGCTGGCTGAGTGCAATGTCCGTGTCCACGAGGCTAAGGCAGTTGGCAGTCACTGACACCATCTCATCTCCAAGTCTACTCCATCCTTAGTACAGTTAGTGTTTGCTGTCTCCTCCTGTCCTTTCACTTTGTTTTTAATGTGAATTTAGTATTTCTTTGCTGTTCTTCCTTGAACTGGGGTGTGTGGTGCACTTACCATTAAGTTAATTCAGTGAATATCTTTGGTTTATTCCTGGGAGGGAAAGTGGCTTTTGTTTATATTTGCTCTTGCCATTTGTTCCTACTTCACTTGAGTTTATTAGTTATTCCTTTCTGCCTTCCTTGAGTTAATCAAATATTTTTCACAGTTCCATTTTGATTTTTCTAGCAGCTTGAGCTATACCTCTGCATTATTGCTTCTGGTTACTCTGGGGCATTGGTGGCAACCCTGTGGTATGAGTGCAACAGCGGGCTGTATCATTGAAAGCTCTAAAAGGTTTGTCATCGCTGTTCTAGGGATTACAATATGTATCTTTTTCAAAATCTAATTAGTATTATGCTACTTTACACCAAAATTAGTAACTTTTAACAGTGTAATCCCATTTTCCCAGTCCATATAAAACACAACCCTGGATAGCATGTAGAGTCTCACAGCTAATTAAAAACTAGTTAGTATGCAGATATGGCTGTTTTTAAGTCAGTATGAAACAGTCTGGGACCTCGAGCAAACCCCACCAGTTAGCAATGAAAGAGATTTGGCCAAAGCACCCAGCAGTATTCATTTAAAAGCTTCATTTGGAGACATTCTACATGCAGTCATTCGGTGATGCATCCAGCACAGGGAGGCTGCTAACAGTGCATCCTGCAAACCTTTCAATCCTTTCAGAGTAAGAAAAGCCCAAAGGATGGATGGAACATCTGAATGGTCCCTGAGGTCTGTTTTGTTTCCCTGCTGGCTTAGCAGTCAGTCATCATGGAGACCTCAGTGTTAAATGTCACCCAAACGCCCTCACCCCAGAGACAGGAGGAGGCATACCACATGTCCTCAGGCAGTCACAGCATCCTCCTCCAGTCCATTCTTTAGGACAGCTGAGCTCCCTGACAAGGTGAAAGGAACAAAGTACTAAGATGATGAAAGCTGTATCACCAAGTCCTCCTGAGTGTGAGCATCATGCCCTGGTTCCCGTGCACTTGGTGAGGCTGCAACCAGGAGGCTAGGTACGATGCCCACTTCTGAGCTGAGCAGACAGGAAGGGTGAATTCCCAGAACCTGCTGTCAGGAACAAGCATCAGAGCAAAGACTCTAGCTCCTGGGAGAAACTCTCCAACCTAGTTGTGTGGCTGAAATTAGTAGGGAAAGGTGAGGAAGTTACGTCTATCTAAGAGCAGGAGGATTAAAAGCTGCCAACTAGGAAGGAAACTGAAATGCTTAAAAAGTTAAAAAAAAATTTTCATTGTAGTCTGATGAATATTTCGAAGTATATAGTAAGGTATTTAACAAGGACTGGTTACCTGTGTGTAGGTTAGAGATACTAAAGTGATATGGTGCGCTGTCAGCCATATGGGGTGCAGACTTCCTCCAAAGCAGATCAATAGACTTATTGTTAAAGACAACATGTGTATTGAAAGTAGCAATTTTATTTGAGTTAAAATTATTTACAAAAACCCAAAGACATACTTCATGAAACTGGTACAAACTATTTTTTTCCTGCCGTTGGCTTTTGCTCCAAAGATCACAGCTGAGAAATACTGTATAAAATAAAAATAGGATTGGATTCAGAAAAGTACTCTACTGTTCTAATTTCCAATTGGTAGTATTTACAGAAATATTTACAGTGG
->XM_028898326.1 PREDICTED: Prosopis alba vestitone reductase-like (LOC114713661), transcript variant X1, mRNA 
-ATGGAAGACAGCAAAGGAAGAGTATGTGTTACTGGTGGTACTGGCTTCATAGGTTCTTGGATCATTAAGAGACTTCTTGAAGATGGCTACTCAGTTAATACTACCGTTAGATCCAACCCAGAACACAAGAAAGATGTGAGCTTCCTCACAGATTTGCCAGGAGCATCTCGGAGGCTACGAATTCTGAAGGCAGACCTAAGCGAGCCAGAAAGTTTCAAGGAAGCCATTGAAGGGTGCATTGGAGTATTCCATGTGGCTACTCCAGTGGATTTTGAGGAAGGGGAACCTGAAGAGATTGTGACCCAAAGATCCATTGATGGGGCATTGGGAATTCTGACGGCATGCCTCACTTCAAAAACTGTGAAGAGAGTCATTTACACTTCCAGTGCCTTTGCTGTTAATTATAGTGCCAAAGAAGAGGAAGTGAAGGATGAGAGCTCATGGACTGACGTGGATTCTCTTAGAACTTCAAAACCATTTGGATGGTCTTATGCAGTTTCTAAGACATTGACAGAGAAAGCAGTGCTTGAATATGGACAACAAAATGGATTAGATGTTGTCACTGTGCTTCCCAGTATTGTTGTTGGATCCTTCATTTGTCCTAAGCTTCCTGGTTCTGTTGGTTCGGCACTCTATTTTTTATTAAGTAAGAACGACCCATTTGCTTATCTGCAGCTACCTATGGTGCATGTGGATGACGTGGCAAGAGCACATGTATTTCTGCTTGAACATCCTAAGCCAAGGGGAAGATATAATTGTTCTTCATGTCTGGCTACTGTTGAAAAACCACTTGAAATTGTGTCTGCTAAATTTCCAGAACTTCAAATTCCAACCATAGAAGAAAGAGCTAGCCTGAAAGTTTCAGATCTGCCATCTAAGAAGCTTATAGATGCTGGATTTGAGTTCAAGTATGGACTTGAGGAAATGTTGGTGGATGCTATTGGATGCTGCAAAGAAAAGGGTTTTTTATAG
->XM_044451096.1 PREDICTED: Varanus komodoensis leucine rich single-pass membrane protein 2 (LSMEM2), mRNA 
-CCTGAGCAGCTGATGTGACAGGCAGAAGCCTGTGTTTACTTCCCCAACCGCTCCCAAGGGATCTGCATAGGCCCCTCATAACTTCTTCCAGACAGATTTTTTTCCCCTTGAGTTGCCTCCGGAACAGCCCAAGGAAGCGGAGTCTGGCTATTGGGATGTCCAGCGAGATTGCAGAAGGCGCTATGGTGAAGGAGGCCACTTCCTCGGATAGGGAGCTTGTTGAGCCCTGCGACACTGACAGGGCAGAAATCAACCTGCATGCAGTGGAATCCATTAGCGACTTGCACTACGCATCCGGCAGACCGGAGGGCTTCAAGGCTTCGGAAGGGAGCAGCCAATCTCAGCCTAACACCCCCTGGACTCCGCACAGTGCTTCCTCCAAGCATTTCTTCTTCCCGAATGAAGAGGACCCCTCCTTCCTGCCAGTCCAGAATTTGCACATTGCCCCCGATTTCTTCTGCTGCCCCTGCTTCAGCCCCACGTGCTGCCCCACAGGCTTCTTCGCTCTCCTCGGCGTGCTGGTAGTGGCCAGCCTTGGCCTGGCCACGCTGGCGGTCTATCTGAGCGTCCTGCAGCGCGAGTCACTCCGTGTCCTCAGCCAGTGGCTGGAGTCCCAAGAAGAGGCCATCCGGCAGATGAGAGCTGTGAGCGTACAGCTCTGGAGGCAGCTCAACGCCAGCGAGCCCGGGGCTCAAACCTGAGTTGCACTGCTCACCCACAGCCTCCTTTTGGGGGCGCTCAATTCCAGTGCGACAGAAGAGGGGACACCAACTCACTGCTTGGCACCTTTTGGACACTGACCTGTGCTGGTTTGGACTGTGTGATCCCAGAAGCTTAAAAAAAAAGCTCTTTTGAATCACGGGTGGGTCTTGTGAGGTTCGTGTGTCTTATTGGAAGCAAAAGCTGGAGACCTTGAGGCTGCCTCAGGCGGAGAGGGGGCAGGCAGGCAGGCAGATGTCCTACCGAGGAGTAAAGCAATTGGGGGTGGGGGGGGGTCTGCTCAGCAGCCTCCCACCAAGGGCAGCATCTCAGCCACTCTTCCTTTCCTTCCTCCACAGCATTTTAAAAGACATCACCTCCATCTTCTCTGTTTTTTCGCTCTGCTTCACTCTATGATTATTTAATGGTTTGCCAATGGAGCACCTATGCAGAAGTGCCTGACAGCACAAAATAAAACCCTCAAGTTTCTGCTGCCA
->XM_004069731.4 PREDICTED: Oryzias latipes pyruvate dehydrogenase complex component X (pdhx), mRNA 
-CAAAGCCAGAATTTACGGACTGGACGAGGGAGGACAGCAACATGGCGGTCTCCTTGCGCCTGGGTCGTCAGGGAGCTCTGCTTGGGCTCAGATTCAACCAATTTAAAAAATCAATATGTCCCACACATTATTTCCAGGACCGAGTTCGACAGTTTTTTCATTCACCATGGGCGCTTGGTGTCACTCCACTCAAAGTGCAAATGCCAGCTCTCTCCCCCACCATGGAGGAAGGGAACATTGTTAAATGGCTTAAAAAAGAAGGTGAGACCGTGGAAGCAGGTGATGCTCTCTGTGAGATCGAGACTGATAAGGCTGTGGTTACCATGGAATCCAGCGACGATGGGATCCTGGCAAAGATACTGATGGAAGAGGGCAGTCGCAATGTGCCCCTTGGCACTCTCATTGCCCTTCTGGTGGAGGAAGGACAAGACTGGAAGCAGGTTGAGGTCCCCTCACCAGATTCTCCATCTGCAGCTCCCACGATTCCCCATGAACCCACTGGCTCCTCTGTGACCCCCGCATCTCCTCCTCTTTTACCCAAACCTGCGACGTCAGGGCCGTTACGTTTAAGTCCAGCAGCACGACACATTCTCAACACCCATGGTATTAACCCAAAACTGGCCACACCCTCTGGACCAAGAGGACTCATTACAAAAGAAGATGCATTGAATCTTTTAAAGGCGTCCCCTCCACCCAAAGCAACACCAGTTGTTGCCACGGCAACTGTCCCAACTCCTGTTCAGAGACCCACCCACACCCCCACAGGTCCCCCACCACCTCCAGGCAGCAGACCGAACATCCCCCCTCTGTCTGTACCAGGGAAGCCCGGAGCACCAGGAACCTTCACAGAAGTCCCAGCCACAAACGTGCGGCGTGTGATCGCTCAAAGACTGACCCAATCAAAGACCACCATCCCACATGCATACGCCTCCATAGACTGTGACATGGCTGCCGTCATTAAGCTCCGTAAAGATCTGGCCAAAGAGCAAATCAAAGTGTCTGTCAATGATTTTATTATCAAAGCAGCCGCTGTTACTCTAAAACAAATGCCAGAGGTGAATGTGACTTGGTCTGGTGATGGACCCCATGCGCTCGATTCAGTCCACATCTCGATTGCTGTGGCGACGGACCGAGGCCTCATCACTCCTATTATCAGGGATGCAGCTAACAAAGGGGTGCAGGAGATCTCAGCTCAAGCTAAGGCACTGGCTCAAAAAGCTCGAGATGGCAAACTTCTTCCTGAGGAATACCAAGGAGGCTCGTTCAGCATATCTAACCTGGGCATGTTTGGAATCAGCGGCTTCAGTGCCGTCATCAACCCTCCTCAGGCTTGCATCCTGGCTGTCGGGACCTCCCGGGCTGAGCTGCAGCTGAAGGAAGAGGATCAGACCGTGCACACGCGGCAGCTCATGACAGTAACCATGTCCAGCGACGGACGACTTGTGGATGACGAGTTAGCGTCTCGGTTTCTTGATCAATTTCGTGCCAATCTAGAACAACCACAGCGTATGGCCCTCGCTTAAAAAAAAAACAAAAAAAAACAAAGATGAGGGGAAAGATAAGAGAAAATTTGAAAAGGTCTCAAGCTATGTCTTTTGACAAGCAAGGAGCTGAAACAGTTTGTGTCTGTCCTTTCTTTAAGGCTTTAAATAAGGTTGTGTACATACTGTGAACTTAAGTTTGTGGCCTCTCTGCTTATTGTCCGCAAGTTTTTGGAGTGGAAATGGATTTCTCCCTAAATTTAAAGGGCTTGTGCAGTGGTTCCACATTCTACCATGAAAGATAAGACGGCAAATGTGATCCATCACACGGGTGTTGTGTATATAAAGAAGTAATTCTTCAATTTCCAGGTCAGACTTCATGAAAGTTGTTTCACTAAACGTAAACGTGAAATTGGTGAAGTCTCCTCATGTAAATTTGTGAGATATTTATTATTTAACATAAGTGACACTGCAGGTAAAATCCATGTAAAGCAGCATTTATTGTTGCTCATTATAAAAGTAAACTTAGTATGTGAACAAATTTATAAATTTATTCAGAATCACACATAAAGAAACATCTCCTTCTGGTCCACATGTATACATCAGGTTTGGTTTTGTTGTCTTAAACTCTGTCCAAGCAATAAAAGTCCTGTTCAACCATCTGA
->XR_004159256.1 PREDICTED: Meleagris gallopavo uncharacterized LOC116216471 (LOC116216471), ncRNA 
-ACCACTGAACAGAGCCTGGCTCTGTCCTCTTTGCATCTCCCATTTTATATATGTTAATGGGACCTCCTTGGGCATTCTCTTTTCTAGCTGATCAGTCTCAGCTCCCTCAGCCTCTCCTCATGGAAGTGCTTGGTATACCCAGGCTAATTTGGAATGACTACCTATTGCTGTCAAAATAGATACCCTACTAACAATTCATTCAATAGGAGCTTACTGCTGTGGAGAAGCTGCCTGCTGCAGTAACAGCATGACATGTTCAGACTTGTTATGTTGCCTGACAGCCTTGACATATTTGCTCTGTTTCCTCTATTTGTATAATGGTCTCTGGCTACAACACACATCCCTGGACATGAATTTTCATTTTAAAGTTCCCAAATGGCCTTCATGAAACTTGTGTGCATATAACCCCAGTATTGCAGAAATAAGTACATCAATCGCAAACTTCAGAAGGGGAGCATGTTTTACACCTGACTGCTCTTCCTAACCCAGAATCCATTTGTTTATTGTATTTTAGTTTGGATTTACACACTAGCGATATGTCTTCTTACTTTATGCAACATTGCAATATTACTGCTTTACATAGAAAAAACATTGGCTGCACTGAGTCTCTGTTTAAAAACTGTTTGGATGTGGTGCTCAGGGACGTGATTTAGCAGAGGGTTGTTGGAGTTAGGGTAGTATGGCTAGGTTGTGGTTGGAATTGATGATCTTTAAGGTTTTTGCAATCTGTAATTCAATGATTTTTGTGATTCTGCAGTGAAAATGCTAAGTCTCGGCTTGGAACAGTGATTGAGCAGCTGGTGGGAAGGCAGGGCCAGCCCAGGAGAACTCAGGTGGATGCACTGTGCTCATTTAAGGGCTGGCAGTGGAGGAAGGTGCATATAAAATGAGAGTTTTCCCTTAAATGAAATATAAGAAATTTCCTAGACTTCTGCTGTGTAACCTACGCTGCTTCCAGCTTCTCCTGATGAGCAACTTGGTAACTGTGCTTTTTGCTCTTTCCTGATGAAGAACTGCTGCCTTCACTGCTCCATTTCCTGCATTGCTCACTCCACCATCCGACACCTTCAGAAAATATTGCCACCTGTTGAGAAATTTTACAATCTTCCTGCCTCTTGATGATGTGTGGGATTTGGAGGAGAGTGGATAAATAGAAGAAGACCTGTAGCCTCTTCATTTGCATCCTTGACCTGCTCAAGGCTTGGGCAGTACCTTGGTGAAGGACTGTTGGTGGTGGTCTCAGAGGAACAACCAGTTAAGAAGTATACTGGAGTTTTGAAAGAACTACATGGACTGAAGTGAAGATCATGTTCCCAAACTTCTGATTCAATGGAAAGCATCCTTTAGCTTGATACAGAGCTATACACTGTCAAAAGGCTTTTTCACATCTCTTTGGGAGACAGATTCAGCCACATGCTCTCGTCATTCACAGTGGAACTTCATGGGTAGGCAGAGGACCTCTCCCTCCGGGCTGATCTGGATGGGGAATGCCCACGGTACCTGGCACCTG
->XM_041282614.1 Brettanomyces bruxellensis uncharacterized protein (BRETT_004118), partial mRNA 
-ATGCCACCGAGAAAAAGAAGAGGCAGAAAGAAAGCCACTTCTGTATCGAAGAAAGCAACCAGAACTAATTCTTCACATGGTACAAGTGATGCCACGCAAGATACCTTGAAAGATGGTGAGAAGAAGATTGAAGAAGCAGCTAAAACTCCCAAAATCACAAAAGATCTCAAAGAGTTGGAGGAAGAACGGAAAGACGCGAAAAGTGAAAAGCATGGCCAAAGTTTACCTGTTACGACTGATGCAACAATTGAAAGCAATGTTAAATCAATAGATTTGAAAAAAGCAGAGCCCAGTAATGTGCTGTCTAAAGAGAAAGAAAAGGATGCATTTGCAGAAACAGAAGCTGATGACATAATGAAGATAGTGAATGAGACGAACGATAAGAAAAGGAGTATAATGAGTCCAATTAAGAGTTTGCAAATAAGCCCTTTAAAGAATATAATAAAAGGCGATACAAAAGATCTAAAACCTGATGCAGGAAGTCCGATCAAACGCAGAAAACTTGATCCTTCTCCAGAACGAAATGTTGATAGAGACACAAGATCTATGGAAATGCACGTTGGTTTATTGTTTCAGAAGAAAGACTTAAAGGGTCTCACTGCCATTTCTCAGAAGACTTCCAGGAGGTCTGCCCAGACATTTGAAAATTACAAAAAGCTAGTTGATCGACGCGCAAAAACTGCAGAGATTATTATTGCGAACCTTACAAAAGAGAATAAGACTTTAAAGAACACAATCAAGGGACTCAGAACTGAGAATCGACATTCAACGAATGCAGTGGATAGCAAAGAGATAAACAAATGGAAAACAAAGGAAGTAGAAACTAGAAAGAAACTAGACAAGTTGGAAGAAGCCAAGAATAGCATAGAATCAAAACTTTCCGATGCGAACAACGAATTAGTGCTATCAGATTCAAAACAGGAAATGATCGAACTGCTATGTGGAACAGCATGTCTTGATTACGAGGAAAATGAAAAAAGCATTATATTTGCGCTTAGACAAAGTGGTACACTGTGTACATTATACTATCAACTCATCATAAATAAGTCCGAGCCATCAGATTTAATATACTCCCCAGTTCAAAAGAAACCGCAGGAATGGCCTACGGATAGTGCAATTTCATGGAAGGTGAATATGGATCGGTTGCACTCACTTCTTCCAGAATACTTGTTGGACAATCTTACTTTCCCTTCAAGCAACTTGAGAAACTTTTATCGAAAAATATCAAAAGCCGTGAATGGAATGGGAAAGCAGAAAGAGGCAGCATGA
->XM_013019345.1 PREDICTED: Dipodomys ordii tumor protein p63 (Tp63), transcript variant X7, mRNA 
-AAAACTTTTTTTTATCCCCAGAAGAGTGGACAGATACCATCAAATCAACTCAGTATCCAAACCCAAGGAAATGTAATTTAGCTGGAGGGAGATGGCCATTCCTCAGACTTGTTATAAAAGTCCAGGCTGCTGAAATTAAACTCTGATGCCATTCAAGCCAACATCCAATCAGGAGAGAGATCAGAAGTTCAGAGATGCCTCCAAGTTGCCAGCAAGTGTGGCCACTGTATGTCAAGGACTCTAAAGCCGTGGAAGAAAGGGAAGAACAACTTTAGTGAGGATGCCCAGCTGGTAAGAATCAACTGTTTGTGATGTTTTAGTCACTTGAGGAATCTCATTGGCTAACTTGAAGAAAGGCTCCACCTCTTTGCAAATATGTGGAATGGGAGAGAGGGGGTGAGGAAGGGGAAGTGTCTGAACTTCTATATCTGATGGCATCTGACCCTAATGCTTTAAGCCTCCTGGCCATATATCTACATATACACAGGTATATGTGTATGTTTTATATAATTGCTCTCCATTTGTTGATATCAAAGAGAGTTGAAGGAAATGAATTTTGAAACGTCACGGTGTGCTCCCCTACAGTACTGCCCCGACCCTTACATCCAGCGTTTCATAGAAACCCCAGCGCATTTCTCTTGGAAAGAAAGTTATTACCGATCCACCATGTCCCAGAGCACACAAACAAGTGAATTCCTCAGTCCAGAGGTTTTCCAGCATATCTGGGATTTTCTGGAACAGCCTATATGTTCAGTTCAACCCATTGACTTGAACTTTGTGGATGAGCCATCAGAAAATGGAGCAACAAACAAGATTGAAATTAGCATGGACTGTATCCGCATGCAAGACTCAGACCTCAGTGACCCCATGTGGCCACAGTACACGAACCTGGGGCTCCTGAACAGCATGGACCAGCAGATCCAGAATGGCTCCTCGTCCACCAGCCCCTACAACACAGACCATGCACAGAACAGCGTCACGGCGCCCTCGCCCTATGCGCAGCCCAGCTCCACCTTTGACGCCCTCTCTCCATCACCTGCCATTCCCTCCAACACAGACTACCCAGGCCCGCACAGCTTCGATGTGTCTTTCCAGCAGTCGAGTACCGCCAAGTCGGCCACCTGGACGTATTCCACAGAGCTGAAGAAGCTATACTGCCAAATCGCAAAGACATGCCCCATCCAGATCAAGGTGATGACCCCTCCACCCCAGGGTGCTGTTATCCGTGCCATGCCTGTCTACAAGAAAGCTGAGCATGTCACTGAGGTGGTGAAGCGGTGCCCCAACCATGAGCTGAGCCGAGAATTCAATGAGGGACAGATGGCTCCTCCTAGTCATTTGATCCGAGTAGAAGGGAACAGCCACGCCCAATATGTAGAAGACCCTATCACAGGAAGGCAGAGTGTACTGGTACCTTATGAGCCACCTCAGGTTGGCACGGAATTTACCACTGTCCTGTATAATTTCATGTGCAACAGCAGCTGTGTCGGAGGGATGAACCGTCGTCCAATTTTAATCATCGTTACTCTGGAAACCAGAGATGGGCAAGTCCTGGGCCGCCGTTGCTTTGAGGCCCGGATCTGCGCTTGTCCTGGAAGAGACAGGAAGGCGGATGAAGACAGCATCCGCAAGCAGCAAGTTTCAGACAGTACAAAGAATGGTGATGCTTTTCGTCAGAACACACATGGCATCCAGATGACATCTATCAAGAAACGAAGATCCCCAGATGATGAGCTTCTATACTTACCAGTGAGAGGCCGTGAGACTTATGAGATGCTGTTGAAGATCAAAGAATCCCTGGAGCTCATGCAGTATCTTCCTCAGCACACAATTGAAACCTACAGGCAGCAGCAACAGCAGCAGCACCAGCACTTACTTCAGAAACATCTCCTTTCAGCCTGCTTCAGGAATGAGCTTGTGGAGCCCCGGAGAGAAACTCCGAAACAATCTGACATCTTCTTTAGACATTCCAACCCCCCAAACCAGTCAGTGTACCCATAGAACCCCATTTCTGTATTTGAGTGTGTGAGGTCATTATGTTTCCGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGAGTGTGTTTATACCCAGCTCTCATAAATAGAACTTGAAGACATTTTGGCTCAGAGACCCAACTGCTCAAAGGCACACAGCCACTAGTGAGAAAGAATCTTTTGAAGGGACTCAAAACTTTACAAGAAAGTATGCTTGCTGCAGATTTTGTACCCTTAGATCCAGCATTGGTTGGACAGGAACCACTGTTGTGTATGTTTGTGAGCTTTTTGTTGTTTCCTGGGAGGGAGGGGATCAGGTGGGGAAAGGGTATTACAATGTTTATAAGACTCCTCTTCTGTTGCTTTCTGTTGTATTTCTAAAACTCATAATGAAGCTTTTGAGCAGGTCTCAAA
->XM_044435426.1 PREDICTED: Varanus komodoensis meiosis initiator (MEIOSIN), mRNA 
-ATGTGGGACCAAATTGGCCGTGTTTGCCCTGAGGAATTACAGCTGAACAGCAAAAAAATCAAACAGAATTCTGATCGAAGAAAACACAGTAACTATACCAGCACTCTTAAAGAACTGGCTCAGATGTTGCCCATCCCTTTGCGGACAAGCTGCAAAAGGTTAACAAAGAAAGAAATGCTTCTCCGAGTCCTCCGTTACATCGAACACCTGCAGGCAAGCATTGATACAGCAAGATCTCTGCTCCAGGTCCACTCTGGGGAGCAAAAAGCAGGAGAATCTGAGCAGATGGTGACAACTGCCCTAAAGAGCGGGCGAAGAGAAACTACACCACGAGTAAAGAAAACGAAGCCACTGGCTGTCTGCAAGAAACCCAGGAAGAGGAGACGCACCCATAAATCAGAGCAACAAGGGGTGAACAAGAAAGTGTGCAAGAGCCTTGCTCTGGAGACCGGAAAGAGCCCTTCCCAAGCCGACGAACAACAGGAGGAGAACCCATCTGCATTGGGAGTTTGGAACTTGAGTGGCAACCATGAAGAAAGCAAGGATTATGCCAATGTGTTTTCTGCGTGTGAAGCTTATGAAGAGCCGCATCGATACACCGAAGTGCCTACGCATTCATTGATGGGGCAGGAGCTGGTGTACTACTATTCCTCTTGTGAGGAAGATGAGGAGGAAGGACCTGAAGCCAGCCCTTGGCTCTCAACCTGGTCCCCTGTGGGCATTTCACATGGTGACCTGCAGCTCTGTTCGCCTGCGATCATCACCCAAAGCAACCGTTGCACAGATCTGGGGTTGAGCCCTTCGCTTTTTTCCTCTCCAGCTCGGTTGCTGCCTACACACATCCTGCAAGGTGGCCAGGAGGAGTTTTCCCCAGTGCTGTTCGAAGATGTATGCCTGTCCCCACAGCCTGGTAGTTTTTCTCAGTCCCTCTCAGGCACCCTGTTAAGAAAGTCAGCATTCACGCTGGATCACTGCTACCTTTCCAACAGCGAAACAGGTAAAAGCAGTTCCAGTCCTGTGTCAAGAGAAAATGAGATCAAGTCATCATGGAACAAGCAGTTCCTTCAAGAGGAAGTTCACACTGCCAGGCCCGAATGCCCTCTGTCCTCCAGTGATGAGAACAGTGACAGCACTTGGACCCCATGCAAGAGGACGAAGCCATCCAGGGCGGCCCGTCGGAAGAAGAAGAAGAAGAAGAAGAGGAAGAAGAAGAAGCGAGCAGGCAGAAGGCAGAGGTGCCGGCCAGTAGCCCGCGAGAAGGGCAGCAACGCCTCCCCTTTGCAGCTGAAGAAGAAGTGTGTGAATGGCTTTATCATGTTTTGCCGCCTGAACCGCAAGCACTTCATCCGCGCTTGTCCAGGCATGGCCTCCACAGCTGCCACAAGAGAGCTGGCCCAGCTGTGGCGTGTGATGACGAAGCAGGAGCGCCACCCATATTGCTTGAAAGCACGGAGATTCAGCCGTCTGAACAATCGCATTGTGAGAGATGACTTCTCTAGCGGGGAAGAGGAACCAGAGCCACCCAAACCTTTCCATCTGCTACTCGCTGAGAAATCCCTCCCTGGCACTGAGAATTTTGGTGACTTCTCTTTACTATAG
->XM_031628525.2 PREDICTED: Nymphaea colorata UPF0548 protein At2g17695 (LOC116253610), transcript variant X2, mRNA 
-ATCTTATTTTTAAGAAGAATTGAAGATGAGAGAGGGAGAGAGATCTGGCAGCAGGTCTGTCTCCCACAAAATGGTGTTCCTGTTCTGGAATCGACCGTCGCCTCATCAACAGTCCGCCTGCCTCAAGCAGGCGGGAGACTTTAACTACGACTCAAAATATCGTTGCTTGACTTCTTCCCCTTCGGATTGCAACCCAAATTCAGCGTCATCTTCGCCGCCACTACCGTCTTCATCTTTGTCTGAGCTCCGACATGGCTCCAACCGCGATGGTTTCGTCGTTAACCGCGCCCGCGTCCTTCTTGGCTCCGGACTCCAGACATACCAACAAGGAAAGCGAGCTCTTCAAGCTTGGAAGCACTTCGGCTTGGATTGGGCGTTTGTGGATCCCAGCAGTCCCGTCGAGGTTGGGGAGAGGTTCTGCGTGTGCGTGAAAGAGCTTGTCCCTTGGGCTGTTCTGCCTCTTCAGATCGTCTACGTTAACGACCATGATGCTGTCAAAGATGGTTCCCTTAAAAGGGGTTTGACGGCCTCCTTCGCTTTCGGGAGCGGAACCCTTCGAGGCCATTTATTGGCTGGAGAAGAGCGGTTCTCGGTTGAGCTGGACGAGGACAACAAAGTGTGGTACGAAATATTCTCAATTTCCAAGCCCGCCCACCTACTTTCCTTTGTCGGTTATCCTTATGTCCGTTTTCGGCAGAAGTACTTCGCCCAACAATCAATGGATGCACTTGTACGACATGTCCACTCTCAAGAGCGTGCTTAATGCAAAGTTCATATCGAAGTCCTCTTGCTCCTGTTATGGCACCAAGAAATTGTTATGGCACCAAGAAATATTGCACACTTCAAAATACATGAGTACTTAGTATTTTCACTCA
->JN440548.1 Uncultured organism clone SBYB_3744 16S ribosomal RNA gene, partial sequence 
-AAAGCAGCTAACTACGATAAACTGGACGGTAAGGGACGAAAGCTTGGGTAGCGAACGGGATTTAGATACCCCGGTAGTCCAAGCCGTAAATGATGCTTGCTAGATGTTTTGGACCCTTGTGGTCTGGAGTGTCGTAATCTAACGAGTTAAGCAAGCCGCCTGGGTAGTATATTCGCAAGAATGATACTCAAAGGGATAGGCGGGGGTACACACAAGCAGTGGATTGTCTAGATTAATTGGACAATAAGCCAAGAATCTTACCTAGATTTGACATGTACTATGTCCTATGTGAAAGCATAGTAGTCCGAGCAATCGGACATGGTATACAGGTGGTGCATGGTCGTCGTCAGCTCGTGCCGTAAGGTGTCTAGTTAAGTCTGGAAACGAGCGCAACCCTCATCTTTAGTTAGAATGTCTAAAGAGACTGCTCTGGTAACGGAGAGGAAGGAGAGGATGACCGTCAGATCCTCATGCCCCTTACATCTAGGGCTTCATAGACAATACAATGGGTGATACAACGAGAAGCTAACACGTGAGGTGGAGCAAACCTCTAAAGTTATCCCAAGTTCGGATGCTAGTCTGGNACTCGACTACATGAAGTTGGNATTGCTAGTAATGNCGGGTCAGCTACACCGCCGTGNATATGTNCCTGTCCATGCACTCACCGCCCGTCANACCATGGGAGCTG
->XM_036157752.1 PREDICTED: Mus musculus predicted gene, 38699 (Gm38699), transcript variant X8, mRNA 
-CGATTGGTGGTCAGGCCTGCGCCCGGCACCGCCGGGCGGTCCTCCGCGCCATCCCCAGCCGGGCCCTCCCCTTTCCGCGGGAGGCTTCCGGGACAGCGGGTTGGTGGCGCGCAGTTCCCCTTGACTGTGCGCGCCCGCGTCTGGGCTCCTTTGCAGAGGACTCGGTAGCTGCAGCTCCCGGAGCACAGCAGACAGAGCTGCAGGCTGCGTGCGCCCCTGCTGCCACCGGACCTGCCGCGGTGGCTCCCGCGCCCCGCGGCGACTTCCGCACCCGCGCTTATCTTTGCTTAAGTCCCCGAGCGGCGGCGGGGTCGGAGCCCGCGCCTTGGGCGACTGAGGCGGCCGCAGTTCGCGGCCCGGCGCCCTGGCGATGCCAGACCAGATCTCCGTGTCGGAATTCGTGGCCGAGACCCTTGAGGACTACAAGGCGCCCACGGCCTCTAGCTTCACCATGCGCACGGCCCAGTGCCGGGACACCGTGGCGGCCATCGAGGAGGCTACACTTGGGAAACCCATCATATTGAAGGACATTGTCAAAGTTCGAGAAGAAATGAAAGCTGCGGGTGGTGTTGGTGTTGGGCTGTGTGTGTGCCTTCCCTTCTTTTGTAGACAGTAAGAGATTATTTACTACCTGTGTTTTCATGTGTATCCTTAACTTCCTCGGTTAGATTCTACCTCTATCTCTTTGTGTTGGTCAGTATGTTTAGAGAGAGGTTGTTTAAATTTGAGTTTATCGTGGACTATCTTAATTTTTTCCATTAACGGTGTAGTCCTTTTTTTACATATTAAAATCCAGGCATCTGTTGTTTTTGCAGCACATGTGTGCAAACCCTTCTGGCGTCTACAAACTCCAAGAAGACATCTGTGATCTTTTTTTTTTTGTTTGGTTTGGTTTGGTTTTTTTTTTTTGTTGTTTGTTTGTTTGTTTGTTTGTTTGTTTTTGAGACAGGGTTTCTCTGTATAGCTCTGGCTATCCTGGAATTCACTTTATAGACCAGGCTGGCCTCGAACTCAGAAATCCGCCTGCCTCTGCCTCCTGAGTGCTGGGATTAAAGGTGTGCGCCACCACGCCCGGCCTGAAGACATCTGTGATCTTAATAGATCTTCCTTTATGTTTTTCCTGGCTTTTTACCTTTGCAGCTTTTAGTATTCTTTCCTTGAACTGTATGTTTTGATTATTACACAGGAAAGAGACTTTATTTTATAGTCCCTTCTGTTTGGTGTTTTGATGATTCTTGTGTTTTCTTTATGTTAGGAAGTTTTTCTTCTAGGATTTGGTTGTCAATACTTTCTGAGACTTTGAGGGAGGATTCTCCTTCCTCTCTTCCTAAGTATTCTTATGTTTAGTCCTTTTACAGTGTCCTGGATTTCCGTGATATTTTATATCAGGAAGATTTAGACTTACCATTTTTTTTTGTTTTTTTTTTTTTTGTCTGATTTACCCATTCCTTCTATTGCTTATTCAATGATTGAGATTTTTCTCCGTATCTCTGTTCTCTGGGTGAACTTTGCCTCTGTAGTTCCTTTTTGCAGTCCTAAATTTTTATTTCCACTATTTCCTAAGATTTAGTTTTCTTTTTTTGCTTCTATTTCCACTTTTATGTATTGAATAGTTTTGTTTACTTCACCCATTGGTGTGTTCTTTCTACGCTTTGTTTATAGGAATTTTGGCTTCCTCTACTTTTTGGTTTGTGTGTTCCTGGCCTTCTTTATGGAATTTATTGATTTCCTCTAATTTTGTTCTGTTTTCCTGGATTTCTCTAAGTGATTTGATCATTTCCTCTTTAAGGAACTCTGTCATCTCCATACATTTGGGGTTAGAGTGTTTTTCTTGTAATTTAGCTTTGTTGGAATATTTAAGACCTTCTTTGACAATATAAATGAGATCAGAGTCATTAGCCAGAGAGTGATAAATGCTGGTCCTTATTACATTATCGAGTACCAATGTCATGGAATGGAATGGCGCTATCTAACCTAAGTATTCAGCTTAGATTTAACCCAATGTTTGATTAATCCCAAGGCTGTCCTTTCCCTTTACACTGGACAGGTAGCCAAGTGAGGCACTTTTTGAAACAGTTACTTTTTGTGAGACACCTGTTTTTAATCACTAACCTTGGGTTAACCATTTAAAAAAAAAAAGACCTGATGTTTACAGGGTGAGTGACTTTGTAATTTTCCAAAATGTATTTATTCATGTCTTGTGAATGAAGACAGACCAGATTGATAGATATGTAAATTGGGGACTTTAGCTTGATTCAAGCAATATTGAATTTCTGACTTTGGAAATATGTCCAATGCACTTTCAGGCTTTATTCAGCTCAGATGATTGTGACACAGGCCATTGGCTGTAGTTATGTGTCATGTTACAGATCACAGCAACTGATATTGCACACAGGAGCCAGGTCAAAGAGTATTGTATTAATGCCATTGTTTTCTGCCAGATAACTTCTCTCTCTCTCTCTCTGTATATATATATATGTATATGCATATATATGTATATATATATAATTATGTTTCATTTTTCCTTTTTTAATTAATTAATTAATTTATGTACATCCTGTTCCTGTTCCACTGTGGATAGAGAGACAAGGCAGTCCTCTGGTACATATGTGCCTGAGGCAATGAGCCAATCCCTGGATGCTCCTTGGTTTTTGCTTGGAGGTCTGAAGTGTCCAGGTCAGCTCAAAGTTTTGTTCTTATCGGGTTGCCATCTTCTTCACCCCCTTAAGTCAGTACAGTGACCTGCCCTTATGTAACATTTCAACCTACAACAATATATCGATATATCGATCTACATATTTCTATATCTATCTATCTATTCATCTATATATCTATATAGCTTTAATCTATACATCTATATATCTATATATCACCTATTAATCTATATATCTACATATCTATATGTATATATCTATACACCTATACATCTATATATCTATCCATATATCAATAAATATATATAATCTCTATATATTATCTATAAATCTACATATCTATAAATCTATATATAAAATCTATATATCTAAAATATATATATACACATATATGTATATTTTTAAATCTATCTATCTATCCATCCATCTATGTATCTATAAGTCTATCCATATGTTTAGCTTGATGTAGCTTTTTTCTTTTTCTGCCAGATAACATATACATATATATTCAATTATGTTTCAATTTTTATTTTTTTAATTAATTTTTTTATTTATTTAAGTACATCCTGTTCCTGTCCCATTGTGGACAGAGAGACAAGGCAGTCCTCTGCTACACATGTGCCTGGGGCAATGAGCCAGCCCCTGGATGCTCCTTGGTTTTTGGCTGGGAGGTCTGAAGTGTTCAGATTGGCTCACGGTTTTGTTTTTCCTATCAGGTTGCCATCCTCTTCACCCCCTGAAGTCAGTACACTGACCTGTCCTTATATAACATTTCAACCTACAACAATATATCAGTATATTGACCTACATATTTCTATATCTACTATCTATTCTTCTATATATCTATTTATCATCTATATATCTTCAATCTATACATATATATATCACCTATAAATCTATATATCTACATATCTATACATATATATTTATATATCTATACATCTATATATCTGTCCATATATCAGTAAATCTAGATAGATAGATATCATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATATAAATCTATATAAAATCTATATATCTATAAATTCTATCTCTATCCATCTGTCTATCTATATGTTTAGCTTGATGTAGCCTTGTCTTAAAGGACTGTTATGTTCTAGGTTTCAGACGTTCAGGCTGAGAGGAAACAGTATGAGTAACATTTGATCTAATACCAGATCCTCGACTCTGGACCCATATTTTATGATAATTTTGGGATTATGATTACATCATTCCTACCTCCTGTGATCAATCAGTAAACACATCTAATGCCAGCAGCTGGCAAGAAGAAAGGTTGATGGCATTTCAGTTCTCGGCCTCGGTGTCTTTGGAAGAGACCATGACGGAGAGGGAAGAAGAAGCAGGAAAAAGGTCCCATGGGTGGATGGATTGGGAGAGCATGTCCAGGAGGGCGAGCCTGAGAGTATGAGCAGCCTGGGCAGAATATGGCAAGTGAGCCGGGCATGGTGGCACTCGCCTTTAATCCCAGCACTTGGGAGGCAGAGGCAGGCAGATTTCTGAGTTCTAAACCAGCTTGGTCTACAAAGTGAGTTCCAGGACAGCCAGGACTATACAGAGAAACCCTGTCTCGAAAAAAATTTTAAAAAAAAGAATATGGCGAGTGATATCTCACAGTTCTTAGTAAAGAAGTAAAGAAATTAGCATAGGGGAATGGTATCTGCCCCATGCTGGTGCTTTAATGCTTATAATTATAATTATTATTATTATTTCTTATTTTATTTTTTCACATTATCATTTACTGCATTATTATATCATATTATTTAATATTATTTCTTTTTATTATTTCATATTATTTATTATTTTATTATTTGATAGCATTGTTTCTTATTCTTATTATTTCTTATTAGTTTATTATCATTTCTTTTTCTCTTCTTCGTATTATTATTATTTCATACCTCTATAATTTATGTGGTGGTAAGAGATCCACAAGTAATATTTACCACAACAAGTTGGATGCAAAAACAGCTTGTACCCAATGAGAAATATGGCCAAAAGTTATTTTCTTGGGATACAGGAAGAAAGTCCTCTGGGGTCTCTGCTAATAAGGTCACACACACACATACCCCATACACATACCCCCACACAAACATGCACACACACACATACTACATACATACA
->XM_012367441.1 PREDICTED: Linepithema humile MAP kinase-activating death domain protein (LOC105672481), transcript variant X6, mRNA 
-ATTTTTAATTTTCTCGGATAATTATACTTACTACGAATATAAAAATCATGTAACGTTAAAGATTGCATCATGCCAGTATTAGGATTAAAATAATAAATTGTATATTCGAGGCTCTTTGGTCTTCAATATAAATTAGTATAGATTTTTATATATTCAATCTAAACTAAACCTTAGATTTTGCGTCAGTTTTGTATCAGAATCTAAAGAAGTAACTGTAGATTTTTTTAAAGGTATTTTAAAGGTATTAAAGGTATAGATATTTAAAGATACGATATAAAGATTATATGATCGATCTAATCAAATCTATAAATATATAGAATAATATTTACAATATAGTTTACGTTTTACGCACTCTTTAAAGCAAACGTTGTATATTTTATATCCTGCGTAAAAAATCAATATCATCTAATACGGTCTAAAATCATATTTTATTACAAAGAAGCGCAATGTTGAAAACTCTTTGGAACTACAGCGTTCGGTTGTTTTCCACTCATTATTCAACCGCGCTTCAACGAGCGAGAAAACGGAAGGATATCGAGCCGACGACAGGGTGTCCCAATAACGGGAGCGGAAATTCACTTTCGGAAGCGGAATCGGGATTCTAGCGCCGGTACTGGAGGCGCGTCCGTCCAGACGTGCGCCTGCCTGGTTCCGGCGAACGATCAGCGGCGCGACGGCGTCGCGACGACCGCGAAGCTCCGGGGCGCGTCGGCGGATCGCCAGTGTGATATCGCCACTTGGCTGATACGGAATACGGCCTGGCCGTCATTCGTATGGCAGTCGGACGAGAACGCGCGGCAGTCACTCGCGTTAACGCGCATTGCAAAACGTGGAATTAATAAGCGAGATAATGGTACAATCATGATTCAAGCTGGAAACGATCTTGAGGAGAGTTCAGAGGCTTGGCTGTCCTGTATATACTGCATACAACGGTGACACAGCTGTATATACATAAATCACAATTATGGATATACAGAAGAAATTCCTGTGCCCCCGATTGGTGGACTACCTCGCCATCGTTGGAGCCAGGATGCCCGCTGTCTCTCGTCAGCCCGTACAGGTCCCAGAGTTGCTACGCAGATATCCGGTAGAGGATCACAAGGATTTTCCTCTGCCTTTGGATATGGTGTACTTCTGCCAACCAGAAGGTTGCAGTAGCGTGGGACCAAAGCGCACGGCCTTACGAGAGGCAACATCCTTCACTTTTACACTCACCGATAAAGATTCAGGAAGAACGCGTTATGGGATTTGCGTGAATTTTTACCGATCTATGGAAAGGGCGGGGCTTGTGGCTGGCGGGGGAATTGCGCTCAAGAGGGAAAAATACAACACCACGTTTCGAAGGGAAAGCTGGAGGAAGAGTATGGAGAGAAGCACGGATTCCGCTTTTTCTAGCGACTATAGGAGCAGTGCAGTAGGTCCTAGTGATTCTGAGAAAGATTGCTCCAGCAGCAGGCGGGATTCGGACACCCCGCAGGTCAGCTCGGTCACCCCGAGATTGGAATTCATCGCAGCGAGCGGAGACAGCGAGAGCGGCGGCAGTCATTCCCCATCGCCACGCGCTTCTCGAAGACGCCAGAGGGTTCGCAATCATTCCTTGACTTCCCTATGCATCATTTCGCACCATCCGTTCTTCTCAATGTTCCGGGAATGTCTTTTCGTCCTGAAGAAAATCATCGACGCGTGCAACGAGAGTTTCTCGCCGCAGAAGGTGGGAGCCTCTCGGCAGACCAACAGAGACACGGTGTGGAGCGTATTAACGGGTCAGGCTCTAGGGGACACGCCGTCCATCGTGCTTCACGACGTTCGCGAGATCGAGACATGGATACTTCGTTTGCTCAGCAGCCCCGTGCCCGTCCCGACAAAGACGCGCGTCGAAGTCGAGATAATATCGCCCAGTATGCAACCACCGCTATGCTTCGCCCTACCGGATCACACTAGATTCTCCCTGGTCGACTTTCCATTGCATTTACCGTTGGAGCTCCTCGGCGTCGACATATGTCTGAAGGTTCTCACGCTGATTCTCTTGGAGAATAAGATTGTACTTCAATCCCGTGATTACAACGCCTTGTCTATGTCGGTCATGGCGTTTGTCACGATGATCTATCCATTGGAGTACATGTTCCCCGCGATACCCTTGCTGCCCACCTGCATGAGTTGCGCGGAGCAACTGCTGCTCGCGCCGACGCCCTTCGTGATCGGGATCCCCGCGTCCTTCCTTATGTACAAGAAGAACTTCAGAATGCCCGACGATATCTGGCTGGTGGACTTGGATAGCAATAAAATAACTGCGCCGAGCGCTCTGAACGATGACGGTTTGCCGCCGCTACCGGAACCGGAGGGCACCATCCTGAAGAATCACCTGAGGCAGGCAATGCAACTGATGGATCAAGTTGGCTCTAGTGCGATGGCTAGCATGACGGGACCGCCATTGCCGTCGCAAGAAATCTCGCAACGTCTCTCTTTTCAAACACCGAGTAGGAGAGAAAGCATGGCGTCGCATCATTCCACCTTAAGCGTAGCTTCAACGAAGCACAGGCCGAGCATCGACCAGTGCGCGCACATTCAGCACTCCCCGCTTAATTCGCCAAGCGTGAGCTCGTCAGCGAGTCCACCTCGTCGGCCGTCGATGCCACAAACGGTTGGAGGAGCCGGGCTGACCGGTCCGCCAAGAGCGCCCGGACAGAGCCCGGCGCCTTTCAATCCCTTCATCTACGGAAATGACGTGGACTCGGTAGACATAGCCACGCGGGTCGCCATGGTGCGCTTCTTCAACTCGCAGAATCTGCTGGCCAACTTCACCGAGCACACGCGCACCCTGCGGCTGTATCCCCGGCCGGTGGTGGCTTTCCAGATCAATTCGTTCCTCCGTTCGCGGCCACGGAAGAGCAGCTTCCTCAACAGATTCGCGCGCACGCAGGCGGTCGAGTTCCTGGCCGAGTGGTCGCTCACGCCGAGCAACGTGGCCTTTCTCCGGGTGCAGACGGGAGTCTTCGATCCTGCACAGATCGGCGACAAGTCGCGCTGGTACGCGACCAACCTCGAGCCGATCTACTTTCCCGTCTGGGACTCCGGTAGTTCGTTGGCGAACGCCCTGAAGGCGATGAAGGAGCACGAGAGTCAGCCCACGGATGAGAGTGGATCGGATTCCGAGGGTGCCGAGAGCACCAGCTCTTCATATTCCTCTCTGAGCGACTTCGTCTCCGAAATGGCGTCGTCCGATTTGTCACCGGGTTACAATCCTCAAGTGAGCCAGCCCCAACAAACGCTCTCAGTGGATCCGAAGAACGTCTACAATCCGCCGAGCTCCTTGCAATATCCGGGAGTGGAAGAGGATTTACCAGCACGACCCGAGAGCCCACCAAGTACTTCTTCCAGTCACAGCGATCTCAGTAGCCCAAGCTTTAACAGGGACTCCGAGCTCGAATTGAACCCAAGAGTTCAAGAGGGTTCGCAGTCCGCTAACGATAAAGAGGAGGGTGGTAGCTTTGAGTCAGACTCCGCGTCGACAATAACACCGCGCACAATCCTGAGCGCACAAAGTTCGGTAGGACAGTTCACAGGGATAAGCATGGGCGCTTTAGGCACTCAATCTTCGCTCAACGACACTGAACGTCCTACCACCCCTCACAGGATCTCGCGCGTCAGTAGATATGTCACTCCTGTGCCACCCACCGGACCAGGTCTGCAACGTCAGCCGAGCGTAGGCAACGTTCTAGCGAGGGCCTCCAGCTTCAGCACCACCGGCGGGCCTCTTCTGCCGCGGCAGATAAGCGCGGTCACCGCTGCTGATCATCATCACGAAGCGACGCAGCTTCAGCGTCAAGCATCCGCGGGAGCGACGGTCGCGCAAAAGCAGAACGACGGCACGGTGCAACGACAGAACAGCGGCGGTTCCACCGGCGCCGCCACCGGGAACGGCGTTCTTCGACAAGGCTCTCAGGGTTCTCTGTTCGAGCAGATCGCCAGCCAGGCGAAGGATTTGGTGCGCGAAACGACCAGACAGAGCAGTCAGGACGGGCTGCTCGCGCACATGGACAAGCTCAAGCATCAGGCGAAGGAAAGAATTACGGAGGCAGGCGAGGATAGTCTGTTCGCGCCGCTGGAACAATTTACGCAACAAACTAAGAAAGCGGTAGGTGAGGCCACCAAGTCGGTGCAAGAGGTATCAAAGAACGCGTTGGAGGCGAGCAAAACGGCGGCGGGTGTAAGCAAGAATACGCTGGACGATTTGACGTACGTCGGCAAAAGCACATTTGGAGATCTGACAAAAAGTGCCAAAGAAGCTGCTGCGAAAAAAGGCTTCATCAAGAGTCTAGAATCACAATCGCCGGTACACTCTCCCTCCTCTTCTAATATGATGCAGCAGCGAAAGGATTCGATTAGCAATCAGTTAGTCGCATCGGACACACGAAGTGGTGTTGGCCGGGATTTCTTCAGCAATATTAGCAGCGATTTGAATGGCTTCGCTGCGCAAACCAGCAGTATGTTCAGCGATTTATTCGGTGGTAAAAATAATTCTAAAGGCAGTAGCTTCTTCCCGCAGAATCAGAAGTCGAAAGAAAAGACCAATCCGATTCTTCCACCATTTCCCAAAGTTGCAGGCAAAACAGGATTAGTAGAGCGTTCCTCGTTGATAAAACATTCCTCGCACAAAATTAATCAGGAAGATGCGCAGAGAATGCAAAACGCGGAACGTTCTAGTACAAATAGCGACAATCAAGCCTTTTTGAACGACGTGATAACGCAAGTGTTGGCCGGTGAAGGTGTTGGTTGGCTGAAATTGAATAGATTGAAAAAATTAATGGAAGATGAGAATTATCGTGATTTGGTCGTGAGAAAATTGAATAAAGGTCTCAATAGGAAGATTAGTCCTGATGATCACATTGACGATGTGGCCATATCAAAACCCGTGTATAAGGGAATGTTAAAGTGCCTTCAAGCAGTAACGCATGGTCTCGCACACACGTATAATAATTTCGGACTAGGCGGGATGGCTTCTGTCTTCCAACTGATGGAAATCGCTCACACGCATTATTGGAGCAAAGATCTGTCGGCGGAGGGTGGTTTCGACAGCTCTTTGATGTCGCAGGCGTCTAGCCCGTTCGGTAGTAGAGAAAACTTGAAGTCCCCACAATCTCCGAATCAGTCTGAATTTACAGAAAGCGCGCAGAAATCAGAACTGCCGCAAGTGCATTTGGAAATGCCGCAAGCACCGTCAGCGGCGGAAACGACCCAGTCAACAACGGACATGTTCCTGGACATGTTTACGAAGAAAGGAAAATTTCTGAGCAAGCTTACCTCATTCGATTCGGAGAGTGGGCGGGGTGGTGGAACGGGGAGCAGCGAAGCTTTATCCACAGACGGAGGTAGCATTATCACTAATCCTGCTTTTCGGCAAGCGCACCAAGCTTCCTTCCGAAGCACCGTATCTGATAGCGAGGTCGAGCAAGGCAATTTTCCACGGCAAGGCAAGCAGCGCTCCGGCAGCGTTTGGTCCAGCAAGTCGTCCTTGAGTACGGGATTCCGTTATCACGGCGGAAGTTTGATACCCACCACGACGCTACCGAGTCCGGACGCTGCGAGAACATATCTCTTCGAAGGTTTACTGGGGAAGGAGAGATCGGGACTGTGGGACGAAATGCAATTCTGGGAGGACGCTTTCTTGGACGCTGTTTCGCAGGAACGCGATATGATGGGCATGGATCAGGGACCTGGCGAAATGGTGGAGAGATACAAAAGTTTAAGCGACAGCGAAAGGCGGCGGTTGGAGCACGAGGAGGACAGACTGCTGTGCACTTTGCTGCACAATCTCACCGCCATCCTGGTAATGTTGAACGTCGACAAGAACGAATTGAAGCGGAAGGTGCGCAGGTTGCTCGGCAAGAGTCACATCGGCCTCATCTACAGCCAAGAATTGAATCTACTTCTCGACCAGATAAACAATCTCCACGGAAACGACATCGATCTGAAGCCGCTGACGTCACGGCAAATGCACCGGCAGTCGTTCACTGTGCATTCGGGGGTCGACGCTGAGGGTGATCTACGATTTCTCGAAGTTCGCCACGACGGTCTCGTCCTGAGGTCGGTGAACGGCGTGATAGTCGAACGTTGGTGGTACGAGCGCGTAGTCAATATGACGTATAGCCCGAAGAATAAGGTTCTGTGCCTGTGGAGGAGGAGCGGCAGCGATACCGAGTTACATAAATATTACACCAAGAAGTGTAAAGATGTGTATTACTGCATAAAGGAAGCGATGGAGAAGGCGGCGGCTCGCGGGCGAGGCGCCAACGTGGGCTACGAGCTCGGCGGCGAGTTTCCGGTGCAGGACATGCGAACGGGCGAGGGCGGGCTCCTGCAGGTTTGCATGGAGGGCGTCGGTCTTCTCTTCGCGAATAGCAAGATCCTAAAACTAGACAAGTAATTCAACGTAAATATAAGTCACAAATGGCTGAAGAGGCGGTTCGTTGCTTGCATAGAATATTTTCCGTCGCATTTACTCTTCATAAGCTTCCATCGGAGACACAGAATAAACATAAGTGC
->XM_001504059.5 PREDICTED: Equus caballus ALG2, alpha-1,3/1,6-mannosyltransferase (ALG2), mRNA 
-TGCGCAGAATCCCCTGAGGGGATGGGGCGCAGGCGTGGCTTCCGGGCCATGGCGGAGAAGCAGGATCGGGACGAGGAGCCGGGTCCCAGCCCGTCGGTGCTGTTCCTGCACCCAGACCTGGGCGTGGGCGGCGCCGAGCGGCTGGTGCTCGACGCGGCGCTGGCGCTGCAGGCGCGCGGATGTAGCGTGAGGATCTGGACCGCGCACTACGACCCAGGCCACTGCTTCGCCGAGAGCCGCGAGCTGCCGGTGCGCTGCGCCGGGGACTGGCTGCCGCGCAGCCTGGGCTGGGGCGGCCGCGGCGCCGCCGTCTGTGCCTACGTGCGCATGATCTTCCTGGCGCTCTACGTGCTGTTCCTCGCCGACGAGGAGTTCGACGTGGTCGTGTGCGACCAGGTTTCTGCCTGTATCCCAGTGTTCAAACTGGCCAGACGGCGTAAGAAGATCCTCTTCTACTGTCACTTCCCGGATCTGCTTCTCACCAGAAGAGACTCTTTTCTTAAACGCCTGTACAGGGCCCCGATTGACTGGGTGGAGGAATACACCACAGGTATGGCAGACTGCGTCTTGGTCAATAGCCAGTTCACAGCTGCCGTTTTTAAGCAAACGTTCAAGTCCCTGTCTCACATAAAGCCCGATATCCTCTACCCATCTCTGAATGTCACCAGCTTTGACTCAGCTGTTCCTGAAAAACTTGATGACCTAGTGCCCGAGGGGAAAAAATTCCTGTTCCTCTCCATCAACAGATACGAAAGGAAGAAAAATCTGACTTTGGCACTGGAAGCCCTGGTAAAGCTGCGTGCGAGATTGACGTCCCGAGACTGGGACAAGGTCCATCTGATCGTGGCAGGTGGCTACGACGAGAGAGTCCTGGAGAACGTGGAACACTACCAGGAATTGAAGAAAATGGTCCAGCAGTCTGACCTTGGCCAGTCTGTGACCTTCCTGCGGTCTTTCTCAGACAAACAGAAGATCTCCCTCCTCCACGGCTGCACGTGTGTGCTTTACACACCAAGCAACGAGCACTTTGGCATCGTCCCTTTGGAGGCCATGTACATGCGGTGCCCGGTCATTGCTGTTAATTCCGGCGGGCCCTTGGAGTCCGTTGTCCACAGCGTCACAGGGTTTCTGTGTGAGCCCGACCCAGTGTGCTTCTCGGAAGCAATAGAAAGGTTCATCCGGGAACCTTCCTTAAAAGCCACCATGGGACTGGCTGGGAGAGCCAGGGTGAAGGAGAAATTCTCCTCTGAAGCGTTTACGGAACAGCTCTACCAATGTGTCACCAGGCTGCTGGTGTAATGGGATGTTTTTTAAGGTCTTTATGCTACATTCATTAATACCATCTTTGTAGATCGTGACTCAGTTTTGAAACCAAAAAGAGAAAAAACCTAGAATCTAATGCAGAAGGGATTAAAAAATATGCACTTGAATCTTGAACCTGAGCCACCTTCCTATATACCACAACTCCCTGTCTGCTTTTTCAGAAAAATAGTATCTTTTATGCTGTAATAATCCTGAGTCTCACCAGTGTTGATTAAGATATAAATATGGTACAGTTCCACGTTCAGCAGAATATTTTAATTATATTTTCTCTAGATTATTGTTGCTCTGCCTATGAATTTTGAGTCATATTGTGCCTTAATTGTTTTAATAATTTAAGTATATCATCATCAAAGTTGATTGTTTGGCTTCGTAATGAGAATAGGGTCCCTGTAGTTCCCAGAATCAATCCACCTGGGTGTTGACTGTCCTCTGTTAGGAATTTTGCTTAGTCATACCTTTGCCTGGATCCGTGGCAAGAGTGATCTTTATTTTTTTACAAATGTGATTTATTGTGTTTTCCCACACTAAGACAATAAAAGATGTTTATCATAGGAAGAGACAAAATTTTA
->XM_004371625.3 PREDICTED: Trichechus manatus latirostris chromosome unknown C19orf12 homolog (LOC101348405), mRNA 
-GTGAGCACAGACTCTGCCAGGCCCGTGTGTCCGGGGATTGCCCAAGCCAGCCAGCAGGCCACGGATGCCAGAGAGGCTAGACTTGCCTCATTTGTGAGGAAGTGTGGACATGTAGCCGGCTCCTCCTTAATCTGGTCAGAAATCAGAAGTGAATCTGAGAGCAAAGAAGACCTTGAATCTCTCTGCTGTTTCTGTTTGCTTGTTAACTAAATGCTGCCCCGGTTTCTCGGTGATAAAGGACTTTCCATAGGATGGAGGCTTTCTGACGTGGCCGTGGCAGGGCTGCTGCTCTCTGCAGAAAATGGGACCCCTCAGAACTTGAGGATGAGTCACATTTGGGTGGAAGGTCTTAAATCCATTAACACTTGCTCTTTGAACTTCTTCCTTTGAGGCCAGCCAAGATGCCTGTCGTGGTAGAGGACATCATGAAGCTGCTCTGCTCCATCTCCGGGGAGAGGAAGATGAGGGCAGCCGTGAAGCACTCTGGGAGGGGCGCCCTGGTCACAGGGGCTGTGGCCTTCGTTGGTGGTTTGGTTGGCGGCCCACCGGGACTAGCCGTCGGAGGGGCCGTCGGGGGCCTGTTAGGTGCCTGGATGACGAGTGGACAGTTTAAGCCAGTTCCTCAGATCATAATGGAGCTGCCCCCTGCCGAGCAGCAGAAGCTCTTCAACGAGGCGGCTGCCATCCTCAGGCACCTGGAGTGGACGGACGCCGTGCAGCTGACCGCGCTGGTCATGGGCAGTGAGGCCCTGCAGCGGCAGCTGCTGGCGATGCTGGTGAGCTACATCAGCAAGGAGCTGCGGGCAGAGATTCAGTACGACGACTAGGCCGCTCCTCCCAGGAAGCGGGGTTCACTCAGAGGATGCGGTAACTCGTCTAGAAGGAGGCCGGCGGCTTGGGGGCAGCTGAGCAGACCCCCCTGAGAATCCTCCACGTCGTCAGTGTATTCCCTTCACCTGGAGCTCAGTTTTCTGTTGGGGGGACTACGGTTGTGCCGTCTCCTGTTCTGGAAGTTACTCCGGAAGAAGATGTGTTCTGTGCTGTCCTGCACGGCATGCACTGATTATCCTGGGACTGGGAGGCTGGCGAGCGGCGGCGGTCAGCAGTGGGCATTGGGGCAGTTTTCCGAATGCTCTGCTGTCGGC
->EU641276.1 Uncultured Burkholderiales bacterium clone GC1m-1-48 16S ribosomal RNA gene, partial sequence 
-TGCAAGTCGAACGGTAGAGGGGGCAACCCCTTGAGAGTGGCGAACGGGTGAGTAATATATCGGAACGTGCCCAGTCGTGGGGGATAACGTAGTGAAAATTACGCTAATACCGCTTACGATCTAAGGATGAAAGCGGGGGATCGCAAGACCTCGCGCGACTGGAGCGGCCGATATCAGATTAGGTAGTTGGTAGGGTAAAGGCCTACCAAGCCAACGATCTGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGAAAGCCTGATCCAGCCATTCCGCGTGCAGGATGAAGGCCCTCGGGTTGTAAACTGCTTTTGTACAGAACGAAAAGGTTTCTATTAATACTAGGAGCTCATGACGGTACTGTAAGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTATATAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTTGAGACTGTATAGCTAGAGTACGGTAGAGGGGGATGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAACACCGATGGCGAAGGCAATCCCCTGGACCTGTACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGTCAACTGGTTGTTGGGTCTTAACTGACTCAGTAACGAAGCTAACGCGTGAAGTTGACCGCCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCG
->XM_029869421.1 PREDICTED: Aedes albopictus transcription factor BYE1-like (LOC115265160), mRNA 
-CGGCATCACTGGTTCACGAACAGGTAGTGAACTCGCCGATACAAAGAAACTAGCTGTCAACGCATAACGACAGAAGGTGTAGGTAGCAAACGTGAAACGTGGTGAAATGACGATTGATCTAATGTTTTGAGATGCTGCAAATGATTATATAATTTGTTATTGGGTGAAGGGAAATTCTTAAAAGTAAGTTTCGTATGTAATACCACAATTGTGAAACCAATTTAGTGTATTTTTCCTCAGAACTTGTAAATTACGCCGTACATATTCCTGCAAGTGAACTGTAGCAGTCTGAATTGTCAGAGTTCGATAGGTAACCTCAACTTAACCCTTATTGGAATACCCATTTGCTAATTCTATATTTATCTAAAAGGACGATAAATCCTCATAAGGGTTTGCTCAGGATAGACCGCGAATTTGAAGATTGTGAGAAGACTATCTTTTGAGCTTCGTTAGACAAAAAAGCTGCAAGGTGCTTCTACAATCCGAACACTCTCAAAAGATACCACTCGAATCGACTCTGATGGCTACAGTGAATCCACCTCACGGAGGCGCCGGTGACCACGACTGCGGGGCGTGCAACCTGCCTAACGATGCCGATCCGCAGATGGTACAGTGTGACGCCTGTCAAGTCTGGTACCATCTGAAGTGCGTCGGAGAGACTCCTGGTGTTGAAAACAGATCGTTCAACTGTCGTGCGTGTCAACCGCCTTCCAATGTCGGTAAGTCGAAGCCTAAGAAGACCAGATCGCAGAAGGGCGTAAGTGAAGGTCAACTGAAGGTTCCCGTCGCGTCTACATCTGGAGTGACACCGATAAAACACCCGGAAGTTCCCAAATGTGTTACGAACAAAGCGACAACAATCAAAACCACTTCGTCGACTTCGCGTTCTCGAGCTCTGACTCTGCAGAGGAGGATTGAAGCGGAGCAGCTTCTGGCGGAAATGAAGCTGGCTGAAGCAGAAAAGCAGCTTGAAGAAGATCGTCTAATGCAGGAAAGACAGCGAGCTCTGCGCGAAGAAAAGATTAGGCTGCAGGAAGATCTATTGCGGAAAATGCAGGAACTAGACGAGGTCGCCGACGCTGAGAGAGCTTCCGAATACACCAGCACCAGTGGAATGCGGAAAGCACGGGAATGGTTAGCGAAGCAACGACAGGAGAACCAACAGCAAGACGACAATGGTTCACACCGGTCAATACCACCGTTTCTACCTTCTAAGAAGTCGGAACGTAGCTCTCAAAAGTCGGTGGGACGCGAAGGATTCAATGCGCAAGGTGGGTCAGATCCCGATACATCCGATGATCCGGAAGGCCCTTCAGAAGAGCCGAATCCGCCGAATATGGACAGAAGAATGTCGTTGGAGAGGTCACCAGCGATGCAGATTACTGGAGAAATGCCGGTCAAGAATACGCTGCAACATCGGAAATTGCCGGGAACGTCATAA
->XM_002072634.3 PREDICTED: Drosophila willistoni nuclear pore complex protein Nup88 (LOC6651485), mRNA 
-GCAAATATTTGCACTGAGAAATATAAGGTAAATAATTTAAACTAAATTGTGTAAAACAATTTGCTACATATTCAGGTGGCAAGCCAGGTTTTCAGTCATTTTATCACATATATAAAAGGAAAAAGTTCTGAAAATAAACAAAGCTACCCGGTCTGCTTGAATATATTATCAGGCAAAATGGCAACTACTGATGTTTTGGGTCTAAATAAAACTGAGATATTTGCAAAAATCCGGGATGGCTTGCCCATTGTGCAAGAATCACAGAATCTCCTGGACTGCAAGGACGATCTTCTTTTCGCGTGGAACTCCAATGACTGCTCATTGCTGGTGAAAAATTGGCGCGCATCTTTGATGGAAGCAGACACAGTACCTGAATCAACTGCAACAAAGCAGAAGAAAATTACTTACCAGACGTTGATACCTTCTAGTACGCTTAGTCTGGACGTGGATCGTGTAGTGGCTTCCAATGAGTGCTCACTGGTGGCTTTGAGTGCGCCACGTGGTGTTTGTATCCTGGACTTGCCTCGTCGCTGGGGACCAGAAGGTTACTTTGATGGTGGAAAGGCGATTATCACCTGTCGCACATATAATCTGGACGGTCAGCTGTTTCAGAGTAATCCTCACTTGGAGGTGCGTCAGATTCGCTGGCATCCTAACTCCGTCTCCGACTCCATGCTGCTGATTCTGTTTAACAACAACACCATCCGGCTCTACAATCATTACAAGCTGATGCATGTGTGGCAAGTTGGTCCCACCATCGTGAGATCCGGGCTGAGAACCTCCGCCTTGGATTTTGGTGAGGCAGCAGTTGACTTTGATATAGCACCGCCTGTGAAATCCAAAAGAGATTTGACAGAAGAACTAGAAGAAAGTGTAAATTTAACAGATAATTCTCTTAAGCAGGACAAGATTGAGTGGCCTCTTGTACTTTTGCGGGAAAATGGAAACATTTATATACTCATGACTGAAATGAGTTCGGACAGAACCCGCCTCCAGGGACCCATTACGATAACCCCTCAGAAAAGGGACAACTATGGACTGGAGTCGTCGTCAATTATGGTCATCCCCTCTTTGCCACCCACTTTGGTTATTGGCGAGTCGAGTGGCAAACTGCATCATGCTCTTTTGCTAGAAGCAGCCACTCCCGAGCATTCGCTCAATGAAGTTGATGATTTTATCGTCATTGAGCCCTCCGAATATGTGATCCATGTGAGAGAGACTGTGGAATTAGAGTTGGGAATAAAATCCGGTACTTCGAAATCGAATTACAAGTCCCCTGTCTACTTAAAACGAGATGTTATCAATGAACTGCGGTACTTTGCATATCACAATGCTGGTCTTCATGTTGTCACCGTGAACTTCATATCCGAATTGCAGCGTTATCTGGAGAGTGAGGCAGAGGAGGACCAGCTGAATTTTACAACGCCCTCACGAGCTGAGTACATACTGTGCACTAAATTTGATTCTAGCGACCACATCAATGCAGTTTTTGGTATTGCTCTACTCCAAACTCCGGCTGGAGTTGTTGTTTTGCTGGGGAGTGGACAGGTAATTAGCCTCAAGCTGGTCGTCGATGCCCAACTGTTAGTTTCACCAAGTGAGCAAACTCTAACGACATCTTCTGTCGAGCAAGGAGAGGCTGGACAAACATTTCAGGACAAGATTAAAAGTATTTTGCAGCGTAGCGTCAATCAGCCCATATTAGCTGATAAGCCCTCCTCCAACGCCAACGAGGGTTACGAGTTGCTTAGCCAAGCCATTGTCGTGCTGCGTTCACAGTACCTCAAACGTCATGAACTGGTGCTTGTCGAGTTTGCTAAGCACATTAATCAAATTCGCATAAAAAGAGATCAACAATTGCAAGAGATTCAGGACCTAGAGGACGAGCGGGAGGTGATTAGTGAGCGTGCTCACAAACTTGCTGAACGTTTTGAGGAAATAAGCGATAATCAGGATTGGCTTGTCCGCAAATGCCATAGACTCCTACAAAATGCCAATACTGCTCTGCCAAACAGCGTTGTGGCTGAACGTGAATTCGCTCAACAGGTGGCAAACATTAATAAGGCTAACAAAAAAATTGCTGCTGCCTTGGAAGATGCCAAGAAGACCATGAACAAACAGCGTTATTTCATAGCCAAAAACCAAGACGAGGTCCGTCAAAATGCATTCGAGTTGCCGGAGAAACAAAATCGGACCATAACCGAGATTCTAATGCAATTGGCCAGTGAAATAGATCGACAGGTCACTGATGTGAAGCGTATAAATAAGATTATTGGTATTTAAATAAATGGCTCTTGCTCATCTTAATTAGAA
->HQ071684.1 Uncultured Leptolinea sp. clone F5OHPNU07IB2R6 16S ribosomal RNA gene, partial sequence 
-GCACAAGCAGCGGAGCGTGTGGTTTAATTCGATGCTACACGAAGAACCTTACCAGGGTTTGACATGCAAGTGGTAGGAACCGAAAGGCGACGACCTTCGGGGAGCTTGCACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTCGGTTAAGTCCGCTAACGAGCGCAACCCTCGCTGTGTGTTACAAGTGTCACACGGTACTGCCGGTCTTAAGCCGGAGGAAGGTGGGGATGACGTCAAGTCAGCATGGCCTTTATGTCCTGGGCTACACACACGCTACAATGGCCAACACAATAGGTTGCTAAGCCGCGAGGTGGAGCCAATCCTCAAAGTTGGTCCCAGTTCAGATTGCAGGCTGCAACCCGCCTGCATGAAGTCGGAATCGCTAGTAATCGCAGGTCAGCATACTGCGGTGAATACGTTCCCGGGCCTT
->XM_022591717.2 PREDICTED: Delphinapterus leucas TATA-box binding protein associated factor 6 like (TAF6L), transcript variant X3, mRNA 
-GTAGAGGGCGGAGTCTGAGCGCCGAGAGAGGGAATTAGTGCGAGCTGAGTGAGAGGGCGCCAGCGCCGCCGCCACCACCGTCGCCGTCACAGATACCGCCGTCCCGGTAACCGCCTTCGCCGTGCCGGAGCCCTCAGGTGGAGAAAGAAGCTTGACAATTATCCGTTGGCGGCTTTCCAACGCCTCGTTTCCTGGCTGGGAATCCAGGCCTTGTTCCCCACACAGCCCGTCGCTCCTCATGATTAGAACGATAGTTGAGTTCTTGCTCCCTACCCAGCAAGTGTTTATTGAGGGCGTGTTATGTGCAGACGCAGTGCCTGACGCGGGGGATGCAAAGTTCCATCGGGGCCATGTCGGAGCGAGAAGAGCGGCGGTTCGTGGAGATCCCTCGGGAGTCTGTCCGGCTCATGGCAGAGAGCACAGGCCTGGAGCTGAGTGATGAGGTGGCGGCCCTGCTCGCAGAGGACGTGTGCTACCGTCTCAGAGAGGCCACCCAGAATAGCTCTCAATTCATGAAACATACCAAACGGCGGAAGCTGACTGTCGAGGATTTCAACCGGGCCCTCAGATGGAGCAGTGTGGAGGCTGTGTGTGGTTATGGGTCCCAGGAGGTGCTGCCCCTGCGCCCTGCCAGGGAGGGTGAGCTCTACTTCCCCGAGGACCGAGAGGTGAACCTGGTGGAGCTGGCCCTGGCCACCAACATCCCCAAAGGCTGCGCCGAGACAGCTGTGAGAGTTCATGTCTCCTACCTAGATGGCAAAGGGAACCTGGCCCCTCAAGGATCGGTGCCCAGTGCTGTGTCTTCACTGACTGATGACCTTCTCAAGTACTACCAGCAAGTGACTCGGGCTGTGCTGGGGGATGATCCACAGCTGATGAAGGTCGCCCTCCAGGACTTGCAGACCAACTCGAAGATTGCAGCGCTCCTGCCGTACTTTGTTTATGTGGTCAGTGGGGTGAAATCTGTAAGCCACGACCTGGAGCAGCTACACCGGCTCTTGCAAGTGGCACGGAGCCTAGTTCGGAACCCACACCTCTGCCTGGGGCCCTATGTCCGCTCCCTGGTAGGCAGTGTCCTCTACTGTGTCCTGGAGCCACTGGCTGCCTCCATCAACCCGCTGAATGACCACTGGACTCTGCGGGATGGAGCTGCCCTCCTGCTCAGTCACATCTTCTGGACTCATGGGGACCTTGTAAGTGGCCTCTATCAGCAGATCCTGCTCTCCCTGCAGAAGGTCTTGGCAGATCCTGTGAGGCCTCTCTGCTCTCACTACGGGGCTGTGGTGGGGCTGCACGCCCTTGGCTGGAAGGCAGTAGAGCGAGTCCTGTACCCACACCTGTCCACTTACTGGACAAATTTGCAGGCTGTGCTAGATGATTATTCAGTATCGAATGCCCAGGTTAAAGCAGATGGGCACAAAGTCTATGGAGCCATTCTGGTGGCCGTAGAACGACTGCTGAAGAGGAAGGCCCAGGCAGCAGAGCCCAACAAGGGTGGGCCAGGCAGCAGGGGCTGCCGCCGCTCAGACGACCTGCCCTGGGACAGCCTTCTCCTGCAGGAGTCTCCCTCCGGGGGCAGCGCAGAGCCCGGCTTTGGGTCTGGTCTCCCGCTGCCGCCAGGAGGCGCGGGGCCGGAGGCTCCTTCCCCTTCGGTGACCCTGGCGGACATCTACCGGGAGCTCTACGCCTTCTTCGGTGACAGCTTGGCCACCCGCTTTGGCACGGGTCAGCCCGCGCCCACGGCCCCGCGGCCGCCTGGGGACAAGAAGGAGCCGGCGGCCGCCCCGGACTCGGTGCGGAAGATGCCGCAGCTGACCGCCAACGCCATGGTCAGCCCGCAGGGCGACGAGAGCCCCCGGGGCGGAGGCCCCCCGTCGGCCTCTGCCCCCACCGCCTCTGAGAGCAGGCCGCTGCCGCGCGTGCACCGGGCGCGGGGGGCGCCCCGGCAGCAGGGCCCGGGCGCCGGCACCCGCGACGTCTTCCAGAAGAGCCGTTTCGCCCCGCGCGGTGCCCCTCACTTCCGTTTCATCATCGCCGGGCGGCAAGCAGGGAGGCGATGCCGCGGGCGCCTCTTCCAGACTGCCTTCCCCGCGCCGTACGGGCCCAGCCCGGCCTCCCGTTACGTGCAGAAGCTGCCCATGATCGGCCGCACCGGCCGCCCGGCCCGCCGCTGGGCGCTCTCGGACTACTCGCTGTACCTGCCGCTGTGAGGCGGCACTGGCCTCTGTGAATAAATCCCGCGCCCGGAAGTGA
->HQ278360.1 Uncultured bacterium clone CB6AA43 16S ribosomal RNA gene, partial sequence
HQ278363.1 Uncultured bacterium clone CB6AA69 16S ribosomal RNA gene, partial sequence 
-AAGACCTCACGTTATTGGAGTGGCCTACGGCTGATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGGGCAACCCTGATCCAGCCATTCCGCGTGAGTGAAGAAGGCCTTCGGGTTGTAAAGCTCTTTCAGCAGGGAAGAAACGGTTACGGCTAATACCTGTGACTAATGACGGTACCTGCAGAAGAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTTTGTAAGTCAGATGTGAAAGCCCCGGGCTCAACCTGGGAATT
->XM_798046.1 Trypanosoma cruzi uncharacterized protein (Tc00.1047053503983.29), partial mRNA 
-ATGTACGCAGGTCTCTTTAAGAAGCGGCCACGTGAAGCCGATGCAGCTTCCCACGGGAACGCACCGGAAGACAGTGGGGATGCATCGAGCAGGGCCGCCGGCATCTCGTCACCCACGCTGTCTCCCCGCACTGTGTACCACTATCCCTCGATGCTGCCATTCCCAACGGTGATAGATTCTGAATTTCCCGCTGAGTCGTATCGTTCCCGCAGCAAAGACGTAAAGGCGGCTATTCATTGGGGCCAGCGGAAACTCTTACTTTCTGAGATTCAGCTCCTCTCCATATATGCTCGGCCGAATGTGTCTTATCACATTGTCTACGCAGGGTCAGCCCCCGGAACTCATCTTGCATTTCTTGACGAACTGTTTCAGAGTCGACACACCTGGGAACTTGTGGATCCGGGAAGATTTGATCGGCCCGTGCTGGAGTCACGACCGAATTTTTCTCTTCGTAACGAATTTTTTACAAACGTGACAGCCTATGGCATTAATGCGCGCCGTCTTTTGGAGGTGCTTCCTGGGCTGGGAACCGTTTACCGTTGTGTTGCCCTGGACGGTGCGTGGTCAACAAAGAAGGAAATCCACCAAAAGCTTCAGAGCATCGTTGGAACGATTGATGTGGCCCGTGGCACGGAAGATATCCCATCCATGTACGAACCGCGGTTGGATCTTCCCTTTGGCTTTGAGCTTCTTTGCTACGTTGGTATGGAGCGAAGCAAGCC
->XM_038047407.1 PREDICTED: Hermetia illucens small conductance calcium-activated potassium channel protein (LOC119646808), transcript variant X7, mRNA 
-GTTGTTGTTCCTGCTTTTGGAAGGGTATTGTACGTATAGATACTATCAATGCGGCGTCGTCGTCGTAGTTGCCGAAATATCTAAAAGAATGCTTACGGACAACAGTCGGACGTCGGACTCGGATATCGTGTGTGAGTTTCGCTTAGGATAGGACTTCAGAGGAGTGTTGCTTTGGGTCCTTTCACTACTTTCTAGTGTGTTTTCGACCAGAAAGGAACGTATGTGTCGTGTGCGTGGTGATTGCTGTGGCCCTGCTGTTGACTATATATACTTCCTGTCGATTTGCAAGTTCTTACGCCTTTAGTCTATGTCGGGATACCCACCTTGGAGGAAACGTTGTGCTTATTTTTCCTCTCGGTTTCTATAAAAATATATTATTATGTTCACACACGCTACACATGCCAGATCATTATAGCGCACGCAATTTTCTTGATTCAAGTTTCGATTTTGTTTGTCGTTTCGTTTATACCGATGCTCCGACTTTTCATTCTCAAACTGTAACAGAGCTTATCGCGACGTCGTGACATCCATAGGGAACAGCTATTTTCTGAATAGTTTCTTCTTTGATTTTGCCATCATTCCGGTAGAGGCAGAATCGCAATTTAAATAGCTTTCGTTTGGATCCCTTCTATCTTTCAGTGTATTATGCGCGAAACTAAAATTTTCGGTTCGCTTTCTTGATACAGATCCATTCAATTGGGGAGCAGAATTTGAGAGCATCTCCTCGGAGGAGATAGTGATTGAATTATTCGATTCGATTTCGAGACTCGTGTGAGAGGGATAATAAATAGAAAATCTTTAGATATTGTCGTTGCTAAGAAATTGGTATCTGTCGTCGTTACTGTGAATGTGTCGTCGATTTTGGTCTCTTCAAAAGACACAAACTTTGGGGATGTTGTCCGGCAAGTGAATATAAACGAATAACATGCAGTGTGTGGTTTTTCGAAAGATTTTCGAAGTCGTATCCGAAACGTCGGATTCGTAGTCAGCAAATCTTGAGAATACGAAGCAATCAAATCCTTGCCCAAGTCGGTGCCGGATTTTCAGATGGATTTTCGTGCGGTTTGATTTTTCGGGGTGGTTGCTTGGGACTTTTAACCTTTTTATTCCGTACCCAAGTGTCGAGTGTCTTATCAGTGTCCAAACAAAATCTCTTAGTCCTCATTTATTGTGATTTCCCATTCATTTTGTTACATATATATTATATAGGAAGAAAAAGTAATTTTAGGGTGTGTGCGATTACGACGTGTAAAATTTTCAGAAATATACAGTGTTCGTATAATAGCTAGAAATAAAGAAGTCAAAGCAGCGCAGACGGATAAAAACTAAAGTTGAAAATTAAAAATATACCCCCAAAAAGTGTCACGTATCTGTGCCGTATCAGATCGCTACTGTAGTGCGCTTTTAGCAGCCGATTTCTAAAATTATTCGGCAAGAATAAATGCAAAGCAGATTGAATCCTAATCCATCCTTTCATTCCCTTTCCGTGCCGCTTTCAATTCCACTCCGATTCGCACGTATTTGCCGCTCCTAACGCCTTGCTCTTTCCCTGTATCCAACCCTCATCAGTGGTTTGGAATGTGGAGAAGTGCTCTTTTGATTAATTAGCAAGCAAAACTACTCTACGCGCCGTATTCATGACATCCATGATATCCCGCCGTCGACGAGTCAAAAGCCCATGTCCTCTTCATCGTTACCAGGACAAGAAACTATTAGACGAGGGTGTGTTCCATAGAATCACGACACGGCAAGCAAAGGGCATACCCTCAGGATTTCATAGTTGTGAATAAACAAATCGACGTCATAGAAATCACAGATGCGAAAAATATCAAGCCAAATGATAGATTTTGTGCAAAGACGCGAAAGCGTAGCCACAGCAGAAGTACTTCCAAAAAGGAATTCTAGATGAACGGGCGTGCCGAGAAAACAAGGAAAAGTCAGAATGACAGCGGAAGAAAAATCAGCAGCTGCGTCTTTCTAAATGCTTCTTTTGTGTTGTGTGTCCTACACCATAATTTTTCGGTCGTGCATCATTAAAACCCAAGAATACAAATGCCATCTTCGTCAATAAGACTTGGCTTAAATAATTGAGCAGCGTTTACTCAATGAATGACGGCAAAAATGCATTTAGCTTAGCGACTTTCCGTTCACTTTTCCAACTCAGTTCGATTGTACATACTTACGAGTATGAACAGATGGATACAGATAGATACGCAAACTGACAGCCACATAGACTGATTGAAAACATCATGTGAGAGCTTTGTGCCTTCTCTGTGCGAGTCCTGTTCACCCGTATCCGTATATGTACGTATACACGCAATTCAAGCGGACAAATAACGTGGATCAATCGATTTTCTATTCCTTCCGAACAGATATCCTTTTGTCTTTGGCAAAATAAAAATATCAAGGAAAGGAAACCGAAGGGCAGTCAAGGAAAAAATAAGAAGAAAACAGTACCTCGCTTTTCCTTCAACGACAGAAAACCCAACACGCGGTTATAACGGAACTAAGCATACATTGCGTATGTACTATCTTGCTGATAACCCTTCTCAATGCCACAAAAAAATTCTACTTAAAGTTAATCGCCAGCGGGCCTGCATAATACTCAACTTCTATATACATAGTCTGTTCAATTAGTGATAAATCCCGCGATTTGTATTTCTGAATTTCGGTGTTGATACCAAGTAGTATGTGAGTATGAAATCCTCAGAATGAACGCTTAACGACTGACTGGCTTCAACCAGCGTGACTAAGGACATGAAGACGAAGGTCGTCTGCCTTTTTTGTGATATCAGCTAATCCCCCGCAATTCAAACCCAACAAAAACCATTAAAAACGACAACGCGACCAAATCTTAATTTGATTTAATAAAATTGCTTTAATTTCGAGTATTAAATAAAGACCTAATTCGTAAAATTATGGAGTTGACGTCAATAACGAACTATTCAAAATATGACGGGAAAAATGAAATGCGGCAATATCTCAATATAAATACCAAGCAAAGGTTTGGATTTGCTGCCGTGTCTGCTGCTAGTTGTTCCGGACTACGATTCAAAATTCAAATCTCAACGGTCAATGAGCTGACGTAGAGATTGTGAGCGTGAGTGTTTCAATCGCCATCAATCTGTATGTGCAGCTCCGAAAACCGGTGTCCACGTTGTCGATTCCTGGCTCGATGAAAACACCCTGCGCTGGAAATCGAGAACAAATTTCGTCTGCATGCAACGAAGAAGCTGGCGTTGCACTCGTGGGTGTTCACTCAGAATATCCCAGGTACATGGAGGAGCGAGGATTGACCGGCGTCAAAGCACCTGGAGCTGGTTCAACACCGGGAACTCAGAAACATAAGCCGAATGTTGGCTATCGATTAGGTCGAAGAAAAGCTTTATTTGAGAAAAGAAAACGAATAAGTGATTACGCTCTTGTAATGGGTATGTTTGGAATTATCGTAATGGTTATAGAAAACGAATTAAGTAGCGCTGGAGTTTATTTAAAGTCTTCGTTTCATTCGACAGCCTTGAAAACATTAATATCCGTGTCGACTGTGATCCTTTTAGGTCTTATTGTTGCTTACCATGCTCTGGAAGTTCAGTTATTTATGATCGACAATTGTGCAGATGATTGGCGAATCGCTATGACGTGGCAACGAATTAGTCAAATAGGTCTAGAACTTTTAATATGTGCTGTGCATCCAATACCAGGCGAATATTACTTCCTCTGGACAACAAAACTTGCTAATAAAAATAAATCAATGGGCACGGAGTTGGTGCCGTATGATGTTGCATTATCATTGCCAATGTTCCTTCGATTATATCTAATATGTCGTGTTATGTTGCTACATTCAAAATTATTCACAGACGCCTCATCACGTAGCATAGGTGCACTAAATCGTATAAATTTTAATACCAGATTTGTCCTTAAAACACTAATGACAATATGTCCGGGAACAGTTTTATTAGTTTTTATGGTATCTCTATGGATTATCGCCTCATGGACGCTGCGACAGTGTGAAAGGTTTCACGATGAAGAACATGCAAACCTTTTGAATGCCATGTGGCTTATAGCCATAACATTTTTAAGTGTTGGGTTTGGTGATATTGTACCAAATACTTATTGTGGTCGTGGTATTGCGGTCAGCACAGGAATTATGGGAGCTGGATGCACTGCTTTGCTGGTAGCTGTTGTGTCTCGGAAGTTAGAGCTATCCCGGGCTGAAAAACATGTTCATAACTTTATGATGGATACCCAGCTAACAAAAAGGCTAAAAAATGCGGCAGCGAATGTGTTGCGAGAAACATGGCTGATATATAAACACACAAGGCTGGTGAAAAGAGTTAACCCTGGACGAGTGCGGACGCATCAGAGGAAATTCCTTCTAGCAATTTATGCATTACGAAAAGTAAAAATGGATCAACGAAAACTTATGGATAATGCAAATACAATAACCGATATGGCCAAAACACAAAATACGGTGTACGAGATTATCTCGGATATGTCAACAAGGCAGGATGCGATTGAGGAAAGACTATCAAGTTTAGAGGACAAAATGCAGGCGTTGCAGGATCATATGGAGTCATTACCGGAGATAGTCACACGGTGTCTCACTCAACATCAAGAACGGTTGGAACAGCGGAGAAATTTTCTGCATCCGGATGCTGCAGTAACAGCGTCTGCACAACCGTCGCAGCCGCCACCTCTAGTTTCACCTTTACTCTTTCCACATTCCAGGAGTGTACCATCTACAAACAATGCAATTTTCCAATGGCCAACAAGTCCAATTCTGCCACCGGTATCGAGTAGAACGCCTCATTTGGTGCCTGACACATATATTCCATCGACTTTAGCTGCGACGGCGACACCAGCTGCAGCCACAAGTTCAACCTCTCTAACAAATAATAATAACGTTAACACATCTTCCAGTAAATTAAACAGCTGAATCGAACCTGCACAAACTCAACAAACGCATTCTATGGTGTGTCCGGCGTCAACCTCAATCACGACGGCCAGCAACAAATACACGAGACGGAGGGAACGACAACGAAAAGCCCAGTTCAGAGCAATGGCAACAACATCAACAGAAGCAACAGCAACATCAACAGAAACATCAAAATCACATAGTAACTCATTAGAAGACATTTTTACGCAACAAGGCAACTCGTGAGAAAATAATGATAGTAGAAAAATTGAATAGTGACGATTTTACTATGTAATGGGAATAAATTATTATTACTATTATATAAAGACTAGGAAATGAAGCAACTAAGAAATAAGTAAGCAAAAAGACATAGGCCAATTTCTAAGGTTCTAGAAAAGTAATAATCAATTGAGACGGGGGAGAAAATATGAATAAAATTCGTGAATTTAGGGTGTAAATCATTGGAATAAATTTTGATAAGAAGGAACTCGTTTTGTTGTTTGAGTATTACGGTTATTTAGTTTTTAATTATGTCACATTTTCCAGTCCCTTAGAAACTACAGAAAAATTCTCATCTGATATACCAAGTGAAAGAAAATATTGAGTCAAATTCTCCCTTAGAGAACTGACCCGTTGATCAGGGCTGCATGTGCACTTCTTGGCAAACACATTTGACCAAATAAAAGTTTTTCCTCTAGCAAATTGTTTAGTATCCAAGTCACACATCAATAGGAAAAAAGTGATATTTTGCCGTTTTAGTGATTTTAAAATTCAGCCCTTATAATGCGGAGGACCCAACGGAATTTACTTAGTATTTTCTGTTACTGGTCATTCAGTAATATTACTCAAAGTAGAAACGAACCACAAAAGTACGCAAATTAGTAACATAGAGACTAGATTTTAAAAAAACGTACTTTTAATTTTCTTTAAAAATATTCGAAACTATGGGGCCCACTTTAATAGTCATTCGAGCGAATAACGGAAGACAAATAATCGAAATTAAAAACAACCTGATTGCTTGGATTTAGATCTTAACCGGTTTCAATATCATCAAAAAAACAACCACTCAAGAAATCCTCTTCAACCTCCGGATGAAATGAGCAACTGAACATTATGTTGAACAATAAAAGAAAGCTTTACGACAAAATAGAAACATCAATAACTTCATAGACTTCATACCTAAGACGAAACAAGCTTACGATATTAAAGCCACAAATTATAAATGATAAGAAAATCTCGAAACGAAAAAGTGAACCACTACCAAAGTGAAGTTATGTAACGAAGATAGGAAATGACAAAACCCTATAGAAATGTAGAAACAATTATTTCATCTTTAGTATCTCTTAGACCATTCATTTTCTACGAAGTCAAGGACGAAATTGTTTTAAGTGAATTAAGAACCCTTTTAGTGTATTCATTTCGTTCTATGTAATTACTAAAAAGCGTGTTTCGCGAAAAAGCTTTAAGATTTAGGGTGCCTGCATTTGCTAAGAAAAAACTTAGATTTAAAGAGAATATTACTTATTATTATTAAAATTATTATTATCACATGATGGTAGTAAGAACAAGTAACATTAGTAGAAAAATAAACCCTTGCGGAAGTAGGTCATGCATATTATGTAACATATGTTTTGTTTATGTTTGAATCGGTACATTCAAACTCAATTTGTCCAAAAATATAAAAGTTTCGACAGATCGTTTTTACTTTTGTTAGAAAAGGTTTTACGTGTGTTGCTGAATAAAATTGAATAGAATATACGGAAAAGTCTATTGTACAAATTTAGTTTATATAAAGTTGTTGCAATTATACATAAAAGAGCAAGAAAGATAAAAGTCTAAACCAAAATTGATTTTCAAAGTTAAGGACAATTTAAAAGTATTCGCATATTTACCTATATACAAAACATATTACAACAACTATTAAGAAATTATACAAAAACAACAAAAACCTAAAAAACCATCCCTCAAAGAAATTAAAAGGAATTTAAAAAGGATCAAAACGGTATCTAAGCGTAAAATAATTGAAGAAAATCCATACTAGTCTGTTTTATTATGAATTACATAAAATACGGATGAATAATTATGAACATTCTTTGAAATGTATAAATTTCGATCTTAAAAGTAACAAACGAACACACCAATTTGAACGTATCTTGCAATAGTCGTCCATTTCATTCAGCCATTGTATTATATATTTAAAGATATATATATATGTCTAAAACAAATTTATAGATAAAAAAGTGAATTGATAAAACTCAACTAAAATTAAATTTAAACCTGTGAATCATAGAAAACCCGAAAGTATGTGGATTAAATTATGGTCTTATAAAAAATATTTAAAGCAAATATATAAAAATTAAACTTTAAAGAAAATCTGCTCACATGCGCTAAGTACTAATATGATAAAGTTTAAATCTAAAAAATTAATAAATTTTAAATTATCTCAACATTCAATACAGTAAATTTATGGGTACGACATAAGGCTGAAGTGTAGGAATAAATAAAATCGAGAATGGAAGACTATTGCAACTGTATTGTCACCTTGTTATATTTTGGCTCTCCTGATAAAGAAAATAAAAAAGAAATTACGAAATCACTAAAAAGAGAAAGATAAAAACCCTAATCTAGTTATTATTATTATATAGAGAGAGAATCGTTATTTCGCAACATTAATATAAAAATATTTATTGTAAATTGTTCTGTTTTGTATGATATAATCATGTATATTTAGTTTACAATTAAATACGTTTTCTGCA
->XR_007117108.1 PREDICTED: Pieris napi uncharacterized LOC125050190 (LOC125050190), ncRNA 
-CCCAACCAACATTTTGGCGCTAATTTTCACCACTCTAATCGTTTGTATTGTTTTAACGGGTATATAAAAGTGTCTAGTAAAACTTTTGTTGGTTTAATGGTCATGAATATAACTAAATAACTCATTAAGATGAGTAACAGTAACAATAATTCATAATATAACTTAAGAAGTTATAAAAGAGTTAAGCTGAACCACAGTAACGCTAGGTGTTGTAACCTCAAGTAACAATAAGTACCTCAAGTAGTAATAAGGTTTCTAGTAAGTCTTACTATTCCCAAGTGTTGTTTAAGAGTGCTAAGTAAATGTTTTTTACCACTTAGCTTGCCTAAAAACGTAATATTACTTAAGAAGGTATGAAGGTTATAGTCACAACCATCATAGAACTTACTCTTATATAAATTCAAGTAACGCGAAACACTTAAAGTAATATTATAGTTTCTAATAACTCTTTCTACCGACAAAAGCTCTTGAAAATAGTTGACAAAATATTTTTATCACCTAAATTGCTACAAAAGAAGTAATTGGAACTTATTTACAGCAATTTAATTTAGAAATTAGAAACCACTATATATGATATTAGTTGGTATTATGGAGTTATTTTTAGAGCCCTGTTCTTTACAACGGTGTTCGAATTTACCTTTATGTTATTCTAAGAAATATGAAAATACAATTTAAACGTTGTAACTTTTATTTTCACTTGAAGTTATAAAATATTACCTACTTTATAGCTGTATAATGTCTCTAACCTCAAAATTGTGTATAGTCTGATTTGCTCTGAAGTCTGTTTGCTCTTGCTTGCTTAATTTTTGCTATGAGTTCGTGGAAAAAACGAAAAAGATGTGGAGGAGTCAAAAGAAAAATATCAAACGAATACAAATTAATAATCAGATCAAATCAATCAGTGTCATCCTGCGATAAAACCACCAAACTGCAAACAGTGACCAGTATCAGTGATGCAGTTCAGCATCATAGTTCTTCGTTGAAGAGAAGTATTGATGACGCTAGTCTGGGTTGTAGTAGTTTTTGCAACGAATATTTTCATCCAGCGCAGCTTAAATGTCAACGAAAATGTTCGTACTGTCGTAGAAACTCCATCGAAAATGTCGGTCAAGTGCGGGAATTTCAACAAGGACTAGAAAATCATAATATGTATGTGAGCAGTAAACATGGTGAAACGCAAGATATTGAACAGGGTTCTGTAAGTGAGCATTTTATAATTTCTTGTAAAGAGAGGAATAAATATTTTCTATCATCAACTGATGATATTATTGAAGTCCTAAATATATCAATTATATCGACAATGACAAATAGAGAAACTATTATGATACAAATAGGAGGAGATGCTATCGAATATGTAGATCACTACGTATATTTAGGGCAAATAATATAATTTCATGACCAAAGGGATCTTGAGATAGAAAGAAGAGTGTCTAGCGCCTGGAAGAGATTTTGGTCACTCAAGGAAGTACTTAAAAGTAAAGACTTCCCAATAGTAGCTAAGAAAAAGGTGTTCAATCTATGTATACTACCATGTGTTACATACGGCTGCGAGACTTGGGCTTTATCTCAGAAACATCTTCTAAAGTTGAGAACATGCCAAAGAGGAATGGAAAGAAGCATGGTGGGTGTAACACTGAGACATCGAAAAAGAGCAGAAGAGATCAGATCAACGACCAAAGTAGAAGACATTATAAAGAAAATAAGGCAGTTGAAATGGCGCTGGACTGGGTACATGACGAGAGATAGCAGGTTGAAATGGACAAAAATAATTACAGAATGGCAACCACGTGATG
->XM_017443506.2 PREDICTED: Diaphorina citri phospholipase A2-like (LOC103507865), mRNA 
-TTTTACTCGTCACCATGAAGTCTATCCGGGCTCTCCCTGTGAGTGTTTTACTCATCTTTGTATTCATCTCCTCTGTTCGTAGCTTTGATCAGTCCTACTATAAAAACGCGTATAATCACAACAAGTACAATTACTTGAAGGGAAATAACAATAACAAGTATAGTAACTTCAATTCCAACCAGGACAGTTACCGATCCGACAAGAGTGACTTGATCTTCCCTGGAACCAAATGGTGCGGTGCAGGAGACATTGCCACCGACTACAATGACCTAGGAACCAATGTAGAGACAGACAAGTGCTGTCGAGACCATGACCATTGCTCGGAATACATCTTGGCGAAGAGTTCTCTCCATGGACTGCGAAACAACGCACCCTTTACCCGAGTTCACTGCAGATGTGACAAGAAGTTCTACGACTGTTTAAAGACGGCGGCTGACACGGGAGATCAACCTTCCCAGATGGTGGGATACATGTATTTCAATTTACTAGAGACCCAGTGCTTCCAGGAAGTGTCACTGCTGTTATTTTAA
->XM_002502056.1 Micromonas commoda predicted protein partial mRNA 
-ATCCCGGGCCAGGCGGACACCGAGGCCATCACCGCCGTCGCCTTCAGCCAGTGCAAGAGCTACGTGGCCGTCGCGGAACGCGCGGAGAGGGGTGTCATCACCGTTTACGATCTCACCACGACGACGGGCTCGCCCAGGAAGCGCGTGCTCGCGTCCACCGACGTCGGGTCCAAGGAGTACGTGAGCGTCGCCTTCTCCCCCGACGGCAAGTGGGTCATCGCGCAGGGCGGCGCCCCCGAATGGAACGTGACGCTGTGGAACTGGGAGCGGTGCAAGCAGCTCGCGTGCGTGCCTGCCAAGCCGCTCGGATCGGACGCGGGCGCCGTTCGCCAGGTGAGATTCGCCGCGCACGACCCCGGTCTGGCGTCGTGCGCGGGCGAGGGCCTCTTCCGCACGTTCAAGTGCGCGGAATCCGGGGTCAGGGCGCTTCCGGATGTTAAGCTCCCGCCCGCCAAGTCGGGCGCGATTAAGAATTACACGGCGCACTGTTGGCTTCCCGACGACGCCGAGGTGACGGACGGCGGGGAGGAGGGAGCCGAGCGCCGCGAGCGGTGCATCCTGGCGACGGACGGCGGGGAGTTGCTGGTCGTCGAGCTCAACGAGGTCAAGGCGACGATACCGGCTTTGAGCGACTGGAAGGGTGTCGACTGCGTGATTCCCTACGGCGCCGGCGGGTTTGTGTGCGGCGGCGCGGACGGGACCGTGAGCGTCTACGAAAAGACGGACGAGAAGGAGCTCTACAAGCGCGTGAAGCACTTCGTGATCAAGCAGTCGCCCGGCGCGAGGGTGACGGCGCTCGCGCTATCCCCGACGGACGAGACTTTGCTGTGCTCCACCGACGATAACCAGATGTACGAGGTTGACATGTCCAACGTCGACGTCGTGAAGAGCGAGGACATCGAGTGCCAACTGTTCACGCAGGGGCACCACACGCAGGGCGTGACGGGCGTGGATCTGTGCGTGCGTAAGCCGCTGGCGGTGACGTGCTCGAGCGATAAGTCCGTGCGCGTGTGGAATTACTTGGACAAGGCTGACGAGATTTGCAAGTACTTCGCGGAGGAGGCGCACAGCGTCGCGTTCCACCCCAGCGGGCTGCACGTTCTGGTGGGGTTCAGCGACAAGCTCCGGCTGTGTAACCTGCTCATGGACGACATCAGGCCGTACCGCGAGTTCAGCATCAAGGGCTGCCGCGAGTGCTCCTTCAGCAACGGCGGCAAGTATTTCGCCGCCGTGAACGGGCCCGTGATCCAGGTGTATAACATGTACACGTGCGAGAACGTGGGCAACTGCCGCGGCCACGGCGGCAAGGTGACCGGCATCGCCTTCTCCGCCGACGATAAGCGCCTGTTATCTACCGGCCTGGACGGCGCCGTGTACGAGTGGTCCCTGTCCACGTTCCAGCGCGAGAAGGAGAACGTCATCAAGTCCAACGAGTACGCCTCCGTCGCGATCGCTCCCGACGATACTTACGTCTTCGCCGTCGGCTCGGACGCGACGCTCAAGCAGCTCGACGGCGAGGACCTCATGCTCAACGAGGAGTTCGCCCTCACGGGGACCGGCGGTGATGGCGGCCAAACCCAAACCCAAACCTTCACGCGCGTCCGGCTCACCAACGGCGGCAGACGGCTCTTCGCCGCGACGTCCACGGGGGCTGTGAGGGCGTACGAGTTGGACGGCGGCCGGATCGCTGGCGAGGGCAAGGAGTTCAAGGAGCTTCGGTGCCACACGGGTCCAGTGACGGGGATGCGGGTCAACTTCGACGATACCCTGCTCTTCTGCGTCGGCGAGGACGGGGTGTTGTCCGTCTTTGACGTCAAGGAGCGCGCGATGGAGGGCGCGACGAAGGCTGGCGAGGGGATGGTGTTTGCTCAGGAGGTGCTCATGACGAAGGCTGACCTCGAGGATATTCGCAGCAGGATGCACGAGCTCGAGGTTCAGGTCAACGAGCTCACCCTTCAGGGCGAGTACCAGCTTCGCCTTAAGGACCTAAACATGAACGAGAAGATCAAGGATCTCACCGACAAGTTCCAGGGCGAACTCGAAGGCGAGCGGTCCAAGTACGACGCGCTGCTCCAGGAGAAGAACGAGCTCGAGATGGATTTCGCGGACCAGATGAAAACCACCGAGAACAAGCACGCGCAGGCCACGGCCGCAACCGAGTCTTCGTTCCAGAACAAGATCCTGAACGAGATCGAGCGGTACCAAGCGCTCGTGGAGGAGAAGGAGGAGCTCAACCGCGGATGGGACGAGCAGAACACCGCACTCGCCGAGTCGCATGATCGCCTCGTGGCGGATCTCACCGAGGAGTTTGCCGGTAAACTTCAGGAAGAGCAGATGCACTCGGAGACTCTTCGGCTGCAGCTGGAGGAGGCCCGCGCGGCTGCGAATGAGCGCGAGAACCAGCTCGAGGAGGACGCCGACCTCGAGATTGACGAGCTCAAGGAAAAGTACGAATTAAGGCTCAAGGAACAGCGCGACGTGTCGCTGAGGTTGAAGGGCGAGAACGGCATCATGAAGAAGAAGTTCACCACCATGCAGAAGAGCATCGCGGAGCAGAAGGACGAGATTGCCGGTCTCTTCACCGATAAGAAGAACCTGTACGCCACGATCGCAGATCTGGAGAAGGACGTCGCGGGCCTTAAGCGCGAGATCCGGGACAGGGACGAGACGATCGGGGACAAGGAGAAGCGAATCTACGACTTGAAGAAGAAGAACCAGGAGCTGGAGAAGTTCAAGTTTGTCCTCGACTTCAAGATCAAGGAGCTCAAGCGGACTATCGAACCCCGCGAGCAGGACATCTCGGATATGAAGAATCAGATCACTGAGATGGACAAGGAGCTGGAGAGGTACAACAAGAGCAACACCCACCTCGACCTCACCATCAAGGACCTTCGCAACAAGCTCCTCGGGATGGGCCAGGACGTCAAGCGCAAGCAGAAGGCGATTGAGGACCGGGACTCTGCAATTCATTCGTTCCAGAAGGATCTCCACGAGGCCACGAAACACGTCCAGACGCCCAAGCGACTCGCCGAGGAGGTCAAGTCCCTGTACGCGAAGCACATGACGCAGAAGATCGACGACAAGCCCCCCGACAAGGACATCCAGCGCGAGTACAATCGCCAGCGAGAGTACCTGGAGAAGACCATCGATCAGTTCAAGCGCAAGCTCGCGAAGGACGTCGAGACGCACAAGAAGGACAACATGGCGCTGATGA
->EF225152.1 Uncultured bacterium clone Br_008751_0450_0145 16S ribosomal RNA gene, partial sequence 
-CACCGCCCGTCACATCACGAAAGACCACGTTGTACTAGAAGCCGGCAATTCAACCGCAAGGAGATAGCCGTCCAAGGTATGACTGGTGATTGGGGTG
->XR_004539126.1 PREDICTED: Geotrypetes seraphini TIA1 cytotoxic granule associated RNA binding protein like 1 (TIAL1), transcript variant X6, misc_RNA 
-CCTCTCCTCTCGCGTAGGGTCCGAGGAGAGCGGAGGTCGGCGCCTGCGCGTTGCGGGGATTCCTGCCTGACTGACTGGCGGCCGCCATTTTGTTATCCCGGATCTGCAGCGGATGAGCCGTGCTGTAGGAGACGTAGTTGTCTGCTCGCTCCCTCCCCGCCCGTCCATCTCTCCCTCGCCCCGGCAGCCATGATGATGATGATGATGGAAGACGACGGGCAGCCACGGACCCTCTATGTCGGTAACCTTTCCAGAGATGTCACAGAAGTTCTTATTCTCCAGTTATTCAGTCAGATTGGCCCCTGCAAAAGCTGTAAAATGATAACTGAGCAACCTGATAGCAGAAGGGTCGGCTCTTCTGTTGGATTTTCTGTTTTGCAGCATCCAAGCAATGACCCGTATTGCTTTGTGGAATTCTATGAACACAGAGATGCAGCTGCTGCATTAGCTGCCATGAATGGGCGAAAAATATTGGGAAAGGAAGTCAAAGTAAACTGGGCAACTACCCCAAGTAGCCAGAAAAAAGACACTTCCAATCATTTCCATGTGTTCGTTGGAGATTTAAGTCCAGAAATCACAACAGAAGACATAAAGTCAGCATTTGCTCCTTTTGGTAAAATCTCGGATGCACGTGTGGTCAAAGACATGGCAACAGGCAAATCAAAAGGCTATGGTTTTGTTTCATTTTATAACAAATTGGATGCAGAAAATGCAATTGTGCACATGGGAGGCCAGTGGTTAGGAGGTCGTCAGATCAGAACCAATTGGGCGACACGCAAACCACCTGCTCCAAAAAGTACACAAGAAAATAACACAAAACAGCTAAGGTTTGACGATGTAGTGAACCAGTCAAGTCCCAAAAATTGTACTGTGTATTGTGGAGGAATTGCTTCCGGACTTACAGATCAACTTATGCGACAAACGTTTTCTCTGTTTGGGCAGATCATGGAAATACGAGTTTTTCCAGAAAAGGGCTATTCCTTTGTCAGGTTTTCAACTCATGAAAGTGCTGCTCATGCTATTGTTTCAGTGAATGGAACTACGATTGAGGGGCATGTTGTTAAATGCTATTGGGGTAAAGAATCCCCTGACATGTCTAAAAACGTACAGCAGGTCTGTGAGATGCCTCTTATGTGTGTATTTCATTGATTGCCATACACACTATCTCTTCAATTTTAATTTTTGGACTTGTGGCATTTGTATATAGACACCTAAAGATGGAGTATGGGCAGTGGGGACAGTGGAGTCAGGTGTATGGAAATCCACAGCAGTATGGACAGTATGTGACCAATGGATGGCAAGTACCTTCATACGGGATGTATGGTCAAGCATGGAATCAGCAAGGATT
->XM_013369717.2 PREDICTED: Columba livia parathyroid hormone like hormone (PTHLH), transcript variant X6, mRNA 
-GAATCGTTTCACCCGGTTAGAAGATTACACCAGGTCAGACGTGGCTAAGGATTTTCTTATTCCTGACAGCAGCAGGAAGGAGAGGAAGGCAACCTTGATGGGAGCTGGGAACAGAGTGCAACAGGGAGGAAGATTTCGCTTCTGAGCAACTTTTGGGGAGCCTGGTCGCCCACCCATCTGCAGCCCCTGGCTCTATTCACCGCTCAGGAATTACGTGCCAAACCTGGAACAGGGACTTACCTTCCTAGCCAAGCTCTCAGGATAAAATATAGTTTTGGAAGCAATTGCTGAGAAGATCAACCACTGTTGGCCAGGGTGATCTCTGAGAAGCACAGAGGGCTGTAACTCAAGGAAAAGGTTTTAAGACCCGGAGGATACAATGTTCACTAAACTCTTCCAGCAGTGGAGTTTCGCAGTGTTTCTGCTGAGTTATTCCGTGCCTTCTTACGGGAGATCAGTAGAGGGGATCAGCCGCAGACTCAAACGAGCTGTATCAGAGCACCAGCTATTGCATGACAAGGGCAAGTCAATCCAAGACTTACGAAGAAGAATATTCCTTCAAAATTTAATTGAAGGTGTCAACACTGCAGAAATTCGTGCAACTTCAGAGGTTTCACCTAACCCTAAGCCTGCTACCAACACGAAGAACTACCCTGTCCGATTTGGTAGCGAAGATGAGGGCAGATACCTAACTCAGGAGACAAACAAATCACAGACCTACAAGGAGCAACCCCTGAAGGCATCAGGGAAGAAAAAGAAAGCAAAGCCTGGAAAACGTAAGGAACAGGAGAAGAAAAAGAGGCGAGCTCGCTCAGCTTGGCTAAATTCTGACATGTATGGAAGCAGTGTGACCGTGAGCCCACTCTTGGACAACTCCGTTACTACACATAATCACAATTTAAGGAGGCGCTGACATTTTCAGCAAGAAATTTTTGGAAGACATATTGCAGTATTCTGTAATAGTGAACATATGGGAAGTATTAAAATATTTATTACCTGTAAATATTGTAAATGCTCAGAATAAAACTTTTTCCCCCATTGCTCTCTGAAACTGCACATTTGGTTATTGTGAATTTTCTTTGTTTCTTTTTTTTTTTTCCCCTAAGGCTAAGACAATTATTATTATCACATTTAACATAATTTATTTTGTTGACTGGTGTATTTATTTTGTGAACGTATCTTGGTGCTGCTGACTTTCTATATTTTTTGTAACATAATGCACTTTAGATATACATATCGAGTACATTGATAAGTGACATAAAATGTTCCCATTTCGTGGTTGACTTCAATGAATGCCTACATACAATTGTTCAAACTGATTTTCCTTTGTGCATGTATAATAGCAGTATTTTAAAATTTGTAAAGAATGTCTAATAAAATATAATCTAATTAAATCA
->XM_027670495.1 PREDICTED: Neopelma chrysocephalum smoothelin (SMTN), transcript variant X3, mRNA 
-GGGAGCGCAGCCGAGCCAAGCGCGGGGCCGCGCTGCCCCGGACGCCCTTTGTTGTCTCGGTCGCCGCTGAGCCCCGGCCGCAGCAGCGCGGGCCCGGCGGGCGGGATGTCCCAGGAGAGCCTCCTCGGGATGGACGAGGGAGCGCTGCGGAAGCTGCTCGAGGCCACGCTGGACCTGGCTGAGCGGCGCCGCATCCGTTCGGCCATCCGGGAGCTGCAGCGGCAGGAGCTGGAGCGGGACGAGGAGGCGCTGGCATCCAAGCGCTTCCGCCCAGAGCGCGGCAGCCACAGACAGGACGACAAGGAGAACTGGCCACGGTCTCAGCACCTGGAGGAGGAGCAGCAGGCAGCCCTGGCCGCCTTGTCCCAGGAGCTCGAAACAATCACCAGCGTGGAGGAGCTGACAAAACTGCTGCGGGCAGCGGGTGAGTATGAGGAGCGCAAGGTGATCCGAGCTGCCATCCGTAAGCTGCGGGCTGAGGAGATCAAAGCTGCGACACTGGCTGGGAATGTGCAGAGCAGCCGGAGGGATGGCAACGAGCCCCGCACTGTGCCTGGGGATGCGAAAAGTATCCAGAGGGACAATGCTGAAACACCAGCCCTTACTGGGAGTGGGGAAAGCCTTGGTGAGGGCAGCACCAAGCCCCTGGGCACAGCCAGGAGAGGGGAGAGCAGCCGTCAGGACGATGCAGAACTGCCGGCACTGGCTGAGCTAGAGGAGAGTGGGCACAGGGGGGCTGCGGAGCAGCCCCCTGCCCAGGAGCCTGAAGTTTCGGCGGACCATGAGCGAGAGGACATGGTGGAGCAGGAGCATGTCCCAGCCAGGATGCAGGAGCTGTGCAGCCAGCAGGCGGGAGACCCCCAGAAACCCAGTGTCCAGGAAGTGGTGTCGGGGACCCTTGTGCTTCTGGAGCTGCAGCCGGCCCCAGAGCCCAATCCGGAGCCTGAGGATGGTGTTGAGGAGCTGGAGCAGGGCCAGCCCCAGGGGCAGCAACAGGCAGCCTGGAAGGCAGGGAGCCTGGACAGCCCAGCCACTGCTGCGGAGCCCAGCAGGAGGCAAAGCCCTAGAGGGGAGCAGCCACCCCTGGGCCAGCCTGGTGCTGCCAGCCAGCTCCATGTTGGGGTGCGCTGCCAGGCACTGGGGCCAGATGGGAGACACGGGAGGCCACCAGTGGCGCCAGTGTCCACCCAAGATCTCGTAGGGACCCCAGCTCGCCTGAACACTCACCAGTGGGAGCAGGTGCCCTCCTCTTCGTGCCCAGCTGGCCCCACGGAGGTGACCCTGGGGCTGCGGAGCACCCCCATCCGCATCACCACCATTCCCAGCAGTGTCAGCAGTATCTGCAACATCAGCAGTGTCAGCAGCAATGTCACCAAGATGGAGCCGGAGGTGGTGGAGCAGCCCCAGGTTCTGAGGCTGGAGCCAGAGCTGCCCAACGGCATGGAGAAGGTGCAAGTGAGGGAGGTAGAGAGAAGGAGCAAGCTGAATGTCGAGGAGCTGAGCAGGATTGAGGATGAGGATGTTCTGGATAAGATGCTGGATCGGACAACAGACTTTGAGGAGCGACGGCTGATCCGAAATGCCATGCGGGAGCTGCGCCAGCGCAAGCGAGACCAGCGGGAGAAGGAGCGAGACCAGCGGCTGCAGGAGGCTAGGAGCCAGGCTATGGCAGGAAGGGCTGGCCACGCCACCGAGACCACCACCACGCAGAGCACTCAGTCAGCTGACGGCTCAGCTCGCAGCACCGTCACCAAGACTGAGCGTCTCGTCCAGTCTAGTGATGGCACCAAGACCTCCCGTACCACAACCATGGAGTCAAGTTATGTGAAGAGATCAGACAGTGGCAACAGCACGTTTGTTCAAACCAAATCATCCTACAGCTCCTCGTCCAAGAAGACCGGCAGCGTCTTTGACCGTGAAGATGAGAGTGCCTCCAGGCAGAGCAGCCTGGCTGCACTGGAGCGACGTCAGGCAGAGAAGAAGAAGGAGCTAATGAAGGCTCAGAGCCTGCCCAAGACCTCAACCTCACAGGCACGCAAGGCCATGATGGAGAAGCTGCAGAAGGAAGGCGGGAGCTCACCAAACCCCGCAGCATCACAGACCACTGTGCAGCGCTCCTCCAGCTTCGGCGTGCCCAATGCCAACAGTATCAAGCAGATGTTGCTGGACTGGTGCAGAGCCAAGACCCGGGGCTACGAGCATGTGGACATCCAGAACTTCTCGTCCAGCTGGAGTGACGGCATGGCCTTCTGTGCCTTGGTCCACAACTTCTTCCCTGATGCGTTTGACTACAGTAAGCTGACACCCCAGAACCGCCGCCACAACTTTGAGGTGGCCTTCTCTTCTGCAGAGACGCTGGTGGACTGCGTGCCGCTGGTGGAGGTCGAAGACATGATGATCATGGGGAAGAAGCCAGACGCCAAGTGCGTCTTCACCTACGTGCAGTCCCTCTACAACCACCTGCGTCGCCACGAGTTGCGCATGCGGCAGAAAGAGTGCTAGAGCCTGCCCTGCCCACCCCCCCACTGTCCTTGCTGCCAGGGCTGCCAGTGGGCAGGGGAGCTGTCTGCCCCAGGAGGGTCTGGCAGGGCCACAGGTCTGGCACTGAGGACAGGGGGAACTCTGACACCCAGGCAGTCCCCTGCCTCTGCCTTGCCAGAGCTGCCTCTGCCCCGGCCAGCTGCGGGCTGACCCCATGAGCAGGGCCAGGCAGGCACTGCTGGGGATGCTCCTGGCTTGGCTTGCCCCCTGCGCTCCAGCCTGTTAAGTTATTTGTTCTCCAGGAATTGTGTACCCTGCGGGCAGCACTCCTGTGTCCCTGGGTGGCACAGCTGCGCCCTCAGGCCTGGGGCACAGTGTGGGTCAGTGGCTGAGCAGGACCGTGTAGCCCAGCCAGGCATCCCACAGGCAGCATCTGTCAGTGGTTCCCATGGCTCCCTGTGAGGAAGCCCCTCTGCCCACCGCAGGCCCTGCTTGGTGTCACCTCCCTGGGGACAGCTCCACAGCTGTGCCGACACCCTGCTTCCCACCTTCACGTGCACCTGGGGCACTTCCGCACTAGGGGCTGCAGCACCTGTGGGCTGGGGAGCGGGCAGGGGTGAGAGGTCCCAGGGGAGCACGAGGCTGAAGGAGCCAGCCAGGATGGCAGCCCCTTCTCCCCTCTCCTGCTCAGGGCACCACGCGCTCAGCGCCGCTCGCCCCTCCGTCACGTCTCTACACCTGTAACGACACGTGTACCAACACCAGCCAGATAATAAAGGTTTACCTAGGGTGA
->XM_032185005.1 PREDICTED: Aythya fuligula latent transforming growth factor beta binding protein 1 (LTBP1), transcript variant X5, mRNA 
-AGGAAATCAATGGATACCAAAGTGTTCTGTTTATTTTTCTTTTTTTCTTTGCCTCCGCTGACAGTGGGAAATCACACTGGTCGCATCAAGGTGGTCTTTACACCCAGCATCTGCAAAGTGACTTGCACCAAGGGCAACTGTCAGAACAACTGTGAGAAGGGAAATACCACCACCCTCATCAGTGAGAATGGCCATGCTGCTGACACTCTGACAGCCACTAACTTCCGAGTAGTTATTTGCCACCTTCCATGCATGAATGGAGGCCAGTGCAGTTCTAGAGATAAATGCCAGTGCCCTCCTAATTACACTGGTAAACTTTGTCAGATCCCTGTGCAGACTGCCAATACTCCAAAACTGTATCATCACCCACAACAGGTGAACAAAGCTGTAGGATCTCAAATTATCCACTCGACTCATACTTTACCACTGACAATGTCTGGACAACAAGGTGTAAAAGTGAAGTTCCCTCCTAACATAGTGAATATCCATGTGAAACATCCCCCTGAAGCCTCAGTTCAGATACATCAAGTTTCAAGAATTGACAGCGCATCAACAGGACAAAAACCGAAAGTACCTCAGCCAGGACATCCACAGGTCTCTTACCAAGGTCTTCCATATCAGAAGACCCAGAAAGGACATACTGCTTACACAAATCAACAACCCATTCCTCATGTGTTTCCTGTTTCAGTTAAAACTCAGCTTGGACGTTGCTTCCAGGAGACTATTGGAACACAGTGTGGCAAAGCACTTCCTGGCCTTTCCAAGCAAGAAGACTGCTGTGGAACCGTGGGTACTTCCTGGGGTTTTAACAAATGCCAGAAATGTCCTAAGAAGCCATCATACCATGGATACAGTCCTATGATGGAATGCCCCCAAGGCTACAAGAGAATCAATGCTACATTTTGTCAAGATATTAATGAATGTCAGTTACAAGGAGTATGCCCTAATGGTGAGTGTTTGAATACCATGGGCAGCTACAGATGTACCTGCAAAATGGGATTTGTGCCAGATCCTACCCTCTCAAGATGCATAGCTGATAGTCCTATGGTTGCTGAAGAGAAAGGACCCTGCTACCGGTTTGTTAGTGCAGGAAAACAATGCATGCATCCTCTTTCTGTTCAGCTCAGCAAGCAGCTTTGCTGTTGCAGTGTTGGCAAAGCCTGGGGCCCACACTGTGAGAAGTGTCCCCTCCCAGGAACAGCAAAGGAAGAGCCAGTGGAGGCACTGACCTTCTCACAGAAAAGTGAGCCTGAGATGGCTGTGCAAGAAGTGGCAACTGCAGCCCCTGATCAGGAATTAGTTTCACTCGATCAAGAAAAGCAAATCGTAGAGCCTGGACAGCCCCAGCTCTCTCCTGGAATTTCAACAATTAACCTGCATCCACAGTTTCCAGTAGTGATTGAGAAAACATCTCCTCCTCTGCCTGTTGAAGTTGCTCCTGAAGTCTCTACTTCAAGTGCAAGTCAAGTAATTGCACCTACTCAAGTTACAGAAATCAACGAGTGCACAGTTAATCCTGATATCTGTGGAGCAGGACACTGCGTTAATTTGCCTGTGGGATACACATGCATCTGCTACGAGGGATACAAACTTAATGATCAGCAGACAAAATGCTCTGATATTAATGAGTGTAATCAGACACCTCATCTCTGTTCCCTTGGACGCTGTGAAAATACAGAAGGAAGTTTCCTATGTATTTGCCAAGCTGGATTCATGGCCAGTGAAGATGGAACTGACTGCGTTGATTTTGATGAATGTTCAAGACCTCATACTTGTGGGGAAGGCTTCTGTATAAATACTGTTGGCTCGTATAGGTGTGAATATTGTGATAATGGCTACCAAATGAACAGGAGAGGGGAATGTGAAGACATTGATGAATGCATGACCCCAACGACTTGTCCAGATGCACAGTGTGTTAATGCTCCTGGCTCTTACCAGTGCATTCCTTGCAGAGTGGGATTCAGAGGCTGGAATGGACAGTGCCATGATATAAATGAATGTCAGTATGGCAATCTCTGTACACATGGACGTTGTGAAAATACTGAGGGGTCTTTCAGATGTATTTGTGGCCAAGGTTTCAAACTCTCTGCATCAGAGGATCAGTGTGAAGATATAGATGAATGCCAGCACAGATCACTTTGTGTGAATGGGCACTGCAGGAACACAGAAGGGTCTTTTAGATGTGTTTGTAACCAAGGTTACACATTATCTTCTACTGGAGATCAGTGTGAAGATATTGATGAATGCCTTCAAGACAGTGATGTATGCCTTCGAGGAAACTGCATGAATACTGATGGGTCTTACAAATGCACTTGTCCAGATGGCTTCCAGCAGATAGCAAATAGGGGATGTCAAGATATCAATGAATGTGAGAGATCTGACCTCTGTTCACCTCACGGGGAGTGTCTGAACACAGATGGGTCCTACCAGTGCATATGTGAGCAGGGCTTTTCTGTGTCTGCAGATGGCCGAACATGTGAAGATGTTGATGAATGTGTGAACGGCACACTGTGCGGCAGTCATGGGTTCTGTGAAAATATGGATGGCTCCTATCGCTGTCTCTGTTACCAAGGGTATCAGGATGCACAAGATGGGCAAGGTTGTACAGATGTGAATGAATGTGAAATGCTGAGTGGGGTATGTGGTGAAGCCCTCTGTGAAAACGTCGATGGTTCTTTCCTCTGCCTGTGTTCTGATGAAAACCAGGAGTATGATCCGATGACCGGACAGTGTCGCTTCCGTACCTCACCAGAATTGCCAATAGAGGCCGATCAACATGAAGATGGAAAGAAGGAGTGCTACTACAATCTGAATGATGCTAATTTCTGTGACAACGTGCTTACATCTAATGTAACCAAACAGGAATGCTGCTGTACTTTGGGTGCTGGCTGGGGTGACAACTGTGAAATCTTCCCATGCCCTGTCTTTGGAACTGCTGAATTTACTGATTTGTGTCCTGAAGGGAAAGGTTTCATTCCCTCTGGAGAATCATCTTACGGGCTTCTTGCTGAGAATTACAAAGATGCTGATGAATGCCAGCTCTTTGGAGAAGAAATCTGTAAAAATGGCTTCTGTTTGAATACGCAGCCAGGTTATGAGTGCTACTGCAAACAGGGCACGTACTATGACCCTGTTAAGCTCCAGTGCTTTGACACGGATGAATGTCAGGACCCAAACAGCTGTATTGATGGCCAGTGCATTAACACAGAAGGATCTTACAACTGTTTCTGTACACACCCAATGATTTTGGACGCAACAGAAAAGCGGTGCATCAGACCAGCAGATTCAAGTGAACAAACTGAAGAAACTGAGGTCTACCAGGATCTTTGCTGGCAGCATCTAAGCGATGATTTTGTTTGTAGTCGACCTCTGGTTGGAAAGCAGACTACGTACACTGAGTGCTGTTGCTTGTATGGTGAAGCCTGGGGCATGCAGTGCGCCTTGTGTCCTATGAAGGAGTCAGAGGATTATGCCCAGCTGTGCAACATTCCTGTTCCAGGATCTCGACGTCCATATGGACAAGATGCTTTGGTTGACTTCGAGGAGCACTACACTCCAGAAACTAATCCATACTTTGTTGAAGACCGTTTCCTGAACAGCTTTGAGGAGTTACAAGCAGAGGAATGTGGTATTCTGAATGGATGTGAAAATGGCCGATGTGTAAGAGTCCAGGAAGGCTACACCTGTGACTGCTTTGATGGTTATCACCTGGACATGGCCAAAATGACTTGTGTTGATGTGAATGAGTGCAATGAGCTGAACAACAGGATGTCTCTCTGCAAGAATGCCAAATGCATTAACACAGAAGGTTCGTACAAGTGTTTGTGTCTCCCCGGGTACGTACCTTCAGACAAGCCAAACTACTGCACACCACTGAACTCAGAACTAGACAGTGAACTGGAGTAGAGGAAAATCTCCATATCCTAAGCCCATATACTCTGCACTGTATAAAGAAAAGGAAGAAAAGTATTTAACTTGAGAAGAGAAGGCACCAGAGTAGTGAACATAAGGGGAAAAACACATTAAAATGTGTCAAAGGTGAGACATGATGGGCTGATTGTATGTCAGCTTCACTGAAGTGACAGACCAAATGGACACATTACTCTGTATGAAAGAAACAATCAAGTATATAGTGTGTTCATAAGAAAAAAAAAAAAA
->XM_038354470.1 Zerene cesonia endocuticle structural glycoprotein SgAbd-5-like (LOC119831184), mRNA 
-AACACATTGCAAGTGAAGACGATACGGTCACAAAGCTGCGAAGCAAATCCAATCATGAAATTTTTGGTGGTAATTGGTTTCTTGGCATTAGTGTCGGCTGCTCCCGCACCGCAACGTCAGCCAGGTGCCCCAAATCCACAAGAAGTTCAAATTCTTCGCCTCGAAACTGAAAACGACGGCCTCGGCTCGTACAGATATGCTTTGGAACAAAGCGATGGCACGAAGAAGGAAGAGCAAGGGGAACTGAAGAACGCTGGTAAAGATGACGAGGCGATCTCGGTCAGGGGATCTTACGCCTGGGTTGGACCTGACGGTGTGACATACATTGTTACTTATCTTGCTGATGAAAACGGTTTTCAACCAACGATAGAACAGGGCCCAGGTGGTGCTGTGCCTTCTGCTGTCATCGCGTCCCTCGTCGGCTGATCAACAAATAACCCAAAACCTAGTCGCCAAATAAATTACCATATTTTTTTAA
->XM_035478915.1 Colletotrichum scovillei oxidoreductase (HER10_EVM0009428), partial mRNA 
-ATGGCTTCCGTACCCACGCTTCGAGAGCTTGCAAAGCAAGTCTCTGAATCCATCTCAGACGAACATCTCGCCGGTAGTACGTTTGCTATTGGCGGTGAGATCCCAATTGAGCAGCCCAAAGACGAATCTAGCCCTACGACTCAGGTTGTGTCTTCTTCGGTCGTTCTTCGGTGGGACAATCCGGGGGAACATCCTGGCCCCCAGCGAGTCTCCTTCCCAGTCGCTTCAGATGACGACGCTGTCGCCTTCAATCACCTCCTCAAAGCCTCTGAAAAGGCTACATTCGGTCTCAACGGACGGCACGAATTCGATGAAACGTACCGCAAGGCTCAGAAGCTCGGTGCGGGTGATTTCTGCACCACCTTCTGCCCATATGAAACAGGCATCATCGACGCTGTTTGCCAGGTTCTTCTCCCTAGCTACGATACGGACGAAGACACGCGGGCAATCCGGGCGGAGCTGTACAATATGAATATCTACTCTGGTCCTTCGGGCAAGTTCAAGGCGCACGTCGATACTCCTCGTTCGCCCTACCAGATTGGCTCTTTGGTTGTCTGTCTTCCGATGAAGCATGAGGGTGGCGAGCTGGCAGTGAGACATTTTGGACAGACTCACACCTTTGACTGGGCCAAGAACTCCAACAACTCCGTCATTCAGTGGGCGGCCTTCTACAGCGACTGCGAACATGAAGTGCTCGAGGTCAAGTCCGGTCACAGAGTTACACTCACATACAACTTATATGCCACAGCAGGAAACGGAGAACTCGCAGGTGAAACGTCTGCTTTCAGCCCTACTTCGCTGCCACTCTATAGCCAGATCGTAGACTTGCTCGGCTCCAAGAAATTCCAGTCCAAGGACAGACTTCTGGGAGTCTACAGCACGCACGCGTATCCTCACACCGAAAAGGAACACGGCCTTCCGTTCTGCCTCAAGGGTCTTGACATGGTGCTCTACAACACCTTCAAGAGCCTAGGCTTGAAAGTCAACTTGTGTGCCATTCTCGAAAACCCGAAAGGCTTTTGCAGACGTAAGCTTTACAATGGAGAGTTTTCCGATGAGGATTCAGATACCGAGCCAACGCAGAAGGTGACATTGGCGAAGAACGATAGCGGGGACAAATTTGACTCGGACGGCGACGATAGCGGGGACCAATCTGACTCGGACGACGACGATAGTAATAAGTACTACACCAGAACCGTCGGATACATCAATCAAGCATTCTCCACTGACGAGCTGGTTGAGGACGACGATGATCTGAAAAGCATCATCAGCCGGGCCATGAGAACCAACAAGGTCAAGTTCGACGCCAGCAAGATCATCTGGCTGAACAAGAACAATGGCGAGTCGAATATGCAGGTGTCATATATGGCATACGGCAATGAGCCATCCTCCGAGGAAATCTACTCATACTTTGCGATGGTCATTGAGATCCCTGGTGTTGGAGTGAATGCAAGCGATAACGCGGAAGCGTAG
->XM_041571208.1 PREDICTED: Xenopus laevis lysine-specific demethylase 2A (LOC108697539), transcript variant X12, mRNA 
-ATGTATAAGTCCATATGGGCAGCACTCCACTCTTGATGTTTAAACTCGGGTGCAAGGTAAAAGAATCAGTTATGTAGACAAATGACCAGCAACACCGAGATATTTCGTGAATAGTTCAAGTGTATTCAGTAAAAGACACCTGGTTACAGAGACCACTAAAAGATGGTTGCTATAAATGCACCAATTGCCTAACGTGCAGGGGAATGTTACAGGGCACACATTTCACCCATCCTAGGACTGGAACTAAATTTCGGATCAACCATAGGGTCACTTGTACCACAGATCACGTCGTATATATGGCCTGGTGTCCGTGTGGATTACACTACATTGGGAAGGCATCCACCACATACCGCGAACGGATGAACAACCATCGTTGTGCCATCAGAAGTGCCCTGACTACTGGGAAAGCAGATCAACCCATTACGAAACATTGGCTGAATAGCAAGCACACCCTCCCACAGTTCCGGCACATGATCATAGACTATGTGCCTGTTCCTAGGAGAGGTGGCAACAGAGGCCTCCTACTACTACAGAAGGAATCCATGTGGATTTACAAACTAGATACCTTGTCACGAGACACTTCCTATGTCCCCCTTTTATTGAGATCGGAACACTGGGTCATAAACTATCCACAGTATAATTACCTCAAATGAAGACTTTGACAGTTGGGTTTGACTAATCTTTATTTTGTTGGTTTTTATTACCGTTTGCATTTTTTGACTCTTTGGCTTCTGGATGTGAATGTCACAACAGTAATAGTATAGAATTGCAAATATGGGCTCTGGCGGCTGAGAGTTGGACTCATCGAGTGTATGAGTCGATATCTCTTTTGCTTTTGGGGTTGATCGTTTCCTCGCATTCCAAGGTGCTGGTGCCGTTCTGATCCAGCTATATAACAATATGTATAAGATTATTCTTGATTGTTGACAGGTGACTTATCAGAGTTTATCACAGGCAACTAATGACATATGTATTGCATATATGATATTTTTACAACAGGCTAGCTTCCATGAGGACGAGGGGGACAACAACAGAACATTTCGGTCGGCCTTTTGGCAGGATGATGGACCAACCAGTCATATGTGACCGTGGACCTCGCTTAGGTTAGCAGTGAGGCGCTGTGCTAAGGAGTCCTACGAGAACATGCTCCCAAACAAACACATCACACTGCACCAGGACTGATAAGAAATGTGGTTTGGCCGTCAGGTACACACAGCCTAAATATGCCCTGAGGGGAGTGAGCGTGGGGCAGGCCTTTCACTTACGTCTAGCTGACACTCCAGGGCATCGCTGTCTGGACGGTGTAACGAATCCACAAACACTTCGGTTCGATCAAGGGACTGCAATATCCCTCTTAGGGATTCCCTTACTGGGCGGTGCGCTAAGAGGTGTGGCTGACAAATACTAACTGTGATAGGAAGGAGCCTCTCGAGACGGACTGAAGGACAGCACGCGCCTCCAGCTTTTGTACGCTGGCGGCGCTTTTACAATACCTGAGAAGGGATTGACCACGTACTCACTTGTGACACAGATGGTTGGCCCGCTGTCTGCAGTATGGGCGAAATCGCTATGATACTTCTCTGTGGAATTGATCCCTCTCGTCGGGCTAGCTGGGTCCTGCTGGTATTGTCTCATGAGTGTTCGTGGATGTTATACAGATTTTCATGTGGACTTTGGTGGCACATCTGTGTGGTACCACATACTAAGGGGAGGCAAGGTGTTTTGGCTAATACCTCCTACAGATCAAAATCTGGAACTCTATGAGAATTGGCTGCTCTCGGGCAAACAAGGTGACGTTTTTCTTGGGGACAGAGCAACAGAGTGTCAGCGAATTGAACTAAAACAAGGCTACACATTTGTTATTCCCTCAGGATGGATTCATGCTGTGTACACACCTCAGGACACACTGGTGTTTGGGGGAAATTTTCTGCACAGCTTCAACATTCCAATGCAACTTCGTATATATAGCATCGAGGACAGGACGAGGGTACCTACAAAATTCCGATATCCTTTTTACTATGAAATGTGTTGGTATGTGCTTGAAAGATATGTCTATTGCATGACTCAACGCTCTCATCTCACAAAGGAGTTCCAAAGGGAGTCTCTGAGTATTGATTTAGAGCTTAACGGTCGCCAGAGACCAGACACTCCATCCTTATCCTCATCCGCTTCATCTGAATTATCGTCTTCCTCTGATAATGATGATTCCTCTGATCAAGATTGGGAGGAAGAAGGAAGTCTTAAGAAGAGGGAAAGAGATAGACTTAGAGTGGAGCATGAACTTCAGAGGAGAAGGAACAGGGATAGGCAACAAAGAGACCAAGAAAGAGATCATCAACATGCTGAGAGAATAATTATCCATACTCTACCTGCGTCACTACGTCCTTTAACTCCACCACCTTCCCTTCCTCTGCCAACACCAGATTCACCTCCCAGCACTTCTCCTTACTTGACATGGTTTGAGATTGAAGGATTACACTGTCTTGTGCTGAAACTTGAATCCTTGCCACCTCATAAAAAGTGCCTACCAGATGGTATCCATGACCCAGAAGCTCTTATCTCTGATATCAAGAGTCTTCTTGAGGACCACTCTCATGATCCACCTGAGCTTGCACTCACTGGCGTTCCAATAGTTCAGTGGCCCAAGAGAAATCAGTATAAGGTCCACCTTCGGCCCAAGATTCAGTTTACAAAACCTCACACTATGCGTCCAGCTTCCCGTCACTCCACAGCTCCTCCTAGGACATTAGGCACTCCATCTGGTACTACAGCTTCTTCGGGTGCTCGAAGGCGTCGTGTCAGGTGTCGCAAATGTCAAGCTTGTGTCCAGCGAGAGTGTGGGACTTGCCACTACTGTAAGGATATGAAGAAGTTTGGAGGGCCAGGCCGTATGAAACAATCTTGTGTACTAAGGCAGTGCCTTGCTCCCAGACTGCCCCATTCTGTAACCTGTGCTTTGTGTGGGGAGGTGGATCAAACAAATGACACACAGGATTTTGAAAGAAAACTCATGGAGTGTTCAGTTTGCAATGAAATTGTTCACCCAGGATGTCTAGAGATGGATGGTGAAGGACTTCTAAGTGATGAACTTCCAAACTACTGGGAGTGCCCCAAATGTTATGAGGGGCAGAAGCACACGATGCAACCAAATCATGATCACATCGAACTGCACAGTAAACGTAAAGCTGCTGACTATGAGAGCAGCCATTTCTACCCTGCCAAAGTTCTGCGGCCTCCACTGGGGCAGAGCCCCCCATCCCCACCTCTTTTGCTCCCACCTTCTCCTTCATCTGCTCCACCTACACCACCCTCTTCGCAGACACAAGTCCCACCTGCAAGCCGAGAAGAGCGAGCAAAGAGGCGCCAACTTACTAGAGAGAAAGAGAACCACCCGACTGGATGTGATCAGTCTGAGGGAGATCGCTTGCGGCTTAGGGGGCCCTACCTCGCGGTCACTCTTCAGCGTTCACCAAAAGAATTAAGCTTCACTTCCATTGTCCCCAAGTTACAAGCCATCACACCAAATCCCCGTCAGCCTATGCATGCAGCTCCACCACAGCATCCTGATGAGGAAGAAGAGGAGGAAGAGACAGAGAACAGTCTCATACTGGGTCAAAGAAAAAACAACATATCAATGCAGAAAGTTGTTTGGCTCTCTGTTTTCCATTACCTCACACATGAAGAGCTTTGCATCTGTATGACAGTGTGCAAATCCTGGTACAAATGGGGCTGTGACAAACGTCTCTGGTCCAAGATTGATGTTAGCCGCTGCAAGTCTCTAGTACCACAGGCTCTCAGTGGCATTAATAAACGTCAACCTGTATATCTTGACTTGAGCTGGACAAATGCATCAAAGAAGCAACTTATATGGCTTATCAACCGGTTGCCAGGTCTGAAGGATTTAATCCTTGCTGGGTGCACTTGGTCTGCTGTCTCTGCCCTTGCTAGCTGCAGATGTCCCCTCCTGCGTACTCTGGACCTGCGCTGGACTGTTGGAATCAAAGATACTCAGATTAGAGAGTTGCTTACACCAGCCTCAGACAAAACAGGACATGACTCTCGCAGCAAGCTACGTCTGCTAACAGATCTGCGCCTTTCTGGCCTTGATATTTCTGATGTTACTTTAAGGTTAATCATGCGCCATTGCCCACTTCTGTCTAAGCTTGACCTCAGCCACTGTCCCCTGCTTTCCGATCAGTCTGTAAACCTCCTTACAGCTGTGGGCTCTTCTACAAGAGGAATACTCACTCACATACACTTAGCAGGTTGTAAAGGGGTGACAGATGAGTCTCTTCTATATCTACGACGTGCCACCAACCTGTCCCTTATTGACTTGCGTGGTTGCAAGCAGGTTACTCGGGGAGCTTGTGAGGGATTTATTTCAGACCTCTCTGTAAGCATCTTGTATTGTCTATCAGATGATAACCTTATCCAGAGGATCACCTAGAGTGGAAGGACCTGTTAATTGTACTGGAAGAGGTTAGAGGAGGAATGTGGAAGAACATAATCTCCCCTGCCTCTCATCTGCTCTCTCCTGCCACTCCATAAGATACAAAGAAGGAGCAATAATTGGAATCTCTGCCTACATCCTCCAGTGAAACCATTGTTTGATCCAAGGAAATGTGCCATTAAAACGTGTATATAACCAACTGTGGTTGGCATAGTGCCCTAATGGTTTATGGGGCCCCTCAACTCATTAGGGCACCCTGCCAACTCTTACTCATTTTTTTGCTTAACTCACTCTATTCTTCAGGCTGGTCAGTGTGCATAGCAAGGGTGAAGGAAGGTTTTGTTTTAAGGGTTTTTTTCTGTTGTTGTTTTGCCTTTTAGGGATTTGAGAGATATGAGAGAGAATGCTCCGCTAAAGTTATATAGGTGTCTGATGAGTTGTGTGTTTAATTATATGTTTGAGAGGGAACAGGCAGGTTTTGTGATAAATAGTTTTTTTTTTTTTTTAATTGGATTGTAGCTGTTTGCCCATTACCTCTCATACAGAGTACAGACATTCATTTACACTTAATAGTACATTTATTTTATGCACCAGTGCAGCCATTTGTGGATATATACATATATAGATATATATTAAATGCCGGTAGGTACACAGAGTGTTATGTATGTCAGTGCCAGTGGCACAATCGGCTGTCCTCGCCTTTGACCTGGCATTAGATTGTATAAAAAAAAGAGCCTGGATAATATTTTTCTCTGTGGAGCGATCTTGCTTTCCCTTTATTTCTTTTGCAATAAAAAAAAGTTTATGATACAA
->KF978784.1 Uncultured bacterium clone 16SOTU48 16S ribosomal RNA gene, partial sequence 
-TCCTACGGGGGGCAGCAGTGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCAACGCCGCGTGCGGGATGAAGGCCTTCGGGTTGTAAACCGCTTTCAGCAGGGAAGAAGCGAAAGTGACGGTACCTGCAGAAGAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCTCGTAGGCGGTTAGTCACGTCGGATGTGAAAACCCGGAGCTTAACTCCGGGCCTGCATTCGATACGGGCTGACTCGAGTGTTGTAGGGGAGACTGGAACTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCGGTGGCGAAGGCGGGTCTCTGGGCAACTACTGACGCTGAGGAGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGGTGGGCGCTAGGTGTGGGGAACATTCCACGTTCTCCGTGCCGCAGCTAACGCATTAAGCGCCCCGCCTGGGGAG
->XR_005054034.1 PREDICTED: Manis javanica uncharacterized LOC118967152 (LOC118967152), ncRNA 
-GGGTTGAAAAAAAATATGAGTGCTCTCTTTTGTGTGCGGACAAACAGCCGAGCGCGGGGAGGTCGGGGCCGGGGTCAGGCGCTCCGGGCTGCAGCTGCCGCCGTGGGGAGGGGGGCCCCGGGCGGCCCCCCGGAGTCGCGGCCACGGCGGCATCAGCCTTCCGGCGGCGCGGGCGGCCACTGTCCTCGCGCGACCCCGGCCTGTCGGGAGCGAGACCCGCTCCGCCCCTGGGGCGCCCAGCCCCGAGCAAGGAAGTCACAGTAAAAGAATCAAAGCTCATGACGCCCATCCAGAGTACTCCTGGTGACACTTCCTGACATAAAGTCATAAATGCAGCTGGAAAGAAAATGTGGAGGACACAGAAAAGTGGAAATGAAAACTGAAAGGCCCCAGCGGGCCCGCCGGCCCCTCTCCAGGGGAGCCCGAGTCCCTGCCAGCAGCAGTGGCCCAGGAGCCTTCAGATTCTGTGCCCTGTCCCTTCGCTGTTACCCACATGTGGACACCAGGAAGTTAGATTCCTAGAAGCATCAATTCCAACCCAACCCATGTATGCATTTTCAGTCTGGCTGGATTTACACTTCCTTCCACAAGGATGAGGTTCGTCTCCACAGCCCCTGCCAGCCCTGGGCATCACCACGTCTGGGTAGTTTCCATGCGAGGCACGTGCTCAGGGACAGCCTTGTGAGGCCCCACAGGCCACAGTGATGAGGCAGAGAGGCAGAGATGAGAAGTGGGCTCAGGGACTCTCTGGGACCTGGGAGGATGGGCCAGAGCCACAGCCCATGGCCACACCCTCAGGGCCTGGCAGGCCCACCCTGCATTCACCTCCCATGACATCTTACAGAGTGAAGGGCCTGCCTTTGGGCCAAAAAAGGTGACTGGGATGTTACGGGCCAGCTTGCTCCAGGCCGTTTGTGAGACAGCCCTCTGCAGGGGCTGCGGCTGAGACACCTGCCCCGGGGCACTTAACCATCCACCTGCCTCTGCTGTGGTCTCCTTGGCAGATTCAGCTCTGCCCTCAGAGAGCTGGCGACTTGTGGAAACAGTCAGATGCCATTCTGAGCCAAGCCCAGCGGGGCTGCTGCCGGGAGAGACCCAGGCCACTCGGGCAAGAGACCTCCAAACAGTGAAGCCCATGTGCCCCAAACCACCACTGCTTGGATAAAGTTCTGAGAGAGAGGGTGCAAACTTGTTTCCATGGGTGGTGGTGTCGCCAGGTCAGGAGGCAGCCTCCAAGGTGACAAGGGAACTCACAGGGAGAGAGTGAGTTCAGCACGTCAGTTAAAATCTCCATTTGCTGGGCCCATCACCTGCCTCCACGGGGGTCGGGCACCGTCTGCTGAGCTTGGCCACACAGTGCTCTTCCCCCGGCCGCCGCCTCGCCCCCCAGGCCCCCCGGAGCCCCTTGCTCCTCCCACAGCCTACTGAGCTTCCATCTCATTGTGCAGCCACTTCTTGTCACCTTGACCACCCTCCCCATCCCAACACCCAGTCCCTGGAGGCCAAAGATCATGTCTTTCCCCAGCTGTGTCTCCACAGCTCAAAACAGCACATGCTGCATGGTAGGGATGTGGTACATCAGGGGTGGAAGAAGAGAGGCCCTGGGGCAGGGCATCCAGAGACCTGGGACTGGGTCCTGGGCTGGCCGCTGGCACCGGGATCTTGTTCCTCAGTTTCTTCATCTGGGCGAAGGGTAGTTGGGATAACAGGTGCCAGAGGCCTTTCCAATTCCATTGTGTGAGGGCTCTTCAGGCCAGGGCTTGATGGGAGAGGCCAGGGCAAGCTGAGGCGGCCCCACCTCTGCCCCGTGCGTGATGAGGGGCAGCCTCCTCCACGGCCTCCCTCTGTGTGCTCAGTGCCTCCAGGCCAGCTCCAGGCCCGTCGGCATCCCAGGAAGGCAGCAGAGGTGGACGGAGGGCACGAAAGGACACGCTTTCACTGACCACCCAGCCCAGCAAAGCTAGAATCTGTCAAAAAGTAAAAATTCCATTTGTAAACAAGATCAAATTATTTGATTGTGAAACCAGGGTCCATGGAATTTAAAACAATTTAATGTGAAACAATATAATTTGAAATGCTGACCAGCCAAGACCTGGGGGTGGAGGGGCTCAGCCTCCTGTGGCCAGACACATGGAACCCAGCCTCAAGGAATAATAAGTCACTGTTCGACAAGGGTGAATGGGCATCAGCTGCGTGGCAACCCCAGGCCAGACCTGGGGCAGCAGGCCCGGCTCCCGTCCTCCTGGGGCTGGCAGTCCTGATGGGCAAGCAGGACTCTCACAATCAGAAAAGCAGTGCCAGAGAGCGGGAAGGGCTCCGTGGAGTGGCATATGATCCAAGTGACAAGGGAGGCTCAGAGAGAGCCCCGAGGGGCACCCGGTGGGCAGGACAGCAGAGAAGCATATTCAGGGTGGAAAGGGCGGTCAGGTCCCTCCCAGCTGCGGGTGTGCTGCCCTGCGTGATTCTGGGCCAGCAAATCACTCGTTAGCCTCAGTGTTGTTATCCACAGAATGGGAAACATCTCAGTCCCGCTCCCCACCTGCAGTGAGGATGAGAAATCGTTTCCGGGCATCCCACCCCACCAAGCTGACGTCACCAGTGGACAAACAAGCAAGCATGAGTGATGCAGTGGCCTGGTGAGCAGCTGCTGCGGGCATGTGGCAGGCAGGTGCCCGGAGGCGCTGCAGTGCGTTCTGTGTCCAGCACCTGCGGGTGCTTTCCAGAGGGACGGCGGAGGCAGGGCCCGGCAGGTCCTGGTGCAGCAGAGCTCTGCTTCCACGTACCCTGCCTCAACGTAAACACAGCTGGTAATGTTTCAGTACTGTAGGAGCAGGAATAACAGACCCAGAGAAGCCAGACCAAGAGCTCGCGAATGCTGACTTTCATGTCGCACCCAGGCATCGCATGTGCATCTTGGCGCCTGCGGGCCTGTTGCTCGGTGGGGAGGTGGGGGGCTAGTGTGTTTAGGAAACCGAACTACGGGCACAGCAGCGGGAGGATGTCAGGCCTCACCTCCCTTCATCCTCCCAAACGCAGCTCCCACCACAGCAAACCTGGAGGCTACCTGGGATGTGGGGGGGCACCAGGGCCTCTAGGTTTTAAGTGACCTAGGAGACAGTGGGGCAGGGTGGGGACTTCTCATCAGTGAGGTGCCACCTTAGGCACATCCCCTAACCTCTGCATGCAAACAGGCCCTGGAATACACCCAAGGTCAACTGGCCAGTGAGAAGCTGACCTAGAACTCAAGCCAGGCCCCAGTCTCCCCATGTCCCTGCTGCCCGCTGCGGAACCTGACCCACTGCCAGACCCGAACCTGCAAACCAACCACCTGTGGGTTCTGGGTAGCACAGAGCCCTTGGAGACCGTGATGCTGAGAAGCAGTGTTTTTGTTCGCCCCTGAGTCTTGCCAGGTCACATTGTCAAGGCCAGCACTTTGGAGA
->XM_053291376.1 PREDICTED: Hemicordylus capensis complement C4-like (LOC128343033), transcript variant X1, mRNA 
-GAGAAGGCATCTGCCCTGCACAGACGCAGCCCAGAGATGTTCTCTCAAAAGCTGCTGCTGCTCTGGCTAGCATGGATGGGGACTCTGGTAGCCCTGAGCCACCAAACTCCAAGGTTGCTAATGGTTGCCCCAAGTGTGATACCAGTGGGGGCCGAGGTGGGGATCGTGCTTCAGGTCGAGGGGGCCACATCCAGGTTCTCAGGCACAATCTATTTCCAGAATGAGAATAACATGAAAAAATGTTCCAATGAGGAGTCATTCAACTTTTTGCCCAACACCTTTGTGCAAAAGGTTACTCTGAAGGTGACCCACGAACTCTTTACCGAATGTGTTCTGGCTCGCCAGCGACGGAACCGCTACATCCAACTTGTTGCCCGCAACTCCCTGCTCCCCAATGGCGGCGTTCAAACCCTCAACCTGCGCTGGAGTGCCCGGCAAGGGTACCTGCTGGTGCAGACGGACAAGCCAATTTACACCCCACAGCAAAAGGTGAATTTCCGAGTCTTTGCCCTGGATCACAAATTGCGGCCAAGCACTGAGCCAGTTGTCATCACTGTGCAGAACTCACGAGGTCTTCAGATCCGGAAAGTTGAGCGTGTGCCAGTGAATTTTGTGATAAACGATCACCTGTCTATCCCTGATATCTCTGAGCCAGGCATTTGGCGTATCACAGCCCAGTTTGTCAACACACTGAATTTCAACACAACAACAGAGTTCGAGGTGAAAAAATATGTGCTCCCTCATTTTGATGTGACAATTGTTCCAGAACGTAAATACATCCTCCTTTCAGGACAGCAGGACTCTGAATTGCGAATTGACCTCCAGGCTAAATTTTTCTATGGGAAGGGGGTCAATGGCACAGCCTACGTGCGGTTTGGTGTGAGTGATGACAATAAGGAGAAAGTTTATATCCCAGGACTCGAGCAACAAGTCTCCATAACCGATGGCCGTGGCTCACTAATGCTGAAACGCAGCCTCCTCGCAGAGAAACTGGGGCGCCCTCTGGAGAACCTAATTGGAACAGCACTCTACATTGCAGCCACTGTCATAGAGGCAGCAAGTGGCGAGCTGGAGGAGCAGGAGCTTGCTTCAGTGAAATTTTTGGCATCTCCATATTCAGTTGATCTGTCCAAAACCAAGCGCCATTTTGTCCCTGGTGCACCCTTTGAAGTGCTGGCTACTGTTTCACTCTCAGATGGCACTCCTGCCTCCAACCTCCCAGTCCGTTTCTCAACCCAGATAAGAGGGGGCTCATCCCCCAATGATGAGCGAGTGGACAGCAGTGAGCAAGGGGCTGTGATATACAGGATGAATGTTCCCTCTGGAGCTACCTCCATCACTTTCACGATAACAGCAGGGACAGAGTCTCCAACAGAAGTCACTCTGACTGCCAAAGCAATGAACTCTCCAAGAGGCAACTACTTGATCATTGAAAGCCCAAAATACCAAGGCTTGAACCCCGGAGAAACTCTCTCGCTGGGGCTGAAACACGTTGGATCGGCTGCCTTCTCCCACTTCTACTACCTGGTTTTGAACAAAGGCGACATTGTCTCTGCCAACAGTATCAACCGTGGAACCTTTACGGTCATCTCTATCCCCATCACACCCAGCCTGATGCCAACGTTCCGCTTTGTGGCCTTCTACCGTGTTGGGGATGAAGTTGTGGCAAACTCCATCTGGGTTGACGTCGTGGACCGCTGTGACGGAAGACTGGAGCTCCGCACATTAGGAAACCCTGACCAGCTGCAACCTCAGGACCTCCTGAAACTCGCCATAACCACTGATGTGAAATCCTTTGTGTCGCTTGCTGCTGTTGATACTGCGGTTTACGCCCTCAACCGGAAGAATCGCCTCACACAGGGCAAGGTTTTCCAGGCTATGGGAAGCTATGACCTTGGCTGCACAGCTGGCAGTGGGGAAGATACCCTTGGCGTTTTCACTGATGCTGGACTCTCTCTGCGTACTGGTTCTCTACAGAGTGAGCTCCGGAAAGCACATGGGTGCAGTGAGAGTGTTTCCCGGAAGAAGCGTTCGCCGCAGTTCCAGTTCCAACTCCAAAGCATGCGTTCCAAGTACTCAACCCCTGAATCGCGGAAATGCTGCCAGGATGGCATGGTGCTCCTTCGAAGAGCCATAACATGTGAGGACCGTGCCAGGCGGATATCAACGCGAGAGTCTGAGGAATGTCATCGTGCCTTCCTTGAATGCTGCAAATATGCTGCCCGTCTACGACGCAAATCCTGGGGATCCCACAATCTTGGGCGAACTCTAGATGAGGAAGATGAGGATTTCATTGATGACGATTCCATTCAACTCCGGAGCGTCTTCCCTGAGAGCTGGCTCTGGAAAACTTTCTCCGTAGAAGGAACCCGCACGGAAAACTTGATTCTCCCCGATTCCATCACCACCTGGGAGATCCAGGCTGTTAGCATGTCCTCTGCAAAAGGGATCTGCGTCTCAGAACCTCTTCGAGTTAGAGTCTTCCAAGATTTCCACATCTCTCTCAGGCTGCCGTACTCAGTGAAACGGTTCGAACAGATAGAGCTTCGCCCTGTTCTGTACAACTACCATTCACAACCAGTCAGTGCCTTGGTGTATCTGGAGCCTGCTGAGGGCATCTGCTCTCCAGCAACCGTCGGCCCGGCTCGGAAGCAGAGGGTTGTTGTGCCTGGGAATTCAGCGGTGCCCCTGCCCTTTGTTTTGGTTCCCATGGGAGCAAACGACATTCCCATCACCGTTGTTGCCATTGGCGGCTGGGGGGTGGGCGACAAAGTTTCCAAGAACCTACGGATTGAGAGAGAGGGTGCTGTTCGGGTGGAAGAATACACCATCCCCATATCAAGTGAAGCTGGACAATCCAGATCTGTGGAGATTTTAGGAGATATACCCTCCAACTCCATTCCTGATGGCGACTTCAAGATGAGTGTCCGGTTGACAGGATCGCTGCCAGCTGACACTCTGGAGAGTTCTCTGACACCAGAAGGTCTGTCAACTCTCTTGCGGGTTCCACATGGATGTGGGGAGCAAACCATGTTATTGATGGCCCCTGGGGTCTATGCCATGCGCTACCTGGACAGCACTGAGCAGTGGCTACACCTGAAACCGGAGAGCAAGGAGAAGGCACTGGATAACCTCCGTACAGGCTATGAGCGAATCCTCACTTTTCGGAAGCGTGATGGGTCGTATGGAGCTTGGCTCACCCACCCTAGCAGTACTTGGCTGACGGCTTTTGTGGTGAAAGTTTTATCTCTGGCCCGTGAGTACCAGGGTGTGGATGAGACTAAGGTCCGTGAGTCAGTGCAGTGGCTTCTGGCAAAGCAACAGTCAGATGGTTCCTTCCAAGACCCAGCCCCTGTCTATCACCGGGAAATGCAGGGTGGTGTTGGCGGCCTTCACGCAGGAGTCTCACTCACAGCGTTTGTCACCATCGCACTTCAAGAGGCCTTGGTCATGTATGAAGGAGAGAACCTTGAACCAGAGAAGCAGCAACAGCTGAGCCAAGTGAAACACCGCCTGGCTCAGGCTACCTCCTTCCTTGCCCTCTCCTTGGAAGAGCGATCTCTGGGTGCCTATCCTGTCGCCATTGCTGCTTACGCCCTCTCGATTGCTTCTGCCAACCTGTCGGCCATCACTACTGCTGATTCTCACCTGAGGAGGCTGGCTACAGAGGACAAAAACAACACGATGTTTTGGGCGGTGGAAGAGCGGGACCGACTGAGAGGGGAGAAGAGATCTGGGCAGGTTCCCTCTGCCTCAGCCATCTCGGTGGAGGCCACAAGCTACGCTCTCCTCTACTTGGTGAAAAAAAAGGACATCACAATGGCCCACAAGGTTTATAAGTGGCTGACAGAACAGAGGAACTATGGAGGAGGCTTCAAATCCACCCAGGACACAGTGGTGGCCCTGGAAGCTCTGTCGCAGTACTGGATCAGCACCTACCAGGAGGAAGACAATGAACTGAAAGTGACCCTCAGCGTTGCTGGGAAAAGCTGGCCGATCTCCCTCTCACCTGGGAGATCAAACCATCCAGTCCAGGAAGAACTGCAGTTTTCTTTGGGGAGTAACATCAATGTAAAGGTGGAGGGGAAAGGAAAAGGGACTTTGACAGTCCTGAAGCAATATCTGGTCTTGGCTATGCAAAACACTACCTGCCAAACCCTTGGGTTAGAGGTGAAGGTGAGCGGCTCCATTCAGCGTTCACGTGAAATGCTTGACTACTACTACGAATATGAAGATGAGGATGAGGTTGAGGTTGCCGGTGAAAGAAAGGCACGGTCTCTACCTGCTGACCAGCCATTGTCTCCTATCCACTTGTTTGATGCCCGGCAACGCCGCAGGAGGGAAGTCAAAGCCCCCGGCCAGCCGCAACGGGTTGTCACCTATGAAGTCTGTTTTTGGAGGCAACCTGGAGCACATGTCTCAGGCATGGTCATCGTTGACATCACTATGCTTAGCGGCTTCCAACCCGACAAGGACGACCTTGACAAGCTCAAAGATCTTGCTGATAAGTACATCAGCCACTGGGAGCTCCAAGGACCACGGCTGTTGCTGTACATTGACTCGGTTCCAGCAACAGAACGTGAATGTATAGAATTTGCAGCAAAGCAGTTAGTAGCTGTGGGGAAACTCCAGCCAGCAAGTGCCACTCTGTATGACTTCTATGAACCAGACAAGCGCTGCAGCATCTTCTACGGTGCCCCCAACAAGGACCAGTATGTGTCAGCCTTGTGCTCGGATGATGTCTGCCAATGCGCTGAAGGGGCCTGCCCACGGTTGAAGCGTACCCTGGATGAGGCCATTACAGAAGAAGACCGCATGCAGTTTGCGTGTTACGAACCTCGTGTGCACTATGCATTCCAGGTTCGAGTGGAACGTGAGAGCAAAGAAAGTGCCTTTCGTGTCTACGAAGCTACGATCTTGGAACCCTTGCAATTTACTGCAGACATTGGCATCTCCCAGAACCAGACCCGGCGCTTTGTGGTCCGTGCAGCGTGCCGGACCCGCTTGGCCGCAGGCAGCAAATATCTGCTGATGGGACGTGATGGAGAAACCCGTGACTCTGAAGACCGCCCCCAGTATCTGCTGGATAGGAACTCTTGGGTGGAGGAAATACCAAAGGCCCAGCGCTGCCGAGCCACCCAGCACCGTAACACCTGCCTCCAGTTCAAGTCTTTCACCACTGCTTTTGCTGAGAATGGCTGCCGTGTCTGAGCCAGAGAACTGGACCAGAATGATCACCTGCACTTTCTCCCATCTTCCTGCACCAGAAGGTTCTCTCGGAATGGAATGGAAGATGCCAAAAGGCCTATTCTCTGATCACTGTCTTTTCCCCTTGATGCTTTGTATTTGGACAATTTAAGAATGTAAGAAGAGCCCTGCTTGCTCAAGCCAAAGGCCCATCTGGTCCAGTATTCAGATTCCAACAGGGGCTACCCAGAAGCCTCTTCCACAAGCCCTTCCCTGTTTTTTGTCCCCAGTCCATGGTACTCAGGCTTATTTTAAGCCAAATTTTGGGTTACAGCCCATTTGACCCACGAGTATACCCCCTAGGTTCTGGCATCACTTGGTGATCGTCATTGATGGACCTATCTTCCATGGACAGGTCTAGAAAGTCTACAAGCCTGGTCTTTCAGCCATCTCTCTGGGCACACTAACCAGAGGGAAATTGTGATTCAGAGGTTCTTAAACTCGAGTCCCCAGCTGTTGTTGGACTACAACTTCCATTATCCCCCTCTTATAAGGACAATATTGGACAATATTGTCCCCTTGTTAAGTCTCTTTTTTGTAATTCCTGCACATTGGCTACTATGTTGCAACTACCATTTTTTAGTGCCACTTGGGTTCTCTGATACTTTTTCTTTGTACTGGTCCCCAAAAATGCACATCTTTAAAACTGCATATGATCATAGCAACAGACAAATGCATGACCACAGCCATATTCACACTTTAAACAACAACTTTGGTCTATGAATAAGGACTGTTTGGCTGTGATAATGATCACACTTCAGTGAGCAGCTTTAGCATAATTCTGTAAAGATTTTTTTTTAATGAGGTGTTTGTTTTGTGCCTCTGTCACTAGCTAACATGCCTCACAAAGCTATTTTGTTGAATAAAGAGTATCATTCTATA
->XM_022636737.1 Penicillium arizonense hypothetical protein (PENARI_c034G09255), partial mRNA 
-ATGAACCCAACCCCCATCAGCATGTCAGTCCGTACAGCGATAACCTTCAGCCGACTGAACCCCGCGGCGCCCTCGCTCGCCGGCGCCCTCCGTCCGCTCAACCAACGCACCTCCGGAACAGTCTCCAAGCAGCTCACACGCCTCAGCTCGACAACAGCTCGCCCAGCCATGGCGGCACCCGTGACCCTGGACACCCGCCCACAGACCCAGACCATCTCCACCCGCCCCATTGGCCTGCGCGCACAGTCGACTGCTTCTGGTAACGGTACCGGCAACGAGGAAGTCAAGCTCGACTGGGACTCCTTCTTCAAGCTCCGCGCTTCCCGTCGCCGTTATTCTCTTGCTTCATCCATTACCACTGCGGCTCTTTCGACTACGGCTGGTGTGCAGATTCTGTCCGCTCAGGATTTGGAGTCCCTTGGCGCGCAGGTTATGGGCCTGGACCCATTCGTTGTTCTCGGATTGGCGACCGCTGCGTGTGGTGCTATTGGATGGTTGCTTGGGCCGATGGTTGGAAACGGTCTCTGGGGATTGGTATACAGGAAATATAAGCCTTCCGTTGCGACGAAAGAGAAAGAGTTCTTCGATCGCATTCGTCGCTTCCGTGTTGACCCATCGACCAACTCGATTGCCAACCCCGTTCCCGATTACTACGGCGAGAAGATTGGTAGTGTGCAGGGATACCGACAGTGGCTGAAGGACCAACGGGCTTACAACCGCAAGCGCCGCAACTTCATTGCTTGA
->XM_039112273.1 PREDICTED: Rattus norvegicus zinc finger and BTB domain containing 1 (Zbtb1), transcript variant X5, mRNA 
-TCTGGGGTATAGGGTATTTGTATTTGTGTTCGATCATGTTCCTAAATCGAGTGTCGCTGTGACGGTACACGTAGATTCTCCACTGGTTAGAATGTATTTCCGTACAGTATCTATCGCTGCGGCAACATTTTCCCCTTTGACACTGGAATCCACGAAGCGTTCCAAGCATTTTTTTTCCCCTTTTTTGAGACAAGGTCTGACTAGATAGCCCAAGATCGTTTGGATAGAATTCTCCTGCCTCAGGAAATCCTAAATTCTGGGGTGATAGGCATGTTCTGAGACTTTCCAAGACCACTTAGAATTAATTTCTTGAGCCAAAGTTTGAGGCACCACCAAGTCAATTGGTGAGAACGATGTAGTTCTTATGAGAACTTTAAAGCAACCACGGTTTTTTAAAAGGTATAAACTAGATTTTCTGGAATTTTGTCACTTTAAATGGGGAGAATGAAGGTACAAGAGACTGAAGTCCCAGTGATGGATGGCTGGTCATTTGCCCAGAACTGTAAAACTTCCCTTTTGAATCACTGGCTGTTGTTATCTCCCTAAGTCTCAGTAATATTGAGTGGCAGCCACATGGGCTTTCTTCCTCTTAAAGAAATAGACAGACTTAAAGTAGACACGAAGTGAAATGCCTTTCCAAAGGTTAATACTTAGAGTTTTGTAGTGTAATGTTGTGTTATAGCCACTTGCACTCATTTTAACGCCAGGATTTCTTCTCGGACAGCAGAGTTTTACAGGGTGTGGTTGTGCACGCCTGTGATCCCAGCACTTCAAGAGGTTGGATCAGAAGCCTGAGGCCAGCCTGGATCTGGCATACAGAGCAAGACCCTTTACAAAGCTCAGGGCTGGAGAGATGGCTCAATGGTTAAGGGCACTTGCCTTTCTTCCAGAGGGACTAAGTTTGACTCCCAGCACCCCCACACCAGGCAGCTCACAACTACCTGTAACTTCATTTCCAGGGAACTCCACACTCTTCTTCTGGACTCTAGGACATCTGTATTCATGTGCGCACCCCTCCCCCCCCCACTACACATAATCAGAAATTAACATGAAAAACCCCAAAGCCTCATTTTCATGATTCGGAGTAAACCCTGGTTGAGCAGTCCTTCCAGCTGGCTGTGTTCTTCCAGTTCCTAACGTTATGCCTGCTGGTTTCACCACTGTGGCTGCATCCTTGTGAGGAAAGAGAAGCCACTTTTGACCAGGGCATGAGCACAGCTTCCTCACCTTGTTATGTTGGTTTTTGGTGTTTTGAGACAAGTGTTTCTCAGTGTATCCCTGGCTGTCCTGGAACTCACTCAAGACCAGGCTGACCTCAAAGGCTGAAGAAATCCACCTGCCTCTGCCTCCTGGGTGTCAGGATTGAAAGTGTGGACCACTGAAACTGCTGTTTTATGTTTTGTTTTGTTTTGTTTTTTAAAGCTAGGTTCTCACTGTTTGGTCCATGGCCAGCCATAGCTTTCCGTCCTCTGGCTTCGACCTCTCACCTAGTGGTGGGATAACAGGTCTGCACCGCCATACAGGATTCTGACATGGGTTTTTTGTCTTTGTGAAGCAGGGTCTCACTGTGCAGCCCTGGATGACCTCAGACTCTAAGAGATAGGCCTGCCTCTGCACCCACAGTGCTAGCATCAAAGACTCGTGCTGCTACGCCTGCTCATGACCTTGTGTTTTTATTTCATGATAGCTGCCAACTGTTTGTACCTTCTGCTTCCTCATTCCTCCACATTCCCCCACTTTTGTCAGTTTCTGGTACAGTTAGGGCCTTTTCAAAGTGCCCAGTGTCCCTTGCAACACCATTCAGGAGAAAATGTTGCTGCTTTTTTTTTTTTTTAAAGGCCTATTTTTCTCTATACAGGACACAGACTGTCTAGAGAAAAGAGGGGAAAAAAAAACCTTTGTGTTAGAATACAGAAAAAAATAGAGGCTGCAGTCTGATGTCTCGGAGGAGGGTTAAATGTGTAAAACATCTGCTTGACGTTCACTTAGGTCTCTGTAATATTTTTCATAGTTTCTTGTGTTATAAAATAATGAAAATGCTTTGCTATTCATGTTTTTATGTTAGCCTAATTAAGTTATTTATGCCTATTTTTTCTCAAAGTGGAATACCTTTTCAATGATAAAAGCAGATGCCCTTTATAAAAGTTCCAACTATACTAAAGTACATAAAATACAAAACTGAAAGTCGCTCTGACTCCCACTCCCCAGAGATAATCACTGTGAACAATCAATCCCTTGTTTAAAAACATGAAGGCAGCATCAGAGCGTCTTGCTGTGTGTGCCTCACCCCAGCCTGTTCCTGTTCACAGGCTGGTGCTTTCTGCTCCTACCTCAGATTGTTGAGAATTCCCAGGTTGAGGCGGGTGGGGGGTTGCATTGAGCTGATGTCAAATTCTATAACCTAGTGACGTGTGAAAGTTTTCATGTTTAATAGGGCTGCTGTTTTAGGTTAGTCCTCGTTCATTCTCCTTGGTGGGCTTCTTCTCACCCTTAGCAAATGTTGCAATCTGTTATCTGATTGATTTGTGCAGACTACACTCGTTAAAACAAACCCTTCGAGTGGAGAGAGCTTCTTAGCTTATCATTGGGAATGAGTAGGGACACTTGCCACAAAGACCACCGCCAAGATATCCCTGTGCCTTTTGTGATGGTGTGGGTTCCTCATGGTCAGCATCCAAGAAAATCGTGATAGAAAGGAAATTAGAGTAACGGTGGGCATTAATTACTGTTGTTTTAAGTTATGGGAAGGAATGGGAGGGGGTGTGTGCAAAGACTAGCCTGAATTCTACCCACATTAGACATCTTACATATTTAAGGTAATTTCTAAGTATACTGATATTTTGTCCTGCATAGTCATTACAAAGCTACTTAGGCCGGTGTGTTCAAGAAGGATGAGCTGTGGGGTTGATTTCCTAGTAAAGCTCCAAAATAGCAGGCTCAGATTTAATCACAGTAATTCCTGGAAGGTGTTGAGGACATGCTGCTTTTTTGAGAAGGGGGTCTCTGTAGCATTGGCTGTCCTGGAACTCACAGAGATCCATCTGTCACCAACTGCTTTTTTTGGGGGGGGAGTGGGGTGGTAAAAACACTACTATGTGAATATACATTGTTTTCAGAATCACATCTGAAGGCATGGAGGTGTATAACCTAGTATAAGAGTGCTTGCCTATCACACCTGAGGCCCTAGGTTCAGTCCCCAGCACTACAAAATAATGAGTATTAAAACATAAAGAATAGCAGTGTGTAGGGTGCATGACTTTAATCCCAGCATTTGGAAGGTAGAGGCAAGTAGATTTCTGTGGGTTCAAGGCCAGCTTAGTATACATAGTTCCAGCCAGCTACATAGTGAGACCCTGTCACCAAAAATAAATAAATAAATAAATAAATAAATAAATAAAATAAAAAATAAAAAATAATAAATTGCTAATTATATTTTCTATTAGTTTGTTCTGTGAGGTGCATGTTGTCTTTTTAAAAGCTAACTCCTTCCCACTTGAAATTGACAGCAGTGGGGGTGGCCATGGTGGTCAGCAGATGGAAAAGGAGGTGGGGAGAGGGGTGCGTTCTGCTTGCCTATTAGATAAGACAGCAAGAATGATAGGAGCTTTTACAGCGATGGAAAATGTGACTGTGGGAGGCTTAGAATGTTCCAGAGGGGCACTTCACTTAATAATCATACCCAGAAAGTGTTGTCTGGATTACAGAAACTGAAACTGTGCATCTTGAATCAAGAGTTAGGGTTTCAGCCCCAGCTTCTGTTTACAAGATGGGTAGTTAACTACTGCACGTGTTTTCTTCATTCACAAAAAACATAGATAATTAAAGGCCTGTCTCAGTGCACTGATGTGTGAAAGAGGCCCTATAAATCGACAACAGTGTTTCAGTGACGGCCATAAGTAAGAACTGATGAGCAAAACAAGACTTGCCCAGTTCAGCATTTGTTCCTGGAAAAACTCGTTATCATTTAAATGCCAAGCAACTACTAGAATCCAGGGTTGTAATGATGCCTGACACAACACCTTCGTCTTGAGGTACATACAGCCTCCAGTTTAGATGGCCCATCTCCTGTCTCCCTGCGGCTCCCACCATAAAGAGGTGCCTGCCTCATGCTAAGTCAGGAAAGGGTCCCCAAAGATGGCTCTAAGCAAAGGAATGGTGTTTATGAAGTAAGGAAGACTTCCACTTTTCCCGTGTTTGGGGATGGGGGAAGTCTTAAGAGATGTAAGGCTTAGGGATGGAATTGTGTTTAGAATGGATCTTTTTTACTGGTACTTTTAATTGGTTTTATTTCATTTATTTTAATTAGATAAAATTTTGGAGTTTGAATAGCTGTGATAGCTTCCAGCACTCAAGGCAGAGGCAGGCTGACCTCTAGAGGCCAGCCTAATATAGGGAGAGACCCTTTCTCCAAAAAGAAAAGAAGTTTTCTCAGCCTTGGTTAGAACTGACAGGAAGCCCTGGAGCTGCAGAGCTGGAAACGGATACTTCATTCAGCTTACAGGCTCTGCGAGCAGAGGAAGCAAATAATCACGGGGGGAGCTCCCTGGCAGGCCACACAGCAGATTTTACTGAACACTTAAGTTCTAAAACGGCCTGCCTTCAAGTTGTTAACAGTTGTAGCAGACAGTGTGAGCTCACAGAGCCAATACTTTGGAATAAGTAAAAATACTACAAAATAGGGTGGAGGGATGGCTCAGCGGTTAAGAGCACCCGACTGCTCTTCCAGAGGTCATGAGTTCAATTCCCAGCAACCACATGGTGGCTCACAACCATCTGTAAAGAGATCCAATGCCCTCTTCTGGTGTATCAGAAGACAGCTACAGTGTACTTAAATATAATAAATAAATCTTTAAAAAAAAATACTACAAAATAAACTCCAGCAATACAGATGCCATGTGCTGGGAACCAACTTGGTGTAGCTGCTTTTAAAGGTCACAGGTGCACACACCGCCCTCTGGTGTTCAGAACATGGCTGTACAGCCTCTAGTTTAGAGGGTTAAAAATGGATGTGTAAAATACCTTTCCTCTTATACCAGAGAGAAAGCAGAGGCCAGCACTCCATTCTCTTCCCTCTGCCTTCTGTGTGGATGGACTCCATGTGGAGTCCAGTTGAACTACAGAAATGGCTCGTTCCTGTTACTTGGTAACATTTATTATCCGCTGACCTGCCATGAAGCCAAAAGATAATTTGGTTACCTTCTACATAGTACAAAACAAAGGACCTCAAAGAAGTAAATTATGTACTTGTTTCACGGCCTATAGGAGATTAAAATGGTGGACAGCAGATCAGCGTGCCTTTTAGAAGTGACAACTGTTGGCTTGACGAGGGGAAGAACAGAAACAGACAGGCCAAAGAGCAGCAGTCTCGTTTTGAATAGGTGCAAACAGGCTCACCGGCAGGAGATGGCCAAGCCCAGCCACAGCAGCTACGTCCTGCAGCAGCTAAACAACCAGAGAGAGTGGGGCTTTCTGTGCGACTGCTGCATCGCCATTGACGACACTTACTTCCAAGCACACAAGGCCGTGCTAGCTGCCTGTAGCTCCTACTTCAGGATGTTCTTCATGAACCATCAGCATAGCACTGCCCAGCTGAACCTCAGCAACATGAAGATCAGCGCCGAGTGCTTCGATCTCATTTTGCAGTTCATGTATTTAGGGAAGATTCTGACCGCTCCTTCCAGTTTTGAGCAGTTCAAAGTGGCTATGAACTACCTCCAGCTCTACAATGTTCCTGACTGCTTAGAAGATATACAGGACTCAGACTGTTCCAGCTCGAAGTGCTCGTCTTCCGCCTCCAGCAAACACAACAGCAAGATGATCTTTGGGGTGAGGATGTATGAAGACACAGTGGCTAGAAACGGCAGTGAAGCCAACCGGTGGAGTGCGGAGCCCAGTTCAACGGTGAATACGCCACATAACAGAGAGCCTGAGGAGGAGTCTTTACCGTTGGCCAACTTTCCTGAGCCACTGTTTGACGTGTGTAAAAAAAGTTCCGTGTCCAAGTTATCTACTCCAAAAGAACGTGTGTCGCGACGCTTTGGACGGAGTTTTACCTGTGACAGTTGTGGGTTTGGCTTTAGCTGTGAAAAGCTGCTGGACGAACACGTGCTGACCTGCACCAACAGGCACTCCTACCAGAGCACGGCGAGAGCCTACCACCGAGTGGTGGATGCTAGAGATGGGAAAGACAGTGCCATCAAAGCTGAACTCGGTGACAAGGGCTCTCCTACAGCGTTTTCTGCACACACAGACAAATACAGAGAAGACGCCAGCCAGGCGCCCGATGACTCAGCCTCGCCCACTGGGAGCAGAAAAAGCACTGTGGAGTCCGGCACAGCTGGTGAAGAGAAGAGCAGAGCTGCGGAGACAAAAAGAGTTGTCATCAAGATGGAGCCAGAGGACGTCCCTGCAGACGACATGAAGGACTTCACCATCGTCAAGGTCACCGAGAAAGACTGCAACGAGTCCACCGACAACGATGAGCTAGAGGACGAGCCCGAGGAGCCGTTCTACAGATACTACGTCGAGGAAGATGTTGGCATTAAAAAAAGTGGTAGGAAAACCCTAAAACCTCGGATGTCCGTCGGCGTGGATGAAAGGGGTGGTTTGGAGAACATGAGACCCCCAAACAACAGCAGCCCCAGACAGGAGGACGCCGAGAATGCGTCTTGTGAGTTGTGTGGGCTCACGATAACGGAGGAGGACCTGTCCTCTCATTACTTAGCCAAGCACATTGAAAATATCTGCGCATGTGGTAAATGTGGGCAGATACTTGTCAAGGGCAGACAGCTTCAGGAACACGCTCAGAGGTGTGGCGAACCTCAGGACCTGACGATGAACGGGCTGGGGAACACTGACGAGAAGATGGACATGGAAGAGAACCCAGATGAGCAGTCTGAGATAAGAGACATGTTTGTTGAGATGCTGGATGATTTCAGAGACAATCATTACCAAATAAACAGTATCCAGAAAAAACAGTTATTTAAACATTCTGCCTGTCCTTTTCGATGTCCTAATTGTGGCCAGCGTTTTGAAACTGAAAATCTAGTGGTGGAGCATATGTCTAGCTGCCTAGACCAAGACATGTTTAAGGGCGCCGTCATGGAGGAGAATGAACGAGATCACAGACGGAAACATTTCTGTAACCTGTGTGGAAAAGGCTTCTATCAGCGCTGTCATTTGAGAGAGCACTATACTGTTCATACTAAAGAAAAGCAGTTTGTTTGTCAGACATGTGGGAAGCAGTTTTTAAGAGAGCGCCAGTTGCGTCTGCACAATGATATGCACAAAGGCATGGCCAGTCTCTGGCTCATACTGGCCTGGAACTCACTATGCAGTGATCATCCCGCCTCTTGGTCCCGACTGTGGAGATTAGGTATGTGCCACCACTCCCACCTGGGCTGAGCTTTTAATGTGTTCTGAATTATAATTATCAAAAGAAAAAGAGCCTGTTTTAAAACATAATACACAGGAAACATAAAAGGTATTGACACAATGAGTATGTGTTTTTTTGTGTGTGTGTGTGTGTGTGTTTTTTTTTTTTTTTTTTGTTCTTTTTTT
->OL802220.1 Portunus trituberculatus vitellogenin receptor mRNA, partial cds 
-ATGACCTTCTGCGACTTCCTTCAGCGTCTATTTTTGCTGACGCTTGTGCTAGCGGCCGTAGTTTCTGTTGGCTGCGGTTATCGTGATGGCAATAATATTAAAGATGCTTTGAAACATCTGGAACAGCATCGCAACAAGTCCACTGATGCTGACGCAGTGAATCGTCGGGAAGTGAGGGGACAGGACGTAACTCCCACCACTACCACATCTAGTACCACTAGACGCTCCTTTACTTATAAAGGTATATGCAATACGATGTTCCTGTTCCGCTGTGACAACGGTGAATGTATATCGAGGAATTTCCTTTGTGACGGAGGCAATGATTGCTCAGATGGATCTGATGAGAAAAACTGCCAGAAATCTACAGAAGGAAAATGCAATTCAAACCAATTTACGTGCAAGAACGGGAGGTGCATTCGTCCTGAGGAACGGTGCGACGGATTGGATGACTGCAAGGATAATTCCGATGAAGTTGACTGTAAGAATTGTCACGGAGACGAGTTCCTATGCAAAAGTGGGAAGTGTATAGCCAATGACACTTTATGTGATGGTGACAAGAACTGCGAAGACGGCGACGACGAAGCAAACTGTGAAAAGGCACACTGCCTCTCTATACCAGGCCACTACCAGTGCCAATCAGGGGAGTGCGTGCCGCCCATTAAGGTGTGTGACAATAGGACGGATTGCTTGGACGAATCGGATGAAGGGCAGGCTTGTGCTACAACATGTGCAGCCAGTAACTGCACGCAGGGATGCTTCCGAACGCCAAAAGGTCCTCATTGTTTATGTAGACGAGGGTATTACCTAGAACGTGATCAAGTAACCTGCTCTGATATAAACGAGTGTGCTTGGAGCGACAAATTAGTGTGCGACCATTACTGTGAGAACACCAAGGGCGGGTTTCAGTGCTCCTGTCACCACAAGTATATACTGCAGAGTGATAACGTTACCTGCAAGCACCAGCAGTCCGGAAGTGCATTTCTTTTAATAGCACAGGACGATGGAATCAGGCAGCTGTTCCTGGATGGCTCTCGCAACGTGCAAATTGTTCACTCGGGGAATGCATCGGTCATAGGATTGGGTTATGACCCTGTAACTCGCACGATGTTCTGGAGTACCTTTGGTAATGTGTTAAAAGCGGAAGTGGTACCTAATGCAGTGACTCACAAACTGTTGCGTGATGGCTTCATTGTGGCTGAGGGTTTGGCCGTGGACTGGACTGGTAGGAACCTGTACCTCACAGATCCCAAAATGAAACATATCATGGTGTGTAAAATGGACGGCTCCTCCTGCTACTCGCTATTGAGTGGTCTTGGTCATCCAAGAGCCATCCAGTTGGATATGGTTAATAGGTATATGTATTGGACTGACGTGAAGGACGGCACAATTCGCAAGGCTGGAATGGATGGTACTAATCATGATGTGGTGGCAATGAATGGAGTACTGTGGCCCAACGCCATGGCACTTGACCTGCCTGCTGGTCGTCTCTACTGGCTGGATGCTAACAAGGACCATGCCTTCAGCATCAAGTTGGATGGTACAGACCAGAAGTCGCTCCAACATGCTGTGATCCACCATCCCTTCGCCATGGCACAGTGGGAGGACCGTCTGTATTGGACTGACTGGAGCAAAAAAGTAATCTTCTCCTGCATCAAAAGGGATGGCAGACATGGGAGGACGGTGCTGAAAGGAGGCTACACGATGTACTTTGGCCTCATTCTTTATCACCCAGCCATGATGGAAGACATATCCAACCCATGCCGATATTCAAACTGCAGCCATATGTGTCTTCTGTCTCCTCACTCCCCTGGGTATACCTGTGCCTGTCCCAGTGGCATCATGGAGCTCAGCCGTGACAGTCATACATGTGTTGATACATCGGCTAGAGTTTACTTGATAGTCAGCAGCCTCAAGAAATTGTACATGCTGTCACCACACAAGTTTGGCCGTGCCGACCAGCATGTCTTGGAGCCACAACCAGATATCAAAGGCATAGGTGATATGGAGTATTCCCCAGAGCAAGGC
->XM_036181832.1 PREDICTED: Onychomys torridus olfactory receptor 13-like (LOC118579991), mRNA 
-ATGGGAAATCAGACCTGGGTTACACAGTTCATTCTCTTGGGATTTCCACTCAGCCCAAGGATGCAGATGTTCCTCTTTGCTCTCTTCTCCCTGTGCTATGCCTTCACCCTGCTGGGGAATGGGATCATCGTGGGGCTTATCTGCCTGGACTCCAGACTCCACACTCCCATGTACTTCTTCCTATCCCACCTGGCCATTGTTGACATTGCCTATGCCTGCAACACAGTGCCTCAGATGCTGGTGAACCTTCTAGATTCAACCAAGCCCATCTCCTTTGCTGGATGCATGATGCAGACCTTTCTCTTTTTGACATTTGCACACACAGAATGTCTGCTCCTAGTGGTGATGTCCTATGATAGGTATGTGGCCATCTGCCACCCTCTCCGATACACTGCCATCATGAGCTGGAGAGTTTGTATTACCCTAGTGGCGACTTCCTGGATTTTAGGAGTCCTCTTGGCCCTGGTCCATCTAGTATTACTATTACCATTGCCCTTCTGTGGATCTCAAAAAGTAAATCACTTTTTCTGTGAAATTATAGCTGTTCTCAAACTTGCCTGTTCAGACACCCATGTCAATGAGATTATGGTTTTGGCTGGGGCTGTGTCTGTGCTTGTGGGACCATTTTCTTCGATTGTGGTCTCTTATGCTCATATTCTGTGTGCCATCCTGAAGATCCAGTCACGCCAGGGGCGCCAGAAAGCCTTCTCCACCTGTTCCTCCCATCTCTGTGTTGTTGGACTCTTTTATGGTACAGCCATTGCCATGTACATTGGGCCTCAACAGGAGAATTCCAATGAGCAGAAGAAATACCTCTTGCTATTCCATAGCCTTTTCAATCCTATGCTCAACCCACTGATCTATAGCTTGAGAAACAAAGATGTCAAAAGTGCTCTGAAGAGGATGCTCATAAAGAAGGATACCTCTCAGGAGCATTAA
->KC494783.1 Ornebius sp. 10 BHW-2013 isolate REU1901 12S ribosomal RNA gene, partial sequence; mitochondrial
KC494784.1 Ornebius sp. 10 BHW-2013 isolate REU1902 12S ribosomal RNA gene, partial sequence; mitochondrial 
-AATAAGTGTAAATATAAAAGGTTTAGGTAGTAGGAGTTAAGATCTTGAAACTTAAAGAATTTGGCGGTGTTTTATTCTGTTCAGAGGAATCTGTTTTGTAATCGATAGAACACGATTGAATAAACTTGAATTTATAATTTGTATATCGCCGTCATCAGATTATTTTGAATGGAGGAATTTAAATATTAAAATATTTATTAGGATAAAATGTCAGGTCAAGGTGCAGTTTATATTTAAGTATATAATGGATTACAATAAATGAAAATTTATTTGGATTATAAATATGATTATTTATACGAAATTGGATTTGAAAGTAAATTGGTTGAAATTAATAAATTGAATAAGCGCTGAAGCATGC
->XM_015123435.2 PREDICTED: Macaca mulatta zinc finger protein 493 (LOC693611), transcript variant X2, mRNA 
-TGTCCTCAGCGTGTGTGGCTTCATGACCCGAAGGTATTGGGAGATCCATAGCTAAGATGCCAGGACCCCCTGAAAGCCTAGAAATGGGAACTGATTTTCTGCTGTATTTTTCACCTGTGTCCCAAGCAGCGTCTTGGAACCCATCCCCCATTTCTCCAGCCTCACTCTGGCTTGCAGGGCCGTTGACATTTAGGGATGTGGCCATAGAATTCTCTCTGGAGGAGTGGCAATGCCTGGACACTGCTCAGCAAGATTTGTATAGGAAAGTGATGTTAGAGAACTACAGAAACCTGGTCTTGGGTATTGATGTCTCTAAGCCAAATCTGATCACCTGTCTGGAGCAAGGAAAATATCCCTGGAATATGAAGAGACACAGTATGGTAGTGAAACCCCCAGTTATATGTTCTCATTTTGCTGAAGACCTTTGCCCAGGGCCAGGCATTAAAGATTCTTTTCAAAAAGTGATACTGAGAGAATATGTAAAATGTGGACACAAGGATTTACAGTTAAGAAAAGGCTGTAAAAGTGTGAATGAGTGTAATGTGCACAAAGAAGGTTATAATGAACTAAACCTGTGTTTGACAACTACCCAGAGAAAAATACTTCAATGTGATAAATATGTGAAAGTCTTCCACAAATTTTTAAATTCAAATAGACATAACACAAAACATACTAGAAAGAAACCTTTCAAATGTAAAAAATGTGGCAAATCATTTTGCCTGCTTTTACACCTACATCAGCATAAAAGAATTCATATTAGAGAGAATTCTTACCAATGTGAAGAATGTGGCAAAGCGTTTATCTGGTTCTCAACCCTTACTAGACACAGGCGGGTTCATACTGGAAAGAAATCCTACAAATACGAAGAATGTGGCAAAGCTTTTAACCAGGACTCAAACCTTTCTACACATAAGAGAATTCATACTGGACAGAAATCCTACAAATGTGAAGAATGTGGCACAGCTTTCTACCAATTCTCACACCTTACTAGGCATAAGTTAATTCATACTGGAGAGAAACCCTACAAATGTGAAGAATGTGGCAAAGCTTTTAACCGATCTTCAACCCTTACTAGACATAAGATAATTCATACTGGAGAAAAACCCTATAAATGTGAAGAATGTGGCAAAGCCTTTAGTGTTTTCTCAACCCTTACTAAACATAAGATAATTCACACTGGAGAGAAACCCCACAGATGTGAAGAATATGGCAAAGCTTATAAGGAGTCCTCACACCTTACTACACATAAAAGAATTAATACTGGAGAGAAACCATACAAATGTGAAGAATGTGGCAAAACCTTTAGTATATTCTCAATCCTTACTAAACATAAGATAATTCATACAGAAGAGAAACCCTACAAATGTGAAGAATGTGGCAAAGCTTTTAAACGATCTTCAACCCTTACTAACCATAAGATAATTCATACTGAAGAGAAACCCTACAAATGTGAAGAATGTGGTAAAGCTTTTAAACAATCTTCAACCCTTACTATACATAAAATAATTCATACTGGAGAAAAACCCTACAAATGTGAAGAATGTGGCAAAGCTTTTAAGCGATCTTCAACCTTTACTATACATAAAATAATTCATACTGGAGAAAAACCCTACAAATGTGAAGAATGTGGCAAAGCTTTTAATCGGTCCTCACACCTTACTACACATAAGAGAATTCATACTGGACAGAAACCCTACAAATGTAAAGAATGTGGCAAATCCTTTAGTGAATTCTCAACACTTACTAAACATAAGATAATTCATACTGAAGAGAAACCCTACAAATGTGAAGAATGTGGCAAAGCTTTTAACCGATCTTCAATCCTTAGTATACATAAGAAAACTCATACTGGAGAAAAACCCTACAAATGTGAAGAATGTGGCAAAGCTTTTAAGCAGTCCTCACACCTCGCTGGGCATAAGCATGTTCATGGTGGACAGAAACCCTACAAATGTGAATTATGTGGCAAAGCCTTTAGTATATTCTCAACCCTTACTAAACATAAGATAATTCATACTGAAGAGAAACCCTACAAATGTGAAGAATGTGGCAAAACTTTCTACCGATTCTCAAACCTTAATACGCATAAGATAATTCATACTGGAAAGAAACCCTGCAAATGTGAAGAATGTGGCAAAGCTTTCAACCATTCCTCAAACCTTACTAAACATAAGCTAATTCATACTGGAGACAAACCCTACAAATGTGAACAATGTGGCAAAGCTTTTAGGCGGTCTTCACATCTTAGTAGACATAAGATAATTCATATTGGAATTCATACTGAAGAGATTCTACAAATGTGAAGAATGTGGCAAAAGCCTCTTCCCTTACTAAAGAATGTGGCAAAGCTTTTAATCAGAACTTCACCCTTACTACACATAAGATAATTCATGCTGGAGAGAAACCCTACAAATGTGAAGAATGTGGCAAAGATTTCTATT
->XM_036871986.1 PREDICTED: Balaenoptera musculus vestigial like family member 2 (VGLL2), transcript variant X3, mRNA 
-CTTCTATCTCGGAGCGCGGTGGCAGCTGGAATTGCAGGGGTGGGAAGGGAGCGTGCGAGCGGGATCCCGAGCCGCGGAGCACGCTGCCCCTCGCTCCGCCGCGGATGACTTGGGAGCTCGGGTCCAAGTGCCGCCCATGCAGCATCCCTGCCCTCCGCCGCCCGAGAGTTGATGATAAAACACTTAACCGTCTCCGCTGCGGGAAGCCATGAGCTGTCTGGATGTTATGTACCAAGTCTACGGTCCTCCCCAGCCTTACTTCGCAGCCGCCTACACCCCTTACCACCAGGGTCTGTCGGACTCCAGATTTCTTCCGAGCCCGGTGCTGGCGCGGGAAGATGCGAGCAAAGCTCACGCAGGGAAAACCAAAATTTGGTCCCAAAGAAACTAGCCTATTACTCCAAAATGCAGGAAGCCCAGGAGTGCAACGCCAGCCCCAGCAACAGCAGCGGCAGTGGCAGCTCCTTCTCCAGCCAAACTCCGGCTAGTATAAAAGAAGAAGAAGGCAGCCCGGAGAAAGAGCGCCCACCAGAGGCGGAGTACATCAACTCCCGCTGCGTCCTTTTCACCTATTTCCAGGGAGACATCAGCTCTGTGGTGGACGAGCACTTCAGCCGGGCCCTGAGCCAGCCTAGCAGCTATTCCCCAAGCTGTACAAGCAGCAAAGCCCCGCGGAGCTCTGGGCCCTGGCGGGACGGCTCCTTCCCGATGAGCCAGCGCAGCTTCCCCGCCTCCTTCTGGAACAGCGCTTACCAGACGCCGGTGCCCGCGCCACTGGGCAGCCCTCTGGCCGCCGCTCACTCGGAGCTGCCCTTCGCCGCTGCCGACCCCTACTCGCCGGCCGCGCTGCACGGCCACCTGCACCAGGGCGCGGCAGAGCCCTGGCACCACGCGCATCCCCACCACGCGCATCCGCACCACCCCTACGCGCTGGGCGGCGCCCTCGGCGCCCAGGCCGCCGCCTACCCGCGGCCCGCCGCCGTGCACGAGGTCTACGCGCCGCACTTCGACCCGCGCTACGGGCCGCTGCTGATGCCCGCCGCCTCGGGGCGCCCGGCCCGCCTCGCTCCCGCGCCGGCCCCCGCGCCAGGCAGCCCGCCCTGTGAGCTCTCGGCCAAGGGCGAGCCGGCCGGCGCCACGTGGGCCGCGCCCGGGGGACCTTTCGCGAGCCCCACGGGGGACGTGGCCGGGGGTCTGGGCCTCAGCGTGGACTCAGCTCGTCGTTATTCCCTCTGTGGTGCATCCCTCCTGAGCTGATCTGCTGACCCAGGGTTTCCCCTTCCCTTTCCCTTCTGACCAGCCATGGAGGCTGGCATCTGTGCCTCTCACTTCATGGATGAGGACATGGGGGAATGCAGAGACTTCAAACTTCTCCGTGTATTGGGAAAACCAGAACACACATCGACAGAATTTTCATCTAAAAATAATTCCTTCTGCCAAAAGAGGAAATCCAAAGACTCTGAATGATGCTTAATGACTTTTGGGCAAATCACTGGAAATATCCATGGTGATCACTTAGGTGACATGATTCATAGTTTTCTCGGAAAGAGGGAAAGAAAAAGAGATGTTTTGGTGTGAATATTTTTTATGCTGATGTGAATTATTTCATTAAGTAGTGTGATCATAGCACTGCAATGTCAATATCCTCAGACTGAAATGTATTTGTATTTGCATCAAAGACTGTGGTAGAGAAGTCAAAAGAAGCCAATTCCTTCTTCCTCACCTGTAGCCTCCAGCTCCTTTCCTGCCCACTCCCTCCCTACAACACCCACTCCAGACACAAAGACACACTTTCTTCTTCGGACTGTGAACGTGGAAGCCTCAGCCCGAATGTGAGCGGCAAGTGGCGAATCTGGAGCCACCTGCCCGAGTCTTACTGAAATGCAGCTGTTGTAGGACAACTGTTTAAAACTCCAGAAATACATCGACCAAAGGGGGCACTTCCCAGTGTTTGGCACAGCAATTGCAGTTGCACTGGATATGTTTTATACGTGTGTGTGTGTGTATATATCATATTTTTTACAAAGAACATTTTATGATGAAAGAAGAAGCTCTCTCTGCCTTCTCTCCCACGAATTCTGTCCCTCCCTCTATCCTTCTTTGGGTGAAAAAAAGTAAGCATCAAGAGGCCCCAGTTGTCTCCAAGAAGAAGAACTAGGAGTCACCACAAGGGGAAGAGATGCCCATGGAGTCTCTGGTACCTCGAATATTCTTCTCAGTCTCTGTGGTCATGATTTGGTCACTTTAGTGTTGGGACAGGGGAAGGGGTACACATGTGGGCAAAACTGAAGGGGATGAGGAAGAAGAAACGAACATTAAAGATGTTTGTTTACCACTA
->OV289143.1 uncultured Bacterium partial 16S rRNA gene 
-GGACTACTGGGGTATCTAATCCTGTTTGCTCCCCACGCTTTCGCGCCTCAGCGTCAGTATCGATCCAGAAAGCCGCCTTCGCCTCTGGTGTTCTTCCTAATATCTACGAATTTCACCTCTACACTAGGAATTCCGCTTTCCTCTATCGATCTCTAGCCACCCAGTATTAAACGCAATTCCTAGGTTGAGCCTAGGGCTTTCACGTCTAACTTAAGTGGCCGCCTACGCGCCCTTTACGCCCAGTAATTCCGAACAACGCTAGCTCCATCCGTCTTACCGCGGCTGCTGGCAC
->KT295441.1 Uncultured Klebsiella sp. clone M01598_122_000000000-ADV8A_1_1102_4097_6649 16S ribosomal RNA gene, partial sequence 
-CCTACGGGCGGCTGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGCGGGGAGGAAGGCGTTAAGGTTAATAACCTTGTCGATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTCTGTCAAGTCGGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTCGAAACTGGCAGGCTAAAGTCTTGTAGAGGGGGGTAGAATTCCGGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACAAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTAGTAGTC
->XM_053381890.1 PREDICTED: Podarcis raffonei L3MBTL histone methyl-lysine binding protein 3 (LOC128410530), transcript variant X3, mRNA 
-GCACAGCCTCTCGCCCAGGGGATGGGACCCGAGGTGGTGGGGGAAAGTGGCCCGGCGCCTGCGAAGTGGCTGGGGAGTGTGGGTCGGCCACGGGGGGTTCCTTCCCTAAAAAAGCCCCTAAGTGCGTGAGAGTGAAAGAGGAACAAAAGAGTGGGCGAGGGAGAGCCAGAGAGAGGTGCCTTCGGCGTCCGCGCCCCCCACCCCGCTCGCTTCTTCCCCAACATATGACGGTATATGCACCATGAATGAACCAACTTCTAGTGGAAGTGGGCAAGACTTTGATGTATTTAGTGTAATGGACTGGAAGGACGGAATTGGTACCTTGCCTGGAAGTGATCTGAAGTTTCGTGTGAATGAGTTTGGTGCCCTAGAAGTAATCACCGATGAAACAGAGATGGAAAGTGTTAAGAAGGCTACAGCTACCACAACCTGGATGGTGCCTACTGCTCAAGAAGCCTTCTCAGAAAATACAGAAGTACCACAAAAACTGAAGGAAGCTAGCAAGGTTGACGGGCCTCATTTCTGTGAACGTTGTTTTCATTCTGGAACCACAGTGGACTTTGTAGCTGGAGAAAGATCTTGCAGCCAAAAATGTGCACATCAGATTAAAAACAAAGAGCAAAGGGAGGACAACGATGTCTCGGAAGTCAATGATGAGGACTGTTCCAAGGGCACTCAAAAAAGAAAAACCAAATCGCCCTCAAAAGGAGAATGTATGGAAGACAATGTCAAGAAGTATGAGGCAATGGAGGAGAAACCTGAAGGGAGGATACTAAGAGTCTCTCAGAGAGCCACACGGAAAAGGAAAAGAGAGATGGCAGTTCTAAAACAGACTTTGATGTCAAAGGCAAAGAAAACATGGAGTTGGTCTTCGTATTTGGAAGAAGAAAAGGCTATAGCAGCACCACCTAAGATTTTTAAAGAGTATCAATCCTTCCCGTACAACAAAAATGGATTCAAAGTTGGAATGAAACTAGAAGGGGTGGACCCTGAGCACCAGTCAATGTATTGTGTGCTTACAGTAGCTGAGACTTGTGGTTACAGAATTAGACTTCACTTTGATGAATACCCAGAGTGTTACGATTTTTGGCGGAATGCTGATTCTTCTGATATTCACCCAGTTGGTTGGTGCGAGAAAACAGGACACAAACTTCATCCACCAAAAGGATATAAAGAAGATGAATTTAATTGGTCCTCGTATCTGAAGAAATGTAAGGCTCAAGCTGCTCCTAAATCCTTGTTTGAAAACCAAAACTCAACGGTGATTCCATCAGGGTTTCGAGTGGGGATGAAGCTTGAAGCAGTAGACAAAAAGAACCCTGCATTCATATGTGTTGCTACAGTAACTGACATTGTGGACAGTCGTTTTCTGGTTCATTTTGACAACTGGGATGAGAGTTATGACTACTGGTGTGAAGCGGCTAGTCCACATATTCATCCAGTTGGCTGGTGTAAAGAGCACAGAAAGACCCTTGTAACCCCTCGAGACTATCCACATGCCAAGCATTTTTCTTGGGAGAAATATTTGGAAGAAACTAGTTCTTTACCAGCACCTGCCAGGGCTTTTAAAGTGAAGTCTCAGCTGGACCAAAGAGCTTTTCAGCAGTGGAAGGACACAATTGCATACAACACAAAGTCATTAACAAAGAAACCTTCTCATGGATTCCAGAAGAATATGAAACTTGAAGTAGTTGACAAGAGAAATCCTGTACTAATCAGGGTCGCAACCGTGGTAGATACTGATGACCACAGAATTAAAGTCCACTTCGATGGCTGGGATAGTATTTATGATTATTGGATCGATGCAGATAGCCCTGATATCCATCCTGCTGGCTGGTGTGGGAAAACTGGACATCCTCTTCAGCCCCCACTTAGTCCTTTGGAATTGGTAGAAGCTTTAGAACAAGGAGGATGTCCTACAGTGGGCTGCAAAGGAGTTGGACACATAAAAAGAGCCAGACATACGGGCCACCACAGTGCTCTCAGCTGCCCATATTCTGAGATAAATCTGAGCAAAGAACATATCCTTTCAGACCGCTTAAGTGGAGAGATGCCTCAGAGTATTCCGCCTCTGCATTGGAACCGGAAGCCAGAAGCAAATGAAAGATCTGCATCTCCTGTAATCAGTAATAGAAAATGTCCCAGTCCCATTGTCCTAAAATCTTCAGCTCATCTCCATTCATCAAAGCAGGAAGACACAGAGGTGAAACCTCTTTGCAAAAAGCCTCTAATGTTTGATGTCAAAGAAAAGAACTACAGGGGATGCCAGGCAACTAAGGATTTTGCAAAGAAAGATGGCTGTGCAGGCAGGAAGATGGAAAATGAAGAGTCATCTCTAAATGAATCCAAAGACACCAAGGAATCCAGTAACAGGAGTTCCCATCCTCAGCCAGTTATTTTGACCTCGAAGTTGACAATCCCAGCCTTTCCATTGCGATGGGAACAGCAGAGTAAACTCCTTCCTACTGTGGCTGGAATCCCTGCCAGTAAAGTTTCCAAGTGGAGCACAGATGAGGTGTCAGAATTCATACGGAGTTTGCCAGGCTGTGAGGAACATGGCAAGGTGTTCAAAGACGAACAAATTGATGGAGAAGCTTTCCTTCTAATGACCCAAACAGATATAGTAAAAATAATGAGCATTAAGCTAGGACCAGCCCTAAAGATCTTCAACTCAATCCTGATGTTCAAGGCTGCCGATAAGAACTCGCACAATGAACTCTGATGGAAAAGTGACTACAGGGCAGCTCTCTCCATTGCAGCTCATGTTTTATTCAAAGCACAAAGACTCCAAAGGATCATCAAGGAGGAACTCTATAAGGCGAAAAATCAGAGTGGATGGAGTGTTGATTTTCTCCAAGAGCCTGAGCAAACTAACACTTCTGGGAAGTGCTTAAGCTTTTTAGTAAGATGCTCTTACAAAAGAGTGGGTACTTGATGTTTACTGGCTGATGGCTCTAATTTTCCCACAACTAGCCATCCTTAATTTTATCGGGGATCCATTAACTAAGTTAACATACTAAAATTATGGAAATAATATCCTTTTCTAAGGATACACAAAATACACACTTCATGAATTTACTTCTTCACCAATGAATTCCTTTGTATCGTTTCATCATTTTCATTAAAAAAAAAATTGTTCGCAGTTTAAAATAAGTGGACTACAGTTAATGAAGACTGTTAACAAGTCGTCTTAGTTTCACACAGCAGCTCAAATTTAACACTTTGCTGTGTACAATGAAGCTGATCGATTTATTCTGTTGTATGAAAACATTGCTGGAGACCAATGCTATGTTTTTTTGTTTTTGTTTTTTTGCATGATTAAAGAAGTTTAATGAATATTTCCACCAGCATA
->XM_027574246.1 PREDICTED: Zalophus californianus family with sequence similarity 71 member F1 (FAM71F1), transcript variant X2, mRNA 
-GGCAAACTTGCAGCAGGCCCCTGAGCATGTGCGGAAATGTTGTCATCAGTTCCACAGAGAAAGACTCGGTGGAAATCAAAGAAGACAGTAAAAGTCACAAGATCTTTTCCAACCTTCCCTTCCCTGAATGCCTGGGAAGAAGTCAGGGGCCTCTTGCCTGTGGATGGGGAGCCAAACCCTGGAGTGGGCCTGGGTGTGGAGGAGGGACTGCTCTGCCAGATTCTTCATTCTCCAGAATTCAACCTATTTCCTGACTCAGTGGTGTTTGAAAGCAACTTTGTCCAGGTCAGAAAGGGCAGGGACTGGATAGACATCTACAAGGCCTCCAACACCATGGCCCTTGGGGTAACCTCCTCCGTGCCCTGCCTGCCCCTTCCCAATATCCTCCTCATGGCTAATGTCAAATGGCACCAGGGACAGAGCCAGACATGGAACAGACCATCTATGGCCCCAAACATCAAGCTGAAGAGGATCCTCCCATTGAAGTTTGTGGAGTTCCAGGTCTGTGACCGGCTTCAACGCATCCTGCGTTTGAGGACAGTCACTGAGAAGATCTACTACCTAAGGCTCCACCCTGACCATCCTAGGACTGTCTTCCACTTCTGGATCCGACTGGTTCAAATTCTGCATAAGGGCCTGTCCATCACCACCAAGGACCCTAGGATTCTTGTCACTCACTGTCTGGTACCCAAGAACAGCTGCAGCCCCTCGGGAGACTCTAACTCGGTAGAGAAGAAACCCCAAGCCTCCCAGCCCAGCGAGAGCCTCATGCAGCTGATGGCCAAGGGGGAGAGTGAGGCGCTCTCTCAGATTTTTGCCGACCTGCACCAGCACAATGAGTTCAGGAGCAGCAAAAAGACACAGACCAAAAGGGACAGCTCAGAGAAAGATACTCACAGTGAAGACGGCATCCCTTGCACCCGCGACCTCAGTTGGAGAGATTCGCTCACTTATGGAGAGTGGGAAAGAGAGAACCCCTCTGGGCCACAGCCCCTTTCACTCCTCAGCACCCTGGCAGCCTCCACGGGGCCACAGCTGGCCCCACTCATATAGGAAATTCTATTTAAACTACCTTTTCGCACTGGGGAGAATCTATGCAGCCCTCGCCAACGCCACTCTGCAGCATGCAGCTTTCTGAGGGACTCTGTCTGGATGTAGGGGAGAAGAAAGCTACAACTAAGGAAAAACTAGACTCATCTCATGCTGATAGCATAGCCTTTCCTTGGAGAACCACCTGGGAGCATGGCTCCGGGTAAGAGCATTATTCCAGCATCATGCCAGTACGTAACTCCGGATCCGTGCCACTACCCATCACACCTTGCCTCCGTTAACCACCACCAGGGCAGGCACAAGAAGATGTGCTCTCAGAAGGGCCACGGACAAGAGATGGAGAGAAGGAAGGAAAGGGAAGCAGGACCGGAGGAGAGGGGGACGAGAACAAAATGGCGGTGAAGAGCAGGTGGAGGGAGAAAGTCAGAGAAGAAGGGGGATCTTACAGAGAGGTGGTAAGAAAACAGAAGGGACCTGAATGAGAAGCTGAAAAGGACAAGAGAAGAAATACACCACTGAGAGATGCCTCACGAAGCTTCTATTTATCTAATTTAAAACTTGAAAGTAAGGCCATATACCCAAACAAATGTGTTTTCTTCTCTGTGCCAATTATTCTGGATAACTATGAGGGGCTAAAAACTAATTCCAGCCAAGGGCCTCTCCTGAAGT
->KM481143.1 Uncultured bacterium clone 2010ECS-StD#1958 16S ribosomal RNA gene, partial sequence 
-GGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCAGGGCTTAAATGTAAGTTGCATGGATCAGAGATGGTCCTTTCTTCGGACTACTTACAAGGTGCTGCATGGTTGTCGTCAGCTCGTGCCGTGAGGTGTCAGGTTAAGTCCTATAACGAGCGCAACCCCTATTGTTAGTTGCCAGCGGGTCAAGCCGGGTACTCTAGCGAGACTGCCGGTGCAAACCGAGAGGAAGGTGGGGACGACGTCAAATCATCACGGCCCTTACGTCCTGGCTACACACGTGCTACAATGGCCGGTACAGAGAGCAGCCACCCCGCGAGGGGGCGCG
->KP968504.1 Sarocladium sp. strain LA-MB10 18S ribosomal RNA gene, partial sequence 
-TCTTTGTTTGTGTGTGTCTGTCCTACTCCAGGTTTCCTCTCTAATTGGGACCACGTGTGTGTCTCCGGGTTATATCTGGGCAAAACCCCCCCCTCCACCAGGGGTTGGGAGGTGGTTATCTATCCAACCCAATCCGGGGCCGTTCGGGGTTGTTTGTGATTCATGAAACTAATAGAATCGCCCGCCCTGGCCCTGCGGTGGATCATTCCACTTACTACCTTATCAACTTTCGATGTTGGCTATTGCCAATCATGGTGCAACGGGTAACGGAGGGTTAGGGCTCGACCCCGGAGAAGGAGCCTGAGAAACGGCTACTACATCCAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCCGACTCGGGGAGGTAGTGACAATAAATACTGATACAGGGCCCTTTCGGGCCTTGTAATTGGAATGAGTACAATTTAAATCCCTTAACGAGGAACAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGTGGTTAAAAAGCTCGTAGTTGAACCTTGGGCCTGGCTGGCCGGTCCGCCTCACCGCGTGCACTGGTCCGGCCGGGCCTTTCCCTCTGTGGAACCCCATACCCTTCACTGGGCGTGGCGGGGAAACAGGACATTTACTTTGAAAAAATTAGAGTGCTCCAGGCAGGCCTATGCTCGAATACATTAGCATGGAATAATAAAATAGGACGCGCGGTTCTATTTTGTTGGTTTATAGGACCGCCGTAATGATTAATAGGGACAGTCGGGGGCATCAGTATTCAACTGTCAGAGGTGAAATTCTTGGATCAGTTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAGGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGACGGTGTTATTCATGACCCGTTCGGCACCTTACGAGAAATCAAAGTGCTTGGGCTCCAGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGAAATTGAC
->JF420835.1 Centroptilum triangulifer heat shock protein 70 mRNA, partial cds 
-TCGAGGCAGACAGATCCTCTTGAGCACATTTCCTCTTTTTCATCTGCAATCATCCGCTAAAGAAATGGCAAAGCCGGGCCCCGCAGTCGGTATCGATCTTGGAACCACCTACTCCTGCGTTGGAGTTTTCCAGCACGGAAAGGTGGAAATTATTGCCAATGACCAGGGCAACAGAACAACCCCTAGCTACGTGGCTTTCACTGACACCGAGCGTCTCATTGGAGATGCCGCCAAGAACCAAGTGGCCATGAATCCTAGCAACACCATCTTTGATGCTAAGCGTTTGATCGGGCGCAAGTTTGAAGATGCTACAGTGCAAGCCGACATGAAGCACTGGCCATTCACAGTCATTAGCGAGGATGGCAAGCCCAAACTGCAGGTGGAATATAAGGGAGAGACCAAGGCCTTTTTCCCTGAGGAAGTCAGTTCGATGGTGCTCATCAAGATGAAAGAGACCGCCGAGGCCTACCTGGGCAAGACTGTCAACAATGCCGTCATCACCGTGCCGGCTTACTTCAACGATAGCCAGCGCCAGGCCACCAAGGACTCGGGCACCATCGCTGGACTGAACGTGCTCAGGATCATCAACGAGCCCACTGCGGCTGCCATCGCCTATGGTCTAGACAAGAAAGGCCAGGGTGAGAGGCATGTCCTCATCTTTGACTTGGGTGGCGGCACCTTTGATGTGTCCATCCTGACCATTGAGGATGGAATCTTCGAGGTCAAGTCCACTGCTGGAGACACCCATCTTGGAGGTGAGGACTTTGACAACCGCATGGTCAACCACTTTGTGCAGGAGTTCAAGCGCAAGTACAAGAAGGACCTGACCACCAACAAGCGTGCCTTGAGGCGTCTCAGGACGGCGTGCGAGAGGGCAAAGAGGACCCTCTCTTCGTCCACTCAGGCCTCCATAGAGATTGACTCTCTCTTTGAGGGCATCGATTTCTACACTTCCATCACCAGGGCTCGTTTTGAGGAGCTCTGCGCTGATCTCTTCAGGTCCACCCTTGAGCCCGTTGAGAAGTCCCTGAGGGATGCTAAGATGGACAAGGCCCAGATCAATGATATTGTTCTTGTCGGAGGTTCTACCCGTATTCCCAAGATCCAGAAGCTCCTGCAGGACTTCTTCAATGGCAAGGAGCTCAACAAGTCCATCAACCCTGATGAGGCTGTTGCCTATGGAGCAGCTGTCCAGGCTGCTATCTTGGCTGGAGACAAGTCTGAGGCTGTCCAGGACCTTCTCCTGTTGGACGTCACTCCCCTTAGCTTGGGTATCGAGACTGCTGGTGGTGTGATGACCACCCTTATCAAGAGAAACACCACCATTCCCACCAAGCAGACCCAGACCTTCACCACCTACTCAGACAATCAACCTGGAGTGCTCATTCAGGTCTATGAGGGCGAGCGTGCCATGACCAAGGACAACAACATTTTGGGCAAGTTCGAGCTTGCGGGCATCCCTCCTGCTCCCCGTGGTGTGCCCCAGATTGAGGTCACCTTTGACATTGACGCCAACGGCATCTTGAACGTCTCTGCAATTGAAAAGTCTACCAACAAAGAAAACAAGATCACCATCACCAATGACAAGGGTCGCTTGTCTAAGGAGGAGATTGAGCGTATGGTCAACGACGCAGAGAAGTACAAGGCCGAGGATGAGAAGCAGCGCACCGTCATTGCTTCCAAGAACAGCCTCGAGTCCTATTGCTTCAACATGAAGTCAACCATGGAAGGTGAGAAGCTGAAGGACAAGATCCCCGAGGAAGACAAGAAAATTATCATGGACAAGTGTAACGAGGTGATCCGTTGGATGGACTCGAACCAGCTGGCTGACAAGGAGGAGTTCGAACATAAGCAAAAGGAGCTTGAAGGCGTCTGCAACCCCATCATCACCAAGCTGTACCAGAGCGGT
->MF207496.1 Uncultured bacterium clone denovo1205_590_10496 16S ribosomal RNA gene, partial sequence 
-GTTCCTACGGGGCGCAGCAGTGGGGGATATTGGACAATGGGGGGAACCCTGATCCAGCGACGCCGCGTGAGTGAAGAAGTATTTCGGTATGTAAAGCTCTGTCAGCAGGGAAGAAAGCAATGACGGTACCTGACCAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGGAGGATGCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGTGCGTAGGCGGACAGTCAAGTCAGCGGTAAAAATGCGGTGCTCAACGCCGTACAGCCGTTGAAACTGGCAGTCTTGGGTGGGCGAGA
->XM_015122060.2 PREDICTED: Macaca mulatta SMG7 nonsense mediated mRNA decay factor (SMG7), transcript variant X2, mRNA 
-AACTTGGAGGTCTGCCTTTAATAATCAAGCAGGATCCCCACTGCGGGTGCCTATCAGAGTTATGGCGATAGTCAGCCTTCCGGTTAGTCCCCGACTTAAATGATAGAAAACACGTGTTACCCTTCTAGGATGCATTCCTACCCTCACCCTGGCCTCGCAGCAGGATCGCGACAGCTAGGTCAGGAGGGAGTACGCGGGTGGGGTGGATTTGGGGGAGGGGTTGACTCGCCAAAAGTCGGCTATCCCCGTCGGCAGGGGAGGCATCACGGCTGTCGTGTGCCGCTCTCCTCCCTCAGGGACCCCGTTCAGGCGGGATCCCGCCTCCCAGAGCCCAAGGCAGTTGTGGGGAAACCCCTTGCCCTTCCTCGCCGCTTGGCACTGCCGCCTCGCTCTCCCGACTCCAGCCCGCCGCCCGCCAGCCTCCAGGCCATGCATCTTCTTCGCAGGCCCAGCCCTCTCCACGCCCGGCTCTGAGAGGAAACTATGGAGGTGGTTCCCGCCTGCAGGCGGGTGGAAAAGCCCATGGTGAATGTCTCGGGGTGTCCCCCCAGTTGCTGTGAGAAGTGGGAAGGGAGGAGGAAGTGGACTTCACCACCGGGGAGAACTACCTCTATTCCTAACTTGGGGGAGGCCTTTAGATGGAAGGGATGCCAACGGGGAACCCTGGGCGGTTTCCAGGGAATCCATTGGCCAAGGGGAGGGTCACCCTGTCTGCACACACTGGTTACTATGACAATACAACCACAGCCTCCAGTTGCCATGGCAGCTGTCTATCCAATCCGATTCTTTTCTTTTCTCTTCCTCTCCGGGCCCCACCTTATCCCCTCCAAGAGTCTCCCAGCGTGCATGGGGAGGGGCTGCAGAGAAGAGGAAAGGGGGTCCTTCGAGTCACTCTCTACGCGCGAGAGAAGACAAGAGTCGAGGGACTGCTGGGAGGAACTGTAGGAGGAAGGGGCGGCGTTTCCGGTGGGGAAGAGTGGAGGCGTGCAAAAAGGAAGAGAGAAATCCGCTGGAGTGATAAGAAGGGGGAAGACTTTGAGTGTAACTCCCGGTTCTTTGGGCCTCGGTGTTCTTGGTGGGGTTGGGATTGCCCCCTTGCGCGGGAGGAGAAGGGTGGATTGGCAGGAAGCCTCCAAGCGCCACCAGCCGGTAGCTCAGAAGCCGCACACGCGCCACACAGCTTGTTGATCCCAAAAGGGAGCGCTACAGAGAAGCGGAAATCACCGGGAGAGACAGGCGCTGCTGAAATCTCGCGAGAGGGAGCCCCCCTCGTAGCCGACTTCCTTCCTCTGCTTCTCCTCTTTCCCCCGCCCCTCCTCCCTCCTCCTCCCCCCCTGGGTCGGAGTGTCCCTGCGCCCCACGGGCCGGAGCAGCAGCGAAAGCAGCTTTCCCCGCTCCCTCCCCCTCGCCTCATTCACCCCCACCCCCTTGCCGAGCGAGGAGGAGCCGGAGGAGAGGAAGATGGCGGCGGCCGCCAGCACCCGCGGTGCCGCGGGGCCGCTCCGAGGAGCCTGAGAGACCCACGGAGGCTTCGCGGGAAGACGCGGCGGCGGAGGATGAGCCTGCAGAGCGCGCAGTACCTCCGGCAGGCAGAAGTCCTGAAGGCTGACATGACAGATTCTAAGCTGGGTCCAGCTGAAGTCTGGACATCCAGGCAGGCTCTGCAGGACCTGTACCAGAAAATGCTAGTTACTGATTTGGAATACGCTTTAGACAAGAAAGTAGAACAGGATCTCTGGAATCACGCCTTTAAGAATCAGATCACAACACTACAAGGCCAGGCAAAGAATCGAGCAAATCCGAATCGAAGTGAAGTTCAGGCAAACCTTTCTCTGTTCCTAGAGGCAGCTAGTGGCTTCTATACCCAGTTATTACAAGAACTGTGTACAGTATTTAATGTAGATTTACCATGCCGTGTGAAGTCTTCCCAGTTGGGAATTATCAGCAATAAACAGACGCATACCAGCGCCATAGTGAAGCCACAGTCTAGCTCCTGTTCCTATATCTGCCAGCACTGCCTCGTCCACCTTGGAGACATTGCTCGATACAGAAACCAGACCAGCCAGGCAGAGTCCTACTATAGGCATGCAGCTCAGCTTGTCCCCTCCAATGGTCAGCCTTATAATCAGTTGGCTATCTTAGCTTCTTCCAAAGGAGACCATCTGACCACAATTTTCTACTACTGCAGAAGCATTGCTGTGAAGTTCCCTTTCCCAGCTGCCTCCACTAATCTGCAAAAAGCACTTTCTAAAGCACTGGAAAGCCGAGATGAGGTGAAAACCAAGTGGGGTGTTTCTGACTTCATCAAGGCCTTTATTAAATTCCACGGTCATGTGTACCTGAGTAAGAGCTTGGAAAAGTTGAGCCCTCTTCGAGAAAAATTGGAAGAACAGTTTAAGAGGCTGCTATTCCAAAAAGCTTTCAACTCTCAGCAGTTAGTTCATGTCACTGTCATTAACCTGTTTCAACTTCATCACCTTCGTGACTTTAGCAATGAAACTGAGCAGCACAGTTATAGCCAAGATGAGCAGCTATGTTGGACACAGTTGCTGGCCCTCTTTATGTCTTTTCTTGGCATCCTGTGCAAGTGTCCTCTACAGAATGAGTCTCAGGAGGAGTCCTACAATGCCTATCCTCTTCCAGCAGTCAAGGTCTCCATGGACTGGCTAAGACTCAGACCCAGGGTCTTTCAGGAGGCAGTGGTGGATGAAAGACAGTACATTTGGCCCTGGTTGATTTCTCTTCTGAATAGTTTCCATCCCCATGAAGAGGACCTCTCAAGTACTAGTGCAACACCACTTCCAGAGGAGTTTGAATTACAAGGATTCTTGGCATTGAGACCTTCTTTCAGGAACTTGGATTTTTCCAAAGGTCACCAGGGTATTACAGGAGACAAAGAAGGCCAGCAACGACGATTACGACAGCAGCGCTTGATTGCTATAGGCAAATGGATTGCTGATAATCAGCCAAGGCTGATTCAGTGTGAAAATGAGGTAGGGAAATTGTTGTTTATCACAGAAATCCCAGAATTAATACTGGAAGACCCCAGTGAAGCCAAAGAGAACCTCATTCTGCAAGAAACATCTGTAATAGAGTCGCTGGCTGCAGATGGGAGCCCAGGGCTAAAATCAGTGCTATCTACAAGCCGAAATTTAAGCAACAACTGTGACACAGGAGAGAAGCCAGTGGTTACCTTCAAAGAAAACATTAAGCCACGAGAAGTGAACAGAGACCAAGGAAGAAGTTTTCCTCCCAAAGAGGTAAAATCCCAGACAGAACTAAGAAAGACTCCAGTGTCTGAAGCCAGAAAAACACCTGTAACTCAAACCCCAACTCAAGCAAGTAACTCCCAGTTCATCCCCATTCATCACCCTGGAGCCTTCCCTCCTCTTCCCAGCAGGCCAGGGTTTCCACCACCAACATATGTTATCCCCCCTCCTGTGGCATTTTCTATGGGCTCAGGTTACACCTTCCCAGCTGGTGTTTCTGTCCCAGGAACCTTTCTTCAGCCTACAGCTCACTCTCCAGCAGGAAACCAGGTGCAAGCTGGGAAACAGTCCCACATTCCTTACAGCCAGCAACGGCCCTCTGGACCAGGGCCAATGAACCAGGGACCTCAACAATCACAGCCACCTTCCCAGCAACCCCTTACATCTTTACCAGCTCAGCCAACAGCACAGTCTACAAGCCAGTTGCAGGTTCAAGCTCTAACTCAGCAACAACAGTCCCCTACAAAAGCTGTGCCGGCTTTGGGGAAAAGCCCGCCTCACCACTCTGGATTCCAGCAGTATCAACAGGCAGATGCCTCCAAACAGCTGTGGAATCCCCCTCAGGTTCAAGGCCCATTAGGGAAAATTATGCCTGTGAAACAGCCCTACTACCTTCAGACCCAAGACCCCATAAAACTGTTTGAGCCGTCATTGCAACCTCCTGTAATGCAGCAGCAGCCTCTAGAAAAAAAAATGAAGCCTTTTCCCATGGAGCCATATAACCATAATCCCTCAGAAGTCAAGGTCCCAGAATTCTACTGGGATTCTTCCTACAGCATGGCTGATAACAGATCTGTAATGGCACAGCAAGCAAATATAGACCGCAGGGGCAAACGGTCACCAGGAGTCTTCCGTCCAGAGCAGGATCCTGTACCCAGGATGCCATTTGAGGACCCCAAGAGCTCCCCTCTGCTTCCTCCGGACCTGTTAAAGAGTCTGGCTGCCTTGGAGGAAGAGGAAGAGCTGATTTTTTCTAACCCTCCTGATCTTTACCCGGCTCTGCTGGGGCCTCTCGCCTCTCTTCCTGGACGAAGCCTTTTTAAATCCTTATTGGAGAAGCCCTCAGAGCTCATGTCACATTCATCCTCTTTCCTGTCCCTCACCGGATTCTCTCTCAATCAGGAAAGATACCCAAATAATAGTATGTTCAATGAGGTATATGGGAAAAACCTGACATCCAGCTCCAAAGCAGAACTCAATCCCTCAATGGCCCCCCAGGAAACATCTCTGTATTCCCTTTTTGAAGGGACTCCGTGGTCTCCATCACTTCCTGCCAGTTCAGATCATTCAACACCAGCCAGCCAGTCTCCTCATTCCTCTAACCCAAGCAGCCTGCCCAGTTCTCCTCCAACACACAACCATAATTCTGTTCCATTCTCCAATTTTGGACCCATTGGGACTCCAGATAACAGGGATAGAAGGACTGCAGATCGGTGGAAAACTGATAAGCCAGCCATGGGTGGGTTTGGCATTGATTACCTCTCAGCGACGTCATCCTCTGAGAGCAGTTGGCATCAGGCCAGCACTCCGAGTGGCACCTGGACAGGCCATGGCCCCTCCATGGAGGATTCCTCTGCTGTCCTCATGGAAAGCCTAAAGTCTATCTGGTCCAGTTCCATGATGCATCCTGGACCTTCCGCTCTGGAGCAGCTGTTAATGCAGCAGAAGCAGAAACAGCAACGGGGACAAGGCACCATGAACCCTCCACACTGAGGCCAAAGTGACAACCTGGGAATGAAGGCTCCATAAACCATGGCATGTTGGGTTTGCAGGACTGGCCCACACAGTCCCCTGCAGGTGGCAGCCCTCTTTTCTGTTTCTTGCTGTCAAGAGGGTGTAAGTATTCCACCAGCCCGCTGAGTGTGCACGAAATGTTCGCAGTGCAACAAAAAGAAAAATCCATCAGGAACTCTCCATCCCCCCGGGGCCTTCCGGAGGGAGAGAGAGAGGAACTGCTGTTTATCTCACTCAGTTACTTGGTATCACCGCCTCTCACCTTCTCCATCGTGCATGTCCCCAGCCACATGGGAAGTGAAAGCTGAGAAGGGAAGGCAGATGGGAGAAGCCAATGGGAACTTCTCAGTCCTTTTTCCCTCTTTGGGGAATAAAATAGGAATCCATTAATGGTTGCTTTGCTGACTGA
->XM_048567351.1 PREDICTED: Pyrus x bretschneideri alcohol dehydrogenase 1-like (LOC125469685), mRNA 
-ATACGATTCACTTTCAAGATGCCTTAATTCATCAAAGTGTTCTAGAGAGAGAGAGAGAGACTCATCTTCTCTCTCCTAAGAATAAGTTAACAGAGAGTCCCGTGGAGTAGTTATTGGAGGCCATTTTTTCTCAACATCCTCCCAAAAATAGGCAAAGAATTGCTCTTGACCTTTGATATTATATTTCACCATCTGTGTTTGCCAATTGGCATTTTCATCTTTCTTTTTTCTTTCTAAGTAGAACACTGTGAATTACACACCATGCACAAAATGCATAAGAGTTTTAGAACATTGGTGCACAATGACCATTTCTTGAAGCTCCTAAATAACCAAAAATCTAGGTTCCTCAGACCGGAACTTTACAGCACTTCGGCTCATGCTGGCCGTGCGATCACCAGCAAAGCGGCTGTTGCTTGGGAAGCAGGGAAGCCCTTGGTGATAGAGAAGGTGGATGTTGCTCCACCGCAAGCCAATGAAGTTAGGGTCCAAATCAAATACACCTCTCTTTGTCACACTGATATCTACTTCTGGGAAGCTAAGGGCCAGACACCATTGTTCCCTAGGATTTTCGGACACGAAGCAGCTGGCGTCGTTGAGAGTGTTGGTGAAGGCGTTAAGAACCTCAAGCCGGGGGATCATGTGCTTCCAGTTTTCACTGGGGAATGTGGGGATTGTCCACATTGCAAGTCTGAGGAAAGCAACATGTGTGAGCTGCTGAGAATCAATTGCGATAGAGGAGTCATGATTGGTGACGGGAAAGCAAGGTTTTCGCAGAATGGGACTCCGATTAATCACTTTCTCGGCACATCCACGTTTAGCGAGTACACAGTTATCCACGAAGGCTGCCTTGCCAAGATCGACCCAAAGGCACCATTGGATAAAGTCTGCATCCTCAGTTGTGGTGTGTCGACTGGCTTAGGTGCCACTCTGAAAGTAGCAAAACCAAAGAAGGGTTCTTCAGTTGCTATCTTTGGACTTGGAGCTGTTGGCCTCGCTGCTGCAGAAGGTGCAAGGATTTCTGGGGCATCAAGGATTATTGGGGTAGACTTGAATCCCCATAGATTTGAGCAAGCCAAGAACTTCGGAGTAAACGAGTTTGTGAACCCGAAAGACCATAACAAGCCAGTGCAGGAGGTTATCGCTGAGATGACGGATGGTGGAGTTGACAGAAGCTTAGAGTGCACCGGGAACATTAATTCGATGATCTCCGCTTTCGAATGTGTTCATGATGGGTGGGGTGTAGCGGTGCTTGTAGGAGTGCCAACCAAAGATGCAATCTTCAAGACAAACCCCATGAAAGTACTTGATGAAAGAACCCTCAAAGGAACATTTTTCGGCAACTACAAGCCTCGGAGCGACCTTCCCTCTCTCGTGGACATGTACATGAACAAGAAACTGGAAGTAGAGAAGTTTATAACGCATCGACTTCCTTTCTCGGAGATCAACAGAGCTTTTGACCTAATGTTGAAGGGGGAAGGCTTGCGGTGCGTCATTAGCATGGAAGAGTAGGATTAATGTCCAAATTCATATACGA
->XM_039052777.1 Cantharellus anzutake uncharacterized protein (EI90DRAFT_2259046), mRNA 
-GAAGTGGGTATAATGTACTTGACCCATGGTTTGAGAGAACCATGAACTGTCGGAAGTGATGTCCAACAGTGTTCAGTACCCCATAACTGCGTGCAGAGAGACCGAAAACGACTCGGGAGAAGCGCTTAAGCAACAAAGCGGTAATCGAAGTGTTGCAGGCACCAAGAAGGGCATGTAACTTAGGTATTTCAGGGCCTAGAGTCCACATATTCGTAACCGGAATGACACCGCTAAGGTATGATATCCCCATCACATTCGCGTCTGCTGGAGTGCTCCATTGACGAGATAGACAACGTGTCTCCAGTATCGCTCAGGTCCGTCTATCCATGCCGTCGCCCCAACACCCCACCAGGAAGGGGAAGAGGAAACACAACGGTTTGGAGGCCGTGGAAATTACCAACGGGCCTGCATGAAGCACGAAGTAGCCCAATGTGCGATTCCAAGCATTTCTCAGTTGGTGTATTCCCAGATCCATGTGATCTTGCCGAACAGGCTGACGAAAAGAGCGCAGTTAGAGCGCACTACCACCGCGGTCCCTCGCCTCTTGAGCCCAAGGAGGAGGCGATTTGTAAAGTCCGTGCACGGCATATGATCTCACCCCGGATGCTCGCAGGCATTGTAACATCCCAAGGTAAAGAAGACTCCCGACCCCGGACATCCGGCACTGACCAGGGAAGCCTGCAAGATGTAGCCCTGATCGCCAGCAGGGGGGTTTTATAACCTCCAGAGTTCGGTCCCACCCCCAATCGACGC
->XM_046171703.1 Alternaria rosae uncharacterized protein (BKA58DRAFT_402161), partial mRNA 
-ATGAATCAGAAACACGTTCCAGTCACTTCAACGCAACTACACACTTTCAACTGCGAGGTCTCAGGTGCGGCTCAGAAAGACATTTACCAAAACGACAGCAAACATCCCATCGGCTTCAACACTCAACATTCAAAACGCCATGGCAGCCTTCCATGGACCCTCAACCACTCCATTAAGCGAGCTGAACTCCTCAGAGTCTGGCAAAGTCGTTTCATCGAGCGATTCGAGAGCGTGAAGCAGCTGACCGTGGGGAACCTCGCTGCACTGCAGGCTGGTTACAATGACGTACAATCTCAGCCTACATCACCTCTAGACGGCGAGTTGCACCTCAGACCGTCTCCCGGTGCAACGGCATCTCTCATCAAACGTAAGCCGCTGCCAGATACAGCGCAAAAAGCAATCATAGAGATGAGAAATGAGACCGATGTAGAGTCGTTTGGAAACAGCGGAGATGAAGCTTCCCATCAAAACCACACACTTGCGCATCCAACGCACGGCCGCAGGCCGTCTTTCCATCGCACGAATACCGTGTTCACGGATTTCTTGCCTTACAACCAGGTGCGAACCTGGCAACAGGTTGATAATGAGGAATATCAAGACCGTTGTAGGCATTCCTTATCAGCTATTGCGTTGGATAGAATGAAAAAGCTCAATCTAGACCGCGATACACTATCGGCTCAAAGGAAGAAGACTGCAAATCAGTTGAAGAAAGTGATCGAACAGCACATACTTGACAAGGAGAAGTCAATTTCATAG
->XM_004366041.1 Dictyostelium fasciculatum hypothetical protein (DFA_12355) mRNA, complete cds 
-ATGGAGGATCAGAGCAGTCCATTTCTTGTCGATACAAAAGATACAACAACGACAGATACAACTCAACAACAACAACAACAACAAGAACATGTTCAACAACAAACAGCAGGTCAACTTGACGATAGAGTTGATCAAGAAGAATCGATAACTATGGGTGATGATCAAAATATATCAAGACAACAACGACAAAGAAGACTACTGTTGGTGAGCAAACCAAGTGCATTCTCGGTTGGTTATGAAAGAATAATGAAAAGATACTTTAAAGATTATGAATCATTGATGAAAGAGCATTTCAAACAACTAGAAGATCCATTAAAAAAGGTTAACTTGATTGATAGAAGAATAGAGAAACAAAAAGCTTGTATACCTAGAAATGTGGCATTGTTACAATGGATTATTCAAGGTCAAACAAATCAAGATCAAAGATTAAAGGTGATATCACCACCAAATTCATTAGAGTCATCACCATCTGCGTCACCTTCATCAAAAGATGGTGCTCTTTCATATCAAGAACAACAACAACAACAATTGTATGATGAAGAGAATGATGATATTGATAGAGATGATCAATTCCCAAATGAATTCACATCAGAGGATATAAAACAAAAATTGGAAACTTGTTTAACAAATATTGTTAGAGATTGGAGTTTTGATGGTAAAAGAGAAAGAGATCAAACCTATTTACCAATTTTAAATGATTTACAATCAATTTATCCATTGGAAAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATAATGGAAATAATAATAGAAATTCAATTAAAGTTTTATGTCCTGGATGTGGTCTTGGTAGATTAGCATATGAAATAGCATCACTTGGTTTTGATACAGAATTAAATGAACAATCTATATTTTTTATTATACCTCTAAAGAAAATATTAACAACAGAATTTGAAAATATTGAATCAAAGACTGTATATCCATACATTTCAATTTTAAAGAATACTAAAAGTATAGATTCAATTACTAAACAAATCAAGATACCGGATATCATTCCAGACAGAACGGTGATTGATAGAATGACATTGGCAGAAGGTGATATTTTCGAGTTTTATGAAAGCACTACGCAGTGCTACCAATACTTTGATGTTGTTACAACTTGTTTCTTTATCGATGTAGTTTTGGATATTTTACAACTTTTCAAAACCATTTCATCGGTCATCAAACCCGGAGGCTATTGGATCAACAATGGTCCATTATTTTATCATTTCAATGAAACTTTAAATCTTTCATACGATGAAATTATTATATTGGTTGAATCGTATGGTTTTACAATTCTTAAAAAAGATATTTTACTAGGTTTATCATATACCAATAACAAAGATTCATTATATCATCCAAATTTTGATAGTGTATACTTTGTTGCAAAGAAAAATACAATCAACAACAACTAA
->XM_023231809.3 PREDICTED: Piliocolobus tephrosceles aminomethyltransferase (AMT), transcript variant X2, mRNA 
-GAACCTGGGAGGCGGAGTTTGCAGTGAGCTGAGATCCGGCCACTGCACTCCAGCCTGGGTGACAGAGCCAGACTCCGTCTCAAAAAAAAAAAAAAAAGAACTGGGACCCTTCTGCCATCTGACATAGTCCAAAGCACATCCCTATCCTTTCTCCCAGTTGTCTCGCTCCTTTTTTTTTTTTTTTTTTTTTTGTTGGAGTTCTGCTTTTGTTGCCCAGGCTGGAGTGCAATGGTGCAATCTCGGCTCACTGCAACCTCCACTTCCCAGGTTCAAGCGATTCTCCTGCCTCAGCCTCCCGAGTAGCTGGGATTACAGGCATGTGCTGCCACACCCGGCCTGCCCCTTTCCAAGAGAGATGCTCAGCATGATGAGAGATCAGCCAGGGTAGGGAATGGGTCCGAGTAAGGGTTTGCATTGTTGCCTTTTAAGAGGCCTAGGTCCTCCATTAACTCAGGCCAACCATTAAGTGATGCAGGCTGCTCTTCCTTCATGTGAGAAAAACCTGTTTCCCTCTGGTTCTTCCTGACTTTGCACCTGGTGGCTATTATGAAGCAGTACTGCAGTATGTCTTGGACCTGGAAAGTTGGACATGCGTGCGGCTCAACAGTTTTCTCGGAAGAGTTCAGTGACCTTTTGGTGGCCACCCTCTGCTCTTACCTATGAGTTCTTCCAGGTGGCGACTTTACCTGCAAGGTCACTTACATAGCCCCACTCAGCTGCTTTGGAAAGCATGATGGAGCAGTAGTCCTCAATGTGTGTGTGAGTGAAGAGGACCTTGTGGTAGCAGGGACCATGCTTCATTTGTGGCTGCATCCCCGTCCGAGGGCCTGGTATGCAGTAAGATCAATACATACTTGTGGAATGCATGACTCTGTTGGCTGCCTGTGTCTGCCTGGTGGGAGAGCTGTGGACCTAGGGGTCCACATGAGGCCAGACTACTGTGGTGCTGCCTACCTGCAAGGCTGGCTCCACCCTGCTGTGACCTCTCCACCTTCCCCACCCCTACTTGACCTTACTCCCTTGAGGTCCTAAAGGTACGATTCAGACCTTTCCGCCCTTTCTGGAACTTTGACTGTTTGGAGACAGGGCGGTTCGGAGACAGGGCAGTTCGGAGACAGGGCGGTTCTGCAGGGGGCAGTCTAGCCCCTAGCTCGCTTCTGGGCAGCCCAATCAGCTCTGGATTGCCCAAGCTGCCCTGAAAAGCCAGCCGAAAGAGCCGGAGGCTGCTTCCCTATGGTTGGGAGTTCCTGCATTCTCTGCTCTAAATCCCAGCCTGCCCTCGGGGCTGCCCACGCCCCCTTCAGATCCTTTGCTCCGGAGAGAGACCTGTCCGAGCAGAGGCCTGGACTACATCTCCCGGCGTGCCTGGCAGTGTGGTGTCCTCTGTGCGCCATCTGTACTTGTTGCAGGCGACGATGCAGAGGGTTGTAAGTGTGGTGGCCCATCTGGGCTTTCGCTTGCAGGCATTGCCCCCGGCCTTGTGTCGTCCACTCAGTTGCGCACAGGACGTGCTCCGCAGGACACCGCTCTATGACTTCCACCTGGCCCACGGCGGGAAAATGGTGGCGTTTGCGGGTTGGAGTCTGCCAGTGCAGTACCGGGACAGTCACACTGACTCGCACCTGCACACACGCCAGCACTGCTCGCTCTTTGACGTGTCTCATATGCTGCAGACCAAGATATTTGGTAGTGACCGGGTGAAGCTGATGGAGAGTCTAGTGGTTGGAGACATTGCAGAGCTAAGACCAAACCAGGGGACACTGTCGTTGTTTACCAACGAGGCTGGAGGCATCTTAGATGACTTGATTGTAACTAATACTTCTGAGGGGCACCTGTATGTGGTGTCCAACGCTGGCTGCTGGGAGAAAGATTTGGCCCTCATGCAGGACAAGGTCAGGGAGCTTCAGAACCAGGGCAGAGATGTGGGCCTGGAGGTGCTGGATAATGCCCTGCTAGCTCTGCAAGGCCCCACTGCAGCCCAGGTACTACAGGCCAGCGTGGCAGATGATCTGAAGAAACTGCCCTTCATGACTAGTGCTGTGATGGAGGTGTTTGGCGTGTCTGGCTGCCGTGTGACCCGCTGTGGCTACACAGGAGAAGACGGTGTGGAGATCTCGGTGCCAGCAGCGGGGGCAGTTCACCTGGCAACAGCTCTTCTGAAAAACCCAGAGGTGAGGCTGGCAGGGCTGGCAGCCAGGGACAGTCTGCGCCTGGAGGCAGGCCTCTGCCTGTATGGGAATGACATTGATGAACACACTACACCTGTGGAGGGCAGCCTCAGCTGGACACTGGGGAAGCGCCGCCGAGCTGCTATGGATTTCCCTGGAGCCAAGGTCATTGTTCCCCAACTGAAGGGCAAGGTGCAGCGGAGGCGTGTGGGGTTGATGTGTGAGGGGGCCCCAATGCGGGCACACAGTCCCATCCTGAACATGGAGGGTACCAAGATTGGTGCTGTGACTAGTGGCTGCCCCTCGCCCTCTCTGAAGAAGAATGTGGCAATGGGTTATGTGCCCTGCGAGTACAGTCGTCCAGGGACAATGCTGCTGGTAGAGGGTTCCTGAAATGCCGACCCAGTGCCTGCCTTCCTGGCCTCCAAGACAAGCTTGGAATAGGTTCTCCTTGAAAGGGGCCAGTCTATAAGAATGGAGATATTGCCCATTGGGCACCCCATCCCTGCTCCTCCAGGGAGCTGGCATCACCTCTCCCCTCCCTGCAAGTTGTTGCATCTGGGTCCCAAGGGGCAACAGCTTCCAGGATGTTCTCTCTCTCACTGCCCTTGTGCATGCATACCCTTGTTCTGTCTGAATAACCACAACAACTGATGCACTTCCGTGTTTAATAAGCCACATCCTCAGTTGAGCCTGAGGTGAAATGTGA
->XM_035095448.1 PREDICTED: Chelonus insularis structural maintenance of chromosomes protein 5 (LOC118074325), mRNA 
-AAAAATAGAAGACAATAGCGGTATGACAAAGAAAGATCGGAAAGGAAATGCGCAGTTATTCAGTTTCCCTCTAAAAAAGTAACGTAGAGGGTTAAAACAATTCGTTCGTGAACTTTACTTGTTTATTCGTGATGTAATTAAACTTTTCAAAATGACAAATACGGACATCATAAGCCAAGGAATCATTAAAAAAATTTTCCTGAAAGATTTTATTACATATGATGAGATAGTTTTCTTGCCTGGAAGATACTTCAATGTTGTCATAGGACCAAATGGTACCGGTAAGTCTACACTCGTAGCAGGAATAGCCTTAGGGCTAGGAGGATGTCCTAAAGATCTTGGTAGAATTGGTGAAATTTCTCAATACATAAAAGGTCAATGTGAAAAAGCATTGATTGAAATTGAACTTGAAAATGGACCGAACGAAACTGTCAAAATCAGTCGCATGTTCAATACAAGGAACAGGTCTACATGGATGATTAATGGAAAAACTGTTACTGAAGCTGAAGCTCAAGATTTGATTGCAAAATTCAATATTCAGGTGAACAATCTTTGTCAATTTATACCGCAAGAAAAAATTAATGATTTCGCAAAAATGAGCCCACAGGAGCTGCTATTAAATACAGAAAAGTCTGTAGGAGATCCAAAAGTATATGATTACCACATGCAATTAATAAGAAATAAGCAAAAACAAGAAGAAATATCTAACGAAATTGGTCAGAAAAAAACTGTGCTTGAATCTGATACTCAAAAATATCAACAATTAGATGAAATTGCTTCACAATATAGAGAAAGAAAAGCAATTATGAAAAAAATAAAAAATTTGGGACAAAAAAAAGCTTGGGTACTGTATGATATGACAAGAACAGAACTGATTAATTTGAAACATCAAAGCAATGGTCTTAAGAGTCAAATATCTGATCTAAAATCGACTTTGGATCCCATTTTAAGTCAAATGAATGAAAAAGGCAAAAAAATAAAAGAATTAGAAACTTCTGTTCAATCTTACAATCTACAAATTAAAAATTGTGAAACTAAATTATTAAAAAATATTGAAACTATTGAGAGTCTTCATCTTAATGTAATAAATATAAAGAAAAATTGCAAAGAAGAACTAAAAATGGAAGAAAGTCGAGATAAATCTATTAAACTTGAAGAAACACATAAAAGTAAATTAGAAAATGACATGCAGCTATTGATGGAAGAAATCGGTACTGAAGAATCAGTTCATAAAAAATTACAAGTAATCAATGATAAAATAAACAACGAAAGAAAAAAAATGGATGAAATTAATAACGAAGCTGTATTTTATAGAGAAAAGTTGAATCTTGTAGCACGTAAAATACATCAACTAGAAGGAGAATTAAAGCAGCTTAGCGATGTTCAGTCGAAACGTTTAGATTTACTTCGTTCTATGAATTCACATGCTTATGAAGCAGTTATGTGGCTTCGAAATAATAGAGATAAATTTCGAAGTGTCATTTATGAACCTATGATTTTACATATCGATATTAAAGAACTTAAATATGGTAAATTTTTTGAAAAGATAATTCCTAGACGAGATTTGGAAGCTTTCGTTTGTGAAGATAAACAAGATATGAATCTTTTATTAAGATATTTACGCGATCAGCAAAATCTAGTAGTCAATGTAGTCCATTCTGATTCAACTGAATCATTAAGTACTGTACCCAGGATACCACTCAATAATCTTACACGATACGGATTCTATTCTTATGCAATTTCTTTTATTTCTGCTCCTGACTTAATTATGAAGTATCTAATAAAAACATACCATATTCACAATATTCCATTTGGTACAGCTGCTGTAGACGATAACATTGATGCAGTGCCTACTGAGTTATTCTCTTTTTTCAGTCCTAATTATCATTATAATGTTCGAGTATCTAGGTATACTAAAGACAAATCCACACAAATTAATCCTTTGCCAAATCATGTACGAATGTTTTCTATTGTTGTGGATCATAACAAAATTGCGGAAAATACTCAATTATTAGAACAAAGACGAAATGAGCATGCACAACATGAATCGAAATTAAGAGAGACTGAAACAAAGTTGATGGAATATAACGATAAAATGGAATCGCTTCGTAAGTCAAGAAAAGATTTAGATACTAAGAGTAAACAAATTCAGATGCTTAATAGTCAAATCAAAAGGAAAACTAATGAAATTATACAGCTTCAAAATCAACGAAGGAGTTTTGAAGATATTAAAAATGCTGCAAATAATGCAATACTAAGTGTTTTGAAAAAACAAACAGAACTGTATAAAGAATGTGCTGGAGAGCATAAAAAAGCGATTGACATTATTAAACAATCGAAAACTAACAATTTTTTATTGAAATTAGCAGAACGTGAGTTAAAAAAAATTTCTGATAGTTCGAGACAATATAAAGACCAACTACAGGAAGTGGAGAATGAATTCAGAACATTGGCCAGGCAAATAGAACCAATGCAAGTTGAGATTAAAAGATTGCTTGGTGAAGCTATACGTTCCACAGACAATGTCAGTTCTAGCGATAGAGCAGCATTTGCTAAATATGAAAGAATCTTTGCTAAATTACCTCCGACAATTGAGGAGATAGACGAAGCTATTCAGTCAGCTAAAGCTCGACTTTTCTGTGCAGGTGACACTCATCACGGCGAAGAAATCCTTGAAGAATGTGAATTAGTTAAACGAAAAATTGAATCACTTAAAGTAGAGATAGAAAAATTAGAAGAAACATTAGCGAAAAATAAAAGAGATACAGAGGAGTTACGTGATCAGTGGTTACCACTAATTGAAAAGCTTACTCGTACGATTAATGGCAAGTTTTCAAATGGTTTCCAATCAATTGGATGTGTCGGTGAAATACAACTCAAACATAATGGAAATCCGATGGATTTTGATCAATATGAATATAAAATTTACGTTAAATTTCGAGATGTTGATGATTTACAAGAGTTCAATATAAACCGTCAAAGTGGTGGTGAACGAGCTTTTACAACTGCTGTTTACATGCTGTCTCTTCAAGAGATGTGTCGAGTGCCATTTAGAGTTGCTGATGAAATAAATCAGGGTATGGATGCTATTTATGAAAGGAAAATATTTGATAAACTTGTTGAGCTTACGTCAACAGCACATGGATCACAATATTTTTTGATTACTCCCAAGTTACTTCCTAATTTACAATACAACGAAAATGTAAGAGTTCATGTTGTTCACAATGGGCCATATATTATTCCATATGATAGATTCAATCTACAAGATTATTGTGCGAAATTGGAAAGGAATTAATTATCTTTAACTATATATTGTATTATATTTTTGTTCTTTATCATTTTTATTTGATTGTTTTTAATTATGATCTCGTTAAAACTGACAAAGTCAGTGTACGCATTTCCAATACATGCAATATAATTTATCTTTGAGTATTGCATTGACTATTATCTTACTTTCGATTTATTATTATTAAAAAAAATTTCTCAAGTATTATTCTATGAAAATAGCTTTGCTTGATTCTGTTTATTTTATGAGCCAGACAAAAATATTGTAGAAAAAATAAGCAAAATAATTACTATCAAGAGTTTTAATCA
->XM_013003374.1 PREDICTED: Erythranthe guttatus uncharacterized LOC105977970 (LOC105977970), mRNA 
-CAAAAACCTCACCAAATTTCCCCAAAATTGATTCTTTCGTTCTTCACTCAAATCAATGGCGTTGTCGATAATCCAATGCCCTAAACACTCAAAGTTTCCGCCCAGCAATTATTTTCTGAAAGCAAATTCACTCCCACTTCACCCCACATTTGTCAGGTTTTCCAGATTACAGCCAATCAGCAGCAATCGGGTGGTTTGCGCCGCATTTTCTGCCGCCGGTGGTTCCGGTGCAAACGGCGATGTAAACCCTTACGAGGTTCTTGGTGTAAATCCTCTAGAGGGATTCGACATGGTGAAGGCGGCTTACACGAAAAGGCGCAAGGATGCTGAGAGGAGAGGCGATGAAGCTGCTGCAGCACAATTGGAAAAAGCATACGACACTATAATGATGTCTCAATTGAAGAAACGGAAGAAGGGCGAAACTTTCGGTCCGTTTCGGGTTTCGAAAGATATAAAATATGCCGATAAGCAGCCAATTGTTCCGTGGGGCCCAAGGTTTGCCAAATCGGAGGTCAAAGATATTCGAATCAACATGGCAATATCAGCTGTATTTACGGCTTGGATTCTTATCAAGGGCAGTGCCGAATACAAACCTTTGCAATTCTTGGCCTTTGTTTTCGTTTATCGGATATTTGAGAAGTTAAAGTCGTTCGAATCACCTGCACCTACCACATTTACAGAAGAAGGTGGTGAGGATGAAGGGAGAATGTTGAAAATGGGCAAAAGACTGCTTCGATCACTTGCATTGGGTTTTGGATGCGTCGCTTTTGCCTCTTTGGGGTACACTGCAGTGTTGAATTGTATTGAATTTGCAGCTGGCTATATACCTATTTTCTTGTACAACAACCAGGAGTTGTTTGTAACTGCGTCAACGGCACTAATGCTTTATGTTCTAGCTTCGTACTACAAATGAAAATTCTGCATCTATCAAGGGAGGATTGAAGATCGATTTATTTTATTTGGAATTAATTAGACGAATAATTCCGTGTTTCAAGATTTAAATTTTGTATATGAGTTCAAATTTTGGGACTTGATTGTAATGTGTTTAACTTGTTAGTGATATTGTTTGCGACTCCGAGTCGAAATCGAGAAAGTAAGGAACAAAATAGTTGCGGGTTGTGTGCTAAAAAAATTGCATTTTATA
->MW016101.1 Clionaida sp. 1 JV-2020 voucher UF 3823 large subunit ribosomal RNA gene, partial sequence 
-GAGCATGAAATCCCTGGCAGGTGCTGTCAGAGAATTGTGGCCGGGAGAGGCGGTGGAGCTCCGACTGTTGCTGTCGAAGTTGACCTGGAAAGGCACGTCAGAGAGGGTGAGAGCCCCGTGGTCGACACCGACGGGAAGGGCCGTAGCCGTCTTCGGAGAGTCGGGTTGTTTGGGAATGCAGCCCAAAGTGGGTGGTAAACTCCATCTAAAGCTAAATACTGGCACGAGACCGATAGCGAACAAGTACCATGAGGGAAAGGTGAAAAGTACTTTGAAAAGAGAGTCAAAAAGACCGCGAAACCGTTAGGAGGGAAACGAATGCAGCTGAAGTGGCTCCGTATCAGGTTCAGGGGATGTCGGTGGACGTTCCGGCTGCGGACAGCTAACGCGTCCTCGGTCGGAGAGGCTGCCGACTTCCTTGCACTCCTGTTGGGAGCCGGCCAACAGCGGTTGTTCCTGGCCCAGAAGGCCGGTCGGGAGGTACCTCCGCACTCGTGCAGAGAACGTATAGCCGTCCGGTTCGGCGGTCTGGGAGCGACCKAGGAGAGTCGTGAACTTTCACGCTTGCAGCGCAGGCCCCTCGGGGCCGGGTCGCCTCTGTTCGTTTGGGCCCCGCGGTTGGGACTGCTTGCAGTGTCTGCCGACGGTCAGCCTGCTCGGTCGGGGGATTGGCCACGCCTTGCGCTCTAGTTGTTGGTGCTCGAATGGCTGCATCCGACCCGTCTTGAAACACGGACCAAGGAGTGCAACATGCGTGCGAGTCTTTGGGTGGCAAACCCGTCGGCGCAATGAAGGTGAAGGCAGGCGTTGGTCTGCTTAGGCGAGAGCTTCCTCGGGAGCGCATCGTCGACCGATCCCAGGCTACGCTGTGGCGGGATTTGAGTAAGAGCGTGCCTGTTGCGACCCGAAAGATGGTGAACTATGCCTGAATAGGGTGAAGCCAGAGGAAACTCTGGTGGAAGCTCGTAGCGATTCTGACGTGCAAATCGATCGTCAAATTTGGGTATAGGGGCGAAAGACTAATCGAACC
->JQ151355.1 Uncultured bacterium clone J2_5_82 16S ribosomal RNA gene, partial sequence 
-AGTGAACGCTGGCGGCATGCTTAACACATGCAAGTCGCGCGGTCAGCAATGGCAGCGGCGGACGGGTGAGTAACGCGTAGGAATGTATCCAGAGGTGGGGGACAACCCCGGGAAACTGGGGCTAATACCGCATATGTCCTGAGGGACAAAGCAGTAATGCGCCTTTGGAGCAGCCTGCGTCCGATTAGGTAGTTGGTGGGGTAATGGCCTACCAAGCCTGCGATCGGTAGCTGGTCTGAGAGGACGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGTCTTCGGATCGTAAAGCACTTTCGACAGGGACGATGATGACGGTACCTGTAGAAGAAGCCCCGGTAACTTCGTGCCAGCAGCCGCGGTAAGCATACTCGTA
->AY190253.1 Dothideomycete sp. G11-R40 18S ribosomal RNA gene, partial sequence 
-GATTAAGCCATGCATGTCTAAGTATAAGCAACTATACGGTGAAACTGCGAATGGCTCATTAAATCAGTTATCGTTTATTTGATAGTACCTTACTACTTGGATAACCGTGGTAATTCTAGAGCTAATACATGCTAAAAACCTCGACTTCGGAAGGGGTGTATTTATTAGATAAAAAACCAGCGCCCTTCGGGGCTCCTTGGTGATTCATAATAACTAAACGAATCGCATGGCCTTGCGCCGGCGATGGTTCATTCAAATTTCTGCCCTATCAACTTTCGATGGTAGGATAGTGGCCTACCATGGTATCAACGGGTAACGGGGAATTAGGGTTCTATTCCGGAGAGGGAGCCTGAGAAACGGCTACCACATCCAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCCGACACGGGGAGGTAGTGACAATAAATACTGATACAGGGCTCTTTTGGGTCTTGTAATTGGAATGAGTACAATTTAAATCCCTTAACGAGGAACAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAACCTTGGGCCTGGCTGGCCGGTCCGCCTCACCGCGTGTACTGGTCCGGCCGGGCCTTTCCTTCTGGGGAGCCGCATGCCCTTCACTGGGCGTGTCGGGGAACCAGGACTTTTACTTTGAAAAAATTAGAGTGTTCAAAGCAGGCCTTTGCTCGAATACATTAGCATGGAATAATAGAATAGGACGTGCGGTTCTATTTTGTTGGTTTCTAGGACCGCCGTAATGATTAATAGGGATAGTCGGGGGCATCAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAGTGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGGCGATGTTATCATTTTGACTCGCTCGGCACCTTACGAGAAATCAAAGTCTTTGGGTTCTGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGAAATTGACGGAAGGGCACCACCAGGCGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTCACCAGGTCCAGACACAATAAGGATTGACAGATTGAGAGCTCTTTCTTGATTTTGTGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGCTTAATTGCGATAACGAACGAGACCTTAACCTGCTAAATAGCCCGGCCCGCTTTGGCGGGTCGCCGGCTTCTTAGAGGGACTATCGGCTCAAGCCGATGGAAGTTTGAGGCAATAACAGGTCTGTGATGCCCTTAGATGTTCTGGGCCGCACGCGCGCTACACTGACAGAGCCAACGAGTTCATCACCTTGGCCGAAAGGTCTGGGTAATCTTGTTAAACTCTGTCGTGCTGGGGATAGAGCATTGCAATTATTGCTCTTCAACGAGGAATGCCTAGTAAGCGTACGTCATCAGCGTGCGTTGATTACGTCCCTG
->XM_019758284.1 PREDICTED: Branchiostoma belcheri mitochondrial dicarboxylate carrier-like (LOC109461823), mRNA 
-TCGCGCGGGAAACGCCCCTCGTGGGGTCACCAGAGTTCATCCGCCATCTTGTTTACGAAGTTGTTTGTCTCTCACAACCTGCACGTCAGCTGGGTACGTCACGTAGGTCACGTGCGGCTTCGCTCAAAGGTCGTTTTTGTTGCAGACATTGCATGTTCAGCTTTTCGGCGTCTGCAGGCGCGCCTGGCTGCTCAGTGCTGCCCAGTTTGTACCCGATGGTAGGACGCTTGCTTTTGGCCACGCCACGTCACAGGTCACCGCCCCCCTCCCCACCATTCAAATCATCAGCCAGCTTCCTGCCAGGATTTGTACGTAATGATGGCCATGTGACATGTGATCGTGCGTGAACAGATGATTATACCCTCGGGACGTCTTTGTTTAGCTGTACTGAAGTCGATCGGATCCATGGAAACGTAGCAGCCCGGTGTACCTTATTGTTTGCTGACTCACAATGATTGCAGCTTTTTTGTCAAAAATCACAAGTTGAACGGAGCTCTTACACGTACGTCACCACGCCACGCCAGGGAGGTCGTGACTTTTCCAGCGCCCGCTTGCTTGAACTGGACTGGATGTGCTGTCAGCCTGACTTGTAAGACTATTTATTCAAACGTTGAAACAAACAAGAGACTTGTGTACAGTTTGCTCATCTGTTTACCTTAGTCTCCACCATGACGTTCCTGGGATTTGCGGACAGTGAAGAACTGAAAGCTAAGAAGATCGGAAGATGGTATTTTGGGGGCGTGGCATCAGCCATGGCCGCCTGCTGTACCCACCCACTAGACCTGCTCAAAGTCCACCTGCAAACTCAACAGAAGAAAGAGTTTGGGTTGTTGCAAATGGGTGTGAAGGTTGTGAAGGCGGATGGCATTGTAGGGTTGTACAACGGGATCACAGCGTCGGTCATGCGACAGCTGACCTACTCCATGACCAGGTTTGCCATCTACGAGACGGCGAAGAAGAAGCTAGCAGAACATTCGGGTGGCGCGAATCTGCCCTTCCACCAGAAGGTGATGCTGGCCTCGCTGGGAGGGTTCTGTGGCGGGATTGTGGGTACGCCGGCGGACATGGTGAACGTGAGGATGCAGAACGATATGAAGCTGCCGGCGGAGTTGAGGCGGAACTACCGGCACGTGTTCCACGGGTGGAGGTGCGTGGTGGCGGAGGAGGGCGTGAAGGGTTTGTTCTCGGGCGTGACGATGGCGTCGTCCAGGGCGATTCTGGTGACGGTGGGACAGATCGCGTTCTACGACCAGTTCAAACAGACGCTCCTGTCCACGAGCTTTTTTAACGACAACATCGTCACCCACTTCACCGCAAGCTTCCTCGCTGGTGGCGTAGCGACGGCCATGACACAACCGGCGGACGTGATGAAGACACGATTGATGAACGCAGCACCGGGGCAGTACTCGAGTATTTTGTCCTGCGCAATAGACATCGGAAAAGTTGGTCCATTTGGGTTCTTCAAGGGGTTTGTTCCAGCGTTCGTGCGTCTCGGCCCTCACACCATCCTCACCTTTATCTTCTTTGAGCAGCTCAGGAAGAACATGGGTGTGCTGCCTGCCTACACGGTATAAGCGCCATCTAGCCAACTGTACTGGCACTGCAGGACTTCTAATTCATGGCAATGAAAATCTCAAGGATCAAGTGGAAAAATGGACTCTGTTGCAAAACCATAGCAGTGATGGGTTGATGGTTTCAGTGTAGGGAGATAGTAGGGTATACATCAGTCTTTTGAAGAGGTAAATAGCAAAAGAGCATAACTGGCCTGCATGAAGGTTGTTTGCATCCCCATATGCTATGCATTCCCGTAGGCCTGCTTAATTGTGTTAACTGTGGCAGTATTAATTTTGGATATGTCAGACAAACAAATGTAATTTCCATGTCAGTGTTGCTATGTAATTGAACAAACATATAAATGGATGGTTTTCAAATATTCTAGCTCATCTCGGAACATATCAGCACCTTCAAGATCGGGACAATTACTAGTATACCTCCTCAATGTTGCATGATTTACCGGTAACCATAAAGAGCCAATTATTTCATGGACTTGTAGTAAAGAAAAATACAGCTGCCTTCATCCAGATGAGTTATATTGACCAACATGTCTATTCATATGAAGAAATAACTTGTAAACTAAATGTGATACAGCTCTAAAGGATACAAATGTGAATCAATATGCTTTTAGCAATTGAATATACAAACCAGTAGTTACTGTTAGTAAACACACCTATGGAACAACAAGATACCTTCTGAAAACTAGCTGTACATATAGATTTACTGAACAATCAGGAGATCAAAGAGGTGTGAGTGAGTTAAGCTTTGTTTTGTTTTGTTTTGTTTCTTCTCTTTATTTAATGCTTAGTAAAGATATCTGATCATAGATATTATTATAGCAAGGTGTATATTTGTGACCAAACTAGTTTGTACCAAATAACTACTAAAGTAATAATGTAGATCTTTTTTCATTTTTAGGTGATCAGTCATTTTAAGTAGAGTCTAAGCAAATTTGTTTTAACTTTGCTGTTAGATGTTTTCTTTTTATGGTTGTCAGATGTTCAATGTGTAATAAAATGCATCTGGGACCCAG
->XR_004573716.1 PREDICTED: Drosophila guanche uncharacterized LOC117582427 (LOC117582427), transcript variant X2, ncRNA 
-GTACACTCTCACTCACTCTCGCGCTGTCGCCCACGATACATGCAGCTTGCAAGCTCGGCGTCTAATCATTAGTAATGTGCCTATAACCGAAAGCAACTGCAGTGCAAATTACAAATATACAGTGTCAGGCCCGATGCCTCTGCAGCCCTCTGTCCTTTGCCCCAGAATGAAAAACGGAGGCAATCGGCATGGGATCGCCTCCTCATCGCCTCTACTGAAAATATGGGATCGAAGATCACTTGAGATGAAGAATTTCATCTAGCTTTCACTCACCATCAAACGCGGAAGACCAGCAGTCT
->XM_043480802.1 PREDICTED: Cervus canadensis olfactory receptor 56A4-like (LOC122449258), mRNA 
-ATGCTGCCTTATAGGAACACCTCCCTCTCTACTGAAGTCTCTGAGTTCCTCCTGAACTGTTTTGTCAGGTCACCCACCTGGCAGCTCTGGCTGTCCCTGCCCCTCAGTCTCCTCTTCCTCCTGGCCATGGGGGCCAACGCCACCCTCCTGCTCACCATCCGGCTGGAGGCCTCTCTGCACGAGCCCATGTACTACCTGCTCAGCCTGCTCTCCCTGCTGGACATGGCGCTCTGCCTCACTGTCATCCCCAAGGTCCTGGCCATCTCTGCACAGCTCCATTATTGTGGAAAAAATATAATTGAAAACTGTATCTGTGCCAACCTCTCCGTGTCCAAGCTCTCTTGTGGTAACATCACCCTTAACAAAATCTACCAATTAATTTTAGCCTGGACTCTGCTGGGCTCTGACCTCATCCTCATCTTCCTCTCCTACATCTTCATCCTCCGAGCTGTCCTTCGACTCCATACAAAAGGAGCAGCTGCTAAAGCTCTGAGCACCTGTGGCTCTCACTTCATCCTTATCCTCTTCTTCAGCACCATCCTGCTGGTTTTTGTTTTTACCCATTTGGCCAAGAAAAAGCTTTCACCTGATATTCCTGTCTTACTTAATGTCCTCCACCATGTCATTCCTGCAGCTCTCAACCCAATTGTCTATGGTGTTCGAACTCAGGAAATTAAGCAGGGGATTTGGAAATTATTGAGGAAGGGTAGTGACAGCAGAAAGTAA
->XM_014024072.1 PREDICTED: Austrofundulus limnaeus gelsolin-like (LOC106528817), mRNA 
-CCCAGGGCAGCACCAACAGGATGTGCAGAAAACAGGAAGGGCTGTGGCACGGCTTCTTCTTCTTCTCCTTCTTCACACTCAACATCTGACTTCTGTCTTCAGCAGACCCGGAGCAACATGGCCCACAAAGAGTTCGAGAACGCAGGGAAGAAGCCCGGCCTGCAGGTGTGGCGGGTGGAGAAAATGGATTTAAAACCCGTTCCAACTCAGCTCTACGGAGACTTCTTCACCGGAGATGCCTACATTGTGCTCTTCACCACCCCGGCACCTTCTTACGCTCTGCATTCGTGGACCGGAAATGAAGCTTCCCAAGATGAAGCCGGAGCCGTTGCCATTTTCCTGACTCAGATGGATGACTACATGAAGGGACTCCCGGTGCAGTTCAACGAGTTTCAAGGTGAAGAGTCGACCTGTTTTCAAGGCTACTTCAAGTCTGGAATGAAGTACAAGAAGGGTGGCGTGGCCTCAGGCTTCCATCATGTGGTGACCAACGACATGAACGTGAAGCGTCTGCTGCACGTTAAAGGTCGTCGTCTGATCAAAGGCACTGAGGTGGACCTGAGCTGGTCCAGCTTCAACAAGGGAGACTGCTTCATCATTGACCTGGGAAAGGACATCTACCACTGGTCCGGCAGTGAAAGCAATCGCTACGAACGCCTCAAAACCACTCAGATGGCCAACGACATCCGCGACAACGAGCGAAAAGGCCGCGCTAAAGTGCACATGATTGAAGAAGGTTCTGAGCCAGAGGCTGTCATTCAAGAACTTGGACCAAAGCCGGAGCTCCCTCCTGGGGAATGTGATACGGCAGAAGAAAAAACCCAGAAGACCAAGACATCTCTGTATCAGATTTCTGACGCCACTGGTAAAATGACCACAACGTTTGTGTCCAACGGTCCCTTCAAACAAAGCATGCTCTCCCAGAAGGAATGCTACATCCTGGACGATGGAGGAAACAACATATTTGTCTGGAAGGGAAAAGATGCAAATCCAGATGAGCGCAAAGCTGCAATGACTGCTGCAAAGACGTATATTACAGAAAAAAAATACCCCACAAAAACAAAGGTGCAGGTAATTCCTGCAGGAAGTGAGACCACGATGTTCAAACAGTTCTTCTTTAAATGGCTGGAGGGCGAGGCCACAGGAAAGACCTACACTGTGGGTCGCATCGCGAAGGTGGAGCAGATTCCCTTCGACTCCTCCAAACTCCACAGCAACAAGGCAATGGCTGCCCAGCACGGCATGGTGGACGACGGCTCCGGGAAAGTCCAGATCTGGCGTGTGGAGGGAAAGGATAAAGCAGCCGTGGACCCCTCCAGTTATGGACACTTCTTTGGTGGTGACTGTTACCTGGTGCTTTACTCCTACAATGATGGTGGCAGAACGAAGCATATCATCTACACCTGGCAAGGTCAGAAGTGTACTCAGGATGAGCTGGCTGCTTCAGCTTTCCTCACCGTCAAACTGGATGACTCCATGGGCGGAGTGGCCACACAGGTCAGGGTCAGTCAGGGCCAGGAGCCCCCTCATCTCGTCAGCTTGTTTAAAAACAAGCCTTTGGTCATCCACCTGGGTGGGACGTCCCGTAAGGGTGGTGACAGCACCCCTGGCAGCACGCGGCTCTTCCACATCCGTCAGAGCTCCACCAAAGCTACACGAGCTGTTGAGGTGGAACCCAAAGCCTCCTCTCTGAACACCAACGACGCGTTTGTGCTAAAGACACCATCTTCCCTGTTTGTGTGGAAGGGAAAAGGAGCGAGTTCAGATGAGACGTCGGCAGCTGAGTATGTCGCCAAGTTTCTGGGAGGAGCTGTCACCAAGCTGGATGAGACAAAAGAGCCAGATGGTTTCTGGTCAGCGCTGGGTGGGAAGGGCAACTATCAGACCTCCAAGGCCCTGCAGAACGTGATCAGACCTCCTCGACTCTTCGGTTGTTCAAACAAGACTGGCAGGCTCATTGCAGAAGAGGTTCCTGGTGACTTTACTCAGATCGATCTGGCCACAGATGATGTCATGATCCTGGACAGCTGGGATCAGATCTTTGTTTGGATCGGAAATGAAGCCAATGAAACTGAGAAATTAGGAGCTCCAAAAATTGCCCAAGAATATGTGGATTCTGACCCCGCCGGACGTCGTGGTGTCCCCATCACCACCATCAAGCAGGGCCAGGAGCCACCGTCATTCACGGGCTGGTTTCAAGCTTGGGACCCCCACATGTGGGACTAAGCTCATCATTAGAGCAGAAAGCATCGACTTACTAAACATCAGTAGTTGGATAAAATGCATAATCTTCACACAATGAGCTTAAGATTTTTATAGATGTAGATCAGATTTTAGACAAAATCTTATATGTCTGTGCTTTCAGTGTAACAGAAATACTCACCAAAGCTGAAAACTTACATATTTTGTGGCAATAAGCTGTTTTTCTTTTAATGAGGAACTGGCAAATAAAAATAATATGTGCTAATTTAAATGTCATATCCGTATTCTGGTTTAAATTTTAAAGAAAAATTAAGTTGACTCTAAAACAAATCATTAAAAGTTCTGAACCCCA
->KM104095.1 Uncultured fungus clone rcw_159 internal transcribed spacer 1, partial sequence; 5.8S ribosomal RNA gene, complete sequence; and internal transcribed spacer 2, partial sequence 
-CGGAAGGATCATTATCGTGCTTTGGGGCATGGCTCCGGCCGTGCTCCTCCAGCCCCACCCGTGTTTACCACACCTGTTGCTTCGGCGGGCCCGGCGGCCCTGGCCGCTGCCCCGGGGGGGGATGTTTTCTCCCTCCGGGTGTCCGCGCCCGCCGAAGACCCTCTGAACTCTAGTGACCTGTGTCGTCTGAGCTTCATGATCAAATCATTAAAAAACTTTCAACAACGGATCTCTTGGTTCCGACATCGATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAGTTCCGTGAATCATCGAATCTTTGAACGCATATTGCGCCCCCTGGTATTCCGGGGGGCATGTCTGTTCGAGCGTCATTGCAACCCTCAAGCACGGCTTGTGTGTTGGGCCCGGATGTCCCGGTGTGGACAGGCCCGAAAAGCAGTGGCTGGGATGTGTCTCGGCGCCCAAGCGTATGGGGACTCTTGTCACCCGCTTGCATGGCCCGGGCGGTCCCCGTCGACCTCTTTCTCTCCGGAAGGGCGCCCCCCTTTCGTCGGTTGACCTC
->XM_019782364.1 PREDICTED: Branchiostoma belcheri tryptophan 5-hydroxylase 2-like (LOC109480215), mRNA 
-ATCCATGTTCGTCAGAAGTTGTCTGAGAATCAGTTCCAAGATGTCGTCGGGAAGAAAACTGTTAGGGCGGCGGTTTTCTGACGTCTTCCCTTTAAACAACGGCAGCCGAGGCCCCCTTCTTACCAAGGACGGGACTGCAGGGGCAAGAACCCGTAGGCGCATCTCGTCTTTCCCTTGTGAGGAGACGTTTGCACCTGTTCGCACTCCGGTCATCCTGTCTATGAGGAAGGACGTTGGGGGCCTTGCTGCCGTGCTACAGTTATTTCAGGAAGAACAGGTCAGCGTTCTGCATATCGAGTCCCGACGCTCTCTTCGGCGGAAATCGGTGGTTGAAATCTACATGGACTGTGAGGCCGACAAGACCCGAATGAACGAACTGATCTCCCGGATTCAGAGGGAGACCAAGATGGTCAAGGTGGACACACCAGACAGCATCGGCAAGGGCAATGCACAAGATGAGGAGGGGTTTGAGGTTCCCTGGTTCCCGCGCAAAATCAGCGAGCTGGACAAGACGGCGTGCCGAGTCCTGATGTACGGAAACGACCTGGATGCCGACCACCCGGGTTTTAAGGACAATGTCTACCGGGAGAGAAGAAAGCTGTTCGCTGAAATCGCTCTGAACTACAAATACGGTCAACCTATACCCAGAATAAAGTATACCGAAGAAGAAGTGAACACATGGGGTGCAGTGTACCGTGAGCTGACGTCACTCTACCCGACACACGCCTGTCAACAGCACCTCAACAACCTGCCGCTACTGCGCATGTACTGCGGATATAGAGAAGACAACATCCCTCAGTTGGAAGATGTGTCCGCATTTCTTAAAGAACGAACAGGTTTCCAGTTGCGGCCGGTGGCGGGGTACCTGACACCACGTGACTTCCTGGCAGGACTTGCCTTCCGCGTGTTCCACTGTACCCAGTACATCCGCCACAGCACCGACCCCTTCTACACACCGGAACCGGACTGTTGTCACGAGTTGCTGGGTCACGTGCCCATGCTGGCCGACCCGAGTTTTGCCGAGTTCTCCCACGAGATCGGACTGGCTTCGCTCGGCGCCTCGGATGAGGAGGTACAAAAGTTAGCCACGTGCTACTTCTTCTCGGTAGAGTTCGGCCTGTGTAAAGAGGACGGGAAGATCAGGGCATACGGAGCAGGACTGCTGTCATCTGCCGGCGAGCTAAAGCATGCACTGACACAAGAGGATAAAGTTCTGCCCTTTGACCCGGAAGCTGTTGTACAACAGGAGTGTCTCATCACCACCTATCAGGACGTCTATTTCATGTCCGACAGTTTTGAGGAGGCTAAACAGCAGATGAGGTAATTTTCTCATTATTGTGCTTAG
->XR_008187289.1 PREDICTED: Carassius gibelio uncharacterized LOC128029018 (LOC128029018), ncRNA 
-CCATTACAGCAACAAACATTTTTAATGCAATTTTCTTTTTCAAAATTCACATCTGAGGTATGACAGTGTGTAATTTATATTGTAGGTTTAATAGGGAACATCTCTTGAATTCATGTTAATCACGTATCTTACTTTGCTTAAAGCTGAGCTAAACAGAACTAATTTGATTATTTTACCTTTTCAGCTGAATTGTGCCCAACCAGGGTAACAGTTGTCTGATTTCACAAGTGATTTTGCTCTTCCTGAAGTCCAGCTTTAAATTCAGAGCTTGATGTTGCAGCAGGTAATGAATCACTTCCCAGGTCAGTGAACAGGAAGTCAGATCTTTAGGCACCTTCTTCAGGAAAAAGCATGTCAGTTCATCATCCTGTGCTTCATACACCACTGAAACCAGCTGCTGAAGAGTTTCTTTAGAGAACCTGA
->XM_005997745.2 PREDICTED: Latimeria chalumnae BTB/POZ domain-containing protein KCTD6 (LOC102358416), transcript variant X1, mRNA 
-TCTCTATGGTTGGTCCTGTAGATATGATGCTGATTCCATGTTTTGGGTTGGCACGGCGCTGTTTTGAAACGAGCTTCGGGGTTTCGGGTTCAGTACGAGGGTTAAAAAAAAAAAAATGTTTGCTTATTTTTAAAGTGAAATCATTTCGAATGAGTGAATTTTGAGACAGTCAGAAGTCCTAGTTGGAATAAACTTTAGGTTTATGACGGAGAACCTTTCCAGATTATCATTGGAACACACAATTGAAAAATAAGAGCCACACTGGAGAACGGGAGGTGATTATTGCTTCTACCCTGCAATCTTTCATTGTTGAATCCTAAGAGAATTACTCGAGCATTGAAGCAGATGGATAATGGAGACTGGGGACATATGATGACTGATCCAGTCACGTTAAATGTAGGTGGCCACCTCTATGCAACCTCAATCTCCACTCTGACCCGTTACCCTGATTCCATGCTGGGAGCCATGTTTAGGGGAGGTTTTCCCACTGCCAGAGACTCCCAGGGTAACTACTTTATTGACAGAGATGGACCTCTATTCAGGTACATCTTGAATTTCTTAAGAACTTCTGAACTGACTCTTCCTCAAGACTTCAAAGAAATTGATTTGCTTCGAAAAGAGGCAGACTTTTACCAAATTGAGCCCCTGATCCAAAGTCTTAATGACCCCAAACCACTCTACCCCTTGGACACGTTTGAGGAAGTGGTGGAACTGTCAAGCACACGTAAACTTTCCAAATATTCTAATCCTGTAGCGGTCATTATAACTCAACTTACTATAACAACAAAGGTTCATTCTTTACTTGAAGGCATTTCCAACCATTTTACCAAGTGGAATAAGCATATGATGGACACGAGGGACTGCCAGGCTTCTTTTACGTTTGGGCCATGTGACCACCACCAAGAGGTCTCCCTTCGAGTTCACCTGATGGAGTATATTACAAAGCAAGGATTCACTATCCGAAATACAAGAATGCACCATATGAGTGAGAGGGCCAATGAGAATACAGTAGAGCATAACTGGACATTTTGCAGATTGGCACGAAAAATAGAAGACTGAAGCTGAATAGATCTTTTTTTGCTGTTGTTTTTTTTCAGTTGAAGACAGCATTAGTATCTCTTTGGAGCTGCATGAAGACCACTGTAAATACAGAGAAGAAAACAAAAATGATATGGGCTGTTCTTACAGCTACTTTTTGTTAATCGCCCTTAACAATGATTCTTTTGAAGATTGTATAGAAATTCCTCATAACTATGCATGTGCCTATTAAAGCTGCTATAGAACTAGAAAGTGACTTTCTCATTAACTTTTGAACAGATATCCTCTGTTTCTTTGAGAATATTAAAAACCACTTTAAGCTA
->XR_002182326.1 PREDICTED: Bos indicus uncharacterized LOC109569253 (LOC109569253), ncRNA 
-TTTTAGGACTGAAGCCCCCCCAGCTACCTCTGGCTCCTTGGGTGACCTAAAGATAATAGRCTACTCTGTGCACATGGGTCAGTGCCCCARAAAGGAGCAGCAGCCAGGACTGGTGTGGACCAGGCTGAGACATTTTAACCATACCCCTGCGTCCATTCCCAAAGCGCAAAGGTCAAAAGTACTCTGAGAACGTCCAAGGGGTCACATGCCACTGTCTGGTGGCTGGCATGGCTCTGATTGGTGAGAAAAGAGCACAACAGGGGAAAGGTGGGKGGGGCTCTCTCCTCTTGAAACCACAGGGCGTAGCTGCTGTTGAGGGCTGGCTGGGCTGRTCAAAAGCAGCTCCCACATRRGGACACATTGTCCTCCAGGCATCATCATRGGACATGCTGTGCTCTGGGAGGAGGGACACAGACRGTGACAGATTCTGCGGACAGAAACAACAAGCGTGGGGTKATCTGGGAACTTTTGTATCTGGGAGCCCAAGGGTGGGACCCTGGTTATCTTGCTGTGTAGTGACAAGCARCTAATAATGGAGACCTCAGAGCTGCCCATGTCAGAGGCATGAGGACATGGACTGCTGGTTCTGAGAYGGTTGCCTAGTGATACAGTGAGGAAAGGAYTAAGACCTAGAAGAACAAARTCACAGGATGTTAAGATTGAAGGAATCCACCTCTCAGTCTAGTTCCTTTGACATCATCTAYAACAAGTATCCTAACTCTACACTAACAGTCTCTTGAGGTTAGGCACCCCACTTGTTCATTCGTTATTGTGTCTACAGTGTGGTAGCCAGCCTCTGAGATTGATCCTCATCTCTGRYACTCATAACCTCATGTGGTCCCTCTCATATTAAAGAGGGCTGACCAACGTGATCAACAGGTTATTGYGAAAGTCATGGTACGTAACTCCCAAATGTGGAGCATAAAGGCCACAGCRGCTTCCATCCTGCTTTCTCTTGGACTCTGAGGGGAGGCAGTCACCACGTTGTAATGTTGTGATGAGGGACATCATAGGAAGCCCCATGGAGGGTCCRCATAGGAAGGTACTACCGCCYCTCCTCAACAGCCAGCACCGACTTGCCAGCTGTGTGGGTGAGCCTCCTTGGAAGAGATCCTCCAGCCTTGGTGGAGCCTTCAGATGACCACAGACCCAGRCAACGTCCTGCCTGCAACYTCATGACGCATCCTGAGTCAGAACCACACAGTCAAGCCACTGGCTTGCAGAAATCGCAGACTCCCAACCATTGGACCACCAGGGAAGTCCCTGCTGCTTAGCACCAAACACCTCCACTGATAGCCARCTTACCACCTCGYGAAACAATTGATTCTATCTTYGGACAACTCTGTTCAAGACTACCAAAATTAAATTGGTTCTTCCTAAA
->XM_001444626.1 Paramecium tetraurelia uncharacterized protein (GSPATT00012774001), partial mRNA 
-ATGTTAAAAAGTAATTCTTATCATCTAAAAACCAATAAGAAACATAAATCATCTCCATTAGCTTCCATAGAGCTACTACAAAAGTTATTGGATTTTAAATAAACGTAAACTTCCATGAATTGTTCCTAAGAAAACAAAACTCTAGTCATGAATGGGAATTTAGCAAAACAAATCTCGAAATCAATTTCAATTGGCAGTCAAAGTTGGAAGGATATAGCACCTCCAATTCATGAATCTGATAATTTGCTTAGAAAAAAGGAGGAAATCCTCAATACATTGAAGAAATCAAAGCATGTCAGACATATAAGTTAGATTTGGTCAATGAGAAATAGAACTGATAGTAATGTCCATACTCCAAGAAAAGAAGGGGTAAACGATTTTATTTAAAATGCAAGAATCTTTTTGAAAGAGAAACTATTAGAAAATAAGTTAGATAAGCTCTGCTATTAGGTTTAATAATTAAAAAATAAATCCGATATTTTGGAAATCTAAAATAAATTGCTTTTCGAGAACCTTAAGCAACATCATAATGACCATAATAACGTGCACGAAAGAAAGGTTTTGATGGGAAAGCTCGATTAAATGATAACGATGCAAAAGAAATAAGAATAAAGCTTAAATTATTTTAAGCAATTATTCCAAGAGAATGACGAAGGAAGGAGAGTGAAAACCTAAACCTCCTATCCCAAGCTGAGACCTGCCCTATACTCTGGCTACGTCGGATTAAAAATGTGA
->XM_047096667.1 PREDICTED: Lynx rufus CUGBP Elav-like family member 5 (LOC124524401), transcript variant X11, mRNA 
-ATGAAGGACCTGGACGCCATCAAGCTCTTCGTGGGCCAGATCCCGCGCAACCTGGACGAGAAGGACCTCAAGCCGCTCTTCGAGCAGTTCGGCCGCATCTACGAGCTCACGGTGCTCAAAGACCCCTACACGGGCATGCACAAAGGCTGTGCCTTTCTCACCTACTGTGCCAGGGACTCCGCCATCAAAGCTCAGACTGCCCTGCACGAACAGAAGACCTTGCCCGGGATGGCGCGGCCGATCCAGGTGAAGCCTGCGGACAGTGAAAGCCGCGGAGGGGACCGGAAGCTGTTTGTGGGGATGCTGAACAAGCAGCAGTCGGAAGAGGACGTGCTGCGGCTGTTCCAGCCCTTTGGGGTCATCGACGAATGCACCGTGCTCCGCGGGCCTGACGGCAGCAGCAAAGGCTGTGCCTTTGTGAAGTTCTCCTCCCACACGGAGGCCCAAGCGGCCATCCACGCGCTGCACGGCAGCCAAACCATGCCGGGTGCCTCCTCCAGCCTGGTGGTCAAGTTTGCCGACACGGACAAGGAGCGGACGCTCCGGCGCATGCAGCAGATGGTGGGCCAGCTGGGCATCCTGACGCCATCCCTCACCCTGCCCTTCAGCCCCTACAGTGCCTACGCCCAGGCCCTCATGCAGCAGCAGACAACGGTCCTGTCCACGTCGGGCAGCTACCTGAGCCCTGGCGTGGCCTTCTCACCCTGCCACATCCAGCAGATCGGCGCCGTCAGCCTTAACGGGCTGCCTGCCACACCCATCGCCCCTGCCTCTGGACTGCACTCGCCCCCGCTGCTTGGTTCCACTGCCGTGCCCGGGCTCGTGGCTCCCATCACCAATGGCTTCGCAGGTGTCGTGCCCTTCCCTGGGGGGCACCCTGCCCTAGAGACCGTGTATGCCAATGGCCTCGTGCCCTACCCAGCTCAGAGCCCGACCGTGGCCGAGACCCTCCATCCTGCCTTCTCCGGAGTCCAGCAGTACACAGGTACGGACGGCACCATGTACCCCACCGCGGCCATCACGCCCATCGCGCACAGCGTCCCCCAGCCGCCGCCCCTCCTGCAGCAGCAGCAGCGAGAAGGCTTCGTGAGCTTTGACAACCCGGCCAGCGCGCAGACCGCCATCCAGGCCATGAACGGCTTTCAGATCGGCATGAAGAGACTCAAAGTGCAGCTGAAGCGGCCCAAAGACCCGGGACACCCCTACTGACCGCGCCCACAGCCGCCCGGAGGCTGCGGGCCTGGCCCAGGTGAGCCGCCAGGCGGCCCCACCCGCCCCCACCCCCGCCCCCCACCCCCCCGTCTTGGCCAAACACCCCCTCGTTCTCCATGCCCTCCCCACCCCCCAGGGGGGATGCCGCTGGAGACCACAAGGAGCCCCCAGGTTGGGATGGTGGGGACAGAGCTAGAGAGTCACCCTCCAATCCCCCCTTTGATCAGGGCTGGGACAGAGGGTGGAACCGGGGTAGAAGGGGGTTGGGGAATCCTTCCAGAAGGTTTTGAAGGATGAATAGAAGTTCACTTGAGAGGCCAGGTTTGGTCTGGGGTGGGGCATGCTGCGAGGGAGGGGCTTCTGTCCTGTCCTGTGACTCTCCCAGCTGGGCCCCTGTCCAAGTTCCTCATTTGGTGTCACCCGCGTTCAGTGAACTGGCGAAAAAGTGGAATGTTTGCCCTGCTCACCAGCATGCCCCCCCCAAAGAGACCCCCCCCCCAACAAATCCCCAAGAGTGTATTTTGCCACCAGAGAGAACAACTTTATCAACAACTAAGCACCTTCTTTGGGGGAATGAACAGTGAGCCTAAGGGGCCAGTAGGGAAACATAACTGACCACAGCCTTGATGAGCCTCATCTGTGAAATGGGTTCACGAAAGTCGCCTCCCCAGAAGCAGCAGGGAGGATCCGCTCGGGGACGCGGTGTTTTCCCAGCTGAGCCCAGGACCCGCCACCTGGAAAGCTCTTGATCATTTGTTTTGATTTTGTTTTTGTTTTGTTTTTAATCATGAGCGCCGTCGTCATCAAAGCGCCGCGCCTGGGGTCTGGCGCGAAGTAGATGCTCAGTTAGGGGCTGCGCATGCTTTTCAGACCCTGCCAAATCAGCACCCGCAGAGTCGAAGGTCACGGGATCAGACAACTAACAGGCGACCCATGCACTTTAACACCCTGGGACAGCAAATCCTTTCTGAGCACCTACTATGCGCTAGGCACTGTTTGGGGACAGCGCTCGGGGACACAGCTGTGAATGACGAGAAACGGGGCGGGGGTTGGGAGAGAACTGCCTTCGTGGCAGGGAGCAGGGGAGACAAGATGAGACAAGAATAAACGCAACTGTTTGCCCCCGGGGGTTGCCAGATGAGGAAACAGCCTCGGTGGCCAGTCCTTTTCCAAGGCGGACCGCTGGCCTCTGAACCTGGAAATGGACTCTCTCTGAGCAGACAGGGGCCCTTGGGTTCCTGGAACCCAGCCTGGCCAGGGCAAGGGGGCGGGCGGGGGGCGATGTCGTCGGCCTGCATGCCCCCCATCACCGCACCCTAACGCCCCTCCCTTCTCCGCCAGGTGAGGGGCCTTCCCACCCCAGGAGGGCCTCCCGCTTCCAACCGACCCCGGACTTTTCCGTAAATTACAACCAAGTTTGGACACCAGCCCCACCCCCTCCCGTCTCCCCTTGCCCCCCCGCCCGCTTCCTAATGTGAAACACTACTGCGGGCCACACGGAGTGGGAAGGGGGCTTCGTGGTCCGCCCCAGCTGGGGAGGGGGGCTCCTGAGTTGGGGGCCGAGGGCTTCACTGCCCCCACCCTTGGTGGCTTCCCCAAATTAAATCACAACTTTTCCTATATATATATATATGCATATATATATAGAGCTATAGACAGTATATATATTTTTTGAGTATAGATCATGGGACCAAACTTTTCCGACTTCCTTCCATCCAAGAGAAGGTGACCCTGGCCCGGTCACTCAGCAGGGACATAAGAAGGGCTGAGGATGACCGGGCAGCCCAGTGTGTCCCCACCTCCCGCTGTCATGTCAGACCAGGGCACGGAGAAGCACTGGGAATCATCAGCCAACGCGATATACCTCCAGGACATTGGGCCCCTGCCACCGACGTTCTCGCAGGCCCTTGGGCTCGGCCAGCTCGAGTGTCCCTGGTCTTAGCTGCAGCTTCTGGAACCCCTACCCCCTCCCTCACCCCAGGGCCCTGCCTTCCCCGACATAGGCAAAGAAGAGACCCCCCCCCTGGCCTCCCACCCCCACCCCCGTCATAGCCTTACTCATGTGACCAATAGCCCTTAGCTTTCCGTCAGGGGCAGACAGGGTCGGGGGAGCCCCCCTGCCCCTCGCGCCCCCTCCCAAGGGCAGGCAGCCGCCCTCCCTGCCTTCGGATCACCAGCCTGGAGTTCACGATCTCATGACCAAGATCGCCACGCGCGTTGGACAAACCCAACCCGCTCTGGCCCAGCACCCCTTTACCAGAGATACCTCTACAAATAATTTTTTTTTTTGAATTTTGGTCTTTCTGAGAAGATACAAAGAAGAAAAGAGAAAAAAAAATGGGGAAAAAAAATCAGACAACAGTGGATTTTTGTTTCCTAGTTGGGGCGGGGAGGGAGGTCTTGTGGGGCGCCTCTGTATAGCTACTCAAACCGCGAAAACCCATCTTGAAGCACAGAGTCAAGTTCGTTGGACGTCCAGTGGGGCCTCTTGCCAAATGAGGCACCAGAGAACTTCATAAGCTCAAGAAAAAAAAAAAAAATTTGTAAAGAAAAAACAGCCTTCCCTTTTGTTTCTACCAAAATGTGTTGACCCAGAAAAAAAAAAAAAAAAAAAAGAAAAAAAAAACCACATAGCAAAAAAAAAAAAAAAAAAGGAAAAGAAAAAAAAAATCTTATGACCAACTTGTTTCGATATTCCAGAGTTTGATAATTGTTCCGAGACACTCTAGCGTGCCTGTGTCCTGTGCGTCTGCGTGTGCAAGCGTGTGCTCAGGGGCCACGAGGGGGCCTCGTCCGCGTCCCCGGCACCTGCCCAGCCCCGGCCAGGCCTGCTTGGGAGAGCGTGCTGGCGTGCAGTGGCGTTGTGTCCTTCTGGTCCATGTTTACTGGCTGTAAATACCATTTTTATACTCCACATCGAAGACCTACGTGATTTGTACGATGTACTTTATTTCTGCTACGAGTAATTTCATGAAGTTTCAACTTGCAAACCGACTTTTGGAGACAAATCGCCACACACACACACACACACACACACACACACAGAAAAGGAAGACAAGAAAGGAACTTACAGGGAACTTTGGGTGGACTGGGTTTGCATTTCTGGCTGGAGAGGTCCTTGGCACTGTGGTGTGTTTCAGGTGAGAAGCTGCAACCATCATCTTAATGTCCAAACGCCTCTCTTTGGTCTGGAGAAACTGAAAGTTTATTTAATAAAAGTTTTACTTGCTAAA
->XM_016552280.1 PREDICTED: Sinocyclocheilus rhinocerous general transcription factor IIH subunit 3-like (LOC107740007), mRNA 
-AAACCCTTCAGTGAATCCACAGAAGAAGAGCTCATTATGAGTCGGAACACAACTTTTAACAATATTGGAGGAAATACTAACTGAAATACCTTTACATAGCGATTTAGAGATAAAAGAATCGCAATAATGGCCTCTGACGACGAAATTAATATTCTGGTCATTGTGTTAGATGTCAACCCTATTTGGTGGGGCCAGCAAGCTCAGCGGGAACCTCAGTTCACTCTTTCAACATGCCTGGATTCTTTGATGGTCATGGCAAATGCCCATTTAGTGATGTCAAGAACCAACAAACTAGCCGTCATTGCAAACCTGTATCAAAAGAGCCACTTTCTATATCCAAGTAAGCAGTGGAAATCAGGGGATGAAATATCTGTAAGTAGCGATGGCAAATATGAACTTCTGTCAGTTACCAATGAACTCTTTGCGGAAGAGATCAGGAATCTCATGGACAGAACAGAGGTCAATGGCAGTCAAACAGACAGCCTGTTGGCCGTATCACTCGCCAAAGCTCTGTGCTATATTCATCGAGTCTCAAAGGATGTGCAAGCTGGACAGGACATGAAATCAAGGATTTTGGTAATAAAAGCTGCTGAGGATTCTACATTACAGTATATGAACTTCATGAATGTGATCTTTGCAGCACAGAAGAAGAATATCCTGATTGATGCCTGTGTGTTGGACGCTGACTCAGGACTGCTGCAGCAGGCTTGTGACATAACTGGAGGCTTGTATCTCAGAATTCCCCAGAAGATCGCACTCACACAGTATTTGTTGTGGGTATTTTTCCCAGACACAGACCAGAGATCCCAGCTGTTATTGCCTCCTCCGACATTCCTGCTTGTGACATAA
->XM_045728814.1 PREDICTED: Procambarus clarkii trans-1,2-dihydrobenzene-1,2-diol dehydrogenase-like (LOC123746912), mRNA 
-AATTTGTATCTGGCAACCCTGAGTCGCCCCGGCCGCTCGAGATTTGACTTGACATTTCAGCAGCAACATGGCAACACGGTGGGGCATAGTAAGTGCCGGTCTGATCTCCAATGACTTTGTAAATGCATTGAAGGCCTTACCCCCAGGGGAGCACCGCCTGGTGGCTGTAGCTGCACGCTCACTTGACAGTGCAAAAAGCTTTGCATCAAGAAATGGAGTGGAAAAGGCATATGGGTCATATGCAGAGCTTGCTCAGGATCCTGATGTAGAGGTGGTGTATATTGGCACAATCCAGACACAGCACCTCGCTGCTGCTTCCCTCATGATCCAGTCTGGGAAACATGTCCTTTGTGAGAAACCCCTTTGTTTAAATGTGAAGGAGACTAAGCAGCTTATTCAACTTGCTGAGGAAAAGAAGGTTTTCCTGATGGAGGCAGTATGGTCAAGGTTCTTCCCTGTGTACCAGGAGATGACAAGAAGAATCAAGTCAGGAGAGATTGGAGACGTGGTGCAAGTTATCTGTTCCTTTGGCAAATCAGTGGAGAATGTAGAGAGGCTGCTGAAGAAAGAAACTGGCGGAGGAGTCACCCTGGAAATAGGAATTTACCCAGTGCAGTTTACCACACTAGTAATGGGAGGAAAGAAGCCACAGAAAGTGCTTGCTGGTGGACACCTGAATGCCAATGGTGTAGAAGAATCAACAAGTGTCTCGCTTGTCTACTCTGGACGACGCTTGGCTTCTCTGAGTGCCACCATCAGGGCATGTTTGCCTTCAGAGGCCTTTGTTATTGGCACTAAGGGCACTATCAAGGTGAACTATCCCATGTGGTGTCCTGAAAGCCTGGAGTCACCATCAGGAAAATTTGAGTCACCACTTCCCAAAACAGGTCACACTTTCAACTTTGATAATAGCCAAGGATTAATGTATGAGGCAATTGAAGTGAGACGCTGTCTTAAAGAAGGTTTGCTGGAGAGTCCAGGGATGAGCCACAAAGAGAGTCTCACTATTGCTGAAGTCATGGAGCAAATAAGACGACAGGTTGGAGTAGAATTTGACTAGAACATCAAGGCAATCTAACAGTGTTAAGCTTTCATATAAAGTCGTAAACTAATTGCTGTTATTGAAGACTGGAGCCCAACTATATACTGTATAGTGATAGCAATAAGATAATCAGTGGTATAGTATTAGAGTTCTTTTAGAATATTGTATTAATCTTTACTTTCATGACATCAGTAGTTTGCAGTATGGAACTGTACTTGTGTTTTCTAACATTTATACTCAATGATACAATCAAAGTTAGAAGATTCTTAATTCATTAATTAAGTTTTATTACCATCTCGGTTATTACAGAACAAAATTGTAATTTTGTCGTGGAAGTCAAAATCCTCATTAGTATGTAATTCATGTAATTATGGTTATTCACTTGTTTATGGAATACACGAAGTTTCAATTTGTTATGTAGCTTAATTCTGTTAATTTGTATTTCAACAAGTCCTTCATTATATCTTGAGATATATCTTGAGATGATTTCGGGGCTTTAGTGTCCCCGCGGCCCGGTCCTTGACCAGGCCTCCAGTAAGTCCAGTATAGCAGCTTTATAGTAAGAACTAACTGGTAGCATATTCAACTGTACCATGGAAATATGTACAGGAATTTGAGAAATGCAGACCATAATAAAATTATAAAATAATTGTAAGTTAATGGTCTGAAATGCTCAATTACTATGCAGTACATTTTTTTTCTCAACAATAGTAATGTTTTTATATTAAAAGGATTTTCTATTTCAGAATTCAGTTTTCTTAGTAGTACAAAAGATGGTGATATTGTTGACAGCAGCTTAAATTTTACTTGGCTTTACCTGTTGCAACATTTGTTTAAATTAATGGTTGTTAGAAAACTTCAGTTTGGTTAATTTTTCTATAAGTGAATGCCTGTTTTGCTCATTTAAAATTATTTAATAAAAATCAAATGTTCACACAATAACATAAATAGCCTTAGAAAATTTTAAGTAAATAACTTAACAAATGCTAATCTGCAGTAGCAACTAGACTGAACCAGAAATGAGTTACTTTACAAACTGCTCATAGAGCACATAATTCTTCTAGAAAATTTAATGAAACATTTTAGCTAATTAATAAGGCATGTGAAGTATCAAGAAAATTGTACTTTAACAAATATTAATGCAAAATCACTAGAACTCCTAGCCTGACCCTATGACTAAATGTATGTCAAATTACTTTCTTACAGTACAGTACTCTTACTTTGTCCATCATGCATAAATATATATAACTAGCACAATAA
->XM_028373142.1 PREDICTED: Glycine soja putative GPI-anchor transamidase (LOC114409625), transcript variant X2, mRNA 
-AAAAATACTCGAAGAAAGAGTTGGTTGTGAAAAACTAGAACTAGAAGAACTGCCACCAGAAGACGCCGATCTCGTTCGCCCGAAGAACTACCTAATTTATTTACACTCCCGCTGACGCCGACACCAAACTCATTTAATTCAGTGTTTGATTTGACCTACATGATCCTTAAACTACCCGAATCATCAGCTGTTTTGCGATTGCGGGATTGATTTGTGGTTGCAGTGAATGTGATGGAACACTTATTTGGTACCGGAAGAAAAGAAGGACAAGTTAGCATACTCCTCATCTGCGTTTGAGTCTACAATGCACACTAATAATTGGGCTGTTTTGGTCTGCACGTCTCGCTTCTGGTTTAATTATCGGCATATGGCCAATACCCTGTCATTGTATAGGACAGTTAAACGGCTAGGAATACCGGATGAGAGGATTATACTCATGCTAGCAGATGACATGGCATGTAATGCTAGAAACAAGTACCCTGCCCAAGTTTTTAATAATGAAAACCATATACTTAATCTGTATGGGGATAATGTTGAGGTAGACTATCGTGGCTATGAAGTGACAGTGGAAAACTTTTTACGGGTACTTACTGGACGTCATGAGACATCTGTTCCAAGGTCCAAACGACTTCTTAGTGATGAGGGAAGTCATATTCTTCTGTATATGACAGGGCATGGAGGTGATGAGTTTTTGAAGTTTCAGGATTCGGAAGAGCTTCAAAGTCACGATTTAGCTGATGCTGTGAAGCAAATGAAAGAGAAGCGCAGGTTTAAGGAGCTTCTGATAATGGTGGACACCTGCCAAGCCTCTACTCTTTTTTCCCAGCTTCATTCACCAGGTGTTTTGGCAATTGGAAGTAGTATGAAAGGAGAAAATTCATATTCACATCATTTGGATTCAGATGTTGGCGTTTCAGTTGTTGATCGTTTTACATTTTACACTCTTGCTTTCTTTGAGAGGCTGAATATGTATGACAATGCTTCGTTGAGCAGCCTTTTCAATTCATATAATCCAAATTTGTTGATGTCGACTGCATATTACAGAATGGATATATACCAACGCTATTTAAAGGAGGTACCTGTGACAAACTTCTTTGGTTCTGTAATGAAAACGATACATACTGATTCAGCCTACAGATCCCGGTCAAATAAAAAAATTGAGGAAGCTAAAAGCAATATGTCTTTGGATGAATCAATCTCTGACAGTGACTCGGATGACGAGGATCAATTTAATAATTTAACTGCTGAGAAATATCTCTGGTATAGTGTTGGACCACTATGGAGTGCTATTCTCAGCAATGCCAATACTTCTGAAAGCATCGATACTTTGGTGTGCTATGGACTGCTTTTAATGCTTCCTTTGCTGATATTTTCCACATGGCTGTCAAAGTAAAGATTGGGGAAATATTCCGTAAGTTTGTTAGCAGAGCAGACACATTTCTTTGATGCTGCTAGATGGCACCGTTGCTTGAAATGCAATTTCACCCGAAAAAGCAGATTATTTGGCTGCATAATATGTGGGACGCAAACTACTGGTAGAGCAGCTTCATAGTTGTTGCCTATCAGCTGTATTCTGTTAGCTATTGCTTTTGCCTTGGTGCAGTTTATTCTGGTAGCCATTGGTGATGTTGGCTTGCTGCTGCTGTCATGTTTCGCCTTGTATTTTGATGATGATTATGATTATGATTGCAAACTGTAAAATTTTTGTAAAACCTCGCTCTATTTTTAGATATTATGTTGATGTCCAACATTAGAACACTGCTCTTTTAAGAACTCGGAAATGAAAATGCTTGATCATTTTATCTACTTGTA
->JF971034.1 Uncultured archaeon clone E09_A-C5_0239GSNP001F_P1 16S ribosomal RNA gene, partial sequence 
-AGGGCCCCCCCTGGGCAAAGGGGTAACCCCAGGGGCCGCCGGAAAAAGGCGGCTTTTCCTTGGTCTAAAACCCCTAGGGAATAAGAGGGGGGCAAGACTGGTGTCAGCCGCCCCGGTAACACCAGCCCCTCGAGTGGTGGGGATGATTATTTGGCCTAAAGCGTCCGTAGCCGGGCCGGGTAAGTCTCCCGTTAAATCCAGCGTCTCAAGCGTTGACTGCGGGAGATACTGTCTGGCTAGAGAGTGGGGAGAGGTGTACGGTATTCTGGGGGTAGGGGCGAAATCACACTAGAACACGTCTGACGGTCAGGGACGAAAGCTGGGGTAGCGAACCGGATTAGATACCCGGGTAGTCCCAGCCGTAAACGATGCACGCTAGGTGTTGGGGCGGGGCTCCGAGCCCCGATTAGTGTCGGAGAGAAGTTGTTAAGCAAGCTGCCTGGGAAGTACGATCGCAAGATTGAAACTTAAAGGAATTGGCGGGGGGAGCACAGCAACGGGTGGAGCGTGCGGTTTAATT
->XM_046691669.1 PREDICTED: Haliotis rubra tolloid-like protein 1 (LOC124257572), mRNA 
-AAAACCATACTCACTTACCCTGACCATACCGGTATATGCGACCAGTGAACTAACGCAGTAAGGACAGCCACACGCTTGACATTGTGCACCTGGCAACTGGCTCAATTTACCGAGTCATTCATATGCCTCCGCACCTGCACCGCTTCAGTGAGCACAAGTGTGGTTCACAACATGCAATAGTGTTTCGTTACCTGGGACATGCTGTTACTCTTTACTGGACATTTGACATGGAAACAGCTACAAGCGTGTTCAAAATGTCCAAACGGCGACCACAACAGCTGGCTATTTTGATAACAGTAACGTCGTTGTGGACGCGGATACTAGGTCAACCTTGGGCAGATGATGAATGCAACAACGTCATCGTGCCAGACCTATCGAGACAAGAAGTGAGGTCAGAAGGCTACCCGTCCGGATATGAACTGAATCAAGAGTGCAGATGGGAGTTTGATGCAACGAAGTGGTTTAACCAGAACAAAACACTTAGTGTGCAATTTGTCGTGGACATTGAAAAGACTACAGATTGTTCAAGAGAATCTGTTTCAGTGTATGCTTTCACATCGTCCAGCAATACACAGCTAGCGGTTATGTGTGGTCAGACTGTAAGACAGTATACGTTCTTCATCAAGTCCCTCCTGGTTGTACTGAAGACTGGATCTAGTCCTACACAGGGCCGGCGTGGTCTTAAGATGACACACCAGATGATTGATGACGAATCCTGCCGTGAGTGGTTGTATTCAGATACACACAAGACAGGTGCCATTCATTCACCCAGATATCCTGATCCGTATCCGAGCTTTCAGAGATGCACGTACCACATACGGAGTCGGACTCCCAACCGTAACGCCGAACTTAAAGTCATCCTTTCCGAGCTGAGCAGTGACTGTCACAAGGAATATGTCCTGGTCTATGACGGGAATTCAGAAAAAGGGTCCTTACTTGGAAAATGGTGCGGTTCAGAACGACCGACGTTCAACAGCCTGAGACAACAACTCTATGTAGTGTTTGTGAGCCATGACAACATCAGCGGACGAAGGGGGTTCAGGGCAGATTTCAAAGACGTCATATGTGGAGGCGCGGCATCAGCTGGACAGTACTATGGAAACGACATCGTATTTCCTGGGCAAGAGAGAGCATTTCACCATTACATCACGTGTCGCTGGTACATCAGACCTTCCCGCGGATTTACAGGCTTGATGGTGGAGTTCAGAAACCTTCAGGTCGACTGTGACAAAAGCAGGATTTCAGTGTATGACGGGCCAAGCGCTACAGACTACACAAGGACCTGGAAGATCTGCGGTAAAATGGATTATTCCTACCTGATTTCCGGGGCGGGCGTGTTCATCGAGTTCAGTAGCCAAGGCAACACAGCAGAGCCGGTCTCCTTCAAAATCAAATACAGGGGGAGCCGCGTTACAGGTTGCAGACTGAAAGGAAAGGAGGGCGACAAGGCTTACCTTGTGGCTTACTCTTACGAACAGATACTCCTGTCCCCGGGATATCCCGATCTATATCCAGATCGGATACAGTGTATGTGGCAAGTGAAGACTGGCCTTCTCGTGGACATTGTCATGATTGATGTTGTACGGCTGAATCTCCACTCACAGCCTGCATGTGACGACAGCATCAGTTTATATCATGGTCCAATATCTGATATCAGCAAGACACCGGCCATGGTGTTGTGTGGCACCACGACCGATGTTTTCTACAGCACTGGTCGGTACGCTACCATTGTGTTTTCAACCAATGACGTTGGAGTAGGAAGCGGCTTCACCATCAGTTACAAGTCTGTACCAAAGAAGAGCGCCGATACTGGAACCGCAGCTTCAGTTTCATCCAGTGCGTCAACGATAGTGATTGTTTGTTGTGTAATCTTCATCATCATCACCATAGTGGTTATCGTAACTTGTTTCGTTTGGAGAAAAAGACGCAGTGATCGCAATCGACAGCCACCGATTGTCCAAACATCTCCGGATCCAAACCCCCAGACTAGCGGCCAGGCAACCCCATTTTTGCCGCCCAATACCACCGGTACCACCAATCCTACCAATACCCCCGCTACCACCAACACCAGTGCGTCGCCCCCTGAATACCAGGATGTAAACTTCCTGCCCGTCACAGAACCATCAGCGCCAGAGATGCCGCCTCCCAGTTATGAAGATGCTGTGTCGAAGGGAATGATAGACACGGAAACTAGGTTTTGAGGCGTTTTGACAAGGTGTCTTCAAATTATAAACAGACGCTTTGACATGCATCACAAGGCAGTGGTCAGAATGTGAGTGAGTGAGTTGTTTTTAAGCCGCTTTGAACAGTACTCGATCGTAGAGTGTCTGCATAGCGTGGACGTAAGGTCATCAGAAAGTAGTTTCCTGATATCTAGTGTAGCTGTCTCATTGTCAGAAATATTATCCACGCATTTAGTACATGGTATTTGTCAGGAAGATACTCTAGGACATGGTATTGGTCAGAAAGAGACACTGGAACATGGTATTGATCAGGAAGATACTCTAGGACAAGGTATTGGTCAGAAAGAGACACTGAAACATGGTATTGATCAGGAAGAGACACTAGGACATGGTATTGGTCAGAACGAGACCAGTGGTGATTCCAGGTTAGATGAAGTCACAAGCAGCCTTTGCTGGTCGTAAGGGGTGACTAAATGAATCAGATGGTCAGACTTGGATGACGTCACGTAAACGTCGCTCATAATGTCAATCACTGAAATGTCTGGCGCAGTTATTTGAAGACCCCGTTACAGAGCTAGAAAGTCGCTACGTTATAACAAACAACAAAGACGCCCATCTACAAAAAGTTGATTCCGAAAAGACAAATCTGCAGAAGCCTACGATGACTTGTGGAGTATTTGTGTGGAGTAATGATGCTCAGTTTAAAAAACCTCTCAGTGGTATTTCCCAAAAGGAATCTGTTAACACCCAGGACTATCTCAGACACAAGTGGAGGCGTTGCACTCATATATTGTAGGAGTGGGTTCTTTCTCATCTGATTGGATGAATGGGTAGGGCAGATGGCCGAATCGTTTTAACGGGTGCGGCCAGGTTTCCCCGCTCATAAAACTGCTCCCCGGAAGACAATTCCCCACTGGTTGCAGAAATGTCAAGAACGTCTGGGGGTGGGGCGGAGAACATGACCTGGGGAGAATTTTCTTAGTAGGGGCAGTTGATCTGACGCCATATTAACACATCTTAGGTGTGGCGTGCAAAAGCTTTAGAAACTAAGCGGCCGGAGTGAGGGTTCAGATGCTACGAGCTTGGTGAAGCATCTCAGCATCTTTGATTATAGGTTCTTGAATATGTAACAATATGTGAGCCTGCTTTTAGCATTACCAGCATCTCCACCGAAACATCCCACTGAAGGTGAAATTGAACAGAAGTTGAACTTTATACTTGTATTCCGACTCTGTGTTCTGTTATGAATTCCTTTAAAAGAACATTCCAGTTTTAATGACATCATATATTGACGGGTTTCAGAGGGCAAAGGAAACGATTTCTGCTCAGGAACACTCAGCCCTGAAAATACCTTTGTATTTTGAATACAACAGAAATAGGGGGTCAACCGACAGTGTTGGATCCAAGTGGATTAAATATGTATTTGAATATATGCAAGTGCATTATTGTTTATATTATATATGTTTTATATAACATTTTGTATGATTTTATTGCGAGATACACGAGTCATAACACCATCGTGAGCGTGTTTGTTTTATTTGTTTATACACGTTTTATACATGATGACAGAACATTACACAGTAACATCTCACTTGTAGGACATGTTACTGAAGTAC
->XM_048419471.1 PREDICTED: Myodes glareolus docking protein 6 (Dok6), mRNA 
-GAGGGGGGCACAGCTGGGGGCGGCGCTAGCCGCGGTGCTCCCCTCGTGGTCGGGGGCGAAGGTGAAGACCGCTCTCAAGGTGCTGGTGCTGCTGAGCAGATTCGGGCCCGGTTCCCTGGTCCGGGTGCTTGGCGGCCCTGCTATCGACTCAGCGTCCGCGCCGGCAGGAGCCTGGGGAAGAACTGGCGGTGGCGCGACTGCCGGCGACGGCCGGCTGGATGCGAGACCTGCGTGGACCGGGCGGTGGACAGCGGTTGACGACTCCAAGAAGCGGATCACCTAGCAGAGGAGCCCGACCGCGCTGGCCATGGCCTCCAACTTTAACGACATAGTCAAGCAGGGCTACGTGAAAATCCGCAGCAGGAAGCTAGGGATTTTCAGACGATGTTGGTTGGTTTTTAAGAAGGCTTCTAGCAAGGGACCCAGAAGGCTAGAAAAATTTCCAGATGAAAAGGCAGCTTATTTCAGAAACTTTCACAAGGTAACTGAACTGCACAACATCAAAAATATTACCAGACTGCCTCGAGAGACCAAGAAGCATGCCGTGGCCATTATCTTTCATGACGAAACGTCAAAGACATTTGCTTGTGAGTCAGAGCTGGAGGCTGAGGAGTGGTGCAAACACCTTTGCATGGAATGCCTGGGGACAAGGCTGAATGACATCAGCCTTGGGGAGCCTGACCTACTGGCAGCTGGGGTGCAGCGGGAACAGAATGAACGATTCAATGTTTATCTTATGCCTACACCCAACCTGGATATTTATGGTGAATGCACAATGCAGATCACTCATGAGAATATCTATCTCTGGGATATCCACAATGCCAAGGTCAAGCTGGTGATGTGGCCTCTTAGCTCACTAAGAAGATATGGTCGGGATTCAACGTGGTTCACCTTTGAGTCAGGAAGAATGTGTGACACGGGAGAAGGACTATTCACTTTTCAAACAAGGGAAGGAGAAATGATCTATCAGAAGGTCCACTCTGCAACACTGGCCATAGCTGAGCAACATGAAAGATTAATGCTAGAAATGGAGCAGAAGGCCCGGCTTCAGACAAGCTTGACTGAACCAATGACATTATCGAAATCCATCTCTCTTCCTCGTAGTGCATACTGGCATCACATTACGCGTCAGAACAGCGTTGGAGAAATCTACAGCTTGCAAGGTCATGGGTTTGGCTCATCAAAGATGTCCAGGGCACAGACATTTCCAAGTTATGCTGCAGAACAGAGTGAAGAGGCTCAGCCACCATTGTCTCGGTCCAGCAGTTATGGATTCAGCTATAGCTCCAGCCTCATTCAGTGACATACAGAGGCCACCACTGACCAGCAAAACAGTCTGCCCTGGACCTGCCATGGGGTCATTTCGCCCTGTGTATCCTGGAAGATCAATTGCTGTACAAATTAACATTGGTAGGGCGTAGTCCCAACTGAAAGGTTAAAAACTGAAGTTCTGCTTCCTTGATTCAGTGGTTAAGTCCTTTATTTATTGAATTTCTATGGGGGAAATCTATGTTTTACAAAAAAATCCAATAATATGAACACTCATTTCAATACAACAAATTCTTTGTGTCTGACAGTAGCAGAAGCCTTGGCACTGGGAAATTTGCCCACTCTAGTTTGTGCCTGGTTGGGGTCACCAAAATTTGTCTTTCAGACTGTTTGCTCCTGTTTCGACACAGGGCCTGTCTTTAAACATAATAATGACCCACTCTAAGCTCTGTGGCTTTTTCAATTTTGACAGAAACAAATCATGTAATCTTTACTCATGGTATCATAACTCTCCATGTAAAGAAGTCCAGTGACAATTAAGGGGGTGTTAAATTAGAATATTCTATTCAGAAGGACCCTGTAGCTCGAGTGTGTGTGGATGTGGGGGGTTGTATGTCTGTGTCTCTATGTATGTAGGAAATTACTATAACCATCTACAGATTAGGGTATATCAAATGTGCTAAATGTGACAGGATATGCTCACTTAAATTATTTAAAACTAATTTGTCACATTAAAATTAAAACTATGTTGAATAACTATTTTTAAATTAGTGCTGTTAGAATATGAAAAAGGTCCCCTGTTAGAAAATGAAAAAGGTTCCCTACTAACAACAGTATCTCTGAAGCCCACTCTGGTCTTATGAGGATTATGATCAGAAACACAAGAAGGAAGCACTTTGGAAACAAGATTACCATCCCAGCTGCCCTGCATGTCCATTACACTGTCTGTCTGGTTGATGTTGCCTTGTTGTTGACTGTTTCTTCCATCTGAGCTACTTGAGAAATTGGTGTAATCTCCAACTCTAAAATGTTTGAGAAAGACACAAAGCTACACTGAAAATGAACTCAGCTGTTTGTAGTTAAAAGAAGAACAAATGATACATGAAAGTAGATGTTTTAAGTTTCACAGAGGAATTTTTGCATGGGTCGTTGGGGTCTTGGCATCTGCTATGGAAACAGAACTTACATGACTTGAATTTTTTTTGCCCTGAACTTGATTGGTTGGGATGAAAAGAGAAAATGTTTGGCTTGCAAATTTTTTTCAGTTCTACCACCTGACAATGTCCAAGTTTAAAGGGAAATGGAAAATTCCTCTCTAAAAGAGAAAGTTTGGCTTGTTCAGGTCAACATAGACATATTTTGAGCATAATTTAGTGAGTGAAAATATAAATTACTCTGTGAGACTCACCTGGTGTCACTTGCCTAAACCAGATATCAATTAAGGAATCCAGATCATATTCCTGAACACAAGGTCAAGGTCAAGCAAGAGGAAAACCTGTTTTTTTCTTTGATAGCAAAATGTTCTACCAAACTTAGTCTACTGAAAGGGTACCTTTTTGCTGATCCTTGTTAAGATTTCATTCATCCTGAGTCAGGCAGTAGTGGTTCATGCCTTTAATCCCTGTACTTGGGAGGCAAAGGCAGGAGAATACAAGAGCTAA
->XM_045791904.1 PREDICTED: Ursus americanus glycerol kinase 5 (GK5), transcript variant X2, mRNA 
-CCGGATCTCGCGGAGGGGCGGGCCGGGGGCGGCGGCCCCGCGGGGCGCGCTCGGCTCCTGAGGTGCGGGCCTTTATAGACGCGCCCTCTCGGCAGGCGGTTGTTGCGGAGAGGCTTGCGGGCTCGGAATGTCGGGGGTGCGCGCGGTCCAGGAGCAGAGCACGGCGGGCGCGTCTCCCGCGGGCTTCGTGTTGGGGCTGGACGTGGGCAGCTCAGTGATCCGCTGCCACGTCTATGACCACGCGACGCGGATCTGCGGCTCCAGCGCGCAGAAGCTGGAAAGTCTTTATCCTCAAGCTGGCCGGGTTGAAATTGATCCCGATGTTCTCTGGCTTCAGTTTGTGACTGTAATAAAAGAATCTGTTAAAGCTGCAGGAATAGAGATGAATCAAGTTGTTGGTCTTGGCATTTCAACACAGAGAGCAACTTTTATTACGTGGAACAAGAAAACAGGAAATCATTTTCACAACTTCATTAGTTGGCAAGACCTAAGAGCTGTTGAACTTGTAAAATCTTGGAATAATTCTCTCACAATGAAGGTGCAAAAGGCAGTTGAAGAAGATAATTGCTGCTTTGGGACTATTGACACCTGGTTGTTACATAAGCTCACAAAAGGTTCTGAATTTGCCACGGATTTTTCAAATGCTAGTACAACTGGACTATTTGACCCTTTTAAGATGCGTTGGAGCAGGCTCCTTACTTCCCTGCTTTCGATACCACTGTCTATCCTGCCTCCTGTGAGGGATACGAGCCACAATTTTGGATCAGCGGATGAAGAGATATTTGGGGTGCCTATACCAATAGTGGCCTTGGTCGCTGATCAGCAATCAGCCATGTTTGGAGAATGCTGCTTCCACACAGGAGATGTGAAACTAACCATGGGAACTGGGACATTTTTGGATATAAATACTGGAAATGATCTTCAACACACCGTTAGAGGCTTTTATCCACTAATTGGGTGGAAGATTGGCCAAGAAGTTGTATGCTTAGCTGAAAGCAATGCAGGAGACACTGGTACTATCATAAGATGGGCTCAAGAATTAGATCTTTTCACAGATGCTGCTGAGACTGAAAAAATGGCCAAAAGTTTAGAAGATTCTGAAGGAGTCTGTTTTGTTCCATCTTTTAGTGGATTGCAGGCTCCATTAAATGACCCCTGTGCATGTGCCTCTTTTATGGGTTTGAAGCCTTCCACCAATAAATACCATCTCGTACGAGCAATATTGGAGTCAATAGCTTTCAGAAACAAACAGTTATATGAGTTGATGCAGAAAGAGATCCATATCCCTGTGACAAAAGTCCGGGCAGATGGAGGAGTTTGTAGGAACAATTTTGTTATGCAGATGACTTCAGACCTGATTAATGCAAATATAGAGAGACCTGTCAACATAGACGTGTCCTGCCTGGGTGCTGCTTCTCTAGCTGGCCTTGCTGTTGGGTTTTGGACTGATAAGGAGGAACTAAAGAAACTGAGGCAAAGTGAAGTGGTTTTCAAGCCACAGAAGAAATGGCAAGAATATGAAATGAGTATGGAAAACTGGGTCAAAGCAGTGAAACGCTCCATGAATTGGTATAACAAGATGTAGCGCTAACTGGAACGACTGCAACCATATACGGCTGGCTGATACGACATGCAGATGAGACACAGCTCAGGGATAAAAACCCAATACGACGATGACTGAGAGCATTTCAGATGAGCTTTGCAACCTGAGAGAAAAAACATTGCTTTTTTGAATACAAAACAAAATCCCTCATTTTTAAATCTAAACCTTGGTAAGATTGTAAGGCAACAGTACCTCAAAACTTTATATCTTCTGTTTTGTAGCAAATTCCAAAGGACGTTAGCCATTTCTAGCCATATTTTGACAGCTGTGGGTCCTCCCCGTTTTTATACTGGGTCAGCGATACATACAAACATAATGGTTTACTATCTGAGTTAGTAGTTCTGGGTCAAGCACCATTCATGTTTTGTTCCAAAATTAAGTGACAAGTGTTCCTTTAATTATTTAAGATTAAGTAGGCTATATGAAGTTCACATAGCTATAAAGAAAGAATAACTGAGGAAATGTGGAGTTTTGCAACATTAATATTTTATATTTAAAACCATAATTGTTCAATACTCTATCCAAATATGAGCTCGATACGCCCCTCTCGGATACGCTTATTGTTAGTCAATTCTTTCTTTTATTGGGCTTAAAGACACTCACTGCCTTAATTTTTCCTTGGTTAACCAAAATCTGAGCATTCTTTTTGTATTGAAAAAATAACTTTAGTGAATGAAACTACAAAGGATAATGATTCATAAAGAACAAGAAAATATTTTCTTTCTCAAATGGGATTTCTTTCGAAAACTTCTGGCTAAAGTGTAACATCCCATTTTTTACAAAATGCAGGTAGTGGATAGAAATCTTGCTTTTCTCTTCCCGTTCTTCATCTTTGTTGTTGAGATGCTTGCATAAATGTCTTTTGTTTTAAATTAAGTGCCTAACTGACAACTTAATTTGAAGACAGTGCCCTAATTCATTGGTGACGTGGGAATTGCCTTCATTGGGGTACTTTACTTCCGCAGGTATCTTTTACTTCAGTTCAATCTACTCATCTCTGTGAGACAGGAGCAGTAGGTAGCTGCCAGAGGTAATGGGGGCGTGTTCATGCAAACGATTGCCTTGCAGTTACGGGGCGGAGCTCCGCAGAGAGGGACAGGGACAGTTCCACATTTTCAAACTTTTGTGATAGAAACAAACGTAAAGGAATCAGAGTTGTGAGTAGCTCTGGGCTGGTGTAAAACTGTCCTATGGCACCAGACTGCCCTCCAACTTGTTCTCATGTAATTTGCCCCTCCCTCCACTTGGGCTAGGTTCCATTTCGATTTGTATTAATAATGAATTTATTTCCCTCTTGGTCAGGCTTTGTGACATAAAGATCTACTGTTATAGAGCTAGTTGTTAAATACTAATGTACTTTAAAAAGTGACTGTTAGAGGGATTTTTGTTGTTGCCATCATATATGTCCATTTCAGGGACAGATAGCTAGAACTAGGGGTCACACTGCATTTCTGCAAATTCCATTTCAGTGAAGTTTGTCTTCTTGAAGTATTAACATTTTTGATAGAATCATAATAGCCAATATATAGTATCATTAACTCCATTAATTAAGATTTGGAATTTTTTTTGTGAAGTGGAGGTATTTTGTTTACGGTAACAAGTCAGATTACATTATGTAGATAATATTCTTCTTTTTAATTCTTTTCATTTTTCTTACGTCCCTTTTACAAAGCTTAGTGACCAATTGTAGGCCCTTTTATCAAAATCAGATCACGTGCAAGCTGCTCTGTTGTTTTACTGTTTCTTATAGATTCTGCTTCTCAGAGGGTATGATTTCATAGGAAAGAATTGTCTCTTTGTGTTAGGATATACTGAATTGTAATATTATTAATACTTAAAATTTGTTGGCTCATTTCTTTTTCACATTCTTCTTTCTCATCATCAAACACAAAATAAAGGATAAATACCTTTTAGATAATGTGAAAAAGTAACTGTGAACATGTTTTCATCGGAATTGAGCATCTCCTCAAAAATCAGTGGCTAGTTTTTTCTTCTGTTAGTCTAGAATTAATCTTTTATTTTTACTACTTCTGGCTTTTTTAGTGACACAGTTTAGTAAATCTTTTGCCAGATTTGACCTAAATCAGAAACGTGACCACATTTGCTTTTGTGGTTGTAGAAACAGTTGATATTCAAAATCAGTTGAGCAAAAAAATTGTGCTACGATTTCTCAGCATGTTCTATTTTCCCATTATGGATCAACCAGATATTTTTAGCAGGTCTGTAGCTATCTTATCAAGGAGGAGAATGTTTCTGTACAATCCTTCTTGAAGTGGTACTAATTTCTTTCATACCTAGACTTACCGATTTTAAATTTTTTTATATCCTACCATAATACGGTTTCTCAGTCTCAGCATTATTGACATTTGGGACAGGTAGTTCTTTGTTTTGGGACGTTGTGCTATGCAAGATAGGGTATTTGGCAGCTCAACCTGCTAGCTACCAGCAGCATCCCCTAGTTGTTGTGGTCAAAAATGTCTCGTAACACTGCCAAATGGCCCCCAGGAGGCAGTATCACCTCCAGTTGAGAACCACTAATTTGGACTATTAGAAGAAAGTTAAAGGCTCAGCAAATGTAGTGTGTCTATCATGCTCCTTTTCTCTCTGCCTCATTTTACCTTAGGAAATCGTTGTTAGCAAAAAGAGGTGGTTGTATCTTAAAACAAATAGGGTTTCTACTTTCCCAGTTAATGAGGGAAAAAAAAAATCTGATTTTACCCACTCAC
->XM_020802708.1 PREDICTED: Pogona vitticeps SH2B adaptor protein 3 (SH2B3), transcript variant X4, mRNA 
-AAGCTGTTCTATTTTAGAGCGCGCGCAGGGCGGCCTTTGGCGTACGACGTCAAAACCATCCGGTCCCCCTGTTTTGGCAGGAAATCGCAAGGCGCTGCCGGTGGGCATGTCGTTCTGTCTGGAGGTGGGCTTCCCTCATGGACTGGCCTCCCTTTTTTGGCCTGCGTGCAGTCAGTGGCCGGTCTAGCTTCTGCAAAGGACATCTGAGTGTTTCAAGTTCCTACCATGAATGGACACGCTGGGCCACCCATAGATCCTGCGCACGCCGGGGGCTGGAGCGAGTTCTGCGAACAGCATGCCGTCACCACCGCTCGAGAGCTGGCCCGGAAGTACCTCCTGTTTGTCAGCGAAAACCCCGAGCACGAAATCTTGGCGGCCGACAACTTCTCCCTCCAGTTTGCTGACCTCTTCCAGCAGTATTTCCGCAATGAGGTGAAGGACCATTCCGCCATGAACCAGTTCCGCGTTCTGCCCTTTAGCAAGGTGCGGGACTACAGGGAGACTGGCCGAACTCATGCCGGCGCCTCCCCCACTGGGACGTTAGGGGCCAAGAGTGAAATGGAACTGGGTGGACCAGTTGACCGGGGACCACCTGAGGCCCGTCCCGCCGGCCTCCCCAAATCGTGGAGTTCTGAGGAACTTACTGGAACGCCTCCTTCCTTGGCCGTCAGGAGACACTTTTCCCTCACCCGCCTGAGGAGGAGTTGGCGTAACTTTTTCCGCAGGAGGTCCTCAGAGCCGCCCCCTCCCGATGGGGAAATGTCGGATTCTGTGCTGAAGTCTAACCTGGCGCGGAAGATCTTCCCGTGGGCCCTTTCGCGAGACCCACCGCCTCAGGTCCGGAAAGAAGGCGGTCTCAAATACTGGATGGTGACCGAGGCCAACGTGGACAACGGGACGCGCTGGCAGAGGTGCCGGCTCGTTTTACGGAAAGAAGGGCCTTCAGAGAGTGAAAATTACGTCCTGGCGCTGTTTGACCCCCCCAAGAGCTCAAAGCCCAGACTCCAAGCCGCCTGTTCATCAATCCAAGAAATCAGACGGTGCACCAGCCTGGAGATGCCAGACAACGCGCACACCTTTGTGCTGAAGGTAAATGCCTCCACCGACATTATATTCGAGGCTGGGGATGACCAGCAGCTGTCTTCCTGGATGTCTGAAATTAAAGAATGCCTCCCTCAAGGGTCCACAGGAGCCGACCCGGACCTGGCCCCCGACTCCCTCTCGGAGGTCACGACGGCCAGCCCCACCACCACCACCAGCAGCAGCAGCGTGGATTCCCGGAACCAAGGCGCGACGCCCCCGAACGCCCCCGACCAGCCCTGCCAAAAGACGGACCGCTACCTTTCCGCTTTCCCCTGGTTCCACGGACCCATTTCTCGCTTCAAGGCCGCCCAGCTGGTCCAGTTCCAGGGCCCCGAAGGGCACGGAGTCTTCCTCATCCGACAGAGCGAGACCCGGAGGGGAGAATATGTCCTCACGTTCAATTTCCAAGGAGTAGCTAAGCACCTGCGGCTTTCGCTGACCGAGAGGGGCCAGTGTCGGATCCAGCATTTGCACTTCTCCTCGATCCTGGATATGCTACACCATTTCCAGCGCTGCCCGATTCCCCTGGAGTGTGGCGCTGCCTGCAACGTGCAGCTGTCCAGCTACGTGGTGGTTGTCCCAAACGCCCAAGGCTCGACCAACACGGCACCTTTCCCCCCCGCCATCCACCGCTACAACCCGGAGTTCGGCCTCCTCCAGCTCACGCCCTCCAGCTTCGCCCGGATCCGCCTCCCGGACCATCCTCACCGCCACCACAACTCCTCCGTGGAGCAGATCTTCCACTTGGTGCCCCCTCCGGAAGAGCTGGCCGGCAGCCTGTGGCCCCACAGAGGCCGGCCCGCCTCCCACCACCCCTTGCCGGCCCCCCGGCCCTGGGACGGCGATTACGAGACGGACTCCCACGGGAGGGGGCACCTGCGGGCGGTCAACAACCAGTACCTGTCCCTTTGACCCAGTGCGGCGGGGGCCCCCCCACCCTGCTTTTGCCCGAGACTCTTCCTCAAAGGACATCTTCCTCTCTCTTGGCAACGTTGAATATTTGGTTTGTAAGATAAGACGGATCGCTCCCGTCGCTGCGGCTGCAGCTCTTGATTTAGGCCTGTTGAAGGGCCCGTTTGTTCCTTTTTATTATTATTTTTTTCTCAGTCAAAACATTCTTTTCTCTCTTATCGGTTTTGCACACGACCTTCCTTTTGTGTTGAGGGTTTTACGAGTACATGCAGTACTTTGCAGCGGGTTAGCGCTGGTCCCCCTTTCTCTAGCCCCGTCCTCCTTGGAGAAGACGGGCTGGGTGGGGGAATAAGAGGACAGGTCAGCCAAGCAGCGTTCGTGGCCCGTCCAGAGTTATACGGGGGCTTCCTTAGGGTTGTGTTCTACGAAATCCCTGTCGTGAAGGCTAAGGCAAACAGGCATCAGGCAGCGGCTGAAAGGGCGCCCAACAGACGCGAGCAGGAGAAAAACATCTCCAGACACTCCCGTGGGAGTTGCAGTGTGACGGCACCCGCAGGGCGCTGTGCTGGTAGCGTGGCACAGTCTGAGACGCTACGCTCGATGGACGGCCACTCTCTGGCAGGGACAGCCCTCTTCCCCCCCATCCCCAGTAGCCAGTTCCCTTGCGCCGGAAAGTGCGGGAAGCGTTCATGGAGGGCCCAAATGGGTGCAAACACCGTAGCCTGCTTTTGGTGTAAGTCCCCCTCTTACAGCCAGCTGCCTGAGGGCCACCAGCCACGCAAGGAGCAGGTCCCTGATGAACTGTTTTCTGCTTCCAGTCTTGGCAGCCTAAGTCTGGATCACTCCCGTTTACACATTTGCACCACTTATGTGCCTTAGCTGGAAAAAGGGTGGGCGAGTCCCCAAACCCTAAGCTGTTGGCTTCTCTTTTCACTCTGAAGGTAGTCGCTTGGTTTAAAATAAAGAAGGCGCCCGTT
->XM_030133558.1 PREDICTED: Sphaeramia orbicularis signal peptidase complex subunit 3 (spcs3), mRNA 
-GTATAGTCGACATTTCCGGTTTGAACATTAGCTAAACTAGCTAGTACAACATAGCATTGTAGTCGAACGGTTATTTGTTCTCATTGTTTTTCGGTTTTGGCAGTTTTTCACGATGAATACGGTTTTATCAAGGGCCAACTCTTTGTTTGCCTTTTCTCTGAGTGTCATGGCGGCGTTAACTTTCGGCTGTTTCATCACTACGGCTTTTAAAGACAGAAGAGTTCCTGTGGACATCCACGTCTCTAAAGTCATGCTGAAGAATGTGGATGACTTCACAGGACCCAGAGAGCGCAGTGATCTGGGTTTCATCACATTTGACCTCTCAGCTGATTTGCAGCCAATTTTTGACTGGAATGTCAAACAGCTGTTCCTCTATCTGTCTGCAGAATATGCCACAAAGAGCAATGCTCTGAACCAGGTGGTCCTGTGGGATAAGATTGTCCTACGAGGGGAAAACACCAAACTGAACCTCAGAGACATGAAATCTAAATACTTCTTTTTCGATGATGGGAATGGACTCAGGGCCAATAAGAACATCACGTTGATGCTGTCGTGGAATGTGGTCCCTAACGCTGGAATCCTGCCCCTTGTGGCTGGAAGTGGACAAATCAGCCTGCCTTTCCCTGACACATACGAGAGCACCAAGAGCTACTAGACCCAACCAGATGTCCATGCTTTCATTACACACTGTACACGCCAGAAAAACAGAAACAAGCACAGACGCCAACAGATGACTCACACATTCTGTATATTATTGTTTCTTCATAGATGTACATCAATTTTTGGTTTATAAAAAAAAAAAAATTCGGA
->KP159845.1 Uncultured fungus clone OTU_86F_4_49 5.8S ribosomal RNA gene and internal transcribed spacer 2, partial sequence 
-CGCACATTGTGCCCTCTGGTATTCCGGGGGGGCATGCCTGTTCGAGCGTCATTATAACCACTCAAGCTCTCGCTTGGTATTGGGGTTCGCGGTTTCGCGGCCCCTAAAATCAGTGGCGGTGCCTGTCGGCTCTACGCGTAGTAATACTCCTCGCGATTGAGTCCGGCAGGTCTACTTGCCAGCAACCCCTTAATTTTTTT
->XM_014413384.2 PREDICTED: Maylandia zebra KN motif and ankyrin repeat domains 4 (kank4), transcript variant X2, mRNA 
-TATTAAGAGAGACAGGGTCAGTAGCATTCACAGAAACAGGAAGGACAGGAGGTAAGAAGAGCTATATGGCAGGCTGTTAGCTCCTACTCTAGCAAACACAAGTAGATGACTGAGAACTCGGCCTCCCATGATGGACAAGAAAAGTGCCAATGGCTTTCAGTCCAAGGCCAGTGAGGGTGGTGTTCAAAGGAAGCAGCTGCCCTACTCAGTGGAGACTCCCTATGGCTTCCACCTGGATCTTGATTTCCTCAAGTATGTTGATGATATTGAAAAAGGCAACACAATCAAAAGGGTCCACATTCAGCGCAGGGTAAAGGGCCCACCTAAATTCAGCACTCTGCCCAGAAATTTTAGTCTTCCTGGGCATGGAGTAAGGCCTCCCCCAAAGGAAAAGGACAGTACTTGGTCTGGGACGTCTACCCTGGGTCCCAAGCCTAAATCACGAGTGACAGAGGTTCAACAGATCTTTGACTTTCGAGCAAATGAAGGCGTGATTTCCAGCCAGAGCTGCAGGGGGACCACAAGTCAAGGAACTGGCTATGTTTCAACTAAACCCAAAGATGAAGTAGGCGCGGGGGCTCGCGGTGCTGAAGACAAAACTGGGGGGATTCAGATTCAGAGTCGTCCAAATCTGCTCAGAGCATCGAGCATGCCCATCACGCTACAGCAGCGTAAGAGTTCAGATTCAAGCAGTCCTGACCGTACCGTGGGAACACCAGAAAACGGCTCAACAGAGAACATGTTCCGGGCTTCACCAGACGTAACAGAAAGACGCTGTGTTCCCCAAGATCGAGCAGGTCTTCACCAGCAGATTACTGTTGCACTGAAGCGGGTCAGAGAGCTCGAGGAACAGGTCAAAACCATCCCAGAACTGAAAGCTCAGATCTGCTCTTTGAGGGAGGAGCGGGAGCAGCTGCTTCTTCAGCTACAAGCACAAGCCAAGGCCCAGGCTTCCAAATTATCTGCTACAGTACCAACAGGTTACGATTCTAGGACAAATAATCAATCGCAAGGACAGAGACCTTCACAGGAGATGAAGTTAGTCCTAAAGACTCAACCCACTGGACGTTTAGAAGACACAAGTCTTGGGCCATCAAACCAAGCTGCAGGGAAGGAGAAACAAGGTGAGACAGAGAAAACTAACGTGTTACTATCTGAAGTGGAGAGCTCGGCACAAGGAAAAAGTAGCATGTCCTCAGCACAAGAAGTGGAGAGACAATCACTGCAGCTGGACATACTTGAAAAACAAAAAGAAACAGAGAGTCCACTGGGACAGACAGTGCAAAAACTGCCACGAGACATTTCAGGGGAGGAATTACTATCTATCACAGTGGCTTTAAAAGAAACAGAGACTGCAGCAAAAGAAGGAAAACCAAAGGATCCAGATGATATGCAGAAGTTGCAGGAGAAGCTAACAGTACTAGAGACTAAACTTATTCAGGCTAGCCAGGAGCTAGAGAGCACTAATGCTCTTTTGAAACAGCAAATAGAGGAGAACAAGCTAAAAGAGGAGAGAATACTACAACTGAGTGAGGGAACGAGAGTGGAGGTTTGCACCGCACATGAACGTCCAAGAAGAGAGAGCATTGACACAGGGACAGTGACAGAAAGGATAGATTTTACCCACCAAGAAACAGAGACAGAATCGCCTGGTACTGTAGATCAGGGGACAGACACTGAAAAAATCTGCATTGAAGTGTGCATACCAAAACAAGAGACTAAAAGTACAGATCAAGGACCAGTGACGGGAAAAGCTGACACGCATGACCAGGAGACAGAGATGGAGGCGGCGATAACAGCGACAAGTCCACCGAGGCCCAGAGCCAACAGCATGGAACGAGGCACACTAACCGAGAGCATCATCACCCTGGATCAGATGACCGAGACCCCCGTGGCCGAAAGGGTAAACCAAGTCACAGAAACAGAAGGCGAGATGGTGACGGACCATCCTCACAGACCGAGGGCCAGCAGTGTTGACAGAGGGACAGAGACAGAAAGGGTGGGCACTGTGGACAGAGTGACAGAGACAGAGGTAGCCCAGAGAGCAGACCAGCAGACTGAGACAGAGATGGAGAGACGTCATGACAACAACCCAGCCAGAGGTGTAGAAGCAGAGAGTCAAGTGAGTGAGAACACAGGCAGCCAAAGAGACGAAGTCGTGGTGAGTGAAAGAACAGAAGACAGGGAAACATACGAAAGAATTCAAAGAGAGAGTGAACGTTTAGTTGCTGAGGTTTTATCAGAAAGCTCAGCGGCAGCTGTAGAAAGCATAAAAACTTTAGATGTTGTTAGGAAGAATGAAGAGTGCGCCAGTTCGGCTGCTAAAGCAGAAGAAAATAAGATTAAAGTGAGTTCCGAACAAGATGACTCAGAAACAAAAGAAATTACAGAAGTGGTTGAAACAAGACCAGCTGCCCTACAGAGAAGAGACCAGCTGCCCTACAGAGAAGAGACTACAGAGAAGAAAGAAACAGGAGCCGGGGAGGTTATGTCTGCAGCAGTCAAAGAAACTGTAGCCGCTGACACTGTTGCAGTAACTGAGGGGAATTCAGCTGTGAAGACAGCAGCTCCTGTAAGACCACAAAGAGGCAGGAAACCCTCAGTGGAGCAAACTCAGCCGTCACCTCCTCAACTTCAGGTGGTGCCTGTGCGTCCTCGTAGGGGATCCAGTGAAACTCAGACCCAGCCGCAGACGAAAACCCAGCCCCAGGTGCAGGAACAGAGTGCAGCTCAGCTTGAAGCTCGGTCCCCAGAACAGCTCTCTGAAACACAGGTAAAACATCAAACACCGTCTGTGCCTCAGGTTGAGGACCACACTATAGCAAAGAAACCTCCTGGAGGGTCTGGAGAGAAGCAGTCTGAATCTCGACTTCAGTCTGAGACTCAGGCCTTGTCTCCGGGCTCTAGTGAAGTCCAAGTCAGGCCTAAATCAATACAAGCGCAATCTCAAACTTCTGTACCTCGGCGGGACTCAAAAGAGCTGAAAGCACCGCAGAGGGTGTCTGGTGCATCACACACTCCTAGACGGGGATCGGGAGAAGCCCAGACCCAACCACCTCGCCAAGCGTCAAGCGATGCTCAAACTCAACCTCAGGGTTCACGTAGAAGCTCCAGTGAGGCTCAGGCCTCTCCGAAAGATGCCAGTGAGACACAGTCACTGCGCAGAGGCTCCAGTGAAGCAGCTCAGCGCCGTGGCTCCAGTGAAGCAGCTCAGCGCCGTGGCTCAAGCGAAGCCCAGGGTTCACGTCGCGACACCGGGGAGGCCCAGCCTCCTCGAAGAGGCTCCAGCGAATCACCAACATCGCCTGCAGCTTTGGGTCAAGTTGTAACTCGGATAACGGGGCTGCTAGGAGAGCAGTGGGCACATCTCGGAAGCAGCTCTGGCACTCAGCAAACAGCCAGCCAGCAGGAGAGCGCGAGCACACAGAAAAAGACGACAGGGAAAAGAGCAGAGGCTGGAAAGGCAACGTCAGCCAAGCCAGCGGGGAAAGCAGCCCCATCAGCAGCAGCGACAGGGAAACCAGCGGGGAAACCTGGTACTTCCAAAATGAGCTCCATTCAGAGCCAACTGGTCAGCTCCCTCAGTGTCCTCTCTGCCTTCTACTCCCCAAGCCAGAAAGCGGCTGCTGCCAGCAAACAGCAAGAACAAGGTCTCAAATCCATCATGAAGAAAAATGGTGGAGCAGGCAAGCAGGGGAACAAGGGAGCCAAGAAAAACCTGAAGTTTGTGGGGGTGAATGGAGGATATGAGACGACATCCAGTGAAGAGTCCAGTGGAGATGAGAAGTCAAAGGTGGAGGTAGAAGAGGAAGATAGCTCAGAACCAGAAGTGGAGAAGGAGCCTGAGAAGGAGCCTGAGAAGGAGCCTGAGAAGCAGCCAGAGGAGGGAGCAGAAGCCCAGAGAAAAGATGCAGAGGTCCCAACTGAGGGAGGAGGTGCTGTGGCTAAAGAGAAGGAGACTGAAAGAGGTCTGCTGGATCCAGAAAGTAGCCAGGAGCTCCTGGAAGAGCAGGCTGGAGGGGGAAGAGTCGACAAGGGGTTTATAGATGCATGCCTTTATGTAAAGGACCGCATGGAGGAGGTTTCATCCCCAGATAAAGAAATGCGCCAGGTTTTAGTGGTGCTCTACCAGGAGTGGTTCAGAGTCTCCAGTCAAAAGGACTCGCAGGCAGATACTGTCAGATTATACCTGCGACAAGTGGGGATGACCACACCCACTCTCCTGCCATATGTTGTTAACTTGACAGACGGCAATGGGAATATGGCTCTTCACTACAGCGTGTCACACTCCAACTTCCCTGTGGTCAAACTGCTGCTGGATACCGGCCTGTGCGAAACAGACAATCTCAATAAGGCAGGCTATACTCCAGTGATGCTGGCTGCTCTGACGGCTGCTGAGAGCCCCGATGATCTTGAAGTGGCACAGCAACTGTTGAAAGTGGGAGATGTCAACGCACGCTCCAGACAGGCGGGCCAGACAGCACTCATGCTTGCGGTGAGCCATGGCCGCGTTGCCATGGTGAAGCTGCTCCTGAGCTGCGGCGCGGATGTAAATGCCCAGGACCGCGAGGGCTCGACGGCCCTGATGTGTGCCAGCGAGCACGGGCACACGCACATCGCTCGCCTGCTGCTGGAGACAGGTCGCTGTGATACCAGCCTCAAAGATAAGAACAGTTCTCCACAGTCGCTGTCCACATGGGTCAGTGGGACCAAGAAGCACTCTGCTAATGTGTGGACTCTGACCAGCAACATCCAGCAGGACCCAGACAGCGTTTTCTATCTCCCAGCTGGAGTTTTTGTTTGTCTGTGACTGGAGAGTCAGATTTTTGTTGAGCTTCACACTTGCAGACCTAAGTCAGTTTGCAGAG
->XM_013897292.1 Thecamonas trahens ATCC 50062 hypothetical protein partial mRNA 
-ATGGCCGACGAACCTTCACCAAATCAGCCCGTGCCGCCCTGGGCCGATGCCGATCTCTCGCGATGCCTGCCGACGCTCGCCGCCGGCGGTGAGCGTCAGGATATGGAGTTCAAGGAACGCTTTCCCGGCCAGGCACGCGATCTCGCCAAGGAGATTGCGGCCTTCGCCACCTCCAATTTCGGCACGATCCTGCTCGGCGTCTCCAAGGCGGGCGGGGTGATCGGCCTCGCGGATTGCGAAAGCGCGTCCGAGCGGGAACGCCTGCTCGACCGCGTCGCGGGCATCTGTGCGAACAGCATCAAACCGTCGGTGACGCCGGCGCTCGCGTTCGCCGTGGTCGAAGACCGCACCGTGCTCGCCATCGCCGTGCCGAAGGGCGATGCGCCGCTCTACTACGTCGCCGGAGTGCCGTACCTCCGCCAGATGGCTACCTCGCGGCCGGCTGAGCCGCACGAGGTGATCGACCGGGTTCTCGATTGGGACCGGGCGAGAAACGGCAGCGGCCGGCCGAGCCCGGAATCCGAGTTCTTGAGCCAGACCGCGTCGCTCGTCGTCGATGTCGTCGTATACGCCGACGAACTCGAAGAACGTCGCGTCAAGCCGTGGCTCAACGAGACACGCCACGGACTCGCATGGGCGGCCGAAACGGCGCGCGACCTCGCGGCCCGGACGCCGGGAGACTTCGCGGAGATGGTCGAGCCGTTGGAGGAGATGGCGAGCAATCTCGACCGTGCTGCACACGAACGTCTCTCCATGGGCGGCGGCTGGGACGAGATGGACGCGGCGGCGCGGGCGGCAAGGGAGACGGCACGGAGCATCTGGACACGCTGGATCGAGCCGCACGGCTTCCATGCTGACTCGGTCGCCGGCGTGCGGGAGACGGTCTCGGAAAACGCGCGAAAGCTCGCGAGCCTCGCGGCGCGGCTCCAGGAAATGGACGATCAGGGACGGCTCGACGGCATCCAGTCGTCGGCCGGAGAGATCGGACTGGTGCTGCTCAAGGCCGCAACCTTCGGCGTCGGGCTCGGGGACGATCAGCGGATCGAGGAGTTGACAGCGATCGGCCGCGCCTTGCGCGACGTGGAGACCCGGACGATCTACGCCGACGGCGGCCAGTCAGCCCGGAGAATACTCGACGACGTCCGTGACGCGAGCGCGAGGCTGAACGCTTGGCTCGCCGGCCTTCCGTCTGAAGCGGAAGCGGGAGCATGA
->LN881636.1 Terribacillus sp. 1011TES3C6,21 partial 16S rRNA gene, isolate 1011TES3C6,21 
-GGGAAATGGCGCGTGTCTATACATGCAAGTCGAGCGCAGGAAACAGATGACCCCTTCGGGGTGATTCTGGTGGAATGAGCGGCGGACGGGTGAGTAACACGTGGGCAACCTGCCTGTAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAGTATTTCCTTTCTCCTGATTGGAAATGGAAAGACGGTTTCGGCTGTCACTTACAGATGGGCCCGCGGTGCATTAGCTAGTTGGTGGGGTAATGGCCCACCAAGGCGACGATGCATAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGCGATGAAGGCCTTCGGGTCGTAAAGCTCTGTTGTTAGGGAAGAACAAGTACGAGAGTAACTGCTCGTACCTTGACGGTACCTAACCAGAAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGTAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCACAGCTCAACTGTGGAGGGTCATTGGAAACTGGGGAACTTGAGTGCAGAAGAGGAGAGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGATATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAGGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGAAGTTAACGCATTAAGCACTCCGCCTGGGGAGTACGGCCGCAAGGCTGAAACTCAAAAGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCGCTGACAATCTTGGAGACAAGACGTTCCCTTCGGGGACAGCGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGATTCTAGTTGCCAGCATTAAGTTGGGCACTCTAAAGTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGGATGACGTCAAATCATCATGGCCCCTTAT
->XM_022540745.1 Aspergillus glaucus CBS 516.65 hypothetical protein (ASPGLDRAFT_127844), partial mRNA 
-ATGATTCCAACTCTGCTGTTCTCAGGTTTCTTTTTCGCCAATGCCTTTGCCATTCCCCTTGCAGGCCACGAGCAGCAGCAGCAGCAGCAGCAGCCATTGGGTAATGGGGTCTCTTCCTCCACGGCGCATAGCGCTGGAGGGGCGCAGAGGCTGACTGGGCGATTCCTGCATATCACTGATCCTCATCCTGATTCGCACTATAAACAAGGAGCGTCGGCCGACAATAATTGCCATCGAGGCCATGGATCTGCTGGATACTTTGGAGCGGACGGAACCGATTGCGATGCCCCGATCACCCTGATGAATGCGACTTTCCGATGGATCGAGCGAAATTTAAAGGGGAATATCGACTTCGTGCTCTGGACCGGCGACTCCGCCCGCCACGACAGGGATGAAAAGATGCCGCGGAAAATGGAAGAAATCATCCACCTGAATGAAATCTTGTCCCAGCAATTCATCGATGTTTTCCAGGACTCCATCCCCGTCGTTCCGACATTTGGCAACAACGATATCATGCCGCATAACACCATGAAAGAGGGACCGAACCGCTGGACGAAGACTTTTGTGGATGTTTGGGGCAAATTTATCCCGGAGGCTGAGCGCCATAGTTTTGTGGAGGGTGGCTGGTTCACGAGCGAAGTGATTCCTGGCAAATTATCAGCCATCAGTCTCAACACCATGTACTTCTACAGCTCCAACTCCGCCGTGGATGGATGCGACGACAAGGATGAGCCGGGATACGAGCATATGGAGTGGCTCAGAGTTCAACTGAAACTGCTTCGCCAGCGCAATATGAAGGCCATCCTGATTGGACATGTACCTCCGGCCCGGGCAGGCCCGAAACAAGGATGGGATGAAACGTGCTGGCAGAAATACACCCTGTGGTTGCATCAATATCGAGATGTCATCGTTGGGAGCGTCTATGGACATATGAATATCGACCACTTTATGTTCCAGGACAGCCACGATATCGACATCGTCGATTTGGAAGGTGACAACACGGGATCTAATGATTTCTCTGTCCAATCCATGGAAGACTATCTCGAGGCCCTTCGGGGCCAATGGTCCGATATGCCATCCCCGCCATCTGGTCTTTCAATTGAGGAATGCTTGGATGAAGACTTTGCGGAGACTGATGGCAATGCGCCTTGGACGGACATATCCAAGAAGAGAAAGAAGAAGAAGTTCCTGAGAAAGATCGGTGGCCCTCTGGCCGAAAGATATAGTGTCTCTTTGGTGTCGCCCAGTTTGGTGCCAGAATACTTTCCTACGCTCCGGGTGATTGAGTACAACATTACTGGCTTGGAAGATATGCCAACTTGGTCTGATATTCAAGAAAACACACAGATCTCATATCCCAACGACGATGACACACCGTCCGTTTTGGAATCCGAAGACTCTCCGATGATGAACAATGACAAGAAAAACAAGAAGAAGCCAAAATTCAAAGTACCAGAACCCCCACCGTCTTCTGCTCTTCCGGGCCCTGGCTACTCGAACCAGCAGTTGTCCTGGCTCGGATATACGCAGTACTACGCCAACCTAACGAGGATCAACGAGGAAGTGGCTTTGCACGAATCGACGCACCAAGACGGAACCGGGAATAACGTCAATGCTACCAGCGTTGATGATGTATTTGGCTTTGAGGTCGAGTACGATACTCGTAACGACCATATCTACAAAATGAAGGATCTTACAGTCCGCAGCTACTTCGATCTAGCCAGTCGGATTGCGAACAACATTCCGAATACCCTGGAATCACCTGATGACACGAACGACGACGGTTATGATAGCCAGAAGAAGAAGAAAAAGAAGAAGGGGAAAAAGAAGAAGGGGAAAAAGAAGAAGAATAAGAACAGGACATGGAAGACCTTTTTTGATCGGGCGTTCGTCGGGTACCTGGACATCAATGATCTTGAAGAGACAGAATCATGA
->KX654414.1 Uncultured bacterium clone OTU 2009 16S ribosomal RNA gene, partial sequence 
-GGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGAATGATGAAGGCCTTAGGGTTGTAAAGTTCTTTTGTCAGGGAAGATGATGACGGTACCTGAAGAATAAGCACCGGCTAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGGTGCTAGCGTTGTTCGGAATCACTGGGCGTAAAGCGCGCGTAGGCGGCTTTCCAAGTCAGAGGTGAAATCCCTGGGCTCAACCCAGGAACTGCCTTTGAAACTGTAAAGCTGGAGTGTCGGAGGGGATGGCGGAATTGCTAATGTAGAGGTGAAATTCGTAGATATTAGCAGGAACACCGGTGGCGAAGGCGGCCATCCGGACGACAACTGACGCTGAGGCGCGAAAGCGTGGGGATCAAAC
->XR_002806955.1 PREDICTED: Equus caballus NK6 homeobox 1 (NKX6-1), transcript variant X2, misc_RNA 
-ACAAAGGCTTTGGGGTCTCCCGGGCCTGCAAACTGTTGATGAACAAAAGGAATCAAGCCCCCGCCTTTGAAATTAGGTTAATCTAGATAGTAGAATGTGCTGGGGGAACTCGCCATTATTAGAGAATAAAAGCCTTACCAAAATATCAGCCCTGAGGATAGATCAGGCCAGTTAGATAGCTTCCATTTATTCTATTTGTAAAGATATTCAAGCTTTTGTTTATCAATTCAGGCCCCACTAGTTATATAAGTTCCTAATGTGTATCAGCATTATAGTGCTACTATATTAACTTGCAGGGTAAAAAAAAAAAAAAAAAAATCCAAGGATCTAAACACTTAGCACGGACGAATCTATCTGCTTTTAGCTTAGCAGAAAGCAGTCACTTTGGAATAGTAATTTTCCAAATGAATTGACAAGATTATTACTATATTATGAAATTGAATTCTGTTTAAAATAAGTTTATCCACAGATGTAAGATATTTTACTGTTTGTGACAATTTATAATTAAAATGTCACTTAGCTTATAATTGACTTGTACAGTGTATTTCCAGGGAATCAAATTTGAGAAATCTTTCCTTGGAAAATAAAGGGATTGAGCCAGCTAGGCAAATTAAATCCACAGTTTCCTGTATTTCCAGTATTCCCTTTTGTTCCTCTTCTTCAGTTTATTATATTTGGGGGTTTTTTTGGGGGGAGGCAAGTGTATTTTCATTAGTTATATTGTTGCTCTTTAAATTAAGTAGGAATAACATTAGCCATGTCTGCTGGTTAGAGTGTATTTCTCCCTGGACAAGCATCATAAAATGCATTTCAGGAGTGATTTTGTATGTGACCATTAGAATACCATCACAGTTAAAATTATTTTTGCAGTGGTTGGTACAGAGCCTACCACAGTAATCTAGAGGTCTTCATTTGTCACCATAAATATGTCTGCATGGCTAGAAGTGAATTATTATAGCTGTATAAAGAAAATAAAAATCACTTTCTTAATTCCGATTCTCTAGGTAAAATACATAACGGATGAGAAAATGGATGAGAAGCATAAAGACAAGATAATTCAATATATTTGGGAAATTGCTTGCTTATTCCTGATGCTTTAGGTTGCAATATGTGTATCAAACACAGTGTCAAACATCGTGAATAGGCCTAAAGTATTTGTATATAAAAAGATTGTCTTGGGGAGAAACAATATTAAAATAATATTTGAAAGACCTGGCATGTTAATAGTGGGAAATAATGTAATGGTAATAATGGGGAAAAATGTAATTGGCAAAATTACGCTTTTAAAAAATAACTGATGAAAATTTTAGCCTTGACTTTGATTTTATGAAAATCATTAAACCCGAGAGACAGAGATTGAGAGAGAGAAAGAGAAACCACTGTGATGATTTTGACTGAGCTATTAAATATTTTCATGCGTTTATGTTGGTTAGCATTAGTGATTTGAGGTTTCTGTTCAGCAGATTTTTTTAACTTTACATCATACACTGCAAGTGTAAATAGGGTGGGGAGTGTTTTCCTACCATGTTTGTGTGTATTCAGACCGGGAGAAGTGTAACAGGCAAATATCCAAAAGCGAAAAGGAGAGCAGAGGTAATTGGGGGAAATGCTGTGCCTTCTCCCACAAATCACACAAAACAGCAAGTACGCTTCAGGTTGTTTGAAATATCTTAATCTGAGAAAGAAAATAACGAATACAGTCACAGTCATCATGGGGCAACTTTACGAAGGGGAAAAGTTTTCTACTTCAAACTGGAAAGTAGGAAAGCGGACTCATTTTTAGGGAGACTCATTTTAAGTTTCCAAGTTTTTTCTCTTCTGAGAAATCGCTCTCTGACAACCTCAATACTCTTGTGTTACCATCGCTATGGCAACGGCAGTTTGTTGGTGCCTGTTACTCGGAGGAACCTGGGGCGACGGAGACTGACTTTGACGGCCCAGACAAGGAGGTCTGGTTCCAGAACCGCCGGACCAAGTGGAGGAAGAAGCACGCGGCCGAGATGGCCACCGCCAAGAAGAAGCAGGACTCGGAGACCGAGCGGCTCAAGGGGGCCTCGGAGAACGAGGAGGAGGACGACGACTACAACAAGC
->XM_006965968.1 Trichoderma reesei QM6a uncharacterized protein (TRIREDRAFT_108278), partial mRNA 
-ATGGACGAGCAAGAACAAGACAACCTCATCCAAACCCTCACAACCCAAAACGCCTCCCAAAACAAATCCACAGCACGCACCCTCCTCCTCCTCCCCCTTCTCTCAACAATAGCCTACATCCGCCCGCTCTTCGACCCCGCGACCGCTTCCTTTGCGATATTCTGTCTCACGTCCCTCCTCGCTACCGCGTTCCTCTTGTACCGCCTTCCGCCGACCGAGACGGGTATAATCATCGTCGATGACTGGGCGCACAGACGAACTGCTTCTTCTTCTTCTTCTTCGTCGTCGTCTGTCAATGCTTCTCTACGACAGCATAATCAGTCGCTGAGGGGCCTTTTGGGAAGGGCGCAGGTGGAATGGCGGTCTCCCTTGGAGAGGACGCTGCCGTATCTGAATCTCGGTTTGGTTGTGCTCTTGAGTCTCATGGGGCTGGTAAGGGGCGACCATCGAGCAGGTGGCTTTGGGTGGGTGAGCATGGGCAACGTACCAGGCCTGGTTTACTCTGTCGCCATCACGGCAAAAGTCGTCATGGCGGGCGTTGACCCCGAAAGGGAGCTGTCGGGCCTCAAGTACGGCTACAAAGGCGCTTGA
->XM_008866548.1 Aphanomyces invadans hypothetical protein mRNA 
-CGTCCATTCCGCGTGAAGTCGGTTGCCGCCCGCGCGAAGGAACAACTGGCGACGCATCCCCCAAACAGGAACAGGTGATGAGGAAGCAGCAACGTGGAGGTGGAGACGGTGACTACGGATCCAGTCGCGGCCTGGAGCGTCAGAAGCAGCTCTGCGATGAAGGCATGGCGCTGGTGAACGAAAGCGTCGGCATTCAAAACTCGGGGGGAGACACGGACCTGGCTGAGCGCAATTTGAACCGCGCTGTCGAGATATTTGAGACGGCTCTGGCAATTCAATACAGCACACAAGAAGAACAGGAAGCGGCCACTCGTCTGAACAACAAGATGCTTCGCTATGTCAAAATGATCAAGACTCAAAAAGCCAAGAACCCCGCGATCGGCGGCAACAAGCGCACCGCGTCCAAGTATAACATTCTCGAACTCGACAATCTCCCGCAGATTTATCATTCCATTGCGGGCAAACTGTTCAACTCGCAAGTTGGTGACGTGTTTGAATCGCTCAAAACGACTTTTGGTTTCCAGGACAACAACGTGCTCAACCAAAAAGAGCATGTCCTCTTGCTCTTGACAAACTACAAAGAGCAGCTGGACGTTCCAGACCCCAAGGCACCGGCGAACCAGCCCGTCCCCGCTCGCGACCAGCAAAGGGAGATGCAGTTGGCAGACAAAGCTGTCACCAAGTTCCATGCCAAATTGTTTGACAATTACAAAAAGTGGTGCAAGTATATTGGCCAAAAGCCCAAATTTACTCGGGACAACTTGACTGATATCGTGCTCTTCTTCCTCATTTGGGGGGAAGCTGGCAACTTTCGACAGACACCGGAATTGCTTTGCTTTTTGTTTCACAATCTCGCTCCGGCGTCGCAATCGGGCGGTTCGAAGGAGTCAGGAGACTTTTTGGCATCGGTGATCCGCCCCATGTACAACGAACTGAAAAAGGACAACGACAAGAAGACTTCCAAGGGCCAGCGCGCCCCGCACAATGAAATTCGCAACTACGACGACTTTAATGAGTTCTTTTGGACGAAAAAGTGCCTCAAGTACAACGCGTACACGATCGGGGAAGCGTTTGCAAGCGCCGACAAGAAGGGCAATCCGAAGGTCGTGAAGAAGACGTTCATCGAGAAGCGAACTTGGTTCCGTGCCCTAACGTCATTCCGCCGTATTTTCCTCTTCAACTTTGCACTGTTTTTGGCCACGGTTGGGTTTGCTATCAACATGATCACGCTGTGCCCGGACAGTCCGATCATGTATGGCCCTGACCTGGGCAAGATTGAAGTGTTCGGGAAAAAGTACTACGACAGCGTCACCTACACCACGCCGTTGACGGACACCGAAACTACCGCCCTGACGGCAGTCGAAGTTGACAGCACTCAAAAACTTTGCAACCCCGCGAAGTTGGCGACTTGCTTGGGAGTTGGAACCTATGTCCGAGGCGAGACGTTTGCGCACTATCCCCGCGACTTCAAGGAATTGATGAGTCAAATTCCTTTTCAGGACTGCATTGAAAGGCAAAGCGGCCGTTGCACGTGCTACATTGATCTGATCGAGAAGTGCTTTTCTCAAACTGGAAATGCAACCGTATACCCTGATGGCGGTTTGAAGAGCATTCCGGTCCAGTACGATCAAAAGTTGTGCGATCTGGTGTACAAGAAGACTGCCTTGGCCATCTTGAACAACAACACAGACGGAAGACTCAACTGCGACATGTGTCGTTTGGAGCCGCAGAGTTTGTTAAAGTCGTTGCCCAAACTGATCGGTTCATTTATCGATTTCAACCGATTCACCAAGAAACGCGACTTTGGTCCGCTGTTTTTCTTGGGTGGGGTGGGGTGTTTGGTCCTGGTGTTTGCGTGCGAGCTCCTCGGTCGAATGATATCGGGTGTCGGCGTCGGATATGTCGGTCGGTCGCTGCCAGTCCCATTTGGCGCGTATTGCCGGTACACGTGCTTTTGGCTCTTTTTGTTTGCTTGCAAACTCACGTTTGACTACCAATTCATGGTCAAGAACTTGGTGGAAACGACCGTGTTCATTTGGTCGACGGACGCAAAGTTGCACCACCCGACGACCCAGTTCCTCATCAGCTTCAGCTTCCACAACATTTTGTACATTGCTTTCTTGTGGATTCCGGCCATCACGGTGTTCCTGTACGACGCCCAGATCTTTTACGCACTCTTGTCGGTCATCTTTGGGTCGGTCCGCGGGTTCAACTTGCGCATTGGCGAGCTCCGATCGTTTCGCATTCTTCGGTTGACGTTTAAGTCGATCCCAAAAGTCTTCAACAAGAAGCTCGTGTCCAACTTGATTGAACGTGGCGGCAAGAAGAAAGGCAAGAAGGACAAATCGAAGAAGGGGTCCAAGGACGATCCTGCTCCGGAACGTCGATTCCAGCGCGTCTCGTACTCGGAAGGGAGCAAGCCATTGACCGGCACGGCCAAAGGTTTCAGTTCACTGTTGGAAAACGACGGATACAACGAGCTGCGAACCCCCGGTGGTGTCGATGCGGACTCGAGTACTGGACGCAATTCCAACATCACGTCCATCACCGGTGTTTCTGGGGCTGAATTTGAGCGCACGATTCCATTCGCCATGGCTTGGAACCGCTGTCTCGCTAGTATGCGCGAAGCGGATGTGTTGAGCGACCGCGAACTGAACGTACTAAGCTACTTGATCGACTCGAAAGACGTGGCGGAGCGACGTCTGTACCCGCCAGCTTTTTTGACGGCTGGCAAGTTAGACGAGTCCATCGACATCATTATTGAAAGCTACACGTTGCACGACAAGCTCAAGTCGGACAAAAAGAAGGACAAGACTCTGCAAAAGGTTGAAGTGTCGATGCGCGAACGATTGACCAAGGACGATCTGCGCGTGGAAGCCATTTTGGGCTCGTACAAGTTTTCGTCACAAGTGATTAAGTTATTGCTTGGCGACGAACACAAAGAGTTGGAAGCGTGTTTCAGCTTCATGGAGGAGATGGCAACCAACAAGACGACGTTGAAAGGTCTCAACTTCAGCAACTTGTACCAGGCTCGTTCGTCGTGTGCGGATTTGATGAAGTCGATTTTGGAAGTGCCCAAAGGCGCCCAGGAAGGCAGCATCAAGTTTTTGCGCTCGTTGTACCACGTTATCGACAACGTCGAAGCTGTCATGGGGTGCCTGAAGAAGGTCCTCTCGAAGCAAGAACACTTGGTCAAAATTTTGAACGACACGCCATTGAAGCCCAACTCATTCTTTTTCCCTGGCGACGCACAACACTATGCGAGTTCGCAACTCCAGCGCATCGTGAACGATCAAACGGCGATTGACATTGTGTCTCGGGCGTACCAGCTCCTTACGGTGGACAACTTCGATGCCGAGCCTCGATCTGAGGAAGGGCAGCGCCGTCTACGCTTTTTCACCAACTCGCTGTTCATGGAAATGCCTGAAGCCAAACCTGTGAGTCAGATGCACTCGTTTTCGATTTCGACGCCGTATTTCAACGAAATCGTGTTGTACTCGGTGAAAGAGCTGACTGCTGAAAATGACGACTCGATCAAGCTGCTGTACTACTTGCAAACAATCGATCCGTTCGAGTGGGAGAACTTTTTGGAACGCATCAACGTCAAGGATATGAACGAAGCCTTGAAAAAGTACCCGGAAGAAGTGCAGCTATGGGCGTCCTACCGCGGCCAAACGCTAGCCCGTACAGTTCGGGGAATGATGTACAACGAAGAAGCCATTCGGTTCTTGTACTGGTTGGAAATCGGCGAAAACGAACCCATGCATTTGCACGGATGCTCATGCAATCGGTGTATCAAGTTGGACGAAATGGTCGCGCTCAAGTTCAACTATATCTGCTCGTGCCAGATCTATGGCAAACACAAGGACGAACAGCGCCAACAAGCGCAAGACATTGACTACCTGCTCATGAAGCATCCTGGTCTTCGTGTTGCATACGTTGATGGCCCCAAGAAGGTCAAGGATGGGCCACCCAAGTACTTTTCCGTGCTCATTCGCGGAATCGGCGACAAGATCGTCGAGGTATACCGCGTCGAGTTACCGGGGGATCCCATCATCGGTGAAGGGAAGCCCGAGAACCAGAATCACGCGATCATTTTCACACGGGGGGAAATGCTCCAGTGTATTGATATGAACCAAGACGGGTACCTAGAAGAGTGTTTGAAGATGCCCAACTTGCTCGCTACGGTGGACCGCAAGGAGCACTCGAAGAACCCGTTGACGATTATTGGTTTTCGGGAATACGTGTTCACTGGTGCCGTGTCCAACTTGGCGAGTTTCATGCAAATCCAAGAACTGTCGTTTGTGTCGCTGGGTCAACGCATGCTCGCCCTGTTCCACGTCCGACAACACTATGGCCATCCAGACGTGTTTGACAAGATGTTTGCCATGACAACGGGGGGAACTGCCAAGCCTTCGAAAGGCATCAACTTGTCGGAAGATATTTTCGCCGGGTTCAACACGACGCTGCGCGGTGGTCGTGTGTCCCACGAAGAGTTCATTCAAGTGGGCAAAGGTCGTGATGTCGGCATGCAACAATTGGCGTTGTTTGAGGCCAAGTTGTCGTCTGGTGCCGGGGAGTGTGTCATTTCTCGCGATGCGTCCCGAATGGGCAGCCGCCTCGACTTTTGGCGCCTCAACTCTTGGTTTTATGGCAACCTGGGGTGGTACTTCACGCAAACGATGACCGTGTTCGGCATTTACGCGTTTATCTACGGCAAGATCTACTTTGCGTTGAGTGGCCTTGACTCATTTTTCCTCAAATCCGGTCGTCTTGGGATCAGTGGAGTCCTCAACACGTCATGGGCATTGCAGTTTGGTTTCCTCCTCGTCGTGCCTGTCATTGCCGTCGTGGGTGTCGAGCGCGGTTTCCGTCACGGGTTCTCGTACTTGGTGTGGAACGTGTTGACGCTTGGCCCGCTCTTCTTTACGTTCCAAATGGGCAACCGCATGAACTATTTTGATCGGACGTTGATCCATGGCGGCGCCAAGTACCGCGCAACCGGGCGTGGGTTTACCATCAAGCACGAAAAGTTTGCCGAACTGTTTCGATTTTACGCGTTCAGCCACTTTTACCGCGGCGTCGAGTTGGTGTTTTTGCTCATCCTGTTTTCAGCATACGGGACGTTTTCATGGTGCAACTGCTCTTGGCGTGTCGACCAGCTCTTTTACAACAACATTGAGCCACTGCAGTATGAATGGGACAAGCGATGTTATGCCAACTTTTACCAGATCTGCGTGTTGCCAACGAACCAAAACTACGGCATTATGAGTTTCTCGCTGTGGATTATTGCTGGCACTTGGCTGTGGGCGCCGTTCTTCTTCAACCCGAGCGGCCTGGATTGGGACAAGTGCATTGACGACTATAACGACTGGCAAAACTGGCTGCAGACCAAGAACGACTCGTCGGAGAGTTGGTTTGGGTGGTGGTCGAACGAACTCGAATACTTGGAGCACTCTAGCGTGAGTGCGCGCGTCGTCCAGTTTTTGCGCAAGTGCCGTTTCTTGTTTGTTGCGGTTGGCATTTATCTGCAGCTCATGTATCGCTTGTTTTACAAGGACCAGAACAAGGTGATCGTGTTCGACTTCCAAAGGAACTTCATTGAGTCCCTCAAGCCATTCATCATTGTCGGTGCATTGGTGGTGGTCATGCTGCTCTTGATTTGCTGTGGGTACTGCGCGAGTCGGTTTTCGAAGCGCAGTCAAATGAAGCAGAAGAAGTTGCGCAAGATCAAGTTCAACGTGAGCTTCTTCATCATGGTGCTCGTGCTGTTCTCGCTGCTGTACTTGACCATTTTGCAGCTCGTCGAGGTGTTTTTGATTGTTGTGCTGGCCGTGTACTGGTTTGTCCAGTTTGCCATCGTGCGCCTCAAGTCGAACCATGTCGTGATCCTTGCAATGGCCAAGAGCTTTGACCGGGCCGTGGGCTGGATCGTGTTTGGTCCAATTTTGTTTATCGCCATGTTTATGCCGTTCATTTCGTCGTTCCAGCAACGCGTGATGTTCAACAGCGCATTTACGTCGGGACTGGAGGTGTCCAAGCTCTTTTCCCACGACGTCATGCCGTCGCACACGGTCAAGACCAAACGCTCCAAGAAGAAGAAGCGCGACGAGTAATTGCGATTTTTGTATACCAAAGAATACATTTATAAATTCGTCGCCATTTTGGCCATTGTTGCCACAGTGGTCATTCGTTTCCAGTGACGAAATTCGGGTTTCATTCGAATTAAAAAAAAAACAAATTCGATTTTTCC
->XM_050630547.1 PREDICTED: Bombus huntii uncharacterized LOC126871580 (LOC126871580), mRNA 
-TGAAGATCTTATTATATTGTACATAGAGAATGAAGTGGATAGTTTTTGGTATCACATTAGTAATACGCAATTATATAATATCCTGTCAGGATATTGTATTTCCAAATAATGAAGAGATATCTCACGTGAGCGGCAATGCGGCGATAACAGAACGTATTCCAGTGGCTGCACCAAATATATGTCCCAAAGGCATGCTTCTTTATCCTGGAGCTGGAAGTAAAAGTACATGGGTATGCGATTGTAGACCTAGATTTCTATATTTTCCATTGAATGATAGTTGTCATGAAGCATATAGACAAGGACCTTGTGCACCACAGAATTATGTTGTACTTCCTAAGGATGAAGTTATACCAAAGTGTGTGAAAAATCCTTGCCTGGAAGACGGCTTAGTACAATATAATAATACATGTTATCCTCTAAGAACTACAGGTGGTCCTTGTGCCCCTAATGGAGTAATAGGAGTGAATGAAACTACATTTGACTTAGAATGTATGTCAACAGATATTGCACCATTCATAATTATTGATCCACCTTTAAGAAAGTGTCCCGTGGGAAGCCGTAGGAATGTACTTGGAATATGTAGAGTAATTTTAACCTAATATGTTTCTATTTAACAAATTTCTGTTTTTTTAATAACCTGGTATTTATTTGTTTGGCCTCTTTCATATAATAAATATCAATATATTATTATAATTCTGATATATTACGAGAATATATATAACATTTATATTTACAAAATATAGTTCTTATTACATTTA
->XM_020521000.2 PREDICTED: Rhincodon typus raftlin family member 2 (rftn2), transcript variant X1, mRNA 
-GTCTACAACCATTTTGGAACTTTCTACTTCAGAGTTTCCATCTGCTGTTTGGACAGCCATCTGACTGCGCCCAGAGCACTTCTTCACATCGCAGATTCTGCCATGGGTTGTGGGCTACGAAAGCTGGAAGAGCCTGATGATAGTAGCCCTGGCAAAATATTTTCTACTCTGAAGAGACCACAAGTGGAAACAAAGATTGATATTTCATATGAATACCTTTTGCTGGATTTTACTTTAGATATTGGTTCAGCAAACCCAGATGTTATTAAGATCTCCTCTCTTCTGGATCTTAATTCCAAATTGGAAGCATACTACAAGAGAGGATATGTTGTTGTCACTATCCACCCTACAGTTCTTTCTATGGGGCAAAGAAAACGATCTCCACTGAGTTACATTTATAGAGTTATATTAACTAAAGTAAGATCAGGTATAAAGACGTCAGAACAAGGAGAACCAAGACACTTAAAGCTAGTTGTTGAAGAATGGTCTGTGAGCAATCAAACACTTACCATTGATGTTGTAAAAGGACTGTTAGAAAAGGTGAATGACTTAACTAAGAAAGGAATGAGGTTTGTCGGATTTTTAAATCCACTCAGTACCCATTCAAAGGCCTGCAATGGTACAAAATCATCAAGAGAACTAGATGCAGATTTGGGACAGGATGTTGACCTTAAATTGCCAGATCAACAAAAGCAAAACCCCGATAACCATATAAAGTGCAGTGAGGAGACTTTTACCAAAAAGCCAATGGAATTTGCAACAGAAAGAGAACACTGTTGCAGTAAAGTCACTGATGTTTTAGAGAATAGACCAGCTCCAGAGGAGGATCTTTTGCATGGAAGAGAGAAAAGGATTGGAAACGAAACCTGTCCTTGCAGTGAACCAAAGGAAGATTTCAAACTGTTTGCTGTGTTCAATGTGTCGGATGAAGACTTCAGTGAACGGTCCTACCATGAAGGCAATATATCACTCAGAGTAACAAGGAAGGGCCAAACCATTTGTACCCTGGAGGCAGATTGGTTGGAAATCACAACATCTTATTATAAAAGTGGGATGTCGTTGGTTGATTCATTCATAGTTTGGGAAACAATGAAAGGAGACTACTTGTCCAAGTCTGTGGATGGAATATTTATTTATGAGGAACATCATTTGGGGGCTTTTGAGTCAAGCAAGATACCAAATGATGCAATTGTTGTTGAACAGTGGACTGTCATTGAGGGTTGTGAAGTAAAGACTGATTATGGTCCTTTGCTGCATACACTGGCAGAGTTTGGATGGCTGGTTACTTGTGTGCTGGCCACACCTATCATTCGCCATGACAGTGAAGGAAATTTAGCAACAAAACAAGTGATATTCTTGCAGAGACCTGCCATAACCAACAATGATCTAAGTCTAAAACCATTAGAGAAAAGATCTACTCGGCAAGCAAGTGAAAGAACCAAAAATTGGAACAGAAATGTGGGTGTGACCACCGGTAAAAACAAGCATTCAGAAACAAAGTCTCCTGAAGATTCTTGCACCACTTCAGAAATCAATTCACATCAATATGGAGGCATTTCAGGCATGAGTCATATTGATAGTGTTTCCAAAGACTTGGATGATGGGCAGCTGGATCAAGAGGAAGAAACAACTCAGGTTACCTGCATATAACATTGCAGAATTCAGATCTGTATTGAAGACAACAGTTTAAAGAAAGCAGACTTTCCAGAGTATAATATGATTGATAATAGCTAATGGCTTTGCAAGATGTGATTTTTGTTTTTGTTCTGTATGAAAGTGTGCTCTTTTTTAAACATTTTCTATAATCCTACAGGGAATAAAAGTATTAACAAATATTTCAGTTCTCGGGATTTATGCAAACAGATCCAGGCTTCTTTAGCAAAGTAGAACTGTTGATTACAATTTGCTATCAGAAAGAGCTTCACCTGATGATTTAAAATTACGTTCAACAAATTTAGGAAAGCCATAGCAAAGCATATTTACAGATGTTTATATTTACTTTTAAATTCTCAAGTAATATTTTTGTTACTTTTTCTATTTGTATGTGCTAATTTTTAAAAATCATTTGTTACTTTTTTCCTGTCATTTTTCTTTGCATATTCTTGGGATCATGTTTTGCAATCAACTTGTTCAAGAATATGCTCATGCAAAACAGTGCTGTCTCTGCAAGATCGAAAGGAGTCATTTTTGAGGATTGTTCAGTCAAGGTAACGTTAGTTGTCCTGCTAAGTAATATATGTATGGCAATGAACTG
->XM_047696666.1 PREDICTED: Lutra lutra methyl-CpG binding domain protein 1 (LOC125081859), transcript variant X5, mRNA 
-CCAGCGGGTTTCCGGTTCCGGGAGCAACGAACGGCCGCGGCAGCGACAGCTACCGCTTCAGAGGAAGCGTCTGCGGAGGAGGAAGAAGAGCAGGGCAAGGCGGGAGTCACAGGCGGGACCCTCGCCATGGGTCCGCGGACCTAGAGCGGCGGAAGCTACCGGCCTGGTGCCGAGCTGGCCGCTGCTCCTTCCCGTGGCTTCCATGGCTGAGGACTGGCTGGAGTGCCCAGCCTTGGGCCCTGGCTGGAAACGCCGTGAGGTCTTTCGAAAGTCAGGTGCCACCTGTGGACGCTCAGACACCTATTACCAGAGCCCCACAGGAGACAGGATCCGAAGCAAAGTTGAGCTGACCCGATACCTGGGCCCTGCGTGCGACCTCACCCTCTTCGACTTCAAACAAGGCATTCTGTGTTATCCAGCCCCCAAGCCCCAGTCCTTACCTGTCCCTAGCAGGAAGCGGAAGAAACCTTCACGGCCAGCCAAGACTCGGAAACGTCAGGTTGGACCCCAGAAGGGTGAGGTCAGGAAGGAGGCCCCAGGGGATGAGACCAAGGCTGATGCTGACACAGCCCCAGCTTCACTGCCTGCTCCTGGGTGCTGTGAGAACTGTGGAATCAGCTTCTCAGGGGATGGTACCCGAAGACAGCGGCTCAAGACATTATGCAAGGACTGCAGAGCACAGAGAATTGCTTTCAACCGGGAGCAAAGGATGTTTAAGCGTGTGGGCTGCGGGGAGTGCGCAGCCTGCCGGGTAACCGAGGACTGCGGGGCCTGCTCCACATGCCTTCTGCAGTTGCCCCATGATGTGGCCTCGGGGCTGTTCTGCAAATGTGAGCGGAGACGGTGCCTCCGGATTGTGGAAAGGAGCCGAGGGTGTGGAGTGTGCAGGGGCTGTCAGACCCGCGAGGACTGTGGCCGTTGTCGAGTTTGCCTTCGCCCTCCCCGCCCTGGTCTCAGGCGCCAATGGAGGTGTGTCCAGCGGCGCTGCTTACGGCACCTTGCCCACCGTCTCCGTCGCCACCATCAGCGATGTCAACGACGCCCTCCCCTAGCTGTGGCTCCCCCTGCTGGTAAACGTAGCCGCCGCAGAGGAGGCTGTGACTCCAAGATGGCTGCCCGGCGGCGCCCCCCCCGGACCCAGCCACTGCCTCCAGTTCCCCCATCACAGCCTCCAGCGTCTCCAGAGCTGCAGCCTTACACGAACCGTCGGCAGAACCGTAAGTGTGGGGCCTGTGCAGCTTGCCTGCGCCGGATGGACTGTGGTCGCTGTGACTTCTGCTGTGACAAGCCGAAATTTGGGGGCAGCAATCAGAAGCGCCAGAAGTGTCGTTGGCGCCAGTGCCTGCAGTTTGCCATGAAGCGGCTGCTGCCTAGTGTCTGGGCAGGATCTGAGGATGGAGCAGGGCCGCCCCCACCGTACTCTCGTCGAAAGAGACCTGGCTCTACTCGACGGCCCCGTCTGGGCCAGATACTGAAGACCTTGACCACACCCACAGTCAGATCAGGCCGTGCCCAAACTCCAATGAAACAGGAAACGGGCAGTGGCTTTGTGCTACCCCCACCTGGCACTGACCTTGTGTTCTTACGGGAAGGTGCAAGCAGTCCTGTGCAGGTGCCTGGCCCTGCTACAGCTTCCACAGAAGCCCTCTTGCAGGAGGCCCAGTGCCCAGGCCTGAGTTGGGTTGTGGCCTTACCCCAGGTGAAGCAAGAGAAGGTGGATGCCCAGGAAGAATGGACACCGGGCACAGCCATCCTGACTTCTCCTGTATTGCTGTCTGGCTGCCCCAGCAAGGCAGTAGATGCAGGCCTGCCACCTGTGAAGCAAGAGCCATTGGACCCTGAGGAGGACAAGGAGGAAGAGAGCAAGGATGACTCCGCCTCCGACTTGGCCCCAGAGGAGGAGGCAGGAGGGGCTGGCACACCCGTGATCACGGAGATTTTCAGCCTGGGTGGAACCCGCCTCCGGGACACAGCGGTCTGGTTGCCAAGTCTGCAGGGCAGGCAATCGGGAAGGGAAGATGGATGTAAAGTGTGGGAGACGGAGGACACTTTGGCGTGCACGAGCAAGAGCTGGAACCGGCGAGGATGGCCTAGAACCCATGTCAGTGTCTCACCATCTCCAACTGCGATAATGTGGGTGTCCTGCAGAAGAAGCTGGTGCCCTTCATCACAGAGTTAAATACTCATCTGGCCCAGGAGTTAGAGAAGCAGAAGGAAGATCCAGGGGAAGTGGAGCAGCTGCAGGCCTGACTGCAGGCCTGACTGCTGCCCCACACCAACGAGGTGAGCCAGCAGATAAGTGACAACATGTGTGAACTGCAACAGTGCCTGGTGCGCCTGCACCAACCTTCCGAGTGTAAAAACAGTATGCTGCTGCTTCACTTCTGTCCTCCAGTTACCATGCAAACTGTCTCTTGTGGCCCATCCTAACCGGAAGCATACAGGGAAGGGAGTTCTGGGAAACGTAGCCTAGTCAAGGTGACACATTACAAAGCCACCCTGCCATGAATCAGCTCCCAAGGGTCTCACTGCTCACCTGAGGATAACTTGATAAAGCTGCGTTGCTGGAAATGCAAAGCTGAAGACCATGGATTTCATGGTGACCCCAGCAAGTACAGAAATACTGTCAAGCCTACCCAGAAAAAAACTGGCTGGTCTCGGCTATTTTTGTGTCATTCATTCAAGTAATGAGAACCTGGCCCATGGTAGGCACTGTACTTGATACTGGGATACAGGAATGAAAAAGATACAGTCCATGCAATTTTATTAAATAACATAAGTATGTATTACAAATGGTGAATGGATATCCAACTTTATCATGGAATTTAATGGTGAAAATAGAGAATTCAGGAAACTGTCGGGAGGAAAGCTCTTGCGTGAACCTTGGGGCACAATAGGAATTGGAAATAATATAAATAGTTTCTATCTCTGAGCTGTTCTATTTTAAAATTATTTTAAAATGATTTTGATTGTCCCGTTTACTGTTTTATATATTTAGTGTTTCTTTGGGGAGTGTCTTGATGGTGTAACAGTGTTGACTCTGAGAAAGTGGGATGGTGGGTGGCAAGATCAAGGTCAGGTTCTGTCGAAGGACCTTGGGCCAACCACTTCTCTAGGCCTTGGGGCTTGGCTGAAGGTGGAGGCTCACCGCTGGTCCCGGTCCCGCCCCTCCACCGTTTTAATAGGCCCCCGCCAGGGGGCGCCGGGGCCGCGGTCATCCCACCACTGCTCTGGGAAGACGCAGCCCCTCACCCCTGGCCAGGGCGGCCCGGGGGCGTGGCCTCCACCCCGGCCGAGACA
->XM_019948349.2 PREDICTED: Tursiops truncatus tripartite motif containing 44 (TRIM44), transcript variant X5, mRNA 
-CCTGACGGGGACAGGGAAAGTGGAACCGGGGCGGCGCGGGGGCCGGCGGCACCGCGCTCGCCGGGGCAGCGGGGGGGCCGAGCGGGCGGCGCGGCGCAGGGGCCGACGGGGGCGCTGGGCGGCTGCGCCGGAAGTGCCCAGAACGCCGGAGGAAGCACAGCGGCCGCCAGGCTGCCGAGCCGGCGGCGAGGCCCTGTGCTCCTGGGCTGGGTGCAGACTGCTGGGAACAGGCGGCAGCGGCGCCGAGGCTGCGGGACACGGCGCGGCCAGTCTGCGGGACGGGCCCCAGGTGGGGAGGAGGACGCGAGGAGGCCGCGCCGAGGCCAGGCAGCGAGCTCTGAAGCCCGGAGACCCGGGCCGCGGCACAGCTCCCACATGGCCTCCGGAGGGGGCGCGGCCTTCGAGGAGCTGCCGCCCGACGGCACGTGTGATGAGTGCGAGCCAGACGAGGCTCCGGGAGCCGAGGAAGTGTGCCAGGAATGCGGCTTCTGCTACTGCCGCCGCCACGCGGAGGCGCACGGGCAGAAGTTCCCCAGGCACCACCTGGCCGAGTACGTCCACGAAGCCGCCCAGGCCTGGACCCCGGGAGCCCGGGGGGATGGGGCGGGAGAGGAAGAAGTCGAGGCCCAGGTAGAGAACGAGAAGGCCCTAGAAAGCGAGGCGGGGGAAGAGAGCGAGTCCGAGGAAGACTGTGAGTCCGAAGAAGAGAGTCAGACGGAGGAGGAGAGCGAAGACGAGAGTGAGGAAGACAGTGAGGAAGACAGTGAGGAAGAAATGGAGGATGAGCAAGAGAGTGAAGCAGAGGAAGACAACCAGGAGGAAGGAGAATCGGAAGCGGAGGGAGAAACTGAGGCAGAAAGCGAATTTGACCCAGAAATAGAAATGGAAGCGGAGAGAGTGGCCAAGAGGAAGTGTCCGGACCATGGGCTCGATTTGAGTACCTATTGCCAGGAAGATAAGCAGCTCATCTGTGTCCTGTGCCCAGTCATTGGGGCACATCAGGGCCACCAGCTCTCCACCCTAGACGAAGCCTTCGAAGAACTAAGAAGCAAAGATTCAGGCGGACTGAAGGCGGCTATGATAGAGTTGGTGGAAAGGTTAAAGTTCAAGAGCTCAGACCCTAAAGTAACCCGGGACCAGATGAAGGTGTTTATACAGCAGGAATTTAAGAAAGTTCAAAAAGTGATTGCTGATGAGGAGCAGAAGGCCCTTCATTTAGTGGACATCCAGGAAGCAATGGCCACAGCTCATGTGACTGAGATACTGGCAGACATCCAGTCCCATATGGATAGATTGATGACTCAGATGGCCCAAGCCAAGGAACAACTTGATACCTCTAATGAATCAGCTGAGCCAAAGGCAGAGGGCGACGAGGAAGGACCCAGTGGTGCCAGTGAAGAAGAAGACACATGAAGGCCTGCCATCCCCAGTGGAAAATCATCCCTTCCCCTTGTGTGTATGTGACGGCGTATATGTAATGGCTTCTGATTCCTGTGAAAGCTGCCCAGCAACAAACGTGCTTCCACCAGATGCCTCCCCAGATCCACAGCAGGCACATAGCTCTCCAAGGAATGACCAGTTTTACTCTTGCTGACTGTGCTTCTCATTCTCTTGTCGTGATAGGTCAAGGAAAATGCCCCTTTGATCAACCAGGAGCAATTAAAGGGTCCTTCAGGTAAATCCCTCGATGGCTGCTTTGAACTTGCTCGGGAAAGCCAGCCCCTGTCATAGTGTATACCCAAACAGTATCACTTCATTAAGAAGGATCTGGAATAATCTTGAAGGGCAGTCAGAATTTGTTTCCCTACCTGCTAATAAAACCACACTTTATTCATATTGAAGCATGGAATAAATGAGGGAAAAGTAGGGGCGAATCAACCCACATAGTTCGTCTCTAAAAGTCCATTTAATACATCTGTGAAAATGTGGTTTCATGAAATAATATGGACGGCTTGAAAACAGATAAAGAGTTAAAAGTTAGAAATATATAGAGATATTTTTAGTACATGAGGTTATCCAGGATTTCAGATTCATAATTCAGTGCTGTGGAAATGAAAA
->JF973483.1 Nocardia cyriacigeorgica strain DSSHB7 16S ribosomal RNA gene, partial sequence 
-CTGATGCAGCGACGCCGCGTGAGGGATGACGGCCTTCGGGTTGTAAACCTCTTTCGACAGGGACGAAGCGCAAGTGACGGTACCTGTAGAAGAAGCACCGGCCAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCGAGCGTTGTCCGGAATTACTGGGCGTAAAGAGCTTGTAGGCGGCTTGTCGCGTCGATCGTGAAAACTTGGGGCTCAACCCCAAGCTTGCGGTCGATACGGGCAGGCTTGAGTACTTCAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGAAGTAACTGACGCTGAGAAGCGAAAGCGTGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGGTGGGTACTAGGTGTGGGTTTCCTTCCACGGGATCCGTGCCGTAGCTAACGCATTAAGTACCCCGCCTGG
->XM_004257108.1 Entamoeba invadens IP1 hypothetical protein (EIN_015440) mRNA, complete cds 
-ATGAGTCAATTGGATGGCTATAACATGATGATTGTTTCAAAATATTTTAAAGATATTAAAGACTTTGCCACCCTCATTTTTGTGTGCAAGAAATTTTCAGACACCGCTGTTAAGTTTCATTTCAACCCAATACCTTTAACTCGAGAAACACTCAAATTCTTCCCACATATTGAAACACTCTTTTTGTACTCAATAAAAGACCCGATACTCCGTGACGGGAATATTCAAAGATATTTTGCGAATTTCACATGTAGTGTATGGGGATACAAATTCTATTTGTCTCATGGTGTCGAGTGTCGAGACGTCGGGTTTTTTTATAAAGACTGTCTGTCAGAAGAACCGCCAGCAATTCCAAAAGTAGTGTCATCCTTCAATCCATATTGTTTTAGTCGTCACGCGATGCCAACGATTATCGTCACCAAGAACATTCGAAGAGTTGCTGAGCTGTCGTTTGCAACAGCAAATGTTCGGAATGTTGTTTTTGAAAATTTGATAACAGACCTTCCATTTGGGACATTTTTGAATTGTAATCACCTCACAAACATCACTTTACCACAGACAATCACTTCTATACAAAACTTGTGTTTTTGTGGGTGCATGTTTTCCAGTATAAAAATCCCCGATGGCGTGGTTTATATGGGAGAGCAGTGCTTTTCACATTGTATAAAATTAAGGGAAATCCATTTCCCTCCAAAAGTAACAAAAATTGAAAATTATTCTTTTATAGGAAATGACGCACTTTATTTTATTGATTTTAAAAACATTAGCGAGATCGGGGAGAGTGCCTTTTATAAGTGTAAAAGTCTTCATAATATTGAATTTGGTAAAAGTGTCAAAAAACTCGGGGAAAGTTGTTTTTCGAATTGCACAAATTTAGTTTCTGTAAGATTCCCTATAACACTCACTTCGATCGGTTCGCTTGCGTTTTCTAAATGTAAACTACAACTTGTGGATATCGATTATACACTCGAAGATAACAGGGAAGTGCGTTTTGTTCAAGAAAACGTCGTGTTTCAGCACAACAAAACGCTTTTATCATTTTATTGTAATAATCCTGATATTAAAGTGAATGGAATTAATGTCATACAAAATACGCATTTTGTAATTTCAAATGCTATTTTGTGTTTGTCCAATTATTGTTTTTCAAATTGTTTTGACATCACAGAAATGGTCATTCCAAGTTCAGTTTCAAAGATTAAAAATGATTGTTTTTACCGCTGTGCAAAATTACACAAAGTGATTTTTATGGAAAACAGACAAAGTGATCTTATTCTTGGCCAAAACGCATTTTATTCTTGTGCTCAATTAAGTGTTATAAATGTGCCAAAAGAACTGACACGTGTTGGACAAAAGTGCTTTTCACAGTGCAATTTTTCCATTTTTGATTTTCAGAAGAGCACAAAAATAAAATCAATTAAAGCTTTTACTTTTGAAAATGATAAAATGCTCACCTCAATCCAAATTCCGTCCACAATCACTAAAATTGGACAATACGCTTTTTGTGGGTGTGAAAAGTTACAAATTTTTTTATTTCCTACGCAATTACACAAAATAGAAAATAACTGTTTTTCTCACTGTAATTTAACAGCTCTTGACTTTGCACCACTTCACAATTTGACATCAATTGGAGCGTCTTCTTTTTCGTTTTGTTCATCTCTTCGTCAAATTTCAATGGGTTCAGTGTTAACAAAACTCCCTGACAATTGCTTTGAAAATTGCGTTTTGTTGTCCGCAATTGAAATTCCACAAAATGTGACATATTTAGGAAATAGATGTTTTTCATATTGTTACAGTTTGAAAAGTGTTGTTCTTCCAGACAACTTGCGTTTTGTTGGCCATCACTGCTTTTCGTGTTGCGCAGTTCAAAATGTGATTTGGCCATCAATTGCTTCCGTCCCAAATTTCTGTTATTACAATTGCAGAAATTTGGAATCTTTCACTTTTGCTGAACAACAAAATGCGTCAATCACAATTGGTATTGCCTCTTTCTACAATTGTATCGCGTTAAAAAGAGTTTTGTTATCAAAAAATGTCACAGAAATTTGTGATTTTGCATTTTCAAATTGTAAAAAGATTTTAACTTTTTCAATCCCACAAAGTGTGACTTACCTTTCTTCTTTCTGCTTTGAAGAGCCCAACGACATGTCCGCGCTTTTCATTGGTTTTTGA
->XR_005782624.1 PREDICTED: Puma yagouaroundi uncharacterized LOC121013303 (LOC121013303), ncRNA 
-TCCTGGAACTCATTTGTTTCTGACTCTTCGAAGACCTCCCAAGTGTAAGGTCTTTTCCTTGTAAGACTACTCCAAACAAATGCAGTGACCTGAAGACTCCCAGAATAGGCACCACAAATTCTCTAAGAGGAAGGCTTATTTCTCTCATGCCCAGCCTTCCCTCTGCCCACCTGTCAACATGTAAACCTCGTGGTGTTTAGCCAAATTCCGTGCTTTATATGTTAGTGTCCTTTATCACATGCTATATTTCAAGGCAAATGAGCTAAAACATGATAATAACTAGCAAAAGATGCCACTCCTTTCAAGAAGGGTACCGTTTAGGCAGAGAATTATAGGGGGATAAAATGGAACAAAAACCAATAAGGCAAATCTTAAGAATATGGCCAGAAGACCATCCTCTTAGAGTTATTCTGAAAAATGGAGCTAAACACCATGTTGTCTGACTCAGAGAAGGATTAGATTTCAAGGGGAAATGGATTTGGGTCCATTTCCTTGAGAAGAGTTGCTATGAGACTGAGAGCCAGCATTCTCTTCACTGAGTGTTTGAGGGATAAATGCACAGAGCAATTTAGCAGCATTTCAGAAATGTAAAGTTCTCAGAAGCCACATTCCAAGTGAAGCAGATCTTGCTGAAGAAGTTGGGATGTGTGAGTCTAAAAAGAACGCTTTGAGCCCTCTGCTTCTCTTAGCTTAAATCCATATATGGCTTTGTTGCTGTTGCTGTTTTCATTTTAAACATAACCAAACAACACTGGTGCCCAGGAAATGGACTTCCAAAGAGAGGAGGGAAAAGCCCAAAAAATTCTTTCAGCATAAAGAAGACCAGTCTTGTTTAAATCAAAGAAAGGGCGCTGCCATCCCTTCAACAGCCAAGACCACAGATCTTGAAATCTTCTTCATCTCAGTGCTCCATGCTATACCCACACTGGAGTAACGAGGGTTTGCTCAGGCTCTGCTCTCTTCAGAGGCTGAGGTGGATTCAGCCGTGGCCTCAACTGCTTATCCTGACCAAACCCAGAGGATGTAGGAAAAGCCCTTCTCCACTCAGGAGTATGGATATCATGCAGACCCCTGGAGACACGGTGGTACTCAATAAGTATCTATGAGTTGACTTACACTGAATCCGAACTAACACAGACTTGAAG
->XM_053456309.1 PREDICTED: Spea bombifrons ADP ribosylation factor like GTPase 11 (LOC128474053), mRNA 
-CTTCCTGAGCTGGACTGCATTACTTTATCCTGTAGTCACCAAACTTCTGCTTTCTGGGAAACTCTTCTTAAAGACAGGATGAAAGACAGAGCACAGAAACACTGGTCTTTCAAGGCAAAGGAGTATAGGAATTAATCAAGACGTCATCATGGGAGGTCAAAATTCAACACACAAGAAGCAAGCAAGAGTTGTGATGATGGGTCTGGACCTTTCTGGAAAATCAACTATTTTATATAAACTTAAAATGAATCGTACGATGGAGACTTTTCCTACTGTGGGGTTTAACGTGGAATCCTTAGAAATGGCTAAAAATATGTCAGTAACCATTTGGGACGTTGGTGGCCAAGACAAACTTAGATCGAATTGGAAAGAATATCTCGAAGACACAGATGCCCTGATCTTTGTGGTTGACAGTTCAGATACAAGCAGACTACCAGATGCTAGAGCAGAGCTACAGACTGTCCTGAAGGATGAGAATATGTCTGGAGTTCCATTCTTAATTCTGGCCAACAAACAGGATGTGCCTGGTGCTTTGTCTACAAATGAACTGTTACAAGGTCTCAAGCTGGGAAGCTATGAAGACAGAAGTTGGGAGATTCAAGGCTGTAGCGCATACACGGGAGAAGGTCTTGCTGAAGCCATGAGTGCAGTGTCACGTCTACTAAAAAGGGCATAAAACTCCAAATGGCTGTTTAATTTTATTTGTGGCTCTTTCATATATGTAAAATATCCATCAAAATACCGTATTCAATCATGGTTTACAAGCCGGTAGATGTTACAGGTTTGAGACTCTGGGAGTTTTACACATTTCATCGTATAATTATCTACATGGATTTTACTTGAATAAGCCATGTGTTATAAAATGATACAGAAAAAAGACGATCTAAACTCCAGTGAGTTTGTTTACACTTCTGCTATATGATGTCAACATTATGTGTCATACTGTGGTATACATAATTTTTGTTAATGAGTTAATAATGAGTAATTAAAATTGCATTTAGTTATGTTTA
->XM_023958536.1 PREDICTED: Oryzias latipes uncharacterized LOC101166636 (LOC101166636), transcript variant X1, mRNA 
-TGTCAAGAGTCAGCTAACATCCTTAAATCATGTTAGCGTGTTTTTATTTCCGCTCCCAAATGCTTTGTTGCACATCAAAACACTTAAAGAGAGTAATGCTCTTCCAGCTCATCTTAGGGTGTGTGTAATGTCTGTGTGGGAAACATTGTTTCCTCCCACTCGTTGCTAAATTGATGTAACTAGGCGGTTGAAACCACAATTATCTGAGTGTGCCATCGCCATGGGACGAAGGAGCCTGCTGCAAGTTTGTTTGCTTCTTCTCGCCTTTTTCAAAGATATGTCCTCCCTAAAGATTCGTAATAAATTGCTGGGTAAATGCCTACAGGTGTCAGAGGAACGTGCAGGAGGAGGAGTTTCTCTAGAGGGTTGCGATCCATTTTCACCCCTGCAGGAGTGGCTCTGGCTGCCTGAGGGCCATGCTCTGCGCAGTCACCACACCGGGGACTGCCTGACTGCACCGAATGCGGAGTACGAAGGCGTCCGCCTACAGCCCTGCATTTTTACAAGTGGAGTGGTCATAGTGGATGTGGGAGGAGAAGCTAGCAGCCAGGCATGGAGCTGCTCCAAGAAAGGACACCTGACTTTGAAGGGCAGTGAGCGACACCTGACTGCTTCTCATGAATCCAGTTTAGTCTTCTTGTCAGGGGAACATAAGAGGCCAGGTAGTAGGTGGCGATCTCTGGATAACCAGACGCTTTGCAGTGGCAAAGGCATCAAACAGGACATAAGCCAACCCCAACAGCAGCTGGGAAAGACAAAGCCAGTCATCTCTCCAAGTGATGGTTCAGACACAAAGAGACTCGCCGACACATTTTCAGAAAATATGTCTTGGGGACTTGAATTTTTTCCTTTAACAGAAATTCTAGATGCGGCTACAGTGGGTACTGCTGGGACAGATTCTTATCAAGCAGGAAATATGACTCATTTCTTCCTCAGTACCAAATCCCCTCAAGATCCAACCATGATCTTTTTCACTATAGACTACGGGATGGGCTGGAAGATCACAATGCTGGTGTTGACCTCCCTGGCTCTGGTCTTAGGAGCCGTCATCCTCATCCTCAGTGTTTACTCTAACAGAAAGAAGAAGATGGTTTGTGTCGTGAAGTCGTTCAATCCCAGACCAGACATGAGTGCTCCGGGATCCCCGCTGCTCAGTGAAAGAGCCCCACTGACGGAGCACGCCATGCATCTCTCCCACTCTTCCCCCTACTTACAGCGAGGAGATATTCTAATAGAATGGAAAGATGGCACTGTTACTCCCCTGTATGAGGCTTAAATGTCGATGAAGGCAGTGCAGATGTGATTGTTTTCTGTAAAAGCACGCCGGCAGCTTGTGTGTGATTTGGCATGTTGCCCCACCACAACCAGCATCTCTCCCAGTGTCTCCTGGAAGCAAAAAAAAACAAAATTGAGAAAGTGAGGTGAAAAGAAAACTCAGCCTCAGCATTATTAGAACTAACTTTGTGAAGCTTTCAGAGTAGAATGTTAGTTTTCAAAGAAAAGTTCTTAACTGAGTTGTGATTTGACAGACTCCAAGGAAGACAAACTTTACCACTTTAGAAGCACTTAAATAGTTCAGCAAAGCCACTACATCTGTCATCTGGTATCAACCTTTGCACCAGTAAATAGAAAATTAATATTTACTTGAACCATTATGACCAGCTGACCTAGTCTCTGTTTCATGACAAACACTGCTGTGCTAACTGTTTGGCAGTGCTATGTGTGCTTTATTTTGTGAACTTAATTTTGTTTAAAAAAAAATTAAGATCCCCTGTTACTACTAAGAATCCAGATTTCTTGTCTGATTTGTAGATTTTTTTTTTTTGCAGTCTGGTGGTGTTGAAAACTGTTTCCAATGTTTTAAAGGTAGAAAGCTAACTAAATTCATTTATTAAGTGCAAACTTTTGTAATTGTGTTGAGTCCTGCATGTACACTGACTTGTTTGTCCATTCATGAGGGCTCTTCTTTAGTTGTGACAAATTCTCAGTTGGCTTAAAAGTATTTTCGGTAGTGCCTCAACTGCCTTTAAAGATCATCAGATTTCAGAGTGAAGAACATCACAGGCCAAATTCAGAGATCAACTGAAAGATAAACTGAACCTTTGGATTTAGTTGCTGGTGGTAAAAGTGTGAGCAAAACTCAAATTAAAGAAAGGATCAGCTGAATTTGATTTGACCACAAGGAGATTAATGGATTATTGAATTGAGAGCATTGTGACATTGCTGGTAAATATCTTAACCCTTGTGCTATCCATGGCCCGTTAACATTTGGAGTGGGGTCATCTGGACCCCACAAGACAGTGCGCTAAACTTTTATTCTTCAATAATTTGTGAGATTCACTTGTGTCCATGGAGTATATGAAATCCTCTTCACTTTTATCCACCTTTGTCCTGGTAGGGAGTCAATGTAAGGGTGGGGTCATCTGGACCCCATAAGATAACACAAAATCAGAATAGGTGGGAAACTGTGTACTTTGGACTGTTACCTAATAAGGCAGGGCCATTTCAGGATCAAACCAGAAAAGCAGGTTTTGTCATGACGTAATCTAGGAAATTGCAGAATAACATCTTAATTATCTGTAACTGTGAAAGTACTCTGGAGCTTGTTTTTGGGTAACAATAACTGGGTAACAACTGGCATCTTGTGAAAGGGGACACGCCCTCTCCTTTTATCAGTCGGGAAGCTTCTGTTATCCGCATTGCTTCACAAGTTATCCCAGGAAAAAGAGAAATAATAGTTTGTTTAAAAACAAGAAAACTAACAACAAATCACAGGAAAAGTTTTTGTTTTAATGTTTTCTAGCCTGTAAACAAGCAATAAAATGAGTTTTATACCTAA
->XM_018291179.1 Pochonia chlamydosporia 170 vacuolar ATP synthase (VFPPC_13402), partial mRNA 
-ATGGTCTCCGAGCTTTGCCCCGTTTACGCGCCCTTTTTCGGCGCCATGGGTTGCACCTGTGCCATTGTCTTCACCTGCCTGGGTGCTTCTTACGGTACCGCCAAGTCTGGTGTTGGTATCGCCGCCATGGGTGTCCTCCGCCCTGACCTTATCGTGAAGAACATTGTTCCCGTCATTATGGCTGGTATCATTGGTATTTACGGTCTGGTCGTGTCCGTCCTTATTTCCGACGGTCTGAAGCAGGAGCTCCCTCTGTACACTGGTTTCATCCAGTTCGGTGCTGGTCTGGCTGTCGGCCTTGCCGGTCTTGCTGCCGGTTTCGCCATCGGTATCGTTGGTGACGCTGGTGTCCGAGGAACTGCCCAGCAACCCCGTCTCTTTGTCGGCATGATTTTGATTCTCATTTTCGCCGAAGTCCTGGGTCTGTATGGTCTCATTGTTGCTCTTCTCATGAACTCTAAGGCTACCCAAGATACTGTCTGCCAGTAG
->MN512539.1 Penicillium crustosum strain MMS small subunit ribosomal RNA gene, partial sequence; internal transcribed spacer 1 and 5.8S ribosomal RNA gene, complete sequence; and internal transcribed spacer 2, partial sequence 
-TTTCCTGAACTTGCGGAAGGATCATTATCGAGTGAGGGCCCTCTGGGTCCAACCTCCCACCCGTGTTTATTTTACCTTGTTGCTTCGGCGGGCCCGCCTTAACTGGCCGCCGGGGGGCTTACGCCCCCGGGCCCGCGCCCGCCGAAGACACCCTCGAACTCTGTCTGAAGATTGAAGTCTGAGTGAAAATATAAATTATTTAAAACTTTCAACAACGGATCTCTTGGTTCCGGCATCGATGAAGAACGCAGCGAAATGCGATACGTAATGTGAATTGCAAATTCAGTGAATCATCGAGTCTTTGAACGCACATTGCGCCCCCTGGTATTCCGGGGGGCATGCCTGTCCGAGCGTCATTGCTGCCCTCAAGCCCGGCTTGGGG
->XM_002370192.2 Toxoplasma gondii ME49 ribonucleoside-diphosphate reductase large chain mRNA 
-CCGTTTCTGGGTCGTTTTTTGTCTTGGCGGTTCTCTTCGTGTGACGCGTGGCGCAGAGTTTGTCCGTTTCCGTTTGTCAAAATTTCCGTTTCCGCGTCCGCGGTGTGGGTTCGAGCACCGCTGACCAGCTTGCGTTTTCCACCGACGAAACTGACACATGCGGTGAGCCTTGTTTCGTTCTTTGCGCGCCGAAGCGCTCGCTGCTGGTTTCCCGCGCCTGTCTGGAAGAAGACGCCGTTCTCTCTCTGTGGATACCAGACGCCGTTAACGCTGCTGCCAGACAACTTGAAAGTGTTTTTCCGAGAGGGCTTTTCCGCAGTTCCAAAACATTCCACCGTGTTTCTACCGTTTTGTCGGGCTTTTTCGCGTGCACGCATTTCCGTGGGACAACCATCGTGGCCCCTGCTCGTCTTCCACTCGCCACCGTAAAAGCTAGGTTTCCATCGCACCGTCAGCCACCGTCGACCGTCCACCCGCCCTCCCCCCCTGGCGTGGCCCGTCTCGCGACTCACTTTCCTCGGAACCGAGTCGCGATTGTGTGCAACGAAGAGCGAATTTTCTCCATTTCCAACAAAAAGTGTCTCAACGAAGCGGAGAAACATCGCCACACTACTGTTCTCCGCCCCATTCTTCCGCATTTCCAACCTGTATAAAGGTATCCCCTTTTCTCTGTCGCGGATGTGTGTGTGTTCTAGCCTCTGTGTATCGGTATGCGATGTCCAAAAAGTAGCTGAGTGCGTTGGCGTCTGTGTGTGCGTTTCCTGTTGTCTCCTTTGTCCTCGGAGTCCCTCCTTTTGATCGTTTCCAGATTGTTTCCTCTTGGCGCTCGCCAGCCTCCGTTCTGTCGCAGACTCAAAACCGCCGTGTCCACCCGCTGTTGGCGGCTACACACCCGCCACCTTTGTCTTCTATCGGTGTACACACCCCCCTCCCACACTTGCGTGCGTTGCAGAGAACGCATTTTTTTCTTTTTCCCCGCTTCCCCGCGTTTCTCTCCTCAGTCCCCCTTTTCCCAGTGCCCCCGGAAGTCGCTCGTGTGCCCGTCTCAACTCTGGTGTGCCTGTCGCCTTCCCGCCGAGCAAAAAAATGGAAATCCCGGCGCCCTCGAGTCCGACCGCTCTCAAGGCGGCCGTACCCGTCTCGTCTCCGACCATGGCTCTGCACACACACGGGTCTCTCAGCAGTTCTTTTTCAGAGGCCGTTTCGCCGTCCAAAAAGACAGGATCTGCTGGCGCCTCTCCCGTCCACGGCGCAGGTCGTGGCATGTACGTCGTCAACCGCCGCGGCGAAGAGGAGCCTGTTTCCTTCGACCAGATTCTGAAGAGAATAGAGAAGCTCTCTTTCGGCCTCCACCCTCTCGTCGACCCCGCTCGCGTTGCACAGGCCGTTATCAACGGCATGTACGCGGGGATTCGAACAAGCGAGTTGGATGACCTGGCTGCACAGACCAGCGCTTACATGGCCGCTTCTCACCCTGACTTCTCCAGACTGGCTGCTCGGATCGCCATCGACAACCTCCACAAAAACACAACAGACAACTTCTTGACTGTCATCGATCAGCTGCATGGCTACGTCGACAAACTGGGGCGCGAGGCGAAGCTCGTCAGCACTGAGGTGTACGAATTCGTGAGGGAAAATGAGCAGGCGCTGAACGAGGCTCTGAACTACTCCAGAGATTTCGACTACGACTATTTTGGATTCAAGACACTGGAACGGTCGTACCTCCTGAAGATCCACGACCGGATTGTCGAGCGTCCCCAGCACATGCTCATGAGAGTCGCATGCGGCATTCATTGTGGGGATGTGGAGAAAGCAATCGAAACCTACGAACTGATGAGTCAGAAGTTCTTCACGCATGCAACGCCGACCCTGTTCAACGCCGGCACCCCCCGCCCACAGATGAGCAGCTGTTTTCTGCTGACGATGCAAGAGGACTCGATCGATGGAATTTTCAGCACACTGAAGCAATGCGCGTTGATTTCCAAGACAGCTGGGGGCCTCGGTCTCGCCGTGACAGACATTCGAGCCACAAACAGCTACATCCGAGGAACGAATGGCTACTCGAATGGCCTTCTGCCGATGCTCAGAGTCTTCAACGACGCCGCGCGCTACGTCGACCAGGGCGGCGGCAAACGCAAAGGCAGCCTCGCCATTTACTTGGAACCTTGGCACTTTGATGTTTTTGATTTCCTCGACATCAAGAAGAACCATGGCAAGGAAGAGCGACGGGCGCGCGACCTCTTCTGCGCCCTCTGGATCCCAGATCTCTTCATGGAACGTGTGAACGACAACGCGGGGTGGACGCTGATGTGCCCTAACGAATGCCCCGGTTTGACGGAGGTGTGGGGCGACGAATTCAAAGAGTTGTACGAGCGCTACGAACGCGAAGGTCGAGGCCGGAAGACGATTCCAGCTCAGCATCTTTGGTTTGCGATTCTCCAGGCGCAGATCGAGACGGGGACGCCGTACATGCTGTACAAAGACGCATGCAATCGGAAGAGCAACCAGAAGAACTTGGGAACGATCAAGTGCAGCAACTTGTGCACAGAAGTCGTCGAATATACGAGCAAAGACGAGGTGGCTGTCTGCAACTTGGCCTCCGTCTCGCTGCCCAAGTTCGTGGACCGCGAGAGCCGAACTTTCGACTACGAACACTTGAAGCGAATCGTCAAAGTCATGACGAGAAACTTGAACCGCGTGATCGATCGAAACTACTACCCAGTCCCAGAAGCGAAGAAGAGCAACTTGCGGCACCGACCTGTCGGTTTGGGAGTCCAAGGTCTCGCAGACGCCTTCATGCTTCTTCGCTATCCGTTCGACAGCCCCGAAGCTCGCGTCTTGAACAGAAACATCTTCGAGTGTATCTACTTTGCCGCTCTCGAGGCCAGCTGCGAACTCGCCGCCGAAGAAGGCCCCTACGCGACTTACGAGGGATCGCCGGTGTCTCAGGGCATTCTCCAGTTCGACATGTGGGGTGTGACTCCGTCGAGCGGTTTGTGTGACTGGGATGGTCTGAGAGAGAAGATCAAGGCACACGGAGTGAGAAACTCGCTCCTCGTGTCTCCGATGCCTACGGCCAGTACCTCTCAGATTCTGGGGAACAACGAGGCGTTTGAGCCGTACACTTCCAACATTTACTACCGCCGAGTGTTGAGCGGAGAGTTTTTCGTAGTGAATCCACACCTGCTGCGAGACTTGCTCGAGCGGGACCTGTGGTCTGAGGACGTCAAGCAGCAGCTGATTGCGCACAACGGCAGTGTCCAGAACATGGACGTCATCCCAGACGACTTGAAGGCACTGTACAAGACCGTTTGGGAGATCAAGCAGCGCGTCGTCCTCGACCTGGCGATCGACCGGGCACCGTTCATCGACCAGTCTCACTCGCTGAACATCCACATGGTCAATCCAACCTACGCGAAGCTCTCCACTATGCACTTTTACGGCTGGAGAGGCGGCCTGAAAACTGGGCTGTACTACCTCCGGACGCAGGCGGCAGCGGACGCGATCAAGTTCACTGTCGACTCGCAACTCGCCATGAGTGCGAAAGCGAAACTCAGCGGCGCCACTGTGGGAGCTCTCACGACGACCAGTTCCGGCGCCGACGAAGACAAGCGACAAGACGTCGCAGAGACGGAGAAAATCGAGCCTGTAGCTCCCGTCTGCAGGTGGAGACGTACAGGCGCTTCTCCAGATGAACCCTGTGAAATGTGCTCAGGCTAATCGCGTGCGTCAGCATGCAACGTACATATACACATATATATACATATATACATATATATATATATATATATTTATTTATTTATATATTTATTTATTTATATTTACATATAAAAATTTGATATAAACGAAAATGCATATGCATACACTTGTACACAGCCAAATGTGTTTCCATATGTATAAGTGTGTGAAGAGTGTACAGTTGTCTCGTAGAGGCGGACGGATGGGGATTCGATCTTTTGGGCTGCTCAAGGTTGCATGCGTCGCTTCTGAAAGCAGAGGGGGAAAAGAAGCACGGTGAGGAGAGTCCGAAACATTCTGCGCGGGCGTTTCTACAACTTGGCACTCGCGAGAAAACAGTGTTTGTCAAAAACAGAATTCTTGGGTCTTGTCTGAGTCGCGGAACCTTTTGTATTTACTCGAACGTTTGTACGAGAGAGCCCTGAGTCCTCAAATGTCGCTCCGGTGTGCCATTTTCGTGGTTTTCGAGTTTCCACAAATGCACATGCGATCGCATTTTATACATGTCGCTCTGTGCATTCACCTATATGGCTGTACAGAGAGAGGGATGATTTCCTTGCGCAGGACTCTGGGATTTGTCGACTTGTTCGTTTCTTCACCTTTGGCAAGTTTTACGCCTTCCAAGATCCGATTCACTGTTTAAAATGCGTTTTTTGTGTAAGGTGCACTTGTATGCAAAGAATCTTTCGCACTTGAGAATGGGTCTTTTCTGGCCTTCGTTTGTATCACAGTGACGCGACTCTTCTTCGCTGCAGCACTTTGTGGGGAGTCTTGCTTGTGCAGTTCTGTTTTGACAGGGAAAAGACCTTTGAACGTTTCGAGAAAGAGCGGAGAATCTGGGGACTTGGCCGTCTCTCTAGCTCCGTTTGCTTGACTTTGTGTAACTGTCTGATGCTCTCTTCGCGGCACCGTATGCGCGCCTGTGCATGCGAAGCGACTCTCACGGGCAGAACCGACAACGAAAAGGAACATCCATTGAGAAGAAAAA
->XM_037917243.1 PREDICTED: Penaeus monodon D-dopachrome decarboxylase-A-like (LOC119568800), mRNA 
-CTTGGGTCTCCCCTTTTAGTCAGCTGATAAATCCCGTCCTAGCAACGTTAGTTGGAATAGCTTCCAGTGACAGCATTTTTTTTTTCTCTCTTTCTAAAGGGATATTTCAGATATGCCTTTCGTGACGCTGACTACTAATCTGTCTTCTGAAAAAGTGGACAAGGCTTTTTCTGAGAGCTTTTCGGAAAAGTTGGCAGAAACTTTGGGGAAGCCCATAGAACGTATTTCAGTGACTGTAGTGGCTGGGCAGCAGATGTGCCGAGGAGGAAGCTGGGACCCGTTGTGTGAGGTTCACGTGTTGGCCATTGGACTCGATTCCGCCGAGAAAACCCAGAAGCCAGCTGAAGAAATAACCAAATTCTTGTCTGACCGTACTGGGATTCAGCCTGCAAGAATCTGCTTAACTTTCCGACCAGTGCTGCCTCATCAGGTTTCCGTCAATGGCGCTTTAATGGGATGATTTCAACAGCCAGTGAATGGGACTGCAACCATGAGAGAGTATGTGGAATGATCTAGCAATAAACTATTCTACAGTT
->XM_040043500.1 PREDICTED: Simochromis diagramma methyltransferase like 3 (mettl3), mRNA 
-ACTGGTTTAGTTACCAACATGCCACTTTCGTAGACTGAGATATATATGTATTATATTTTACATCATATACCCTCAATCCTAAAACCACGACAAATCACTACGAAAGCGGAACGTTCAATCCCAATCAACCCGTGTGCTACCCGACACACGTTTTCGTGTTGCACCGTACCCGCTTCCCTCCAAGAGTGGACTGGATTCAACTTTTGTTTAGTTTCCCGGACACTCGGTGCTCGGTGAGGCCAGTATTGGTGTTTTTCCTTCAGCTGAGTCCATTTCGTCATGTCGGACACATGGAGCAACATCCAGGCGCACAAGAAGCAGCTGGACTCTCTGCGGGAGAGGCTGCAGCGACGACGGAAAGACCCGGCTCAGCTGTCCGCCGATGGTGGTGGCAGCACAGACGGCACCACAGTCAGGAGTGACAGCCCTGCCCCAGCAGCTCCGTCCACCTCGCAGGAGGAAACAGAAAAACCACCAGACCCTGAACTGGAGAAGAGGCTGCTGGGATATCTGTCTGATCTGAGTCTCACACTGCCAACAGACTCCCTTTCCATCACAAATGAACTCAACAGTTCAGAAACAGCCGTTAGTCACGGCTGCATCCAGAGCCTGCTGCTTAAATTCTCTGCTCAGGAGCTCATCGAGGTCCGAGAGCCCACCTCGGCTCCTTCTTCTTCTACAACTTCCTCCTCCACGTCAACCCCCACGGTGGTCGTAGCTGTGGACCACACAAAACTTTGGGCTATGATTGGATCTGTAGCTGGAGCCCAGAGAACTGGAGTCAAGAGAAAAGCAGAAGACCAAATGCACAGCAAAAGGGCTGCAGGCTTCTCGCCCTCGCTTCAGAGCTCTGCTTCTCCTCCTCACTCGTCAACCACATCGCTGACGCCGGCCTCCTCCTCAGAGCCGGGGCCTTCGGCGTCAGGGAGCGGGACGGAGAAGAAGGGCAGGAGCAGTAAAAGCCAGTCGTCTCATTTGGACATGGAGATCGAAAGCCTCCTGAACCAACAGTCCACCAAGGAGCAGCAGAGCAAGAAGTTAAGCCGAGAGATTCTGGAGCTGCTGAACGCCAGCACAGCCAAGGAGCAGTCCATCGTGGAAAAGTTCAGATCCCGCGGCCGAGCTCAGGTCCAAGAGTTCTGCGATCATGGGACCAAAGAAGAATGTGTTCGCGCTGGAGACACGCCTCAGCCATGCACCAAGTTACACTTTCGTCGCATCATCAACAAGCACACAGACGAGAGCCTCGGCGACTGCTCCTTCCTCAACACCTGTTTCCACATGGACACCTGTAAGTACGTCCACTATGAGATCGACAGCCCCCCGGAGACCGAGGGGAACCTGCTGGGGCCCCAGGCGGGGACCACAGAGCTTGGTCTCCACGCAGGGGACGCCGACAGCAATGTGGGCAAACTCTTCCCTTCACAGTGGATCTGCTGTGATATCCGCTACCTGGACGTGTCCATCCTGGGTAAGTTCGCCGTAGTGATGGCTGACCCTCCCTGGGACATCCACATGGAGCTGCCCTACGGTACTCTGACCGATGACGAGATGAGAAAACTGAACATCCCCATCCTGCAGGATGACGGCTTCCTCTTCCTTTGGGTCACTGGCAGGGCTATGGAGCTGGGCAGAGAGTGTCTCAGCCTTTGGGGCTATGAGCGTGTGGATGAAATCATTTGGGTGAAAACCAACCAGCTCCAGAGAATCATCCGCACCGGCAGGACGGGTCATTGGCTGAACCACGGGAAGGAGCACTGCCTGGTTGGTGTAAAAGGAAACCCGCAGGGGTTCAACAGGGGTTTGGACTGTGATGTCATCGTGGCAGAGGTCCGCTCCACGAGTCACAAGCCAGACGAGATCTACGGCATGATAGAGAGACTCTCACCCGGCACCAGGAAGATTGAGCTCTTTGGTCGACCCCACAATGTCCAGCCTAACTGGATAACTCTCGGGAACCAGCTGGACGGCATTCATCTGTTGGATCCCGAGGTCGTGGCTCGGTTTAAGAAACGTTATCCAGACGGCGTCATCTCCAAACCCAAAAACATCCAGTCATCATAACTGCTCACAACTCTGAAGAAGTTTGTTTTCAAACTGTTTTATTTTTTTTATACCTGTAAACATTTTTTTAATAAATATTGTCCACTAGATGCCCCGTCTCCATCTTGCCTGTGTACTTTTCACGGCTTCTCTGCACATTATCCATAATGATCGCATCGCCGGGCCTCCACACGATACCATATTATTGCTATTTTTAGTATTTTGCGATAAAACATGCAACTTATCACATTTTTTCAACAACAAATTGTGTCCTCAAAGCTAAAAGTTTGTCATCTGTTTCATCCAGTAACATAAAGTTATCTCACTTTATTTTTTTCCTGCAAAATGAGACTGTCAAGCAGACCGTCACTAAAACCTGCCATAAATGTTGCTATAAGAGCGAGCACGTCTGATATCAGTCCACAAGTTGGAAGTTATTTGCAATTTGTTTCTGATAACACTCCAATTAACTGCGATAAATCATCAAAACTCACATCTGCTGTTGTCTACACAAACAGAAATTCACATTTAACTATTAGATTTGCACTCAGTAAACTTCCTGTTCCATAGTAATATAACCAGAAAACAAACAGTAGGCAGCCAGTCGAGTTGGGCTCATGTGCCTGAGCTTATTCTGAGTTAGGAAGCAGCTTCGTTAAGGTCAGTGTCCAGTGTTGAACCGCGAGTTTGCTTAGGTGATGTTTTTTGCAGATGGTCGTGCACGAGAGGAGCCCTCTTGTTTGTAGCATTCCTGGAGTATTTGAATTTAGTTTTTAGAAAATGCCAATATTTGGTATCCTTGTGTCTTTACAACATTGTCAAGCAATATATCCCCCAGCCCAAAAAAAACACACCGGAGACATTTTGTTACAACTTATTTTATATTTGCTTAGTTTAGAATGAAGATATTTTTGACGTACTCTGGATTTGAACAAGTGATCATTAGTCTTTTTTTTTTTTTTTGATCAGCATTTAACAGTCATAGCTTTTCAATTTGGGCAAATACAGAAAGGTTTTCTTACAAAAAAAAAAAAACGTGCATTTTAAAAACACAGCCAGAGCGTCTTTTTTTCTAATTAAAAATATTGATCAGAATCAAGCAAGACTAAGAAAATACCTATCAGAAATAAGCTGCTGTGTAGCTCGGCTTATTTCATACGGTTGCCCTGTGGTGCACAACACAACTGGATTTCAGCAAGCCTTTCTGAAAGTATCAGGGCCACCGTAGATCTCACAGATGAACTATTAACTATTAACAACACTGCTGTTAAACAGGCTCAGACCTGGTCAGCAGTTAATGTCTTTTATAAAACAGCAAACCATTTTCTGTTTTATTACCTCACTTTAAACTAGCAGGGTTCTGTGTCACAGAGCAGGATTAGAAAGTTAATTCACGATGATGACTTAATGATGAGGTTTAGATAGTCACACACTTCATCACACTCAATGCTATCTTCCTCCTCTCGCTTTGTGAAACAGCCTTAATTAACTCCAGCCATGATCTAATAAGCAAATTGATCTTTTTCTACAAAGGTAGTCAAAAAAAAAAGAAATATAAAAGAAACACAGTAAAAAAAAAA
->AY653294.1 Chlamys farreri ferritin CFB mRNA, partial cds 
-ATCAACCGGCAGATTAACATGGAGTTGTATGCCAGCTACTGTTACCAGTCCATGTCCTTTTACTTCGACCGTGATGATGTCGCTCTCCCTGGCTTTTCAAAATACTTCAAGAAAGCCTCAGATGAGGAACGTGAACATGCCGAGAAGTTCATGAAGTATCAGAACAAGAGGGGAGGCAGGATTGTCCTTCAGGACATCAAGAAGCCGGACAAGGATGAGTGGGGAAGTGCCCTGGAGGCCATGCAGGTTGCTCTGGCTCTGGAGAAGAATGTAAACCAGTCTCTCCTGGACCTCCACTGTGTTGGGGACAAACATGGCGATTCTCAGTTCATGGACTTCCTTGGGGGCGAATACCTGGAGGAACAGGTGAACGCGATCAAGGAGATCTCTGACCATATCACCAACCTGAAACGCGTGGGACCTGGACTCGGGGAGTACATGTACGACAAAGAGTCCATCAATGGATCCTAGACCAGAGGCACCCCCTGTGGAAGCTTCTAGCAGTGTTGAACATTTTGCCCAGAATGTGTTGTCTACTAAAATACTATATAACCACTCAGTAACATGTGAATTATAATATTCCTGGAAGAACTTTCTAGAAAAATCAATGCATAATACACAAAAAGAAAAAGAAATAATGGGCACAAAAGAAAAGTTGAAAAAAAAAAAAAAAAAAAA
->XM_025196037.1 PREDICTED: Alligator sinensis chromosome unknown C5orf24 homolog (CUNH5orf24), transcript variant X2, mRNA 
-TTATACATGTTTGTCTCCTTTATTTTGGTAGAAAATGATGCATCCTGTTGCCAGCAGTAATACAGCTTTCTGTGGGACTGGCAAGAGTTCTTGCCTTAATGAAGACAACGTGAGAGCCACTGACCAGTTTGATTTATATTCCACACAGCAAAGCAAATACAGCCACGCAGTCAGCCACAAACCAATTGCATGCCAGAGACAAGACACGTTAAATGAATCGCACTTGCAGACCACAAGTGGCAGGAATATAGAGACAAAAGATGAACTAAAGAAAAAGAAAAACCTCAACCGGTCTGGCAAACGTGGAAGGCCTTCGGGGACCACAAAATCAGCAGGGTACCGAACCAGCACAGGTCGACCCCTTGGGACCACCAAAGCAGCTGGATTTAAGACAAGTCCAGGCAGACCCTTGGGTACAACTAAAGCTGCAGGATACAAAGTCAGCCCAGGGAGACCTCCAGGAAAAAAGCAGCAAGCCTTCAGGTGTTCCAGTGATGCCTAACACATAATGAGCTGGACTTTATGCTGTACTTTACAATAGAATACTAGCAGCACGGTTTGGCAGGAAAAAGAAAGATGGCTGCCATCAGAAGGTACCTAACTTTTAATCCTATGGTGGTATTTTTCAATATCAGCAGTTGGCTTGGTCATTTAAGCAACAGTCTTTACATGTTACATTTACTTCAAATTAATCAAAGAAAACGTCAAAACCCATTGAACAGCTCTTTTCTGAAGTGTGCTTTTGTTTTGCCAGAAAGATTTTTCTTAAGCGTTCAGTCAAGACCCTACCAAACCAAGTCATTAAGAAGTGGTGTGTCTGAGAAAAGAATCACTTTGCTCTAAAATACATAAAGTAATTCTGATCAGAACTTCACTTTTTTTCCATTTCGAAGAGCTTTAAAAGGCAGAGCAGTTTAAGGTTATTTGTCTATTGGTTTCATTAGTTATGACTCTGCTTTTTTGTTACTATATGTACAGTAATGTTTCATACTATCCCTATAGACGATTACAAATAAAACAATCGCAATTGTAAAGACTTTGAACTGCAAACATTGTTTCTGACCACAAGATAAGTTTGTTCCTCTTTTTTATTATAATGCATATATTTTAACATTGCTTAAATATATTTATGAACTCTAGTTAGAGACTAGAGCTTTTTCTTTGCAATTTTTTCCAAGTAGGTAAATCTTTTTTATGAAAAATATGATGATGGTATGATCATTTTTTAGGAATGTTATGCTCATTGCTTGGTAATTTGGACCACTTTATGATTCTTTATCTTTTACAATTTGCTTTTCCACAGGTTCATTTTGGAGGAAACAATTATCCATTAAGTAACTAATATCAGCACCCTGCCCTCTGCTGTAAAAAGCCTGATTAGATACTGTGTATGTTTTTATGTCCATGAACTTGAGCTACTCGTGTGCAATTATGTGTATGGGAATGGAGTAGTGTTCATGATCTGTATTTACATCATCATATGGATGTATATTTATTAATAAAGTCAGTACTTTAAAACCAAA
->XM_009169100.1 Opisthorchis viverrini hypothetical protein partial mRNA 
-ACTTCCGGCCGTGTGAGAGTATACAGCGTGCTCTCCAAAAGCTTCCGTACACCTAGTGGTGTCCGTCAGGGATGCTCACTCTCTCCACTCATATTCAAATTTGTTATCGATGAAATAATGCAACTAACGCTGGAATGTCTTCGGAACCCCGGTGTTCAAATAGCCTGTGACGAAAACCTTGTCGATCTGGAATATGCAGACGACATCGTTCTCATCTTCAGAGAAGAGGTGAAGGCGCATGTGTTTTTGGATGAACTCACGAAAGTCATTCCGTCCTTTGAAATGCACTTTGCACACACAAAGTGTAAAGTCATGTTCATGGACATGCAGCTACTGAACACGCCACTTACCATCCAAACCCTGCGTTTCAATATCGTTTCGGATTCTGCAATAAAACAGATGGAATTCGTGCCAATAGCAGAAAGTGCGATTGTAGGCGCACCAGATTGGTTTCTTTCCGGGGCAATTACAACGAGCAACTCACATTTGCGCGGGGATGTTCGATCTGCTCTCGTGGCCTTCTCCTCCAAACCCTACGTTCATATATTTTTGGTCAAAGTCAGGTCCGCAGAACAGCATGACGTCAGCTCAGTAGTCTACGTAGGTCAGATTCAAGCACACCACGAACGTATTTCAGGCTTGTCCTTTTGCGAATCCGTGAATTTTTCATCTTCATCGGATATTCAGATGTTCTCTTGTGGACAGGACGGACTTGTTCGACATTGGAGCTATCACAGTCATGAGTGGTTGCTCACCAAAGAATTGAATATTCGTTCATTCAATGAATCGCTGCTTCCCACATGCCTGGATACAATTGTGATCGCTGACCAAATTCTCGCTTTAGTTGGGACAAACAAAGGAACATTGCTTGTTTGGGCTGTGTTTGCACTATCCACTGAACCCGTCTGCTTGACAAAGAAATTCGAAAATGATTCAGCGACAACTTGTGCTTGGGAACCGTGCAACTTGTCGGGTTGCATACGCCTGGCGATTGGATACAAAAAGGGGATCATAGGAGTTTACCTCTATCAACATTCCTCTGTGACCGCAGCGTCTTCCTTGACTCAACTATCTCGTTTCTATGCCCACGAACGGGACATATGTCACGTTGTGTGGAATCCATCTGCACACGGATACTCAGAAGTGGCAGCGTCGGAACCAGAGTTATTATCTACTGGACGGGACCAGATGGTTAAAATATGGAACATTGCCAGTTCGTGGTGTTGTGGTTCGGTCAGAGTTCCTGGGAGTGCACGTTCAATGCCAAAAGAATCGGATTCATCCAACCTGACAAAAAACCAGTCTACAGGTGCTCCTTGGATATCTGCTTGTTGGTTCCCAGAAAAAACGGACAATCCGGGCAGAAATATAGTTGTATCCGGTCTTCGAGGTGAATTGTATAGCTGGTCCGATTCGTCACAGCTGGTTCGTTTACACACCGAGAACCATGGTCACTCAATGCTTGTTTTCGCTATTCGTTCTATCCCTGATATGGACGGATTGTTCTTCACAATTGGCCAGGATCGTCAAGTTATTCTCTGGACATATCGTTGTCCGACTGACTTGACATTCATGCTTCGTGTGCCTACTATAGCTGCTGGTATCTCTGCTTTGGCACAGTCGGACCACGGACATGGACCAATTGCAGCAGGCGTGGCAGATGGATCAATTTTATTGTGGCGGCACTGCAGCTCTTTACAAGAAGAATCTTCTTCAACGAACCCGGTGACTTCTTACTGGCCACGTGGTGTGCACGGCAGCTGTGTGACTGCCTTAGCTTGGCATCCTTCAGTTCGCCATGAAAGTCTACTTGCCTACGGAACCGAGTCAGGATGTGTGGAACTCATTGACACATCCAAAATTCCCAAAAGTGCTACTCAGAGGTCGAAAACGCAGCCATATATTTTTGGATCAACCGTCTATCGAGTTGCTTGGGGACCTCCACTTTTCACAGATTCAGGGAAGGATCAGGTTGTTGAAACAGCTGTCTCAGAACACGATGCGAATGGTTCGACAGATAGCACAGATACGGTGGAACAAAAAGACTCAACAAACAAATCCTCGAGTACTCCCAAGTTCTCATCTTATATATACAGCGTATGCAAAGGGAAGATTTTTTGCCACGTTGGCTTCCAGCGACCACCTTTGGATGTAACTTTGAAGTTTCCCTCTGTTCCCGGAATCTCTACAGAGGACTGGGTAAATGACAAACGAACCGACATCGCGTTTTTATACCTGGAGAATTCCACCCGTTCCGTTGACAGTCCTTCTGAAGAGAATGAGATCCGCGAGTGTTTCAGCTGTTTGATCACCGTCGGCTACCGATCTGGGTCGGTGGATGTATACGGACTCGTGAAATCGAAGGAGCATGTATCGGTCGACCTTATTCGACCATTGTGTCGTATTTCTTGTCATACGAAGGGTGTCAATTGCTTGGCTTGGTCCTTTGACCGCTACTGGCTTGCAGTTGGCACTAATGAGTCCTTCATCACTGTAACTGATGTTGGGCACATTCTGAAACAAGCCACGAAACCCAATAATCCCTCTTTCCGACAAATTTCAACTTATTTGGCACATCTGGAGGGCCACGGCAACAGGATCACATGCTTGGACTGGTCTCCGCATGAAAATGGTCTCCTGCTTTCCGCTTCATTTGATGGCACTGCAAATGTCTGGAAAGTAACTCATAGTGACACCGAGTCAGGTTCCACATCTGTAGCGAATTTTCGAGCTCATCGTCTTCGCCTATTTGCCTGTCTGTGGAGTCGTCAGGAGGCGGACCTGGCTTTTAGCGGTGGTGAACTCTGTCACCTATTTAGCTGGCGTCCATCCAAACTCGCACATAAAGAGCCACCTAATTCCCGTCGTTATAGGCCTCCTTCAGTTAAACGTGTGCCCACCGATTCAAAGGATCCCTTAATGCCGTCGGGCATTCTCGAGCCTTCGGCCATTGTTGTCACCTCACAAGAAGTAAATCATACGGAATGTGTACCAGAGCCCATACATCACACTGATACGTCCGTTGGGACAAGTGTCCCACTTGAACTACCGGTGAAATCTGTGACTACGAAAAAACCTGGTTCAGGGGACAAACGCAAGCGACCGTCTTTGTGTCCACATTTTTTGCATCGCGGTTCACTTGAACCAAGTACGACGGATCTGGGATTTTGCCCTCCTTTTCGCCTAGGCTCAAGGTTTCTGCAAGTATCGCACGTACTAAATCTGTTGAAAAACGATGTTGATCTACCTGAATCGGACTGCGATCTTCTGTTCCTATTGCCAGAAACAAACAAAACACGATCAGCCTTGGTGCGATTTTTGACCAGTGAAGCAACTCATCATCTGTCAGCATATCGTGCAACTCAGCGATCTAATGGGCTTATGCATTTGGATGCTTATTGTATCATTCTTCTATGGCTTGGACGTACTCCGTTGGTTGCGCAGACAATGTGTTCTGAGAAACACATGCCCTTTTGGTTGCTTTGGGCAGTTCAATTGGCTCAAACAACCGTACCGGCCTTCTCCGCTCCCCGAAACTCATCAGGTGATCACGCGGATATAGATCTAGCTGGAGAAAAGGTCAAGGATATGACAAGCAACAGCCCTGATGTTTTGGTGTCTTCCACGTTACTTGTTTGTGCGGGTCGACATCAGGAGGCCGTTGATTACCTATTTGCACAAGATCGAGTGAAAGAAGCCTTGTTGCTTGCACGGCTCAGACTCAGTCCCATGGACGCGAACTCAGCAATGCAGAAGTGTATTGCTCGCATCATCGAACGGCGGTTGTGTCCGGAGGTTCCGTTCGTCAGAGTTTTACATGAACTTGGAGCTGGCGAGTGGGAGCGGGCACAGACAGTTCTACGTCAGGCAGCCGTAGTTTCCCTTTCACGCCAGGACATGGAAGTTGAGCAAGTTGCAAGTAGCTGGGTAGAACTTAATATTCTCCTCAGCTGTCCGGATGACAGTTTACCGACGAATGCGTTTGTTCGATTTGCTTTAAGCTGTCTGGCCGTTGGCTTCCAGTTGCCAGAAGCACAATCCATAGTTTACTTTCAGCGGTGTCAAGAAGCTGTGACTCTGTCAGCTGTCTTGGCTACTGGGACGGATTGCTTTCGACTGTTGTTAAATACTGGCCTTCGGTTTGCTGCTATTCTTACTGGCTCTTCTCAAACAGAACTCGAATTGGATATGGAACTACATGCAGATGTGAGAGATATTGTACACTGTCTTCGCTACGCAACGCTTGATCGTCAGCCAGCGAATCAGTGGTCTGCATGTGCTTCCCAGTTGGCACTTGATTTCACCATTTGCCTTCTTTCATCTAAAAAATTGACGTCTCAAGACCAATCCACTGAGGACCTTAATCGGCTGGAAGCGAGTTTGCGTTTGTGTTCAAAAGTCAATCCCACAAACACACAACAACTCAGTGACCTCCTGTTCCACTCCCAGACTTCTTCGGACCTTGACTCACGTTTGAAGCGGTTACAATCGACTGCGCTCCGCCCCTCAGACAATACAGATGAGCAAATCGGAAACACTTGTCCAGTGTTCTGTTCTCCTTTTAGCCAAACAACAATGCCTTCCGTCCGATCGCGGCGTAGCACATTATCTTACTCCGCCGAACTGGAGCGAGCCGGGATGGCCCCCATTGAAACCCCGATTGAACGCGTCACGGGTTCAACCGTGGTAGACGCTCGAATGTCTAGCGCTTCTAGATTTTGGAATCAGGATAATACACTTGTTAACATAAGAATGACCCCTTTCGGACACGAAAGAACCGACTACACATACGGAGATAGTGGAAGTTATCGGTCAGAGCGGGTTAAGACCAAATGGAACACACCGAATATGTCGCGCCTACCCGTTCATGGGAACCACGTTGCTGGACAACACATCGCCACTTTGGGTTCCCGTACTTTGAATGACTCAGATTTTGAAATGGATTCCGTTCTGACCGATGAAAGGTTGTCAGCGGTCATTCCGGGCCTAGGAGGCAATCGCGAGGAAGAGTTAGAAGATGATGAGCTTAGTAGTAGGGCTTCAGTTGCCTCATCTCGATCCAGCACCCGTATGTCGCGTGTCCGCTGCATACGCGTGCAAGGTGAATGGTGCGTTCATTCTGAGTGTATCGCTTCTACTCCTGGGAACCGACGTATGAACTTGGTTGCTCGTCAGCGCAATACAAACAATACTGCTGACGTCACTCACATCGTCGATGGGACTGATACAGAAACTCCCACTGGAAGATCTCGACATAAACACGAACAGCAGCAGTTGGTTTCTCGAAGATCCACTCGCGCCGGTGTGAGACCCTCGATTACGGCAACGAAAACCACTACATCTCAAAATCGCATTGAGTCGAATCCTCACACGGATCGTTCGAATCAGTTGGCTTCTGCTAGTTCCACGTATGTCTACACCTATGTAGCACCAGATGCTGACCATATGCGACCAGGAGAAGGCGGAGACAAAAGCTCGTTCGAGAGAGGAGACATTCCTGATTCGAATGGCAGAATGTGGGGTGCACAACCTCCACACGTTTCATCAAATGATCCCACTACTGAGCGATCATTCTTAGCCAATAGGTTTGTTTGCTCCAGTGGAACGTCTTCCGCTGGAAACAAAGCCCAGAAATGGCTTGCTCGACACATTTTTGGCCTTGAGTCATCTGCCCCGGTGAGTACTTCGAACCATTTTGTACCCAGTGATACTGAAGAGTCAGATACAATCACAACTGGTCGCTCCGTTGCTCGTGGGAAATACGTACACAAACCAAGCGTCACACGAAGCCATCGACTGCACCATATAGATTCATCATCAACAACCTGGTTCTTCCGACCGTTGATGCAAGGAGCAGAGAAGCTGAAAGGAGTGATTTTCTCGAGTATAGCTTTTGTATTGGCTGGCATCTTCATCGCCTACGATGCTTTCAGTTCTTGCGTCCGTAATTTGTCATCCGCCGTTTGGACCTTTTGGTTCCGTTATTCCAGTCCTTTGCCCCACCGTTCTCGTGATAAACTGACCGTTCATCCACGGCTAACTCAATTCGACAACCACGTCACTCTTCAAATCTCATCGGTCGAGGAATCTGACTTCTTCTCTCGATCGTTCCGGGCAAGCTACGTCTGGTTTACCAGAGCTGGGACGATCTGTGTTCGTCTGGTGGGCTGTCTTTGTTTCCTAATCCCGCTCCTCTTACTTTTGGCTTTCTTATTCGCACCAGTTGCTGTCAATGACGACGAACCACCTCCAGTGTGGCCTTCTTTTCTTTCGGATACCGACTGTAAAAAGGCCCTACTCGAATCTCGCCCCAGCGATGCAACAGCTTGGCAGCTCGCCCTTTGGAGATTCCGCTGTCTGTACAATCTATACTTCCTAACTCCCGACTTTCCGTCAAATGCTACCACTTCGGAAAGCTCTTCATTGTGGCAGAAGTTTAAAAGTTGGTTGTGGCCTTCTACATCCGTTGTACCCTCCCCGGTCATCGTACCAACTGATCTACCGTCATACGTCGACAGTAAGTTGCTCGCTCAGCTGGAAGCATTCCGGGATTTTGTGAACGATCGATTGGATGGTTTGTCAAACACTATACGTCATACGGAAGAACGTGTGTCCGAGATGGAACAACGATCTGAGACACAGTTCAATGACCTCAGTATACATATTAACAATTTGAAACAACACTTTAACGAGCACACCACTGCATTGGATTCCTGGCATGTCCAGCTACAAGCACTGCAGGCTCTTGCAGGCCGCTTGGACAGTTCGGAGCCATCAAAGGTGACTCTAAACGAATACGATCGACTCTTCAATGCGGTTATCAGTGCCGCAAATCAAACCGTTTCCAAGGAGTTGAATTTACTTCGGATCGAACTGGATGAGAAGTCAAGTTCAATGTGGAACCGACACAACTCCAGTTTCACACAACTGTCCCTGTTAATTTCTCGTCTGCGTGAAGAACTGAACGACCGCTTGCTTCAAACGGAACACAGGCTTGGTGAACTACGTTCACAACTAAACTCGGGAATTCATGCACAAGTAGTCAACCATACGTCGCTCGTTATCCAAATGGACGAAATCCGCCTAACATTAGGCAATCTATCGGAGCGTGTGGCACAAGTCCGGAGCGCTAATGAGGGGCTGGATGGACTGTTCAAGAAACTACAAGAAGCCACACGAGACTGTAGTGAACGACAATTGCATCAAGTAGAAGACTGTAAGCAAGCGGCCATCGAACGAGCGGAAATTGCCGTGAATGCTTTTTCCGAACGTTTCACCGATCAAATTTCCGTTCTTGTCAAGGAGGCTTTGCTGCATTGGCTGAATGATGTGTCGGTTGAGGAAGCCCTGGATTTGAAACTATCAGAACTGGTTAAACAGTCCACACGAGAAGCCGTAGATCGAGCCATCCGTGAATCCGCGATCTCAGGGTACGCTCCGAGCGTGGACACCAGCGCAGAACAAACCGACGAATTAAAATCCCGAGTATTCATTCAGAAGCTTATTGACGCTGCCCTAGAGCGTTTTGCCGCCGATCGAGTGGGGATGGCCGACTTCGCTTTGGAATCCGCTGGTGGGTCTATCGTAGGCACACGCTGTACGCGGACTTACACAGAACGGGCAGCACTCTTCACCATATTCGGCATACCTTTGGCTCGTTTAAGCAACTCAGCAAGAACCATTTTGCAACCAAGCAACAATCCCGGTGATTGTTGGGCATTCCATGGAAGTACGGGACAGGCGGTAATTCGCCTCTCAGCACCTATTGTCATAACGTCCGTCACCCTGGAGCACCTACCTCGTGTTCTTTCACCAAACCAAAGGGTGGATTCGGCGCCGAAGGATTTTGTCATCAAGGGTCTATCATCGGAAACTGATGAAGGGGTCGTAATTGGAACATTTGTCTACGATATCAATGGTCCTGCCATACAAACATTTCCGATAGAAGGTCAGTCATCTACGTGGCATTTAATCGAGTTGGGAATCCTCAGCAATCACGGACATCCACTATACACATGCGTGTATCGCTTGCGTGTACATGGAAGAATACCAGACTCCTAGGCAACTTGACGACTGACTGACTGTGAATTGCCAGCATGTTTCTGTCTGCCCACATGTACATATCGACCCCGGCTGTATTTTCAGACTCGTTAACACGTCTGTTGTCCCCGGTGTTTTATAGTATTCCAACTTCCCATACAAAGTGTATACTCTCTGAAACACCTCTAACCGATGAATGTGATTTTCCTCTACTGCAGGCGACCGGTAGGCAGCCTAATCTCCTAATACCCGCTCATGTCTTAATGATTCATGTGTAACTTTGAATATCTTTTCTGCCGCCGCCGTCGCTGATCCACCACTCATTCACCTCGCTTATCTAATTACAAACGTTCTTC
->XM_021551582.2 PREDICTED: Lonchura striata domestica carbohydrate sulfotransferase 9 (CHST9), transcript variant X2, mRNA 
-ATGTAGTGCTTCTTGAGGTTGGTGTCTCTGGGGAAGACACCGAAGAAGATGCAGGCATGCTGAAGACTTCAGAGAAGTGAGCAATGAGTCCTTCTGAAAGCTGAAGAAAAGCCCCCTTGTAGGGTCATGAACCTAAGACAAGTCTTCGTGTCTGTACTGCTGTTTGGAGTAGCTGGTCTACTCCTCTTCATGTATCTGCAAGCTTGGATTGAAGAACAGCATACAGAGTCTGGAAAAAAGCTGCAACAAGAGACAATTAATCAGGATTTCACACTCCAGCCTCTGGGGATGCCAAGGAAAGCAGCATGGAGAAGAATTGTTCCTGTGGGCCTCAGTAACCCTGAGATGGCTGTCTCAAGCAGCAGGCACTGGCAGGGCAGGGCTGACCCTTTTGGTGTGGTGGCTGCCTCCTCGAGGAGCTGGCTGCCTGAGCAGAAGATGAGTGAGTCCCCTCTCAGCTGGTTCAGAGGGGCGTATTTACCTCCTGCTCTGCACCCATTAAACAAGACATTTGTCAAGGGTGGTGAGTGGCAGGACATAGACAGCACCCAGGAAAAGCGCAGGGCCTTCCTGCAGGGCATCTGTAGGAAACACAATAGCAGAAGGAAGCTGCAAACCCATCTGGTGCACCTGGTGTCAAGAATTTACGTAGAGGACAGGCACAAGGTTTTGTACTGTGAAGTGCCAAAAGCAGGCTGCTCCAACTGGAAAAGGGTCCTCATGGTGCTCAGTGGACTCGCTGCTTCAGCAAACAACATCTCCCATGATGATGTGCACTATGGAAAGCATCTAAGGAAATTGGACAGTTATGACCTAAAAGGGATCTACACACGCTTGAACATGTACACCAAGTTTATATTTGTACGTGATCCTATGGAAAGATTGGTATCTGCCTTCAGGGATAAGTTTGAACATCCAAACAGCTATTACCATCCCGTATTTGGGAAGGCAATAATAAAAAAGTATAGACATAATGCAGATGAAGAAGCACTGAAAACAGGATCGGGAGTTAAGTTCAAGGAGTTTATCCAGTATTTGTTGGATTCCCACCGACCAGTAGGAATGGACATTCACTGGGAGCAAGTCAGTAAGCTCTGCTATCCCTGCCTCATCAACTATGATTTTATAGGAAAATTTGAAACCCTGGAAGAAGATGCCAATTACTTTCTGCAGCTGGTAGGTGCTCCAGCCAATCTGAAGTTCCCTAAATTCAAAGACAGACATTCCTCTGATGAGCGAACAAGTACAGAAGTAGTGAGGCAATATTTAAAGGAATTGTCTAAGGAGGAGAGACAGCTGACCTATGACTTCTATTACTTGGATTACTTAATGTTCAATTATACATCACCACTTGTATAGCACTAGAATAGCTTCAGGCTTCTACTAGATACTTATCATGTTGGGATTCAAAACAACTACTTTGATATTAGCCCTGAAAGGAAACAAAGTTACTGCTAAGTAGAGTTGTCTTGAATTAGTGGGGATTTTATAAGCTAGAGTGGTATCAATTGATACTAAATTATGGAGAATGCAAAGAAAAAAGACCTGCAAACAGCATAGATTGCACTAAAATGCCTGGAAAAGCTGTTTTTACCATTATGGATTATATTATGGAAGCAGTAGCTCAGACAGCTGTTGCATTAGCTTACCTAATGTTCTTTTAATGGTTTAAGAAAAAAAAATTGGAGTGGCATGATTCTTTTTTGGTATGTTTTCTTTAGAAATGGATTTTGAAAAAATTTTGAATGTATTTTTACTTTCTGTCACTTATTAATAAATGATCATAGGCTAA
->XM_027345943.1 PREDICTED: Dermatophagoides pteronyssinus SOSS complex subunit B1-like (LOC113795734), mRNA 
-TTGAATTATTTATTTACTTATATTTTTTTATTTAATTTTTTTTTGTAATTAAAATATATTTTTTTCCTATAAAAAATATTATGGGCTATTCGATTAATCAGATAAATATGACCGATAAAATTGATTCAATAAAAGATATTAAAGCACCATCGAACAAATTAAATGTTATTGCAATTGCAGTTGAAATTGTTTCACGTTTAATAACCAAAGATAATCATGAAATACGTGTAATGAGATTTGCCGATCGTACTGGTTGTATAAATATGTGTCTTTATGATGAATTAGGCGCAACGGTTCAACCAGGTGATATATGTCATATAACACGTTGCTATGCAACATTTCATAAAGGTGCATTAACATTATATATGGGTCGTCATGGTAAATTGACAAAAATTGGTGAATTTTGTATGACGTTTACTGAAACACCAAATATGAGTGATGGTGATCCATCTACATTATCATCACCATCAACTTCATCAACATCAACGTCGTCGTCGTCGTCGTCGTCATCAACGTCATCAGGTCCACCAACAAATTCATAAATATTTTTCATTTTTTTTTCTTTTCAAAAATTGTG
->EU801997.1 Uncultured bacterium clone 3C003382 16S ribosomal RNA gene, partial sequence 
-AGGGTTTGATCATGGCTCAGATTGAACGCTGGCGGAATGCTTTACACATGCAAGTCGAACGGCAGCACGGACTTCGGTCTGGTGGCGAGTGGCGAACGGGTGAGTAATATATCGGAACGTGCCCAGTCGTGGGGGATAACGTAGTGAAAATTACGCTAATACCGCATACGATCTAAGGATGAAAGCGGGGGATCGCAAGACCTCGCGCGATTGGAGCGGCCGATATCAGATTAGGTAGTTGGTGAGGTAAAGGCTCACCAAGCCAACGATCTGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGACGCAAGTCTGATCCAGCCATTCCGCGTGCAGGACGAAGGCCTTCGGGTTGTAAACTGCTTTTGTACAGAACGAAAAGGTCTCTATTAATACTAGGGGCTCATGACGGTACTGTAAGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTATATAAGACAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTTGTGACTGTATAGCTGGAGTGCGGCAGAGGGGGATGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAACACCGATGGCGAAGGCAATCCCCTGGGCCTGCACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGTCAACTGGTTGTTGGGTCTTCACTGACTCAGTAACGAAGCTAACGCGTGAAGTTGACCGCCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGATGATGTGGTTTAATTCGATGCAACGCGAAAAACCTTACCCACCTTTGACATGTACGGAATTCGCCAGAGATGGCTTAGTGCTCGAAAGAGAACCGTAACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGCCATTAATTGCCATCATTTAGTTGGGCACTTTAATGGGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTATGGCCAGGGCTTCACACGTAATACAATGGTCGGTACAGAGGGTTGCCAAGCCGCGAGGTGGAGCCAATCCCAGAAAGCCGATCGTAGTCCGGATTGTAGTCTGCAACTCGACTACATGAAGTCGGAATCGCTAGTAATCGCGGATCAGCATGTCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTTTACCAGAAGTAGGTAGTCTAACCTTCGGGAGGACGCTTACCACGGTAGTATTCATGACTGGGGTGAAGTCATAACAAGGTAACCGTA
->XM_007934102.1 Pseudocercospora fijiensis CIRAD86 uncharacterized protein (MYCFIDRAFT_212712), mRNA 
-CTTTCATGTTGTATGCTGGAGTCTGCATGTCCGCGGACACTTGCGCACGAGAGCATCAGCGCCCAGCGAGCTTGCGGAATGCGGAGCTGTCATGGTCGTACATCTGCCGAGTGTCCGTAACTGATATCGGTAGCCTCCTCAATTCTGGAAGCCTCTCAGATCCCAGCGTCCTTGTTCGCGCTGACGTTCTCTATGTCGCTTCTTTCCGCGGTGTTTCGCTTCAAATTCTCTCCCACAATCTCTTATGCAGTCTCTTCCACGCCCTCTTGCACGCCCACATCACCAGCAATGATTTCCTTCGGGTTGGCGGCTCGAGAGCTTATTGCAGCCTTGGTGAGAGGTGTAGGTCCCACGTCGTGACTTGTCCCGACGACAGGTCTCGCAGTGCATGCATCTTCGTCTTCTGGGGGTGTGAGATCGCTATCTCAACTGCCCTCGAGCTACGACTTCCATATCCCGCCTTCCTACTCCACCTTCTCCAAAGCCGGCCACATGTCGCAGACGTAGCGCTTCATGCACTGGACGGCTCTCTTGGCGGCGATTCCGAGGATAGCGACTTCACAGATGGTGCAAATTTGAACGACGTGACGGAGGAGAAGCTCTGAACCGGATCCACTGTGGTGAGAAGGTTGATTCCACAGCTCATCTCTGCATCCCTGTGGCCTTCCATCCCAGATGCGATTGAGTGAGGATCGGGTCATTTGCTGTGAGTTGAACTTGTCTTGGATGAAGCATACGATAAGTGTGATGTTGTAATAATCTCAACAGTCATGAACAATGACGG
->XM_026366555.1 PREDICTED: Anabas testudineus cytochrome c oxidase subunit 5A, mitochondrial-like (LOC113166428), mRNA 
-TCGAGTACGTGACCGGCTAAGTTAGCATTAGCTTCCTCCTGCCAGACCTCACCGGTTCGAGGAGCTAGCTGCCGCTCATCATGTTCAGAGCCGCCGTCCGACTTTCTGTCTCCGGTGTCCGGGGTTTAACCCGTACGCAACCACGGTGCCAAGCTGTTTTGGCCTCAAGATGGTACTCACATGGGAAACAAGAGACGGATGAGGAGTTTGATGCCCGTTGGGTCACTTATTTCAACAAGCCAGACATTGATGCATGGGAGCTGAGAAAAGGGATGAACACGTTGATTGGTTACGATCTGGTACCTGAGCCAAAGATTCTTGAGGCAGCACTGAGAGCCTGTCGAAGGTTAAACGACTTGGCCAGCGCTATCCGAATTTTGGAAGCTGTAAAGGAGAAAGCCGGTCCTCATAAAGACATCTACCCGTACGTGATCCAGGAGCTACGGCCAACATTAGATGAACTTGGCATCTCCACACCTGAAGATCTTGGCATTGACAAAGTGTAAATAAGTATCTGATAGTGAATAACCCCAGGACGCAGAATCATTGTACTTACATGTTTGCCTCACCTGATATGTGTGATATTTAATTTGCCCTTTATTAAGTTCTTTTGTTGTAAAATATTGATGAACCTAATAAAGGAAAACGAATCTTTATTGAGTGTCACATATTTTGAGAGATTTTAAACAGCCTGGTTACATATTGAAGCAATATTTTTGAAGTTGCTTTAACAGCAGAGCAGAGCGTCACTTGATGGTGCAAGTTGTCTCATTCTTCTGAGAGTCGCGTTTTGCCACCAGGGAGCAGCGTTTTCACATGAATGTAAAAATCATTCTTCTGTATTCAATCTATATTTCATCTGTTCAGGGAAGATATACATGCTGGTGAAATAAACTTGTTCAAATGTCAAA
->XM_008046871.1 Trametes versicolor FP-101664 SS1 uncharacterized protein (TRAVEDRAFT_136475), partial mRNA 
-ATGAACGAGCTGCAGACTCTCACAACTTTGCAGCCTTCAGCGGTCGTCTCAACTCGCGTCTCGCACTCCCTCGACAGATGTTCCACGCGGTCCTCCATTCTTTCCCATCCGAAGCTGTCACACAAAGTCAAGGGCATCTGCAAGGTCGCGCGTAAGGCCGGCTTCCGCCTCGTCTGGAACGACGCATGCTGCATCGACAAGTCGAGCAGTGCCGAACTCTCTGAGGCGATCAACTCGATGTACGACTGGTTCCGACTCTCGGACATGTGCTACGTCTACCTCCAAGATGTTGCGGACGGCGATAGACCCCAGGAAGCCCAGTCCGATTTCCGGAAGAGCCGATGGCACACCCGCGGTTGGACGCTGCAGGAGCTCATCGCGCCCGAGTGCGTCGAGTTTCTAACGCAGACTTGGCAATTTCTGGGCACGAAGCTGGGGCTTGCCTCGACTTTGGAGGAGATAACCGGAGTCGACGTCAATATTCTCACAGGCCGAGCCACCTTGAACTCTGCTAGCGTTGCGCGGAGGATGTCATGGGCGGCGAAGCGAGAGACGACGCGCATCGAGGACCAGGCGTACTCGCTCATGGGTATTTTCGGCGTCCACATGCCGCCTATATACGGCGAGGGCAACAACGCCTTCCTGCGTCTCCAGGAGGAGATAATCCGGACTATCCCCGATCAGACCATATTTGCCTGG
->FJ010171.1 Homo sapiens TCF7L2 isoform pFC8A_TCF7L2_B4_ex1-no4-11-14 mRNA, complete cds, alternatively spliced 
-TTTTCTTCCAAAATTGCTGCTGGTGGGTGAAAAAAAAATGCCGCAGCTGAACGGCGGTGGAGGGGATGACCTAGGCGCCAACGACGAACTGATTTCCTTCAAAGACGAGGGCGAACAGGAGGAGAAGAGCTCCGAAAACTCCTCGGCAGAGAGGGATTTAGCTGATGTCAAATCGTCTCTAGTCAATGAATCAGAAACGAATCAAAACAGCTCCTCCGATTCCGAGGCGGAAAGACGGCCTCCGCCTCGCTCCGAAAGTTTCCGAGACAAATCCCGGGAAAGTTTGGAAGAAGCGGCCAAGAGGCAAGATGGAGGGCTCTTTAAGGGGCCACCGTATCCCGGCTACCCCTTCATCATGATCCCCGACCTGACGAGCCCCTACCTCCCCAACGGATCGCTCTCGCCCACCGCCCGAACCTCTAACAAAGTGCCAGTGGTGCAGCACCCTCACCATGTCCACCCCCTCACGCCTCTTATCACGTACAGCAATGAACACTTCACGCCGGGAAACCCACCTCCACACTTACCAGCCGACGTAGACCCCAAAACAGGAATCCCACGGCCTCCGCACCCTCCAGATATATCCCCGTATTACCCACTATCGCCTGGCACCGTAGGACAAATCCCCCATCCGCTAGGATGGTTAGTACCACAGCAAGGTCAACCAGTGTACCCAATCACGACAGGAGGATTCAGACACCCCTACCCCACAGCTCTGACCGTCAATGCTTCCATGTCCAGGTTCCCTCCCCATATGGTCCCACCACATCATACGCTACACACGACGGGCATTCCGCATCCGGCCATAGTCACACCAACAGTCAAACAGGAATCGTCCCAGAGTGATGTCGGCTCACTCCATAGTTCAAAGCATCAGGACTCCAAAAAGGAAGAAGAAAAGAAGAAGCCCCACATAAAGAAACCTCTTAATGCATTCATGTTGTATATGAAGGAAATGAGAGCAAAGGTCGTAGCTGAGTGCACGTTGAAAGAAAGCGCGGCCATCAACCAGATCCTTGGGCGGAGGTGGCATGCACTGTCCAGAGAAGAGCAAGCGAAATACTACGAGCTGGCCCGGAAGGAGCGACAGCTTCATATGCAACTGTACCCCGGCTGGTCCGCGCGGGATAACTATGGAAAGAAGAAGAAGAGGAAAAGGGACAAGCGGCCGGGAGAGACCAATGGAGAAAAAAAAAGTGCGTTCGCTACATACAAGGTGAAGGCAGCTGCCTCAGCCCACCCTCTTCAGATGGAAGCTTACTAGATTCGCCTCCCCCCTCCCCGAACCTGCTAGGCTCCCCTCCCCGAGACGCCAAGTCACAGACTGAGCAGACCCAGCCTCTGTCGCTGTCCCTGAAGCCCGACCCCCTGGCCCACCTGTCCATGATGCCTCCGCCACCCGCCCTCCTGCTCGCTGAGGCCACCCACAAGGCCTCCGCC
->KX179358.1 Uncultured bacterium clone MA_1774 16S ribosomal RNA gene, partial sequence 
-ACGGGGGGCGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCGGGCAGGCGGTCCGCTAAGTCTTTTGTGAAACTCCAGAGCTCAACTCTGGACATGCATAAGATACTGGCGGACTAGAGACCGGTAGAGGCTAGTGGAATTCCTGGTGTAGCGGTGGAATGTGTAGATATCAGGAAGAACACCAGTGGCGAAGGCGACTAGCTGGGCCGGGTCTGACGCTCATCCGCGAAAGCGTGGGGAGCAAACAGG
->XM_004415061.2 PREDICTED: Odobenus rosmarus divergens fidgetin-like 1 (FIGNL1), mRNA 
-AGCATGCAGGCCTCCAGCTCCAGGTCTGTGCACCTGAGTGAATGGCAGAAGAATTACTTTGCAATTACATCTGGCACATGTACCCCAGGACAGAAGGCAGATGCGTACCGAGCACAGATATTACGCATTCAGTATGCATGGGCAAATGCTGAGCTCTCCCAAGTCTGCGCCACCAAACTGTTCAGAAAATATGCAGAGAAATACTCTGCAGTTATTGATTCTGACAGTGTCGAGACTGGCTTGAATAACTACGCAGAATGCATTTCAACTTTAGCAAGATCTCAGCAGACTGACAGTGACAAGTGGCAGTCTGGATTGTCAATAAATAATGTTTTCAAAATGAGTAATGTACAGGAGATGATGCAAGCTGGCAAAAAATCCAGAGACTCTCTGTTGGCACCTGCCAGTGCATCGGTAGTAATCCATAAAGAGGCGCTTGTCCTCGATCCTCCTAAACTTAGTGTTTGTGGGGGTTCTGGGGAGAGTGGCCCATTAACTAACGCAGCTCCTGATACAAACAGGACCCAAGATATCCCAGAGAGCAGTCCTTCGAAGTGTCCTCAGGATGCTCAGCCACCTGTGCCGACTAACACCAGAAAGACCTGTCCTTCATCCTTAACACCGTTTGGTGACTTTGCCACTGCAAAAATCCATGCCACACCATTATTTGGAAATGCCAAGAAGGAAAATAACAGCTCTCCAAAGGCCAACGTAGGACTAAATATGTTCTCATCTAATCAGTCTTGTTTGCCTTCTGGCTTTGAAAATCCACGGGAGAGAAAAACTTTTTATGGTTCTGGCACCACTGATGCCCTTTCTGCCCCAGGAGTGAATAAGGCTTTTAGTAAAACAGAGGATAATGGCCAAAGGGAAGAGAGTAGCCTGCCTACTTTTAAAACTGCAAAAGAACAGTTATGGATAGATCAGCAAAAAAAGTACCACCAACCCCAGCGTGCATCCGGGTCTTCGTACGGTGGTGTAAAGAAGTCTCTGGGAGCTAGTAGGTCCCGAGGAATATTTGGGAAGTTCATTCCTCCTATACCTAAGCCAGATGGGGGAGATCAGAATGGGGGAATGCAGTATAAGGCTTACGGCGCAGGACCTGCAGAGCCAACACATCCAATTGATGAGCGGCTGAAGAACTTGGAGCCAAAGATGATTGAACTTATCATGAATGAGATTATGGATCATGGACCGCCCATAAGCTGGGATGATATTGCAGGAGTAGAATTTGCCAAAGCCACAATAAAGGAGATAGTCGTGTGGCCCATGATGAGGCCAGACATCTTTACGGGTTTACGAGGACCCCCTAAAGGAATTCTGCTCTTCGGGCCCCCCGGGACTGGTAAAACTCTAATTGGCAAGTGCATTGCTAGTCAGTCTGGGGCAACGTTCTTCAGTATCTCTGCTTCCTCTTTGACGTCTAAGTGGGTAGGTGAGGGGGAGAAAATGGTCCGTGCATTGTTTGCCGTGGCAAGGTGTCAGCAGCCGGCTGTGATATTCATTGATGAAATTGATTCCCTGTTATCTCAACGAGGAGATGGTGAGCATGAATCTTCTAGAAGGATAAAAACGGAATTTCTAGTGCAGTTAGATGGAGCAACCACATCTTCTGAAGATCGGATTCTAGTGGTGGGAGCAACCAATCGGCCCCAAGAAATTGATGAGGCTGCCCGGAGAAGGTTGGTCAAAAGGCTTTATATTCCACTCCCAGAAGCTGCGGCTAGGAAACAGATCGTGATTAATCTGATGTCCAAGGAGCAGTGCTGCCTCAGTGAGGAGGAAATTGCCCTGGTTGTAAGGCAGACCGATGGGTTCTCGGGAGCTGACATGACACAGCTTTGCAGAGAGGCGTCTCTCGGGCCTATTCGCAGTTTACAAACTGTTGACATCGCCACAGTAACACCCGATCAAGTTCGGCCAATAGCTTATATTGATTTTGAGAACGCCTTCAGAACCGTGCGACCTAGCGTGTCTCCTAAAGATTTAGAGGTCTATGAGAACTGGAACAGAACTTTTGGTTGTGGGAAGTGAAGGGGACACACGGGACACTTGAAATCTAAAGATGGCATCTTTGTAATGCAGCCTTCCCCACTTTTTAGCATGGGAAACTGGGAATTTATTAATTGTACTTTATAGTGTATATTTTGAATTCTATACCTCAAATAAAATAGTAACAGCTTAAAT
->XM_018530727.1 Alternaria alternata hypothetical protein mRNA 
-CCATCATGCAGTCTCAGCAAACTCCTCGGTATGTAAGCTAGAAGAGATGGCCTGTTGTTTAGGCACTTGCTGGACAGACCGATGGCTAGACCTCTATGCGATAGATGTAGAACAACACAAACAACAACTTGGACTAAACTTGCACGACGGTAGTCGGCAGTACGCCTTAAAATCAGAGAAATGTCTCGACACGTTTGGCCTTCCAATACGCTATCTACGTAGCACTTCACTCACCCTGATCATCTTAGCACATGAATACAGGCATATATGTCAGATACACGCAAAGTACAATAACTTGGCTTCACAGCGATCTTGGTGGAATCAATCACGTCTTCACGCAGAACTAGTGCTTGGAGAGTCAATTCAATACGAGTCGGAAACTCCCGAGGTCATCTTTACCGGCCGATGTGGTCTTACTGGAGAGAAGTTCGGAATTTTTCTAGTCAATATGATTATTATATTTCTCTTGCACAAGCACATACGACCACAGGATCTTGAGACCACGGCTTCCCGTTCGCTCAGCCCTAGTTAAGCAAGATACCGGCGGATTAGTAGTCAGGTGGGTGACCACTGGCGAATCCCCGCTGTTGTATGTTTTTTTGTTTCTTTCGAAAGAAGATCATTAGGCCGAAAATAGGCGTACTTGTTATTTTTTTGTCTTCCCGCAGATGCTGTTTCGCATGGTCGAACTTCTTTGACGTCGAGATAGGTAGTAAAGAGTAGGCAATAATTGTGGTTTCATCGTG
->DQ227595.1 Uncultured bacterium clone ZFos29a01 16S ribosomal RNA gene, partial sequence 
-GAGTTTGATCCTGGCTCAGGATGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGATGACTTCTGTGCTTGCACAGAATGATTAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTCGGGATAAGCCTGGGAAACCGGGTCTAATACCGGATACGACCTCCTGGCGCATGCCATGGGGGTGGAAAGCTTTATTGCGGTTTTGGATGGACTCGCGGCCTATCAGCTTGTTGGTTGGGGTAATGGCCCACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACACTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCGACGCCGCGTGAGGGATGACGGNCTTCGGGTTGTAACCCTCTTCAGCANGNAAGAAGCGAAAGTGACGGTACCTGCAGAAGAAGCGCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAAGGGCGCAGCGTTATCCGGAATTATTGGCCGTAAAGAGCTCGTAGGCGGTTTGTCCCGTTCTGCTGTAAAACCCGGGGGCTCACCCCCGGGTTCTGANTGGGTT
->XM_001452590.1 Paramecium tetraurelia uncharacterized protein (GSPATT00002630001), partial mRNA 
-ATGAAAGTGCGTAAGTAAGCACCCCAATTTACAGCATCAGCCTACTTTAATAAATAGTTTAAGAGAATATCTCTAAGTGATTATAAAAATAGATATGTTGTTCTATTCTTCTATCCATTGGATTTTACATTTGTATGTCCAACAGAAATAATCCAGTTTTCTGATCGAGTTGAGGAATTCAAAGCAAATGGTTGTGATATTTTGGGTGTCTCTGTAGACTCCTAATTTTCTCATATGAAATATTGTAAATAAACACGTAATAATGGAGGATTGGGTGAGATGCAATTTCCTCTGATTTCAGATTTAAGTTAGGAAATCTCTAAAAAATATGGAGTCATTATAGATGATTCTGAAGATCCAGATTTTGGTGTTGCTTTCAGAGGGACATTCATAATCGACGGAAAAGGAATCCTCAGACATTATTCCATTAATGATTTACCTGTGGGTAGAAATGTAGACGAAGTCTTAAGATTAGTGTAAGCATTTAAATTTACAGATGAACATGGAGAAGTTTGTCCTGCACAATGGAAACCAGGATAGCCAACTTTGGTTACGAATCATTCTGACCCAAAGACTTAGAAATATTGGAATGAAGAACATATAAAATAAGCTAAATGA
->XM_007882153.1 Pseudozyma flocculosa PF-1 uncharacterized protein (PFL1_04627), partial mRNA 
-ATGGGCTTCTTCGACGTCGGCTCCATGCGGAGCAAAAAGTCCAACGCGGAGCTTACACAGGAAGCACGCATGCAGAGGCGCAAGAACGACGAGATCCTCGCAGCCAACCTCGGCCTCGACTACTCGCATGGCGGCAGCAGCAATCGCAGCAACGGCAAGTCGAGTCGTGACCGGCTCCACGACGACTTTGCAACGGGGCACGGCGCCGCCGCATCGACTGCGGCCAGGGACGCGACAAGACGGAGCAAGCTGGAGAGGATGATGGGTGCCGACGTGCCACTGCCCGACTCGCTCTCGGCGCCCAATGCTGACCATCGGCGAGGGCAGCATCAGGCCGACGCGGCATCCCAGATCTACGGCTCAAACGGAGGCTCGGCGCTCCACCTGCCCATGTCCAAGGGATCCTTTGACGCCATGAGCCAGCATTCGTCACACTCCTCCGGCCGCGAGCGTCAGTCGAGCGGAAGATCGTTTGATCCGCTCCCCGGCGCTTCAACGACCTTCACCGAGATGGCCGAGGTTGACTGCCCTGTCTGTCTGGAGCCGCTTTCGTACCGGCTCGCCGGCGAAAAGCCTCACGTTGTGCCCAATTGCGGCCACGCGCTGCACAACGCTTGCTTCACCGCCGTCTACGGCCCGCCGGAAGCCATCATTGCGCAGCAGAATGCGGCCTTGGGGGCAGGCAACGGTCGCACAAAGGGCGCCGGTCTGGTCCAGCGGACCCCGGCCGCAAACCCGCCAGGCATGTGCGGTGTATGCCGTCGAGCCATCGTGCTCGGCGGTGACGAGGCCACCGCCAAGTCTCAGAAGCTGGCGGGGCTGGGTCCGCACGGGTCGCAGGCCGATCGGATGACTCTGAGCTCGGACTCGGCCTCGGTTCGAGCCCTCTCTGAAGCCCACGAGGACGACCCTCTCGAGAGCCAGGCAAAAGGCCGGTCTGCCAACATCTCGGGACCCATCACGACCCCGACGATCCGGGCTAGGCCAGAGTACTCGACCATCTACAAGAAGGCCGATCGCAAGGACAACAGCAAGGTCAATGTGGTCTGCGTGCTCTCGGTCGAGGTGCCATCGAGAAGGCCGAGCTCTGACGATGCGGTCGAGTCCGGCCTTGACACGATCGAGGATCGCGGCTACGCTGAGGAAGAGTTTGACGAGGAGGACGAGCGCGACTACGAGGGCGAGGACTCGTACTCGGACGACCTCAAGCGCAGCGGCTCCGAGTACGTCCCCAACGACCGCAGGTCGAGCGGTCAGCGCAGCCCGCTGCCGACGTCGTACGCCAACGGCGCCGACGGAAAGCAGGCCGCCAGCCCGGAGCGCTGCATCTCTCCCGAAAGTCAGGCCGGGTTCTCGTACAGTGCGACGCCGGCAGCGCAGCAGCGGCTCAACGATCCCAACCTCGCTGTGGTCGAGGACCTCCGCAGTCGCGTGGCCGATTGGAAGGGTCACTCGCTCGAGCATTTCGGCGAGCTCGTGCTGCACGACCTTCTCAACGTCCGCCAGGACAGTGTCGTACGCGAGTTCCACGTCTACCTGTTCGAGGGCGCGCTGCTCTGCGTCACCGAGGAGAAGCGAAAGGGTCTCAGCCGGTTCATTCCTGCGGCACCTCCGGCCGCTCCGGGTGCCACCCCCGACGTTCCTGCCATGCCCAAACCCGCGCTCAAGCTCAAGGGCCGCATCTACCTCAAGCACATCCGCCGCGTCATCGACTCGTCGGTCGCTGGCGAGCTCAGCATCAGCATCACGATGGACGAGAGCCTGGATCAGTTTGTCCTCTGCTTCCGCGATCGCGAGACTCTGTCGGTGTGGAAAGAGCGTCTCAGCCAGAAGGTCGCCGCACAGTCCAAGTCGGCGGCGGCGGCAACTACGGCCAAGGAGGCGGCCAAGCCCGAGGAACCGGCATCAGCCTTCGACGCCGCCTCGGCCGCTCACTCGGCCGCGAGCCATGGCATGCACCCCCTCGACGACCACCAGCGCCTCCGCGGCCTTCCCGCGGCACCCAGCCACGGAGTTTCGATCTCGCGGGCGAATAGCGGCGCCGCATCAATCATCAGCGGCAAGACGGGCTCTCACCAAGGCGCCCTCTCTCCGGCCGACTACAGGAACATGCGACGCTTGTCGAACGTCTCGAGCGTCCAGAGCCACGGCAGCCACCGCAGCCGCACCTCGACAGCTTCGGACACGGTGCCTCGCCACCAGCAGTGGTCCGCCTCGGGCGGGCTCGACCCGAGGATCCCACCGCCTCCGATGCTGCCACACACGCCGCTCGACTTGGTGCTCATGTTCGCCGTGCCTCCGGTCCTGCCCAACAACGCACAGGGCTCGATCAACTCGTCGGCCGCGCTCAAGCTTCGCCTGGTCCGATCGACGCTTGACTTTGTTGTCAGCCACATGGGACCCAAGGACCGCGTCTCGCTCGTGGCCTACTCGGTCGGCTATGAGGGCGAGGTGAAGCGCACGGCGCTCCTCAACCCGAGGCGCTCGTCGAGCCGACAGATGCTGGGCGAGTTCATCCAGTGCATCGGCAGGCCTTGGGACGGCCACGCCGAGGACCCGTTCCGCGTCGACCTGGACCGGCTGGGCGGAACGAGCGAGCGGACCGATTCGGTGACGGCGGTCAATGTCGGGCTGGACATCGTGCTGCAGCGCAAGCAGAAGAACCCGATCACGGGCATGATTCTCGTCAACGACACGGCCGACGGACCCAAGCGGCACCAGATGGACCTGGTCATGGCGCGGGCCGAGGCGGCCAACGTGCCCATCCACTGCTTCGGCTACGGCAAGACGCACGACCCGTCTTCGCTGTGGCTGATCTCGAACCACACAAAGGGCTCGTACACGTTTGTGCGCGAGTGGTACCAGCTGCGCGAGTGCCTGGCCGGCTGCATTGGATCGATGATGTCGATCGCGCTGACCGACGTCAAGCTGCACGTCAGTGTGCCCCACGACAACCAGTTCCGCGTCCGCAAGATTGCCGGCATGCCCGGAGCCATCATCTCGTCGTCTGGCAAGGACGTCGACATCGACATGGGCGACATTCGCTTTGGCGACGCGCGCGAGCTGCTGGTGGAGCTCGAGCTCGATCTCGAGAGCCTGCTGCCGCGCCTCAACGCCAGCAGCAGCAGCAGCCGCAAGCTCTCTGCGCCTCCCATCGAGCAGGGCAGCGCTACCGACGACTTCATGCAGCGACTCGGCATCCAGGGGCTGAGCCTTGCCGACTCGGACGGCGCCGAGGGGTCATTTGAGCACCTGATCGACGAGGTCCCTGTCTTTGAGGCCGATGCCGGTTTCCGCGACCCGACCAACGGCACCAGCACGTCGAGGCTGGCCAACCCGACGATCCTGACGCTCGAGATCGACTGCCAGTCGCCGGACCCCGTGTCCTCCGGGCCGCCGGGCCTGGCCGCTGCGATGGCCGATCCAACCGTGACGCGGCGGCGGCTCGAGGTGTTGGTGTCGGAGATGATTACGCGCTCGCTGCTGCTCATCTCTCGCTCCAACTACGCCCAGGCGCAGAAGGTGTTCAACGAGACGCGGAGGATCATTGAGACGGTGGTGCGGGCAATCCCGCTGCCCGCCGGCGGCAGCGGCAGCGGCTCGCGGCGGCGGGCGCCGATGGGCAACTCGCGCTCCGCGGCCAAGCGGCAGCGCGACGCGCTCAACCGCAAGACGATCGACAGCCTGATGGCCATGATGAATGACCTCGACACGCTGCTGGAAGGGCTCGAGGCGCAGAACCGGACGACGTTCGAGCGCGACGGGCGCAACTTTGGCGCGCAGCAGGCCATGATCCTGCGCGATCAAAAGGCGTGGACGACGCGGACCGACACCGAGTATCAAAACTTCCGCGACGACAACGCCGCCGCTTTCGCTGCCTACGGTGCTTCGTACGCCAGCTCGCGGTGA
->XM_033386580.1 PREDICTED: Drosophila miranda mucin-5AC (LOC108151008), transcript variant X9, mRNA 
-AATGTTTGTCTTTAACTCATACGCGAATTCGTTACGCTCCCCAACTGTTAAAAGACCAACGATGTCTTCGAAGGCTTCTTCACGAGATTTATTAAGATTTATAATATCACTAGTAGTGCTCAGCCAAATCATACTCAAAAAAGCAGAGAGTGCCTCGGTTGAAAAAGTGCATTTAAAAAGTGCGCAAGTGAAAAACAATCTAATTGAATATGACTCACAGTTTGGCCGAGATACAAAATTTAATCATAAAAAAACAACTATAGCAAACGATATTACATCTGCACCTGAAGAGAGAACATCAGCCGCACATTCGACTTTTGCACCTGCGGAGAGCACCACAGCTGGGGGCAATACGACTTCTGCTCCGGAAGAAAACAACACATCTGAGGACGATACTACTCGTTCTACTTCTGAAAAAAGCACAAAAGCTAATGATTCGACATCTGCAGCACCCGATATAAGCACCACAGTTCAAGATTCGACATCTGAACCTGAAGAAAGCACTACAGCTAAGGACAACTCTACTTCTGCTCCTGAAAAAAGCACCACAGCTGAAGGGGATTCTCCTGCTGCTCCTGAAGAAAGCACCACAGCTGAAGAGGATTCTTCTTCTTCTCCTGAAGAAAGCACAACAGTTGAAGATTCGACCTCCGAACCTAAAGAAAGCACGACAACTGAAGGCGATTCTACTGCTGCTCCTGAAGAAAGCACCACAGCTGAAAATTCGACATCCAAACCTGTAGAAAGCACTACAGCTGAGGAGGATACTACTTCTACTTCTGAAAAAAGCACAACAGATAAAAATTCGACGTCTGAACCTGAAGAAAGCACCGCAGCTGGGGTCGATTCTACTTCAGCTCCTGAAGAAAGCACCACAGCTGAAGAGGATTCTTCTTCTGCTCCTGAAGAAAACACAACTGTTGAAGATTCGACCTCCGAACCTGAAGAAAGCACTACAGCTGAAGACGATTCTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGATTCGACTTCCGCTGCACCTGAGATAAGCACCACAGCTGAAGATTCAACGTCAGAACCTGAAGAAAGCACTACAGCTGAAGGCGATTCTACTTCTGCCCCTGAAGAAAGCACCACAGCTGAAGATTCGACTTCCGCGGCAACTGAGATAGGCACCACAGCTGAAGATTCGACGTCTGAACCTGAAGAAAGCACTTCAGCTGAAGGCGATTCTACTTCTGCTCCTGAAGAAAGCACCACTGGTGAAGATTCGACGTCTAAACCTAATGAAAGTACCACAACTGAGGTCGAAACTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGATTCGAAATCAGAGCCTGAAGAAAGCACCACAGCTGAAGAGGATTCTACTTCTGCTCCTGAAGTCACCACTACAGCTGATGACTATACTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGTTTCGACATCTGAACCTGAAGAAAACTCCACGGCAGAGGACGATTCTACTTCTACTCCTGAAGAAAGCACCACAGCTGAGCACGATTCTTCTTCTGCTCCTGAAGAAAGCACGACAGCTGAAGATTCGACTTCCGCGGCACCTGATATAAGCACCACAGCTGAAGATTCGACGTCTGAACCTGAAGAAAGCACTACAGCTGAAGGAGATTCTACTTCTGATATTGAAGAAAGCACCACAGCTGAAGATTCGACTTCCGCGGCAACTGAGATAAGCACCACAGCTGAAGATTCGACGTCTGAACCTGAAGAAAGCACTTCAGCTGAAGGCGATTCTACTTCTGCTCCTGAAGAAAGCACCACAGATGAAGATTCGACATCTGAGCCTGAAGAAAGCACCACAGCTGAAGATTCGACATCAGAGCCTGAAGAAAGCACTACAACTAAAGGCGATTCTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGACGATACTACTTCTGCTCCCGAAGAAAGCACCACAGCTGAAGATTCAACATCAGAGCCTGAAGAAAGCACTACAACTGAAGGCGATTCTACTTCTGCTCCAGAAAAAAGCACCACAGCTGAAGATTCGACTTCCGCGGCAACTGAGATAAGCACCACAGCTGAAGATTCGACGTCTGAACCTGAGGAAAGCACTTCAGCTGAAGGCGATTCTACTCCTGCTTCTGAAGAAAGCACCACAGCTGAAGACGATACTACTTTTGCTCCTGAAAAAAGCACCACAGCTGAAGATTCAACATCAGAGCCTGAAGAAAGCACTACAACTGAAGGCGATTCTACCTCTGCACCTGATGAAAGCACCACAGCTGAAGAGGATTCTTCTTCTGCTTCTGAAGAAAGCACAACAGTTGAAGATTCGACCCCCGAACCTGAAGAAAGCACGACAACTGAAGGCGATTCTACTTCTGCTCCTGAAGAAAGCACCACAACTGAAGATTCGACGTCTGACCCTAATGAAAGTACCACCACTGAGGTCGAAACTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGATTCGACATCTGAGCCTGAAGAAAGCACCACTGCTGAAGATTCGACATCAGATTCTGAAGAAAGCACCACAGCTGAAGATTCGACTTCCGCGGCAACTGAGATATGCACCACAGCTGAAGATTCGACGTCTGAACCTGAAGAAAGCACTTCAGCTGATGACGATACTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGTTTCGACATCTGAACCTGAAGAAAACTCCACTGCAGAGGACGATTCTACTTCTACTCCTGAAGAAAGCACCACAGCTGAGGACGATTCTTCTTCTGCTCCTGAAGAAAGCACCACAGCTGAAAATTCGACATCAGAGCCTGAAGAAAGCACTACAACTGAAAGTGATTCTACCTCTACCCATGAAGAAAGCACCACAGCTGAAGATTCGACTTCCGCGGCAACTGAGATAAGCACCACAGCTGAAGATTCGACGTCTGAACCTGAAGACAGTTCTACAGCTGATGACGATACTACTTCTGCTCCTGGAGAAAGCACCACAGCTGAAGTTTCGACATCTGAACCTGAAGATAACTCCACGGCAGAGGACGATTCTACTTCTACTCCTGAAGAAAGCACCACAGCTGAGGACGATTCTTCTTCTGCTCCTGAAGAAAGCACCCCAGCTGAAGATGTGACTTCCGAGGCACCTGATATAAGCACCACAGCTAAAGATTCGACGTCTGAACCTGAAGAAAGCACTACAACTGAAGGAGATTCTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGATTCGAGTTCCGCGGCAACTGAGATAGGCACCACAGCTGAAGATTCGACGTCTGAACCTGAAAAAAGCACTTCAGCTGAAGGCGATTCCACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGACGATACTACTTTTGCTCCTGAAGAAAGCACCACAGCTAAAGATTCGACATCTGAGCCTGAAGAAAGCACCACAGCTGAAGGTTCGACATCAGAGCCTGAAGAAAGCACTACAACTGAAGGTGATTCTACTTCTGCCCCTGAAGAAAGCACCACAGCTGACGATTCGACTTCCGCGGCAACTGAGATAAGCACCACAGCTCAAGATTCGACGTCTGAACCTGAAGAAAGCACTACAGCTGATGACGATACTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGTTTCGACATCTGAACCTGAAGAAAACTCCACGGCAGAGGACGATTCTACTTCTACTCCTGAAGAAAGCACCACAGCTGAGGACGATTCTTCTTCTGCTCCTGAAGAAAGCACGACAGCTGAAGATTCGACTTCCGCGGCACCTGATATAGGCACCACAGCTGAAGATTCGACGTCTGAACCTGAAGAAAGCACTACAGCTGAAGGAGATTCTTCTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGATTCGACTTCCGCGGAAACTGAGATAAGCACCACAGCTGAAGATTCGACGTCTGAACCTGAAGAAAGCACTTCAGCTGAAGGCGATTCTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGATTCGACATCTGAGCCTGAAGAAAGCACCACAGCTAAAGATTCGACATCAGAGCCTGAAGAAAGCACTACAACTGAAGGTGATTCTACTTCTGCCCCTGAAGAAAGCACCACAGCTGACGATTCGACTTCCGCGGCAACTGAGATAAGCACCACAGCTCAAGATTCGACGTCTGAACCTGAAGAAAGCACTACAGCTGATGACGATACGACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGTTTCGACATCTGAACCTGAAGAAAACTCCACGGCAGAGGACGATTCTACTTCTGCTCCTGAAGAAAGCACCACAGCTGAAGATTCGACATCTGAACCTGAAGAAAGCACCACAGCTGAAGATTCGACTTCCGCTGCACCTGAGATAAGCACTACGGCTAAAAATTCGACATCCGAACCTGACGAAAGCACTACATCTGAGGACGATTCTACATCTGCTCCTAAAGAAAGCACCACAGCTGAGGCCGATACAACATCTGATCCTGAAGACAGCACAGTTCAGGACGATACTACTTCTGCTTCTGAGGAAAGCACCACAGAAATCACCACAGCTGAGGATGGTGCTACTTCTGCTCCTATAGAGAGCACTACTGCTAAAGTAGATTCTACCACTGGATCGACGTCTAGCCCGGCGACATCACCTTCTCCTATACCGCCTATGTCATGTGCAAGTGGCGCTCCATACTTACCGCATCCATCGGATTGCCATAAATTTATTCAGTGCAGCAACGGACATGAGTACATCATGCATTGTCCAGATGATCTCTTCTGGGACTATCAGAATTTATACTGTGGGTATGATGACAGCGGTTGCTATAACAAAGTGGATCCCGAGGAAACGGTTTGCAAGCACGGCATGGATTTTCTACCAGACCCAACTGATTGTACGAAATATATCCAGTGCAGTAATGGTCAACCAATCGTCCAGAAGTGTCCTGAGCCTTTGTATTGGAACCAAAATCTTAAAGTATGTGATTGGTTCAGTAGCTCCTGCAAAACTCTACAAAAGAATGAAATAATATCTTGTAAAATGGGTATGAGTTTTGACGTTTTTCCAACCGACTGTTCGAAATATATTAAGTGTTTTGGTGAGCGCGGTGTAATAATGAGCTGTAATTCTGGACTTTTCTGGAACTCTTTGCAGGAAGTATGCGAAAAATCCCAGCGGTTCTGCAAATAATATGTAAGCATAAACAGTTACTCGTATAATATTATTCACTCTTGGTAGATTTTCTTGTTAAATGAATTGAAGAATATTACAGAAAATATAAAGGCATTACCCATTCTTTAATC
->XM_029689086.1 PREDICTED: Oncorhynchus nerka SWI/SNF-related matrix-associated actin-dependent regulator of chromatin subfamily B member 1-A-like (LOC115147092), mRNA 
-ATGGTGTCAGGTGTGCGGGATAATCAGCAGCCTGATGACCTAGAGGCCGGAGAAAGGGAGTATAGGGAGCAGAAGGCAAAGAGGAACAGCCAGTGGGTCCCCACGCTGCCCAACAGCTCCCACCACCTGGATGCTGTGCCCTGCTCCACCACCATCAATCGCAACCGAATGGGCCGCGACAAGAAGAGGACCTTCCCCCTGTGCTTTGGCGACCACGACCCGGCGGTGATCCACGAGAATGCGTCTCAGGCCGAGGTGTTGGTTTGTCTGGACATGGAGATTGACGGGCAGAAGCTCCGAGATGCCTTCACCTGGAACATGAATGAGAAGCTGATGACCCCAGAGATGTTTGCTGAGATCCTGTGTGACGACCTGGACCTGAACCCCCTGGCCTTTGTCCCGGCCATCGCCTCAGCTATCCGCCAGCAGATAGAGTCCTACCCCACAGACAGCATCCTGGATGAACAGACCGACCAGAGGGTCATCATCAAGCTGAACATCCACGTGGGGAACATCTCCCTGGTGGACATGTCGGAGAGGGAGAACTCTCCGGAGACGTTTGGCCTGATGCTGTGCTCCGAGCTGGGCCTGGGAGGAGAGTTTGTTACTACCATTGCCTACAGCATCCGCGGCCAGCTCAGCTGGCACCAGAGGACGTACGCCTTCAGGGCTGATTTCAGTGAGAACCCCCTGCCAAAGGTGGAGATTGCCATCCGCAACACAGGTGACGCATGGTGCCCTCTGCTGGAGACCCTGACAGATGCAGAGATGGAGAAGAAGATCAGGGACCAGGACAGGAACACCAGGCGCATGAGACGACTTGCCAACACTGCCCCCGCCTGGTAGAGAGAAGCACCAATAAGCTACTACAGAGCCTCTAGTCCAGTGGTTCCCAACCTCTTTTTGAACCGTGGCACACCTTGATGGGATATACAATTATGCCCTGCACACCAAATTCATTCATTTAGTGGTGATGACATCCATCTGATCTATATTGCATATCATCTATTTTCTGTGACAAATGTTTACTAAATAGGGTTTGTTTGAAGTATTTTCATAGTTCCTTACTCATGAAGGTTCATTTCTGTATACCCCTTTAAGAGTATCCCGCAAATAGGTATTTAGTTTTGAACAGTCTGTGTTAGAGGTACAACCACGTACACATAGCCAAGCTCCATTTGTTTTTATGGCAAGAGGCTGTGGTATAGCTAATAAATTACTCTCGCTAAGCCTAATCAAACTTACAAGTGATAATGGTTATCACAGACTAAGTAAAATAATAAAAATGACTTTGCTCGTGATGCGAGCCCCTCAAATGATACAAATGGAACAGCCTGAGTGCACTGGACTTGGAACAACGATACAGATGTAACAATGTACCATTTAATCTATTATCTGACTGGCACAGGTGCTCCCAAATCAAAATTACAGAGTGTACAAACATTTTTATCAAGATTAGGAAAGGTTTTGTGGCACACCACTGCTTCTAGTCAGCTAACAGTCAACTCCTATGGGCCCTCTGTGGAGACACACACACAAACAAACGTGACAAAAGACAGTCAACTGGTCCCTTCTTACAGCCCCCGTAATATTAAACTAGCTTTATGCTTGATTGTCATACTAATCCAGTACCAATGCCACATCTCTACTCCCATTAATAAAAATAATTACATCTGATCCCAGATCAGAGACTGTTCAAGGAGCCTTCTCCATTTCTAGCCCCTCTATTGGTTCAACCGCTACTCATTTCTGATGAGATGAGGCGACGTGGTATATAAAAGGTGCCATGGGTAGAGTGTATTTGTCCGTATGAAATGTAGCCATTGTCGATTGTACGGACTCACCATCTAAGTGAGCTCTACCTGTAATACTGCTTTGATGCACTTATATCTCTCATGATAGACAATGCTGACGGACTTGATCTGTCTGTTAATAGAAACACTCAGACTCAACTCTTGGGAATAATGTAAAGTTCTGTATTTATGCTGATACTTTTAGTATATTTTTTAGTTTCCTTTTTTAATAAAATAACATAAACCAGA
->XM_028986422.1 PREDICTED: Denticeps clupeoides disintegrin and metalloproteinase domain-containing protein 11-like (LOC114794095), transcript variant X1, mRNA 
-GGAGCTCCCGGTCCCACGTGTCCTGCCTTCCTCCGCTGGCTCGGCGCTTCTTCCTTCCTTTCTTTTAATCGACAGCTCCCTCCTTTCGCAGGCTGGCCGCGTTTTTCATTTGATTTCATTTTTTCATTTTTTTTTTCCTTTGGAACCGCAGCGCCGCCCAGTCTCACATTCGCCCGCGACGGGGCGCGCATCTCCCCGCATCGCCGCCCGCCCGCCCCGCTCCCCCGGTTCATATTTATCGACCGCCTCGTCGTCGTGAGCACGTTCCCGTCCGGTTTTTCCTGCTCCATGTGAGCCCGCGGGGCGACGTGAACAGGATGCTGGTCCTGCGGTGCCTCGTGTTCGCTGCTGCGGGCGCCGGGCTGTCCGCGACAGGCGTGAGCGGCGGGTCTCCAGCTCAGGATGCAGGCTTGTGGGACCGGGTCCTCCCAGTCCTCCCAGAAGAGGAAGAGGAGCTGTCCCGGCCACACCGGCTGCTGCCGTGGAGGGACTCGGACAGGGAGAGCCCACACAGTCACCTGGACACCCGGTTGAGGGACAGCAGCGGGAGCGTCACGCCTGTCCATTTGGCCCAGAGCAGCTTCCAGGTGGAGGCCTTTGGGAGCGTCTTCACTCTGGACCTGGAGCTGAATCATAATCTGCTCTCGTTGGATTATGTGGAACGGCACTTTGACCGGAGCGGAAATCCTTCAGAGTCGCTGGGAGGCGAGCACTGCTATTACCATGGTAAACTGAGGGGAGTACCAGGCTCCTGGGCAGCTCTGTCAACATGCCATGGCCTATGTGGCATGTTTTCAGATGGCCTCCACTCCTATGCCATTGAGCCCATCTTCAACGGGACCAATCAGGCTGATGGCACTCATAAAATCCGTAAAATGCCTGATGTCAGACTTCCAGCCTCCTGTTCAGGTTGTGAACAAGACGGAGAAAATGACACTGGTGACAATGACAGTAGTGAAAATCTGGACCCTCAGAGAAGGCCGAAACATACGGAGGGACTGAAACGTTCCAAAAGAGCGCTCTCGCGGCCCAGGGTGCAGACCGAAACCAAGTACATTGAGCTCATGGTGATTAATGACTTTGAAATGTTCGTTCTTCTCCGGCGCTCCACTGCTCAGACCAGGAACTTTGCCAAAGCGGTGGTGAACATGGCCGATGCGATCTACAAGGAGCAGCTAAACACCCGAATTGTGCTGGTTGCCATGGAGACCTGGACATCTGGGAACCCCATTACAGTGGAGTCGGACCCCCTGATAACTCTTCAGAACTTCATGAAGTACCGCACGGAGAATGTGAAAGAACAGAGCGATGTGGTGCACCTTTTCTCGGGCAGCACGTACCAGAGCAGCCGCAGTGGGACGGCATACTCAGGCGGAGTGTGTTCCCTTGCCAGGGGAGGAGGCATCAATGAGTATGGGAATGTAGGTCCCATGGCCATCACGCTTTGCCAGAGTCTGGGTCAGAATATTGGCATGAAATGGAACAACATCCGCAACTCAGCAGGTGACTGTAAGTGTCCTGACACTTGGCTGGGATGCATCATGGAGGATACTGGCTACTACCTTCCACGGAAATTCTCCCGCTGCAGTGTGGATGAGTACACACAGTTCCTGCTCCAGGGAGGTGGGAGCTGCCTCTTCAACAAGCCCAACAAGCTGCTGGACCCACCTGAATGTGGGAATGGTTTTGTGGAGACTGGAGAGGAATGTGACTGTGGCTCGCAAGTGGAGTGTGCCCGCAGTGGAGGGGCGTGCTGTAAAAAGTGCACACTTACTCATGATGCCATGTGCAGCAATGGACTGTGCTGCCGGGAATGCAGGTATGAGCAGAGGGGAGTGGTGTGCAGAGAGCCGGTGAATGACTGTGACATAGCTGAGACCTGCACAGGAGACTCCAGTCAGTGTCCACATAATGTACATAAGCTGGATGGGTACATGTGTGACAACAGCCAGGGTCGTTGTTATAATGGTCGTTGTCGGACACTAGATGGACAGTGCAGACGTCTCTGGGGCTTCAACGCTGCTGATCGGTTCTGTTATGAGAAGCTGAATTCTGAGGGAACAGAGAAAGGGAACTGTGGCCGCAACCCTGGTGGACAGGGCTGGATGCAGTGCAATAAACCGGACGTATTGTGTGGCTTTCTGTTCTGCTCTAACATGACTGCTAAGCCTAAATTTGGGGACCTTCAGGGTGAGGTGACCAGTCTGACCATCTACCACCAGAACAAGTATCTGGACTGCAGAGGAGGGCATGCAGTTCTAGAGGATGGTTCAGATTTGGGTTATGTGGAGGACGGGACGCCTTGTGGACCCAACATGATGTGCCTGGAGCGCCGCTGTCTTCCCATGTCTTCATTCAACCTCAGCACTTGCCCTGGGTCCAGCTATGGACGCACCTGTTTTGACCACGGAACTTGCAGTAATGAGGTCAAGTGTATATGTGACAGTGACTACACAGGGAAGGACTGCAGCGTGTATGACCCCATCCCTGACCCCACAAATCCTCCTGGCCCAGATAAAAAAGGAACATACGAAGAGGAAGATCTGGAGGGGGATAAAATCGATCTTCCTGTCTGTGTCCATGTTGCTGTGTGTCTGTGCTGTCTTCCTTACACTGTGTCCTTTCCACATCGGAGAAGAACAAGTCTTCCAACCACACCATTCCCTACAAAATATCCTCTGAATAGCTTCCAACCGAGATTCATCTCAATGTCCCTCTGTGCCGTCTAACGGCCTGCAACAGTGGAGCGTCTCCTGTCATATTCCAGCCTGCCATGTGTCTTCAGGCGAACCTCATTGACAGTATGGTCATTTCCAGATATAGGGGAGAGTGGTCCTTTGAAGATGACAGACAGCAAGGACTTGTATGTGTTTTTATGTGTGCGTTTATATATCTGTTCCCTCAATTCCATTGTTGAGTGTCCAGGAAGGGAACATGAAATGGATGGAAGGAGCACCATGTAATGATCTCACAAAGACACAGAGCAGTTTTTTTTATGACCTTTGTTCTTGGCTCTCCTGGTCACTGCTTGTCTGTTGCAGAACCTGGAGACCTTGCTCAGACCGGGTTTTTTGAACATACTTTTGAAAAACGTGACTTGAAACAAGAGAGACAATTTTCATGAGAAAACAGGCTGATTAGGAGCTGTTATATCAAAGAAGTTGGATTTCAGTCGAAGAAAGACTGGTTAGTTCTTCTCTTCCCAAAGAAAAAGGCCAGAAGAAGGAACAGATCAACATTGCAGGAGTGGAACTCCATGGACTAAGCCTGGAACTACAGCGGCGGGTCTTACATCTGCCAGTCTGAGCTCAACAGCTATAACTGTGTGCGCTTGCGTGTGTGTGTGTGTGCGCGTGTGTGTGTGTGTGTGTGAGACAGACTGTGTTTTTGGTTTTGGGATCATTGTTACTCCTGCCAGTCTTAGTGACAACCTTGTACAGGGCAGGGACCAGGTCAGTACTATAGAAAAGCAACATTCCACGTGGTTTTGTGTAGACCTTTTTCTTCCACAATATTTGTCTAAAAAACATTTTGAGAAGACCAAAAGTCCTAGAAAGTATGCCTCAAGGATAACTGTGAGCACATGCATGTGTCTGAGGATGTGAGAAATGATGCACAGGTTGACAGCTCTTAAATGTAGATATGAATGTCATCACTATGTTGTGCTGCAGATTAATGTCAGCGTTAGACCAGCAGCACACTACACGGAAAAAAAGGTTTTCATATGATGCAAACATAAGGAACACTAAAATGTGTTCACTCATATGCACTTGTACATTATGGCATTTGCAAGAGACATGTTAATACATGTGAATACATACGTTAATAATATTCTATGAATTCCATAATGCAAATTGTTTATTTGATAAAAATAAGTAAATATCATCTATCTATCTTATCTATCTATCTATCTAACTAACTATGGGCTTGGTAGCATTTAAGTCTTCTGAATATACAGAACGCACAAGAGGTCCTACCACTCCCACTGATTCTTAATCTGTTTACCACAGTGAGATATTCCGTGTTTTTCGCTTCAGCCTGCGCCCATGCATCATCAGTTCGTAATGTTTGTGGACCTGTCCAGATATCCACCCCATTAGCTGTACTTCACTGCCCTCGTTTTCTACTGTAAATGTGTTGATAGGCCCGTAGCCATGAGTTTAACCCGTAGGCTGCATAGACTTTGTTTAGTCTTTCATCGTAAATGAGATTACTTGGTCATATGGTTCCAGTAAGTGTAGCTTCCAAATAAACATTCATGAGCACCTACCAAGTAGCGGTGTTCCTGCACAGCACCCTACGCAATGCTCACAAGTTCCTCTGTAGTGCCTCGCAGGAAAACGGTCTAATACAGCGTTCTGAAATCTGTATGCAAGTCTCGATACCGGTGCCGAATGTCTGTTAATCCAAGCTACACTTAGAAGTCCAATGTGACCAAATGAAAGGAATAAATGTGAACGCTTGTGGGGATAAAAGCATTATTGGGTTGGGTGCTTGTAAAGAAGAGCTTTTTGCACTAAGGTAGATACACATTAGTCATGTACAGTAGGGACTGGGGATTGGGGCTGGTGAATGCTGGTTTCAAATTAAGAGGACAGAGGCTTTATGAGGAAAAGACCCCCGTCCATGACTTTTTAATGTGACCTTTTTAAACAATGTTGCAGTCATTATGACTGAGTGAATGGACGTGACTGTACGAAACACCCATAAAATAAAAATTTAGACATGAAAAATAA
->XM_008008285.2 PREDICTED: Chlorocebus sabaeus four and a half LIM domains 2 (FHL2), transcript variant X2, mRNA 
-TAAAGAAACATCTGCAGGGTAAGAAGGAAAAAAATCCACCGTGCAAATACATCCCAGGCACATGCCTCCTGAGAAGTGGCCCCCTCCTCCCTCCGCCGCCCCCGGCACCTCCTCGGGCTTCGCCAGCTTCCTGCTCCTGGGAGCAGGCAGAGATCCCGGCGTGGGCAGACCCCTGCCACTGGCGTCCAGGCCCCGTCCGAAACTCACGCCCACGTCGGAGGAGACTCTCGGGATAACCTCGGTGCTCCCAAGACCCGGAGGGCAAGAAGAAAGAGCCCTGGCAAACAAAGGGCACGGGCCGGCAGCGCTGCAGCCCGGGGTGGGGGCACGGTGACCGCTAGGCCTGGGGGCGCCCGCCCCCAGCGCCCCACGCCCGGTGCCTGCGAGCCGAGGCGTGCATCTCCTTATATGGTCAAATGACACGGAGGGGGTTCTCGAGGGCGGGAGCCGCGCAGCGCTCCACTCGGCCGGCAGCGGAGCCGCAGCCACCAGCCGCCCGCGCCCGCCCGCCCCGTCCGGCAGTCTCCGGGCCGCTGCGGCGCGGTGAGTACCTCCAACTCCCTGCGCCCCGGAGGGAGGCCGAGGGGCTTAGCCACCAGGACTCGGAAGAGGGGGCCGAATCCGGTGCGAGACCCGGGGAGAGGGGAGCAGATCCGGAGTTGGGGAGACCGGTTGCTGAAAAGGCAGGTGTCAAAATGACCGAGCGCTTTGACTGCCACCATTGCAACGAATCTCTCTTTGGCAAGAAGTACATCCTGCGAGAGGAGAGCCCATACTGCGTGGCGTGCTTCGAGACCCTCTTTGCCAACACCTGCGAGGAGTGTGGGAAGCCCATCGGCTGTGACTGCAAGGACTTATCCTACAAGGACCGGCACTGGCATGAAGCCTGTTTCCACTGCTCGCAGTGCAGAAACTCACTGGTGGACAAGCCCTTTGCTGCCAAGGAGGACCAGCTGCTCTGTACAGACTGCTATTCCAACGAGTACTCATCCAAGTGCCAGGAATGCAAGAAGACCATCATGCCAGGTACCCGCAAGATGGAGTACAAGGGCAGCAGCTGGCATGAGACCTGCTTCATCTGCCACCGCTGCCAGCAGCCAATTGGAACCAAGAGTTTCATCCCCAAAGACAATCAGAATTTCTGTGTGCCCTGCTATGAGAAACAACATGCCATGCAGTGCGTTCAGTGCAAAAAGCCCATCACCACGGGAGGGGTCACTTACCGGGAGCAGCCCTGGCACAAGGAGTGCTTTGTGTGCACCGCCTGCAGGAAGCAGCTGTCTGGGCAGCGCTTCACGGCTCGCGATGACTTTGCCTACTGCCTGAACTGCTTCTGTGACTTGTATGCCAAGAAGTGTGCTGGGTGTACCAACCCCATCAGCGGACTTGGCGGCACAAAATACATCTCCTTTGAGGAACGGCAGTGGCATAACGACTGCTTTAACTGTAAGAAGTGCTCCCTCTCACTGGTGGGGCGTGGCTTCCTCACAGAGAGGGACGACATCCTGTGCCCCGACTGTGGGAAAGACATCTGAAGTCAACACGGAGAAGTTGCTGCTTGTGATCTCACACACAGATTTTTATGTTTTCTTTCTCACCCAGGCAATCTTGCCTTCTGGTTTCTTCCAGCCACATCGAGACTTTCTTCTAGTGCTTTTCAGTGATACTCACGTTTGCTTCAACCCTTTAGTGCTTTGTGCTAGTTCAGTCCCAGGGAAAGAGAAAACTTGCCCTAGGCCCTAGGTGGGAAGCTGGTTTGAAATTTTTGTAATCAAGTAAGGCACAACCAAATGTAAAAATCCTTTTGAATGATGTCTTTATAAATCTTTCTCTCACTGCCTATTTAAGTGCAATTAATGTATGCCACAAACTTGAAAGTTTTCTAAACTCAGTAAGGTAATGACCAATTGGTATTTACAGCTCTGTAACTTCCTGTTGTGTCAAGTCTAAACCAAGATTATGTGACTTGCAATAAAGTTATTCAGAACTAAA
->XR_006147264.1 PREDICTED: Dipodomys spectabilis small nucleolar RNA SNORA40 (LOC122106945), ncRNA 
-AGCAATTGTATGTGTGCCTTTGTTTCATTTGTAACAAAGCCATATAGACAGGTGCAAACAGCAAATCCTCTACAACCCAGAACTCATTGTTGAATATGAGTTTGGCACATGTAAAAAGAATATG
->XM_034342832.1 PREDICTED: Prunus dulcis ATP-dependent 6-phosphofructokinase 6 (LOC117614132), transcript variant X3, mRNA 
-CCAATTTACTAACAGCCCCTCCTCCCCTGTCCGAGGACCATACACTCCGATTTCGTTTCTGCTTCAATTACTTTCAATCGCAGATTATTCTTCTGGTTTTGTTATGAGTGATCAGAAATCCGCAAAAGCAATGGGGCCTACTGGAAACTTGCAGATGAAGGTCGTGAAAGGCGATTTTGGTTATGTGCTCGAAGACGTGCCTCATCTCTGCGACTACTTGTCCGATCTTCCTACTTATCCCAATCCGTTGCAATTCAATCCGGCTTATTCAGTTGTAAAGCAGTATTTTGTTAATGTGGACGATACTGTTGCTCAAAAGATTGTTGTCCACACGGATAGTCCAAGAGGGACGCATTTTCGGCGAGCAGGACCACGCCAAAAGGTGTATTTTGACTCGGATGAAGTTCATGCTTGTATTGTAACATGTGGTGGTTTGTGCCCTGGACTCAACACGGTGATCAGGGAAATTGTGTGTGGACTTTATCACATGTATGGCGTCAACAAAGTTCTTGGGATAGATGGAGGATACAAGGGTTTCTATGCCCGAAATACCATTGACTTAACACCCAAGGTTGTCAATGACATCCACAAACGTGGTGGTACTATCCTTGGTACATCACGAGGAGGACATGATACCTCAAAGATTGTTGACAGCATTCAGGATCGTGGAATTAATCAGGTTTACATAATTGGAGGTGATGGAACTCAAAAAGGAGCAGCTGTCATCTATGAGGAAATTAGACGGCGCGGCCTCAAAGTTTCCGTTGCAGGAATTCCTAAAACCATAGACAATGACATTCCGGTTATAGACAGATCCTTTGGCTTTGATACTGCAGTTGAGGAGGCTCAACGTGCCATTAATGCAGCTCATGTTGAAGCTGAAAGTATTGAGAATGGTATTGGTGTTGTGAAGCTAATGGGACGCTACAGCGGTTTCATAGCTATGTATGCTACACTTGCCAGCCGAGATGTGGACTGCTGTTTGATTCCGGAGTCCCCCTTCTATCTTGAAGGAAGAGGTGGACTTTTCGAGTACATAGAAAAACGACTCAAAGAAAATGGGCATATGGTTATTGTGATAGCTGAGGGTGCGGGACAGGATCTTCTGTCAGAGAGCTTGCAATCCATGAACCAGCAGGATGCTTCAGGAAACAAGCTACTTAAAGATGTTGGCCTATGGATTTCTCAGAGGATAAAGAATCATTTTGGGAGACAACAAAAGATTTCCATCAATCTCAAGTATATAGCATATCACTGAGAAGCAAAACAAGGTTGTGATTACCGACAGGATGTGGGCACGACTTCTTTCTTCAACTAACCAGCCGAGCTTCTTGAACCCCAAAGACGTCATTGAAGTCCAAG
->KU329545.1 Uncultured bacterium clone OTU_22088 16S ribosomal RNA gene, partial sequence 
-TACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTTTGTAAGTCGGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCGTTCGAAACTGCAAGGCTAGAGTATGGTAGAGGGGGGTAGAATTCCACGTGTAGCAGTGAAATGCGTAGAGATGTGGAGGAATACCAATGGCGAAGGCAGCCCCCTGGACTAATACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGG
->XM_012378055.1 PREDICTED: Linepithema humile serine/threonine-protein phosphatase 4 regulatory subunit 2 (LOC105678582), mRNA 
-TCCCTCCTGTCATATCTCTCATTGTTGCTGTTTTGTGGCCGATAATCAAGACAGTCGAGAGGAAGCAGGGAAGACTTGTCAGAGGAGGTTGTCGGCGGCGGCGGGGAAGATGGAAAATTTAGAGGAGGTGTTGCAAGCGCTCGATGAGTTCCAGAAAATGCGGCCGACGGTAATCCCGCAGGAGTTGGAGGATTATCTGTGCTGGGTCGCAAAGACGGGCGATCCCGTCTACCAGTGGCCGTTGATCAAAACGCTCTTCAGGGAGAAGCTCACGCGCGTAATGACAGATTTTTACGAGAGTTGTCCCTCTCTGGAGCTGGCGACCTGTCCCAACGTGGAGCACTTCAACTACGACACGATGAAGAGCAGCCTTCTGGAGAGATTAGAGTCATTTGCGAATGCGCCCTTCACAGTCCAGCGGATATGTGAATTACTGACGGCGCCGCGCAAAGAGTACAATCGCGTGGATAAATTTATGCGCGCCATCGAGAAAAACATTCTGGTGGTTTCGACACGTGAACCCGGGCCTATCGCCAGACGCGGCGAGACCGGCGACGGTATGGTGAACGGGTCCGTCGAGGAGGACACAGCCTCGATCATGCAGCAGCAACCACCGCCACCGCCTCTCTCATTGTCACCGTCGCCGTCATCGTCGCTATCACCGTCATCGTCGCCGTCGCCATCGTCATCGCCATCGGCATCACCGTCGCCATCACCTTCGCTCTCACCCTCGTCCTCACCTTTGCCCTCACCCTCATCGTCGTCATTACCTTCACTGTCACAGCCACCGTTGCAGTCGTCACCGCAATCACCGTCGCAACTACCACAGACAACGCAACCGGCGCAGACAGGTCAGCCAAACTCTCAGGATGTGGAGATGGAATACTGGGAAAAGGACTGCACCTCAACCGTCACCATCAGTGTGCACACCGTTGTGGAAAACGAAACGCCTCCTCTCTTGCACAGCGGCGTCATACCGGCCGCTGGCTCACCACTGGCTAAAAGCATATTCACCGCGAGTGAGGCGACGCGGGAGAAGCTGGAGCAGGTCGCCTCTAGAACGGAAATCGCGACGTCCAATTATGTCCCCGCTACTTCAGACTTTTCTACTATATCGAATTTAACCTCGCAGGAGTCGGCGCCGACCGCCGTTCCAGTTGTGCAAAGTCTACCGGCTGCTGAAACGGTCTCCGACGATTCGCCTGTCGGCAGCGCCGACGTGGCGGAGGCGATCATGAACGAGGACACGACTTCTCAACCTAATCTAGATTTGGAGAGCGAAGAGATCGAACCGGCCGCAACGGCGACCACCACGACGACAACGATGACGACAACGGCGACAACAACAGCGACATCGTCGACGACGTCGACGTCGGCGGCAACGACGACGGTGACCGTTGTAGCGACGGTGATACCGTTGACGACGGACACCACGCAGAAGCTGCAGGCCGCTTTCCAAGCGAAGCACTTTGAGCCCGACGATAATAAGTGTCTGGAAAAATCCAACGAGAAGACACCGGTCTCGTCAACGGTGGAAGAAGGAATTGAACATTCCATGAAGAATGAAGAAACGACATTGGCAAAATCGAAGCCCGAGTGTGCGGATTCCAACGAGATGTCTCACAATGAAAGTAGGTTAACTGAAAATTTGCTAGAAACGGATATCGAGATGAGATCCGACGCTCTGGCGAATGACGCGGAAAGTGTCAGCGAGGAGAGAACTGCGAATAAACCGGAAGAGGAGGGAACATCGGTCCTCGAAGATGTGGATGAAGAACATTTACGGGTGGAGGAAGATGCGAAAGGAGAAACGGCGGTATTCGTCGAGTCGCAATCCACGGAGAAGGACAGTGCAGTCACGCCTGACGAATGCGCGGTTATTGTATCCAGCGGCGAGGCATTGTACAAAGCGGAGAAGGCCGAGACGCATCCCACGGAAACGTCGACGACAATTTCCTTGAAGGAGAGTTTTACACATGACCAATCTATAAGCCAAAAAGCTGAAATTATAGAAGTAATGGATAAGGTTCTAGAGGCCGTTCCTAAGATAGCGTCTTCTAACGGCAACGACGACGGACAGGAAATACAGGACACTGAATTCAACACGGATAATTTGAAAATGATGGAAATCATCAACGAGAAGGTGAGTCTTACCGAGTCCGCGATGTCGGATCCGATAAGCGTTATAGAGAAACCGAAAGAAGTGACATCCGTGATTGAGAAACTCGAGCTCGTCTCGCCTACTGTCGAAATGACAGAGAGCTCTGATAACGTTGGCTATCAGTCGCCAAAGGACGATAATTCAGCAGGCATCCAGGACGACGGTTTAGCGAATGCGCAAGGTAATAAAATGGCGTGCGTCATTAAAGAGAATCAGTCTTCTGTAATAGAGAGTGTGGCGTGTAGAAGAGAATCGATGGAGTTGATGGAAGTTGACGACGAGGAATCACCGTCGACATTTCAGCAAGACGAACCGATGGAGCAGGAAACAATGGACGATTTGTCGAAGAGTTAATCCCGGCTCATTTAATCGGTTGCATGTCTCTTTCCCTCTGTTTGATATCTATTTTTAAGGGTAGATGTCGCGAAATAAGAGCTAATACGTAAGATATCTTCTTGCGCGTAAGATGCTTGGTAACTGACGAACACAATTAAGCATATAATTTTTAATAGCCGTTAATTATGAATTGGAATTCAAATTATGAGCAAAAATTCTCGATATTGTTTGCTGCTTTATTTATTTCGGATACTTCGCCGTTTAGACTGAGCTCCGGTATTTACTTACAAAGAGATTTATCGAAGTGAATTTTCTAACTCTTGGAAGAAGAAAAAAAGAACACTGCCTATTCCCAAACGATTGTAATACTGAAACTGCTTGTATAGAAATCAGATTTGGTAAACATTTCAATATCGATTTATACAAATACCATAGATATCTGCTTAGAATAAGGTTGTGCCTACAACTATTGTGTATATTGCGTATTGGACAAGTATACCTGATGCATAAATTTTTAAATGATGACGTATAAGCACTACAGATTCGAGTATCTCGCGGTCGAGGTAAACGAAACAGCGTTCGTTCACGATCACAGCCTTATACTAAGTTGCGGTTGAATCTCGAAACGCTTCACGGCTACTTCTGAGAGAACGTTCGAGATTGATCGAAGATATTATTCCTTGCTAAAACTTTCTACAGTACGTAACGGCATTTGGAAATGTGTTAGAACGATGTTACTTCGAGCAGCTGTCTACTAAAACTCCGCTACAGCTAATTCAAAATTGATATTCCAGACGTATCGCTTGAAATCAGTATGTCAATTTCATTTCGTTTCTGTTATTATATCAGTGGGCAAAAATAGTTTCCTTCTTTTTTTACCGAGTGTTTACTGCATATGAAATGTAAAGAAAAAAAGAGACTAGTAACAAACTATATTTTATGAATTACACTAGCTCTTTGTATTTTCGTTCCTCCTATTTTGATATTGTATTTTCAGTAAATGAAGAATGTAGTTAAGTCGCAGATGCGTGCGAATCGGAACAGAAATCTTCAAGTGGCCCAAAACTGATAAAATCGATTCACCGCGGGGGCGCCCAGGATCCCGTTAAGATCGTTTCGAACCGCTTACAGTTTATGTATCGGCACAAGATGTTTTCGAGCGGATTCGGATTCGATGCGGATCCACCGAACCGTTATTAGAAGAATATCGTAGGAATGGGATATTAATTTAAGAATTAATATAGATTAATGATACATGATACACGCGAATGTGGATATCTGAAAAAAAATAGCTGTACATTATTTTATAAGAAAATATATAAAAATGATTGTCAA
->AB050083.1 Mus musculus VH2C mRNA for anti-A/dT antibody, partial cds 
-GGAATTCATGAAGTTCGGGCTAAGCTTGATTTTCCTTGTCCTTATTTTAAAAGGTGTCCAGTGTGATGTGCAGCTGGTGGAGTCTGGGGGAGGCTTAGTGCAGCCTGGAGGGTCCCGGAAACTCTCCTGTGCAGCCTCTGGATTCACTTTCAGTAGCTTTGGAATGCACTGGGTTCGTCAGGCTCCAGAGAAGGGGCTGGAGTGGGTCGCATACATTAGTAGTGGCAGTAGTACCATCTACTATGCAGACACAGTGAAGGGCCGATTCACCATCTCCAGAGACAATCCCAAGAACACCCTGTTCCTGCAAATGACCAGTCTAAGGTCCGAGGACACGGCCATGTATTACTGTGCAAGAAGGGGTACTACGGCCCTTTACTATGCTATGGACTACTGGGGTCAAGGAACCTCAGTCACCGTCTCCTCAGAGAGTCAGTCCTTCCCAAATGTCTTCCCCCTCGTAAGCTTGGG
->XM_010007313.1 PREDICTED: Chaetura pelagica leucine-rich repeat-containing protein 4B-like (LOC104397361), partial mRNA 
-AGCATCCCCTCCTACGCCTTCAACCGCGTCCCCTCCCTGCGCCGCCTGGACCTGGGCGAGCTGAAGCGCCTGGAGTACATCTCGGAGGCGGCTTTCGAGGGCCTGGTCAACCTCAGGTACCTCAACCTGGGCATGTGCAACCTGAAGGAGATCCCCAACCTGACGGCCTTGGTGAGGCTGGAGGAGCTGGAGCTGTCGGGGAACCGCTTGGGCAGGGTCAGGCCCGGCTCCTTCCAGGGCCTGGGCAGCCTGAGGAAGCTGTGGCTGATGCACGCGCGGGTGGCGGCCGTGGAGAGAAACGCCTTCGACGACCTGAAGGCCCTGGAGGAGCTCAACTTGGCCCACAACGAGTTGGCCTCTTTGCCCCACGACCTCTTCGCCCCTTTGCACCGCCTGGAGCGGGTCCACCTGCACCACAACCCCTGGCGCTGCGACTGCGACGTCCTGTGGCTCAGCTGGTGGCTCCGGGAGACCGTGCCCAGTAACACCAGTTGCTGCGCCCGTTGCCACGCGCCCCCGGCTCTGCGGGGTCGGTACCTGGGGGAGCTGGAACCCGGGCACTTCACCTGCTACGCCCCGGTCATCGTGGAACCTCCCGCCGACCTGACCGTCACCGAGGGGCTGGCGGCAGACC
->XM_053147013.1 Fusarium falciforme Sm domain-containing protein (NCS54_00138400), partial mRNA 
-CCAACTCTACCACGCCCTCTATTGATTTCGCCGCCTGCGGAAATGGACTCGGAGCAGGCTCGAGAATACCTATCGGGTATTCTAAACAAGAACCTGCGTGTATACACCACAGATGGTCGCCTATTCTGGGGTGCTCTAAAATGCACCGACCCTGATAGGAACATTGTTCTTGCTCATACATACGAGTACCGGCAACCGTCATCTAGGCAGCGTGCAGAAGCAGCCGAAAAGGCCGGTGGCGAAACAATCAAGCTTGACATGAGCTCCCGCTATCTGGGACTAGTAGTGGTGCCTGGACATCACATCGTCAAGATGGAGGTTGAGGAATTTGCGAGCCAAATGCGGAACCAGATTTGA
->XM_010271001.2 PREDICTED: Nelumbo nucifera uncharacterized hydrolase YugF (LOC104606003), mRNA 
-CACCCATCCAAATACTAATTGCAAACTGCAGCATTTATAATCGTATTCTCTCGTTTGAGCTTGAGGTCTCTCTTTCACTCTCCCCTCTTATTGGATGCCGAAATCTGCGGTTCCTTCTGTTCGTTGGTATGGTTGGGGTCGCCACTCGCCACCTGAGACCTCACCTCTAATAGGTAGGTATTGTTTGGCTACAGCTCCACCGCACCCCTTTCTCATTTCTCCTCTTCTGCTTTGGGAATCCTATAGTTCAATCGGTTCTGCATCGCCCCAGATTGATCATACTTCGGACTCGGAGGCGTATTTCGCTCAGATCTGTATAATTATCGTACCCATTTCATAGCTGGATTGAAATCGAACAACCTCCCAGTTTGTAGTGGTTCCGGTCCCTCTATTCCCTCCCAAACCTTCCATGGTGAAATCCCCAATTATCTGGTCTCCAACCGGAGAGACACCCTCCATTCGCGAGTCCCTTCCAATTTCATCAAGAAATCCGCACAAACAATAATAGTAAGGATAGAAGAACTTGGACCCCTCATCCCTCTCTCTCTCTGTAATTGATCCCTTACTCTCTCTCATGGCTAATAAATGTTTCAGCTTCACCGCATCAAGGGACTGGTGCTACCGTTACGCCTTCGCTAGCACTGGGCTTCGATCGGCCACGACCGACCTCGGCGATGGCACTGTCGTACATTGTTGGGTCCCCAAGACGCACAAACAGAACAAACCAACTCTGCTCCTACTCCATGGATTTGGAGCCAACGCAATGTGGCAATGGGGCGATATCCTCCGCAGCTTCGTCTCCCGCTTCAATATTTACGTCCCCGACCTCCTCTTCTTCGGTGACTCGTTCACCACTCGCCCCGAGCGGTCCGAGTCGTTCCAGGCCCAGTGCATGATGAGAATGATGGCGGCCCACGGGGTGCAAAAGATGATCTTGATTGGGCTAAGCTACGGCGGGTTCGTCGGGTACGGCATGGCGGCGCAGTTCCCGGAGGCGGTGGAGAAGGTGGTGATATGTTGCTCCGGGGTGTGCCTGGAGGAGAAGGATATGTCGGAGGGCTTGTTCATCGTCTCCAACTTGGACGATGTCTTCAGCGTTTTGCTGCCGCAGACGCCGGAGAAGCTTAGAGAGCTCATGCGGTTATCGTTCGTCAAGCCGGCCAAGATCGTTCCTTCTTGCTTCCTTCGCGATTTCATCGACGTTATGTGTACAGAATATGTTGAAGAGAAAAAGGAGTTGATCCATGCTTTACTCAAAGACAGGAAGCTTTCTGATCTTCCCAAAATCTCTCAGCCAACGTTAATAATCTGGGGAGAGCAAGATCAGGTATTCCCATTGGTGTTGGGACACAGATTGAAAAGTTATCTTGGGGAGAATGCTCAGCTAGTAGTGATAAAGAATGCGGGGCATGCTGTCAACTTTGAGAAGCCCAAGGAGATATACAAGCACTTGAAACCCTTCCTTTTTGATTCTCCTCCTCCTTCTCCTCCATCACAGCATCCTCCTTCAAAGTTTCTTGAAAACAAAGTAGATTGATGAACTGGTTTAATCTGATACGTACTACATTGTTAAACTAATATCATGGCTATATGGAAGCTGCTGGTGGCCTGGTGGGACTCTTAGAAAAGGCAGGCAGAGGAAGGTTTAGTCCAAATGTGCAACAAATTAATTAAGGATCCATATTGGTGATGATGAGTATGTATAATTGATTGATAACATAAATGCATATTGTACAATAGATCGATTGATTCATTGATTGA
->KP859945.1 Uncultured bacterium clone OTU_340 16S ribosomal RNA gene, partial sequence 
-CACGTAGGGGGCGAGCGTTGTCCGGAATCACTGGGCGTAAAGGGCGTGTAGGCGGCTAAGTAAGTCAGGTGTGAAATCCCTCGGCTCAACCGAGGAATAGCACATGAAACTATCTAGCTTGAGTGCAGGAGAGGGGAGCGGAATTCCCGGTGTAGCGGTGAAATGCGTAGATATCGGGAAGAACACCGGTGGCGAAGGCGGCTCTCTGGACTGTAACTGACGCTGAGGCGCGAAAGCTGGGGTAGCGAACGGGATTAGATACCCCGGTAGTCCCAGCCGTAAACTATGGGTACTAGGTGTTGGCAGTTAACCTGTCAGTGCCGCAGCAAACGCATTAAGTATCCCGCCTGGGGAGTACGGCCGCAAGGCTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCAGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCGGGGATTGACATCTTGTCGAACTTGGTAGAGATACCGAGGTGCCTTCGGGAACGTCAAGACAGGTGGTGCATGGTT
->XM_014748744.1 PREDICTED: Polistes canadensis E3 SUMO-protein ligase NSE2-like (LOC106786730), transcript variant X4, mRNA 
-TTTAATAACAAAAAACAAATAAAAATGACTCAATCAAAAGAAGTAGCCGAAGAATTGTTCGAATGTTATACAAAAACTGCTGAGAATATAGTTATATACTTTCAAGATAAAGAAAAGATAATAGCTGATTTGAAAGATGTTGTACAAAAGAACTGTGAAATAGATACTAAATTAAGTATGATTCAAGAGATAAAGGATGAAATATTAGAGAAATATGGTGATAAGAAAATAACGGAAAAAAATATACCTAAAATTATTAAGGATTATGAGAAATCTATATCTACAATGAATGTTGATGTATCTACAAATAAAAGATTACTGGAATTTAATAGACAATTGGAAGCATTATTGAACGATGCGAACAAAAATCAGAATATTGAGGAAAGTAACAGTGACGAAGAATTACAATTACAAACAGATTCTATGAATGTGATAGATCCTATTTCAAAAATGAGGATAAAAGATCCGATTAAAAATATTGCATGTGGACATACTTATGATCGTCAAAATATTATGGCATTGTTAAAAGTAAATAAAAAAACAAGGTGTCCCATGGTTGGATGCAAGAATACAAAATACATAGAAATCACAAATCTTCAAACGGATGTTGCAATGAAAGTATTTCTTCAAAGAAATCCTGTTTAATATTGTGACATTAAATGATTTTGTTCAGACATGCTAAAAATGTGATTATTTACTAATGTAAACAAATCACAAAATATTTCTATATATATTTAGATTTATATATATTATATAAATACAATTAGTATACCTACACAGAGATAAAG
->XM_023661946.1 PREDICTED: Cucurbita pepo subsp. pepo vacuolar protein sorting-associated protein 54, chloroplastic-like (LOC111781387), mRNA 
-GAGGCGGAGGTGGAGGTGGATTCCACTTCATAGAGGCGAGAGGCTTGAGGCTTGAGGCGAGAGGCTTGAGGCTTGAGGCGAGGCGCGCACGGAATTCTTGAACGAGATCTACCGCGGCACCGGACTTGCATTGCCAACTCTTATTTTCTCTCTCTTTCCTTCACCCAGCGGCGTCCACAACCTCTGTTTTCTTCATCATTCCTTTTCCATCTGGTGATTGAGATCCATCCGAAGCACTTCTTCATCTCGATCTCTCTCGCGATTGGAATTCATCTACTGAATGCCATCTTTGGAACCCGCCATTAGTTCATGATTCTAAGACTTTGAGCATGGACTCCCAGCCTTCCCAATCGGGAAGGTCCCCGACCGAGTATTCCAGCCTTCTCAGTAGAGAAACGACTCTTGGTCGAACTACTTCATCCTCCTCGCCTAAATCCAACCCCGATGCCAGCAGCCAGAGCTTGTCTTCAATTCTCAACAACCCTCACGCTGGCAAGTCCGATGCGTCCTGGGTTGGCTGGTGGTCCTCTTCCTCCACCGTCACCCCACCTGAGTTTATTCCCCTCACATCCTCCACAGCCTCATCGGAAGTTACTCGATTCGATTTTAACAACTACACGGCCTTGATCTCCGATTCTTATAACCGATTCGAGGACATACGAAACCATTCCAGCAAAGAGAACGGTGGCTTGGATAGCATTGGGGGCCAGGGGGAAGCCCTTGTGGCATGTTTGAGAGAGGTTCCGGCGCTTTACTTTAAGGAAGATTTCGCATTGGAGGACGGGGCGACATTCCGTGCAGCGTGCCCCTTCTTGAATGTATCGCAGAATTTAGTGCTGCAAGAGAAGCTTTCGCATTATTTAGATGTCGTGGAGTTGCATTTGGTCAAGGAAATTTCACTGCGTTCCAATTCTTTCTTCGAGGCTCAGGGGCAGCTACAAGACTTAAATGTGAAGATTGTGGAGGGATGTAGCCGGCTACGGCAATTAAAGGAGACCATACGGCTCTTGGATGTTGATTTAGTGGACTCTGCCAGGCAAATTCAGGAGCAGAATGCGACCAGGAACAATTTGTTGGCTCTTCAGCAGAAATTGAAGCTTATTTTATACGTTAATCAGGCCATTTCAGCTCTTAAATTGCTTGTAGCATCGGCAGATTGTGCTGGAGCCTTGGATGTGACCGATGATTTATTACATCTTCTGGAGGGTGATGAACTTGCCGGTCTACATTGCTTTCGCCACCTCCGTGATCATGTGGCAGCATCACTCGAATCCATAACCAGCATTCTTTCAGCAGAATTTATGCGTGCCTCAATTCATGATGCTGGAGATGTTGATCTCGTAATTATATCTGAAACAAAAGCAAGCATTTCAAATTTAATGAATGGAAAGGATGAAGTCAAGTTAACATGTATCTTGGATGAGGAAGAAACCTCCAACTTCCGTGATCGTCTTCTTCCTATTATCATTGGATTGCTTAGGACCGCCAAGCTTCCCTCTGTGTTGAGGTTATATCGTGATGCAGTTACAGTTGATATGAAAACTGCTATTAAGAATGCAGTGGCAGAATTACTTCCCGTTCTTCTAGTCAGACCTCTAGACTCAGATTTTGCACCGGGAGAGAGAACGAAGGATACAGATGGTGGAGCATCACTCGCAAGCAAGCTGAGGGGCCTGTCATCTGAAGGTTTTGTTCAACTTTTAAATGCCATTTTCAAGATTGTACAGGTACATTTGGTGCGTGCTGCAGAAGTGAAAAAGTCTATCGAATGGATTATGTGCAACCTTGATGGCCATTATGCTGCGGATTCAGTTGCTGCTGCAATTGCTACAGGTGCTGCAGCTTCTGGTACAGCTCAAGATAGTGATAACCAAGGTGGTTTGCCTCTTCCTCATGTACCTCAGGGTGCTGCCAAGGTTACTTCCTTACAGGGAAAAGCAAATGATGCGGCAAACCCTTCAAACATGTCTAGAAATTTCAGGGCTGATGTACTGCGAGAAAATACGGAAGCTGTTTTTGCAGCTTGTGATGCTGCTCATGGAAGATGGGCTAAACTCCTTGGTGTTCGCATTCTAGTTCACCCAAAGCTGAGGTTGCAGGAGTTTTTAAGCATATACAACATTACACAAGATTTTATAATGGCCACTGAAAAGATTGGTGGAAGGTTGGGATATAGCATTCGTGGAACTTTGCAGTCCCAGGCCAAAGCTTTCGTTGATTTTCAGCATGAATTTCGTATGACAAAAATAAAAGCAGTGCTTGATGTTGAAACATGGGTTGAAGTGGATGTTCCCGATGAATTTCAAACCATAGCTGAATCACTATGTTTTCATGAGCTGCTTTCTGCAAAACTTGATGATTCTCAGGGTAATATGGATCAAAGCTACAGTGATGTAGCTACAAATAATGAAGATGCACGCATTATAGGTGGTGTCAATGCTCAACAGCACTCTGAACAGGTTGATTCAAGTGACATTTCTGGGAGGAATACTGAACATGTGAAGCCTACTCCTGCAGATACAATTGAAAACAGTAAAGCTGATGTTGCAATTCCTGCGACACAAAATAACAATACTAATGTGAAGGAACGTGGAAAATCAAGTTCTCTGACTTTGCAATACAAAGGCGTTGGTTATCACATGGTTAACTGTGGGTTGATCTTGCTCAAGATGTTGTCTGAGTACGTTGACATGAATGATTCTTTGCCAGCACTATCTTCTGAAATCGTTCATCGTGTTGTGGAAATTCTCAAGTTTTTCAATACAAGGACTTGTCAACTTGTTCTTGGAGCTGGTGCTATGCAGGTGTCTGGTTTGAAGTCCATCACATCCAAACACTTGGCTCTTGCCAGTCAAGTTATCAGTTTCACCTTCGCCATTATTCCTGAAATGAGAAGAATCCTTTTTCTCAAGGTACCTGAGGCACGAAAGACACTATTGCTCTCAGAGATTGATCGAGTGGCTCAAGATTACAAAGTTCACCGAGATGAAATTCATACTAAGCTGGTCCAGATAATGAGGGAAAGGTTGTTAGTACATCTACGTGGCCTGCCGCAAATTGTTGAAAGTTGGAATAGACTAGAGGATGCTGACCCTCAGCCCAGTCAGTTTGCTCGATCCCTTACCAAGGAAGTTGGGTACCTTCAGCGTGTTTTATCTCGAACCTTACATGAGGCTGATGTTAAGGCAATATTTAGGCAAGTGGTCAAAATCTTCCATTTACAAATTTCTGAGGCATTTTCACGGTTAGACATAAGCACCCCTCAAGCAAAGGACAGGTTGCTTCGGGATGTTAAGCACATTCTTGGCTGCATAAGATCTTTGCCTTGTGATGATTCGAGTAAACCTGACATCCCAAACTGGGGGCAACTTGATGAATTCTTGGACCAGAGACTCGGATCTGAAGCTGGATAATGATGTGAATGTGTATTTTCCATTGTTTGCTTTTTTGATGAAGGGGGTCATATTTGAGGAGTAAATAACAGGATATCAGAAGTCAATTTTCAACCTATGTCATCTCCCTTGTACACCTAAAAATCAAGGTTTTGCGATTCTCATGGACAGGCGTGAAGTACAGTTTGGGATTCAGATATTTCAACGAAGTTGGGCCTTGCCCTTTTTGCTGAAACACATAACATATTATATGTTGTATTGGCTAGGCCAACACTTTTTGCTGCCCTAATTGTAGTTATGTTTAGAGAAAGAACAGATCAATTTGTTTACTCGAATAGATTTTAGTTCCTTGCTTTCTTTTCTTTCCCCCCCTTCAATTTTTATGGGCTTTCGTACAGTTACGCATGTTTGTACTTTGTAGAGCTAAATTTGTCATTATTGCCTATAAATAATTTTGCTTA
->XR_005523613.1 PREDICTED: Hibiscus syriacus uncharacterized LOC120200931 (LOC120200931), ncRNA 
-AAGTAAAATCAAAAGATTCAAACATTGGAATATACACTTGATCAAAAACACACTAACCCTTTTTTACAAATCTTTCTTCTTTTCATCATCTGACCCTTACCTCTTTGTCCCAGTGTCTCCTACGGTGAAACTTCGGTATCTGGGTTTTACCTTTTTTCTTTTACCAGAGATAAAATTTCACTGCTTTGGATCCGCCCCATACCCCTACTTTTTACCCTACCTTCCTTTCACCCTTTAAATTGCTAGACGATCCAAGCTCGCCTAAAGAAAGAAACAAGTGAAAGAAGAAACAAAATTTTCTAACTCTTTGAAAAGTTGGGTCAATCGCCAGTACATTCCAACACTTGTTTCTCTCTGGCAGTATGGATGATTATTACAGAAGGAACCATGTTCCAGCTTTTGGTAGCTGGGATTGGAACAATGACCTTCCTTTTACTCAGTGTTTGAATCGGCTCGGCAAACCGGATTCCTTCGTTATAGCTACGCCGAGGATCGTGATTTATACGTCGCTGGCGATCTTTATGAGAACGATGTCGTCACTCCCGCCGTGATTGTCGTTCCTCGTAAAAGGACAAAAGTAAGACAGTCGCATGTTAAAGACGGCAAAAAGCAAGAATGGGAGGTCAGTGACGTGAAACAACCGGCATCGGCAGCAAGCCCCATTCCCGTGTCCAAGCCAACTCCAAAACCCGTTGATGAAGACCTTTACAAAATCTCGCCTGACCTACTTTACACTAAAACCAAAAAGAAAAAAAGGTTGAGCTTGTTCTCATGCTGTTTGGTGCCAAGTTGATCATCTTGGAGGATTACGTAAATATAGTTCTTTTGATCCGTCCCTTCCCCTTGGTGTACTCAAGGGT
->XM_003231613.2 Trichophyton rubrum CBS 118892 uncharacterized protein (TERG_07960), partial mRNA 
-ATGGCACCATACACCAAGGTACAGGAGGCGAAAAACAGCAACGGTCAGGCAACAGGGCCTCCTGGCCCTCCACCAGCCGCAGTCCCTCCTCCGCCTGCTGATCTACCACCAGGGGCCGTTCAGCAAAAGCCTGAAGCCGCTGTCGTCCCGGCTATTGTGGTCCGGGACTGGACGAACGAGGACAACGCCCAGTTGAAGAAGTTGAAGGAGGACAACATCAGCTGGCGGAAAATCGCAGAGACGATGAACTGGCCGGTCCACGAGCTAAGGGAACGATGGCGGGCCATCAAGCCTGAGCTGCCTAAGAAGTCGCAGCAAGAGCCAGAAAAGGTCAAGCAAGACGGCGTTCAGGAGAAGCAAGTCGTGTTTATGGAGTCAGTCAAGGAGAAAAAGAGTAAAGAAATCCCAAAGGTGGTATATGCAGACGAGAGTCTGAGTACAGAGGAGGCCGTCCTGCTCAGCAAGCTTGCGGACAAGTACGACAAGGAGATGTGGTTACGCATCTGCTCCAAGTTCTTTGACAAGACCGGCAAGCGACTTGATCCAGACGAGGCCAGACGGCACATCCGTCCGTCATAA
->X84340.1 H.sapiens mRNA for Ig light chain, variable region (ID:CLL001VL) 
-CAGTCTGTGCTGACGCAGCCGCCCTCAGTGTCTGGGGCCGCAGGGCAGGGGGTCACCATCTCCTGCACTGGGAGCAACTCCAACGTCGGGGCAGGTTATGATGTGCACTGGTACCAGCAGCTTCCAGGAAAAGCCCCCAAACTCGTCATCCATGGTAATAGCAATCGGCCCTCAGGGGTCCCTGGCCGATTCTCTGGCTCCAAGTCTGGCGCCTCAGCCTCCCTGGCCATCACTGGACTCCAGTCTGAGGATGAGGCTGATTATTACTGCCAGACCTATGACAGCAGGCTGAATATTTGCGTGTTCGGCGGGGGGACCAGGCTGACCGTCGTAG
->XM_033723222.1 Mytilinidion resinicola uncharacterized protein (BDZ99DRAFT_493278), mRNA 
-CGCGTTAGTCTGTCCACGTCGTCACTCGAAATCTCTTGCTAGGCTTGCTTGTTCGCACACTTAAGCTGCTCCTCTTCAGCGCTCTCGCAGCACCCCGAAACGCGTCAAGATGCAGCCCCTGGAACGAAGTGACATAGACCCGCATGCCGAAAGGACGCTTCATGCTCAGGGTAGAGGAGAGAAAAGAAAGCTTCTAGTGCTATCCGAAGACACCCTTGAAAGACATAACAAGTGCTATCGAAAGACGAATGAAGCCTTCGGAAAGTCCGCCATTCGCCAGGAGGGGGCGCTGGCTTACGAAGAGGAAATGTATCATCTGCACTACGGCAAAAAAGTCGTAGCATTGCACGACGGATTCGTGCCTGGGCCCGACAAGAGAAGCATGCCGCCGCCGTCGCCGCCATCCGCCAATAACATGAACATATACAGCGCAACGCCCTCGTCCGAGACTCCGATGCGTCGCTTCATGTTTCCAAGCACGGCTCATGACGCCCAGCCATGGCTGGCACGAGGGATGCTTGAAGACAGCGGAATAGGCTGCGGCGACCTAGACAGCCTCGAGTTGAGAAGGCTGGCAGGGCAGGTCATAGTTCCTGACGAGAATGGAGATGAGACAGAGGGCAGCCTGTGTCCTTCATCGCCCACTCTGTCGAATGCGCAAGCGATGCGGGTGGTGAAAGAGAAGCAGGAAAGGGGATCTAAAGAGAACCCGCGAGTCCGAAAATTGATAAAGAGACATCGGGCGCATACTTCTAGAGATGCGCAGGATTCAGGGAATACCCCCGAGTAGAACAGGCTAGAGGCGGTACACCACACCACCTGCAGGCGGCTCTATGGGCTCAAGCTGCCGGCAAATGGTGTCGAGACGAGGAAAGATGTATGTACCTACAGATGCGGTGGATATCAGAAGTTTCGGGTTTTCTAGTTCGTCTTGCTAGTATGGATAGGCAGCACAGGCAGTCAGGCATGGTATACGATTAAATGAGAGACTCCAAAACTGGTGGGAGCACGACGCTTTTGAAGACTTCTAAAGCCACAACAAAGACTGCAC
->XM_042379977.1 PREDICTED: Homarus americanus putative transcription factor capicua (LOC121875420), transcript variant X2, mRNA 
-CTGGCTGCCATAACTCTTCCCATGCAGCAGTTGTCTCCATCTCAACAGCTTCAACAACAACAGCAACAACAAGTACAACAACAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAGCAACAGAAAGTTAAAGCCCAGGTTGCTAGTATACCTGTAGCAGTGCCAGGAGGAAGACCTTTAGACGACGAAGAATTAGACGACAAACCAAAGTTTATTTTGGCTCCTACGCCGGCACAGCTCGGCAAGGCCCCTAGACAAAAGCGACTCAACTCTTCAGGGCAAATATCATCTATAGGAGACACTGCACCACAGTTATCTCCGGACGTAAAGATGGCTCCTCCGCACCACCCCAGCGGAGACAGTAAGGTATCTCCGGTGTTGAGTAATGCTTCAGAGGGCGACTCATCAGTACAGACGACCACCCAGCAGATGGTCTCTGTTCCACCATCACCTAGTGAGAAGAAGAGTTTCTTTAAGAAAAATATTGAGGATGGCATGGACAAGGTCCTTGAAGAGGTGAATTTCGAGCAGAAGTTCGGAGCGCTGCCCGAGTTTAACCCTGACGAGGTCCAGTCCCCCAGTGTCAACGCTAGCACTGGGCCCTCCGTACCTTCCTCCCCGCGGACCTTTATTACGTCTTACAGGAAAAAACGTAAACATTCCAGTGGTGAAGAGTCAGGCTCAGATACTCCCATGAGTGTCACCCCTCACCAGACACCCTCACTGACACCCTCCTCCACACTGCAAGGATCCAAGTTCTTTCCTCCTGATTTCAACCCAGAGACTTTCAAGGTTGGTGAGTCTCGGGCGGACAAGTGCGAGATAGAGTCACCTGCTGCAGGAGGCCGTTCACCCAAGACTCCCAGAGATGCGGACAAGAGCCATTCATCCTTGAGGCACATCCTGGATCAGAGGCGCACCCTTGTGATGCAGCTCTTTACTGAATATGGCTGGTTCCCATCTGCCCAAGCCGTCGCAGCATTCCAGTCTCGATACTCGGACATCTTCCCTACCAAGAACTGTCTGATACTCAAGATAAGAGAAGTACGTCAGAAGGTCCACCAGAACACACCCAACACACCTGGTGTACCGAGCAGTCCTAACCCGGCCACACACACTGGGTCCTCCTTACAACACCCCCACAACAACCACCACAAATTTCTGGTTAACCAAAAAGAATGTCGTGGCCGAACCATCGTACACGATCATCTCTCACTGCCGCTGTGTCAACGTCAAATCAAGCCACCACTTCCCTCCCAGTCGGCACATAATGCCACATCTCGGCTAGATTATTAATTTTACTGTGTTGTTTTTTTATTTTTATTTATATTTTAACCAATGGCTACCCAGCATTACTACATAATAATAACATTGGCATTTTACTACTGTTAAGAGTTGAATGTGTACTTTGTATAAATTAGCGACAGTTA
->XM_004341098.1 Acanthamoeba castellanii str. Neff uncharacterized protein (ACA1_236710), partial mRNA 
-ATGCCGCTGCCGCCGCCGGCCGTGGTTGCTGGGATTGAGGGCGCCGACGCGGCTCGCGGGACGCCGCCGTGGGGACCGCGCTCGATAACCGTTCCAGCCTTGACCGTCTCGCGCGGGTGCGGCTCCGACGTCGTCGTCGACCCCGGGGCGTCGCCGCCGCTCTCCTTCCTGCGCTTGCGCTCCTCCTCGATGAGGCGCATCTCCTCTTCCTTCTTGCGCGCCGCCTCGCTGTCGGCCCGCTCCTTCTCGCGCTCCTCCTCCTCGATCTTCTTCTTCCAGTCCTCCTCAGTGATCTTCACGCTGCGACGGTTGGCCAGCTTCTGCTGCTTCTCGCGCTCCTCCTTCTCGCGCTTCTCCTTCTCCTCCTGCTCGACCTTCTTGCGCCACTCCTCCTCGACGTTCTTGCGTGGCGTCTTGGCCAGCGCCTCCTCGCGCTCGATCTCCTTCTGGATCTTGTCGTCCTTGGGCTCCTCGCCGCTCAGGAACGCGCTCTCCTGCTTGCGCTCCTTGACGGCCTCGGCGATGCGGCGCATCTCCTCTTCCTTCTCGCGCGCCTTGTCGCTCTCCCTCTTCTCGCGCTCCTCCTCCTCGATCTTCTTCTTCCAGTCCTCCTCAGTGATCTTCACGCTGCGACGGTTGGCCAGCTTCTGCTGCTTCTCGCGCTCCTCCTTTTCGCGCTTCTCCTTTTCCTCCTGCTCGACCTTCTTCTTCCACTCCTCTTCAACGTTCTTGCGTGGCGTCTTGGGGAGGGCCTCCTCGCGCTCGACCTCCTTCTGGTGCCTGTCGTCCTTGGGCTCCTCGCCGCTCAGGAACGCGCTCTCCTGCTTGCGCTCCTTGACTGCTTCGGCGATGCGGCGCATCTCCTCTTCCTTCTCGCGCGCCTTGTCGCTCTCCTTCTTCTCGCGCTCCTCCTCCTCGATCTTCTTCTTCCAGTCCTCCTCAGTGATCTTCACGCTGCGACGGTTGGCCAGCTTCTGCTGCTTCTCGCGCTCCTCCTTCTCGCGCTTCTCCTTCTCCTCCTGCTCGACCTTCTTCTTCCACTCCTCTTCAACGTTCTTGCGCGGCGTCTTGGGGAGAGCCTCCTCGCGCTCGACCTCCTTCTGGTGCCTGTCGGCGCTGTCGTCGTCGGGACCCTTGAGGAACGCGCTCTCCTGCTTGCGCTCCTTGACGGCCTCGGCGATGCGGCGCATCTCCTCCTCCTTCTCGCGCGCCTCCTCGGCCCTGTCGCGCTCCTTGACCTCGCCCGTGAACATGGAGGCGATGCGACCCACCTTGGCGTTGCGCGCCAGCTGCTGTCGCTCCTCCTCCTTCTTGCGGCGGATCTCCTCCTCCTTGGCCTTCGATCCGCCCTCGTCGTCGCCCGACCCGATCTTGTTGCGCCACGCCTCCTCCTTCTCCTTCTGCGTCTTGGGCTT
->NM_001302118.2 Gallus gallus CDC28 protein kinase regulatory subunit 2 (CKS2), mRNA 
-AGTCGTTAGGGGGTTTGCGGGCAGATAGTATTGTGCCTAGAGTTCCGCCACTTTTTGCCATGGCTCACAAGGATATCTACTACTCCGATAAGTACTTTGATGAGCAATACGAGTACCGGCATGTAATGCTACCAAGAGAACTCTTGAAACGAATGCCAAAAGCTCATCTTCTGTCTGAAGAGGAATGGAGAAGCCTTGGTGTTCAGCAAAGTCTTGGATGGGTTCATTATATGATCCATGAACCAGAGCCACACATTCTTCTCTTTAGAAGACCTCTTCCAAAAGATGATCAGAAATGAACTACTGTCTAGAAATATTCTTAATCTTCTGGAACTTTGTGTATGCATGTATATATGTTGGTAGTATTCAGTGAATACTTTATGTACAAAACATACAACTGTACCTGTGCATGAGCTGTATTATTCACAGCAACAAAGCTCAGTCAAATGCAATTTCTAGTAGGCTGCTATTCTTTCAAAGAGAAGTGGAACTTCTAATAGTTCCTCTTAGTCTGAAATGAGTTCTCTAATAAAGTTTACTATTGTG
->XM_032261620.1 PREDICTED: Sapajus apella otolin 1 (OTOL1), transcript variant X1, mRNA 
-GGTCTTTTCATCTATTCTGGGTATACTGATGATCTCTTAGGAGTTAGACAGAAGTAAGAGAAGTGTATTGTTTTATAATCTAGTAATAGCCTCTGGTTGCAGATCTTTCCTAGGAAATTTGAAAATGTTTTTACTCCTTTATGAAATAAAAATTTTAGTTTTATTATATAAGGCTTTGTAGTTTGGGTTTATCTGAAGTAAGCCACCCATTCACTGGCATTGAGAAAGACTGTGGAATGGTTTTTGTGGTCACATGTCTTTTGAATCCAGGTTCGCTGGGCATATATCCTGGCTCTGCTAAACTGTATACATGACCTTGGGAACTTCCTTTACATTTCTTGGTCAGTTTCTTCATTTGTAAAATCAGTCTGGCAATAATGACTACTTCTTAGCTGTTTAAAGCATTTAGTGAGTTATTGAATGTTAAGTGCCTGACTCTTGCTTAGGACTCAATAAATGTTAGATATTACTATTAGTGACTACTGTACAATGAAATAAGATTACCTACAACTGTGAAGATAACTAATTAAAACAATAATCAAGACTGGAAAACATATATTTATTGTGTACTATATAAAAACATTCCATCAAGATAGAATAAAGCTATGAAGTCAGACAGATACAGGCTTGAAAATTTGGTATGTGTCATACTGCAGGTAACTTAGCTGTTCCTGAGCCTTGGTTTTATCTTCAAAATGGAGACAATTCTGCTTTGGAGGACTGTTGTGAGCAGAAACAAGAACATTTGGAAGAGGCTGGTGTACTCAATACAAATGGCTATTATACTTTTTATTGCTACTTGCTTTTCTTGAACTAAATTTTAAATAGCAACTCCTCTTTTTTATGGAAATCTAGGGAGTCTGATTTAGAGGAAGTGAGTACATGCTGTAGAATGGCCCATATGCCATTTTGCTATTAGAATATGAGTCATTATTTCTAAACTTAGTATTGCTTTATTTGTATGTTCCTTGCTTTTCTCAGAATCCCTAAGTCAGATCCAACCATAAACTTTGGATCATAAAAGAAAGCAACTTCAATTAAGTGGATTTTTGGAGTCACTGCAAGTCACTCATATGAGGCTGTCTGACCAAGCAGTGATGTAAAGAGGGCTAATAGTATTTCAGTGAGCAGCTCTGGCATTTTATGTTTGTACAGAGTGCTTCTACTTAACGAAAGTTTTAAATTTGTATTATCTTTTGTATTGAGGTACAATTTACATATGTTGAAATGTGTAGATCTTAATTGTGCATTCCCTCAGTCCTGACAGATACATACACTTCTATTAAGATACAGAATATTTCCAGAAAGTGTCCTCGTGTCCCTTCTCAGTCAATCCTTTCTCTTTTCCCATGCAACCACTATTCTGATTCCTATTGCCTTTGGTCAGCTTTTCTTGCTGTGGAACTTCACATAAATGGAATCCTGCAGCCTTTTGTGTCTGTACTTTTTTCCTTACCATAATGCTTTTGAGATTCAGCTGTATTATTATATGCATCAGTATAGTTTATTGTTGTTGGTGAGTAGTATTCCATTGTATGGATATACCAAAGTTTGTTTATCCATTTTCCGATTAAGAGACATTTGGGAAATTTCTGTTACTTCTTTTGATCATTATTGTAATGTTGTTGGAAGGTCAGAAGATTCTACTATCTTATTCTCTAGATTAGGAAGCTGGGATTCAGAGAAGTGAGACAACTCAAGGTAAATGGGGAACTCGAGAAGAGAACCTGATTATCTGGGCCCAGATCCTCTGCTTCCTTTACTTTCTATTTTCTGAGCCCAGGTTATTTTTGGCCCTGACTAGGAGTTCTGCCCTGTCTGACACCAGGATTTGACCTGACCTGTCTTATCTTTGATGGAGAAAGACCTAGAATATCAAAATTTAGGAATGTAGCCCTAATCTGGGCTAACCCTTGCCTAAGCCTTAGTTTCTTTCAGGTGCAGTGAATAGACTTCTTAGGCTGGCTCAAAAGTTGAGCAAGTAGAGGATCTGGATTACACCGGTTTAGATTACAGAATGCCTGAAGATATTCTAGGAGAGCTTTGTCTTTCATAGTGGCAAAGGGGAAATAGGATGAACATGGAATAAGATAAGCGTCTCTTAAATCCTAGCTCTGCCACCTATTAGTTGTGTGAGGTTGGGTAACTCAACTCTCTGGGTCTCTTTCTCCGTCTGTAGAAGAGGTAGTACAATGCTTCCCTCTCAAGTCTCGGCAAGGAAGTTCCTGACACAACCTGTCCTTTCTGTGCTCGATCAAGGTTGGAATTAAGAGAGCATTATAATATGATATTGATATTGCTGTGGGATTTTCATTGTATGGAAGAATGAATTCTTCCCTTTATCTCAGAAGACAATTCATTATTTATAGAATCTGAATAAAAATAGAAAAGTTAATTTGTCAGTAAAGTCCTCATAAAAATAAAGCAAGAGAGGGGCAAAGAGGAATGTGTTTACTTTAAGACAGCTGGAAAAATGAATATAGGTAAATAGGTCCTTTGAAGACACTCTCTTCCTTCTCAGGAAAAAGGCAAACATATTTAGAAGGTTAATCCTTGTTCAGGATGCTGATTAGGCTGTGTGGTTAAATAAGGTCTGTAGGAGAACCAAAAGGAAAAAGGATCTTAAGGGAACCCCATTCCTGCCCTATTATGGATTTAATGAGGTCTCTGGGTCACAGTTTCTCCATCTGTAATCCCTAAATAGCACTTTTTAATCACATATCTCAGGATTTGATGTGAAATTTGATGTGTTCAATTTTCTCATAATTTATATAGTTGCAAAAATTTTGCATAAAAAGAATAGTATTTATGTGTATTTTATGTAATTTAAGGCAAAGTATGCTGTCCAAGAAAATCTTACAGTTTATGAGAAGATTGACATGTGAATGACTTAACAGCAGAATACATTAAATGCTTGTCATAACAAAAATTGGCAGGAGTCTTAGAAGAACCTAGAGTTAGATGATTAGCTTGGTTCATAAAAGCTTCTAAAGGAAATTTCAAAGACTTAATGACATCACTGAACTTTTCCAACCAATATTGAGAGAAGCTGGTATGAAATGATTCAAGGAGTATTTACTGCTCTGCAAAACAGCTTTGCCTTTAATGTTTCCCAAGAAAAGGACATACTTGTAAAGACTTAATGCTTGTCCTAGAGAGGAAAAACAATTTCAACAGTCAGGACATCAGAGTGGTGGAAAGTATTCATGCAGGAAACTGAATGATGTACTTTATTTGTGAATTTTCATAATTAGCATTGAAACACCGCTACTTTGCTGGCTCAGCTTTTTAATGTATCAGATCCTTTGTGTGTAGGAAGAAAGAAGAATAAATGTGTCTCTGAATGTGGGGTGCTCTCTTTTAATAAAGAAACTTGAGAGAAAAGAGACGACAATAGGCAAATATGAAATAAGTTAAAAGAAGTAGGCAGAAAATAGAGAAAACTGCATCTCATGCAGTTGACGTTTATGTGGCAATTGCTTGGTTTGGACTTTTTGTCGGAGAACTTTTTTTTCAGAATTTATTTTGTGTATCACTAGTAAGTGTTGCATAATTTCCATATTTATTTATACTATGGGTCTGTCTCTCCTTCCAGACATAAAGGACACTTTGAATTTCAGGTGATAATGGAGCATACAATCACAGCAATCATATGATGAAAGTATGATTATTATTTTTATTGTCCCTGTGTTACAGGTGAGGAAACCGAAGGCAAGAAGTTGCCAAGTTTAGACAATTACTACTCACTCTGTCTCATGACAGCTGGATCAGAAGTGGGCAACTGATGGAGTCTGGATCCATGAGGAGTTCACGTTGCTAGAAAGGGTGGTGACCATGACTCCCTATTCTTAGGGGTGGCAGTGATTGCAATGCTTCAAAATTCAAAGGAGGTGTCAAAATGGAGGGTAGGGAAAAGGCGTGAGCTCTGCCTTCCCCTTGGCAGTGGCGAAGTGATATGGAGTGTGGGCAGGGAGGTGGCGCATTATAGGACTCAACACCACGCTCGTTTATACATAAGATTCCTACCCATTGGATCACTTGAGGAAAGGAGTTCAAGACCAGCCTGGCCAATATGAGTTCAGGCAGAGGACAATATGCAAAGATTGGGAACTAGAAAGAAAACAACATGCCTGTTTATTAAATGATTATAATTACCAATGTACCAGTTATTGTCTGGGAGTACTCAGGCCTATACCTGTCTTGTACCAATGGGGTAGAACTCCTGAGAACTACCTTCCCAAGATCCCCTTGACAGCTGGTTTCCAGCCTGGTTCTTCTAATGGGCTGGACTCCTATGTAATGAGAGGGAGATGGCAGAAGTAACTTGAAGGTCCTAGACTTCTGGTCCCAGCTGCAGAGCTGACATGCACCTGTGAATGCTTGCAAGGTTCCAGTGGCAGCAGCAGTGAATGTGTGCTCTGTGATGGATGCCCATTGTTTAGGGCAGACCAGTGTGGCCTCCTGCAGGTCCTGGTCCCTGAGAGACATTACTTTCCCCTCATGTCTCCTCTAGGCCTTCCCCTCGTGTCTCCAACAGTGTTGTAGGTTAACTCTCTGGATTAGATTCTTTTCTGTTTTGAATAATTAGAGTGCTTTCTATTTTGCTGATTGAATTCTTGACTGTTATCCCCCTATAATATGGCTGTTCTGGCAAGCTAAATTAGAGGACAGGAGAGCTATAAGGCCAGAGGCTTGAATAGGCTTTTTCAAAACTAAGATGACTGGAACTGAAGAGAAGATTTTGAGCAGACTTACCTTCCCTGTCTAGGGAGGAGCTGCTGGAATGCAGAAAATGTTATGAACTTGCTCCAAAGAACCAGAACCACATATACGTGCTAATTAGACTGAAAAACAGAATAGGAGAGAAACACCAGAACATGGCTGCAAGCCCTTAAGAAAAAGCAGTCTTATCTGTTCATAAAATGCAGGATAATGACCAATCCATTGATCATCATCTCCTTCTTACAGGAGGAAGAGTAAGGGGAATGGGTGGAAGTACCCAACATGCATGGGGAGAGCTGGAAACGTCTGCCTCTGAGCTGTGTTGGAAACCTGAGAAGCCTCAATTATGTGGATGTTTACTTGGCTTTGTGCTATTTTAATTATTTTGGCTATTGCTGGTATGAACACAATAGCAAAGACCACACCGTATACCAAATTTACGAAGAAATCTGAGGAAAGAGAGATGCCAAAGGGTCTAAAGCCATCCAGTGGCCCACCTCCACAAGAAGAAGAAACCCTCTTCACAGAAATGGCTGAAATGGCAGAACCAATCACCAAACCCTCAGCCTTGGATTCTGTGTTTGGCACTGCCACTCTCTTTCCCTTTGAAAACTTCACTCTTGACACAGCTGATTTCTTTTTGAATTGTTGTGATTGTTGTTCACCTGTACCTGGGCAGAAAGGAGAACGTGGAGAGACTGGAAAGCCAGGCCCTAAAGGAGAGACTGGGAATTTGGGGATCCCAGGGCCACCAGGAGTTGTTGGGCCCCAAGGCCCTAAAGGCTACAAAGGAGAGAAAGGGCTCAAAGGAGAACGTGGGGACCAAGGAATTCCAGGATACCCAGGAAAACCTGGAGCACAAGGTGAACTTGGCCCTAAGGGAGATAAAGGAAACACTGGTTTGGCAGGAGTGAAAGGACAAAAAGGCTCCAAGGGAGACACATGTGGGAATTGTACCAAAGGCGAAAAAGGAGACCAAGGGGCTATGGGCTCACCGGGCCTGCACGGAGGGCCTGGCACCAAGGGAGAGAAGGGGGAGATGGGGGAGAAAGGCTACTGCAGAGATTCTGGGGAGAAAGGAGGAAAAGGACAGAAAGGTGAGGCAGGTATAAAAGGAGAAAAAGGTTACAAAGGGGATAGTGGAATGGAAGGCAAAAGTGGTCACAGTGGTCTGCCTGGGGCCAAAGGTGATCCAGGGGTTAAAGGAGAAAAGGGAGAGTTAGGTCCTCCTGGTCTCCTGGGACCTACTGGGCCAAAGGGTGACATTGGCAGTAAAGGGGTCCGAGGCCCCATTGGGAAGAAGGGCTCTCGGGGCTTTAAAGGCTCCAAGGGTGAGGTGGCTAGAGTGCCACAGTCAGCTTTCAGTGCTGCTTTGTCAAAGCCTTTCCCTCCTCCAAACATCCCCATCAAATTTGACAAGGTTCTCTATAATGACCAAGGGAGTTATAGTCCTGTCACTGGGAAGTTTAACTGCTCTATTCCTGGGACATATGTTTTTTCCTACCATGTAACTGTGAGGGGCCGACCTGCTCGAATCAGTCTGGTGGCCCAGAATAAGAGGCAGTTCAAGTCCAGAGAAACTCTGTATGGTCAGGAAATAGACCAGGCATCTCTCCTCATTATCTTGAAATTAAGTGCAGGAGACCAAGTCTGGCTTGAAGTGTCAAAAGATTGGAATGGGGTGTATGTCAGTGCTGAGGATGACAGCATTTTTACTGGGTTTCTTTTGTACCCAAAGGAAACTTCTGGAATTTCACCATAAGTTTATGTCTTCAATCTCGTAGTTTAGATTTAGTGGAATAGGTCAATTAACATAGACTAGTGCTATTAAAAAAAAACTTCAATTTTTTCAAGACTATAAAAATAATGCAGAAATTTTTTTAAAAAATGTCTCTTGGAGTCAATTGTTATTTCTATTTTAAGGCACCTCCTTTAAAAATACTTATATATATTTCAGAACATATGTCAGTAACTTTGTAGCTAGGCTTTAAAATTTAGCATTATAATATCAGCATTATTCATGCCATTTAAGTATAATAATAATATCTGTATACAAAATATGAATGAGATTTATAGTTAATAAATATGTTCTTACTAAATATCTTCTATATCTCAGATAAATGTATGTCACTTCTTTTTGTGTAAATTGCATAGTATGACAGCAAGGTTTTGACTCTCTTGGATGGGTTGCCTTCTGACAAAATGGAACTCCTCTCATGTTGGTTTAATTCATGGAGATGACAGAAAGAGTGGCAAAGACTAGCTAAAGGATATTTAACATTTATCAGTGTCTAAAGGTTTGCTCACAAAACTTGTATTATATGGACTTGTGTGTTGGGTAAAATGTAAGAAAAAGTTGATAATCATAGTGAAGATGAAATCATTAATCAAATTATTGTGCTTAGAAGAACTGAATGTCCCCAAAAGAATAAAATGAAATCATTATTGATTTG
->XM_007480608.2 PREDICTED: Monodelphis domestica spermatogenesis associated 1 (SPATA1), transcript variant X3, mRNA 
-GGCGGACGGTGGAGGACGGGCGCGCCTCGGGGGCGCGCGCACGTGCGCGCGCGGCTGGCTCGACGCCCCAACCCCCCTCCTCTTCCTCCTCTACGCCTTCCTTGAGAGAGCGAGCGAGCGAGCGACCGGGAGGGAGGGGAGCGCTGGCATTTACATGACTTGAAGACAAAAGATGAATGGAATGCTATCATTAAGTCACCTAGAGGATTTAGTGACCCTTATCATTAAGTAATGCTTAAATGAAAAAGAAGACCACCAAGAAGCAATTAAAAGCAATTGTTACTTACTCAGGCATCAATGACTACGTCATTCAATAGAAGTCGACCTTCTTCATCAGAGTTGGTGGAACTTCATGTTTTTTATGTCCCTGAAGGATCATGGAACTATAAGCTAAATACTATTTCAGTAGAAGTTGTCAGTAAATTTATTTCAGCTGGATTTATAAGGGTGTCACCTCATCTTACTTTGCAAGCCCTGAGAGAGCAGCTGGGTGAGTTCCTTGGTGAAGAGGCTGTTGCAGAAAAATTCTTGTTTTTGAAATGCATAGGGAACAATTTAGCTGTGGTGAAGACAAAGCAAGAAAAAGAACTAAAGCTTAAGTCATTTGCTCCACCATATGCTCTTCAACCAGAATTATATTTGCTTCCCATAGTGGACCACTTAGGAAATATTTATTCATCATCATCATCCTCTGCTATGGGAGATACACAGCAGAATAATACTGATGTTTTTGAGAATGATAAAACTACTCAGAAACCAGATAGTTGTGCAGCATCTTCAAACAAGGAACATGAAAAAGATCCAAGCCCTATAGAAAATACTGATAAAGTTCCTCCCCTCAAGAATCAGGAAGAAGTCAGCCTAAAAGACAACAAGATTAAAAAATATCCAGCAAGAAAGTATGGATTTCTAGAAGCAATTGATGATAAGCGTCTTTTTCTTGCACAAAACAAAAAAAGCCAATTCCAATGGGAAAACGGAGACAAGATAACTGATACCAGTAGAAGAAAAGAAGATGGGTTAGGTGATGAAGATTTTGACAAGCCACCAGGTCCTTCTGCTCCTCCTTCATTACCACTCCTTGCTTTTGCTCCAGGAATGCTTGAAAATTCTGGTTTACAAAATGAGAAACCTGAGATGGAACCTTTGCCATGGAGGCAAATACTGTACAGCCACAAAGAAAGTAACAGTCAAGGACTCAAGATTATGCAACAAATGAAGCAAGTAAAGGAAGAAAGATGTCAGTTGGAAGAGACTAGAGAAGAACTGTTAAAAAGAGTTAAAAGTTTATTTGAACAAAGCAAAATGAAAAGATATCGTGTCCAGGAAGCTTGGAAGAAAAAATATTTTGAAACCAAGAAAATCACAGCTTCTTTGGAGGAAGTTTTAACCAAACTTCAAGAAGATTTAGAACTTTATTATAAAAAATTGCTCATGCAGCTAGAAGCTAGGGAGATCAAGATGCGGCCCAAAAATCTGGCAAATATGGAAGATTCAAAGAATAATCTAATAATCCAAATCACGGAGGTACAGCATGCAATTGACCAACTAAAGAGAAAACTGGACACTGACAAAATGAAACTCATGATAGAAATTAAGATGAGAAAACAAGCAATTTCAGACATACGAACATTAAAAATGGAACTGGAACAGAAGAAAATGAAGACACCTTTAAGCTCCTAGTCAAATGTATTTACTTAGAAGTGTCTTAGTTTTCAAAATGTTTAGACTTATTGGAAGACTGTCCATCCATTGTTCTTGCTGATGTTTCTTTATAAGCCTTGTATTTCTATTCCTTTATTTTTCATGCTGAGTTTATGAAGTGACTCACAAAATGTTAAGCACAGTATACTTCTCCAGTACCTGGAGGATCTGTGATTTTATCAGAGTGGGTGGTACCTCCACTGAAACAGATCATACCTCCTCCACAAGTTGGGAGATGGATTTTGAGAATAGCTTTAGTTTAAAAAAAAAAGGTAGGAAGGAAGGAAAAAAGAAAGAGAGAAAGAAAGAGCAAAGTGGAAAGCTAAGTAATTTGTTCAGGGCATTATTTAGTTATTTTTGAGTACTTCAAGAAAACTGGATTTCATTTTACAGTAAAGTATTGCATTATTAAATTGCTGGGTTTAAAGATAATTCATCTAAGAATTAAGAATAAAGGCCTATTATTAGTCTTAGCAAACCACCATGTCTTGGTACAAAAGGCTACATTGATTTTTTTTCAATGTAACCTTGATAATTAAAAGAATAATCCTTTTATTTCATTTTAACTAAACAGACTAAGAATCTAAGACTCAGGAAATTGAGATTACCATTTGGAGCACTCAGAGGAAACTCCTGGGATTAGTATCCAAGAACTGACTTATTAACATATTTTAGAAGCATAGAATCCATCAGTAATTCAAAATAAGTTATGAAACATCATCCTTTTGAATGGATGTTCCAGGGCCTCTGCCATAAGCAACCTTGTAAATTGGGAGCAGAGATCTTAAATATGAACTAGACCCAGCAAGGATGGTCAAATTTTTACTTGCTTTTATTCTGATTTATGGGAAAAACCACTAAGGAAGCCTAGATTTCTATTAGCCCAGGGTTCACAGGAATAGGTTTGTGATGCCCCTAGACAGTTATACAGCCAGTGCCATCAAAATGGAAATAATAAATTTGACATTTTCCCGATGCCTATAATGTACCATATGAAAAAGCAGATAGTTCTGAAGTGAAACCTGGCTAAAGGTTTAGAAAAGTTATAAACATTAAACTACTGTGTTTTAGAAATAGAAACATCAGTTCATAAACTAATGTCATGAGGTTAAAATTAGATTCCAATGTGGGAAAATATTGTAAAATTTTTTTTAAAAAAACTAAGCAATAAGGTTGCCAATGAATAAATTACAGATGCACAGAAAAGGATCTTAGGAGAATTGTTTCATCAAGAATAGCATAAGAATAATATCAGATTATCCGCTAAGTTATCCCTATAGTAAATTTAATAATAATAAAATTCTTCTTGAAAATATCTGTCTCAAAAGCATAATTTAGCTAAAAATGTAGGCAACACCACCATACTAGTTTAAAAGATTATCTTTTAAATTCTCTAGGCCAACTCTGTATCTTTTATCTTAGAGTTACTTGTCTGAAGGTTTGGGATGAAGCAAAAAGCAAGTATCACAGGGCACTGAGGTGCTACTTGGAAATAAGAATCATTGACCCAACAGCCCATCCTTCTTTTAACAATACATTGGTCCTAAGGAGAAGACACTATATATCAACCAACTTTAATATTAGGCTTATTGGACAAATAAAATTACAGAGTGAATTGCTTCTCAGAGAATGGGTATTTAAAAAAAAAATCTGTCCTAAGCAAACTAGGCTTTCCTTTACAAGTCTTAGAGCATTTTGCATAGTTTATAAATATGTAAGCATACATGTTAATATCATGTACAAAAGACATGAACATAATAAAATTATGAAAATACCGGTTTATTAAGTGACAGATAAAACATCTTATAAAATAAAGAAGATTATTTCATACT
->JN080695.1 Uncultured bacterium clone HI04_FZZ71GH04EJVXU 16S ribosomal RNA gene, partial sequence 
-GATCCTGGCTCAGGACGAGCGCTGGCGGCGTGCTTAACGCATGCAAGTCGAACGAGAATCTGTGGAAAGAGGATTCGTCCAATTGAAGCAGAGGACAGTGGCGGACGGGTGAGTAACGCGTGAGGAACCTGCCTTTCAGAGGGGGACGAACAGTTGGAAACGACTGCTAATACCGCATAACACATTGAGGTCGCATGGCCTTAATGTCAAAGATTTATCG
->XR_008021246.1 PREDICTED: Diospyros lotus uncharacterized LOC127792942 (LOC127792942), transcript variant X2, ncRNA 
-ATGGATTGGAGGGAGTGCTCCGAAATCAAAATATCTAAAAACAATTATATGAAACGAACGAGAATTTCGATACGATTATTATGACATCGAAAAAAATCTGATCAGAAACAGTTTTTTGGGCAGCTAAAAATCAGGCAGAAAATCGAATCGTCGTAATTCGTTCACAAAAAGTCAATTGAACACAAAATACAGTTTAATTTAGTTATTGGAACAACCTTTTGGTTGTTTAATGTTGAAACAAAAGTACTAGCGATCTTATCGAACAATAGGACGTAAGCGTAATTTCTTCATTTTTCCCGACTTTGCTCGAAAAAAGAAATTTCCTTTTTTTTTTTTTTGTCAATTTTCAATGGTGGAATGAAGATAATTTCATATGGTTTTAAGTGTAGTTTTATTTGGAAGTGTAATTGAAATATTCAAAAGATTAGGGGTTTAACTTGATTTTCGGTACAATTATGAGTAACCGAATGGATTGGAGGGAGTGCTCCGAAATCAAGATATCTAAAAACAATTATATGAAACGAACCAGAATTTCGATACGATTATTATGACATCGAAAAAAATCTGATCGGAAACAGTTTTTTGTGCAGCTAAAAATCAGGCCGAAAAGACGAATCGTCGTAATTCGTTCACAAAAAGTCAATTGAACTCAAAATACACTTTAATTTAGTTATTAGAACAACCTTTTGATTGTTTAATGTTGAAACAAAAGTACTAGCGATCAAATCGAACAATAGGACGTAAGCGTAATTTCTTCATTTTTCCCGACTTTGGTCGAAAAAAGAAATTTCTTTTTTTTTTTGTCAATTTTCAATGGTGGAATGAAGATAATT
->XM_038964517.1 PREDICTED: Salvelinus namaycush extensin-1-like (LOC120020894), mRNA 
-ATGTCCAAACCCTTCCCCAGAGGCCTGCCCAACCCCTTTCTCAGAAGCCTGACCAACCCCTTCCTCAGAAGCCTGCCCAACCCCTTCCTCAGTGGCATGTCCAACCCCTTCCCCAGAGGCCTGCCCAACCCCTTCCTCAGAAGCCTGACCAACCCCTTCTTCAGAGGCCCGCCCAACCCCTTCTTCAGAGGCCCGCCCAACCCCTTCCCCAGAGGCCTGCCCAACCCCTTTCTCAGAAGCCTGACCAACCCCTTCCTCAGAAGCCTGCCCAACCCCTTCCTCAGTGGCATGTCCAACCCCTTCCCCAGAGGCCTGCCCAACCCCTTCCTCAGAAGCCTGCCCAACCCCTTCTTCAGAGGCCCGCCCAACCCCTTCTTCAGAGGCCCGCCCAACCCCTTCTTCAGAGGCCCGCCCAACCCCTTCCTCAGATGCCTACCCAACCCCTTCCTCGGTGGACTACCCAACCCCTTCCTCGGTGGACTACCCAACCCCTTCCTCAGACGCCTGCCCAACCCCTTCCTCAGACGCCTGCCCAACCCCTTCCTCAGATGCCTGCCCAACCCCTTCCTCAGTGGACTGCCCAACCCCTTCCTCAGCGGACTGCCCAACCCCTTCCTCAGATGCCTGCCCAACCCATTCCTCAGCGGACTGGCCAACCCCTTACTCAGATGCCTGGCCAACCCCTTACTCAGTGGCCTGCCCAACCCCTTTCTCAGTGGCCTGCCCAACCCCTTCCCCAGAGGCCAGCCCAACCCCTGA
->XM_033401886.2 PREDICTED: Orcinus orca KAT8 regulatory NSL complex subunit 3 (LOC101288842), transcript variant X6, mRNA 
-TATATTTTTAAAACTCCAGAACATTATGAAGTCGTTGCAAAACTTTTGTTTAACACAAACGAGACGTCAAGGGCTTCCGTGAGGCCCACGTTAAGCAGCTGTTCCTGGGATGCTCACGCTACTGCTGGAGACGGCTCTGGGAAGCTTTCGAGAATGGTGACTAGCATGCAGGTACCCGTTCTCTGACTTGCTGCCCCTCTTCTGACATGGCCCACCGCGGTGGGGAGAGGGACTTCCAGACGTCAGCGCGGCGCATGGGCACCTCGCTGCTCTTCCAGCTTTCGGTGCATGAGCGGGAGCTGGACCTGGTGTTTCTGGATCATAGCTATGCCAAGCCGTGGAGCGCCCACCCAGATGCCAGTAGTGCCCGCCCCACCCGCATGCTCTTTGTTACTCCCCGGAGGCAGCACGAAAGTACCATCGAGTCAGATGTCCCACTAGATGTGGAGACAGTCACGTCAACCCCTGTGCCACTTTATGACAATCAGAAGGCACGCAGCGTGATGAATGAGTGTGAACGGCATGTCATCTTCGCCAGGACCGATGCGGATGCACCTCCCCCTCCAGAGGACTGGGAGGAGCACGTCAACAGGACTGGCTGGACAATGGCCCAGAACAAGCTATTCAACAAGATCCTCAAAGCCCTGCAGTCTGATCGGCTTGCCCGCTTGGCCAACGAAGGGGCTTGTAACGAGCCAGTGCTGCGCCGTGTTGCCGTGGACAAGTGTGCGAGGAGAGTGCGGCAAGCTCTGGCGAGTGTGAGCTGGGACACCAAGCTGGTCCAGTGGCTGCACACCACGCTGGTGGAGACCTTGAGTCTGCCCATGCTGGCCGCCTACCTGGATGCTTTGCAGACACTGAAAGGGAAGATCCCTACCTTGATTGACCGGATGCTCGTGTCGTCCAACACGAAGACCGGGGCTGCTGGAGCTGAGGCCTTGTCCCTCCTACTGAAGAGGCCCTGGGACCCCGCTGTGGGAGTGCTCTCTCATAACAAACCAAGCAAACTCCCCGGCTCTCCTCTCATTCTCATTGCCTCCTCCGGGCCCTCCAGCTCCGTGTTCCCCACCTCGCGCCGCCACCGCTTCTGGCAGTCTCAGCTGTCCTGCTTAGGCAAGGTCATCCCTGTTGCCACGCATCTGCTGAACAATGGTAGTGGAGTAGGAGTTCTGCAGTGTCTGGAGCACATGATTGGGGCAGTGCGAAGCAAAGTGCTAGAGATTCACAGCCATTTCCCGCACAAACCCATTATCTTGATTGGCTGGAATACAGGAGCCTTGGTGGCCTGTCACGTGTCGGTGATGGAATACGTCACTGCAGTTGTCTGCCTTGGGTTTCCTCTGCTTACCGTGGATGGCCCCAGAGGGGATGTGGATGATCCCCTCTTGGATATGAAGACTCCAGTCCTCTTTGTCATTGGTCAGAATTCCCTGCAGTGTCACCCTGAAGCCATGGAAGACTTCCGGGAGAAGATTCGGGCTGAGAACAGCTTGGTGGTGGTTGGGGGAGCTGATGATAATCTCAGAATAAGCAAAGCAAAGAAGAAATCGGAAGGGTTGACTCAGAGCATGGTGGACAGATGTATTCAGGATGAGATTGTGGACTTCCTGACTGGAGTGCTCACTCACGCGGAGGGGCACGTGGGCTCTGAGCCTCGGGATCAAGATGCTGAGAAGAAGAAGAAGCCCCGGGACGTGGCCCGCAGAGACCTGGCCTTTGAGGTCTCTGAGCGGGGCAGTCGACCTGCGTCACCAGCTGCCAAGCTACCTGCCTCACCCTCAGGCTCGGAGGATCTCTCCAGTGTGTCCAGTAGCCCCACCTCCAGTCCCAAGACCAAGGTGACCACAGTGGCCTCTGCCCAGAAGTCCAGTCAGATCGGAAGCACTCAGCTGCTGAAGAGACACGTGCAGCGGACAGAGGCTGTGCTGACCCACAAACAGGCTCAAGTTCCTGTTTCATCAGAACAAACGGAGGAAGCCGAGAAAGAGGATCTCAGGGTCCAGCTGAAGCGGCACCATCCCTCCAGTCCTCTTCCTGGCAGTAAGACCTCCAAGCGACCGAAGATCAAGGTGTCCCTTATCTCCCAAGGGGACACAGCTGGAGGGCCTTGTACTCCTTCCCAAGGAGGAGCTCCAGAAGCCGCAGGAGGGAAGCCCATCACCATGACACTGGGGCAAGCTTCCACAGGGGCCAAGGAGCTCACAGGACTCCTCACCACAACCAAGTCAAGTGCTGCTGAAGGGGGAGTCTCAGCCAGCCCAGCGTCCTCAGTGGTCTCTAGCAGCACTGCTCCCAGTGCCTTGCACACACTCCAGAGCCGCCTGGTGGCCACCTCTCCTGGCAGCTCCCTCCCAGGGGCCGCATCAGCCAGCAGCCTCCTCCAAGGCCTCAGCTTCAGCTTGCAGGATATCAGCAGCAAGACCTCTGGCCTCCCAGCAAACCCCTCTCCCGGGCCAGCCCCACAGGCCACCAGTGTGAAGTTGCCCACCCCCATGCAGAGCCTGGGTGCCATCACCACGGGCACCAGCACCATTGTCCGTACCATTCCTGTGGCCACCACTCTCTCCTCCTTGGGTGCCACTCCTGGTGGGAAGCCCACAGCCATCCACCAGCTGCTGACCAATGGGGGCCTCGCCAAGTTGGCAAGCAGCCTCCCTGGCCTGGCTCAGATCTCTAACCAAGCTTCAGGCTTGAAGGTCCCCACCACCATCACTCTGACACTACGTGGCCAGCCCAGCCGAATCACCACACTGAGCCCCATGGGCTCAGGAGCAGCCCAGTCAGAAGAGCCCACCTCCCAGGCGCTGCCCTCCAGCTCACAGCGCCTGCCTCCAGCGCCCTGAAGATGCCATGCGATATGTCCTCCTTTACCAGGTTGGTGACGGCTGCTGCACGGTGAGGCCTGGCACATGTGCTGTCCTGCTGAGCTGTACACTTGTCTGAAGACCTCTTTAAGACAGTCATTTTTGCCTCTCTGCCAACTGTCTTCAGGGCTGGGCCTCTGGGTCTTACGTAACCATTAGACAAGGTGATATGGCGCCAGCAGGGGGGGCCTTGTCCTTTAGCATCTGCAGGTCTGGTTCCCAGAATCTCCAGGTCCTCAGCAGATCTGGCCGTGTATGGATTGGAGGCACTTCTTCCCCAGCATTAGCTGTAACTTGACCCAAGTAGCAGTGTGGGACTGCTCACTGCATTTTAATAAAGGAGCTCCCCTTCGAAGTCTGTACTGCCCCGTGCCAAGTTGGGAGGAGACGTCCGTGTGGTCTGGGACTGAGAGCCCTGTGCTGAGGACCGGGATCATCCTGGCCCACTGGCCAGTGGTTCAGTGCCAGAAGGGCTTGTTTTGCACATCACTGTTGCCTTCACCAAGCAGCCATGGGAGAGTGCTCCCCGTGCAGCTCCCTCCTTACGAGCCACACTGGATACTGAGTACCTGCTGAGACCTGGGAACTCTTCATTTCAAACCCACGATAGGGCACAGAGAACTGGGCTGTCATCTTTCAGTCCCTTTGGTCACCTGTAGATGTTGGGACCAGCAGTCGCCAGGAGGTGAAAGCTGGCTTCTTTCTTTTTTCCATCATGCTTTGGGCAGTTCTTGTATCCAGAAAGCCTGCAGGTCCAGAAAGGCTGAAGAAGAGGAAGGGAACAGCAGATGAAGTGGCTTGAAGGACACGTCAGTGGTGAAAACGATTTGGGCTTGAGGCTTAGCATCTGGTACCTAAGGAGCCGTTGATTCAACTGGAGATGAGAAGAATTTGCCAAGCCAGAGGAGAGAAACTTCAGCCCCTGAAATTTCTGTCTCCAGTGCTTGGAAGTGGAACAGGGGTAACTGCTAAGTTAACGTCTTGGCCGTCCCATGAAGCTCAGGCATCAGGATGATGAAGGCCATGCTTCAGTGTTTCTGTTTCAGCTCTGTGCAACTTTTTGTCTTCTTGCTTAGAAGTGGGAAAATTATTGGTATTGACTCTGCTGTGCAGGGCTCTTGGTACCAGCCTGAGCCCTGGAGGTGGAGGTCTCTGGAGAAGTGATCACTGAAGATGGAGCTCTGAGCCCCTCCTTACCTCCTCACAATACTTGTGTGCAAAAAGTATTTTAGATTTGGCTGACAACCTATCCTCCAGAGCAGGCTCCTTTCCCTTCCATACTCTAGAATGTTTCCAGCCAAGGCGATGAATAAGGCAACCCAGATATAACTCTTCAGTATCTGTACTGAAGGCAGGGAGGGCCCACAGCGTGCCGTGGCTGGACTTGTGGTCCAGGGTCCTGACCCGTATAGTGCATCCATCGTATATCCAAACCAGGCCACCTGCATTCAATCCAGGAGCCTCACCTCCAGTATGAGTGGCAGCCAGGAGGGAGTACACAGTGTGCAGGATTCTCAGACAAGGCCATTTGGGGTGGTACAGGCAGGGCCAGGGACTGTGTATGATAGGAGTGGAGTGGGCAGATTATACACCATACGCTTCCTCCCCGACCTCCTGCAGAGCTGGTCTCAGCAGTGACTCACACAGAATTAGGCTGCATCCCTGTACTAGCTGGCAGGTAGCTGCTTTCTGAAATTCAGGAGGCGTTTAGTAAGTTGGAGGAAGATACGAAATCTGAAAGAGACATCCAGTGTCAGGGGTTTAATAACTTTACAGGTAGGATAGTAACACACCAATAGGAATTGAGGATGGTGAAACTGAGACTATGTGAAGTTTTAGGAATCATTCAGGACAGAGGTTCCTGAACAACCCATTCATGACTTAAGAGTGCAGTCTAGACAGCACTGGAGGGGCTGCTCCTGAAAGATGCTGGCCCTGTGTGTGCTGGGGCCAAAGGAGAAACTAACGCATCGTCCTGCATTTGCGTAAATCCTAGTATGCTTCTCATGGATGATTTCCTGAGGCTTGTGTTGTACACCTTAAAGAATGCCAAAAGGAGAAGGGAAGTTGTAAGGACATTGATTCTTCTGCACCCTGGAGGGACAGGCCTAAGGAGGAAGTGGTTGAAGTCTATACAGTCATGTTCCCCAATTCCATACTTCTCCAGCCCTTGAAGTGTAAAAGGAAGCTTTCCTCCGCCTATCATGTAGCAAACCTGGAGTCCATAACCTCAGAAGGTGATAACTACTGGCCGAAAGTGTAGAAGGATCAAGAGGGCTTTAGCTGATTTCTTGGATGACAGATACATGTTGATGCTCTATGGAAGATGTCCTTGTTTTGAGAAGAGGTCACTGATGGAGGAAGACCTGTCTGCCCTTGGCTCTACCACTAGAACAGTCTTGGGCTGGATGGGTTATAGAGCTGAGCTGCTGTGACGGTTCTGTTCTTCCATTAGCCAAAACAATTAAAAATAAAAACAAATTTGGATTGCTTCAATG
->XR_003982306.1 PREDICTED: Sparus aurata uncharacterized LOC115573581 (LOC115573581), ncRNA 
-CACCACTTTGTACCTCAAGAGGCGATAGTACAGAAGTGGGCTGCTGCAGAAACATGGCGGTGTAACATGGCAGACTCCGCGACAGAGGACCTGCTTCTTTTAAGGTAATCCCAGGAAAGTCTGGCTGGAGGCTGGAGACACGTTTGTCAGGAAAGTACGTGCCTGATCTGATGTGACCCCTCCAATCATCAAACTGTCAGATATGATTGAGAGGGTAGAGTCCACTGCTCTGACTGTATGGTATATCACTACGTTGGTGATATGAACTGTGAAGGTATTAA
->XM_040635235.1 PREDICTED: Ursus maritimus RNA polymerase III subunit E (POLR3E), transcript variant X3, mRNA 
-CACGTGTCCGCTGGAGTTTCTCCACCAGCAACATGGCCGCTGCCTAACAGAAGAGCCGGGCCGCCGCCACCTCTGCAGCCCGCGGGTACCTGGGCCGTTGCCGCCGCCCGCGCGCGGCCCCCGCGGAGAGATTGAGTCCAACGATCGTGCGGCTGGCTCCCCCCTAGTATGGCCAATGAAGAGGATGATCCAGTCGTACAGGAGATCGACGTGTACTTGGCCAAAAGTCTGGCAGAGAAGCTGTATTTGTTTCAGTACCCTGTGCGCCCAGCCTCGATGACCTACGATGACATTCCACACCTCTCAGCCAAGATCAAGCCCAAGCAGCAGAAGGTAGAGCTTGAGATGGCCATCGACACCCTGAACCCCAACTATTGCCACAGCAAAGGGGAGCAGATTGCACTCAACGTGGACGGCGCCTGCGCGGATGAGAGCAGCACTTACTCCTCGAAGCTGATGGACAAGCAGACATTCTGTTCCTCCCAGAGCACCAGTAACACAGCCCGTTACGCTGCCGCACTCTACAGGCAAGGTGAGCTGCACCTGACGCCTCTCCACGGCATCCTGCAGCTGCGGCCCAGCTTCTCCTACCTGGATAAGGCGGACGCCAAGCACCGGGAGAGGGAGGCGGCCAACGAAGCAGGAGACTCTTCACAGGATGAGGCGGAAGAAGACGTGAAGCAGATCACGGTGCGGTTCTCCCGTCCTGAGTCAGAGCAGGCCCGCCAGCGCCGCGTGCAGTCCTACGAGTTCCTGCAGAAGAAGCACGCCGAGGAGCCCTGGGTGCACCTGCACTACTACGGCCTGAGGGATAGCCGCTCTGAGCATGAGCGCCAGTACCTGCTGTGCCAGGGTTCCAGCGGGGTTGAGAACACAGAGCTCGTCAAGTCACCCAGTGAGTACCTCATGATGCTGATGCCGCCCAGCCCGGAGGAGGAGAAAGACAAACCCGTGGCCCCCAGCAACGTCCTGTCTATGGCCCAGCTGCGCACGTTGCCCCTGGCCGATCAGATCAAGATCCTGATGAAGAATGTGAAGGTCATGCCTTTTGCCAACCTGATGAGCCTCCTCGGCCCCTCCATCGACTCTGTGGCTGTTCTGCGTGGCATCCAGAAGGTGGCGATGTTGGTCCAAGGAAACTGGGTTGTGAAGAGCGACATCCTGTACCCCAAGGACTCCTCCAGCCCTCACAGCGGCGTCCCTGCCGAGGTGCTCTGCCGGGGTCGTGACTTCGTTATGTGGAAGTTCACGCAGAGCCGGTGGGTGGTGAGGAAAGAGGTGGCGGCAGTGACTAAACTGTGCACGGAGGATGTGAAGGACTTCCTAGAGCACATGGCCGTGGTGCGGATCAATAAGGGCTGGGAGTTCATACTGCCTTACGATGGGGAGTTCATCAGGAAGCATCCAGATGTGGTCCAGCGGCAGCATATGCTGTGGACGGGCATCCAGGCCAAATTAGAAAAAGTGTATAATCTTGTGAAGGAAAGCTTGCCAAAGAAGCCAGATGGACAATCAGGGCCTGCTGCTCTGCTCTCTGGGGACCAGCGGGTCCAAGTGGCCAAAAGCAAGGCCCAGCAGAACCACGCACTGCTGGAACGGGAGCTGCAGCGGAGGAAAGAGCAGATGCAGGCGTCCTCGGTCCTGCCTGGCGTGCGGATCAAGGAGGAGCCCATGAGTGAGGAGGGAGAGGAAGAAGAAGATCGAGATGCAGAGGAAGACGAGGAGCCCATGGACACCTCTCTTGGTGGCAGCCTCCACAACAGGCTGGCCAATGGGTTGCCTAGCGGGCGGGCGACAGGCGGGGACAGCTTCAATGGGCACCCGCCCCCAGGCTGTGCCAGCACCCCCGTGGCCCGGGAACTGAGGGCCTTCGTGGAGGCCACCTTTCAGAGACAGTTTGTGCTCACGCTGAGTGAACTCAAGCGCCTCTTCAACCTGCATCTGGCCAGCCTGCCACCTGGCCACACACTGTTCAGTGGCATCTCGGACCGCATGCTGCAGGACACGGTGCTGGCCGCCGGTTGCAAGCAGATATTGGTGCCTTTTCCCCCCCAGACTGCTGCGTCCCCAGATGAGCAGAAGGTGTTCGCCCTCTGGGAGTCTGGAGACATGAGCGATCAGTTATCATGAAACACCAAGTCTAAACTGCTTGTCCTCGGCTGGCGCGTCCCTGGCTTTGTTGTCTTCTTCCTGGGGTCTCGGG
->XR_001152071.1 PREDICTED: Microcebus murinus uncharacterized LOC105866893 (LOC105866893), ncRNA 
-TGCTAGCTCCTCGTTAAGGAAGTGACAAGGTTGTAGACACTGGAGGTGGCTCAGTTACAACTGCCTTTACCGTGTGGCTGAGAATTCACTCCCTTCCAGGTCTGGACCTCATGGTTCTGTCACCAAATCGGCTGCCCCTGGATAGAACAAAAAGGCAGAGGCCCTTCTCTTCTGAGCTGGGACACCCATCGTCTCCTGCCCTTGGACATGAGAACTGCACATTCTCCGGCTTTCAGACTCTGAGACTTACATCACTGGCTCCCAGGTTTTGACAACTTTGGACTTGAACTGAGCTATGCAACTGGCTTCCCGGGTGCTCCAACTTGCAGTGGGACTTCTTCCTCAGCCTCCATAATTGATGAACAGAGCAAACCTTATCACCAGAGATGGAGAATCAGAACCAAGATGAGTCTGCACAAATGAAGCTTACTAAAATTATACTTATCTTCCATTCATTTCCCCCACATCCA
->XM_037676314.1 PREDICTED: Nematolebias whitei ALG2 alpha-1,3/1,6-mannosyltransferase (alg2), mRNA 
-TCTCACTAAAATCGTGTGCTTTAAAGTGAGAAGGAAATAGGCGCCATTGTGGTCCAAACACGAAGCTCGTGTAGCTTAACTCTAACGGGCAATTAGAGCCAAAATGGCGTTTAACTGTTAGAGATTCTTGAAATCGGCTGACAAGTAGGCGAGTTTAATCAATGGTTTCTAAACCTTGACTGGATAGAGGAGAGATTCAAAGGATGGCCCGGGTGGTGTTTCTCCATCCGGATCTTGGTATCGGAGGAGCAGAGAGGCTAGTGGTTGATGCCGCTGTTGCCCTGAAGTCCCAGGGGTGTAGTGTTCAGATATGGACGGCCCATTATGATCCAACTCACTGCTTCTCAGAGACCCTGGACCCAGACCTGCCTGTGGTTTGTGTGGGTGACTGGTTACCTACCAGTGTGTATGGCTACCTTCATGCTCTCTGTGCATATATAAGAATGATCTATGTGGCTCTGTACCTGGTCTTCCTCAGTGGTGTTGAGTATGACGTCATCTTCTGTGATCAGGTGTCTGTGTGTATACCTGCACTGCGGTTGTCCCGTCACAGAAAGAAAGTTCTGTTTTACTGCCACTTCCCAGACCAACTGCTGACCCAGAGAACGTCGGCCCTAAAGAAATTTTACAGAGCTCCCATTGACTGGTTGGAGGAACGCACCACTGGCATGGCTGATATGATTCTGGTAAACAGCCAGTTCACCGCAGGCATCTTCAGGGAGACATTTCAGAGTCTGAGCAGGGTCCAGATAGACGTCCTGTATCCCTCCCTGAACACACAGACCTTTGACCAGGGGTCCACTGAGGCTCAGGGCCTGCAAGGTCTGCTTCCTGAGGGAACTTCTCACATGTTTCTGTCTCTGAACCGATACGAGAGAAAGAAGAACCTGGGTCTGGCTCTGGAGGCTCTGGCAGTCCTGAGGTGCAGCCTTACACCTGCTCAGAACGCAGGTGTTCACCTGGTGGTCGCGGGAGGCTACGATGATCGCGTTACTGAGAACGTTCAGCACTACAGTGAGCTGAAAGAATTAGCCGAGCAGCTCTACCTGATGGACTGTGTCACGTTTCTGCGCTCCCCCTCCGATTCCCTGAAGGTGGCGCTGCTGCGGGGCAGCACCGCAGTTCTTTACACCCCCAGCAGGGAACATTTTGGGATAGTTCCTGTGGAGGCCATGTATTGCTGCTGTCCTGTTATCGCTGTGAACTCTGGGGGGCCCCTGGAAAGCATAGCAGACGGGGAGACAGGCTTCCTGTGCGAGCCCACCGCTGACGCCTTCTCCAAGGCCATGGAGAGGCTTATCAAGGAGCAGCAGCTCTGCAGGGACATGGGGCAGGCTGGGAGGAGGAGGGTGCAGGAGAAGTTCTCTCTTCAGGCCTTCTCAGACCAGCTCTATGGGTACATTGTCCGGCTGAACCAGTGATGGGAAGGCAGGTGAAACCTATGACTGCACAGAGGATTTAAGTGTAAATGTGAAGGGAGGTGGGGGTGTATTAAGAAGACAATTAATCAGCATTCCACTGGAGGGGTTGCTGA
->XM_034454558.1 PREDICTED: Crassostrea gigas ankyrin and armadillo repeat-containing protein-like (LOC105340499), transcript variant X6, mRNA 
-TCGAGAATTAACGAAAGTGACCAATCAAACTTTCGCTTCTATTTGTACATCGTCGTCGACACCAACAGGTTGTGGAAACGACTGCAGTAGGGCAAAATACAAAATGCACACAGGATCTATAAATAGCTGACATGGCCACTATGAATGCTGGGACCCCCCAGCCGGGGGAACCCACGGACGAGGCCCAGCTCCAGGCCAAACTGGAACGCTTGGCCAGTACGTACTTCGAGAAGTTCTCCACCCCTGTGTTCAGAATGCAGGAGCTGATTGGCTTCCACAAAAACCACTGGCTGCTCTCTGACGATTTCAAGATGGCGTACGATCAACCGGACGGCCTCATTAAAGGTTTGAACCCGCTTAACTCCAACAGCTGTGTTCTGATGGTGCCGGAGGACCCAGTCCTAGCAGAGAATAAGCTTGGCCTGGACTACCGCGAGGTTCACCAGGTGATCCGGGAGCTGACCTACGGGATCTACGTCCTGAATCAGACCCCCAGCATCTCCCTGGAGGCACTGTATGATCAGGGCACATGGTGTAACCTACCCCCGGGCTTCAACGACACTCACATCGGTCAGCTGTTGATCAGCGTTGACTACATGATGAAGTCCCTGTGGCATGGAGCTTACTTTCCCAAAGAGAAGAGGACCAAATTCAACGACAAATGGAGGGAGCACTTCCAAGTGTCCAAACAGAATGGAAAACCAGAGAAAGAGAAATCCTTCCTCTCCGATTTCCTCAGTCATGGCATGGTAGATATGGGAAAAGATCCGGATTACTGTGACGCGTACAATGACCTTCAGTTCGATAACGAGGACGACCCAGACATGATAAAAGAGCGAATTCACTTTATGAAGCACATAGAGGACATTTGTATGCAGATGACGCTGTACCAGAAAAAAGTGATGCATGAAAAAGACATCTACATGATGGAGGCCGATATGACCATATCCAGTATCGTTCGACTGCTGGACGATCGGATAAATCACGACGACTACGAGCGTGTGAATACGAGACTTCAAATGCATGAAAACATGCTGAGGGAAAACCTTATGAAGAAGATGGACATCAGGCGACAGTTGTTCATTCTGAAGTTTGTGAGTTTTCTGACGCCGTTTTTGATCGGAATGAGGAAGAGAATGAAGATTCCCGACACTACACGATTTCTGCCAGATCTCTCAGAATCAGAAACAGAGGACCAATGTAAGACAGAAGAAGAGCTGCCACCATTAATGCTGGGAGACGACTTTAAGTGTAAAAACTTCTACCCCGACAAAAACAAGTACTTTCACCTACACGGGGGAATAAACATCGACTTTGAGACAGACGATCTAGAAGCGACTCCAAAGGAAGTGACCAACAGATACTCGGATATCCTAGCAATGGCTGAGCAAGGTTTTATAAAAGCCATTTCCATGGAAACTATCAAAGAGCATTATGAGGTGCCAAAAATTACAGTGGACGGAAAAGAGTATTACCTGATCTTCCTGGAGTTTGAGACGTTCTTTAACCCCCAACAGCCCGCCTGGATAAAGGCCTTCAACACAAAGCTGACCATTGACCTAGAAAGAAAGTACCTCCCCCTACAGGACACGCCCATGTGGGACATCTTTGTCAAACATTTTGGCAAGAAAAAGACAGGAAAGTTAAAGGCTCAGATGACGGGACCGCGAGCGGCGGCCATTAGAGGACTGGTCATCATATTTGTCCATATGTGTCGCAAAACTCTGGGACAGCAGATGTCAAGGTTGACAAAGCAAGACGAACACGGTCTATCGCTTTTGCATCATGCTGCGATGAACAATCGGCCGCAGATAATTGTCAGTCTGCTGCGACAAACTGTGGATATCAACTCTAGACGCAACAACATCTTGTCCACAGGTCCGACCGGGCTCCATATAGCTGCCCGTTGTGGGGCCTTGGATGCTGCTGCCTGTCTGTTGGCCTGTTGTGCGGGACAGACATTGTACGATCAGGACGGATGGGCCCCGATCCACCACGCTGCTTTTTTCGACCACGAGTCTATCATCAAGTTGATGGCCAGGAGGAACAATCCAGTCATAGAGCTGCTGACTAGGAATGATGTTCGGTCGACACCTCTGTTGCTAGCCGCGAGTTCTGGAGGACTCTCTGCCGTGAAATGTTTGATCAAACTCGGAGCGGACATTTCCCGGCTGGACGGGGAAGGGAACGGAATGGTCAATCTCGCTGCCATGAGATTCCACACTAACGTCTTGGAGTATCTCATTGAGTGGGGCCACCAAAAAGCCCCTGTGTGGAAGATTCTTGTCAAAATGCTGACTGATCCAGAAGTGGAAAAGAAAGACAGTGCTGTCAAATGTCTGGAGGTCTTGTCTACGTCAAAACCGGAGCACTGGAAATCCATTCTGGAAGCAGGGGGTATCCCAGCCTTGGTGACCTTGCTGAGTTCAGACAATGAAGTCCTCCAATCAGTGGCCGCCTCCGTCATCGTCAACATCTCGGAACACGCGGAGGTTCGTCACGCTCTGACGGCTGCCAAAGCCGCCCCAATTCTGATCCAGCTGCTCAACTCTCCAGACGATAACATTCAGTCTCGTGTGGCCATAATCCTGTCGGACATTGCCAGTGTCCAAGGAAACCAGTCGCTTATTGCGGACGAAGGCGGGATTCCCCCGCTGATTCATCTCATGGACTCTGAGCTGGAGGAAGTCCTGATAAACACTGTCAATGCCGTCCGTGTTCTCTGTGCAGGAAATCCCCCCAATCAGGACGCGGTGGCGGAAAACGGAGGAATCGCATTTCTTCGCGAGTTTCTGACATTGGATTCAGAGAAATTAAAAGCGGCAACAGCAGCATGTATTGCGGCGATCTCTTCAGGAAATAAAAAGAACCAGGACGCTCTGTTAGAGGCGGGAGCTTTAGAGCCCTTGGTGGATATAATTAATGGAACAGCTAATGAGACGGTGCGGGTGAAGTGTGCTAATGCCATCGAGGCGCTGGCCCAGGATAACCTTGCCTGCCAACAGACCTTTCTCCGAATTAAGGCCCCCACTGCCCTCAAAAAACTCCTCAAGAACTTTAATGTGTCGGTGAAGGAACATGGGGCCAAGGCACTCTGGGCGCTGGCGGGCAGCACCACGTCCCAGCAGAAGTACATCGCAGAGAAAACCAGCATCCCCGACATCTGTAGCATGCTACTGGAGGACACTGAGAAACTGCTGCAAGTCGGCTGCATGATGTCGATAGCCTTGGGGAGAGAGAATATCGAGAACCAGATCAAACTAGCTCAGACAGAGGCTTTCAATCAACTCGTCCGTCTGCTGCGGACTCACAAAGACTCGCCTCAAGTCATACTCATGGTCATCCAGGTGCTTGGAATTCTGTGTGTGGGTGTTGCATATTGTAACAACAAAGTAACACAGAGAAAAATAGCGGAAGAAGGGGCTATTCCGACCCTGGTGACCTACTTAAATCAGCCTCCTTCAGAAGAGGTCCAGGTGGAAGTTGCCATAGCGCTGGGGTGCATCGTCCTTAGCAACACTCGTAACCAGGAACTACTTCAAGAAGAACCAGGATTTAACTTTGATGTGCTACTGGATTTGTTGAAGTCAAAGAGTGAAGCTATTCGACTCCGAGCAGGCATGGCCCTGACCATCTTCGCATTTAACAATACTCCGCAACAGTACGCCATCCGAGAGGCAGGCGGCATAAAATACTCTGTCTTCGAACCTTTCCTCAACTCCAGCATAGAATATGATGTCTGTTACGCTGCGTTTCAGATCGTGGTGCTTGCGCGGGTGATTGTCGACCAAGACCAGGTGATGTTGACGGCTCGCGGTGTCACGCTGCTCGTAGAGAAGCTCCACTCCACAGAGGACAATGTGATCGTACTCGCCGCGAGTCTCCTATCGAGTCTCGCTCACACGCGGGCAGGAATCCCTGATGCCATGGTAACCACAGGCGCCATCGATGTGCTAGTGGAAAAACTCTCCTCACGGAATGACCAAGTTCGGAGTGCATGTGCGGTTGCCCTCGGTTACTTGACTTTCAACAGGACTGCTGCGAGGATTTTGTTCAGTGCTTGTCGAAACACTCCTGGATTGTACAAAAAGCTCGACGAAAACATTGGGAAAAATGCCAAAATTAGTCAGGAGTTTGTGCAGGATTTCAAACGAGCAAAGATTGTTGGATTGCCGTCTCAATGCCTTGAGATTAATGGTGGACCTCCAGTAATTCCTCCCAGCAGAAACAGTATGAGACCGATGACTGGTACGACAAGTCGAGCTACCACCGCCCAAGCTACAAGCCGAGCGAAATCAGCTCCGGGGAAGAGACCGCCGCCGAGATCATCCCCTAACCCCAGCGTGGTTGTTGTAAGTACCCCCGACAACAGTCGCCCCTCAACGGCCTCACCCCTCAGGATCCACCCCAGCTCTCTGTTCCGACCTGCCTCCTCCCCCCACACCAGAAAAGGGGCGCGGTCACCCCCAGATGCAACCTTCAAAACGCGGTTATCTTCGTGGAAAGAAGAAATCTGATGAAAATGTTTCTCTCTGAGTTTTTTGTATCAAATGAAATGTAATTCACTTCTGTGTGTTAAATACCCCCAAATTGTATAAGTCTATAAAATTATTATTTT
->HM490822.1 Uncultured Thermovirga sp. clone GE7GXPU01D8TM1 16S ribosomal RNA gene, partial sequence 
-GTACGTGTTACTGATCTGAGAGGACGAGGGACCCATGCTTCGGTATGGGAGCGTACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTGCATCCAGTTGCCATCGGGCGAGCCGGGCACTCTGGAGGGACTGCCGGCGACAAGCCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTATGTCCAGGGCGACACACGTGCTACAATGGCCGGCACAGCGGGAAGCGGAGGGGCGACCCTGAAGCGGATCCCTTGAAAGCCGGTCCCAGTTCGGATTGCAGTCTGCAACTCGACTGCATGAAGTTGGAATCGCTAGTAATCGCGGATCAGCCAAGCCGCGGTGAATACGTTCCCGGGCCTT
->XR_005682382.1 PREDICTED: Panicum virgatum uncharacterized LOC120691804 (LOC120691804), transcript variant X1, ncRNA 
-TCCCTCTTGCCGGCGGCCTCGCCGACGTTTGCCGGCACGCTCGAGGTCGATCCGCTCATGGTTGCGGGCTCCTCTGTTGCCGCTAGGCGTACTCGTTCCTACCTTCGTTGCTGCAACCACGCCCTCCCAGTTGGACCTACGGAACCTTTGTTGCGGCATCCATCCCCTCCTAGATACAGTCCTCGGATTCTGATGCTCCCGCTAGCAAGGTTGCTCTTGCTTCTGTTGGTCAATCGTGCAACTGGTGGAAGGAGGACCACGGTTCTCCATGCTGTGGTGTAGATTAGGCGCTAGGTGCTTGATGTCACTGAAGAGAAAGAAGTAGAGGAGCTTATGTTCTTATGTTCGCTTTGGTGGCCAGTTGCTTATAATTTATTTGATACGGCGGCTTAGGATTATAGTCTTATGTAACCGTGAAAATTGTCTTTGGCAAATTTACTAAGTAGTTCAGAAGACTCACTTTGTATTGTATTGTATTTTAATAATTTATTGTTGTTGTGATCAATCAATATAAATTTGCAATGATATATATA
->JN143486.1 Uncultured eukaryote clone KYD009 18S ribosomal RNA gene, partial sequence 
-AGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGAAAACTCACCCGGCCCGGACACTGTAAGGATTGACAGACTGAGAGCTCTTTCTTAATTCGGTGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGCGATTTGTCTGGTTAATTCCGATAACGAACGAGACTCTGGCCTATTAAATAGACGGTGTATCTTGAAGTATACCGCGCTTCTTAGAGGGACAAGCGGCGTCTAGCCGCATGAAATAGAGCAATAACAGGTCTGTGATGCCCTTAGATGTCCGGGGCTGCACGCGCGCTACACTGAAAGAATCAGCGTGCGATTAGCCTGGTTCGGAAGAATCGGGTAACCCAAGTAAATTCTTTCGTGCTTGGGATAGGGAATTGCAATTATTTCCCTTAAACGAGGAATTCCCAGTAAATGCGGGTCATAAGCTCGCGTTGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTACTACCGATTGGATGACTCAGTGT
->XM_052629031.1 PREDICTED: Gossypium raimondii plasmodesmata-located protein 6 (LOC105780626), transcript variant X2, mRNA 
-TCTCTCATTTACACTCTTCTTTTCTATATATTCTCTTTTAAACCTTTTTTTGTTTTCTCAATATCTTCACTTATGGCTTTAGCGGCGAAACAATTATCGTCACCTTTTGTTATTTTTCTCATATTATCAATTTTCTTAGTTGGGCCATCGTTTTCCGGCACCGATACTTTCGTTTTCGGCGGCTGTTCGCAGCTGAAATTCACTTCAGGCTCACAGTACGAGTACAACGTCAACTCGATACTCACTTCCCTAGTCAACTCAGCCATGTTCACTTCTTACGACAACTTCACCATGTCAGCTTCCGGTGGTTGCAGTGCCGTTTACGGGCTGTTCCAATGCCGTGGTGACCTAAACAACCGTGACTGTAACCGTTGTGTAGCTAAAGCGGTGAGTCAAATTGGAACTCTTTGCTTTTACTCAACGGGTGGTGTGTTGCAACTCGAAGGGTGTTTAGTTAAATACGATAATGTAACTTTTTTGGGTGTGGAAGATAAGACCGTGGTAGTGAAGAAATGTGGACCGTCGTTCTCGTCTTACTCGGACGCTTTGACTCGGCGTGACTCGGTGCTGAGTTACTTGGAAGCGAGTGATGGGACGTATAAGCCGTTTCGGATCAGCGAGTCGGGGAATTTACAGGGTGTGGCTCAGTGTGTTGGTGATTTGAGTCCGAGTGAGTGCCAAGATTGCCTATCGGAGGCAATCGGACAGCTGAAAACTGAGTGTGGGGCAGCAAAATGGGGTGATTTGTATTTGGCTAAGTGCTACGTGCGGTTCTCGGAAGGTGGATACCACTCGCATGCCGGAAAGAGTAGCTAAATAAACAAAGGAAACTGACAATTGTTGTGAGGAATCCAAAAGAAAACCCTTTGCATTTGGTCTTCATTTCTTTTATCTGTTTATATTTAGACAACTATTGTACTGTCCGGGCGAGAAAATTTA
->HQ761033.1 Uncultured organism clone ELU0047-T268-S-NIPCRAMgANa_000215 small subunit ribosomal RNA gene, partial sequence 
-AGNGAAAGGCGCTTTCGGGTGTCGCTGATGGATGGACCCGCGGTGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCCACGATGCATAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGACGAAAGTCTGACCGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAACTCTGTTGTTAGAGAAGAACAAGGACGTTAGTAACTGAACGTCCCCTGACGGTATCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGCGAGCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAGGGTCATTGGAAACTGGGAGACTTGAGTGCAGAAGAGGAGAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAGGAACACCAGTGGCGAAGGCGGCTCTCTGGTCTGTAACTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTGGAGGGTTTCCGCCCTTCAGTGCTGCAGCAAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCTTTGACCACTCTAGAGATAGAGCTTTCCCTTCGGGGACAAAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATTGTTAGTTGCCATCATTTAGTTGGGCACTCTAGCGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGGAAGTACAACGAGTCGCTAGACCGCGAGGTCATGCAAATCTCTTAAAGCTTCTCTCAGTTCGGATTGCAGGCTGCAACTCGCCTGCATGAAGCCGGAATCGCTAGTAATCGCGGATCAGCACGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAGAGTTTGTAACACCCGAAGTCGGTGAGGTAACCTTTTTGGAGCCAGCCGCCTAAGGTGGGATAGATGATTGG
->XM_033535937.1 Aplosporella prunicola CBS 121167 uncharacterized protein (K452DRAFT_19523), mRNA 
-CTGGGGCGGCGGAAGAGGGCAGAACTCCGAAACACTCACTACACCCACGTCGGGTAGCTCGTCGCCAAGGTGGTACTCTACTCTAGCTGTGTTCCGCCATCCGGAGGCCTACACGTAAGGTCCATGTCGTGCAATTGGACTAGAGACGCACTCGTCTCCCACGCAATTCTGTCGTGCAGATGTACGGTTACTTCGTACTTTTGACAGATGCCTCGTCCGTCGTCCATCGTCCATCTGCATTTATGGTCGACGTTTCTCTCCAACCATGAATGCATGCTCGTATCTACTTCCCTAAGTAACATCGAGCGCATACAACCAAGACAACAAGGCCGACTGTGGGCTGCAATCCTCAGGGGACCAAAAAATTTCTGGTGCCACTACTGCACATACACGCGTTCTACGGTTAGCGTCAAGTATGCAAGCCACGAGAGTACAACAAGGGATGGGCTACAGCTTGGAACGGCCAGCCATTGGTCGCACACGCTAGCATACACTTTTATCTGGCTCCTCTGCTGGATAATCGCATTCCGCCGCCGTTTCGTGCTTCGCAGGCATGCCCATGCTCTGTCTCCATGCTGCATCTCAAATCCAGCGTATCGTGCATGTTTTGGTGCTTTGATGCAGGTCCATGACGTCACCGGCAAGGCATCGACAACGCATTGTCTGCACCGGGCAGATCAGAGTCCCTCTCATGCCCCATAATCCGTAGCGGTGCATTTATCCATGGATTCCTTGTCTTATACCGACCCGGCGTTAGCAGACGTTAACTCGTTCTGACTCGATCTC
->XM_008727620.1 Cladophialophora carrionii CBS 160.54 hypothetical protein partial mRNA 
-ATGTCTGAACAGTCCAGCGAACCGCGAATAAAGTCGCACAAGAGGAACGTCGCCCACCGTCGACGCCGGGATGACGACGATTTCGAGGACCGGTGGGGCGATGAAGAGGTTGCCGAGGACGACGACGCAGATGGACACGCGCAGGCTGAATTCCCAGAGTCGTCGTCCAAACGGGTGAAATTGTCTGATGGCTCGGCATCGCATCGGGCGAAGAATTCCACACCCACCCCTCCACCAGAAACGGAAGAGGAGAAAGCACAAAGGGACCGAAAGGAGCGAGACGAATTCGCGAAGCGGTTGGCAAAGAAGGACGAAGAGCGGGCGAAGAAGATCGTGGAAGACAGGTCCGCTGCAAAGGACAGTGCGACGGCGCAGCGGCGGGCATTGGCAGACGATGCGTCCGCGAGAGACGCTGCGATGCCGGATTTGAGGCTTCGGTCCCGTCAGGACTACCTTAAGAAGCGGGAAGCCGAGAGGTTGGCTCTGCTGCGCAAACAGGTCGCTGAGGAGCAGCAGGAGTTGAGGGACAACCCGGACCTGACGCGGCGGGAGAAGGAGGAATTCGCGCGCAACAAGGAGATCCTGCGCATCGCGGAGGAGAGGCTGGCCATTGACGATCACTTGGACGGCTATGCCTTGCCGGAAGACTACATTACCGAGAAAGGGAAAATCGACAAGCGGAAGAAGGAACAAGCACTCTACCAACGTTATGTCGATCGCGACGAGGCCGGCCGAGAACGCTATGTCACCGAGCACGAAGAGTGGGAGAGAGAGCAAACCAAGCGAGCCGAGGCCCAGATCAAGAAGTCCGAATTCGTAGACGAAGGCGACTACGGCTACGTGTTCGACGAAAGCCAGCAAATGAAGTTCATCCTGGCGGACAAGCTGGAGGGGGACAAGGGGATGACCAAGGAGCGCAGAGAAATGGAACAGCGGCTCAACGCGGCAGAAGCAAAAGCCAAGAGCATCGAGGAGACGAGGAAGAGTCTACCCATTTACCAATTCCGAGACGAGATCATCCAAGCCGTGAAAGACCATCAGGTCTTGATCATCGTAGGCGAAACTGGCAGCGGGAAGACCACTCAATTGCCACAGTACTTGCACGAAGCGGGTTTCACAAAAGGTGGCATGAAGATCGGATGTACTCAACCGCGAAGGGTTGCTGCCATGTCCGTTGCAGCCAGAGTAGCAGAAGAGATGGGCAAGCGGCTAGGGAACGAAGTGGGCTACGCCATCCGCTTCGAAGACAACACCAGCGAGAAGACGGTCCTCAAGTACATGACCGACGGCATGCTGCTGCGAGAACTGCTCACCGACCCGGAACTCTCTCAATATTCGGCCCTCATGATCGATGAGGCTCACGAACGCACCGTCTCCACCGACATCGCGTGCGGCCTGCTCAAGGACATCGCCCGCGCCAGACCAGACCTCAAGCTCCTGATATCCTCTGCAACCATGGATGCCCGCAAATTCCAGAAGTACTTTGACGACGCACCCATCTTCAACATCCCGGGAAGAAGATACGCGGTCGACGTGCATTACACGGCCCAACCGGAGGCGAATTACCTGGCCGCGGCGATCACGACGGTGTTCCAGATCCACATCACGCAAGGACCAGGCGACATCCTCGTGTTCCTGACGGGCCAAGAGGAGATCGAAGCCATGGAAGCAAGCCTGCAAGAGACGGCGCGCAAACTAGGCAGCAAGGTCAAAGAGATGATCATCTGTCCCATTTACGCCAACCTCCCAACCGACCTGCAGGCCAAGATCTTCGAGCCGACGCCCGCCGGCGCCAGGAAGGTCGTCCTCGCCACCAACATTGCAGAGACGTCCCTGACCATCGACGGCATCGTCTACGTCATCGACCCCGGCTTTGTCAAGGAGAACCAGTACAACCCACGCACAGGGATGGAATCCCTCGTCGTGGTGCCGTGCTCACGCGCCTCGGCGGGCCAACGAGCGGGGCGCGCGGGTCGCGTCGGCCCAGGCAAGTGCTTCCGCCTGTACACGTCGCAGGCGTACAAGAACGAACTGGACGAGAACACGACGCCGGAGATCCAGCGGACCAACCTGTCGGGGGTGATCCTACTGCTCAAGTCGCTGGGCATCAACGACCTGCTCGACTTTGACTTTATGGACCCGCCGTCGACGGACACGATCGTGCGCGCCGTGGAACAGCTGTACGCGCTCGGCGCGCTCAACAACGCCGGGGAACTGACCAAGATCGGGCGGCAGATGGCCGAGTTCCCGACGGACCCGATGCTGGCGCGCGCCATCCTCGCGGCGGACAAGTACGGGTGCGTGGACGAGGTGCTGTCCATCATCGCCATGCTGGGCGAGGCGTCGGCGCTGTTCTTCCGGCCCAAGGACAAGAAGATCCACGCCGACAGCGCGCGCGCGCGCTTCACCAACAAGGACGGCGGCGACCACCTGTCGCTGCTGAACATCTTCCACGAGTGGGTCGACAGCGACTACAGCTTCGTGTGGGCCAAGGAGAACTTCCTGCAGCAGCGCAGCCTGACGCGCGCGCGCGACGTGCGCGACCAACTCGCCCGGCTGTGCGACCGCGTCGAGGTCGACGCTGCCAAGTCGTGCGGCGGGGCCAGCAACATCGAGCCCATCCAGAAGGCCATCACGGCCGGGTTCTTCCCTCACTCGGCGCGGCTCCAGCGCGACGGGCAGAGCTATCGCACCGTCAAGAACGGGCAGGTCGTCTACATCCACCCGTCGGGCGTGCTGATCGAGACGCGGCCGAAATGGGTCATCTACCACGAATTGGTGCTCACGAGCAAAGAGTACATGCGCAGTTGCATGCCGTTGAAGCCCGAGTGGCTCATCGAGGTGGCACCGCATTACTACAAAAAGAAGGATCTGGAGAGCCTGGGCGTGGAGCGGAAGGTGCCGAGAGGAGAGGGTAAAGGGCAGAGTAAGATTTGA
->HF913007.1 Uncultured Anaerolineaceae bacterium partial 16S rRNA gene, clone 4_45 
-GATGAACGCTGGCGGCGTGCTTAATACATGCAAGTCGAACGAAGATGTTCTTGAGTTTACTCGAGAGCTCTTAGTGGCGGACGGGTGAGTAACGCGTTGGTGACCTGCCCTAAAGAAGGGAACAACCTCGGGAAACTGAGGCTAATACCCTATGTGCTTATTTAGATTAGATGCTTTATAAGTAAAGGTTCTGTGGACGAAAGGCCACGGTGCCACTTTAGGAGGGGCCTGCGTACCATCAGCTAGTTGGTAGGGTAATGGCCTACCAAGGCAAAGACGGGTAGGGGACCTGAGAGGGTGGCCCCCCACAATGGAACTGAAACACGGTCCATACACCTACGGGTGGCAGCAGTAGGGAATATTGCACCATGGGCGAAAGCCTGATGCAGCAACGCCGCGTGAGTGATGAAGGCCTTCGGGTCGTAAAACTCTTTTCAAGGGGAAGAGGAAGGACG
->XM_035019610.1 PREDICTED: Mirounga leonina family with sequence similarity 43 member B (FAM43B), mRNA 
-CCTACTCCTTAACTGCCCCTCCATCCCCACCCCTCCAATAAGAATGATTAATCCCGTTCCACCGCGCCTGTGCCGGGTCCCGGGCGAAGAGCAGCGCTAGCCGGCGCGGGGGAGGAGAGAGAGGAGAGCGAGGGGAGGGGACAAGAGAGCTAGCGGTCCCGCCCGGTGATGTAGGCAGCCCGGGGAGGTGGAGCCGCGACGCCTGAAGGAGTCCCCACCGCAGTCTCGCGCTCTCGGTCTACCCCTCCGAGCGGCCAGCCGCCAACCCCAGCTCCGGCGACCTCCCTGCCGCCGCAATTTGGGCGGCGGGGACTGCGGGATCCCCCCCCCCAGTTCGGGCCCGGGGGGCCCCTCCACCACGCCCAGCCCCCCTCCCCTCCTCGCTTCCCGGACGGCTGGAGCTACTCCCGGGGGAAGCTGTTCCCGGACGCTCGGCCGCCGCCCCGGCATCTCGGCTGCCAGCCCGGCCGGGCACCGGGCATCTCCGGGCACCGACTGGCTCCGGCGCCGCCCAGCTGCTCGCGACCCCGGGGCCGCGGGCTTCTGCTCGCCCTCCCCTCCCCCGGCCGCCGGCCAGGACGCCCGTGAGCTCCCGGTGCCCCCAGCCCCTCTGGCCGCCGCCGCCGCGATGCTGCCCTGGAGACGCAACAAATTCGTGCTGGTGGAGGACGAGGCCAAGTGCAAGGCGAAGAGCCTGAGTCCGGGACTCGCCTACACGTCGCTACTCTCCAGCTTCCTGCGCTCCTGTCCGGACCTGCTGCCCGACTGGCCGCTGGAGCGCCTGGGCCGCGTGTTTCGCAGCCGGCGCCAGAAAGTGGAGCTCAACAAGGAGGACCCGACCTACACCGTGTGGTACCTGGGCAACGCCGTCACCCTGCACGCCAAGGGCGACGGCTGCACCGACGACGCCGTGGGCAAGATCTGGGCGCGCTGCGGGCCGGGCGGGGGCACCAAGATGAAGCTGACGCTGGGGCCGCACGGCATCCGCATGCAGCCGTGCGAGCGCGGCGCCTCGGGGGGCTCGGGGGGCTCGGGGGGCCGCCGGCCGGCGCACGCCTACCTGCTGCCGCGCATCACCTACTGCACCGCGGACGGGCGCCACCCGCGCGTCTTCGCCTGGGTCTACCGCCACCAGGCGCGCCACAAGGCCGTGGTGCTGCGCTGCCACGCCGTGCTGCTGGCGCGGGCGCACAAGGCGCGCGCCCTGGCCCGCCTGCTCCGCCAGACCGCGCTGGCGGCCTTCAGCGACTTCAAGCGCCTGCAGCGCCAGAGCGACGCTCGCCACGTGCGCCAGCAGCACCTCCGCGCCGGGGGCGCCGCCGCCTCGGTGCCCCGCGCCCCGCTGCGCCGGCTGCTCAACGCCAAGTGCGCCTACCGGCCGCCGGCCGCCGAGCGCGGCCGTGGGGCGCCGCGCCTCAGCAGCATCCAGGAGGAGGACGAGGAGGAGGACGCGGACGCGGAGGAGCGCGAGCGGCCCGAGGTGCTCAGCCTGGCCCGGGAGCTGAGGACGTGCAGCCTGCGGGGCGCCCCGGCGCCGCCGCCGCCCGCGCAGCCCCGCCGCTGGAAGGCCGGCCCCAGGGAGCGGGCGGGCCAGGCGCGCTGAGAGCGCGGCGGGGGGGGGGTGCGGGGGGAGGGGCGCGGGCCTCGCGGCCCCAGCCCCCCGCCGGCCTGACTTCCAGCCTCCAACCCTGGCCCTGCCCGCTTCGGCTCCCCTCTGGTCCCCCGGCCCTTGCCTCCCTCGTGGTCTCTGTTGTTGTCTGCCCCGCGTCTCATCCTGGCTCAGGGTGACGCCTGATACGCCCTTGATTATTGGGGGACAAAGGGGAGGAGAGCAGCAGAAGTACTCGATGTTCGCCTCTCCCCCACATCCGGAGTTGCTGAGCGCCCTCCATCGTGGAATTGCTCGTAAGCTTTACAACAGGTCTTTGCCCATAGACCACCCTCTCCCTCCCAGAACAACCCCTCCAAAGAAGGGGGAAGAAGTTTCCAGAAATCCAGGAGGGTGGCCCTGGACGTTGGCCAGGTGGAAGCCGTGGTCCTGCCCTTGGCCAGTCAAGCCTTCCTCCCTGGGATGGGACCAGTTCTGGGCAGGCATGCTTGCAGAGAAAGAATAGTGGCCCGGGAGACCGGAGGCCAGGTCCAAGGTGGGAAGTGAGTCGGCTGCCATATACACAAGGAAGGATTCTCAGGCCCTGTGCCTGGCCTCTCTACCCCTTGGAGGATTTCTGGACTTCACTGCTCCATCTCCGGAGAAGACTGGGCTGGTCCTACCAACCCAAACAACAGGTTAGAGCAGGTAACAGCCCTCTGCTCTGGGCAGCTGCCCAAGAGTATGCCCTGGCACCTGGCACCCCCACAAGACTCCACCCACCCCACATCTCTGCAGACAGATGTGTGGGGTTCCCCACTAGGTGCCTCCAACTAGGACCAAGATGGGGTCTCCAAAGGAGGTAAGGAGAACCTTTGGCAGGTGCTTGAGGACACTGACCACCCAGAAAGTGGACACAGGAGGGATGCCCTCCCGTCCCCTCCCGCCCCCTGAGTCGGGGCTTGTCAGAGCAGGAGGGTCCTGACAGCAGTTGGGTTCTCATAGCCGGCTGAGGAAGGAGAGTGTGTTCACCCAGCAGAGGGAGTGGGCCCCCTGCCCAGGTGTCCCAACAAGGCCACAAAAAGCCCAAAGATCTATGTGTCACCAACTGATCGTTGTAAATAAAGTGGACCTGCTTTTTCA
->MN887529.1 Glyphodes pyloalis putative family 31 glucosidase KIAA1161 protein mRNA, complete cds 
-GGGGGGGGGGGCAGTAGGTGTGTGAGACAAGATGAAGCTGATACTTCTGTTGGCAGGCGTGTCGGTCGCGCTGGGCGGTATTGCGCGCGCGCCGACCAAGCGTGACTTCTTCGTCGACCAGCGGGAAGATGGCGGCCTCGACTTCATCGTGGTGTCCAGCGAGAAGGGTACACTGACCCTCGGGCACATCGGCCGCAAGGTGGCCGCAGACGACCCTGAGGTGACCTTCGACATGGATGCGCAGCTCGATGAGGCCAGCGGCGGCTGGAAGGTCACCATCAGCTGGGAAGGGCCCAGCGACAGAGTCTTCGAGGACTGCTTTGGCTTCAGAGGCAAAGAATGGTACGGAGGTCCCGAGCAGAAGGAGCAGTACTGGCCGATTCAGCACGGGAAGCTGGAGAAGTACTCCATCATCTCTAAGGAGGACGACAACGCCGCCGTCTCCGAGAGATACTGGCTCAACTCCGCCGGCTACTACTTCTACGTACACCCAGAGGCTCCCCTCTTCGTCGACTACCACAACACCAAGAACGATAACATCTGCTTCATCGCTGAAGTCGCCGCACCTTACTCCACCAAGCGTACACACAACGTTCTCAAATACGACATCTGGTTCTTTGACAACGCCAAGGTCGCCCACCAGCACGCCGTTGACACTTACCTGGGAAAGCCATCTGGCATTCCAGACTACAGAATGATCCAATACCCAATCTGGAACACTTGGGCGAGGTACTCCCGCGGAATCGACGAGGATCTTCTATGGGAATTCGCGAATGAAATCGCGGACAGTGGATTCCCTAACTCTCACTTTGAAATCGATGACCAATGGGAGGTGTGCTATGGATCTCTGACCGTCGATGAGGGCAAGCTCCCCAACTTGAAGCAGTTGGTTCAGAAAATCAAAGGACTTGGATTTAGAGTCGGCATGTGGGTGCATCCCTTCATTAACCAGGATTGTGAGCCTTGGTATTCTGAAGCTTTAGAAAATGGTTACTTGGTACTGAATGAAGAAGGAAATCCAGAAACCAGCTGGTGGAACAACAATGGCTCCATCCCTGCCTACGTTGACTTTACCAACCCTGAAGCCAAGAACTGGTACACCTCGCGAATCCAGAACCTCATTGACACTTACGCTTTGGACACTCTCAAGTTTGACGCTGGAGAATCGAGCTGGTCTCCTCAGATCCCAGTCCAGAATGGTGACATCGACCTTCATCCGGGACACATCGTGCAGGAATACGTGCGCGCAGTTGTCCAGTTTGGAGACATGATCGAAATTAGGTCTGGAATAAGAACCCAGGATCTGCCTGTGTTCATCCGTATGGTCGACAAAGACACCTACTGGGGCTTCAACAACGGCCTGGCGACATTGGTCACTACTCTGCTCGCAATGAACCTGAACGGCTACACGCTGGTCCTGCCCGACATGATCGGCGGCAACGGGTACAACGACAAACCAGAAAAGGAGCTGTTCATCCGCTGGCTTCAGGCCAACGTGTTCATGCCTAGCCTGCAGTACTCCTTCGTGCCGTGGGATCATGATGATGAGACCGTTGAGATCAGTCGCAAATACACGACTTTGCACGCGGAGTACGCCGACACCATCGTGGCTGCCATGGAAGCCTCCGTGAGGGACGGCACTCCTGTCAACCCTCCCATCTGGTGGTTGGACCCAACCGACGAAGACGCTCTAGCAGTTTGGGATGAATTCCTCCTCGGTGAGAAGATCCTAGCAGCGCCGGTGCTCGAAGAAGGCGCGGTGTCCAGGGACATCTACCTACCCACAGGCTCTTGGCGCGACGGCGTGACAGGCGAGTTGGTGCAGGGCCCAGTCTGGCTCATCGACTACTCCGCCCCCCTCGACACGCTGCCCTACTTCACCCTGGAAGATTAAGTCGAGACCTTCAGAAGGGTCTTGGGAGTTCCTAATTGATAAGTTTTAAAATAAAGTTGTTGTTTTCAAAAAAAAAAAAAAAAAAAA
->JX367473.1 Uncultured fungus clone 035A13021 18S ribosomal RNA gene, partial sequence; internal transcribed spacer 1, complete sequence; and 5.8S ribosomal RNA gene, partial sequence 
-AAAAAACGCTTGGTCATTTAGAGGAAGTAAGAGTCGTAACAAGGTCTCCGTAGGTGAACCTGCGGAGGGATCATTACACAATAAAATATGAAGGCCTGGCTTCGCGGCCGGCTGAAATATTTTTTCACCCATGTCTTTTGCGCACTTGTTGTTTCCTGGGCGGGTTCGCCCGCCACCAGGACCAAACCATAAACCTTTTTCTTATGCAGTTTCCATCAGCGTCAGTAAAAACAATGTAATAATTACAACTTTCAACAACGGATCTCTTGGTTCTGGCATCGATGAAGAACGCAGCGAAATGCGATACGTAGTGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACNCACATTGCGCCCTTTGGTATTCCAAAGGGCATGCCTGTTCGAGCGTCATTTGTACCTTCAAGTCTTTTGCTTTGGTGTTTGGGTCGTTTTTTGT
->XR_006640209.1 PREDICTED: Bubalus bubalis uncharacterized LOC123465122 (LOC123465122), ncRNA 
-GCCGAGAGAGTAGGTCGTCAGGCGGCCCTTGAGTTTTTTTCTCTTAGTGTAAACGTGTGCTGCGCGCTTAGCCGTCCAACCGGCTCTCGCCACGCCCATCTTCAGGGTCCCGCTGGTTCGGTCGACAGCCCGGTTTCCGGAGAAGCCGCGTCCTCTCCCCGGTCCTGGGATTCTGGAGAGCCCGGCCGGCCCCCGAGACCCCCTTTCTCCCACCCTCTGCCCTCGCGTCTCCTCAGGCCAATCGTTCTGTCCCGCAGGCCTCCCTTCCTGGGATGGTTAACCTTCAAGGATGTGGTGATCGAATTCTCTCAGGAGAAGTGGGAATGCCTGGACCCTGTTCAGAGGGCCTTGTACAGGGACATGATGCTGGAGACCTAGAAGAACCTGCTCTCCCTGGATCTATCTATCTGATACATGTGGTCAACCAATTACAACCCAAAGCAGACAGTGATACAGGAGAAGTATTCCAAACAGCAATCTTGGGAAGACCTAAAAGTCATGAAATCAAACATTTTTACCTCAGAGAACTCCAGGAAGACATGTATGACTTTGAGTATCATTGGAGAAGTGGTGGAAGAAATAACAAAGGAACGCGTATAACTCATGACAGAAATCTCACTGATGGCAGAGGTCAACAATGTAGAAAGGATGTGGAAATCAAGCCCTTTGTAAATAGGCTTGGATTTAACATGCAGGATAAACTTCAGATATTTCAAACTGACGGGATAATTTCTGAATGTAATAAAGTTACAAGGTAGTCAACAGTAGTTT
->XM_023049778.1 PREDICTED: Onthophagus taurus uncharacterized LOC111417487 (LOC111417487), mRNA 
-TTTAAGTTTTTTAATAAATAATTTTTAATAACAACTTTTTAGCAACAAAAATTAAAAAATGTGTACACCCGAACCGCTTCAACTAAATACAACAAAAGGAAAATGTTCAATCTCACCTTTCACATGCATTTTAAAGTTTTTGATACGTTCGTTGGAATGTCCGGAAAGTGAAAAGTTTATTTCACGTTTTGAGGATCAATTAAATCAATTGATTGCTGTTGGAGGTGTTAATGTTTCCGTTCGCGAATTAGCTGATTTAATAAAACTAATTTCTTTAACGTTTCAAAGAATCGATGAAAAACCTGCTTATTTAGAAGCTTTTTATAAATTATTAAATTTTAGTTCGCAAAATTTGGTATTTTTGATAACCAGCGACATGATAAGTTATGCTGAAATTATACAAGATTTTTTCAACATGCTGGGTTATTTACTGGGTAGTACAGAAAATCTGGATTGCATTCAACACATTTTAAACAGCATATTAAAAATGATTGCAATGGCAAAGAAAAAACCTTATTTACAATCAAAAGTACTTTTAGACGCTTTTGCAAATAGTCAAATACCACCGATTTTTAGCGAATTACTATACATATCTGAATTCGACGTTTACATCAAGTATTTAACAGTTTTAGAAAAATTCTTTGTATCGGAAAGCATCTGTCAAGCCTTTTTAAAATGTAAAGTTTTCGACACTGTCGTTCAAAGGGTTTGTTTAAAATGGAGAGATGAAATTAATTACCCAGATGAAGTTCTTCCAACTTTAGATTTACCACCACATTTAAATGTAACCCAAAGGATTCTTTGGACATTAACAATGATTTATAACGATAGCTCGACAACTTTTAAAAATAGTATTGGGTATTTAGTTGAAGGATCTTCTTTGAGAGGTCCTCGCAATGTTTTAATAACATTAATAACATCAAATAAAGATAAACACATGAGAAATATGTTTTATCTGCTTTTAAGAGCGATTGCTGGTACTGTGCCTTTTCGTCATTATAGAAGTTTAAATAATGAATTGCATATTTTAACGTTTACAACTGAAGTGGAACAATCTCATCCTTGGGCAAAAAGAATGGTGTTACGTGCAGATGATCTTGATTTTGAGTTTAAAATGATGCTGGTTTCAATGTTATGCATTAATAGAGTTTACCCACAAAGCTTAGATCTTTTTAGAAAAATGAATGCCGTTCAAGGAATTTTTACGTTAATCGATACAGATATACAATTAATTTGGTCGACTTATCAACGGTTAGAATTAATGAAAGGGGCATTAATTGGAATGGAAAATATGATTTTTCATGTCATCGATGATTATATTCACTACGGGGGACCTGGTAAATTATTAAAAGTTCTTACAAAAGTTGTTGAAGGTGAACTACATTCAACCCTTTTATTACCAATATTAAGATGTATTAATACATCCTTAAACGTTCCGAGTAATGTGCAAGAAAAGGTCGCTAAACTTTACAGAATGAAACATATCATTGAAATTTTAACAACTACAATTGAAAATGTAATTAATGCTGAATTCATAACAAAATTAAACTTAAGCTGTTTAGCTGTAAGTTATTGTATTTTGGAGAAAGTTGCGAAACCCAACGAACCAAAATTAACAGACGTAACAAAAACGGGAATTGCAATTTTAAAAAAATACTTAAATCCAGATCCTAGTATTTCTTTCTTAGCACCGAAAGTTCTCATTGCTGTGATGAGTTTTATATGGGAAAATGTAGTTTATTGTGAAAACGGGATACACGAATTCAGTTCTACAGGTGGCGTTTACGTCATCTTAGACATAATTGAGAAATTTCCTCTTGCCATTAAAGTTTTAGGTTTAAGCATGATAGCTGATTTTTGTCAAATTCAAGAATTTCTTTCATGCATTTTAACTTGGAAAGGTAAATCTGAACAAACGATTGTTCCATTTTTATTGGATATTTATAAAGATCAAGCTCGTTTTGATAAAGATCACACTGATATAAAATCAACACTTCAAGATTTAGAAAATCCAATTTTTGGTGATAAATACAACGAAATGAAAAAGAACTACATCAACAACGAATATGCAAGTTTCGCAACTTTGGATTTTTTAGGAAATTGTAAACCATCAATCTACGCAATTTTAACACTTTTAAGATGCGACGAAGACAAAGAGTTAATTAATAACACGTATAAAATATCAAAAGAAAATTTAACAAACAAAGAAAAAATTGTTGCTGCGTTAGCTGAAAATTATCTTCCATTATCGATAGGTGAATCTTGGATAGAAGTTAATCAACATTTTCAAACGAAAGGAGTACGCCCGTTAGTTTTCGATCAAATACTAATCGCTGCAAAGCTACAAGAACATCGTGAAAGAGCCAAATTAATTCAAATTGATCAATTGACATGTGAAATTTCTGAAAATAATCGCGAAATTTGTGTTGAACGGCAATTTTACGAACGTCTCCGAGAAGAAGTTCTCAACGAGTCTTTAGATGCATTAAACGAACTTCGATATTATACAAGATGCGTTGATACAATGGCTCGTTTAGAACAATGTACTCAACTTACTTTTGAAACTGAAAATGTGACCGCTGGTCGGCTTGATAAATCGATGTTGGTCGACTATCATAAAACTTTACCCGAATATATTAATATTACACCACATTTTAATCAACATGTCAGCATTCAAAGTAACGTCATTATTGATCCTAACAAAGAAAAAACTCCAGATGCAGTTTCTTTAGATAGCACCGAGCAAGGAATTATAGCTGCAAAAAAATTTGCTGATTTAATGCGTAAACGTGCTCCTAATCCTAATCCAACTTCTTATGATGTTACACGTTCGAAATATGCACGTTATTACAGTGTTGATTTTCATTAAT
->XM_020844603.2 PREDICTED: Dendrobium catenatum transcription termination factor MTEF1, chloroplastic (LOC110112391), mRNA 
-TATGCGGACAATGCTCAATGCCACTCACACTCACTATGCTCAGTTTCCACTCCCCTCTCGGTTCTCTCACTCACCCCAAACCTCTCCAAACGCTAAACCCTAATCCAGCCCTCCGATTTTTACCTCCGGTCGCTGGCACCACTTACATCTCCGGCAACGACGCGGGCTTGCGCTTCCGCGAAAAGCTTCTCTTCCTCGAACACGACCTTGGCGTCAATTCACTCCGCGCCCTTTCCCTCAACCCTAGCCTCCGCTCCGCTCCTCTCTCCTCTCTCAAATCGCTATCGTCCCTCCTCTCCTCCTTCGGCCTACTTCAATCCGATTCCTCTCGGGTCCTCTCCCTCCACCCCTCCCTCCTCACCGCCGATCCATCCGCCTCAATCCTCCCCGCCATCCACTTCCTTCTCGACACCGTATCCATCCCCTTCTTGGACCTTCGCCTCTCCATCAACCGCTGCCCTAGACTTCTCCTCTCCAGTGTCCCCGATCGCCTCCTGCCTTCCTTTAATTTCCTCCGTGGCCTCGGCTTTGTCGGTCGCCACCGCATCACCGCTCGTACTACTGTCCTTCTCATATCTGATGTTGAGGAGACGCTCATTCCCAAGCTTGATTTTGTCCAGAGCCTTGGGTTTTCTTATACGGATACTGTGAAATTGGTTTTGAGGATGCCTAGTCTGCTCACTTTTAGCGTTGAGAAGAATTTTCGGCCTAAGGTGGAGTTTTTAGTGGGGGAAATGGGGAGGGAAATTGTGGACTTGAAGGAGTTTCCGCAGTACTTTGCTTATAGTCTTGAGGGAAGGATTAAACCGCGACATACAATGATGGTAGAGAGAGGCTTTGGCTCCTCATCTATTTCACTTGGGGAGATGCTCAAGGCCAGTGATGGAGAGTTTCGAGAACGGCTACTAGAGATGCGGCTTAGTTCCGTGGGTGAGAAATTGTAGCTTGGTATGATGTGGGTTTCTTTTCCCCTTTCCAATTTTTTGAAGAAGTTGCATGCCTCCTAGATGCATACTTAGATTTGTAAATGTAAAATATTTGATGGGCCTGCCACATTAGTATTGTTGTAATAAGTACAATTCCCTGTATGTTATTATATTTTTAATTTTTGCTTATTTGGCTACCCAATA
->XM_026866306.1 PREDICTED: Athene cunicularia multiple EGF like domains 10 (MEGF10), transcript variant X1, mRNA 
-CAGGACTCTTTTGGGGCCTTTGGTGAATTTAAAGGATTTACACAGCAAGTAATAACATTATCACCTGCCATCTTTTTTTTGGAAAGATGTTTCTTCATTTGAATTTCTTTTTTGGCTTCCCTGTCATATTCCTGTACAACTGGATGGGGACAACTTTATCTTTGAATCTGGAAGATCCCAATGTGTGTAGCCATTGGGAAAGTTACTCAGTTACAGTGCAAGAGTCATATCCTCATCCTTTTGATCAAATTTACTACACCAGTTGTACTGACATCCTGAACTGGTTTAAGTGCACACGACACAGGATCAGTTACCGTACTGCCTACAGACATGGTGAAAAAACAATGTACAGACGTAAATCCCAGTGCTGCCCTGGTTTTTATGAAAGCAGGGAAATGTGTATCCCTCATTGTGCTGATAAATGTGTCCACGGTCGGTGTATTGCTCCAAACACCTGTCAGTGTGAGCCTGGCTGGGGAGGACCCAACTGCTCCAGTGCTTGTGACAGTGACCACTGGGGACCTCACTGCAGCAGCCGCTGCCAGTGCAAAAATGGAGCCTTGTGCAACCCCATCACTGGAGCCTGCCACTGTGCATCAGGTTTCAAAGGTTGGCGCTGTGAGGAGCACTGCGGTCAGGGGACGTATGGAAACGATTGCCATCAAAAATGCCAGTGTCAAAATGGAGCCACCTGCGACCATGTGACTGGAGAGTGTACATGTCCTCCTGGATACACTGGTGCCTTCTGCGAGGACCTTTGTCCCCCTGGGAAGCATGGGCCGCAGTGCGAGGAGAGATGCCCGTGCCAGAATGGAGGCGTCTGTCACCATGTCACCGGGGAGTGTGCCTGCCCACCAGGATGGATGGGCATGGTCTGTGGTCAGCCTTGTCCTGAGGGTCGTTATGGAAAAAACTGTTCCCAGGAGTGCCAGTGCCACAATGGAGGGACCTGTGACTCAGCGACAGGTCAATGCTATTGCAGCCCAGGTTACACAGGAGAACGATGCCAAGATGAATGTCCAGTGGGAACTTATGGAGTGCAGTGTGCTGAGACCTGCAAGTGTATGAATAGGGGGAAATGTTACCATATTAGTGGTGCCTGTCTCTGTGAACCAGGATACACTGGAGAGCACTGTGAAACAAGGCTTTGCCCTGAGGGAATTTATGGTCTCAAGTGTGATAAAAAGTGTCCCTGCCACATGCCCAATACCTGGAGCTGTCACCCTATGTCTGGGGAATGCTCCTGCAAGCCCGGCTGGTCTGGACTCTACTGCAATGAGACATGTTCTCCGGGATTCTACGGCAAGTCATGTCAGCAGATCTGCAGCTGCCAAAATGGTGCTGACTGTGATAGTGTGACTGGAAAATGCACCTGTGCCCCTGGATTTAAGGGTGCTGCTTGTGGTACCCCTTGTCTTCCGGGGACATACGGAGTAAACTGTTCGTCTGTGTGCAATTGCAAAAATGAAGCTATCTGTTCACCAGTAGATGGTTCTTGTGCCTGCAAAGCAGGTTGGCATGGTGTAGATTGCTCAGTAAATTGTCCCAGTGGTACCTGGGGACTTGGCTGTAACTTAACTTGCCAGTGTCTTAACGGAGGGGCTTGCAGTGCTCTGGATGGAACCTGTACCTGTGCCCCGGGCTGGAGAGGAGAAAAATGTGAACTCCCTTGCCAGGACGGCACTTATGGTATGGATTGTGCTGAGCGCTGTGACTGCAGCCATGCAGATGGTTGTCATCCCACCACAGGTTACTGTCGCTGTCTACCGGGATGGTCAGGCATTCACTGTGACAGTGTGTGTGCTGAGGGACAGTGGGGTCCAAATTGCTCATTGTCCTGTTACTGCAAAAATGGAGCATCCTGCTCTCCAGATGATGGAATCTGTGAGTGTGCACCAGGATACAGAGGCACCACTTGTCAGAGAATTTGTTCTCCTGGGTTTTATGGACACCGCTGCAGCCAGACATGCCCCCAGTGTGTACACAGTAGTGGTCCCTGCCACCATATTACTGGCTTATGTGACTGCTTACCTGGATTTACAGGAGCCCTCTGTAATGAAGTATGTCCCAGTGGCAGATTCGGCAAGAACTGCATTGGAATATGCACCTGCACCAATAATGGAACATGTAATCCTATTGATAGATCCTGTCAGTGTTACCCTGGCTGGATTGGTAGTGACTGCTCTCAGCCTTGCCCACCTTCCCACTGGGGACCAAACTGCATCCACACGTGCAACTGCCATAATGGAGCTTACTGCAGTGCCTATGATGGGGAGTGCAAATGTACCCCAGGATGGACTGGCCTGTATTGTACACAAAGATGTCCTCTAGGGTTTTATGGGAAGGACTGTGCATTGGTATGCCAATGTCAGAACGGAGCTGACTGCGACCACATCAGTGGGCAGTGCACGTGCCGCACAGGGTTCATGGGGAAGCACTGCCAGCAGAAGTGTCCTCAAGGTACGTATGGGTATGGATGTCGGCAGATATGTGACTGTCTGAACAACTCAACCTGTGACCACATCACGGGAACATGTTACTGCAGCCCAGGCTGGAAAGGTGCCAGGTGTGATCAAGCTGGTGTAATTATAGTGGGAAACTTGAACAGTTTAAGTCGTACCAGTACTGTCATCCCTGCTGACTCTTACCAGATAGGAGCTATAGCAGGCATCATCATTCTTGTCCTGGTTGTCCTTTTCCTGCTAGTGCTGTTCATCATTTACAGACATAAGCAGAAAGGAAAAGAAACAAATATGCCCTCAGTGACCTATACCCCCGCTATGAGGGTCATCAATGCAGATTATACCATTTCAGAAACCATCCCTCACAGTAATGGTGGAAATGCTAACAGTCACTATTTCTCTAACCCTAGTTATCATACTCTAACTCAATGTACTACCCCACCTCACGTCAACAACATCGACAGACTGACCCTAGCAAAGGCAAAAAACAATCAGCTGTTTGTGAACCTTAAAAATGTGCAATCTGGAAAACGAGGAACTGTCATGGACTACACAGGAACACTGCCTGCAGACTGGAAACATGGTGGCTACCTCAATGAGCTTGGTGCTTTTGGACTTGACAGGGGATATTTGGGAAAGTCCCTGAAAGATCTAGTGAAGAACTCTGAATACAATTTAAGTAATTGCTCATTAAGTAGTTCTGAGAACCCATACGCTACTATAAAAGACCCACCAACTCTTGTACCAAAAAGTTCTGAATGTGGATATGTTGAAATGAAGTCACCAGCACGCAGGGACTCTCCATATGCTGAGATTGCCAGCTCTTCTTCAGCCAGTAAAAATGTTTATGAAGTTGAACCTACAGTCAGCATTGTGCAGGGAGCATTCAGCAGCAGCGGACGTTTCAGCCAGGATCCTTATGATCTTCCAAAAAACAGCCATATTCCATGTCATTATGACTTGCTACCGGTTCGAGATAGCCCCACATCCTCTACAAAGGAGTTCAGCAGCGAATGACCCCAAAAGCTGATGTGTAGGACTCTGAAGGGGCAGAGTGGCATGGTTGTGCTCCTTCTTCTAATTCAGCATAATTTTTGGCTCTTAATCTGTCCAGCAAACAATTGCTGTACATTAAATAGAATCTCAACATGAGGTTTGTATTGTGTATACAAGTGACAGATGGGCAAATGCCACACTCTGGGGATCCTGATCATTCTTTTTTTCATGGCAGTAAATGTTACAGAAACAGGTATGCAACTCATTTATTCTATAATATACTGGCTTAAAAATACATTTGCAGATTAGTTTTGATAACATCCCATTTCATCTACTTTAAATATAGACTTCATATTTGTCATGTTTCAGCGTAGAAATACTCCCAGGACAGTGCAGTTTACCAAATACCACTTTGTACAGGTGATCTGATTCACTAGTTACGTAGAAGAAAAACTGCTTTGCCAAATTTTACCTTCCATTGTGATCTTTAGTCAAGACATACTAAGAAACAAGATTGGATGGGGATAAGTAAGCACAATACTGCAGTTGTTTGGGAAATCCATCAGGCTTTTTCGTCTACTACTGGCAGTGGGGTATCTTGCTTGAGTAGTTTTGGAGATAAAAGCATTGCATACATCAATATTATATGATGCCTCAAGATCTATTAGTACTCCAGACCCAGCACCAGTCTTCAGCAAATCTTTTGCTATGATTCAGCTCCATATGTTGCAGTTCTGACCACTATGTCTGCCATACGCAAGTAAAAATACATATCAGTAATTCAGAAATTATGTAAATGAAATCAGTCTTACTTTTATCACCATGGACTGATTATGTAAGGAGTGGACAAAGGTGATGACTGCTGTAAATCTTAACTGCAAGGAAAGGTTTACGTTTTATAAACAGATAGTAATAATGACTGTAATATAGAATAAAAATAGTAAAGTGTTCTGTTTTTTTTTCTTAGAAATAACTAATCAATCTCTGTGCATACTTGCTAAAAAGGCACCTTTTTTTATAATTGATGTCATGCTTAAGCTGGTCTTTTGCATTGCTAATAATGTGACACGTACTCCCCATTCTTCATTAACTTGTGTCTCCTTGTTGTGTCTGTGTTTCTAGTGATCTAGCTTGTAATTGCAAAAGTGTTCTACTTTGTGTCCATTTATTTTGCATTTTTGTCAGCTGGACTTTATTTATCTGGTTAAAGGGACCTCTGGGCAGAGGGAGAGGATTAAGATGTTTATCCAGAGGTAGTTAGCTAATCCATAATAGTTTAACTTAATGAATTGGTGAAAAAAATCAAGGTGTTTTTCTCAAGGATAATTAAAAGAATGCTGAAGGAAAGTGAAAAGCAGTCCCTCTTGAAAGTTTAGCTTATTCTGATGACTATATGGATGGACATCATCTTTCCAAAAGGCTCCCTTCTCTCCCTCCAAAAGAATCTGTTATGAACTGCATAATTCAGAGAAAATTAAATTTGCCAAGGTATCCATCTGTTGAAGCAAAATTGTCCCCCAAACACATCATCCTAA
->XM_053267654.1 PREDICTED: Hemicordylus capensis uncharacterized LOC128332879 (LOC128332879), mRNA 
-AAGGCTGGCTCTCACGTAGGCGCAAACAGCGGGGAAGGCCGAGCGGCGGGAAGGAGGAAGCGAGGCAAAGCATAAGCCCCAGGATGGGGAGAGAGGGGCAGCATCTGAGCCGCACCTGGGGACTTCCAGTAGGGAAGAACAAGAGGCGCCCCTGGCAGGCAGCAGCCCTCGCAGCCTCAATCCTGAGTTCTTGCTTTCTCCTGACTCAAGCCAAGAAGAGAGTGATCTCCAACATTCCTATCACATTGAGCCCATTAAATCCAGTTAGTGGGCAGAGGGTTGTCTTTGCACTTGGAGAGCTTGTGAGACGGAAGTCCATTTGCGAGTGGTACCGAGGGTCCAGTGACAAGGAGAACAAGATATTGGAATATGACTTTGGGTTGACCCAGTCCTCCTTTTCTGCCATACACAACACCCTCAAAGGCATTGACAGTTACATCAAGGGTGATGCTCATACTGGGCGGGAGAAGGTGTCCTCAAACTGCTCCCTTTATTTGGATCAATTACTGTTAAGTGACACTGGAACATACACAGTAGAAATGAAAAGATCTGGACAAGTTAAACAAAGAGGGCGTGTTTTCCTAGAAGTCTCAGATGTTCCTCCTGATTTGGGAGCGATTCTCCCCGATTCTCCCAAGGATGATGGTGACTATGATTATTTGCCGACTCCATCTTCCATGCTAGTTCCTGCTCTTGATATACAAGATCCTTCTCATTTAAAGCTACCTCTGGAGATCATTTGGAGGATCATTATTGGGTCTTTGGCTGTGACCACAGTCCTGGAGTTCCTACTTTACTTCCTTCTTCGTTCCTGTTATTGGAGGAACAGAAATTCTAACCGAATTATCTCAGCTACTCCAGGGTGTGGGATGATTCCCTCTTCTGCAAAGATGCTGAATCAACATGGAGACCCCGCTGTGCAGAGCAAGCTGTGA
->XM_046173440.1 Alternaria rosae uncharacterized protein (BKA58DRAFT_436843), partial mRNA 
-ATGCACGCTACTGCAGGCTCAATCTTAGGACCCACTAGCGCACACGGCCTGCCAATCACGCCAGCACTTGGCGGCCTCTCATCAGCGCACAAGCTCCAGCCCCGGGCGCCCCTTCCCTTCGACGCGATTGACGGCTCTTCTGACAACTCTCCCAAAAAGCAGTGCCACAACGGGAAGCCGGCTCCCAGACACCTCCAAGCACGCGCAACCCTCACCTCAGTCATTCGTTTCAGACAACAAACCAGCAAAGACAGCACACAGCAGCAACCTGCACCTAATACACCCCCCCGTACCATCACCGTCACATTCACCGTGCGCCAAGCAACGCTTCTCCCGGCACTTCCTCATCCGCAAACGCCTGCATCGCAAGAGCGACCGACTCTCGCCCACCTCGTTTCTGCCGTCCGTAATCGATTCCGGAGACCATTGCGCGCCCTTGCGAGGCTAATTGGCAGCTTCACTGGAACCAGCCTACCGGATCCAGCGATCGCGACGACGCTGAGCAAACCGCACCTGCCTCCCCGCCCACCGACATCCGCTCTCATGCCTATCGTGGCCACCCCTTCTTCATAA
->XM_010558636.1 PREDICTED: Tarenaya hassleriana carboxyl-terminal-processing peptidase 2, chloroplastic (LOC104826103), transcript variant X2, mRNA 
-AGAAAAACACAGCTGGAAATTTCTGGGGACGCGCTTTCATGGATGTCTCAGCGAGCTCCTCACTATCCCCAATTTTCACCAAGCATAATGACAATAGCAGGAGCCCTAATTTCTCTTCGAAGAACCCGGCATTCCAGGTGAAATCGTTTATTACATGCCAACCTCCAAAGTTTTTGGAAGTTGGCTTTACAAAACATGCAAGAAATGTCAGTATCAAGCCCAGGAGCCATGGAATCCTGAGAATCGTGGTCTTGCCCGAGTTTGCTCCAACCACAAGAAGCGAAAATCTGCGGAACAAATTTCTGCGTCTCGTCAAATGCAATTACCATAAGAACAGGCCTGGGGAAGTGGTCATGAATTGTTCCAACAAGTTCAGACAGAATGTCTCCCTTGCATTAGTTCGGCTTGTTTCTGTTCTGCTTGTCTCTTCCATCTCCGTTGTTCTCACTGAATCTCCATCCTGGGCTCTTACCGAAGAAAACCTTCTCTTCCTCGAGGCATGGAGAACGATTGATCGCGCTTATATCGACAAAACCTTCAACGGGCAGAGCTGGTTTCGTTACAGAGAGAATGCTCTGCGAAATGAACCAATGAACACGAGACAAGAGACATACATGGCTATTAAGAAGATGCTTGCCACATTGAACGATCCTTTCACCCGGTTTCTGGAGCCTGAAAAGTTCAAGAGTTTGCGGTCTGGAACACAAGGGGCGCTCACCGGTGTAGGGCTGTCGATAGGGTACCCTCCTGGATCGGGTGGATCACCAGCTGGCATTGTCGTTATATCAGCTGCTCCAGGAGGTCCTGCAAACAGAGCAGGGATTTCTCCCGGGGATGTTATCCTATCAATAGATAAGACTACAACAGAAAGCCTAACTATATACGACGCTGCAGGGATGTTGCAGGGACCTGACGGGAGCACGGTGGAGTTAACGATTCAGAGTGGACCCGAAACAAAAGTCTTGTCTTTGACGCGAGAGAAAGTATCAATGAATCCAGTGAAGTCAAGATTATGTGAAATTCCTGGTTCTGAGAAGAATGCCCCCAAGATCGGGTATATCAAACTAACATCATTCAACCAGAACGCTTCTGGTGCCATCAAGGAAGCAATTGAGACTCTAAGAAGCAACCACGTTAACGCATTCATATTGGATCTCCGAGACAATAGCGGTGGGCTTTTCCCAGAAGGAATCGAGATCGCCAAGATTTGGTTAGATAAGGGAGTGATCGTATACATTTGCGACAGTAGAGGCGTACGAGATATATACGACACAGATGGAAGCAATGCCTTAGCGGCTTCCGAGCCTTTAGCCGTCCTCGTTAACAAGGGAACGGCTAGTGCCAGCGAGATATTAGCCGGCGCCTTGAAGGATAACAAACGTGCCGTCGTGTTTGGGGAGCCGACCTACGGGAAAGGTAAGATACAGTCAGTGTTTCAGCTGTCAGATGGTTCTGGCCTGGCTGTGACTGTTGCTCGTTACGAAACCCCGGCCCACACTGATATCGACAAGGTCGGCGTAATTCCCGACCATCCGCTTCCTCGGTCTTTCCCGAAGGACGAGGATGCTTTCTGTGGCTGCCTCAAGGATCCCGGAGCTGAGTGTTATCTCAACCAAGGCCAGCTGTTTTCTAGATGATCATTCTTACTTCTCAAGGATGAGCATTCTTTGTTGAAGATTTTTCCTTACCTGTAATCCTTCAAAGATGTAGAGTTTAAGATACATGTATAAATATAAGAACCCATGACAATGGGAACCAGTTCAAGTCATTAAGACAGAACAGACCATGGATGGATTTCTAACTTCCTCTGTACTGTCTTGTTGTTTCAAGAAACAATTTCTCAAGTCTCAAA
->EF527335.1 Lepiotaceae sp. PA501 internal transcribed spacer 1, partial sequence; 5.8S ribosomal RNA gene, complete sequence; and internal transcribed spacer 2, partial sequence 
-GTAGGTGAACCTGCGGAAGGATCATTATTGAATACCACTCGATGGGTTGTAGCTGGCTCTTTGGAGTATGTGCACACCTGTCTTGATTCTATTCATCCACCTGTGCATTTTTTGTAGTCTTCTGAGGGTTGGATCAGTCGAAAGACTGGATAAGAAGAGGATTGCAAGCACGCAAGTGCAAGCTCTCTTCAGTAAACCAGCCTTTAGAGTCTATGTCTTTTTCATAAACGATGTATAAGAATGTGATCAAATGGGTCTTTGTACCTATATAAAATGTCATACAACTTTCAGCAACGGATCTCTTGGCTCTCGCATCGATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACCTTGCGCTCCTTGGTATTCCGAGGAGCATGCCTGTTTGAGTGTCAGTAATTTCTCAAACCCTTCTGGCTTTTTGTAGTCGGCTTGGGCTTGGATAGTGGAGGTTTTGCAGGCCCCCCCCCCCTGTGTCTGCTCCTCTGAAATGCATTAGCGGAACCTTGTTTGCGATCCGTCACTGGTGTGATAATTATCTACACCAAGTGGGTTGCTCTCTAGATGTTCAGCTTCCAATGGTCCCTCTGTGTGGGACAACTTTCTGACTTCTTGACCTCAAATCAGGTAGGACTACCCGCTGAACT
->XM_002141234.1 Cryptosporidium muris RN66 flavodoxin-like fold family protein, mRNA 
-ATGACTAGGAATGGGGTAACTGGTCCAGATGGTGCACATATATTGGTAATCTTGTCACATCCAGGGAAATCAATAGCAAATCAAGCAATAATTGATACTCTAGTTGAGAAGTTTGGCCAAAATATTCAGGTCAGACACTTGAATCAACTTTATCCAGACCAGAAGATAGATATAGAAGCTGAACAAAGAGCCTTAATTAGTGCAGAGCTTGTTATCTTGCAATTCCCAATGTATTGGTATAATATGCCTCCCTCATTAAAGAACTGGCTAGATTTGGTTCTCTCCTATGGATTTGCATATGGAACCTCGTATAAACTTGAGGATAAACTTCTCCTTGTATCTATTACCACAGGGGGTGAGGATAAAAAGTATGAAAAAAATACAGTAAATGACTATCTAATGTCTTTAGAATCAACATCAGAATTTATTAAGATGAAGTTTGCCGGTATACTAGCAGTTCATTCAATGCTATTAGTGCCAGGATTAGTGGGAGAGGAATCTGATATTAGGAAGAGAGCAAGTAACCATGCAAAACAAGTCGTCATCCCGAAAATTGAGAGTTTATTATCTAGATAG
->JN440197.1 Uncultured organism clone SBYB_3348 16S ribosomal RNA gene, partial sequence 
-AACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATGCAGGCGTTATCCGGATTTATTAGGTTTAAAGGGTGTTCAGGCTGTCTGGTAAGTCAGAGGTGAAAGTCGGTTGCTTAACGATCGAATTGCGCTTTGAAACTGTCAGACTTGAGTATGGATGTGGTAGNCGGAATGTGTAGTGTANCGGTGAAATGCATAGATATTACACAGAACTCCAATTGCGAAAGCAGCTTACCAAACCAGCACTGACGCTGAAGCACGAAAGCGTGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCACGCAGTAAACGATGCTCACTCGCTGTTGGCAATACACCGTCAGCGGCTAAGGGAAACCGATAAGTGAGCCACCTGGGGAGTACGATCGCAAGATTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAACATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCTGGGCTTAAATGTGAAGTGCATTGTTTGGAAACAGACATTTCCTTCGGGACTCTTTACAAGGTGCTGCATGGTTGTCGTCAGCTCGTGCCGTGAGGTGTCGGGTTAAGTCCCATAACGAGCGCAACCCCTATTGTTAGTTACCAGCGCGTCAAGGCGGGGACTCTAACGAGACTGCCGGTGTAAACCGCGAGGAAGGTGGGGATGACGTCAAATCAGCACGGCCCTTATGTCCAGGGCTACACACGTGTTACAATGGTCGGTACAGAGGGCAGCTAGGCAGCGATGTCAAGCGAATCTCGAAAGCCGATCCCAGTTCGGATTGGAGTCTGCAACCCGACTCCATGAAGGTGGAATCGCTAGTAATCGCGCATCAGCCATGGCGCGGTGAATACGTTCCCGGGCATTGTACACACCGCCCGTCAAGCCATGGAAGTCTGGGGTGCATGAAGGCCGTAACCGCAAGGAGCGGTCTAGGGTAAACAGATGACTG
->HQ302012.1 Uncultured bacterium clone E416QYJ01EWDEE 16S ribosomal RNA gene, partial sequence 
-ACGCTCGACACCTACGGGAGGAAGCAGTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGGAGGAAGAAGGTCTTCGGATTGTAAACTCCTGTTGTTGGGGAAAAAGAGGATGGTACCCAACAAGGAAGTGACGGCTAACTACGTGCCAGTAGCCGCGGTAATCTGAGCGGGCTGGCAAGGC
->XR_004686820.1 PREDICTED: Populus alba membrane-anchored ubiquitin-fold protein 3 (LOC118044643), transcript variant X2, misc_RNA 
-TGTGTTTCAGTTCACCAACAAAATAACAAACAAAACACCTACTCCCCCTCCTCCTCCACCTTCTTCACTACCAATCCAAGCCCGTCTCCTTTTTATCTTTTTCCCAAAAAAAAAAGGCAGACTGTTAATTATTTTGTCATCAAAATTTAAAGAAAAGAAAAAGGTGTCTTTTTTGATTGGGGAAACCGAGAGTGGAATATTAAACACGTTGTGGTAATTGGTTGGAGGAGGAGAAGGAAACAGGTCAAAAGTCAAATAGAAATGCCGGAGGAGGATTTGGTGGATATAAAGTTCAGGCTTTATGACGGGTCGGATATCGGACCGTTCCGGTACTCATCAACGTCTACTGTTGATATGCTTAAGCAGCGGATTGTTTCTGATTGGCCCAGAGGCAAAACAATAACTCCCAAGGCAGTGAATGAAATCAAGCTGATAAGCTCTGGTAAAGTCTTGGATAACAACAAGACTGTGGGTCAATGTAGAACACCTTTCGGAGAAGCGGCCGGGGGAGTTATCATAATGCATGTTGTTGTACAGCCATCTCTAGCAAAAACCAAAACAGAAAAGAAGATTGATAAATCTCCGAAGAAAATCGTGTGTTCGTGTTCCATAATGTGAAGGCAAAGTACGTAGAAATCTCGGGAATTGCACCCATGGTACCAACACTTTAGGTTACAGAAATACGGATTC
->XR_004968528.1 PREDICTED: Myotis myotis U6 spliceosomal RNA (LOC118659394), ncRNA 
-GTGCCCGCTTCGGCAGCACATAGACTAAAATTGGAACGATACAGAGATTAGCGTGGCCCCTGCGCAAGGATGACATGAAAATTCCTGAAGTGTTCCATATTTTT
->XM_034024519.2 PREDICTED: Acipenser ruthenus methionine aminopeptidase 2-like (LOC117414742), mRNA 
-GCGCTTCCTCTCTCGTTGTGTTTCCATCATGGCGGACATGGTGCGGCAACAGGAGCAAGAGAAAAAATCTGAGCAAGAGAAACACTTGAACGGGGAGATGGAACCCGAAGACAAGGAAGAGGCGGATACGACAGAGGAAGCAGCAAAGAAGAAGAAGAAAAAGAAGAAGAAAAACAAGTCTGCAGGAAATAATGAAAATGAGAGTAATGCCAATGCTGCTGGTGTTGACAAAGTGACAGATCAACTGGAGAAACAAGCCCTGGAAGACAAAGAGAAGGATGAGGAAGGAGAGGAAGATGGAGAGGAAGGAGAAAATTCAGCTGGGAAGAAAAAGAAGAAGAAAAAAAAGAAAAAGGGATCAAAGGTTCAAACTGATCCACCTTCAGTTCCAATCTGTGACCTCTACCCAAGTGGAGTCTTCACAAAGGGACAAGAATGCGAATATCCATCTACGCAAGACGGACGAAGTGCTGCCTGGCGCATGACCAATGAGGAAAAGAAAGTATTGGATAAAGCCAATGAAGAGGTTTGGAGTGATTTCAGACAAGCAGCTGAGGCTCATAGACAAGTCAGGAAGTACGTCTCAAGCTGGATCAAACCTGGAATGACCATGATTGAGATCTGTGAAAAGCTGGAAGACTGTTCCAGAAAACTGATCAAAGAGAATGGTTTACATGCAGGCCTGGCATTTCCAACTGGCTGTTCTCTGAATAACTGTGCTGCTCACTATACGCCCAATGCTGGAGACCCGACAGTTTTGCAGTATGATGATGTCTGTAAAATAGACTTCGGAACGCACATCAATGGTCGCATCATTGATTGTGCTTTTACTGTAACGTTCAATCCAAAGTATGATAAGCTTCTTGAAGCTGTGAAAGATGCCACCAATACTGGAATCAAGTGCGCTGGGATAGATGTCCGCCTTTGTGATGTTGGTGAAGCTATACAGGAAGTCATGGAATCCTATGAGGTTGAACTTGATGGCAAAACATATCAAGTGAAGCCAATACGTAACTTAAATGGGCACTCCATTGGACAGTACAGGATACATGCTGGCAAAACTGTTCCCATTGTCAAAGGAGGAGAAGCAACACGAATGGAGGAAGGAGAAGTGTATGCCATAGAGACTTTTGGCAGCACAGGAAAGGGGGTCGTTCATGATGACATGGAGTGTTCGCATTATATGAAGAATTTTGATGTTGGACATGTGCCAATCAGGCTACCCAGGGCTAAACACATGCTGAATGTAGTCAATGAACATTTTGGCACGCTGGCTTTTTGCCGCAGGTGGTTGGATCGCCTGGGTGAGACAAAATATTTAATGGCTCTGAAGAACCTTTGTGACTTGGGTATAGTGGATCCCTACCCTCCACTCTGTGATACTAAAGGCTCCTATACAGCACAGTTTGAGCACACCATTCTGTTACGCCCCACTTGCAAAGAAGTTGTGAGCCGTGGAGATGATTATTAAGCTCTGCAATTTATTTTCTTTCTTACATTATTTTTCCTGACAAGCTTTATCCTTTCTCACTTTGCTTTGGCAGAAATCAGCATGAACTAATTAATCTGAAGCTCGGTGTCTGTCTAAGCAGGGGACTTGTATATCTGCCATGTTTTGACAGGGATGGGAAATAGGTGACAAACTAATGTTTTCAGTTTTTTGTATATTTCTTTCTTGATCTAGAAATGATGAATGTATGCACATCCTATTGCTGATTTATAACACCTATGCCCAGTGTAGGATTGCCTTTTGAATTTTCCTGAAAGTTTTTTTTTTTTGTAAAAATAAAGATTAAACTCAAATCTGATTATTGGTTTCAATATTAATTCAATGTGTTAATTCTTCTGATTTGTCTATTCATCTTCTTTCCCCTGCCTCACTTACTTTTAGAACAGAGCATTGTAATTTATGGTCTTTCTGATTTTAATTGGGCAAGCTACACTTTTTAAATGATTTAATTGTGATTTTATTTATCAGTAATTCCACAATCCTTGCCACAACTTCCATCCATGATTCAGTACACACTGGGAAAGCATCCACAAACACCAGAAAGTAAGGATATTTATGTAGGTAGTATGTTCTGAACTGTACTTGCCTTCATACACGCTTGATTATTTTTTTATTTGTTTAGTGTTTTTACTCCCAATATAATTAATTTGGTACTGAAACTACTTTTGGGAGCAGCAGCCAGAATTACATGAAGTCTTTTTACTAATTTCCTCTTAAGTGTGAAGATAAACAGACGTGATTCTGGCCCAGGTGATCTCTCGTGCAAGTTTTAACTTAGTGTGAAAACAGTATTAGGTTTCTAGGTAGCCTCACTACTGCATAACTGATTTGAGTTTGAAAACTAAAGATGGTAATGAAC
->XM_046102345.1 Truncatella angustata uncharacterized protein (BKA67DRAFT_558781), mRNA 
-GCCGCCGCAGCCCTTTCCACGCCCGGCGCCGCCTACTCATCCTACGACCAGGTCATTACATCCGATGACTCGGACCGCATTTTCCACTACTACCCCGACGTGATGAATGCCTTCGGCGTTTCACGTCTCCGTCTGAGCAGCATTGACGAGATTCCTAAGGGCGCCGATATCATCACCTTGTTGCCCGTGAACTATGATGAATCGGACTCTACCCCTGGAATATACATGGCAGTCGATACCAAGGGCAACTACTTCTACATCATGGCCTGTGACATCGAGGGTGACGCTGCCAAGATCTTCATTGCGTCTGATCCGGATGCTGGTGCTGCCAAACTTGCCGAGGCGGATCTGCGCTACATCGTTACTGGTGGTGTTGTTCAGGATTGTTCCTTCATGCCATTTGTCTCGACTGGTGCCGGTTTGTCTTAAATGAATTTGGTGGCGTAGTGCTGTGAGTCGTACATTTGGCAAAAGGCACCTTGGTTTCTTATTACCTTAATTTGGGGCTTTCTTTGAGTACTACCGTACAACCCAATTTTTCATTGTCACAGCCATGTACCAACCATCATATGAGTAATACTTAACTGGCCCACAGAAAGTATGCACTGGAAAGAGGCCTTCTATTTCCAGTGCAACAACAATATAAGCAGTTACCTCAAA
->XM_052329315.1 PREDICTED: Diospyros lotus uncharacterized LOC127796910 (LOC127796910), mRNA 
-ATGGTCGCCGACGAAGCTTCGTCGTCGGCGACCATGGAGATCGACCGGGCTTCGTCGCGAACGAAGCCCCACGGTCGGGCTTCGTTCGCGACGAAGCCCGCTGGGGAGAGGAAGCGCCCGATCGGGCTTCAATTACAGACGAAGCCCGATCGGGCTTCGATTGAAGACCCAAGGAAGCCCGATCGGGCTTCGATTGCAGACAAAGCCCGATCGGGCGCGACTAAGCCCCACACCCAATTGGGCTCCCCCGACTGTTGGGCTATGACACAGCCCGATTATCGTTGCCCAACAAAGCCCAATCAAATGGCTGAACAACAAACTACAAAATTTGCTTATGTTCATGCTCACCGAATATTACCCCCCGGAATGCGAGTTACTACTCATTGTGGGATTAAACACCTTGAGGCGATGCGTCGTGCTCTAGACCGATACAAGTTATTGGATAGATTCCTACAGGGCCCATTAGGACATTTCTTGAAGATGCCTTTGTCCCTCCATTTGACTGCACCACAGTTGATATATCATGTTCTACTTAGGGAGGTGACATTTTCGAGTGCCCGCCACGATGAGATGTGGTTCGAGATTGGCGGCACACCATACAGATACGGGAGGCAGGAGTTCATACTTATTAGTGGACTCCGATTTGGGGCTATTGATAGGGAAAGCCTTGAACCGAAACCTATTGAGCCGGAGAGTTTACGTGCTCGACTATTTCCACAACATAAGAAAGGGGTGACTGGAGACGACCTTGAATTACTTATTAGTACCAAAGAGGATATGGTTTCAGAGGATGCCCTGAAACTGATTTACATTGCTGTGGTCGACATGTTTTTGTTGGGCCAGGATGAGCGTGGGCATGTGGATGATTTCTTGTGGACTATGGCCGAGGATTTACAAGCATTTGAGATGTTCCCTTGGGGTACATATGTCTACAGTAAGAGTCAACATTACATCCGGTTGGCCACGAAAGAAAGAAAATTGACTGGTGAAGGTGGGAAGAAAATCAACCTTTATGGTTTTGTATGGGCGTTTCAGTGGTGGTTGATCGAAACGTTCCCATGGATTCAGAATAAATGGGCCGTCAGACCGTCCGAAGCAGACATTCCAAGATGCAGAAAATGA
->XM_019061330.1 PREDICTED: Bemisia tabaci neutral ceramidase (LOC109043949), mRNA 
-ATCATTGAAACCCCGTTTAGGTCAAGCTCGCAGTTAAAAATGGATTTCGTCCAGTGCGCTTGAGTACAGCAGGAGCTGAAGCTTTGTATTACTATAATGCGAGAACACTTTTTACTCTGAAAGGCTGGATAACTGAGAAGACCAAAGTCGTAGTTCGAAATGCCGGGTGTATCGCGACAAGTCTGTTTGATATTGGCCAGCTTTGTAGCTTTCTGCGAATCGGCTTACAAGATTGGAGTGGGGATAGGGGATGTGACTGGTCCAGCGGTTGGAATCCCATTCATGGGCTACGCAAACCTCAGGCAGAGGGGTGAGGGATTGCATTTGCGACAATTTGCAAGAGCTTTCATCATAGGTGACTCCTACGAGAAACTCGTTTTCGTGAGTGTAGACGTGGGAATGGGCGCACACGGAGTCCGAATGAAGGTGCTGAAGCGGCTGAGGGAAAAATTCGGCGAGGAGTTCTCGGAGAGGAACTTGATGATAAGCGGGACGCATACCCACTCGGCGCCAGGCGGGTTCCTCATGCATTTCATGTTCGACATTAGCACCATGGGCTTCGTCCCTGAGACTTATGACGCCCTTGTTTCCGGCATTGTTACGAGCATAACCCGGGCGAGGAGTAACATGCGGAAAGGAAGTATATTTTTCTCGACAGGAGAAGTTTTGGACGCCAATACGAACAGGAGTCCATCCGCTTATGACAACAATCCAGAGAGCGAAAAAGCCAGATTCGAGTACAACGTGGATAAAAGGCTGATTCAGATGAAATTCGTGGCGGAAACGGGTCAACCGATGGGCGTGCTTAACTGGTTCCCGGTGCACCCAACCAGCATGAACAACACCAACACCCTCATCTCCAGCGACAACGTCGGTCTCGCCTCTGTCCTCTTCGAACAGCAGATGAATCCGGGACGTTCTATCGGCAAAGGCCCTTTTGTTGCAGCGTTCGCCTCGAGCAACTTGGGGGACGTGTCGCCGAACCTACGATCGCCGGTCTGCCTGAAAACCGGGGAGCCCTGCGACATGCTAACGAGCTCCTGCCCGGACGAACATGACATGTGCGTCGCCCTCGGACCCGGCGAGGACATGTTCCAGAGCACAAAAATCATCGCTCAACGGATCCTCGCCACCGCTATATCTCTTTGGAATGATCCTAACTCATGGGAGATCAAAGGACCCGTCCGGATGGTTCATCAATTTGTGAACATGGCTAAGCGGGAGGCAACATATCAAGATCCAAATACTGGCCAGATCCGACAGGTGCACGGTTGCAAGCCAGCTATGGGCCATAGTTTTGCTGCAGGGACAACCGATGGGCCTGGTCTTTTTGCGTTCAAGCAAGGAACCAAAAGTCCGGACAATCCACTCTGGAACTCTGTTTCCAGGATACTGCCCAACGCTTCAGCAGAGAGTGTTTCCTGCCATGGAGGAAAACCAATCTTGTTATCCACAGGCGAGATGAACTTCCCTTTCCAATGGCAACCGGAGATCGTGCCGACGCACCTGGCGACGATTGGGCAGCTGGCGGTGGCCTGCGTGCCGGGGGAGTTCACGACGATGGCCGGCCGCCGACTCAGAACCGCCCTCCGCAATCGCCTCGGCCTCGCCGACGACACCCACGTTATCATCGCCGGCCTTTGCAACGAGTACAGCGACTACATCACCACGCCCGAGGAATACGAGGTGCAGCGTTATGAAGGTGCGTCAACAATTTATGGCCCAGAAACACTACCACTCTACATCAGGCAGTACGAGGACCTGGCTGATCATATTCTTCGGAAAATGGACCCAGAGCGGGGCCCAGTTCCTCCTGAGTTTCTAAACAAATTAATTGTTCTCACACCACCTGTTTTATACGATGCTCCACCCTACGACCAAGACTTCGGAGCTTGTTTACAACATCCACCACTGAACGTCACCAGAGGCGAAACTGTCAACACTACGTTCGTCTCGGGGCACTTGCGCAACAACATGATGCGCGGCTCCAGCTTCCTCCTCGTCGAGCACCTTCCGATTAACGGGAACAAGTGGGAGGTCGTCGCCACCGACGCCAACTGGGAGACCATCATCACGTGGAAGCGGCAATCACTGCTACTGGGTACTAGTGCGGTGGTGATCAAGTGGACGGTGCCTGAGGACGCGCCGTTTGGGAAGTACAGGATCAAACACCAAGGCTACAGCAAACCCGTCATCGGGGCCCTGCACCAGTATCAAGGGCTCAGCAGAGTCTTCCAAGTTGTACCCAAAGATCTACCCTATTCATACGATGTCCCGCAAATACACGAGTGATCCTCTCAA
->XM_034027490.2 PREDICTED: Acipenser ruthenus phospholipid scramblase family member 5 (LOC117416435), mRNA 
-GAGGGATCGGAGACAGAGAGAGCAGCGACTTGAGAACAGAAGGCAAGCTTCATCCTCTGTGATCTACCGTACAGGACACAGTTCACTTGTGGCTGGGTGGAAGGATTTAAAGAGGATGCCGGTGATCACGGCCCAGCCGCCCCCCTTCGGCAGGCTGCAGAGGGAGAAGCACATCGAACAGCTCTTCAGGTCCTTACGCCAAGGGAGTAGGGGGTCCCAGGAGCCACGGCACAGTCTGGGAGAGGAGGCAGGACAGGGGGACTCTGAGACACTGGAGCTGCGTTGCACGACGGAGCCGGAGGCCCAGTCCAGCATCCCCAGAGTCCTCAAGCCAGCGGGCGCCACGGAGAGCAGCGAGCAGAGCCTGGCTCTCTTAGCGGACGTGGAGCAGCTGTGCATCATAGCCAGGCCGGGGCTCCAAGGACTGGCCTGTGAGCCTGGGAGGACCTACAGCATCTCCACAGCTTCCGGGAGTCAGCTCTACGTGGTGGTCGAAGACACGTCATGCCTGTGTCTGCTCTCCTGCGGTCCCGCTCGCTCCTGCTCTCTCCGAGGGTATGACAGAATGGCGCAGGAGGTCTTCCTGTTTGAGAGGCCCCTGAGGGCTGATGCGTGCTGTCTGGGCTGCTGCCTGATGGAAATGCAAGTGTTCACACCTGACCACCAGCTCATCGGGACTGTGCGTCAGAAGTGGAGCATGTTTACCCCCCTCATGGAGCTCAGCGACTCGGACGGGACGTCCTATATCAGGATTCAGGGCCCCTGCTGCCCCTGTCGTTGCTACTCCAGCCAGGAGTTTCAGGTGGTGTCCAAGATTGGAGACAAATTGGGAAAGATTTGGAAAAAATGGCCTGGCTTCAATGAAGAGTACAACATGGACCACGAATACTTCGGGCTGGATGTCCCAGCTGAAATGAGCCCGGAAACCAAAGTGCTGTTACTGGCTGCTGCGTTCTTACTGAACTACATGTTCTTTGAGATGAGCTGAACATACTGGAAGAGTACAGAGCGCCAGCCCTGACCAATGGGAGCACAGAGAGATCATGATGTCACAATGAAAGGTGTCACAGTGGCTGCACAAGGAGTAACGTTAAGAATCACATGTTTGTATCGGAAAACATTATTGCAGCAGTTTGAATGCCAGGGCATGGATAGGATTATTAACAGAGGCATTCACAGTGCAAGAGCCCCATTCAGACAATGCGCAGAAGGGTTAGATCACCCACAGCATATTCAACTAATGTAAAGCACTCAACTTTAATCCAATACCAGACACATACCTGCTCACCCTGAGATCGAAATCCTATGGATCATTCCAGCTGAAATCTGTGTCATAAAAAGTGCCCTGAAAAAATCTACCTTTAAAGAGCAAAGGAGCCCCCTTCAGGACATCATAAGCATGTAATGGCACCGGACTTTATACAATGACAGCATGTTGATGTAAGCAGGTACAGTATGTTAACATGAGCAGCACACTGTGCTCCTCAATGTGGTGAGGCTCACATTACTAATCTTGTGTTGTACTACAGTATATCCTGATCTGTGCTCCTCAATGTGGTGAGGCTCACATTACTAATCTTGTGTTGTACTACAGTATATCCTGATCTGTGCTCCTCAATGTGGTGAGGCTCACATTACTAATCATGTGTTGTACTACAGTATATCCTGATCTGTGCTCCTCAATGTGGTGAGGCTCACATTACTAATCTTGTGTTGTACTACAGTATATCCTGATCTGTGCTCCTCAATGTGGTGAGGCTCACATTACTAATCATGTGTTGTACTACAGTATATACTGATCTGCAACATGTACCTGCATGTGACTGACTGATTGCAGGAGCTACATGTTTACAGCCACCTCTGAATCAAGACTCAGAATAGCCTTCTTTTCATGCTTTTTCTTTTTTAATTTGATAAATAAAAACGATTTTGTAAAATA
->XM_048518335.1 PREDICTED: Sphaerodactylus townsendi coiled-coil domain containing 88A (CCDC88A), transcript variant X5, mRNA 
-GAAGGGAGAGGCTGAAGCAGCTGTTTTTTTTGGGGGGGGGGGATGAAGGAATAGGCAACGGGTGGGGTCCTGCTAGCAGTAGTTGACCTACCATTTTTGAAAAGGCAAGTCGGGGAGGCACCTCCAGATATCTGGTGGTGGTGGCAGAGAGAGAGCGCGCCCCTGTTTCCTGGGAAAGTGGGCGAGGTTGCCCGGGCGCCTCTTGTCTGCAGAAAAGGAAGATCAGTGCTAGTTCGGTGGAAAGAGGAGTGGTTTTTCTCTCTGAGCTGGCCTTGGGTGAATGGTTGTTCCTGCAAGGAAGAGAGACTTGTTGGGGGCTGATGAGGGAGGAGGTCGCTGCTGCCCTCCCCGCGGCTGGCACGCTCTTGGTGGGTCAGGGGTAATTAGCTGAGAGGAGTTTCACTGGCGTGTCTCCCCCTGGAGCACGCCGGCTGCTGGCTCGCTGGTGCTGCAGCCCGAGGCGGAGTGGGGGGGAATGCATGCTTGCTTGCGCGGCTGATGTAGGATCTTAGTAAGGTCCTTCCTTTCTTTCTCTTCTTGCTTCCTCTTCGGCACGGAGAGAGGAGGAAGAAGGAGTCATTTGGTGGAAATAAAGAAAAACAACCAGAAATGAACGTGGACTGCCTCTTGATTGTTCCCTTTCTGGACGAGGAAGAGAAAGCTCTTTTGACCGATAGCCTGACTACTTTTTAAATTGTATTGGGGGAACTGCCTTGGATATATATTTTTTCTTGAAATCGTGGAGCATTTCACGGAATTACTGCAACGAAAGGCACCGAATCTCTCCGTTTTTTTAGTCCTGGTTTAATAAAAACCCTCTTAATTATAAAGCATGGAAAACGAAATATTCACGCCTCTGTTGGAGCTCTTCATGACCAGCCCTCTTGTTACCTGGGTTAAGACATTTGGACCGTTAGCTGGAGGAAATGGAACCAACTTGGAGGAATATGTTGCGCTTGTGGACGGAGTTTTCCTGAATGAAGTCATGCTGCAAATCAACCCCAAAGCTACCAGTCAGAGAGTAAATAAGAAAGTCAACAATGATGCATCCCTGAGAATTCAAAATTTGTCTGTTTTGGTGAGGCAGGTTAAATCGTACTATCAGGAGACTTTACAGCAGTTGATTATGATGCCTTTGCCAAATGTCTTAATAATTGGCAAAAACCCCTTTTCAGAACAAGGTACTGAAGAAGTAAAAAAGCTACTTCTACTCCTGCTTGGCTGTGCAGTTCAGTGTCAGAAGAAAGAAGAATTCATTGAAAGAATCCAGAGTTTAGACTTTGATATAAGAGCAGCTGTTGCAGCCCACATACAAGAGGTGACACACAACCAGGAAAATGTTTTTGATCTGCAGTGGATGGAAGATGGTGCTCTCTCACAAGAGTATATTGAACCCCTCCTAAAAAATATGGCATTGCATTTAAAAAAACTTATAGATGAACGAGATGAGCATTCTGAGACTATTATAGAGCTCTCTGAAGAACGAGACTCTCTCCATTTTCTACCTCATGCTTCAGTGGCACAATCGCCTTGTGGATCTCCAGGCATGAAACGTACTGAAAGCAGACAGCATTTATCAGTAGAGCTAGCAGATGCCAAAGCAAAGATCAGAAGACTTAGACAAGAGCTTGAGGAAAAGACAGAACAGTTGCTGGATTGTAAACAAGAACTGGAGCAGATGGAAGTTGAGTTGAAGAGACTACAGCAAGAGAATATGAATTTGCTTTCGGATGCACGCTCTGCTAGAGTGTACCGTGATGAACTAGATGCTCTCAGGGAGAAGGCAATCCGTGTCGACAAGCTTGAAAGTGAAGTCAGCAGATATAAAGAGAGGCTACATGACATTGAATTCTACAGAGCTAGAGTGGAGGAACTCAAAGAAGATAATCAAGTATTGCTGGAAACAAAAACAATGTTGGAAGATCAACTGGAGGGGACCCGGGCTCGTTCAGATAAATTACATGAATTGGAGAAGGAGAATCTACAGTTAAAAGCTAAACTGCATGATATGGAGATGGAACGTGACATGGATCGGAAGAAAATTGAGGAACTTATGGAAGAAAACATGACTCTAGAAATGGCTCAGAAGCAAAGTATGGATGAGTCACTGCATCTTGGATGGGAACTTGAACAAATAAACAGATCCACTGAACTATCTGAAGTGCCACGAAAATCACTGGGGCATGAAGTGAATGAACTGGCATCGAGTAGGTTACTGAAACTGGAAATGGAAAACCAAAGTTTGATAAAGACTGTGGAAAAGCTACAAAGTACAATGGGATCTGCAGAAGGCAGTAATTCAAAACTTCTGAAAATGGAAAAGGAAAACCTGAGACTTAGTAAAAAGCTGCAAGGACTTGAGAATGAATTTAGCGAAGAGAAGCAAAGTCTTCAGAATAGTCAAAATCTAAGCAAAGATCTGATGAAAGAGAAAGCACAGCTTGAAAAGACAATTGAAACTCTGCGAGAAAACTCAGAGAGACAGATTAAAACATTGGAACAGGAGAATGAGCATTTGAATCAAACAGTGGCTTCCCTCAGACAGCGCTCTCAAATCAGTGCTGAAGCAAGAGTCAAAGATATTGAAAAGGAGAATAAAATTCTTCATGAATCTATCAAAGAAACAAGCAGTAAATTAAATAAGTTAGAATTTGAAAAGAAGCAAATTAAAAAAGAATTGGAACACTATAAAGAGAAGGGAGAGAGGGCAGATGAGCTGGAAAAAGAAGTACAACATCTTGAAAAAGAAAACGAGCTGCTACAGAAAAAGGTTACTAACTTAAAGATCACTTGTGAAAAAATAGATACTTTAGAGCAAGAAAACTCCAATCTGGATATGGAAAACAGAAAGCTGAAAAAGACCTTAGATAGCCGGAAAAACCTCAGCTTTCAGCTAGAATCTTTAGAGAAAGAGAATACACAACTTGATGAAGAAAATTTAGAACTCAGAAGAACAGTTGAATCTTTGAAGAGCATAAACATCAAAATGGCTCAGTTACAATTAGAAAACAAAGAATTGGAAAGTGAGAAAGAGCAGCTTCAGAAGAGCTTGGAGCTTATGAAAACATCTTTTAAGAAGACTGAACGTTTAGAAGTCAGTTACCAAGGTCTGGATACGGAAAACCAAAGGCTGCAGAAAGCCCTAGAAAACAGCAACAAAAAGATTCAGCATTTAGAAAGCGAACTACAAGATCTAGAGACAGAAAATCAAACCTTGCAAAAAAATTTAGAAGAACTCAAAATTTCTAGTAAACGCTTGGAACAGTTGGAGAAAGAAAACAAACTTTTGGAGCAAGAAACCTCTCAATTGGAGAAAGATAAAAAGCAACTGGAGAAAGAGAACAAGAGACTGCGGCAACAAGCAGATATTAAAGACAGCACTTTAGAAGAAAACAACGCAAAAATCTGTAACTTGGAAAAAGAGAACAAGTCTCTCATTAAGGAAATTGGTCTATGTAAAGAAGCTTCTATTCGACTAAAAGAAGCTGAAAAAGAGAATAAAGAACTTGTAAAGCGAGCCACCATTGACAAGAAAACGCTTGTCACATTGCGAGAGGATTTGGTGAATGAAAAGCTGAAGACGCAGCAGATGAATAATGATTTAGAGAAGCTTACACACGAACTTGAAAAGATTGGTTTGAATAAGGAGCGCCTTTTGCATGATGAGCAGAGTAGTGATGACAGTAAATACAAACTGTTAGAGTCAAGGTTGGAATCCACATTGAAGAAATCGCTTGAAATAAAAGAAGAAAAAATTGCTGCTTTGGAAGCTCGACTAGAAGAATCAACAAATTTAAACCAACAGCTGCGCCAGGAACTTAAAACAGTTAAAAAGAACTATGAAGCACTCAAACAGAGACAAGAGGAGGAGAAAATGGTACAGAACTGTTCCCCAAGAACTGGAGAAGAATCTCAGTCGGTTAATAAGTGGGAGAGAGAAAGTCAGGAAACTACTAGAGAACTTTTGAAGATTAAAGATAGATTAATTGAAATTGAGAGAAATAATGCAACACTGCAGGCAGAGAAGCAAGCTCTGAAAACACAACTAAAGCAACTTGAGACACAGAACAATAATCTGCAGGCTCAGATTTTGGCTCTTCAGAGACAAACAGTTTCCTTACAAGAACAAAATACAACTTTACAAACTCAGAATGCCAAGCTTCAGGTAGAAAATTCAGCTATTAATTCACAAAGTACATCTCTTATGAATCAAAATGCACAGCTGCTGATCCAACAGTCTGCCTTAGAAAATGAAAATGAATCTATAATCAAAGAACGGGAGGAACTGAAATCACTGTATGATTCACTAGTCAGAGATCATGAAAAACTGGAACAGCTTCATGAACGGCAGGCTGCAGAATATGAATTATTAATTTCCAAGCATGGAAACCTTAAGTCAATGCACAAAAATCTTGAAATGGAACATAAGGACTTAGAAGACAGATATAATCAGCTGCTGAAACAAAAAGTGCAATTAGAAGAATTTGAGAAAGTTCTCAAAGCAGAACAAGAGAAGATGGTACAGCAGAACAAAATGCATGAAACTGTAGCTGCAGAATACAAAAAGCTTTGTGAGGAAAATGGCAGGTTAAATCATACATATACCCAACTTTTGAGAGAGAATGAAGGTCTCCAAGTGGATCATAAGAATTTGAAAACACTTCTGAACAGTTCTAAACTGGAACAAACAAGATTAGAAGCTGACTTTTCCAAGCTCAAAGAACAGTACCAACAACTGGACATTAAGCATACAAAATTGAATAATCAGTGTGAGTTGCTTAGCCAATTAAAAGGAAACTTGGAGGAAGAAAACAGGCATTTGTTGGATCAAATCCAAACATTAATGCTGCAAAATAGAACACTATTGGAGCAGAATATGGAAAGTAAAGATCTCTTCCATGTTGAACAGAGACAGTATATAGACAAGCTAAATGAATTAAGAAGACAAAAAGAGAAACTGGAAGAAAAGATTATGGATCAGTATAAGTTTTATGAACCGTCACCACCAAGAAGGAGGGGTAATTGGATTACTCTGAAAATGAGGAAGTTGATAAAATCTAAGAAGGATGTTAACCGAGAACGACTCAAGTCTCTTACTCTGACACCCACCCGCTCCGAGTCAAGTGAAGGATTTCTTCAGCTGCCCCATCAGGACAGTCAAGATAGCTCTTCGGTGGGCTCAAACTCACTTGAGGATGGTCAGACTGTGGGGGCCAAAAAAAGCAGCACCATGAATGACCTGGTGCAGTCCATGGTCCTAGCAGGAGGACAATGGCCAGGTAGTTCTGAGCACCTGGAGGGTCCTGATGATATATCTACGGGTAAAAGGAGAAAAGAATTGGGATCTATGGCCTTCTCTACTACATCCATCAACTTTGCAACTGCCAACTCTGCTGCAGGCTTGAGATCCAAGCAGTTGCTTAATAATAAAGATGCTACATCTTTTGAAGATGTAAGTCCACAAGGAATTAGTGATGATTCTAGTACTGGATCAAGAATTCATGCTTCCAGACCAGCCAGCCTTGATAGTGGCAGAACATCCACTAGCAATAGCAATAATAATGCCTCACTCCATGAAATCAAAGCAGGTGCAGTTAATAATCAAAGCAGGCCACAAAGCCACAGCAGTGGAGAATTTAGCCTTCTTCATGATCACGAAGCATGGTCCAGCAGCAGCAGCAGTCCTGTCCAGTATCTGAAAAGCCACACCAAGTCTAGTCCGATACTCCATCATAGACTGTCAGAAACCCTGGACAGACAAGGAACGTGGAAAATTAAGACCGACTCTCCTGGCAGTGAAGTGGTTTCCCTGCAGCAGTTTTTAGAAGAAAGTAATAAGGTTATTTCAACTGAGATCAAATCCTCAAGCCAAGAGAATCTTCTGGATGAAGTAATGAAAATTTTCTCTGAAAATGCTGAATTAGCTGGAAGAGATAAACCAAGAAAACACTCAACAGTCAGCAGTGGTATCGCCAGATCACAGAGTGTAAAAAACACATATGAATTCTCTGATGGAAAATTAGCTAGCCAAGATCACCTTGCAAGGTCCAGTACATATAGAGTGGAAGAGCCCAACTTCTTGAACTCTTCAAAAACACTTACAACAGGGACTAGAGGCAAGACCAAGTCTGTTAAGGAAAATATACAAATGAGCCAATCACGACAATCAAAAGATTGTAATCCTTATGCTACTTTACCTCGTGCAAGCAGTGTGATTTCTACAGCTGAAGGAACTACTCGGAGAACAAGCATCCATGACTTTTTATCTAAAGACCCTAGACAGCCAGTATCCATTGATCCATCTCCACCTACAGTTGACAGAAGCGTCCCATCAGCTTCTAGTGAGTACGGTCCTCCAGAACAGTCCTCTTGTGTTTTTCATTATAAACCTTTTACTGCAGTTACCCTGTCAGAAAATGATTTAGGCAGTATAGCTATGTTAGGTTATTCTGCTCATAAATCAGAAGAGCAGAATGTAAAGACTAGTGAGACAAATTTTAATGCTAAAACACTTTCTTATAGTGACATGTACAGTGAAAAGGTAGGCCCATCAATAAGCAGTGTAGGGAAATTCTCTCTCGCCTGTTTATCCATGCCATTTTTGACACTTAATACTGAATTAGTCAGTAGTGTAAGTGGATTGCCTCAAAGGCCTGTATCAAAAGCAACCAGCACAACTTCTGGATCATCAGTGAAAGCTGCACAGAAGGATCATAAGCTACCTTCTGAGAATCAGAGATCTGATGACAGAAATTTAGAAGTGACTCAGAACAGGAGTGAATATACTGTTGTTGCACATGTAAACATTAATGAGAGTAAATCCCCATTACCAGTTTCTGACGATACCCAAACTATTTGGTATGAATATGGCTGTGTGTGACTAAATAAAGATTAAATATATTCTCCCA
->XM_002842962.1 Microsporum canis CBS 113480 conserved hypothetical protein (MCYG_08091), partial mRNA 
-ATGTCGGCGCCAAATCGACGTGGTGATGGGCAGACACCGCTAAACTCAGCTGGACCCAGCTCCAGTCCAGCCAAAACACCCTACAATGCGCTATTCAGATTATCGAGACTAGTGGCAGCGCCTTCGACTCCGGCACAGCAGAATGCTACCTCGTTCAACTCAAACAGACCGTCAGCGTCTCGGGCTGGCCGCCGGAAATCAGGGATGACGCCGTCACGGACAAGAGGCGGAGGTGAACATATACCAGTGACTCCGCATACGATAAGGGCATTCCAGAGACGTGCAGCAACATATACTCCGGGGCGGGATAGACGGAAGAGTCAGCGCTTCAAGCGGGAGACGCCAATGGATATTTTGAAAAACCTGGGGAAAGCTCTTGCGCCAATATCAAAACCGGTATCGTCTTCTCCGCAGACCGAACTAGAGGACGAGCCGGAGCCCCCAGTGGACGAAATTGAAGAATTAGACAGGGAGCCTCCCATTCCACCACCGAGACTTTCACTCCCGCTTAATGAGATGACTGTGGTCCAGGAGGACGATAACAGTCCCGAGATACCCCCTCCAAAACTGTCTCTCCTCCCAGAGGATGAGGACATTACGAGAGGGTCGATTGAATTGCCCCGGAGAGAGCGGTCAGGTCGAGATCTGGCCAGGCTGTCGAGAGTAAGCTTCGCCAGTAATCGTTTCAGTGATCATTTTGGGGACACCACGAACCTTGAAGATCCGGCAGAGGCATTGGACTTTCGTGTTGGACCAGAAGAGGACTTTGATGAGGATGTTGACAATACGACCGGACAACCGATGTTGGATGCAGGGGGAGAAACCGAGGATTTGGGCCGATTTAACCTCGATTTTGCCTTCCCAACGCCTGAAGCGCCTCATACTATGCCAATAGAGAATGATAATGAGCAGGACACCTTCGAGTTAGATGCAGTGCCACCCGAATTCGGTGGACCAGACAGTCCTTCATCAGGAAGCGATTTCGGGACAGCAGGATTCGAACCAGCCATGACCGATAGGTCGTCTAATCGGGGAGTCGTAGAGGAAGAAGAGGAGGAGGAGCAGGAGCAGCAACAGGAAGACCAGCCTGAGCCACCGCAGAAGAAACAAAAGCTGTCTAAACATGGGATACCGGTCCCAAGTCTGCCTTCTGGAGTCGTAAAGAAGCTGGCCATGCGGTTTGCAAGGTCCGGGAATAAAAAGACGAGAATCAACAAGGATACGATGGCGGCCATCCAGCAGGCAACGGATTGGTTCTTCGAACAAGCGAGCGGGGATTTGTCGACATATTCCAAACACTCTGGCCGAAAAACAATTGATGAAACAGATGTCATCGCACTGATGAGAAGGTAG
->JX319470.1 Uncultured fungus clone 034A1751 18S ribosomal RNA gene, partial sequence; internal transcribed spacer 1, complete sequence; and 5.8S ribosomal RNA gene, partial sequence 
-AAAAAAAGCTTGGTCATTTAGAGGAAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTACAGAGTTCATGCCCTTACGGGTAGACCTCCCACCCTTGAATACTATACCTCTTGTTGCTTTGGCGGGCCGCTCCGGCTACCGGCTCCGGCTGGTGAGTGCCCGCCAAGGGACCTAAACTCTTGAATTATTGTGTCGTCTGAGTACTATATAATAGTTAAAACTTTCAACAACGGATCTCTTGGTTCTGGCATCGATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAATTTAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCCTTGGTATTCCGAGGGGCATGCCTGTTCGAGCGTCATTAT
->XM_040766144.1 Sporothrix brasiliensis 5110 uncharacterized protein (SPBR_07890), partial mRNA 
-ATGGTCATTGAGACCAGCGGCAAGCTGCTGAAGGGGTATGATGACAAAGGGTACAGCCGAGCCTTCAACCGATTGTTTACAAAGGCCCCGGCAAACGCCGGGTACAACGACGGCTTGTCGGCCCCGCAGCCCGACTTCGTAGAGGGCCTCGAGAAACAAGAGTTCCGCCCGTTCCAGGCCGCCGACTATATCCCTGGAGCCACTCTTTATAAGGACGACCCCCGTTCCATAACCCTACCGATGATTGCTGGAGAATGGAAGGGCCCTGCTGGGGACATGAGAGAAACGAGAGTGCAGAGTGCCTACGACGGAGCAGCTCTTGTCCACGCAAGAAACCAAGCACTCGCCTACATGGGAGGGTCTGATCCCCCAGGCCACGCAGAAGTCACAACATTCACCGCAGACGGCACCAATCTCAACCTGACGGACGGAGACGTCTCAGGAACGCCCAAGACTATGCGAAGACTCAGTCCGAAGAACTAA
->L38765.1 Pisolithus tinctorius (F00031) mRNA, EST0038 
-CGGCTAGCTGCTTTTAACTGAAGTATTGCAGCATGTAAGTTGTGGTTTATAAAGTCTTTCGCCATGCGAGGAACAAGTCGACAAATTTGATGAGCTTATTCATCTTATTTGTGTATGTTACCACACAATGATTCCCTTCTTTAATTGAAGTATTTGAG
->XM_018671993.2 PREDICTED: Lates calcarifer inhibitor of growth family, member 1 (LOC108880464), transcript variant X1, mRNA 
-TCAATACACAGTCAGTGAGATGAAGGAACAAACCCGTCAGTGCCAAAGCAATGGGGACTCTGTAAATGGTGCAAGTGACTGGGTGTCCTGTGATAAAGACGAATTCGCAATGTTGAACCCCACCAATGGTGATCCAGGACATGTTGTCGTCAATTATGTGGAGGAGTATTTGGACCTCGTGGAATCACTACCTTTTGACCTACAGAGGAGTGTGTCTCTCATGAAGGAAATTGATGCCAAGTATCAAGATATTCTGAAGGAGCTTGATGACGCTTATGAACGTTATCGGCGGGAATCTGACTCACTTCAGAGGCGCAAGCTTCAGTCATCGATTCAGAGGGCGCTGATCCGCAGTCAAGAGCTTGGTGATGAAAAGATCCAGATAGCTGGTCAAATGGTGGAGTTGGTTGAGAACCGAACACGACAGTTAGACTGGCATTCTGAACTTCTCCTCTCCTCTCAAGAAGTCCCTGAGAGCCACGTTCCTACAGCAGCATCCATGACCACCACTGCAGCATCCTTGATGTCCTCATCATCAGCCACAATCACTCCAGGGAAACCTGGCCACCATGACAAGAAGCGTGATGAGGTAACCCCAGGCTCAGGTGGTGCAGACAAGGCTGGAGGGAAACGCTCAAGACGTCAGAAAAATGGAGAAAATCGGGAAAGTTATGGGGGTCTGGATCACACAGAGGAAGTGGGAGTGGGGGCGTCGCGGGAAAAACGTGCCAAAACATCTTCCAAGAAGAAGAAACGGTCAAAAGGAAAGTCTGAGAGAGAAGTGTCACCTCCAGACCTGCCCATTGATCCAGATGAGCCAACGTACTGCCTGTGTGAGCAGGTGTCCTATGGCGAAATGATAGGCTGTGATAACGATGAGTGTCCCATTGAGTGGTTTCATTTCTCCTGTGTTGGCCTCCATCATAAGCCAAAGGGAAAATGGTACTGCCCTAAGTGCAGAGGTGAGAATGAGAAGACCATGGACAAGGCCTTAGAAAGGGCCAAGAAGGAGAGGGCATACAACAGGTAGCTCGCGCTGCCTGGCCAAACGAACACTACTGCAGAGAAATTTAATTTTCTGTCTTGTCTTTGTTTCCATTTACTATTAACAGTGTTCAAAAAGAGTAATGAGTTGATGAGAGGGATCTTGTACATAGTTATTTTTGTAACTGCTGCATAGCCGAGAAACAAGATCACTCCCTCCCCCATTGGGATTATTTGTAATTGACACAGTACAGCACAGTACAACCTGCATGTTTGTAACCAGCTGTCCTCCACTCACATCCCCCATGTTTTCATCATGCATGCAACATCACCCACTCCACTATATATGCTCAATTAACAAATAAAATATTTCTAAACAAGGAAGAA
->XM_046503406.2 PREDICTED: Haliotis rufescens thymidine kinase, cytosolic-like (LOC124137211), transcript variant X3, mRNA 
-GTCTAGTCCCTGAAGTGGTGTGAAAACCCGTAAACCATTTATGTGTACCTTATTTAATTAACCTCGGGCGACAAGCGAACTCGTGCACATTTCTGTGTTCCGTGTTGCTGCCAGTCGCATGTTCGCCTAATTTAGAACCTCAGTGGGCGTGATCCGGGGCGGAGCATAGCGATGTCAGTGGATCACACTTGTTAGAGCTTTAGACTAACTGTGATTATTATGGAACAAGCACGTTTCGCTACATCTATAACATATATCAATATGATGTCTACAAATCACCTGATCCCTTCACCAACGGCAGTTACCAGCCACAGAGGGCATATTCAGATAATCTTTGGACCCATGTTCTCCGGCAAAACCACAGAATTAATGAGATTAATGAAGAGATACCAGGTAGCTAACCACTCCTGTCTCATAGTGAAGTACGCCAAAGACACCCGCTACGACAATCATGGCATCGCTACACACGACAGAACAGTGTTGTCTGCCACTGCTGCCCATGAGCTGATGTCTCTCATACCTGAGGCGCTGAAGTATGACGTCATAGGCATTGACGAGGGACAGTTCTTTCCTGACGTGGTGGTTTTTGCTGATACAATGGCAGAGAAGGGGAAAGTTGTCATAGTAGCAGCACTAGACGCGACATTCCAGAAGAAGGTGGAGGTGATCGGGGGCAAAGACAAATATCTAGCGGTGTGTCGTGCATGCTTCCGAGGGAACAGTTTTCACCAACAAACCAACACCACGACTGAGTAGTCCACGCCTCTATCGATCAGCCGTGTCTGTGTGGTGGAAGAAAAGGTGTCTGTGATTTTTGTCTGAGACAAAACAGTTATTTTAATGTCTTCCTTTTAGTATTCATCATACAGCTCAGCAGACATATATTTCACAAAGAACATTGTCCGGGCAAGCATGCCACTGTGATGTAGTCAAAGGGCATATTATGTATTACACAGAATAATATTCATATTTTTTAATATTTAAACAAGACTTGTATACATACAGACCTAGAAACTATTTGTTATTAAAGTATGTCAGTAAATTGCATTGACCATTTCTTCTCAAACTTTGCAACAACAGATATTAAGTAGTTTAGGAACGGCCATAATATATTCTAGGTTAGGCTGTTGTTTTAGTTTAAGTTATTTTATAGCGCTTCAAAACGTTATCCGAGCATTCAGAAGTCATGCTGGATTCTACACACTAAAAACCCCACTGTACTCAGTGATCTGTGATCTGTTTGAAGCTCGCGTACAACCAAAATATTTTTCTTCTCAAGATGTTGTTATGTTTGCTGCTATGTTACACTGCACGAACTTGTTCCTTTGACATTAATCGACTTGGGTGCCATTTAGCTGTTATTGCTATGGTTATATGCTAGGAATCTTCATCATGAGATAACAGGTTTATTATATACTTCAGTGTGAAAGACTGAGTTTTCTGAAGTTGAAAAAAGTGATATTTTCATTGCAGTGAACATAACACTTGATATTTCACTGCGGTGAACATAACACCTGATATTTCACTGCAGTGAACATAACATGTTGACGGAACTATGTTGGCCTACACGAGACAGCTCGTACACAAACTGTTGATTTACGTCAGTTCAACGTTGACAAGTCATATAATGACAGATGGTCATTTATGTAGTTAATACCGATTCTTATCGTTTGTTTATTTTGTTGAAAATGAATTGTATTAAACTGTGAATTTCTCTTCTGA
->XM_040439057.1 PREDICTED: Bufo bufo zinc finger MYND-type containing 8 (ZMYND8), transcript variant X7, mRNA 
-TCAAAAGATCTGACAGCCCCCGTGCTCCTCCTGTGTCCCGGGAAGGCCCTCTCTGGTTCCTAGTGTCACCGTTCTCATTGCTCCTTGCACTTTACCTGGATTCTCTGCTCCACAGCTCAGGGACAGGTCTCACAGGATGGCTCCTGCCTGCAAGAGCTGTACAAAGATAATCACTCAGGAAGTGGCTCAGCCAATGGCCTGAAGCATTACATGTGGATTCCCGAAAGCCTCCAATCCTGCCCCAGCTTGCAACAGGGGAGTCTGATCATCAGGCTGAAGTGCCAAGCCCTTTCTGTCTGAGAACTGAGAGTCTGTCCTCCATGTTTTATAAGTATTGACATATAACACTGTAACAATGCATCCACACAGGTAAGCCAGAGCTTGTCTTTTTTTGTAGTTTATTCCCATCTCTTGGACACTGTGCTTTTGCAGGTTGCATTTCCGCGACTTCTCGGGCCAAATTCGCTAAACCAGCAAGTGTTTTGAATTTTGACTTTCTGGAGAGATCACATGGTTGGGTGCCATTAGCCAGTGACTGCTGCTGGGGGTTCCAGGGGTACACTGCACAATTAACTTTTTTGTTTTGTAAAGAGTGGTGGGTTTCTGCACAGCCCCCTTCACTCCCCTGTTCACCAAGGAAGATCTCTGCATTATTGTGTATTCCTGTGTCACATGCTGCTCAGAGGAACATGGAGGCTGCCTCAGCACAAGGCTTCAGCTGACGTACAGGCCACCAAGCAAAGCACACTTTATTCACCCTCTATCTAAAGGACAAGAGCCAGACTAACCCAGGACTGTTACTTTTGATACCGACCACAGAGACTCTCAGCATTTATGCCTGACATACGTCTGGGGCCTAGCTTTGGATTTTTCAAATACCACCATATCTGAAGCCTTTCTCCGGTTTACTTGGTGCCCTGTGGACCCGGCACAGTGTGCGTGTACATGATTTTTCTTGCTTTTTACCCATATATTGTTTTTTGAGATTTTTTTATTTTTTATGTTCTGGATATATGATTTCCTGAGGCTGGGAGCTAACCAATATGGATGTCAAACATTTGGCAGAGGAGGAAGTGAAGATTGAGCCGGAGCTGGTGGAGGGGATGGATGTCACCACTCGATCCAAAGGTCCTGCTGTTGCATATCCAGAGGGATTATCGCAAGAACATGGAGACAGTCAGCAGTCCAACCCAGGCTCAGGGCAGAAAAGGAAGATTTCCAGCCCTCAGCACTCATCCAATGGGCACTCTCCTCAAGATGTATCCGGCAGCCCAAGTAAAAAGAAGAAGAAACCAGGAATGTTGAACAGTCACAACAAAGACCAGTCAGAGCTAAGACATGGTCCGTTTTACTATATGAAGCAGCCACTCACCACAGACCCTGTTGATGTTGTACCGCAGGACGGCCGCAATGACTTCTACTGCTGGGTTTGTCACCGGGAAGGTCAAGTCCTATGCTGTGAGCTCTGCCCCAGAGTTTATCATGCTAAGTGTCTGAAACTGACTGCTGAGCCTGAGGGTGACTGGTTTTGTCCTGAGTGTGAGAAAATCACAGTTGCAGAATGCATAGAGACACAGAGTAAAGCAATGACTATGTTGACCATAGAGCAGCTTTCGTACCTGCTGAAATTTGCTCTCCAGAAGATGAAACAGCCGGGGACAGAACCCTTCCAGAAGCCGGTGTCATTGGAGCAGCATCCTGATTATGCAGAATATATATTTAATCCTATGGATCTCAGTACGCTAGAAAAGAATGTTAAAAAGAAAATGTATGGTTGCACAGAAGCCTTCTTGGCAGATGCCAAATGGATATTGCATAACTGCATTATATACAATGGGGGAAATCACAAATTAACACAAACTGCAAAAGTAATAATCAAGATATGTGAACATGAGATGAATGAAATTGAAGTCTGCCCTGAATGTTATTTAGCTGCTTGCCAAAAAAGAGATAATTGGTTTTGTGAACCGTGTAGCAATCCGCACCCTCTGGTCTGGGCTAAATTAAAAGGATTTCCCTTCTGGCCTGCTAAAGCTCTGAGAGATAAAGATGGACAGGTGGACGCCCGCTTCTTTGGACAGCATGACAGGGCATGGGTTCCAATGAACAATTGCTACCTCATGTCAAAAGAAATCCCTTTTTCTGTAAAGAAGACGAAGAGCATCTTCAACAGTGCCATGCAGGAGATGGAGGTGTATGTGGAAAACATTCGCAAAAGGTTTGGTGTATTTAATTACGCTCCCTTTCGGACACCTTACACACCCAACAACCAGTACCAAATGCTGCTTGACACTACCAATCCAAGTGCTGGTACTGCCAAGACAGACAAACAGGAAAAGATCAAGCTGAACTTTGACATGACTGCATCTCCGAAGATCCTGATGAGCAAACCCATATTAAGCAGCAGTGGAGGCCGACGGATTTCATTAACAGACATGCCACGGTCCCCAATGAGCACAAACTCCTCTGTGCACACAGGCTCAGATGTAGAACCAGACGCTGAGAAGAAAGCAGTGTCCAGCCACTACAGTGCAAGTGAAGAGTCCATGGACTTTATAGATAAGAGTACAGCTTCTCCTGTATCCATAAAGACCGGACATGGTGGCAGTATATCAGGCAGCCCCAAACCTTTCTCACCACAATCCTCTACACCAGTAAAATGTAAGACGGAGAGGAACACAAGCACAGGCAGCATCCTCAACCTCAATCTTGACCGCAGTAAAGCGGAAATGGACTTGAAGGAGCTGAGTGAGTCTGTGCTTCAGCAGTCCACGGCAACCCCACTCATCTCTCCCAAAAGGCAGATCCGCAGCCGATTCCAGCTCAATCTGGACAAAACCATTGAGAGCTGCAAAGCCCAATTAGGAATTAACGAGATTCCGGATGATCCTGATGCCACAGTGGAACACAGTGATTCTGAGGAGTCAGAGAAGACAGATTCTAGTGACAGTGAGTATGGGAGCGACGATGAGCCGAAGTCAAAAAATGATGAGGAAGAAAAGGAAAGTGTGAAGGAAAAGGAACTCCCTCCATCTTCAGTAAAGAAAAAATCCAAGCCCTCAATCCAAATAGAGGCAAAGGATGAATCCAAGAGTGCAACAGCGACAACAGATAAAGCGGATGCAGGGGGTAAGGATAAGCTGGCATCCACTGTAGAGAAGGATGTTCCTGACAAAGGTAAACCCCTGACGCACTCTGCAAAGGAAAAAGTGAAGGGAAAGGATGATACAGACTCTCCTACTGTACACCTTGGACTGGACTCTGACTCTGAGAGCGAACTGGTCATTGACTTGGGTGAAGATCATTCGGGGCGAGAAGGACGTAAAGCCAAAAAGGATGCTAAAATAACAGCAACAAAACACCCAGAAATAAAATCCCCAACCACAGCCAGTGTCAGCAGTCTGCCAGCAGTTGACACCCCTATCATGACCCGCTCTGCATCCCAGGCTGCCCCTGCTGTAGGGGTAACAGTGACTACAAGTTCAGCATCAGCTGCAAGCACTCCGACGGCAGCTACTGGCAGCCCAGTGAAGAAGCAGAGACCTCTGCTCCCCAAGGAGACAGTTCCCACCGTGCAGAGAGTGGTGTGGAATTCTTCCAGTAAGTTTCAGACCTCATCCCAGAAATGGCACATGCAGAAAGTTCAAAGGCAACAGCAGCAGCAACAACAGCAGCAGCAACAGCCGAGCACGCCTGCGCCGTCACAGTCTCCACAAGGGACGAGATACCAGACACGGCAGGCTGTGAAAGCGGTGCAGCAAAAAGAAGTCACACAAGCCACATCCACCTCCACCATAACCCTTGTGACCACCGCCCCACCACTAGCCATGGTGACCAGCCCAGGACAGCCACTGACCACATCAATCACCAGTGACCTGCCCATCGCTACCGCCTCAGCTGATGTTGCTGCTGACATTGCCAAATACACCAGCAAGATGATGGAGGCAATTAAAGGCACAATGACTGAGATATACAACGACTTGTCTAAGAATACCACGGGGAATACCATAGCGGAGATTCGACGCTTACGAATAGAGATTGAAAAACTGCAGTGGCTTCATCAGCAGGAGCTGTCTGAAATGAAGCATAATTTAGAACTAACCATGGCAGAGATGAGGCAGAGTCTGGAGCAGGAGAGGGACCGGCTGATTGCAGAGGTGAAGAAACAAACTGAGCTGGAAAAGCAGCAAGCAGTGGATGAGACCAAGAAGAAGCAGTGGTGTGCCAATTGCAAGAAGGAGGCCATTTTCTACTGTTGCTGGAACACCAGCTACTGTGATTACCCGTGCCAGCAGGCGCACTGGCCCGAGCACATGAAGTCCTGCACGCAGTCAGCCTCTGCTACACAGCAGGAAGCTGACCCTGACCTCAGCACGGATAAAACGGCACAAGCAACAACAGGTACCCAGCCACAGCCTGCTGAAACCACCACAACGCCGAAAGAGAAGGATGGCACAGCTGATAAGAGCAAAGAGAGTGTCACTACCATCCCTGTGGTTGTAAGCCCCAGTGCCGGAGCGGTGGCGATGAGAGCCGGTGTTCAGTATGTGCAGACCACCATGCCGGTCCAGGTGAGAAGAGTGTGACCTGTAAGCATTAAAAACAGCAAGACAATACAGAAACACTACATTGTGCGTGTCCGGAGCCAGCGCCTCGTCCTGTATGTAAATAATGTACAATCTGTGGATGTGATTAAGAGTAGAACCATCTTTTTATATTTGTATTCACTTTAACTTATGAACGTTTATCCGGAGCCACGACATTAAAACACCGATTATGACAGATACTGCTGAAATCCTGCTATCTCGCAGAACGGATGGATGCCAAGGTGTAGATAAAGCAGATTACTCTTGTATCAGTATAATCAGTGTACAAAGGAGCAGTGAATGATACAAGCGTCTATGTGAATAATCACAGCTAATGCCGCATTCATGGCAAGAGGCAGCGGCATTCAATCAAACATTAACCCTAGTGTGGGATCGTCCCGCAGGAACAACCCTAATAACCGGAGAGGAAAACGAAGCACCATATTTATCTGTGGACAACGTTGCAAAAAATATATGGTGGCGCCTTCAGTCTGTTACATTGCCACCACAGATTCACTTTGTATCTTATGTAAAATCACTGCTGATGTCTGTATATGAGGACCCTCTGTATAAAATCATTCCAGTGCCACGCGTTGTACATTTATCACACTGTTGATTTTTCACCATTGTTAATAACGGAGATAGTGTGTACAGTAACCAATGGCGAATACAAGATGGAAGCAAGGCGCCATCAACCCTGAGCGAGAGGCAATATCAGTGGCAAGCGGTTTGAAATGCGGGACTGGCCAGCTTTCCCTTGTGAAACATAATTGCTTTTAGCATATGGAAGTATTTTTTCACATTTTCTTTGTATAAAATTTGTATTAAATTCAAACATTTCTTTTT
->XM_027968038.2 PREDICTED: Ovis aries RAD52 homolog, DNA repair protein (RAD52), transcript variant X6, mRNA 
-AGCGAGTTTCTGCGCGTTCAGTCTGAACAGAGCCCTGTCCGCTCTGCGCGGCTGAGGCGCTACCAGTACACAGTGGAAGAACACCAGGCCATCCAGAACGCCCTGAGGCAGAGGCTGGGCCCAGAGTACATCAGTAGCCGCATGGCTGGAGGAGGCCAGAAGGTGTGTTACATCGAGGGTCACAGGGTCATTAATCTGGCCAATGAGATGTTTGGCTACAATGGCTGGGCGCACTCCATCACTCAGCAGAACGTGGATTTTGTTGACCTTAACAATGGCAAGTTCTACGTGGGCGTCTGTGCGTTTGTGCGAGTCCAGCTGAAGGATGGCTCGTATCATGAAGATGTGGGCTATGGTGTCAGCGAAGGCCTTAAGTCAAAAGCCTTGTCCTTGGAAAAGGCCAGGAAGGAGGCAGTAACAGATGGGCTGAAGCGGGCGCTGAGAAGTTTTGGGAACGCACTCGGAAACTGTATTCTGGACAAAGACTATCTGAGGTCACTGAACAAGCTTCCACACCAGCCGCCTCTTGAAGTGGATTTAACTAACGCAAAGAGACAAGATTTTGAACCATCTGTTGAACAAGCCAGATACAGCAGCTGCCAGCAGAATGCGACCCTGGAGCCCCCTAAAACCCAGGAGGCGACCTCTCCATGCAGACGGAGCCACTTGGCTGGACCCCACACCGTGACGCAGGGGGCCACGGAGAGCAGCTCCCGAAGCCTGGCCCCCGGCACCGCGGAGAGTGAAGCCACGCTCCAGCGGAAGCTCCGGCAGCAGCAGCTGCAGCAGCAGTTCCGGAAACAGATGGAGAGACAGCAGCAGGCTGCCACCTCTGCTCTGTCCTCTGGAAGGACGGACCAGGCACAGCCGCCACCGGTGCCTCCTACCAAGCCCAGCCTCCCCAGGACCCGCTCACCTTCAGAGCCACTCACCCAGACAGACCTGCTCCCAGACAGTCTTGAAATGTGGGACATGGCTATGGATGCAGAGGACAGCGTGCTCAAGACCTTTTCGAAACCAGAACCACCGGAGACCCCTGCCATCTCGGTCCTGAAGAACCACATGGAGACCCAGAACAGGATCCCACCAAGCCTTTGCCACCAGAATCCACAGGCACAATCTGGACCCTGGCACCTCCAAACTTCCAGCCTTAACCAAGACACCACAGGGAATTGTGACTCCTCTAGGAAGAATCAGGACATGAAGAAAAGGAAACTGGACCCACCTTAACCACGGCTCAGGGCACCTCCTGAACTGTCCTGATGGGACTTCATTTTGGTCATGAAATGACTGGTCCTGCCTGAGGAGTGCACTCTGCCTCAGGGCTCTACCTGCTTCATCCTGAACTCTGCTGGGGGACTCAGCACCTGCTCACATCAAGTCGGGCATTTGGGAAGCTCTGTAGAGACTCGGTGCCTTTTCTTGGGCTCCTCACTCTTTATTCCTAAGCTATTGTGTTAATGAAGACAGAAATCACCTCAGCCTGTGGTGCGTTCCTGAGTGACCGCTGACCTCTTGCTGTGGGGGCCCCCCGTTATCTAACGCTGCCATGCAAGATTGCAGTCTTCATCACTATTGTTCATCGGCTCATGAAACTACTTCCCTTTTCTCCTAAGACCAAAGAAAAGGTATTTTTAAGAAAGCAAAATTAAATCCTACCCTGTAACAATGTAA
->XM_028824534.2 PREDICTED: Erpetoichthys calabaricus F-box and WD repeat domain containing 8 (LOC114668659), mRNA 
-CGCTTTTGGTGACGGAAAAGGCGGTGCATCACTTCTTGACTCCCCATCTGTTATGGATGTGCTGTAAATAAATATTTGCGGCGCCGTGCGCAATGGAGTTGGAACAATTCAGAGAGCAGTGGAAGAAAGAACTAGCGGTGCAGCGGAGTGCTATCGGTATCGGCCGGAAAGAGGCACGACGGTTTCAAGAAAGTACTCGTCCTGAGGTGTTGAAAACAAACAGAAAATTTAAACATGAGTCGGAGCTCGTTAATGAACAAACTACAGACGCAAAGACGGGAACGGTCTCGTTGCCCGACAGACCCCCGAAAAAGAGGTGGTACCCACACGGAGATCGACCGCAACATCTGCGGAAAGCGCCGCGGGAAGAGCGTTTGCTGGATCGGTTAATCCAAGACTTGAATGAAATTAATGAGATACCATTTTTTGACATGGATTTGCCATATGAATTAGCCCTGAAAATATTTCAGCATTTGAACACAACTGAGCTTGGAAGGTGTGCCCAGGTGAGTAAGGCTTGGAAGATACTTGCTGAAGATGAGCTGCTTTGGTACAGACACTGCCTGAAGGAAGGACATTTGATTGGGTCAAGTATATCAGACTCGCCCTGCTGGAAAAGTACCTTGCGTGATTGTCGGCAGATGGAACACACGATGCGGACTAATTGGAAGAACCGTGTCGGGGCCATCAGCCAGCTGCAGTATGAACTGGGAAAGGTGCTGTGTGATGTCAACTCATGTGCTGGACATGTTATAGCTGGGTACACTTCCGGAGATGTGAGGCTGTGGGACACTCAGAATTTGGATATTGGTTCGCCTTACCTGAGACCTAGCCATGTGTCCAGAGAAAGTGCCTTACGGCCACATGTCAGTCATGTCTGTGTGAATGAAAATGTGGCTGTGGCTGCCTATGAAGATGGCATCATAGATGTCTGGAGCATTGAAGCTGGCCGGGAACCCATCCACCATTATCAGCACCTGCAGCGGGTGCAGGCTTTGGCTTTGGGGGCTGAGGGGACCACTGTAGCCTCTGCCTCTGGTAAGCAGGTGCGAGTGGAACAGCCAGATGAGCAGGGCTACTGGCAGACAACAGCCCAGTTTGAGCTGGAGAAGTTGGTGGACTTTGCTCAAATCATTCCAGGAGTGCGTCCTCGGACACTGGCTGTTGTTGCTGCCTCTGACACAGTCTATCTCCTAGAGCCTGGCAAAGACCCCAGCATCCTTCACTGTGTGTACAGTCACCCAATAACCTGCCTTGACACCTCCTCCTCACAGGCTGCTGTGGGTGTGAAGAGCTTTGGGTGGGCAATGAATATGGGAAACAAGATTGATGTGTACAGCTGGGAGACTGGCCAGGCAGTTGTATCCTTGGGGTCATCCAGTGGAGATTTTACTTGTGTCAACTTGAAGGACAGTCCTCCAAATCTGCTGGTGTCTGGCAACAAAGACCGAAGAGTGCGGGTGTTTGATCTGAGGACAGCAAAGTCTGTCACATCTCTGTACGGCCATCACATGGGGGTTTCTGCGGTGCAGGCAGATGACTGGAAGATTGTAAGCGGTGGGGAGGAGGGTCTGCTCTGCGTCTGGGAAATGAGGATGGCAGCCAAGCTCTGGGAAATGCACAACAGGCACCCTGTTCGACATATCCACTTCCACACCCAGACCTTAGTAACAGCTAATATTCCAGACGAGAAGACTCCCAGGGGAGCATGCATCACCGATGATGACCTCACTGCACATCGACGGCACAGAGGGACCATCTACCTGTACGACTTTTCTGTGGACATGTCCAGCACCGATCACATCCTTCCTATCTGCCGCTCAAGTTACGCCGAGTCCCATGGTTATAACTACAACATTGGGCTGGCCGTTCCATATGATAACATCCTCGCCGCTTCTGTGGCGACCAGGCCACACGTGTCTTGAGCAAGACTAAAGACTGTCATGGAGGAGGAGGACGACATTTCTAATGGATCTGAGCACACATTTGAACACCTCTTGTCATTTTCCAGAAGTGTTCCTTTTAATATTTATTTTTCAATATGTTAGTATGTTAACATTTTTAAAATCTTAAAAGACAGTTCACTGCACAGTGCAGATGTGTCATACACAGGGGACTTGGCACAGTTCAGGTTAAAGTGAAAGCTTCAGTGTGGAGTTGTGCAAGCAGGACGACGGGCTCTGTGATTCATTGATGGCTCTTGTCTTGCACGTCGATCATTTTCTCTTTAATTATTCCTGCAAGTTGAGGAGCTGAGAATCAGTTCTCACGTTAACTTACCCGTCAGCCTTGCTCTTGCACAGAGATTTGTGTATATTGTATATAAATTGTATCATACTCCAGTATTTTGCAATGTCCCTAATGATTTATTTATTTCTTGTAAACACGTAGTTCTGATGT
->XM_045577126.1 PREDICTED: Pipistrellus kuhlii transient receptor potential cation channel subfamily M member 4 (TRPM4), transcript variant X6, mRNA 
-TCCGGGCCGGCGGCCAGCCGGGAAGCGGCAGATCCGGTTTGTCCGGGGCGGACCTGAGGTCGGGGTGGCGGAGGGAATGCGGGGAGCCGGATAGGCGGCGGCGGCATGGCGGGCCCGAAAGAGCAGAGCTGGATCCCCAAAATCTTCAAGAAGAAGACATGCACCGCCTTCATCGTGGACCCCGCAGACCCGGGAGGGACCCTGTGCCAGTGCGGGCGCCCCCGGAGCGCACACCTGGCTGTGGCCGTGGAGGACGCGTTCGGGGCGGCCGTGGTGACCGAGTGGGACCGGGACCTGCACACCACGGAGAAGCCCACCGACGCCTTCGGGGACCTGGACTTCCTGGGCGCCGGCCGCAAGGCCAGCAACTTCCTCCGGCTCTCGGACCGCACGGACCCGGCCACGGTGTATAACCTGGTCACACGCACCTGGGGCTTCCGGGCCCCGAACCTGGTGGTGTCGGTGCTGGGGGGCTCGGGGGGCCCCGTGCTCCAGACCTGGCTGCAGGACCTGCTGCGCAGCGGGCTGGTGCGGGCCGCGCAGAGCACAGGGGCCTGGATCGTCACCGGGGGGCTGCACACGGGCATCGGCCGGCACGTCGGCGTCGCCGTGCGGGACCACCAGACGGCCAGCACCGGCGGCACCAAGGTGGTGGCCATGGGCGTGGCCCCCTGGGGCGTGGTCCGCAACCGGGAGGCCCTCACCAACCCCAAGGGCTCCTTCCCCGCCAGCTACCGGTGGCGCGGGGACCCCCAGGACGGGGTGCAGTTCCCCCTGGACTACAACTACTCGGCCTTCCTGCTGGTGGACGACGGCACGCACGGCCGCGTGGGCGGCGAGAACCGCTTCCGCCTGCGCTTCGAGTCCTACATCGCGCAGCAGAAGACGGGCCTGGGGGGGACTGGCATCGACATCCCGGTCCTCCTCCTCCTGATTGATGGGAACCAGGAGATGTTGAAGCGGATAGAGAATGCCACTCAGGCTCAGCTCCCCTGCCTCCTGGTGGCGGGTTCGGGGGGCGCCGCGGACTGCCTGGCGGAGATCCTGGAGGACTCTCTGGCTCCGGGGAGCGGAGGGGGCCGGCGAGGGGATGCCCGAGACCGGATCAGGCGTTTCTTCCCCAAAGGGGACCCCGACGTCCTGCAGGCCCAGGTGGAGCGGATCATGACCCGGAAGGAGTTGCTGACAGTCTACTCTTCGGAGGACGGCCCCGAGGAGTTCGAGACCATCGTTCTGAGGGCTCTCGTCAAGGCCTGCGGGAGCTCCGAGGCCTCAGCCTACCTGGACGAGCTGCGCCTGGCTGTGGCTTGGAACCGCGTGGACATCGCCCAGAGCGAGCTCTTCCGGGGTGACATCCAGTGGCGGTCCGTCCACCTGGAGGCCTCCCTCATGGACGCCCTCCTGAACGACCGGCCGGAGTTCGTGCGCCTGCTCATCTCGCACGGCCTCAGCCTGGGCCACTTCCTGACGCCGGCGCGCCTGGCCCAGCTCTACAGCGCGGCGCCCCCCAGCTCGCTCATCCGCAGCCTGCTGGACCAGGCGTCCCCCGGCGCCGGCGCCAAAGGCCCGGCCCTGAAGCCCTCCGCCGAGCCCCGGCTCCCCGACGTGGGGCGGGTGCTGCGGCTGCTGCTGGGCGAGATGTGCGCGCCCAGGTATCGCGCCTGGGCCGCGGGGGACCCCCACCGCGACCACGGCTGCAGGGACGGCGGCGGCGGCGGCCTGGAGAGCGCCCAGCTGCTGTGCGTCAGGACCCCCTCGGAGCTCATGCTGGACGCGGTGCTGGGGCAGACCCCGTGGAGCGACCTGTTTCTCTGGGCGCTGCTGCTGAACAGGGCGCAGATGGCCCTGTACTTCTGGGAGATAGGCTCCAACGCCGTGGCCTCGGCTCTGGGCGCCTGCCTGCTGCTCCGGGTGCTGGCGCGCATGGAGTCTGAGGCCGAGGAGGCAGCTCGGAGGAAGGAGCTGGCAGCCAAGTTCGAGGGGCTCGGTGTTGACCTCTTCGGCGAGTGCCACCGCAGCAGCGAGGAGCGTGCCGCCCACCTGCTGCTCCGGCGCTGCCCGTTCTGGGGGGACGCCACCTGCCTGCAGCTCGCCATGCAGGCCGACGCCCGCGCCTTCTTTGCCCAGGATGGGGTGCAGTCTCTGCTGACCCAGAAGTGGTGGGGGGAGATGGACAGCTCCATGCCCATCTGGGCCCTGGTTCTCGCCTTCTTTTGCCCCCCACTCATCTACACCAACCTCATCACCTTCAGGAAGTCAGCGGAGGAGTCCACACAGAAGGACCTGGGGTTTGACATGGACGGGAGCCTCAATGGGGAAGGGCCTGTCAGGCTGACCCCGGGCCTGTATGACCTGGGCCGCACAGTCCTCTGCCTGGACTTCATGGTCTTCACGCTGCGCCTGCTGCACATCTTCACGGTCAATAAACAGCTGGGGCCCAAGATCGTCATCGTGAACAAGATGATGAAGGACGTGTTCTTCTTCCTCTTCTTCCTCGGAGTGTGGCTGGTGGCCTACGGGGTGGCCACGGAGGGTCTCCTCAGGCCCAAGGACCAGGACCTCCCACAAATCCTGCGCCGCGTCTTCTACCGGCCCTACCTGCAGATCTTCGGGCAGGTCCCGCAGGAGGAGATGGACGTGGCCCTCATGGAGCTCGCCAACTGCTCCTCGGAGGCGGGCCAGTGGGCGCGCCCGGTGGGGGCCCAGGCCGGCTCCTGCGTCTCCCTCTACGCCAACTGGCTGGTGGTGCTGCTCCTCGTCATCTTCCTGCTCGTGGCCAACATCCTGCTGGTCAACCTCCTCATCGCCATGTTCAGCTACACCTTTGGCAAAGTACAGGGCAACAGCGACCTCTATTGGAAGGCGCAGCGCTATAGCCTCATCCGGGAATTTCACTCTCGGCCCGCGCTGGCCCCGCCCTTCATCATCATCTCGCACGTGCGCCTCCTCTTCCGTCGATTGCGCAGGCACAGGGCCAGACTGCCGGCCTCCCCCAACCTCCAGCATTTCCGGGTCCACCTCCCTAAGGAAGCCGAGAGGAAGCTGCTGACCTGGGAATCGGTGCGGAAGGAGAATTTCCTGTTGGCGCGCGCTAGGGACAAGCGGGAGAGTGACTCAGAGCGTCTCAAGCGCACGTCTCAGAAGGTGGACATGGCCTTGAAGCAGCTGAGACAGATCCGCGAGTACGAGCAGCGCCTGAAAGGGGTGGAACAGGAGGTCCAGCACTGCAGCCGCGTCCTGGGCTGGGTGGCCGAGGCCCTGAGCCGCTCTACGTTGCTTCCCCCAGGGGGGCCTCCACCCCCGACCCCGCCTGGGCCCAAAGACTGAGCCCTGACGGCGGACTTCAAGGAGTAGCACCATGGGCGGTTTTTGCCCCCTGGACCCCAGTAGGTGGTGGCCCTGTCTTGAGGTGGGCCCTGTGCCATGGACTGGATCGCCGTGGGGACCACTGCAGGAGTCTCACCCGTTCGGACCACAGCAGGCCGGGCCCCGCCCAGAGCCAGCCCCACTGTGGGAGGTGCCGCCTCTGGAGGCCAGGCTGGCCCCTCCGCAGGCCCTGCCCCGGCCCGCGGGGCTGGAGAAGGCGTCAGGTCCTGGGGGCACAGGGACCACAGACCGCACTCAGCTCCCCACACTGGGGAAATAAAGCCACGTGAGCGTC
->MT775861.1 Lolium arundinaceum CDF1 (CDF1) mRNA, complete cds 
-ATGGGGCAGTACAGGTCGGCGGCCGGAGGAGGAGGAGACTGCCAGATCAAGCTGTTCGGGAAGACCATCCCCGTGCCGGACGCCAGCGCCGGTGCCGACGACAAGCAGAACCTTCAGCACAGCAGCAGCAGCATGATAGAACCAAGAGTAAAAGAAATCGTCCCTCAGGACTCCACGGATTCGCCTCCACAGCCCGAGGTTGTGGACATGGAGGACCCATCTGCTGTCAAGAACTCGTCAGAAGATCAGCAGGAGGAACAGGGTGACACGGCCAATCAGAAGGAGAAGCTCAAGAAGCCTGACAAGATCCTGCCCTGCCCCCGGTGTAGCAGCATGGACACCAAGTTCTGCTACTACAACAACTACAATATCAACCAGCCGCGGCACTTCTGCAAGAATTGCCAGAGGTACTGGACGGCAGGTGGTGCCATGCGCAACGTGCCCGTGGGTGCAGGCCGTCGCAAGAGCAAGAGTATAACGGCCGCTTCCCACTTCCTTCAGAGGATCAGGGCCGCTATGCCCGGTGATCCTCTCTGCACCCCAGTCAAGACCAACGGCACGGTGCTCAGCTTCGGGTCCAGCACATCCACCTTAGACCACACAGAACAAATGAAGCACATCAAGGAGCTCATCCCAATAACCCGGATCGAGAACACCGATGACCCATCGGTTGGGTCTTGTGCTGATGGATGGGCCAAGGCAGAAGAGTCAAACCAAATGAATTCAAGGGAGAGAGTTGCAGCAGATGAACCCGCAAACGTTGTGCAGCATCCATGCATGAACGGGGGAACCATGTGGCCATTCGGTTACGCACCATCACCTGCCTATTTCACCTCAAACGTAGCAATTCCATTCTATCCAGCACCTGCTGCTTACTGGGGCTGCATGGTTCCGGGAGCCTGGAACACTCCATGGCAGCCACAGTCTCAATCTCAATCTGGCTCATCACCTAGTGCTGCTTCTCCAGTATCAACAGTGTCGAGCTGCTTCCAGTCACGAAAGCACCCTAGAGATGGAGATGAGGAAAGAAATGCCAACGGTAATGGCAAGGTGTGGGTGCCGAAGACGATCCGGATTGATGACGTAGACGAGGTGGCCAGGAGTTCTATCTGGTCGCTTATTGGGATCAAGGGCGACAAGGTGGGGACAGATGATTCCAGAGGGTGTAAGCTTGCAAGGGTTTTTGATCCAAAGGATGCGGCAAAGACGACAACTCACAGAGTTATCAATAGCTCGCCGTTCTTGAAGGGGAACCCAGCTGCACTATCGCGATCAGTGACCTTTCAAGAGAGATCTTGA
->XM_033534398.1 Aaosphaeria arxii CBS 175.79 glycoside hydrolase family 5 protein (BU24DRAFT_56693), mRNA 
-ATATACACTACGCTATTACACTACGAGCCGCCGCCGCCGTTATGGTTTGTTCGCTCGCCACAGCTCCCTCCGTGTCGAAAAGGGTAATGGTTTGATTTACTTCGAGATGGAATTGAATTTCGAGGACTTTATATTCGAGGCTTTTGCCTGCAATTTTCGAGTTTGATTTCTGTAGCAATCTCAATTGTCAATTACTGAGGTCGAAGAATCATGCTGTTTGATCTGCCAACTTTCATCTCTTTGGCCCTTGTGGCAAGCCAGGGTACGTCGGCTGCTGCTGTCATCGGCAAGAGACAGCAATCGTCAAGTGGATTCGTCACTACGGATGGAAACAAGTTCTTGCTTGATGGGAAGGACTTCTACTTCGCCGGTAGCAATGCCTACTATTTCCCTTTCAACGACAAGGCAGAAGACGTTGAAGCCGGCCTCACTGCCGCAAAGGAAGCAGGTCTGAGTGTATTCAGAACTTGGGGATTCAACGATAAGAACAAGACTTATGTCCCAGGTGGTTTGCCCCAGTATGGAGGCGAAGGTGCGGGAGATACCTCGAATGTGTTGCAGCTGTGGGAGAATGGCACTTCGACTATCAACCTCAAGCCATTTGACAAAGTTGTTGCTGCAGCCGAGAAGACTGGCATCAAGCTTGTCGTTGCTCTGACCAACAACTGGGCGGACTACGGTGGTATGGATGTTTACACCGTACAACTAGGTGGCAGATATCACGATGATTTCTACCGCCTACCGGCGATCAAGACCGCATTCAAGAGATACGTCAAGGAGATCGTAACCCGCTACTCCAACTCCAGCGCGATCATGGCCTGGGAACTCGGCAACGAGCCCCGCTGCGGCGCCGACGGCACGCGCAACCTCCCGCGCTCCGACGACTGCAAGCCCGAGCTCCTGACCGCCTGGACGGACGAAATGAGCACGTACATCAAGAGCCTCGACAAGAACCACCTCGTGACCTGGGGCGGCGAGGGCGGCTTCAACATCCAAGGCCACGAGGACGGGTTCTACAACGGCTGGGACGGCGGCGACTTCGACGTCGAGCTCGCGCTCGAGAACATCGACTTCGGCACTTTCCATTCGTATCCGGATTGGTGGTCGAAGACGGTGGAGTGGACGGATCAGTGGATCAAGGACCACGCTGCGTCGGGTCGAAAGGTCGGAAAGCCTGTCGTTCACGAAGAATACGGATGGCTCACCGACGACAAGCGCCAGGAATACCTCGGCAAGACGTCCAACATCACTCGCATCGAGGCGCTCGGCCTCTGGCAAGCAACCTCCATCGCCGAGAAGATGCCAGACATGTACTGGCAGTTCGGCTTCTCCAACTACTCGTACGGAAGGAATCACGACGATGGGTTCACCATCTTCCTTGACGACGCGGAGGCTCAGACTTTGATCTACGACCATGCTAAGAAGGTTAATGCTTTGAATGGGAACTCGACGCTGCGTAGGTAGGACGTT
->XM_050200589.1 PREDICTED: Aphis gossypii uncharacterized LOC114125601 (LOC114125601), transcript variant X2, mRNA 
-TACATTTTAGTGTTATTATCTATATCATTTTACATAATACTTATAACAATTATATTTATATAATAGGTATGATTATATTATACATATTATTTTATGTTAATCTATGATTCATCAGCAGAATAGTTAAAATAAACACTAAATGGCCACGATAAGACAACAAATCAAACGGAACACGAGAATACACAAGAACGTCAAGAGCCTAAACTCGAAGGCTAACAGTTTGGTTCTTATTATGTAATGATTTATAGGTAGTTGTTCATATTATAATTCGCATCATTTGCCATTTGTATAAAAAACGATTCGTTGTAACCCTTACATTATGGATTTCGAAAGTGAATTTTTGAAGACTTATAGAATTTTGAAATGGGATGAGTTCACTGTGCTGAATAATGACCGTATATCAATCAACGAGAAAATCACTAACAAGGTGATAACTAAACATGAGTTGTTACTGCAGTTTAAAGCAGAGCTGAGTTTGCTTAATGCGTGTAAACACAAAATCAAAGACGAGTTGGAACAAGGTTTAGATGTTATTGATACTCAAGTACTTGTCCTCCTAAGCAAACGTGTTATTGAATTGTTTGATCATATGCATGTTCTGTTTTCTATTGATGAGAAGCTGTTATTTTATTTTATCAACTTTTGTCAAGACAATGTAAGCTACATACATGTAGACCAGCTAGATATTTTATTAGATGCTGTTTTGTGTACAGAAAATAATCAAAAGATTTGGATACGATTATTAAAGCTTTATTTGGAATTAAATAGTTTTGATAAATTGATGACTGTTTTTCAAGAAGGTGTTCGTTCATTAAAAAAAAATTCACTACCTTTATGGAAGATTATAATTCGATTTATGCAAATTAGGCGTCCTGATATGTACAAAGACATAGATGCAACTCGTAACCTGTTCAATGAACTAAAAAAGTTAAAGCCACCATGTTATAAATTGTATTTAATAATGATGGCTATTGAATCAGAGACATCAGATTTTGAATTACTGACTGTTAGAAAATTGTATGATGAAGCTTGCATTTTATTTGGCACAGATAACATTGAAGTATGGCTTGATTATATTCGTTTTGAACAGACTGATGGCTCCCCAAAATTAATGGAAAGTATTTATACTAGAGGTTTATGGAAACTGGAACCGAATTTAAAAAATACTTTCATAGAAGAGTATAATAATATTAAACGTGAATTTATGAATAGTTTAGGAAAAGAAGTTATAGTCATTGATGATTGAAATATATATTATATATTATAAACAAAAAATGGCGAATTTATTTAGAGATCTCCTTATTTATTTAATTTTTAAATTAATATTATAAGTGGGTCACTTAATAATATTAATACATTTGTATACTTTGGTTTTATTTGGTCATATAAAACAGTTTATTGTATTAGGCAAACAGTGTAGTACAGTGAAACTTCTGTTAATAGTTTACTTTGAAAGACTTCTAAATAAATAAATATGTATAATATGTATGTACAACATCACTTCTGCAAAGTTGCATTTTTTTCTGTTTTCTATAGTTGAACAGTACAAAAGTCTCACTGTACCATTTAGACGTCACAGTTAATGACACAATCTTAAATTTAACAATAGAAGGTTAATGGTATTTTTTTCTTTTATAATGTGTGTAATTGAATAATGTTTTATGTTACTTAATATTTTAAGCACTATTATATTTATAAATATATCATTTTATTTTATTTACATTGTCATAATTGTAATTTGTGCAATACCTATTAAAATAGACGGTTTGATGATAATAAATTATAATTTTTTACCTAA
->XM_026522476.1 PREDICTED: Papaver somniferum putative F-box protein At1g52490 (LOC113272669), mRNA 
-ATGGAGAAGAAGTTTCCTAGTGACATAATGCTAGATATAGTATCTCCCTTACGGCACGAAACCATAATACATTGCAAACTAGTTTGCAAACCCTGGCGAGATATACTAAACAATATCAAGGTAGGTGTCCTTTTTAGGTTTGGGAAACCTGCTTTCAATTTCTGTTATAGAGGAGAGCAATACGATGATATTGATATGCATGAGAATTACTCTTACACGACACTGGTGGAAATCGATAAGCATCGGCCTGTCGAGCTAGAACCCTTGTCTGACATGGTTGGTTCATGTAATGGTTTGGTTTGTTTTTCTGTAAGGCGCAAGTTCACTGTTGCGTATGATCCCATCTACATCTGTAATCCCGTCACAGAGGAATATGTATATCTTCCAACATTCAACTATGATGAACCATATGATGATCTCCGGGTAGCTGGTTCTTTTGATTGTGGTTTTGGTTATCATCGTTTCATGGATGAGTACAAAGTCGTTAGAATCCACGGGGCTCTGAGAGATTTTAGTAAACGCTCGCAGAGCCGGAAAGTTGAAGTATACACTTTGGGTAGTGGTCATGGGTGGAGAGATAAAGGAAGCATCGATCACTTATTAGTTTGGGACCATGGAGTTTGTGCAAATGGAGCCATTCATTGGGTAGAGTATCGGAAAAATAAAATTGTGGCTTTCGATTGTAGCAAATGA
->XR_001996655.2 PREDICTED: Juglans regia pentatricopeptide repeat-containing protein At5g61990, mitochondrial (LOC108994206), transcript variant X3, misc_RNA 
-ACCATCTCTGCTCTGCCTCTCGAGTCCGAGTCCCCGCAGCCGTCTCTCACGCCGAGCCCCTCTCTCACGCCGTCAACAGCCCCTCGCCGTCGACACTGTTATTCCGTTCTGTTCTCCTCCGCTTCCAGTTGTTCCCGAGGCTACAGAATCACAGATATTGTTTTCCCCTCTCTCGGCGAGCTAATCGGTCAGGAATAAAATGGGTCTACTTTCTCAGAGAAACCTCCTTGCATTTGCACTCCGAAATCGAAATGTTGTCGCAGAAGCACAACCATCAAGACTTCTTTTTGTTTATGCCAAATCCTTCAGCTTTTGCACCTCGCAGACTTCAAAACAGAATGAAGAGCTCACAATCGAAGAAATCTCCGCCTTTCTCAAGCAAAGCAACTGGCAGTACCTCATGGAATCGTCAAATATACCCAAGAAGCTGAACCCAGAGGTGGTTCGGTCTGTTCTTCAACATAACTGGGTGAGTGACCCCAAACGCCTCCTTCATTTTTTTGATTGGTCCGCTTCTTTGATGGGCGTTCCTCAAAATCAGTATTCTTTCTCGATTCTTGCAATTGCTCTATGTAATTCGAGGCTTTTCGCCCATGCTAATGGCGTCTTAGAGCGAATGGTGGGAACCCGGAAGCCGCCGTTGGAAATTCTTGATTCCATTGTTACTTTCTTTGTAGAATGTGGTGGGTCTAATGTGGTAGTTTTTGAGATTTTGGTGAATGCTTATAGGAAAGTGGGGATGTTGAATGAGGCTGCTAGCGTGTTTTTGGGAATTAAAAATGATGGGTTTTTGCCTACTTTGGTGTTTTGTAATTCTTTGTTGAAGGACTTGGCAAAGTGTAATAGGATGGAGTTGTTTTGGAAGGTTTATGATCGGATGTTAGAGGCTAAGATGAGTCCGGATGTTTATACTTATTCTACTGTGATAAATGCGCATTGTAAGGTTGGGAATGTTGAAGAGGGTAGGAGGGTGCTATTTGGTATGGAGGAGAAGGGCTGTAGTCCTAATTTGGTTACCTACAATGTGGTGATTGGCGGATTGTGCAAACATGGGGCTGTTGATGAGGCTCTTGAGTTGAAGAAGTTCATGGCTGGGAAGGGGTTGATCCCAGATGCCTATACTTACTCTATGCTTGTTGATGGGTTTTGCAAACAGAAAAGGTCAGAAGAAGCAAAGTCGATATTGGAAGAGATGTTTGGTATGGGTTTACGTCCTGATCACATTACCTACACTGCTTTGGTTGATGGGTTCATGAAACAAGGTAAGGTAGAAGATGCCTTGAGAATCAAAGATGAGATGGTTGCCCGTGGAGTAAGCTTAACTTTGGTAACATATAATGTACTTGTCGGTGGGTTTTGTAAGGTTGGTGAGATGACGAAGGCCAAAGCTCTCATCAATGAGATGAGTGTGATGGGAATAAAACCAGATAGTTATACTTTTAACTCTTTAATTAGTGGTTATTACAAAAAGAAAAATATGGTTGAGGCTTATCAACTTCTTCTTGAGATGAAGAAGTGGAACTTGGCACCCACAATATTCACTTATGGTGTGATAATAAATGGCCTATGCCATTGTGGAGATCTGCAAGCAGCTAATGGTGTTTTGGAGCAGATGATTGCAGGGGGTTTGAAACCAAATGCTGTTCTATTCTCAACTCTAATCAAAGGTCATGTACAACAAAGTAGATTTGACGAGGCAATAACGATATTAAAAGGAATGGAGGAAAAGGGCGTTCTGCCTGACATGTTTTGTTATAATTCTCTTATAATTGGCCTCTGCAAGGCCAAAAAAATGAAAGATGCTGAGAATTTCTTGGTTGAAATGATCGAGAGGGGTCTTAAACCTAATGAATATACATATGGGACTTTCATCGATGGATATGCTAAGGCGGGGAATATGCAATTAGCATACGGTTATTTCATAGAAATGCTAGGTTGGGGTATAGCGCCCAATGGTTTGATCTGCACGGCCTTGATTGATGGGCACTTTAAAGATGGTAACGTAACTGGAGCTCTTTCTGCATTTCAATTATTACTTGGACAAAGGGTCATCCCAGATATCCAGACTTATAGTGTTCTCATCCATGGTCTTTCTATGAATGGAAAAATTGAGGAAGCAATGGAGGTTTTATCTGAAGTCCTTGACAAGGGTCTGGTGCCAGATGTTTTTACCTACACCTCTCTCATTTCTGGATCCTGTAAGCAAGGTGATTTAGACAGAGCTTTTCAACTCTATGATGAGATGTGCCAGAAAGGCATCACTCCAAACATTGTTACTTATAACTCCTTGATCAATGGACTTTGCAAGTCGGGTGACATTGAGAGAGCTAGGGAACTGTTTGATGGAATCTCAAGAAAGGGTTTGGCTAAGAATGGTGTGACCTATGCTACGATTATAGATGGATACTGCAAATCTGGAAATTTAGTTGAGGCATTTCAATTAATGGATGAGATGCCATCTATGGGGGTTCCACCTGATTGTTTCATCTATTGTGCCCTTGTTGATGGGTGCTGCAAAGCAGGAAACATGGAGAAGGCCCTTTCCTTATTTCATGAGATGGTGCAGAAGGGCTTTGCTTCCACACCTTCTTTTAATGCTTTGATTGATGGCTTCTCCAAGTCCGGGAAATTGGATGAAGCTAACCAATTGTTTGAAGACATTGTTGATAAGCATGTGACCCCAGATGATGTGACCTACACAATTCTGATCAATTCGCACTGCAAGGCTGGATTAATGAAGGAAGCTGAGAAGCTCTTTCTGGAGATCAAAAAAAGAAATCTCAAGCCAAATATTTTAACTTACACTGCACTCCTGCATGGGTACAACAACATAGGGAGCAGAGATAAGATGTGTGCTCTTTTCGATGAAATGGTGGCAGCGGGGATTGACCCTGATGAAGAAACATATGGCATGCTCGAGAGAATTCCGTTGATATCTGAGGCTGCAAATACAGAGAGGCCATCTTCAATCACAACTAGCCTTTTCATTGGTGGGGCGCTGGCTGCAAGATCTGATATCTGACAATGAAGATACAAATATTAGTAGTATCTTTGAAGAAGCTTCTGATTCTATTGATCATGTTGAACAAATAGGTAGAAGTGCCACCTTGGTGATGGCGTACTTAATGCTCAGGAAGAACCTAACTCTACTAAAACGAGTTCACCACTGAGCCCAGCGCAATGATGGCTTTGCTAGGATCCTTTTGGATCTGGATAGGAAATTACATGGGACACAGCATCCATGGAATGGCGACAACGAAAGCCAATGATGAAAGTTTGCCCCATTTGTGGGAAGAAGGCCGGTCTGAGCAGCAGTTCACTTAAGCTTCATTCGCAGAAATCACACAAGAATCTTTAATCAGGAAGTGTGGACAGTGGCATGACCATGGAAATACAAAAGTCTTTGACAGCACTCAAACGGGGTCTGCCCGAGTCGAAACTGCTCCCTCGCCTGCGTCGATTGTGCTCTGCCCACCGCCTCCAGCGACACCATCTCTTTCCAGCGACACCGAGGCCGTCTGCACAGCTTCGCCACACCCCTTGTCGCCCAGCTTTCCTCCCTCCCCATTGCCAGCCCATCTCCTTTTCTTCCTCTCCCCACCCCTCGCATCTCCCCCCACCCGCGCCAGTGTACCGGATTCACTAAACGCCCAGCCCTCGTCCCACAGCTCTCCTCCCTCCCTGTTGCCCTCATCGTCCCAGAATTGATATCAACGATCCCTAGAGTCCCTGCTTCAGAATCGACATCAATGAATCTACATCTTGGCAGCCAGGTCCGCTTTATCTGAAACTCCTCACAAAGCATCACCAGCAACTCCAAGAGTTGCTAGACCAAGCAGGGGAGTAGCTAAATCATAATCTGATTCACCCTCTCCTTTGCAAAGTTCACGCCTTTCAGTTGATCGGTCTCCACGATCAGTTCCCTTGAAGCCCACCATAAGATCACCAAAACTTGCTACCCCACCTGAAGTCACTGCAATTGAAATTAATAACCTTTTTCGCGAAGACCTCTTCCTTGCCAAGGTTGGGATGGAGTGCGGCATCGGGATTTTGCAACGTCATTTTCAAGATTGTAAGGGAATCACAACATGAAGCTTTTGCAGCTCTTCATCACAGCATCAATTCCAGTCTTGAAACTGCTCTTGATTTCTGGACTTAGGGTTTATGCCAATCAGAAGAAGATAAACTAATAGAAAGAGAGAATGATCTTCACAAGCTTGAGGACGAACTTTGAAAGCGGATAGTAGAGAATAAATGTGCACATATATTATTGTGTTTGTACTAAGTTTTATTTATTGTAATGGTTTCTAGTTGGTTCAGACTATTTCTGGTTGGTTTTATCATCAATGTGTACTTTATCTATTGCTGAAGATGAATTTAGTTCCTTTTTTTCTCTC
->HQ320065.1 Uncultured bacterium clone RMAM1139 16S ribosomal RNA gene, partial sequence 
-CAGTCGAGGGGCAGCGGGGGTAGCAATACCCGCCGGCGACCGGCGCACGGGTGAGTAACGCGTATGCAACTTACCTATCAGAGGGGGATAACCCGGCGAAAGTCGGACTAATACCGCATGAAGCAGGGGCCCCGCATGGGGATATTTGCTAAAGATTCATCGCTGATAGATAGGCATGCGTTCCATTAGGCAGTTGGCGGGGTAACGGCCCACCAAACCGACGATGGATAGGGGTTCTGAGAGGAAGGTCCCCCACATTGGTACTGAGACACGGACCAAACTCCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGGCGCGAGCCTGAACCAGCCAAGTCGCGTGAGGGATGAAGGTTCTATGGATCGTAAACCTCTTTTATAAGGGAATAAAGTGCGGGACGTGTCCTGTTTTGTATGTACCTTATGAATAAGGATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATCCGAGCGTTATCTGGATTTATTGGGTTTAAAGGGTGCGTAGGCGGCCTTTTAAGTCAGCGGTGAAAGTCTGTGGCTCAACCATAGAATTGCCGTTGAAACTGGGGGGCTTGAGTATGTTTGAGGCAGGCGGAATGCGTGGTGTAGCGGTGAAATGCTTAGATATCACGCAGAACCCCGATTGCGAAGGCAGCCTGCCAAGCCATGACTGACGCTGATGCACGAAAGCGTGGGGATCAAACAGGATTAGATACCCTGGTAGTCCACGCAGTAAACGATGATCACTAGCTGTTTGCGATACACTGTAAGCGGCACAGCGAAAGCGTTAAGTGA
->XM_048817709.1 PREDICTED: Caretta caretta kinesin family member 19 (KIF19), transcript variant X2, mRNA 
-GTGCTACTGTGTCAACAGGAGCCTGCTGCGCTGCGGTTGTTGTGTACAGTTTAAAGATCTCCAGGGGAGCCGGCGAGATCCCGCAGGCAGCAAAAGCAGCTGGGCAGAGCTGGGCTGGCCCTCCTGAGTACAGCCCGGTCAGCTGGCGTGAGAGGCAGCCGGGGCTAGAGCTCCCCGAAGGGAGCAGGAATGCTGCACCCCAGCCCTTTGTGGCTCTGTAGCCTCCTGGGGGGCCGAGAGGACAAAAGGCCCTGAGCCCGTGGATGGGAAAGGAGCAGGCAGGGCTGGCGTCGTCCCTGCAGCCCGCCTCCCCCTTTTGTCTCTGGGAGGATTAGCCTAAGTCTCAGGTTGTTTAGGAAACAGCGGATGCAAGTGACAGGTCTGTGGAGGGGGGAGTGGCGGTTGCAGGGTCCTGAGAGCCATGCCTGTGGCAGCTGCTGCTGGCCCTCCCCTCTAGACCCTCTGTGCACCTGCCAGGATCATGAAGGAGGTGAAGGAGTCCAGAGACCAGCAACTCACGGTGGCCCTTCGGATCCGGCCGATCAGCATGGTGGAGCTGGAGGAAGGAGCTACTCTCATAGCTCATAAAGTGGATGAACAGGTAGCGGTGCTCATGGACCCCATGGAGGACCCCGAGGACATCCTGCGAGCCAACCGCTCCCGCGAGAAATCCTATGTCTTCGACGTGGCCTTTGACTTCACGGCAACTCAGGAGATGGTCTATCGCGCCACCACCAAGGGCCTGATCGAAGGTGTCATCTCTGGGTACAACGCAACCGTCTTCGCCTACGGCCCCACCGGCTGCGGGAAGACGTACACCATGCTGGGCACAGACCGTGAGCCCGGCATCTACGCACGCACCCTCCATGACCTCTTCAGAGCCATTGAGGAGACCAGCGATGACATGGAGTATGAGGTGTCGATGTCCTACCTCGAGATCTACAACGAGATGATCCGGGACCTGCTCAACCCGTCGCTGGGCTTCCTGGAGCTGCGGGAGGACGCCAAGGGAGTGATCCAGGTGGCGGGGATCACGGAAGTCTCCACCATCAACGCCAAGGAGGTCATGCAGCTGCTGCTGAAGGGGAACAAGCAGAGGATGCAGGAGCCCACGGCCGCCAACCAGACGTCGTCGCGGTCCCACGCTGTGCTGCAGGTCACCGTCCGCCAGAAGCCCCGCATCAGGAACATCATGCAGGAGGTGCGGGTGGGGCGGCTCTTCATGATCGACCTGGCTGGCTCCGAGAGGGCATCTCAGACCCAGAACCGTGGGCAGAGGATGAAGGAGGGAGCCCACATCAACCGCTCGCTGCTGGCCCTGGGGAACTGCATCAATGCCCTGAGCGACAAGGGGGCCCCCAAGTACGTCAACTACCGTGACAGCAAGCTCACCCGCCTCCTGAAGGACTCCCTCGGGGGCAACAGCCGCACAGTCATGATCGCCCACATCAGCCCTGCCAGCAGCGCCTTCGAGGAGTCCCGCAGCACCCTCACCTACGCCGACCGCGCCAAGAGCATCAAAACCACGGTGAAGCGGAACCTGCTCAATGTCTCATACCACATTGCCCAGTACACCAGCATCATCTCGGACCTGCGCAGCGAGATCCAACGCCTCAAGTGCAAGATCGACGCGCCGGGGCCGCGCCCGGCCCGGGGCGAGCGGGGTGACATCCGCCACATCCAAGCCGAGGTGCAGCTCCTCAGCTCCCTCTGCGACCGGCAGGAGATGGACCAGCTGCGGGAACAGCTGATCGGTGCCTTCCAGGAGCAGATGGACCTGCGGCGCCAGCTGATGGAGCTGGAGAACAGCTACATGGAGATCCAGATCGAGAGCACCCGGCACCTGCTGACCATTGCGGACTGGGACCAGGAGAAGAGGCACCGGGCGCAGAAGTGCAGGGAGGAGCTGAGGAAGGAAGAGAGCGAGAAGGATTCGGACACCGGGGATGAGCAGCCGGACGCGCCGGAGCCACAGGAAGTGAGCTCGGCCAGGGAGAACATCGCCGCCCTCATGGGGGAGCAGAAGAAGCTGCGCAAGCAAAAGGCGGAGCTGGAGAAGCGGTTCAAGGAGATCCGCCAGCGGGGGCGGCGGCTGGAGGAGGTCCTGCCTCGGCGCATCAGCTCGGAGGAGCAGCGCGAGGTGCTGAGCCTGCTCTGCAAGGTGCACGAGCTGGAGCTGGAGAACACAGAGATGCAGTCCAGCGCCCTGCTGAAGGACGGCGTCATCCGCCACAAGAACTACGTGGTCCGGCGCTTCGAGCAGCACCGCAGCCTCTGTGGCCGCATCATCCAGCAGCAGAGGCAGATCATCCACGAATATCACCTCTCAGTCCCGCACCACCTGGAGGAGCTGTATGAGATCTACCTGCGGGAGCTGGAGGAGGGCAGCCTGGACCGGGTTGCCAGCCTGGACCGCGTGGCCGCCAAAGCCCTGAAGGATACGTCTCTGCCCAAGATCCCCCACCTCCCGGCTGCTGAGAGCGCCCTGGACTCCGACCAGGAGAGCGTGAGGACGCTGGGCTCAGAGCACCAGCCACTGCTGCGGCGTGACTCCCGCAGGCAGGCCCTGCCGCCCCTCGTGCTGGATGCAGAGAGCGACCCGGCCCAGGTGTTCAGGACCAGCCCTCGGGTGCGGCAGATCAAGAGTTCGGCTGTGCTGACCCCGCCCCCCATCCACATGAACGGCATGGTGACCCAAGAGTACCTGCACCGGGGGAGCCTGGCCAGCCTGGAGAGCCCCCCCAACTCCTCCCCGGACAGCAGCGAGAACTGCTCGGACGTCGCTCTGACGCGCAGAGAGCGCAGGGAGATCCTGAGCAGCACCAAGAACATCGCGGTGAAGGCTGCCCGGCGCCGCTCCAGGGTGCTGGAGTCCGACCGGCTGCAGCTGCTGGAGCCCATGAAGGAGCGGAGCAGCCTGTCGCTGCACTCCCTGAGCGAGAGCGAAGACCCCCTCTCCCCAGAGACCCCCGCCTCCCGGGGCCCGCCGTGCCCCGGCCTGCAGCATGCCGCCAGCGAGGACAACCTGTCCAGCAGCACCGGGGAGACGGCCTCGCGGGCCGAGGGCCCCTGCCCCAGCCACTCCCCCGGGCCCTGGCTCCGGGGGCACAAGGAGGCTGGCAAGAAGCTGGAGAAGAGGGAGGAGTCGCTGGACGGCAGAAGGCGGAAACGACGGTCCAGGTCCTTCGAAGTCACCGGCCACGGGGTCTGGGGGACCCGGCATCTCTCCCGCTCCCCCTCCCTCCTCCCGGCAACTTGAAGAAAGGCCCCCAGCCCAGCCAGCACCCCCGCCTGAGCTACATCACGCTGAACGGCACCAACGCTTACGCCAAGGACGGCAGGAGCCGGC
->BC147860.1 Bos taurus hypothetical protein LOC785621, mRNA (cDNA clone IMAGE:8182959), partial cds 
-GAGTGAGAGGTAAAGCATCTCAGACACCAGAGTTAGGCATTTTGTTAAGACAGCTTCTCTTCCTAACAACCTCCATCAGAAGAAATATAAGTCCTTTGTCATTCTTATTCAGAGAAACCTGGGTTCAAGTCAGCCAGTCTTCAGACTTACTTGTGGGGAACCTGTTAGAAAGGAGCTCACTGCCGCTTCACTGCTCTACTATGTCCTTGGTGTTCACCTTGATGCTTGAGATGCTCCTGTTTCTGACAGGAGCTGGAGCCCAGTCAGTGACCCAGCCTGATGACCACATTGCTGTCTCTGAAGGAGCCCGTCTGGAGCTGAAGTGCAACTACTCATCTTCTGTTTCACCGTATCTCTTCTGGTACATACAGTACCCCAACCAAGGACTCCAGCTTCTCCTGAAGTACGTGTCTGGAGACAATCTTGTTTCAGGCATCAAAGGTTTTGAGGCTGAATTTAGGAACAGTGAGACGTCTTTCCACCTGAGGAAAATACCAGCTCATTGGAAAGACTCGGCCAAGTACTTCTGTGCTCTGAGCCCGATGGATGGCAACTATCAGTGGATCTGGGGCTCTGGGACCAAACTAATTATAAAGCCAGAAGTCAAGGACCCCAACCCCACTGTGTACCAGCTGAGAAGCCCCCAATCCAGTGACACTTCTGTCTGCCTATTCACCGATTTTGATTCAAATCAAGTCAACATGGAAAAAATCATGGGGTCCGAGGGGAGCACGGTGCACAAAACAAACAGCACCGTGCTCAACATGGAGATCCTGGGATCCAAGAGCAACGGGATAGTGACTTGGGGAAACACCAGCGATGCTGGATGCGAATACACCTTCAACGAGACCATTCCCTTCGCCTCCAGCTTGGAAATCTCCTGTAATGCCAAGCTGGTAGAGAAAAGCTTTGAAACAGATATAAACCTAAACTCCCAAAACCTGTCAGTGATAGTGTTCCGCATCCTCCTCCTGAAGGTGGTCGGGTTTAATCTGCTCATGACGCTGCGGCTCTGGTCCAGTTGAGGTCACCGACAACCTGAGAGCCCCGTGCTCCCTCGCCCCTTGCTCCTCGTCGCCCTTCCTCTCCCTCTTCAAGCAGAGAGGCGCACTCTCTGCCCCCATGGATGAGAAGGCTCCCTCCTCCTCTCTGGCCTGGCTGGCCATAACACCAACTGGATCCTCCAGATACTGGTGATCAAGATGCTGACAAGCTGCCCAGCACGGCTGCCACCCACTCTCTTCCTCACTGCTGCTTGTCACTGCCTGGCATTCTTGGCAAAGTCGGGGGGCTGCTGCAGCCTCTCCTGGCTGTGGGGACACTCCCTCCCCACCCCCACCCCCCAGAGACTGCCTCTGATGTCCCACTGGATGGTGGATCCCCAGTGGGTTCTCCTGGGCTCTAGCTCCTGGAGAATGTTGTGTGTTGTTTATATTTTTTACATAGTGTTCATAAAAAAATATATATCACCCTTTTCCCCAACATGTGGGGAAAAATTATCTTTTCACGATCTAGGCCCTGCTCTTCTGTGTATCCGAGCCACATTGTATATTCTGCTGCCACGGCTTCAATAAAAGCGATTTGGAAGAGAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
->XR_006744459.1 PREDICTED: Melitaea cinxia uncharacterized LOC123662241 (LOC123662241), ncRNA 
-TTTTTGTATGACGCGAACTATAACGGTCGACTTTTACCTATACACAAGTATTAAGTTGCTTACCGTAGGAAGAGACGACCGAGTGTGTAT
->XM_022921984.1 PREDICTED: Stylophora pistillata protein ZINC INDUCED FACILITATOR-LIKE 1-like (LOC111319159), mRNA 
-TGTACCTAGTTGTTTTTATTTTGCATCGGCAGCAGTTGTGATTAATCTTAGGAAGGAAGTTGTTGTTGTACCCACAATGAATTTCTTAATGTCTTTCTTGCGTGGAATATTTTATCCTCCGGGAACAAATTCTTTGAATTGGAAGCTCTTCTTCATCGTTTTCCTCTCTACATTGTGTTCTGCAATGTCCATCACGATATTGTTTCCATTTTTACCAGCTATGGTGAAGAGTTTTGGGATCTCAGATGAAGACACAGGATATTTTGCGGGTCTTATAGCATCTTCAATGTTTATTGGACGCACAGCAGCTTGGTAAGTGTGGAGTGAATCTCTATTTCAATCAA
->XR_008133656.1 PREDICTED: Oncorhynchus keta uncharacterized LOC118373694 (LOC118373694), ncRNA 
-TGCCCCTGAACTAGACAGACTGGAACAACCTCCGTGATTTACAAGAAATCACCCGACTGTCTAGAAATGGAAAACCTTCAAACTAAGGCTGACCTATCACTTCATGAAGTACAACTTGGCCCCACATCACTTTAAAACATCAGCTGTCAATCCTCCCGCAGACATACAACTCCAGATACCCAACTCAACAGGCAGTATACATCAATGATGTCGCTCTTGCTGCTGGTGATTCTCTGATCCACCTCTACGCAGACGACACCATTCTGTATACTTCTGGCCTGATGCTGAATGAAGAGCTCTTCACTAGATACCAACACACTCAAAGGCGATTTTCTGAAAACCGCCGGAAAACGTGTGGCGAGACCCCATTTGCTCCAGTACTTTTTGATCTGCTGCAGCGCTGCTACACCACTTTCAGAGCAGCAGCACCAACCAAGACACTTCTCAGCACATTTTTGCATTCCAGTTCAACATTTACCTGCTCTGTTGCAGTCTATCGTTCTACTTCTGTGGGTTTTATGGCGGACTACAACCCCAAAATGTGTGTTCCCGCCACCAACTTGATGGGGTTGAAAAAACAAGTACATGTTCAAAGGTGGAAGAGACCCTCCAGAGTTGCTGCAGTGTGTGTTCTACTGGCTGTGATCATAGGCCTGTGGGATTCCTATGCAACTGCAGAGAGAGACCAGCTACAAAAAAGTCTAAATACCTCAACCAGAGAGAGAGACCAGCTACAGAATAGTCTGAATACCATGACCACAGAGAGAGACCAGCTACAGAATAGTCTGAATACCATGACCACAGAGAGAGACCAGCTACAGAATAGGCTAAATACCATGACCACAGAGAGAGACCAGCTACGTAATAGTCTATTTTCCACGAACACAAAGAAAGACCAGCCACAAAATAGTCTAATTTCCACAACCACAGAGAGAGACCAGCTACAGAATAGTCTGAAAACCATG
->HM666087.1 Uncultured bacterium clone GB7N87003F9F57 small subunit ribosomal RNA gene, partial sequence 
-AGAGCGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGCCCGTAGCAATACGGGAGCGGCAGACGGGATAGTAACACGTGGGAACGCGCCCTTCGGTTCGGAATAACTCAGGGAAACTTGAGCTAATACCGGATACGCCCTTACGGGGAAAGATTTATTGCCGAAGGAACGGCCCGCGTCCGATTAGCTAGTTGGTGAGGTAATGGCTCACCAAGGCGACGATCGGTAGCTGGTCTGAGAGGATGACCAGCATCACTGGGACTGAGGCACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGGATGATGAAGGCCTTAGGGTTGTAAAGTCCTTTTAACGGGGAAGATAAGTGACGGTACCCGTAGAATAAGCCCCGGCTAACTTCGCGCCAGCAGCCGC
->XM_042080615.1 PREDICTED: Alosa sapidissima tensin 1a (tns1a), transcript variant X8, mRNA 
-TTCTTTCTTTCTTTCTGTCTGTCTCTCTCTCTCTCTCTCGCTCTCCCTCCCTCCTCTCCCTCTCCCCCTGTGAGTCGTGTCATGGATTTGCCTTGCCTGGAGAGGCAGCCTTTCGAAATACCAGGCGTTTTTGGGAATACTGCATCCGATGCGGAGATCCGCTGACTCCCTGGAGATGCCCTCCGTGTCCCTCGGACTTCCGGCAGCTTTGGCCGGCCGGGCCAGGACCTGGGTCTGTCTCTCCTGCATGTTCTGGCCAGATGAGTTTGAAGGGGTCCACTCCCATACCTTCCGTGTGAAGGCATTCAAGAAAGCCAAGTGCTGTGCAGTATGCAAGCAGGCTGTCACCAAGGAAGGCCTGGTCTGCAAAGCTTGCCGGTTATCATGTCATAAGAAGTGTGAAGTGAAGGTCTCCACTGCCTGCACGACTGCTGCCAACTATGAGCTGCCTCCCACTGCTGAACTTCCCCTGAAACATGTAGAGACTCCGGGATCCACCAAATCCACCAGAAGTATGGACTCTCGTCAGAGACCCTCACGGAGCCTGAGTATGATCCAGAACCTGGATGACACGGAGGTGGACCTGGTCTACATCACAGAGCGGATCATCTCACTGTCCTTCCCCACGGGCTCCGACGAGCACAGCTACACCTCCCACCTCAAGGACGTGGCCGCCATGATGAGGTCCAAGCACGGAGAGCACTACCTGGTTCTTAACTTGAGTGAACACCGAAATGACATCGTCAAGCTGAACCCAAAGGTCATGGACTTTGGCTGGCCCGATCAACATGCACCTGCCCTGGACAAGATCTGTAGCATCTGCAAGGCCATGGACACCTGGCTCAATGCAGACATACACAATGTAGTTGTCCTACACAACAAGGGCAATCGGGGTCGGACAGGGGTTGTGATCGCGGCCTACATGCACTACAGCAACATCTCTGCCAGTGCTGACCAGGCCCTGGACAGGTTCGCCATGAAGCGCTTTTATGAAGACAAAGCCCTGCCAGTGGGCCAGCCGTCCCAGAGGAGATATGTACAGTATTTCAGCGGACTTCTCTCTGGTCATATCAAGATCAACAACAAGCCTCTGTTCCTGCACCACGTCATCATGCACGGCATCCCCAACTTCGAGTCCAAAGGAGGTTGCAGGCCGTTTCTAAAGATCTATCAGGGGATGCAGCCAATTTATATGTCTGGGATATACAATGTTCAAGGTGACAGCTCCACAAGTATCTGCATAACCATAGAGCCTGGCCTTCTCTTGAAGGGAGACATCCTGCTGAAGTGCTACCACAAGCGCTTCAGGAGCCCGAGCAGGGACGTGATCTTCAGGGTGCAGTTCCACACGTGTGCTGTCCACGACCTCGCCGTGGTCTTCACCAAGAATGAGCTCGACGAGACATTCAAAGATGACAGATTTCCTGAGTATGGGAAGGTTGAGTTTATCTTCTCATTTGGACCAGAAAAGATAAAAGGGCTTGATCATCTGGAGAACGGTCCGAGTGTGTCAGTAGACTACAATACCCAGGACCCCCTGATCCGTTGGGACTCCTATGACAACTTCCACAAGCGCTGTGAAGATGCACCAGACGACGTAGTGCACACGCAGGGTCCAGTCGACGGCAGTCTCTACGCTAAGATCCGAAAGAAGGACTCCAACGAGGGCATTGTTTCCGTTAACGGCCTTCCGCCCTCCGAGCGTGCTCATCCTCCCCTCCAGCAGGCAGTCGGAGTAGCCAACCACGCGCTTCCTCTCCCTGTCGCCAACCACGCCCTCCCGGTCGCTGACCACGCGCTCTCTGTGAGCAGCGACTCGGGCAACTCCACCGCCTCCGTCAAGACCGACCGCACCGATGACCCGCAGTCCCAGCAGGGCGGCGCCGCCGGCGGAGGAAGTGGCAGCGGGGGGGCCTGCGTGAGCCAGCCGCCCGGCGCCGAACCGTCCCTGAGTCCGCGGGAGAAGCGCGAGCTCGAGCAGCTGCTCAGCGGTCTCGAGGGAGGAGGAGGAGCCCAGGGGGGCCGACAGGGGAGCCCAGCGGCCGTCGGGGGTATCCTCCACCTGGTGCCCGCGCAGGTGCACGTGAACGGGCGTGGCTTGATCCGCGCCAACACCGTCCCGGCAGCAGCATCCGCGCGCGCCGCAGACAGCCGGAGCGAAACCGAACGCGAGACTGATATCCTTGACGACGAGCTCCCAGAGGCTCCCAACAGCGCCGACAGCCTCGGGACGATCTCGTCTCTGGACGGACACGAGACGCCAGCCGCCGACAGCCAGGGACACAGCGACTACCAGACTCCCCAGCAGCAGCAGCAGCAGCAGCAGCAGCAACCGCCGTCTGACTCGACCACCGTGGACATCGAGGGACCGTCGGCTCTCCCAGATCTCCGGTCCAGCAGGAGAGACATGCCGGTGCACCAGGTGCACGGCTCGGCCTCCGCGCAGGAGCGTCTGATCGACTACAGCGACCAGAACGGGGCCATGTACCGCTCACAGTCCTACGGGGCTGCCCCAGCCATGGACCCAGGGGCAGCTGCCAGGCTTCTGCCCCAAGCGCCCGAAAGGAGCACGAGCAGCCGCGAGGCCGTCCAGCGCGGCCTCAACGCCTGGCACCAGTACGGCCTGGTGGACGACCCGTTCTTCGGGCCCATGTCGGGCCTGTCGCGCTTCCCCACGTCGCCGAGCGGCGCCTCGCAGAACGACGTGGAGCAGTCCATCGAGGCCCTCAACATGCTCATGATGGACCTTGAGCCCACGCAGACGCCTGTACCCAAGTCCCAGAGCGCCCCCCCGGGCGACAACCCGGCTACCTACCAGACGCCCTTCGCCCAGAACTACCCGAGGCCCTCGTACCAGGCGGACCAGGCCATCCACAGCTACTCGACGGGCTACCCGCCCTCCACCTCGGCCAGCTACGGCCAGTCCTCTCAGAGGTCCTCCCCGGCCTACCCGCCCATGTCGCCCTCCATGGAGCCCCACAGGGGGGCTTTCCACTCCCCCACCCACCCACAGGAGGCGTACATCCACCGGGGAGGTCCCGGGTCCCCGTCCCCCACCCTGCACCACCCGCAACCCCTGAAGCCCCAGAGCGCCTTCACCCCAGGGGGAGGCAGCTCGGTGTGCTACACCCCGGAGCTCCAGGGCATCTCCCCGTACCCCACCACCCAGATGAGCTACAGTGCCTCCTCCTCTCCCCTCCCGTCGGTTACCCCCGCCAGGGAGGCTGACCCCGAGGAGGAGAGCCTGAACCTGGAGGGGCTGGTGGCCCACCGCATAGCTGAGTACAACGCTCGCATCCGGGGCATCTCGGCGAGTATGAGCCCCCAGCCCCAGCCCCGCGAACGCCATCGCTCCTATTCTTTTTCTGGGTCAAGGTCACACACAGCAACCCCAGATGAGTCCGGTTCATCCATGCGTCGCCGCACGACCAGCGAGGGTCAGTACCACAACGGTCACGAGGATCGTCCAGCTCACGGGAATGCCTCCCGCACCCCTGTCTCGCCAGAGTTTGTTACTGTTATCGCCTCGAATCCAGGAGGCCGACCAAGGGAGGTTCACATGCACAGCTATCGGGAGGCGTTTGACGACACCCCAGACGGCAGCGGTGGCGCCCCCACCAGCCCAACCCCCAGCGCCGGTGGTCGCTCCCCGCCAGGCTTGGCCAAGACGCCTCTGTCAGCCCTGGGGCTGAAGGCGCAGAGCCCCAACGATGTTCACATGCAGCAGAGCAGCTCCGAGCCGCGAGGCTACATTGGGCCCGTGGCACACGTTGGAGGGAGGGGTCTCGGCATGTCCCCTAGCCACCAGCACCCCCTGTACCCGTCTGAAGCTATGGAGAGGGCGGCACCCCCTGCCCACGGCATCAACCCCCCGCTCTCACCCCTTGGCACCAGCCACCACCCTGAGGGACACTTCTCACATCCTGACGGCTCCATGCGAGTGGCCAGTCCCCCTGTCCCTGTGTCCAACGTGGGCTACCCGCCCAACACCACCGAGCTCACGCACCCCCACTTTTACCCCGACCCGCTGGGCTACCTGGATCCTGAAACGGCCACGGTCAACATCATGGGCGTCCATCGTGTGCCGGGCAGCCCCAACACGCTCCACCGCACCGTTGCCACCAACACCGCCCCCAGCCCCGTCCTCCAGCGCCGGCTAGCCAATCAGAGCCCAGTCACCGGGCACCGGGTCCCCCCAGCCAATGGCGGCGACCCCAACAGCCCTGTGCCCGCGCGCCACATGGGTGCCACCAAAGCGGTGCCCCAGAGCCCCACGATGGGCCGCCACACTCAGAGCCCGGGCAGCGCCGGAAGCCTGAGTCCGGAGAGGAGGCCCAGCAGGCAGGCCAGCCCCGACGAGAGGCCCGGCGGGCGCCAGTCCGGCGCCTCTGGAGGTCACCTGTATGGCGCGGAGCCAGGCTCCCAGCCCCTGCTGCCCGATAAGAGGCCCAGTGCCACCCCAACTGAGGGCTCCATGAACAGGAAGATGTCCTCGCCAGGGCCCAGCGGTGCCAGCACGCCCGTCATGCCCCCGCACGCAACGTCTGAACCTGCCATTGTCTCCATCTATGCTGATGGACCACCAGACATCAAGCTCAACGTAAAGTTTGTGCAGGACACATCCAAGTTCTGGTACAAGCCAGAGATCTCCCGGGAGCAAGCTATCTGCGTGCTGAAGGACAGAGAGCCTGGGGCGTTTGTTATCCGAGACAGCCACTCCTTCAAGGGGGCCTACGGCCTGGCCATGAAGGTGGCCTCACCTCCACCCACTGTGCAACAGAACAAGAAAGTGGGAGACATCACTAACGAGCTGGTTCGTCACTTCCTGATTGAGACTAGTGCTAAGGGTGTGAGGCTGAAGGGCTGTCCCAACGAGCCCTACTTTGGCTGTCTCTCTGCATTGGTGTACCAGCACTCCATGACACCCCTGGCTCTCCCATGCAAGCTAATGATCCCAACCCGAGACCCGAATGAGGAAGCCATTGAGTTAGCCACCCCAACAAGCTCCACCATTGACCTACTGAAGCAGGGTGCAGCCCCTGTCGGTCCCCTGACAGTTTGTCCCTCTTATGTCACCGTAGGGCCGAAGGTTCCTGATGAGTCACAGGCATGCAATGTTCTGTATATTAACTCGGTGGAGATGGAGTCCCTGACAGGCCCCCAGGCCATTGCCAAAGCCATCAGCGAGACGCTGGCGGCCCAGCCACTGCCCAGTGCCACTGTCGTCCACTTCAAGGTGTCCACCCAGGGCATCACCCTCACCGACAATCAGAGGAAAATCTTCTTCCGGCGCCACTATCCCATCAACACCGTCACCTACTGTAACCTTGACCCGCAGGACAGAAAGTGGAACAAGACAGAGGGTGGAGCGGCTAAGTTGTTTGGATTTGTGGCCCGGAAACAAGGAAGCACAACAGACAACGTCAGTCACCTGTTTGCCGAATTGGAGCCAGACCAGCCGGCCAGTGCCATTGTCAGTTTTGTCTCCAAGGTCATGCTCGGCAACCCCAAACAGTGAAGACTGCCCTGGCAGACATTTTGTTTTTTCTCTAAACTGCGTGTGTTCTTTTTTTCCTCCCACAAAGACACGTTTTTTCATGCCCTTTTTGTGTGGATATATTTTTTCATAAAGGTCTCCCCGCCCCCGTCCTTCTTTCGAAGAGATGGGAAGGAGGAGTTGAGTAAAACTGTTGACTTTATTTTATTTTTTTTTTCTTTAAGTTTTCAAGGTGTTGATTTTTCCTTCAGTGAAGTAGGAGAACATTCAGGATGGAGTCTATGCACGTGCAGGAGAGCTCAGAGGTTTTTCTGGAAGAGGAAGGGGAGAATACTTCTCCCAGTGGTTCATCCAGACTTGAAGAGAATTTAGGAATTAATGAGTTTTAAAAGAAAGACAAGTGAAGAAACAAAAAAGCAACAAAGAATCATTTTTCAGATAGAACAACCAAAGGTAGTGTTCAGAACAAGTATGCCATTATTGGACAATGTATTCCATTTTGTTTTGTAAAGGAATTTTACTTTTAACCAGACTGTCAAAAAAGTACAAAATCCCTCTGGACAAAAAAAAAAGATTTTTTTGTCTGTCTCTGTGACTTCTTCTTTCAAAAAGAACATTGAAAAAAAAAGAAAAAGTATTCAGTGACGATATGCATGTTCGCTTGCAAATGGTCCTTAGCTGCTTCTCTAACCCTTCGTTGTTGGTCAAGACTGCTCTCTTTGTAGACACTGGTGGACTCGAGATTGTAGGATGCTACCAGGTCTACCGATCACAACACCTACACACACAGACACCAGTTCAGTTGACCAAACTGCATATCAGGAAAAAAATTGAAAAACACTGTGGTCCAACATCAGCAATAATGTCACCCAGGCCCCAGGCTCAACTAGTCAAACTCAGAAAGAGGGGGAACTGTTGGGGTGGAGAGGATTGTGGATCGGCTGCTCTGGCCTGTAGATGCAAAATGTGTGTGACTGCACTGTATCAGGATGCAGGTGAGGATACAAGTCTCAGCTCATGCACAGAGCCTGTAAAGCAGGAGAGAGATGTTCTACAGGTCACCTCATACACACACAGACACACACACAGACACACACACACACACACACACACACACACACACTCACACACATACACACAATTACTGTACACACACAGAAATGTGCACATCTCCCTATAATGACCCACACTGGACACTGGAGGGGTGAACAATTCATCGCCTGGATGGACCAACAGCGATGCCCCCGCATGCCGTAGTGCAAAAGTAGCTCCTTTAACCTTTAACCTTTACCCTTCAACCTGACTCAATGAACTTTACCCCCCAGCCCCCCACTATCCTCTGAACGCAGATCACCCCTTTCCCCTGCTGTAGGAAAGAAACAAAAAAAGAAGAAAAATTGCTATGGCGACACTGATCGCTAGAGACTTCAACTGCATGTGATGCTACCTTCAGGTTTTTCTTTTCTTTTCTTTTTTACTTCAAAAAAAGGGTCTTACATCTTGTTGAAGTTCGCTATGCTCTGTCTTTATCTTTGTCACACACACACACACATACTAACACACACACACACACACACACACACACATACTAACACACACACACATCATTTCCTCTCCCGAGTGGAGTTTTATTTCAGCCAAATACACATTAGGCAATGTCTACCTTTTCTTTCAAGAAAAAACAGAGTTGCTTTCTGTTCACACTGCCCATTACCACACTTCTTTTATTCACTGTGTGAGAGCGTGGCTTAAAAAAAGAAGACAACATAAAGAAAAAACAATACACAAAGCCCAATCTTCATAAGCTATTGAAAAAAGATAAACATGACTATAAATAATGATGACTACATATGTATTACTATAAAAAGGTGACTTTAATGAAAATATTTATTTTTGTTGCTCTCTCTTGCTTTTGGGTTATTCATGCAGTATATTGAAATGACAAGATATTGTATAGTCAACATTCAAAACATCTGAGACTACATGGGGGGGAAATTATTTTGGTTAAGAGTTAAAAGTCATGAGTGAAAAAAGACATCTTGTGTGTCCAGCTGAGAGTCACTTTGTTTTGCGTGTGGCCACTGCTCCATTTTGTCTCATGTTGAGGTGTTTGAGGTGTGTGAGGGGAAGACATTCATGTATAAAAAAAAACACAATGTTTTTATTTTTGTTTTTATGCATTTTTTTATTTGTAATCCATCAGTTTGTGCCGTTGCAGGATGATAACGCTGTCTGTCAGTTGTGTGTGTGATGGAGATGGAACTAGAAGTCTGCCAGCTACAGACACTAATTTGCCCATCAAGAATGTCAAGAGGAAGGCACACAAATGTGTTTGCCAAAGAGGCAAACTCAGAAGATCCACAGCGTAGGCTACCCCATCTTTATAATTGTATAGCACTTACAGACTGCCAGTGCCACCCTAGTTAAGTTAAACCAGAATCTAAACATGTCCTCATGACTTTTCTAAGGACAAGCTACAACAGATGTCGGTGCAGTTCTTACATAGCTTCTGTTGTTGGGATTCAGTATTGGAAACGGTTGAATAATATCTCGTTATTATTAGGGGAAGAGCAGGTGTCATGGCTGCCAAGAACCTTTGTTGTAGATCATGCCGCTATTAAGCACCATACTCCATTCAAAACCACTATAGCTGTACACATATATGCAGTTTCTTCGCCTTTTTCATGTAACAAGACCTCAAAGCGAACACAAGATAACAAATGATACTGACTGTCCTTTGTGTAACATAAAAGTATGTATTTATTTCTGTTTTTAAATTATGTTTTGTTTGTGTTTTTTTCACTCACCGGTTGGTCTTCCCCATAGTCAGGCCCAGTGCTTTGGTGTCATCAGTGTTACCCAGAATGCTCTAGACTCGCAGGCGACCCGGCGGACATTTTCCTCGGATGTTTGCCTGAAGTCAGTGAGTTGGCTTTGCGAAGATGAAGTCTGGGGTTTGAATGTGTGAATGTACTACTAAGGCTGTACAGAGCTTCTGTGGGATTTATGTGTTTTTATTTTATTTTATGTTTATTTGTGTTATAATGCAATGGCTTTGTTCCTGAGGAGAAAAAAAAAAAAACATTAAAGCAATACAAACCAGTTA
->XM_031525737.1 PREDICTED: Punica granatum senescence/dehydration-associated protein At4g35985, chloroplastic-like (LOC116196154), mRNA 
-CTTTCGAATCAAACACAGCACAACTTCCTCTGTAAGCCATTCCTATTCCCTTGCCAGCCAATCACAATGTTCTTCTATTCCATGTCCTGACAAAACCAAACACAGCTCTCTCCAAGAACAGGTCCACTTCATCTGCGGGAGAGACAGAGAGGAAGAGGAAGATGGGCTGTTTCAGCTGTGGAAGCAGCAGAAGCAACAGCAGCAGCAGAGGAGGTTCAAATTCTACGTACTTTGATCCTTATGAGACAACCCAGCAAAACTCGGAACCCAGAACGACCAAGCAGCAAGTTCTGCTCCAAATCCCGTCATGCACCGTCCACTTAATGGACCAAGGAGAAGCTTTGGAGCTCTCCAGTGGCAGAGAGTTCACCCTTCTCACCATCTCGGACGAGAACATCTCCCTGGCAACCATCATAAAGGTCGGTGATGACCTCCAGTGGCCGCTCACCAAGGACGAGCCGGTCGTGAAGTTAGACTCCCTTCACTACCTCTTCTCCCTGCCCGTGAAAGATGGTGACCCGCTCAGCTATGGAGTCACTTTCATGGAACAGTATGTAAGCTATTTGGGGTACTTGGACAAGTTCCTTGAAGAACATTCGTGCTTCTCTTCTTCGGCTCCTGCTTCTTCATCTTCATATTCTGCACCGAACCGGAACCTTAACTGGAAGGAGTTTGCCCCGAAAATCAATGACTATAACAATGTCTTGGCTAAGGCCATTGCCGGAGGGACTGGTCAGATTGTTAAAGGCATCTTTATGTGTAGCAATGGCTACACCAATCAGGTCCACAAGGGAGGAGAAATGATCATGACTAGTGTTGTGGAGCAGAGGAATGGTTCGAGTTACCATGAAAGCTATGGAGGCAGCAATGGGGGTGCCCAGAAGAAGAGCGCAGTCAATATAAGCCTGAAACGTGTAAGAAAGGTGTCTAAAATGACTGACAAGATCAGCAAGAAACTGCTAGATGGAGTTCAATTTGCCACTGGATCGGTAATGGCGCCGATGGTGAAGTCCCAAGCAGGGAAGTCCTTCCTAGCAATGGTTCCAGGAGAGGTTCTGCTGGCTTCACTTGATGCTGTCGATAAGGTGTTAGATGCAGCTGAAGCGGCTGAGAAGCAAGCTTACTCGGCTACCTCAAAAGCTGCTACGAGAATGGTCAGCAGAAGGTTTGGAGAGAGTGCAGGGGAGGCAACAGAAGATGCGCTTGCAACAGCAGGTCACTGTGCAAGCACTGCTTGGAACGTCTTCAAGATCAGGAAGGCCGTCAATCCGGCATCTTCCGTCTCCACTGGGGTGCTAAAAAATGCGGGCAAGGCCAAGAATTCATACTCTTGAATTCAGTCCGATTCAACTCTATTAGTTAAAGTCTAGATGGACTAGAAACAGCATGCTCGGGTTTGTAATGGAGTCTGGAATATCTGTCTAGAACTAACTGAGAATGATTTGGTATATCATTTGCATATTGCCATTGCTGCTTCTTTCCTCAGATAGATCTTCCAATGTATGTCTGCACAATTTGTACGTAAGACATTTTTAATGCGTTTGAATTCAGAGTTAAAAAGTAACTTTAATTTTGATTTA
->LC139547.1 Uncultured bacterium gene for 16S rRNA, partial sequence, clone: SdRy21_50 
-GTGCCAGCAGCCGCGGTAATACGGAGGGGGCAAGCGTTGCTCGGATTTACTGGGCGTAAAGGGTCCGCAGGCGGTTAAGTAAGTTAGATGTGAAAGCTCAAGGCTTAACCTTGAAACTGCATCTAAAACTGCTCGACTAGAGTCCAAGAGGGGTCGGCGGAATTCCCGGTGTAGCGGTGAAATGCGTAGATATCGGGAGGAACACCAGTGGCGAAGGCGGCCGACTGGCTTGGAACTGACGCTCAGGGACGAAAGCGTGGGTAGCGAACCGGATTAGATACCCGGGTAGTCCACGCCCTAAACGATGGATGCTAGGTGTGGGGATTTTATCTCCTTGCCGAAGCTAACGCATTAAGCATCCCGCCTGGGGAGTACGGTCGCAAGGCTGAAACTCAAAGGAATTGGCGGGGGCCCGCACAAGCGGTGGAGCACGTGGTTTAATTCGATGATAAGCGAAGAACCTTACCAGGACTTGACATGTTTACCTAAGCCGATGCGAAAGCATTTGGTGGTTTTGAGCTTGCTTAGAACGGTATTCACAGGTGCTGCATGGCTGTCGTCAGCTCGTGCCGTGAGGTGTCCGGTTAAGTCCGGTAACGAGCGCAACCCCTATTTTTAGTTGCCAGCATTTCGGATGGGCACTCTAAAGGGACTGCCGGTGACAAACCGGAGGAAGGTGGGGACGACGTCAAGTCAGCATGGCCCTTATGTCCTGGGCTACACACATGCTACAATGGCTAGTACAATGGGTTGCCAAATCGCAAGATGGAGCTAATCCCATCAAAGCTAGTCTCAGTTCGGATTGCAGGCTGCAACTCGCCTGCATGAAGCTGGAATCGCTAGTAATCGTGGATCAGCATTGCCACGGTGAATACGTTCCCGGGCCTTGCACACACCGCCCGTC
->XM_007532958.2 PREDICTED: Erinaceus europaeus C1q and tumor necrosis factor related protein 1 (C1QTNF1), transcript variant X1, mRNA 
-CCCCCCCCCCCAGGACTTTTCATTTGTCCCACTGGTTCTCCTTCCACAAGTCTGTTTGGACCTAGAAAAAGCTCAGCTGCTGGGAGATGATCTAACCAGTGTCCCAAGAGCCCGTGGCAGTGGGCGCTCCCACTCAGGAGTCAGAGGCTTGGAGGGAAAATGGGCTGCCAGGCACTGGGATTCTCTCTGACCAGCTGCCTGCTCCTGGCCTTTACCTGCAGCCTGGTGCTGAGCCGTGTGCCACATGGACAGCCAGACCCTCAGGAGCAAGAGGGAACTGGGGAGCCACCATTGGATCACACTGAAAGGATTGAAGAAAATCATGAAAAATACAGCCCCAAGCAAGATGAGGAGCCCTCAGCAACCCAGTGTTTGCGCTGCTGTGACCCCAGCACCCCCATGTACCAAGCCATCCCAGTGCCCCAGATCAACATCACCATTCTGAAAGGTGAGAAGGGAGACCGAGGGGACAGGGGCTTGCAGGGCAAATATGGCAAGACAGGCTCTGCAGGTGCCCGGGGCCACATGGGCCCCAAGGGACAGAAGGGGTCCATCGGAGCCCCTGGGGACCGCTGCAAGAATCACTATGCAGCCTTCTCAGTGGGCCGCAAGAAGCCACTGCACAGCAATGACTACTACCAGACTGTCATCTTCGACACGGAGTTTGTGAACCTCTACGGCCACTTCAACATGTTCACAGGCCGGTTCTACTGCTATGTACCTGGCATCTACTTCTTCAACCTCAACGTGCACACTTGGAACCAGAAGGAGACCTACCTGCATATCATGAGGAATGAGGAGGTGGCAGTGATCCTGTACGCCCAGGTGAGCGACCGCAGCATCATGCAGAGCCAGAGCCTGCTGCTGGAGCTGCAGGAGCAGGACGAGGTTTGGGTGAGGCTCTTCCGGGGGGAGCGCGAGAACGCCATCTTCAGCGATGAGTTTGACACCTACATCACCTTCAGTGGCTACCTGGTCAAGCACTCCACAGAGCCCTAACCCATGGCACCTCCTCATCTCCAGCTTGCCTGTTCTCCCACCCCACTGGGTTCCAATGGTCCAGCATCAAAAGGCCCCCTGGCCCTTCACCTCCCCCACTACCCTGCTCCCTGCTCCCCAGCTCTGGCGTTCTACCCCACATTTTTCTTTAGCAGGGACAGGAAGTGAATGTTGCTGTGTGTTCTGGCCCTCTGTGGATGAAATCACAGGGGCAAATGCCCCCTCTGGAATCACATCCTTAAGTGGCCCATGGCCCAGGCAAAACATGTCTGGATATGGCAAAGAGTCTTCTTTCCTTTTCTTTTTAAA
->XM_032266396.1 PREDICTED: Sapajus apella transmembrane protein 108 (TMEM108), transcript variant X7, mRNA 
-TGTGTTTATGTAAATATTATGTCAGATTGTCTTTATTTTAGCTGTTAAAGGTACTAATTAAATATTTGTTAATGAATTATAGTGCTGTATTTATCAAGTTCTGATTTACAGGGTAAAAGCACAGTTGACCAAATTGTGTGAAACCTTGAACCTCAGACCCTCTGACGTGGGCTTACTGCTGCATTAACACCCTGTGCATCTGGTGGTAGCTTCCAAAATGATAGCTGAGGGTCTGAGTCGAAATAAATGGCTTTTAGCAAGTGTTGAACTTTGAATGTGCTATTTAACCTCTGATTAATTGATTACTCAGCTCTGAATATGAGAGGTGTATAGCTATCCCTTATCTCACTTAAGTGATTTGAGCATGGATGCTCCTCTCATTTGAATACAGTTTTTGGGGTGGGTGGGGGTGATATCAGATCCCAGGGTACATGCTATGATAATGACAGGCTTAATTATCACTCAGTATGGTTTAGGACAAAGGTTTTCTTTTGATCACAATATTAAGAAACCTTTCTTTAACAGATAGTTTTACTTGTACGTATGAAGTATATATATAAATTTATCATTTCCTATATATTTGATTCACATTCAGAGGGTATTTAAAATAGTATCTTCTTCAGAATGTATATGTTGGGATTATATATTACTGTTTCTTTCCTTTTTATGTAGTTTCTTTTTGTGGTCAGGTAAAAGAAGACTAAAGGGATGTGATATTTAGTCTCAAATATTTGAAGTATAGTCACTGTTCTGTTTCAGGGCTGTTTCCCTCTATCAATTCCTTTGATATGGAACTCCAATGTCATTTTTACTTTACAATTGATCACATGCTGGCTCACTGACATCAATTAACTAATTTGAGGCAAATTTTTAAACCAAATGCCAAATTTTAATTTACTGAGAGAATATAATCTAATAAGAAAGACTACCCTTGGGCTCTTCACATGGTGAACCCTAGTGTGGTTTTGATAAAGAAGCCCAAGTATATACTAACTATAATCTTTTCTTAAAAAAAAGTGGTGTTCTTATCTAGACCCTCCAGAATCTAGAGTAGCATCGTCCAATAAAAATGTAATATAAACCTCAAGTATGAGCTTTATATGTAATTTTAAATGTTCTAATAGCCACTTTAAAAATGAAATGTGAAATTAATTTTAGCTCTATATTTTATGTTGCTTAATATATGCAGCATATTATTTCAACATGTACAGTTGACCCTTGGTATCCATGGAGAATTGGTTCCAGGACTGCCCACAGATACCGAAATCTGTGGATGCCCAAGTCCCTTGTATAAAATGATGAGGTATTTGCATATAACATGTGCATATCCTCCCATATATTTTAAATCATCTTTAGATAACTTAAAATACCTAATACAATGTAAATGCTATGTAAATAATTGTTGTACTATATTATCTATATTGTTTTTTGTTTTTTATTAATTTACTTTTTAAAAATATTTTTACTGGGCAGTTGGTTGCATATGCAGAACCCATGGATATCGAGGGTTGACTGTAACTAATATAATGAATTATTAATGAGATATTTTGTATTTTTAAAATACAAAGTCTTGAAAGTCCAATTGAGATGTGCTGTAAGCATATTTTACACTTATAGCACATCTCAACTGGGACACTGAGGTTTCATGTACAGTACTTGATCTGTACTTAAATTAAAACTTACAGTAGAAAAAATAGATTCACATACCCAAGTCATTCCAAACATGCAAATCAGTTGTCCAGTAACTGAATCGGTGTCCATTTCTAAATTTAAATTTAACTTTAATTAAAATTAAATAAAATTTAAAGTAAAATTCAATTCCTGATTGACACTAGCAATGTTTAAAGCACTCAGTAACCACCTGTGGAGTGGCTGCCATGTTGTGTTGGACAGCACAGAAAGGACTGCTTTCTCTAGCCTTTTCCTTCACTCCTGCATGTCTCAGATGGGAAGACTTGTGTGAGACCTCTGATGGGAAGAGAATCTCATTTTGAAAGTGTGGAACCACAGACAAAGAGTTGACTTTCTTAAAAAGAAGTTTCCATTCAGGCTATATTAGAACCTGCCTGGCAAGGAGTTATCTGTCTAATATACCACATTATCTCCACCCTTGTTCCTAAATACACCCCTCATTGTCTCCCCAACAGATAAAAATATGCCAACCTTGTGTCAAGGTTGCCTCCCTGATCCCCTTGTCCTCCACTGCAGGCTGGCTCATTTCCATTACGTCAGTGTATTTCCTGGTTATAGTCCTCCTTTCTCATTGTTTCAGTTTCCACATTTGGCCTTAATTTCTATGATACCTCAGTGAAGCATTCAAATGTTTAAATTCCAATTTAGTTCTTAATTAAGGTCATGTATATCAAGGTCAATGTTATGTTAATTTGGATAACAGACATTTCCTTTGTCCCTTGCTCCAGATTTCTAGAGTGGCTGGGCTGAGAAACTTTACTTCCTGTTCACCTAGACAGAATCATGAATAAACTGGAGGATAAGCAGGACCAGATGATACCATGAAGAGAAGTTTACAGGCCCTCTATTGCCAACTGTTAAGTTTCCTGCTGATCTTGGCACTGACCGAAGCGCTGGCATTTGCCATCCAGGAACCATCTCCCAGGGAATCTCTTCAGGTCCTCCCTTCAGGCAGTCCCCCAGGAACCATGATGACAGCACCCCACAGCTCTACCAGACACGCTTCTGTGGTGACACTGACCCCCAATCCCAATGGACCCCCCTCACAGGCTTCAGCTCCCATGGCAACACCGACACCCCATACAGAGGGGCACCCTCCTACGCACACCATCTCCACCATCGCTGCGACAGTAACCACCCCCCATTCTAAAAGCTCCCTACCCACAGGGCCCTCTCCAGTGGCCACAGCAACCACATCCTCCCACCCAGAGGGCCGCCCCCCGGGGCAGGCTACTCCCACCATCCTGCTGACAAAGCCACCGAGGGCCACCGGTCGCCCCACTGCAGCGCCCCCACGCGCTACCACACGCAGGCCCCCCAGGCCCCCAGGCTCCTCCCGAAAAGGGGCTGGCAATTCATCACGCCCTGTCCCACCTGCACCTGGTGGCCACTCCAGGAGTAAGGAAGGACAGCGGGGACGAAACCCAAGCTCCACACCTCTAGGGCAGAAGCGGCCCCTGGGGAAAATCTTCCAGATCTACAAGGGCAACTTCACTGGGTCTGTGGAGCTGGACCCTTCTGCCCTCACCCCCAGGACCCGGCTCTGGGGCTACTCCTCTTCACCACAGCCCCAGACAATGGCTGTCACTACAGCGCCCAGCAATACCTCGTGGGCACCTCCCACCACCTCCCTGGGGCCTGCAGAGGACAAGCCAGGCCTTCGCAGAGTGGCCCAGGGAGGTGGTTCGACCTTCACCAGCCAAGGAGGGACGCCAGATGCCACAGCAGCCTCAGGTGCCCCTGCCAGTCCACAACCTGCCCCAGTGCCTTCTCAGCGCCCCCACCGCGGTGACCCACAGGACGGCCCCAGCCATAGTGACTCTTGGCTTACTGTCACCCCTGGCACCAACAGACCTCCATCTGCCAGCTCTGGGGTCTTCACGGCCGCCACGGGGCCCACCCCAACTGCCTTCGATGCCAGTGTCTCAGCCCCTTCCCAGGGGATTCCTCAGGGAGCATCCACAACCACGCAGGCTCCAACCCATCTCCCCAGGGTCTCAGAAAGCACTATTTCTGGAGCCAAGGAAGAGACTGCAGCCACCTACACCATGACCGACAGGGTGCCCAGTCCTTTCTCCACAGTGGTATCCACAGCCACAGGCAACTTCCTCAACCGCCTGGTTCCTGCCGGGACCTGGAAGCCTGGGACAGCAGGGAACATATCCCACGTGGCCGAAGGGGACAAACCCCAGCACAGAGCCACCATCTGCCTGAGCAAGATGGATATCGCCTGGGTGATCCTGGCCATCAGCGTGCCCATCTCCTCCTGCTCTGTCCTGCTGACAGTGTGCTGCATGAAGAGGAAGAAGAAGACTGCCAACCCAGAGAACAACCTGAGCTACTGGAACAATGCCATCACCATGGACTACTTCAACAGGCATGCTGTGGAGCTGCCCAGGGAGATCCAGTCCCTGGAAACCTCTGAGGACCAGCTTTCAGAGCCCCGTTCCCCAGCCAATGGCGACTACAGAGACACTGGGATGGTCCTTGTTAACCCCTTCTGTCAAGAAACACTGTTTGTGGGAAACGATCAAGTATCTGAGATCTAACTGCAGCAGGCTTCGCTTTGCTATTCCCTATTTTTCGTCTCTAAATTATAAATATACAAATATATATATTATAAATATAACCTTTGTGTAACCCTGACTTAATGAGAAACATTTTCAGCTTTCTTTTCCTATGAATTGTCAACATCTTTTTTACAAGTGTGGTTTAAAAAAAAATTTACAGAATGATCTGTGGCTTTATAAAATAAAGGTATTTCTAAGCAAAGCAGTTGCATTGATTGCTTCTCTTAATAACTATTTTTGAGCACCTGGGGATCCCAGGAACCCTAGTCAGGTGAGGTAAGAGACTGACCTCCTGTAGAAGCTCAGTGTTACAGTGGTCAAGTGCACAGTTCTTTGAGTGATTCTTAAAGCTCTGGTTCCTCTTGATTTGGCGTGGCCCATTTCCTCCCTCTCATACGCACACCTGTAAAGGGAACTGGGCCACCTGGGGGAAGATGGCAGACTCATGCACAGGGCAGGAAAAGGGAACACCTCATCACCCCCAAGGATGGGGGCCCTGGAGCCTCACGACACCACCATTGGATGTCATGTTTAAAAGTTGTAGACAGCAGACAGAAGCATGGAGTCCTTGGGAATCCATGGAGGACATCAAGGCATCCCAAGGCCACATCCCCCTAACATTGCTTCCACTGCTAACAACAAGACTGCCTTTCCCTGGTGGGAAAATGCTCCCTTCATGCCCGTTCCTGCATCCCCTCCAACGCTCAATCTGCATTAAACACCCGTGCCTTTCTCTTGGAGAGGGTTTAGATGCAGATCCCAGCCTTGGAGCTTTAAAATGCTTGCCCTTCTTCAAGGATCAAATGTTTATTGGGGTTTAGCTTTGTTTTCTCAAAAGGCCACGGTATTGTGCCCCTAAGGAACACGTTTATCTAAGAAGCTTTGAGGTAGCAGAGCTATGATTTTTGAAACCTTCCTCCTGCAATCTTTAAAAAAAAAAAAAAAAAAGATTGCCAAGCAAGTCATTTCCGAGAAGACATCATTACACTCCTACTTGCCCCTGCAAACCTGCTCGAAGCACCAGCCGGTGGACTTGCCACGCAGCTCGCAGCTTCCACTGCTCGCCTCGTTCCCCACTGGCTGGCTGCCTCACCGTGCCGTGTCCAGCGTGGCCAACAGGGTCAGACCCTCAGAGATGCCCAAGAGGCTGCCAGAGGTGGCTGCTTCTCTATTTTTTCCTGATCGTGGCTGAGAGAGATGATTACTGCTTTGACACTTTCTTTCTCTAAAATAAAGCTAGTTTGATAGTATATTTTGAATATAGATGCTCTTATAGTTGGATTGGGAATTGAACTCGAATGTTGATTCATATGTTTGTGTTGTTGCTGTGGTCTTTTTATCATGACTTTTTTCTTTCTGCGTTTTCCTTAAAAAAAAAGATGGCCTTCAAAAGTGTGTTCTTAGTGTTGTATAAACCTACTTCATATGAGTTCAGTTGTTGTCTCTCTTCAAAGACTCTTCAACCCACAAAGAAGCAGGTTAAATGTTTCTCTAAGTTTAATTTTCTAGCGTGTTGTTGTCTGACCTTTTTAACCTTACCATAATATTTCTGTTAACTGTTACATTTAATATACCAATGTGTGTGAGTATACATAGAGAAAAATCTGTAAAGTAAAATTTATATATAATATATGTAATCCAAGATACATATGTTATATATACACGTACGTGGATGTATGACTTATTTTTCCGTATCCACAGATTTCGGCTACCATGGATATATAAATAAACTTATTTTGTTAGCCAGAGGA
->XR_006349495.1 PREDICTED: Manihot esculenta small nucleolar RNA SNORD34 (LOC122722555), ncRNA 
-GGAGGCCTAGGATGATCTTAAATTTGCCTACATTGTCAGAGTGTTTAAATCATGACAGATTATTGAATGATTCTGAGGCCACT
->XM_008548960.2 PREDICTED: Microplitis demolitor basic salivary proline-rich protein 2 (LOC103571010), mRNA 
-TATTGTTATGATTATTGGCGGCCATATTTGAAATTTATTCGAGTTTCCAATGTAAAAAACGCCCGAGCTTTAGTTTGGTTTTCATACCCAAGCAAATGTTTGGTCACTAAAAAAAAAGGACTCAACTACGTAATTGTCAGATTATTGTCATAAATCTCATTGTAATAAATTACTTGAAACGTGTGGGTGTGCGGTATTGTATTGGTGATAAAAGAGTAAGAAAAAAAGTAAAACGTGGTATTGTTTTATTAAAATATATCACCAGCCACTAAATTGTGGTATATATATTTAGTTTAGCTTTAAGTAACTAAAAATGTCAGCTACTTTTGCACAACGCGGTCGTGTACCGCCAACTCCAGCTCAAATTCAGAAGATGCTGGACGAGAATAGTCATTTGATACAGACGATACAGGAGTACCAGAATAAAGGAAAACCTCAGGAATGTTTACAATATCAACAGATATTACATCGGAATTTAGTTTATCTCGCTTCTATTGCTGATGCGAATCAAAATATCCAGGCACTGCTACCGCCGCCACAGGGTTTGCCGCCGATGACAAATGGTCCGCAGCATGGAATGATGGGTCCGCAAGGGCCACCGAATGTCGCTCCGGGAACTCCAGGGCCTGGAGGTGAAATGCCACCGAATCCTCCGCAGCCTATGCCAATGCAGGGATTTAATCAGGGACAGCCGATGCCTCAGGGTGGCTACCGTGGTCCAGTGATGGCTGGACAGGGTCCTCCGATGAATAGAGCGAACCCTGGACCTGGGCCTCAGCAGTATCGAGGTGGGCCACAGGCTTATCCGCAGCAACCTGGACAGCAGGGGTATCCTGCTGGTTATGGGGGACAGAATCCTGGTGGGAATTATCCACAAGGTCCTCAGGGAAGTGGTTATGGAGCTGGACAGCCTAATCAGTACCCGCCTAATGCACCGCAGCAAGGCTACCCGGCGTCAGGACAGCAGAATTATGGGCCTCCGGGTTCTGTTAATAGTTATGGAGGTCAACCGGGTGCTTATCCGCCACCGGGAGGTAATCAGCCCTCTGGTGGCTACGGTCCTCCGCCGCCGAATCAGCAAGGATATCCCCCGCCTACTACGCAGCAAAACTTCTCGCCTAATCCTCAGCAGCAGCAGCAACAACAGCAGCAACAACAACAACAGCAACAGCAGCAGCAACAACAACCTGGACAGTATGGTAGTCCTAGTCCTCAGCCAAACTATCAGCCTCCTTCCCAAGCTCCTAATCAGAATGCTTATGGTCCAGGTCAGACTCCCGGTAATTATCCTCCTCAATCCTCTCAAGCTTATCCTAATAATGTTCCTCCACAGAATTATCCTCCTCCACCTCCGACGTCTAATAATGTTGCCCAGCCTAGCCAAGGACCACCACAGCAGAGTCAAGGTGGGCCGCCGCAGAATTACTCAAGTCAGCCAAGTCCTGGTGGTGGACCACCAACTCCATATGGACCTTCATCTACATCACCGCCATTTAGCACCAGTAATGTGAGTGGAGTTAATACGTATGCTCCTAGTAATCAACCTACGAGTACACCTTCTGCTTCGACTCAGACTTACCCACCATCCAGTGGACCTCCACCAGCAACTTCGCAAGCTGGTAGTTATGTTCCTGGGCCTACTCCTTCCGGGTATCCGGTGCATCAGCCGTCGCATCAAGCTCATGGTCCACATGGGCCTCATCCTGGCTCTCATCAGATTCCTCATCCTCCGCCATCACAGTCGCAACCTGGACCGCCACCTCAGTCGCAGCCACCTGGTCAATCGCAGCAACCTTCTCAACAACCGTCTCAGCAGCAGCAGTCTCAGCAACAACCACCAGCCCAATCACCACAGCAGCAACAACAACAAGGACCTCCACCTCAAGGACCCCCTCAGCAGCAACAATCTCAGCAGGGAGCGCCACAGTCTCAACATCAACAATCCCCGAGTCCAGTTCCGAGTAATTTCCCACCAACTTCCGGACCAATATCACAGGGTCCACCCTCTGGGCCTCCAGGTCCACCGGGTCCACCTCAACAACCTCCTGGTGGATATGGACCTCCACAATCTCACCCAGCGACGACGCAGACTTACGTACCCCCGGGTTCTGGTCAACCACCACAAGGCTATCCGACTCACCCCCCATCTCAAGGAGGCCAACCGCATTATGGTCATCCACAGTATCCTCCTCAAAATTATCCGCCTCATCCTCCACCGCCTTCTGCTGGTCAAGGTTATCCTCAGTATCCTCCTCGAGGTCCCCCTGGTGGTCATATGCCACCACCACCGGGTCCTCAAGGTCCTCCGCCACCGAATCAGTATGCAGGGTATGGTTACCAACAACCTCCGCAGTAAATAAAAAAATAACGAGACTTTTTTTAAATAATTCGACTATAGGATTTGTGCTATTTAATGATGTGTAATGTAATGGTTTTTTGCATTGTAATTTTTATATTTTATATATGTAATAATTTGATGATATTGATAATTAAATAAACTGATTTTTTTGTTGTACTTGTGGGATCGTTTGTGGAATAAAAAATGATTTTTGAAATCTTATTAATTATTTTATTATTTTAATTTTAATGCTCACACTTCAGCTGCCCAATTTCAAAACACAGTAAGGGACAAATTTTTCAAAGTTGATTTTTTAGAATTTATAGTTCCAGTGGAGTCTTATGGACATAATTTATTTCATATTTCAAAAATTTTCTTTTTGTCAGTTACTGTGTTTTGAAATTGAGCAGCCGATTTACTCGTACATATTTCCTTTGATATTATTAAGGTAAGAGACCTAGTACCCGATCAGGGAACTAGGATTCGATCGTTTTATAAATTTGTATGTCTATATTTAGTAAATATAGATATACAAATATATGAGTGATCAAGTACTGGGTCTTTTACCTTATATTTATTATTTAATACTTGGTAA
->JN883616.1 Uncultured bacterium clone 254_InIs3-B9 16S ribosomal RNA gene, partial sequence 
-AGAGTTTGATCCTGGCTCAGGATGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGAAGCACTTTATCACGATTTCTTCGGAATGACGATTTGGTGACTGAGTGGCGGACGGGTGAGTAACGCGTGGGTAACCTGCCTTATACAGGGGGATAACAGTTGGAAACGGCTGCTAATACCGCATAAGCGCACAGGGTCGCATGACCTGGTGTGAAAAACTCCGGTGGTATGAGATGGACCCGCGTTGGATTAGCTGGTTGGTGAGGTAACGGCCCACCAAGGCGACGATCCATAGCCGACCTGAGAGGGTGACCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCGACGCCGCGTGAGCGAAGAAGTATTTCGGTATGTAAAGCTCTATCAGCAGGGAAGATAATGACGGTACCTGACTAAGAAGCACCGGCTAAATACGTGCCAGCAGCCGCGGTAATACGTATGGTGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGCAGGCGGTACGGCAAGTCTGATGTGAAAGCCCGGGGCTCAACCCCGGTACTGCATTGGAAACTGTCGAACTAGAGTGTCGGAGGGGTAAGTGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCTTACTGGACGATAACTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAATACTAGGTGTCGGGGAGCAAAGCTCTTCGGTGCCGTCGC
->MZ592923.1 Lysinibacillus sp. strain KEI8 16S ribosomal RNA gene, partial sequence 
-CTTGCTCCTTTTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGGCAACCTACCCTATAGTTTGGGATAACTCCGGGAAACCGGGGCTAATACCGAATAATCTCTTTTGCTTCATGGTGAAAAATTGAAAGACGGTTTCGGCTGTCGCTTTAGGATGGGCCCGCGGCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCGACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCACAATGGGCGAAAGCCTGATGGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAACTCTGTTGTAAGGGAAGAACAAGT
->XR_004099807.1 PREDICTED: Ipomoea triloba uncharacterized LOC116026275 (LOC116026275), ncRNA 
-TTTTTCCCATTAATCTGCAAAAATGAAGGCATTTTGATTAATAATTCAGGAGTGCTATGAAGGTTAGAGCCATACTTCGGTTGTGGAAAGGGAAGGCTCTTCCGAAAAAAAAGAGCAAAGAAATCATCTTCCACGACGAACAGGAATCGAGCTACATAACAGAGTAGTATGTACCAGTTGATATGTTGAAGGTTATCTCTATATTCCACAATAAAAAAGAGTATCCAGTAAAGGTCCATTGTATGTATCAGTTTCTTTGTTGAATTAAGTTCATTGTTCATATTAAATGAACTATTGAAAATATGAATATGTTCGTGATTTTTTTCTTTATGTTTTTTTTTTCTTTATGTTATGTCCATTGTTCATATAACAAAGTAGCATGTACCAGGTTTTGTTTCTTTAACTGTGTAGTTTAAGAAAAAGTTGTGGTTCTTCTCCTTTT
->XM_029121761.2 PREDICTED: Esox lucius contactin 5 (cntn5), mRNA 
-CCCCGCGCACCAGCACGCCGCAGAACAGAAGCTGCTGAGACCAACCGCCAGTCTGACGTGCAGAGTCAACCACCGAATTGTCATCTCCGCGGCTTTTATCCATTTCAAACGGCGTTCGGTAACTGGAAGGTTCCCGAAGTGTTGGCCAAGGAAGTCCAGAAAGCAACCGTCGGTGGAGAAATCGACACAAGATTACAGCGAAAGGAGGGAGGGATGTAGCTACTATTCACGTCGTCGTCTTATTCAGTAAAGACAGAGGAAAGGACCGGTTTGGAATCAGGCTGCTTTGGCATTCTGTGGTTCGGGGCGACGGAGACTGGTTGGTTACCGTTAGATTATCTGGGACTGGCAGTTGAAACAACTTGACGTTACGAAGGGAAAACCTGCATGTTCCCAGCTTTTGGCGGCACAGCTTTAATGAAGGATCACACCTGTTAACAACACTTGTGAAGGGGGCACCCACCTGAACGAGCATGGGGTCGCCGTGGAAACCACTTCTCCTGCTGTCCATCATCAGTGGCCTTTCAGACTTCGCCAAAGCTGTAGGAGGGAGGCAAGTGTCCTACGCAGCTGTTCTGAGAATGAAAGGGGACAGCTCATCATCACTGCTCAGTTCACGGAGCCGACATGCCTACAGCAGAGGACTGGTGACTCCTGATTGGCCGACGTCCTTTTCCAGCCAGCACCCGTCGCCTCTCAATCTGCTCAGCTATCAGGAGGAATACAGGAGTCAAGAGAGTGAGGAGTTCGGGCCAACATTTTCCCAGGAGCCAGATGACTCTATCTTTGCACTGGACTCTGAGGAGAAGAAAGTGATGATGAGCTGTGAAGCCAGAGGCAACCCAACACCTGCCTACAGTTGGTTCATTAATGGGACTAAGCTGGATGTAGAGGCAGATTACCGATACAGCTTGATGGACGGCAACTTGATAATAACCAACGCCAGCGAGACGGCAGATTACGGCAGATACCAGTGCATGGCGGAGAACAGCTACGGGATGATTCTGAGCAGGGATGCGCTCCTACAATTCGCCTATCTCAGGGCCTTCAGCGGCAGGACGCGAGGAGCCGTGTCTGTAAGGGAAGGACAAGGAGTGGTGCTCATGTGCAGCCCTCCACCTCATTCACCAGAGATTATCTACAGCTGGGTCTTCAATGAGTTCCCGTCATTCGTTGCCGAGGACAGCCGGCGGTTTATCTCCCAGGTAACGGGCAACCTGTATGTCTCCAAGGTGCAGCCTAGCGATGTGGGCAGCTACATCTGTCTGGTGAAGAACACTGTGACCAACGCCAAGGTCCTCAGCCCGCCCACGCCCCTTACACTCAGAACAGATGGTGTAATGGGAGAATATGAACCTAAAATCGAGGTGCATTTTTCCCCGTCTGTATTAGCAGCTAATGGAGTCACCGTGAGACTGGAGTGTTTTGCCCTGGGGAATCCTGTTCCAACCATCACATGGAGAAAGATGAACGGTAACATTCCTAAGAAGGCTCGTCTGAGGAAGTCCCAGGCAGTGCTGGAGATCCCAAATGTTCAGCTAGAGGACTCAGGCACCTACGAGTGTAAAGCAGAGAATCCCAGGGGAGGAACGGCCTTCAAGGGACACCTCCAAGTTTACACCCTGCCCCAGTGGAGCAGCAGGATAAATGACACCCAGCTGGACAGTGGGGAGCAGCTCCAGTGGGAGTGCAGAGCCACCGGGAGGCCTAGACCCTCCTATCGCTGGCTCCGTAATGGACAGCCAATTACACAACAGAGCAGGTTGGAGATGGTGAGTGGGGAGCTTATCATTCACAAGGTCCAGCAAGATGACTCAGGGATGTACCAGTGTGTGGCTGAAAACAAGTATGGAGCAATCTACTCCAGTGCAGAACTCAAGATCTTAGCTTCAGCCCCGGTCTTCAACCCCAACCCTATACGCCTGATCGCTACTTTGGGGAAGGACGTGTCGCTGGAGTGTAAACCTAAAGCATCTCCCAAGCCCAGAGTAACATGGAGGAGAGGGGACCGTAGAATACAGCCCAACAGAAGAATAATGCTGTTACGAAACAACACGCTGAGGCTCGTCAACGCCAGCCGCTCTGATGAGGGAAACTACGTCTGTCGGGCTGAGAATCAGTTTGGCTCAGCCGAGATGACGGCCACACTGTGGGTAAAAGAGGCCATGCGTGTGGACCTGAGCCCCAGCAGGGTGGAGGTGACGGTGGGGGAGAGTGTGGTGCTCAGCTGCAAAGCATCACATGACCCTTCTCTGGACGTGTCCTTCCAGTGGCTCCTCAACCAGCAACCCCTCGACTTCCAACAGGAGGGTGGCCATTTTGAATACATCCAAACACAGTCCTCCACGGTGGACCTGATGATCAGAAGCATCTTGCTGAAGCATGCTGGGAAATACGGCTGCCGAGCTCAGACCAGCGCAGACACAGTGTTTGCTGAGGCTGAACTTCTGGTCAGAGGCCCCCCAGGACCTCCTGGGGTGGTGATTGTGGAAGAGATCACAGACACCACAGCCACCCTGTCATGGAGTGCAGGTCTGGACAACCACAGCCCCATCAGCACCTACCACCTCCAGGCCCGGAGCCCTTTCTCCCTGGGCTGGCAGACTGTACGCACAGACCCCGATCCAGTGACAGGGGTTATGGAGTCGGCCATGGCTGTTGAGCTGAACCCCTGGGTGGAGTATGAGTTCAGGGTGGTGGCCAGCAACGCCATTGGGACGGGAGACCCCAGCGTTCCATCCAGAGGAGTGAGGACGAAAGAAGCAGTACCTTCAGTGGCTCCGGCTAACGTCAGTGGAGGGAACGGTCGAAGGCATGAACTGGTCATCTCTTGGGAGCCTGTGTCAGAAGAGTTCCAGAATGGGGAGGGTTTTGGCTACATCGTGGCATTCCGAGCCAATGGGACGAGAGGCTGGAAGGAGAAGATGGTGACATCAGCAGATTCCACTACATACAAGTACAGGGATGAGACATTCCCTCCCCTCACCCCCTTTGAAGTGAAGGTGGGCGTGTACAACAACAAAGGAGATGGGCCCTTCAGTGGAGTGGTCACGGTGTACTCTGCAGAGGGTGAGCCCAGAGAGGCCCCATCTGAGGTAAAAACTTCCAGCACTTCCTCTTCGGAAATTAAGATCACATGGCGACCGCCGAACCCTGGCCCAGGAAGGCCTGCAGGATACGAGGTGAGCTACTGGAGGGAGGGAGAACAGGAGGAATCTGGGAAGAAGAAGAAGACGATAGGGAACGAGACGTCTATGATGCTGACCGGCCTGGGCGGGAATAGTGTGTACCTCATTACAGTCCGAGGCTTCAACAGCATTGGCCAGGGCCCTGCAAGCATACCAAGCGCTGCCAAGACCAGGAAGGACCCTCCTGTCCAGCCTCCAGCCAACCTCATGTGGATTCAGGAAGGGAACAATGTGTCATTAAACTGGGACCCGGTCAAGTCTCAACCAAATGAGTCAGATGTCATTGGATACAAGGTCTTGTTGAGTCAGGAGGGGCGTGTCCACCACCAGGTGATGAGAACCATCAATCCCTCTGCCATCCTAACCCTACCAGAGGGGGGCACCTACATCATTGAAGTGCGGGCAGTTAGTGAGGGAGGAGAGGGAGCAGCCAGCTCCCTGGTCCGTGTACTCACCTCTTCAGGAGTGCGGGCAAAGAGCAGCCAGTGTTCAGTCCACTGTGTTCGACCCTGGGCTCTGCCATGGACATGGACTGCTCTGCTCCTTACTGTTCCTCTGGTGCCTTCAGCTTCCTGGTGAGGCCTACAGAGACCTCCTGCTCCTCTTTTACATGGAGGGACTGGGCCTCTCCTTTGTCCCCTCGCCCTCCTTCCATTCATCTCCTCCTGAAACTGTTTGCTTGCTCTGGCCTTGCCCATCAGCCAGACAGATCTGGGGCCTGCTGAGCGGATCCACTTCTAAAACCAACAAACAGATGGTCAAAAAATAACTCATTTCTGTCTTTTTTTTTCTTCACCTATCAACTTCCTGAGAGCTAAACAAAACTCTTCCTTTTTTTCTTTGGCGGGGGGGGGG
->XM_016506093.1 PREDICTED: Sinocyclocheilus anshuiensis guanylyl cyclase-activating protein 1-like (LOC107703476), mRNA 
-TGTCATTATCCCATTAGCAGTAGTTATTTTAAGGTGCCACCTCTTTTTATTGGTACTTGGATCTAATAGTTTCAGACATTCAGTATCCTGTGCTGTCACTGTGTGCGGAGGCCAGTCTGCACCTCGTTGTCAGAGCTCACAGGCCTGCAACCGTCTGGTCCAGCCATGGGGAACACACACGCAAGTCTGGACGACATACTCGCTGAGGACATGCACCACTGGTATAACAAGTTCATGAGGGAGTCTCCATCAGGCCTGATCACACTTTTTGAACTCAAATCCATCCTGGGACTGCAGGGCATGAATGAGGATGCTAACAGTTATGTGAACCAGGTGTTCTTCACTTTCGACATGGATGGGGATGGATACATAGATTTTGTGGAATATATCGCTGCTATTAGCTTAATGCTGAAGGGGGAAATCAATCAGAAACTGAAATGGTACTTCAAACTTTTTGACCAGGATGGCAATGGAAAAATTGACAAGGATGAATTGGAAACAATATTTACTGCTATACAACACATTACAAGAAATCATGACATTGTGCCAGAGGAAGTAGTGGCTCTTATATTTGAAAAGATTGATGTTAACGGAGAAGGTGAACTGACGCTGGAGGAGTTCATTGAAGGAGCCAAAGATCATCCTGACATTATGGATATGCTGAAGAAACTGATGGACCTCACTCCAGTCCTGGTCATTATTGTGGAAGGGCGACAGAAACCAATCAATACAAGTTAGGCTGACTAAACTCCAACTTAAGGACAGAGAAAACAGAAAATTCTCCGCCTGAAAGCAAAATGAAAGTGGAGTTTGGTAGTCCCACTCTTGAGGAACAGATGTAGCTTCCCACAGCACCTGTGAGAAAATTCTCGGGGGAACTTTTGCCCAAGCATGGTCCTGTCTGACCCCAGTGGAGATACCAAGCCTTGCATCTGAGCTGTCCTCAGCTAAACATTGATCTTCTAATGCTATAAGGGGGATTCAGGAAACTAAGGAACTGCTGGCAAGGCTTAGGAGTGAGCAGTGTGGTGCTTTTTAAGGAAAGGCTCAGTAGAGAACACTGTGCACACATCTAGTGACTTTCATTGGATGAGCACATCATATAATCCATGTACTTGTGCTTGAACTATTTATGGCATGACTATATTGCTCTGAGAGTGAACTCTGAGACAGTACATTGCCGATGTGGCCTGAATTGCCCTAAGAACTGGGAAATGTAGAGCAATGGTTCTCAGCTGGTTTTTGCCTACATTTTAAATTGGACATCAAATGGCAACCCAACACAGAACAAAAATAGTTTATTGTACAAAATGTACCTGTAAATCAAACATTTCTATAGAATGTTGTAATCAACATAATATTACAATGAACTGCATAGACCCAACAATTTACTACATTAGCAACCTGACCAGGCTGAGTGAGAAATATAACAATTTGATAAATTCATAAATGCAATAGTTGGCCACAATATGTTGACATCAATATCTTTGGCGTTATTAACAATGGGAAGTTGTGCCTGTTTATTTTGTTGTCCGTGACCCAGAACAGACCTAAAACCAATTTCTTGTCTGTGGCCCACCAGTTGTGACCACTGATATAATATCACAAATATTATAGCACTTTATCAAAGGAAAGCATCAAATTTTCCTGATACAGTTACCTTATGCAGTAGGTGCAAAAGAAATTCATTAAATGCATTTCCACCTGTCTTTTAGCTGATCTAAACTTGTCAAAACATTAAAACTAAAAGTTTTCAAAATTAGTACCTGCATTTTTTAGACTTATATCCTTTACCATTCAAAGGTTTGGGTT
->XR_004899828.1 PREDICTED: Phyllostomus discolor uncharacterized LOC118497304 (LOC118497304), ncRNA 
-CTGAACACACCTGCTTCATAGCATAACTGTGGGGCTGGCCAAAGTCTGTTTGTTTTTTTCTGTAAAATAAAAGACCCATTTTTCATTTTCACCAATGACATTATTGACTTGGACATTTGGACTATGGCCGCTCTCTCCCGTATGGTAGAACATTGACCGTTCTCCTTCAAAGTCTCAGTGTGATCGCTGTCGATTTCATCTGGTCTGCCCGACTGTGGGGCATCGTCCAGAGAGGAGTCTCCAGCACAGAACTTCGCAAACCACTCCTGACACGTTCCACCAGTCACGGCACCTTCTCCACACACTGCACACATCTTTTTTTGCATTTCAGTTGCATATTTACCTTTCTTGAAATAATAAAGCACAATACACAAAAATGTCTATATACCAGCCCTGG
->MG876669.1 Uncultured bacterium clone 7H_2119_4993_17823 16S ribosomal RNA gene, partial sequence 
-TGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCAACGCCGCGTGAGGGATGAAGGATTTTGGTTCGTAAACCTCTGTCAAGTGGGAAGAATAATGACGGTACCACTAAAGGAAGCCCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGGGCAAGCGTTGTTCGGAATTATTGGGCGTAAAGAGTATGTAGGCGGCTAGATAAGTCAGACGTGTAAGCCCATGGCTCAACCATGGAATTGCGTTTGAAACTATTTAGCTTGAGTGCAGGAGAGGAAAGCGGAATTCCCAGTGTAGCGGTGAAATGCATTGATATTGGGAAGAACACCGGTGGCGAAGGCGGCTTTCTGGTCTGTTACTGACGCTGAGATACGAAAGCCAGGGGAGCAAAGGGG
->JF603243.1 Uncultured bacterium clone GDIC2IK01C8G26 16S ribosomal RNA gene, partial sequence 
-TCAGGATGAACGCTAGCGACAGGCCTAACACATGCAAGTCAGGGGCAGCACAAGGAGCAATCTGAGGTGGCGACCGGCGCACGGGTGAGTAACACGTATGCAACCTGCCTGTAAGCGGGGAATAACCCGTTGAAAGACGGACTAATACCGCATAATACTAAATTACTGCATGGTAATTTATTTAAACATTTATGGCTTACAGATGGGCATGCGCATGATTAGCTAGTTGGAGAGGTAACGGCTCCCCAAGGCAACGATCATTAGGGGTTCTGAGAGGAGGGTCCCCCCACACTGGTACTGAGACACGGACCAGACTCCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGACGAGAGTCTGAACCAGCCAAGTCGCGTGCAGGAAGAATTGTCCTATGGATTGTAAACTGCTTTTGCAGGGGAATAAAGTGCATCACGTGTGATGTTTTGTATGTACTCTGCGAATAAGGATCGGCTAACTCCGTGCCAGCCGCGGC
->XM_029711062.1 PREDICTED: Salmo trutta sodium channel protein type 2 subunit alpha-like (LOC115160726), transcript variant X3, mRNA 
-ACCCTGCATCTCTGCAGTCATTTGTACCCGGTAACAACCGGAAGCGCAACAGAATGCTCTGAACAAGGCGACTGTGGTGGCAGCAATTTCATAACGCTCTCCTGTGTGATTTTTTTGGGGGGGGTCCATCTCTGGGAAATACTACATTACAGAGAGGAGAACCTTTTGACTTAATCAAGTATCCACATGTGTCCTCGAATCACCTTTTTACTCGGGAGAAAGCAACATCAAGGCGTGCCTGGCGATTTTTGGCGGATTCTTCCCCTTCTTGGATGAAAAACTAATGCCCTTTCTAATGCAGGAGGCTAGCCGTTCACTCTGAAAGTGCAGGATGAAAAGATGGCACAGCTGCTTGTACCGCCAGGACCAGACAGCTTCCGCCCGTTTTGTCGTGAGTCCCTCGATGCCATCGAGAGGCGGATCGCTGACGAGAACGCCAAAAAGTCCAAGGCGAAGCCCAACAACAATGACGACGACGGGCCTAAGCCCAGCAGTGACCTGGAGGCGGGAAAATCACTGCCACTCATATATGGGGACATTCCCAAAGGATTGGTGTCCACACCACTGGAGGATTTGGACACCTTCTACAGCAACCAGAAAACCTTTATAGTGTTGAACCGAGGGAAGGCCATCTTCCGCTTCAACGCCACTCCTGCCTTGTATGTCTTAAACCCCTTCAACCCTCTTAGAAGAATATCAATTAAGGTTTTGGTACACTCATTGTTCAGCATGGTAATCATGTTGACTATCCTTACCAACTGTGCGTTTATGACCCTGAGTCAGCCCCCGGACTGGGCAAAGAATGTAGAGTACACATTCACTGGAATCTACACATTTGAATCTCTTATAAAAATTCTGGCAAGGGGCTTCTGTGTAGGGAAGTTTACCTTTCTCCGAGACCCATGGAACTGGTTGGATTTCTGTGTTATTGTCATGGCATATGTCACAGAGTTTGTGGACCTGGGCAATGTCTCAGCACTGAGAACTTTCAGGGTTCTCCGAGCTTTGAAAACTATATCGGTCATCCCAGGCCTCAAGACCATTGTGGGAGCGCTGATCCAGTCAGTGAAGAAACTATCAGATGTGATGATCCTCACTGTATTCTGCCTAAGTGTCTTTGCCCTGGTAGGGCTGCAGTTGTTCATGGGGAATTTAAGAAACAAATGTTTAAGGATCCCTCTTAACTCAACCGACCTCTTCGATGATTCATTCGACTTTAATGGGACGGACCTCAACAAGACCAAGTCGTTCAACTGGACCTATTACATGAACGATCCCAAAAATTATTACTACCTCCCAGGTAAAAAAGATGCTTTGCTTTGTGGAAATGGCAGTGGTGCTGGGCTGTGCCCAGAGGGATTCTGGTGCATCAAAGCGGGCCGGAACCCAGATTACGGCTACACCAGCTTTGACACGTTCAGCTGGGCCTTCCTGTCTCTGTTCAGACTGATGACTCAGGACTACTGGGAGAACCTCTACCAGCAGACCCTGAGGGCTGCTGGGAAGCCATACATGATCTTCTTTGTGTTGGTCATCTTCCTGGGCTCCTTCTACCTTATCAACCTAATCCTGGCTGTGGTTGCCATGGCCTACGACGAGCAGAACCAGGCCACCATTGAGGAGGCTCAGCAGAAGGAGGAGGAGTTTCAGAAGCTGAAGAAACAGCAGGAGGACGCACAGGCAGCGGCAGCGGTGACAGCGGCTGAGAGCGGGGAGTTCAGTGAGAGAGGGGAGCTCACTGACACCTCCTCAGAGGCCTCCAAACTCAGTTCCAAGAGCGCCAAAGAGAGACGCAACAGGCGCAAGAAGAAAAAGCAGAGAGAGGAGGAGGAGAGAGGGGACAATGACAAGTTTCACAGGTCTGAGTCTGAGGGCAGTGTGCAAAAGAGTCGTTTCCGCTTCTCCATAGATGCCTCCAACCTGCTCAACTACGACATGAGATGTTCCACACCACACCAGTCCTTCCTGAGTATCCGTGGACCCCTGTTCTCATCCAGACGAAACAGCCAGGCAAGCCTCTTCAGCTTCCGGGAACGAGCGCAAGATATGGGCTCGGAGAACGACTTTGCCGACGACGAGAACAGTACTTTCGAGGACAACGACAGTCGCCGGGGATCTCTGTTTGTTCCCCGGCGGAGCGACCGGCGCTCCAGCAACCTCAGCCAGAACAGCATGTCGTCACATGTCCTGTTGCCGGCCAATGGGAAGAAGCACAGCTCCGTGGACTGCAATGGGGTGGTGTCCCTGGTGGGCGGGGCTTCACTTCCCACATCACCTGAGGGACTCCTTCTGCCAGAGGGCAACACTACGGAGACAGAGTACAGAAAGGCCCAATGTGAATCGTACCAGGCCTCTATGAACTTCCTGGAGGACCCAGGGGCCAGGCAGAGGGCCTTCAGTGTAGCTAGTGTTATAACTAATACTATGGAAGAACTTGAAGAGTCGAGACAGGAGTGCCCTCCTTGCTGGTACAAGTTCTCCAACACTTTCCTCATCTGGGACTGTTGTCCGGCATGGCTGAGGATCAAGAAGACAGTCAAGATGATCGTGATGGACCCTTTTGTAGACCTGACTATTACCATATGTATTGTTCTGAACACAGTGTTCATGGCTATGGAGCACCACCCAATGTCTGGGGATTTCAAAAAAATGCTTTCTGTGGGAAACCTGGTGTTTACAGGTATCTTCACAGCTGAGATGTGTTTCAAGATTATTGCTTTGGATCCGTACTGTTATTTTAAGGAAGGCTGGAATATATTTGATGGTATCATTGTCAGTTTGAGCTTGATGGAGATTGGCTTGGCCAACGTGTCTGGAATGTCTGTCCTCAGATCATTCCGATTGCTGAGAGTATTCAAACTGGCCAAGTCTTGGCCCACACTGAACATGCTGATCAAGATCATTGGTAACTCAGTGGGGGCTCTGGGTAACCTCACCCTGGTCCTGGCCATCATTGTCTTCATCTTCGCGGTGGTGGGCATGCAGCTGTTTGGGAAGAACTACAGAGACTGTGTGTGTAAGATCTCTACAGACTGCACACTGCCCCGCTGGCACATGCATGACTTCTTCCACTCCTTCCTGATTGTGTTCCGGGTGCTGTGTGGGGAGTGGATCGAGACCATGTGGGACTGTATGGAGGTGGCTGGCCAGAGCATGTGTCTCATCGTCTTCATGATGGTCATGGTCATCGGGAACCTGGTGGTCCTGAATCTGTTCCTGGCCCTGCTGCTGAGCTCGTTCAGTGCTGATAACCTGGCGGCCACGGATGATGACAGCGAGATGAACAATCTGACGGTGGCCATAGGCCGCATCCACCAGGGCATCGCCTTTGTCAAGGCCTTGGTGTGCCGCTCCTTCCACAGCATCTGTCTGAGGAAAAAGAAGGGGAGCCTGGATGACCTCCACAGAACCAACTACAACTCCAACCACACCACTGTGGAGATCATGAAAGACCCTGAATACGTGAAGGATGACAATGGCACCACCGGTGGGGTAGGCATGGGAGTGGGTAGCAATGCAGCAGGGAAATACATAGTCAACGACAACACTGACTACATGCAGTTCATCCACAACCCCAGTCTGACCGTCACGGTGCCCATCGCTGTGGGGGAGTCGGACTTTGAAAATCTCAACACTGAGGACTTCAGCAGCGATTCCTCGGACATAGAGGGAAGCAAAGAGCAGCTAGCTAAAGACCGTCCACTGAGCTCATCAGAGGGCAGTACAGTGGACATCAGGGCCCCAGGAGAGAGAGAGGGCTCGGTGGACATGGAGCCTGAGGAGTCCATGGAAGCTGAAGGATGCTTCACTGATGGCTGTGTCCGTAGATTCCAATGCTGCCAAGTGAACGTTGAGGAGGGCAAGTGGAAGATGTGGTGGACATTGAGGAAGACCTGCTTCAGGATAGTGGAGCACAACTGGTTTGAGAGCTTTATCATCTTCATGATCCTGCTCAGCAGTGGAGCACTGGCATTTGAGGACATCTACATCGAACAGAGGAAGACCATTAAGACATTGTTGGAGTTTGCGGACAAAATCTTCACCTACATCTTCATCCTGGAGATGTTGCTGAAATGGGTGGCCTATGGATTCGCCAAATACTTCACCAACGCCTGGTGCTGGTTGGACTTTCTTATTGTTGACGTCTCTTTGGTCAGCCTTGTGGCCAACGCCCTGGGCTACGCTGAGCTGAGTGCCATCAAGTCCCTGAGGACGCTGCGAGCGCTGAGGCCCCTGAGAGCGCTGTCCCGCTTCGAGGGCATGAGGGTGGTCATAAACGCTCTGCTTGGAGCCATCCCCTCCATCTTCAATGTGCTGCTGGTCTGCCTCATCTTCTGGCTCATCTTCAGCATCATGGGTGTCAACCTGTTTGCAGGGAAATACTACCATTGTATCAACATGACCACGAGTGATCGCTTCGAAGTCAGAGACGTGGCTAACAAGACAGAATGTTTGGCTTTGACAGGTACCCACTGGAAGAATGTCAAGATCAACTTTGATAACGTGGGAGCAGGCTATCTGGCACTGTTACAAGTGGCTACATTCAAAGGCTGGATGGACATCATGTATGCAGCTGTGGACTCTCGCAATTTGGATGATCAACCCGACTACGAAGTGAATCTGTACATGTATCTGTACTTTGTGGTATTCATCATATTTGGATCCTTCTTCACACTCAATCTCTTCATTGGTGTCATTATAGACAACTTCAATCAGCAAAAGAAAAAGTTTGGAGGTCAAGACATCTTCATGACAGAGGAACAGAAGAAATACTACAATGCTATGAAGAAGCTTGGCTCAAAGAAACCCCAAAAGCCTATCCCTAGGCCAGTGAACAAGTTTCAAGGGTTTGTCTTTGATTTCATTACAAAGCAAGCCTTCGACATTGTCATCATGATTCTTATATGCCTTAATATGGTCACCATGATGGTGGAGACGGAAGACCAGACAGACGACATTCGTAAAATTCTCTACAAGATCAACCTGGTGTTTATTGTCATGTTCACCGGGGAGTGTATTCTGAAGATGATCTCACTCCGACAATACTATTTTACCATTGGTTGGAATGTATTTGACTTTATCGTTGTTATCCTGTCGATAATTGGTATGTTTCTCTCGGAACTGATAGAGAAGTACTTGGTTTCACCAACCTTATTCCGAGTCATTCGACTGGCCCGAATTGGTCGCATCCTTCGCCTCATCAAGAGTGCCAAGGGAATCCGTACACTCTTGTTTGCGTTGATGATGTCACTTCCTGCATTGTTCAACATTGGTCTTCTGCTCTTCTTAGTGATGTTTATCTATGCAATCTTTGGCATGTCAAACTTTGCATACGTCAAGAAGGAGTCTGGGATTGACGACATGTTCAACTTTGAGACGTTCGGCAACAGCATGATCTGCCTGTTCCAGATCACCACGTCTGGGGGCTGGGATCTCCTGCTGGCCCCCATCCTCAACAAGGGAGAGCCAGACTGCGACAGCCGGAAAGAGCACCCAGGAAGCACGTACAAGGGGGGAGACTGTGGAAACCCCCCTGTGGCCATTATCTTCTTTGTGAGCTACATAATCATCTGTTTCCTTGTTGTGGTCAACATGTACATTGCTGTCATTCTAGAGAACTTCAGTGTGGCCACTGAGGAGAGCGCTGAGCCCCTGAGCGAGGATGACTTTGAGATGTTCTATGAGGTCTGGGAGAAGTTTGATGCGCGAGCCACCCAGTTCATGGAGTATGACAAGCTGTCAGACTTTGCTGATGCCCTAGACCCCCCGCTACGCATCTCTAAGCCCAACAAGATCCAGTTGATCTCAATGGATTTACCCATGGTGAGTGGGGAGCGCATCCACTGCCTGGACATCCTGTTTGCCTTCACCAAACGTGTCCTTGGCGAGGGGGAAGGCTTGGACATCCTCAGGGGTCAAATGGAGGAGCGATTTATGGCCTCCAACCCCTCCAAGGTGTCCTACGAACCAATCACCACCACACTGCGCCGCAAGCTAGAGGACATGTCTGCCCTGGTCATCCAGAGAGCTTTCAGACGATATCTTCTCAAGCGTATTGTTAAGCGGGCCTCTGCCATGTACAAGGAGAAAATGCAAAGTGGAGGCACGCTCCTTGATAAAGAGCTTCTCGTCATAGACAAATTTAACGAGATCTCTACTTCAGACAGAACTGACATGACACCCTCCACAGCTTCTCCCCCATCATATGACAGTGTCACAAAACCTGAAAAAAACAAATATGAAAAAGACAAGAGAAAGAAGGAGGTGAAGGAGAAAAAAAAGTACATGGATGTTGGGAAGATTTAGCATAGAATTCATTCTGCTACAAATTGTTTACAGCCTTTGAAGGTGACCAATGCGTCAAGTGAAGTGTCTTTGGTGTGAATATCTATGCCAAACTGACAATGCTTACTTGAGTCTAAATGTAAGGTTGGTGCCTAACATGAGGCAGTGACTCACATTCTTAGGCTGTAAGAATTGTTTGGATGTTAATGGGGACTAAAACAAATGTTTGCCAGCTTTATAGGGACAGGTAAAACATTTTGTTGTGTGTTGTTACAATCAGAAACGTTTAGTTATACTGTAACTTCTCTTGCAGCTAGTACTTCCAGGGTTGCATCCAGTGTCTTGCATTATAACTGCCATATGATTTACTAACTTATTTTTCTTACAGAATCTTGTTTTTAAAACTCATAGGTTGATTGTGTGACTATTTTTGTAAACATATGTTTTACTGTAAAAAGAGGGGTTTCATGTATTGCTTTAAAGGTAGTCTTGTTCACTTTAAATGTTCATACAACTTGACTTGTCAAGTGTGATCAAACACACATCCTTGTGGGGTGCAGGGCCCAAAAAAAAGTTGGTATAAAAGAAATTGTGCCCGCACACTCATAAACCGTTTTTAAATGAAGGTACATGGTGGAGCTTATGCATGTGCGGGCTCTGTTTCGAGCATAAGACATGACTACTCATGACAACCATTATTGCTGCAGTGCAGTTAGGGGGATTGCTGCAGTTCAATCGACGTGTAGACTTGCATGAATGCTTACCCATGATTACAGTGTCGCATTACGCACCATCACCAAAATGAGCTTGATTTCTCCGTGATGTCTGAGGGACTCATACTTTGATGAATCTGTAACATTATGTTACTCTCACTATTACAAATCAACAGAAAAGATTTCTCCTGAGCATACAGTCCAAATACCATTACCAACAACTGTTGTCTATAATCAGTTTCCGAACAATAACACGCTCTAGAAAAACATAGTTTTCCTCCTTTCATTCATCAGAAACTACAGTACAATGCAGAATACATTCATCTTTAGTGCTGGTTGACAGAGTTGATACACATAGTATTCGTAGTCCAGCTCTTCTCTCCAGCTTGAACCTAAATGGCCTCAAAGACATGTCTATACTGTATTTTCTCTTCATAGTGGTGAATGATAAAATGAGGCAATTTCCTCTGCACAGTATAGTTGTGACCATCAGGTGTAAATCGCCTGAAATAATCTCCAAGCCTAGTCTGACAGGTGAAACACTGTATTCTGTGTCATATATGCTCACTTAAGAGGCATTCCGACAGCATGTATCTTGTGTACTCTGTGGTTTTGGTACTGCAACATCATTAGTAAGTGCTATAAAACTTGTCATTTACCAAATCTAAATTGCTTTGAGTTTACCTTTCCTACCCACTTCCCAAATATTTTTCCATTGTTGTTGATGTATCTGTATGTACATATTCTATAATATATGAAATATACAAATATATTTGATATATTATGTGATGTTTCATGTATAATGGAATATATGAAGTTGTTAATGTTATTTAATACATATATCTATTATATTCTGCATTCTCTGCTCTATATGGCAGACAGACCAGAGTATGAAGCATCCAGTTGAGGCTGTGGGAAGATTTTGTAGTTAGATTACACTCAATGTCTATATAAATATTGTAATATAATCATTTTTCTTTGTACTGTACAACTGTTTTGTAAATAGTTTGCTATACAATATAGCCACACTGTCTGCGCTATAGCCACTTTAGTTATTTTAAGTTTCACTGCACCCTTTCATTTGGAAATGCCTCATGTGATCTAGTGAAGGGGATGTGGACATCTCATTTTGATTCTTACATCTTTTATTTTGTGTCATTTGTAAACTGTTGTCACATTTTACCTCACATGCTTTATCATAATAAATATCTAAGATGGAACATCAGGTTCAGAGAATTCTGAATATGATTGTCTCAAGGCTAGTGTGACAGCACAAGTCTTCGATTGTTTCCTACATTTGTTTACATAGTAATCCAATTCCTCAGGATGTTACTTTTGTCAGCTGTTCCCTTTGTATAAAGTGTCACAAGTATCTGTAATTAAAATGTTATAAAGTATGTTATAAAGAGCATATGTTGCATGTAATAAAAACGTTCAGAATATGTATATACTATATATGTATACACAATGAATGTTTTGATTACATAACATTTAATAGATCACATCTTTATATGCATTATGCTTGTAGTGTATGAGTAAACTGCATGCAAGATATTGCTATAACCCATCTCATTGAAAAGCCAAAAGAATAAAGAATACATGTACCTCA
->XR_989699.2 PREDICTED: Macaca nemestrina uncharacterized LOC105485591 (LOC105485591), transcript variant X1, ncRNA 
-TGGTTTGCTGCAGGTCCGCTCCAGACCTTATTCCACTGAATCTTTCCTGCTCTTGGAGATAACACCAGTGGAGTCTGCAGAACGGCAAAGGCGGCTTTCTGCTTCTTCCTCTGAAACCTTTGTGGCAAAGGAGCACTGACATGATGGCAGCCGGAACTCTCCTGTGAAATAGGAAGATGAAGGCTGGAGTTGCATAATGATCCTTCTATTATGAGCTTTGGTAACGTCATTTTCCAGAGGGATAGTCATAAATCTTATTAGTAAAACTCAATTGCACATTTTCATCAAAAATGAGGCAGTTCCTCTAATTCAAATGAACATACACGTTTAAATACAGTCGCTGCTCTTGAGAACGTGTGTCAGTGCGCTCAGTAATTCACCATTGGTGAAGACTGACCTCTACTAAAAAAAAAAAAAAAAGAAAAAGAAAAACTGAGCATCCAAATTCAGAGAGCCTATCAAGAAATTCAGAAAGCCTATCAACAAGAATAATGCACATACCATTCCAACACTGTGTGAAGTGAGAGGACATGAGACAAGGTCATTCTTAAGCAACAAATTCTGAAGACAGACCAAAGTGTTCTGCATATCAAGCAGGTTGTGAGGTCAACGTGCAGAAAATATCACAACATAAGTTAATGCCTGCGAATGACACCCTAAAAACAACTTTTAAAAGCAGTCCTGACAGCTAGAGCATCTGCAGAAATTACCTCCACATGAAACGTTGCTTGGTGCTGCAGAAGGGGCCTCCTGTTAAGGAATACATTTGACAGTGATATCAAGAAGTGCTAGGGCGATTTAGTGGCAAGATGGCCGAATAGGAACAGCTCCAGTTTCCA
->XR_003517074.1 PREDICTED: Zalophus californianus uncharacterized LOC113913036 (LOC113913036), transcript variant X2, ncRNA 
-CCCCGACGTGCACACCCGAGGACCTAAGACACGGCTCCTACACCTGCCGCGTGCGACACCCCCGCACGGAAATCCCGCTCCTCGGCTGACCTGGTGACACAGGCCGTCACCCCTACCCCCACTTCCCCCCCTCCACCCCACTCTCTGCGTTGCTTCCGTGAGGTCAGCACTCACCTTCCCTGCAGGGATGAAAAGGGCAATTCGCGCCTCCCGCCAGCCAAGGAGTCTGCCCTTTCTTCCCCCACGCCGGGCGCTTAGAGAAGAGGAAGGACAGCAAGCTTGCTTTTGCTTTACCCTTACCTTATAAAGCACCGCTCTCGTGGTTCTGACTCAGAAGACCCCGGGGGCCCAATAAGCCAGGCCTGAGCAGCAAGCAAGCGAGGCCCGAGCAACAAGCGAGTGAACGACCAACTTGGAGTGGGAAGAGACCAGACTTAAAGCACTGAACAGGAATTCTGAAACCTAAGAAGTCAATGTTAAGGCTAGTTTCCCTAACTTACAAGGCTGGACAATACTCTTCACCATTTCATGTGGCCCAGATAGCTGGAACAGCTCCAGTCACCAGACCTCACACCAATGTCGCAAGCAAGAAGGAAAAGCAGAGACCAAGAAACTACTTGTAATTCTCAAATCGGTACCAGCAGCTGCCATGGGCCCGCTTCACTTTCACACAAAACAAAACAAACGAGAAAGCACGTATCTTTCCTTTGGCTTTGTGTAAGCTCCTTGACAAAAGATAATGACAAGATGGCCGAGAATTCGGCATCTGACCAGCACCGCATGT
->XM_028148513.1 PREDICTED: Eptesicus fuscus transcription factor 7 (TCF7), transcript variant X4, mRNA 
-CAGCTTTTCCCGCGCCCCTCACGGCCCCTCTGGATTTCCCCGCAGGCTCTCGGGCGGGAACACACTTCGCAGAGACTTTTCCCCGACAAACTTCCAGAATCTCTGGAGGACGGCCTGAAGGCCCCGGAGTGCGCCAGCAGCATGTACAAAGACACCGTCTACTCCGCCTTCAATCTGCTCATGCACTACCCGCCCCCCTCGGGAGCAGGGCAGCACCCCCAGCCGCAGCCCCCACTGCACAACAAGGCCAGTCAGCCTGCCCATGGCGTCACCCAACTCTCTCCTCTCTATGAACATTTCAGCAGCCCACACCCCACACCTGCACCGGCCGAAATCAACCAGAAGCAAGTTCACAGGCCTCTGCAGACCTCTGACATCTCTGGCTTCTACTCTCTGACCTCAGGCAGCATGGGACAGCTCCCCCACACTGTGAGCTGGCCCAGCCCTCCTCTCTATCCCCTGTCCCCTTCCTGCGGATATAGACAGCACTTCCCTGCCCCCACTGCAGCCCCTGGCGCCCCCTATCCCAGGTTCACCCACCCATCCCTGATGCTAGGTTCCAGCGTACCTGGTCACCCAGCAGCCATTCCCCACCCGGCCATTGTGCCCCCCTCAGGGAAGCAGGAACTACAGCCTTATGATCGAAGCCTGAAGACGCAGGCAGAATCCAAGGCAGAGAAGGAGGCCAAGAAACCAACCATCAAGAAGCCACTCAATGCTTTCATGCTGTACATGAAGGAGATGAGAGCCAAGGTTATTGCAGAATGCACACTCAAGGAGAGTGCTGCCATCAACCAGATCCTGGGCCGCAGGTGGCACGCACTGTCACGGGAGGAACAGGCCAAGTATTACGAGCTGGCCCGCAAGGAGAGGCAGCTGCACATGCAGCTATACCCAGGCTGGTCAGCGCGGGACAATTACGGGAAGAAGAAGAGGCGGTCCAGAGAAAAGCACCAAGAATCCAACACAGGAGGAAAAAGAAATGCATTCGGTACTTACCCGGAGAAGGCCGCTGCCCCAGCCCCTTTCCTTCCGATGACAGTTCTCTAGGTTGCTCCGGGTCCCCAGTCCCCCAGGACTCACCCTCATACCTCCTGCTGCCTCACTTCCCTACTGCACTACTTGCTAGCCCTGCAGAACCGGCGCCTACATCACCAGGTCTCTCTGCGGCACTCAGCCTCCCAGC
->XM_032234808.1 PREDICTED: Thamnophis elegans microtubule affinity regulating kinase 3 (MARK3), transcript variant X2, mRNA 
-AGGAAGCCGGGCGGCCATCTTGGATCATCCGGGAGCGGCGGCGTTGTTGCCGCCGCCGCTGCTGCTGCTAGTACTGTGGCTACTGGTTGAGAGAGCCGAGGGAGCTGGTTTGACGGCGGCAGCAGCAGCGCCAGAGGGGTTGTCTTCCTTCAGTGTTTCCAACCCAGGCTGTGACGGAAGCGTCTTTCTCCTTGGGTCTGAGCCTTCCCCCTTTGGGATAGGGGGTTGGTAGGCAGCGAAGGACTTGGGAGTTCTGGAGAAGAAGGAAGAGGAGGGGGCGCAATTAAGTCATGAGAGCCCGAGGCCCGGCGAAGCAATCCGTGTAGAGTTAGAAAACGGCTGAGGGCTTGGCCCGCTTCCCTTTGACCAGCTCTGGGGGGTTGGGGGGGTTGGTTGTTCTTTCGCAGCCGACAGTGGTTGCGCGGAAAGCGGCGGCTGCTTCCCCACTTTTCCTTCCTCAGCAGCCTGCTAGTTGGGCTGTACCGTAATTGCTGCAGCGCCTGCCCTCTCCCGGCTCCCCGCTTTTTTCTTTCGTCTTTTAACGGCACCGGACCATTTTTTGCCCCGTTTTTCTTTTGGTGCTCCATGAGAATCTCCTCTAATCTGTCCGTCCCCACCTTCTAAAGACCCTAATCTGTCTATAAGATGATTCCTGAAGATTCCCAGAGGAATCTAATGCTGCATTATCAGACTGGAAGATAGATGAGAAAAAGGGTGGTGGAGAAAATAATCACCCCAAATTTCTCTTCCCCCGTACTACCTTTTCCTTTGATGGTGGCACTTGATAACTGCTATCATGCTGTAAAATCACATTTTTTTGTAAATATATATATGTATATGTGCTCGGAGGGAGGGAGGTGTTAGGATTTTTTTATTTTTATATAATAAATAGTTGGATTTTGCCATTGCAAACGGTGCTTCAGCTAAGTGAATGAAAATGTCTACTAGAACTCCATTGCCCACGGTGAATGAACGGGACACTGAAAACCATATCTCTCACAGTGAAGGACGACAGGAAATTTCCTCCCGAACTGGTCGGTCTGGGGCTCGCTGTAGGAATTCTATAGCTTCCTGTGCAGATGAGCAGCCTCATATTGGGAATTACAGACTCCTTAAGACAATTGGAAAGGGAAATTTTGCAAAAGTGAAACTGGCCAGACATATCCTTACTGGCAGAGAGGTTGCAATAAAAATAATTGACAAAACTCAATTGAATCCAACTAGTCTACAAAAGCTGTTTAGGGAAGTAAGAATAATGAAGATTTTAAATCATCCTAACATAGTTAAATTATTTGAAGTAATTGAGACTGAAAAAACACTCTACTTAATCATGGAATATGCAAGTGGAGGGGAGGTATTTGATTATTTAGTTGCACATGGAAGAATGAAGGAAAAAGAAGCAAGAGCGAAATTTAGACAGATAGTATCTGCAGTGCAGTATTGTCACCAAAAGCATATTGTTCACAGAGATCTCAAGGCTGAAAATCTATTACTTGATGCAGACATGAACATTAAAATAGCCGATTTTGGTTTTAGTAACGAGTTTACAGTTGGTAATAAACTGGACACATTTTGTGGCAGCCCTCCCTATGCTGCTCCAGAACTCTTCCAAGGCAAGAAATATGATGGACCAGAAGTAGACGTTTGGAGCTTAGGTGTCATTCTTTATACCCTTGTGAGTGGATCTCTGCCTTTTGATGGGCAGAATCTAAAGGAACTCAGAGAGAGAGTGTTAAGAGGAAAATACAGGATTCCTTTCTACATGTCAACAGATTGTGAAAACCTGCTAAAACGTTTCCTGGTGCTAAACCCAACTAAAAGAGGCACTCTTGAGCAAATAATGAAGGACAGATGGATCAATGCAGGACATGAGGATGATGAACTTAAACCATTTGTGGAACCAGAATTAGACATCGCAGACCAAAAGAGAATAGATATTATGATTGGAATGGGATATTCTCAAGAAGAAATTCAGGAATCTCTCAGTAAAATGAAATATGATGAAATCACTGCTACATACTTACTACTCGGGAGGAAATCATCAGAGTTGGATGCTAGTGACTCAAGCTCTAGCAGCAACCTTTCTCTTGCTAAAGTCAGGCCAAGTAGTGATCTCAATAATAGCACTGGACAGTCTCCACATCACAAAGTTCAAAGAAGTATATCTTCTAGCCAGAAGCAGCGAAGGTACAGCGACCATGCTGGTCCATCTATTCCTCCAGTAGCAGCATATCCTAAAAGGAGCCAGACGAGTACTACTGACAATGACCTCAAGGAAGAAGGGATTCCATCAAGGAAATCCAACAGCAATGCAGCTGGAGGAAAAGGAATTGCTCCTGCTAGTCCTATGCTTGGGAATGCAAACAATCCAAATAAAGCTGACATACCTGAGCGTAAAAGAAGTTCTGTTACACCCAATAGCAACACTACACCTGGAGCAGCCATGACACGGCGAAACACTTATGTTTGTAGTGAACGAACTGCTGCAGACAGACACTCGGTAATTCAAAATGGCAAGGAAAGCAGTACCATTCCTGACCAGAGAACACCAGTTGCTTCAACTCACAGTATCAGCAGTGCAACAACACCCGATCGTATCCGATTCCCAAGAGGAACTGCCAGTCGTAGTACTTTCCATGGTCAGCTTAGAGAAAGGCGCACTGCCACCTATAATGGACCTCCTGCGTCACCTAGTTTATCCCATGAGGCAACACCACTTTCACAGACACGAAGTAGGGGCTCCACTAATTTGTTCAGTAAATTGACTTCAAAGCTGACTAGAAGAAACATGTCATTCAGGTTTATCAAAAGTCGTAACGTAGCCGTTGATCAGAAGGATGACAGCAAGGAAGCCAAACCCCGTTCACTACGATTTACTTGGAGCATGAAAACTACCAGTTCAATGGATCCTAATGATATGATGAGGGAAATTCGCAAGGTCCTGGATGCCAATAATTGTGACTATGAACAGAGGGAACGTTTCTTGCTTTTCTGTGTCCATGGGGATGGCCATGCAGAAAACCTCGTGCAATGGGAGATGGAAGTGTGTAAGCTTCCCAGACTGTCTCTGAACGGAGTTCGCTTTAAACGGATATCGGGAACATCCATAGCTTTTAAAAACATTGCTTCCAAAATTGCCAATGAATTAAAGCTGTAATGAGAAGAGCAATCGAGTTTGTAAATTAAGTAGCAAATTCAAGTGTTTTTGTTTTGTTTTTGAGGACACCAATGGTCATGTATAGAATACTTAGGGCAATAACTTCTGCATCTTCTGGATCGTGATATTAAAACAAAACAGTTCAGACAAGCTGCTGAGCTGGGAGGGAAGTTGGACTTTTTTTTATAAGTGCACTACAGCATTAAAGTTGCCTATGTAAAATATTCCCTTCTGCTTTATTTCCATTGCTTTGAGTCTTGACAAACAATCTAAAACACACCATGTATACATTTGGATATTCCTCCTGTTGTGTGGATGTGTGAATGTACAGTATGTGTGTATAATTATAATATAAAAGTATTATATGTAAACAATTCATTTATAGCATCAGAACTGTACCAGTACCTCTTCCGGGTTAATTTTGGTGCTAAAATGGAAATGGCCAAGGTGAAAGCCCTTAAGAATACTAAATAATCGGTAAACACAAGCTTCACAGTTCACTGTTGTGTTTAAGATTATGGAGGTTTGGGTTTATGGGTGTGAACATTATTCCTGTATTTTTTAAAATTAATTTTCATAACATGATTTAAATCCCCCCAAATAATTCTTTCTTTTCTTTTGCCTATTTATTATTATTTAAGTCTGAAATCAATTTAAATTACTTAATTATGATAATGAAAATTGTGGGGGAAATGCTTCAAGGTTACATGTTTTTTTCCTTTGCTAAGCTGATTGAGCATTTTATCCTCACCTTTTTTTGCTAGTACATATTATAATTTTAAAAATTTTACTTGAAAAGTTTGTTCTCAACTCCCATTCATTTCAGTGGAGCTGGTGCAGAGAAAACTTGTTACTAATGAAATACTGTAGAAACAGCCTGAACAATTGATATAAATTTTACATTTAGGCTACCTTATAATAATGTATTTTGAAGTTTAAAAAAACCATATTCAGACATTTCTAGTGTGAAAGAAATTCCTATGGCAAAATAATTGTGCCAGATCAGCAAAAAATGATCAGGAGAGAGAACTTTTGAATTCTAGTAATTTAATATTCTTGTACGTACTATACAATGACTGATAATGTTAATCATAATCAAAACACTATCAGCAAAGTTTATAAAAGTGAGAAAGTATGACCTGTCCAGCCAGGATTTGTGTTTTATTTGGTCTTTCCCAATTGTTTGCTGCCCAGATTTTAAAATTGGTTATGCAGGCTGGGAATTATGGGAATGGTAAAAATAAATATATTAAGGGAGATTAGAGGATTGAGAAAAGCTATTCTAAGTCTATGTCATGTGTTTCAATTTTGTCAGAGGCTTAAACTTCTTAAAAGCCTTGTTGCTGGCCAAGTCTTCCTTCATCATCAATTGCATCTCTCTAGCAAATTCTGCCCTTAGAGACAAAAAGCTATTGAAAACAGGGTGGGTAGGTAGGTGGAGAGGATTGCCTGCCAGTGACATGATAGCTCATAATTTCCATTTGGAAATGCTTCTGTAAATCTGAACAGGTTTATATGCTTTCTTGCACAGCTTCATATTTAAAAATATTTTAGTCACAATGCACTGGAGTTTAGAAGGGGGTTGTAAATGACTTAAATCTTTGTTTTTATGCTGGGTAAACAAATCCAATCCCTGGACCTTTATCTAAACTTCTATTTTCTAAGCTTGTGACAAAGCTTCAGACATTCAACATAATTATGATGACTAAAACACTTTTTAAGAAGGCTTGCTGGTCCTGCATTGCAGGTGATACGAAGCAATTTTAGGGTGTACTCTACATGAATTGGCTGTAACTATCTGCCTTTTTCAAACTGCTATCTCCTCTGCTGGTCCTTACTAAATTGGGTATGATTTGTCTAAATCAAGTCATAGGATGATATAATCTTTTCTGCTGCCTTAATCAATGCCTTTTGATTCAAACTTGTTAGGAGCTTAAAGTATCATGTATTAGATATATGGTCTGGCAGAAAAAACCTTCATTTAAAATGTAGTGAATTGAATTATAATATTTCATTTGGAGGCACCCAACTAAAATTCAATCCAGAGTGGTAATACAGAATACTGAATGTTCTAGACATTTTTCATTTATGTGTAATTCTCCCTTGAAACTTTGTAAAGATGTTATATTAATCCTGCATTGCGGTACTATAGCACAAAGTGACTGACTTCTGGTTTGTTTTTGATTTTTCTTAATGAAAAGAACAGTATTCTGTATAGAGATTTAATTATAACAATTGTTCAACAGTGGCTGTAGCAAGTACTGATTCTCCATTTT
->XM_019789640.1 PREDICTED: Branchiostoma belcheri mucin-5AC-like (LOC109485937), mRNA 
-AGGTGTGTACATGTGAAGTCTATTGATCCCCAACCGCCGTCCTGTGAGACACTTGCCTTCACCATGGAGCCGGGGAAACACATCTGCGCCGCGGTAGTCCTGTTGGGGTACGTTATTTCAATAATATCGACTTCAACAAGCCCGATATATCATGTAAGCTACCAACGTCTTGCCGATGCAACACAAGTGCCACCAACGTCTCAGCAGGAACATACCATTTCGACTGACAAAGAAGCCCCCACAGACAATGTGCAGACCACGGTAGAACAGGATACAGCAACTTCATCCGGTGGGAATGGAGTGACAGCCTTGGGAACAGCAATATCTACAATAACAAGGTTGGTAACAACGTCATTAGTTGACTCTAGTACTGAGTCTGACACTGTTCAGAACACAAACACGACAGCAACAGACGCGTTTACAATTGTGGATGCCCAAAGTACTGCAAACAGTGCCACGGGCGTTGTAACGGCAGCTGTTACAACTGAAAAGTCTTTCGTTACTACCGATACTGTTACAACAACTGATACAGTAACCCCGGTCATTACTACTGATGTTGGCATAAATGACGCAACTGGGTCCACCACCACTGACACCTTCATCACTCCAGTTACAACTGATCCTGTCATTACAACGAAAGCTGGTACAGCATCTGTAAAAACCGAGTCTGGCCTTTCCACACATGCTATCACGCCGTCTATCACAACGGAACCTGTTCAAACAACATATGTTTCTACACCTGCAACAACAGAGAATGTCATTACCGACAATGGCATAACAACACCCGTTACCACAGATTCTGCCCTTACCACTGATGCAATTGCAACATCTAGTAGAACAGAAGATGTCATTACAACTGATGCTGGTACAACGTACGTCAATACACAACCTGCGATAACCACGTATGTTGTAGCAACAGCAGCCACTTCACAGCCAACCGTCATCACTAATGCAGCCACAGCACCTGTTACACCACAACCTGGCCTTATAATAATTACCACTAACGCGGTTACAGCATCAGTTATAACACAGTATGACCTTCCCAGTGGCGCGGTTACAACGCCGGTTACAACACATCCTGGCATTACCACTGGTGCTAACACAATATCGATTACAACAGATCCTATTTCTACCACCAACGCGAATACAACATCACTTACACCACAGCCTACCCCCACCACCATCGCTGATACAACATCTGTCACAACAGATCCTATTTCTACCACGAACGCCGTTACAACATCAGTAACAATAGAACCTATCTCTATCACTAACGTCGATACAACATCTGTTACAGCAGAAACTATTTCTACCACCAACGCTGATACAACACCAGTCACAACAAATCCTATTTCCACCACCAACGCTGTTACATCAGTTACAACAGAACCTATTCCCACTACCAACGCTGAAACAACATCAGTCACAACACAACTCATTCCCACGACGAACGCCGAAACAACATCAGTTAAAACAGATCCTATTCTCACCACCAACGCCAATACAACGGTATTTACAACACAACCTATCCCAACCACCATTGGCTTTACAACATCAGATGTCACATATCCTATTTCTACTACCAACGCTGTCACATCAGTGACACACTGCCTACCCCCACCATCAACTCTGATACAACATCGGTCACAGCAGATTCAATCTCTACCACCAACACTGGTACAACATCAGTCACAACAGATCCCATTTCTACAACCAACGCTGTTACATCAGTCACAACACAGCCTACCCCCGCCACCAACGCTGTAACAACATCTGTCACAA
->XM_034695841.1 PREDICTED: Notolabrus celidotus SPO11 initiator of meiotic double stranded breaks (spo11), transcript variant X5, mRNA 
-GAAGTAAACAACGGCCAAGCTGATAGCGAACCTGCTTCTTTTGCATCACTTAAGAAGTAGTTTGTATGGAATTCAACAACATTCACAGCACCTAAAAACTGAGATCCCTGTCAAACGCGAAGAAAAAAGGAAAGCGGATACGAGCGCTGTGCATTATGGGAAACAGTACGCGAGGTAGACTGGTCCTATGAAAACTTCCCAGATCAGTACGACATCGAGCTGTATTCTGAAATTGACAAGCTCCGTGCTCAGCTGCTGCACAATGTCGAATTAATGTCGGACCGCCAGTGGATGATAGAAGAAATCAGCGACAGAGAAATTCTGACCCGCATCGAAAATGTAATCCTTGGAATAGTGACAAGTCTGTCCAAAGATGAGGCCCCTGTCCTGGCACTGCCCAACAGATCCAGCTGGGCCAACATCAGTTTTGACAGTGCTGTTGGGCTTCAAATGAGTTCAGGAAGTTCTGTCACAACCATAAGGAGCGACTGTAGCTCATCCATCACGAAATTTGCTCAAATTCTCAAGATCCTGGCGGCCATCTACAGACTGGTGCAGAGCAACTCTTATTCTACCAAGAGAGACATCTACTACAACAACCCACAGCTGTTTGTTTCACAAAGGACTGTTGATAGTATAGTAGATGACATCTCCTGTATGCTAAAGGTTCCTCGCAGATCTCTACATGTGTTGGCCTCGTCCAAAGGATTGATCTCAGGTGATCTGTCTTATCTTGAAGAGGACGGCACAAGAGTTGACTGCCGCTCAAGCTCTGCTGCTGTTGCTGTATCGTCAAACATTGGTGGGATTAAGAATATTGTATCATCTGCAAAGTTTGTCATGATAGTGGAGAAGGATGCGACGTTTCAGCGACTGCTCGACAACGACTTCTGCACAAAGCTCGCTCCCTGCATCATCATCACAGGAAAAGGCATGCCAGATGTGAACAGCAGGTTGATGGTGAGAAAGCTTTGGGACACGCTACACATCCCCATCTTCGCTCTGGTGGACGCCGACCCTCACGGGATGGAGATCATGTGTGTCTACAAGTATGGATCAGTGGCCATGTCGTTTGAGGCCCACAGCCTGACCGTCCCCAGCGTTATGTGGCTGGGCCTCCTCCCCTCTGACCTCCAGAGGTTGCGGGTTCCTGAGGATGCCCTGATCCCTCTTACAAAGAGAGACCAAAGCAAACTCAACAGCCTCCTGGAGAGACCGTACTTAAGCAGCCAGTCAGACTGGCAGAAAGAGATGGAGCTGATGCAGCAGAGTAAAGTCAAGGCTGAAATACAGTCCCTGGATGCTATTGCACCTGATTTCCTGACCAGCATCTACCTGCCCAATAAGCTGCGTTATGGTGGCTGGGTATGAGTGCAATGCTGCCACCTAGTGGGGATCTAAGACTACTGAGATCCCTCACCCTTTTATTAAAACCCTGTGAATATGGTGAAAACTCGCACCATGTTTTTTGTGTTTATGTTCCCAAGATGTTTGGACATGCTGTTGAAGTCTCATCAAACACACTATGTTAGTTTAAGTAAAGTCCAGCCTGTTTTACAACCACTCAACACCCCTAAGTATGCTCATTAAAAGACTTCAAGTCAACAGA
->XR_007695918.1 PREDICTED: Diabrotica virgifera virgifera uncharacterized LOC126878978 (LOC126878978), ncRNA 
-TCGGAAAGGAGGTGTTCTCTTCACCAGTTGGTGGTTTTAAAGGCCGTAGCATACCTAGAAGGGCGGTGAATGTGGTTGGACCAAACCCTTTTTCAATTATTTGGACCAAAAGAGACCAATTATAGAAAAAACTCGAGATAATCTGAATTGCGGCATTATTTTGAGTTAGTGTTTTCTATTACGTTTCGCCATGGTTTGACCATGTGATCGTGGTACCTTTTTGTAACATCGGCTATTTATTTTAGGGTTTTTATTTTGGGGGAAAACAGATTTCCTGTATACTTTTATCTTTGATGGGAGATGTTTGCATTTTGATTAAACATATTGCATATTTTGCTGTAGTACTGTACTGGAGTTTTGGTGAATGGTAGTTTCCTGGATTCGCTTGCACGTGGTTTCATTGAGGTTCTGGGGGAACCATGCGGCGTAGCTGAACCTTTTCAGTGGAACGGGTGGATTGGTAACCTATTCAGTTATTTCTATAGGATTTATAGGAGTCCCGTGGGGACGTGATGACCTTAGTTGGGGACAATTGGAGAAGTGTAAATAACTATTTTTATTTATATTGTTTATTGACCTGGGAGGTGCTGCTTGTAAAGAGAAATGGCGAAATTTGCGTGTTGTGTTTATGAGACACTTGAAACCTTTGCCAAGTGGTTCTAAAAAAAAAGACCGTACTATTTACTTGATTATATCCAATTTTTGTCGCCATATGTAAAACCAATTAATCTGCCCGAAGTAGGGGACCTCCCGTCCACTTCAACAGAGGATACCGAAATACATGCTACCATTGATGTGTCAAACGATGTTCCAGAAGATTTGGCTACAGAGTCCGAGCAATCTAAAAAGCCTACCTCTCCCAGTATACATAATAGTACAATAATTCAACATTCTTCCAACTCAAAGCAAATGAAGTTTTCATTTCACGAGACAGATAAGTTTTTCCTCAATTATTTAAAAGAAAAAGCTACTAAATCTTCTACGGAGACTTCCACGGACTCTGTTATGTCATTTTTAAACACTCTTGCACCCGAATTAAGAGAAATGAATATGCACTAGGTCAAAATATTCAAAAGACGTGCACTAAGCCTAGTTGATGATATATTGAATCCATCTTCTACTGCGCCTGAAAGTCAAACAATGAGTGCATTAACTAAATTAAGTAGTGAAACGTCCCGGGACACAATATATTCTCCGCAGCCGTATGGTAGTCCTTCATTTGTGCAGCCACTGCAGTAAGTACCAACAACTAATCCTCTGGACTTCAGCGGGGTACGAACACAAAACTTTATGCAGGCAGTATCAACAACTAATCCTTTGGACTTAAGCGGAGTATCGACAGAAATCTCATTAAATTGTACAGAATACCCTTCTGTCAGCCAGAACATGTCGTTATAACTCATTTTATGTTTAAATATAAGTAATAATAATTAGATACCTACTGATAAAAATTAGATTTCGTCATTTCAATATTATTTTAATCATTGATTTAAATAAATATTTTAAAATACTTA
->AB291824.1 Bradyrhizobium sp. Pd-E-(r)-e-D-6(2) gene for 16S rRNA, partial sequence 
-TTTATCGCCGAAAAGATCGGCCCCGCGTTCTGATTAGCTAGTTGGTGAGGTAATGGCTCACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGAGTGATGAAGGCCCTAGGGTTGTAAAGCTCTTTTGTGCGGGAAGATAATGACGGTACCGCAAGAATAAGCCCCGGCTAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGGGGCTAGCGTTGCTCGGAATCACTGGGCGTAAAGGGTGCGTAGGCGGGTCTTTAAGTCAGGGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTTGATACTGAAGATCTTGAGTTCGGGAGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGATACTGACGCTGAGGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAATGCCAGCCGTTGG
->XM_037164408.2 PREDICTED: Artibeus jamaicensis staufen double-stranded RNA binding protein 1 (LOC119063191), transcript variant X6, mRNA 
-GTTTCTTCCTTCTTTCCTTCTTCCTTCCTTCCTTCTCGCCGCCGCCGCCCAGGACCGCCGGTCAGGAGACGAGCTCCGGGCAGCAGCCAGGAGTTTTCTAACCACATAACCACTCAGATCTGAACCAAAACAACATTGTTCCCGGAGCACCTCTTTTTAAGGTAGAACTTTAGACTTCATAGCACTGAATTAACCTGCACTGAAAGCTGTTTACCTGCAGTTATTCACTTTTGTTGAAAGTGACCATGTCTCAAGTTCAAGTGCAAGTTCAGAACCCATCTGCTGCTCTCTCAGGGAGCCAAATACTGAACAAGAACCAGTCTCTTCTCTCACAGCCTTTGATGAGTATTCCTTCTACTACTAGCTCTCTACCCTCTGAAAATGCAGGTAGACCTATTCAAAACTCTGCTTTACCCTCTGCATCTATTACATCCACCAGTGCAGCTGCAGTTCCTTCTAGCATGGCACACCCCAAAGAGAAAACCCCAATGTGTCTTGTGAATGAGTTAGCCCGTTTCAACAAGATTCAGCCTGAGTATAAGCTTTTGCGTGAGCAAGGTCCGGCTCACTGTAAGGTGTTTACAGTACAGCTAACACTTGGAGATCAGCACTGGGAAGCTGAAGGAAGTAGTATTAAAAAAGCCCAACACACAGCTGCTGCCAAAGCTTTGGAAGGAACAAAATTTCCTAGACCCATAGTCCGCCCTTTTCGTAGCGAAGGAAGGAATCCAGAAAGCATAACCCCTACTGTAGAGCTAAATGCACTGTGCATGAAACTTGGAAAAAAACCAATGTACAAACCCGTTGACCCTTACTCTCGGATGCAGTCCACCTATAACTACAATATGAGAGGAGGTGCTTATCCCCCAAGGTACTTTTACCCATTTCCAGTACCACCCTTACTTTATCAAGTTGAACTTTCTGTGGGAGGACAGCAATTTAACGGGAAAGGAAAAACGAGACAGGCTGCGAAACACGATGCTGCTGCGAAAGCTTTGAGGATCCTGCAGAACGAGCCCCCGCCCGAGAGGCTGGAGGTGAACGGAAGAGAATCAGAAGAAGAAAATCTCAATAAATCTGAAATAAGTCAAGTGTTCGAGATTGCACTTAGACGGAACTTGCCTGTGAATTTTGAGGTCGCCCGGGAAAGTGGCCCACCTCACATGAAGAGCTTTGTGACCAAGGTGTCGGTTGGGGAGTTTGTGGGGGAAGGTGAAGGGAAGAGCAAGAAGATTTCAAAGAAAAATGCTGCTATAGCTGTTCTTGAGGAGCTGAAGAAGTTACCACCCCTGCCTGCAGTCGAGCGGGTGAAGCCCCGAATCAAAAAGAAAACAAAGCCCATAGTCAGGGTACAGAGTGGCCCAGAGCATGGCCAGGCGATGAACCCCATCAGCAGACTCGCCCAGATCCAGCAGGCGAAGAAGGACAAGGAGCCGGAGTACATGCTCCTCACAGAGCGAGGCCTCCCACGTCGCAGAGAGTTTGTGATGCAGGTGAAAGTGGGAAAGCACACTGCAGAGGGAACGGGCACCAACAAGAAGGTAGCCAAGCGCAATGCGGCCGAGAACATGCTGGAGATTCTTGGTTTCAAAGTCCCACAAGCTCAGCCCACCAAACCAGCCCTCAAGTCAGAGGATAAGACACCCATAAAGAAACCAGGGGATGGAAGAAAAGTAACCTTTTTTGAACCTGGCTCTGGGGATGAAAATGGGACTAGCAATAAGGAGGATGAATTTAGGATGCCTTATCTTAGTCATCAGCAACTGCCTGCTGGAATTCTTCCCATGGTGCCCGAGGTTGCCCAAGCCGTAGGAGTCAGTCAAGGACATCACACCAAAGATTTTACCAGGGCAGCTCCGAATCCCGCGAAGGCCACGGTAACTGCCATGATAGCCCGTGAATTGTTGTATGGGGGCACGTCGCCCACAGCCGAGACCATTTTAAAGAATAACATCTCTTCAGGCCACGCACCCCATGGACCTCTCACGAGACCCTCTGAGCAGTTGGACTATCTTTCCAGAGTCCAGGGATTCCAGGTCGAATACAAAGACTTCCCCAAAAACAACAAGAACGAATTTGTATCTCTTATCAATTGCTCCTCTCAGCCACCTCTGATCAGCCACGGTATTGGAAAGGATTTGGAGTCCTGCCATGACATGGCTGCACTGAACATTTTAAAGTTGCTGTCTGAGCTGGACCAACAAAGCACAGAGATGCCAAGACCAGGAAATGGACCAATGTCTGTGTGTGGGAGGTGCTGAACCTCTTCTGGTCATGAACCGTTATATAAACTTCCCAACAGATACTGAAAATCCTGAGACTGCTTTTGAAAATTTGGAATTTCTGATACCTCGAGTGGGCCGAGAGACGCGATGGGTAAAGAACTGGAGACAGCAGTGGTGACAGAGGCTGAGGCTGCTCGCATGTGCTGTGGTTTGTCCCCACACGGCAGCAGCTGCTGTGGGGGAGGTTGGGACCTGCCAAGCAGCCCTTAATTGCAAAACCAGCAGGTCCCTGCCCCTGGCACTTCAGTGCTTGGGTTTTTTTTTTTTTTTTTTTTTTT
->XM_035643150.2 PREDICTED: Scophthalmus maximus uncharacterized LOC118315681 (LOC118315681), transcript variant X2, mRNA 
-GCTCCGGGTCCACGTTCAGTTCATCTGGTTTCCTTGTTGCACCCAGCCAGAGGACAGGACTTTAGAAACCTCACACTTTACTTTCAAAGAAGACAATTTGTTGCCTCTGCAGAACTAGAGCCGACTTAAAACATGGTTGATAGAAGGATTGCACTGGAGGCGTTGGGTGTGCTCTGCAATGCCAATGTGACGTCTGTTCAGCAACAGAGATCACAACCTGGTGTGTGCATCCTTCAAGGACGACAGGAGCAGCTGTTCATCAAGCAGCTCATCCCCTCTGTCTTGGATGCAGATGAAACCTGCCAGGTGTCCAGATCCAGCTTCTACCGCATCCAAGCCATCTTGGAGAGCAGTGAACCGGCAGATGGCTTCCCCAGGCTGGCCGTGGTGGCTGTTCCAAAGAAGGACCACATCATCGATGAGGAAGAATTCTTTGCGCCGCAGTTTGACTATGATTTCACCAAGCTGACCGACAGCGAGACTTATTGGAGGGGCGGAGAGAAGTACGAGCGCCCGTGTGGTTGGTACCGCTTTGGCCTCAAGGTCCTGGACAAGTACTGTGGAAACACCTGGCTGGGAACCACATACCGGAGCACCCAGTCCTGTCCAGGGGAGTGGCCCGTGTCCTACCACGGGACATCAAAGAAAGGTGCTGAGGGCATCATCGGAGACCACTACAAGCCAGGCTGTTTTAAAGGAATTTGGTATCAACGTCTCTGCCACACCAAGGGGACACAGAAGGCTGAACAGTATATCACAACTGTGCCCGTATCATTTTCTATTTCGCAAAACTGGGCTTGTATTTGCAATGCAGAGTTGGAGAAAAGAGTCCCAGGAGAGGTTTGGCTGCCGTGATTATTTGAAATCAGATTTTGAGACGACTTCTAGTAAAGAATGTGTGTCTGGGCCGACCGATGAAGTTTTTCCACTTTCATTGGAACTCACTAGCCACAACAGGGAGTCGTGACCTTGAGGTTATATAGAATAAATAAGTGAAACTGCCTAA
->XM_038305068.1 Cyprinodon tularosa uncharacterized protein LOC119796484 transcript variant X1 (LOC119796484), mRNA 
-TTCAATCCTCCAGCTGCACTTGATCAAGCAGTTTGACTAGAAGAGAATCAAGCAGAGCTCTGACAGCACAGAGACCATCATGAGACAGAAACCTCTAGAGATGGAGTTTAAAGACTCCCATGTTCCAGTTCTCAGTGTGTCTCACTGCTCCTCTCTTTCCCTCTCTGTCTCCTCAGCAGCAACATTTGTAGTGAATGTGACACAGAGCTCCTATCAGGCAGAGGAGAACCACAACATCACTCTGGAGTGGACCTTCACCACAAGACCCAACAGAACCTGGATCATCTACTGTTGCGTGTTGACTCTTCCCAGAGAAATAGTCCTCTATTCAGTCTATGAAGATGTTGAAGAGACAGAGTTTACAGATGAACACTTTAAAGGACGAGTCCAGATGGACAAAGACGTCCTCAGAGAAGGACGGATCAGATTCCATCTGTCCAGACTGAGGACTGAAGACTCTGGACTGTATGTGTGTAACATCAGGACTGACTATGGGGAAGGTTCTGCAGACTGCAACGTTACAATCACTGAGACGGTTCCTGAGAGAAACCTCATCACTCCGACTCTACAGGATAAAACCATCAGTAACGGAGGTCGGTCCAGGCTCTTCCTTTTATTTCCTTTTATTTTCTTCATCATTTCTCCGTGTTTGGTTTTACTCTTCATTTCTAAAAATAAGAACTCTAGGAAGAGTCCTTCTAGGTCAACCATCTACATTACAGAATGGAAACCTTGCATAAGGGCAAACTTGTGTTAATGTAGCTGAGATCAGAGCAAAGTCTTCTCTCCTTCATCTTTCTGAGGTCTCCAACTGTTCAATAAATTGCAGGAGACCCTGGAGATAGAAGGAGTCTTAATGATACCTTAGAAGCTGTTGATGAAACCAGGAGTCTTTTCAATGTTTAAAGTCAGTCTCTGCAGGAACCCAACAAACTTCACATCAAAACACAATCAGATGCTGTGGATTTATCTCCAGGAAGAGGAAAATCAGACATTTCGGAAATTGTGCATTGTTTTCTCACAGCAGTGATTTTTTTTTTCTCCCTCAATGCATTTTATCAAAGTACAGATAAAAAAAATGCTAACCCTCGGTTGGGGGGAATCTTCAAATTTCATGTATATATGTTATTTATTATTATTATTTTTTTATTATTGTTTTTTACTCTGTTGTAATTAAAGAAAGGCTACATATGTAAAGTGTTTCATAAATATTGATTTTTGTAATTATTCATTATTAAATAATAGTTATCATTATTACCTCCAACTACATGGCTAAGAACCTCATCTTTTCCTTTTCTACAACTCTCAACTGCCTGTAGGACACATT
->HQ018492.1 Uncultured Candidatus Microthrix sp. clone R4CP1R1E11 16S ribosomal RNA gene, partial sequence 
-TCGCGTAACACGTAGGCAACCTGCCTCGAAGTGGGGGACAACAGCCCGAAAGGGTTGCTAATACCGCATGTGGATGTTTGGTGGCATCACCGATCATCTAAAGCCTTGTGCGCTTCGAGATGGGCTTGCGGCCTATCAGGTAGTTGGTGGGGTAATGGCCTACCAAGCCGACGACGGGTAGCTGGTCTGAGAGGACGATCAGCCGGATTGGGACTGAGATACGGCCCAGACTCCTACGGGGGGCAGCAATTAGGAATCTTGCGCAATGGGGGAAACCCTGACGCAGCGACAGCCGCGTGCGGGATGACG
->XM_013285616.1 PREDICTED: Papilio polytes antichymotrypsin-2-like (LOC106105325), mRNA 
-ATGTTTAAATCAGCTAAACCAAGGTACGATACTGCCGTTGAATCATTATGGCAAGGAAATACGGAGTTCACACTAAACTTTTTAAATTTAAAACTAAATGAAAGTCCTTATAACAGTTTTATAGTATCTCCGTTTTCTGTTCTAATACCCCTGGCAGAACTTGCACTGTACGCCAATGGAACAACACACGATCAACTAACAAATATCCTTCATGTCGACAATAGAATAGAGGTTGGGGGTGGTTTCCGTGAAATTTTGAAGTCTTTTTCATCTTCTGATGATGTACAGATTTCATTAGCTCAAAGAATCTACTCCAATGTAAATACAGAATTATCTGAAGACTTTAAAAATGACACTAAGGATTATTTTAATGCCGAAGCTCAAAATGTAGACTTTGAAAAGAATCAAGAAGTAGCGAAAATGATCAACGAGTGGGTGCAAGAACAAACCCATGGTCTCATTTCACGAATTGTTGAACCCAATATGTTGGACCAATCAACAAATATGGTTTTAGTTAATGCCATTTATTTCAAGGGTGATTGGGACTATGCTTTCAATCCAAATGACACAAAACATAAAGACTTTTACTTATCGATAGGCGAGCAGGTTGAAGTAAAAATGATGTATCAAAAGAATACGTTTAAATACATGGAAAATCCAGCTCTTCAAATAAAGGCATTGCAACTACCATACACGAAGCAGCATTATAGCCTTTTAGTTATACTACCCACGTCACGAGTTGATTATGGTTTGCAAAAAGTGGCTAAGAGGATTAGAAATCCCCAAGTGTTTACAGAAATTATCGATGATTTGAGAAACGCAGAAGTTGAAGTATCATTACCGTCTATAGAAACTTCCAGTACAACAGATTTACAGGGAATCCTAAAAGGCGTAAATGTCACTGAAATGTTCGTGTCTGGCAATTCGGATCTTAATGGGTTACTGAAAAATAATCAATCAATACATATCTCTGTTGCTGTTCAAAAAGCCGTTGTGGTTATCAATGAGTTGGGTACAAAAGCAGCTGCATCAAATAATATAGAATTTTTACCATCGGCGCCACTGGTCAAACCGCCCCCAATAACTTTCAACGCTAACCGGCCTTTCCTTTATTTCATTCTATATAAGAAGAACGTTTTGTTCTGTGGATCATACTATGGAGAATACTTAAAAACCAGAGAAAATCCTGGACAAGGTTTCATAGCATCGCCATTCTCTGTGTTGCTGCCTTTAGCGGAACTTACGCTATATGCCACTAGAATAGCGTACGAACAACTTTCTAATGTTTTGAATATTGATGAAAGAGATGAGGTTCGACTGGGATTCAGAAAACTTTTGGATAACTTTGCGTTGCCACAAAAAGTATCAATTACTTTTGCTCAAAAAGTATACGGCAGTCTCGATTTCGATTTCATTGACGACTTTAAATATGATACCAAAGAATATTTTGATGCAGAAGCACAAAATTTAGATTTCAGTCAAAACCAACAAGCTGCAGAAATAATCAACGATTGGGCTAAATGGAAAGATCCATTTGACCCAGATGATACTAAACCAGAAGACTTTTATATAACAAAAGATGAAAAAATAACCGTTAACATGATGTTTCAAGAAGGATATTTCTTATACGCTGAAAACCCTGAACTACAAATACAGGCATTGGAACTAAAGTATGAAGACGAAGATTATAGTCTCTTGATTATTTTGCCAACGTCTGAAGATGATTACAGCGTAGAAGGTGTAGTACAAAAAATTCAAGAACCACATGTTTTTGAAGGAATAATTAACGATTTATCAATTGATGAAGTTGAAGTACATTTACCTTCAATATTAACTACTACAACAACAGATCTAAAACCAATTCTAGAAGGAGTTAATGTTACTGAAATATTTAACCCAGATACAACTGACATAAGTGGGATGCTAGAATACATTCAGCCAATGCACGTTTCCGTAGCTATCCAAAAAGCAGTCTGTAATAACCAGCCTGAGAATGGCAATTATAAAGTCAGCAATTTTTAA
->FQ672044.1 16S rRNA amplicon fragment from a soil sample (ferralsol, Madagascar) resulting from a 16 days laboratory incubation experiment 
-TGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGGGTGATGAAGGCCCTAGGGTTGTAAAGCCCTTTCGGCGGGGAAGATAATGACGGTACCCGCAGAAGAAGCCCCGGCTAATTTCGTGCCAGCAGCCGCGGTAATACGAAGGGGGCTAGCGTTGCTCGGAATCACTGGGCGTAAAGCGCACGTAGGCGGATTGTTAAGTCAGGGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTTGATACTGGCGATCTTGAGTCCGGGAGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAAGAACACCAGTG
->XM_030518924.1 PREDICTED: Scaptodrosophila lebanonensis dynein beta chain, ciliary (LOC115624302), transcript variant X1, mRNA 
-ATGGAGCCATCCACGAGCGCCGAAGCAGCTGCAGCCGCTGCCGGCGGTGGGCCGGATCCACGTTTGGAGCTGATGGGTTCCTTTGTCATCAAGTCCCTCAAACTGAAGCCGGAGAAATGGACGCGTGTCATCACCGTGGAGGAGCACAAGGGCATTATTAAGGAGTTCTTGGATCGAAATACACCGGTAGTGCTCATCATTATATTGACAACCGCTGCCCAATTGGTGCCCTCCACCACCTTTCCGCTGTCGCAGCTCAAGAGCAAGGGGGTGTACTTCATAAAGAAGTACGCCAAGCCGATACCACGCGAGCTCTGTGAGAATTTCATTATTTTCGGCGACTTGGCAACGCGCACCATCGACCAACTGTCCGCCCTGGTGGAGGAGGTGGTTGTGCCTCTGCTCTCCAACGAGGACAATTACAGGGCCTGGCCCACTATGGTGGCGCAGGATGTGCAGAAGCATGTGCATAGCCTAAAGAGTACGGTGCACCAGGTGAAGGGTCAGGTGAGCGGTGAAACTATTCTGGCCATGCCTGTGGGCGTCGAGAAAATTGTCAAGGCCGCCAAGGAGTTGGTCGAAACCGAACAATGCCAGTTCGATCTGTATCTGAAGAGCGCCATCGAGGGTGTGGTCATCAAGTGGGCGACACAGATCCATGAGGTCATCAAGGAGAGTCCGTCGAATGCCTTCGCCAATGGCCAGAATCCCACGCCCCACACAGAATTTACATTTTGGAATAATCGCCTTAAGAACCTATCTTTTATCTACGACCAATTGCGCAACGAACGTATCCGTGCCATGGCAATAATACTTGAATACTCGCTAAGTGCCTACCATCCGTGCTTTCAAACGCTCTTCAAGAACGTCGTTACGGCACTCGCCGAAGCAAAGGACATAACACTCTATTTAAATCCATTGAAACGTCCATTGCAACAGCTGGAGGAAATAGATTTTGCGGAAAGCAAGCCACTGCTCATCCCCTTCATGAATATCGTCTGTATTCTGTGGGGAAACTCGCGCTATTATTGTCAGTCATCGAAAATAACGATTCTGTTGCAAGAGATATGCAATCTGATTATCCATCAGGCCAAACGCTATTTGGATCCCTCGTCAATTTTTCACAGCGACATCGATGAGGCCATGCAACGCCTCACTCTCTCCATACAGATACTGAAGTTCTTTCGGGAGCTTTTCGATTATTATAAGGAACGTTTGGCCGATTTCTTTACAGAGCCCGAGGAGCGGCCACCGATTTTCTGGACTTTTCATCCAAATTCAGTTTTCAAGCGCTTTAATGCATTCCTAGAGCGTTTAACAACCATACAATGGTTCTTCTTTACTGTGATTGAATTCCTGAAATTAGAGAAAGTCGAAATCGGTGGCTTGCGTGGTCGTCAGCTCAGCACACGCATTACAGATGTCTATGTCGAGTTCAATCAATATTTTACAGCCTTTGCGTCCAAAAGCTACGATGTGCTGGACCCAGACGATCATGACTTTGACGATGACTTTAAGGGCTTTCAAACCCGTATACTTGAACTAGATATGAAGTTGGCCGCCATATTGTGCCAGGCCTTTGATGATTGCCACAATTTGGAGAGCATTTTTAAGCTCATTAGCATTGTGGGTAGCGTTTTAGATAGACCCAAAATTAGAGAAGAATTCACACAACGCTATGCCGAAATTCTTGAGATGCTGAACGATGAGATGACGATGTGTGAGGCCATCTACGAGAAGCAAATGGAACTGAGAAAGATTGGCGAGAATCTCTATCCGGACTATAACTGTCCACCTGTGGCTGCCTTCATACGTTGGTGCAATCAGCTGGAGACTCGTATTACAGGGCCTGTGAAGAACTTCAAGGCGCTTCAGCATGAAATATCAAAGTGTGAGAAGGCTCTAGAGATAATGGAACGCTACGATCGCTTGATCGAAAAGTTGGGTGCCTGTAAGACACAGTGTTTTGAGGAATGGAGCTCCCAGCTAGCCGAACAAATCGAGGAGAATCTAAAGAAGTCGCTTATTGCGCGCGGTCCCCAAGGCAACTCGTTAATTTTAAACTTTAGCGCTGCCCTATTCTCAATACTGCGTGAGGTTCATTATATGCAGCAAATGAAAATCGAAGGCATACCCGATATAGCTATAGAGTTCGCTGAGAAGAGCGATGTCTTTCGTGGATATACGTTGAATTTGGAGAAGACTATCGATTGGTATAACAGCATACAGGAGGCTAGCTCGCCGGTTGAGTTGCAATTGATTGGACCCGAAATAAAAATGATTGATGACCTTGTGGAGATCGGTGTGGATAACTTAGTCTGGAATTCAGAAGACATCTTGACGTATTTGGAAAAGTTACGTAAGCCCGTTGCTGCTCTCCAATATCGCATGGATCATACGCAGGGAAATTTGCGGCAAATACGCAAAATTATGAGTGTGTGGGCCAAGCAGCCGTTGTTTGAGCGTCGGGACTGCAAAAAGGATTCGGTGTTGTCTATTGACGAGCGACCTGATCGCACCTCCAAGCGTTATGCTGAGATACAAGCGGCCTCCGTTGAGATACACAAACTACTGCACGACAATATGCTGCAGTTCGACATGGAGGATAAACAGCAGGATGAGGTCTGGCTCAGCTATGTGAACTTTGTCGATAACATCGTCTACGAGAACCTGCTGCGCACTGTGGGCGTAAGTGTTGGGTATTTAGCCGAGAACATGGATCCGGAGAACAATTATGCACCACTTTTTGAGTCCCGTCTGGAGCTAGTCGAACCCGATCTTGTGTTTGTGCCCTCCCTTGAGCCGGAAGACCCGATGGGCTTTAACAACATGCTGATTGAATTAATGCGCGATATTATGAAAATGGGTTCGCTAATCAAGCGTCTGACTCACGAGAAGCGCAGCTATGCTGAGATTATTAAAGAGAACCAGGACATAATTGATATGCGACGTGAAATTCTGAACGGTGTGGACTTGGTAATGGAGGAGGCATCCCGTTTTTGTCGCCAGTTTGAACGCTACTCGTACCTATGGCTGGATGATCGCGAGGAATGCATGGAATACTTTTTGGAATATGGTCATATTTTGGATCCCGACGAAATCGAATTAGTTTTGATGAACGATCCGAATGCACCGAAGCCCTGTTTGCCAACCATTGAGGCATTCCGAGAGCAGATCGATAACTATGAGTCGCTATTCAATGAGATTGAGGATATATCGCCATTTCAAGTGTTTAGCTCGTGGTTTCAAGTGGATGTGCGACCCTTTCGTCAAGCGCTGCTCAATACAGTGTGCAAATGGGGAAATATGTTCAAGGAGCATTTGGTTACAACCGTCACAACCAATCTAATGGACTTAAGTCACTTCATACACAAGGCCGACGAGGGTTTGCTGCAAACAGTGAAGGAGGGCGACTACGAGGGCTTGGTTAATCTAATGGCCTATCTTATGCAGGTTAAGGAGCGGGCCATCAAGACAGATGATATGTTCGAGCCGATGCAGGAAACCATACAGCTGCTAAAATACTATGACATGGATATACCTGAGGAGGTGAATGTGTTGCTTCAAGAATTGCCCGAACAATGGGCCAACACCAAGAAGATTGCTTCAACGGTTAAGCAACAGGTATCGCCACTCCAAGCCACTGAGGTGGTCAGCATACGGAACAAGATAGCGTTATTTGAGGCCCACATACAGCTCTTCCGGGAGGTCTTCAAGAATTACGACTTCTTTCGCTTTGATTGTCATAAGCCATACCAACTTATGGATCGCATTAACGATGACATGTTTCTGTGCGAGAGCGAAATGCGCGACATACAAGAGTCGGGCAGTCTCTTCGAGGTCAATATACCAGAGTTCAAAGTGCTGAGGCAATGTCGCAAGGAATTACGCATGCTTAAGCAACTCTGGGATTATGTTAATATTGTGCAGACCAGCATCGAAGATTGGAAGACTACGCCATGGCGTAAAGTCGATGTGGAGAATATGGATATAGAGTGCAAGAAGTTTGCCAAGGATATACGCTTGTTGGATAAGGAAATGCGTGCCTGGGACACTTTCATAAATCTCGAGTCGACGGTGAAAAATATGTTAACCTCATTGCGCGCTGTGGGAGAGCTACAGAATCCTGCCATACGTGAGAGACACTGGAATCAGCTGATGAACTCGACAAAGAGCCTTGCCGCCTTGCCCAAGGAAGTGACCGTGAAATTTATAATGGATCATGAGACAACGTTGGCAGAGCTTCTGGGCTTGAACCTGCACGAGTGCGAGGAGGAGGTGAAAAACATTGTTGATAAGGCTGTTAAGGAAATGTCTATGGAGAAAATATTGCGTGATTTAAACACAACATGGTCTGCGATGGAATTCGATCATGAACTCCATCCACGCACTGGCTGTAATCTCCTTAAAGCATCGGAAGAACTCATAGAGACGCTCGAAGATAATCAGGTTTGCCTACAAAATTTAATAACATCCAAGTACATCGCCCATTTTCTCGAAGAAGTTTCAACTTGGCAAAATAAATTAATGATCGCCGATCAAGTGATAACCGTTTGGTTCGAGGTGCAACGCACTTGGACCCATCTTGAGAGTATCTTCATGAGTTCGGAAGACATACGCAAACAGCTGCCCGTCGACTCGGATCGTTTCGATAATATCGACGCCGAATTTCGTATACTCATGGATGAGATGTGCGTCTCATCGAATGTTGTGGCCTCGACTAATCGATCTGGGCTAATCGAACGTTTGGAGCATTTGCAGAAGGAGCTTACACTTTGCGAAAAGGCACTGGCAGAGTACTTGGAAACGAAGCGTTTGGCTTTTCCTCGTTTCTACTTTGTATCATCGGCCGATCTTCTCGATGTCCTAAGCAATGGCATCCAACCGGAAATGGTGACCAAACATCTAACAAAATTATTCGATTCGATCGCACGCTTAAAATTCAATCGCGATACGGCCAATGAGATAGAGACAGCTTCGGGCATGTATGCCAAAGATGGCGAATACGTTGAGTTCAACGAGCTGGCCAGCATACGCGGGCCGGTTGAGGTGTGGCTGAATCGTATACAAGCGGCCATGCGAGCCACCCTGCGACACTATGTCACAGAAGCTGTGGTCGCTTATGAGGAAAAGCAACGCGAACAGTGGTTATTCGATTATCCTGCACAGGTGTCGCTCTGTGGATCACAAATCTGGTGGTCGACAGAGGTGAACATTGCCTTCAGCCGTTTAGAGGAAGGTTACGATAATGCCATCAAGGACTACTATAAGAAACAGATCTCACAACTCAGTTTACTCATAACACTGCTGCTGGGCGAGCTGACCAAGGGTGATCGTCAAAAAATAATGACGATTTGCACAATTGATGTGCACTCACGAGACGTGGTCGCTAAGATGATTCAGGCCAAATTGGATTCAGGTTCGGCTTTTATGTGGCAATCGCAGCTAAGGCATCGCTTCGACGATGTAGAGAAGGATTGCTTTGCCAATATTTGCGACGCTGAGTTCCAGTATTGTCACGAATACTTAGGCAATACGCCACGACTGGTCATCACGCCTCTGACAGATCGCTGCTACATTACACTAACACAGAGTCTACACTTAATTTTGGGCGGTGCGCCTGCAGGTCCAGCTGGAACAGGGAAAACAGAGACTACAAAGGATCTGGGACGTGCCATTGGAATAATGGTGTACGTGTTCAATTGCTCAGAGCAAATGGACTATCAGTCGTGTGGTAATATTTACAAGGGTCTAGCCCAGACAGGGGCCTGGGGCTGCTTCGATGAGTTCAACCGCATTACTGTCGAGGTGTTGTCTGTGGTGGCAGTGCAGGTGAAGTCTGTGCAGGATGCGATACGTGACAAAAAGGACAAGTTTAATTTTATGGGCGAGATTATAACCTGTGTGCCCACAGTTGGCATATTTATAACCATGAATCCCGGCTACGCGGGTCGCACAGAGCTGCCGGAGAATTTGAAGGCACTTTTTAGGCCGTGCGCCATGGTGGTGCCAGACTTTGAGCTGATCTGCGAGATTATGTTGGTCGCCGAGGGCTTTCAAGATGCACGAATATTGGCGCGTAAGTTCATCACACTCTATACACTCTGCAAGGAGCTGCTTTCCAAACAGGATCACTATGATTGGGGATTGCGCGCAATTAAATCTGTATTGGTCGTTGCTGGATCGCTGAAGCGTGGTGATCCTGGCCGTCCTGAGGAGGAGGTCCTTATGCGTGCCTTGCGCGATTTCAATATACCAAAAATAGTTACCGATGATATGCCCGTGTTCATGGGGCTCATCAGCGATTTATTTCCCGCTTTGGATGTGCCGCGCAAACGTGATCAGGACTTTGAACGCACCGTAAAACAAGCTGCCTCCGATTTGCTACTACAACCCGAAGATAATTTTATATTGAAAGTGGTGCAACTGGAGGAACTGTTGGAGGTACGTCACTCTGTGTTCATCGTTGGCAATGCTGGCACTGGAAAGACACAAGTGTGGAAAACGCTGCTGCGCACCTATCAGAACATCAAGCGCAAGCCCATTTTCAATGACTTGAACCCGAAAGCCGTGACCAATGACGAACTTTTCGGCATTATAAACCCAGCTACGCGTGAATGGAAAGACGGCCTCTTCTCGGTACTGATGCGGGATCAGGCAAATATCGCGGGTGATCAACCAAAATGGATAGTCCTAGATGGTGATATTGATCCCATGTGGATCGAGAGCTTAAATACCGTCATGGATGATAATAAGGTCTTGACTTTGGCGAGCAATGAACGTATTGCTTTGACGCCTTCAATGCGCTTGCTTTTCGAAATCTCCAATCTGAGAACAGCAACACCGGCAACTGTATCCAGAGCCGGCATATTGTATATCAATCCGCAGGACTTGGGTTGGAATCCCTATGTAACCAGTTGGGTTGAGACGCGCAAAATTCCAGCCGAAAAGTCCAATTTGGTCATGTTATTCGATAAGTACATACCATCATCATTGGAGACGATACGCGTGCGTTTTAAAAAGATCACGCCTATCGCCGAAATGGCCCACATACAAATGTTGTGCCATCTATTGGACTGTTTTCTAATACCAGCGAACACACCGGCCGATTGTCCAAAGGAATGGCATGAGCTCTACTTCGTGTTTGCCTGCATTTGGGCCTTCGGATCGGCTATGTTCCAGGATCAAGCCATTGATTATCGTGTGGAGTTCAGCAAATGGTGGGTAAATGAGTTCAAAACAGTTAAGTTCCCAGCAGGTGGCACTGTTTTCGATTATTTTTTGGATAGCGAGACTAAGACATTTCTGCCCTGGATCGAGAAGACACCCAAATTCGAGCTGGACTCTGATCTGCCATTGCAAGCTGTACTCGTGCACACCTCCGAGTCCATTCGCTTGCGTTTCTTTTTGGACTTACTTATGGATAAGAAGCACCCGGTGATGCTAGTCGGCAATGCCGGTTGCGGCAAAAGTGTTTTGGTCAACGAGAAGCTTCAATCGCTTTCTGAGAATTTCGCTGTCACCACAATACCATTCAATTACTACACAACGTCCGAAATGTTGCAAAAGATATTGGAGAAGCCGCTGGAGAAGAAAGCGGGACGCAACTTTGGACCGCCCGGCAATAAAACCTTGATATACTTCATCGACGACATCAATATGTCGGAGGTAGACTGCTACGGCACCGTACAACCCCACACTCTAATGCGCCAGCATCTTGATTATGGCCATTGGTACGATAGGAACAAACTAACTCTCAAGGATATACACAATTGTCAGTATGTGGCGTGCATGAACCCAACTTCGGGCAGCTTTACCATCAATCCGCGACTCCAACGCCACTTCTGCGTATTAGCTGTCAGTTTTCCGGGACCCGATTCGATAACCGTCATGTACTCGGCCATCTTGTCTCAACATTTTGCGAATGCCGAGCAGAAATTCATTCCGATCGTAACACGCATGACGCCAAATATTGTGGCCGCAACCATAGCGTTGCACAACAAATGCCTCCAGATATTCCTGCCCACGGCCATAAAGTCACACTATATATTCAATTTGCGCGACATCAGCAATGTATTTCAAGGTTTACTCTTCAGTTCAACAGAATGCCTAACGGGCTCTACAGATCTTATACGTTTGTGGCAACATGAGACACAGCGTGTCTACGCCGATAAGCTAACCGATGATAAGGATATTGATAGCTTTACTAAAATGCAGCATGACATTGTTAAGAAATCGTTCGAGGAAATTGACGAATCCGTAATATTCGACAAACCGAATATCTATTGTCATTTCGCTGGAGGAATTGGTGATCCTAAGTACATGCCCATCAAGGGCTGGCCTGAGCTTCACAAACTCCTTCAGGAAGCAATGTCATCGTATAATGATCTGGTCGCTGCCATGAATCTGGTGTTATTCGAAGATGCGATGATGCATGTGTGCAGAATCAATCGCATATTAGAATCACCGCGTGGCAGCGCTTTATTGGTTGGTGTTGGTGGCAGTGGTAAACAATCTCTAGCGCGCTTGGCAGCATTCATATCCAGCTTGGAGGTCGTGCAGATACAGCTTAAGAAGGGCTATGGTGTCAACGACTTGAAGATTGAGTTTTCCGGTTTGTATCTGAAAGCGGGACTTAAAAACGTCAGCATCATGTTCCTAATGACGGATGCGCAAATTCCCAGTGAGGATTTTCTTGTCTTAATCAACGATATGTTAGCCACTGGCGAGATTCCAGATCTATTTCCGGACGACGAAATCGAGAACATAATCGCTGGCGTGCGTAATGAGGTCAAAGGTGCGGGGCTGGTTGATACGCGAGAAAACTGCTGGAAATTCTTCATCGATCGTGTACGCAAGCAACTGAAGATAGTTCTGTGTTTTTCACCAGTGGGCTCAACATTGCGTGTTCGGTCGAGAAAATTCCCTGCCATCATCAATGCAACGTCCATCAATTGGTTCCACGAATGGCCTCAAGAGGCACTCATATCGGTTGCCATGAACTTTTTGGCACAGAACAAAGTACTGCCTGACAATCATCGGGACTCTGTTGCTAAATTCATGGCATATGTCCACACAGCTGTAAATTCCACATCCAAAGTTTATTTGCAGAACGAGCGCCGTTACAACTACACAACTCCCAAGAGCTATCTCGAGCAAATAAATCTCTATTTAAAGCTACTGAATCACAAAAACCAGGATTTGCAGAGCAAAATCGAGCGTCTGGAAAATGGATTGGAGAAGCTTCGTTCCACGGCCGTCCAGGTGGCCGATTTAAAAGTTAAGCTAGCCGTTCAGGAGGTCGAGCTTAAAGAGAAGAACGAGGCGGCCGATGCTTTAATTGAAATTGTGGGTATTGAAACGGAGAAAGTGCAGACGGAGAAAGCGGTGGCGGATGAGGAGGAAATGAAGGTTGCTTTGATAGCGGACGAAGTCAGCAAGAAACAACGTGATTGTGAAGAGGATCTATTAAAGGCCGAACCGGCGCTTCTCGCAGCCCAGGAAGCCTTGAACACGTTGAACAAAGCGAATCTAACGGAATTAAAGAGTTTTGGTTCGCCCCCGGGTGCGGTCACAAACGTAACAGCCGCCGTTATGGTATTGCTGGCTCCAGGTGGAAAACTGCCCAAGGACCGCTCCTGGAAAGCTGCAAAAATTTCGATGGCAAAAGTCGACGCCTTTCTAGACGCATTGATCAATTATGACAAAGAAAACATACATCCTGAAATCATTAAGGCTATACAACCATATCTAAAGGATCCAGAATTTGAGCCCGAATTCGTGCGCTCCAAGTCAGGTGCAGCGGCCGGTTTGTGTGCTTGGGTTATCAACATTATCAAGTTTTATGAAGTCTATTGCGACGTGGAGCCCAAACGTAAGGCGTTAGCAGCCGCCAATGCAGAGTTGGCTGCTGCTCAGGATAAGCTTGCGGGCATTAAACGCAAAGTGGCGAGTCTGGAGGAACAACTAGCTAAGCTAACAGCCGATTTTGAGAAGGCCACGGCGGACAAATTGCGTTGCCAGCAGGAAGCTGATGCCACGCAAGCAACCATAGCATTGGCTAATCGTCTTGTAGGTGGTCTAGCCAGCGAGAATGTGCGCTGGGCAGAGGCTGTCAATAACTTTGTCAAGCAGGGCATTACGCTTCCCGGCGACATTCTACTGATTACCGCCTTCATTTCCTATGTTGGCTGTTTCACGAAAGGATTTCGCATCGATTTGCTGCAAAAGATGTGGACACCCTTCCTGAAGGGCATCGATCCTCCCATACCCACAACCGAAAATCTCGATCCACTCTCGCTGCTGACAGATGACACAACCATCGCCGTTTGGACAAACGAGGGCCTGCCGAGTGATCGCATGTCCATTGAGAATGCAACCATTCTTTCCAACTCTGATCGCTGGCCACTGATGATAGATCCCCAGCTGCAGGGTGTGAAATGGATTAAACAGAAATATGGCGATGAACTTAAGGTTATCCGTTTGGGTCAGCGCAGCTATTTGGACATCATAGAGAAGGCCATAAACACGGGTAGCACTGTCTTGATTGAGAACATAGATGAGAACTTGGATCCTGTTTTGGATTCATTGCTTGGTCGTAATCTCATCAAAAAGGGAAAAGCTATTAAAATCGGCGACAAAGAGGTCGAGTATAACTCCAACTTCCGTTTGATCCTGCACACGAAACTAGCAAATCCACATTATAAGCCCGAGATGCAAGCACAAACCACACTTATTAATTTCACTGTTACCCGCGATGGGTTAGAAGATCAATTGCTGGCGGAAGTTGTGAAGGCCGAACGTCCCGATCTGGAGGATCTCAAGGCCGAATTAACCAAACAACAGAATGACTTCAAAATCATGCTAAAGAAACTGGAGGACGATTTGCTGTCGCGCTTATCGTCTGCTGGTGAGAATATTTTAGGTGACACCGCTTTGGTGGAAAATCTAGAGACCACAAAGAGTACAGCATCGGAGATTGAGGAGAAAGTGGCTGAGGCCAAGATCACATCGAAGGAGATTGACAAGGCGCGTGAATACTACAGACCAGCGGCGACCAGAGCCAGCTTGCTTTACTTCATCTTAAATGAACTAAACACTATAAATCCGATCTATCAGTTTTCCCTGAAGGCTTTTAGTGTAGTTTTCCAAAAGGCCATAGCTAAGGCTGAACCAGGCGAATCCTTGGATTTGCGTGTCTCCAATCTGATCGATTGCATAACGTACTCGGTCTTTCAGTATACTTCGCGTGGTCTTTTTGAATGCGACAAACTGATATTCGCATCTCAAATGACTTTTCAGATACTGCTTATGAACGAGGAAGTAACATCTGTGGAACTGGACTTCCTACTCCGCTTCCCGATCAAACCGCATGTGACAAGTCCTGTTGACTTTTTGTCAAACCAATCGTGGGGCGGAATATGCAGTCTAGCGTCCAAGGATGAGTTTAGGAATTTGGACCGTGACATAGAGACCTCATCGAAGCGTTGGAAGAAACTGGTGGAATCGGAACTGCCGGAGAAGGAGAAGTTCCCACAGGAGTGGAAGAATAAAACGGCTCTGCAACGTCTTTGCATGATTAGAGCTTTGCGACCTGATCGCATGACTTATGCTCTAGGGGATTTTATTGAGGAGAAACTGGGCTCCAAATATGTGGAAAGTCGAGCAATGGAATTTGCAAAATCTTTCGAAGAGGCTAGTCCTTCAACACCCATCTTCTTCATATTATCGCCTGGCGTCAATCCTCTGAAGGATGTGGAAGCGTTGGGAAAACAGCTGGGCTTTTCCATGGATCTGGGCAATTTTCACAATGTATCACTGGGTCAGGGTCAGGAGGCAATTGCTGAAGCGGCCATGGATATAGCAGCAAAGAATGGACACTGGGTCATACTACAGAACATACATCTGGTACGCAAATGGCTGCCTGCCCTGGAGAAGAAGCTGGAATATTATGCTGAGGGCTCACATAAAGATTATCGCATGTTTCTGAGTGCAGAGCCCGCATCTACGCCCTCGGCGCATATTATACCACAGGGAATTTTGGAGTCATCGATTAAGATCACAAATGAACCCCCCACGGGCATGCTGGCGAATCTGCACAAGGCCCTCGATAATTTTACACAAGAAACACTGGAAATGTCCGGCAAGGAGGCCGAATTCAAGGCAATACTTTTTTCGCTTTGCTACTTCCATGCTGTGGTGGCTGAGCGCCGTAAATTTGGTCCACAAGGTTGGAATAAGATATATCCGTTTAATGTGGGTGACTTGAACATAAGCGTATCGGTTCTCTACAACTATCTGGAGGCCAACGCAAAGGTGCCGTGGGAGGACCTGCGCTATCTGTTTGGAGAAATTATGTACGGTGGACATATAACTGACGATTGGGATCGACGCTTATGCATCACCTATCTAGAGGAGTATATGCAACCTGATTTGGTGGACGGTGAACTTTTTCTGGCGCCATCATTTCCCGCCCCACCAAATACCGATTATCTCGGCTATCACACATATGTCGACGAAATGATGCCCGCCGAGTCGCCTTATCTCTATGGCTTACACCCGAATGCCGAGATAGGTTTTTTGACCACACGTGCCGAGAACATTTTCCGCACCGTCTTCGAAATGCAACCTCGGGAGGCTGGCGCTGGAGGCGGCGCCACTGTGACGCGTGAGGACAAGGTCAAACAAATCGTGGATGAAATACTGGAAAAGTTGCCCGAGGAATTTAACATGGTGGAGATAATGAACAAAGTGGAGGAGCGCACGCCATATGTAATTGTGGCTTTTCAGGAATGCGAGCGCATGAATTACCTAACAAGCGAAATGAAGCGTAGCTTGAAGGAGCTAGACCTCGGCCTTAAGGGCGAATTAACCATAACTTCGGATATGGAAGTGCTGGAAAACTCTTTATTTTTGGATCAAGTGCCGCCGATTTGGACATCGCGCGCCTATCCATCCCTCTTAGGTCTAAACAATTGGTTCATTGACTTATGTTTGCGTTTGCGGGAGTTGGAGACTTGGTCAACGGATTTTGTGCTTCCGTCTTGCGTCTGGTTAGCCGGATTCTTTAATCCCCAATCACTGCTAACGGCCATTATGCAGAGTACGGCGCGTCGCAACGAATTGCCGCTGGACAAGATGTGTTTGCAATGCGATGTCACTAAGAAGCAGAAGGAGGACTTTACAACGGCACCGCGCGAGGGCGCCTACGTTCATGGCATATTTATGGAAGGCGCCAGATGGGACATACAGCAGGGTATTATAATGGAGTCGCGTCTTAAAGAGCTCTATCCATCAATGCCAGTCATCAATATTCGGGCCATTACCCAAGATAAGCAGGATTTGCGTAATATGTACGAGTGCCCCGTCTATAAGACACGCACACGTGGACCAACCTATGTTTGGACATTTAATTTGAAGACCAAAGATAAGCCCGGCAAATGGACGTTGGCCGGCGTGGCATTATTGCTACAAACTTAGCTGGAATATACCTATATCGACATTTTTCCAATTCATTTTTCTCGAATTAAATT
->XR_002553663.2 PREDICTED: Helianthus annuus DNA-binding protein HEXBP-like (LOC110871340), transcript variant X4, misc_RNA 
-TTGGGATCGATCGAACAAGGGCAGGGAGAGGGTGAATAACCCTAAACTCAAGAAATCAAGAATTGAAGCTAAAATCTCAAGGAAAATTCGATGCATGAGCCCTTCTTTGCGAAAATCTAACCCTAATTATTGAAGTGGCGTGAAAGAAGAAGGTACAAGCACTAAGCAAGCGGAAGGAGCACGAGATCGAGGTAAAGCACCTCTATAGGCGATATGGAGATATGGAACGAGCACATGTTTAAGCCTTATAATACCAAGCGCTTTCGC
->XM_033245137.1 PREDICTED: Anneissia japonica ataxin-2-like protein (LOC117104323), mRNA 
-ATTGGCCTTTAGCATAATTATTTTCTGGTCTCTGTCGAAGGCCAAAGCATTGTCGATTTATCAAAAACATTGCCTTTGAAATCATCCTCTGGTGGTAGTGGGAAGCAGTTGCGAATATTAAAGACAAGCATTTTTATCGATATGCTTTGTTGATTGTTATAAAATACAAATTAATTGATTTTGCAAGGCTCGTGCTTCTGAGAAGCAGCTCACCGGCGATCCGAAGGCATGATGAGTACACAGCAAGCACCACAAAACAAACGTAAAGGGGGGAGAACCGGGAACAGTGGTCATGGAAGAAATCGAAACTCAACTCGATCAAGTAATCTTACAGCTAACTCGCAATCACACTCAACGCCGGTCATTCCACCTAGATTATACGCAAATGCTCACTTTGTACACGCTACAGCTGTTCTCAAGGGATTAAAAGTTCAAGTTGTGGTTGTATCAGGCAAAAAGTATGAGGGAATATTCAGCACAATAAGTAATAATGGTGAGATTGTAATAGAATTGGCACACATGGTAGAAGGCAATACAAATGCTGTACCAAGCAAGGAAAGGACAATTGATAAGCTGGTTGTTAAGTTCAAAGATGTAGTCTCGCTTACAGCATTAGATGTTGATCTCGAATACGCTGTTAAAAGCGATGTTCAGCCTGGATTTCAGACAGATTCAGATATCAGCGGGAAGAAATCGAATGGTCAAGCAGGAGAGAGAGAATTACAGCAGTGGACTCCAAGCAATGAGACCCCAGCAGATTTATCATTAGATGGTGATACTAATGGATGGAGTGTGGAAGATATGTTTAAAGCTAATGAAAAACAATTTGGTTATGAATCCTCATACGACACAACTCTAAAAGATTACACGACGCTCTTACGCAAAGAGGATACAGAGGAGTTCCGTCAGAAATCAGAAAGGGCGAATAGACTAGCAATGGAAATTGAAGAAAGTGCAGGCTACAAACAAAGAGCAGCTCTTGAATTAGATGATGGGCAAACAGAGGAGGATAGATTCAGTGCTGTGCAACGGCCGAAGGCCAGAATGAGCCCATCGGGATCACAGCAGGGAAGATCCGCTAGCCCAAAAGGAAACCCACAGTTTGATGGTAATGCATCAACTAATAAGTATGTACCCCCTCATTTAAGAAATAACAAGCCGGCTCAAAGGAATTATAATCAACCCTCACATAGGCCTCACACTCCAACACAGGGGGGCCAAAGAGGACCGACACACGCACAGAACATGGCTAGGCCACCTAGACATGCTGTGCCTGATGAACGTCTGACAATGCAAGATGTACGAATGTCACCAGAATCTAGGCAATCCCAAGATGTTAGGTTGTCACAGGATGCAAGGCTTGCGTATGAACCTCGACCTCAAAGGTCTGCTGCACAAGTTGTTGCAGGAAGCAATCCCCAACGTGGCATGGTTCCACAGCAACAAAATGTTATGAAGCAACGAGAAGTCAAGCCGGAGTCCATAGGAATATCGCCCAGCCCAGGCCCTCCAGCAAACATGGCCAAGCAGCCTACAAAAGATATACCTAGGGTACCAAGCCCAATGGTTGGAAGCTTACCACCAACAGGTGAAACCAATCCTCAACACCCAGTTGCATCAGAGGATAAGAAGCCACAGAAATCACAGAAATCTCAAAAAATTAGTGAATTGAATGAATTTAGCAACAACTTCAGGTTACAAGAGAATCAAACTACACCTAGCAACAACCATGTTGCTACCCAGGCCCATGAAGCCAAACCAGTTCAGTCCTTAAATCCAGCTCCAACACCACAGCAAGGAAACCAGCAACCTGTACCCCAACAGGCAGCACAACAGGTAGCTCAGCCATCTTCTCAGTCGCCTCAAACACGACCAGTACCACCACCTGCGCAGGCTCAACCGCAGGCACTTATTACACAAATTATACAACAGCAACCTTTACCGGCTCAGAAGCTAGGCCAGGCACCATCTCAAGTATCAATTCTTCAGCACCAGGCTCATTCCCAAGCTCAACCTATCTCCACAGCTCAGCCACCAAGGCCAGTGGATGAAAAGAAACCAGAATTTAAGCTGAACCCAAATGCTAAGGAATTTACCTTGAACCCATCAGCTAAGCCTTTCACACCGAACTCACTACGTAAGGGGGTGAGTGTGAGTAAAACACCGACACCTCCCCGACCGCATTCACGACAGAGTCAGAGTCCAACACTCCATCCACCATCAATGCCAATGACCCAAATAATGACTGGTGGACCCCCTCCACCGCACACCTTTATCCCTCAAATGCCCTCAGTTGTCTATGCACACCAAATTCCTCTTCAGAAAAAATATCCTAAAAGTCCGGCAACCAATCTACCACAGCCCCCAAGGCAGCAGCAACCAGGGGATATATCTGGACAAATGATGTCGGCATCAACAGCAACCGGGCAACCACTGCTAGCCCCTTCTCATTTTGTACCGCCGTATCATCAGCATCCAGGGGCACATCCTGGTCAGATGATCCCAGGTCAGCCTATAATGCAACCTCAACCCATGCCATTTGTGCAGATGCAACAACAAAAGCTGCCTTATCGTCACGCCAGTTCGATGTCCAATGTACAACAATCACAAGCTCAACTCCATCCACTGCCAGAGGTCTCTCCAAATACCCCTCTCTTTGTTACACCCCAAGGTTCCAGTCAAGTCTATCCAGGTCAGCAACAGCCATCAGTGTACCCTCATCACCCCTCATCTGCTCAACAAGGAGGCCAACAACATCCCCAGGGCCAAGCAGGTCACCATCAAATGGTCCAGTCAGCCCATCCTCACTCCCATGGAGCTCAACAAGGACAAAACCAGCACCATCAAGGCCAGCCTCAGGGTCATAGACCAACGCCTAGCCCAGTTCAACATTCTATACAGTCACCCTCACAATCTACTCAGCAAAATATACCGTTACCGATATATTACAACATGCCACAGCACAGCCAACCAATTCAAGGTCACACACCTCAATCTCAGCAGACGTTTACAACTGTTTTAATGCATCAACAACAGCAGCAGCCTCAACCCCAGCCATACTCTGCTACCTCCCACAGCATAACAAATATGACGACAGTTCACACTAGCCCTCACCCGCACCCTCATGCACAACCTGGCAATGTGATGTATGTAGGAGGGGGACAGCCAGTCCCCCAACATTCACACACAGTCATGCTACCAAGTGGAAGCATATCATATCTGCCCCCACAAGGAGGTCAAGGTCAACACCCTCCTATTCAAGCCTACCAGCAGACTAACTAGAGCAATGTGTAGTGCATAAAATTCAAAAATATATATAGAACTGATCAAGGCCTTCATAATTTATTATATTATAGAGACCTGATGTCTAAGAGCTGGAGGAATTTCTTATTGAAAAGGATATATGCTGCTTATGTGTGACAGCTGAGCCTTGTATTGAATGTACAAGATGTGTTTTACCTGATGGGAAATAATGTTGTTTCCTCCTGATGGATCGGCTCTTAGGAAAATCCTACCAAGGGCCTAGGATTTAAATTGAAGCAAGCAGAAGAATCCTACAGAATTATCTAATCGTACTCCAAGAATCATATTGTGCAAGTTACCAACATGTTTGGTTTTCTTTTAATGCACCTTATAATTAAAAACTACCGGGGGCTTGTGTCTGCTCCTGGCCCTCTATGTGGAGTACAAACAGGGTTTCTGTCTGCTCTGAATATTTATAGAGTACCACCAGCCAGGCTGCAGTAGTTTACTGTCTGATCCAGCCTTTTAAAATGGATTTGCCAATTGGCCTAGTGTGCTGTTTGCTCTTTACTCTCTAAATGGAGTGCCAACAAGGCTCCTGGTCCGCAGATATTATTGAGATTTTAACAATGAGGATATAAGTCAGAATCGTAGGCTAATTATTGCTGACTAAACTCTAGATGAATTAAATTAAGGTTTTAAGATGTTTCTGCAACAGATTTATCCTATCTAAAGATTTCAAAATTCGCCCCATAAATTGGTAAATTATTCTTATTTAAATATTGTTTAAATGACCTTGACTTCAGATTCTTTATATGCAAATGTATTTTCCCTGATATTAAATTCTAAATTCCATTTAAATGTGATAATTTACATCACAAAATTAAAGAAAACAAATACGATATATATATTATGAAATTTGAAAACCATGTCATTTAATTGAAAACTCTGGTGACTGAATAGTGCTTACATTGAATATGTAATTTCACATTCATTGCATATTCCTATGAATCTAAGTAAAAAATAATATGCATGAATGAGCACAGAAATAATTGTTAAAGTTGCTTACCTTTGCTTTATTCATCCTGATAACACTAATTGTATTCTAATATTTTATTATGTAGCTTATGTTTTCTCGGTCCCCCACATGTGGACAATGTTCACACGTTTTCTGGTCCCTATGTATAAATATTAGGGTATGCTTACTGATAGTCCCTCAGGTTAGTTATTCAAATATATTGGTAATATTTTCACCCCGTAAGGATTAACACGAAACAACTGTTTTATAAAATGATTATTGTTGATTTCATGTTTTAGTTAAAATGATTAAGTTGATCAGTGAAGTAATGCAAATTGGATGTTAAGCTATTATTTTGAAATAGTTTCTACTTAATAATTTAACAATCTGTCATCAAATGCCATTGCATAAATGAATGTCGGCTTTTTTTTTACTGATCTGTGGTGTTGACTTATGACACCTAATTATAGTTCTTTGTGACAGGAGTTCCTGCTTCACTTCAGATTTCTTTGAGTGAGCCAATTACATGGTGTGAACAGCTCCACAGTTAATTAGATATGAGTAAGGTATTCTTGAAATCACTCCATTTAAGATGCATATCACTTTACAGTATAAGGCATAGTTGTTTATTTCATTAATCATTAAGATAACACATATCATCAGTGACATCTAATGTCATAAATACATGGCTAAGCCTGGTATAGTCTGCAAATGCAAAATGGGGTGTAAATGTTTTGGTTGTTTCAGATTTAATTTCAACACAGTTATTTATTCAGGATGTGAAATGGAAATAGTTTGACTGTTTTTATCGACAATTTCTTAACCAGTGCATCAAAGTATATAAATATTTATTTTATTAATGCAGTATTATATTATTATTATTATTATTATTATTATTATTATTATTATTATTATTCATATATTGATTTTAGTGTTTATTTTTAAAATAAAATAATGCTGATGTGTAATGAACTACTGTATTAAAATGAACATTTTACATTATATACATGTACATGCATGTTGGTGACACATGCATACATACATACATACATACATACATACACACACACACGCACACAAGGATGAGCAAAGCAAAAGTTTAAACTTACAGATCTTTATGACCTGTTTGCTGCCCTCTATAGTTAAGTTATTTTGGCAGCTACTGTAGTTTAAAGAATCTGATATTTGAATTAGTTCTATCATGTCTATGTTTTTATGACAACAATATAAGGGGGTTATTTTCAAGGATATAGCAAGGGAGGGCACTGCTCAAGGGAAGTGTATGAAAACGGTGAACATCGTTCTTTGTGTTACAAACGAGTTCTATTGTTCTTCCGTTTTTTGTCTTGATGTGAAATGAAATAAAAAATGACATGATTGCATTTTATCCAAATAAGAA
->LN587638.1 Uncultured eukaryote partial 18S rRNA gene, clone SIGW489_N9D4_16S_A 
-AGTCGGCTCAGCGCCTGGTCATCCGTATGGGAAACTAGCTCGACCTTCACTGGTCGGCTAGTGGATCATACACTTTACTTTGAAAAAATTAGAGTGTTTCAGGCAGGCAATTGCTTGGATACTGTAGCATGGAATATGGAATAGGACTTTGACCTTATTTGTTGGTTTCTCGAGGTCAAAGTAATGATTAATAGGGACAGTTGGGGGCATTCGTATTTAATTGTCAGAGGTGAAATTCTTGGATTTTTTAAAGACGAACTTATGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCAAAGACGATCAGATACCGTCCTAGTCTTAACCATAAACTATACCGACTAGGGATTGGTGAGGTCTTTTAAGCCTCATCAGCACCTTATGAGAAATCAAAGTCTTTGGGTTCTGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTTACCAGGTCCAGACATAGTTAGGATTGACAGATTGAGAGCTCTTTCTTGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGTTAACGAACGAGACCTTAACCTGCTAACTAGTCACCTTTATGTCAATAGGGGTCTGACTTCTTAGAGGGACTTTATG
->XR_004845356.1 PREDICTED: Anopheles albimanus uncharacterized LOC118464036 (LOC118464036), transcript variant X5, ncRNA 
-CTCTCTCTCTCTCTCTCTGAATTGCTCTCTCCCTGACAGTCTCTATCTCTGTTTTACTTCATGCCCATCGCCTGCTTGTCCAGGTTCCGTGTGGCACGTACAGGATACGAAATTCTTCCTATTTCTTCTGAATGGCAAACTGACATGCCTTGCATTCGAAATTTCGAGTATTGTACAGAGAACGACGGCATGTGCTGCATAACCAATGAAACCGGTGCGTTACAGCCGATGAGTCGCTGCGGAGTGTGATTTCGAAAGTGCCGACAGTCGGAAGTGGTGGCCGCTCCTAGGAGGACGTTCGCTTATCTCTGTAGCAGTGTTCTTGAAAAATATTCTAGAATTAAGCGTGAGAAACATGCGTTTAGCTAGGTGGAATACTATTTTACGAACCTGAGGAAGTTCCCCGGAACAGTGTGAGACTCACACTCACTAAACCTCACTAGCTTGGTTTTCCGTTACCACCCTGCAGCTGTGTGCCTCTTTCGAGATGACTTGCAGCGAGGGTGGCAACGCCGAACCACTTGCTGCGCGAAAACATGGGTCTGAAGCGACTATATTTTTTGGAGTAACGTTGTTAAAACCACCTTACACGCTCGTTACTGCTAAAAAACGGTCCTCGCAAATGCGCGGGTGGCCGAATGGAAGGTACTCTCTGAAGTACCCATGTCCCGATAGGAACGGGGCCAAGCAGGGGTTAATCTCGCCGTATCTACGAGACAACCATCTCTCAAGATTGGGAAGTAGACGATAAGTCCATCGGCCGTTCTGGTCATTTTCCCATTATCGTTGCCAGCGCTGCAGCGACCTCGCCCGCCTCGCCACGACCAGCGTAGCGTTCCCTGTTCTCTTCGATGAGAATGCCAACCGGGATCATGCCGGTGATCACACTGATGGCCGCTGGTGATACGGTTGGGAAGGCACCCGCAACCCCAATCCCAGTAAGCCTGTGAACGCGGTTCAGCTCGACCAGGTTCCGTCCGGTCGACAGAGCCGAATACCGAGGTGACTACGCTGGATAGTAACCTCGTCCTCGAGCAACTGAGGCCGTCTGCTCCACGCATAATGGCCGAAAGGGCGTTAAGAGCCATCAGTGCGTTAAGAGGTGGTAGCATAATCAACATGGTCTCCGAAGGCAAGCGTGCGATCTACTATCACCCCGAGGTACTTAATCGCCTCCTGGGACCGATCCACTAGATCGCCGATTTCAATCGATATCTCTTGGACAGGCTGCAGGCTGCTAACAAGCATTGCCTTGGTTTTGTGCACGCTTCCACTGATTCGATCAACCGTTCCGCGTTAACTTTCACCTCGCTCAGGCTCTGACCATTAACCGCTAGGACCATATCGACGACCAATGACATAACAGGGAGTTTCGGCCGCAGAACCCCGTCAAACATCATTTTTCAGAATGTTGGCCCTAGAACGGATCCTTGGAGAACGTCAGCCGTAAGCGGCATTACCTCTGGTCATGAGTCGGTGTCGTACAGCAGAACGCGTCGATCGAAGTGCCTACCCAGGATGCGCCCGAGGGATCGCCACCCCAATTGGCGTTGTTGAAGGCGTTCTTCGCGTCGATCCGCGTGACAACCGCGCAGAGACGGTCGGCTCCCCGCTTTTGGCGAACACCACTAGCAGTTTCGAGTACCATCTTTATCGCGTCCAAATATAATTCAGCTGGTGTAGCTAGAAATGTTGTATAATACCTAAAGGCAGTTGGGTATTGTTTAGTTAATGCTCAACATTTTTGTGCACTTAGTAGATTAGATATGGTTGGTCGTAGTGGTTAAGTGGCCCAACCGTACCCGATCAGAATGAAAATGGAATACTCCAATACTGTCCTAGTCTAACATTGCGACAAGAGACGGTTCAGATACTCTCATTTCTTCCTCCTTACACATCCGCTGAAGTTACTCTACTGGAATATTTGGGGCGATGGTTTTCCAGTTTCCAAACCAGTTTGGACTGTATCTCAGGTGAGAGAACATGGTCACAATGCATCTTCTGAGACCCAAGAGAATGGGCGCTGGGTTTTGTATCCCTTTCTCGCGAGGACAGCACTGATTATAAAACATGAAACTAAAGTTTCTATTGTAGAAGGTTTGTAGTACCAGATGAAAAGCCCGTTAACTTGCAGATTTCAGACCAGGTCATGGGTAATACTGCCTCCAATCATAATTGCAATAATTAAAATGTGTAAAATTTCGGACGATGTAACTCAGTAATTAATTTGCACCACCAAAGTGAATGAAACCCCCTATTTTATTGCTAGAAACTCGATATAACGGATATGATATGTGTGAAAAAATCGGATATCGCAGCATATAATCGGTCCATTAAGCTACTGACCTGCAAGCCACAATGGGACTCGCAAACCCGTACTGCACTTGCCACATGCGACAGGATGAAATCGCCCGTAGGTACAATGGTTCACTGTTTGATTATCGTCAGAAAACAACGGCTAATCAAATGATGCAACAAAACGGGCATCAATGGTGGTTTAGGCCATTACAGGATGTGTTGGGGTTAAGGGTGACATGACTCTTTGGAAAACCAGAAAGGTGGGGCAAACAGCCATCAATGGTAGTATGTTGGAGTGACTACCTATTAGGAAAGCGAGTAGGAAAAGGTTCACCTTTCCGGTATGGTAATTCACCGAAAAAAATGAACTGATATACATAATACAACTGATACACTAATATACCAAAGCATTAATGCTTGCGATCGAACTTCGCAAACCTCAATTGTTGCAGATCTGCTCTTTGATGTGCTTGGTTCGCCAATCGATCTGATCGAGGACTTTTAGCGGCCGCAGGCAGGTAACGCTAAATCGTGGAAGCATTGGATCAGGACAGTCGCTTACGTCTGAATCGCGCATCGCCATTGATCCAAAGGGTGTTGAAAACATACGTCAGTATGTTGTACAGCCTGCCCTAAACATAGTGCAACAATCGAATTGCTTGTGTCTTTGCACTCATCGTTTGCGAACTTGCCGAGAGAGATAAGTGGGCAAATGATGCATATTCAATGAAGTTGGCTTTGGCAGCTATTGCATATGTTGCAGCCAACATACACATTCCAAAGGCACCAAACACATATAATGTTGAATATCTTCTGATTTGGCTATTATCTATTCGAACTTTCTCATGATAAAGCATTCTGTAAATTTTTCAAGGTTTTAACGAGACATGTTGCTCTTGAAGCATGGACACGCGAATGTTCGATCGGTAATGCACCGCTTCCTCTCATGCATTGGTCACTGTTATCAGCATATCCGAACTGCCACCGATCGAATTGTCCTGTCACTAAAGGAACATGAACATTACCGCCATTAGTTGCAGAAGTGGCCACCCTAGAGCACCAATCTATCCAGGCAGTGCAATGGTTCCATATCGGACACAATTAATCATCCGTGCAAAAGAAGTATGCGGATGACGATCAACATGGTACATGTCCCTCAAAGTGCATGACCACGATCTAACGTTATGTGACTCTTACACGTGGAAAATCGCAAGCAAACGTAATGGCGCTGATCTTGGACTCAATAGTAAAAAATATGTATCGGTTTGGAATGGAAGATTTTGAGGACTGAGTACTCACGTCTGGCGAAACTGATGCGTTCGTGCTCTACGTATGGTATCAATGGCCCCTATTATGAAACAAGTCGATAACGCTATCGATCGACAAGAGTAAATTTTTGAATGAACTTTTCTTGCAAACGAACATAAAAATGAACACTTGTCGACTTTTTTGTCGATCGATAACGTTATCGACTTTTTCATAATAGGGGCCACTGTCCGTCTGCAATTGTTTCTATGCTATCCGCTGCCGATGGTCCTGTGTTTGCCACTTATAGGCTACGGTAGATCCTTGCAACAAAAGCTCTTCTAGTCAATGCAATCAATAAACTTACAGTGTTTTTTCTAAGATGTTCGCAGCGTTCAAATGGCACTCCTGGAAACAGCTGAACAAACATCAATAATCTGTTGAATGGAGAAAATAAGCCTGCCTCGGATAGAACAATCAGAATGAATAGAAAATAACAGCAATTTACACCTAGAAGAAGCCTCTCATCTTTGTAATGTATGCGTACCCTGAATTCTAGCTCCATGGATGATAAACTATTCTTAGATGATGAGCTAGACTGTTAAAGTAATGTTATTAGTTCATCAAGTGTCAGTTGCACAGCTGATTATAAAAACAAGACAAAGTGCGTTGTTAAAGGGAAAACACATCGCGATAGTCATTTGGAATACTCAGCTTTTACAGTTATTGTGGTGAGCATTTAATGTGTTTGAGTATAGAATTGAAAAAGAACCAAAATGAGTTTTGTCTAAAATACACTAATATAAAACCAGCTTATCATATAGACTATTTGTTGTATTTTGATAATTTCTGTTTTTCCAAAAAGCGTTGTATTGGCAGACAGGCGTCAGTTCCGTTCCTCTTCCTAAAAGCAGAGGATCGCCAGATGCGGCGCAATCACGATCACTATAATTGAAAGTAAAATGAAGACCCTCCACTCCCATTCCTTTCAATGGCAATTCAATGGCCCGTACGCGCCATTCTCCTACTCCCGAGACCAGCGCTTCAACGCCTTTTAACTTACCGTAAATGCCATCGAATTGCACTCTTTCTCACTCAATGGGTATTCTGATGCGGATCCTATCTCCAATTACACATACGGTCCTCAAACATCCAATGCACAAATGATAAACCCACCCTTCGGTGAGTAGAATGAATTGAGTTTTTGCAGGTGACGCTTTGGTTAGACAGTCGGTCGACCGATTCCCATATATCACAGTTAATCATCACGCCGAGATACCTGACAGCATGATTCAACGAAAAACCACGCAACTTTAGTTTTGTGATTCGCGAAGAGTAAACTTTCTCTCGTTTATTTTGCCCCTTTTCCAGGATTTGGCCACAGATTCTATAGATCACTGATACATGCGATAATCAAAACCCCTAAAGAAAGCGCTTGAGATCAGCGCCCGACATGTACGTATTTATAGATGTCAATTCCTCAAAACGCCGGTTATTTATTGGTTTTTATCATAATAACTGCGTGTTTTCATACACATAGTGTTGATAGTTGGTTGGTCGTTACTATTTCTTCCTTCATTTAACTGTCATTTTAAGATTGCCTTAGAAACTTGCCATAAGGAATTCAAAAACGAGCATTTTCAACGGACATCTGTCAGCCAGAATGAAAGTTAAAAGTCATTGAACAAAATGTAATATATATTATTAGTAAACCATTATCTTAAGTATTTGAAGAATTGAATTTAAGAATTTCTTTTGTAAAATTTAATGTATAAGTAAAATTGAAGCACTGTTGTAAAGTTTAAGTAGCTTTTAAACTATGCTATTCTGTAAAACGAGAATGCAAACCCAAGAGATTGGACACGCATTTAAAATCCTAGCAAAGCATTTTCTAGCATCGTCGAATGGTGCCAATTGTTTCATCTTTTTCGTATTGGTTAGTTTAAAAAGGAATATGAAGAATGGATTTTAATTTGATTATATAAATTCATAGAAAACACATTTCCTAGAGCATTGCCATTATCGACATCGATTGACACCATTCACGAAGCCTGATTGTTAAAATGAAGAAACACCTCCGCTCCTCTATTCAACACTACCGGGATCTACTCAATAAATATGCAAATCATGTAGCTACTACGCTCTTACTGTTAAAAGATCCTATTCATGGTATTCTCCAAAAATATTCAAGATTTATGAATATATTTACATCAATTGTGTCAAACGAAGGACTCTTCGTTTCACCTTTATTCTGTAGCTATTTATGAAGACGCGTGCCGCGTTGTGTGTTGTTGGGGCAATTTTAATGTCATCATCGTGCCGTGAGGGAATGGTAACTGAAAGGCTTTAAGATGCAAAAAGTTTAAAATTCCAGTAGCAGAATTACTTGAAGGATAATTCTTCTGAAGAAATGAAACCCATAAAATATGAATATTAGACTGTGTACCTGCATTAGTCTAACACCAAAATGTATGACCTTCCACAAATCATCCTACCACCCACGACACATGGATCAAACATCAGCTGTATATTGTAATATATTTTATCAAGATTGTTCTAATATCGATGAAATCTTAGTTTGTAAATGAAGATATCCATCTTTATTTTGCCTCGGTTCTCATCAGTGCTCAATGAAGTTGAAACTGTTTAGAATTGACTGACTCTGTTTTTTTTTTTTTTATTGAAAACATCTAGCGATTTGTGAAGAAAGAAACTTAATAAAACTGATAATATTTGATAATAAAAAATCAATAAAAAGATAGCCATTTGAAATAATCAGGCTATACAGGTGCGTAACCAACATGCCTCCAAACTCATTCCGGAACCATTCCGGAAACTTCTCTGACGTCTACCATAAAGCAAATAAACTTAATTGACCATATCTCAATTCAGTCAAACAACCGGTCAAAAAGCAATAATCTTTTGCCCAGGGATGTGGCTGCATGCAAACGTTTACCATGGGATAAGGCAGCAAGTGCCCCGGCTCGTGCCCTTGGACGCTGTGACTGGGCTAAATCATTGGGGAATTGGTCAACGGTCACCTAATGGATAGGCACAAGGAATGAAATCAATTATTACTACTCATGTGGAAAATGCCGTCAACATTGCTTACAAGGGGGTGCAAACTATTCAAATACTCTCACTATTAGAAGTAATACAGTTCGTAAGCAAACGTGTGCAGCAGGTTTTTTTTATTGAAAAAAAAAACACAAAATTGTAATAAAACTGCTACTTGCACCTTTTTCACCTTGCATATTTTTTCTGAGTGGTGAAACTTCCAACAGTATTGCGTAATCGTTTTAGAGCAATCGAATTAATTTGCGCATGGTAGCTTTTGTTTTAATAAAGTTACTTTTACTTTATTTTAAGAAGATCCCGAACCCCCCTACAAATTCTGAGCAGTGCCTTTTGAAGCGGATATCTCAAAACTATGGTTTTCAATCTCGATGGTCATTACAGTACTTCCTTTCGTTTTGAAATTTTGAACACATCATTTACCCTTTAAATGTTTACTTGTCAAGCTCGAACATTTTTTAAATTTTTCGATACTTTTTATACCCCAAAGGAAAAATCGATTATCGATTGTATTGATTGGTAGTAATCGTTCTAAATGCACAAACAATTATTTCTGCAGCTTAGGAGAATCATACCCGTATGCCTTTATCGAACAGTAATTGACGGACGTAGTGAATCGTTTAGAGCAATCGAATCGTTTTAGAGCAATCGAAT
->XM_009271859.1 Wallemia ichthyophaga EXF-994 Phenol 2-monooxygenase partial mRNA 
-ATGGCGTCAGATCCGCAAATCAAAAACTCAAACGTAGACGTACTAATCATCGGAGCTGGTCCTGCTGGTGTCATTGCCGCTGACTGGCTCGCGAGATTCACCAAATACGGTGTTAAGACAAGGGTGGTGGACAAGCGCTCGCACAAAGTCTTCACCGGACAAGCAGACGGACTCAACCCGCGCTCTATTGAAATGTTCCAGTCTTTCAACATTGCAAACAAGATCGTCAGTGAAGCGAACCCGATGAATGAGGTTTGTTTCTGGGCCCCAAATGAGAGCCATGGTGGTATTGAGCGTGGTAGACGTATTCCAGATACCATCCCTGGTATATCAAGATACGTCCAGTCTGTCCTCCACCAAGGTAGAATCGAGAGACACATCCTCGACGACATGAACGAAAAGAGCAATGGTACAATGAAGATCGAGCGTGGTGTGCTTCCCGAGACGTTGGAAGTCAATGAAGAACTCTGCCAAGACGACAACGCGTACCCAGTCAAAGTCGGTATTCGCCAACTCTCAGAAGAGGAATCACGTCCAAAGCTAGGCTCAAAGAACGGTGAAGTAGAATCTGGTCTCTACAAGTCAAACCTCGTCAAGGATGAAGACGATGACGTCGAATTCAAACCAGATGTTCCGGTCGGCGACAGAGAAATTATCAACGCAAAGTATGTTATTGGTGCAGATGGTGCGCACTCGTGGGTGCGTCGTCAATTAGGATTCAAGATGCAAGGTGAAGGATCTGATTTCGTTTGGGGTGTTGTCGATGGTGTTCCAATCACAAACTTCCCTGATATCCGCTGCCGTGCTGCTATCCACTCAAACGCTGGTAGCATGATGATCATTCCACGCGAAGGTAGCCTCGTTCGTCTGTACATTCAGCTCAACTTGCAAGTGGACGAGGGTGGACATGTCGACCGTAGCTTGATCACACCAAAGATGCTGATGGACCAAGCTAAGGCTGTGTTCCATCCATACTCGATCGAGATTCCTGATATCATGTGGTACACCGGTTACCAAGTCGGACAACGTCTCACCTCGGAGTATGCAAAGAATGACCGTGTTTTCATCGCCGGTGACGCTTGCCACACGCACTCTCCTAAGGCCGGTCAGGGTATGAATGCATCCATGGCTGACACATACAACCTGTGTTGGAAAATTGGTCATGTCTTAGCTGGACACGCTCCACGCTCCATTCTCAAAACATACGAGAGCGAGAGACGTCCATTCGCGGAGCACTTGATTATGAACGATGCCCAACTCGCCAAGCTCTTTTCAGGAAAGCCATTGTCATCAGCTGAGCTTAATGAACTTGGTGTCGACATGAAGGACTTTGAAAACATTCTCGAGAGAGGAATTTCATTCTTTTTGGGTACTTCTATTGAGTACTTCAACTCCACTGCCACCGCCAACGGAAGAGACGGTAGACTTTCATCGAAGCAGGAGCTGGCGAAGAATATACCAGTCGGACAACGTTTCCCCTCTCACCAAGTCGTCTCGCAGTTCGACGGCAGACACTACCACTTAGTCGACACCATGTTTGCTGATGGACAGTTTACTATTGTGTTATTCGCAGGCAATATGGACAAACAAGTAAACCGTCAACGTTTGCAAACCATTGCTCAACGTCTCGACAGCGATGATGGCGTAGTGAGCAAGTATACACCTAAGGACAGACAAAGAGATGGCGTGATTGACGTCAAGACAGTCCACTGTGGAGGCAGAACGAACATTGAAGTGCATGAGTTCCCACAACCAACTATTTACCCACCAGGCACATACAACAAGCTCTACGTCGACGACGTTTCCTACCACGCAGGTCACGGAGAGGCTTACAAGAACTACGACATCAGCAAGGAAGATGGTGCTGTTGTTGTTGTGCGTCCAGACCACTTTGTCGGATTAGTTACCTCGCTCGACGGTGCTGGTATGGATGATGTCGACAAATACTTTAGCGGATTGCTCAAGACTGTTCCGGCAGAGCAACGCAACTCGGCAAAGGATATCAAGGTTATTCCACAACCTAAAGTTTAA
->XM_041320268.1 Suillus paluster uncharacterized protein (EDB91DRAFT_1172848), partial mRNA 
-ATAACCCTCCTTGGGCACGCTATCCTTTATTGCTCTCTTTCCCCACAACTCCATTGCATGTGCTGCCACACCTCCTTCACCTCCCTCCGATGATAACAGCACACTTGTTGATCTTACAGTTCATGAGACACTGTTGGACTGCTGCATGGGAAGCATCGAGGAGAAAGCATATATAGCTCCTCCTACCAGTGACAGATATCAACCTCACACACTTCTGTGCAGCTTCGGTTATCGACGATGACAAGCTCATTGCATATTAATAAAGTGGCGTATTCATCGTGGGCGCTGGCAAGTTGGTCTGGAGCGTCGTGTGGTAGACATACAGTGCAGCAGTTCAACTCATCAGTGTCAGAAAGACAGGCGTACACGACCTGCTCAGATAGCATTATGAGTATTTTGACTTCATTCTGCGCTACATATTCAAGGCGACAGACACCCGTCCCCACACCTCAGTCTCGTTAACCGTTGACTGAGGCTCGTGCACTAGCTCTTACCTTTGATACTCTGCTACTTCTCCAGCTACCTTAAAAGCCCGCCTATCAACAATTGCTCGTTCATCCAGGTCATGCATT
->XM_025612137.1 Aspergillus sclerotioniger CBS 115572 methyltransferase (BO94DRAFT_536881), mRNA 
-GAACTATGCGCATTGCACACCGAATTTCCTGTTCCTTAGTGAAGTCTAGAAATGTGACAGCCATGCATCGCCCTGATATACGAGGCATTTCAAGCGCATATAAAAGGCGAAGACGCCCCAGCTGTACGAGAGGTGATGTCGCCATCAACGTAATTTTACAGAGCAAAATGCCGACCACTATCGCTCAGACCATCCAATCTTACGCCCTTCGCTTGGTACAAGACACTCTGCGGCAGATTGCAGCCCCTGTGAAACTGATCTATGTTGTTGATGGAGTGAAGAGTGTCTTGTACAACGACCCAGCGATACAGGATGCCGATAAAGCGGTGATCTATGTCACCCATGTGAATTTCTGGAGAAAAGTCCTCCTAGACTTCGATCTGGGATTTGCAGAAGCCTTCATGCTTCAGGAAGTGGAATGCGACCAACTAAGTAAAGTCTTCGACTTATATATCAAAAACCGCGCGACCCTCGACTCCGGTGACTCACTGTTTCATCTCGCTCAGCGATTAGCCCAGTGGTGGAGACCAGCGAACAACATCGACAATGCGCGCATCAACATCGCATCCCATTATGACACCTCAAATGGATTATTTACCAACTTTCTCTCTGCAGATATGAACTATTCCTGTGCGCACTGGTCCAACGATACTGCGGAATCCCTACAGACAGCACAGCGACGCAAGGTTCACTATATGATCAGAAAGGCCCGCGTGCAACACGACCACCACTTATTAGACGTCGGTTGCGGATGGGGAGATTTGATTATCGAAGCGGCGCAACTAACCGGCTGTCGAGCGACAGGTTTGACACTCTCAGAAGAGCAAAAGAATTTGACGGATGAGCGCATCCGTGACGCGGGCCTGCAGGACCGCGTTCGTGTACTGTTGTGCGACTATCGCAACGCCCCGCGGCCAGGCAACGGATATGATTGCATTATCTCAATCGGCATGTTTGAACACGTCGGACCTGAGTATATGGATCAATATTTCGAAGTGATATCTCAATTACTAAAGTCTCAAAACGGCGTGATGGTCATTGACGGCATAACTAAAATACACCCATTTCACGAGACCAATCCTCGCGTGGGTGATTACATCAATCGCTACGTCTTCCCAGGCGGATACTTGCCCACACCAAGTATACTCTTCGAGGCACTCCATCGGGGCAGCAAAGGGACATTGGAAGTGTCCTCTGTTCTCAACACCGGTCCTCACTACGGCAAAACCTTACTAGCTTGGAGGAACAACTTCATTTCCAACTGGGAACATATCCGATCTGATTTTTCCCCCCGATATCCCGATGCGTCGGAAAAGGAAATCGAGACCTACCGGCGGCGCTGGCTATACTACTTTGAGTATTGCGAGGCTGGGTTCCGTAATCGTATCTTGGGAAATTACACCATTTGCGCGGTCCGCACCCCCGAGGTGACCATTGACTACAAGAGCCTGGACATTGATGATGCGCAGAGTATCAAATTATATGAATGAATCATTGTTCTTATTGGGGTCTGGGTCTTCAAATACGTCTTGACTTCATGATGAGCTGCAGAACAAAGATAAGTCATGCTTTATGTTCGGC
->XM_041003117.1 PREDICTED: Ochotona curzoniae negative regulator of reactive oxygen species (NRROS), transcript variant X3, mRNA 
-TCCTTCCGCAAGTGCGAAAATAACCCGATGCCCTAGAGAGCAGGCAGCCCAGCCCTGCGTTTGGTTGCTCTCAGGGAGGCAGGAGCCCTGGGAGAGGATGCACCCCGCCGAGCCGCCTGGGCCTGCGGGAGGAGCCGGCTGCCCTTGAAATGGAGTTGCTGCCCCTCTGGCTCTGCCTGGGTTGTCACTTCTTAGCCGTGGGATGGACAAAGAGCAGTGGAGCGGACATTGCTGTGTCCCAAGGGAGCTGCAAGTGGGACGACGGAACCGGAACCGCTGACTGCCGTGCTCAGGGCCTGGCCTCGGTGCCCAGCAGCCTCTCTCCGCGCTCTCGGACGCTCCTCCTGGAGGCCAACCCGCTTGAGAAGCTAGAGAATCACTCCCTGCAGCGTTACCGTCTCCTGGAGAGCCTCGGCCTGCGCGGCTGCCACCTGCACCGTCTGGACCGCAACGCCTTCCGCCAGCAGCAAGGCCACCTCCGCAGCCTGGACCTGGCTGACAACCGACTGGCCGAGGACTACCACGAGGCAGCCGCCGCCCTGCACACTCTGCCGCACCTGCAGACGCTCGACCTGTCCGGGAACTCCCTGACGGAAGACATGGCGGCCGTCCTGCTGCACAACCTGTCGTCGCTGGAGGCCGTGTCTCTGGCCAGGAACACGCTCATGAGGCTGGACGAGTCGGTCTTCGAGGGCCTGGAGCGTCTCCGGGAACTGGATCTACAGAGAAACTACATCTTCGAGATCGAAGGCGCCGCCTTTGACGGCCTGCCGGGGCTCCAGCGTCTCCACCTGGCCTACAACAACCTGCCGTGCATCGTGGACTTCCGCCTCACGCAGCTGCGCTTCCTCAACGTCAGTTACAACGGCCTTGAGTGGTTCCTGGCGTCGAGGACCGAGGCCACCTTCGAGCTGGAGACGCTGGACCTGTCCCACAACCAGCTGCTCTTCTTCCCGCTGCTGCCCCAGTGCCCCAAGCTGCGCACACTGCTGCTGCGGGACAACAACATGGGCTTCTACCGGGACCTATATAACACCTCATCACCTCAGGAGATGGTGGCCCAGTTCCTCCTGGTGGACGGCAACGTGACCAACGTGACCACCGTCAGCCTCTGGGACGAGTTCTCTGCCAACAGCCTCCCGGACCTCCGTCTCCTGGACCTGAGCCAGAATCAGTTCCAGTACCTGCCCGAAGGCTTCCTGAGGCAAATGCCTGCCCTCGCCCACCTCAACCTCAACCGGAACTGCCTGACCACGCTCCACATCCAGGAGCAGGAGCCCCCCGGGGCGCTCACCGAGCTGGATCTGAGCCACAACCAGCTGTCGCAGCTGCACCTGACGCCCGGGCCCAGTGGCTGCCTGAGAAACCTCCGCTCCTTCAATTTGAGCTCCAATCAGCTCCTGGACGTGCCCTCCGGCCTTTTTGCCAATGCCAGCAGCATCACTACAATCGACATGAGCCACAATCGAATCTCACTGTGTCCCGGGGCTGGCCCATCCAGCTGTGTGGATTTCAGGAATCTCACCTCTCTGAGGAGCCTCTCTCTGGAGGACTGCGGGCTGGACACGTTGCGGGACTGCCCATTCCAAGGGACACCCCTTACGCACTTGGACCTGTCCAGCAACTGGGGTGTTCTAAACGGGGGTATCAGCCCACTGCGGGATGTTGCCCCCATGCTGCAGGTCCTGGCCCTCAGGGATGTGGGCCTCAGTTCCAGTTTGACCCAGTTGGACTTCTCCGGGTTTGGGCACTTGCAGAACCTGGATTTGGCAGGAAACGCCTTGACCAGCTTCCCGAGGCTAGGGGGCAGCCTGCCCCTGCAGACCCTGGATCTGCGCAGGAACCGACTCACAGCCCTGCCCCACAAGGCTGTGTCTGAGCAGCTCCCTCAGAGTCTGCGGATCATCTACCTCAGTCACAATCCCTATGACTGCTGCCTGGTGGAGGGCTGGGACGCCCTGCAGCACCTGGGCGTCGTGGCTGACGCAGCCTCCATCACCTGCAACCTGTCCTCCAGGGTCATTCGTGTGCTGGAGCTGCCCGGTAGTGTGTGGCATGACTGTAAGTGGGAGCAGGTGGACACGGGCCTCCTCTACCTTGTGCTCATCCTGCCCAGCTGCCTCACCCTGCTGGTGGCCTGCACTGTCATCTTCCTCACCTTTAAGAAACCTCTGTTCCTACTGATCAAGACCCGCTGCCGCTGGTCCTCTGTGTACTGACTCAGGGGCAAGCCTGGGTTTGCTACTGGGCCTGGGCAGCTGAGGACATCTCTGGGCTGGACTGGGGGCTCTCCATGCAGAGGCTAGTGTGATAAGCCAGGGTTTAAATTAAACTGGAAAATGGTTCCATCCCTTAGCCTCTGCCTCCCCCTCCACCTATAAGTTTTTATCTCATTTTGATGGTTCAGCCTCATCATTCTGGTCAAATATTTATTAAATGACACTGTATAAAAATAAAAGACAATGGTCTCATATA
->XM_043331653.1 Rhizoctonia solani uncharacterized protein (RhiXN_11838), partial mRNA 
-ATGTCTCGCCTCGCCGCTGTGGCCTTTATTCTTCTTTCACTCAGCTTCCTTGCTCATGCCTCGCCCATCGCCGCCCCTGCTCCAGAGCCCGAGCCTGGGAAGAAAATTGTTGCGATTGAGGAGCGCGCTGGAAGCCATTGCTACGGGGGATATTGCTACGGTGGTCTAGACCTTGTGACTCTACTCTTGCAACTCCAGGCTGCGATTGAAATCAAGCTTGGGTTGCTTGATGGATGTCTACACGGCGGAGATTACAAGGCGATTATCCTTGAGATTGAAGCGCTGTTGTATGCTGCTATTGGTGCTGTCCGAGGCTACAAAATTGGTCTTCTTGGGCTTCTCACTGGCAAGATTCTGGTCATCGCTAAAATCTGGTTTGCTATCGTGATTTCTATTGCTACTCACTGTGGAAAATGGGCAGGCCACGCAGATTTTGAGATCTTCCTGGTTCTTATCGTCAAACTTGATCTTGCCCTTAAGCTCTTGCTCCTTGCCATCATTAATCTCGGCGGTATTCTCAGTGGCTTGCTTAGCATCATTATCGGCTTGTTTGCGAAGGTTCATATTGCTCTACTAATCAAAGTCAAGTTCTTCCTGTGCCTTGGCGCTCTGAGACTCGGCGGCTACTAA
->XM_039822988.1 PREDICTED: Perca fluviatilis glucosidase 2 subunit beta-like (LOC120573318), transcript variant X6, mRNA 
-TTTCAGGAAGTCAGGACATGGCCAGTTTAAATGTTGGATGTCATGAGTTTGAAACACCTTTGAGCGGGTTTTTGCGAGGCAGGAGGCAGACAATTTACAATTATGTCATCTGACATGCATTTCCATATTATTATCGCCGCTGTCTTTTGGTGTGGTTTCGTAGACTCGCGGAAAATAAGAGGGATATCTTCGTCCTGTCCTTATCTTCAACACAGACAACATGTTGCAAGTTCCTATCAAGTTGCCATCGCTGCAGATGACAAGCGGTTCTACAGGGAGAGGAAGTCTTTTCTGTGCATTGATGGGTCGAAGATCATCCCATTTGAGCAGGTGAACGATGACTACTGCGACTGTGAAGATGGCTCTGATGAACCTGGCACCTCAGCCTGTCCTCGTGGCCGATTCTACTGCACCAATCTGGGTTTCCGCCCACACTACATCCCATCATCGCGAGTCAATGATGGCATCTGTGATTGCTGCGATGCCTCCGATGAATACAACAGCCACGCTCACTGCCAGAACACTTGCTGGAATCTGGGACAGAGAGAGAGAGCATACGTGGAGGGCCAGATGAGGACCTTGGACGAGGGTTTGCAACTCAAGCAGCAACTGATTGAGGAAGGAGTACTGCTCTGGAGGGAGAAACAGGCCCAGCTCAGAGAGCTTCAGCAAGTAGCTGAGGACCTACAGATCAAATTAGAGGAACACAGAAGGAAGAAACATGAGGCCGACCGACTCAAAGAGCAAACTATAAAGGCGCTGGAAGCAGGGGGCAGCAGTCTCAGACGTCAAAACAGGACAGTATCAAGTACTTTCAAGCTACTGGACAGCAATAAAGATGGCAGTATAACAGTGGATGAAGTCCAGGCAAAAGTGGCACTCGTCCATGATGAAGAGCAGGTTCTCTCTGAGGATGAAGCAGTGGCTTTGTTGGGCGGAGGCCATCAGATGGATCTCACCAAGTTTCAGTACACTCTCTGGGACATCCTGACAAAAGGAGACCATGTCAAGATCAAAGACACCCGTGGTGCACCAGGCAGTCTTGTGGGTGAAGATCCTCACTTAAAGGCAGCTGATACAGATATCATGACCCGGTTACTCAAGATAATCCACAGACCTGGTTGTGGGCAGATTAATTTAGGAAACTATTTTCTTTCTACCGAACTCCACCCGCCAAACGTACCACGGTGCAGAAGGAAGCATACTTATGGACTAGCGGCTACTCCTCTTTGGCTGAGCTGTAACGTTGCTTACTGATAATGCTAGCTGACGTGAGCTAGCTTACGCTACAGCTCTGCAGGGAAGGACGCCATAGATGTTTACATCTCGCGCTTTCACAAGCACAAGCCTCTCGTCCATTAGTACTCTTCCTTGTCGAAAAATTAATCTAAAACATTTAGAAGATAACTTATGATGGACACTATTTTTAAACAAGTGTAAAGTTTATGTGATTATTGCATGTTTTAAAGAAGAAAATGAGACAGTCCTGTTAAAATTTTGGTGGAGGGGGTGGTGGTGGTTGCAGTCTTTTTTAATACCACCACTAGACGGTGCCAAAGTCAGAAATGTACACATCCTAAATAGTAGCTTTAACTTATTATTAAATACTTACTTATTTACACACAATTTGTTTAGCTTTTTGTATTAAGTGGATTTTGGAAATATATATATATATATAAAAAAAAGGTGCAGACCCAGAGGGGACTGAAATGTTAGTTTTCATAATAAATGGTGATGCTAGAGCAAGAGTAGAGTGTGAGATTTTTCTTTTCTTTGTTCAAGTTTGTGAT
->XM_017639444.1 PREDICTED: Rhagoletis zephyria uncharacterized LOC108383066 (LOC108383066), partial mRNA 
-ATGGAGCAATTGGAGAAGGAATTTGCTGACTTCTTCGGCGAATGTAAGCAGCAAGGATTTACCTCCAAAGAAATGCGTGCCATATGTCAGCCGCTGTTGCATCGTCGCAACAACAGATGTTACGTGTTACTGGGCGTCTTGTTGGCTATGATGGCCGCCTTTTATTTACTCTATAACTGGTCCGAAGAATTTAGTTGGTTTGTTAGCGCCATTGGACGTTTGGTGTTGCTACAGCTGTTGCCCTACTGGAATTGGACGCCTCTATATAGTAGCCGGTGTCTAATTGAGCGTGCGGTAGATAAAAACGGTGCGCAGAGTGCAACTTCAACAACGAAAGCCTTGGGCCGTTATGAGACTGAAGCTGAAAATTGCGTACTTTGCGAGACGCTTG
->XM_047907316.1 Fulvia fulva Putative ariadne-like RING finger protein (CLAFUR5_08168), partial mRNA 
-ATGGCCAACAGCTCGGAAAAAGAGGTTGTGGACCTCCTCATACTGGTTGACGCCACGGCGTCTATGACCAGCTATCTCCAAGCACTGAAGCAATCACTACCACAAATCATCTCTATTTCAGCCCTGACGAACTGCTTTGATCGCATCGGCATACTAGCGTATCGCGACTATGCCCACCGCGACCTCCTCGACTGGTCAGGCTGGACTTCTTGCGCTCAAATGCAGCAAGACGGCGGAGCCACCCTAATCGCCAAAGCAAACGCTCTGCACGCCGTTCGCGGGGAATCCGACGACCACCCTGAAGCCGCGAAGACTGGCCTTGCTCAGGCATATGAGTACATGCGCACCGATGCAAAGACCCTCATGCTAGTCTACGCCGATGCGCCACCTCATATCGAAGGCCTTAAGACCCGTGCTCACAACGGAGACAAGGAGTTACAAGCCCTCTCTGATCCGCAGAGTTATGGCGGATACGGGCCACTCTTCGCGGATTGGGTCTCTGCTGCGAAGACCATGCGCGAGGGAGAGAAGAGGGTACAAGTCATGTCGATTCTACACTTCCCGTACCATCCACAGGATTCTGCCTATTTCGACTACCTAGCCACCATGACGCGAGGCGCTGCTATTCACTTGAACAACTCCCAGGCACGTACCATTTCTGAGGTCACGGTTGAGGTCTTGCTAGCTTGGATGGGTGTGAAGAAGGAGGGAGCTGGATCGGTCGCACTTCCTGCGAAGCTCTCCTGGTACGTGGACACAGATATCGGAAAAGTGAAAGCAGAAGGCGAGCTCGCTGCTTTCCTCCCGTTTGGAGATGTGATTGCATCTCAACGGCTAGCTCTCACATCCGAGCTTCTCGAACAACGACTGCCAAAGAAGGCGACTCCGCTAAAGGACTTTGCACGGTCTTATAAGGAAGATGCAGCGTATCGAGACATCGTTACCACGCATCTCCGCGCTATTATTGAGAGCGATGTGGCTGCTATGAGCTTGAATCCTGTCTTTGGTTCTCTTTGGCGGACCTTCTGTAATGATAAGGAAAACCCTCATGGGCAAGACCTCCTGGATCTGTTCGGGCTGAAAGTCAACGGTCTCGCGTACGCGGATGACCGAGCGAAGATGAAGACCTGGCTGGAAGAGTCTTACGACTATACTGCAGAGGTTCTCGAGGCTATCGCTAAGGTGCCAAAGGGGTTGCAGTATCCATGCGTATGCTTGGATCCAACGCTGTCGTATGAGTTGGCGCCTCAAGCCGAGGACGAGGACAGCGAAGACAACCGCCCCATCACTTCCTTCCGGCGGGATGAGCTCCTAGAGCTGGGACGATCTTGTGATTACCGTATCCTGCGACGCTTAGGACGAGTGCTTACCCGACTGACATTTGTCGAGTCTGCTGATGCGATGCCAGGTCACATTGCTGCCGCTGGACAGGAGACTGTGACCAGGATCCCTATGGCATTGGTCCGAAAGGAGTATGGCCGCAAGTTCTGGCGGATTCTCCTACATATCGTGGTCCCGGGTACTATGCTCTCCGGTCGCGCTGCTGCATTGCTTGGAGCTCTCACTATCCGGATGGGAGTACAGCCCCTGAGACGTGCTGCTGAGGAAATTCCTGAGACGTGGAATGTCAGCTGTCTGTCCCTGATTCTTGATGCTGATAAGGCTTATACTGAGCACTATAATGACGGCTTCATGGGAAGTGAGGCTGGCTTGCTCTGGGACCAGGATCGGGAGCTGTTCAGGCGCCTCGTGGATTACAAGATGTTGGAGCTTAATCTTGATACAACGCTGCACGCTCAAGTAGCCTGGACGCCTCACAAGACGACTATGTCTCTCGGTCCTACCATCATGTGCAAGCTATGCCAGTACCATCGATCAGTGACTGGCATGGGACCAGAAAACATTTGTGGACTGTGCTGCTACAATCGTGACAATCCCAATGCCACTGATCAAGCCAATATCCATTGCCACACTGCAGACGCTGATGGCGAAGCGGAGAACATATACTGGTACGAATGCAGCGCTAAGCACTGTCGAGCCCAGTACATCGTCCACGAAGCCGACAGGCTGAACGTGCGACCAAAGTGTCATTACTGCCGCATGGGAGAAACCGCTCCGATACTAGAATGCTCCAAGTGTCTCAACGGAATGATCAGGCCGCTGGAGTATCGACACGGCCTGGACGAAGCAACCTTTACTTGTGTAGGCTGCTCACAGGGACGCCAGACAATCATCGATATTTATGAGCATATGAACGAGGCGCATGGAGGGTACTATGGTGATTTGGAGGATGATGAGGACGGGGAATAG
->LN871451.1 Bacillus licheniformis partial 16S rRNA gene, strain IRQBAS20 
-TCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTTTTCGGATCGTAAAACTCTGTTGGTAGGGAAGAACAAGTACCGTTCGAATAGGGCGGTACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAGGGTCATTGGAAACTGGGGAACTTGAGTGCAGAAGAGGAGAGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGAGGGTTTCCGCCCTTTAGTGCTGCAGCAAACGCATTAAGCACTCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCTCTGACAACCCTAGAGATAGGGCTTCCCCTTCGGGGGCAGAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGATCTTAGTTGCCAGCATTCAGTTGGGCACTCTAAGGTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGGCAGAACAAAGGGCAGCGAAGCCGCGAGGCTAAGCCAATCCCACAAATCTGTTCTCAGTTCGGATCGCAGTCTGCAACTCGACTGCGTGAAGCTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAGAGTTTGTAACACCCGAAGTCGGTGAGGTAACCTTTGGAGCCAGCCGCCGAATGATGATATGAAATC
->OP114738.1 Raoultella ornithinolytica strain X13 16S ribosomal RNA gene, partial sequence 
-TGCAAGTCGAGCGGTAGCACAGAGAGCTTGCTCTCGGGTGACGAGCGGCGGACGGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACTGGAAACGGTAGCTAATACCGCATAACGTCGCAAGACCAAAGTGGGGGACCTTCGGGCCTCATGCCATCAGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAATGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGAGGAGGAAGGCGTTAAGGTTAATAACCTTAGCGATTGACGTTACTCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTCTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTTGAAACTGGCAGGCTTGAGTCTTGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACAAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGTCGACTTGGAGGTTGTTCCCTTGAGGAGTGGCTTCCGGAGCTAACGCGTTAAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTACTCTTGACATCCAGAGAACTTAGCAGAGATGCTTTGGTGCCTTCGGGAACTCTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGATTCGGTCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGAGTAGGGCTACACACGTGCTACAATGGCATATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCATAAAGTATGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTAGATCAGAATGCTACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTACCAC
->XM_021864905.1 PREDICTED: Chenopodium quinoa outer envelope protein 61-like (LOC110688195), transcript variant X2, mRNA 
-TAAGAGTCCTAGTCCTAATTCAAGTGTGGTTGGCGTCTTGGCGACCCACCTTATTTATTTCCAACAAAATTAAAATTATAAATTCTAATTCTTCACCTCTTTCCTCTATTTAACTTCACAATTATCACCGAATTTCCCTAACTGTTTAATTCTCTCTCTTCAATTTTGCATCCATCGCAATTAATCAATCCCTAGATTCTACGAATTTCTGCTTCGATTTGATCTCAATTGTAACTTATTGATTTTGAAACCCTAATCAATCGAAGGATTTTGCCAGATGTTTAACGGTATGATGGATCCTGAGTTGTTTCGGATTGCGCAAGAACAGATGAGTCGCATGTCTCCTGCTGAGATGGCTAAGATCCAACAGCAGATGATGTCTAATCCGGAATTGCTTAAGATGGCTTCGGAAGGTATGAAGAATATGAGACCTGAGGATCTAAAGATGGCTGCAGAGCAAATGAAGAATGTACGTCCTGAAGAAATGGCTCAGATTGGTGAGAAGATGGCTAATTCATCCCCGGAAGAAATTGCATCAATGCGTGCACGTGCTGATGCTCAATTAGTCTACGAGTTAGATGCAGCTGAATTACTAAAGAAACAGGGAAATGACCTTCACAAACAGGGGAAGTATCATGACGCTGCACAGAAATACTTGCGGGCAAAGAACAACCTACAAGGGGCTCCAGTTGCCAGAAGTAGAGCATTGCAGTTGGCATGCTCACTTAATCTGATGACATGTTATTTGAAAACAAGACAATTTCATGACTGTGTCAAAGAAGGCAGTGAGGTTTTGGCCTATGATGAAAAGAATGTCAAGGCCTTGTACCGTAGGGGTCAAGCATACAAAGAATTAGGTCAATTAGAGGTTGCTGCTTCTGACCTGACAAGGGCACTTGAAGTTACCCCTGGTGATGACACAATTGCTGAAGTTTTAAGGGAGGTCAAAGAAAGTCTAGGAAAAGAAGGTGTCACACGAACTTCGACAGTTGCAAATGGTAAGAGAACGTCTCAAGATTGTTCAGTTACTCAACCTGAGGAAAGCAGTGGGCATTCTAAATATCAATCAGAAACTGTTAGTAAGAGACCAACGACAGAATCAGAATGTTTGCAGGCAATGAAGGATGATCCAGACACAATCAGATCTTTCCAGAATTTCATTTCCGAAACTGATCCTGAGGTTCTAGCCAGAATGAATATTGGAAACAACAGAGAGGTTCCTGCTGACATGCTGAAGACAGCATCAAATATGATTGGACGAATGTCTCCTGAGGAGCTCCAAAATATGGTGAAAATGGCCTCCTCATTTAAGGGTGATAATTCACCCTTTAATGGTAACTTTGGACCGGGCTCAGTTCCTCCAAATTTGTCACCTGAAATGCTGAAAACAGCTAGTGATATGATGGGTAAAATGTCACCTGAGGAAGTTCAAAGGATGTTTGAGATGGCTTCCTCTTTGAAGCAGGACTCAGTTCCTAGCTCATCAGGTTCGTCAAGTGGCAGATCGAGTTTGGAGTCTGGTTCAAAGTTCACTGCAACTCGGGGTGTACCTGTTGATAGAAATAATGTTATTGGTGAGAGGAGCAGTATTTCTGGCTCATATTCTAATCCTGGAAGTACTTCCCAATCAAGTTTTCCTACATCAATGGGTGATATGCAAGAACAGATGAGAAATCAAATGAAGGATCCTGCCATGCGACAAATGTTTTCGTCGATGATGAAAAATATGAGCCCCGATATGATGGCCAGCATGAGTGAGCAATTTGGACTCAAGCTTTCTAAAGAAGACGCTGCAAAAGCTCAAGAAGCCATGTCGTCATTGTCACCTGAAGACCTAGATAAAATGATGCGTTGGGCAGATAGAATTCAAAGAGGAGTAGAAGGTGCGAAGAAGACAAAGAACTGGCTACTGGGAAGACCGGGGATGATTATAGCCGTATGCATGCTTCTTCTGGCTGTTATCCTTCACTTTTTCGGCTTCATTGGTAGGTGATTTTTCAGGACAGTAAGATAAATCTCCTGTTATAACAGCTTGTACTTGCTGATATCAGCAAATCCAGGGCCGAACTTATGGTGTTCAAGGGGTGTGTAAATC
->XM_028853279.1 PREDICTED: Macaca mulatta estrogen related receptor gamma (ESRRG), transcript variant X13, mRNA 
-GGAAGCTTGTACTGAAATATATACAAATAATTAAGAATACTTTTAGTGCACTGTTTAGTAATGCTCTCCCTACAAAAAAAAAAAAAAAATGCTCTCTTTATTTTGTCAAAATGCATTGAGAGAGATTTAATTCGCTATTTACCCCCACAACCCTCAGTCTCCCCACCCCTAAAACTGAAGAAGCCAATTTGTCCTGCGGTTGTTTACCTTTGTTTTGAAAAGCTATGCGTTGTATCTACACGTAAAGAGACAGTCGCAGGTATAGAAAGGTTTACACATATAATTTACTTAGGCATTCTCTCAAATTGTATTGTCACTGTTTCCTCTTCTGTAGTTGTGTAAAACTGCATTCCACCTCAGAGATGACGATCCCAGTTCACATGCTCAAACAATTTAGAAGAATGTCTTTATTATTATTATTTTTAATGCCCAGCATACATCAGGAAAACAGGAAAAGACATGATTAGGAATACATGAGAAAGTACAGCACCAAATAAACAGCAGCCCCCGGTGTAATCAAAACACAGACAACGGCAGGACAAACTTAATTCTCTACCTTCCGCAGAATCCTTTCCCAAATTAACTGAGAGTCTGCGTGAGTTCTCCTTTTCAAGGCAAAAGAGATCTTAGGTTAGAAATCAAAGGCAAATCCCTCCAGTGCTTAGAGAGTTAAGTTAGTTATGTTTCTTTTGTAGCTTCCCAGAAGAAAAAAAAAAAGAGAGAGAGAGAGAGAAGGGAGGAAAAAAAAAAAATCAAACCCGAGAGTGTGTATTGGGAGCGTTTCAACCGCTCCCTTCTCCGCTCCCTTTTTCTCTGCCCACTCTCAGTTTCCAGCCCCCTTCGGCTCTCTGCACCCTGCCTACCTGCCTGGCTCCTCTCGCTCCGTGCAGCCTCCCGTCGCCTCCCTCCTGATTGGGCAGAGGCCCCCCAATCGGCTGCGCGGCTGGGCCGGTGGGACTGCATATGTAAAGCCCTACTTCATATTAATAAGCTCCAATCGGGGCTTTAAGTCCTTGATTAGGAGAGTGTGAGAGCTTTGGTCCCAACTGGCTGTGCCTATAGGCTTGTCACTAGGAGAACATTTGTGTTAATTGCACTGTGCTCTGTCAAGGAAACTTTGATTTATAGCTGGGGTGCACAAATAATGGTTGCCGGTCGCACATGGATTCGGTAGAACTTTGCCTTCCTGAATCTTTTCCCCTGCACTACGAGGAAGAGCTTCTCTGCAGAATGTCAAACAAAGATCGACACATTGATTCCAGCTGTTCGTCCTTCATCAAGACGGAACCTTCCAGCCCGGCCTCCCTGACGGACAGCGTCAACCACCACAGCCCTGGTGGCTCATCAGACGCCAGTGGGAGCTACAGTTCAACCATGAATGGCCATCAGAACGGACTTGACTCGCCACCTCTCTACCCTTCTGCTCCTATCCTGGGAGGTAGTGGTCCTGTCAGGAAACTGTATGATGACTGCTCCAGCACTATCGTTGAAGATCCCCAGACCAAGTGTGAATACATGCTCAACTCGATGCCCAAGAGACTGTGTTTAGTGTGTGGTGACATCGCTTCTGGGTACCACTATGGGGTAGCGTCATGTGAAGCCTGCAAGGCGTTCTTCAAGAGGACAATTCAAGGGGTGCGTCTTGACAGAGTACGTGGAGGTCGGCAGAAGTACAAGCGCAGAATAGATGCGGAGAACAGCCCATACCTGAACCCTCAGCTGGTTCAGCCAGCCAAAAAGCCATTGCTCTGGTCTGATCCTGCAGATAACAAGATTGTCTCACATTTGTTGGTGGCTGAACCGGAGAAGATCTATGCCATGCCTGACCCTACTGTCCCCGACAGTGACATCAAAGCCCTCACTACACTGTGTGACTTGGCCGACCGAGAGTTGGTGGTTATCATTGGATGGGCGAAGCATATTCCAGGCTTCTCCACGCTGTCCCTGGCAGACCAGATGAGCCTTCTGCAGAGTGCTTGGATGGAAATTTTGATCCTTGGTGTCGTATACCGGTCTCTTTCGTTTGAGGATGAACTTGTCTATGCAGACGATTATATAATGGACGAAGACCAGTCCAAATTAGCAGGCCTTCTTGATCTAAATAATGCTATCCTGCAGCTGGTAAAGAAATACAAGAGCATGAAGCTGGAGAAAGAAGAATTTGTCACCCTCAAAGCTATAGCTCTTGCTAATTCAGACTCCATGCACATAGAAGATGTTGAAGCCGTTCAGAAGCTTCAGGATGTCTTACATGAGGCGCTGCAGGATTATGAAGCTGGCCAGCACATGGAAGACCCTCGTCGAGCTGGCAAGATGCTGATGACACTGCCACTGCTGAGGCAGACCTCTACCAAGGCCGTGCAGCATTTCTACAACATCAAACTAGAAGGCAAAGTCCCCATGCACAAACTTTTTTTGGAAATGCTGGAGGCCAAGGTCTGACTAAAAGCTCCCTGGGCCTTCCCATCCTTCATGCTGAAAAAGGGAAAATAAACCCAAGAGTGACGTCAAAGAAACTTAGAGTTTAGTTAACAACATCAAAAATCAACAGACTGCACTGACAATTTAGCAGCAAGACTATGAAGCAGCTTTCAGATTCCTCCATAGCTTCCTGATGAGTTTCTTTCTACTTTCTCCATCATCTTCTTTCCTCTTCCTTCCCACATTTCTCTTCCTGTTTATTTTTTCTCCCTTTCTTCTTTCCCCCTCCCTTATTTCTTTGCTTCTTTCATTCCTAGTTCCCATTCTCCTTTATTTTCTTCCCATCTGCCTGCCTGCCTTCTTTCTTTTCTTTGCTGCTCTCGTTCCTCTCTTTACTCATCTTCCTCCTGTTTTCTAAATTTTAAATAGCTTTAGTTGTAAAAAAAAAAAAAAAATCCTTCCTTCCCCCTTTCCTTTCTCTTTCTTCCCTTTTTTCCTTTTTCCCTTTCCCCTTTGCCCTTTCCCCTTTCCTTTCCTTCTGATCTTCTTTCCATCTTTCTTTTTCTTCCTTCTGCTGCTGAACTTTTAAAAGAGGTCTCTAACTGAAAAGAGATGGAAGCCAGCCCTGCCAAAGGATGGAGATCCATAATATGGATGCCAGTGAACTTATTGTGAACCATACCGTCCCCAGTGACTAAGGAATCAAAGAGAGAGAACCAACGTACCTAAAAGTACAGTGCAACATATACGAATTGACTGAGTGCAGTATTAGATTTCATGGGAGCAGCCTCTAATTAGACAACTTAAGCAACGTTGCATCGGCTGCTTCTTATCATTGCTTTTCCATCTAGATCAGTTACAGCCATTTGATTCCTTAATTGTTTTTTCAAGTCTTCCAGGTATTTGTTAGTTTAGCTACTATGTAACTTTTTCAGGGAATAGTTTAAGCTTTATTCATTCATGCAATACTAAAGAGAAATAAGAATACTGCAATTTTGTGCTGGCTTTGAACAATTATGAACAATAATGAAGGACAAATGAATCCTGAAGGAAGATTTTTAAAAATGTTTTGTTTCTTCTTACAAATGGAGATTTTTTTGTACCAGCTTTACCACTTTTCAGCCATTTATTAATATGGGAATTTAACTTACTCAAGCAATAGTTGAAGGGAAGGTGCATATTATCACGGATGCAATTTATGTTGTGTGCCAGTCTGGTCCCAAACATCAGTTTCTTAACATGAGCTCCAGTTTACCTAAATGTTCACTGACACAAAGGATTAGATTACACCTACAGTGACTCTGAGTAGTCACACATATAAGCACTGCACATGAGATATAGATCCGTAGAATTATCAGGAGTGCACCTCTCTACTTGGGAGGTACAGTTGCCATATGATTTCTAGCTGCCACGGTGGTTAGGAATGTGATACTGCCTGTTTGCAAAGTTACAGACCTTGTCTCAGAAGGAGCTGTGAGCCAGTATTCATTTAAGAGGCAATAAGGCAAATGCCAGAATTTAAAAAAAAAAAAAAAATCATCAAAGACAGAAAACGCCTGACCAAATTCTAAAACCTAATCCATATAAGTTTATTCATTTAGGAATGTTTGTTTAAATTAATCTGCAGTTTTTACCAAGAGCTAAGCCAATATATGTGCTTTTCAACCAGTATTGTCACAGCATGAAAGTCAGTCAGGTTCCAGACTGTTAAGAGGTGTAATCTAATGAAGAAATCAATTAGATGCCCCAAAATCTACAGTCGCTGAATAACCAATAAACAGTAACCTCCATCAAATGCTATACCAATGGACCAGTGTTAGTAGCTGCTCCCTGTACTATGTGAACAGTCTTATTCTATGTACACAGATGTAATTAAAATTGTAATCCTAACAAACAAAAGAAATGTAGTTCAGCTTTTCAATGTTTCATGTTTGCTGTGCTTTTCTGAATTTTATGTTGCATTCAAAGACTGTTGTCTTGTTCTTGTGGTGTTTGGATTCTTGTGGTGTGTGCTTTTAGACACAGGGTAGAATTAGAGACAATATTGGATGTACAATTCCTCAGGAGACTACAGTAGTATATTCTATTCCTTACCAGTAATAAGGTTCTTCCTAATAATTAATTAAGAGATTGAAACTCCAAACAAGTATTCATTATGAACAGATACACATCAAAATCATAATAATATTTTCAAAACAAGGAATAATTTCTCTAATGGTTTATTATAGAATACCAATGTATAGCTTAGAAATAAAACTTTGAATATTTCAAGAATATAGATAAGTCTAATTTTTAAATGCTGTATATATGGCTTTTGCTCAATCATCTCTCAGATGTTGTTATTAACTCGCTCTGTGTTGTTGCAAAACTTTTTGGTGCAGATTCGTTTCCAAAACTATTGCTACTTTGTGTGCTTTAAACAAAATACCTTGGGTTGATGAAACATCAACCCAGTGCTAGGAATACTGTGTATCTATCATTAGCTATATGGGACTATATTGTAGATTGTGGTTTCTCAGTAGAGAAGTGACTGTAGTGTGATTCTAGATAAATCATCATTAGCAATTCATTCAGATGGTCAATAACTTGAAATTTATAGCTGTGATAGGAGTTCAGAAATTGGCACATCCCTTTAAAAATAACAACAGAAAATACAACTCCTGGGAAAAAAGGTGCTGATTCTATAAGATTATTTATATATGTAAGTGTTTAAAAAGATTATTTTCCAGAAAGTTTGTGCAGGGTTTAAGTTGCTACTATTCAACTACACTATATATAAATAAAATATATACAATATATACATTGTTTTCACTGTATCACATTGAAGTACTTGGGCTTCAGAAGTAAGAGCCAACCAACTGAAAACCTGAGATGGAGATATGTTCAAAGAATGAGATACAATTTTGTAGTTTTCAGTGTAACTCTCGGCATTTCAAAAGAGTAAGTATCTCACAAATAGGAAATACAACTAAAACGTAGATTTAAAAAGAACTGCACGGGCTTTAGGGTAATTGCTCATCTTAAACCTCACTAGAGGGAAGTCTTTTCAAGTTTCAAGCAAGACCATTTACTTAATGTGAAGTTTTGGAAAGTTATAAAGGTGTATGTTTTAGCCATATGATTTTAATTTTAATTTTGCTTCTTTTAGGTTCGTTCTTATTTAAAGCAATATGATTGTGTGACTCCTTGTAGTTGCACTTGTGTTTCAATCAGATCAGATTGTTGTATTTATTCCACTATTTTGCATTTAAATGATAACATAAAAGATATAAAAAATTTAAAACTGCTATTTTTCTTATAGAAGAGAAAATGGGTGTTGGTGATTGTATTTTAATTATTTAAGCGTCTCTGTTTACCTGCCTAGGAAAACATTTTATGGCAGTCTTATGTGCAAAGATCGTAAAAGGACAAAAAATTTAAACTGCTTCTAATAATCCAGGAGTTGCATTATAGCCAGTAGTAAAAATAATAATAATAATAATAATAATAATAAAACCATGTCTATAGCTGTAGATGGGCTCCACATCTGTAAAGCAATCAATTGTATATTTTTGTGATGTGTACCATACTGTGTGCTCCAGCAAATGTCCATTTGTGTAAATGTATTTATTTTATATTGTATATATTGTTAAATGCAAAAAGGAGATATGATTCTGTAACTCCAATCAGTTCAGATGTGTAACTCAAATTATTATGCCTTTCAGGATGATGGTAGAGCAATATTAAACAAGCTTCCACTTTTGACTGCT
->AF377161.1 Rhizopogon sp. AHF133 internal transcribed spacer 1, partial sequence; 5.8S ribosomal RNA gene, complete sequence; and internal transcribed spacer 2, partial sequence 
-TCCGTAGGTGAACCTGCGGAAGGATCATTAACGAATATAATTCGAGGGGTTGTCGCTGGCCTCGCTCGCGCGAGGCATGTGCACGCTTCTCGTTTTTCTCTCAACTCACCTGTGCACCTAATGTAGGATGCCTCTCCTCCGGGAGGGGGGACCTATGTCTTCGTAACATCTTCGTGTAGAAAGTCTTTGAATGTTTACTATCATCGAGTCGCGACTTCTAGGAGACGCGATTCTTTGAGATAAAAGTTATTACAACTTTCAGCAACGGATCTCTTGGCTCTCGCATCGATGAAGAACGCAGCGAAAAGCGATATGTAATGTGAATTGCAGATCTACAGTGAATCATCGAATCTTTGAACGCACCTTGCGCTCCTCGGTGTTCCGAGGAGCATGCCTGTTTGAGTGTCAGTAAATTCTCAACCCCTCTCGATTAGCTTCGAGAGGGAGCTTGGATAGTGGAGGTTGCCGGAGACTTGGATTCGTCCGAGACTCGGGCTCTTCTGAAATGCATCGGCTTGCGGTCGACTTTTGACTATGTGCGACAAGGCTTTCGGCGTGATAATGATCGCCGTTCGCTGAAGCGCATGACTGAACGTCCCGTGCCTCTAATACGTCGACCGCTTATTATCTCTCCGGAGAGAACAGGGTCTTCCTTATTGACTTTGACCTCAAATCAGGTAGGACTACCC
->XM_023987877.2 PREDICTED: Salvelinus alpinus transmembrane protein 88-like (LOC111964137), mRNA 
-AGACAGACAGGAGACAGACAGGAGACAGAGGGGAGACAGACAGGAGACAGACAGGAGACAGAGGGGAGACTCAGTGACTAACCAAACTGGAATGAAAGTGAGGAAACAGCACGGCAGGAAAGGAAGAGTCAGAGCCAAACAGAAAAGCAATATTTGCCTTAACTGTGCAGAGCGTAGAATTTAACACAAAGCAAAGGGGAAAGAGAGTGACACCGACTGAGACCTTTGCAGACACAAAGCATCTGCTGAATACCTGGAGTTTCAGAAACACCAGGATATATCAGAGAATGACAAAGGTCTAAACTCTCATCATCAGGGTATAAACCTCCACCTGGTCAATGTCATCAGTCTGACCTCAGGATCTGGATGTTCATGTCGTGGAGACCTACCTCTTCTTCTCTCGACGCGCATTCTCAGAGAAGGAAGACAGGTTAAAGAATAGAGTGTATTCACATCTTCTCTTACTGCTACTGTGAGAGGCGAGAGACAGAGAGACAAATCCTCAGAACTGCTCCACCAATCACAAAGCCTAGGGAGGATGAGTCTGCCGAGGAACCAGACCCTGGAGAACGGCATCACCAAGCTGCATCACATTAACAATGGGGAACCTCTGTCTTCACTGCAGTTCCACCTCCAGCACACAGGCTCTGTGACCTCTGTGCCWGGGTCGCCCACGGGGGGGTCAGGGGTGGTGGTGCCACCCCCGTACTCAGTAGCGGGCAGCGTGGCGGGGGCTACGGACGCCACTCTGGAGCTAAGAGGCTCTCTGGACTGCTGGGCGTGCTCAGTACTGGTGACGGCTCAGAACCTGATCATTGCCCTGGTCAACAGTACGCTGGTCAGTATTGTGTTCGGCACCATCATGACCCCAGCGCTGGTCATGGTCGTGTTTGGCTTCCTATGTCACTCTACGGTGCAACCCAATGGCACGTCCCTGTACTGTTCAGACCTGCTGGATGACGGTGGCTGTGTGGCCCTGCTGGTGGTGGGCTTCATCCTGGTCACCCCTCTCCTGGTCCTGGCTCTGGCTGCTTACTGCCGCCTGGCCCGCCACCTCCAACTGGGCCTCTGTTTCATCCCCTACAGCAGGGCCGTCTACAAGAACCTGCCTGCCTCGCGCCAACGTGGAGGAGGCTGCTGTGGCCAGCAGGGGGCCTCAGAGGGGGAGGGCAAAGGCAGTGTGTGGGTGTGAGGGGAGGGATATGTTGACCCTAACCACTGATGCAGGGTCAGATAACATTTTCTTGCCTCTTAAGGTTAAGGTTAGGATTGGGGATCAAGTAATCTGATCCTAGATCTGTAGATAGAGGCAACTTCTACCTTGAGCAGGGAGGGAAGGAATGTGAAGGAAGGGAGAAAACAGGGCATGAGGGTAGTAGGGAAAGTTGAGGTGTGGACACGTGGAGATGATGTTTATGGACACAGTTATAATATGCCTATGAGTCTTTTGGTGGGGGTGGTGTGGAGGTGGATCTTACAATACACTGGTTTGTAGATTGCAGAGAGCAAAGGTGAAGCTGTAAAAACACAAGTATGCTACATGAAGTACTATCAAATACCACTGTAACTACACTGCAATTATTTGTTATTATGTTTGTTTTTTATGTTGAATTATCCTGTACTATTATTAAATTATGTTTGTTTAGAATAAAATATTTCCATTA
->XR_003517021.2 PREDICTED: Zalophus californianus uncharacterized LOC113912871 (LOC113912871), transcript variant X2, ncRNA 
-TAATGCTCCCCTCCTCCTCCCCTCTCCTCCTGGGCTCCTAGCCCGCCCGCTTGCCAGCCCGGGCGGCGGCGGGACCGCAGGGCCCCGTGCCTCGGCCTCTCCCCCGACGCCTGGCCCCCCCTCGCCGCCCAGTGGGACCGGGCGGGGGCGGGGTGGGGGGAGAGGGAGAAGGGTGCAGTTACGGAGGGGACCCGGGCAGACGCCGCGGCCACGCCTGGCACCCTGTGCCGGGCGGGTGGGGGTGGCGAGGGTGGCGGGGCCGGGGTCACCCGGAGGGGACGCGTCGGAGAGGGCCAGGCGGAACCAGCGCCCTGCCTAACCTGAGGGGGTGGCCCGGGGGTGTGCACCGCTGGACCTGATGTGGTCCTGAAGGCGTCCTTAAATTGTTAAAAATAGTCTCGCTGTATAGAGAAGAACACTGGAACCTTTTAAGTCCCCATCCCCTCGCCTGAGTCCGGAGTGAAACTCCAAACATACTTATTAAGAAACTGTTGCTTTATTTTGACTCGTTTACATAAATTTTCCACTTTGGGGGGATGGTGGTGGGCTTGTGGAATTCCTAAAATAACTTTTAATGGAGCGAAGCCTTCCATTATGGGAAGCGCCTAGACGCGAGAGGCGTCTGGAGGCCTAGGTTCCCGTCACAGCCCTGCCACCAACTGGCTGAGCGACTGAGGCACATCGCCGCCCCTCTCGGCCGGGGTTAGGAGAGTGGACGCCCCCTCCACCCCGAAAGGGGAGACCGGAGAGCTGTCTCAACCATTAATAATGAGACTGGGTTTTCCTTCCTTAAAATGTTCTGATAGTATGGAGAGGCAACTTGGAGATGAGAATAAAAATAAAAGAGGGAGCCATAACAGGTTTATGGCCCTGACCCGGGGAGGCCCTGCCCACCTTACCACCGAGGATCCGAGAAGCTGAGTACTGTGGACACCTGGGTGAAACAGCCATGAAGCTTTACTAACTGCTCTGCAGCCTGACTCACTTGGGGCGGGTCTACACCACAGTCTAAGTACAGCGAAGGAGGAAAGTGACTTCAAGCAAACTGAAAACCATTTGGAAGAAGAGACAGTAGGCACACAGTGTGACGAAGTCTGCGCTGGAGCTAGAAGGACGAGTATGCCCGCAGCTCTGTCCCGAACTGACCTCAAAGGGCCATCAGAGGACTGCCGTGAGGTGCAGCGAAGGGGACGCGGAGCCGCACGGGGATAAAACCACTCGCCCAGGGTCACCAGGCTAATGCTCCTTAAAGGTTCTTGTCTCAGTCATGTCCTCTAACCGGCTGGCTCACCAAGCTGCCGCTGTGACCAGGAGTTGTATTGTTTCCTTAA
->AJ288639.1 Centruroides exilicauda mitochondrial partial 16S rRNA gene, haplotype CexTE 
-CCCCTCCTCTTGCGGAGTGGAGGAAATCTAATCCAACATCGAGGTCGCAAACATGTTTGTCAATTTGAGCTTTCAAAACACATTACGCTGTTATCCCTAAAGTAACTTATTTAACTTTCAAAAATTTTGGGTATTAAAATAATGTCATTTATATATTTTAAAAGTGTTTTTCTTCTTACCGCCCCAGTAAAACATATTTTTAATTTATTAAATTATTTTATGTAAAGCTTTATAGGGTCTTCTTGTCTAAAAGAAACATTTTAGCCTTTTTACTAAAAAGTAAATTTCAAAAGAAAAAGTCAAGAAAGAAACTTTCTAGTTTATCCTTTCATTCCAGTCTTAAATTACAAGACTA
->XM_012291159.1 PREDICTED: Megachile rotundata mucin-17-like (LOC100879044), transcript variant X1, mRNA 
-GACCAGTGCACGCGACAAGAAGGAAGAAGCCGCGTGGCCCCAGGTGTTTTGAAATGAAACATTGGATCGGACTCTAAGAAGCTGCAAGAATGGCGCGGAGATTTTCGTGGTGCACGGCGGTGGCATTGGTGGTGCTGCTTTTCGTCACGACCGAAGGTCTTCGTGAACGTGGCACTCAGGTCGACGATCAGAAAACCGCAGGTCGAGGTACTCTGAGGTTCAACTCAAGATCGCTAGAGGAATCCACAACCGCTTCGCTCTCAAGATCCAGATCTCAAGACAGATCGCAGTCAAGAAAATCGAACTTCGAACGAAACGACAGAACAACCTCATCGAACTTCGAACGAAACGACAGAACAACCTCTCCGACCGACTCGGAGTCCACAACCAAACGTCCAAGCCCCACAGCGAGCGATGTGACCGAAATCCCCGCAAGAAGGACCACGGACCCGAACAGAAGAAACGGTAAAAGGTTCTCTCCAGAGAGGACGAGGTCGAAGGATGAAAACGCGATAGATTCCAAGGTCATATCTCGAAGGGTGTCGAACGGGAGATCCGACGGAGTCACGGAGAGGCTGGACAACACAGGGCCGTCGGTCTTCGCGTTGACGACGGAGTCCTCGAGGTCGAGGACCGGCAGGAAGATCCAGACGACGTTCTCCACGAAGGACCTGAAGACGCAGATACCCGCGTCGAGGAGGTATAATAAAAAATCGGAGAACGTAGAGGCGACTACAGTTTCCTTCAAAAGAGGCAGACCCACAACGGAGCGCAGTAGGTCCGGCAGGTCGAAGGTGAACAGGGAGAACTCTGTTGCTCGCAAAGGTCAAGAAGCCCTTTTGTACGAGTCTGAAAGCGTCAGAGTCGACATTCCTCTCGCAGTCGACGGAACAGAGAGTCCTTCCAGTGATCCAACGACCGTCGGCTTCGGTATCGTTTCCCAAAGAAGGTCGGACACCAAGGAGACTCTCAGGGGCAGGTCAGGAGCCGAGAGGAAGAGCAGAGGACGATCGAGCGACTCCGAAGCTGCCGGCTCCTCCAGAAACGGCTCCCGAAGAGGATCGTCCAGGTTCAACGACTTCTCCACCACGGAAGCTAACGAGGTTGGTTCGAGGAAAAGCTCTTCCAGGGATCGTTTGAAGGAAACTAGGAAGAGCGCTAGTGAATCGAGATCGAGATCTAGAGGTAGAGAACAGACGAAGAGTGCAGATGTGGATGTCAAACGAAAATCGGGAGACAGGAATTCTTTGGATAGGAGGTCCAGACTTTCCGAGGGAACTACGAGGTCGGTGGAAAGTCGCGGACAGGATCAGGATGCCAGGAGATCCAGGAGCAGAGCGAGGACGGAAACGACGCCTCTGGCTACGGATGTCACCACAACCGTCGCGCCAGAGACAACAGTCTTCACCGACTCGACGAGCACCGAGCCCGAAGTCTCCAGCACCACCCTTAAACCAACGACAACTTCAACCACAACCCGAAGCACGTCGCGATCATCTTCTACAACCGAAAGAAACCGAGGAAGAGGCAGAGGCAATCAAGGAAGAAAACTAAAGGAAGATTTCTTCAACCACGGACTCGGATTTCGAGGACGAAAGCCATCTCTGGATGCATCAAGCACCGGGGAGTCCAGAAGACCCACCCCCAAAAACGATTCCTACATAAACCCCGGTTGGACCCTCAGAAGACGACCACCTAACTTGAACTACTCCGACAACCTTCCACAAACGATCCCTTCGTCGAGAGACCAAACGAACGAAGTGATTCCTCAGAACGAGGTATCGACGAGCACCGAAATCGTAACTACGGTGGAAACCTCTACATCCACCGCGAGAAGAGGTTCTAAAAAGCTGCAGTCCACGGAGGAGAGCACTACGGAGATGGATGTTACTACGAAGAGTTTCAGAAGGGGTAATAAAACGTTCGAGAAGAATAGGAACGTTGCACCTGGGAAGCAGGAGCATGAAGAGAGCGACAACTATCCGCCGGAGTTTAAGGCCAGGTTGTCTCTGTTGAAGAGTACGAACACGAAAATACCAGCCCCGAAAACTACCTCTAGAACGCCATTGGAGGTGAAGAGATCGTCGGCCGCTCTGTTCGCCGAACGATCGAGGATGAAGCTGGAGCTGGCTAGGAGGTTAGTGAAGCCAGAGTTGAACATCGAGGAGAATGATCTCGACGCAACCACGGCCTCCTCTTTCAGCAAACCGAGGCCGACCGTGGCGTCGACGGTCGATGAGACGGCCAAGGTCGCCAAGTTCGTTAAACCGTCTGCGGGTCGCAGAACGTCCACGGAAAAGAGGTCTCGAGAAGACGAGAAGTCGAAAGTTTCCGCGAGGACAGGCGACGACTCCTCTAGGTTCGCTAGACCGAATTCGAAGAAAGGACGAATCATCTCCGAGAGAATGGTCACCTCGATCTCGGTGGAGGAAAGGGCTGCCGAACAAACCACCAAGCCATACTCGTCGAGTCAGTCGGTGGTCACCTTGTCCTCCGCTGAAGAGGGATCGGCGACCACCATAGACACCACGCGGATTCGCCTGTCCAGCGCTCGGAACGGAAAGAAATCCAAGGAGGAGACCTCGAAGAGACGCGAACACGACGACACCATTACCACTTTCAAACCGAAGAAGCCCTACGCGTATCAATCGCGCGTCACCAAATCGCAGGAACAATCTACGACCCCCGAAGAGAATCTAGTAACGTCCAAAAAGACCTACGCCTCGTCCAAACAGAACGGAGGGCAACGGAAGTTCCAAAGCTCCCGCGAAGAGGATGCGAGAAGAACCAAGTCCACGACAGTTACCAAACCCACCTTCAGACCCCGATACAGCAAACGAACGAAACCGAAATCGATCGACGACAAGTTGACAGACTACGAAGCGACGATCACCACGAAGGTACCTGTTGCTACCAGCAGGTACTCCAGGAAGAAGTCCGTGGTAAAGGCTACAGAGGGTAAATCGAAGACCACCACGGAAGGAGTAGCAACGCAGACGAAGAAGCTGGAGTTTCGTCCTAGAACCGCGACCTACAGAAGACACTCCGAGGTGCCGACGACCTTGGTGGAATCGAGTACCAAGGTTGAGGGTGCAGGAGTCGCCATCACTCCCAGATCGACCAAGTATTCCGCGACTCTGAAGACCTCGACAGAAAGCGCTCGATCGGTAGCGCAGGAACCGCAGGTTAACCTGAGGATCAGCAACGACACCGCGCAGGAAGCGGCTGGCATTACCGGCAGCAGTAACGGAGACACCGGCAGCAATATCTTCAATCCGACCAGAAGCACCATTCTCGCTGGAAATGGAACCCTGTTGGAACAACTGCGAAGCACCGTCGCGCCGCTGCTCAACTCGCTCGGTAACAAGACTCCGGTGTTCTCTGGATCCTACAGCAACGTTAATGTGAATTCAGCTCCCAGAATCACACCAAACGGATCACCGCCCCGATTTAGCGCGAGATACAAAGGTGCAGAATTATTTGTCAGAAAACAAAATAACATTTATCAACCCACTGTGCCATCGATCACTAGCTCGTCTACAACACCAGCTACAACCGTAGAGAACTCTGGTTCGGCACCACCGATCGATGTCTCGAGTCCTGGCGAGCCAAGGTTCTTGACCCTTTATCACGCGTTGGAGTCGGCAGACATCAGGAACGAATTAGAAGCGAACACGAGCGTACAGGCCGACAGGGTTCTCCAGGTAGACTCTAACGCCACTGTCGCTAACGACAACAGCAGTAATTCTAACAATGACACCACAAGCCCCTCCGTAGCGACCACCGGCCCACAGACCCCAGACACCACCGCGAACACTACTCTGACCTCGAGATTATCCGAGGATACGGAGAACACCACCCCCGCGGTTACCACGGGAGTCCCTGAAACCCCTGCGACCACCGAACAACCCTCTAACGCCGAACAACAAGCCTCCAGCACGGAATCACCCTCTACCGAGCAACCTTCCACCAACGCAGTTTCCATGTCGCCACCTGAACAAAGTAGCACGGATGCGCCGACTACGACCGTCGGAAACTCAGAAAGTAGTCAGATACTCTCGACGACTACCACGGAAGTTCCTACCACGACAGGGTCCAGTACCGAAGCAAATGTGCCTAGTACGACCGAGGCCGCGTCGACCACTCAAGGTGCGCAAGGTCTGACGGAGAGTACCACGATGGCTGCCGTCAGCGACGCCGCGAGTATGTCCGAAAGTCCGGAGAGCAATACTATACCGTTCTCCGAGACGCCAGCCACTCAGTCGACCGATTCGAGTTCGACCGATGCCCCCACGACCGAGGCCATATCGAGCAATATGGTGGATGCGGAGACAACTACCGTGATACCTACCACCACGTCGCGACCTAGACTGATCGATTTAGCGCAGGATATTCTGTCCCGTTTGCAAGCGTCTCTGAACGTTACCACGCAGCCGAGTGTAGACTCCACGACTATACCTCCAACGACCGAGATATCGAACGCGATATTAGATATTAGATTCGACGCGAACAATACCCTGCAGAGTCTGTCGCAGTTGAACGAAACGGGAACAGCTGAACCGGCAACCACCGATGAAACCACTACCCAGAGCGCAGTAGGCTCAGTCCCTACTACGACACCTGCGACCACGAATGACCCGTCCAGCTCAATGGTATCTACCCAAGAAGCCAACACGCTGGACGAATCGAGTCCAGTTACAACCACCACACCAGTAACACCACAAGACTCTCAAACAGTTCCGAACACAGAATCGACCACCGTAGGCGACCCCAACAGTTCCTCCAGCCCTCCGTTAGACGTTGATGCGACCACTGCGTCGACGGTTACCACCACGAACGATACTTTACTGACAGAATTAATGTCCATCGCCAAGACCCTCTTTTCGGAAGAGATGAACGACACCGAAACATCGGTACCTGTTCAAACGACGACCGATGTTTCTGGCGTGTCAGGCACGATTCAAGCCACGGAATCGTCGTCGATTTCGCCGGATGTCACGACAGAAACCGTAGAAGCAACTCCGACCACTGTAACTATGTCTGACGTTACCACATTTTCGGTCGATCCCTCGCAGAACGAGGTGGACTCCACAGACCCCACCGTGACCGTTTCGTCTACGGAGAGTTCGACAGACACGCCCAGTACAACTCTAGTGAATAACATGCTCGACAACCTGGTGGATGTCGCGCGAACGAACGACACCGCAACGTTAGGAACACCCCTCGCCGAGAACGTAGAGTCGACCACCCCCTCGTTAACGACCGAAAACGAACAAACGACCCTCTCGATTAACGTATTGTCCAGGCTCGAAAGTGGCCCGGACACCACGACTCAGTTGTCGACAACCACACAAAACACGGAAACGACAGTCGCATCCACCGCCATTAATTTTGAACTAACCACTAACACGTTCGATTTGATATCGACCGACTCGACGACGACGACGACGGGGCCGCAAGCGGCTCCCGAACTTACAGAAACCACCACACCATTAACCGATCTCACGACCGTAACACCAGAGCTTTCGCCAAACACTAGCACTAATCAACCCGAAGTAACCACGATTCCTGAAACAACTCAGTCCACTGTAAATACGATGAGCACGCCGTTGCCCGAAATGATAGTCGAGCAAACCACGGTGGTGTCCACTACAGAGTCGATCCAAAGCGTAACAACCGACGTGACAACCACGTCGCCGATCACGAGCACTCCGCGATTGGACGTTAACCCGATGGACGACGCTGAGGTCACCACCAGCCAGACCCCGCTAACGTCCAGCCTAGAGTCCATTGTGGAAACCACTACTAATACGCCCAGCGAAACAACAAACCTCCCCCAAACAACCCCGACCCTCGAGAACGAAACTCCAACTGTTGTTGCCCGTTTCCAGGATACGACATCAGCAACCGCCCAAGGGACGGCAGGTTCAGGAATCGGCCAAACGACCGAGAACACCACTCCCATGACCATGATACCTTCCACACCTTCTCCCATGCAATCCACCACCCAGTCTCTCGTTTCAACCACTTCATCTTCGGTCGAGACTACGACTACGACGCCGACGATGACTACGACGACGCAGACAACGACGAAAATCGGACGCGTTCCCGAGCTCGCAACGACACAGTCGAGCATGGGTGTCGTCACCGTCACGCCGATGCCCGACACGACGGTTCCTACGACGGTCACGGGTGCCGTAGAGGACAATCTCGTTTCCACCGAAGCTGGGACAACGATGCAACCTATGGGACCCATGAACGCAACGATGATGACCATGAACGCAACCGCCGCGAACACAACCGCCGAAACGACGACCCCGTCGATGCAAACCACTCCTGCGACTTCGACGATGGCTCCGTCTTCTCAGGCTCCCACGACGGCGTACATGGGTCGATTCGGGGGCTCCAGGTTGACGCCTGCCCCCAGGTTCAGCCTCAGCTCCACCACCAGAGCTCCTCTGCGGGACTATCTGGTCTACGGGATATATCCTAACAAAACGATCGTTAGGAAACGACCGGAGGACAACCTGATCGACGCTAGGAACGTGGACAGCCCGTACGTGATATTCGGTATCTTCCCGGATGGCAGGCTGGTCCGGAAATTCCCGAACGGAACGATAATACCGGACCCACCTAGGAGCCCCGTCGAGGTTGTGTTCTCACTTAGCACTACCACTACCACTAACAGGCCACCACCCAGACCGTATTATAACCAGGCTAACCAAGGCGTTTACAATCAGTATCAAGGCCCGGTGTACAGTAATATTCGTAGACCTGAGCCGATGAGAATCGTCCAAAGTCCCGGCACCGTTGACCTCGGCCTTACTGGTAACGCGATCGTCGGCCCCAATGGAGGTGGACCCGGTTTCACGGGGCCACTTGGTACCCCTGCTAGCCTCCCGAGCACCAACGAAATGAGCAATGCCCTGGTAAATACGCAAATGGGGACAGCATCGGTGACGCCGACAGTAAGTACCGGTCGACCGCCGACCGTTTCGCAGGGCGGTCGTATCGTACAGGATCGAGAGAGGGACGAGGCCACCAGGACGAAAGAGGTCGGAGGTCAACGCAGCTCCGTGTACATCGGACAGGACAAGTTCGTCAATTATTGGACCGATGGGGCCTCCACCACCAACCCGCGTGTCCTCGGTGTCAAAATAAACTCGGTGGCTACCGGATCAAATTTGGGACCGTCGCCATCCGTGCCGTCTTTCGCAAATCTTTTGAACAATGAACCAGGAGGTCAAGTTACAGCTCCACCAGGATTCCCATGGAGGGATCCATTGGATCAAATTTTCGGTATTACTACCTCCTCGCCGATAATAACAGCTTCAGTTGCATCGAACTCGCTGGATGATTCTTCGGAATCGAGCAATCCGACTGCAGCAAGGCCGGTGAACCCATTCGTGGAAATTTTCACTCCACTTTCGAACGCGATTGGTATGCCAAGGGGAAATGGCGTGCTTAGTGTCACAGGAGCTGTTCCTAGTACGACGATGCAAACTACTCCTATTACTACTACTATGGCACCAACACCACCAGCTGCACCATCAACACCACCAGCAACACCACCACCACCTCCATCAACACCACCAACTACTACCGCAGCTCCAACTACAACTACACCACCTACAACTACACCACAGCCTACAACTCCTCAAACTAATGCTGCATCGCAAGCACCTCAGTCAACTCCTGGATCCACAGGACCTCCTTCGACAACACCGACTAATTTGCCTGCAAACTTGTTGAATAATATGCAACAGCAGAACGCATTTGGAACGTCGTTTAATGACCTGGTGTTCCTGAATTCGTTGTTGCAGGATAATTCTCGAGGATCTAAAACAAAGACGCTGACCCAAGTCGAGCAGCTGTTAGCCAACAAGATTTTGTCCCTGGCACTGAACGGCCCCGACCCAGGCCCAACCCGCGCCCCAAAGGCCATCAGCTTCGAGAACGCCTCTCCGAATTCCGTCTACCAGTCTCCAAAGTCCTACGAGCCGATAGTGATCGATTTATCCCCATCATCGACCGCCACGTCGCCAACGTGGAAACCGACCCAGCAAACTAGTCAGAAAGCGCCCATTAGTTCAACGACGGAACAAGTCACTCAGACCTCGATTTCGACCACGACCGCGAAGAGAGACATCATCACGAGCGCTCCTTCGACGACTGACAAAACCACCCTAATAAGCACCACAAAAGTCCCAGTCTCCCCTAAAACAGTGACTCGGCCCAGAACCACCACTGAGGCTCCCGTGGGTTTAGCGGGACTCTTGTGGCAAACTCTTCTGGGCGGAGGACTTTTTGGGCCATCGACTACTGAGAGACCTTTGAGGACTAAGCAGGTGAAGACTGTTACGAAGTCTGTGAACATCACTCCGAAGCCGATACCAACTACGCAAAGACCGACGACGACTAGTACCACTACCACAACTACCACCACGACTACCACAGCTCGTACTACAACAGTCAACACGATTGATATCTCGAAGATTCATGTGAGCACTCCGAATTCGATCGGAGTAGAAAAGAAGGCTGCTACGCCGGTTCCACTGTTGTCGACGACGAAGAAGTCGTTGCTGAATAATCCGAACCCCAGGTTGTCTGTTCCTACTTCCACTTTCTCTCCTGAAGAGGAGACCAGGTTCTTGCTGTCGATACTGAGAGCCGCTCAACAGGATGAGAAAGCTGGCGGTTCGAAAAATTCTCTGGACGATGAAGCCTTCTTGAGAGCAATTTTAAGCGGACAGGCTTCCCCGACAAGTACTCCTCCTCCGCAAACGGAAATCAGCAACGCTGCTCTGTTGGCAGCGTTGTTGAAGGCTCAAGGCATCGAACCCGAAACGCCTGCTACTAACATCAGGGAGCAATTGCAGTTGGCTAGCCTCGGCCAGAGCGTCACCTCTGCTCCGAGCTTATCCCCGGCTAGCAGCGGGTCTACGACAATTACAACAAGGCCGACTTCGACTGCGACTCGAGCCACGGATACGACGAAAAACACGGTGACACCGAGACCAACCTCAAGACCAAGGGTACGCACAACAACGTGGTCGCCGAGCTCCACGTATCCACCTCCTCTCTTCAGCTCCTTCTCCAATTACGCTACACCGGGACAGTCGGCTGCCGCTGGCAATTCGGATAATGGCGCGATATTTGGTGCTACCAGGGCGTTCAGTCAATTCCTCGGTGCTGCATTAAGCGGAGCGGCACAACAGTTGCAGTCGTTAGTGAGAAATGGTACTAGGATCGTGTCCGAAGTAGTGGGATAAAATTAGCAAGAAAATAATAAAAATTTTTCGCGTAATCCATAGAATAAGAGAAGCGATTCGCGAGCATGAAAATCTGGAATGAACAAGCTGGTGGTAGCGATGCTTCGAAATAAGTATTCTTTTAGATATTCATTAAAAGTCAATCTGTTTGCTCGATGTTGAAGAGAAACTTCTCGAAATTTCCTCCTCCTTTTTTTATGTATAGATCGTAGCGTTACGCGCAGATAGTTGTTGGGTGATTATGTATTTTATTTTTATTGTACGTAGCTGATAACGGGACGTGACGTGACTCGATCGTTCATTCTTAAAACATGAAGAACGTATTTTATAATAATTCATTTTCAACTTTTCCGAAATATAATTTAGTAACTTTTAATTTTCAAGTTTGTTACATTTTGAGGAAGAGAGATGTAAAAGTATTAACAGTTGAAAATTTAGAAATATTGTAATTTTAATTTTCTATATTGTTTACTTATAAGTTTTTATGAATGTAATTCAGAGCTTCAGAACTTTATAAATTTATAAATTGAGAAATGTAATAATTTAGTGAGTGATTTAGTTTTAATTGAGTGATTTAATCTTCATGTTTTAAGAGTTGAGCGATGCCCGTCGACAGCGATGACGAAACAATTCGGAAAGTGTGGAGTTTCGTTCCGATTCGCGACAGGAGTAACGACTGGACGCCTTGCAAACGTTTCTGGGGTAGGAGCGACCGATGGCTCGTACCACTTTGAAACATTTGTAACGTTGGTCGCAATTAAGGTAATTAATCGAGGGCGATGCGGCTCGTCACGACTCTCTGGACAGTGACGATCCGCGGTGTCTTCGCGTGAAAGAGGGCGTTCCGACTTCTGATGCCCACCCACAAAGATCGATTTAAGGGTCCAGTATCGTGGACCTCTTCCGGGAAAATCGAAAAGCCGACTTCATTTCTTCTGCGATAAAAGCAATTTAACTAATGTATGATTATCAAGCGAAACACCTCGTACTGTCATTCTCAAAATATTC
->OQ027676.1 Uncultured bacterium clone 703 16S ribosomal RNA gene, partial sequence 
-TGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCGACGCCGCGTGCGGGATGAAGGCCTTCGGGTTGTAAACCGCTTTCAGCAGGGACGAGGCCGCAAGGTGACGGTACCTGCAGAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCGAGCGTTATCCGGATTCATTGGGCGTAAAGCGCGCGTAGGCGGCTTGTTAGGTCGGAGGTTAAAGACCGAGGCTCAACCTCGGCACGCCTCCGATACCGGCAGGCTTGAGTGTGGTAGAGGAAGGTGGAATTCCCAGTGTAGCGGTGGAATGCGCAGATATTGGGAAGAACACCAGCGGCGAAGGCGGCCTTCTGGGCCATTACTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACAGG
->XM_035742444.2 PREDICTED: Oncorhynchus keta protein phosphatase 2, regulatory subunit B', gamma a (LOC118362247), transcript variant X2, mRNA 
-CGCTTCATTTTCTCATCTGCTTTTGTGCTAAAATGGAGGCTGGCCCCTTACCTTAAGTGGATTGCCTTCCTGGTCGAGTTTAGATGTTGACATGCAATAAAGCTGGAATCAGGATGGTTGTGGATGCACCTAATTCCAATGGGCCTTTCCAGCCGGTGGCTCTTATGCACTTCAGAGACTGTGCTCCGGCAGAGCAGGAGAAGCTGTTTGTGCAGAAGCTGCGCCAGTGCTGCGTGCTCTTTGACTTCCTGTCGGACCCACTAAGTGACCTGAAATGGAAGGAGGTGAAGCGGGCGGCGCTGAGCGAGATGGTGGAGTACATCACGCACAACCGGAATGTCATCACAGAGCCCATCTACCCAGAGGTGGTGCATGTGTTTGCGGTGAACATGTTCCGAACGTTGCCTCCGTCGTCCAACCCCACAGGAGCAGAGTTCGACCCCGAGGAGGACGAGCCTACACTTGAGGCTGCATGGCCACATCTCCAGCTCGTCTACGAATTTTTCCTTCGGTTTTTAGAATCCCCTGATTTTCAACCGAACATAGCGAAGAAGTACATCGACCAGAAGTTTGTGATGCAGCTTTTAGACCTGTTTGACAGTGAAGACCCACGGGAGAGGGACTTCCTCAAAACAACTCTCCACAGGATATATGGGAAGTTCCTGGGACTACGGGCCTACATCAGAAAACACATCAATAATATATTTTATAGGTTTATCTATGAGACTGAGCACCATAATGGAATTGCAGAATTACTGGAGATACTTGGAAGTATAATCAATGGGTTTGCCTTACCACTAAAAGAGGAGCACAAGATATTCCTTTTAAAGGTCCTGTTGCCTTTGCACAAAGTCAAATCACTTAGTGTCTACCATCCGCAGTTGGCATACTGTGTGGTGCAGTTTCTAGAGAAGGACAGCACTCTCACTGAACCAGTGGTCATGGCCCTTCTGAAATACTGGCCCAAGACTCACTCCCCCAAAGAGGTGATGTTCCTTAACGAGCTGGAGGAGATTCTAGACGTCATCGAGCCATCCGAGTTCGTCAAGGTCATGGAGCCACTGTTCAGGCAGCTGGCCAAGTGTGTGTCCAGCCCACACTTCCAGGTAGCAGAGAGAGCTCTGTACTACTGGAACAACGAGTACATCATGAGTCTGATCAGTGACAACGCAGCCAAGATCCTGCCCATCATGTTCCCGGCGCTCTACCGCAACTCCAAGACCCACTGGAACAAGACCATCCATGGCCTCATCTACAACGCTCTCAAGCTCTTCATGGAGATGAACCAGAAGTTGTTTGATGACTGCACACAGCAGTTCAGAGCAGAGAAAAACAAAGAGAAGGCCAAGTCAAAAGACCGGGAAGAGGCTTGGATAAAGATTGAGAACCTTGCCAAATCCAACCCACAGGTAGTCTTCTAGGGTGGATGTTGAACAGTCCTAGCATAAGTTACGAACGAGAGACCAGAGGAAAGACCGGCCTATGAAGCGGCGTAAGTCTGATCTCCCTCAGGACATCTACACCGCAAAAGCCTTGGAGACCCGTCGCCGAGCCGACGTCATGATCACTACCCGCGATGGGCTCTAGGTCTGCCCCTCTCTCTCTCTAGTTTCCAGTCCCATCTTCTCTCTTTCCTCTAGTGTCCAGTCCCCTCTTCTCTCCACCCTCATCCACACAGCACATTCAGATTACTGGCCCAGTTTCCTCATCGTCGCCAGTACACAACCCCCTGGATTTCTGCTTTCTCAGGTGTTTCTTTTTGGGAGGGGTGGGGCCGCAACTTTCTTTTTTAGTCTTGCCGTCAATTTTTTATTTTTTTTTGCTTAATCGTGCATAACAGTATCGGCTCATCCCTCCAGGCTCTTACTGTACAAATGAAAATGGGGGAAGTTCCGTTCCACTAGCAACATGACAAGCTCCTATGTTCCCCCATTGAGCGCAGTTGGTAGAGAGCAGAAACAGAATGGGGGAGGCTCCTCTCGTTTCCTCTCATGTCAGTTTCTGTTAAGGGGAAACAAAACTAAGAACAGCCATTGTTGGATGGTGGGGGGTGATTGGATCGACTTTTCTGAAGTTTTGTTTCTTCTCTTTTTTTGTAATCCCAGGGACATTTGCCAGTGCCAAGACTGTTTGTTCTTTCTGTGTCTGTGTTTTTCTGTGTGAGAGAAACCAGGATGACTGACTATCTAGGTAGACAGCCTGTGTCGTTTGCCTTCGTTTTTTTTTTTGGAGCCTCAGATGATTCAAATGTTGTTTTTTTAATAAGCTGAAGAGCAACAGGACTTTCTGAAGTGACTGATCCATCTGTTCTGATGAAGTCACTTTATGACTAGGATGGGTGGCAGGACGGGAGGTTCTCTGTGGACACTGGACTCTTTACACCCTACACTTTGTGCCATGCACATTCTTTCGTTGGATTGATTTCCTTTCTGTTGAAGTCCATTGGCAATATGTGAGCCAGATCACAATGAAATATTGACAGTTCAAACAATGGTACTTATTTCATACGCAGAAACACATTGGGTGGTTGTTAGTCTGCACCCACTTTGTCATATTCAAAAGCCCTTCTTAGACATTTCAGTCTCCTTAATTCATACATAATGCATGTCCCCAGTTCTTACTGCTATTGGGAAGCTTCATTTAAATCTCAATGGCCAGCTAGGAAGTGTTTGGTTTGACACAGAGTCCATCAAGACACCTGTAGCCACACACACTGTAATGCTACGTTATGCAGAACATTCCACAAACGTTCCAACTGAAATTACATTATGACACTTTACCTGGGGGTGTCAGTTTGAGGAAGGCGAGGTGCAGAATTACTCATCTCGATCACATAATACGTTATGTGGGATGTAGGGTGATGTTGTAGAACTGTGATTCTGCACAGCCTGACTGTAATGAAGTCCTTCTCAAAAGCACACCTTGTCCTCAGATGCAGGCTTTTCAGAATCCCCGGCGCTGCTTGCTAGTCAAGCATGTTCCAGAAGTACACATGGTATCACATGCCCTGAAGCCCCCCCACACAGCGGTCTCACGTTTCCCCATGTTGGTTTTTACCAGTGCCCTCCTACCCAGAGGTGCTTTGCTGTGGAGCTGAAAGGACTGTTACGTGTCTTGTTGTGAAGTACTGAACAAATGGGGATCAGAGAGCCGTTTATGGAATGGCGGAATGCTACAGGATGAGAACATCAACACTGTTTGGATGACAACCGTTTCATGTGACAGTTGAATGAGCATTGGAAGAGGTGATTTCAAACCTGAATACCTCTTTGGATGATATCTGTAACCGTTGAGAATACGTCTATTGAAAAAGCACTTCCTGAAACTTGAAAGATGTGACATGTTTGTGTATCTTCATTGAAGCGCTCTTCAGTGTCCCGTTGAGTCTATATGTACAGTCTGCTCTGCTTTGTCAAGTTCAGGAAGCTGTCCATTTCCTGGACTGGACAAGGAAACGACCCATAAGTAAGCATTTCAGTGTTAGTCCACGCCTGTTGTTTACGAAGCATGTGACGAATACAATTTTATTTGATTGGGGCCCCATTGTAAATGTTAGTCTTTCTCTGGTACCATTGTTTGAACTTGCAAATCTAGTACGTGTATCCAATCTGTATTGTCTTTTCTGTTTCTAGTCTGGCAACTGGTAGCCTGGATGCTCATTTTAGCATTGTAGCTGCCAATGGAAAGGGCCAATGTTGAAAGACTGGCATCCAGGCTTGGCTTGGTAACTACATTATTAATACTTAAATGCAAAAAGGTGTTCATTTAACTACCATGTATCTTTTGTCCTGGACGAATGGCACTCGCCGAAACAATTTGACCCCCCCCAAAAAAAAAAAAAAAAATCTTCACTTTTATATAACAGTATCATTTGGAAAGATGTTTGATCAGTTTGCTTTTTATTTGTGTTCAAACTTTTTTTTTTTTTTAGACACATCAATTACTCGTATGACAAGTTAGACAACAAATGTTTTGGATTGTTTTCCAGAATTGTTTGCTTGGCCTCTGCAGGTTTTTAGTTAGAACATGTACTTTCCAGAATATAATAACTTGACAAGTGTCCTTTTGTCTGTGATCTGTACTATGTGGCTTCATTTAATATTGTACATATGATTTACTTTGTTTTATGTAGTGTTATATCTAGATTAATTTTGTATAAAATTGTCCTCTGTACAGAATAAAACATCAATAGCAATGACAAAGAAGTCAATGTGGCACATAACTTCTCTCTCCCCTGTAACTTTCTGCATTATTAGAAATAACACATCTAATATTTTCTTTAATTCCCAATTATCTGTGACCAGATTTCAGTCCGTAGCCTTTTGTGTGCTTTTATCACAATCTCAACTGGTGTTCATCTGTAATAGAATGAATAAAGAGAATATTTGAATTTTATATTTTCAACCATA
->XM_023493610.1 PREDICTED: Eurytemora affinis uncharacterized LOC111718108 (LOC111718108), mRNA 
-GGCTCGTAAACTAGGGTTTAAAAAAGATTACTACCTGGAATCAGAGAACTGGTTTGGAAACACAACAAACATGACTTCAGATCAGATCCTTCAGGAGATAGTTCTGAAGAGGAATGAAGTGTTTGCTGACAACGATGCGATCAGAATCAAGACAGGGCAAGAGTATTGGAAGTTTTATATAGAGAAAGGGTATTACAGGTCACCAGGACCTGATTTTAGGTACTACTACTACGAGAGGCCGGATAGTAACATCAGTTCTCCTCTGTTTACGGAGAAGAATAAAAACTCTGGTGTCTGTTATAAGTTCCAGGTTCCAGAGTTTCTCTGGAAGAAAGGAGTTTCACAAATTTATATAAATACAAAGGTTAACACATTGATCGGATTCAGCCACTATGGCCAGAGGAGTGGAATTGACAATCAGGACAGGGTGTTCCTAAATACAGATGAGAAGATATATCTAATATTAACCCAACAGCACTTTGAGAGGATCCGGGTTCATGGAAAGCTCTGCAATTCAGAACTAAATACCGGGTTTGACAGTTGCAATGAGCAATGGCTTCATGATTACTCTGTGGCAGAGTATGGATGTATAAGTCCATGGAACAATGTTCCCTCCAACTACTCTGTGTGTAAGAATAAAACGTGTACTAGCGGAGTAAATGATATTGTTTTGAACTGGGTTAATGGATTCAATGATAGTATGTGTGGATCCCCGTGTGAGAGCTCGGAGGTGATGTTTGCCTCGCAGTTCTCCTACAAGGTGGAGGGGATGGGGTATGGATACCTAGCCATCACATTCAAACAATCTGTCAAGGTTACGAGGTCTTCTATACCCTACGGGTTTCTAGAGATGCTGGCTGAAGTAGGAGGATATGTTGGACTATTCCTAGGAGTCTCTATTCAACAACTTGTAGCCATGCCAGAGACCTTTATTGATAAAATATACAAAATACAGTTTTAAATATATCACCATCATCATACACTACACTAGTTAAACAATGATCAGTTTTTGGTAAGAAATATTTGT
->XM_035042612.1 PREDICTED: Populus alba uncharacterized LOC118036784 (LOC118036784), transcript variant X6, mRNA 
-AATCAGCTCGCCCATGATTCCTCACAACCACATCTCACCAACAAACCCTCAATATGCATTCAGCAGTCCAGTTCAGATGCTATTCATCAGAAACTATGAATATTTCTGCTGGTGCTAACAACTGTTCTGGTCTTGACATTATTATGGGAAGGGGAAGAAAAGAGGAGTACAAAATATTGAGGATGTTTACATCAAGCAGCTTTATGGGAGCCGAATCAAGTTCATATATCAGAGATGGCTTGAAGCTGCATTGATGAGAGTATTGACTTTGCAAATCGCTATTTAGAATGACATGATACATGCAGCACAGTAAAGACAACGTTTGGTTTGGACGAGTGGGTGATTTTAGAAAAAGAAAACAGGATGCTCGGACAGACAAAACATGCATGCTTTTCTGTCAGATTATATGCAAATCTGAACGACACCCTGTAAGATTAAAAAAAGAAAAAGCAAAGAGAAACTCGATCGAGAGTACTGACGAGCTGCCAGCAAGAGTACTAGTTTGAAAGGTCATGGATTGAATTTTTATTTTATTTTATCTACTGACTTGGAAAATTATGCCCAAGTGTCCAAGTCCTTTTGACCAAAAGACTCGCCTTTGAGTAAGTGGGCCATTGTCAAATTCGGACACCAAAAGGGAAGGGCTGAACTGTTAGATATGATGCCTCAGCTTCATAGAAGTAAGTTGATTCCCAAGTATTAATTATGCCGACTAGGAGAAAACCAAAGGAGTACTGCATGCATGTGAACTCTGGAAGAAACACATCTACACACGATAAAACCGCCGACGGCTATGGAGTGAACCCATTTCCAATCGGGCAGTGCCTATCACCTCTACCTGGAGAGTCTCCTACTGCCCATACTAAGCCGAAAAGAAAAGCTCCTAAAACTGCCAAGGATCTTGAAAAGAAAAGAGAGTACGACAGGGCATATCGGCGACGATGCAGGGAAAATAAAAGGAAAACTGAGCAAGAATTGTTTGTGCTCACAGAAGAGAATAAGAAATTAAATAGAGAGAATGACTACTTCAAAAGGGAAGAAGTTCAGCTGCAAGAGATGGTGCAATCTCAGAAAGACGAAATGACACTGCTACAGAATAAACTTCGCCAACAGAAGGCCCAGCTTCAGGGGCAAAATGTAGTCGTGGATGTGCTTTCGAAGAAAGTAGCTAGTATCGAAGATAATATGGATCCTCAGCGCGAAAATAAACGGCTGAAATTAGAAATGGATTTGCTGATTAAGAAGATTAACAACGATGACTATTTAAACCTCATTCAACCTCGAGAAAAAAACATGAAACTAGAAAAAGAGAAGAATGATCTCCAGTTGATTATTGATGCCTTATGTGCAAAGATAAACAAGGATAATGACCTCGAACCAAAGCAAGCATCCTAATTAATGTACTGAGCTACAAAGTAAATGGACAGAGGAGGTGTTCTGACAGGAGAATTAAGAGGCTACACGAATTTAAATACCCAAGGATGTGACCTAATGTGTTCTTAGAATTGCATGACCTATTATATTGACCTAATCATCATGTATGAAGGGTGTTCTTAGATTTTAGCAGCAAAAGTATCAAGAAGTAAATAAATAAATTGGTACTTGGAGGTTTTGATTTGCCTTTTAAATTGGTAATCTCTCTTGTACTTAGTGTATGTAAATCTCACTGGTTAAGGCCATCTTATAAGCCTACTAATATCGCTCATGAGCACCGGTCTCCCCCATTTGATGGAGGAATAAAATTGACAGTGGTGGAACCAGCAAGATGAATGATCCGTATAGGGATATTTCCTTGGGGTATTTCATGGCAGGATTTGCAGCTGGATTGGCTATGGAATTTGGGAATCAGATGTTTGCATCTTGAAGTAGCTTCCAAGTGGTTAAACATGTTTTGGCAGATGATCAAGGACAGGGCAGGCCCTTATGCTATTTTTCCAAGATGGGTATAAATCTTCCACGCAGCGACTGGAGGGCAGAAACCTCTCCAGTGTAGGGGGGGTCTAGCTCATGTTCTTATAG
->XM_011946569.1 PREDICTED: Colobus angolensis palliatus RIB43A domain with coiled-coils 1 (RIBC1), transcript variant X2, mRNA 
-GGAGTTGGTGCTGGGCGGAGTCAGAGCAGCTCTTGAGGGTCAAGGAGGCGGGGGAGACCTGAGTTCACGCTTGCTGAGACAGAAGTCACAGCAGGATTATGCCCCTCAGGGCAAGAGGAAGGTGGGAGCTCGGCTGTGGCTTTAGCCTGGCCAACCTTCAAGGCTAGGACAAGGACAGGGGCGGGAATTGGAAAGACCCGGGGGGAGCGGAGGGCTGGACGAGAATGAGGGGCCAACGGGAGGATTCAGTGTTAGAGTTCAGAAACTGCCGCTGTAACCCAAGAACAAGGTTGCATGCAGAGCCAACCTAAGAGCTTCAAAATCGGGATTCCTTACTGAGAAAGATGTATAACATAAACCAGTCAACAGATACCAAGGAAGCAGCAGCCATCGAGGCCAGAAGAAATCGAGAAAAAGAGCGACAAAACCGATTCTTCAATGTGCGGAACCGAGTCATGGGGGTGGATGTCCAGGCCCTGAACAACCAGGTAGGAGACCGAAAGCATCAGGAAGCAGCAGAAAGAAGCAAGGAGGCAGCTTATGGTACCAGCCAGGTGCAGTATGATGTGGTAGTCCAGATGTTAGAGAAGGAAGAGGCAGATCGAACACGTCGGCTGGCCAAGAAAGTCCAGGAGTTTCGGGAGCAGAAGCAGCAGCTCAAGAACGGGCGTGAATTTAGTCTTTGGGATCCAGACCAAGTCTGGAAGGGGCTTCCAACCTATCTTAGTTACAGTAATACCTATCCTGGTCCAGCCAGCCTGCAGTACTTCTCTGGGGAAGACCTAGACAGGGCCACACGGCTGAGAATGCAGCAGAGGCAGTTCAGGTACAACTTGGAAAGGCAGCAGCAGGAGCAACAGCAAGCCAAGGTTGATGAGAATTGTGCAGATGCGCTCAGTAACCAGCTGCGCCTCGCCATGGACGCGCAGGCCACCCATCTGGCCAGGCTGGAGGAGTCTTGTCGTGCGGCCATGATGTGTGCCATGGCCAATGCCAACAAAGCGCAGGCAGCTGTGCAGGCTGGGCGTCAGCGCTGTGAGCGTCAGCGTGAAAAGAAGGCCAACCTTGCAGAGATCCGGCACCAGAGCACAAGTGACCTACTGACTGAAAACCCCCAGGTCGCCCAACACCGTACAGCTCCCCACCGGGTCCTGCCCTATTGCTGGAAGGGCATGACTCCAGAGCAGCGAGCTGCCATCAGGAAAGAGCAGGAAGTACAACGCTCTAAGAAGGAAGCTCACCGTCAGGCTGAGAAAACACTGGATACTGAATGGAAAAGCCAGACCATGAGTTCAGCCCAGGCATTGCTGGAGCTAGAAGAGCAGGAGAGGGAATTGTGTGCTGTATTTCAAAGGGGTCTAGGCTCTTTCAACCAGCAGCTGGCTAATGAGCAAAAAGCCCAGCAGGATTACCTGAATTCAGTAATCTATACCAATCAACCTACAGCCCAGTATCACCGGCAGTTTAACACCAGCAGCCGCTAAGTTCAGGATGTTTATCTCTTCCTTCTCCTCCATCAAGCTCACAGGCAGTTAGGAGTCAAAGAGAAAAATGCTGCATACTCCCACCTTCTAACCTAGGTAATAAAGTTCTTCACTCAAAATCAA
->HM954641.1 Uncultured Sphingobacteriales bacterium clone GG5QJA201E0Q5R 16S ribosomal RNA gene, partial sequence 
-TAAAGGGATACTTCTTCGGACAATATACAAGGTGCTGCATGGTTGTCGTCAGCTCGTGCCGTGAGGTGTCGGGTTAAGTCCCATAACGAGCGCAACCCCTATCATTAGTGCCATCAGGTCAAGCTGGGGACTCTAATGAAACTGCCTACGCAAGTAGTGAGGAAGGTGGGGATGACGTCAAATCAGCACGGCCCTTACGTCCAGGGCTACACACGTGCTACAATGGCCGGTACAAAGGGCAGCTACCTGGTGACAGGATGCTAATCTCAAAAGCCGGTCTCAGTTCGGATCGGAGTCTGCAACCCGACTCCGTGAAGCTGGAATCGCTAGTAATCGCGCATCAGCCATGGCGCGGTGAATACGTTCCCGGGCCTT
->JN110382.1 Trichosporon asahii strain f2fp12 26S ribosomal RNA gene, partial sequence 
-ACGGCGAGTGAAGCGGGAAGAGCTCAAATTTGAAATCTGGCAGTCTTCGATTGTCCGAGTTGTAATCTATAGAGGCGTTTTCCGTGCCGGACCGTGTCCAAGTCTCCTGGAAAGGAGTATCAAAGAGGGTGATAATCCCGTACTTAACACGACCACCGGTGCTCTGTGATACGTCTTCTACGAGTCGAGTTGTTTGGGAATGCAGCTCAAAATGGGTGGTGAATTCCATCTAAAGCTAAATATTGGCGAGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGATGAAAAGCACTTTGGAAAGAGAGTTAAACAGTACGTGAAATTGTTGAAAGGGAAACGATTGAAGTCAGTCGTGTTCTTTGGATTCAGCCAGTTCTGCTGGTCTACTTCCTTGGAACGGGTCAACATCAGTTTTGTCCGGTGGATAAAGGTAGTAGGAATGTGACTTCTCCGGAAGTGTTATAGCCTATTATCACATACACTGGGTGAGACTGAGGACTGCAGCTCGCCTTTATGGCCGGCCTTCGGGCA
->XM_022629730.1 Penicillium arizonense hypothetical protein (PENARI_c005G05025), partial mRNA 
-ATGGCCCCCGTGGAAACACAGCAGTATGATTACATTGTCCTTGGCGGTGGTAGCGGTGGCAGTGGAAGCGCTCGCCGTGCAGCCGGTTGGTATGGTAAAAAGACCTTGATTGTGGAAAGTGGACGGTCAGGAGGTACCTGTGTCAACGTTGGTTGTGTGCCTAAGAAAATGACCTGGAACTTCGCAACCATTAACGAGATGCTGCATGTTGGCAAGAGCTATGGCTATGACATTCCTGATAACATCGCTATGGACTACACCCACTTCAAGAACACCCGTGACGCCGTTATTAAGCGGCTCAATGGCGCATACGAGCGCAACTGGAACCGGGAAGGAATTGATCTCGTGCAGGGTCGTGCAGGCTTCGTTGAGCCTCAAACCATTGAGGTCAAGCTAGCCGACGGCTCCGGTTCTGCCCGCTACACTGCGCCGCACATCCTCTTGGCCACCGGCGGCCGGCCCAACATCCCCTCCGTGCCCGGTGCCGAGCACGGTATCACTAGCGACGGATTCTTTGAGATGGAGGATCTTCCCCCGAAGGTTGCAGTCGTGGGTGCTGGCTACATTGCTGTCGAGCTTGCTGGCGTCATGAACGCTGTCAATGTCGAGACCCACATGTTCATTCGCGGGGAAACCTTCCTCCGCAAGTTTGACCCTATGATCCAGAAGACCATGACCGATCGGTATGAGGCTTCCGGTGTCAAGCTTCACCGTAACCACTCCGGATTCAAGGAAGTGCAACTCATCCGTGACGGCAAAGGCAAGGATAAATTGCTCAAGCTCATTGGCCATGACGGCTCTGAGCTTGAGGTGAACGAGCTGCTCTGGGCCGTGGGTCGTGCCCCCGAGGTCGAGGACCTGAACCTCAATATCCCCGGAGTCAAGCTGAATGCCGGCGGTCACGTTGTGGTTGACGAGTACCAGAACACCTCGGTCGAAGGTGTCTATGCTCTTGGTGACGTGACAGGTCAAGCCGAGCTGACCCCAGTCGCCATCGCCGCCGGTCGTCAACTCGGCAGCCGTCTGTTCGGTCCCCCGGAGCTCAAGTCATCCAAGCTTTCATACGAGAACATCCCTACGGTCGTCTTCTCCCACCCCGAAGTCGGCTGTGTTGGTCTCACGGAGCCCGAGGCCCGCGAGCGCTACGGTGATGACAAGATCAAGATCTACCACACCAAGTTCACGGCCATGTTCTACGACGTCATGCCCGCCGAGGAGAAGGCTAAGAATCCGACTGAGATGAAGATAATCTGCGCCGGTCCCCAGGAGAAGGTTGTCGGTCTCCACATCTTGGGCCTCGGTGTCGGTGAGATGCTTCAGGGCTTCGGTGTCGCTGTCAAGATGGGCGCCACAAAGCAGGACTTTGATAGCTGTGTTGCTATCCACCCTACTAGCGCCGAGGAGCTGGTGACGATGCGGTGA
->AF339527.1 Harposporium helicoides strain Arsef 5354 large subunit ribosomal RNA gene, partial sequence 
-AAATTTGAAATCTGGCCCCCCCCGGGGGGCCCGAGTTGTAATTTGCAGAGGATGCTTCTGGCGCGGCGCCTTCCGAGTTCCCTGGAAAGGGACGCCACAGAGGGTGAGAGCCCCGTCTGGTCGGACGCCAAGCCTGTGTGAAGCCCCTTCGACGAGTCGAGTAGTTTGGGAATGCTGCTCAAAACGGGAGGTATATGTCTTCTAAAGCTAAATACCGGCCAGAGACCGATAGCGCACAAGTAGAGTGATCGAAAGATGAAAAGCACTTTGAAAAGAGGGTTAAACAGTACGTGAAATTGTTGAAAGGGAAGCGCTTGTGACCAGACTCGGACCCGGCGAATCACCCAGCGTTCTCGCTGGTGCACTTCGCCGGGCCCGGGCCAGCATCAGTTCGCCGCGGGGGACAAAGGCGGCGGGAACGTGGCTCCCCCGGGAGTGTTATAGCCCGCCGCGCAATGCCCTGGGGCGGACTGAGGTTCGCGCTCCGCAAGGATGCTGGCGTAATGGTCACCAGCGACCCGTCTTGAAACACGGACCAAGGAGTCGTCTTCGTATGCGAGTGTTCGGGTGTGAAACCCTTGCGCGTAATGAAAGTGAACGCAGGTGAGAGCTTCGGCGCATCATCGACCGATCCTGATGTTCTCGGATGGATTTGAGTAAGAGCATACGGGGCCGGACCCGAAAGAAGGTGAACTATGCCTGTGTAGGGTGAAGCCAGAGGAAACTCTGGTGGAGGCTCGCAGCGGTTCTGACGTGCAAATCGATCGTCA
->XM_024173345.1 PREDICTED: Morus notabilis allantoinase (LOC21397670), transcript variant X1, mRNA 
-GTTCATGAACCTCTCCACGACACGAGCGAGATTCTTCTCTCTCTTTCTCTCTCTTATTGGTCAGTGTAACGCATAATATTAGAAGTAGATGAAGAAGAGAGAGAATATGGAGAATAGGCTTCAATGGAGGCTCTTTCCCCTGCTTGCGATACTCGCTTCATATTTGGTCTTCTTCTACGTCCAAAACCATTCCGAGCTCTCACATAATAGATGTAGTCTGCTGCCTCACCAACACTATTGGATAGCTAGCAAGCGGATTGTGATACCACAAGGGATTATATCTGGAGCAGTTGAGGTGAAGAATGGGAAGATTGTATCGATTGTCAAAGAAGAAGAAAGGTTGTGGAGTTCCAAGTTGGGGCAAGTAATTGACTATGGAGATGCGGTTGTCATGCCTGGCTTGATTGACGTGCATGCACATCTTGATGATCCCGGAAGAACTGAATGGGAAGGATTTCCTTCAGGAACTAAAGCGGCTGCTGCTGGAGGTATAACGACATTGGTTGACATGCCTCTGAATAGTTTCCCCTCAACTGTGTCTAGGGACACATTGAAACTTAAGATTAAGTCGGCAGAGAACAGAATTCATGTCGATGTTGGTTTTTGGGGAGGTCTTGTTCCTGAAAATGCGTTCAACCATTCCGCTCTTGAAGACCTCTTAAATGCTGGTGCTCTTGGTCTAAAGTCGTTTATGTGTCCTTCAGGGATCGATGATTTTCCCATGACAAACATTAGTCATATTAAGGAGGGCCTGTCAATACTTGCAAAATTTAGAAGACCTTTACTTGTGCATTCAGAGATTCAAAAAGATCTTGAAAGCCCTTTGGGACTCGAAGAAGATGGTGCCAATGACCCTCGTTCTTATTCAACATATCTCAAGACTAGGCCGCCTTCAATGTTGCTGAAACTTTCCAACTCTGTTTTTTTAACTTTTTGGTTCAAACACAGGGAGGAAGCAGCTATTAGGGAGCTCTTGACAGTGTCAAAAGACACGAGGATTGGTGGCCCTTTAGTTGGAGCTCATCTTCACATTGTTCACTTGTCTGATTCAAGTTCTTCCTTGAATCTTATCAAGGAAGCAAAACGTGGCGGTGACAGTTTGACTGTTGAGACTTGCCCACACTACTTGGCTTTCTCAGCGGAAGAAATTAAGGACGGAGACACTCGTTTTAAGTGTGCGCCACCCATTCGCGACGCAGTCAATAGAGAAAAACTGTGGGAGGCAGTAATGGAAGGACATATCGACATGTTAAGTTCCGATCATTCGCCAACAGAGCCAAAACTCAAGCTTCTTGAGGAGGGTAACTTCTTAAAGGCATGGGGAGGAATATCATCTTTGCAGTTTGTGCTTCCTGTGACATGGTCATATGGGAGAAAATATGGTGTAACATTGGAACAATTAGCTTTATGGTGGAGTGAGAGGCCCGCAAAGCTTGCTGGACAAGAATTAAAGGGGTCCATTGCAGTTGGTAATTATGCAGATATAGTTGTATGGGAACCTGAAGTAGAGTTCAACCTCAATGATGAATATCCTGTATACCTTAAACATCCTGGTATTTCTGCCTACATGGGAAGCAAGCTATATGGAAGAGTTTCGGCAACCTTTGTGAGGGGAAACCTTGTCTACAAAGAGAAGAACCATGCCACTGCTGCTTGTGGTGTCCCAATCCTCGCAATATAGAAGTTGCTGCACCATTGAACTCCTTTTGTTTTCCTCTTCTTTTTTTTTTTTGGTTTATGTTATGTAATTAAACATCGAGTTTGTTGTTTCTTTCTTAACATCATGTGAATATTATGTACATCTGTATAGTACACCACTTTTAAGTACTTTTTCTGTTTTTTCTTTTTTTTCAATACAATACGGAATCAAACCCGCACTCTCAATTGAAGCTC
->XM_016927369.2 PREDICTED: Pan troglodytes S100 calcium binding protein A8 (S100A8), transcript variant X2, mRNA 
-GAGAAACCAGAGACTGTAGCAACACTGGCAGGGAGAAGCTGTCTCTGATGGCCTGAAGCTGTGGGCAGCTGGCCAAGCCTAACCGCTATAAAAAGGAGCTGCCTCTCAGCCCTGCATGTCTCTTGTCAGCTGTCTTTCAGAAGACCTGGTTCTGTTTTTCAGGTGGGGCAAGTCCGTGGGCATCATGTTGACCGAGCTGGAGAAAGCCTTGAACTCTATCATCGATGTCTACCACAAGTACTCCCTGATAAAGGGGAATTTCCATGCCGTCTACAGGGATGACCTGAAGAAATTGCTAGAGACTGAGTGTCCTCAGTATATCAGGAAAAAGGGTGCAGACGTCTGGTTCAAAGAGTTGGATATCAACACTGATGGTGCAGTTAACTTCCAGGAGTTTCTCATTCTGGTGATAAAGATGGGCGTGGCAGCCCACAAAAAAAGCCACGAAGAAAGCCACAAAGAGTAGCTGAGTTACTGGGCCCAGAGGCTGGGCCCCTGGACATGTACCTGCAGAATAATAAAGTCATCAATACCTCA
->XM_050595833.1 PREDICTED: Cataglyphis hispanica C1GALT1-specific chaperone 1-like (LOC126851659), transcript variant X2, mRNA 
-TCGCGTTGCGAGAGTGGACAAGCGGCAGCATGCATATAGCATCTCCGGATGTCCACTCAACGCAGATAGTGCGGCCACCGTGAGGCTTTAGTGGGTAAAAATCTCACATAATCCTCGACTCTCCCCGAAGTCGAGGATATCTTTGGAAGATTTCCTCACGTAAAAAAAAAAAAGAATGCATTTATATACCAATCATACACATATATGATTGGTGGTGGAAGGGGAAGAGGGTTATGTGAGTTAGGTTAAGCAAACAGATGACTTGTTTATGTCACCTGTTGAATATTGTGATCACTAGCAAACACTACCGATTGATCGTCGCAGATGTATATAGGTGTGTTTATAATGTAAAAATGTCAGATATAGAATTTTACACAATTATGTAAACGCTTCAAAATATAATCTTCATGTTAATTCGTCGAATAATATTATAAATGATTTTGCGATGATTTCATCGCATATTTTTATCGATAATACAAGCGCAAAATGCATACTACAGACTATATACATCAACTTTACAAATAAGAGGATACATATAAATTTAAAGTATGCATAAGAAAAGATCTTAATGAGATAATTGAGTTTAACGAAGGTCAAATATAATGATAGTCAAAGAAACTTGTGATTGGCATTACTTGACTACTTGGCATTAGTGTTGAGAGAACTGGATTGTTATTATGTATTTATCGAATTCAATTTTTACTGTGATGACAAGATGCGATTTCGATTTTTAAAACAGAGATCTATATTTCTGATTGGTTTGACAATTGGCTTTGTTTTTCCATTATTGTTATCTTTATTAAGGAATATATTTGTGATTGATTCGATGTGTAAACAAGATCAACCATTGTGGCAACCTGAATATTATCTGAGTAAGGAACCTCACCACGAAGAAATTATTTTACAGCATTGGGAAAAAGTGAAGAGATCTGGAAATTTTAATATCGTTACATACAACACTTGGTTGGCAGCACAAAACTTGAAACCATACAAACTTGATTTGGATAGATATCTATATCTCCAAAAAGGATACAATACAAGAAAAATTGAAAGCGAATGGAACTGGTTAAAAGAACGAGTATCTGTCACATGTATAGTTTTTGTAGAAAAACTCAAATTGGGGAAATCAATCCAGAATACATGGGGTAAACGCTGTAACAATATTTATTTCTTTGGACACCGTTTGAAAGACGATGAATTGCCTATTATAAATATAAATACAAAGATTGTGTCATCTTGGCAATTGCTGTGTGAAGCTATGAACTACATTTGGAAAAAAGAAGCAGACAAATTGGAGTGGATTATTTTCGTAAAAGATAATACTATAGTCATACCGGAAAATCTGCGCTATATGATTGCTCCGTTAGACCACAGAGATGATTACTATCTGGGTCATCCAATAGTTCTGTGGGGTCAGATTTATAACGTTGCTCAATCTGGATATGTTCTTAGTAAAGGAGCACTTGTTAAAGTATTACAAATGTTCAATACTACAGAAAAATGCATTGAAGGTGGAAAATATTGGAAGAAGGAAGATTATTATCTTGGAAAACACTTATCGTTTTTGGGTATACGTCCATCTGATACCAGAGATCAGTATTTGAGAGGTACTTTTCATGGTCATTCTTTACAAAATCTTCTATGGGGTATTATCAGACCAGATAGCTACTTTACACATGCTGTGTATCCGACGAAAGGAGAATGCTGTTCACCGATATCTGTGACTTTCAGTGTCAGTGAACCCGACAAAATGCATATGTTAAATTATTTGCTATATCACTTGCATGTATTTAACAGTGAAAGCAAATTTGGCAATATATCCATCAAAATTCAAGTACCTGAAGACAATGTATGGAAGATTGCACTGCAGGAGGAATTCAACATCACACATTTGAACGATATATCGAGTGACGCTTATTACGAAATATGGCACTCGAAATATTCGGAACCTGGACAGCTAAGAATTGCTAAAAATTATCGAATGACGTCGGATGTACTAAACTGTTTATTGACGAACTACAAAACAGGAAACACGTCTGCGTATAATTGTAGAAGTAAAACAGTCGTCGACAGTACAAAAACCTAAGCCATTAAAACAGCTATTAAAACATTATTTAACAGCTTTATATTATTATTATCAAGACAGAAGATTTACAAAAAACCAATAGACGGTGAATATCTCCAGTCTTGTAATATGCGATTTTCTATACATAAAAATCACGTTATAAACTTTAACAGATAAGTACATTAATAAAGTTAATATTATTTGACCTAA
->XM_030571406.1 PREDICTED: Gopherus evgoodei complement factor H-related protein 2-like (LOC115655701), mRNA 
-ATGACGCAGCTTGGATATACTGCCATTCTGATATTATGGGCGTGCTCCACTGCATTAGCTATTTCATGTGGTAACATAGAAAATGGGAGGGTAAAGCCAAGTTTCTTCTTCCAGAGAAGAAAAAGAACATTTGAATGTAATGCCGGGTATATAGCAGAAAATGACAACAACAGAATTGAGTGTACTTCTTCAGGATGGGCTCCTGTACCCAGATGCATTCCAATACAATGTGGAAGGATAGAAAATGGGAAAATAGTGGACAAAGTTGAAGAAAAAACCACCTTTCGATGTGATCATGGATATAAATCTGAAAATGGAATTAATGAAACTACCTGTACCGCTGAAGGCTGGTCTCCAGTACCTATATGTATTGTTCAAGAGTGTTCGCATCCACCTGACATCGATTTGGCAGAAATTGTCAGTGGGGAGAAAGCAGAATATCAGGAGGGTGATGTTGTTCAGTACAGGTGCTACCCAGGATATACTTTGGCAGGATCTGAAAGGATAACATGCAATGGAGAAAAATGGACACCTCCACCAAAGTGCTTCGCTCCATGTATTATCACAAGGCAGCAATTAGAAACAAAAAAATTGCTTCTGTCTAATGGCCGAAGACGTACAGTATTGATTCAAAGTGACCAAACAATGGAATTTCTTTGTGGTGAACATTCTGACCTTAAAATCCCCTACTTCATCAAGTGTGTAGATGGGCACATGGATTTACCAACTTGTGTATCAGGAACTGGGGAAAAGTGTGGCCGGCCACCTACTATTGAGAACGGAGACATAACTACTTTATCCCTAAAAGAGTATGCATTTGGATCTTCGGTAGAATACAGATGCCAGCATTATTACATAATAGAAGGAGACCGGAAATCATACTGTTACAATGGAATCTGGACAAAAGTACCAGTTTGTTTGGAGCCATGTGTTATCACGCAAGAAGATATGAGATCACGCAACATAGATCTAAAGGGGGAGTCAGCTCAAAAACGCTATGTGTCACATGGAGATTTTGTAGAGTTTAAGTGTAGATCCAGTTGGTTTCAAAACTCTTCAAATAATTATAGAGTGCAGTGCAATGCGGGCCAAATACCTTATCCCCAATGCACTTAG
->XM_045878377.1 PREDICTED: Mirounga angustirostris ret proto-oncogene (RET), transcript variant X2, mRNA 
-CCAGACCCAGGCGCGCAGCAGCGGAGGGCAGCTGGAGTCCGCGCCCCGACGCTCTGCGCCCCCCGTGTCTCCCGCGTCCGCCGCGCCCCGGGCGGGCATGGGGCGGCCAGGCTGAGCGCCGCACCCCGCCGCCGACACCCCGGGCCCCAGCCAGCAGCCCTCTTGCCGCGGCCCCGGCGCGCACGGGCCATGGCGAAGGCGACGGCGACGGCCGGCGCCGCGGGGCTGCGGCTGCTGCTGCTGCTGCCGCTGCTCAGCGAAGCTCCGCTAGGACTCTACTTCTCTAGGGATGCTTACTGGGAGAAACTGTATGTGGACCAGCCAGCTGGCATGCCCCTGCTCTATGTCCATGCCCTGCGGGACGTCCCCGAGGAGGTGCCCAGCTTCCGCCTGGGTCAGCATCTCTACGGCATCGCCTACCGTGCGAGGCTGCATGAGAACGACTGGATCCGCATCGAGGAGGACACAGGCCTTCTCTACCTTAACCGGAGCCTAGATCGCAGCGCCTGGGAGAAGCTCAGCATCCAAAATGGCGGCTTCCCTGTGCTCACCATCTACCTCCAGGTCTTCCTGTTGTCTACGTCCCTGCGTGAGGGCGAGTGCCAGTGGCCAGGCTGTGCCCGGGTGTACTTCTCCTTCATCAACACTTCCTTCCCGGCTTGTGGTTCCCTCAAACCCCGGGAGCTCTGCTTTCCCGAAACAAGCGTCTCCTTCCGCATCAGAGAGAACAGGCCTCCTGGCACCTTCCACCAATTCCGGCTGCTGCCTGTGCAGTTCCTGTGCCCCAACATCAGTGTGTCCTACAGGCTCCTAGAAGGTGAGAATCTGCCCTTCCGTTGCGCCCCGGACAGCCTGGAGGTGAGCACACGCTGGGCCCTGGACCGCGAGCTGCGGGAGAAGTATGAGCTGGTGGCCGCGTGCACGGTGCGCGTCGGCGCGCGCAAAGAGGAGGTGGTGATGGTGCCCTTCCCCGTGACCGTGTATGATGAGGACGACTCGGCGCCCACCTTCCTCGGGGGCTTCGACACCGCCAGCGCTGTGGTGGAGTTCAAGAGGAAGGAGGGCACTGTGGTGGCCACGATACGTGTCTTCGATGCAGATGTGGTGCCAGCATCTGGGGAGCTGCTGAGGCGATACACAAGCACACTACTCCCTGGGGATGCCTGGGCCCTCCAGACTTTCCGTGTCGAGCACTCACCCAACGAGACCTTGACCCAGGCCAACGGCAGCTTTGTGCGGGCAACTGTGCATGACTACAGGCTGGTTCTCAACCGGAGCCTCCCCATCTCGGAGTGCCGCTCGCTGCAGCTGGCCGTGCTGGTCAATGACTCGGACTTCCAGGGCCCGGGGGAGGGCGTCCTCCGCCTCCACTTCAACGTGAGCGTGCTGCCCGTCAGCCTGCACTTACCCAGCGCCTACTCCTTCACTGTGAGCAGGCGAGCCCGCCGCTTTGCCCAGATTGGGAAAGTCTGTGTGGACAACTGCCAGGAGTTCAGCGGCATCCACGTGCAGTACAAGCTGCAGCTGTCCAGCACCAACTGCAGTGTCCTGGGGGTGGTCACCTCAGCCGAGGACACCACGGGGACCCTGTTCGTGAATGACACGGAAGCCCTGCAGCGGCTCGATTGTTCTCAACTCCAGTACACGGTGGTGGCCACCAACCGGCCAACCCGCAGGCAGACCCAGGCCCCGCTGGTCGTCACCGTGGAGGGGACGTATGTGGCTGAGGAGCCAGGCTGCCCCCTGTCCTGTGCAGTCAGCAAGAGGCGGCCTGAGTGTGAGGAGTGCGGCGGCCTGGGCTCTCTGACGGGCAGGTGCGAGTGGAGACAGGGAGATGGCAAAGGGATCACCAGGAACTTCTCCACCTGCTCCCCCAGCATCAAGACCTGCCCCGATGGCCACTGTGATGCTGTGGAGAGCAGAAATGTCAACATCTGCCCCCAGGACTGCCTCCGGGGCGGCAGCATCATTGGTGGGCACGAGCCAGGGGACCGCTGGGGGATAAAAGCTGGCTTCGGTATCTGCAACTGTTTCCCTGAAGAGAAGAAGTGCTTCTGTGAGCCTGAAGACAGCCAGGACCCGCTGTGCGATGAGCTCTGCCGCACAGTGATCGCGGCGGCCGTGCTCTTCTCCTTCATCGTCTCCATGCTGCTCTCCACCTTCTGCATTCACCGCTACCACAAGAATGCCCACAAGCCGCCCGTCGCCTCCGCCGAGATGACTTTCCGCCGGCCGGCCCAGGCCTTCCCAGTCAGCTACTCCTCGTCGGGCGCCCGCCGGCCCTCCTTGGACTCCATGGAGAACCAGGTTTCTGTGGACGCCTTCAAGATCCCGGAGGATCCGAAGTGGGAATTCCCTCGGAAGAACTTGGTTCTTGGAAAAACTCTGGGAGAAGGCGAATTTGGAAAAGTGGTTAAGGCAACAGCCTTCCGGCTTAAAGGCAAAGCAGGATACACGACCGTGGCCGTGAAGATGCTGAAAGAGAACGCCTCCCCAAGCGAGCTGCGGGACCTGCTGTCAGAGTTCAACCTCCTGAAGCAGGTCAACCACCCGCACGTCATCAAGCTGTACGGGGCCTGCAGCCAGGATGGGCCACTCTTCCTCATTGTGGAGTATGCCAAGTACGGCTCCCTGCGGGGCTTCCTCCGAGAGAGCCGCAAGGCGGGGCCGGGCTACGTGGGCAGTGGAGGCAGCCGCAGCTCCAGCTACCTGGACAACCCCGAGGAGCGGGCCCTGACCATGGGCGACCTAATCTCCTTCGCCTGGCAGATCTCTCGGGGGATGCGGTACCTGGCGGAGATGAAGCTTGTCCATCGGGACTTGGCCGCCAGAAACGTCCTGGTAGCCGAGGGGCGGAAGATGAAGATTTCGGACTTTGGCCTATCCCGAGATGTTTATGAAGAGGATTCCTACGTGAAGAGGAGCAAGGGTCGGATTCCAGTCAAATGGATGGCAATTGAGTCTCTTTTCGATCATATCTACACCACCCAAAGTGATGTGTGGTCCTTCGGTGTCCTGCTGTGGGAGATTGTGACTCTGGGGGGCAACCCCTACCCCGGGATTCCTCCGGAGCGGCTCTTCAACCTTCTGAAGACAGGCTACCGGATGGAGAGGCCCGACAACTGCAGTGAGGAGATGTACGGTCTAATGCTGCAGTGTTGGAAGCAGGAACCAGACAAGAGGCCAGTGTTTGCTGACATCAGCAAAGACCTGGAGAAGATGATGGTTAAGAACAGAGACTACTTGGACCTGGCCGCGTCCACCCCATCTGACTCCCTGCTTTATGACGACGGCCTCTCGGAGGAGGAGACGCCCCTGGTGGACTGTAATAATGCTCCCCTCCCTCGAGCCCTCCCCTCCACGTGGATTGAAAACAAACTCTATGGTAGAATTTCACATGCATTTACTAGATTCTAGCAACATCGTTCCTCTCTGCACTATCCTTACTCTCTGTAATGCTTTTTAAGAGTGTTTCTGATCTGAATGAAACCAAAGTTCTCCCTGAACCTTTTTATTTGTAAATGTCTGACTTTGCATCCGTTTACATTCGGGCATTTTTGAAACTATGTTTTTTTAAAAGGATGTGAAAATAAGTATAATTACCACACTGCCCGGCTACTTATGATTATGGAGAAGAAAGGGAGCTGGGCAGAACTCTCAGGGGATATTGAGAAGATGATAAATAAGTCGTCTCTGGGGTGGGTATGTATCAAGTCATAGTACTTCTAATTTAACTACTGGGATAAATTTACCCAATCTGGGGAGGCAGTTAATTGAGACAGGAGGAGCCAGCACCACCCTGCCTGCACTGAGGGCACAGCCTGTGGTCACTCCCAGACCCCATCTGGGCGGGCAGGTGGCTCTCAGAGGCCACTTGGTACTAGGGAGCATTGGCCCGCCCGGCCTGAGCCCCGCCCACATGCCCACTATCAGGGAGGACACCTGCAGACTGCTGTTTTCACATCCTTTGCATTACACACTGTCATGACAGTTGTCACTCATGAAGTCAGTGCTAAAAGCTGAAGCAAATGCTTTTGAAAGAACATAGTCTGTGGTGCTGTGGTCTTGCAATGGACAGTAAATATGGTTCTTGCCAAAACTCCTTCTTTTGTCTTTGATTAAATACTTGAAAATTT
->XM_028244121.1 PREDICTED: Camellia sinensis uncharacterized LOC114299398 (LOC114299398), mRNA 
-ACACCGACGACACGAGTCGTCGTCGCGAGTCGTGACTCATCTCATCTGCACTTCACAAGAAGTTAGTCACCAGACCCCCCCGTATGCACCATCATCAATCAATGTCTTTCCATGTATGAAACCCTAGCTTTGCAAAGCATTTTTCCTATTCAGGAACTAGGGTTTCTCTCTCTCTCTCTCTCTCTCTAAATTAGGGTTTCTATTTTTCTTCAGTCACTCTTGCGCGCTTTCTCTCAAACCCTCCATCGAATCAATTTTTTTTGTCTTTTCTTTTAATTTTATCGTTGTCAGGTAGTTTCCAGGAAAAAAAAATTGTAAATGCGAGAAATCGTAAGAAAGACGTTTTGACACAGCAGGTGCTTTCTTGGAAACCCCATCAAAGATTCCATCTATTTCCTTTCAATATCTTTGATGACAGTGAGGAGGAAGAGGAAAACACATGAAAGATTCGAGAATTTGTGCGAAAATTGTTGAAAAACCTAGGCACTAGTGTGAACTTCGATGGAGTCGACGCATGTGGTACTCGATATAAGCTCGGACGAAGATTATGATTATGATTGGATATCGGAGTTTTTGGACGATGCGGATGACTCTGATGAAGTGGTGGTGGTGAGTGAAGTTGTGGCGAATCACAAGCAGAGGTCGTCAAAGTCTTCTAGTGTTGCTGCTGCGAAGCCGAAAGATTTGGATGATGATTGTGTGGTATTGGAGGGTGATCCAGATAAACCGGTTGCGATCGAGATCGAGAACAATACGGAAGGTGATTCGGATGATTTGTCCATTGTTGGCGAGAAGGGGCAGATTGCTTGCAGAGATTACCCTCACGCTCGCCACCTCTGTGCTAAGTTTCCTTTCACTTCCTCTCTGCATGAGAGGCATTGTCCTCAGTGCCACTGCTATGTATGTGACTCACTTGCACCATGTGTCAATTGGGGCAATGGCACTTCCAGAAATGACCATTGTCACGCTACCGATAAAGATGAGTTCTGGAAATCTCAGAGGCAGAGTTTCAAGCAAGGGAATAAAGCCCCACTACCAGGTCCTAAATTTCCTGACACTTCTCGCTCAATTCGACCACCGCCAACAATCACACAGCTGCAACCAAAGAATCAGATCTCCAGGTCAGCCACAATCCGTGCTTGCTCTATGCCTACCAGTTTTGGCGTCCCAAATATCACAGATCAAGGCAGAAGCCAACAGTCTGTATATGTAAGAAACAAATTCCACCCAGATTTGGTCTCTCGGCAGTTGCTTAGTACCCGTAATAATATCATTCAAAGGGACAGAAGGTTTGGTAATTTAGGGCCTCCATATATCAATTCCCACACAATTTTCAAAAGGGCAGCAGGATCAACTAGAGTTGCTTTGGCAACAAATCGAACTAGATATGGCTCATCTGACAACAATTATGCAACTCAATTCTCCAGAAATCCCTCTCCTGTGGCAGCTTCAAATGATAACAATCCCACTAGGTGGCGAGACCTTTCAAGTGGAATGATTTCAGACTCAGAAGCATATCAGAACCTCTCCCAGCAAAACACTGGCAGCAGCTTGGAGAATTCAGTGCCTTCTCAACCCCTGTTATCCTCACATCCAAACATGGGCAGTGTCTTTCTGAATTCAGTGCCTTCTGGACCCCGACTGTCCTCCCAGCCAAACATAGGCTGCAGCTTTGTCGATTCAGTGCCTTCACCGCAAGTCTCTTCCCAGCCAAGCATGGGAAGCAATTTCGAAAATCCTTTGTCTTGTCAACCGCAAGTGTCCTCACGGCCAAACATGGGCAGCAGCTTTGTCTATCCTGTGCCTTCGCAACCCCAAGTGTATAGTAGTCAGCCTATTCCTGCAGCAAATGATGGCCAATATGGCTTCCAGCAAGGAAACGAGACTCAAAGTGCTGTGGATCCAAGTTTTTCAGATTTTGACTCAAGTTGGGTTGCCCCAACTGGCTGCCAGAGCAACCAACCTTTGGCAGATAATTCCCTATTTCAAATTCCAGGGCTGACTTATCATCATCCTCCTCTTGTCACAGGGTTTGATCCCCAGATTCCTGTAAACACAAATCCAGGCTTACCGGACTTCCAATTTGATTGGATGTTGGAGAATCAATCTTTTTCTGGGGCCCTAGAAGTTCCTGTTCCTTCTGGATGCAATGTATACTCTCCGGAAACTGCCCCTGTTGATGATGTTGCGTTCTTTGATTTCTAAACCTCCTGGGAGTAACCAACCCATGTAAAAAGCCCTCAACCCTGCAAAGAATGAAAATGGCATTCCATTCTTTGGATGATATAATAGGGATTATTAGTAATTGGGTTAAAACATCAACAGTAGAACAGTTGTACTGTACAGTATTTTTTTGTTTTTAATTTTAATATGAGGTACATACTCAAGTAGCCTTGTTTTTACGGTTGCTTTAGGGATGTAGGGTGCCGGTGATGTAACATTATATATGAAATTCTCAGATTGTCATTTTTCTATCCAATCATTTTAGGCTCTACTCAAA
->HM725485.1 Uncultured bacterium clone GB7N87003GN9MT small subunit ribosomal RNA gene, partial sequence 
-AGGACGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAGCGGGGTCCATCCAGTGGCAACACTGGTGAAGACCTAGCGGCGAACGGGTGAGTAACACGTGAGAAACCTGCCCTGAAGTCTGGGATAACCCGAGGAAACTCGAGCTAATACCGGATGTCCCCACCGAGCCGCATGGTTTGGTGAGGAAAGATTTATCGCTTCAGGAGGGTCTCGCGGCCTATCAGCTAGTTGGCGGGGTAACGGCCCACCAAGGCATCGACGGGTAGCTGGTCTGAGAGGACGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCAACGCCGCGTGCGGGATGAAGGCCTTCGGGTTGTAAACCGCTTTCAGTGGGACGAAAACGAGACGGTACCCACAGAAGAACGCCCGGCCAACTACGTGCCAGCAGCCGCGGT
->EF082344.1 Picea sitchensis clone WS0277_P22 unknown mRNA 
-CCCCCAAAAATGAAAGAAGCAGAGGAGAGGAGAAAGCAAGAGGAAGAAGAGAAGCAAAGAAGAGAGGAGGAAGAACGGCTCAGATTAGAAGAACTAGAAAGAGAGAAAGAGGAAGCAAAACGCCGGAAGAAAGAACGGGAAAAGGAAAAGATCCTGAAGAAGAAGCAGGAAGGCAAATTGTTGACTGGCAAAAAGAAGGAAGAAGCTCGTAGGTTGGCTATAATGAGAGAACAATTTCTTGCTCAAAGTGGGGTTTCATCCGATATCTCAAAGGAGGAAAATCATGCTATGCCCAAGAAACCAAAGTATGAAACAAAGAAGAAGAGGCATGGTCCAATTATTTCTGATGCTGTGGCAGTTGAGCCTGTTGAGATTCAGCCAGATGTGGAAATGAAAGAAGCAGAGGAGAGGAGAAAGCAAGAGGAAGAAGAGAAGCAAAGAAGAGAGGAGGAAGAACGGCTCAGATTAGAAGAACTAGAAAGAGAGAAAGAGGAAGCAAAACGCCGGAAGAAAGAACGGGAAAAGGAAAAGATCCTGAAAAAAAAAAAAAAAA
->KJ417285.1 Leucopaxillus eucalyptorum strain REH9110 voucher NYBG:01115433 18S small subunit ribosomal RNA gene, partial sequence; internal transcribed spacer 1 and 5.8S ribosomal RNA gene, complete sequence; and internal transcribed spacer 2, partial sequence 
-GAAGGATCATTATTGAATAAATTGAGTTGGGTTGTTGCTGGCTCTTAGGAGTAATGTGCACACTTGACATTAATTTTATTTTACCACCTGTGCACTTTGTGTAGATTTGGGGGAAACTGTATTATTGAGTTGTCATGTGTATATTTGCATTTGGCTCTCGTTGATATATTATTTTCCAAGTCTATGTATTTTATATACCCCTATAGTATGTCAAAGAATGTAGTGAAGGGCATGAATGGCCCTATAAACTTAATACAACTTTCAACAACGGATCTCTTGGCTCTCGCATCGATGAAGAACGCAGCAAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACCTTGCGCTCCTTGGTATTCCGAGGAGCATGCCTGTTTGAGTGTCATGAAATTCTCAACCCTACAAAGTTATTTACTTTGTCTGGCTTGGATTGTGGGATCTGCTGGCTTGTTCAGCTCTCCTTAAATGTATTAGCAGAATCTTATATGGGTCAGCTTTTAGTGTGATAATTATCTACGCTATAAAGTGACTTGTTTGTAATTCAGCTTCTAATTGTCTGATTTTTGAAGACACCCTATGA
->XR_007078499.1 PREDICTED: Homo sapiens uncharacterized LOC124906680 (LOC124906680), ncRNA 
-CTCATGGCGGCCTCTGCAGGCCCAGCTGTTCCTCCTGGCTGCATCTCTCGGCCCAGCTCCTGCCTCCCAGCAGGCAAGCTCTTTTGGCTCAGCTCCCTCCAGCGTTTGTAGACCCCGAAGTTTCTGCAGCCAAGCTCTTCAGGCCCACATCCTGCCTCCCGGCGGGCGCGAAGAGCTTGGCTCGAGAAAGTTCGGGGCCTACAAAGGCGGTTTTGAGCTGGGCAGGAGTTGAGCCCAAAGAGCTTGCTTACTTGCTGGGAGGCAGGGCCGGGAGACGCTGACTTCAGGACGACTTGGGCCTGCAGAGGTCGCCAGGAGGCCCAAGCTGGGCGCGGAGGAGCCCACCGACCGGAGACCGTTTGGGGCCTGGAGACGCCATCGGAGGGCAGGAGCTGATCCTGGAGAGGCCACCGTGAGGCCTGACCTGGGCCTGGGGAGCTTGGCTTGAGGAAGCTGTGGGCCGACCAAGGCCGCCAGGAGATGGGCAGGCGCTGAGTCCAAAGAGGTTGTTGGGAGGCAGCAGTCGGGCCTGGAGACGCAGCCGGGAGGAAGAGCTGGGCCCGGAGAGGACGCCGGGAGGCCGCATGTGGGTCTGGAGAGGCCGACTTGAGGAGGCCCGGCCTCTGCCTCCCTCAGGGCGGCCTCTGCAGGCCCAGCTGTTCCTCCTGGCTGCATCTCTCGGCCCAGCTCCTGCCTCCCAGCAGGCAAGCTCTTTTGGCTCAGCTCCCTCCAGCGTTTGTAGACCCCGAAGTTTCTGCAGCCAAGCTCTTCAGGCCCACATCCTGCCTCCCGGCGGGCGCGAAGAGCTTGGCTCGAGAAAGTTCGGGGCCTACAAAGGCGGTTTTGAGCTGGGCAGGAGTTGAGCCCAAAGAGCTTGCTTACTTGCTGGGAGGCAGGGCCGGGAGACGCTGACTTCAGGACGACTTGGGCCTGCAGAGGTCGCCAGGAGGCCCAAGCTGGGCGCGGAGGAGCCCACCGACCGGAGACCGTTTGGGGCCTGGAGACGCCATCGGAGGGCAGGAGCTGATCCTGGAGAGGCCACCGTGAGGCCTGACCTGGGCCTGGGGAGCTTGGCTTGAGGAAGCTGTGGGCCGACCAAGGCCGCCAGGAGATGGGCAGGCGCTGAGTCCAAAGAGGTTGTTGGGAGGCAGCAGTCGGGCCTGGAGACGCAGCCGGGAGGAAGAGCTGGGCCCGGAGAGGACGCCGGGAGGCTGCATGTGGGTCTGGAGAGGCCGACTTGAGGAGGCCCGGCCTCTGCCTCCCTCATGGCGGCCTCTGCAGGCCCAGCTGTTCCTCCTGGCTGCATCTCTCGGCCCAGCTCCTGCCTCCCAGCAGGCAAGCTCTTTTGGCTCAGCTCCCTCCAGCGTTTGTAGACCCCGAAGTTTCTGCAGCCAAGCTCTTCAGGCCCACATCCTGCCTCCCGGTGGCCTGTACAGTCCCAGCTCTGGCAGCAGAAGAGCGTCAGCAGGCCCCGCTGTTGCCTCCCAGGGGCGTCTCCAGGCCCAGCTCTCGCCCCACCACGGCCTCCCGCGGCCAAGTCCCTGCCTGCTCCCGGCAGCCTGCGTACGGCCCTGCTCCTCCCTCACGGTGGCCTGTTGAGGCAGGGGCTCACGCTGACCTCTCTCGGCGTGGGAGGGGCCGGTGTGAGGCAAGGGCTCACGCTGACCTCTCTCGGCG
->XM_014708519.1 Ordospora colligata OC4 valyl-tRNA synthetase partial mRNA 
-ATGGAATCTGAGAAAGATGAAAAGAAAAGGATTAAAGAGGAGAAGAAAAGACAGAAGCTTGAGAAGTTTCTACAGAAGAAAACACAGGAAGTGAGTGTGACAAAACCCAGAGGAGAGTACAAATCAGGAGGATACGACCCTATGGAGATTGAAAGTAAATGGTATAAGTACTGGGAGAGCAATGGTCTTTTTAAGCCAATGCGCAGTGAGAAGAAGTATGTTATTCCCATTCCACCGCCAAATGTGACTGGAAATCTGCATATTGGGCATGCTATGATGGTTTCTATACAGGATGCGATATGCAGGTATAAAAGGATGTGTGGATATGAAGTTCTGTATATTCCCGGGACCGATCATGCAGGAATAGCAACACAAAGTGTTGTTTCTAAGCAATTGGCCAAGGAAGGAGTGGTTGATGTTGATCGAGGAAGGTTTTTGAAGAGAGCATGGGAATGGAAGAATACGCATGGAAGTAAGATATATGAGCAGTTTAAGAGACTGGGTACCAGTGTTGATTTTTCAAGGGAAAGATTTACTCTTGATCCTGGGATGAGTGATGCAGTTAGTGAGGCTTTTGTGAGATTGTATGAGAAAGGACTGATATACAGGGAGCCAAAGATAGTGAATTGGTGTGGGAAGTTGTGTACGACTATAAGTGATCTTGAGGTGAATCATGAAGAGATTGAACCGAATACTGTTATTCAGGTTGATGGAGGTATGTATGAGTTTGGAGTCATTTATCATGTGAAGTATCCATTAACTACATGTGCAGAATATAAAGGATGTGTTAGTGAACTACCAAGTGTTGAGATAGCAACCACAAGACCTGAAACGATTCTTGGAGACACAGCTATATGTGCGAATGCAAATGACGAACGATTTGGCAGTGATGGGATAAGGAAGATGTTTGGAGATGTATCTCGAGATACAAAGGTGTATGGAGTGAATCCATTGACAAAGAGAGTGATTCCTGTGATATTTGATGATTATGCAGACATGAGTTTTGGAACGGGCGTACTGAAGGTGACACCTGCACATGATGCAAATGATTTTGAGTTGTCTAAGAGACATGGGCTTGAATGTATTGTTGTATTTGATGAAAATAATAAAGTGAGTGTTGAGGGAGAGTTTAAAGGGCTTGGAAGGTTTGAAGCTAGGAAGGCGGTTATATGCGATCTTAAGTCTATGGGACTGTATGTGGGTAAGAAAGGACATCCTCAAGTGATTCCAAGATGCTCTAGATCGAATGATGTTATTGAGCCTATGATCAAAAGTCAGTGGTGGATGGATTGTAAGGAGATGGCAAGAAAAGCAATTGATGTGGTTAGGAATGGTGAGATGGATATTCTACCACCAGGTGCTGAGAAGCAATGGTATAAGTGGCTTGAGAATATAAGAGATTGGTGTTTATCAAGGCAGTTGTGGTGGGGACATAGGATACCAGCGTATAGAGTATCTGATGGACAGTGGGTAGTTGGAAGAACGAAGGAAGAGGCGTATGAGAAGATGAGAAAAGAGTATCCTGAGTGCAAGTGTACAATTGATGAAATGGAGCAGGACGAGGATGTATTAGACACCTGGTTTTCATCTGGGCTATGGCCATTTGCAGTGCTTGGATGGCCTAATATAGCAGATGATTATGCGCGATATTATCCAACTACGCTTCTTGAGACTGGTAGTGATATTCTTTTTTTCTGGGTTGCCAGGATGGCAATGCTAGGGATAGAACTTACGAGAAAGATCCCGTTTGATCAGGTTCTTCTGCATGGGATAGTTAGGGATGCACATGGAAGAAAGATGAGCAAAAGTCTTGGGAACGTGATAGACCCGATATTTGTGATAGATGGATGCAGCTTGAATGAACTTATTGCAACGATGAAGAGTGGAAACCTTGATGAGAAGGAAGTGAAAGTTGCTGAAGCAGCTTTGCGTAAAGACTTTCCGAACGGAATACCTAGATGTGGTGCAGATGCACTTCGTTTTACGTTACTCTCTTACACTTCAGGAATGAAAGACATTAATTTAGATGTGCTTAGGGTTGAAGGATACAGAAGGTTCTGCAATAAGATTTGGAATGCACAAAAGTTTGTTAAGATGATGGTTGATGAAGCAAAGGATTGCCTGAGCTCTGAATGTGGATATGCAGAGTATACTTTAAATGTCTCTGACCTTACTAATGGATTTGATTCTGGGCCGATTGAATGGATCCTTATGAAAAGAAACGAAACAATAGAGTATGTCAAAGAGATGATGGAGATGTATAAGTTTATGGAGGCAACACAGGCAATTCATCAGTTTTTTATGTATGACATTTGCGATGTTTTTATTGAGATTGTGAAAGGAAACAAGGAAAAGATGTATGTCAGTGTCTTACTGACAGTGTTTATTGACTCTATGAAGATATTTCATCCGTTCATGCCTTTTATTACTGAAGAAGTGTTTTCAAGCTACTTTGATACATCAATTTCAACATCGGAATATCCAGTAAGTGATGGTAATGCTCACAACAATAATTTTGGTGCAACATTACAACTGGTGAAGCATCTGAGAGGTTTATTGGAGACGAATGGGCCTGGAGGAATGAATGTGCTTGAGATTGTCCCTGGACCTGAGATTAACCACCATGATTTGAAATTTATCCATCTGCTTTGTAGAAGGATATGCAGTGTTGAAATATTATGCGATTATGACGAGAGGTTCTTGGACTTCGGAGGCACAAAAGCATATCTTCGGAAAATTGAATAA
->XM_039636903.2 PREDICTED: Drosophila santomea uncharacterized LOC120452602 (LOC120452602), mRNA 
-TCCAGTATTCTATCAGTATAGAAAACAACACACACACACTTTGTAGACACGCGTAAATAATTTTTCGAAATTTGTACTTTTATGCGTGCTATTCTTTTTCGACTTTTATCTTAAATATATTACCATTTTCAAACTATAAAGAACATATTTACAATCACCGAACCTCAAAATGCCGCCCGTTTTAAAACGGAGTCTACGGAAAAGATCAAAACCAGTTCAAGAAACTCCAGCCGAAATCAAGAAGACGAGTACGCTTTCGAAAATAATCATTCAAGGCACTGAACAGCTGTTATTGGATTCTGAAAATAATCCAAATATTCGAGTTATTGAAAAACCCAGAAAAATGCGGTATTCAAAATCATCGATTCCCACTGCGGAACCGGATTTCCAGCTGCATTCCACACCGAAAATTGGTAATCTGGCAAATAAAAGCAACGCACGCGGGATGTTTGGTCCGATCAAAAATAAACAGACATCCATAGAAGCTATTTCTGAAATTAGTGATATGTCCATTGCTTCAGTGTCGGTGAGGAATCAGCCGTTTGTGAACTTTCTCCAGGATTTCTGCATGACTCGTGGTTCCGATCCCAGAGAAAGTGTTCAAGAGGCCATCGCCAAATGGGATAAAATGACACCCAAACAAAAAGCAGAATTCAGTCCAGAAAACTACGTTCTAAAATTGTGTAATCAAGTGCAGAATCGTAATGAAATTTTAAATGCGGTTGCACTGCAGCCGGTTTATGAAACTACAAAAAAAAATCAAAATGGATTTAATAAAGCCAGCAAGGTCAAGAGATTGTCTCCAAAGCTACGTAAGTTGACAAAGCGATTAAACCCAAGACCACGAGGTGTGGTGAGTCCCAGAAAATCAATTAAAAATGCGGCCAAAAAGGAGGTGCCTCCAATGGTGTCGGTGCGTCTAACTAATAGTGCTTCGGCTTACAAAAACTTTCTGCGCAAAGTCCGTCAAGCAAATCCTGGTCTGATGTCCGTAGAAAAGACCTCCCTGTGGCGCAAAATGACTCCTGCCGAAAAGGATCTCTATCGGGTAGTCAGCAAGCGAAGCCAAGAGAAAACCAATGTCAAGAAAACCAAGTTAAGAGCTCTAGCTGCCAAACGCGTAAGGAAGCAAAGAACCTCACGATCAACCCAGATGCCTGAAAATGCTTTACATTATTTGCAAAGCAGTTTCGATATTCAGCGAGATGGCCAACTAGAAATTTGGAACGAGAGCAACACTTTGCTACGGGATAGTCAACGCTCCTGGGTCACACTTGACTACATTTCAAAAGCCTTTGAAAAAGTGAAGAATATATTTAGTTAACTACTTGTTGTCCAAATTTTATACAAAACATATGTAATTGCTATAAAAAAAACTGCGTAGAAACATA
->XM_045247888.1 PREDICTED: Portunus trituberculatus adhesive plaque matrix protein-like (LOC123499604), transcript variant X2, mRNA 
-GGCAGGATGAGGGTGGTCACTTGTAGGAAGAACACGAGAGGAGGAGGAGGTCATGACGAGGTTCACAGGACGGTCGCTGGTGGTGGTGGTGGTGGTGGCGGTGGTGGTGGTGGTGGGAGTGGCAGGGGAGAAGCTGGAACACGGTCTGGAGCTCATCACACGGGGGGAGCTGACGGGGGAGACAGACTTTGCGCCCCAGGGGAGGGAAGATGAGCGGACCAGCGCCCACCGAAGCTTTCCCGCGGCGCCCATAGCCCTCACCTACCTGCCGCCCATACAGAGCCCCTTACCCATAGAGGAAACACAGGGGACCACCACAGGCACCAGCGCTACCCCGGGGGAGGTCTTCGTGGCTCCTGACCATGGGGGAGAGATACTTAGACCATTCAACCAAGCAGGGTCACACCTCGAGCAGACCAGCCAACAGCACCACCACCACCATCACCACCTTGGCCCCTTTGAGTCCTCCCAAGAGAACACGCCCTTCCATACAGAGTTCCAGCCCTCAACAAGTGACCAGGACCCAGACGCCCTCCCAGCTGTGGTCCCAGGCCTGAAGAGCGCAGTAACAGCCAAGACAGAAGCATTTGGTACCCTCACGAAAGCTGCACCGTTTGAACACACCCCCCAAACTGCACCAGCCCCCGTGGTACCGTACCCGATCTACCCGCCGTACCCCAAGCCCCAGCAGACGTACCCCCAGCCTTCCTACGTGTACCACAAAGCCTCGTATCCTCAGCCAGTGTACCATAAACCAGTGTACCATAAGCAAATGTACCCTGTAGTGGTGTACCCTGGATATCATCAGTACCACGCCAAGCCGAGCCCCCTGGAGGCGTTGAAGGCTAAGGTGGAGGGCTACGTGGAGACTAAGAGAGCGGCTGTGAGTGGAGCGCTGGCCAAGGTGGAGGAGGCTAAGGCGAAGCTGGACGCAAAAATCAAAGGTCTTTTTAAACCCACTTCCTTGAAAAAAACACCTATTCCATACCCTTCCAAGCCCCTTCCAGCCCCGTCTGCACCCTTCTACCCCTTCAGACCCTATCTCAATGTGCCCCTGACGCCTCACAAGGGGTACTCCATCAAGGCCACCCCTGCCAAGCCCCTGCCAGCCCCTGTACACCACGTCAAAGGCCCGGTACCAAAACCTTACCCTGTGAATGTATACCCAGCCATACCACAGCCTTCCCTTGCTACTACCCCTGCTCCTACCCCTGTCCCGATCCCTGCCACGCTTCCTGCCGCTTCTACAGGCCCCCAGATACCCCAGGAGACCTACCCCATGGCCACAGCACCCCAGTATCAGCCTGTGTATGCAATTTACCCCGTGGCAGCCTCGCCTGACGTGGGACTCAAGGAAAAGCTGGAGGCGAAGAAGAAGCAAGTGATGGGAGCGATTACAGGCGCGTTTGCAAAGTTGAAGGCGCCATTCCAGTACCTGCACCCTTCCTACTCCTACTACTACGCCCCCCAGCATTGGTAGAGGCGCGGCAGGGGCTGGGAAGGCGGCAGGGGGTAAAAAGCTAAGGAGGTATTGGATTAAGCACGTGGTAAGCAGACGCCTTTCAGCCGCCCTGCTCGTGACGTCATCTTAGAGACCGCGGGTGTAAACTAAAATTAAATACATTGGGTTAAAAATATTAGTAATCTGAGCCTATGTTAGTTTATAGTGTGTAATATTTTGTTTATTAGTTAATCTTCTATATAATGTTAATTTGTAGGGTTATGATTGTTATTCTTAAGAGTTTTGAGATTAAGTTTATATTTTATTTTTGGGGTTTTGTATGTAAGGAAGGTACTGGCTAATGGAAGACAAAAAAATGAAATATATAAAAAAAAATGAGTTTAAATGCCAGACCTAACATGAAAAGCACCAAAAGGATTATGAAATTTGGAGAAGTGTTCGATAATAAGGAACAAAGGTACGATGCAGCGAGGAGAGCGCGGCATTTTCAAAACACTGCTAGCGCGCTCCTTTTTAGCCAAGTAGAAGTGAAAAAAAAAGTGCTAAATATTTTTCTAACTCTTGTTATATGTTAATAAAAAAATAAAATAGTTGTTTTT
->MH123473.1 Homo sapiens isolate NUB087 cytochrome b (CYTB) gene, partial cds; tRNA-Thr and tRNA-Pro genes, complete sequence; and D-loop, partial sequence; mitochondrial 
-GGGCCTGTCCTTGTAGTATAAACTAATACACCAGTCTTGTAAACCGGAGATGAAAACCTTTTTCCAAGGACAAATCAGAGAAAAAGTCTTTAACTCCACCATTAGCACCCAAAGCTAAGATTCTAATTTAAACTATTCTCTGTTCTTTCATGGGGAAGCAGATTTGGGTACCACCCAAGTATTGACTCACCCATCAACAACCGCTATGTATTTCGTACATTACTGCCAGCCACCATGAATATTGTACGGTACCATAAATACTTGATCACCTGTAGTACATAAAAACCCAATCCACATCAAAATGCTTACAAGCAAGTACAGCAATCAACCTTCAACTATCACACATCAACTGCAACTCCAAAGCCACCCCTCACCCACTAGGATACCAACAAACCTACCCTCCCTTAACAGTACATAGCACATAAAGCCATTTACCGTACATAGCACATTACAGTCAAATCCTTTCTCGCCCCCATGGATGACCCCCCTCAGATAGGGGTCCCTTGGCCACCATCCTCCGTGAAATCAATATCCCGCACAAGAGTGCTACTCTCCTCGCTCCGGGCCCATAACACTTGGGGGTAGCTAAAGTGAACTGTATCCGACATCTGGTTCCTACTTCAGGGCCATAAAGCCTAAATAGCCCACACGTTCCCCTTAAATAAGACATCACGATGGATCACAGGTCTATCACCCTATTAACCACTCACGGGAGCTCTCCATGCATTTGGTATTTTCGTCTGGGGGGTGTGCACGCGATAGCATTGCGAGACGCTGGAGCCGGAGCACCCTATGTCGCAGTATCTGTCTTTGATTCCTGCCCCATCCTATTATTTATCGCACCTACGTTCAATATTACAGGCGAACATACTTACTAAAGTGTGTTAATTAATTAATGCTTGTAGGACATAATAATAACAATTGAATGTCTGCGCAGCCGCTTTCCACACAGACATCATAACAAAAAATTTCCACCAAAGCTTCTGGCCACAGCACTTAAACACATCTCTGCCAAACCCCAAAAACAAAGAACCCTAACACCAGCCTAACCAGATTTCAAATTTTATCTTTTGGCGGTATGCACTTTTAACAGTCACCCCCCAACTAACACATTATTTTCCCCTCCCACTCCCATACTACTAATCTCATCAATACAACCCCCGCCCATCCTACCCAGCCGCTGCTAACCCCATACCCCGAACCAACCAAACCCCAAAGACACCCCCC
->XM_026551140.1 PREDICTED: Papaver somniferum ketol-acid reductoisomerase, chloroplastic-like (LOC113302251), mRNA 
-GAGTCAGTTGGCTCCCTGCAATCGTTCTGGCGGGATGGAGTTGAACAGTGAGTCGAAGTTAAAAGTTTGAATCTTTTACTACCTCGTATAGAAGAGTCCAAGGGAGGTAAAAATATAGAAGAGGAGGAGTTATGGATTAAGTAACCGCTGTATCCGCACTGAACTGCAGGAGAAACTTATCCAGATGAAATTCGTGTGATTATGGATTCGTTTGGGTTTCATTTCCGCTGATTTGAATTCCTATGATATACTTGCTGTATTTGGTTAATTCTCAAGTAGAATTTGTTACTCATGGGAACTTCCACTCCGTCCATAGCTTCTTCTTGTTCATTTAAAACCCTAAAACTACTTCACTCAACATCCTCCTCTTCTTCTTTGGGTTTTAAAGTAGGGTTTCTTTCTTCATCTTCTAAAACCTTAAAATTTCTTCTTATTCGTGTTTCTAACAACAGTGTCTCGTTCCCTATTGGATCATCTCTTCTTGCATCTCGTATGATGGTTTCAGTTCCCGATACTAAACCTTTGACTGCTCTTGATTTTGAAACCTCTGTGTTTTACAAGGAGAAGGTCACTCTTGCTGGAAATGACGAGTATGTTGTGAGAGGAGGAAGGGATTTATTCCATTTGTTGCCTGAAGCATTCAAAGGAATTAAGCAGATTGGTGTTCTTGGTTGGGGTTCTCAGGCTTGTGCACAAGCTCAGAACTTGAGGGATTCACTTGCAGAAGCCAGATCTAACATTGTTGTCAAGATCGGATTGAGGAAGGGATCCCGTTCTTTTGCTAAAGCACGTGCTGTTGGTTTTACCGAGGAGACTGGAACTCTGGGTGATATATATGAAACAGTAGCAGAGAGTGATCTTGTGCTGCTATTAATTTCTGATTCTGCACAGGCAGATAATTATGAGAAAATATGCTCCCACATGAAACCTAACAGCATTCTTGGACTCTCTCATGGATTCCTCCTTGGACACCTACAGTCCCTAGGGCTCGACTTCCCTGAAAGTGTGAGTGTGATAGCTGTGTGCCCCAAGGGCCTGGGTCCGTCTATCAGAAGACTTTATGTTCAAGGGAAAGGGATAAATGGTCCTGGAGTTAATGCAAGTTTTGCCGTCCACCAGGATGTTGATGGTAGAGCAACAGATGTCGCCTTAGCATGGTCTGTTGCTCTTGGTTCTCCTTTAACATTCTCCACTACTCTGGAACAAGAATACAAGAGAGACACTTTCGGAAACCAGGATAGCCAGGAAACTGAAAGACGGAGAAAGATAGGGTTTGCAAACAAAGGGAGAACACCATGGAACAAAGGAAAGAAACACAGTGCCGAGACTCGTAAGAAGATCAAACAAAGAACCATAGAGGCACTGAGTGATCCCAAGGTCAGAAAGAAGATGTCTGAGTGTCCCCGTGCTCATAGTGAGGAGAACAAGATAAAAATAAGCATTGCTCAGAAGAAAATGTGGAGAAAACGCTTGCAGATGAAAAGACTGAAGGATGAGTTTTATCTGAAGTGGGCAGAAAGAATTGCAGAGGCAGCTAGGTTAGGCGGCTGTGACCAACAGGAACTAAATTGGGATAGCCATGAAAAGATCACAGAGGAATTGGTTCTTAAACAGCTTCAGTTGACTGCAGATAAAGCAAGGGAAAAAGAAATTGCAAAATTAAGAAGAGCTAGAGCAGCGAAGGAAAGAGAGGAGAAAATGGCTAGAATTGCCCAGAGGAGAAAAGAGAGGATAGAAAAGGAGAGGGAAGAAAAATCAAAACCCAGAGTAGAAATAAAGAGAAAGACACGTAGAAAATCAGAAAAAGAGAAGCAACTACTGGCTCTTTCCAAGGGCTCAAAACTCAAGGAAAAATTGACGAAGATTCGCCGTAAGAAGACTGTTGATGGTCAAGGAGTAGTGGCAACCGGCAATCAACCAGCGATTGAGAAATTGGATTTAGAGTTTATAGAAAGAGAGAAACTGCGGAAGGAAGTGTCTCTTGCGGATCAGATTCGAGCTGTAAAAAAGATGAGAGAGGAGTTAAACAAGGAACCTCTTGCCAGAGCCATCTTATAGATTAAGCCAGCTAGATCATTTTCCTAGTCGAAGTGTTTAGGCTTGGGCTGCTATACATGTCAAAGTTGATAGGCTGAAAACTAAATTAGAAATAAGAACATGAGTTGATCTAGGCTTAGATTTGTTTTTGTTTTTTTTTCCCTCATTCTCCTTGTAAGAACAAATAAGAGCACCAACATCGTCTACCTTCTTTTATCAATCAGTTTTGAAATTGTTGAAGGAAAATGTTATGTCGTTGGGTAATAGATTTGTCCAAAACTTACACTTGGGCACCAACGTATGTCCAGGTGGTTATTATTGACCAATTGAATTTGAAAAAGATATT
->OK585766.1 Setaria viridis SvmiRp606 miRNA gene, partial sequence 
-TCGGACCAGGCTTCAATCCC
->XM_008174878.2 PREDICTED: Chrysemys picta bellii olfactory receptor 52R1-like (LOC101936597), transcript variant X1, mRNA 
-ATGTCAGATTCCAACACAACCGAATTCACCAACCCCTCCACTTTCATCCTGCTGGGCATTCCTGGCCTGGAGGCAGCCCATGTCTGGATCTCCATCCCCTTCTGCACCATGTACACCATAGCCATCTTGGGGAACTTCACCATCCTATTCATTGTGAAGATGGAGCCGAGTCTCCATGGGCCCATGTACTATTTCCTTTGCATGCTGGCCGTCACTGACCTGGTGGAATCTACGTCCATTGTGCCCAAAATGCTGAGCATCTTCTGGTTCAATTCGAGAGAGATAGATTTCAATTCTTGCCTCACCCAGTTGTACTTCATTCACTGCTTCTCAGTGATGGAGTCTGGGATCTTCTCAGGCATCTTTGTGGCTATGGCTTTGGATCGCTACGTGGCCATCTGCAATCCCCTGAGACATTTCACCATCCTGACAAACTCCATCGTGGCCAAGATTGGCCTGGCCATGATGCTGCGCAGCGGCTTGCTTGCATTGCCCTATCCCTTCCTGGTAAGACAATGGCCATATTGCAGAACCAACATCATCCCCCAGTCGTACTGCGCACACATTGCCGTGGTGAAGCTGGCCTGCACCGACATCCGCGTCAGTAGTTACTATGGCCTCTTTGTGGTATTCTGTGTGATGGGTCTGGATGCGATTTTTATTGCCCTGTCCTACTCCCAGATCCTCAGGGTCATCTTCAGCCTCCCCACAAAGGATGCCCGGATAAAGACTTTTGGGACCTGCATCTCCCACCTTTGTGCCATCTTAGCCTTTTACATCCCAAGTCTCTTCTTCTCCCTCATGTATCGGTTTGGCCAGAATGTGCCCCTGCATTTCCACGTTCTCATTGCCAACGTTTACCTCTTGATGCCCCCCATGCTAAATCCCATCATCTACGGGGTGAGGACCAAACAGATCCGGGACAGGCTGCTCCGACTCTTTACTCATAAAGGGACCTAA
->XM_013231282.1 PREDICTED: Biomphalaria glabrata lipoxygenase homology domain-containing protein 1-like (LOC106071234), partial mRNA 
-GATGACATTGCCACAGATTGGAAAGTTGATAATCTTGTCATGGAAAATCCTAGCACTGGTGAGAAGCACAGCTTTGAGGTGAACAGATGGCTGTCCCATAAAGAAATTGATGGAGACATTGTATTTGAAGGTGCAGTCAAACAGCACAACCAACCAGTTGCTTCTACTTGTAAATACATTGTTAAGACCATTACTGAAAGTGAAGAAAATGCAGGAACTGAGGCTAATGTGTATATAAATCTTATAGGAAATCTAGGGGATTCTGGAAAAAGATTTCTAGTGAACAGCAGTAATGGAGGTGAAAAGTTTTCAGCAGGAAAAACAAACTATTTCACTATTGAAGCAGTGGATCTTGGTGATCTAGAAAAAATAGTCATTGGTCATGATGGAACAACACCTGAAGATGCTTGGAAACTTCTGTGCGTTATGGTTCGCAAAGCTGACTCTGCCAACAGAGATACTTCTGTGTTTCCTTGTGGAAA
->XM_017243286.2 PREDICTED: Drosophila bipectinata nuclear transcription factor Y subunit gamma (LOC108126631), mRNA 
-TTTCACCCCTAACTGGAGGCTGCCACACTGTTCGCGTGTATGTGTGCATTGCGCATTTCGTTGATTTTAACAAAATTTTAGCCTTCCAGCCGGCTGTGATAGCCAAACCGTTGCCGTCACCGCACCGCAGATCACGTGAGTCAACCGGGACATGTACGCCACCAACAACGGTGGCACAAACAAGGCGCCAAACAGCAATGCCAGCACGCTGTTCGAGAACACCATAACCGTGACGCCAATTAAGGTGGAGTTGGGCACAACGTATGGCGCCGGAAAGCCACCCACACCGGCGCTACAACGAAGGACGCCCAATGCCGTGGTGGTGACCACTAGTAATCCGCAACAACAGCAGCAGCAGCAGCAGCAACAACAGCATCAAACTGGTGCCGGAACCACCACTCTGAACCTGCCCATGCAAGCCACCCTGGTCTCGAATGCCTGCACCATAATGAATCCCAGCCTGAGTGTGACTGTGAATACCACCACCACTGGAGCCCTGGCCAAGGAACCGAAGGGTAAAGCAGCGCGGGCGCAGGTGGTACGGAAACCGCCGCCTACCATCGACAACTTCTGGCCGAATATCGTGAACGAGGTGCATGCAATCGGGCAAGTGGACGCCAAGCATCAAGTCTTGCCACTGGCGCGGATCAAGAAGATAATGAAGCTGGACGAGAATGCCAAGATGATAGCGGGCGAGGCGCCGCTGCTGTTTGCCAAGGCGTGCGAATACTTCATCCAGGAGCTGACGATGCACGCGTGGGTGCACACCGAGGAGAGCAGACGTCGCACGCTCCAGAGATCGGACATTGCCCAGGCGATCGCCAATTATGATCAGTTCGACTTCCTTATTGACATTGTGCCGCGCGAGGAGATCAAGCCGTCGTCGGCGCAGAAGAGCAAGGATGCGGGTGGATCGAGTACGTCGAGCGGGAGTGCCACAGGAGTTACCTCATCCACGTCGTCCGGCACCAGTGCCGGCGGTGTCGTCAGTTCTTCCGTCAATGCATCTGCAGCTTCGGTCACGGGATCGGCTGGAGCCGCTGGGAATTTCGTGGTCGGAGCCACTGCTGTACCTGCTGCCAAGATGGATACGGGTGGAGGAGCCACCGCTACAGAGGTACTAGGCTTTAGCACGGTCACGCCGGACCTGTTCGCCACGCAACTGCAGCAGCAGCAGCAGCAGCACGTCGCCCAGCAGCAACAGCAGCAACAACAACAGCAGCAGGCGCATCCACAACAAGTGCAAATAATCCAGCAGGCCGGACACGGCGGCGCCCAGCAATTGCAGTACTTTATTGCGCTGCCGGGCCAGCAGACGGCACAGCCGGCCCAGAATCATCTGGCCAATAGTCTGGGCCTCAACATTGTGGCCGCCCAACAGCCCGCCCAGCAGCTGATCCTCACCGCGGGCCCCAACGGCCAGCTAACTGCCACCCCAGCCCCCGCGGCCACGGTGCAGCAACAACAGACGGCCCTGCTCCAGAATCTCGCCCAGCAGCAGCAACAGCAACAGCAGGCCCAGCAGCAACAGCAGCAGATCCAATTGCTCCAGCAGGTGGTCACTCCCACGGGGGAACTGACCAATGTCCCGATTGCAATCAATGCCAACCACTTGCATCTGCTCCGGTTGCAGATGCAGCAACAACAACAGCAGCAACAGCAACAACAGCAGCAGCAACAACAACAGCAGGTGATAATACCGACACAGTTGCTGACGGCACAACAGATACTCCAATTGGGCGGAGCACCCGCTACCGTTGGACAGCAGCAGGCGCAGGTTCAAGTCCAGCAGCAGCAGCCACAGGTGCAAGTTCAAGTCCAACAGCAGCATCCAAATCTCAGTCAGGGCAATGCCAGTGCCACGCCCATTTTTATAAATTCAACAGCGACACAGCAAGTGGCGCAACAGCAGGCGCAGCAACAGCAACAACAACAACAACAGGCGCAACAGCAACAACAACAACAACAACAACAGCAGCAGCAACAACAACAACAACAGAGCAACATGGCCGGGGAAAGGACACTAACCGGAGGATTTCGGTAAAAGGAGCTCGCGCTGAGCGTGCACTGGTCGTGCAATGGTAACCATATCGAGGCATGGGTGGGAAAGGTCCAGCACAATTTGTATAATATATAGTTTACGTTTGTATATCGGAAAGAAGATTATATATATAGTTAGTGCTGTAAGTGTAGAAACGA
->XM_002365330.1 Toxoplasma gondii ME49 Ctr copper transporter family protein mRNA 
-AGAATTGAGTTGGTGGTTGTTTTCGATGGAAGGAAGCGAGAGTTTCGGAAGAATTCTCGGAAAAGTGGATGTCAACCTGGCAATTCTGTCCCGTTCGCGGGGGGCTCTCCTTTTCCGTGCAAGCACGCGTCCACCTTGATCTCGCGTTCTGCGCTGTGGATTGCAGGAGACGTGTAAGGCAGGCGCCTCTGTTTCCCCGCGGGAGGCACAGGCGATGCAGGAAGCGTCTCCTTTCACGACACCTTGGCAATTCACGAAGGAAATTCCCGTCTGCCTTGTCTGACTCAGGTGGCAAAACTCTTCCTGCGTTCTTGCTGCCTCTGAGTCGAGGGTTTAGGGACTTTTAGGGTTTAAGCCTTCAACTGCCGAGGGCCCCCCCGCGAGTCAAAGACACACGCCGCGTGTCTCTCCTGTGGCGACTCTCCGCGAGAGAGGAAAGAAAACTTCACAAGAATCATAGGCTGAAGCGAACCTCCGATTAACAAGTGTGTGCGCTCCGTGGGGAGAGAGAACGCGTTCGAGAAAGACCTACAGAGGGCAGACCAAGAGAGTCAAGATGGCAACGCACGCTCAGTCAGGTGCTTCCTGCTCTCTGAGCACTTCTCCGAGATCTGGACGCGAAGGAGGACAGAGAAAGACGGAAGCCTACCTTCTGTCCCTCCGCAAAATCCCCAGTTCCAGACGGCGAGGTCTTCCGACCGGTCCTCAATCAAAGGCCTCTCTTCTGCGAGTGTCCACGTTCTTCCTTGTTTGCGCGCTTCACTGCGTGTCTTCTCTCCCCGGCGCTCTGTCCTCCGCCTCGAACTCTCCCGTCTCTTCTGACAACGAGGTGCCCGACCCTCAGCGAAACCGTGACAGCTCAAAACCTTCCAGTTCCGATGCTACGCCAGATAAGACGCATGACAAGCAGCGGCCGAGAAACAGGTATGAAGATGTCGAGGACTGCTGCAAGGGACAGAAGAAGCGCGCTGCCGACGACGCTTCTGCTGCGAGAGAGGCGGACGGAAAAGAGGAGTCTTGCTGCGACAAGAAAGGCGCTGCCGGAGGGTCGGGCGGAGAGGGACCTTCCAGTGAAGGAAAACAGTCCTGCTGTAAAAAGAAGAAAGCAGTGGCTGCGGAAGGAACCGCCCACGTCGCTGCGGAGGGACATAAGTCCTCTTGCTGTGGGGTCATGCCCATGTCTTTTCAAAACTCGCTGCACACCGTGATTCTCTTCCACTCATGGGAGACACTCGAGCGGTGGCAGTACGTGCTGTCGCTGCTGACGTGCGTGGTTCTGGGGATGCTCTCCGTGGTTCTGAAAGTCCTTCGCCTGCGACTCGAGTTCTTCCTCGCCAAGCGCGACCGCGCCGCGGAGGACGCCCAACGAGTCGAGAAATTGAAGGAAAAGGAAGGACAGAGTTCGGCGGCTTCTCCGTCTTCAGCAATTGTCGAACGCCTTTGCGGGAATTTCCCTCTGAAGCAAAACTCCTGGCGGATGCTGGAGGCGTTCGTCATCTACGGGTACGACTACCTTCTCATGCTGATCGTGATGACCTACAACGTAGGGCTCTTCTTCGCTGTCACGGGAGGCCTCGCTCTGGGCTTCTTCTGCTTCGGGCACCTCCTCAGAATCCAGGCAGAAAAAGAAGAGAACTCGCTGGAAGAAGACTACCGCGGGGACCCCTGCTGCTGCGGAACATAAGAACTGGAGACAAAAAGAGAAGACGAAAGGTGTTGGAGACCGAGAATGAAGGAAGAGGAGACAGAGAAAGAAGGAAAGGGAGACAGAGAAAGAAGAAACTGAAGAGTGGAACTAGGAGAGACCACAGGAAGGCGTGGAGCTGGAAATTATTCCTTTGAAACTGGTAGCAGAGCAGGGAGGTCCCTTGAACTTTTGGATTTAAAACATCCTTTTTTTAAAAGCCTCCCTGAGGGAAGAAGCTGGAACGCAGGGTCAAGAGACTAAGGTTGCCGCGTGGAATCGGTTGATCCGCCGTTTTTGTGTAGAACTGCATTCTTTACCGACGCGTTTCAGCGCGTTTTTTGCCGTCGGGGAAGAGTCGAGAAGGGCGCACACATGCGTGTACAAGATGCACACAGACTGTGGCCCTCGTCTGTTCTCCAACAGACCGCGTTTCAGAACGAACATGTAGAATACGCACAGAGACGCGTTCAAGCCTCTGCGCCGGTG
->XM_037418793.1 PREDICTED: Rhipicephalus microplus uncharacterized LOC119167324 (LOC119167324), mRNA 
-TGCAAGAAACTACGTACATCATGGTCTCGAGAACTTCCTCCGTATAAAGGTCCAATCGTAGCGCTGATATATGTTTATTTTCGCCTTTTACGACGTGCATCAACAGGAGCACCATGCAAACAGGGAATGGCGTCGTACTGCTCTTGGTTATTTTATCTTATTTGACAGGATTTGGCCAGTCAATATTCATAAAGGAAAATGATTTCAAAGTGTTCTTAAACACAACGCAACCCATATGGACCTTCAACACGACAAACAAATACAACAAGAATTACTGCATTGTGGACGTTACAAAAAAACTGCTGGGAGAAACTGTCATGTATACTCACTCCTTCTATGTCGACCCCACGAGAAAACAGAGGGTTTCTGTTCATATGGAAGGTGCCTTGAAATATAGCAATAAAATGGTTGCCACGCAAAAAGGTTCGAAAGTGACTTTTAAGCACAAGCTCGTGTATCTTGACTTCGACAACATGTGCGCTGTGGTGAAAGTTACTCCAAAGCTTCCTATCCCTGGGCAGCCTTGGCATGACCTGCGAATGTGGAATTCCTCGCTTGTGAGACATCGCCACCCTTCGATAACCTGTTTACACTATTTCAATCTTGAAGCAAAGCATGGACGCCTAACTTATAAGCCTATATGCCAAAAACTCCTTTATCAAGTGAATCCGTATCAAAAGAAAATTCTTCAAGGGCAGAAGACGCCGCAGACATACAGGAGCACGAGCGTGTGAACTGTCGAGCATACTTCGGAAGTATGTAGCACATCAAAGCTTTCTCTAGTGGTTCACGAGAACCACTGGAGGCAGAGATGAATAACTTGTCTAGCCTGTGCTATAAATTTCCATGGGTAAAATGAACAAATCGTTGTCTGATTTCATATGTGTGGTATAATGCGCGCAGCGCTTACATAGATTGCCACAGCTTTCAAGCAGCAACACAACGTGCAACATAAATATGCTGAACCTTACAGATACGCAACCAATAAGTTTTAAATAATGTAAAAATCCACAGACAATGAAA
->XM_027137582.2 PREDICTED: Tachysurus fulvidraco probable endonuclease 4 (si:ch211-141o9.10), transcript variant X3, mRNA 
-GACGCAGCTAATTATGAAAACGAGTCCTCCACAGTGCTGTTTGTAACTATGCAATGGGGATAATGTAAACGAAGAAAAGACCACACTGGTTTTAAAGCGTTGAAAAGTCAGTTGGTTGACGGTCGGCCATTTTACTGCTCGGATTATACACTTAAAGTGAGCGAATCCCTTCTCACTGACAACAGTACATAAATTAAAGGCACATTGACCACGCCCCCATACCAAAGTATATGTGGAGATGGGCGGGGCTACAACACACACCTACATACCTACCTACACCTACCTCTCGATGATACAGATTGTGATCTTTTAAGGTGACTAAACTGAAAAAGAGATGGCTTCGTGCAAAAAAGGAGAGAAGAGAAGAAAAGAGAGAAATGTGAAAACGTTAGAGGAATTTGAAGACTCGGCTGAAAGGAAAGGAAGGACAAGAGAACAAAAAAAGTACATTGGTGCTCATGTGTCCATAGTAGGAGGGATATGGAAAGCAGTTGAAGCAAGTGTAGAAATGGGGGGCCACAGTTTTGGATTATTTTTGGGTTCCCAACGCTCTTGGCAAAGACCTGCTCTTGATCAGAAAGCTGCAGTGAAATTTCAGCAGGCTTGTGCTCAACACAGCTTTGACGCAAGACACATTCTGCCACATGGATCTTACCTGATGAATTGTGGCTCTCCCAAAGAAGATGTGTTTAGTAAGAGCCAGGTCATGCTGGTTGATGAACTCAGTCGCTGTAGTCTTTTGGGCCTTACTCAGTTCAACTTTCACCCCGGGGCCTCCCTTGACTCCAGCAAAGAGCAATGTATCGAGAGGATTGCCGAAGCTATAAACAATGCTCACCAGCAAATACCTGCAGTCTGTACCGTTCTTGAAAATATGAGTGGACAGGGAAGTACAGTTGGTGGAGATTTTAATGAACTGAAGTCCATAATTGACCGTGTTCGAGATAAGACACGTGTTGGAGTATGTCTAGACACGTGCCATGCATTTGCAGCAGGTTATGACATTTCTTCAGAGGGAGGAGTGAAGTCTGTGCTTGATGAATTTGACCAAGTGGTTGGACTGCACTACCTGAGAGCAGTTCATCTAAATGACTCAAAAGGTAAATTGGGCTGCCATCTGGATCGCCATGAGGACATTGGCCGTGGACAGATTGGCATCTCTGCTTTCCGAAACATTGTGAATGAACCTCGATTTGACAACATCCCTCTTATTCTCGAGACACCTGGCCGCCCAGGTTTTGAATATGCTGAACAAATACAGCTCCTGTATTCTTTATGTGAGGACTAGAATGCAAGAGGACCTCTTCATTAGACAGTTATAAAGATTTTGTGTTCTATTTTATTCTGTTCACGCATTGTATATTTCATACAGGCATACAATAAACATAAATTGGATTCATATAATCTGTTATCTGTAAAGTATAAAGTACTGTAAAGTGTAGTTGATTGCACAACTACAATTTAGTTGTTTAGTCAGCAGAGGGAGCTGGAAACAAGGAAAACATGATAGAGTAGGTTGAAATCCCATCAGTAAATCTTAAACTAGGTCTGCTAAAGCAATTCTGCTTCCATATTGTACTTTCATATGTATTAAAGAATTTACTCAATCA
->BT130104.1 Oryza sativa clone RRlibC00934 mRNA sequence 
-CCCTTTCATCCATCCATCCATCCATCCATCCACATAGCAACGACCTCTCACAATTCACGAATCACCACTGCACACTACACTAGCGGCAGCAAGGATGAAGCTTATTGGCAGCGGCAGCGGCAGCGGCGGGCAGAGGAGAGGGATCGCGAGGGCACTCAAGGAGCACAAGGCGAGGCTCTACATCATCCGCCGATGCGTCGTCATGCTCCTCCGCTGCTGATGATCGAGCTGAGGATGGCGTGCACACGCCTTAATTTCTTCTCGGTGGAATATCTTTCGCAGTTTTTCTCTCACCAATTCACCATGGATCGGTGGGGGCGAATGTTTGTCCCTTGTTTGGGTAGATCTGTTTGGATCTGTCTCTCTTAAATTTGTACATACTGATGAGCTAGTGTAGACCATATCAATATAGGATGCAGATGGAAGTAGTATTAGTTAGTATGAGAGGTAAATTAGTTAGTTGGGGCTGAAGAATTGGGGGTTGTCCTCTACCCAGGACCAATTTTGCCTTGTATGATGATCAGAAGTGGGAATGCAAGAGAAATCTACATGATTTACAAAACAAAAAAAAAAAAAAA
->XM_020061516.1 Plasmodium coatneyi Cleavage and polyadenylation specifity protein partial mRNA 
-ATGAACAACATTAATATTGTGTGCCTGGGTGGGGCGAGCGAAGTGGGTCGTTCGTGCGTAATTATAGAAAGTGCGAACAGGTCAATTATGTTGGATTGTGGAATTCACCCTGCCTTTATGGGGATTGGCTGTTTACCCATCTATGACGCGTACGACATTTCGAAGGTGGACTTGTGTTTAATAACACATTTCCATATGGATCACAGTGGTGCCTTACCGTACTTGGTTAACAGAACCCGTTTTAAAGGAAAGGTATACATGACCGAGGCGACGAAAAGTATCTGCTATTTATTATGGAACGACTATGCAAGAATTGAAAAATGTATGCACATGATGAATAAGATGAAAGGAGGTAGGAGTAAAAATGAAGCGGGTGAAAATGAAACAGACGAATATGGAAACAAGGTTAAAAGAGGAGGACTATACTCCAGTGATGAATACGCAAGTGAAGACAATGAAGACGATGATTATTACCAAAGTTACATTTGCGAAATGGGAGATGGAGATATAAAGCATAATGTACTGTATGACGAAAATGATATAAACGCAGCGATGAAAAGGATAGAAACTTTAAATTTTCACGAACACATAGAATTTGAGGATGTAAAATTTACAGCATATAGAGCAGGACACGTGATCGGTGCGTGTATGTTCCTAGTCGAAATAAATAATATACGTTTTTTGTACACAGGAGATTATAGCAGGGAGGTGGATAGGCACATTCCCATAGCGGAGATCCCCACTATTGATGTCCACGTGTTAATTTGCGAAGGAACCTATGGAATAAAAGTGCATGACGATAGAAAAAAAAGGGAAATTCGCTTCCTTAACATGATTACCAGTATATTAAATAATAAAGGGAAAGTGTTACTCCCTGTGTTTGCTTTAGGAAGGGCTCAAGAATTGCTGCTAATTATGGAAGAACATTGGGAAAGAAACACACAGTTGCAGAAAATCCCCATTTTTTACATATCCTCTATGGCTACAAAATCGTTATGTATATATGAGACCTTCATAAATTTGTGTGGAGATTTTGTAAGGCATGTATTAAATGAAGGAAAGAATCCTTTTAACTTTAAGTTTGTAAAGTATGCGAAATCTTTGGACTCCATTTTGAATTATTTATACCAGGATAATTATCCGTGTGTTGTTATGGCTTCGCCTGGTATGCTACAGAATGGAATTTCGAAAAATATTTTTAACATCATTGCACCTGATAAGAAGAGTGGAGTTATCCTTACTGGGTATACAGTCAAGGGAACTTTGGCCCATGAGTTAAAAACTGAACCGGAATATGTCCTCATTAACGACAAACCGGTTAAGAGGAGGTGCCGCTTCGAGGAAATTTCCTTCAGTGCTCATTCTGATTTTAATCAAACTAAAACGTTTATTGAAAAGTTGAAGTGCCCAAATGTGGTTCTTGTGCATGGCGATAGGAATGAATTGAACAGACTGAAAAATAAGCTAACGGAGGAGAAAAAATATTTGTCCGTTTTTACGCCCGAGTTGCTGCAGAGGCTGACTTTTCGCTTTGAGCACAGTGACCACGTGGTGTCCCTAGGTCGGCTTTCCCAACATATTAGAGGGAAGCACCAACCGGGGGATGAAAAACTGAGTGACAGAAATGGAGAGGAAAAAACAATTCCCAACGGGGTGGATGCCATAATAATATCGGAGCCGAAAGCCATCCCGATTATGATTTACGCCAAGGATATTTATGAGTATACAAATTTGAAGACTGCGCTGATCGACCAGACGATTAGCATAAAATTCCCCTACAAGTTCGAGCTGCTGTATCATATGTTGAAGGGTGTGTACGAGGAAACGCATATGGAGGGTGAAGGCAGCGAAAGTGGGAATAGTAACAATGGTGATAATGGTGTCAATGGTGACAACGGCGGAGCGGTCATCTTCGTGCAGGACGTAAAAATCCACCACTGCAGGAAAGAGAAGGTTATTAGTATTAATTGGCTTTCAAGCCCAGTGAACGACCTAGTAGCTGACAGCGTCAATTTTCTAATTCTAGAATTTCTCGACACCATGAAGAATAACAACAACCACCTGCCCATCTGCGACGAAGTAACAGATGATGAGATTTATGAAATGATCATTTCGTATGTGCGGGAAAATTATACCAATGTGGAGAGATTTTCCAAAGTGGAGTTGAAAAGGTTTCTTTTGCAAAATGGCTGTGACAGTCCCGAGGGGGGAAAAAACGAAAAAGCAAATGCTTCATACACAGATGGGTTGACCCATTTGAAGAATGCCCAATCGTATTCATCTGGCAGGGTGAACCAAATCGATCATAACAGAATGGAAGAAGGGGTTACTTTACACGAGGAACATGATGAACAAAGCGGGGATGGAGACAAAATGAAGAAATTCCGCGCCCTTGATAAAATCTTATTCGACTATATCGCGGCAGATGCTAGTTTAGCCATGTCCACTGATGAGGAGGAACCCGTTGTACCGGTTCTTAATGGCGGGATGCTTTATGAAATACTAAAGTTTGAGGTGAAGGATAATAACAACAACGACGTTAATGTGTACGTCGATATAGACAACCGGGAAGTCATCTGTGAGGAAGTTACAATTTTGTCAAAAATTAGAGAAATTCTAAAAAATATAGAGGAGTCGCTATTGCCCATGTGCTTCTAA
->XR_001369330.2 PREDICTED: Pelodiscus sinensis uncharacterized LOC102457183 (LOC102457183), transcript variant X2, ncRNA 
-TTTCTCTAGTGCTCAGTCATTGCCTAGTGCCAAGGCTCAAGATCTTTCTCTGCCCTGAGCTGAAACCGTTGCATTTGTTACATTTGTTCTAGAGCCACTGGAGCATTTCAGGCCATTCATCTCATGAGACACGTGAACTAAAGACACTTTGCTGGCATGGAGATGGCCAGTTCCTGGCACAGGACCTTTCCAATCAGTACTGCTCTGCATTGCAAGGTGCAGAAGGAAGCAGAATTGCAGGAGTTTGGTCAAATCTCCAGGAGATCATAACAAGTCCATAAGAGTAAGTCACCACTACTTGCAGGGATCTCGTGTGGGGCTGGCATATGCTTCCATTACTTTGTCACGTCTGCTTCTAGTCGGGTGCGTGACTGCAAACATACGAGAAATCTCTCAGAGTACCTCGCCTGCATTTTCTCCTGTTCCCAGACTTCCTTCTTGTGAAGCAACTGGCCCAACAGCTACTTGGCTTCTTTGTGATCTTGAAGACACTTTACACTTAGATTTGATCATCACCTGCTGGGTTATTTCCCCAATCCTCTCGTTTATGCCTTCACAATGGTGATTGTGTTTCTAGAAGCTCTATGTGCAACATCTGGCAAGACACAGGCATCCAAGATGGCTCCGCCTGACTCTATTCTTCATGCCACGGTGCCTTTGCCTGGCTTTGCCTTAATAGTTTAAAACAGCTGGTCACAGATGATTCAGGAAAACATGAAGAGGAAGCGTTATCTGTGTGTGTAGAGTACAGGCGCTACGGTTTTTGCTTCATTCTTCTTTAAAGAACCAGTGCGAGACTCATGTTAGACATGGGGAACAATACCTCCTACGCTACAGCATAGGGAGAGAAAAACACTTTTGGGGTTCTTGCCTTTATGTTCTAGTCCATAAATTCTACTTTGCTATATATAATCCTTAGCTAGAGGTACAGGCAGTCCCTGGGTTATGTACAAGA
->XM_048564862.1 PREDICTED: Pyrus x bretschneideri LIM domain-containing protein WLIM2b (LOC103942600), transcript variant X2, mRNA 
-GCTTTTTATTTATATTTTATAACGCCTTTAAAATCTCTCCCATCGGATTTGGAGGGGTCTCTCTCACGCTCTAATCTCTGTAATTTCATCGTCGTCGTCTTCCTCCACTACGCCGCATCCGCTCCCTGCAAAAAGCCTTCGCCATTCACCGTCCGCCATCTCATTCCTTCTGTACGGAAAAGGACCCATTTGCGCTCCTCACTTTTTTTCGCTCTTTCCATTTTTCAAAATCTTTTCTCTTTTATTCTACCCTTTTTATTTGTCGAGATTTTTTAGCTTCACTCAGTCAGCCTTAAAGCTTTTAAGGGTACGCTTTTCTGACTCTGAAGAATGTTTATTGACTTCAATTTATAATCTCTGCTGCCAGATCTCCATTCATTTGTTCTTGCATTTGTGTGCTTTGAAGGTGGAAGCTTAAGAGGTGGTGGTCTGGGTTGGGAGAGAAGAATCAGATCTAGAAGGAGAAAGAATTATGTCTTTCATTGGCACCCAGCAGAAATGCAAGGCTTGTGAAAAGACAGTTTACCCAGTGGAGGAGCTTTCTGCTGATGGGATTTCCTACCACAAGTCTTGCTTCAAATGCACCCACTGCAAAGGGACTTTGAAGCTGAGCAATTATTCCTCAATGGAAGGTGTCCTGTACTGTAAGCCTCACTTTGAGCAACTGTTCAAGGAGACTGGCAATTTCAACAAGAACTTTCAGTCGCCTGCAAAGTCAGCTGAGAAGTTAACTCCAGAGCTGACTAGATCACCTAGCAAAGCTGCTAGCATGTTTTCTGGAACACAAGACAAATGTGCTACTTGTGGTAAAACAGCTTACCCATTGGAGAAGGTGACAGTGGAGAGCCAGGCCTACCACAAGTCGTGTTTCAAGTGTTCTCACGGCGGCTGTCCTATTACTCCCTCAAACTACGCCGCCCTGGAGGGCATTTTATACTGCAAACACCATTTCTCCCAGCTTTTCAAGGAGAAGGGGAGCTACAACCATCTTATTAAGTCTGCATCAATCAAGCGCACAGCAGCTGCAGCAGCAGCGGCAGCAGCAACAGTAGCCTCCATTCCAGAAGCATAAATTCCATATTTAAATGTTCGATTACATGGCTTTCGTTTGTTTGAGAGTGTTGCATCCCTCTTCAACCTCACGCTTTTCCATGGCGGAGTGAGAAAACTTGGTTCTTCTCTTTTGTATTTGGCTCATCAATCTTGGGCACATTGTTGTGTTTTGCTTCATGTATGTGATTCTGGGTCCGGCAGTTAGTAAAATGACCTTCTTCGGGA
->MG270501.1 Uncultured bacterium clone OTU7751 16S ribosomal RNA gene, partial sequence 
-GTGAGGAATATTGGTCAATGGGCGGGAGCCTGAACCAGCCAAGTCGCGTGAGGGAAGACGGTCCTATGGATTGTAAACCTCTTTAGGCGGGGAGCAATGCCGGGCACGCGTGCCCGGAGGGAGAGTACCCGCAGAATAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATGCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGTGCGTAGGCGGATTTTTAAGTCAGCGGTAAAATGTCCGGGCTCAACCCGGGCCGGCCGTTGAAACTGGGGATCTTGAGTGGGCGAGAAGTATGCGGAATGCGTGGTGTAGCGGTGAAATGCATAGATATCACGCAGAACTCCGATTGCGAAGGCAGCATACCGGCGCCCGACTGACGCTGAGGCACGAAAGCGTGGGGATCGAACAGG
->MT590786.1 Dendriscosticta praetextata isolate 16_52820 small subunit ribosomal RNA gene, partial sequence; internal transcribed spacer 1, 5.8S ribosomal RNA gene, and internal transcribed spacer 2, complete sequence; and large subunit ribosomal RNA gene, partial sequence 
-AAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTATCGAGAGAGGCGTCCCGCCTCGGGGGGGGCTTCCGGCCCCCCGACTCTTCACCCGATGGGTACTCAGCAGCGTTTCTTTGGCGGCGGCTCTTCCGCCGTCCGAGGACCCCCTCCACCACTCCAGTGATTGATGTCGTCGGAGCGCGAAACGAATGAACGCAAAACTTTCAACAACGGATCTCTTGGTTCTGGCATCGATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCCTTGGTATTCCGAGGGGCATGCCTGTTCGAGCGTCATTACACCCGTCAAGCCGTGCTTGGTGTTGGGCCGACGTCCCGTTCCGGGACGGGCTCGAATGGCAGTGGCGGCCCGGCGTGGCTTCGAGCGGAGTAGACGTATGCCGTGTCGCTCGGGAGACGCGTCCGGGTCCGGCCAGTCAACCCTTTTTTTTTCTATGTTTGACCTCGGATCAGGTAGGGATACCCGCTGAACTTAAGCATATCA
->CR627091.1 Homo sapiens mRNA; cDNA DKFZp779E152 (from clone DKFZp779E152) 
-TGTGCAAAACCCAGGAGCCACCCCTGCCAAGTGCTGGGCGTGTCTGTGGAGCAGATGAGGCCACAGGCACTGGCCACAGGACTGCGCTGTCTGGAGAGGGATTCGCACACATTTGCAGGGGTGCAGGGCTGGTGTTCTCAGGATTTTGCCTGGCTTCTCTGGATCCGGAGGTCCTGGGAAGGTGGCTTGGACCCTGGTGGGCGGAGTCTTTGAAGTGCAGTCTGGAATCTTCCATGCACAGTTGGGCGACCTGGACAGTGCCCACTGTGTTCTCTAGAGAGTTCCTCAAGGATGCAGCCCCTTTGTCCAGACACTGTTGCAGGAGGCAGGGAGGGAGGCCTGCCCCATGTCCCCTGGATGGCAGGATGGGCTCCCACCTTGTGTCTGGCTGGGCTGTAGTGTGCGGGGCAGCCAAAAGGCACCCTCCGGGTAATCAAGGCCTACCCCACATGGGGACTCTGGTGAGAACCGGGCCTCCACCGACCCCCTGTCCAGGGTGCAGGAGCCAGGCCCGTGCTGTCAGCTGTGTCTGTTTGTCTGTGGTTTCCCTGTGGCTTCATGGCACATGCAGGTCTCTCTTCATGCTTTGGGTGTGGAAGCCGTCGTCAGCTGAGAGTGTTCTGTGGGTGGGTAGCTCTCCTTCCTCCTGAATTTGGGGTGACCTTCTGTGTGGAGGCCCATGACGGTTTCCCATGCATTCTGGGGCTCTGGGATGCTGTGGGCACGAGTTCTGGAGGGGTCTGCACACCTAGGTTCATCTCACGGGCCTCGGGGTGGGCAGAGGGTCCTGGACTGCAGGGACTTGCCCTTCTTTGCAGCTTTGTGCTTTGGTGGTAAAGAAAGGGCTGTGTCCTCAGCCACACTGGGAGCTGCTGCCCTTGCGTGGAACAGGAGCAGCTGTTTGTGGGCAGTCCAGGTGTGGGCTGCAGGCGGGTCGGGGTGGGCTGCAGGCAGGCATTTAAGGAAGTCACAGCTCCAGGCACCAAGGAGGCAGTGGCTGCTGGCCCTGTCCTTTGCTGCATTTCTGTGGACTCCTAGCCCAGGGAATGGAGCCCTGGAGGGTCCCAGGGTAGTCGGTGTCACCTGAAGTGTCCCAGGGACACCTGGTCCTCTGGCTGATGGGGCCGCCCTGTGGGGTAGGCCAGGCCCTGGCTCTCTGGCCCTCAGGGCAGGGTGCGGGTTCCCCACTTCCCCGGCCCTCACACACACCCTTCCAGCCACCCGCGTGAGCATGCTCCAAACACGGCCTTCTGCCCTTGCCTTTTCTTCTCCTTTTGCGTTTTAAAAATCAAATCAGCGGTTCGGAAGGCCTGGAGCTTGGAGGACTCACGCAGAGGCGGCCTTCTGCCTGCCCTCAGGGGCTCCTGAACTTCCCAGAAGCAGCCCTCCCTCCCAGGCTGAACTTTCTGTCTCAGTCCCCGCACTTTCCCAGCTAGGCGGGCTCCTTGTTCCTGCCCATTTTACTCCAGAAGCGAAGCAGGCAGGCCCGGGTTATCCTGCAGGTGCCAGGAGCCCCCTTGGCCAAGCTCCATCTGTGCATAATGGGGGCTCCAGTGGTTTGGGGGGTTGGTCCATGGGAGAACTGGATGTTCACCAGGGGTCAGCATTGGCCTTGAAGTGTGGAGAAGGGTCATCTTGGCAGAGGTGGCAAGGTGGTGAGCCCCTGGGGCTGAGCACAGGTGCGTCTGGTGAGAGGGGCCTGGCCATGACCGCAGTGACTGCTCTTCACTGTCACCTCCTTTGCTCCTCAGGCCACCTGCGCAGAGGGTGTGATCCTTGCATGACTTTGCCATTGAGGAAATGCAAGGGTAGAAAGTGCAGTCTCGTCGGCCGCCTCGGCCTCTAGAATGCCCAAGCAGTGGTATCAACGCAGAGTCGCCATTATGGCCGGGACCACAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
->JN907114.1 Uncultured microorganism clone GF13U7304JJ6AB 16S ribosomal RNA gene, partial sequence 
-GAGTTTGATCATGGCTCAGAACGAACGCTGGCGGCGTGGATAAGACATGCAAGTCGAACGGGAGAATTGCTAGCTTGCTAATAATTCTCTAGCGGCGCACGGGTGAGTAACACGTGAGTAACCTGCCCCGAGAGCGGGATAGCCCTGGGAAACTGGGATTAATACCGCATAGTATCGAAAGATTAAAGCAGCAATGCGCTTGGGGATGGGCTCGCGGCCTATTAGTTAGTTGGTGAGGTAACGGCTCACCAAGGCGATGACGGGTAGCCGGTCTGAGAGGATGTCCGGCCACACTGGAACTGAGACACGGTCCAGACACCTACGGGTGGCAGCAGTCGAGAATCATTCACAATGGGGGAAACCCTGATGGTGCGACGCCGCGTGGGGGAATGAAGGTCTTCGGATTGTAAACCCCTGTCATGTGGGAGCAAATTAAAAAGATAGTACCACAAGAGGAAGAGACGGCTAACTCTGTGCCAGCCGCCGCAGT
->XM_019753900.1 PREDICTED: Rhinolophus sinicus cytochrome c oxidase assembly factor 5 (LOC109459430), mRNA 
-TTCCGGTTCTTTCCTCCGGACGTTGTTCGCTCGCAGCCGGGTCGCCGCGGTTGCGGACGGAAGCGGTGGGGACGGCGGCGGCCGAGAGGCGCGGCCATGCCCCGGTATTACGAGGACAAGCCGGAGGGCGGCGCGTGCGCGGGCGTGAAGGAGGACCTGGGCTCCTGCCTGCTGCAGTCGGACTGTGTGCTCCAGGAAGGAAAATCCCCTCGGCAGTGTCTGAAGGAGGGAAACTGCAAAGCTTTGAAATATTCATTTTTTGAATGTAAAAGATCAATGTTGGATGCCAGATCAAGATTCAGAGGAAGAAAAGGATATTGACACTACTATGTTGAAACTGAGCTGAAAACAACAAGGGATTTTTTCTGGTCATTAAAACAGAGAAGCCAAAATAGGAAACATACTTTTTCTCACATCCGTTTGGTTAGACCAGTTTTTCCCTCCGTGGGACACTGGAGAAATGCATGAGTTCTAGTTTTGAATATGTATAAATGATCCTCTTGCTCTAAGTTATTTTTAGAAGAAAAATGTAATGGATGAGTTACGAGCTCGGAGTATGAGAATTGTTCTGAAGCACAAAGAATGGAAAGGTTGTTATTTTCAAACCTGACTCCTCAAATGACAATTAGTACATCCTTTGTGAATGTTATCAAGGCCACTGATGGGACTGTTAAAATGAGGAACATGGAGCCTGGGGAGAAGGTATCTATTGGGAAAGTTTAGGATACAACTTTCTGTTATTCATTCTGTCCTGTTTACTTCTAAAATAAACTGTGTTTGATTCCTGGGA
->XM_052447470.1 PREDICTED: Populus trichocarpa kinesin-like protein KIN-10C (LOC7454519), transcript variant X5, mRNA 
-TTTGAAAAAAAAAAACAGAAAAGAAACAGCAGAGCCCTTCCTTCTTTCGACGTCTCTCTTTCCTTCTTTCCTTTTTTATTATCATCAAATTAATTACTACAAAATATCATCCATTTCAATCTCTCTCTCTATATCTCTATCTACGAATTCAAACACTCTCTCTCTCTCTCTCTCTCTCTCTCTCAATCAACCAGGTAAAGAAGAAGAAGAAGCAGAAGCAGAAGCAGAAGAAGAAGAAGAGTAAAGATGAGTGGCGTACCAAGAAAGCAAAACCTCAACCCCAAGGTTCGCGTCATTGCCAAAATCAGAGGTTCCTCACATCTTGACGGTCTTTCAACTTCTTGGATTTCCGTTCACAATAACATACGTGACGGCATTTTTTCTCACTCTCTCACTTTTTCTCTTGGAGACCGACCAGTTGCTACCAGTGGTGGTGGTGGTAGGAAGGAGGCTTATGTGGTGGATTATTGCTACGAACAAAACGAGAAAAATGATTTGGTTTTTGAAAGAGAAGTTAAGCCTTTTATTAATGAAGTTTTTGATGGCCGTAATGCCACGATTATTGCTTGTGGAGCAAGGGGCACTGGAAAATCCTACCTCTTTCAGGGTACGGATGATGAACCGGGTCTGACAGTGTTGGCTGTGGATGAAATGCTTCGATTGGCTGCGGATAACGGGAAGTCCATTGCCGTTTCCTTTTATGAGGTTGATCAAGATCATCATGTCAAAGACTTGTTGGATCCCAATCGACAACAAGTTTTTGTATTGAAGGATGCTCATGGAAAAACACAATTAAAAGGACTTTCTCAGGTTTCGGTGACATCCGTGTCTCAATTTCACAATTTCTATGGTGGTGGGACTAATCCACGTAAATCGATTCAGAAAGCAGTGACTGAACTTCCCAAGAGAAGTCATAAAGGGTTGATAGTATATGTATCGTCTCATGGTGGAGAAAAGTTGGACGTTTCTGTCAGCAAATTGAATTTTGTTGACTTGGCAGGTTATCAGGATGCTAGAAGGAAGAGTATTGATGGACATAATTTGGTTGAGAGTACAAGGAATATTAATAAGTCCATTCATGCCATTCATAATGTTGTTTACTCTTTGAAAGCTAATGAAACTCATGTGCCATACCGGGAAAGTAAGATCACTACCATGTTGCAAGATTCACTAGGAGGGGCTGGCAGAATTTTGATGGTCACTTGCTTAAACCCATCTTTTTGCCAAGAATCTATTTACATGGTGAAATTAGCATCTCGTTCTTGTCAAGGAAGTAGTTGGGCTATCACAGACTCCACAAAGAAAGCCAACAGCTCAGCAAGACCAATGGTGCCTTCTTCACATAATAGCCGGATGCTTGGTAGTGTTTCCACATCTGTGAAGAAACAAATTGTGTCTCGAGGGCACATTTCTGGAAAAAAAGCACACTGTTCAACTTCCACACTGAAAGCTAGGAAACTGTTTGATGAGTCAAGTGATTTGATATCTCAGAAGATTACTGTGCAGCCAAGTTCCTCAAACAATGTTCCAACAGTTGAATCTGTTATGCATGAAGCGGACCAGCTCACTTCAAATGTTGCCAAAGAAGCATCATCTTTGGAAGAAGGTGTATCATTGTTCACTCATGAGGATTCAAACTCTGTTTCTGTGGATGTTTCTCCTGTAGCAGCAATTTCTAGTACTTGTGAAACTACAATACTTGATAAGGAAGTTTCTCCTGTAGCAGCAGTTTCTGTTACTTGTGAAGCTACAATACTTGATAAGGAAGCTTCTCCACTAGCTATTTCCAGTACTTGTGAAATTACCGTACTTGATAAGGCTGACGAGGACCAAAACAAAACTGTGCTTTACACTGGAGAGTTATCTATGTTCAATGAAGGTAAAAAAATAGACAAGGAAAACAACAGTTCAATTGTCAATCAAGGTGGATCGCCACCCATTAGCGCACAATTGCAAGAACTATCAAACAGTTTGAAGTTACTATGTTCCTCAACCCCATCGTGCATGGATATAACACTAAAAAATGATGCATTTCACAATCAAACTTCAACTGATATCGGGGAACCAACAACTCCCAGTTCAAGTATGAGAGTAACAAATAGGGAAATTACAAGCTTTTGTAGTCCATGGGAAAAATTCAACGCCCGCAGCACTGGGATGAAGAACTCACTTGTTCAAGATTATCTTAGATTGTTGAACACAGCTGACAAGGAAGAATTGAGGAAATTGAAGGGTATTGGAGAAAAGAGAGCTACTTCCATCCTTGAACTTCGAGAAGATTGTCCAGAGCCATTTAAGAATCTTGATGATTTGAAAGACATCGGACTCTCAGCCAAGCAGGTAAAAGGATGGCTTAAAAAGGAAGTTGGGGGACTCTTTGATTAGCATGGCAGCTATGATTAATATGTTGGTTTGGAAGATAATTTACTTTGGGCAACCGAAAGTTGCTTTGAAACTTAATTAGAATTGATTGTAAAGTGGTTACTATATATATATAAATTTGGCATGCATTATTATTCA
->XM_013532536.1 PREDICTED: Lingula anatina FMRFamide receptor (LOC106157047), mRNA 
-TACTTATGAACTCCGCTGTGACCAAAAAAAGGAGAAATAAAACACAAAGAGAAAACTGATATTTAAAAAAACTGTAGGTAGAATTGACCTCTGGAAGTGAAAAAACCAGCACCAATATAAACTTTTGTACCTGGACTACCTTATCTGAAGTACTGCTCTGAGGAAAAAGAGTCACCTGTCAAGAATGGACCACTCGGCATTGATATTGGGAACCTTGATTCCAACGGCTGCTGCTGAGCCACAGGGAAATCTCACTGCTGAACTTTACATGGCAGGAGGTGGCGAAAACCAGTTTCCATCCCATGACTTGAGCTACCAGGACAAGCAGCAATGCTTTAATTATGCCAATGGCTCTTTTAAGGATGATGAGCGACTTGAGCAGATACAGTTTGTGATGTTTGGAATAATCTTGCACATCATTTGCATATTTGGAGTTGTTGGCAACCTTGTTTCGTTCTTTGTCCTCAGCAGAAAAGAAATGCGCTCCTCTTCCTCCTGCTATCTTATGGCTTTAATGATATTCAATACAGTTGTCCTACTGACTGCATATTCCAATGATGTTATGACAGGTATTGGAGTGGGAAGCATGTATGGCGCTGTTTCCAACTATATCCTGACATTTGGTTCAGCTGTTGGTCAGTGGTGTTCCGACTGCAGCACTTGGTTGACCATTGCCCTCACTGTAGAACGCTACATATTTGTCTGTCACACTTTTCAAGCTTCAACAATGTGTACCATGCGCCGAGCCATCATAGTTATTGTGTTTTTGTCTATTGGGATGTTTCTTTATGATATCCCATGGTTTCTGCGGCAAGAAGTGAGAAGTGTCACTTGTCCATTTAACGATGAGCCTATCACATACATTGTGATGCGTTCTGAAAAGCATCGCCCTTCAGATATGTACTATAATATACAGCTTTTGTATATTATGCCTGCCTTATTTCTCATTGTGCCCATATTTGTTTTGACAGCGTTCACAGTAATCTTGTTACTTGAGGTGCGAAAGTCAAATAAGCTACGCCAACAGATGTCTACCACACAGACTGCTGAGATCAATGTCACAGTTGTTCTCATCAGTGTTGTTGTGGTTTTTCTTATTTGCACCCTACCAAATTGTATTTTTGCCATTACTCGCACTGTTAAAAAAATTGAAAAAGCAGACGACCCATATTTCGACATTTACTTCACTTTCACTGGAAGAGTCTGTTTTATTGTAGCAAATGTGTTCTTTTATTCAAATTCAGCTCTAAATTTCTTGATTTTTTGTACAGTTGGTCAAAAATTTAGAAAAACATTCAAGCGTATATTTCTTCGACGCTGCAAGTTCTTGACAACGGAAGTGGTTCGTTACAGCAGTGTGAGTGTTGGCTCGAGAACTGGTTCAACCAGGGCAAGCTTTTATCAGACTGAGACAAACATATAGTCAGGTGACAAGTTCTATAGTTATTGGAAATGCAAGAGAGACTGATTTTTTAAATGAAAGTACTATCATTTCAATATTTATAAACATGATTTATAAGTTGCATTGATACTATCATTTTGATTTTGACAACATATATGACCTGATTCTTTTAGAGTTAAAAAGGGTCATTTGCCCATGAATTGATGTGTTTTAATCAGTTTATAAAAGTACAATTAATGAGATTTGATCTATATTCAGGTAGCAGAATATCTGTGGATTTTTTGTTTCAAGGCAACAGTTTCTGAACATGAAAAGGTTAAATTAACCAAAGCAGAGCAGGAAATGTAACTTTTGATGCTATTGATTTTGCAGCTCATGCAAAAATGGACAAAAAATTCAAATTTCTTTAAAACTAACATCAGTTGTGGTAAATCGATTTCCCAGGACGTCACAGTTGGTAGAATGATCCAACAAAAACGTCATATTACAGGAAAGACAAGGTACTAGAAACTAGATTACAGAATGGAGTTCAGGTTCTATTAAGATCTATATTTGTTACTGAATATAGCAGAATTCTAAATTTAAAGGTGCTTCAGAATTTTTTGTAACATGTTGATGGTGTTATCACCCATTTACTACGTTGTGGGTAATTTTTACGGTAATCGTTATTTCGATTAGAGCAAAATGCTTAATGTACTTTGTATACATGTAACATAATTTATACCACTGCTCAAGCAAGAAACAATGGGTCACACCATGACCTGTTCCAAGCAGAGTCGTGGCACACATGGTTGAGTATTGATTCCATTTCTAATTGGTTTTAAATCTGATAAAGCTCTCGTGCTGAAGCTTAGATTTATGTAAAATGGAGGAGTATCCAATTATTTCCACTATTTTACTTAAAACTTTGCGATCTTTATCTTTCATGTTATTGTCACTGCAGAAGTGGTCAAAATATCACAGCTGTTCATTAATGACATGTTTCAAATATGTATCACGAGGCACTTGTGCTTTTTTTTAATGTGCAAGTGACGTGAAATTGAATTTTAATTTAAATATTTATTAGGTAGGTCTGTATTTTACATGATTTGCCAGTGTAACGGTTGTATTTTAAGCTACTTTGGCTGAATGTACTTTTTATGTAAGACTATAGTAAAATAATTAAGTCTGATATTGTTTGATAAGTTGGTGTGGCAGTAGATTGTAATTTTTGTCGATCTATTTAGTTTCTATGTTTGCTTGTTTGAACTTTTCACCTAAAAAATAAATAGTTATGTTTATCATGATCCTACCTGTTTATTGTGATTCTCACAATAAGTA
->XM_030059219.1 PREDICTED: Myripristis murdjan zinc finger and BTB domain containing 5 (zbtb5), transcript variant X2, mRNA 
-AGGTCATGGATGCGAAGAATAGCGTCACCTTGTGAGTCTGGCTGTAAAACACAGTCTGGGAGAGGAAATTCTTAGGGAATATTATACATACATATTCATACCTGAGCGGTGGGGATTGTTAGCTAGTAGGCTCCCTCGTACAGTTTTTGGTGAACATCTGTTTTAAACACAACTTAGCGTGTAAACAGATGTGTGTGTGTGTGTGCTGAAGCTGCTCCAGCCCGTGGATGTAACGGCAGCTCCAGCCAGACAACCGTCGCGGACGCACAGCCACGGCAGTGCCCCCGCCCCTGCCCTGACCATGCACCCTACATACACCGGATAGAGGATAACGGTGGGACACGGAAAAGATTTGGATAAACTTTTGGGGTTTTATCGGAAGAAAGTAGCCTTGCGATACACAAACATTAATCCTGGTGGCCGCATGTGAGTGCTGCTTGAAAGCGACAACTCAGCGAGCTAACGGGCTAGCCTGCTAATCGCTAGCCAGCTAGCTTTGTTAGTTGGTGGTCGGGGGCCCTGTTGTACTTCGCCTTACACTTTTACCTTCACCTGTTCCGGACAATTCAAGGAACATGGATTTCCCAGGTCACTTTGAGCAGATCTTTCAGCAGCTGAATTACCAGCGTGTCCATGGCCAGCTGTGCGACTGTGTTATAGTCGTGGGCAGCCGTCACTTCAAGGCCCACCGCTCAGTGCTGGCAGCCTGCAGCACCCACTTCAGAGCCCTGTTCACTGTTGCAGAGGGAGATGCTAGCATGAACATGATCCAGCTGGACAGTGAGGTGGTGACAGCTGAGGCTTTTGCCGCCCTGGTGGACATGATGTACACCTCAACACTGATGCTGGGAGAGAGCAATGTAATGGACATCCTCCTTGCAGCCTCACACCTGCACCTCAACAATGTAGTCAAAGCCTGCAAACACTATTTGACCACCCGCACCCTGCCCATGTCCCCATCATCTGACAGACCCACCCATCGCCACCCTCAACAGGACCAGCCGAGACACAGGCAGCAGCAACAGCAGCAACAAGTAGCAGATTTAGCAGTGAATCCTAATCTAGCAGCTAATGCCAATCTTGCAGCTAATGCTGCTACATCCAGGTTGCAGCGCTCCTTCCTTCTGCAGCAGCTGGGGCTGAGTTTGGTGAGCTCTGCCCTAGGGGGGATGGAGGAAGATGGGGTGGGCAACGTAGTTGGCAATGGAGTAGTTGAACAGAGAGCTTCCTTTCCAATCAGACGCTTCCACAAGCGTAAGCCCTCTCATGCCCTGGCCATATCAGATGACAGACCTCGGCAGAGGGCGCGTCCCTCTGCCCCTCCTCGGGGTTTGCTGGGAGAGGAAGGGGTTAATGTTGAGCGGGAGGAAGGAGCACTGCTCTCTCCGGATTCCCATAAAATGGGAGATGAATCGAAATTGGATGCTGCAATTGCGGGCCTAGTGGGGGTGTCCCCAGATGATCCTCAAATGCCTAGCCAGTCAGACAGTGGTCACTGTGAAGGAGAGGACTCAGGGAGGATGCAGGGAGGAGTGGGGAAGGAGGAGTACATGGAAGACGGGGATCACCAGGACAATAGAGTTGGGACTAAGATTAAGTCTGGGACGGAGGAAGAGGAAGAGGTGGAAGCACAGGAACAGAAGGTGGTGGTAAAACGAGAACCACTGAGCTCCCCTGAGCCAACAGATGAAACCAGTGATGTAACATCACAGGCAGAAGGCAGCGACACAGCTGCGCCCGGAGGCCAGGAGGAGGAGGAGAAGGTGGAGCTGAGCCCAGAGAGCAGCGACCGCAGCTTTACCTCTGACCCCCAGTCCAGTTCTGACCCTCTGCTTAAGCCCAGCTCCCAGCTCCTCCTCAAGACCAGTATGGGTGGAGGCGCTGGGGCTGAAGGAGGTGGAGGAGGTTTTGGGTGTAGCAATGGATTGAATGGCAAATCTGGTTTCAGCATTTCCAGTTTTCTCAGCCCTAAGGGTTTCAGGGGTGGCGAGGCAGGCTTGGTTGCTGGGGACGATGACCTCCCCAACACAACAACTGGTGATGCAGCCACACATCACTTCCTGCTTGGACAGGAAGCTGCTGGGACATCTGCCTCTGCTTCTAGCTCTCTCCTGCAATCCAGTTCACTGAACTGTGAGAATCATAGCAGTTTTGGAGACAGCCTCCAGGCTGATTCTCTTTTCCTTCGACCCCTGCATGACGGGTTGGGAAGCCCCAGAGGAAGTGGAGGAAGTGGTGGAGGAGGAGGGGTAGACCCCTTTGGTTTGGACTACCAGCGCTCCAGTCTGGGGCTGCACTCCCTGGCACGAGCCACAAGAGGGGCTGGAGGAGCCGCTGCTGCTTCTCTGGGCTACCCAGGCTACCGTCGCATAGCTCCCAAAATGGCCAATGGCATGGGAGGAGAAGGAGATGTGGGTGCTGTGCTCCAGGATGCTGCCTCCTCCTCCTCAAGTCTAGGAGGGCCCCTGCTTCTCAATGAGAGCGGTGGTTATGAGATGAACAGCGGCAGGCCCACTTCCCTTCCCCCTCAGCTGACACGAGCCTCTGCCGATGTGCTGTCCAAGTGTAAGAAGGCTCTGTCAGAGCACAATGTCTTAGTTGTGGAGGGAGCCCGAAAATATGCCTGCAAAATCTGTTGCAAAACCTTCCTCACCCTGACTGATTGCAAGAAGCACATTCGGGTCCACACAGGAGAGAAACCCTATGCTTGTCTCAAGTGTGGAAAGCGCTTCAGTCAGTCCTCCCATCTATACAAGCATTCCAAGACAACCTGTCTACGCTGGCAGAACAGCAACACGCCCAATGCCCTGCTATAGAACTGAGACAGCTGCATCAAAACACCATCTATTCCCCCGCTCCTTAGAGCAAATCATGGTATGGAACTAATCAGGCAAGCTCTCAGTCACAGTGGTGCCTCCCCTGCCTGTTCATGTGGCCTGTCATTTGTTTTGTTACCCACTCCCCTCTCCCGACACACACACGCACACACATACAAGGAATTATCCAGCAGCTGTCATTACCAGCTGTGATGTATACAGTATATGGAAGCCCCGCTTCCCCAGCAAGTTTGCCATCATTACTCTTCTGCTGCCTCTGGACCTCGCATCTTGGAAACTTCTGGGCTCTTCTTTTGGATGCGGTAAACCCCAGTTGTATGTATCCTTGATTCAGATATGGATTCCAGATATATTGCTTCTAAAAAGGAAGTATTAATCCAGAAACTGTTAAGCATCTAAACTTGTGTAAGAACTGGTGGTAGTTTTGTGCGTTCTTGATGTTTCTGTGTACTGTAGAAAGAGAGAGGGTCAAGCTCTATCCTGTGTGCTTGTTGCTACCTCCATTCCCTTAAGAAAGGGTGGAAAGCCGAAGATGTTAATGAGGAGGAGTTAGACCATTCCTCTTCTCGTACTAAATCAGTTCAAATCCATGTGAGATGTTTGACATCTGAAGTTGCCTTTGCGTACAAGCACCTTTTTAATCACCAGTGGTTTTGTTTAGGTTACAGAAGGGGAGAGCTAATTTGTCCCGGCTGGCTTTCTTTACTTGTAGTATCAGTGACTCAGAGCTCTTGCATGCAAAAATAAGGTTTGCACTGACAGGGCATTGGGTCTGTAAGTGACTTAGCTGACGAGTCACTGCTGTGGCCCATCGTGGATGGTGTAAGAGACTCAGATTGTGTTTATGTAATAGTCTGCAGCTGCAAAGATTTAAACAGACAAATCAGGTTTTTGCTCCTGAAAAGTTTTAACATGTTAACATAGCTAGCTTGCAAGCGTAAACTAGGTAGCACTGAGTGAAAACATACAGAAAAAAAACTCTTGTCGACATATTAATTATCTAATGTTTATTCCGGCTGTTGACCACTGGGAAGTTTTGAATGACTGTAACCAACTTCTTAACCATTTTGCAATTGCCTGTTGGAACTATTTATAATACAATGAAGGCACATCAGTCGAGCAACAAACAAGCATGAAAATCTGAGCATCTGTTCCCCCGTCCCAATTCGGCCCTTAAACGCTGACGCCCAGGAAATATACTGTGCGGCTGTAAACTACAAAAAGAACATTCCAGTGCTGCATCCTTTACACAGACATGTTGAGAAACATGTCTTTTCTTAGTAGTATGGTATATTTATATCAGAGTCCTATGGATGGAACTGGATTAAAAAACAACATAAAAGTTAAATTAAAGAAATAATGAGAATCAGCCACACATAATTTAAATAAATGGCGAAATTGTAAAATGTGTTGTTTGAGTGTTTACTCAGATTTTCAATGTCAGCTGTGAACTTTACATGTTTTCAGGGGGAAAACATTAATTGTTTGTCCCGTGGTTTAACCATGTTTCCCCATTTGATCATTTCATATTTGTGAAACAGTCCAATGAAATTTGTACAGTTCCAAATTGTTCAGATAAAAAGTGGCACATTCATTAATTAAGGTACTTAATTTAAAGCCGTATTTGTAGGAAGTTGGCTTCTCCTTTGCCACGCTCTCCGCTGTGGGTAATTTTGGTATCCAAGTGCCTGCTGGGGGCAGCTCTTGCTTACCAGCACTTTTAATTCCTTCAGTTTCAGTGGAACGCAGGTGGCTTTAACAGCCACTACCGCTCGCTTCAGTTGGCTCACTTGGTAATGGGACCTGGTTGAACTTAGTGGTGGTGAGTGAGCAAATCTATGATTGGTACCTAGGTTTAGTGTTGAGGGGTGGAATTGGAACAAGGGTTATCAAGTGTCCTGCAGTAAGCAAACCCAAACAAAAGTAGTACTTTGTCCATTTCTGATTTAAGTTTGAACTTGCAATAGAACAGTATAAAGTGAATATATACTCCTGTAAAAGCTCGTGAAGTTGCTCTCAAATGCTGACATGGTTTGATGTCTGTTGCTGGTAACACTGAACAGTTGCATCAGCAAAGCTAGACATTTACATCACCCTAATTTCTTAATCAGTTTAAGTTTATGTATCATGTTCATGTTTTCATCTAGTCAGCGATATAGTTATCCCCTCACAGCTAAATGAACTTCAGCTCGACTTGGCTCCCAGCCAGGCACAAAGGACTAAGGGTTGCAGATTGCAGGAGGCCCCCTAGTTGCTCCTGATTGGCTCTTTACAGTCAACAACCGCCAAATGTCCAGCCATGGCCAACTTTCTTAGCTGACAAGCTTGTTGACCGTCCAAACACCAGCTGAGTGTCTCTGGTCGCTCAGCTGTGTGGTGAATGAATGAACTCCTCGTGAGCTGTTGAGTGTGTTGCTGGTAATCTGAATGCATGGTAAGATTAAAAATGTGCCGACAAAGGCATCGTTAAGAGAAGGTCTTCGAATAGGTGGCTTTGAGCTGATGTGACTTCTGTTTGTTTTCATTTGCACTTTGTGTGTCTATGCGCGCAAGATTGTGTTTGTGTTTGAAAAGGGCAGTGATGTTGAGTCCAGCATTTTGTACTGAGAGGCAGAGTCAACCGAACTTAGCTGGTTGCAGACTTTTTTTTTTTTTTTTTTTTTTTTTGGTGTACAGCACTTGTTGAACAGTGCTTTCAAAGTGTAAATATGACACATTTGTGATGTCTGTCATTTTCACTTGGAACAGAAATATAAAAAACAACACATAATGAACTAAATGTTGTGTAAAAGTTTGCTACTCTACTTGGTATCAGTGCTTTCTACATATCTCTTATATGTCAAATGTTTCATCCATAACAAAACAAAGGCACTTAGAGACAAATCTTTGTTTTTTAGGATAGTCCAAAAATGTTTACTGGAATGTTGAACTATGTGAAAATATTGCTGTTTTTCAATTATCCAACTCTACATCTCTGATGTCTATTACAATAGGTGTCCAAGCCAAAGCGAGTTTGTTGCATTGTGGTCTTCTAACTAGGTGATTTTTTTATTTATGTCATTGAAGGAAAACCCAAAAGGAAAGACTTCTAAAGAATGGAAATCTAACTGGAAGTGTGGGAGTGTTTGTTCTGTTTATTTGTTTGTTCATTTGATTTACAATTTGTGCTTGTTTCTGAATGCAGGATGGTAACACTCCCCTCAGCCCCATTTTAACTCTCATAGAAACCAAACAATATATAATTTAATAAGAAATTATATATATAAGAAATTCCCCATAGAGCAAAACACCACCATGTGGGGAAGGAATCTTAATTTGCCTTTTATAAGAATAAGCATAATTAAAGTCATCAAACAATCATCAATCTCAGTTTTAGAGTCCTGATTTCCAACTGGTTGGAAACAAGAGAGGCTCCATGGGTAGAAAGTTGGGTAATTGAGATCAGCATTCATGCAGTGCTGTAGACTTCTGCTTTAGTGAAGTGGAGGAAAAAATGAAGAAGAAAGAAAACACCTTAATTACACGTTTGCCTTTTTGTATACTTTATTTCGTGTCATATTGTGTCACCTGCACTGTCACTGAGAATTACAAGGTCCTTGCTTCCATTCCTAGTTGGCACCTTATTGTACAGTCGTTACACTGTTAGTCTGTACAAAACGATCTGACAGTTTTATTTGAGGCAAGTAAATGGATAATTCTGCCTTTTTATTTTGCTAGAAAAATAACTGCCTTGCAGGATGTTCTTACTGTAAACATAAGCTAGTATACTGTTTCTTTGAGTAAGTCTTGAATATACAGAACCAATAGTATTTCAGTCACACTGAGGATATTTTCTAGCTTGTCTTGAGTGTTTAAAACAACCACTGATGGTTAAATCTTGAATCTGACTTCTGTTCCTTAGTGTTCATATTCAAGAGAAAGGAGGCTGTGATAGACCCAATAGCATAAATATTGTTATTATTATTATTTTTTTGTTTGTTTTAAAGACATGGAGGGGAGGGGATATACAGAACCAATGAGAGATTAAGTCATCCAAAATGGCTTCCATGTCTCACACAGTGGCCTGAACAGATCTGTTATGGTGCTGTCTTCTGAAACTGTTGCATGGACAGTTTACAGTATGTGAATCTATGAAAAATGCACTGAAATATTGTTAATTTATTACCCCTGTATAAATATGCCAAAACTAAAATGTGTACAAGGCCTAAATTGACCATCAAATTCACTGCCTTATGTGCTCTAGCTTGAAAAGCTGAGCTTTTATTGATATGCCAAAATTGAAGGATTTTGTTCTTTCTGTATACCTAACATAGTGTAACCATGAGAGAACTAAATGTTTGTCTCTTTACTGTTGAAGGTTATGAAGGATGTACAGTATTTTCAGTTGTTGTATAGACTGAATTAAAAAAATGAAATTTTA
->XM_043813081.1 PREDICTED: Vespula pensylvanica cytochrome P450 9e2-like (LOC122629547), mRNA 
-GTTAGTAGTATTGAACCTCTCGCTAGCATAACGTTGAGTAGTTTTCCACTCAGGATCTTTTAATTAATCGAGCACACGATGGAGACTTGGGCAATGATCTTGGCCTTGGTAGCAGTGATAGTCAGCATTTATTACTACGTCTTTAAGGACTTGAGTTACTTCAAAAAAATTGGTATACCGTATTTAGAACCATGGCCGATTGTGGGCAACATGGGCCCAGCAATTTTACGTCTGAAATCGCTGATTAATATAATTAAAGACATTTACAATCTAAATCCGGAAGCCAAATACGTAGGCTTCTTCGATATGGGTAAACCAGTTTTCTTTATTCGCGATCCAGAATTAATCAAAATGATCGCGGTTAAGAGTTTCGATAATTTCCCGGATCACAGAGGTTTCGTCGACGAGGTACAAGAGCCACTGTTCGGAAAGAATTTGTTTTCCTTGAAAGGCAATCGATGGAGAGAAACTAGAACGATGTTGAGTCCGGCGTTTACTTTGCGCAAGCTAAAGGGTATGTTCAAATTGATGAACGAATGCGGAGCAGATTTTACCGATTATCTATCGAAAATGCCGAAGGATAAGAAAACTATAGAAATGAAGGACGTCTTCGCGAGATATACCAACGACGTAATAGCCACTTGTGCATTTGGTATCAGTATTAATTCTATGAAAGATCGGAACAACGATTTCTACGTTCTCGGTAGAAAAGCAACCAATTTCGAAGGTATTCAATTTCTGAAATTCTTCCTTATTCGTTCTTTCCCAAATATTGTAAAATTTTTCAACGTCAAGCTCATATCCGGTAATATCGACAATTTCTTCACGAACGTTGTCAAGGAAGTAATCGACACTAGAGATCAAAATAAGATCGTACGATCAGACATGATACAATTGATGATGGAAGCTAGAGACAAGAGAGTCGAAATGGGACAAGAATTACCTCTGATAGACATAGTAGCTCAAGCGTTTATATTTTTCTTTGGTGGCTTTGACACCGTCTCCACGGCCATGTGCTTCACCTGTCACGAAATTGGTATCAATCTGGATATACAAAAGAGATTGCAGCAAGAGATCGACGAGGTCATTGAGAAGACCAATGGAAATCTAACTTATGATATTATCAACACCATGCAATATTTAGACGCCGTGATACAAGAATCCCTACGGAGATATCCGATCGTTGTCTTTCTTGATAGAGTATGCATCGAAGATTTCGAACTGCCACCAAGTTTACCTGGAAAGAAACCTTTGTTAATAAAAAAAGGCACGAATGTTTGGTTCCCAGTTAGTGCACTCCACTTGGACCTCAAATATTTCGAGGATCCGTACAAATTCGATCCAGAAAGATTTATAAAAAATGGAAAGGAGATCAACAATTCCGGTGTCTATTTGCCCTTCGGATTAGGACCTAGAATGTGCATTGGTAATAGATTCGCTTTGCTGGAGATAAAAGTTTTGATATTTAATTTATTGGCAAGATGTAGTCTGAAGCCATCCATCAAAACCCAAAATCCAATTCGATTATCCAAGAGTGGAATCAACTTGTCGGCTGAAAAAGGTTTTTGGATGGATTTAGAAGAAAGAAGCGATGTTCATCCTGCTCTTAAAAATATTGTCTGTAATAATAATTCTGATACTATTAAACTATGTAGCCATTAATGGAGTTACTATTGATCGTACTGTTAAAACTTAAGATATAGAAATGAAATAATGAAAATAATTTTATGAAGATAAACTTATGTAATGGATATATATATATTTTTTTTTCGTGATCGAAATGATAAAACATCGAATTTGGATTAAACGTTTACGTATCGTAGTCGGTGCTATTAGGAATTATCCTCTTTTAAATTTCACACAACTATAAAAGCATAACCTCTTGTCATTGAATTACGTATCGTTTTAGAGATTAATACAACTGAAGCTGTTATTTTATTATTATCTTACGATATAAATAACGTATAATTACTA
->XM_001591429.1 Sclerotinia sclerotiorum 1980 UF-70 predicted protein partial mRNA 
-ATGGCTAAAGGGCTAAAGCTTATCACAAATGGCGACGATGCAACCACCCTAACTCAAGCACAGCAGGAACAAGCCGCTGAAGAAAGAATTACTTGGCCGGAGATTGGTTGTATTGGGACATCTTAG
->XM_006974024.3 PREDICTED: Peromyscus maniculatus bairdii hook microtubule tethering protein 1 (Hook1), transcript variant X1, mRNA 
-GGTGCCGTGGCACGGGACGGACGCGGTGGGCGAGGGGGGCGGTCGCGCCGCGGCGACGTCGGCGGCGTGAGGCTTCGCGCGTGAGCGGCGCGGGCGCCAGGCCTGACGGCCGAGCTCCGGGTGGCGGGCGCGTAGGTCGTTGACGCGGGCCCGGGCCGGAGGTGCGTCCGTCGCCGAGAGCGCGGCGTCGAGGTTCCCGGACCATGGAGGACCCGCAGCCGCTGCCCCAGCCCGAGCTGCCGCTGTGTGACAGCCTCATCATCTGGCTGCAGACATTCAAGACTGCCTCACCCTGTCAAGATGTCAAACAGCTGACTAATGGAGTGACCATGGCACAAGTTCTTCATCAAATTGACGTAGCCTGGTTCAACGATTCTTGGTTAAGCCGAATTAAAGATGATGTTGGAGACAACTGGAGAATAAAGGCTAGTAACTTAAAGAAGGTCCTCCATGGAATTACAAGTTATTATCATGAGTTTTTGGGGCAGCAGATTTCTGAAGAACTTATCCCTGATTTAAACCAAATAACTGAGTGTTCAGACCCTGTGGAGCTTGGAAGGTTGCTTCAGCTTATTCTAGGCTGTGCAGTCAACTGTGAAAGGAAGCAAGAGCATATTAAAAATATAATGACCCTTGAAGAATCTGTTCAGCATGTGGTCATGACTGCAATTCAGGAGTTGATGAGTAAAGAAATCGTGAGCTCTCCTGCAAGTGACACCATTGGAGAATTAGAGCAGCAGCTTAAAAGGGCATTAGAAGAGCTTCAGGAAGCCACAGCAGAGAAGGAAGAGCTGAAGCAAAGGTGCCAGGAACTGGATATGCAGGTGACTGCACTTCAAGATGAGAAGAACTCACTGGTTTCTGAGAATGAGATGATGAATGAAAAGCTTGACCAGTTGGATGGCTCTTTTGATGATCCAAATACAATGGTTGCGAAAAAGTATTTTCATGCACAGTTACAACTAGAACAATTACAAGAAGAAAACTACAGGCTTGAAGCTGCAAAAGATGATTACCGTGTTCACTGTGAGGAACTTGAAAAGCAGCTGATTGAATTTCAGCACAGAAACGATGAGCTGACGAGCCTTGCTGAGGAAACCAGAGCCCTGAAAGATGAGATAGATGTTCTTAGGGCTACCTCAGACAAAGCAAATAAACTGGAGTCGGCAGTGGAAGTGTATCGTCAGAAGCTACAGGATCTAAATGACCTCCGTAAGCAGGTGAAATCTTTACAGGAGACAAATATGATGTATATGCACAACACCGTGAGCTTGGAAGAGGAGCTGAAGAAGGCCAACGCAGCACGTGCGCAGCTGGAGACCTATAAGCGCCAGGTTCAAGACCTTCACACTAAGCTTTCCTCTGAGTCTAAAAGGGCAGATACACTAGCATTTGAGATGAAACGGCTTGAAGAAAAACATGAAGCTTTACTCAAGGAAAAAGAGAGACTGATAGAACAGCGTGACACTCTGAAAGAGACGAATGAGGAGCTACGGTGCTCACAGGCACAGCAAGATCACCTAAATCAAGCTGATGCATCTACTACAAAAAGTTATGAGAACCTCGCTGCTGAGATCATGCCAGTGGAATACAGAGAGGTGTTCATTCGACTGCAGCATGAAAACAAAATGCTTCGCCTGCAGCAGGAAGGGACGGAGAATGAACGCATTGAGCAGCTGCAGGAGCAGCTGGAGCAGAAGCACCGCAAGATGAACGAGTTGGAAACTGAACAAAGATTGAGCAAGGAGCGCATTGGAGAATTGCAGCAGCAAATTGAGGACCTCCAGAAATCGTTACAAGAACAGGGCTCCAAGACTGAAGGCGAAAGTTCCAGCAAACTAAAGCAGAAGTTGGAAGCTCATATGGAAAAACTAACAGAAGTCCATGAAGAATTACAGAAGAAACAGGAGCTCATTGAAGACCTTCAGCCAGATATAAGTCAGAACGTCCAAAAGATCAGTGAGCTTGAAGCTGCTCTTCAGAAGAAGGATGAAGACATGAAAGCAATGGAGGAGAGATATAAAATGTACTTAGAGAAAGCCAGAAATGTAATAAAAACTTTAGATCCCAAATTAAATCCAGCATCAGCAGAAATAATGTTACTTAGAAAGCAGCTGGCGGAGAAAGAAAGAAGAATTGAGATTCTAGAGAGTGAATGTAAAGTAGCAAAATTCCGTGATTATGAGGAAAAACTCATTGTTTCTGCCTGGTATAACAAGAGCCTGGCGTTTCAGAAACTGGGCATGGAGTCTCGGCTTGTGAGCGGCACTGGTGCTTGCAAAGACGCTGGTGCGGGGGCGCCTGCACGGTCCTTCTTAGCACAGCAGCGGCACATCACCAGCACCCGGAGAAATCTCTCTGTTAAAGTCCCAGCCGCGGCATCTGACTAGTCCGCAAAGCAAACACGAACAGAAGTGCCTCAAAATGTTTTGTACCCCAAGAAACTACCAGATGGAAAACAAAGGTTAAGATGCTTGGTAGCAGCTAGTTTTGTTTGGATTTTGTTTTGAGATAGGGTCTCCCATCCCCCAAACTGGCACTGAATTGACAGCGTATTCAAGGATGACCTTGCCATCTGATCAGTCCTTCCCTCACTTCCTGCATGCTGGGATTAATAGTTGTGTACCACCATATTGGGTGGATACAGTGCTGGGGATCAAAACTTGCACTTAGGTCAAGCCAGCTACCAACTAGCTACATTCCTAACCTGGGTATCAACTATTTTTATGTCAAAATATATCAAGTTAACATTTAAGTTTACTCTGAAAACAAAATGCAAAATCAGCTCTGTCCCTGGGCAGCACTTTTGAGTAGTTGGAAGTGTGATAAAACAAATATTTGTCTTGAGATGGCATCATGTGTGGGAAAGCAACTGCATATTCCAGCTTTATGCTTTCAGTTGTAACAGCGAGTCAGTTAAGGTAGAAAAGTAATAGTTTGTCATTTAGTAATATATCTAGATTTGCTTTATGGGAAGCAGCCTCCAGTAAGGCATGTAGATAAGAACTGTGCAAAGTAATTTCTTTGACCTGGTGTGTACAAAGCTTTCCTCTACTTGCTAGTTCTGTCCTCAAGAGGATCCTTTGTCATGCTGTGGAATCGATAATGCATGGAAGACTTTACTGTTGGAGTGACTTTGTCCTATAAAAGCGACTGATTGGACATTTGCAGTTTCTCTGAGCTGTATCTCAGTTTGTACATGTACTGCTGTGAATGAAGACTTTGGAGGGCTTGACTGAAATGGTAAGGTGGGAAATAAACTGGTATTTCTAAGAGGTACCTTTCTGTTGGAAAGCAAACTAGAAGAATACATGTTGAAATATCCATATGCTTTTGAGCATGAAATTGTTGTGGCCTTTGTTTTCAAAGAAGGGTATAATTTTGCTTTATTACCTGTAAAGAAACAATGATGAAACAGCTTAGGACCAGTTTGGTTTCTGCTTACCTCTTACGGAGTTTCTGGAGCTGGATTTGTGGCATTCAGTTCATTTCTGCCCAGGGTTGTTCTTTTCAGAGATGTTACTTTCTAATTTGGGGTCACTTTTTAAAGTCACACTTTGGAATATTAGTTGTTAAATCAGTATTGATTGATGTAGCCACAAGTGGTTCATTCTTGTGTCAGACACATTTCCAACACTTAGCAGCCACGTTTCCATCATTGTTGAGAGTTCTGGTGTGATGCAGTGTCACGGTAGATCTTGGTTTTGGTAACTTGGGAAAATTCTTTGATCCTTAGACTACAGAAGTGGGAATAATTCATCTCATATCTAGAGAAGAATCAGATGGTGACAAGAATGCAGCAACACAAATGTCGCAGCATTGTGTATACACTGAACGTTAGCAGGCATTCTGTGAGGGAGTGAGCTTGTGGGCTGCATGATCCTTGATTGGTCAGCTCCTCACCACTCCCCTCAGCATGAAAGGAGGGATGCTAATATGTAAACAAAATGGGTGTGAGCCAGATTAAGCTGGCAGGCTGTAGAGCTGTGGTCTACACTTTATTCTTAGTCCTTCATAAATATGAGTATTGTTCTATTTGAAGTGTTAACTCATGTAGATAACTGCCTTTAAATCCTTGCCCAGTAATTTTTTTAACCACTTAACAACACAAGAATTTCACAGTGATTTGGGGTTTTGAGATTAGTGGCATCTGCCAGGATATTTTGTTTTATCAGGGTTCCTTCTGTTGACTACCTCTTAGATTTTTATGCTTTGTGCATTTAAACTGTTGGTTTGCATTTTGGTATGTTCTTATGGTGTCTGCTTGCCTATGTCTTTTAGTGAAATAGGACTTTGGAAAATACTTTAGCATGCTATTTAAAATTTTCTAAAAATTGTGGCATTTGGGTATATTTTTGTTAATGAAGATATTGATGTTAGTGTTTGTATTTGCTTATAATTGAGATTTTACAAGTTCTCTTTTAATGGAACTTACTGTAAAAGATGAACTTCAATAAATTAATGTTTCTAGTGTAATTGCTCATAAATTTCTAAATAACTAATGTAGCATAGATAAGGACATAAGGATAAGTTTTCTTTTCTTAAAGAAAAGGCAGATTTTCTGATTTTTCTAGTTTTAAGTAGAATTTCAAACGTTTGATACATGTTTATACAAAACTATGTAAAGTTCTATATAATTGAGACTAATCACAGAAATTGAGGCAGTGATCAGGGTGATTCTTTCCCTATGTGGTTCATGCAGTGAGATCGGTGCCTGCCACATATAAAGTATACATGTTTCATCTGGAACCATAATTCTACAAATGTGTTACAAGGGAGGACTGAATGTATAAACATGGAATTGACAAAAAAAATTTATGTCCCAGTGATTATAAAGTTAGAAACAATTTTGAATTTCAAGTGGTTGTCCTTGGATTGATATTCCTTTCTCTTTTTGGATATAATTATGACCAATTGTTTATCTTGGAAATTAACTTAATGTATTGAAAAATATTTGAAGTTTATTCTATTTTTTCCCGTGATTAAAACTAATGATTTAATGTAAGTTAAAAATACCTTGCCTAGCATCCTTTAGCAGAGTATCCCTTAGTAAGATCTGGTAGATTGTTGATGACTAGATGTTAAACACTTCAAAAACACACCTACTTTTGTGTAATGTACATCTGGCCTTTGGGAATGATGGTGATTTAGGCCAGAGTAGTGTCACTTTGTGTAAAAATAAATGTATATGGCTCGTTATACATACAGTCTTATTGTGATCTTGTTTATTGCACAGAAATTGGACACTTATAAAGCACAAATCATCAGAGGAAATAGTGTGTAGTTTATTGAATTTGAGGAAGTCTCAGTACAGTGTTTAGTTTATAAAAAGGTCCTTTCTATTTTCTATGACAAATACTGTCACACTTGAAAAATAGATGCAATACTTGATTTATTTTTGTAAGTATTTAGAATATTATTTTAAATAAATGATTGTCAATATAATTGTGAAATGTTTTGAGTAAATAAACTTCTGCTTCTGTA
->XR_008312440.1 PREDICTED: Hemicordylus capensis uncharacterized LOC128337805 (LOC128337805), ncRNA 
-CGGAGGGTGGCGGACCGCCAGAAGGGTGGCAGAGGCCGAAGGAGATGCAAGAGAAATGGATTGGGAAGGGCAGGATCATCAGAGGACCAACATCTCCCCAGCATAAAGACACTATCGTGGAAATGCAGAATGCATCGGACAAGTACCTAGGCATGCTGCTGACCACCTGTTGGATGCTCACCATGTCCAGCGAAGGGCCATCACACGCCAGACCATTGCGCCAGCTCCCTGCGCTGGTTGGAGCCGCTTCTGGGAGTTCAACGGCCTCCTTCCTCCCACTTCTGGCTGGAGATTCTTCTGGCTGGCAGCAGCACCCTGAAGCCAACACGAGGCTTCTTCCCATCTTGCACTTTGTCCAGGTGGCACCAGCAGCAGCAGCAGCAGCAGCAGCAGCACCAATATTTATATACCGCTTTTCAACAAAAGAGAACAAAGCGGTTTACTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCATATTTCTATGCCGCCTAATATGTACATCTCTAGGCTGTTTACACAGAGAAATAATAAATAAATGAATGAATAATTGA
->XM_024685516.1 PREDICTED: Selaginella moellendorffii transcription factor TCP20-like (LOC112350051), mRNA 
-ATGGGATCTAGTAGCGAGGTCTCGGAGGACATCGAGTGGCACTCCCCGGGAGGAGTGCCAGCGGCGGCTGCGCCATCGCCAGCCCCGCCGGAGGAGGCGAAATTGATCGCGCCCATCAAAGGCAAGCGGAGCTGCGGGATCAGGAAGAGGAATTCGAGCGTGAAAAATCGCAAGGCTGAAGTGGTGGAGGAGGAGCCGGAGGAGAAGAAGTTGAAGAAGGCGGCGCCAAAGCGGAGCTCGACCAGGGATCGCCACACCAAGGTGGAGGGGCGGGGGCGGAGAATCAGGATGCCGGCGGCGTGCGCCGCCAGGATCTTCCAGCTCACGCGGGAGCTGGGCAATAAGTCTGAGGGCGAGACCATCGAGTGGCTGCTCAAGCAGGCGGAACCTTCGATCATCAAGGCCACGGGCACAGGTACCATCCCGGCGCTCGCCTTCTCAGTGGCGGCGCCGCTGGCCCTCCGCCAGGCCGCCGCCAATTACGTCTCGCCGATCGCCGTCGCCACCCGCTCCAGCCTGCCGCTGGATTTCGCGGCGCCGCGAGTGGACAACGCTAACGCCACCACCACCACCACCACCACCACCACCACTATCACCACCGAGGGTGGCGGCGGTGGTGGCGGTGGCGGCGATGAGAACTCCAACGAGAGCCATCGAAGGTACGAGTTCCAAGAGAATGGGGACAGTGGATCCATCGGAGACGATCATGGAGAGGGGAACGCCAAGAACTTGCTCACTAGCTTGAAAGATGATCCACGATCTCTCCAATCCAAGCAACAGCAAGCTCTCGACGACCACCACCAGCATGACCAAGAAGAACTCGCGATCCATCACCAGCAGCAGCAAATCTCTTGGCCCGTGCCAAACCTGTGGATGCTGCCAGTTCCATCTATGGGTGATCACTCGTGGGCATACACCACTTCGACTTCGTGTCCCTCGAGCTTCTCATCGTCGGCGGCGATGATCCAGCAGCAGCTCCAGCGGATGAATGCGAGCAGCCTGATCGAGCTGGGGCCTCTGGGATCGATGCTGGCGATGCAGCATCACCCGGATCTTTGCGCCCCTGGCAGCGATAACTTCAACCTCTTTGCCGCGACGTACCACCACCATCTCCAACGCCAAACATATGATCCTCACGTTACTTCACGAGACGATAGCGGCTAG
->XM_053129038.1 Zychaea mexicana uncharacterized protein (BDB00DRAFT_931432), partial mRNA 
-TGCCACGATGGCCCTGGTATCCTCACAGGCTGTTACCAGAAGTGTCATCGCCATGTTAGTCCAGCCATCGAGGAAACCATCCACCCAGATATCCGGACTGCACCTCATCGACTGACTCCCACGAGCACCGTGACCGCACCATCAGCAGAGCCTGCAGATGTTTTTCCGTTTGGTTATGATATTGGGAATAGCCGCCGTGCGCAACGAGAGCGCACCCAGAACGCAAGCAAACGAAACGCAAAGGCGCAACGCACACCACAGAGGAATACCAAAGATGGCGGAAGAAAAGAAAGGGGGGCCGGAACGGAAGGCAGATACGGAACATACTGAATAGATCTTGGTGAAACACCGATCAGCTATGCTCAGGAAGAAGTTGTCATTATTGGGATCACGTAATTCAC
->XM_050140454.1 PREDICTED: Microtus fortis uncharacterized LOC126500504 (LOC126500504), mRNA 
-CTCGGATCCCCCGCACTCCCGGAAGAGAATGTCCACCGCTCCTGCGGGAGAGGAAGGCGAGTTTTGCAGCCATGCTCCGCAGAGTGGCCCGGACCGTGGTCCCAGGGCTCAAGGTGCCCTGGGCGCGGTGGTCTAGGAACTGGGCGGGGGTCCCAGACCAGGTGGTAGACCTGCGCAGCGACACGGTGACCCGGCCAGGGCCGGCCATGAGGCGCGCCATGGCCGAGGCGGTCGTGGGAGACGACGATTACGGCGAAGACCCTACGGTCCTCGAACTGCAGGAGAAGGCTGCAAAGCTGCTTGGGGTGGAGCAGACCCTGTTTGTGCCAACCAACACCATGGCCAACCTCATCTCTGTGATGGGTCACTGCCGGCGCCGGGGTTCCCAGGTCCTCCTTGGGCAGGAATGCCACCTCCACATCTATGAGCAGGGCGGGGTGGCTCAGATCGCCGGGGTGCATTCCCAGCCCCTCCCAGACATGCCCCATGGCACCTTGGACCTGAACGAGCTGGAGAGGGCACTCTCTCGGGGTTTCAGGAACTCCTACCATCCTGTCTGTGAGCTTGTGTGTCTGGAGAACACACACAGCAGCGCAGGGGGCCGGGTCCTTCCCATCCACTACCTCCGCCAGGTGCGCCTCCTGGCCCACGCCTACGGAGCACGGGTCCACCTGGATGGGGCGCGGCTGATGAATGCAGCTGTGGCTCTGCGTGTGCCTCCCGCCCACCTCGTGGAGCACTGTGACTCCGTATCCTTCTGCTTCTCTAAGGGTCTTGGTGCACCAGTCGGGGCGCTGGTCGGTGGAGCCAAAGGCTTCATTGAGGAAGCCTGGCGCCTCCGCAAAGCCCTGGGTGGAGGCATGCGCCAGGCTGGAGTACTGGCTGCGGCTGCCATGGTGGGACTGGCTGAGGCAGAGGAGGTGCTGCCAAGAGATCATGAGAATGCCCGGAGATTCGCTAAAGGACTCCGGGACCTGGCATCACCCATTTGCTCCGTGGATCCCGACACTGTGGAGACCAACATGGTGCTGGTGCAGGTGGCGGGGCGGCCTCCTGCAGAACTGTGCCAGCGCCTACAGGCTGTGAGCGCCGAGGAGGTGGCTCAGACTGGCCGCGCTGTGAGCGTGCTGCTCTTTCCCTGGACAGAACACTCCGTGCGGGCCGTGTGGCACCGGGATGTGTCTGCTCAGGACACGGAACTGGCGCTGAGGAAATGGGAATTTGTGCTGAGGCAGTTGAGGCCCTGAGATCAGGGGACCAGGAGCCCTGTGCCCTGGCTAGGATTGAAGTGTAGAGTAAGCTGGTCCAAGCCATTAGCCTAGTGGAGGCCCGCCCTTCTGGGGGATGACGACACCATTCCGGCCTCTGAATTCCTCCACTGACACTCATGTGATGGCCTCATTCAATCAGGAACAACCAGGCACGGGCTGGGATAAGAAGGGGCTGAATATCAAGAGAAGGGAATGAATTCAGGAAGCAGACCTGGGGCTGGGACGTGCAGCGTGACTGCCTGGTGTGTGTAAGCCCCGGGTCTAGTCCCAGCACTGTATAAACAGGTGTGTTGACTCACACCTGTAATCTTAGCAAGCTGAGAAATTAGAAGTTCAAGGTTGGGCTGGAGAGATGGCTCAGGGGTTGAGAGCACTGGCTGCTCTTCCAGAGTTCGATTCCCAGCAACCACATGGTGGCTCACCACCATTTGTAATGAGATCTGGTGCCCTCTTCTGGCCTGCAGCCATACATGCAGGCAGAGCACTGTATAGATAATAAATATTTTTTTTTAAAAAGTTCAGTCATTCTCAGATACAGAGTTTGATTCAACCCTGGGCTACATGAGACCCTATCTGCAAACAAACAGATCCTGTGTGACTGGCATAGTTATTAGAGATGGACTGTAAAATAATAATGTGGGATTTCCTTCTGTGTGCTGTGATTACCATTAATGAATAAACTGCTTTGGGCCTGTTGATAGAGCAGAACTTAGATAGGCGGGGAAAACTAAATGGAATGCTGGGAGGAAGAAGGCGGAGTCAGGGAGCCGCCATGGAGCAGCCAGAGTCAGACATGCCAAAACTGCTGATAAGCCACTGCCACGTGGTGATACACAGATTAATAGAAATGGGTTAAATGAAGAGGTAAGAGTTAGCCAGTAAGAAGCTAGAGCTAATGGGCCAAGCAGTGTTATAATTAATATAGTTTCTGTGTGGTTATTTTGGTTCTGGGCAGCCAGGATGAACAAGTGACCCTTCCCCCAATAAAGTATTGAAGGAGCTGTATTTGTACTTTTAT
->XM_025755560.1 PREDICTED: Arachis hypogaea protein LURP-one-related 10 (LOC112703951), mRNA 
-TGCATGAAAAATATGAGAACCAACTACTTCATCTCCTATATATGATAGTGTTCTTACTTCTTACAACTGAAAAAGGAAACTCTTATCAATTAATTTGTGAAGTAATGGAGGCAAGTGCACCTGATTTTGCATTGGCACATGGGTTCCCCATGAATATGATAAGTGTAGTAGATGATAAGTTCTATGTTGCAAACCCAACAGAAATGATTGTGAAGAAGAAATACAATGGATTGTTGTTGAAGCAACGTTACAAAGTGAAAGATGTTAATGGGAAACTCTTGCTTCAAGTTGATGGGCCAAGCTTAAGCATCCACAAAAAGAGGGTTATGCGTGATGCTCAAGGTTCACCAATCCTCATAATGCAAGAGAAGGTTAAAATGGTATCGCTCCGGCACAGGTGGACGGTTCATAGAGGGAAAAGCTCAGATGATAAGAATGTGATATTTGGGGTGAAAAGGTCACACCCAATGGACATGAAACCACGGCTTGATGTGTTCATGCCTGGTAATACTGATGAAGATGTAAGCAACTTTCAAGTTGTTGGTAGCCACATTCAAAAATCTTGCACTATTTACAAAGGTGACACCATCATTGCTCAGGTAAGTGATGTGTTCCCAAGCAGAAACTTCAGCAAATGGAAAGAAAGCTATAAAGTGAAGATTAATGAAGGGGTGGATTATGCTTTCGTCATGGCATTACTTGTAATATTAACCGTAAATGACTACATTTGAATTTGGTTTCCCTCAACATTAAATCAATAATAATAATAAGAAGTAGGAGTGGGAATATGTACCTTACCTGCAGGTACCCAATCCGATCTTACCTGATCGGGTAGGGTTGTCAACCCAATCCGCAGCGGGTAGGGTAGAGTGCGGGTAGGATTTTCATGTAGGTCGGATAGAGTGCGGGTTGAACTTCAATCCTACCCGACCAACCCGCACCCTATATATGTATATGTTATATACTTATATAAAAATATGTTCTAAGTGGATGTTGAA
->XR_004838883.1 PREDICTED: Vespa mandarinia uncharacterized LOC118444101 (LOC118444101), transcript variant X2, misc_RNA 
-GATTTATATTTAATTTAAAAAATTTTTTTTCTTCAATAGTTCCTAAATAAAAAATTATTTCTTATTTTCAAAATCAAAAATGATAGTTCCTAAATATCTATTTTAATAGTAATAAAGTACTTCAATGGCAAAAGTTCGTAAGTCCATATTCTAAATTATATCAATCTTTAAATTAATTTTATGAAGAATTAATATTAATAGTACAATATGAATATTATAACAGAGGATGATAAATTTGTCCCATTACATTTTGTATTTTGTAATTTTTATGGTGAAGATACATGTTTTTGTTGGAACGATGATAAATTTGTTATGTTTCCATACATACAAGAAAAATATACATCTTTGCTGCCAGTTTTGATTGCACCGAGGCAAATAAAAACTATACAATGTTTTTCCAATAGAGTTTTCTTTACATGTTTACCCCATGGTGTATATAAACTTTCAAGAGATAGAAGATTCAGTGTATTAAGTAAAAGTGCTATAAGTGTTGGTTCCATATTTTTTGAGATACTTAAGACAAAGGATGATCACTTATATTTGGAAAATAAACAGAACAAATCGAGTAAGATATTACTCCATTTGCCACTCATGTCAAAACAACTAGAAGAATTATGTACTTTTCCTTTGAACATGGAAAATTCAGAACATGAATTTAGAAACATATTACTAGATGAAATTGATATGGTAGATAATTTATGTTTGATTGGTAATGGTAAAAAGTTATTTACTTTAACAAAAGAAGTAATTCATTTAATTCATAGTTTTGATAATAAAATAATAAACATTGTACCTATACAAAATGACAAAAAGATTAATGGATTAGTACTTATAACAAATACAGATGCAATTATCATTGTGCATTCAAAAAATAATATATTACGCTATAAAAAACTTTATCTAGGAGTAAATGTTAAAACCCTTTGCGCAGGACTTAATCATCAATGTAGCGATAAAATATGGATTGTTTATTCCGATGAATCCAAATTGTATTACATGATAATGACACTTTCTACCGAAATATATAAGAAAGTAAAAATAGAAGAAAAAAATTTTATTTGCCTGCAATATTATGAAAAAGATAAATTTGTAGGTCTAACTAAAACAAAAGAACTTCATGAATTATCCATTAATACAATAGAAAATTGTGTAAATGAAGAAATTTCCAAAGATGATTTTATAAATCTTCATAAAGATATGTTAAAAGGTACAGATTTAATTGTTGAACAAATCTATGAAAGAGCAAAAGAATTAGAATTGTGGAATAAAATACTTCTTACTGAAGAAGATAAACTTTATAGAATAAATCTTTATGCTTGCAGAAAGAAAATACAAATGTATCCTAAAATGACAGTATATAGAATAGCAAAACAATTATTTCTTAATATAGATTTTCAAGAAAATTTACCAAAAAATGTTTATATTGTTTGTTTCTTAGTATCCAATCATGAAACAACTTTCTCTATCAAAGAAATAGTAAATAATGAAACTTCAATCGATTTACCTATAGTAACAAAAAAATTATTTAATTCTTTACAAATCAGAATGGATTTAGTAACAATCATAAACGTAGAACAACCATGGTTTCTTATAAAAGATTTTGTAACAGATCCAGTTATAGAGAAGAAAAAGAAACAAAAAGAAATGCAAATTAAGAGAGATAAAACAAATTTTATAAATGCTAAAATAAATCTTATAAGGAATTTAATGTTGACAAAAAACTTAACTATGAAGAAATTATCAGAGATGAAAAAGAAGATAAGAAAAGAAATATGTGACTTTTAATTTAATAATGTAAGCAATCATTTCATAACATAAAATGTCTTATGTTATTACTATCACAATTTTTTAAAAAAGTTTATAAAATCGTTTATGTAATTAAGAACTGGGCATTTCTATTATACTTCCAATACTGCAACTGGAACTCTTTGGTTGTTTCACAGAATTTCTAAAACTATTTTGTATTCTGGGACCACCAAGTCGATCTTGAAGTGTATCTAATGATTTAGCACTTTTCTTCGAACCATTAGCACTACGATCTTCTTGTTCATCGTTTTTATTGGAACGACGTTGTAGAATTTTGGTAACACAGACTTTAAAGTTTTCTGAGAATATACCATAAAGAATAGGATTGACCACTGTATTCAATTGAGCTGTAATAAGTGCCCAAATGAAATGATGCGATCTCATGAAAAAATCAGTTTGTTTAGGTGGTCTCTGAGCATCAATGAAAAGCAAGAGAGCGATGATCGTTATTGGCAACCACATGACTAAAACGGCAACTACGTTTAATAATAAAATCCGCATGACACGTATATGCTTGTGAAGACGGACTTCCTCGTGTTGTGACATACTACCAGTTCTACCAGTACGTTCTATAACTGATGATGTAGATAATTTTCTTCCAACCCATGGTATTAATGATCCTACCACCGATAATTCCGAATCTCTTCTGTTTCCTTTACCAGTTGTTAAGTCCTATAAGATATAAAATTTATCAAATTAAATTAAAAAGATTTAGCAA
->XM_033905725.1 PREDICTED: Pecten maximus uncharacterized LOC117343383 (LOC117343383), mRNA 
-TACCGCCAGAGGGCAGTATGTCTCGCATTACTTCCGGATAGTTCAGTAAACAATGGCGGACCGTAGCAACAGTATAAACAAAGAGAATGAAGACGTGAACCTGCAGACAATTGATCGGCTTACTGTTCAAGAATTGAAGAGTTTTTTGCGCCAGCATGACCAGCCAGTTAGTGGACGATCAACTGAATTAAAGGAACGTGCGAAAGGTGTGTTGAAACTTGGTATCAGACGGAAAGATATACTACAGCGGGAAGATGAAAGACAATCCACTCTCTACCAAGCCCGTAAGTTCGTGTCCCCTCTTGGCGAAATTTTACCCCACCCATCCACATTGAAGAACTGGACCGACAATGCTAGGCAGATACCTGTGTTTCTAGAAGATGCCTTATATAATTACCTTGTTCTGAACAGACAGCGGACGTTTGATAATGCTCCAATGGGTGCTGTTAAACAACTTAAAGCAAAGGTCTTCTATGAAGATAGTCATGTTCACCATATACGATACAGCCCTATCACAGACCTCTGTTCTCACTGTTATGTATCATGTAAAGTGGTACCATCCATGCCAACGGCAGATGTGAACAAGTCTCCTGACTACAGTGTTTGGATATGTATATCGAAGCAGACTGGACAAGTGCATGCAGCTGATTGTAACTGTCCTGCAGGAAATGGAGAATCGTGCAACCATGTGGCAAGTCTTCTGTATGGCCTTGTTGACATCACAGAGAAGAAGCAGTCTGGGGAATTAGCGCCAACCGCTGAACCCTGTAAATGGAGCCAGCCAAGAAAGAGGAAATTGTCCCCCAAAAAGGCAGAACAGATGAAATTTCGAAAATACACAAATACTGGTAATGCTGATAAATCAGACTACACATTATTCCGACCATCTGGAGTTCAGCCACCATTGGATAGGAATTCGTTCCTAGCAGAGATGAAGGAAGTCTTGCCAAATGCAGGGTACATGAAGCTGTTTCCAAAACAGAAAGCTCCAGAACATGTCTTACAAGAGTGTTGTTTACCAGAACCAAAATTTAATTTTCATAATAGTGTAGACTTGTCTTCAAGTGCTTGTCAGATTGAGTTTGATAACTATGTACAGGATTTGATAGACAATAGTGCATGTACAGATACTATTGAGGGATTGACCAAAGGACAGAGTACAAATGATGTCTGGCTGAAAGCAAGAATAGGGCGGATCACAGCATCGCGTTTCGGGGTAGTGTGTCGCAGGAAACAAGATGTAAATCCAAACAGTCTGGTAAAATCTGTAATGGGTTATTACTCTGATAAAACCAACGATGGAATGGAATGGGGGATTAATCATGAAAGAACAGCCAATCTGGAATATATTCAGAAGATGAGAAGCAATGGTCATAGCTCAATAACTGTGCAAGAGAGTGGACTGTGTGTTATGGTAGATCATCCATATATAGGTGCTAGTCCTGATGGTTTTGTTTCATGTGGTGACTGTGAAGACAGTAAAGGACTGGAAATCAAATGTCCTTTCAAATATCGAGACTTTTTCTCCAAAACATGCTGCTACACATAA
->XM_034976728.1 PREDICTED: Maniola hyperantus cytochrome c oxidase assembly factor 6 homolog (LOC117989378), mRNA 
-AGACATTTGTCAAATACGAAATATCCGTCCTACAATTTTCTGCGAGGTTATATTTTGCTCTCAAGATAAAAAATCGCTAATTTCATTATCTAAATCGAAAGCTTCATCAAGATTTGATCTTTGAAACAAGTACATAGGCTCAAAGATGTCATTTCCTGATAAACAACAACGAAAGATTTGTTGGGATTCTAGAGACCGTTACTGGGAATGTTTAGACGATCAAAGTATAAAAGACAATTCGCTAAAGCCTAAAGTATGCGCGGAGCTTAGGAGAATATTTGAAAAGTCGTGCCCCCCCAAATGGGTGACCCATTTCGATAGGAAGCGAGACTATGAAATATTTAAACAAAAAATGCAAAAAGAGGGTTTTGACCCTATTAAAGACAGTAAATAATTACTCTAAGTAATTTATTTAATTGTGATTGTAAATATAGTTTATTTATTTAGTGAAGTAAATTGTTTTTATTT
->XM_046179821.1 Filobasidium floriforme uncharacterized protein (HD553DRAFT_310221), mRNA 
-GCGAGCTACGTATACATCAACCGGTAAACGTAGCTGTCGAACAGGCCACGTTAAGGACTTCCATTAGGACCGAGAAATGCAACTGACCGACGACCGACCTACCCGGGTCAACCGATATTCGGCTCCCCCCTTCTTCCCTGTACCGGCACTCCTGCTCGTCCTCATACCTTTCCAACTCTTCGTACACTTCTCTTCGCACTCGATAGCCGCCTACGTCAAGGATACAGTCGAGGGTCTTCTCGGGAAGGGGTTCGTTGCTGCGAGTTTCAAGTTTCTGCTCGGAGCCGTAAGCACCTCTTGCCCGTCGTCCACCGCATTTCGCCGTCTTTACAACTTACCGGACTCGACCTTGTTTATCGAAGCACGGAGCGGAAGCCTCGTACATGCTATCCCAATGCATCAAGTATCACTGCCCAGCGGATGTTGGTGCCAAGTACGTCGTGACCACCCTCTTGTTCGGGTTTGTGGGGATACAACAGTTCAATCGGCAAGCGAGGATAGCGGAGAAGGGGAAATCCAAGGGTCTTTGATGAGGGAGACGCTTCTATACCGGGCTTGTGGCCGTACAAGAGATGTCGAGATTAGGATGATCAGAGATGGACGAGATGATAGTCCAGCTGGCGATCGCGATAGCTGTTCAGCTAGCTAAAGGCGACCTGGGTAGTCTTGACCATAACCGTGCGTTTTGCGGGTATGCGAGCCGACAGTATCAGCGGGAGGGATCGGAGACCATGACAACAGATGACGGAGAAGTTGGGCATGGTCATCGGGCTTCTCTTCATGTTGTCATACTTTTACATCTACTCTAGGCGAAATACAACTCGTGACA
->XM_009314119.1 Trypanosoma grayi hypothetical protein partial mRNA 
-ATGCCCTCAACGGGTTCCGGCTACACCTTTGAGGACTTCCTCAAGCGGATGGAGCGCAGCCCCACGTCACATATGTCGCCACTCTACCACGAGCATCGGGAACTATTCGTTGGCCGCCCCGACATGTTCACTCGCGCTATTAGCTCCGTTTCGTGGGAGAAGGGGTGTGCGTTGGTCGACGCCGCCTACCACTCGCAGCCCATCGCAGTCGACACGTACCGTGCCCTGCTGGCCCGCATGTTGCTGCACAATCGCCATGTACAGCGCAGCGGTGCCGGTAGCCTTGTTATGTGGAAGGCGGCCTTCCGCACATACTCGGAGGCCATCCTTTCCCACGGAAATGCTGTTCCCACACGCATGACTTTATCCACGCTGCGCTTGCTTGCTCCGCACCGCCAGTGGGAAGCCGCCGTGTCTTTACTGAAGCTCAGCCAGGCGAACGAGAAGCTGACACTTCCGATGCTTGTTGACGCCGCTCGTTGCTCAGCGACGCCAGCGACGTGGCCTATGGCATTGGACTTTCTCAGCATGGTGCATGCGCAGGCACCCAACATGCTCGCTGATAGCATACAGAGTCTGCGGCCGCTTGGTACAAGCGCCGCAACAGTATCTGCTGCTGCGAATGCGATGCTGGTGGACAACAGCAAGGGGCCGACGGCAGAACAGAGACACGTTTTGTCGGTGCTTAACGATGTGGTAGCGGCTGTGCCATGGAAAACGGCACTGTCGAACGAGATGTGTGTGTCCTACCTCACGTATCTTGCCGCGAGTACGACGTACCCATCGCAGGAAAAGACTGTTGCGCTCACAGCCGTGTTGCGGCAGTACCCGTGGGAGGCATTCAAGCAGCTGATGATGAGGCAGAGTGTTGTGCTGCCGGCGGTCTCTGGTGAGGCCACTTCGCCGCCAATCCCGGAGGACAAGAAACTGCTGCATCAGCAACAGGAGTATAAACTGGAGGCTTCACCACTGAACTACCCCGCAGTTCAAGAAAGCCTGCTGCTGCTTAAAAGTGAACCCGAGACAGCGGTGCCATTTATTGCAGCTATCGTTGAGAAACTTCCTTCCGCCGAGGTCTCCGCCTCGTTTCTTCACGAGACGGCCGACATACATCGCGACACTAGGGTTGCCGCTGCGCTGCGCCACCCCTTGGTGGTGAGTGCCCTGCTGCGAAAATGCGCGGAACATAATGAATGGCGTCTCGCGTCCTCGGTAATGCTGTCGATGTCCCCAAGCACGATTCCATGCGACGTAGCCAGCACGCTCGTGCTGCAGATGCGGGCTGCTAAACAGGCATCCCTGGTGGTGGAGATACTACAAAAGTGCATTGTGCCCTCAAGGACCATGCTGACGCAAGAAGCAATGGAGGCGGTGCTCCTGTGTGTGCTCGCACATAATCGCGCCATAACCGAAACCGCATCACTCACATTCCCCAAGACGCGAAATACGAACACCACGGCAGTGATACACTGGCGCTCTGCGTTGAGTTGGGCGGTGGACTTGCTGCAGGACGACACGGAGGGACGCATTGTGGAGACAGGCTCCGCTCCCTCCAAGGGCGCCGTGAGACACACGCATACCAAGGTGATTCCACGCCTAAAGCCCATGTCTTCTCGCATACTCAGTCTTCTTATTCACATTTGTGTGAACGCCGGTAGTCCGCAAGGAGCATTGCAGGCAATGGGATATGCTCGCACTGTCAACAAGACGGAGTTGGCCATGTCAGATGAGATCCAAGCGCTTCTGTACTGCATGCTGTACGACCG
->XM_020925385.1 PREDICTED: Boleophthalmus pectinirostris protocadherin beta-15-like (LOC110160707), mRNA 
-ATGATGGAGATTAAAAGGCCATTTGCAGTGGGAATCAGCGCGTGGATCGTTTTGTGTTCGGCTCTACTGCTGCTTTTTGGACAGTCCGTTTTGGCTCAGATCAGATACTCTGTTCCGGAGGAGGTGAAGGACGGGACTGTGGTTGGAAATGTGGCAAAGGATCTTGGTCTTGATGTTGCCTCTTTGGGTGAGAGACGGTTCCGTATTTCTGAAACAAAGGACACTATATTTGCTGTAAACTCTGATAATGGCGCTTTGTACGTCCACGGGCGCATTGACAGAGAGCAGCTGTGTCAGGGCAGCGGTACGTGTCTGATGGAGCTGAAGGTTCTGGTGGAAAACCCTTTGGAAGTTCACTATGTTGTTGTAGAAATCACCGATGTAAACGACCACGCGCCCACCTTTCCCAAAAGAAATGAAACCATAGAAATAGCGGAACATACCTTATCTGGAAAACGATTTCAGCTGCACTCTGCTCATGATCCTGACGCAGGGATGAACTCAGTCCGCACGTACAGTTTGTCTGCTAATGAACATTTTGACATTAATATTCGCGAAACTAATGGTGAAAAAATACCATTTCTAGTTTTGAAAAAAATGCTGGACAGAGAAAAAAGCAGTGAACATTCTTTAGTGGTCACAGCGGTTGATGGAGGTAAACCCCAGAGGTCAGGCACACTTAATGTTACCATTATTGTTCTTGATACTAATGATAATAGACCAGTTTTTAGTCAAGAGATTTATGAAATTACAGCGAAAGAAAATCTACAAACAGGCACGTCAATTTTTAAGCTCACAGCTACAGACCCAGACGAAGGAACAAACGGAGAAATTGATTATAGTCTGGCAAAAATATTAAAGCAAAGAATCTATGATATTTTTGAATTAGACACGAAAACAGGAGACATTGTTGTAAAGGGGCACATCGATTACGAAGAAAATGATTTCTATGAATTGGAAGTGCAAGCGTCAGATAAAGGCACACCTCCATTAACAGGTGAATGTAGAGTTATTATAAAAATCATAGATGTAAATGATAATTCTCCAGAAATAGACGTGACTTCTCTGTCAAACACAGTGTCTGAAGACTCCAAACCAGGGACAGTAGTTTCTCTCATTCGCGTCAAAGACAAAGACTCTGGTGTCAATGGTAAAATCATCGCTCACATAACAAACAACGTGCCTTTTGAACTCAAACCCTCGTATAAAGAAAACACATATTCAGTTGTCACTAAGGATTTCCTGGACAGGGAGGAGGTGTCACATTATGACATAACTATAAAAGCCACTGACTGTGGGGAGCCTCCTTTATCCACCACTAAAACTCTGAGTATTCAGATATTAGATGTAAACGACAACAGTCCACAGTTTGAACAAAATCCTCTGTACTTTTATATTGTAGAAAATAACGTGGCAGGGACGTCACTGTTCTCTGTAACTGCATCAGACAAAGACAAGAATGAAAACGCAGATATTTCCTACAGCATTGCGCGTGCAGGACAGGAGAAGGACGTGACGCTCTTTTTAAACGTGAACGCGGAAAATGGTCAAATCACTGCTCTGAAAAGCTTTGACTTTGAGACATTAAAGTCTTTCCAGTTTCAAGTCGTGGCCTCAGACTCTGGGACTCCGTCACTGAGCAGCAACGCGACAGTGCACGTGTTCATCCTGGATCAGAACGACAACGCTCCAGTCATTCTGTATCCAGTCAGGTCTAATGGTTCTGCTGAAGGAGTGGAGGAGATCCCCCGCAATGTGAACGCGGGACACTTGGTGACTAAAGTCAGGGCCTATGACTCTGATATCGGATATAACGGCTGGCTGCTGTTTTCACTGCAGGAAGTGACTGACCACAGTCTGTTTGGGTTGGACCGCTACACAGGACAGATCAGGACACTTCGCTCGTTCACAGAGACAGACGAGGCCGAGCACAAACTCGTCATACTGGTCAAAGACAATGGCAACGTGTCCCTGTCAGCTACAGCTACTGTGCTCGTGAAAGTGGTGGAGCCCAGAGAGGCTTTTGCAGCTTCTGACGTTAAGAGCTCCTCTAAAGACTCTGAGGACACTAACGTGACTTTTTACCTGATGATAACTCTGGCCTCGGTCTCAGCTCTGTTCATTCTCAGTATCATTGTGCTGATTGCAATGCAGTGCTCCAAGTCCAGCACTGACTACACCTCCAAGTACTTACAGGACACAAACTATGACGGGACTCTGTGCCACAGCATCCAGTACAGATCTGGAGACAAGCGCTACATGTTAGTTGGACCCAGAATGAGCGTAGGATCCACTATAGTCCCAGGGAGCCAAGCCAACACACTGGTGCTGCCTGACAGGAGGAGGCCCTCTGAGGAGGACACAAACTATGACGGGACTCTGTGCCACAGCATCCAGTACAGATCTGGAGACAAGCGCTACATGTTAGTTGGACCCAGAATGAGCGTAGGATCCACTATAGTCCCAGGGAGCCAAGCCAACACACTGGTGCTGCCTGACAGGAGGAGGCCCTCTGAAGAGGTAAAGAGACAAGCGCTACATGTTAGTTGGACCCAGAATGAGCGTAGGATCCACTATAGTCCCAGGGAGCCAAGCCAACACACTGGTGCTGCCTGA
->XM_042877628.1 PREDICTED: Lagopus leucura von Willebrand factor D and EGF domain-containing protein-like (LOC122183568), transcript variant X25, mRNA 
-TTGCTCAGTCCAAATGCCAGGAGGCAGTGCTAAGATACAAATTTTTAACTTATTTAACTGTTGGAAGAGTTGGGTATCACCTACATGGCTAATGTGATATCCCTAGCTAGGGATGGTGAAGTCCAGGTTCACTGGGAAGATAGTAGTAAGCCCTTAAGTAGCAAACTGTTGCTGGGCTTCAATACAATCACATCTGATAGGAAAATCAGAGCAAAGATACAGGCCCTCCCCATGTTTTGCTGGAGCAAGACTCTGCAGTGGCTTTCTGCCTGTATTTCTGAGGACTTCTTGATAAACTAATGATGATTTTCACCGTGTTACCACAGTGGTCAGCGTTGCATTGTGTCTGACAACAGTATGCTGATAGCTCAGCTGGCAGGAGTTTTGCAAGAGATCAAGGTGCAAGGTAACAACCAGGCACTCCACATAGGAAGCAACCCAGCTGGAAATGTAAGATAATATCCAAAATAATTAAAAGCTCCTCACACTATATTTCCTGCTCGCATTCTGTCTCCAAGACATCTTCCACGGGAGCAATTCAGCTCTATGTATACACTGGGACCAATTCTGCCCTACTGAAAATATGTGGAATTTCATGGCTGACTTCTCCAGGATCAGGATCAGTCCACAGAGAAAATATAGTGTGTTGTGTGTGTTCGGACCATCAAACCCCAAAGCTGACCCTACACCCTATGCACAGAACCTCACCCTGCCCAGCAGAGATGTGTAGGTCGAGACTCATCATGGAACTGTCTGCACTGCCTGGAGCACAAGTTCAGTGTTTAGTGCCTGAATGCAAACTTGGTTCCACCCATGAAGACTCTGGTGCCGCAGCCCCAGAAGTTTCTTCTCCCTCTCTCCTTATGCATACGTATATGGAAATGTGTCTGAGGGCTGCTGATCCAAAGGGGCTCCTTGGCAGCAGGGAGGGAGAGATGCATGGATGATTGTCCTGCACATTACAAACAACAGGGTAGCCTCCCCGTAGCCATGATTCCCACCTGGGAGGAGCTGACAGCCTGAGGGAGGACTTGTCCACATTTACACTGTGTCTCCAATGTGCTCTCCTACAGTCACCTAACAGTCAGGTGTGTGCAGCGTGGACAAATGGTAAAACCTTCTTACACTCCTTACTGGACATCCCTCTCTCCTTGTCCCATGGAAAGCAATACAGATAGCACCAGCAACGAGCAATTTCAAGCCCCAATTATTGAATTTACTGACAGCTCATGTGTTTCCATGGAATTACCATGCCAGCAGGATCAGGCAGGACATTTCTTTAGCTACACCTTTGCATTTTTGAGGGTTTGAAAAGGAGCTGAAATGCTGTTTCAGGATGACAGGGAGAAGAGAGGCAAAGTCTGAAGAGCACAGAAACACACTGCAAGCACAACATAATTTGGACAAATAGAAGTGCTTAGTTCTGTTTAATGTGAATTAGCTTTCAGAAGTGTTGCTGGTTCTCAATACACACGTGCATTGGTGTCTCAGAGGCCGGAGGGGAGGACCAGTAGTACTGCAGGATCCTTGCTCAGTGTCTGCCATCAGTGAACCATACTGCTGTGCGATGCACATCTGACCCCAAAACAATGGAAGAAGAGTGATAACAGAAATGAACACTGCTGACAAGGTAAACAGAGAGACATGGCAGCCTGCTTGTTAGAGACAGCTAATGCTTGAGGGAACTCTGCATTCAACTCCATTGCAAGAAAAAAATCTAAAGACGAGTTCCACCCATTGAAGTGAATTGGCTTCTCAATGTTTTTCAGTGAGGTATCATTCGAATTTGGCTAGGAATCTTAATATATTTTTGACTCTCCATTATTACATTAATTTGAGTTAATTGCATTTATGCGGCTTGTTCTTTTTGATAGGCTTCAGAGCAAATGCTGGGTGTAAAAATCACCAGTCATGATACAGTGGTTTCCTAACACTTAAGACAGTTTCATAACAGAAGAAAAATTCTACAAACAGATGCTCTCGCTTCTCTGTAGATGGAGAATATAAATGTGTTATTACTGTGGAACTTCATAGTGCAATTTATGTATTTGGTTTATTCATAAGTTATGTTCACATTTTAAGAATAAACATATTCAGTTTTCCACTGCAGATAAAATTATTCTCAGATTTTAAATGCTGCTTTTCATCAGATTAGTCTTGTTTGTAAGATTGTGTAAAGTAATAAAGGTACATTTTCCTGCTAAACGCATTTGGGGATGGAAAACACCTAGCAATAACAATAACAGCAATTCTTGGCATTACTGTAGCAACTTTCATCCAAAGATCTCCAAATGCTTTCCAATAAGTAATTAATTAGGCCTCACAGCACCCTGGAGAGTTAATTACAAATTATCAAGCATACTCTCAAACCATTTCCATTGAAATTATACTTGTTCCCTTTCCAGAAGAAAACAAAATACGCTGGCTATCATACCATGACCTTTCAATACCATGATTCATTTTGAAAATGTAATTAGATGAGAATTTGAACGTATCCAGTTTTAGGAAAAGCTAATATAATTATACCTGACCACAAAACTCATTAGAATTTTTGGTTTCTTCAGTGAGATGATACTTTTTAATCTAACTCTTTAATAAAACTGCAACATCTATAGGAAAAAAAAAAATGAAATGCAGCTGGATATCCCAGTAAAATTCCAGAGAGATTTTAAATTGTGGACATCCATCTGTTCTTCCGTCACAAGAGTGTTTGGTTTTGAGGATGTTTGATCCAGACTTTGCTTCTGACACAGTCAGAAGGCAGAAGGACAAATCAGTGTTGCCTCCAGACTGAGCATCCCTCCAGAAATGTAGTGAGCTCCACTAATTCAAGTGCTGCAATCTGGGCCAGAGGAGGTATTTGTTAGAGAATGTTGTTTGCCACAGAATGTAGGAGGCAGAGAAAGGCAAGAAAAGGCTGAAATCTCAAATCCATTTATAATGGAAACATCCTGCATTTCCTGAAGCACTGAGTAGATGCTACAAGATATAATTCCTTCCTACCAAAAATCTGAAGCTGTAATTTTACCTTCATCACATAGAATCATGGGAGTAATTAAAAACACTTTTACTATGTCTTTTGCTGCAACATAGTGATTGTCTTGTTTTGATGTAAGATGAAAGTAGTTTTCTTGCATAATTTTCTGAAGGCAAAGAATTTTCTTCTTTTACATCCTAGTTTTGTAGGAAAGCAAAATAATGCTTGTTTGCATGGACAGAACTTGCATATAATTTGAAAAAAAAACCTAGTATTTTATCGATGAAAATATGGTACAAATGAAAATATATCCGCATCTCATAGATTTCAAAGGCTGCATTAAATTAACAGTGAAGATCTATTTTTCCTTATTGTATGGGAACTGCTGAGTTACGGCCTGAACCTCTGATTGATCACCTGAGGGAATCCACCTCTCTTTGAGAAGAAAGAACTGTCTACGGCTTGTTCAGAGCACACAGGGTCTGGACAAGAGGAATGCAGAGGACTCTGGGCAGTCCCATTGCTGAAGAAAAACTCTAAACAGGCATTCTTCAGGATTCAGTTATAGAGTAAAGCAATATCTGGACAAGGTGACTGACAGACCCTGGTCCCCCACTGGGGCAGGACTGACCTACATGGATATTTCTCTGAGCAAGGAAGGAGACATTTCCTAAAAAACTGTGTTCAAGATCTGCTTTCATTTGAACCTATCCTGAAGTCAAAGAAGTTAATGTGGCTTCATCTGAGAGCAGAATTTTGTCTAAAATCTTCATTACATGCCAATTCCACGAGGATAATTCATAGTTAAGGCCTCTGAACACCTTTAAAATAATCCTCTTTTGCTTCATATAATGAATAGAATAGATAGGGAATTGCTTTCCCAGACTTTCTGAGGAAACTGAAGCAATGTGTTAAAGTTTTAACAGCTTTTATTTCTCTTTTCAGATCTTAACCCAGTATCAAATATTAAAGTCCTAATATATTTAAGGAAAGCAGAAGTTGCTGTTATAATTAATTTCCTATCTGAGGGGAAAAATAAATGTATTGCTAGCCCTTTTGGAAAGAATCTCAGTTGCAGACTTGTAGTGATCACCTGGAAGAGCATGCAGTGATTTCATGAAATCATACTGGAAGAGGAAAAGGATGATTTCACAGGAATTCTGTTGGGAGGATTTTAGATGCTGCAAATGAACTGGAAAAAGAGGCTGAGAAAATGCTAAAGCAGCATAATTTTTGTCTTCTTCCAGTGGAGGAAAATACCGACAGATTTATTATACCCAGACTTTTGCTGAGAAACAAGCATTTGGGATCTATTTTAAATTAATTTTGCAAGAATTTTATTTTTTTTTTTAATGAGAAATAATTTATTTTCCTTCTGGTTAAATCTTGAAATACTAGAAGCAGTATGAAAGAAACACTTGTAGATAAGCTTAAAAATTCCAGTATTTTAATTTGCTTATGCATTCACATCTTGGTTTATTATTTGCAGTCTAACAGTCTTCATGCTTAGTCTAAAACCTTTAATTTCCTCTATAATATGTATCGCCGTGAAAGTGAACATATCAGAAGACTTAGGCACTACAGACATGACAGCAGACAACCCTTTGAAAATGTTTTTAAGGTTTCACTTGAAAAGGAAATTATGCCAATGGGCATTAATCATTTTGGAGGCTTCATATTGCTTCACAGATATTTATAATGTTAATGAAAACAGTGACGCTGTTATGAGCTACTGAATCAAGAAGTTCATTTGCCCCAATAACAGCAGGGGCTTGAAATGAGAAAAAAAATCTTTCAGACAGGGATGCTGCAAAGTTCTGAGTATGGAAAATCTTAGGAGTGTTGTGACATTCAAAAATGTCTCCAAAGATGTGTTATGCCAAAAAGCCTGAAAATAGGCACATGCATATCTTACCTTTCTGCATTTCTTTGCATTGTAAACTACACAACAACATTTTTTTTTTCTGTCTACATCACTTTACTTAATAATATAGGGCAGTGATAGAGTTTTAAAAGTTCCTTGTGATTTTTTCATTACAGCATTTTGATTGGTTTTAAGGTTAACATAAACTGATCTTTTCTGCCTAATTGGCTTTTTTTTTTCTCTTTTATATAAGCAATTTAATTCCCAGTTGTGATATATCATGCAGGAGAAATATATATCAGAGAAAGAAGAAGATATGTCATGTGGAAAGGAGGAAGGAAGGAACTGCAAGAGGGATAGGCTATAACCTTAAAAAAAAAGATTGAAAGTTATCCAGAGTTTTTTTCTGTGGGGCCATACAATCTGTGTGTGATCTTGAAATGATTGGTTTTGGTCACAGCGGGCAAGATGTTGAATGTGGTCTTATTTGTGTTATTAGACATCTTCCATTTAATGCCATGGCTGTAAAGGGTGATACAAGTGTTGGCTTCATTTCAGAGTCAGTAGTACCAGCAAACATAGCCCAGCTAAAAATAATGAATTTTCAACTACTTATTTTCCTATTTTGCCTTGAGGTTAAGGCACTTTAGCATGCAAGCCTTCTGCAAGACATATTTGAGTCTACCAAATGTAGTTTAGCAGGTAATGAGATGCATTTTTTCATCAGGGTCATGCTACCTAATCAGACGCTAAATGTAATTATTCACGATCGAACCTCAAATGCAATTTTAGAAAGTGTCTGTATTACAAACTAAGAAATCAACAGGAGGACTGCTTTAAACATGTTTTCAGTATGCCAACATTGCCTTTAATTATTTTTTGATGTTTTATATGAAGTCAAAAGACAAAAAGAACAAGCTCTGAAAAAGTTGTGAAAAAGAGATAGCATGTGCGTGTCAGAAGAAACACAGGGAGAGAGAACATGAAAGAAAGTATAGAAAAAGAAAGGAAGTACTAAAAAGATGAAGAAACAGAGAAAGAAAGAAAGAGAGATAGAGAATAGAACTCACATATAGCATTTGATAGCCGTAATTGCTCTGCTCTTTTATAAAGGCTTCCTTTTTCTGATTAGAGACTTTAAGATAGTTACTACCGAAAACAGTATTTAAAATTCATTCTTTTCCTCCTTTTTCTTTGAATTCTTCATTATGTAAAACATGTACTTCAGTGCTCTTGAAATGTTTTGTTCTCTTCATTAAATTGCTCCATTTTTATTTTAATGTCCCTGTAGTCTGGATTTTTCTCTAAAAATGTCTGTATATCTGTTAAGAACACTTGTTCTTTCAGAACCTGTTTTCCCTTTTATTTTTTTAATTCTATTTCTGAGTGAAAATGTGATTTTGTTTCTTTTTTCTTTTTTTTTTTAACACCTATTTGTCTTTTTTCTTTTTCTTTCAACAATTCTTTTGCACCAGCAAAGGGCCCATCATTCCAGACCACATTCATTTTGTTTAAATCTGGCCAAAGAAGGACTGTGCACGATTAGTATATACAATAGATGAGTAATGATGATTTTTATTCCATCAGTATTAATTTTATGCCCTTGCCTAAAGATTACTTGTAAATGCTTAGATTTTAAGTATTAAAGTAAACATCACCCCTATTGATATTTTGGAAATGTCAGGTTAGTTAATTGGGGTAATATACAGGTACAAGTTTCCAAACCATTATATCAAACTTTGCCCACCATTGGGCTCATGCTCTGTCAGCTAGCAGAGGAAAGAAAGCCAGAGGAGCAGCTCAGGCCACCATAACCCATTCTTGCCTGCTCCTCTCTACTCTTTTTTTGCTCCCCAAAGTGAGTTCAGCAAATGCCTATTTAGTTGGACCAGTTCTTTTGATATAGGCTTATACGTCTTCACTTAAGGAAACGTTTTTATTGAGGGAGAAAAGCCTCATGACGGTATTTGTTTTTACTGTGGGTTTCAGCACTTCAAGAGTTATGGACACCATCTAACCTGCACTAATGTGCAGAAGCAGTATCAGGCTGATATACTGAGCATCATTACTTACCGTGGTCTTTTTAAGAAGTTGGGAATTGAAGGCTGAAATCTCAAGACAGTCCTCTCAGCAGTCCAAGGACTTGAGTTTAGAGTTATCTGTAAATTCTGTTTATGTTTATCCAATAAGAACTCAGCCAGTGAGTGCTGCAAATAATCGTTTACTTAAACATAAATGGGAATTAATTAGTCTATCAAATGAAAGGAAAGAAGATTCTGAGCCAGGAATGCACTCATAGTCACAGTAGCACATCATAACTTTGCTCGATGTACCTAAAATTTCTTTTAAGTGTGGCTGCCAAATCATCATGATTCTTTTGTTTATTAGCCAAAAATCCTACCCAAAATGGGAAAACTTCCAGTCTTTTCTATGATACTTATGACAGCCTTTTTTAGTAGCTGATTTCTTATTAGAATATATTCCTCTAAAAAAATACATTTGGCTATTTATTGATTAATGCTCATTTTTTAATGGAGCTGTTTTGCTAAGATTCAGTGTCAGGTGCATTTCTAACACCCCAGCTCCTCTGTTCTGTGCATCAATTGGCACACTCATCAGTTAGCCAGTTCTGCAATAAAATAAATTAATGGACTATCCTATTTCATTTCATGGCATCCGGCCGATGGAGTACAGAAACTGCTATAAACCCTAGGACTCAGTGGGACTGCTGGTATGAGGAAGGAGTGCAGCATTTGGCCCACATTTTGCATTGATCAAGCAGAATTAAAATTAGCACAGCAGTTTGCCTTGAATGAAGCAGAAAAGCGTGGTGCAGGCTATGCAGCCTCCCAACTACTAAATTGACCCCTTTTCCCTTTTATTTTCTCTTAGCTTAATTTTTGCCCTACTGAAATAAATGAGGCTACTTATACTGTGAAAGGAAGGACTGGATAATCTGACCAGTATAGCATATTAAAATTATATGTATTCTATGGTTCATAATCAAATATGATTCTCTTCCTGAAATAAGCACTATATGGCTGTAGTGATAATCACTAATGGGTCAGTTGGGTACCAGAGCACTGTAAATTCTGGTGATGAATACACGGGGATGCTGTAGACTTCTGCCTTGTATTATTTTAATAGAGAGCAGAGGAAAACAAGGGAAGATTTCCTCGGAGGTATACTGATAAAATCTCACTTAATTATGTTATAGATCTCACATTGCTTAATTTTTTTTCTTAAAACTTCAGCTCTTTGAATCGCATTATTTAAAAATGGATTTCCCTGGATGGGAAAAAAAAAAAAAAGAAGAGAGAATTCTTCATAGCTGGGAAGAAAATCTTTACACTGGAAGCTTAAAAAGCAGAGAGTAAACACAAACAAAGAAGAAAAATGGAGGACCAGCGGTGAAATCATAGGCTGAGTGATGTCATGGAAATAATGTCCTTAGAGGAGGACTTCATGCCAAAACCCAGGAGCAGACAGATTTCTGAGAAAGATCTTGATCATCAATAACTCCTGCTAATTCAGTGGAAATCACAGTCAGGTTGGCAAGCACTATGAATCATCTCTTCTGATCCCTGCATGCTTTTGTAGAAGAAATTGGAAAGGCAACATCCACGAGGAAATACATGAAGATCTAACCTGGCCTGTGTGAAAATATTCATGTCATAACCCAGACAAGAAACAAATGTGCCATCTCAGACGAATCCACCTTTCTCTCTTTGCATCTCATGGAAGACTTTGAAATTTCGGGACAAAATTGCATTCTCTTATTCAAAACTGAACAAAGCAGGGCGAGTCCTGCCGTTTTGCTGAAAATGCTCTGTATAGAAAGTATATGTACATTAAATTGCCTCTGTGACCATGTTTGACTCTTACTCTACAAATAAATGGGAGTAGATAGCTCCCTTCCCTCAGGAACTTCTGTCTGCGAAAACTGTGGATTGCTGGGATATGCAGATGAAACATCTCTTTCTCTCCACCAAGATATGAAAGCAAAGAGCTCCTTCCCCTTCTGAGCTTCAGGCCAAGGGGCTCCGACACACACCGAGCAAATGGGAAGATGTGTGATTAGGTAACTTCCAAACTTCAGAAACATTTCCATTTCAAATTCTGACTTCCTGCCATGCACATACTCTTCTGCAGCCAGCTCCGAGGCAATTTATTAACAACTCCAGTGGAGTGATATCTGCAGAATCTGTTTTTCAGCTTTTGACAGCTGAGCTGGGCTAATGTTCCTGTTCCAGAGTGCCGTCGTGGAAGCAGTGCATATTCTATATATTCAATGAAGAAGTGTCCTTTGAAAGTGTAAATGAAATCGCTTATCTGAAGTAAAGAGATAAAAAATCAATTTAAAACATTTTAGATTGTTTATCAGCATGTAAGAAAAAAATACAAGATTGACCAGGTTTTACAAAGAAAGTTTTAAACCACAAACTACCAGTACTTTTAGGTTGTATTTCCTGTTCACTAAATTAAACGTTTCAATGGATAGCAATGCATTTCAGAAAAATAAATTAAAAACAAATCAATAAACAATAGAATAAAACCTACTAAATGCTTTCAGTATTTTAACTTCTTAAATACAAAAGCCTATTGAAGTTGTTTCTGCAACCTTAAAATATAACAGAACCCATTGAGATCAGCACTACATCCAAGATCTGAAATGAGGGGTTTTAAAAAATACCTGAAATACTCTAAATATTAGATAAAGAAAAGTTAGAGAGGTGTTCAGGGAAAGAAAAAGGGCAATTTTTTCACATCAGGGATTTAAACGAATGTGAAATCATGAAAGTCTTAACACTGTTCTTGAACTTTCACAGAACATAGGTCTTACTTGGATGAATGTTACAAGGAGAGTGGAAGAAGGACTTAGACTAAAAACAGGATTGACATGCATGATGAATTACAGTTCATTAATCCAATTAATGAGTAATTTCAGAGGCTTTAATCCCAGATAAAGCTCCTTATTGCAGCTCTGTTGGCTAGTGATGCACAAACTAAGAGCCTGTCAGCAAATCAATTGTAAAATTCTATTAAATAAAGCCTGCCATACACTTCTGTAGCTTATGTGACAATATTTTGTCCAAAAAAACCCCAAAAACATATATATATATATGTACATATGTAAGAGAAGGAGAGGAGGGAGCAATCTCTAACCTTATTCACCCTGATTTGTAATATAAGAGTTCAAGATATATTTAAAATGATGCAAGCCAGCTGAATGCAACTTCAGATATTTATAAGCACTCTTGATTTAGAAGGTAAACATATGCCCCAGTTTCTGAAGTCATCTGTATGTATGATTTCCTCATACACATTCTGTTGACTAATGGGAGTCAATAAAGTACATCAGGCTGCTTTGGGAATAGTCTCTGTTCTGTTCTTAGTTTATTTTATTTGTGGTGCCACTGCATCCAAGTGATTCTTTCTGAGCGCTTCAGAAATAGACTCTGTCCTCCAAAAGTCTCACAAGCAGAGAGCAAAGAAAGGAGATAAAGAGAGGAAAAATTGTGAGAGTTGTCTTCATTGACTGTAGAATCATAGCACAACAGCTGACAGAGCAGTAAGTATGAAGCAAGCATTTGAAATTTCAGCTAAAAAGTCAAAACCTAAAAACCTAAAACCTAAAAACCTAAAGAGTCAAAACATGATTTAAAGCAGAAACAACAGTGTTTCACGGCTTCTCAGAAAACCAGGAGGACTCCCCTCCCAAAAAACCATTCCCCTCTGACTGAACCAGGCTTTGTATCCCTGTTATAACAACCCTCTCCCCCTGACAATCAAGCACTTCAAATATTCCCTTGCCCACCATAATGGAATGAAGAGTGGACCTTCACTAAGACGCCTCTGAAAACAGGCAGGCTGGCAACTTGCAGTGACAGCCATGTACTGACTTCTATGTAGCGACTTTGATTTGTTGAGTACTGGGCTACCCTGCACAAAAAACATAAATGCATTCCATTTTAACAATGAAGAAGGCTTGCAGTACTGTGAGAGGCTGTGCAACACACACAAATATTGATCCTGATCTCTTTGAACAGCTATGTCAATTACCTTCCGCATTCTCAGTTTGTAAAAGCTGTGTTACCAAAGAGACAAGATCCTGCTATGACGACTATTTAAGTAAAAGTGCATCCTTTCTGATATTGCCGAAGAGTATGCTGTGGGAGGATGGCAGTTCACACCCAATTACACACCATGATGGATTCATATTTCTTGATCTTTGAAGCCTTCTGAAACAACATTGCACAATGACCCTCAGTCTTAAAGACCAAATAAGATGATTAGTGACATGCAGAAAAAAGGCTCAGAATTTCATGCATGTCAGAAAAACTCTTAAGCACTTTCTGTTTGTGGCAGTGCTCCTGAACTGGAAGAAACTTCAGTCACTCCAGCACAGAGAAAGCTGTTTGATGGAAACAAACAACTGCAGAGACTATAAGATCGGTAACACCATTGTCCCTAAAAGGCTCCCATTTAACAAAAGATATATCACAATTTGAAACCAAAAGCAAAATACTTGTGTGCCTATTGCTAGAATTTTGGATTTCTGCAGTTTGAAAATACAATGGAAATCACAAATGTTAATGAAGATTCAGTGCACATCAGCGTGATGATGCATATTACTATAGCTGACAGATTTTGAAAATGAAGGTCATAAGAAATTGTGGCATTGAGAAAATCTTTTATGCTACTAGTGCTAAAAGTTTGTTCTATACCACGCAAAGCAAACGCTGTGTACTTCAGAAAATGCAGCTGTTGAAGGAAAATGAATCTGATCCACAGCTTAATCCCATTGTATGAATACAATCCTGAAAGTATGATGTCTATCCAGGAGAAACAATGCATGAATCAGTACTTAACTAATGGAAACAATAATTCCTGTAGTTGTTTCAATAACAACCATGGCTGAGAGTGTCCTAAAGGATCAACCAGGCTGAGGGTAAGACTGCTCAGCAGATTAGAAATCAAATCAAAATGAAAATGGGAGTGGAGAAAGAAAGTTCTCACCCTTGCAAAGTCCCAAGGAATATCAGAGCCACTCTGGGAGCATCTCCATGTGGGGATGTCAGATGCCATCCTTCACCTTCTCTCTGCACTGACCCACATGGGGGCACCTAGGAGGGTGGGCCAGTTCTGCCACCATCAAAATCTTTGATGACTGCAGCTTTTGGCCTCCCACCACAGCAGGCGTGTTAGCAGCCAGGTCACCAGAGGAACTGCCAAACATATGACAAGTGACAGGAATTGAAACACTTTGACCTTGAGCCATGCATAGGCTTGAAGCAGTGCATTTAGTGCCTCGAGAGGAGCAGGAGGTGTGAGACGTGCGTTTTGAAGAGAAAACTAAAACTGATAAAAGCACAAGATTAAGAAACGAATGAAAGTTACCAAAAAATGACCAGGCTGTTTAATGTGAGGAGAAAATGATCATGCTATAGTCCTCCAAATGCTTTTAAAGACAGAAAGGTATCCATATATCTTTTCTTCCGCCTTTGAAGCTTCAACTGTGAAAGTTAATCTAAAGGAAGCAAAATGCAGCCACTCTCTTCAGACCATTTGATATGCTATTGCTTGCAAACTTCCTTTAAAAATATCTTTCATAACTAAGAAAATTGCCATATGCTCACTGGCTTATAAATGGGAAATTAAAGATAAGAAAGTCTGAATAAAATAAGACTACTCGATATTAGCATTCCGAGCACTTGGCCAGTATCGGTCAATTACTTCACTGCTCTTCTTTGCCATCCCCAATCTCACTGAAAAATACAAGCCCACAACTTCCCCACGAGATGGATGTTATTAACCCATTTTTCACAGCTGAGAGCTGAGACACAGGGGAGATGGGTGACTCCCTCTGGGTCACCGTGCTGCTATTGAGAAAGCTGGAAATAGGCCTTGAATCTCGTTTATAAGACAAGACACGGGGCAGTTCATTTCAACCAGAGTGGTTTCCACATTGGGATTTTACAAGCTTACATTATATGGATGAATTAATAATTTGACGTCTCAAAAGCCTCCTGCTATTCACAGAACTCGTTTTAATTCTTACGTTACTTTTTTTTTGGCAAGACTGTGACGAGCAGTGTGAGGGCAGAGGTGTGGTCTGATGGCATTTATCAGTGTCAGTTGTCACCTTACAAAGCGTTATGGGGATGTACGTGTCCAGCTTTCACTGTTTGCACTGCTGGCAGATTGTGTGATCCCACTTTATTGCCTTTTGGCTTTTTCCCTTAAAAACAAACAAACAGTATACTGTTCCCTGGAGAAGGACAGGTAGTGCTTTTTACATCTAATAACGAGCCAAGAAGAAATCTATTCTGGAACACTCATTTTCACTCTGTTGCTGATTGTAACATCAGTACTTCTTTTCTACGAGCACTCATTCAGTCTGCTGTTCCTACTAACACATTATACATGACATTTGCTATGTATAGTTAAATCAAATTTTATTTATGATATTCTCCATAGTGATAATGCACTTTGTGTCCAGGCCAAAACATTGAGAATTCAGTTGTTTTGCATTCATTATATGCTTCTTCCTCCCCAACCATACAAGGAATAGCATCCAAGCGATGTTTGGATCCCCTGTCCCAATGCCAGGCAAGTCTCTGCCAAAGACAGTTCTGATAAGAGGTGTTAAATAGTTAAACACAATGGATTTTGATTTTTTTTTTCATTTTATTTTCAGTCATTAGGGTAATTTCTTATATATGGAACATCACTTGTTCTTGAATACTGTGATAATGCGAGTCTCCAGTTAAAGACTGAAGATGAAATAATTAAAAATGGCTTATTGACCTTGAAAGCCATGTCCTTCTGAGCATCAATATGAGATATGCACATTAATTAGTGTTTTTCAAATTCAATCCTTAACATTTACCAAAGGAGAACAGTTTTCTCAGTAAGTCAAAGACAGGCCTGGTTAGCCAGTAACTTATTACATATTTGTCCACATCACAATTTTCTTCATCCTTGATTTAATCTGCAAAAATATTTAATAAGGAAAGCTCTGTTGAAAATAACATGTTTATTAGAGCTTCATTTTTGAAAAAAAATTCTTTTGAATAGCAGACTGAATTGCTAGCATTATAGAGTAACCACTTCTTAATGAATAATAGAAATTTGAGATAAAGGACATCAAATTATTATGACTTATTAGAAGATACAAAGGACCAAATTTGCAAATGAAACTGGCTAAATTTTAACAAATATGTCCATAATAAATCTTAATTTCAGTATGACTTTCTAAAACTCCATTTCTATAGTATTTAACAAAAAGCTCTGCAAAGAAGAGCTTAAGCTTTATATTTTTTCACTTATTAGAGCGAGGAGTGGAATTTCTGACAAACACCAATAAAGAGTAAAATTTATATCTTGTCAATAGGACCTATTTTGTTGCTAAATTATCTCAGAAGTCTCACAGTCAGGAACACAGTAGTCTAAAGCAGTCAGGACATAGAAGAAACAATGGGCAGACAATCTTGTGCTAACTGAAAAGTGAGCACTGTAAGGGAACAGCTGAATTGGGGCCTGAACCTCTGATTGACCACCTGAGGTGAGTAATGAGCCAGCTGTGGGAGCACAGGTGAAGGCAATTCATGTGTGCTGCTGGAAGGGGTGGAGCCTGGCTGCACCTCTCCTGGACCCATTTAAGAGCTGACTACTGGGGTGGAAAGATCTTTTTGTGGAGATCCCTCCTTTGGAGTTTTACAGTGTGCCCAGGATAAGGTGAAGAAAGTAAGTTCAAGTGACTGGTCCAAAATTACACAACCACACTGATGCTCAGCTAGCAACGGGGACTTCCTTCATCCAGTGCGGCACACCATCGCTTTACATCACTCAGCTTGCAGAGAGAGAAGATTGAAGTTATTTGTGGGCAAATTTATGCTGATAAGAGAGAGCACAGAGAGCCCCAGAGATGGAAAGGTTTCAGAAGACACTTCTGCTGGAAAGCCAGCTCCTGAGTGCTCCCCAGCTGGACATCGCATCCTCCGCAGCCCATACCGCAGCACCAGGTTTGACTCGCTGGAGCTGCAGCGAACGTCTGCTCAGGTCCTGGTGTGTGACCACTCATTGCCACCAGCATGGTATCGGTTCATGATCAACAACACGCCTGCGGAAATGCCAACGAGATGCATTGAAATGAACAAATGTGGGACACAAGCTCCGGTGTGGCTGTCACTGAGGTCTGAATCCCTGCCTGCTCCAGGTGAAAGCAAGCACCTGATGGCCTGTGGTACCTGGCAGGTCTTTGGGGGCACCAAGGACTGCTGCTTGTTCCGGATACCCATCACTGTCAGGAACTGCATCAAGTTCTTTGTTTATCTCTTGCAGCCGACTCAAGGATGCATGGGCTACTGTGCAGAAGAAAAACTCCCAAGCCTGACTTTACAGCCAGTGATAACTTCTGAGCTCGTGCGAGGTCGCGCCCACCTGAAATGCGCCTACAGCTCACCCAGCTGGGGGCTGAGCTACACGGTGCTCTGGTCACGTCTGGTCGCCCCGGGCAAACAGGAGCAGATCCATCAGGACACCACCCTGCAGACGTGTTCCTACCTGGAGATAAGCAGCAGACATCTCCAGCTGGGAGACACAGTCTTCTGCACTGTGACTGCATTTGCAAGGGACACTTCTGAGCAGCGGTCATTGCCTGAGCAGAGCAAAGGTTTCTACGCTGGGATTAAGTTTTTACCAGAATCATTACAAATTGCAGAAGATGGCAAGGAGCACATTTTGACCATCCTGAGCACTGTGCCCATTACCTGTGCTGGGCATAACGATTCATGTAAAATCACATTACGGCTCAGTACTGAGGATCTGGACAGCCAATTACTGGGGCCCCCAAACACTGTCCTCTCAGCGTGCCAGGTGGATCTGGTGCCGGCGCCCTGCTCACAAGGCAGCTGTGCAGCAGCTGTACTAACAGTGACAGCCGTCACCGACTTCGCTCAGGATGGGAACCGCGTCAGCTACATCAGAGCCGAGCCAGTTGGACACAGAGATGTACTTTGGAGGGCTCACGCCTCGAAGGATGTAAAGGTCACAGTTCAGGACCTCCCAACAGGGAACTGCTACTCTTTCACTGATCCACACATTATCACGTTTGATGGATGGCGTTACGATAACTATAAAATCGGCACCTTCCTTTTGTGCCAGAGCACGTCACGGGCATTCGAAGTGCACGTCCGTCAGTGGGACTGTGGGGGACACCACTCTGCCACTGCCTGCAACTGTGGGGTGGCTGCATGGGAAGGGAGCGACGTCGTCCGCCTGGATGCCTGCAATGGGCACTTTCGGGACAGCAGGCCGCAGCTCAGCATCCAAAGTACTGAGGCATCACCACAGGTCAAAATCCTAACGTCCTACGGAGGGAGAAAGATAACAATCCTATTCCCTTCAGGAGCGTTCATTCGAGCCGATGTGAGTGAGTGGGGAATGGGCTTGACAGTGAGGATACCAAGCAGTGACTTCAACAGCACCAGAGGTTTGTGTGGCCTCTTTGATGGGATCAGTCACAACGACTTGAACAATGTGCCTGAGGAAGACTTCATAGAGGAGTGGAGAATACCTCCAGGGAAGAGTTTATTTGACAAAACTCCAGCATCTTCAGAGGGGAAGCAGAGGAAAAACTACTGCAGATGCCAGAAGGAGAGCACAAAGTCCATGCCCTTGCTAAAGACGCTGAATGCCTTTCAGATGCAATCTCCTGGTTGTCATTATGATAATGTGGATTACACTTTTGCAATTCCATATCTGGATGTTACATCAGAGTTTGTCACTCACTCAGGCAAAGAGTTTGCTTCAAGAGATGATGAGGAACGGTCGCCCAAGTCTTTTGATCAAAGATCTCTCCCTAAATCAGCCAAGAAGCGAGGTAGCCGTGAGGAGCGATTAAAACCCTTCTCACATCATGCTTCCATGAAAAACAACAGTTCCCTTAACTTTACCAAGCCAACAGAAGAACTACAGAGACCAAAAAGACAAGAAAACTACTTTGAATACTCAGCCCTTCACCCGTTGCATAGCCCAAGCCAGACAGACACGGAAAGCTTTGCCTATTTTTTCCCAGAGGATTATTTTGAAGGGATTCGGATAAAACTCCCACTGGGATGGCCCACTCCCAGCGGCCTAACCTCTGCCAAAGCTCAGGAGATTTGCCACCAAATTCTTGCAAATTCCACCATTGGCTTAGCGTGTAAGTCTCTGCTGGGAAAACTGATAGATGAGGCCATCAATATATGCATGTTAGATCTGCAGCTCAAGGATGATGTGGCCTGGGTAAGGGCACTGATAGCGCTTTTGGAAAATGAGTGTGAAAGACGAGTGCTGAGGCACAGAGGTGAAGTGTTTCGTGTTGGAAGCCAGCCAACTTCTAACCAGGAGGAAATCCTTACCATTCTCCGCTGTCCTGCTTTCTGTAATGGCAATGGACAATGTACAGACATGGGCTGCCAATGCTTTGAAGACCACAGCTCTTATGATTGTAGCACTGCCAGAAAGCAAACTCTGGAAATCACAAGCTTGGAGAACAGGGGCCTATGTGACATTCGCACCTCTGACTGCAGTCGTGTCCGAGTGTTTGGCGTTGGCTTCAAGGATTCTCCCCATCTGCACTGTGAAGTCACCAGATTAATTCATCTCAACGGCGAATGGATATCAAGAGAGCAAGAAACCACACAAGCAGATTTTCTCAGCTCTAAGGCTGTTGACTGCCAGATTCCTCTCCTGAACATTGCAGAGACGGAGGCTGTGCACTTTGTAGCTGGCGATGAGCCGTTCGCAAGATGGCAAGTAAAAATCACTGATGATGGCTTCCAGTACAGTAATTCCAGAGTGCTGACCCTGTACGACGCAGTCTGCCAGGCCTGCGAATCCCATCCAACTGGACTTTGTAAATTAAAGGACAATACTTGTAATATAGATGGACTTTGCTATGGGGAAGGAGAGTCAAACCCTGCCAGTCCTTGTCTTCTCTGTGAACCTGATATCTCTAAGTTCACCTGGTCTATTAATGAAAACAACCTGCCTCCTGTGTTCCAGGCCCCCTCCAGCCAGCTGCTGACATTTATTGGTGAGAATTTTGTTTACCAGTTAACAGCGGTGGATCCGGAAGGGTCAGCTGTGCTATTCATCTTAGAGGCTGGGCCACAGGATGCCAGGCTCTCTCCCGCTGGCCTTCTTATCTGGAAAGTTGATTCAGAAGAAATGCAGACCTTTGAATTCACTGTGTCGGATGAATGCAACGCGCAGAGCAGATACGCTGTTGAGGTTCGAGTGAAGCCCTGCAGCTGTCTCAATGGCGGAACGTGTGTTACCAATATTAAATTCCCCCCGGGCCTTGGTGAATATCTGTGTTTATGTCCAAATGGATTTGATGGAGGGCTTTGCCAGGAAGATATTAATGAGTGCAAATCAAACCCGTGCAAAAGCGGAACTTGTGTGGATGGTGTGGACAGCTATGCTTGTCAATGTCCCCCTGGTTTAGGAGGGCTTACTTGTCAGGAAGACAAGAATGAGTGTGAAGAAGGTCTGTGTTTTCCAGGAGTGTCCTGCATGAACACCTTTGGATCATACGTGTGTGGAATTTGTCCAAGTGGGATGGAGGGAAATGGTAAAACTTGCAAATCTGTGCTTGCTGGTGACTTTACAAAAGCTTTAATCGTTGACAACAACAATGGCAAAGGTGATTTGAACAAAACTGAAGTTGAGTGGCCACTGCACCCCTTAGAAGCAAATAATTCTCCTGTAATTAGGAATTTTAACATAAGCACTAATCATGTCCACACAGCACATCAGCCCCGTGTTACCACCTGTGCCAATAGGCCATGCTTTCCTGGAGTGCTGTGTTTCAATAGGAAACCCCCTTACGTTGGCTATGTCTGTGGCCGATGTCCAATAGGGTTTTTTGGAAATGGCCGAACCTGCAGCAAAGCCTCCAGACCAGTTTCAAGATCTTCCCAAAGCCATACAGATGTTGCTGAAAGAAATAGTGAAGATGCCAGAGGCTCTCATCAGGAAGGCAAGACATCAAGAAACATCTATTCGTTCCTATCCCAAACCCAAATTCCAAGGCAAGAAACTACATACTTTGTGGAAAGAAACCACACAGTTATTAATGCAGCATCCTTTACAACGAAAAGGAAGATTTCCCAGCCTCAGATGCTGTCAGCAAAAATACCTGATACAGAGTCCACTGTATCTGAGAAACAGACTTTTACTGAAAAAAGAAGTCATACACACACTTTCCTTCTGCATGAGGAGCCAGATCCCAAAGCAGCAGCTGTCAATGTGACTACTCCTACCCCTGTGCATTTTAAACAGTACAAGCCAGGAACAAGACAGACCATTCCTTCTCATCTCAACACAAACGCAAGCTCACTCTTCGCACGGCTGCATGCTGTACAGCAAGCTCGTTCCAGATACAGCTTATCTTCCAGGAAATGGCCCAGTCAAGTGACAGGCTCAAAGACTGAACTCTCCAAAAATCTCCCAACAAAGCAGCAGAGAGTTTCTTCTTTGGAAACATCCCTCACATCCCCTTTGCATGAAATAGGTTTTTCCCTTGACACAGCTCCACAGAGTGCCAGTGTCCTGCCTGGACCTGCTCCCCCAGCAAGGCTTCCAGCACATACCACAACCTTCAGAAGAGCATCCAGTGTAGCAATGGACCATGCAGAACTGCCAAAACCCATCAGTGGGTCCTATGAGAAAGCTCTCTGTGGTTCAACACCATGCTTTAGTGGTGTGCAGTGTGAGCTAGCCAAAGATGGAGAATTTAAATGTGGGTCTTGTCCCAGTGGATACAGCGGTAATGGAATTACATGTGAAGTGCAGTGTGACCCACCGTGTGAGCATGGAGGAACCTGTGTAGCTCAGAACACTTGTTCTTGTGCCTATGGATTTGTTGGTCCTCGATGTGAAACAATGGTGTGTAACAGGCACTGCCATAATGGCGGGGTCTGTGTGTCGCCAGACGAGTGCAAATGCAGAAGCGGATGGAGCAGCCCTTCCTGTGAAATAGCTGTGTGCAACCCTGTGTGCTTAAATGGAGGAATCTGCGTGCGACCAAACACTTGCACGTGTCCTTACGGTTTCTATGGGCCCCAGTGCCAGAGAGCTGTCTGCATTCCTCCTTGTAAGAATGGCGGCCACTGTGTTCGAACCAACGTGTGCTCCTGTACTGAGGGCTACACTGGAAGAAGATGTCAGAAGAGTGTCTGTGATCCTGCGTGCATGAATGGAGGGAAATGTGTAAGCCCAAATGTTTGTGACTGCCCATCTGGTTGGAGAGGAAAGCACTGTAATAAACCTGTTTGCCTGCAGAAATGCCTGAATGGTGGAGAATGTATAGGTCCAAACATCTGCGAGTGCCCTGAAGGATGGGTGGGAATGCTGTGCCAAACCCCAATTTGTGAGCAAAAATGTCTGTTTGGAAGCAGATGCATAAAACCAAATGTCTGTGCTTGCAGAAGTGGCTATACTGGGTCAGCATGTGAAAAGAAGGAGTACTCAAAGCTAATGACTGCTCATTTAGAAACCATATCTTTAACTACCCACAGGATGAAGATAACATAACAGCAGGACAATGAAGACAATCATTTGGGTATCGATAAGCCCAAACTGAGTTCGTTTTTCATTTGGGAAGACACGGTGTGAAAACATTACTACTTCTCTCCCTTCTACTCTCCTATAATCACAAAGAAAAACTAAAACAAAACACCAAGGCATATGTCAATAAACAGACCTCTATTTTCAAAA
->XM_038827982.1 PREDICTED: Tripterygium wilfordii uncharacterized LOC119984160 (LOC119984160), mRNA 
-CCTACTTCTCACCGCCATTATTAACCTCCTAAACCTTCTCTTCTCTGCAAAAATTGTTAAAAAAATACAAATTATATATAAACCAAACAACAAATCCTGTATTATACAGAAACCTTGATAACTGATCGTCCGCAATCATTCACATCCTCTCTCTCGAGTCGCAACGAATCCAAATCTTCATCGTTGGATCAGAGGGCCAGACCAAACACCACCACTAGCAGAAAACATGGTTGAAACCAGACGCAGCTCTTCGTCTAAGCGCCCTCTCGCCTCGTCTGCTAACCCCGTGCCTTCACCATCGGCCAAGCGATCCAAGGCTGGTGAGGCATCCTCGAAGGCAAACGATGCGGCGGCGGTTGAGTTATCGACGGATACCAATGGTTCGGTCAAAGAATCTGGGTCTGGAAGTCTTGAACCGGAGCTGCAATCCCCTGATCTGCAGGCCGACGATGCTGCCAAGCCCGCCGATGGGGAGAAATCGCCAGATGCTGAGGTGGAAGAGGAGGCCTTGGCGTCTCCGCGCTCCATAGGTGAAGCTGCAGTGGATGCTGCGGGTAATCGGCAGAAGAAGCGGCCTGTGAAAGCGGCAAAACTGAATACGAAGGCTGCGTGGGGAAAGCTTCTTTCGCAGTTCTCCCAGAATCCTCACCTTAACATGTGTGGTGCTACTTTCACTGTTGGCCAAAGTCGTACTTGCAATTTGTGTCTTAATGATCCATCCGTCAGTTCTACTTTATGTAAACTGAGGCATGTTGAGCGTGGAGGTTCATCTGTTGCCCTATTGGAGATATCTGGGGGCAAAGGATTTGTCCAAGTGAATGGGAAAATTTACTACAAGAATTCCAGTAAGACATTAACTAGTGGTGATGAACTGGTTTTCAGTTCTTCTGGAAAACATGCTTACATTTTTCAGCAGCTCACTCATGATACTGTAGCTGCTACCGGTCTATCTTCATCATTAAGCATTCTGGAAGCACAAAGTGCTCCATTAAAGGAAATACATATTGAGGCAAGGGCAGGGGACTCCTCTGCTGTTGCTGGAGCGTCAATATTAGCCTCTTTGTGCCAGAAGGACATATCCCTTCTTCCTCCACCCCCCAAGACTAGTGGTGATGTGCAGCAAAGCACTGAGATGCCTCAACTTCCGTCTGGATGTGGAGAATCTGATGATCGCACTCCAGACATTGATATGAAGGATGGTCCGAGTACTAATGAGCCTGCTGATGCTTCTTTGAGGGGAAAAACTGGTTGTCCATCATCTTGTGCTGCTCATGAAAACCACAATATTGATAGCCTTGGATTGGATTCATGTCCACATGCCGCCTCCAAAAAGATTAGTGGGACAACGTACGAGTTGACGCCTCTACTGAGGATGCTTACGGGAACGTCATCATCTAATTATGATTCAAGAGGCGGCATTCCTAAAATACCTGATGAGCATAGGGAAATCAGGGACCTGCTGAAGGAGTTTGGTTCTCGTGCAAATTTGATTAAACGACAAGCACTTAAGGATAGTTTGCAGCAAGGAATCCTAAATCCTGGCAGCATTGGTATTTCATTTGCAAGTTTTCCATATTACCTCAGCGACACTACGAAGAATGTTTTGATAGCTTCTACATACATCCAGCTGAAGTGTGACAAGTTTTCAAAATTGGCCTCAGATCTTCCTACTGTGTCTCCCCGAATATTATTATCTGGTCCAGCAGGTTCTGAGATATACCAGGAGACATTGGTGAAGGCACTTGCCACACATTTTGGGGCTAGACTTCTAATTGTTGATTCCCTTCTCTTGGCCGGTGGATCAGGGGCCAAAGATTCTGATTTGGTGAAGGAAAGTTCAAGGCCTGAGAGAGTCTCTGCATTTGCAAAACGAGCTTCACATGCTGCTGCATTGCAGCATAAAAAACCGACATCTACTGTTGAGGCTGATATTACGGGTGGCTCAATGATAAATTCTCAGACGCCGACAAAGCAGGAGACGTCAACTGCTTCATCCAAAAACTATACATTTAAACAAGGTGACAGAGTGAAGTTTGTGGGCAGCTGTCATACAGTTGCTTCCATACAACCTCCTTTGAGGGGACCGACAGTTGGTTTTCGAGGCAAAGTAGTCCTTGCTTTTGAAGACAATAGTTCCTCAAAAATTGGGGTTAGATTTGATAAATCAATCCCTGAAGGAAATGACCTTGGGGGTCTCTGCGAAGAAGATCACGGTTTCTTCTGCTCTGCTAATTCCCTTCGGTTAGAGAGTTCTGCTGGGGATGATGTTGACAAATTTGCTATTAATGAACTTTTTGAGGTTGCTTCAAATGAAAGTAAAAGTGGTTCCTTGATACTGTTTATGAAAGACATAGAGAAGTCTATGGTGGGGAATCAGGATGCATATGTGGCCTTCAAGAGTAAGTTCGACAATTTACCAGGGAATGTTGTTGTAATTGGCTCCCATACACAGGCGGACAGCCGTAAAGAGAAGTCTCATCCTGGAGGTCTTCTATTTACGAAATTTGGAAGCAATCACACAGCTTTACTTGATCTTGCTTTCCCGGATAGCTTTGGTAGGCTGCATGAGCGGGGGAAAGAGACGCCCAAAACGATGAAGCAACTTTCTCGACTTTTCCCTAACAAAGTGGGAATACAGCTGCCCCAGGATGAAGCTTTACTTTTGGACTGGAAGCAGCAGTTGGAGCGTGATATTGAAACTTTAAAAGCACAGGCCAACATTGTTAGCTTTCGCTCGGTGCTCGGTCGGATTGGCCTGGAATGCCCTGATCTTGAAAGTCTTTGCATCAATGATCAGGCTCTTACAACTGAAAATGTGGAGAAAATAGTAGGCTGGGCTTTAAGTCACCACTTGATGCATTATTCAGAAGGTTTGGCCAGAGATGCTAAGCTTGCGATTTCTACTGAAAGTATAAGGTATGGTTTGAACATTTTACTAGGCGTTCAAAACGAAAGCAAGAGCTTGAAGAAATCACTCAAGGATGTCGTAACGGAGAATGAATTTGAGAAGAAACTTCTTGCGGATGTTATTCCTCCAAATGACATCGGGGTCACATTTGATGACATAGGAGCCTTAGAAAATGTCAAGGATACCTTGAAGGAGCTGGTGATGCTTCCTCTTCAGAGGCCGGAATTGTTTTTGAAAGGACAGCTGACTAAGCCATGCAAGGGAATTTTACTGTTTGGGCCTCCTGGCACTGGAAAAACAATGTTAGCCAAGGCTGTCGCGACTGAGGCGGGTGCAAATTTTATCAATATATCAATGTCAAGCATCACTTCAAAGTGGTTTGGTGAAGGCGAGAAATATGTTAAAGCAGTGTTCTCTTTAGCTAGTAAAATTGCTCCTAGTGTTGTTTTTGTTGACGAGGTTGATAGCATGTTGGGTAGACGTGAAAATCCAGGAGAACATGAAGCTATGCGCAAAATGAAGAATGAATTTATGGTGAATTGGGATGGTCTTCGTACAAAGGATAAAGAGCGGGTATTGGTACTTGCTGCCACCAATAGGCCTTTTGATCTTGACGAGGCTGTTATAAGAAGGTTACCCCGGAGGTTGATGGTTAATTTGCCTGATGCCTCCAACAGAGAGAAAATCCTTAAAGTTATCTTAGCCAAAGAAGAATTGTCACCCGATGTGGAGTTAGAGGCAATTGCAAATATGACTGATGGGTATTCTGGAAGTGACCTTAAGAATCTGTGTGTGACTGCAGCTCATTTTCCGATACGCGAAATACTTGAGAGAGAAAAGAAGGAGAGAGCTTCAGCATTGGCGGAAAACAGACCATTGCCTGGACTTCATAACAGCACTGATGTACGCTCTCTGAAGATGGATGATTTTAAGTGTGCGCATGAACAAGTATGTGCAAGCGTTTCATCGGAGTCTACAAATATGAATGAGCTCCTCCAGTGGAATGATTTATATGGAGAAGGTGGCTCCAGGAAAAAGACGTCTCTCAGCTACTTCATGTAGAGAACGTATGTTTGTGTACAGCGATCCATGTTACAGATGTTTATTCACCTCTCTCTACCTGGCAGAGTCGGGAGTCGGGACACCATTGATTATGGAATTCTATCGCAGGTACTGAGCTCGGTGTACCATATTATCATAGGTTTTGGAATCATTTACCATTTTAGGGAGGTTTTACAATATTTATCAAGCAGGTTTTGTTTGACGGAAGCCGTCTTCTTGTTAATCTATCTAGTTTTGAATTCCTTCTCTTTCCCCTTTTCTTGTCTCGTCTGTAGCATGTAAATTCTCATTTTGATCAATTGAATAAGCATTCCCCTCTTTTTCTCCC
->XR_004155863.1 PREDICTED: Punica granatum putative leucine-rich repeat receptor-like protein kinase At2g19210 (LOC116201365), transcript variant X2, misc_RNA 
-GAACTAAACTTCTATAAGTGCCCATATTATTTGTATCAAATCTCTGTTGTGTATTATAATTAGCATGAAGATGTTATTCGTGATACTTGTATGTATCAGTCTCAATGCTATCGCTCAAGCACAAGAAAATCCAGGTTTCATAAGCATCGACTGTGGAGCACCTAATGGTTATCACGATGACAACCTTGACATTTACTACACGATAGACACGGGATTTGTTGAGTCAGGGAAAAACATGCAGATTTCTTCGAAGTACATCGATCGAGTTCCTATGCAACAGCTAATGAACTTGAGATGCTTTCCTAATGGAACAAGGAACTGTTACACGCTAAGGCCAACGCAAGGGAAGAGCAAGAGATATCTAATCCGGGCATCTTTCTTTTACGGAAATTATGATACTCTCTCCCAAACCCCAACATTCGACCTCTATATCGATGTAAACTACTGGATCACCGTGAAAGATCCATCAAACTACACGTACGAAGAGATTATATACACTACCTCAAGAGATTATATACAAGTGTGTCTTGTGAATCGGGGCTCGGGGGTTCCCTTCATTTCAGCACTAGAGCTACGAACCCTCGACAATTCCACTTATGATACTTCAGCTGGAGCACTACAGACCTCATGGCGATATAATATTGGGTCCAAAACCACATACAGGCATCCGCAAGATGACTATGACCGGATTTGGGAAGGCCAGAGTTTCAATTGGACTACAATCACAAACAAGACGAATGTTGACAGCTTAAGAAGCACAAACAATGCGTATAAAGTTCCACTGGAAGTCCTAATGACTGGCCAACAATCCCTGGATAATATTTCAAGCAGCCTGAAATTATTCTGGATTTCTTCTGAACCCACATATAAATGGTACTTGTTCTTTCACTTCGCCGAGTTTCAGGTATTGCGATCCGGACAGCTGAGGCGATTCAGAGTTTACGTCAATGATAACAAACTGATAACAACCGTTACACCTGAGTACCTCAAACCTGTGACCGTGTCCACGTTTCCCTTTGATGGGACCGTCCTGAACTTCTCAATCACCTCTGTGACTTCTCAATCAAGCCTCCCGCCGTTCCTCAATGCTGTCGAGTGGTTTCGTTCCATTGACCTTCCACATTCTACCACGGACTTAAATGATGTTACCGGTATTAACAGCATCAAGACGATTTACGGAGTGGCTATAGATGACTGGCAGGGCGATCCATGTGTTCCAGTGTCTTTTATTTGGAGTTTTTTGAACTGCAGCGAAGACGATATTCCGAGGATCATCTCCTTGAACTTGAGCTCTAGCAATTTGAAGGGGAGCATTGCTACCTCATTCTCCAGTCTCACGGCATTAGTCTCCCTGGATCTATCGTTCAATGAACTAAGTGGACAGATACCTGATTTTTTTGCTGACATGCCGAATTTGAGGATCTTAAACTTAAGTGGAAACAACCTCAACGGTTCAATTCCTGCAGTTCTTGAAAAGAAGATGGCGGATAAGACATTGCAATTAAGCTTGGATGGTAATCCGAATCTTTGTCGACAAGACTCTAATTGCAATCAAGACGGCCGCAAGAAGAAAAATACCGTTGTCCCAGCTGTTGCTGCTACTGTGGGCTCATTGGCTCTGGTATTCTTTCTCATTTGTGCCATCGTTGTCATTCGCAGACGTAGGAAGAAGATAGAAGAAATTAATACTGGATCAATGGAAGTCACTGCATCGAAGGAACATAGACCTAAGGAGGTATCCGAGCCTAGTACTGGTACCGGATTTAACGAGGGGCGACTAGTAGTTGGAAAGAACCGACCATTTACATCTGCTGAAGTTTTGAGTATCACCGGGAACTTCAGAACAGTTATCGGGGAAGGTGGATTCGGAAACGTGTACCTTGGAACTCTCGATGATGGTTGGAAAGTCGCAGTGAAAGTGCTCTCTCAGTCATCAAAGCAGGGCTACAAGGAATTCCAAGCAGAGGCACAGCTTCTGATGATTGTTCATCACAAAAATCTTGTTTCTCTCATCGGGTATTGCGAAGATTTCGATAACATGGCCCTGATTTATGAATTTATGCCCAATGGAAACTTAAGGCAGCATCTGGCAGGAAACACATCTAATGTCATAAGTTGGAGTCAGAGACTGCAAATTGCAATAGACGCAGCACAGGTTTTGGTCAATCTTTTGATGCAGGGCTGGAGTATTTGCATAATGGTTGCCGACCTTCGATCATTCACAGAGATCTCAAGACTTCAAATATCCTTCTAAATGAGAACATGCAAGCCAAAATAGCTGATTTTGGTCTCTCTCGGGTTTTCATGATGGAAGATGGCTGTCAAATTTCGACTCAACCTGCCGGCACACCCGGTTACCTTGACCCGGTGTTCAACACGGGTGGAAACTTGAACAAGAAAAGTGATGTGTACAGCTTCGGGATCATTCTGTTCGAGCTGATTACCGGACAGCCTGCTATTCTAAGAAGTCCGACGGGCAGTATTCACATCGTTAAATGGGTGACTCCACTC
->XM_030225762.1 PREDICTED: Drosophila hydei latent-transforming growth factor beta-binding protein 2 (LOC111599265), partial mRNA 
-CAATCGCGTAACGATCAGTGCACAGCAAACGAGATCCAGCTCGATCCCCACGACTGTGCTGCCTATTTCCTATGTGTGAAGGGAGAATTTGTGAGTCAGAAATGTGTTCGTGGCTTTTACTTCGATGCCGCAATCCAGGCGTGTGTGGGCGACACCAAAGAGTCGTCTAACAAGCGGACTGCGAAAATGGCTCACAATAGAAACCTCAAATTTGTGTATCTCCTTTCCATTGCTGTGACCCTGGTCTTTGGAGCTGCAGCCGATGATGATTGCTGTCAACCCGGCGATACCAAGCCCGTCGAAGGCGATTGCACCCAGTACTACGGCTGCTGTACGGGAAAGTTCGTTCTGAAGTCGTGCCCTAGCGGACAATACTGGAATTCAAACAACCAACAATGTGAACCTGACAACGGCCAATGCGTTCCTGTTGAGCCCGGTGCGCCCGGTGCGCCCTGTGCGCCCGGTGAGCCCGGTGCGCCCGGTGCATGCACAGAAGGAGATACCAAAGTGGATGCCTCCGATTGTACCAAATATCAAGTCTGCAAGAACGGAGAGTATGTCTCGGCCTCCTGTAACTCTGGTTACTACTGGAACTCGGCTAACAGCCAGTGCGAGCAGGATAACGGCCAGTGCGTTTCAGTAACATGTAAGGACGGAGAGCTTAGTGCAGACTCATCTGACTGCGCAGGCTACTTCATATGTCTGGATAATAAGTTAGTCAAGAGGAAGTGCGCTAGTCAAACCTATTTCGATGCCAGTCTGGAGACTTGCGTTATCGACACTGAGGGTGTTTGCATACCCAAGGTTTGCGATTCCGAATGCTGCGATAAGCCCAACAATTGGATTGGACCCGTCGATAAGAACTGCTCCGCATTCATTCACTGCCTTTACGGCCAACTGATTCAACAGACCTGTCCCAACAATCTGCAGTTCAACAACATTACCAAGCAGTGCGACTTCCCCGATGTTGTCCAATGCGATGACGGCAGCCCACCGCCAAGCGGACCCACAGCCGGTCCCTCGGGCACCTACTGTGAGAGCAAGGGTCGCTGCGTCGGACAACGTGATGGCGCCATGTTCGCCGATGCCAAGTCTGCCTCCAGTGGTGGCTACATCGTATGCCAATGTGAATGTGAGATTAACTTCAACTGTGTCGCCGGCTTAGTTTTCAACGAGAAGATTCGCACCTGCGATTGGCCATAA
->XM_035486762.1 Talaromyces rugulosus uncharacterized protein (TRUGW13939_03582), partial mRNA 
-ATGACACCCAAGCGAGTGAGAACTGTCGAGGGCTCATGCTGGCTATGCAAAGATCGCCGGGTTCTATGCGACTTGCAGCAGCCTCGTTGCTCCCGATGCGTGTCCAAAGGTGAACCATGTGAATACGGTGAGGTACGCTTGCGCTGGTGCAATGGCGTAGCGGCTCGAGGCCGATATGCTGGTCAGAATGTACCTGTGTCAATACCATCAGCCAGGAGGGATTCTTCTAGAGGGTCGTTAGGAAAGACACCGCCGTTGCAATCAACCGAAAACGATCAAGGTGATGGGGAAGTCCCTAAAGTCGAAACATTGTCGCCAGTAAGCTCCAATGCACTACAGATATCGGGGCTTTCATCACAAGTGACAGCAGAGCAGCTATTGCTCTATTTTTCCAACGTCGTGGTCGACCGTTTCAGCCTTTCCACGGATCGGATATCGATTAATCTCCCATCAGTATGCGAAGAGCCTGCTCTTCGTGACTCGATGAGCGCCGTTGCAAATGCACATCATGTTCTTTCCCTGTATCCTGGTCGTCCAGGTGTAGGGCTCGCCAAGAAGAGGGCACGTTGGAGCGCTATTCACAATTTCCGAGCTCGGCTGGAATGCCCGAGCATGGAGTCGAGGACACCGGGCCTCGATCTGTTCATGGCCAACGTCCTGCTCTGTATACTAGACGGAGTCATTGACCCGCATGACGAAAGCGCAGCTACTCATATGCATTATCGCGGCGGACGAGCAATCCTCAGTCAATGGAAGCTTCAGAAACAGTTATATCAGGAAAAACGCGGCTTGCCGGCTTTGATGTTGTCTGTTTTTGCAACCATGGATTTGACATACTCGATGCTTAGCGGTGAAGAACAGTATTTTCAGCATACTATCTGGAATGGCTTTGCTGAGAGTGATGGCTGGTGGGGGACTCTTCCTCAAGATGATCCCTTTTTGGAAGTTATGTGTACTCTATCGCGTCTGACTCGACTGGGGTCTCTCGTAAGCAAGGGCCTTGATTTTCCTGATGAGGCCCTCAACGAGGAAGTGAGTACTCTCCTGACGACTCTGCAGGGCCCTCCCCAGATTCCGTATGATATTTCTTGTCCCGAAAGAATGGACTTGGAAGACCAACCGGCTCCTCTATTGCTTTTTACCTCGCCAGGCCACCACGATTTAGATCACAACCAGTCATGGATTGTCTTCTGCAATGCATACCGGATTGCCGGTCTAATATACGCGTACCGCGTCTTTTATCGGCTAAATTTCGGCGATCCCTTGATACAACAGGCCGTGAACCTGGGTATACAAGCCGTCTGCAAAACACGACTAACAGGCAAACTATCACACTGCTTGCTCTTCCCAGCGCTCGTAATCGGAAGCCATTGCCAATCCAACGAAGACCAGGCAGCGATACTCGCGACGATCCAATCAACCGCGGCATTCTTGCATTTTGGGTCGCTTCGAGTTATGGAGAGCTTTTTGCATCGAGTGTGGGAGCGAGCTCCAGCGGCGGAGACTTGGTGGCAGTTTTTTGAGCCGATTTCCAAGAAGGCCTTTTTATTTTGA
->XM_012357333.1 Saprolegnia parasitica CBS 223.65 hypothetical protein partial mRNA 
-ATGGGCATCAAGATCCGCAACGACACGCGCCACGACGTCCTCGTCATTGTCTTCACGTACTTCACGACGCCGTTCCCGACGCTGTACTACCGCAAGACACTGCTCATCCCGGCCGGCGAGCGCTACAACTGCCCGACGTGGCAGAGCGCTGTCAAGATCTACGCGTGGGAAGCCGACAGTAGCAACGG
->XM_021677838.1 PREDICTED: Neomonachus schauinslandi translation initiation factor IF-2-like (LOC110569879), mRNA 
-ATGGCGTCGCCGCGGAGTCCGGCACACGCATCCATTTTATCAGGAGCCCGGCGCGGCGGCGCTCAGGAACGAAGGCTGCGGTGTGGAAGGCCGGGCCGGCTCCGCGCTCAGCGAGCGGAGACCCCGCGGCCGCCGCAGGTGCAAGCGCCGCAAGCCCCGCCCCGCCCGCCGCCCCAGCCAACCGCGGGCGGCGGGGGCGGGGCCTGGACCCGCCACACCTGGGGCGGCCGCCCGGCCGTGTCCCAACCACGCTGCCCACAGCCCGCGGCCCGCCGCTCAAGCCCGCCGCCCCGCCCCACCCGCGTCCCCGGCCCCTGCCTGCCCCGCGACCGGTGCGAGGCCCGCCCTGCCCACCCGGCCGGAGTCGTCCCCTCAGTCCCGCCGCCGCGCCGCCCCAGCCGTTTCCACAACGGCTCCGCCTCAACCGTCGGGAGGCTGGCCGTCCGCCCGCTCGCCCACCCGCCGCTGCTGGAGACCGGCCCGGCGTCACGGCCCCCCTCCACGCAGCCCCGCTGTCAGGGAGGCCCGGCCCGGCGCCCGGCTCTACCTGCGGCTGGAGGAAGCCTCCCCGTCCGGGCCCGGGAGCCGCCGCCACGGCCGCCGACTCGAGTCGCGTCTCTGCTCTCCGCGACCGCCGCGGCTCTTCAGGCGGCCGACGGTGGGCGGGAAGCGCCCGCCCAATCAGCGCCGCGTGCGTTCGGAATCGCGTCCAATCAGCGCAGCTCGCAGTCCAGGCTCCGCCCCTCGTGCTCGCCGGCGACGCAGGGGTCGCCAGAGGCCGAAGCCAGGGGCGCCGCGGTGGGCGCGGCTCGGGGCCGGGCCGGGTAG
->MF950468.1 Uncultured bacterium clone OTU1501_Control_T4.8037 16S ribosomal RNA gene, partial sequence 
-ATACGGGAGGCAGCAGTGGGGAATCTTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGAGCGATGAAGCCCTTCGGGGTGTAAAGCTCTTTCGGCGGGGACGATAATGACGGTACCCGCAGAAGCAGCTGCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGCAGCGAGCGTTGTTCGGAGTTACTGGGCGTAAAGGGTGTGTAGGCGGTTCCTTAAGTTTGGTGTGAAATCTCCCGGCTCAACTGGGAGGGTGCGCCGGATACTGAGGAGCTAGAGTGCGGGAGAGGAAAGTGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCTGTGGTGTAGACGGCTTTCTGGACCGTGACTGACGCTGAGACACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGT
->XM_038920781.1 Brettanomyces nanus uncharacterized protein (FOA43_000450), partial mRNA 
-ATGATGAAAGCTTTAACATATGTCAGACCAGGAGTTATCAAGTACCAGGATGTGGAGAAACCAAAATTACTTCAGCCTACAGATGTGATCGGAAAGACCGTTGTAACAACTATTTGCGGATCGGATCTTCATATCCTTTCAGGTGCTTTCCCAGAGTTCAACAAGTTGGCCGAGAAAAAGGCTGGCCGAGGATTTATCTTGGGTCATGAGGGTATCATCAAGGTGGAGCAAATAGGTTCTGAAGTAAAGAACTTTAAAGTCGGTGATGTGTGCATCGTCTCTTGCATCACTCCTTGTGGTGAATGCTTTTACTGTAAAGAAGGTTGCGAAGCTCATTGTACACAGAACGAGGGAACCTGTGGATGCATCTTGGGTAGTGAGATTGATGGAACTCAAGCTGATTATGTTAGAGTTCCTCTTGCTGACAATTCTTTAATCAAATGCCCGGATAACGTGAAGTTGGAGTCTTTATTAATGCTTAGTGACATTTTACCAACCTCCTACGAACTTGGTGTTCTGGATGGAGGTGTCAAAGAAGGAAGTACCGTTGCCATTGTCGGTATGGGACCTGTTGGGTTGGCTGCTTTGATCAGTGCTAAGGCATTGAATCCAGATTATATTGTTGCTATCGACTTGAACGAATCCAGATTGAAGACTGCCAAAAAATTGGGTGCCGACTACACCTTTAATCCAAGCAAGGATGATGTTGTTAAACTTGTTATGGGGCTTCCTGTGAAACAGGGTAAGCTACCCGGTGTCGATGTGGCCATCGAATGCTGTGGTATTCCGGCAACTTTCGAGATGTGCCAGGATATTGTTGGTATGAACGGTAGAATTGCCAATGTCGGTGTTCACTCTAAGTCATGCAAACTTGCTATGGAAAAGTTATGGGTCATGAATATCAACATAAGTACCGGATTGGTCTGCGGCCATTCTACAAAAGATTTACTCAGGAAAGTTGTATCCGGAGAATTGGATCCTTCGTCTTTGATTACTCATCGCTTCAAACTAAATGAGATCGAAAAGGCTTACGATGTCTTCAGCAATGCTTCTGAGACTGATGCCATTAAGATGCTTCTTATCAACGATTGA
->MW263500.1 Cortinarius sp. PDD 112391 isolate JAC15241 large subunit ribosomal RNA gene, partial sequence 
-CATATCAATAAGCGGAGGAAAAGAAACTAACAAGGGATTCCCCCTAGTAACTGCGAGTGAAGCGGGAAAAGCTCAAATTTAAAATCTGGCGGTCTTTGGCTGTCCGAGTTGTAATCTAGAGAAGTGTTATCCGCGCCGGACCGTGTACAAGTCTCCTGGAATGGAGCGTCATAGAGGGTGAGAATCCCGTCTTTGACACGGACTACCGGGGCTTTGTGATGCGCTCTCAAAGAGTCGAGTTGTTTGGGAATGCAGCTCAAAATGGGTGGTAAATTCCATCTAAAGCTAAATATTGGCGAGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGATGAAAAGAACTTTGGAAAGAGAGTTAAACAGTACGTGAAATTGCTGAAAGGGAAACGCTTGAAGTCAGTCGCGTTGTCCAGGGATCAACCTTGCTTTTGCTTGGTGCACTTTCTGGTTGACGGGTCAGCATCAATTTTGACTATTGGAAAAAGATTAGGGGAATGTGGCATCTTTGGATGTGTTATAGCCCTTGGTTGCATACAATGGTTGGGATTGAGGAACTCAGCACGCCGCAAGGCCGGGTTTTTAACCACGTACGTGCTTAGGATGCTGGCATAATGGCTTTAATCGACCCGTCTTGAAACACGGACCAAGGAGTCTAACATGCCTGCGAGTGTTTGGGTGGAAAACTCGAGCGCGTAATGAAAGTGAAAGTTGAGATCCCTGTCGTGGGGAGCATCGACGCCCGGACCAGACCTTTTGTGACGGTTCCGCGGTAGAGCATGTATGTTGGGACCCGAAAGATGGTGAACTATGCCTGAATAGGGTGAAGCCAGAGGAAACTCTGGTGGAGGCTCGTAGCGATTCTGACGTGCAAATCGATCGTCAAATTTGGGTAT
->MN640403.1 Mycobacterium simiae strain a18 16S-23S ribosomal RNA intergenic spacer and 23S ribosomal RNA gene, partial sequence 
-GAATCTTGACTGGGGTGTGAGCCGTGAGGGGTTCTCGTCTGTAGTGGACGAGGGCCGGGTGCACAACAACAGGCAATCGCCAGACACACTATTGGGCCCTGAGACAACACTCGGCCGACTTCGGTTGAAGTGGTGTCCCTCCATCTTGGTGGTGGGGTGTGGTGTTTGAGTATTGAATAGTGGTTGCGAGCATCAGGAGGTACCTCCGTTCTGTTTGAGTATTGGATAGTGGTTGCGAGCATCAGGGTGGTGGGGTGTGGGGTTTGACATCAGAATGGTGAAGGCAATTATCAGGTACCGCCTC
diff --git a/src/alphafold3/test_data/miniature_databases/pdb_mmcif/5y2e.cif b/src/alphafold3/test_data/miniature_databases/pdb_mmcif/5y2e.cif
deleted file mode 100644
index 5bdf12d8578f56fb7ade71be04307468ca0c311d..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/pdb_mmcif/5y2e.cif
+++ /dev/null
@@ -1,562 +0,0 @@
-data_5Y2E
-#
-_entry.id 5Y2E
-#
-loop_
-_chem_comp.formula
-_chem_comp.formula_weight
-_chem_comp.id
-_chem_comp.mon_nstd_flag
-_chem_comp.name
-_chem_comp.pdbx_synonyms
-_chem_comp.type
-"C3 H7 N O2"     89.093  ALA y ALANINE         ? "L-peptide linking" 
-"C6 H15 N4 O2 1" 175.209 ARG y ARGININE        ? "L-peptide linking" 
-"C4 H7 N O4"     133.103 ASP y "ASPARTIC ACID" ? "L-peptide linking" 
-"C5 H10 N2 O3"   146.144 GLN y GLUTAMINE       ? "L-peptide linking" 
-"C5 H9 N O4"     147.129 GLU y "GLUTAMIC ACID" ? "L-peptide linking" 
-"C2 H5 N O2"     75.067  GLY y GLYCINE         ? "peptide linking"   
-"C6 H10 N3 O2 1" 156.162 HIS y HISTIDINE       ? "L-peptide linking" 
-"H2 O"           18.015  HOH . WATER           ? non-polymer         
-"C6 H13 N O2"    131.173 ILE y ISOLEUCINE      ? "L-peptide linking" 
-"C6 H13 N O2"    131.173 LEU y LEUCINE         ? "L-peptide linking" 
-"C6 H15 N2 O2 1" 147.195 LYS y LYSINE          ? "L-peptide linking" 
-"C5 H11 N O2 S"  149.211 MET y METHIONINE      ? "L-peptide linking" 
-"C4 H9 N O3"     119.119 THR y THREONINE       ? "L-peptide linking" 
-"C5 H11 N O2"    117.146 VAL y VALINE          ? "L-peptide linking" 
-#
-_entity.id               1
-_entity.pdbx_description "Non-structural glycoprotein 4"
-_entity.type             polymer
-#
-_entity_poly.entity_id      1
-_entity_poly.pdbx_strand_id A
-_entity_poly.type           polypeptide(L)
-#
-loop_
-_entity_poly_seq.entity_id
-_entity_poly_seq.hetero
-_entity_poly_seq.mon_id
-_entity_poly_seq.num
-1 n MET 1  
-1 n ILE 2  
-1 n GLU 3  
-1 n LYS 4  
-1 n GLN 5  
-1 n MET 6  
-1 n ASP 7  
-1 n ARG 8  
-1 n VAL 9  
-1 n VAL 10 
-1 n LYS 11 
-1 n GLU 12 
-1 n MET 13 
-1 n ARG 14 
-1 n ARG 15 
-1 n GLN 16 
-1 n LEU 17 
-1 n GLU 18 
-1 n MET 19 
-1 n ILE 20 
-1 n ASP 21 
-1 n LYS 22 
-1 n LEU 23 
-1 n THR 24 
-1 n THR 25 
-1 n ARG 26 
-1 n GLY 27 
-1 n ILE 28 
-1 n GLU 29 
-1 n GLN 30 
-1 n VAL 31 
-1 n GLU 32 
-1 n LEU 33 
-1 n LEU 34 
-1 n LYS 35 
-1 n ARG 36 
-1 n ILE 37 
-1 n HIS 38 
-1 n ASP 39 
-1 n LYS 40 
-1 n LEU 41 
-1 n MET 42 
-1 n ILE 43 
-1 n ARG 44 
-1 n ALA 45 
-1 n VAL 46 
-1 n ASP 47 
-#
-_exptl.method "X-RAY DIFFRACTION"
-#
-_pdbx_audit_revision_history.revision_date 2018-03-14
-#
-_pdbx_database_status.recvd_initial_deposition_date 2018-03-14
-#
-loop_
-_pdbx_poly_seq_scheme.asym_id
-_pdbx_poly_seq_scheme.auth_seq_num
-_pdbx_poly_seq_scheme.entity_id
-_pdbx_poly_seq_scheme.hetero
-_pdbx_poly_seq_scheme.mon_id
-_pdbx_poly_seq_scheme.pdb_ins_code
-_pdbx_poly_seq_scheme.pdb_seq_num
-_pdbx_poly_seq_scheme.pdb_strand_id
-_pdbx_poly_seq_scheme.seq_id
-B 94  1 n MET . 94  A 1  
-B 95  1 n ILE . 95  A 2  
-B 96  1 n GLU . 96  A 3  
-B 97  1 n LYS . 97  A 4  
-B 98  1 n GLN . 98  A 5  
-B 99  1 n MET . 99  A 6  
-B 100 1 n ASP . 100 A 7  
-B 101 1 n ARG . 101 A 8  
-B 102 1 n VAL . 102 A 9  
-B 103 1 n VAL . 103 A 10 
-B 104 1 n LYS . 104 A 11 
-B 105 1 n GLU . 105 A 12 
-B 106 1 n MET . 106 A 13 
-B 107 1 n ARG . 107 A 14 
-B 108 1 n ARG . 108 A 15 
-B 109 1 n GLN . 109 A 16 
-B 110 1 n LEU . 110 A 17 
-B 111 1 n GLU . 111 A 18 
-B 112 1 n MET . 112 A 19 
-B 113 1 n ILE . 113 A 20 
-B 114 1 n ASP . 114 A 21 
-B 115 1 n LYS . 115 A 22 
-B 116 1 n LEU . 116 A 23 
-B 117 1 n THR . 117 A 24 
-B 118 1 n THR . 118 A 25 
-B 119 1 n ARG . 119 A 26 
-B 120 1 n GLY . 120 A 27 
-B 121 1 n ILE . 121 A 28 
-B 122 1 n GLU . 122 A 29 
-B 123 1 n GLN . 123 A 30 
-B 124 1 n VAL . 124 A 31 
-B 125 1 n GLU . 125 A 32 
-B 126 1 n LEU . 126 A 33 
-B 127 1 n LEU . 127 A 34 
-B 128 1 n LYS . 128 A 35 
-B 129 1 n ARG . 129 A 36 
-B 130 1 n ILE . 130 A 37 
-B 131 1 n HIS . 131 A 38 
-B 132 1 n ASP . 132 A 39 
-B 133 1 n LYS . 133 A 40 
-B 134 1 n LEU . 134 A 41 
-B 135 1 n MET . 135 A 42 
-B 136 1 n ILE . 136 A 43 
-B 137 1 n ARG . 137 A 44 
-B 138 1 n ALA . 138 A 45 
-B ?   1 n VAL . 139 A 46 
-B ?   1 n ASP . 140 A 47 
-#
-_pdbx_struct_assembly.details            author_and_software_defined_assembly
-_pdbx_struct_assembly.id                 1
-_pdbx_struct_assembly.method_details     PISA
-_pdbx_struct_assembly.oligomeric_count   4
-_pdbx_struct_assembly.oligomeric_details tetrameric
-#
-_pdbx_struct_assembly_gen.assembly_id     1
-_pdbx_struct_assembly_gen.asym_id_list    A,B,C,D,E,F,G
-_pdbx_struct_assembly_gen.oper_expression 1
-#
-_pdbx_struct_oper_list.id                 1
-_pdbx_struct_oper_list.matrix[1][1]       1.0000000000
-_pdbx_struct_oper_list.matrix[1][2]       0.0000000000
-_pdbx_struct_oper_list.matrix[1][3]       0.0000000000
-_pdbx_struct_oper_list.matrix[2][1]       0.0000000000
-_pdbx_struct_oper_list.matrix[2][2]       1.0000000000
-_pdbx_struct_oper_list.matrix[2][3]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][1]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][2]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][3]       1.0000000000
-_pdbx_struct_oper_list.name               1_555
-_pdbx_struct_oper_list.symmetry_operation x,y,z
-_pdbx_struct_oper_list.type               "identity operation"
-_pdbx_struct_oper_list.vector[1]          0.0000000000
-_pdbx_struct_oper_list.vector[2]          0.0000000000
-_pdbx_struct_oper_list.vector[3]          0.0000000000
-#
-_refine.ls_d_res_high 2.70
-#
-_software.classification other
-_software.name           "DeepMind Structure Class"
-_software.pdbx_ordinal   1
-_software.version        2.0.0
-#
-_struct_asym.entity_id 1
-_struct_asym.id        B
-#
-loop_
-_atom_site.group_PDB
-_atom_site.id
-_atom_site.type_symbol
-_atom_site.label_atom_id
-_atom_site.label_alt_id
-_atom_site.label_comp_id
-_atom_site.label_asym_id
-_atom_site.label_entity_id
-_atom_site.label_seq_id
-_atom_site.pdbx_PDB_ins_code
-_atom_site.Cartn_x
-_atom_site.Cartn_y
-_atom_site.Cartn_z
-_atom_site.occupancy
-_atom_site.B_iso_or_equiv
-_atom_site.auth_seq_id
-_atom_site.auth_asym_id
-_atom_site.pdbx_PDB_model_num
-ATOM 1   N N   . MET B 1 1  ? 2.644   6.839  -46.028 1.00 83.71  94  A 1 
-ATOM 2   C CA  . MET B 1 1  ? 1.400   7.612  -45.825 1.00 86.32  94  A 1 
-ATOM 3   C C   . MET B 1 1  ? 1.210   7.971  -44.344 1.00 87.15  94  A 1 
-ATOM 4   O O   . MET B 1 1  ? 1.479   7.188  -43.421 1.00 80.48  94  A 1 
-ATOM 5   C CB  . MET B 1 1  ? 0.170   6.890  -46.382 1.00 88.07  94  A 1 
-ATOM 6   C CG  . MET B 1 1  ? -0.124  7.275  -47.840 1.00 91.84  94  A 1 
-ATOM 7   S SD  . MET B 1 1  ? -1.789  6.807  -48.325 1.00 103.69 94  A 1 
-ATOM 8   C CE  . MET B 1 1  ? -2.264  8.027  -49.569 1.00 97.89  94  A 1 
-ATOM 9   N N   . ILE B 1 2  ? 0.696   9.166  -44.185 1.00 87.93  95  A 1 
-ATOM 10  C CA  . ILE B 1 2  ? 0.364   9.779  -42.948 1.00 84.67  95  A 1 
-ATOM 11  C C   . ILE B 1 2  ? -0.678  8.946  -42.258 1.00 75.98  95  A 1 
-ATOM 12  O O   . ILE B 1 2  ? -0.634  8.714  -41.080 1.00 67.98  95  A 1 
-ATOM 13  C CB  . ILE B 1 2  ? -0.321  11.082 -43.309 1.00 89.99  95  A 1 
-ATOM 14  C CG1 . ILE B 1 2  ? 0.696   12.146 -43.577 1.00 94.59  95  A 1 
-ATOM 15  C CG2 . ILE B 1 2  ? -1.197  11.546 -42.182 1.00 92.79  95  A 1 
-ATOM 16  C CD1 . ILE B 1 2  ? 1.132   12.780 -42.294 1.00 93.36  95  A 1 
-ATOM 17  N N   . GLU B 1 3  ? -1.625  8.499  -43.046 1.00 71.66  96  A 1 
-ATOM 18  C CA  . GLU B 1 3  ? -2.745  7.716  -42.585 1.00 68.44  96  A 1 
-ATOM 19  C C   . GLU B 1 3  ? -2.273  6.463  -41.883 1.00 69.98  96  A 1 
-ATOM 20  O O   . GLU B 1 3  ? -2.890  6.024  -40.946 1.00 67.88  96  A 1 
-ATOM 21  C CB  . GLU B 1 3  ? -3.613  7.332  -43.745 1.00 73.44  96  A 1 
-ATOM 22  C CG  . GLU B 1 3  ? -4.382  8.485  -44.320 1.00 87.42  96  A 1 
-ATOM 23  C CD  . GLU B 1 3  ? -3.735  9.039  -45.551 1.00 89.38  96  A 1 
-ATOM 24  O OE1 . GLU B 1 3  ? -4.454  9.413  -46.477 1.00 97.81  96  A 1 
-ATOM 25  O OE2 . GLU B 1 3  ? -2.511  9.105  -45.593 1.00 88.14  96  A 1 
-ATOM 26  N N   . LYS B 1 4  ? -1.212  5.844  -42.364 1.00 71.45  97  A 1 
-ATOM 27  C CA  . LYS B 1 4  ? -0.676  4.669  -41.671 1.00 72.76  97  A 1 
-ATOM 28  C C   . LYS B 1 4  ? 0.097   5.062  -40.408 1.00 74.11  97  A 1 
-ATOM 29  O O   . LYS B 1 4  ? 0.209   4.268  -39.462 1.00 77.84  97  A 1 
-ATOM 30  C CB  . LYS B 1 4  ? 0.197   3.807  -42.578 1.00 66.63  97  A 1 
-ATOM 31  N N   . GLN B 1 5  ? 0.624   6.270  -40.364 1.00 72.03  98  A 1 
-ATOM 32  C CA  . GLN B 1 5  ? 1.295   6.749  -39.158 1.00 65.60  98  A 1 
-ATOM 33  C C   . GLN B 1 5  ? 0.255   7.097  -38.099 1.00 58.64  98  A 1 
-ATOM 34  O O   . GLN B 1 5  ? 0.462   6.888  -36.942 1.00 52.26  98  A 1 
-ATOM 35  C CB  . GLN B 1 5  ? 2.143   7.976  -39.487 1.00 63.76  98  A 1 
-ATOM 36  N N   . MET B 1 6  ? -0.861  7.648  -38.542 1.00 49.04  99  A 1 
-ATOM 37  C CA  . MET B 1 6  ? -1.953  7.954  -37.679 1.00 45.66  99  A 1 
-ATOM 38  C C   . MET B 1 6  ? -2.486  6.679  -37.100 1.00 50.63  99  A 1 
-ATOM 39  O O   . MET B 1 6  ? -2.882  6.643  -35.948 1.00 50.11  99  A 1 
-ATOM 40  C CB  . MET B 1 6  ? -3.050  8.640  -38.449 1.00 42.97  99  A 1 
-ATOM 41  C CG  . MET B 1 6  ? -4.395  8.703  -37.753 1.00 42.67  99  A 1 
-ATOM 42  S SD  . MET B 1 6  ? -5.430  9.916  -38.524 1.00 47.21  99  A 1 
-ATOM 43  C CE  . MET B 1 6  ? -6.803  9.938  -37.397 1.00 48.85  99  A 1 
-ATOM 44  N N   . ASP B 1 7  ? -2.531  5.622  -37.894 1.00 56.67  100 A 1 
-ATOM 45  C CA  . ASP B 1 7  ? -3.070  4.383  -37.401 1.00 55.17  100 A 1 
-ATOM 46  C C   . ASP B 1 7  ? -2.223  3.846  -36.257 1.00 53.54  100 A 1 
-ATOM 47  O O   . ASP B 1 7  ? -2.785  3.365  -35.256 1.00 47.69  100 A 1 
-ATOM 48  C CB  . ASP B 1 7  ? -3.067  3.354  -38.520 1.00 57.94  100 A 1 
-ATOM 49  C CG  . ASP B 1 7  ? -3.936  2.164  -38.236 1.00 62.42  100 A 1 
-ATOM 50  O OD1 . ASP B 1 7  ? -5.111  2.416  -37.949 1.00 67.59  100 A 1 
-ATOM 51  O OD2 . ASP B 1 7  ? -3.401  1.020  -38.206 1.00 61.64  100 A 1 
-ATOM 52  N N   . ARG B 1 8  ? -0.900  3.909  -36.428 1.00 54.78  101 A 1 
-ATOM 53  C CA  . ARG B 1 8  ? -0.002  3.384  -35.432 1.00 61.23  101 A 1 
-ATOM 54  C C   . ARG B 1 8  ? -0.168  4.177  -34.127 1.00 63.20  101 A 1 
-ATOM 55  O O   . ARG B 1 8  ? -0.017  3.620  -33.077 1.00 67.94  101 A 1 
-ATOM 56  C CB  . ARG B 1 8  ? 1.484   3.327  -35.943 1.00 64.73  101 A 1 
-ATOM 57  C CG  . ARG B 1 8  ? 2.403   4.541  -35.635 1.00 73.16  101 A 1 
-ATOM 58  N N   . VAL B 1 9  ? -0.406  5.483  -34.222 1.00 63.14  102 A 1 
-ATOM 59  C CA  . VAL B 1 9  ? -0.546  6.334  -33.061 1.00 59.81  102 A 1 
-ATOM 60  C C   . VAL B 1 9  ? -1.853  6.121  -32.347 1.00 55.82  102 A 1 
-ATOM 61  O O   . VAL B 1 9  ? -1.880  6.066  -31.150 1.00 48.46  102 A 1 
-ATOM 62  C CB  . VAL B 1 9  ? -0.421  7.813  -33.454 1.00 60.39  102 A 1 
-ATOM 63  C CG1 . VAL B 1 9  ? -0.731  8.703  -32.272 1.00 60.03  102 A 1 
-ATOM 64  C CG2 . VAL B 1 9  ? 0.994   8.091  -33.943 1.00 61.68  102 A 1 
-ATOM 65  N N   . VAL B 1 10 ? -2.941  6.014  -33.079 1.00 56.18  103 A 1 
-ATOM 66  C CA  . VAL B 1 10 ? -4.231  5.743  -32.481 1.00 53.53  103 A 1 
-ATOM 67  C C   . VAL B 1 10 ? -4.236  4.419  -31.704 1.00 52.90  103 A 1 
-ATOM 68  O O   . VAL B 1 10 ? -4.772  4.355  -30.607 1.00 49.99  103 A 1 
-ATOM 69  C CB  . VAL B 1 10 ? -5.317  5.742  -33.553 1.00 51.75  103 A 1 
-ATOM 70  C CG1 . VAL B 1 10 ? -6.606  5.137  -33.045 1.00 52.18  103 A 1 
-ATOM 71  C CG2 . VAL B 1 10 ? -5.610  7.153  -33.983 1.00 52.67  103 A 1 
-ATOM 72  N N   . LYS B 1 11 ? -3.601  3.402  -32.243 1.00 55.55  104 A 1 
-ATOM 73  C CA  . LYS B 1 11 ? -3.521  2.104  -31.626 1.00 56.87  104 A 1 
-ATOM 74  C C   . LYS B 1 11 ? -2.709  2.164  -30.350 1.00 60.76  104 A 1 
-ATOM 75  O O   . LYS B 1 11 ? -2.986  1.464  -29.399 1.00 58.80  104 A 1 
-ATOM 76  C CB  . LYS B 1 11 ? -2.837  1.155  -32.582 1.00 60.72  104 A 1 
-ATOM 77  C CG  . LYS B 1 11 ? -3.729  0.487  -33.601 1.00 72.80  104 A 1 
-ATOM 78  C CD  . LYS B 1 11 ? -2.915  -0.472 -34.451 1.00 79.85  104 A 1 
-ATOM 79  C CE  . LYS B 1 11 ? -3.664  -0.963 -35.666 1.00 84.90  104 A 1 
-ATOM 80  N NZ  . LYS B 1 11 ? -5.110  -0.693 -35.513 1.00 94.50  104 A 1 
-ATOM 81  N N   . GLU B 1 12 ? -1.674  2.982  -30.369 1.00 56.70  105 A 1 
-ATOM 82  C CA  . GLU B 1 12 ? -0.798  3.204  -29.249 1.00 54.71  105 A 1 
-ATOM 83  C C   . GLU B 1 12 ? -1.507  3.946  -28.155 1.00 52.45  105 A 1 
-ATOM 84  O O   . GLU B 1 12 ? -1.387  3.608  -27.007 1.00 51.88  105 A 1 
-ATOM 85  C CB  . GLU B 1 12 ? 0.404   4.036  -29.667 1.00 60.63  105 A 1 
-ATOM 86  C CG  . GLU B 1 12 ? 1.418   4.261  -28.569 1.00 71.75  105 A 1 
-ATOM 87  C CD  . GLU B 1 12 ? 2.100   2.985  -28.105 1.00 83.66  105 A 1 
-ATOM 88  O OE1 . GLU B 1 12 ? 1.973   1.951  -28.793 1.00 97.71  105 A 1 
-ATOM 89  O OE2 . GLU B 1 12 ? 2.729   3.008  -27.039 1.00 91.62  105 A 1 
-ATOM 90  N N   . MET B 1 13 ? -2.250  4.972  -28.495 1.00 50.99  106 A 1 
-ATOM 91  C CA  . MET B 1 13 ? -2.993  5.703  -27.508 1.00 53.07  106 A 1 
-ATOM 92  C C   . MET B 1 13 ? -4.045  4.874  -26.849 1.00 51.54  106 A 1 
-ATOM 93  O O   . MET B 1 13 ? -4.220  4.974  -25.651 1.00 48.88  106 A 1 
-ATOM 94  C CB  . MET B 1 13 ? -3.640  6.915  -28.107 1.00 61.60  106 A 1 
-ATOM 95  C CG  . MET B 1 13 ? -2.651  8.032  -28.402 1.00 65.35  106 A 1 
-ATOM 96  S SD  . MET B 1 13 ? -3.551  9.590  -28.498 1.00 76.88  106 A 1 
-ATOM 97  C CE  . MET B 1 13 ? -3.620  9.931  -26.737 1.00 76.03  106 A 1 
-ATOM 98  N N   . ARG B 1 14 ? -4.714  4.016  -27.571 1.00 53.52  107 A 1 
-ATOM 99  C CA  . ARG B 1 14 ? -5.703  3.187  -26.952 1.00 50.53  107 A 1 
-ATOM 100 C C   . ARG B 1 14 ? -5.040  2.268  -25.975 1.00 51.01  107 A 1 
-ATOM 101 O O   . ARG B 1 14 ? -5.527  2.040  -24.903 1.00 48.89  107 A 1 
-ATOM 102 C CB  . ARG B 1 14 ? -6.358  2.367  -28.011 1.00 54.79  107 A 1 
-ATOM 103 C CG  . ARG B 1 14 ? -7.580  1.648  -27.566 1.00 60.71  107 A 1 
-ATOM 104 C CD  . ARG B 1 14 ? -7.895  0.586  -28.570 1.00 70.83  107 A 1 
-ATOM 105 N NE  . ARG B 1 14 ? -8.689  1.116  -29.658 1.00 78.79  107 A 1 
-ATOM 106 C CZ  . ARG B 1 14 ? -8.278  1.182  -30.911 1.00 81.77  107 A 1 
-ATOM 107 N NH1 . ARG B 1 14 ? -7.086  0.746  -31.233 1.00 91.09  107 A 1 
-ATOM 108 N NH2 . ARG B 1 14 ? -9.071  1.675  -31.832 1.00 79.36  107 A 1 
-ATOM 109 N N   . ARG B 1 15 ? -3.896  1.754  -26.355 1.00 46.73  108 A 1 
-ATOM 110 C CA  . ARG B 1 15 ? -3.174  0.827  -25.534 1.00 45.05  108 A 1 
-ATOM 111 C C   . ARG B 1 15 ? -2.681  1.503  -24.248 1.00 47.85  108 A 1 
-ATOM 112 O O   . ARG B 1 15 ? -2.752  0.930  -23.189 1.00 50.40  108 A 1 
-ATOM 113 C CB  . ARG B 1 15 ? -2.063  0.286  -26.404 1.00 50.23  108 A 1 
-ATOM 114 C CG  . ARG B 1 15 ? -1.165  -0.750 -25.876 1.00 59.06  108 A 1 
-ATOM 115 C CD  . ARG B 1 15 ? -0.358  -1.317 -27.046 1.00 59.59  108 A 1 
-ATOM 116 N NE  . ARG B 1 15 ? 0.861   -1.991 -26.583 1.00 65.92  108 A 1 
-ATOM 117 N N   . GLN B 1 16 ? -2.221  2.739  -24.349 1.00 49.74  109 A 1 
-ATOM 118 C CA  . GLN B 1 16 ? -1.810  3.511  -23.193 1.00 47.85  109 A 1 
-ATOM 119 C C   . GLN B 1 16 ? -2.993  3.774  -22.279 1.00 48.41  109 A 1 
-ATOM 120 O O   . GLN B 1 16 ? -2.898  3.560  -21.091 1.00 46.33  109 A 1 
-ATOM 121 C CB  . GLN B 1 16 ? -1.209  4.809  -23.611 1.00 49.18  109 A 1 
-ATOM 122 C CG  . GLN B 1 16 ? 0.208   4.681  -24.112 1.00 53.75  109 A 1 
-ATOM 123 C CD  . GLN B 1 16 ? 0.618   5.857  -24.974 1.00 61.24  109 A 1 
-ATOM 124 O OE1 . GLN B 1 16 ? -0.145  6.791  -25.159 1.00 69.70  109 A 1 
-ATOM 125 N NE2 . GLN B 1 16 ? 1.786   5.782  -25.546 1.00 63.00  109 A 1 
-ATOM 126 N N   . LEU B 1 17 ? -4.098  4.266  -22.817 1.00 45.61  110 A 1 
-ATOM 127 C CA  . LEU B 1 17 ? -5.278  4.506  -22.010 1.00 41.80  110 A 1 
-ATOM 128 C C   . LEU B 1 17 ? -5.848  3.244  -21.329 1.00 44.01  110 A 1 
-ATOM 129 O O   . LEU B 1 17 ? -6.378  3.314  -20.232 1.00 49.63  110 A 1 
-ATOM 130 C CB  . LEU B 1 17 ? -6.380  5.133  -22.818 1.00 41.83  110 A 1 
-ATOM 131 C CG  . LEU B 1 17 ? -6.545  6.610  -23.075 1.00 44.57  110 A 1 
-ATOM 132 C CD1 . LEU B 1 17 ? -6.481  7.448  -21.815 1.00 46.53  110 A 1 
-ATOM 133 C CD2 . LEU B 1 17 ? -5.534  7.076  -24.054 1.00 46.70  110 A 1 
-ATOM 134 N N   . GLU B 1 18 ? -5.724  2.085  -21.974 1.00 48.92  111 A 1 
-ATOM 135 C CA  . GLU B 1 18 ? -6.176  0.854  -21.354 1.00 50.45  111 A 1 
-ATOM 136 C C   . GLU B 1 18 ? -5.278  0.446  -20.173 1.00 50.00  111 A 1 
-ATOM 137 O O   . GLU B 1 18 ? -5.748  -0.088 -19.155 1.00 52.97  111 A 1 
-ATOM 138 C CB  . GLU B 1 18 ? -6.361  -0.236 -22.405 1.00 54.05  111 A 1 
-ATOM 139 C CG  . GLU B 1 18 ? -7.693  -0.095 -23.112 1.00 59.57  111 A 1 
-ATOM 140 C CD  . GLU B 1 18 ? -7.804  -0.858 -24.438 1.00 68.03  111 A 1 
-ATOM 141 O OE1 . GLU B 1 18 ? -6.834  -1.521 -24.893 1.00 73.96  111 A 1 
-ATOM 142 O OE2 . GLU B 1 18 ? -8.896  -0.808 -25.069 1.00 73.24  111 A 1 
-ATOM 143 N N   . MET B 1 19 ? -4.000  0.760  -20.284 1.00 48.79  112 A 1 
-ATOM 144 C CA  . MET B 1 19 ? -3.094  0.512  -19.186 1.00 52.15  112 A 1 
-ATOM 145 C C   . MET B 1 19 ? -3.371  1.430  -18.007 1.00 47.91  112 A 1 
-ATOM 146 O O   . MET B 1 19 ? -3.429  0.986  -16.872 1.00 45.58  112 A 1 
-ATOM 147 C CB  . MET B 1 19 ? -1.653  0.667  -19.617 1.00 54.11  112 A 1 
-ATOM 148 C CG  . MET B 1 19 ? -1.053  -0.654 -20.052 1.00 58.96  112 A 1 
-ATOM 149 S SD  . MET B 1 19 ? 0.471   -0.323 -20.923 1.00 65.09  112 A 1 
-ATOM 150 C CE  . MET B 1 19 ? 1.501   -0.237 -19.466 1.00 67.56  112 A 1 
-ATOM 151 N N   . ILE B 1 20 ? -3.541  2.711  -18.297 1.00 43.25  113 A 1 
-ATOM 152 C CA  . ILE B 1 20 ? -3.900  3.677  -17.287 1.00 40.09  113 A 1 
-ATOM 153 C C   . ILE B 1 20 ? -5.165  3.240  -16.596 1.00 40.28  113 A 1 
-ATOM 154 O O   . ILE B 1 20 ? -5.297  3.383  -15.395 1.00 41.67  113 A 1 
-ATOM 155 C CB  . ILE B 1 20 ? -4.079  5.077  -17.885 1.00 41.26  113 A 1 
-ATOM 156 C CG1 . ILE B 1 20 ? -2.700  5.633  -18.275 1.00 39.56  113 A 1 
-ATOM 157 C CG2 . ILE B 1 20 ? -4.715  6.029  -16.880 1.00 44.72  113 A 1 
-ATOM 158 C CD1 . ILE B 1 20 ? -2.722  6.963  -19.009 1.00 37.40  113 A 1 
-ATOM 159 N N   . ASP B 1 21 ? -6.096  2.680  -17.346 1.00 41.39  114 A 1 
-ATOM 160 C CA  . ASP B 1 21 ? -7.302  2.201  -16.728 1.00 46.35  114 A 1 
-ATOM 161 C C   . ASP B 1 21 ? -7.074  1.044  -15.762 1.00 45.76  114 A 1 
-ATOM 162 O O   . ASP B 1 21 ? -7.662  1.035  -14.682 1.00 43.56  114 A 1 
-ATOM 163 C CB  . ASP B 1 21 ? -8.272  1.734  -17.759 1.00 51.71  114 A 1 
-ATOM 164 C CG  . ASP B 1 21 ? -9.647  1.640  -17.208 1.00 60.74  114 A 1 
-ATOM 165 O OD1 . ASP B 1 21 ? -10.153 2.682  -16.742 1.00 68.50  114 A 1 
-ATOM 166 O OD2 . ASP B 1 21 ? -10.199 0.528  -17.210 1.00 73.36  114 A 1 
-ATOM 167 N N   . LYS B 1 22 ? -6.258  0.070  -16.178 1.00 47.51  115 A 1 
-ATOM 168 C CA  . LYS B 1 22 ? -5.942  -1.062 -15.321 1.00 50.59  115 A 1 
-ATOM 169 C C   . LYS B 1 22 ? -5.255  -0.563 -14.028 1.00 52.11  115 A 1 
-ATOM 170 O O   . LYS B 1 22 ? -5.648  -0.941 -12.919 1.00 55.27  115 A 1 
-ATOM 171 C CB  . LYS B 1 22 ? -5.085  -2.111 -16.025 1.00 52.86  115 A 1 
-ATOM 172 C CG  . LYS B 1 22 ? -5.829  -3.010 -17.008 1.00 57.80  115 A 1 
-ATOM 173 N N   . LEU B 1 23 ? -4.266  0.312  -14.176 1.00 48.62  116 A 1 
-ATOM 174 C CA  . LEU B 1 23 ? -3.594  0.880  -13.039 1.00 44.80  116 A 1 
-ATOM 175 C C   . LEU B 1 23 ? -4.511  1.665  -12.106 1.00 44.04  116 A 1 
-ATOM 176 O O   . LEU B 1 23 ? -4.412  1.565  -10.897 1.00 41.22  116 A 1 
-ATOM 177 C CB  . LEU B 1 23 ? -2.492  1.781  -13.511 1.00 43.26  116 A 1 
-ATOM 178 C CG  . LEU B 1 23 ? -1.353  1.039  -14.177 1.00 45.18  116 A 1 
-ATOM 179 C CD1 . LEU B 1 23 ? -0.449  2.064  -14.839 1.00 45.01  116 A 1 
-ATOM 180 C CD2 . LEU B 1 23 ? -0.582  0.210  -13.156 1.00 45.90  116 A 1 
-ATOM 181 N N   . THR B 1 24 ? -5.402  2.445  -12.674 1.00 49.17  117 A 1 
-ATOM 182 C CA  . THR B 1 24 ? -6.382  3.155  -11.886 1.00 49.60  117 A 1 
-ATOM 183 C C   . THR B 1 24 ? -7.250  2.198  -11.085 1.00 51.60  117 A 1 
-ATOM 184 O O   . THR B 1 24 ? -7.503  2.441  -9.918  1.00 50.82  117 A 1 
-ATOM 185 C CB  . THR B 1 24 ? -7.248  4.024  -12.811 1.00 54.67  117 A 1 
-ATOM 186 O OG1 . THR B 1 24 ? -6.463  5.126  -13.253 1.00 58.01  117 A 1 
-ATOM 187 C CG2 . THR B 1 24 ? -8.464  4.559  -12.141 1.00 57.77  117 A 1 
-ATOM 188 N N   . THR B 1 25 ? -7.718  1.116  -11.704 1.00 53.09  118 A 1 
-ATOM 189 C CA  . THR B 1 25 ? -8.495  0.117  -10.981 1.00 50.55  118 A 1 
-ATOM 190 C C   . THR B 1 25 ? -7.709  -0.503 -9.820  1.00 49.50  118 A 1 
-ATOM 191 O O   . THR B 1 25 ? -8.267  -0.695 -8.720  1.00 50.25  118 A 1 
-ATOM 192 C CB  . THR B 1 25 ? -8.933  -0.983 -11.947 1.00 53.52  118 A 1 
-ATOM 193 O OG1 . THR B 1 25 ? -9.796  -0.396 -12.916 1.00 60.17  118 A 1 
-ATOM 194 C CG2 . THR B 1 25 ? -9.619  -2.127 -11.260 1.00 58.18  118 A 1 
-ATOM 195 N N   . ARG B 1 26 ? -6.447  -0.762 -10.054 1.00 48.62  119 A 1 
-ATOM 196 C CA  . ARG B 1 26 ? -5.575  -1.319 -9.076  1.00 52.29  119 A 1 
-ATOM 197 C C   . ARG B 1 26 ? -5.362  -0.349 -7.936  1.00 56.15  119 A 1 
-ATOM 198 O O   . ARG B 1 26 ? -5.203  -0.758 -6.818  1.00 60.08  119 A 1 
-ATOM 199 C CB  . ARG B 1 26 ? -4.262  -1.609 -9.738  1.00 57.25  119 A 1 
-ATOM 200 C CG  . ARG B 1 26 ? -4.341  -2.608 -10.845 1.00 67.09  119 A 1 
-ATOM 201 C CD  . ARG B 1 26 ? -4.671  -3.974 -10.307 1.00 78.77  119 A 1 
-ATOM 202 N NE  . ARG B 1 26 ? -4.743  -4.923 -11.390 1.00 95.96  119 A 1 
-ATOM 203 C CZ  . ARG B 1 26 ? -3.703  -5.558 -11.900 1.00 111.57 119 A 1 
-ATOM 204 N NH1 . ARG B 1 26 ? -3.881  -6.412 -12.892 1.00 120.54 119 A 1 
-ATOM 205 N NH2 . ARG B 1 26 ? -2.494  -5.350 -11.417 1.00 114.95 119 A 1 
-ATOM 206 N N   . GLY B 1 27 ? -5.312  0.940  -8.241  1.00 57.29  120 A 1 
-ATOM 207 C CA  . GLY B 1 27 ? -5.176  2.005  -7.265  1.00 55.03  120 A 1 
-ATOM 208 C C   . GLY B 1 27 ? -6.391  2.105  -6.381  1.00 51.16  120 A 1 
-ATOM 209 O O   . GLY B 1 27 ? -6.273  2.252  -5.174  1.00 48.31  120 A 1 
-ATOM 210 N N   . ILE B 1 28 ? -7.570  1.983  -6.973  1.00 48.29  121 A 1 
-ATOM 211 C CA  . ILE B 1 28 ? -8.807  2.040  -6.198  1.00 51.59  121 A 1 
-ATOM 212 C C   . ILE B 1 28 ? -8.893  0.889  -5.227  1.00 54.18  121 A 1 
-ATOM 213 O O   . ILE B 1 28 ? -9.376  1.068  -4.118  1.00 53.53  121 A 1 
-ATOM 214 C CB  . ILE B 1 28 ? -10.053 2.141  -7.095  1.00 55.27  121 A 1 
-ATOM 215 C CG1 . ILE B 1 28 ? -10.187 3.601  -7.621  1.00 55.95  121 A 1 
-ATOM 216 C CG2 . ILE B 1 28 ? -11.306 1.807  -6.320  1.00 61.76  121 A 1 
-ATOM 217 C CD1 . ILE B 1 28 ? -11.126 3.822  -8.793  1.00 55.74  121 A 1 
-ATOM 218 N N   . GLU B 1 29 ? -8.420  -0.273 -5.627  1.00 61.84  122 A 1 
-ATOM 219 C CA  . GLU B 1 29 ? -8.319  -1.378 -4.700  1.00 67.68  122 A 1 
-ATOM 220 C C   . GLU B 1 29 ? -7.415  -1.069 -3.537  1.00 65.03  122 A 1 
-ATOM 221 O O   . GLU B 1 29 ? -7.791  -1.331 -2.393  1.00 64.70  122 A 1 
-ATOM 222 C CB  . GLU B 1 29 ? -7.868  -2.634 -5.431  1.00 78.78  122 A 1 
-ATOM 223 C CG  . GLU B 1 29 ? -9.069  -3.428 -5.962  1.00 86.76  122 A 1 
-ATOM 224 C CD  . GLU B 1 29 ? -8.878  -4.019 -7.353  1.00 87.49  122 A 1 
-ATOM 225 O OE1 . GLU B 1 29 ? -7.768  -4.558 -7.636  1.00 84.73  122 A 1 
-ATOM 226 O OE2 . GLU B 1 29 ? -9.870  -3.959 -8.121  1.00 77.87  122 A 1 
-ATOM 227 N N   . GLN B 1 30 ? -6.256  -0.484 -3.829  1.00 59.57  123 A 1 
-ATOM 228 C CA  . GLN B 1 30 ? -5.315  -0.084 -2.773  1.00 55.23  123 A 1 
-ATOM 229 C C   . GLN B 1 30 ? -5.910  0.955  -1.841  1.00 51.86  123 A 1 
-ATOM 230 O O   . GLN B 1 30 ? -5.662  0.942  -0.653  1.00 44.12  123 A 1 
-ATOM 231 C CB  . GLN B 1 30 ? -4.037  0.514  -3.362  1.00 55.92  123 A 1 
-ATOM 232 C CG  . GLN B 1 30 ? -3.221  -0.371 -4.262  1.00 61.37  123 A 1 
-ATOM 233 C CD  . GLN B 1 30 ? -2.863  -1.664 -3.614  1.00 62.35  123 A 1 
-ATOM 234 O OE1 . GLN B 1 30 ? -2.326  -1.663 -2.512  1.00 63.09  123 A 1 
-ATOM 235 N NE2 . GLN B 1 30 ? -3.188  -2.787 -4.276  1.00 70.63  123 A 1 
-ATOM 236 N N   . VAL B 1 31 ? -6.703  1.858  -2.386  1.00 57.05  124 A 1 
-ATOM 237 C CA  . VAL B 1 31 ? -7.323  2.883  -1.569  1.00 56.37  124 A 1 
-ATOM 238 C C   . VAL B 1 31 ? -8.333  2.246  -0.629  1.00 61.68  124 A 1 
-ATOM 239 O O   . VAL B 1 31 ? -8.461  2.699  0.470   1.00 58.51  124 A 1 
-ATOM 240 C CB  . VAL B 1 31 ? -7.969  3.950  -2.456  1.00 57.06  124 A 1 
-ATOM 241 C CG1 . VAL B 1 31 ? -9.007  4.756  -1.702  1.00 58.79  124 A 1 
-ATOM 242 C CG2 . VAL B 1 31 ? -6.871  4.864  -2.974  1.00 58.78  124 A 1 
-ATOM 243 N N   . GLU B 1 32 ? -9.044  1.205  -1.068  1.00 67.95  125 A 1 
-ATOM 244 C CA  . GLU B 1 32 ? -9.940  0.481  -0.175  1.00 64.07  125 A 1 
-ATOM 245 C C   . GLU B 1 32 ? -9.140  -0.246 0.887   1.00 61.43  125 A 1 
-ATOM 246 O O   . GLU B 1 32 ? -9.521  -0.248 2.049   1.00 58.85  125 A 1 
-ATOM 247 C CB  . GLU B 1 32 ? -10.821 -0.511 -0.911  1.00 70.57  125 A 1 
-ATOM 248 C CG  . GLU B 1 32 ? -11.844 0.047  -1.875  1.00 81.60  125 A 1 
-ATOM 249 C CD  . GLU B 1 32 ? -12.772 1.105  -1.306  1.00 92.01  125 A 1 
-ATOM 250 O OE1 . GLU B 1 32 ? -13.833 0.773  -0.713  1.00 101.96 125 A 1 
-ATOM 251 O OE2 . GLU B 1 32 ? -12.392 2.286  -1.482  1.00 95.64  125 A 1 
-ATOM 252 N N   . LEU B 1 33 ? -8.042  -0.849 0.489   1.00 55.72  126 A 1 
-ATOM 253 C CA  . LEU B 1 33 ? -7.201  -1.483 1.447   1.00 58.91  126 A 1 
-ATOM 254 C C   . LEU B 1 33 ? -6.628  -0.487 2.476   1.00 56.58  126 A 1 
-ATOM 255 O O   . LEU B 1 33 ? -6.271  -0.829 3.592   1.00 59.20  126 A 1 
-ATOM 256 C CB  . LEU B 1 33 ? -6.089  -2.149 0.676   1.00 63.68  126 A 1 
-ATOM 257 C CG  . LEU B 1 33 ? -5.181  -3.155 1.283   1.00 71.88  126 A 1 
-ATOM 258 C CD1 . LEU B 1 33 ? -4.453  -3.972 0.195   1.00 73.91  126 A 1 
-ATOM 259 C CD2 . LEU B 1 33 ? -4.179  -2.480 2.169   1.00 75.78  126 A 1 
-ATOM 260 N N   . LEU B 1 34 ? -6.482  0.743  2.064   1.00 51.59  127 A 1 
-ATOM 261 C CA  . LEU B 1 34 ? -6.054  1.821  2.952   1.00 47.43  127 A 1 
-ATOM 262 C C   . LEU B 1 34 ? -7.162  2.293  3.867   1.00 49.18  127 A 1 
-ATOM 263 O O   . LEU B 1 34 ? -6.917  2.748  4.956   1.00 48.29  127 A 1 
-ATOM 264 C CB  . LEU B 1 34 ? -5.537  2.996  2.165   1.00 43.17  127 A 1 
-ATOM 265 C CG  . LEU B 1 34 ? -4.031  2.968  1.890   1.00 42.73  127 A 1 
-ATOM 266 C CD1 . LEU B 1 34 ? -3.630  4.313  1.305   1.00 42.46  127 A 1 
-ATOM 267 C CD2 . LEU B 1 34 ? -3.088  2.610  3.005   1.00 43.31  127 A 1 
-ATOM 268 N N   . LYS B 1 35 ? -8.399  2.214  3.408   1.00 52.51  128 A 1 
-ATOM 269 C CA  . LYS B 1 35 ? -9.553  2.535  4.233   1.00 52.46  128 A 1 
-ATOM 270 C C   . LYS B 1 35 ? -9.710  1.492  5.330   1.00 53.78  128 A 1 
-ATOM 271 O O   . LYS B 1 35 ? -10.040 1.823  6.442   1.00 47.30  128 A 1 
-ATOM 272 C CB  . LYS B 1 35 ? -10.830 2.641  3.381   1.00 54.62  128 A 1 
-ATOM 273 C CG  . LYS B 1 35 ? -12.138 2.251  4.078   1.00 59.22  128 A 1 
-ATOM 274 N N   . ARG B 1 36 ? -9.454  0.236  4.997   1.00 56.56  129 A 1 
-ATOM 275 C CA  . ARG B 1 36 ? -9.471  -0.853 5.953   1.00 60.75  129 A 1 
-ATOM 276 C C   . ARG B 1 36 ? -8.392  -0.650 7.014   1.00 59.48  129 A 1 
-ATOM 277 O O   . ARG B 1 36 ? -8.620  -0.927 8.185   1.00 63.52  129 A 1 
-ATOM 278 C CB  . ARG B 1 36 ? -9.292  -2.210 5.247   1.00 65.76  129 A 1 
-ATOM 279 C CG  . ARG B 1 36 ? -10.535 -2.769 4.547   1.00 68.71  129 A 1 
-ATOM 280 C CD  . ARG B 1 36 ? -10.167 -3.835 3.488   1.00 67.67  129 A 1 
-ATOM 281 N N   . ILE B 1 37 ? -7.221  -0.161 6.611   1.00 54.56  130 A 1 
-ATOM 282 C CA  . ILE B 1 37 ? -6.140  0.129  7.539   1.00 49.62  130 A 1 
-ATOM 283 C C   . ILE B 1 37 ? -6.541  1.250  8.466   1.00 49.00  130 A 1 
-ATOM 284 O O   . ILE B 1 37 ? -6.319  1.155  9.647   1.00 47.20  130 A 1 
-ATOM 285 C CB  . ILE B 1 37 ? -4.839  0.472  6.806   1.00 51.01  130 A 1 
-ATOM 286 C CG1 . ILE B 1 37 ? -4.243  -0.830 6.231   1.00 57.41  130 A 1 
-ATOM 287 C CG2 . ILE B 1 37 ? -3.851  1.181  7.755   1.00 49.06  130 A 1 
-ATOM 288 C CD1 . ILE B 1 37 ? -2.922  -0.695 5.533   1.00 59.59  130 A 1 
-ATOM 289 N N   . HIS B 1 38 ? -7.179  2.276  7.957   1.00 50.21  131 A 1 
-ATOM 290 C CA  . HIS B 1 38 ? -7.618  3.356  8.797   1.00 53.53  131 A 1 
-ATOM 291 C C   . HIS B 1 38 ? -8.670  2.891  9.780   1.00 62.35  131 A 1 
-ATOM 292 O O   . HIS B 1 38 ? -8.744  3.378  10.880  1.00 61.76  131 A 1 
-ATOM 293 C CB  . HIS B 1 38 ? -8.175  4.452  7.947   1.00 51.42  131 A 1 
-ATOM 294 C CG  . HIS B 1 38 ? -9.034  5.412  8.688   1.00 54.14  131 A 1 
-ATOM 295 N ND1 . HIS B 1 38 ? -10.380 5.221  8.850   1.00 59.92  131 A 1 
-ATOM 296 C CD2 . HIS B 1 38 ? -8.749  6.586  9.283   1.00 55.36  131 A 1 
-ATOM 297 C CE1 . HIS B 1 38 ? -10.887 6.229  9.522   1.00 62.46  131 A 1 
-ATOM 298 N NE2 . HIS B 1 38 ? -9.918  7.073  9.795   1.00 61.48  131 A 1 
-ATOM 299 N N   . ASP B 1 39 ? -9.476  1.928  9.394   1.00 63.84  132 A 1 
-ATOM 300 C CA  . ASP B 1 39 ? -10.480 1.421  10.286  1.00 65.95  132 A 1 
-ATOM 301 C C   . ASP B 1 39 ? -9.837  0.648  11.420  1.00 61.61  132 A 1 
-ATOM 302 O O   . ASP B 1 39 ? -10.164 0.840  12.551  1.00 56.16  132 A 1 
-ATOM 303 C CB  . ASP B 1 39 ? -11.456 0.577  9.509   1.00 73.60  132 A 1 
-ATOM 304 C CG  . ASP B 1 39 ? -12.373 1.404  8.658   1.00 76.60  132 A 1 
-ATOM 305 O OD1 . ASP B 1 39 ? -12.277 2.631  8.703   1.00 70.60  132 A 1 
-ATOM 306 O OD2 . ASP B 1 39 ? -13.195 0.833  7.937   1.00 81.44  132 A 1 
-ATOM 307 N N   . LYS B 1 40 ? -8.926  -0.245 11.106  1.00 59.87  133 A 1 
-ATOM 308 C CA  . LYS B 1 40 ? -8.191  -0.985 12.129  1.00 59.13  133 A 1 
-ATOM 309 C C   . LYS B 1 40 ? -7.573  -0.021 13.157  1.00 58.88  133 A 1 
-ATOM 310 O O   . LYS B 1 40 ? -7.579  -0.267 14.361  1.00 63.83  133 A 1 
-ATOM 311 C CB  . LYS B 1 40 ? -7.093  -1.864 11.503  1.00 58.69  133 A 1 
-ATOM 312 C CG  . LYS B 1 40 ? -7.577  -3.018 10.646  1.00 62.42  133 A 1 
-ATOM 313 C CD  . LYS B 1 40 ? -6.463  -3.844 9.987   1.00 62.93  133 A 1 
-ATOM 314 N N   . LEU B 1 41 ? -7.038  1.086  12.674  1.00 60.19  134 A 1 
-ATOM 315 C CA  . LEU B 1 41 ? -6.454  2.092  13.561  1.00 62.93  134 A 1 
-ATOM 316 C C   . LEU B 1 41 ? -7.487  2.707  14.452  1.00 63.64  134 A 1 
-ATOM 317 O O   . LEU B 1 41 ? -7.205  2.982  15.605  1.00 73.06  134 A 1 
-ATOM 318 C CB  . LEU B 1 41 ? -5.765  3.197  12.764  1.00 64.98  134 A 1 
-ATOM 319 C CG  . LEU B 1 41 ? -4.531  2.611  12.036  1.00 68.88  134 A 1 
-ATOM 320 C CD1 . LEU B 1 41 ? -4.332  3.201  10.638  1.00 78.49  134 A 1 
-ATOM 321 C CD2 . LEU B 1 41 ? -3.301  2.685  12.900  1.00 67.40  134 A 1 
-ATOM 322 N N   . MET B 1 42 ? -8.669  2.955  13.913  1.00 63.76  135 A 1 
-ATOM 323 C CA  . MET B 1 42 ? -9.752  3.512  14.704  1.00 67.57  135 A 1 
-ATOM 324 C C   . MET B 1 42 ? -10.186 2.561  15.817  1.00 72.44  135 A 1 
-ATOM 325 O O   . MET B 1 42 ? -10.413 2.985  16.975  1.00 66.48  135 A 1 
-ATOM 326 C CB  . MET B 1 42 ? -10.932 3.853  13.816  1.00 69.82  135 A 1 
-ATOM 327 C CG  . MET B 1 42 ? -10.710 5.112  13.020  1.00 74.54  135 A 1 
-ATOM 328 S SD  . MET B 1 42 ? -10.062 6.547  13.958  1.00 82.27  135 A 1 
-ATOM 329 C CE  . MET B 1 42 ? -11.073 6.663  15.446  1.00 83.33  135 A 1 
-ATOM 330 N N   . ILE B 1 43 ? -10.271 1.274  15.477  1.00 81.93  136 A 1 
-ATOM 331 C CA  . ILE B 1 43 ? -10.594 0.243  16.446  1.00 79.15  136 A 1 
-ATOM 332 C C   . ILE B 1 43 ? -9.526  0.183  17.546  1.00 79.65  136 A 1 
-ATOM 333 O O   . ILE B 1 43 ? -9.854  0.128  18.719  1.00 82.01  136 A 1 
-ATOM 334 C CB  . ILE B 1 43 ? -10.781 -1.129 15.738  1.00 80.39  136 A 1 
-ATOM 335 C CG1 . ILE B 1 43 ? -12.176 -1.237 15.090  1.00 78.84  136 A 1 
-ATOM 336 C CG2 . ILE B 1 43 ? -10.586 -2.294 16.708  1.00 84.53  136 A 1 
-ATOM 337 C CD1 . ILE B 1 43 ? -12.480 -0.642 13.720  1.00 74.74  136 A 1 
-ATOM 338 N N   . ARG B 1 44 ? -8.250  0.200  17.158  1.00 85.15  137 A 1 
-ATOM 339 C CA  . ARG B 1 44 ? -7.131  0.216  18.111  1.00 90.78  137 A 1 
-ATOM 340 C C   . ARG B 1 44 ? -7.103  1.498  18.957  1.00 91.00  137 A 1 
-ATOM 341 O O   . ARG B 1 44 ? -6.632  1.453  20.068  1.00 96.79  137 A 1 
-ATOM 342 C CB  . ARG B 1 44 ? -5.803  0.033  17.373  1.00 95.82  137 A 1 
-ATOM 343 C CG  . ARG B 1 44 ? -4.883  -1.005 17.902  1.00 101.09 137 A 1 
-ATOM 344 C CD  . ARG B 1 44 ? -3.772  -1.099 16.880  1.00 107.64 137 A 1 
-ATOM 345 N NE  . ARG B 1 44 ? -2.978  -2.299 17.060  1.00 124.71 137 A 1 
-ATOM 346 C CZ  . ARG B 1 44 ? -2.237  -2.882 16.112  1.00 137.30 137 A 1 
-ATOM 347 N NH1 . ARG B 1 44 ? -2.186  -2.387 14.871  1.00 128.35 137 A 1 
-ATOM 348 N NH2 . ARG B 1 44 ? -1.533  -3.990 16.400  1.00 147.87 137 A 1 
-ATOM 349 N N   . ALA B 1 45 ? -7.688  2.601  18.506  1.00 92.41  138 A 1 
-ATOM 350 C CA  . ALA B 1 45 ? -7.783  3.810  19.381  1.00 96.29  138 A 1 
-ATOM 351 C C   . ALA B 1 45 ? -8.773  4.837  18.851  1.00 95.46  138 A 1 
-ATOM 352 O O   . ALA B 1 45 ? -8.386  5.847  18.235  1.00 81.53  138 A 1 
-ATOM 353 C CB  . ALA B 1 45 ? -6.408  4.475  19.603  1.00 97.91  138 A 1 
-#
diff --git a/src/alphafold3/test_data/miniature_databases/pdb_mmcif/6s61.cif b/src/alphafold3/test_data/miniature_databases/pdb_mmcif/6s61.cif
deleted file mode 100644
index b762402006f21a7318791798e392ed19a89e10b5..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/pdb_mmcif/6s61.cif
+++ /dev/null
@@ -1,3293 +0,0 @@
-data_6S61
-#
-_entry.id 6S61
-#
-loop_
-_chem_comp.formula
-_chem_comp.formula_weight
-_chem_comp.id
-_chem_comp.mon_nstd_flag
-_chem_comp.name
-_chem_comp.pdbx_synonyms
-_chem_comp.type
-"C3 H7 N O2"     89.093  ALA y ALANINE         ? "L-peptide linking" 
-"C6 H15 N4 O2 1" 175.209 ARG y ARGININE        ? "L-peptide linking" 
-"C4 H8 N2 O3"    132.118 ASN y ASPARAGINE      ? "L-peptide linking" 
-"C4 H7 N O4"     133.103 ASP y "ASPARTIC ACID" ? "L-peptide linking" 
-"C3 H7 N O2 S"   121.158 CYS y CYSTEINE        ? "L-peptide linking" 
-"Fe 3"           55.845  FE  . "FE (III) ION"  ? non-polymer         
-"C5 H10 N2 O3"   146.144 GLN y GLUTAMINE       ? "L-peptide linking" 
-"C5 H9 N O4"     147.129 GLU y "GLUTAMIC ACID" ? "L-peptide linking" 
-"C2 H5 N O2"     75.067  GLY y GLYCINE         ? "peptide linking"   
-"C6 H10 N3 O2 1" 156.162 HIS y HISTIDINE       ? "L-peptide linking" 
-"H2 O"           18.015  HOH . WATER           ? non-polymer         
-"C6 H13 N O2"    131.173 ILE y ISOLEUCINE      ? "L-peptide linking" 
-"C6 H13 N O2"    131.173 LEU y LEUCINE         ? "L-peptide linking" 
-"C6 H15 N2 O2 1" 147.195 LYS y LYSINE          ? "L-peptide linking" 
-"C5 H11 N O2 S"  149.211 MET y METHIONINE      ? "L-peptide linking" 
-"C9 H11 N O2"    165.189 PHE y PHENYLALANINE   ? "L-peptide linking" 
-"C5 H9 N O2"     115.130 PRO y PROLINE         ? "L-peptide linking" 
-"C3 H7 N O3"     105.093 SER y SERINE          ? "L-peptide linking" 
-"C4 H9 N O3"     119.119 THR y THREONINE       ? "L-peptide linking" 
-"C11 H12 N2 O2"  204.225 TRP y TRYPTOPHAN      ? "L-peptide linking" 
-"C9 H11 N O3"    181.189 TYR y TYROSINE        ? "L-peptide linking" 
-"C5 H11 N O2"    117.146 VAL y VALINE          ? "L-peptide linking" 
-"Zn 2"           65.409  ZN  . "ZINC ION"      ? non-polymer         
-#
-loop_
-_entity.id
-_entity.pdbx_description
-_entity.type
-1 "Ferritin heavy chain" polymer     
-3 "ZINC ION"             non-polymer 
-#
-_entity_poly.entity_id      1
-_entity_poly.pdbx_strand_id M
-_entity_poly.type           polypeptide(L)
-#
-loop_
-_entity_poly_seq.entity_id
-_entity_poly_seq.hetero
-_entity_poly_seq.mon_id
-_entity_poly_seq.num
-1 n MET 1   
-1 n THR 2   
-1 n THR 3   
-1 n ALA 4   
-1 n SER 5   
-1 n PRO 6   
-1 n SER 7   
-1 n GLN 8   
-1 n VAL 9   
-1 n ARG 10  
-1 n GLN 11  
-1 n ASN 12  
-1 n TYR 13  
-1 n HIS 14  
-1 n GLN 15  
-1 n ASP 16  
-1 n ALA 17  
-1 n GLU 18  
-1 n ALA 19  
-1 n ALA 20  
-1 n ILE 21  
-1 n ASN 22  
-1 n ARG 23  
-1 n GLN 24  
-1 n ILE 25  
-1 n ASN 26  
-1 n LEU 27  
-1 n GLU 28  
-1 n LEU 29  
-1 n TYR 30  
-1 n ALA 31  
-1 n SER 32  
-1 n TYR 33  
-1 n VAL 34  
-1 n TYR 35  
-1 n LEU 36  
-1 n SER 37  
-1 n MET 38  
-1 n SER 39  
-1 n CYS 40  
-1 n TYR 41  
-1 n PHE 42  
-1 n ASP 43  
-1 n ARG 44  
-1 n ASP 45  
-1 n ASP 46  
-1 n VAL 47  
-1 n ALA 48  
-1 n LEU 49  
-1 n LYS 50  
-1 n ASN 51  
-1 n PHE 52  
-1 n ALA 53  
-1 n LYS 54  
-1 n TYR 55  
-1 n PHE 56  
-1 n LEU 57  
-1 n HIS 58  
-1 n GLN 59  
-1 n SER 60  
-1 n HIS 61  
-1 n GLU 62  
-1 n GLU 63  
-1 n ARG 64  
-1 n GLU 65  
-1 n HIS 66  
-1 n ALA 67  
-1 n GLU 68  
-1 n LYS 69  
-1 n LEU 70  
-1 n MET 71  
-1 n LYS 72  
-1 n LEU 73  
-1 n GLN 74  
-1 n ASN 75  
-1 n GLN 76  
-1 n ARG 77  
-1 n GLY 78  
-1 n GLY 79  
-1 n ARG 80  
-1 n ILE 81  
-1 n PHE 82  
-1 n LEU 83  
-1 n GLN 84  
-1 n ASP 85  
-1 n ILE 86  
-1 n LYS 87  
-1 n LYS 88  
-1 n PRO 89  
-1 n ASP 90  
-1 n ARG 91  
-1 n ASP 92  
-1 n ASP 93  
-1 n TRP 94  
-1 n GLU 95  
-1 n SER 96  
-1 n GLY 97  
-1 n LEU 98  
-1 n ASN 99  
-1 n ALA 100 
-1 n MET 101 
-1 n GLU 102 
-1 n CYS 103 
-1 n ALA 104 
-1 n LEU 105 
-1 n HIS 106 
-1 n LEU 107 
-1 n GLU 108 
-1 n LYS 109 
-1 n SER 110 
-1 n VAL 111 
-1 n ASN 112 
-1 n GLN 113 
-1 n SER 114 
-1 n LEU 115 
-1 n LEU 116 
-1 n GLU 117 
-1 n LEU 118 
-1 n HIS 119 
-1 n LYS 120 
-1 n LEU 121 
-1 n ALA 122 
-1 n THR 123 
-1 n ASP 124 
-1 n LYS 125 
-1 n ASN 126 
-1 n ASP 127 
-1 n PRO 128 
-1 n HIS 129 
-1 n LEU 130 
-1 n CYS 131 
-1 n ASP 132 
-1 n PHE 133 
-1 n ILE 134 
-1 n GLU 135 
-1 n THR 136 
-1 n TYR 137 
-1 n TYR 138 
-1 n LEU 139 
-1 n SER 140 
-1 n GLU 141 
-1 n GLN 142 
-1 n VAL 143 
-1 n LYS 144 
-1 n SER 145 
-1 n ILE 146 
-1 n LYS 147 
-1 n GLU 148 
-1 n LEU 149 
-1 n GLY 150 
-1 n ASP 151 
-1 n HIS 152 
-1 n VAL 153 
-1 n THR 154 
-1 n ASN 155 
-1 n LEU 156 
-1 n ARG 157 
-1 n LYS 158 
-1 n MET 159 
-1 n GLY 160 
-1 n ALA 161 
-1 n PRO 162 
-1 n GLU 163 
-1 n ALA 164 
-1 n GLY 165 
-1 n MET 166 
-1 n ALA 167 
-1 n GLU 168 
-1 n TYR 169 
-1 n LEU 170 
-1 n PHE 171 
-1 n ASP 172 
-1 n LYS 173 
-1 n HIS 174 
-1 n THR 175 
-1 n LEU 176 
-1 n GLY 177 
-1 n HIS 178 
-1 n GLY 179 
-1 n ASP 180 
-1 n GLU 181 
-1 n SER 182 
-#
-_exptl.method "ELECTRON MICROSCOPY"
-#
-_pdbx_audit_revision_history.revision_date 2019-07-10
-#
-_pdbx_database_status.recvd_initial_deposition_date 2019-07-10
-#
-_pdbx_nonpoly_scheme.asym_id       PA
-_pdbx_nonpoly_scheme.auth_seq_num  201
-_pdbx_nonpoly_scheme.entity_id     3
-_pdbx_nonpoly_scheme.mon_id        ZN
-_pdbx_nonpoly_scheme.pdb_ins_code  .
-_pdbx_nonpoly_scheme.pdb_seq_num   201
-_pdbx_nonpoly_scheme.pdb_strand_id M
-#
-loop_
-_pdbx_poly_seq_scheme.asym_id
-_pdbx_poly_seq_scheme.auth_seq_num
-_pdbx_poly_seq_scheme.entity_id
-_pdbx_poly_seq_scheme.hetero
-_pdbx_poly_seq_scheme.mon_id
-_pdbx_poly_seq_scheme.pdb_ins_code
-_pdbx_poly_seq_scheme.pdb_seq_num
-_pdbx_poly_seq_scheme.pdb_strand_id
-_pdbx_poly_seq_scheme.seq_id
-M ?   1 n MET . 0   M 1   
-M ?   1 n THR . 1   M 2   
-M ?   1 n THR . 2   M 3   
-M ?   1 n ALA . 3   M 4   
-M ?   1 n SER . 4   M 5   
-M 5   1 n PRO . 5   M 6   
-M 6   1 n SER . 6   M 7   
-M 7   1 n GLN . 7   M 8   
-M 8   1 n VAL . 8   M 9   
-M 9   1 n ARG . 9   M 10  
-M 10  1 n GLN . 10  M 11  
-M 11  1 n ASN . 11  M 12  
-M 12  1 n TYR . 12  M 13  
-M 13  1 n HIS . 13  M 14  
-M 14  1 n GLN . 14  M 15  
-M 15  1 n ASP . 15  M 16  
-M 16  1 n ALA . 16  M 17  
-M 17  1 n GLU . 17  M 18  
-M 18  1 n ALA . 18  M 19  
-M 19  1 n ALA . 19  M 20  
-M 20  1 n ILE . 20  M 21  
-M 21  1 n ASN . 21  M 22  
-M 22  1 n ARG . 22  M 23  
-M 23  1 n GLN . 23  M 24  
-M 24  1 n ILE . 24  M 25  
-M 25  1 n ASN . 25  M 26  
-M 26  1 n LEU . 26  M 27  
-M 27  1 n GLU . 27  M 28  
-M 28  1 n LEU . 28  M 29  
-M 29  1 n TYR . 29  M 30  
-M 30  1 n ALA . 30  M 31  
-M 31  1 n SER . 31  M 32  
-M 32  1 n TYR . 32  M 33  
-M 33  1 n VAL . 33  M 34  
-M 34  1 n TYR . 34  M 35  
-M 35  1 n LEU . 35  M 36  
-M 36  1 n SER . 36  M 37  
-M 37  1 n MET . 37  M 38  
-M 38  1 n SER . 38  M 39  
-M 39  1 n CYS . 39  M 40  
-M 40  1 n TYR . 40  M 41  
-M 41  1 n PHE . 41  M 42  
-M 42  1 n ASP . 42  M 43  
-M 43  1 n ARG . 43  M 44  
-M 44  1 n ASP . 44  M 45  
-M 45  1 n ASP . 45  M 46  
-M 46  1 n VAL . 46  M 47  
-M 47  1 n ALA . 47  M 48  
-M 48  1 n LEU . 48  M 49  
-M 49  1 n LYS . 49  M 50  
-M 50  1 n ASN . 50  M 51  
-M 51  1 n PHE . 51  M 52  
-M 52  1 n ALA . 52  M 53  
-M 53  1 n LYS . 53  M 54  
-M 54  1 n TYR . 54  M 55  
-M 55  1 n PHE . 55  M 56  
-M 56  1 n LEU . 56  M 57  
-M 57  1 n HIS . 57  M 58  
-M 58  1 n GLN . 58  M 59  
-M 59  1 n SER . 59  M 60  
-M 60  1 n HIS . 60  M 61  
-M 61  1 n GLU . 61  M 62  
-M 62  1 n GLU . 62  M 63  
-M 63  1 n ARG . 63  M 64  
-M 64  1 n GLU . 64  M 65  
-M 65  1 n HIS . 65  M 66  
-M 66  1 n ALA . 66  M 67  
-M 67  1 n GLU . 67  M 68  
-M 68  1 n LYS . 68  M 69  
-M 69  1 n LEU . 69  M 70  
-M 70  1 n MET . 70  M 71  
-M 71  1 n LYS . 71  M 72  
-M 72  1 n LEU . 72  M 73  
-M 73  1 n GLN . 73  M 74  
-M 74  1 n ASN . 74  M 75  
-M 75  1 n GLN . 75  M 76  
-M 76  1 n ARG . 76  M 77  
-M 77  1 n GLY . 77  M 78  
-M 78  1 n GLY . 78  M 79  
-M 79  1 n ARG . 79  M 80  
-M 80  1 n ILE . 80  M 81  
-M 81  1 n PHE . 81  M 82  
-M 82  1 n LEU . 82  M 83  
-M 83  1 n GLN . 83  M 84  
-M 84  1 n ASP . 84  M 85  
-M 85  1 n ILE . 85  M 86  
-M 86  1 n LYS . 86  M 87  
-M 87  1 n LYS . 87  M 88  
-M 88  1 n PRO . 88  M 89  
-M 89  1 n ASP . 89  M 90  
-M 90  1 n ARG . 90  M 91  
-M 91  1 n ASP . 91  M 92  
-M 92  1 n ASP . 92  M 93  
-M 93  1 n TRP . 93  M 94  
-M 94  1 n GLU . 94  M 95  
-M 95  1 n SER . 95  M 96  
-M 96  1 n GLY . 96  M 97  
-M 97  1 n LEU . 97  M 98  
-M 98  1 n ASN . 98  M 99  
-M 99  1 n ALA . 99  M 100 
-M 100 1 n MET . 100 M 101 
-M 101 1 n GLU . 101 M 102 
-M 102 1 n CYS . 102 M 103 
-M 103 1 n ALA . 103 M 104 
-M 104 1 n LEU . 104 M 105 
-M 105 1 n HIS . 105 M 106 
-M 106 1 n LEU . 106 M 107 
-M 107 1 n GLU . 107 M 108 
-M 108 1 n LYS . 108 M 109 
-M 109 1 n SER . 109 M 110 
-M 110 1 n VAL . 110 M 111 
-M 111 1 n ASN . 111 M 112 
-M 112 1 n GLN . 112 M 113 
-M 113 1 n SER . 113 M 114 
-M 114 1 n LEU . 114 M 115 
-M 115 1 n LEU . 115 M 116 
-M 116 1 n GLU . 116 M 117 
-M 117 1 n LEU . 117 M 118 
-M 118 1 n HIS . 118 M 119 
-M 119 1 n LYS . 119 M 120 
-M 120 1 n LEU . 120 M 121 
-M 121 1 n ALA . 121 M 122 
-M 122 1 n THR . 122 M 123 
-M 123 1 n ASP . 123 M 124 
-M 124 1 n LYS . 124 M 125 
-M 125 1 n ASN . 125 M 126 
-M 126 1 n ASP . 126 M 127 
-M 127 1 n PRO . 127 M 128 
-M 128 1 n HIS . 128 M 129 
-M 129 1 n LEU . 129 M 130 
-M 130 1 n CYS . 130 M 131 
-M 131 1 n ASP . 131 M 132 
-M 132 1 n PHE . 132 M 133 
-M 133 1 n ILE . 133 M 134 
-M 134 1 n GLU . 134 M 135 
-M 135 1 n THR . 135 M 136 
-M 136 1 n TYR . 136 M 137 
-M 137 1 n TYR . 137 M 138 
-M 138 1 n LEU . 138 M 139 
-M 139 1 n SER . 139 M 140 
-M 140 1 n GLU . 140 M 141 
-M 141 1 n GLN . 141 M 142 
-M 142 1 n VAL . 142 M 143 
-M 143 1 n LYS . 143 M 144 
-M 144 1 n SER . 144 M 145 
-M 145 1 n ILE . 145 M 146 
-M 146 1 n LYS . 146 M 147 
-M 147 1 n GLU . 147 M 148 
-M 148 1 n LEU . 148 M 149 
-M 149 1 n GLY . 149 M 150 
-M 150 1 n ASP . 150 M 151 
-M 151 1 n HIS . 151 M 152 
-M 152 1 n VAL . 152 M 153 
-M 153 1 n THR . 153 M 154 
-M 154 1 n ASN . 154 M 155 
-M 155 1 n LEU . 155 M 156 
-M 156 1 n ARG . 156 M 157 
-M 157 1 n LYS . 157 M 158 
-M 158 1 n MET . 158 M 159 
-M 159 1 n GLY . 159 M 160 
-M 160 1 n ALA . 160 M 161 
-M 161 1 n PRO . 161 M 162 
-M 162 1 n GLU . 162 M 163 
-M 163 1 n ALA . 163 M 164 
-M 164 1 n GLY . 164 M 165 
-M 165 1 n MET . 165 M 166 
-M 166 1 n ALA . 166 M 167 
-M 167 1 n GLU . 167 M 168 
-M 168 1 n TYR . 168 M 169 
-M 169 1 n LEU . 169 M 170 
-M 170 1 n PHE . 170 M 171 
-M 171 1 n ASP . 171 M 172 
-M 172 1 n LYS . 172 M 173 
-M 173 1 n HIS . 173 M 174 
-M 174 1 n THR . 174 M 175 
-M 175 1 n LEU . 175 M 176 
-M 176 1 n GLY . 176 M 177 
-M ?   1 n HIS . 177 M 178 
-M ?   1 n GLY . 178 M 179 
-M ?   1 n ASP . 179 M 180 
-M ?   1 n GLU . 180 M 181 
-M ?   1 n SER . 181 M 182 
-#
-_pdbx_struct_assembly.details            author_and_software_defined_assembly
-_pdbx_struct_assembly.id                 1
-_pdbx_struct_assembly.method_details     PISA
-_pdbx_struct_assembly.oligomeric_count   24
-_pdbx_struct_assembly.oligomeric_details 24-meric
-#
-_pdbx_struct_assembly_gen.assembly_id     1
-_pdbx_struct_assembly_gen.asym_id_list    A,B,C,D,E,F,G,H,I,J,K,L,M,N,O,P,Q,R,S,T,U,V,W,X,Y,Z,AA,BA,CA,DA,EA,FA,GA,HA,IA,JA,KA,LA,MA,NA,OA,PA,QA,RA,SA,TA,UA,VA,WA,XA,YA,ZA,AB,BB,CB,DB,EB,FB,GB,HB,IB,JB,KB,LB,MB,NB,OB,PB,QB,RB,SB,TB,UB,VB,WB,XB,YB,ZB
-_pdbx_struct_assembly_gen.oper_expression 1
-#
-_pdbx_struct_oper_list.id                 1
-_pdbx_struct_oper_list.matrix[1][1]       1.0000000000
-_pdbx_struct_oper_list.matrix[1][2]       0.0000000000
-_pdbx_struct_oper_list.matrix[1][3]       0.0000000000
-_pdbx_struct_oper_list.matrix[2][1]       0.0000000000
-_pdbx_struct_oper_list.matrix[2][2]       1.0000000000
-_pdbx_struct_oper_list.matrix[2][3]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][1]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][2]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][3]       1.0000000000
-_pdbx_struct_oper_list.name               1_555
-_pdbx_struct_oper_list.symmetry_operation ?
-_pdbx_struct_oper_list.type               "identity operation"
-_pdbx_struct_oper_list.vector[1]          0.0000000000
-_pdbx_struct_oper_list.vector[2]          0.0000000000
-_pdbx_struct_oper_list.vector[3]          0.0000000000
-#
-_refine.ls_d_res_high 1.84
-#
-_software.classification other
-_software.name           "DeepMind Structure Class"
-_software.pdbx_ordinal   1
-_software.version        2.0.0
-#
-loop_
-_struct_asym.entity_id
-_struct_asym.id
-1 M  
-3 PA 
-#
-loop_
-_struct_conn.conn_type_id
-_struct_conn.id
-_struct_conn.pdbx_ptnr1_PDB_ins_code
-_struct_conn.pdbx_ptnr1_label_alt_id
-_struct_conn.pdbx_ptnr2_PDB_ins_code
-_struct_conn.pdbx_ptnr2_label_alt_id
-_struct_conn.pdbx_role
-_struct_conn.pdbx_value_order
-_struct_conn.ptnr1_auth_asym_id
-_struct_conn.ptnr1_auth_seq_id
-_struct_conn.ptnr1_label_asym_id
-_struct_conn.ptnr1_label_atom_id
-_struct_conn.ptnr1_label_comp_id
-_struct_conn.ptnr1_label_seq_id
-_struct_conn.ptnr1_symmetry
-_struct_conn.ptnr2_auth_asym_id
-_struct_conn.ptnr2_auth_seq_id
-_struct_conn.ptnr2_label_asym_id
-_struct_conn.ptnr2_label_atom_id
-_struct_conn.ptnr2_label_comp_id
-_struct_conn.ptnr2_label_seq_id
-_struct_conn.ptnr2_symmetry
-metalc metalc1 ? ? ? ? ? ? M 27 M OE2 GLU 28 1_555 M 201 PA ZN ZN . 1_555 
-metalc metalc2 ? ? ? ? ? ? M 62 M OE1 GLU 63 1_555 M 201 PA ZN ZN . 1_555 
-metalc metalc3 ? ? ? ? ? ? M 65 M ND1 HIS 66 1_555 M 201 PA ZN ZN . 1_555 
-#
-_struct_conn_type.criteria  ?
-_struct_conn_type.id        metalc
-_struct_conn_type.reference ?
-#
-loop_
-_atom_site.group_PDB
-_atom_site.id
-_atom_site.type_symbol
-_atom_site.label_atom_id
-_atom_site.label_alt_id
-_atom_site.label_comp_id
-_atom_site.label_asym_id
-_atom_site.label_entity_id
-_atom_site.label_seq_id
-_atom_site.pdbx_PDB_ins_code
-_atom_site.Cartn_x
-_atom_site.Cartn_y
-_atom_site.Cartn_z
-_atom_site.occupancy
-_atom_site.B_iso_or_equiv
-_atom_site.auth_seq_id
-_atom_site.auth_asym_id
-_atom_site.pdbx_PDB_model_num
-ATOM   1    N  N    . PRO M  1 6   ? 122.212 117.597 42.494 1.00 9.28  5   M 1 
-ATOM   2    C  CA   . PRO M  1 6   ? 122.084 118.174 43.835 1.00 9.28  5   M 1 
-ATOM   3    C  C    . PRO M  1 6   ? 120.908 117.581 44.601 1.00 9.28  5   M 1 
-ATOM   4    O  O    . PRO M  1 6   ? 119.808 117.491 44.064 1.00 9.28  5   M 1 
-ATOM   5    C  CB   . PRO M  1 6   ? 121.864 119.662 43.555 1.00 9.28  5   M 1 
-ATOM   6    C  CG   . PRO M  1 6   ? 121.230 119.694 42.219 1.00 9.28  5   M 1 
-ATOM   7    C  CD   . PRO M  1 6   ? 121.846 118.564 41.447 1.00 9.28  5   M 1 
-ATOM   8    H  HA   . PRO M  1 6   ? 122.903 118.063 44.342 1.00 9.28  5   M 1 
-ATOM   9    H  HB2  . PRO M  1 6   ? 121.285 120.040 44.235 1.00 9.28  5   M 1 
-ATOM   10   H  HB3  . PRO M  1 6   ? 122.714 120.128 43.534 1.00 9.28  5   M 1 
-ATOM   11   H  HG2  . PRO M  1 6   ? 120.274 119.558 42.308 1.00 9.28  5   M 1 
-ATOM   12   H  HG3  . PRO M  1 6   ? 121.419 120.545 41.793 1.00 9.28  5   M 1 
-ATOM   13   H  HD2  . PRO M  1 6   ? 121.199 118.179 40.836 1.00 9.28  5   M 1 
-ATOM   14   H  HD3  . PRO M  1 6   ? 122.642 118.866 40.982 1.00 9.28  5   M 1 
-ATOM   15   N  N    . SER M  1 7   ? 121.145 117.181 45.845 1.00 7.08  6   M 1 
-ATOM   16   C  CA   . SER M  1 7   ? 120.080 116.612 46.653 1.00 7.08  6   M 1 
-ATOM   17   C  C    . SER M  1 7   ? 119.029 117.671 46.964 1.00 7.08  6   M 1 
-ATOM   18   O  O    . SER M  1 7   ? 119.342 118.844 47.176 1.00 7.08  6   M 1 
-ATOM   19   C  CB   . SER M  1 7   ? 120.641 116.033 47.949 1.00 7.08  6   M 1 
-ATOM   20   O  OG   . SER M  1 7   ? 119.605 115.511 48.745 1.00 7.08  6   M 1 
-ATOM   21   H  H    . SER M  1 7   ? 121.906 117.238 46.241 1.00 7.08  6   M 1 
-ATOM   22   H  HA   . SER M  1 7   ? 119.655 115.894 46.159 1.00 7.08  6   M 1 
-ATOM   23   H  HB2  . SER M  1 7   ? 121.264 115.319 47.741 1.00 7.08  6   M 1 
-ATOM   24   H  HB3  . SER M  1 7   ? 121.098 116.727 48.450 1.00 7.08  6   M 1 
-ATOM   25   H  HG   . SER M  1 7   ? 119.939 115.148 49.425 1.00 7.08  6   M 1 
-ATOM   26   N  N    . GLN M  1 8   ? 117.777 117.226 47.005 1.00 6.97  7   M 1 
-ATOM   27   C  CA   . GLN M  1 8   ? 116.610 118.112 47.218 1.00 6.97  7   M 1 
-ATOM   28   C  C    . GLN M  1 8   ? 116.732 118.800 48.583 1.00 6.97  7   M 1 
-ATOM   29   O  O    . GLN M  1 8   ? 116.136 119.848 48.758 1.00 6.97  7   M 1 
-ATOM   30   C  CB   . GLN M  1 8   ? 115.306 117.326 47.078 1.00 6.97  7   M 1 
-ATOM   31   C  CG   . GLN M  1 8   ? 115.074 116.345 48.214 1.00 6.97  7   M 1 
-ATOM   32   C  CD   . GLN M  1 8   ? 113.835 115.494 48.045 1.00 6.97  7   M 1 
-ATOM   33   O  OE1  . GLN M  1 8   ? 112.862 115.903 47.422 1.00 6.97  7   M 1 
-ATOM   34   N  NE2  . GLN M  1 8   ? 113.875 114.298 48.614 1.00 6.97  7   M 1 
-ATOM   35   H  H    . GLN M  1 8   ? 117.574 116.339 47.027 1.00 6.97  7   M 1 
-ATOM   36   H  HA   . GLN M  1 8   ? 116.628 118.808 46.520 1.00 6.97  7   M 1 
-ATOM   37   H  HB2  . GLN M  1 8   ? 114.560 117.960 47.043 1.00 6.97  7   M 1 
-ATOM   38   H  HB3  . GLN M  1 8   ? 115.326 116.836 46.229 1.00 6.97  7   M 1 
-ATOM   39   H  HG2  . GLN M  1 8   ? 115.854 115.755 48.288 1.00 6.97  7   M 1 
-ATOM   40   H  HG3  . GLN M  1 8   ? 115.001 116.846 49.054 1.00 6.97  7   M 1 
-ATOM   41   H  HE21 . GLN M  1 8   ? 114.576 114.063 49.098 1.00 6.97  7   M 1 
-ATOM   42   H  HE22 . GLN M  1 8   ? 113.201 113.736 48.510 1.00 6.97  7   M 1 
-ATOM   43   N  N    . VAL M  1 9   ? 117.388 118.172 49.551 1.00 6.25  8   M 1 
-ATOM   44   C  CA   . VAL M  1 9   ? 117.529 118.728 50.894 1.00 6.25  8   M 1 
-ATOM   45   C  C    . VAL M  1 9   ? 118.772 119.591 51.047 1.00 6.25  8   M 1 
-ATOM   46   O  O    . VAL M  1 9   ? 118.891 120.310 52.048 1.00 6.25  8   M 1 
-ATOM   47   C  CB   . VAL M  1 9   ? 117.547 117.608 51.957 1.00 6.25  8   M 1 
-ATOM   48   C  CG1  . VAL M  1 9   ? 116.257 116.809 51.898 1.00 6.25  8   M 1 
-ATOM   49   C  CG2  . VAL M  1 9   ? 118.761 116.689 51.824 1.00 6.25  8   M 1 
-ATOM   50   H  H    . VAL M  1 9   ? 117.757 117.402 49.445 1.00 6.25  8   M 1 
-ATOM   51   H  HA   . VAL M  1 9   ? 116.763 119.289 51.092 1.00 6.25  8   M 1 
-ATOM   52   H  HB   . VAL M  1 9   ? 117.602 118.020 52.833 1.00 6.25  8   M 1 
-ATOM   53   H  HG11 . VAL M  1 9   ? 116.190 116.261 52.696 1.00 6.25  8   M 1 
-ATOM   54   H  HG12 . VAL M  1 9   ? 115.507 117.422 51.853 1.00 6.25  8   M 1 
-ATOM   55   H  HG13 . VAL M  1 9   ? 116.261 116.241 51.112 1.00 6.25  8   M 1 
-ATOM   56   H  HG21 . VAL M  1 9   ? 118.720 116.025 52.530 1.00 6.25  8   M 1 
-ATOM   57   H  HG22 . VAL M  1 9   ? 118.732 116.240 50.965 1.00 6.25  8   M 1 
-ATOM   58   H  HG23 . VAL M  1 9   ? 119.588 117.186 51.922 1.00 6.25  8   M 1 
-ATOM   59   N  N    . ARG M  1 10  ? 119.714 119.469 50.120 1.00 6.80  9   M 1 
-ATOM   60   C  CA   . ARG M  1 10  ? 121.028 120.137 50.287 1.00 6.80  9   M 1 
-ATOM   61   C  C    . ARG M  1 10  ? 120.873 121.657 50.283 1.00 6.80  9   M 1 
-ATOM   62   O  O    . ARG M  1 10  ? 120.265 122.177 49.352 1.00 6.80  9   M 1 
-ATOM   63   C  CB   . ARG M  1 10  ? 122.014 119.698 49.205 1.00 6.80  9   M 1 
-ATOM   64   C  CG   . ARG M  1 10  ? 123.450 120.070 49.528 1.00 6.80  9   M 1 
-ATOM   65   C  CD   . ARG M  1 10  ? 124.419 119.495 48.512 1.00 6.80  9   M 1 
-ATOM   66   N  NE   . ARG M  1 10  ? 125.813 119.611 48.924 1.00 6.80  9   M 1 
-ATOM   67   C  CZ   . ARG M  1 10  ? 126.705 118.641 48.816 1.00 6.80  9   M 1 
-ATOM   68   N  NH1  . ARG M  1 10  ? 126.346 117.466 48.336 1.00 6.80  9   M 1 
-ATOM   69   N  NH2  . ARG M  1 10  ? 127.944 118.830 49.223 1.00 6.80  9   M 1 
-ATOM   70   H  H    . ARG M  1 10  ? 119.572 119.093 49.304 1.00 6.80  9   M 1 
-ATOM   71   H  HA   . ARG M  1 10  ? 121.392 119.870 51.162 1.00 6.80  9   M 1 
-ATOM   72   H  HB2  . ARG M  1 10  ? 121.952 118.726 49.097 1.00 6.80  9   M 1 
-ATOM   73   H  HB3  . ARG M  1 10  ? 121.758 120.115 48.356 1.00 6.80  9   M 1 
-ATOM   74   H  HG2  . ARG M  1 10  ? 123.539 121.047 49.539 1.00 6.80  9   M 1 
-ATOM   75   H  HG3  . ARG M  1 10  ? 123.681 119.732 50.419 1.00 6.80  9   M 1 
-ATOM   76   H  HD2  . ARG M  1 10  ? 124.207 118.548 48.368 1.00 6.80  9   M 1 
-ATOM   77   H  HD3  . ARG M  1 10  ? 124.299 119.960 47.657 1.00 6.80  9   M 1 
-ATOM   78   H  HE   . ARG M  1 10  ? 126.081 120.373 49.252 1.00 6.80  9   M 1 
-ATOM   79   H  HH11 . ARG M  1 10  ? 125.518 117.337 48.069 1.00 6.80  9   M 1 
-ATOM   80   H  HH12 . ARG M  1 10  ? 126.939 116.820 48.270 1.00 6.80  9   M 1 
-ATOM   81   H  HH21 . ARG M  1 10  ? 128.184 119.612 49.550 1.00 6.80  9   M 1 
-ATOM   82   H  HH22 . ARG M  1 10  ? 128.532 118.178 49.155 1.00 6.80  9   M 1 
-ATOM   83   N  N    . GLN M  1 11  ? 121.516 122.324 51.239 1.00 6.12  10  M 1 
-ATOM   84   C  CA   . GLN M  1 11  ? 121.478 123.774 51.352 1.00 6.12  10  M 1 
-ATOM   85   C  C    . GLN M  1 11  ? 122.621 124.235 52.245 1.00 6.12  10  M 1 
-ATOM   86   O  O    . GLN M  1 11  ? 122.708 123.833 53.406 1.00 6.12  10  M 1 
-ATOM   87   C  CB   . GLN M  1 11  ? 120.137 124.237 51.920 1.00 6.12  10  M 1 
-ATOM   88   C  CG   . GLN M  1 11  ? 119.911 125.721 51.902 1.00 6.12  10  M 1 
-ATOM   89   C  CD   . GLN M  1 11  ? 118.537 126.076 52.435 1.00 6.12  10  M 1 
-ATOM   90   O  OE1  . GLN M  1 11  ? 117.830 125.223 52.962 1.00 6.12  10  M 1 
-ATOM   91   N  NE2  . GLN M  1 11  ? 118.126 127.312 52.236 1.00 6.12  10  M 1 
-ATOM   92   H  H    . GLN M  1 11  ? 121.988 121.938 51.846 1.00 6.12  10  M 1 
-ATOM   93   H  HA   . GLN M  1 11  ? 121.591 124.163 50.470 1.00 6.12  10  M 1 
-ATOM   94   H  HB2  . GLN M  1 11  ? 119.423 123.835 51.401 1.00 6.12  10  M 1 
-ATOM   95   H  HB3  . GLN M  1 11  ? 120.071 123.946 52.843 1.00 6.12  10  M 1 
-ATOM   96   H  HG2  . GLN M  1 11  ? 120.572 126.146 52.470 1.00 6.12  10  M 1 
-ATOM   97   H  HG3  . GLN M  1 11  ? 119.997 126.048 50.993 1.00 6.12  10  M 1 
-ATOM   98   H  HE21 . GLN M  1 11  ? 118.637 127.884 51.847 1.00 6.12  10  M 1 
-ATOM   99   H  HE22 . GLN M  1 11  ? 117.347 127.547 52.514 1.00 6.12  10  M 1 
-ATOM   100  N  N    . ASN M  1 12  ? 123.445 125.121 51.688 1.00 6.65  11  M 1 
-ATOM   101  C  CA   . ASN M  1 12  ? 124.619 125.702 52.391 1.00 6.65  11  M 1 
-ATOM   102  C  C    . ASN M  1 12  ? 125.569 124.588 52.872 1.00 6.65  11  M 1 
-ATOM   103  O  O    . ASN M  1 12  ? 126.059 124.697 53.982 1.00 6.65  11  M 1 
-ATOM   104  C  CB   . ASN M  1 12  ? 124.137 126.571 53.556 1.00 6.65  11  M 1 
-ATOM   105  C  CG   . ASN M  1 12  ? 125.258 127.385 54.163 1.00 6.65  11  M 1 
-ATOM   106  O  OD1  . ASN M  1 12  ? 126.071 127.935 53.440 1.00 6.65  11  M 1 
-ATOM   107  N  ND2  . ASN M  1 12  ? 125.302 127.463 55.473 1.00 6.65  11  M 1 
-ATOM   108  H  H    . ASN M  1 12  ? 123.269 125.513 50.886 1.00 6.65  11  M 1 
-ATOM   109  H  HA   . ASN M  1 12  ? 125.105 126.283 51.760 1.00 6.65  11  M 1 
-ATOM   110  H  HB2  . ASN M  1 12  ? 123.438 127.176 53.235 1.00 6.65  11  M 1 
-ATOM   111  H  HB3  . ASN M  1 12  ? 123.749 125.994 54.246 1.00 6.65  11  M 1 
-ATOM   112  H  HD21 . ASN M  1 12  ? 124.657 127.104 55.959 1.00 6.65  11  M 1 
-ATOM   113  H  HD22 . ASN M  1 12  ? 125.976 127.875 55.869 1.00 6.65  11  M 1 
-ATOM   114  N  N    . TYR M  1 13  ? 125.844 123.567 52.055 1.00 5.90  12  M 1 
-ATOM   115  C  CA   . TYR M  1 13  ? 126.657 122.414 52.440 1.00 5.90  12  M 1 
-ATOM   116  C  C    . TYR M  1 13  ? 127.687 122.174 51.341 1.00 5.90  12  M 1 
-ATOM   117  O  O    . TYR M  1 13  ? 127.385 121.578 50.305 1.00 5.90  12  M 1 
-ATOM   118  C  CB   . TYR M  1 13  ? 125.780 121.196 52.694 1.00 5.90  12  M 1 
-ATOM   119  C  CG   . TYR M  1 13  ? 126.505 120.044 53.350 1.00 5.90  12  M 1 
-ATOM   120  C  CD1  . TYR M  1 13  ? 126.937 120.148 54.661 1.00 5.90  12  M 1 
-ATOM   121  C  CD2  . TYR M  1 13  ? 126.681 118.836 52.705 1.00 5.90  12  M 1 
-ATOM   122  C  CE1  . TYR M  1 13  ? 127.578 119.120 55.287 1.00 5.90  12  M 1 
-ATOM   123  C  CE2  . TYR M  1 13  ? 127.319 117.786 53.335 1.00 5.90  12  M 1 
-ATOM   124  C  CZ   . TYR M  1 13  ? 127.766 117.935 54.631 1.00 5.90  12  M 1 
-ATOM   125  O  OH   . TYR M  1 13  ? 128.404 116.916 55.298 1.00 5.90  12  M 1 
-ATOM   126  H  H    . TYR M  1 13  ? 125.574 123.542 51.239 1.00 5.90  12  M 1 
-ATOM   127  H  HA   . TYR M  1 13  ? 127.152 122.600 53.253 1.00 5.90  12  M 1 
-ATOM   128  H  HB2  . TYR M  1 13  ? 125.041 121.450 53.268 1.00 5.90  12  M 1 
-ATOM   129  H  HB3  . TYR M  1 13  ? 125.430 120.884 51.845 1.00 5.90  12  M 1 
-ATOM   130  H  HD1  . TYR M  1 13  ? 126.822 120.949 55.119 1.00 5.90  12  M 1 
-ATOM   131  H  HD2  . TYR M  1 13  ? 126.385 118.735 51.829 1.00 5.90  12  M 1 
-ATOM   132  H  HE1  . TYR M  1 13  ? 127.875 119.221 56.163 1.00 5.90  12  M 1 
-ATOM   133  H  HE2  . TYR M  1 13  ? 127.445 116.981 52.887 1.00 5.90  12  M 1 
-ATOM   134  H  HH   . TYR M  1 13  ? 128.383 116.208 54.846 1.00 5.90  12  M 1 
-ATOM   135  N  N    . HIS M  1 14  ? 128.905 122.635 51.599 1.00 7.28  13  M 1 
-ATOM   136  C  CA   . HIS M  1 14  ? 129.958 122.673 50.597 1.00 7.28  13  M 1 
-ATOM   137  C  C    . HIS M  1 14  ? 130.572 121.284 50.442 1.00 7.28  13  M 1 
-ATOM   138  O  O    . HIS M  1 14  ? 130.617 120.503 51.393 1.00 7.28  13  M 1 
-ATOM   139  C  CB   . HIS M  1 14  ? 131.006 123.701 51.029 1.00 7.28  13  M 1 
-ATOM   140  C  CG   . HIS M  1 14  ? 131.952 124.116 49.949 1.00 7.28  13  M 1 
-ATOM   141  N  ND1  . HIS M  1 14  ? 133.111 123.432 49.663 1.00 7.28  13  M 1 
-ATOM   142  C  CD2  . HIS M  1 14  ? 131.927 125.178 49.112 1.00 7.28  13  M 1 
-ATOM   143  C  CE1  . HIS M  1 14  ? 133.748 124.039 48.678 1.00 7.28  13  M 1 
-ATOM   144  N  NE2  . HIS M  1 14  ? 133.051 125.103 48.327 1.00 7.28  13  M 1 
-ATOM   145  H  H    . HIS M  1 14  ? 129.149 122.936 52.367 1.00 7.28  13  M 1 
-ATOM   146  H  HA   . HIS M  1 14  ? 129.593 122.954 49.743 1.00 7.28  13  M 1 
-ATOM   147  H  HB2  . HIS M  1 14  ? 130.552 124.500 51.338 1.00 7.28  13  M 1 
-ATOM   148  H  HB3  . HIS M  1 14  ? 131.532 123.326 51.753 1.00 7.28  13  M 1 
-ATOM   149  H  HD2  . HIS M  1 14  ? 131.267 125.832 49.071 1.00 7.28  13  M 1 
-ATOM   150  H  HE1  . HIS M  1 14  ? 134.552 123.767 48.298 1.00 7.28  13  M 1 
-ATOM   151  H  HE2  . HIS M  1 14  ? 133.267 125.657 47.706 1.00 7.28  13  M 1 
-ATOM   152  N  N    . GLN M  1 15  ? 131.037 120.970 49.229 1.00 7.51  14  M 1 
-ATOM   153  C  CA   . GLN M  1 15  ? 131.561 119.634 48.946 1.00 7.51  14  M 1 
-ATOM   154  C  C    . GLN M  1 15  ? 132.800 119.311 49.780 1.00 7.51  14  M 1 
-ATOM   155  O  O    . GLN M  1 15  ? 133.039 118.148 50.120 1.00 7.51  14  M 1 
-ATOM   156  C  CB   . GLN M  1 15  ? 131.867 119.500 47.450 1.00 7.51  14  M 1 
-ATOM   157  C  CG   . GLN M  1 15  ? 132.933 120.431 46.917 1.00 7.51  14  M 1 
-ATOM   158  C  CD   . GLN M  1 15  ? 133.162 120.248 45.425 1.00 7.51  14  M 1 
-ATOM   159  O  OE1  . GLN M  1 15  ? 132.551 119.386 44.791 1.00 7.51  14  M 1 
-ATOM   160  N  NE2  . GLN M  1 15  ? 134.052 121.052 44.861 1.00 7.51  14  M 1 
-ATOM   161  H  H    . GLN M  1 15  ? 131.058 121.511 48.561 1.00 7.51  14  M 1 
-ATOM   162  H  HA   . GLN M  1 15  ? 130.879 118.977 49.157 1.00 7.51  14  M 1 
-ATOM   163  H  HB2  . GLN M  1 15  ? 132.164 118.595 47.269 1.00 7.51  14  M 1 
-ATOM   164  H  HB3  . GLN M  1 15  ? 131.057 119.680 46.948 1.00 7.51  14  M 1 
-ATOM   165  H  HG2  . GLN M  1 15  ? 132.652 121.347 47.070 1.00 7.51  14  M 1 
-ATOM   166  H  HG3  . GLN M  1 15  ? 133.774 120.264 47.370 1.00 7.51  14  M 1 
-ATOM   167  H  HE21 . GLN M  1 15  ? 134.462 121.642 45.333 1.00 7.51  14  M 1 
-ATOM   168  H  HE22 . GLN M  1 15  ? 134.218 120.981 44.020 1.00 7.51  14  M 1 
-ATOM   169  N  N    . ASP M  1 16  ? 133.599 120.324 50.111 1.00 7.21  15  M 1 
-ATOM   170  C  CA   . ASP M  1 16  ? 134.771 120.116 50.956 1.00 7.21  15  M 1 
-ATOM   171  C  C    . ASP M  1 16  ? 134.371 119.680 52.361 1.00 7.21  15  M 1 
-ATOM   172  O  O    . ASP M  1 16  ? 135.026 118.818 52.953 1.00 7.21  15  M 1 
-ATOM   173  C  CB   . ASP M  1 16  ? 135.610 121.393 51.009 1.00 7.21  15  M 1 
-ATOM   174  C  CG   . ASP M  1 16  ? 136.321 121.680 49.696 1.00 7.21  15  M 1 
-ATOM   175  O  OD1  . ASP M  1 16  ? 136.404 120.772 48.845 1.00 7.21  15  M 1 
-ATOM   176  O  OD2  . ASP M  1 16  ? 136.805 122.815 49.519 1.00 7.21  15  M 1 
-ATOM   177  H  H    . ASP M  1 16  ? 133.476 121.137 49.858 1.00 7.21  15  M 1 
-ATOM   178  H  HA   . ASP M  1 16  ? 135.320 119.415 50.571 1.00 7.21  15  M 1 
-ATOM   179  H  HB2  . ASP M  1 16  ? 135.034 122.148 51.207 1.00 7.21  15  M 1 
-ATOM   180  H  HB3  . ASP M  1 16  ? 136.282 121.306 51.703 1.00 7.21  15  M 1 
-ATOM   181  N  N    . ALA M  1 17  ? 133.297 120.259 52.899 1.00 6.09  16  M 1 
-ATOM   182  C  CA   . ALA M  1 17  ? 132.760 119.819 54.182 1.00 6.09  16  M 1 
-ATOM   183  C  C    . ALA M  1 17  ? 132.287 118.373 54.109 1.00 6.09  16  M 1 
-ATOM   184  O  O    . ALA M  1 17  ? 132.504 117.591 55.040 1.00 6.09  16  M 1 
-ATOM   185  C  CB   . ALA M  1 17  ? 131.615 120.738 54.603 1.00 6.09  16  M 1 
-ATOM   186  H  H    . ALA M  1 17  ? 132.865 120.907 52.533 1.00 6.09  16  M 1 
-ATOM   187  H  HA   . ALA M  1 17  ? 133.452 119.884 54.859 1.00 6.09  16  M 1 
-ATOM   188  H  HB1  . ALA M  1 17  ? 131.308 120.487 55.488 1.00 6.09  16  M 1 
-ATOM   189  H  HB2  . ALA M  1 17  ? 131.935 121.654 54.614 1.00 6.09  16  M 1 
-ATOM   190  H  HB3  . ALA M  1 17  ? 130.887 120.656 53.967 1.00 6.09  16  M 1 
-ATOM   191  N  N    . GLU M  1 18  ? 131.621 118.014 53.012 1.00 5.83  17  M 1 
-ATOM   192  C  CA   . GLU M  1 18  ? 131.183 116.639 52.793 1.00 5.83  17  M 1 
-ATOM   193  C  C    . GLU M  1 18  ? 132.369 115.677 52.836 1.00 5.83  17  M 1 
-ATOM   194  O  O    . GLU M  1 18  ? 132.351 114.658 53.547 1.00 5.83  17  M 1 
-ATOM   195  C  CB   . GLU M  1 18  ? 130.451 116.566 51.447 1.00 5.83  17  M 1 
-ATOM   196  C  CG   . GLU M  1 18  ? 129.838 115.239 51.109 1.00 5.83  17  M 1 
-ATOM   197  C  CD   . GLU M  1 18  ? 129.069 115.276 49.797 1.00 5.83  17  M 1 
-ATOM   198  O  OE1  . GLU M  1 18  ? 129.047 116.341 49.148 1.00 5.83  17  M 1 
-ATOM   199  O  OE2  . GLU M  1 18  ? 128.489 114.242 49.415 1.00 5.83  17  M 1 
-ATOM   200  H  H    . GLU M  1 18  ? 131.409 118.555 52.378 1.00 5.83  17  M 1 
-ATOM   201  H  HA   . GLU M  1 18  ? 130.552 116.395 53.488 1.00 5.83  17  M 1 
-ATOM   202  H  HB2  . GLU M  1 18  ? 129.737 117.223 51.446 1.00 5.83  17  M 1 
-ATOM   203  H  HB3  . GLU M  1 18  ? 131.070 116.780 50.732 1.00 5.83  17  M 1 
-ATOM   204  H  HG2  . GLU M  1 18  ? 130.539 114.574 51.031 1.00 5.83  17  M 1 
-ATOM   205  H  HG3  . GLU M  1 18  ? 129.220 114.990 51.814 1.00 5.83  17  M 1 
-ATOM   206  N  N    . ALA M  1 19  ? 133.426 116.014 52.101 1.00 5.64  18  M 1 
-ATOM   207  C  CA   . ALA M  1 19  ? 134.627 115.186 52.077 1.00 5.64  18  M 1 
-ATOM   208  C  C    . ALA M  1 19  ? 135.261 115.089 53.461 1.00 5.64  18  M 1 
-ATOM   209  O  O    . ALA M  1 19  ? 135.695 114.008 53.887 1.00 5.64  18  M 1 
-ATOM   210  C  CB   . ALA M  1 19  ? 135.619 115.756 51.068 1.00 5.64  18  M 1 
-ATOM   211  H  H    . ALA M  1 19  ? 133.469 116.730 51.627 1.00 5.64  18  M 1 
-ATOM   212  H  HA   . ALA M  1 19  ? 134.387 114.294 51.780 1.00 5.64  18  M 1 
-ATOM   213  H  HB1  . ALA M  1 19  ? 136.445 115.249 51.108 1.00 5.64  18  M 1 
-ATOM   214  H  HB2  . ALA M  1 19  ? 135.231 115.688 50.181 1.00 5.64  18  M 1 
-ATOM   215  H  HB3  . ALA M  1 19  ? 135.792 116.686 51.281 1.00 5.64  18  M 1 
-ATOM   216  N  N    . ALA M  1 20  ? 135.309 116.209 54.182 1.00 5.19  19  M 1 
-ATOM   217  C  CA   . ALA M  1 20  ? 135.912 116.226 55.509 1.00 5.19  19  M 1 
-ATOM   218  C  C    . ALA M  1 20  ? 135.118 115.366 56.484 1.00 5.19  19  M 1 
-ATOM   219  O  O    . ALA M  1 20  ? 135.694 114.687 57.340 1.00 5.19  19  M 1 
-ATOM   220  C  CB   . ALA M  1 20  ? 136.010 117.663 56.015 1.00 5.19  19  M 1 
-ATOM   221  H  H    . ALA M  1 20  ? 134.988 116.964 53.924 1.00 5.19  19  M 1 
-ATOM   222  H  HA   . ALA M  1 20  ? 136.813 115.873 55.449 1.00 5.19  19  M 1 
-ATOM   223  H  HB1  . ALA M  1 20  ? 136.318 117.661 56.935 1.00 5.19  19  M 1 
-ATOM   224  H  HB2  . ALA M  1 20  ? 136.643 118.153 55.468 1.00 5.19  19  M 1 
-ATOM   225  H  HB3  . ALA M  1 20  ? 135.136 118.080 55.963 1.00 5.19  19  M 1 
-ATOM   226  N  N    . ILE M  1 21  ? 133.794 115.373 56.355 1.00 4.65  20  M 1 
-ATOM   227  C  CA   . ILE M  1 21  ? 132.950 114.537 57.205 1.00 4.65  20  M 1 
-ATOM   228  C  C    . ILE M  1 21  ? 133.187 113.062 56.918 1.00 4.65  20  M 1 
-ATOM   229  O  O    . ILE M  1 21  ? 133.212 112.237 57.837 1.00 4.65  20  M 1 
-ATOM   230  C  CB   . ILE M  1 21  ? 131.466 114.924 57.036 1.00 4.65  20  M 1 
-ATOM   231  C  CG1  . ILE M  1 21  ? 131.165 116.301 57.642 1.00 4.65  20  M 1 
-ATOM   232  C  CG2  . ILE M  1 21  ? 130.563 113.897 57.679 1.00 4.65  20  M 1 
-ATOM   233  C  CD1  . ILE M  1 21  ? 131.182 116.337 59.164 1.00 4.65  20  M 1 
-ATOM   234  H  H    . ILE M  1 21  ? 133.365 115.839 55.774 1.00 4.65  20  M 1 
-ATOM   235  H  HA   . ILE M  1 21  ? 133.213 114.693 58.125 1.00 4.65  20  M 1 
-ATOM   236  H  HB   . ILE M  1 21  ? 131.263 114.954 56.088 1.00 4.65  20  M 1 
-ATOM   237  H  HG12 . ILE M  1 21  ? 131.845 116.927 57.348 1.00 4.65  20  M 1 
-ATOM   238  H  HG13 . ILE M  1 21  ? 130.297 116.611 57.340 1.00 4.65  20  M 1 
-ATOM   239  H  HG21 . ILE M  1 21  ? 129.700 114.308 57.842 1.00 4.65  20  M 1 
-ATOM   240  H  HG22 . ILE M  1 21  ? 130.447 113.140 57.083 1.00 4.65  20  M 1 
-ATOM   241  H  HG23 . ILE M  1 21  ? 130.944 113.601 58.521 1.00 4.65  20  M 1 
-ATOM   242  H  HD11 . ILE M  1 21  ? 131.445 117.226 59.450 1.00 4.65  20  M 1 
-ATOM   243  H  HD12 . ILE M  1 21  ? 130.292 116.138 59.495 1.00 4.65  20  M 1 
-ATOM   244  H  HD13 . ILE M  1 21  ? 131.804 115.688 59.529 1.00 4.65  20  M 1 
-ATOM   245  N  N    . ASN M  1 22  ? 133.341 112.698 55.646 1.00 4.76  21  M 1 
-ATOM   246  C  CA   . ASN M  1 22  ? 133.649 111.301 55.339 1.00 4.76  21  M 1 
-ATOM   247  C  C    . ASN M  1 22  ? 134.999 110.889 55.925 1.00 4.76  21  M 1 
-ATOM   248  O  O    . ASN M  1 22  ? 135.141 109.784 56.475 1.00 4.76  21  M 1 
-ATOM   249  C  CB   . ASN M  1 22  ? 133.598 111.055 53.832 1.00 4.76  21  M 1 
-ATOM   250  C  CG   . ASN M  1 22  ? 132.178 111.044 53.293 1.00 4.76  21  M 1 
-ATOM   251  O  OD1  . ASN M  1 22  ? 131.264 110.549 53.941 1.00 4.76  21  M 1 
-ATOM   252  N  ND2  . ASN M  1 22  ? 132.000 111.547 52.086 1.00 4.76  21  M 1 
-ATOM   253  H  H    . ASN M  1 22  ? 133.277 113.220 54.965 1.00 4.76  21  M 1 
-ATOM   254  H  HA   . ASN M  1 22  ? 132.976 110.740 55.755 1.00 4.76  21  M 1 
-ATOM   255  H  HB2  . ASN M  1 22  ? 134.078 111.762 53.373 1.00 4.76  21  M 1 
-ATOM   256  H  HB3  . ASN M  1 22  ? 134.006 110.200 53.626 1.00 4.76  21  M 1 
-ATOM   257  H  HD21 . ASN M  1 22  ? 132.665 111.877 51.652 1.00 4.76  21  M 1 
-ATOM   258  H  HD22 . ASN M  1 22  ? 131.214 111.556 51.737 1.00 4.76  21  M 1 
-ATOM   259  N  N    . ARG M  1 23  ? 135.968 111.799 55.858 1.00 5.20  22  M 1 
-ATOM   260  C  CA   . ARG M  1 23  ? 137.304 111.552 56.459 1.00 5.20  22  M 1 
-ATOM   261  C  C    . ARG M  1 23  ? 137.134 111.402 57.973 1.00 5.20  22  M 1 
-ATOM   262  O  O    . ARG M  1 23  ? 137.736 110.506 58.538 1.00 5.20  22  M 1 
-ATOM   263  C  CB   . ARG M  1 23  ? 138.287 112.670 56.112 1.00 5.20  22  M 1 
-ATOM   264  C  CG   . ARG M  1 23  ? 138.602 112.743 54.626 1.00 5.20  22  M 1 
-ATOM   265  C  CD   . ARG M  1 23  ? 139.855 113.564 54.401 1.00 5.20  22  M 1 
-ATOM   266  N  NE   . ARG M  1 23  ? 139.739 114.892 54.977 1.00 5.20  22  M 1 
-ATOM   267  C  CZ   . ARG M  1 23  ? 139.293 115.956 54.319 1.00 5.20  22  M 1 
-ATOM   268  N  NH1  . ARG M  1 23  ? 138.919 115.844 53.060 1.00 5.20  22  M 1 
-ATOM   269  N  NH2  . ARG M  1 23  ? 139.230 117.132 54.915 1.00 5.20  22  M 1 
-ATOM   270  H  H    . ARG M  1 23  ? 135.834 112.649 55.562 1.00 5.20  22  M 1 
-ATOM   271  H  HA   . ARG M  1 23  ? 137.651 110.704 56.097 1.00 5.20  22  M 1 
-ATOM   272  H  HB2  . ARG M  1 23  ? 137.907 113.526 56.400 1.00 5.20  22  M 1 
-ATOM   273  H  HB3  . ARG M  1 23  ? 139.120 112.524 56.609 1.00 5.20  22  M 1 
-ATOM   274  H  HG2  . ARG M  1 23  ? 138.737 111.838 54.272 1.00 5.20  22  M 1 
-ATOM   275  H  HG3  . ARG M  1 23  ? 137.852 113.155 54.148 1.00 5.20  22  M 1 
-ATOM   276  H  HD2  . ARG M  1 23  ? 140.622 113.103 54.803 1.00 5.20  22  M 1 
-ATOM   277  H  HD3  . ARG M  1 23  ? 140.021 113.643 53.437 1.00 5.20  22  M 1 
-ATOM   278  H  HE   . ARG M  1 23  ? 139.984 115.002 55.807 1.00 5.20  22  M 1 
-ATOM   279  H  HH11 . ARG M  1 23  ? 138.963 115.063 52.658 1.00 5.20  22  M 1 
-ATOM   280  H  HH12 . ARG M  1 23  ? 138.624 116.549 52.626 1.00 5.20  22  M 1 
-ATOM   281  H  HH21 . ARG M  1 23  ? 139.480 117.211 55.756 1.00 5.20  22  M 1 
-ATOM   282  H  HH22 . ARG M  1 23  ? 138.932 117.833 54.473 1.00 5.20  22  M 1 
-ATOM   283  N  N    . GLN M  1 24  ? 136.303 112.230 58.589 1.00 4.27  23  M 1 
-ATOM   284  C  CA   . GLN M  1 24  ? 136.057 112.163 60.050 1.00 4.27  23  M 1 
-ATOM   285  C  C    . GLN M  1 24  ? 135.381 110.826 60.366 1.00 4.27  23  M 1 
-ATOM   286  O  O    . GLN M  1 24  ? 135.792 110.182 61.304 1.00 4.27  23  M 1 
-ATOM   287  C  CB   . GLN M  1 24  ? 135.231 113.334 60.583 1.00 4.27  23  M 1 
-ATOM   288  C  CG   . GLN M  1 24  ? 135.188 113.347 62.108 1.00 4.27  23  M 1 
-ATOM   289  C  CD   . GLN M  1 24  ? 136.537 113.649 62.722 1.00 4.27  23  M 1 
-ATOM   290  O  OE1  . GLN M  1 24  ? 137.398 114.230 62.085 1.00 4.27  23  M 1 
-ATOM   291  N  NE2  . GLN M  1 24  ? 136.731 113.278 63.973 1.00 4.27  23  M 1 
-ATOM   292  H  H    . GLN M  1 24  ? 135.752 112.801 58.143 1.00 4.27  23  M 1 
-ATOM   293  H  HA   . GLN M  1 24  ? 136.933 112.175 60.501 1.00 4.27  23  M 1 
-ATOM   294  H  HB2  . GLN M  1 24  ? 135.623 114.172 60.260 1.00 4.27  23  M 1 
-ATOM   295  H  HB3  . GLN M  1 24  ? 134.319 113.266 60.231 1.00 4.27  23  M 1 
-ATOM   296  H  HG2  . GLN M  1 24  ? 134.542 114.023 62.406 1.00 4.27  23  M 1 
-ATOM   297  H  HG3  . GLN M  1 24  ? 134.878 112.473 62.429 1.00 4.27  23  M 1 
-ATOM   298  H  HE21 . GLN M  1 24  ? 136.087 112.865 64.417 1.00 4.27  23  M 1 
-ATOM   299  H  HE22 . GLN M  1 24  ? 137.504 113.442 64.368 1.00 4.27  23  M 1 
-ATOM   300  N  N    . ILE M  1 25  ? 134.455 110.366 59.533 1.00 4.04  24  M 1 
-ATOM   301  C  CA   . ILE M  1 25  ? 133.757 109.072 59.780 1.00 4.04  24  M 1 
-ATOM   302  C  C    . ILE M  1 25  ? 134.814 107.969 59.775 1.00 4.04  24  M 1 
-ATOM   303  O  O    . ILE M  1 25  ? 134.825 107.162 60.686 1.00 4.04  24  M 1 
-ATOM   304  C  CB   . ILE M  1 25  ? 132.669 108.811 58.722 1.00 4.04  24  M 1 
-ATOM   305  C  CG1  . ILE M  1 25  ? 131.463 109.726 58.927 1.00 4.04  24  M 1 
-ATOM   306  C  CG2  . ILE M  1 25  ? 132.268 107.346 58.704 1.00 4.04  24  M 1 
-ATOM   307  C  CD1  . ILE M  1 25  ? 130.542 109.790 57.732 1.00 4.04  24  M 1 
-ATOM   308  H  H    . ILE M  1 25  ? 134.294 110.730 58.714 1.00 4.04  24  M 1 
-ATOM   309  H  HA   . ILE M  1 25  ? 133.339 109.104 60.659 1.00 4.04  24  M 1 
-ATOM   310  H  HB   . ILE M  1 25  ? 133.057 109.027 57.838 1.00 4.04  24  M 1 
-ATOM   311  H  HG12 . ILE M  1 25  ? 130.953 109.407 59.703 1.00 4.04  24  M 1 
-ATOM   312  H  HG13 . ILE M  1 25  ? 131.783 110.631 59.129 1.00 4.04  24  M 1 
-ATOM   313  H  HG21 . ILE M  1 25  ? 131.520 107.219 58.094 1.00 4.04  24  M 1 
-ATOM   314  H  HG22 . ILE M  1 25  ? 133.020 106.805 58.408 1.00 4.04  24  M 1 
-ATOM   315  H  HG23 . ILE M  1 25  ? 132.004 107.068 59.598 1.00 4.04  24  M 1 
-ATOM   316  H  HD11 . ILE M  1 25  ? 129.788 110.372 57.933 1.00 4.04  24  M 1 
-ATOM   317  H  HD12 . ILE M  1 25  ? 131.027 110.141 56.966 1.00 4.04  24  M 1 
-ATOM   318  H  HD13 . ILE M  1 25  ? 130.213 108.898 57.525 1.00 4.04  24  M 1 
-ATOM   319  N  N    . ASN M  1 26  ? 135.739 107.997 58.831 1.00 4.23  25  M 1 
-ATOM   320  C  CA   . ASN M  1 26  ? 136.770 106.935 58.766 1.00 4.23  25  M 1 
-ATOM   321  C  C    . ASN M  1 26  ? 137.629 107.000 60.033 1.00 4.23  25  M 1 
-ATOM   322  O  O    . ASN M  1 26  ? 137.870 105.966 60.618 1.00 4.23  25  M 1 
-ATOM   323  C  CB   . ASN M  1 26  ? 137.632 107.025 57.513 1.00 4.23  25  M 1 
-ATOM   324  C  CG   . ASN M  1 26  ? 138.457 105.768 57.372 1.00 4.23  25  M 1 
-ATOM   325  O  OD1  . ASN M  1 26  ? 139.615 105.766 57.731 1.00 4.23  25  M 1 
-ATOM   326  N  ND2  . ASN M  1 26  ? 137.836 104.688 56.940 1.00 4.23  25  M 1 
-ATOM   327  H  H    . ASN M  1 26  ? 135.874 108.705 58.276 1.00 4.23  25  M 1 
-ATOM   328  H  HA   . ASN M  1 26  ? 136.310 106.063 58.747 1.00 4.23  25  M 1 
-ATOM   329  H  HB2  . ASN M  1 26  ? 137.058 107.133 56.728 1.00 4.23  25  M 1 
-ATOM   330  H  HB3  . ASN M  1 26  ? 138.224 107.802 57.579 1.00 4.23  25  M 1 
-ATOM   331  H  HD21 . ASN M  1 26  ? 136.953 104.669 56.909 1.00 4.23  25  M 1 
-ATOM   332  H  HD22 . ASN M  1 26  ? 138.302 103.982 56.685 1.00 4.23  25  M 1 
-ATOM   333  N  N    . LEU M  1 27  ? 137.977 108.199 60.481 1.00 4.02  26  M 1 
-ATOM   334  C  CA   . LEU M  1 27  ? 138.840 108.382 61.679 1.00 4.02  26  M 1 
-ATOM   335  C  C    . LEU M  1 27  ? 138.126 107.816 62.917 1.00 4.02  26  M 1 
-ATOM   336  O  O    . LEU M  1 27  ? 138.760 107.121 63.684 1.00 4.02  26  M 1 
-ATOM   337  C  CB   . LEU M  1 27  ? 139.149 109.873 61.835 1.00 4.02  26  M 1 
-ATOM   338  C  CG   . LEU M  1 27  ? 140.085 110.228 62.989 1.00 4.02  26  M 1 
-ATOM   339  C  CD1  . LEU M  1 27  ? 141.294 109.307 63.013 1.00 4.02  26  M 1 
-ATOM   340  C  CD2  . LEU M  1 27  ? 140.521 111.687 62.919 1.00 4.02  26  M 1 
-ATOM   341  H  H    . LEU M  1 27  ? 137.610 108.970 60.164 1.00 4.02  26  M 1 
-ATOM   342  H  HA   . LEU M  1 27  ? 139.678 107.884 61.539 1.00 4.02  26  M 1 
-ATOM   343  H  HB2  . LEU M  1 27  ? 139.548 110.193 61.001 1.00 4.02  26  M 1 
-ATOM   344  H  HB3  . LEU M  1 27  ? 138.305 110.351 61.961 1.00 4.02  26  M 1 
-ATOM   345  H  HG   . LEU M  1 27  ? 139.588 110.099 63.834 1.00 4.02  26  M 1 
-ATOM   346  H  HD11 . LEU M  1 27  ? 141.901 109.586 63.720 1.00 4.02  26  M 1 
-ATOM   347  H  HD12 . LEU M  1 27  ? 141.003 108.393 63.178 1.00 4.02  26  M 1 
-ATOM   348  H  HD13 . LEU M  1 27  ? 141.753 109.351 62.156 1.00 4.02  26  M 1 
-ATOM   349  H  HD21 . LEU M  1 27  ? 141.103 111.888 63.672 1.00 4.02  26  M 1 
-ATOM   350  H  HD22 . LEU M  1 27  ? 141.001 111.843 62.087 1.00 4.02  26  M 1 
-ATOM   351  H  HD23 . LEU M  1 27  ? 139.737 112.262 62.953 1.00 4.02  26  M 1 
-ATOM   352  N  N    . GLU M  1 28  ? 136.831 108.071 63.062 1.00 4.01  27  M 1 
-ATOM   353  C  CA   . GLU M  1 28  ? 136.023 107.567 64.213 1.00 4.01  27  M 1 
-ATOM   354  C  C    . GLU M  1 28  ? 135.968 106.029 64.180 1.00 4.01  27  M 1 
-ATOM   355  O  O    . GLU M  1 28  ? 136.192 105.431 65.200 1.00 4.01  27  M 1 
-ATOM   356  C  CB   . GLU M  1 28  ? 134.646 108.231 64.224 1.00 4.01  27  M 1 
-ATOM   357  C  CG   . GLU M  1 28  ? 134.708 109.746 64.330 1.00 4.01  27  M 1 
-ATOM   358  C  CD   . GLU M  1 28  ? 135.022 110.278 65.717 1.00 4.01  27  M 1 
-ATOM   359  O  OE1  . GLU M  1 28  ? 135.132 111.477 65.845 1.00 4.01  27  M 1 
-ATOM   360  O  OE2  . GLU M  1 28  ? 135.180 109.480 66.654 1.00 4.01  27  M 1 
-ATOM   361  H  H    . GLU M  1 28  ? 136.336 108.472 62.412 1.00 4.01  27  M 1 
-ATOM   362  H  HA   . GLU M  1 28  ? 136.491 107.832 65.039 1.00 4.01  27  M 1 
-ATOM   363  H  HB2  . GLU M  1 28  ? 134.174 107.988 63.400 1.00 4.01  27  M 1 
-ATOM   364  H  HB3  . GLU M  1 28  ? 134.133 107.879 64.981 1.00 4.01  27  M 1 
-ATOM   365  H  HG2  . GLU M  1 28  ? 135.391 110.078 63.709 1.00 4.01  27  M 1 
-ATOM   366  H  HG3  . GLU M  1 28  ? 133.846 110.118 64.045 1.00 4.01  27  M 1 
-ATOM   367  N  N    . LEU M  1 29  ? 135.785 105.403 63.026 1.00 3.51  28  M 1 
-ATOM   368  C  CA   . LEU M  1 29  ? 135.765 103.946 62.933 1.00 3.51  28  M 1 
-ATOM   369  C  C    . LEU M  1 29  ? 137.136 103.360 63.258 1.00 3.51  28  M 1 
-ATOM   370  O  O    . LEU M  1 29  ? 137.245 102.337 63.952 1.00 3.51  28  M 1 
-ATOM   371  C  CB   . LEU M  1 29  ? 135.301 103.527 61.538 1.00 3.51  28  M 1 
-ATOM   372  C  CG   . LEU M  1 29  ? 133.853 103.850 61.150 1.00 3.51  28  M 1 
-ATOM   373  C  CD1  . LEU M  1 29  ? 133.595 103.571 59.675 1.00 3.51  28  M 1 
-ATOM   374  C  CD2  . LEU M  1 29  ? 132.868 103.099 62.048 1.00 3.51  28  M 1 
-ATOM   375  H  H    . LEU M  1 29  ? 135.653 105.809 62.280 1.00 3.51  28  M 1 
-ATOM   376  H  HA   . LEU M  1 29  ? 135.135 103.595 63.582 1.00 3.51  28  M 1 
-ATOM   377  H  HB2  . LEU M  1 29  ? 135.875 103.956 60.885 1.00 3.51  28  M 1 
-ATOM   378  H  HB3  . LEU M  1 29  ? 135.409 102.566 61.462 1.00 3.51  28  M 1 
-ATOM   379  H  HG   . LEU M  1 29  ? 133.694 104.797 61.289 1.00 3.51  28  M 1 
-ATOM   380  H  HD11 . LEU M  1 29  ? 132.643 103.636 59.502 1.00 3.51  28  M 1 
-ATOM   381  H  HD12 . LEU M  1 29  ? 134.053 104.234 59.135 1.00 3.51  28  M 1 
-ATOM   382  H  HD13 . LEU M  1 29  ? 133.912 102.684 59.442 1.00 3.51  28  M 1 
-ATOM   383  H  HD21 . LEU M  1 29  ? 132.022 102.980 61.589 1.00 3.51  28  M 1 
-ATOM   384  H  HD22 . LEU M  1 29  ? 133.233 102.231 62.281 1.00 3.51  28  M 1 
-ATOM   385  H  HD23 . LEU M  1 29  ? 132.726 103.616 62.856 1.00 3.51  28  M 1 
-ATOM   386  N  N    . TYR M  1 30  ? 138.197 104.018 62.789 1.00 3.71  29  M 1 
-ATOM   387  C  CA   . TYR M  1 30  ? 139.553 103.601 63.125 1.00 3.71  29  M 1 
-ATOM   388  C  C    . TYR M  1 30  ? 139.788 103.627 64.630 1.00 3.71  29  M 1 
-ATOM   389  O  O    . TYR M  1 30  ? 140.367 102.694 65.193 1.00 3.71  29  M 1 
-ATOM   390  C  CB   . TYR M  1 30  ? 140.558 104.494 62.407 1.00 3.71  29  M 1 
-ATOM   391  C  CG   . TYR M  1 30  ? 141.983 104.208 62.780 1.00 3.71  29  M 1 
-ATOM   392  C  CD1  . TYR M  1 30  ? 142.637 103.095 62.294 1.00 3.71  29  M 1 
-ATOM   393  C  CD2  . TYR M  1 30  ? 142.674 105.050 63.634 1.00 3.71  29  M 1 
-ATOM   394  C  CE1  . TYR M  1 30  ? 143.934 102.835 62.635 1.00 3.71  29  M 1 
-ATOM   395  C  CE2  . TYR M  1 30  ? 143.977 104.793 63.983 1.00 3.71  29  M 1 
-ATOM   396  C  CZ   . TYR M  1 30  ? 144.601 103.678 63.482 1.00 3.71  29  M 1 
-ATOM   397  O  OH   . TYR M  1 30  ? 145.902 103.394 63.809 1.00 3.71  29  M 1 
-ATOM   398  H  H    . TYR M  1 30  ? 138.158 104.711 62.281 1.00 3.71  29  M 1 
-ATOM   399  H  HA   . TYR M  1 30  ? 139.690 102.691 62.818 1.00 3.71  29  M 1 
-ATOM   400  H  HB2  . TYR M  1 30  ? 140.472 104.349 61.452 1.00 3.71  29  M 1 
-ATOM   401  H  HB3  . TYR M  1 30  ? 140.372 105.424 62.613 1.00 3.71  29  M 1 
-ATOM   402  H  HD1  . TYR M  1 30  ? 142.192 102.514 61.720 1.00 3.71  29  M 1 
-ATOM   403  H  HD2  . TYR M  1 30  ? 142.251 105.805 63.975 1.00 3.71  29  M 1 
-ATOM   404  H  HE1  . TYR M  1 30  ? 144.359 102.079 62.298 1.00 3.71  29  M 1 
-ATOM   405  H  HE2  . TYR M  1 30  ? 144.429 105.369 64.556 1.00 3.71  29  M 1 
-ATOM   406  H  HH   . TYR M  1 30  ? 146.373 103.345 63.115 1.00 3.71  29  M 1 
-ATOM   407  N  N    . ALA M  1 31  ? 139.356 104.699 65.292 1.00 3.35  30  M 1 
-ATOM   408  C  CA   . ALA M  1 31  ? 139.528 104.812 66.738 1.00 3.35  30  M 1 
-ATOM   409  C  C    . ALA M  1 31  ? 138.774 103.707 67.462 1.00 3.35  30  M 1 
-ATOM   410  O  O    . ALA M  1 31  ? 139.276 103.129 68.437 1.00 3.35  30  M 1 
-ATOM   411  C  CB   . ALA M  1 31  ? 139.056 106.184 67.214 1.00 3.35  30  M 1 
-ATOM   412  H  H    . ALA M  1 31  ? 138.946 105.361 64.927 1.00 3.35  30  M 1 
-ATOM   413  H  HA   . ALA M  1 31  ? 140.472 104.735 66.949 1.00 3.35  30  M 1 
-ATOM   414  H  HB1  . ALA M  1 31  ? 139.116 106.235 68.181 1.00 3.35  30  M 1 
-ATOM   415  H  HB2  . ALA M  1 31  ? 139.622 106.867 66.821 1.00 3.35  30  M 1 
-ATOM   416  H  HB3  . ALA M  1 31  ? 138.134 106.318 66.945 1.00 3.35  30  M 1 
-ATOM   417  N  N    . SER M  1 32  ? 137.564 103.400 66.993 1.00 3.18  31  M 1 
-ATOM   418  C  CA   . SER M  1 32  ? 136.811 102.293 67.567 1.00 3.18  31  M 1 
-ATOM   419  C  C    . SER M  1 32  ? 137.603 100.999 67.464 1.00 3.18  31  M 1 
-ATOM   420  O  O    . SER M  1 32  ? 137.641 100.201 68.404 1.00 3.18  31  M 1 
-ATOM   421  C  CB   . SER M  1 32  ? 135.466 102.139 66.865 1.00 3.18  31  M 1 
-ATOM   422  O  OG   . SER M  1 32  ? 134.752 101.051 67.407 1.00 3.18  31  M 1 
-ATOM   423  H  H    . SER M  1 32  ? 137.174 103.793 66.335 1.00 3.18  31  M 1 
-ATOM   424  H  HA   . SER M  1 32  ? 136.630 102.476 68.502 1.00 3.18  31  M 1 
-ATOM   425  H  HB2  . SER M  1 32  ? 134.939 102.946 66.973 1.00 3.18  31  M 1 
-ATOM   426  H  HB3  . SER M  1 32  ? 135.620 101.974 65.922 1.00 3.18  31  M 1 
-ATOM   427  H  HG   . SER M  1 32  ? 135.094 100.829 68.141 1.00 3.18  31  M 1 
-ATOM   428  N  N    . TYR M  1 33  ? 138.275 100.799 66.337 1.00 3.03  32  M 1 
-ATOM   429  C  CA   . TYR M  1 33  ? 138.957 99.533  66.105 1.00 3.03  32  M 1 
-ATOM   430  C  C    . TYR M  1 33  ? 140.246 99.446  66.928 1.00 3.03  32  M 1 
-ATOM   431  O  O    . TYR M  1 33  ? 140.590 98.384  67.463 1.00 3.03  32  M 1 
-ATOM   432  C  CB   . TYR M  1 33  ? 139.148 99.386  64.594 1.00 3.03  32  M 1 
-ATOM   433  C  CG   . TYR M  1 33  ? 139.641 98.067  64.082 1.00 3.03  32  M 1 
-ATOM   434  C  CD1  . TYR M  1 33  ? 139.026 96.900  64.464 1.00 3.03  32  M 1 
-ATOM   435  C  CD2  . TYR M  1 33  ? 140.504 98.008  63.005 1.00 3.03  32  M 1 
-ATOM   436  C  CE1  . TYR M  1 33  ? 139.409 95.696  63.962 1.00 3.03  32  M 1 
-ATOM   437  C  CE2  . TYR M  1 33  ? 140.878 96.805  62.460 1.00 3.03  32  M 1 
-ATOM   438  C  CZ   . TYR M  1 33  ? 140.315 95.642  62.942 1.00 3.03  32  M 1 
-ATOM   439  O  OH   . TYR M  1 33  ? 140.653 94.414  62.435 1.00 3.03  32  M 1 
-ATOM   440  H  H    . TYR M  1 33  ? 138.348 101.369 65.698 1.00 3.03  32  M 1 
-ATOM   441  H  HA   . TYR M  1 33  ? 138.370 98.818  66.396 1.00 3.03  32  M 1 
-ATOM   442  H  HB2  . TYR M  1 33  ? 138.302 99.563  64.154 1.00 3.03  32  M 1 
-ATOM   443  H  HB3  . TYR M  1 33  ? 139.791 100.056 64.312 1.00 3.03  32  M 1 
-ATOM   444  H  HD1  . TYR M  1 33  ? 138.426 96.924  65.175 1.00 3.03  32  M 1 
-ATOM   445  H  HD2  . TYR M  1 33  ? 140.889 98.792  62.686 1.00 3.03  32  M 1 
-ATOM   446  H  HE1  . TYR M  1 33  ? 139.016 94.918  64.286 1.00 3.03  32  M 1 
-ATOM   447  H  HE2  . TYR M  1 33  ? 141.500 96.784  61.769 1.00 3.03  32  M 1 
-ATOM   448  H  HH   . TYR M  1 33  ? 141.157 94.498  61.768 1.00 3.03  32  M 1 
-ATOM   449  N  N    . VAL M  1 34  ? 140.915 100.585 67.121 1.00 3.46  33  M 1 
-ATOM   450  C  CA   . VAL M  1 34  ? 142.055 100.663 68.039 1.00 3.46  33  M 1 
-ATOM   451  C  C    . VAL M  1 34  ? 141.629 100.281 69.455 1.00 3.46  33  M 1 
-ATOM   452  O  O    . VAL M  1 34  ? 142.290 99.482  70.134 1.00 3.46  33  M 1 
-ATOM   453  C  CB   . VAL M  1 34  ? 142.683 102.071 68.007 1.00 3.46  33  M 1 
-ATOM   454  C  CG1  . VAL M  1 34  ? 143.748 102.219 69.088 1.00 3.46  33  M 1 
-ATOM   455  C  CG2  . VAL M  1 34  ? 143.311 102.347 66.654 1.00 3.46  33  M 1 
-ATOM   456  H  H    . VAL M  1 34  ? 140.716 101.332 66.744 1.00 3.46  33  M 1 
-ATOM   457  H  HA   . VAL M  1 34  ? 142.735 100.036 67.747 1.00 3.46  33  M 1 
-ATOM   458  H  HB   . VAL M  1 34  ? 141.995 102.736 68.165 1.00 3.46  33  M 1 
-ATOM   459  H  HG11 . VAL M  1 34  ? 144.305 102.986 68.882 1.00 3.46  33  M 1 
-ATOM   460  H  HG12 . VAL M  1 34  ? 143.331 102.360 69.952 1.00 3.46  33  M 1 
-ATOM   461  H  HG13 . VAL M  1 34  ? 144.301 101.423 69.110 1.00 3.46  33  M 1 
-ATOM   462  H  HG21 . VAL M  1 34  ? 143.667 103.249 66.651 1.00 3.46  33  M 1 
-ATOM   463  H  HG22 . VAL M  1 34  ? 144.029 101.713 66.500 1.00 3.46  33  M 1 
-ATOM   464  H  HG23 . VAL M  1 34  ? 142.654 102.259 65.946 1.00 3.46  33  M 1 
-ATOM   465  N  N    . TYR M  1 35  ? 140.530 100.866 69.919 1.00 3.20  34  M 1 
-ATOM   466  C  CA   . TYR M  1 35  ? 140.001 100.604 71.283 1.00 3.20  34  M 1 
-ATOM   467  C  C    . TYR M  1 35  ? 139.639 99.114  71.378 1.00 3.20  34  M 1 
-ATOM   468  O  O    . TYR M  1 35  ? 139.849 98.500  72.402 1.00 3.20  34  M 1 
-ATOM   469  C  CB   . TYR M  1 35  ? 138.841 101.546 71.587 1.00 3.20  34  M 1 
-ATOM   470  C  CG   . TYR M  1 35  ? 139.250 102.931 72.020 1.00 3.20  34  M 1 
-ATOM   471  C  CD1  . TYR M  1 35  ? 140.196 103.117 73.010 1.00 3.20  34  M 1 
-ATOM   472  C  CD2  . TYR M  1 35  ? 138.646 104.058 71.485 1.00 3.20  34  M 1 
-ATOM   473  C  CE1  . TYR M  1 35  ? 140.544 104.389 73.448 1.00 3.20  34  M 1 
-ATOM   474  C  CE2  . TYR M  1 35  ? 138.992 105.335 71.899 1.00 3.20  34  M 1 
-ATOM   475  C  CZ   . TYR M  1 35  ? 139.942 105.505 72.889 1.00 3.20  34  M 1 
-ATOM   476  O  OH   . TYR M  1 35  ? 140.290 106.755 73.319 1.00 3.20  34  M 1 
-ATOM   477  H  H    . TYR M  1 35  ? 139.962 101.356 69.405 1.00 3.20  34  M 1 
-ATOM   478  H  HA   . TYR M  1 35  ? 140.725 100.784 71.935 1.00 3.20  34  M 1 
-ATOM   479  H  HB2  . TYR M  1 35  ? 138.284 101.619 70.784 1.00 3.20  34  M 1 
-ATOM   480  H  HB3  . TYR M  1 35  ? 138.294 101.144 72.294 1.00 3.20  34  M 1 
-ATOM   481  H  HD1  . TYR M  1 35  ? 140.606 102.366 73.404 1.00 3.20  34  M 1 
-ATOM   482  H  HD2  . TYR M  1 35  ? 137.992 103.955 70.813 1.00 3.20  34  M 1 
-ATOM   483  H  HE1  . TYR M  1 35  ? 141.198 104.495 74.119 1.00 3.20  34  M 1 
-ATOM   484  H  HE2  . TYR M  1 35  ? 138.571 106.086 71.515 1.00 3.20  34  M 1 
-ATOM   485  H  HH   . TYR M  1 35  ? 139.593 107.177 73.589 1.00 3.20  34  M 1 
-ATOM   486  N  N    . LEU M  1 36  ? 139.084 98.533  70.325 1.00 3.08  35  M 1 
-ATOM   487  C  CA   . LEU M  1 36  ? 138.744 97.115  70.332 1.00 3.08  35  M 1 
-ATOM   488  C  C    . LEU M  1 36  ? 139.990 96.254  70.508 1.00 3.08  35  M 1 
-ATOM   489  O  O    . LEU M  1 36  ? 139.984 95.281  71.274 1.00 3.08  35  M 1 
-ATOM   490  C  CB   . LEU M  1 36  ? 138.005 96.750  69.045 1.00 3.08  35  M 1 
-ATOM   491  C  CG   . LEU M  1 36  ? 137.534 95.304  68.916 1.00 3.08  35  M 1 
-ATOM   492  C  CD1  . LEU M  1 36  ? 136.553 94.968  70.028 1.00 3.08  35  M 1 
-ATOM   493  C  CD2  . LEU M  1 36  ? 136.903 95.067  67.564 1.00 3.08  35  M 1 
-ATOM   494  H  H    . LEU M  1 36  ? 138.894 98.952  69.598 1.00 3.08  35  M 1 
-ATOM   495  H  HA   . LEU M  1 36  ? 138.158 96.956  71.088 1.00 3.08  35  M 1 
-ATOM   496  H  HB2  . LEU M  1 36  ? 137.216 97.310  68.970 1.00 3.08  35  M 1 
-ATOM   497  H  HB3  . LEU M  1 36  ? 138.587 96.937  68.292 1.00 3.08  35  M 1 
-ATOM   498  H  HG   . LEU M  1 36  ? 138.295 94.706  68.982 1.00 3.08  35  M 1 
-ATOM   499  H  HD11 . LEU M  1 36  ? 136.178 94.088  69.867 1.00 3.08  35  M 1 
-ATOM   500  H  HD12 . LEU M  1 36  ? 137.019 94.970  70.879 1.00 3.08  35  M 1 
-ATOM   501  H  HD13 . LEU M  1 36  ? 135.843 95.629  70.043 1.00 3.08  35  M 1 
-ATOM   502  H  HD21 . LEU M  1 36  ? 136.535 94.170  67.543 1.00 3.08  35  M 1 
-ATOM   503  H  HD22 . LEU M  1 36  ? 136.197 95.717  67.423 1.00 3.08  35  M 1 
-ATOM   504  H  HD23 . LEU M  1 36  ? 137.580 95.162  66.875 1.00 3.08  35  M 1 
-ATOM   505  N  N    . SER M  1 37  ? 141.069 96.611  69.816 1.00 3.69  36  M 1 
-ATOM   506  C  CA   . SER M  1 37  ? 142.323 95.872  69.937 1.00 3.69  36  M 1 
-ATOM   507  C  C    . SER M  1 37  ? 142.871 95.954  71.360 1.00 3.69  36  M 1 
-ATOM   508  O  O    . SER M  1 37  ? 143.339 94.957  71.924 1.00 3.69  36  M 1 
-ATOM   509  C  CB   . SER M  1 37  ? 143.339 96.419  68.940 1.00 3.69  36  M 1 
-ATOM   510  O  OG   . SER M  1 37  ? 144.559 95.726  69.033 1.00 3.69  36  M 1 
-ATOM   511  H  H    . SER M  1 37  ? 141.104 97.291  69.290 1.00 3.69  36  M 1 
-ATOM   512  H  HA   . SER M  1 37  ? 142.174 94.940  69.715 1.00 3.69  36  M 1 
-ATOM   513  H  HB2  . SER M  1 37  ? 142.982 96.331  68.042 1.00 3.69  36  M 1 
-ATOM   514  H  HB3  . SER M  1 37  ? 143.507 97.356  69.128 1.00 3.69  36  M 1 
-ATOM   515  H  HG   . SER M  1 37  ? 144.931 95.734  68.280 1.00 3.69  36  M 1 
-ATOM   516  N  N    . MET M  1 38  ? 142.811 97.145  71.956 1.00 3.57  37  M 1 
-ATOM   517  C  CA   . MET M  1 38  ? 143.243 97.312  73.342 1.00 3.57  37  M 1 
-ATOM   518  C  C    . MET M  1 38  ? 142.431 96.421  74.277 1.00 3.57  37  M 1 
-ATOM   519  O  O    . MET M  1 38  ? 142.984 95.719  75.141 1.00 3.57  37  M 1 
-ATOM   520  C  CB   . MET M  1 38  ? 143.122 98.784  73.749 1.00 3.57  37  M 1 
-ATOM   521  C  CG   . MET M  1 38  ? 144.133 99.719  73.108 1.00 3.57  37  M 1 
-ATOM   522  S  SD   . MET M  1 38  ? 143.865 101.435 73.612 1.00 3.57  37  M 1 
-ATOM   523  C  CE   . MET M  1 38  ? 145.135 102.271 72.672 1.00 3.57  37  M 1 
-ATOM   524  H  H    . MET M  1 38  ? 142.498 97.857  71.588 1.00 3.57  37  M 1 
-ATOM   525  H  HA   . MET M  1 38  ? 144.179 97.066  73.411 1.00 3.57  37  M 1 
-ATOM   526  H  HB2  . MET M  1 38  ? 142.236 99.102  73.516 1.00 3.57  37  M 1 
-ATOM   527  H  HB3  . MET M  1 38  ? 143.231 98.858  74.710 1.00 3.57  37  M 1 
-ATOM   528  H  HG2  . MET M  1 38  ? 145.022 99.457  73.394 1.00 3.57  37  M 1 
-ATOM   529  H  HG3  . MET M  1 38  ? 144.086 99.664  72.141 1.00 3.57  37  M 1 
-ATOM   530  H  HE1  . MET M  1 38  ? 145.182 103.200 72.947 1.00 3.57  37  M 1 
-ATOM   531  H  HE2  . MET M  1 38  ? 145.984 101.832 72.837 1.00 3.57  37  M 1 
-ATOM   532  H  HE3  . MET M  1 38  ? 144.920 102.220 71.728 1.00 3.57  37  M 1 
-ATOM   533  N  N    . SER M  1 39  ? 141.125 96.439  74.059 1.00 3.57  38  M 1 
-ATOM   534  C  CA   . SER M  1 39  ? 140.177 95.667  74.882 1.00 3.57  38  M 1 
-ATOM   535  C  C    . SER M  1 39  ? 140.572 94.195  74.781 1.00 3.57  38  M 1 
-ATOM   536  O  O    . SER M  1 39  ? 140.725 93.591  75.818 1.00 3.57  38  M 1 
-ATOM   537  C  CB   . SER M  1 39  ? 138.755 95.858  74.453 1.00 3.57  38  M 1 
-ATOM   538  O  OG   . SER M  1 39  ? 137.885 95.283  75.403 1.00 3.57  38  M 1 
-ATOM   539  H  H    . SER M  1 39  ? 140.739 96.797  73.317 1.00 3.57  38  M 1 
-ATOM   540  H  HA   . SER M  1 39  ? 140.271 95.958  75.829 1.00 3.57  38  M 1 
-ATOM   541  H  HB2  . SER M  1 39  ? 138.563 96.819  74.367 1.00 3.57  38  M 1 
-ATOM   542  H  HB3  . SER M  1 39  ? 138.616 95.434  73.576 1.00 3.57  38  M 1 
-ATOM   543  H  HG   . SER M  1 39  ? 138.336 95.071  76.086 1.00 3.57  38  M 1 
-ATOM   544  N  N    . CYS M  1 40  ? 140.888 93.717  73.583 1.00 4.32  39  M 1 
-ATOM   545  C  CA   . CYS M  1 40  ? 141.264 92.302  73.348 1.00 4.32  39  M 1 
-ATOM   546  C  C    . CYS M  1 40  ? 142.555 92.007  74.115 1.00 4.32  39  M 1 
-ATOM   547  O  O    . CYS M  1 40  ? 142.598 91.009  74.795 1.00 4.32  39  M 1 
-ATOM   548  C  CB   . CYS M  1 40  ? 141.449 92.000  71.865 1.00 4.32  39  M 1 
-ATOM   549  S  SG   . CYS M  1 40  ? 139.891 91.997  70.941 1.00 4.32  39  M 1 
-ATOM   550  H  H    . CYS M  1 40  ? 141.025 94.242  72.853 1.00 4.32  39  M 1 
-ATOM   551  H  HA   . CYS M  1 40  ? 140.545 91.729  73.700 1.00 4.32  39  M 1 
-ATOM   552  H  HB2  . CYS M  1 40  ? 142.044 92.671  71.472 1.00 4.32  39  M 1 
-ATOM   553  H  HB3  . CYS M  1 40  ? 141.874 91.124  71.765 1.00 4.32  39  M 1 
-ATOM   554  H  HG   . CYS M  1 40  ? 140.354 91.741  69.861 1.00 4.32  39  M 1 
-ATOM   555  N  N    . TYR M  1 41  ? 143.500 92.935  74.109 1.00 4.38  40  M 1 
-ATOM   556  C  CA   . TYR M  1 41  ? 144.808 92.747  74.775 1.00 4.38  40  M 1 
-ATOM   557  C  C    . TYR M  1 41  ? 144.627 92.543  76.279 1.00 4.38  40  M 1 
-ATOM   558  O  O    . TYR M  1 41  ? 145.227 91.640  76.793 1.00 4.38  40  M 1 
-ATOM   559  C  CB   . TYR M  1 41  ? 145.702 93.952  74.532 1.00 4.38  40  M 1 
-ATOM   560  C  CG   . TYR M  1 41  ? 147.002 93.889  75.275 1.00 4.38  40  M 1 
-ATOM   561  C  CD1  . TYR M  1 41  ? 148.056 93.128  74.805 1.00 4.38  40  M 1 
-ATOM   562  C  CD2  . TYR M  1 41  ? 147.181 94.611  76.438 1.00 4.38  40  M 1 
-ATOM   563  C  CE1  . TYR M  1 41  ? 149.266 93.079  75.479 1.00 4.38  40  M 1 
-ATOM   564  C  CE2  . TYR M  1 41  ? 148.382 94.574  77.123 1.00 4.38  40  M 1 
-ATOM   565  C  CZ   . TYR M  1 41  ? 149.423 93.798  76.649 1.00 4.38  40  M 1 
-ATOM   566  O  OH   . TYR M  1 41  ? 150.601 93.766  77.329 1.00 4.38  40  M 1 
-ATOM   567  H  H    . TYR M  1 41  ? 143.368 93.789  73.825 1.00 4.38  40  M 1 
-ATOM   568  H  HA   . TYR M  1 41  ? 145.245 91.942  74.397 1.00 4.38  40  M 1 
-ATOM   569  H  HB2  . TYR M  1 41  ? 145.886 94.017  73.571 1.00 4.38  40  M 1 
-ATOM   570  H  HB3  . TYR M  1 41  ? 145.218 94.761  74.802 1.00 4.38  40  M 1 
-ATOM   571  H  HD1  . TYR M  1 41  ? 147.951 92.633  74.009 1.00 4.38  40  M 1 
-ATOM   572  H  HD2  . TYR M  1 41  ? 146.475 95.140  76.771 1.00 4.38  40  M 1 
-ATOM   573  H  HE1  . TYR M  1 41  ? 149.973 92.549  75.150 1.00 4.38  40  M 1 
-ATOM   574  H  HE2  . TYR M  1 41  ? 148.487 95.066  77.920 1.00 4.38  40  M 1 
-ATOM   575  H  HH   . TYR M  1 41  ? 150.480 93.440  78.113 1.00 4.38  40  M 1 
-ATOM   576  N  N    . PHE M  1 42  ? 143.784 93.325  76.942 1.00 3.75  41  M 1 
-ATOM   577  C  CA   . PHE M  1 42  ? 143.626 93.250  78.424 1.00 3.75  41  M 1 
-ATOM   578  C  C    . PHE M  1 42  ? 142.893 91.962  78.827 1.00 3.75  41  M 1 
-ATOM   579  O  O    . PHE M  1 42  ? 142.921 91.650  79.995 1.00 3.75  41  M 1 
-ATOM   580  C  CB   . PHE M  1 42  ? 143.056 94.559  78.978 1.00 3.75  41  M 1 
-ATOM   581  C  CG   . PHE M  1 42  ? 144.075 95.668  78.885 1.00 3.75  41  M 1 
-ATOM   582  C  CD1  . PHE M  1 42  ? 145.167 95.702  79.740 1.00 3.75  41  M 1 
-ATOM   583  C  CD2  . PHE M  1 42  ? 144.003 96.615  77.879 1.00 3.75  41  M 1 
-ATOM   584  C  CE1  . PHE M  1 42  ? 146.147 96.675  79.609 1.00 3.75  41  M 1 
-ATOM   585  C  CE2  . PHE M  1 42  ? 144.963 97.613  77.774 1.00 3.75  41  M 1 
-ATOM   586  C  CZ   . PHE M  1 42  ? 146.039 97.634  78.626 1.00 3.75  41  M 1 
-ATOM   587  H  H    . PHE M  1 42  ? 143.184 93.883  76.545 1.00 3.75  41  M 1 
-ATOM   588  H  HA   . PHE M  1 42  ? 144.541 93.169  78.795 1.00 3.75  41  M 1 
-ATOM   589  H  HB2  . PHE M  1 42  ? 142.257 94.803  78.468 1.00 3.75  41  M 1 
-ATOM   590  H  HB3  . PHE M  1 42  ? 142.799 94.426  79.914 1.00 3.75  41  M 1 
-ATOM   591  H  HD1  . PHE M  1 42  ? 145.254 95.040  80.407 1.00 3.75  41  M 1 
-ATOM   592  H  HD2  . PHE M  1 42  ? 143.271 96.606  77.284 1.00 3.75  41  M 1 
-ATOM   593  H  HE1  . PHE M  1 42  ? 146.871 96.699  80.214 1.00 3.75  41  M 1 
-ATOM   594  H  HE2  . PHE M  1 42  ? 144.890 98.263  77.093 1.00 3.75  41  M 1 
-ATOM   595  H  HZ   . PHE M  1 42  ? 146.689 98.314  78.553 1.00 3.75  41  M 1 
-ATOM   596  N  N    . ASP M  1 43  ? 142.191 91.322  77.898 1.00 4.58  42  M 1 
-ATOM   597  C  CA   . ASP M  1 43  ? 141.473 90.038  78.080 1.00 4.58  42  M 1 
-ATOM   598  C  C    . ASP M  1 43  ? 142.425 88.840  77.923 1.00 4.58  42  M 1 
-ATOM   599  O  O    . ASP M  1 43  ? 142.006 87.752  78.194 1.00 4.58  42  M 1 
-ATOM   600  C  CB   . ASP M  1 43  ? 140.329 89.942  77.072 1.00 4.58  42  M 1 
-ATOM   601  C  CG   . ASP M  1 43  ? 139.568 88.639  77.147 1.00 4.58  42  M 1 
-ATOM   602  O  OD1  . ASP M  1 43  ? 139.070 88.323  78.243 1.00 4.58  42  M 1 
-ATOM   603  O  OD2  . ASP M  1 43  ? 139.491 87.950  76.115 1.00 4.58  42  M 1 
-ATOM   604  H  H    . ASP M  1 43  ? 142.065 91.654  77.065 1.00 4.58  42  M 1 
-ATOM   605  H  HA   . ASP M  1 43  ? 141.091 90.021  78.989 1.00 4.58  42  M 1 
-ATOM   606  H  HB2  . ASP M  1 43  ? 139.701 90.677  77.231 1.00 4.58  42  M 1 
-ATOM   607  H  HB3  . ASP M  1 43  ? 140.690 90.039  76.168 1.00 4.58  42  M 1 
-ATOM   608  N  N    . ARG M  1 44  ? 143.669 89.028  77.488 1.00 4.59  43  M 1 
-ATOM   609  C  CA   . ARG M  1 44  ? 144.629 87.906  77.341 1.00 4.59  43  M 1 
-ATOM   610  C  C    . ARG M  1 44  ? 144.872 87.264  78.707 1.00 4.59  43  M 1 
-ATOM   611  O  O    . ARG M  1 44  ? 144.960 87.979  79.676 1.00 4.59  43  M 1 
-ATOM   612  C  CB   . ARG M  1 44  ? 145.945 88.407  76.749 1.00 4.59  43  M 1 
-ATOM   613  C  CG   . ARG M  1 44  ? 145.842 88.780  75.285 1.00 4.59  43  M 1 
-ATOM   614  C  CD   . ARG M  1 44  ? 147.064 89.496  74.784 1.00 4.59  43  M 1 
-ATOM   615  N  NE   . ARG M  1 44  ? 148.304 88.846  75.136 1.00 4.59  43  M 1 
-ATOM   616  C  CZ   . ARG M  1 44  ? 149.445 89.019  74.482 1.00 4.59  43  M 1 
-ATOM   617  N  NH1  . ARG M  1 44  ? 149.498 89.823  73.439 1.00 4.59  43  M 1 
-ATOM   618  N  NH2  . ARG M  1 44  ? 150.530 88.386  74.877 1.00 4.59  43  M 1 
-ATOM   619  H  H    . ARG M  1 44  ? 144.027 89.832  77.290 1.00 4.59  43  M 1 
-ATOM   620  H  HA   . ARG M  1 44  ? 144.238 87.234  76.736 1.00 4.59  43  M 1 
-ATOM   621  H  HB2  . ARG M  1 44  ? 146.239 89.192  77.257 1.00 4.59  43  M 1 
-ATOM   622  H  HB3  . ARG M  1 44  ? 146.623 87.708  76.852 1.00 4.59  43  M 1 
-ATOM   623  H  HG2  . ARG M  1 44  ? 145.710 87.966  74.753 1.00 4.59  43  M 1 
-ATOM   624  H  HG3  . ARG M  1 44  ? 145.059 89.356  75.152 1.00 4.59  43  M 1 
-ATOM   625  H  HD2  . ARG M  1 44  ? 147.011 89.569  73.807 1.00 4.59  43  M 1 
-ATOM   626  H  HD3  . ARG M  1 44  ? 147.069 90.407  75.149 1.00 4.59  43  M 1 
-ATOM   627  H  HE   . ARG M  1 44  ? 148.305 88.305  75.821 1.00 4.59  43  M 1 
-ATOM   628  H  HH11 . ARG M  1 44  ? 148.775 90.249  73.178 1.00 4.59  43  M 1 
-ATOM   629  H  HH12 . ARG M  1 44  ? 150.258 89.935  73.012 1.00 4.59  43  M 1 
-ATOM   630  H  HH21 . ARG M  1 44  ? 150.499 87.850  75.555 1.00 4.59  43  M 1 
-ATOM   631  H  HH22 . ARG M  1 44  ? 151.285 88.501  74.438 1.00 4.59  43  M 1 
-ATOM   632  N  N    . ASP M  1 45  ? 145.103 85.958  78.766 1.00 4.97  44  M 1 
-ATOM   633  C  CA   . ASP M  1 45  ? 145.355 85.256  80.057 1.00 4.97  44  M 1 
-ATOM   634  C  C    . ASP M  1 45  ? 146.668 85.742  80.712 1.00 4.97  44  M 1 
-ATOM   635  O  O    . ASP M  1 45  ? 146.819 85.489  81.891 1.00 4.97  44  M 1 
-ATOM   636  C  CB   . ASP M  1 45  ? 145.349 83.739  79.894 1.00 4.97  44  M 1 
-ATOM   637  C  CG   . ASP M  1 45  ? 146.620 83.284  79.220 1.00 4.97  44  M 1 
-ATOM   638  O  OD1  . ASP M  1 45  ? 147.606 83.093  79.940 1.00 4.97  44  M 1 
-ATOM   639  O  OD2  . ASP M  1 45  ? 146.633 83.234  77.997 1.00 4.97  44  M 1 
-ATOM   640  H  H    . ASP M  1 45  ? 145.234 85.444  78.027 1.00 4.97  44  M 1 
-ATOM   641  H  HA   . ASP M  1 45  ? 144.615 85.487  80.666 1.00 4.97  44  M 1 
-ATOM   642  H  HB2  . ASP M  1 45  ? 145.279 83.310  80.771 1.00 4.97  44  M 1 
-ATOM   643  H  HB3  . ASP M  1 45  ? 144.582 83.466  79.350 1.00 4.97  44  M 1 
-ATOM   644  N  N    . ASP M  1 46  ? 147.649 86.258  79.969 1.00 4.81  45  M 1 
-ATOM   645  C  CA   . ASP M  1 46  ? 148.928 86.748  80.536 1.00 4.81  45  M 1 
-ATOM   646  C  C    . ASP M  1 46  ? 148.867 88.257  80.847 1.00 4.81  45  M 1 
-ATOM   647  O  O    . ASP M  1 46  ? 149.900 88.769  81.216 1.00 4.81  45  M 1 
-ATOM   648  C  CB   . ASP M  1 46  ? 150.117 86.389  79.649 1.00 4.81  45  M 1 
-ATOM   649  C  CG   . ASP M  1 46  ? 149.985 86.864  78.215 1.00 4.81  45  M 1 
-ATOM   650  O  OD1  . ASP M  1 46  ? 148.921 87.352  77.865 1.00 4.81  45  M 1 
-ATOM   651  O  OD2  . ASP M  1 46  ? 150.959 86.728  77.462 1.00 4.81  45  M 1 
-ATOM   652  H  H    . ASP M  1 46  ? 147.592 86.348  79.066 1.00 4.81  45  M 1 
-ATOM   653  H  HA   . ASP M  1 46  ? 149.061 86.277  81.392 1.00 4.81  45  M 1 
-ATOM   654  H  HB2  . ASP M  1 46  ? 150.928 86.785  80.029 1.00 4.81  45  M 1 
-ATOM   655  H  HB3  . ASP M  1 46  ? 150.227 85.417  79.642 1.00 4.81  45  M 1 
-ATOM   656  N  N    . VAL M  1 47  ? 147.711 88.919  80.748 1.00 4.20  46  M 1 
-ATOM   657  C  CA   . VAL M  1 47  ? 147.532 90.321  81.107 1.00 4.20  46  M 1 
-ATOM   658  C  C    . VAL M  1 47  ? 146.468 90.377  82.200 1.00 4.20  46  M 1 
-ATOM   659  O  O    . VAL M  1 47  ? 146.740 90.802  83.326 1.00 4.20  46  M 1 
-ATOM   660  C  CB   . VAL M  1 47  ? 147.159 91.167  79.874 1.00 4.20  46  M 1 
-ATOM   661  C  CG1  . VAL M  1 47  ? 146.894 92.607  80.267 1.00 4.20  46  M 1 
-ATOM   662  C  CG2  . VAL M  1 47  ? 148.260 91.084  78.816 1.00 4.20  46  M 1 
-ATOM   663  H  H    . VAL M  1 47  ? 146.975 88.546  80.505 1.00 4.20  46  M 1 
-ATOM   664  H  HA   . VAL M  1 47  ? 148.355 90.681  81.473 1.00 4.20  46  M 1 
-ATOM   665  H  HB   . VAL M  1 47  ? 146.348 90.817  79.473 1.00 4.20  46  M 1 
-ATOM   666  H  HG11 . VAL M  1 47  ? 146.844 93.141  79.459 1.00 4.20  46  M 1 
-ATOM   667  H  HG12 . VAL M  1 47  ? 146.053 92.662  80.747 1.00 4.20  46  M 1 
-ATOM   668  H  HG13 . VAL M  1 47  ? 147.615 92.937  80.825 1.00 4.20  46  M 1 
-ATOM   669  H  HG21 . VAL M  1 47  ? 148.056 91.680  78.078 1.00 4.20  46  M 1 
-ATOM   670  H  HG22 . VAL M  1 47  ? 149.110 91.329  79.214 1.00 4.20  46  M 1 
-ATOM   671  H  HG23 . VAL M  1 47  ? 148.314 90.176  78.480 1.00 4.20  46  M 1 
-ATOM   672  N  N    . ALA M  1 48  ? 145.252 89.939  81.871 1.00 4.09  47  M 1 
-ATOM   673  C  CA   . ALA M  1 48  ? 144.226 89.581  82.848 1.00 4.09  47  M 1 
-ATOM   674  C  C    . ALA M  1 48  ? 143.784 90.780  83.690 1.00 4.09  47  M 1 
-ATOM   675  O  O    . ALA M  1 48  ? 143.736 90.720  84.918 1.00 4.09  47  M 1 
-ATOM   676  C  CB   . ALA M  1 48  ? 144.712 88.431  83.733 1.00 4.09  47  M 1 
-ATOM   677  H  H    . ALA M  1 48  ? 144.982 89.848  81.060 1.00 4.09  47  M 1 
-ATOM   678  H  HA   . ALA M  1 48  ? 143.445 89.262  82.369 1.00 4.09  47  M 1 
-ATOM   679  H  HB1  . ALA M  1 48  ? 143.981 88.111  84.285 1.00 4.09  47  M 1 
-ATOM   680  H  HB2  . ALA M  1 48  ? 145.014 87.713  83.155 1.00 4.09  47  M 1 
-ATOM   681  H  HB3  . ALA M  1 48  ? 145.456 88.731  84.279 1.00 4.09  47  M 1 
-ATOM   682  N  N    . LEU M  1 49  ? 143.443 91.870  83.008 1.00 3.91  48  M 1 
-ATOM   683  C  CA   . LEU M  1 49  ? 142.931 93.101  83.616 1.00 3.91  48  M 1 
-ATOM   684  C  C    . LEU M  1 49  ? 141.549 93.386  83.022 1.00 3.91  48  M 1 
-ATOM   685  O  O    . LEU M  1 49  ? 141.416 94.075  82.011 1.00 3.91  48  M 1 
-ATOM   686  C  CB   . LEU M  1 49  ? 143.918 94.244  83.389 1.00 3.91  48  M 1 
-ATOM   687  C  CG   . LEU M  1 49  ? 145.258 94.024  84.111 1.00 3.91  48  M 1 
-ATOM   688  C  CD1  . LEU M  1 49  ? 146.322 95.005  83.680 1.00 3.91  48  M 1 
-ATOM   689  C  CD2  . LEU M  1 49  ? 145.071 94.083  85.631 1.00 3.91  48  M 1 
-ATOM   690  H  H    . LEU M  1 49  ? 143.516 91.927  82.153 1.00 3.91  48  M 1 
-ATOM   691  H  HA   . LEU M  1 49  ? 142.808 92.984  84.571 1.00 3.91  48  M 1 
-ATOM   692  H  HB2  . LEU M  1 49  ? 144.095 94.342  82.440 1.00 3.91  48  M 1 
-ATOM   693  H  HB3  . LEU M  1 49  ? 143.525 95.066  83.722 1.00 3.91  48  M 1 
-ATOM   694  H  HG   . LEU M  1 49  ? 145.595 93.140  83.896 1.00 3.91  48  M 1 
-ATOM   695  H  HD11 . LEU M  1 49  ? 147.187 94.570  83.732 1.00 3.91  48  M 1 
-ATOM   696  H  HD12 . LEU M  1 49  ? 146.165 95.292  82.767 1.00 3.91  48  M 1 
-ATOM   697  H  HD13 . LEU M  1 49  ? 146.309 95.769  84.278 1.00 3.91  48  M 1 
-ATOM   698  H  HD21 . LEU M  1 49  ? 145.899 94.367  86.048 1.00 3.91  48  M 1 
-ATOM   699  H  HD22 . LEU M  1 49  ? 144.367 94.712  85.853 1.00 3.91  48  M 1 
-ATOM   700  H  HD23 . LEU M  1 49  ? 144.830 93.201  85.954 1.00 3.91  48  M 1 
-ATOM   701  N  N    . LYS M  1 50  ? 140.522 92.794  83.640 1.00 4.48  49  M 1 
-ATOM   702  C  CA   . LYS M  1 50  ? 139.116 92.801  83.147 1.00 4.48  49  M 1 
-ATOM   703  C  C    . LYS M  1 50  ? 138.529 94.213  83.070 1.00 4.48  49  M 1 
-ATOM   704  O  O    . LYS M  1 50  ? 137.806 94.487  82.119 1.00 4.48  49  M 1 
-ATOM   705  C  CB   . LYS M  1 50  ? 138.251 91.891  84.020 1.00 4.48  49  M 1 
-ATOM   706  C  CG   . LYS M  1 50  ? 138.716 90.445  84.052 1.00 4.48  49  M 1 
-ATOM   707  C  CD   . LYS M  1 50  ? 137.781 89.541  84.839 1.00 4.48  49  M 1 
-ATOM   708  C  CE   . LYS M  1 50  ? 138.133 88.076  84.693 1.00 4.48  49  M 1 
-ATOM   709  N  NZ   . LYS M  1 50  ? 136.916 87.233  84.702 1.00 4.48  49  M 1 
-ATOM   710  H  H    . LYS M  1 50  ? 140.604 92.440  84.474 1.00 4.48  49  M 1 
-ATOM   711  H  HA   . LYS M  1 50  ? 139.122 92.429  82.235 1.00 4.48  49  M 1 
-ATOM   712  H  HB2  . LYS M  1 50  ? 138.251 92.242  84.935 1.00 4.48  49  M 1 
-ATOM   713  H  HB3  . LYS M  1 50  ? 137.331 91.918  83.686 1.00 4.48  49  M 1 
-ATOM   714  H  HG2  . LYS M  1 50  ? 138.785 90.113  83.132 1.00 4.48  49  M 1 
-ATOM   715  H  HG3  . LYS M  1 50  ? 139.611 90.408  84.454 1.00 4.48  49  M 1 
-ATOM   716  H  HD2  . LYS M  1 50  ? 137.820 89.785  85.789 1.00 4.48  49  M 1 
-ATOM   717  H  HD3  . LYS M  1 50  ? 136.861 89.680  84.528 1.00 4.48  49  M 1 
-ATOM   718  H  HE2  . LYS M  1 50  ? 138.613 87.935  83.854 1.00 4.48  49  M 1 
-ATOM   719  H  HE3  . LYS M  1 50  ? 138.716 87.803  85.427 1.00 4.48  49  M 1 
-ATOM   720  H  HZ1  . LYS M  1 50  ? 137.138 86.370  84.536 1.00 4.48  49  M 1 
-ATOM   721  H  HZ2  . LYS M  1 50  ? 136.512 87.285  85.513 1.00 4.48  49  M 1 
-ATOM   722  H  HZ3  . LYS M  1 50  ? 136.338 87.519  84.064 1.00 4.48  49  M 1 
-ATOM   723  N  N    . ASN M  1 51  ? 138.832 95.061  84.037 1.00 4.04  50  M 1 
-ATOM   724  C  CA   . ASN M  1 51  ? 138.313 96.445  84.094 1.00 4.04  50  M 1 
-ATOM   725  C  C    . ASN M  1 51  ? 138.979 97.259  82.986 1.00 4.04  50  M 1 
-ATOM   726  O  O    . ASN M  1 51  ? 138.313 98.120  82.470 1.00 4.04  50  M 1 
-ATOM   727  C  CB   . ASN M  1 51  ? 138.358 97.030  85.502 1.00 4.04  50  M 1 
-ATOM   728  C  CG   . ASN M  1 51  ? 137.360 96.332  86.403 1.00 4.04  50  M 1 
-ATOM   729  O  OD1  . ASN M  1 51  ? 136.337 95.857  85.933 1.00 4.04  50  M 1 
-ATOM   730  N  ND2  . ASN M  1 51  ? 137.675 96.201  87.674 1.00 4.04  50  M 1 
-ATOM   731  H  H    . ASN M  1 51  ? 139.425 94.854  84.696 1.00 4.04  50  M 1 
-ATOM   732  H  HA   . ASN M  1 51  ? 137.356 96.389  83.863 1.00 4.04  50  M 1 
-ATOM   733  H  HB2  . ASN M  1 51  ? 139.259 96.924  85.868 1.00 4.04  50  M 1 
-ATOM   734  H  HB3  . ASN M  1 51  ? 138.149 97.986  85.462 1.00 4.04  50  M 1 
-ATOM   735  H  HD21 . ASN M  1 51  ? 138.442 96.521  87.975 1.00 4.04  50  M 1 
-ATOM   736  H  HD22 . ASN M  1 51  ? 137.119 95.793  88.228 1.00 4.04  50  M 1 
-ATOM   737  N  N    . PHE M  1 52  ? 140.264 97.074  82.697 1.00 3.78  51  M 1 
-ATOM   738  C  CA   . PHE M  1 52  ? 140.889 97.787  81.553 1.00 3.78  51  M 1 
-ATOM   739  C  C    . PHE M  1 52  ? 140.179 97.325  80.269 1.00 3.78  51  M 1 
-ATOM   740  O  O    . PHE M  1 52  ? 139.787 98.165  79.473 1.00 3.78  51  M 1 
-ATOM   741  C  CB   . PHE M  1 52  ? 142.386 97.523  81.457 1.00 3.78  51  M 1 
-ATOM   742  C  CG   . PHE M  1 52  ? 143.231 98.417  82.334 1.00 3.78  51  M 1 
-ATOM   743  C  CD1  . PHE M  1 52  ? 143.460 98.114  83.666 1.00 3.78  51  M 1 
-ATOM   744  C  CD2  . PHE M  1 52  ? 143.836 99.549  81.815 1.00 3.78  51  M 1 
-ATOM   745  C  CE1  . PHE M  1 52  ? 144.276 98.921  84.452 1.00 3.78  51  M 1 
-ATOM   746  C  CE2  . PHE M  1 52  ? 144.649 100.353 82.597 1.00 3.78  51  M 1 
-ATOM   747  C  CZ   . PHE M  1 52  ? 144.872 100.031 83.914 1.00 3.78  51  M 1 
-ATOM   748  H  H    . PHE M  1 52  ? 140.864 96.663  83.243 1.00 3.78  51  M 1 
-ATOM   749  H  HA   . PHE M  1 52  ? 140.741 98.761  81.665 1.00 3.78  51  M 1 
-ATOM   750  H  HB2  . PHE M  1 52  ? 142.552 96.589  81.703 1.00 3.78  51  M 1 
-ATOM   751  H  HB3  . PHE M  1 52  ? 142.662 97.640  80.524 1.00 3.78  51  M 1 
-ATOM   752  H  HD1  . PHE M  1 52  ? 143.069 97.340  84.040 1.00 3.78  51  M 1 
-ATOM   753  H  HD2  . PHE M  1 52  ? 143.705 99.767  80.906 1.00 3.78  51  M 1 
-ATOM   754  H  HE1  . PHE M  1 52  ? 144.419 98.703  85.359 1.00 3.78  51  M 1 
-ATOM   755  H  HE2  . PHE M  1 52  ? 145.049 101.123 82.225 1.00 3.78  51  M 1 
-ATOM   756  H  HZ   . PHE M  1 52  ? 145.407 100.591 84.454 1.00 3.78  51  M 1 
-ATOM   757  N  N    . ALA M  1 53  ? 139.908 96.025  80.142 1.00 3.65  52  M 1 
-ATOM   758  C  CA   . ALA M  1 53  ? 139.238 95.471  78.940 1.00 3.65  52  M 1 
-ATOM   759  C  C    . ALA M  1 53  ? 137.855 96.116  78.772 1.00 3.65  52  M 1 
-ATOM   760  O  O    . ALA M  1 53  ? 137.594 96.572  77.712 1.00 3.65  52  M 1 
-ATOM   761  C  CB   . ALA M  1 53  ? 139.126 93.973  79.054 1.00 3.65  52  M 1 
-ATOM   762  H  H    . ALA M  1 53  ? 139.978 95.422  80.819 1.00 3.65  52  M 1 
-ATOM   763  H  HA   . ALA M  1 53  ? 139.784 95.690  78.148 1.00 3.65  52  M 1 
-ATOM   764  H  HB1  . ALA M  1 53  ? 138.698 93.617  78.257 1.00 3.65  52  M 1 
-ATOM   765  H  HB2  . ALA M  1 53  ? 140.013 93.587  79.145 1.00 3.65  52  M 1 
-ATOM   766  H  HB3  . ALA M  1 53  ? 138.593 93.746  79.835 1.00 3.65  52  M 1 
-ATOM   767  N  N    . LYS M  1 54  ? 137.059 96.217  79.827 1.00 4.07  53  M 1 
-ATOM   768  C  CA   . LYS M  1 54  ? 135.720 96.798  79.806 1.00 4.07  53  M 1 
-ATOM   769  C  C    . LYS M  1 54  ? 135.766 98.273  79.442 1.00 4.07  53  M 1 
-ATOM   770  O  O    . LYS M  1 54  ? 134.953 98.751  78.641 1.00 4.07  53  M 1 
-ATOM   771  C  CB   . LYS M  1 54  ? 135.038 96.601  81.160 1.00 4.07  53  M 1 
-ATOM   772  C  CG   . LYS M  1 54  ? 134.600 95.184  81.418 1.00 4.07  53  M 1 
-ATOM   773  C  CD   . LYS M  1 54  ? 133.912 95.041  82.759 1.00 4.07  53  M 1 
-ATOM   774  C  CE   . LYS M  1 54  ? 133.444 93.611  82.976 1.00 4.07  53  M 1 
-ATOM   775  N  NZ   . LYS M  1 54  ? 132.778 93.456  84.294 1.00 4.07  53  M 1 
-ATOM   776  H  H    . LYS M  1 54  ? 137.302 95.910  80.593 1.00 4.07  53  M 1 
-ATOM   777  H  HA   . LYS M  1 54  ? 135.183 96.335  79.144 1.00 4.07  53  M 1 
-ATOM   778  H  HB2  . LYS M  1 54  ? 135.659 96.855  81.860 1.00 4.07  53  M 1 
-ATOM   779  H  HB3  . LYS M  1 54  ? 134.249 97.163  81.211 1.00 4.07  53  M 1 
-ATOM   780  H  HG2  . LYS M  1 54  ? 133.980 94.913  80.723 1.00 4.07  53  M 1 
-ATOM   781  H  HG3  . LYS M  1 54  ? 135.371 94.596  81.413 1.00 4.07  53  M 1 
-ATOM   782  H  HD2  . LYS M  1 54  ? 134.544 95.254  83.463 1.00 4.07  53  M 1 
-ATOM   783  H  HD3  . LYS M  1 54  ? 133.151 95.641  82.799 1.00 4.07  53  M 1 
-ATOM   784  H  HE2  . LYS M  1 54  ? 132.810 93.380  82.279 1.00 4.07  53  M 1 
-ATOM   785  H  HE3  . LYS M  1 54  ? 134.202 93.006  82.939 1.00 4.07  53  M 1 
-ATOM   786  H  HZ1  . LYS M  1 54  ? 132.343 92.681  84.331 1.00 4.07  53  M 1 
-ATOM   787  H  HZ2  . LYS M  1 54  ? 133.386 93.475  84.944 1.00 4.07  53  M 1 
-ATOM   788  H  HZ3  . LYS M  1 54  ? 132.201 94.122  84.421 1.00 4.07  53  M 1 
-ATOM   789  N  N    . TYR M  1 55  ? 136.721 99.003  80.017 1.00 3.64  54  M 1 
-ATOM   790  C  CA   . TYR M  1 55  ? 136.889 100.416 79.716 1.00 3.64  54  M 1 
-ATOM   791  C  C    . TYR M  1 55  ? 137.089 100.630 78.223 1.00 3.64  54  M 1 
-ATOM   792  O  O    . TYR M  1 55  ? 136.367 101.408 77.587 1.00 3.64  54  M 1 
-ATOM   793  C  CB   . TYR M  1 55  ? 138.079 100.968 80.500 1.00 3.64  54  M 1 
-ATOM   794  C  CG   . TYR M  1 55  ? 138.327 102.435 80.293 1.00 3.64  54  M 1 
-ATOM   795  C  CD1  . TYR M  1 55  ? 137.546 103.371 80.930 1.00 3.64  54  M 1 
-ATOM   796  C  CD2  . TYR M  1 55  ? 139.335 102.885 79.461 1.00 3.64  54  M 1 
-ATOM   797  C  CE1  . TYR M  1 55  ? 137.758 104.712 80.757 1.00 3.64  54  M 1 
-ATOM   798  C  CE2  . TYR M  1 55  ? 139.557 104.229 79.278 1.00 3.64  54  M 1 
-ATOM   799  C  CZ   . TYR M  1 55  ? 138.761 105.141 79.932 1.00 3.64  54  M 1 
-ATOM   800  O  OH   . TYR M  1 55  ? 138.958 106.493 79.769 1.00 3.64  54  M 1 
-ATOM   801  H  H    . TYR M  1 55  ? 137.298 98.689  80.572 1.00 3.64  54  M 1 
-ATOM   802  H  HA   . TYR M  1 55  ? 136.094 100.896 79.997 1.00 3.64  54  M 1 
-ATOM   803  H  HB2  . TYR M  1 55  ? 137.905 100.843 81.446 1.00 3.64  54  M 1 
-ATOM   804  H  HB3  . TYR M  1 55  ? 138.884 100.486 80.254 1.00 3.64  54  M 1 
-ATOM   805  H  HD1  . TYR M  1 55  ? 136.866 103.082 81.495 1.00 3.64  54  M 1 
-ATOM   806  H  HD2  . TYR M  1 55  ? 139.873 102.270 79.017 1.00 3.64  54  M 1 
-ATOM   807  H  HE1  . TYR M  1 55  ? 137.219 105.326 81.201 1.00 3.64  54  M 1 
-ATOM   808  H  HE2  . TYR M  1 55  ? 140.238 104.516 78.714 1.00 3.64  54  M 1 
-ATOM   809  H  HH   . TYR M  1 55  ? 139.605 106.634 79.252 1.00 3.64  54  M 1 
-ATOM   810  N  N    . PHE M  1 56  ? 138.045 99.916  77.638 1.00 3.26  55  M 1 
-ATOM   811  C  CA   . PHE M  1 56  ? 138.361 100.183 76.241 1.00 3.26  55  M 1 
-ATOM   812  C  C    . PHE M  1 56  ? 137.272 99.657  75.307 1.00 3.26  55  M 1 
-ATOM   813  O  O    . PHE M  1 56  ? 137.034 100.239 74.247 1.00 3.26  55  M 1 
-ATOM   814  C  CB   . PHE M  1 56  ? 139.732 99.626  75.871 1.00 3.26  55  M 1 
-ATOM   815  C  CG   . PHE M  1 56  ? 140.876 100.339 76.545 1.00 3.26  55  M 1 
-ATOM   816  C  CD1  . PHE M  1 56  ? 141.155 101.654 76.234 1.00 3.26  55  M 1 
-ATOM   817  C  CD2  . PHE M  1 56  ? 141.736 99.677  77.390 1.00 3.26  55  M 1 
-ATOM   818  C  CE1  . PHE M  1 56  ? 142.198 102.309 76.825 1.00 3.26  55  M 1 
-ATOM   819  C  CE2  . PHE M  1 56  ? 142.796 100.338 77.966 1.00 3.26  55  M 1 
-ATOM   820  C  CZ   . PHE M  1 56  ? 143.023 101.646 77.678 1.00 3.26  55  M 1 
-ATOM   821  H  H    . PHE M  1 56  ? 138.498 99.287  78.010 1.00 3.26  55  M 1 
-ATOM   822  H  HA   . PHE M  1 56  ? 138.401 101.145 76.120 1.00 3.26  55  M 1 
-ATOM   823  H  HB2  . PHE M  1 56  ? 139.762 98.690  76.124 1.00 3.26  55  M 1 
-ATOM   824  H  HB3  . PHE M  1 56  ? 139.856 99.697  74.912 1.00 3.26  55  M 1 
-ATOM   825  H  HD1  . PHE M  1 56  ? 140.589 102.126 75.666 1.00 3.26  55  M 1 
-ATOM   826  H  HD2  . PHE M  1 56  ? 141.590 98.782  77.595 1.00 3.26  55  M 1 
-ATOM   827  H  HE1  . PHE M  1 56  ? 142.360 103.203 76.628 1.00 3.26  55  M 1 
-ATOM   828  H  HE2  . PHE M  1 56  ? 143.367 99.891  78.548 1.00 3.26  55  M 1 
-ATOM   829  H  HZ   . PHE M  1 56  ? 143.739 102.093 78.069 1.00 3.26  55  M 1 
-ATOM   830  N  N    . LEU M  1 57  ? 136.563 98.594  75.692 1.00 3.56  56  M 1 
-ATOM   831  C  CA   . LEU M  1 57  ? 135.447 98.132  74.871 1.00 3.56  56  M 1 
-ATOM   832  C  C    . LEU M  1 57  ? 134.337 99.173  74.852 1.00 3.56  56  M 1 
-ATOM   833  O  O    . LEU M  1 57  ? 133.737 99.449  73.801 1.00 3.56  56  M 1 
-ATOM   834  C  CB   . LEU M  1 57  ? 134.908 96.802  75.395 1.00 3.56  56  M 1 
-ATOM   835  C  CG   . LEU M  1 57  ? 133.841 96.119  74.535 1.00 3.56  56  M 1 
-ATOM   836  C  CD1  . LEU M  1 57  ? 134.418 95.725  73.192 1.00 3.56  56  M 1 
-ATOM   837  C  CD2  . LEU M  1 57  ? 133.244 94.918  75.242 1.00 3.56  56  M 1 
-ATOM   838  H  H    . LEU M  1 57  ? 136.694 98.147  76.415 1.00 3.56  56  M 1 
-ATOM   839  H  HA   . LEU M  1 57  ? 135.769 97.997  73.966 1.00 3.56  56  M 1 
-ATOM   840  H  HB2  . LEU M  1 57  ? 135.644 96.179  75.496 1.00 3.56  56  M 1 
-ATOM   841  H  HB3  . LEU M  1 57  ? 134.506 96.958  76.264 1.00 3.56  56  M 1 
-ATOM   842  H  HG   . LEU M  1 57  ? 133.119 96.743  74.361 1.00 3.56  56  M 1 
-ATOM   843  H  HD11 . LEU M  1 57  ? 133.810 95.111  72.751 1.00 3.56  56  M 1 
-ATOM   844  H  HD12 . LEU M  1 57  ? 134.521 96.524  72.652 1.00 3.56  56  M 1 
-ATOM   845  H  HD13 . LEU M  1 57  ? 135.280 95.300  73.323 1.00 3.56  56  M 1 
-ATOM   846  H  HD21 . LEU M  1 57  ? 132.555 94.538  74.675 1.00 3.56  56  M 1 
-ATOM   847  H  HD22 . LEU M  1 57  ? 133.937 94.258  75.403 1.00 3.56  56  M 1 
-ATOM   848  H  HD23 . LEU M  1 57  ? 132.855 95.206  76.083 1.00 3.56  56  M 1 
-ATOM   849  N  N    . HIS M  1 58  ? 134.052 99.759  76.015 1.00 3.86  57  M 1 
-ATOM   850  C  CA   . HIS M  1 58  ? 133.085 100.842 76.095 1.00 3.86  57  M 1 
-ATOM   851  C  C    . HIS M  1 58  ? 133.498 102.006 75.206 1.00 3.86  57  M 1 
-ATOM   852  O  O    . HIS M  1 58  ? 132.668 102.593 74.502 1.00 3.86  57  M 1 
-ATOM   853  C  CB   . HIS M  1 58  ? 132.940 101.305 77.539 1.00 3.86  57  M 1 
-ATOM   854  C  CG   . HIS M  1 58  ? 131.986 102.439 77.703 1.00 3.86  57  M 1 
-ATOM   855  N  ND1  . HIS M  1 58  ? 130.619 102.276 77.663 1.00 3.86  57  M 1 
-ATOM   856  C  CD2  . HIS M  1 58  ? 132.202 103.764 77.863 1.00 3.86  57  M 1 
-ATOM   857  C  CE1  . HIS M  1 58  ? 130.035 103.449 77.821 1.00 3.86  57  M 1 
-ATOM   858  N  NE2  . HIS M  1 58  ? 130.974 104.369 77.942 1.00 3.86  57  M 1 
-ATOM   859  H  H    . HIS M  1 58  ? 134.418 99.555  76.766 1.00 3.86  57  M 1 
-ATOM   860  H  HA   . HIS M  1 58  ? 132.222 100.514 75.798 1.00 3.86  57  M 1 
-ATOM   861  H  HB2  . HIS M  1 58  ? 132.604 100.567 78.072 1.00 3.86  57  M 1 
-ATOM   862  H  HB3  . HIS M  1 58  ? 133.803 101.589 77.879 1.00 3.86  57  M 1 
-ATOM   863  H  HD2  . HIS M  1 58  ? 133.029 104.185 77.920 1.00 3.86  57  M 1 
-ATOM   864  H  HE1  . HIS M  1 58  ? 129.118 103.603 77.835 1.00 3.86  57  M 1 
-ATOM   865  H  HE2  . HIS M  1 58  ? 130.840 105.212 78.049 1.00 3.86  57  M 1 
-ATOM   866  N  N    . GLN M  1 59  ? 134.786 102.339 75.238 1.00 3.55  58  M 1 
-ATOM   867  C  CA   . GLN M  1 59  ? 135.333 103.431 74.394 1.00 3.55  58  M 1 
-ATOM   868  C  C    . GLN M  1 59  ? 135.113 103.056 72.914 1.00 3.55  58  M 1 
-ATOM   869  O  O    . GLN M  1 59  ? 134.716 103.896 72.159 1.00 3.55  58  M 1 
-ATOM   870  C  CB   . GLN M  1 59  ? 136.821 103.672 74.668 1.00 3.55  58  M 1 
-ATOM   871  C  CG   . GLN M  1 59  ? 137.147 104.192 76.061 1.00 3.55  58  M 1 
-ATOM   872  C  CD   . GLN M  1 59  ? 136.194 105.252 76.544 1.00 3.55  58  M 1 
-ATOM   873  O  OE1  . GLN M  1 59  ? 135.612 105.142 77.613 1.00 3.55  58  M 1 
-ATOM   874  N  NE2  . GLN M  1 59  ? 136.019 106.291 75.759 1.00 3.55  58  M 1 
-ATOM   875  H  H    . GLN M  1 59  ? 135.416 101.843 75.668 1.00 3.55  58  M 1 
-ATOM   876  H  HA   . GLN M  1 59  ? 134.834 104.257 74.591 1.00 3.55  58  M 1 
-ATOM   877  H  HB2  . GLN M  1 59  ? 137.298 102.828 74.527 1.00 3.55  58  M 1 
-ATOM   878  H  HB3  . GLN M  1 59  ? 137.153 104.314 74.006 1.00 3.55  58  M 1 
-ATOM   879  H  HG2  . GLN M  1 59  ? 137.133 103.442 76.693 1.00 3.55  58  M 1 
-ATOM   880  H  HG3  . GLN M  1 59  ? 138.056 104.561 76.058 1.00 3.55  58  M 1 
-ATOM   881  H  HE21 . GLN M  1 59  ? 135.434 106.916 75.978 1.00 3.55  58  M 1 
-ATOM   882  H  HE22 . GLN M  1 59  ? 136.486 106.365 75.013 1.00 3.55  58  M 1 
-ATOM   883  N  N    . SER M  1 60  ? 135.331 101.813 72.512 1.00 3.24  59  M 1 
-ATOM   884  C  CA   . SER M  1 60  ? 135.143 101.390 71.126 1.00 3.24  59  M 1 
-ATOM   885  C  C    . SER M  1 60  ? 133.699 101.592 70.690 1.00 3.24  59  M 1 
-ATOM   886  O  O    . SER M  1 60  ? 133.420 102.123 69.604 1.00 3.24  59  M 1 
-ATOM   887  C  CB   . SER M  1 60  ? 135.541 99.924  70.959 1.00 3.24  59  M 1 
-ATOM   888  O  OG   . SER M  1 60  ? 135.301 99.505  69.637 1.00 3.24  59  M 1 
-ATOM   889  H  H    . SER M  1 60  ? 135.602 101.192 73.042 1.00 3.24  59  M 1 
-ATOM   890  H  HA   . SER M  1 60  ? 135.722 101.916 70.552 1.00 3.24  59  M 1 
-ATOM   891  H  HB2  . SER M  1 60  ? 136.482 99.810  71.163 1.00 3.24  59  M 1 
-ATOM   892  H  HB3  . SER M  1 60  ? 135.013 99.373  71.558 1.00 3.24  59  M 1 
-ATOM   893  H  HG   . SER M  1 60  ? 136.017 99.537  69.199 1.00 3.24  59  M 1 
-ATOM   894  N  N    . HIS M  1 61  ? 132.766 101.182 71.545 1.00 3.61  60  M 1 
-ATOM   895  C  CA   . HIS M  1 61  ? 131.351 101.333 71.224 1.00 3.61  60  M 1 
-ATOM   896  C  C    . HIS M  1 61  ? 130.969 102.807 71.111 1.00 3.61  60  M 1 
-ATOM   897  O  O    . HIS M  1 61  ? 130.209 103.194 70.212 1.00 3.61  60  M 1 
-ATOM   898  C  CB   . HIS M  1 61  ? 130.503 100.619 72.274 1.00 3.61  60  M 1 
-ATOM   899  C  CG   . HIS M  1 61  ? 130.658 99.131  72.259 1.00 3.61  60  M 1 
-ATOM   900  N  ND1  . HIS M  1 61  ? 130.123 98.316  73.233 1.00 3.61  60  M 1 
-ATOM   901  C  CD2  . HIS M  1 61  ? 131.295 98.310  71.392 1.00 3.61  60  M 1 
-ATOM   902  C  CE1  . HIS M  1 61  ? 130.422 97.058  72.962 1.00 3.61  60  M 1 
-ATOM   903  N  NE2  . HIS M  1 61  ? 131.131 97.028  71.850 1.00 3.61  60  M 1 
-ATOM   904  H  H    . HIS M  1 61  ? 132.932 100.839 72.316 1.00 3.61  60  M 1 
-ATOM   905  H  HA   . HIS M  1 61  ? 131.177 100.924 70.362 1.00 3.61  60  M 1 
-ATOM   906  H  HB2  . HIS M  1 61  ? 130.749 100.941 73.155 1.00 3.61  60  M 1 
-ATOM   907  H  HB3  . HIS M  1 61  ? 129.567 100.820 72.116 1.00 3.61  60  M 1 
-ATOM   908  H  HD2  . HIS M  1 61  ? 131.758 98.559  70.625 1.00 3.61  60  M 1 
-ATOM   909  H  HE1  . HIS M  1 61  ? 130.179 96.315  73.466 1.00 3.61  60  M 1 
-ATOM   910  H  HE2  . HIS M  1 61  ? 131.444 96.322  71.471 1.00 3.61  60  M 1 
-ATOM   911  N  N    . GLU M  1 62  ? 131.505 103.647 71.997 1.00 3.84  61  M 1 
-ATOM   912  C  CA   . GLU M  1 62  ? 131.212 105.075 71.925 1.00 3.84  61  M 1 
-ATOM   913  C  C    . GLU M  1 62  ? 131.729 105.689 70.628 1.00 3.84  61  M 1 
-ATOM   914  O  O    . GLU M  1 62  ? 131.069 106.546 70.032 1.00 3.84  61  M 1 
-ATOM   915  C  CB   . GLU M  1 62  ? 131.806 105.801 73.132 1.00 3.84  61  M 1 
-ATOM   916  C  CG   . GLU M  1 62  ? 131.117 105.507 74.458 1.00 3.84  61  M 1 
-ATOM   917  C  CD   . GLU M  1 62  ? 129.702 106.056 74.531 1.00 3.84  61  M 1 
-ATOM   918  O  OE1  . GLU M  1 62  ? 129.434 107.105 73.910 1.00 3.84  61  M 1 
-ATOM   919  O  OE2  . GLU M  1 62  ? 128.856 105.440 75.213 1.00 3.84  61  M 1 
-ATOM   920  H  H    . GLU M  1 62  ? 132.043 103.424 72.630 1.00 3.84  61  M 1 
-ATOM   921  H  HA   . GLU M  1 62  ? 130.249 105.187 71.946 1.00 3.84  61  M 1 
-ATOM   922  H  HB2  . GLU M  1 62  ? 132.737 105.543 73.223 1.00 3.84  61  M 1 
-ATOM   923  H  HB3  . GLU M  1 62  ? 131.758 106.757 72.975 1.00 3.84  61  M 1 
-ATOM   924  H  HG2  . GLU M  1 62  ? 131.068 104.548 74.594 1.00 3.84  61  M 1 
-ATOM   925  H  HG3  . GLU M  1 62  ? 131.631 105.913 75.173 1.00 3.84  61  M 1 
-ATOM   926  N  N    . GLU M  1 63  ? 132.904 105.264 70.167 1.00 3.87  62  M 1 
-ATOM   927  C  CA   . GLU M  1 63  ? 133.445 105.837 68.937 1.00 3.87  62  M 1 
-ATOM   928  C  C    . GLU M  1 63  ? 132.639 105.379 67.724 1.00 3.87  62  M 1 
-ATOM   929  O  O    . GLU M  1 63  ? 132.447 106.143 66.768 1.00 3.87  62  M 1 
-ATOM   930  C  CB   . GLU M  1 63  ? 134.923 105.479 68.779 1.00 3.87  62  M 1 
-ATOM   931  C  CG   . GLU M  1 63  ? 135.854 106.022 69.867 1.00 3.87  62  M 1 
-ATOM   932  C  CD   . GLU M  1 63  ? 135.896 107.537 69.978 1.00 3.87  62  M 1 
-ATOM   933  O  OE1  . GLU M  1 63  ? 135.774 108.240 68.963 1.00 3.87  62  M 1 
-ATOM   934  O  OE2  . GLU M  1 63  ? 136.035 108.032 71.115 1.00 3.87  62  M 1 
-ATOM   935  H  H    . GLU M  1 63  ? 133.388 104.654 70.533 1.00 3.87  62  M 1 
-ATOM   936  H  HA   . GLU M  1 63  ? 133.379 106.804 68.981 1.00 3.87  62  M 1 
-ATOM   937  H  HB2  . GLU M  1 63  ? 135.006 104.513 68.804 1.00 3.87  62  M 1 
-ATOM   938  H  HB3  . GLU M  1 63  ? 135.238 105.797 67.919 1.00 3.87  62  M 1 
-ATOM   939  H  HG2  . GLU M  1 63  ? 135.596 105.675 70.735 1.00 3.87  62  M 1 
-ATOM   940  H  HG3  . GLU M  1 63  ? 136.753 105.720 69.663 1.00 3.87  62  M 1 
-ATOM   941  N  N    . ARG M  1 64  ? 132.101 104.161 67.796 1.00 3.76  63  M 1 
-ATOM   942  C  CA   . ARG M  1 64  ? 131.222 103.585 66.708 1.00 3.76  63  M 1 
-ATOM   943  C  C    . ARG M  1 64  ? 129.982 104.548 66.721 1.00 3.76  63  M 1 
-ATOM   944  O  O    . ARG M  1 64  ? 129.586 104.978 65.656 1.00 3.76  63  M 1 
-ATOM   945  C  CB   . ARG M  1 64  ? 130.958 102.003 66.808 0.50 3.76  63  M 1 
-ATOM   946  C  CG   . ARG M  1 64  ? 129.868 101.512 65.865 0.50 3.76  63  M 1 
-ATOM   947  C  CD   . ARG M  1 64  ? 130.261 101.575 64.397 0.50 3.76  63  M 1 
-ATOM   948  N  NE   . ARG M  1 64  ? 130.583 100.261 63.843 0.50 3.76  63  M 1 
-ATOM   949  C  CZ   . ARG M  1 64  ? 129.698 99.402  63.345 0.50 3.76  63  M 1 
-ATOM   950  N  NH1  . ARG M  1 64  ? 130.106 98.233  62.883 0.50 3.76  63  M 1 
-ATOM   951  N  NH2  . ARG M  1 64  ? 128.413 99.701  63.309 0.50 3.76  63  M 1 
-ATOM   952  H  H    . ARG M  1 64  ? 132.146 103.647 68.546 1.00 3.76  63  M 1 
-ATOM   953  H  HA   . ARG M  1 64  ? 131.743 103.924 65.813 1.00 3.76  63  M 1 
-ATOM   954  H  HB2  . ARG M  1 64  ? 131.792 101.531 66.603 0.50 3.76  63  M 1 
-ATOM   955  H  HB3  . ARG M  1 64  ? 130.704 101.784 67.729 0.50 3.76  63  M 1 
-ATOM   956  H  HG2  . ARG M  1 64  ? 129.643 100.585 66.092 0.50 3.76  63  M 1 
-ATOM   957  H  HG3  . ARG M  1 64  ? 129.062 102.055 65.999 0.50 3.76  63  M 1 
-ATOM   958  H  HD2  . ARG M  1 64  ? 129.523 101.967 63.883 0.50 3.76  63  M 1 
-ATOM   959  H  HD3  . ARG M  1 64  ? 131.040 102.163 64.298 0.50 3.76  63  M 1 
-ATOM   960  H  HE   . ARG M  1 64  ? 131.419 100.014 63.850 0.50 3.76  63  M 1 
-ATOM   961  H  HH11 . ARG M  1 64  ? 130.961 98.028  62.902 0.50 3.76  63  M 1 
-ATOM   962  H  HH12 . ARG M  1 64  ? 129.522 97.667  62.549 0.50 3.76  63  M 1 
-ATOM   963  H  HH21 . ARG M  1 64  ? 128.135 100.477 63.619 0.50 3.76  63  M 1 
-ATOM   964  H  HH22 . ARG M  1 64  ? 127.838 99.124  62.975 0.50 3.76  63  M 1 
-ATOM   965  N  N    . GLU M  1 65  ? 129.447 104.893 67.887 1.00 4.14  64  M 1 
-ATOM   966  C  CA   . GLU M  1 65  ? 128.292 105.783 67.961 1.00 4.14  64  M 1 
-ATOM   967  C  C    . GLU M  1 65  ? 128.612 107.153 67.371 1.00 4.14  64  M 1 
-ATOM   968  O  O    . GLU M  1 65  ? 127.777 107.746 66.678 1.00 4.14  64  M 1 
-ATOM   969  C  CB   . GLU M  1 65  ? 127.806 105.917 69.404 1.00 4.14  64  M 1 
-ATOM   970  C  CG   . GLU M  1 65  ? 127.215 104.648 70.011 1.00 4.14  64  M 1 
-ATOM   971  C  CD   . GLU M  1 65  ? 126.815 104.819 71.470 1.00 4.14  64  M 1 
-ATOM   972  O  OE1  . GLU M  1 65  ? 127.167 105.858 72.067 1.00 4.14  64  M 1 
-ATOM   973  O  OE2  . GLU M  1 65  ? 126.168 103.907 72.026 1.00 4.14  64  M 1 
-ATOM   974  H  H    . GLU M  1 65  ? 129.750 104.624 68.646 1.00 4.14  64  M 1 
-ATOM   975  H  HA   . GLU M  1 65  ? 127.573 105.393 67.440 1.00 4.14  64  M 1 
-ATOM   976  H  HB2  . GLU M  1 65  ? 128.554 106.187 69.959 1.00 4.14  64  M 1 
-ATOM   977  H  HB3  . GLU M  1 65  ? 127.121 106.603 69.441 1.00 4.14  64  M 1 
-ATOM   978  H  HG2  . GLU M  1 65  ? 126.423 104.393 69.514 1.00 4.14  64  M 1 
-ATOM   979  H  HG3  . GLU M  1 65  ? 127.878 103.941 69.968 1.00 4.14  64  M 1 
-ATOM   980  N  N    . HIS M  1 66  ? 129.829 107.640 67.616 1.00 4.22  65  M 1 
-ATOM   981  C  CA   . HIS M  1 66  ? 130.308 108.938 67.079 1.00 4.22  65  M 1 
-ATOM   982  C  C    . HIS M  1 66  ? 130.290 108.866 65.548 1.00 4.22  65  M 1 
-ATOM   983  O  O    . HIS M  1 66  ? 129.822 109.783 64.939 1.00 4.22  65  M 1 
-ATOM   984  C  CB   . HIS M  1 66  ? 131.713 109.301 67.587 1.00 4.22  65  M 1 
-ATOM   985  C  CG   . HIS M  1 66  ? 131.792 109.546 69.053 1.00 4.22  65  M 1 
-ATOM   986  N  ND1  . HIS M  1 66  ? 133.003 109.665 69.722 1.00 4.22  65  M 1 
-ATOM   987  C  CD2  . HIS M  1 66  ? 130.831 109.635 69.993 1.00 4.22  65  M 1 
-ATOM   988  C  CE1  . HIS M  1 66  ? 132.776 109.838 71.000 1.00 4.22  65  M 1 
-ATOM   989  N  NE2  . HIS M  1 66  ? 131.461 109.838 71.198 1.00 4.22  65  M 1 
-ATOM   990  H  H    . HIS M  1 66  ? 130.452 107.215 68.128 1.00 4.22  65  M 1 
-ATOM   991  H  HA   . HIS M  1 66  ? 129.676 109.640 67.364 1.00 4.22  65  M 1 
-ATOM   992  H  HB2  . HIS M  1 66  ? 132.330 108.571 67.356 1.00 4.22  65  M 1 
-ATOM   993  H  HB3  . HIS M  1 66  ? 132.020 110.107 67.116 1.00 4.22  65  M 1 
-ATOM   994  H  HD2  . HIS M  1 66  ? 129.904 109.592 69.854 1.00 4.22  65  M 1 
-ATOM   995  H  HE1  . HIS M  1 66  ? 133.434 109.962 71.662 1.00 4.22  65  M 1 
-ATOM   996  H  HE2  . HIS M  1 66  ? 131.063 109.939 71.973 1.00 4.22  65  M 1 
-ATOM   997  N  N    . ALA M  1 67  ? 130.747 107.775 64.950 1.00 3.84  66  M 1 
-ATOM   998  C  CA   . ALA M  1 67  ? 130.771 107.598 63.501 1.00 3.84  66  M 1 
-ATOM   999  C  C    . ALA M  1 67  ? 129.362 107.575 62.928 1.00 3.84  66  M 1 
-ATOM   1000 O  O    . ALA M  1 67  ? 129.078 108.216 61.908 1.00 3.84  66  M 1 
-ATOM   1001 C  CB   . ALA M  1 67  ? 131.504 106.307 63.143 1.00 3.84  66  M 1 
-ATOM   1002 H  H    . ALA M  1 67  ? 131.105 107.131 65.393 1.00 3.84  66  M 1 
-ATOM   1003 H  HA   . ALA M  1 67  ? 131.257 108.336 63.100 1.00 3.84  66  M 1 
-ATOM   1004 H  HB1  . ALA M  1 67  ? 131.443 106.159 62.186 1.00 3.84  66  M 1 
-ATOM   1005 H  HB2  . ALA M  1 67  ? 132.433 106.374 63.413 1.00 3.84  66  M 1 
-ATOM   1006 H  HB3  . ALA M  1 67  ? 131.087 105.565 63.608 1.00 3.84  66  M 1 
-ATOM   1007 N  N    . GLU M  1 68  ? 128.465 106.843 63.583 1.00 4.02  67  M 1 
-ATOM   1008 C  CA   . GLU M  1 68  ? 127.104 106.708 63.080 1.00 4.02  67  M 1 
-ATOM   1009 C  C    . GLU M  1 68  ? 126.361 108.039 63.154 1.00 4.02  67  M 1 
-ATOM   1010 O  O    . GLU M  1 68  ? 125.551 108.363 62.274 1.00 4.02  67  M 1 
-ATOM   1011 C  CB   . GLU M  1 68  ? 126.385 105.614 63.868 1.00 4.02  67  M 1 
-ATOM   1012 C  CG   . GLU M  1 68  ? 126.941 104.210 63.617 1.00 4.02  67  M 1 
-ATOM   1013 C  CD   . GLU M  1 68  ? 126.280 103.138 64.473 1.00 4.02  67  M 1 
-ATOM   1014 O  OE1  . GLU M  1 68  ? 125.463 103.483 65.352 1.00 4.02  67  M 1 
-ATOM   1015 O  OE2  . GLU M  1 68  ? 126.596 101.946 64.273 1.00 4.02  67  M 1 
-ATOM   1016 H  H    . GLU M  1 68  ? 128.615 106.433 64.324 1.00 4.02  67  M 1 
-ATOM   1017 H  HA   . GLU M  1 68  ? 127.136 106.429 62.152 1.00 4.02  67  M 1 
-ATOM   1018 H  HB2  . GLU M  1 68  ? 126.479 105.804 64.815 1.00 4.02  67  M 1 
-ATOM   1019 H  HB3  . GLU M  1 68  ? 125.445 105.608 63.630 1.00 4.02  67  M 1 
-ATOM   1020 H  HG2  . GLU M  1 68  ? 126.785 103.976 62.689 1.00 4.02  67  M 1 
-ATOM   1021 H  HG3  . GLU M  1 68  ? 127.896 104.193 63.787 1.00 4.02  67  M 1 
-ATOM   1022 N  N    . LYS M  1 69  ? 126.644 108.836 64.186 1.00 4.51  68  M 1 
-ATOM   1023 C  CA   . LYS M  1 69  ? 126.058 110.167 64.286 1.00 4.51  68  M 1 
-ATOM   1024 C  C    . LYS M  1 69  ? 126.543 111.060 63.145 1.00 4.51  68  M 1 
-ATOM   1025 O  O    . LYS M  1 69  ? 125.765 111.831 62.573 1.00 4.51  68  M 1 
-ATOM   1026 C  CB   . LYS M  1 69  ? 126.392 110.761 65.656 1.00 4.51  68  M 1 
-ATOM   1027 C  CG   . LYS M  1 69  ? 125.744 112.081 65.984 1.00 4.51  68  M 1 
-ATOM   1028 C  CD   . LYS M  1 69  ? 126.140 112.584 67.379 1.00 4.51  68  M 1 
-ATOM   1029 C  CE   . LYS M  1 69  ? 125.446 111.817 68.486 1.00 4.51  68  M 1 
-ATOM   1030 N  NZ   . LYS M  1 69  ? 125.760 112.374 69.836 1.00 4.51  68  M 1 
-ATOM   1031 H  H    . LYS M  1 69  ? 127.178 108.638 64.831 1.00 4.51  68  M 1 
-ATOM   1032 H  HA   . LYS M  1 69  ? 125.092 110.102 64.227 1.00 4.51  68  M 1 
-ATOM   1033 H  HB2  . LYS M  1 69  ? 126.106 110.132 66.337 1.00 4.51  68  M 1 
-ATOM   1034 H  HB3  . LYS M  1 69  ? 127.353 110.884 65.706 1.00 4.51  68  M 1 
-ATOM   1035 H  HG2  . LYS M  1 69  ? 126.054 112.738 65.342 1.00 4.51  68  M 1 
-ATOM   1036 H  HG3  . LYS M  1 69  ? 124.779 111.993 65.944 1.00 4.51  68  M 1 
-ATOM   1037 H  HD2  . LYS M  1 69  ? 127.097 112.483 67.503 1.00 4.51  68  M 1 
-ATOM   1038 H  HD3  . LYS M  1 69  ? 125.887 113.517 67.465 1.00 4.51  68  M 1 
-ATOM   1039 H  HE2  . LYS M  1 69  ? 124.487 111.865 68.351 1.00 4.51  68  M 1 
-ATOM   1040 H  HE3  . LYS M  1 69  ? 125.737 110.892 68.471 1.00 4.51  68  M 1 
-ATOM   1041 H  HZ1  . LYS M  1 69  ? 126.614 112.223 70.038 1.00 4.51  68  M 1 
-ATOM   1042 H  HZ2  . LYS M  1 69  ? 125.615 113.252 69.847 1.00 4.51  68  M 1 
-ATOM   1043 H  HZ3  . LYS M  1 69  ? 125.247 111.989 70.453 1.00 4.51  68  M 1 
-ATOM   1044 N  N    . LEU M  1 70  ? 127.821 110.946 62.778 1.00 4.14  69  M 1 
-ATOM   1045 C  CA   . LEU M  1 70  ? 128.312 111.688 61.615 1.00 4.14  69  M 1 
-ATOM   1046 C  C    . LEU M  1 70  ? 127.628 111.240 60.328 1.00 4.14  69  M 1 
-ATOM   1047 O  O    . LEU M  1 70  ? 127.352 112.060 59.446 1.00 4.14  69  M 1 
-ATOM   1048 C  CB   . LEU M  1 70  ? 129.824 111.540 61.473 1.00 4.14  69  M 1 
-ATOM   1049 C  CG   . LEU M  1 70  ? 130.714 112.224 62.508 1.00 4.14  69  M 1 
-ATOM   1050 C  CD1  . LEU M  1 70  ? 132.178 111.871 62.320 1.00 4.14  69  M 1 
-ATOM   1051 C  CD2  . LEU M  1 70  ? 130.530 113.726 62.481 1.00 4.14  69  M 1 
-ATOM   1052 H  H    . LEU M  1 70  ? 128.408 110.456 63.170 1.00 4.14  69  M 1 
-ATOM   1053 H  HA   . LEU M  1 70  ? 128.095 112.626 61.732 1.00 4.14  69  M 1 
-ATOM   1054 H  HB2  . LEU M  1 70  ? 130.029 110.592 61.501 1.00 4.14  69  M 1 
-ATOM   1055 H  HB3  . LEU M  1 70  ? 130.074 111.883 60.601 1.00 4.14  69  M 1 
-ATOM   1056 H  HG   . LEU M  1 70  ? 130.458 111.911 63.390 1.00 4.14  69  M 1 
-ATOM   1057 H  HD11 . LEU M  1 70  ? 132.659 112.176 63.105 1.00 4.14  69  M 1 
-ATOM   1058 H  HD12 . LEU M  1 70  ? 132.281 110.911 62.229 1.00 4.14  69  M 1 
-ATOM   1059 H  HD13 . LEU M  1 70  ? 132.517 112.314 61.527 1.00 4.14  69  M 1 
-ATOM   1060 H  HD21 . LEU M  1 70  ? 131.231 114.137 63.010 1.00 4.14  69  M 1 
-ATOM   1061 H  HD22 . LEU M  1 70  ? 130.577 114.045 61.566 1.00 4.14  69  M 1 
-ATOM   1062 H  HD23 . LEU M  1 70  ? 129.667 113.945 62.865 1.00 4.14  69  M 1 
-ATOM   1063 N  N    . MET M  1 71  ? 127.364 109.948 60.208 1.00 4.44  70  M 1 
-ATOM   1064 C  CA   . MET M  1 71  ? 126.697 109.405 59.001 1.00 4.44  70  M 1 
-ATOM   1065 C  C    . MET M  1 71  ? 125.291 110.001 58.920 1.00 4.44  70  M 1 
-ATOM   1066 O  O    . MET M  1 71  ? 124.905 110.440 57.849 1.00 4.44  70  M 1 
-ATOM   1067 C  CB   . MET M  1 71  ? 126.674 107.880 59.051 1.00 4.44  70  M 1 
-ATOM   1068 C  CG   . MET M  1 71  ? 128.068 107.310 58.992 1.00 4.44  70  M 1 
-ATOM   1069 S  SD   . MET M  1 71  ? 128.013 105.515 59.092 1.00 4.44  70  M 1 
-ATOM   1070 C  CE   . MET M  1 71  ? 129.764 105.161 59.006 1.00 4.44  70  M 1 
-ATOM   1071 H  H    . MET M  1 71  ? 127.457 109.354 60.890 1.00 4.44  70  M 1 
-ATOM   1072 H  HA   . MET M  1 71  ? 127.206 109.698 58.210 1.00 4.44  70  M 1 
-ATOM   1073 H  HB2  . MET M  1 71  ? 126.238 107.593 59.878 1.00 4.44  70  M 1 
-ATOM   1074 H  HB3  . MET M  1 71  ? 126.151 107.542 58.297 1.00 4.44  70  M 1 
-ATOM   1075 H  HG2  . MET M  1 71  ? 128.499 107.576 58.152 1.00 4.44  70  M 1 
-ATOM   1076 H  HG3  . MET M  1 71  ? 128.600 107.661 59.738 1.00 4.44  70  M 1 
-ATOM   1077 H  HE1  . MET M  1 71  ? 129.900 104.207 59.039 1.00 4.44  70  M 1 
-ATOM   1078 H  HE2  . MET M  1 71  ? 130.121 105.509 58.180 1.00 4.44  70  M 1 
-ATOM   1079 H  HE3  . MET M  1 71  ? 130.213 105.578 59.752 1.00 4.44  70  M 1 
-ATOM   1080 N  N    . LYS M  1 72  ? 124.578 110.039 60.037 1.00 5.09  71  M 1 
-ATOM   1081 C  CA   . LYS M  1 72  ? 123.268 110.672 60.109 1.00 5.09  71  M 1 
-ATOM   1082 C  C    . LYS M  1 72  ? 123.349 112.134 59.697 1.00 5.09  71  M 1 
-ATOM   1083 O  O    . LYS M  1 72  ? 122.508 112.617 58.933 1.00 5.09  71  M 1 
-ATOM   1084 C  CB   . LYS M  1 72  ? 122.703 110.527 61.522 1.00 5.09  71  M 1 
-ATOM   1085 C  CG   . LYS M  1 72  ? 121.325 111.109 61.739 1.00 5.09  71  M 1 
-ATOM   1086 C  CD   . LYS M  1 72  ? 120.796 110.746 63.129 1.00 5.09  71  M 1 
-ATOM   1087 C  CE   . LYS M  1 72  ? 119.462 111.406 63.437 1.00 5.09  71  M 1 
-ATOM   1088 N  NZ   . LYS M  1 72  ? 118.368 110.935 62.544 1.00 5.09  71  M 1 
-ATOM   1089 H  H    . LYS M  1 72  ? 124.846 109.694 60.777 1.00 5.09  71  M 1 
-ATOM   1090 H  HA   . LYS M  1 72  ? 122.666 110.214 59.501 1.00 5.09  71  M 1 
-ATOM   1091 H  HB2  . LYS M  1 72  ? 122.640 109.582 61.732 1.00 5.09  71  M 1 
-ATOM   1092 H  HB3  . LYS M  1 72  ? 123.310 110.959 62.144 1.00 5.09  71  M 1 
-ATOM   1093 H  HG2  . LYS M  1 72  ? 121.371 112.076 61.677 1.00 5.09  71  M 1 
-ATOM   1094 H  HG3  . LYS M  1 72  ? 120.720 110.757 61.068 1.00 5.09  71  M 1 
-ATOM   1095 H  HD2  . LYS M  1 72  ? 120.682 109.785 63.191 1.00 5.09  71  M 1 
-ATOM   1096 H  HD3  . LYS M  1 72  ? 121.431 111.046 63.798 1.00 5.09  71  M 1 
-ATOM   1097 H  HE2  . LYS M  1 72  ? 119.208 111.187 64.347 1.00 5.09  71  M 1 
-ATOM   1098 H  HE3  . LYS M  1 72  ? 119.546 112.368 63.342 1.00 5.09  71  M 1 
-ATOM   1099 H  HZ1  . LYS M  1 72  ? 117.580 111.187 62.871 1.00 5.09  71  M 1 
-ATOM   1100 H  HZ2  . LYS M  1 72  ? 118.464 111.284 61.731 1.00 5.09  71  M 1 
-ATOM   1101 H  HZ3  . LYS M  1 72  ? 118.388 110.047 62.481 1.00 5.09  71  M 1 
-ATOM   1102 N  N    . LEU M  1 73  ? 124.372 112.846 60.176 1.00 4.70  72  M 1 
-ATOM   1103 C  CA   . LEU M  1 73  ? 124.575 114.232 59.765 1.00 4.70  72  M 1 
-ATOM   1104 C  C    . LEU M  1 73  ? 124.735 114.343 58.257 1.00 4.70  72  M 1 
-ATOM   1105 O  O    . LEU M  1 73  ? 124.121 115.210 57.626 1.00 4.70  72  M 1 
-ATOM   1106 C  CB   . LEU M  1 73  ? 125.792 114.820 60.486 1.00 4.70  72  M 1 
-ATOM   1107 C  CG   . LEU M  1 73  ? 126.197 116.293 60.314 1.00 4.70  72  M 1 
-ATOM   1108 C  CD1  . LEU M  1 73  ? 126.895 116.563 58.993 1.00 4.70  72  M 1 
-ATOM   1109 C  CD2  . LEU M  1 73  ? 125.020 117.220 60.465 1.00 4.70  72  M 1 
-ATOM   1110 H  H    . LEU M  1 73  ? 124.966 112.543 60.719 1.00 4.70  72  M 1 
-ATOM   1111 H  HA   . LEU M  1 73  ? 123.795 114.747 60.024 1.00 4.70  72  M 1 
-ATOM   1112 H  HB2  . LEU M  1 73  ? 125.621 114.717 61.435 1.00 4.70  72  M 1 
-ATOM   1113 H  HB3  . LEU M  1 73  ? 126.570 114.287 60.259 1.00 4.70  72  M 1 
-ATOM   1114 H  HG   . LEU M  1 73  ? 126.833 116.516 61.011 1.00 4.70  72  M 1 
-ATOM   1115 H  HD11 . LEU M  1 73  ? 127.419 117.376 59.068 1.00 4.70  72  M 1 
-ATOM   1116 H  HD12 . LEU M  1 73  ? 127.480 115.818 58.782 1.00 4.70  72  M 1 
-ATOM   1117 H  HD13 . LEU M  1 73  ? 126.229 116.668 58.295 1.00 4.70  72  M 1 
-ATOM   1118 H  HD21 . LEU M  1 73  ? 125.345 118.132 60.408 1.00 4.70  72  M 1 
-ATOM   1119 H  HD22 . LEU M  1 73  ? 124.387 117.048 59.750 1.00 4.70  72  M 1 
-ATOM   1120 H  HD23 . LEU M  1 73  ? 124.600 117.070 61.327 1.00 4.70  72  M 1 
-ATOM   1121 N  N    . GLN M  1 74  ? 125.569 113.483 57.671 1.00 4.76  73  M 1 
-ATOM   1122 C  CA   . GLN M  1 74  ? 125.839 113.540 56.238 1.00 4.76  73  M 1 
-ATOM   1123 C  C    . GLN M  1 74  ? 124.544 113.406 55.449 1.00 4.76  73  M 1 
-ATOM   1124 O  O    . GLN M  1 74  ? 124.287 114.173 54.515 1.00 4.76  73  M 1 
-ATOM   1125 C  CB   . GLN M  1 74  ? 126.819 112.433 55.835 1.00 4.76  73  M 1 
-ATOM   1126 C  CG   . GLN M  1 74  ? 127.295 112.530 54.401 1.00 4.76  73  M 1 
-ATOM   1127 C  CD   . GLN M  1 74  ? 128.249 113.676 54.194 1.00 4.76  73  M 1 
-ATOM   1128 O  OE1  . GLN M  1 74  ? 127.849 114.775 53.838 1.00 4.76  73  M 1 
-ATOM   1129 N  NE2  . GLN M  1 74  ? 129.532 113.391 54.310 1.00 4.76  73  M 1 
-ATOM   1130 H  H    . GLN M  1 74  ? 125.987 112.851 58.078 1.00 4.76  73  M 1 
-ATOM   1131 H  HA   . GLN M  1 74  ? 126.241 114.394 56.014 1.00 4.76  73  M 1 
-ATOM   1132 H  HB2  . GLN M  1 74  ? 127.609 112.511 56.392 1.00 4.76  73  M 1 
-ATOM   1133 H  HB3  . GLN M  1 74  ? 126.415 111.560 55.961 1.00 4.76  73  M 1 
-ATOM   1134 H  HG2  . GLN M  1 74  ? 127.762 111.711 54.171 1.00 4.76  73  M 1 
-ATOM   1135 H  HG3  . GLN M  1 74  ? 126.548 112.649 53.793 1.00 4.76  73  M 1 
-ATOM   1136 H  HE21 . GLN M  1 74  ? 129.777 112.597 54.532 1.00 4.76  73  M 1 
-ATOM   1137 H  HE22 . GLN M  1 74  ? 130.123 114.002 54.182 1.00 4.76  73  M 1 
-ATOM   1138 N  N    . ASN M  1 75  ? 123.737 112.412 55.802 1.00 4.47  74  M 1 
-ATOM   1139 C  CA   . ASN M  1 75  ? 122.429 112.141 55.138 1.00 4.47  74  M 1 
-ATOM   1140 C  C    . ASN M  1 75  ? 121.453 113.301 55.386 1.00 4.47  74  M 1 
-ATOM   1141 O  O    . ASN M  1 75  ? 120.756 113.695 54.470 1.00 4.47  74  M 1 
-ATOM   1142 C  CB   . ASN M  1 75  ? 121.854 110.804 55.586 1.00 4.47  74  M 1 
-ATOM   1143 C  CG   . ASN M  1 75  ? 122.406 109.660 54.764 1.00 4.47  74  M 1 
-ATOM   1144 O  OD1  . ASN M  1 75  ? 122.981 109.885 53.713 1.00 4.47  74  M 1 
-ATOM   1145 N  ND2  . ASN M  1 75  ? 122.233 108.443 55.235 1.00 4.47  74  M 1 
-ATOM   1146 H  H    . ASN M  1 75  ? 123.885 111.904 56.543 1.00 4.47  74  M 1 
-ATOM   1147 H  HA   . ASN M  1 75  ? 122.592 112.080 54.168 1.00 4.47  74  M 1 
-ATOM   1148 H  HB2  . ASN M  1 75  ? 122.072 110.660 56.529 1.00 4.47  74  M 1 
-ATOM   1149 H  HB3  . ASN M  1 75  ? 120.879 110.827 55.495 1.00 4.47  74  M 1 
-ATOM   1150 H  HD21 . ASN M  1 75  ? 121.801 108.321 55.996 1.00 4.47  74  M 1 
-ATOM   1151 H  HD22 . ASN M  1 75  ? 122.549 107.747 54.790 1.00 4.47  74  M 1 
-ATOM   1152 N  N    . GLN M  1 76  ? 121.463 113.847 56.588 1.00 5.04  75  M 1 
-ATOM   1153 C  CA   . GLN M  1 76  ? 120.581 114.983 56.952 1.00 5.04  75  M 1 
-ATOM   1154 C  C    . GLN M  1 76  ? 120.881 116.181 56.044 1.00 5.04  75  M 1 
-ATOM   1155 O  O    . GLN M  1 76  ? 119.961 116.839 55.678 1.00 5.04  75  M 1 
-ATOM   1156 C  CB   . GLN M  1 76  ? 120.835 115.462 58.374 1.00 5.04  75  M 1 
-ATOM   1157 C  CG   . GLN M  1 76  ? 119.945 114.854 59.435 1.00 5.04  75  M 1 
-ATOM   1158 C  CD   . GLN M  1 76  ? 119.808 115.830 60.585 1.00 5.04  75  M 1 
-ATOM   1159 O  OE1  . GLN M  1 76  ? 118.777 115.913 61.234 1.00 5.04  75  M 1 
-ATOM   1160 N  NE2  . GLN M  1 76  ? 120.836 116.632 60.800 1.00 5.04  75  M 1 
-ATOM   1161 H  H    . GLN M  1 76  ? 122.100 113.657 57.209 1.00 5.04  75  M 1 
-ATOM   1162 H  HA   . GLN M  1 76  ? 119.639 114.714 56.850 1.00 5.04  75  M 1 
-ATOM   1163 H  HB2  . GLN M  1 76  ? 121.769 115.267 58.599 1.00 5.04  75  M 1 
-ATOM   1164 H  HB3  . GLN M  1 76  ? 120.725 116.436 58.392 1.00 5.04  75  M 1 
-ATOM   1165 H  HG2  . GLN M  1 76  ? 119.060 114.661 59.057 1.00 5.04  75  M 1 
-ATOM   1166 H  HG3  . GLN M  1 76  ? 120.336 114.015 59.757 1.00 5.04  75  M 1 
-ATOM   1167 H  HE21 . GLN M  1 76  ? 121.177 117.105 60.136 1.00 5.04  75  M 1 
-ATOM   1168 H  HE22 . GLN M  1 76  ? 121.175 116.708 61.613 1.00 5.04  75  M 1 
-ATOM   1169 N  N    . ARG M  1 77  ? 122.137 116.447 55.723 1.00 5.21  76  M 1 
-ATOM   1170 C  CA   . ARG M  1 77  ? 122.556 117.638 54.929 1.00 5.21  76  M 1 
-ATOM   1171 C  C    . ARG M  1 77  ? 122.537 117.372 53.405 1.00 5.21  76  M 1 
-ATOM   1172 O  O    . ARG M  1 77  ? 122.838 118.277 52.658 1.00 5.21  76  M 1 
-ATOM   1173 C  CB   . ARG M  1 77  ? 123.908 118.130 55.452 1.00 5.21  76  M 1 
-ATOM   1174 C  CG   . ARG M  1 77  ? 123.873 118.631 56.893 1.00 5.21  76  M 1 
-ATOM   1175 C  CD   . ARG M  1 77  ? 122.925 119.810 57.098 1.00 5.21  76  M 1 
-ATOM   1176 N  NE   . ARG M  1 77  ? 123.250 120.925 56.224 1.00 5.21  76  M 1 
-ATOM   1177 C  CZ   . ARG M  1 77  ? 124.148 121.866 56.492 1.00 5.21  76  M 1 
-ATOM   1178 N  NH1  . ARG M  1 77  ? 124.811 121.845 57.631 1.00 5.21  76  M 1 
-ATOM   1179 N  NH2  . ARG M  1 77  ? 124.387 122.830 55.625 1.00 5.21  76  M 1 
-ATOM   1180 H  H    . ARG M  1 77  ? 122.822 115.881 55.924 1.00 5.21  76  M 1 
-ATOM   1181 H  HA   . ARG M  1 77  ? 121.896 118.347 55.108 1.00 5.21  76  M 1 
-ATOM   1182 H  HB2  . ARG M  1 77  ? 124.554 117.395 55.388 1.00 5.21  76  M 1 
-ATOM   1183 H  HB3  . ARG M  1 77  ? 124.221 118.856 54.873 1.00 5.21  76  M 1 
-ATOM   1184 H  HG2  . ARG M  1 77  ? 123.594 117.896 57.481 1.00 5.21  76  M 1 
-ATOM   1185 H  HG3  . ARG M  1 77  ? 124.776 118.902 57.161 1.00 5.21  76  M 1 
-ATOM   1186 H  HD2  . ARG M  1 77  ? 122.005 119.519 56.922 1.00 5.21  76  M 1 
-ATOM   1187 H  HD3  . ARG M  1 77  ? 122.974 120.106 58.032 1.00 5.21  76  M 1 
-ATOM   1188 H  HE   . ARG M  1 77  ? 122.839 120.970 55.456 1.00 5.21  76  M 1 
-ATOM   1189 H  HH11 . ARG M  1 77  ? 124.661 121.204 58.213 1.00 5.21  76  M 1 
-ATOM   1190 H  HH12 . ARG M  1 77  ? 125.402 122.472 57.804 1.00 5.21  76  M 1 
-ATOM   1191 H  HH21 . ARG M  1 77  ? 123.947 122.853 54.863 1.00 5.21  76  M 1 
-ATOM   1192 H  HH22 . ARG M  1 77  ? 124.980 123.453 55.815 1.00 5.21  76  M 1 
-ATOM   1193 N  N    . GLY M  1 78  ? 122.159 116.191 52.933 1.00 5.50  77  M 1 
-ATOM   1194 C  CA   . GLY M  1 78  ? 122.140 115.887 51.522 1.00 5.50  77  M 1 
-ATOM   1195 C  C    . GLY M  1 78  ? 123.459 115.443 50.939 1.00 5.50  77  M 1 
-ATOM   1196 O  O    . GLY M  1 78  ? 123.541 115.249 49.723 1.00 5.50  77  M 1 
-ATOM   1197 H  H    . GLY M  1 78  ? 121.916 115.531 53.428 1.00 5.50  77  M 1 
-ATOM   1198 H  HA2  . GLY M  1 78  ? 121.495 115.178 51.372 1.00 5.50  77  M 1 
-ATOM   1199 H  HA3  . GLY M  1 78  ? 121.836 116.659 51.020 1.00 5.50  77  M 1 
-ATOM   1200 N  N    . GLY M  1 79  ? 124.495 115.290 51.756 1.00 5.18  78  M 1 
-ATOM   1201 C  CA   . GLY M  1 79  ? 125.727 114.712 51.279 1.00 5.18  78  M 1 
-ATOM   1202 C  C    . GLY M  1 79  ? 125.645 113.205 51.198 1.00 5.18  78  M 1 
-ATOM   1203 O  O    . GLY M  1 79  ? 124.682 112.590 51.648 1.00 5.18  78  M 1 
-ATOM   1204 H  H    . GLY M  1 79  ? 124.512 115.509 52.587 1.00 5.18  78  M 1 
-ATOM   1205 H  HA2  . GLY M  1 79  ? 125.940 115.050 50.395 1.00 5.18  78  M 1 
-ATOM   1206 H  HA3  . GLY M  1 79  ? 126.453 114.957 51.874 1.00 5.18  78  M 1 
-ATOM   1207 N  N    . ARG M  1 80  ? 126.638 112.620 50.533 1.00 5.31  79  M 1 
-ATOM   1208 C  CA   . ARG M  1 80  ? 126.688 111.162 50.279 1.00 5.31  79  M 1 
-ATOM   1209 C  C    . ARG M  1 80  ? 127.898 110.553 51.001 1.00 5.31  79  M 1 
-ATOM   1210 O  O    . ARG M  1 80  ? 129.032 110.956 50.759 1.00 5.31  79  M 1 
-ATOM   1211 C  CB   . ARG M  1 80  ? 126.670 110.918 48.767 1.00 5.31  79  M 1 
-ATOM   1212 C  CG   . ARG M  1 80  ? 125.405 111.442 48.090 1.00 5.31  79  M 1 
-ATOM   1213 C  CD   . ARG M  1 80  ? 124.176 110.697 48.584 1.00 5.31  79  M 1 
-ATOM   1214 N  NE   . ARG M  1 80  ? 122.876 111.198 48.135 1.00 5.31  79  M 1 
-ATOM   1215 C  CZ   . ARG M  1 80  ? 121.961 111.743 48.932 1.00 5.31  79  M 1 
-ATOM   1216 N  NH1  . ARG M  1 80  ? 122.198 111.880 50.220 1.00 5.31  79  M 1 
-ATOM   1217 N  NH2  . ARG M  1 80  ? 120.804 112.149 48.440 1.00 5.31  79  M 1 
-ATOM   1218 H  H    . ARG M  1 80  ? 127.344 113.082 50.191 1.00 5.31  79  M 1 
-ATOM   1219 H  HA   . ARG M  1 80  ? 125.874 110.763 50.663 1.00 5.31  79  M 1 
-ATOM   1220 H  HB2  . ARG M  1 80  ? 127.450 111.355 48.367 1.00 5.31  79  M 1 
-ATOM   1221 H  HB3  . ARG M  1 80  ? 126.744 109.954 48.602 1.00 5.31  79  M 1 
-ATOM   1222 H  HG2  . ARG M  1 80  ? 125.303 112.399 48.282 1.00 5.31  79  M 1 
-ATOM   1223 H  HG3  . ARG M  1 80  ? 125.482 111.330 47.118 1.00 5.31  79  M 1 
-ATOM   1224 H  HD2  . ARG M  1 80  ? 124.254 109.759 48.308 1.00 5.31  79  M 1 
-ATOM   1225 H  HD3  . ARG M  1 80  ? 124.185 110.708 49.565 1.00 5.31  79  M 1 
-ATOM   1226 H  HE   . ARG M  1 80  ? 122.678 111.115 47.290 1.00 5.31  79  M 1 
-ATOM   1227 H  HH11 . ARG M  1 80  ? 122.964 111.608 50.556 1.00 5.31  79  M 1 
-ATOM   1228 H  HH12 . ARG M  1 80  ? 121.590 112.243 50.741 1.00 5.31  79  M 1 
-ATOM   1229 H  HH21 . ARG M  1 80  ? 120.638 112.062 47.579 1.00 5.31  79  M 1 
-ATOM   1230 H  HH22 . ARG M  1 80  ? 120.205 112.515 48.973 1.00 5.31  79  M 1 
-ATOM   1231 N  N    . ILE M  1 81  ? 127.627 109.572 51.839 1.00 4.71  80  M 1 
-ATOM   1232 C  CA   . ILE M  1 81  ? 128.644 108.852 52.587 1.00 4.71  80  M 1 
-ATOM   1233 C  C    . ILE M  1 81  ? 129.483 108.029 51.621 1.00 4.71  80  M 1 
-ATOM   1234 O  O    . ILE M  1 81  ? 128.948 107.277 50.797 1.00 4.71  80  M 1 
-ATOM   1235 C  CB   . ILE M  1 81  ? 127.982 107.961 53.650 1.00 4.71  80  M 1 
-ATOM   1236 C  CG1  . ILE M  1 81  ? 127.205 108.806 54.675 1.00 4.71  80  M 1 
-ATOM   1237 C  CG2  . ILE M  1 81  ? 129.034 107.088 54.347 1.00 4.71  80  M 1 
-ATOM   1238 C  CD1  . ILE M  1 81  ? 126.224 108.031 55.531 1.00 4.71  80  M 1 
-ATOM   1239 H  H    . ILE M  1 81  ? 126.825 109.314 52.012 1.00 4.71  80  M 1 
-ATOM   1240 H  HA   . ILE M  1 81  ? 129.217 109.490 53.040 1.00 4.71  80  M 1 
-ATOM   1241 H  HB   . ILE M  1 81  ? 127.353 107.381 53.193 1.00 4.71  80  M 1 
-ATOM   1242 H  HG12 . ILE M  1 81  ? 127.845 109.217 55.277 1.00 4.71  80  M 1 
-ATOM   1243 H  HG13 . ILE M  1 81  ? 126.688 109.497 54.232 1.00 4.71  80  M 1 
-ATOM   1244 H  HG21 . ILE M  1 81  ? 128.684 106.748 55.185 1.00 4.71  80  M 1 
-ATOM   1245 H  HG22 . ILE M  1 81  ? 129.264 106.336 53.780 1.00 4.71  80  M 1 
-ATOM   1246 H  HG23 . ILE M  1 81  ? 129.820 107.628 54.525 1.00 4.71  80  M 1 
-ATOM   1247 H  HD11 . ILE M  1 81  ? 125.755 108.653 56.109 1.00 4.71  80  M 1 
-ATOM   1248 H  HD12 . ILE M  1 81  ? 125.587 107.584 54.952 1.00 4.71  80  M 1 
-ATOM   1249 H  HD13 . ILE M  1 81  ? 126.695 107.375 56.068 1.00 4.71  80  M 1 
-ATOM   1250 N  N    . PHE M  1 82  ? 130.802 108.170 51.715 1.00 5.36  81  M 1 
-ATOM   1251 C  CA   . PHE M  1 82  ? 131.748 107.327 50.988 1.00 5.36  81  M 1 
-ATOM   1252 C  C    . PHE M  1 82  ? 132.688 106.692 51.999 1.00 5.36  81  M 1 
-ATOM   1253 O  O    . PHE M  1 82  ? 133.540 107.371 52.577 1.00 5.36  81  M 1 
-ATOM   1254 C  CB   . PHE M  1 82  ? 132.521 108.111 49.933 1.00 5.36  81  M 1 
-ATOM   1255 C  CG   . PHE M  1 82  ? 131.690 108.495 48.747 1.00 5.36  81  M 1 
-ATOM   1256 C  CD1  . PHE M  1 82  ? 131.427 107.575 47.748 1.00 5.36  81  M 1 
-ATOM   1257 C  CD2  . PHE M  1 82  ? 131.162 109.762 48.634 1.00 5.36  81  M 1 
-ATOM   1258 C  CE1  . PHE M  1 82  ? 130.659 107.920 46.658 1.00 5.36  81  M 1 
-ATOM   1259 C  CE2  . PHE M  1 82  ? 130.395 110.107 47.545 1.00 5.36  81  M 1 
-ATOM   1260 C  CZ   . PHE M  1 82  ? 130.144 109.187 46.560 1.00 5.36  81  M 1 
-ATOM   1261 H  H    . PHE M  1 82  ? 131.185 108.757 52.213 1.00 5.36  81  M 1 
-ATOM   1262 H  HA   . PHE M  1 82  ? 131.278 106.615 50.526 1.00 5.36  81  M 1 
-ATOM   1263 H  HB2  . PHE M  1 82  ? 132.867 108.921 50.338 1.00 5.36  81  M 1 
-ATOM   1264 H  HB3  . PHE M  1 82  ? 133.258 107.563 49.620 1.00 5.36  81  M 1 
-ATOM   1265 H  HD1  . PHE M  1 82  ? 131.775 106.715 47.806 1.00 5.36  81  M 1 
-ATOM   1266 H  HD2  . PHE M  1 82  ? 131.328 110.393 49.297 1.00 5.36  81  M 1 
-ATOM   1267 H  HE1  . PHE M  1 82  ? 130.491 107.296 45.990 1.00 5.36  81  M 1 
-ATOM   1268 H  HE2  . PHE M  1 82  ? 130.045 110.966 47.479 1.00 5.36  81  M 1 
-ATOM   1269 H  HZ   . PHE M  1 82  ? 129.627 109.423 45.824 1.00 5.36  81  M 1 
-ATOM   1270 N  N    . LEU M  1 83  ? 132.516 105.396 52.207 1.00 4.68  82  M 1 
-ATOM   1271 C  CA   . LEU M  1 83  ? 133.289 104.642 53.174 1.00 4.68  82  M 1 
-ATOM   1272 C  C    . LEU M  1 83  ? 134.622 104.239 52.562 1.00 4.68  82  M 1 
-ATOM   1273 O  O    . LEU M  1 83  ? 134.746 104.069 51.348 1.00 4.68  82  M 1 
-ATOM   1274 C  CB   . LEU M  1 83  ? 132.521 103.401 53.623 1.00 4.68  82  M 1 
-ATOM   1275 C  CG   . LEU M  1 83  ? 131.190 103.642 54.335 1.00 4.68  82  M 1 
-ATOM   1276 C  CD1  . LEU M  1 83  ? 130.481 102.327 54.590 1.00 4.68  82  M 1 
-ATOM   1277 C  CD2  . LEU M  1 83  ? 131.353 104.418 55.627 1.00 4.68  82  M 1 
-ATOM   1278 H  H    . LEU M  1 83  ? 131.943 104.919 51.778 1.00 4.68  82  M 1 
-ATOM   1279 H  HA   . LEU M  1 83  ? 133.461 105.184 53.960 1.00 4.68  82  M 1 
-ATOM   1280 H  HB2  . LEU M  1 83  ? 132.339 102.858 52.840 1.00 4.68  82  M 1 
-ATOM   1281 H  HB3  . LEU M  1 83  ? 133.082 102.899 54.235 1.00 4.68  82  M 1 
-ATOM   1282 H  HG   . LEU M  1 83  ? 130.625 104.170 53.750 1.00 4.68  82  M 1 
-ATOM   1283 H  HD11 . LEU M  1 83  ? 129.639 102.499 55.040 1.00 4.68  82  M 1 
-ATOM   1284 H  HD12 . LEU M  1 83  ? 130.314 101.894 53.738 1.00 4.68  82  M 1 
-ATOM   1285 H  HD13 . LEU M  1 83  ? 131.041 101.763 55.146 1.00 4.68  82  M 1 
-ATOM   1286 H  HD21 . LEU M  1 83  ? 130.496 104.434 56.082 1.00 4.68  82  M 1 
-ATOM   1287 H  HD22 . LEU M  1 83  ? 132.017 103.986 56.187 1.00 4.68  82  M 1 
-ATOM   1288 H  HD23 . LEU M  1 83  ? 131.630 105.324 55.420 1.00 4.68  82  M 1 
-ATOM   1289 N  N    . GLN M  1 84  ? 135.620 104.103 53.420 1.00 4.98  83  M 1 
-ATOM   1290 C  CA   . GLN M  1 84  ? 136.983 103.695 53.032 1.00 4.98  83  M 1 
-ATOM   1291 C  C    . GLN M  1 84  ? 137.424 102.574 53.977 1.00 4.98  83  M 1 
-ATOM   1292 O  O    . GLN M  1 84  ? 136.776 102.330 54.991 1.00 4.98  83  M 1 
-ATOM   1293 C  CB   . GLN M  1 84  ? 137.940 104.889 53.070 1.00 4.98  83  M 1 
-ATOM   1294 C  CG   . GLN M  1 84  ? 137.481 106.057 52.206 1.00 4.98  83  M 1 
-ATOM   1295 C  CD   . GLN M  1 84  ? 137.435 105.714 50.736 1.00 4.98  83  M 1 
-ATOM   1296 O  OE1  . GLN M  1 84  ? 136.691 106.307 49.957 1.00 4.98  83  M 1 
-ATOM   1297 N  NE2  . GLN M  1 84  ? 138.254 104.763 50.333 1.00 4.98  83  M 1 
-ATOM   1298 H  H    . GLN M  1 84  ? 135.530 104.287 54.308 1.00 4.98  83  M 1 
-ATOM   1299 H  HA   . GLN M  1 84  ? 136.952 103.340 52.113 1.00 4.98  83  M 1 
-ATOM   1300 H  HB2  . GLN M  1 84  ? 138.027 105.190 53.998 1.00 4.98  83  M 1 
-ATOM   1301 H  HB3  . GLN M  1 84  ? 138.823 104.592 52.766 1.00 4.98  83  M 1 
-ATOM   1302 H  HG2  . GLN M  1 84  ? 136.587 106.339 52.496 1.00 4.98  83  M 1 
-ATOM   1303 H  HG3  . GLN M  1 84  ? 138.091 106.814 52.338 1.00 4.98  83  M 1 
-ATOM   1304 H  HE21 . GLN M  1 84  ? 138.896 104.475 50.869 1.00 4.98  83  M 1 
-ATOM   1305 H  HE22 . GLN M  1 84  ? 138.164 104.414 49.526 1.00 4.98  83  M 1 
-ATOM   1306 N  N    . ASP M  1 85  ? 138.495 101.908 53.612 1.00 4.69  84  M 1 
-ATOM   1307 C  CA   . ASP M  1 85  ? 139.059 100.852 54.433 1.00 4.69  84  M 1 
-ATOM   1308 C  C    . ASP M  1 85  ? 139.338 101.384 55.830 1.00 4.69  84  M 1 
-ATOM   1309 O  O    . ASP M  1 85  ? 139.747 102.533 56.005 1.00 4.69  84  M 1 
-ATOM   1310 C  CB   . ASP M  1 85  ? 140.360 100.325 53.827 1.00 4.69  84  M 1 
-ATOM   1311 C  CG   . ASP M  1 85  ? 140.159 99.642  52.493 1.00 4.69  84  M 1 
-ATOM   1312 O  OD1  . ASP M  1 85  ? 139.068 99.089  52.247 1.00 4.69  84  M 1 
-ATOM   1313 O  OD2  . ASP M  1 85  ? 141.111 99.651  51.689 1.00 4.69  84  M 1 
-ATOM   1314 H  H    . ASP M  1 85  ? 138.954 102.090 52.908 1.00 4.69  84  M 1 
-ATOM   1315 H  HA   . ASP M  1 85  ? 138.430 100.116 54.494 1.00 4.69  84  M 1 
-ATOM   1316 H  HB2  . ASP M  1 85  ? 140.983 101.059 53.707 1.00 4.69  84  M 1 
-ATOM   1317 H  HB3  . ASP M  1 85  ? 140.739 99.671  54.435 1.00 4.69  84  M 1 
-ATOM   1318 N  N    . ILE M  1 86  ? 139.106 100.539 56.825 1.00 3.70  85  M 1 
-ATOM   1319 C  CA   . ILE M  1 86  ? 139.459 100.834 58.207 1.00 3.70  85  M 1 
-ATOM   1320 C  C    . ILE M  1 86  ? 140.807 100.167 58.441 1.00 3.70  85  M 1 
-ATOM   1321 O  O    . ILE M  1 86  ? 140.902 98.937  58.481 1.00 3.70  85  M 1 
-ATOM   1322 C  CB   . ILE M  1 86  ? 138.405 100.331 59.202 1.00 3.70  85  M 1 
-ATOM   1323 C  CG1  . ILE M  1 86  ? 137.025 100.939 58.911 1.00 3.70  85  M 1 
-ATOM   1324 C  CG2  . ILE M  1 86  ? 138.841 100.699 60.622 1.00 3.70  85  M 1 
-ATOM   1325 C  CD1  . ILE M  1 86  ? 135.886 100.255 59.630 1.00 3.70  85  M 1 
-ATOM   1326 H  H    . ILE M  1 86  ? 138.741 99.767  56.719 1.00 3.70  85  M 1 
-ATOM   1327 H  HA   . ILE M  1 86  ? 139.559 101.790 58.338 1.00 3.70  85  M 1 
-ATOM   1328 H  HB   . ILE M  1 86  ? 138.343 99.365  59.135 1.00 3.70  85  M 1 
-ATOM   1329 H  HG12 . ILE M  1 86  ? 137.028 101.876 59.163 1.00 3.70  85  M 1 
-ATOM   1330 H  HG13 . ILE M  1 86  ? 136.822 100.870 57.965 1.00 3.70  85  M 1 
-ATOM   1331 H  HG21 . ILE M  1 86  ? 138.100 100.616 61.243 1.00 3.70  85  M 1 
-ATOM   1332 H  HG22 . ILE M  1 86  ? 139.559 100.111 60.906 1.00 3.70  85  M 1 
-ATOM   1333 H  HG23 . ILE M  1 86  ? 139.154 101.617 60.629 1.00 3.70  85  M 1 
-ATOM   1334 H  HD11 . ILE M  1 86  ? 135.049 100.509 59.210 1.00 3.70  85  M 1 
-ATOM   1335 H  HD12 . ILE M  1 86  ? 136.000 99.294  59.564 1.00 3.70  85  M 1 
-ATOM   1336 H  HD13 . ILE M  1 86  ? 135.882 100.509 60.566 1.00 3.70  85  M 1 
-ATOM   1337 N  N    . LYS M  1 87  ? 141.853 100.969 58.576 1.00 4.77  86  M 1 
-ATOM   1338 C  CA   . LYS M  1 87  ? 143.193 100.423 58.707 1.00 4.77  86  M 1 
-ATOM   1339 C  C    . LYS M  1 87  ? 143.363 99.744  60.060 1.00 4.77  86  M 1 
-ATOM   1340 O  O    . LYS M  1 87  ? 142.782 100.155 61.065 1.00 4.77  86  M 1 
-ATOM   1341 C  CB   . LYS M  1 87  ? 144.243 101.521 58.530 1.00 30.00 86  M 1 
-ATOM   1342 C  CG   . LYS M  1 87  ? 144.208 102.201 57.170 1.00 30.00 86  M 1 
-ATOM   1343 C  CD   . LYS M  1 87  ? 144.545 101.226 56.055 1.00 30.00 86  M 1 
-ATOM   1344 C  CE   . LYS M  1 87  ? 144.582 101.921 54.704 1.00 30.00 86  M 1 
-ATOM   1345 N  NZ   . LYS M  1 87  ? 144.888 100.972 53.599 1.00 30.00 86  M 1 
-ATOM   1346 H  H    . LYS M  1 87  ? 141.807 101.827 58.599 1.00 4.77  86  M 1 
-ATOM   1347 H  HA   . LYS M  1 87  ? 143.330 99.755  58.017 1.00 4.77  86  M 1 
-ATOM   1348 N  N    . LYS M  1 88  ? 144.175 98.693  60.077 1.00 4.97  87  M 1 
-ATOM   1349 C  CA   . LYS M  1 88  ? 144.415 97.973  61.311 1.00 4.97  87  M 1 
-ATOM   1350 C  C    . LYS M  1 88  ? 145.153 98.877  62.302 1.00 4.97  87  M 1 
-ATOM   1351 O  O    . LYS M  1 88  ? 145.866 99.795  61.895 1.00 4.97  87  M 1 
-ATOM   1352 C  CB   . LYS M  1 88  ? 145.223 96.704  61.055 1.00 4.97  87  M 1 
-ATOM   1353 C  CG   . LYS M  1 88  ? 146.628 96.926  60.549 1.00 4.97  87  M 1 
-ATOM   1354 C  CD   . LYS M  1 88  ? 147.328 95.606  60.302 1.00 4.97  87  M 1 
-ATOM   1355 C  CE   . LYS M  1 88  ? 148.741 95.814  59.822 1.00 4.97  87  M 1 
-ATOM   1356 N  NZ   . LYS M  1 88  ? 149.425 94.518  59.579 1.00 4.97  87  M 1 
-ATOM   1357 H  H    . LYS M  1 88  ? 144.595 98.383  59.393 1.00 4.97  87  M 1 
-ATOM   1358 H  HA   . LYS M  1 88  ? 143.546 97.705  61.648 1.00 4.97  87  M 1 
-ATOM   1359 H  HB2  . LYS M  1 88  ? 145.284 96.205  61.885 1.00 4.97  87  M 1 
-ATOM   1360 H  HB3  . LYS M  1 88  ? 144.759 96.168  60.393 1.00 4.97  87  M 1 
-ATOM   1361 H  HG2  . LYS M  1 88  ? 146.599 97.427  59.719 1.00 4.97  87  M 1 
-ATOM   1362 H  HG3  . LYS M  1 88  ? 147.152 97.407  61.209 1.00 4.97  87  M 1 
-ATOM   1363 H  HD2  . LYS M  1 88  ? 147.360 95.100  61.129 1.00 4.97  87  M 1 
-ATOM   1364 H  HD3  . LYS M  1 88  ? 146.855 95.105  59.619 1.00 4.97  87  M 1 
-ATOM   1365 H  HE2  . LYS M  1 88  ? 148.727 96.320  58.995 1.00 4.97  87  M 1 
-ATOM   1366 H  HE3  . LYS M  1 88  ? 149.236 96.296  60.503 1.00 4.97  87  M 1 
-ATOM   1367 H  HZ1  . LYS M  1 88  ? 150.258 94.655  59.296 1.00 4.97  87  M 1 
-ATOM   1368 H  HZ2  . LYS M  1 88  ? 149.448 94.051  60.337 1.00 4.97  87  M 1 
-ATOM   1369 H  HZ3  . LYS M  1 88  ? 148.985 94.051  58.963 1.00 4.97  87  M 1 
-ATOM   1370 N  N    . PRO M  1 89  ? 145.005 98.637  63.607 1.00 4.65  88  M 1 
-ATOM   1371 C  CA   . PRO M  1 89  ? 145.751 99.442  64.578 1.00 4.65  88  M 1 
-ATOM   1372 C  C    . PRO M  1 89  ? 147.253 99.252  64.431 1.00 4.65  88  M 1 
-ATOM   1373 O  O    . PRO M  1 89  ? 147.727 98.300  63.811 1.00 4.65  88  M 1 
-ATOM   1374 C  CB   . PRO M  1 89  ? 145.249 98.925  65.928 1.00 4.65  88  M 1 
-ATOM   1375 C  CG   . PRO M  1 89  ? 143.930 98.331  65.641 1.00 4.65  88  M 1 
-ATOM   1376 C  CD   . PRO M  1 89  ? 144.058 97.737  64.286 1.00 4.65  88  M 1 
-ATOM   1377 H  HA   . PRO M  1 89  ? 145.536 100.384 64.490 1.00 4.65  88  M 1 
-ATOM   1378 H  HB2  . PRO M  1 89  ? 145.858 98.253  66.272 1.00 4.65  88  M 1 
-ATOM   1379 H  HB3  . PRO M  1 89  ? 145.173 99.666  66.549 1.00 4.65  88  M 1 
-ATOM   1380 H  HG2  . PRO M  1 89  ? 143.743 97.634  66.289 1.00 4.65  88  M 1 
-ATOM   1381 H  HG3  . PRO M  1 89  ? 143.239 99.011  65.663 1.00 4.65  88  M 1 
-ATOM   1382 H  HD2  . PRO M  1 89  ? 144.416 96.837  64.330 1.00 4.65  88  M 1 
-ATOM   1383 H  HD3  . PRO M  1 89  ? 143.192 97.751  63.850 1.00 4.65  88  M 1 
-ATOM   1384 N  N    . ASP M  1 90  ? 148.000 100.181 65.028 1.00 6.42  89  M 1 
-ATOM   1385 C  CA   . ASP M  1 90  ? 149.444 100.220 64.829 1.00 6.42  89  M 1 
-ATOM   1386 C  C    . ASP M  1 90  ? 150.160 99.064  65.521 1.00 6.42  89  M 1 
-ATOM   1387 O  O    . ASP M  1 90  ? 151.321 98.786  65.205 1.00 6.42  89  M 1 
-ATOM   1388 C  CB   . ASP M  1 90  ? 150.000 101.563 65.307 1.00 6.42  89  M 1 
-ATOM   1389 C  CG   . ASP M  1 90  ? 149.765 101.813 66.789 1.00 6.42  89  M 1 
-ATOM   1390 O  OD1  . ASP M  1 90  ? 149.098 100.993 67.452 1.00 6.42  89  M 1 
-ATOM   1391 O  OD2  . ASP M  1 90  ? 150.256 102.842 67.298 1.00 6.42  89  M 1 
-ATOM   1392 H  H    . ASP M  1 90  ? 147.692 100.794 65.546 1.00 6.42  89  M 1 
-ATOM   1393 H  HA   . ASP M  1 90  ? 149.632 100.154 63.880 1.00 6.42  89  M 1 
-ATOM   1394 H  HB2  . ASP M  1 90  ? 150.954 101.594 65.135 1.00 6.42  89  M 1 
-ATOM   1395 H  HB3  . ASP M  1 90  ? 149.555 102.273 64.818 1.00 6.42  89  M 1 
-ATOM   1396 N  N    . ARG M  1 91  ? 149.525 98.437  66.501 1.00 6.46  90  M 1 
-ATOM   1397 C  CA   . ARG M  1 91  ? 150.159 97.302  67.210 1.00 6.46  90  M 1 
-ATOM   1398 C  C    . ARG M  1 91  ? 149.116 96.345  67.771 1.00 6.46  90  M 1 
-ATOM   1399 O  O    . ARG M  1 91  ? 147.959 96.741  67.965 1.00 6.46  90  M 1 
-ATOM   1400 C  CB   . ARG M  1 91  ? 151.033 97.810  68.360 1.00 6.46  90  M 1 
-ATOM   1401 C  CG   . ARG M  1 91  ? 150.288 98.636  69.392 1.00 6.46  90  M 1 
-ATOM   1402 C  CD   . ARG M  1 91  ? 151.196 99.661  70.045 1.00 6.46  90  M 1 
-ATOM   1403 N  NE   . ARG M  1 91  ? 152.000 99.066  71.096 1.00 6.46  90  M 1 
-ATOM   1404 C  CZ   . ARG M  1 91  ? 152.762 99.746  71.952 1.00 6.46  90  M 1 
-ATOM   1405 N  NH1  . ARG M  1 91  ? 152.826 101.065 71.888 1.00 6.46  90  M 1 
-ATOM   1406 N  NH2  . ARG M  1 91  ? 153.443 99.097  72.877 1.00 6.46  90  M 1 
-ATOM   1407 H  H    . ARG M  1 91  ? 148.725 98.709  66.841 1.00 6.46  90  M 1 
-ATOM   1408 H  HA   . ARG M  1 91  ? 150.726 96.813  66.571 1.00 6.46  90  M 1 
-ATOM   1409 H  HB2  . ARG M  1 91  ? 151.438 97.038  68.808 1.00 6.46  90  M 1 
-ATOM   1410 H  HB3  . ARG M  1 91  ? 151.757 98.353  67.985 1.00 6.46  90  M 1 
-ATOM   1411 H  HG2  . ARG M  1 91  ? 149.539 99.099  68.960 1.00 6.46  90  M 1 
-ATOM   1412 H  HG3  . ARG M  1 91  ? 149.923 98.043  70.083 1.00 6.46  90  M 1 
-ATOM   1413 H  HD2  . ARG M  1 91  ? 151.787 100.051 69.366 1.00 6.46  90  M 1 
-ATOM   1414 H  HD3  . ARG M  1 91  ? 150.651 100.384 70.423 1.00 6.46  90  M 1 
-ATOM   1415 H  HE   . ARG M  1 91  ? 151.982 98.198  71.177 1.00 6.46  90  M 1 
-ATOM   1416 H  HH11 . ARG M  1 91  ? 152.368 101.496 71.274 1.00 6.46  90  M 1 
-ATOM   1417 H  HH12 . ARG M  1 91  ? 153.329 101.507 72.457 1.00 6.46  90  M 1 
-ATOM   1418 H  HH21 . ARG M  1 91  ? 153.398 98.218  72.919 1.00 6.46  90  M 1 
-ATOM   1419 H  HH22 . ARG M  1 91  ? 153.948 99.544  73.444 1.00 6.46  90  M 1 
-ATOM   1420 N  N    . ASP M  1 92  ? 149.508 95.111  68.064 1.00 7.52  91  M 1 
-ATOM   1421 C  CA   . ASP M  1 92  ? 148.594 94.135  68.707 1.00 7.52  91  M 1 
-ATOM   1422 C  C    . ASP M  1 92  ? 149.003 94.016  70.176 1.00 7.52  91  M 1 
-ATOM   1423 O  O    . ASP M  1 92  ? 148.133 93.680  70.973 1.00 7.52  91  M 1 
-ATOM   1424 C  CB   . ASP M  1 92  ? 148.599 92.781  68.004 1.00 7.52  91  M 1 
-ATOM   1425 C  CG   . ASP M  1 92  ? 149.977 92.479  67.459 1.00 7.52  91  M 1 
-ATOM   1426 O  OD1  . ASP M  1 92  ? 150.923 92.558  68.246 1.00 7.52  91  M 1 
-ATOM   1427 O  OD2  . ASP M  1 92  ? 150.093 92.229  66.240 1.00 7.52  91  M 1 
-ATOM   1428 H  H    . ASP M  1 92  ? 150.363 94.825  67.949 1.00 7.52  91  M 1 
-ATOM   1429 H  HA   . ASP M  1 92  ? 147.678 94.499  68.666 1.00 7.52  91  M 1 
-ATOM   1430 H  HB2  . ASP M  1 92  ? 148.342 92.079  68.636 1.00 7.52  91  M 1 
-ATOM   1431 H  HB3  . ASP M  1 92  ? 147.956 92.789  67.266 1.00 7.52  91  M 1 
-ATOM   1432 N  N    . ASP M  1 93  ? 150.256 94.338  70.525 1.00 6.76  92  M 1 
-ATOM   1433 C  CA   . ASP M  1 93  ? 150.729 94.272  71.901 1.00 6.76  92  M 1 
-ATOM   1434 C  C    . ASP M  1 93  ? 150.848 95.690  72.446 1.00 6.76  92  M 1 
-ATOM   1435 O  O    . ASP M  1 93  ? 151.701 96.460  71.996 1.00 6.76  92  M 1 
-ATOM   1436 C  CB   . ASP M  1 93  ? 152.072 93.541  71.962 1.00 6.76  92  M 1 
-ATOM   1437 C  CG   . ASP M  1 93  ? 152.556 93.294  73.379 1.00 6.76  92  M 1 
-ATOM   1438 O  OD1  . ASP M  1 93  ? 151.901 93.735  74.341 1.00 6.76  92  M 1 
-ATOM   1439 O  OD2  . ASP M  1 93  ? 153.612 92.646  73.529 1.00 6.76  92  M 1 
-ATOM   1440 H  H    . ASP M  1 93  ? 150.867 94.598  69.979 1.00 6.76  92  M 1 
-ATOM   1441 H  HA   . ASP M  1 93  ? 150.095 93.777  72.443 1.00 6.76  92  M 1 
-ATOM   1442 H  HB2  . ASP M  1 93  ? 151.972 92.679  71.528 1.00 6.76  92  M 1 
-ATOM   1443 H  HB3  . ASP M  1 93  ? 152.743 94.066  71.499 1.00 6.76  92  M 1 
-ATOM   1444 N  N    . TRP M  1 94  ? 149.999 96.024  73.413 1.00 4.79  93  M 1 
-ATOM   1445 C  CA   . TRP M  1 94  ? 149.951 97.357  74.005 1.00 4.79  93  M 1 
-ATOM   1446 C  C    . TRP M  1 94  ? 150.818 97.490  75.257 1.00 4.79  93  M 1 
-ATOM   1447 O  O    . TRP M  1 94  ? 150.931 98.589  75.800 1.00 4.79  93  M 1 
-ATOM   1448 C  CB   . TRP M  1 94  ? 148.495 97.714  74.308 1.00 4.79  93  M 1 
-ATOM   1449 C  CG   . TRP M  1 94  ? 147.719 97.784  73.062 1.00 4.79  93  M 1 
-ATOM   1450 C  CD1  . TRP M  1 94  ? 146.925 96.817  72.544 1.00 4.79  93  M 1 
-ATOM   1451 C  CD2  . TRP M  1 94  ? 147.702 98.862  72.130 1.00 4.79  93  M 1 
-ATOM   1452 N  NE1  . TRP M  1 94  ? 146.394 97.228  71.353 1.00 4.79  93  M 1 
-ATOM   1453 C  CE2  . TRP M  1 94  ? 146.862 98.483  71.073 1.00 4.79  93  M 1 
-ATOM   1454 C  CE3  . TRP M  1 94  ? 148.312 100.113 72.090 1.00 4.79  93  M 1 
-ATOM   1455 C  CZ2  . TRP M  1 94  ? 146.612 99.311  69.994 1.00 4.79  93  M 1 
-ATOM   1456 C  CZ3  . TRP M  1 94  ? 148.066 100.930 71.015 1.00 4.79  93  M 1 
-ATOM   1457 C  CH2  . TRP M  1 94  ? 147.222 100.529 69.984 1.00 4.79  93  M 1 
-ATOM   1458 H  H    . TRP M  1 94  ? 149.420 95.479  73.741 1.00 4.79  93  M 1 
-ATOM   1459 H  HA   . TRP M  1 94  ? 150.269 98.003  73.356 1.00 4.79  93  M 1 
-ATOM   1460 H  HB2  . TRP M  1 94  ? 148.102 97.033  74.876 1.00 4.79  93  M 1 
-ATOM   1461 H  HB3  . TRP M  1 94  ? 148.451 98.582  74.739 1.00 4.79  93  M 1 
-ATOM   1462 H  HD1  . TRP M  1 94  ? 146.766 95.992  72.944 1.00 4.79  93  M 1 
-ATOM   1463 H  HE1  . TRP M  1 94  ? 145.858 96.772  70.859 1.00 4.79  93  M 1 
-ATOM   1464 H  HE3  . TRP M  1 94  ? 148.878 100.387 72.775 1.00 4.79  93  M 1 
-ATOM   1465 H  HZ2  . TRP M  1 94  ? 146.050 99.045  69.303 1.00 4.79  93  M 1 
-ATOM   1466 H  HZ3  . TRP M  1 94  ? 148.466 101.769 70.978 1.00 4.79  93  M 1 
-ATOM   1467 H  HH2  . TRP M  1 94  ? 147.074 101.107 69.270 1.00 4.79  93  M 1 
-ATOM   1468 N  N    . GLU M  1 95  ? 151.384 96.385  75.738 1.00 6.28  94  M 1 
-ATOM   1469 C  CA   . GLU M  1 95  ? 152.486 96.279  76.696 1.00 6.28  94  M 1 
-ATOM   1470 C  C    . GLU M  1 95  ? 152.172 96.600  78.151 1.00 6.28  94  M 1 
-ATOM   1471 O  O    . GLU M  1 95  ? 152.860 96.079  79.032 1.00 6.28  94  M 1 
-ATOM   1472 C  CB   . GLU M  1 95  ? 153.654 97.191  76.296 1.00 6.28  94  M 1 
-ATOM   1473 C  CG   . GLU M  1 95  ? 154.410 96.800  75.049 1.00 6.28  94  M 1 
-ATOM   1474 C  CD   . GLU M  1 95  ? 155.561 97.748  74.768 1.00 6.28  94  M 1 
-ATOM   1475 O  OE1  . GLU M  1 95  ? 155.686 98.769  75.478 1.00 6.28  94  M 1 
-ATOM   1476 O  OE2  . GLU M  1 95  ? 156.334 97.480  73.823 1.00 6.28  94  M 1 
-ATOM   1477 H  H    . GLU M  1 95  ? 151.108 95.601  75.516 1.00 6.28  94  M 1 
-ATOM   1478 H  HA   . GLU M  1 95  ? 152.814 95.366  76.679 1.00 6.28  94  M 1 
-ATOM   1479 H  HB2  . GLU M  1 95  ? 153.340 98.102  76.181 1.00 6.28  94  M 1 
-ATOM   1480 H  HB3  . GLU M  1 95  ? 154.302 97.181  77.018 1.00 6.28  94  M 1 
-ATOM   1481 H  HG2  . GLU M  1 95  ? 154.776 95.909  75.164 1.00 6.28  94  M 1 
-ATOM   1482 H  HG3  . GLU M  1 95  ? 153.808 96.816  74.289 1.00 6.28  94  M 1 
-ATOM   1483 N  N    . SER M  1 96  ? 151.102 97.336  78.433 1.00 4.95  95  M 1 
-ATOM   1484 C  CA   . SER M  1 96  ? 150.767 97.707  79.804 1.00 4.95  95  M 1 
-ATOM   1485 C  C    . SER M  1 96  ? 149.509 98.565  79.794 1.00 4.95  95  M 1 
-ATOM   1486 O  O    . SER M  1 96  ? 149.121 99.130  78.771 1.00 4.95  95  M 1 
-ATOM   1487 C  CB   . SER M  1 96  ? 151.907 98.467  80.503 1.00 4.95  95  M 1 
-ATOM   1488 O  OG   . SER M  1 96  ? 152.134 99.722  79.901 1.00 4.95  95  M 1 
-ATOM   1489 H  H    . SER M  1 96  ? 150.553 97.645  77.848 1.00 4.95  95  M 1 
-ATOM   1490 H  HA   . SER M  1 96  ? 150.583 96.900  80.310 1.00 4.95  95  M 1 
-ATOM   1491 H  HB2  . SER M  1 96  ? 151.648 98.620  81.425 1.00 4.95  95  M 1 
-ATOM   1492 H  HB3  . SER M  1 96  ? 152.735 97.962  80.503 1.00 4.95  95  M 1 
-ATOM   1493 H  HG   . SER M  1 96  ? 152.947 99.803  79.704 1.00 4.95  95  M 1 
-ATOM   1494 N  N    . GLY M  1 97  ? 148.886 98.664  80.967 1.00 4.08  96  M 1 
-ATOM   1495 C  CA   . GLY M  1 97  ? 147.786 99.597  81.142 1.00 4.08  96  M 1 
-ATOM   1496 C  C    . GLY M  1 97  ? 148.198 101.035 80.900 1.00 4.08  96  M 1 
-ATOM   1497 O  O    . GLY M  1 97  ? 147.507 101.781 80.204 1.00 4.08  96  M 1 
-ATOM   1498 H  H    . GLY M  1 97  ? 149.080 98.206  81.669 1.00 4.08  96  M 1 
-ATOM   1499 H  HA2  . GLY M  1 97  ? 147.044 99.362  80.564 1.00 4.08  96  M 1 
-ATOM   1500 H  HA3  . GLY M  1 97  ? 147.481 99.547  82.062 1.00 4.08  96  M 1 
-ATOM   1501 N  N    . LEU M  1 98  ? 149.324 101.444 81.487 1.00 4.35  97  M 1 
-ATOM   1502 C  CA   . LEU M  1 98  ? 149.821 102.805 81.323 1.00 4.35  97  M 1 
-ATOM   1503 C  C    . LEU M  1 98  ? 150.076 103.129 79.861 1.00 4.35  97  M 1 
-ATOM   1504 O  O    . LEU M  1 98  ? 149.678 104.190 79.371 1.00 4.35  97  M 1 
-ATOM   1505 C  CB   . LEU M  1 98  ? 151.098 102.993 82.141 1.00 4.35  97  M 1 
-ATOM   1506 C  CG   . LEU M  1 98  ? 151.816 104.337 82.014 1.00 4.35  97  M 1 
-ATOM   1507 C  CD1  . LEU M  1 98  ? 150.932 105.487 82.425 1.00 4.35  97  M 1 
-ATOM   1508 C  CD2  . LEU M  1 98  ? 153.073 104.329 82.842 1.00 4.35  97  M 1 
-ATOM   1509 H  H    . LEU M  1 98  ? 149.820 100.947 81.983 1.00 4.35  97  M 1 
-ATOM   1510 H  HA   . LEU M  1 98  ? 149.157 103.427 81.660 1.00 4.35  97  M 1 
-ATOM   1511 H  HB2  . LEU M  1 98  ? 150.874 102.876 83.078 1.00 4.35  97  M 1 
-ATOM   1512 H  HB3  . LEU M  1 98  ? 151.731 102.304 81.884 1.00 4.35  97  M 1 
-ATOM   1513 H  HG   . LEU M  1 98  ? 152.095 104.478 81.096 1.00 4.35  97  M 1 
-ATOM   1514 H  HD11 . LEU M  1 98  ? 151.461 106.299 82.385 1.00 4.35  97  M 1 
-ATOM   1515 H  HD12 . LEU M  1 98  ? 150.183 105.557 81.812 1.00 4.35  97  M 1 
-ATOM   1516 H  HD13 . LEU M  1 98  ? 150.611 105.342 83.329 1.00 4.35  97  M 1 
-ATOM   1517 H  HD21 . LEU M  1 98  ? 153.583 105.131 82.647 1.00 4.35  97  M 1 
-ATOM   1518 H  HD22 . LEU M  1 98  ? 152.832 104.310 83.781 1.00 4.35  97  M 1 
-ATOM   1519 H  HD23 . LEU M  1 98  ? 153.598 103.545 82.616 1.00 4.35  97  M 1 
-ATOM   1520 N  N    . ASN M  1 99  ? 150.760 102.206 79.194 1.00 4.75  98  M 1 
-ATOM   1521 C  CA   . ASN M  1 99  ? 151.113 102.418 77.769 1.00 4.75  98  M 1 
-ATOM   1522 C  C    . ASN M  1 99  ? 149.818 102.556 76.966 1.00 4.75  98  M 1 
-ATOM   1523 O  O    . ASN M  1 99  ? 149.706 103.465 76.165 1.00 4.75  98  M 1 
-ATOM   1524 C  CB   . ASN M  1 99  ? 151.972 101.305 77.182 1.00 4.75  98  M 1 
-ATOM   1525 C  CG   . ASN M  1 99  ? 152.324 101.638 75.750 1.00 4.75  98  M 1 
-ATOM   1526 O  OD1  . ASN M  1 99  ? 152.887 102.690 75.506 1.00 4.75  98  M 1 
-ATOM   1527 N  ND2  . ASN M  1 99  ? 152.012 100.765 74.813 1.00 4.75  98  M 1 
-ATOM   1528 H  H    . ASN M  1 99  ? 150.924 101.371 79.514 1.00 4.75  98  M 1 
-ATOM   1529 H  HA   . ASN M  1 99  ? 151.621 103.260 77.698 1.00 4.75  98  M 1 
-ATOM   1530 H  HB2  . ASN M  1 99  ? 152.791 101.209 77.709 1.00 4.75  98  M 1 
-ATOM   1531 H  HB3  . ASN M  1 99  ? 151.479 100.460 77.212 1.00 4.75  98  M 1 
-ATOM   1532 H  HD21 . ASN M  1 99  ? 152.223 100.926 73.970 1.00 4.75  98  M 1 
-ATOM   1533 H  HD22 . ASN M  1 99  ? 151.592 100.017 75.028 1.00 4.75  98  M 1 
-ATOM   1534 N  N    . ALA M  1 100 ? 148.838 101.713 77.239 1.00 3.93  99  M 1 
-ATOM   1535 C  CA   . ALA M  1 100 ? 147.559 101.755 76.541 1.00 3.93  99  M 1 
-ATOM   1536 C  C    . ALA M  1 100 ? 146.852 103.084 76.778 1.00 3.93  99  M 1 
-ATOM   1537 O  O    . ALA M  1 100 ? 146.297 103.679 75.850 1.00 3.93  99  M 1 
-ATOM   1538 C  CB   . ALA M  1 100 ? 146.675 100.583 76.973 1.00 3.93  99  M 1 
-ATOM   1539 H  H    . ALA M  1 100 ? 148.889 101.110 77.850 1.00 3.93  99  M 1 
-ATOM   1540 H  HA   . ALA M  1 100 ? 147.721 101.661 75.589 1.00 3.93  99  M 1 
-ATOM   1541 H  HB1  . ALA M  1 100 ? 145.808 100.671 76.547 1.00 3.93  99  M 1 
-ATOM   1542 H  HB2  . ALA M  1 100 ? 147.087 99.751  76.692 1.00 3.93  99  M 1 
-ATOM   1543 H  HB3  . ALA M  1 100 ? 146.559 100.585 77.936 1.00 3.93  99  M 1 
-ATOM   1544 N  N    . MET M  1 101 ? 146.875 103.575 78.018 1.00 3.66  100 M 1 
-ATOM   1545 C  CA   . MET M  1 101 ? 146.250 104.859 78.321 1.00 3.66  100 M 1 
-ATOM   1546 C  C    . MET M  1 101 ? 146.962 106.005 77.611 1.00 3.66  100 M 1 
-ATOM   1547 O  O    . MET M  1 101 ? 146.317 106.935 77.120 1.00 3.66  100 M 1 
-ATOM   1548 C  CB   . MET M  1 101 ? 146.231 105.092 79.833 1.00 3.66  100 M 1 
-ATOM   1549 C  CG   . MET M  1 101 ? 145.292 104.199 80.617 1.00 3.66  100 M 1 
-ATOM   1550 S  SD   . MET M  1 101 ? 143.559 104.519 80.234 1.00 3.66  100 M 1 
-ATOM   1551 C  CE   . MET M  1 101 ? 142.752 103.227 81.176 1.00 3.66  100 M 1 
-ATOM   1552 H  H    . MET M  1 101 ? 147.250 103.190 78.690 1.00 3.66  100 M 1 
-ATOM   1553 H  HA   . MET M  1 101 ? 145.330 104.834 78.013 1.00 3.66  100 M 1 
-ATOM   1554 H  HB2  . MET M  1 101 ? 147.126 104.958 80.182 1.00 3.66  100 M 1 
-ATOM   1555 H  HB3  . MET M  1 101 ? 145.954 106.006 80.000 1.00 3.66  100 M 1 
-ATOM   1556 H  HG2  . MET M  1 101 ? 145.479 103.273 80.397 1.00 3.66  100 M 1 
-ATOM   1557 H  HG3  . MET M  1 101 ? 145.427 104.340 81.567 1.00 3.66  100 M 1 
-ATOM   1558 H  HE1  . MET M  1 101 ? 141.803 103.421 81.221 1.00 3.66  100 M 1 
-ATOM   1559 H  HE2  . MET M  1 101 ? 142.900 102.372 80.743 1.00 3.66  100 M 1 
-ATOM   1560 H  HE3  . MET M  1 101 ? 143.121 103.207 82.073 1.00 3.66  100 M 1 
-ATOM   1561 N  N    . GLU M  1 102 ? 148.293 105.953 77.550 1.00 4.25  101 M 1 
-ATOM   1562 C  CA   . GLU M  1 102 ? 149.059 106.982 76.855 1.00 4.25  101 M 1 
-ATOM   1563 C  C    . GLU M  1 102 ? 148.734 106.993 75.366 1.00 4.25  101 M 1 
-ATOM   1564 O  O    . GLU M  1 102 ? 148.533 108.059 74.766 1.00 4.25  101 M 1 
-ATOM   1565 C  CB   . GLU M  1 102 ? 150.554 106.754 77.092 1.00 4.25  101 M 1 
-ATOM   1566 C  CG   . GLU M  1 102 ? 151.008 107.015 78.528 1.00 4.25  101 M 1 
-ATOM   1567 C  CD   . GLU M  1 102 ? 152.467 106.671 78.766 1.00 4.25  101 M 1 
-ATOM   1568 O  OE1  . GLU M  1 102 ? 153.102 106.091 77.863 1.00 4.25  101 M 1 
-ATOM   1569 O  OE2  . GLU M  1 102 ? 152.977 106.981 79.862 1.00 4.25  101 M 1 
-ATOM   1570 H  H    . GLU M  1 102 ? 148.774 105.332 77.901 1.00 4.25  101 M 1 
-ATOM   1571 H  HA   . GLU M  1 102 ? 148.837 107.850 77.227 1.00 4.25  101 M 1 
-ATOM   1572 H  HB2  . GLU M  1 102 ? 150.781 105.839 76.862 1.00 4.25  101 M 1 
-ATOM   1573 H  HB3  . GLU M  1 102 ? 151.049 107.359 76.518 1.00 4.25  101 M 1 
-ATOM   1574 H  HG2  . GLU M  1 102 ? 150.901 107.961 78.712 1.00 4.25  101 M 1 
-ATOM   1575 H  HG3  . GLU M  1 102 ? 150.471 106.507 79.156 1.00 4.25  101 M 1 
-ATOM   1576 N  N    . CYS M  1 103 ? 148.657 105.810 74.757 1.00 4.27  102 M 1 
-ATOM   1577 C  CA   . CYS M  1 103 ? 148.305 105.715 73.345 1.00 4.27  102 M 1 
-ATOM   1578 C  C    . CYS M  1 103 ? 146.880 106.192 73.098 1.00 4.27  102 M 1 
-ATOM   1579 O  O    . CYS M  1 103 ? 146.597 106.836 72.083 1.00 4.27  102 M 1 
-ATOM   1580 C  CB   . CYS M  1 103 ? 148.489 104.281 72.869 1.00 4.27  102 M 1 
-ATOM   1581 S  SG   . CYS M  1 103 ? 150.209 103.771 72.899 1.00 4.27  102 M 1 
-ATOM   1582 H  H    . CYS M  1 103 ? 148.795 105.055 75.144 1.00 4.27  102 M 1 
-ATOM   1583 H  HA   . CYS M  1 103 ? 148.905 106.272 72.824 1.00 4.27  102 M 1 
-ATOM   1584 H  HB2  . CYS M  1 103 ? 147.991 103.688 73.453 1.00 4.27  102 M 1 
-ATOM   1585 H  HB3  . CYS M  1 103 ? 148.161 104.199 71.960 1.00 4.27  102 M 1 
-ATOM   1586 H  HG   . CYS M  1 103 ? 150.444 103.312 73.983 1.00 4.27  102 M 1 
-ATOM   1587 N  N    . ALA M  1 104 ? 145.972 105.900 74.029 1.00 3.59  103 M 1 
-ATOM   1588 C  CA   . ALA M  1 104 ? 144.597 106.367 73.899 1.00 3.59  103 M 1 
-ATOM   1589 C  C    . ALA M  1 104 ? 144.523 107.884 74.011 1.00 3.59  103 M 1 
-ATOM   1590 O  O    . ALA M  1 104 ? 143.741 108.529 73.307 1.00 3.59  103 M 1 
-ATOM   1591 C  CB   . ALA M  1 104 ? 143.717 105.700 74.952 1.00 3.59  103 M 1 
-ATOM   1592 H  H    . ALA M  1 104 ? 146.139 105.455 74.746 1.00 3.59  103 M 1 
-ATOM   1593 H  HA   . ALA M  1 104 ? 144.259 106.114 73.026 1.00 3.59  103 M 1 
-ATOM   1594 H  HB1  . ALA M  1 104 ? 142.844 106.122 74.943 1.00 3.59  103 M 1 
-ATOM   1595 H  HB2  . ALA M  1 104 ? 143.625 104.758 74.741 1.00 3.59  103 M 1 
-ATOM   1596 H  HB3  . ALA M  1 104 ? 144.128 105.802 75.825 1.00 3.59  103 M 1 
-ATOM   1597 N  N    . LEU M  1 105 ? 145.337 108.468 74.889 1.00 3.78  104 M 1 
-ATOM   1598 C  CA   . LEU M  1 105 ? 145.427 109.922 74.991 1.00 3.78  104 M 1 
-ATOM   1599 C  C    . LEU M  1 105 ? 145.897 110.530 73.678 1.00 3.78  104 M 1 
-ATOM   1600 O  O    . LEU M  1 105 ? 145.317 111.505 73.182 1.00 3.78  104 M 1 
-ATOM   1601 C  CB   . LEU M  1 105 ? 146.367 110.302 76.139 1.00 3.78  104 M 1 
-ATOM   1602 C  CG   . LEU M  1 105 ? 146.670 111.778 76.392 1.00 3.78  104 M 1 
-ATOM   1603 C  CD1  . LEU M  1 105 ? 145.424 112.550 76.719 1.00 3.78  104 M 1 
-ATOM   1604 C  CD2  . LEU M  1 105 ? 147.682 111.933 77.520 1.00 3.78  104 M 1 
-ATOM   1605 H  H    . LEU M  1 105 ? 145.854 108.045 75.430 1.00 3.78  104 M 1 
-ATOM   1606 H  HA   . LEU M  1 105 ? 144.547 110.272 75.200 1.00 3.78  104 M 1 
-ATOM   1607 H  HB2  . LEU M  1 105 ? 145.973 109.969 76.960 1.00 3.78  104 M 1 
-ATOM   1608 H  HB3  . LEU M  1 105 ? 147.217 109.853 76.006 1.00 3.78  104 M 1 
-ATOM   1609 H  HG   . LEU M  1 105 ? 147.066 112.161 75.594 1.00 3.78  104 M 1 
-ATOM   1610 H  HD11 . LEU M  1 105 ? 145.649 113.493 76.738 1.00 3.78  104 M 1 
-ATOM   1611 H  HD12 . LEU M  1 105 ? 144.751 112.394 76.038 1.00 3.78  104 M 1 
-ATOM   1612 H  HD13 . LEU M  1 105 ? 145.089 112.268 77.584 1.00 3.78  104 M 1 
-ATOM   1613 H  HD21 . LEU M  1 105 ? 147.677 112.852 77.830 1.00 3.78  104 M 1 
-ATOM   1614 H  HD22 . LEU M  1 105 ? 147.440 111.344 78.251 1.00 3.78  104 M 1 
-ATOM   1615 H  HD23 . LEU M  1 105 ? 148.565 111.701 77.193 1.00 3.78  104 M 1 
-ATOM   1616 N  N    . HIS M  1 106 ? 146.934 109.922 73.114 1.00 4.28  105 M 1 
-ATOM   1617 C  CA   . HIS M  1 106 ? 147.520 110.383 71.834 1.00 4.28  105 M 1 
-ATOM   1618 C  C    . HIS M  1 106 ? 146.438 110.299 70.751 1.00 4.28  105 M 1 
-ATOM   1619 O  O    . HIS M  1 106 ? 146.286 111.244 70.023 1.00 4.28  105 M 1 
-ATOM   1620 C  CB   . HIS M  1 106 ? 148.773 109.591 71.459 1.00 4.28  105 M 1 
-ATOM   1621 C  CG   . HIS M  1 106 ? 149.411 110.133 70.226 1.00 4.28  105 M 1 
-ATOM   1622 N  ND1  . HIS M  1 106 ? 150.540 110.923 70.253 1.00 4.28  105 M 1 
-ATOM   1623 C  CD2  . HIS M  1 106 ? 149.036 110.055 68.935 1.00 4.28  105 M 1 
-ATOM   1624 C  CE1  . HIS M  1 106 ? 150.858 111.276 69.023 1.00 4.28  105 M 1 
-ATOM   1625 N  NE2  . HIS M  1 106 ? 149.945 110.764 68.197 1.00 4.28  105 M 1 
-ATOM   1626 H  H    . HIS M  1 106 ? 147.356 109.193 73.463 1.00 4.28  105 M 1 
-ATOM   1627 H  HA   . HIS M  1 106 ? 147.772 111.331 71.941 1.00 4.28  105 M 1 
-ATOM   1628 H  HB2  . HIS M  1 106 ? 149.416 109.629 72.202 1.00 4.28  105 M 1 
-ATOM   1629 H  HB3  . HIS M  1 106 ? 148.531 108.650 71.313 1.00 4.28  105 M 1 
-ATOM   1630 H  HD2  . HIS M  1 106 ? 148.293 109.590 68.597 1.00 4.28  105 M 1 
-ATOM   1631 H  HE1  . HIS M  1 106 ? 151.595 111.806 68.774 1.00 4.28  105 M 1 
-ATOM   1632 H  HE2  . HIS M  1 106 ? 149.939 110.854 67.325 1.00 4.28  105 M 1 
-ATOM   1633 N  N    . LEU M  1 107 ? 145.669 109.220 70.709 1.00 3.81  106 M 1 
-ATOM   1634 C  CA   . LEU M  1 107 ? 144.621 109.008 69.718 1.00 3.81  106 M 1 
-ATOM   1635 C  C    . LEU M  1 107 ? 143.511 110.042 69.856 1.00 3.81  106 M 1 
-ATOM   1636 O  O    . LEU M  1 107 ? 143.052 110.622 68.865 1.00 3.81  106 M 1 
-ATOM   1637 C  CB   . LEU M  1 107 ? 144.061 107.593 69.870 1.00 3.81  106 M 1 
-ATOM   1638 C  CG   . LEU M  1 107 ? 142.912 107.169 68.954 1.00 3.81  106 M 1 
-ATOM   1639 C  CD1  . LEU M  1 107 ? 143.350 107.247 67.519 1.00 3.81  106 M 1 
-ATOM   1640 C  CD2  . LEU M  1 107 ? 142.426 105.770 69.294 1.00 3.81  106 M 1 
-ATOM   1641 H  H    . LEU M  1 107 ? 145.758 108.572 71.268 1.00 3.81  106 M 1 
-ATOM   1642 H  HA   . LEU M  1 107 ? 145.012 109.084 68.834 1.00 3.81  106 M 1 
-ATOM   1643 H  HB2  . LEU M  1 107 ? 144.787 106.968 69.716 1.00 3.81  106 M 1 
-ATOM   1644 H  HB3  . LEU M  1 107 ? 143.748 107.493 70.783 1.00 3.81  106 M 1 
-ATOM   1645 H  HG   . LEU M  1 107 ? 142.159 107.768 69.075 1.00 3.81  106 M 1 
-ATOM   1646 H  HD11 . LEU M  1 107 ? 142.668 106.841 66.962 1.00 3.81  106 M 1 
-ATOM   1647 H  HD12 . LEU M  1 107 ? 143.463 108.179 67.276 1.00 3.81  106 M 1 
-ATOM   1648 H  HD13 . LEU M  1 107 ? 144.193 106.777 67.423 1.00 3.81  106 M 1 
-ATOM   1649 H  HD21 . LEU M  1 107 ? 141.544 105.640 68.911 1.00 3.81  106 M 1 
-ATOM   1650 H  HD22 . LEU M  1 107 ? 143.047 105.123 68.923 1.00 3.81  106 M 1 
-ATOM   1651 H  HD23 . LEU M  1 107 ? 142.374 105.669 70.257 1.00 3.81  106 M 1 
-ATOM   1652 N  N    . GLU M  1 108 ? 143.069 110.235 71.091 1.00 4.12  107 M 1 
-ATOM   1653 C  CA   . GLU M  1 108 ? 141.969 111.176 71.413 1.00 4.12  107 M 1 
-ATOM   1654 C  C    . GLU M  1 108 ? 142.399 112.588 70.991 1.00 4.12  107 M 1 
-ATOM   1655 O  O    . GLU M  1 108 ? 141.596 113.279 70.406 1.00 4.12  107 M 1 
-ATOM   1656 C  CB   . GLU M  1 108 ? 141.587 111.054 72.884 1.00 4.12  107 M 1 
-ATOM   1657 C  CG   . GLU M  1 108 ? 140.923 109.727 73.206 1.00 4.12  107 M 1 
-ATOM   1658 C  CD   . GLU M  1 108 ? 139.792 109.399 72.241 1.00 4.12  107 M 1 
-ATOM   1659 O  OE1  . GLU M  1 108 ? 138.811 110.143 72.219 1.00 4.12  107 M 1 
-ATOM   1660 O  OE2  . GLU M  1 108 ? 139.909 108.409 71.485 1.00 4.12  107 M 1 
-ATOM   1661 H  H    . GLU M  1 108 ? 143.492 109.895 71.822 1.00 4.12  107 M 1 
-ATOM   1662 H  HA   . GLU M  1 108 ? 141.187 110.921 70.871 1.00 4.12  107 M 1 
-ATOM   1663 H  HB2  . GLU M  1 108 ? 142.395 111.150 73.430 1.00 4.12  107 M 1 
-ATOM   1664 H  HB3  . GLU M  1 108 ? 140.975 111.784 73.114 1.00 4.12  107 M 1 
-ATOM   1665 H  HG2  . GLU M  1 108 ? 141.592 109.010 73.166 1.00 4.12  107 M 1 
-ATOM   1666 H  HG3  . GLU M  1 108 ? 140.564 109.755 74.118 1.00 4.12  107 M 1 
-ATOM   1667 N  N    . LYS M  1 109 ? 143.643 112.984 71.226 1.00 4.42  108 M 1 
-ATOM   1668 C  CA   . LYS M  1 109 ? 144.089 114.320 70.843 1.00 4.42  108 M 1 
-ATOM   1669 C  C    . LYS M  1 109 ? 144.176 114.453 69.325 1.00 4.42  108 M 1 
-ATOM   1670 O  O    . LYS M  1 109 ? 143.880 115.518 68.773 1.00 4.42  108 M 1 
-ATOM   1671 C  CB   . LYS M  1 109 ? 145.424 114.669 71.504 1.00 4.42  108 M 1 
-ATOM   1672 C  CG   . LYS M  1 109 ? 145.316 114.840 73.017 1.00 4.42  108 M 1 
-ATOM   1673 C  CD   . LYS M  1 109 ? 146.618 115.261 73.686 1.00 4.42  108 M 1 
-ATOM   1674 C  CE   . LYS M  1 109 ? 146.896 116.730 73.440 1.00 4.42  108 M 1 
-ATOM   1675 N  NZ   . LYS M  1 109 ? 148.084 117.253 74.164 1.00 4.42  108 M 1 
-ATOM   1676 H  H    . LYS M  1 109 ? 144.242 112.493 71.600 1.00 4.42  108 M 1 
-ATOM   1677 H  HA   . LYS M  1 109 ? 143.439 114.968 71.158 1.00 4.42  108 M 1 
-ATOM   1678 H  HB2  . LYS M  1 109 ? 146.060 113.958 71.328 1.00 4.42  108 M 1 
-ATOM   1679 H  HB3  . LYS M  1 109 ? 145.752 115.499 71.124 1.00 4.42  108 M 1 
-ATOM   1680 H  HG2  . LYS M  1 109 ? 144.645 115.513 73.209 1.00 4.42  108 M 1 
-ATOM   1681 H  HG3  . LYS M  1 109 ? 145.041 114.001 73.418 1.00 4.42  108 M 1 
-ATOM   1682 H  HD2  . LYS M  1 109 ? 146.543 115.125 74.644 1.00 4.42  108 M 1 
-ATOM   1683 H  HD3  . LYS M  1 109 ? 147.358 114.745 73.330 1.00 4.42  108 M 1 
-ATOM   1684 H  HE2  . LYS M  1 109 ? 147.028 116.881 72.491 1.00 4.42  108 M 1 
-ATOM   1685 H  HE3  . LYS M  1 109 ? 146.130 117.236 73.754 1.00 4.42  108 M 1 
-ATOM   1686 H  HZ1  . LYS M  1 109 ? 147.963 118.112 74.361 1.00 4.42  108 M 1 
-ATOM   1687 H  HZ2  . LYS M  1 109 ? 148.197 116.799 74.921 1.00 4.42  108 M 1 
-ATOM   1688 H  HZ3  . LYS M  1 109 ? 148.814 117.172 73.661 1.00 4.42  108 M 1 
-ATOM   1689 N  N    . SER M  1 110 ? 144.542 113.374 68.629 1.00 4.37  109 M 1 
-ATOM   1690 C  CA   . SER M  1 110 ? 144.545 113.402 67.165 1.00 4.37  109 M 1 
-ATOM   1691 C  C    . SER M  1 110 ? 143.136 113.581 66.609 1.00 4.37  109 M 1 
-ATOM   1692 O  O    . SER M  1 110 ? 142.915 114.377 65.684 1.00 4.37  109 M 1 
-ATOM   1693 C  CB   . SER M  1 110 ? 145.161 112.117 66.620 1.00 4.37  109 M 1 
-ATOM   1694 O  OG   . SER M  1 110 ? 144.341 111.009 66.927 1.00 4.37  109 M 1 
-ATOM   1695 H  H    . SER M  1 110 ? 144.787 112.625 68.973 1.00 4.37  109 M 1 
-ATOM   1696 H  HA   . SER M  1 110 ? 145.089 114.145 66.862 1.00 4.37  109 M 1 
-ATOM   1697 H  HB2  . SER M  1 110 ? 145.240 112.181 65.655 1.00 4.37  109 M 1 
-ATOM   1698 H  HB3  . SER M  1 110 ? 146.039 111.988 67.011 1.00 4.37  109 M 1 
-ATOM   1699 H  HG   . SER M  1 110 ? 144.057 111.077 67.715 1.00 4.37  109 M 1 
-ATOM   1700 N  N    . VAL M  1 111 ? 142.176 112.838 67.158 1.00 4.23  110 M 1 
-ATOM   1701 C  CA   . VAL M  1 111 ? 140.783 112.978 66.746 1.00 4.23  110 M 1 
-ATOM   1702 C  C    . VAL M  1 111 ? 140.298 114.398 67.013 1.00 4.23  110 M 1 
-ATOM   1703 O  O    . VAL M  1 111 ? 139.589 114.998 66.193 1.00 4.23  110 M 1 
-ATOM   1704 C  CB   . VAL M  1 111 ? 139.905 111.926 67.453 1.00 4.23  110 M 1 
-ATOM   1705 C  CG1  . VAL M  1 111 ? 138.430 112.153 67.153 1.00 4.23  110 M 1 
-ATOM   1706 C  CG2  . VAL M  1 111 ? 140.296 110.511 67.023 1.00 4.23  110 M 1 
-ATOM   1707 H  H    . VAL M  1 111 ? 142.302 112.255 67.777 1.00 4.23  110 M 1 
-ATOM   1708 H  HA   . VAL M  1 111 ? 140.727 112.817 65.791 1.00 4.23  110 M 1 
-ATOM   1709 H  HB   . VAL M  1 111 ? 140.028 111.997 68.412 1.00 4.23  110 M 1 
-ATOM   1710 H  HG11 . VAL M  1 111 ? 137.929 111.367 67.422 1.00 4.23  110 M 1 
-ATOM   1711 H  HG12 . VAL M  1 111 ? 138.098 112.918 67.649 1.00 4.23  110 M 1 
-ATOM   1712 H  HG13 . VAL M  1 111 ? 138.322 112.290 66.199 1.00 4.23  110 M 1 
-ATOM   1713 H  HG21 . VAL M  1 111 ? 139.830 109.881 67.595 1.00 4.23  110 M 1 
-ATOM   1714 H  HG22 . VAL M  1 111 ? 140.028 110.373 66.101 1.00 4.23  110 M 1 
-ATOM   1715 H  HG23 . VAL M  1 111 ? 141.253 110.372 67.097 1.00 4.23  110 M 1 
-ATOM   1716 N  N    . ASN M  1 112 ? 140.717 114.929 68.153 1.00 4.52  111 M 1 
-ATOM   1717 C  CA   . ASN M  1 112 ? 140.342 116.303 68.560 1.00 4.52  111 M 1 
-ATOM   1718 C  C    . ASN M  1 112 ? 140.887 117.288 67.517 1.00 4.52  111 M 1 
-ATOM   1719 O  O    . ASN M  1 112 ? 140.143 118.121 67.037 1.00 4.52  111 M 1 
-ATOM   1720 C  CB   . ASN M  1 112 ? 140.871 116.639 69.955 1.00 4.52  111 M 1 
-ATOM   1721 C  CG   . ASN M  1 112 ? 140.253 117.911 70.489 1.00 4.52  111 M 1 
-ATOM   1722 O  OD1  . ASN M  1 112 ? 139.121 118.212 70.161 1.00 4.52  111 M 1 
-ATOM   1723 N  ND2  . ASN M  1 112 ? 140.984 118.639 71.313 1.00 4.52  111 M 1 
-ATOM   1724 H  H    . ASN M  1 112 ? 141.351 114.540 68.678 1.00 4.52  111 M 1 
-ATOM   1725 H  HA   . ASN M  1 112 ? 139.358 116.369 68.580 1.00 4.52  111 M 1 
-ATOM   1726 H  HB2  . ASN M  1 112 ? 140.666 115.899 70.563 1.00 4.52  111 M 1 
-ATOM   1727 H  HB3  . ASN M  1 112 ? 141.843 116.744 69.913 1.00 4.52  111 M 1 
-ATOM   1728 H  HD21 . ASN M  1 112 ? 141.775 118.347 71.578 1.00 4.52  111 M 1 
-ATOM   1729 H  HD22 . ASN M  1 112 ? 140.683 119.419 71.599 1.00 4.52  111 M 1 
-ATOM   1730 N  N    . GLN M  1 113 ? 142.141 117.072 67.128 1.00 5.11  112 M 1 
-ATOM   1731 C  CA   . GLN M  1 113 ? 142.834 117.940 66.147 1.00 5.11  112 M 1 
-ATOM   1732 C  C    . GLN M  1 113 ? 142.073 117.860 64.820 1.00 5.11  112 M 1 
-ATOM   1733 O  O    . GLN M  1 113 ? 141.691 118.896 64.332 1.00 5.11  112 M 1 
-ATOM   1734 C  CB   . GLN M  1 113 ? 144.297 117.557 65.966 1.00 5.11  112 M 1 
-ATOM   1735 C  CG   . GLN M  1 113 ? 145.022 118.572 65.094 1.00 5.11  112 M 1 
-ATOM   1736 C  CD   . GLN M  1 113 ? 144.785 119.967 65.611 1.00 5.11  112 M 1 
-ATOM   1737 O  OE1  . GLN M  1 113 ? 145.184 120.306 66.717 1.00 5.11  112 M 1 
-ATOM   1738 N  NE2  . GLN M  1 113 ? 144.062 120.770 64.847 1.00 5.11  112 M 1 
-ATOM   1739 H  H    . GLN M  1 113 ? 142.599 116.316 67.344 1.00 5.11  112 M 1 
-ATOM   1740 H  HA   . GLN M  1 113 ? 142.790 118.868 66.475 1.00 5.11  112 M 1 
-ATOM   1741 H  HB2  . GLN M  1 113 ? 144.728 117.512 66.845 1.00 5.11  112 M 1 
-ATOM   1742 H  HB3  . GLN M  1 113 ? 144.348 116.671 65.551 1.00 5.11  112 M 1 
-ATOM   1743 H  HG2  . GLN M  1 113 ? 145.984 118.380 65.094 1.00 5.11  112 M 1 
-ATOM   1744 H  HG3  . GLN M  1 113 ? 144.696 118.505 64.171 1.00 5.11  112 M 1 
-ATOM   1745 H  HE21 . GLN M  1 113 ? 143.722 120.470 64.088 1.00 5.11  112 M 1 
-ATOM   1746 H  HE22 . GLN M  1 113 ? 143.918 121.606 65.096 1.00 5.11  112 M 1 
-ATOM   1747 N  N    . SER M  1 114 ? 141.629 116.668 64.416 0.55 4.90  113 M 1 
-ATOM   1748 C  CA   . SER M  1 114 ? 140.863 116.555 63.144 0.55 4.90  113 M 1 
-ATOM   1749 C  C    . SER M  1 114 ? 139.536 117.326 63.248 0.55 4.90  113 M 1 
-ATOM   1750 O  O    . SER M  1 114 ? 139.168 118.017 62.297 0.55 4.90  113 M 1 
-ATOM   1751 C  CB   . SER M  1 114 ? 140.631 115.110 62.773 0.55 4.90  113 M 1 
-ATOM   1752 O  OG   . SER M  1 114 ? 139.747 114.492 63.686 0.55 4.90  113 M 1 
-ATOM   1753 H  H    . SER M  1 114 ? 141.266 116.108 65.036 0.55 4.90  113 M 1 
-ATOM   1754 H  HA   . SER M  1 114 ? 141.406 116.977 62.424 0.55 4.90  113 M 1 
-ATOM   1755 H  HB2  . SER M  1 114 ? 140.252 115.063 61.866 0.55 4.90  113 M 1 
-ATOM   1756 H  HB3  . SER M  1 114 ? 141.490 114.631 62.771 0.55 4.90  113 M 1 
-ATOM   1757 H  HG   . SER M  1 114 ? 139.464 115.080 64.225 0.55 4.90  113 M 1 
-ATOM   1758 N  N    . LEU M  1 115 ? 138.859 117.253 64.392 1.00 4.69  114 M 1 
-ATOM   1759 C  CA   . LEU M  1 115 ? 137.594 117.954 64.591 1.00 4.69  114 M 1 
-ATOM   1760 C  C    . LEU M  1 115 ? 137.776 119.467 64.575 1.00 4.69  114 M 1 
-ATOM   1761 O  O    . LEU M  1 115 ? 136.914 120.196 64.076 1.00 4.69  114 M 1 
-ATOM   1762 C  CB   . LEU M  1 115 ? 136.965 117.506 65.904 1.00 4.69  114 M 1 
-ATOM   1763 C  CG   . LEU M  1 115 ? 136.436 116.074 65.961 1.00 4.69  114 M 1 
-ATOM   1764 C  CD1  . LEU M  1 115 ? 136.142 115.718 67.392 1.00 4.69  114 M 1 
-ATOM   1765 C  CD2  . LEU M  1 115 ? 135.185 115.889 65.113 1.00 4.69  114 M 1 
-ATOM   1766 H  H    . LEU M  1 115 ? 139.121 116.786 65.065 1.00 4.69  114 M 1 
-ATOM   1767 H  HA   . LEU M  1 115 ? 136.991 117.729 63.865 1.00 4.69  114 M 1 
-ATOM   1768 H  HB2  . LEU M  1 115 ? 137.632 117.597 66.602 1.00 4.69  114 M 1 
-ATOM   1769 H  HB3  . LEU M  1 115 ? 136.223 118.099 66.102 1.00 4.69  114 M 1 
-ATOM   1770 H  HG   . LEU M  1 115 ? 137.112 115.463 65.628 1.00 4.69  114 M 1 
-ATOM   1771 H  HD11 . LEU M  1 115 ? 135.645 114.886 67.426 1.00 4.69  114 M 1 
-ATOM   1772 H  HD12 . LEU M  1 115 ? 136.992 115.614 67.847 1.00 4.69  114 M 1 
-ATOM   1773 H  HD13 . LEU M  1 115 ? 135.636 116.432 67.811 1.00 4.69  114 M 1 
-ATOM   1774 H  HD21 . LEU M  1 115 ? 135.004 114.939 65.032 1.00 4.69  114 M 1 
-ATOM   1775 H  HD22 . LEU M  1 115 ? 134.437 116.323 65.552 1.00 4.69  114 M 1 
-ATOM   1776 H  HD23 . LEU M  1 115 ? 135.315 116.259 64.226 1.00 4.69  114 M 1 
-ATOM   1777 N  N    . LEU M  1 116 ? 138.878 119.960 65.131 1.00 5.05  115 M 1 
-ATOM   1778 C  CA   . LEU M  1 116 ? 139.138 121.397 65.104 1.00 5.05  115 M 1 
-ATOM   1779 C  C    . LEU M  1 116 ? 139.387 121.874 63.680 1.00 5.05  115 M 1 
-ATOM   1780 O  O    . LEU M  1 116 ? 138.920 122.949 63.282 1.00 5.05  115 M 1 
-ATOM   1781 C  CB   . LEU M  1 116 ? 140.322 121.733 66.011 1.00 5.05  115 M 1 
-ATOM   1782 C  CG   . LEU M  1 116 ? 140.104 121.561 67.520 1.00 5.05  115 M 1 
-ATOM   1783 C  CD1  . LEU M  1 116 ? 141.408 121.733 68.279 1.00 5.05  115 M 1 
-ATOM   1784 C  CD2  . LEU M  1 116 ? 139.056 122.534 68.048 1.00 5.05  115 M 1 
-ATOM   1785 H  H    . LEU M  1 116 ? 139.484 119.491 65.522 1.00 5.05  115 M 1 
-ATOM   1786 H  HA   . LEU M  1 116 ? 138.360 121.870 65.437 1.00 5.05  115 M 1 
-ATOM   1787 H  HB2  . LEU M  1 116 ? 141.064 121.161 65.761 1.00 5.05  115 M 1 
-ATOM   1788 H  HB3  . LEU M  1 116 ? 140.578 122.655 65.850 1.00 5.05  115 M 1 
-ATOM   1789 H  HG   . LEU M  1 116 ? 139.769 120.669 67.702 1.00 5.05  115 M 1 
-ATOM   1790 H  HD11 . LEU M  1 116 ? 141.268 121.446 69.195 1.00 5.05  115 M 1 
-ATOM   1791 H  HD12 . LEU M  1 116 ? 142.101 121.192 67.870 1.00 5.05  115 M 1 
-ATOM   1792 H  HD13 . LEU M  1 116 ? 141.673 122.666 68.255 1.00 5.05  115 M 1 
-ATOM   1793 H  HD21 . LEU M  1 116 ? 139.130 122.592 69.013 1.00 5.05  115 M 1 
-ATOM   1794 H  HD22 . LEU M  1 116 ? 139.204 123.408 67.653 1.00 5.05  115 M 1 
-ATOM   1795 H  HD23 . LEU M  1 116 ? 138.172 122.210 67.813 1.00 5.05  115 M 1 
-ATOM   1796 N  N    . GLU M  1 117 ? 140.102 121.074 62.890 1.00 6.09  116 M 1 
-ATOM   1797 C  CA   . GLU M  1 117 ? 140.283 121.391 61.476 1.00 6.09  116 M 1 
-ATOM   1798 C  C    . GLU M  1 117 ? 138.942 121.417 60.745 1.00 6.09  116 M 1 
-ATOM   1799 O  O    . GLU M  1 117 ? 138.692 122.295 59.908 1.00 6.09  116 M 1 
-ATOM   1800 C  CB   . GLU M  1 117 ? 141.244 120.379 60.849 1.00 6.09  116 M 1 
-ATOM   1801 C  CG   . GLU M  1 117 ? 142.676 120.511 61.372 1.00 6.09  116 M 1 
-ATOM   1802 C  CD   . GLU M  1 117 ? 143.615 119.439 60.848 1.00 6.09  116 M 1 
-ATOM   1803 O  OE1  . GLU M  1 117 ? 143.145 118.498 60.174 1.00 6.09  116 M 1 
-ATOM   1804 O  OE2  . GLU M  1 117 ? 144.829 119.532 61.124 1.00 6.09  116 M 1 
-ATOM   1805 H  H    . GLU M  1 117 ? 140.479 120.343 63.141 1.00 6.09  116 M 1 
-ATOM   1806 H  HA   . GLU M  1 117 ? 140.686 122.270 61.398 1.00 6.09  116 M 1 
-ATOM   1807 H  HB2  . GLU M  1 117 ? 140.938 119.480 61.047 1.00 6.09  116 M 1 
-ATOM   1808 H  HB3  . GLU M  1 117 ? 141.261 120.514 59.889 1.00 6.09  116 M 1 
-ATOM   1809 H  HG2  . GLU M  1 117 ? 143.029 121.370 61.094 1.00 6.09  116 M 1 
-ATOM   1810 H  HG3  . GLU M  1 117 ? 142.679 120.468 62.341 1.00 6.09  116 M 1 
-ATOM   1811 N  N    . LEU M  1 118 ? 138.050 120.493 61.095 1.00 5.44  117 M 1 
-ATOM   1812 C  CA   . LEU M  1 118 ? 136.683 120.381 60.513 1.00 5.44  117 M 1 
-ATOM   1813 C  C    . LEU M  1 118 ? 135.896 121.645 60.854 1.00 5.44  117 M 1 
-ATOM   1814 O  O    . LEU M  1 118 ? 135.268 122.209 59.984 1.00 5.44  117 M 1 
-ATOM   1815 C  CB   . LEU M  1 118 ? 136.001 119.162 61.135 1.00 5.44  117 M 1 
-ATOM   1816 C  CG   . LEU M  1 118 ? 135.154 118.291 60.216 1.00 5.44  117 M 1 
-ATOM   1817 C  CD1  . LEU M  1 118 ? 134.146 117.487 61.035 1.00 5.44  117 M 1 
-ATOM   1818 C  CD2  . LEU M  1 118 ? 134.466 119.108 59.137 1.00 5.44  117 M 1 
-ATOM   1819 H  H    . LEU M  1 118 ? 138.182 119.944 61.808 1.00 5.44  117 M 1 
-ATOM   1820 H  HA   . LEU M  1 118 ? 136.748 120.280 59.536 1.00 5.44  117 M 1 
-ATOM   1821 H  HB2  . LEU M  1 118 ? 136.695 118.598 61.532 1.00 5.44  117 M 1 
-ATOM   1822 H  HB3  . LEU M  1 118 ? 135.431 119.476 61.865 1.00 5.44  117 M 1 
-ATOM   1823 H  HG   . LEU M  1 118 ? 135.758 117.649 59.768 1.00 5.44  117 M 1 
-ATOM   1824 H  HD11 . LEU M  1 118 ? 134.618 116.943 61.689 1.00 5.44  117 M 1 
-ATOM   1825 H  HD12 . LEU M  1 118 ? 133.634 116.908 60.443 1.00 5.44  117 M 1 
-ATOM   1826 H  HD13 . LEU M  1 118 ? 133.542 118.095 61.495 1.00 5.44  117 M 1 
-ATOM   1827 H  HD21 . LEU M  1 118 ? 133.946 118.518 58.565 1.00 5.44  117 M 1 
-ATOM   1828 H  HD22 . LEU M  1 118 ? 133.876 119.761 59.551 1.00 5.44  117 M 1 
-ATOM   1829 H  HD23 . LEU M  1 118 ? 135.136 119.569 58.602 1.00 5.44  117 M 1 
-ATOM   1830 N  N    . HIS M  1 119 ? 135.947 122.064 62.122 1.00 5.74  118 M 1 
-ATOM   1831 C  CA   . HIS M  1 119 ? 135.252 123.284 62.608 1.00 5.74  118 M 1 
-ATOM   1832 C  C    . HIS M  1 119 ? 135.812 124.508 61.869 1.00 5.74  118 M 1 
-ATOM   1833 O  O    . HIS M  1 119 ? 135.030 125.369 61.545 1.00 5.74  118 M 1 
-ATOM   1834 C  CB   . HIS M  1 119 ? 135.357 123.419 64.135 1.00 5.74  118 M 1 
-ATOM   1835 C  CG   . HIS M  1 119 ? 134.535 124.536 64.685 1.00 5.74  118 M 1 
-ATOM   1836 N  ND1  . HIS M  1 119 ? 134.975 125.837 64.658 1.00 5.74  118 M 1 
-ATOM   1837 C  CD2  . HIS M  1 119 ? 133.302 124.564 65.235 1.00 5.74  118 M 1 
-ATOM   1838 C  CE1  . HIS M  1 119 ? 134.060 126.618 65.183 1.00 5.74  118 M 1 
-ATOM   1839 N  NE2  . HIS M  1 119 ? 133.035 125.861 65.563 1.00 5.74  118 M 1 
-ATOM   1840 H  H    . HIS M  1 119 ? 136.410 121.635 62.778 1.00 5.74  118 M 1 
-ATOM   1841 H  HA   . HIS M  1 119 ? 134.298 123.198 62.373 1.00 5.74  118 M 1 
-ATOM   1842 H  HB2  . HIS M  1 119 ? 135.068 122.576 64.550 1.00 5.74  118 M 1 
-ATOM   1843 H  HB3  . HIS M  1 119 ? 136.298 123.565 64.378 1.00 5.74  118 M 1 
-ATOM   1844 H  HD1  . HIS M  1 119 ? 135.747 126.104 64.341 1.00 5.74  118 M 1 
-ATOM   1845 H  HD2  . HIS M  1 119 ? 132.745 123.826 65.397 1.00 5.74  118 M 1 
-ATOM   1846 H  HE1  . HIS M  1 119 ? 134.129 127.551 65.291 1.00 5.74  118 M 1 
-ATOM   1847 H  HE2  . HIS M  1 119 ? 132.296 126.153 65.935 1.00 5.74  118 M 1 
-ATOM   1848 N  N    . LYS M  1 120 ? 137.117 124.588 61.642 1.00 6.94  119 M 1 
-ATOM   1849 C  CA   . LYS M  1 120 ? 137.704 125.731 60.953 1.00 6.94  119 M 1 
-ATOM   1850 C  C    . LYS M  1 120 ? 137.252 125.769 59.501 1.00 6.94  119 M 1 
-ATOM   1851 O  O    . LYS M  1 120 ? 136.968 126.841 58.957 1.00 6.94  119 M 1 
-ATOM   1852 C  CB   . LYS M  1 120 ? 139.226 125.668 61.063 1.00 6.94  119 M 1 
-ATOM   1853 C  CG   . LYS M  1 120 ? 139.965 126.875 60.528 1.00 6.94  119 M 1 
-ATOM   1854 C  CD   . LYS M  1 120 ? 141.474 126.717 60.664 1.00 6.94  119 M 1 
-ATOM   1855 C  CE   . LYS M  1 120 ? 141.924 126.836 62.124 1.00 6.94  119 M 1 
-ATOM   1856 N  NZ   . LYS M  1 120 ? 143.405 126.855 62.278 1.00 6.94  119 M 1 
-ATOM   1857 H  H    . LYS M  1 120 ? 137.682 123.981 61.870 1.00 6.94  119 M 1 
-ATOM   1858 H  HA   . LYS M  1 120 ? 137.406 126.548 61.382 1.00 6.94  119 M 1 
-ATOM   1859 H  HB2  . LYS M  1 120 ? 139.445 125.586 62.004 1.00 6.94  119 M 1 
-ATOM   1860 H  HB3  . LYS M  1 120 ? 139.553 124.888 60.587 1.00 6.94  119 M 1 
-ATOM   1861 H  HG2  . LYS M  1 120 ? 139.763 126.981 59.585 1.00 6.94  119 M 1 
-ATOM   1862 H  HG3  . LYS M  1 120 ? 139.697 127.666 61.021 1.00 6.94  119 M 1 
-ATOM   1863 H  HD2  . LYS M  1 120 ? 141.736 125.844 60.333 1.00 6.94  119 M 1 
-ATOM   1864 H  HD3  . LYS M  1 120 ? 141.916 127.413 60.152 1.00 6.94  119 M 1 
-ATOM   1865 H  HE2  . LYS M  1 120 ? 141.562 127.647 62.515 1.00 6.94  119 M 1 
-ATOM   1866 H  HE3  . LYS M  1 120 ? 141.600 126.065 62.615 1.00 6.94  119 M 1 
-ATOM   1867 H  HZ1  . LYS M  1 120 ? 143.619 127.107 63.104 1.00 6.94  119 M 1 
-ATOM   1868 H  HZ2  . LYS M  1 120 ? 143.740 126.045 62.127 1.00 6.94  119 M 1 
-ATOM   1869 H  HZ3  . LYS M  1 120 ? 143.762 127.429 61.699 1.00 6.94  119 M 1 
-ATOM   1870 N  N    . LEU M  1 121 ? 137.154 124.601 58.866 1.00 6.89  120 M 1 
-ATOM   1871 C  CA   . LEU M  1 121 ? 136.638 124.530 57.503 1.00 6.89  120 M 1 
-ATOM   1872 C  C    . LEU M  1 121 ? 135.186 124.986 57.441 1.00 6.89  120 M 1 
-ATOM   1873 O  O    . LEU M  1 121 ? 134.803 125.757 56.555 1.00 6.89  120 M 1 
-ATOM   1874 C  CB   . LEU M  1 121 ? 136.786 123.102 56.978 1.00 6.89  120 M 1 
-ATOM   1875 C  CG   . LEU M  1 121 ? 136.318 122.766 55.565 1.00 6.89  120 M 1 
-ATOM   1876 C  CD1  . LEU M  1 121 ? 137.080 123.577 54.538 1.00 6.89  120 M 1 
-ATOM   1877 C  CD2  . LEU M  1 121 ? 136.493 121.280 55.308 1.00 6.89  120 M 1 
-ATOM   1878 H  H    . LEU M  1 121 ? 137.359 123.837 59.205 1.00 6.89  120 M 1 
-ATOM   1879 H  HA   . LEU M  1 121 ? 137.162 125.118 56.936 1.00 6.89  120 M 1 
-ATOM   1880 H  HB2  . LEU M  1 121 ? 137.730 122.882 57.011 1.00 6.89  120 M 1 
-ATOM   1881 H  HB3  . LEU M  1 121 ? 136.308 122.511 57.580 1.00 6.89  120 M 1 
-ATOM   1882 H  HG   . LEU M  1 121 ? 135.373 122.969 55.487 1.00 6.89  120 M 1 
-ATOM   1883 H  HD11 . LEU M  1 121 ? 136.899 123.221 53.654 1.00 6.89  120 M 1 
-ATOM   1884 H  HD12 . LEU M  1 121 ? 136.791 124.502 54.586 1.00 6.89  120 M 1 
-ATOM   1885 H  HD13 . LEU M  1 121 ? 138.029 123.518 54.730 1.00 6.89  120 M 1 
-ATOM   1886 H  HD21 . LEU M  1 121 ? 136.305 121.089 54.376 1.00 6.89  120 M 1 
-ATOM   1887 H  HD22 . LEU M  1 121 ? 137.408 121.035 55.519 1.00 6.89  120 M 1 
-ATOM   1888 H  HD23 . LEU M  1 121 ? 135.882 120.783 55.875 1.00 6.89  120 M 1 
-ATOM   1889 N  N    . ALA M  1 122 ? 134.366 124.518 58.380 1.00 6.56  121 M 1 
-ATOM   1890 C  CA   . ALA M  1 122 ? 132.956 124.884 58.403 1.00 6.56  121 M 1 
-ATOM   1891 C  C    . ALA M  1 122 ? 132.772 126.373 58.681 1.00 6.56  121 M 1 
-ATOM   1892 O  O    . ALA M  1 122 ? 131.834 126.996 58.172 1.00 6.56  121 M 1 
-ATOM   1893 C  CB   . ALA M  1 122 ? 132.228 124.038 59.443 1.00 6.56  121 M 1 
-ATOM   1894 H  H    . ALA M  1 122 ? 134.599 123.980 59.009 1.00 6.56  121 M 1 
-ATOM   1895 H  HA   . ALA M  1 122 ? 132.566 124.688 57.537 1.00 6.56  121 M 1 
-ATOM   1896 H  HB1  . ALA M  1 122 ? 131.302 124.321 59.497 1.00 6.56  121 M 1 
-ATOM   1897 H  HB2  . ALA M  1 122 ? 132.279 123.107 59.175 1.00 6.56  121 M 1 
-ATOM   1898 H  HB3  . ALA M  1 122 ? 132.657 124.155 60.305 1.00 6.56  121 M 1 
-ATOM   1899 N  N    . THR M  1 123 ? 133.659 126.961 59.484 1.00 7.31  122 M 1 
-ATOM   1900 C  CA   . THR M  1 123 ? 133.606 128.398 59.721 1.00 7.31  122 M 1 
-ATOM   1901 C  C    . THR M  1 123 ? 134.046 129.166 58.482 1.00 7.31  122 M 1 
-ATOM   1902 O  O    . THR M  1 123 ? 133.495 130.227 58.173 1.00 7.31  122 M 1 
-ATOM   1903 C  CB   . THR M  1 123 ? 134.470 128.769 60.928 1.00 7.31  122 M 1 
-ATOM   1904 O  OG1  . THR M  1 123 ? 133.960 128.120 62.097 1.00 7.31  122 M 1 
-ATOM   1905 C  CG2  . THR M  1 123 ? 134.483 130.277 61.145 1.00 7.31  122 M 1 
-ATOM   1906 H  H    . THR M  1 123 ? 134.302 126.556 59.886 1.00 7.31  122 M 1 
-ATOM   1907 H  HA   . THR M  1 123 ? 132.694 128.650 59.934 1.00 7.31  122 M 1 
-ATOM   1908 H  HB   . THR M  1 123 ? 135.385 128.481 60.782 1.00 7.31  122 M 1 
-ATOM   1909 H  HG1  . THR M  1 123 ? 133.261 127.701 61.895 1.00 7.31  122 M 1 
-ATOM   1910 H  HG21 . THR M  1 123 ? 134.748 130.484 62.055 1.00 7.31  122 M 1 
-ATOM   1911 H  HG22 . THR M  1 123 ? 135.113 130.697 60.539 1.00 7.31  122 M 1 
-ATOM   1912 H  HG23 . THR M  1 123 ? 133.599 130.644 60.988 1.00 7.31  122 M 1 
-ATOM   1913 N  N    . ASP M  1 124 ? 135.030 128.636 57.753 1.00 8.30  123 M 1 
-ATOM   1914 C  CA   . ASP M  1 124 ? 135.501 129.298 56.541 1.00 8.30  123 M 1 
-ATOM   1915 C  C    . ASP M  1 124 ? 134.428 129.291 55.460 1.00 8.30  123 M 1 
-ATOM   1916 O  O    . ASP M  1 124 ? 134.339 130.227 54.657 1.00 8.30  123 M 1 
-ATOM   1917 C  CB   . ASP M  1 124 ? 136.770 128.620 56.028 1.00 8.30  123 M 1 
-ATOM   1918 C  CG   . ASP M  1 124 ? 137.366 129.322 54.822 1.00 8.30  123 M 1 
-ATOM   1919 O  OD1  . ASP M  1 124 ? 136.811 130.351 54.385 1.00 8.30  123 M 1 
-ATOM   1920 O  OD2  . ASP M  1 124 ? 138.392 128.834 54.304 1.00 8.30  123 M 1 
-ATOM   1921 H  H    . ASP M  1 124 ? 135.429 127.895 57.930 1.00 8.30  123 M 1 
-ATOM   1922 H  HA   . ASP M  1 124 ? 135.715 130.220 56.753 1.00 8.30  123 M 1 
-ATOM   1923 H  HB2  . ASP M  1 124 ? 137.433 128.611 56.737 1.00 8.30  123 M 1 
-ATOM   1924 H  HB3  . ASP M  1 124 ? 136.561 127.710 55.765 1.00 8.30  123 M 1 
-ATOM   1925 N  N    . LYS M  1 125 ? 133.639 128.218 55.448 1.00 7.98  124 M 1 
-ATOM   1926 C  CA   . LYS M  1 125 ? 132.537 127.992 54.479 1.00 7.98  124 M 1 
-ATOM   1927 C  C    . LYS M  1 125 ? 131.232 128.616 54.993 1.00 7.98  124 M 1 
-ATOM   1928 O  O    . LYS M  1 125 ? 130.244 128.495 54.287 1.00 7.98  124 M 1 
-ATOM   1929 C  CB   . LYS M  1 125 ? 132.390 126.495 54.199 1.00 7.98  124 M 1 
-ATOM   1930 C  CG   . LYS M  1 125 ? 133.616 125.856 53.570 1.00 7.98  124 M 1 
-ATOM   1931 C  CD   . LYS M  1 125 ? 134.148 126.682 52.423 1.00 7.98  124 M 1 
-ATOM   1932 C  CE   . LYS M  1 125 ? 135.243 126.000 51.635 1.00 7.98  124 M 1 
-ATOM   1933 N  NZ   . LYS M  1 125 ? 135.481 126.687 50.345 1.00 7.98  124 M 1 
-ATOM   1934 H  H    . LYS M  1 125 ? 133.694 127.571 56.087 1.00 7.98  124 M 1 
-ATOM   1935 H  HA   . LYS M  1 125 ? 132.780 128.441 53.637 1.00 7.98  124 M 1 
-ATOM   1936 H  HB2  . LYS M  1 125 ? 132.195 126.037 55.044 1.00 7.98  124 M 1 
-ATOM   1937 H  HB3  . LYS M  1 125 ? 131.625 126.363 53.602 1.00 7.98  124 M 1 
-ATOM   1938 H  HG2  . LYS M  1 125 ? 134.314 125.758 54.252 1.00 7.98  124 M 1 
-ATOM   1939 H  HG3  . LYS M  1 125 ? 133.380 124.961 53.244 1.00 7.98  124 M 1 
-ATOM   1940 H  HD2  . LYS M  1 125 ? 133.408 126.894 51.815 1.00 7.98  124 M 1 
-ATOM   1941 H  HD3  . LYS M  1 125 ? 134.496 127.528 52.777 1.00 7.98  124 M 1 
-ATOM   1942 H  HE2  . LYS M  1 125 ? 136.069 126.000 52.154 1.00 7.98  124 M 1 
-ATOM   1943 H  HE3  . LYS M  1 125 ? 134.993 125.073 51.461 1.00 7.98  124 M 1 
-ATOM   1944 H  HZ1  . LYS M  1 125 ? 136.152 126.274 49.896 1.00 7.98  124 M 1 
-ATOM   1945 H  HZ2  . LYS M  1 125 ? 134.728 126.664 49.841 1.00 7.98  124 M 1 
-ATOM   1946 H  HZ3  . LYS M  1 125 ? 135.712 127.551 50.495 1.00 7.98  124 M 1 
-ATOM   1947 N  N    . ASN M  1 126 ? 131.229 129.276 56.154 1.00 8.52  125 M 1 
-ATOM   1948 C  CA   . ASN M  1 126 ? 130.015 129.901 56.741 1.00 8.52  125 M 1 
-ATOM   1949 C  C    . ASN M  1 126 ? 128.888 128.867 56.820 1.00 8.52  125 M 1 
-ATOM   1950 O  O    . ASN M  1 126 ? 127.810 129.160 56.312 1.00 8.52  125 M 1 
-ATOM   1951 C  CB   . ASN M  1 126 ? 129.529 131.135 55.978 1.00 8.52  125 M 1 
-ATOM   1952 C  CG   . ASN M  1 126 ? 130.525 132.269 56.008 1.00 8.52  125 M 1 
-ATOM   1953 O  OD1  . ASN M  1 126 ? 130.814 132.840 54.977 1.00 8.52  125 M 1 
-ATOM   1954 N  ND2  . ASN M  1 126 ? 131.085 132.562 57.168 1.00 8.52  125 M 1 
-ATOM   1955 H  H    . ASN M  1 126 ? 131.987 129.495 56.603 1.00 8.52  125 M 1 
-ATOM   1956 H  HA   . ASN M  1 126 ? 130.235 130.189 57.658 1.00 8.52  125 M 1 
-ATOM   1957 H  HB2  . ASN M  1 126 ? 129.357 130.885 55.047 1.00 8.52  125 M 1 
-ATOM   1958 H  HB3  . ASN M  1 126 ? 128.685 131.439 56.371 1.00 8.52  125 M 1 
-ATOM   1959 H  HD21 . ASN M  1 126 ? 130.925 132.059 57.876 1.00 8.52  125 M 1 
-ATOM   1960 H  HD22 . ASN M  1 126 ? 131.621 133.262 57.235 1.00 8.52  125 M 1 
-ATOM   1961 N  N    . ASP M  1 127 ? 129.169 127.682 57.357 1.00 6.70  126 M 1 
-ATOM   1962 C  CA   . ASP M  1 127 ? 128.151 126.617 57.571 1.00 6.70  126 M 1 
-ATOM   1963 C  C    . ASP M  1 127 ? 127.847 126.621 59.071 1.00 6.70  126 M 1 
-ATOM   1964 O  O    . ASP M  1 127 ? 128.430 125.802 59.748 1.00 6.70  126 M 1 
-ATOM   1965 C  CB   . ASP M  1 127 ? 128.649 125.263 57.062 1.00 6.70  126 M 1 
-ATOM   1966 C  CG   . ASP M  1 127 ? 127.592 124.162 57.047 1.00 6.70  126 M 1 
-ATOM   1967 O  OD1  . ASP M  1 127 ? 126.669 124.198 57.869 1.00 6.70  126 M 1 
-ATOM   1968 O  OD2  . ASP M  1 127 ? 127.711 123.274 56.207 1.00 6.70  126 M 1 
-ATOM   1969 H  H    . ASP M  1 127 ? 130.003 127.458 57.645 1.00 6.70  126 M 1 
-ATOM   1970 H  HA   . ASP M  1 127 ? 127.350 126.846 57.064 1.00 6.70  126 M 1 
-ATOM   1971 H  HB2  . ASP M  1 127 ? 128.987 125.374 56.150 1.00 6.70  126 M 1 
-ATOM   1972 H  HB3  . ASP M  1 127 ? 129.391 124.967 57.628 1.00 6.70  126 M 1 
-ATOM   1973 N  N    . PRO M  1 128 ? 126.965 127.479 59.619 1.00 5.77  127 M 1 
-ATOM   1974 C  CA   . PRO M  1 128 ? 126.741 127.524 61.065 1.00 5.77  127 M 1 
-ATOM   1975 C  C    . PRO M  1 128 ? 126.225 126.213 61.679 1.00 5.77  127 M 1 
-ATOM   1976 O  O    . PRO M  1 128 ? 126.600 125.891 62.754 1.00 5.77  127 M 1 
-ATOM   1977 C  CB   . PRO M  1 128 ? 125.692 128.634 61.255 1.00 5.77  127 M 1 
-ATOM   1978 C  CG   . PRO M  1 128 ? 125.083 128.814 59.877 1.00 5.77  127 M 1 
-ATOM   1979 C  CD   . PRO M  1 128 ? 126.196 128.501 58.906 1.00 5.77  127 M 1 
-ATOM   1980 H  HA   . PRO M  1 128 ? 127.581 127.794 61.513 1.00 5.77  127 M 1 
-ATOM   1981 H  HB2  . PRO M  1 128 ? 125.010 128.365 61.906 1.00 5.77  127 M 1 
-ATOM   1982 H  HB3  . PRO M  1 128 ? 126.113 129.466 61.561 1.00 5.77  127 M 1 
-ATOM   1983 H  HG2  . PRO M  1 128 ? 124.330 128.202 59.749 1.00 5.77  127 M 1 
-ATOM   1984 H  HG3  . PRO M  1 128 ? 124.766 129.732 59.755 1.00 5.77  127 M 1 
-ATOM   1985 H  HD2  . PRO M  1 128 ? 125.845 128.154 58.065 1.00 5.77  127 M 1 
-ATOM   1986 H  HD3  . PRO M  1 128 ? 126.741 129.289 58.725 1.00 5.77  127 M 1 
-ATOM   1987 N  N    . HIS M  1 129 ? 125.348 125.514 60.982 1.00 5.02  128 M 1 
-ATOM   1988 C  CA   . HIS M  1 129 ? 124.765 124.273 61.476 1.00 5.02  128 M 1 
-ATOM   1989 C  C    . HIS M  1 129 ? 125.834 123.227 61.751 1.00 5.02  128 M 1 
-ATOM   1990 O  O    . HIS M  1 129 ? 125.834 122.585 62.805 1.00 5.02  128 M 1 
-ATOM   1991 C  CB   . HIS M  1 129 ? 123.744 123.740 60.480 1.00 5.02  128 M 1 
-ATOM   1992 C  CG   . HIS M  1 129 ? 123.184 122.415 60.872 1.00 5.02  128 M 1 
-ATOM   1993 N  ND1  . HIS M  1 129 ? 123.741 121.229 60.452 1.00 5.02  128 M 1 
-ATOM   1994 C  CD2  . HIS M  1 129 ? 122.173 122.082 61.706 1.00 5.02  128 M 1 
-ATOM   1995 C  CE1  . HIS M  1 129 ? 123.067 120.221 60.972 1.00 5.02  128 M 1 
-ATOM   1996 N  NE2  . HIS M  1 129 ? 122.113 120.712 61.739 1.00 5.02  128 M 1 
-ATOM   1997 H  H    . HIS M  1 129 ? 125.099 125.746 60.192 1.00 5.02  128 M 1 
-ATOM   1998 H  HA   . HIS M  1 129 ? 124.296 124.455 62.305 1.00 5.02  128 M 1 
-ATOM   1999 H  HB2  . HIS M  1 129 ? 123.005 124.365 60.417 1.00 5.02  128 M 1 
-ATOM   2000 H  HB3  . HIS M  1 129 ? 124.156 123.652 59.606 1.00 5.02  128 M 1 
-ATOM   2001 H  HD2  . HIS M  1 129 ? 121.611 122.670 62.158 1.00 5.02  128 M 1 
-ATOM   2002 H  HE1  . HIS M  1 129 ? 123.240 119.319 60.828 1.00 5.02  128 M 1 
-ATOM   2003 H  HE2  . HIS M  1 129 ? 121.547 120.247 62.189 1.00 5.02  128 M 1 
-ATOM   2004 N  N    . LEU M  1 130 ? 126.756 123.052 60.813 1.00 5.28  129 M 1 
-ATOM   2005 C  CA   . LEU M  1 130 ? 127.830 122.084 60.980 1.00 5.28  129 M 1 
-ATOM   2006 C  C    . LEU M  1 130 ? 128.739 122.462 62.142 1.00 5.28  129 M 1 
-ATOM   2007 O  O    . LEU M  1 130 ? 129.133 121.600 62.940 1.00 5.28  129 M 1 
-ATOM   2008 C  CB   . LEU M  1 130 ? 128.616 121.985 59.676 1.00 5.28  129 M 1 
-ATOM   2009 C  CG   . LEU M  1 130 ? 129.788 121.014 59.622 1.00 5.28  129 M 1 
-ATOM   2010 C  CD1  . LEU M  1 130 ? 129.324 119.615 59.936 1.00 5.28  129 M 1 
-ATOM   2011 C  CD2  . LEU M  1 130 ? 130.428 121.058 58.252 1.00 5.28  129 M 1 
-ATOM   2012 H  H    . LEU M  1 130 ? 126.778 123.490 60.073 1.00 5.28  129 M 1 
-ATOM   2013 H  HA   . LEU M  1 130 ? 127.435 121.218 61.169 1.00 5.28  129 M 1 
-ATOM   2014 H  HB2  . LEU M  1 130 ? 128.001 121.743 58.966 1.00 5.28  129 M 1 
-ATOM   2015 H  HB3  . LEU M  1 130 ? 128.971 122.866 59.479 1.00 5.28  129 M 1 
-ATOM   2016 H  HG   . LEU M  1 130 ? 130.459 121.278 60.271 1.00 5.28  129 M 1 
-ATOM   2017 H  HD11 . LEU M  1 130 ? 129.948 118.980 59.550 1.00 5.28  129 M 1 
-ATOM   2018 H  HD12 . LEU M  1 130 ? 129.297 119.505 60.899 1.00 5.28  129 M 1 
-ATOM   2019 H  HD13 . LEU M  1 130 ? 128.439 119.477 59.562 1.00 5.28  129 M 1 
-ATOM   2020 H  HD21 . LEU M  1 130 ? 131.261 120.562 58.278 1.00 5.28  129 M 1 
-ATOM   2021 H  HD22 . LEU M  1 130 ? 129.823 120.652 57.612 1.00 5.28  129 M 1 
-ATOM   2022 H  HD23 . LEU M  1 130 ? 130.597 121.979 57.999 1.00 5.28  129 M 1 
-ATOM   2023 N  N    . CYS M  1 131 ? 129.088 123.745 62.240 1.00 5.91  130 M 1 
-ATOM   2024 C  CA   . CYS M  1 131 ? 129.904 124.227 63.347 1.00 5.91  130 M 1 
-ATOM   2025 C  C    . CYS M  1 131 ? 129.253 123.901 64.682 1.00 5.91  130 M 1 
-ATOM   2026 O  O    . CYS M  1 131 ? 129.891 123.335 65.574 1.00 5.91  130 M 1 
-ATOM   2027 C  CB   . CYS M  1 131 ? 130.131 125.729 63.203 1.00 5.91  130 M 1 
-ATOM   2028 S  SG   . CYS M  1 131 ? 131.134 126.159 61.782 1.00 5.91  130 M 1 
-ATOM   2029 H  H    . CYS M  1 131 ? 128.856 124.353 61.678 1.00 5.91  130 M 1 
-ATOM   2030 H  HA   . CYS M  1 131 ? 130.777 123.805 63.314 1.00 5.91  130 M 1 
-ATOM   2031 H  HB2  . CYS M  1 131 ? 129.273 126.171 63.104 1.00 5.91  130 M 1 
-ATOM   2032 H  HB3  . CYS M  1 131 ? 130.578 126.060 63.998 1.00 5.91  130 M 1 
-ATOM   2033 H  HG   . CYS M  1 131 ? 130.449 126.104 60.798 1.00 5.91  130 M 1 
-ATOM   2034 N  N    . ASP M  1 132 ? 127.967 124.217 64.820 1.00 5.48  131 M 1 
-ATOM   2035 C  CA   . ASP M  1 132 ? 127.281 123.991 66.084 1.00 5.48  131 M 1 
-ATOM   2036 C  C    . ASP M  1 132 ? 127.145 122.505 66.376 1.00 5.48  131 M 1 
-ATOM   2037 O  O    . ASP M  1 132 ? 127.222 122.085 67.531 1.00 5.48  131 M 1 
-ATOM   2038 C  CB   . ASP M  1 132 ? 125.909 124.656 66.064 1.00 5.48  131 M 1 
-ATOM   2039 C  CG   . ASP M  1 132 ? 125.215 124.578 67.402 1.00 5.48  131 M 1 
-ATOM   2040 O  OD1  . ASP M  1 132 ? 125.634 125.300 68.328 1.00 5.48  131 M 1 
-ATOM   2041 O  OD2  . ASP M  1 132 ? 124.254 123.795 67.528 1.00 5.48  131 M 1 
-ATOM   2042 H  H    . ASP M  1 132 ? 127.475 124.553 64.200 1.00 5.48  131 M 1 
-ATOM   2043 H  HA   . ASP M  1 132 ? 127.803 124.396 66.794 1.00 5.48  131 M 1 
-ATOM   2044 H  HB2  . ASP M  1 132 ? 126.005 125.590 65.820 1.00 5.48  131 M 1 
-ATOM   2045 H  HB3  . ASP M  1 132 ? 125.348 124.203 65.415 1.00 5.48  131 M 1 
-ATOM   2046 N  N    . PHE M  1 133 ? 126.935 121.698 65.339 1.00 4.96  132 M 1 
-ATOM   2047 C  CA   . PHE M  1 133 ? 126.879 120.250 65.500 1.00 4.96  132 M 1 
-ATOM   2048 C  C    . PHE M  1 133 ? 128.176 119.716 66.096 1.00 4.96  132 M 1 
-ATOM   2049 O  O    . PHE M  1 133 ? 128.164 118.980 67.093 1.00 4.96  132 M 1 
-ATOM   2050 C  CB   . PHE M  1 133 ? 126.616 119.617 64.138 1.00 4.96  132 M 1 
-ATOM   2051 C  CG   . PHE M  1 133 ? 126.460 118.140 64.172 1.00 4.96  132 M 1 
-ATOM   2052 C  CD1  . PHE M  1 133 ? 125.267 117.579 64.563 1.00 4.96  132 M 1 
-ATOM   2053 C  CD2  . PHE M  1 133 ? 127.501 117.309 63.819 1.00 4.96  132 M 1 
-ATOM   2054 C  CE1  . PHE M  1 133 ? 125.111 116.227 64.590 1.00 4.96  132 M 1 
-ATOM   2055 C  CE2  . PHE M  1 133 ? 127.340 115.952 63.850 1.00 4.96  132 M 1 
-ATOM   2056 C  CZ   . PHE M  1 133 ? 126.146 115.419 64.239 1.00 4.96  132 M 1 
-ATOM   2057 H  H    . PHE M  1 133 ? 126.826 121.970 64.531 1.00 4.96  132 M 1 
-ATOM   2058 H  HA   . PHE M  1 133 ? 126.144 120.020 66.090 1.00 4.96  132 M 1 
-ATOM   2059 H  HB2  . PHE M  1 133 ? 125.790 119.981 63.782 1.00 4.96  132 M 1 
-ATOM   2060 H  HB3  . PHE M  1 133 ? 127.343 119.833 63.533 1.00 4.96  132 M 1 
-ATOM   2061 H  HD1  . PHE M  1 133 ? 124.556 118.129 64.802 1.00 4.96  132 M 1 
-ATOM   2062 H  HD2  . PHE M  1 133 ? 128.317 117.667 63.553 1.00 4.96  132 M 1 
-ATOM   2063 H  HE1  . PHE M  1 133 ? 124.299 115.859 64.854 1.00 4.96  132 M 1 
-ATOM   2064 H  HE2  . PHE M  1 133 ? 128.043 115.393 63.610 1.00 4.96  132 M 1 
-ATOM   2065 H  HZ   . PHE M  1 133 ? 126.034 114.496 64.259 1.00 4.96  132 M 1 
-ATOM   2066 N  N    . ILE M  1 134 ? 129.305 120.104 65.501 1.00 5.03  133 M 1 
-ATOM   2067 C  CA   . ILE M  1 134 ? 130.616 119.674 65.982 1.00 5.03  133 M 1 
-ATOM   2068 C  C    . ILE M  1 134 ? 130.840 120.153 67.413 1.00 5.03  133 M 1 
-ATOM   2069 O  O    . ILE M  1 134 ? 131.305 119.397 68.272 1.00 5.03  133 M 1 
-ATOM   2070 C  CB   . ILE M  1 134 ? 131.719 120.176 65.028 1.00 5.03  133 M 1 
-ATOM   2071 C  CG1  . ILE M  1 134 ? 131.577 119.558 63.624 1.00 5.03  133 M 1 
-ATOM   2072 C  CG2  . ILE M  1 134 ? 133.105 119.929 65.596 1.00 5.03  133 M 1 
-ATOM   2073 C  CD1  . ILE M  1 134 ? 131.748 118.039 63.534 1.00 5.03  133 M 1 
-ATOM   2074 H  H    . ILE M  1 134 ? 129.335 120.630 64.821 1.00 5.03  133 M 1 
-ATOM   2075 H  HA   . ILE M  1 134 ? 130.642 118.704 65.994 1.00 5.03  133 M 1 
-ATOM   2076 H  HB   . ILE M  1 134 ? 131.619 121.137 64.938 1.00 5.03  133 M 1 
-ATOM   2077 H  HG12 . ILE M  1 134 ? 130.691 119.745 63.277 1.00 5.03  133 M 1 
-ATOM   2078 H  HG13 . ILE M  1 134 ? 132.226 119.978 63.038 1.00 5.03  133 M 1 
-ATOM   2079 H  HG21 . ILE M  1 134 ? 133.751 120.040 64.881 1.00 5.03  133 M 1 
-ATOM   2080 H  HG22 . ILE M  1 134 ? 133.296 120.575 66.294 1.00 5.03  133 M 1 
-ATOM   2081 H  HG23 . ILE M  1 134 ? 133.155 119.026 65.946 1.00 5.03  133 M 1 
-ATOM   2082 H  HD11 . ILE M  1 134 ? 131.674 117.779 62.602 1.00 5.03  133 M 1 
-ATOM   2083 H  HD12 . ILE M  1 134 ? 132.622 117.784 63.869 1.00 5.03  133 M 1 
-ATOM   2084 H  HD13 . ILE M  1 134 ? 131.051 117.593 64.041 1.00 5.03  133 M 1 
-ATOM   2085 N  N    . GLU M  1 135 ? 130.489 121.403 67.667 1.00 5.70  134 M 1 
-ATOM   2086 C  CA   . GLU M  1 135 ? 130.686 122.013 69.003 1.00 5.70  134 M 1 
-ATOM   2087 C  C    . GLU M  1 135 ? 129.853 121.255 70.039 1.00 5.70  134 M 1 
-ATOM   2088 O  O    . GLU M  1 135 ? 130.444 120.817 71.036 1.00 5.70  134 M 1 
-ATOM   2089 C  CB   . GLU M  1 135 ? 130.277 123.487 68.999 1.00 5.70  134 M 1 
-ATOM   2090 C  CG   . GLU M  1 135 ? 131.234 124.397 68.267 1.00 5.70  134 M 1 
-ATOM   2091 C  CD   . GLU M  1 135 ? 130.626 125.767 68.005 1.00 5.70  134 M 1 
-ATOM   2092 O  OE1  . GLU M  1 135 ? 129.620 126.068 68.646 1.00 5.70  134 M 1 
-ATOM   2093 O  OE2  . GLU M  1 135 ? 131.138 126.504 67.151 1.00 5.70  134 M 1 
-ATOM   2094 H  H    . GLU M  1 135 ? 129.997 121.908 67.091 1.00 5.70  134 M 1 
-ATOM   2095 H  HA   . GLU M  1 135 ? 131.639 121.943 69.245 1.00 5.70  134 M 1 
-ATOM   2096 H  HB2  . GLU M  1 135 ? 129.391 123.562 68.586 1.00 5.70  134 M 1 
-ATOM   2097 H  HB3  . GLU M  1 135 ? 130.200 123.790 69.927 1.00 5.70  134 M 1 
-ATOM   2098 H  HG2  . GLU M  1 135 ? 132.051 124.508 68.798 1.00 5.70  134 M 1 
-ATOM   2099 H  HG3  . GLU M  1 135 ? 131.482 123.989 67.409 1.00 5.70  134 M 1 
-ATOM   2100 N  N    . THR M  1 136 ? 128.607 120.926 69.710 1.00 5.69  135 M 1 
-ATOM   2101 C  CA   . THR M  1 136 ? 127.648 120.409 70.673 1.00 5.69  135 M 1 
-ATOM   2102 C  C    . THR M  1 136 ? 127.901 118.943 70.981 1.00 5.69  135 M 1 
-ATOM   2103 O  O    . THR M  1 136 ? 127.792 118.527 72.139 1.00 5.69  135 M 1 
-ATOM   2104 C  CB   . THR M  1 136 ? 126.231 120.615 70.132 1.00 5.69  135 M 1 
-ATOM   2105 O  OG1  . THR M  1 136 ? 125.987 122.016 69.958 1.00 5.69  135 M 1 
-ATOM   2106 C  CG2  . THR M  1 136 ? 125.180 120.022 71.054 1.00 5.69  135 M 1 
-ATOM   2107 H  H    . THR M  1 136 ? 128.290 121.021 68.916 1.00 5.69  135 M 1 
-ATOM   2108 H  HA   . THR M  1 136 ? 127.735 120.908 71.500 1.00 5.69  135 M 1 
-ATOM   2109 H  HB   . THR M  1 136 ? 126.146 120.171 69.274 1.00 5.69  135 M 1 
-ATOM   2110 H  HG1  . THR M  1 136 ? 126.306 122.271 69.224 1.00 5.69  135 M 1 
-ATOM   2111 H  HG21 . THR M  1 136 ? 124.308 120.381 70.826 1.00 5.69  135 M 1 
-ATOM   2112 H  HG22 . THR M  1 136 ? 125.137 119.058 70.952 1.00 5.69  135 M 1 
-ATOM   2113 H  HG23 . THR M  1 136 ? 125.382 120.243 71.977 1.00 5.69  135 M 1 
-ATOM   2114 N  N    . TYR M  1 137 ? 128.255 118.148 69.967 1.00 5.32  136 M 1 
-ATOM   2115 C  CA   . TYR M  1 137 ? 128.285 116.699 70.109 1.00 5.32  136 M 1 
-ATOM   2116 C  C    . TYR M  1 137 ? 129.681 116.086 70.112 1.00 5.32  136 M 1 
-ATOM   2117 O  O    . TYR M  1 137 ? 129.812 114.924 70.507 1.00 5.32  136 M 1 
-ATOM   2118 C  CB   . TYR M  1 137 ? 127.446 116.053 68.996 1.00 5.32  136 M 1 
-ATOM   2119 C  CG   . TYR M  1 137 ? 125.993 116.445 69.078 1.00 5.32  136 M 1 
-ATOM   2120 C  CD1  . TYR M  1 137 ? 125.173 115.917 70.061 1.00 5.32  136 M 1 
-ATOM   2121 C  CD2  . TYR M  1 137 ? 125.435 117.320 68.164 1.00 5.32  136 M 1 
-ATOM   2122 C  CE1  . TYR M  1 137 ? 123.854 116.266 70.149 1.00 5.32  136 M 1 
-ATOM   2123 C  CE2  . TYR M  1 137 ? 124.109 117.674 68.238 1.00 5.32  136 M 1 
-ATOM   2124 C  CZ   . TYR M  1 137 ? 123.318 117.142 69.235 1.00 5.32  136 M 1 
-ATOM   2125 O  OH   . TYR M  1 137 ? 121.991 117.479 69.329 1.00 5.32  136 M 1 
-ATOM   2126 H  H    . TYR M  1 137 ? 128.481 118.435 69.189 1.00 5.32  136 M 1 
-ATOM   2127 H  HA   . TYR M  1 137 ? 127.872 116.438 70.947 1.00 5.32  136 M 1 
-ATOM   2128 H  HB2  . TYR M  1 137 ? 127.794 116.325 68.132 1.00 5.32  136 M 1 
-ATOM   2129 H  HB3  . TYR M  1 137 ? 127.491 115.087 69.065 1.00 5.32  136 M 1 
-ATOM   2130 H  HD1  . TYR M  1 137 ? 125.528 115.329 70.687 1.00 5.32  136 M 1 
-ATOM   2131 H  HD2  . TYR M  1 137 ? 125.965 117.681 67.491 1.00 5.32  136 M 1 
-ATOM   2132 H  HE1  . TYR M  1 137 ? 123.322 115.905 70.821 1.00 5.32  136 M 1 
-ATOM   2133 H  HE2  . TYR M  1 137 ? 123.756 118.269 67.616 1.00 5.32  136 M 1 
-ATOM   2134 H  HH   . TYR M  1 137 ? 121.786 118.019 68.719 1.00 5.32  136 M 1 
-ATOM   2135 N  N    . TYR M  1 138 ? 130.715 116.820 69.695 1.00 4.75  137 M 1 
-ATOM   2136 C  CA   . TYR M  1 138 ? 132.058 116.267 69.521 1.00 4.75  137 M 1 
-ATOM   2137 C  C    . TYR M  1 138 ? 133.140 116.945 70.353 1.00 4.75  137 M 1 
-ATOM   2138 O  O    . TYR M  1 138 ? 133.898 116.247 71.032 1.00 4.75  137 M 1 
-ATOM   2139 C  CB   . TYR M  1 138 ? 132.409 116.289 68.026 1.00 4.75  137 M 1 
-ATOM   2140 C  CG   . TYR M  1 138 ? 131.612 115.244 67.293 1.00 4.75  137 M 1 
-ATOM   2141 C  CD1  . TYR M  1 138 ? 132.096 113.958 67.141 1.00 4.75  137 M 1 
-ATOM   2142 C  CD2  . TYR M  1 138 ? 130.320 115.500 66.879 1.00 4.75  137 M 1 
-ATOM   2143 C  CE1  . TYR M  1 138 ? 131.360 112.991 66.518 1.00 4.75  137 M 1 
-ATOM   2144 C  CE2  . TYR M  1 138 ? 129.567 114.535 66.263 1.00 4.75  137 M 1 
-ATOM   2145 C  CZ   . TYR M  1 138 ? 130.093 113.277 66.087 1.00 4.75  137 M 1 
-ATOM   2146 O  OH   . TYR M  1 138 ? 129.368 112.286 65.485 1.00 4.75  137 M 1 
-ATOM   2147 H  H    . TYR M  1 138 ? 130.649 117.652 69.486 1.00 4.75  137 M 1 
-ATOM   2148 H  HA   . TYR M  1 138 ? 132.058 115.331 69.774 1.00 4.75  137 M 1 
-ATOM   2149 H  HB2  . TYR M  1 138 ? 132.226 117.161 67.643 1.00 4.75  137 M 1 
-ATOM   2150 H  HB3  . TYR M  1 138 ? 133.350 116.078 67.917 1.00 4.75  137 M 1 
-ATOM   2151 H  HD1  . TYR M  1 138 ? 132.959 113.757 67.423 1.00 4.75  137 M 1 
-ATOM   2152 H  HD2  . TYR M  1 138 ? 129.963 116.350 66.999 1.00 4.75  137 M 1 
-ATOM   2153 H  HE1  . TYR M  1 138 ? 131.714 112.139 66.400 1.00 4.75  137 M 1 
-ATOM   2154 H  HE2  . TYR M  1 138 ? 128.706 114.734 65.975 1.00 4.75  137 M 1 
-ATOM   2155 H  HH   . TYR M  1 138 ? 129.810 111.572 65.461 1.00 4.75  137 M 1 
-ATOM   2156 N  N    . LEU M  1 139 ? 133.243 118.277 70.343 1.00 5.15  138 M 1 
-ATOM   2157 C  CA   . LEU M  1 139 ? 134.409 118.924 70.952 1.00 5.15  138 M 1 
-ATOM   2158 C  C    . LEU M  1 139 ? 134.414 118.788 72.475 1.00 5.15  138 M 1 
-ATOM   2159 O  O    . LEU M  1 139 ? 135.460 118.504 73.074 1.00 5.15  138 M 1 
-ATOM   2160 C  CB   . LEU M  1 139 ? 134.485 120.398 70.541 1.00 5.15  138 M 1 
-ATOM   2161 C  CG   . LEU M  1 139 ? 134.810 120.765 69.087 1.00 5.15  138 M 1 
-ATOM   2162 C  CD1  . LEU M  1 139 ? 134.728 122.282 68.909 1.00 5.15  138 M 1 
-ATOM   2163 C  CD2  . LEU M  1 139 ? 136.168 120.241 68.631 1.00 5.15  138 M 1 
-ATOM   2164 H  H    . LEU M  1 139 ? 132.663 118.816 70.008 1.00 5.15  138 M 1 
-ATOM   2165 H  HA   . LEU M  1 139 ? 135.217 118.493 70.633 1.00 5.15  138 M 1 
-ATOM   2166 H  HB2  . LEU M  1 139 ? 133.626 120.801 70.744 1.00 5.15  138 M 1 
-ATOM   2167 H  HB3  . LEU M  1 139 ? 135.163 120.828 71.085 1.00 5.15  138 M 1 
-ATOM   2168 H  HG   . LEU M  1 139 ? 134.147 120.368 68.501 1.00 5.15  138 M 1 
-ATOM   2169 H  HD11 . LEU M  1 139 ? 134.996 122.514 68.006 1.00 5.15  138 M 1 
-ATOM   2170 H  HD12 . LEU M  1 139 ? 133.819 122.579 69.071 1.00 5.15  138 M 1 
-ATOM   2171 H  HD13 . LEU M  1 139 ? 135.323 122.712 69.543 1.00 5.15  138 M 1 
-ATOM   2172 H  HD21 . LEU M  1 139 ? 136.264 120.441 67.687 1.00 5.15  138 M 1 
-ATOM   2173 H  HD22 . LEU M  1 139 ? 136.878 120.678 69.128 1.00 5.15  138 M 1 
-ATOM   2174 H  HD23 . LEU M  1 139 ? 136.219 119.282 68.765 1.00 5.15  138 M 1 
-ATOM   2175 N  N    . SER M  1 140 ? 133.263 118.984 73.122 1.00 5.52  139 M 1 
-ATOM   2176 C  CA   . SER M  1 140 ? 133.212 118.887 74.580 1.00 5.52  139 M 1 
-ATOM   2177 C  C    . SER M  1 140 ? 133.454 117.457 75.050 1.00 5.52  139 M 1 
-ATOM   2178 O  O    . SER M  1 140 ? 134.145 117.230 76.053 1.00 5.52  139 M 1 
-ATOM   2179 C  CB   . SER M  1 140 ? 131.870 119.403 75.101 1.00 5.52  139 M 1 
-ATOM   2180 O  OG   . SER M  1 140 ? 131.723 120.784 74.840 1.00 5.52  139 M 1 
-ATOM   2181 H  H    . SER M  1 140 ? 132.513 119.176 72.748 1.00 5.52  139 M 1 
-ATOM   2182 H  HA   . SER M  1 140 ? 133.909 119.450 74.952 1.00 5.52  139 M 1 
-ATOM   2183 H  HB2  . SER M  1 140 ? 131.153 118.933 74.647 1.00 5.52  139 M 1 
-ATOM   2184 H  HB3  . SER M  1 140 ? 131.806 119.255 76.058 1.00 5.52  139 M 1 
-ATOM   2185 H  HG   . SER M  1 140 ? 130.981 121.049 75.132 1.00 5.52  139 M 1 
-ATOM   2186 N  N    . GLU M  1 141 ? 132.881 116.482 74.341 1.00 5.44  140 M 1 
-ATOM   2187 C  CA   . GLU M  1 141 ? 133.127 115.075 74.648 1.00 5.44  140 M 1 
-ATOM   2188 C  C    . GLU M  1 141 ? 134.614 114.753 74.571 1.00 5.44  140 M 1 
-ATOM   2189 O  O    . GLU M  1 141 ? 135.157 114.061 75.441 1.00 5.44  140 M 1 
-ATOM   2190 C  CB   . GLU M  1 141 ? 132.330 114.187 73.684 1.00 5.44  140 M 1 
-ATOM   2191 C  CG   . GLU M  1 141 ? 132.429 112.681 73.926 1.00 5.44  140 M 1 
-ATOM   2192 C  CD   . GLU M  1 141 ? 133.700 112.071 73.369 1.00 5.44  140 M 1 
-ATOM   2193 O  OE1  . GLU M  1 141 ? 134.274 112.642 72.421 1.00 5.44  140 M 1 
-ATOM   2194 O  OE2  . GLU M  1 141 ? 134.137 111.025 73.895 1.00 5.44  140 M 1 
-ATOM   2195 H  H    . GLU M  1 141 ? 132.350 116.619 73.678 1.00 5.44  140 M 1 
-ATOM   2196 H  HA   . GLU M  1 141 ? 132.818 114.891 75.549 1.00 5.44  140 M 1 
-ATOM   2197 H  HB2  . GLU M  1 141 ? 131.391 114.422 73.750 1.00 5.44  140 M 1 
-ATOM   2198 H  HB3  . GLU M  1 141 ? 132.635 114.353 72.778 1.00 5.44  140 M 1 
-ATOM   2199 H  HG2  . GLU M  1 141 ? 132.425 112.522 74.882 1.00 5.44  140 M 1 
-ATOM   2200 H  HG3  . GLU M  1 141 ? 131.671 112.224 73.528 1.00 5.44  140 M 1 
-ATOM   2201 N  N    . GLN M  1 142 ? 135.292 115.259 73.542 1.00 4.79  141 M 1 
-ATOM   2202 C  CA   . GLN M  1 142 ? 136.713 114.986 73.383 1.00 4.79  141 M 1 
-ATOM   2203 C  C    . GLN M  1 142 ? 137.530 115.642 74.486 1.00 4.79  141 M 1 
-ATOM   2204 O  O    . GLN M  1 142 ? 138.505 115.063 74.971 1.00 4.79  141 M 1 
-ATOM   2205 C  CB   . GLN M  1 142 ? 137.196 115.455 72.011 1.00 4.79  141 M 1 
-ATOM   2206 C  CG   . GLN M  1 142 ? 136.700 114.641 70.837 1.00 4.79  141 M 1 
-ATOM   2207 C  CD   . GLN M  1 142 ? 137.195 113.215 70.874 1.00 4.79  141 M 1 
-ATOM   2208 O  OE1  . GLN M  1 142 ? 136.418 112.283 71.061 1.00 4.79  141 M 1 
-ATOM   2209 N  NE2  . GLN M  1 142 ? 138.501 113.044 70.749 1.00 4.79  141 M 1 
-ATOM   2210 H  H    . GLN M  1 142 ? 134.959 115.766 72.933 1.00 4.79  141 M 1 
-ATOM   2211 H  HA   . GLN M  1 142 ? 136.847 114.028 73.454 1.00 4.79  141 M 1 
-ATOM   2212 H  HB2  . GLN M  1 142 ? 136.902 116.370 71.877 1.00 4.79  141 M 1 
-ATOM   2213 H  HB3  . GLN M  1 142 ? 138.165 115.421 71.989 1.00 4.79  141 M 1 
-ATOM   2214 H  HG2  . GLN M  1 142 ? 135.730 114.621 70.832 1.00 4.79  141 M 1 
-ATOM   2215 H  HG3  . GLN M  1 142 ? 137.031 115.050 70.022 1.00 4.79  141 M 1 
-ATOM   2216 H  HE21 . GLN M  1 142 ? 139.007 113.729 70.633 1.00 4.79  141 M 1 
-ATOM   2217 H  HE22 . GLN M  1 142 ? 138.848 112.257 70.771 1.00 4.79  141 M 1 
-ATOM   2218 N  N    . VAL M  1 143 ? 137.154 116.857 74.890 1.00 4.49  142 M 1 
-ATOM   2219 C  CA   . VAL M  1 143 ? 137.859 117.519 75.985 1.00 4.49  142 M 1 
-ATOM   2220 C  C    . VAL M  1 143 ? 137.719 116.709 77.269 1.00 4.49  142 M 1 
-ATOM   2221 O  O    . VAL M  1 143 ? 138.703 116.478 77.990 1.00 4.49  142 M 1 
-ATOM   2222 C  CB   . VAL M  1 143 ? 137.350 118.966 76.144 1.00 4.49  142 M 1 
-ATOM   2223 C  CG1  . VAL M  1 143 ? 137.845 119.590 77.428 1.00 4.49  142 M 1 
-ATOM   2224 C  CG2  . VAL M  1 143 ? 137.827 119.821 74.969 1.00 4.49  142 M 1 
-ATOM   2225 H  H    . VAL M  1 143 ? 136.490 117.304 74.577 1.00 4.49  142 M 1 
-ATOM   2226 H  HA   . VAL M  1 143 ? 138.802 117.565 75.764 1.00 4.49  142 M 1 
-ATOM   2227 H  HB   . VAL M  1 143 ? 136.380 118.968 76.157 1.00 4.49  142 M 1 
-ATOM   2228 H  HG11 . VAL M  1 143 ? 137.733 120.551 77.358 1.00 4.49  142 M 1 
-ATOM   2229 H  HG12 . VAL M  1 143 ? 137.317 119.266 78.174 1.00 4.49  142 M 1 
-ATOM   2230 H  HG13 . VAL M  1 143 ? 138.783 119.383 77.559 1.00 4.49  142 M 1 
-ATOM   2231 H  HG21 . VAL M  1 143 ? 137.236 120.583 74.866 1.00 4.49  142 M 1 
-ATOM   2232 H  HG22 . VAL M  1 143 ? 138.728 120.131 75.150 1.00 4.49  142 M 1 
-ATOM   2233 H  HG23 . VAL M  1 143 ? 137.831 119.297 74.152 1.00 4.49  142 M 1 
-ATOM   2234 N  N    . LYS M  1 144 ? 136.507 116.220 77.544 1.00 4.83  143 M 1 
-ATOM   2235 C  CA   . LYS M  1 144 ? 136.288 115.404 78.735 1.00 4.83  143 M 1 
-ATOM   2236 C  C    . LYS M  1 144 ? 137.105 114.119 78.678 1.00 4.83  143 M 1 
-ATOM   2237 O  O    . LYS M  1 144 ? 137.698 113.704 79.680 1.00 4.83  143 M 1 
-ATOM   2238 C  CB   . LYS M  1 144 ? 134.801 115.079 78.899 1.00 4.83  143 M 1 
-ATOM   2239 C  CG   . LYS M  1 144 ? 133.922 116.256 79.272 1.00 4.83  143 M 1 
-ATOM   2240 C  CD   . LYS M  1 144 ? 132.501 115.808 79.620 1.00 4.83  143 M 1 
-ATOM   2241 C  CE   . LYS M  1 144 ? 131.707 115.401 78.389 1.00 4.83  143 M 1 
-ATOM   2242 N  NZ   . LYS M  1 144 ? 130.284 115.092 78.707 1.00 4.83  143 M 1 
-ATOM   2243 H  H    . LYS M  1 144 ? 135.811 116.327 77.050 1.00 4.83  143 M 1 
-ATOM   2244 H  HA   . LYS M  1 144 ? 136.569 115.910 79.514 1.00 4.83  143 M 1 
-ATOM   2245 H  HB2  . LYS M  1 144 ? 134.473 114.724 78.058 1.00 4.83  143 M 1 
-ATOM   2246 H  HB3  . LYS M  1 144 ? 134.693 114.412 79.595 1.00 4.83  143 M 1 
-ATOM   2247 H  HG2  . LYS M  1 144 ? 134.301 116.702 80.045 1.00 4.83  143 M 1 
-ATOM   2248 H  HG3  . LYS M  1 144 ? 133.865 116.875 78.527 1.00 4.83  143 M 1 
-ATOM   2249 H  HD2  . LYS M  1 144 ? 132.542 115.043 80.215 1.00 4.83  143 M 1 
-ATOM   2250 H  HD3  . LYS M  1 144 ? 132.032 116.540 80.050 1.00 4.83  143 M 1 
-ATOM   2251 H  HE2  . LYS M  1 144 ? 131.724 116.123 77.741 1.00 4.83  143 M 1 
-ATOM   2252 H  HE3  . LYS M  1 144 ? 132.098 114.597 78.012 1.00 4.83  143 M 1 
-ATOM   2253 H  HZ1  . LYS M  1 144 ? 129.888 114.729 77.997 1.00 4.83  143 M 1 
-ATOM   2254 H  HZ2  . LYS M  1 144 ? 130.240 114.522 79.389 1.00 4.83  143 M 1 
-ATOM   2255 H  HZ3  . LYS M  1 144 ? 129.853 115.839 78.925 1.00 4.83  143 M 1 
-ATOM   2256 N  N    . SER M  1 145 ? 137.167 113.489 77.507 1.00 4.26  144 M 1 
-ATOM   2257 C  CA   . SER M  1 145 ? 137.864 112.212 77.389 1.00 4.26  144 M 1 
-ATOM   2258 C  C    . SER M  1 145 ? 139.374 112.391 77.507 1.00 4.26  144 M 1 
-ATOM   2259 O  O    . SER M  1 145 ? 140.058 111.572 78.133 1.00 4.26  144 M 1 
-ATOM   2260 C  CB   . SER M  1 145 ? 137.494 111.546 76.069 1.00 4.26  144 M 1 
-ATOM   2261 O  OG   . SER M  1 145 ? 136.114 111.241 76.049 1.00 4.26  144 M 1 
-ATOM   2262 H  H    . SER M  1 145 ? 136.834 113.784 76.771 1.00 4.26  144 M 1 
-ATOM   2263 H  HA   . SER M  1 145 ? 137.575 111.628 78.108 1.00 4.26  144 M 1 
-ATOM   2264 H  HB2  . SER M  1 145 ? 137.692 112.151 75.337 1.00 4.26  144 M 1 
-ATOM   2265 H  HB3  . SER M  1 145 ? 138.006 110.728 75.968 1.00 4.26  144 M 1 
-ATOM   2266 H  HG   . SER M  1 145 ? 135.685 111.835 76.460 1.00 4.26  144 M 1 
-ATOM   2267 N  N    . ILE M  1 146 ? 139.906 113.464 76.921 1.00 3.93  145 M 1 
-ATOM   2268 C  CA   . ILE M  1 146 ? 141.327 113.772 77.054 1.00 3.93  145 M 1 
-ATOM   2269 C  C    . ILE M  1 146 ? 141.676 114.000 78.517 1.00 3.93  145 M 1 
-ATOM   2270 O  O    . ILE M  1 146 ? 142.687 113.494 79.012 1.00 3.93  145 M 1 
-ATOM   2271 C  CB   . ILE M  1 146 ? 141.700 114.985 76.176 1.00 3.93  145 M 1 
-ATOM   2272 C  CG1  . ILE M  1 146 ? 141.605 114.623 74.688 1.00 3.93  145 M 1 
-ATOM   2273 C  CG2  . ILE M  1 146 ? 143.080 115.516 76.549 1.00 3.93  145 M 1 
-ATOM   2274 C  CD1  . ILE M  1 146 ? 141.639 115.802 73.726 1.00 3.93  145 M 1 
-ATOM   2275 H  H    . ILE M  1 146 ? 139.459 114.044 76.469 1.00 3.93  145 M 1 
-ATOM   2276 H  HA   . ILE M  1 146 ? 141.845 113.016 76.736 1.00 3.93  145 M 1 
-ATOM   2277 H  HB   . ILE M  1 146 ? 141.057 115.690 76.348 1.00 3.93  145 M 1 
-ATOM   2278 H  HG12 . ILE M  1 146 ? 142.348 114.041 74.462 1.00 3.93  145 M 1 
-ATOM   2279 H  HG13 . ILE M  1 146 ? 140.779 114.139 74.530 1.00 3.93  145 M 1 
-ATOM   2280 H  HG21 . ILE M  1 146 ? 143.453 116.028 75.814 1.00 3.93  145 M 1 
-ATOM   2281 H  HG22 . ILE M  1 146 ? 143.004 116.096 77.322 1.00 3.93  145 M 1 
-ATOM   2282 H  HG23 . ILE M  1 146 ? 143.670 114.772 76.744 1.00 3.93  145 M 1 
-ATOM   2283 H  HD11 . ILE M  1 146 ? 141.513 115.471 72.823 1.00 3.93  145 M 1 
-ATOM   2284 H  HD12 . ILE M  1 146 ? 140.926 116.419 73.952 1.00 3.93  145 M 1 
-ATOM   2285 H  HD13 . ILE M  1 146 ? 142.493 116.259 73.778 1.00 3.93  145 M 1 
-ATOM   2286 N  N    . LYS M  1 147 ? 140.838 114.750 79.232 1.00 3.89  146 M 1 
-ATOM   2287 C  CA   . LYS M  1 147 ? 141.100 115.021 80.643 1.00 3.89  146 M 1 
-ATOM   2288 C  C    . LYS M  1 147 ? 141.039 113.741 81.475 1.00 3.89  146 M 1 
-ATOM   2289 O  O    . LYS M  1 147 ? 141.881 113.521 82.354 1.00 3.89  146 M 1 
-ATOM   2290 C  CB   . LYS M  1 147 ? 140.111 116.076 81.137 1.00 3.89  146 M 1 
-ATOM   2291 C  CG   . LYS M  1 147 ? 140.203 116.479 82.594 1.00 3.89  146 M 1 
-ATOM   2292 C  CD   . LYS M  1 147 ? 141.543 117.081 82.931 1.00 3.89  146 M 1 
-ATOM   2293 C  CE   . LYS M  1 147 ? 141.512 117.806 84.271 1.00 3.89  146 M 1 
-ATOM   2294 N  NZ   . LYS M  1 147 ? 141.164 116.952 85.399 1.00 3.89  146 M 1 
-ATOM   2295 H  H    . LYS M  1 147 ? 140.115 115.097 78.920 1.00 3.89  146 M 1 
-ATOM   2296 H  HA   . LYS M  1 147 ? 141.991 115.394 80.726 1.00 3.89  146 M 1 
-ATOM   2297 H  HB2  . LYS M  1 147 ? 140.260 116.884 80.621 1.00 3.89  146 M 1 
-ATOM   2298 H  HB3  . LYS M  1 147 ? 139.208 115.763 80.971 1.00 3.89  146 M 1 
-ATOM   2299 H  HG2  . LYS M  1 147 ? 139.522 117.145 82.774 1.00 3.89  146 M 1 
-ATOM   2300 H  HG3  . LYS M  1 147 ? 140.052 115.711 83.167 1.00 3.89  146 M 1 
-ATOM   2301 H  HD2  . LYS M  1 147 ? 142.200 116.369 82.982 1.00 3.89  146 M 1 
-ATOM   2302 H  HD3  . LYS M  1 147 ? 141.797 117.719 82.246 1.00 3.89  146 M 1 
-ATOM   2303 H  HE2  . LYS M  1 147 ? 142.398 118.159 84.450 1.00 3.89  146 M 1 
-ATOM   2304 H  HE3  . LYS M  1 147 ? 140.870 118.533 84.241 1.00 3.89  146 M 1 
-ATOM   2305 H  HZ1  . LYS M  1 147 ? 140.321 116.682 85.309 1.00 3.89  146 M 1 
-ATOM   2306 H  HZ2  . LYS M  1 147 ? 141.684 116.230 85.411 1.00 3.89  146 M 1 
-ATOM   2307 H  HZ3  . LYS M  1 147 ? 141.256 117.398 86.164 1.00 3.89  146 M 1 
-ATOM   2308 N  N    . GLU M  1 148 ? 140.069 112.873 81.186 1.00 3.93  147 M 1 
-ATOM   2309 C  CA   . GLU M  1 148 ? 139.953 111.593 81.882 1.00 3.93  147 M 1 
-ATOM   2310 C  C    . GLU M  1 148 ? 141.201 110.738 81.676 1.00 3.93  147 M 1 
-ATOM   2311 O  O    . GLU M  1 148 ? 141.770 110.195 82.632 1.00 3.93  147 M 1 
-ATOM   2312 C  CB   . GLU M  1 148 ? 138.707 110.863 81.379 1.00 3.93  147 M 1 
-ATOM   2313 C  CG   . GLU M  1 148 ? 138.412 109.544 82.057 1.00 3.93  147 M 1 
-ATOM   2314 C  CD   . GLU M  1 148 ? 137.135 108.897 81.547 1.00 3.93  147 M 1 
-ATOM   2315 O  OE1  . GLU M  1 148 ? 136.491 109.475 80.647 1.00 3.93  147 M 1 
-ATOM   2316 O  OE2  . GLU M  1 148 ? 136.772 107.813 82.046 1.00 3.93  147 M 1 
-ATOM   2317 H  H    . GLU M  1 148 ? 139.476 112.996 80.575 1.00 3.93  147 M 1 
-ATOM   2318 H  HA   . GLU M  1 148 ? 139.842 111.748 82.833 1.00 3.93  147 M 1 
-ATOM   2319 H  HB2  . GLU M  1 148 ? 137.937 111.438 81.511 1.00 3.93  147 M 1 
-ATOM   2320 H  HB3  . GLU M  1 148 ? 138.820 110.688 80.432 1.00 3.93  147 M 1 
-ATOM   2321 H  HG2  . GLU M  1 148 ? 139.142 108.926 81.893 1.00 3.93  147 M 1 
-ATOM   2322 H  HG3  . GLU M  1 148 ? 138.316 109.694 83.011 1.00 3.93  147 M 1 
-ATOM   2323 N  N    . LEU M  1 149 ? 141.633 110.603 80.423 1.00 3.53  148 M 1 
-ATOM   2324 C  CA   . LEU M  1 149 ? 142.801 109.782 80.110 1.00 3.53  148 M 1 
-ATOM   2325 C  C    . LEU M  1 149 ? 144.070 110.354 80.727 1.00 3.53  148 M 1 
-ATOM   2326 O  O    . LEU M  1 149 ? 144.912 109.604 81.235 1.00 3.53  148 M 1 
-ATOM   2327 C  CB   . LEU M  1 149 ? 142.940 109.646 78.594 1.00 3.53  148 M 1 
-ATOM   2328 C  CG   . LEU M  1 149 ? 141.908 108.748 77.901 1.00 3.53  148 M 1 
-ATOM   2329 C  CD1  . LEU M  1 149 ? 141.939 108.934 76.394 1.00 3.53  148 M 1 
-ATOM   2330 C  CD2  . LEU M  1 149 ? 142.163 107.282 78.252 1.00 3.53  148 M 1 
-ATOM   2331 H  H    . LEU M  1 149 ? 141.264 110.980 79.743 1.00 3.53  148 M 1 
-ATOM   2332 H  HA   . LEU M  1 149 ? 142.663 108.899 80.487 1.00 3.53  148 M 1 
-ATOM   2333 H  HB2  . LEU M  1 149 ? 142.866 110.527 78.196 1.00 3.53  148 M 1 
-ATOM   2334 H  HB3  . LEU M  1 149 ? 143.824 109.298 78.397 1.00 3.53  148 M 1 
-ATOM   2335 H  HG   . LEU M  1 149 ? 141.017 108.970 78.215 1.00 3.53  148 M 1 
-ATOM   2336 H  HD11 . LEU M  1 149 ? 141.323 108.313 75.976 1.00 3.53  148 M 1 
-ATOM   2337 H  HD12 . LEU M  1 149 ? 141.662 109.840 76.186 1.00 3.53  148 M 1 
-ATOM   2338 H  HD13 . LEU M  1 149 ? 142.840 108.782 76.068 1.00 3.53  148 M 1 
-ATOM   2339 H  HD21 . LEU M  1 149 ? 141.692 106.719 77.618 1.00 3.53  148 M 1 
-ATOM   2340 H  HD22 . LEU M  1 149 ? 143.113 107.090 78.213 1.00 3.53  148 M 1 
-ATOM   2341 H  HD23 . LEU M  1 149 ? 141.832 107.102 79.146 1.00 3.53  148 M 1 
-ATOM   2342 N  N    . GLY M  1 150 ? 144.227 111.677 80.690 1.00 3.59  149 M 1 
-ATOM   2343 C  CA   . GLY M  1 150 ? 145.373 112.298 81.331 1.00 3.59  149 M 1 
-ATOM   2344 C  C    . GLY M  1 150 ? 145.401 112.034 82.822 1.00 3.59  149 M 1 
-ATOM   2345 O  O    . GLY M  1 150 ? 146.454 111.747 83.394 1.00 3.59  149 M 1 
-ATOM   2346 H  H    . GLY M  1 150 ? 143.677 112.226 80.321 1.00 3.59  149 M 1 
-ATOM   2347 H  HA2  . GLY M  1 150 ? 146.196 111.985 80.925 1.00 3.59  149 M 1 
-ATOM   2348 H  HA3  . GLY M  1 150 ? 145.322 113.257 81.197 1.00 3.59  149 M 1 
-ATOM   2349 N  N    . ASP M  1 151 ? 144.233 112.095 83.464 1.00 3.83  150 M 1 
-ATOM   2350 C  CA   . ASP M  1 151 ? 144.141 111.783 84.884 1.00 3.83  150 M 1 
-ATOM   2351 C  C    . ASP M  1 151 ? 144.541 110.337 85.159 1.00 3.83  150 M 1 
-ATOM   2352 O  O    . ASP M  1 151 ? 145.269 110.058 86.121 1.00 3.83  150 M 1 
-ATOM   2353 C  CB   . ASP M  1 151 ? 142.722 112.049 85.382 1.00 3.83  150 M 1 
-ATOM   2354 C  CG   . ASP M  1 151 ? 142.356 113.522 85.358 1.00 3.83  150 M 1 
-ATOM   2355 O  OD1  . ASP M  1 151 ? 143.268 114.366 85.450 1.00 3.83  150 M 1 
-ATOM   2356 O  OD2  . ASP M  1 151 ? 141.152 113.836 85.264 1.00 3.83  150 M 1 
-ATOM   2357 H  H    . ASP M  1 151 ? 143.483 112.301 83.098 1.00 3.83  150 M 1 
-ATOM   2358 H  HA   . ASP M  1 151 ? 144.747 112.358 85.377 1.00 3.83  150 M 1 
-ATOM   2359 H  HB2  . ASP M  1 151 ? 142.097 111.579 84.809 1.00 3.83  150 M 1 
-ATOM   2360 H  HB3  . ASP M  1 151 ? 142.633 111.725 86.292 1.00 3.83  150 M 1 
-ATOM   2361 N  N    . HIS M  1 152 ? 144.078 109.425 84.300 1.00 3.63  151 M 1 
-ATOM   2362 C  CA   . HIS M  1 152 ? 144.374 107.967 84.419 1.00 3.63  151 M 1 
-ATOM   2363 C  C    . HIS M  1 152 ? 145.893 107.773 84.328 1.00 3.63  151 M 1 
-ATOM   2364 O  O    . HIS M  1 152 ? 146.470 107.176 85.208 1.00 3.63  151 M 1 
-ATOM   2365 C  CB   . HIS M  1 152 ? 143.627 107.139 83.350 1.00 3.63  151 M 1 
-ATOM   2366 C  CG   . HIS M  1 152 ? 142.152 107.067 83.552 1.00 3.63  151 M 1 
-ATOM   2367 N  ND1  . HIS M  1 152 ? 141.562 107.495 84.711 1.00 3.63  151 M 1 
-ATOM   2368 C  CD2  . HIS M  1 152 ? 141.148 106.653 82.753 1.00 3.63  151 M 1 
-ATOM   2369 C  CE1  . HIS M  1 152 ? 140.263 107.300 84.645 1.00 3.63  151 M 1 
-ATOM   2370 N  NE2  . HIS M  1 152 ? 139.980 106.801 83.453 1.00 3.63  151 M 1 
-ATOM   2371 H  H    . HIS M  1 152 ? 143.551 109.623 83.584 1.00 3.63  151 M 1 
-ATOM   2372 H  HA   . HIS M  1 152 ? 144.079 107.668 85.311 1.00 3.63  151 M 1 
-ATOM   2373 H  HB2  . HIS M  1 152 ? 143.806 107.531 82.466 1.00 3.63  151 M 1 
-ATOM   2374 H  HB3  . HIS M  1 152 ? 143.990 106.226 83.347 1.00 3.63  151 M 1 
-ATOM   2375 H  HD1  . HIS M  1 152 ? 141.990 107.805 85.410 1.00 3.63  151 M 1 
-ATOM   2376 H  HD2  . HIS M  1 152 ? 141.232 106.303 81.885 1.00 3.63  151 M 1 
-ATOM   2377 H  HE1  . HIS M  1 152 ? 139.639 107.518 85.316 1.00 3.63  151 M 1 
-ATOM   2378 N  N    . VAL M  1 153 ? 146.528 108.396 83.356 1.00 3.75  152 M 1 
-ATOM   2379 C  CA   . VAL M  1 153 ? 147.971 108.297 83.143 1.00 3.75  152 M 1 
-ATOM   2380 C  C    . VAL M  1 153 ? 148.724 108.840 84.351 1.00 3.75  152 M 1 
-ATOM   2381 O  O    . VAL M  1 153 ? 149.692 108.237 84.822 1.00 3.75  152 M 1 
-ATOM   2382 C  CB   . VAL M  1 153 ? 148.374 109.028 81.848 1.00 3.75  152 M 1 
-ATOM   2383 C  CG1  . VAL M  1 153 ? 149.883 109.083 81.695 1.00 3.75  152 M 1 
-ATOM   2384 C  CG2  . VAL M  1 153 ? 147.762 108.349 80.624 1.00 3.75  152 M 1 
-ATOM   2385 H  H    . VAL M  1 153 ? 146.125 108.884 82.774 1.00 3.75  152 M 1 
-ATOM   2386 H  HA   . VAL M  1 153 ? 148.214 107.364 83.040 1.00 3.75  152 M 1 
-ATOM   2387 H  HB   . VAL M  1 153 ? 148.054 109.943 81.879 1.00 3.75  152 M 1 
-ATOM   2388 H  HG11 . VAL M  1 153 ? 150.096 109.335 80.783 1.00 3.75  152 M 1 
-ATOM   2389 H  HG12 . VAL M  1 153 ? 150.253 109.751 82.293 1.00 3.75  152 M 1 
-ATOM   2390 H  HG13 . VAL M  1 153 ? 150.261 108.211 81.886 1.00 3.75  152 M 1 
-ATOM   2391 H  HG21 . VAL M  1 153 ? 147.770 108.976 79.884 1.00 3.75  152 M 1 
-ATOM   2392 H  HG22 . VAL M  1 153 ? 148.296 107.572 80.397 1.00 3.75  152 M 1 
-ATOM   2393 H  HG23 . VAL M  1 153 ? 146.848 108.071 80.793 1.00 3.75  152 M 1 
-ATOM   2394 N  N    . THR M  1 154 ? 148.291 109.995 84.858 1.00 3.85  153 M 1 
-ATOM   2395 C  CA   . THR M  1 154 ? 148.932 110.603 86.022 1.00 3.85  153 M 1 
-ATOM   2396 C  C    . THR M  1 154 ? 148.898 109.660 87.218 1.00 3.85  153 M 1 
-ATOM   2397 O  O    . THR M  1 154 ? 149.918 109.443 87.885 1.00 3.85  153 M 1 
-ATOM   2398 C  CB   . THR M  1 154 ? 148.248 111.938 86.336 1.00 3.85  153 M 1 
-ATOM   2399 O  OG1  . THR M  1 154 ? 148.471 112.832 85.239 1.00 3.85  153 M 1 
-ATOM   2400 C  CG2  . THR M  1 154 ? 148.742 112.558 87.655 1.00 3.85  153 M 1 
-ATOM   2401 H  H    . THR M  1 154 ? 147.608 110.423 84.559 1.00 3.85  153 M 1 
-ATOM   2402 H  HA   . THR M  1 154 ? 149.860 110.796 85.817 1.00 3.85  153 M 1 
-ATOM   2403 H  HB   . THR M  1 154 ? 147.293 111.795 86.429 1.00 3.85  153 M 1 
-ATOM   2404 H  HG1  . THR M  1 154 ? 147.948 112.664 84.604 1.00 3.85  153 M 1 
-ATOM   2405 H  HG21 . THR M  1 154 ? 148.362 113.444 87.759 1.00 3.85  153 M 1 
-ATOM   2406 H  HG22 . THR M  1 154 ? 148.441 112.039 88.417 1.00 3.85  153 M 1 
-ATOM   2407 H  HG23 . THR M  1 154 ? 149.709 112.627 87.668 1.00 3.85  153 M 1 
-ATOM   2408 N  N    . ASN M  1 155 ? 147.717 109.104 87.452 1.00 3.90  154 M 1 
-ATOM   2409 C  CA   . ASN M  1 155 ? 147.514 108.206 88.617 1.00 3.90  154 M 1 
-ATOM   2410 C  C    . ASN M  1 155 ? 148.382 106.953 88.457 1.00 3.90  154 M 1 
-ATOM   2411 O  O    . ASN M  1 155 ? 149.095 106.632 89.362 1.00 3.90  154 M 1 
-ATOM   2412 C  CB   . ASN M  1 155 ? 146.035 107.938 88.833 1.00 3.90  154 M 1 
-ATOM   2413 C  CG   . ASN M  1 155 ? 145.392 109.062 89.613 1.00 3.90  154 M 1 
-ATOM   2414 O  OD1  . ASN M  1 155 ? 145.664 109.232 90.787 1.00 3.90  154 M 1 
-ATOM   2415 N  ND2  . ASN M  1 155 ? 144.564 109.846 88.966 1.00 3.90  154 M 1 
-ATOM   2416 H  H    . ASN M  1 155 ? 147.019 109.144 86.870 1.00 3.90  154 M 1 
-ATOM   2417 H  HA   . ASN M  1 155 ? 147.833 108.687 89.416 1.00 3.90  154 M 1 
-ATOM   2418 H  HB2  . ASN M  1 155 ? 145.592 107.849 87.964 1.00 3.90  154 M 1 
-ATOM   2419 H  HB3  . ASN M  1 155 ? 145.926 107.097 89.323 1.00 3.90  154 M 1 
-ATOM   2420 H  HD21 . ASN M  1 155 ? 144.376 109.687 88.117 1.00 3.90  154 M 1 
-ATOM   2421 H  HD22 . ASN M  1 155 ? 144.194 110.535 89.378 1.00 3.90  154 M 1 
-ATOM   2422 N  N    . LEU M  1 156 ? 148.402 106.337 87.289 1.00 4.14  155 M 1 
-ATOM   2423 C  CA   . LEU M  1 156 ? 149.191 105.131 87.050 1.00 4.14  155 M 1 
-ATOM   2424 C  C    . LEU M  1 156 ? 150.684 105.404 87.191 1.00 4.14  155 M 1 
-ATOM   2425 O  O    . LEU M  1 156 ? 151.413 104.605 87.787 1.00 4.14  155 M 1 
-ATOM   2426 C  CB   . LEU M  1 156 ? 148.864 104.560 85.670 1.00 4.14  155 M 1 
-ATOM   2427 C  CG   . LEU M  1 156 ? 147.513 103.856 85.526 1.00 4.14  155 M 1 
-ATOM   2428 C  CD1  . LEU M  1 156 ? 147.157 103.593 84.075 1.00 4.14  155 M 1 
-ATOM   2429 C  CD2  . LEU M  1 156 ? 147.544 102.535 86.278 1.00 4.14  155 M 1 
-ATOM   2430 H  H    . LEU M  1 156 ? 147.967 106.623 86.605 1.00 4.14  155 M 1 
-ATOM   2431 H  HA   . LEU M  1 156 ? 148.956 104.473 87.722 1.00 4.14  155 M 1 
-ATOM   2432 H  HB2  . LEU M  1 156 ? 148.864 105.293 85.035 1.00 4.14  155 M 1 
-ATOM   2433 H  HB3  . LEU M  1 156 ? 149.564 103.938 85.417 1.00 4.14  155 M 1 
-ATOM   2434 H  HG   . LEU M  1 156 ? 146.815 104.402 85.921 1.00 4.14  155 M 1 
-ATOM   2435 H  HD11 . LEU M  1 156 ? 146.301 103.139 84.044 1.00 4.14  155 M 1 
-ATOM   2436 H  HD12 . LEU M  1 156 ? 147.092 104.435 83.598 1.00 4.14  155 M 1 
-ATOM   2437 H  HD13 . LEU M  1 156 ? 147.842 103.039 83.669 1.00 4.14  155 M 1 
-ATOM   2438 H  HD21 . LEU M  1 156 ? 146.739 102.033 86.079 1.00 4.14  155 M 1 
-ATOM   2439 H  HD22 . LEU M  1 156 ? 148.323 102.036 85.987 1.00 4.14  155 M 1 
-ATOM   2440 H  HD23 . LEU M  1 156 ? 147.597 102.688 87.234 1.00 4.14  155 M 1 
-ATOM   2441 N  N    . ARG M  1 157 ? 151.130 106.511 86.611 1.00 4.62  156 M 1 
-ATOM   2442 C  CA   . ARG M  1 157 ? 152.566 106.885 86.712 1.00 4.62  156 M 1 
-ATOM   2443 C  C    . ARG M  1 157 ? 152.921 107.087 88.185 1.00 4.62  156 M 1 
-ATOM   2444 O  O    . ARG M  1 157 ? 153.909 106.536 88.619 1.00 4.62  156 M 1 
-ATOM   2445 C  CB   . ARG M  1 157 ? 152.855 108.202 85.999 1.00 4.62  156 M 1 
-ATOM   2446 C  CG   . ARG M  1 157 ? 152.830 108.083 84.492 1.00 4.62  156 M 1 
-ATOM   2447 C  CD   . ARG M  1 157 ? 153.154 109.409 83.844 1.00 4.62  156 M 1 
-ATOM   2448 N  NE   . ARG M  1 157 ? 153.240 109.244 82.412 1.00 4.62  156 M 1 
-ATOM   2449 C  CZ   . ARG M  1 157 ? 152.921 110.186 81.543 1.00 4.62  156 M 1 
-ATOM   2450 N  NH1  . ARG M  1 157 ? 152.486 111.355 81.979 1.00 4.62  156 M 1 
-ATOM   2451 N  NH2  . ARG M  1 157 ? 153.027 109.953 80.247 1.00 4.62  156 M 1 
-ATOM   2452 H  H    . ARG M  1 157 ? 150.642 107.005 86.024 1.00 4.62  156 M 1 
-ATOM   2453 H  HA   . ARG M  1 157 ? 153.121 106.166 86.331 1.00 4.62  156 M 1 
-ATOM   2454 H  HB2  . ARG M  1 157 ? 152.188 108.864 86.277 1.00 4.62  156 M 1 
-ATOM   2455 H  HB3  . ARG M  1 157 ? 153.737 108.524 86.279 1.00 4.62  156 M 1 
-ATOM   2456 H  HG2  . ARG M  1 157 ? 153.485 107.412 84.204 1.00 4.62  156 M 1 
-ATOM   2457 H  HG3  . ARG M  1 157 ? 151.940 107.789 84.201 1.00 4.62  156 M 1 
-ATOM   2458 H  HD2  . ARG M  1 157 ? 152.455 110.063 84.060 1.00 4.62  156 M 1 
-ATOM   2459 H  HD3  . ARG M  1 157 ? 154.009 109.746 84.189 1.00 4.62  156 M 1 
-ATOM   2460 H  HE   . ARG M  1 157 ? 153.523 108.480 82.102 1.00 4.62  156 M 1 
-ATOM   2461 H  HH11 . ARG M  1 157 ? 152.417 111.503 82.842 1.00 4.62  156 M 1 
-ATOM   2462 H  HH12 . ARG M  1 157 ? 152.272 111.983 81.403 1.00 4.62  156 M 1 
-ATOM   2463 H  HH21 . ARG M  1 157 ? 153.315 109.170 79.965 1.00 4.62  156 M 1 
-ATOM   2464 H  HH22 . ARG M  1 157 ? 152.811 110.582 79.670 1.00 4.62  156 M 1 
-ATOM   2465 N  N    . LYS M  1 158 ? 152.072 107.791 88.925 1.00 5.18  157 M 1 
-ATOM   2466 C  CA   . LYS M  1 158 ? 152.305 108.139 90.355 1.00 5.18  157 M 1 
-ATOM   2467 C  C    . LYS M  1 158 ? 152.363 106.858 91.193 1.00 5.18  157 M 1 
-ATOM   2468 O  O    . LYS M  1 158 ? 153.242 106.774 92.033 1.00 5.18  157 M 1 
-ATOM   2469 C  CB   . LYS M  1 158 ? 151.255 109.143 90.834 1.00 5.18  157 M 1 
-ATOM   2470 C  CG   . LYS M  1 158 ? 151.459 110.545 90.277 1.00 5.18  157 M 1 
-ATOM   2471 C  CD   . LYS M  1 158 ? 150.766 111.657 91.039 1.00 5.18  157 M 1 
-ATOM   2472 C  CE   . LYS M  1 158 ? 151.182 113.041 90.582 1.00 5.18  157 M 1 
-ATOM   2473 N  NZ   . LYS M  1 158 ? 152.590 113.343 90.962 1.00 5.18  157 M 1 
-ATOM   2474 H  H    . LYS M  1 158 ? 151.240 108.010 88.630 1.00 5.18  157 M 1 
-ATOM   2475 H  HA   . LYS M  1 158 ? 153.187 108.574 90.412 1.00 5.18  157 M 1 
-ATOM   2476 H  HB2  . LYS M  1 158 ? 150.368 108.823 90.568 1.00 5.18  157 M 1 
-ATOM   2477 H  HB3  . LYS M  1 158 ? 151.282 109.184 91.812 1.00 5.18  157 M 1 
-ATOM   2478 H  HG2  . LYS M  1 158 ? 152.422 110.733 90.258 1.00 5.18  157 M 1 
-ATOM   2479 H  HG3  . LYS M  1 158 ? 151.140 110.558 89.349 1.00 5.18  157 M 1 
-ATOM   2480 H  HD2  . LYS M  1 158 ? 149.796 111.565 90.928 1.00 5.18  157 M 1 
-ATOM   2481 H  HD3  . LYS M  1 158 ? 150.970 111.564 91.995 1.00 5.18  157 M 1 
-ATOM   2482 H  HE2  . LYS M  1 158 ? 151.094 113.105 89.612 1.00 5.18  157 M 1 
-ATOM   2483 H  HE3  . LYS M  1 158 ? 150.594 113.708 90.984 1.00 5.18  157 M 1 
-ATOM   2484 H  HZ1  . LYS M  1 158 ? 152.792 114.199 90.737 1.00 5.18  157 M 1 
-ATOM   2485 H  HZ2  . LYS M  1 158 ? 152.696 113.238 91.856 1.00 5.18  157 M 1 
-ATOM   2486 H  HZ3  . LYS M  1 158 ? 153.153 112.781 90.528 1.00 5.18  157 M 1 
-ATOM   2487 N  N    . MET M  1 159 ? 151.514 105.879 90.895 1.00 5.22  158 M 1 
-ATOM   2488 C  CA   . MET M  1 159 ? 151.432 104.578 91.613 1.00 5.22  158 M 1 
-ATOM   2489 C  C    . MET M  1 159 ? 152.658 103.713 91.315 1.00 5.22  158 M 1 
-ATOM   2490 O  O    . MET M  1 159 ? 152.825 102.725 91.997 1.00 5.22  158 M 1 
-ATOM   2491 C  CB   . MET M  1 159 ? 150.172 103.809 91.228 1.00 5.22  158 M 1 
-ATOM   2492 C  CG   . MET M  1 159 ? 148.916 104.469 91.735 1.00 5.22  158 M 1 
-ATOM   2493 S  SD   . MET M  1 159 ? 147.452 103.782 90.930 1.00 5.22  158 M 1 
-ATOM   2494 C  CE   . MET M  1 159 ? 147.174 102.347 91.968 1.00 5.22  158 M 1 
-ATOM   2495 H  H    . MET M  1 159 ? 150.989 105.909 90.152 1.00 5.22  158 M 1 
-ATOM   2496 H  HA   . MET M  1 159 ? 151.413 104.766 92.580 1.00 5.22  158 M 1 
-ATOM   2497 H  HB2  . MET M  1 159 ? 150.128 103.739 90.254 1.00 5.22  158 M 1 
-ATOM   2498 H  HB3  . MET M  1 159 ? 150.229 102.903 91.593 1.00 5.22  158 M 1 
-ATOM   2499 H  HG2  . MET M  1 159 ? 148.843 104.335 92.704 1.00 5.22  158 M 1 
-ATOM   2500 H  HG3  . MET M  1 159 ? 148.958 105.433 91.559 1.00 5.22  158 M 1 
-ATOM   2501 H  HE1  . MET M  1 159 ? 146.343 101.926 91.717 1.00 5.22  158 M 1 
-ATOM   2502 H  HE2  . MET M  1 159 ? 147.900 101.722 91.853 1.00 5.22  158 M 1 
-ATOM   2503 H  HE3  . MET M  1 159 ? 147.129 102.623 92.891 1.00 5.22  158 M 1 
-ATOM   2504 N  N    . GLY M  1 160 ? 153.447 104.059 90.305 1.00 6.11  159 M 1 
-ATOM   2505 C  CA   . GLY M  1 160 ? 154.641 103.293 89.915 1.00 6.11  159 M 1 
-ATOM   2506 C  C    . GLY M  1 160 ? 154.401 102.326 88.772 1.00 6.11  159 M 1 
-ATOM   2507 O  O    . GLY M  1 160 ? 155.296 101.539 88.514 1.00 6.11  159 M 1 
-ATOM   2508 H  H    . GLY M  1 160 ? 153.270 104.785 89.785 1.00 6.11  159 M 1 
-ATOM   2509 H  HA2  . GLY M  1 160 ? 155.354 103.929 89.655 1.00 6.11  159 M 1 
-ATOM   2510 H  HA3  . GLY M  1 160 ? 154.964 102.788 90.703 1.00 6.11  159 M 1 
-ATOM   2511 N  N    . ALA M  1 161 ? 153.295 102.429 88.028 1.00 5.68  160 M 1 
-ATOM   2512 C  CA   . ALA M  1 161 ? 153.010 101.513 86.900 1.00 5.68  160 M 1 
-ATOM   2513 C  C    . ALA M  1 161 ? 154.054 101.713 85.779 1.00 5.68  160 M 1 
-ATOM   2514 O  O    . ALA M  1 161 ? 154.506 102.844 85.635 1.00 5.68  160 M 1 
-ATOM   2515 C  CB   . ALA M  1 161 ? 151.618 101.684 86.356 1.00 5.68  160 M 1 
-ATOM   2516 H  H    . ALA M  1 161 ? 152.714 103.128 88.073 1.00 5.68  160 M 1 
-ATOM   2517 H  HA   . ALA M  1 161 ? 153.078 100.613 87.280 1.00 5.68  160 M 1 
-ATOM   2518 H  HB1  . ALA M  1 161 ? 151.477 101.064 85.620 1.00 5.68  160 M 1 
-ATOM   2519 H  HB2  . ALA M  1 161 ? 150.970 101.504 87.058 1.00 5.68  160 M 1 
-ATOM   2520 H  HB3  . ALA M  1 161 ? 151.503 102.595 86.037 1.00 5.68  160 M 1 
-ATOM   2521 N  N    . PRO M  1 162 ? 154.409 100.749 84.886 1.00 7.28  161 M 1 
-ATOM   2522 C  CA   . PRO M  1 162 ? 154.085 99.312  84.954 1.00 7.28  161 M 1 
-ATOM   2523 C  C    . PRO M  1 162 ? 154.971 98.516  85.926 1.00 7.28  161 M 1 
-ATOM   2524 O  O    . PRO M  1 162 ? 154.581 97.457  86.342 1.00 7.28  161 M 1 
-ATOM   2525 C  CB   . PRO M  1 162 ? 154.330 98.822  83.521 1.00 7.28  161 M 1 
-ATOM   2526 C  CG   . PRO M  1 162 ? 155.490 99.653  83.076 1.00 7.28  161 M 1 
-ATOM   2527 C  CD   . PRO M  1 162 ? 155.248 101.006 83.709 1.00 7.28  161 M 1 
-ATOM   2528 H  HA   . PRO M  1 162 ? 153.129 99.190  85.181 1.00 7.28  161 M 1 
-ATOM   2529 H  HB2  . PRO M  1 162 ? 154.554 97.867  83.506 1.00 7.28  161 M 1 
-ATOM   2530 H  HB3  . PRO M  1 162 ? 153.546 98.977  82.953 1.00 7.28  161 M 1 
-ATOM   2531 H  HG2  . PRO M  1 162 ? 156.335 99.269  83.388 1.00 7.28  161 M 1 
-ATOM   2532 H  HG3  . PRO M  1 162 ? 155.514 99.725  82.100 1.00 7.28  161 M 1 
-ATOM   2533 H  HD2  . PRO M  1 162 ? 156.091 101.420 83.972 1.00 7.28  161 M 1 
-ATOM   2534 H  HD3  . PRO M  1 162 ? 154.791 101.601 83.086 1.00 7.28  161 M 1 
-ATOM   2535 N  N    . GLU M  1 163 ? 156.116 99.069  86.313 1.00 9.11  162 M 1 
-ATOM   2536 C  CA   . GLU M  1 163 ? 157.116 98.359  87.156 1.00 9.11  162 M 1 
-ATOM   2537 C  C    . GLU M  1 163 ? 156.554 97.984  88.534 1.00 9.11  162 M 1 
-ATOM   2538 O  O    . GLU M  1 163 ? 156.810 96.847  88.932 1.00 9.11  162 M 1 
-ATOM   2539 C  CB   . GLU M  1 163 ? 158.407 99.172  87.161 1.00 9.11  162 M 1 
-ATOM   2540 C  CG   . GLU M  1 163 ? 158.962 99.335  85.753 1.00 9.11  162 M 1 
-ATOM   2541 C  CD   . GLU M  1 163 ? 159.605 98.072  85.199 1.00 9.11  162 M 1 
-ATOM   2542 O  OE1  . GLU M  1 163 ? 160.214 97.338  85.995 1.00 9.11  162 M 1 
-ATOM   2543 O  OE2  . GLU M  1 163 ? 159.535 97.834  83.968 1.00 9.11  162 M 1 
-ATOM   2544 H  H    . GLU M  1 163 ? 156.311 99.945  86.185 1.00 9.11  162 M 1 
-ATOM   2545 H  HA   . GLU M  1 163 ? 157.316 97.512  86.695 1.00 9.11  162 M 1 
-ATOM   2546 H  HB2  . GLU M  1 163 ? 158.228 100.055 87.545 1.00 9.11  162 M 1 
-ATOM   2547 H  HB3  . GLU M  1 163 ? 159.070 98.718  87.722 1.00 9.11  162 M 1 
-ATOM   2548 H  HG2  . GLU M  1 163 ? 158.236 99.605  85.151 1.00 9.11  162 M 1 
-ATOM   2549 H  HG3  . GLU M  1 163 ? 159.631 100.052 85.753 1.00 9.11  162 M 1 
-ATOM   2550 N  N    . ALA M  1 164 ? 155.776 98.815  89.227 1.00 7.30  163 M 1 
-ATOM   2551 C  CA   . ALA M  1 164 ? 155.234 98.411  90.546 1.00 7.30  163 M 1 
-ATOM   2552 C  C    . ALA M  1 164 ? 154.122 97.408  90.223 1.00 7.30  163 M 1 
-ATOM   2553 O  O    . ALA M  1 164 ? 153.116 97.838  89.664 1.00 7.30  163 M 1 
-ATOM   2554 C  CB   . ALA M  1 164 ? 154.740 99.593  91.340 1.00 7.30  163 M 1 
-ATOM   2555 H  H    . ALA M  1 164 ? 155.409 99.570  88.902 1.00 7.30  163 M 1 
-ATOM   2556 H  HA   . ALA M  1 164 ? 155.952 97.964  91.051 1.00 7.30  163 M 1 
-ATOM   2557 H  HB1  . ALA M  1 164 ? 154.393 99.288  92.195 1.00 7.30  163 M 1 
-ATOM   2558 H  HB2  . ALA M  1 164 ? 155.473 100.212 91.492 1.00 7.30  163 M 1 
-ATOM   2559 H  HB3  . ALA M  1 164 ? 154.034 100.043 90.847 1.00 7.30  163 M 1 
-ATOM   2560 N  N    . GLY M  1 165 ? 154.236 96.151  90.658 1.00 6.92  164 M 1 
-ATOM   2561 C  CA   . GLY M  1 165 ? 153.314 95.083  90.241 1.00 6.92  164 M 1 
-ATOM   2562 C  C    . GLY M  1 165 ? 151.868 95.338  90.628 1.00 6.92  164 M 1 
-ATOM   2563 O  O    . GLY M  1 165 ? 151.010 95.167  89.782 1.00 6.92  164 M 1 
-ATOM   2564 H  H    . GLY M  1 165 ? 154.779 95.909  91.347 1.00 6.92  164 M 1 
-ATOM   2565 H  HA2  . GLY M  1 165 ? 153.372 94.981  89.258 1.00 6.92  164 M 1 
-ATOM   2566 H  HA3  . GLY M  1 165 ? 153.612 94.231  90.648 1.00 6.92  164 M 1 
-ATOM   2567 N  N    . MET M  1 166 ? 151.605 95.837  91.826 1.00 5.59  165 M 1 
-ATOM   2568 C  CA   . MET M  1 166 ? 150.221 96.059  92.311 1.00 5.59  165 M 1 
-ATOM   2569 C  C    . MET M  1 166 ? 149.565 97.323  91.718 1.00 5.59  165 M 1 
-ATOM   2570 O  O    . MET M  1 166 ? 148.351 97.431  91.853 1.00 5.59  165 M 1 
-ATOM   2571 C  CB   . MET M  1 166 ? 150.183 96.094  93.844 1.00 5.59  165 M 1 
-ATOM   2572 C  CG   . MET M  1 166 ? 149.711 94.770  94.463 1.00 5.59  165 M 1 
-ATOM   2573 S  SD   . MET M  1 166 ? 150.210 94.519  96.182 1.00 5.59  165 M 1 
-ATOM   2574 C  CE   . MET M  1 166 ? 150.247 96.218  96.745 1.00 5.59  165 M 1 
-ATOM   2575 H  H    . MET M  1 166 ? 152.252 96.152  92.384 1.00 5.59  165 M 1 
-ATOM   2576 H  HA   . MET M  1 166 ? 149.687 95.288  92.011 1.00 5.59  165 M 1 
-ATOM   2577 H  HB2  . MET M  1 166 ? 151.079 96.301  94.177 1.00 5.59  165 M 1 
-ATOM   2578 H  HB3  . MET M  1 166 ? 149.584 96.812  94.130 1.00 5.59  165 M 1 
-ATOM   2579 H  HG2  . MET M  1 166 ? 148.732 94.732  94.416 1.00 5.59  165 M 1 
-ATOM   2580 H  HG3  . MET M  1 166 ? 150.062 94.028  93.926 1.00 5.59  165 M 1 
-ATOM   2581 H  HE1  . MET M  1 166 ? 149.345 96.557  96.802 1.00 5.59  165 M 1 
-ATOM   2582 H  HE2  . MET M  1 166 ? 150.662 96.258  97.616 1.00 5.59  165 M 1 
-ATOM   2583 H  HE3  . MET M  1 166 ? 150.754 96.752  96.122 1.00 5.59  165 M 1 
-ATOM   2584 N  N    . ALA M  1 167 ? 150.296 98.233  91.066 1.00 5.07  166 M 1 
-ATOM   2585 C  CA   . ALA M  1 167 ? 149.727 99.509  90.580 1.00 5.07  166 M 1 
-ATOM   2586 C  C    . ALA M  1 167 ? 148.602 99.286  89.562 1.00 5.07  166 M 1 
-ATOM   2587 O  O    . ALA M  1 167 ? 147.510 99.735  89.842 1.00 5.07  166 M 1 
-ATOM   2588 C  CB   . ALA M  1 167 ? 150.817 100.366 89.972 1.00 5.07  166 M 1 
-ATOM   2589 H  H    . ALA M  1 167 ? 151.155 98.122  90.809 1.00 5.07  166 M 1 
-ATOM   2590 H  HA   . ALA M  1 167 ? 149.348 99.989  91.353 1.00 5.07  166 M 1 
-ATOM   2591 H  HB1  . ALA M  1 167 ? 150.435 101.202 89.655 1.00 5.07  166 M 1 
-ATOM   2592 H  HB2  . ALA M  1 167 ? 151.494 100.556 90.643 1.00 5.07  166 M 1 
-ATOM   2593 H  HB3  . ALA M  1 167 ? 151.224 99.894  89.227 1.00 5.07  166 M 1 
-ATOM   2594 N  N    . GLU M  1 168 ? 148.815 98.511  88.504 1.00 4.44  167 M 1 
-ATOM   2595 C  CA   . GLU M  1 168 ? 147.748 98.325  87.474 1.00 4.44  167 M 1 
-ATOM   2596 C  C    . GLU M  1 168 ? 146.605 97.530  88.114 1.00 4.44  167 M 1 
-ATOM   2597 O  O    . GLU M  1 168 ? 145.468 97.850  87.878 1.00 4.44  167 M 1 
-ATOM   2598 C  CB   . GLU M  1 168 ? 148.344 97.782  86.175 1.00 4.44  167 M 1 
-ATOM   2599 C  CG   . GLU M  1 168 ? 149.229 98.839  85.535 1.00 4.44  167 M 1 
-ATOM   2600 C  CD   . GLU M  1 168 ? 149.720 98.632  84.117 1.00 4.44  167 M 1 
-ATOM   2601 O  OE1  . GLU M  1 168 ? 149.618 97.495  83.616 1.00 4.44  167 M 1 
-ATOM   2602 O  OE2  . GLU M  1 168 ? 150.234 99.621  83.538 1.00 4.44  167 M 1 
-ATOM   2603 H  H    . GLU M  1 168 ? 149.551 97.986  88.400 1.00 4.44  167 M 1 
-ATOM   2604 H  HA   . GLU M  1 168 ? 147.392 99.221  87.272 1.00 4.44  167 M 1 
-ATOM   2605 H  HB2  . GLU M  1 168 ? 148.872 96.980  86.369 1.00 4.44  167 M 1 
-ATOM   2606 H  HB3  . GLU M  1 168 ? 147.619 97.540  85.561 1.00 4.44  167 M 1 
-ATOM   2607 H  HG2  . GLU M  1 168 ? 148.743 99.691  85.554 1.00 4.44  167 M 1 
-ATOM   2608 H  HG3  . GLU M  1 168 ? 150.020 98.955  86.104 1.00 4.44  167 M 1 
-ATOM   2609 N  N    . TYR M  1 169 ? 146.921 96.577  88.980 1.00 4.01  168 M 1 
-ATOM   2610 C  CA   . TYR M  1 169 ? 145.892 95.728  89.630 1.00 4.01  168 M 1 
-ATOM   2611 C  C    . TYR M  1 169 ? 144.938 96.568  90.492 1.00 4.01  168 M 1 
-ATOM   2612 O  O    . TYR M  1 169 ? 143.761 96.423  90.331 1.00 4.01  168 M 1 
-ATOM   2613 C  CB   . TYR M  1 169 ? 146.555 94.628  90.464 1.00 4.01  168 M 1 
-ATOM   2614 C  CG   . TYR M  1 169 ? 145.550 93.777  91.191 1.00 4.01  168 M 1 
-ATOM   2615 C  CD1  . TYR M  1 169 ? 144.937 92.700  90.566 1.00 4.01  168 M 1 
-ATOM   2616 C  CD2  . TYR M  1 169 ? 145.160 94.088  92.479 1.00 4.01  168 M 1 
-ATOM   2617 C  CE1  . TYR M  1 169 ? 143.997 91.924  91.224 1.00 4.01  168 M 1 
-ATOM   2618 C  CE2  . TYR M  1 169 ? 144.243 93.310  93.161 1.00 4.01  168 M 1 
-ATOM   2619 C  CZ   . TYR M  1 169 ? 143.646 92.236  92.524 1.00 4.01  168 M 1 
-ATOM   2620 O  OH   . TYR M  1 169 ? 142.716 91.496  93.177 1.00 4.01  168 M 1 
-ATOM   2621 H  H    . TYR M  1 169 ? 147.751 96.468  89.336 1.00 4.01  168 M 1 
-ATOM   2622 H  HA   . TYR M  1 169 ? 145.357 95.295  88.917 1.00 4.01  168 M 1 
-ATOM   2623 H  HB2  . TYR M  1 169 ? 147.091 94.061  89.871 1.00 4.01  168 M 1 
-ATOM   2624 H  HB3  . TYR M  1 169 ? 147.158 95.045  91.115 1.00 4.01  168 M 1 
-ATOM   2625 H  HD1  . TYR M  1 169 ? 145.176 92.483  89.680 1.00 4.01  168 M 1 
-ATOM   2626 H  HD2  . TYR M  1 169 ? 145.567 94.814  92.922 1.00 4.01  168 M 1 
-ATOM   2627 H  HE1  . TYR M  1 169 ? 143.597 91.189  90.788 1.00 4.01  168 M 1 
-ATOM   2628 H  HE2  . TYR M  1 169 ? 143.994 93.534  94.042 1.00 4.01  168 M 1 
-ATOM   2629 H  HH   . TYR M  1 169 ? 142.054 91.991  93.406 1.00 4.01  168 M 1 
-ATOM   2630 N  N    . LEU M  1 170 ? 145.441 97.487  91.311 1.00 4.13  169 M 1 
-ATOM   2631 C  CA   . LEU M  1 170 ? 144.616 98.274  92.218 1.00 4.13  169 M 1 
-ATOM   2632 C  C    . LEU M  1 170 ? 143.909 99.399  91.476 1.00 4.13  169 M 1 
-ATOM   2633 O  O    . LEU M  1 170 ? 142.798 99.792  91.845 1.00 4.13  169 M 1 
-ATOM   2634 C  CB   . LEU M  1 170 ? 145.469 98.813  93.366 1.00 4.13  169 M 1 
-ATOM   2635 C  CG   . LEU M  1 170 ? 146.030 97.767  94.341 1.00 4.13  169 M 1 
-ATOM   2636 C  CD1  . LEU M  1 170 ? 146.951 98.399  95.361 1.00 4.13  169 M 1 
-ATOM   2637 C  CD2  . LEU M  1 170 ? 144.904 97.009  95.034 1.00 4.13  169 M 1 
-ATOM   2638 H  H    . LEU M  1 170 ? 146.286 97.642  91.355 1.00 4.13  169 M 1 
-ATOM   2639 H  HA   . LEU M  1 170 ? 143.922 97.699  92.576 1.00 4.13  169 M 1 
-ATOM   2640 H  HB2  . LEU M  1 170 ? 146.226 99.287  92.988 1.00 4.13  169 M 1 
-ATOM   2641 H  HB3  . LEU M  1 170 ? 144.932 99.435  93.881 1.00 4.13  169 M 1 
-ATOM   2642 H  HG   . LEU M  1 170 ? 146.553 97.119  93.843 1.00 4.13  169 M 1 
-ATOM   2643 H  HD11 . LEU M  1 170 ? 147.356 97.694  95.890 1.00 4.13  169 M 1 
-ATOM   2644 H  HD12 . LEU M  1 170 ? 147.644 98.911  94.915 1.00 4.13  169 M 1 
-ATOM   2645 H  HD13 . LEU M  1 170 ? 146.426 98.981  95.933 1.00 4.13  169 M 1 
-ATOM   2646 H  HD21 . LEU M  1 170 ? 145.268 96.464  95.749 1.00 4.13  169 M 1 
-ATOM   2647 H  HD22 . LEU M  1 170 ? 144.268 97.648  95.391 1.00 4.13  169 M 1 
-ATOM   2648 H  HD23 . LEU M  1 170 ? 144.460 96.432  94.393 1.00 4.13  169 M 1 
-ATOM   2649 N  N    . PHE M  1 171 ? 144.530 99.912  90.419 1.00 3.79  170 M 1 
-ATOM   2650 C  CA   . PHE M  1 171 ? 143.872 100.895 89.568 1.00 3.79  170 M 1 
-ATOM   2651 C  C    . PHE M  1 171 ? 142.682 100.273 88.847 1.00 3.79  170 M 1 
-ATOM   2652 O  O    . PHE M  1 171 ? 141.621 100.894 88.730 1.00 3.79  170 M 1 
-ATOM   2653 C  CB   . PHE M  1 171 ? 144.874 101.442 88.562 1.00 3.79  170 M 1 
-ATOM   2654 C  CG   . PHE M  1 171 ? 144.340 102.550 87.735 1.00 3.79  170 M 1 
-ATOM   2655 C  CD1  . PHE M  1 171 ? 144.342 103.846 88.205 1.00 3.79  170 M 1 
-ATOM   2656 C  CD2  . PHE M  1 171 ? 143.774 102.294 86.510 1.00 3.79  170 M 1 
-ATOM   2657 C  CE1  . PHE M  1 171 ? 143.840 104.856 87.442 1.00 3.79  170 M 1 
-ATOM   2658 C  CE2  . PHE M  1 171 ? 143.267 103.300 85.759 1.00 3.79  170 M 1 
-ATOM   2659 C  CZ   . PHE M  1 171 ? 143.300 104.576 86.223 1.00 3.79  170 M 1 
-ATOM   2660 H  H    . PHE M  1 171 ? 145.328 99.706  90.173 1.00 3.79  170 M 1 
-ATOM   2661 H  HA   . PHE M  1 171 ? 143.555 101.638 90.105 1.00 3.79  170 M 1 
-ATOM   2662 H  HB2  . PHE M  1 171 ? 145.651 101.772 89.040 1.00 3.79  170 M 1 
-ATOM   2663 H  HB3  . PHE M  1 171 ? 145.148 100.727 87.967 1.00 3.79  170 M 1 
-ATOM   2664 H  HD1  . PHE M  1 171 ? 144.718 104.044 89.032 1.00 3.79  170 M 1 
-ATOM   2665 H  HD2  . PHE M  1 171 ? 143.749 101.423 86.186 1.00 3.79  170 M 1 
-ATOM   2666 H  HE1  . PHE M  1 171 ? 143.856 105.730 87.758 1.00 3.79  170 M 1 
-ATOM   2667 H  HE2  . PHE M  1 171 ? 142.897 103.113 84.927 1.00 3.79  170 M 1 
-ATOM   2668 H  HZ   . PHE M  1 171 ? 142.954 105.265 85.703 1.00 3.79  170 M 1 
-ATOM   2669 N  N    . ASP M  1 172 ? 142.886 99.054  88.392 1.00 4.02  171 M 1 
-ATOM   2670 C  CA   . ASP M  1 172 ? 141.806 98.292  87.727 1.00 4.02  171 M 1 
-ATOM   2671 C  C    . ASP M  1 172 ? 140.659 98.138  88.738 1.00 4.02  171 M 1 
-ATOM   2672 O  O    . ASP M  1 172 ? 139.533 98.351  88.327 1.00 4.02  171 M 1 
-ATOM   2673 C  CB   . ASP M  1 172 ? 142.330 96.951  87.193 1.00 4.02  171 M 1 
-ATOM   2674 C  CG   . ASP M  1 172 ? 141.273 96.045  86.572 1.00 4.02  171 M 1 
-ATOM   2675 O  OD1  . ASP M  1 172 ? 140.506 95.464  87.323 1.00 4.02  171 M 1 
-ATOM   2676 O  OD2  . ASP M  1 172 ? 141.246 95.911  85.334 1.00 4.02  171 M 1 
-ATOM   2677 H  H    . ASP M  1 172 ? 143.713 98.680  88.321 1.00 4.02  171 M 1 
-ATOM   2678 H  HA   . ASP M  1 172 ? 141.480 98.822  86.962 1.00 4.02  171 M 1 
-ATOM   2679 H  HB2  . ASP M  1 172 ? 143.014 97.129  86.515 1.00 4.02  171 M 1 
-ATOM   2680 H  HB3  . ASP M  1 172 ? 142.753 96.464  87.929 1.00 4.02  171 M 1 
-ATOM   2681 N  N    . LYS M  1 173 ? 140.916 97.846  90.025 1.00 4.18  172 M 1 
-ATOM   2682 C  CA   . LYS M  1 173 ? 139.818 97.616  90.960 1.00 4.18  172 M 1 
-ATOM   2683 C  C    . LYS M  1 173 ? 139.128 98.913  91.381 1.00 4.18  172 M 1 
-ATOM   2684 O  O    . LYS M  1 173 ? 137.897 98.991  91.389 1.00 4.18  172 M 1 
-ATOM   2685 C  CB   . LYS M  1 173 ? 140.325 96.848  92.179 1.00 4.18  172 M 1 
-ATOM   2686 C  CG   . LYS M  1 173 ? 140.865 95.460  91.866 1.00 4.18  172 M 1 
-ATOM   2687 C  CD   . LYS M  1 173 ? 139.777 94.534  91.328 1.00 4.18  172 M 1 
-ATOM   2688 C  CE   . LYS M  1 173 ? 140.229 93.101  91.153 1.00 4.18  172 M 1 
-ATOM   2689 N  NZ   . LYS M  1 173 ? 139.141 92.269  90.574 1.00 4.18  172 M 1 
-ATOM   2690 H  H    . LYS M  1 173 ? 141.708 97.794  90.356 1.00 4.18  172 M 1 
-ATOM   2691 H  HA   . LYS M  1 173 ? 139.134 97.087  90.521 1.00 4.18  172 M 1 
-ATOM   2692 H  HB2  . LYS M  1 173 ? 141.048 97.352  92.584 1.00 4.18  172 M 1 
-ATOM   2693 H  HB3  . LYS M  1 173 ? 139.597 96.747  92.812 1.00 4.18  172 M 1 
-ATOM   2694 H  HG2  . LYS M  1 173 ? 141.556 95.531  91.189 1.00 4.18  172 M 1 
-ATOM   2695 H  HG3  . LYS M  1 173 ? 141.237 95.075  92.675 1.00 4.18  172 M 1 
-ATOM   2696 H  HD2  . LYS M  1 173 ? 139.010 94.546  91.921 1.00 4.18  172 M 1 
-ATOM   2697 H  HD3  . LYS M  1 173 ? 139.524 94.850  90.446 1.00 4.18  172 M 1 
-ATOM   2698 H  HE2  . LYS M  1 173 ? 140.984 93.064  90.545 1.00 4.18  172 M 1 
-ATOM   2699 H  HE3  . LYS M  1 173 ? 140.476 92.729  92.014 1.00 4.18  172 M 1 
-ATOM   2700 H  HZ1  . LYS M  1 173 ? 139.354 91.406  90.625 1.00 4.18  172 M 1 
-ATOM   2701 H  HZ2  . LYS M  1 173 ? 138.377 92.403  91.010 1.00 4.18  172 M 1 
-ATOM   2702 H  HZ3  . LYS M  1 173 ? 139.022 92.484  89.719 1.00 4.18  172 M 1 
-ATOM   2703 N  N    . HIS M  1 174 ? 139.898 99.937  91.734 1.00 4.28  173 M 1 
-ATOM   2704 C  CA   . HIS M  1 174 ? 139.326 101.141 92.340 1.00 4.28  173 M 1 
-ATOM   2705 C  C    . HIS M  1 174 ? 138.808 102.130 91.299 1.00 4.28  173 M 1 
-ATOM   2706 O  O    . HIS M  1 174 ? 137.635 102.510 91.318 1.00 4.28  173 M 1 
-ATOM   2707 C  CB   . HIS M  1 174 ? 140.365 101.793 93.254 1.00 4.28  173 M 1 
-ATOM   2708 C  CG   . HIS M  1 174 ? 140.680 100.984 94.467 1.00 4.28  173 M 1 
-ATOM   2709 N  ND1  . HIS M  1 174 ? 139.808 100.871 95.527 1.00 4.28  173 M 1 
-ATOM   2710 C  CD2  . HIS M  1 174 ? 141.767 100.251 94.792 1.00 4.28  173 M 1 
-ATOM   2711 C  CE1  . HIS M  1 174 ? 140.345 100.097 96.451 1.00 4.28  173 M 1 
-ATOM   2712 N  NE2  . HIS M  1 174 ? 141.533 99.709  96.031 1.00 4.28  173 M 1 
-ATOM   2713 H  H    . HIS M  1 174 ? 140.752 99.957  91.635 1.00 4.28  173 M 1 
-ATOM   2714 H  HA   . HIS M  1 174 ? 138.576 100.895 92.904 1.00 4.28  173 M 1 
-ATOM   2715 H  HB2  . HIS M  1 174 ? 141.193 101.898 92.761 1.00 4.28  173 M 1 
-ATOM   2716 H  HB3  . HIS M  1 174 ? 140.046 102.661 93.547 1.00 4.28  173 M 1 
-ATOM   2717 H  HD2  . HIS M  1 174 ? 142.533 100.137 94.277 1.00 4.28  173 M 1 
-ATOM   2718 H  HE1  . HIS M  1 174 ? 139.951 99.866  97.261 1.00 4.28  173 M 1 
-ATOM   2719 H  HE2  . HIS M  1 174 ? 142.076 99.200  96.462 1.00 4.28  173 M 1 
-ATOM   2720 N  N    . THR M  1 175 ? 139.668 102.559 90.381 1.00 3.92  174 M 1 
-ATOM   2721 C  CA   . THR M  1 175 ? 139.281 103.609 89.443 1.00 3.92  174 M 1 
-ATOM   2722 C  C    . THR M  1 175 ? 138.388 103.072 88.331 1.00 3.92  174 M 1 
-ATOM   2723 O  O    . THR M  1 175 ? 137.333 103.648 88.043 1.00 3.92  174 M 1 
-ATOM   2724 C  CB   . THR M  1 175 ? 140.529 104.288 88.884 1.00 3.92  174 M 1 
-ATOM   2725 O  OG1  . THR M  1 175 ? 141.222 104.932 89.958 1.00 3.92  174 M 1 
-ATOM   2726 C  CG2  . THR M  1 175 ? 140.176 105.309 87.815 1.00 3.92  174 M 1 
-ATOM   2727 H  H    . THR M  1 175 ? 140.472 102.269 90.290 1.00 3.92  174 M 1 
-ATOM   2728 H  HA   . THR M  1 175 ? 138.774 104.287 89.917 1.00 3.92  174 M 1 
-ATOM   2729 H  HB   . THR M  1 175 ? 141.117 103.628 88.485 1.00 3.92  174 M 1 
-ATOM   2730 H  HG1  . THR M  1 175 ? 141.349 105.742 89.774 1.00 3.92  174 M 1 
-ATOM   2731 H  HG21 . THR M  1 175 ? 140.922 105.911 87.670 1.00 3.92  174 M 1 
-ATOM   2732 H  HG22 . THR M  1 175 ? 139.977 104.866 86.975 1.00 3.92  174 M 1 
-ATOM   2733 H  HG23 . THR M  1 175 ? 139.402 105.826 88.086 1.00 3.92  174 M 1 
-ATOM   2734 N  N    . LEU M  1 176 ? 138.787 101.981 87.690 1.00 3.89  175 M 1 
-ATOM   2735 C  CA   . LEU M  1 176 ? 138.029 101.435 86.571 1.00 3.89  175 M 1 
-ATOM   2736 C  C    . LEU M  1 176 ? 137.001 100.390 86.986 1.00 3.89  175 M 1 
-ATOM   2737 O  O    . LEU M  1 176 ? 136.269 99.897  86.125 1.00 3.89  175 M 1 
-ATOM   2738 C  CB   . LEU M  1 176 ? 138.981 100.835 85.536 1.00 3.89  175 M 1 
-ATOM   2739 C  CG   . LEU M  1 176 ? 139.949 101.826 84.877 1.00 3.89  175 M 1 
-ATOM   2740 C  CD1  . LEU M  1 176 ? 140.858 101.121 83.920 1.00 3.89  175 M 1 
-ATOM   2741 C  CD2  . LEU M  1 176 ? 139.256 102.990 84.197 1.00 3.89  175 M 1 
-ATOM   2742 H  H    . LEU M  1 176 ? 139.499 101.538 87.883 1.00 3.89  175 M 1 
-ATOM   2743 H  HA   . LEU M  1 176 ? 137.528 102.142 86.135 1.00 3.89  175 M 1 
-ATOM   2744 H  HB2  . LEU M  1 176 ? 139.518 100.161 85.981 1.00 3.89  175 M 1 
-ATOM   2745 H  HB3  . LEU M  1 176 ? 138.456 100.406 84.843 1.00 3.89  175 M 1 
-ATOM   2746 H  HG   . LEU M  1 176 ? 140.518 102.192 85.573 1.00 3.89  175 M 1 
-ATOM   2747 H  HD11 . LEU M  1 176 ? 140.996 101.648 83.117 1.00 3.89  175 M 1 
-ATOM   2748 H  HD12 . LEU M  1 176 ? 141.711 100.998 84.365 1.00 3.89  175 M 1 
-ATOM   2749 H  HD13 . LEU M  1 176 ? 140.472 100.264 83.679 1.00 3.89  175 M 1 
-ATOM   2750 H  HD21 . LEU M  1 176 ? 139.918 103.538 83.747 1.00 3.89  175 M 1 
-ATOM   2751 H  HD22 . LEU M  1 176 ? 138.608 102.648 83.562 1.00 3.89  175 M 1 
-ATOM   2752 H  HD23 . LEU M  1 176 ? 138.811 103.528 84.870 1.00 3.89  175 M 1 
-ATOM   2753 N  N    . GLY M  1 177 ? 136.922 100.050 88.265 1.00 4.79  176 M 1 
-ATOM   2754 C  CA   . GLY M  1 177 ? 135.933 99.110  88.758 1.00 4.79  176 M 1 
-ATOM   2755 C  C    . GLY M  1 177 ? 134.724 99.796  89.358 1.00 4.79  176 M 1 
-ATOM   2756 O  O    . GLY M  1 177 ? 134.403 100.926 88.999 1.00 4.79  176 M 1 
-ATOM   2757 H  H    . GLY M  1 177 ? 137.440 100.352 88.881 1.00 4.79  176 M 1 
-ATOM   2758 H  HA2  . GLY M  1 177 ? 135.628 98.522  88.049 1.00 4.79  176 M 1 
-ATOM   2759 H  HA3  . GLY M  1 177 ? 136.344 98.561  89.444 1.00 4.79  176 M 1 
-HETATM 2760 ZN ZN   . ZN  PA 3 .   ? 134.712 110.111 68.601 1.00 16.76 201 M 1 
-#
diff --git a/src/alphafold3/test_data/miniature_databases/pdb_mmcif/6ydw.cif b/src/alphafold3/test_data/miniature_databases/pdb_mmcif/6ydw.cif
deleted file mode 100644
index 040f961e6b8b732218c13c13db8f378502a151d5..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/pdb_mmcif/6ydw.cif
+++ /dev/null
@@ -1,2467 +0,0 @@
-data_6YDW
-#
-_entry.id 6YDW
-#
-loop_
-_chem_comp.formula
-_chem_comp.formula_weight
-_chem_comp.id
-_chem_comp.mon_nstd_flag
-_chem_comp.name
-_chem_comp.pdbx_synonyms
-_chem_comp.type
-"C10 H14 N5 O8 P"   363.221 5GP . "GUANOSINE-5'-MONOPHOSPHATE"                  ? non-polymer         
-"C10 H14 N5 O7 P"   347.221 A   y "ADENOSINE-5'-MONOPHOSPHATE"                  ? "RNA linking"       
-"C3 H7 N O2"        89.093  ALA y ALANINE                                       ? "L-peptide linking" 
-"C6 H15 N4 O2 1"    175.209 ARG y ARGININE                                      ? "L-peptide linking" 
-"C4 H8 N2 O3"       132.118 ASN y ASPARAGINE                                    ? "L-peptide linking" 
-"C4 H7 N O4"        133.103 ASP y "ASPARTIC ACID"                               ? "L-peptide linking" 
-"C9 H14 N3 O8 P"    323.197 C   y "CYTIDINE-5'-MONOPHOSPHATE"                   ? "RNA linking"       
-"C3 H7 N O2 S"      121.158 CYS y CYSTEINE                                      ? "L-peptide linking" 
-"C6 H11 N O3 S"     177.221 FME n N-FORMYLMETHIONINE                            ? "L-peptide linking" 
-"C10 H14 N5 O8 P"   363.221 G   y "GUANOSINE-5'-MONOPHOSPHATE"                  ? "RNA linking"       
-"C5 H10 N2 O3"      146.144 GLN y GLUTAMINE                                     ? "L-peptide linking" 
-"C5 H9 N O4"        147.129 GLU y "GLUTAMIC ACID"                               ? "L-peptide linking" 
-"C2 H5 N O2"        75.067  GLY y GLYCINE                                       ? "peptide linking"   
-"C10 H17 N6 O13 P3" 522.196 GNP . "PHOSPHOAMINOPHOSPHONIC ACID-GUANYLATE ESTER" ? non-polymer         
-"C10 H16 N5 O14 P3" 523.180 GTP n "GUANOSINE-5'-TRIPHOSPHATE"                   ? non-polymer         
-"C6 H10 N3 O2 1"    156.162 HIS y HISTIDINE                                     ? "L-peptide linking" 
-"H2 O"              18.015  HOH . WATER                                         ? non-polymer         
-"C6 H13 N O2"       131.173 ILE y ISOLEUCINE                                    ? "L-peptide linking" 
-"C6 H13 N O2"       131.173 LEU y LEUCINE                                       ? "L-peptide linking" 
-"C6 H15 N2 O2 1"    147.195 LYS y LYSINE                                        ? "L-peptide linking" 
-"C5 H11 N O2 S"     149.211 MET y METHIONINE                                    ? "L-peptide linking" 
-"Mg 2"              24.305  MG  . "MAGNESIUM ION"                               ? non-polymer         
-"C9 H11 N O2"       165.189 PHE y PHENYLALANINE                                 ? "L-peptide linking" 
-"C5 H9 N O2"        115.130 PRO y PROLINE                                       ? "L-peptide linking" 
-"C3 H7 N O3"        105.093 SER y SERINE                                        ? "L-peptide linking" 
-"C10 H26 N4"        202.340 SPM . SPERMINE                                      ? non-polymer         
-"C4 H9 N O3"        119.119 THR y THREONINE                                     ? "L-peptide linking" 
-"C11 H12 N2 O2"     204.225 TRP y TRYPTOPHAN                                    ? "L-peptide linking" 
-"C9 H11 N O3"       181.189 TYR y TYROSINE                                      ? "L-peptide linking" 
-"C9 H13 N2 O9 P"    324.181 U   y "URIDINE-5'-MONOPHOSPHATE"                    ? "RNA linking"       
-"C4 H9 N O2"        103.120 UNK . UNKNOWN                                       ? "L-peptide linking" 
-"C5 H11 N O2"       117.146 VAL y VALINE                                        ? "L-peptide linking" 
-"Zn 2"              65.409  ZN  . "ZINC ION"                                    ? non-polymer         
-#
-_entity.id               17
-_entity.pdbx_description "Mitochondrial ribosomal protein L46"
-_entity.type             polymer
-#
-_entity_poly.entity_id      17
-_entity_poly.pdbx_strand_id Bj
-_entity_poly.type           polypeptide(L)
-#
-loop_
-_entity_poly_seq.entity_id
-_entity_poly_seq.hetero
-_entity_poly_seq.mon_id
-_entity_poly_seq.num
-17 n MET 1   
-17 n ALA 2   
-17 n ALA 3   
-17 n PRO 4   
-17 n VAL 5   
-17 n ARG 6   
-17 n ARG 7   
-17 n THR 8   
-17 n MET 9   
-17 n LEU 10  
-17 n ARG 11  
-17 n VAL 12  
-17 n VAL 13  
-17 n ARG 14  
-17 n GLY 15  
-17 n TRP 16  
-17 n ARG 17  
-17 n ARG 18  
-17 n PHE 19  
-17 n GLU 20  
-17 n GLY 21  
-17 n PRO 22  
-17 n TRP 23  
-17 n ALA 24  
-17 n HIS 25  
-17 n SER 26  
-17 n LEU 27  
-17 n GLY 28  
-17 n SER 29  
-17 n ARG 30  
-17 n ASN 31  
-17 n LEU 32  
-17 n ALA 33  
-17 n LEU 34  
-17 n ALA 35  
-17 n VAL 36  
-17 n ALA 37  
-17 n PRO 38  
-17 n SER 39  
-17 n SER 40  
-17 n SER 41  
-17 n SER 42  
-17 n SER 43  
-17 n PRO 44  
-17 n TRP 45  
-17 n ARG 46  
-17 n LEU 47  
-17 n LEU 48  
-17 n GLY 49  
-17 n ALA 50  
-17 n LEU 51  
-17 n CYS 52  
-17 n LEU 53  
-17 n GLN 54  
-17 n ARG 55  
-17 n PRO 56  
-17 n PRO 57  
-17 n LEU 58  
-17 n VAL 59  
-17 n THR 60  
-17 n LYS 61  
-17 n PRO 62  
-17 n LEU 63  
-17 n THR 64  
-17 n PRO 65  
-17 n LEU 66  
-17 n GLN 67  
-17 n GLU 68  
-17 n GLU 69  
-17 n MET 70  
-17 n ALA 71  
-17 n ASP 72  
-17 n LEU 73  
-17 n LEU 74  
-17 n GLN 75  
-17 n GLN 76  
-17 n ILE 77  
-17 n GLU 78  
-17 n ILE 79  
-17 n GLU 80  
-17 n ARG 81  
-17 n SER 82  
-17 n LEU 83  
-17 n TYR 84  
-17 n SER 85  
-17 n ASP 86  
-17 n HIS 87  
-17 n GLU 88  
-17 n LEU 89  
-17 n ARG 90  
-17 n ALA 91  
-17 n LEU 92  
-17 n ASP 93  
-17 n GLU 94  
-17 n ALA 95  
-17 n GLN 96  
-17 n GLN 97  
-17 n LEU 98  
-17 n ALA 99  
-17 n LYS 100 
-17 n LYS 101 
-17 n LYS 102 
-17 n SER 103 
-17 n ASP 104 
-17 n LEU 105 
-17 n TYR 106 
-17 n GLU 107 
-17 n GLU 108 
-17 n GLU 109 
-17 n ASP 110 
-17 n GLU 111 
-17 n GLN 112 
-17 n ASN 113 
-17 n ILE 114 
-17 n LEU 115 
-17 n LEU 116 
-17 n ALA 117 
-17 n GLN 118 
-17 n ASP 119 
-17 n LEU 120 
-17 n GLU 121 
-17 n ASP 122 
-17 n MET 123 
-17 n TRP 124 
-17 n GLU 125 
-17 n GLN 126 
-17 n LYS 127 
-17 n PHE 128 
-17 n LEU 129 
-17 n HIS 130 
-17 n PHE 131 
-17 n LYS 132 
-17 n LEU 133 
-17 n GLY 134 
-17 n ALA 135 
-17 n ARG 136 
-17 n LEU 137 
-17 n THR 138 
-17 n GLU 139 
-17 n ALA 140 
-17 n ASP 141 
-17 n LYS 142 
-17 n LYS 143 
-17 n ASP 144 
-17 n ASP 145 
-17 n ARG 146 
-17 n THR 147 
-17 n SER 148 
-17 n LEU 149 
-17 n HIS 150 
-17 n ARG 151 
-17 n LYS 152 
-17 n LEU 153 
-17 n ASP 154 
-17 n ARG 155 
-17 n ASN 156 
-17 n LEU 157 
-17 n ILE 158 
-17 n LEU 159 
-17 n LEU 160 
-17 n VAL 161 
-17 n ARG 162 
-17 n GLU 163 
-17 n LYS 164 
-17 n LEU 165 
-17 n GLY 166 
-17 n ASP 167 
-17 n GLN 168 
-17 n ASP 169 
-17 n ILE 170 
-17 n TRP 171 
-17 n MET 172 
-17 n LEU 173 
-17 n PRO 174 
-17 n GLN 175 
-17 n SER 176 
-17 n ASP 177 
-17 n TRP 178 
-17 n GLN 179 
-17 n PRO 180 
-17 n GLY 181 
-17 n GLU 182 
-17 n THR 183 
-17 n LEU 184 
-17 n ARG 185 
-17 n GLN 186 
-17 n THR 187 
-17 n ALA 188 
-17 n GLU 189 
-17 n ARG 190 
-17 n THR 191 
-17 n LEU 192 
-17 n ALA 193 
-17 n THR 194 
-17 n LEU 195 
-17 n SER 196 
-17 n GLU 197 
-17 n ASN 198 
-17 n ASN 199 
-17 n MET 200 
-17 n GLU 201 
-17 n ALA 202 
-17 n LYS 203 
-17 n PHE 204 
-17 n LEU 205 
-17 n GLY 206 
-17 n ASN 207 
-17 n ALA 208 
-17 n PRO 209 
-17 n CYS 210 
-17 n GLY 211 
-17 n HIS 212 
-17 n TYR 213 
-17 n LYS 214 
-17 n PHE 215 
-17 n LYS 216 
-17 n PHE 217 
-17 n PRO 218 
-17 n GLN 219 
-17 n ALA 220 
-17 n MET 221 
-17 n ARG 222 
-17 n THR 223 
-17 n GLU 224 
-17 n THR 225 
-17 n SER 226 
-17 n LEU 227 
-17 n GLY 228 
-17 n ALA 229 
-17 n LYS 230 
-17 n VAL 231 
-17 n PHE 232 
-17 n PHE 233 
-17 n PHE 234 
-17 n LYS 235 
-17 n ALA 236 
-17 n LEU 237 
-17 n LEU 238 
-17 n LEU 239 
-17 n THR 240 
-17 n GLY 241 
-17 n ASP 242 
-17 n PHE 243 
-17 n SER 244 
-17 n GLN 245 
-17 n ALA 246 
-17 n GLY 247 
-17 n LYS 248 
-17 n LYS 249 
-17 n GLY 250 
-17 n HIS 251 
-17 n HIS 252 
-17 n VAL 253 
-17 n TRP 254 
-17 n VAL 255 
-17 n SER 256 
-17 n LYS 257 
-17 n GLU 258 
-17 n GLU 259 
-17 n LEU 260 
-17 n GLY 261 
-17 n ASP 262 
-17 n TYR 263 
-17 n LEU 264 
-17 n LYS 265 
-17 n PRO 266 
-17 n LYS 267 
-17 n TYR 268 
-17 n LEU 269 
-17 n ALA 270 
-17 n GLN 271 
-17 n VAL 272 
-17 n ARG 273 
-17 n ARG 274 
-17 n PHE 275 
-17 n LEU 276 
-17 n LEU 277 
-17 n ASP 278 
-17 n LEU 279 
-#
-_exptl.method "ELECTRON MICROSCOPY"
-#
-_pdbx_audit_revision_history.revision_date 2020-07-15
-#
-_pdbx_database_status.recvd_initial_deposition_date 2020-07-15
-#
-loop_
-_pdbx_poly_seq_scheme.asym_id
-_pdbx_poly_seq_scheme.auth_seq_num
-_pdbx_poly_seq_scheme.entity_id
-_pdbx_poly_seq_scheme.hetero
-_pdbx_poly_seq_scheme.mon_id
-_pdbx_poly_seq_scheme.pdb_ins_code
-_pdbx_poly_seq_scheme.pdb_seq_num
-_pdbx_poly_seq_scheme.pdb_strand_id
-_pdbx_poly_seq_scheme.seq_id
-Q ?   17 n MET . 1   Bj 1   
-Q ?   17 n ALA . 2   Bj 2   
-Q ?   17 n ALA . 3   Bj 3   
-Q ?   17 n PRO . 4   Bj 4   
-Q ?   17 n VAL . 5   Bj 5   
-Q ?   17 n ARG . 6   Bj 6   
-Q ?   17 n ARG . 7   Bj 7   
-Q ?   17 n THR . 8   Bj 8   
-Q ?   17 n MET . 9   Bj 9   
-Q ?   17 n LEU . 10  Bj 10  
-Q ?   17 n ARG . 11  Bj 11  
-Q ?   17 n VAL . 12  Bj 12  
-Q ?   17 n VAL . 13  Bj 13  
-Q ?   17 n ARG . 14  Bj 14  
-Q ?   17 n GLY . 15  Bj 15  
-Q ?   17 n TRP . 16  Bj 16  
-Q ?   17 n ARG . 17  Bj 17  
-Q ?   17 n ARG . 18  Bj 18  
-Q ?   17 n PHE . 19  Bj 19  
-Q ?   17 n GLU . 20  Bj 20  
-Q ?   17 n GLY . 21  Bj 21  
-Q ?   17 n PRO . 22  Bj 22  
-Q ?   17 n TRP . 23  Bj 23  
-Q ?   17 n ALA . 24  Bj 24  
-Q ?   17 n HIS . 25  Bj 25  
-Q ?   17 n SER . 26  Bj 26  
-Q ?   17 n LEU . 27  Bj 27  
-Q ?   17 n GLY . 28  Bj 28  
-Q ?   17 n SER . 29  Bj 29  
-Q ?   17 n ARG . 30  Bj 30  
-Q ?   17 n ASN . 31  Bj 31  
-Q ?   17 n LEU . 32  Bj 32  
-Q ?   17 n ALA . 33  Bj 33  
-Q ?   17 n LEU . 34  Bj 34  
-Q ?   17 n ALA . 35  Bj 35  
-Q ?   17 n VAL . 36  Bj 36  
-Q ?   17 n ALA . 37  Bj 37  
-Q ?   17 n PRO . 38  Bj 38  
-Q ?   17 n SER . 39  Bj 39  
-Q ?   17 n SER . 40  Bj 40  
-Q ?   17 n SER . 41  Bj 41  
-Q ?   17 n SER . 42  Bj 42  
-Q 43  17 n SER . 43  Bj 43  
-Q 44  17 n PRO . 44  Bj 44  
-Q 45  17 n TRP . 45  Bj 45  
-Q 46  17 n ARG . 46  Bj 46  
-Q 47  17 n LEU . 47  Bj 47  
-Q 48  17 n LEU . 48  Bj 48  
-Q 49  17 n GLY . 49  Bj 49  
-Q 50  17 n ALA . 50  Bj 50  
-Q 51  17 n LEU . 51  Bj 51  
-Q 52  17 n CYS . 52  Bj 52  
-Q 53  17 n LEU . 53  Bj 53  
-Q 54  17 n GLN . 54  Bj 54  
-Q 55  17 n ARG . 55  Bj 55  
-Q 56  17 n PRO . 56  Bj 56  
-Q 57  17 n PRO . 57  Bj 57  
-Q 58  17 n LEU . 58  Bj 58  
-Q 59  17 n VAL . 59  Bj 59  
-Q 60  17 n THR . 60  Bj 60  
-Q 61  17 n LYS . 61  Bj 61  
-Q 62  17 n PRO . 62  Bj 62  
-Q 63  17 n LEU . 63  Bj 63  
-Q 64  17 n THR . 64  Bj 64  
-Q 65  17 n PRO . 65  Bj 65  
-Q 66  17 n LEU . 66  Bj 66  
-Q 67  17 n GLN . 67  Bj 67  
-Q 68  17 n GLU . 68  Bj 68  
-Q 69  17 n GLU . 69  Bj 69  
-Q 70  17 n MET . 70  Bj 70  
-Q 71  17 n ALA . 71  Bj 71  
-Q 72  17 n ASP . 72  Bj 72  
-Q 73  17 n LEU . 73  Bj 73  
-Q 74  17 n LEU . 74  Bj 74  
-Q 75  17 n GLN . 75  Bj 75  
-Q 76  17 n GLN . 76  Bj 76  
-Q 77  17 n ILE . 77  Bj 77  
-Q 78  17 n GLU . 78  Bj 78  
-Q 79  17 n ILE . 79  Bj 79  
-Q 80  17 n GLU . 80  Bj 80  
-Q 81  17 n ARG . 81  Bj 81  
-Q 82  17 n SER . 82  Bj 82  
-Q 83  17 n LEU . 83  Bj 83  
-Q 84  17 n TYR . 84  Bj 84  
-Q 85  17 n SER . 85  Bj 85  
-Q 86  17 n ASP . 86  Bj 86  
-Q 87  17 n HIS . 87  Bj 87  
-Q 88  17 n GLU . 88  Bj 88  
-Q 89  17 n LEU . 89  Bj 89  
-Q 90  17 n ARG . 90  Bj 90  
-Q 91  17 n ALA . 91  Bj 91  
-Q 92  17 n LEU . 92  Bj 92  
-Q 93  17 n ASP . 93  Bj 93  
-Q 94  17 n GLU . 94  Bj 94  
-Q 95  17 n ALA . 95  Bj 95  
-Q 96  17 n GLN . 96  Bj 96  
-Q 97  17 n GLN . 97  Bj 97  
-Q 98  17 n LEU . 98  Bj 98  
-Q 99  17 n ALA . 99  Bj 99  
-Q 100 17 n LYS . 100 Bj 100 
-Q 101 17 n LYS . 101 Bj 101 
-Q 102 17 n LYS . 102 Bj 102 
-Q 103 17 n SER . 103 Bj 103 
-Q 104 17 n ASP . 104 Bj 104 
-Q ?   17 n LEU . 105 Bj 105 
-Q ?   17 n TYR . 106 Bj 106 
-Q ?   17 n GLU . 107 Bj 107 
-Q ?   17 n GLU . 108 Bj 108 
-Q ?   17 n GLU . 109 Bj 109 
-Q ?   17 n ASP . 110 Bj 110 
-Q ?   17 n GLU . 111 Bj 111 
-Q ?   17 n GLN . 112 Bj 112 
-Q ?   17 n ASN . 113 Bj 113 
-Q ?   17 n ILE . 114 Bj 114 
-Q ?   17 n LEU . 115 Bj 115 
-Q 116 17 n LEU . 116 Bj 116 
-Q 117 17 n ALA . 117 Bj 117 
-Q 118 17 n GLN . 118 Bj 118 
-Q 119 17 n ASP . 119 Bj 119 
-Q 120 17 n LEU . 120 Bj 120 
-Q 121 17 n GLU . 121 Bj 121 
-Q 122 17 n ASP . 122 Bj 122 
-Q 123 17 n MET . 123 Bj 123 
-Q 124 17 n TRP . 124 Bj 124 
-Q 125 17 n GLU . 125 Bj 125 
-Q 126 17 n GLN . 126 Bj 126 
-Q 127 17 n LYS . 127 Bj 127 
-Q 128 17 n PHE . 128 Bj 128 
-Q 129 17 n LEU . 129 Bj 129 
-Q 130 17 n HIS . 130 Bj 130 
-Q 131 17 n PHE . 131 Bj 131 
-Q 132 17 n LYS . 132 Bj 132 
-Q 133 17 n LEU . 133 Bj 133 
-Q 134 17 n GLY . 134 Bj 134 
-Q 135 17 n ALA . 135 Bj 135 
-Q 136 17 n ARG . 136 Bj 136 
-Q 137 17 n LEU . 137 Bj 137 
-Q 138 17 n THR . 138 Bj 138 
-Q 139 17 n GLU . 139 Bj 139 
-Q 140 17 n ALA . 140 Bj 140 
-Q 141 17 n ASP . 141 Bj 141 
-Q 142 17 n LYS . 142 Bj 142 
-Q 143 17 n LYS . 143 Bj 143 
-Q 144 17 n ASP . 144 Bj 144 
-Q 145 17 n ASP . 145 Bj 145 
-Q 146 17 n ARG . 146 Bj 146 
-Q 147 17 n THR . 147 Bj 147 
-Q 148 17 n SER . 148 Bj 148 
-Q 149 17 n LEU . 149 Bj 149 
-Q 150 17 n HIS . 150 Bj 150 
-Q 151 17 n ARG . 151 Bj 151 
-Q 152 17 n LYS . 152 Bj 152 
-Q 153 17 n LEU . 153 Bj 153 
-Q 154 17 n ASP . 154 Bj 154 
-Q 155 17 n ARG . 155 Bj 155 
-Q 156 17 n ASN . 156 Bj 156 
-Q 157 17 n LEU . 157 Bj 157 
-Q 158 17 n ILE . 158 Bj 158 
-Q 159 17 n LEU . 159 Bj 159 
-Q 160 17 n LEU . 160 Bj 160 
-Q 161 17 n VAL . 161 Bj 161 
-Q 162 17 n ARG . 162 Bj 162 
-Q 163 17 n GLU . 163 Bj 163 
-Q 164 17 n LYS . 164 Bj 164 
-Q 165 17 n LEU . 165 Bj 165 
-Q 166 17 n GLY . 166 Bj 166 
-Q 167 17 n ASP . 167 Bj 167 
-Q 168 17 n GLN . 168 Bj 168 
-Q 169 17 n ASP . 169 Bj 169 
-Q 170 17 n ILE . 170 Bj 170 
-Q 171 17 n TRP . 171 Bj 171 
-Q 172 17 n MET . 172 Bj 172 
-Q 173 17 n LEU . 173 Bj 173 
-Q 174 17 n PRO . 174 Bj 174 
-Q 175 17 n GLN . 175 Bj 175 
-Q 176 17 n SER . 176 Bj 176 
-Q 177 17 n ASP . 177 Bj 177 
-Q 178 17 n TRP . 178 Bj 178 
-Q 179 17 n GLN . 179 Bj 179 
-Q 180 17 n PRO . 180 Bj 180 
-Q 181 17 n GLY . 181 Bj 181 
-Q 182 17 n GLU . 182 Bj 182 
-Q 183 17 n THR . 183 Bj 183 
-Q 184 17 n LEU . 184 Bj 184 
-Q 185 17 n ARG . 185 Bj 185 
-Q 186 17 n GLN . 186 Bj 186 
-Q 187 17 n THR . 187 Bj 187 
-Q 188 17 n ALA . 188 Bj 188 
-Q 189 17 n GLU . 189 Bj 189 
-Q 190 17 n ARG . 190 Bj 190 
-Q 191 17 n THR . 191 Bj 191 
-Q 192 17 n LEU . 192 Bj 192 
-Q 193 17 n ALA . 193 Bj 193 
-Q 194 17 n THR . 194 Bj 194 
-Q 195 17 n LEU . 195 Bj 195 
-Q 196 17 n SER . 196 Bj 196 
-Q 197 17 n GLU . 197 Bj 197 
-Q 198 17 n ASN . 198 Bj 198 
-Q 199 17 n ASN . 199 Bj 199 
-Q 200 17 n MET . 200 Bj 200 
-Q 201 17 n GLU . 201 Bj 201 
-Q 202 17 n ALA . 202 Bj 202 
-Q 203 17 n LYS . 203 Bj 203 
-Q 204 17 n PHE . 204 Bj 204 
-Q 205 17 n LEU . 205 Bj 205 
-Q 206 17 n GLY . 206 Bj 206 
-Q 207 17 n ASN . 207 Bj 207 
-Q 208 17 n ALA . 208 Bj 208 
-Q 209 17 n PRO . 209 Bj 209 
-Q 210 17 n CYS . 210 Bj 210 
-Q 211 17 n GLY . 211 Bj 211 
-Q 212 17 n HIS . 212 Bj 212 
-Q 213 17 n TYR . 213 Bj 213 
-Q 214 17 n LYS . 214 Bj 214 
-Q 215 17 n PHE . 215 Bj 215 
-Q 216 17 n LYS . 216 Bj 216 
-Q 217 17 n PHE . 217 Bj 217 
-Q ?   17 n PRO . 218 Bj 218 
-Q ?   17 n GLN . 219 Bj 219 
-Q ?   17 n ALA . 220 Bj 220 
-Q ?   17 n MET . 221 Bj 221 
-Q ?   17 n ARG . 222 Bj 222 
-Q ?   17 n THR . 223 Bj 223 
-Q ?   17 n GLU . 224 Bj 224 
-Q ?   17 n THR . 225 Bj 225 
-Q ?   17 n SER . 226 Bj 226 
-Q 227 17 n LEU . 227 Bj 227 
-Q 228 17 n GLY . 228 Bj 228 
-Q 229 17 n ALA . 229 Bj 229 
-Q 230 17 n LYS . 230 Bj 230 
-Q 231 17 n VAL . 231 Bj 231 
-Q 232 17 n PHE . 232 Bj 232 
-Q 233 17 n PHE . 233 Bj 233 
-Q 234 17 n PHE . 234 Bj 234 
-Q 235 17 n LYS . 235 Bj 235 
-Q 236 17 n ALA . 236 Bj 236 
-Q 237 17 n LEU . 237 Bj 237 
-Q 238 17 n LEU . 238 Bj 238 
-Q 239 17 n LEU . 239 Bj 239 
-Q 240 17 n THR . 240 Bj 240 
-Q 241 17 n GLY . 241 Bj 241 
-Q 242 17 n ASP . 242 Bj 242 
-Q 243 17 n PHE . 243 Bj 243 
-Q 244 17 n SER . 244 Bj 244 
-Q 245 17 n GLN . 245 Bj 245 
-Q 246 17 n ALA . 246 Bj 246 
-Q 247 17 n GLY . 247 Bj 247 
-Q 248 17 n LYS . 248 Bj 248 
-Q 249 17 n LYS . 249 Bj 249 
-Q 250 17 n GLY . 250 Bj 250 
-Q 251 17 n HIS . 251 Bj 251 
-Q 252 17 n HIS . 252 Bj 252 
-Q 253 17 n VAL . 253 Bj 253 
-Q 254 17 n TRP . 254 Bj 254 
-Q 255 17 n VAL . 255 Bj 255 
-Q 256 17 n SER . 256 Bj 256 
-Q 257 17 n LYS . 257 Bj 257 
-Q 258 17 n GLU . 258 Bj 258 
-Q 259 17 n GLU . 259 Bj 259 
-Q 260 17 n LEU . 260 Bj 260 
-Q 261 17 n GLY . 261 Bj 261 
-Q 262 17 n ASP . 262 Bj 262 
-Q 263 17 n TYR . 263 Bj 263 
-Q 264 17 n LEU . 264 Bj 264 
-Q 265 17 n LYS . 265 Bj 265 
-Q 266 17 n PRO . 266 Bj 266 
-Q 267 17 n LYS . 267 Bj 267 
-Q 268 17 n TYR . 268 Bj 268 
-Q 269 17 n LEU . 269 Bj 269 
-Q 270 17 n ALA . 270 Bj 270 
-Q 271 17 n GLN . 271 Bj 271 
-Q 272 17 n VAL . 272 Bj 272 
-Q 273 17 n ARG . 273 Bj 273 
-Q 274 17 n ARG . 274 Bj 274 
-Q 275 17 n PHE . 275 Bj 275 
-Q 276 17 n LEU . 276 Bj 276 
-Q 277 17 n LEU . 277 Bj 277 
-Q 278 17 n ASP . 278 Bj 278 
-Q 279 17 n LEU . 279 Bj 279 
-#
-_pdbx_struct_assembly.details            author_defined_assembly
-_pdbx_struct_assembly.id                 1
-_pdbx_struct_assembly.method_details     ?
-_pdbx_struct_assembly.oligomeric_count   95
-_pdbx_struct_assembly.oligomeric_details 95-meric
-#
-_pdbx_struct_assembly_gen.assembly_id     1
-_pdbx_struct_assembly_gen.asym_id_list    A,B,C,D,E,F,G,H,I,J,K,L,M,N,O,P,Q,R,S,T,U,V,W,X,Y,Z,AA,BA,CA,DA,EA,FA,GA,HA,IA,JA,KA,LA,MA,NA,OA,PA,QA,RA,SA,TA,UA,VA,WA,XA,YA,ZA,AB,BB,CB,DB,EB,FB,GB,HB,IB,JB,KB,LB,MB,NB,OB,PB,QB,RB,SB,TB,UB,VB,WB,XB,YB,ZB,AC,BC,CC,DC,EC,FC,GC,HC,IC,JC,KC,LC,MC,NC,OC,PC,QC,RC,SC,TC,UC,VC,WC,XC,YC,ZC,AD,BD,CD,DD,ED,FD,GD,HD,ID,JD,KD,LD,MD,ND,OD,PD,QD,RD,SD,TD,UD,VD,WD,XD,YD,ZD,AE,BE,CE,DE,EE,FE,GE,HE,IE,JE,KE,LE,ME,NE,OE,PE,QE,RE,SE,TE,UE,VE,WE,XE,YE,ZE,AF,BF,CF,DF,EF,FF,GF,HF,IF,JF,KF,LF,MF,NF,OF,PF,QF,RF,SF,TF,UF,VF,WF,XF,YF,ZF,AG,BG,CG,DG,EG,FG,GG,HG,IG,JG,KG,LG,MG,NG,OG,PG,QG,RG,SG,TG,UG,VG,WG,XG,YG,ZG,AH,BH,CH,DH,EH,FH,GH,HH,IH,JH,KH,LH,MH,NH,OH,PH,QH,RH,SH,TH,UH,VH,WH,XH,YH,ZH,AI,BI,CI,DI,EI,FI,GI,HI,II,JI,KI,LI,MI,NI,OI,PI,QI,RI,SI,TI,UI,VI,WI,XI,YI,ZI,AJ,BJ,CJ,DJ,EJ,FJ,GJ,HJ,IJ,JJ,KJ,LJ,MJ,NJ,OJ,PJ,QJ,RJ,SJ,TJ,UJ,VJ,WJ,XJ,YJ,ZJ,AK,BK,CK,DK,EK,FK,GK,HK,IK,JK,KK,LK,MK,NK,OK,PK,QK,RK,SK,TK,UK,VK,WK,XK,YK,ZK,AL,BL,CL,DL,EL,FL,GL,HL,IL,JL,KL,LL,ML,NL,OL,PL,QL,RL,SL,TL,UL,VL,WL,XL,YL,ZL,AM,BM,CM,DM,EM,FM,GM,HM,IM,JM,KM,LM,MM,NM,OM,PM,QM,RM,SM,TM,UM,VM,WM,XM,YM,ZM,AN,BN,CN,DN,EN,FN,GN,HN,IN,JN,KN,LN,MN,NN,ON,PN,QN,RN,SN,TN,UN,VN,WN,XN,YN,ZN,AO,BO,CO,DO,EO,FO,GO,HO,IO,JO,KO,LO,MO,NO,OO,PO,QO,RO,SO,TO,UO,VO,WO,XO,YO,ZO,AP,BP,CP,DP,EP,FP,GP,HP,IP,JP,KP,LP,MP,NP,OP,PP,QP,RP,SP
-_pdbx_struct_assembly_gen.oper_expression 1
-#
-_pdbx_struct_oper_list.id                 1
-_pdbx_struct_oper_list.matrix[1][1]       1.0000000000
-_pdbx_struct_oper_list.matrix[1][2]       0.0000000000
-_pdbx_struct_oper_list.matrix[1][3]       0.0000000000
-_pdbx_struct_oper_list.matrix[2][1]       0.0000000000
-_pdbx_struct_oper_list.matrix[2][2]       1.0000000000
-_pdbx_struct_oper_list.matrix[2][3]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][1]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][2]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][3]       1.0000000000
-_pdbx_struct_oper_list.name               1_555
-_pdbx_struct_oper_list.symmetry_operation ?
-_pdbx_struct_oper_list.type               "identity operation"
-_pdbx_struct_oper_list.vector[1]          0.0000000000
-_pdbx_struct_oper_list.vector[2]          0.0000000000
-_pdbx_struct_oper_list.vector[3]          0.0000000000
-#
-_refine.ls_d_res_high 4.20
-#
-_software.classification other
-_software.name           "DeepMind Structure Class"
-_software.pdbx_ordinal   1
-_software.version        2.0.0
-#
-_struct_asym.entity_id 17
-_struct_asym.id        Q
-#
-loop_
-_atom_site.group_PDB
-_atom_site.id
-_atom_site.type_symbol
-_atom_site.label_atom_id
-_atom_site.label_alt_id
-_atom_site.label_comp_id
-_atom_site.label_asym_id
-_atom_site.label_entity_id
-_atom_site.label_seq_id
-_atom_site.pdbx_PDB_ins_code
-_atom_site.Cartn_x
-_atom_site.Cartn_y
-_atom_site.Cartn_z
-_atom_site.occupancy
-_atom_site.B_iso_or_equiv
-_atom_site.auth_seq_id
-_atom_site.auth_asym_id
-_atom_site.pdbx_PDB_model_num
-ATOM 1    N N   . SER Q 17 43  ? 162.672 264.147 303.911 1.00 104.46 43  Bj 1 
-ATOM 2    C CA  . SER Q 17 43  ? 161.478 264.930 303.620 1.00 104.46 43  Bj 1 
-ATOM 3    C C   . SER Q 17 43  ? 160.551 264.181 302.669 1.00 104.46 43  Bj 1 
-ATOM 4    O O   . SER Q 17 43  ? 160.970 263.766 301.589 1.00 104.46 43  Bj 1 
-ATOM 5    C CB  . SER Q 17 43  ? 161.857 266.287 303.024 1.00 104.46 43  Bj 1 
-ATOM 6    O OG  . SER Q 17 43  ? 162.640 267.043 303.931 1.00 104.46 43  Bj 1 
-ATOM 7    N N   . PRO Q 17 44  ? 159.295 264.000 303.074 1.00 115.21 44  Bj 1 
-ATOM 8    C CA  . PRO Q 17 44  ? 158.333 263.328 302.193 1.00 115.21 44  Bj 1 
-ATOM 9    C C   . PRO Q 17 44  ? 157.997 264.188 300.984 1.00 115.21 44  Bj 1 
-ATOM 10   O O   . PRO Q 17 44  ? 157.754 265.392 301.099 1.00 115.21 44  Bj 1 
-ATOM 11   C CB  . PRO Q 17 44  ? 157.110 263.118 303.093 1.00 115.21 44  Bj 1 
-ATOM 12   C CG  . PRO Q 17 44  ? 157.236 264.161 304.150 1.00 115.21 44  Bj 1 
-ATOM 13   C CD  . PRO Q 17 44  ? 158.707 264.346 304.379 1.00 115.21 44  Bj 1 
-ATOM 14   N N   . TRP Q 17 45  ? 157.996 263.551 299.814 1.00 124.11 45  Bj 1 
-ATOM 15   C CA  . TRP Q 17 45  ? 157.732 264.221 298.549 1.00 124.11 45  Bj 1 
-ATOM 16   C C   . TRP Q 17 45  ? 156.706 263.430 297.755 1.00 124.11 45  Bj 1 
-ATOM 17   O O   . TRP Q 17 45  ? 156.918 262.249 297.460 1.00 124.11 45  Bj 1 
-ATOM 18   C CB  . TRP Q 17 45  ? 159.014 264.384 297.726 1.00 124.11 45  Bj 1 
-ATOM 19   C CG  . TRP Q 17 45  ? 159.872 265.522 298.174 1.00 124.11 45  Bj 1 
-ATOM 20   C CD1 . TRP Q 17 45  ? 160.962 265.456 298.990 1.00 124.11 45  Bj 1 
-ATOM 21   C CD2 . TRP Q 17 45  ? 159.709 266.903 297.831 1.00 124.11 45  Bj 1 
-ATOM 22   N NE1 . TRP Q 17 45  ? 161.490 266.710 299.176 1.00 124.11 45  Bj 1 
-ATOM 23   C CE2 . TRP Q 17 45  ? 160.738 267.616 298.475 1.00 124.11 45  Bj 1 
-ATOM 24   C CE3 . TRP Q 17 45  ? 158.793 267.605 297.042 1.00 124.11 45  Bj 1 
-ATOM 25   C CZ2 . TRP Q 17 45  ? 160.877 268.997 298.355 1.00 124.11 45  Bj 1 
-ATOM 26   C CZ3 . TRP Q 17 45  ? 158.932 268.975 296.925 1.00 124.11 45  Bj 1 
-ATOM 27   C CH2 . TRP Q 17 45  ? 159.966 269.656 297.577 1.00 124.11 45  Bj 1 
-ATOM 28   N N   . ARG Q 17 46  ? 155.602 264.083 297.413 1.00 135.34 46  Bj 1 
-ATOM 29   C CA  . ARG Q 17 46  ? 154.591 263.520 296.531 1.00 135.34 46  Bj 1 
-ATOM 30   C C   . ARG Q 17 46  ? 154.887 263.943 295.098 1.00 135.34 46  Bj 1 
-ATOM 31   O O   . ARG Q 17 46  ? 155.343 265.063 294.855 1.00 135.34 46  Bj 1 
-ATOM 32   C CB  . ARG Q 17 46  ? 153.191 263.983 296.943 1.00 135.34 46  Bj 1 
-ATOM 33   C CG  . ARG Q 17 46  ? 152.052 263.259 296.243 1.00 135.34 46  Bj 1 
-ATOM 34   C CD  . ARG Q 17 46  ? 150.703 263.776 296.723 1.00 135.34 46  Bj 1 
-ATOM 35   N NE  . ARG Q 17 46  ? 149.585 263.097 296.074 1.00 135.34 46  Bj 1 
-ATOM 36   C CZ  . ARG Q 17 46  ? 148.306 263.372 296.309 1.00 135.34 46  Bj 1 
-ATOM 37   N NH1 . ARG Q 17 46  ? 147.977 264.316 297.180 1.00 135.34 46  Bj 1 
-ATOM 38   N NH2 . ARG Q 17 46  ? 147.353 262.704 295.673 1.00 135.34 46  Bj 1 
-ATOM 39   N N   . LEU Q 17 47  ? 154.641 263.040 294.152 1.00 137.26 47  Bj 1 
-ATOM 40   C CA  . LEU Q 17 47  ? 154.910 263.296 292.743 1.00 137.26 47  Bj 1 
-ATOM 41   C C   . LEU Q 17 47  ? 153.644 263.057 291.937 1.00 137.26 47  Bj 1 
-ATOM 42   O O   . LEU Q 17 47  ? 152.955 262.053 292.143 1.00 137.26 47  Bj 1 
-ATOM 43   C CB  . LEU Q 17 47  ? 156.056 262.414 292.233 1.00 137.26 47  Bj 1 
-ATOM 44   C CG  . LEU Q 17 47  ? 156.329 261.107 292.986 1.00 137.26 47  Bj 1 
-ATOM 45   C CD1 . LEU Q 17 47  ? 155.350 260.012 292.587 1.00 137.26 47  Bj 1 
-ATOM 46   C CD2 . LEU Q 17 47  ? 157.766 260.652 292.776 1.00 137.26 47  Bj 1 
-ATOM 47   N N   . LEU Q 17 48  ? 153.331 263.982 291.030 1.00 138.18 48  Bj 1 
-ATOM 48   C CA  . LEU Q 17 48  ? 152.120 263.883 290.230 1.00 138.18 48  Bj 1 
-ATOM 49   C C   . LEU Q 17 48  ? 152.394 264.339 288.806 1.00 138.18 48  Bj 1 
-ATOM 50   O O   . LEU Q 17 48  ? 153.199 265.246 288.575 1.00 138.18 48  Bj 1 
-ATOM 51   C CB  . LEU Q 17 48  ? 150.977 264.725 290.818 1.00 138.18 48  Bj 1 
-ATOM 52   C CG  . LEU Q 17 48  ? 150.485 264.427 292.237 1.00 138.18 48  Bj 1 
-ATOM 53   C CD1 . LEU Q 17 48  ? 151.283 265.210 293.269 1.00 138.18 48  Bj 1 
-ATOM 54   C CD2 . LEU Q 17 48  ? 149.000 264.730 292.359 1.00 138.18 48  Bj 1 
-ATOM 55   N N   . GLY Q 17 49  ? 151.716 263.701 287.855 1.00 135.43 49  Bj 1 
-ATOM 56   C CA  . GLY Q 17 49  ? 151.707 264.149 286.482 1.00 135.43 49  Bj 1 
-ATOM 57   C C   . GLY Q 17 49  ? 150.384 264.812 286.131 1.00 135.43 49  Bj 1 
-ATOM 58   O O   . GLY Q 17 49  ? 149.360 264.601 286.775 1.00 135.43 49  Bj 1 
-ATOM 59   N N   . ALA Q 17 50  ? 150.428 265.639 285.090 1.00 130.02 50  Bj 1 
-ATOM 60   C CA  . ALA Q 17 50  ? 149.244 266.346 284.629 1.00 130.02 50  Bj 1 
-ATOM 61   C C   . ALA Q 17 50  ? 149.304 266.468 283.116 1.00 130.02 50  Bj 1 
-ATOM 62   O O   . ALA Q 17 50  ? 150.384 266.588 282.529 1.00 130.02 50  Bj 1 
-ATOM 63   C CB  . ALA Q 17 50  ? 149.121 267.730 285.275 1.00 130.02 50  Bj 1 
-ATOM 64   N N   . LEU Q 17 51  ? 148.131 266.439 282.491 1.00 127.85 51  Bj 1 
-ATOM 65   C CA  . LEU Q 17 51  ? 148.013 266.429 281.039 1.00 127.85 51  Bj 1 
-ATOM 66   C C   . LEU Q 17 51  ? 147.458 267.759 280.549 1.00 127.85 51  Bj 1 
-ATOM 67   O O   . LEU Q 17 51  ? 146.498 268.285 281.121 1.00 127.85 51  Bj 1 
-ATOM 68   C CB  . LEU Q 17 51  ? 147.117 265.280 280.572 1.00 127.85 51  Bj 1 
-ATOM 69   C CG  . LEU Q 17 51  ? 146.876 265.173 279.065 1.00 127.85 51  Bj 1 
-ATOM 70   C CD1 . LEU Q 17 51  ? 148.194 265.030 278.321 1.00 127.85 51  Bj 1 
-ATOM 71   C CD2 . LEU Q 17 51  ? 145.949 264.010 278.748 1.00 127.85 51  Bj 1 
-ATOM 72   N N   . CYS Q 17 52  ? 148.064 268.295 279.492 1.00 126.27 52  Bj 1 
-ATOM 73   C CA  . CYS Q 17 52  ? 147.580 269.488 278.806 1.00 126.27 52  Bj 1 
-ATOM 74   C C   . CYS Q 17 52  ? 147.282 269.077 277.369 1.00 126.27 52  Bj 1 
-ATOM 75   O O   . CYS Q 17 52  ? 148.176 269.073 276.517 1.00 126.27 52  Bj 1 
-ATOM 76   C CB  . CYS Q 17 52  ? 148.607 270.615 278.866 1.00 126.27 52  Bj 1 
-ATOM 77   S SG  . CYS Q 17 52  ? 149.201 271.004 280.527 1.00 126.27 52  Bj 1 
-ATOM 78   N N   . LEU Q 17 53  ? 146.033 268.707 277.107 1.00 117.88 53  Bj 1 
-ATOM 79   C CA  . LEU Q 17 53  ? 145.621 268.248 275.787 1.00 117.88 53  Bj 1 
-ATOM 80   C C   . LEU Q 17 53  ? 145.134 269.436 274.969 1.00 117.88 53  Bj 1 
-ATOM 81   O O   . LEU Q 17 53  ? 144.159 270.096 275.343 1.00 117.88 53  Bj 1 
-ATOM 82   C CB  . LEU Q 17 53  ? 144.526 267.191 275.898 1.00 117.88 53  Bj 1 
-ATOM 83   C CG  . LEU Q 17 53  ? 143.910 266.774 274.563 1.00 117.88 53  Bj 1 
-ATOM 84   C CD1 . LEU Q 17 53  ? 144.958 266.142 273.659 1.00 117.88 53  Bj 1 
-ATOM 85   C CD2 . LEU Q 17 53  ? 142.749 265.828 274.792 1.00 117.88 53  Bj 1 
-ATOM 86   N N   . GLN Q 17 54  ? 145.803 269.698 273.851 1.00 118.52 54  Bj 1 
-ATOM 87   C CA  . GLN Q 17 54  ? 145.488 270.830 272.992 1.00 118.52 54  Bj 1 
-ATOM 88   C C   . GLN Q 17 54  ? 144.817 270.326 271.723 1.00 118.52 54  Bj 1 
-ATOM 89   O O   . GLN Q 17 54  ? 145.391 269.510 270.993 1.00 118.52 54  Bj 1 
-ATOM 90   C CB  . GLN Q 17 54  ? 146.748 271.626 272.652 1.00 118.52 54  Bj 1 
-ATOM 91   C CG  . GLN Q 17 54  ? 147.464 272.202 273.860 1.00 118.52 54  Bj 1 
-ATOM 92   C CD  . GLN Q 17 54  ? 148.683 273.016 273.478 1.00 118.52 54  Bj 1 
-ATOM 93   O OE1 . GLN Q 17 54  ? 148.961 273.222 272.297 1.00 118.52 54  Bj 1 
-ATOM 94   N NE2 . GLN Q 17 54  ? 149.419 273.484 274.478 1.00 118.52 54  Bj 1 
-ATOM 95   N N   . ARG Q 17 55  ? 143.598 270.796 271.480 1.00 113.62 55  Bj 1 
-ATOM 96   C CA  . ARG Q 17 55  ? 142.952 270.625 270.189 1.00 113.62 55  Bj 1 
-ATOM 97   C C   . ARG Q 17 55  ? 143.238 271.852 269.337 1.00 113.62 55  Bj 1 
-ATOM 98   O O   . ARG Q 17 55  ? 142.879 272.968 269.740 1.00 113.62 55  Bj 1 
-ATOM 99   C CB  . ARG Q 17 55  ? 141.455 270.444 270.349 1.00 113.62 55  Bj 1 
-ATOM 100  C CG  . ARG Q 17 55  ? 140.733 270.185 269.037 1.00 113.62 55  Bj 1 
-ATOM 101  C CD  . ARG Q 17 55  ? 139.290 270.650 269.102 1.00 113.62 55  Bj 1 
-ATOM 102  N NE  . ARG Q 17 55  ? 139.013 271.693 268.119 1.00 113.62 55  Bj 1 
-ATOM 103  C CZ  . ARG Q 17 55  ? 139.321 272.974 268.284 1.00 113.62 55  Bj 1 
-ATOM 104  N NH1 . ARG Q 17 55  ? 139.923 273.375 269.395 1.00 113.62 55  Bj 1 
-ATOM 105  N NH2 . ARG Q 17 55  ? 139.032 273.855 267.337 1.00 113.62 55  Bj 1 
-ATOM 106  N N   . PRO Q 17 56  ? 143.874 271.703 268.180 1.00 114.98 56  Bj 1 
-ATOM 107  C CA  . PRO Q 17 56  ? 144.258 272.868 267.384 1.00 114.98 56  Bj 1 
-ATOM 108  C C   . PRO Q 17 56  ? 143.057 273.471 266.683 1.00 114.98 56  Bj 1 
-ATOM 109  O O   . PRO Q 17 56  ? 142.018 272.811 266.528 1.00 114.98 56  Bj 1 
-ATOM 110  C CB  . PRO Q 17 56  ? 145.255 272.283 266.375 1.00 114.98 56  Bj 1 
-ATOM 111  C CG  . PRO Q 17 56  ? 144.800 270.875 266.201 1.00 114.98 56  Bj 1 
-ATOM 112  C CD  . PRO Q 17 56  ? 144.288 270.438 267.549 1.00 114.98 56  Bj 1 
-ATOM 113  N N   . PRO Q 17 57  ? 143.156 274.726 266.247 1.00 116.15 57  Bj 1 
-ATOM 114  C CA  . PRO Q 17 57  ? 142.053 275.331 265.494 1.00 116.15 57  Bj 1 
-ATOM 115  C C   . PRO Q 17 57  ? 141.864 274.658 264.144 1.00 116.15 57  Bj 1 
-ATOM 116  O O   . PRO Q 17 57  ? 142.830 274.337 263.446 1.00 116.15 57  Bj 1 
-ATOM 117  C CB  . PRO Q 17 57  ? 142.492 276.791 265.334 1.00 116.15 57  Bj 1 
-ATOM 118  C CG  . PRO Q 17 57  ? 143.977 276.762 265.492 1.00 116.15 57  Bj 1 
-ATOM 119  C CD  . PRO Q 17 57  ? 144.251 275.681 266.490 1.00 116.15 57  Bj 1 
-ATOM 120  N N   . LEU Q 17 58  ? 140.600 274.449 263.778 1.00 116.27 58  Bj 1 
-ATOM 121  C CA  . LEU Q 17 58  ? 140.270 273.823 262.504 1.00 116.27 58  Bj 1 
-ATOM 122  C C   . LEU Q 17 58  ? 140.215 274.830 261.361 1.00 116.27 58  Bj 1 
-ATOM 123  O O   . LEU Q 17 58  ? 140.604 274.507 260.234 1.00 116.27 58  Bj 1 
-ATOM 124  C CB  . LEU Q 17 58  ? 138.934 273.084 262.609 1.00 116.27 58  Bj 1 
-ATOM 125  C CG  . LEU Q 17 58  ? 138.884 271.888 263.562 1.00 116.27 58  Bj 1 
-ATOM 126  C CD1 . LEU Q 17 58  ? 137.503 271.254 263.554 1.00 116.27 58  Bj 1 
-ATOM 127  C CD2 . LEU Q 17 58  ? 139.946 270.864 263.194 1.00 116.27 58  Bj 1 
-ATOM 128  N N   . VAL Q 17 59  ? 139.743 276.044 261.628 1.00 110.63 59  Bj 1 
-ATOM 129  C CA  . VAL Q 17 59  ? 139.613 277.074 260.606 1.00 110.63 59  Bj 1 
-ATOM 130  C C   . VAL Q 17 59  ? 140.674 278.138 260.846 1.00 110.63 59  Bj 1 
-ATOM 131  O O   . VAL Q 17 59  ? 141.190 278.295 261.959 1.00 110.63 59  Bj 1 
-ATOM 132  C CB  . VAL Q 17 59  ? 138.197 277.692 260.596 1.00 110.63 59  Bj 1 
-ATOM 133  C CG1 . VAL Q 17 59  ? 138.060 278.749 261.681 1.00 110.63 59  Bj 1 
-ATOM 134  C CG2 . VAL Q 17 59  ? 137.873 278.271 259.228 1.00 110.63 59  Bj 1 
-ATOM 135  N N   . THR Q 17 60  ? 141.010 278.864 259.784 1.00 105.54 60  Bj 1 
-ATOM 136  C CA  . THR Q 17 60  ? 142.011 279.914 259.869 1.00 105.54 60  Bj 1 
-ATOM 137  C C   . THR Q 17 60  ? 141.427 281.168 260.510 1.00 105.54 60  Bj 1 
-ATOM 138  O O   . THR Q 17 60  ? 140.245 281.483 260.349 1.00 105.54 60  Bj 1 
-ATOM 139  C CB  . THR Q 17 60  ? 142.562 280.246 258.481 1.00 105.54 60  Bj 1 
-ATOM 140  O OG1 . THR Q 17 60  ? 143.384 281.417 258.558 1.00 105.54 60  Bj 1 
-ATOM 141  C CG2 . THR Q 17 60  ? 141.426 280.489 257.498 1.00 105.54 60  Bj 1 
-ATOM 142  N N   . LYS Q 17 61  ? 142.275 281.882 261.244 1.00 98.53  61  Bj 1 
-ATOM 143  C CA  . LYS Q 17 61  ? 141.844 283.097 261.913 1.00 98.53  61  Bj 1 
-ATOM 144  C C   . LYS Q 17 61  ? 141.540 284.190 260.890 1.00 98.53  61  Bj 1 
-ATOM 145  O O   . LYS Q 17 61  ? 142.039 284.151 259.762 1.00 98.53  61  Bj 1 
-ATOM 146  C CB  . LYS Q 17 61  ? 142.918 283.578 262.886 1.00 98.53  61  Bj 1 
-ATOM 147  C CG  . LYS Q 17 61  ? 143.171 282.633 264.046 1.00 98.53  61  Bj 1 
-ATOM 148  C CD  . LYS Q 17 61  ? 144.091 283.258 265.081 1.00 98.53  61  Bj 1 
-ATOM 149  C CE  . LYS Q 17 61  ? 144.264 282.348 266.288 1.00 98.53  61  Bj 1 
-ATOM 150  N NZ  . LYS Q 17 61  ? 145.130 282.959 267.333 1.00 98.53  61  Bj 1 
-ATOM 151  N N   . PRO Q 17 62  ? 140.716 285.171 261.253 1.00 97.74  62  Bj 1 
-ATOM 152  C CA  . PRO Q 17 62  ? 140.458 286.288 260.340 1.00 97.74  62  Bj 1 
-ATOM 153  C C   . PRO Q 17 62  ? 141.703 287.136 260.133 1.00 97.74  62  Bj 1 
-ATOM 154  O O   . PRO Q 17 62  ? 142.668 287.080 260.898 1.00 97.74  62  Bj 1 
-ATOM 155  C CB  . PRO Q 17 62  ? 139.357 287.083 261.049 1.00 97.74  62  Bj 1 
-ATOM 156  C CG  . PRO Q 17 62  ? 139.506 286.725 262.488 1.00 97.74  62  Bj 1 
-ATOM 157  C CD  . PRO Q 17 62  ? 139.933 285.287 262.495 1.00 97.74  62  Bj 1 
-ATOM 158  N N   . LEU Q 17 63  ? 141.667 287.934 259.071 1.00 100.40 63  Bj 1 
-ATOM 159  C CA  . LEU Q 17 63  ? 142.797 288.761 258.672 1.00 100.40 63  Bj 1 
-ATOM 160  C C   . LEU Q 17 63  ? 142.618 290.179 259.198 1.00 100.40 63  Bj 1 
-ATOM 161  O O   . LEU Q 17 63  ? 141.553 290.781 259.027 1.00 100.40 63  Bj 1 
-ATOM 162  C CB  . LEU Q 17 63  ? 142.946 288.779 257.150 1.00 100.40 63  Bj 1 
-ATOM 163  C CG  . LEU Q 17 63  ? 143.056 287.411 256.475 1.00 100.40 63  Bj 1 
-ATOM 164  C CD1 . LEU Q 17 63  ? 143.238 287.556 254.972 1.00 100.40 63  Bj 1 
-ATOM 165  C CD2 . LEU Q 17 63  ? 144.195 286.614 257.080 1.00 100.40 63  Bj 1 
-ATOM 166  N N   . THR Q 17 64  ? 143.657 290.697 259.845 1.00 107.97 64  Bj 1 
-ATOM 167  C CA  . THR Q 17 64  ? 143.667 292.093 260.253 1.00 107.97 64  Bj 1 
-ATOM 168  C C   . THR Q 17 64  ? 143.516 292.982 259.019 1.00 107.97 64  Bj 1 
-ATOM 169  O O   . THR Q 17 64  ? 144.073 292.666 257.964 1.00 107.97 64  Bj 1 
-ATOM 170  C CB  . THR Q 17 64  ? 144.974 292.410 260.987 1.00 107.97 64  Bj 1 
-ATOM 171  O OG1 . THR Q 17 64  ? 145.120 291.524 262.105 1.00 107.97 64  Bj 1 
-ATOM 172  C CG2 . THR Q 17 64  ? 145.005 293.848 261.485 1.00 107.97 64  Bj 1 
-ATOM 173  N N   . PRO Q 17 65  ? 142.750 294.076 259.102 1.00 107.81 65  Bj 1 
-ATOM 174  C CA  . PRO Q 17 65  ? 142.603 294.962 257.932 1.00 107.81 65  Bj 1 
-ATOM 175  C C   . PRO Q 17 65  ? 143.921 295.427 257.333 1.00 107.81 65  Bj 1 
-ATOM 176  O O   . PRO Q 17 65  ? 144.005 295.621 256.112 1.00 107.81 65  Bj 1 
-ATOM 177  C CB  . PRO Q 17 65  ? 141.785 296.141 258.486 1.00 107.81 65  Bj 1 
-ATOM 178  C CG  . PRO Q 17 65  ? 141.775 295.966 259.988 1.00 107.81 65  Bj 1 
-ATOM 179  C CD  . PRO Q 17 65  ? 141.881 294.498 260.212 1.00 107.81 65  Bj 1 
-ATOM 180  N N   . LEU Q 17 66  ? 144.958 295.608 258.152 1.00 108.37 66  Bj 1 
-ATOM 181  C CA  . LEU Q 17 66  ? 146.280 295.907 257.613 1.00 108.37 66  Bj 1 
-ATOM 182  C C   . LEU Q 17 66  ? 146.764 294.776 256.714 1.00 108.37 66  Bj 1 
-ATOM 183  O O   . LEU Q 17 66  ? 147.264 295.010 255.605 1.00 108.37 66  Bj 1 
-ATOM 184  C CB  . LEU Q 17 66  ? 147.261 296.150 258.760 1.00 108.37 66  Bj 1 
-ATOM 185  C CG  . LEU Q 17 66  ? 148.674 296.601 258.394 1.00 108.37 66  Bj 1 
-ATOM 186  C CD1 . LEU Q 17 66  ? 148.637 297.948 257.693 1.00 108.37 66  Bj 1 
-ATOM 187  C CD2 . LEU Q 17 66  ? 149.550 296.661 259.635 1.00 108.37 66  Bj 1 
-ATOM 188  N N   . GLN Q 17 67  ? 146.602 293.533 257.172 1.00 108.81 67  Bj 1 
-ATOM 189  C CA  . GLN Q 17 67  ? 146.992 292.387 256.360 1.00 108.81 67  Bj 1 
-ATOM 190  C C   . GLN Q 17 67  ? 146.109 292.247 255.126 1.00 108.81 67  Bj 1 
-ATOM 191  O O   . GLN Q 17 67  ? 146.569 291.758 254.091 1.00 108.81 67  Bj 1 
-ATOM 192  C CB  . GLN Q 17 67  ? 146.951 291.114 257.204 1.00 108.81 67  Bj 1 
-ATOM 193  C CG  . GLN Q 17 67  ? 147.901 291.140 258.391 1.00 108.81 67  Bj 1 
-ATOM 194  C CD  . GLN Q 17 67  ? 148.113 289.770 259.002 1.00 108.81 67  Bj 1 
-ATOM 195  O OE1 . GLN Q 17 67  ? 147.728 288.754 258.424 1.00 108.81 67  Bj 1 
-ATOM 196  N NE2 . GLN Q 17 67  ? 148.730 289.735 260.177 1.00 108.81 67  Bj 1 
-ATOM 197  N N   . GLU Q 17 68  ? 144.851 292.683 255.209 1.00 110.89 68  Bj 1 
-ATOM 198  C CA  . GLU Q 17 68  ? 143.985 292.678 254.034 1.00 110.89 68  Bj 1 
-ATOM 199  C C   . GLU Q 17 68  ? 144.476 293.670 252.987 1.00 110.89 68  Bj 1 
-ATOM 200  O O   . GLU Q 17 68  ? 144.512 293.356 251.791 1.00 110.89 68  Bj 1 
-ATOM 201  C CB  . GLU Q 17 68  ? 142.545 292.997 254.438 1.00 110.89 68  Bj 1 
-ATOM 202  C CG  . GLU Q 17 68  ? 141.839 291.878 255.186 1.00 110.89 68  Bj 1 
-ATOM 203  C CD  . GLU Q 17 68  ? 141.367 290.766 254.268 1.00 110.89 68  Bj 1 
-ATOM 204  O OE1 . GLU Q 17 68  ? 141.481 290.917 253.034 1.00 110.89 68  Bj 1 
-ATOM 205  O OE2 . GLU Q 17 68  ? 140.877 289.740 254.783 1.00 110.89 68  Bj 1 
-ATOM 206  N N   . GLU Q 17 69  ? 144.845 294.877 253.421 1.00 119.08 69  Bj 1 
-ATOM 207  C CA  . GLU Q 17 69  ? 145.448 295.841 252.506 1.00 119.08 69  Bj 1 
-ATOM 208  C C   . GLU Q 17 69  ? 146.723 295.281 251.888 1.00 119.08 69  Bj 1 
-ATOM 209  O O   . GLU Q 17 69  ? 146.964 295.440 250.684 1.00 119.08 69  Bj 1 
-ATOM 210  C CB  . GLU Q 17 69  ? 145.744 297.150 253.237 1.00 119.08 69  Bj 1 
-ATOM 211  C CG  . GLU Q 17 69  ? 144.526 297.820 253.844 1.00 119.08 69  Bj 1 
-ATOM 212  C CD  . GLU Q 17 69  ? 144.878 299.094 254.586 1.00 119.08 69  Bj 1 
-ATOM 213  O OE1 . GLU Q 17 69  ? 146.016 299.584 254.422 1.00 119.08 69  Bj 1 
-ATOM 214  O OE2 . GLU Q 17 69  ? 144.018 299.605 255.334 1.00 119.08 69  Bj 1 
-ATOM 215  N N   . MET Q 17 70  ? 147.551 294.620 252.702 1.00 119.12 70  Bj 1 
-ATOM 216  C CA  . MET Q 17 70  ? 148.786 294.039 252.184 1.00 119.12 70  Bj 1 
-ATOM 217  C C   . MET Q 17 70  ? 148.499 292.952 251.153 1.00 119.12 70  Bj 1 
-ATOM 218  O O   . MET Q 17 70  ? 149.177 292.872 250.123 1.00 119.12 70  Bj 1 
-ATOM 219  C CB  . MET Q 17 70  ? 149.628 293.487 253.335 1.00 119.12 70  Bj 1 
-ATOM 220  C CG  . MET Q 17 70  ? 150.879 292.746 252.892 1.00 119.12 70  Bj 1 
-ATOM 221  S SD  . MET Q 17 70  ? 151.859 293.670 251.693 1.00 119.12 70  Bj 1 
-ATOM 222  C CE  . MET Q 17 70  ? 152.198 295.174 252.604 1.00 119.12 70  Bj 1 
-ATOM 223  N N   . ALA Q 17 71  ? 147.494 292.112 251.408 1.00 117.23 71  Bj 1 
-ATOM 224  C CA  . ALA Q 17 71  ? 147.151 291.056 250.461 1.00 117.23 71  Bj 1 
-ATOM 225  C C   . ALA Q 17 71  ? 146.601 291.635 249.164 1.00 117.23 71  Bj 1 
-ATOM 226  O O   . ALA Q 17 71  ? 146.901 291.130 248.075 1.00 117.23 71  Bj 1 
-ATOM 227  C CB  . ALA Q 17 71  ? 146.146 290.093 251.089 1.00 117.23 71  Bj 1 
-ATOM 228  N N   . ASP Q 17 72  ? 145.790 292.690 249.260 1.00 117.37 72  Bj 1 
-ATOM 229  C CA  . ASP Q 17 72  ? 145.300 293.360 248.060 1.00 117.37 72  Bj 1 
-ATOM 230  C C   . ASP Q 17 72  ? 146.459 293.920 247.245 1.00 117.37 72  Bj 1 
-ATOM 231  O O   . ASP Q 17 72  ? 146.511 293.759 246.020 1.00 117.37 72  Bj 1 
-ATOM 232  C CB  . ASP Q 17 72  ? 144.317 294.468 248.446 1.00 117.37 72  Bj 1 
-ATOM 233  C CG  . ASP Q 17 72  ? 143.468 294.941 247.276 1.00 117.37 72  Bj 1 
-ATOM 234  O OD1 . ASP Q 17 72  ? 143.969 294.974 246.132 1.00 117.37 72  Bj 1 
-ATOM 235  O OD2 . ASP Q 17 72  ? 142.289 295.283 247.504 1.00 117.37 72  Bj 1 
-ATOM 236  N N   . LEU Q 17 73  ? 147.405 294.580 247.919 1.00 119.96 73  Bj 1 
-ATOM 237  C CA  . LEU Q 17 73  ? 148.572 295.115 247.226 1.00 119.96 73  Bj 1 
-ATOM 238  C C   . LEU Q 17 73  ? 149.385 294.005 246.571 1.00 119.96 73  Bj 1 
-ATOM 239  O O   . LEU Q 17 73  ? 149.873 294.161 245.443 1.00 119.96 73  Bj 1 
-ATOM 240  C CB  . LEU Q 17 73  ? 149.436 295.910 248.205 1.00 119.96 73  Bj 1 
-ATOM 241  C CG  . LEU Q 17 73  ? 150.798 296.368 247.685 1.00 119.96 73  Bj 1 
-ATOM 242  C CD1 . LEU Q 17 73  ? 150.633 297.215 246.438 1.00 119.96 73  Bj 1 
-ATOM 243  C CD2 . LEU Q 17 73  ? 151.550 297.134 248.760 1.00 119.96 73  Bj 1 
-ATOM 244  N N   . LEU Q 17 74  ? 149.546 292.877 247.266 1.00 118.44 74  Bj 1 
-ATOM 245  C CA  . LEU Q 17 74  ? 150.309 291.766 246.709 1.00 118.44 74  Bj 1 
-ATOM 246  C C   . LEU Q 17 74  ? 149.627 291.192 245.476 1.00 118.44 74  Bj 1 
-ATOM 247  O O   . LEU Q 17 74  ? 150.288 290.911 244.472 1.00 118.44 74  Bj 1 
-ATOM 248  C CB  . LEU Q 17 74  ? 150.513 290.683 247.766 1.00 118.44 74  Bj 1 
-ATOM 249  C CG  . LEU Q 17 74  ? 151.495 291.024 248.888 1.00 118.44 74  Bj 1 
-ATOM 250  C CD1 . LEU Q 17 74  ? 151.535 289.909 249.915 1.00 118.44 74  Bj 1 
-ATOM 251  C CD2 . LEU Q 17 74  ? 152.883 291.289 248.326 1.00 118.44 74  Bj 1 
-ATOM 252  N N   . GLN Q 17 75  ? 148.305 291.017 245.529 1.00 121.57 75  Bj 1 
-ATOM 253  C CA  . GLN Q 17 75  ? 147.584 290.533 244.356 1.00 121.57 75  Bj 1 
-ATOM 254  C C   . GLN Q 17 75  ? 147.705 291.512 243.195 1.00 121.57 75  Bj 1 
-ATOM 255  O O   . GLN Q 17 75  ? 147.891 291.101 242.042 1.00 121.57 75  Bj 1 
-ATOM 256  C CB  . GLN Q 17 75  ? 146.116 290.286 244.704 1.00 121.57 75  Bj 1 
-ATOM 257  C CG  . GLN Q 17 75  ? 145.881 289.058 245.568 1.00 121.57 75  Bj 1 
-ATOM 258  C CD  . GLN Q 17 75  ? 146.176 287.763 244.836 1.00 121.57 75  Bj 1 
-ATOM 259  O OE1 . GLN Q 17 75  ? 146.161 287.713 243.606 1.00 121.57 75  Bj 1 
-ATOM 260  N NE2 . GLN Q 17 75  ? 146.449 286.705 245.592 1.00 121.57 75  Bj 1 
-ATOM 261  N N   . GLN Q 17 76  ? 147.617 292.813 243.483 1.00 121.41 76  Bj 1 
-ATOM 262  C CA  . GLN Q 17 76  ? 147.734 293.811 242.425 1.00 121.41 76  Bj 1 
-ATOM 263  C C   . GLN Q 17 76  ? 149.103 293.751 241.760 1.00 121.41 76  Bj 1 
-ATOM 264  O O   . GLN Q 17 76  ? 149.204 293.703 240.529 1.00 121.41 76  Bj 1 
-ATOM 265  C CB  . GLN Q 17 76  ? 147.468 295.209 242.984 1.00 121.41 76  Bj 1 
-ATOM 266  C CG  . GLN Q 17 76  ? 146.016 295.474 243.336 1.00 121.41 76  Bj 1 
-ATOM 267  C CD  . GLN Q 17 76  ? 145.782 296.899 243.795 1.00 121.41 76  Bj 1 
-ATOM 268  O OE1 . GLN Q 17 76  ? 146.644 297.764 243.637 1.00 121.41 76  Bj 1 
-ATOM 269  N NE2 . GLN Q 17 76  ? 144.612 297.151 244.370 1.00 121.41 76  Bj 1 
-ATOM 270  N N   . ILE Q 17 77  ? 150.173 293.743 242.560 1.00 121.50 77  Bj 1 
-ATOM 271  C CA  . ILE Q 17 77  ? 151.509 293.737 241.969 1.00 121.50 77  Bj 1 
-ATOM 272  C C   . ILE Q 17 77  ? 151.794 292.406 241.283 1.00 121.50 77  Bj 1 
-ATOM 273  O O   . ILE Q 17 77  ? 152.530 292.360 240.289 1.00 121.50 77  Bj 1 
-ATOM 274  C CB  . ILE Q 17 77  ? 152.579 294.076 243.026 1.00 121.50 77  Bj 1 
-ATOM 275  C CG1 . ILE Q 17 77  ? 152.598 293.031 244.141 1.00 121.50 77  Bj 1 
-ATOM 276  C CG2 . ILE Q 17 77  ? 152.341 295.466 243.594 1.00 121.50 77  Bj 1 
-ATOM 277  C CD1 . ILE Q 17 77  ? 153.596 293.329 245.239 1.00 121.50 77  Bj 1 
-ATOM 278  N N   . GLU Q 17 78  ? 151.203 291.311 241.770 1.00 127.63 78  Bj 1 
-ATOM 279  C CA  . GLU Q 17 78  ? 151.360 290.022 241.105 1.00 127.63 78  Bj 1 
-ATOM 280  C C   . GLU Q 17 78  ? 150.720 290.042 239.724 1.00 127.63 78  Bj 1 
-ATOM 281  O O   . GLU Q 17 78  ? 151.334 289.616 238.738 1.00 127.63 78  Bj 1 
-ATOM 282  C CB  . GLU Q 17 78  ? 150.751 288.916 241.968 1.00 127.63 78  Bj 1 
-ATOM 283  C CG  . GLU Q 17 78  ? 150.750 287.538 241.324 1.00 127.63 78  Bj 1 
-ATOM 284  C CD  . GLU Q 17 78  ? 149.964 286.520 242.129 1.00 127.63 78  Bj 1 
-ATOM 285  O OE1 . GLU Q 17 78  ? 149.341 286.910 243.139 1.00 127.63 78  Bj 1 
-ATOM 286  O OE2 . GLU Q 17 78  ? 149.967 285.329 241.753 1.00 127.63 78  Bj 1 
-ATOM 287  N N   . ILE Q 17 79  ? 149.483 290.539 239.634 1.00 128.89 79  Bj 1 
-ATOM 288  C CA  . ILE Q 17 79  ? 148.823 290.642 238.336 1.00 128.89 79  Bj 1 
-ATOM 289  C C   . ILE Q 17 79  ? 149.572 291.607 237.426 1.00 128.89 79  Bj 1 
-ATOM 290  O O   . ILE Q 17 79  ? 149.639 291.400 236.208 1.00 128.89 79  Bj 1 
-ATOM 291  C CB  . ILE Q 17 79  ? 147.349 291.057 238.519 1.00 128.89 79  Bj 1 
-ATOM 292  C CG1 . ILE Q 17 79  ? 146.601 290.011 239.349 1.00 128.89 79  Bj 1 
-ATOM 293  C CG2 . ILE Q 17 79  ? 146.667 291.245 237.171 1.00 128.89 79  Bj 1 
-ATOM 294  C CD1 . ILE Q 17 79  ? 145.159 290.370 239.635 1.00 128.89 79  Bj 1 
-ATOM 295  N N   . GLU Q 17 80  ? 150.159 292.661 237.996 1.00 120.51 80  Bj 1 
-ATOM 296  C CA  . GLU Q 17 80  ? 150.899 293.625 237.187 1.00 120.51 80  Bj 1 
-ATOM 297  C C   . GLU Q 17 80  ? 152.154 292.998 236.589 1.00 120.51 80  Bj 1 
-ATOM 298  O O   . GLU Q 17 80  ? 152.403 293.116 235.384 1.00 120.51 80  Bj 1 
-ATOM 299  C CB  . GLU Q 17 80  ? 151.254 294.849 238.029 1.00 120.51 80  Bj 1 
-ATOM 300  C CG  . GLU Q 17 80  ? 150.076 295.764 238.317 1.00 120.51 80  Bj 1 
-ATOM 301  C CD  . GLU Q 17 80  ? 150.361 296.745 239.436 1.00 120.51 80  Bj 1 
-ATOM 302  O OE1 . GLU Q 17 80  ? 151.384 296.573 240.132 1.00 120.51 80  Bj 1 
-ATOM 303  O OE2 . GLU Q 17 80  ? 149.562 297.686 239.621 1.00 120.51 80  Bj 1 
-ATOM 304  N N   . ARG Q 17 81  ? 152.958 292.327 237.415 1.00 127.65 81  Bj 1 
-ATOM 305  C CA  . ARG Q 17 81  ? 154.175 291.694 236.924 1.00 127.65 81  Bj 1 
-ATOM 306  C C   . ARG Q 17 81  ? 153.910 290.416 236.139 1.00 127.65 81  Bj 1 
-ATOM 307  O O   . ARG Q 17 81  ? 154.830 289.913 235.485 1.00 127.65 81  Bj 1 
-ATOM 308  C CB  . ARG Q 17 81  ? 155.125 291.390 238.086 1.00 127.65 81  Bj 1 
-ATOM 309  C CG  . ARG Q 17 81  ? 155.793 292.620 238.677 1.00 127.65 81  Bj 1 
-ATOM 310  C CD  . ARG Q 17 81  ? 156.934 292.237 239.606 1.00 127.65 81  Bj 1 
-ATOM 311  N NE  . ARG Q 17 81  ? 157.606 293.409 240.160 1.00 127.65 81  Bj 1 
-ATOM 312  C CZ  . ARG Q 17 81  ? 158.686 293.357 240.933 1.00 127.65 81  Bj 1 
-ATOM 313  N NH1 . ARG Q 17 81  ? 159.223 292.186 241.246 1.00 127.65 81  Bj 1 
-ATOM 314  N NH2 . ARG Q 17 81  ? 159.230 294.475 241.393 1.00 127.65 81  Bj 1 
-ATOM 315  N N   . SER Q 17 82  ? 152.693 289.881 236.188 1.00 132.55 82  Bj 1 
-ATOM 316  C CA  . SER Q 17 82  ? 152.370 288.695 235.409 1.00 132.55 82  Bj 1 
-ATOM 317  C C   . SER Q 17 82  ? 152.400 289.006 233.917 1.00 132.55 82  Bj 1 
-ATOM 318  O O   . SER Q 17 82  ? 152.138 290.132 233.487 1.00 132.55 82  Bj 1 
-ATOM 319  C CB  . SER Q 17 82  ? 150.995 288.155 235.799 1.00 132.55 82  Bj 1 
-ATOM 320  O OG  . SER Q 17 82  ? 150.618 287.084 234.953 1.00 132.55 82  Bj 1 
-ATOM 321  N N   . LEU Q 17 83  ? 152.726 287.986 233.123 1.00 141.40 83  Bj 1 
-ATOM 322  C CA  . LEU Q 17 83  ? 152.784 288.167 231.677 1.00 141.40 83  Bj 1 
-ATOM 323  C C   . LEU Q 17 83  ? 151.391 288.102 231.062 1.00 141.40 83  Bj 1 
-ATOM 324  O O   . LEU Q 17 83  ? 150.906 289.086 230.495 1.00 141.40 83  Bj 1 
-ATOM 325  C CB  . LEU Q 17 83  ? 153.703 287.117 231.046 1.00 141.40 83  Bj 1 
-ATOM 326  C CG  . LEU Q 17 83  ? 155.217 287.359 231.080 1.00 141.40 83  Bj 1 
-ATOM 327  C CD1 . LEU Q 17 83  ? 155.777 287.271 232.494 1.00 141.40 83  Bj 1 
-ATOM 328  C CD2 . LEU Q 17 83  ? 155.934 286.382 230.159 1.00 141.40 83  Bj 1 
-ATOM 329  N N   . TYR Q 17 84  ? 150.729 286.953 231.185 1.00 138.40 84  Bj 1 
-ATOM 330  C CA  . TYR Q 17 84  ? 149.374 286.749 230.687 1.00 138.40 84  Bj 1 
-ATOM 331  C C   . TYR Q 17 84  ? 148.911 285.361 231.099 1.00 138.40 84  Bj 1 
-ATOM 332  O O   . TYR Q 17 84  ? 149.722 284.476 231.384 1.00 138.40 84  Bj 1 
-ATOM 333  C CB  . TYR Q 17 84  ? 149.286 286.904 229.164 1.00 138.40 84  Bj 1 
-ATOM 334  C CG  . TYR Q 17 84  ? 148.728 288.236 228.722 1.00 138.40 84  Bj 1 
-ATOM 335  C CD1 . TYR Q 17 84  ? 147.825 288.929 229.517 1.00 138.40 84  Bj 1 
-ATOM 336  C CD2 . TYR Q 17 84  ? 149.110 288.805 227.515 1.00 138.40 84  Bj 1 
-ATOM 337  C CE1 . TYR Q 17 84  ? 147.313 290.147 229.120 1.00 138.40 84  Bj 1 
-ATOM 338  C CE2 . TYR Q 17 84  ? 148.604 290.023 227.109 1.00 138.40 84  Bj 1 
-ATOM 339  C CZ  . TYR Q 17 84  ? 147.706 290.690 227.916 1.00 138.40 84  Bj 1 
-ATOM 340  O OH  . TYR Q 17 84  ? 147.198 291.905 227.517 1.00 138.40 84  Bj 1 
-ATOM 341  N N   . SER Q 17 85  ? 147.594 285.185 231.119 1.00 142.26 85  Bj 1 
-ATOM 342  C CA  . SER Q 17 85  ? 146.972 283.899 231.385 1.00 142.26 85  Bj 1 
-ATOM 343  C C   . SER Q 17 85  ? 146.297 283.383 230.122 1.00 142.26 85  Bj 1 
-ATOM 344  O O   . SER Q 17 85  ? 145.916 284.154 229.237 1.00 142.26 85  Bj 1 
-ATOM 345  C CB  . SER Q 17 85  ? 145.951 284.005 232.523 1.00 142.26 85  Bj 1 
-ATOM 346  O OG  . SER Q 17 85  ? 145.350 282.749 232.786 1.00 142.26 85  Bj 1 
-ATOM 347  N N   . ASP Q 17 86  ? 146.159 282.058 230.045 1.00 146.76 86  Bj 1 
-ATOM 348  C CA  . ASP Q 17 86  ? 145.513 281.453 228.884 1.00 146.76 86  Bj 1 
-ATOM 349  C C   . ASP Q 17 86  ? 144.067 281.911 228.760 1.00 146.76 86  Bj 1 
-ATOM 350  O O   . ASP Q 17 86  ? 143.592 282.202 227.656 1.00 146.76 86  Bj 1 
-ATOM 351  C CB  . ASP Q 17 86  ? 145.586 279.929 228.976 1.00 146.76 86  Bj 1 
-ATOM 352  C CG  . ASP Q 17 86  ? 147.009 279.410 228.939 1.00 146.76 86  Bj 1 
-ATOM 353  O OD1 . ASP Q 17 86  ? 147.939 280.227 228.775 1.00 146.76 86  Bj 1 
-ATOM 354  O OD2 . ASP Q 17 86  ? 147.198 278.182 229.073 1.00 146.76 86  Bj 1 
-ATOM 355  N N   . HIS Q 17 87  ? 143.355 281.991 229.886 1.00 143.58 87  Bj 1 
-ATOM 356  C CA  . HIS Q 17 87  ? 141.955 282.403 229.864 1.00 143.58 87  Bj 1 
-ATOM 357  C C   . HIS Q 17 87  ? 141.808 283.826 229.339 1.00 143.58 87  Bj 1 
-ATOM 358  O O   . HIS Q 17 87  ? 141.013 284.086 228.428 1.00 143.58 87  Bj 1 
-ATOM 359  C CB  . HIS Q 17 87  ? 141.361 282.274 231.266 1.00 143.58 87  Bj 1 
-ATOM 360  C CG  . HIS Q 17 87  ? 139.966 282.801 231.387 1.00 143.58 87  Bj 1 
-ATOM 361  N ND1 . HIS Q 17 87  ? 138.892 282.220 230.748 1.00 143.58 87  Bj 1 
-ATOM 362  C CD2 . HIS Q 17 87  ? 139.468 283.854 232.078 1.00 143.58 87  Bj 1 
-ATOM 363  C CE1 . HIS Q 17 87  ? 137.793 282.893 231.039 1.00 143.58 87  Bj 1 
-ATOM 364  N NE2 . HIS Q 17 87  ? 138.115 283.889 231.844 1.00 143.58 87  Bj 1 
-ATOM 365  N N   . GLU Q 17 88  ? 142.573 284.764 229.906 1.00 144.20 88  Bj 1 
-ATOM 366  C CA  . GLU Q 17 88  ? 142.496 286.152 229.463 1.00 144.20 88  Bj 1 
-ATOM 367  C C   . GLU Q 17 88  ? 142.938 286.295 228.013 1.00 144.20 88  Bj 1 
-ATOM 368  O O   . GLU Q 17 88  ? 142.350 287.073 227.251 1.00 144.20 88  Bj 1 
-ATOM 369  C CB  . GLU Q 17 88  ? 143.348 287.040 230.370 1.00 144.20 88  Bj 1 
-ATOM 370  C CG  . GLU Q 17 88  ? 142.916 287.043 231.827 1.00 144.20 88  Bj 1 
-ATOM 371  C CD  . GLU Q 17 88  ? 141.589 287.744 232.044 1.00 144.20 88  Bj 1 
-ATOM 372  O OE1 . GLU Q 17 88  ? 141.201 288.571 231.193 1.00 144.20 88  Bj 1 
-ATOM 373  O OE2 . GLU Q 17 88  ? 140.932 287.466 233.070 1.00 144.20 88  Bj 1 
-ATOM 374  N N   . LEU Q 17 89  ? 143.972 285.551 227.614 1.00 150.45 89  Bj 1 
-ATOM 375  C CA  . LEU Q 17 89  ? 144.455 285.625 226.240 1.00 150.45 89  Bj 1 
-ATOM 376  C C   . LEU Q 17 89  ? 143.384 285.161 225.263 1.00 150.45 89  Bj 1 
-ATOM 377  O O   . LEU Q 17 89  ? 143.108 285.834 224.263 1.00 150.45 89  Bj 1 
-ATOM 378  C CB  . LEU Q 17 89  ? 145.732 284.795 226.090 1.00 150.45 89  Bj 1 
-ATOM 379  C CG  . LEU Q 17 89  ? 146.537 284.942 224.794 1.00 150.45 89  Bj 1 
-ATOM 380  C CD1 . LEU Q 17 89  ? 148.022 284.792 225.081 1.00 150.45 89  Bj 1 
-ATOM 381  C CD2 . LEU Q 17 89  ? 146.100 283.926 223.748 1.00 150.45 89  Bj 1 
-ATOM 382  N N   . ARG Q 17 90  ? 142.765 284.008 225.537 1.00 152.73 90  Bj 1 
-ATOM 383  C CA  . ARG Q 17 90  ? 141.701 283.518 224.667 1.00 152.73 90  Bj 1 
-ATOM 384  C C   . ARG Q 17 90  ? 140.519 284.478 224.647 1.00 152.73 90  Bj 1 
-ATOM 385  O O   . ARG Q 17 90  ? 139.922 284.715 223.590 1.00 152.73 90  Bj 1 
-ATOM 386  C CB  . ARG Q 17 90  ? 141.249 282.128 225.114 1.00 152.73 90  Bj 1 
-ATOM 387  C CG  . ARG Q 17 90  ? 142.304 281.042 224.985 1.00 152.73 90  Bj 1 
-ATOM 388  C CD  . ARG Q 17 90  ? 141.785 279.721 225.532 1.00 152.73 90  Bj 1 
-ATOM 389  N NE  . ARG Q 17 90  ? 142.813 278.685 225.563 1.00 152.73 90  Bj 1 
-ATOM 390  C CZ  . ARG Q 17 90  ? 142.621 277.456 226.032 1.00 152.73 90  Bj 1 
-ATOM 391  N NH1 . ARG Q 17 90  ? 141.435 277.105 226.511 1.00 152.73 90  Bj 1 
-ATOM 392  N NH2 . ARG Q 17 90  ? 143.613 276.577 226.022 1.00 152.73 90  Bj 1 
-ATOM 393  N N   . ALA Q 17 91  ? 140.174 285.051 225.804 1.00 151.16 91  Bj 1 
-ATOM 394  C CA  . ALA Q 17 91  ? 139.046 285.974 225.863 1.00 151.16 91  Bj 1 
-ATOM 395  C C   . ALA Q 17 91  ? 139.295 287.204 225.000 1.00 151.16 91  Bj 1 
-ATOM 396  O O   . ALA Q 17 91  ? 138.448 287.586 224.184 1.00 151.16 91  Bj 1 
-ATOM 397  C CB  . ALA Q 17 91  ? 138.774 286.377 227.313 1.00 151.16 91  Bj 1 
-ATOM 398  N N   . LEU Q 17 92  ? 140.462 287.836 225.160 1.00 153.35 92  Bj 1 
-ATOM 399  C CA  . LEU Q 17 92  ? 140.757 289.032 224.378 1.00 153.35 92  Bj 1 
-ATOM 400  C C   . LEU Q 17 92  ? 140.911 288.700 222.898 1.00 153.35 92  Bj 1 
-ATOM 401  O O   . LEU Q 17 92  ? 140.504 289.488 222.035 1.00 153.35 92  Bj 1 
-ATOM 402  C CB  . LEU Q 17 92  ? 142.008 289.729 224.920 1.00 153.35 92  Bj 1 
-ATOM 403  C CG  . LEU Q 17 92  ? 143.367 289.021 224.908 1.00 153.35 92  Bj 1 
-ATOM 404  C CD1 . LEU Q 17 92  ? 144.128 289.267 223.608 1.00 153.35 92  Bj 1 
-ATOM 405  C CD2 . LEU Q 17 92  ? 144.198 289.456 226.107 1.00 153.35 92  Bj 1 
-ATOM 406  N N   . ASP Q 17 93  ? 141.477 287.531 222.583 1.00 158.04 93  Bj 1 
-ATOM 407  C CA  . ASP Q 17 93  ? 141.618 287.134 221.188 1.00 158.04 93  Bj 1 
-ATOM 408  C C   . ASP Q 17 93  ? 140.259 286.958 220.528 1.00 158.04 93  Bj 1 
-ATOM 409  O O   . ASP Q 17 93  ? 140.031 287.459 219.422 1.00 158.04 93  Bj 1 
-ATOM 410  C CB  . ASP Q 17 93  ? 142.435 285.845 221.091 1.00 158.04 93  Bj 1 
-ATOM 411  C CG  . ASP Q 17 93  ? 142.537 285.325 219.671 1.00 158.04 93  Bj 1 
-ATOM 412  O OD1 . ASP Q 17 93  ? 143.236 285.958 218.852 1.00 158.04 93  Bj 1 
-ATOM 413  O OD2 . ASP Q 17 93  ? 141.915 284.283 219.372 1.00 158.04 93  Bj 1 
-ATOM 414  N N   . GLU Q 17 94  ? 139.338 286.257 221.195 1.00 152.75 94  Bj 1 
-ATOM 415  C CA  . GLU Q 17 94  ? 138.009 286.061 220.624 1.00 152.75 94  Bj 1 
-ATOM 416  C C   . GLU Q 17 94  ? 137.242 287.374 220.544 1.00 152.75 94  Bj 1 
-ATOM 417  O O   . GLU Q 17 94  ? 136.508 287.609 219.576 1.00 152.75 94  Bj 1 
-ATOM 418  C CB  . GLU Q 17 94  ? 137.232 285.028 221.439 1.00 152.75 94  Bj 1 
-ATOM 419  C CG  . GLU Q 17 94  ? 137.821 283.622 221.404 1.00 152.75 94  Bj 1 
-ATOM 420  C CD  . GLU Q 17 94  ? 137.812 283.008 220.014 1.00 152.75 94  Bj 1 
-ATOM 421  O OE1 . GLU Q 17 94  ? 138.701 283.342 219.202 1.00 152.75 94  Bj 1 
-ATOM 422  O OE2 . GLU Q 17 94  ? 136.913 282.189 219.734 1.00 152.75 94  Bj 1 
-ATOM 423  N N   . ALA Q 17 95  ? 137.404 288.249 221.541 1.00 149.73 95  Bj 1 
-ATOM 424  C CA  . ALA Q 17 95  ? 136.744 289.549 221.485 1.00 149.73 95  Bj 1 
-ATOM 425  C C   . ALA Q 17 95  ? 137.228 290.374 220.300 1.00 149.73 95  Bj 1 
-ATOM 426  O O   . ALA Q 17 95  ? 136.409 290.925 219.556 1.00 149.73 95  Bj 1 
-ATOM 427  C CB  . ALA Q 17 95  ? 136.966 290.311 222.791 1.00 149.73 95  Bj 1 
-ATOM 428  N N   . GLN Q 17 96  ? 138.545 290.458 220.098 1.00 150.30 96  Bj 1 
-ATOM 429  C CA  . GLN Q 17 96  ? 139.069 291.205 218.961 1.00 150.30 96  Bj 1 
-ATOM 430  C C   . GLN Q 17 96  ? 138.693 290.549 217.637 1.00 150.30 96  Bj 1 
-ATOM 431  O O   . GLN Q 17 96  ? 138.419 291.247 216.653 1.00 150.30 96  Bj 1 
-ATOM 432  C CB  . GLN Q 17 96  ? 140.587 291.346 219.080 1.00 150.30 96  Bj 1 
-ATOM 433  C CG  . GLN Q 17 96  ? 141.037 292.145 220.293 1.00 150.30 96  Bj 1 
-ATOM 434  C CD  . GLN Q 17 96  ? 142.543 292.301 220.364 1.00 150.30 96  Bj 1 
-ATOM 435  O OE1 . GLN Q 17 96  ? 143.262 291.925 219.438 1.00 150.30 96  Bj 1 
-ATOM 436  N NE2 . GLN Q 17 96  ? 143.029 292.859 221.467 1.00 150.30 96  Bj 1 
-ATOM 437  N N   . GLN Q 17 97  ? 138.657 289.214 217.595 1.00 151.44 97  Bj 1 
-ATOM 438  C CA  . GLN Q 17 97  ? 138.274 288.528 216.367 1.00 151.44 97  Bj 1 
-ATOM 439  C C   . GLN Q 17 97  ? 136.824 288.819 216.005 1.00 151.44 97  Bj 1 
-ATOM 440  O O   . GLN Q 17 97  ? 136.511 289.077 214.838 1.00 151.44 97  Bj 1 
-ATOM 441  C CB  . GLN Q 17 97  ? 138.504 287.024 216.512 1.00 151.44 97  Bj 1 
-ATOM 442  C CG  . GLN Q 17 97  ? 138.299 286.242 215.225 1.00 151.44 97  Bj 1 
-ATOM 443  C CD  . GLN Q 17 97  ? 138.665 284.777 215.367 1.00 151.44 97  Bj 1 
-ATOM 444  O OE1 . GLN Q 17 97  ? 138.752 284.049 214.377 1.00 151.44 97  Bj 1 
-ATOM 445  N NE2 . GLN Q 17 97  ? 138.881 284.336 216.601 1.00 151.44 97  Bj 1 
-ATOM 446  N N   . LEU Q 17 98  ? 135.926 288.798 216.992 1.00 148.86 98  Bj 1 
-ATOM 447  C CA  . LEU Q 17 98  ? 134.535 289.147 216.723 1.00 148.86 98  Bj 1 
-ATOM 448  C C   . LEU Q 17 98  ? 134.399 290.617 216.343 1.00 148.86 98  Bj 1 
-ATOM 449  O O   . LEU Q 17 98  ? 133.602 290.963 215.462 1.00 148.86 98  Bj 1 
-ATOM 450  C CB  . LEU Q 17 98  ? 133.663 288.821 217.936 1.00 148.86 98  Bj 1 
-ATOM 451  C CG  . LEU Q 17 98  ? 132.970 287.455 217.941 1.00 148.86 98  Bj 1 
-ATOM 452  C CD1 . LEU Q 17 98  ? 133.982 286.318 217.938 1.00 148.86 98  Bj 1 
-ATOM 453  C CD2 . LEU Q 17 98  ? 132.028 287.335 219.129 1.00 148.86 98  Bj 1 
-ATOM 454  N N   . ALA Q 17 99  ? 135.174 291.494 216.988 1.00 145.68 99  Bj 1 
-ATOM 455  C CA  . ALA Q 17 99  ? 135.111 292.915 216.661 1.00 145.68 99  Bj 1 
-ATOM 456  C C   . ALA Q 17 99  ? 135.546 293.172 215.225 1.00 145.68 99  Bj 1 
-ATOM 457  O O   . ALA Q 17 99  ? 134.966 294.018 214.534 1.00 145.68 99  Bj 1 
-ATOM 458  C CB  . ALA Q 17 99  ? 135.974 293.716 217.636 1.00 145.68 99  Bj 1 
-ATOM 459  N N   . LYS Q 17 100 ? 136.567 292.452 214.755 1.00 146.95 100 Bj 1 
-ATOM 460  C CA  . LYS Q 17 100 ? 137.039 292.630 213.387 1.00 146.95 100 Bj 1 
-ATOM 461  C C   . LYS Q 17 100 ? 136.219 291.845 212.371 1.00 146.95 100 Bj 1 
-ATOM 462  O O   . LYS Q 17 100 ? 136.274 292.159 211.177 1.00 146.95 100 Bj 1 
-ATOM 463  C CB  . LYS Q 17 100 ? 138.514 292.233 213.279 1.00 146.95 100 Bj 1 
-ATOM 464  C CG  . LYS Q 17 100 ? 139.442 293.056 214.160 1.00 146.95 100 Bj 1 
-ATOM 465  C CD  . LYS Q 17 100 ? 139.237 294.550 213.946 1.00 146.95 100 Bj 1 
-ATOM 466  C CE  . LYS Q 17 100 ? 139.610 294.973 212.533 1.00 146.95 100 Bj 1 
-ATOM 467  N NZ  . LYS Q 17 100 ? 139.301 296.408 212.288 1.00 146.95 100 Bj 1 
-ATOM 468  N N   . LYS Q 17 101 ? 135.468 290.833 212.812 1.00 146.63 101 Bj 1 
-ATOM 469  C CA  . LYS Q 17 101 ? 134.598 290.100 211.900 1.00 146.63 101 Bj 1 
-ATOM 470  C C   . LYS Q 17 101 ? 133.263 290.804 211.699 1.00 146.63 101 Bj 1 
-ATOM 471  O O   . LYS Q 17 101 ? 132.679 290.714 210.613 1.00 146.63 101 Bj 1 
-ATOM 472  C CB  . LYS Q 17 101 ? 134.377 288.677 212.420 1.00 146.63 101 Bj 1 
-ATOM 473  C CG  . LYS Q 17 101 ? 133.447 287.827 211.565 1.00 146.63 101 Bj 1 
-ATOM 474  C CD  . LYS Q 17 101 ? 133.953 287.708 210.137 1.00 146.63 101 Bj 1 
-ATOM 475  C CE  . LYS Q 17 101 ? 132.991 286.903 209.277 1.00 146.63 101 Bj 1 
-ATOM 476  N NZ  . LYS Q 17 101 ? 133.449 286.811 207.864 1.00 146.63 101 Bj 1 
-ATOM 477  N N   . LYS Q 17 102 ? 132.768 291.510 212.721 1.00 149.37 102 Bj 1 
-ATOM 478  C CA  . LYS Q 17 102 ? 131.516 292.243 212.568 1.00 149.37 102 Bj 1 
-ATOM 479  C C   . LYS Q 17 102 ? 131.629 293.337 211.515 1.00 149.37 102 Bj 1 
-ATOM 480  O O   . LYS Q 17 102 ? 130.622 293.722 210.910 1.00 149.37 102 Bj 1 
-ATOM 481  C CB  . LYS Q 17 102 ? 131.084 292.839 213.908 1.00 149.37 102 Bj 1 
-ATOM 482  C CG  . LYS Q 17 102 ? 130.550 291.819 214.900 1.00 149.37 102 Bj 1 
-ATOM 483  C CD  . LYS Q 17 102 ? 130.124 292.485 216.198 1.00 149.37 102 Bj 1 
-ATOM 484  C CE  . LYS Q 17 102 ? 129.052 293.533 215.952 1.00 149.37 102 Bj 1 
-ATOM 485  N NZ  . LYS Q 17 102 ? 127.840 292.944 215.321 1.00 149.37 102 Bj 1 
-ATOM 486  N N   . SER Q 17 103 ? 132.836 293.849 211.283 1.00 153.12 103 Bj 1 
-ATOM 487  C CA  . SER Q 17 103 ? 133.065 294.846 210.248 1.00 153.12 103 Bj 1 
-ATOM 488  C C   . SER Q 17 103 ? 133.347 294.232 208.883 1.00 153.12 103 Bj 1 
-ATOM 489  O O   . SER Q 17 103 ? 133.244 294.935 207.872 1.00 153.12 103 Bj 1 
-ATOM 490  C CB  . SER Q 17 103 ? 134.228 295.762 210.645 1.00 153.12 103 Bj 1 
-ATOM 491  O OG  . SER Q 17 103 ? 135.428 295.024 210.805 1.00 153.12 103 Bj 1 
-ATOM 492  N N   . ASP Q 17 104 ? 133.696 292.950 208.828 1.00 150.06 104 Bj 1 
-ATOM 493  C CA  . ASP Q 17 104 ? 133.990 292.286 207.564 1.00 150.06 104 Bj 1 
-ATOM 494  C C   . ASP Q 17 104 ? 133.253 290.954 207.461 1.00 150.06 104 Bj 1 
-ATOM 495  O O   . ASP Q 17 104 ? 132.042 290.886 207.671 1.00 150.06 104 Bj 1 
-ATOM 496  C CB  . ASP Q 17 104 ? 135.497 292.067 207.412 1.00 150.06 104 Bj 1 
-ATOM 497  C CG  . ASP Q 17 104 ? 135.859 291.377 206.111 1.00 150.06 104 Bj 1 
-ATOM 498  O OD1 . ASP Q 17 104 ? 135.698 292.000 205.040 1.00 150.06 104 Bj 1 
-ATOM 499  O OD2 . ASP Q 17 104 ? 136.307 290.212 206.158 1.00 150.06 104 Bj 1 
-ATOM 500  N N   . LEU Q 17 116 ? 133.163 280.213 224.046 1.00 145.92 116 Bj 1 
-ATOM 501  C CA  . LEU Q 17 116 ? 133.824 281.452 224.439 1.00 145.92 116 Bj 1 
-ATOM 502  C C   . LEU Q 17 116 ? 134.248 281.400 225.904 1.00 145.92 116 Bj 1 
-ATOM 503  O O   . LEU Q 17 116 ? 134.010 280.409 226.594 1.00 145.92 116 Bj 1 
-ATOM 504  C CB  . LEU Q 17 116 ? 132.909 282.657 224.197 1.00 145.92 116 Bj 1 
-ATOM 505  C CG  . LEU Q 17 116 ? 132.645 283.081 222.748 1.00 145.92 116 Bj 1 
-ATOM 506  C CD1 . LEU Q 17 116 ? 133.940 283.098 221.947 1.00 145.92 116 Bj 1 
-ATOM 507  C CD2 . LEU Q 17 116 ? 131.596 282.203 222.072 1.00 145.92 116 Bj 1 
-ATOM 508  N N   . ALA Q 17 117 ? 134.878 282.476 226.373 1.00 150.38 117 Bj 1 
-ATOM 509  C CA  . ALA Q 17 117 ? 135.358 282.543 227.748 1.00 150.38 117 Bj 1 
-ATOM 510  C C   . ALA Q 17 117 ? 134.316 283.114 228.702 1.00 150.38 117 Bj 1 
-ATOM 511  O O   . ALA Q 17 117 ? 134.259 282.710 229.870 1.00 150.38 117 Bj 1 
-ATOM 512  C CB  . ALA Q 17 117 ? 136.638 283.378 227.815 1.00 150.38 117 Bj 1 
-ATOM 513  N N   . GLN Q 17 118 ? 133.490 284.050 228.229 1.00 142.89 118 Bj 1 
-ATOM 514  C CA  . GLN Q 17 118 ? 132.488 284.656 229.099 1.00 142.89 118 Bj 1 
-ATOM 515  C C   . GLN Q 17 118 ? 131.425 283.644 229.507 1.00 142.89 118 Bj 1 
-ATOM 516  O O   . GLN Q 17 118 ? 130.930 283.680 230.639 1.00 142.89 118 Bj 1 
-ATOM 517  C CB  . GLN Q 17 118 ? 131.852 285.861 228.409 1.00 142.89 118 Bj 1 
-ATOM 518  C CG  . GLN Q 17 118 ? 132.831 286.982 228.103 1.00 142.89 118 Bj 1 
-ATOM 519  C CD  . GLN Q 17 118 ? 132.150 288.215 227.546 1.00 142.89 118 Bj 1 
-ATOM 520  O OE1 . GLN Q 17 118 ? 130.942 288.218 227.309 1.00 142.89 118 Bj 1 
-ATOM 521  N NE2 . GLN Q 17 118 ? 132.924 289.274 227.337 1.00 142.89 118 Bj 1 
-ATOM 522  N N   . ASP Q 17 119 ? 131.065 282.731 228.601 1.00 146.82 119 Bj 1 
-ATOM 523  C CA  . ASP Q 17 119 ? 130.108 281.686 228.951 1.00 146.82 119 Bj 1 
-ATOM 524  C C   . ASP Q 17 119 ? 130.655 280.792 230.056 1.00 146.82 119 Bj 1 
-ATOM 525  O O   . ASP Q 17 119 ? 129.943 280.472 231.016 1.00 146.82 119 Bj 1 
-ATOM 526  C CB  . ASP Q 17 119 ? 129.759 280.857 227.715 1.00 146.82 119 Bj 1 
-ATOM 527  C CG  . ASP Q 17 119 ? 129.136 281.688 226.613 1.00 146.82 119 Bj 1 
-ATOM 528  O OD1 . ASP Q 17 119 ? 128.456 282.687 226.932 1.00 146.82 119 Bj 1 
-ATOM 529  O OD2 . ASP Q 17 119 ? 129.325 281.343 225.428 1.00 146.82 119 Bj 1 
-ATOM 530  N N   . LEU Q 17 120 ? 131.922 280.388 229.941 1.00 143.97 120 Bj 1 
-ATOM 531  C CA  . LEU Q 17 120 ? 132.531 279.559 230.976 1.00 143.97 120 Bj 1 
-ATOM 532  C C   . LEU Q 17 120 ? 132.639 280.316 232.294 1.00 143.97 120 Bj 1 
-ATOM 533  O O   . LEU Q 17 120 ? 132.434 279.736 233.367 1.00 143.97 120 Bj 1 
-ATOM 534  C CB  . LEU Q 17 120 ? 133.907 279.077 230.517 1.00 143.97 120 Bj 1 
-ATOM 535  C CG  . LEU Q 17 120 ? 133.963 278.376 229.157 1.00 143.97 120 Bj 1 
-ATOM 536  C CD1 . LEU Q 17 120 ? 135.379 277.917 228.843 1.00 143.97 120 Bj 1 
-ATOM 537  C CD2 . LEU Q 17 120 ? 132.992 277.205 229.107 1.00 143.97 120 Bj 1 
-ATOM 538  N N   . GLU Q 17 121 ? 132.949 281.613 232.235 1.00 138.39 121 Bj 1 
-ATOM 539  C CA  . GLU Q 17 121 ? 133.032 282.405 233.459 1.00 138.39 121 Bj 1 
-ATOM 540  C C   . GLU Q 17 121 ? 131.674 282.510 234.141 1.00 138.39 121 Bj 1 
-ATOM 541  O O   . GLU Q 17 121 ? 131.573 282.370 235.366 1.00 138.39 121 Bj 1 
-ATOM 542  C CB  . GLU Q 17 121 ? 133.586 283.796 233.152 1.00 138.39 121 Bj 1 
-ATOM 543  C CG  . GLU Q 17 121 ? 133.560 284.751 234.337 1.00 138.39 121 Bj 1 
-ATOM 544  C CD  . GLU Q 17 121 ? 134.430 284.285 235.491 1.00 138.39 121 Bj 1 
-ATOM 545  O OE1 . GLU Q 17 121 ? 135.428 283.575 235.242 1.00 138.39 121 Bj 1 
-ATOM 546  O OE2 . GLU Q 17 121 ? 134.114 284.628 236.650 1.00 138.39 121 Bj 1 
-ATOM 547  N N   . ASP Q 17 122 ? 130.617 282.755 233.364 1.00 136.27 122 Bj 1 
-ATOM 548  C CA  . ASP Q 17 122 ? 129.278 282.822 233.938 1.00 136.27 122 Bj 1 
-ATOM 549  C C   . ASP Q 17 122 ? 128.853 281.471 234.501 1.00 136.27 122 Bj 1 
-ATOM 550  O O   . ASP Q 17 122 ? 128.190 281.408 235.543 1.00 136.27 122 Bj 1 
-ATOM 551  C CB  . ASP Q 17 122 ? 128.281 283.308 232.888 1.00 136.27 122 Bj 1 
-ATOM 552  C CG  . ASP Q 17 122 ? 128.626 284.682 232.352 1.00 136.27 122 Bj 1 
-ATOM 553  O OD1 . ASP Q 17 122 ? 129.645 285.254 232.793 1.00 136.27 122 Bj 1 
-ATOM 554  O OD2 . ASP Q 17 122 ? 127.881 285.189 231.488 1.00 136.27 122 Bj 1 
-ATOM 555  N N   . MET Q 17 123 ? 129.232 280.381 233.829 1.00 138.10 123 Bj 1 
-ATOM 556  C CA  . MET Q 17 123 ? 128.929 279.051 234.345 1.00 138.10 123 Bj 1 
-ATOM 557  C C   . MET Q 17 123 ? 129.632 278.806 235.675 1.00 138.10 123 Bj 1 
-ATOM 558  O O   . MET Q 17 123 ? 129.032 278.278 236.618 1.00 138.10 123 Bj 1 
-ATOM 559  C CB  . MET Q 17 123 ? 129.329 277.991 233.319 1.00 138.10 123 Bj 1 
-ATOM 560  C CG  . MET Q 17 123 ? 128.950 276.572 233.702 1.00 138.10 123 Bj 1 
-ATOM 561  S SD  . MET Q 17 123 ? 129.525 275.362 232.494 1.00 138.10 123 Bj 1 
-ATOM 562  C CE  . MET Q 17 123 ? 128.763 275.986 230.998 1.00 138.10 123 Bj 1 
-ATOM 563  N N   . TRP Q 17 124 ? 130.906 279.192 235.770 1.00 136.46 124 Bj 1 
-ATOM 564  C CA  . TRP Q 17 124 ? 131.634 279.040 237.027 1.00 136.46 124 Bj 1 
-ATOM 565  C C   . TRP Q 17 124 ? 131.008 279.885 238.129 1.00 136.46 124 Bj 1 
-ATOM 566  O O   . TRP Q 17 124 ? 130.875 279.430 239.272 1.00 136.46 124 Bj 1 
-ATOM 567  C CB  . TRP Q 17 124 ? 133.102 279.416 236.828 1.00 136.46 124 Bj 1 
-ATOM 568  C CG  . TRP Q 17 124 ? 133.795 278.588 235.791 1.00 136.46 124 Bj 1 
-ATOM 569  C CD1 . TRP Q 17 124 ? 133.472 277.320 235.405 1.00 136.46 124 Bj 1 
-ATOM 570  C CD2 . TRP Q 17 124 ? 134.920 278.975 234.994 1.00 136.46 124 Bj 1 
-ATOM 571  N NE1 . TRP Q 17 124 ? 134.331 276.891 234.423 1.00 136.46 124 Bj 1 
-ATOM 572  C CE2 . TRP Q 17 124 ? 135.229 277.889 234.152 1.00 136.46 124 Bj 1 
-ATOM 573  C CE3 . TRP Q 17 124 ? 135.698 280.134 234.913 1.00 136.46 124 Bj 1 
-ATOM 574  C CZ2 . TRP Q 17 124 ? 136.283 277.927 233.242 1.00 136.46 124 Bj 1 
-ATOM 575  C CZ3 . TRP Q 17 124 ? 136.743 280.169 234.009 1.00 136.46 124 Bj 1 
-ATOM 576  C CH2 . TRP Q 17 124 ? 137.026 279.073 233.186 1.00 136.46 124 Bj 1 
-ATOM 577  N N   . GLU Q 17 125 ? 130.604 281.116 237.802 1.00 133.02 125 Bj 1 
-ATOM 578  C CA  . GLU Q 17 125 ? 129.992 281.984 238.803 1.00 133.02 125 Bj 1 
-ATOM 579  C C   . GLU Q 17 125 ? 128.671 281.413 239.299 1.00 133.02 125 Bj 1 
-ATOM 580  O O   . GLU Q 17 125 ? 128.403 281.405 240.507 1.00 133.02 125 Bj 1 
-ATOM 581  C CB  . GLU Q 17 125 ? 129.785 283.386 238.231 1.00 133.02 125 Bj 1 
-ATOM 582  C CG  . GLU Q 17 125 ? 131.071 284.154 237.985 1.00 133.02 125 Bj 1 
-ATOM 583  C CD  . GLU Q 17 125 ? 130.819 285.533 237.408 1.00 133.02 125 Bj 1 
-ATOM 584  O OE1 . GLU Q 17 125 ? 129.640 285.874 237.179 1.00 133.02 125 Bj 1 
-ATOM 585  O OE2 . GLU Q 17 125 ? 131.799 286.274 237.184 1.00 133.02 125 Bj 1 
-ATOM 586  N N   . GLN Q 17 126 ? 127.828 280.928 238.383 1.00 132.06 126 Bj 1 
-ATOM 587  C CA  . GLN Q 17 126 ? 126.550 280.374 238.808 1.00 132.06 126 Bj 1 
-ATOM 588  C C   . GLN Q 17 126 ? 126.735 279.073 239.580 1.00 132.06 126 Bj 1 
-ATOM 589  O O   . GLN Q 17 126 ? 125.981 278.808 240.520 1.00 132.06 126 Bj 1 
-ATOM 590  C CB  . GLN Q 17 126 ? 125.624 280.176 237.605 1.00 132.06 126 Bj 1 
-ATOM 591  C CG  . GLN Q 17 126 ? 126.097 279.164 236.583 1.00 132.06 126 Bj 1 
-ATOM 592  C CD  . GLN Q 17 126 ? 125.303 279.223 235.293 1.00 132.06 126 Bj 1 
-ATOM 593  O OE1 . GLN Q 17 126 ? 124.412 280.057 235.137 1.00 132.06 126 Bj 1 
-ATOM 594  N NE2 . GLN Q 17 126 ? 125.624 278.335 234.359 1.00 132.06 126 Bj 1 
-ATOM 595  N N   . LYS Q 17 127 ? 127.748 278.271 239.234 1.00 128.96 127 Bj 1 
-ATOM 596  C CA  . LYS Q 17 127 ? 128.037 277.081 240.029 1.00 128.96 127 Bj 1 
-ATOM 597  C C   . LYS Q 17 127 ? 128.495 277.455 241.433 1.00 128.96 127 Bj 1 
-ATOM 598  O O   . LYS Q 17 127 ? 128.100 276.813 242.414 1.00 128.96 127 Bj 1 
-ATOM 599  C CB  . LYS Q 17 127 ? 129.093 276.223 239.332 1.00 128.96 127 Bj 1 
-ATOM 600  C CG  . LYS Q 17 127 ? 128.593 275.496 238.093 1.00 128.96 127 Bj 1 
-ATOM 601  C CD  . LYS Q 17 127 ? 129.699 274.667 237.457 1.00 128.96 127 Bj 1 
-ATOM 602  C CE  . LYS Q 17 127 ? 129.191 273.901 236.246 1.00 128.96 127 Bj 1 
-ATOM 603  N NZ  . LYS Q 17 127 ? 130.253 273.047 235.645 1.00 128.96 127 Bj 1 
-ATOM 604  N N   . PHE Q 17 128 ? 129.328 278.493 241.547 1.00 124.78 128 Bj 1 
-ATOM 605  C CA  . PHE Q 17 128 ? 129.778 278.943 242.861 1.00 124.78 128 Bj 1 
-ATOM 606  C C   . PHE Q 17 128 ? 128.613 279.459 243.694 1.00 124.78 128 Bj 1 
-ATOM 607  O O   . PHE Q 17 128 ? 128.543 279.208 244.903 1.00 124.78 128 Bj 1 
-ATOM 608  C CB  . PHE Q 17 128 ? 130.845 280.026 242.703 1.00 124.78 128 Bj 1 
-ATOM 609  C CG  . PHE Q 17 128 ? 131.325 280.607 244.004 1.00 124.78 128 Bj 1 
-ATOM 610  C CD1 . PHE Q 17 128 ? 132.290 279.956 244.754 1.00 124.78 128 Bj 1 
-ATOM 611  C CD2 . PHE Q 17 128 ? 130.821 281.810 244.470 1.00 124.78 128 Bj 1 
-ATOM 612  C CE1 . PHE Q 17 128 ? 132.737 280.489 245.948 1.00 124.78 128 Bj 1 
-ATOM 613  C CE2 . PHE Q 17 128 ? 131.264 282.348 245.663 1.00 124.78 128 Bj 1 
-ATOM 614  C CZ  . PHE Q 17 128 ? 132.223 281.687 246.403 1.00 124.78 128 Bj 1 
-ATOM 615  N N   . LEU Q 17 129 ? 127.688 280.186 243.064 1.00 122.50 129 Bj 1 
-ATOM 616  C CA  . LEU Q 17 129 ? 126.535 280.696 243.799 1.00 122.50 129 Bj 1 
-ATOM 617  C C   . LEU Q 17 129 ? 125.558 279.583 244.162 1.00 122.50 129 Bj 1 
-ATOM 618  O O   . LEU Q 17 129 ? 124.879 279.670 245.192 1.00 122.50 129 Bj 1 
-ATOM 619  C CB  . LEU Q 17 129 ? 125.829 281.784 242.989 1.00 122.50 129 Bj 1 
-ATOM 620  C CG  . LEU Q 17 129 ? 126.260 283.226 243.273 1.00 122.50 129 Bj 1 
-ATOM 621  C CD1 . LEU Q 17 129 ? 126.103 283.546 244.752 1.00 122.50 129 Bj 1 
-ATOM 622  C CD2 . LEU Q 17 129 ? 127.688 283.484 242.817 1.00 122.50 129 Bj 1 
-ATOM 623  N N   . HIS Q 17 130 ? 125.472 278.535 243.339 1.00 124.27 130 Bj 1 
-ATOM 624  C CA  . HIS Q 17 130 ? 124.581 277.424 243.653 1.00 124.27 130 Bj 1 
-ATOM 625  C C   . HIS Q 17 130 ? 125.137 276.570 244.785 1.00 124.27 130 Bj 1 
-ATOM 626  O O   . HIS Q 17 130 ? 124.395 276.174 245.691 1.00 124.27 130 Bj 1 
-ATOM 627  C CB  . HIS Q 17 130 ? 124.343 276.571 242.407 1.00 124.27 130 Bj 1 
-ATOM 628  C CG  . HIS Q 17 130 ? 123.598 277.281 241.320 1.00 124.27 130 Bj 1 
-ATOM 629  N ND1 . HIS Q 17 130 ? 122.957 278.485 241.521 1.00 124.27 130 Bj 1 
-ATOM 630  C CD2 . HIS Q 17 130 ? 123.400 276.962 240.019 1.00 124.27 130 Bj 1 
-ATOM 631  C CE1 . HIS Q 17 130 ? 122.391 278.873 240.392 1.00 124.27 130 Bj 1 
-ATOM 632  N NE2 . HIS Q 17 130 ? 122.645 277.967 239.465 1.00 124.27 130 Bj 1 
-ATOM 633  N N   . PHE Q 17 131 ? 126.434 276.275 244.753 1.00 123.12 131 Bj 1 
-ATOM 634  C CA  . PHE Q 17 131 ? 127.041 275.459 245.795 1.00 123.12 131 Bj 1 
-ATOM 635  C C   . PHE Q 17 131 ? 127.241 276.280 247.061 1.00 123.12 131 Bj 1 
-ATOM 636  O O   . PHE Q 17 131 ? 127.634 277.449 247.007 1.00 123.12 131 Bj 1 
-ATOM 637  C CB  . PHE Q 17 131 ? 128.378 274.890 245.322 1.00 123.12 131 Bj 1 
-ATOM 638  C CG  . PHE Q 17 131 ? 128.932 273.819 246.221 1.00 123.12 131 Bj 1 
-ATOM 639  C CD1 . PHE Q 17 131 ? 128.636 272.485 245.993 1.00 123.12 131 Bj 1 
-ATOM 640  C CD2 . PHE Q 17 131 ? 129.747 274.145 247.292 1.00 123.12 131 Bj 1 
-ATOM 641  C CE1 . PHE Q 17 131 ? 129.144 271.497 246.816 1.00 123.12 131 Bj 1 
-ATOM 642  C CE2 . PHE Q 17 131 ? 130.257 273.162 248.118 1.00 123.12 131 Bj 1 
-ATOM 643  C CZ  . PHE Q 17 131 ? 129.955 271.837 247.880 1.00 123.12 131 Bj 1 
-ATOM 644  N N   . LYS Q 17 132 ? 126.965 275.659 248.206 1.00 116.35 132 Bj 1 
-ATOM 645  C CA  . LYS Q 17 132 ? 127.090 276.303 249.505 1.00 116.35 132 Bj 1 
-ATOM 646  C C   . LYS Q 17 132 ? 128.171 275.612 250.323 1.00 116.35 132 Bj 1 
-ATOM 647  O O   . LYS Q 17 132 ? 128.289 274.383 250.305 1.00 116.35 132 Bj 1 
-ATOM 648  C CB  . LYS Q 17 132 ? 125.759 276.283 250.264 1.00 116.35 132 Bj 1 
-ATOM 649  C CG  . LYS Q 17 132 ? 125.018 277.611 250.239 1.00 116.35 132 Bj 1 
-ATOM 650  C CD  . LYS Q 17 132 ? 124.841 278.121 248.819 1.00 116.35 132 Bj 1 
-ATOM 651  C CE  . LYS Q 17 132 ? 124.220 279.507 248.803 1.00 116.35 132 Bj 1 
-ATOM 652  N NZ  . LYS Q 17 132 ? 124.099 280.040 247.419 1.00 116.35 132 Bj 1 
-ATOM 653  N N   . LEU Q 17 133 ? 128.955 276.411 251.041 1.00 122.76 133 Bj 1 
-ATOM 654  C CA  . LEU Q 17 133 ? 130.066 275.909 251.829 1.00 122.76 133 Bj 1 
-ATOM 655  C C   . LEU Q 17 133 ? 129.629 275.679 253.274 1.00 122.76 133 Bj 1 
-ATOM 656  O O   . LEU Q 17 133 ? 128.461 275.844 253.634 1.00 122.76 133 Bj 1 
-ATOM 657  C CB  . LEU Q 17 133 ? 131.244 276.879 251.757 1.00 122.76 133 Bj 1 
-ATOM 658  C CG  . LEU Q 17 133 ? 131.666 277.326 250.356 1.00 122.76 133 Bj 1 
-ATOM 659  C CD1 . LEU Q 17 133 ? 132.813 278.319 250.434 1.00 122.76 133 Bj 1 
-ATOM 660  C CD2 . LEU Q 17 133 ? 132.045 276.128 249.501 1.00 122.76 133 Bj 1 
-ATOM 661  N N   . GLY Q 17 134 ? 130.584 275.293 254.118 1.00 129.65 134 Bj 1 
-ATOM 662  C CA  . GLY Q 17 134 ? 130.282 275.055 255.514 1.00 129.65 134 Bj 1 
-ATOM 663  C C   . GLY Q 17 134 ? 130.327 276.328 256.339 1.00 129.65 134 Bj 1 
-ATOM 664  O O   . GLY Q 17 134 ? 131.088 277.255 256.064 1.00 129.65 134 Bj 1 
-ATOM 665  N N   . ALA Q 17 135 ? 129.488 276.366 257.371 1.00 138.35 135 Bj 1 
-ATOM 666  C CA  . ALA Q 17 135 ? 129.408 277.524 258.252 1.00 138.35 135 Bj 1 
-ATOM 667  C C   . ALA Q 17 135 ? 130.539 277.469 259.271 1.00 138.35 135 Bj 1 
-ATOM 668  O O   . ALA Q 17 135 ? 130.677 276.482 260.002 1.00 138.35 135 Bj 1 
-ATOM 669  C CB  . ALA Q 17 135 ? 128.051 277.571 258.950 1.00 138.35 135 Bj 1 
-ATOM 670  N N   . ARG Q 17 136 ? 131.347 278.530 259.322 1.00 130.79 136 Bj 1 
-ATOM 671  C CA  . ARG Q 17 136 ? 132.483 278.568 260.234 1.00 130.79 136 Bj 1 
-ATOM 672  C C   . ARG Q 17 136 ? 132.087 278.942 261.655 1.00 130.79 136 Bj 1 
-ATOM 673  O O   . ARG Q 17 136 ? 132.785 278.556 262.599 1.00 130.79 136 Bj 1 
-ATOM 674  C CB  . ARG Q 17 136 ? 133.536 279.556 259.727 1.00 130.79 136 Bj 1 
-ATOM 675  C CG  . ARG Q 17 136 ? 133.810 279.469 258.237 1.00 130.79 136 Bj 1 
-ATOM 676  C CD  . ARG Q 17 136 ? 135.032 280.286 257.861 1.00 130.79 136 Bj 1 
-ATOM 677  N NE  . ARG Q 17 136 ? 134.968 281.647 258.384 1.00 130.79 136 Bj 1 
-ATOM 678  C CZ  . ARG Q 17 136 ? 135.943 282.541 258.256 1.00 130.79 136 Bj 1 
-ATOM 679  N NH1 . ARG Q 17 136 ? 137.061 282.218 257.620 1.00 130.79 136 Bj 1 
-ATOM 680  N NH2 . ARG Q 17 136 ? 135.801 283.757 258.764 1.00 130.79 136 Bj 1 
-ATOM 681  N N   . LEU Q 17 137 ? 130.992 279.683 261.830 1.00 133.57 137 Bj 1 
-ATOM 682  C CA  . LEU Q 17 137 ? 130.559 280.141 263.149 1.00 133.57 137 Bj 1 
-ATOM 683  C C   . LEU Q 17 137 ? 129.570 279.126 263.717 1.00 133.57 137 Bj 1 
-ATOM 684  O O   . LEU Q 17 137 ? 128.360 279.345 263.762 1.00 133.57 137 Bj 1 
-ATOM 685  C CB  . LEU Q 17 137 ? 129.956 281.539 263.059 1.00 133.57 137 Bj 1 
-ATOM 686  C CG  . LEU Q 17 137 ? 130.891 282.628 262.527 1.00 133.57 137 Bj 1 
-ATOM 687  C CD1 . LEU Q 17 137 ? 130.188 283.977 262.488 1.00 133.57 137 Bj 1 
-ATOM 688  C CD2 . LEU Q 17 137 ? 132.159 282.703 263.364 1.00 133.57 137 Bj 1 
-ATOM 689  N N   . THR Q 17 138 ? 130.111 277.993 264.160 1.00 133.35 138 Bj 1 
-ATOM 690  C CA  . THR Q 17 138 ? 129.322 276.936 264.778 1.00 133.35 138 Bj 1 
-ATOM 691  C C   . THR Q 17 138 ? 129.133 277.144 266.275 1.00 133.35 138 Bj 1 
-ATOM 692  O O   . THR Q 17 138 ? 128.651 276.236 266.959 1.00 133.35 138 Bj 1 
-ATOM 693  C CB  . THR Q 17 138 ? 129.970 275.573 264.522 1.00 133.35 138 Bj 1 
-ATOM 694  O OG1 . THR Q 17 138 ? 131.309 275.575 265.032 1.00 133.35 138 Bj 1 
-ATOM 695  C CG2 . THR Q 17 138 ? 129.999 275.269 263.033 1.00 133.35 138 Bj 1 
-ATOM 696  N N   . GLU Q 17 139 ? 129.508 278.309 266.795 1.00 134.95 139 Bj 1 
-ATOM 697  C CA  . GLU Q 17 139 ? 129.306 278.647 268.196 1.00 134.95 139 Bj 1 
-ATOM 698  C C   . GLU Q 17 139 ? 128.457 279.891 268.396 1.00 134.95 139 Bj 1 
-ATOM 699  O O   . GLU Q 17 139 ? 127.841 280.034 269.453 1.00 134.95 139 Bj 1 
-ATOM 700  C CB  . GLU Q 17 139 ? 130.659 278.842 268.900 1.00 134.95 139 Bj 1 
-ATOM 701  C CG  . GLU Q 17 139 ? 130.604 278.798 270.422 1.00 134.95 139 Bj 1 
-ATOM 702  C CD  . GLU Q 17 139 ? 130.428 280.169 271.046 1.00 134.95 139 Bj 1 
-ATOM 703  O OE1 . GLU Q 17 139 ? 130.488 281.174 270.307 1.00 134.95 139 Bj 1 
-ATOM 704  O OE2 . GLU Q 17 139 ? 130.231 280.241 272.277 1.00 134.95 139 Bj 1 
-ATOM 705  N N   . ALA Q 17 140 ? 128.404 280.792 267.412 1.00 139.06 140 Bj 1 
-ATOM 706  C CA  . ALA Q 17 140 ? 127.569 281.980 267.543 1.00 139.06 140 Bj 1 
-ATOM 707  C C   . ALA Q 17 140 ? 126.090 281.623 267.616 1.00 139.06 140 Bj 1 
-ATOM 708  O O   . ALA Q 17 140 ? 125.316 282.326 268.275 1.00 139.06 140 Bj 1 
-ATOM 709  C CB  . ALA Q 17 140 ? 127.829 282.937 266.380 1.00 139.06 140 Bj 1 
-ATOM 710  N N   . ASP Q 17 141 ? 125.681 280.539 266.954 1.00 140.48 141 Bj 1 
-ATOM 711  C CA  . ASP Q 17 141 ? 124.289 280.111 267.023 1.00 140.48 141 Bj 1 
-ATOM 712  C C   . ASP Q 17 141 ? 124.001 279.307 268.283 1.00 140.48 141 Bj 1 
-ATOM 713  O O   . ASP Q 17 141 ? 122.859 279.293 268.754 1.00 140.48 141 Bj 1 
-ATOM 714  C CB  . ASP Q 17 141 ? 123.924 279.291 265.784 1.00 140.48 141 Bj 1 
-ATOM 715  C CG  . ASP Q 17 141 ? 124.675 277.976 265.714 1.00 140.48 141 Bj 1 
-ATOM 716  O OD1 . ASP Q 17 141 ? 125.822 277.916 266.203 1.00 140.48 141 Bj 1 
-ATOM 717  O OD2 . ASP Q 17 141 ? 124.116 277.002 265.168 1.00 140.48 141 Bj 1 
-ATOM 718  N N   . LYS Q 17 142 ? 125.010 278.635 268.840 1.00 134.61 142 Bj 1 
-ATOM 719  C CA  . LYS Q 17 142 ? 124.797 277.853 270.053 1.00 134.61 142 Bj 1 
-ATOM 720  C C   . LYS Q 17 142 ? 124.838 278.740 271.293 1.00 134.61 142 Bj 1 
-ATOM 721  O O   . LYS Q 17 142 ? 123.839 278.877 272.005 1.00 134.61 142 Bj 1 
-ATOM 722  C CB  . LYS Q 17 142 ? 125.847 276.744 270.155 1.00 134.61 142 Bj 1 
-ATOM 723  C CG  . LYS Q 17 142 ? 126.107 276.000 268.857 1.00 134.61 142 Bj 1 
-ATOM 724  C CD  . LYS Q 17 142 ? 124.858 275.311 268.339 1.00 134.61 142 Bj 1 
-ATOM 725  C CE  . LYS Q 17 142 ? 125.153 274.532 267.067 1.00 134.61 142 Bj 1 
-ATOM 726  N NZ  . LYS Q 17 142 ? 123.939 273.858 266.530 1.00 134.61 142 Bj 1 
-ATOM 727  N N   . LYS Q 17 143 ? 125.993 279.349 271.561 1.00 130.78 143 Bj 1 
-ATOM 728  C CA  . LYS Q 17 143 ? 126.225 280.262 272.679 1.00 130.78 143 Bj 1 
-ATOM 729  C C   . LYS Q 17 143 ? 125.934 279.638 274.039 1.00 130.78 143 Bj 1 
-ATOM 730  O O   . LYS Q 17 143 ? 125.924 280.350 275.050 1.00 130.78 143 Bj 1 
-ATOM 731  C CB  . LYS Q 17 143 ? 125.421 281.559 272.519 1.00 130.78 143 Bj 1 
-ATOM 732  C CG  . LYS Q 17 143 ? 125.982 282.503 271.471 1.00 130.78 143 Bj 1 
-ATOM 733  C CD  . LYS Q 17 143 ? 127.408 282.899 271.812 1.00 130.78 143 Bj 1 
-ATOM 734  C CE  . LYS Q 17 143 ? 127.980 283.857 270.782 1.00 130.78 143 Bj 1 
-ATOM 735  N NZ  . LYS Q 17 143 ? 129.382 284.238 271.109 1.00 130.78 143 Bj 1 
-ATOM 736  N N   . ASP Q 17 144 ? 125.698 278.330 274.099 1.00 131.40 144 Bj 1 
-ATOM 737  C CA  . ASP Q 17 144 ? 125.447 277.643 275.360 1.00 131.40 144 Bj 1 
-ATOM 738  C C   . ASP Q 17 144 ? 126.492 276.583 275.666 1.00 131.40 144 Bj 1 
-ATOM 739  O O   . ASP Q 17 144 ? 127.062 276.578 276.763 1.00 131.40 144 Bj 1 
-ATOM 740  C CB  . ASP Q 17 144 ? 124.048 277.003 275.351 1.00 131.40 144 Bj 1 
-ATOM 741  C CG  . ASP Q 17 144 ? 122.935 278.027 275.449 1.00 131.40 144 Bj 1 
-ATOM 742  O OD1 . ASP Q 17 144 ? 122.551 278.595 274.407 1.00 131.40 144 Bj 1 
-ATOM 743  O OD2 . ASP Q 17 144 ? 122.442 278.263 276.571 1.00 131.40 144 Bj 1 
-ATOM 744  N N   . ASP Q 17 145 ? 126.762 275.685 274.723 1.00 125.63 145 Bj 1 
-ATOM 745  C CA  . ASP Q 17 145 ? 127.651 274.554 274.962 1.00 125.63 145 Bj 1 
-ATOM 746  C C   . ASP Q 17 145 ? 129.095 275.042 274.977 1.00 125.63 145 Bj 1 
-ATOM 747  O O   . ASP Q 17 145 ? 129.719 275.197 273.922 1.00 125.63 145 Bj 1 
-ATOM 748  C CB  . ASP Q 17 145 ? 127.441 273.482 273.897 1.00 125.63 145 Bj 1 
-ATOM 749  C CG  . ASP Q 17 145 ? 128.031 272.142 274.292 1.00 125.63 145 Bj 1 
-ATOM 750  O OD1 . ASP Q 17 145 ? 128.682 272.064 275.355 1.00 125.63 145 Bj 1 
-ATOM 751  O OD2 . ASP Q 17 145 ? 127.837 271.162 273.542 1.00 125.63 145 Bj 1 
-ATOM 752  N N   . ARG Q 17 146 ? 129.624 275.289 276.173 1.00 123.19 146 Bj 1 
-ATOM 753  C CA  . ARG Q 17 146 ? 131.031 275.617 276.354 1.00 123.19 146 Bj 1 
-ATOM 754  C C   . ARG Q 17 146 ? 131.912 274.378 276.423 1.00 123.19 146 Bj 1 
-ATOM 755  O O   . ARG Q 17 146 ? 133.141 274.505 276.438 1.00 123.19 146 Bj 1 
-ATOM 756  C CB  . ARG Q 17 146 ? 131.221 276.448 277.628 1.00 123.19 146 Bj 1 
-ATOM 757  C CG  . ARG Q 17 146 ? 130.339 277.684 277.717 1.00 123.19 146 Bj 1 
-ATOM 758  C CD  . ARG Q 17 146 ? 130.774 278.756 276.734 1.00 123.19 146 Bj 1 
-ATOM 759  N NE  . ARG Q 17 146 ? 130.058 280.011 276.945 1.00 123.19 146 Bj 1 
-ATOM 760  C CZ  . ARG Q 17 146 ? 130.291 281.128 276.265 1.00 123.19 146 Bj 1 
-ATOM 761  N NH1 . ARG Q 17 146 ? 131.225 281.151 275.325 1.00 123.19 146 Bj 1 
-ATOM 762  N NH2 . ARG Q 17 146 ? 129.590 282.224 276.524 1.00 123.19 146 Bj 1 
-ATOM 763  N N   . THR Q 17 147 ? 131.314 273.189 276.464 1.00 120.18 147 Bj 1 
-ATOM 764  C CA  . THR Q 17 147 ? 132.038 271.936 276.619 1.00 120.18 147 Bj 1 
-ATOM 765  C C   . THR Q 17 147 ? 132.125 271.136 275.328 1.00 120.18 147 Bj 1 
-ATOM 766  O O   . THR Q 17 147 ? 132.651 270.018 275.343 1.00 120.18 147 Bj 1 
-ATOM 767  C CB  . THR Q 17 147 ? 131.373 271.081 277.702 1.00 120.18 147 Bj 1 
-ATOM 768  O OG1 . THR Q 17 147 ? 130.082 270.655 277.249 1.00 120.18 147 Bj 1 
-ATOM 769  C CG2 . THR Q 17 147 ? 131.209 271.884 278.982 1.00 120.18 147 Bj 1 
-ATOM 770  N N   . SER Q 17 148 ? 131.625 271.672 274.219 1.00 118.54 148 Bj 1 
-ATOM 771  C CA  . SER Q 17 148 ? 131.618 270.943 272.961 1.00 118.54 148 Bj 1 
-ATOM 772  C C   . SER Q 17 148 ? 133.006 270.928 272.336 1.00 118.54 148 Bj 1 
-ATOM 773  O O   . SER Q 17 148 ? 133.743 271.916 272.398 1.00 118.54 148 Bj 1 
-ATOM 774  C CB  . SER Q 17 148 ? 130.617 271.567 271.988 1.00 118.54 148 Bj 1 
-ATOM 775  O OG  . SER Q 17 148 ? 130.928 272.926 271.735 1.00 118.54 148 Bj 1 
-ATOM 776  N N   . LEU Q 17 149 ? 133.361 269.790 271.735 1.00 117.15 149 Bj 1 
-ATOM 777  C CA  . LEU Q 17 149 ? 134.619 269.711 271.001 1.00 117.15 149 Bj 1 
-ATOM 778  C C   . LEU Q 17 149 ? 134.608 270.627 269.785 1.00 117.15 149 Bj 1 
-ATOM 779  O O   . LEU Q 17 149 ? 135.662 271.129 269.377 1.00 117.15 149 Bj 1 
-ATOM 780  C CB  . LEU Q 17 149 ? 134.891 268.267 270.579 1.00 117.15 149 Bj 1 
-ATOM 781  C CG  . LEU Q 17 149 ? 136.256 267.992 269.944 1.00 117.15 149 Bj 1 
-ATOM 782  C CD1 . LEU Q 17 149 ? 137.367 268.200 270.960 1.00 117.15 149 Bj 1 
-ATOM 783  C CD2 . LEU Q 17 149 ? 136.314 266.588 269.358 1.00 117.15 149 Bj 1 
-ATOM 784  N N   . HIS Q 17 150 ? 133.431 270.864 269.203 1.00 119.46 150 Bj 1 
-ATOM 785  C CA  . HIS Q 17 150 ? 133.275 271.750 268.056 1.00 119.46 150 Bj 1 
-ATOM 786  C C   . HIS Q 17 150 ? 132.939 273.179 268.467 1.00 119.46 150 Bj 1 
-ATOM 787  O O   . HIS Q 17 150 ? 132.307 273.912 267.695 1.00 119.46 150 Bj 1 
-ATOM 788  C CB  . HIS Q 17 150 ? 132.203 271.196 267.115 1.00 119.46 150 Bj 1 
-ATOM 789  C CG  . HIS Q 17 150 ? 132.333 271.667 265.700 1.00 119.46 150 Bj 1 
-ATOM 790  N ND1 . HIS Q 17 150 ? 133.406 271.334 264.901 1.00 119.46 150 Bj 1 
-ATOM 791  C CD2 . HIS Q 17 150 ? 131.523 272.440 264.939 1.00 119.46 150 Bj 1 
-ATOM 792  C CE1 . HIS Q 17 150 ? 133.252 271.884 263.709 1.00 119.46 150 Bj 1 
-ATOM 793  N NE2 . HIS Q 17 150 ? 132.118 272.561 263.706 1.00 119.46 150 Bj 1 
-ATOM 794  N N   . ARG Q 17 151 ? 133.334 273.589 269.675 1.00 116.45 151 Bj 1 
-ATOM 795  C CA  . ARG Q 17 151 ? 133.014 274.930 270.155 1.00 116.45 151 Bj 1 
-ATOM 796  C C   . ARG Q 17 151 ? 133.683 276.000 269.299 1.00 116.45 151 Bj 1 
-ATOM 797  O O   . ARG Q 17 151 ? 133.011 276.780 268.616 1.00 116.45 151 Bj 1 
-ATOM 798  C CB  . ARG Q 17 151 ? 133.432 275.069 271.620 1.00 116.45 151 Bj 1 
-ATOM 799  C CG  . ARG Q 17 151 ? 133.285 276.474 272.176 1.00 116.45 151 Bj 1 
-ATOM 800  C CD  . ARG Q 17 151 ? 133.694 276.533 273.637 1.00 116.45 151 Bj 1 
-ATOM 801  N NE  . ARG Q 17 151 ? 133.681 277.899 274.151 1.00 116.45 151 Bj 1 
-ATOM 802  C CZ  . ARG Q 17 151 ? 133.957 278.225 275.408 1.00 116.45 151 Bj 1 
-ATOM 803  N NH1 . ARG Q 17 151 ? 134.267 277.282 276.287 1.00 116.45 151 Bj 1 
-ATOM 804  N NH2 . ARG Q 17 151 ? 133.923 279.495 275.788 1.00 116.45 151 Bj 1 
-ATOM 805  N N   . LYS Q 17 152 ? 135.011 276.043 269.313 1.00 117.42 152 Bj 1 
-ATOM 806  C CA  . LYS Q 17 152 ? 135.770 277.054 268.591 1.00 117.42 152 Bj 1 
-ATOM 807  C C   . LYS Q 17 152 ? 136.622 276.389 267.521 1.00 117.42 152 Bj 1 
-ATOM 808  O O   . LYS Q 17 152 ? 137.171 275.304 267.735 1.00 117.42 152 Bj 1 
-ATOM 809  C CB  . LYS Q 17 152 ? 136.655 277.866 269.542 1.00 117.42 152 Bj 1 
-ATOM 810  C CG  . LYS Q 17 152 ? 135.879 278.626 270.605 1.00 117.42 152 Bj 1 
-ATOM 811  C CD  . LYS Q 17 152 ? 136.809 279.386 271.538 1.00 117.42 152 Bj 1 
-ATOM 812  C CE  . LYS Q 17 152 ? 136.029 280.083 272.644 1.00 117.42 152 Bj 1 
-ATOM 813  N NZ  . LYS Q 17 152 ? 136.923 280.801 273.593 1.00 117.42 152 Bj 1 
-ATOM 814  N N   . LEU Q 17 153 ? 136.727 277.048 266.368 1.00 116.24 153 Bj 1 
-ATOM 815  C CA  . LEU Q 17 153 ? 137.460 276.511 265.234 1.00 116.24 153 Bj 1 
-ATOM 816  C C   . LEU Q 17 153 ? 138.638 277.371 264.802 1.00 116.24 153 Bj 1 
-ATOM 817  O O   . LEU Q 17 153 ? 139.490 276.883 264.051 1.00 116.24 153 Bj 1 
-ATOM 818  C CB  . LEU Q 17 153 ? 136.518 276.317 264.036 1.00 116.24 153 Bj 1 
-ATOM 819  C CG  . LEU Q 17 153 ? 135.239 275.539 264.342 1.00 116.24 153 Bj 1 
-ATOM 820  C CD1 . LEU Q 17 153 ? 134.370 275.417 263.102 1.00 116.24 153 Bj 1 
-ATOM 821  C CD2 . LEU Q 17 153 ? 135.573 274.168 264.908 1.00 116.24 153 Bj 1 
-ATOM 822  N N   . ASP Q 17 154 ? 138.712 278.626 265.242 1.00 114.21 154 Bj 1 
-ATOM 823  C CA  . ASP Q 17 154 ? 139.819 279.499 264.880 1.00 114.21 154 Bj 1 
-ATOM 824  C C   . ASP Q 17 154 ? 140.864 279.628 265.977 1.00 114.21 154 Bj 1 
-ATOM 825  O O   . ASP Q 17 154 ? 141.912 280.237 265.742 1.00 114.21 154 Bj 1 
-ATOM 826  C CB  . ASP Q 17 154 ? 139.301 280.893 264.510 1.00 114.21 154 Bj 1 
-ATOM 827  C CG  . ASP Q 17 154 ? 138.591 281.574 265.661 1.00 114.21 154 Bj 1 
-ATOM 828  O OD1 . ASP Q 17 154 ? 138.041 280.861 266.526 1.00 114.21 154 Bj 1 
-ATOM 829  O OD2 . ASP Q 17 154 ? 138.580 282.823 265.698 1.00 114.21 154 Bj 1 
-ATOM 830  N N   . ARG Q 17 155 ? 140.614 279.065 267.154 1.00 117.24 155 Bj 1 
-ATOM 831  C CA  . ARG Q 17 155 ? 141.560 279.082 268.258 1.00 117.24 155 Bj 1 
-ATOM 832  C C   . ARG Q 17 155 ? 141.854 277.656 268.702 1.00 117.24 155 Bj 1 
-ATOM 833  O O   . ARG Q 17 155 ? 141.141 276.711 268.356 1.00 117.24 155 Bj 1 
-ATOM 834  C CB  . ARG Q 17 155 ? 141.020 279.897 269.441 1.00 117.24 155 Bj 1 
-ATOM 835  C CG  . ARG Q 17 155 ? 140.581 281.306 269.091 1.00 117.24 155 Bj 1 
-ATOM 836  C CD  . ARG Q 17 155 ? 140.132 282.057 270.334 1.00 117.24 155 Bj 1 
-ATOM 837  N NE  . ARG Q 17 155 ? 139.613 283.382 270.013 1.00 117.24 155 Bj 1 
-ATOM 838  C CZ  . ARG Q 17 155 ? 139.268 284.288 270.921 1.00 117.24 155 Bj 1 
-ATOM 839  N NH1 . ARG Q 17 155 ? 139.392 284.015 272.212 1.00 117.24 155 Bj 1 
-ATOM 840  N NH2 . ARG Q 17 155 ? 138.803 285.469 270.538 1.00 117.24 155 Bj 1 
-ATOM 841  N N   . ASN Q 17 156 ? 142.922 277.508 269.478 1.00 113.83 156 Bj 1 
-ATOM 842  C CA  . ASN Q 17 156 ? 143.233 276.233 270.102 1.00 113.83 156 Bj 1 
-ATOM 843  C C   . ASN Q 17 156 ? 142.516 276.132 271.441 1.00 113.83 156 Bj 1 
-ATOM 844  O O   . ASN Q 17 156 ? 142.286 277.135 272.123 1.00 113.83 156 Bj 1 
-ATOM 845  C CB  . ASN Q 17 156 ? 144.741 276.067 270.300 1.00 113.83 156 Bj 1 
-ATOM 846  C CG  . ASN Q 17 156 ? 145.277 276.908 271.442 1.00 113.83 156 Bj 1 
-ATOM 847  O OD1 . ASN Q 17 156 ? 144.906 278.071 271.601 1.00 113.83 156 Bj 1 
-ATOM 848  N ND2 . ASN Q 17 156 ? 146.154 276.320 272.247 1.00 113.83 156 Bj 1 
-ATOM 849  N N   . LEU Q 17 157 ? 142.156 274.908 271.811 1.00 117.97 157 Bj 1 
-ATOM 850  C CA  . LEU Q 17 157 ? 141.427 274.665 273.045 1.00 117.97 157 Bj 1 
-ATOM 851  C C   . LEU Q 17 157 ? 142.163 273.643 273.900 1.00 117.97 157 Bj 1 
-ATOM 852  O O   . LEU Q 17 157 ? 142.908 272.801 273.397 1.00 117.97 157 Bj 1 
-ATOM 853  C CB  . LEU Q 17 157 ? 139.997 274.188 272.760 1.00 117.97 157 Bj 1 
-ATOM 854  C CG  . LEU Q 17 157 ? 139.112 275.189 272.013 1.00 117.97 157 Bj 1 
-ATOM 855  C CD1 . LEU Q 17 157 ? 137.703 274.642 271.833 1.00 117.97 157 Bj 1 
-ATOM 856  C CD2 . LEU Q 17 157 ? 139.084 276.528 272.733 1.00 117.97 157 Bj 1 
-ATOM 857  N N   . ILE Q 17 158 ? 141.952 273.734 275.213 1.00 113.83 158 Bj 1 
-ATOM 858  C CA  . ILE Q 17 158 ? 142.549 272.815 276.169 1.00 113.83 158 Bj 1 
-ATOM 859  C C   . ILE Q 17 158 ? 141.443 272.284 277.071 1.00 113.83 158 Bj 1 
-ATOM 860  O O   . ILE Q 17 158 ? 140.365 272.871 277.184 1.00 113.83 158 Bj 1 
-ATOM 861  C CB  . ILE Q 17 158 ? 143.669 273.481 276.999 1.00 113.83 158 Bj 1 
-ATOM 862  C CG1 . ILE Q 17 158 ? 144.690 272.440 277.466 1.00 113.83 158 Bj 1 
-ATOM 863  C CG2 . ILE Q 17 158 ? 143.086 274.213 278.188 1.00 113.83 158 Bj 1 
-ATOM 864  C CD1 . ILE Q 17 158 ? 145.859 273.029 278.223 1.00 113.83 158 Bj 1 
-ATOM 865  N N   . LEU Q 17 159 ? 141.723 271.155 277.716 1.00 117.96 159 Bj 1 
-ATOM 866  C CA  . LEU Q 17 159 ? 140.729 270.429 278.495 1.00 117.96 159 Bj 1 
-ATOM 867  C C   . LEU Q 17 159 ? 140.864 270.768 279.973 1.00 117.96 159 Bj 1 
-ATOM 868  O O   . LEU Q 17 159 ? 141.962 270.695 280.535 1.00 117.96 159 Bj 1 
-ATOM 869  C CB  . LEU Q 17 159 ? 140.876 268.922 278.285 1.00 117.96 159 Bj 1 
-ATOM 870  C CG  . LEU Q 17 159 ? 139.756 268.048 278.849 1.00 117.96 159 Bj 1 
-ATOM 871  C CD1 . LEU Q 17 159 ? 138.420 268.435 278.235 1.00 117.96 159 Bj 1 
-ATOM 872  C CD2 . LEU Q 17 159 ? 140.053 266.577 278.608 1.00 117.96 159 Bj 1 
-ATOM 873  N N   . LEU Q 17 160 ? 139.745 271.135 280.597 1.00 129.48 160 Bj 1 
-ATOM 874  C CA  . LEU Q 17 160 ? 139.681 271.396 282.030 1.00 129.48 160 Bj 1 
-ATOM 875  C C   . LEU Q 17 160 ? 138.594 270.526 282.642 1.00 129.48 160 Bj 1 
-ATOM 876  O O   . LEU Q 17 160 ? 137.483 270.456 282.110 1.00 129.48 160 Bj 1 
-ATOM 877  C CB  . LEU Q 17 160 ? 139.396 272.874 282.319 1.00 129.48 160 Bj 1 
-ATOM 878  C CG  . LEU Q 17 160 ? 140.586 273.780 282.641 1.00 129.48 160 Bj 1 
-ATOM 879  C CD1 . LEU Q 17 160 ? 141.302 273.297 283.894 1.00 129.48 160 Bj 1 
-ATOM 880  C CD2 . LEU Q 17 160 ? 141.543 273.865 281.466 1.00 129.48 160 Bj 1 
-ATOM 881  N N   . VAL Q 17 161 ? 138.908 269.869 283.754 1.00 136.87 161 Bj 1 
-ATOM 882  C CA  . VAL Q 17 161 ? 137.973 268.976 284.427 1.00 136.87 161 Bj 1 
-ATOM 883  C C   . VAL Q 17 161 ? 137.583 269.581 285.768 1.00 136.87 161 Bj 1 
-ATOM 884  O O   . VAL Q 17 161 ? 138.402 270.219 286.438 1.00 136.87 161 Bj 1 
-ATOM 885  C CB  . VAL Q 17 161 ? 138.566 267.564 284.611 1.00 136.87 161 Bj 1 
-ATOM 886  C CG1 . VAL Q 17 161 ? 138.693 266.867 283.267 1.00 136.87 161 Bj 1 
-ATOM 887  C CG2 . VAL Q 17 161 ? 139.917 267.637 285.303 1.00 136.87 161 Bj 1 
-ATOM 888  N N   . ARG Q 17 162 ? 136.323 269.392 286.149 1.00 151.13 162 Bj 1 
-ATOM 889  C CA  . ARG Q 17 162 ? 135.837 269.829 287.450 1.00 151.13 162 Bj 1 
-ATOM 890  C C   . ARG Q 17 162 ? 135.852 268.656 288.420 1.00 151.13 162 Bj 1 
-ATOM 891  O O   . ARG Q 17 162 ? 135.243 267.615 288.155 1.00 151.13 162 Bj 1 
-ATOM 892  C CB  . ARG Q 17 162 ? 134.425 270.405 287.339 1.00 151.13 162 Bj 1 
-ATOM 893  C CG  . ARG Q 17 162 ? 133.794 270.771 288.675 1.00 151.13 162 Bj 1 
-ATOM 894  C CD  . ARG Q 17 162 ? 134.649 271.772 289.435 1.00 151.13 162 Bj 1 
-ATOM 895  N NE  . ARG Q 17 162 ? 134.041 272.166 290.702 1.00 151.13 162 Bj 1 
-ATOM 896  C CZ  . ARG Q 17 162 ? 134.595 273.012 291.565 1.00 151.13 162 Bj 1 
-ATOM 897  N NH1 . ARG Q 17 162 ? 135.775 273.556 291.298 1.00 151.13 162 Bj 1 
-ATOM 898  N NH2 . ARG Q 17 162 ? 133.971 273.316 292.694 1.00 151.13 162 Bj 1 
-ATOM 899  N N   . GLU Q 17 163 ? 136.552 268.826 289.540 1.00 162.19 163 Bj 1 
-ATOM 900  C CA  . GLU Q 17 163 ? 136.655 267.786 290.555 1.00 162.19 163 Bj 1 
-ATOM 901  C C   . GLU Q 17 163 ? 136.528 268.410 291.935 1.00 162.19 163 Bj 1 
-ATOM 902  O O   . GLU Q 17 163 ? 137.204 269.398 292.237 1.00 162.19 163 Bj 1 
-ATOM 903  C CB  . GLU Q 17 163 ? 137.981 267.024 290.442 1.00 162.19 163 Bj 1 
-ATOM 904  C CG  . GLU Q 17 163 ? 138.128 266.212 289.165 1.00 162.19 163 Bj 1 
-ATOM 905  C CD  . GLU Q 17 163 ? 139.362 265.332 289.175 1.00 162.19 163 Bj 1 
-ATOM 906  O OE1 . GLU Q 17 163 ? 140.126 265.387 290.161 1.00 162.19 163 Bj 1 
-ATOM 907  O OE2 . GLU Q 17 163 ? 139.566 264.582 288.197 1.00 162.19 163 Bj 1 
-ATOM 908  N N   . LYS Q 17 164 ? 135.663 267.833 292.764 1.00 165.97 164 Bj 1 
-ATOM 909  C CA  . LYS Q 17 164 ? 135.477 268.256 294.149 1.00 165.97 164 Bj 1 
-ATOM 910  C C   . LYS Q 17 164 ? 136.057 267.171 295.050 1.00 165.97 164 Bj 1 
-ATOM 911  O O   . LYS Q 17 164 ? 135.463 266.101 295.210 1.00 165.97 164 Bj 1 
-ATOM 912  C CB  . LYS Q 17 164 ? 134.004 268.509 294.456 1.00 165.97 164 Bj 1 
-ATOM 913  C CG  . LYS Q 17 164 ? 133.424 269.735 293.773 1.00 165.97 164 Bj 1 
-ATOM 914  C CD  . LYS Q 17 164 ? 132.024 270.035 294.284 1.00 165.97 164 Bj 1 
-ATOM 915  C CE  . LYS Q 17 164 ? 131.472 271.312 293.673 1.00 165.97 164 Bj 1 
-ATOM 916  N NZ  . LYS Q 17 164 ? 130.115 271.638 294.195 1.00 165.97 164 Bj 1 
-ATOM 917  N N   . LEU Q 17 165 ? 137.217 267.450 295.636 1.00 168.90 165 Bj 1 
-ATOM 918  C CA  . LEU Q 17 165 ? 137.880 266.496 296.515 1.00 168.90 165 Bj 1 
-ATOM 919  C C   . LEU Q 17 165 ? 137.275 266.587 297.915 1.00 168.90 165 Bj 1 
-ATOM 920  O O   . LEU Q 17 165 ? 136.251 267.238 298.138 1.00 168.90 165 Bj 1 
-ATOM 921  C CB  . LEU Q 17 165 ? 139.386 266.743 296.518 1.00 168.90 165 Bj 1 
-ATOM 922  C CG  . LEU Q 17 165 ? 140.073 266.659 295.154 1.00 168.90 165 Bj 1 
-ATOM 923  C CD1 . LEU Q 17 165 ? 141.578 266.829 295.293 1.00 168.90 165 Bj 1 
-ATOM 924  C CD2 . LEU Q 17 165 ? 139.738 265.346 294.462 1.00 168.90 165 Bj 1 
-ATOM 925  N N   . GLY Q 17 166 ? 137.912 265.927 298.884 1.00 171.61 166 Bj 1 
-ATOM 926  C CA  . GLY Q 17 166 ? 137.369 265.914 300.232 1.00 171.61 166 Bj 1 
-ATOM 927  C C   . GLY Q 17 166 ? 137.561 267.231 300.961 1.00 171.61 166 Bj 1 
-ATOM 928  O O   . GLY Q 17 166 ? 136.656 267.703 301.656 1.00 171.61 166 Bj 1 
-ATOM 929  N N   . ASP Q 17 167 ? 138.736 267.843 300.815 1.00 174.91 167 Bj 1 
-ATOM 930  C CA  . ASP Q 17 167 ? 139.046 269.091 301.495 1.00 174.91 167 Bj 1 
-ATOM 931  C C   . ASP Q 17 167 ? 139.291 270.254 300.545 1.00 174.91 167 Bj 1 
-ATOM 932  O O   . ASP Q 17 167 ? 139.620 271.352 301.010 1.00 174.91 167 Bj 1 
-ATOM 933  C CB  . ASP Q 17 167 ? 140.268 268.910 302.408 1.00 174.91 167 Bj 1 
-ATOM 934  C CG  . ASP Q 17 167 ? 141.477 268.372 301.667 1.00 174.91 167 Bj 1 
-ATOM 935  O OD1 . ASP Q 17 167 ? 142.126 269.149 300.937 1.00 174.91 167 Bj 1 
-ATOM 936  O OD2 . ASP Q 17 167 ? 141.778 267.169 301.815 1.00 174.91 167 Bj 1 
-ATOM 937  N N   . GLN Q 17 168 ? 139.144 270.054 299.236 1.00 175.00 168 Bj 1 
-ATOM 938  C CA  . GLN Q 17 168 ? 139.378 271.108 298.261 1.00 175.00 168 Bj 1 
-ATOM 939  C C   . GLN Q 17 168 ? 138.382 270.985 297.119 1.00 175.00 168 Bj 1 
-ATOM 940  O O   . GLN Q 17 168 ? 138.082 269.879 296.661 1.00 175.00 168 Bj 1 
-ATOM 941  C CB  . GLN Q 17 168 ? 140.810 271.056 297.710 1.00 175.00 168 Bj 1 
-ATOM 942  C CG  . GLN Q 17 168 ? 141.878 271.477 298.705 1.00 175.00 168 Bj 1 
-ATOM 943  C CD  . GLN Q 17 168 ? 143.281 271.320 298.157 1.00 175.00 168 Bj 1 
-ATOM 944  O OE1 . GLN Q 17 168 ? 143.477 270.789 297.063 1.00 175.00 168 Bj 1 
-ATOM 945  N NE2 . GLN Q 17 168 ? 144.267 271.783 298.916 1.00 175.00 168 Bj 1 
-ATOM 946  N N   . ASP Q 17 169 ? 137.876 272.129 296.665 1.00 168.27 169 Bj 1 
-ATOM 947  C CA  . ASP Q 17 169 ? 136.985 272.221 295.510 1.00 168.27 169 Bj 1 
-ATOM 948  C C   . ASP Q 17 169 ? 137.646 273.173 294.517 1.00 168.27 169 Bj 1 
-ATOM 949  O O   . ASP Q 17 169 ? 137.390 274.379 294.534 1.00 168.27 169 Bj 1 
-ATOM 950  C CB  . ASP Q 17 169 ? 135.589 272.706 295.915 1.00 168.27 169 Bj 1 
-ATOM 951  C CG  . ASP Q 17 169 ? 134.950 271.832 296.978 1.00 168.27 169 Bj 1 
-ATOM 952  O OD1 . ASP Q 17 169 ? 135.285 270.631 297.048 1.00 168.27 169 Bj 1 
-ATOM 953  O OD2 . ASP Q 17 169 ? 134.109 272.348 297.743 1.00 168.27 169 Bj 1 
-ATOM 954  N N   . ILE Q 17 170 ? 138.499 272.629 293.653 1.00 159.42 170 Bj 1 
-ATOM 955  C CA  . ILE Q 17 170 ? 139.305 273.423 292.734 1.00 159.42 170 Bj 1 
-ATOM 956  C C   . ILE Q 17 170 ? 138.930 273.073 291.301 1.00 159.42 170 Bj 1 
-ATOM 957  O O   . ILE Q 17 170 ? 138.527 271.941 291.010 1.00 159.42 170 Bj 1 
-ATOM 958  C CB  . ILE Q 17 170 ? 140.815 273.204 292.968 1.00 159.42 170 Bj 1 
-ATOM 959  C CG1 . ILE Q 17 170 ? 141.172 271.723 292.823 1.00 159.42 170 Bj 1 
-ATOM 960  C CG2 . ILE Q 17 170 ? 141.225 273.726 294.336 1.00 159.42 170 Bj 1 
-ATOM 961  C CD1 . ILE Q 17 170 ? 142.645 271.427 293.007 1.00 159.42 170 Bj 1 
-ATOM 962  N N   . TRP Q 17 171 ? 139.059 274.056 290.411 1.00 144.42 171 Bj 1 
-ATOM 963  C CA  . TRP Q 17 171 ? 138.893 273.855 288.972 1.00 144.42 171 Bj 1 
-ATOM 964  C C   . TRP Q 17 171 ? 140.241 273.390 288.437 1.00 144.42 171 Bj 1 
-ATOM 965  O O   . TRP Q 17 171 ? 141.054 274.182 287.960 1.00 144.42 171 Bj 1 
-ATOM 966  C CB  . TRP Q 17 171 ? 138.414 275.138 288.303 1.00 144.42 171 Bj 1 
-ATOM 967  C CG  . TRP Q 17 171 ? 138.043 274.985 286.860 1.00 144.42 171 Bj 1 
-ATOM 968  C CD1 . TRP Q 17 171 ? 138.831 275.252 285.779 1.00 144.42 171 Bj 1 
-ATOM 969  C CD2 . TRP Q 17 171 ? 136.785 274.539 286.340 1.00 144.42 171 Bj 1 
-ATOM 970  N NE1 . TRP Q 17 171 ? 138.144 274.997 284.618 1.00 144.42 171 Bj 1 
-ATOM 971  C CE2 . TRP Q 17 171 ? 136.885 274.557 284.935 1.00 144.42 171 Bj 1 
-ATOM 972  C CE3 . TRP Q 17 171 ? 135.586 274.124 286.925 1.00 144.42 171 Bj 1 
-ATOM 973  C CZ2 . TRP Q 17 171 ? 135.832 274.177 284.106 1.00 144.42 171 Bj 1 
-ATOM 974  C CZ3 . TRP Q 17 171 ? 134.541 273.747 286.101 1.00 144.42 171 Bj 1 
-ATOM 975  C CH2 . TRP Q 17 171 ? 134.672 273.775 284.707 1.00 144.42 171 Bj 1 
-ATOM 976  N N   . MET Q 17 172 ? 140.479 272.086 288.520 1.00 147.69 172 Bj 1 
-ATOM 977  C CA  . MET Q 17 172 ? 141.806 271.514 288.352 1.00 147.69 172 Bj 1 
-ATOM 978  C C   . MET Q 17 172 ? 142.015 270.976 286.940 1.00 147.69 172 Bj 1 
-ATOM 979  O O   . MET Q 17 172 ? 141.082 270.507 286.285 1.00 147.69 172 Bj 1 
-ATOM 980  C CB  . MET Q 17 172 ? 142.030 270.391 289.368 1.00 147.69 172 Bj 1 
-ATOM 981  C CG  . MET Q 17 172 ? 143.468 269.917 289.488 1.00 147.69 172 Bj 1 
-ATOM 982  S SD  . MET Q 17 172 ? 143.610 268.411 290.466 1.00 147.69 172 Bj 1 
-ATOM 983  C CE  . MET Q 17 172 ? 142.770 267.241 289.402 1.00 147.69 172 Bj 1 
-ATOM 984  N N   . LEU Q 17 173 ? 143.260 271.057 286.478 1.00 139.16 173 Bj 1 
-ATOM 985  C CA  . LEU Q 17 173 ? 143.650 270.404 285.241 1.00 139.16 173 Bj 1 
-ATOM 986  C C   . LEU Q 17 173 ? 143.738 268.894 285.468 1.00 139.16 173 Bj 1 
-ATOM 987  O O   . LEU Q 17 173 ? 143.996 268.445 286.588 1.00 139.16 173 Bj 1 
-ATOM 988  C CB  . LEU Q 17 173 ? 144.996 270.950 284.764 1.00 139.16 173 Bj 1 
-ATOM 989  C CG  . LEU Q 17 173 ? 145.334 270.960 283.270 1.00 139.16 173 Bj 1 
-ATOM 990  C CD1 . LEU Q 17 173 ? 144.311 271.766 282.496 1.00 139.16 173 Bj 1 
-ATOM 991  C CD2 . LEU Q 17 173 ? 146.725 271.512 283.037 1.00 139.16 173 Bj 1 
-ATOM 992  N N   . PRO Q 17 174 ? 143.500 268.080 284.423 1.00 136.31 174 Bj 1 
-ATOM 993  C CA  . PRO Q 17 174 ? 143.610 266.621 284.586 1.00 136.31 174 Bj 1 
-ATOM 994  C C   . PRO Q 17 174 ? 144.959 266.176 285.134 1.00 136.31 174 Bj 1 
-ATOM 995  O O   . PRO Q 17 174 ? 146.003 266.377 284.503 1.00 136.31 174 Bj 1 
-ATOM 996  C CB  . PRO Q 17 174 ? 143.377 266.087 283.164 1.00 136.31 174 Bj 1 
-ATOM 997  C CG  . PRO Q 17 174 ? 143.447 267.291 282.257 1.00 136.31 174 Bj 1 
-ATOM 998  C CD  . PRO Q 17 174 ? 142.983 268.434 283.092 1.00 136.31 174 Bj 1 
-ATOM 999  N N   . GLN Q 17 175 ? 144.935 265.578 286.323 1.00 135.35 175 Bj 1 
-ATOM 1000 C CA  . GLN Q 17 175 ? 146.121 265.112 287.030 1.00 135.35 175 Bj 1 
-ATOM 1001 C C   . GLN Q 17 175 ? 146.040 263.602 287.238 1.00 135.35 175 Bj 1 
-ATOM 1002 O O   . GLN Q 17 175 ? 145.028 262.962 286.944 1.00 135.35 175 Bj 1 
-ATOM 1003 C CB  . GLN Q 17 175 ? 146.278 265.834 288.372 1.00 135.35 175 Bj 1 
-ATOM 1004 C CG  . GLN Q 17 175 ? 146.579 267.318 288.255 1.00 135.35 175 Bj 1 
-ATOM 1005 C CD  . GLN Q 17 175 ? 146.837 267.965 289.602 1.00 135.35 175 Bj 1 
-ATOM 1006 O OE1 . GLN Q 17 175 ? 146.707 267.325 290.646 1.00 135.35 175 Bj 1 
-ATOM 1007 N NE2 . GLN Q 17 175 ? 147.204 269.241 289.585 1.00 135.35 175 Bj 1 
-ATOM 1008 N N   . SER Q 17 176 ? 147.130 263.036 287.754 1.00 133.75 176 Bj 1 
-ATOM 1009 C CA  . SER Q 17 176 ? 147.220 261.598 287.965 1.00 133.75 176 Bj 1 
-ATOM 1010 C C   . SER Q 17 176 ? 148.177 261.315 289.116 1.00 133.75 176 Bj 1 
-ATOM 1011 O O   . SER Q 17 176 ? 148.730 262.227 289.736 1.00 133.75 176 Bj 1 
-ATOM 1012 C CB  . SER Q 17 176 ? 147.683 260.882 286.694 1.00 133.75 176 Bj 1 
-ATOM 1013 O OG  . SER Q 17 176 ? 146.894 261.256 285.582 1.00 133.75 176 Bj 1 
-ATOM 1014 N N   . ASP Q 17 177 ? 148.364 260.026 289.395 1.00 134.79 177 Bj 1 
-ATOM 1015 C CA  . ASP Q 17 177 ? 149.341 259.551 290.362 1.00 134.79 177 Bj 1 
-ATOM 1016 C C   . ASP Q 17 177 ? 149.995 258.296 289.806 1.00 134.79 177 Bj 1 
-ATOM 1017 O O   . ASP Q 17 177 ? 149.390 257.559 289.023 1.00 134.79 177 Bj 1 
-ATOM 1018 C CB  . ASP Q 17 177 ? 148.706 259.260 291.728 1.00 134.79 177 Bj 1 
-ATOM 1019 C CG  . ASP Q 17 177 ? 148.221 260.516 292.424 1.00 134.79 177 Bj 1 
-ATOM 1020 O OD1 . ASP Q 17 177 ? 147.166 261.051 292.025 1.00 134.79 177 Bj 1 
-ATOM 1021 O OD2 . ASP Q 17 177 ? 148.898 260.969 293.370 1.00 134.79 177 Bj 1 
-ATOM 1022 N N   . TRP Q 17 178 ? 151.238 258.056 290.216 1.00 142.13 178 Bj 1 
-ATOM 1023 C CA  . TRP Q 17 178 ? 152.031 256.996 289.615 1.00 142.13 178 Bj 1 
-ATOM 1024 C C   . TRP Q 17 178 ? 153.041 256.465 290.620 1.00 142.13 178 Bj 1 
-ATOM 1025 O O   . TRP Q 17 178 ? 153.592 257.217 291.429 1.00 142.13 178 Bj 1 
-ATOM 1026 C CB  . TRP Q 17 178 ? 152.752 257.500 288.360 1.00 142.13 178 Bj 1 
-ATOM 1027 C CG  . TRP Q 17 178 ? 153.556 258.740 288.606 1.00 142.13 178 Bj 1 
-ATOM 1028 C CD1 . TRP Q 17 178 ? 153.092 260.023 288.654 1.00 142.13 178 Bj 1 
-ATOM 1029 C CD2 . TRP Q 17 178 ? 154.966 258.815 288.843 1.00 142.13 178 Bj 1 
-ATOM 1030 N NE1 . TRP Q 17 178 ? 154.126 260.891 288.906 1.00 142.13 178 Bj 1 
-ATOM 1031 C CE2 . TRP Q 17 178 ? 155.287 260.173 289.026 1.00 142.13 178 Bj 1 
-ATOM 1032 C CE3 . TRP Q 17 178 ? 155.987 257.865 288.916 1.00 142.13 178 Bj 1 
-ATOM 1033 C CZ2 . TRP Q 17 178 ? 156.588 260.604 289.277 1.00 142.13 178 Bj 1 
-ATOM 1034 C CZ3 . TRP Q 17 178 ? 157.276 258.293 289.166 1.00 142.13 178 Bj 1 
-ATOM 1035 C CH2 . TRP Q 17 178 ? 157.565 259.650 289.344 1.00 142.13 178 Bj 1 
-ATOM 1036 N N   . GLN Q 17 179 ? 153.282 255.155 290.554 1.00 140.75 179 Bj 1 
-ATOM 1037 C CA  . GLN Q 17 179 ? 154.303 254.528 291.375 1.00 140.75 179 Bj 1 
-ATOM 1038 C C   . GLN Q 17 179 ? 155.685 254.777 290.770 1.00 140.75 179 Bj 1 
-ATOM 1039 O O   . GLN Q 17 179 ? 155.812 254.956 289.556 1.00 140.75 179 Bj 1 
-ATOM 1040 C CB  . GLN Q 17 179 ? 154.047 253.026 291.496 1.00 140.75 179 Bj 1 
-ATOM 1041 C CG  . GLN Q 17 179 ? 154.330 252.219 290.233 1.00 140.75 179 Bj 1 
-ATOM 1042 C CD  . GLN Q 17 179 ? 153.239 252.345 289.187 1.00 140.75 179 Bj 1 
-ATOM 1043 O OE1 . GLN Q 17 179 ? 152.254 253.059 289.380 1.00 140.75 179 Bj 1 
-ATOM 1044 N NE2 . GLN Q 17 179 ? 153.408 251.645 288.072 1.00 140.75 179 Bj 1 
-ATOM 1045 N N   . PRO Q 17 180 ? 156.741 254.792 291.602 1.00 139.20 180 Bj 1 
-ATOM 1046 C CA  . PRO Q 17 180 ? 158.082 255.138 291.101 1.00 139.20 180 Bj 1 
-ATOM 1047 C C   . PRO Q 17 180 ? 158.545 254.295 289.922 1.00 139.20 180 Bj 1 
-ATOM 1048 O O   . PRO Q 17 180 ? 159.406 254.726 289.148 1.00 139.20 180 Bj 1 
-ATOM 1049 C CB  . PRO Q 17 180 ? 158.976 254.914 292.327 1.00 139.20 180 Bj 1 
-ATOM 1050 C CG  . PRO Q 17 180 ? 158.072 255.131 293.486 1.00 139.20 180 Bj 1 
-ATOM 1051 C CD  . PRO Q 17 180 ? 156.734 254.597 293.063 1.00 139.20 180 Bj 1 
-ATOM 1052 N N   . GLY Q 17 181 ? 157.983 253.098 289.770 1.00 135.25 181 Bj 1 
-ATOM 1053 C CA  . GLY Q 17 181 ? 158.324 252.240 288.655 1.00 135.25 181 Bj 1 
-ATOM 1054 C C   . GLY Q 17 181 ? 157.674 252.589 287.337 1.00 135.25 181 Bj 1 
-ATOM 1055 O O   . GLY Q 17 181 ? 157.880 251.875 286.352 1.00 135.25 181 Bj 1 
-ATOM 1056 N N   . GLU Q 17 182 ? 156.897 253.667 287.282 1.00 137.08 182 Bj 1 
-ATOM 1057 C CA  . GLU Q 17 182 ? 156.183 254.062 286.078 1.00 137.08 182 Bj 1 
-ATOM 1058 C C   . GLU Q 17 182 ? 156.697 255.404 285.572 1.00 137.08 182 Bj 1 
-ATOM 1059 O O   . GLU Q 17 182 ? 157.089 256.276 286.354 1.00 137.08 182 Bj 1 
-ATOM 1060 C CB  . GLU Q 17 182 ? 154.675 254.141 286.339 1.00 137.08 182 Bj 1 
-ATOM 1061 C CG  . GLU Q 17 182 ? 153.829 254.307 285.086 1.00 137.08 182 Bj 1 
-ATOM 1062 C CD  . GLU Q 17 182 ? 152.344 254.191 285.367 1.00 137.08 182 Bj 1 
-ATOM 1063 O OE1 . GLU Q 17 182 ? 151.980 253.776 286.487 1.00 137.08 182 Bj 1 
-ATOM 1064 O OE2 . GLU Q 17 182 ? 151.541 254.515 284.466 1.00 137.08 182 Bj 1 
-ATOM 1065 N N   . THR Q 17 183 ? 156.690 255.560 284.252 1.00 130.92 183 Bj 1 
-ATOM 1066 C CA  . THR Q 17 183 ? 157.170 256.770 283.603 1.00 130.92 183 Bj 1 
-ATOM 1067 C C   . THR Q 17 183 ? 156.071 257.827 283.567 1.00 130.92 183 Bj 1 
-ATOM 1068 O O   . THR Q 17 183 ? 154.878 257.512 283.596 1.00 130.92 183 Bj 1 
-ATOM 1069 C CB  . THR Q 17 183 ? 157.647 256.460 282.182 1.00 130.92 183 Bj 1 
-ATOM 1070 O OG1 . THR Q 17 183 ? 158.349 255.210 282.177 1.00 130.92 183 Bj 1 
-ATOM 1071 C CG2 . THR Q 17 183 ? 158.582 257.550 281.671 1.00 130.92 183 Bj 1 
-ATOM 1072 N N   . LEU Q 17 184 ? 156.490 259.094 283.506 1.00 129.02 184 Bj 1 
-ATOM 1073 C CA  . LEU Q 17 184 ? 155.532 260.194 283.444 1.00 129.02 184 Bj 1 
-ATOM 1074 C C   . LEU Q 17 184 ? 154.716 260.147 282.159 1.00 129.02 184 Bj 1 
-ATOM 1075 O O   . LEU Q 17 184 ? 153.502 260.384 282.173 1.00 129.02 184 Bj 1 
-ATOM 1076 C CB  . LEU Q 17 184 ? 156.266 261.528 283.563 1.00 129.02 184 Bj 1 
-ATOM 1077 C CG  . LEU Q 17 184 ? 157.066 261.730 284.849 1.00 129.02 184 Bj 1 
-ATOM 1078 C CD1 . LEU Q 17 184 ? 157.941 262.967 284.754 1.00 129.02 184 Bj 1 
-ATOM 1079 C CD2 . LEU Q 17 184 ? 156.125 261.830 286.034 1.00 129.02 184 Bj 1 
-ATOM 1080 N N   . ARG Q 17 185 ? 155.367 259.842 281.035 1.00 125.72 185 Bj 1 
-ATOM 1081 C CA  . ARG Q 17 185 ? 154.653 259.763 279.767 1.00 125.72 185 Bj 1 
-ATOM 1082 C C   . ARG Q 17 185 ? 153.671 258.598 279.760 1.00 125.72 185 Bj 1 
-ATOM 1083 O O   . ARG Q 17 185 ? 152.540 258.735 279.279 1.00 125.72 185 Bj 1 
-ATOM 1084 C CB  . ARG Q 17 185 ? 155.652 259.644 278.618 1.00 125.72 185 Bj 1 
-ATOM 1085 C CG  . ARG Q 17 185 ? 155.034 259.681 277.235 1.00 125.72 185 Bj 1 
-ATOM 1086 C CD  . ARG Q 17 185 ? 156.064 260.119 276.211 1.00 125.72 185 Bj 1 
-ATOM 1087 N NE  . ARG Q 17 185 ? 155.563 260.025 274.845 1.00 125.72 185 Bj 1 
-ATOM 1088 C CZ  . ARG Q 17 185 ? 156.149 260.598 273.800 1.00 125.72 185 Bj 1 
-ATOM 1089 N NH1 . ARG Q 17 185 ? 157.250 261.316 273.971 1.00 125.72 185 Bj 1 
-ATOM 1090 N NH2 . ARG Q 17 185 ? 155.631 260.462 272.587 1.00 125.72 185 Bj 1 
-ATOM 1091 N N   . GLN Q 17 186 ? 154.083 257.448 280.298 1.00 132.51 186 Bj 1 
-ATOM 1092 C CA  . GLN Q 17 186 ? 153.167 256.318 280.411 1.00 132.51 186 Bj 1 
-ATOM 1093 C C   . GLN Q 17 186 ? 151.994 256.642 281.326 1.00 132.51 186 Bj 1 
-ATOM 1094 O O   . GLN Q 17 186 ? 150.860 256.229 281.055 1.00 132.51 186 Bj 1 
-ATOM 1095 C CB  . GLN Q 17 186 ? 153.914 255.087 280.925 1.00 132.51 186 Bj 1 
-ATOM 1096 C CG  . GLN Q 17 186 ? 155.119 254.696 280.089 1.00 132.51 186 Bj 1 
-ATOM 1097 C CD  . GLN Q 17 186 ? 155.882 253.529 280.683 1.00 132.51 186 Bj 1 
-ATOM 1098 O OE1 . GLN Q 17 186 ? 155.493 252.978 281.713 1.00 132.51 186 Bj 1 
-ATOM 1099 N NE2 . GLN Q 17 186 ? 156.978 253.147 280.037 1.00 132.51 186 Bj 1 
-ATOM 1100 N N   . THR Q 17 187 ? 152.245 257.383 282.408 1.00 131.91 187 Bj 1 
-ATOM 1101 C CA  . THR Q 17 187 ? 151.163 257.778 283.304 1.00 131.91 187 Bj 1 
-ATOM 1102 C C   . THR Q 17 187 ? 150.188 258.718 282.606 1.00 131.91 187 Bj 1 
-ATOM 1103 O O   . THR Q 17 187 ? 148.971 258.593 282.773 1.00 131.91 187 Bj 1 
-ATOM 1104 C CB  . THR Q 17 187 ? 151.737 258.432 284.560 1.00 131.91 187 Bj 1 
-ATOM 1105 O OG1 . THR Q 17 187 ? 152.712 257.561 285.147 1.00 131.91 187 Bj 1 
-ATOM 1106 C CG2 . THR Q 17 187 ? 150.634 258.703 285.570 1.00 131.91 187 Bj 1 
-ATOM 1107 N N   . ALA Q 17 188 ? 150.705 259.659 281.814 1.00 133.19 188 Bj 1 
-ATOM 1108 C CA  . ALA Q 17 188 ? 149.827 260.556 281.066 1.00 133.19 188 Bj 1 
-ATOM 1109 C C   . ALA Q 17 188 ? 149.020 259.794 280.020 1.00 133.19 188 Bj 1 
-ATOM 1110 O O   . ALA Q 17 188 ? 147.848 260.110 279.775 1.00 133.19 188 Bj 1 
-ATOM 1111 C CB  . ALA Q 17 188 ? 150.647 261.666 280.409 1.00 133.19 188 Bj 1 
-ATOM 1112 N N   . GLU Q 17 189 ? 149.632 258.789 279.390 1.00 135.20 189 Bj 1 
-ATOM 1113 C CA  . GLU Q 17 189 ? 148.905 257.958 278.433 1.00 135.20 189 Bj 1 
-ATOM 1114 C C   . GLU Q 17 189 ? 147.783 257.190 279.121 1.00 135.20 189 Bj 1 
-ATOM 1115 O O   . GLU Q 17 189 ? 146.649 257.145 278.628 1.00 135.20 189 Bj 1 
-ATOM 1116 C CB  . GLU Q 17 189 ? 149.869 257.000 277.732 1.00 135.20 189 Bj 1 
-ATOM 1117 C CG  . GLU Q 17 189 ? 150.860 257.688 276.807 1.00 135.20 189 Bj 1 
-ATOM 1118 C CD  . GLU Q 17 189 ? 151.898 256.735 276.247 1.00 135.20 189 Bj 1 
-ATOM 1119 O OE1 . GLU Q 17 189 ? 151.856 255.537 276.598 1.00 135.20 189 Bj 1 
-ATOM 1120 O OE2 . GLU Q 17 189 ? 152.755 257.183 275.457 1.00 135.20 189 Bj 1 
-ATOM 1121 N N   . ARG Q 17 190 ? 148.085 256.576 280.268 1.00 137.16 190 Bj 1 
-ATOM 1122 C CA  . ARG Q 17 190 ? 147.053 255.885 281.035 1.00 137.16 190 Bj 1 
-ATOM 1123 C C   . ARG Q 17 190 ? 145.950 256.847 281.459 1.00 137.16 190 Bj 1 
-ATOM 1124 O O   . ARG Q 17 190 ? 144.768 256.483 281.473 1.00 137.16 190 Bj 1 
-ATOM 1125 C CB  . ARG Q 17 190 ? 147.674 255.206 282.256 1.00 137.16 190 Bj 1 
-ATOM 1126 C CG  . ARG Q 17 190 ? 146.670 254.507 283.159 1.00 137.16 190 Bj 1 
-ATOM 1127 C CD  . ARG Q 17 190 ? 147.358 253.841 284.338 1.00 137.16 190 Bj 1 
-ATOM 1128 N NE  . ARG Q 17 190 ? 148.133 254.792 285.129 1.00 137.16 190 Bj 1 
-ATOM 1129 C CZ  . ARG Q 17 190 ? 147.632 255.522 286.120 1.00 137.16 190 Bj 1 
-ATOM 1130 N NH1 . ARG Q 17 190 ? 146.352 255.413 286.445 1.00 137.16 190 Bj 1 
-ATOM 1131 N NH2 . ARG Q 17 190 ? 148.412 256.362 286.786 1.00 137.16 190 Bj 1 
-ATOM 1132 N N   . THR Q 17 191 ? 146.318 258.084 281.795 1.00 139.17 191 Bj 1 
-ATOM 1133 C CA  . THR Q 17 191 ? 145.327 259.090 282.158 1.00 139.17 191 Bj 1 
-ATOM 1134 C C   . THR Q 17 191 ? 144.388 259.378 280.996 1.00 139.17 191 Bj 1 
-ATOM 1135 O O   . THR Q 17 191 ? 143.164 259.268 281.131 1.00 139.17 191 Bj 1 
-ATOM 1136 C CB  . THR Q 17 191 ? 146.024 260.373 282.606 1.00 139.17 191 Bj 1 
-ATOM 1137 O OG1 . THR Q 17 191 ? 146.894 260.085 283.707 1.00 139.17 191 Bj 1 
-ATOM 1138 C CG2 . THR Q 17 191 ? 144.999 261.416 283.027 1.00 139.17 191 Bj 1 
-ATOM 1139 N N   . LEU Q 17 192 ? 144.945 259.747 279.841 1.00 141.63 192 Bj 1 
-ATOM 1140 C CA  . LEU Q 17 192 ? 144.109 260.056 278.687 1.00 141.63 192 Bj 1 
-ATOM 1141 C C   . LEU Q 17 192 ? 143.341 258.840 278.185 1.00 141.63 192 Bj 1 
-ATOM 1142 O O   . LEU Q 17 192 ? 142.352 259.004 277.463 1.00 141.63 192 Bj 1 
-ATOM 1143 C CB  . LEU Q 17 192 ? 144.956 260.651 277.557 1.00 141.63 192 Bj 1 
-ATOM 1144 C CG  . LEU Q 17 192 ? 146.099 259.830 276.954 1.00 141.63 192 Bj 1 
-ATOM 1145 C CD1 . LEU Q 17 192 ? 145.628 258.957 275.794 1.00 141.63 192 Bj 1 
-ATOM 1146 C CD2 . LEU Q 17 192 ? 147.225 260.747 276.511 1.00 141.63 192 Bj 1 
-ATOM 1147 N N   . ALA Q 17 193 ? 143.770 257.628 278.546 1.00 143.93 193 Bj 1 
-ATOM 1148 C CA  . ALA Q 17 193 ? 143.045 256.438 278.119 1.00 143.93 193 Bj 1 
-ATOM 1149 C C   . ALA Q 17 193 ? 141.916 256.066 279.074 1.00 143.93 193 Bj 1 
-ATOM 1150 O O   . ALA Q 17 193 ? 140.870 255.584 278.626 1.00 143.93 193 Bj 1 
-ATOM 1151 C CB  . ALA Q 17 193 ? 144.010 255.261 277.971 1.00 143.93 193 Bj 1 
-ATOM 1152 N N   . THR Q 17 194 ? 142.098 256.279 280.377 1.00 145.46 194 Bj 1 
-ATOM 1153 C CA  . THR Q 17 194 ? 141.129 255.841 281.375 1.00 145.46 194 Bj 1 
-ATOM 1154 C C   . THR Q 17 194 ? 140.242 256.970 281.888 1.00 145.46 194 Bj 1 
-ATOM 1155 O O   . THR Q 17 194 ? 139.014 256.846 281.870 1.00 145.46 194 Bj 1 
-ATOM 1156 C CB  . THR Q 17 194 ? 141.855 255.179 282.553 1.00 145.46 194 Bj 1 
-ATOM 1157 O OG1 . THR Q 17 194 ? 142.819 256.090 283.094 1.00 145.46 194 Bj 1 
-ATOM 1158 C CG2 . THR Q 17 194 ? 142.563 253.912 282.096 1.00 145.46 194 Bj 1 
-ATOM 1159 N N   . LEU Q 17 195 ? 140.840 258.069 282.358 1.00 142.21 195 Bj 1 
-ATOM 1160 C CA  . LEU Q 17 195 ? 140.050 259.165 282.911 1.00 142.21 195 Bj 1 
-ATOM 1161 C C   . LEU Q 17 195 ? 139.145 259.793 281.860 1.00 142.21 195 Bj 1 
-ATOM 1162 O O   . LEU Q 17 195 ? 138.038 260.239 282.181 1.00 142.21 195 Bj 1 
-ATOM 1163 C CB  . LEU Q 17 195 ? 140.968 260.229 283.517 1.00 142.21 195 Bj 1 
-ATOM 1164 C CG  . LEU Q 17 195 ? 141.597 259.972 284.891 1.00 142.21 195 Bj 1 
-ATOM 1165 C CD1 . LEU Q 17 195 ? 142.698 258.923 284.829 1.00 142.21 195 Bj 1 
-ATOM 1166 C CD2 . LEU Q 17 195 ? 142.128 261.271 285.480 1.00 142.21 195 Bj 1 
-ATOM 1167 N N   . SER Q 17 196 ? 139.594 259.839 280.604 1.00 140.98 196 Bj 1 
-ATOM 1168 C CA  . SER Q 17 196 ? 138.776 260.410 279.541 1.00 140.98 196 Bj 1 
-ATOM 1169 C C   . SER Q 17 196 ? 137.616 259.503 279.154 1.00 140.98 196 Bj 1 
-ATOM 1170 O O   . SER Q 17 196 ? 136.610 259.998 278.635 1.00 140.98 196 Bj 1 
-ATOM 1171 C CB  . SER Q 17 196 ? 139.642 260.710 278.317 1.00 140.98 196 Bj 1 
-ATOM 1172 O OG  . SER Q 17 196 ? 138.870 261.273 277.272 1.00 140.98 196 Bj 1 
-ATOM 1173 N N   . GLU Q 17 197 ? 137.739 258.194 279.389 1.00 135.62 197 Bj 1 
-ATOM 1174 C CA  . GLU Q 17 197 ? 136.656 257.236 279.156 1.00 135.62 197 Bj 1 
-ATOM 1175 C C   . GLU Q 17 197 ? 136.208 257.234 277.696 1.00 135.62 197 Bj 1 
-ATOM 1176 O O   . GLU Q 17 197 ? 135.013 257.193 277.396 1.00 135.62 197 Bj 1 
-ATOM 1177 C CB  . GLU Q 17 197 ? 135.470 257.510 280.085 1.00 135.62 197 Bj 1 
-ATOM 1178 C CG  . GLU Q 17 197 ? 135.840 257.617 281.554 1.00 135.62 197 Bj 1 
-ATOM 1179 C CD  . GLU Q 17 197 ? 134.680 258.079 282.413 1.00 135.62 197 Bj 1 
-ATOM 1180 O OE1 . GLU Q 17 197 ? 133.581 258.302 281.863 1.00 135.62 197 Bj 1 
-ATOM 1181 O OE2 . GLU Q 17 197 ? 134.868 258.222 283.639 1.00 135.62 197 Bj 1 
-ATOM 1182 N N   . ASN Q 17 198 ? 137.171 257.276 276.779 1.00 129.66 198 Bj 1 
-ATOM 1183 C CA  . ASN Q 17 198 ? 136.857 257.290 275.358 1.00 129.66 198 Bj 1 
-ATOM 1184 C C   . ASN Q 17 198 ? 138.089 256.875 274.568 1.00 129.66 198 Bj 1 
-ATOM 1185 O O   . ASN Q 17 198 ? 139.210 256.881 275.082 1.00 129.66 198 Bj 1 
-ATOM 1186 C CB  . ASN Q 17 198 ? 136.372 258.671 274.903 1.00 129.66 198 Bj 1 
-ATOM 1187 C CG  . ASN Q 17 198 ? 137.500 259.681 274.800 1.00 129.66 198 Bj 1 
-ATOM 1188 O OD1 . ASN Q 17 198 ? 138.430 259.675 275.605 1.00 129.66 198 Bj 1 
-ATOM 1189 N ND2 . ASN Q 17 198 ? 137.425 260.552 273.801 1.00 129.66 198 Bj 1 
-ATOM 1190 N N   . ASN Q 17 199 ? 137.862 256.515 273.307 1.00 121.02 199 Bj 1 
-ATOM 1191 C CA  . ASN Q 17 199 ? 138.944 256.208 272.374 1.00 121.02 199 Bj 1 
-ATOM 1192 C C   . ASN Q 17 199 ? 139.384 257.519 271.734 1.00 121.02 199 Bj 1 
-ATOM 1193 O O   . ASN Q 17 199 ? 138.711 258.055 270.850 1.00 121.02 199 Bj 1 
-ATOM 1194 C CB  . ASN Q 17 199 ? 138.496 255.185 271.335 1.00 121.02 199 Bj 1 
-ATOM 1195 C CG  . ASN Q 17 199 ? 137.204 255.577 270.646 1.00 121.02 199 Bj 1 
-ATOM 1196 O OD1 . ASN Q 17 199 ? 136.405 256.339 271.189 1.00 121.02 199 Bj 1 
-ATOM 1197 N ND2 . ASN Q 17 199 ? 136.993 255.057 269.443 1.00 121.02 199 Bj 1 
-ATOM 1198 N N   . MET Q 17 200 ? 140.516 258.044 272.190 1.00 123.96 200 Bj 1 
-ATOM 1199 C CA  . MET Q 17 200 ? 141.014 259.341 271.760 1.00 123.96 200 Bj 1 
-ATOM 1200 C C   . MET Q 17 200 ? 142.451 259.205 271.279 1.00 123.96 200 Bj 1 
-ATOM 1201 O O   . MET Q 17 200 ? 143.258 258.501 271.895 1.00 123.96 200 Bj 1 
-ATOM 1202 C CB  . MET Q 17 200 ? 140.927 260.358 272.901 1.00 123.96 200 Bj 1 
-ATOM 1203 C CG  . MET Q 17 200 ? 141.315 261.768 272.517 1.00 123.96 200 Bj 1 
-ATOM 1204 S SD  . MET Q 17 200 ? 141.001 262.928 273.857 1.00 123.96 200 Bj 1 
-ATOM 1205 C CE  . MET Q 17 200 ? 141.986 262.202 275.165 1.00 123.96 200 Bj 1 
-ATOM 1206 N N   . GLU Q 17 201 ? 142.767 259.880 270.176 1.00 115.66 201 Bj 1 
-ATOM 1207 C CA  . GLU Q 17 201 ? 144.092 259.821 269.570 1.00 115.66 201 Bj 1 
-ATOM 1208 C C   . GLU Q 17 201 ? 144.889 261.040 270.022 1.00 115.66 201 Bj 1 
-ATOM 1209 O O   . GLU Q 17 201 ? 144.619 262.164 269.586 1.00 115.66 201 Bj 1 
-ATOM 1210 C CB  . GLU Q 17 201 ? 143.988 259.759 268.048 1.00 115.66 201 Bj 1 
-ATOM 1211 C CG  . GLU Q 17 201 ? 143.149 258.601 267.531 1.00 115.66 201 Bj 1 
-ATOM 1212 C CD  . GLU Q 17 201 ? 143.120 258.531 266.017 1.00 115.66 201 Bj 1 
-ATOM 1213 O OE1 . GLU Q 17 201 ? 143.950 259.207 265.373 1.00 115.66 201 Bj 1 
-ATOM 1214 O OE2 . GLU Q 17 201 ? 142.265 257.803 265.470 1.00 115.66 201 Bj 1 
-ATOM 1215 N N   . ALA Q 17 202 ? 145.869 260.814 270.892 1.00 117.10 202 Bj 1 
-ATOM 1216 C CA  . ALA Q 17 202 ? 146.717 261.870 271.422 1.00 117.10 202 Bj 1 
-ATOM 1217 C C   . ALA Q 17 202 ? 148.131 261.723 270.876 1.00 117.10 202 Bj 1 
-ATOM 1218 O O   . ALA Q 17 202 ? 148.651 260.609 270.767 1.00 117.10 202 Bj 1 
-ATOM 1219 C CB  . ALA Q 17 202 ? 146.744 261.840 272.952 1.00 117.10 202 Bj 1 
-ATOM 1220 N N   . LYS Q 17 203 ? 148.748 262.853 270.539 1.00 120.82 203 Bj 1 
-ATOM 1221 C CA  . LYS Q 17 203 ? 150.096 262.887 269.981 1.00 120.82 203 Bj 1 
-ATOM 1222 C C   . LYS Q 17 203 ? 150.986 263.704 270.910 1.00 120.82 203 Bj 1 
-ATOM 1223 O O   . LYS Q 17 203 ? 150.846 264.929 270.994 1.00 120.82 203 Bj 1 
-ATOM 1224 C CB  . LYS Q 17 203 ? 150.087 263.476 268.572 1.00 120.82 203 Bj 1 
-ATOM 1225 C CG  . LYS Q 17 203 ? 151.408 263.346 267.834 1.00 120.82 203 Bj 1 
-ATOM 1226 C CD  . LYS Q 17 203 ? 151.757 261.888 267.591 1.00 120.82 203 Bj 1 
-ATOM 1227 C CE  . LYS Q 17 203 ? 153.066 261.752 266.833 1.00 120.82 203 Bj 1 
-ATOM 1228 N NZ  . LYS Q 17 203 ? 153.409 260.327 266.571 1.00 120.82 203 Bj 1 
-ATOM 1229 N N   . PHE Q 17 204 ? 151.897 263.028 271.606 1.00 125.72 204 Bj 1 
-ATOM 1230 C CA  . PHE Q 17 204 ? 152.832 263.707 272.490 1.00 125.72 204 Bj 1 
-ATOM 1231 C C   . PHE Q 17 204 ? 153.972 264.322 271.689 1.00 125.72 204 Bj 1 
-ATOM 1232 O O   . PHE Q 17 204 ? 154.445 263.744 270.707 1.00 125.72 204 Bj 1 
-ATOM 1233 C CB  . PHE Q 17 204 ? 153.391 262.739 273.531 1.00 125.72 204 Bj 1 
-ATOM 1234 C CG  . PHE Q 17 204 ? 152.415 262.383 274.614 1.00 125.72 204 Bj 1 
-ATOM 1235 C CD1 . PHE Q 17 204 ? 151.538 261.325 274.454 1.00 125.72 204 Bj 1 
-ATOM 1236 C CD2 . PHE Q 17 204 ? 152.379 263.106 275.795 1.00 125.72 204 Bj 1 
-ATOM 1237 C CE1 . PHE Q 17 204 ? 150.641 260.996 275.451 1.00 125.72 204 Bj 1 
-ATOM 1238 C CE2 . PHE Q 17 204 ? 151.484 262.782 276.795 1.00 125.72 204 Bj 1 
-ATOM 1239 C CZ  . PHE Q 17 204 ? 150.615 261.725 276.624 1.00 125.72 204 Bj 1 
-ATOM 1240 N N   . LEU Q 17 205 ? 154.414 265.504 272.120 1.00 121.24 205 Bj 1 
-ATOM 1241 C CA  . LEU Q 17 205 ? 155.467 266.215 271.402 1.00 121.24 205 Bj 1 
-ATOM 1242 C C   . LEU Q 17 205 ? 156.851 265.713 271.799 1.00 121.24 205 Bj 1 
-ATOM 1243 O O   . LEU Q 17 205 ? 157.602 265.202 270.961 1.00 121.24 205 Bj 1 
-ATOM 1244 C CB  . LEU Q 17 205 ? 155.344 267.719 271.658 1.00 121.24 205 Bj 1 
-ATOM 1245 C CG  . LEU Q 17 205 ? 153.967 268.330 271.399 1.00 121.24 205 Bj 1 
-ATOM 1246 C CD1 . LEU Q 17 205 ? 153.973 269.814 271.724 1.00 121.24 205 Bj 1 
-ATOM 1247 C CD2 . LEU Q 17 205 ? 153.536 268.092 269.962 1.00 121.24 205 Bj 1 
-ATOM 1248 N N   . GLY Q 17 206 ? 157.202 265.847 273.070 1.00 130.10 206 Bj 1 
-ATOM 1249 C CA  . GLY Q 17 206 ? 158.515 265.444 273.539 1.00 130.10 206 Bj 1 
-ATOM 1250 C C   . GLY Q 17 206 ? 158.419 264.700 274.853 1.00 130.10 206 Bj 1 
-ATOM 1251 O O   . GLY Q 17 206 ? 157.446 264.831 275.598 1.00 130.10 206 Bj 1 
-ATOM 1252 N N   . ASN Q 17 207 ? 159.458 263.909 275.133 1.00 132.28 207 Bj 1 
-ATOM 1253 C CA  . ASN Q 17 207 ? 159.476 263.119 276.359 1.00 132.28 207 Bj 1 
-ATOM 1254 C C   . ASN Q 17 207 ? 159.764 263.982 277.581 1.00 132.28 207 Bj 1 
-ATOM 1255 O O   . ASN Q 17 207 ? 159.380 263.618 278.699 1.00 132.28 207 Bj 1 
-ATOM 1256 C CB  . ASN Q 17 207 ? 160.510 261.999 276.242 1.00 132.28 207 Bj 1 
-ATOM 1257 C CG  . ASN Q 17 207 ? 160.456 261.029 277.405 1.00 132.28 207 Bj 1 
-ATOM 1258 O OD1 . ASN Q 17 207 ? 159.414 260.859 278.039 1.00 132.28 207 Bj 1 
-ATOM 1259 N ND2 . ASN Q 17 207 ? 161.581 260.384 277.690 1.00 132.28 207 Bj 1 
-ATOM 1260 N N   . ALA Q 17 208 ? 160.429 265.117 277.395 1.00 129.27 208 Bj 1 
-ATOM 1261 C CA  . ALA Q 17 208 ? 160.739 265.987 278.515 1.00 129.27 208 Bj 1 
-ATOM 1262 C C   . ALA Q 17 208 ? 159.476 266.692 279.008 1.00 129.27 208 Bj 1 
-ATOM 1263 O O   . ALA Q 17 208 ? 158.549 266.940 278.230 1.00 129.27 208 Bj 1 
-ATOM 1264 C CB  . ALA Q 17 208 ? 161.789 267.020 278.115 1.00 129.27 208 Bj 1 
-ATOM 1265 N N   . PRO Q 17 209 ? 159.410 267.019 280.299 1.00 132.17 209 Bj 1 
-ATOM 1266 C CA  . PRO Q 17 209 ? 158.236 267.726 280.821 1.00 132.17 209 Bj 1 
-ATOM 1267 C C   . PRO Q 17 209 ? 158.110 269.117 280.221 1.00 132.17 209 Bj 1 
-ATOM 1268 O O   . PRO Q 17 209 ? 159.065 269.686 279.688 1.00 132.17 209 Bj 1 
-ATOM 1269 C CB  . PRO Q 17 209 ? 158.499 267.795 282.331 1.00 132.17 209 Bj 1 
-ATOM 1270 C CG  . PRO Q 17 209 ? 159.515 266.734 282.598 1.00 132.17 209 Bj 1 
-ATOM 1271 C CD  . PRO Q 17 209 ? 160.359 266.661 281.366 1.00 132.17 209 Bj 1 
-ATOM 1272 N N   . CYS Q 17 210 ? 156.902 269.668 280.318 1.00 129.55 210 Bj 1 
-ATOM 1273 C CA  . CYS Q 17 210 ? 156.616 271.006 279.817 1.00 129.55 210 Bj 1 
-ATOM 1274 C C   . CYS Q 17 210 ? 156.563 272.051 280.922 1.00 129.55 210 Bj 1 
-ATOM 1275 O O   . CYS Q 17 210 ? 156.967 273.196 280.703 1.00 129.55 210 Bj 1 
-ATOM 1276 C CB  . CYS Q 17 210 ? 155.294 271.012 279.044 1.00 129.55 210 Bj 1 
-ATOM 1277 S SG  . CYS Q 17 210 ? 155.139 269.674 277.842 1.00 129.55 210 Bj 1 
-ATOM 1278 N N   . GLY Q 17 211 ? 156.076 271.687 282.100 1.00 136.75 211 Bj 1 
-ATOM 1279 C CA  . GLY Q 17 211 ? 156.066 272.608 283.225 1.00 136.75 211 Bj 1 
-ATOM 1280 C C   . GLY Q 17 211 ? 156.247 271.868 284.528 1.00 136.75 211 Bj 1 
-ATOM 1281 O O   . GLY Q 17 211 ? 155.885 270.695 284.650 1.00 136.75 211 Bj 1 
-ATOM 1282 N N   . HIS Q 17 212 ? 156.808 272.561 285.516 1.00 134.65 212 Bj 1 
-ATOM 1283 C CA  . HIS Q 17 212 ? 157.023 272.000 286.842 1.00 134.65 212 Bj 1 
-ATOM 1284 C C   . HIS Q 17 212 ? 156.523 272.973 287.897 1.00 134.65 212 Bj 1 
-ATOM 1285 O O   . HIS Q 17 212 ? 156.786 274.177 287.812 1.00 134.65 212 Bj 1 
-ATOM 1286 C CB  . HIS Q 17 212 ? 158.502 271.694 287.090 1.00 134.65 212 Bj 1 
-ATOM 1287 C CG  . HIS Q 17 212 ? 158.933 270.348 286.601 1.00 134.65 212 Bj 1 
-ATOM 1288 N ND1 . HIS Q 17 212 ? 159.905 269.605 287.236 1.00 134.65 212 Bj 1 
-ATOM 1289 C CD2 . HIS Q 17 212 ? 158.530 269.612 285.539 1.00 134.65 212 Bj 1 
-ATOM 1290 C CE1 . HIS Q 17 212 ? 160.079 268.468 286.587 1.00 134.65 212 Bj 1 
-ATOM 1291 N NE2 . HIS Q 17 212 ? 159.258 268.447 285.553 1.00 134.65 212 Bj 1 
-ATOM 1292 N N   . TYR Q 17 213 ? 155.805 272.454 288.892 1.00 135.25 213 Bj 1 
-ATOM 1293 C CA  . TYR Q 17 213 ? 155.323 273.300 289.979 1.00 135.25 213 Bj 1 
-ATOM 1294 C C   . TYR Q 17 213 ? 155.377 272.542 291.296 1.00 135.25 213 Bj 1 
-ATOM 1295 O O   . TYR Q 17 213 ? 154.938 271.392 291.372 1.00 135.25 213 Bj 1 
-ATOM 1296 C CB  . TYR Q 17 213 ? 153.896 273.793 289.707 1.00 135.25 213 Bj 1 
-ATOM 1297 C CG  . TYR Q 17 213 ? 153.785 274.683 288.490 1.00 135.25 213 Bj 1 
-ATOM 1298 C CD1 . TYR Q 17 213 ? 153.974 276.055 288.588 1.00 135.25 213 Bj 1 
-ATOM 1299 C CD2 . TYR Q 17 213 ? 153.497 274.151 287.241 1.00 135.25 213 Bj 1 
-ATOM 1300 C CE1 . TYR Q 17 213 ? 153.875 276.870 287.476 1.00 135.25 213 Bj 1 
-ATOM 1301 C CE2 . TYR Q 17 213 ? 153.395 274.957 286.125 1.00 135.25 213 Bj 1 
-ATOM 1302 C CZ  . TYR Q 17 213 ? 153.585 276.315 286.248 1.00 135.25 213 Bj 1 
-ATOM 1303 O OH  . TYR Q 17 213 ? 153.485 277.120 285.137 1.00 135.25 213 Bj 1 
-ATOM 1304 N N   . LYS Q 17 214 ? 155.902 273.189 292.333 1.00 138.67 214 Bj 1 
-ATOM 1305 C CA  . LYS Q 17 214 ? 156.024 272.582 293.650 1.00 138.67 214 Bj 1 
-ATOM 1306 C C   . LYS Q 17 214 ? 155.177 273.334 294.667 1.00 138.67 214 Bj 1 
-ATOM 1307 O O   . LYS Q 17 214 ? 154.975 274.547 294.559 1.00 138.67 214 Bj 1 
-ATOM 1308 C CB  . LYS Q 17 214 ? 157.483 272.554 294.123 1.00 138.67 214 Bj 1 
-ATOM 1309 C CG  . LYS Q 17 214 ? 158.319 271.446 293.510 1.00 138.67 214 Bj 1 
-ATOM 1310 C CD  . LYS Q 17 214 ? 159.715 271.422 294.112 1.00 138.67 214 Bj 1 
-ATOM 1311 C CE  . LYS Q 17 214 ? 160.537 270.265 293.567 1.00 138.67 214 Bj 1 
-ATOM 1312 N NZ  . LYS Q 17 214 ? 159.905 268.949 293.855 1.00 138.67 214 Bj 1 
-ATOM 1313 N N   . PHE Q 17 215 ? 154.684 272.594 295.658 1.00 143.45 215 Bj 1 
-ATOM 1314 C CA  . PHE Q 17 215 ? 153.944 273.179 296.769 1.00 143.45 215 Bj 1 
-ATOM 1315 C C   . PHE Q 17 215 ? 154.171 272.332 298.012 1.00 143.45 215 Bj 1 
-ATOM 1316 O O   . PHE Q 17 215 ? 154.077 271.103 297.954 1.00 143.45 215 Bj 1 
-ATOM 1317 C CB  . PHE Q 17 215 ? 152.446 273.293 296.456 1.00 143.45 215 Bj 1 
-ATOM 1318 C CG  . PHE Q 17 215 ? 151.816 272.015 295.975 1.00 143.45 215 Bj 1 
-ATOM 1319 C CD1 . PHE Q 17 215 ? 151.873 271.659 294.637 1.00 143.45 215 Bj 1 
-ATOM 1320 C CD2 . PHE Q 17 215 ? 151.143 271.185 296.855 1.00 143.45 215 Bj 1 
-ATOM 1321 C CE1 . PHE Q 17 215 ? 151.287 270.489 294.190 1.00 143.45 215 Bj 1 
-ATOM 1322 C CE2 . PHE Q 17 215 ? 150.553 270.015 296.414 1.00 143.45 215 Bj 1 
-ATOM 1323 C CZ  . PHE Q 17 215 ? 150.626 269.667 295.079 1.00 143.45 215 Bj 1 
-ATOM 1324 N N   . LYS Q 17 216 ? 154.477 272.988 299.126 1.00 149.62 216 Bj 1 
-ATOM 1325 C CA  . LYS Q 17 216 ? 154.790 272.310 300.375 1.00 149.62 216 Bj 1 
-ATOM 1326 C C   . LYS Q 17 216 ? 153.709 272.593 301.408 1.00 149.62 216 Bj 1 
-ATOM 1327 O O   . LYS Q 17 216 ? 153.137 273.687 301.440 1.00 149.62 216 Bj 1 
-ATOM 1328 C CB  . LYS Q 17 216 ? 156.158 272.749 300.906 1.00 149.62 216 Bj 1 
-ATOM 1329 C CG  . LYS Q 17 216 ? 157.300 272.479 299.940 1.00 149.62 216 Bj 1 
-ATOM 1330 C CD  . LYS Q 17 216 ? 158.639 272.904 300.519 1.00 149.62 216 Bj 1 
-ATOM 1331 C CE  . LYS Q 17 216 ? 159.771 272.621 299.544 1.00 149.62 216 Bj 1 
-ATOM 1332 N NZ  . LYS Q 17 216 ? 161.098 272.996 300.105 1.00 149.62 216 Bj 1 
-ATOM 1333 N N   . PHE Q 17 217 ? 153.435 271.602 302.250 1.00 143.58 217 Bj 1 
-ATOM 1334 C CA  . PHE Q 17 217 ? 152.407 271.732 303.275 1.00 143.58 217 Bj 1 
-ATOM 1335 C C   . PHE Q 17 217 ? 153.018 272.091 304.624 1.00 143.58 217 Bj 1 
-ATOM 1336 O O   . PHE Q 17 217 ? 152.899 271.339 305.590 1.00 143.58 217 Bj 1 
-ATOM 1337 C CB  . PHE Q 17 217 ? 151.599 270.437 303.392 1.00 143.58 217 Bj 1 
-ATOM 1338 C CG  . PHE Q 17 217 ? 150.831 270.087 302.150 1.00 143.58 217 Bj 1 
-ATOM 1339 C CD1 . PHE Q 17 217 ? 150.463 271.069 301.245 1.00 143.58 217 Bj 1 
-ATOM 1340 C CD2 . PHE Q 17 217 ? 150.477 268.774 301.886 1.00 143.58 217 Bj 1 
-ATOM 1341 C CE1 . PHE Q 17 217 ? 149.756 270.748 300.101 1.00 143.58 217 Bj 1 
-ATOM 1342 C CE2 . PHE Q 17 217 ? 149.771 268.447 300.744 1.00 143.58 217 Bj 1 
-ATOM 1343 C CZ  . PHE Q 17 217 ? 149.410 269.435 299.851 1.00 143.58 217 Bj 1 
-ATOM 1344 N N   . LEU Q 17 227 ? 157.135 268.148 304.312 1.00 125.05 227 Bj 1 
-ATOM 1345 C CA  . LEU Q 17 227 ? 156.195 267.564 303.362 1.00 125.05 227 Bj 1 
-ATOM 1346 C C   . LEU Q 17 227 ? 156.009 268.470 302.151 1.00 125.05 227 Bj 1 
-ATOM 1347 O O   . LEU Q 17 227 ? 155.534 269.599 302.277 1.00 125.05 227 Bj 1 
-ATOM 1348 C CB  . LEU Q 17 227 ? 154.846 267.299 304.034 1.00 125.05 227 Bj 1 
-ATOM 1349 C CG  . LEU Q 17 227 ? 153.726 266.761 303.141 1.00 125.05 227 Bj 1 
-ATOM 1350 C CD1 . LEU Q 17 227 ? 154.132 265.448 302.492 1.00 125.05 227 Bj 1 
-ATOM 1351 C CD2 . LEU Q 17 227 ? 152.443 266.591 303.938 1.00 125.05 227 Bj 1 
-ATOM 1352 N N   . GLY Q 17 228 ? 156.388 267.969 300.971 1.00 128.22 228 Bj 1 
-ATOM 1353 C CA  . GLY Q 17 228 ? 156.244 268.718 299.745 1.00 128.22 228 Bj 1 
-ATOM 1354 C C   . GLY Q 17 228 ? 155.646 267.856 298.647 1.00 128.22 228 Bj 1 
-ATOM 1355 O O   . GLY Q 17 228 ? 155.531 266.635 298.775 1.00 128.22 228 Bj 1 
-ATOM 1356 N N   . ALA Q 17 229 ? 155.272 268.518 297.555 1.00 135.59 229 Bj 1 
-ATOM 1357 C CA  . ALA Q 17 229 ? 154.709 267.825 296.410 1.00 135.59 229 Bj 1 
-ATOM 1358 C C   . ALA Q 17 229 ? 155.086 268.574 295.142 1.00 135.59 229 Bj 1 
-ATOM 1359 O O   . ALA Q 17 229 ? 155.273 269.793 295.151 1.00 135.59 229 Bj 1 
-ATOM 1360 C CB  . ALA Q 17 229 ? 153.186 267.691 296.522 1.00 135.59 229 Bj 1 
-ATOM 1361 N N   . LYS Q 17 230 ? 155.195 267.821 294.052 1.00 134.09 230 Bj 1 
-ATOM 1362 C CA  . LYS Q 17 230 ? 155.610 268.330 292.755 1.00 134.09 230 Bj 1 
-ATOM 1363 C C   . LYS Q 17 230 ? 154.658 267.812 291.689 1.00 134.09 230 Bj 1 
-ATOM 1364 O O   . LYS Q 17 230 ? 154.215 266.660 291.748 1.00 134.09 230 Bj 1 
-ATOM 1365 C CB  . LYS Q 17 230 ? 157.044 267.900 292.437 1.00 134.09 230 Bj 1 
-ATOM 1366 C CG  . LYS Q 17 230 ? 157.266 266.407 292.605 1.00 134.09 230 Bj 1 
-ATOM 1367 C CD  . LYS Q 17 230 ? 158.738 266.053 292.685 1.00 134.09 230 Bj 1 
-ATOM 1368 C CE  . LYS Q 17 230 ? 158.919 264.566 292.931 1.00 134.09 230 Bj 1 
-ATOM 1369 N NZ  . LYS Q 17 230 ? 158.240 264.126 294.181 1.00 134.09 230 Bj 1 
-ATOM 1370 N N   . VAL Q 17 231 ? 154.339 268.668 290.723 1.00 135.01 231 Bj 1 
-ATOM 1371 C CA  . VAL Q 17 231 ? 153.447 268.325 289.624 1.00 135.01 231 Bj 1 
-ATOM 1372 C C   . VAL Q 17 231 ? 154.143 268.676 288.317 1.00 135.01 231 Bj 1 
-ATOM 1373 O O   . VAL Q 17 231 ? 154.717 269.766 288.179 1.00 135.01 231 Bj 1 
-ATOM 1374 C CB  . VAL Q 17 231 ? 152.083 269.037 289.740 1.00 135.01 231 Bj 1 
-ATOM 1375 C CG1 . VAL Q 17 231 ? 152.256 270.540 289.888 1.00 135.01 231 Bj 1 
-ATOM 1376 C CG2 . VAL Q 17 231 ? 151.200 268.706 288.544 1.00 135.01 231 Bj 1 
-ATOM 1377 N N   . PHE Q 17 232 ? 154.109 267.736 287.371 1.00 135.12 232 Bj 1 
-ATOM 1378 C CA  . PHE Q 17 232 ? 154.776 267.856 286.079 1.00 135.12 232 Bj 1 
-ATOM 1379 C C   . PHE Q 17 232 ? 153.708 267.897 284.994 1.00 135.12 232 Bj 1 
-ATOM 1380 O O   . PHE Q 17 232 ? 152.998 266.910 284.777 1.00 135.12 232 Bj 1 
-ATOM 1381 C CB  . PHE Q 17 232 ? 155.736 266.691 285.848 1.00 135.12 232 Bj 1 
-ATOM 1382 C CG  . PHE Q 17 232 ? 156.600 266.370 287.032 1.00 135.12 232 Bj 1 
-ATOM 1383 C CD1 . PHE Q 17 232 ? 157.175 267.378 287.786 1.00 135.12 232 Bj 1 
-ATOM 1384 C CD2 . PHE Q 17 232 ? 156.831 265.055 287.394 1.00 135.12 232 Bj 1 
-ATOM 1385 C CE1 . PHE Q 17 232 ? 157.968 267.079 288.875 1.00 135.12 232 Bj 1 
-ATOM 1386 C CE2 . PHE Q 17 232 ? 157.623 264.749 288.481 1.00 135.12 232 Bj 1 
-ATOM 1387 C CZ  . PHE Q 17 232 ? 158.192 265.763 289.223 1.00 135.12 232 Bj 1 
-ATOM 1388 N N   . PHE Q 17 233 ? 153.597 269.034 284.318 1.00 138.91 233 Bj 1 
-ATOM 1389 C CA  . PHE Q 17 233 ? 152.629 269.220 283.246 1.00 138.91 233 Bj 1 
-ATOM 1390 C C   . PHE Q 17 233 ? 153.266 268.835 281.917 1.00 138.91 233 Bj 1 
-ATOM 1391 O O   . PHE Q 17 233 ? 154.289 269.410 281.525 1.00 138.91 233 Bj 1 
-ATOM 1392 C CB  . PHE Q 17 233 ? 152.141 270.667 283.211 1.00 138.91 233 Bj 1 
-ATOM 1393 C CG  . PHE Q 17 233 ? 151.342 271.064 284.416 1.00 138.91 233 Bj 1 
-ATOM 1394 C CD1 . PHE Q 17 233 ? 151.971 271.457 285.584 1.00 138.91 233 Bj 1 
-ATOM 1395 C CD2 . PHE Q 17 233 ? 149.959 271.042 284.380 1.00 138.91 233 Bj 1 
-ATOM 1396 C CE1 . PHE Q 17 233 ? 151.233 271.818 286.695 1.00 138.91 233 Bj 1 
-ATOM 1397 C CE2 . PHE Q 17 233 ? 149.218 271.404 285.489 1.00 138.91 233 Bj 1 
-ATOM 1398 C CZ  . PHE Q 17 233 ? 149.856 271.793 286.646 1.00 138.91 233 Bj 1 
-ATOM 1399 N N   . PHE Q 17 234 ? 152.663 267.863 281.235 1.00 134.22 234 Bj 1 
-ATOM 1400 C CA  . PHE Q 17 234 ? 153.088 267.418 279.917 1.00 134.22 234 Bj 1 
-ATOM 1401 C C   . PHE Q 17 234 ? 152.037 267.799 278.884 1.00 134.22 234 Bj 1 
-ATOM 1402 O O   . PHE Q 17 234 ? 150.840 267.584 279.098 1.00 134.22 234 Bj 1 
-ATOM 1403 C CB  . PHE Q 17 234 ? 153.301 265.902 279.885 1.00 134.22 234 Bj 1 
-ATOM 1404 C CG  . PHE Q 17 234 ? 154.564 265.447 280.554 1.00 134.22 234 Bj 1 
-ATOM 1405 C CD1 . PHE Q 17 234 ? 154.684 265.473 281.933 1.00 134.22 234 Bj 1 
-ATOM 1406 C CD2 . PHE Q 17 234 ? 155.625 264.972 279.802 1.00 134.22 234 Bj 1 
-ATOM 1407 C CE1 . PHE Q 17 234 ? 155.845 265.047 282.547 1.00 134.22 234 Bj 1 
-ATOM 1408 C CE2 . PHE Q 17 234 ? 156.786 264.542 280.410 1.00 134.22 234 Bj 1 
-ATOM 1409 C CZ  . PHE Q 17 234 ? 156.896 264.580 281.784 1.00 134.22 234 Bj 1 
-ATOM 1410 N N   . LYS Q 17 235 ? 152.488 268.350 277.760 1.00 127.98 235 Bj 1 
-ATOM 1411 C CA  . LYS Q 17 235 ? 151.591 268.748 276.685 1.00 127.98 235 Bj 1 
-ATOM 1412 C C   . LYS Q 17 235 ? 151.407 267.614 275.685 1.00 127.98 235 Bj 1 
-ATOM 1413 O O   . LYS Q 17 235 ? 152.342 266.861 275.399 1.00 127.98 235 Bj 1 
-ATOM 1414 C CB  . LYS Q 17 235 ? 152.120 269.988 275.962 1.00 127.98 235 Bj 1 
-ATOM 1415 C CG  . LYS Q 17 235 ? 151.913 271.288 276.717 1.00 127.98 235 Bj 1 
-ATOM 1416 C CD  . LYS Q 17 235 ? 152.321 272.477 275.865 1.00 127.98 235 Bj 1 
-ATOM 1417 C CE  . LYS Q 17 235 ? 151.978 273.788 276.547 1.00 127.98 235 Bj 1 
-ATOM 1418 N NZ  . LYS Q 17 235 ? 152.378 274.957 275.719 1.00 127.98 235 Bj 1 
-ATOM 1419 N N   . ALA Q 17 236 ? 150.191 267.503 275.155 1.00 124.65 236 Bj 1 
-ATOM 1420 C CA  . ALA Q 17 236 ? 149.871 266.534 274.120 1.00 124.65 236 Bj 1 
-ATOM 1421 C C   . ALA Q 17 236 ? 148.912 267.176 273.129 1.00 124.65 236 Bj 1 
-ATOM 1422 O O   . ALA Q 17 236 ? 148.201 268.130 273.453 1.00 124.65 236 Bj 1 
-ATOM 1423 C CB  . ALA Q 17 236 ? 149.260 265.254 274.706 1.00 124.65 236 Bj 1 
-ATOM 1424 N N   . LEU Q 17 237 ? 148.905 266.645 271.911 1.00 117.02 237 Bj 1 
-ATOM 1425 C CA  . LEU Q 17 237 ? 148.078 267.159 270.829 1.00 117.02 237 Bj 1 
-ATOM 1426 C C   . LEU Q 17 237 ? 146.925 266.201 270.561 1.00 117.02 237 Bj 1 
-ATOM 1427 O O   . LEU Q 17 237 ? 147.072 264.984 270.709 1.00 117.02 237 Bj 1 
-ATOM 1428 C CB  . LEU Q 17 237 ? 148.906 267.358 269.556 1.00 117.02 237 Bj 1 
-ATOM 1429 C CG  . LEU Q 17 237 ? 148.232 268.081 268.388 1.00 117.02 237 Bj 1 
-ATOM 1430 C CD1 . LEU Q 17 237 ? 147.874 269.508 268.773 1.00 117.02 237 Bj 1 
-ATOM 1431 C CD2 . LEU Q 17 237 ? 149.124 268.062 267.157 1.00 117.02 237 Bj 1 
-ATOM 1432 N N   . LEU Q 17 238 ? 145.780 266.752 270.167 1.00 111.74 238 Bj 1 
-ATOM 1433 C CA  . LEU Q 17 238 ? 144.598 265.953 269.875 1.00 111.74 238 Bj 1 
-ATOM 1434 C C   . LEU Q 17 238 ? 144.550 265.637 268.385 1.00 111.74 238 Bj 1 
-ATOM 1435 O O   . LEU Q 17 238 ? 144.436 266.545 267.555 1.00 111.74 238 Bj 1 
-ATOM 1436 C CB  . LEU Q 17 238 ? 143.330 266.688 270.308 1.00 111.74 238 Bj 1 
-ATOM 1437 C CG  . LEU Q 17 238 ? 142.006 266.022 269.930 1.00 111.74 238 Bj 1 
-ATOM 1438 C CD1 . LEU Q 17 238 ? 141.964 264.588 270.427 1.00 111.74 238 Bj 1 
-ATOM 1439 C CD2 . LEU Q 17 238 ? 140.831 266.812 270.482 1.00 111.74 238 Bj 1 
-ATOM 1440 N N   . LEU Q 17 239 ? 144.634 264.350 268.050 1.00 112.02 239 Bj 1 
-ATOM 1441 C CA  . LEU Q 17 239 ? 144.528 263.909 266.665 1.00 112.02 239 Bj 1 
-ATOM 1442 C C   . LEU Q 17 239 ? 143.084 263.603 266.282 1.00 112.02 239 Bj 1 
-ATOM 1443 O O   . LEU Q 17 239 ? 142.601 264.068 265.245 1.00 112.02 239 Bj 1 
-ATOM 1444 C CB  . LEU Q 17 239 ? 145.409 262.678 266.433 1.00 112.02 239 Bj 1 
-ATOM 1445 C CG  . LEU Q 17 239 ? 146.918 262.867 266.591 1.00 112.02 239 Bj 1 
-ATOM 1446 C CD1 . LEU Q 17 239 ? 147.642 261.536 266.459 1.00 112.02 239 Bj 1 
-ATOM 1447 C CD2 . LEU Q 17 239 ? 147.442 263.866 265.571 1.00 112.02 239 Bj 1 
-ATOM 1448 N N   . THR Q 17 240 ? 142.387 262.825 267.107 1.00 112.72 240 Bj 1 
-ATOM 1449 C CA  . THR Q 17 240 ? 140.988 262.492 266.862 1.00 112.72 240 Bj 1 
-ATOM 1450 C C   . THR Q 17 240 ? 140.284 262.360 268.201 1.00 112.72 240 Bj 1 
-ATOM 1451 O O   . THR Q 17 240 ? 140.656 261.510 269.017 1.00 112.72 240 Bj 1 
-ATOM 1452 C CB  . THR Q 17 240 ? 140.855 261.198 266.056 1.00 112.72 240 Bj 1 
-ATOM 1453 O OG1 . THR Q 17 240 ? 141.478 261.363 264.776 1.00 112.72 240 Bj 1 
-ATOM 1454 C CG2 . THR Q 17 240 ? 139.389 260.842 265.860 1.00 112.72 240 Bj 1 
-ATOM 1455 N N   . GLY Q 17 241 ? 139.281 263.204 268.427 1.00 112.39 241 Bj 1 
-ATOM 1456 C CA  . GLY Q 17 241 ? 138.518 263.163 269.658 1.00 112.39 241 Bj 1 
-ATOM 1457 C C   . GLY Q 17 241 ? 137.166 262.503 269.490 1.00 112.39 241 Bj 1 
-ATOM 1458 O O   . GLY Q 17 241 ? 136.235 263.106 268.948 1.00 112.39 241 Bj 1 
-ATOM 1459 N N   . ASP Q 17 242 ? 137.047 261.262 269.950 1.00 120.39 242 Bj 1 
-ATOM 1460 C CA  . ASP Q 17 242 ? 135.806 260.495 269.875 1.00 120.39 242 Bj 1 
-ATOM 1461 C C   . ASP Q 17 242 ? 135.359 260.229 271.309 1.00 120.39 242 Bj 1 
-ATOM 1462 O O   . ASP Q 17 242 ? 135.683 259.189 271.887 1.00 120.39 242 Bj 1 
-ATOM 1463 C CB  . ASP Q 17 242 ? 136.006 259.200 269.088 1.00 120.39 242 Bj 1 
-ATOM 1464 C CG  . ASP Q 17 242 ? 134.704 258.479 268.811 1.00 120.39 242 Bj 1 
-ATOM 1465 O OD1 . ASP Q 17 242 ? 133.900 258.990 268.004 1.00 120.39 242 Bj 1 
-ATOM 1466 O OD2 . ASP Q 17 242 ? 134.484 257.400 269.399 1.00 120.39 242 Bj 1 
-ATOM 1467 N N   . PHE Q 17 243 ? 134.612 261.172 271.876 1.00 125.10 243 Bj 1 
-ATOM 1468 C CA  . PHE Q 17 243 ? 134.205 261.109 273.274 1.00 125.10 243 Bj 1 
-ATOM 1469 C C   . PHE Q 17 243 ? 132.791 260.548 273.376 1.00 125.10 243 Bj 1 
-ATOM 1470 O O   . PHE Q 17 243 ? 131.858 261.086 272.771 1.00 125.10 243 Bj 1 
-ATOM 1471 C CB  . PHE Q 17 243 ? 134.284 262.493 273.916 1.00 125.10 243 Bj 1 
-ATOM 1472 C CG  . PHE Q 17 243 ? 133.967 262.500 275.384 1.00 125.10 243 Bj 1 
-ATOM 1473 C CD1 . PHE Q 17 243 ? 134.948 262.216 276.319 1.00 125.10 243 Bj 1 
-ATOM 1474 C CD2 . PHE Q 17 243 ? 132.690 262.797 275.830 1.00 125.10 243 Bj 1 
-ATOM 1475 C CE1 . PHE Q 17 243 ? 134.661 262.224 277.670 1.00 125.10 243 Bj 1 
-ATOM 1476 C CE2 . PHE Q 17 243 ? 132.398 262.805 277.179 1.00 125.10 243 Bj 1 
-ATOM 1477 C CZ  . PHE Q 17 243 ? 133.384 262.518 278.100 1.00 125.10 243 Bj 1 
-ATOM 1478 N N   . SER Q 17 244 ? 132.637 259.471 274.141 1.00 130.58 244 Bj 1 
-ATOM 1479 C CA  . SER Q 17 244 ? 131.334 258.873 274.383 1.00 130.58 244 Bj 1 
-ATOM 1480 C C   . SER Q 17 244 ? 130.729 259.423 275.668 1.00 130.58 244 Bj 1 
-ATOM 1481 O O   . SER Q 17 244 ? 131.444 259.824 276.591 1.00 130.58 244 Bj 1 
-ATOM 1482 C CB  . SER Q 17 244 ? 131.443 257.349 274.467 1.00 130.58 244 Bj 1 
-ATOM 1483 O OG  . SER Q 17 244 ? 130.182 256.759 274.733 1.00 130.58 244 Bj 1 
-ATOM 1484 N N   . GLN Q 17 245 ? 129.395 259.434 275.717 1.00 128.80 245 Bj 1 
-ATOM 1485 C CA  . GLN Q 17 245 ? 128.640 259.945 276.861 1.00 128.80 245 Bj 1 
-ATOM 1486 C C   . GLN Q 17 245 ? 129.024 261.398 277.157 1.00 128.80 245 Bj 1 
-ATOM 1487 O O   . GLN Q 17 245 ? 129.573 261.730 278.209 1.00 128.80 245 Bj 1 
-ATOM 1488 C CB  . GLN Q 17 245 ? 128.834 259.050 278.092 1.00 128.80 245 Bj 1 
-ATOM 1489 C CG  . GLN Q 17 245 ? 127.890 259.349 279.253 1.00 128.80 245 Bj 1 
-ATOM 1490 C CD  . GLN Q 17 245 ? 126.435 259.074 278.920 1.00 128.80 245 Bj 1 
-ATOM 1491 O OE1 . GLN Q 17 245 ? 126.126 258.253 278.055 1.00 128.80 245 Bj 1 
-ATOM 1492 N NE2 . GLN Q 17 245 ? 125.531 259.762 279.608 1.00 128.80 245 Bj 1 
-ATOM 1493 N N   . ALA Q 17 246 ? 128.731 262.266 276.186 1.00 127.68 246 Bj 1 
-ATOM 1494 C CA  . ALA Q 17 246 ? 129.038 263.683 276.337 1.00 127.68 246 Bj 1 
-ATOM 1495 C C   . ALA Q 17 246 ? 128.140 264.366 277.359 1.00 127.68 246 Bj 1 
-ATOM 1496 O O   . ALA Q 17 246 ? 128.472 265.463 277.821 1.00 127.68 246 Bj 1 
-ATOM 1497 C CB  . ALA Q 17 246 ? 128.926 264.394 274.987 1.00 127.68 246 Bj 1 
-ATOM 1498 N N   . GLY Q 17 247 ? 127.018 263.748 277.720 1.00 128.61 247 Bj 1 
-ATOM 1499 C CA  . GLY Q 17 247 ? 126.115 264.325 278.695 1.00 128.61 247 Bj 1 
-ATOM 1500 C C   . GLY Q 17 247 ? 126.252 263.710 280.072 1.00 128.61 247 Bj 1 
-ATOM 1501 O O   . GLY Q 17 247 ? 125.267 263.595 280.808 1.00 128.61 247 Bj 1 
-ATOM 1502 N N   . LYS Q 17 248 ? 127.468 263.311 280.433 1.00 125.96 248 Bj 1 
-ATOM 1503 C CA  . LYS Q 17 248 ? 127.713 262.724 281.739 1.00 125.96 248 Bj 1 
-ATOM 1504 C C   . LYS Q 17 248 ? 127.891 263.817 282.791 1.00 125.96 248 Bj 1 
-ATOM 1505 O O   . LYS Q 17 248 ? 127.941 265.012 282.488 1.00 125.96 248 Bj 1 
-ATOM 1506 C CB  . LYS Q 17 248 ? 128.946 261.822 281.702 1.00 125.96 248 Bj 1 
-ATOM 1507 C CG  . LYS Q 17 248 ? 130.258 262.572 281.540 1.00 125.96 248 Bj 1 
-ATOM 1508 C CD  . LYS Q 17 248 ? 131.448 261.630 281.626 1.00 125.96 248 Bj 1 
-ATOM 1509 C CE  . LYS Q 17 248 ? 132.761 262.393 281.596 1.00 125.96 248 Bj 1 
-ATOM 1510 N NZ  . LYS Q 17 248 ? 133.934 261.479 281.668 1.00 125.96 248 Bj 1 
-ATOM 1511 N N   . LYS Q 17 249 ? 127.991 263.389 284.050 1.00 120.94 249 Bj 1 
-ATOM 1512 C CA  . LYS Q 17 249 ? 128.204 264.319 285.150 1.00 120.94 249 Bj 1 
-ATOM 1513 C C   . LYS Q 17 249 ? 129.630 264.849 285.213 1.00 120.94 249 Bj 1 
-ATOM 1514 O O   . LYS Q 17 249 ? 129.879 265.823 285.932 1.00 120.94 249 Bj 1 
-ATOM 1515 C CB  . LYS Q 17 249 ? 127.843 263.653 286.481 1.00 120.94 249 Bj 1 
-ATOM 1516 C CG  . LYS Q 17 249 ? 126.360 263.355 286.649 1.00 120.94 249 Bj 1 
-ATOM 1517 C CD  . LYS Q 17 249 ? 125.530 264.631 286.660 1.00 120.94 249 Bj 1 
-ATOM 1518 C CE  . LYS Q 17 249 ? 124.617 264.713 285.447 1.00 120.94 249 Bj 1 
-ATOM 1519 N NZ  . LYS Q 17 249 ? 123.811 265.964 285.445 1.00 120.94 249 Bj 1 
-ATOM 1520 N N   . GLY Q 17 250 ? 130.565 264.239 284.488 1.00 123.18 250 Bj 1 
-ATOM 1521 C CA  . GLY Q 17 250 ? 131.923 264.742 284.431 1.00 123.18 250 Bj 1 
-ATOM 1522 C C   . GLY Q 17 250 ? 132.013 266.047 283.669 1.00 123.18 250 Bj 1 
-ATOM 1523 O O   . GLY Q 17 250 ? 131.833 266.074 282.448 1.00 123.18 250 Bj 1 
-ATOM 1524 N N   . HIS Q 17 251 ? 132.289 267.138 284.379 1.00 125.29 251 Bj 1 
-ATOM 1525 C CA  . HIS Q 17 251 ? 132.322 268.470 283.778 1.00 125.29 251 Bj 1 
-ATOM 1526 C C   . HIS Q 17 251 ? 133.687 268.686 283.137 1.00 125.29 251 Bj 1 
-ATOM 1527 O O   . HIS Q 17 251 ? 134.647 269.104 283.786 1.00 125.29 251 Bj 1 
-ATOM 1528 C CB  . HIS Q 17 251 ? 132.019 269.538 284.821 1.00 125.29 251 Bj 1 
-ATOM 1529 C CG  . HIS Q 17 251 ? 130.737 269.315 285.560 1.00 125.29 251 Bj 1 
-ATOM 1530 N ND1 . HIS Q 17 251 ? 129.511 269.688 285.053 1.00 125.29 251 Bj 1 
-ATOM 1531 C CD2 . HIS Q 17 251 ? 130.489 268.757 286.769 1.00 125.29 251 Bj 1 
-ATOM 1532 C CE1 . HIS Q 17 251 ? 128.563 269.370 285.917 1.00 125.29 251 Bj 1 
-ATOM 1533 N NE2 . HIS Q 17 251 ? 129.131 268.803 286.966 1.00 125.29 251 Bj 1 
-ATOM 1534 N N   . HIS Q 17 252 ? 133.771 268.392 281.842 1.00 117.65 252 Bj 1 
-ATOM 1535 C CA  . HIS Q 17 252 ? 134.965 268.633 281.044 1.00 117.65 252 Bj 1 
-ATOM 1536 C C   . HIS Q 17 252 ? 134.674 269.751 280.053 1.00 117.65 252 Bj 1 
-ATOM 1537 O O   . HIS Q 17 252 ? 133.661 269.713 279.348 1.00 117.65 252 Bj 1 
-ATOM 1538 C CB  . HIS Q 17 252 ? 135.405 267.363 280.309 1.00 117.65 252 Bj 1 
-ATOM 1539 C CG  . HIS Q 17 252 ? 134.422 266.883 279.289 1.00 117.65 252 Bj 1 
-ATOM 1540 N ND1 . HIS Q 17 252 ? 133.315 266.131 279.617 1.00 117.65 252 Bj 1 
-ATOM 1541 C CD2 . HIS Q 17 252 ? 134.377 267.051 277.946 1.00 117.65 252 Bj 1 
-ATOM 1542 C CE1 . HIS Q 17 252 ? 132.631 265.856 278.521 1.00 117.65 252 Bj 1 
-ATOM 1543 N NE2 . HIS Q 17 252 ? 133.254 266.403 277.493 1.00 117.65 252 Bj 1 
-ATOM 1544 N N   . VAL Q 17 253 ? 135.556 270.746 280.008 1.00 119.25 253 Bj 1 
-ATOM 1545 C CA  . VAL Q 17 253 ? 135.344 271.959 279.228 1.00 119.25 253 Bj 1 
-ATOM 1546 C C   . VAL Q 17 253 ? 136.541 272.173 278.314 1.00 119.25 253 Bj 1 
-ATOM 1547 O O   . VAL Q 17 253 ? 137.691 272.100 278.762 1.00 119.25 253 Bj 1 
-ATOM 1548 C CB  . VAL Q 17 253 ? 135.137 273.190 280.131 1.00 119.25 253 Bj 1 
-ATOM 1549 C CG1 . VAL Q 17 253 ? 134.861 274.428 279.291 1.00 119.25 253 Bj 1 
-ATOM 1550 C CG2 . VAL Q 17 253 ? 134.007 272.948 281.121 1.00 119.25 253 Bj 1 
-ATOM 1551 N N   . TRP Q 17 254 ? 136.269 272.431 277.036 1.00 115.00 254 Bj 1 
-ATOM 1552 C CA  . TRP Q 17 254 ? 137.283 272.897 276.101 1.00 115.00 254 Bj 1 
-ATOM 1553 C C   . TRP Q 17 254 ? 137.325 274.418 276.147 1.00 115.00 254 Bj 1 
-ATOM 1554 O O   . TRP Q 17 254 ? 136.330 275.082 275.836 1.00 115.00 254 Bj 1 
-ATOM 1555 C CB  . TRP Q 17 254 ? 136.987 272.415 274.681 1.00 115.00 254 Bj 1 
-ATOM 1556 C CG  . TRP Q 17 254 ? 136.967 270.928 274.547 1.00 115.00 254 Bj 1 
-ATOM 1557 C CD1 . TRP Q 17 254 ? 135.876 270.139 274.334 1.00 115.00 254 Bj 1 
-ATOM 1558 C CD2 . TRP Q 17 254 ? 138.092 270.046 274.625 1.00 115.00 254 Bj 1 
-ATOM 1559 N NE1 . TRP Q 17 254 ? 136.251 268.819 274.269 1.00 115.00 254 Bj 1 
-ATOM 1560 C CE2 . TRP Q 17 254 ? 137.607 268.735 274.446 1.00 115.00 254 Bj 1 
-ATOM 1561 C CE3 . TRP Q 17 254 ? 139.461 270.236 274.827 1.00 115.00 254 Bj 1 
-ATOM 1562 C CZ2 . TRP Q 17 254 ? 138.443 267.622 274.463 1.00 115.00 254 Bj 1 
-ATOM 1563 C CZ3 . TRP Q 17 254 ? 140.289 269.130 274.842 1.00 115.00 254 Bj 1 
-ATOM 1564 C CH2 . TRP Q 17 254 ? 139.778 267.840 274.662 1.00 115.00 254 Bj 1 
-ATOM 1565 N N   . VAL Q 17 255 ? 138.473 274.965 276.535 1.00 119.35 255 Bj 1 
-ATOM 1566 C CA  . VAL Q 17 255 ? 138.586 276.379 276.870 1.00 119.35 255 Bj 1 
-ATOM 1567 C C   . VAL Q 17 255 ? 139.797 276.969 276.160 1.00 119.35 255 Bj 1 
-ATOM 1568 O O   . VAL Q 17 255 ? 140.791 276.276 275.919 1.00 119.35 255 Bj 1 
-ATOM 1569 C CB  . VAL Q 17 255 ? 138.678 276.575 278.400 1.00 119.35 255 Bj 1 
-ATOM 1570 C CG1 . VAL Q 17 255 ? 139.988 276.026 278.940 1.00 119.35 255 Bj 1 
-ATOM 1571 C CG2 . VAL Q 17 255 ? 138.506 278.030 278.766 1.00 119.35 255 Bj 1 
-ATOM 1572 N N   . SER Q 17 256 ? 139.702 278.248 275.804 1.00 122.61 256 Bj 1 
-ATOM 1573 C CA  . SER Q 17 256 ? 140.792 278.967 275.164 1.00 122.61 256 Bj 1 
-ATOM 1574 C C   . SER Q 17 256 ? 141.580 279.743 276.219 1.00 122.61 256 Bj 1 
-ATOM 1575 O O   . SER Q 17 256 ? 141.375 279.576 277.423 1.00 122.61 256 Bj 1 
-ATOM 1576 C CB  . SER Q 17 256 ? 140.249 279.877 274.066 1.00 122.61 256 Bj 1 
-ATOM 1577 O OG  . SER Q 17 256 ? 141.298 280.548 273.390 1.00 122.61 256 Bj 1 
-ATOM 1578 N N   . LYS Q 17 257 ? 142.489 280.613 275.772 1.00 127.00 257 Bj 1 
-ATOM 1579 C CA  . LYS Q 17 257 ? 143.375 281.318 276.695 1.00 127.00 257 Bj 1 
-ATOM 1580 C C   . LYS Q 17 257 ? 142.610 282.285 277.595 1.00 127.00 257 Bj 1 
-ATOM 1581 O O   . LYS Q 17 257 ? 142.840 282.324 278.811 1.00 127.00 257 Bj 1 
-ATOM 1582 C CB  . LYS Q 17 257 ? 144.455 282.054 275.899 1.00 127.00 257 Bj 1 
-ATOM 1583 C CG  . LYS Q 17 257 ? 144.923 283.367 276.506 1.00 127.00 257 Bj 1 
-ATOM 1584 C CD  . LYS Q 17 257 ? 146.041 283.168 277.511 1.00 127.00 257 Bj 1 
-ATOM 1585 C CE  . LYS Q 17 257 ? 146.569 284.511 277.993 1.00 127.00 257 Bj 1 
-ATOM 1586 N NZ  . LYS Q 17 257 ? 147.753 284.372 278.882 1.00 127.00 257 Bj 1 
-ATOM 1587 N N   . GLU Q 17 258 ? 141.695 283.069 277.021 1.00 126.69 258 Bj 1 
-ATOM 1588 C CA  . GLU Q 17 258 ? 141.007 284.103 277.788 1.00 126.69 258 Bj 1 
-ATOM 1589 C C   . GLU Q 17 258 ? 140.134 283.494 278.880 1.00 126.69 258 Bj 1 
-ATOM 1590 O O   . GLU Q 17 258 ? 140.313 283.776 280.071 1.00 126.69 258 Bj 1 
-ATOM 1591 C CB  . GLU Q 17 258 ? 140.173 284.979 276.851 1.00 126.69 258 Bj 1 
-ATOM 1592 C CG  . GLU Q 17 258 ? 140.982 285.777 275.834 1.00 126.69 258 Bj 1 
-ATOM 1593 C CD  . GLU Q 17 258 ? 141.362 284.971 274.602 1.00 126.69 258 Bj 1 
-ATOM 1594 O OE1 . GLU Q 17 258 ? 141.635 283.760 274.732 1.00 126.69 258 Bj 1 
-ATOM 1595 O OE2 . GLU Q 17 258 ? 141.381 285.553 273.498 1.00 126.69 258 Bj 1 
-ATOM 1596 N N   . GLU Q 17 259 ? 139.174 282.652 278.490 1.00 129.80 259 Bj 1 
-ATOM 1597 C CA  . GLU Q 17 259 ? 138.332 281.997 279.482 1.00 129.80 259 Bj 1 
-ATOM 1598 C C   . GLU Q 17 259 ? 139.126 281.043 280.365 1.00 129.80 259 Bj 1 
-ATOM 1599 O O   . GLU Q 17 259 ? 138.712 280.779 281.498 1.00 129.80 259 Bj 1 
-ATOM 1600 C CB  . GLU Q 17 259 ? 137.179 281.259 278.797 1.00 129.80 259 Bj 1 
-ATOM 1601 C CG  . GLU Q 17 259 ? 136.278 282.148 277.950 1.00 129.80 259 Bj 1 
-ATOM 1602 C CD  . GLU Q 17 259 ? 136.700 282.197 276.494 1.00 129.80 259 Bj 1 
-ATOM 1603 O OE1 . GLU Q 17 259 ? 137.140 281.154 275.965 1.00 129.80 259 Bj 1 
-ATOM 1604 O OE2 . GLU Q 17 259 ? 136.592 283.278 275.878 1.00 129.80 259 Bj 1 
-ATOM 1605 N N   . LEU Q 17 260 ? 140.270 280.549 279.888 1.00 130.83 260 Bj 1 
-ATOM 1606 C CA  . LEU Q 17 260 ? 141.148 279.742 280.729 1.00 130.83 260 Bj 1 
-ATOM 1607 C C   . LEU Q 17 260 ? 141.669 280.562 281.901 1.00 130.83 260 Bj 1 
-ATOM 1608 O O   . LEU Q 17 260 ? 141.580 280.142 283.062 1.00 130.83 260 Bj 1 
-ATOM 1609 C CB  . LEU Q 17 260 ? 142.301 279.197 279.882 1.00 130.83 260 Bj 1 
-ATOM 1610 C CG  . LEU Q 17 260 ? 143.280 278.143 280.407 1.00 130.83 260 Bj 1 
-ATOM 1611 C CD1 . LEU Q 17 260 ? 143.986 277.497 279.232 1.00 130.83 260 Bj 1 
-ATOM 1612 C CD2 . LEU Q 17 260 ? 144.307 278.740 281.346 1.00 130.83 260 Bj 1 
-ATOM 1613 N N   . GLY Q 17 261 ? 142.232 281.735 281.610 1.00 132.72 261 Bj 1 
-ATOM 1614 C CA  . GLY Q 17 261 ? 142.661 282.625 282.674 1.00 132.72 261 Bj 1 
-ATOM 1615 C C   . GLY Q 17 261 ? 141.510 283.111 283.530 1.00 132.72 261 Bj 1 
-ATOM 1616 O O   . GLY Q 17 261 ? 141.689 283.389 284.720 1.00 132.72 261 Bj 1 
-ATOM 1617 N N   . ASP Q 17 262 ? 140.317 283.220 282.943 1.00 135.25 262 Bj 1 
-ATOM 1618 C CA  . ASP Q 17 262 ? 139.148 283.630 283.717 1.00 135.25 262 Bj 1 
-ATOM 1619 C C   . ASP Q 17 262 ? 138.742 282.558 284.722 1.00 135.25 262 Bj 1 
-ATOM 1620 O O   . ASP Q 17 262 ? 138.354 282.874 285.853 1.00 135.25 262 Bj 1 
-ATOM 1621 C CB  . ASP Q 17 262 ? 137.986 283.951 282.778 1.00 135.25 262 Bj 1 
-ATOM 1622 C CG  . ASP Q 17 262 ? 136.680 284.169 283.519 1.00 135.25 262 Bj 1 
-ATOM 1623 O OD1 . ASP Q 17 262 ? 136.568 285.178 284.246 1.00 135.25 262 Bj 1 
-ATOM 1624 O OD2 . ASP Q 17 262 ? 135.764 283.332 283.373 1.00 135.25 262 Bj 1 
-ATOM 1625 N N   . TYR Q 17 263 ? 138.823 281.286 284.330 1.00 135.63 263 Bj 1 
-ATOM 1626 C CA  . TYR Q 17 263 ? 138.387 280.204 285.207 1.00 135.63 263 Bj 1 
-ATOM 1627 C C   . TYR Q 17 263 ? 139.450 279.853 286.242 1.00 135.63 263 Bj 1 
-ATOM 1628 O O   . TYR Q 17 263 ? 139.148 279.738 287.435 1.00 135.63 263 Bj 1 
-ATOM 1629 C CB  . TYR Q 17 263 ? 138.020 278.968 284.383 1.00 135.63 263 Bj 1 
-ATOM 1630 C CG  . TYR Q 17 263 ? 136.748 279.113 283.580 1.00 135.63 263 Bj 1 
-ATOM 1631 C CD1 . TYR Q 17 263 ? 136.444 278.220 282.560 1.00 135.63 263 Bj 1 
-ATOM 1632 C CD2 . TYR Q 17 263 ? 135.849 280.139 283.842 1.00 135.63 263 Bj 1 
-ATOM 1633 C CE1 . TYR Q 17 263 ? 135.282 278.346 281.823 1.00 135.63 263 Bj 1 
-ATOM 1634 C CE2 . TYR Q 17 263 ? 134.685 280.272 283.109 1.00 135.63 263 Bj 1 
-ATOM 1635 C CZ  . TYR Q 17 263 ? 134.407 279.373 282.101 1.00 135.63 263 Bj 1 
-ATOM 1636 O OH  . TYR Q 17 263 ? 133.250 279.500 281.367 1.00 135.63 263 Bj 1 
-ATOM 1637 N N   . LEU Q 17 264 ? 140.698 279.676 285.808 1.00 134.80 264 Bj 1 
-ATOM 1638 C CA  . LEU Q 17 264 ? 141.750 279.206 286.706 1.00 134.80 264 Bj 1 
-ATOM 1639 C C   . LEU Q 17 264 ? 142.092 280.291 287.720 1.00 134.80 264 Bj 1 
-ATOM 1640 O O   . LEU Q 17 264 ? 142.757 281.278 287.390 1.00 134.80 264 Bj 1 
-ATOM 1641 C CB  . LEU Q 17 264 ? 142.981 278.790 285.908 1.00 134.80 264 Bj 1 
-ATOM 1642 C CG  . LEU Q 17 264 ? 142.804 277.524 285.068 1.00 134.80 264 Bj 1 
-ATOM 1643 C CD1 . LEU Q 17 264 ? 144.129 277.063 284.492 1.00 134.80 264 Bj 1 
-ATOM 1644 C CD2 . LEU Q 17 264 ? 142.169 276.422 285.898 1.00 134.80 264 Bj 1 
-ATOM 1645 N N   . LYS Q 17 265 ? 141.633 280.107 288.955 1.00 137.65 265 Bj 1 
-ATOM 1646 C CA  . LYS Q 17 265 ? 141.877 281.041 290.049 1.00 137.65 265 Bj 1 
-ATOM 1647 C C   . LYS Q 17 265 ? 143.260 280.904 290.689 1.00 137.65 265 Bj 1 
-ATOM 1648 O O   . LYS Q 17 265 ? 143.947 281.921 290.850 1.00 137.65 265 Bj 1 
-ATOM 1649 C CB  . LYS Q 17 265 ? 140.794 280.889 291.122 1.00 137.65 265 Bj 1 
-ATOM 1650 C CG  . LYS Q 17 265 ? 140.067 279.555 291.107 1.00 137.65 265 Bj 1 
-ATOM 1651 C CD  . LYS Q 17 265 ? 139.195 279.392 292.339 1.00 137.65 265 Bj 1 
-ATOM 1652 C CE  . LYS Q 17 265 ? 140.022 279.484 293.612 1.00 137.65 265 Bj 1 
-ATOM 1653 N NZ  . LYS Q 17 265 ? 141.088 278.445 293.660 1.00 137.65 265 Bj 1 
-ATOM 1654 N N   . PRO Q 17 266 ? 143.720 279.709 291.071 1.00 140.01 266 Bj 1 
-ATOM 1655 C CA  . PRO Q 17 266 ? 144.940 279.634 291.881 1.00 140.01 266 Bj 1 
-ATOM 1656 C C   . PRO Q 17 266 ? 146.183 279.907 291.050 1.00 140.01 266 Bj 1 
-ATOM 1657 O O   . PRO Q 17 266 ? 146.185 279.801 289.822 1.00 140.01 266 Bj 1 
-ATOM 1658 C CB  . PRO Q 17 266 ? 144.937 278.195 292.416 1.00 140.01 266 Bj 1 
-ATOM 1659 C CG  . PRO Q 17 266 ? 143.732 277.520 291.808 1.00 140.01 266 Bj 1 
-ATOM 1660 C CD  . PRO Q 17 266 ? 143.299 278.360 290.659 1.00 140.01 266 Bj 1 
-ATOM 1661 N N   . LYS Q 17 267 ? 147.260 280.264 291.753 1.00 148.42 267 Bj 1 
-ATOM 1662 C CA  . LYS Q 17 267 ? 148.508 280.602 291.080 1.00 148.42 267 Bj 1 
-ATOM 1663 C C   . LYS Q 17 267 ? 149.209 279.379 290.506 1.00 148.42 267 Bj 1 
-ATOM 1664 O O   . LYS Q 17 267 ? 150.039 279.526 289.603 1.00 148.42 267 Bj 1 
-ATOM 1665 C CB  . LYS Q 17 267 ? 149.447 281.333 292.041 1.00 148.42 267 Bj 1 
-ATOM 1666 C CG  . LYS Q 17 267 ? 149.947 280.481 293.195 1.00 148.42 267 Bj 1 
-ATOM 1667 C CD  . LYS Q 17 267 ? 150.971 281.233 294.030 1.00 148.42 267 Bj 1 
-ATOM 1668 C CE  . LYS Q 17 267 ? 151.539 280.354 295.132 1.00 148.42 267 Bj 1 
-ATOM 1669 N NZ  . LYS Q 17 267 ? 152.570 281.070 295.935 1.00 148.42 267 Bj 1 
-ATOM 1670 N N   . TYR Q 17 268 ? 148.900 278.181 291.005 1.00 155.87 268 Bj 1 
-ATOM 1671 C CA  . TYR Q 17 268 ? 149.550 276.982 290.487 1.00 155.87 268 Bj 1 
-ATOM 1672 C C   . TYR Q 17 268 ? 149.064 276.652 289.082 1.00 155.87 268 Bj 1 
-ATOM 1673 O O   . TYR Q 17 268 ? 149.833 276.147 288.255 1.00 155.87 268 Bj 1 
-ATOM 1674 C CB  . TYR Q 17 268 ? 149.315 275.807 291.434 1.00 155.87 268 Bj 1 
-ATOM 1675 C CG  . TYR Q 17 268 ? 149.991 275.984 292.771 1.00 155.87 268 Bj 1 
-ATOM 1676 C CD1 . TYR Q 17 268 ? 151.334 275.678 292.934 1.00 155.87 268 Bj 1 
-ATOM 1677 C CD2 . TYR Q 17 268 ? 149.290 276.466 293.867 1.00 155.87 268 Bj 1 
-ATOM 1678 C CE1 . TYR Q 17 268 ? 151.960 275.843 294.150 1.00 155.87 268 Bj 1 
-ATOM 1679 C CE2 . TYR Q 17 268 ? 149.907 276.633 295.090 1.00 155.87 268 Bj 1 
-ATOM 1680 C CZ  . TYR Q 17 268 ? 151.242 276.319 295.225 1.00 155.87 268 Bj 1 
-ATOM 1681 O OH  . TYR Q 17 268 ? 151.863 276.483 296.440 1.00 155.87 268 Bj 1 
-ATOM 1682 N N   . LEU Q 17 269 ? 147.796 276.926 288.793 1.00 143.98 269 Bj 1 
-ATOM 1683 C CA  . LEU Q 17 269 ? 147.256 276.720 287.458 1.00 143.98 269 Bj 1 
-ATOM 1684 C C   . LEU Q 17 269 ? 147.228 277.995 286.627 1.00 143.98 269 Bj 1 
-ATOM 1685 O O   . LEU Q 17 269 ? 147.115 277.912 285.399 1.00 143.98 269 Bj 1 
-ATOM 1686 C CB  . LEU Q 17 269 ? 145.845 276.130 287.545 1.00 143.98 269 Bj 1 
-ATOM 1687 C CG  . LEU Q 17 269 ? 145.752 274.727 288.149 1.00 143.98 269 Bj 1 
-ATOM 1688 C CD1 . LEU Q 17 269 ? 144.310 274.253 288.179 1.00 143.98 269 Bj 1 
-ATOM 1689 C CD2 . LEU Q 17 269 ? 146.624 273.751 287.375 1.00 143.98 269 Bj 1 
-ATOM 1690 N N   . ALA Q 17 270 ? 147.339 279.164 287.255 1.00 137.42 270 Bj 1 
-ATOM 1691 C CA  . ALA Q 17 270 ? 147.361 280.426 286.528 1.00 137.42 270 Bj 1 
-ATOM 1692 C C   . ALA Q 17 270 ? 148.680 280.671 285.810 1.00 137.42 270 Bj 1 
-ATOM 1693 O O   . ALA Q 17 270 ? 148.785 281.646 285.059 1.00 137.42 270 Bj 1 
-ATOM 1694 C CB  . ALA Q 17 270 ? 147.068 281.588 287.482 1.00 137.42 270 Bj 1 
-ATOM 1695 N N   . GLN Q 17 271 ? 149.681 279.820 286.021 1.00 132.72 271 Bj 1 
-ATOM 1696 C CA  . GLN Q 17 271 ? 150.970 279.944 285.357 1.00 132.72 271 Bj 1 
-ATOM 1697 C C   . GLN Q 17 271 ? 151.126 278.967 284.199 1.00 132.72 271 Bj 1 
-ATOM 1698 O O   . GLN Q 17 271 ? 152.241 278.789 283.699 1.00 132.72 271 Bj 1 
-ATOM 1699 C CB  . GLN Q 17 271 ? 152.102 279.749 286.366 1.00 132.72 271 Bj 1 
-ATOM 1700 C CG  . GLN Q 17 271 ? 152.097 280.762 287.495 1.00 132.72 271 Bj 1 
-ATOM 1701 C CD  . GLN Q 17 271 ? 153.182 280.502 288.519 1.00 132.72 271 Bj 1 
-ATOM 1702 O OE1 . GLN Q 17 271 ? 154.178 279.838 288.232 1.00 132.72 271 Bj 1 
-ATOM 1703 N NE2 . GLN Q 17 271 ? 152.994 281.024 289.725 1.00 132.72 271 Bj 1 
-ATOM 1704 N N   . VAL Q 17 272 ? 150.038 278.325 283.767 1.00 127.77 272 Bj 1 
-ATOM 1705 C CA  . VAL Q 17 272 ? 150.113 277.466 282.590 1.00 127.77 272 Bj 1 
-ATOM 1706 C C   . VAL Q 17 272 ? 150.313 278.305 281.335 1.00 127.77 272 Bj 1 
-ATOM 1707 O O   . VAL Q 17 272 ? 150.913 277.842 280.356 1.00 127.77 272 Bj 1 
-ATOM 1708 C CB  . VAL Q 17 272 ? 148.858 276.577 282.494 1.00 127.77 272 Bj 1 
-ATOM 1709 C CG1 . VAL Q 17 272 ? 147.619 277.418 282.237 1.00 127.77 272 Bj 1 
-ATOM 1710 C CG2 . VAL Q 17 272 ? 149.029 275.519 281.414 1.00 127.77 272 Bj 1 
-ATOM 1711 N N   . ARG Q 17 273 ? 149.836 279.552 281.344 1.00 126.48 273 Bj 1 
-ATOM 1712 C CA  . ARG Q 17 273 ? 150.044 280.452 280.218 1.00 126.48 273 Bj 1 
-ATOM 1713 C C   . ARG Q 17 273 ? 151.496 280.886 280.074 1.00 126.48 273 Bj 1 
-ATOM 1714 O O   . ARG Q 17 273 ? 151.838 281.516 279.067 1.00 126.48 273 Bj 1 
-ATOM 1715 C CB  . ARG Q 17 273 ? 149.146 281.684 280.353 1.00 126.48 273 Bj 1 
-ATOM 1716 C CG  . ARG Q 17 273 ? 147.662 281.390 280.204 1.00 126.48 273 Bj 1 
-ATOM 1717 C CD  . ARG Q 17 273 ? 146.993 281.126 281.543 1.00 126.48 273 Bj 1 
-ATOM 1718 N NE  . ARG Q 17 273 ? 146.890 282.333 282.357 1.00 126.48 273 Bj 1 
-ATOM 1719 C CZ  . ARG Q 17 273 ? 146.190 282.414 283.484 1.00 126.48 273 Bj 1 
-ATOM 1720 N NH1 . ARG Q 17 273 ? 145.525 281.357 283.930 1.00 126.48 273 Bj 1 
-ATOM 1721 N NH2 . ARG Q 17 273 ? 146.150 283.552 284.163 1.00 126.48 273 Bj 1 
-ATOM 1722 N N   . ARG Q 17 274 ? 152.349 280.573 281.051 1.00 119.98 274 Bj 1 
-ATOM 1723 C CA  . ARG Q 17 274 ? 153.770 280.876 280.920 1.00 119.98 274 Bj 1 
-ATOM 1724 C C   . ARG Q 17 274 ? 154.394 280.073 279.786 1.00 119.98 274 Bj 1 
-ATOM 1725 O O   . ARG Q 17 274 ? 155.151 280.611 278.970 1.00 119.98 274 Bj 1 
-ATOM 1726 C CB  . ARG Q 17 274 ? 154.489 280.596 282.239 1.00 119.98 274 Bj 1 
-ATOM 1727 C CG  . ARG Q 17 274 ? 155.996 280.753 282.164 1.00 119.98 274 Bj 1 
-ATOM 1728 C CD  . ARG Q 17 274 ? 156.653 280.440 283.497 1.00 119.98 274 Bj 1 
-ATOM 1729 N NE  . ARG Q 17 274 ? 158.106 280.552 283.422 1.00 119.98 274 Bj 1 
-ATOM 1730 C CZ  . ARG Q 17 274 ? 158.925 280.351 284.449 1.00 119.98 274 Bj 1 
-ATOM 1731 N NH1 . ARG Q 17 274 ? 158.434 280.026 285.638 1.00 119.98 274 Bj 1 
-ATOM 1732 N NH2 . ARG Q 17 274 ? 160.236 280.475 284.288 1.00 119.98 274 Bj 1 
-ATOM 1733 N N   . PHE Q 17 275 ? 154.086 278.781 279.719 1.00 124.86 275 Bj 1 
-ATOM 1734 C CA  . PHE Q 17 275 ? 154.571 277.923 278.649 1.00 124.86 275 Bj 1 
-ATOM 1735 C C   . PHE Q 17 275 ? 153.499 277.598 277.619 1.00 124.86 275 Bj 1 
-ATOM 1736 O O   . PHE Q 17 275 ? 153.784 276.886 276.652 1.00 124.86 275 Bj 1 
-ATOM 1737 C CB  . PHE Q 17 275 ? 155.151 276.626 279.226 1.00 124.86 275 Bj 1 
-ATOM 1738 C CG  . PHE Q 17 275 ? 154.189 275.853 280.081 1.00 124.86 275 Bj 1 
-ATOM 1739 C CD1 . PHE Q 17 275 ? 153.410 274.846 279.535 1.00 124.86 275 Bj 1 
-ATOM 1740 C CD2 . PHE Q 17 275 ? 154.073 276.123 281.434 1.00 124.86 275 Bj 1 
-ATOM 1741 C CE1 . PHE Q 17 275 ? 152.527 274.130 280.320 1.00 124.86 275 Bj 1 
-ATOM 1742 C CE2 . PHE Q 17 275 ? 153.191 275.411 282.224 1.00 124.86 275 Bj 1 
-ATOM 1743 C CZ  . PHE Q 17 275 ? 152.418 274.412 281.666 1.00 124.86 275 Bj 1 
-ATOM 1744 N N   . LEU Q 17 276 ? 152.279 278.098 277.799 1.00 117.83 276 Bj 1 
-ATOM 1745 C CA  . LEU Q 17 276 ? 151.240 277.932 276.795 1.00 117.83 276 Bj 1 
-ATOM 1746 C C   . LEU Q 17 276 ? 151.359 279.017 275.733 1.00 117.83 276 Bj 1 
-ATOM 1747 O O   . LEU Q 17 276 ? 151.592 280.188 276.045 1.00 117.83 276 Bj 1 
-ATOM 1748 C CB  . LEU Q 17 276 ? 149.857 277.977 277.444 1.00 117.83 276 Bj 1 
-ATOM 1749 C CG  . LEU Q 17 276 ? 148.658 277.885 276.498 1.00 117.83 276 Bj 1 
-ATOM 1750 C CD1 . LEU Q 17 276 ? 148.689 276.585 275.710 1.00 117.83 276 Bj 1 
-ATOM 1751 C CD2 . LEU Q 17 276 ? 147.359 278.018 277.275 1.00 117.83 276 Bj 1 
-ATOM 1752 N N   . LEU Q 17 277 ? 151.203 278.619 274.472 1.00 108.03 277 Bj 1 
-ATOM 1753 C CA  . LEU Q 17 277 ? 151.313 279.567 273.372 1.00 108.03 277 Bj 1 
-ATOM 1754 C C   . LEU Q 17 277 ? 150.175 280.577 273.422 1.00 108.03 277 Bj 1 
-ATOM 1755 O O   . LEU Q 17 277 ? 149.048 280.245 273.802 1.00 108.03 277 Bj 1 
-ATOM 1756 C CB  . LEU Q 17 277 ? 151.306 278.836 272.032 1.00 108.03 277 Bj 1 
-ATOM 1757 C CG  . LEU Q 17 277 ? 152.569 278.060 271.666 1.00 108.03 277 Bj 1 
-ATOM 1758 C CD1 . LEU Q 17 277 ? 152.537 277.695 270.195 1.00 108.03 277 Bj 1 
-ATOM 1759 C CD2 . LEU Q 17 277 ? 153.805 278.877 271.992 1.00 108.03 277 Bj 1 
-ATOM 1760 N N   . ASP Q 17 278 ? 150.474 281.816 273.030 1.00 106.80 278 Bj 1 
-ATOM 1761 C CA  . ASP Q 17 278 ? 149.461 282.864 273.029 1.00 106.80 278 Bj 1 
-ATOM 1762 C C   . ASP Q 17 278 ? 148.629 282.835 271.754 1.00 106.80 278 Bj 1 
-ATOM 1763 O O   . ASP Q 17 278 ? 147.422 283.101 271.794 1.00 106.80 278 Bj 1 
-ATOM 1764 C CB  . ASP Q 17 278 ? 150.123 284.231 273.199 1.00 106.80 278 Bj 1 
-ATOM 1765 C CG  . ASP Q 17 278 ? 151.058 284.283 274.390 1.00 106.80 278 Bj 1 
-ATOM 1766 O OD1 . ASP Q 17 278 ? 150.918 283.436 275.297 1.00 106.80 278 Bj 1 
-ATOM 1767 O OD2 . ASP Q 17 278 ? 151.932 285.174 274.420 1.00 106.80 278 Bj 1 
-ATOM 1768 N N   . LEU Q 17 279 ? 149.259 282.519 270.625 1.00 104.98 279 Bj 1 
-ATOM 1769 C CA  . LEU Q 17 279 ? 148.601 282.483 269.320 1.00 104.98 279 Bj 1 
-ATOM 1770 C C   . LEU Q 17 279 ? 147.938 283.817 268.987 1.00 104.98 279 Bj 1 
-ATOM 1771 O O   . LEU Q 17 279 ? 148.618 284.810 268.729 1.00 104.98 279 Bj 1 
-ATOM 1772 C CB  . LEU Q 17 279 ? 147.567 281.354 269.263 1.00 104.98 279 Bj 1 
-ATOM 1773 C CG  . LEU Q 17 279 ? 148.068 279.941 269.566 1.00 104.98 279 Bj 1 
-ATOM 1774 C CD1 . LEU Q 17 279 ? 147.007 278.919 269.200 1.00 104.98 279 Bj 1 
-ATOM 1775 C CD2 . LEU Q 17 279 ? 149.365 279.652 268.834 1.00 104.98 279 Bj 1 
-#
diff --git a/src/alphafold3/test_data/miniature_databases/pdb_mmcif/7rye.cif b/src/alphafold3/test_data/miniature_databases/pdb_mmcif/7rye.cif
deleted file mode 100644
index 5ff8f4c606c7dc9f4679569eb994c59974f4ff26..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/pdb_mmcif/7rye.cif
+++ /dev/null
@@ -1,893 +0,0 @@
-data_7RYE
-#
-_entry.id 7RYE
-#
-loop_
-_chem_comp.formula
-_chem_comp.formula_weight
-_chem_comp.id
-_chem_comp.mon_nstd_flag
-_chem_comp.name
-_chem_comp.pdbx_synonyms
-_chem_comp.type
-"C3 H7 N O2"     89.093  ALA y ALANINE         ? "L-peptide linking" 
-"C6 H15 N4 O2 1" 175.209 ARG y ARGININE        ? "L-peptide linking" 
-"C4 H8 N2 O3"    132.118 ASN y ASPARAGINE      ? "L-peptide linking" 
-"C4 H7 N O4"     133.103 ASP y "ASPARTIC ACID" ? "L-peptide linking" 
-"C3 H7 N O2 S"   121.158 CYS y CYSTEINE        ? "L-peptide linking" 
-"C5 H10 N2 O3"   146.144 GLN y GLUTAMINE       ? "L-peptide linking" 
-"C5 H9 N O4"     147.129 GLU y "GLUTAMIC ACID" ? "L-peptide linking" 
-"C2 H5 N O2"     75.067  GLY y GLYCINE         ? "peptide linking"   
-"C6 H10 N3 O2 1" 156.162 HIS y HISTIDINE       ? "L-peptide linking" 
-"C6 H13 N O2"    131.173 ILE y ISOLEUCINE      ? "L-peptide linking" 
-"C6 H13 N O2"    131.173 LEU y LEUCINE         ? "L-peptide linking" 
-"C6 H15 N2 O2 1" 147.195 LYS y LYSINE          ? "L-peptide linking" 
-"C5 H11 N O2 S"  149.211 MET y METHIONINE      ? "L-peptide linking" 
-"C9 H11 N O2"    165.189 PHE y PHENYLALANINE   ? "L-peptide linking" 
-"C5 H9 N O2"     115.130 PRO y PROLINE         ? "L-peptide linking" 
-"C3 H7 N O3"     105.093 SER y SERINE          ? "L-peptide linking" 
-"C4 H9 N O3"     119.119 THR y THREONINE       ? "L-peptide linking" 
-"C11 H12 N2 O2"  204.225 TRP y TRYPTOPHAN      ? "L-peptide linking" 
-"C9 H11 N O3"    181.189 TYR y TYROSINE        ? "L-peptide linking" 
-"C5 H11 N O2"    117.146 VAL y VALINE          ? "L-peptide linking" 
-#
-_entity.id               1
-_entity.pdbx_description "Protein PrgI"
-_entity.type             polymer
-#
-_entity_poly.entity_id      1
-_entity_poly.pdbx_strand_id J
-_entity_poly.type           polypeptide(L)
-#
-loop_
-_entity_poly_seq.entity_id
-_entity_poly_seq.hetero
-_entity_poly_seq.mon_id
-_entity_poly_seq.num
-1 n MET 1  
-1 n ALA 2  
-1 n THR 3  
-1 n PRO 4  
-1 n TRP 5  
-1 n SER 6  
-1 n GLY 7  
-1 n TYR 8  
-1 n LEU 9  
-1 n ASP 10 
-1 n ASP 11 
-1 n VAL 12 
-1 n SER 13 
-1 n ALA 14 
-1 n LYS 15 
-1 n PHE 16 
-1 n ASP 17 
-1 n THR 18 
-1 n GLY 19 
-1 n VAL 20 
-1 n ASP 21 
-1 n ASN 22 
-1 n LEU 23 
-1 n GLN 24 
-1 n THR 25 
-1 n GLN 26 
-1 n VAL 27 
-1 n THR 28 
-1 n GLU 29 
-1 n ALA 30 
-1 n LEU 31 
-1 n ASP 32 
-1 n LYS 33 
-1 n LEU 34 
-1 n ALA 35 
-1 n ALA 36 
-1 n LYS 37 
-1 n PRO 38 
-1 n SER 39 
-1 n ASP 40 
-1 n PRO 41 
-1 n ALA 42 
-1 n LEU 43 
-1 n LEU 44 
-1 n ALA 45 
-1 n ALA 46 
-1 n TYR 47 
-1 n GLN 48 
-1 n SER 49 
-1 n LYS 50 
-1 n LEU 51 
-1 n SER 52 
-1 n GLU 53 
-1 n TYR 54 
-1 n ASN 55 
-1 n LEU 56 
-1 n TYR 57 
-1 n ARG 58 
-1 n ASN 59 
-1 n ALA 60 
-1 n GLN 61 
-1 n SER 62 
-1 n ASN 63 
-1 n THR 64 
-1 n VAL 65 
-1 n LYS 66 
-1 n VAL 67 
-1 n PHE 68 
-1 n LYS 69 
-1 n ASP 70 
-1 n ILE 71 
-1 n ASP 72 
-1 n ALA 73 
-1 n ALA 74 
-1 n ILE 75 
-1 n ILE 76 
-1 n GLN 77 
-1 n ASN 78 
-1 n PHE 79 
-1 n ARG 80 
-#
-_exptl.method "ELECTRON MICROSCOPY"
-#
-_pdbx_audit_revision_history.revision_date 2021-11-10
-#
-_pdbx_database_status.recvd_initial_deposition_date 2021-11-10
-#
-loop_
-_pdbx_poly_seq_scheme.asym_id
-_pdbx_poly_seq_scheme.auth_seq_num
-_pdbx_poly_seq_scheme.entity_id
-_pdbx_poly_seq_scheme.hetero
-_pdbx_poly_seq_scheme.mon_id
-_pdbx_poly_seq_scheme.pdb_ins_code
-_pdbx_poly_seq_scheme.pdb_seq_num
-_pdbx_poly_seq_scheme.pdb_strand_id
-_pdbx_poly_seq_scheme.seq_id
-J ?  1 n MET . 1  J 1  
-J ?  1 n ALA . 2  J 2  
-J 3  1 n THR . 3  J 3  
-J 4  1 n PRO . 4  J 4  
-J 5  1 n TRP . 5  J 5  
-J 6  1 n SER . 6  J 6  
-J 7  1 n GLY . 7  J 7  
-J 8  1 n TYR . 8  J 8  
-J 9  1 n LEU . 9  J 9  
-J 10 1 n ASP . 10 J 10 
-J 11 1 n ASP . 11 J 11 
-J 12 1 n VAL . 12 J 12 
-J 13 1 n SER . 13 J 13 
-J 14 1 n ALA . 14 J 14 
-J 15 1 n LYS . 15 J 15 
-J 16 1 n PHE . 16 J 16 
-J 17 1 n ASP . 17 J 17 
-J 18 1 n THR . 18 J 18 
-J 19 1 n GLY . 19 J 19 
-J 20 1 n VAL . 20 J 20 
-J 21 1 n ASP . 21 J 21 
-J 22 1 n ASN . 22 J 22 
-J 23 1 n LEU . 23 J 23 
-J 24 1 n GLN . 24 J 24 
-J 25 1 n THR . 25 J 25 
-J 26 1 n GLN . 26 J 26 
-J 27 1 n VAL . 27 J 27 
-J 28 1 n THR . 28 J 28 
-J 29 1 n GLU . 29 J 29 
-J 30 1 n ALA . 30 J 30 
-J 31 1 n LEU . 31 J 31 
-J 32 1 n ASP . 32 J 32 
-J 33 1 n LYS . 33 J 33 
-J 34 1 n LEU . 34 J 34 
-J 35 1 n ALA . 35 J 35 
-J 36 1 n ALA . 36 J 36 
-J 37 1 n LYS . 37 J 37 
-J 38 1 n PRO . 38 J 38 
-J 39 1 n SER . 39 J 39 
-J 40 1 n ASP . 40 J 40 
-J 41 1 n PRO . 41 J 41 
-J 42 1 n ALA . 42 J 42 
-J 43 1 n LEU . 43 J 43 
-J 44 1 n LEU . 44 J 44 
-J 45 1 n ALA . 45 J 45 
-J 46 1 n ALA . 46 J 46 
-J 47 1 n TYR . 47 J 47 
-J 48 1 n GLN . 48 J 48 
-J 49 1 n SER . 49 J 49 
-J 50 1 n LYS . 50 J 50 
-J 51 1 n LEU . 51 J 51 
-J 52 1 n SER . 52 J 52 
-J 53 1 n GLU . 53 J 53 
-J 54 1 n TYR . 54 J 54 
-J 55 1 n ASN . 55 J 55 
-J 56 1 n LEU . 56 J 56 
-J 57 1 n TYR . 57 J 57 
-J 58 1 n ARG . 58 J 58 
-J 59 1 n ASN . 59 J 59 
-J 60 1 n ALA . 60 J 60 
-J 61 1 n GLN . 61 J 61 
-J 62 1 n SER . 62 J 62 
-J 63 1 n ASN . 63 J 63 
-J 64 1 n THR . 64 J 64 
-J 65 1 n VAL . 65 J 65 
-J 66 1 n LYS . 66 J 66 
-J 67 1 n VAL . 67 J 67 
-J 68 1 n PHE . 68 J 68 
-J 69 1 n LYS . 69 J 69 
-J 70 1 n ASP . 70 J 70 
-J 71 1 n ILE . 71 J 71 
-J 72 1 n ASP . 72 J 72 
-J 73 1 n ALA . 73 J 73 
-J 74 1 n ALA . 74 J 74 
-J 75 1 n ILE . 75 J 75 
-J 76 1 n ILE . 76 J 76 
-J 77 1 n GLN . 77 J 77 
-J 78 1 n ASN . 78 J 78 
-J 79 1 n PHE . 79 J 79 
-J 80 1 n ARG . 80 J 80 
-#
-_pdbx_struct_assembly.details            author_defined_assembly
-_pdbx_struct_assembly.id                 1
-_pdbx_struct_assembly.method_details     ?
-_pdbx_struct_assembly.oligomeric_count   24
-_pdbx_struct_assembly.oligomeric_details 24-meric
-#
-_pdbx_struct_assembly_gen.assembly_id     1
-_pdbx_struct_assembly_gen.asym_id_list    A,B,C,D,E,F,G,H,I,J,K,L,M,N,O,P,Q,R,S,T,U,V,W,X
-_pdbx_struct_assembly_gen.oper_expression 1
-#
-_pdbx_struct_oper_list.id                 1
-_pdbx_struct_oper_list.matrix[1][1]       1.0000000000
-_pdbx_struct_oper_list.matrix[1][2]       0.0000000000
-_pdbx_struct_oper_list.matrix[1][3]       0.0000000000
-_pdbx_struct_oper_list.matrix[2][1]       0.0000000000
-_pdbx_struct_oper_list.matrix[2][2]       1.0000000000
-_pdbx_struct_oper_list.matrix[2][3]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][1]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][2]       0.0000000000
-_pdbx_struct_oper_list.matrix[3][3]       1.0000000000
-_pdbx_struct_oper_list.name               1_555
-_pdbx_struct_oper_list.symmetry_operation ?
-_pdbx_struct_oper_list.type               "identity operation"
-_pdbx_struct_oper_list.vector[1]          0.0000000000
-_pdbx_struct_oper_list.vector[2]          0.0000000000
-_pdbx_struct_oper_list.vector[3]          0.0000000000
-#
-_refine.ls_d_res_high 3.90
-#
-_software.classification other
-_software.name           "DeepMind Structure Class"
-_software.pdbx_ordinal   1
-_software.version        2.0.0
-#
-_struct_asym.entity_id 1
-_struct_asym.id        J
-#
-loop_
-_atom_site.group_PDB
-_atom_site.id
-_atom_site.type_symbol
-_atom_site.label_atom_id
-_atom_site.label_alt_id
-_atom_site.label_comp_id
-_atom_site.label_asym_id
-_atom_site.label_entity_id
-_atom_site.label_seq_id
-_atom_site.pdbx_PDB_ins_code
-_atom_site.Cartn_x
-_atom_site.Cartn_y
-_atom_site.Cartn_z
-_atom_site.occupancy
-_atom_site.B_iso_or_equiv
-_atom_site.auth_seq_id
-_atom_site.auth_asym_id
-_atom_site.pdbx_PDB_model_num
-ATOM 1   N N   . THR J 1 3  ? 180.798 156.981 49.506 1.00 100.87 3  J 1 
-ATOM 2   C CA  . THR J 1 3  ? 180.336 158.053 50.380 1.00 100.87 3  J 1 
-ATOM 3   C C   . THR J 1 3  ? 178.888 157.811 50.811 1.00 100.87 3  J 1 
-ATOM 4   O O   . THR J 1 3  ? 178.076 157.312 50.030 1.00 100.87 3  J 1 
-ATOM 5   C CB  . THR J 1 3  ? 180.468 159.436 49.691 1.00 100.87 3  J 1 
-ATOM 6   O OG1 . THR J 1 3  ? 180.169 160.478 50.627 1.00 100.87 3  J 1 
-ATOM 7   C CG2 . THR J 1 3  ? 179.541 159.546 48.488 1.00 100.87 3  J 1 
-ATOM 8   N N   . PRO J 1 4  ? 178.569 158.139 52.065 1.00 96.05  4  J 1 
-ATOM 9   C CA  . PRO J 1 4  ? 177.201 157.918 52.554 1.00 96.05  4  J 1 
-ATOM 10  C C   . PRO J 1 4  ? 176.203 158.873 51.924 1.00 96.05  4  J 1 
-ATOM 11  O O   . PRO J 1 4  ? 176.293 160.090 52.112 1.00 96.05  4  J 1 
-ATOM 12  C CB  . PRO J 1 4  ? 177.326 158.152 54.065 1.00 96.05  4  J 1 
-ATOM 13  C CG  . PRO J 1 4  ? 178.504 159.047 54.212 1.00 96.05  4  J 1 
-ATOM 14  C CD  . PRO J 1 4  ? 179.457 158.664 53.117 1.00 96.05  4  J 1 
-ATOM 15  N N   . TRP J 1 5  ? 175.251 158.334 51.169 1.00 82.05  5  J 1 
-ATOM 16  C CA  . TRP J 1 5  ? 174.242 159.172 50.543 1.00 82.05  5  J 1 
-ATOM 17  C C   . TRP J 1 5  ? 173.275 159.710 51.591 1.00 82.05  5  J 1 
-ATOM 18  O O   . TRP J 1 5  ? 173.068 159.105 52.647 1.00 82.05  5  J 1 
-ATOM 19  C CB  . TRP J 1 5  ? 173.467 158.390 49.486 1.00 82.05  5  J 1 
-ATOM 20  C CG  . TRP J 1 5  ? 172.575 159.261 48.675 1.00 82.05  5  J 1 
-ATOM 21  C CD1 . TRP J 1 5  ? 172.953 160.130 47.697 1.00 82.05  5  J 1 
-ATOM 22  C CD2 . TRP J 1 5  ? 171.158 159.402 48.811 1.00 82.05  5  J 1 
-ATOM 23  N NE1 . TRP J 1 5  ? 171.856 160.778 47.189 1.00 82.05  5  J 1 
-ATOM 24  C CE2 . TRP J 1 5  ? 170.741 160.351 47.859 1.00 82.05  5  J 1 
-ATOM 25  C CE3 . TRP J 1 5  ? 170.199 158.807 49.634 1.00 82.05  5  J 1 
-ATOM 26  C CZ2 . TRP J 1 5  ? 169.408 160.720 47.709 1.00 82.05  5  J 1 
-ATOM 27  C CZ3 . TRP J 1 5  ? 168.877 159.176 49.482 1.00 82.05  5  J 1 
-ATOM 28  C CH2 . TRP J 1 5  ? 168.493 160.120 48.527 1.00 82.05  5  J 1 
-ATOM 29  N N   . SER J 1 6  ? 172.676 160.860 51.291 1.00 78.94  6  J 1 
-ATOM 30  C CA  . SER J 1 6  ? 171.730 161.484 52.213 1.00 78.94  6  J 1 
-ATOM 31  C C   . SER J 1 6  ? 170.799 162.391 51.422 1.00 78.94  6  J 1 
-ATOM 32  O O   . SER J 1 6  ? 171.235 163.417 50.892 1.00 78.94  6  J 1 
-ATOM 33  C CB  . SER J 1 6  ? 172.462 162.265 53.300 1.00 78.94  6  J 1 
-ATOM 34  O OG  . SER J 1 6  ? 173.149 161.389 54.176 1.00 78.94  6  J 1 
-ATOM 35  N N   . GLY J 1 7  ? 169.526 162.014 51.347 1.00 80.09  7  J 1 
-ATOM 36  C CA  . GLY J 1 7  ? 168.512 162.855 50.750 1.00 80.09  7  J 1 
-ATOM 37  C C   . GLY J 1 7  ? 168.082 163.958 51.698 1.00 80.09  7  J 1 
-ATOM 38  O O   . GLY J 1 7  ? 168.539 164.059 52.838 1.00 80.09  7  J 1 
-ATOM 39  N N   . TYR J 1 8  ? 167.174 164.804 51.207 1.00 78.37  8  J 1 
-ATOM 40  C CA  . TYR J 1 8  ? 166.760 165.964 51.991 1.00 78.37  8  J 1 
-ATOM 41  C C   . TYR J 1 8  ? 166.084 165.523 53.284 1.00 78.37  8  J 1 
-ATOM 42  O O   . TYR J 1 8  ? 166.332 166.093 54.351 1.00 78.37  8  J 1 
-ATOM 43  C CB  . TYR J 1 8  ? 165.830 166.858 51.167 1.00 78.37  8  J 1 
-ATOM 44  C CG  . TYR J 1 8  ? 165.412 168.151 51.846 1.00 78.37  8  J 1 
-ATOM 45  C CD1 . TYR J 1 8  ? 164.409 168.939 51.311 1.00 78.37  8  J 1 
-ATOM 46  C CD2 . TYR J 1 8  ? 166.073 168.622 52.974 1.00 78.37  8  J 1 
-ATOM 47  C CE1 . TYR J 1 8  ? 164.036 170.122 51.913 1.00 78.37  8  J 1 
-ATOM 48  C CE2 . TYR J 1 8  ? 165.705 169.801 53.581 1.00 78.37  8  J 1 
-ATOM 49  C CZ  . TYR J 1 8  ? 164.688 170.550 53.044 1.00 78.37  8  J 1 
-ATOM 50  O OH  . TYR J 1 8  ? 164.318 171.735 53.638 1.00 78.37  8  J 1 
-ATOM 51  N N   . LEU J 1 9  ? 165.226 164.506 53.213 1.00 73.64  9  J 1 
-ATOM 52  C CA  . LEU J 1 9  ? 164.645 163.967 54.439 1.00 73.64  9  J 1 
-ATOM 53  C C   . LEU J 1 9  ? 165.730 163.390 55.340 1.00 73.64  9  J 1 
-ATOM 54  O O   . LEU J 1 9  ? 165.719 163.604 56.560 1.00 73.64  9  J 1 
-ATOM 55  C CB  . LEU J 1 9  ? 163.595 162.906 54.109 1.00 73.64  9  J 1 
-ATOM 56  C CG  . LEU J 1 9  ? 162.192 163.335 53.661 1.00 73.64  9  J 1 
-ATOM 57  C CD1 . LEU J 1 9  ? 162.211 164.303 52.488 1.00 73.64  9  J 1 
-ATOM 58  C CD2 . LEU J 1 9  ? 161.355 162.112 53.321 1.00 73.64  9  J 1 
-ATOM 59  N N   . ASP J 1 10 ? 166.683 162.668 54.750 1.00 75.23  10 J 1 
-ATOM 60  C CA  . ASP J 1 10 ? 167.828 162.189 55.511 1.00 75.23  10 J 1 
-ATOM 61  C C   . ASP J 1 10 ? 168.631 163.360 56.062 1.00 75.23  10 J 1 
-ATOM 62  O O   . ASP J 1 10 ? 169.140 163.297 57.186 1.00 75.23  10 J 1 
-ATOM 63  C CB  . ASP J 1 10 ? 168.695 161.293 54.624 1.00 75.23  10 J 1 
-ATOM 64  C CG  . ASP J 1 10 ? 169.793 160.577 55.393 1.00 75.23  10 J 1 
-ATOM 65  O OD1 . ASP J 1 10 ? 169.921 160.785 56.617 1.00 75.23  10 J 1 
-ATOM 66  O OD2 . ASP J 1 10 ? 170.537 159.796 54.764 1.00 75.23  10 J 1 
-ATOM 67  N N   . ASP J 1 11 ? 168.742 164.442 55.289 1.00 76.21  11 J 1 
-ATOM 68  C CA  . ASP J 1 11 ? 169.449 165.624 55.770 1.00 76.21  11 J 1 
-ATOM 69  C C   . ASP J 1 11 ? 168.755 166.229 56.984 1.00 76.21  11 J 1 
-ATOM 70  O O   . ASP J 1 11 ? 169.416 166.658 57.932 1.00 76.21  11 J 1 
-ATOM 71  C CB  . ASP J 1 11 ? 169.573 166.658 54.651 1.00 76.21  11 J 1 
-ATOM 72  C CG  . ASP J 1 11 ? 170.510 166.210 53.546 1.00 76.21  11 J 1 
-ATOM 73  O OD1 . ASP J 1 11 ? 171.452 165.444 53.836 1.00 76.21  11 J 1 
-ATOM 74  O OD2 . ASP J 1 11 ? 170.303 166.623 52.386 1.00 76.21  11 J 1 
-ATOM 75  N N   . VAL J 1 12 ? 167.423 166.274 56.973 1.00 71.19  12 J 1 
-ATOM 76  C CA  . VAL J 1 12 ? 166.679 166.814 58.107 1.00 71.19  12 J 1 
-ATOM 77  C C   . VAL J 1 12 ? 166.846 165.921 59.330 1.00 71.19  12 J 1 
-ATOM 78  O O   . VAL J 1 12 ? 167.032 166.405 60.457 1.00 71.19  12 J 1 
-ATOM 79  C CB  . VAL J 1 12 ? 165.197 166.989 57.729 1.00 71.19  12 J 1 
-ATOM 80  C CG1 . VAL J 1 12 ? 164.358 167.240 58.967 1.00 71.19  12 J 1 
-ATOM 81  C CG2 . VAL J 1 12 ? 165.039 168.124 56.733 1.00 71.19  12 J 1 
-ATOM 82  N N   . SER J 1 13 ? 166.779 164.604 59.130 1.00 71.31  13 J 1 
-ATOM 83  C CA  . SER J 1 13 ? 167.004 163.691 60.244 1.00 71.31  13 J 1 
-ATOM 84  C C   . SER J 1 13 ? 168.397 163.882 60.831 1.00 71.31  13 J 1 
-ATOM 85  O O   . SER J 1 13 ? 168.555 163.965 62.054 1.00 71.31  13 J 1 
-ATOM 86  C CB  . SER J 1 13 ? 166.801 162.246 59.794 1.00 71.31  13 J 1 
-ATOM 87  O OG  . SER J 1 13 ? 165.459 162.023 59.402 1.00 71.31  13 J 1 
-ATOM 88  N N   . ALA J 1 14 ? 169.413 163.985 59.972 1.00 73.94  14 J 1 
-ATOM 89  C CA  . ALA J 1 14 ? 170.773 164.209 60.451 1.00 73.94  14 J 1 
-ATOM 90  C C   . ALA J 1 14 ? 170.904 165.566 61.130 1.00 73.94  14 J 1 
-ATOM 91  O O   . ALA J 1 14 ? 171.700 165.728 62.061 1.00 73.94  14 J 1 
-ATOM 92  C CB  . ALA J 1 14 ? 171.765 164.087 59.295 1.00 73.94  14 J 1 
-ATOM 93  N N   . LYS J 1 15 ? 170.140 166.557 60.668 1.00 71.21  15 J 1 
-ATOM 94  C CA  . LYS J 1 15 ? 170.140 167.860 61.321 1.00 71.21  15 J 1 
-ATOM 95  C C   . LYS J 1 15 ? 169.612 167.753 62.742 1.00 71.21  15 J 1 
-ATOM 96  O O   . LYS J 1 15 ? 170.146 168.383 63.660 1.00 71.21  15 J 1 
-ATOM 97  C CB  . LYS J 1 15 ? 169.311 168.855 60.511 1.00 71.21  15 J 1 
-ATOM 98  C CG  . LYS J 1 15 ? 170.142 169.773 59.635 1.00 71.21  15 J 1 
-ATOM 99  C CD  . LYS J 1 15 ? 169.313 170.920 59.089 1.00 71.21  15 J 1 
-ATOM 100 C CE  . LYS J 1 15 ? 170.176 171.888 58.300 1.00 71.21  15 J 1 
-ATOM 101 N NZ  . LYS J 1 15 ? 169.369 172.970 57.676 1.00 71.21  15 J 1 
-ATOM 102 N N   . PHE J 1 16 ? 168.559 166.963 62.943 1.00 68.61  16 J 1 
-ATOM 103 C CA  . PHE J 1 16 ? 168.102 166.713 64.308 1.00 68.61  16 J 1 
-ATOM 104 C C   . PHE J 1 16 ? 169.128 165.927 65.120 1.00 68.61  16 J 1 
-ATOM 105 O O   . PHE J 1 16 ? 169.342 166.226 66.300 1.00 68.61  16 J 1 
-ATOM 106 C CB  . PHE J 1 16 ? 166.749 166.005 64.309 1.00 68.61  16 J 1 
-ATOM 107 C CG  . PHE J 1 16 ? 165.587 166.929 64.088 1.00 68.61  16 J 1 
-ATOM 108 C CD1 . PHE J 1 16 ? 165.736 168.293 64.256 1.00 68.61  16 J 1 
-ATOM 109 C CD2 . PHE J 1 16 ? 164.345 166.437 63.736 1.00 68.61  16 J 1 
-ATOM 110 C CE1 . PHE J 1 16 ? 164.670 169.147 64.068 1.00 68.61  16 J 1 
-ATOM 111 C CE2 . PHE J 1 16 ? 163.277 167.286 63.544 1.00 68.61  16 J 1 
-ATOM 112 C CZ  . PHE J 1 16 ? 163.439 168.643 63.710 1.00 68.61  16 J 1 
-ATOM 113 N N   . ASP J 1 17 ? 169.768 164.918 64.521 1.00 77.06  17 J 1 
-ATOM 114 C CA  . ASP J 1 17 ? 170.752 164.149 65.286 1.00 77.06  17 J 1 
-ATOM 115 C C   . ASP J 1 17 ? 171.927 165.017 65.719 1.00 77.06  17 J 1 
-ATOM 116 O O   . ASP J 1 17 ? 172.413 164.888 66.848 1.00 77.06  17 J 1 
-ATOM 117 C CB  . ASP J 1 17 ? 171.254 162.929 64.509 1.00 77.06  17 J 1 
-ATOM 118 C CG  . ASP J 1 17 ? 170.136 162.119 63.888 1.00 77.06  17 J 1 
-ATOM 119 O OD1 . ASP J 1 17 ? 170.103 162.001 62.647 1.00 77.06  17 J 1 
-ATOM 120 O OD2 . ASP J 1 17 ? 169.286 161.602 64.642 1.00 77.06  17 J 1 
-ATOM 121 N N   . THR J 1 18 ? 172.399 165.901 64.845 1.00 76.90  18 J 1 
-ATOM 122 C CA  . THR J 1 18 ? 173.485 166.801 65.205 1.00 76.90  18 J 1 
-ATOM 123 C C   . THR J 1 18 ? 173.016 167.991 66.028 1.00 76.90  18 J 1 
-ATOM 124 O O   . THR J 1 18 ? 173.851 168.678 66.626 1.00 76.90  18 J 1 
-ATOM 125 C CB  . THR J 1 18 ? 174.203 167.303 63.949 1.00 76.90  18 J 1 
-ATOM 126 O OG1 . THR J 1 18 ? 175.476 167.849 64.314 1.00 76.90  18 J 1 
-ATOM 127 C CG2 . THR J 1 18 ? 173.381 168.373 63.253 1.00 76.90  18 J 1 
-ATOM 128 N N   . GLY J 1 19 ? 171.709 168.255 66.067 1.00 78.19  19 J 1 
-ATOM 129 C CA  . GLY J 1 19 ? 171.207 169.320 66.916 1.00 78.19  19 J 1 
-ATOM 130 C C   . GLY J 1 19 ? 171.381 169.012 68.389 1.00 78.19  19 J 1 
-ATOM 131 O O   . GLY J 1 19 ? 171.777 169.879 69.172 1.00 78.19  19 J 1 
-ATOM 132 N N   . VAL J 1 20 ? 171.089 167.780 68.785 1.00 76.12  20 J 1 
-ATOM 133 C CA  . VAL J 1 20 ? 171.317 167.329 70.150 1.00 76.12  20 J 1 
-ATOM 134 C C   . VAL J 1 20 ? 172.694 166.684 70.220 1.00 76.12  20 J 1 
-ATOM 135 O O   . VAL J 1 20 ? 173.054 165.862 69.368 1.00 76.12  20 J 1 
-ATOM 136 C CB  . VAL J 1 20 ? 170.212 166.362 70.606 1.00 76.12  20 J 1 
-ATOM 137 C CG1 . VAL J 1 20 ? 168.869 167.069 70.596 1.00 76.12  20 J 1 
-ATOM 138 C CG2 . VAL J 1 20 ? 170.158 165.132 69.713 1.00 76.12  20 J 1 
-ATOM 139 N N   . ASP J 1 21 ? 173.487 167.090 71.210 1.00 78.41  21 J 1 
-ATOM 140 C CA  . ASP J 1 21 ? 174.863 166.617 71.290 1.00 78.41  21 J 1 
-ATOM 141 C C   . ASP J 1 21 ? 174.916 165.113 71.524 1.00 78.41  21 J 1 
-ATOM 142 O O   . ASP J 1 21 ? 175.347 164.349 70.653 1.00 78.41  21 J 1 
-ATOM 143 C CB  . ASP J 1 21 ? 175.608 167.363 72.396 1.00 78.41  21 J 1 
-ATOM 144 C CG  . ASP J 1 21 ? 175.835 168.824 72.061 1.00 78.41  21 J 1 
-ATOM 145 O OD1 . ASP J 1 21 ? 175.946 169.149 70.861 1.00 78.41  21 J 1 
-ATOM 146 O OD2 . ASP J 1 21 ? 175.903 169.647 72.998 1.00 78.41  21 J 1 
-ATOM 147 N N   . ASN J 1 22 ? 174.471 164.668 72.693 1.00 74.91  22 J 1 
-ATOM 148 C CA  . ASN J 1 22 ? 174.565 163.267 73.084 1.00 74.91  22 J 1 
-ATOM 149 C C   . ASN J 1 22 ? 173.277 162.819 73.765 1.00 74.91  22 J 1 
-ATOM 150 O O   . ASN J 1 22 ? 173.294 162.151 74.799 1.00 74.91  22 J 1 
-ATOM 151 C CB  . ASN J 1 22 ? 175.777 163.050 73.987 1.00 74.91  22 J 1 
-ATOM 152 C CG  . ASN J 1 22 ? 175.825 164.032 75.138 1.00 74.91  22 J 1 
-ATOM 153 O OD1 . ASN J 1 22 ? 174.925 164.855 75.304 1.00 74.91  22 J 1 
-ATOM 154 N ND2 . ASN J 1 22 ? 176.881 163.956 75.938 1.00 74.91  22 J 1 
-ATOM 155 N N   . LEU J 1 23 ? 172.134 163.193 73.182 1.00 72.21  23 J 1 
-ATOM 156 C CA  . LEU J 1 23 ? 170.852 162.915 73.824 1.00 72.21  23 J 1 
-ATOM 157 C C   . LEU J 1 23 ? 170.648 161.425 74.053 1.00 72.21  23 J 1 
-ATOM 158 O O   . LEU J 1 23 ? 170.248 161.010 75.146 1.00 72.21  23 J 1 
-ATOM 159 C CB  . LEU J 1 23 ? 169.708 163.483 72.989 1.00 72.21  23 J 1 
-ATOM 160 C CG  . LEU J 1 23 ? 168.328 163.271 73.612 1.00 72.21  23 J 1 
-ATOM 161 C CD1 . LEU J 1 23 ? 168.229 163.983 74.946 1.00 72.21  23 J 1 
-ATOM 162 C CD2 . LEU J 1 23 ? 167.237 163.743 72.669 1.00 72.21  23 J 1 
-ATOM 163 N N   . GLN J 1 24 ? 170.920 160.601 73.039 1.00 70.63  24 J 1 
-ATOM 164 C CA  . GLN J 1 24 ? 170.840 159.157 73.230 1.00 70.63  24 J 1 
-ATOM 165 C C   . GLN J 1 24 ? 171.802 158.707 74.320 1.00 70.63  24 J 1 
-ATOM 166 O O   . GLN J 1 24 ? 171.425 157.974 75.242 1.00 70.63  24 J 1 
-ATOM 167 C CB  . GLN J 1 24 ? 171.143 158.435 71.917 1.00 70.63  24 J 1 
-ATOM 168 C CG  . GLN J 1 24 ? 170.834 156.949 71.947 1.00 70.63  24 J 1 
-ATOM 169 C CD  . GLN J 1 24 ? 169.405 156.644 71.556 1.00 70.63  24 J 1 
-ATOM 170 O OE1 . GLN J 1 24 ? 168.697 157.505 71.042 1.00 70.63  24 J 1 
-ATOM 171 N NE2 . GLN J 1 24 ? 168.972 155.412 71.801 1.00 70.63  24 J 1 
-ATOM 172 N N   . THR J 1 25 ? 173.052 159.167 74.242 1.00 72.05  25 J 1 
-ATOM 173 C CA  . THR J 1 25 ? 174.029 158.829 75.267 1.00 72.05  25 J 1 
-ATOM 174 C C   . THR J 1 25 ? 173.628 159.382 76.627 1.00 72.05  25 J 1 
-ATOM 175 O O   . THR J 1 25 ? 173.752 158.681 77.636 1.00 72.05  25 J 1 
-ATOM 176 C CB  . THR J 1 25 ? 175.407 159.349 74.865 1.00 72.05  25 J 1 
-ATOM 177 O OG1 . THR J 1 25 ? 175.777 158.785 73.601 1.00 72.05  25 J 1 
-ATOM 178 C CG2 . THR J 1 25 ? 176.447 158.961 75.898 1.00 72.05  25 J 1 
-ATOM 179 N N   . GLN J 1 26 ? 173.147 160.627 76.676 1.00 73.20  26 J 1 
-ATOM 180 C CA  . GLN J 1 26 ? 172.756 161.219 77.951 1.00 73.20  26 J 1 
-ATOM 181 C C   . GLN J 1 26 ? 171.656 160.400 78.610 1.00 73.20  26 J 1 
-ATOM 182 O O   . GLN J 1 26 ? 171.709 160.118 79.814 1.00 73.20  26 J 1 
-ATOM 183 C CB  . GLN J 1 26 ? 172.301 162.663 77.739 1.00 73.20  26 J 1 
-ATOM 184 C CG  . GLN J 1 26 ? 173.397 163.693 77.939 1.00 73.20  26 J 1 
-ATOM 185 C CD  . GLN J 1 26 ? 172.920 165.105 77.674 1.00 73.20  26 J 1 
-ATOM 186 O OE1 . GLN J 1 26 ? 171.782 165.454 77.979 1.00 73.20  26 J 1 
-ATOM 187 N NE2 . GLN J 1 26 ? 173.791 165.926 77.101 1.00 73.20  26 J 1 
-ATOM 188 N N   . VAL J 1 27 ? 170.660 159.989 77.824 1.00 70.38  27 J 1 
-ATOM 189 C CA  . VAL J 1 27 ? 169.615 159.113 78.339 1.00 70.38  27 J 1 
-ATOM 190 C C   . VAL J 1 27 ? 170.211 157.789 78.796 1.00 70.38  27 J 1 
-ATOM 191 O O   . VAL J 1 27 ? 169.787 157.217 79.808 1.00 70.38  27 J 1 
-ATOM 192 C CB  . VAL J 1 27 ? 168.521 158.911 77.274 1.00 70.38  27 J 1 
-ATOM 193 C CG1 . VAL J 1 27 ? 167.570 157.803 77.685 1.00 70.38  27 J 1 
-ATOM 194 C CG2 . VAL J 1 27 ? 167.761 160.204 77.059 1.00 70.38  27 J 1 
-ATOM 195 N N   . THR J 1 28 ? 171.208 157.285 78.067 1.00 66.97  28 J 1 
-ATOM 196 C CA  . THR J 1 28 ? 171.814 156.011 78.437 1.00 66.97  28 J 1 
-ATOM 197 C C   . THR J 1 28 ? 172.453 156.080 79.821 1.00 66.97  28 J 1 
-ATOM 198 O O   . THR J 1 28 ? 172.163 155.246 80.688 1.00 66.97  28 J 1 
-ATOM 199 C CB  . THR J 1 28 ? 172.841 155.591 77.388 1.00 66.97  28 J 1 
-ATOM 200 O OG1 . THR J 1 28 ? 172.192 155.449 76.118 1.00 66.97  28 J 1 
-ATOM 201 C CG2 . THR J 1 28 ? 173.475 154.265 77.774 1.00 66.97  28 J 1 
-ATOM 202 N N   . GLU J 1 29 ? 173.322 157.072 80.055 1.00 72.66  29 J 1 
-ATOM 203 C CA  . GLU J 1 29 ? 173.906 157.156 81.396 1.00 72.66  29 J 1 
-ATOM 204 C C   . GLU J 1 29 ? 172.874 157.531 82.451 1.00 72.66  29 J 1 
-ATOM 205 O O   . GLU J 1 29 ? 172.996 157.088 83.594 1.00 72.66  29 J 1 
-ATOM 206 C CB  . GLU J 1 29 ? 175.107 158.111 81.526 1.00 72.66  29 J 1 
-ATOM 207 C CG  . GLU J 1 29 ? 176.428 157.677 80.874 1.00 72.66  29 J 1 
-ATOM 208 C CD  . GLU J 1 29 ? 176.594 158.116 79.452 1.00 72.66  29 J 1 
-ATOM 209 O OE1 . GLU J 1 29 ? 175.740 158.874 78.981 1.00 72.66  29 J 1 
-ATOM 210 O OE2 . GLU J 1 29 ? 177.582 157.707 78.806 1.00 72.66  29 J 1 
-ATOM 211 N N   . ALA J 1 30 ? 171.858 158.331 82.113 1.00 71.55  30 J 1 
-ATOM 212 C CA  . ALA J 1 30 ? 170.840 158.641 83.113 1.00 71.55  30 J 1 
-ATOM 213 C C   . ALA J 1 30 ? 170.124 157.377 83.571 1.00 71.55  30 J 1 
-ATOM 214 O O   . ALA J 1 30 ? 169.974 157.134 84.776 1.00 71.55  30 J 1 
-ATOM 215 C CB  . ALA J 1 30 ? 169.842 159.654 82.555 1.00 71.55  30 J 1 
-ATOM 216 N N   . LEU J 1 31 ? 169.710 156.541 82.619 1.00 67.57  31 J 1 
-ATOM 217 C CA  . LEU J 1 31 ? 169.026 155.299 82.949 1.00 67.57  31 J 1 
-ATOM 218 C C   . LEU J 1 31 ? 169.947 154.332 83.681 1.00 67.57  31 J 1 
-ATOM 219 O O   . LEU J 1 31 ? 169.513 153.645 84.613 1.00 67.57  31 J 1 
-ATOM 220 C CB  . LEU J 1 31 ? 168.470 154.664 81.675 1.00 67.57  31 J 1 
-ATOM 221 C CG  . LEU J 1 31 ? 167.565 153.444 81.827 1.00 67.57  31 J 1 
-ATOM 222 C CD1 . LEU J 1 31 ? 166.434 153.521 80.822 1.00 67.57  31 J 1 
-ATOM 223 C CD2 . LEU J 1 31 ? 168.355 152.161 81.641 1.00 67.57  31 J 1 
-ATOM 224 N N   . ASP J 1 32 ? 171.217 154.256 83.275 1.00 72.67  32 J 1 
-ATOM 225 C CA  . ASP J 1 32 ? 172.149 153.367 83.960 1.00 72.67  32 J 1 
-ATOM 226 C C   . ASP J 1 32 ? 172.379 153.821 85.398 1.00 72.67  32 J 1 
-ATOM 227 O O   . ASP J 1 32 ? 172.414 152.997 86.319 1.00 72.67  32 J 1 
-ATOM 228 C CB  . ASP J 1 32 ? 173.467 153.305 83.188 1.00 72.67  32 J 1 
-ATOM 229 C CG  . ASP J 1 32 ? 174.413 152.240 83.718 1.00 72.67  32 J 1 
-ATOM 230 O OD1 . ASP J 1 32 ? 174.073 151.558 84.706 1.00 72.67  32 J 1 
-ATOM 231 O OD2 . ASP J 1 32 ? 175.507 152.083 83.137 1.00 72.67  32 J 1 
-ATOM 232 N N   . LYS J 1 33 ? 172.532 155.130 85.610 1.00 71.55  33 J 1 
-ATOM 233 C CA  . LYS J 1 33 ? 172.715 155.655 86.958 1.00 71.55  33 J 1 
-ATOM 234 C C   . LYS J 1 33 ? 171.496 155.382 87.824 1.00 71.55  33 J 1 
-ATOM 235 O O   . LYS J 1 33 ? 171.628 155.006 88.994 1.00 71.55  33 J 1 
-ATOM 236 C CB  . LYS J 1 33 ? 173.001 157.155 86.900 1.00 71.55  33 J 1 
-ATOM 237 C CG  . LYS J 1 33 ? 174.385 157.517 86.392 1.00 71.55  33 J 1 
-ATOM 238 C CD  . LYS J 1 33 ? 174.482 159.007 86.104 1.00 71.55  33 J 1 
-ATOM 239 C CE  . LYS J 1 33 ? 174.396 159.829 87.379 1.00 71.55  33 J 1 
-ATOM 240 N NZ  . LYS J 1 33 ? 174.607 161.279 87.119 1.00 71.55  33 J 1 
-ATOM 241 N N   . LEU J 1 34 ? 170.296 155.566 87.269 1.00 70.34  34 J 1 
-ATOM 242 C CA  . LEU J 1 34 ? 169.095 155.291 88.045 1.00 70.34  34 J 1 
-ATOM 243 C C   . LEU J 1 34 ? 168.944 153.807 88.358 1.00 70.34  34 J 1 
-ATOM 244 O O   . LEU J 1 34 ? 168.263 153.458 89.327 1.00 70.34  34 J 1 
-ATOM 245 C CB  . LEU J 1 34 ? 167.865 155.824 87.305 1.00 70.34  34 J 1 
-ATOM 246 C CG  . LEU J 1 34 ? 166.493 155.819 87.987 1.00 70.34  34 J 1 
-ATOM 247 C CD1 . LEU J 1 34 ? 165.645 156.923 87.403 1.00 70.34  34 J 1 
-ATOM 248 C CD2 . LEU J 1 34 ? 165.773 154.496 87.808 1.00 70.34  34 J 1 
-ATOM 249 N N   . ALA J 1 35 ? 169.587 152.930 87.582 1.00 66.69  35 J 1 
-ATOM 250 C CA  . ALA J 1 35 ? 169.434 151.494 87.785 1.00 66.69  35 J 1 
-ATOM 251 C C   . ALA J 1 35 ? 169.942 151.034 89.144 1.00 66.69  35 J 1 
-ATOM 252 O O   . ALA J 1 35 ? 169.492 149.995 89.640 1.00 66.69  35 J 1 
-ATOM 253 C CB  . ALA J 1 35 ? 170.153 150.726 86.678 1.00 66.69  35 J 1 
-ATOM 254 N N   . ALA J 1 36 ? 170.865 151.775 89.759 1.00 67.09  36 J 1 
-ATOM 255 C CA  . ALA J 1 36 ? 171.402 151.403 91.059 1.00 67.09  36 J 1 
-ATOM 256 C C   . ALA J 1 36 ? 171.016 152.357 92.179 1.00 67.09  36 J 1 
-ATOM 257 O O   . ALA J 1 36 ? 171.066 151.959 93.347 1.00 67.09  36 J 1 
-ATOM 258 C CB  . ALA J 1 36 ? 172.933 151.307 90.996 1.00 67.09  36 J 1 
-ATOM 259 N N   . LYS J 1 37 ? 170.632 153.590 91.860 1.00 66.94  37 J 1 
-ATOM 260 C CA  . LYS J 1 37 ? 170.209 154.579 92.850 1.00 66.94  37 J 1 
-ATOM 261 C C   . LYS J 1 37 ? 168.843 155.099 92.431 1.00 66.94  37 J 1 
-ATOM 262 O O   . LYS J 1 37 ? 168.736 156.111 91.726 1.00 66.94  37 J 1 
-ATOM 263 C CB  . LYS J 1 37 ? 171.229 155.709 92.979 1.00 66.94  37 J 1 
-ATOM 264 C CG  . LYS J 1 37 ? 172.582 155.242 93.477 1.00 66.94  37 J 1 
-ATOM 265 C CD  . LYS J 1 37 ? 172.450 154.552 94.823 1.00 66.94  37 J 1 
-ATOM 266 C CE  . LYS J 1 37 ? 173.808 154.194 95.400 1.00 66.94  37 J 1 
-ATOM 267 N NZ  . LYS J 1 37 ? 173.680 153.478 96.700 1.00 66.94  37 J 1 
-ATOM 268 N N   . PRO J 1 38 ? 167.768 154.426 92.850 1.00 68.68  38 J 1 
-ATOM 269 C CA  . PRO J 1 38 ? 166.442 154.759 92.315 1.00 68.68  38 J 1 
-ATOM 270 C C   . PRO J 1 38 ? 165.804 155.974 92.952 1.00 68.68  38 J 1 
-ATOM 271 O O   . PRO J 1 38 ? 165.061 156.684 92.265 1.00 68.68  38 J 1 
-ATOM 272 C CB  . PRO J 1 38 ? 165.630 153.501 92.616 1.00 68.68  38 J 1 
-ATOM 273 C CG  . PRO J 1 38 ? 166.222 153.021 93.902 1.00 68.68  38 J 1 
-ATOM 274 C CD  . PRO J 1 38 ? 167.701 153.332 93.834 1.00 68.68  38 J 1 
-ATOM 275 N N   . SER J 1 39 ? 166.056 156.240 94.230 1.00 70.54  39 J 1 
-ATOM 276 C CA  . SER J 1 39 ? 165.383 157.320 94.933 1.00 70.54  39 J 1 
-ATOM 277 C C   . SER J 1 39 ? 166.204 158.596 94.992 1.00 70.54  39 J 1 
-ATOM 278 O O   . SER J 1 39 ? 165.705 159.612 95.488 1.00 70.54  39 J 1 
-ATOM 279 C CB  . SER J 1 39 ? 165.027 156.887 96.360 1.00 70.54  39 J 1 
-ATOM 280 O OG  . SER J 1 39 ? 166.196 156.601 97.104 1.00 70.54  39 J 1 
-ATOM 281 N N   . ASP J 1 40 ? 167.425 158.579 94.500 1.00 71.51  40 J 1 
-ATOM 282 C CA  . ASP J 1 40 ? 168.310 159.702 94.730 1.00 71.51  40 J 1 
-ATOM 283 C C   . ASP J 1 40 ? 167.868 160.912 93.909 1.00 71.51  40 J 1 
-ATOM 284 O O   . ASP J 1 40 ? 167.348 160.766 92.800 1.00 71.51  40 J 1 
-ATOM 285 C CB  . ASP J 1 40 ? 169.741 159.324 94.374 1.00 71.51  40 J 1 
-ATOM 286 C CG  . ASP J 1 40 ? 170.519 158.829 95.569 1.00 71.51  40 J 1 
-ATOM 287 O OD1 . ASP J 1 40 ? 170.038 159.024 96.701 1.00 71.51  40 J 1 
-ATOM 288 O OD2 . ASP J 1 40 ? 171.606 158.245 95.379 1.00 71.51  40 J 1 
-ATOM 289 N N   . PRO J 1 41 ? 168.040 162.115 94.445 1.00 72.15  41 J 1 
-ATOM 290 C CA  . PRO J 1 41 ? 167.725 163.323 93.677 1.00 72.15  41 J 1 
-ATOM 291 C C   . PRO J 1 41 ? 168.792 163.594 92.630 1.00 72.15  41 J 1 
-ATOM 292 O O   . PRO J 1 41 ? 169.806 162.902 92.531 1.00 72.15  41 J 1 
-ATOM 293 C CB  . PRO J 1 41 ? 167.709 164.427 94.737 1.00 72.15  41 J 1 
-ATOM 294 C CG  . PRO J 1 41 ? 167.558 163.713 96.031 1.00 72.15  41 J 1 
-ATOM 295 C CD  . PRO J 1 41 ? 168.278 162.420 95.862 1.00 72.15  41 J 1 
-ATOM 296 N N   . ALA J 1 42 ? 168.537 164.627 91.831 1.00 68.90  42 J 1 
-ATOM 297 C CA  . ALA J 1 42 ? 169.449 165.183 90.837 1.00 68.90  42 J 1 
-ATOM 298 C C   . ALA J 1 42 ? 169.710 164.237 89.674 1.00 68.90  42 J 1 
-ATOM 299 O O   . ALA J 1 42 ? 170.388 164.632 88.718 1.00 68.90  42 J 1 
-ATOM 300 C CB  . ALA J 1 42 ? 170.795 165.605 91.445 1.00 68.90  42 J 1 
-ATOM 301 N N   . LEU J 1 43 ? 169.199 163.008 89.712 1.00 66.88  43 J 1 
-ATOM 302 C CA  . LEU J 1 43 ? 169.214 162.168 88.523 1.00 66.88  43 J 1 
-ATOM 303 C C   . LEU J 1 43 ? 167.793 161.722 88.216 1.00 66.88  43 J 1 
-ATOM 304 O O   . LEU J 1 43 ? 167.436 161.561 87.048 1.00 66.88  43 J 1 
-ATOM 305 C CB  . LEU J 1 43 ? 170.136 160.956 88.678 1.00 66.88  43 J 1 
-ATOM 306 C CG  . LEU J 1 43 ? 169.723 159.783 89.565 1.00 66.88  43 J 1 
-ATOM 307 C CD1 . LEU J 1 43 ? 170.578 158.575 89.251 1.00 66.88  43 J 1 
-ATOM 308 C CD2 . LEU J 1 43 ? 169.875 160.147 91.011 1.00 66.88  43 J 1 
-ATOM 309 N N   . LEU J 1 44 ? 166.976 161.526 89.255 1.00 62.81  44 J 1 
-ATOM 310 C CA  . LEU J 1 44 ? 165.564 161.231 89.034 1.00 62.81  44 J 1 
-ATOM 311 C C   . LEU J 1 44 ? 164.891 162.349 88.255 1.00 62.81  44 J 1 
-ATOM 312 O O   . LEU J 1 44 ? 164.229 162.103 87.240 1.00 62.81  44 J 1 
-ATOM 313 C CB  . LEU J 1 44 ? 164.850 161.025 90.366 1.00 62.81  44 J 1 
-ATOM 314 C CG  . LEU J 1 44 ? 164.662 159.603 90.876 1.00 62.81  44 J 1 
-ATOM 315 C CD1 . LEU J 1 44 ? 164.144 159.655 92.300 1.00 62.81  44 J 1 
-ATOM 316 C CD2 . LEU J 1 44 ? 163.706 158.844 89.980 1.00 62.81  44 J 1 
-ATOM 317 N N   . ALA J 1 45 ? 165.051 163.589 88.717 1.00 63.51  45 J 1 
-ATOM 318 C CA  . ALA J 1 45 ? 164.565 164.727 87.951 1.00 63.51  45 J 1 
-ATOM 319 C C   . ALA J 1 45 ? 165.278 164.805 86.611 1.00 63.51  45 J 1 
-ATOM 320 O O   . ALA J 1 45 ? 164.660 165.085 85.577 1.00 63.51  45 J 1 
-ATOM 321 C CB  . ALA J 1 45 ? 164.759 166.015 88.748 1.00 63.51  45 J 1 
-ATOM 322 N N   . ALA J 1 46 ? 166.587 164.547 86.611 1.00 63.88  46 J 1 
-ATOM 323 C CA  . ALA J 1 46 ? 167.322 164.470 85.356 1.00 63.88  46 J 1 
-ATOM 324 C C   . ALA J 1 46 ? 166.799 163.335 84.489 1.00 63.88  46 J 1 
-ATOM 325 O O   . ALA J 1 46 ? 166.675 163.486 83.270 1.00 63.88  46 J 1 
-ATOM 326 C CB  . ALA J 1 46 ? 168.815 164.297 85.627 1.00 63.88  46 J 1 
-ATOM 327 N N   . TYR J 1 47 ? 166.483 162.190 85.100 1.00 60.60  47 J 1 
-ATOM 328 C CA  . TYR J 1 47 ? 165.886 161.089 84.350 1.00 60.60  47 J 1 
-ATOM 329 C C   . TYR J 1 47 ? 164.618 161.528 83.639 1.00 60.60  47 J 1 
-ATOM 330 O O   . TYR J 1 47 ? 164.476 161.336 82.427 1.00 60.60  47 J 1 
-ATOM 331 C CB  . TYR J 1 47 ? 165.579 159.921 85.282 1.00 60.60  47 J 1 
-ATOM 332 C CG  . TYR J 1 47 ? 164.985 158.730 84.578 1.00 60.60  47 J 1 
-ATOM 333 C CD1 . TYR J 1 47 ? 165.771 157.885 83.811 1.00 60.60  47 J 1 
-ATOM 334 C CD2 . TYR J 1 47 ? 163.629 158.457 84.675 1.00 60.60  47 J 1 
-ATOM 335 C CE1 . TYR J 1 47 ? 165.223 156.798 83.168 1.00 60.60  47 J 1 
-ATOM 336 C CE2 . TYR J 1 47 ? 163.073 157.376 84.037 1.00 60.60  47 J 1 
-ATOM 337 C CZ  . TYR J 1 47 ? 163.872 156.550 83.285 1.00 60.60  47 J 1 
-ATOM 338 O OH  . TYR J 1 47 ? 163.317 155.471 82.646 1.00 60.60  47 J 1 
-ATOM 339 N N   . GLN J 1 48 ? 163.681 162.118 84.380 1.00 61.22  48 J 1 
-ATOM 340 C CA  . GLN J 1 48 ? 162.418 162.506 83.769 1.00 61.22  48 J 1 
-ATOM 341 C C   . GLN J 1 48 ? 162.618 163.572 82.703 1.00 61.22  48 J 1 
-ATOM 342 O O   . GLN J 1 48 ? 162.021 163.485 81.623 1.00 61.22  48 J 1 
-ATOM 343 C CB  . GLN J 1 48 ? 161.441 163.000 84.832 1.00 61.22  48 J 1 
-ATOM 344 C CG  . GLN J 1 48 ? 160.073 163.333 84.276 1.00 61.22  48 J 1 
-ATOM 345 C CD  . GLN J 1 48 ? 159.096 163.765 85.344 1.00 61.22  48 J 1 
-ATOM 346 O OE1 . GLN J 1 48 ? 159.445 163.860 86.519 1.00 61.22  48 J 1 
-ATOM 347 N NE2 . GLN J 1 48 ? 157.858 164.028 84.941 1.00 61.22  48 J 1 
-ATOM 348 N N   . SER J 1 49 ? 163.461 164.571 82.975 1.00 66.01  49 J 1 
-ATOM 349 C CA  . SER J 1 49 ? 163.666 165.643 82.010 1.00 66.01  49 J 1 
-ATOM 350 C C   . SER J 1 49 ? 164.298 165.117 80.729 1.00 66.01  49 J 1 
-ATOM 351 O O   . SER J 1 49 ? 163.843 165.437 79.628 1.00 66.01  49 J 1 
-ATOM 352 C CB  . SER J 1 49 ? 164.529 166.744 82.623 1.00 66.01  49 J 1 
-ATOM 353 O OG  . SER J 1 49 ? 164.839 167.732 81.658 1.00 66.01  49 J 1 
-ATOM 354 N N   . LYS J 1 50 ? 165.348 164.301 80.851 1.00 62.23  50 J 1 
-ATOM 355 C CA  . LYS J 1 50 ? 165.992 163.755 79.662 1.00 62.23  50 J 1 
-ATOM 356 C C   . LYS J 1 50 ? 165.074 162.806 78.908 1.00 62.23  50 J 1 
-ATOM 357 O O   . LYS J 1 50 ? 165.080 162.796 77.674 1.00 62.23  50 J 1 
-ATOM 358 C CB  . LYS J 1 50 ? 167.292 163.045 80.036 1.00 62.23  50 J 1 
-ATOM 359 C CG  . LYS J 1 50 ? 168.320 163.948 80.688 1.00 62.23  50 J 1 
-ATOM 360 C CD  . LYS J 1 50 ? 168.804 165.014 79.725 1.00 62.23  50 J 1 
-ATOM 361 C CE  . LYS J 1 50 ? 169.815 165.927 80.391 1.00 62.23  50 J 1 
-ATOM 362 N NZ  . LYS J 1 50 ? 171.093 165.218 80.672 1.00 62.23  50 J 1 
-ATOM 363 N N   . LEU J 1 51 ? 164.282 162.004 79.620 1.00 55.13  51 J 1 
-ATOM 364 C CA  . LEU J 1 51 ? 163.386 161.078 78.942 1.00 55.13  51 J 1 
-ATOM 365 C C   . LEU J 1 51 ? 162.306 161.830 78.175 1.00 55.13  51 J 1 
-ATOM 366 O O   . LEU J 1 51 ? 161.984 161.482 77.034 1.00 55.13  51 J 1 
-ATOM 367 C CB  . LEU J 1 51 ? 162.773 160.118 79.955 1.00 55.13  51 J 1 
-ATOM 368 C CG  . LEU J 1 51 ? 161.865 159.044 79.373 1.00 55.13  51 J 1 
-ATOM 369 C CD1 . LEU J 1 51 ? 162.675 158.158 78.450 1.00 55.13  51 J 1 
-ATOM 370 C CD2 . LEU J 1 51 ? 161.246 158.227 80.487 1.00 55.13  51 J 1 
-ATOM 371 N N   . SER J 1 52 ? 161.739 162.876 78.783 1.00 58.66  52 J 1 
-ATOM 372 C CA  . SER J 1 52 ? 160.769 163.700 78.069 1.00 58.66  52 J 1 
-ATOM 373 C C   . SER J 1 52 ? 161.418 164.423 76.896 1.00 58.66  52 J 1 
-ATOM 374 O O   . SER J 1 52 ? 160.815 164.553 75.825 1.00 58.66  52 J 1 
-ATOM 375 C CB  . SER J 1 52 ? 160.119 164.699 79.023 1.00 58.66  52 J 1 
-ATOM 376 O OG  . SER J 1 52 ? 159.266 164.041 79.940 1.00 58.66  52 J 1 
-ATOM 377 N N   . GLU J 1 53 ? 162.646 164.910 77.081 1.00 65.81  53 J 1 
-ATOM 378 C CA  . GLU J 1 53 ? 163.360 165.549 75.985 1.00 65.81  53 J 1 
-ATOM 379 C C   . GLU J 1 53 ? 163.519 164.593 74.816 1.00 65.81  53 J 1 
-ATOM 380 O O   . GLU J 1 53 ? 163.285 164.966 73.663 1.00 65.81  53 J 1 
-ATOM 381 C CB  . GLU J 1 53 ? 164.729 166.027 76.468 1.00 65.81  53 J 1 
-ATOM 382 C CG  . GLU J 1 53 ? 164.823 167.501 76.834 1.00 65.81  53 J 1 
-ATOM 383 C CD  . GLU J 1 53 ? 164.613 168.437 75.659 1.00 65.81  53 J 1 
-ATOM 384 O OE1 . GLU J 1 53 ? 164.395 167.965 74.524 1.00 65.81  53 J 1 
-ATOM 385 O OE2 . GLU J 1 53 ? 164.659 169.667 75.875 1.00 65.81  53 J 1 
-ATOM 386 N N   . TYR J 1 54 ? 163.901 163.351 75.104 1.00 59.32  54 J 1 
-ATOM 387 C CA  . TYR J 1 54 ? 164.070 162.346 74.065 1.00 59.32  54 J 1 
-ATOM 388 C C   . TYR J 1 54 ? 162.742 162.013 73.396 1.00 59.32  54 J 1 
-ATOM 389 O O   . TYR J 1 54 ? 162.683 161.828 72.175 1.00 59.32  54 J 1 
-ATOM 390 C CB  . TYR J 1 54 ? 164.710 161.104 74.676 1.00 59.32  54 J 1 
-ATOM 391 C CG  . TYR J 1 54 ? 164.986 159.991 73.707 1.00 59.32  54 J 1 
-ATOM 392 C CD1 . TYR J 1 54 ? 166.049 160.070 72.828 1.00 59.32  54 J 1 
-ATOM 393 C CD2 . TYR J 1 54 ? 164.208 158.845 73.697 1.00 59.32  54 J 1 
-ATOM 394 C CE1 . TYR J 1 54 ? 166.316 159.055 71.945 1.00 59.32  54 J 1 
-ATOM 395 C CE2 . TYR J 1 54 ? 164.470 157.819 72.819 1.00 59.32  54 J 1 
-ATOM 396 C CZ  . TYR J 1 54 ? 165.527 157.929 71.944 1.00 59.32  54 J 1 
-ATOM 397 O OH  . TYR J 1 54 ? 165.800 156.912 71.061 1.00 59.32  54 J 1 
-ATOM 398 N N   . ASN J 1 55 ? 161.668 161.931 74.183 1.00 55.92  55 J 1 
-ATOM 399 C CA  . ASN J 1 55 ? 160.344 161.659 73.629 1.00 55.92  55 J 1 
-ATOM 400 C C   . ASN J 1 55 ? 159.925 162.748 72.647 1.00 55.92  55 J 1 
-ATOM 401 O O   . ASN J 1 55 ? 159.524 162.458 71.511 1.00 55.92  55 J 1 
-ATOM 402 C CB  . ASN J 1 55 ? 159.340 161.529 74.777 1.00 55.92  55 J 1 
-ATOM 403 C CG  . ASN J 1 55 ? 157.922 161.278 74.306 1.00 55.92  55 J 1 
-ATOM 404 O OD1 . ASN J 1 55 ? 157.659 161.123 73.117 1.00 55.92  55 J 1 
-ATOM 405 N ND2 . ASN J 1 55 ? 156.998 161.213 75.253 1.00 55.92  55 J 1 
-ATOM 406 N N   . LEU J 1 56 ? 160.012 164.010 73.071 1.00 57.85  56 J 1 
-ATOM 407 C CA  . LEU J 1 56 ? 159.659 165.115 72.183 1.00 57.85  56 J 1 
-ATOM 408 C C   . LEU J 1 56 ? 160.587 165.185 70.980 1.00 57.85  56 J 1 
-ATOM 409 O O   . LEU J 1 56 ? 160.148 165.503 69.871 1.00 57.85  56 J 1 
-ATOM 410 C CB  . LEU J 1 56 ? 159.665 166.437 72.945 1.00 57.85  56 J 1 
-ATOM 411 C CG  . LEU J 1 56 ? 158.428 166.781 73.772 1.00 57.85  56 J 1 
-ATOM 412 C CD1 . LEU J 1 56 ? 158.257 165.920 74.998 1.00 57.85  56 J 1 
-ATOM 413 C CD2 . LEU J 1 56 ? 158.539 168.224 74.179 1.00 57.85  56 J 1 
-ATOM 414 N N   . TYR J 1 57 ? 161.872 164.895 71.176 1.00 60.05  57 J 1 
-ATOM 415 C CA  . TYR J 1 57 ? 162.800 164.844 70.054 1.00 60.05  57 J 1 
-ATOM 416 C C   . TYR J 1 57 ? 162.362 163.824 69.013 1.00 60.05  57 J 1 
-ATOM 417 O O   . TYR J 1 57 ? 162.299 164.134 67.817 1.00 60.05  57 J 1 
-ATOM 418 C CB  . TYR J 1 57 ? 164.203 164.534 70.578 1.00 60.05  57 J 1 
-ATOM 419 C CG  . TYR J 1 57 ? 165.239 164.289 69.513 1.00 60.05  57 J 1 
-ATOM 420 C CD1 . TYR J 1 57 ? 165.328 163.058 68.881 1.00 60.05  57 J 1 
-ATOM 421 C CD2 . TYR J 1 57 ? 166.114 165.288 69.127 1.00 60.05  57 J 1 
-ATOM 422 C CE1 . TYR J 1 57 ? 166.257 162.825 67.909 1.00 60.05  57 J 1 
-ATOM 423 C CE2 . TYR J 1 57 ? 167.052 165.063 68.149 1.00 60.05  57 J 1 
-ATOM 424 C CZ  . TYR J 1 57 ? 167.118 163.828 67.545 1.00 60.05  57 J 1 
-ATOM 425 O OH  . TYR J 1 57 ? 168.044 163.579 66.567 1.00 60.05  57 J 1 
-ATOM 426 N N   . ARG J 1 58 ? 162.069 162.598 69.446 1.00 58.38  58 J 1 
-ATOM 427 C CA  . ARG J 1 58 ? 161.680 161.562 68.498 1.00 58.38  58 J 1 
-ATOM 428 C C   . ARG J 1 58 ? 160.373 161.916 67.804 1.00 58.38  58 J 1 
-ATOM 429 O O   . ARG J 1 58 ? 160.238 161.726 66.587 1.00 58.38  58 J 1 
-ATOM 430 C CB  . ARG J 1 58 ? 161.566 160.217 69.208 1.00 58.38  58 J 1 
-ATOM 431 C CG  . ARG J 1 58 ? 162.900 159.553 69.491 1.00 58.38  58 J 1 
-ATOM 432 C CD  . ARG J 1 58 ? 163.871 159.707 68.335 1.00 58.38  58 J 1 
-ATOM 433 N NE  . ARG J 1 58 ? 165.241 159.437 68.753 1.00 58.38  58 J 1 
-ATOM 434 C CZ  . ARG J 1 58 ? 166.293 159.472 67.948 1.00 58.38  58 J 1 
-ATOM 435 N NH1 . ARG J 1 58 ? 166.171 159.760 66.663 1.00 58.38  58 J 1 
-ATOM 436 N NH2 . ARG J 1 58 ? 167.498 159.214 68.445 1.00 58.38  58 J 1 
-ATOM 437 N N   . ASN J 1 59 ? 159.399 162.432 68.558 1.00 58.16  59 J 1 
-ATOM 438 C CA  . ASN J 1 59 ? 158.133 162.817 67.945 1.00 58.16  59 J 1 
-ATOM 439 C C   . ASN J 1 59 ? 158.327 163.928 66.924 1.00 58.16  59 J 1 
-ATOM 440 O O   . ASN J 1 59 ? 157.735 163.893 65.839 1.00 58.16  59 J 1 
-ATOM 441 C CB  . ASN J 1 59 ? 157.133 163.240 69.017 1.00 58.16  59 J 1 
-ATOM 442 C CG  . ASN J 1 59 ? 156.401 162.065 69.619 1.00 58.16  59 J 1 
-ATOM 443 O OD1 . ASN J 1 59 ? 156.905 161.403 70.521 1.00 58.16  59 J 1 
-ATOM 444 N ND2 . ASN J 1 59 ? 155.203 161.796 69.117 1.00 58.16  59 J 1 
-ATOM 445 N N   . ALA J 1 60 ? 159.154 164.925 67.250 1.00 62.06  60 J 1 
-ATOM 446 C CA  . ALA J 1 60 ? 159.407 166.012 66.314 1.00 62.06  60 J 1 
-ATOM 447 C C   . ALA J 1 60 ? 160.081 165.504 65.052 1.00 62.06  60 J 1 
-ATOM 448 O O   . ALA J 1 60 ? 159.709 165.896 63.940 1.00 62.06  60 J 1 
-ATOM 449 C CB  . ALA J 1 60 ? 160.257 167.092 66.980 1.00 62.06  60 J 1 
-ATOM 450 N N   . GLN J 1 61 ? 161.067 164.621 65.203 1.00 65.39  61 J 1 
-ATOM 451 C CA  . GLN J 1 61 ? 161.748 164.072 64.037 1.00 65.39  61 J 1 
-ATOM 452 C C   . GLN J 1 61 ? 160.774 163.310 63.148 1.00 65.39  61 J 1 
-ATOM 453 O O   . GLN J 1 61 ? 160.735 163.512 61.925 1.00 65.39  61 J 1 
-ATOM 454 C CB  . GLN J 1 61 ? 162.895 163.171 64.494 1.00 65.39  61 J 1 
-ATOM 455 C CG  . GLN J 1 61 ? 164.044 163.067 63.519 1.00 65.39  61 J 1 
-ATOM 456 C CD  . GLN J 1 61 ? 165.192 162.262 64.080 1.00 65.39  61 J 1 
-ATOM 457 O OE1 . GLN J 1 61 ? 166.240 162.807 64.420 1.00 65.39  61 J 1 
-ATOM 458 N NE2 . GLN J 1 61 ? 164.998 160.957 64.189 1.00 65.39  61 J 1 
-ATOM 459 N N   . SER J 1 62 ? 159.959 162.442 63.753 1.00 64.39  62 J 1 
-ATOM 460 C CA  . SER J 1 62 ? 159.025 161.644 62.969 1.00 64.39  62 J 1 
-ATOM 461 C C   . SER J 1 62 ? 157.998 162.522 62.267 1.00 64.39  62 J 1 
-ATOM 462 O O   . SER J 1 62 ? 157.716 162.331 61.078 1.00 64.39  62 J 1 
-ATOM 463 C CB  . SER J 1 62 ? 158.333 160.619 63.865 1.00 64.39  62 J 1 
-ATOM 464 O OG  . SER J 1 62 ? 157.410 159.843 63.125 1.00 64.39  62 J 1 
-ATOM 465 N N   . ASN J 1 63 ? 157.438 163.504 62.976 1.00 65.16  63 J 1 
-ATOM 466 C CA  . ASN J 1 63 ? 156.437 164.361 62.357 1.00 65.16  63 J 1 
-ATOM 467 C C   . ASN J 1 63 ? 157.033 165.219 61.252 1.00 65.16  63 J 1 
-ATOM 468 O O   . ASN J 1 63 ? 156.389 165.421 60.216 1.00 65.16  63 J 1 
-ATOM 469 C CB  . ASN J 1 63 ? 155.767 165.233 63.413 1.00 65.16  63 J 1 
-ATOM 470 C CG  . ASN J 1 63 ? 154.853 164.439 64.316 1.00 65.16  63 J 1 
-ATOM 471 O OD1 . ASN J 1 63 ? 154.525 163.290 64.026 1.00 65.16  63 J 1 
-ATOM 472 N ND2 . ASN J 1 63 ? 154.434 165.045 65.416 1.00 65.16  63 J 1 
-ATOM 473 N N   . THR J 1 64 ? 158.252 165.729 61.444 1.00 66.60  64 J 1 
-ATOM 474 C CA  . THR J 1 64 ? 158.875 166.543 60.408 1.00 66.60  64 J 1 
-ATOM 475 C C   . THR J 1 64 ? 159.147 165.725 59.153 1.00 66.60  64 J 1 
-ATOM 476 O O   . THR J 1 64 ? 158.846 166.169 58.035 1.00 66.60  64 J 1 
-ATOM 477 C CB  . THR J 1 64 ? 160.169 167.158 60.935 1.00 66.60  64 J 1 
-ATOM 478 O OG1 . THR J 1 64 ? 159.877 167.977 62.072 1.00 66.60  64 J 1 
-ATOM 479 C CG2 . THR J 1 64 ? 160.819 168.011 59.865 1.00 66.60  64 J 1 
-ATOM 480 N N   . VAL J 1 65 ? 159.707 164.523 59.310 1.00 64.00  65 J 1 
-ATOM 481 C CA  . VAL J 1 65 ? 159.978 163.718 58.124 1.00 64.00  65 J 1 
-ATOM 482 C C   . VAL J 1 65 ? 158.671 163.316 57.452 1.00 64.00  65 J 1 
-ATOM 483 O O   . VAL J 1 65 ? 158.580 163.285 56.220 1.00 64.00  65 J 1 
-ATOM 484 C CB  . VAL J 1 65 ? 160.858 162.499 58.464 1.00 64.00  65 J 1 
-ATOM 485 C CG1 . VAL J 1 65 ? 162.203 162.957 58.999 1.00 64.00  65 J 1 
-ATOM 486 C CG2 . VAL J 1 65 ? 160.176 161.571 59.442 1.00 64.00  65 J 1 
-ATOM 487 N N   . LYS J 1 66 ? 157.626 163.047 58.241 1.00 65.12  66 J 1 
-ATOM 488 C CA  . LYS J 1 66 ? 156.341 162.691 57.649 1.00 65.12  66 J 1 
-ATOM 489 C C   . LYS J 1 66 ? 155.745 163.847 56.855 1.00 65.12  66 J 1 
-ATOM 490 O O   . LYS J 1 66 ? 155.240 163.645 55.745 1.00 65.12  66 J 1 
-ATOM 491 C CB  . LYS J 1 66 ? 155.366 162.235 58.733 1.00 65.12  66 J 1 
-ATOM 492 C CG  . LYS J 1 66 ? 153.992 161.855 58.202 1.00 65.12  66 J 1 
-ATOM 493 C CD  . LYS J 1 66 ? 154.088 160.891 57.032 1.00 65.12  66 J 1 
-ATOM 494 C CE  . LYS J 1 66 ? 152.711 160.542 56.496 1.00 65.12  66 J 1 
-ATOM 495 N NZ  . LYS J 1 66 ? 151.754 160.214 57.587 1.00 65.12  66 J 1 
-ATOM 496 N N   . VAL J 1 67 ? 155.779 165.064 57.402 1.00 65.92  67 J 1 
-ATOM 497 C CA  . VAL J 1 67 ? 155.163 166.185 56.696 1.00 65.92  67 J 1 
-ATOM 498 C C   . VAL J 1 67 ? 155.958 166.528 55.442 1.00 65.92  67 J 1 
-ATOM 499 O O   . VAL J 1 67 ? 155.381 166.863 54.397 1.00 65.92  67 J 1 
-ATOM 500 C CB  . VAL J 1 67 ? 154.993 167.401 57.629 1.00 65.92  67 J 1 
-ATOM 501 C CG1 . VAL J 1 67 ? 156.328 167.937 58.097 1.00 65.92  67 J 1 
-ATOM 502 C CG2 . VAL J 1 67 ? 154.200 168.492 56.929 1.00 65.92  67 J 1 
-ATOM 503 N N   . PHE J 1 68 ? 157.288 166.435 55.509 1.00 66.56  68 J 1 
-ATOM 504 C CA  . PHE J 1 68 ? 158.076 166.682 54.308 1.00 66.56  68 J 1 
-ATOM 505 C C   . PHE J 1 68 ? 157.826 165.606 53.260 1.00 66.56  68 J 1 
-ATOM 506 O O   . PHE J 1 68 ? 157.772 165.899 52.059 1.00 66.56  68 J 1 
-ATOM 507 C CB  . PHE J 1 68 ? 159.558 166.785 54.657 1.00 66.56  68 J 1 
-ATOM 508 C CG  . PHE J 1 68 ? 159.991 168.177 55.012 1.00 66.56  68 J 1 
-ATOM 509 C CD1 . PHE J 1 68 ? 160.099 168.568 56.333 1.00 66.56  68 J 1 
-ATOM 510 C CD2 . PHE J 1 68 ? 160.268 169.101 54.022 1.00 66.56  68 J 1 
-ATOM 511 C CE1 . PHE J 1 68 ? 160.490 169.850 56.660 1.00 66.56  68 J 1 
-ATOM 512 C CE2 . PHE J 1 68 ? 160.658 170.384 54.343 1.00 66.56  68 J 1 
-ATOM 513 C CZ  . PHE J 1 68 ? 160.769 170.758 55.664 1.00 66.56  68 J 1 
-ATOM 514 N N   . LYS J 1 69 ? 157.646 164.356 53.694 1.00 70.04  69 J 1 
-ATOM 515 C CA  . LYS J 1 69 ? 157.283 163.302 52.755 1.00 70.04  69 J 1 
-ATOM 516 C C   . LYS J 1 69 ? 155.929 163.584 52.123 1.00 70.04  69 J 1 
-ATOM 517 O O   . LYS J 1 69 ? 155.731 163.326 50.934 1.00 70.04  69 J 1 
-ATOM 518 C CB  . LYS J 1 69 ? 157.291 161.944 53.465 1.00 70.04  69 J 1 
-ATOM 519 C CG  . LYS J 1 69 ? 157.067 160.718 52.570 1.00 70.04  69 J 1 
-ATOM 520 C CD  . LYS J 1 69 ? 155.593 160.436 52.289 1.00 70.04  69 J 1 
-ATOM 521 C CE  . LYS J 1 69 ? 155.424 159.353 51.239 1.00 70.04  69 J 1 
-ATOM 522 N NZ  . LYS J 1 69 ? 153.999 158.953 51.085 1.00 70.04  69 J 1 
-ATOM 523 N N   . ASP J 1 70 ? 154.979 164.093 52.908 1.00 70.15  70 J 1 
-ATOM 524 C CA  . ASP J 1 70 ? 153.667 164.418 52.356 1.00 70.15  70 J 1 
-ATOM 525 C C   . ASP J 1 70 ? 153.770 165.503 51.293 1.00 70.15  70 J 1 
-ATOM 526 O O   . ASP J 1 70 ? 153.172 165.386 50.216 1.00 70.15  70 J 1 
-ATOM 527 C CB  . ASP J 1 70 ? 152.719 164.850 53.472 1.00 70.15  70 J 1 
-ATOM 528 C CG  . ASP J 1 70 ? 152.353 163.710 54.396 1.00 70.15  70 J 1 
-ATOM 529 O OD1 . ASP J 1 70 ? 152.337 162.552 53.930 1.00 70.15  70 J 1 
-ATOM 530 O OD2 . ASP J 1 70 ? 152.082 163.970 55.587 1.00 70.15  70 J 1 
-ATOM 531 N N   . ILE J 1 71 ? 154.538 166.558 51.574 1.00 64.31  71 J 1 
-ATOM 532 C CA  . ILE J 1 71 ? 154.721 167.619 50.588 1.00 64.31  71 J 1 
-ATOM 533 C C   . ILE J 1 71 ? 155.375 167.070 49.326 1.00 64.31  71 J 1 
-ATOM 534 O O   . ILE J 1 71 ? 154.941 167.362 48.203 1.00 64.31  71 J 1 
-ATOM 535 C CB  . ILE J 1 71 ? 155.545 168.772 51.188 1.00 64.31  71 J 1 
-ATOM 536 C CG1 . ILE J 1 71 ? 154.860 169.327 52.435 1.00 64.31  71 J 1 
-ATOM 537 C CG2 . ILE J 1 71 ? 155.751 169.866 50.159 1.00 64.31  71 J 1 
-ATOM 538 C CD1 . ILE J 1 71 ? 155.778 170.127 53.325 1.00 64.31  71 J 1 
-ATOM 539 N N   . ASP J 1 72 ? 156.423 166.261 49.492 1.00 68.85  72 J 1 
-ATOM 540 C CA  . ASP J 1 72 ? 157.144 165.727 48.343 1.00 68.85  72 J 1 
-ATOM 541 C C   . ASP J 1 72 ? 156.266 164.795 47.517 1.00 68.85  72 J 1 
-ATOM 542 O O   . ASP J 1 72 ? 156.316 164.814 46.282 1.00 68.85  72 J 1 
-ATOM 543 C CB  . ASP J 1 72 ? 158.398 165.005 48.825 1.00 68.85  72 J 1 
-ATOM 544 C CG  . ASP J 1 72 ? 159.551 165.947 49.062 1.00 68.85  72 J 1 
-ATOM 545 O OD1 . ASP J 1 72 ? 160.691 165.462 49.183 1.00 68.85  72 J 1 
-ATOM 546 O OD2 . ASP J 1 72 ? 159.318 167.171 49.125 1.00 68.85  72 J 1 
-ATOM 547 N N   . ALA J 1 73 ? 155.464 163.963 48.181 1.00 65.97  73 J 1 
-ATOM 548 C CA  . ALA J 1 73 ? 154.553 163.081 47.466 1.00 65.97  73 J 1 
-ATOM 549 C C   . ALA J 1 73 ? 153.501 163.878 46.715 1.00 65.97  73 J 1 
-ATOM 550 O O   . ALA J 1 73 ? 153.128 163.520 45.593 1.00 65.97  73 J 1 
-ATOM 551 C CB  . ALA J 1 73 ? 153.894 162.103 48.437 1.00 65.97  73 J 1 
-ATOM 552 N N   . ALA J 1 74 ? 153.004 164.960 47.319 1.00 64.99  74 J 1 
-ATOM 553 C CA  . ALA J 1 74 ? 152.063 165.819 46.610 1.00 64.99  74 J 1 
-ATOM 554 C C   . ALA J 1 74 ? 152.700 166.405 45.358 1.00 64.99  74 J 1 
-ATOM 555 O O   . ALA J 1 74 ? 152.080 166.428 44.288 1.00 64.99  74 J 1 
-ATOM 556 C CB  . ALA J 1 74 ? 151.567 166.931 47.533 1.00 64.99  74 J 1 
-ATOM 557 N N   . ILE J 1 75 ? 153.947 166.864 45.469 1.00 67.26  75 J 1 
-ATOM 558 C CA  . ILE J 1 75 ? 154.634 167.425 44.307 1.00 67.26  75 J 1 
-ATOM 559 C C   . ILE J 1 75 ? 154.797 166.367 43.222 1.00 67.26  75 J 1 
-ATOM 560 O O   . ILE J 1 75 ? 154.522 166.615 42.042 1.00 67.26  75 J 1 
-ATOM 561 C CB  . ILE J 1 75 ? 155.993 168.017 44.717 1.00 67.26  75 J 1 
-ATOM 562 C CG1 . ILE J 1 75 ? 155.807 169.113 45.765 1.00 67.26  75 J 1 
-ATOM 563 C CG2 . ILE J 1 75 ? 156.721 168.564 43.502 1.00 67.26  75 J 1 
-ATOM 564 C CD1 . ILE J 1 75 ? 154.983 170.274 45.286 1.00 67.26  75 J 1 
-ATOM 565 N N   . ILE J 1 76 ? 155.244 165.170 43.607 1.00 71.16  76 J 1 
-ATOM 566 C CA  . ILE J 1 76 ? 155.503 164.119 42.627 1.00 71.16  76 J 1 
-ATOM 567 C C   . ILE J 1 76 ? 154.216 163.694 41.935 1.00 71.16  76 J 1 
-ATOM 568 O O   . ILE J 1 76 ? 154.164 163.579 40.705 1.00 71.16  76 J 1 
-ATOM 569 C CB  . ILE J 1 76 ? 156.205 162.925 43.299 1.00 71.16  76 J 1 
-ATOM 570 C CG1 . ILE J 1 76 ? 157.602 163.325 43.761 1.00 71.16  76 J 1 
-ATOM 571 C CG2 . ILE J 1 76 ? 156.302 161.755 42.342 1.00 71.16  76 J 1 
-ATOM 572 C CD1 . ILE J 1 76 ? 158.489 163.764 42.631 1.00 71.16  76 J 1 
-ATOM 573 N N   . GLN J 1 77 ? 153.158 163.457 42.708 1.00 74.01  77 J 1 
-ATOM 574 C CA  . GLN J 1 77 ? 151.870 163.093 42.139 1.00 74.01  77 J 1 
-ATOM 575 C C   . GLN J 1 77 ? 151.276 164.203 41.291 1.00 74.01  77 J 1 
-ATOM 576 O O   . GLN J 1 77 ? 150.522 163.917 40.355 1.00 74.01  77 J 1 
-ATOM 577 C CB  . GLN J 1 77 ? 150.903 162.718 43.266 1.00 74.01  77 J 1 
-ATOM 578 C CG  . GLN J 1 77 ? 149.608 162.063 42.818 1.00 74.01  77 J 1 
-ATOM 579 C CD  . GLN J 1 77 ? 148.547 163.075 42.436 1.00 74.01  77 J 1 
-ATOM 580 O OE1 . GLN J 1 77 ? 148.119 163.881 43.261 1.00 74.01  77 J 1 
-ATOM 581 N NE2 . GLN J 1 77 ? 148.126 163.046 41.178 1.00 74.01  77 J 1 
-ATOM 582 N N   . ASN J 1 78 ? 151.610 165.453 41.583 1.00 75.47  78 J 1 
-ATOM 583 C CA  . ASN J 1 78 ? 151.007 166.584 40.903 1.00 75.47  78 J 1 
-ATOM 584 C C   . ASN J 1 78 ? 151.656 166.793 39.532 1.00 75.47  78 J 1 
-ATOM 585 O O   . ASN J 1 78 ? 151.100 167.503 38.692 1.00 75.47  78 J 1 
-ATOM 586 C CB  . ASN J 1 78 ? 151.109 167.797 41.862 1.00 75.47  78 J 1 
-ATOM 587 C CG  . ASN J 1 78 ? 150.672 169.138 41.268 1.00 75.47  78 J 1 
-ATOM 588 O OD1 . ASN J 1 78 ? 150.393 169.290 40.093 1.00 75.47  78 J 1 
-ATOM 589 N ND2 . ASN J 1 78 ? 150.555 170.120 42.149 1.00 75.47  78 J 1 
-ATOM 590 N N   . PHE J 1 79 ? 152.755 166.084 39.244 1.00 76.77  79 J 1 
-ATOM 591 C CA  . PHE J 1 79 ? 153.341 166.125 37.905 1.00 76.77  79 J 1 
-ATOM 592 C C   . PHE J 1 79 ? 152.308 165.775 36.843 1.00 76.77  79 J 1 
-ATOM 593 O O   . PHE J 1 79 ? 152.188 166.465 35.824 1.00 76.77  79 J 1 
-ATOM 594 C CB  . PHE J 1 79 ? 154.513 165.146 37.794 1.00 76.77  79 J 1 
-ATOM 595 C CG  . PHE J 1 79 ? 155.770 165.599 38.471 1.00 76.77  79 J 1 
-ATOM 596 C CD1 . PHE J 1 79 ? 155.885 166.866 39.000 1.00 76.77  79 J 1 
-ATOM 597 C CD2 . PHE J 1 79 ? 156.855 164.744 38.553 1.00 76.77  79 J 1 
-ATOM 598 C CE1 . PHE J 1 79 ? 157.054 167.261 39.614 1.00 76.77  79 J 1 
-ATOM 599 C CE2 . PHE J 1 79 ? 158.021 165.138 39.162 1.00 76.77  79 J 1 
-ATOM 600 C CZ  . PHE J 1 79 ? 158.121 166.398 39.692 1.00 76.77  79 J 1 
-ATOM 601 N N   . ARG J 1 80 ? 151.557 164.702 37.066 1.00 84.01  80 J 1 
-ATOM 602 C CA  . ARG J 1 80 ? 150.552 164.246 36.118 1.00 84.01  80 J 1 
-ATOM 603 C C   . ARG J 1 80 ? 149.236 164.973 36.361 1.00 84.01  80 J 1 
-ATOM 604 O O   . ARG J 1 80 ? 148.856 165.220 37.506 1.00 84.01  80 J 1 
-ATOM 605 C CB  . ARG J 1 80 ? 150.365 162.730 36.232 1.00 84.01  80 J 1 
-ATOM 606 C CG  . ARG J 1 80 ? 149.526 162.108 35.127 1.00 84.01  80 J 1 
-ATOM 607 C CD  . ARG J 1 80 ? 148.094 161.873 35.581 1.00 84.01  80 J 1 
-ATOM 608 N NE  . ARG J 1 80 ? 148.029 160.982 36.733 1.00 84.01  80 J 1 
-ATOM 609 C CZ  . ARG J 1 80 ? 146.964 160.838 37.510 1.00 84.01  80 J 1 
-ATOM 610 N NH1 . ARG J 1 80 ? 145.848 161.512 37.286 1.00 84.01  80 J 1 
-ATOM 611 N NH2 . ARG J 1 80 ? 147.022 159.999 38.541 1.00 84.01  80 J 1 
-ATOM 612 O OXT . ARG J 1 80 ? 148.527 165.332 35.421 1.00 84.01  80 J 1 
-#
diff --git a/src/alphafold3/test_data/miniature_databases/pdb_seqres_2022_09_28__subsampled_1000.fasta b/src/alphafold3/test_data/miniature_databases/pdb_seqres_2022_09_28__subsampled_1000.fasta
deleted file mode 100644
index 711714d7676dbcffb7bd5d60aa02f34d036ceaf0..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/pdb_seqres_2022_09_28__subsampled_1000.fasta
+++ /dev/null
@@ -1,2000 +0,0 @@
->4ffz_X mol:protein length:111  Envelope protein E
-MASMTLKGMSYVMCTGSFKLEKEVAETQHGTVLVQVKYEGTDAPCKIPFSSQDEKGVTQNGRLITANPIVTDKEKPVNIEAEPPFGESYIVVGAGEKALKLSWFKKGSSIG
->2y3e_A mol:protein length:134  STREPTAVIDIN
-MAEAGITGTWYNQLGSTFIVTAGADGALTGTYESAVGNAEGDYVLTGRYDSAPATDGSGTALGWTVAWKNNYRNAHSATTWSGQYVGGAEARINTQWLLTSGTTEANAWKSTLVGHDTFTKVKPSAASHHHHHH
->7rye_J mol:protein length:80  Protein PrgI
-MATPWSGYLDDVSAKFDTGVDNLQTQVTEALDKLAAKPSDPALLAAYQSKLSEYNLYRNAQSNTVKVFKDIDAAIIQNFR
->5eq0_B mol:protein length:6  unc3866
-XFALXX
->5thk_C mol:protein length:266  Putative dehydrogenase
-MAHHHHHHMVATHTLADKVVLIAGGAKNLGGLIARDLAGHGAKAVAIHYNSAASQAQAEETAAAVRAAGAEAATFQADLTTAAAVEKLFDDAKQRFGKIDIAINTVGKVLKKPFTEISEAEYDEMFAVNSKSAFFFIKEAGRHLEDHGKLVTLVTSLLGAFTPFYAAYEGSKAPVEHFTRAASKEYGARGISVTAVGPGPMDTPFFYPAEGADAVAYHKTAAALSPFSKTGLTDIEDVVPFIRHLVTDGWWITGQTILINGGYTTK
->1svu_B mol:protein length:327  Modification methylase HhaI
-MIEIKDKQLTGLRFIDLFAGLGGFRLALESCGAECVYSNEWDKYAQEVYEMNFGEKPEGDITQVNEKTIPDHDILCAGFPCQAFSISGKQKGFEDSRGTLFFDIARIVREKKPKVVFMENVKNFASHDNGNTLEVVKNTMNELDYSFHAKVLNALDYGIPQKRERIYMICFRNDLNIQNFQFPKPFELNTFVKDLLLPDSEVEHLVIDRKDLVMTNQEIEQTTPKTVRLGIVGKGGWGERIYSTRGIAITLSAYGGGIFAKTGGYLVNGKTRKLHPRECARVMGYPDSYKVHPSTSQAYKQFGNSVVINVLQYIAYNIGSSLNFKPY
->3c0r_B mol:protein length:75  Ubiquitin
-MQIFVKTLTGKTITLEVEPSDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRG
->3dnn_H mol:protein length:170  HIV-1 envelope glycoprotein gp120
-TSVITQACPKVSFEPIPIHYCAPAGFAILKCNNKTFNGTGPCTNVSTVQCTHGIRPVVSTQLLLNGSLAEEEVVIRSVNFTDNAKTIIVQLNTSVEINCTGAGHCNISRAKWNNTLKQIASKLREQFGNNKTIIFKQSSGGDPEIVTHSFNCGGEFFYCNSTQLFNSTWF
->4igl_D mol:protein length:690  YenC2
-MDIQLFSKTPSVTVFDNRGLSVRDIAYRRHPDTPKVTEECITYHQFDFRGFLAQSLDPRLNHKEVTNFSYLTDLNGNIIYTQSVDAGNTLVLNDTEGRSVIAMTNISRGENGKDDLSLAVTRTFQYENAPLPGRPLSVTEQVNGENARITEHFVYAGNTPQEKNLNLAGQCVSYYDAAGLIQTDSVSLTGKPLSVSRKLLKNLDDTNILADWQGNDTSAWNSLLATEIYTTVTRTDAAGAVLTTIDAVGNQQRVAFDIAGQLSASWLTLKGGQEQVIIKVLTYSAAGQKLREEGGNGVVTTYTYEAETQRLIGIKTERPNGHAAGAKVLQDLRYEYDPVGNVLSITNDAEETRFWRNQKVVPENAYRYDSLYQLVSASGREVAGAGQQGSDLPSPLVPLPSDSSVYTNYTRTYTYDSAGNLMRIRHSAPATNNNYTLNITVSERSNRGVMSSLTENPADVDALFTASGSQKCLQQGQSLIWTPRGELRTVLLVARGETADDSESYRYDGSSQRILKISSQQTNHSARVQRALYLPGLEWRTMTGGVAEAENLQVICIGEAGRAQVRVLHWESGKPDGIINDQIRWSYDNLTCSSGLEVDGDGLVISMEEYYPYGGTAVWAARSHIETAYKTVRYSGKERDATGLYYYGFRYYQPWAGRWLSADPAGTVDGLNLYRMVRNNPLRLTDPDGM
->2y1z_B mol:protein length:94  ALPHA-CRYSTALLIN B CHAIN
-GAMEMRLEKDRFSVNLDVKHFSPEELKVKVLGDVIEVHGKHEERQDEHGFISREFHGKYRIPADVDPLTITSSMSSDGVLTVNGPRKQVSGPER
->7vy3_V mol:protein length:54  Antenna pigment protein alpha chain
-MSKFYKIWMIFDPRRVFVAQGVFLFLLAVMIHLILLSTPSYNWLEISAAKYNRV
->7v2c_P mol:protein length:208  NADH dehydrogenase [ubiquinone] iron-sulfur protein 3, mitochondrial
-TRPTIRPRNDVVHKQLSAFGQYVAEILPKYVQQVQVSCFNELEIFIHPDGVIPVLTFLRDHTNAQFKSLADLTAVDVPTRQNRFEIVYNLLSLRFNSRIRVKTYTDELTPIESSVTVYKAANWYEREIWDMFGVFFANHPDLRRILTDYGFEGHPFRKDFPLSGYVELRYDDEVKRVVAEPVELAQEFRKFDLNSPWEAFPAYRQPPE
->7eca_A mol:protein length:333  Kelch-like ECH-associated protein 1
-MGHHHHHHENLYFQGHMTLHKPTQAVPCRAPKVGRLIYTAGGYFRQSLSYLEAYNPSNGSWLRLADLQVPRSGLAGCVVGGLLYAVGGRNNSPDGNTDSSALDCYNPMTNQWSPCASMSVPRNRIGVGVIDGHIYAVGGSHGCIHHSSVERYEPERDEWHLVAPMLTRRIGVGVAVLNRLLYAVGGFDGTNRLNSAECYYPERNEWRMITPMNTIRSGAGVCVLHNCIYAAGGYDGQDQLNSVERYDVETETWTFVAPMRHHRSALGITVHQGKIYVLGGYDGHTFLDSVECYDPDSDTWSEVTRMTSGRSGVGVAVTMEPCRKQIDQQNCTC
->2maa_A mol:protein length:13  Temporin-A
-FLPLIGRVLSGIL
->7xi7_A mol:protein length:187  Dihydrofolate reductase
-MVGSLNCIVAVSQNMGIGKNGDLPWPPLRNEFRYFQRMTTTSSVEGKQNLVIMGKKTWFSIPEKNRPLKGRINLVLSRELKEPPQGAHFLSRSLDDALKLTEQPELANKVDMVWIVGGSSVYKEAMNHPGHLKLFVTRIMQDFESDTFFPEIDLEKYKLLPEYPGVLSDVQEEKGIKYKFEVYEKND
->6zmn_A mol:protein length:125  Mothers against decapentaplegic homolog 3
-GPAVKRLLGWKQGDEEEKWCEKAVKSLVKKLKKTGQLDELEKAITTQNVNTKCITIPRSLDGRLQVSHRKGLPHVIYCRLWRWPDLHSHHELRAMELCEFAFNMKKDEVCVNPYHYQRVETPVLP
->7vbn_G mol:protein length:88  Acyl carrier protein, mitochondrial
-SDAPPLTLEAIKDRVLYVLKLYDKIDPEKLSVNSHFMKDLGLDSLDQVEIIMAMEDEFGFEIPDIDAEKLMCPQEIVDYIADKKDVYE
->7vaq_J mol:protein length:188  V-type ATP synthase subunit E
-MSKLEAILSQEVEAEIQALLQEAEAKAEAVKREAEEKAKALLQARERALEAQYRAALRRAESAGELLVATARTQARGEVLEEVRRRVREALEALPQKPEWPEVVRKLALEALEALPGAKALVANPEDLPHLEALARERGVELQAEPALRLGVRAVGAEGKTQVENSLLARLDRAWDALSSKVAQALWG
->7osz_B mol:protein length:512  Bifunctional glutamate/proline--tRNA ligase
-GAGEGQGPKKQTRLGLEAKKEENLADWYSQVITKSEMIEYHDISGCYILRPWAYAIWEAIKDFFDAEIKKLGVENCYFPMFVSQSALEKEKTHVADFAPEVAWVTRSGKTELAEPIAIRPTSETVMYPAYAKWVQSHRDLPIKLNQWCNVVRWEFKHPQPFLRTREFLWQEGHSAFATMEEAAEEVLQILDLYAQVYEELLAIPVVKGRKTEKEKFAGGDYTTTIEAFISASGRAIQGGTSHHLGQNFSKMFEIVFEDPKIPGEKQFAYQNSWGLTTRTIGVMTMVHGDNMGLVLPPRVACVQVVIIPCGITNALSEEDKEALIAKCNDYRRRLLSVNIRVRADLRDNYSPGWKFNHWELKGVPIRLEVGPRDMKSCQFVAVRRDTGEKLTVAENEAETKLQAILEDIQVTLFTRASEDLKTHMVVANTMEDFQKILDSGKIVQIPFCGEIDCEDWIKKTTARDQDLEPGAPSMGAKSLCIPFKPLCELQPGAKCVCGKNPAKYYTLFGRSY
->6y0u_A mol:protein length:115  Fucose-binding lectin
-MATQGVFTLPANTRFGVTAFANSSGTQTVNVLVNNETAATFSGQSTNNAVIGTQVLNSGSSGKVQVQVSVNGRPSDLVSAQVILTNELNFALVGSEDGTDNDYNDAVVVINWPLG
->3j3y_5T mol:protein length:231  capsid protein
-PIVQNLQGQMVHQAISPRTLNAWVKVVEEKAFSPEVIPMFSALSEGATPQDLNTMLNTVGGHQAAMQMLKETINEEAAEWDRLHPVHAGPIEPGQMREPRGSDIAGTTSTLQEQIGWMTHNPPIPVGEIYKRWIILGLNKIVRMYSPTSILDIRQGPKEPFRDYVDRFYKTLRAEQASQEVKNWMTETLLVQNANPDCKTILKALGPAATLEEMMTACQGVGGPGHKARVL
->7pmz_D mol:protein length:504  Inosine-5'-monophosphate dehydrogenase
-GSHMTANVDGVPEKFATLGLTYDDVLLLPGASAVLPNAVDTSSRISRNVRVNIPLLSAAMDKVTESRMAISMARQGGVGVLHRNLSIEDQANQVDLVKRSESGMVANPITIHPDATLGEADALCAKFRISGVPVTDGAGKLLGIVTNRDMAFETDRSRQVREVMTPMPLVTGQVGISGVDAMELLRRHKIEKLPLVDGDGILKGLITVKDFVKAEQYPHAAKDAKGRLLVGAAVGASPEALDRAQALAEAGVDFLVVDTSHGHNSNALSWMSKIKSSVGIDVVGGNVATRDGAQALIDAGVDGIKVGVGPGSICTTRVVAGIGVPQVTAIYEASLAARAAGVPLIGDGGLQYSGDIGKALAAGADTVMLGSLLAGCEESPGELQFINGKQFKSYRGMGSLGAMQSRGQGRSYSKDRYFQAEVASDDKLVPEGIEGQVPYRGPLANVLHQLVGGLRQTMGYVGAATIEEMESKGRFVRITSAGLKESHPHDIQMTVEAPNYSRSK
->3ccr_F mol:protein length:120  50S ribosomal protein L7Ae
-MPVYVDFDVPADLEDDALEALEVARDTGAVKKGTNETTKSIERGSAELVFVAEDVQPEEIVMHIPELADEKGVPFIFVEQQDDLGHAAGLEVGSAAAAVTDAGEADADVEDIADKVEELR
->5omf_A mol:protein length:774  DNA polymerase,DNA polymerase,DNA polymerase
-MILDTDYITEDGKPVIRIFKKENGEFKIEYDRTFEPYFYALLKDDSAIEEVKKITAERHGTVVTVKRVEKVQKKFLGRPVEVWKLYFTHPQDVPAIRDKIREHPAVIDIYEYDIPFAKRYLIDKGLVPMEGDEELKMLAFAIATLYHEGEEFAEGPILMISYADEEGARVITWKNVDLPYVDVVSTEREMIKRFLRVVKEKDPDVLITYNGDNFDFAYLKKRCEKLGINFALGRDGSEPKIQRMGDRFAVEVKGRIHFDLYPVIRRTINLPTYTLEAVYEAVFGQPKEKVYAEEITTAWETGENLERVARYSMEDAKVTYELGKEFLPMEAQLSRLIGQSLWDVSRSSTGNLVEWFLLRKAYERNELAPNKPDEKELARRRQSYEGGYVKEPERGLWENIVYLDFRSLYPSIIITHNVSPDTLNREGCKEYDVAPQVGHRFCKDFPGFIPSLLGDLLEERQKIKKKMKATIDPIERKLLDYRQRAIKILANSYYGYYGYARARWYCKECAESVTAWGREYITMTIKEIEEKYGFKVIYSDTDGFFATIPGADAETVKKKAMEFLKYINAKLPGALELEYEGFYKRGFFVTKKKYAVIDEEGKITTRGLEIVRRDWSEIAKETQARVLEALLKDGDVEKAVRIVKEVTEKLSKYEVPPEKLVIHEQITRDLKDYKATGPHVAVAKRLAARGVKIRPGTVISYIVLKGSGRIGDRAIPFDEFDPTKHKYDAEYYIENQVLPAVERILRAFGYRKEDLRYQKTRQVGLSAWLKPKGT
->4chk_E mol:protein length:127  AUXIN RESPONSE FACTOR 5
-GAMSKGSSWQKIATPRVRTYTKVQKTGSVGRSIDVTSFKDYEELKSAIECMFGLEGLLTHPQSSGWKLVYVDYESDVLLVGDDPWEEFVGCVRCIRILSPTEVQQMSEEGMKLLNSAGINDLKTSVS
->5yfm_A mol:protein length:414  Isocitrate dehydrogenase [NADP] cytoplasmic
-MSKKISGGSVVEMQGDEMTRIIWELIKEKLIFPYVELDLHSYDLGIENRDATNDQVTKDAAEAIKKHNVGVKCATITPDEKRVEEFKLKQMWKSPNGTIRNILGGTVFREAIICKNIPRLVSGWVKPIIIGRHAYGDQYRATDFVVPGPGKVEITYTPSDGTQKVTYLVHNFEEGGGVAMGMYNQDKSIEDFAHSSFQMALSKGWPLYLSTKNTILKKYDGRFKDIFQEIYDKQYKSQFEAQKIWYEHRLIDDMVAQAMKSEGGFIWACKNYDGDVQSDSVAQGYGSLGMMTSVLVCPDGKTVEAEAAHGTVTRHYRMYQKGQETSTNPIASIFAWTRGLAHRAKLDNNKELAFFANALEEVSIETIEAGFMTKDLAACIKGLPNVQRSDYLNTFEFMDKLGENLKIKLAQAKL
->1h0k_B mol:protein length:364  2,4-DIENOYL-COA REDUCTASE
-MITAQAVLYTQHGEPKDVLFTQSFEIDDDNLAPNEVIVKTLGSPINPSDINQIQGVYPSKPAKTTGFGTAEPAAPCGNEGLFEVIKVGSNVSSLEAGDWVIPSHVNFGTWRTHALGNDDDFIKLPNPAQSKANGKPNGLTINQGATISVNPLTAYLMLTHYVKLTPGKDWFIQNGGTSAVGKYASQIGKLLNFNSISVIRDRPNLDEVVASLKELGATQVITEDQNNSKEFGPTIKEWIKQSGGEAKLALNCVGGKSSTGIARKLNNNGLMLTYGGMSFQPVTIPTSLYIFKNFTSAGFWVTELLKNNKELKTSTLNQIIAWYEEGKLTDAKSIETLYDGTKPLHELYQDGVANSKDGKQLITY
->1b4n_B mol:protein length:619  FORMALDEHYDE FERREDOXIN OXIDOREDUCTASE
-MYGWWGRILRVNLTTGEVKVQEYPEEVAKKFIGGRGLAAWILWNEARGVEPLSPENKLIFAAGPFNGLPTPSGGKLVVAAKSPLTGGYGDGNLGTMASVHLRRAGYDALVVEGKAKKPVYIYIEDDNVSILSAEGLWGKTTFETERELKEIHGKNVGVLTIGPAGENLVKYAVVISQEGRAAGRPGMGAVMGSKKLKAVVIRGTKEIPVADKEELKKLSQEAYNEILNSPGYPFWKRQGTMAAVEWCNTNYALPTRNFSDGYFEFARSIDGYTMEGMKVQQRGCPYCNMPCGNVVLDAEGQESELDYENVALLGSNLGIGKLNEVSVLNRIADEMGMDTISLGVSIAHVMEAVERGILKEGPTFGDFKGAKQLALDIAYRKGELGNLAAEGVKAMAEKLGTHDFAMHVKGLEVSGYNCYIYPAMALAYGTSAIGAHHKEAWVIAWEIGTAPIEGEKAEKVEYKISYDPIKAQKVVELQRLRGGLFEMLTACRLPWVEVGLSLDYYPKLLKAITGVTYTWDDLYKAADRVYSLIRAYWVREFNGKWDRKMDYPPKRWFTEGLKSGPHKGEHLDEKKYDELLSEYYRIRGWDERGIPKKETLKELDLDFVIPELEKVTNLE
->5b66_c mol:protein length:455  Photosystem II CP43 reaction center protein
-NSIFATNRDQESSGFAWWAGNARLINLSGKLLGAHVAHAGLIVFWAGAMTLFELAHFIPEKPMYEQGLILIPHIATLGWGVGPGGEVVDTFPFFVVGVVHLISSAVLGFGGVYHAIRGPETLEEYSSFFGYDWKDKNKMTTILGFHLIVLGIGALLLVAKAMFFGGLYDTWAPGGGDVRVITNPTLDPRVIFGYLLKSPFGGEGWIVSVNNLEDVVGGHIWIGLICIAGGIWHILTTPFGWARRAFIWSGEAYLSYSLGALSMMGFIATCFVWFNNTVYPSEFYGPTGPEASQAQAMTFLIRDQKLGANVGSAQGPTGLGKYLMRSPTGEIIFGGETMRFWDFRGPWLEPLRGPNGLDLNKIKNDIQPWQERRAAEYMTHAPLGSLNSVGGVATEINSVNFVSPRSWLATSHFVLAFFFLVGHLWHAGRARAAAAGFEKGIDRESEPVLSMPSLD
->6ujv_A mol:protein length:129  Envelope glycoprotein GP41
-LLELDKWASLWNWFDITNWLWYIRIFIIIVGSLIGLRIVFAVLSLVNRVRQGYSPLSFQTHLPTPRGPDRPEGIEEEGGERDRDRSIRLVNGSLALIWDDLRSLSLFSYHRLRDLLLIVTRIVELLGRR
->5lzf_d mol:protein length:205  30S ribosomal protein S4
-ARYLGPKLKLSRREGTDLFLKSGVRAIDTKCKIEQAPGQHGARKPRLSDYGVQLREKQKVRRIYGVLERQFRNYYKEAARLKGNTGENLLALLEGRLDNVVYRMGFGATRAEARQLVSHKAIMVNGRVVNIASYQVSPNDVVSIREKAKKQSRVKAALELAEQREKPTWLEVDAGKMEGTFKRKPERSDLSADINEHLIVELYSK
->3j92_l mol:protein length:51  eL39
-MSSHKTFRIKRFLAKKQKQNRPIPQWIRMKTGNKIRYNSKRRHWRRTKLGL
->4ato_A mol:protein length:194  TOXN
-MTNKDNPKFHTISTEYIDYLREADSKVPFNKDEQHSRPYVGVLEKINGHDYFVPLTSRNDKNFNSQVSVKLFDNDEKRIGVLLVNNMIPVPEKECKEIDIAEKTAADPQYGNLMLKQYLFLKENMDRVTNKVEKVYKDVTVQGKPSHKQKFLKGVCCDFPKLEEKCQEYKERDQAKERDKARRIAYMRQMGRER
->6sh8_N mol:protein length:174  CRISPR-associated protein Cmrx
-MSTQREYVFIPITNSITIDVKITIGGSDHITNIDERGIHNVLVITGYAVDEKNGRLVPTLDPCDYVKGILVAGTPQQAQSNDFLTLKLPANKLYLIRKKGNISDDLKIYIPYSSPDARNSMKTKPVSISDDTIVNNIIKEVFDKIYNITQKEKVKIEKVKEDIKELFSYYALEQ
->4v86_S mol:protein length:520  Capsid protein VP1
-GADGVGNASGNWHCDSTWLGDRVITTSTRTWALPTYNNHLYKQISSASTGASNDNHYFGYSTPWGYFDFNRFHCHFSPRDWQRLINNNWGFRPKRLNFKLFNIQVKEVTTNDGVTTIANNLTSTVQVFSDSEYQLPYVLGSAHQGCLPPFPADVFMIPQYGYLTLNNGSQAVGRSSFYCLEYFPSQMLRTGNNFTFSYTFEDVPFHSSYAHSQSLDRLMNPLIDQYLYYLNRTQNQSGSAQNKDLLFSRGSPAGMSVQPKNWLPGPCYRQQRVSKTKTDNNNSNFTWTGASKYNLNGRESIINPGTAMASHKDDKDKFFPMSGVMIFGKESAGASNTALDNVMITDEEEIKATNPVATERFGTVAVNLQSSSTDPATGDVHVMGALPGMVWQDRDVYLQGPIWAKIPHTDGHFHPSPLMGGFGLKHPPPQILIKNTPVPANPPAEFSATKFASFITQYSTGQVSVEIEWELQKENSKRWNPEVQYTSNYAKSANVDFTVDNNGLYTEPRPIGTRYLTRPL
->4kis_B mol:protein length:328  Putative integrase [Bacteriophage A118]
-RDRMVMGKIKRIEAGLPLTTAKGRTFGYDVIDTKLYINEEEAKQLRLIYDIFEEEQSITFLQKRLKKLGFKVRTYNRYNNWLTNDLYCGYVSYKDKVHVKGIHEPIISEEQFYRVQEIFSRMGKNPNMNKESASLLNNLVVCSKCGLGFVHRRKDTVSRGKKYHYRYYSCKTYKHTHELEKCGNKIWRADKLEELIIDRVNNYSFASRNIDKEDELDSLNEKLKIEHAKKKRLFDLYINGSYEVSELDSMMNDIDAQINYYEAQIEANEELKKNKKIQENLADLATVDFNSLEFREKQLYLKSLINKIYIDGEQVTIEWLLEHHHHHH
->3vap_A mol:protein length:272  Aurora kinase A
-GAMGSKRQWALEDFEIGRPLGKGKFGNVYLAREKQSKFILALKVLFKAQLEKAGVEHQLRREVEIQSHLRHPNILRLYGYFHDATRVYLILEYAPLGTVYRELQKLSKFDEQRTATYITELANALSYCHSKRVIHRDIKPENLLLGSAGELKIADFGWSVHAPSSRRTTLCGTLDYLPPEMIEGRMHDEKVDLWSLGVLCYEFLVGKPPFEANTYQETYKRISRVEFTFPDFVTEGARDLISRLLKHNPSQRPMLREVLEHPWITANSSKPS
->2ybu_F mol:protein length:381  ACIDIC MAMMALIAN CHITINASE
-EAEAYQLTCYFTNWAQYRPGLGRFMPDDINPCLCTHLIYAFAGMQNNEITTIEWNDVTLYQAFNGLKNKNSQLKTLLAIGGWNFGTAPFTAMVSTPENRQTFITSVIKFLRQYEFDGLDFDWEYPGSRGSPPQDKHLFTVLVQEMREAFEQEAKQINKPRLMVTAAVAAGISNIQSGYEIPQLSQYLDYIHVMTYDLHGSWEGYTGENSPLYKYPTDTGSNAYLNVDYVMNYWKDNGAPAEKLIVGFPTYGHNFILSNPSNTGIGAPTSGAGPAGPYAKESGIWAYYEICTFLKNGATQGWDAPQEVPYAYQGNVWVGYDNIKSFDIKAQWLKHNKFGGAMVWAIDLDDFTGTFCNQGKFPLISTLKKALGLQSASCTAPA
->7ebk_A mol:protein length:187  Tripartite motif-containing protein 66
-SPIENEDFCAVCINGGELLCCDRCPKVYHLSCHVPALLSFPGGEWVCTLCRSLTQPEMEYDCENARYGVRVLPGLSMYDQKKCEKLVLSLCCNSLSLPFHEPVSPLARHYYQIIKRPMDLSIIRRKLQKKDPAHYTTPEEVVSDVRLMFWNCAKFNYPDSEVAEAGRCLEVFFEGWLKEIYPDKCFA
->4pcf_B mol:protein length:239  Ma18-TIM
-MSKPQPIAAANWKSGSPDSLSGLIDLFNSTSINHDVQCVVASTFVHLAMTKERLSHPKFVIAAQNAGNTDALASLKDFGVNWIVLGHFERRWYYGETNEIVADKVAAAVASGFMVIACIGETLQERESGRTAVVVLTQIAAIAKKLKKADWAKVVIAYEPVWAIGTGKVVTPQQAQEAHALIRSWVSSKIGADVAGELRILYGGSVNGKNARTLYQQRDVNGFLAGLKPEFVDIIKATQ
->3txx_F mol:protein length:359  Putrescine carbamoyltransferase
-MGSSHHHHHHSSGLVPRGSHMKRDYVTTETYTKEEMHYLVDLSLKIKEAIKNGYYPQLLKNKSLGMIFQQSSTRTRVSFETAMEQLGGHGEYLAPGQIQLGGHETIEDTSRVLSRLVDILMARVERHHSIVDLANCATIPVINGMSDYNHPTQELGDLCTMVEHLPEGKKLEDCKVVFVGDATQVCFSLGLITTKMGMNFVHFGPEGFQLNEEHQAKLAKNCEVSGGSFLVTDDASSVEGADFLYTDVWYGLYEAELSEEERMKVFYPKYQVNQEMMDRAGANCKFMHCLPATRGEEVTDEVIDGKNSICFDEAENRLTSIRGLLVYLMNDYEAKNPYDLIKQAEAKKELEVFLDTQSI
->6oro_A mol:protein length:153  RC1 variant of HIV-1 Env glycoprotein gp41
-AVGIGAVSLGFLGAAGSTMGAASMTLTVQARNLLSGIVQQQSNLLRAPEPQQHLLKDTHWGIKQLQARVLAVEHYLRDQQLLGIWGCSGKLICCTNVPWNSSWSNRNLSEIWDNMTWLQWDKEISNYTQIIYGLLEESQNQQEKNEQDLLALD
->2yso_A mol:protein length:46  Zinc finger protein 95 homolog
-GSSGSSGSREKSHQCRECGEIFFQYVSLIEHQVLHMGQKNSGPSSG
->7nal_H mol:protein length:697  NAD(+) hydrolase SARM1
-LAVPGPDGGGGTGPWWAAGGRGPREVSPGAGTEVQDALERALPELQQALSALKQAGGARAVGAGLAEVFQLVEEAWLLPAVGREVAQGLCDAIRLDGGLDLLLRLLQAPELETRVQAARLLEQILVAENRDRVARIGLGVILNLAKEREPVELARSVAGILEHMFKHSEETCQRLVAAGGLDAVLYWCRRTDPALLRHCALALGNCALHGGQAVQRRMVEKRAAEWLFPLAFSKEDELLRLHACLAVAVLATNKEVEREVERSGTLALVEPLVASLDPGRFARCLVDASDTSQGRGPDDLQRLVPLLDSNRLEAQCIGAFYLCAEAAIKSLQGKTKVFSDIGAIQSLKRLVSYSTNGTKSALAKRALRLLGEEVPRPILPSVPSWKEAEVQTWLQQIGFSKYCESFREQQVDGDLLLRLTEEELQTDLGMKSGITRKRFFRELTELKTFANYSTCDRSNLADWLGSLDPRFRQYTYGLVSCGLDRSLLHRVSEQQLLEDCGIHLGVHRARILTAAREMLHSPLPCTGGKPSGDTPDVFISYRRNSGSQLASLLKVHLQLHGFSVFIDVEKLEAGKFEDKLIQSVMGARNFVLVLSPGALDKCMQDHDCKDWVHKEIVTALSCGKNIVPIIDGFEWPEPQVLPEDMQAVLTFNGIKWSHEYQEATIEKIIRFLQGRSSRDSSAGSDTSLEGAAPMGPT
->3dv5_C mol:protein length:402  Beta-secretase 1
-GPDEEPEEPGRRGSFVEMVDNLRGKSGQGYYVEMTVGSPPQTLNILVDTGSSNFAVGAAPHPFLHRYYQRQLSSTYRDLRKGVYVPYTQGKWEGELGTDLVSIPHGPNVTVRANIAAITESDKFFINGSNWEGILGLAYAEIARPDDSLEPFFDSLVKQTHVPNLFSLQLCGAGFPLNQSEVLASVGGSMIIGGIDHSLYTGSLWYTPIRREWYYEVIIVRVEINGQDLKMDCKEYNYDKSIVDSGTTNLRLPKKVFEAAVKSIKAASSTEKFPDGFWLGEQLVCWQAGTTPWNIFPVISLYLMGEVTNQSFRITILPQQYLRPVEDVATSQDDCYKFAISQSSTGTVMGAVIMEGFYVVFDRARKRIGFAVSACHVHDEFRTAAVEGPFVTLDMEDCGYNI
->5lky_C mol:protein length:300  N-acetylneuraminate lyase
-MEHHHHHHNKDLKGLYAALLVPFDENGQVNEQGLKQIAQNAIETEELDGLYVNGSSGENFLLNTEQKKQVFKVAKEAVGDKVKLIAQVGSLDLNEAIELGKYATELGYDALSAVTPFYYPFTFEEIRDYYFDIIEATQNNMIIYAIPDLTGVNISIEQFSELFNHEKIVGVKYTAPNFFLLERIRKAFPDKLILSGCDEMLVQATISGVDGAIGSTYNVNGRRARKIFDLARQGQIQEAYQLQHDSNDIIETVLSMGIYPTLKEILRHRGIDAGLPKRPFKPFNEAHRQTLDQLIAKYDL
->5lzz_OO mol:protein length:168  uS11
-MKARALSGSGVRRRRAAMAPRKGKEKKEEQVISLGPQVAEGENVFGVCHIFASFNDTFVHVTDLSGKETICRVTGGMKVKADRDESSPYAAMLAAQDVAQRCKELGITALHIKLRATGGNRTKTPGPGAQSALRALARSGMKIGRIEDVTPIPSDSTRRKGGRRGRRL
->6swb_A mol:protein length:135  Two-component response regulator
-HHHHHHWKVLIADDEAIIREGIRESIDWNEFNMEVVAEAEDGEEALELALRHRVDVLFVDLSMPIMDGLTLMKYAREKLPNCHMIVITGYDEFSYAQEAIRLQVDDYLLKPTDPQRLREVVAKVKEKLEQEQKEK
->1z7h_A mol:protein length:447  Tetanus toxin light chain
-GSHMMPITINNFRYSDPVNNDTIIMMEPPYCKGLDIYYKAFKITDRIWIVPERYEFGTKPEDFNPPSSLIEGASEYYDPNYLRTDSDKDRFLQTMVKLFNRIKNNVAGEALLDKIINAIPYLGNSYSLLDKFDTNSNSVSFNLLEQDPSGATTKSAMLTNLIIFGPGPVLNKNEVRGIVLRVDNKNYFPCRDGFGSIMQMAFCPEYVPTFDNVIENITSLTIGKSKYFQDPALLLMHELIHVLHGLYGMQVSSHEIIPSKQEIYMQHTYPISAEELFTFGGQDANLISIDIKNDLYEKTLNDYKAIANKLSQVTSCNDPNIDIDSYKQIYQQKYQFDKDSNGQYIVNEDKFQILYNSIMYGFTEVELGKKFNIKTRLSYFSMNHDPVKIPNLLDDTIYNDTEGFNIESKDLKSEYKGQNMRVNTNAFRNVDGSGLVSKLIGLCKKII
->6sic_o mol:protein length:174  CRISPR-associated protein Cmrx
-MSTQREYVFIPITNSITIDVKITIGGSDHITNIDERGIHNVLVITGYAVDEKNGRLVPTLDPCDYVKGILVAGTPQQAQSNDFLTLKLPANKLYLIRKKGNISDDLKIYIPYSSPDARNSMKTKPVSISDDTIVNNIIKEVFDKIYNITQKEKVKIEKVKEDIKELFSYYALEQ
->1nlq_C mol:protein length:108  Nucleoplasmin-like protein
-MAEESFYGVTLTAESDSVTWDVDEDYARGQKLVIKQILLGAEAKENEFNVVEVNTPKDSVQIPIAVLKAGETRAVNPDVEFYESKVTFKLIKGSGPVYIHGHNIKDDV
->3gtc_A mol:protein length:358  Beta-lactamase
-APQQINDIVHRTITPLIEQQKIPGMAVAVIYQGKPYYFTWGYADIAKKQPVTQQTLFELGSVSKTFTGVLGGDAIARGEIKLSDPTTKYWPELTAKQWNGITLLHLATYTAGGLPLQVPDEVKSSSDLLRFYQNWQPAWAPGTQRLYANSSIGLFGALAVKPSGLSFEQAMQTRVFQPLKLNHTWINVPPAEEKNYAWGYREGKAVHVSPGALDAEAYGVKSTIEDMARWVQSNLKPLDINEKTLQQGIQLAQSRYWQTGDMYQGLGWEMLDWPVNPDSIINGSDNKIALAARPVKAITPPTPAVRASWVHKTGATGGFGSYVAFIPEKELGIVMLANKNYPNPARVDAAWQILNALQ
->7av1_A mol:protein length:613  Leukotriene A-4 hydrolase
-GPGPEIVDTCSLASPASVCRTKHLHLRCSVDFTRRTLTGTAALTVQSQEDNLRSLVLDTKDLTIEKVVINGQEVKYALGERQSYKGSPMEISLPIALSKNQEIVIEISFETSPKSSALQWLTPEQTSGKEHPYLFSQCQAIHCRAILPCQDTPSVKLTYTAEVSVPKELVALMSAIRDGETPDPEDPSRKIYKFIQKVPIPCYLIALVVGALESRQIGPRTLVWSEKEQVEKSAYEFSETESMLKIAEDLGGPYVWGQYDLLVLPPSFPYGGMENPCLTFVTPTLLAGDKSLSNVIAHEISHSWTGNLVTNKTWDHFWLNEGHTVYLERHICGRLFGEKFRHFNALGGWGELQNSVKTFGETHPFTKLVVDLTDIDPDVAYSSVPYEKGFALLFYLEQLLGGPEIFLGFLKAYVEKFSYKSITTDDWKDFLYSYFKDKVDVLNQVDWNAWLYSPGLPPIKPNYDMTLTNACIALSQRWITAKEDDLNSFNATDLKDLSSHQLNEFLAQTLQRAPLPLGHIKRMQEVYNFNAINNSEIRFRWLRLCIQSKWEDAIPLALKMATEQGRMKFTRPLFKDLAAFDKSHDQAVRTYQEHKASMHPVTAMLVGKDLKVD
->3wkm_B mol:protein length:180  Putative zinc metalloprotease aq_1964
-GSEVPKYLKEPVVVGYVQRDSIAQKIGIKPGDKIIKINGYEVRTWEDLRDALIRLSLDGVKETTLFLERNGEVLHLTIKVPNVQKGEELGIAPLVKPVVGGVKKGSPADQVGIKPGDLILEVNGKKINTWYELVEEVRKSQGKAIKLKILRNGKMIEKELIPAKDPKTGTYFIGLFPKTE
->7mei_e mol:protein length:215  DNA-directed RNA polymerases I, II, and III subunit RPABC1
-MDQENERNISRLWRAFRTVKEMVKDRGYFITQEEVELPLEDFKAKYCDSMGRPQRKMMSFQANPTEESISKFPDMGSLWVEFCDEPSVGVKTMKTFVIHIQEKNFQTGIFVYQNNITPSAMKLVPSIPPATIETFNEAALVVNITHHELVPKHIRLSSDEKRELLKRYRLKESQLPRIQRADPVALYLGLKRGEVVKIIRKSETSGRYASYRICM
->1e67_D mol:protein length:128  AZURIN
-AECSVDIQGNDQMQFNTNAITVDKSCKQFTVNLSHPGNLPKNVMGHNWVLSTAADMQGVVTDGMASGLDKDYLKPDDSRVIAHTKLIGSGEKDSVTFDVSKLKEGEQYMFFCTFPGHSALMKGTLTLK
->5dzn_F mol:protein length:114  T-cell immunoglobulin and mucin domain-containing protein 4
-MVTSETVVTEVLGHRVTLPCLYSSWSHNSNSMCWGKDQCPYSGCKEALIRTDGMRVTSRKSAKYRLQGTIPRGDVSLTILNPSESDSGVYCCRIEVPGWFNDVKINVRLNLQRA
->3s34_L mol:protein length:214  1121B Fab light chain
-DIQMTQSPSSVSASIGDRVTITCRASQGIDNWLGWYQQKPGKAPKLLIYDASNLDTGVPSRFSGSGSGTYFTLTISSLQAEDFAVYFCQQAKAFPPTFGGGTKVDIKRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNRGEC
->6wz5_A mol:protein length:135  Histone H3.2
-ARTKQTARKSTGGKAPRKQLATKAARKSAPATGGVKKPHRYRPGTVALREIRRYQKSTELLIRKLPFQRLVREIAQDFKTDLRFQSSAVMALQEASEAYLVALFEDTNLCAIHAKRVTIMPKDIQLARRIRGERA
->6r1u_A mol:protein length:135  Histone H3.2
-ARTKQTARKSTGGKAPRKQLATKAARKSAPATGGVKKPHRYRPGTVALREIRRYQKSTELLIRKLPFQRLVREIAQDFKTDLRFQSSAVMALQEASEAYLVALFEDTNLCAIHAKRVTIMPKDIQLARRIRGERA
->1ht6_A mol:protein length:405  ALPHA-AMYLASE ISOZYME 1
-HQVLFQGFNWESWKQSGGWYNMMMGKVDDIAAAGVTHVWLPPPSHSVSNEGYMPGRLYDIDASKYGNAAELKSLIGALHGKGVQAIADIVINHRCADYKDSRGIYCIFEGGTSDGRLDWGPHMICRDDTKYSDGTANLDTGADFAAAPDIDHLNDRVQRELKEWLLWLKSDLGFDAWRLDFARGYSPEMAKVYIDGTSPSLAVAEVWDNMATGGDGKPNYDQDAHRQNLVNWVDKVGGAASAGMVFDFTTKGILNAAVEGELWRLIDPQGKAPGVMGWWPAKAVTFVDNHDTGSTQAMWPFPSDKVMQGYAYILTHPGIPCIFYDHFFNWGFKDQIAALVAIRKRNGITATSALKILMHEGDAYVAEIDGKVVVKIGSRYDVGAVIPAGFVTSAHGNDYAVWEKN
->2av7_E mol:protein length:100  Beta-2-microglobulin
-MIQRTPKIQVYSRHPAENGKSNFLNCYVSGFHPSDIEVDLLKNGERIEKVEHSDLSFSKDWSFYLLYYTEFTPTEKDEYACRVNHVTLSQPKIVKWDRDM
->5pcd_A mol:protein length:138  Bromodomain adjacent to zinc finger domain protein 2B
-MHHHHHHSSGVDLGTENLYFQSMSVKKPKRDDSKDLALCSMILTEMETHEDAWPFLLPVNLKLVPGYKKVIKKPMDFSTIREKLSSGQYPNLETFALDVRLVFDNCETFNEDDSDIGRAGHNMRKYFEKKWTDTFKVS
->5cx1_L mol:protein length:523  Nitrogenase molybdenum-iron protein beta chain
-MSQQVDKIKASYPLFLDQDYKDMLAKKRDGFEEKYPQDKIDEVFQWTTTKEYQELNFQREALTVNPAKACQPLGAVLCALGFEKTMPYVHGSQGCVAYFRSYFNRHFREPVSCVSDSMTEDAAVFGGQQNMKDGLQNCKATYKPDMIAVSTTCMAEVIGDDLNAFINNSKKEGFIPDEFPVPFAHTPSFVGSHVTGWDNMFEGIARYFTLKSMDDKVVGSNKKINIVPGFETYLGNFRVIKRMLSEMGVGYSLLSDPEEVLDTPADGQFRMYAGGTTQEEMKDAPNALNTVLLQPWHLEKTKKFVEGTWKHEVPKLNIPMGLDWTDEFLMKVSEISGQPIPASLTKERGRLVDMMTDSHTWLHGKRFALWGDPDFVMGLVKFLLELGCEPVHILCHNGNERWKKAVDAILAASPYGKNATVYIGKDLWHLRSLVFTDKPDFMIGNSYGKFIQRDTLHKGKEFEVPLIRIGFPIFDRHHLHRSTTLGYEGAMQILTTLVNSILERLDEETRGMQATDYNHDLVR
->3cw1_1 mol:protein length:86  Small nuclear ribonucleoprotein F
-MSLPLNPKPFLNGLTGKPVMVKLKWGMEYKGYLVSVDGYMNMQLANTEEYIDGALSGHLGEVLIRCNNVLYIRGVEEEEEDGEMRE
->7toc_A mol:protein length:363  Ketol-acid reductoisomerase, mitochondrial
-SNAPVVSAAPLATRGLKTINFGGTEEVVHERADWPREKLLEYFKNDTMALIGYGSQGYGQGLNLRDNGLNVIIGVRKNGASWKAAIEDGWVPGENLFDVKEAITKGTIIMNLLSDAAQSETWPDLKPLITEGKTLYFSHGFSPVFKDLTKVEPPSNVDVILAAPKGSGRTVRSLFLEGRGINSSYAVWNDVTGKAEEKAIAMAVAIGSGYVYQTTFEREVNSDLYGERGCLMGGIHGMFLAQYEVLRENGHTPSEAFNETVEEATQSLYPLIGKYGMDYMYDACSTTARRGALDWYPRFKDALKPVFVELYESVKNGTETQRSLDFNGAPDYRERLEEELETIRNMEIWKVGKEVRKLRPENQ
->6yfg_IG mol:protein length:130  coat protein
-SKPIAIFKLRELSSDSTLFTLPGHSVTLPNTLGIVSHLPTPRKGNPGTVKTMRNLRKTILLGAGTASERAVPIVIKTETSFPVGTTEEDRAEVLKQMASFLIEEVKNNQELAYSGYVQDKYFIEDLVITE
->4ac5_H mol:protein length:258  REACTION CENTER PROTEIN H CHAIN
-MYHGALAQHLDIAQLVWYAQWLVIWTVVLLYLRREDRREGYPLVEPLGLVKLAPEDGQVYELPYPKTFVLPHGGTVTVPRRRPETRELKLAQTDGFEGAPLQPTGNPLVDAVGPASYAERAEVVDATVDGKAKIVPLRVATDFSIAEGDVDPRGLPVVAADGVEAGTVTDLWVDRSEHYFRYLELSVAGSARTALIPLGFCDVKKDKIVVTSILSEQFANVPRLQSRDQITLREEDKVSAYYAGGLLYATPERAESLL
->5m9e_B mol:protein length:77  Microtubule integrity protein mal3
-SGSAKQAQQQITSLETQLYEVNETMFGLERERDFYFNKLREIEILVQTHLTTSPMSMENMLERIQAILYSTEDGFEL
->5o61_BH mol:protein length:132  30S ribosomal protein S8
-MTMTDPIADFLTRLRNANSAYHDEVTLPHSKLKANIAEILKREGYISDYRTEDARVGKSLVVQLKYGPSRERSIAGLRRVSKPGLRVYAKSTNLPRVLGGLGVAIISTSSGLLTDRQAARQGVGGEVLAYVW
->6owg_CF mol:protein length:105  Ethanolamine utilization protein EutN/carboxysome structural protein Ccml
-MQMAKVCGTVVGTQKLPSMTGVKLLLLQFIDANGELLPKYEVAADPVGAGLGEWVLVNRGSAARQTEYHQNRPLDAMVVAIIDTVTVNNRRLYGEGSWSHPQFEK
->6ywv_K mol:protein length:249  60S ribosomal protein L16
-MKHNASSALLSAFQGLRISSSATPFRAASLATSAVRRPIAPTPVSVASHVRLFSATAIQAGSWLEPNLNRKKKMMKGRPRVPTGGSTKGTTVVWGDYGLRMRDHHRRISAQQLKLAEDTIKQRLRGQKYRLYKRVACNVGVYVSGNEMRMGKGKGSFDHWATRVAVNQIIFEIRGQLHEQVIRDAFRLAGHKLPGLYEFVKKGDPPVVGITKLEDGLTVEDLKNPRKKLLMPEITQSAASTSSTAAPPS
->2f0x_F mol:protein length:148  Thioesterase superfamily member 2
-MTSMTQSLREVIKAMTKARNFERVLGKITLVSAAPGKVICEMKVEEEHTNAIGTLHGGLTATLVDNISTMALLCTERGAPGVSVDMNITYMSPAKLGEDIVITAHVLKQGKTLAFTSVDLTNKATGKLIAQGRHTKHLGNLEHHHHHH
->2q28_B mol:protein length:564  oxalyl-CoA decarboxylase
-MSDQLQMTDGMHIIVEALKQNNIDTIYGVVGIPVTDMARHAQAEGIRYIGFRHEQSAGYAAAASGFLTQKPGICLTVSAPGFLNGLTALANATVNGFPMIMISGSSDRAIVDLQQGDYEELDQMNAAKPYAKAAFRVNQPQDLGIALARAIRVSVSGRPGGVYLDLPANVLAATMEKDEALTTIVKVENPSPALLPCPKSVTSAISLLAKAERPLIILGKGAAYSQADEQLREFIESAQIPFLPMSMAKGILEDTHPLSAAAARSFALANADVVMLVGARLNWLLAHGKKGWAADTQFIQLDIEPQEIDSNRPIAVPVVGDIASSMQGMLAELKQNTFTTPLVWRDILNIHKQQNAQKMHEKLSTDTQPLNYFNALSAVRDVLRENQDIYLVNEGANTLDNARNIIDMYKPRRRLDCGTWGVMGIGMGYAIGASVTSGSPVVAIEGDSAFGFSGMEIETICRYNLPVTIVIFNNGGIYRGDGVDLSGAGAPSPTDLLHHARYDKLMDAFRGVGYNVTTTDELRHALTTGIQSRKPTIINVVIDPAAGTESGHITKLNPKQVAGN
->3n7k_A mol:protein length:426  Botulinum neurotoxin type C1
-NNINDSKILSLQNRKNTLVDTSGYNAEVSEEGDVQLNPIFPFDFKLGSSGEDRGKVIVTQNENIVYNSMYESFSISFWIRINKWVSNLPGYTIIDSVKNNSGWSIGIISNFLVFTLKQNEDSEQSINFSYDISNNAPGYNKWFFVTVTNNMMGNMKIYINGKLIDTIKVKELTGINFSKTITFEINKIPDTGLITSDSDNINMWIRDFYIFAKELDGKDINILFNSLQYTNVVKDYWGNDLRYNKEYYMVNIDYLNRYMYANSRQIVFNTRRNNNDFNEGYKIIIKRIRGNTNDTRVRGGDILYFDMTINNKAYNLFMKNETMYADNHSTEDIYAIGLREQTKDINDNIIFQIQPMNNTYYYASQIFKSNFNGENISGICSIGTYRFRLGGDWYRHNYLVPTVKQGNYASLLESTSTHWGFVPVSE
->6q6g_A mol:protein length:1855  Anaphase-promoting complex subunit 1,Anaphase-promoting complex subunit 1
-MSNFYEERTTMIAARDLQEFVPFGRDHCKHHPNALNLQLRQLQPASELWSSDGAAGLVGSLQEVTIHEKQKESWQLRKGVSEIGEDVDYDEELYVAGNMVIWSKGSKSQALAVYKAFTVDSPVQQALWCDFIISQDKSEKAYSSNEVEKCICILQSSCINMHSIEGKDYIASLPFQVANVWPTKYGLLFERSASSHEVPPGSPREPLPTMFSMLHPLDEITPLVCKSGSLFGSSRVQYVVDHAMKIVFLNTDPSIVMTYDAVQNVHSVWTLRRVKSEEENVVLKFSEQGGTPQNVATSSSLTAHLRLAPETEPIVPELCIDHLWTETITNIREKNSQASKVFITSDLCGQKFLCFLVESQLQLRCVKFQESNDKTQLIFGSVTNIPAKDAAPVEKIDTMLVLEGSGNLVLYTGVVRVGKVFIPGLPAPSLTMSNTMPRPSTPLDGVSTPKPLSKLLGSLDEVVLLSPVPELRDSSKLHDSLYNEDCTFQQLGTYIHSIRDPVHNRVTLELSNGSMVRITIPEIATSELVQTCLQAIKFILPKEIAVQMLVKWYNVHSAPGGPSYHSEWNLFVTCLMNMMGYNTDRLAWTRNFDFEGSLSPVIAPKKARPSETGSDDDWEYLLNSDYHQNVESHLLNRSLCLSPSEASQMKDEDFSQNLSLDSSTLLFTHIPAIFFVLHLVYEELKLNTLMGEGICSLVELLVQLARDLKLGPYVDHYYRDYPTLVRTTGQVCTIDPGQTGFMHHPSFFTSEPPSIYQWVSSCLKGEGMPPYPYLPGICERSRLVVLSIALYILGDESLVSDESSQYLTRITIAPQKLQVEQEENRFSFRHSTSVSSLAERLVVWMTNVGFTLRDLETLPFGIALPIRDAIYHCREQPASDWPEAVCLLIGRQDLSKQACEGNLPKGKSVLSSDVPSGTETEEEDDGMNDMNHEVMSLIWSEDLRVQDVRRLLQSAHPVRVNVVQYPELSDHEFIEEKENRLLQLCQRTMALPVGRGMFTLFSYHPVPTEPLPIPKLNLTGRAPPRNTTVDLNSGNIDVPPNMTSWASFHNGVAAGLKIAPASQIDSAWIVYNKPKHAELANEYAGFLMALGLNGHLTKLATLNIHDYLTKGHEMTSIGLLLGVSAAKLGTMDMSITRLLSIHIPALLPPTSTELDVPHNVQVAAVVGIGLVYQGTAHRHTAEVLLAEIGRPPGPEMEYCTDRESYSLAAGLALGMVCLGHGSNLIGMSDLNVPEQLYQYMVGGHRRFQTGMHREKHKSPSYQIKEGDTINVDVTCPGATLALAMIYLKTNNRSIADWLRAPDTMYLLDFVKPEFLLLRTLARCLILWDDILPNSKWVDSNVPQIIRENSISLSEIELPCSEDLNLETLSQAHVYIIAGACLSLGFRFAGSENLSAFNCLHKFAKDFMTYLSAPNASVTGPHNLETCLSVVLLSLAMVMAGSGNLKVLQLCRFLHMKTGGEMNYGFHLAHHMALGLLFLGGGRYSLSTSNSSIAALLCALYPHFPAHSTDNRYHLQALRHLYVLAAEPRLLVPVDVDTNTPCYALLEVTYKGTQWYEQTKEELMAPTLLPELHLLKQIKVKGPRYWELLIDLSKGTQHLKSILSKDGVLYVKLRAGQLSYKEDPMGWQSLLAQTVANRNSEARAFKPETISAFTSDPALLSFAEYFCKPTVNMGQKQEILDLFSSVLYECVTQETPEMLPAYIAMDQAIRRLGRREMSETSELWQIKLVLEFFSSRSHQERLQNHPKRGLFMNSEFLPVVKCTIDNTLDQWLQVGGDMCVHAYLSGQPLEESQLSMLACFLVYHSVPAPQHLPPIGLEGSTSFAELLFKFKQLKMPVRALLRLAPLLLGNPQPMVM
->6riq_F mol:protein length:144  MinC
-KDSAPRKPAEEPSPSVGEARPEPAKAEEKPAEPVSRPTKVVKTPVRGGMQIYAAGGDLIVLAAVSPGAELLADGNIHVYGPMRGRALAGVKGDATARIFCQQLAAELVSIAGNYKVAEDLRRSPQWGKAVHVSLSGDVLNITRL
->7ohr_v mol:protein length:231  Nucleolar protein 16
-MTSVRKRKMNRSSVGKATRRNKDKQRKINIQSNPIIAANWDYSLTMAQNYKKLGLRAKLQTPAGGKEADLSKVVKRIPLTKPVLDEDEDEDEGEDEQNDYNAATVELDENEIPEGGARIQRDKNGDVVRVVYGKKKNFDADEDVNEIKARDTTEETEVVKKLEELASRPVIRKERSQSEREEEWLEKLYKKHGDDYKKMFFDKKLNIYQQSEGDLKRRLLRWKKRNGIASK
->4v89_B7 mol:protein length:65  50S ribosomal protein L35
-MPKIKTVRGAAKRFKKTGKGGFKHKHANLRHILTKKATKRKRHLRPKAMVSKGDLGLVIACLPYA
->3gdv_D mol:protein length:3  YQF peptide
-YQF
->7du2_M mol:protein length:708  DNA-directed RNA polymerase III subunit RPC5
-MANEEDDPVVQEIDVYLAKSLAEKLYLFQYPVRPASMTYDDIPHLSAKIKPKQQKVELEMAIDTLNPNYCRSKGEQIALNVDGACADETSTYSSKLMDKQTFCSSQTTSNTSRYAAALYRQGELHLTPLHGILQLRPSFSYLDKADAKHREREAANEAGDSSQDEAEDDVKQITVRFSRPESEQARQRRVQSYEFLQKKHAEEPWVHLHYYGLRDSRSEHERQYLLCPGSSGVENTELVKSPSEYLMMLMPPSQEEEKDKPVAPSNVLSMAQLRTLPLADQIKILMKNVKVMPFANLMSLLGPSIDSVAVLRGIQKVAMLVQGNWVVKSDILYPKDSSSPHSGVPAEVLCRGRDFVMWKFTQSRWVVRKEVATVTKLCAEDVKDFLEHMAVVRINKGWEFILPYDGEFIKKHPDVVQRQHMLWTGIQAKLEKVYNLVKETMPKKPDAQSGPAGLVCGDQRIQVAKTKAQQNHALLERELQRRKEQLRVPAVPPGVRIKEEPVSEEGEEDEEQEAEEEPMDTSPSGLHSKLANGLPLGRAAGTDSFNGHPPQGCASTPVARELKAFVEATFQRQFVLTLSELKRLFNLHLASLPPGHTLFSGISDRMLQDTVLAAGCKQILVPFPPQTAASPDEQKVFALWESGDMSDQHRQVLLEIFSKNYRVRRNMIQSRLTQECGEDLSKQEVDKVLKDCCVSYGGMWYLKGTVQS
->6qiu_P mol:protein length:10  Ataxin-1 phosphopeptide
-KRRWSAPESR
->7dbc_D mol:protein length:445  Tubulin beta chain
-MREIVHIQAGQCGNQIGAKFWEVISDEHGIDPTGSYHGDSDLQLERINVYYNEATGNKYVPRAILVDLEPGTMDSVRSGPFGQIFRPDNFVFGQSGAGNNWAKGHYTEGAELVDSVLDVVRKESESCDCLQGFQLTHSLGGGTGSGMGTLLISKIREEYPDRIMNTFSVMPSPKVSDTVVEPYNATLSVHQLVENTDETYCIDNEALYDICFRTLKLTTPTYGDLNHLVSATMSGVTTCLRFPGQLNADLRKLAVNMVPFPRLHFFMPGFAPLTSRGSQQYRALTVPELTQQMFDSKNMMAACDPRHGRYLTVAAIFRGRMSMKEVDEQMLNVQNKNSSYFVEWIPNNVKTAVCDIPPRGLKMSATFIGNSTAIQELFKRISEQFTAMFRRKAFLHWYTGEGMDEMEFTEAESNMNDLVSEYQQYQDATADEQGEFEEEEGEDEA
->2kd3_A mol:protein length:113  Sclerostin
-GSHMNGGRPPHHPYDAKDVSEYSCRELHYTRFLTDGPCRSAKPVTELVCSGQCGPARLLPNAIGRVKWWRPNGPDFRCIPDRYRAQRVQLLCPGGAAPRSRKVRLVASCKCKR
->3e15_D mol:protein length:312  Glucose-6-phosphate 1-dehydrogenase
-MAHHHHHHMDCQALAKSLEQMNHLHNVKYLEAKDLTDFNQKSAYYICHQIAEKQLSKEGGHVVIGLSGGKTPIDVYKNIALVKDIKIDTSKLIFFIIDERYKRDDHKFSNYNNIKFLFESLKINEKEQLYRPDTSKNIVECVRDYNEKIKNMVKKYTKVDIAILGMGSDFHIASLFPNIFFNIYMNNYQNSYIYDESSIKVANSNDTSDNDNLDLLKEYVYFTTTNNFDVRKRITVSLDLLGNASSKIFLLNSTDKLDLWKNMLLKSYVDVNYCLYPAVYLIDSMNTTVVTCGYTNYPQMLEDIYVSNSSLS
->6xhv_1S mol:protein length:112  50S ribosomal protein L18
-MARLTAYERRKFRVRNRIKRTGRLRLSVFRSLKHIYAQIIDDEKGVTLVSASSLALKLKGNKTEVARQVGRALAEKALALGIKQVAFDRGPYKYHGRVKALAEGAREGGLEF
->4l1u_E mol:protein length:138  RNA polymerase-associated protein RTF1 homolog
-GDITHMVSLPEELNRVRLSRHKLERWCHMPFFAKTVTGCFVRIGIGNHNSKPVYRVAEITGVVETAKVYQLGGTRTNKGLQLRHGNDQRVFRLEFVSNQEFTESEFMKWKEAMFSAGMQLPTLDEINKKELSIKEALN
->4v3p_LX mol:protein length:122  60S ribosomal protein L23a
-RKSKKIRTSVTFHRPKTLKKARDPKYPRVSAPGRNKLDQYQILKYPLTTESAMKKIEDNNTLVFIVDLKADKKKIKAAVKKMYDIQAKKVNTLIRPDGKKKAYVKLTPDYDALDVANKIGII
->6vwr_A mol:protein length:346  Clavaminate synthase 3
-MGSSHHHHHHSSGLVPRGSHMMMTVVDCSEYSADLLALASRLPRIPRQDLYGFLDAAHEAAGDLPEGLGTALDRFNADGSHDGYLMLRGLPVEDDDDLPATPTSTPAPVDRPLQNMEAMLAVIGRRLGLHTGYRELRSGTVYHDVYPSPGAHHLSSETSETLLEFHTEMAYHVLQPNYVMLACSRADHERKAATLVGSIRKALPLIPEEVRARLFDRPMPCCVDVAFRGGVENPGAIANVKPLYGDPRDPFLGYDRELLAPREPDDVEAVAVLSKALDEVSEAVRLTPGDLLVVDNFRTTHARTPFSPRWDGKDRWLHRVYIRTDRNDQLSGGERAGDVVDFSPRR
->6hsv_A mol:protein length:124  Toxin B subunit
-TPQNITDLCAEYHNTQIYTLNDKIFSYTESLAGKREMAIITFKNGAIFQVEVPGSQHIDSQKKAIERMKDTLRIAYLTEAKVEKLCVWNNKTPHAIAAISMANGVSALEKEVSALKEKVSALEF
->4u1v_DW mol:protein length:76  50S ribosomal protein L27
-TRNGRDSEAKRLGVKRFGGESVLAGSIIVRQRGTKFHAGANVGCGRDHTLFAKADGKVKFEVKGPKNRKFISIEAE
->5s53_D mol:protein length:445  Tubulin beta-2B chain
-MREIVHIQAGQCGNQIGAKFWEVISDEHGIDPTGSYHGDSDLQLERINVYYNEATGNKYVPRAILVDLEPGTMDSVRSGPFGQIFRPDNFVFGQSGAGNNWAKGHYTEGAELVDSVLDVVRKESESCDCLQGFQLTHSLGGGTGSGMGTLLISKIREEYPDRIMNTFSVMPSPKVSDTVVEPYNATLSVHQLVENTDETYCIDNEALYDICFRTLKLTTPTYGDLNHLVSATMSGVTTCLRFPGQLNADLRKLAVNMVPFPRLHFFMPGFAPLTSRGSQQYRALTVPELTQQMFDSKNMMAACDPRHGRYLTVAAIFRGRMSMKEVDEQMLNVQNKNSSYFVEWIPNNVKTAVCDIPPRGLKMSATFIGNSTAIQELFKRISEQFTAMFRRKAFLHWYTGEGMDEMEFTEAESNMNDLVSEYQQYQDATADEQGEFEEEEGEDEA
->3tbt_I mol:protein length:9  GLYCOPROTEIN G1
-KAPSNFATM
->6yfg_LM mol:protein length:130  coat protein
-SKPIAIFKLRELSSDSTLFTLPGHSVTLPNTLGIVSHLPTPRKGNPGTVKTMRNLRKTILLGAGTASERAVPIVIKTETSFPVGTTEEDRAEVLKQMASFLIEEVKNNQELAYSGYVQDKYFIEDLVITE
->2b9v_H mol:protein length:652  alpha-amino acid ester hydrolase
-APAADAAQAHDPLSVQTGSDIPASVHMPTDQQRDYIKREVMVPMRDGVKLYTVIVIPKNARNAPILLTRTPYNAKGRANRVPNALTMREVLPQGDDVFVEGGYIRVFQDIRGKYGSQGDYVMTRPPHGPLNPTKTDETTDAWDTVDWLVHNVPESNGRVGMTGSSYEGFTVVMALLDPHPALKVAAPESPMVDGWMGDDWFHYGAFRQGAFDYFVSQMTARGGGNDIPRRDADDYTNFLKAGSAGSFATQAGLDQYPFWQRMHAHPAYDAFWQGQALDKILAQRKPTVPMLWEQGLWDQEDMWGAIHAWQALKDADVKAPNTLVMGPWRHSGVNYNGSTLGPLEFEGDTAHQYRRDVFRPFFDEYLKPGSASVHLPDAIIYNTGDQKWDYYRSWPSVCESNCTGGLTPLYLADGHGLSFTHPAADGADSYVSDPAHPVPFISRPFAFAQSSRWKPWLVQDQREAESRPDVVTYETEVLDEPVRVSGVPVADLFAATSGTDSDWVVKLIDVQPAMTPDDPKMGGYELPVSMDIFRGRYRKDFAKPEALQPDATLHYHFTLPAVNHVFAKGHRIMVQIQSSWFPLYDRNPQKFVPNIFDAKPADYTVATQSIHHGGKEATSILLPVVKQKLGPEQKLISEEDLNSAVDHHHHHH
->7z1z_G mol:protein length:281  Pol polyprotein
-WIENIPLAEEEHNKWHQDAVSLHLEFGIPRTAAEDIVQQCDVCQENKMPSTLRGSNKRGIDHWQVDYTHYEDKIILVWVETNSGLIYAERVKGETGQEFRVQTMKWYAMFAPKSLQSDNGPAFVAESTQLLMKYLGIEHTTGIPWNPQSQALVERTHQTLKNTLEKLIPMFNAFESALAGTLITLNIKRKGGLGTSPMDIFIFNKEQQRIQQQSKSKQEKIRFCYYRTRKRGHPGEWQGPTQVLWGGDGAIVVKDRGTDRYLVIANKDVKFIPPPKEIQKE
->5lj5_O mol:protein length:590  Pre-mRNA-splicing factor CEF1
-MPPVPIYVKGGVWTNVEDQILKAAVQKYGTHQWSKVASLLQKKTARQSELRWNEYLNPKLNFTEFSKEEDAQLLDLARELPNQWRTIADMMARPAQVCVERYNRLLESEDSGGAALSTGVTDLKAGDINPNAETQMARPDNGDLEDEEKEMLAEARARLLNTQGKKATRKIRERMLEESKRIAELQKRRELKQAGINVAIKKPKKKYGTDIDYNEDIVYEQAPMPGIYDTSTEDRQIKKKFEQFERKVNRKGLDGNKDKPSKKNKDKKRKHDENEHVEKAALGESTTLTDEYKKPKLILSAPGTKQGKVTYKKKLESKRQKLIEAQATGTVLTPKELLPHDSGQEDNERSNIKSGKQLKSRIRKFLVQMFASLPSPKNDFEIVLSEDEKEEDAEIAEYEKEFENERAMNEEDNFIEPPSQNDAPRVSLVAVPLAYSTLPIPEFKNNPQSAIDNKYNLLVANAINKEPHMVPEDTVDFLKEVESRMQHITQGRTSMKIQFKTAMPPTEVLLESIQSKVESIEQLQRKLQHVQPLEQQNNEMCSTLCHHSLPALIEGQRKYYADYYAYRQEIRSLEGRRKRLQAMLNSSSSI
->6j8m_D mol:protein length:147  Cytochrome c oxidase subunit 4 isoform 1
-AHGSVVKSEDYALPSYVDRRDYPLPDVAHVKNLSASQKALKEKEKASWSSLSIDEKVELYRLKFKESFAEMNRSTNEWKTVVGAAMFFIGFTALLLIWEKHYVYGPIPHTFEEEWVAKQTKRMLDMKVAPIQGFSAKWDYDKNEWKK
->6vw1_F mol:protein length:217  SARS-CoV-2 chimeric RBD
-RVVPSGDVVRFPNITNLCPFGEVFNATKFPSVYAWERKKISNCVADYSVLYNSTFFSTFKCYGVSATKLNDLCFSNVYADSFVVKGDDVRQIAPGQTGVIADYNYKLPDDFMGCVLAWNTRNIDATSTGNYNYKYRLFRKSNLKPFERDISTEIYQAGSTPCNGVEGFNCYFPLQSYGFQPTNGVGYQPYRVVVLSFELLNAPATVCGPKLSTDLIK
->3n99_b mol:protein length:290  uncharacterized protein TM1086
-HHHHHHGHMRTNKDRLVRISVVGEIAPAKMRSPYSVTTEGTVRVIPVLGGITYNVKVGDSAYGWAGDHVEPGVSVMARRKEEEIPLMTLSCIGNEVIVMSGDAKGSRGFVTGKHGGVNHVLVHFEEEVLGKLMVGDKILIKAWGQGLKLLDHPDVKVMNIDPDLFEKLGIQEKNGKIHVPVVAKIPAHMMGSGIGASSSASTDYDIMASNPEDLGVADLKLGDIVAIQDHDNSYGVGKYRKGAVSIGVVVHSACVSAGHGPGVVVIMTGDESKILPEEVERANISDYLVR
->2j1k_M mol:protein length:197  FIBER PROTEIN
-MRGSHHHHHHGSPPAAPITLWTGPGPSINGFINDTPVIRCFICLTRDSNLVTVNASFVGEGGYRIVSPTQSQFSLIMEFDQFGQLMSTGNINSTTTWGEKPWGNNTVQPRPSHTWKLCMPNREVYSTPAATISRCGLDSIAVDGAPSRSIDCMLIINKPKGVATYTLTFRFLNFNRLSGGTLFKTDVLTFTYVGENQ
->5dc3_D1 mol:protein length:87  40S ribosomal protein S21-A
-MENDKGQLVELYVPRKCSATNRIIKADDHASVQINVAKVDEEGRAIPGEYVTYALSGYVRSRGESDDSLNRLAQNDGLLKNVWSYSR
->1nun_A mol:protein length:145  Fibroblast growth factor-10
-GRHVRSYNHLQGDVRWRKLFSFTKYFLKIEKNGKVSGTKKENCPYSILEITSVEIGVVAVKAINSNYYLAMNKKGKLYGSKEFNNDCKLKERIEENGYNTYASFNWQHNGRQMYVALNGKGAPRRGQKTRRKNTSAHFLPMVVHS
->2w58_A mol:protein length:202  PRIMOSOME COMPONENT (HELICASE LOADER)
-DERKRQESLIQSMFMPREILRASLSDVDLNDDGRIKAIRFAERFVAEYEPGKKMKGLYLHGSFGVGKTYLLAAIANELAKRNVSSLIVYVPELFRELKHSLQDQTMNEKLDYIKKVPVLMLDDLGAEAMSSWVRDDVFGPILQYRMFENLPTFFTSNFDMQQLAHHLTYSQRGEEEKVKAARIMERIRYLAYPIEITGPNRR
->4bp7_CY mol:protein length:129  COAT PROTEIN
-ASNFTQFVLVDNGGTGDVTVAPSNFANGVAEWISSNSRSQAYKVTCSVRQSSAQNRKYTIKVEVPKVATQTVGGVELPVAAWRSYLNMELTIPIFATNSDCELIVKAMQGLLKDGNPIPSAIAANSGIY
->6kbp_A mol:protein length:338  D-amino-acid oxidase
-MRVVVIGAGVIGLSTALCIHERYHSVLQPLDIKVYADRFTPLTTTDVAAGLWQPYLSDPNNPQEADWSQQTFDYLLSHVHSPNAENLGLFLISGYNLFHEAIPDPSWKDTVLGFRKLTPRELDMFPDYGYGWFHTSLILEGKNYLQWLTERLTERGVKFFQRKVESFEEVAREGADVIVNCTGVWAGALQRDPLLQPGRGQIMKVDAPWMKHFILTHDLERGIYNSPYIIPGTQTVTLGGIFQLGNWSELNNIQDHNTIWEGCCRLEPTLKNARIIGERTGFRPVRPQIRLEREQLRTGPSNTEVIHNYGHGGYGLTIHWGCALEAAKLFGRILEEKK
->6yfg_HY mol:protein length:130  coat protein
-SKPIAIFKLRELSSDSTLFTLPGHSVTLPNTLGIVSHLPTPRKGNPGTVKTMRNLRKTILLGAGTASERAVPIVIKTETSFPVGTTEEDRAEVLKQMASFLIEEVKNNQELAYSGYVQDKYFIEDLVITE
->2wqj_K mol:protein length:35  TUMOR PROTEIN P73
-GSDEDTYYLQVRGRENFEILMKLKESLELMELVPQ
->3lyc_F mol:protein length:241  Putative pectinase
-GGDGNITTENIPVSEYDCLELEGGGMVVNYTQSDAPEGLEIKTDRNIFEKYEFNVENHKLKIRPKKEFRKHTNFRPTEFMVTANSRNLKKLAAAGSTHVNINSPLQAEEFEAGLAGSGIIQFHDTASFTNLKIEIAGSGDFVGHKVYCEELNGDMAGSNTIVLGGTVGIAEFSIAGSGTVRAFDCTMDELECKIAGSGDIEAFVVNKIKAEIAGSGSVKYKGDPQDIQKKVMGSGKIEKVE
->6oj2_QQ mol:protein length:105  30S ribosomal protein S17
-MPKKVLTGVVVSDKMQKTVTVLVERQFPHPLYGKVIKRSKKYLAHDPEEKYKLGDVVEIIESRPISKRKRFRVLRLVESGRMDLVEKYLIRRQNYESLSKRGGKA
->3sln_J mol:protein length:311  Capsid
-ESRTKPFTVPILTVEEMTNSRFPIPLEKLFTGPSSAFVVQPQNGRCTTDGALLGTTQLSPVDICTFRGDVTHIAGTQNYTMNLASQNWNNYDPTEEIPAPLGTPDFVGKIQGVLTQTTRRDGSTRGHKATVSTGSVHFTPKLGSVQFSTDTSNDFETGQNTRFTPVGVVQDGSTTHQNEPQQWVLPDYSGRDSHNVHLAPAVAPTFPGEQLLFFRSTMPGCSGYPNMNLDCLLPQEWVQHFYQESAPAQSDVALLRFVNPDTGRVLFECKLHKSGYVTVAHTGQHDLVIPPNGYFRFDSWVNQFYTLAPMG
->6yfh_AK mol:protein length:156  coat protein
-PAMTNIVLRDDQTSVATKTLIPIVSDGNMSVWRENAANVPIDGQIKLTGQWERMKDGTYRLNAKLEVPVMETAGAGGAYVAPPKVAYKVTASLTLYAPSRSTIADRANAMKMLSAVLCGADATAGTTLSPQSVTGDAWKNSALPFVFGFINQAFPT
->4qe8_D mol:protein length:13  Nuclear receptor coactivator 2
-KENALLRYLLDKD
->5gaq_I mol:protein length:310  Lysenin
-MSAKAAEGYEQIEVDVVAVWKEGYVYENRGSTSVDQKITITKGMKNVNSETRTVTATHSIGSTISTGDAFEIGSVEVSYSHSHEESQVSMTETEVYESKVIEHTITIPPTSKFTRWQLNADVGGADIEYMYLIDEVTPIGGTQSIPQVITSRAKIIVGRQIILGKTEIRIKHAERKEYMTVVSRKSWPAATLGHSKLFKFVLYEDWGGFRIKTLNTMYSGYEYAYSSDQGGIYFDQGTDNPKQRWAINKSLPLRHGDVVTFMNKYFTRSGLCYDDGPATNVYCLDKREDKWILEVVGLVPRGSGHHHHHH
->4c5q_B mol:protein length:79  PHOSPHOPROTEIN
-MGDHYDDELFSDVQDIKTALAKIHEDNQKIISKLESLLLLKGEVESIKKQINRQNISISTLEGHLSSIMIAIPHHHHHH
->6f2n_A mol:protein length:227  Metallo-beta-lactamase type 2
-SQKVEKTVIKNETGTISISQLNKNVWVHTELGSFNGEAVPSNGLVLNTSKGLVLVDSSWDDKLTKELIEMVEKKFQKRVTDVIITHAHADRIGGIKTLKERGIKAHSTALTAELAKKNGYEEPLGDLQTVTNLKFGNMKVETFYPGKGHTEDNIVVWLPQYNILVGGCLVKSTSAKDLGNVADAYVNEWSTSIENVLKRYRNINAVVPGHGEVGDKGLLLHTLDLLK
->5ef0_F mol:protein length:74  Transcription attenuation protein MtrB
-MYTNSDFVVIKALEDGVNVIGLTRGADTRFHHSEKLDKGEVLIAQFTEHTSAIKVRGKAYIQTRHGVIESEGKK
->3tsz_A mol:protein length:391  Tight junction protein ZO-1
-GSHMILRPSMKLVKFRKGDSVGLRLAGGNDVGIFVAGVLEDSPAAKEGLEEGDQILRVNNVDFTNIIREEAVLFLLDLPKGEEVTILAQKKKDVYRRIVESDVGDSFYIRTHFEYEKESPYGLSFNKGEVFRVVDTLYNGKLGSWLAIRIGKNHKEVERGIIPNKNRAEQLASVQYTLPKTAGGDRADFWRFRGLRSSKRNLRKSREDLSAQPVQTKFPAYERVVLREAGFLRPVTIFGPIADVAREKLAREEPDIYQIAKSEPRDAGTDQRSSGIIRLHTIKQIIDQDKHALLDVTPNAVDRLNYAQWYPIVVFLNPDSKQGVKTMRMRLCPESRKSARKLYERSHKLRKNNHHLFTTTINLNSMNDGWYGALKEAIQQQQNQLVWVSEG
->3jaj_d mol:protein length:107  Ribosomal protein eL31
-NEVVTREYTINIHKRIHGVGFKKRAPRALKEIRKFAMKEMGTPDVRIDTRLNKAVWAKGIRNVPYRIRVRLSRKRNEDEDSPNKLYTLVTYVPVTTFKNLQTVNVDE
->5a1v_E mol:protein length:874  COATOMER SUBUNIT GAMMA-1
-MLKKFDKKDEESGGGSNPLQHLEKSAVLQEARVFNETPINPRKCAHILTKILYLINQGEHLGTTEATEAFFAMTKLFQSNDPTLRRMCYLTIKEMSCIAEDVIIVTSSLTKDMTGKEDNYRGPAVRALCQITDSTMLQAVERYMKQAIVDKVPSVSSSALVSSLHLLKCSFDVVKRWVNEAQEAASSDNIMVQYHALGLLYHVRKNDRLAVSKMISKFTRHGLKSPFAYCMMIRVASKQLEEEDGSRDSPLFDFIESCLRNKHEMVVYEAASAIVNLPGCSAKELAPAVSVLQLFCSSPKAALRYAAVRTLNKVAMKHPSAVTACNLDLENLVTDSNRSIATLAITTLLKTGSESSIDRLMKQISSFMSEISDEFKVVVVQAISALCQKYPRKHAVLMNFLFTMLREEGGFEYKRAIVDCIISIIEENSESKETGLSHLCEFIEDCEFTVLATRILHLLGQEGPKTNNPSKYIRFIYNRVVLEHEEVRAGAVSALAKFGAQNEEMLPSILVLLKRCVMDDDNEVRDRATFYLNVLEQKQKALNAGYILNGLTVSIPGLEKALQQYTLEPSEKPFDLKSVPLATTPMAEQRPESTATAAVKQPEKVAATRQEIFQEQLAAVPEFQGLGPLFKSSPEPVALTESETEYVIRCTKHTFSDHLVFQFDCTNTLNDQTLENVTVQMEPTEAYEVLSYVPARSLPYNQPGTCYTLVALPTEDPTAVACTFSCVMKFTVKDCDPNTGEIDEEGYEDEYVLEDLEVTVADHIQKVMKVNFEAAWDEVGDEFEKEETFTLSTIKTLEEAVGNIVKFLGMHPCERSDKVPENKNTHTLLLAGVFRGGHDILVRSRLLLLDTVTMQVTARSSEELPVDIILASVG
->1b12_C mol:protein length:248  SIGNAL PEPTIDASE I
-VRSFIYEPFQIPSGSMMPTLLIGDFILVEKFAYGIKDPIYQKTLIETGHPKRGDIVVFKYPEDPKLDYIKRAVGLPGDKVTYDPVSKELTIQPGCSSGQACENALPVTYSNVEPSDFVQTFSRRNGGEATSGFFEVPKNETKENGIRLSERKETLGDVTHRILTVPIAQDQVGMYYQQPGQQLATWIVPPGQYFMMGDNRDNSADSRYWGFVPEANLVGRATAIWMSFDKQEGEWPTGLRLSRIGGIH
->1ev4_D mol:protein length:221  GLUTATHIONE S-TRANSFERASE A1-1
-SGKPVLHYFNARGRMECIRFLLAAAGVEFDEKFIQSPEDLEKLKKDGNLMFDQVPMVEIDGMKLAQTRAILNYIATKYDLYGKDMKERALIDMYSEGILDLTEMIMQLVICPPDQKEAKTALAKDRTKNRYLPAFEKVLKSHGQDYLVGNKLTRVDIHLLELLLYVEEFDASLLTSFPLLKAFKSRISSLPNVKKFLQPGSQRKLPMDAKQIEEARKIYKF
->7eyd_V4 mol:protein length:173  C-phycocyanin beta subunit
-MTLDVFTKVVSQADSRGEFLSNEQLDALANVVKEGNKRLDVVNRITSNASAIVTNAARALFEEQPQLIAPGGNAYTNRRMAACLRDMEIILRYVTYAILAGDASVLDDRCLNGLRETYQALGTPGSSVAVGVQKMKDAAVGIANDPNGITKGDCSQLISEVASYFDRAAAAVG
->2cvk_A mol:protein length:110  Thioredoxin
-MAKPIEVTDQNFDETLGQHPLVLVDFWAEWCAPCRMIAPILEEIAKEYEGKLLVAKLDVDENPKTAMRYRVMSIPTVILFKDGQPVEVLVGAQPKRNYQAKIEKHLPATA
->4ctf_D3 mol:protein length:226  P1
-APIRVVSVPESDSFMSSVPDNSTPLYPKVVVPPRQVPGRFTNFIDVAKQTYSFCSISGKPYFEVTNTSGDEPLFQMDVSLSAAELHGTYVASLSSFFAQYRGSLNFNFIFTGAAATKAKFLVAFVPPHSAAPKTRDEAMACIHAVWDVGLNSAFSFNVPYSSPADFMAVYSAEATVVNVSGWLQVYALTALTSTDIAVNSKGRVLVAVSAGPDFSLRHPVDLPDKQ
->6vgn_G mol:protein length:200  ATP-dependent Clp protease proteolytic subunit
-ILPSFIEHSSFGVKESNPYNKLFEERIIFLGVQVDDASANDIMAQLLVLESLDPDRDITMYINSPGGGFTSLMAIYDTMQYVRADIQTVCLGQAASAAAVLLAAGTPGKRMALPNARVLIHQPSLSGVIQGQFSDLEIQAAEIERMRTLMETTLARHTGKDAGVIRKDTDRDKILTAEEAKDYGIIDTVLEYRKLSAQTA
->6ase_A mol:protein length:170  GTPase KRas
-GMTEYKLVVVGAGGVGKSALTIQLIQNHFVDEYDPTIEDSYRKQVVIDGETCLLDILDTGGQEEYSAMRDQYMRTGEGFLCVFAINNTKSFEDIHHYREQIKRVKDSEDVPMVLVGNKCDLPSRTVDTKQAQDLARSYGIPFIETSAKTRQGVDDAFYTLVREIRKHKEK
->1nno_B mol:protein length:543  NITRITE REDUCTASE
-KDDMKAAEQYQGAASAVDPAHVVRTNGAPDMSESEFNEAKQIYFQRCAGCHGVLRKGATGKPLTPDITQQRGQQYLEALITYGTPLGMPNWGSSGELSKEQITLMAKYIQHTPPQPPEWGMPEMRESWKVLVKPEDRPKKQLNDLDLPNLFSVTLRDAGQIALVDGDSKKIVKVIDTGYAVHISRMSASGRYLLVIGRDARIDMIDLWAKEPTKVAEIKIGIEARSVESSKFKGYEDRYTIAGAYWPPQFAIMDGETLEPKQIVSTRGMTVDTQTYHPEPRVAAIIASHEHPEFIVNVKETGKVLLVNYKDIDNLTVTSIGAAPFLHDGGWDSSHRYFMTAANNSNKVAVIDSKDRRLSALVDVGKTPHPGRGANFVHPKYGPVWSTSHLGDGSISLIGTDPKNHPQYAWKKVAELQGQGGGSLFIKTHPKSSHLYVDTTFNPDARISQSVAVFDLKNLDAKYQVLPIAEWADLGEGAKRVVQPEYNKRGDEVWFSVWNGKNDSSALVVVDDKTLKLKAVVKDPRLITPTGKFNVYNTQHDVY
->6u3m_C mol:protein length:191  HLA class II histocompatibility antigen, DQ alpha 1 chain
-EDIVADHVASYGVNLYQSYGPSGQYTHEFDGDEQFYVDLGRKETVWSLPVLRQFRFDPQFALTNIAVLKHNLNSLIKRSNSTAATNEVPEVTVFSKSPVTLGQPNILICLVDNIFPPVVNITWLSNGHSVTEGVSETSFLSKSDHSFFKISYLTLLPSAEESYDCKVEHWGLDKPLLKHWEPETSGDDDDK
->6wdh_z mol:protein length:58  50S ribosomal protein L30
-AKTIKITQTRSAIGRLPKHKATLLGLGLRRIGHTVEREDTPAIRGMINAVSFMVKVEE
->4nrl_D mol:protein length:182  Hemagglutinin HA2 chain
-GFFGAIAGFLEGGWEGMIAGWHGYTSHGAHGVAVAADLKSTQEAINKITKNLNSLSELEVKNLQRLSGAMNELHDEILELDEKVDDLRADTISSQIELAVLLSNEGIINSEDEHLLALERKLKKMLGPSAVEIGNGCFETKHKCNQTCLDRIAAGTFNAGDFSLPTFDSLNITAASGALVPR
->43ca_H mol:protein length:117  PROTEIN (IMMUNOGLOBULIN (HEAVY CHAIN))
-QVQLVESGPGLVAPSQSLSITCTVSGISLSRYNVHWVRQSPGKGLEWLGMIWGGGSIEYNPALKSRLSISKDNSKSQIFLKMNSLQTDDSAMYYCVSYGYGGDRFSYWGQGTLVTVS
->5us9_c mol:protein length:541  Capsid protein VP2
-MSENEIQDQQPSDSMDGQRGGGGGATGSVGGGKGSGVGISTGGWVGGSYFTDSYVITKNTRQFLVKIQNNHQYKTELISPSTSQGKSQRCVSTPWSYFNFNQYSSHFSPQDWQRLTNEYKRFRPKGMHVKIYNLQIKQILSNGADTTYNNDLTAGVHIFCDGEHAYPNATHPWDEDVMPELPYQTWYLFQYGYIPVIHELAEMEDSNAVEKAICLQIPFFMLENSDHEVLRTGESTEFTFNFDCEWINNERAYIPPGLMFNPLVPTRRAQYIRRNNNPQTAESTSRIAPYAKPTSWMTGPGLLSAQRVGPATSDTGAWMVAVKPENASIDTGMSGIGSGFDPPQGSLAPTNLEYKIQWYQTPQGTNNNGNIISNQPLSMLRDQALFRGNQTTYNLCSDVWMFPNQIWDRYPITRENPIWCKKPRSDKHTTIDPFDGSLAMDHPPGTIFIKMAKIPVPSNNNADSYLNIYCTGQVSCEIVWEVERYATKNWRPERRHTTFGLGIGGADNLNPTYHVDKNGTYIQPTTWDMCFPVKTNINKVL
->8dja_G mol:protein length:123  Major prion protein
-GSKKRPKPGGWNTGGSRYPGQGSPGGNRYPPQGGTWGQPHGGGWGQPHGGSWGQPHGGSWGQPHGGGWGQGGGTHNQWNKPSKPKTNLKHVAGAAAAGAVVGGLGGYMLGSAMSRPMIHFGND
->4z96_A mol:protein length:530  Ubiquitin carboxyl-terminal hydrolase 7
-SGPLGSEAHLYMQVQIVAEDQFCGHQGNDMYDEEKVKYTVFKVLKNSSLAEFVQSLSQTMGFPQDQIRLWPMQARSNGTKRPAMLDNEADGNKTMIELSDNENPWTIFLETVDPELAASGATLPKFDKDHDVMLFLKMYDPKTRSLNYCGHIYTPISCKIRDLLPVMCDRAGFIQDTSLILYEEVKPNLTERIQDYDVSLDKALDELMDGDIIVFQKDDPENDNSELPTAKEYFRDLYHRVDVIFCDKTIPNDPGFVVTLSNRMNYFQVAKTVAQRLNTDPMLLQFFKSQGYRDGPGNPLRHNYEGTLRDLLQFFKPRQPKKLYYQQLKMKITDFENRRSFKCIWLNSQFREEEITLYPDKHGCVRDLLEECKKAVELGEKASGKLRLLEIVSYKIIGVHQEDELLECLSPATSRTFRIEEIPLDQVDIDKENEMLVTVAHFHKEVFGTFGIPFLLRIHQGEHFREVMKRIQSLLDIQEKEFEKFKFAIVMMGRHQYINEDEYEVNLKDFEPQPGNMSHPRPWLGLDHFN
->3d2c_A mol:protein length:181  Lipase
-AEHNPVVMVHGIGGSSSNFEGIKSYLVSQGWSRDKLYAVDFWDKTGTNYNNGPVLSRFVQKVLDETGAKKVDIVAHSMGGANTLYYIKYLDGGNKVANVVTLGGANRLTTDKAPPGTDPNQKILYTSIYSSDDMIVMNYLSRLDGARNVQIHGVGHMGLLYSSQVYSLIKEGLNGGGQNTN
->6yxl_HHH mol:protein length:221  ACPA F3 Fab fragment - heavy chain
-QVQLVQSGAEVKKPGASVRVSCKASGFVTDYFIQWVRQAPGQGPEWMAWINPHNGETDYAPKLQDRVTVTCDTSTNTAFMELSRLTSDDTALYYCGRSGRTDARRAPVSYWGQGALVTVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKRVEP
->2jdt_I mol:protein length:20  CAMP-DEPENDENT PROTEIN KINASE INHIBITOR ALPHA
-TTYADFIASGRTGRRNAIHD
->4qua_D mol:protein length:6  ACE-ASP-GLU-VAL-ASP-CHLOROMETHYLKETONE INHIBITOR
-XDEVDX
->3daq_C mol:protein length:292  Dihydrodipicolinate synthase
-THLFEGVGVALTTPFTNNKVNLEALKAHVNFLLENNAQAIIVNGTTAESPTLTTDEKELILKTVIDLVDKRVPVIAGTGTNDTEKSIQASIQAKALGADAIMLITPYYNKTNQRGLVKHFEAIADAVKLPVVLYNVPSRTNMTIEPETVEILSQHPYIVALKDATNDFEYLEEVKKRIDTNSFALYSGNDDNVVEYYQRGGQGVISVIANVIPKEFQALYDAQQSGLDIQDQFKPIGTLLSALSVDINPIPIKALTSYLGFGNYELRLPLVSLEDTDTKVLREAYDTFKAGE
->2ddw_B mol:protein length:283  Pyridoxine kinase
-MSSLLLFNDKSRALQADIVAVQSQVVYGSVGNSIAVPAIKQNGLNVFAVPTVLLSNTPHYDTFYGGAIPDEWFSGYLRALQERDALRQLRAVTTGYMGTASQIKILAEWLTALRKDHPDLLIMVDPVIGDIDSGIYVKPDLPEAYRQYLLPLAQGITPNIFELEILTGKNCRDLDSAIAAAKSLLSDTLKWVVVTSASGNEENQEMQVVVVTADSVNVISHSRVKTDLKGTGDLFCAQLISGLLKGKALTDAVHRAGLRVLEVMRYTQQHESDELILPPLAEA
->6xt5_A mol:protein length:451  Legumain
-RGSHHHHHHGSEVGTRWAVLVAGSNGYGNYRHQADVCHAYQLLIKGGVKEENIVVFMYDDIAYNAMNPRPGVIINHPQGPDVYAGVPKDYTGEDVTPENLYAVILGDKSKVKGGSGKVINSNPEDRIFIFYSNHGGPGVLGMPNAPFVYAMDFIDVLKKKHASGGYKEMVIYIEACESGSIFEGIMPKDLNIYVTTASNAQENSFGTYCPGMNPPPPEEYVTCLGDLYSVSWMEDSETHNLKRETVQQQYQSVRKRTSNSNSYRFGSHVMQYGDTNITAEKLYLYHGFDPATVNFPPHNGNLEAKMEVVNQRDAELLFMWQMYQRSNHQPEKKTHILEQITETVKHRNHLDGSVELIGVLLYGPGKSSSVLHSVRAPGLPLVDDWTCLKSMVRVFETHCGSLTQYGMKHMRAFGNVCNSGVSKASMEEACKAACGGYDAGLLYPSNTGYSA
->6l3t_E mol:protein length:279  Gap junction gamma-3 protein
-MCGRFLRRLLAEESRRSTPVGRLLLPVLLGFRLVLLAASGPGVYGDEQSEFVCHTQQPGCKAACFDAFHPLSPLRFWVFQVILVAVPSALYMGFTLYHVIWHWELSGKGKEEETLIQGREGNTDVPGAGSLRLLWAYVAQLGARLVLEGAALGLQYHLYGFQMPSSFACRREPCLGSITCNLSRPSEKTIFLKTMFGVSGFCLLFTFLELVLLGLGRWWRTWKHKSSSSKYFLTSESTRRHKKATDSLPVVETKEQFQEAVPGRSLAQEKQRPVGPRDA
->3uk4_B mol:protein length:6  C-terminal peptide from Lactotransferrin
-LEACAF
->1ztg_A mol:protein length:74  POLY(RC)-BINDING PROTEIN 1
-GILTIRLLMHGKEVGSIIGKKGESVKRIREESGARINISEGNCPERIITLTGPTNAIFKAFAMIIDKLEEDINS
->1usv_H mol:protein length:170  AHA1
-MRGSHHHHHHGMASMVVNNPNNWHWVDKNCIGWAKEYFKQKLVGVEAGSVKDKKYAKIKSVSSIEGDCEVNQRKGKVISLFDLKITVLIEGHVDSKDGSALPFEGSINVPEVAFDSEASSYQFDISIFKETSELSEAKPLIRSELLPKLRQIFQQFGKDLLATHGNDIQV
->5mfc_B mol:protein length:257  (KR)4-Green fluorescent protein,Green fluorescent protein
-GPGSGSPKRKRKRKREGKLMSKGEELFTGVVPILVELDGDVNGHKFSVRGEGEGDATNGKLTLKFICTTGKLPVPWPTLVTTLTYGVQCFSRYPDHMKRHDFFKSAMPEGYVQERTISFKDDGTYKTRAEVKFEGDTLVNRIELKGIDFKEDGNILGHKLEYNFNSHNVYITADKQKNGIKANFKIRHNVEDGSVQLADHYQQNTPIGDGPVLLPDNHYLSTQSVLSKDPNEKRDHMVLLEFVTAAGITHGMDELYK
->4v7s_CF mol:protein length:100  30S ribosomal protein S6
-MRHYEIVFMVHPDQSEQVPGMIERYTAAITGAEGKIHRLEDWGRRQLAYPINKLHKAHYVLMNVEAPQEVIDELETTFRFNDAVIRSMVMRTKHAVTEAS
->6zvt_ZA mol:protein length:258  Vipp1
-MGLFDRIKRVVSSNLNDLVNKAEDPEKMLEQAILEMQEDLVQLRQGVAQAIAAQKRSEKQYNDAQNEINKWQRNAQLALQKGDENLARQALERKKTYTDTSAALKASLDTQSTQVETLKRNLIQLESKISEAKTKKEMLKARITTAKAQEQLQGMVRGMNTSSAMSAFERMEEKVLMQESRAQALGELAGADLETQFAQLEGGSDVDDELAALKAQMLPPATPVTQAQLPPQQETTPAKSNEVVDAELDSLRKQLDQL
->6pg2_A mol:protein length:189  Thiol:disulfide interchange protein DsbA
-AQYEDGKQYTTLEKPVAGAPQVLEFFSFFCPHCYQFEEVLHISDNVKKKLPEGVKMTKYHVNFMGGDLGKDLTQAWAVAMALGVEDKVTVPLFEGVQKTQTIRSASDIRDVFINAGIKGEEYDAAWNSFVVKSLVAQQEKAAADVQLRGVPAMFVNGKYQLNPQGMDTSNMDVFVQQYADTVKYLSEKK
->6pm2_B mol:protein length:458  Glycine receptor subunit alphaZ1
-MFALGIYLWETIVFFSLAASQQAAARKAASPMPPSEFLDKLMGKVSGYDARIRPNFKGPPVNVTCNIFINSFGSIAETTMDYRVNIFLRQQWNDPRLAYSEYPDDSLDLDPSMLDSIWKPDLFFANEKGANFHEVTTDNKLLRISKNGNVLYSIRITLVLACPMDLKNFPMDVQTCIMQLESFGYTMNDLIFEWDEKGAVQVADGLTLPQFILKEEKDLRYCTKHYNTGKFTCIEARFHLERQMGYYLIQMYIPSLLIVILSWVSFWINMDAAPARVGLGITTVLTMTTQSSGSRASLPKVSYVKAIDIWMAVCLLFVFSALLEYAAVNFIARQHKELLRFQRRRRHLKEDEAGDGRFSFAAYGMGPACLQAKDGMAIKGNNNNAPTSTNPPEKTVEEMRKLFISRAKRIDTVSRVAFPLVFLIFNIFYWITYKIIRSEDIHKQLVPRGSHHHHHHHH
->5nc7_J mol:protein length:12  ActA-derived 10-mer Ac-FPPPPTEDEL-NH2 with acetylated (Ac) and amidated (NH2) termini. Phe is substitued by Trp to increase affinity for crystallization
-XWPPPPTEDELX
->7cwl_B mol:protein length:1273  Spike glycoprotein
-MFVFLVLLPLVSSQCVNLTTRTQLPPAYTNSFTRGVYYPDKVFRSSVLHSTQDLFLPFFSNVTWFHAIHVSGTNGTKRFDNPVLPFNDGVYFASTEKSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCEFQFCNDPFLGVYYHKNNKSWMESEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLREFVFKNIDGYFKIYSKHTPINLVRDLPQGFSALEPLVDLPIGINITRFQTLLALHRSYLTPGDSSSGWTAGAAAYYVGYLQPRTFLLKYNENGTITDAVDCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESIVRFPNITNLCPFGEVFNATRFASVYAWNRKRISNCVADYSVLYNSASFSTFKCYGVSPTKLNDLCFTNVYADSFVIRGDEVRQIAPGQTGKIADYNYKLPDDFTGCVIAWNSNNLDSKVGGNYNYLYRLFRKSNLKPFERDISTEIYQAGSTPCNGVEGFNCYFPLQSYGFQPTNGVGYQPYRVVVLSFELLHAPATVCGPKKSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFGRDIADTTDAVRDPQTLEILDITPCSFGGVSVITPGTNTSNQVAVLYQDVNCTEVPVAIHADQLTPTWRVYSTGSNVFQTRAGCLIGAEHVNNSYECDIPIGAGICASYQTQTNSPRRARSVASQSIIAYTMSLGAENSVAYSNNSIAIPTNFTISVTTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLNRALTGIAVEQDKNTQEVFAQVKQIYKTPPIKDFGGFNFSQILPDPSKPSKRSFIEDLLFNKVTLADAGFIKQYGDCLGDIAARDLICAQKFNGLTVLPPLLTDEMIAQYTSALLAGTITSGWTFGAGAALQIPFAMQMAYRFNGIGVTQNVLYENQKLIANQFNSAIGKIQDSLSSTASALGKLQDVVNQNAQALNTLVKQLSSNFGAISSVLNDILSRLDKVEAEVQIDRLITGRLQSLQTYVTQQLIRAAEIRASANLAATKMSECVLGQSKRVDFCGKGYHLMSFPQSAPHGVVFLHVTYVPAQEKNFTTAPAICHDGKAHFPREGVFVSNGTHWFVTQRNFYEPQIITTDNTFVSGNCDVVIGIVNNTVYDPLQPELDSFKEELDKYFKNHTSPDVDLGDISGINASVVNIQKEIDRLNEVAKNLNESLIDLQELGKYEQYIKWPWYIWLGFIAGLIAIVMVTIMLCCMTSCCSCLKGCCSCGSCCKFDEDDSEPVLKGVKLHYT
->7oo2_B mol:protein length:214  anti-MenX Fab light chain
-ETTVTQSPASLSVATGEKVTIRCITSTDIDDDMTWYQQKPGEPPKLLISEATTLRPGVPSRFSASGYGTDFVFTIENTLSEDVADYYCLQSDNMPYTFGGGTKLEIKRADAAPTVSIFPPSSEQLTSGGASVVCFLNNFYPKDINVKWKIDGSERQNGVLNSWTDQDSKDSTYSMSSTLTLTKDEYERHNSYTCEATHKTSTSPIVKSFNRNEC
->1h4l_D mol:protein length:147  CYCLIN-DEPENDENT KINASE 5 ACTIVATOR
-STSELLRCLGEFLCRRCYRLKHLSPTDPVLWLRSVDRSLLLQGWQDQGFITPANVVFLYMLCRDVISSEVGSDHELQAVLLTCLYLSYSYMGNEISYPLKPFLVESCKEAFWDRCLSVINLMSSKMLQINADPHYFTQVFSDLKNES
->3b07_A mol:protein length:309  Gamma-hemolysin component B
-MGHHHHHHAMEGKITPVSVKKVDDKVTLYKTTATADSDKFKISQILTFNFIKDKSYDKDTLVLKATGNINSGFVKPNPNDYDFSKLYWGAKYNVSISSQSNDSVNVVDYAPKNQNEEFQVQNTLGYTFGGDISISNGLSGGLNGNTAFSETINYKQESYRTTLSRNTNYKNVGWGVEAHKIMNNGWGPYGRDSFHPTYGNELFLAGRQSSAYAGQNFIAQHQMPLLSRSNFNPEFLSVLSHRQDGAKKSKITVTYQREMDLYQICWNGFYWAGANYKNFKTRTFKSTYEIDWENHKVKLLDTKETENNK
->6zqn_B mol:protein length:510  ATP synthase subunit alpha, mitochondrial
-EKTGTAEVSSILEERILGADTSVDLEETGRVLSIGDGIARVHGLRNVQAEEMVEFSSGLKGMSLNLEPDNVGVVVFGNDKLIKEGDIVKRTGAIVDVPVGEELLGRVVDALGNAIDGKGPIGSKARRRVGLKAPGIIPRISVREPMQTGIKAVDSLVPIGRGQRELIIGDRQTGKTSIAIDTIINQKRFNDGTDEKKKLYCIYVAIGQKRSTVAQLVKRLTDADAMKYTIVVSATASDAAPLQYLAPYSGCSMGEYFRDNGKHALIIYDDLSKQAVAYRQMSLLLRRPPGREAYPGDVFYLHSRLLERAAKMNDAFGGGSLTALPVIETQAGDVSAYIPTNVISITDGQIFLETELFYKGIRPAINVGLSVSRVGSAAQTRAMKQVAGTMKLELAQYREVAAFAQFGSDLDAATQQLLSRGVRLTELLKQGQYSPMAIEEQVAVIYAGVRGYLDKLEPSKITKFENAFLSHVISQHQALLGKIRTDGKISEESDAKLKEIVTNFLAGFEA
->7oue_C mol:protein length:242  N-glycosylase/DNA lyase
-GSHMIARIIGEIGIEGARFIEENIDEQFKALRYLSKGIDSETFVKLVIANSLVSYQLTGKGEQWWWEFAKYFYGRDVKSIYLAYKEFLPNSRFNRRLIPQKLSRIRRVETFLSTLTEERIEEYYGDMSSLWGSIARALGVDKESKTVVFSVKMFGYAARIVLSTFNPYPMEIPIPEDSRIVKLTKKLTNEKPRKFWMKIARESGVPPLHIDSILWPLLGGASIDSAPPELRDKLAELIKIIR
->6vyy_h mol:protein length:273  50S ribosomal protein L2
-MAVVKCKPTSPGRRHVVKVVNPELHKGKPFAPLLEKNSKSGGRNNNGRITTRHIGGGHKQAYRIVDFKRNKDGIPAVVERLEYDPNRSANIALVLYKDGERRYILAPKGLKAGDQIQSGVDAAIKPGNTLPMRNIPVGSTVHNVEMKPGKGGQLARSAGTYVQIVARDGAYVTLRLRSGEMRKVEADCRATLGEVGNAEHMLRVLGKAGAARWRGVRPTVRGTAMNPVDHPHGGGEGRNFGKHPVTPWGVQTKGKKTRSNKRTDKFIVRRRSK
->6hgh_B mol:protein length:40  Alpha-1-antichymotrypsin
-SALVETRTIVRFNRPFLMIIVDHFTWSIFFMSKVTNPKQA
->4g7g_B mol:protein length:448  sterol 14-alpha-demethylase
-GKLPPVYPVTVPILGHIIQFGKSPLGFMQECKRQLKSGIFTINIVGKRVTIVGDPHEHSRFFLPRNEVLSPREVYSFMVPVFGEGVAYAAPYPRMREQLNFLAEELTIAKFQNFVPAIQHEVRKFMAANWDKDEGEINLLEDCSTMIINTACQCLFGEDLRKRLDARRFAQLLAKMESSLIPAAVFLPILLKLPLPQSARCHEARTELQKILSEIIIARKEEEVNKDSSTSDLLSGLLSAVYRDGTPMSLHEVCGMIVAAMFAGQHTSSITTTWSMLHLMHPANVKHLEALRKEIEEFPAQLNYNNVMDEMPFAERCARESIRRDPPLLMLMRKVMADVKVGSYVVPKGDIIACSPLLSHHDEEAFPEPRRWDPERDEKVEGAFIGFGAGVHKCIGQKFGLLQVKTILATAFRSYDFQLLRDEVPDPDYHTMVVGPTASQCRVKYIRR
->4glm_A mol:protein length:72  Dynamin-binding protein
-GGAAQPAMAQGALTYGVALYRFQALEPNELDFEVGDKIRILATLEDGWLEGSLKGRTGIFPYRFVKLCPAAA
->7eyd_V5 mol:protein length:173  C-phycocyanin beta subunit
-MTLDVFTKVVSQADSRGEFLSNEQLDALANVVKEGNKRLDVVNRITSNASAIVTNAARALFEEQPQLIAPGGNAYTNRRMAACLRDMEIILRYVTYAILAGDASVLDDRCLNGLRETYQALGTPGSSVAVGVQKMKDAAVGIANDPNGITKGDCSQLISEVASYFDRAAAAVG
->1mfr_K mol:protein length:176  M FERRITIN
-MVSQVRQNYHSDCEAAVNRMLNLELYASYTYSSMYAFFDRDDVALHNVAEFFKEHSHEEREHAEKFMKYQNKRGGRVVLQDIKKPERDEWGNTLEAMQAALQLEKTVNQALLDLHKLATDKVDPHLCDFLESEYLEEQVKDIKRIGDFITNLKRLGLPENGMGEYLFDKHSVKESS
->7nvm_Q mol:protein length:548  T-complex protein 1 subunit theta
-MALHVPKAPGFAQMLKEGAKHFSGLEEAVYRNIQACKELAQTTRTAYGPNGMNKMVINHLEKLFVTNDAATILRELEVQHPAAKMIVMASHMQEQEVGDGTNFVLVFAGALLELAEELLRIGLSVSEVIEGYEIACRKAHEILPNLVCCSAKNLRDIDEVSSLLRTSIMSKQYGNEVFLAKLIAQACVSIFPDSGHFNVDNIRVCKILGSGISSSSVLHGMVFKKETEGDVTSVKDAKIAVYSCPFDGMITETKGTVLIKTAEELMNFSKGEENLMDAQVKAIADTGANVVVTGGKVADMALHYANKYNIMLVRLNSKWDLRRLCKTVGATALPRLTPPVLEEMGHCDSVYLSEVGDTQVVVFKHEKEDGAISTIVLRGSTDNLMDDIERAVDDGVNTFKVLTRDKRLVPGGGATEIELAKQITSYGETCPGLEQYAIKKFAEAFEAIPRALAENSGVKANEVISKLYAVHQEGNKNVGLDIEAEVPAVKDMLEAGILDTYLGKYWAIKLATNAAVTVLRVDQIIMAKPAGGPKPPSGKKDWDDDQND
->6s61_M mol:protein length:182  Ferritin heavy chain
-MTTASPSQVRQNYHQDAEAAINRQINLELYASYVYLSMSCYFDRDDVALKNFAKYFLHQSHEEREHAEKLMKLQNQRGGRIFLQDIKKPDRDDWESGLNAMECALHLEKSVNQSLLELHKLATDKNDPHLCDFIETYYLSEQVKSIKELGDHVTNLRKMGAPEAGMAEYLFDKHTLGHGDES
->5j8k_F mol:protein length:429  COMPLEX I 51KDA/NDUFV1
-XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXCXXCXXCXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXCXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
->4wuz_B mol:protein length:229  Exonuclease
-GSHMTPDIILQRTGIDVRAVEQGDDAWHKLRLGVITASEVHNVIAKPRSGKKWPDMKMSYFHTLLAEVCTGVAPEVNAKALAWGKQYENDARTLFEFTSGVNVTESPIIYRDESMRTACSPDGLCSDGNGLELKCPFTSRDFMKFRLGGFEAIKSAYMAQVQYSMWVTRKNAWYFANYDPRMKREGLHYVVIERDEKYMASFDEIVPEFIEKMDEALAEIGFVFGEQWR
->7xve_C mol:protein length:215  Sodium channel subunit beta-2
-MHRDAWLPRPAFSLTGLSLFFSLVPPGRSMEVTVPATLNVLNGSDARLPCTFNSCYTVNHKQFSLNWTYQECNNCSEEMFLQFRMKIINLKLERFQDRVEFSGNPSKYDVSVMLRNVQPEDEGIYNCYIMNPPDRHRGHGKIHLQVLMEEPPERDSTVAVIVGASVGGFLAVVILVLMVVKCVRRKKEQKLSTDDLKTEEEGKTDGEGNPDDGAK
->5nd8_G mol:protein length:179  50S ribosomal protein L5
-MNRLKEKFNTEVTENLMKKFNYSSVMEVPKIDKIVVNMGVGDAVQNSKVLDNAVEELELITGQKPLVTKAKKSIATFRLREGMPIGAKVTLRGERMYEFLDKLISVSLPRVRDFQGVSKKAFDGRGNYTLGVKEQLIFPEIDYDKVSKVRGMDIVIVTTANTDEEARELLANFGMPFRK
->7pr0_E mol:protein length:205  Spike protein S1
-ETGHHHHHHTNLCPFGEVFNATRFASVYAWNRKRISNCVADYSVLYNSASFSTFKCYGVSPTKLNDLCFTNVYADSFVIRGDEVRQIAPGQTGKIADYNYKLPDDFTGCVIAWNSNNLDSKVGGNYNYLYRLFRKSNLKPFERDISTEIYQAGSTPCNGVEGFNCYFPLQSYGFQPTNGVGYQPYRVVVLSFELLHAPATVCGKK
->2af7_A mol:protein length:125  gamma-carboxymuconolactone decarboxylase
-MERYRRGMEILNRMNRKSYTAIRDELEDVAPDLARFVAEFAYGDVYSRGVLDLKTRELLTLAALTVLRADDQLKSHVRGALNAGCSKDEIIEVMIQMAVYAGFPAAINAVLAAKEVFTENDPAEV
->7ukn_A mol:protein length:1142  DNA damage-binding protein 1
-GAMSYNYVVTAQKPTAVNGCVTGHFTSAEDLNLLIAKNTRLEIYVVTAEGLRPVKEVGMYGKIAVMELFRPKGESKDLLFILTAKYNACILEYKQSGESIDIITRAHGNVQDRIGRPSETGIIGIIDPECRMIGLRLYDGLFKVIPLDRDNKELKAFNIRLEELHVIDVKFLYGCQAPTICFVYQDPQGRHVKTYEVSLREKEFNKGPWKQENVEAEASMVIAVPEPFGGAIIIGQESITYHNGDKYLAIAPPIIKQSTIVCHNRVDPNGSRYLLGDMEGRLFMLLLEKEEQMDGTVTLKDLRVELLGETSIAECLTYLDNGVVFVGSRLGDSQLVKLNVDSNEQGSYVVAMETFTNLGPIVDMCVVDLERQGQGQLVTCSGAFKEGSLRIIRNGIGIHEHASIDLPGIKGLWPLRSDPNRETDDTLVLSFVGQTRVLMLNGEEVEETELMGFVDDQQTFFCGNVAHQQLIQITSASVRLVSQEPKALVSEWKEPQAKNISVASCNSSQVVVAVGRALYYLQIHPQELRQISHTEMEHEVACLDITPLGDSNGLSPLCAIGLWTDISARILKLPSFELLHKEMLGGEIIPRSILMTTFESSHYLLCALGDGALFYFGLNIETGLLSDRKKVTLGTQPTVLRTFRSLSTTNVFACSDRPTVIYSSNHKLVFSNVNLKEVNYMCPLNSDGYPDSLALANNSTLTIGTIDEIQKLHIRTVPLYESPRKICYQEVSQCFGVLSSRIEVQDTSGGTTALRPSASTQALSSSVSSSKLFSSSTAPHETSFGEEVEVHNLLIIDQHTFEVLHAHQFLQNEYALSLVSCKLGKDPNTYFIVGTAMVYPEEAEPKQGRIVVFQYSDGKLQTVAEKEVKGAVYSMVEFNGKLLASINSTVRLYEWTTEKELRTECNHYNNIMALYLKTKGDFILVGDLMRSVLLLAYKPMEGNFEEIARDFNPNWMSAVEILDDDNFLGAENAFNLFVCQKDSAATTDEERQHLQEVGLFHLGEFVNVFCHGSLVMQNLGETSTPTQGSVLFGTVNGMIGLVTSLSESWYNLLLDMQNRLNKVIKSVGKIEHSFWRSFHTERKTEPATGFIDGDLIESFLDISRPKMQEVVANLQYDDGSGMKREATADDLIKVVEELTRIH
->4i10_A mol:protein length:406  Beta-secretase 1
-MRGSFVEMVDNLRGKSGQGYYVEMTVGSPPQTLNILVDTGSSNFAVGAAPHPFLHRYYQRQLSSTYRDLRKGVYVPYTQGKWEGELGTDLVSIPHGPNVTVRANIAAITESDKFFINGSNWEGILGLAYAEIARPDDSLEPFFDSLVKQTHVPNLFSLQLCGAGFPLNQSEVLASVGGSMIIGGIDHSLYTGSLWYTPIRREWYYEVIIVRVEINGQDLKMDCKEYNYDKSIVDSGTTNLRLPKKVFEAAVKSIKAASSTEKFPDGFWLGEQLVCWQAGTTPWNIFPVISLYLMGEVTNQSFRITILPQQYLRPVEDVATSQDDCYKFAISQSSTGTVMGAVIMEGFYVVFDRARKRIGFAVSACHVHDEFRTAAVEGPFVTLDMEDCGYNIPQTDESRSHHHHHH
->5j88_D1 mol:protein length:56  50S ribosomal protein L32
-AVQQNKPTRSKRGMRRSHDALTAVTSLSVDKTSGEKHLRHHITADGYYRGRKVIAK
->6wl8_oA mol:protein length:29  Form 2 peptide
-QAKILEADAEILKAYAKILEAHAEILKAQ
->4z3s_1q mol:protein length:105  30S ribosomal protein S17
-MPKKVLTGVVVSDKMQKTVTVLVERQFPHPLYGKVIKRSKKYLAHDPEEKYKLGDVVEIIESRPISKRKRFRVLRLVESGRMDLVEKYLIRRQNYESLSKRGGKA
->1tyq_D mol:protein length:300  Arp2/3 complex 34kDa subunit
-MILLEVNNRIIEETLALKFENAAAGNKPEAVEVTFADFDGVLYHISNPNGDKTKVMVSISLKFYKELQAHGADELLKRVYGSYLVNPESGYNVSLLYDLENLPASKDSIVHQAGMLKRNCFASVFEKYFQFQEEGKEGENRAVIHYRDDETMYVESKKDRVTVVFSTVFKDDDDVVIGKVFMQEFKEGRRASHTAPQVLFSHREPPLELKDTDAAVGDNIGYITFVLFPRHTNASARDNTINLIHTFRDYLHYHIKCSKAYIHTRMRAKTSDFLKVLNRARPDAEKKEMKTITGKTFSSR
->7jxs_F mol:protein length:137  Matrix protein
-GARASVLSGGELDKWEKIRLRPGGKKQYKLKHIVWASRELERFAVNPGLLETSEGCRQILGRLQPSLQTGSEELRSLYNTIAVLYCVHQRIDVKDTKEALDKIEEEQNKSKKKAQQAAADTGNNSQVSQNYHHHHHH
->1ww4_D mol:protein length:160  galectin
-TTSAVNIYNISAGASVDLAAPVTTGDIVTFFSSALNLSAGAGSPNNTALNLLSENGAYLLHIAFRLQENVIVFNSRQPNAPWLVEQRVSNVANQFIGSGGKAMVTVFDHGDKYQVVINEKTVIQYTKQISGTTSSLSYNSTEGTSIFSTVVEAVTYTGLA
->3waa_G mol:protein length:131  Histone H2A.V
-GSHMAGGKAGKDSGKAKAKAVSRSQRAGLQFPVGRIHRHLKTRTTSHGRVGATAAVYSAAILEYLTAEVLELAGNASKDLKVKRITPRHLQLAIRGDEELDSLIKATIAGGGVIPHIHKSLIGKKGQQKTA
->6ryr_H mol:protein length:123  Histone H2B 1.1
-MAKSAPAPKKGSKKAVTKTQKKDGKKRRKTRKESYAIYVYKVLKQVHPDTGISSKAMSIMNSFVNDVFERIAGEASRLAHYNKRSTITSREIQTAVRLLLPGELAKHAVSEGTKAVTKYTSAK
->6umr_A mol:protein length:441  Damage-control phosphatase DUF89
-MAVVPASLSGQDVGSFAYLTIKDRIPQILTKVIDTLHRHKSEFFEKHGEEGVEAEKKAISLLSKLRNELQTDKPFIPLVEKFVDTDIWNQYLEYQQSLLNESDGKSRWFYSPWLLVECYMYRRIHEAIIQSPPIDYFDVFKESKEQNFYGSQESIIALCTHLQQLIRTIEDLDENQLKDEFFKLLQISLWGNKCDLSLSGGESSSQNTNVLNSLEDLKPFILLNDMEHLWSLLSNCKKTREKASATRVYIVLDNSGFELVTDLILADFLLSSELATEVHFYGKTIPWFVSATTIHDFNWLIEQVKHSNHKWMSKCGADWEEYIKMGKWVYHNHIFWTLPHEYCAMPQVAPDLYAELQKAHLILFKGDLNYRKLTGDRKWEFSVPFHQALNGFHPAPLCTIRTLKAEIQVGLQPGQGEQLLASEPSWWTTGKYGIFQYDGPL
->1m64_A mol:protein length:571  flavocytochrome c3
-ADNLAEFHVQNQECDSCHTPDGELSNDSLTYENTQCVSCHGTLAEVAETTKHEHYNAHASHFPGEVACTSCHSAHEKSMVYCDSCHSFDFNMPYAKKWLRDEPTIAELAKDKSERQAALASAPHDTVDVVVVGSGGAGFSAAISATDSGAKVILIEKEPVIGGNAKLAAGGMNAAWTDQQKAKKITDSPELMFEDTMKGGQNINDPALVKVLSSHSKDSVDWMTAMGADLTDVGMMGGASVNRAHRPTGGAGVGAHVVQVLYDNAVKRNIDLRMNTRGIEVLKDDKGTVKGILVKGMYKGYYWVKADAVILATGGFAKNNERVAKLDPSLKGFISTNQPGAVGDGLDVAENAGGALKDMQYIFAHPTLSVKGGVMVTEAVRGNGAILVNREGKRFVNEITTRDKASAAILAQTGKSAYLIFDDSVRKSLSKIDKYIGLGVAPTADSLVKLGKMEGIDGKALTETVARYNSLVSSGKDTDFERPNLPRALNEGNYYAIEVTPGVHHTMGGVMIDTKAEVMNAKKQVIPGLYGAGEVTGGVHGANRLGGNAISDIITFGRLAGEEAAKYSKKN
->5kwy_D mol:protein length:133  Epididymal secretory protein E1
-EPVQFKDCGSVDGVIKEVNVSPCPTQPCQLSKGQSYSVNVTFTSNIQSKSSKAVVHGILMGVPVPFPIPEPDGCKSGINCPIQKDKTYSYLNKLPVKSEYPSIKLVVEWQLQDDKNQSLFCWEIPVQIVSHLA
->5jc9_AU mol:protein length:56  30S ribosomal protein S21
-PVIKVRENEPFDVALRRFKRSCEKAGVLAEVRRREFYEKPTTERKRAKASAVKRHA
->2jd7_C mol:protein length:174  FERRITIN HOMOLOG
-MLSERMLKALNDQLNRELYSAYLYFAMAAYFEDLGLEGFANWMKAQAEEEIGHALRFYNYIYDRNGRVELDEIPKPPKEWESPLKAFEAAYEHEKFISKSIYELAALAEEEKDYSTRAFLEWFINEQVEEEASVKKILDKLKFAKDSPQILFMLDKELSARAPKLPGLLMQGGE
->4r6o_H mol:protein length:19  Agglutinin beta-3 chain
-EQSGISQTVIVGPWGAKVS
->2hzi_B mol:protein length:277  Proto-oncogene tyrosine-protein kinase ABL1
-GAMDPSPNYDKWEMERTDITMKHKLGGGQYGEVYEGVWKKYSLTVAVKTLKEDTMEVEEFLKEAAVMKEIKHPNLVQLLGVCTREPPFYIITEFMTYGNLLDYLRECNRQEVNAVVLLYMATQISSAMEYLEKKNFIHRDLAARNCLVGENHLVKVADFGLSRLMTGDTYTAHAGAKFPIKWTAPESLAYNKFSIKSDVWAFGVLLWEIATYGMSPYPGIDLSQVYELLEKDYRMERPEGCPEKVYELMRACWQWNPSDRPSFAEIHQAFETMFQES
->6wyd_E mol:protein length:467  Myeloperoxidase heavy chain
-VNCETSCVQQPPCFPLKIPPNDPRIKNQADCIPFFRSCPACPGSNITIRNQINALTSFVDASMVYGSEEPLARNLRNMSNQLGLLAVNQRFQDNGRALLPFDNLHDDPCLLTNRSARIPCFLAGDTRSSEMPELTSMHTLLLREHNRLATELKSLNPRWDGERLYQEARKIVGAMVQIITYRDYLPLVLGPTAMRKYLPTYRSYNDSVDPRIANVFTNAFRYGHTLIQPFMFRLDNRYQPMEPNPRVPLSRVFFASWRVVLEGGIDPILRGLMATPAKLNRQNQIAVDEIRERLFEQVMRIGLDLPALNMQRSRDHGLPGYNAWRRFCGLPQPETVGQLGTVLRNLKLARKLMEQYGTPNNIDIWMGGVSEPLKRKGRVGPLLACIIGTQFRKLRDGDRFWWENEGVFSMQQRQALAQISLPRIICDNTGITTVSKNNIFMSNSYPRDFVNCSTLPALNLASWREAS
->3cgx_A mol:protein length:242  Putative nucleotide-diphospho-sugar transferase
-GMSESCILFFVKYPEPGKVKTRLGEVVGNDKAAMLYRHFVQDMLQGLARLHADLHICYVPGDADLPEKFKAWLGPQHMFAAQQGLDLGERMKHAMQKAFDDGYDRVVLMGSDIPDYPCELVQKALNDLQHYDAAIGPAFDGGYYLIGFRKDSFCPDVFDGIRWGEADVYQPTVEKMRRARLEVLQLPDWNDVDTVWDLNVLYRTNKNSSFRRSSTYALLRENDALIRQYDIDLPGMAPVEKE
->3dke_X mol:protein length:164  Lysozyme
-MNIFEMLRIDEGLRLKIYKDTEGYYTIGIGHLLTKSPSLNAAKSELDKAIGRNTNGVITKDEAEKLFNQDVDAAVRGILRNAKLKPVYDSLDAVRRAAAINLVFQMGETGVAGFTNSLRMLQQKRWDEAAVNLAKSRWYNQTPNRAKRVITTFRTGTWDAYKNL
->6jxq_A mol:protein length:147  Lysozyme C
-MRSLLILVLCFLPLAALGKVFGRCELAAAMKRHGLDNYRGYSLGNWVCAAKFESNFNTQATNRNTDGSTDYGILQINSRWWCNDGRTPGSRNLCNIPCSALLSSDITASVNCAKKIVSDGNGMNAWVAWRNRCKGTDVQAWIRGCRL
->1ju2_A mol:protein length:536  hydroxynitrile lyase
-LATTSDHDFSYLSFAYDATDLELEGSYDYVIVGGGTSGCPLAATLSEKYKVLVLERGSLPTAYPNVLTADGFVYNLQQEDDGKTPVERFVSEDGIDNVRGRVLGGTSIINAGVYARANTSIYSASGVDWDMDLVNQTYEWVEDTIVYKPNSQSWQSVTKTAFLEAGVHPNHGFSLDHEEGTRITGSTFDNKGTRHAADELLNKGNSNNLRVGVHASVEKIIFSNAPGLTATGVIYRDSNGTPHQAFVRSKGEVIVSAGTIGTPQLLLLSGVGPESYLSSLNIPVVLSHPYVGQFLHDNPRNFINILPPNPIEPTIVTVLGISNDFYQCSFSSLPFTTPPFGFFPSSSYPLPNSTFAHFASKVAGPLSYGSLTLKSSSNVRVSPNVKFNYYSNLTDLSHCVSGMKKIGELLSTDALKPYKVEDLPGVEGFNILGIPLPKDQTDDAAFETFCRESVASYWHYHGGCLVGKVLDGDFRVTGINALRVVDGSTFPYTPASHPQGFYLMLGRYVGIKILQERSASDLKILDSLKSAASLVL
->3oi9_A mol:protein length:164  Molybdenum cofactor synthesis domain
-GPGSMTTRSARVIIASTRASSGEYEDRCGPIITEWLAQQGFSSAQPEVVADGSPVGEALRKAIDDDVDVILTSGGTGIAPTDSTPDQTVAVVDYLIPGLAEAIRQSGLPKVPTSVLSRGVCGVAGQTLIVNLPGSPGGVRDGLGVLAGVLDHALDQLAGKDHPR
->5zf0_C1 mol:protein length:80  Photosystem I iron-sulfur center
-AHTVKIYDTCIGCTQCVRACPTDVLEMVPWDGCKAGQIASSPRTEDCVGCKRCETACPTDFLSIRVYLGAETTRSMGLAY
->3fq3_H mol:protein length:197  Inorganic pyrophosphatase:Bacterial/Archaeal inorganic pyrophosphatase
-MAHHHHHHMGTLEAQTQGPGSMNIDAISIGSNPPEDVNVIIEVPVGGQPIKYEMDKKAGALIVDRFLYTPMTYPGNYGFVPHTLSEDGDPIDVLVCNTRPLIPGCVINVRPIGVLVMEDNSGKDEKIIAVPSPHLTRRYEKIHDYTDMPEITLKQIAHFFEHYKDLEPGKWVKIGDWGDEDYARKFIVEAIERAKGK
->7s5z_A mol:protein length:390  ATP-sensitive inward rectifier potassium channel 11
-MLSRKGIIPEEYVLTRLAEDPAKPRYRARQRRARFVSKKGNCNVAHKNIREQGRFLQDVFTTLVDLKWPHTLLIFTMSFLCSWLLFAMAWWLIAFAHGDLAPSEGTAEPCVTSIHSFSSAFLFSIEVQVTIGFGGRMVTEECPLAILILIVQNIVGLMINAIMLGSIFMKTAQAHRRAETLIFSKHAVIALRHGRLCFMLRVGDLRKSMIISATIHMQVVRKTTSPEGEVVPLHQVDIPMENGVGGNSIFLVAPLIIYHVIDANSPLYDLAPSDLHHHQDLEIIVILEGVVETTGITTQARTSYLADEILWGQRFVPIVAEEDGRYSVDYSKFDNTVKVPTPLCTARQLDEDHSLLEALTLASARGPLRKRSVPMAKAKPKFSISPDSLS
->6zsb_g mol:protein length:166  39S ribosomal protein L49, mitochondrial
-MAATMFRATLRGWRTGVQRGCGLRLLSQTQGPPDYPRFVESVDEYQFVERLLPATRIPDPPKHEHYPTPSGWQPPRDPPPNLPYFVRRSRMHNIPVYKDITHGNRQMTVIRKVEGDIWALQKDVEDFLSPLLGKTPVTQVNEVTGTLRIKGYFDQELKAWLLEKGF
->7xoa_C mol:protein length:1270  Spike glycoprotein
-MFVFLVLLPLVSSQCVNLITRTQSYTNSFTRGVYYPDKVFRSSVLHSTQDLFLPFFSNVTWFHAIHVSGTNGTKRFDNPVLPFNDGVYFASTEKSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCEFQFCNDPFLDVYYHKNNKSWMESEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLREFVFKNIDGYFKIYSKHTPINLGRDLPQGFSALEPLVDLPIGINITRFQTLLALHRSYLTPGDSSSGWTAGAAAYYVGYLQPRTFLLKYNENGTITDAVDCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESIVRFPNITNLCPFDEVFNATRFASVYAWNRKRISNCVADYSVLYNFAPFFAFKCYGVSPTKLNDLCFTNVYADSFVIRGNEVSQIAPGQTGNIADYNYKLPDDFTGCVIAWNSNKLDSKVGGNYNYLYRLFRKSNLKPFERDISTEIYQAGNKPCNGVAGFNCYFPLRSYGFRPTYGVGHQPYRVVVLSFELLHAPATVCGPKKSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFGRDIADTTDAVRDPQTLEILDITPCSFGGVSVITPGTNTSNQVAVLYQGVNCTEVPVAIHADQLTPTWRVYSTGSNVFQTRAGCLIGAEYVNNSYECDIPIGAGICASYQTQTKSHGSASSVASQSIIAYTMSLGAENSVAYSNNSIAIPTNFTISVTTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLKRALTGIAVEQDKNTQEVFAQVKQIYKTPPIKYFGGFNFSQILPDPSKPSKRSPIEDLLFNKVTLADAGFIKQYGDCLGDIAARDLICAQKFNGLTVLPPLLTDEMIAQYTSALLAGTITSGWTFGAGPALQIPFPMQMAYRFNGIGVTQNVLYENQKLIANQFNSAIGKIQDSLSSTPSALGKLQDVVNHNAQALNTLVKQLSSKFGAISSVLNDILSRLDPPEAEVQIDRLITGRLQSLQTYVTQQLIRAAEIRASANLAATKMSECVLGQSKRVDFCGKGYHLMSFPQSAPHGVVFLHVTYVPAQEKNFTTAPAICHDGKAHFPREGVFVSNGTHWFVTQRNFYEPQIITTDNTFVSGNCDVVIGIVNNTVYDPLQPELDSFKEELDKYFKNHTSPDVDLGDISGINASVVNIQKEIDRLNEVAKNLNESLIDLQELGKYEQYIKWPWYIWLGFIAGLIAIVMVTIMLCCMTSCCSCLKGCCSCGSCCKFDEDDSEPVLKGVKLHYT
->5dgf_M9 mol:protein length:188  60S ribosomal protein L19-A
-ANLRTQKRLAASVVGVGKRKVWLDPNETSEIAQANSRNAIRKLVKNGTIVKKAVTVHSKSRTRAHAQSKREGRHSGYGKRKGTREARLPSQVVWIRRLRVLRRLLAKYRDAGKIDKHLYHVLYKESKGNAFKHKRALVEHIIQAKADAQREKALNEEAEARRLKNRAARDRRAQRVAEKRDALLKEDA
->4otz_A mol:protein length:395  Amino acid/amide ABC transporter substrate-binding protein, HAAT family
-SNATNTDTNSTNNSPNNTTNTTTNVTTTSDKNTIPIGIALAQTSNVALLGQEQVAGAKIAEKYFNDKGGVNGTPIKLIFQDTAGDEAGTINAFQTLINKDKVVGIVGPTLSQQAFSANPIAERAKVPVVGPSNTAKGIPEIGDYVARVSAPVSVVAPNSVKAALKQNPNIKKVAVFFAQNDAFSKSETEIFQQTVKDQGLELVTVQKFQTTDTDFQSQATNAINLKPDLVIISGLAADGGNLVRQLRELGYQGAIIGGDGLNTSNVFAVCKALCDGVLIAQAYSPEYTGEINKAFRQAYVDQYKKEPPQFSAQAFAAVQVYVESLKALDTKNKVSKIQLPELRTELNKQLLTGKYNTPLGEISFTPIGEVVQKDFYVAQIKMEKDGSQGKFTFLK
->1dps_L mol:protein length:167  DPS
-MSTAKLVKSKATNLLYTRNDVSDSEKKATVELLNRQVIQFIDLSLITKQAHWNMRGANFIAVHEMLDGFRTALIDHLDTMAERAVQLGGVALGTTQVINSKTPLKSYPLDIHNVQDHLKELADRYAIVANDVRKAIGEAKDDDTADILTAASRDLDKFLWFIECNIE
->7wxi_A mol:protein length:776  Delta-1-pyrroline-5-carboxylate synthase
-MLQNSFKLAQSLRNGFYRNAWRAFSSHGPRQPLVSPERRLEKAHPTFTERSQLKYARRLVVKLGSAVITREDNHGLALGRLASIVEQVAECHLEGREVMMVTSGAVAFGKQKLAQELLMSLSMRETLNPKDSKEFDGATLEPRAAAAVGQSGLMSLYDAMFAQYGVKIAQVLVTKPDFYNEETRNNLFCTLSELISLNIVPIINTNDAVSPPMFIRDDEPAGGARRGIPIKDNDSLSAMLAAEVQADLLILMSDVDGIYNKPPWEDGAKLMHTYTSDDSNSIEFGKKSKVGTGGMDSKVKAATWALDRGVSVVICNGMQEKAIKTIIGGRKVGTFFTEATESANAVPVEVMAENARTGSRQMQALTPAQRASAVNTLADLLVSREKFILDANAKDLAEAQKSGLAKPLLSRLSLNPAKLKNLSVGLKQIAEDSHKNVGRVLRRTRLADQLELKQVTVPIGVLLVIFESRPDSLPQVAALAMASANGLLLKGGKEAAHSNKALMELVKEALATVGAEHAVSLVSTREEISDLLSMENHIDLIIPRGSSDLVRSIQQQSLHIPVLGHAEGVCHVYIDRDADLEKALRIARDAKCDYPAACNAMETLLIHEDLMSGAIFGDVCNMLKREGVKIYAGPRLNQQLTFGPPAAKSLKHEYGALECCIEVVPSLDEAINHIHTYGSSHTDVIVTENDAAARQFLGSVDSACVFHNASSRFADGFRFGLGAEVGISTARIHARGPVGVEGLLTTKWILEGQDHAAADFAEGGGRTWLHETLPLD
->4u1v_B3 mol:protein length:64  50S ribosomal protein L35
-PKIKTVRGAAKRFKKTGKGGFKHKHANLRHILTKKATKRKRHLRPKAMVSKGDLGLVIACLPYA
->5l5h_J mol:protein length:198  Proteasome subunit beta type-4
-MDIILGIRVQDSVILASSKAVTRGISVLKDSDDKTRQLSPHTLMSFAGEAGDTVQFAEYIQANIQLYSIREDYELSPQAVSSFVRQELAKSIRSRRPYQVNVLIGGYDKKKNKPELYQIDYLGTKVELPYGAHGYSGFYTFSLLDHHYRPDMTTEEGLDLLKLCVQELEKRMPMDFKGVIVKIVDKDGIRQVDDFQAQ
->6mu3_M mol:protein length:225  Fab 2G12, heavy chain
-EVQLVESGGGLVKAGGSLILSCGVSNFRISAHTMNWVRRVPGGGLEWVASISTSSTYRDYADAVKGRFTVSRDDLEDFVYLQMHKMRVEDTAIYYCARKGSDRLSDNDPFDAWGPGTVVTVSPASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEPKS
->3sud_B mol:protein length:203  NS3 protease, NS4A protein
-GSHMASMKKKGSVVIVGRINLSGDTAYAQQTRGEEGCQETSQTGRDKNQVEGEVQIVSTATQTFLATSINGVLWTVYHGAGTRTIASPKGPVTQMYTNVDKDLVGWQAPQGSRSLTPCTCGSSDLYLVTRHADVIPVRRRGDSRGSLLSPRPISYLKGSAGGPLLCPAGHAVGIFRAAVSTRGVAKAVDFIPVESLETTMRSP
->6bfq_I mol:protein length:127  Granulocyte-macrophage colony-stimulating factor
-APARSPSPSTQPWEHVNAIQEARRLLNLSRDTAAEMNETVEVISEMFDLQEPTCLQTRLELYKQGLRGSLTKLKGPLTMMASHYKQHCPPTPETSCATQIITFESFKENLKDFLLVIPFDCWEPVQE
->5fl8_R mol:protein length:189  60S ribosomal protein L19-A
-MANLRTQKRLAASVVGVGKRKVWLDPNETSEIAQANSRNAIRKLVKNGTIVKKAVTVHSKSRTRAHAQSKREGRHSGYGKRKGTREARLPSQVVWIRRLRVLRRLLAKYRDAGKIDKHLYHVLYKESKGNAFKHKRALVEHIIQAKADAQREKALNEEAEARRLKNRAARDRRAQRVAEKRDALLKEDA
->6hiv_BJ mol:protein length:333  mL76
-MLRLSSWNLKSQHHNVLRRSRPHIHKYRELNRWQRQAQGISKWDQSHSHRPLPYVERFNPESVGLTRGTSAFAWKWWHTQYPWLPNVPPEAAQIDEAQKQERRSHRPPAWDDEFAKVVLNMNDAEIREYLMSKLTDVIFLETQRDGYELRRLDFEGKPLTSLPEPRIIENFVLEEETIRERVIYQVVEGVFRLSPTSADRRELRSVANIIDYVLTHVRAARPTDRERRQERPITSAALAVMQKCPIQPQLGFVHALPHDTRDALLQEWERMHHLDWQFGKAVYTPRSKENVRGNLTWLREDRHYDQRMKFMQEVESGEARAKHMKLIAEAAGN
->7kf1_B mol:protein length:218  anti-VEGF-A Fab bH1 light chain
-DIQMTQSPSSLSASVGDRVTITCRASQDIPRSISGYVAWYQQKPGKAPKLLIYWGSYLYSGVPSRFSGSGSGTDFTLTISSLQPEDFATYYCQQHYTTPPTFGQGTKVEIKRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNRGEC
->2v7n_B mol:protein length:229  IMMUNOGLOBULIN HEAVY CHAIN
-QVQLVESGGGLVQPGGSLRLSCAASGFTFRNSAMHWVRQAPGKGLEWVSSIWYSGSNTYYADSVKGRFTISRDNSKNTLYLQMNSLRAEDTAVYYCARFAGGWGAYDVWGQGTLVTVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEPKSEFHHHHHH
->4ium_A mol:protein length:142  papain-like protease 2
-GYNPPGDGACGYRCLAFMNGATVVSAGCSSDLWCDDELAYRVFQLSPTFTVTIPGGRVCPNAKYAMICDKQHWRVKRAKGVGLCLDESCFRGICNCQRMSGPPPAPVSAAVLDHILEAATFGNVRVVTPEGQGSSGHHHHHH
->5qob_B mol:protein length:189  Thiol:disulfide interchange protein
-AQYEDGKQYTTLEKPVAGAPQVLEFFSFFCPHCYQFEEVLHISDNVKKKLPEGVKMTKYHVNFMGGDLGKDLTQAWAVAMALGVEDKVTVPLFEGVQKTQTIRSASDIRDVFINAGIKGEEYDAAWNSFVVKSLVAQQEKAAADVQLRGVPAMFVNGKYQLNPQGMDTSNMDVFVQQYADTVKYLSEKK
->7odk_AAA mol:protein length:617  Receptor-like protein kinase HSL1
-GSSMDNQDGFILQQVKLSLDDPDSYLSSWNSNDASPCRWSGVSCAGDFSSVTSVDLSSANLAGPFPSVICRLSNLAHLSLYNNSINSTLPLNIAACKSLQTLDLSQNLLTGELPQTLADIPTLVHLDLTGNNFSGDIPASFGKFENLEVLSLVYNLLDGTIPPFLGNISTLKMLNLSYNPFSPSRIPPEFGNLTNLEVMWLTECHLVGQIPDSLGQLSKLVDLDLALNDLVGHIPPSLGGLTNVVQIELYNNSLTGEIPPELGNLKSLRLLDASMNQLTGKIPDELCRVPLESLNLYENNLEGELPASIALSPNLYEIRIFGNRLTGGLPKDLGLNSPLRWLDVSENEFSGDLPADLCAKGELEELLIIHNSFSGVIPESLADCRSLTRIRLAYNRFSGSVPTGFWGLPHVNLLELVNNSFSGEISKSIGGASNLSLLILSNNEFTGSLPEEIGSLDNLNQLSASGNKFSGSLPDSLMSLGELGTLDLHGNQFSGELTSGIKSWKKLNELNLADNEFTGKIPDEIGSLSVLNYLDLSGNMFSGKIPVSLQSLKLNQLNLSYNRLSGDLPPSLAKDMYKNSFIGNPGLCGDIKGLCGSENEAKKRGYVLEGSENLYFQ
->1ixm_B mol:protein length:192  PROTEIN (SPORULATION RESPONSE REGULATORY PROTEIN)
-MKDVSKNQEENISDTALTNELIHLLGHSRHDWMNKLQLIKGNLSLQKYDRVFEMIEEMVIDAKHESKLSNLKTPHLAFDFLTFNWKTHYMTLEYEVLGEIKDLSAYDQKLAKLMRKLFHLFDQAVSRESENHLTVSLQTDHPDRQLILYLDFHGAFADPSAFDDIRQNGYEDVDIMRFEITSHECLIEIGLD
->7c0w_A mol:protein length:406  Sugar ABC transporter, periplasmic sugar-binding protein
-MMKPEDVIKEQCARAKVVAELWHGFTGGAPKAALENLVVEFNKAQQGRCVRPVPQGGYRDLSTKIKAAFAAGKVPTMAQAFENNIALYLEAKALLPIESLGVKLQGVNLTFLNAVRFGGVVYGVPFNKSIQVLYYNKDLLKKHGVPVPATLEEFVAAAKKLSRAEGGPVYWFQPDASTFAYFFFNLGGSYLKDGKLVLNSKEAVEALTLLQNGVKEGWAKPITSGAINQNLGSGPYAFSVDTSAGYTYYLRAAKFDLGVATLPGRTKGQPGYGLVQGTNLVVFRQASKEEQAVAKDFLEFVLSPRAQAVFATATGYVPVTEGALKDPVYQAYAAENPDYATIVRQSRYAKFEPALAEWEQIRFDILGQAIKEAILNKADPKAALDRAQKLAEDLLSSRTRHHHHHH
->5pln_A mol:protein length:364  Lysine-specific demethylase 4D
-MHHHHHHSSGVDLGTENLYFQSMETMKSKANCAQNPNCNIMIFHPTKEEFNDFDKYIAYMESQGAHRAGLAKIIPPKEWKARETYDNISEILIATPLQQVASGRAGVFTQYHKKKKAMTVGEYRHLANSKKYQTPPHQNFEDLERKYWKNRIYNSPIYGADISGSLFDENTKQWNLGHLGTIQDLLEKECGVVIEGVNTPYLYFGMWKTTFAWHTEDMDLYSINYLHLGEPKTWYVVPPEHGQRLERLARELFPGSSRGCGAFLRHKVALISPTVLKENGIPFNRITQEAGEFMVTFPYGYHAGFNHGFNCAEAINFATPRWIDYGKMASQCSCGEARVTFSMDAFVRILQPERYDLWKRGQDR
->7xxg_A mol:protein length:277  VP1
-GDNQDRTVANTQPSGPSNSKEIPALTAVETGHTSQVDPSDTLQTRHVVNFHSRSESTVENFMGRAACVFMDQYKLNGEETSTDNFAVWTINVREMAQLRRKCELFTYMRFDIEMTMVITSCQDQGTQLEQDMPVLTHQIMYVPPGGPIPAKVDSYEWQTSTNPSVFWTEGNAPARMSIPFISVGNAYSLFYDGWSHFTQDGTYGYTTLNAMGKLFVRHVNKSSPHQITSTIRVYFKPKHIKAWVPRPPRLCPYINKGDVNFVVTEVTDARKSITDTP
->6ynl_A mol:protein length:183  YTHDC1
-MHHHHHHSSGRENLYFQGTSKLKYVLQDARFFLIKSNNHENVSLAKAKGVWSTLPVNEKKLNLAFRSARSVILIFSVRESGKFQGFARLSSESHHGGSPIHWVLPAGMSAKMLGGVFKIDWICRRELPFTKSAHLTNPWNEHKPVKIGRDGQEIELECGTQLCLLFPPDESIDLYQVIHKMRH
->7xat_A mol:protein length:563  Somatostatin receptor type 2,LargeBit
-MKTIIALSYIFCLVFADYKDDDDKGSGSHHHHHHHHHHLEVLFQGPMDMADEPLNGSHTWLSIPFDLNGSVVSTNTSNQTEPYYDLTSNAVLTFIYFVVCIIGLCGNTLVIYVILRYAKMKTITNIYILNLAIADELFMLGLPFLAMQVALVHWPFGKAICRVVMTVDGINQFTSIFCLTVMSIDRYLAVVHPIKSAKWRRPRTAKMITMAVWGVSLLVILPIMIYAGLRSNQWGRSSCTINWPGESGAWYTGFIIYTFILGFLVPLTIICLCYLFIIIKVKSSGIRVGSSKRKKSEKKVTRMVSIVVAVFIFCWLPFYIFNVSSVSMAISPTPALKGMFDFVVVLTYANSCANPILYAFLSDNFKKSFQNVLCLVKVSGTDDGERSDSKQDKSRLNETTETQRTVFTLEDFVGDWEQTAAYNLDQVLEQGGVSSLLQNLAVSVTPIQRIVRSGENALKIDIHVIIPYEGLSADQMAQIEEVFKVVYPVDDHHFKVILPYGTLVIDGVTPNMLNYFGRPYEGIAVFDGKKITVTGTLWNGNKIIDERLITPDGSMLFRVTINS
->3k7z_A mol:protein length:33  General control protein GCN4
-RMKQLEDKVEELLSKAYHLENEVARLKKLVGER
->1uld_C mol:protein length:150  galectin-2
-MLYHLFVNNQVKLQNDFKPESVAAIRSSAFNSKGGTTVFNFLSAGENILLHISIRPGENVIVFNSRLKNGAWGPEERIPYAEKFRPPNPSITVIDHGDRFQIRFDYGTSIYYNKRIKENAAAIAYNAENSLFSSPVTVDVHGLLPPLPPA
->1nz0_A mol:protein length:118  Ribonuclease P protein component
-GSTESFTRRERLRLRRDFLLIFKEGKSLQNEYFVVLFRKNGMDYSRLGIVVKRKFGKATRRNKLKRWVREIFRRNKGVIPKGFDIVVIPRKKLSEEFERVDFWTVREKLLNLLKRIEG
->7wt2_B mol:protein length:184  Lactoylglutathione lyase
-MAEPQPPSGGLTDEAALSCCSDADPSTKDFLLQQTMLRVKDPKKSLDFYTRVLGMTLIQKCDFPIMKFSLYFLAYEDKNDIPKEKDEKIAWALSRKATLELTHNWGTEDDETQSYHNGNSDPRGFGHIGIAVPDVYSACKRFEELGVKFVKKPDDGKMKGLAFIQDPDGYWIEILNPNKMATLM
->4v79_AS mol:protein length:81  30S ribosomal protein S19
-XRSLKKGPFIDLHLLKKVEKAVESGDKKPLRTWSRRSTIFPNMIGLTIAVHNGRQHVPVFVTDEMVGHKLGEFAPTRTYRX
->4prp_B mol:protein length:99  Beta-2-microglobulin
-IQRTPKIQVYSRHPAENGKSNFLNCYVSGFHPSDIEVDLLKNGERIEKVEHSDLSFSKDWSFYLLYYTEFTPTEKDEYACRVNHVTLSQPKIVKWDRDM
->6zpo_H mol:protein length:146  ATP synthase subunit delta, mitochondrial
-AEAAAAQAPAAGPGQMSFTFASPTQVFFNSANVRQVDVPTQTGAFGILAAHVPTLQVLRPGLVVVHAEDGTTSKYFVSSGSVTVNADSSVQLLAEEAVTLDMLDLGAAKANLEKAQSELLGAADEATRAEIQIRIEANEALVKALE
->1yxo_B mol:protein length:328  4-hydroxythreonine-4-phosphate dehydrogenase 1
-MSLRFALTPGEPAGIGPDLCLLLARSAQPHPLIAIASRTLLQERAGQLGLAIDLKDVSPAAWPERPAKAGQLYVWDTPLAAPVRPGQLDRANAAYVLETLTRAGQGCLDGHFAGMITAPVHKGVINEAGIPFSGHTEFLADLTHTAQVVMMLATRGLRVALATTHLPLREVADAISDERLTRVARILHADLRDKFGIAHPRILVCGLNPHAGEGGHLGREEIEVIEPCLERLRGEGLDLIGPLPADTLFTPKHLEHCDAVLAMYHDQGLPVLKYKGFGAAVNVTLGLPIIRTSVDHGTALDLAGSGRIDSGSLQVALETAYQMAASRC
->7n2u_Pp mol:protein length:3  Nascent peptide
-MFK
->4ui8_C mol:protein length:48  TANKYRASE-2
-MAHSPPGHHSVTGRPSVNGLALAEYVIYRGEQAYPEYLITYQIMRPEG
->4v8d_DT mol:protein length:96  50S ribosomal protein L23
-MKTAYDVILAPVLSEKAYAGFAEGKYTFWVHPKATKTEIKNAVETAFKVKVVKVNTLHVRGKKKRLGRYLGKRPDRKKAIVQVAPGQKIEALEGLI
->5dcm_B mol:protein length:243  PhoB family transcriptional regulator
-MSQEQGKIYIVEDDMTIVSLLKDHLSASYHVSSVSNFRDVKQEIIAFQPDLILMDITLPYFNGFYWTAELRKFLTIPIIFISSSNDEMDMVMALNMGGDDFISKPFSLAVLDAKLTAILRRSQQFIQQELTFGGFTLTREGLLSSQDKEVILSPTENKILSILLMHPKQVVSKESLLEKLWENDSFIDQNTLNVNMTRLRKKIVPIGFDYIHTVRGVGYLLQNDPSSSVDKLAAALEHHHHHH
->6v1q_A mol:protein length:773  Two pore channel 3
-MSEGKTEKTSHTLTKDEGFTNGGNHVPSNVTDQMTEKFDLATVYVSDAKYNRNIFFDTSPQAVKLYLLYNHWFMQTLVYVFIIINLALALFEDPAVVPLPIWATSTIETICLSAFTVRIIHYAKVIPKDKFWKDPKNICIIIIVTLSFIDMVIYGALKATGHYGIRWSRVLRPLLLVNVTEGRQLRRAFRSIRNALPQISYVFFLFMFSVLVFSLMALKLFGKRGLLTINGSPYFTDYMDIVFDLYVLVTTANSPDVMMPAYNSSVYFTIFFILYIVINTYTFMSFFLAVVYNNYKKYLKEEVRQLVKAKRIKMCRAFSLLQENRGEGGEPVVTQANWNHLVKLVKPKISTAHRELLWSVLDDQNKGHIGKFAFVQLADLLSIQVITVKSQAHPIQICFPSLYNSLPSRFIRQMVHHRVFVYAYDLIILVNAVFIGLDEENPVVSNAEWGFLALYMLEILLKLYATEPRAFFARHQFWNWFDTIIVVSALFGTIINSALKHSGGYTSRQVLDIVFILRVLRLIRVVDSIKRFRAIINTLIKIGPTILTFGQLILVVYYIFAMVGMELFKGKIQFFEPNSTSPDREYCGNPLLKSTSFAKLNYCKNNFNDVISSFILLLELTVVNQWHVLTSGFTAVTHVSARLFFVIFHIVVVIIIINIFVAFILEAFLVEYTVDKSELQTSLEKKIEELELNVQQDGVDTGLVDAMETNDSDLGSSEDGKRKPSLMFKIASRRSRTVDGLLQRMFETDLRPEDFNEEELDNTNFSNPVFDSV
->6xza_O2 mol:protein length:117  50S ribosomal protein L18
-MDKKSARIRRATRARRKLQELGATRLVVHRTPRHIYAQVIAPNGSEVLVAASTVEKAIAEQLKYTGNKDAAAAVGKAVAERALEKGIKDVSFDRSGFQYHGRVQALADAAREAGLQF
->7of6_J mol:protein length:192  39S ribosomal protein L11, mitochondrial
-MSKLGRAARGLRKPEVGGVIRAIVRAGLAMPGPPLGPVLGQRGVSINQFCKEFNERTKDIKEGIPLPTKILVKPDRTFEIKIGQPTVSYFLKAAAGIEKGARQTGKEVAGLVTLKHVYEIARIKAQDEAFALQDVPLSSVVRSIIGSARSLGIRVVKDLSSEELAAFQKERAIFLAAQKEADLAAQEEAAKK
->5ltq_M mol:protein length:269  Green fluorescent protein blFP-Y3
-MRGSHHHHHHGMASMTGGQQMGRDLYDDDDKDPMVSKGEEDNMASLPATHELHIFGSFNGVDFDMVGRGTGNPNDGYEELNLKSTKGALQFSPWILVPQIGYGFHQYLPFPDGMSPFQAAMKDGSGYQVHRTMQFEDGASLTSNYRYTYEGSHIKGEFQVIGTGFPADGPVMTNSLTAADWCVTKMLYPNDKTIISTFDWTYTTGSGKRYQSTARTTYTFAKPMAANILKNQPMFVFRKTELKHSKTELNFKEWQKAFTDVMGMDELYK
->1rx0_B mol:protein length:393  Acyl-CoA dehydrogenase family member 8, mitochondrial
-MVQTGHRSLTSCIDPSMGLNEEQKEFQKVAFDFAAREMAPNMAEWDQKELFPVDVMRKAAQLGFGGVYIQTDVGGSGLSRLDTSVIFEALATGCTSTTAYISIHNMCAWMIDSFGNEEQRHKFCPPLCTMEKFASYCLTEPGSGSDAASLLTSAKKQGDHYILNGSKAFISGAGESDIYVVMCRTGGPGPKGISCIVVEKGTPGLSFGKKEKKVGWNSQPTRAVIFEDCAVPVANRIGSEGQGFLIAVRGLNGGRINIASCSLGAAHASVILTRDHLNVRKQFGEPLASNQYLQFTLADMATRLVAARLMVRNAAVALQEERKDAVALCSMAKLFATDECFAICNQALQMHGGYGYLKDYAVQQYVRDSRVHQILEGSNEVMRILISRSLLQE
->1c4y_1 mol:protein length:36  THROMBIN:SHORT CHAIN
-TFGSGEADCGLRPLFEKKSLEDKTERELLESYIDGR
->7tab_A mol:protein length:130  Isoform 4 of Transcription activator BRG1
-GSAEKLSPNPPNLTKKMKKIVDAVIKYKDSSSGRQLSEVFIQLPSRKELPEYYELIRKPVDFKKIKERIRNHKYRSLNDLEKDVMLLCQNAQTFNLEGSLIYEDSIVLQSVFTSVRQKIEKEDDSEGEES
->6p4h_E mol:protein length:281  uS3
-MSARRRRRRAAFRRRAEPFIPISVREPLPFLSAARGGKMAVQISKKRKFVADGIFKAELNEFLTRELAEDGYSGVEVRVTPTRTEIIILATRTQNVLGEKGRRIRELTAVVQKRFGFPEGSVELYAEKVATRGLCAIAQAESLRYKLLGGLAVRRACYGVLRFIMESGAKGCEVVVSGKLRGQRAKSMKFVDGLMIHSGDPVNYYVDTAVRHVLLRQGVLGIKVKIMLPWDPSGKIGPKKPLPDHVSIVEPKDEILPTTPISEQKGGKPEPPAMPQPVPTA
->6zzy_7 mol:protein length:221  Chlorophyll a-b binding protein, chloroplastic
-VRELWFPGNKEVVPDYLDGSLVGDHGFDPLGLGSSPEQLSWNVHAEIFHGRLAMTGVAGILLTSLLHKGGADVPEWFEAGRVYLDRNPNVDFGALLFSTIVMSGFVEFKRLNDIRNPGSQGSGILPEDFKGVGGPQGRTVGGPYVGGRYFDPMGLCRGSPEQTLKYKWNEIRNGRLAMMAFLGFAAQYAATGKGPIDNLVDHVADPFHTTFVHNGVSVPFI
->5ai4_A mol:protein length:549  BIFUNCTIONAL EPOXIDE HYDROLASE 2
-GMTLRAAVFDLDGVLALPAVFGVLGRTEEALALPRGLLNDAFQKGGPEGATTRLMKGEITLSQWIPLMEENCRKCSETAKVCLPKNFSIKEIFDKAISARKINRPMLQAALMLRKKGFTTAILTNTWLDDRAERDGLAQLMCELKMHFDFLIESCQVGMVKPEPQIYKFLLDTLKASPSEVVFLDDIGANLKPARDLGMVTILVQDTDTALKELEKVTGIQLLNTPAPLPTSCNPSDMSHGYVTVKPRVRLHFVELGSGPAVCLCHGFPESWYSWRYQIPALAQAGYRVLAMDMKGYGESSAPPEIEEYCMEVLCKEMVTFLDKLGLSQAVFIGHDWGGMLVWYMALFYPERVRAVASLNTPFIPANPNMSPLESIKANPVFDYQLYFQEPGVAEAELEQNLSRTFKSLFRASDESVLSMHKVCEAGGLFVNSPEEPSLSRMVTEEEIQFYVQQFKKSGFRGPLNWYRNMERNWKWACKSLGRKILIPALMVTAEKDFVLVPQMSQHMEDWIPHLKRGHIEDCGHWTQMDKPTEVNQILIKWLDSDARN
->6vlz_A0 mol:protein length:218  28S ribosomal protein S34, mitochondrial
-MARKKVRPRLIAELARRVRALREQLNRPRDSQLYAVDYETLTRPFSGRRLPVRAWADVRRESRLLQLLGRLPLFGLGRLVTRKSWLWQHDEPCYWRLTRVRPDYTAQNLDHGKAWGILTFKGKTESEAREIEHVMYHDWRLVPKHEEEAFTAFTPAPEDSLASVPYPPLLRAMIIAERQKNGDTSTEEPMLNVQRIRMEPWDYPAKQEDKGRAKGTPV
->3j3q_eB mol:protein length:231  capsid protein
-PIVQNLQGQMVHQAISPRTLNAWVKVVEEKAFSPEVIPMFSALSEGATPQDLNTMLNTVGGHQAAMQMLKETINEEAAEWDRLHPVHAGPIEPGQMREPRGSDIAGTTSTLQEQIGWMTHNPPIPVGEIYKRWIILGLNKIVRMYSPTSILDIRQGPKEPFRDYVDRFYKTLRAEQASQEVKNWMTETLLVQNANPDCKTILKALGPAATLEEMMTACQGVGGPGHKARVL
->1c2y_H mol:protein length:156  PROTEIN (LUMAZINE SYNTHASE)
-MNELEGYVTKAQSFRFAIVVARFNEFVTRRLMEGALDTFKKYSVNEDIDVVWVPGAYELGVTAQALGKSGKYHAIVCLGAVVKGDTSHYDAVVNSASSGVLSAGLNSGVPCVFGVLTCDNMDQAINRAGGKAGNKGAESALTAIEMASLFEHHLKA
->7vfk_B mol:protein length:505  Glycosyl transferase, group 1 family protein
-SMNYFVGNSLGVNLTGIEKAIINRLNLFKEMGRPAQCVFLSWNRYLYRNAQNYITSSDYINMYDFFQEATYLERNEPFDWLSYWTDECHYTLKHVENSHDFRIYDQERFLMYAHFQDPKYRILDYVNHFDSQRRKVKRDFYDVRGFLSCSRILVDKQQTLCEFFYNPEGDTKLEKYFSYKDGKPEVQKIIVYYANKQYFFNNETELGAFFIKQLYQHGDLFFSDRNVYTAPIFNLTPESIPVVAVLHSTHIKNIDALDSSPFKNVYKAMFENLSRYRAIIVSTEQQKLDVEKRINHTIPVVNIPVGYSETIDTPVQTLDQRSVKLISVARYSPEKQLHQQIELIKRLVSYVPKIELHMYGFGSESKKLNELIQKYGLENHVYLRGFLSNLDQEYSDAYLSLITSNMEGFSLALLESLAHGVPVISYDIKYGPNELITSDFNGYLITKNDEDALFDKVKYVIDHPEVQQRLSKGSLAKAQQYSKASLIKQWDQFVRLILEHHHHHH
->5wns_L mol:protein length:124  30S ribosomal protein S12
-PTINQLVRKGREKVRKKSKVPALKGAPFRRGVCTVVRTVTPKKPNSALRKVAKVRLTSGYEVTAYIPGEGHNLQEHSVVLIRGGRVKXLPGVRYHIVRGVYDAAGVKDRKKSRSKYGTKKPKEA
->4wss_B mol:protein length:514  Hemagglutinin
-ADPGDKICIGYHANNSTTQVDTILEKNVTVTHSVELLETQKESRFCRVLNKAPLDLGDCTTEGWILGNPRCDKLLGDRSWSYIVERPDAQNGICYPGVLKEAEELKALIGSIDTIQRFEMFPKSTWTGVDTNSGVTSACTYNGGSSFYRNLLWIIKIRSDPYSLIKGTYTNTGSQSILYFWGVHHPPDDVEQANLYGLGTRYVRMGTESMNFAKGPEIADRPPANGQRGRIDYYWSVLKPGETLNVESNGNLIAPWYAYKFTSSRHKGAIFRSDLPIENCDAVCQTLTGAINTNKTFQNVSPIWIGECPKYVKSKSLKLATGLRNVPQVKTRGLFGAIAGFIEGGWTGMVDGWYGYHHENSQGSGYAADKESTQKAIDGITNKVNSIIDKMNTQFEAVEHEFSNLEKRISNLNKRMEDGFLDVWTYNAELLVLLENERTLDMHDANVKNLHEKVKSQLRDNAKDLGNGCFEFWHKCDNECINSVKNGTYNYPKYQEESRLNREEIKSGRLVPRG
->6ip5_2X mol:protein length:125  60S ribosomal protein L31
-MAPAKKGGEKKKGRSAINEVVTREYTINIHKRIHGVGFKKRAPRALKEIRKFAMKEMGTPDVRIDTRLNKAVWAKGIRNVPYRIRVRLSRKRNEDEDSPNKLYTLVTYVPVTTFKNLQTVNVDEN
->5lng_C mol:protein length:164  Putative Fml fimbrial adhesin FmlD
-FSCNVDGGSSIGAGTTSVYVNLDPVIQPGQNLVVDLSQHISCWNDYGGWYDTDHINLVQGSAFAGSLQSYKGSLYWNNVTYPFPLTTNTNVLDIGDKTPMPLPLKLYITPVGAAGGVVIKAGEVIARIHMYKIATLGSGNPRNFTWNIISNNSVVMPTHHHHHH
->6u42_Z0 mol:protein length:443  Tubulin beta
-MREIVHIQGGQCGNQIGAKFWEVVSDEHGIDPTGTYHGDSDLQLERINVYFNEATGGRYVPRAILMDLEPGTMDSVRSGPYGQIFRPDNFVFGQTGAGNNWAKGHYTEGAELIDSVLDVVRKEAESCDCLQGFQVCHSLGGGTGSGMGTLLISKIREEYPDRMMLTFSVVPSPKVSDTVVEPYNATLSVHQLVENADECMVLDNEALYDICFRTLKLTTPTFGDLNHLISAVMSGITCCLRFPGQLNADLRKLAVNLIPFPRLHFFMVGFTPLTSRGSQQYRALTVPELTQQMWDAKNMMCAADPRHGRYLTASALFRGRMSTKEVDEQMLNVQNKNSSYFVEWIPNNVKSSVCDIPPKGLKMSATFIGNSTAIQEMFKRVSEQFTAMFRRKAFLHWYTGEGMDEMEFTEAESNMNDLVSEYQQYQDASAEEEGEFEGEEEEA
->6htr_b mol:protein length:196  PROTEASOME SUBUNIT BETA TYPE-1
-TSIMAVTFKDGVILGADSRTTTGAYIANRVTDKLTRVHDKIWCCRSGSAADTQAIADIVQYHLELYTSQYGTPSTETAASVFKELCYENKDNLTAGIIVAGYDDKNKGEVYTIPLGGSVHKLPYAIAGSGSTFIYGYCDKNFRENMSKEETVDFIKHSLSQAIKWDGSSGGVIRMVVLTAAGVERLIFYPDEYEQL
->3loe_A mol:protein length:30  Neutrophil defensin 1
-ACYCRIPACIAGERRYGTCIYQGRLWAACC
->7o5h_K mol:protein length:117  30S ribosomal protein S11
-RKQVSDGVAHIHASFNNTIVTITDRQGNALGWATAGGSGFRGSRKSTPFAAQVAAERCADAVKEYGIKNLEVMVKGPGPGRESTIRALNAAGFRITNITDVTPIPHNGCRPPKKRRV
->4dsq_D mol:protein length:184  Peroxiredoxin type-2
-MGHHHHHHMSDLVNKKFPAGDYKFQYIAISQSDADSESCKMPQTVEWSKLISENKKVIITGAPAAFSPTCTVSHIPGYINYLDELVKEKEVDQVIVVTVDNPFANQAWAKSLGVKDTTHIKFASDPGCAFTKSIGFELAVGDGVYWSGRWAMVVENGIVTYAAKETNPGTDVTVSSVESVLAHL
->5nhk_B mol:protein length:140  Ferric uptake regulation protein
-MNSKNLDLKEFGFKVTQPRVEILKLFEKNKDKHLSPDDVFSKLKAQGSTTGIATVYRVLNQFESAGIINRLKLDNEQVMYELNQGEHHDHIICVKCNMIQEFYSPGIEALQKQIVESFGAEMIDYSLNIYVKCKSCREKI
->4gkf_A mol:protein length:169  CRISPR system Cmr subunit Cmr5
-MEVHMLSKDNKKSIRKTLEQRRGEYAYYVIKEVADLNDKQLEEKYASLVKKAPVMILSNGLLQTLAFLLAKAETSPEKANQILSRVNEYPPRFIEKLGNDKDEHLLLYLHIVYWLRENVDRNIDVKTLLSQDYSKVLWATKEAIALLNWMRRFAVAMLKEEGKENEGSS
->3sdj_B mol:protein length:448  Serine/threonine-protein kinase/endoribonuclease IRE1
-PEKKKRKRGSRGGKKGRKSRIANIPNFEQSLKNLVVSEKILGYGSSGTVVFQGSFQGRPVAVKRMLIDFCDIALMEIKLLTESDDHPNVIRYYCSETTDRFLYIALELCNLNLQDLVESKNVSDENLKLQKEYNPISLLRQIASGVAHLHSLKIIHRDLKPQNILVSTSSRFTADQQTGAENLRILISDFGLCKKLDSGQSSFRTNLNNPSGTSGWRAPELLEESTKRRLTRSIDIFSMGCVFYYILSKGKHPFGDKYSRESNIIRGIFSLDEMKCLHDRSLIAEATDLISQMIDHDPLKRPTAMKVLRHPLFWPKSKKLEFLLKVSDRLEIENRDPPSALLMKFDAGSDFVIPSGDWTVKFDKTFMDNLERYRKYHSSKLMDLLRALRNKYHNFMDLPEDIAELMGPVPDGFYDYFTKRFPNLLIGVYMIVKENLSDDQILREFLYS
->3oeb_A mol:protein length:144  S-layer associated multidomain endoglucanase
-MVNMVSNPGFEDGLDSWQDWQQDMSAVPEAAHNGALGLKIGGGKAAGGGQDIPLKPNTTYILGAWAKFDSKPAGTFDVVVQYHLKDANNTYVQHILNFNETDWTYKQLLFTTPDVFGSTPELALWKGDTSKANLYVDDVYLVEV
->6y5l_E mol:protein length:70  X-31 Influenza Haemagglutinin HA1,X-31 Influenza Haemagglutinin HA1
-AVPNGTLVKTITDDQIEVTNATELVCITPNGSIPNDKPFQNVNKITYGACPKYVKQNTLKLATGMRNVPE
->5den_A mol:protein length:453  Phenylalanine-4-hydroxylase
-MAAVVLENGVLSRKLSDFGQETSYIEDNSNQNGAISLIFSLKEEVGALAKVLRLFEENDINLTHIESRPSRLNKDEYEFFTYLDKRSKPVLGSIIKSLRNDIGATVHELSRDKEKNTVPWFPRTIQELDRFANQILSYGAELDADHPGFKDPVYRARRKQFADIAYNYRHGQPIPRVEYTEEEKQTWGTVFRTLKALYKTHACYEHNHIFPLLEKYCGFREDNIPQLEDVSQFLQTCTGFRLRPVAGLLSSRDFLGGLAFRVFHCTQYIRHGSKPMYTPEPDICHELLGHVPLFSDRSFAQFSQEIGLASLGAPDEYIEKLATIYWFTVEFGLCKEGDSIKAYGAGLLSSFGELQYCLSDKPKLLPLELEKTACQEYSVTEFQPLYYVAESFSDAKEKVRTFAATIPRPFSVRYDPYTQRVEVLDNTQQLKILADSINSEVGILCNALQKIKS
->7jsd_A mol:protein length:263  Lysine hydroxylase
-GPHMDVHEIDETLEKFLAENYTPERVQQLADRFQRTGFVKFDSHMRIVPEELITAVRAEADRLVREHKERRDLVLGTTGGTPRNLSVVKSQDVEQSDLIRAVTRSEVLLTFLAGITRERIIPEVSDDERYLITHQEFASDTHGWHWDDYSFAFNWALRMPPIASGGMVQAVPHTHWDKNAPRINETLCERQIDTYGLVSGDLYLLRSDTTMHRTVPLTEDGAVRTMLVVSWSAERDLGKVLTGNDRWWENPEAGAAQPVHRAG
->3hzo_B mol:protein length:293  protein Rv0554, putative Bromoperoxidase
-MSYYHHHHHHDYDIPTTENLYFQGAMDPEFRVINLAYDDNGTGDPVVFIAGRGGAGRTWHPHQVPAFLAAGYRCITFDNRGIGATENAEGFTTQTMVADTAALIETLDIAPARVVGVSMGAFIAQELMVVAPELVSSAVLMATRGRLDRARQFFNKAEAELYDSGVQLPPTYDARARLLENFSRKTLNDDVAVGDWIAMFSMWPIKSTPGLRCQLDCAPQTNRLPAYRNIAAPVLVIGFADDVVTPPYLGREVADALPNGRYLQIPDAGHLGFFERPEAVNTAMLKFFASVKA
->4whv_G mol:protein length:83  Polyubiquitin-B
-GPGYQDPMQIFVKTLTGKTITLEVEPSDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGG
->4ng3_D mol:protein length:335  5-carboxyvanillate decarboxylase
-SLRLIATEEAVTFQPVVDALRAHSRTDDASLDMILVRDVYGDEPARPAMIGRLSDVTGERLAEMDSNGVDMHLLSLTAPGVQMFDAETGTRLARIANDLMAQTVAANPTRFAGLGTFAPQDPASAAREIERVATQLRLNGLVINSHTNDLYYDDPFFHPVFEAIEASGLALYIHPRAPSKQIDRAFRDYGMNSAIWGYGIETSTNAVRMILSGLFDRFPRLKIVLGHMGEAIPFWLWRLDYMHGNATTFGGAPKLKLKPSEYFRRNFAITTSGVESHAALRYSIEVLGPENVMWAIDYPYQPMAPAVQFIRTAPIPEDVKAMVAGGNAARIFRIT
->7og4_0 mol:protein length:188  39S ribosomal protein L32, mitochondrial
-MALAMLVLVVSPWSAARGVLRNYWERLLRKLPQSRPGFPSPPWGPALAVQGPAMFTEPANDTSGSKENSSLLDSIFWMAAPKNRRTIEVNRCRRRNPQKLIKVKNNIDVCPECGHLKQKHVLCAYCYEKVCKETAEIRRQIGKQEGGPFKAPTIETVVLYTGETPSEQDQGKRIIERDRKRPSWFTQN
->7kbl_B mol:protein length:481  2-oxoglutarate carboxylase small subunit
-MKHHHHHHAMFKKVLVANRGEIACRVIRACKELGIQTVAIYNEIESTARHVKMADEAYMIGVNPLDTYLNAERIVDLALEVGAEAIHPGYGFLAENEHFARLCEEKGITFIGPHWKVIELMGDKARSKEVMKRAGVPTVPGSDGILKDVEEAKRIAKEIGYPVLLKASAGGGGRGIRICRNEEELVRNYENAYNEAVKAFGRGDLLLEKYIENPKHIEFQVLGDKYGNVIHLGERDCSIQRRNQKLVEIAPSLLLTPEQREYYGSLVVKAAKEIGYYSAGTMEFIADEKGNLYFIEMNTRIQVEHPVTEMITGVDIVKWQIRIAAGERLRYSQEDIRFNGYSIECRINAEDPKKGFAPSIGTIERYYVPGGFGIRVEHASSKGYEITPYYDSLIAKLIVWAPLWEVAVDRMRSALETYEISGVKTTIPLLINIMKDKDFRDGKFTTRYLEEHPHVFDYAEHRDKEDFVAFISAVIASYHGL
->3itu_D mol:protein length:345  cGMP-dependent 3',5'-cyclic phosphodiesterase
-GSAMDDEYTKLLHDGIQPVAAIDSNFASFTYTPRSLPEDDTSMAILSMLQDMNFINNYKIDCPTLARFCLMVKKGYRDPPYHNWMHAFSVSHFCYLLYKNLELTNYLEDIEIFALFISCMCHDLDHRGTNNSFQVASKSVLAALYSSEGSVMERHHFAQAIAILNTHGCNIFDHFSRKDYQRMLDLMRDIILATDLAHHLRIFKDLQKMAEVGYDRNNKQHHRLLLCLLMTSCDLSDQTKGWKTTRKIAELIYKEFFSQGDLEKAMGNRPMEMMDREKAYIPELQISFMEHIAMPIYKLLQDLFPKAAELYERVASNREHWTKVSHKFTIRGLPSNNSLDFLDEE
->7mt7_n mol:protein length:61  30S ribosomal protein S14 type Z
-MAKKALVNKAAGKPRFAVRAYTRCSKCGRPRAVYRKFGLCRICLREMAHAGELPGVQKSSW
->5xnl_2 mol:protein length:232  Chlorophyll a-b binding protein 8, chloroplastic
-RKSATTKKVASSGSPWYGPDRVKYLGPFSGESPSYLTGEFPGDYGWDTAGLSADPETFSKNRELEVIHSRWAMLGALGCVFPELLSRNGVKFGEAVWFKAGSQIFSEGGLDYLGNPSLVHAQSILAIWATQVILMGAVEGYRIAGGPLGEVVDPLYPGGSFDPLGLADDPEAFAELKVKELKNGRLAMFSMFGFFVQAIVTGKGPLENLADHLSDPVNNNAWSYATNFVPGK
->6cjn_B mol:protein length:225  Chalcone--flavonone isomerase 1
-GSHMAASITAITVENLEYPAVVTSPVTGKSYFLGGAGERGLTIEGNFIKFTAIGVYLEDIAVASLAAKWKGKSSEELLETLDFYRDIISGPFEKLIRTSKIRELSGPEYSRKVMENCVAHLKSVGTYGDAEAEAMQKFAEAFKPVNFPPGASVFYRQSPDGILGLSFSPDTSIPEKEAALIENKAVSSAVLETMIGEHAVSPDLKRCLAARLPALLNEGAFKIGN
->2d10_F mol:protein length:28  Ezrin-radixin-moesin binding phosphoprotein 50
-KERAHQKRSSKRAPQMDWSKKNELFSNL
->1xbp_D mol:protein length:180  50S ribosomal protein L5
-MQQLKTKYNDQVRPALMQQFGYSSVMAVPRIEKIVVNEGLGSSKEDSKAIDKAAKELALITLQKPIITKAKKSISNFKLRQGMPVGIKVTLRGERMYVFLEKLINIGLPRIRDFRGINPNAFDGRGNYNLGIKEQLIFPEITYDMVDKTRGMDITIVTTAKTDEEARALLQSMGLPFRKQ
->4y8m_R mol:protein length:260  Proteasome subunit alpha type-5
-MFLTRSEYDRGVSTFSPEGRLFQVEYSLEAIKLGSTAIGIATKEGVVLGVEKRATSPLLESDSIEKIVEIDRHIGCAMSGLTADARSMIEHARTAAVTHNLYYDEDINVESLTQSVCDLALRFGEGASGEERLMSRPFGVALLIAGHDADDGYQLFHAEPSGTFYRYNAKAIGSGSEGAQAELLNEWHSSLTLKEAELLVLKILKQVMEEKLDENNAQLSCITKQDGFKIYDNEKTAELIKELKEKEAAESPEEADVEMS
->6jvb_B mol:protein length:540  Dihydropyrimidinase-related protein 2
-MHHHHHHHMSYQGKKNIPRITSDRLLIKGGKIVNDDQSFYADIYMEDGLIKQIGENLIVPGGVKTIEAHSRMVIPGGIDVHTRFQMPDQGMTSADDFFQGTKAALAGGTTMIIDHVVPEPGTSLLAAFDQWREWADSKSCCDYSLHVDISEWHKGIQEEMEALVKDHGVNSFLVYMAFKDRFQLTDCQIYEVLSVIRDIGAIAQVHAENGDIIAEEQQRILDLGITGPEGHVLSRPEEVEAEAVNRAITIANQTNCPLYITKVMSKSSAEVIAQARKKGTVVYGEPITASLGTDGSHYWSKNWAKAAAFVTSPPLSPDPTTPDFLNSLLSCGDLQVTGSAHCTFNTAQKAVGKDNFTLIPEGTNGTEERMSVIWDKAVVTGKMDENQFVAVTSTNAAKVFNLYPRKGRIAVGSDADLVIWDPDSVKTISAKTHNSSLEYNIFEGMECRGSPLVVISQGKIVLEDGTLHVTEGSGRYIPRKPFPDFVYKRIKARSRLAELRGVPRGLYDGPVCEVSVTPKTVTPASSAKTSPAKQQAPPVR
->2pmp_A mol:protein length:160  2-C-methyl-D-erythritol 2,4-cyclodiphosphate synthase
-TLPFRIGHGFDLHRLEPGYPLIIGGIVIPHDRGCEAHSDGDVLLHCVVDAILGALGLPDIGQIFPDSDPKWKGAASSVFIKEAVRLMDEAGYEIGNLDATLILQRPKISPHKETIRSNLSKLLGADPSVVNLKAKTHEKVDSLGENRSIAAHTVILLMKK
->4lbp_A mol:protein length:100  5-chloro-2-hydroxyhydroquinone dehydrochlorinase (TftG)
-MLFLIYRKDRPGSLQVRIDNYAAHLAYLEPLKAKIQVGGPTLGAGTGTDDKDMTGSFLIMEAESWDEVHSFVENDPFTKAGLFAATIVERWKHGKHNDSK
->6jmq_D mol:protein length:219  Antibody
-DIVMSQSPSSLVVSVGEKVTMSCXXXXXXXXXXXXXXXXXWYQQKPGQSPKLLIYXXXXXXXGVPDRFTGSGSGTDFTLTISSVKAEDLAVYYCXXXXXXXXXFGGGTKLEIKRADAAPTVSIFPPSSEQLTSGGASVVCFLNNFYPKDINVKWKIDGSERQNGVLNSWTDQDSKDSTYSMSSTLTLTKDEYERHNSYTCEATHKTSTSPIVKSFNRNE
->5j46_A mol:protein length:189  Peptide deformylase
-MAHHHHHHMANAAHRFTEYRKTMALLNILHYPDKRLHKVAKPVDKVDDRIRKLVADMAETMYAAPGIGLAATQVDVHERVIVIDVSEDKNELRAFINPEIIWSSDGKQVYEEGCLSVPGIYDEVERPDRVRVRALNEQGETFELDCEGLLAVCIQHEMDHLMGRVFVEYLSPLKQSRIKTKMKKLERAM
->5pf4_A mol:protein length:138  Bromodomain adjacent to zinc finger domain protein 2B
-MHHHHHHSSGVDLGTENLYFQSMSVKKPKRDDSKDLALCSMILTEMETHEDAWPFLLPVNLKLVPGYKKVIKKPMDFSTIREKLSSGQYPNLETFALDVRLVFDNCETFNEDDSDIGRAGHNMRKYFEKKWTDTFKVS
->6zcd_V mol:protein length:95  Vascular endothelial growth factor A
-EVVKFMDVYQRSYCHPIETLVDIFQEYPDEIEYIFKPSCVPLMRCGGCCNDEGLECVPTEESNITMQIMRIKPHQGQHIGEMSFLQHNKCECRPK
->4zzc_B mol:protein length:317  Proton-gated ion channel
-GQDMVSPPPPIADEPLTVNTGIYLIECYSLDDKAETFKVNAFLSLSWKDRRLAFDPVRSGVRVKTYEPEAIWIPEIRFVNVENARDADVVDISVSPDGTVQYLERFSARVLSPLDFRRYPFDSQTLHIYLIVRSVDTRNIVLAVDLEKVGKNDDVFLTGWDIESFTAVVKPANFALEDRLESKLDYQLRISRQYFSYIPNIILPMLFILFISWTAFWSTSYEANVTLVVSTLIAHIAFNILVETNLPKTPYMTYTGAIIFMIYLFYFVAVIEVTVQHYLKVESQPARAASITRASRIAFPVVFLLANIILAFLFFGF
->5t0x_C mol:protein length:19  Estrogen receptor peptide
-RAANLWPSPLMIKRSKKNS
->6msb_d mol:protein length:349  26S proteasome non-ATPase regulatory subunit 8
-FIKGRAPRAPPRERRRATRGGLRQVVAPPRALGSTSRPHFRRASVCRRRCRKSGGLLAASRKMAAAAVNGAAGFSSSGPAATSGAVLQAATGMYEQLKGEWNRKSPNLSKCGEELGRLKLVLLELNFLPTTGTKLTKQQLILARDILEIGAQWSILRKDIPSFERYMAQLKCYYFDYKEQLPESAYMHQLLGLNLLFLLSQNRVAEFHTELERLPAKDIQTNVYIKHPVSLEQYLMEGSYNKVFLAKGNIPAESYTFFIDILLDTIRDEIAGCIEKAYEKILFTEATRILFFNTPKKMTDYAKKRGWVLGPNNYYSFASQQQKPEDTTIPSTELAKQVIEYARQLEMIV
->7o7y_Aq mol:protein length:135  40S ribosomal protein eS17
-MGRVRTKTVKKAARVIIEKYYTRLGNDFHTNKRVCEEIAIIPSKKLRNKIAGYVTHLMKRIQRGPVRGISIKLQEEERERRDNYVPEVSALDQEIIEVDPDTKEMLKLLDFGSLSNLQVTQPTVGMNFKTPRGAV
->1trs_A mol:protein length:105  THIOREDOXIN
-MVKQIESKTAFQEALDAAGDKLVVVDFSATWCGPCKMIKPFFHSLSEKYSNVIFLEVDVDDAQDVASEAEVKATPTFQFFKKGQKVGEFSGANKEKLEATINELV
->6zv6_I mol:protein length:208  40S ribosomal protein S8
-MGISRDNWHKRRKTGGKRKPYHKKRKYELGRPAANTKIGPRRIHTVRVRGGNKKYRALRLDVGNFSWGSECCTRKTRIIDVVYNASNNELVRTKTLVKNCIVLIDSTPYRQWYESHYALPLGRKKGAKLTPEEEEILNKKRSKKIQKKYDERKKNAKISSLLEEQFQQGKLLACIASRPGQCGRADGYVLEGKELEFYLRKIKARKGK
->3nff_D mol:protein length:121  RNA polymerase I subunit A34.5
-MGYQPPSDYKQCKHLKSFPVSELKGDNKELWLMKVPANIDISQLKSLPLDTDATVSTVELGSKNFNVLQNTSTQEGSDNTNLSLLIPSEKKKETLKVATSKDNKSVYFDRVFTISETARIP
->7lus_B mol:protein length:207  Immunoglobulin heavy constant gamma 2
-GPSVFLFPPKPKDTLMISRTPEVTCVVVDVSHEDPEVQFNWYVDGVEVHNAKTKPREEQFNSTFRVVSVLTVVHQDWLNGKEYKCKVSNKGLPAPIEKTISKTKGQPREPQVYTLPPSREEMTKNQVSLTCLVKGFYPSDIAVEWESNGQPENNYDTTPPMLDSDGSFFLYSDLTVDKSRWQQGNVFSCSVMHEALHNHYTQKSLSL
->5t15_E mol:protein length:4676  Ryanodine receptor 1,Ryanodine receptor 1,Ryanodine receptor 1,Ryanodine receptor 1,Ryanodine receptor 1,Ryanodine receptor 1,Ryanodine receptor 1
-QFLRTDDEVVLQCSATVLKEQLKLCLAAEGFGNRLCFLEPTSNAQNVPPDLAICCFTLEQSLSVRALQEMLANTVEAGVESSQGGGHRTLLYGHAILLRHAHSRMYLSCLTTSRSMTDKLAFDVGLQEDATGEACWWTMHPASKQRSEGEKVRVGDDLILVSVSSERYLHLSTASGELQVDASFMQTLWNMNPICSCCEEGYVTGGHVLRLFHGHMDECLTISAADSDDQRRLVYYEGGAVCTHARSLWRLEPLRISWSGSHLRWGQPLRIRHVTTGRYLALTEDQGLVVVDACKAHTKATSFCFRVSKEKLDTAPKRDVEGMGPPEIKYGESLCFVQHVASGLWLTYAAPDPKALRLGVLKKKAILHQEGHMDDALFLTRCQQEESQAARMIHSTAGLYNQFIKGLDSFSGKPRGSGPPAGPALPIEAVILSLQDLIGYFEPPSEELQHEEKQSKLRSLRNRQSLFQEEGMLSLVLNCIDRLNVYTTAAHFAEYAGEEAAESWKEIVNLLYELLASLIRGNRANCALFSTNLDWVVSKLDRLEASSGILEVLYCVLIESPEVLNIIQENHIKSIISLLDKHGRNHKVLDVLCSLCVCNGVAVRSNQDLITENLLPGRELLLQTNLINYVTSIRPNIFVGRAEGSTQYGKWYFEVMVDEVVPFLTAQATHLRVGWALTEGYSPYPGGGEGWGGNGVGDDLYSYGFDGLHLWTGHVARPVTSPGQHLLAPEDVVSCCLDLSVPSISFRINGCPVQGVFEAFNLDGLFFPVVSFSAGVKVRFLLGGRHGEFKFLPPPGYAPCHEAVLPRERLRLEPIKEYRREGPRGPHLVGPSRCLSHTDFVPCPVDTVQIVLPPHLERIREKLAENIHELWALTRIEQGWTYGPVRDDNKRLHPCLVNFHSLPEPERNYNLQMSGETLKTLLALGCHVGMADEKAEDNLKKTKLPKTYMMSNGYKPAPLDLSHVRLTPAQTTLVDRLAENGHNVWARDRVAQGWSYSAVQDIPARRNPRLVPYRLLDEATKRSNRDSLCQAVRTLLGYGYNIEPPDQEPSQVENQSRWDRVRIFRAEKSYTVQSGRWYFEFEAVTTGEMRVGWARPELRPDVELGADELAYVFNGHRGQRWHLGSEPFGRPWQSGDVVGCMIDLTENTIIFTLNGEVLMSDSGSETAFREIEIGDGFLPVCSLGPGQVGHLNLGQDVSSLRFFAICGLQEGFEPFAINMQRPVTTWFSKSLPQFEPVPPEHPHYEVARMDGTVDTPPCLRLAHRXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXMPLSAAMFLSERKNPAPQCPPRLEVQMLMPVSWSRMPNHFLQVETRRAGERLGWAVQCQDPLTMMALHIPEENRCMDILELSERLDLQRFHSHTLRLYRAVCALGNNRVAHALCSHVDQAQLLHALEDAHLPGPLRAGYYDLLISIHLESACRSRRSMLSEYIVPLTPETRAITLFPPGRKGGNARRHGLPGVGVTTSLRPPHHFSPPCFVAALPAAGVAEAPARLSPAIPLEALRDKALRMLGEAVRDGGQHARDPVGGSVEFQFVPVLKLVSTLLVMGIFGDEDVKQILKMIEPEVFTEEEEEEEEEEEEEEEEEEDEEEKEEDEEEEEKEDAEKEEEEAPEGEKEDLEEGLLQMKLPESVKLQMCNLLEYFCDQELQHRVESLAAFAERYVDKLQANQRSRYALLMRAFTMSAAETARRTREFRSPPQEQINMLLHFKDEADEEDCPLPEDIRQDLQDFHQDLLAHCGIQLEGEEEEPEEETSLSSRLRSLLETVRLVKKKEEKPEEELPAEEKKPQSLQELVSHMVVRWAQEDYVQSPELVRAMFSLLHRQYDGLGELLRALPRAYTISPSSVEDTMSLLECLGQIRSLLIVQMGPQEENLMIQSIGNIMNNKVFYQHPNLMRALGMHETVMEVMVNVLGGGETKEIRFPKMVTSCCRFLCYFCRISRQNQRSMFDHLSYLLENSGIGLGMQGSTPLDVAAASVIDNNELALALQEQDLEKVVSYLAGCGLQSCPMLLAKGYPDIGWNPCGGERYLDFLRFAVFVNGESVEENANVVVRLLIRKPECFGPALRGEGGSGLLAAIEEAIRISEDPARDGPGVRRDRRREHFGEEPPEENRVHLGHAIMSFYAALIDLLGRCAPEMHLIQAGKGEALRIRAILRSLVPLDDLVGIISLPLQIPTLXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXNFDPRPVETLNVIIPEKLDSFINKFAEYTHEKWAFDKIQNNWSYGENVDEELKTHPMLRPYKTFSEKDKEIYRWPIKESLKAMIAWEWTIEKAREGEEERTEKKKTRKISQTAQTYDPREGYNPQPPDLSGVTLSRELQAMAEQLAENYHNTWGRKKKQELEAKGGGTHPLLVPYDTLTAKEKARDREKAQELLKFLQMNGYAVTRXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXTPLYNLPTHRACNMFLESYKAAWILTEDHSFEDRMIDDLSKAGEQEEEEEEVEEKKPDPLHQLVLHFSRTALTEKSKLDEDYLYMAYADIMAKSCHLEEGGENGEAEEEEVEVSFEEKEMEKQRLLYQQSRLHTRGAAEMVLQMISACKGETGAMVSSTLKLGISILNGGNAEVQQKMLDYLKDKKEVGFFQSIQALMQTCSVLDLNAFERQNKAEGLGMVNEDGTVINRQNGEKVMADDEFTQDLFRFLQLLCEGHNNDFQNYLRTQTGNTTTINIIICTVDYLLRLQESISDFYWYYSGKDVIEEQGKRNFSKAMSVAKQVFNSLTEYIQGPCTGNQQSLAHSRLWDAVVGFLHVFAHMMMKLAQDSSQIELLKELLDLQKDMVVMLLSLLEGNVVNGMIARQMVDMLVESSSNVEMILKFFDMFLKLKDIVGSEAFQDYVTDPRGLISKKDFQKAMDSQKQFTGPEIQFLLSCSEADENEMINFEEFANRFQEPARDIGFNVAVLLTNLSEHVPHDPRLRNFLELAESILEYFRPYLGRIEIMGASRRIERIYFEISETNRAQWEMPQVKESKRQFIFDVVNEGGEAEKMELFVSFCEDTIFEMQIAAQISEPEGEPEADEDEGMGEAAAEGAEEGAAGAEGAAGTVAAGATARLAAAAARALRGLSYRSLRRRVRRLRRLTAREAATALAALLWAVVARAGAAGAGAAAGALRLLWGSLFGGGLVEGAKKVTVTELLAGMPDPTSDEVHGEQPAGPGGDADGAGEGEGEGDAAEGDGDEEVAGHEAGPGGAEGVVAVADGGPFRPEGAGGLGDMGDTTPAEPPTPEGSPILKRKLGVDGEEEELVPEPEPEPEPEPEKADEENGEKEEVPEAPPEPPKKAPPSPPAKKEEAGGAGMEFWGELEVQRVKFLNYLSRNFYTLRFLALFLAFAINFILLFYKVSDSPPGEDDMEGSAAGDLAGAGSGGGSGWGSGAGEEAEGDEDENMVYYFLEESTGYMEPALWCLSLLHTLVAFLCIIGYNCLKVPLVIFKREKELARKLEFDGLYITEQPGDDDVKGQWDRLVLNTPSFPSNYWDKFVKRKVLDKHGDIFGRERIAELLGMDLASLEITAHNERKPDPPPGLLTWLMSIDVKYQIWKFGVIFTDNSFLYLGWYMVMSLLGHYNNFFFAAHLLDIAMGVKTLRTILSSVTHNGKQLVMTVGLLAVVVYLYTVVAFNFFRKFYNKSEDEDEPDMKCDDMMTCYLFHMYVGVRAGGGIGDEIEDPAGDEYELYRVVFDITFFFFVIVILLAIIQGLIIDAFGELRDQQEQVKEDMETKCFICGIGSDYFDTTPHGFETHTLEEHNLANYMFFLMYLINKDETEHTGQESYVWKMYQERCWDFFPAGDCFRKQYEDQLS
->2isc_A mol:protein length:239  purine nucleoside phosphorylase
-ATPHNSAQVGDFAETVLMCGDPLRAKLIAETYLENPKLVNNVRGIQGYTGTYKGKPISVMGHGMGLPSICIYAEELYSTYKVKTIIRVGTCGAIDMDIHTRDIVIFTSAGTNSKINRIRFMDHDYPATASFDVVCALVDAAKELNIPAKVGKGFSTDLFYNPQTELAQLMNKFHFLAVEMESAGLFPIADLYGARAGCICTVSDHILHHEETTAEERQNSFQNMMKIALEAAIKLHHHH
->4kzx_b mol:protein length:84  40S ribosomal protein S27
-MPLAKDLLHPSPEEEKRKHKKKRLVQSPNSYFMDVKCPGCYKITTVFSHAQTVVLCVGCSTVLCQPTGGKARLTEGCSFRRKQH
->1y5k_A mol:protein length:141  Hemoglobin alpha chain
-VLSPADKTNVKAAWGKVGAHAGEYGAEALERMFLSFPTTKTYFPHFDLSHGSAQVKGHGKKVADALTNAVAHVDDMPNALSALSDLHAHKLRVDPVNFKLLSHCLLVTLAAHLPAEFTPAVHASLDKFLASVSTVLTSKYR
->3ddo_D mol:protein length:253  Uridine phosphorylase
-MSKSDVFHLGLTKNDLQGAQLAIVPGDPERVEKIAALMDKPVKLASHREFTSWRAELDGKAVIVCSTGIGGPSTSIAVEELAQLGIRTFLRIGTTGAIQPHINVGDVLVTTASVRLDGASLHFAPMEFPAVADFACTTALVEAAKSIGATTHVGVTASSDTFYPGQERYDTYSGRVVRRFKGSMEEWQAMGVMNYEMESATLLTMCASQGLRAGMVAGVIVNRTQQEIPNAETMKQTESHAVKIVVEAARRLL
->2klw_C mol:protein length:32  (POG)10
-XPPGPPGPPGPPGPPGPPGPPGPPGPPGPPGX
->6qml_B mol:protein length:76  Polyubiquitin-B
-LQIFVKTLTGKTITLEVEPSDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGG
->6s1v_A mol:protein length:114  Gag-Pro-Pol polyprotein
-WVQPITCQKPSLTLWLDDKMFTGLINTGADVTIIKLEDWPPNWPITDTLTNLRGIGQSNNPKQSSKYLTWRDKENNSGLIKPFVIPNLPVNLWGRDLLSQMKIMMCSPNDIVTA
->6cbe_X mol:protein length:736  Capsid protein VP1
-MAADGYLPDWLEDTLSEGIRQWWKLKPGPPPPKPAERHKDDSRGLVLPGYKYLGPFNGLDKGEPVNEADAAALEHDKAYDRQLDSGDNPYLKYNHADAEFQERLKEDTSFGGNLGRAVFQAKKRVLEPLGLVEEPVKTAPGKKRPVEHSPVEPDSSSGTGKAGQQPARKRLNFGQTGDADSVPDPQPLGQPPAAPSGLGTNTMATGSGAPMADNNEGADGVGNSSGNWHCDSTWMGDRVITTSTRTWALPTYNNHLYKQISSASTGASNDNHYFGYSTPWGYFDFNRFHCHFSPRDWQRLINNNWGFRPKRLNFKLFNIQVKEVTQNDGTTTIANNLTSTVQVFTDSEYQLPYVLGSAHQGCLPPFPADVFMVPQYGYLTLNNGSQAVGRSSFYCLEYFPSQMLRTGNNFTFSYTFEDVPFHSSYAHSQSLDRLMNPLIDQYLYYLSRTNTPSGTTTQSRLQFSQAGASDIRDQSRNWLPGPCYRQQRVSKTSADNNNSEYSWTGATKYHLNGRDSLVNPGPAMASHKDDEEKFFPQSGVLIFGKQGSEKTNVDIEKVMITDEEEIRTTNPVATEQYGSVSTNLQRGNRQAATADVNTQGVLPGMVWQDRDVYLQGPIWAKIPHTDGHFHPSPLMGGFGLKHPPPQILIKNTPVPANPSTTFSAAKFASFITQYSTGQVSVEIEWELQKENSKRWNPEIQYTSNYAKSANVDFTVDNNGVYSEPRPIGTRYLTRNL
->2ide_E mol:protein length:157  Molybdenum cofactor biosynthesis protein C
-MDLTHFQDGRPRMVDVTEKPETFRTATAEAFVELTEEALSALEKGGVGKGDPLVVAQLAGILAAKKTADLIPLCHPLPLTGVEVRVELLKAEKRVRIEATVKTKAETGVEMEAMTACAVAALTVYDMLKAASKGLVISQVRLLHKAGGKSGEWRREQ
->7f27_D mol:protein length:408  3-oxoacyl-(Acyl-carrier-protein) synthase
-MKRVVVTGMAGITSLGETADDIFARFEAGKSGIRYMPEWEQYVDLRTKLAGPVETFHIPKHFNRKVTRGMGRVALMSVVCAETALQNAGLLGHEILSSGEAGVAFGSSAGSVDAVGEFASMLLHQSMSKINATTYIRMMAHTSAVNMTVYFGLKGLTLPTSSACTSGSMAIGQAYEAIKYGKQQVMIAGGAEELSAAGAAVFDVLFATSGMNDQPEKTPRPFDAKRDGLVIGEGAGCLILEEYEHAKARGAHIYAEVIGYGSNTDGQHVTRPESEMMGRCMELALKDASVEAKDIAYVNAHGTSTDQGDVAESQATAKVLGYKPISSLKSYFGHTLGACGAIEAWLSIEMMNRGRFIPTLNLDEIDSLCGELDYIVQQPRNLDADIIMSNNFAFGGINTSLIFKRVKQ
->3fi2_A mol:protein length:353  Mitogen-activated protein kinase 10
-MSKSKVDNQFYSVEVGDSTFTVLKRYQNLKPIGSGAQGIVCAAYDAVLDRNVAIKKLSRPFQNQTHAKRAYRELVLMKCVNHKNIISLLNVFTPQKTLEEFQDVYLVMELMDANLCQVIQMELDHERMSYLLYQMLCGIKHLHSAGIIHRDLKPSNIVVKSDCTLKILDFGLARTAGTSFMMTPYVVTRYYRAPEVILGMGYKENVDIWSVGCIMGEMVRHKILFPGRDYIDQWNKVIEQLGTPCPEFMKKLQPTVRNYVENRPKYAGLTFPKLFPDSLFPADSEHNKLKASQARDLLSKMLVIDPAKRISVDDALQHPYINVWYXXXXXXDEREHTIEEWKELIYKEVMNSE
->4p18_G mol:protein length:176  Ferritin, middle subunit
-MVSQVRQNYHSDCEAAVNRMLNLELYASYTYSSMYAFFDRDDVALHNVAEFFKEHSHEEREHAEKFMKYQNKRGGRVVLQKIKKPERDEWGNTLEAMQAALQLEKTVNQALLDLHKLATDKVDPHLCDFLESEYLEEQVKDIKRIGDFITNLKRLGLPENGMGEYLFDKHSVKESS
->4lb1_D mol:protein length:30  Neutrophil defensin 1
-ACYCRIPACIAGERRAGTCIYQGRLWAACC
->6unz_H mol:protein length:604  fumarate hydratase 2
-MGSSHHHHHHSSGLVPRGSHMASMTGGQQMGRGSEFMSLCDQCEIGCRRVGIKDIEDASAVNADFHFSAIFQPTDPHHHQTEFAKVEGSEKYVEEVEVFGRQALKVNPEALTILAHRAFSDVHHFFRKDHLEGWRRAIEDPEASDNDRYVATTLLKNACIAAGRVLPSCQDTGTAIVLGKRGELCWTGGEDEKYLSKGIWNAYRYHNLRYSQTAALDMFKECNTGDNLPAQLDLLAVPGSDYEFLFIAKGGGSANKAYLYQETKALLNPKSLRAFIEEKLKTLGTAACPPYHIALVIGGTSAEMTMKTVKLASCRYYDSLPTTGDKYGRAFRDPEWEKIVMEVAQKSGIGAQFGGKYFAHQARVIRLPRHGASCPVGLAVSCSADRQILAHINKSGIYIEQLEQNPAQYLPDIPEVHLSTTSVKVDLKRPIDKVRQQLSQYPVGTRVMLNGTLIVARDIAHAKIKEMMDNGEPLPEYMKTSPIYYAGPAKTPEGYASGSFGPTTAGRMDSYVDLFQSHGGSYITLAKGNRSKQVTDACKKHGGFYLGSIGGPAAILAKDSIKQVTCLAFPELGMEAVWKIEVEDFPAFIVVDDKGNDMYSKTLA
->7emd_A mol:protein length:275  Leucocyte antigen
-GPHSLSYFYTAVSRPDRGDSRFIAVGYVDDTQFVRFDSDAPNPRMEPRAPWIQQEGQDYWDRETRKQRDTSQTYRVGLKNLRGYYNQSEAGSHTYQSMYGCYLGPDGLLLRGYRQYAYDGADYIALNEDLRSWTAADTAAQITKRKWETANVAERRRSYLQGLCVESLREYLEMGKDTLQRAEPPKTHVTRHPSSDLGVTLRCWALGFYPKEISLTWQREGQDQSQDMELVETRPSGDGTFQKWAALVVPPGEEQSYTCHVQHEGLQEPLTLRWD
->7sym_K mol:protein length:194  uS4
-MPVARSWVCRKTYVTPRRPFEKSRLDQELKLIGEYGLRNKREVWRVKFTLAKIRKAARELLTLDEKDPRRLFEGNALLRRLVRIGVLDEGKMKLDYILGLKIEDFLERRLQTQVFKLGLAKSIHHARVLIRQRHIRVRKQVVNIPSFIVRLDSQKHIDFSLRSPYGGGRPGRVKRKNAKKGQGGAGAGDDEEED
->2n8n_A mol:protein length:72  Translation initiation factor IF-1
-MAKQDVIELEGTVLDTLPNAMFKVELENGHEILAHVSGKIRMNYIRILPGDKVTVEMSPYDLTRGRITYRYK
->6v8z_O mol:protein length:231  VRC03 Fab Heavy Chain
-QVQLVQSGAVIKTPGSSVKISCRASGYNFRDYSIHWVRLIPDKGFEWIGWIKPLWGAVSYARQLQGRVSMTRQLSQDPDDPDWGVAYMEFSGLTPADTAEYFCVRRGSCDYCGDFPWQYWCQGTVVVVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEPK
->5nqv_H mol:protein length:11  EAR motif of IAA27
-TELRLGLPGSE
->2fzd_A mol:protein length:316  aldose reductase
-MASRILLNNGAKMPILGLGTWKSPPGQVTEAVKVAIDVGYRHIDCAHVYQNENEVGVAIQEKLREQVVKREELFIVSKLWCTYHEKGLVKGACQKTLSDLKLDYLDLYLIHWPTGFKPGKEFFPLDESGNVVPSDTNILDTWAAMEELVDEGLVKAIGISNFNHLQVEMILNKPGLKYKPAVNQIECHPYLTQEKLIQYCQSKGIVVTAYSPLGSPDRPWAKPEDPSLLEDPRIKAIAAKHNKTTAQVLIRFPMQRNLVVIPKSVTPERIAENFKVFDFELSSQDMTTLLSYNRNWRVCALLSCTSHKDYPFHEEF
->4x0g_D mol:protein length:109  Blastoderm-specific gene 25A
-PMVTIGPNGTEVSRISLSAINWAMTGPSITRKLLCEIFDRDTLAHHTLSGKPSPAFRDCARPSKQQLDPLKVADLVYLMTNSCDMTPREVRTAITTKCADENKMLRSRM
->6cxa_C mol:protein length:209  Chimeric T cell antigen receptor alpha chain Va14,Va24,Ja18
-MKTQVEQSPQSLVVRQGENCVLQCNYSVTPDNHLRWFKQDTGKGLVSLTVLVDQKDKTSNGRYSATLDKDAKHSTLHITATLLDDTATYICVVGDRGSALGRLHFGAGTQLIVIPDIQNPDPAVYQLRDSKSSDKSVCLFTDFDSQTNVSQSKDSDVYITDKCVLDMRSMDFKSNSAVAWSNKSDFACANAFNNSIIPEDTFFPSPESS
->5y6p_z6 mol:protein length:177  R-phycoerythrin beta chain
-MLDAFSRVVVNSDSKAAYVGGSDLQSLKTFISDGNKRLDAVNCIVSNASCIVSDAISGMICENPGLIAPGGNCYTNRRMAACLRDGEIILRYVSYALLAGDSSVLDDRCLNGLKETYIALGVPTASTSRAVSIMKAASTAFIMNTASGRKIEIAAGDCQALQSEAAAYFDKVGSAVD
->4r8o_B mol:protein length:104  Uncharacterized protein
-GGNPGDNLIYNAEEVNGVVVSETIFKMEGTMLTNYMKHNYKYDANNQRTEDEAQKWNSNKNRWENNLCIRYTYGNKSMTTEYYKWNSKKKEYILVPEMTVTMDK
->2big_B mol:protein length:361  PHOSPHOSERINE AMINOTRANSFERASE
-MVKQVFNFNAGPSALPKPALERAQKELLNFNDTQMSVMELSHRSQSYEEVHEQAQNLLRELLQIPNDYQILFLQGGASLQFTMLPMNLLTKGTIGNYVLTGSWSEKALKEAKLLGETHIAASTKANSYQSIPDFSEFQLNENDAYLHITSNNTIYGTQYQNFPEINHAPLIADMSSDILSRPLKVNQFGMIYAGAQKNLGPSGVTVVIVKKDLLNTKVEQVPTMLQYATHIKSDSLYNTPPTFSIYMLRNVLDWIKDLGGAEAIAKQNEEKAKIIYDTIDESNGFYVGHAEKGSRSLMNVTFNLRNEELNQQFLAKAKEQGFVGLNGHRSVGGCRASIYNAVPIDACIALRELMIQFKENA
->1dmx_A mol:protein length:248  MURINE CARBONIC ANHYDRASE V
-CATGTRQSPINIQWKDSVYDPQLAPLRVSYDAASCRYLWNTGYFFQVEFDDSCEDSGISGGPLGNHYRLKQFHFHWGATDEWGSEHAVDGHTYPAELHLVHWNSTKYENYKKASVGENGLAVIGVFLKLGAHHQALQKLVDVLPEVRHKDTQVAMGPFDPSCLMPACRDYWTYPGSLTTPPLAESVTWIVQKTPVEVSPSQLSMFRTLLFSGRGEEEDVMVNNYRPLQPLRDRKLRSSFRLDRTKMRS
->6u42_Z7 mol:protein length:451  Tubulin alpha
-MREVISIHIGQAGIQVGNACWELYCLEHGIQPDGQMPSDKTIGGGDDAFNTFFSETGAGKHVPRCIFLDLEPTVVDEVRTGTYRQLFHPEQLISGKEDAANNFARGHYTIGKEIVDLALDRIRKLADNCTGLQGFLVFNAVGGGTGSGLGSLLLERLSVDYGKKSKLGFTVYPSPQVSTAVVEPYNSVLSTHSLLEHTDVAVMLDNEAIYDICRRSLDIERPTYTNLNRLIAQVISSLTASLRFDGALNVDITEFQTNLVPYPRIHFMLSSYAPIISAEKAYHEQLSVAEITNAAFEPASMMVKCDPRHGKYMACCLMYRGDVVPKDVNASVATIKTKRTIQFVDWCPTGFKCGINYQPPTVVPGGDLAKVQRAVCMISNSTAIGEIFSRLDHKFDLMYAKRAFVHWYVGEGMEEGEFSEAREDLAALEKDFEEVGAESAEGAGEGEGEEY
->3oda_H mol:protein length:116  Poly [ADP-ribose] polymerase 1
-MGSSHHHHHHSSGLVPRGSHMAESSDKLYRVEYAKSGRASCKKCSESIPKDSLRMAIMVQSPMFDGKVPHWYHFSCFWKVGHSIRHPDVEVDGFSELRWDDQQKVKKTAEAGGVTG
->3kaq_A mol:protein length:147  Flavodoxin
-SKVLILFGSSTGNTESIAQKLEELVAAGGHEVTLLNAAEASADNLADGYDAVLMGCSAWGMEDLELQDDFAPLFDEMENMGLKGKKLAAFASGDMEYEHYCGAVPAIEEKARGLGAEVICEGLKIEGDASSDPDAVSAFAEDVLKKL
->5xxb_c mol:protein length:120  Ribosomal protein eL31
-MKGTTRKAQNKSLQPVCRDYTIHLHKLIHGIQFKKRAPRALREIRRFAQKTMHTKDVRIDTKLNKFIWSGGIRNVPRRVRVRIARRRNDDEDSKEKFYTLVQHVPVASFENLKTEYVNEE
->2j57_B mol:protein length:105  AMICYANIN
-DKATIPSESPFAAAEVADGAIVVDIAKMKYETPELHVKVGDTVTWINREAMPHNVHFVAGVLGEAALKGPMMKKEQAYSLTFTEAGTYDYHCTPHPFMRGKVVVE
->6y2l_SV mol:protein length:83  40S ribosomal protein S21
-MQNDAGEFVDLYVPRKCSASNRIIGAKDHASIQMNVAEVDKVTGRFNGQFKTYAICGAIRRMGESDDSILRLAKADGIVSKNF
->7vxc_A mol:protein length:1261  Spike glycoprotein
-MFVFLVLLPLVSSQCVNLTTRTQLPPAYTNSFTRGVYYPDKVFRSSVLHSTQDLFLPFFSNVTWFHAIHVSGTNGTKRFDNPVLPFNDGVYFASTEKSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCEFQFCNDPFLDVYYHKNNKSWMKSEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLREFVFKNIDGYFKIYSKHTPINLVRDLPQGFSALEPLVDLPIGINITRFQTLLALHRSYLTPGDSSSGWTAGAAAYYVGYLQPRTFLLKYNENGTITDAVDCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESIVRFPNITNLCPFGEVFNATRFASVYAWNRKRISNCVADYSVLYNSASFSTFKCYGVSPTKLNDLCFTNVYADSFVIRGDEVRQIAPGQTGKIADYNYKLPDDFTGCVIAWNSNNLDSKVGGNYNYRYRLFRKSNLKPFERDISTEIYQAGSTPCNGVQGFNCYFPLQSYGFQPTNGVGYQPYRVVVLSFELLHAPATVCGPKKSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFGRDIADTTDAVRDPQTLEILDITPCSFGGVSVITPGTNTSNQVAVLYQGVNCTEVPVAIHADQLTPTWRVYSTGSNVFQTRAGCLIGAEHVNNSYECDIPIGAGICASYQTQTNSRGSASSVASQSIIAYTMSLGAENSVAYSNNSIAIPTNFTISVTTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLNRALTGIAVEQDKNTQEVFAQVKQIYKTPPIKDFGGFNFSQILPDPSKPSKRSFIEDLLFNKVTLADAGFIKQYGDCLGDIAARDLICAQKFNGLTVLPPLLTDEMIAQYTSALLAGTITSGWTFGAGAALQIPFAMQMAYRFNGIGVTQNVLYENQKLIANQFNSAIGKIQDSLSSTASALGKLQDVVNQNAQALNTLVKQLSSNFGAISSVLNDILSRLDPPEAEVQIDRLITGRLQSLQTYVTQQLIRAAEIRASANLAATKMSECVLGQSKRVDFCGKGYHLMSFPQSAPHGVVFLHVTYVPAQEKNFTTAPAICHDGKAHFPREGVFVSNGTHWFVTQRNFYEPQIITTDNTFVSGNCDVVIGIVNNTVYDPLQPELDSFKEELDKYFKNHTSPDVDLGDISGINASVVNIQKEIDRLNEVAKNLNESLIDLQELGKYEQGSGYIPEAPRDGQAYVRKDGEWVLLSTFLENLYFQGDYKDDDDKHHHHHHHHH
->6yam_f mol:protein length:71  ribosomal protein eS31
-KKSYTTPKKNKHKRKKVKLAVLKYYKVDENGKISRLRRECPSDECGAGVFMASHFDRHYCGKCCLTYCFNK
->2fvv_A mol:protein length:194  Diphosphoinositol polyphosphate phosphohydrolase 1
-MHHHHHHSSGVDLGTENLYFQSMMKLKSNQTRTYDGDGYKKRAACLCFRSESEEEVLLVSSSRHPDRWIVPGGGMEPEEEPSVAAVREVCEEAGVKGTLGRLVGIFENQERKHRTYVYVLIVTEVLEDWEDSVNIGRKREWFKIEDAIKVLQYHKPVQASYFETLRQGYSANNGTPVVATTYSVSAQSSMSGIR
->4fna_C mol:protein length:280  Ferric hydroxamate receptor 2
-GSNNKAETKSYKMDDGKTVDIPKDPKRIAVVAPTYAGGLKKLGANIVAVNQQVDQSKVLKDKFKGVTKIGDGDVEKVAKEKPDLIIVYSTDKDIKKYQKVAPTVVVDYNKHKYLEQQEMLGKIVGKEDKVKAWKKDWEETTAKDGKEIKKAIGQDATVSLFDEFDKKLYTYGDNWGRGGEVLYQAFGLKMQPEQQKLTAKAGWAEVKQEEIEKYAGDYIVSTSEGKPTPGYESTNMWKNLKATKEGHIVKVDAGTYWYNDPYTLDFMRKDLKEKLIKAAK
->3zw8_A mol:protein length:742  PEROXISOMAL BIFUNCTIONAL ENZYME
-MGSSHHHHHHSSGLVPRGSHMAEYLRLPHSLAMIRLCNPPVNAVSPTVIREVRNGLQKAGSDHTVKAIVICGANGNFCAGADIHGFSAFTPGLALGSLVDEIQRYQKPVLAAIQGVALGGGLELALGCHYRIANAKARVGLPEVTLGILPGARGTQLLPRVVGVPVALDLITSGKYLSADEALRLGILDAVVKSDPVEEAIKFAQKIIDKPIEPRRIFNKPVPSLPNMDSVFAEAIAKVRKQYPGVLAPETCVRSIQASVKHPYEVGIKEEEKLFMYLRASGQAKALQYAFFAEKSANKWSTPSGASWKTASAQPVSSVGVLGLGTMGRGIAISFARVGISVVAVESDPKQLDAAKKIITFTLEKEASRAHQNGQASAKPKLRFSSSTKELSTVDLVVEAVFEDMNLKKKVFAELSALCKPGAFLCTNTSALNVDDIASSTDRPQLVIGTHFFSPAHVMRLLEVIPSRYSSPTTIATVMSLSKKIGKIGVVVGNCYGFVGNRMLAPYYNQGFFLLEEGSKPEDVDGVLEEFGFKMGPFRVSDLAGLDVGWKIRKGQGLTGPSLPPGTPVRKRGNSRYSPLGDMLCEAGRFGQKTGKGWYQYDKPLGRIHKPDPWLSTFLSQYREVHHIEQRTISKEEILERCLYSLINEAFRILEEGMAARPEHIDVIYLHGYGWPRHKGGPMFYAASVGLPTVLEKLQKYYRQNPDIPQLEPSDYLRRLVAQGSPPLKEWQSLAGPHGSKL
->7ad0_M mol:protein length:14  Modified p53 peptide
-ATSFAEYWALLXPA
->2d0c_A mol:protein length:310  ribonuclease HIII
-MSNYVIQADQQLLDALRAHYEGALSDRLPAGALFAVKRPDVVITAYRSGKVLFQGKAAEQEAAKWISGASASNETADHQPSALAAHQLGSLSAIGSDEVGTGDYFGPIVVAAAYVDRPHIAKIAALGVKDSKQLNDEAIKRIAPAIMETVPHAVTVLDNPQYNRWQRSGMPQTKMKALLHNRTLVKLVDAIAPAEPEAIIIDEFLKRDSYFRYLSDEDRIIRERVHCLPKAESVHVSVAAASIIARYVFLEEMEQLSRAVGLLLPKGAGAIVDEAAARIIRARGEEMLETCAKLHFANTKKALAIAKRRK
->6ba1_O mol:protein length:321  Inosine-uridine preferring nucleoside hydrolase
-GSHMKKLILDLDTGVDDTLAISYALGSPEMELIGITGTYGNVLMEQGVRNALAITDLLGHPEVKVYKGLSHASTKDSFEVLPISAFIHGDNGIGDVEIPDSPRKAEDESAVDFIIDSVKKYGKDLVYVPTGPMTNIAAALKKAPEIKDEIGKIVLMGGALTIHGNVNAWTEANISQDPDAADILFRSGAPVTMIGLDVTLQTLLTYKETKQWRDLNTKAGKFLADMTDFYIKAYETTAPHLGGCGLHDPLAVAVAVDPTLVTTLPINMQVDVEGPTRGRTIGDVTRLNDPVKTMQVAVGVDVPRFLNEFMTRISGLAKIAG
->3fch_B mol:protein length:281  Carboxysome shell protein CsoS1D
-MSYYHHHHHHDYDIPTTENLTFQGAMEPTSSLNRGDRKKGSSLVTGSEVQSQSNGASCFITTDSEKSLVSRQASQVEQIELRTYVFLDSLQPQLAAYMGTVSRGFLPIPGDSCLWMEVSPGMAVHRVTDIALKASNVRLGQMIVERAFGSLALYHKDQSTVLHSGDVVLDAIGSEVRKRTKPSTSWTEVICAITPDHAVLINRQNRSGSMIQSGMSMFILETEPAGYVLKAANEAEKSANITIIDVKAVGAFGRLTLAGKEGDVEEAAAAAIRAIDQISNY
->3r37_B mol:protein length:151  4-hydroxybenzoyl-CoA thioesterase
-MHRTSNGSHATGGNLPDVASHYPVAYEQTLDGTVGFVIDEMTPERATASVEVTDTLRQRWGLVHGGAYCALAQMLATEATVAVVHEKGMMAVGQSNHTSFFRPVKEGHVRAEAVRIHAGSTTWFWDVSLRDDAGRLCAVSSMSIAVRPRRD
->7zpp_G mol:protein length:281  Integrase
-WIENIPLAEEEHNKWHQDAVSLHLEFGIPRTAAEDIVQQCDVCQENKMPSTLRGSNKRGIDHWQVDYTHYEDKIILVWVETNSGLIYAERVKGETGQEFRVQTMKWYAMFAPKSLQSDNGPAFVAESTQLLMKYLGIEHTTGIPWNPQSQALVERTHQTLKNTLEKLIPMFNAFESALAGTLITLNIKRKGGLGTSPMDIFIFNKEQQRIQQQSKSKQEKIRFCYYRTRKRGHPGEWQGPTQVLWGGDGAIVVKDRGTDRYLVIANKDVKFIPPPKEIQKE
->3aty_B mol:protein length:379  Prostaglandin F2a synthase
-MATFPELLRPLKLGRYTLRNRIIMAPLTRCQATEDDHVPRTESMLKYYEDRASAGLIIAEATMVQPNYTGFLTEPGIYSDAQIEEWRKIVDAVHKKGGLIFLQLIHAGRAGIPEKILQQSKSDQDPLAGRLLAASAIPIKDHRIPAYFAASGEKETYGVPEELTDDEVRDGIIPLFVEGAKNAIFKAGFDGVEIHGANGYLLDAFFRESSNKRQSGPYAGTTIDTRCQLIYDVTKSVCDAVGSDRVGLRISPLNGVHGMIDSNPEALTKHLCKKIEPLSLAYLHYLRGDMVNQQIGDVVAWVRGSYSGVKISNLRYDFEEADQQIREGKVDAVAFGAKFIANPDLVERAQQNWPLNEPRPETYYTRTAVGYNDYPTYNK
->3rkc_A mol:protein length:148  Capsid protein
-SRPFSVLRANDVLWLSLTAAEYDQTTYGSSTNPMYVSDTVTFVNVATGAQGVSRSLDWSKVTLDGRPLTTIQQYSKTFFVLPLRGKLSFWEAGTTKAGYPYNYNTTASDQILIENAPGHRVCISTYTTNLGSGPVSISAVGVLAPHSA
->3gew_B mol:protein length:224  Chaperone protein faeE
-SLAVDQTRYIFRGDKDALTITVTNNDKERTFGGQAWVDNIVEKDTRPTFVVTPSFFKVKPNGQQTLRIIMASDHLPKDKESVYWLNLQDIPPALEGSGIAVALRTKLKLFYRPKALLEGRKGAEEGISLQSRPDGRTMLVNTTPYIFAIGSLLDGNGKKIATDNGTTQKLLMFMPGDEVQVKGNVVKVDSLNDYGELQTWTINKKKPAAPEAAKAEKADTAEQK
->2zmv_A mol:protein length:227  Trafficking protein particle complex subunit 4
-MAIFSVYVVNKAGGLIYQLDSYAPRAEAEKTFSYPLDLLLKLHDERVLVAFGQRDGIRVGHAVLAINGMDVNGRYTADGKEVLEYLGNPANYPVSIRFGRPRLTSNEKLMLASMFHSLFAIGSQLSPEQGSSGIEMLETDTFKLHCYQTLTGIKFVVLADPRQAGIDSLLRKIYEIYSDFALKNPFYSLEMPIRCELFDQNLKLALEVAEKAGTFGPGSLEHHHHHH
->6y7f_A mol:protein length:288  Elongation of very long chain fatty acids protein 7
-MAFSDLTSRTVHLYDNWIKDADPRVEDWLLMSSPLPQTILLGFYVYFVTSLGPKLMENRKPFELKKAMITYNFFIVLFSVYMCYEFVMSGWGIGYSFRCDIVDYSRSPTALRMARTCWLYYFSKFIELLDTIFFVLRKKNSQVTFLHVFHHTIMPWTWWFGVKFAAGGLGTFHALLNTAVHVVMYSYYGLSALGPAYQKYLWWKKYLTSLQLVQFVIVAIHISQFFFMEDCKYQFPVFACIIMSYSFMFLLLFLHFWYRAYTKGQRLPKTVKNGTCKNKDNAENLYFQ
->3ejm_A mol:protein length:146  Nucleoside diphosphate kinase
-YKKAGLQRTLVLIKPDAFERSLVAEIMGRIEKKNFKIVSMKFWSKAPRNLIEQHYKEHSEQSYFNDNCDFMVSGPIISIVYEGTDAISKIRRLQGNTNPLASAPGTIRGDLANDIRENLIHASDSEDSAVDEISIWFPETKMETDN
->4hem_E mol:protein length:123  Anti-baseplate TP901-1 Llama vHH 02
-QVQLVESGGGLVQAGGSLRLSCAASESTFSNYAMGWFRQAPGPEREFVATISQTGSHTYYRNSVKGRFTISRDNAKNTVYLQMNNMKPEDTAVYYCAAGDNYYYTRTYEYDYWGQGTQVTVSS
->3njk_A mol:protein length:128  Peptidase
-SNAMFAPQGLAQFIKVNVTLENGEPVFIYTDANGQVCQGDITVTQAGTITYLLNDQTLKGLKFVGVGFVTPFDGIIDAVTISSDGMLVQLVDLDKTPGTTKFQFVLSNTANTLLVLSPAPQIINRPQN
->2xwq_B mol:protein length:133  SIROHYDROCHLORIN COBALTOCHELATASE
-GMRRGLVIVGHGSQLNHYREVMELHRKRIEESGAFDEVKIAFAARKRRPMPDEAIREMNCDIIYVVPLFISYGLHVTEDLPDLLGFPRGRGIKEGEFEGKKVVICEPIGEDYFVTYAILNSVFRIGRDGKGEE
->7spi_F3 mol:protein length:453  TraB
-MANVNKVVRRRQVALLIALVLGIGAGGAGTWMVSEMNLKKAPPAKAPKGEPAPDMTGVVNQSFDNKVQRSAIAEAQRLNKETQTEIKKLRTEMGLVSRDLKGSQDRIRELEDQNQLLQTQLEAGKNFDSLSAEPLPGALASQGKPAPAGNVPPPTSFWPAGGGQAPAAPVMTPIQRPGMMDSQEFSLPDTGPKKPRFPWISSGSFVEAIVVEGADANASVTGDKNTAPMQLRLTGKVQMPNDEEFDLTGCFVTLEAWGDVSSERAIVRSRSISCKLGDDDIDQKIAGHVSFMGKNGIKGEVVMRNGQILLYAGGAGFLDGIGKGIEKASSTTVGVGATASMSAADIGQAGLGGGVSSAAKTLSDYYIKRAEQYHPVIPIGAGNEVTLVFQDGFQLETLEEARAKAAARKKQNQPSASSTPAAMPGNTPDMLKQLQDFRVGDTVDPATGQVVTQ
->4clr_D mol:protein length:288  PTERIDINE REDUCTASE 1
-MGSSHHHHHHSSGLVPRGSHMEAPAAVVTGAAKRIGRAIAVKLHQTGYRVVIHYHNSAEAAVSLADELNKERSNTAVVCQADLTNSNVLPASCEEIINSCFRAFGRCDVLVNNASAFYPTPLVQGDHEDNSNGKTVETQVAELIGTNAIAPFLLTMSFAQRQKGTNPNCTSSNLSIVNLCDAMVDQPCMAFSLYNMGKHALVGLTQSAALELAPYGIRVNGVAPGVSLLPVAMGEEEKDKWRRKVPLGRREASAEQIADAVIFLVSGSAQYITGSIIKVDGGLSLVHA
->4u50_C0 mol:protein length:105  40S ribosomal protein S10-A
-MLMPKEDRNKIHQYLFQEGVVVAKKDFNQAKHEEIDTKNLYVIKALQSLTSKGYVKTQFSWQYYYYTLTEEGVEYLREYLNLPEHIVPATYIQERNPTQRPQRRY
->7ezx_G8 mol:protein length:177  B-phycoerythrin beta chain
-MLDAFSRVVVNSDAKAAYVGGSDLQALKSFIADGNKRLDAVNSIVSNASCMVSDAVSGMICENPGLISPGGNCYTNRRMAACLRDGEIILRYVSYALLAGDASVLEDRCLNGLKETYIALGVPTNSSIRAVSIMKAQAVAFITNTATERKMSFAAGDCTSLASEVASYFDRVGAAIS
->5da5_c mol:protein length:116  Rru_A0973
-MAQSSNSTHEPLEVLKEETVNRHRAIVSVMEELEAVDWYDQRVDASTDPELTAILAHNRDEEKEHAAMTLEWLRRNDAKWAEHLRTYLFTEGPITAANSSSVDKLAAALEHHHHHH
->2amf_A mol:protein length:259  1-Pyrroline-5-Carboxylate reductase
-SNAMKIGIIGVGKMASAIIKGLKQTPHELIISGSSLERSKEIAEQLALPYAMSHQDLIDQVDLVILGIKPQLFETVLKPLHFKQPIISMAAGISLQRLATFVGQDLPLLRIMPNMNAQILQSSTALTGNALVSQELQARVRDLTDSFGSTFDISEKDFDTFTALAGSSPAYIYLFIEALAKAGVKNGIPKAKALEIVTQTVLASASNLKTSSQSPHDFIDAICSPGGTTIAGLMELERLGLTATVSSAIDKTIDKAKSL
->4v5r_AJ mol:protein length:105  30S RIBOSOMAL PROTEIN S10
-MPKIRIKLRGFDHKTLDASAQKIVEAARRSGAQVSGPIPLPTRVRRFTVIRGPFKHKDSREHFELRTHNRLVDIINPNRKTIEQLMTLDLPTGVEIEIKTVGGGR
->7n02_B mol:protein length:362  Aminopeptidase P family protein
-MSKIERISAFLNDKEVDMTFITNPTTLNYLTGLAISPHERIAGLMIFRDSTPMLFTPALEVEKAKEHTSGLDIFGYEDSQNPWEVVKNHVKSDVKSIAVEFSDIPLAKTEGLKAQFGDINFVNLTPLIERMRLIKSADEIEKMKVAGDFADKCFEIGFATAAERNGVTESDIVAKIEYEMKRMGVPQMSFDTLVLSGARAANPHGAPENVEIQENKLLLFDLGVMSGGYASDATRTIAIGQPNDFDAEIHKIVKEAQQAAMDFIKPGVTAHEVDAVARDLITKAGYGEYFNHRLGHGIGMDVHEYPSIVAGNDLVIQEGMCFSNEPGIYIPGKVGVRIEDCLYVTENGCESFTHTDHDLLIF
->2ivq_J mol:protein length:156  CYANATE HYDRATASE
-MIQSQINRNIRLDLADAILLSKAKKDLSFAEIADGTGLAEAFVTAALLGQQALPADAARLVGAKLDLDEDSILLLQMIPLRGCIDDRIPTDPTMYKFYEMLQVYGTTLKALVHEKFGDGIISAINFKLDVKKVADPEGGERAVITLDGKYLPTKPF
->2p1n_D mol:protein length:160  SKP1-like protein 1A
-MSAKKIVLKSSDGESFEVEEAVALESQTIAHMVEDDCVDNGVPLPNVTSKILAKVIEYCKRHVEAAASKAEAVEGAATSDDDLKAWDADFMKIDQATLFELILAANYLNIKNLLDLTCQTVADMIKGKTPEEIRTTFNIKNDFTPEEEEEVRRENQWAFE
->6png_A mol:protein length:421  Nitric oxide synthase, brain
-CPRFLKVKNWETEVVLTDTLHLKSTLETGCTEYICMGSIMHPSQHARRPEDVATKDQLFPLAKEFIDQYYSSIKRFGSKAHMERLEEVNKEIDTTSTYQLKDTELIYGAKHAWRNASRCVGRIQWSKLQVFDARDCTTAHGMFNYICNHVKYATNKGNLRSAITIFPQRTDGKHDFRVWNSQLIRYAGYKQPDGSTLGDPANVQFTEICIQQGWKPPRGRFDVLPLLLQANGNDPELFQIPPELVLEVPIRHPKFEWFKDLGLKWYGLPAVSNMLLEIGGLEFSACPFSGWYMGTEIGVRDYCDNSRYNILEEVAKKMNLDMRKTSSLWKDQALVEINIAVLYSFQSDKVTIVDHHSATESFIKHMENEYRCRGGCPADWVWIVPPMSGSITPVFHQEMLNYRLTPSFEYQPDPWNTHVWK
->4v55_DR mol:protein length:103  50S ribosomal protein L21
-MYAVFQSGGKQHRVSEGQTVRLEKLDIATGETVEFAEVLMIANGEEVKIGVPFVDGGVIKAEVVAHGRGEKVKIVKFRRRKHYRKQQGHRQWFTDVKITGISA
->5y6p_v1 mol:protein length:161  beta_APC
-MQDAITAVINTADVQGKYLDDNSLDKLRGYFETGELRVRAAATIAANAATIIKESVAKALLYSDITRPGGNMYTTRRYAACIRDLDYYLRYATYGMLAGDPSILDERVLNGLKETYNSLGVPIGATVQAIQAMKEVTASLVGTNAGQEMAVYFDYICSGLS
->1lqo_A mol:protein length:135  PROBABLE Fosfomycin Resistance Protein
-MLTGLNHLTLAVADLPASIAFYRDLLGFRLEARWDQGAYLELGSLWLCLSREPQYGGPAADYTHYAFGIAAADFARFAAQLRAHGVREWKQNRSEGDSFYFLDPDGHRLEAHVGDLRSRLAACRQAPYAGMRFAD
->1z5n_B mol:protein length:242  MTA/SAH nucleosidase
-FQGAMDPEFSMKIGIIGAMEEQVTLLRDKIENRQTISLGGCEIYTGQLNGTEVALLKSGIGKVAAALGATLLLEHCKPDVIINTGSAGGLAPTLKVGDIVVSDEARYHDADVTAFGYEYGQLPGCPAGFKADDKLIAAAEACIAELNLNAVRGLIVSGDAFINGSVGLAKIRHNFPQAIAVEMEATAIAHVCHNFNVPFVVVRAISDVADQQSHLSFDEFLAVAAKQSSLMVESLVQKLAHG
->2xm1_A mol:protein length:716  O-GLCNACASE BT_4395
-QNVSLQPPPQQLIVQNKTIDLPAVYQLNGGEEANPHAVKVLKELLSGKQSSKKGMLISIGEKGDKSVRKYSRQIPDHKEGYYLSVNEKEIVLAGNDERGTYYALQTFAQLLKDGKLPEVEIKDYPSVRYRGVVEGFYGTPWSHQARLSQLKFYGKNKMNTYIYGPKDDPYHSAPNWRLPYPDKEAAQLQELVAVANENEVDFVWAIHPGQDIKWNKEDRDLLLAKFEKMYQLGVRSFAVFFDDISGEGTNPQKQAELLNYIDEKFAQVKPDINQLVMCPTEYNKSWSNPNGNYLTTLGDKLNPSIQIMWTGDRVISDITRDGISWINERIKRPAYIWWNFPVSDYVRDHLLLGPVYGNDTTIAKEMSGFVTNPMEHAESSKIAIYSVASYAWNPAKYDTWQTWKDAIRTILPSAAEELECFAMHNSDLGPNGHGYRREESMDIQPAAERFLKAFKEGKNYDKADFETLQYTFERMKESADILLMNTENKPLIVEITPWVHQFKLTAEMGEEVLKMVEGRNESYFLRKYNHVKALQQQMFYIDQTSNQNPYQPGVKTATRVIKPLIDRTFATVVKFFNQKFNAHLDATTDYMPHKMISNVEQIKNLPLQVKANRVLISPANEVVKWAAGNSVEIELDAIYPGENIQINFGKDAPCTWGRLEISTDGKEWKTVDLKQKESRLSAGLQKAPVKFVRFTNVSDEEQQVYLRQFVLTIEKK
->3dll_2 mol:protein length:47  50S ribosomal protein L34
-MKRTYQPNNRKRAKTHGFRARMKTKSGRNILARRRAKGRHQLTVSDE
->4cub_B mol:protein length:183  BETA-GALACTOSIDASE
-QTEQGANISDQWTGSELPLAFASDSNPSDPVSNVNDKLISYNNQPANRWTNWNRSNPEASVGVLFGDSGILSKRSVDNLSVGFHEDHGVGAPKSYVIEYYVGKTVPTAPKNPSFVGNEDHVFNDSANWKPVTNLKAPAQLKAGEMNHFSFDKVETYAIRIRMVKADNKRGTSITEVQIFAKQV
->1otr_B mol:protein length:76  Ubiquitin
-MQIFVKTLTGKTITLEVESSDTIDNVKSKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGG
->2oig_A mol:protein length:111  RS21-C6
-GPLGSRPFRFSPEPTLEDIRRLHAEFAAERDWEQFHQPRNLLLALVGEVGELAELFQWKSDTEPGPQAWPPKERAALQEELSDVLIYLVALAARCHVDLPQAVISKMDTNR
->5vhr_E mol:protein length:262  26S proteasome regulatory subunit 10B
-GNVSYSEIGGLSEQIRELREVIELPLTNPELFQRVGIIPPKGCLLYGPPGTGKTLLARAVASQLDCNFLKVVSSSIVDKYIGESARLIREMFNYARDHQPCIIFMDEIDAIGGRRFSEGTSADREIQRTLMELLNQMDGFDTLHRVKMIMATNRPDTLDPALLRPGRLDRKIHIDLPNEQARLDILKIHAGPITKHGEIDYEAIVKLSDGFNGADLRNVCTEAGMFAIRADHDFVVQEDFMKAVRKVADSKKLESKLDYKPV
->6zke_s mol:protein length:137  NADH:ubiquinone oxidoreductase subunit B7
-MGAHLARRYLGDASVEPEPLRMPTFPPDYGFPERKEREMVATQQEMNDAQLVLQQRDYCAHYLIRFLKCKRDSFPNFLACKHEQHDWDYCEHLDYVKRMKEFERERRLLQRKKRREQREADMAKGLGPGEVAPEVAL
->7lmx_C mol:protein length:75  Integrin inhibitor
-STKCVVRFVFRGDLATLMLRAVKDHLKKEGPHWNITSTNNGAELVVRGIHESDAKRIAKWVEKRFPGVHTETQCD
->6qn7_L mol:protein length:216  Light chain of bovine anti-RSV B13
-QAVLTQPPSVSGSLGQRVSITCSGSSDNIGIFAVGWYQQVPGSGLRTIIYGNTKRPSGVPDRFSGSKSGNTATLTINSLQAEDEADYFCVCGESKSATPVFGGGTTLTVLGQPKSPPSVTLFPPSTEELNGNKATLVCLISDFYPGSVTVVWKADGSTITRNVETTRASKQSNSKYAASSYLSLTSSDWKSKGSYSCEVTHEGSTVTKTVKPSECS
->5b00_A mol:protein length:294  MoeN5
-MAHHHHHHVDDDDKAASWSHPQFEKGAENLYFQSMLAAEAANRDHVTRCVAQTGGSPDLVAHTAALRLYLRVPHFLTEWTTDPDRRAAVSRALALDIVSMKLLDDLMDDDTGLDRVELACVCLRLHLRALHELESLARDPKAVTDILEQDAVHLCGGQIRTKRSRATNLREWRAHASTYGSTFLGRYGALAAACGGEGQPADSVREFAEAFAMTITMADDLTDYDRNGERDGNLAHLMRTGAVAGQDVVDLLEELRGRALAAVAAPPGAPGLVPVVHLYTDDVLVRLLPRHLGE
->6iqt_D mol:protein length:166  Cag pathogenicity island protein (Cag10)
-GTSSMADIGSGEFKIVKRSDARQIVNSEAVVDSATSKFVSLLFGYSKNSLRDRKDQLMQYCDVSFQTQAMRMFNENIRQFVDKVRAEAIISSNIQREKVKNSPLTRLTFFITIKITPDTMENYEYITKKQVTIYYDFARGNSSQENLIINPFGFKVFDIQITDLQN
->4o26_A mol:protein length:257  Telomerase reverse transcriptase
-GSGFLYGGRGMHGFCLNRKRRTAAGPRRLQGQDLVRLVFFEGLPYLNGQERKPKKLPLRYFNMVPVFGRLLQRHRKCRYSSVLHRMCPVVELSRAAQGELSSLIPQHCAPHRVYLFVRECLTAVVPEELWGSDHNRLQFFSRVRGFLKSGKFERISVAELMWKIKVMDCDWLKLRRTAGRFPPSELAYRTRILSQFLTWLLDGFVVGLVRACFYATESVGQKNAIRFYRQEVWSKLQDLAFRRHIAKGEMEELSPAQ
->8d0k_B mol:protein length:374  CST complex subunit STN1
-MHHHHHHQPGSSRCEEETPSLLWGLDPVFLAFAKLYIRDILDMKESRQVPGVFLYNGHPIKQVDVLGTVIGVRERDAFYSYGVDDSTGVINCICWKKLNTESVSAAPSAARELSLTSQLKKLQETIEQKTKIEIGDTIRVRGSIRTYREEREIHATTYYKVDDPVWNIQIARMLELPTIYRKVYDQPFHSSALEKEEALSNPGALDLPSLTSLLSEKAKEFLMENRVQSFYQQELEMVESLLSLANQPVIHSASSDQVNFKKDTTSKAIHSIFKNAIQLLQEKGLVFQKDDGFDNLYYVTREDKDLHRKIHRIIQQDCQKPNHMEKGCHFLHILACARLSIRPGLSEAVLQQVLELLEDQSDIVSTMEHYYTAF
->7mus_FD mol:protein length:163  DotD
-MNNNKIVIMFIFSALLAGCAGTMKFKKPPINNPSDDATIKLAEAAVSVSDSMLEMAKVEKVITPPSKDNTLTIPNAYNLQARASVDWSGPIEELTARIAKAAHFRFRVLGKSPSVPVLISISTKDESLAEILRDIDYQAGKKASIHVYPNSQVVELRYAKIYS
->2olh_A mol:protein length:361  Chitinase-3-like protein 1
-YKLICYYTSWSQYREGDGSCFPDAIDPFLCTHVIYSFANISNNEIDTWEWNDVTLYDTLNTLKNRNPKLKTLLSVGGWNFGPERFSKIASKTQSRRTFIKSVPPFLRTHGFDGLDLAWLYPGRRDKRHLTALVKEMKAEFAREAQAGTERLLLSAAVSAGKIAIDRGYDIAQISRHLDFISLLTYDFHGAWRQTVGHHSPLFRGNSDASSRFSNADYAVSYMLRLGAPANKLVMGIPTFGRSFTLASSKTDVGAPISGPGIPGRFTKEKGILAYYEICDFLHGATTHRFRDQQVPYATKGNQWVAYDDQESVKNKARYLKNRQLAGAMVWALDLDDFRGTFCGQNLTFPLTSAVKDVLARV
->6ue6_D mol:protein length:141  Histone-lysine N-methyltransferase NSD2
-GGRDKDHLLKYNVGDLVWSKVSGYPWWPCMVSADPLLHSYTKLKGQKKSARQYHVQFFGDAPERAWIFEKSLVAFEGEGQFEKLCQESAKQAPTKAEKIKLLKPISGKLRAQWEMGIVQAEEAASMSVEERKAKFTFLYVG
->2nvy_C mol:protein length:318  DNA-directed RNA polymerase II 45 kDa polypeptide
-MSEEGPQVKIREASKDNVDFILSNVDLAMANSLRRVMIAEIPTLAIDSVEVETNTTVLADEFIAHRLGLIPLQSMDIEQLEYSRDCFCEDHCDKCSVVLTLQAFGESESTTNVYSKDLVIVSNLMGRNIGHPIIQDKEGNGVLICKLRKGQELKLTCVAKKGIAKEHAKWGPAAAIEFEYDPWNKLKHTDYWYEQDSAKEWPQSKNCEYEDPPNEGDPFDYKAQADTFYMNVESVGSIPVDQVVVRGIDTLQKKVASILLALTQMDQDKVNFASGDNNTASNMLGSNEDVMMTGAEQDPYSNASQMGNTGSGGYDNAW
->2vd0_D mol:protein length:199  GLUTATHIONE-REQUIRING PROSTAGLANDIN D SYNTHASE
-MPNYKLTYFNMRGRAEIIRYIFAYLDIQYEDHRIEQADWPEIKSTLPFGKIPILEVDGLTLHQSLAIARYLTKNTDLAGNTEMEQCHVDAIVDTLDDFMSCFPWAEKKQDVKEQMFNELLTYNAPHLMQDLDTYLGGREWLIGNSVTWADFYWEICSTTLLVFKPDLLDNHPRLVTLRKKVQAIPAVANWIKRRPQTKL
->1yf1_B mol:protein length:186  Alkyl hydroperoxide reductase subunit C
-SLINTKIKPFKNQAFKNGEFIEVTEKDTEGRWSVFFFYPADFTFVCPTELGDVADHYEELQKLGVDVYSVSTDTHFVHKAWHSSSETIAKIKYAMIGDPTGALTRNFDNMREDEGLADRATFVVDPQGIIQAIEVTAEGIGRDASDLLRKIKAAQYVAAHPGEVCPAKWKEGEATLAPSLDLVGKI
->4g4s_B mol:protein length:250  Proteasome component Y7
-MTDRYSFSLTTFSPSGKLGQIDYALTAVKQGVTSLGIKATNGVVIATEKKSSSPLAMSETLSKVSLLTPDIGAVYSGMGPDYRVLVDKSRKVAHTSYKRIYGEYPPTKLLVSEVAKIMQEATQSGGVRPFGVSLLIAGHDEFNGFSLYQVDPSGSYFPWKATAIGKGSVAAKTFLEKRWNDELELEDAIHIALLTLKESVEGEFNGDTIELAIIGDENPDLLGYTGIPTDKGPRFRKLTSQEINDRLEAL
->6mjz_C mol:protein length:495  Fusion glycoprotein F0
-QIDITKLQHVGVLVNSPKGMKISQNFETRYLILSLIPKIEDSNSCGDQQIKQYKRLLDRLIIPLYDGLKLQKDVIVTNQESNENTDPRTERFFGGVIGTIALGVATSAQITAAVALVEAKQAKSDIEKLKEAIRDTNKAVQSVCSSVGNCIVAIKSVQDYVNKEIVPSIARLGCEAAGLQLGIALTQHYSELTNCFGDNIGSLQEKGIKLQCIASLYRTNITEIFTTSTVDKYDIYDLLFTESIKVRVIDVDLNDYSITLQVRLPLLTRLLNTQIYKVDSISYNIQNREWYIPLPSHIMTKGAFLGGADVKECIEAFSSYICPSDPGFVLNHEMESCLSGNISQCPRTTVTSDIVPRYAFVNGGVVANCITTTCTCNGIGNRINQPPDQGVKIITHKECNTIGINGMLFNTNKEGTLAFYTPDDITLNNSVALDPIDISIELNKVKSDLEESKEWYRRSNQKLSAIEDKIEEILSKIYHIENEIARIKKLIGEAP
->5vbr_A mol:protein length:113  Bromodomain testis-specific protein
-GAASTNQLQYLQKVVLKDLWKHSFSWPFQRPVDAVKLQLPDYYTIIKNPMDLNTIKKRLENKYYAKASECIEDFNTMFSNCYLYNKPGDDIVLMAQALEKLFMQKLSQMPQEE
->1wuu_B mol:protein length:399  Galactokinase
-MAHHHHHHAALRQPQVAELLAEARRAFREEFGAEPELAVSAPGRVNLIGEHTDYNQGLVLPMALELMTVLVGSPRKDGLVSLLTTSEGADEPQRLQFPLPTAQRSLEPGTPRWANYVKGVIQYYPAAPLPGFSAVVVSSVPLGGGLSSSASLEVATYTFLQQLCPDSGTIAARAQVCQQAEHSFAGMPCGIMDQFISLMGQKGHALLIDCRSLETSLVPLSDPKLAVLITNSNVRHSLASSEYPVRRRQCEEVARALGKESLREVQLEELEAARDLVSKEGFRRARHVVGEIRRTAQAAAALRRGDYRAFGRLMVESHRSLRDDYEVSCPELDQLVEAALAVPGVYGSRMTGGGFGGCTVTLLEASAAPHAMRHIQEHYGGTATFYLSQAADGAKVLCL
->1wp9_D mol:protein length:494  ATP-dependent RNA helicase, putative
-MVLRRDLIQPRIYQEVIYAKCKETNCLIVLPTGLGKTLIAMMIAEYRLTKYGGKVLMLAPTKPLVLQHAESFRRLFNLPPEKIVALTGEKSPEERSKAWARAKVIVATPQTIENDLLAGRISLEDVSLIVFDEAHRAVGNYAYVFIAREYKRQAKNPLVIGLTASPGSTPEKIMEVINNLGIEHIEYRSENSPDVRPYVKGIRFEWVRVDLPEIYKEVRKLLREMLRDALKPLAETGLLESSSPDIPKKEVLRAGQIINEEMAKGNHDLRGLLLYHAMALKLHHAIELLETQGLSALRAYIKKLYEEAKAGSTKASKEIFSDKRMKKAISLLVQAKEIGLDHPKMDKLKEIIREQLQRKQNSKIIVFTNYRETAKKIVNELVKDGIKAKRFVGQASKENDRGLSQREQKLILDEFARGEFNVLVATSVGEEGLDVPEVDLVVFYEPVPSAIRSIQRRGRTGRHMPGRVIILMAKGTRDEAYYWSSRQKEKIMQE
->6mxv_B mol:protein length:252  Rhodanese-like family protein
-MKIMQHSSGFLKLVDDAKSRIQECSVDDIQKMNETQTLDGLLIDTREESEVANGYIPNAIHLSKGIIESAIESAVPNKNQKMYFYCGGGFRSALVADKLREMGYKNVISVDGGWRAWNAKGYPTVSPNQFRPNEFLKLVNNAKTQIKECSTTELYNKINSQELDGIVFDVREDSEFNRFHIQGATHLSKGQIEVKIENLVPNKQQKIYLYCGSGFRSALAAESLQHMGYTNVVSIAGGIKDWLANNYPVSQN
->6owg_B9 mol:protein length:113  Microcompartments protein
-MAVAVGMIETLGFPAVVEAADAMVKAARVTLVGYEKIGTGRVTVIVRGDVSEVQASVSAGTESVKRVNGGQVLSTHIIARPHENLEYVLPIRYTEEVEQFREGVGTPRNITRQ
->6x6s_IC mol:protein length:481  Type IV secretion system apparatus protein Cag3
-MFRKLATAVSLIGLLTSNTLYAKEISEADKVIKATKETKETKKEAKRLKKEAKQRQQIPDHKKPQYVSVDDTKTQALFDIYDTLNVNDKSFGDWFGNSALKDKTYLYAMDLLDYNNYLSIENPIIKTRAMGTYADLIIITGSLEQVNGYYNILKALNKRNAKFVLKINENMPYAQATFLRVPKRSDPNAHTLDKGASIDENKLFEQQKKMYFNYANDVICRPDDEVCSPLRDEMVAMPTSDSVTQKPNIIAPYSLYRLKETNNANEAQPSPYATATAPENSKEKLIEELIANSQLVANEEEREKKLLAEKEKQEAELAKYKLKDLENQKKLKALEAELKKKNAKKPRVVEVPVSPQTSNSDETMRVVKEKENYNGLLVDKETTIKRSYEGTLISENSYSKKTPLNPNDLRSLEEEIKSYYIKSNGLCYTNGINLYVKIKNDPYKEGMLCGYESVQNLLSPLKDKLKYDKQKLQKALLKDSK
->6th6_Al mol:protein length:135  30S ribosomal protein S9
-MRVIQTAGKRKTAVARATIREGKGRVRINHKPVEIIEPEIARFTIMEPLILAGEEIVSRVDIDVKVEGGGFMGQAEAARVAIARALVEWTNDMNLKEKFMKYDRTMLVGDSRRTEPHKPNRSTKGPRAKRQKSYR
->6lvv_G mol:protein length:775  N,N-dimethylformamidase large subunit
-MKDIAIRGYCDRPSVATGETIRFYVSANETRGTFDAELVRLIHGDSNPAGPGYKEEAIKSDLEGQYPARFQRTQFGSYVEVADPDAGLQPDGAFSVHLFLWSTTPSRGRQGIASRWNDERQSGWNLAIEDGRVVFTIGDGSGATSSVVSDRPLFQQIWYSITGVYDPEKKQLRLYQKSVVNRTNSRFGLVVPLDSDCAVSADATVKAADSETSLLIAGLGEAAAQDGRTWCIAHYNGKVDAPKIYGCALGQDDAEKLSRGEIVRPISRLAHWDFSAGIGLNGIPTDHVVDASGYGHHGRCMNQPSRGSTGWNWDGHEENFIHCPEQYGALWFHEDCLDDCRWEKDFEFTVPEGLKSDFYAVKIRYEDTEDYIPFFVLPPRGTATAPILVIASTLSYLAYANEQIMHKADIGQAVAGHTPVLNENDVELHKNLSYYGLSTYDGHIDGRGVQYTSWRRPIMNLRPKHRQGFGSIWELPADLHLIDWLNHNGFEYDVATEHDLNDQGAELLRRYKVVLTGSHPEYQTWANADAWEDYLADGGRGMYLAANGMYWIVEVHPEKPWVMEVRKELGVTAWEAPPGEYHYSTNGRRGGRFRGRARATQKIWGTGMSSFGFDHSGYFVQMPDSQDERVAWIMEGIDPEERIGDGGLVGGGAGGYELDRYDLALGTPPNTLLLASSVEHSVVYTVIPDDKAFPHPGMNGGEHPFVRADITYFSTANGGGMFATSSISWLGSLSWNDYDNNVSKMTKNVLNQFIKDEPAPRVKLAAALEHHHHHH
->1esb_A mol:protein length:240  PORCINE PANCREATIC ELASTASE
-VVGGTEAQRNSWPSQISLQYRSGSSWAHTCGGTLIRQNWVMTAAHCVDRELTFRVVVGEHNLNQNNGTEQYVGVQKIVVHPYWNTDDVAAGYDIALLRLAQSVTLNSYVQLGVLPRAGTILANNSPCYITGWGLTRTNGQLAQTLQQAYLPTVDYAICSSSSYWGSTVKNSMVCAGGDGVRSGCQGDSGGPLHCLVNGQYAVHGVTSFVSRLGCNVTRKPTVFTRVSAYISWINNVIASN
->3wry_B mol:protein length:431  Tm-1 protein
-MATAQSNSPRVFCIGTADTKFDELRFLSEHVRSSLNSFSNKSSFKVGVTVVDVSTSWKETNSCADFDFVPSKDVLSCHTLGEETMGTFADTRGLAIAIMSKALETFLSIANDEQNLAGVIGLGGSGGTSLLSSAFRSLPIGIPKVIISTVASGQTESYIGTSDLVLFPSVVDICGINNVSKVVLSNAGAAFAGMVIGRLESSKEHSITNGKFTVGVTMFGVTTPCVNAVKERLVKEGYETLVFHATGVGGRAMEDLVRGGFIQGVLDITTTEVADYVVGGVMACDSSRFDAILEKKIPLVLSVGALDMVNFGPKTTIPPEFQQRKIHEHNEQVSLMRTTVGENKKFAAFIAEKLNKASSSVCVCLPEKGVSALDAPGKDFYDPEATSCLTRELQMLLENNERCQVKVLPYHINDAEFANALVDSFLEISPK
->4i55_F mol:protein length:384  Tubulin tyrosine ligase, TTL
-MYTFVVRDENSSVYAEVSRLLLATGQWKRLRKDNPRFNLMLGERNRLPFGRLGHEPGLVQLVNYYRGADKLCRKASLVKLIKTSPELSESCTWFPESYVIYPTNLKTPVAPAQNGIRHLINNTRTDEREVFLAAYNRRREGREGNVWIAKSSAGAKGEGILISSEASELLDFIDEQGQVHVIQKYLEKPLLLEPGHRKFDIRSWVLVDHLYNIYLYREGVLRTSSEPYNSANFQDKTCHLTNHCIQKEYSKNYGRYEEGNEMFFEEFNQYLMDALNTTLENSILLQIKHIIRSCLMCIEPAISTKHLHYQSFQLFGFDFMVDEELKVWLIEVNGAPACAQKLYAELCQGIVDVAISSVFPLADTGQKTSQPTSIFIKLHHHHHH
->3dal_B mol:protein length:196  PR domain zinc finger protein 1
-SSGLVPRGSKKMDMEDADMTLWTEAEFEEKCTYIVNDHPWDSGADGGTSVQAEASLPRNLLFKYATNSEEVIGVMSKEYIPKGTRFGPLIGEIYTNDTVPKNANRKYFWRIYSRGELHHFIDGFNEEKSNWMRYVNPAHSPREQNLAACQNGMNIYFYTIKPIPANQELLVWYCRDFAERLHYPYPGELTMMNLTQ
->6pjj_A mol:protein length:351  Serine/threonine-protein kinase PRP4 homolog
-SMDFKENPNLRDNWTDAEGYYRVNIGEVLDKRYNVYGYTGQGVFSNVVRARDNARANQEVAVKIIRNNELMQKTGLKELEFLKKLNDADPDDKFHCLRLLRHFYHKQHLCLVFEPLSMNLREVLKKYGKDVGLHIKAVRSYSQQLFLALKLLKRCNILHADIKPDNILVNESKTILKLCDFGSASHVADNDITPYLFSRFYRAPEIIIGKSYDYGIDMWSVGCTLYELYTGKILFPGKTNNHMLKLAMDLKGKMPNKMIRKGVFKDQHFDQNLNFMYIEVDKVTEREKVTVMSTINPTKDLLADLIGCQRLPEDQRKKVHQLKDLLDQILMLDPAKRISINQALQHAFIQE
->7ajb_AO mol:protein length:75  ATP synthase F(0) complex subunit C2, mitochondrial
-DIDTAAKFIGAGAATVGVAGSGAGIGTVFGSLIIGYARNPSLKQQLFSYAILGFALSEAMGLFCLMVAFLILFAM
->7a4g_FI mol:protein length:197  Antitermination protein N,6,7-dimethyl-8-ribityllumazine synthase,6,7-dimethyl-8-ribityllumazine synthase
-MGNAKTRRRERRAEKQAQWKAANAGAGAGAMATPHFDYIASEVSKGLANLSLELRKPITFGVITADTLEQAIERAGTKHGNKGWEAALSAIEMANLFKSLRGTGHHHHHHGSSMEIYEGKLTAEGLRFGIVASRFNHALVDRLVEGAIDCIVRHGGREEDITLVRVPGSWEIPVAAGELARKEDIDAVIAIGVLIRG
->6r8h_E mol:protein length:250  Triosephosphate isomerase
-ASNRKFFVGGNWKMNGSKESNQKLLKTLSDAKPDANTEILVAVPFVYLKDVREHLDKRFHVAAQNCYKVASGAFTGEISPAMIRDCGCEWVILGHSERRHIFGESDELIGEKVNHALTCGLKVVPCIGEKLDEREAGKTEQVCFRQLDAIKKGIPKAEDWSRVVIAYEPVWAIGTGKTASPEQAQEVHHAVRQWLEKNVSQAVASSLRITYGGSVTAANCKELAKKPDVDGFLVGGASLKPEFVDICNAN
->7of2_U mol:protein length:153  39S ribosomal protein L23, mitochondrial
-MARNVVYPLYRLGGPQLRVFRTNFFIQLVRPGVAQPEDTVQFRIPMEMTRVDLRNYLEGIYNVPVAAVRTRVQHGSNKRRDHRNVRIKKPDYKVAYVQLAHGQTFTFPDLFPEKDESPEGSAADDLYSMLEEERQQRQSSDPRRGGVPSWFGL
->1xa6_A mol:protein length:466  Beta2-chimaerin
-MRLLSSLSGSSVSSDAEEYQPPIWKSYLYQLQQEAPRPKRIICPREVENRPKYYGREFHGIISREQADELLGGVEGAYILRESQRQPGCYTLALRFGNQTLNYRLFHDGKHFVGEKRFESIHDLVTDGLITLYIETKAAEYISKMTTNPIYEHIGYATLLREKVSRRLSRSKNEPRKTNVTHEEHTAVEKISSLVRRAALTHNDNHFNYEKTHNFKVHTFRGPHWCEYCANFMWGLIAQGVRCSDCGLNVHKQCSKHVPNDCQPDLKRIKKVYCCDLTTLVKAHNTQRPMVVDICIREIEARGLKSEGLYRVSGFTEHIEDVKMAFDRDGEKADISANVYPDINIITGALKLYFRDLPIPVITYDTYSKFIDAAKISNADERLEAVHEVLMLLPPAHYETLRYLMIHLKKVTMNEKDNFMNAENLGIVFGPTLMRPPEDSTLTTLHDMRYQKLIVQILIENEDVLF
->6y9i_BBB mol:protein length:292  Major Capsid Protein VP1
-GSHMGGVEVLNIITGPDSTTEIELYLEPRMGINSPTGDKKEWYGYSEVIHHADGYDNNLLSIQMPQYSCARVQLPMLNTDMTSDTLMMWEAVSCKTEIVGIGSLISVHLLEAKMAAKEGGDGPSQPIEGMNYHMFAVGGEPLDLQGIESNALTKYASAIPPKTIHPNDIAKLAEEEKPQLQGLVPKAKARLDKDGFYPIEEWSPDPSRNENSRYFGSFVGGLNTPPNLQFTNAVTTVLLDENGVGPLCKGDGLFVSAADICGVMVKADNEAIRYRGLPRYFKVTLRKRAVKN
->5hrm_B mol:protein length:504  Haloalkylphosphorus hydrolase
-QVVIGPGDRPETGLQGQTTIEDVVSGRSKLPYHAGVRLVGRTDIWNRGGNLQLSWVDQCAYVSTFKQAGPITANSRSALFLREPAGVAVIDVRDPRAPKPVRLLRDRGSIDAVETMHAIAAPGRKVLVAGAYSGGIAGRGEEDAAWLSIYDASNCLNPKLQSEFKWPANIHMVTISPNGRRVYGTEVVPGLGSGKGGLHVLDISDMKRPRYLGRFGVTRPNGLTAGFTPHEVSISHDERRIYAAVLASETGDVPVGASILASDGDVPVENGSVYILDNSDIVDGRSQPKMRLVGEAKQGGFHSVVPASINGVPHLVGAAELGACPGTWPRIINIADEKNPKIVGEFKLQMNIKENCDAIRFTPRKEDPYASFIPIPDITARLGAVGSHFNDVDDARNTRLGLFPFFAGGVRIVDLRDPTKPVEVGYYKPGANPDTPLSGNGLNWTGLNDQVTDGCMSHVRYVPESGHIWFACVTTGFHVVELNPDLRARLGFPTVKLEHHHHHH
->1s5c_F mol:protein length:103  cholera enterotoxin B-subunit
-TPQNITDLCAEYHNTQIHTLNDKIFSYTESLAGKREMAIITFKNGATFQVEVPGSQHIDSQKKAIERMKDTLRIAYLTEAKVEKLCVWNNKTPHAIAAISMAN
->3nvv_K mol:protein length:334  Xanthine dehydrogenase/oxidase
-LFNPEEFMPLDPTQEPIFPPELLRLKDVPPKQLRFEGERVTWIQASTLKELLDLKAQHPEAKLVVGNTEIGIEMKFKNQLFPMIICPAWIPELNAVEHGPEGISFGAACALSSVEKTLLEAVAKLPTQKTEVFRGVLEQLRWFAGKQVKSVASLGGNIITASPISDLNPVFMASGTKLTIVSRGTRRTVPMDHTFFPSYRKTLLGPEEILLSIEIPYSREDEFFSAFKQASRREDDIAKVTCGMRVLFQPGSMQVKELALCYGGMADRTISALKTTQKQLSKFWNEKLLQDVCAGLAEELSLSPDAPGGMIEFRRTLTLSFFFKFYLTVLKKLG
->6lum_G mol:protein length:138  Succinate dehydrogenase subunit C
-MSTQTEVPAPQPKKTRRRTLYRGDPGMWSWVLHRITGATIFFFLFVHVLDTALVRVSPQAYNEVIETYKTPIVGLMEIGLVAAVLFHALNGIRVILIDFWAKGPRYQRQMLAVIAGLFLVIFIAAVGVIGMHMVERFL
->1vav_B mol:protein length:222  Alginate lyase PA1167
-PDLSTWNLTIPQGRPAITISTSQLQRDYRSDYFQRTADGIRFWVPVNGSHTRNSEFPRSELRETLSSGRPYNWRYARADNWLEATLRIEAVPSTRRMIIGQIHSDGSNSGQAAPLVKLLYQLRLDQGRVQALVRERPDDGGTRAYTLMDGIPLGQPFSYRIGVSRSGLLSVSVNGSALEQQLDPQWAYQGLYFKAGLYLQDNRGPSSEGGRATFSELRVSHQ
->3q6e_A mol:protein length:21  Insulin A chain
-GIVEQCCTSICSLYQLENYCN
->4s17_F mol:protein length:481  Glutamine synthetase
-SNAMTALETKADAEALINKEGIEYVSVRFTDLIGVQQHFTVPASEFLKDAFTDGMPFDGSSVEGFQAINESDMKLVPDVSTAFIDPFRKHKTLDVAFSIVDPLTDEPYSRDPRQVAGKAEAYLKSTGIADTASFAPEAEFFIFDKVRFENSMQRSFYEVDSIEAPWNSGIDTEDDGTPNIAFKNRVKKGYFPVPPIDHTQDLRDDMVANLQKVGLILERSHHEVAGAGQQEINYRFNSLQHAGDDLMKYKYVVHETAALAGKAATFMPKPIAGDNGTGMHCHQSLWKDGKPLFYDEKNYGGLSDLARWYIGGLIKHSSSVLAFTNPSLNSYHRLVPGFEAPVNLVYSARNRSAAIRIPLAGTSPAAKRIEFRAPDPSCNPFLAFSAQLMAGLDGILNHIEPPAPVDKDLYELPPEEHAGIKQVPSSLAEAMDALEEDHDFLTAGDVFTDDLIDTWISIKRGEIDQARLAPTPLEYELYFHI
->4dv4_D mol:protein length:209  ribosomal protein S4
-MGRYIGPVCRLCRREGVKLYLKGERCYSPKCAMERRPYPPGQHGQKRARRPSDYAVRLREKQKLRRIYGISERQFRNLFEEASKKKGVTGSVFLGLLESRLDNVVYRLGFAVSRRQARQLVRHGHITVNGRRVDLPSYRVRPGDEIAVAEKSRNLELIRQNLEAMKGRKVGPWLSLDVEGMKGKFLRLPDREDLALPVNEQLVIEFYSR
->3zv2_A mol:protein length:320  Tyrosine-protein phosphatase non-receptor type 1
-MEMEKEFEQIDKSGSWAAIYQDIRHEASDFPCRVAKLPKNKNRNRYRDVSPFDHSRIKLHQEDNDYINASLIKMEEAQRSYILTQGPLPNTCGHFWEMVWEQKSRGVVMLNRVMEKGSLKCAQYWPQKEEKEMIFEDTNLKLTLISEDIKSYYTVRQLELENLTTQETREILHFHYTTWPDFGVPESPASFLNFLFKVRESGSLSPEHGPVVVHAAAGIGRSGTFCLADTCLLLMDKRKDPSSVDIKKVLLEMRKFRMGLIQTADQLRFSYLAVIEGAKFIMGDSSVQDQWKELSHEDLEPPPEHIPPPPRPPKRILEPH
->4lyc_A mol:protein length:129  Lysozyme C
-KVFGRCELAAAMKRHGLDNYRGYSLGNWVCAAKFESNFNTQATNRNTDGSTDYGILQINSRWWCNDGRTPGSRNLCNIPCSALLSSDITASVNCAKKIVSDGNGMNAWVAWRNRCKGTDVQAWIRGCRL
->6gaw_Bp mol:protein length:112  mL53
-MAAALARLGLRAVKQVRVQFCPFEKNVESTRTFLQAVSSEKVRCTNLNCSVIADVRHDGSEPCVDVLFGDGHRLIMRGAHLTAQEMLTAFASHIQARGAAASGDKPSASTGR
->3bvb_B mol:protein length:99  Protease (Retropepsin)
-PQITLWKRPLVTIKIGGQLKEALLNTGADDTVIEEMSLPGRWKPKMIGGIGGFIKVRQYDQIIIEIAGHKAIGTVLVGPTPVNIIGRNLLTQIGATLNF
->5djb_E mol:protein length:99  Microcompartments protein
-MADALGMIEVRGFVGMVEAADAMVKAAKVELIGYEKTGGGYVTAVVRGDVAAVKAATEAGQRAAERVGEVVAVHVIPRPHVNVDAALPLGRTPGMDKSA
->6jpa_F mol:protein length:1046  Voltage-dependent calcium channel subunit alpha-2/delta-1
-FPSAVTIKSWVDKMQEDLVTLAKTASGVHQLVDIYEKYQDLYTVEPNNARQLVEIAARDIEKLLSNRSKALVRLALEAEKVQAAHQWREDFASNEVVYYNAKDDLDPEKNDSEPGSQRIKPVFIDDANFRRQVSYQHAAVHIPTDIYEGSTIVLNELNWTSALDDVFKKNREEDPSLLWQVFGSATGLARYYPASPWVDNSRTPNKIDLYDVRRRPWYIQGAASPKDMLILVDVSGSVSGLTLKLIRTSVSEMLETLSDDDFVNVASFNSNAQDVSCFQHLVQANVRNKKVLKDAVNNITAKGITDYKKGFSFAFEQLLNYNVSRANCNKIIMLFTDGGEERAQEIFAKYNKDKKVRVFTFSVGQHNYDRGPIQWMACENKGYYYEIPSIGAIRINTQEYLDVLGRPMVLAGDKAKQVQWTNVYLDALELGLVITGTLPVFNITGQFENKTNLKNQLILGVMGVDVSLEDIKRLTPRFTLCPNGYYFAIDPNGYVLLHPNLQPKPIGVGIPTINLRKRRPNVQNPKSQEPVTLDFLDAELENDIKVEIRNKMIDGESGEKTFRTLVKSQDERYIDKGNRTYTWTPVNGTDYSLALVLPTYSFYYIKAKIEETITQARYSETLKPDNFEESGYTFLAPRDYCSDLKPSDNNTEFLLNFNEFIDRKTPNNPSCNTDLINRVLLDAGFTNELVQNYWSKQKNIKGVKARFVVTDGGITRVYPKEAGENWQENPETYEDSFYKRSLDNDNYVFTAPYFNKSGPGAYESGIMVSKAVEIYIQGKLLKPAVVGIKIDVNSWIENFTKTSIRDPCAGPVCDCKRNSDVMDCVILDDGGFLLMANHDDYTNQIGRFFGEIDPSLMRHLVNISVYAFNKSYDYQSVCEPGAAPKQGAGHRSAYVPSIADILQIGWWATAAAWSILQQFLLSLTFPRLLEAADMEDDDFTASMSKQSCITEQTQYFFDNDSKSFSGVLDCGNCSRIFHVEKLMNTNLIFIMVESKGTCPCDTRLLIQAEQTSDGPDPCDMVKQPRYRKGPDVCFDNNVLEDYTDCG
->2zoq_A mol:protein length:382  Mitogen-activated protein kinase 3
-LGSMAAAAAQGGGGGEPRRTEGVGPGVPGEVEMVKGQPFDVGPRYTQLQYIGEGAYGMVSSAYDHVRKTRVAIKKISPFEHQTYCQRTLREIQILLRFRHENVIGIRDILRASTLEAMRDVYIVQDLMETDLYKLLKSQQLSNDHICYFLYQILRGLKYIHSANVLHRDLKPSNLLINTTCDLKICDFGLARIADPEHDHTGFLTEYVATRWYRAPEIMLNSKGYTKSIDIWSVGCILAEMLSNRPIFPGKHYLDQLNHILGILGSPSQEDLNCIINMKARNYLQSLPSKTKVAWAKLFPKSDSKALDLLDRMLTFNPNKRITVEEALAHPYLEQYYDPTDEPVAEEPFTFAMELDDLPKERLKELIFQETARFQPGVLEAP
->6pee_K mol:protein length:562  Protein InvG
-MKTHILLARVLACAALVLVTPGYSSEKIPVTGSGFVAKDDSLRTFFDAMALQLKEPVIVSKMAARKKITGNFEFHDPNALLEKLSLQLGLIWYFDGQAIYIYDASEMRNAVVSLRNVSLNEFNNFLKRSGLYNKNYPLRGDNRKGTFYVSGPPVYVDMVVNAATMMDKQNDGIELGRQKIGVMRLNNTFVGDRTYNLRDQKMVIPGIATAIERLLQGEEQPLGNIVSSEPPAMPAFSANGEKGKAANYAGGMSLQEALKQNAAAGNIKIVAYPDTNSLLVKGTAEQVHFIEMLVKALDVAKRHVELSLWIVDLNKSDLERLGTSWSGSITIGDKLGVSLNQSSISTLDGSRFIAAVNALEEKKQATVVSRPVLLTQENVPAIFDNNRTFYTKLIGERNVALEHVTYGTMIRVLPRFSADGQIEMSLDIEDGNDKTPQSDTTTSVDALPEVGRTLISTIARVPHGKSLLVGGYTRDANTDTVQSIPFLGKLPLIGSLFRYSSKNKSNVVRVFMIEPKEIVDPLTPDASESVNNILKQSGAWSGDDKLQKWVRVYLDRGQEAIK
->6zg6_C mol:protein length:1273  Protein transport protein SEC31
-MVKLAEFSRTATFAWSHDKIPLLVSGTVSGTVDANFSTDSSLELWSLLAADSEKPIASLQVDSKFNDLDWSHNNKIIAGALDNGSLELYSTNEANNAINSMARFSNHSSSVKTVKFNAKQDNVLASGGNNGEIFIWDMNKCTESPSNYTPLTPGQSMSSVDEVISLAWNQSLAHVFASAGSSNFASIWDLKAKKEVIHLSYTSPNSGIKQQLSVVEWHPKNSTRVATATGSDNDPSILIWDLRNANTPLQTLNQGHQKGILSLDWCHQDEHLLLSSGRDNTVLLWNPESAEQLSQFPARGNWCFKTKFAPEAPDLFACASFDNKIEVQTLQNLTNTLDEQETETKQQESETDFWNNVSREESKEKPSVFHLQAPTWYGEPSPAAHWAFGGKLVQITPDGKGVSITNPKISGLESNTTLSEALKTKDFKPLINQRLVKVIDDVNEEDWNLLEKLSMDGTEEFLKEALAFDNDESDAQDDANNEKEDDGEEFFQQIETNFQPEGDFSLSGNIEQTISKNLVSGNIKSAVKNSLENDLLMEAMVIALDSNNERLKESVKNAYFAKYGSKSSLSRILYSISKREVDDLVENLDVSQWKFISKAIQNLYPNDIAQRNEMLIKLGDRLKENGHRQDSLTLYLAAGSLDKVASIWLSEFPDLEDKLKKDNKTIYEAHSECLTEFIERFTVFSNFINGSSTINNEQLIAKFLEFINLTTSTGNFELATEFLNSLPSDNEEVKTEKARVLIASGKSLPAQNPATATTSKAKYTNAKTNKNVPVLPTPGMPSTTSIPSMQAPFYGMTPGASANALPPKPYVPATTTSAPVHTEGKYAPPSQPSMASPFVNKTNSSTRLNSFAPPPNPYATATVPATNVSTTSIPQNTFAPIQPGMPIMGDYNAQSSSIPSQPPINAVSGQTPHLNRKANDGWNDLPLKVKEKPSRAKAVSVAPPNILSTPTPLNGIPANAASTMPPPPLSRAPSSVSMVSPPPLHKNSRVPSLVATSESPRASISNPYAPPQSSQQFPIGTISTANQTSNTAQVASSNPYAPPPQQRVATPLSGGVPPAPLPKASNPYAPTATTQPNGSSYPPTGPYTNNHTMTSPPPVFNKPPTGPPPISMKKRSNKLASIEQNPSQGATYPPTLSSSASPLQPSQPPTLASQVNTSAENVSHEIPADQQPIVDFLKEELARVTPLTPKEYSKQLKDCDKRLKILFYHLEKQDLLTQPTIDCLHDLVALMKEKKYKEAMVIHANIATNHAQEGGNWLTGVKRLIGIAEATLN
->6v00_F mol:protein length:355  MCherry fluorescent protein,Potassium voltage-gated channel subfamily E member 3
-GGMVSKGEEDNMAIIKEFMRFKVHMEGSVNGHEFEIEGEGEGRPYEGTQTAKLKVTKGGPLPFAWDILSPQFMYGSKAYVKHPADIPDYLKLSFPEGFNWERVMNFEDGGVVTVTQDSSLQDGEFIYKVKLRGTNFPSDGPVMQCRTMGWEASTERMYPEDGALKGEIKQRLKLKDGGHYDAEVKTTYKAKKPVQLPGAYNVDIKLDILSHNEDYTIVEQYERAEGRHSTGGMDELYKGSGENLYFQSSRATMETTNGTETWYESLHAVLKALNATLHSNLLCRPGPGLGPDNQTEERRASLPGRDDNSYMYILFVMFLFAVTVGSLILGYTRSRKVDKRSDPYHVYIKNRVSMI
->5a15_L mol:protein length:120  BTB/POZ DOMAIN-CONTAINING PROTEIN KCTD16
-SMGSAVPNSFPEVVELNVGGQVYFTRHSTLISIPHSLLWKMFSPKRDTANDLAKDSKGRFFIDRDGFLFRYILDYLRDRQVVLPDHFPEKGRLKREAEYFQLPDLVKLLTPDEIKQSPDE
->4k6a_B mol:protein length:279  Triosephosphate isomerase
-MHHHHHHSSGVDLGTENLYFQSNAMRHPLVMGNWKLNGSRHMVHELVSNLRKELAGVAGCAVAIAPPEMYIDMAKREAEGSHIMLGAQNVDLNLSGAFTGETSAAMLKDIGAQYIIIGHSERRTYHKESDELIAKKFAVLKEQGLTPVLCIGETEAENEAGKTEEVCARQIDAVLKTQGAAAFEGAVIAYEPVWAIGTGKSATPAQAQAVHKFIRDHIAKVDANIAEQVIIQYGGSVNASNAAELFAQPDIDGALVGGASLKADAFAVIVKAAEAAKQA
->4yzv_QL mol:protein length:132  30S ribosomal protein S12
-MPTINQLVRKGREKVRKKSKVPALKGAPFRRGVCTVVRTVTPKKPNSALRKVAKVRLTSGYEVTAYIPGEGHNLQEHSVVLIRGGRVKDLPGVRYHIVRGVYDAAGVKDRKKSRSKYGTKKPKEAAKTAAKK
->5iia_D mol:protein length:129  Vitelline envelope sperm lysin receptor
-AQTNAAADWDVYCSQDESIPAKFISRLVTSKDQALEKTEINCSNGLVPITQEFGINMMLIQYTRNELLDSPGMCVFWGPYSVPKNDTVVLYTVTARLKWSEGPPTNLSIQCYMPKSPVAPKLEHHHHHH
->7br8_y mol:protein length:176  Small capsomere-interacting protein
-MARRLPKPTLQGRLEADFPDSPLLPKFQELNQNNLPNDVFREAQRSYLVFLTSQFCYEEYVQRTFGVPRRQRAIDKRQRASVAGAGAHAHLGGSSATPVQQAQAAASAGTGALASSAPSTAVAQSATPSVSSSISSLRAATSGATAAASAAAAVDTGSGGGGQPHDTAPRGARKKQ
->1aql_A mol:protein length:532  BILE-SALT ACTIVATED LIPASE
-AKLGSVYTEGGFVEGVNKKLSLFGDSIDIFKGIPFAAAPKALEKPERHPGWQGTLKAKSFKKRCLQATLTQDSTYGNEDCLYLNIWVPQGRKEVSHDLPVMIWIYGGAFLMGASQGANFLSNYLYDGEEIATRGNVIVVTFNYRVGPLGFLSTGDSNLPGNYGLWDQHMAIAWVKRNIEAFGGDPDNITLFGESAGGASVSLQTLSPYNKGLIKRAISQSGVGLCPWAIQQDPLFWAKRIAEKVGCPVDDTSKMAGCLKITDPRALTLAYKLPLGSTEYPKLHYLSFVPVIDGDFIPDDPVNLYANAADVDYIAGTNDMDGHLFVGMDVPAINSNKQDVTEEDFYKLVSGLTVTKGLRGANATYEVYTEPWAQDSSQETRKKTMVDLETDILFLIPTKIAVAQHKSHAKSANTYTYLFSQPSRMPIYPKWMGADHADDLQYVFGKPFATPLGYRAQDRTVSKAMIAYWTNFARTGDPNTGHSTVPANWDPYTLEDDNYLEINKQMDSNSMKLHLRTNYLQFWTQTYQALPTV
->2acl_C mol:protein length:238  Retinoic acid receptor RXR-alpha
-SANEDMPVERILEAELAVEPKTETYVEANMGLNPSSPNDPVTNICQAADKQLFTLVEWAKRIPHFSELPLDDQVILLRAGWNELLIASFSHRSIAVKDGILLATGLHVHRNSAHSAGVGAIFDRVLTELVSKMRDMQMDKTELGCLRAIVLFNPDSKGLSNPAEVEALREKVYASLEAYCKHKYPEQPGRFAKLLLRLPALRSIGLKCLEHLFFFKLIGDTPIDTFLMEMLEAPHQMT
->7p1t_J mol:protein length:265  29 kDa antigen, Cfp29
-MNNLYRDLAPVTEAAWAEIELEAARTFKRHIAGRRVVDVSDPGGPVTAAVSTGRLIDVKAPTNGVIAHLRASKPLVRLRVPFTLSRNEIDDVERGSKDSDWEPVKEAAKKLAFVEDRTIFEGYSAASIEGIRSASSNPALTLPEDPREIPDVISQALSELRLAGVDGPYSVLLSADVYTKVSETSDHGYPIREHLNRLVDGDIIWAPAIDGAFVLTTRGGDFDLQLGTDVAIGYASHDTDTVRLYLQETLTFLCYTAEASVALSH
->7pk6_K mol:protein length:758  Biodegradative arginine decarboxylase
-MRALIVYTELTDKDSVISHAVARLASELNDEHVETVIIRDFEDGLAYIRSNTSIDCLLYGRDMSDRDEQIQAHRLITQLHRRQEDVPVFLLSDREEALVAFDRNMMEQVDEFAWILEDSADFIAGRVLAAIQRYRSQLLPPLMKSLIKYSDVHEYSWAAPGHQGGVGFTKTPAGRIYHDFFGENLFRTDIGIERVAVGSLLDHTGAFGECEKNAARIFGADQSYSVVVGTSGSNRTIMQACMTDDDVVVIDRNCHKSIEQGLILTGAKPVYMIPSRNRYGIIGPIYPKEMTPDAIKFKIAANPLTKGKVKQKPAYSVVTNCTYDGVCYNARKVQDLLDGSLDRIHFDEAWYGYARFNPLYRNHFAMRDEERTENEPTIFATHSTHKLLNALSQASFIHVRNGRNAIDFNRFNQAYLMHSTTSPLYAICASNDIAADMMDGNSGRSLTDEVIRESIDFRQSLAYLYKEFLNDDEWFFKPWNQEMVKDPATGKRYAFEDAPVELLMREQSCWVMHPEDKWHGFNDIPDNWAMLDPIKVSILAPGMGDDGKLLDTGVPAALVTAWLNHYGIVPTRTTDFQIMFLFSMGITKGKWGTLVNTLLSFKRHYDNNTALKKVLPEVVASAPEIYGEMGLRDLGDKMFAYLQKNNPGARLNQAYSQLPQVMMTPRDAYQQIVANRVEAVPVDQLMGRVAANSIIPYPPGIPMLLSGENFGDENSPHIHYLRSLQAWDSEFPGFEHETEGTEIIDGQYYVMCVKTCDE
->3pvg_A mol:protein length:331  Casein kinase II subunit alpha
-SKARVYADVNVLRPKEYWDYEALTVQWGEQDDYEVVRKVGRGKYSEVFEGINVNNNEKCIIKILKPVKKKKIKREIKILQNLCGGPNIVKLLDIVRDQHSKTPSLIFEYVNNTDFKVLYPTLTDYDIRYYIYELLKALDYCHSQGIMHRDVKPHNVMIDHELRKLRLIDWGLAEFYHPGKEYNVRVASRYFKGPELLVDLQDYDYSLDMWSLGCMFAGMIFRKEPFFYGHDNHDQLVKIAKVLGTDGLNVYLNKYRIELDPQLEALVGRHSRKPWLKFMNADNQHLVSPEAIDFLDKLLRYDHQERLTALEAMTHPYFQQVRAAENSRTRA
->2bcb_A mol:protein length:75  CALBINDIN D9K
-KSPEELKGIFEKYAAKEGDPNQLSKEELKLLLQTEFPSLLKGGSTLDELFEELDKNGDGEVSFEEFQVLVKKISQ
->6w6c_B mol:protein length:313  Probable dimethyladenosine transferase
-MPKVKSGAIGRRRGRQEQRRELKSAGGLMFNTGIGQHILKNPLIINSIIDKAALRPTDVVLEVGPGTGNMTVKLLEKAKKVVACELDPRLVAELHKRVQGTPVASKLQVLVGDVLKTDLPFFDTCVANLPYQISSPFVFKLLLHRPFFRCAILMFQREFALRLVAKPGDKLYCRLSINTQLLARVDHLMKVGKNNFRPPPKVESSVVRIEPKNPPPPINFQEWDGLVRITFVRKNKTLSAAFKSSAVQQLLEKNYRIHCSVHNIIIPEDFSIADKIQQILTSTGFSDKRARSMDIDDFIRLLHGFNAEGIHFS
->4pbp_B mol:protein length:210  C-reactive protein
-MEFFKNLSGKVLQFKTATDNSYVKLYPEKPLSLSAFTLCMRVATELPLDREVILFAYYTPDVDELNVWRERDGRVSLYIQSSKDAAFFRLPPLSTLQTHLCVAWESATGLTAFWMDGRRSLHQVYRKGYSIRSGGTVVLGQDPDSYVGSFDVDQSFVGEIANLQMWDYVLSSAQIKAVYYNQDNRVKGNVFDWDTIEYDVTGNVLVVPDN
->3pdg_A mol:protein length:98  Fibronectin(III)-like module
-MVTIDSPVAGERFEAGKDINISATVKSKTPVSKVEFYNGDTLISSDTTAPYTAKITGAAVGAYNLKAVAVLSDGRRIESPVTPVLVKVIVLEHHHHHH
->1ttv_A mol:protein length:107  Ubiquitin-protein ligase E3 Mdm2
-NHISTSDQEKLVQPTPLLLSLLKSAGAQKETFTMKEVLYHLGQYIMAKQLYDEKQQHIVHCSNDPLGELFGVQEFSVKEHRRIYAMISRNLVSANVKESSEDIFGNV
->6mux_Z mol:protein length:211  20S proteasome beta-5 subunit
-TTTLAFKFKDGIIVAVDSRASMGSFISSQNVEKIIEINKNILGTMAGGAADCLYWEKYLGKIIKIYELRNNEKISVRAASTILSNILYQYKGYGLCCGIILSGYDHTGFNMFYVDDSGKKVEGNLFSCGSGSTYAYSILDSAYDYNLNLDQAVELARNAIYHATFRDGGSGGKVRVFHIHKNGYDKIIEGEDVFDLHYHYTNPEQKDQYVM
->4wiz_CB mol:protein length:338  Coat protein
-MVRKGEKKLAKPATTKAANPQPRRRANNRRRSNRTDAPVSKASTVTGFGRGTNDVHLSGMSRISQAVLPAGTGTDGYVVVDATIVPDLLPRLGHAARIFQRYAVETLEFEIQPMCPANTGGGYVAGFLPDPTDNDHTFDALQATRGAVVAKWWESRTVRPQYTRTLLWTSSGKEQRLTSPGRLILLCVGNNTDVVNVSVLCRWSVRLSVPSLENPEETTAPIMTQGSLYNDSLSTNDFKSILLGSTPLDIAPDGAVFQLDRPLSIDYSLGTGDVDRAVYWHLKKFAGNAGTPAGWFRWGIWDNFNKTFTDGVAYYSDEQPRQILLPVGTVCTRVDSEN
->6b55_D mol:protein length:48  Flower-specific defensin
-ARECKTESNTFPGICITKPPCRKACISEKFTDGHCSKILRRCLCTKPC
->4hnp_L mol:protein length:222  Proteasome component C5
-QFNPYGDNGGTILGIAGEDFAVLAGDTRNITDYSINSRYEPKVFDCGDNIVMSANGFAADGDALVKRFKNSVKWYHFDHNDKKLSINSAARNIQHLLYGKRFFPYYVHTIIAGLDEDGKGAVYSFDPVGSYEREQCRAGGAAASLIMPFLDNQVNFKNQYEPGTNGKVKKPLKYLSVEEVIKLVRDSFTSATERHIQVGDGLEILIVTKDGVRKEFYELKRD
->3i4e_B mol:protein length:439  Isocitrate lyase
-GPGSMSRQQQAQELQKQWETDPRWKGIKRAFTAEDVVRLRGSIQQEHTLAKRGAEKLWTLINNEPFVNALGALTGNQAMQQVKAGLKAIYLSGWQVAGDANVAGEMYPDQSLYPANSVPLVVKRINNTLTRADQIQWSEGKNPGDEGYVDFFAPIVADAEAGFGGVLNAFELMKAMIEAGASGVHFEDQLASVKKCGHMGGKVLVPTREAVAKLTAARLAADVMGTPTVLVARTDAEAADLITSDIDDNDKPYLTGERTVEGFFRTKPGLEQAISRGLAYAPYADLIWCETGKPDLEYAKKFAEAIHKQFPGKLLSYNCSPSFNWKKNLDDATIAKFQKELGAMGYKFQFITLAGFHALNYSMFNLAHGYARTQMSAFVELQQAEFAAADKGFTAVKHQREVGTGYFDAVTQTVEREASTTALHGSTEDEQFFDGQKVA
->1s89_C mol:protein length:152  Methylglyoxal synthase
-MELTTRTLPARKHIALVAHDHCKQMLMSWVERHQPLLEQHVLYATGTTGNLISRATGMNVNAMLSGPMGGDQQVGALISEGKIDVLIFFWDPLNAVPNDPDVKALLRLATVWNIPVATNVATADFIIQSPHFNDAVDILIPDYQRYLADRLK
->7az7_H mol:protein length:6  Peptide 37
-XQAXLF
->4elf_B mol:protein length:166  Dihydrofolate reductase
-MIVSFMVAMDENRVIGKDNNLPWRLPSELQYVKKTTMGHPLIMGRKNYEAIGRPLPGRRNIIVTRNEGYHVEGCEVAHSVEEVFELCKNEEEIFIFGGAQIYDLFLPYVDKLYITKIHHAFEGDTFFPEMDMTNWKEVFVEKGLTDEKNPYTYYYHVYEKQQLVPR
->4ji2_B mol:protein length:256  RIBOSOMAL PROTEIN S2
-MPVEITVKELLEAGVHFGHERKRWNPKFARYIYAERNGIHIIDLQKTMEELERTFRFIEDLAMRGGTILFVGTKKQAQDIVRMEAERAGMPYVNQRWLGGMLTNFKTISQRVHRLEELEALFASPEIEERPKKEQVRLKHELERLQKYLSGFRLLKRLPDAIFVVDPTKEAIAVREARKLFIPVIALADTDSDPDLVDYIIPGNDDAIRSIQLILSRAVDLIIQARGGVVEPSPSYALVQEAEATETPEGESEVEA
->6ydp_Ak mol:protein length:325  Mitochondrial ribosomal protein S35
-MAATSLPAWLILKSRAGTFRAFSTAMSPATRSPRPALRTTERTSKPERALRRKALPPRTEKMAVDQDWPSVYPVAAPFKPSAVPLPVRMGYPVKRGVPMAKEGNLELLKIPNFLHLTPVAIKRHCEALKDFCTEWPAALDSDEKCEKHFPIEIDTADYVSAGPSIRNPKARVVTLRVKLSSLNLDDHAKKKLIKLVGDRYCKSTDVLTIKTDRCPLKRQNYDYAVYLLTVLYHESWKTEEWEKKKTEADMEEYIWENSTSEKNILETLLQIKAAEKNLELSKEELLGTKEVEDYRKSVVSLKNEGDNENTLSQYKESVKRLLNLA
->7f5s_Ld mol:protein length:125  60S ribosomal protein L31
-MAPAKKGGEKKKGRSAINEVVTREYTINIHKRIHGVGFKKRAPRALKEIRKFAMKEMGTPDVRIDTRLNKAVWAKGIRNVPYRIRVRLSRKRNEDEDSPNKLYTLVTYVPVTTFKNLQTVNVDEN
->1izl_L mol:protein length:472  Photosystem II: Subunit PsbB
-MGLPWYRVHTVLINDPGRLIAAHLMHTALVAGWAGSMALYELATFDPSDPVLNPMWRQGMFVLPFMARLGVTGSWSGWSITGETGIDPGFWSFEGVALAHIVLSGLLFLAACWHWVYWDLELFRDPRTGEPALDLPKMFGIHLFLAGLLCFGFGAFHLTGLFGPGMWVSDPYGLTGSVQPVAPEWGPDGFNPYNPGGVVAHHIAAGIVGIIAGLFHILVRPPQRLYKALRMGNIETVLSSSIAAVFFAAFVVAGTMWYXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXGGELNGQTFTDPPTVKSYARKAIFGEIFEFDTETLNSDGIFRTSPRGWFTFAHAVFALLFFFGHIWHGARTLFRDVFSGIDPELSPEQVEWGFYQKVGDVTTRRKEAV
->2y0d_D mol:protein length:478  UDP-GLUCOSE DEHYDROGENASE
-HHHHHHGSMNLTIIGSGKVGLVTGACLADIGHDVFCLDVDQAKIDILNNGGVPIHEPGLKEVIARNRSAGRLRFSTDIEAAVAHGDVQFIAVGTPPDEDGSADLQYVLAAARNIGRYMTGFKVIVDKSTVPVGTAERVRAAVAEELAKRGGDQMFSVVSNPEFLKEGAAVDDFTRPDRIVIGCDDDVPGERARELMKKLYAPFNRNHERTLYMDVRSAEFTKYAANAMLATRISFMNELANLADRFGADIEAVRRGIGSDPRIGYHFLYAGCGYGGSCFPKDVEALIRTADEHGQSLQILKAVSSVNATQKRVLADKIVARFGEDLTGRTFAIWGLAFKPNTDDMREAPSRELIAELLSRGARIAAYDPVAQEEARRVIALDLADHPSWLERLSFVDDEAQAARDADALVIVTEWKIFKSPDFVALGRLWKTPVIFDGRNLYEPETMSEQGIEYHPIGRPGSRQAVAARVTGTAPASA
->7pi2_J mol:protein length:343  Cysteine-rich protective antigen
-DSRHVFIRTELSFIKNNVPCIRDMFFIYKRELYNICLDDLKGEEDETHIYVQKKVKDSWITLNDLFKETDLTGRPHIFAYVDVEEIIILLCEDEEFSNRKKDMTCHRFYSNDGKEYNNAEITISDYILKDKLLSSYVSLPLKIENREYFLICGVSPYKFKDDNKKDDILCMASHDKGETWGTKIVIKYDNYKLGVQYFFLRPYISKNDLSFHFYVGDNINNVKNVNFIECTHEKDLEFVCSNRDFLKDNKVLQDVSTLNDEYIVSYGNDNNFAECYIFFNNENSILIKPEKYGNTAAGCYGGTFVKIDENRALFIYSSSQGIYNIHTIYYANYEGGGGSEPEA
->1n2r_A mol:protein length:276  HLA class I histocompatibility antigen, BW-44(B-12) B*4403 alpha chain
-GSHSMRYFYTAMSRPGRGEPRFITVGYVDDTLFVRFDSDATSPRKEPRAPWIEQEGPEYWDRETQISKTNTQTYRENLRTALRYYNQSEAGSHIIQRMYGCDVGPDGRLLRGYDQDAYDGKDYIALNEDLSSWTAADTAAQITQRKWEAARVAEQLRAYLEGLCVESLRRYLENGKETLQRADPPKTHVTHHPISDHEVTLRCWALGFYPAEITLTWQRDGEDQTQDTELVETRPAGDRTFQKWAAVVVPSGEEQRYTCHVQHEGLPKPLTLRWEP
->2nxx_B mol:protein length:235  Ultraspiracle (USP, NR2B4)
-MTSNLQADMPLERIIEAEKRVECNDPLVALVVNENNTTVNNICQATHKQLFQLVQWAKLVPHFTSLPLTDQVQLLRAGWNELLIAAFSHRSMQAQDAIVLATGLTVNKSTAHAVGVGNIYDRVLSELVNKMKEMKMDKTELGCLRAIILYNPDVRGIKSVQEVEMLREKIYGVLEEYTRTTHPNEPGRFAKLLLRLPALRSIGLKCLEHLFFFKLIGDVPIDTFLMEMLEGTTDS
->4s3s_A mol:protein length:143  Thermonuclease
-ATSTKKLHKEPATLIKAIDGDTAKLMYKGQPMTFRLLLVDTPEFNEKYGPEASAFTKKMVENAKKIEVEFDKGQRTDKYGRGLAYKYADGKMVNEALVRQGLAKVAYVYKGNNTHEQLLRKAEAQAKKEKLNIWSEDNADSGQ
->4e9x_C mol:protein length:339  Multicopper oxidase
-MAEREFDMTIEEVTIKVAPGLDYKVFGFNGQVPGPLIHVQEGDDVIVNVTNNTSLPHTIHWHGVHQKGTWRSDGVPGVTQQPIEAGDSYTYKFKADRIGTLWYHCHVNVNEHVGVRGMWGPLIVDPKQPLPIEKRVTKDVIMMMSTWESAVADKYGEGGTPMNVADYFSVNAKSFPLTQPLRVKKGDVVKIRFFGAGGGIHAMHSHGHDMLVTHKDGLPLDSPYYADTVLVSPGERYDVIIEADNPGRFIFHDHVDTHVTAGGKHPGGPITVIEYDGVPVDDWYVWKDKDYDPNFFYSESLKQGYGMFDHDGFKGEFEQRQRRPGRKLAAALEHHHHHH
->6tg2_A mol:protein length:351  MotA
-MGSSHHHHHHSSGLVPRGSHMDVVIASSGGGWQEAQDKALWAPAAKALNITYTQDTFQNWAEARAQVESGSVTWDIIQIGIADEPQAKAAGVLEKLDPDIVNKADFPPGSVTDSFVANSNYSTLIAWNKKTYGDNGPKSMADFFDVKKFPGKRALWNQPIGMIEAAALALGTPRDKVYEFLSTEEGRKAAIAKLTELAPSVSVWWESGAQAAQLIKDGEVDMIITWGGRVQGAINDGANFAYTFNDAQLGTDGYAIVKGAPHRDAAMRFLKEMSKAEYQKDLPNSFATAPANMKAYDLAKYTPEKMATMASAPENVAVQYSVDPNFWAKHAKWASEAYDNVRLSRHHHHHH
->6p60_K mol:protein length:212  Antibody A12V163-a.02 light chain
-QFVLAQPPSVSGAPGQRVTLSCTGSNSNIGVNYVQWYQQLPGTAPKLLIYENNKRPSGVSDRFSGSQSGTSASLTITGLQSEDEADYYCQCYDISLGAHVFGSGTELTVLGQPKAAPSVTLFPPSSEELQANKATLVCLISDFYPGAVEVAWKADGSAVNAGVETTKPSKQSNNKYAASSYLSLTSDQWKSHKSYSCQVTHEGSTVEKTVAP
->5pg2_A mol:protein length:138  Bromodomain adjacent to zinc finger domain protein 2B
-MHHHHHHSSGVDLGTENLYFQSMSVKKPKRDDSKDLALCSMILTEMETHEDAWPFLLPVNLKLVPGYKKVIKKPMDFSTIREKLSSGQYPNLETFALDVRLVFDNCETFNEDDSDIGRAGHNMRKYFEKKWTDTFKVS
->2oa6_C mol:protein length:320  Aristolochene synthase
-MKKPNGTNGASSSLEPPPSTFQPLCHPLVEEVSKEVDGYFLQHWNFPNEKARKKFVAAGFSRVTCLYFPKALDDRIHFACRLLTVLFLIDDLLEYMSFEEGSAYNEKLIPISRGDVLPDRSIPVEYIIYDLWESMRAHDREMADEILEPVFLFMRAQTDRTRARPMGLGGYLEYRERDVGKELLAALMRFSMGLKLSPSELQRVREIDANCSKHLSVVNDIYSYEKELYTSKTAHSEGGILCTSVQILAQEADVTAEAAKRVLFVMCREWELRHQLLVARLSAEGLETPGLAAYVEGLEYQMSGNELWSQTTLRYSVVVD
->6qz0_5b mol:protein length:448  Major capsid protein
-MRITFNDVKTSLGITESYDIVNAIRNSQGDNFKSYVPLATANNVAEVGAGILINQTVQNDFITSLVDRIGLVVIRQVSLNNPLKKFKKGQIPLGRTIEEIYTDITKEKQYDAEEAEQKVFEREMPNVKTLFHERNRQGFYHQTIQDDSLKTAFVSWGNFESFVSSIINAIYNSAEVDEYEYMKLLVDNYYSKGLFTTVKIDEPTSSTGALTEFVKKMRATARKLTLPQGSRDWNSMAVRTRSYMEDLHLIIDADLEAELDVDVLAKAFNMNRTDFLGNVTVIDGFASTGLEAVLVDKDWFMVYDNLHKMETVRNPRGLYWNYYYHVWQTLSVSRFANAVAFVSGDVPAVTQVIVSPNIAAVKQGGQQQFTAYVRATNAKDHKVVWSVEGGSTGTAITGDGLLSVSGNEDNQLTVKATVDIGTEDKPKLVVGEAVVSIRPNNASGGAQA
->7eqd_3 mol:protein length:62  Light-harvesting protein B-870 alpha chain
-MWRIWQLFDPRQALVGLATFLFVLALLIHFILLSTERFNWLEGASTKPVQTSMVMPSSDLAV
->5k5o_A mol:protein length:98  AspA
-GKISTDKYIFLTPRAYIIVHLLKVGKAKASEISENTQIPYQTVIQNIRWLLAEGYVVKEQKGEEIYYKLTDKGKQLATAELEKIRKLVEVVQHHHHHH
->3dby_N mol:protein length:269  uncharacterized protein
-MSLERNYEESALFEHQFWLKVLTDHAQFLLDALAPKEKEDIKKATYFVETFTNLLNKVRNVNLMAFSKEAEQAAKEIRAFKLNIIQKQLEGKITIHFTPTFINHMVNEVEEYIAVLEFLKKGEVPPVFHELHYHLVWLTDAAGHAGSISGGLDLVEKRLKEKSEEFTKHFEQFYLKAVEMTGYLRTELHHFPALKKFTKDVSLELKLFSHFLHEVEELELSNEVLSVLSARMADHMAREECYYLLKLAQSSGLEMPKCNPLEGHHHHHH
->1sfo_E mol:protein length:215  DNA-directed RNA polymerases I, II, and III 27 kDa polypeptide
-MDQENERNISRLWRAFRTVKEMVKDRGYFITQEEVELPLEDFKAKYCDSMGRPQRKMMSFQANPTEESISKFPDMGSLWVEFCDEPSVGVKTMKTFVIHIQEKNFQTGIFVYQNNITPSAMKLVPSIPPATIETFNEAALVVNITHHELVPKHIRLSSDEKRELLKRYRLKESQLPRIQRADPVALYLGLKRGEVVKIIRKSETSGRYASYRICM
->2zee_B mol:protein length:329  Glutaminyl-peptide cyclotransferase
-ASAWPEEKNYHQPAILNSSALRQIAEGTSISEMWQNDLQPLLIERYPGSPGSYAARQHIMQRIQRLQADWVLEIDTFLSQTPYGYRSFSNIISTLNPTAKRHLVLACHYDSKYFSHWNNRVFVGATDGAVPCAMMLELARALDKKLLSLKTVSDSKPDLSLQLIFFDGEEAFLHWSPQDSLYGSRHLAAKMASTPHPPGARGTSQLHGMDLLVLLDLIGAPNPTFPNFFPNSARWFERLQAIEHELHELGLLKDHSLEGRYFQNYSYGGVIQDDHIPFLRRGVPVLHLIPSPFPEVWHTMDDNEENLDESTIDNLNKILQVFVLEYLHL
->6cae_1c mol:protein length:239  30S ribosomal protein S3
-MGNKIHPIGFRLGITRDWESRWYAGKKQYRHLLLEDQRIRGLLEKELYSAGLARVDIERAADNVAVTVHVAKPGVVIGRGGERIRVLREELAKLTGKNVALNVQEVQNPNLSAPLVAQRVAEQIERRFAVRRAIKQAVQRVMESGAKGAKVIVSGRIGGAEQARTEWAAQGRVPLHTLRANIDYGFALARTTYGVLGVKAYIFLGEVIGGQKPKARPELPKAEERPRRRRPAVRVKKEE
->3hhq_J mol:protein length:167  Deoxyuridine 5'-triphosphate nucleotidohydrolase
-MGSSHHHHHHSSGLVPRGSHMTATSDKVLKIQLRSASATVPTKGSATAAGYDIYASQDITIPAMGQGMVSTDISFTVPVGTYGRIAPRSGLAVKNGIQTGAGVVDRDYTGEVKVVLFNHSQRDFAIKKGDRVAQLILEKIVDDAQIVVVDSLEESARGAGGFGSTGN
->2a3s_A mol:protein length:101  Myocyte Nuclear Factor
-ESKPPYSYAQLIVQAISSAQDRQLTLSGIYAHITKHYPYYRTADKGWQNSIRHNLSLNRYFIKVPRSQEEPGKGSFWRIDPASEAKLVEQAFRKRRQRGVS
->5dcp_A mol:protein length:175  Filamin-B
-SMMNGLGFKPFDLVIPFAVRKGEITGEVHMPSGKTATPEIVDNKDGTVTVRYAPTEVGLHEMHIKYMGSHIPESPLQFYVNYPNSGSVSAYGPGLVYGVANKTATFTIVTEDAGEGGLDLAIEGPSKAEISCIDNKDGTCTVTYLPTLPGDYSILVKYNDKHIPGSPFTAKITDD
->2qsp_B mol:protein length:145  Hemoglobin subunit beta
-MLTAEEKAAVTAFWGKVKVDEVGGEALGRLLVVYPWTQRFFESFGDLSTADAVMNNPKVKAHGKKVLDSFSNGMKHLDDLKGTFAALSELHCDKLHVDPENFKLLGNVLVVVLARNFGKEFTPVLQADFQKVVAGVANALAHRYH
->3fp9_H mol:protein length:153  Proteasome-associated ATPase
-MPSGYGVLLATHDDDTVDVFTSGRKMRLTCSPNIDAASLKKGQTVRLNEALTVVEAGTFEAVGEISTLREILADGHRALVVGHADEERVVWLADPLIAEDLPDGLPEALNDDTRPRKLRPGDSLLVDTKAGYAFERIPKAEVEDLVLEELVPR
->6v3o_E mol:protein length:970  Phosphoenolpyruvate carboxylase
-MASTKAPGPGEKHHSIDAQLRQLVPGKVSEDDKLIEYDALLVDRFLNILQDLHGPSLREFVQECYEVSADYEGKGDTTKLGELGAKLTGLAPADAILVASSILHMLNLANLAEEVQIAHRRRNSKLKKGGFADEGSATTESDIEETLKRLVSEVGKSPEEVFEALKNQTVDLVFTAHPTQSARRSLLQKNARIRNCLTQLNAKDITDDDKQELDEALQREIQAAFRTDEIRRAQPTPQDEMRYGMSYIHETVWKGVPKFLRRVDTALKNIGINERLPYNVSLIRFSSWMGGDRDGNPRVTPEVTRDVCLLARMMAANLYIDQIEELMFELSMWRCNDELRVRAEELHSSSGSKVTKYYIEFWKQIPPNEPYRVILGHVRDKLYNTRERARHLLASGVSEISAESSFTSIEEFLEPLELCYKSLCDCGDKAIADGSLLDLLRQVFTFGLSLVKLDIRQESERHTDVIDAITTHLGIGSYREWSEDKRQEWLLSELRGKRPLLPPDLPQTEEIADVIGAFHVLAELPPDSFGPYIISMATAPSDVLAVELLQRECGVRQPLPVVPLFERLADLQSAPASVERLFSVDWYMDRIKGKQQVMVGYSDSGKDAGRLSAAWQLYRAQEEMAQVAKRYGVKLTLFHGRGGTVGRGGGPTHLAILSQPPDTINGSIRVTVQGEVIEFCFGEEHLCFQTLQRFTAATLEHGMHPPVSPKPEWRKLMDEMAVVATEEYRSVVVKEARFVEYFRSATPETEYGRMNIGSRPAKRRPGGGITTLRAIPWIFSWTQTRFHLPVWLGVGAAFKFAIDKDVRNFQVLKEMYNEWPFFRVTLDLLEMVFAKGDPGIAGLYDELLVAEELKPFGKQLRDKYVETQQLLLQIAGHKDILEGDPFLKQGLVLRNPYITTLNVFQAYTLKRIRDPNFKVTPQPPLSKEFADENKPAGLVKLNPASEYPPGLEDTLILTMKGIAAGMQNTG
->2gf0_C mol:protein length:199  GTP-binding protein Di-Ras1
-SMPEQSNDYRVVVFGAGGVGKSSLVLRFVKGTFRDTYIPTIEDTYRQVISCDKSVCTLQITDTTGSHQFPAMQRLSISKGHAFILVFSVTSKQSLEELGPIYKLIVQIKGSVEDIPVMLVGNKCDETQREVDTREAQAVAQEWKCAFMETSAKMNYNVKELFQELLTLETRRNMSLNIDGKRSGKQKRTDRVKGKCTLM
->1p3q_Q mol:protein length:54  Vacuolar protein sorting-associated protein VPS9
-SSLIKKIEENERKDTLNTLQNMFPDMDPSLIEDVCIAAASRIGPCVDALLSLSE
->3c91_O mol:protein length:233  Proteasome subunit alpha
-MQQGQMAYDRAITVFSPDGRLFQVEYAREAVKKGSTALGMKFANGVLLISDKKVRSRLIEQNSIEKIQLIDDYVAAVTSGLVADARVLVDFARISAQQEKVTYGSLVNIENLVKRVADQMQQYTQYGGVRPYGVSLIFAGIDQIGPRLFDCDPAGTINEYKATAIGSGKDAVVSFLEREYKENLPEKEAVTLGIKALKSSLEEGEELKAPEIASITVGNKYRIYDQEEVKKFL
->4wra_1A mol:protein length:105  30S ribosomal protein S10
-MPKIRIKLRGFDHKTLDASAQKIVEAARRSGAQVSGPIPLPTRVRRFTVIRGPFKHKDSREHFELRTHNRLVDIINPNRKTIEQLMTLDLPTGVEIEIKTVGGGR
->4n06_A mol:protein length:347  CRISPR-associated endonuclease Cas1 1
-GGMRLVVDGFGKYLGIENGLIVVKEKGKALRKVRPEDLKQVLIIGKAAISSDAIKLLLKNRVDVVFLDFNGEILGRLSHPLIGTAKTRREQYLAYGDKRGVHLAKEFIKAKMANQMAILTNLAKARKDSNPEVAESLLKAKKEIDACLNELDGVEAEMIDKVRERLLGIEGKASKHYWDAISLVIPEEYRFNGRRGIEIGSPRYAKDIVNAMLNYGYSILLAECVKAVELAGLDPYAGFLHVDVSGRSSLAIDLMENFRQQVVDRVVLRLISYRQIKPEDCEKRNMVCQLSDNARRLLLASLLERLDSKTQYRGRNLAYSSIILLHARDVVAFLRGERRYEGFVQKW
->6d6e_A mol:protein length:129  Lysozyme C
-KVFGRCELAAAMKRHGLDNYRGYSLGNWVCAAKFESNFNTQATNRNTDGSTDYGILQINSRWWCNDGRTPGSRNLCNIPCSALLSSDITASVNCAKKIVSDGNGMNAWVAWRNRCKGTDVQAWIRGCRL
->1v1m_A mol:protein length:400  2-OXOISOVALERATE DEHYDROGENASE ALPHA SUBUNIT
-SSLDDKPQFPGASAEFIDKLEFIQPNVISGIPIYRVMDRQGQIINPSEDPHLPKEKVLKLYKSMTLLNTMDRILYESQRQGRISFYMTNYGEEGTHVGSAAALDNTDLVFGQYREAGVLMYRDYPLELFMAQCYGNISDLGKGRQMPVHYGCKERHFVTISSPLATQIPQAVGAAYAAKRANANRVVICYFGEGAASEGDAHAGFNFAATLECPIIFFCRNNGYAISTPTSEQYRGDGIAARGPGYGIMSIRVDGNDVFAVYNATKEARRRAVAENQPFLIEAMTYRIGHASTSADSSAFRSVDEVNYWDKQDHPISRLRHYLLSQGWWDEEQEKAWRKQSRRKVMEAFEQAERKPKPNPNLLFSDVYQEMPAQLRKQQESLARHLQTYGEHYPLDHFDK
->7pak_H mol:protein length:132  30S ribosomal protein S9
-MEKQSYYGLGRRKSSSAKVYLTPTQDKGKITVNRRDPSEYFPNKLVIQDMEQPLDLTDLKKNFDINVVVKGGGFTGQAGAIRLGIVRALLQFNPELKKILKSKKLTTRDKRVKERKKFGLYGARRAPQFTKR
->4gob_A mol:protein length:230  Kaede-type Fluorescent Protein
-MSVIKSDMKIKLRMEGTVNGHKFVIEGEGEGKPYEGTQTMNLKVKEGAPLPFAYDILTTVFHYGNRVFAKYPKHIPDYFKQSFPEGYSWERSMTFEDGGICTARNDITLEGDCFFNEIRFDGVNFPPNGPVMQKKTLKWEPSTEKMYVRDGVLTGDINMALLLEGGGHYRCDFKTTYKAKKGVQLPDYHFVDHCIEILSHDKDYNNVKLYEHAVAHSGLPRQAKHHHHHH
->5f5k_B mol:protein length:7  Peptidic derivative of Gurken: ACE-ARG-LYS-VAL-ARG-MET-ALA-aldehyde
-XRKVRMX
->6rkm_P mol:protein length:12  Cellular tumor antigen p53
-KLMFKTEGPDSD
->2p1m_B mol:protein length:594  TRANSPORT INHIBITOR RESPONSE 1 protein
-MQKRIALSFPEEVLEHVFSFIQLDKDRNSVSLVCKSWYEIERWCRRKVFIGNCYAVSPATVIRRFPKVRSVELKGKPHFADFNLVPDGWGGYVYPWIEAMSSSYTWLEEIRLKRMVVTDDCLELIAKSFKNFKVLVLSSCEGFSTDGLAAIAATCRNLKELDLRESDVDDVSGHWLSHFPDTYTSLVSLNISCLASEVSFSALERLVTRCPNLKSLKLNRAVPLEKLATLLQRAPQLEELGTGGYTAEVRPDVYSGLSVALSGCKELRCLSGFWDAVPAYLPAVYSVCSRLTTLNLSYATVQSYDLVKLLCQCPKLQRLWVLDYIEDAGLEVLASTCKDLRELRVFPSEPFVMEPNVALTEQGLVSVSMGCPKLESVLYFCRQMTNAALITIARNRPNMTRFRLCIIEPKAPDYLTLEPLDIGFGAIVEHCKDLRRLSLSGLLTDKVFEYIGTYAKKMEMLSVAFAGDSDLGMHHVLSGCDSLRKLEIRDCPFGDKALLANASKLETMRSLWMSSCSVSFGACKLLGQKMPKLNVEVIDERGAPDSRPESCPVERVFIYRTVAGPRFDMPGFVWNMDQDSTMRFSRQIITTNGL
->1jf1_B mol:protein length:100  beta-2-microglobulin
-MIQRTPKIQVYSRHPAENGKSNFLNCYVSGFHPSDIEVDLLKNGERIEKVEHSDLSFSKDWSFYLLYYTEFTPTEKDEYACRVNHVTLSQPKIVKWDRDM
->7vot_Y mol:protein length:53  Rsp_7571 Protein-Y PufY
-MPEVSEFAFRLMMAAVIFVGVGIMFAFAGGHWFVGLVVGGLVAAFFAATPNSN
->7o11_C mol:protein length:308  Probable ABC transporter ATP-binding protein NosF
-MNAVEIQGVSQRYGSMTVLHDLNLNLGEGEVLGLFGHNGAGKTTSMKLILGLLSPSEGQVKVLGRAPNDPQVRRQLGYLPENVTFYPQLSGRETLRHFARLKGAALTQVDELLEQVGLAHAADRRVKTYSKGMRQRLGLAQALLGEPRLLLLDEPTVGLDPIATQDLYLLIDRLRQRGTSIILCSHVLPGVEAHINRAAILAKGCLQAVGSLSQLRAEAGLPVRIRASGISERDSWLQRWTDAGHSARGLSESSIEVVAVNGHKLVLLRQLLGEGEPEDIEIHQPSLEDLYRYYMERAGDVRAQEGRL
->7nt9_A mol:protein length:1287  Spike glycoprotein
-MGILPSPGMPALLSLVSLLSVLLMGCVAETGMFVFLVLLPLVSSQCVNLTTRTQLPPAYTNSFTRGVYYPDKVFRSSVLHSTQDLFLPFFSNVTWFHAIHVSGTNGTKRFDNPVLPFNDGVYFASTEKSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCEFQFCNDPFLGVYYHKNNKSWMESEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLREFVFKNIDGYFKIYSKHTPINLVRDLPQGFSALEPLVDLPIGINITRFQTLLALHRSYLTPGDSSSGWTAGAAAYYVGYLQPRTFLLKYNENGTITDAVDCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESIVRFPNITNLCPFGEVFNATRFASVYAWNRKRISNCVADYSVLYNSASFSTFKCYGVSPTKLNDLCFTNVYADSFVIRGDEVRQIAPGQTGKIADYNYKLPDDFTGCVIAWNSNNLDSKVGGNYNYLYRLFRKSNLKPFERDISTEIYQAGSTPCNGVEGFNCYFPLQSYGFQPTNGVGYQPYRVVVLSFELLHAPATVCGPKKSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFGRDIADTTDAVRDPQTLEILDITPCSFGGVSVITPGTNTSNQVAVLYQDVNCTEVPVAIHADQLTPTWRVYSTGSNVFQTRAGCLIGAEHVNNSYECDIPIGAGICASYQTQTNSPSRASSVASQSIIAYTMSLGAENSVAYSNNSIAIPTNFTISVTTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLNRALTGIAVEQDKNTQEVFAQVKQIYKTPPIKDFGGFNFSQILPDPSKPSKRSFIEDLLFNKVTLADAGFIKQYGDCLGDIAARDLICAQKFNGLTVLPPLLTDEMIAQYTSALLAGTITSGWTFGAGAALQIPFAMQMAYRFNGIGVTQNVLYENQKLIANQFNSAIGKIQDSLSSTASALGKLQDVVNQNAQALNTLVKQLSSNFGAISSVLNDILSRLDPPEAEVQIDRLITGRLQSLQTYVTQQLIRAAEIRASANLAATKMSECVLGQSKRVDFCGKGYHLMSFPQSAPHGVVFLHVTYVPAQEKNFTTAPAICHDGKAHFPREGVFVSNGTHWFVTQRNFYEPQIITTDNTFVSGNCDVVIGIVNNTVYDPLQPELDSFKEELDKYFKNHTSPDVDLGDISGINASVVNIQKEIDRLNEVAKNLNESLIDLQELGKYEQSGRENLYFQGGGGSGYIPEAPRDGQAYVRKDGEWVLLSTFLGHHHHHH
->5euj_T mol:protein length:573  Pyruvate decarboxylase
-MYTVGMYLAERLAQIGLKHHFAVAGDYNLVLLDQLLLNKDMEQVYCCNELNCGFSAEGYARARGAAAAIVTFSVGAISAMNAIGGAYAENLPVILISGSPNTNDYGTGHILHHTIGTTDYNYQLEMVKHVTCAAESIVSAEEAPAKIDHVIRTALRERKPAYLEIACNVAGAECVRPGPINSLLRELEVDQTSVTAAVDAAVEWLQDRQNVVMLVGSKLRAAAAEKQAVALADRLGCAVTIMAAAKGFFPEDHPNFRGLYWGEVSSEGAQELVENADAILCLAPVFNDYATVGWNSWPKGDNVMVMDTDRVTFAGQSFEGLSLSTFAAALAEKAPSRPATTQGTQAPVLGIEAAEPNAPLTNDEMTRQIQSLITSDTTLTAETGDSWFNASRMPIPGGARVELEMQWGHIGWSVPSAFGNAVGSPERRHIMMVGDGSFQLTAQEVAQMIRYEIPVIIFLINNRGYVIEIAIHDGPYNYIKNWNYAGLIDVFNDEDGHGLGLKASTGAELEGAIKKALDNRRGPTLIECNIAQDDCTETLIAWGKRVAATNSRKPQALVPRGSGGGLEHHHHHH
->5y6p_A2 mol:protein length:318  LR_gamma4
-MDSPAFAVNGMFSAVKVGNSSFTENKVTAVSKTAPTASVRMVVDPFQRKFQSIGKIGIDYSRPKKLATYKRVGYSVGLDFPNAVSMAGHYSLTDCTRAGGAAKILMKYDEYCAKGMLQVYKRSAVSTGVYTTKCTEATQPGVAYDVRVFNRTAAFRQAQKPVNVRLGEQYAARKACVTLAHNCSREEAQFKNMPMSCATFLAGKMEAMGTCYRTVRPSSKAEDYMAGSVRMQVYQKGNASGVYPVGGCEDGHAKGDADLRRVIALASEYRAAQQGAAAVTGAQYASSKMAIQLYGHSCNHEEGQFCDYPAVAAAMCRY
->7qgr_S mol:protein length:179  50S ribosomal protein L5
-MAKLHDYYKDEVVKKLMTEFNYNSVMQVPRVEKITLNMGVGEAIADKKLLDNAAADLAAISGQKPLITKARKSVAGFKIRQGYPIGCKVTLRGERMWEFFERLITIAVPRIRDFRGLSAKSFDGRGNYSMGVREQIIFPEIDYDKVDRVRGLDITITTTAKSDEEGRALLAAFDFPFRK
->3q9i_A mol:protein length:10  Cyclic pseudo-peptide LV(4BF)FA(ORN)(HAO)LK(ORN)
-LVYFAAXLKA
->4a35_A mol:protein length:441  MITOCHONDRIAL ENOLASE SUPERFAMILY MEMBER 1
-SMVRGRISRLSVRDVRFPTSLGGHGADAMHTDPDYSAAYVVIETDAEDGIKGCGITFTLGKGTEVVVCAVNALAHHVLNKDLKDIVGDFRGFYRQLTSDGQLRWIGPEKGVVHLATAAVLNAVWDLWAKQEGKPVWKLLVDMDPRMLVSCIDFRYITDVLTEEDALEILQKGQIGKKEREKQMLAQGYPAYTTSCAWLGYSDDTLKQLCAQALKDGWTRFKVKVGADLQDDMRRCQIIRDMIGPEKTLMMDANQRWDVPEAVEWMSKLAKFKPLWIEEPTSPDDILGHATISKALVPLGIGIATGEQCHNRVIFKQLLQAKALQFLQIDSCRLGSVNENLSVLLMAKKFEIPVCPHAGGVGLCELVQHLIIFDYISVSASLENRVCEYVDHLHEHFKYPVMIQRASYMPPKDPGYSTEMKEESVKKHQYPDGEVWKKLLPA
->3zpv_S mol:protein length:62  PROTEIN PYGOPUS
-GAMAIYPCGMCHKEVNDNDEAVFCESGCNFFFHRTCVGLTEAAFQMLNKEVFAEWCCDKCVS
->7y15_C mol:protein length:71  Guanine nucleotide-binding protein G(I)/G(S)/G(O) subunit gamma-2
-MASNNTASIAQARKLVEQLKMEANIDRIKVSKAAADLMAYCEAHAKEDPLLTPVPASENPFREKKFFCAIL
->3glh_D mol:protein length:376  DNA polymerase III subunit tau
-GPHMSYQVLARKWRPQTFADVVGQEHVLTALANGLSLGRIHHAYLFSGTRGVGKTSIARLLAKGLNCETGITATPCGVCDNCREIEQGRFVDLIEIDAASRTKVEDTRDLLDNVQYAPARGRFKVYLIDEVHMLSRHSFNALLKTLEEPPEHVKFLLATTDPQKLPVTILSRCLQFHLKALDVEQIRHQLEHILNEEHIAHEPRALQLLARAAEGSLRDALSLTDQAIASGDGQVSTQAVSAMLGTLDDDQALSLVEAMVEANGERVMALINEAAARGIEWEALLVEMLGLLHRIAMVQLSPAALGNDMAAIELRMRELARTIPPTDIQLYYQTLLIGRKELPYAPDRRMGVEMTLLRALAFHPRMPLPEPEVPRQ
->3k6s_C mol:protein length:1095  Integrin alpha-X
-FNLDTEELTAFRVDSAGFGDSVVQYANSWVVVGAPQKITAANQTGGLYQCGYSTGACEPIGLQVPPEAVNMSLGLSLASTTSPSQLLACGPTVHHECGRNMYLTGLCFLLGPTQLTQRLPVSRQECPRQEQDIVFLIDGSGSISSRNFATMMNFVRAVISQFQRPSTQFSLMQFSNKFQTHFTFEEFRRSSNPLSLLASVHQLQGFTYTATAIQNVVHRLFHASYGARRDAAKILIVITDGKKEGDSLDYKDVIPMADAAGIIRYAIGVGLAFQNRNSWKELNDIASKPSQEHIFKVEDFDALKDIQNQLKEKIFAIEGTETTSSSSFELEMAQEGFSAVFTPDGPVLGAVGSFTWSGGAFLYPPNMSPTFINMSQENVDMRDSYLGYSTELALWKGVQSLVLGAPRYQHTGKAVIFTQVSRQWRMKAEVTGTQIGSYFGASLCSVDVDSDGSTDLVLIGAPHYYEQTRGGQVSVCPLPRGWRRWWCDAVLYGEQGHPWGRFGAALTVLGDVNGDKLTDVVIGAPGEEENRGAVYLFHGVLGPSISPSHSQRIAGSQLSSRLQYFGQALSGGQDLTQDGLVDLAVGARGQVLLLRTRPVLWVGVSMQFIPAEIPRSAFECREQVVSEQTLVQSNICLYIDKRSKNLLGSRDLQSSVTLDLALDPGRLSPRATFQETKNRSLSRVRVLGLKAHCENFNLLLPSCVEDSVTPITLRLNFTLVGKPLLAFRNLRPMLAADAQRYFTASLPFEKNCGADHICQDNLGISFSFPGLKSLLVGSNLELNAEVMVWNDGEDSYGTTITFSHPAGLSYRYVAEGQKQGQLRSLHLTCDSAPVGSQGTWSTSCRINHLIFRGGAQITFLATFDVSPKAVLGDRLLLTANVSSENNTPRTSKTTFQLELPVKYAVYTVVSSHEQFTKYLNFSESEEKESHVAMHRYQVNNLGQRDLPVSINFWVPVELNQEAVWMDVEVSHPQNPSLRCSSEKIAPPASDFLAHIQKNPVLDCSIAGCLRFRCDVPSFSVQEELDFTLKGNLSFGWVRQILQKKVSVVSVAEITFDTSVYSQLPGQEAFMRAQTTTVLEKYKVHGCGGLENLYFQ
->3tvu_C mol:protein length:769  Acetyl-CoA carboxylase
-MASGSMHLRPIATPYPVKEWLQPKRYKAHLMGTTYVYDFPELFRQASSSQWKNFSADVKLTDDFFISNELIEDENGELTEVEREPGANAIGMVAFKITVKTPEYPRGRQFVVVANDITFKIGSFGPQEDEFFNKVTEYARKRGIPRIYLAANSGARIGMAEEIVPLFQVAWNDAANPDKGFQYLYLTSEGMETLKKFDKENSVLTERTVINGEERFVIKTIIGSEDGLGVECLRGSGLIAGATSRAYHDIFTITLVTCRSVGIGAYLVRLGQRAIQVEGQPIILTGASALNKVLGREVYTSNLQLGGTQIMYNNGVSHLTAVDDLAGVEKIVEWMSYVPAKRNMPVPILETKDTWDRPVDFTPTNDETYDVRWMIEGRETESGFEYGLFDKGSFFETLSGWAKGVVVGRARLGGIPLGVIGVETRTVENLIPADPANPNSAETLIQQAGQVWFPNSAFKTAQAINDFNNGEQLPMMILANWRGFSGGQRDMFNEVLKYGSFIVDALVDYKQPIIIYIPPTGELRGGSWVVVDPTINADQMEMYADVNARAGVLEPEGTVEIKFRREKLLDTMNRLDDKYRELRSQLSNKSLAPEVHQQISKQLADRERELLPIYGQISLQFADLHDRSSRMVAKGVISKELEWTEARRFFFWRLRRRLNEEYLIKRLSHQVGEASRLEKIARIRSWYPASVDHEDDRQVATWIEENYKTLDDKLKGLKLESFAQDLAKKIRSDHDNAIDGLSEVIKMLSTDDKEKLLKTLKLEHHHHHH
->2kj4_A mol:protein length:87  plasminogen
-YVEFSEECMHGSGENYDGKISKTMSGLECQAWDSQSPHAHGYIPSKFPNKNLKKNYCRNPDRDLRPWCFTTDPNKRWEYCDIPRCAA
->7s3d_G mol:protein length:782  Photosystem I P700 chlorophyll a apoprotein A1
-MTASPPKRNQASAATEQSPIPTSFERWAKPGHFDRTLARGPKTTTWIWNLHADAHDFDSHTNDLQDISRKIFSAHFGHLAVVFVWLSGMYFHGARFSNFSSWMADPTHIRPSAQVVWPLVGQDILNGDMGGGFRGIQITSGLFQMWRGEGFTNEFQLYCTAIGALVMAGLMIFAGWFHYHVRSPKLEWFQNVQSMLNHHLAGLLGLGSLGWAGHLIHVALPTNKLLDAGVAPQDIPLPHEFVLDKALMAELYPSFAQGIRPFFTLNWATYSDFLTFNGGLNPVTGGLWMTDIAHHHVAIAVLFIFAGHMYRTNWGIGHSIRTMLEDARHPKMLPFLSFIGPVGHRGLFEVLTTSWHAQLSINLAMMGSLSIIVAQHMYSMPPYPYLATDYGTVTSLFTHHMWIGGFLIVGAAAHAGIFMVRDYDPAENVNNVLDRVLRHRDAIISHLVWVCQFLGFHSFAMYCHNDTMRAFGRPQDMFSDTGIQLQPIFAQWVQHIQTMAVGSAQVAEPLGDALGGIQNIALSGVGTTAPGVASPASYAFGGGLVAVGGKVAMMPISLGTADFLIHHIHAFTIHVTVLVLLKGVLFARNSRLIPDKSELGFRFPCDGPGRGGTCQVSAWDHVFLGLFWMYNSIAMVIFHFFWKMQSDVWGAVDANGTVSHITGGNFAQSSITINGWLRDFLWAQATQVISSYGSALSAYGLMFLAGHFVFAFSLMFLFSGRGYWQELIESIVWAHNKLRITTAIQPRALSITQGRAVGAAHYLLGSIVTTWAFFLARMAAIG
->1hqz_9 mol:protein length:141  ACTIN-BINDING PROTEIN
-MALEPIDYTTHSREIDAEYLKIVRGSDPDTTWLIISPNAKKEYEPESTGSSFHDFLQLFDETKVQYGLARVSPPGSDVEKIIIIGWCPDSAPLKTRASFAANFAAVANNLFKGYHVQVTARDEDDLDENELLMKISNAAGA
->6fq5_H mol:protein length:95  Histone H2B
-RKTRKESYAIYVYKVLKQVHPDTGISSKAMSIMNSFVNDVFERIAGEASRLAHYNKRSTITSREIQTAVRLLLPGELAKHAVSEGTKAVTKYTSA
->6ek5_L mol:protein length:205  Capsid protein
-APMYRKPTMYRMYRSPDIPRGCEGPCKVQSFEQRDDVKHLGICKVISDVTRGPGLTHRVGKRFCIKSIYILGKIWLDETIKKQNHTNNVIFYLLRDRRPYGNAPQDFGQIFNMFDNEPSTATIKNDLRDRFQVLRKFHATVVGGLYCMKEQALVKRFYRLNHHVTYNHQEAGKYENHTENALLLYMACTHASNPVYATLKIRIYF
->6f7b_A mol:protein length:361  Mitotic checkpoint serine/threonine-protein kinase BUB1
-GSSLGTVDAPNFIVGNPWDDKLIFKLLSGLSKPVSSYPNTFEWQCKLPAIKPKTEFQLGSKLVYVHHLLGEGAFAQVYEATQGDLNDAKNKQKFVLKVQKPANPWEFYIGTQLMERLKPSMQHMFMKFYSAHLFQNGSVLVGELYSYGTLLNAINLYKNTPEKVMPQGLVISFAMRMLYMIEQVHDCEIIHGDIKPDNFILGNGFLEQDDEDDLSAGLALIDLGQSIDMKLFPKGTIFTAKCETSGFQCVEMLSNKPWNYQIDYFGVAATVYCMLFGTYMKVKNEGGECKPEGLFRRLPHLDMWNEFFHVMLNIPDCHHLPSLDLLRQKLKKVFQQHYTNKIRALRNRLIVLLLECKRSRK
->3cic_A mol:protein length:390  Beta-secretase 1
-GSFVEMVDNLRGKSGQGYYVEMTVGSPPQTLNILVDTGSSNFAVGAAPHPFLHRYYQRQLSSTYRDLRKGVYVPYTQGKWEGELGTDLVSIPHGPNVTVRANIAAITESDKFFINGSNWEGILGLAYAEIARPDDSLEPFFDSLVKQTHVPNLFSLQLCGAGFPLNQSEVLASVGGSMIIGGIDHSLYTGSLWYTPIRREWYYEVIIVRVEINGQDLKMDCKEYNYDKSIVDSGTTNLRLPKKVFEAAVKSIKAASSTEKFPDGFWLGEQLVCWQAGTTPWNIFPVISLYLMGEVTNQSFRITILPQQYLRPVEDVATSQDDCYKFAISQSSTGTVMGAVIMEGFYVVFDRARKRIGFAVSACHVHDEFRTAAVEGPFVTLDMEDCGYNI
->6qea_A mol:protein length:129  Lysozyme C
-KVFGRCELAAAMKRHGLDNYRGYSLGNWVCAAKFESNFNTQATNRNTDGSTDYGILQINSRWWCNDGRTPGSRNLCNIPCSALLSSDITASVNCAKKIVSDGNGMNAWVAWRNRCKGTDVQAWIRGCRL
->4br6_A mol:protein length:197  SUPEROXIDE DISMUTASE
-KATLPDLKYDYGALEPYISARIMELHHSKHHQTYVNGLNSALEATAEAEAKGDFTKAASLAPLLNFHGGGHLNHTLFWENLAPASREGGGEPDGALKKAIEADFGSFETFRKQMNAALTGIQGSGWAWLAKDKDSGNLAIVTRANQDPVTGQLVPLMGIDAWEHAYYLQYENRKAEYFEAIWNVINWKTVAQRFEKA
->4hpe_B mol:protein length:308  Putative cell wall hydrolase Tn916-like,CTn1-Orf17
-GADSDDENSNFSSGITGMNLSAEVLKHQPMVEKYARENGISEYVNVLLAIIQVESGGTAEDVMQSSESLGLPPNSLDTESSIKQGCKYFASLLSSSKNQGIDDLNVAIQSYNYGGGYVGYVAGKGKKHTFNLAESFAREKSGGKKVTYTNPIAVAKNGGWRWNYGNMFYVELVNQYLTVPQVSGELAQKVMNEALKYQGWKYVYGGSNPNTSFDCSGLTQWCYGKAGISLPRTAQAQYDATQHLPLSQAKAGDLVFFHSTYNAGSYVTHVGIYVGNNQMYHAGDPIGYADLSSSYWQQHLIGAGRVKQ
->6c7g_A mol:protein length:342  cGMP-dependent 3',5'-cyclic phosphodiesterase
-SAMDDEYTKLLHDGIQPVAAIDSNFASFTYTPRSLPEDDTSMAILSMLQDMNFINNYKIDCPTLARFCLMVKKGYRDPPYHNWMHAFSVSHFCYLLYKNLELTNYLEDIEIFALFISCMCHDLDHRGTNNSFQVASKSVLAALYSSEGSVMERHHFAQAIAILNTHGCNIFDHFSRKDYQRMLDLMRDIILATDLAHHLRIFKDLQKMAEVGYDRNNKQHHRLLLCLLMTSCDLSDQTKGWKTTRKIAELIYKEFFSQGDLEKAMGNRPMEMMDREKAYIPELQISFMEHIAMPIYKLLQDLFPKAAELYERVASNREHWTKVSHKFTIRGLPSNNSLDFLD
->6a83_A mol:protein length:394  Phosphoethanolamine transferase EptC
-MGSSHHHHHHSSGLVPRGSHMYRQQLNSLTKLLNENNALPPLANFKDESGNEPRTLVLVIGESTQRGRMSLYGYPRETTPELDALHKTDPNLTVFNNVVTSRPYTIEILQQALTFANEKNPDLYLTQPSLMNMMKQAGYKTFWITNQQTMTARNTMLTVFSRQTDKQYYMNQQRTQSAREYDTNVLKPFQEVLNDPAPKKLIIVHLLGTHIKYKYRYPENQGKFDGNTDHVPPGLNAEELESYNDYDNANLYNDHVVASLIKDFKAANPNGFLVYFSDHGEEVYDTPPHKTQGRNEDNPTRHMYTIPFLLWTSEKWQATHPRDFSQDVDRKYSLAELIHTWSDLAGLSYDGYDPTRSVVNPQFKETTRWIGNPYKKNALIDYDTLPYGDQVGNQ
->4eqh_A mol:protein length:128  Histidine triad nucleotide-binding protein 1
-SLMADEIAKAQVARPGGDTIFGKIIRKEIPAKIIFEDDRCLAFHDISPQAPTHFLVIPKKHISQISVAEDDDESLLGHLMIVGKKCAADLGLNKGYRMVVNEGSDGGQSVYHVHLHVLGGRQMHWPPG
->7mjk_F mol:protein length:244  Fab ab1 Heavy Chain
-EVQLVESGGGLVQPGGSLRLSCAASGFTVSSNYMSWVRQAPGKGLEWVSVIYSGGSTYYADSVKGRFTISRHNSKNTLYLQMNSLRAEDTAVYYCARGYGDYYFDYWGQGTLVTVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEPKSCDKTSGQAGHHHHHHGDYKDDDDKG
->5p35_A mol:protein length:330  endothiapepsin
-STGSATTTPIDSLDDAYITPVQIGTPAQTLNLDFDTGSSDLWVFSSETTASEVDGQTIYTPSKSTTAKLLSGATWSISYGDGSSSSGDVYTDTVSVGGLTVTGQAVESAKKVSSSFTEDSTIDGLLGLAFSTLNTVSPTQQKTFFDNAKASLDSPVFTADLGYHAPGTYNFGFIDTTAYTGSITYTAVSTKQGFWEWTSTGYAVGSGTFKSTSIDGIADTGTTLLYLPATVVSAYWAQVSGAKSSSSVGGYVFPCSATLPSFTFGVGSARIVIPGDYIDFGPISTGSSSCFGGIQSSAGIGINIFGDVALKAAFVVFNGATTPTLGFASK
->3j3y_9P mol:protein length:231  capsid protein
-PIVQNLQGQMVHQAISPRTLNAWVKVVEEKAFSPEVIPMFSALSEGATPQDLNTMLNTVGGHQAAMQMLKETINEEAAEWDRLHPVHAGPIEPGQMREPRGSDIAGTTSTLQEQIGWMTHNPPIPVGEIYKRWIILGLNKIVRMYSPTSILDIRQGPKEPFRDYVDRFYKTLRAEQASQEVKNWMTETLLVQNANPDCKTILKALGPAATLEEMMTACQGVGGPGHKARVL
->2wq5_A mol:protein length:119  PHOSPHOLIPASE A2, ACIDIC
-NLYQFKNMIKCTVPSRSWWDFADYGCYCGRGGSGTPVDDLDRCCQVHDNCYNEAEKISKCWPFFKTYSYKCSQGTLTCKGGNNACAASVCDCDRLAAICFAGAPYNDNNYNIDLKARCQ
->5ot7_H mol:protein length:127  30S ribosomal protein S9
-EQYYGTGRRKEAVARVFLRPGNGKVTVNGQDFNEYFQGLVRAVAALEPLRAVDALGHFDAYITVRGGGKSGQIDAIKLGIARALVQYNPDYRAKLKPLGFLTRDARVVERKKYGKHKARRAPQYSKR
->3iml_D mol:protein length:399  S-adenosylmethionine synthetase
-GPGSMANDYLFTSESVSEGHPDKVADQISDAILDAILAQDKYSRVAAETLCNTGLVVLAGEITTTANIDYIQIARDTIKRIGYDNTDYGIDYRGCAVLVAYDKQSPDIAQGVDRAHDNNLDQGAGDQGLMFGYACDETPELMPLPIHLSHRLVERQANLRRDGRLPWLRPDAKSQVTVRYVDGKPHSIDTVVLSTQHAPEIDLPALREAVIEEVIKPTLPADLIKGDIKFLVNPTGRFVIGGPQGDCGLTGRKIIVDTYGGAAPHGGGAFSGKDPSKVDRSAAYAGRYVAKNIVAAGLASRALIQVSYAIGVAEPTSVMVNTFGTGRVSDETITKLVREHFDLRPKGIIQMLDLLRPIYEKTAAYGHFGREEPEFSWEAADKALALAEAAGVEPAVQVA
->6gsl_H5 mol:protein length:60  50S ribosomal protein L30
-MPRLKVKLVKSPIGYPKDQKAALKALGLRRLQQERVLEDTPAIRGNVEKVAHLVRVEVVE
->3j3q_4p mol:protein length:231  capsid protein
-PIVQNLQGQMVHQAISPRTLNAWVKVVEEKAFSPEVIPMFSALSEGATPQDLNTMLNTVGGHQAAMQMLKETINEEAAEWDRLHPVHAGPIEPGQMREPRGSDIAGTTSTLQEQIGWMTHNPPIPVGEIYKRWIILGLNKIVRMYSPTSILDIRQGPKEPFRDYVDRFYKTLRAEQASQEVKNWMTETLLVQNANPDCKTILKALGPAATLEEMMTACQGVGGPGHKARVL
->5u23_A mol:protein length:382  Putative aminotransferase
-MGSSHHHHHHSSRNLYFQGGGHMFFLNLKQINDRFNTEFITKFKEILESGWYILGKQCEKFENNFAKYCGVKHCIGVANGLDALRLIIKAYDFKENDEIIVPANTYIASILAITDNKCKPILIEPDINTYNINPDLIEEKITKKTKAIMVVHLYGQVCDMEKIQLLANKYNLKIIEDCAQAHGAIYKDKRVGNLGDAAGFSFYPGKNLGALGDAGCICTNDDNFASKIRALANYGSHKKYENLYTGLNSRLDEIQAAFLDIKLKYLDEDNNKRKNIANFYLQNIKNENIILPSNKFDHVWHLFVVKTKLRDELQHYLNNHDIQTIIHYPIPPHKQKCYKDLNHLKLPITENIHQEVLSLPISPTMKENDFKKVADILNKWKV
->6i7v_C5 mol:protein length:45  50S ribosomal protein L36 2
-MKVLNSLRTAKERHPDCQIVKRKGRLYVICKSNPRFKAVQGRKKK
->6mrc_2 mol:protein length:100  10 kDa heat shock protein, mitochondrial
-GQAFRKFLPLFDRVLVERSAAETVTKGGIMLPEKSQGKVLQATVVAVGSGSKGKGGEIQPVSVKVGDKVLLPEYGGTKVVLDDKDYFLFRDGDILGKYVD
->5jw4_B mol:protein length:162  Hemagglutinin
-GLFGAIAGFIEGGWQGMVDGWYGYHHSNEQGSGYAADKESTQKAIDGVTNKVNSIIDKMNTQFEAVGREFNNLERRIENLNKKMEDGFLDVWTYNAELLVLMENERTLDFHDSNVKNLYDKVRLQLRDNAKELGNGCFEFYHKCDNECMESVRNGTYDYPQY
->6rjh_P mol:protein length:171  Ferritin light chain
-SQIRQNYSTEVEAAVNRLVNLYLRASYTYLSLGFYFDRDDVALEGVCHFFRELAEEKREGAERLLKMQNQRGGRALFQDLQKPSQDEWGTTLDAMKAAIVLEKSLNQALLDLHALGSAQADPHLCDFLESHFLDEEVKLIKKMGDHLTNIQRLVGSQAGLGEYLFERLTLK
->6ch9_G mol:protein length:518  Envelope glycoprotein gp120
-MDAMKRGLCCVLLLCGAVFVSPSQEIHARFRRGARAAKKWVTVYYGVPVWKEATTTLFCASDAKAYDTEVHNVWATHACVPTDPNPQEIVLGNVTENFNMWKNNMVEQMHEDIISLWDQSLKPCVKLTPLCVTLNCNNVNTNNTNNSTNATISDWEKMETGEMKNCSFNVTTSIRDKIKKEYALFYKLDVVPLENKNNINNTNITNYRLINCNTSVITQACPKVSFEPIPIHYCAPAGFAILKCNSKTFNGSGPCTNVSTVQCTHGIRPVVSTQLLLNGSLAEEEIVIRSENITDNAKTIIVQLNEAVEINCTRPNNNTRKSIHIGPGRAFYATGDIIGNIRQAHCNISKARWNETLGQIVAKLEEQFPNKTIIFNHSSGGDPEIVTHSFNCGGEFFYCNTTPLFNSTWNNTRTDDYPTGGEQNITLQCRIKQIINMWQGVGKAMYAPPIRGQIRCSSNITGLLLTRDGGRDQNGTETFRPGGGNMRDNWRSELYKYKVVKIEPLGIAPTACKRRVVQ
->1w76_B mol:protein length:543  ACETYLCHOLINESTERASE
-DDHSELLVNTKSGKVMGTRVPVLSSHISAFLGIPFAEPPVGNMRFRRPEPKKPWSGVWNASTYPNNCQQYVDEQFPGFSGSEMWNPNREMSEDCLYLNIWVPSPRPKSTTVMVWIYGGGFYSGSSTLDVYNGKYLAYTEEVVLVSLSYRVGAFGFLALHGSQEAPGNVGLLDQRMALQWVHDNIQFFGGDPKTVTIFGESAGGASVGMHILSPGSRDLFRRAILQSGSPNCPWASVSVAEGRRRAVELGRNLNCNLNSDEELIHCLREKKPQELIDVEWNVLPFDSIFRFSFVPVIDGEFFPTSLESMLNSGNFKKTQILLGVNKDEGSFFLLYGAPGFSKDSESKISREDFMSGVKLSVPHANDLGLDAVTLQYTDWMDDNNGIKNRDGLDDIVGDHNVICPLMHFVNKYTKFGNGTYLYFFNHRASNLVWPEWMGVIHGYEIEFVFGLPLVKELNYTAEEEALSRRIMHYWATFAKTGNPNEPHSQESKWPLFTTKEQKFIDLNTEPMKVHQRLRVQMCVFWNQFLPKLLNATACDGELSS
->7tk0_O mol:protein length:195  ATP synthase subunit 5
-ASKAAAPPPVRLFGVEGTYATALYQAAAKNSSIDAAFQSLQKVESTVKKNPKLGHLLLNPALSLKDRNSVIDAIVETHKNLDGYVVNLLKVLSENNRLGCFEKIASDFGVLNDAHNGLLKGTVTSAEPLDPKSFKRIEKALSASKLVGQGKSLKLENVVKPEIKGGLIVELGDKTVDLSISTKIQKLNKVLEDSI
->5ap8_C mol:protein length:166  TSR3
-MKVYIIDYHKDDPKRCTGKKLVKLKIAEFTRVGKGVVLDPFAQITLSNKDKDIVRRIGITIVDTSWNNTSQSEFKNIRGEHRRIPILFAGNPIHYGIAYKLSSIEALIATLYIVDEVEEAIKLSNVVKWGHTFIELNKELLEAYKNKTEEDIKKIEREIIEKILEK
->5qfe_A mol:protein length:321  Tyrosine-protein phosphatase non-receptor type 1
-MEMEKEFEQIDKSGSWAAIYQDIRHEASDFPSRVAKLPKNKNRNRYRDVSPFDHSRIKLHQEDNDYINASLIKMEEAQRSYILTQGPLPNTVGHFWEMVWEQKSRGVVMLNRVMEKGSLKCAQYWPQKEEKEMIFEDTNLKLTLISEDIKSYYTVRQLELENLTTQETREILHFHYTTWPDFGVPESPASFLNFLFKVRESGSLSPEHGPVVVHCSAGIGRSGTFCLADTCLLLMDKRKDPSSVDIKKVLLEMRKFRMGLIQTADQLRFSYLAVIEGAKFIMGDSSVQDQWKELSHEDLEPPPEHIPPPPRPPKRILEPHN
->5xhz_A mol:protein length:66  SH3 domain-containing kinase-binding protein 1
-GPGSEFRRRRRCQVAFSYLPQNDDELELKVGDIIEVVGEVEEGWWEGVLNGKTGMFPSNFIKELSG
->5ndg_C7 mol:protein length:136  40S ribosomal protein S17-A
-MGRVRTKTVKRASKALIERYYPKLTLDFQTNKRLCDEIATIQSKRLRNKIAGYTTHLMKRIQKGPVRGISFKLQEEERERKDQYVPEVSALDLSRSNGVLNVDNQTSDLVKSLGLKLPLSVINVSAQRDRRYRKRV
->5lzd_e mol:protein length:157  30S ribosomal protein S5
-ELQEKLIAVNRVSKTVKGGRIFSFTALTVVGDGNGRVGFGYGKAREVPAAIQKAMEKARRNMINVALNNGTLQHPVKGVHTGSRVFMQPASEGTGIIAGGAMRAVLEVAGVHNVLAKAYGSTNPINVVRATIDGLENMNSPEMVAAKRGKSVEEILG
->5anb_E mol:protein length:136  60S RIBOSOMAL PROTEIN L23
-MSKAQAVGSNYRVSLGLPVGAVMNSADNSGAKNLYVIAVKGIKGRLNRLPSAGVGDMVMATVKKGKPELRKKVCTGLVVRQRKHWKRKDGVYIYFEDNAGVMCNPKGEVKGNILGPVAKECSDLWPKVATNAGTIV
->6ydw_Bj mol:protein length:279  Mitochondrial ribosomal protein L46
-MAAPVRRTMLRVVRGWRRFEGPWAHSLGSRNLALAVAPSSSSSPWRLLGALCLQRPPLVTKPLTPLQEEMADLLQQIEIERSLYSDHELRALDEAQQLAKKKSDLYEEEDEQNILLAQDLEDMWEQKFLHFKLGARLTEADKKDDRTSLHRKLDRNLILLVREKLGDQDIWMLPQSDWQPGETLRQTAERTLATLSENNMEAKFLGNAPCGHYKFKFPQAMRTETSLGAKVFFFKALLLTGDFSQAGKKGHHVWVSKEELGDYLKPKYLAQVRRFLLDL
->3jbt_N mol:protein length:105  Cytochrome c
-MGDVEKGKKIFVQKCAQCHTVEKGGKHKTGPNLHGLFGRKTGQAPGFTYTDANKNKGITWKEETLMEYLENPKKYIPGTKMIFAGIKKKTEREDLIAYLKKATNE
->1htq_N mol:protein length:477  glutamine synthetase
-TEKTPDDVFKLAKDEKVEYVDVRFCDLPGIMQHFTIPASAFDKSVFDDGLAFDGSSIRGFQSIHESDMLLLPDPETARIDPFRAAKTLNINFFVHDPFTLEPYSRDPRNIARKAENYLISTGIADTAYFGAEAEFYIFDSVSFDSRANGSFYEVDAISGWWNTGAATEADGSPNRGYKVRHKGGYFPVAPNDQYVDLRDKMLTNLINSGFILEKGHHEVGSGGQAEINYQFNSLLHAADDMQLYKYIIKNTAWQNGKTVTFMPKPLFGDNGSGMHCHQSLWKDGAPLMYDETGYAGLSDTARHYIGGLLHHAPSLLAFTNPTVNSYKRLVPGYEAPINLVYSQRNRSACVRIPITGSNPKAKRLEFRSPDSSGNPYLAFSAMLMAGLDGIKNKIEPQAPVDKDLYELPPEEAASIPQTPTQLSDVIDRLEADHEYLTEGGVFTNDLIETWISFKRENEIEPVNIRPHPYEFALYYDV
->1sor_A mol:protein length:235  Aquaporin-0
-RSASFWRAIFAEFFATLFYVFFGLGASLRWAPGPLHVLQVALAFGLALATLVQAVGHISGAHVNPAVTFAFLVGSQMSLLRAICYVVAQLLGAVAGAAVLYSVTPPAVRGNLALNTLHPGVSVGQATIVEIFLTLQFVLCIFATYDERRNGRLGSVALAVGFSLTLGHLFGMYYTGAGMNPARSFAPAILTRNFTNHWVYWVGPVIGAGLGSLLYDFLLFPRLKSVSERLSILKG
->6dv5_A mol:protein length:205  Heat shock protein beta-1
-MTERRVPFSLLRGPSWDPFRDWYPHSRLFDQAFGLPRLPEEWSQWLGGSSWPGYVRPLPPAAIESPAVAAPAYSRALSRQLSSGVSEIRHTADRWRVSLDVNHFAPDELTVKTKDGVVEITGKHEERQDEHGYISRCFTRKYTLPPGVDPTQVSSSLSPEGTLTVEAPMPKLATQSNEITIPVTFESRAQLGGPEAAKSDETAAK
->5dat_c1 mol:protein length:155  40S ribosomal protein S11-A
-STELTVQSERAFQKQPHIFNNPKVKTSKRTKRWYKNAGLGFKTPKTAIEGSYIDKKCPFTGLVSIRGKILTGTVVSTKMHRTIVIRRAYLHYIPKYNRYEKRHKNVPVHVSPAFRVQVGDIVTVGQCRPISKTVRFNVVKVSAAAGKANKQFAKF
->1o1e_2 mol:protein length:375  SKELETAL MUSCLE ACTIN
-DEDETTALVCDNGSGLVKAGFAGDDAPRAVFPSIVGRPRHQGVMVGMGQKDSYVGDEAQSKRGILTLKYPIEHGIITNWDDMEKIWHHTFYNELRVAPEEHPTLLTEAPLNPKANREKMTQIMFETFNVPAMYVAIQAVLSLYASGRTTGIVLDSGDGVTHNVPIYEGYALPHAIMRLDLAGRDLTDYLMKILTERGYSFVTTAEREIVRDIKEKLCYVALDFENEMATAASSSSLEKSYELPDGQVITIGNERFRCPETLFQPSFIGMESAGIHETTYNSIMKCDIDIRKDLYANNVMSGGTTMYPGIADRMQKEITALAPSTMKIKIIAPPERKYSVWIGGSILASLSTFQQMWITKQEYDEAGPSIVHRKCF
->5b02_A mol:protein length:343  MoeN5,DNA-binding protein 7d
-MAHHHHHHVDDDDKMLAAEAANRDHVTRCVAQTGGSPDLVAHTAALRLYLRVPHFLTEWTTDPDRRAAVSRALALDIVSMKLLDDLMDDDTGLDRVELACVCLRLHLRALHELESLARDPKAVTDILEQDAVHLCGGQIRTKRSRATNLREWRAHASTYGSTFLGRYGALAAACGGEGQPADSVREFAEAFAMTITMADDLTDYDRNGERDGNLAHLMRTGAVAGQDVVDLLEELRGRALAAVAAPPGAPGLVPVVHLYTDDVLVRLLPRHLGEAGAGAMATVKFKYKGEEKEVDISKIKKVWRVGKMISFTYDEGGGKTGRGAVSEKDAPKELLQMLEKQKK
->6r4o_A mol:protein length:1533  Adenylate cyclase 9
-MASPPHQQLLQHHSTEVSCDSSGDSNSVRVRINPKQPSSNSHPKHCKYSISSSCSSSGDSGGVPRRMGAGGRLRRRKKLPQLFERASSRWWDPKFDSVNLEEACMERCFPQTQRRFRYALFYIGFACLLWSIYFGVHMKSKLIVMVAPALCFLVVCVGFFLFTFTKLYARHYVWTSLVLTLLVFALTLAAQFQVLTPLSGRVDNFNHTRAARPTDTCLSQVGSFSMCIEVLFLLYTVMHLPLYLSLILGVAYSVLFETFGYHFQDEACFASPGAEALHWELLSRALLHLCIHAIGIHLFIMSQVRSRSTFLKVGQSIMHGKDLEVEKALKERMIHSVMPRIIADDLMKQGDEESENSVKRHATSSPKNRKKKSSIQKAPIAFRPFKMQQIEEVSILFADIVGFTKMSANKSAHALVGLLNDLFGRFDRLCEETKCEKISTLGDCYYCVAGCPEPRADHAYCCIEMGLGMIRAIEQFCQEKKEMVNMRVGVHTGTVLCGILGMRRFKFDVWSNDVNLANLMEQLGVAGKVHISEATAKYLDDRYEMEDGKVTERLGQSVVADQLKGLKTYLIAGQRAKESHCSCSEALLSGFEVLDGSRVSSGPRGQGTASPGSVSDLAQTVKTFDNLKTCPSCGITFTPKPEAGAEGGAVQNGCQEEPKNSAKASGGPSSKTQNGLLSPPPEEKLTNSQTSLCEILQEKGRWAGVSLDQSALLPLRFKNIREKTDAHFVDVIKEDSLMKDYFFKPPINQFSLNFLDPELERAYRTSYQEEVVKSSPVRTFASATFSSLLDVLLSTTVFLILSITCFLRYGAASTPPPPAALAVFGAALLLEILSLVVSVRMVFFLEDVMTCTKRLLEWIAGWLPRHFIGAILVSLPALAVYSHVTSEFETNIHSTMFTGSAVLTAVVQYCNFCQLSSWMRSSLATVVGAGPLLLLLYVSLCPDSSTVISHLDAVQNFSSTRKLCNASLPHDGRSPASLIGQEVILVFFLLLLLVWFLNREFEVSYRLHYHGDVEADLHRTKIQSMRDQADWLLRNIIPYHVAEQLKVSQTYSKNHDSGGVIFASIVNFSEFYEENYEGGKECYRVLNELIGDFDELLSKPDYSSIEKIKTIGATYMAASGLNATQCRDGSHPQEHLQILFEFAKEMMRVVDDFNNNMLWFNFKLRVGFNHGPLTAGVIGTTKLLYDIWGDTVNIASRMDTTGVECRIQVSEESYRVLSKMGYEFDYRGTVNVKGKGQMKTYLYPKCTDSGAAALEVLFQGPGGVSKGEELFTGVVPILVELDGDVNGHKFSVSGEGEGDATYGKLTLKFICTTGKLPVPWPTLVTTFGYGLQCFARYPDHMKQHDFFKSAMPEGYVQERTIFFKDDGNYKTRAEVKFEGDTLVNRIELKGIDFKEDGNILGHKLEYNYNSHNVYIMADKQKNGIKVNFKIRHNIEDGSVQLADHYQQNTPIGDGPVLLPDNHYLSYQSALSKDPNEKRDHMVLLEFVTAAGITLGMDELYKAASAWSHPQFEKGGGSGGGSGGSAWSHPQFEK
->7ac8_E mol:protein length:253  Imidazole glycerol phosphate synthase subunit HisF
-MLAKRIIACLDVKDGRVVKGTNFENLRDSGDPVELGKFYSEIGIDELVFLDITASVEKRKTMLELVEKVAEQIDIPFTVGGGIHDFETASELILRGADKVSINTAAVENPSLITQIAQTFGSQAVVVAIDAKRVDGEFMVFTYSGKKNTGILLRDWVVEVEKRGAGEILLTSIDRDGTKSGYDTEMIRFVRPLTTLPIIASGGAGKMEHFLEAFLAGADAALAASVFHFREIDVRELKEYLKKHGVNVRLEGL
->7l88_D mol:protein length:498  BG505 SOSIP MD39 - gp120
-MGILPSPGMPALLSLVSLLMGCVAETGAENLWVTVYYGVPVWKDAETTLFCASDAKAYETKKHNVWATHCCVPTDPNPQEIHLENVTEEFNMWKNNMVEQMHEDIISLWDQSLKPCVKLTPLCVTLQCTNVTNNITDDMRGELKNCSFNMTTELRDKKQKVYSLFYRLDVVQINENQGNRSNNSNKEYRLINCNTSAITQACPKVSFEPIPIHYCAPAGFAILKCKDKKFNGTGPCPSVSTVQCTHGIKPVVSTQLLLNGSLAEEEVIIRSENITNNAKNILVQLNTPVQINCTRPNNNTVKSIRIGPGQWFYYTGDIIGDIRQAHCNVSKATWNETLGKVVKQLRKHFGNNTIIRFAQSSGGDLEVTTHSFNCGGEFFYCNTSGLFNSTWISNTSVQGSNSTGSNDSITLPCRIKQIINMWQRIGQAMYAPPIQGVIRCVSNITGLILTRDGGSTNSTTETFRPGGGDMRDNWRSELYKYKVVKIEPLGVAPTRCKR
->1v9w_A mol:protein length:130  putative 42-9-9 protein
-GSEGAATMATFEEVSVLGFEEFDKAVKEHESKTIFAYFSGSKDTEGKSWCPDCVEAEPVIREGLKHVTEDCVFIYCQVGDKPYWKDPNNDFRQKLKITAVPTLLKYGTPQKLVESECCQSSLVEMIFSED
->7uck_M mol:protein length:138  60S ribosomal protein L14
-VFRRFVEVGRVAYVSFGPHAGKLVAIVDVIDQNRALVDGPCTRVRRQAMPFKCMQLTDFILKFPHSARQKYVRKAWEKADINTKWAATRWAKKIEARERKAKMTDFDRYKVMKAKKMRNRIIKNEVKKLQRAALLKAS
->4v9j_BU mol:protein length:117  50S ribosomal protein L20
-PRAKTGVVRRRKHKKILKLAKGYWGLRSKSFRKARETLFAAGNYAYAHRKRRKRDFRRLWIVRINAACRQHGLNYSTFIHGLKKAGIEVDRKNLADLAVREPQVFAELVERAKAAQG
->2cvl_D mol:protein length:124  protein translation initiation inhibitor
-MEAVKTDRAPAAIGPYAQAVKAGGFVFVSGQIPLAPDGSLVEGDIRVQTERVMENLKAVLEAAGSGLSRVVQTTCFLADMEDFPGFNEVYARYFTPPYPARATVAVKALPRGVRVEVACVALAE
->1joj_R mol:protein length:8  HEXAPEPTIDE
-XMYWYPYX
->6w83_A mol:protein length:312  Potassium channel subfamily K member 2
-MSFSSKPTVLASRVESDSAINVMKWKTVSTIFLVVVLYLIIGATVFKALEQPQEISQRTTIVIQREKFLRAHPCVSDQELDELIQQIVAAINAGIIPLGASSNQVSHWDLGSSFFFAGTVITTIGFGNISPRTEGGKIFCIIYALLGIPLFGFLLAGVGDQLGTIFGKGIAKVEDTFIKWNVSQTKIRIISTIIFILFGCVLFVALPAVIFKHIEGWSALDAIYFVVITLTTIGFGDYVAGGSDIEYLDFYKPVVWFWILVGLAYFAAVLSMIGDWLRVIAKKTKEAVGEFRAHAAEWTANVTSNSLEVLFQ
->3ijj_B mol:protein length:114  Macrophage migration inhibitory factor
-PMFIVNTNVPRASVPDGFLSELTQQLAQATGKPPQYIAVHVVPDQLMAFGGSSEPCALCSLHSIGKIGGAQNRSYSKLLCGLLAERLRISPDRVYINYYDMNAANVGWNNSTFA
->5c54_F mol:protein length:312  Dihydrodipicolinate synthase/N-acetylneuraminate lyase
-MASATFTGVIPPVMTPLHADGSVDVESLRKLVDHLINGGVDGLFALGSSGEAAFLTRAQRKLALTTIIEHTAGRVPVTAGVIETTTARVIELVEDALEAGAEGLVATAPFYTRTHDVEIEEHFRKIHAAAPELPLFAYNIPVSVHSNLNPVMLLTLAKDGVLAGTKDSSGNDGAIRSLIEARDDAGLTEQFKILTGSETTVDFAYLAGADGVVPGLGNVDPAAYAALAKLCLDGKWAEAAALQKRINHLFHIVFVGDTSHMSGSSAGLGGFKTALAHLGIIESNAMAVPHQSLSDEETARIHAIVDEFLYTA
->6kuo_A mol:protein length:300  Poly(ethylene terephthalate) hydrolase
-MGSSHHHHHHSSGLVPRGSHMRGPNPTAASLEASAGPFTVRSFTVSRPSGYGAGTVYYPTNAGGTVGAIAIVPGYTARQSSIKWWGPRLASHGFVVITIDTNSTLDQPSSRSSQQMAALRQVASLNGTSSSPIYGKVDTARMGVMGWSMGGGGSLISAANNPSLKAAAPQAPWDSSTNFSSVTVPTLIFACENDSIAPVNSSALPIYDSMSRNAKQFLEINGGSHSCANSGNSDQALIGKKGVAWMKRFMDNDTRYSTFACENPNSTRVSDFRTANCSLEDPAANKARKEAELAAATAEQ
->1dmh_B mol:protein length:311  CATECHOL 1,2-DIOXYGENASE
-MEVKIFNTQDVQDFLRVASGLEQEGGNPRVKQIIHRVLSDLYKAIEDLNITSDEYWAGVAYLNQLGANQEAGLLSPGLGFDHYLDMRMDAEDAALGIENATPRTIEGPLYVAGAPESVGYARMDDGSDPNGHTLILHGTIFDADGKPLPNAKVEIWHANTKGFYSHFDPTGEQQAFNMRRSIITDENGQYRVRTILPAGYGCPPEGPTQQLLNQLGRHGNRPAHIHYFVSADGHRKLTTQINVAGDPYTYDDFAYATREGLVVDAVEHTDPEAIKANDVEGPFAEMVFDLKLTRLVDGVDNQVVDRPRLAV
->3j3q_53 mol:protein length:231  capsid protein
-PIVQNLQGQMVHQAISPRTLNAWVKVVEEKAFSPEVIPMFSALSEGATPQDLNTMLNTVGGHQAAMQMLKETINEEAAEWDRLHPVHAGPIEPGQMREPRGSDIAGTTSTLQEQIGWMTHNPPIPVGEIYKRWIILGLNKIVRMYSPTSILDIRQGPKEPFRDYVDRFYKTLRAEQASQEVKNWMTETLLVQNANPDCKTILKALGPAATLEEMMTACQGVGGPGHKARVL
->6q8y_BH mol:protein length:172  60S ribosomal protein L20-A
-MAHFKEYQVIGRRLPTESVPEPKLFRMRIFASNEVIAKSRYWYFLQKLHKVKKASGEIVSINQINEAHPTKVKNFGVWVRYDSRSGTHNMYKEIRDVSRVAAVETLYQDMAARHRARFRSIHILKVAEIEKTADVKRQYVKQFLTKDLKFPLPHRVQKSTKTFSYKRPSTFY
->7wu9_S mol:protein length:255  scFv16
-DVQLVESGGGLVQPGGSRKLSCSASGFAFSSFGMHWVRQAPEKGLEWVAYISSGSGTIYYADTVKGRFTISRDDPKNTLFLQMTSLRSEDTAMYYCVRSIYYYGSSPFDFWGQGTTLTVSSGGGGSGGGGSGGGGSDIVMTQATSSVPVTPGESVSISCRSSKSLLHSNGNTYLYWFLQRPGQSPQLLIYRMSNLASGVPDRFSGSGSGTAFTLTISRLEAEDVGVYYCMQHLEYPLTFGAGTKLELKGENLYFQ
->1rxo_H mol:protein length:475  RIBULOSE BISPHOSPHATE CARBOXYLASE/OXYGENASE
-MSPQTETKASVGFKAGVKDYKLTYYTPEYETLDTDILAAFRVSPQPGVPPEEAGAAVAAESSTGTWTTVWTDGLTNLDRYKGRCYHIEPVAGEENQYICYVAYPLDLFEEGSVTNMFTSIVGNVFGFKALRALRLEDLRIPVAYVKTFQGPPHGIQVERDKLNKYGRPLLGCTIKPKLGLSAKNYGRAVYECLRGGLDFTKDDENVNSQPFMRWRDRFLFCAEALYKAQAETGEIKGHYLNATAGTCEDMMKRAVFARELGVPIVMHDYLTGGFTANTTLSHYCRDNGLLLHIHRAMHAVIDRQKNHGMHFRVLAKALRLSGGDHIHSGTVVGKLEGERDITLGFVDLLRDDYTEKDRSRGIYFTQSWVSTPGVLPVASGGIHVWHMPALTEIFGDDSVLQFGGGTLGHPWGNAPGAVANRVALEACVQARNEGRDLAREGNTIIREATKWSPELAAACEVWKEIKFEFPAMDTV
->6lkh_A mol:protein length:294  ABC transporter, solute-binding protein
-NVLTVYSPYQSNLIRPILNEFEKQEHVKIEIKHGSTQVLLSNLHNEDFSERGDVFMGGVLSETIDHPEDFVPYQDTSVTQQLEDYRSNNKYVTSFLLMPTVIVVNSDLQGDIKIRGYQDLLQPILKGKIAYSNPNTTTTGYQHMRAIYSMHHRVSDVHQFQNHAMQLSKTSKVIEDVAKGKYYAGLSYEQDARTWKNKGYPVSIVYPIEGTMLNVDGIALVKNAHPHPKRKKLVQYLTSRSVQQRLVAEFDAKSIRKDVSEQSDQSIENLKNIPLIPKSKLPDIPHHKFLEMIQ
->2pnv_A mol:protein length:43  Small conductance calcium-activated potassium channel protein 2
-GSHMNIMYDMISDLNERSEDFEKRIVTLETKLETLIGSIHALP
->5uyk_Q mol:protein length:80  30S ribosomal protein S17
-KIRTLQGRVVSDKMEKSIVVAIERFVKHPIYGKFIKRTTKLHVHDENNECGIGDVVEIRECRPLSKTKSWTLVRVVEKAV
->7mtw_q mol:protein length:518  Capsid protein VP1
-DGVGSSSGNWHCDSQWLGDRVITTSTRTWALPTYNNHLYKQISNSTSGGSSNDNAYFGYSTPWGYFDFNRFHCHFSPRDWQRLINNNWGFRPKRLNFKLFNIQVKEVTDNNGVKTIANNLTSTVQVFTDSDYQLPYVLGSAHEGCLPPFPADVFMIPQYGYLTLNDGSQAVGRSSFYCLEYFPSQMLRTGNNFQFSYEFENVPFHSSYAHSQSLDRLMNPLIDQYLYYLSKTINGSGQNQQTLKFSVAGPSNMAVQGRNYIPGPSYRQQRVSTTVTQNNNSEFAWPGASSWALNGRNSLMNPGPAMASHKEGEDRFFPLSGSLIFGKQGTGRDNVDADKVMITNEEEIKTTNPVATESYGQVATNHQSAQAQAQTGWVQNQGILPGMVWQDRDVYLQGPIWAKIPHTDGNFHPSPLMGGFGMKHPPPQILIKNTPVPADPPTAFNKDKLNSFITQYSTGQVSVEIEWELQKENSKRWNPEIQYTSNYYKSNNVEFAVNTEGVYSEPRPIGTRYLTRNL
->7jg2_D mol:protein length:355  Igh protein
-WGQGTLVTVSAESARNPTIYPLTLPPALSSDPVIIGCLIHDYFPSGTMNVTWGKSGKDITTVNFPPALASGGRYTMSSQLTLPAVECPEGESVKCSVQHDSNPVQELDVNCSGPTPPPPITIPSCQPSLSLQRPALEDLLLGSDASITCTLNGLRNPEGAVFTWEPSTGKDAVQKKAVQNSCGCYSVSSVLPGCAERWNSGASFKCTVTHPESGTLTGTIAKVTVNTFPPQVHLLPPPSEELALNELLSLTCLVRAFNPKEVLVRWLHGNEELSPESYLVFEPLKEPGEGATTYLVTSVLRVSAETWKQGDQYSCMVGHEALPMNFTQKTIDRLSGKPTNVSVSVIMSEGDGICY
->6boh_DA mol:protein length:54  50S ribosomal protein L33
-MASEVRIKLLLECTECKRRNYATEKNKRNTPNKLELRKYCPWCRKHTVHREVKI
->6j3h_D mol:protein length:264  Glutathione S-transferase
-GLVPRGSHMIQQIHFYDIPRNRDEDDRTWNPNTSKTRLTLTYKRLPYKTIWVEYPDIERVCKEIGAEPSAFGLLKEGKPYYSLPVIHDPNTGTTISDSIRIARYLDKTYPDTPAVIPAELEAFHAVFEDAFWDTIFMPLFPFLVPAACPQLNPRSEAYFRETREGKFGSILGGKMENWAPTGPVRDDRWKALQAGFTKMAGWLSADGQERPFFMGEKLCYTDIVVGAWLISVKKVFGSDHPEWLQVEKWDGGRWSRLVQVVENF
->3tty_C mol:protein length:675  Beta-galactosidase
-MINEKFPKIWYGGDYNPEQWDKATMEEDMRMFNLAGIDVATVNVFSWAKIQRDEVSYDFTWLDDIIERLTKENIYLCLATSTGAHPAWMAKKYPDVLRVDYEGRKRKFGGRHNSCPNSPTYRKYAKILAGKLAERYKDHPQIVMWHVSNEYGGYCYCDNCEKQFRVWLKERYGTLEALNKAWNTSFWSHTFYDWDEIVAPNALSEEWSGNRTNFQGISLDYRRFQSDSLLECFKMERDELKRWTPDIPVTTNLMGFYPELDYFKWAKEMDVVSWDNYPSMDTPFSFTAMAHNLMRGLKSGQPFMLMEQTPGVQNWQPYNSAKRPGVMRLWSYQAVAHGADTVMFFQLRRSVGACEKYHGAVIEHVGHEHTRVFRECAELGKELQQLGDTILDARSEAKVAVMYDWENRWALELSSGPSIALNYVNEVHKYYDALYKQNIQTDMISVEEDLSKYKVVIAPVMYMVKPGFAERVERFVAQGGTFVTTFFSGIVNENDLVTLGGYPGELRNVMGIWAEEIDALLPGHQNEIVLRQDWGGLRGSYSCGILCDVIHAETAEVLAEYGADYYKGTPVLTRNKFGNGQSYYVASSPDADFLQGLIANLCEEQGVKPLLNTPDGVEVAERVKNGTSYLFVMNHNAEEMTFDAGASRQRDLLTGKTISGQATIPARGVMILERA
->4adj_C mol:protein length:473  E1 ENVELOPE GLYCOPROTEIN
-EEAFTYLCTAPGCATQTPVPVRLAGVRFESKIVDGGCFAPWDLEATGACICEIPTDVSCEGLGAWVPTAPCARIWNGTQRACTFWAVNAYSSGGYAQLASYFNPGGSYYKQYHPTACEVEPAFGHSDAACWGFPTDTVMSVFALASYVQHPHKTVRVKFHTETRTVWQLSVAGVSCNVTTEHPFCNTPHGQLEVQVPPDPGDLVEYIMNYTGNQQSRWGLGSPNCHGPDWASPVCQRHSPDCSRLVGATPERPRLRLVDADDPLLRTAPGPGEVWVTPVIGSQARKCGLHIRAGPYGHATVEMPEWIHAHTTSDPWHPPGPLGLKFKTVRPVALPRALAPPRNVRVTGCYQCGTPALVEGLAPGGGNCHLTVNGEDVGAFPPGKFVTAALLNTPPPYQVSCGGESDRASARVIDPAAQSFTGVVYGTHTTAVSETRFEDDDDKAGWSHPQFEKGGGSGGGSGGGSWSHPQFEK
->5d80_F mol:protein length:517  V-type proton ATPase subunit B
-MVLSDKELFAINKKAVEQGFNVKPRLNYNTVSGVNGPLVILEKVKFPRYNEIVNLTLPDGTVRQGQVLEIRGDRAIVQVFEGTSGIDVKKTTVEFTGESLRIPVSEDMLGRIFDGSGRPIDNGPKVFAEDYLDINGSPINPYARIYPEEMISTGVSAIDTMNSIARGQKIPIFSASGLPHNEIAAQICRQAGLVRPTKDVHDGHEENFSIVFAAMGVNLETARFFKQDFEENGSLERTSLFLNLANDPTIERIITPRLALTTAEYLAYQTERHVLTILTDMSSYADALREVSAAREEVPGRRGYPGYMYTDLSTIYERAGRVEGRNGSITQIPILTMPNDDITHPIPDLTGYITEGQIFVDRQLHNKGIYPPINVLPSLSRLMKSAIGEGMTRKDHGDVSNQLYAKYAIGKDAAAMKAVVGEEALSIEDKLSLEFLEKFEKTFITQGAYEDRTVFESLDQAWSLLRIYPKEMLNRISPKILDEFYDRARDDADEDEEDPDTRSSGKKKDASQEESLI
->5fxy_H mol:protein length:85  METASTASIS-ASSOCIATED PROTEIN MTA1
-GAAMKTRQAFYLHTTKLTRIARRLCREILRPWHAARHPYLPINSAAIKAECTARLPEASQSPLVLKQAVRKPLEAVLRYLETHPR
->1gav_5 mol:protein length:129  BACTERIOPHAGE GA PROTEIN CAPSID
-ATLRSFVLVDNGGTGNVTVVPVSNANGVAEWLSNNSRSQAYRVTASYRASGADKRKYTIKLEVPKIVTQVVNGVELPVSAWKAYASIDLTIPIFAATDDVTVISKSLAGLFKVGNPIAEAISSQSGFYA
->6zkb_k mol:protein length:355  NADH dehydrogenase [ubiquinone] 1 alpha subcomplex subunit 10, mitochondrial
-MALRFLRLVPASAASRGLAAVPPRVGGIHTSVQRKLQYGPLAYILGEKTTKKMTENSKLITVDGNICSGKSKLAKEVAEKLGLKHFPEAGIHYADSTTGDGKPLPVRFSGNCSLEKFYDDPKSNDGNSYRLQAWLYASRLLQYADALEHLLSTGQGVVLERSIYSDFVFLEAMYRQGFIRKQCVDHYNQVKKVTVCEYLPPHVVIYVDVPVSEVQSRIQKKGNPHEMKITSAYLQDIENVYKGTFLPEMSEKCEVLQYSAWEAEDAEKVVEDIQYLKYDKGPWLDQDDRKLHNLRMLVQDKLEVLNYTSIPVFLPEVTIGAHQSDRVFQEFTELPGRKYRAGYNEDVGDKWIWLK
->3kts_A mol:protein length:192  Glycerol uptake operon antiterminator regulatory protein
-MSLELPFSNQSIIPAAHNQKDMEKILELDLTYMVMLETHVAQLKALVKYAQAGGKKVLLHADLVNGLKNDDYAIDFLCTEICPDGIISTRGNAIMKAKQHKMLAIQRLFMIDSSAYNKGVALIQKVQPDCIELLPGIIPEQVQKMTQKLHIPVIAGGLIETSEQVNQVIASGAIAVTTSNKHLWEGHHHHHH
->1tqb_C mol:protein length:219  VRQ14 Fab light chain
-DVVMSQTPLTLSVTIGQPASISCKSSQSLLDSDGKTYLNWLLQRPGQSPKRLIYLVSRLDSGVPDRFTGSGSGTDFTLKISRVEAEDLGIYFCWQGSHFPQTFGGGTKLEIKRADAAPTVSIFPPSSEQLTSGGASVVCFLNNFYPKDINVKWKIDGSERQNGVLNSWTDQDSKDSTYSMSSTLTLTKDEYERHNSYTCEATHKTSTSPIVKSFNRNEC
->5tbw_l mol:protein length:361  60S ribosomal protein L4-A
-SRPQVTVHSLTGEATANALPLPAVFSAPIRPDIVHTVFTSVNKNKRQAYAVSEKAGHQTSAESWGTGRAVARIPRVGGGGTGRSGQGAFGNMCRGGRMFAPTKTWRKWNVKVNHNEKRYATASAIAATAVASLVLARGHRVEKIPEIPLVVSTDLESIQKTKEAVAALKAVGAHSDLLKVLKSKKLRAGKGKYRNRRWTQRRGPLVVYAEDNGIVKALRNVPGVETANVASLNLLQLAPGAHLGRFVIWTEAAFTKLDQVWGSETVASSKVGYTLPSHIISTSDVTRIINSSEIQSAIRPAGQATQKRTHVLKKNPLKNKQVLLRLNPYAKVFAAEKLGSKKAEKTGTKPAAVFTETLKHD
->2z6i_B mol:protein length:332  Trans-2-enoyl-ACP reductase II
-MKTRITELLKIDYPIFQGGMAWVADGDLAGAVSKAGGLGIIGGGNAPKEVVKANIDKIKSLTDKPFGVNIMLLSPFVEDIVDLVIEEGVKVVTTGAGNPSKYMERFHEAGIIVIPVVPSVALAKRMEKIGADAVIAEGMEAGGHIGKLTTMTLVRQVATAISIPVIAAGGIADGEGAAAGFMLGAEAVQVGTRFVVAKESNAHPNYKEKILKARDIDTTISAQHFGHAVRAIKNQLTRDFELAEKDAFKQEDPDLEIFEQMGAGALAKAVVHGDVDGGSVMAGQIAGLVSKEETAEEILKDLYYGAAKKIQEEASRWTGVVRNDLEHHHHHH
->6o7a_B mol:protein length:554  Ion channel CASTOR
-MAKGKSEVVEQNHTLILGWSDKLGSLLNQLAIANESLGGGTIAVMAERDKEDMELDIGKMEFDFKGTSVICRSGSPLILADLKKVSVSKARTIIVLAEDGNADQSDARALRTVLSLTGVKEGLRGHIVVEMSDLDNEVLVKLVGGDLVETVVAHDVIGRLMIQCARQPGLAQIWEDILGFENCEFYIKRWPQLDGMLFEDVLISFPAAIPCGIKVASYGGKIILNPDDSYVLQEGDEVLVIAEDDDTYAPAPLPMVRRGSLPKDFVYPKSPERILFCGWRRDMEDMITVLDASLAPDSELWMFNDVPEKEREKKLIDGGLDISRLENISLVNREGNAVIRRHLESLPLESFDSILILADESVEDSAIQADSRSLATLLLIRDIQARRLPYVAMASQTQGGNFSKGSWIGEMKQASDKTVIISEILDPRTKNLLSMSKISDYVLSNELVSMALAMVAEDRQINDVLEELFAEEGNEMHIRQADIYLREGEEMSFYEIMLRARQRREILIGYRLANAERAVINPPAKTGRRKWSLKDVFVVITEKEGSRSHHHHHH
->3j3q_6T mol:protein length:231  capsid protein
-PIVQNLQGQMVHQAISPRTLNAWVKVVEEKAFSPEVIPMFSALSEGATPQDLNTMLNTVGGHQAAMQMLKETINEEAAEWDRLHPVHAGPIEPGQMREPRGSDIAGTTSTLQEQIGWMTHNPPIPVGEIYKRWIILGLNKIVRMYSPTSILDIRQGPKEPFRDYVDRFYKTLRAEQASQEVKNWMTETLLVQNANPDCKTILKALGPAATLEEMMTACQGVGGPGHKARVL
->7ls9_G mol:protein length:215  1-57 Fab light chain
-EIVLTQSPGTLSLSPGERATLSCRASQSVSSSYLAWYQQKPGQAPRLLIYGASSRATGIPDRFSGSGSGTDFTLTISRLEPEDFAVYYCQQYGSSPSTFGQGTKLEIKRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNRGEC
->2v2z_A mol:protein length:271  4-DIPHOSPHOCYTIDYL-2C-METHYL-D-ERYTHRITOL KINASE
-GSHMIKVLSPAKINLGLWVLGRLPSGYHEILTLYQEIPFYDEIYIREGVLRVETNIGIPQEENLVYKGLREFERITGIEINYSIFIQKNIPPGAGLGGGSSNLAVVLKKVNELLGSPLSEEELRELVGSISADAPFFLLGKSAIGRGKGEVLEPVETEISGKITLVIPQVSSSTGRVYSSLREEHFVTPEYAEEKIQRIISGEVEEIENVLGDIARELYPEINEVYRFVEYLGFKPFVSGSGSTVYFFGGASEELKKAAKMRGWKVVELEL
->2jhu_B mol:protein length:138  RHO GDP-DISSOCIATION INHIBITOR 1
-AMVPNVVVTGLTLVCSSAPGPLELDLTGDLESFKKQSFVLKEGVEYRIKISFRVNREIVSGMKYIQHTYRKGVKIDKTDYMVGSYGPRAAAYEFLTPVEEAPKGMLARGSYSIKSRFTDDDKTDHLSWEWNLTIKKDW
->6bet_A mol:protein length:12  H(DPR)(DVA)CIP(DPR)E(DLY)VC(DGL)
-HPVCIPPEKVCE
->7r3v_D mol:protein length:239  Cytochrome c1, heme protein, mitochondrial
-DLELHPPSYPWSHRGLLSSLDHTSIRRGFQVYKQVCSSCHSMDYVAYRHLVGVCYTEDEAKALAEEVEVQDGPNEDGEMFMRPGKLSDYFPKPYPNPEAARAANNGALPPDLSYIVRARHGGEDYVFSLLTGYCEPPTGVSLREGLYFNPYFPGQAIGMAPPIYNEVLEFDDGTPATMSQVAKDVCTFLRWAAEPEHDHRKRMGLKMLLMMGLLLPLVYAMKRHKWSVLKSRKLAYRPP
->3e21_A mol:protein length:45  FAS-associated factor 1
-GSMDREMILADFQACTGIENIDEAITLLEQNNWDLVAAINGVIPQ
->6gcv_C mol:protein length:146  Chemotaxis transducer
-SGLVPAGSHMYLSMSISPETINVAGAQRMLSQKMAREALQLRLGAGDPKALAATIAQYERSAADLDAGNAERNVSRMGAPEIAAQRQKVAQIWGRYRAMLDQVAQPASQVDLRGFSQYSTELLGELNNLVSLMSARADSVQHTQMW
->6ev1_A mol:protein length:220  Heavy chain
-EVQLQQSGAELAKPGASVKMSCKASGYTFTSYWMHWVKQRPGQGLEWIGYINPSTGYTEYNQKFKDKATLTADKSSSTAYMQLSSLTSEDSAVYYCAPLWPLGTDYWGQGTTLTVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEPKSC
->6pbz_D mol:protein length:494  Guanosine-5'-triphosphate,3'-diphosphate pyrophosphatase
-MGSTSSLYAAIDLGSNSFHMLVVREVAGSIQTLTRIKRKVRLAAGLNSENALSNEAMERGWQCLRLFAERLQDIPPSQIRVVATATLRLAVNAGDFIAKAQEILGCPVQVISGEEEARLIYQGVAHTTGGADQRLVVDIGGASTELVTGTGAQTTSLFSLSMGCVTWLERYFADRNLGQENFDAAEKAAREVLRPVADELRYHGWKVCVGASGTVQALQEIMMAQGMDERITLEKLQQLKQRAIHCGRLEELEIDGLTLERALVFPSGLAILIAIFTELNIQCMTLAGGALREGLVYGMLHLAVEQDIRSRTLRNIQRRFMIDIDQAQRVAKVAANFFDQVENEWHLEAISRDLLISACQLHEIGLSVDFKQAPQHAAYLVRNLDLPGFTPAQKKLLATLLLNQTNPVDLSSLHQQNAVPPRVAEQLCRLLRLAIIFASRRRDDLVPEMTLQANHELLTLTLPQGWLTQHPLGKEIIAQESQWQSYVHWPLEVH
->5k00_A mol:protein length:335  Maternal embryonic leucine zipper kinase
-MDYDELLKYYELHETIGTGGFAKVKLACHILTGEMVAIKIMDKNTLGSDLPRIKTEIEALKNLRHQHICQLYHVLETANKIFMVLEYCPGGELFDYIISQDRLSEEETRVVFRQIVSAVAYVHSQGYAHRDLKPENLLFDEYHKLKLIDFGLCAKPKGNKDYHLQTCCGSLAYAAPELIQGKSYLGSEADVWSMGILLYVLMCGFLPFDDDNVMALYKKIMRGKYDVPKWLSPSSILLLQQMLQVDPKKRISMKNLLNHPWIMQDYNYPVEWQSKNPFIHLDDDCVTELSVHHRNNRQTMEDLISLWQYDHLTATYLLLLAKKARGKPVHHHHHH
->7xtb_R mol:protein length:584  Soluble cytochrome b562,5-hydroxytryptamine receptor 6
-DYKDDDDAKLQTMHHHHHHHHHHHHHHHADLEDNWETLNDNLKVIEKADNAAQVKDALTKMRAAALDAQKATPPKLEDKSPDSPEMKDFRHGFDILVGQIDDALKLANEGKVKEAQAAAEQLKTTRNAYIQKYLASENLYFQGGTVPEPGPTANSTPAWGAGPPSAPGGSGWVAAALCVVIALTAAANSLLIALICTQPALRNTSNFFLVSLFTSDLMVGLVVMPPAMLNALYGRWVLARGLCLLWTAFDVMCCSASILNLCLISLDRYLLILSPLRYKLRMTPLRALALVLGAWSLAALASFLPLLLGWHELGHARPPVPGQCRLLASLPFVLVASGLTFFLPSGAICFTYCRILLAARKQAVQVASLTTGMASQASETLQVPRTPRPGVESADSRRLATKHSRKALKASLTLGILLGMFFVTWLPFFVANIVQAVCDCISPGLFDVLTWLGYCNSTMNPIIYPLFMRDFKRALGRFLPCPRCPRERQASLASPSLRTSHSGPRPGLSLQQVLPLPLPPDSDSDSDAGSGGSSGLRLTAQLLLPGEATQDPPLPTRAAAAVNFFNIDPAEPELRPHPLGIPTN
->6y35_C mol:protein length:119  CCAAT-binding factor complex subunit HapE
-MGTWANVNQGLQGTARDILTTYWQHIINHLESDNHDYKIHQLPLARIKKVMKADPEVKMISAEAPILFAKGCDIFITELTMRAWIHAEDNKRRTLQRSDIAAALSKSDMFDFLIDIVPR
->1bcf_L mol:protein length:158  BACTERIOFERRITIN
-MKGDTKVINYLNKLLGNELVAINQYFLHARMFKNWGLKRLNDVEYHESIDEMKHADRYIERILFLEGLPNLQDLGKLNIGEDVEEMLRSDLALELDGAKNLREAIGYADSVHDYVSRDMMIEILRDEEGHIDWLETELDLIQKMGLQNYLQAQIREEG
->3oqm_A mol:protein length:339  Catabolite control protein A
-MNITIYDVAREANVSMATVSRVVNGNPNVKPTTRKKVLEAIERLGYRPNAVARGLASKKTTTVGVIIPDISSIFYSELARGIEDIATMYKYNIILSNSDQNMEKELHLLNTMLGKQVDGIVFMGGNITDEHVAEFKRSPVPIVLAASVEEQEETPSVAIDYEQAIYDAVKLLVDKGHTDIAFVSGPMAEPINRSKKLQGYKRALEEANLPFNEQFVAEGDYTYDSGLEALQHLMSLDKKPTAILSATDEMALGIIHAAQDQGLSIPEDLDIIGFDNTRLSLMVRPQLSTVVQPTYDIGAVAMRLLTKLMNKEPVEEHIVELPHRIELRKSTKSHHHHHH
->6epf_4 mol:protein length:201  Proteasome subunit beta type-2
-MEYLIGIQGPDYVLVASDRVAASNIVQMKDDHDKMFKMSEKILLLCVGEAGDTVQFAEYIQKNVQLYKMRNGYELSPTAAANFTRRNLADCLRSRTPYHVNLLLAGYDEHEGPALYYMDYLAALAKAPFAAHGYGAFLTLSILDRYYTPTISRERAVELLRKCLEELQKRFILNLPTFSVRVIDKDGIHNLENITFTKRSS
->6t7g_CCC mol:protein length:674  Glyco_hydro_42M domain-containing protein
-MGSSHHHHHHSSGLEVLFQGPAERISKQSTPFVGAQIFIEPGQTQEQIEQWFKLLAESNMTTCRIRMFGKYMKTPSGTYDFTLFDRAFKLADKYHIKVYATLFPDTEFTDVGGFKFPHSREHQKEVEDYIKNVVSHFSQYKNLAAWVLINEPGTPNLPFNEPFTKERFSDWKKEHNFSEYNEKGYPVLNFEKENFIIDYHNWYLNWLANQVRLYDKQHDLHVNPHNVFKLSGLYDFPTWRTFLNSLGGSAHASWHFGYFPRKAYTVAMSANAELIRSGAGELPWLMTELQGGNNLYSGANPLCPTAEEIIQWLWINFATEAKGGIFWSFNARSTAAEAGEWAMINFKNKSSDRLIAAATIGKFITENVKMMSNIKTLNSGISILYNHESMWVEAAQTRGKLNGNGRSIGAVMCSPLSYFEALSETGLQANFKEIKEFDFSLNDYTDQVIILSHQIALDNKVIKQLESFVEKGGTLIADGLTGYYDYQAHSTVVSGFALENLFGSYPIEYKIKENLFSLDFEKDNYKLPAHLWKGTIETSKATPIMDKEGECIACINQYGKGKVFWIPSPIALGARESKDFSELSKLTVSLLPNKILNDNPHFDKHYKDVMMKSFKSNGTMYSLIINKSASVQTVDIVGGKGKAFILFANKNAHSTANKLTISPEETVIIKWKNN
->5ysl_F mol:protein length:215  1H1 light chain
-DIILTQSPAIMSASLGERVTLTCTASSSVSSSYLHWYQQKPGSSPKLWIYSTYNLAGAVPPRFSGSGSGTSYSLTISSMEAEDAATYYCQQYHRSPWTFGGGTKLEIKRADAAPTVSIFPPSSEQLTSGGASVVCFLNNFYPKDINVKWKIDGSERQNGVLNSWTDQDSKDSTYSMSSTLTLTKDEYERHNSYTCEATHKTSTSPIVKNFNRNEC
->5ydz_C mol:protein length:580  mammalian endo-lysosomal TRPML1 channel
-MATPAGRRASETERLLTPNPGYGTQVGTSPAPTTPTEEEDLRRRLKYFFMSPCDKFRAKGRKPCKLMLQVVKILVVTVQLILFGLSNQLVVTFREENTIAFRHLFLLGYSDGSDDTFAAYTQEQLYQAIFYAVDQYLILPEISLGRYAYVRGGGGPWANGSALALCQRYYHRGHVDPANDTFDIDPRVVTDCIQVDPPDRPPDIPSEDLDFLDGSASYKNLTLKFHKLINVTIHFQLKTINLQSLINNEIPDCYTFSILITFDNKAHSGRIPIRLETKTHIQECKHPSVSRHGDNSFRLLFDVVVILTCSLSFLLCARSLLRGFLLQNEFVVFMWRRRGREISLWERLEFVNGWYILLVTSDVLTISGTVMKIGIEAKNLASYDVCSILLGTSTLLVWVGVIRYLTFFHKYNILIATLRVALPSVMRFCCCVAVIYLGYCFCGWIVLGPYHVKFRSLSMVSECLFSLINGDDMFVTFAAMQAQQGHSSLVWLFSQLYLYSFISLFIYMVLSLFIALITGAYDTIKHPGGTGTEKSELQAYIEQCQDSPTSGKFRRGSGSACSLFCCCGRDSPEDHSLLVN
->6gqv_AF mol:protein length:124  40S ribosomal protein S15
-KKRVFKTHSYRGVDLEKLLEMSTEDFVKLAPARVRRRFARGMTSKPAGFMKKLRAAKLAAPENEKPAPVRTHMRNMIIVPEMIGSVVGIYNGKAFNQVEIRPEMLGHYLGEFSITYTPVRHGRA
->3is7_S mol:protein length:158  Bacterioferritin
-MKGDKKVIQHLNKILGNELIAINQYFLHSRMWNDWGLKRLGAHEYHESIDEMKHADKLIERILFLEGLPNLQDLGKLLIGENTQEMLQCDLNLELKATKDLREAIVHCEQVHDYVSRDLLKDILESEEEHIDYLETQLGLIQKVGLENYLQSHMHEDD
->3g5f_A mol:protein length:396  Cytochrome P450 121
-MTATVLLEVPFSARGDRIPDAVAELRTREPIRKVRTITGAEAWLVSSYALCTQVLEDRRFSMKETAAAGAPRLNALTVPPEVVNNMGNIADAGLRKAVMKAITPKAPGLEQFLRDTANSLLDNLITEGAPADLRNDFADPLATALHCKVLGIPQEDGPKLFRSLSIAFMSSADPIPAAKINWDRDIEYMAGILENPNITTGLMGELSRLRKDPAYSHVSDELFATIGVTFFGAGVISTGSFLTTALISLIQRPQLRNLLHEKPELIPAGVEELLRINLSFADGLPRLATADIQVGDVLVRKGELVLVLLEGANFDPEHFPNPGSIELDRPNPTSHLAFGRGQHFCPGSALGRRHAQIGIEALLKKMPGVDLAVPIDQLVWRTRFQRRIPERLPVLW
->6wdh_l mol:protein length:143  50S ribosomal protein L15
-RLNTLSPAEGSKKAGKRLGRGIGSGLGKTGGRGHKGQKSRSGGGVRRGFEGGQMPLYRRLPKFGFTSRKAAITAEIRLSDLAKVEGGVVDLNTLKAANIIGIQIEFAKVILAGEVTTPVTVRGLRVTKGARAAIEAAGGKIEE
->3ej7_D mol:protein length:70  Beta-subunit of trans-3-chloroacrylic acid dehalogenase
-PFIECHIATGLSVARKQQLIRDVIDVTNKSIGSDPKIINVLLVEHAEANMSISGRIHGEAASTERTPAVS
->5t5h_e mol:protein length:245  60S ribosomal protein L2
-GKTVLTCRKGNGSIYQVHGHKRLGPAKLRILDYAERHGFMRGVVKTIEHEPGRGAPLARVEFRHPYKYRRVKELMVAPEGMFTGQSVLCGVKAPLAIGNVLPLGQITEGCIVCNVEAKVGDRGTIARASGDYCIIISHNHETGRTRLKLPSGQKKTVPSNCRAMIGIIAGGGRIEKPVLKAGNSFYRFRGKRNCWPKVRGVARNPVEHPHGGGNHQHIGHPSTVSRHAPPGQKVGLIAARRTGRI
->6nsh_XJ mol:protein length:105  30S ribosomal protein S10
-MPKIRIKLRGFDHKTLDASAQKIVEAARRSGAQVSGPIPLPTRVRRFTVIRGPFKHKDSREHFELRTHNRLVDIINPNRKTIEQLMTLDLPTGVEIEIKTVGGGR
->5lnn_A mol:protein length:206  Histidine kinase CKI1
-GSSHHHHHHSSGLVPRGSHMASTDSESETRVKSVRTGRKPIGNPEDEQETSKPSDDEFLRGKRVLVVDDNFISRKVATGKLKKMGVSEVEQCDSGKEALRLVTEGLTQREEQGSVDKLPFDYIFMACQMPEMDGYEATREIRKVEKSYGVRTPIIAVSGHDPGSEEARETIQAGMDAFLDKSLNQLANVIREIESKRHLEHHHHHH
->2qxu_A mol:protein length:179  Lipase
-HNPVVMVHGIGGASFNFAGIKSYLVSQGWSRDKLYAVDFWDKTGTNYNNGPVLSRFVQKVLDETGAKKVDIVAHSMGGANTLYYIKNLDGGNKVANVVTLGGANRLTTGKALPGTDPNQKILYTSIYSSADMIVMNYLSRLDGARNVQIHGVGHIGLLYSSQVNSLIKEGLNGGGQNTN
->1kyo_A mol:protein length:430  UBIQUINOL-CYTOCHROME C REDUCTASE COMPLEX CORE PROTEIN I
-AEVTQLSNGIVVATEHNPAHTASVGVVFGSGAANENPYNNGVSNLWKNIFLSKENSAVAAKEGLALSSNISRDFQSYIVSSLPGSTDKSLDFLNQSFIQQKANLLSSSNFEATKKSVLKQVQDFEDNDHPNRVLEHLHSTAFQNTPLSLPTRGTLESLENLVVADLESFANNHFLNSNAVVVGTGNIKHEDLVNSIESKNLSLQTGTKPVLKKKAAFLGSEVRLRDDTLPKAWISLAVEGEPVNSPNYFVAKLAAQIFGSYNAFEPASRLQGIKLLDNIQEYQLCDNFNHFSLSYKDSGLWGFSTATRNVTMIDDLIHFTLKQWNRLTISVTDTEVERAKSLLKLQLGQLYESGNPVNDANLLGAEVLIKGSKLSLGEAFKKIDAITVKDVKAWAGKRLWDQDIAIAGTGQIEGLLDYMRIRSDMSMMRW
->7dbn_D mol:protein length:444  HIV-1 RT p51 subunit
-MAHHHHHHALEVLFQGPISPIETVPVKLKPGMDGPKVKQWPLTEEKIKALVEICTEMEKEGKISKIGPENPYNTPVFAIKKKDSTKWRKLVDFRELNKRTQDFWEVQLGIPHPAGLKQKKSVTVLDVGDAYFSVPLDKDFRKYTAFTIPSINNETPGIRYQYNVLPQGWKGSPAIFQSSMTKILEPFRKQNPDIVIYQYMDDLYVGSDLEIGQHRTKIEELRQHLLRWGFTTPDKKHQKEPPFLWMGYELHPDKWTVQPIVLPEKDSWTVNDIQKLVGKLNWASQIYAGIKVRQLSKLLRGTKALTEVVPLTEEAELELAENREILKEPVHGVYYDPSKDLIAEIQKQGQGQWTYQIYQEPFKNLKTGKYARMKGAHTNDVKQLTEAVQKIATESIVIWGKTPKFKLPIQKETWEAWWTEYWQATWIPEWEFVNTPPLVKLWYQ
->7unu_Q mol:protein length:116  50S ribosomal protein L18
-MSVKKETRLRRARKARLKMRELETVRLCVYRSSQHIYAQVIAADGGKVLASASTLDKDLREGATGNIDAAKKVGQLVAERAKAAGVTQVAFDRSGFKYHGRVKALADAAREGGLEF
->7lst_A mol:protein length:800  Pullulanase
-MRTTKKIVSAVLAACMLASTAVVSSFAATADDSSAVSSDYARDNSYTKAAEDIDAQYAYSGNDLGVTYTKDATTFKVWSPTATGVKLNIFTKGSDDEQGASKVASYTLEKMLVDGEWNGVWTITLVGEWKDYYYTYSVTTTDTTHIGSDATKTYETQDVYSTATGVNGKRSMIVDLDETDPEGWSNDSHVLLDKSTKSSVWELHIKDFSYDKASGVSDANRGKYLAFTENGTTLNGEGKVSTCIDYLKELGVTTVQLNPFYDFQSVNEAGDDSQFNWGYDPVNYNVPEGSYSSNPYDGKVRIKECKEMIKALHDAGISVVMDVVYNHTYSTDSCFQYTVPNYYYRMKTTGAFSDGSGCGNEGATERAMYRQYVIDSLKYWVNEYHVDGFRFALMGLMDVETMNMAREALDQIDPRITMWGEGWAGGDSYHPTNTCSGTKFYPATQANASRLSDRIAIFNDGIRDGIKGSAMDISDVGFIQGSKSSAKGVSYGVRANSSGTYKWKAQAPSQCVTYDACHDNATLYDQIIASTGLADYGERNSEAVKMNRLASAIIYTSQGISFTLAGEEMARSKDGDTNSYKSAANLNMIKWQNVVDYADVVSYYKGMMQIKSAFSPLTAMDNSYADKYTFTKKVSASTNQISFTIQNDVEGEWNKMAVIYNNATTAADVTLSDTSVTDWVVIANGETAGLDSLGEVTGSTFTVPARSAIVAVDKAGYESAGIHSSKGKVKVNYVYEATGEKLEDSVILQGSVGSGYVTVPSAVIPDTYIVSRIGGNAEGKYTSDMQEVTYYYTDYIPESL
->4z9k_B mol:protein length:116  VHH2(F5) antibody
-VQLVESGGGLVQPGGSLRLSCAASGFTLDDYAIGWFRQVPGKEREGVACVKDGSTYYADSVKGRFTISRDNGAVYLQMNSLKPEDTAVYYCASRPCFLGVPLIDFGSWGQGTQVTV
->7vnr_G mol:protein length:1049  Potassium voltage-gated channel subfamily KQT member 4,Maltodextrin-binding protein
-MDYKDDDDKAEAPPRRLGLGPPPGDAPRAELVALTAVQSEQGEAGGGGSPRRLGLLGSPLPPGAPLPGPGSGSGSACGQRSSAAHKRYRRLQNWVYNVLERPRGWAFVYHVFIFLLVFSCLVLSVLSTIQEHQELANECLLILEFVMIVVFGLEYIVRVWSAGCCCRYRGWQGRFRFARKPFCVIDFIVFVASVAVIAAGTQGNIFATSALRSMRFLQILRMVRMDRRGGTWKLLGSVVYAHSKELITAWYIGFLVLIFASFLVYLAEKDANSDFSSYADSLWWGTITLTTIGYGDKTPHTWLGRVLAAGFALLGISFFALPAGILGSGFALKVQEQHRQKHFEKRRMPAANLIQAAWRLYSTDMSRAYLTATWYYYDSILPSFRELALLFEHVQRARNGGLRPLEVRRAPVPDGAPSRYPPVATCHRPGSTSFCPGESSRMGIKDRIRMGSSQRRTGPSKQHLAPPTMPTSPSSEQVGEATSPTKVQKSWSFNDRTRFRASLRLKPRTSAEDAPSEEVAEEKSYQCELTVDDIMPAVKTVIRSIRILKFLVAKRKFKETLRPYDVKDVIEQYSAGHLDMLGRIKSLQTRVDQIVGRGPGDRKAREKGDKGPSDAEVVDEISMMGRVVKVEKQVQSIEHKLDLLLGFYSRCLRSGTSALEVLFQGPMAKIEEGKLVIWINGDKGYNGLAEVGKKFEKDTGIKVTVEHPDKLEEKFPQVAATGDGPDIIFWAHDRFGGYAQSGLLAEITPDKAFQDKLYPFTWDAVRYNGKLIAYPIAVEALSLIYNKDLLPNPPKTWEEIPALDKELKAKGKSALMFNLQEPYFTWPLIAADGGYAFKYENGKYDIKDVGVDNAGAKAGLTFLVDLIKNKHMNADTDYSIAEAAFNKGETAMTINGPWAWSNIDTSKVNYGVTVLPTFKGQPSKPFVGVLSAGINAASPNKELAKEFLENYLLTDEGLEAVNKDKPLGAVALKSYEEELAKDPRIAATMENAQKGEIMPNIPQMSAFWYAVRTAVINAASGRQTVDEALKDAQTNAAAEHHHHHHHHHH
->6mng_A mol:protein length:208  4738 TCR alpha chain
-MQQVRQSPQSLTVWEGETAILNCSYENSAFDYLPWYQQFPGEGPALLIAIRSVSDKKEDGRFTIFFNKREKKLSLHITDSQPGDSATYFCAGIDTGANTGKLTFGHGTILRVHPNIQNPDPAVYQLRDSKSSDKSVCLFTDFDSQTNVSQSKDSDVYITDKCVLDMRSMDFKSNSAVAWSNKSDFACANAFNNSIIPEDTFFPSPESS
->4r4j_A mol:protein length:366  Aspartate-semialdehyde dehydrogenase
-MGYTVAVVGATGAVGAQMIKMLEESTLPIDKIRYLASARSAGKSLKFKDQDITIEETTETAFEGVDIALFSAGSSTSAKYAPYAVKAGVVVVDNTSYFRQNPDVPLVVPEVNAHALDAHNGIIACPNCSTIQMMVALEPVRQKWGLDRIIVSTYQAVSGAGMGAILETQRELREVLNDGVKPCDLHAEILPSGGDKKHYPIAFNALPQIDVFTDNDYTYEEMKMTKETKKIMEDDSIAVSATCVRIPVLSAHSESVYIETKEVAPIEEVKAAIAAFPGAVLEDDVAHQIYPQAINAVGSRDTFVGRIRKDLDAEKGIHMWVVSDNLLKGAAWNSVQIAETLHERGLVRPTAELKFELKLEHHHHHH
->7p7j_B mol:protein length:220  NADH-quinone oxidoreductase subunit B
-MDYTLTRIDPNGENDRYPLQKQEIVTDPLEQEVNKNVFMGKLNDMVNWGRKNSIWPYNFGLSCCYVEMVTSFTAVHDVARFGAEVLRASPRQADLMVVAGTCFTKMAPVIQRLYDQMLEPKWVISMGACANSGGMYDIYSVVQGVDKFIPVDVYIPGCPPRPEAYMQALMLLQESIGKERRPLSWVVGDQGVYRANMQSERERKRGERIAVTNLRTPDEI
->1ocz_D mol:protein length:147  CYTOCHROME C OXIDASE
-AHGSVVKSEDYALPSYVDRRDYPLPDVAHVKNLSASQKALKEKEKASWSSLSIDEKVELYRLKFKESFAEMNRSTNEWKTVVGAAMFFIGFTALLLIWEKHYVYGPIPHTFEEEWVAKQTKRMLDMKVAPIQGFSAKWDYDKNEWKK
->7p7q_P mol:protein length:144  50S ribosomal protein L16
-MLVPKRVKHRREFRGKMRGEAKGGKEVAFGEWGLQATESHWITNRQIEAARIAMTRYMKRGGKVWIKIFPHKSYTSKAIGVRMGKGKGAPEGWVSPVKRGKIMFEIAGVPEEVAREALRLASHKLPVKTKIVKREEMGGESNEG
->7tqa_C mol:protein length:231  Fab S9.6 heavy chain
-EVQLQQSGPELVKPGASVKMSCKASGYTFTSYVMHWVKQKPGQGLEWIGFINLYNDGTKYNEKFKGKATLTSDKSSSTAYMELSSLTSKDSAVYYCARDYYGSRWFDYWGQGTTLTVSSAKTTAPSVYPLAPVCGDTTGSSVTLGCLVKGYFPEPVTLTWNSGSLSSGVHTFPAVLQSDLYTLSSSVTVTSSTWPSQSITCNVAHPASSTKVDKKISALPETGGGHHHHHH
->3taz_B mol:protein length:471  DNA double-strand break repair protein nurA
-MGSSHHHHHHSSGLVPRGSHMRLLSKQSIERITKILLDELENVRENEQIRNIINSWKPLPSPEKSSIYAVDGSRSVSRLSGTVIYFLSALAVGSGKQLRLSYANAIKSNYGTSDQIVRMQMETLENMLGYLAYRKLEGEKRAILMDGTLTGSLVRPPVYPEDIRSLNVMRALIGESDFENLLNEFLEKLRDHYRKVEEHLEKNGNYDSPILTDNVVEKLRKKYIDTKVIAYGSGKVKVKIPRKALGYSPRVIPIEVLESSRGKSVDELLQELDEEKVELYLGKDDIYDALHMTLSYIEYLYSIDKLLEVKNLAYIAKSFYTKTLARTLGVEIVDTALLDAVIRTLIGHEKEGYLEIEHAVVPPKWSFPDFLLSKFRNIEKLIDKGIHLAYVRFEQGDVIYMLQSTTNIEKILPLILHHKAGGYLRPLQLAHHGVKISYKEARHTLEALINALRNRDPALKIFVKYGRSPLE
->7uwd_a mol:protein length:823  V-type proton ATPase subunit a
-MAELQSGGGGGCCPPMDLFRSEPMQLVQIIIPIESAHLTVSYLGELGLLQFKDLNSEKSPFQRTYAAQIKKCAEMARKLRFFKEQMLKAGILSSVKSTTRADNNTDDLEVKLGDLEAELVEINANGDKLQRAHSELVEYKLVLQKAGEFFSSALTSAAAQQREMESQQTGEMTIETPLLTDKEMSADPSKQIKLGFIAGLVPREKSMSFERMLFRATRGNVFLRQAVVDEPVVDPVSGEKMEKNVFVVFYSGERAKNKILKICDAFGANRYPFNEEFDKQAQAISEVSGRLSELKTTLDAGLLHRGNLLQTIGDQFEQWNLLVKREKSIYHTLNMLSLDVTKKCLVGEGWSPVFATKQIQDALERAAFDSNSQVGAIFQVLHTKESPPTYFRTNKFTSAFQEIVDAYGVAKYREANPGVFTIVTFPFLFAVMFGDWGHGICLLLGTLVLIVREKKLASQKLDDITDMTFGGRYVILMMALFSIYTGLIYNEFFSVPFEIFSHSAYACRDLSCSEATTVGLIKVRDTYPFGVDPVWHGSRSELPFLNSLKMKMSILLGVAQMNLGIILSYFNATFFRIGVNIWCQFIPQIIFLNSLFGYLSLLIILKWITGSQADLYHVMIYMFLSPTDELGDNQLFPGQKTAQLVLLLLAFVSVPWMLLPKPFILKMQHQDRHQGQSYEALQSTDESLQPDTNHDSHGHEEFEFSEVFVHQMIHTIEFVLGAVSNTASYLRLWALSLAHSELSSVFYEKVLLLAWGYNNILILIVGIIVFIFATVGVLLVMETLSAFLHALRLHWVEFQNKFYEGDGYKFSPFSFALLDDEDE
->2r5b_L mol:protein length:17  HIV entry inhibitor PIE7
-XKGACDYPEWQWLCAAX
->4zzh_A mol:protein length:356  NAD-dependent protein deacetylase sirtuin-1
-GPYTFVQQHLMIGTDPRTILKDLLPETIPPPELDDMTLWQIVINILSEPPKRKKRKDINTIEDAVKLLQECKKIIVLTGAGVSVSCGIPDFRSRDGIYARLAVDFPDLPDPQAMFDIEYFRKDPRPFFKFAKEIYPGQFQPSLCHKFIALSDKEGKLLRNYTQNIDTLEQVAGIQRIIQCHGSFATASCLICKYKVDCEAVRGDIFNQVVPRCPRCPADEPLAIMKPEIVFFGENLPEQFHRAMKYDKDEVDLLIVIGSSLKVRPVALIPSSIPHEVPQILINREPLPHLHFDVELLGDCDVIINELCHRLGGEYAKLCCNPVGGGSGGGSQYLFLPPNRYIFHGAEVYSDSEDDV
->2i03_C mol:protein length:726  Dipeptidyl peptidase 4
-SRKTYTLTDYLKNTYRLKLYSLRWISDHEYLYKQENNILVFNAEYGNSSVFLENSTFDEFGHSINDYSISPDGQFILLEYNYVKQWRHSYTASYDIYDLNKRQLITEERIPNNTQWVTWSPVGHKLAYVWNNDIYVKIEPNLPSYRITWTGKEDIIYNGITDWVYEEEVFSAYSALWWSPNGTFLAYAQFNDTEVPLIEYSFYSDESLQYPKTVRVPYPKAGAVNPTVKFFVVNTDSLSSVTNATSIQITAPASMLIGDHYLCDVTWATQERISLQWLRRIQNYSVMDICDYDESSGRWNCLVARQHIEMSTTGWVGRFRPSEPHFTLDGNSFYKIISNEEGYRHICYFQIDKKDCTFITKGTWEVIGIEALTSDYLYYISNEYKGMPGGRNLYKIQLSDYTKVTCLSCELNPERCQYYSVSFSKEAKYYQLRCSGPGLPLYTLHSSVNDKGLRVLEDNSALDKMLQNVQMPSKKLDFIILNETKFWYQMILPPHFDKSKKYPLLLDVYAGPCSQKADTVFRLNWATYLASTENIIVASFDGRGSGYQGDKIMHAINRRLGTFEVEDQIEAARQFSKMGFVDNKRIAIWGWSYGGYVTSMVLGSGSGVFKCGIAVAPVSRWEYYDSVYTERYMGLPTPEDNLDHYRNSTVMSRAENFKQVEYLLIHGTADDNVHFQQSAQISKALVDVGVDFQAMWYTDEDHGIASSTAHQHIYTHMSHFIKQCFS
->4nb5_B mol:protein length:171  DNA binding protein
-VSVNDGVDQMGAEPDIMEFVEQMGGYFESRSLTRLAGRLLGWLLVCDPERQSSEELATALAASSGGISTNARMLIQFGFIERLAVAGDRRTYFRLRPNAFAAGERERIRAMAELQDLADVGLRALGDAPPQRSRRLREMRDLLAYMENVVSDALGRYSQRTGEDDHHHHHH
->5whf_A mol:protein length:90  Vimentin
-GPHMEMRELRRQVDQLTNDKARVEVERDNLAEDIMRLREKLQEEMLQREEAENTLQSFRQDVDNASLARLDLERKVESLQEEIAFLKKLH
->2rfz_B mol:protein length:430  Cellulose 1,4-beta-cellobiosidase
-QRAGNETPENHPPLTWQRCTAPGNCQTVNAEVVIDANWRWLHDDNMQNCYDGNQWTNACSTATDCAEKCMIEGAGDYLGTYGASTSGDALTLKFVTKHEYGTNVGSRFYLMNGPDKYQMFNLMGNELAFDVDLSTVECGINSALYFVAMEEDGGMASYPSNQAGARYGTGYCDAQCARDLKFVGGKANIEGWKSSTSDPNAGVGPYGSCCAEIDVWESNAYAFAFTPHACTTNEYHVCETTNCGGTYSEDRFAGKCDANGCDYNPYRMGNPDFYGKGKTLDTSRKFTVVSRFEENKLSQYFIQDGRKIEIPPPTWEGMPNSSEITPELCSTMFDVFNDRNRFEEVGGFEQLNNALRVPMVLVMSIWDDHYANMLWLDSIYPPEKEGQPGAARGDCPTDSGVPAEVEAQFPDAQVVWSNIRFGPIGSTYDF
->3blw_J mol:protein length:354  Isocitrate dehydrogenase [NAD] subunit 2
-ATVKQPSIGRYTGKPNPSTGKYTVSFIEGDGIGPEISKSVKKIFSAANVPIEWESCDVSPIFVNGLTTIPDPAVQSITKNLVALKGPLATPIGKGHRSLNLTLRKTFGLFANVRPAKSIEGFKTTYENVDLVLIRENTEGEYSGIEHIVCPGVVQSIKLITRDASERVIRYAFEYARAIGRPRVIVVHKSTIQRLADGLFVNVAKELSKEYPDLTLETELIDNSVLKVVTNPSAYTDAVSVCPNLYGDILSDLNSGLSAGSLGLTPSANIGHKISIFEAVHGSAPDIAGQDKANPTALLLSSVMMLNHMGLTNHADQIQNAVLSTIASGPENRTGDLAGTATTSSFTEAVIKRL
->7nvo_q mol:protein length:548  T-complex protein 1 subunit theta
-MALHVPKAPGFAQMLKEGAKHFSGLEEAVYRNIQACKELAQTTRTAYGPNGMNKMVINHLEKLFVTNDAATILRELEVQHPAAKMIVMASHMQEQEVGDGTNFVLVFAGALLELAEELLRIGLSVSEVIEGYEIACRKAHEILPNLVCCSAKNLRDIDEVSSLLRTSIMSKQYGNEVFLAKLIAQACVSIFPDSGHFNVDNIRVCKILGSGISSSSVLHGMVFKKETEGDVTSVKDAKIAVYSCPFDGMITETKGTVLIKTAEELMNFSKGEENLMDAQVKAIADTGANVVVTGGKVADMALHYANKYNIMLVRLNSKWDLRRLCKTVGATALPRLTPPVLEEMGHCDSVYLSEVGDTQVVVFKHEKEDGAISTIVLRGSTDNLMDDIERAVDDGVNTFKVLTRDKRLVPGGGATEIELAKQITSYGETCPGLEQYAIKKFAEAFEAIPRALAENSGVKANEVISKLYAVHQEGNKNVGLDIEAEVPAVKDMLEAGILDTYLGKYWAIKLATNAAVTVLRVDQIIMAKPAGGPKPPSGKKDWDDDQND
->5z9m_B mol:protein length:207  DNA gyrase subunit B
-GLDAVRKRPGMYIGDTDDGTGLHHMVFEVVDNAIDEALAGHCKEIIVTIHADNSVSVQDDGRGIPTGIHPEEGVSAAEVIMTVLHAGGKFDDNSYKVSGGLHGVGVSVVNALSQKLELVIQREGKIHRQIYEHGVPQAPLAVTGETEKTGTMVRFWPSLETFTNVTEFEYEILAKRLRELSFLNSGVSIRLRDKRDGKEDHFHYEGG
->3c74_F mol:protein length:253  Uridine phosphorylase
-KSKSDVFHLGLTKNDLQGAQLAIVPGDPERVEKIAALMDKPVKLASHREFTSWRAELDGKAVIVCSTGIGGPSTSIAVEELAQLGIRTFLRIGTTGAIQPHINVGDVLVTTASVRLDGASLHFAPMEFPAVADFACTTALVEAAKSIGATTHVGVTASSDTFYPGQERYDTYSGRVVRRFKGSMEEWQAMGVMNYEMESATLLTMCASQGLRAGMVAGVIVNRTQQEIPNAETMKQTESHAVKIVVEAARRLL
->4unm_A mol:protein length:615  SECRETED PROTEIN
-GSHMSTEKYHQYKINQPEYKAANGKWEIIEFPEKYRQNTIHAALLRTGKVLMVAGSGNNQDNSDDKQYDTRIWDPVKGTIKKVPTPSDLFCTGHTQLANGNLLIAGGTKRYEKLKGDVTKAGGLMVVHNENPDKPITLPAGTKFTGKENGKTFVSKDPVLVPRAEKVFDPATGAFVRNDPGLGRIYVEAQKSGSAYETGTEDNYRVQGLSGADARNTYGIAQKLALDKKDFQGIRDAFEFDPVAEKYIKVDPMHEARWYPTLTTLGDGKILSVSGLDDIGQLVPGKNEVYDPKTKAWTYTDKVRQFPTYPALFLMQNGKIFYSGANAGYGPDDVGRTPGVWDVETNKFTKVPGMSDANMLETANTVLLPPAQDEKYMVIGGGGVGESKLSSEKTRIADLKADDPKFVDGPSLEKGTRYPQASILPDDSVLVSGGSQDYRGRGDSNILQARLYHPDTNEFERVADPLVGRNYHSGSILLPDGRLMFFGSDSLYADKANTKPGKFEQRIEIYTPPYLYRDSRPDLSGGPQTIARGGSGTFTSRAASTVKKVRLIRPSASTHVTDVDQRSIALDFKADGDKLTVTVPSGKNLVQSGWYMMFVTDGEGTPSKAEWVRVP
->5nh3_H mol:protein length:121  anti-human ActRIIB mAb BYM338 Fv heavy-chain
-QVQLVQSGAEVKKPGASVKVSCKASGYTFTSSYINWVRQAPGQGLEWMGTINPVSGSTSYAQKFQGRVTMTRDTSISTAYMELSRLRSDDTAVYYCARGGWFDYWGQGTLVTVSSHHHHHH
->5osi_D mol:protein length:182  Vacuolar protein sorting-associated protein 29
-MLVLVLGDLHIPHRCNSLPAKFKKLLVPGKIQHILCTGNLCTKESYDYLKTLAGDVHIVRGDFDENLNYPEQKVVTVGQFKIGLIHGHQVIPWGDMASLALLQRQFDVDILISGHTHKFEAFEHENKFYINPGSATGAYNALETNIIPSFVLMDIQASTVVTYVYQLIGDDVKVERIEYKKP
->6ysr_T mol:protein length:100  50S ribosomal protein L23
-MIREERLLKVLRAPHVSEKASTAMEKSNTIVLKVAKDATKAEIKAAVQKLFEVEVEVVNTLVVKGKVKRHGQRIGRRSDWKKAYVTLKEGQNLDFVGGAE
->2x6r_B mol:protein length:416  TREHALOSE-SYNTHASE TRET
-MKMYEVKEFSSGKRKLEDYKSIIGEEEVSKIQEKAEKLKGRSFVHVNSTSFGGGVAEILHSLVPLLRSIGIEARWFVIEGPTEFFNVTKTFHNALQGNESLKLTEEMKELYLNVNRENSKFIDLSSFDYVLVHDPQPAALIEFYEKKSPWLWRCHIDLSSPNREFWEFLRRFVEKYDRYIFHLPEYVQPELDRNKAVIMPPSIDPLSEKNVELKQTEILRILERFDVDPEKPIITQVSRFDPWKGIFDVIEIYRKVKEKIPGVQLLLVGVMAHDDPEGWIYFEKTLRKIGEDYDVKVLTNLIGVHAREVNAFQRASDVILQMSIREGFGLTVTEAMWKGKPVIGRAVGGIKFQIVDGETGFLVRDANEAVEVVLYLLKHPEVSKEMGAKAKERVRKNFIITKHMERYLDILNSLGG
->6rj0_C mol:protein length:337  Coat protein
-VRKGNKKLAKQATTKAVNPQPRRRNNNRRRGMRADAPLAKASTITGFGRGTNDVHLTGMSRIAQAVIPAGTGTDGYIVVDETIVPELLPRLGFAARIFQRYAVETLEFEIQPMCPANTGGGYVAGFLPDPTDSDHTFDAIQATRGAVVAKWWESRTIRPQYARALLWTSVGKEQRLTSPGRLILLCVGNNTDVVNVSVLCRWSVRLSVPSLETPEDTFAPILTLGPLYNDSLAANDFKSILLGSTQLDIAPEGAVYSLDRPLSIDYNLGTGDVDRAVYWHVKKVAGNAGTPAGWFHWGLWDNFNKTFTQGTAYYSDAQPRQILLPVGTLFTRADSGN
->5qn5_B mol:protein length:189  Thiol:disulfide interchange protein
-AQYEDGKQYTTLEKPVAGAPQVLEFFSFFCPHCYQFEEVLHISDNVKKKLPEGVKMTKYHVNFMGGDLGKDLTQAWAVAMALGVEDKVTVPLFEGVQKTQTIRSASDIRDVFINAGIKGEEYDAAWNSFVVKSLVAQQEKAAADVQLRGVPAMFVNGKYQLNPQGMDTSNMDVFVQQYADTVKYLSEKK
->5e7k_L5 mol:protein length:49  50S ribosomal protein L34
-MKRTWQPNRRKRAKTHGFRARMRTPGGRKVLKRRRQKGRWRLTPAVRKR
->4ru4_F mol:protein length:602  tail spike protein gp49
-GSVGQSLQFLEMGRVTPAQFGAVGDGASHPLSERYATLAEAQTVYPHAVALSDEIDWAALQAAVDSGAPVHIPSGDYQINRGISSTGSLQIAGDGATSIIRPTAAFTGTSVLSCVGSLVALPNISSVSAGSLTIDFASTPNLVAGDVFIIYNPTDSSFSGFRTSYRAGEFCEVRAVSGNTVTIRSALYAAYDGATVAIYKVVSGVVDIASIQIVGGTVPMNGLLVEAVVSPRVDDVTVTLANNAGVYFARCYDAKITNSNISNIGDGGDDYGIIFGNCHDGGADNCKVYARRHAIATGGDAEVGCVPVRNVRMRNCTLRNDITSGTHCADFHGNAEDCSYENCTIYGGATWQGKDISYRHCTITNASGGWIVISAEILGGTFLLDQCTLYTTGDPQPGNRGVIDVGGNSAVLTTNTTQPCNFLIQGGSLRAPSLSTSSYLLRARLEGSTVPVNIQYSGQAIDVGSLGKVLQLDITSGSTSPEYLIVENLAGLPSGITLASAAGGFASAPMRMPVLGGRVQVTTATNASSVTAPVTFRYIYPKAPTVQVTKTDRSYAGNRVGVAIANPTSASGATLGLFTDDGTNFSSAVTNQLNWQAGIYEV
->4y0g_A mol:protein length:90  5'-AMP-activated protein kinase subunit beta-2
-GPLGSPNSQARPTVIRWSEGGKEVFISGSFNNWSTKIPLIKSHNDFVAILDLPEGEHQYKFFVDGQWVHDPSEPVVTSQLGTINNLIHVK
->6pv4_D mol:protein length:653  Glycoside Hydrolase
-MGSSHHHHHHSSGLVPRGSHMASTDGITENFYEIYPKPQEISYSGGEFQISDEINIVYDDGIDTYTKKRVDEVLEASNLEATVSNEIVPGKTNFLVGINESGGVVDNYFNKNIPHDESFFDEKMDANIVSVKDGVIGVIAEDTDSAFYGVTTLKHVFNQLEEGNEIKNFRADDYAEVAHRGFIEGYYGNPWSNEDRAELMKFGGDYKLNQYVFAPKDDPYHNSKWRDLYPEEKLSEIKKLAQMGNETKNRYVYALHPFMNNPVRFDTEENYQNDLGVIKAKFTQLLENDVRQFAILADDASAPAQGASMYVKLLTDLTRWLEEQQSTYPDLKTDLMFCPSDYYGNGSSAQLKELNKAEDNVSIVMTGGRIWGEVDENFANNFMNNISTEGHPGRAPFFWINWPCSDNSKQHLIMGGNDTFLHPGVDPSKIDGIVLNPMQQAEANKSALFAIADYAWNIWDNKEEADENWNDSFKYMDHGTAEETNSSLALREISKHMINQNMDGRVRPLQESVELAPKLEAFKQKYDSGASIKEDALELIEEFTNLQKAAEYYKNNPGNERTRDQIIYWLNCWEDTMDAAIGYLKSAIAIEEGDDEAAWANYSEAQSAFEKSKTYGFHYVDHTEYAEVGVQHIVPFIKSMGQNLSVVIGSIVD
->4e51_A mol:protein length:467  Histidine--tRNA ligase
-MAHHHHHHMGTLEAQTQGPGSMTEQKRKLEKLTGVKGMNDILPQDAGLWEFFEATVKSLLRAYGYQNIRTPIVEHTPLFTRGIGEVTDIVEKEMYSFVDALNGENLTLRPENTAAVVRAAIEHNMLYDGPKRLWYIGPMFRHERPQRGRYRQFHQVGVEALGFAGPDADAEIVMMCQRLWEDLGLTGIKLEINSLGLAEERAAHRVELIKYLEQHADKLDDDAQRRLYTNPLRVLDTKNPALQEIVRNAPKLIDFLGDVSRAHFEGLQRLLKANNVPFTINPRLVRGLDYYNLTVFEWVTDKLGAQGTVAAGGRYDPLIEQLGGKPTAACGWAMGIERILELLKEEHLVPEQEGVDVYVVHQGDAAREQAFIVAERLRDTGLDVILHCSADGAGASFKSQMKRADASGAAFAVIFGEDEVTNGTASVKPLRGTGDDGEKSVQQSVPVESLTEFLINAMVATAEDGDD
->1j0n_A mol:protein length:752  XANTHAN LYASE
-SDEFDALRIKWATLLTGGPALDPADSDIAARTDKLAQDANDYWEDMDLSSSRTYIWYALRGNGTSDNVNAVYERLRTMALAATTVGSSLYGNADLKEDILDALDWLYVNSYNSTRSRSAYNWWHWQLGIPMSLNDTAVLLYDDISAARMATYMDTIDYFTPSIGLTGANRAWQAIVVGVRAVIVKDAVKLAAARNGLSGTGIFPYATGGDGFYADGSFVQHTTFAYTGGYGSSVLETTANLMYLLSGSTWSVSDPNQSNVWQWIYEAYRPLLYKGAMMDMVRGREISRSYAQDHAVGHGIVASIVRLAQFAPAPHAAAFKQIAKRVIQEDTFSSFYGDVSTDTIRLAKAIVDDPSIAPAAAPNLYKQYAAMDRAVLQRPGFALGLALYSTRISSYESINSENGRGWYTGAGATYLYNQDLAQYSEDYWPTVDAYRIPGTTVASGTPIASGTGTSSWTGGVSLAGQYGASGMDLSYGAYNLSARKSWFMFDDEIVALGSGISSTAGIPIETVVDNRKLNGAGDNAWTANGAALSTGLGVAQTLTGVNWVHLAGNTADGSDIGYYFPGGATLQTKREARTGTWKQINNRPATPSTAVTRNYETMWIDHGTNPSGASYGYVLLPNKTSAQVGAYAADPAIEIVVNTSGVQSVKEKTLGLVGANFWTDTTQTADLITSNKKASVMTREIADERLEASVSDPTQANNGTIAIELARSAEGYSADPGITVTQLAPTIKFTVNVNGAKGKSFHASFQLG
->4qyj_D mol:protein length:516  Aldehyde dehydrogenase
-MGSSHHHHHHSSGLVPRGSHMNSSLSAIDGLRLPHQMLIGGQWVSAQSGKTLNVYNPATGDILTEVPDGDVEDVNAAVESAAATLRSDTWRRMPPSARERILLRLADLLEVHGDELARLETLNNGKLLIYSKLMEVGASAQWLRYMAGWATKLTGSTLDLSLPLPPEVRSRASTQRVPVGVVAAIIPWNFPLLMAVWKIAPALACGNTVVLKPAEETPLTALRLAELAMEAGLPAGALNVVTGRGETAGDALVRHPKVAKVAFTGSTEVGRIIGSACGRSLKAVSLELGGKSPVIVLADCDPQEAAEGAAAAIFFNHGQVCTAGSRLYVHESIYEDVIQRLAVIGESIVVGSGLEQGVHMGPMVSKKHHENVLRHIRNGIEDGADLICGGTEAPCAQGFFVKPTIFANREKKDIRLLSQEVFGPVLVATPFSDIAEVVNEANRSVYGLGASIWTNDLSAALRINDELEAGTVWVNTHNMVDPNLPFGGFKDSGVGREHGAAAIEHYTTTRSLVIAY
->4b3w_B mol:protein length:190  CYTOGLOBIN
-MEKVPGEMEIERRERSEELSEAERKAVQAMWARLYANSEDVGVAILVRFFVNFPSAKQYFSQFKHMEDPLEMERSPQLRKQASRVMGALNTVVENLHDPDKVSSVLALVGKAHALKHKVEPVYFKILSGVILEVVAEEFASDFPPETQRAWAKLRGLIYSHVTAAYKEVGWVQQVPNATTPPATLPSSGP
->6sql_A mol:protein length:270  Enoyl-[acyl-carrier-protein] reductase [NADH]
-SMTGLLDGKRILVSGIITDSSIAFHIARVAQEQGAQLVLTGFDRLRLIQRITDRLPAKAPLLELDVQNEEHLASLAGRVTEAIGAGNKLDGVVHSIGFMPQTGMGINPFFDAPYADVSKGIHISAYSYASMAKALLPIMNPGGSIVGMDFDPSRAMPAYNWMTVAKSALESVNRFVAREAGKYGVRSNLVAAGPIRTLAMSAIVGGALGEEAGAQIQLLEEGWDQRAPIGWNMKDATPVAKTVCALLSDWLPATTGDIIYADGGAHTQLL
->2pty_A mol:protein length:432  Enolase
-GSHMTIQKVHGREVLDSRGNPTVEVEVTTEKGVFRSAVPSGASTGVYEACELRDGDKKRYVGKGCLQAVKNVNEVIGPALIGRDELKQEELDTLMLRLDGTPNKGKLGANAILGCSMAISKAAAAAKGVPLYRYLASLAGTKELRLPVPCFNVINGGKHAGNALPFQEFMIAPVKATSFSEALRMGSEVYHSLRGIIKKKYGQDAVNVGDEGGFAPPIKDINEPLPILMEAIEEAGHRGKFAICMDCAASETYDEKKQQYNLTFKSPEPTWVTAEQLRETYCKWAHDYPIVSIEDPYDQDDFAGFAGITEALKGKTQIVGDDLTVTNTERIKMAIEKKACNSLLLKINQIGTISEAIASSKLCMENGWSVMVSHRSGETEDTYIADLVVALGSGQIKTGAPCRGERTAKLNQLLRIEEELGAHAKFGFPGWS
->3otw_D mol:protein length:163  Phosphopantetheine adenylyltransferase
-HHHHHHMQKIGIYPGTFDPVTNGHIDIIHRSSELFEKLIVAVAHSSAKNPMFSLDERLKMIQLATKSFKNVECVAFEGLLANLAKEYHCKVLVRGLRVVSDFEYELQMGYANKSLNHELETLYFMPTLQNAFISSSIVRSIIAHKGDASHLVPKEIYPLISKA
->7ojp_J mol:protein length:261  Acyl-[acyl-carrier-protein]-UDP-N-acetylglucosamine O-acyltransferase
-GSHMSLIDPRAIIDPSARLAADVQVGPWSIVGAEVEIGEGTVIGPHVVLKGPTKIGKHNRIYQFSSVGEDTPDLKYKGEPTRLVIGDHNVIREGVTIHRGTVQDRAETTIGDHNLIMAYAHIGHDSVIGNHCILVNNTALAGHVHVDDWAILSGYTLVHQYCRIGAHSFSGMGSAIGKDVPAYVTVFGNPAEARSMNFEGMRRRGFSSEAIHALRRAYKVVYRQGHTVEEALAELAESAAQFPEVAVFRDSIQSATRGITR
->6ev1_D mol:protein length:213  Light chain
-DIVLTQSPAIMSASPGEKVTMTCSASSSVSYMHWYQQKSGTSPKRWIYDTSKLASGVPARFSGSGSGTSYSLTISSMEAEDAATYYCQQWSSNPPTFGAGTKLELKRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLRSPVTKSFNRGEC
->1p44_B mol:protein length:269  Enoyl-[acyl-carrier-protein] reductase [NADH]
-MTGLLDGKRILVSGIITDSSIAFHIARVAQEQGAQLVLTGFDRLRLIQRITDRLPAKAPLLELDVQNEEHLASLAGRVTEAIGAGNKLDGVVHSIGFMPQTGMGINPFFDAPYADVSKGIHISAYSYASMAKALLPIMNPGGSIVGMDFDPSRAMPAYNWMTVAKSALESVNRFVAREAGKYGVRSNLVAAGPIRTLAMSAIVGGALGEEAGAQIQLLEEGWDQRAPIGWNMKDATPVAKTVCALLSDWLPATTGDIIYADGGAHTQLL
->4v9c_DU mol:protein length:104  50S ribosomal protein L24
-MAAKIRRDDEVIVLTGKDKGKRGKVKNVLSSGKVIVEGINLVKKHQKPVPALNQPGGIVEKEAAIQVSNVAIFNAATGKADRVGFRFEDGKKVRFFKSNSETIK
->6d3g_B mol:protein length:284  Beta-lactamase
-SAQSPLLKEQIETIVTGKKATVGVAVWGPDDLEPLLLNPFEKFPMQSVFKLHLAMLVLHQVDQGKLDLNQSVTVNRAAVLQNTWSPMMKDHQGDEFTVAVQQLLQYSVSHSDNVACDLLFELVGGPQALHAYIQSLGVKEAAVVANEAQMHADDQVQYQNWTSMKAAAQVLQKFEQKKQLSETSQALLWKWMVETTTGPQRLKGLLPAGTIVAHKTGTSGVRAGKTAATNDAGVIMLPDGRPLLVAVFVKDSAESERTNEAIIAQVAQAAYQFELKKLSAVSPD
->7ce1_K mol:protein length:341  LacI-type transcription factor
-ERPTLKTIAYMTGLGITTVSRALKDAPDIGAETKERVRLIAQQIGYQPNRAGVRLRTGKTNVIALVLSVDEELMGFTSQMVFGITEVLATTQYHLVVTPHTHAKDSMVPIRYILETGSADGVIISKIEPNDPRVRFMTERKMPFVTHGRSDMGIEHAYHDFDNEAYAYEAVERLAQCGRKRIAIIVPPSRFAFHDHARKGFTRGIRDFGVSEFPLDAITIETPLDKIRDFGKRLMQSDDRPDGIVSISGSSTIALVAGFEAAGVRIGKDIDIVSKQSAEFLNWIQPQIHTVNEDIKLAGRELAKALLARINGAPPETLQSVSRPVWSSMAPKPLEHHHHHH
->5tzc_B mol:protein length:344  cGMP-dependent 3',5'-cyclic phosphodiesterase
-SAMDDEYTKLLHDGIQPVAAIDSNFASFTYTPRSLPEDDTSMAILSMLQDMNFINNYKIDCPTLARFCLMVKKGYRDPPYHNWMHAFSVSHFCYLLYKNLELTNYLEDIEIFALFISCMCHDLDHRGTNNSFQVASKSVLAALYSSEGSVMERHHFAQAIAILNTHGCNIFDHFSRKDYQRMLDLMRDIILATDLAHHLRIFKDLQKMAEVGYDRNNKQHHRLLLCLLMTSCDLSDQTKGWKTTRKIAELIYKEFFSQGDLEKAMGNRPMEMMDREKAYIPELQISFMEHIAMPIYKLLQDLFPKAAELYERVASNREHWTKVSHKFTIRGLPSNNSLDFLDEE
->1zwu_A mol:protein length:30  AMARANTHUS CAUDATUS ANTIMICROBIAL PEPTIDE 2 (ACMP2)
-VGECVRGRCPSGMCCSQAGYCGKGPKYCGR
->7nei_A mol:protein length:267  Polyester Hydrolase Leipzig 7 (PHL-7)
-MANPYERGPDPTESSIEAVRGPFAVAQTTVSRLQADGFGGGTIYYPTDTSQGTFGAVAISPGFTAGQESIAWLGPRIASQGFVVITIDTITRLDQPDSRGRQLQAALDHLRTNSVVRNRIDPNRMAVMGHSMGGGGALSAAANNTSLEAAIPLQGWHTRKNWSSVRTPTLVVGAQLDTIAPVSSHSEAFYNSLPSDLDKAYMELRGASHLVSNTPDTTTAKYSIAWLKRFVDDDLRYEQFLCPAPDDFAISEYRSTCPFLEHHHHHH
->3ab4_E mol:protein length:421  Aspartokinase
-MALVVQKYGGSSLESAERIRNVAERIVATKKAGNDVVVVCSAMGDTTDELLELAAAVNPVPPAREMDMLLTAGERISNALVAMAIESLGAEAQSFTGSQAGVLTTERHGNARIVDVTPGRVREALDEGKICIVAGFQGVNKETRDVTTLGRGGSDTTAVALAAALNADVCEIYSDVDGVYTADPRIVPNAQKLEKLSFEEMLELAAVGSKILVLRSVEYARAFNVPLRVRSSYSNDPGTLIAGSMEDIPVEEAVLTGVATDKSEAKVTVLGISDKPGEAAKVFRALADAEINIDMVLQNVFSVEDGTTDITFTCPRSDGRRAMEILKKLQVQGNWTNVLYDDQVGKVSLVGAGMKSHPGVTAEFMEALRDVNVNIELISTSEIRISVLIREDDLDAAARALHEQFQLGGEDEAVVYAGTGR
->3qjn_I mol:protein length:7  Beta-PIX
-AWDETNL
->6yft_AD mol:protein length:113  coat protein
-STFSSLVIGSNTFIPTAPGYYSLSTRGFSDPRNQIKISGGKFNAKTGRVTAAVSRLWETDVTVAGLPVRSAAEVAIIMTLGRGITATNADVLLSDLNTLLDPARLDQILQGGF
->5w08_E mol:protein length:291  Hemagglutinin HA1
-TNATELVQNSSIGEICDSPHQILDGENCTLIDALLGDPQCDGFQNKKWDLFVERSKAYSNCYPYDVPDYASLRSLVASSGTLEFNNESFNWNGVTQNGTSSACIRRSNNSFFSRLNWLTHLNFKYPALNVTMPNNEQFDKLYIWGVHHPVTDKDQIFLYAQPSGRITVSTKRSQQAVIPNIGFRPRIRNIPSRISIYWTIVKPGDILLINSTGNLIAPRGYFKIRSGKSSIMRSDAPIGKCKSECITPNGSIPNDKPFQNVNRITYGACPRYVKQSTLKLATGGALEVLFQ
->6t7m_C mol:protein length:266  3-oxoacyl-[acyl-carrier-protein] reductase FabG
-MHHHHHHSSGVDLGTENLYFQSMSFEGKIALVTGASRGIGRAIAETLVARGAKVIGTATSENGAKNISDYLGANGKGLMLNVTDPASIESVLENIRAEFGEVDILVNNAGITRDNLLMRMKDDEWNDIIETNLSSVFRLSKAVMRAMMKKRCGRIITIGSVVGTMGNAGQANYAAAKAGLIGFSKSLAREVASRGITVNVVAPGFIETDMTRALSDDQRAGILAQVPAGRLGGAQEIASAVAFLASDEASYITGETLHVNGGMYMV
->4www_XU mol:protein length:51  30S ribosomal protein S21
-IKVRENEPFDVALRRFKRSCEKAGVLAEVRRREFYEKPTTERKRAKASAVK
->3ab4_I mol:protein length:421  Aspartokinase
-MALVVQKYGGSSLESAERIRNVAERIVATKKAGNDVVVVCSAMGDTTDELLELAAAVNPVPPAREMDMLLTAGERISNALVAMAIESLGAEAQSFTGSQAGVLTTERHGNARIVDVTPGRVREALDEGKICIVAGFQGVNKETRDVTTLGRGGSDTTAVALAAALNADVCEIYSDVDGVYTADPRIVPNAQKLEKLSFEEMLELAAVGSKILVLRSVEYARAFNVPLRVRSSYSNDPGTLIAGSMEDIPVEEAVLTGVATDKSEAKVTVLGISDKPGEAAKVFRALADAEINIDMVLQNVFSVEDGTTDITFTCPRSDGRRAMEILKKLQVQGNWTNVLYDDQVGKVSLVGAGMKSHPGVTAEFMEALRDVNVNIELISTSEIRISVLIREDDLDAAARALHEQFQLGGEDEAVVYAGTGR
->6sn9_E mol:protein length:87  Outer membrane protein assembly factor BamE
-ERVVYRPDINQGNYLTANDVSKIRVGMTQQQVAYALGTPLMSDPFGTNTWFYVFRQQPGHEGVTQQTLTLTFNSSGVLTNIDNKPAL
->5o9f_B mol:protein length:352  Alcohol dehydrogenase
-MKAVQYTEIGSEPVVVDIPTPTPGPGEILLKVTAAGLCYSDISVMDMPAAQYAYGLPLTLGHEGVGTVAELGEGVTGFGVGDAVAVYGPWGCGACHACARGRENYCTRAADLGITPPGLGSPGSMAEYMIVDSARHLVPIGDLDPVAAAPLTDAGLTPYHAISRVLPLLGPGSTAVVIGVGGLGHVGIQILRAVSAARVIAVDLDDDRLALAREVGADAAVKSGAGAADAIRELTGGQGATAVFDFVGAQSTIDTAQQVVAVDGHISVVGIHAGAHAKVGFFMIPFGASVVTPFAGTRSELMEVVALARAGRLDIHTETFTLDEGPAAYRRLREGSIRGRGVVVPTSHHHHH
->7vec_F mol:protein length:118  Gamma-aminobutyric acid receptor-associated protein
-GPMKFVYKEEHPFEKRRSEGEKIRKKYPDRVPVIVEKAPKARIGDLDKKKYLVPSDLTVGQFYFLIRKRIHLRAEDALFFFVNNVIPPTSATMGQLYQEHHEEDFFLYIAYSDESVYG
->6r72_C mol:protein length:599  Multidrug exporter ATP-binding cassette
-MSSSHHHHHHMPTKKQKSKSKLKPFFALVRRTNPSYGKLAFALALSVVTTLVSLLIPLLTKQLVDGFSMSNLSGTQIGLIALVFFVQAGLSAYATYALNYNGQKIISGLRELLWKKLIKLPVSYFDTNASGETVSRVTNDTMVVKELITTHISGFITGIISVIGSLTILFIMNWKLTLLVLVVVPLAALILVPIGRKMFSISRETQDETARFTGLLNQILPEIRLVKASNAEDVEYGRGKMGISSLFKLGVREAKVQSLVGPLISLVLMAALVAVIGYGGMQVSSGELTAGALVAFILYLFQIIMPMGQITTFFTQLQKSIGATERMIEILAEEEEDTVTGKQIENAHLPIQLDRVSFGYKPDQLILKEVSAVIEAGKVTAIVGPSGGGKTTLFKLLERFYSPTAGTIRLGDEPVDTYSLESWREHIGYVSQESPLMSGTIRENICYGLERDVTDAEIEKAAEMAYALNFIKELPNQFDTEVGERGIMLSGGQRQRIAIARALLRNPSILMLDAATSSLDSQSEKSVQQALEVLMEGRTTIVIAHRLSTVVDADQLLFVEKGEITGRGTHHELMASHGLYRDFAEQQLKMNADLENKAG
->2w85_B mol:protein length:12  PEROXIN-19
-SQEKFFQELFDS
->1z4v_A mol:protein length:532  Hemagglutinin-neuraminidase
-SPSESLITQKQIMSQAGSTGSNSGLGSITDLLNNILSVANQIIYNSAVALPLQLDTLESTLLTAIKSLQTSDKLEQNCSWSAALINDNRYINGINQFYFSIAEGRNLTLGPLLNMPSFIPTATTPEGCTRIPSFSLTKTHWCYTHNVILNGCQDHVSSNQFVSMGIIEPTSAGFPFFRTLKTLYLSDGVNRKSCSISTVPGGCMMYCFVSTQPERDDYFSAAPPEQRIIIMYYNDTIVERIINPPGVLDVWATLNPGTGSGVYYLGWVLFPIYGGVIKGTSLWNNQANKYFIPQMVAALCSQNQATQVQNAKSSYYSSWFGNRMIQSGILACPLRQDLTNECLVLPFSNDQVLMGAEGRLYMYGDSVYYYQRSNSWWPMTMLYKVTITFTNGQPSAISAQNVPTQQVPRPGTGDCSATNRCPGFCLTGVYADAWLLTNPSSTSTFGSEATFTGSYLNTATQRINPTMYIANNTQIISSQQFGSSGQEAAYGHTTCFRDTGSVMVYCIYIIELSSSLLGQFQIVPFIRQVTLS
->5xf9_E mol:protein length:591  NAD-reducing hydrogenase
-MTTERQRTAPGLLAALHQARSRFGRPLDAQALAELSTAFSLPPGEIAATASFYHFFQTPPARYQIHFVDHVVDHHAGVAALCNHLCAAFAIQPGQRTADARLFVGWTACAGLSDQAPAALINGRPMPRLDAARIDALIEKIQAQIPMDQWPTEWFAVTNAIHRHGPLLTWLDTTPAEAVFEHPTAHDPDAILQAVTDAGLRGRGGAGFPTATKWRFCRENADPERFLICNADEGEPGTFKDRVLLTRYPEHLFAGMILAARAIGADKAILYLRYEYQYLLPQLEAARERIASAQATVPQAERVTLEIALGAGAYVCGEESALIESLEGKPGRPRVRPPYPVTQGYLGHPTVVNNVETLVAVAAIVGNGAAWWRALGTPDSSGPKLFCVSGDVAQPGLYEFPYGVALGDVVTAARPLGTRYAVQVSGPSGTLLPATPEQLARPLAFEALPCNGTVMVFDVRRDPVAIVHHFARFFAHESCGFCTPCRVGTQLIAKTFEKIAAGYATRFDLERLAPALEAMRLASNCGFGLSAGNPVRDLIAHFRQQLEAQLQPHDFIPAFSLDAELAATRRLTGRDDPHAHLAQFEQPEVTR
->2zh3_A mol:protein length:437  CCA-adding enzyme
-MKVEEILEKALELVIPDEEEVRKGREAEEELRRRLDELGVEYVFVGSYARNTWLKGSLEIDVFLLFPEEFSKEELRERGLEIGKAVLDSYEIRYAEHPYVHGVVKGVEVDVVPCYKLKEPKNIKSAVDRTPFHHKWLEGRIKGKENEVRLLKGFLKANGIYGAEYKVRGFSGYLCELLIVFYGSFLETVKNARRWTRRTVIDVAKGEVRKGEEFFVVDPVDEKRNVAANLSLDNLARFVHLCREFMEAPSLGFFKPKHPLEIEPERLRKIVEERGTAVFAVKFRKPDIVDDNLYPQLERASRKIFEFLERENFMPLRSAFKASEEFCYLLFECQIKEISRVFRRMGPQFEDERNVKKFLSRNRAFRPFIENGRWWAFEMRKFTTPEEGVRSYASTHWHTLGKNVGESIREYFEIISGEKLFKEPVTAELCEMMGVKD
->5md0_C mol:protein length:74  Capsid protein p24
-TSILDIRQGPKEPFRDYVDRFYKTLRAEQASQEVKNWMTETLLVQNANPDCKTILKALGPGATLEEMMTACQGV
->6myg_A mol:protein length:178  Gamma-crystallin S
-MSKTGGKISFYEDRNFLGRRYDCDCDCADFRSYLSRCNSIRVEGGTWAVYERPNFSGHMYILPQGEYPEYQRWMGLNDRLGSCRAVHLSSGGQAKIQVFEKGDFNGQMYETTEDCPSIMEQFHLREIHSCKVVEGTWIFYELPNYRGRQYLLDKKEYRKPVDWGAASPAIQSFRRIVE
->3vyt_B mol:protein length:372  Hydrogenase expression/formation protein HypD
-MEEPFEAYRSREVAMKLVEKIREEAKTLDGEIRIMHVCGTHEDTVTRHGIRSLLPENVKVVSGPGCPVCITPVEDIVAMQLIMRKAREEGEEIILTTFGDMYKIPTPMGSFADLKSEGFDVRIVYGIFDTYRIAKENPDKTVVHFSPGFETTTAPAAGMLNVAAQEELENFKIYSVHRLTPPAVEVLLKQGTVFQGLIAPGHVSTIIGVKGWEYLTEKYGIPQVVAGFEPNDVLMAILMLIRMYKEGEARIINEYERAVKYEGNVVAQKMIDKFFEVVDAKWRALGVFPKSGLELRKEWKDFEIRSFYKVEVPKNLPDLEKGCRCGAVLRGLALPTDCPLFGKTCTPRHPVGPCMVSYEGTCQIFYKYGVLF
->4atq_L mol:protein length:456  4-AMINOBUTYRATE TRANSAMINASE
-MTTTANELSYRIEQKRNINGAFPGPKSQALAERRSAVVAAGVASGVPVYVEDADGGIIRDVDGNSFIDLGSGIAVTSVGASDPAVVAAVQEAAAHFTHTCFMVTPYEGYVAVTEQLNRLTPGDHAKRTVLFNSGAEAVENAVKVARLATGRDAVVAFDHAYHGRTNLTMALTAKAMPYKTNFGPFAPEVYRMPMSYPFREENPEITGAEAAKRAITMIEKQIGGDQVAAIIIEPIQGEGGFIVPAEGFLPALSEWAKEKGIVFIADEVQSGFCRTGEWFAVDHEGVVPDIITMAKGIAGGLPLSAITGRADLLDAVHPGGLGGTYGGNPVACAAALAAIDTMEQHDLNGRARHIEELALGKLRELAAELSAGGGSVVGDIRGRGAMLAIELVQPGSKEPNAELTKAVAAACLKEGVIILTCGTYGNVIRLLPPLVISDELLIDGLEVLAAAIKAHA
->2cha_C mol:protein length:97  ALPHA-CHYMOTRYPSIN A
-ANTPDRLQQASLPLLSNTNCKKYWGTKIKDAMICAGASGVSSCMGDSGGPLVCKKNGAWTLVGIVSWGSSTCSTSTPGVYARVTALVNWVQQTLAAN
->1r7x_A mol:protein length:283  Glycoprotein-fucosylgalactoside alpha-galactosyltransferase
-MVSLPRMVYPQPKVLTPCRKDVLVVTPWLAPIVWEGTFNIDILNEQFRLQNTTIGLTVFAIKKYVAFLKLFLETAEKHFMVGHRVHYYVFTDQPAAVPRVTLGTGRQLSVLEVGAYKRWQDVSMRRMEMISDFCERRFLSEVDYLVCVDVDMEFRDHVGVEILTPLFGTLHPSFYGSSREAFTYERRPQSQAYIPKDEGDFYYMGAFFGGSVQEVQRLTRACHQAMMVDQANGIEAVWHDESHLNKYLLRHKPTKVLSPEYLWDQQLLGWPAVLRKLRFTAVP
->6gzq_S2 mol:protein length:78  30S ribosomal protein S19
-KGVFVDDHLLEKVLELNAKGEKRLIKTWSRRSTIVPEMVGHTIAVYNGKQHVPVYITENMVGHKLGEFAPTRTYRGHG
->4lmv_F mol:protein length:252  Glutathione transferase
-SQPIVFYDIPSNDTLKQSPWSPNTWKIRYALNIKGIKYKTEWVEYPDIEDVVKKLGGKPTGKKPDGRDHYTVPVIYDPNTKTVVEDGIKIAKYLDDAYPDTPRLFPAGTDAFQAAFDDFVWSVTLAFPLLSLLLLDVSNSLPPRSSAYFRATREQQFGKRLEEQGGEERWQQLEAGLGKFKGYLERNGAGNDLLLMGTQGGITYSDVQIASLFVWAKVVWGEGSEKWKRLMGFHGGKWAQFCAQFAEYERAD
->1lhu_A mol:protein length:189  SEX HORMONE-BINDING GLOBULIN
-LRPVLPTQSAHDPPAVHLSNGPGQEPIAVMTFDLTKITKTSSSFEVRTWDPEGVIFYGDTNPKDDWFMLGLRDGRPEIQLHNHWAQLTVGAGPRLDDGRWHQVEVKMEGDSVLLEVDGEEVLRLRQVSGPLTSKRHPIMRIALGGLLFPASNLRLPLVPALDGCLRRDSWLDKQAEISASAPTSLRSCD
->3fx7_A mol:protein length:94  Putative uncharacterized protein
-MSRVQMDTEEVREFVGHLERFKELLREEVNSLSNHFHNLESWRDARRDKFSEVLDNLKSTFNEFDEAAQEQIAWLKERIRVLEEDYLEHHHHHH
->4xkj_A mol:protein length:335  D-lactate dehydrogenase
-MKIIMFSVRDDEEAAIREWEKKTGVQVDINRLELDAETAQLTKGYDGIVIQQRSHISNPAVYETLQKNGLRQLTSRTAGYDMIDLEQASERGLVVTNVPAYSPNSVAELALTQTMRLIRNLPLFDARGAEQDFRWAGLMAREIRSLTVGIIGAGRIGGTVARLFKALGATVIANDIVERVELKDIVTYVSKEELLQAADVVTLHVPLMDSTTQLIDADALALMKNDAVLINASRGPVVDTDALIAALQNKQIAGAALDTLNGEEHFFNQDLCGKELPSEQLKVLRTLPNVLITPHIGFYTNKAVQNMVEISLNDVLAILKTGTSEHQLNKVAVEN
->6aw9_A mol:protein length:228  Catechol O-methyltransferase
-MGDTKEQRILRYVQQHAKPGDPQSVLEAIDTYCTQKEWAMNVGDAKGQIMDEVIQEHNPSLVLELGAYCGYSAVRMARLLSPGARLLTMEKNPDYAAITQQMLNFAGLQDKVTILIGASQDLIPQLKKYDVDTLDMVFLDHWKDRYLPDTILLEECGLLRKGTVLLADNVIVPGTPDFLAYVRGSSSFECTHYSSYLEYMKVVDGLEKAVYKGPSSPKQPLEHHHHHH
->5w93_F mol:protein length:20  Paxillin
-MDDLDALLADLESTTSHISK
->2fkb_C mol:protein length:180  Putative Nudix hydrolase yfcD
-MEQRRLASTEWVDIVNEENEVIAQASREQMRAQCLRHRATYIVVHDGMGKILVQRRTETKDFLPGMLDATAGGVVQADEQLLESARREAEEELGIAGVPFAEHGQFYFEDKNCRVWGALFSCVSHGPFALQEDEVSEVCWLTPEEITARCDEFTPDSLKALALWMKRNAKNEAVETETAE
->4z2y_A mol:protein length:359  CalO6
-GSHMELTTTAARPGLRHRMQQLIYGFFTAQTLHVAVRLRIPDLLADGARDVGDLASATGADAPSLRRLLRALVFLEVLDEPAPGTFALTEQGEVLRADVTGSMRELVLLLSGPESWAAWGQLEHSVRTGEVAWEHVHGRSCFDHLMADPQRQAAFNAAMAEGSRAFVPTLLSAYDFGDLRTVVDVGGGSGALLAGVLAAHPHLRGTVFDTPDGVADAARTVAEQGVADRCGVETGDFFVSVPPGADAYVLKSVLHDWDDEQCVEVLRTVRRAVRPDSRVILVESLMPTTVTTAPSVAQVVMNDLNMMVCHGGRERTVAEFRELLRVAGFRLESVTPCPAPSVVGILEAAPAPATGPDGS
->2prf_A mol:protein length:125  PROFILIN IA
-SWQTYVDTNLVGTGAVTQAAILGLDGNTWATSAGFAVTPAQGQTLASAFNNADPIRASGFDLAGVHYVTLRADDRSIYGKKGSAGVITVKTSKSILVGVYNEKIQPGTAANVVEKLADYLIGQGF
->5m32_I mol:protein length:205  Proteasome subunit beta type-3
-MSIMSYNGGAVMAMKGKNCVAIAADRRFGIQAQMVTTDFQKIFPMGDRLYIGLAGLATDVQTVAQRLKFRLNLYELKEGRQIKPYTLMSMVANLLYEKRFGPYYTEPVIAGLDPKTFKPFICSLDLIGCPMVTDDFVVSGTCAEQMYGMCESLWEPNMDPDHLFETISQAMLNAVDRDAVSGMGVIVHIIEKDKITTRTLKARMD
->1xm2_A mol:protein length:173  Tyrosine Phosphatase
-MARMNRPAPVEVTYKNMRFLITHNPTNATLNKFIEELKKYGVTTIVRVCEATYDTTLVEKEGIHVLDWPFDDGAPPSNQIVDDWLSLVKIKFREEPGCCIAVHSVAGLGRAPVLVALALIEGGMKYEDAVQFIRQKRRGAFNSKQLLYLEKYRPKMRLRFKDSNGHRNNCCIQ
->1nez_B mol:protein length:99  Beta-2-microglobulin
-IQKTPQIQVYSRHPPENGKPNILNCYVTQFHPPHIEIQMLKNGKKIPKVEMSDMSFSKDWSFYILAHTEFTPTETDTYACRVKHDSMAEPKTVYWDRDM
->6i50_A mol:protein length:170  SFRICE_029225
-RPFIAAHFHGNTSHLNSAIHDHYKGNGLVRVSHDAPHDVWYPAPWTVASPHPRPTLTRTGHVHVHHTGVYLVYVQIYYLDSHDTISWVLHRTNADIEGRETLLQCAQSSYSTEPIDKPNSCFSAAALFLKAGDRLAVRNTAGDRHSLMQPEKSFIGLVKLADAEDPTQEL
->5zbo_c mol:protein length:209  Capsid protein
-MGSSHHHHHHSSGLVPRGSHFNTRLSRTFGYTIKRTTVKTPSWAVDMMRFNINDFLPPGGGSNPRSVPFEYYRIRKVKVEFWPCSPITQGDRGVGSSAVILDDNFVTKATALTYDPYVNYSSRHTITQPFSYHSRYFTPKPVLDSTIDYFQPNNKRNQLWLRLQTAGNVDHVGLGTAFENSIYDQEYNIRVTMYVQFREFNLKDPPLNP
->5j8a_BM mol:protein length:114  30S ribosomal protein S13
-ARIAGINIPDHKHAVIALTSIYGVGKTRSKAILAAAGIAEDVKISELSEGQIDTLRDEVAKFVVEGDLRREISMSIKRLMDLGCYRGLRHRRGLPVRGQRTKTNARTRKGPRKP
->7ban_B mol:protein length:1932  Teneurin-4
-METACGDSKDNDGDGLVDCMDPDCCLQPLCHINPLCLGSPNPLDIIQETQVPVSQQNLHSFYDRIKFLVGRDSTHIIPGENPFDGGHACVIRGQVMTSDGTPLVGVNISFVNNPLFGYTISRQDGSFDLVTNGGISIILRFERAPFITQEHTLWLPWDRFFVMETIIMRHEENEIPSCDLSNFARPNPVVSPSPLTSFASSCAEKGPIVPEIQALQEEISISGCKMRLSYLSSRTPGYKSVLRISLTHPTIPFNLMKVHLMVAVEGRLFRKWFAAAPDLSYYFIWDKTDVYNQKVFGLSEAFVSVGYEYESCPDLILWEKRTTVLQGYEIDASKLGGWSLDKHHALNIQSGILHKGNGENQFVSQQPPVIGSIMGNGRRRSISCPSCNGLADGNKLLAPVALTCGSDGSLYVGDFNYIRRIFPSGNVTNILELRNKDFRHSHSPAHKYYLATDPMSGAVFLSDSNSRRVFKIKSTVVVKDLVKNSEVVAGTGDQCLPFDDTRCGDGGKATEATLTNPRGITVDKFGLIYFVDGTMIRRIDQNGIISTLLGSNDLTSARPLSCDSVMDISQVHLEWPTDLAINPMDNSLYVLDNNVVLQISENHQVRIVAGRPMHCQVPGIDHFLLSKVAIHATLESATALAVSHNGVLYIAETDEKKINRIRQVTTSGEISLVAGAPSGCDCKNDANCDCFSGDDGYAKDAKLNTPSSLAVCADGELYVADLGNIRIRFIRKNKPFLNTQNMYELSSPIDQELYLFDTTGKHLYTQSLPTGDYLYNFTYTGDGDITLITDNNGNMVNVRRDSTGMPLWLVVPDGQVYWVTMGTNSALKSVTTQGHELAMMTYHGNSGLLATKSNENGWTTFYEYDSFGRLTNVTFPTGQVSSFRSDTDSSVHVQVETSSKDDVTITTNLSASGAFYTLLQDQVRNSYYIGADGSLRLLLANGMEVALQTEPHLLAGTVNPTVGKRNVTLPIDNGLNLVEWRQRKEQARGQVTVFGRRLRVHNRNLLSLDFDRVTRTEKIYDDHRKFTLRILYDQAGRPSLWSPSSRLNGVNVTYSPGGYIAGIQRGIMSERMEYDQAGRITSRIFADGKTWSYTYLEKSMVLLLHSQRQYIFEFDKNDRLSSVTMPNVARQTLETIRSVGYYRNIYQPPEGNASVIQDFTEDGHLLHTFYLGTGRRVIYKYGKLSKLAETLYDTTKVSFTYDETAGMLKTINLQNEGFTCTIRYRQIGPLIDRQIFRFTEEGMVNARFDYNYDNSFRVTSMQAVINETPLPIDLYRYDDVSGKTEQFGKFGVIYYDINQIITTAVMTHTKHFDAYGRMKEVQYEIFRSLMYWMTVQYDNMGRVVKKELKVGPYANTTRYSYEYDADGQLQTVSINDKPLWRYSYDLNGNLHLLSPGNSARLTPLRYDIRDRITRLGDVQYKMDEDGFLRQRGGDIFEYNSAGLLIKAYNRAGSWSVRYRYDGLGRRVSSKSSHSHHLQFFYADLTNPTKVTHLYNHSSSEITSLYYDLQGHLFAMELSSGDEFYIACDNIGTPLAVFSGTGLMIKQILYTAYGEIYMDTNPNFQIIIGYHGGLYDPLTKLVHMGRRDYDVLAGRWTSPDHELWKHLSSSNVMPFNLYMFKNNNPISNSQDIKCFMTDVNSWLLTFGFQLHNVIPGYPKPDMDAMEPSYELIHTQMKTQEWDNSKSILGVQCEVQKQLKAFVTLERFDQLYGSTITSCQQAPKTKKFASSGSVFGKGVKFALKDGRVTTDIICVANEDGRRVAAILNHAHYLENLHFTIDGVDTHYFVKPGPSEGDLAILGLSGGRRTLENGVNVTVSQINTVLNGRTRRYTDIQLQYGALCLNTRYGTTLDEEKARVLELARQRAVRQAWAREQQRLREGEEGLRAWTEGEKQQVLSTGRVQGYDGFFVISVEQYPELSDSANNIHFMRQSE
->4o6c_D mol:protein length:377  NS1
-AEHHHHHHSSGVDLGTENLYFQSNADTGCAIDISRQELRCGSGVFIHNDVEAWMDRYKYYPETPQGLAKIIQKAHKEGVCGLRSVSRLEHQMWEAVKDELNTLLKENGVDLSVVVEKQEGMYKSAPKRLTATTEKLEIGWKAWGKSILFAPELANNTFVVDGPETKECPTQNRAWNSLEVEDFGFGLTSTRMFLKVRESNTTECDSKIIGTAVKNNLAIHSDLSYWIESRLNDTWKLERAVLGEVKSCTWPETHTLWGDGILESDLIIPVTLAGPRSNHNRRPGYKTQNQGPWDEGRVEIDFDYCPGTTVTLSESCGHRGPATRTTTESGKLITDWCCRSCTLPPLRYQTDSGCWYGMEIRPQRHDEKTLVQSQVNA
->5wyk_AD mol:protein length:575  Utp9
-XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX
->6grj_D mol:protein length:367  AhlB
-MTNATTITMDQGMANQASQAMQIQTYCNSVKQQVPVDFSQFPNLKDNQTQINQGLDLAKGHADLYLNTIQPQIITNISNISNYFALQNAIPAVLPPGSTKAQWLRQLSVIKEQATEYQRLSSDTRLVIVNLNNNLITDSSNFQGIVVNLNSKVQGDNGVLAQLNGDIDKVNAAIDGAIAGIVAGGLLVIGGAFVTAIGAVADFVTAGTSTPVVIGGVAMMVAGAGGITAGAIVLHNSLGARQDLYQKRSSLNSEVLIATQIGNGYKGLQVQAQNAVTAATQMSNAWDSLTSDLGSLITDLDKGITSGDDIRQLWLTAADTTVKTVLTDVTTIKAQIAGVSPLQVPQTDTIANFVARLAALEHHHHHH
->3ria_G mol:protein length:221  Mouse monoclonal Fab fragment, heavy chain
-EVQLQQSGPELVRPGASMKISCKASGYSFTGYTMNWVKQSHGKNLEWIGLINPYNGGTSYNQKFKGKATLTVDKSSSTAYMELLSLTSEDSAVYYCARDGDYYRYGRYFDYWGQGTTLTVSSAKTTPPSVYPLAPGSAAQTNSMVTLGCLVKGYFPEPVTVTWNSGSLSSGVHTFPAVLQSDLYTLSSSVTVPSSTWPSETVTCNVAHPASSTKVDKKIVP
->3jbv_u mol:protein length:104  50S ribosomal protein L24
-MAAKIRRDDEVIVLTGKDKGKRGKVKNVLSSGKVIVEGINLVKKHQKPVPALNQPGGIVEKEAAIQVSNVAIFNAATGKADRVGFRFEDGKKVRFFKSNSETIK
->6tj2_B mol:protein length:285  Alpha/beta hydrolase
-MKSIHIKIVLALCISIFTIMGLQPLNQHSTVAAANHKSSTKQTPLTFVLIHGSWATAGFWDETASELRKLGHTVYTPEYAGHGADKNNNVTHEQITKSVVDYIKQKDLKDFILLGHSFGGSVIQTVSQQVPDRIKRIVFFDAFAPLDGQSVADQFPAESLKSFEQLRDASGNNTITLPFPLFRDTFVNTASLAQAQAFYKQAPPEPATPLFEKLDLKKFYSLQIPKSYLYLTEDTAIPQGPYGFHPTQSSHLGVFRFIEGKGDHMTTVRTEPKMMAELMVKAGRD
->1vy7_AC mol:protein length:239  30S ribosomal protein S3
-MGNKIHPIGFRLGITRDWESRWYAGKKQYRHLLLEDQRIRGLLEKELYSAGLARVDIERAADNVAVTVHVAKPGVVIGRGGERIRVLREELAKLTGKNVALNVQEVQNPNLSAPLVAQRVAEQIERRFAVRRAIKQAVQRVMESGAKGAKVIVSGRIGGAEQARTEWAAQGRVPLHTLRANIDYGFALARTTYGVLGVKAYIFLGEVIGGQKPKARPELPKAEERPRRRRPAVRVKKEE
->6q16_AJ mol:protein length:252  Lipoprotein PrgK
-MIRRYLYTFLLVMTLAGCKDKDLLKGLDQEQANEVIAVLQMHNIEANKIDSGKLGYSITVAEPDFTAAVYWIKTYQLPPRPRVEIAQMFPADSLVSSPRAEKARLYSAIEQRLEQSLQTMEGVLSARVHISYDIDAGENGRPPKPVHLSALAVYERGSPLAHQISDIKRFLKNSFADVDYDNISVVLSERSDAQLQAPGTPVKRNSFATSWIVLIILLSVMSAGFGVWYYKNHYARNKKGITADDKAKSSNE
->2bo9_C mol:protein length:308  CARBOXYPEPTIDASE A4
-SSNNFNYGAYHSLEAIYHEMDNIAADFPDLARRVKIGHSFENRPMYVLKFSTGKGVRRPAVWLNAGIHSREWISQATAIWTARKIVSDYQRDPAITSILEKMDIFLLPVANPDGYVYTQTQNRLWRKTRSRNPGSSCIGADPNRNWNASFAGKGASDNPCSEVYHGPHANSEVEVKSVVDFIQKHGNFKGFIDLHSYSQLLMYPYGYSVKKAPDAEELDKVARLAAKALASVSGTEYQVGPTCTTVYPASGSSIDWAYDNGIKFAFTFELRDTGTYGFLLPANQIIPTAEETWLGLKTIMEHVRDNLY
->7jor_A mol:protein length:137  Dehaloperoxidase B
-GFKQDIATLRGDLRTYAQDIFLAFLNKYPDEKRNFKNYVGKSDQELKSMAKFGDHTEKVFNLMMEVADRATDCVPLASDASTLVQMKQHSGLTTGNFEKLFVALVEYMRASGQSFDSQSWDRFGKNLVSALSSAGMK
->5o09_2C mol:protein length:238  Bacterial kinesin light chain
-DTALERQIASASRSVEEARRLAYHDPIRVGALVEQISVLADLRQKEGDFRKAESLYREALFRAQELRKQDPDLLTGIYSLLAHLYDRWGRMDKAAEFYELALKISAENGLEESDKVATIKNNLAMIFKQLRKFERAEGYYCEALETFQRLDGEQSARVASVYNNLGVLYYSHMDVDRAQVMHERALAIRQNLHEGQMDPADLSQTFINLGAVYKAAGDFQKAEACVDRAKRIRAAMNG
->6eq4_A mol:protein length:182  7,8-dihydro-8-oxoguanine triphosphatase
-MKHHHHHHPMSDYDIPTTENLYFQGAMGASRLYTLVLVLQPQRVLLGMKKRGFGAGRWNGFGGKVQEGETIEDGARRELQEESGLTVDALHKVGQIVFEFVGEPELMDVHVFCTDSIQGTPVESDEMRPCWFQLDQIPFKDMWPDDSYWFPLLLQKKKFHGYFKFQGQDTILDYTLREVDTV
->7ezx_NP mol:protein length:161  Allophycocyanin alpha subunit
-MSIVTKSIVNADAEARYLSPGELDRIKSFVLSGQRRLRIAQTLTENRERIVKQGGQQLFQRRPDVVSPGGNAYGEEMTATCLRDLDYYLRLVTYGIIAGDVTPIEEIGLVGVKEMYSALGTPISGVAEGIRCMKDVACSLLSGEDAAEVGFYFDYTLAAMQ
->5aqj_B mol:protein length:118  BAG FAMILY MOLECULAR CHAPERONE REGULATOR 1
-GPLGSNSPQEEVELKKLKHLEKSVEKIADQLEELNKELTGIQQGFLPKDLQAEALCKLDRRVKATIEQFMKILEEIDTLILPENFKDSRLKRKGLVKKVQAFLAECDTVEQNICQETE
->6d8s_A mol:protein length:31  Potassium channel toxin alpha-KTx 5.4
-AFCNLRRCELSCRSLGLLGKCIGEECECVPY
->1wgj_B mol:protein length:286  INORGANIC PYROPHOSPHATASE
-TYTTRQIGAKNTLEYKVYIEKDGKPVSAFHDIPLYADKENNIFNMVVEIPRWTNAKLEITKEETLNPIIQDTKKGKLRFVRNCFPHHGYIHNYGAFPQTWEDPNVSHPETKAVGDNDPIDVLEIGETIAYTGQVKQVKALGIMALLDEGETDWKVIAIDINDPLAPKLNDIEDVEKYFPGLLRATNEWFRIYKIPDGKPENQFAFSGEAKNKKYALDIIKETHDSWKQLIAGKSSDSKGIDLTNVTLPDTPTYSKAASDAIPPASLKADAPIDKSIDKWFFISGSV
->4jfz_H mol:protein length:235  Fab heavy chain
-EISEVQLVESGGGLVQPGGSLRLSCVTSGFTFRKFGMSWVRQAPGKGLEWVASIATGGHTTYYSDSVKGRFTISRDNSKNTLYLQMNSLRAEDTAVYYCTRGYSSTSYAMDYWGQGTLVTVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEPKSCDKSHTATGA
->5gup_Aj mol:protein length:47  Cytochrome c oxidase subunit 7C, mitochondrial
-SHYEEGPGKNIPFSVENKWRLLAMMTLFFGSGFAAPFFIVRHQLLKK
->4e8g_B mol:protein length:391  Mandelate racemase/muconate lactonizing enzyme, N-terminal domain protein
-MHHHHHHSSGVDLGTENLYFQSMKIAEIHVYAHDLPVKDGPYTIASSTVWSLQTTLVKIVADSGLAGWGETCPVGPTYAPSHALGARAALAEMAPGLIGANPLQPLVLRRRMDGLLCGHNYAKAAIDIAAYDLMGKHYGVRVADLLGGVAAERVPSYYATGIGQPDEIARIAAEKVAEGFPRLQIKIGGRPVEIDIETVRKVWERIRGTGTRLAVDGNRSLPSRDALRLSRECPEIPFVLEQPCNTLEEIAAIRGRVQHGIYLDESGEDLSTVIRAAGQGLCDGFGMKLTRIGGLQQMAAFRDICEARALPHSCDDAWGGDIIAAACTHIGATVQPRLNEGVWVAQPYIAQPYDEENGIRIAGGHIDLPKGPGLGITPDESLFGPPVASFS
->4h5r_B mol:protein length:383  Heat shock cognate 71 kDa protein
-SKGPAVGIDLGTTYSCVGVFQHGKVEIIANDQGNRTTPSYVAFTDTERLIGDAAKNQVAMNPTNTVFDAKRLIGRRFDDAVVQSDMKHWPFMVVNDAGRPKVQVEYKGETKSFYPEEVSSMVLTKMKEIAEAYLGKTVTNAVVTVPAYFNDSQRQATKDAGTIAGLNVLRIINEPTAAAIAYGLDKKVGAERNVLIFDLGGGTFDVSILTIEDGIFEVKSTAGDTHLGGEDFDNRMVNHFIAEFKRKHKKDISENKRAVRRLRTACERAKRTLSSSTQASIEIDSLYEGIDFYTSITRARFEELNADLFRGTLDPVEKALRDAKLDKSQIHDIVLVGGSTRIPKIQKLLQDFFNGKELNKSINPDEAVAYGAAVQAAILSGDK
->6uea_J mol:protein length:245  Immunoglobulin heavy constant alpha 2
-DYKDDDDKLVPRGSCHPRLSLHRPALEDLLLGSEANLTCTLTGLRDASGATFTWTPSSGKSAVQGPPERDLCGCYSVSSVLPGCAQPWNHGETFTCTAAHPELKTPLTANITKSGNTFRPEVHLLPPPSEELALNELVTLTCLARGFSPKDVLVRWLQGSQELPREKYLTWASRQEPSQGTTTYAVTSILRVAAEDWKKGETFSCMVGHEALPLAFTQKTIDRLAGKPTHINVSVVMAEADGTCY
->3pi4_A mol:protein length:152  Hemoglobin II
-XTTLTNPQKAAIRSSWSKFMDNGVSNGQGFYMDLFKAHPETLTPFKSLFGGLTLAQLQDNPKMKAQSLVFCNGMSSFVDHLDDNDMLVVLIQKMAKLHNNRGIRASDLRTAYDILIHYMEDHNHMVGGAKDAWEVFVGFICKTLGDYMKELS
->4hmj_A mol:protein length:143  Thermonuclease
-ATSTKKLHKEPATLIKAIDGDTVKLMYKGQPMTFRDLLVDTPEFNEKYGPEASAFTKKMVENAKKIEVEFDKGQRTDKYGRGLAYIYADGKMVNEALVRQGLAKVAYVYKGNNTHEQLLRKAEAQAKKEKLNIWSEDNADSGQ
->6hhq_AC mol:protein length:59  60S ribosomal protein L29
-MAKSKNHTAHNQTRKAHRNGIKKPKTYKYPSLKGVDPKFRRNHKHALHGTAKALAAAKK
->2c37_X mol:protein length:248  PROBABLE EXOSOME COMPLEX EXONUCLEASE 1
-MREMLQVERPKLILDDGKRTDGRKPDELRSIKIELGVLKNADGSAIFEMGNTKAIAAVYGPKEMHPRHLSLPDRAVLRVRYHMTPFSTDERKNPAPSRREIELSKVIREALESAVLVELFPRTAIDVFTEILQADAGSRLVSLMAASLALADAGIPMRDLIAGVAVGKADGVIILDLNETEDMWGEADMPIAMMPSLNQVTLFQLNGSMTPDEFRQAFDLAVKGINIIYNLEREALKSKYVEFKEEGV
->1gvd_A mol:protein length:52  MYB PROTO-ONCOGENE PROTEIN
-LIKGPWTKEEDQRLIKLVQKYGPKRWSVIAKHLKGRIGKQCRERWHNHLNPE
->5d2q_A mol:protein length:102  Fibroin-modulator-binding protein-1
-MHHHHHHETSEERAARLAKMSAYAAQRLANESPEQRATRLKRMSEYAAKRLSSETREQRAIRLARMSAYAARRLANETPAQRQARLLRMSAYAAKRQASKKS
->1u8t_F mol:protein length:16  Flagellar motor switch protein fliM
-MGDSILSQAEIDALLN
->2vj0_P mol:protein length:12  SYNAPTOJANIN-1
-NPKGWVTFEEEE
->6opd_A mol:protein length:275  HLA class I histocompatibility antigen, A-2 alpha chain
-GSHSMRYFFTSVSRPGRGEPRFIAVGYVDDTQFVRFDSDAASQRMEPRAPWIEQEGPEYWDGETRKVKAHSQTHRVDLGTLRGYYNQSEAGSHTVQRMYGCDVGSDWRFLRGYHQYAYDGKDYIALKEDLRSWTAADMAAQTTKHKWEAAHVAEQLRAYLEGTCVEWLRRYLENGKETLQRTDAPKTHMTHHAVSDHEATLRCWALSFYPAEITLTWQRDGEDQTQDTELVETRPAGDGTFQKWAAVVVPSGQEQRYTCHVQHEGLPKPLTLRWE
->4jaw_B mol:protein length:644  Lacto-N-biosidase
-MGSSHHHHHHSSGLVPRGSHMGYSATAPVNLTRPATVPSMDGWTDGTGAWTLGEGTRVVSSDALAARAQSLASELTKFTDVDIKAATGSATGKDISLTLDASKKAELGDEGFKLNIGSKGLEVIGATDIGVFYGTRSVSQMLRQGQLTLPAGTVATKPKYKERGATLCACQINISTDWIDRFLSDMADLRLNYVLLEMKLKPEEDNTKKAATWSYYTRDDVKKFVKKANNYGIDVIPEINSPGHMNVWLENYPEYQLADNSGRKDPNKLDISNPEAVKFYKTLIDEYDGVFTTKYWHMGADEYMIGTSFDNYSKLKTFAEKQYGAGATPNDAFTGFINDIDKYVKAKGKQLRIWNDGIVNTKNVSLNKDIVIEYWYGAGRKPQELVQDGYTLMNATQALYWSRSAQVYKVNAARLYNNNWNVGTFDGGRQIDKNYDKLTGAKVSIWPDSSYFQTENEVEKEIFDGMRFISQMTWSDSRPWATWNDMKADIDKIGYPLDIREYDYTPVDAGIYDIPQLKSISKGPWELITTPDGYYQMKDTVSGKCLALFTGSKHLDVVTQVGARPELRNCADVSVGQDQRNTANERNTQKWQIRADKDGKYTISPALTQQRLAIATGNEQNIDLETHRPAAGTVAQFPADLVSD
->5e7r_A mol:protein length:314  TAK1 kinase - TAB1 chimera fusion protein
-SLHMIDYKEIEVEEVVGRGAFGVVCKAKWRAKDVAIKQIESESERKAFIVELRQLSRVNHPNIVKLYGACLNPVCLVMEYAEGGSLYNVLHGAEPLPYYTAAHAMSWCLQCSQGVAYLHSMQPKALIHRDLKPPNLLLVAGGTVLKICDFGTACDIQTHMTNNKGSAAWMAPEVFEGSNYSEKCDVFSWGIILWEVITRRKPFDEIGGPAFRIMWAVHNGTRPPLIKNLPKPIESLMTRCWSKDPSQRPSMEEIVKIMTHLMRYFPGADEPLQYPCQHSLPPGEDGRVEPYVDFAEFYRLWSVDHGEQSVVTAP
->4ndy_W mol:protein length:74  Centromere protein X
-SGFRKELVSRLLHLHFKDDKTKVSGDALQLMVELLKVFVVEAAVRGVRQAQAEDALRVDVDQLEKVLPQLLLDF
->6u5t_G mol:protein length:2073  Fatty acid synthase subunit beta
-MDAYSTRPLTLSHGSLEHVLLVPTASFFIASQLQEQFNKILPEPTEGFAADDEPTTPAELVGKFLGYVSSLVEPSKVGQFDQVLNLCLTEFENCYLEGNDIHALAAKLLQENDTTLVKTKELIKNYITARIMAKRPFDKKSNSALFRAVGEGNAQLVAIFGGQGNTDDYFEELRDLYQTYHVLVGDLIKFSAETLSELIRTTLDAEKVFTQGLNILEWLENPSNTPDKDYLLSIPISCPLIGVIQLAHYVVTAKLLGFTPGELRSYLKGATGHSQGLVTAVAIAETDSWESFFVSVRKAITVLFFIGVRCYEAYPNTSLPPSILEDSLENNEGVPSPMLSISNLTQEQVQDYVNKTNSHLPAGKQVEISLVNGAKNLVVSGPPQSLYGLNLTLRKAKAPSGLDQSRIPFSERKLKFSNRFLPVASPFHSHLLVPASDLINKDLVKNNVSFNAKDIQIPVYDTFDGSDLRVLSGSISERIVDCIIRLPVKWETTTQFKATHILDFGPGGASGLGVLTHRNKDGTGVRVIVAGTLDINPDDDYGFKQEIFDVTSNGLKKNPNWLEEYHPKLIKNKSGKIFVETKFSKLIGRPPLLVPGMTPCTVSPDFVAATTNAGYTIELAGGGYFSAAGMTAAIDSVVSQIEKGSTFGINLIYVNPFMLQWGIPLIKELRSKGYPIQFLTIGAGVPSLEVASEYIETLGLKYLGLKPGSIDAISQVINIAKAHPNFPIALQWTGGRGGGHHSFEDAHTPMLQMYSKIRRHPNIMLIFGSGFGSADDTYPYLTGEWSTKFDYPPMPFDGFLFGSRVMIAKEVKTSPDAKKCIAACTGVPDDKWEQTYKKPTGGIVTVRSEMGEPIHKIATRGVMLWKEFDETIFNLPKNKLVPTLEAKRDYIISRLNADFQKPWFATVNGQARDLATMTYEEVAKRLVELMFIRSTNSWFDVTWRTFTGDFLRRVEERFTKSKTLSLIQSYSLLDKPDEAIEKVFNAYPAAREQFLNAQDIDHFLSMCQNPMQKPVPFVPVLDRRFEIFFKKDSLWQSEHLEAVVDQDVQRTCILHGPVAAQFTKVIDEPIKSIMDGIHDGHIKKLLHQYYGDDESKIPAVEYFGGESPVDVQSQVDSSSVSEDSAVFKATSSTDEESWFKALAGSEINWRHASFLCSFITQDKMFVSNPIRKVFKPSQGMVVEISNGNTSSKTVVTLSEPVQGELKPTVILKLLKENIIQMEMIENRTMDGKPVSLPLLYNFNPDNGFAPISEVMEDRNQRIKEMYWKLWIDEPFNLDFDPRDVIKGKDFEITAKEVYDFTHAVGNNCEDFVSRPDRTMLAPMDFAIVVGWRAIIKAIFPNTVDGDLLKLVHLSNGYKMIPGAKPLQVGDVVSTTAVIESVVNQPTGKIVDVVGTLSRNGKPVMEVTSSFFYRGNYTDFENTFQKTVEPVYQMHIKTSKDIAVLRSKEWFQLDDEDFDLLNKTLTFETETEVTFKNANIFSSVKCFGPIKVELPTKETVEIGIVDYEAGASHGNPVVDFLKRNGSTLEQKVNLENPIPIAVLDSYTPSTNEPYARVSGDLNPIHVSRHFASYANLPGTITHGMFSSASVRALIENWAADSVSSRVRGYTCQFVDMVLPNTALKTSIQHVGMINGRKLIKFETRNEDDVVVLTGEAEIEQPVTTFVFTGQGSQEQGMGMDLYKTSKAAQDVWNRADNHFKDTYGFSILDIVINNPVNLTIHFGGEKGKRIRENYSAMIFETIVDGKLKTEKIFKEINEHSTSYTFRSEKGLLSATQFTQPALTLMEKAAFEDLKSKGLIPADATFAGHSLGEYAALASLADVMSIESLVEVVFYRGMTMQVAVPRDELGRSNYGMIAINPGRVAASFSQEALQYVVERVGKRTGWLVEIVNYNVENQQYVAAGDLRALDTVTNVLNFIKLQKIDIIELQKSLSLEEVEGHLFEIIDEASKKSAVKPRPLKLERGFACIPLVGISVPFHSTYLMNGVKPFKSFLKKNIIKENVKVARLAGKYIPNLTAKPFQVTKEYFQDVYDLTGSEPIKEIIDNWEKYEQSDYKDHDGDYKDHDIDYKDDDDK
->2cbo_A mol:protein length:115  NEOCARZINOSTATIN
-AAPTATVTPSSGLSDGTVVKVAGAGLQAGTAYWVAQWARVDTGVWAYNPADNSSVTADANGSASTSLTVRRSFEGFLFDGTRWGTVDCTTAACQVGLSDAAGNGPEGVAISFNHH
->7z46_N mol:protein length:352  Major head protein
-MANPTLFVSYDQNGKKLSFANWISVLSPQDTPFVSMTGKESINQTIFSWQTDALASVDGNNAHVEGSRAEDGEMKPTVIKSNVTQILRKVVRVSDTANTTANYGRGRELMYQLEKKGKEIKRDLEKILLSGQARTDVLADQYLTNSAADPAVAGLNDTHAARKTGAFQFLCAHGGLAGGVVDKTKNGPADPDTGAVTVKVAQNASNPTTNIGFDEADIFDMTLQLYTAGSEADIIMINPAHAKIFAGLQENTQGSRKRIFENTKQFIYEVNSITDPLGQSYKIIVNRWMPTDAVYFFRSADWTQMVLRAPKRTELAKDGSYEKWMIEMEVGLRHRNPYASGVLFTAAGKAAA
->1hmv_D mol:protein length:440  HIV-1 REVERSE TRANSCRIPTASE (SUBUNIT P51)
-PISPIETVPVKLKPGMDGPKVKQWPLTEEKIKALVEICTEMEKEGKISKIGPENPYNTPVFAIKKKDSTKWRKLVDFRELNKRTQDFWEVQLGIPHPAGLKKKKSVTVLDVGDAYFSVPLDEDFRKYTAFTIPSINNETPGIRYQYNVLPQGWKGSPAIFQSSMTKILEPFKKQNPDIVIYQYMDDLYVGSDLEIGQHRTKIEELRQHLLRWGLTTPDKKHQKEPPFLWMGYELHPDKWTVQPIVLPEKDSWTVNDIQKLVGKLNWASQIYPGIKVRQLCKLLRGTKALTEVIPLTEEAELELAENREILKEPVHGVYYDPSKDLIAEIQKQGQGQWTYQIYQEPFKNLKTGKYARMRGAHTNDVKQLTEAVQKITTESIVIWGKTPKFKLPIQKETWETWWTEYWQATWIPEWEFVNTPPLVKLWYQLEKEPIVGAETF
->6e34_AN mol:protein length:233  Capsid protein of PCV2
-MTYPRRRYRRRRHRPRSHLGQILRRRPWLVHPRHRYRWRRKNGIFNTRLSRTFGYTIKRTTVKTPSWAVDMMRFNINDFLPPGGGSNPRSVPFEYYRIRKVKVEFWPCSPITQGDRGVGSSAVILDDNFVTKATALTYDPYVNYSSRHTITQPFSYHSRYFTPKPVLDSTIDYFQPNNKRNQLWLRLQTAGNVDHVGLGTAFENSIYDQEYNIRVTMYVQFREFNLKDPPLNP
->7z4a_X mol:protein length:352  Major head protein
-MANPTLFVSYDQNGKKLSFANWISVLSPQDTPFVSMTGKESINQTIFSWQTDALASVDGNNAHVEGSRAEDGEMKPTVIKSNVTQILRKVVRVSDTANTTANYGRGRELMYQLEKKGKEIKRDLEKILLSGQARTDVLADQYLTNSAADPAVAGLNDTHAARKTGAFQFLCAHGGLAGGVVDKTKNGPADPDTGAVTVKVAQNASNPTTNIGFDEADIFDMTLQLYTAGSEADIIMINPAHAKIFAGLQENTQGSRKRIFENTKQFIYEVNSITDPLGQSYKIIVNRWMPTDAVYFFRSADWTQMVLRAPKRTELAKDGSYEKWMIEMEVGLRHRNPYASGVLFTAAGKAAA
->3l51_B mol:protein length:166  Structural maintenance of chromosomes protein 4
-GKVLDAIIQEKKSGRIPGIYGRLGDLGAIDEKYDIAISSCCHALDYIVVDSIDTAQECVNFLKKHNIGIATFIGLDKMTVWAKKMSKIQTPENTPRLFDLVKVKNEEIRQAFYFALRDTLVANNLDQATRVAYQRDRRWRVVTLQGQIIEQSGTMSGGLEHHHHHH
->5f59_A mol:protein length:154  Histone-lysine N-methyltransferase 2C
-SKSSQYRKMKTEWKSNVYLARSRIQGLGLYAARDIEKHTMVIEYIGTIIRNEVANRKEKLYESQNRGVYMFRMDNDHVIDATLTGGPARYINHSCAPNCVAEVVTFERGHKIIISSSRRIQKGEELCYDYKFDFEDDQHKIPCHCGAVNCRKWM
->6tuv_D mol:protein length:76  Polyubiquitin-C
-MQIFVKTLTGKTITLEVEPSDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGG
->3gfj_A mol:protein length:146  146aa long hypothetical transcriptional regulator
-MLESNENRIQIMSTIAKIYRAMSRELNRRLGELNLSYLDFLVLRATSDGPKTMAYLANRYFVTQSAITASVDKLEEMGLVVRVRDREDARKILIEITEKGLETFNKGIEIYKKLANEVTGDLSEDEVILVLDKISKILKRIEEISQ
->4lf4_H mol:protein length:138  ribosomal protein S8
-MLTDPIADMLTRIRNATRVYKESTDVPASRFKEEILRILAREGFIKGYERVDVDGKPYLRVYLKYGPRRQGPDPRPEQVIHHIRRISKPGRRVYVGVKEIPRVRRGLGIAILSTSKGVLTDREARKLGVGGELICEVW
->5j4d_KC mol:protein length:65  50S ribosomal protein L35
-MPKMKTHKGAKKRVKITASGKVVAMKTGKRHLNWQKSGKEIRQKGRKFVLAKPEAERIKLLLPYE
->2hnb_A mol:protein length:147  Protein mioC
-MADITLISGSTLGGAEYVAEHLAEKLEEAGFTTETLHGPLLEDLPASGIWLVISSTHGAGDIPDNLSPFYEALQEQKPDLSAVRFGAIGIGSREYDTFCGAIDKLEAELKNSGAKQTGETLKINILDHDIPEDPAEEWLGSWVNLLK
->7c2b_C mol:protein length:115  Thioredoxin F2, chloroplastic
-ETVNVTVGQVTEVDKDTFWPIVKAAGDKIVVLDMYTQWCGPSKVIAPKYKELSEKYQDMVFLKLDCNQDNKPLAKELGIRVVPTFKILKDNKVVKEVTGAKYEDLLAAIEAARSG
->6be2_H mol:protein length:227  Fab (F598) Heavy Chain
-QVQLQESGPGLVKPSETLSLTCTVSGGSISGYYWSWIRQPPGKGLEWIGYIHYSRSTNSNPALKSRVTISSDTSKNQLSLRLSSVTAADTAVYYCARDTYYYDSGDYEDAFDIWGQGTMVTVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKAEPKSC
->6uti_E mol:protein length:227  Proteasome subunit alpha
-AYDRAITVFSPDGRLFQVEYAREAVKKGSTALGMKFANGVLLISDKKVRSRLIEQNSIEAIQLIDDYVAAVTSGLVADARVLVDFARISAQQEKVTYGSLVNIENLVKRVADQMQQYTQYGGVRPYGVSLIFAGIDQIGPRLFDCDPAGTINEYKATAIGSGKDAVVSFLEREYKENLPEKEAVTLGIKALKSSLEEGEELKAPEIASITVGNKYRIYDQEEVKKFL
->6rxq_B mol:protein length:254  NAD-dependent protein deacylase
-MGSSHHHHHHSQDPKPRVLVLTGAGISAESGIRTFRAADGLWEEHRVEDVGTPEGFDRDPELVQAFYNARRRQLQQPEIQPNAAHLALAKLQDALGDRFLLVTQNCDNLHERAGNTNVIHMHGELLKVRCSQSGQALDWTGDVTPEDKCHCCQFPAPLRPHVVWFGEMPLGMDEIYMALSMADIFIAIGTSGHVYPAAGFVHEAKLHGAHTVELNLEPSQVGNEFAEKYYGPASQVVPEFVEKLLKGLKAGSIA
->2vil_A mol:protein length:126  VILLIN 14T
-VELSKKVTGKLDKTTPGIQIWRIENMEMVPVPTKSYGNFYEGDCYVLLSTRKTGSGFSYNIHYWLGKNSSQDEQGAAAIYTTQMDEYLGSVAVQHREVQGHESETFRAYFKQGLIYKQGGVASGMK
->5szs_C mol:protein length:1325  Spike glycoprotein
-FFTCNSNANLSMLQLGVPDNSSTIVTGLLPTHWFCANQSTSVYSANGFFYIDVGNHRSAFALHTGYYDANQYYIYVTNEIGLNASVTLKICKFSRNTTFDFLSNASSSFDCIVNLLFTEQLGAPLGITISGETVRLHLYNVTRTFYVPAAYKLTKLSVKCYFNYSCVFSVVNATVTVNVTTHNGRVVNYTVCDDCNGYTDNIFSVQQDGRIPNGFPFNNWFLLTNGSTLVDGVSRLYQPLRLTCLWPVPGLKSSTGFVYFNATGSDVNCNGYQHNSVVDVMRYNLNFSANSLDNLKSGVIVFKTLQYDVLFYCSNSSSGVLDTTIPFGPSSQPYYCFINSTINTTHVSTFVGILPPTVREIVVARTGQFYINGFKYFDLGFIEAVNFNVTTASATDFWTVAFATFVDVLVNVSATNIQNLLYCDSPFEKLQCEHLQFGLQDGFYSANFLDDNVLPETYVALPIYYQHTDINFTATASFGGSCYVCKPHQVNISLNGNTSVCVRTSHFSIRYIYNRVKSGSPGDSSWHIYLKSGTCPFSFSKLNNFQKFKTICFSTVEVPGSCNFPLEATWHYTSYTIVGALYVTWSEGNSITGVPYPVSGIREFSNLVLNNCTKYNIYDYVGTGIIRSSNQSLAGGITYVSNSGNLLGFKNVSTGNIFIVTPCNQPDQVAVYQQSIIGAMTAVNESRYGLQNLLQLPNFYYVSNGGNNCTTAVMTYSNFGICADGSLIPVRPRNSSDNGISAIITANLSIPSNWTTSVQVEYLQITSTPIVVDCATYVCNGNPRCKNLLKQYTSACKTIEDALRLSAHLETNDVSSMLTFDSNAFSLANVTSFGDYNLSSVLPQRNIRSSRIAGRSALEDLLFSKVVTSGLGTVDVDYKSCTKGLSIADLACAQYYNGIMVLPGVADAERMAMYTGSLIGGMVLGGLTSAAAIPFSLALQARLNYVALQTDVLQENQKILAASFNKAINNIVASFSSVNDAITQTAEAIHTVTIALNKIQDVVNQQGSALNHLTSQLRHNFQAISNSIQAIYDRLDSIQADQQVDRLITGRLAALNAFVSQVLNKYTEVRGSRRLAQQKINECVKSQSNRYGFCGNGTHIFSIVNSAPDGLLFLHTVLLPTDYKNVKAWSGICVDGIYGYVLRQPNLVLYSDNGVFRVTSRVMFQPRLPVLSDFVQIYNCNVTFVNISRVELHTVIPDYVDVNKTLQEFAQNLPKYVKPNFDLTPFNLTYLNLSSELKQLEAKTASLFQTTVELQGLIDQINSTYVDLKLLNRFENLIKRMKQIEDKIEEIESKQKKIENEIARIKKIKLVPRGSLEWSHPQFEK
->2fsy_C mol:protein length:282  major capsid protein
-SLGSDADSAGSLIQPMQIPGIIMPGLRRLTIRDLLAQGRTSSNALEYVREEVFTNNADVVAEKALKPESDITFSKQTANVKTIAHWVQASRQVMDDAPMLQSYINNRLMYGLALKEEGQLLNGDGTGDNLEGLNKVATAYDTSLNATGDTRADIIAHAIYQVTESEFSASGIVLNPRDWHNIALLKDNEGRYIFGGPQAFTSNIMWGLPVVPTKAQAAGTFTVGGFDMASQVWDRMDATVEVSREDRDNFVKNMLTILCEERLALAHYRPTAIIKGTFSSGS
->6rxx_Cn mol:protein length:145  40S ribosomal protein s23-like protein
-MSGGKPRGLNAARKLRNNRREQRWADLQYKKRALGTAYKSSPFGGSSHAKGIVLEKVGVEAKQPNSAIRKCVRVQLIKNGKKVTAFVPNDGCLNFVDENDEVLLAGFGRKGKAKGDIPGVRFKVVKVSGVGLLALWKEKKEKPRS
->6xqn_I mol:protein length:394  Calcium uptake protein 1, mitochondrial
-GPTAAALEPHPEEKKKKRSGFRDRKVMEYENRIRAYSTPDKIFRYFATLKVISEPGEAEVFMTPEDFVRSITPNEKQPEHLGLDQYIIKRFDGKKISQEREKFADEGSIFYTLGECGLISFSDYIFLTTVLSTPQRNFEIAFKMFDLNGDGEVDMEEFEQVQSIIRSQTSMGMRHRDRPTTGNTLKSGLCSALTTYFFGADLKGKLTIKNFLEFQRKLQHDVLKLEFERHDPVDGRITERQFGGMLLAYSGVQSKKLTAMQRQLKKHFKEGKGLTFQEVENFFTFLKNINDVDTALSFYHMAGASLDKVTMQQVARTVAKVELSDHVCDVVFALFDCDGNGELSNKEFVSIMKQRLMRGLEKPKDMGFTRLMQAMWKCAQETAWDFALPKQSNW
->4fny_A mol:protein length:327  ALK tyrosine kinase receptor
-RTSTIMTDYNPNYSFAGKTSSISDLKEVPRKNITLIRGLGHGAFGEVYEGQVSGMPNDPSPLQVAVKTLPEVCSEQDELDFLMEALIISKFNHQNIVRCIGVSLQSLPRFILLELMAGGDLKSFLRETRPRPSQPSSLAMLDLLHVARDIACGCQYLEENHFIHRDIAARNCLLTCPGPGRVAKIGDFGMAQDIYRASYYRKGGCAMLPVKWMPPEAFMEGIFTSKTDTWSFGVLLWEIFSLGYMPYPSKSNQEVLEFVTSGGRMDPPKNCPGPVYRIMTQCWQHQPEDRPNFAIILERIEYCTQDPDVINTALPIEYGPLVEEEEK
->7c5l_R mol:protein length:352  Glyceraldehyde-3-phosphate dehydrogenase
-HHHHHHSSGLVPRGSHMASMSKVGINGFGRIGRLVLRRLLEVKSNIDVVAINDLTSPKILAYLLKHDSNYGPFPWSVDFTEDSLIVDGKSIAVYAEKEAKNIPWKAKGAEIIVECTGFYTSAEKSQAHLDAGAKKVLISAPAGEMKTIVYNVNDDTLDGNDTIVSVASSTTNCLAPMAKALHDSFGIEVGTMTTIHAYTGTQSLVDGPRGKDLRASRAAAENIIPHTTGAAKAIGLVIPELSGKLKGHAQRVPVKTGSVTELVSILGKKVTAEEVNNALKQATTNNESFGYTDEEIVSSDIIGSHFGSVFDATQTEITAVGDLQLVKTVAWYDNEYGFVTQLIRTLEKFAKL
->6f0v_B mol:protein length:317  Proton-gated ion channel
-GQDMVSPPPPIADEPLTVNTGIYLIECYSLDDKAETFKVNAFLSLSWKDRRLAFDPVRSGVRVKTYAPEAIWIPEIRFVNVENARDADVVDISVSPDGTVQYLERFSARVLSPLDFRRYPFDSQTLHIYLIVRSVDTRNIVLAVDLEKVGKNDDVFLTGWDIESFTAVVKPANFALEDRLESKLDYQLRISRQYFSYIPNIILPMLFILFISWTAFWSTSYEANVTLVVSTLIAHIAFNILVETNLPKTPYMTYTGAIIFMIYLFYFVAVIEVTVQHYLKVESQPARAASITRASRIAFPVVFLLANIILAFLFFGF
->6yto_C mol:protein length:314  Calcium homeostasis modulator protein 4
-MCPTLNNIVSSLQRNGIFINSLIAALTIGGQQLFSSSTFSCPCQVGKNFYYGSAFLVIPALILLVAGFALRSQMWTITGEYCCSCAPPYRRISPLECKLACLRFFSITGRAVIAPLTWLAVTLLTGTYYECAASEFASVDHYPMFDNVSASKREEILAGFPCCRSAPSDVILVRDEIALLHRYQSQMLGWILITLATIAALVSCCVAKCCSPLTSLQHCYWTSHLQNERELFEQAAEQHSRLLMMHRIKKLFGFIPGSEDVKHIRIPSCQDWKDISVPTLLCMGDDLQGHYSFLGNRVDEDNEEDRSRGIELKP
->6p4g_K mol:protein length:194  uS4
-MPVARSWVCRKTYVTPRRPFEKSRLDQELKLIGEYGLRNKREVWRVKFTLAKIRKAARELLTLDEKDPRRLFEGNALLRRLVRIGVLDEGKMKLDYILGLKIEDFLERRLQTQVFKLGLAKSIHHARVLIRQRHIRVRKQVVNIPSFIVRLDSQKHIDFSLRSPYGGGRPGRVKRKNAKKGQGGAGAGDDEEED
->4v6w_CU mol:protein length:299  60S ribosomal protein L22
-MAPTAKTNKGDTKTAAAKPAEKKAAPAAAAAKGKVEKPKAEAAKPAAAAAKNVKKASEAAKDVKAAAAAAKPAAAKPAAAKPAAASKDAGKKAPAAAAPKKDAKAAAAPAPAKAAPAKKAASTPAAAPPAKKAAPAKAAAPAAAAPAPAAAAPAVAKPAPKPKAKAAPAPSKVVKKNVLRGKGQKKKKVSLRFTIDCTNIAEDSIMDVADFEKYIKARLKVNGKVNNLGNNVTFERSKLKLIVSSDVHFSKAYLKYLTKKYLKKNSLRDWIRVVANEKDSYELRYFRISSNDDEDDDAE
->1oxy_A mol:protein length:628  HEMOCYANIN (SUBUNIT TYPE II)
-TLHDKQIRICHLFEQLSSATVIGDGDKHKHSDRLKNVGKLQPGAIFSCFHPDHLEEARHLYEVFWEAGDFNDFIEIAKEARTFVNEGLFAFAAEVAVLHRDDCKGLYVPPVQEIFPDKFIPSAAINEAFKKAHVRPEFDESPILVDVQDTGNILDPEYRLAYYREDVGINAHHWHWHLVYPSTWNPKYFGKKKDRKGELFYYMHQQMCARYDCERLSNGMHRMLPFNNFDEPLAGYAPHLTHVASGKYYSPRPDGLKLRDLGDIEISEMVRMRERILDSIHLGYVISEDGSHKTLDELHGTDILGALVESSYESVNHEYYGNLHNWGHVTMARIHDPDGRFHEEPGVMSDTSTSLRDPIFYNWHRFIDNIFHEYKNTLKPYDHDVLNFPDIQVQDVTLHARVDNVVHTFMREQELELKHGINPGNARSIKAKYYHLDHEPFSYAVNVQNNSASDKHATVRIFLAPKYDELGNEIKADELRRTAIELDKFKTDLHPGKNTVVRHSLDSSVTLSHQPTFEDLLHGVGLNEHKSEYCSCGWPSHLLVPKGNVAGMEYHLFVMLTDWDKDKVDGSESVACVDAVSYCGARDHKYPDKKPMGFPFDRPIHTEHISDFLTNNMFIKDIKIKFHE
->7vmv_E mol:protein length:82  Core protein
-MSYYHHHHHHDYDIPTTENLYFQGAMGSADLSLEKAANVQWDEMADITGSSPIIEVKQDEDGSFSIRDIEETNMIAQVKTQR
->5o4y_F mol:protein length:16  PHE-MAA-ASN-PRO-HIS-LEU-SER-TRP-SER-TRP-9KK-9KK-ARG-CCS-GLY-NH2
-FANPHLSWSWXXRCGX
->4hel_B mol:protein length:525  60 kDa chaperonin 4
-AAKDVKFGNDARVKMLRGVNVLADAVKVTLGPKGRNVVLDKSFGAPTITKDGVSVAREIELEDKFENMGAQMVKEVASKANDAAGDGTTTATVLAQAIITEGLKAVAAGMNPMDLKRGIDKAVTAAVEELKALSVPCSDSKAIAQVGTISANSDETVGKLIAEAMDKVGKEGVITVEDGTGLQDELDVVEGMQFDRGYLSPYFINKPETGAVELESPFILLADKKISNIREMLPVLEAVAKAGKPLLIIAEDVEGEALATLVVNTMRGIVKVAAVKAPGFGDRRKAMLQDIATLTGGTVISEEIGMELEKATLEDLGQAKRVVINKDTTTIIDGVGEEAAIQGRVAQIRQQIEEATSDYDREKLQERVAKLAGGVAVIKVGAATEVEMKEKKARVEDALHATRAAVEEGVVAGGGVALIRVASKLADLRGQNEDQNVGIKVALRAMEAPLRQIVLNCGEEPSVVANTVKGGDGNYGYNAATEEYGNMIDMGILDPTKVTRSALQYAASVAGLMITTECMVTDLPK
->3dmd_B mol:protein length:328  Signal recognition particle receptor
-GSHMASMFGKLREKLKSFVKRVEEEVEKEEEEVEKKGLLDRILTVEIKEKDVDKALDELEIDLLEADVALEVVDALREKIKQKLVGKKVRIGTDKGKIIEEAVKEAVSEILETSRRIDLIEEIRKAEKPYVIMFVGFNGSGKTTTIAKLANWLKNHGFSVVIAASDTFRAGAIEQLEEHAKRIGVKVIKHSYGADPAAVAYDAIQHAKARGIDVVLIDTAGRSETNRNLMDEMKKIARVTKPNLVIFVGDALAGNAIVEQARQFNEAVKIDGIILTKLDADARGGAALSISYVIDAPILFVGVGQGYDDLRPFEKEWFLERIFGEENA
->3jcd_D mol:protein length:209  50S ribosomal protein L3
-MIGLVGKKVGMTRIFTEDGVSIPVTVIEVEANRVTQVKDLANDGYRAIQVTTGAKKANRVTKPEAGHFAKAGVEAGRGLWEFRLAEGEEFTVGQSISVELFADVKKVDVTGTSKGKGFAGTVKRWNFRTQDATHGNSLSHRVPGSIGQNQTPGKVFKGKKMAGQMGNERVTVQSLDVVRVDAERNLLLVKGAVPGATGSDLIVKPAVKA
->3ccj_K mol:protein length:132  50S ribosomal protein L14P
-MEALGADVTQGLEKGSLITCADNTGARELKVISVHGYSGTKNRHPKAGLGDKITVSVTKGTPEMRRQVLEAVVVRQRKPIRRPDGTRVKFEDNAAVIVDENEDPRGTELKGPIAREVAQRFGSVASAATMIV
->7c2o_A mol:protein length:368  R-specific carbonyl reductase
-MTKAVPDKFQGFAVSDPKNWNRPKLASYERKQINPHDVVLKNEVCGLCYSDIHTLSAGWQPLQRDNLVVGHEIIGEVIAVGDEVTEFKVGDRVGIGAASSSCRSCQRCDSDNEQYCKQGAATYNSKDVRSNNYVTQGGYSSHSIADEKFVFAIPEDLPSSYGAPLMCAGITVFSPLIRNLGLDARGKNVGIIGIGGLGHLALQFANAMGANVTAFSRSSSKKEQAMKLGAHDFVATGEDKTWYKNYDDHFDFILNCASGIDGLNLSEYLSTLKVDKKFVSVGLPPSEDKFEVSPFTFLQQGASFGSSLLGSKTEVKEMLNLAAKHNVRPMIEEVPISEENCAKALDRCHAGDVRYRFVFTDFDKAFKA
->6iax_B mol:protein length:355  Cyclic nucleotide-gated potassium channel mll3241
-MSVLPFLRIYAPLNAVLAAPGLLAVAALTIPDMSGRSRLALAALLAVIWGAYLLQLAATLLKRRAGVVRDRTPKIAIDVLAVLVPLAAFLLDGSPDWSLYCAVWLLKPLRDSTFFPVLGRVLANEARNLIGVTTLFGVVLFAVALAAYVIERDIQPEKFGSIPQAMWWAVVTLSTTGYGDTIPQSFAGRVLAGAVMMSGIGIFGLWAGILATGFYQEVRRGDFVRNWQLVAAVPLFQKLGPAVLVEIVRALRARTVPAGAVICRIGEPGDRMFFVVEGSVSVATPNPVELGPGAFFGEMALISGEPRSATVSAATTVSLLSLHSADFQMLCSSSPEIAEIFRKTALERRGAAASA
->5l64_F mol:protein length:288  Probable proteasome subunit alpha type-7
-MTSIGTGYDLSNSVFSPDGRNFQVEYAVKAVENGTTSIGIKCNDGVVFAVEKLITSKLLVPQKNVKIQVVDRHIGCVYSGLIPDGRHLVNRGREEAASFKKLYKTPIPIPAFADRLGQYVQAHTLYNSVRPFGVSTIFGGVDKNGAHLYMLEPSGSYWGYKGAATGKGRQSAKAELEKLVDHHPEGLSAREAVKQAAKIIYLAHEDNKEKDFELEISWCSLSETNGLHKFVKGDLLQEAIDFAQKEINGDDDEDEDDSDNVMSSDDENAPVATNANATTDQEGDIHLE
->6zn5_a mol:protein length:72  40S ribosomal protein S25
-DKLNNLVLFDKATYDKLCKEVPNYKLITPAVVSERLKIRGSLARAALQELLSKGLIKLVSKHRAQVIYTRNT
->3b3v_A mol:protein length:291  Bacterial leucyl aminopeptidase
-MPPITQQATVTAWLPQVDASQITGTISSLESFTNRFYTTTSGAQASDWIASEWQALSASLPNASVKQVSHSGYNQKSVVMTITGSEAPDEWIVIGGHLDSTIGSHTNEQSVAPGADDDASGIAAVTEVIRVLSENNFQPKRSIAFMAYAAEEVGLRGSQDLANQYKSEGKNVVSALQLDMTNYKGSAQDVVFITDYTDSNFTQYLTQLMDEYLPSLTYGFDTCGYACADHASWHNAGYPAAMPFESKFNDYNPRIHTTQDTLANSDPTGSHAKKFTQLGLAYAIEMGSATG
->2owp_A mol:protein length:129  Hypothetical protein Bxe_B1374
-GMEVNQPDIVAQVQAAFVEYERALVENDIEAMNALFWHTPETVRYGIAEVQHGGEAIRAWRERCEPVPKSRKLHRTVVTTFGTDFATVSTEFTSDATPLLGRQMQTWARLSPADGWKIVAAHVSLIAMP
->6dr6_A mol:protein length:16  ORT-CYS-VAL-PHE-XXX-CYS-GLU-ASP-ORT-ALA-ILE-ILE-GLY-LEU-ORA-VAL
-ACVFACEDAAIIGLAV
->7phw_F mol:protein length:209  Monoclonal antibody Cy.004 light chain
-ALTQPSSVSANPGETVKITCSGSTYNYGWYQQKSPGSAPVTVIYYNDKRPSDIPSRFSGSKSGSTGTLTITGVQAEDEAVYYCGNSDSRNVAFGAGTTLTVLRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNRGEC
->3gvt_B mol:protein length:351  Pumilio homolog 2
-GTGRSRLLEDFRNNRFPNLQLRDLIGHIVEFSQDQHGSRFIQQKLERATPAERQIVFNEILQAAYQLMTDVFGNYVIQKFFEFGSLDQKLALATRIRGHVLPLALQMYGCRVIQKALESISSDQQSEMVKELDGHVLKCVKDQNGNHVVQKCIECVQPQSLQFIIDAFKGQVFVLSTHPYGCRVIQRILEHCTAEQTLPILEELHQHTEQLVQDQYGNYVIQHVLEHGRPEDKSKIVSEIRGKVLALSQHKFASNVVEKCVTHASRAERALLIDEVCCQNDGPHSALYTMMKDQYANYVVQKMIDMAEPAQRKIIMHKIRPHITTLRKYTYGKHILAKLEKYYLKNSPDLG
->6z0l_B mol:protein length:50  Cys-N2 Strand
-XGLCALRSELQALRREGFSPEELAALESELQALERELAALRSELQALRGX
->4ujc_CC mol:protein length:293  40S RIBOSOMAL PROTEIN US5
-MADDAGAAGGPGGPGGPGMGNRGGFRGGFGSGIRGRGRGRGRGRGRGRGARGGKAEDKEWMPVTKLGRLVKDMKIKSLEEIYLFSLPIKESEIIDFFLGASLKDEVLKIMPVQKQTRAGQRTRFKAFVAIGDYNGHVGLGVKCSKEVATAIRGAIILAKLSIVPVRRGYWGNKIGKPHTVPCKVTGRCGSVLVRLIPAPRGTGIVSAPVPKKLLMMAGIDDCYTSARGCTATLGNFAKATFDAISKTYSYLTPDLWKETVFTKSPYQEFTDHLVKTHTRVSVQRTQAPAVATT
->6ywy_OO mol:protein length:320  Related to ribosomal protein S15 (Mitochondrial)
-MPPRLPGPQGLRSLTLCLRPAVASPAQALQPLIQTANISQKEKKRKMKQDPYGWAQAQQRKAVNVKRQAELQAQRDAAWGDPVKGITTPFVESFDSAGQASVSPPKVGPDGQLVEEPKPLPTSPHLRNYLLNKDEFDSAIQYAEHILKPIKAEDRLTADPEKEDEEAREHAARHAKAVAALERIAKLEHGGAKDRKHANIRRCIETFGRHITDQSLERPTPPLARGVEPKPQPVRAGPDTGSSEVQIAILTSKIRALSKALEGHGGNRDKNNKRSLRRLCHKRQRLLRYMERKERGSGRWHHMLETLGLTPATWKGQITL
->5vyo_D mol:protein length:200  Thiol:disulfide interchange protein
-SNAAGFAQASPSAPVAGKDFEVMKSPQPVSAPAGKVEVIEFFWYGCPHAYEFEPTIEAWVKKQGDKIAFKRVPVAFRDDFVPHSKLFYALAALGVSEKVTPAVFNAIHKEKNYLLTPQAQADFLATQGVDKKKFLDAYNSFSVQGQVKQSAELLKNYNIDGVPTIVVQGKYKTGPAYTNSLEGTAQVLDFLVKQVQDKKL
->2i0c_A mol:protein length:259  Glutamate receptor, ionotropic kainate 2
-GSNRSLIVTTILEEPYVLFKKSDKPLYGNDRFEGYCIDLLRELSTILGFTYEIRLVEDGKYGAQDDVNGQWNGMVRELIDHKADLAVAPLAITCVREKVIDFSKPFMTLGISILYRKGTPIDSADDLAKQTKIEYGAVEDGATMTFFKKSKISTYDKMWAFMSSRRQSVLVKSNEEGIQRVLTSDYAFLMESTTIEFVTQRNCNLTQIGGLIDSKGYGVGTPMGSPYRDKITIAICQLQEEGKLHMMKEKWWRGNGCPS
->2pod_A mol:protein length:410  Mandelate racemase / muconate lactonizing enzyme
-MSLKITEIETLRPEEFPNLLWVLVHTDEGITGLGETFYGACSAEAYIHEWAANRLIGEDPLQIDRHAKRLSGYLGFRSAGAEMRGNSALDIALWDIFGKATGQPIYQLLGGKCRDTIRTYNTCAGPHYVRTAKQQSVANWGLANSVSARYDDLNAFLHRADELALDLLDSGITAMKIWPFDPYAEASDGYYISKSDLKRALEPFEKIRRAVGDKMDVMVEFHSLWNLPPALQIAEALREYETFWHEDPIRMDSLSSLKRYAERSLAPVCASETLATRWGFRDLLETNAAGIVMLDISWCGGLSEARKIASMAEAWHLPVAPHDCTGPVVLTASTHLSLNAPNALVQESVRAFYDGWYRDLVTALPTVKDGHITVPDGPGLGLELMPDIRERLTIAVRNTSDCEGHHHHHH
->6bsr_A mol:protein length:666  PBP4 protein
-MGSDKIHHHHHHENLYFQGHMSQWQAKQELAEAKKTATTFLNVLSKQEFDKLPSVVQEASLKKNGYDTKSVVEKYQAIYSGIQAEGVKASDVQVKKAKDNQYTFTYKLSMSTPLGEMKDLSYQSSIAKKGDTYQIAWKPSLIFPDMSGNDKISIQVDNAKRGEIVDRNGSGLAINKVFDEVGVVPGKLGSGAEKTANIKAFSDKFGVSVDEINQKLSQGWVQADSFVPITVASEPVTELPTGAATKDTESRYYPLGEAAAQLIGYTGTITAEDIEKNPELSSTGVIGKTGLERAFDKELRGQDGGSLVILDDKENVKKALQTKEKKDGQTIKLTIDSGVQQQAFAIFDKRPGSAVITDPQKGDLLATVSSPSYDPNKMANGISQKEYDAYNNNKDLPFTARFATGYAPGSTFKTITGAIGLDAGTLKPDEELEINGLKWQKDKSWGGYFATRVKEASPVNLRTALVNSDNIYFAQQTLRMGEDKFRAGLNKFIFGEELDLPIAMTPAQISNEDKFNSEILLADTGYGQGQLLISPIQQATMYSVFQNNGTLVYPKLVLDKETKKKDNVISANAANTIATDLLGSVEDPSGYVYNMYNPNFSLAAKTGTAEIKDKQDTDGKENSFLLTLDRSNNKFLTMIMVENSGENGSATDISKPLIDYLEATIK
->1i48_J mol:protein length:445  CYSTATHIONINE GAMMA-SYNTHASE
-MAKAVDAAAAAAAAIAPVDTTVVNEDVALVENETCNDQNVQFDSLPSMKYASFLNSDGSVAIHAGERLGRGIVTDAITTPVVNTSAYFFNKTSELIDFKEKRRASFEYGRYGNPTTVVLEEKISALEGAESTLLMASGMCASTVMLLALVPAGGHIVTTTDCYRKTRIFIETILPKMGITATVIDPADVGALELALNQKKVNLFFTESPTNPFLRCVDIELVSKLCHEKGALVCIDGTFATPLNQKALALGADLVLHSATKFLGGHNDVLAGCISGPLKLVSEIRNLHHILGGALNPNAAYLIIRGMKTLHLRVQQQNSTALRMAEILEAHPKVRHVYYPGLQSHPEHHIAKKQMTGFGGAVSFEVDGDLLTTAKFVDALKIPYIAPSFGGCESIVDQPAIMSYWDLSQSDRAKYGIMDNLVRFSFGVEDFDDLKADILQALDSI
->3u39_C mol:protein length:319  6-phosphofructokinase
-MKRIGVLTSGGDSPGMNAAIRSVVRKAIYHGVEVYGVYHGYAGLIAGNIKKLEVGDVGDIIHRGGTILYTARCPEFKTEEGQKKGIEQLKKHGIEGLVVIGGDGSYQGAKKLTEHGFPCVGVPGTIDNDIPGTDFTIGFDTALNTVIDAIDKIRDTATSHERTYVIEVMGRHAGDIALWSGLAGGAETILIPEADYDMNDVIARLKRGHERGKKHSIIIVAEGVGSGVDFGRQIQEATGFETRVTVLGHVQRGGSPTAFDRVLASRLGARAVELLLEGKGGRCVGIQNNQLVDHDIAEALANKHTIDQRMYALSKELSI
->5i8e_C mol:protein length:222  VRC34.01 Fab heavy chain
-QEVLVQSGAEVKKPGASVKVSCRAFGYTFTGNALHWVRQAPGQGLEWLGWINPHSGDTTTSQKFQGRVYMTRDKSINTAFLDVTRLTSDDTGIYYCARDKYYGNEAVGMDVWGQGTSVTVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEP
->3mhv_C mol:protein length:117  Vacuolar protein sorting-associated protein 4
-GSPDLAARTTMFEINVGDTPCVLTKEDYRTLGAMTEGYSGSDIAVVVKDALMQPIRKIQSATHFKDVSTEDDETRKLTPCSPGDDGAIEMSWTDIEADELKEPDLTIKDFLKAIKST
->7opd_d mol:protein length:1143  DNA damage-binding protein 1
-SNAMSYNYVVTAQKPTAVNGCVTGHFTSAEDLNLLIAKNTRLEIYVVTAEGLRPVKEVGMYGKIAVMELFRPKGESKDLLFILTAKYNACILEYKQSGESIDIITRAHGNVQDRIGRPSETGIIGIIDPECRMIGLRLYDGLFKVIPLDRDNKELKAFNIRLEELHVIDVKFLYGCQAPTICFVYQDPQGRHVKTYEVSLREKEFNKGPWKQENVEAEASMVIAVPEPFGGAIIIGQESITYHNGDKYLAIAPPIIKQSTIVCHNRVDPNGSRYLLGDMEGRLFMLLLEKEEQMDGTVTLKDLRVELLGETSIAECLTYLDNGVVFVGSRLGDSQLVKLNVDSNEQGSYVVAMETFTNLGPIVDMCVVDLERQGQGQLVTCSGAFKEGSLRIIRNGIGIHEHASIDLPGIKGLWPLRSDPNRETDDTLVLSFVGQTRVLMLNGEEVEETELMGFVDDQQTFFCGNVAHQQLIQITSASVRLVSQEPKALVSEWKEPQAKNISVASCNSSQVVVAVGRALYYLQIHPQELRQISHTEMEHEVACLDITPLGDSNGLSPLCAIGLWTDISARILKLPSFELLHKEMLGGEIIPRSILMTTFESSHYLLCALGDGALFYFGLNIETGLLSDRKKVTLGTQPTVLRTFRSLSTTNVFACSDRPTVIYSSNHKLVFSNVNLKEVNYMCPLNSDGYPDSLALANNSTLTIGTIDEIQKLHIRTVPLYESPRKICYQEVSQCFGVLSSRIEVQDTSGGTTALRPSASTQALSSSVSSSKLFSSSTAPHETSFGEEVEVHNLLIIDQHTFEVLHAHQFLQNEYALSLVSCKLGKDPNTYFIVGTAMVYPEEAEPKQGRIVVFQYSDGKLQTVAEKEVKGAVYSMVEFNGKLLASINSTVRLYEWTTEKELRTECNHYNNIMALYLKTKGDFILVGDLMRSVLLLAYKPMEGNFEEIARDFNPNWMSAVEILDDDNFLGAENAFNLFVCQKDSAATTDEERQHLQEVGLFHLGEFVNVFCHGSLVMQNLGETSTPTQGSVLFGTVNGMIGLVTSLSESWYNLLLDMQNRLNKVIKSVGKIEHSFWRSFHTERKTEPATGFIDGDLIESFLDISRPKMQEVVANLQYDDGSGMKREATADDLIKVVEELTRIH
->7ba7_A mol:protein length:236  14-3-3 protein sigma
-GAMGSMERASLIQKAKLAEQAERYEDMAAFMKGAVEKGEELSNEERCLLSVAYKNVVGGQRAAWRVLSSIEQKSNEEGSEEKGPEVREYREKVETELQGVCDTVLGLLDSHLIKEAGDAESRVFYLKMKGDYYRYLAEVATGDDKKRIIDSARSAYQEAMDISKKEMPPTNPIRLGLALNFSVFHYEIANSPEEAISLAKTTFDEAMADLHTLSEDSYKDSTLIMQLLRDNLTLWT
->4v8d_CE mol:protein length:256  30S RIBOSOMAL PROTEIN S2
-MPVEITVKELLEAGVHFGHERKRWNPKFARYIYAERNGIHIIDLQKTMEELERTFRFIEDLAMRGGTILFVGTKKQAQDIVRMEAERAGMPYVNQRWLGGMLTNFKTISQRVHRLEELEALFASPEIEERPKKEQVRLKHELERLQKYLSGFRLLKRLPDAIFVVDPTKEAIAVREARKLFIPVIALADTDSDPDLVDYIIPGNDDAIRSIQLILSRAVDLIIQARGGVVEPSPSYALVQEAEATETPEGESEVEA
->6ald_D mol:protein length:363  FRUCTOSE-1,6-BIS(PHOSPHATE) ALDOLASE
-PHSHPALTPEQKKELSDIAHRIVAPGKGILAADESTGSIAKRLQSIGTENTEENRRFYRQLLLTADDRVNPCIGGVILFHETLYQKADDGRPFPQVIKSKGGVVGIKVDKGVVPLAGTNGETTTQGLDGLSERCAQYKKDGADFAAWRCVLKIGEHTPSALAIMENANVLARYASICQQNGIVPIVEPEILPDGDHDLKRCQYVTEKVLAAVYKALSDHHIYLEGTLLKPNMVTPGHACTQKYSHEEIAMATVTALRRTVPPAVTGVTFLSGGQSEEEASINLNAINKCPLLKPWALTFSYGRALQASALKAWGGKKENLKAAQEEYVKRALANSLACQGKYTPSGQAGAAASESLFISNHAY
->3eff_N mol:protein length:139  Voltage-gated potassium channel
-SALHWRAAGAATVLLVIVLLAGSYLAVLAERGAPGAQLITYPRALWWSVETATTVGYGDLYPVTLWGRLVAVVVMVAGITSFGLVTAALATWFVGREQERRGHFVRHSEKAAEEAYTRTTRALHERFDRLERMLDDNRR
->1px6_B mol:protein length:209  Glutathione S-transferase P
-PPYTVVYFPVRGRCAALRMLLADQGQSWKEEVVTVETWQEGSLKASCLYGQLPKFQDGDLTLYQSNTILRHLGRTLGLYGKDQQEAALVDMVNDGVEDLRCKYISLIYTNYEAGKDDYVKALPGQLKPFETLLSQNQGGKTFIVGDQISFANYNLLDLLLIHEVLAPGCLDAFPLLSAYVGRLSARPKLKAFLASPEYVNLPINGNGKQ
->6lkn_C mol:protein length:361  Cell cycle control protein 50A
-MAMNYNAKDEVDGGPPCAPGGTAKTRRPDNTAFKQQRLPAWQPILTAGTVLPIFFIIGLIFIPIGIGIFVTSNNIREIEIDYTGTEPSSPCNKCLSPDVTPCFCTINFTLEKSFEGNVFMYYGLSNFYQNHRRYVKSRDDSQLNGDSSALLNPSKECEPYRRNEDKPIAPCGAIANSMFNDTLELFLIGQDSYPIPIALKKKGIAWWTDKNVKFRNPPGGDNLEERFKGTTKPVNWLKPVYMLDSDPDNNGFINEDFIVWMRTAALPTFRKLYRLIERKSDLHPTLPAGRYWLNVTYNYPVHYFDGRKRMILSTISWMGGKNPFLGIAYIAVGSISFLLGVVLLVINHKYRNSSNTADITI
->1ees_A mol:protein length:178  GTP-BINDING PROTEIN
-MQTIKCVVVGDGAVGKTCLLISYTTNKFPSEYVPTVFDNYAVTVMIGGEPYTLGLFDTAGQEDYDRLRPLSYPQTDVFLVCFSVVSPSSFENVKEKWVPEITHHCPKTPFLLVGTQIDLRDDPSTIEKLAKNKQKPITPETAEKLARDLKAVKYVECSALTQKGLKNVFDEAILAALE
->3ow9_B mol:protein length:6  KLVFFA hexapeptide segment from Amyloid beta
-KLVFFA
->7ezx_hI mol:protein length:164  Phycoerythrin alpha subunit
-MKSVITTVVSAADAAGRFPSNSDLESIQGNIQRSAARLEAAEKLAGNHEAVVKEAGDACFAKYAYLKNPGEAGENQEKINKCYRDVDHYMRLVNYCLVVGGTGPLDEWGIAGAREVYRTLNLPTSAYVASIAYTRDRLCVPRDMSAQAGVEFSAYLDYLINALS
->7o2z_P mol:protein length:9  P/A#1 epitope peptide
-XAPAPAAPA
->6zsk_A mol:protein length:158  Cytochrome c
-MNKPSFLLVGLLVVSGVLGAAETKVKYPDGFRSWYHVKSMVIQPGHPLENPFGGIHHVYANAEAIQGLRGGNYPDGAVLVFDLFDYQEDNHALVEGKRKLIGVMERDAKRFSATGGWGYEGFGEGKPDKRLVTDGGQGCFGCHAAQKESQYVFSRLRD
->5k28_B mol:protein length:64  Mitogen-activated protein kinase kinase kinase 11
-HMPVWTALFDYEPSGQDELALRKGDRVEVLSRDAAISGDEGWWAGQVGGQVGIFPSNYVSRGGG
->6xc7_D mol:protein length:215  CC12.3 light chain
-EIVLTQSPGTLSLSPGERATLSCRASQSVSSYLAWYQQKPGQAPRLLIYGASSRATGIPDRFSGSGSGTDFTLTISRLEPEDFAVYYCQQYGSSPRTFGQGTKLEIKRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNRGECS
->3mfe_O mol:protein length:240  Proteasome subunit alpha
-MEQAMRERSELARKGIARAKSVVALAYAGGVLFVAENPSRSLQKISELYDRVGFAAAGKFNEFDNLRRGGIQFADTRGYAYDRRDVTGRQLANVYAQTLGTIFTEQAKPYEVELCVAEVAHYGETKRPELYRITYDGSIADEPHFVVMGGTTEPIANALKESYAENASLTDALRIAVAALRAGSADTSGGDQPTLGVASLEVAVLDANRPRRAFRRITGSALQALLVDQESPQSDGESSG
->5uuh_A mol:protein length:241  DNA-7-methylguanine glycosylase
-GPVPMHPFVKALQEHFTAHQNPEKAEPMARYMKNHFLFLGIQTPERRQLLKDIIQIHTLPDQKDFQIIIRELWDLPEREFQAAALDIMQKYKKHINETHIPFLEELIVTKSWWDSVDSIVPTFLGDIFLKHPELISAYIPKWIASDNIWLQRAAILFQLKYKQKMDEELLFWIIGQLHSSKEFFIQKAIGWVLREYAKTNPDVVWEYVQNNELAPLSKREAIKHIKQNYGINNEKIGETLS
->4y6t_C mol:protein length:166  Coat protein
-MTAPIPVVPVSRPQAKTSLKLPNNQVWVTRKASEWSAKTIDTNDAIPFKTIVEGIPEINSETKFYRLLIGFVAVSDGTFGMVDGVTGDVIPDPPVVGRLGFKKNTYRSRDFDLGGKLLNQLDDRAIVWCLDERRRDAKRVQLAGYWIAISKPAPLMPPEDFLVNQD
->1hx6_B mol:protein length:394  MAJOR CAPSID PROTEIN
-AQVQQLTPAQQAALRNQQAMAANLQARQIVLQQSYPVIQQVETQTFDPANRSVFDVTPANVGIVKGFLVKVTAAITNNHATEAVALTDFGPANLVQRVIYYDPDNQRHTETSGWHLHFVNTAKQGAPFLSSMVTDSPIKYGDVMNVIDAPATIAAGATGELTMYYWVPLAYSETDLTGAVLANVPQSKQRLKLEFANNNTAFAAVGANPLEAIYQGAGAADCEFEEISYTVYQSYLDQLPVGQNGYILPLIDLSTLYNLENSAQAGLTPNVDFVVQYANLYRYLSTIAVFDNGGSFNAGTDINYLSQRTANFSDTRKLDPKTWAAQTRRRIATDFPKGVYYCDNRDKPIYTLQYGNVGFVVNPKTVNQNARLLMGYEYFTSRTELVNAGTISTT
->2hbg_A mol:protein length:147  HEMOGLOBIN (DEOXY)
-GLSAAQRQVIAATWKDIAGADNGAGVGKKCLIKFLSAHPQMAAVFGFSGASDPGVAALGAKVLAQIGVAVSHLGDEGKMVAQMKAVGVRHKGYGNKHIKAQYFEPLGASLLSAMEHRIGGKMNAAAKDAWAAAYADISGALISGLQS
->3wry_D mol:protein length:451  Replicase large subunit
-SYTRSEEIESLEQFHMATASSLIHKQMCSIVYTGPLKVQQMKNFIDSLVASLSAAVSNLVKILKDTAAIDLETRQKFGVLDVASKRWLVKPSAKNHAWGVVETHARKYHVALLEHDEFGIITCDNWRRVAVSSESVVYSDMAKLRTLRRLLKDGEPHVSSAKVVLVDGVPGCGKTKEILSRVNFEEDLILVPGRQAAEMIRRRANASGIIVATKDNVRTVDSFLMNYGKGARCQFKRLFIDEGLMLHTGCVNFLVEMSLCDIAYVYGDTQQIPYINRVTGFPYPAHFAKLEVDEVETRRTTLRCPADVTHFLNQRYEGHVMCTSSEKKSVSQEMVSGAASINPVSKPLKGKILTFTQSDKEALLSRGYADVHTVHEVQGETYADVSLVRLTPTPVSIIARDSPHVLVSLSRHTKSLKYYTVVMDPLVSIIRDLERVSSYLLDMYKVDAGTQ
->6hvt_U mol:protein length:252  Proteasome subunit alpha type-1
-MSGAAAASAAGYDRHITIFSPEGRLYQVEYAFKATNQTNINSLAVRGKDCTVVISQKKVPDKLLDPTTVSYIFCISRTIGMVVNGPIPDARNAALRAKAEAAEFRYKYGYDMPCDVLAKRMANLSQIYTQRAYMRPLGVILTFVSVDEELGPSIYKTDPAGYYVGYKATATGPKQQEITTNLENHFKKSKIDHINEESWEKVVEFAITHMIDALGTEFSKNDLEVGVATKDKFFTLSAENIEERLVAIAEQD
->5z3u_H mol:protein length:122  Histone H2B 1.1
-AKSAPAPKKGSKKAVTKTQKKDGKKRRKTRKESYAIYVYKVLKQVHPDTGISSKAMSIMNSFVNDVFERIAGEASRLAHYNKRSTITSREIQTAVRLLLPGELAKHAVSEGTKAVTKYTSAK
->2ex3_C mol:protein length:575  DNA polymerase
-MKHMPRKMYSCAFETTTKVEDCRVWAYGYMNIEDHSEYKIGNSLDEFMAWVLKVQADLYFHNLKFAGAFIINWLERNGFKWSADGLPNTYNTIISRMGQWYMIDICLGYKGKRKIHTVIYDSLKKLPFPVKKIAKDFKLTVLKGDIDYHKERPVGYKITPEEYAYIKNDIQIIAEALLIQFKQGLDRMTAGSDSLKGFKDIITTKKFKKVFPTLSLGLDKEVRYAYRGGFTWLNDRFKEKEIGEGMVFDVNSLYPAQMYSRLLPYGEPIVFEGKYVWDEDYPLHIQHIRCEFELKEGYIPTIQIKRSRFYKGNEYLKSSGGEIADLWLSNVDLELMKEHYDLYNVEYISGLKFKATTGLFKDFIDKWTYIKTTSEGAIKQLAKLMLNSLYGKFASNPDVTGKVPYLKENGALGFRLGEEETKDPVYTPMGVFITAWARYTTITAAQACYDRIIYCDTDSIHLTGTEIPDVIKDIVDPKKLGYWAHESTFKRAKYLRQKTYIQDIYMKEVDGKLVEGSPDDYTDIKFSVKCAGMTDKIKKEVTFENFKVGFSRKMKPKPVQVPGGVVLVDDTFTIK
->2jo4_D mol:protein length:22  KIA7
-XAKAAAAAIKAIAAIIKAGGYX
->7vd5_b mol:protein length:484  Photosystem II CP47 reaction center protein
-ALPWYRVHTVVLNDPGRLIAVHLMHTALVAGWAGSMALYELAVFDPSDPVLNPMWRQGMFVMPFMTRLGITDSWGGWSITGESVSNPGIWSFEGVALSHIILSGMCFLAAIWHWVYWDLELFRDPRTGEPALDLPKIFGIHLFLSGLLCFGFGAFHVTGLFGPGIWVSDAYGITGKVQPVAPAWGADGFNPFNPGGIAAHHIAAGIFGIFAGIFHLTVRPPQRLYRALRMGNIETVLSSSISAVFFAAFVTSGTMWYGAAATPIELFGPTRYQWDSGYFQQEIERQVETSVSEGLSESQAWSRIPDKLAFYDYIGNNPAKGGLFRAGPMNKGDGIAEAWLGHPIFRDKEGRELTVRRMPAFFETFPVILVDKDGIIRADIPFRRAESKYSIEQVGVTVDFYGGKLNGQTFKDAPTVKKFARKAQLGEVFEFDRTSLESDGVFRSSPRGWYTYGHANFALLFFFGHLWHGGRTIFRDVFTGIGAE
->7c4w_C mol:protein length:240  Capsid protein VP3
-GIPAELRPGTNQFLTTDDDTAAPILPGFTPTPTIHIPGEVHSLLELCRVETILEVNNTTEATGLTRLLIPVSSQNKADELCAAFMVDPGRIGPWQSTLVGQICRYYTQWSGSLKVTFMFTGSFMATGKMLVAYSPPGSAQPANRETAMLGTHVIWDFGLQSSVSLVIPWISNTHFRTAKTGGNYDYYTAGVVTLWYQTNYVVPPETPGEAYIIAMGAAQDNFTLKICKDTDEVTQQAVLQ
->4w2f_CS mol:protein length:93  30S Ribosomal Protein S19
-MPRSLKKGVFVDDHLLEKVLELNAKGEKRLIKTWSRRSTIVPEMVGHTIAVYNGKQHVPVYITENMVGHKLGEFAPTRTYRGHGKEAKATKKK
->5s64_B mol:protein length:445  Tubulin beta-2B chain
-MREIVHIQAGQCGNQIGAKFWEVISDEHGIDPTGSYHGDSDLQLERINVYYNEATGNKYVPRAILVDLEPGTMDSVRSGPFGQIFRPDNFVFGQSGAGNNWAKGHYTEGAELVDSVLDVVRKESESCDCLQGFQLTHSLGGGTGSGMGTLLISKIREEYPDRIMNTFSVMPSPKVSDTVVEPYNATLSVHQLVENTDETYCIDNEALYDICFRTLKLTTPTYGDLNHLVSATMSGVTTCLRFPGQLNADLRKLAVNMVPFPRLHFFMPGFAPLTSRGSQQYRALTVPELTQQMFDSKNMMAACDPRHGRYLTVAAIFRGRMSMKEVDEQMLNVQNKNSSYFVEWIPNNVKTAVCDIPPRGLKMSATFIGNSTAIQELFKRISEQFTAMFRRKAFLHWYTGEGMDEMEFTEAESNMNDLVSEYQQYQDATADEQGEFEEEEGEDEA
->3tdp_B mol:protein length:257  formate/nitrite transporter
-RAHKETLDKLTNAAINKINLLNTSKVKYLVSSAFAGLYVGIGILLIFTIGGLLTDAGSPMTKIVMGLSFAIALSLVIMTGTELFTGNNMVMSAGMLNKGVSIKDTSKIWAYSWVGNLIGALVLGIIFVGTGLVDKGPVAEFFANTAASKASMPFTALFFRGILCNILVCVSVLCSFRTNSDTAKIIMIFLCLFAFITSGFEHSVANMTIYSVSLFSPTISTVTIGGAIYNLVAVTLGNIVGGALFMGLGTYILGKEK
->4jpj_B mol:protein length:181  Germline-targeting HIV-1 gp120 engineered outer domain, eOD-GT6
-DTITLPCRPAPPPHCSSNITGLILTRDGGVSNDETEIFRPSGGDMRDIARCQIAGTVVSTQLFLNGSLAEEEVVIRSVDFRDNAKSICVQLDTSVEIDCTGAGHCDISRAKWDNTLKQIASKLREQFGDRTIIFKQSSGGDPEFVTHSFNCGGEFFYCDSTQLFDSTWFDSTGTKHHHHHH
->5ohm_F mol:protein length:116  K33-specific affimer
-MSAATGVRAVPGNENSLEIEELARFAVDEHNKKENALLEFVRVVKAKEQIWEMDASKETMYYLTLEAKDGGKKKLYEAKVWVKMTHWIGAMNNFKELQEFKPVGDAAAAHHHHHHG
->7eqg_B mol:protein length:434  Type I-F CRISPR-associated protein Csy1
-MTSPLPTPTWQELRQFIESFIQERLQGKLDKLHPDEDDKRQTLLATHRREAWLADAARRVGQLQLVTHTLKPIHPDARGSNLHSLPQAPGQPGLAGSHELGDRLVSDVVGNAAALDVFKFLSLQYQGKNLLNWLTEDSAEAVQALSDNAEQAREWRQAFIGITAVKGAPASHSLAKQLYFPLPGSGYHLLAPLFPTSLVHHVHALLREARFGDAAKAAREARSRQESWPHGFSEYPNLAIQKFGGTKPQNISQLNSERYGENWLLPSLPPHWQRQDQRAPIRHSSVFEHDFGRSPEVSRLTRTLQRLLAKTRHNNFTIRRYRAQLVGQICDEALQYAARLRELEPGWSATPGCQLHDAEQLWLDPLRAQTDETFLQRRLRGDWPAEVGNRFANWLNRAVSSDSQILGSPEAAQWSQELSKELTMFKEILEDERD
->4a98_F mol:protein length:307  CYS-LOOP LIGAND-GATED ION CHANNEL
-PVDVSVSIFINKIYGVNTLEQTYKVDGYIVAQWTGKPRKTPGDKPLIVENTQIERWINNGLWVPALEFINVVGSPDTGNKRLMLFPDGRVIYNARFLGSFSNDMDFRLFPFDRQQFVLELEPFSYNNQQLRFSDIQVYTENIDNEEIDEWWIRGKASTHISDIRYDHLSSVQPNQNEFSRITVRIDAVRNPSYYLWSFILPLGLIIAASWSVFWLESFSERLQTSFTLMLTVVAYAFYTSNILPRLPYTTVIDQMIIAGYGSIFAAILLIIFAHHRQANGVEDDLLIQRCRLAFPLGFLAIGCVLVI
->6trc_z mol:protein length:36  Photosystem I 4.8K protein
-MATKSAKPTYAFRTFWAVLLLAINFLVAAYYFGILK
->3lte_O mol:protein length:132  Response regulator
-MSLKQSKRILVVDDDQAMAAAIERVLKRDHWQVEIAHNGFDAGIKLSTFEPAIMTLDLSMPKLDGLDVIRSLRQNKVANQPKILVVSGLDKAKLQQAVTEGADDYLEKPFDNDALLDRIHDLVNEGHHHHHH
->7jql_1D mol:protein length:276  50S ribosomal protein L2
-MAVKKFKPYTPSRRFMTVADFSEITKTEPEKSLVKPLKKTGGRNNQGRITVRFRGGGHKRLYRIIDFKRWDKVGIPAKVAAIEYDPNRSARIALLHYVDGEKRYIIAPDGLQVGQQVVAGPDAPIQVGNALPLRFIPVGTVVHAVELEPKKGAKLARAAGTSAQIQGREGDYVILRLPSGELRKVHGECYATVGAVGNADHKNIVLGKAGRSRWLGRRPHVRGAAMNPVDHPHGGGEGRAPRGRPPASPWGWQTKGLKTRKRRKPSSRFIIARRKK
->6wvt_O mol:protein length:236  Catenin alpha-1
-AIMAQLPQEQKAKIAEQVASFQEEKSKLDAEVSKWDDSGNDIIVLAKQMCMIMMEMTDFTRGKGPLKNTSDVISAAKKIAEAGSRMDKLGRTIADHCPDSACKQDLLAYLQRIALYCHQLNICSKVKAEVQNLGGELVVSGVDSAMSLIQAAKNLMNAVVQTVKASYVASTKYQKSQGMASLNLPAVSWKMKAPEKKPLVKREKQDETQTKIKRASQKKHVNPVQALSEFKAMDSI
->6oq5_F mol:protein length:142  7F
-SNSQVQLVESGGGLVEAGGSLRLSCVVTGSSFSTSTMAWYRQPPGKQREWVASFTSGGAIKYTDSVKGRFTMSRDNAKKMTYLQMENLKPEDTAVYYCALHNAVSGSSWGRGTQVTVSSEPKTPKPQTSGAPVPYPDPLEPR
->5ekc_C mol:protein length:491  Aldehyde dehydrogenase
-MIDLNIMKVANYINGEFKEPSTGAFQVKTSPVDGSKIAEVPRSGREDAREAIDSAFEALKAWANIPAIRRAEYLYKMLEVFRQMKEDFMKILTVEGGGTYRKVWGEVVFTERLIQNAAELARHYQGRVLQSDSESTISVVFKRSKGVVGVITPWNYPLSISMKKIAHTLAVGNTVVYKPASDTPVTGWLIAQMVAKAGLPKGVFNLVIGPGPVVGEEIVTHKRVAHVTFTGESSTGREIAAKAAGTLKTVTLELGGSDPLIILDDVDVDYAARLAVFASLFHQGQICTSAKRIIVHKAVADKFIERYVHYVKMLRIDDPRKDEKVDLGPLINERQVALMKEFVDDAVSRGGRLLIGGRSWGNFFEPAIFVDVDRNFRIMREEVFGPVRPIVVVENDDQAVEVANDTDYGLSGAVLTNNVNRAFRIAEAVESGMFHINDVTFLEESHVPFGGIKASGVGREGGEWSFHETTYDRWVTVTLRTRRFPIPSALK
->3fby_A mol:protein length:551  Cartilage oligomeric matrix protein
-RSPWPGVPTSPVWWNSAQRFCPDGSPSECHEHADCVLERDGSRSCVCAVGWAGNGILCGRDTDLDGFPDEKLRCPERQCRKDNCVTVPNSGQEDVDRDGIGDACDPDADGDGVPNEKDNCPLVRNPDQRNTDEDKWGDACDNCRSQKNDDQKDTDQDGRGDACDDDIDGDRIRNQADNCPRVPNSDQKDSDGDGIGDACDNCPQKSNPDQADVDHDFVGDACDSDQDQDGDGHQDSRDNCPTVPNSAQEDSDHDGQGDACDDDDDNDGVPDSRDNCRLVPNPGQEDADRDGVGDVCQDDFDADKVVDKIDVCPENAEVTLTDFRAFQTVVLDPEGDAQIDPNWVVLNQGREIVQTMNSDPGLAVGYTAFNGVDFEGTFHVNTVTDDDYAGFIFGYQDSSSFYVVMWKQMEQTYWQANPFRAVAEPGIQLKAVKSSTGPGEQLRNALWHTGDTESQVRLLWKDPRNVGWKDKKSYRWFLQHRPQVGYIRVRFYEGPELVADSNVVLDTTMRGGRLGVFCFSQENIIWANLRYRCNDTIPEDYETHQLRQAGT
->6h58_h mol:protein length:129  30S ribosomal protein S8
-SMQDPIADMLTRIRNGQAANKAAVTMPSSKLKVAIANVLKEEGFIEDFKVEGDTKPELELTLKYFQGKAVVESIQRVSRPGLRIYKRKDELPKVMAGLGIAVVSTSKGVMTDRAARQAGLGGEIICYVA
->4bts_DN mol:protein length:55  40S RIBOSOMAL PROTEIN RPS29E
-MPNKLWRTHPRNYGKDSKECRVCGARQGLITKYEMMTCRRCFREQAPHIGFVKYR
->6qq8_A mol:protein length:239  Green fluorescent protein
-MVSKGEELFTGVVPILVELDGDVNGHKFSVSGEGEGDATYGKLTLKFICTTGKLPVPWPTLVTTLTWGVQCFARYPDHMKQHDFFKSAMPEGYVQERTIFFKDDGNYKTRAEVKFEGDTLVNRIELKGIDFKEDGNILGHKLEYNAISDNVYITADKQKNGIKANFKIRHNIEDGSVQLADHYQQNTPIGDGPVLLPDNHYLSTQSALSKDPNEKRDHMVLLEFVTAAGITLGMDELYK
->1a93_B mol:protein length:34  MAX PROTEIN
-XCGGMRRKNDTHQQDIDDLKRQNALLEQQVRALX
->2fyq_A mol:protein length:194  Chymotrypsin-like cysteine proteinase
-MAHHHHHHDDDDKAPPTLWSRVTKFGSGWGFWVSPTVFITTTHVVPTGVKEFFGEPLSSIAIHQAGEFTQFRFSKKMRPDLTGMVLEEGCPEGTVCSVLIKRDSGELLPLAVRMGAIASMRIQGRLVHGQSGMLLTGANAKGMDLGTIPGDCGAPYVHKRGNDWVVCGVHAAATKSGNTVVCAVQAGEGETALE
->6q98_n mol:protein length:130  30S ribosomal protein S9
-MAENQYYGTGRRKSSAARVFIKPGNGKIVINQRSLEQYFGRETARMVVRQPLELVDMVEKLDLYITVKGGGISGQAGAIRHGITRALMEYDESLRSELRKAGFVTRDARQVERKKVGLRKARRRPQFSKR
->4ujd_Cc mol:protein length:69  40S RIBOSOMAL PROTEIN ES28
-MDTSRVQPIKLARVTKVLGRTGSQGQCTQVRVEFMDDTSRSIIRNVKGPVREGDVLTLLESEREARRLR
->4eef_G mol:protein length:74  F-HB80.4, DESIGNED HEMAGGLUTININ BINDING PROTEIN
-MDYKDDDDKGSHMASTRGSGRPWKFSENIAFEIALSFTNKDTPDRWKKVAQYVKGRTPEEVKKHYELEHHHHHH
->4quo_A mol:protein length:868  Aminopeptidase N
-KTVHYLKDYQTPAYHILKTDLHFDINEPQTVVKSRLTVEPQRVGEPLVLDGSAKLLSVKINGAAADYVLEGETLTIAGVPSERFTVEVETEILPAENKSLMGLYASGGNLFTQCEPEGFRKITFYIDRPDVMSKFTTTIVADKKRYPVLLSNGNKIDGGEFSDGRHWVKWEDPFSKPSYLFALVAGDLAVTEDYFTTMSGRNVKIEFYTTEADKPKVGFAVESLKNAMKWDETRFGLEYDLDIFMVVAVGDFNMGAMENKGLNIFNTKFVLADSRTATDTDFEGIESVVGHEYFHNWTGNRVTCRDWFQLSLKEGLTVFRDQEFSGDRASRAVRRIENIRLLRQHQFPEDAGPTAHPVRPASYEEMNNFYTMTVYEKGAEVVRMYHTLLGEEGFQKGMKLYFQRHDGQAVTCDDFRAAMADANGINLDQFALWYSQAGTPVLEAEGRLKNNIFELTVKQTVPPTPDMTDKQPMMIPVKVGLLNRNGEAVAFDYQGKRATEAVLLLTEAEQTFLLEGVTEAVVPSLLRGFSAPVHLNYPYSDDDLLLLLAHDSDAFTRWEAAQTLYRRAVAANLATLSDGVELPKHEKLLAAVEKVISDDLLDNAFKALLLGVPSEAELWDGAENIDPLRYHQAREALLDTLAVHFLPKWHELNRQAAKQENQSYEYSPEAAGWRTLRNVCRAFVLRADPAHIETVAEKYGEMAQNMTHEWGILSAVNGNESDTRNRLLAQFADKFSDDALVMDKYFALVGSSRRSDTLQQVRTALQHPKFSLENPNKARSLIGSFSRNVPHFHAEDGSGYRFIADKVIEIDRFNPQVAARLVQAFNLCNKLEPHRKNLVKQALQRIRAQEGLSKDVGEIVGKILDSNA
->6olg_BM mol:protein length:120  40S ribosomal protein S12
-VMDVNTALQEVLKTALIHDGLARGIREAAKALDKRQAHLCVLASNCDEPMYVKLVEALCAEHQINLIKVDDNKKLGEWVGLCKIDREGKPRKVVGCSCVVVKDYGKESQAKDVIEEYFKC
->6wgc_9 mol:protein length:513  Cell division control protein 6
-MSAIPITPTKRIRRNLFDDAPATPPRPLKRKKLQFTDVTPESSPEKLQFGSQSIFLRTKALLQKSSELVNLNSSDGALPARTAEYEQVMNFLAKAISEHRSDSLYITGPPGTGKTAQLDMIIRQKFQSLPLSLSTPRSKDVLRHTNPNLQNLSWFELPDGRLESVAVTSINCISLGEPSSIFQKIFDSFQDLNGPTLQIKNMQHLQKFLEPYHKKTTFVVVLDEMDRLLHANTSETQSVRTILELFLLAKLPTVSFVLIGMANSLDMKDRFLSRLNLDRGLLPQTIVFQPYTAEQMYEIVIQKMSSLPTIIFQPMAIKFAAKKCAGNTGDLRKLFDVLRGSIEIYELEKRFLLSPTRGSLNSAQVPLTPTTSPVKKSYPEPQGKIGLNYIAKVFSKFVNNNSTRTRIAKLNIQQKLILCTIIQSLKLNSDATIDESFDHYIKAITKTDTLAPLQRNEFLEICTILETCGLVSIKKTKCKGKTKRFVDKIDVDLDMREFYDEMTKISILKPFLH
->7nqh_BF mol:protein length:294  Mitochondrial ribosomal protein L4
-MLQLVRAGARTWFRPSGCRGLNTLAEEAVQQAEKPESVASLGLQPPVLRKCELPVPAHRRPVQAWIESLRGYEQERVGLTELHPDVFSTAPRLDILHQVAIWQKNFKRISYAKTKTRAEVRGGGRKPWVQKGSGRARHGSIRSPIWRGGGVAHGPRGPTSYYYMLPMKVRVQGLKVALTVKLAQDDLHIVDSLELPTADPQYLIELARYRRWGDSVLLVDLEHEDMPQNVVAATSGLKTFNLVPAVGLNVHSMLKHQTLVLTLPTVAFLEEKLLWHNSRYTPLYPFRLPYCDFP
->1xm9_A mol:protein length:457  plakophilin 1
-GLTIPKAVQYLSSQDEKYQAIGAYYIQHTCFQDESAKQQVYQLGGICKLVDLLRSPNQNVQQAAAGALRNLVFRSTTNKLETRRQNGIREAVSLLRRTGNAEIQKQLTGLLWNLSSTDELKEELIADALPVLADRVIIPFSGWCDGNSNMSREVVDPEVFFNATGCLRNLSSADAGRQTMRNYSGLIDSLMAYVQNCVAASRCDDKSVENCMCVLHNLSYRLDAEVPTRYRQLEYNARNAYTEKSSTGCFSNKSDKMMNNNYDCPLPEEETNPKGSGWLYHSDAIRTYLNLMGKSKKDATLEACAGALQNLTASKGLMSSGMSQLIGLKEKGLPQIARLLQSGNSDVVRSGASLLSNMSRHPLLHRVMGNQVFPEVTRLLTSHTGNTSNSEDILSSACYTVRNLMASQPQLAKQYFSSSMLNNIINLCRSSASPKAAEAARLLLSDMWSSKELQGVL
->6h06_D mol:protein length:219  HUMAN FAB ANTIBODY FRAGMENT OF HCBTAU-22.1
-DVVMTQSPLSLPVTPGEPASISCRSSQSLLHRSGHKYLHWYLQRPGQSPQVLIYLGSNRASGVPDRFSGSGSGTDFTLKISRVEAEDVGLYYCMQTLQTPWTFGQGTKVEIKRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNRGEC
->4xr3_A mol:protein length:316  DNA replication terminus site-binding protein
-MHHHHHHMARYDLVDRLNTTFRQMEQELAIFAAHLEQHKLLVARVFSLPEVKKEDEHNPLNRIEVKQHLGNDAQSLALRHFRHLFIQQQSENRSSKAAVRLPGVLCYQVDNLSQAALVSHIQHINKLKTTFEHIVTVESELPTAARFEWVHRHLPGLITLNAYRTLTVLHDPATLRFGWANKHIIKNLHRDEVLAQLEKSLKSPRSVAPWTREEWQRKLEREYQDIAALPQNAKLKIKRPVKVQPIARVWYKGDQKQVQHACPTPLIALINRDNGAGVPDVGELLNYDADNVQHRYKPQAQPLRLIIPRLHLYVAD
->4wqr_5I mol:protein length:61  30S ribosomal protein S14 type Z
-MARKALIEKAKRTPKFKVRAYTRCVRCGRARSVYRFFGLCRICLRELAHKGQLPGVRKASW
->5dkn_A mol:protein length:92  Protein S100-B
-MSELEKAVVALIDVFHQYSGREGDKHKLKKSELKELINNELSHFLEEIKEQEVVDKVMETLDSDGDGECDFQEFMAFVAMITTACHEFFEHE
->5z0z_B mol:protein length:465  Pilus assembly protein
-MGRDPNSTTTVDFTLHKIEQTSDEQIQNTGHDLGLTGRKPVQGAQFKIFNVTDAFYQLLENHDKTTAASMISQNLGQYVNLQDPNAATVTTDADGLAAFKGLAAKTNGRHSVYAFHEAVTPQPYQKAADMIVSLPVRQDDGSDLTNIHLYPKDSLVTKNLTEINEQAVATKDLHDVAVGDVLTYQVQFQIPHDIGALADHSQDTFKYNQFKVLAYMTKEGLTFKALTAITVDGQDILKALTGKMAFMSSNDAAWQQTHNYPFGFELDFLGGTDPDAVRNLLTQYAGKRVTVAYTGIVNEKMIPDQKVGNTAEVSFDPDSKITVNGPEIQTGGIRFFKHEAGSSKSLANATFILQRMNGNVREYAVLEGVNGMAGTYQPTKITWTTNQDAATRLKTSGAETANLTIQGLLPGRYTLVETAAPEGYEILDPTTDFEVIAGTWGTKTIRIANTPVNQLLPLEHHHHHH
->6bjc_D mol:protein length:445  Tubulin beta chain
-MREIVHIQAGQCGNQIGAKFWEVISDEHGIDPTGSYHGDSDLQLERINVYYNEAAGNKYVPRAILVDLEPGTMDSVRSGPFGQIFRPDNFVFGQSGAGNNWAKGHYTEGAELVDSVLDVVRKESESCDCLQGFQLTHSLGGGTGSGMGTLLISKIREEYPDRIMNTFSVVPSPKVSDTVVEPYNATLSVHQLVENTDETYCIDNEALYDICFRTLKLTTPTYGDLNHLVSATMSGVTTCLRFPGQLNADLRKLAVNMVPFPRLHFFMPGFAPLTSRGSQQYRALTVPELTQQMFDAKNMMAACDPRHGRYLTVAAVFRGRMSMKEVDEQMLNVQNKNSSYFVEWIPNNVKTAVCDIPPRGLKMSATFIGNSTAIQELFKRISEQFTAMFRRKAFLHWYTGEGMDEMEFTEAESNMNDLVSEYQQYQDATADEQGEFEEEGEEDEA
->2v6a_M mol:protein length:140  RIBULOSE BISPHOSPHATE CARBOXYLASE SMALL CHAIN 1
-MMVWTPVNNKMFETFSYLPPLTDEQIAAQVDYIVANGWIPCLEFAEADKAYVSNESAIRFGSVSCLYYDNRYWTMWKLPMFGCRDPMQVLREIVACTKAFPDAYVRLVAFDNQKQVQIMGFLVQRPKTARDFQPANKRSV
->3x37_A mol:protein length:123  ZYRO0C14696p
-MSSWRLVASVRTLPSSLRLELDGAQVNSYEEFVPNIISESRANKIGLRHLIHNPDKYCVLERYGNGFWIRYDVLQMDLQEVEDEFTGNEHLINWAAIKEWNLMGFKDLLPLWKEDLEHHHHHH
->6yfc_EW mol:protein length:124  coat protein
-MRLTDVDLTVGEETREYAVSEQQGTLFRFVDKSGTVANNTGVFSLEQRFGAANSNRKVTMLLTDPVVVKDASGADMTIKANASVTFSLPKTYPNEHITKLRQTLIAWLGQQCVSDPVDSGLNNY
->1vvj_QK mol:protein length:129  30S ribosomal protein S11
-MAKKPSKKKVKRQVASGRAYIHASYNNTIVTITDPDGNPITWSSGGVIGYKGSRKGTPYAAQLAALDAAKKAMAYGMQSVDVIVRGTGAGREQAIRALQASGLQVKSIVDDTPVPHNGCRPKKKFRKAS
->1w4r_A mol:protein length:195  THYMIDINE KINASE
-MRGSHHHHHHLVPRGSKTRGQIQVILGPMFSGKSTELMRRVRRFQIAQYKCLVIKYAKDTRYSSSFCTHDRNTMEALPACLLRDVAQEALGVAVIGIDEGQFFPDIVEFCEAMANAGKTVIVAALDGTFQRKPFGAILNLVPLAESVVKLTAVCMECFREAAYTKRLGTEKEVEVIGGADKYHSVCRLCYFKKAS
->5lmt_D mol:protein length:209  30S ribosomal protein S4
-MGRYIGPVCRLCRREGVKLYLKGERCYSPKCAMERRPYPPGQHGQKRARRPSDYAVRLREKQKLRRIYGISERQFRNLFEEASKKKGVTGSVFLGLLESRLDNVVYRLGFAVSRRQARQLVRHGHITVNGRRVDLPSYRVRPGDEIAVAEKSRNLELIRQNLEAMKGRKVGPWLSLDVEGMKGKFLRLPDREDLALPVNEQLVIEFYSR
->7e6c_A mol:protein length:419  Cysteine desulfurase SufS
-MGHMNITDIREQFPILHQQVNGHDLVYLDSAATSQKPRAVIETLDKYYNQYNSNVHRGVHTLGTRATDGYEGAREKVRKFINAKSMAEIIFTKGTTTSLNMVALSYARANLKPGDEVVITYMEHHANIIPWQQAVKATGATLKYIPLQEDGTISLEDVRETVTSNTKIVAVSHVSNVLGTVNPIKEMAKIAHDNGAVIVVDGAQSTPHMKIDVQDLDCDFFALSSHKMCGPTGVGVLYGKKALLENMEPAEFGGEMIDFVGLYESTWKELPWKFEAGTPIIAGAIGLGAAIDFLEEIGLDEISRHEHKLAAYALERFRQLDGVTVYGPEERAGLVTFNLDDVHPHDVATVLDAEGIAVRAGHHAAQPLMKWLDVTATARASFYLYNTEEEIDKLVEALQKTKEYFTNVFVDLEHHHHHH
->3pkj_F mol:protein length:355  NAD-dependent deacetylase sirtuin-6
-GSVNYAAGLSPYADKGKCGLPEIFDPPEELERKVWELARLVWQSSSVVFHTGAGISTASGIPDFRGPHGVWTMEERGLAPKFDTTFESARPTQTHMALVQLERVGLLRFLVSQNVDGLHVRSGFPRDKLAELHGNMFVEECAKCKTQYVRDTVVGTMGLKATGRLCTVAKARGLRACRGELRDTILDWEDSLPDRDLALADEASRNADLSITLGTSLQIRPSGNLPLATKRRGGRLVIVNLQPTKHDRHADLRIHGYVDEVMTRLMEHLGLEIPAWDGPRVLERALPPLPRPPTPKLEPKEESPTRINGSIPAGPKQEPCAQHNGSEPASPKRERPTSPAPHRPPKRVKAKAVPS
->7mkd_K mol:protein length:91  DNA-directed RNA polymerase subunit omega
-MARVTVQDAVEKIGNRFDLVLVAARRARQMQVGGKDPLVPEENDKTTVIALREIEEGLINNQILDVRERQEQQEQEAAELQAVTAIAEGRR
->1kz8_A mol:protein length:337  FRUCTOSE-1,6-BISPHOSPHATASE
-TDQAAFDTNIVTLTRFVMEQGRKARGTGEMTQLLNSLCTAVKAISTAVRKAGIAHLYGIAGSTNVTGDQVKKLDVLSNDLVINVLKSSFATCVLVTEEDKNAIIVEPEKRGKYVVCFDPLDGSSNIDCLVSIGTIFGIYRKNSTDEPSEKDALQPGRNLVAAGYALYGSATMLVLAMVNGVNCFMLDPAIGEFILVDRNVKIKKKGSIYSINEGYAKEFDPAITEYIQRKKFPPDNSAPYGARYVGSMVADVHRTLVYGGIFMYPANKKSPKGKLRLLYECNPMAYVMEKAGGLATTGKEAVLDIVPTDIHQRAPIILGSPEDVTELLEIYQKHAAK
->5puo_B mol:protein length:156  Bromodomain-containing protein 1
-MHHHHHHSSGVDLGTENLYFQSMEQVAMELRLTELTRLLRSVLDQLQDKDPARIFAQPVSLKEVPDYLDHIKHPMDFATMRKRLEAQGYKNLHEFEEDFDLIIDNCMKYNARDTVFYRAAVRLRDQGGVVLRQARREVDSIGLEEASGMHLPERPA
->6olf_F mol:protein length:294  60S ribosomal protein L5
-VKVVKNKAYFKRYQVKFRRRREGKTDYYARKRLVIQDKNKYNTPKYRMIVRVTNRDIICQIAYARIEGDMIVCAAYAHELPKYGVKVGLTNYAAAYCTGLLLARRLLNRFGMDKIYEGQVEVTGDEYNVESIDGQPGAFTCYLDAGLARTTTGNKVFGALKGAVDGGLSIPHSTKRFPGYDSESKEFNAEVHRKHIMGQNVADYMRYLMEEDEDAYKKQFSQYIKNSVTPDMMEEMYKKAHAAIRENPVYEKKPKKEVKKKRWNRPKMSLAQKKDRVAQKKASFLRAQERAAES
->6x6k_AT mol:protein length:278  Cag pathogenicity island protein
-MKLRASVLIGATILCLILSACSNYAKKVVKQKNHVYTPVYNELIEKYSEIPLNDKLKDTPFMVQVKLPNYKDYLLDNKQVVLTFKLVHHSKKITLIGDANKILQYKNYFQANGARSDIDFYLQPTLNQKGVVMIASNYNDNPNSKEKPQTFDVLQGSQPMLGANTKNLHGYDVSGANNKQVINEVAREKAQLEKINQYYKTLLQDKEQEYTTRKNNQREILETLSNRAGYQMRQNVISSEIFKNGNLNMQAKEEEVREKLQEERENEYLRNQIRSLLS
->3j78_82 mol:protein length:130  60S ribosomal protein L32
-MASLPHPKIVKKHTKKFKRHHSDRYHRVAENWRKQKGIDSVVRRRFRGNISQPKIGYGSNKKTKFLSPSGHKTFLVANVKDLETLTMHTKTYAAEIAHNISAKNRVVILARAKALGIKVTNPKGRLALEA
->3sbp_D mol:protein length:638  Nitrous-oxide reductase
-MSDKDSKNTPQVPEKLGLSRRGFLGASAVTGAAVAATALGGAVMTRESWAQAVKESKQKIHVGPGELDDYYGFWSGGHQGEVRVLGVPSMRELMRIPVFNVDSATGWGLTNESRHIMGDSAKFLNGDCHHPHISMTDGKYDGKYLFINDKANSRVARIRLDIMKCDKMITVPNVQAIHGLRLQKVPHTKYVFANAEFIIPHPNDGKVFDLQDENSYTMYNAIDAETMEMAFQVIVDGNLDNTDADYTGRFAAATCYNSEKAFDLGGMMRNERDWVVVFDIHAVEAAVKAGDFITLGDSKTPVLDGRKKDGKDSKFTRYVPVPKNPHGCNTSSDGKYFIAAGKLSPTCSMIAIDKLPDLFAGKLADPRDVIVGEPELGLGPLHTTFDGRGNAYTTLFIDSQVVKWNMEEAVRAYKGEKVNYIKQKLDVHYQPGHLHASLCETNEADGKWLVALSKFSKDRFLPVGPLHPENDQLIDISGDEMKLVHDGPTFAEPHDCIMARRDQIKTKKIWDRNDPFFAPTVEMAKKDGINLDTDNKVIRDGNKVRVYMTSMAPAFGVQEFTVKQGDEVTVTITNIDQIEDVSHGFVVVNHGVSMEISPQQTSSITFVADKPGLHWYYCSWFCHALHMEMVGRMMVEPA
->6yft_HF mol:protein length:113  coat protein
-STFSSLVIGSNTFIPTAPGYYSLSTRGFSDPRNQIKISGGKFNAKTGRVTAAVSRLWETDVTVAGLPVRSAAEVAIIMTLGRGITATNADVLLSDLNTLLDPARLDQILQGGF
->5w40_B mol:protein length:352  PopP2 protein
-SEFELGAPAGRQAGQQATVDRLRTQVTGFLSGALGKLQALSAQNMDPELAQFRVLDVDRAIMPLLIVAENARNPGLNLVPLHMDMAEDEEVRTQPPMAGSRHIAEFVASARPGRYRAVIDDGSHTRAADIRKDASGTSVIVVDPLRKEKDESAYVDYADNVNMEFGEHAKCAFIPVDIQKSSFDCRILSLSLALKMHDKDDAFAAFHETLRNGGDPSHHVSRAQQTEELGATLVLDGAPLVDARMMKHGQAASSVSRYLGNHPEQSTVPVNKRNETLGERTTRHLVKRKVRNRADSEGRVTSGETKEITFSNSVEQKRIALLNRAASYVNSAPPPVVMRMAKLLQDSLLDTN
->6lqt_B1 mol:protein length:923  Periodic tryptophan protein 2
-MKSDFKFSNLLGTVYRQGNITFSDDGKQLLSPVGNRVSVFDLINNKSFTFEYEHRKNIAAIDLNKQGTLLISIDEDGRAILVNFKARNVLHHFNFKEKCSAVKFSPDGRLFALASGRFLQIWKTPDVNKDRQFAPFVRHRVHAGHFQDITSLTWSQDSRFILTTSKDLSAKIWSVDSEEKNLAATTFNGHRDYVMGAFFSHDQEKIYTVSKDGAVFVWEFTKRPSDDDDNESEDDDKQEEVDISKYSWRITKKHFFYANQAKVKCVTFHPATRLLAVGFTSGEFRLYDLPDFTLIQQLSMGQNPVNTVSVNQTGEWLAFGSSKLGQLLVYEWQSESYILKQQGHFDSTNSLAYSPDGSRVVTASEDGKIKVWDITSGFCLATFEEHTSSVTAVQFAKRGQVMFSSSLDGTVRAWDLIRYRNFRTFTGTERIQFNCLAVDPSGEVVCAGSLDNFDIHVWSVQTGQLLDALSGHEGPVSCLSFSQENSVLASASWDKTIRIWSIFGRSQQVEPIEVYSDVLALSMRPDGKEVAVSTLKGQISIFNIEDAKQVGNIDCRKDIISGRFNQDRFTAKNSERSKFFTTIHYSFDGMAIVAGGNNNSICLYDVPNEVLLKRFIVSRNMALNGTLEFLNSKKMTEAGSLDLIDDAGENSDLEDRIDNSLPGSQRGGDLSTRKMRPEVRVTSVQFSPTANAFAAASTEGLLIYSTNDTILFDPFDLDVDVTPHSTVEALREKQFLNALVMAFRLNEEYLINKVYEAIPIKEIPLVASNIPAIYLPRILKFIGDFAIESQHIEFNLIWIKALLSASGGYINEHKYLFSTAMRSIQRFIVRVAKEVVNTTTDNKYTYRFLVSTDGSMEDGAADDDEVLLKDDADEDNEENEENDVVMESDDEEGWIGFNGKDNKLPLSNENDSSDEEENEKELP
->3fi0_N mol:protein length:326  Tryptophanyl-tRNA synthetase
-MKTIFSGIQPSGVITIGNYIGALRQFVELQHEYNCYFCIVDQHAITVWQDPHELRQNIRRLAALYLAVGIDPTQATLFIQSEVPAHAQAAWMLQCIVYIGELERMTQFKEKSAGKEAVSAGLLTYPPLMAADILLYNTDIVPVGEDQKQHIELTRDLAERFNKRYGELFTIPEARIPKVGARIMSLVDPTKKMSKSDPNPKAYITLLDDAKTIEKKIKSAVTDSEGTIRYDKEAKPGISNLLNIYSTLSGQSIEELERQYEGKGYGVFKADLAQVVIETLRPIQERYHHWMESEELDRVLDEGAEKANRVASEMVRKMEQAMGLGR
->6y67_MMM mol:protein length:293  Capsid protein VP1
-MGSSHHHHHHSSGENLYFQGSHMGGIEVLDVKTGPDSTTTIEAYLNPRVGQNWGFSTEITVASNGYNDAPHLTEIPCYSSARISLPLLNEDITSPTLLMWEAVSVKTEVVGISSMLNMHSYGLRAFGGYGGGYTIEGSHIHFFSVGGEPLDLQGLMQNHSTQYPSPLVGPKKPDGTTDDSAQVLNPIYKAKLDKDATYPIECWCPDPSRNENSRYFGSYTGGVETPPVLSFTNTSTTILLDENGVGPLCKGDGLYLSSADVAGTFVQQTSQKQYWRGLPRYFNITLRKRAVKN
->1dzr_A mol:protein length:183  DTDP-4-DEHYDRORHAMNOSE 3,5-EPIMERASE
-MMIVIKTAIPDVLILEPKVFGDERGFFFESYNQQTFEELIGRKVTFVQDNHSKSKKNVLRGLHFQRGENAQGKLVRCAVGEVFDVAVDIRKESPTFGQWVGVNLSAENKRQLWIPEGFAHGFVTLSEYAEFLYKATNYYSPSSEGSILWNDEAIGIEWPFSQLPELSAKDAAAPLLDQALLTE
->6gmt_A mol:protein length:108  Magnetosome protein MamM
-GSHMEAVQNRIVEAAERVPGVRGVIHLRARYVGQDIWADMIIGVDPENTVEQAHEICEAVQAAVCGKIRRIESLHVSAEAREIGDTTKPSFSDQPLSFDEVMLSKVDN
->5a1w_F mol:protein length:177  COATOMER SUBUNIT ZETA-1
-MEALILEPSLYTVKAILILDNDGDRLFAKYYDDTYPSVKEQKAFEKNIFNKTHRTDSEIALLEGLTVVYKSSIDLYFYVIGSSYENELMLMAVLNCLFDSLSQMLRKNVEKRALLENMEGLFLAVDEIVDGGVILESDPQQVVHRVALRGEDVPLTEQTVSQVLQSAKEQIKWSLLR
->5e81_3E mol:protein length:209  30S ribosomal protein S4
-MGRYIGPVCRLCRREGVKLYLKGERCYSPKCAMERRPYPPGQHGQKRARRPSDYAVRLREKQKLRRIYGISERQFRNLFEEASKKKGVTGSVFLGLLESRLDNVVYRLGFAVSRRQARQLVRHGHITVNGRRVDLPSYRVRPGDEIAVAEKSRNLELIRQNLEAMKGRKVGPWLSLDVEGMKGKFLRLPDREDLALPVNEQLVIEFYSR
->6y5e_F mol:protein length:83  Histone H4
-KVLRDNIQGITKPAIRRLARRGGVKRISGLIYEETRGVLKVFLENVIRDAVTYTEHAKRKTVTAMDVVYALKRQGRTLYGFGG
->5pgy_A mol:protein length:286  Corticosteroid 11-beta-dehydrogenase isozyme 1
-GSHMASMTGGQQMGRGSNEEFRPEMLQGKKVIVTGASKGIGREMAYHLAKMGAHVVVTARSKETLQKVVSHCLELGAASAHYIAGTMEDMTFAEQFVAQAGKLMGGLDMLILNHITNTSLNLFHDDIHHVRKSMEVNFLSYVVLTVAALPMLKQSNGSIVVVSSLAGKVAYPMVAAYSASKFALDGFFSSIRKEYSVSRVNVSITLCVLGLIDTETAMKAVSGIVHMQAAPKEECALEIIKGGALRQEEVYYDSSRWTTLLIRNPCRKILEELYSTSYNMDRFINK
->7r4n_A mol:protein length:362  Hydroxyacid oxidase 1
-MLPRLICINDYEQHAKSVLPKSIYDYYRSGANDEETLADNIAAFSRWKLYPRMLRNVAETDLSTSVLGQRVSMPICVGATAMQRMAHVDGELATVRACQSLGTGMMLSSWATSSIEEVAEAGPEALRWLQLYIYKDREVTKKLVRQAEKMGYKAIFVTVDTPYLGNRLDDVRNRFKLPPQLRMKNFETSTLSFSPEENFGDDSGLAAYVAKAIDPSISWEDIKWLRRLTSLPIVAKGILRGDDAREAVKHGLNGILVSNHGARQLDGVPATIDVLPEIVEAVEGKVEVFLDGGVRKGTDVLKALALGAKAVFVGRPIVWGLAFQGEKGVQDVLEILKEEFRLAMALSGCQNVKVIDKTLVRK
->6dec_R mol:protein length:9  unidentified
-XXXXXXXXX
->6j9f_C mol:protein length:1383  DNA-directed RNA polymerase subunit beta
-MTSYSFTEKKRIRKDFGKQRSILEVPFLLAIQVDSYREFLQEDVESTKRKDLGLHAALKSVFPISSYSGNAALEYVGYKLGQPVFDERECRQRGMSYGAPLRVTVRLVIYDRESSTKAIKYVKEQEVYLGEIPLMTGNGTFIVNGTERVIVSQLHRSPGVFFDHDRGKTHSSGKLLYSARIIPYRGSWLDFEFDPKDALFTRIDRRRKLPVSILLRALGYNNEEMLAEFFEINTFHINPDEGVQLELVPERLRGETLNFDLADGDKVIVEAGKRITARHVKQLEAAGVAALAVPDDYLVGRILSHDVVDGSTGELLANANDEISEDQLTAFRKAGVDAVGTLWVNDLDRGPYLSNTLRIDPTKTQLEALVEIYRMMRPGEPPTKEAAQNLFHNLFFTFERYDLSTVGRMKFNRRVGRKDVLGESVLYDKKYFAERNDEESKRLVAEHTDTSDILEVIKVLTEIRNGRGVVDDIDHLGNRRVRSVGEMAENVFRVGLVRVERAVKERLSMAESEGLTPQELINAKPVAAAIKEFFGSSQLSQFMDQNNPLSEVTHKRRVSALGPGGLTRERAGFEVRDVHPTHYGRVCTIETPEGPNIGLINSLAVFARTNQYGFLETPYRKVLDGKVSDDVEYLSAIEENEYVIAQANALTDAKNMLTEQFVPCRFQGESLLKPPSEVHFMDVSPMQTVSVAAALVPFLEHDDANRALMGANMQRQAVPTLRSQKPLVGTGIERAVARDSGVTVNALRGGVIEQIDAARIVVKVNEAEIGGGTDAGVDIYNLIKYTRSNQNTCINQRPLVNVGDVIARGDVLADGPSTDIGELALGQNMLIAFMPWNGYNFEDSILLSERVVEEDRYTTIHIEELTCVARDTKLGPEEISADIPNVSEQALNRLDESGVVYIGAEVRAGDIMVGKVTPKGESQLTPEEKLLRAIFGEKASDVKDSSLRVPPGMDGTVIDVQVFTRDGIEKDKRARQIEENEIKRVKKDFDDQFRILEAAIYARLRSQIVGKVANGGANLKKGDSVTDAYLDGLKKSDWFQLRMKDEDAADAIERAQKQIQAHEKEFEARFADKRGKITQGDDLAPGVLKMVKVFLAVKRRIQPGDKMAGRHGNKGVVSNVVPVEDMPYMATGESVDIVLNPLGVPSRMNIGQILEVHLGWAAKGLGRKIQRMLEAQAAVSELRKFLDDIYNHDNAINAQRVDLSQFSDEELLNLGKNLIDGVPMATPVFDGASEAEIKRMLELADLPQSGQTQLYDGRTGEAFDRKTTVGYMHYLKLNHLVDDKMHARSTGPYSLVTQQPLGGKAQFGGQRFGEMEVWALEAYGAAYTLQEMLTVKSDDVQGRNQMYKNIVDGEHEMVAGMPESFNVLVKEIRSLAIHMELEE
->2e7s_E mol:protein length:135  Rab guanine nucleotide exchange factor SEC2
-GPLGSLEEQLNKSLKTIASQKAAIENYNQLKEDYNTLKRELSDRDDEVKRLREDIAKENELRTKAEEEADKLNKEVEDLTASLFDEANNLVADARMEKYAIEILNKRLTEQLREKDMLLDTLTLQLKNLKKVMHS
->2wfz_A mol:protein length:537  ACETYLCHOLINESTERASE
-DDHSELLVNTKSGKVMGTRVPVLSSHISAFLGIPFAEPPVGNMRFRRPEPKKPWSGVWNASTYPNNCQQYVDEQFPGFSGSEMWNPNREMSEDCLYLNIWVPSPRPKSTTVMVWIYGGGFYSGSSTLDVYNGKYLAYTEEVVLVSLSYRVGAFGFLALHGSQEAPGNVGLLDQRMALQWVHDNIQFFGGDPKTVTIFGESAGGASVGMHILSPGSRDLFRRAILQSGSPNCPWASVSVAEGRRRAVELGRNLNCNLNSDEELIHCLREKKPQELIDVEWNVLPFDSIFRFSFVPVIDGEFFPTSLESMLNSGNFKKTQILLGVNKDEGSFFLLYGAPGFSKDSESKISREDFMSGVKLSVPHANDLGLDAVTLQYTDWMDDNNGIKNRDGLDDIVGDHNVICPLMHFVNKYTKFGNGTYLYFFNHRASNLVWPEWMGVIHGYEIEFVFGLPLVKELNYTAEEEALSRRIMHYWATFAKTGNPNEPHSQESKWPLFTTKEQKFIDLNTEPMKVHQRLRVQMCVFWNQFLPKLLNATAC
->5cnv_D mol:protein length:761  Ribonucleoside-diphosphate reductase 1 subunit alpha
-MNQNLLVTKRDGSTERINLDKIHRVLDWAAEGLHNVSISQVELRSHIQFYDGIKTSDIHETIIKAAADLISRDAPDYQYLAARLAIFHLRKKAYGQFEPPALYDHVVKMVEMGKYDNHLLEDYTEEEFKQMDTFIDHDRDMTFSYAAVKQLEGKYLVQNRVTGEIYESAQFLYILVAACLFSNYPRETRLQYVKRFYDAVSTFKISLPTPIMSGVRTPTRQFSSCVLIECGDSLDSINATSSAIVKYVSQRAGIGINAGRIRALGSPIRGGEAFHTGCIPFYKHFQTAVKSCSQGGVRGGAATLFYPMWHLEVESLLVLKNNRGVEGNRVRHMDYGVQINKLMYTRLLKGEDITLFSPSDVPGLYDAFFADQEEFERLYTKYEKDDSIRKQRVKAVELFSLMMQERASTGRIYIQNVDHCNTHSPFDPAIAPVRQSNLCLEIALPTKPLNDVNDENGEIALCTLSAFNLGAINNLDELEELAILAVRALDALLDYQDYPIPAAKRGAMGRRTLGIGVINFAYYLAKHGKRYSDGSANNLTHKTFEAIQYYLLKASNELAKEQGACPWFNETTYAKGILPIDTYKKDLDTIANEPLHYDWEALRESIKTHGLRNSTLSALMPSETSSQISNATNGIEPPRGYVSIKASKDGILRQVVPDYEHLHDAYELLWEMPGNDGYLQLVGIMQKFIDQSISANTNYDPSRFPSGKVPMQQLLKDLLTAYKFGVKTLYYQNTRDGAEDAQDDLVPSIQDDGCESGACKI
->6fzd_A mol:protein length:392  Lipase
-SRANDAPIVLLHGFTGWGREEMFGFKYWGGVRGDIEQWLNDNGYRTYTLAVGPLSSNWDRACEAYAQLVGGTVDYGAAHAAKHGHARFGRTYPGLLPELKRGGRIHIIAHSQGGQTARMLVSLLENGSQEEREYAKAHNVSLSPLFEGGHHFVLSVTTIATPHDGTTLVNMVDFTDRFFDFQKFVLKAAAVASNVPYTSQVYDFKLDQWGLRRQPGESFDQYFERLKRSPVWTSTDTARYDLSVPGAEKLNQWVKASPNTYYLSFATERTYRGALTGNYYPELGMNAFSAVVCAPFLGSYRNATLGIDDRWLENDGIVNAFSMNGPKRGSTDRIVPYDGTIKKGVWNDMGTYNVDHFEVIGVDPNPLFDIRAFYLRLAEQLASLQPHHHHHH
->6stf_C mol:protein length:178  Ras-related protein Rab-8A
-MDYLFKLLLIGDSGVGKTCVLFRFSEDAFNSTFISTIGIDFKIRTIELDGKRIKLQIWDTAGQERFRTITTAYYRGAMGIMLVYDITNEKSFDNIRNWIRNIEEHASADVEKMILGNKCDVNDKRQVSKERGEKLALDYGIKFMETSAKANINVENAFFTLARDIKAKMDKKHHHHHH
->7pny_K mol:protein length:128  28S ribosomal protein S14, mitochondrial
-MAAFMLGSLLRTFKQMVPSSASGQVRSHYVDWRMWRDVKRRKMAYEYADERLRINSLRKNTILPKILQDVADEEIAALPRDSCPVRIRNRCVMTSRPRGVKRRWRLSRIVFRHLADHGQLSGIQRATW
->8d5p_C mol:protein length:209  TCR-alpha
-MDSVTQTEGQVALSEEDFLTIHCNYSASGYPALFWYVQYPGEGPQFLFRASRDKEKGSSRGFEATYNKETTSFHLQKASVQESDSAVYYCALGDPTGANTGKLTFGHGTILRVHPNIQNPDPAVYQLRDSKSSDKSVCLFTDFDSQTNVSQSKDSDVYITDKCVLDMRSMDFKSNSAVAWSNKSDFACANAFNNSIIPEDTFFPSPESS
->6o22_D mol:protein length:279  Histone chaperone ASF1
-SSIVSLLGIKVLNNPAKFTDPYEFEITFECLESLKHDLEWKLTYVGSSRSLDHDQELDSILVGPVPVGVNKFVFSADPPSAELIPASELVSVTVILLSCSYDGREFVRVGYYVNNEYDEEELRENPPAKVQVDHIVRNILAEKPRVTRFNIVWDNENEGDLYPPEQPGVDDEEEEDDEEEDDDEDDEDDEDDDQEDGEGEAEEAAEEEEEEEEKTEDNETNLEEEEEDIENSDGDEEEGEEEVGSVDKNEDGNDKKRRKIEGGSTDIESTPKDAARSTN
->6gqb_AA mol:protein length:105  40S ribosomal protein S10-A
-MLMPKEDRNKIHQYLFQEGVVVAKKDFNQAKHEEIDTKNLYVIKALQSLTSKGYVKTQFSWQYYYYTLTEEGVEYLREYLNLPEHIVPGTYIQERNPTQRPQRRY
->1z9x_C mol:protein length:321  Death-associated protein kinase 2
-GMEPFKQQKVEDFYDIGEELGSGQFAIVKKCREKSTGLEYAAKFIKKRQSRASRRGVSREEIEREVSILRQVLHHNVITLHDVYENRTDVVLILELVSGGELFDFLAQKESLSEEEATSFIKQILDGVNYLHTKKIAHFDLKPENIMLLDKNIPIPHIKLIDFGLAHEIEDGVEFKNIFGTPEFVAPEIVNYEPLGLEADMWSIGVITYILLSGASPFLGDTKQETLANITSVSYDFDEEFFSHTSELAKDFIRKLLVKETRKRLTIQEALRHPWITPVDNQQAMVRRESVVNLENFRKQYVRRRSKLAFSIVSLCNHLTR
->6qbx_S3 mol:protein length:228  NADH:ubiquinone oxidoreductase core subunit S3
-ESASADTRPTVRPRNDVAHKQLSAFGEYVAEILPKYVQQVQVSCFSELEICIHPDGVIPVLTFLRDHSNAQFKSLADLTAVDIPTRQNRFEIVYNLLSLRFNSRIRVKTYTDELTPVESSVSVYKAANWYEREIWDMFGVFFANHPDLRRILTDYGFEGHPFRKDFPLSGYVELRYDDEVKRVVAEPVELAQEFRKFDLNSPWEAFPAYRQPPESLKLEAGDKKPEAK
->3h0r_Q mol:protein length:478  Aspartyl/glutamyl-tRNA(Asn/Gln) amidotransferase subunit B
-MNEKYEAVIGLEIHVQMDTKTKMFCGCKVEFGAEPNTNVCPVCLGMPGALPIVNKRAVEYAIRASLALNCEVHEESVFARKHYFYPDLPKGYQISQYEKPLATNGWVELNLPNGEKKKVRIRRLHIEEDAGKNIHEGDKTLVDLNRAGTPLMEIVTEPDIRTPEEARLFLEKLRNIMRYAGVSKADMEKGQLRCDINVSIRPKGSKEFGTRVEIKNVNSFRFVQKALEYEIERQINVVEEGGEVVQETRTFDPQTGKTYPMRTKEEAEDYRYFPDPDLVPLKVKKEWIEEIKKNMPELPDQRFERLIKEYGLSEYEAGILVNHKEVGDFFEEAVRHFKEPKGIVNWLINDLLGLLRDKGISIEESPVKPEHLAELVKLIKEKVISTKIGKEVIKEMVETGKTPSQIVEEKGLKQITDENQIKELVKKIFEKHPKEVERLKQGEEKLIGFFVGQVMRETRGKANPQVVNKVIRELVKEV
->4v99_Al mol:protein length:242  Capsid protein
-MNRNGATPTRGRGKRAIPNPPRRRARGKSVERGSTPLQYVTTLGPSRPRMGQGQGWQKLSHEEIILQVNSSTAADTIQTIPIIPRLSVPAGDKPIYSGSAPHLRTIGSAFAIHRWRALSFEWIPSCPTTTPGNLVLRFYPNYSTETPKTLTDLMDSESLVLVPSLSGKTYRPKIETRGNPPELRNIDATAFSALSDEDKGDYSVGRLVVGSSKQAVVIQLGLLRMRYSAEMRGATSISGVSA
->6zsa_XS mol:protein length:205  39S ribosomal protein L21, mitochondrial
-MAASSLTVTLGRLASACSHSILRPSGPGAASLWSASRRFNSQSTSYLPGYVPKTSLSSPPWPEVVLPDPVEETRHHAEVVKKVNEMIVTGQYGRLFAVVHFASRQWKVTSEDLILIGNELDLACGERIRLEKVLLVGADNFTLLGKPLLGKDLVRVEATVIEKTESWPRIIMRFRKRKNFKKKRIVTTPQTVLRINSIEIAPCLL
->7pe9_I mol:protein length:409  DEP domain-containing mTOR-interacting protein
-MEEGGSTGSAGSDSSTSGSGGAQQRELERMAEVLVTGEQLRLRLHEEKVIKDRRHHLKTYPNCFVAKELIDWLIEHKEASDRETAIKLMQKLADRGIIHHVCDEHKEFKDVKLFYRFRKDDGTFPLDNEVKAFMRGQRLYEKLMSPENTLLQPREEEGVKYERTFMASEFLDWLVQEGEATTRKEAEQLCHRLMEHGIIQHVSSKHPFVDSNLLYQFRMNFRRRRRLMELLNEKSPSSQETHDSPFCLRKQSHDNRKSTSFMSVSPSKEIKIVSAVRRSSMSSCGSSGYFSSSPTLSSSPPVLCNPKSVLKRPVTSEELLTPGAPYARKTFTIVGDAVGWGFVVRGSKPCHIQAVDPSGPAAAAGMKVCQFVVSVNGLNVLHVDYRTVNNLILTGPRTIVMEVMEELEC
->5v3t_A mol:protein length:132  Globin
-MSKQPMTPFEAIGGEQCIEILVDTFYSYVSKHPDLSPIFPDDLTETARKQKQFLTQYLGGPNLYTEEHGHPMLRARHLPFEITPKRAEAWLSCMEQAMDDTGVHGHIREFVFERLALTAQHMVNTPNETGEI
->4wra_E5 mol:protein length:85  50S ribosomal protein L27
-MAHKKGLGSTRNGRDSQAKRLGVKRYEGQVVRAGNILVRQRGTRFKPGKNVGMGRDFTLFALVDGVVEFQDRGRLGRYVHVRPLA
->4waj_A mol:protein length:229  Carbonic anhydrase 2
-MDKIKQLFANNYSWAQRMKEENSTYFKELADHQTPHYLWIGCSDSRVSPEKLTNLEPGELFVHRNVANQVIHTDFNCLSVVQYAVDVLKIEHIIICGHTNCGGIHAAMADKDLGLINNWLLHIRDIWFKHGHLLGKLSPEKRADMLTKINVAEQVYNLGRTSIVKSAWERGQKLSLHGWVYDVNDGFLVDQGVMATSRETLEISYRNAIARLSILDEENILKKDHLENT
->2c97_A mol:protein length:160  6,7-DIMETHYL-8-RIBITYLLUMAZINE SYNTHASE
-MKGGAGVPDLPSLDASGVRLAIVASSWHGKICDALLDGARKVAAGCGLDDPTVVRVLGAIEIPVVAQELARNHDAVVALGVVIRGQTPHFDYVCDAVTQGLTRVSLDSSTPIANGVLTTNTEEQALDRAGLPTSAEDKGAQATVAALATALTLRELRAHS
->5j4b_2e mol:protein length:162  30S ribosomal protein S5
-MPETDFEEKMILIRRTARMQAGGRRFRFGALVVVGDRQGRVGLGFGKAPEVPLAVQKAGYYARRNMVEVPLQNGTIPHEIEVEFGASKIVLKPAAPGTGVIAGAVPRAILELAGVTDILTKELGSRNPINIAYATMEALRQLRTKADVERLRKGEAHAQAQG
->7n6p_A mol:protein length:227  1C3 Fab heavy chain
-QVQLVQSGAEVKKPGSSVKVACKVSGGTFSSYTISWVRQAPGQGLEWMGGIIPSFGVGHYSQKFRDRVTLTADKSTTTAFLELSSVRSEDTALYYCAILGTFNWKSGGNYFGPWGQGTLVTVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEPKSC
->2vt5_B mol:protein length:338  FRUCTOSE-1,6-BISPHOSPHATASE 1
-MADQAPFDTDVNTLTRFVMEEGRKARGTGELTQLLNSLCTAVKAISSAVRKAGIAHLYGIAGSTNVTGDQVKKLDVLSNDLVMNMLKSSFATCVLVSEEDKHAIIVEPEKRGKYVVCFDPLDGSSNIDCLVSVGTIFGIYRKKSTDEPSEKDALQPGRNLVAAGYALYGSATMLVLAMDCGVNCFMLDPAIGEFILVDKDVKIKKKGKIYSLNEGYAKDFDPAVTEYIQRKKFPPDNSAPYGARYVGSMVADVHRTLVYGGIFLYPANKKSPNGKLRLLYECNPMAYVMEKAGGMATTGKEAVLDVIPTDIHQRAPVILGSPDDVLEFLKVYEKHSAQ
->6dhf_c mol:protein length:451  Photosystem II CP43 reaction center protein
-ATNRDQESSGFAWWAGNARLINLSGKLLGAHVAHAGLIVFWAGAMTLFELAHFIPEKPMYEQGLILIPHIATLGWGVGPGGEVVDTFPFFVVGVVHLISSAVLGFGGVYHAIRGPETLEEYSSFFGYDWKDKNKMTTILGFHLIVLGIGALLLVAKAMFFGGLYDTWAPGGGDVRVITNPTLDPRVIFGYLLKSPFGGEGWIVSVNNLEDVVGGHIWIGLICIAGGIWHILTTPFGWARRAFIWSGEAYLSYSLGALSMMGFIATCFVWFNNTVYPSEFYGPTGPEASQAQAMTFLIRDQKLGANVGSAQGPTGLGKYLMRSPTGEIIFGGETMRFWDFRGPWLEPLRGPNGLDLNKIKNDIQPWQERRAAEYMTHAPLGSLNSVGGVATEINSVNFVSPRSWLATSHFVLAFFFLVGHLWHAGRARAAAAGFEKGIDRESEPVLSMPSLD
->5hg0_A mol:protein length:264  Pantothenate synthetase
-SNAMIIADNIKQFHSIRNSLIKQQKIGFVPTMGALHNGHISLIKKAKSENDVVIVSIFVNPTQFNNPNDYQTYPNQLQQDIQILASLDVDVLFNPSEKDIYPDGNLLRIEPKLEIANILEGKSRPGHFSGMLTVVLKLLQITKPNNLYLGEKDYQQVMLIKQLVKDFFINTKIIVCPTQRQPSGLPLSSRNKNLTSTDIEIANKIYEILRQDDFSNLEELTNKINSTGAKLQYIQKLNNRIFLAFYIGKVRLIDNFLKETGPSC
->2h6s_A mol:protein length:340  Candidapepsin-3
-QTVPVKLINEQVSYASDITVGSNKQKLTVVIDTGSSDLWVPDSQVSCQAGQGQDPNFCKNEGTYSPSSSSSSQNLNSPFSIEYGDGTTSQGTWYKDTIGFGGISITKQQFADVTSTSVDQGILGIGYKTHEAEGNYDNVPVTLKNQGIISKNAYSLYLNSRQATSGQIIFGGVDNAKYSGTLIALPVTSDNELRIHLNTVKVAGQSINADVDVLLDSGTTITYLQQGVADQVISAFNGQETYDANGNLFYLVDCNLSGSVDFAFDKNAKISVPASEFTAPLYTEDGQVYDQCQLLFGTSDYNILGDNFLRSAYIVYDLDDNEISLAQVKYTTASNIAALT
->6atb_B mol:protein length:501  Nicotinamide phosphoribosyltransferase
-MNPAAEAEFNILLATDSYKVTHYKQYPPNTSKVYSYFECREKKTENSKLRKVKYEETVFYGLQYILNKYLKGKVVTKEKIQEAKDVYKEHFQDDVFNEKGWNYILEKYDGHLPIEIKAVPEGFVIPRGNVLFTVENTDPECYWLTNWIETILVQSWYPITVATNSREQKKILAKYLLETSGNLDGLEYKLHDFGYRGVSSQETAGIGASAHLVNFKGTDTVAGLALIKKYYGTKDPVPGYSVPAAEHSTITAWGKDHEKDAFEHIVTQFSSVPVSVVSDSYDIYNACEKIWGEDLRHLIVSRSTQAPLIIRPDSGNPLDTVLKVLEILGKKFPVTENSKGYKLLPPYLRVIQGDGVDINTLQEIVEGMKQKMWSIENIAFGSGGGLLQKLTRDLLNCSFKCSYVVTNGLGINVFKDPVADPNKRSKKGRLSLHRTPAGNFVTLEEGKGDLEEYGQDLLHTVFKNGKVTKSYSFDEIRKNAQLNIELEAAHHLEHHHHHHHH
->1oqj_B mol:protein length:97  Glucocorticoid Modulatory Element Binding protein-1
-GAMEDMEIAYPITCGESKAILLWKKFVCPGINVKCVKFNDQLISPKHFVHLAGKSTLKDWKRAIRLGGIMLRKMMDSGQIDFYQHDKVCSNTCRSTK
->5m7g_A mol:protein length:451  Tubulin alpha-1B chain
-MRECISIHVGQAGVQIGNACWELYCLEHGIQPDGQMPSDKTIGGGDDSFNTFFSETGAGKHVPRAVFVDLEPTVIDEVRTGTYRQLFHPEQLITGKEDAANNYARGHYTIGKEIIDLVLDRIRKLADQCTGLQGFLVFHSFGGGTGSGFTSLLMERLSVDYGKKSKLEFSIYPAPQVSTAVVEPYNSILTTHTTLEHSDCAFMVDNEAIYDICRRNLDIERPTYTNLNRLISQIVSSITASLRFDGALNVDLTEFQTNLVPYPRIHFPLATYAPVISAEKAYHEQLSVAEITNACFEPANQMVKCDPRHGKYMACCLLYRGDVVPKDVNAAIATIKTKRSIQFVDWCPTGFKVGINYQPPTVVPGGDLAKVQRAVCMLSNTTAIAEAWARLDHKFDLMYAKRAFVHWYVGEGMEEGEFSEAREDMAALEKDYEEVGVDSVEGEGEEEGEEY
->6z6j_LW mol:protein length:155  60S ribosomal protein L24-A
-MKVEIDSFSGAKIYPGRGTLFVRGDSKIFRFQNSKSASLFKQRKNPRRIAWTVLFRKHHKKGITEEVAKKRSRKTVKAQRPITGASLDLIKERRSLKPEVRKANREEKLKANKEKKKAEKAARKAEKAKSAGTQSSKFSKQQAKGAFQKVAATSR
->6mte_F mol:protein length:225  uL30
-NFAELKIKRLRKKFAQKMLRKARRKLIYEKAKHYHKEYRQMYRTEIRMARMARKAGNFYVPAEPKLAFVIRIRGINGVSPKVRKVLQLLRLRQIFNGTFVKLNKASINMLRIVEPYIAWGYPNLKSVNELIYKRGYGKINKKRIALTDNTLIARSLGKYNIICMEDLIHEIYTVGKHFKEANNFLWPFKLSSPRGGMKKKTTHFVEGGDAGNREDQINRLIRRMN
->4v93_BD mol:protein length:151  EXTRACELLULAR GLOBIN-4
-ADDEDCCSYEDRREIRHIWDDVWSSSFTDRRVAIVRAVFDDLFKHYPTSKALFERVKIDEPESGEFKSHLVRVANGLKLLINLLDDTLVLQSHLGHLADQHIQRKGVTKEYFRGIGEAFARVLPQVLSCFNVDAWNRCFHRLVARIAKDLP
->7nk4_B mol:protein length:757  RNA-directed RNA polymerase catalytic subunit
-MDVNPTLLFLKVPAQNAISTTFPYTGDPPYSHGTGTGYTMDTVNRTHQYSEKGRWTTNTETGAPQLNPIDGPLPEDNEPSGYAQTDCVLEAMAFLEESHPGIFENSCLETMEVVQQTRVDKLTQGRQTYDWTLNRNQPAATALANTIEVFRSNGLTANESGRLIDFLKDVMESMDKEEMEITTHFQRKRRVRDNMTKKMVTQRTIGKKKQRLNKRSYLIRALTLNTMTKDAERGKLKRRAIATPGMQIRGFVYFVETLARSICEKLEQSGLPVGGNEKKAKLANVVRKMMTNSQDTELSFTITGDNTKWNENQNPRMFLAMITYITRNQPEWFRNVLSIAPIMFSNKMARLGKGYMFESKSMKLRTQIPAEMLASIDLKYFNDSTRKKIEKIRPLLIDGTASLSPGMMMGMFNMLSTVLGVSILNLGQKRYTKTTYWWDGLQSSDDFALIVNAPNHEGIQAGVDRFYRTCKLLGINMSKKKSYINRTGTFEFTSFFYRYGFVANFSMELPSFGVSGINESADMSIGVTVIKNNMINNDLGPATAQMALQLFIKDYRYTYRCHRGDTQIQTRRSFEIKKLWEQTRSKAGLLVSDGGPNLYNIRNLHIPEVCLKWELMDEDYQGRLCNPLNPFVSHKEIESVNNAVMMPAHGPAKNMEYDAVATTHSWIPKRNRSILNTSQRGILEDEQMYQKCCNLFEKFFPSSSYRRPVGISSMVEAMVSRARIDARIDFESGRIKKEEFAEIMKICSTIEELRRQK
->2bwp_D mol:protein length:401  5-AMINOLEVULINATE SYNTHASE
-MDYNLALDKAIQKLHDEGRYRTFIDIEREKGAFPKAQWNRPDGGKQDITVWCGNDYLGMGQHPVVLAAMHEALEAVGAGSGGTRNISGTTAYHRRLEAEIAGLHQKEAALVFSSAYNANDATLSTLRVLFPGLIIYSDSLNHASMIEGIKRNAGPKRIFRHNDVAHLRELIAADDPAAPKLIAFESVYSMDGDFGPIKEICDIAEEFGALTYIDEVHAVGMYGPRGAGVAERDGLMHRIDIFNGTLAKAYGVFGGYIAASARMVDAVRSYAPGFIFSTSLPPAIAAGAQASIAFLKTAEGQKLRDAQQMHAKVLKMRLKALGMPIIDHGSHIVPVVIGDPVHTKAVSDMLLSDYGVYVQPINFPTVPRGTERLRFTPSPVHDLKQIDGLVHAMDLLWARCA
->3nno_C mol:protein length:171  Peptidoglycan recognition protein 1
-EDPPACGSIVPRREWRALASECRERLTRPVRYVVVSHTAGSHCDTPASCAQQAQNVQSYHVRNLGWCDVGYNFLIGEDGLVYEGRGWNIKGAHAGPTWNPISIGISFMGNYMNRVPPPRALRAAQNLLACGVALGALRSNYEVKGHRDVQPTLSPGDRLYEIIQTWSHYRA
->2feu_A mol:protein length:411  Cytochrome P450-cam
-NLAPLPPHVPEHLVFDFDMYNPSNLSAGVQEAWAVLQESNVPDLVWTRCNGGHWIATRGQLIREAYEDYRHFSSECPFIPREAGEAYDFIPTSMDPPEQRQFRALANQVVGMPVVDKLENRIQELACSLIESLRPQGQCNFTEDYAEPFPIRIFMLLAGLPEEDIPHLKYLTDQMTRPDGSMTFAEAKEALYDYLIPIIEQRRQKPGTDAISIVANGQVNGRPITSDEAKRMCGLLLVGGLDTVVNFLSFSMEFLAKSPEHRQELIERPERIPAACEELLRRFSLVADGRILTSDYEFHGVQLKKGDQILLPQMLSGLDERENACPMHVDFSRQKVSHTTFGHGSHLCLGQHLARREIIVTLKEWLTRIPDFSIAPGAQIQHKSGIVSGVQALPLVWDPATTKAVHHHHHH
->6v3b_V mol:protein length:85  50S ribosomal protein L27
-MATKKAGGSTKNGRDSNPKMLGVKVYGGQTVTAGNIIVRQRGTEFHAGANVGMGRDHTLFATADGVVKFEVKGQFGRRYVKVETV
->3qjv_C mol:protein length:34  Cytochrome c oxidase polypeptide 2A
-MEEKPKGALAVILVLTLTILVFWLGVYAVFFARG
->6az1_b mol:protein length:112  ribosomal protein S26e
-MTTKRRNHGRSKPAHSRGRVKPIHCFNCGRLTPKDKAVGRFVVRRMLDAASARDVAEASPVYGANFPMPKLYMKQRFCIACAIHSRTVRARPVGNRKIRYTRKVPFRPAGKK
->4v5l_AS mol:protein length:93  30S RIBOSOMAL PROTEIN S19
-MPRSLKKGVFVDDHLLEKVLELNAKGEKRLIKTWSRRSTIVPEMVGHTIAVYNGKQHVPVYITENMVGHKLGEFAPTRTYRGHGKEAKATKKK
->3siq_F mol:protein length:136  Apoptosis 1 inhibitor
-MASVVPIAFDQVDNNTNATQLFKNNINKTRMNDLNREETRLKTFTDWPLDWLDKRQLAQTGMYFTHAGDKVKCFFCGVEIGSWEQEDQPVPEHQRWSPNCPLLRRRTTNNVPINAEALDRILPPISYDLEHHHHHH
->7qp7_H mol:protein length:84  40S ribosomal protein S27
-MPLAKDLLHPSPEEEKRKHKKKRLVQSPNSYFMDVKCPGCYKITTVFSHAQTVVLCVGCSTVLCQPTGGKARLTEGCSFRRKQH
->3wkn_O mol:protein length:54  AFFinger p17
-GPGISAFSPGRGVYDPETGTWYDAAWHLGELVWATYYDPETGTWEPDWQRMLGQ
->5y2e_A mol:protein length:47  Non-structural glycoprotein 4
-MIEKQMDRVVKEMRRQLEMIDKLTTRGIEQVELLKRIHDKLMIRAVD
->3rtf_B mol:protein length:258  Glutamate receptor 2
-KTVVVTTILESPYVMMKKNHEMLEGNERYEGYCVDLAAEIAKHCGFKYKLTIVGDGKYGARDADTKIWNGMVGELVYGKADIAIAPLTITLVREEVIDFSKPFMSLGISIMIKKGTPIESAEDLSKQTEIAYGTLDSGSTKEFFRRSKIAVFDKMWTYMRSAEPSVFVRTTAEGVARVRKSKGKYAYLLESTMNEYIEQRKPCDTMKVGGNLDSKGYGIATPKGSSLGNAVNLAVLKLNEQGLLDKLKNKWWYDKGEC
->7cme_A mol:protein length:214  Cadherin-3
-MDWVVAPISVPENGKGPFPQRLNQLKSNKDRDTKIFYSITGPGADSPPEGVFAVEKETGWLLLNKPLDREEIAKYELFGHAVSENGASVEDPMNISIIVTDQNDHKPKFTQDTFRGSVLEGVLPGTSVMQVTATDEDDAIYTYNGVVAYSIHSQEPKDPHDLMFTIHRSTGTISVISSGLDREKVPEYTLTIQATDMDGDGSTTTAVAVVEILD
->6vq7_h mol:protein length:155  V-type proton ATPase 16 kDa proteolipid subunit
-MADIKNNPEYSSFFGVMGASSAMVFSAMGAAYGTAKSGTGIAAMSVMRPELIMKSIIPVVMAGIIAIYGLVVAVLIANSLTDGITLYRSFLQLGAGLSVGLSGLAAGFAIGIVGDAGVRGTAQQPRLFVGMILILIFAEVLGLYGLIVALILSTK
->5af9_I mol:protein length:12  HIRUDIN VARIANT-2
-GDFEEIPEEYLQ
->3nhn_A mol:protein length:193  Tyrosine-protein kinase HCK
-GIREAGSEDIIVVALYDYEAIHHEDLSFQKGDQMVVLEESGEWWKARSLATRKEGYIPSNYVARVDSLETEEWFFKGISRKDAERQLLAPGNMLGSFMIRDSETTKGSYSLSVRDYDPRQGDTVKHYKIRTLDNGGFYISPRSTFSTLQELVDHYKKGNDGLCQKLSVPCMSSKPQKPWEKDAWELEHHHHHH
->1gn2_H mol:protein length:207  SUPEROXIDE DISMUTASE
-MAEYTLPDLDWDYGALEPHISGQINELHHSKHHATYVKGANDAVAKLEEARAKEDHSAILLNEKNLAFNLAGHVNHTIWWKNLSPNGGDKPTGELAAAIADAFGSFDKFRAQFHAAATTVQGCGWAALGWDTLGNKLLIFQVYDHQTNFPLGIVPLLLLDMWEHAFYLQYKNVKVDFAKAFWNVVNWADVQSRYAAATSQTKGLIFG
->2y2p_A mol:protein length:494  PENICILLIN-BINDING PROTEIN 1B
-DISSISEITYSDGTVIASIESDLLRQDFLPSGTVTGISRDYLYFTTLAEAQERMYDYLAQRDNVSAKELKNEATQKFYRDLAAKEIENGGYKITTTIDQKIHSAMQSAVADYGYLLDDGTGRVEVGNVLMDNQTGAILGFVGGRNYQENQNNHAFDTKRSPASTTKPLLAYGIAIDQGLMGSETILSNYPTNFANGNPIMYANSKGTGMMTLGEALNYSWNIPAYWTYRMLRENGVDVKGYMEKMGYEIPEYGIESLPMGGGIEVTVAQHTNGYQTLANNGVYHQKHVISKIEAADGRVVYEYQDKPVQVYSKATATIMQGLLREVLSSRVTTTFKSNLTSLNPTLANADWIGKTGTTGQDENMWLMLSTPRLTLGGWIGHDDNHSLSQQAGYSNNSNYMAHLVNAIQQASPSIWGNERFALDPSVVKSEVLKSTGQKPGKVSVEGKEVEVTGSTVTSYWANKSGAPATSYRFAIGGSDADYQNAWSSIVGSLP
->7tpb_G mol:protein length:66  Ras GTPase-activating protein 1
-GPLGSRRRVRAILPYTKVPDTDEISFLKGDMFIVHNELEDGWMWVTNLRTDEQGLIVEDLVEEVGR
->3dfq_A mol:protein length:363  Fructose-bisphosphate aldolase A
-PHSHPALTPEQKKELSDIAHRIVAPGKGILAASESTGSIAKRLQSIGTENTEENRRFYRQLLLTADDRVNPCIGGVILFHETLYQKADDGRPFPQVIKSKGGVVGIKVDKGVVPLAGTNGETTTQGLDGLSERCAQYKKDGADFAKWRCVLKIGEHTPSALAIMENANVLARYASICQQNGIVPIVEPEILPDGDHDLKRCQYVTEKVLAAVYKALSDHHIYLEGTLLKPNMVTPGHACTQKYSHEEIAMATVTALRRTVPPAVTGVTFLSGGQSEEEASINLNAINKCPLLKPWALTFSYGRALQASALKAWGGKKENLKAAQEEYVKRALANSLACQGKYTPSGQAGAAASESLFISNHAY
->1anc_A mol:protein length:223  ANIONIC TRYPSIN
-IVGGYTCQENSVPYQVSLNSGYHFCGGSLINDQWVVSAAHCYKSRIQVRLGEHNINVLEGNEQFVNAAKIIKHPNFDRKTLNNDIMLIKLSSPVKLNARVATVALPSSCAPAGTQCLISGWGNTLSSGVNEPDLLQCLDAPLLPQADCEASYPGKITDNMVCVGFLEGGKDSCQGDSGGPVVCNGELQGIVKWGYGCALPDNPGVYTKVCNYVDWIQDTIAAN
->6d0u_I mol:protein length:214  Antibody C05, light chain
-DIQLTQSPSSLSASVGDRVTLTCQASQDIRKFLNWYQQKPGKGPKLLIYDASNLQRGVPSRFSGGGSGTDFTLIISSLQPEDVGTYYCQQYDGLPFTFGGGTKVVIKRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNRGEC
->2nti_F mol:protein length:244  DNA polymerase sliding clamp A
-MKVVYDDVRVLKDIIQALARLVDEAVLKFKQDSVELVALDRAHISLISVNLPREMFKEYDVNDEFKFGFNTQYLMKILKVAKRKEAIEIASESPDSVIINIIGSTNREFNVRNLEVSEQEIPEINLQFDISATISSDGFKSAISEVSTVTDNVVVEGHEDRILIKAEGESEVEVEFSKDTGGLQDLEFSKESKNSYSAEYLDDVLSLTKLSDYVKISFGNQKPLQLFFNMEGGGKVTYLLAPKV
->3prc_C mol:protein length:336  PHOTOSYNTHETIC REACTION CENTER
-CFEPPPATTTQTGFRGLSMGEVLHPATVKAKKERDAQYPPALAAVKAEGPPVSQVYKNVKVLGNLTEAEFLRTMTAITEWVSPQEGCTYCHDENNLASEAKYPYVVARRMLEMTRAINTNWTQHVAQTGVTCYTCHRGTPLPPYVRYLEPTLPLNNRETPTHVERVETRSGYVVRLAKYTAYSALNYDPFTMFLANDKRQVRVVPQTALPLVGVSRGKERRPLSDAYATFALMMSISDSLGTNCTFCHNAQTFESWGKKSTPQRAIAWWGIRMVRDLNMNYLAPLNASLPASRLGRQGEAPQADCRTCHQGVTKPLFGASRLKDYPELGPIKAAAK
->7pi5_V mol:protein length:32  Photosystem II reaction center protein Ycf12
-SLTLILQLVALFAVVAAGPLVVVLLSVRGGNL
->6s39_P mol:protein length:12  Cellular tumor antigen p53
-KLMFKTEGPDSD
->4v1a_b mol:protein length:380  MITORIBOSOMAL PROTEIN ML38, MRPL38
-MAAPWWRAALCASRRWRGFSTSAALSRRAAPLGPMPNEDIDVSDLERLKKYRSFDRYRRRAEQEARKPHWWRTYREHFGEESGPKDRVDIGLPPPKVSRTQQLLERKQALRELRANVEEERAARLQTARIPLEAVRAEWERTCGPYHKQRLAEYCGLYRDLFHGATFVPRVPLHVAYAVGEDDLMPVYHGNEVTPTEAAQAPEVTYEADEGSLWTLLLTNLDGHLLEPDAEYVHWLVTNIPGNRVTEGQETCPYLPPFPARGSGFHRFAFLLFKQDKRIDFSGDTRPSPCYQLAQRTFHTFDFYKKHQDAMTPAGLAFFQCRWDDSVTRVFHQLLDMREPVFEFVRPPPYHPKQKRFPHRQPLRYLDRYRDSHEPTYGIY
->1z7n_E mol:protein length:208  ATP phosphoribosyltransferase
-MIKIAITKGRIQKQVTKLLENADYDVEPILNLGRELQIKTKDDLQIIFGKPNDVITFLEHGIVDIGFVGKDTLDENDFDDYYELLYLKIGQCIFALASYPDFSNKNFQRHKRIASKYPRVTKKYFAQKQEDIEIIKLEGSVELGPVVGLADAIVDIVETGNTLSANGLEVIEKISDISTRMIVNKSSFKFKKDKIIEMVERLEDAQTN
->1ygz_A mol:protein length:173  Inorganic pyrophosphatase
-MNLEKLEVSHDADSLCVVIEISKHSNIKYELDKESGALMVDRVLYGAQNYPANYGFVPNTLGSDGDPVDALVLSDVAFQAGSVVKARLVGVLNMEDESGMDEKLIALPIDKIDPTHSYVKDIDDLSKHTLDKIKHFFETYKDLEPNKWVKVKGFENKESAIKVLEKAIKAYQG
->5rkm_A mol:protein length:149  PH-interacting protein
-MHHHHHHSSGVDLGTENLYFQSMSYDIQAWKKQCEELLNLIFQCEDSEPFRQPVDLLEYPDYRDIIDTPMDFATVRETLEAGNYESPMELCKDVRLIFSNSKAYTPSKRSRIYSMSLRLSAFFEEHISSVLSDYKSALRFHKRNTITKR
->4dvi_B mol:protein length:217  Tankyrase-1
-QGTILLDLAPEDKEYQSVEEEMQSTIREHRDGGNAGGIFNRYNVIRIQKVVNKKLRERFCHRQKEVSEENHNHHNERMLFHGSPFINAIIHKGFDERHAYIGGMFGAGIYFAENSSKSNQYVYGIGGGTGCPTHKDRSCYICHRQMLFCRVTLGKSFLQFSTMKMAHAPPGHHSVIGRPSVNGLAYAEYVIYRGEQAYPEYLITYQIMKPEHHHHHH
->6xu6_CD mol:protein length:290  60S ribosomal protein L5
-KNKQYFKRYQVKFRRRREGKTDYYARKRLTFQDKNKYNTPKYRLIVRLSNKDITVQIAYARIEGDRVVCAAYSHELPKYGIQVGLTNYAAAYCTGLLVARRVLNKLGLDSLYAGCTEVTGEEFNVEPVDDGPGAFRCFLDVGLARTTTGARVFGAMKGAVDGGLNIPHSVKRFPGYSAETKSFNADVHRAHIFGQHVADYMRSLEEEDEESFKRQFSRYIKLGIRADDLEDIYKKAHQAIRNDPTHKVTAKKSSAVTKKRWNAKKLTNEQRKTKIAAHKAAYVAKLQSET
->6m0s_E mol:protein length:159  V-type proton ATPase subunit c
-MTELCPVYAPFFGAIGCASAIIFTSLGAAYGTAKSGVGICATCVLRPDLLFKNIVPVIMAGIIAIYGLVVSVLVCYSLGQKQALYTGFIQLGAGLSVGLSGLAAGFAIGIVGDAGVRGSSQQPRLFVGMILILIFAEVLGLYGLIVALLLNSRATQDVV
->7ckb_Bj mol:protein length:98  Major carboxysome shell protein 1A
-MADVTGIALGMIETRGLVPAIEAADAMTKAAEVRLVGRQFVGGGYVTVLVRGETGAVNAAVRAGADACERVGDGLVAAHIIARVHSEVENILPKAPQA
->7l6g_B mol:protein length:299  Metallo-mystery pair system four-Cys motif protein
-AGVKTQPVAVRFALVADGKEVGCGAPLANLGSGRLAGKLHEARLYVYGFELVDAKGKHTPIALTQNDWQYADVALLDFKDARGGNAACTPGNPAKNTTVVGAAPQGAYVGLAFSVGAPVESLVDGKPVFVNHSNVEAAPPPLDISGMAWNWQAGRRFVTIEVIPPAAVIKPDGSKSRTWMVHVGSTGCKGNPATGEIVACAHENRFPVVFDRFDPKTQRVELDLTTLFESSDISVDKGGAVGCMSALDDPDCPAVFRALGLNLADSAPGANDAGKPSRPGVSPIFSVGAAASKVAGGKQ
->3lcb_C mol:protein length:416  Isocitrate dehydrogenase [NADP]
-MESKVVVPAQGKKITLQNGKLNVPENPIIPYIEGDGIGVDVTPAMLKVVDAAVEKAYKGERKISWMEIYTGEKSTQVYGQDVWLPAETLDLIREYRVAIKGPLTTPVGGGIRSLNVALRQELDLYICLRPVRYYQGTPSPVKHPELTDMVIFRENSEDIYAGIEWKADSADAEKVIKFLREEMGVKKIRFPEHCGIGIKPCSEEGTKRLVRAAIEYAIANDRDSVTLVHKGNIMKFTEGAFKDWGYQLAREEFGGELIDGGPWLKVKNPNTGKEIVIKDVIADAFLQQILLRPAEYDVIACMNLNGDYISDALAAQVGGIGIAPGANIGDECALFEATHGTAPKYAGQDKVNPGSIILSAEMMLRHMGWTEAADLIVKGMEGAINAKTVTYDFERLMDGAKLLKCSEFGDAIIENM
->2wl6_A mol:protein length:392  ACETYL-COA ACETYLTRANSFERASE
-STPSIVIASAARTAVGSFNGAFANTPAHELGATVISAVLERAGVAAGEVNEVILGQVLPAGEGQNPARQAAMKAGVPQEATAWGMNQLCGSGLRAVALGMQQIATGDASIIVAGGMESMSMAPHCAHLRGGVKMGDFKMIDTMIKDGLTDAFYGYHMGTTAENVAKQWQLSRDEQDAFAVASQNKAEAAQKDGRFKDEIVPFIVKGRKGDITVDADEYIRHGATLDSMAKLRPAFDKEGTVTAGNASGLNDGAAAALLMSEAEASRRGIQPLGRIVSWATVGVDPKVMGTGPIPASRKALERAGWKIGDLDLVEAHEAFAAQACAVNKDLGWDPSIVNVNGGAIAIGNPIGASGARILNTLLFEMKRRGARKGLATLCIGGGMGVAMCIESL
->6qz0_6E mol:protein length:448  Major capsid protein
-MRITFNDVKTSLGITESYDIVNAIRNSQGDNFKSYVPLATANNVAEVGAGILINQTVQNDFITSLVDRIGLVVIRQVSLNNPLKKFKKGQIPLGRTIEEIYTDITKEKQYDAEEAEQKVFEREMPNVKTLFHERNRQGFYHQTIQDDSLKTAFVSWGNFESFVSSIINAIYNSAEVDEYEYMKLLVDNYYSKGLFTTVKIDEPTSSTGALTEFVKKMRATARKLTLPQGSRDWNSMAVRTRSYMEDLHLIIDADLEAELDVDVLAKAFNMNRTDFLGNVTVIDGFASTGLEAVLVDKDWFMVYDNLHKMETVRNPRGLYWNYYYHVWQTLSVSRFANAVAFVSGDVPAVTQVIVSPNIAAVKQGGQQQFTAYVRATNAKDHKVVWSVEGGSTGTAITGDGLLSVSGNEDNQLTVKATVDIGTEDKPKLVVGEAVVSIRPNNASGGAQA
->5ez8_D mol:protein length:31  CC-Hept-I-C-I
-XGEIAQALKEIAKALKEIAWACKEIAQALKG
->7jqm_2H mol:protein length:180  50S ribosomal protein L6
-MSRIGRLPIPVPKGVSVEVAPGRVKVKGPKGELEVPVSPEMRVVVEEGVVRVERPSDERRHKSLHGLTRTLIANAVKGVSEGYSKELLIKGIGYRARLVGRALELTVGFSHPVVVEPPEGITFEVPEPTRVRVSGIDKQKVGQVAANIRAIRKPSAYHEKGIYYAGEPVRLKPGKAGAKK
->7ck8_B mol:protein length:173  Ferritin heavy chain
-STSQVRQNYHQDSEAAINRQINLELYASYVYLSMSYYFDRDDVALKNFAKYFLHQSHEEREHAEKLMKLQNQRGGRIFLQDIKKPDSDDWESGLNAMESALHLEKNVNQSLLELHKLATDKNDPHLSDFIETHYLNEQVKAIKELGDHVTNLRKMGAPESGLAEYLFDKHTLG
->5gaq_C mol:protein length:310  Lysenin
-MSAKAAEGYEQIEVDVVAVWKEGYVYENRGSTSVDQKITITKGMKNVNSETRTVTATHSIGSTISTGDAFEIGSVEVSYSHSHEESQVSMTETEVYESKVIEHTITIPPTSKFTRWQLNADVGGADIEYMYLIDEVTPIGGTQSIPQVITSRAKIIVGRQIILGKTEIRIKHAERKEYMTVVSRKSWPAATLGHSKLFKFVLYEDWGGFRIKTLNTMYSGYEYAYSSDQGGIYFDQGTDNPKQRWAINKSLPLRHGDVVTFMNKYFTRSGLCYDDGPATNVYCLDKREDKWILEVVGLVPRGSGHHHHHH
->2g2w_B mol:protein length:165  Beta-lactamase inhibitory protein
-AGVMTGAKFTQIQFGMTRQQVLDIAGAENCETGGSFGDSIHCRGHAAGDYYAYATFGFTSAAADAKVDSKSQEKLLAPSAPTLTLAKFNQVTVGMTRAQVLATVGQGSCTTWSEYYPAYPSTAGVTLSLSCFDVDGYSSTGFYRGSAHLWFTDGVLQGKRQWDLV
->1egm_G mol:protein length:173  PROPANEDIOL DEHYDRATASE
-MNTDAIESMVRDVLSRMNSLQGEAPAAAPAAGGASRSARVSDYPLANKHPEWVKTATNKTLDDFTLENVLSNKVTAQDMRITPETLRLQASIAKDAGRDRLAMNFERAAELTAVPDDRILEIYNALRPYRSTKEELLAIADDLESRYQAKICAAFVREAATLYVERKKLKGDD
->4oko_B mol:protein length:312  Rapid Encystment Phenotype Protein 34 KDa
-MPAQYHIGTPGKKWGSEEKSQWLAEQNKKRSYQQEAEKKILALVSDFDIDEYGQLDYPVGSYKLYALKTKNWDASKPYVLVTGGVHGYETSGVQGAISFAQTRALEFARDYNIVILPCLSPWGYETINRWNPNALDPNRSFYLESGCQEAVLAMKYVFSLGVEFLMHIDLHETTDTDDSEFRPALAAREGIAINKWGIPDGFYLVANNRNPHYDFQKYIIDAVAKVTHIAPTDPSINILGDDIIRDGIMACDSDKERLCMSFTTAEYTTTTEVYPDSPRTNPQECILAQVEAIVAGLNFLKQKNLEHHHHHH
->4cih_B mol:protein length:150  LISTERIA NUCLEAR TARGETED PROTEIN A
-RPKLSTKDLALIKADLAEFEARELSSEKILKDTIKEESWSDLDFANDNINQMIGTMKRYQQEILSIDAIKRSSEASADTEAFKKIFKEWSEFKIERIQVTIDLLNGKKDSEAVFKKTYPNQIIFDDVRTNKLQTALNNLKVGYELLDSQK
->6k3a_A mol:protein length:264  Proliferating cell nuclear antigen
-GPGMFEARLVQGSILKKVLEALKDLINEACWDISSSGVNLQSMDSSHVSLVQLTLRSEGFDTYRCDRNLAMGVNLTSMSKILKCAGNEDIITLRAEDNADTLALVFEAPNQEKVSDYEMKLMDLDVEQLGIPEQEYSCVVKMPSGEFARICRDLSHIGDAVVISCAKDGVKFSASGELGNGNIKLSQTSNVDKEEEAVTIEMNEPVQLTFALRYLNFFTKATPLSSTVTLSMSADVPLVVEYKIADMGHLKYYLAPKIEDEEGS
->1myw_A mol:protein length:239  Green fluorescent protein
-MVSKGEELFTGVVPILVELDGDVNGHKFSVSGEGEGDATYGKLTLKLICTTGKLPVPWPTLVTTLGYGLQCFARYPDHMKQHDFFKSAMPEGYVQERTIFFKDDGNYKTRAEVKFEGDTLVNRIELKGIDFKEDGNILGHKLEYNYNSHNVYITADKQKNGIKANFKIRHNIEDGGVQLADHYQQNTPIGDGPVLLPDNHYLSYQSALSKDPNEKRDHMVLLEFVTAAGITHGMDELYK
->5zmu_A mol:protein length:314  Cis-epoxysuccinate hydrolase
-MGSSHHHHHHSSGLVPRGSHMTRTKLILEARINEYMPRRGNPHVPWTPKEIGEAAAQAREAGASIVHFHARQADGSPSHDYETYAESIREIRARSDVLVHPTLGQITLGGRESRLAHIERLCLDPALKPDFAPVDLGSTNIDRYDDVEKRYETGDRVYLNNIDTLQHFSKRLRELGVKPAFIAWTVPFTRTLDAFMDMGLVDDPAYLLFELTDCGIRGGHPGTIRGLRAHTDFLPPGRQIQWTVCNKIGNLFGPAAAAIEEGGHVAIGLGDYLYPELGTPTNGEVVQTVANMARAMGREIATPAETKEILGISN
->6yfb_CB mol:protein length:166  coat protein
-SYTQSFGYTIPTEKDTLEIPQYQALLAKKASYMDDSQGKNTATYMNTAAPKDQPETITFGVNKVDNVYKQSNVQNQTFYASSSKGTKIRIDGKRIWRTQSTDVNTGLPVIVDCPLWTSFTLGFADFTLVDDSARKSTIEWMISQLELLKDDGVWSKLCSGVTRIYG
->1j0a_A mol:protein length:325  1-aminocyclopropane-1-carboxylate deaminase
-MHPKIFALLAKFPRVELIPWETPIQYLPNISREIGADVYIKRDDLTGLGIGGNKIRKLEYLLGDALSKGADVVITVGAVHSNHAFVTGLAAKKLGLDAILVLRGKEELKGNYLLDKIMGIETRVYDAKDSFELMKYAEEIAEELKREGRKPYVIPPGGASPIGTLGYVRAVGEIATQSEVKFDSIVVAAGSGGTLAGLSLGLSILNEDIRPVGIAVGRFGEVMTSKLDNLIKEAAELLGVKVEVRPELYDYSFGEYGKITGEVAQIIRKVGTREGIILDPVYTGKAFYGLVDLARKGELGEKILFIHTGGISGTFHYGDKLLSLL
->4hgj_B mol:protein length:455  Bifunctional P-450/NADPH-P450 reductase
-TIKEMPQPKTFGELKNLPLLNTDKPVQALMKIADELGEIFKFEAPGRVTRYLSSQRLIKEACDESRFDKNLSQALKFVRDFAGDGLATSWTHEKNWKKAHNILLPSFSQQAMKGYHAMMVDIAVQLVQKWERLNADEHIEVPEDMTRLTLDTIGLCGFNYRFNSFYRDQPHPFITSMVRALDEAMNKLQRANPDDPAYDENKRQFQEDIKVMNDLVDKIIADRKASGEQSDDLLAHMLNGKDPETGEPLDDENIRYQIITFLIAGHETTSGLLSFALYFLVKNPHVLQKAAEEAARVLVDPVPSYKQVKQLKYVGMVLNEALRLWPTAPAFSLYAKEDTVLGGEYPLEKGDELMVLIPQLHRDKTIWGDDVEEFRPERFENPSAIPQHAFKPFGNGQRACIGQQFALHEATLVLGMMLKHFDFEDHTNYELDIKETLTLKPEGFVVKAKSKKIPL
->6vmi_5 mol:protein length:423  39S ribosomal protein L37, mitochondrial
-MALASGPARRALAGSGQLGLGGFGAPRRGAYEWGVRSTRKSEPPPLDRVYEIPGLEPITFAGKMHFVPWLARPIFPPWDRGYKDPRFYRSPPLHEHPLYKDQACYIFHHRCRLLEGVKQALWLTKTKLIEGLPEKVLSLVDDPRNHIENQDECVLNVISHARLWQTTEEIPKRETYCPVIVDNLIQLCKSQILKHPSLARRICVQNSTFSATWNRESLLLQVRGSGGARLSTKDPLPTIASREEIEATKNHVLETFYPISPIIDLHECNIYDVKNDTGFQEGYPYPYPHTLYLLDKANLRPHRLQPDQLRAKMILFAFGSALAQARLLYGNDAKVLEQPVVVQSVGTDGRVFHFLVFQLNTTDLDCNEGVKNLAWVDSDQLLYQHFWCLPVIKKRVVVEPVGPVGFKPETFRKFLALYLHGAA
->6uzq_C mol:protein length:9  Synthetic peptide THR-VAL-ARG-ALA-SER-GLY-HIS-SER-TYR
-TVRASGHSY
->6wwl_A mol:protein length:451  Tubulin alpha-1B chain
-MRECISIHVGQAGVQIGNACWELYCLEHGIQPDGQMPSDKTIGGGDDSFNTFFSETGAGKHVPRAVFVDLEPTVIDEVRTGTYRQLFHPEQLITGKEDAANNYARGHYTIGKEIIDLVLDRIRKLADQCTGLQGFLVFHSFGGGTGSGFTSLLMERLSVDYGKKSKLEFSIYPAPQVSTAVVEPYNSILTTHTTLEHSDCAFMVDNEAIYDICRRNLDIERPTYTNLNRLISQIVSSITASLRFDGALNVDLTEFQTNLVPYPRIHFPLATYAPVISAEKAYHEQLSVAEITNACFEPANQMVKCDPRHGKYMACCLLYRGDVVPKDVNAAIATIKTKRSIQFVDWCPTGFKVGINYQPPTVVPGGDLAKVQRAVCMLSNTTAIAEAWARLDHKFDLMYAKRAFVHWYVGEGMEEGEFSEAREDMAALEKDYEEVGVDSVEGEGEEEGEEY
->7l20_D mol:protein length:305  39S ribosomal protein L2, mitochondrial
-MALCALTRALRSLNLAPPTVAAPAPSLFPAAQMMNNGLLQQPSALMLLPCRPVLTSVALNANFVSWKSRTKYTITPVKMRKSGGRDHTGRIRVHGIGGGHKQRYRMIDFLRFRPEETKSGPFEEKVIQVRYDPCRSADIALVAGGSRKRWIIATENMQAGDTILNSNHIGRMAVAAREGDAHPLGALPVGTLINNVESEPGRGAQYIRAAGTCGVLLRKVNGTAIIQLPSKRQMQVLETCVATVGRVSNVDHNKRVIGKAGRNRWLGKRPNSGRWHRKGGWAGRKIRPLPPMKSYVKLPSASAQS
->7d28_D mol:protein length:117  Endoribonuclease MazF
-MVSDYVPDAGHLVWLNFTPQAGHEQGGRRPALVLSPAAYNGVTGLMQACPVTSRAKGYPFEVTLPAHLGVSGVVLADHCRSLDWRSRRAEQLAEAPADVLAEVRGKLGSLLGMSEKA
->6hvu_b mol:protein length:196  Proteasome subunit beta type-1
-TSIMAVTFKDGVILGADSRTTTGAYIANRVTDKLTRVHDKIWCCRSGSAADTQAIADIVQYHLELYTSQYGTPSTETAASVFKELCYENKDNLTAGIIVAGYDDKNKGEVYTIPLGGSVHKLPYAIAGSGSTFIYGYCDKNFRENMSKEETVDFIKHSLSQAIKWDGSSGGVIRMVVLTAAGVERLIFYPDEYEQL
->2nyz_E mol:protein length:93  Lymphotactin
-VGSEVSDKRTCVSLTTQRLPVSRIKTYTITEGSLRAVIFITKRGLKVCADPQATWVRDVVRSMDRKSNTRNNMIQTKPTGTQQSTNTAVTLTG
->5sce_D mol:protein length:447  Pyruvate kinase
-GSMEGPAGYLRRADVAQLTQELGTAFFQQQQLPAAMADTFLEHLCLLDIDSEPVAARSTSIIATIGPASRSVERLKEMIKAGMNIARLNFSHGSHEYHAESIANVREAVESFAGSPLSYRPVAIALDTKGPGSGPGLSEQDVRDLRFGVEHGVDIVFASFVRKASDVAAVRAALGPEGHGIKIISKIENHEGVKRFDEILEVSDGIMVARGDLGIEIPAEKVFLAQKMMIGRCNLAGKPVVCATQMLESMITKPRPTRAETSDVANAVLDGADCIMLSGETAKGNFPVEAVKMQHAIAREAEAAVYHRQLFEELRRAAPLSRDPTEVTAIGAVEAAFKCCAAAIIVLTTTGRSAQLLSRYRPRAAVIAVTRSAQAARQVHLCRGVFPLLYREPPEAIWADDVDRRVQFGIESGKLRGFLRVGDLVIVVTGWRPGSGYTNIMRVLSIS
->7qrv_B mol:protein length:281  Tripartite motif-containing protein 2
-SMNPIEDDLIFRVGTKGRNKGEFTNLQGVAASTNGKILIADSNNQCVQIFSNDGQFKSRFGIRGRSPGQLQRPTGVAVHPSGDIIIADYDNKWVSIFSSDGKFKTKIGSGKLMGPKGVSVDRNGHIIVVDNKACCVFIFQPNGKIVTRFGSRGNGDRQFAGPHFAAVNSNNEIIITDFHNHSVKVFNQEGEFMLKFGSNGEGNGQFNAPTGVAVDSNGNIIVADWGNSRIQVFDGSGSFLSYINTSADPLYGPQGLALTSDGHVVVADSGNHCFKVYRYLQ
->6wef_L mol:protein length:159  Uncharacterized protein
-GGEVPIGDPKELNGMEIAAVYLQPIEMEPRGIDLAASLADIHLEADIHALKNNPNGFPEGFWMPYLTIAYELKNTDTGAIKRGTLMPMVADHGPHYGANIAMEKDKKGGFGVGNYELTFYISNPEKQGFGRHVDEETGVGKWFEPFKVDYKFKYTGTPK
->1v2a_A mol:protein length:210  glutathione transferase gst1-6
-MDYYYSLISPPCQSAILLAKKLGITLNLKKTNVHDPVERDALTKLNPQHTIPTLVDNGHVVWESYAIVLYLVETYAKDDTLYPKDPKVRSVVNQRLFFDIGTLYKRIIDVIHLVMKKEQPSDEQMEKLKGALDLLEQFVTERAYAAADHLTVADICLLGTVTALNWLKHDLEPFPHIRAWLERVRAEMPDYEEFSKQVADDTLAYVASRK
->6onk_B mol:protein length:137  Dehaloperoxidase B
-GFKQDIATLRGDLRTYAQDIFLAFLNKYPDEKRNFKNYVGKSDQELKSMAKFGDHTEKVFNLMMEVADRATDCVPLASDASTLVQMKQHSGLTTGNFEKLFVALVEYMRASGQSFDSQSWDRFGKNLVSALSSAGMK
->4v8e_CG mol:protein length:182  50S ribosomal protein L5
-MPLDVALKRKYYEEVRPELIRRFGYQNVWEVPRLEKVVINQGLGEAKEDARILEKAAQELALITGQKPAVTRAKKSISNFKLRKGMPIGLRVTLRRDRMWIFLEKLLNVALPRIRDFRGLNPNSFDGRGNYNLGLREQLIFPEITYDMVDALRGMDIAVVTTAETDEEARALLELLGFPFRK
->7d1t_b mol:protein length:505  Photosystem II CP47 reaction center protein
-GLPWYRVHTVLINDPGRLIAAHLMHTALVAGWAGSMALYELATFDPSDPVLNPMWRQGMFVLPFMARLGVTGSWSGWSITGETGIDPGFWSFEGVALAHIVLSGLLFLAACWHWVYWDLELFRDPRTGEPALDLPKMFGIHLFLAGLLCFGFGAFHLTGLFGPGMWVSDPYGLTGSVQPVAPEWGPDGFNPYNPGGVVAHHIAAGIVGIIAGLFHILVRPPQRLYKALRMGNIETVLSSSIAAVFFAAFVVAGTMWYGSATTPIELFGPTRYQWDSSYFQQEINRRVQASLASGATLEEAWSAIPEKLAFYDYIGNNPAKGGLFRTGPMNKGDGIAQAWKGHAVFRNKEGEELFVRRMPAFFESFPVILTDKNGVVKADIPFRRAESKYSFEQQGVTVSFYGGELNGQTFTDPPTVKSYARKAIFGEIFEFDTETLNSDGIFRTSPRGWFTFAHAVFALLFFFGHIWHGARTLFRDVFSGIDPELSPEQVEWGFYQKVGDVTTRK
->1swr_B mol:protein length:127  CORE-STREPTAVIDIN
-AEAGITGTWYNQLGSTFIVTAGADGALTGTYESAVGNAESRYVLTGRYDSAPATDGSGTALGWTVAWKNNYRNAHSATTWSGQYVGGAEARINTQWLLTSGTTEANAAKSTLVGHDTFTKVKPSAAS
->5xke_B mol:protein length:445  Tubulin beta chain
-MREIVHIQAGQCGNQIGAKFWEVISDEHGIDPTGSYHGDSDLQLERINVYYNEATGNKYVPRAILVDLEPGTMDSVRSGPFGQIFRPDNFVFGQSGAGNNWAKGHYTEGAELVDSVLDVVRKESESCDCLQGFQLTHSLGGGTGSGMGTLLISKIREEYPDRIMNTFSVMPSPKVSDTVVEPYNATLSVHQLVENTDETYCIDNEALYDICFRTLKLTTPTYGDLNHLVSATMSGVTTCLRFPGQLNADLRKLAVNMVPFPRLHFFMPGFAPLTSRGSQQYRALTVPELTQQMFDSKNMMAACDPRHGRYLTVAAIFRGRMSMKEVDEQMLNVQNKNSSYFVEWIPNNVKTAVCDIPPRGLKMSATFIGNSTAIQELFKRISEQFTAMFRRKAFLHWYTGEGMDEMEFTEAESNMNDLVSEYQQYQDATADEQGEFEEEGEEDEA
->6nx9_A mol:protein length:333  L-asparaginase 2
-MHHHHHHLPNITILATGGTIAGGGDSATKSNYTVGKVGVENLVNAVPQLKDIANVKGEQVVNIGSQDMNDNVWLTLAKKINTDCDKTDGFVITHGTTTMEETAYFLDLTVKCDKPVVMVGAMRPSTSMSADGPFNLYNAVVTAADKASANRGVLVVMNDTVLDGRDVTTTNTTDVATFKSVNYGPLGYIHNGKIDYQRTPARKHTSDTPFDVSKLNELPKVGIVYNYANASDLPAKALVDAGYDGIVSAGVGNGNLYKSVFDTLATAAKTGTAVVRSSRVPTGATTQDAEVDDAKYGFVASGTLNPQKARVLLQLALTQTKDPQQIQQIFNQY
->2qr0_S mol:protein length:213  Fab-Fragment Light Chain
-DIQMTQSPSSLSASVGDRVTITCRASQSVSSAVAWYQQKPGKAPKLLIYSASSLYSGVPSRFSGSRSGTDFTLTISSLQPEDFATYYCQQYSYYYYPFTFGQGTKVEIKRTVAAPSVFIFPPSDEQLKSGTASVVCLLNNFYPREAKVQWKVDNALQSGNSQESVTEQDSKDSTYSLSSTLTLSKADYEKHKVYACEVTHQGLSSPVTKSFNR
->4v7v_B2 mol:protein length:46  50S ribosomal protein L34
-MKRTFQPSVLKRNRSHGFRARMATKNGRQVLARRRAKGRARLTVSK
->5lze_r mol:protein length:65  30S ribosomal protein S18
-FCRFTAEGVQEIDYKDIATLKNYITESGKIVPSRITGTRAKYQRQLARAIKRARYLSLLPYTDRH
->7b4v_A mol:protein length:132  Broadly neutralizing DARPin bnD.2
-GPGSDLGKKLLEAARAGQDDEVRILMANGADVNASDADVGATPLHLAAWAGHLEIVEVLLKTGADVNAVDIWGLTPLHLAAAVGHLEIVEVLLKHGADVNAQDKFGKTPFDLAIDNGNEDIAEVLQKAAKLN
->7xjh_R mol:protein length:395  Beta-3 adrenergic receptor
-DYKDDDDAMGAPWPHGNGSVASWPAAPTPTPDAANTSGLPGAPWAVALAGALLALEVLATVGGNLLVIVAIARTPRLQTMTNVFVTSLATADLVVGLLVVPPGATLALTGRWPLGATGCELWTSVDVLCVTASIETLCALAVDRYLAVTNPLRYGALVTKRRARAAVVLVWVVSAAVSFAPIMSKWWRVGADAEAQRCHSNPHCCAFASNIPYALLSSSVSFYLPLLVMLFVYARVFLVATRQLRLLRRELGRFPPAESPPAASRSRSPGPARRCASPAAVPSDRLRPARLLPLREHRALRTLGLIVGTFTLCWLPFFVANVMRALGGPSLVPSPALLALNWLGYANSAFNPLIYCRSPDFRSAFRRLLCRCRREEHRAAASPPGDPSENLYFQG
->6bx1_z mol:protein length:540  VP2
-SGVGHSTGNYNNRTIFHYHGDEVTIICHATRHIHLNMSPTEEYKIYDTNHGPEFPNTGDQTQQGRNTVNDSYHAKVETPWYLINPNSWGIWFNPADFQQLITTCTHVTIETLTQEIDNIVIKTVSKQGSGAEETTQYNNDLTALLEVALDKSNMLPWVADNMYLNSLGYIPWRPCKLTQFCYHTNFYNTINLLEGTQQNQWSQIKEGIQYDNLQFTPIETSAEIDLLRTGDSWTSGTYHFKCKPTQLFYHWQSTRHIGAPHPTTSPEQEGQKGQIIQDTNGWQWGDRDNPISASTTVKDFHIGYSWPEWRWHYSTGGPSINPGSAFSQTPWGSEVGGTRLTQGASEKAIFDYNHGEAEPGHRDQWWQNNAQQTGQTNWAIKNAHQSELRNATASRETFWTQDYHNTFGPYTAVDDVGIQYPWGAMWGKQPDTTHKPMMSAHAPFTCQNGPPGQLLVKLAPNYTDSLNNEGLQTNRIVTFATFWWTGRCTFKAKLRTPRQFNAYQLPGIPSGTNPKKFVPDAIGRFELPFMPGRAMPNYTY
->7lkj_D mol:protein length:423  Aminofutalosine deaminase
-MHHHHHHENLYFQGMQEIIGASLVFLCNEKCEVLEDYGVVFDEKIVEIGDYHNLTLKYPHLKAQFFENSVLLPAFINAHTHFEFSNNKASFDYGSFSGWLGSVLNNGGAILENCQGAIQNAIMAQLKSGVGSVGAISNHLIEVNLLKESPLNAVVFLEFLGSSYSLEKLKAFEAKFKELKDLEDQKLKAALAVHAPYSVQKDMALSVIQLAKDSQSLLSTHFLESLEELEWVENSKGWFENFYQRFLKESNFTSLYEGANDYIDMFKDTHTLFVHNQFASLEALKRIKSQVKNAFLITCPFSNRLLSGKALDLERVREAGLSVSVATDGLSSNISLSLLDELRAFLLSHNMPLLELAKIALLGATRHGAKALALNNGEIETNKRADLSVFGFNEKFTKEQAILQFLLHAKEVERLFLGGKRVI
->4xuc_A mol:protein length:218  Catechol O-methyltransferase
-NLLAGDTKEQRILNHVLQHAEPGNAQSVLEAIDTYCEQKEWAMNVGDKKGKIVDAVIQEHQPSVLLELGAYCGYSAVRMARLLSPGARLITIEINPDCAAITQRMVDFAGVKDKVTLVVGASQDIIPQLKKKYDVDTLDMVFLDHWKDRYLPDTLLLEECGLLRKGTVLLADNVICPGAPDFLAHVRGSSCFECTHYQSFLEYREVVDGLEKAIYKGP
->3l0s_A mol:protein length:223  Adenylate kinase
-MNILIFGPNGSGKGTQGNLVKDKYSLAHIESGGIFREHIGGGTELGKKAKEFIDRGDLVPDDITIPMVLETLESKGKDGWLLDGFPRNTVQAQKLFEALQEKGMKINFVIEILLPREVAKNRIMGRRICKNNPNHPNNIFIEAIKPNGDVCRVCGGALSARADDQDEGAINKRHDIYYNTVDGTLAAAYYYKNMAAKEGFVYIELDGEGSIDSIKDTLLAQLA
->7rqc_2P mol:protein length:150  50S ribosomal protein L15
-MKLSDLRPNPGANKRRKRVGRGPGSGHGKTATRGHKGQKSRSGGLKDPRRFEGGRSTTLMRLPKRGMQGQVPGEIKRPRYQGVNLKDLARFEGEVTPELLVRAGLLKKGYRLKILGEGEAKPLKVVAHAFSKSALEKLKAAGGEPVLLEA
->4yus_A mol:protein length:382  Family 3 adenylate cyclase
-MNHKVHHHHHHIEGRHMKRLTYISKFSRPLSGDEIEAIGRISSQKNQQANVTGVLLCLDGIFFQILEGEAEKIDRIYERILADERHTDILCLKSEVEVQERMFPDWSMQTINLDENTDFLIRPIKVLLQTLTESHRILEKYTQPSIFKIISQGTNPLNIRPKAVEKIVFFSDIVSFSTFAEKLPVEEVVSVVNSYFSVCTAIITRQGGEVTKFIGDCVMAYFDGDCADQAIQASLDILMELEILRNSAPEGSPLRVLYSGIGLAKGKVIEGNIGSELKRDYTILGDAVNVAARLEALTRQLSQALVFSSEVKNSATKSWNFIWLTDSELKGKSESIDIYSIDNEMTRKSSGGLEIARNIGHYLERVGDRQPSQIFGVKSLPL
->1ziq_A mol:protein length:173  Gamma crystallin E
-GKITFYEDRGFQGRHYECSTDHSNLQPYFSRCNSVRVDSGCWMLYEQPNFTGCQYFLRRGDYPDYQQWMGFSDSVRSCRLIPHSSSHRIRIYEREDYRGQMVEITDDCPHLQDRFHFSDFHSFHVMEGYWVLYEMPNYRGRQYLLRPGEYRRYHDWGAMNARVGSLRRIMDFY
->4qx8_D mol:protein length:68  Lysine-specific demethylase 2A
-QVHLTHFELEGLRCLVDKLESLPLHKKCVPTGIEDEDALIADVKILLEELASSDPKLALTGVPIVQWP
->6r0z_B mol:protein length:578  V-type ATP synthase alpha chain
-MIQGVIQKIAGPAVIAKGMLGARMYDICKVGEEGLVGEIIRLDGDTAFVQVYEDTSGLKVGEPVVSTGLPLAVELGPGMLNGIYDGIQRPLERIREKTGIYITRGVVVHALDREKKWAWTPMVKPGDEVRGGMVLGTVPEFGFTHKILVPPDVRGRVKEVKPAGEYTVEEPVVVLEDGTELKMYHTWPVRRARPVQRKLDPNTPFLTGMRILDVLFPVAMGGTAAIPGPFGSGKTVTQQSLAKWSNADVVVYVGCGERGNEMTDVLVEFPELTDPKTGGPLMHRTVLIANTSNMPVAAREASIYVGVTIAEYFRDQGFSVALMADSTSRWAEALREISSRLEEMPAEEGYPPYLAARLAAFYERAGKVITLGGEEGAVTIVGAVSPPGGDMSEPVTQSTLRIVGAFWRLDASLAFRRHFPAINWNGSYSLFTSALDPWYRENVAEDYPELRDAISELLQREAGLQEIVQLVGPDALQDAERLVIEVGRIIREDFLQQNAYHEVDAYCSMKKAYGIMKMILAFYKEAEAAIKRGVSIDEILQLPVLERIGRARYVSEEEFPAYFEEAMKEIQGAFKALA
->6fl9_E mol:protein length:320  Cys-loop ligand-gated ion channel
-MASLAAEPSDVFIGLKIDQITGINQKEENFSVVGSLRIDWRQPLLAFEHAPGEPKHRTYTLATFLKLLEEKQIRWPAFTYHNQQGRMDFQNRLISLSEDGTVMYLERFTSTFQAPAFDFRLFPFDNQLFFIHVDSIFPQHLFRFQEMQGFSGLGDQLGEEEWIVTEVNTHLTTHNEFTKGDASRFVLEFHAERHLNYYLMRILIPVLLIITVSWFTFFLQDYTKRIDLAGGNLLLFIAFNFTISSDLPRLGYITLMDAFLVGTFIITALVVLGNVWLRRLENHGKQALARKLDIYAITSYPLAYLLGALTLWLLFFWRSY
->7som_CC mol:protein length:443  Tubulin beta
-MREIVHIQGGQCGNQIGAKFWEVVSDEHGIDPTGTYHGDSDLQLERINVYFNEATGGRYVPRAILMDLEPGTMDSVRSGPYGQIFRPDNFVFGQTGAGNNWAKGHYTEGAELIDSVLDVVRKEAESCDCLQGFQVCHSLGGGTGSGMGTLLISKIREEYPDRMMLTFSVVPSPKVSDTVVEPYNATLSVHQLVENADECMVLDNEALYDICFRTLKLTTPTFGDLNHLISAVMSGITCCLRFPGQLNADLRKLAVNLIPFPRLHFFMVGFTPLTSRGSQQYRALTVPELTQQMWDAKNMMCAADPRHGRYLTASALFRGRMSTKEVDEQMLNVQNKNSSYFVEWIPNNVKSSVCDIPPKGLKMSATFIGNSTAIQEMFKRVSEQFTAMFRRKAFLHWYTGEGMDEMEFTEAESNMNDLVSEYQQYQDASAEEEGEFEGEEEEA
->4r8p_H mol:protein length:122  Histone H2B 1.1
-AKSAPAPKKGSKKAVTKTQKKDGKKRRKTRKESYAIYVYKVLKQVHPDTGISSKAMSIMNSFVNDVFERIAGEASRLAHYNKRSTITSREIQTAVRLLLPGELAKHAVSEGTKAVTKYTSAK
->2euz_A mol:protein length:345  NDT80 protein
-GPLGSMNEMENTDPVLQDDLVSKYERELSTEQEEDTPVILTQLNEDGTTSNYFDKRKLKIAPRSTLQFKVGPPFELVRDYCPVVESHTGRTLDLRIIPRIDRGFDHIDEEWVGYKRNYFTLVSTFETANCDLDTFLKSSFDLLVEDSSVEGRLRVQYFAIKIKAKNDDDDTEINLVQHTAKRDKGPQFCPSVCPLVPSPLPKHQTIREASNVRNITKMKKYDSTFYLHRDHVNYEEYGVDSLLFSYPEDSIQKVARYERVQFASSISVKKPSQQNKHFSLHVILGAVVDPDTFHGENPGIPYDELALKNGSKGMFVYLQEMKTPPLIIRGRSPSNYASSQRITVR
->5e18_A mol:protein length:315  DNA-directed RNA polymerase subunit alpha
-MLDSKLKAPVFTVRTQGREYGEFVLEPLERGFGVTLGNPLRRILLSSIPGTAVTSVYIEDVLHEFSTIPGVKEDVVEIILNLKELVVRFLNPSLQTVTLLLKAEGPKEVKARDFLPVADVEIMNPDLHIATLEEGGRLNMEVRVDRGVGYVPAEKHGIKDRINAIPVDAVFSPVRRVAFQVEDTRLGQRTDLDKLTLRIWTDGSVTPLEALNQAVEILREHLTYFSNPQAAAVAAPEEAKEPEAPPEQEEELDLPLEELGLSTRVLHSLKEEGIESVRALLALNLKDLKNIPGIGERSLEEIKEALEKKGFTLKE
->5xru_A mol:protein length:193  adenylate kinase
-MADKIKDAKIIFVVGGPGSGKGTQCEKIVAKYGYTHLSSGDLLRAEVSSGSERGKQLQAIMQKGELVPLDTVLDMIKDAMIAKADVSKGYLIDGYPREVKQGEEFEKKIGKPCLLLYIDAKGETMVKRLMKRGETSGRADDNEETIKKRLDLYYKATEPVIAFYEGRGIVRKIDSELPVDEVFKQVSTAIDAL
->7oiz_l mol:protein length:136  50S ribosomal protein L16
-MLQPKRTKFRKMHKGRNRGLAQGTDVSFGSFGLKAVGRGRLTARQIEAARRAMTRAVKRQGKIWIRVFPDKPITEKPLAVRMGKGKGNVEYWVALIQPGKVLYEMDGVPEELAREAFKLAAAKLPIKTTFVTKTVM
->7l08_4 mol:protein length:103  39S ribosomal protein L36, mitochondrial
-MANLFIRKMVNPLLYLSRHTVKPRALSTFLFGSIRGAAPVAVEPGAAVRSLLSPGLLPHLLPALGFKNKTVLKKRCKDCYLVKRRGRWYVYCKTHPRHKQRQM
->5w5f_O mol:protein length:163  Tail tube protein gp19
-MFVDDVTRAFESGDFARPNLFQVEISYLGQNFTFQCKATALPAGIVEKIPVGFMNRKINVAGDRTFDDWTVTVMNDEAHDARQKFVDWQSIAAGQGNEITGGKPAEYKKSAIVRQYARDAKTVTKEIEIKGLWPTNVGELQLDWDSNNEIQTFEVTLALDYWE
->1cah_A mol:protein length:259  CARBONIC ANHYDRASE II
-SHHWGYGKHNGPEHWHKDFPIAKGERQSPVDIDTHTAKYDPSLKPLSVSYDQATSLRILNNGHAFNVEFDDSQDKAVLKGGPLDGTYRLIQFHFHWGSLDGQGSEHTVDKKKYAAELHLVHWNTKYGDFGKAVQQPDGLAVLGIFLKVGSAKPGLQKVVDVLDSIKTKGKSADFTNFDPRGLLPESLDYWTYPGSLTTPPLLECVTWIVLKEPISVSSEQVLKFRKLNFNGEGEPEELMVDNWRPAQPLKNRQIKASFK
->1rd4_D mol:protein length:191  Integrin alpha-L
-GAMSCIKGNVDLVFLFDGSMSLQPDEFQKILDFMKDVMKKLSNTSYQFAAVQFSTSYKTEFDFSDYVKRKDPDALLKHVKHMLLLTNTFGAINYVATEVFREELGARPDATKVLIIITDGEATDSGNIDAAKDIIRYIIGIGKHFQTKESQETLHKFASKPASEFVKILDTFEKLKDLFTELQKKIYVIEG
->5tg8_A mol:protein length:332  Hemagglutinin HA1 chain
-ADPGDKICLGHHAVANGTKVNTLTERGVEVVNATETVEITGIDKVCTKGKKAVDLGSCGILGTIIGPPQCDLHLEFKADLIIERRNSSDICYPGRFTNEEALRQIIRESGGIDKESMGFRYSGIRTDGATSACKRTVSSFYSEMKWLSSSMNNQVFPQLNQTYRNTRKEPALIVWGVHHSSSLDEQNKLYGTGNKLITVGSSKYQQSFSPSPGARPKVNGQAGRIDFHWMLLDPGDTVTFTFNGAFIAPDRATFLRSNAPSGIEYNGKSLGIQSDAQIDESCEGECFYSGGTINSPLPFQNIDSRAVGKCPRYVKQSSLPLALGMKNVPEKI
->7pi2_E mol:protein length:231  Monoclonal antibody Cy.003 heavy chain
-AVTLDESGGGLQTPGGALSLVCKGSGFFSFSSYTMQWVRQAPGKGLEWVASISSGGGTNYGAAVKGRATISRDNGQSTLRLQLNNLRAEDTGTYYCAKHGVNGCDWSYSVGCVDAWGHGTEVIVSSASTKGPSVFPLAPSSKSTSGGTAALGCLVKDYFPEPVTVSWNSGALTSGVHTFPAVLQSSGLYSLSSVVTVPSSSLGTQTYICNVNHKPSNTKVDKKVEPKSCDK
->7qyd_B mol:protein length:724  Pesticidal crystal protein Cry11Ba
-MQNNNFNTTEINNMINFPMYNGRLEPSLAPALIAVAPIAKYLATALAKWAVKQGFAKLKSEIFPGNTPATMDKVRIEVQTLLDQRLQDDRVKILEGEYKGIIDVSKVFTDYVNQSKFETGTANRLFFDTSNQLISRLPQFEIAGYEGVSISLFTQMCTFHLGLLKDGILAGSDWGFAPADKDALICQFNRFVNEYNTRLMVLYSKEFGRLLAKNLNEALNFRNMCSLYVFPFSEAWSLLRYEGTKLENTLSLWNFVGESINNISPNDWKGALYKLLMGAPNQRLNNVKFNYSYFSDTQATIHRENIHGVLPTYNGGPTITGWIGNGRFSGLSFPCSNELEITKIKQEITYNDKGGNFNSIVPAATRNEILTATVPTSADPFFKTADINWKYFSPGLYSGWNIKFDDTVTLKSRVPSIIPSNILKYDDYYIRAVSACPKGVSLAYNHDFLTLTYNKLEYDAPTTQNIIVGFSPDNTKSFYRSNSHYLSTTDDAYVIPALQFSTVSDRSFLEDTPDQATDGSIKFTDTVLGNEAKYSIRLNTGFNTATRYRLIIRFKAPARLAAGIRVRSQNSGNNKLLGGIPVEGNSGWIDYITDSFTFDDLGITTSSTNAFFSIDSDGVNASQQWYLSKLILVKESSFTTQIPLKPYVIVRCPDTFFVSNNSSSTYEQGYNNNYNQNSSSMYDQGYNNSYNPNSGCTCNQDYNNSYNQNSGCTCNQGYNNNYPK
->2vbj_B mol:protein length:152  DNA ENDONUCLEASE I-CREI
-NTKYNKEFLLYLAGFVDADGSIIAQIEPNQSSKFKHRLKLTFQVTQKTQRRWFLDKLVDEIGVGYVRDSGSVSNYILSEIKPLHNFLTQLQPFLKLKQKQANLVLKIIEQLPSAKESPDKFLEVCTWVDQIAALNDSKTRKTTSETVRAVLD
->6nlj_K mol:protein length:158  Ferroxidase
-MKGDKKVIQHLNKILGNELIAINQYFLHSRMWNDWGLKRLGAHEYHESIDEMKHADKLIERILFLEGLPNLQDLGKLLIGENTQEMLQCDLNLELKATKDLREAIVHCEQVHDYVSRDLLKDILESEEEHIDYLETQLGLIQKVGLENYLQSHMHEDD
->6zh9_FFF mol:protein length:134  Nanobody H11-H4
-QVQLVESGGGLMQAGGSLRLSCAVSGRTFSTAAMGWFRQAPGKEREFVAAIRWSGGSAYYADSVKGRFTISRDKAKNTVYLQMNSLKYEDTAVYYCAQTHYVSYLLSDYATWPYDYWGQGTQVTVSSKHHHHHH
->6yfp_BQ mol:protein length:164  coat protein
-SYTIDINCSTGDTQANLVLTEIPAEPYVHVSGDNKSTIEYLDTGSDNSLLVRPTQQFNCVSSQYPYRNYSKIPRSQQDPLAVRREFYTRRVEYWRKADASNVDAPEYTLPQSCSIRLASTVTKETTAADIAGIVLRTLAPIFPNGSGDWIKLQQLIDGLPRIFG
->3rap_R mol:protein length:167  PROTEIN (G protein RAP2A)
-MREYKVVVLGSGGVGKSALTVQFVTGTFIEKYDPTIEDFYRKEIEVDSSPSVLEILDTAGTEQFASMRDLYIKNGQGFILVYSLVNQQSFQDIKPMRDQIIRVKRYEKVPVILVGNKVDLESEREVSSSEGRALAEEWGCPFMETSAKSKTMVDELFAEIVRQMNYA
->4fk2_A mol:protein length:903  DNA polymerase
-MKEFYLTVEQIGDSIFERYIDSNGRERTREVEYKPSLFAHCPESQATKYFDIYGKPCTRKLFANMRDASQWIKRMEDIGLEALGMDDFKLAYLSDTYNYEIKYDHTKIRVANFDIEVTSPDGFPEPSQAKHPIDAITHYDSIDDRFYVFDLLNSPYGNVEEWSIEIAAKLQEQGGDEVPSEIIDKIIYMPFDNEKELLMEYLNFWQQKTPVILTGWNVESFAIPYVYNRIKNIFGESTAKRLSPHRKTRVKVIENMYGSREIITLFGISVLDYIDLYKKFSFTNQPSYSLDYISEFELNVGKLKYDGPISKLRESNHQRYISYNIIAVYRVLQIDAKRQFINLSLDMGYYAKIQIQSVFSPIKTWDAIIFNSLKEQNKVIPQGRSHPVQPYPGAFVKEPIPNRYKYVMSFDLTSAYPSIIRQVNISPETIAGTFKVAPLHDYINAVAERPSDVYSCSPNGMMYYKDRDGVVPTEITKVFNQRKEHKGYMLAAQRNGEIIKEALHNPNLSVDEPLDVDYRFDFSDEIKEKIKKLSAKSLNEMLFRAQRTEVAGMTAQINRKALINGLAGALGNVWFRYYDLRNATAITTFGQMALQWIERKVNEYLNEVCGTEGEAFVLYGDTDSIYVSADKIIDKVGESKFRDTNHWVDFLDKFARERMEPAIDRGFREMCEYMNNKQHLMFMDREAIAGPPLGSKGIGGFWTGKKRYALNVWDMEGTRYAEPKLKIMGLETQKSSTPKAVQKALKECIRRMLQEGEESLQEYFKEFEKEFRQLNYISIASVSSANNIAKYDVGGFPGPKCPFHIRGILTYNRAIKGNIDAPQVVEGEKVYVLPLREGNPFGDKCIAWPSGTEITDLIKDDVLHWMDYTVLLEKTFIKPLEGFTSAAKLDYEKKASLFDMFDF
->1yja_A mol:protein length:275  SUBTILISIN 8397+1
-AQSVPYGVSQIKAPALHSQGYTGSNVKVAVIDSGIDSSHPDLKVAGGASFVPSETNPFQDNNSHGTHVAGTVAALDNSIGVLGVAPSASLYAVKVLGADGSGQYSWIINGIEWAIANNMDVINMSLGGPSGSAALKAAVDKAVASGVVVVAAAGNEGTSGSSSTVGYPAKYPSVIAVGAVDSSNQRASFSSVGPELDVMAPGVSICSTLPGNKYGAYSGTSMASPHVAGAAALILSKHPNWTNTQVRSSLENTTTYLGDSFYYGKGLINVQAAAQ
diff --git a/src/alphafold3/test_data/miniature_databases/rfam_14_4_clustered_rep_seq__subsampled_1000.fasta b/src/alphafold3/test_data/miniature_databases/rfam_14_4_clustered_rep_seq__subsampled_1000.fasta
deleted file mode 100644
index 633ee10374ab75f3ffed4faa32723683934dde79..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/rfam_14_4_clustered_rep_seq__subsampled_1000.fasta
+++ /dev/null
@@ -1,2000 +0,0 @@
->AY587142.1/1755-1856 Arsenophonus endosymbiont of Aleurodicus dugesii 16S ribosomal RNA gene, partial sequence; tRNA-Glu gene, complete sequence; and 23S ribosomal RNA gene, partial sequence. 
-CTTTAACAATCTGGAACAAGCTGAAAATTGAAACACACATTATTGAAAAATAGTGTGGGGAACTCTCAAAACTCCAAGTTGAAGTGTTATGCAAATAGGCAG
->MTKT01000541.1/46599-46389 Punica granatum cultivar Dabenzi scaffold481, whole genome shotgun sequence. 
-CTCATTACCCTAAAACCACAGGTTTCCGCAAAGTCGTAAGACCATGTATGGGGGCTGACGCTTGCCCTGTGTCGGAAGGTCAAGGAAGTTGATGACCTGATGACGAGGGAGTCGACGATCGAAGCCCCGGTGGACGAAGACTGTAACTATAACAGTCCTAAGGTAGGGAAATTTCTTGTCGGGTAAGTTCCAACCCGCACAAAAGGCGTAA
->ABRO02008320.1/60058-60003 Dipodomys ordii contig_8320, whole genome shotgun sequence. 
-GGAGATATGGCTCAAGTGGTAGAGCACCTGCCTAGAAAGCACGTGGCCTATTGCCA
->MTKT01004810.1/4745052-4744924 Punica granatum cultivar Dabenzi scaffold70, whole genome shotgun sequence. 
-TCGTTTGCAGATGCAGCTTCATCAAGATTCACATGCCGGCCTCTACGTTCGTCAGAGGTACCGTGTTTCTCGGACAGCTATAGTAGGTTCTGGTATTGGGAATCTTGATGATGCTGCATCGGCAAGAGA
->ABRO02033548.1/61663-61950 Dipodomys ordii contig_33548, whole genome shotgun sequence. 
-GTAAGGGCAATCTGGCTACAACATCTGTCACCTCATTGATCACCACGGTTGATCTGGGTATCTGGCCTGCTAGGCAGGTGTCCCCTTCCTCCCTTACCTGTGTGCCCCTCCTGAAGCTGCATGCTTGGTTGAGGACGACCATCCCAGCATCTGATCGAGGAGGACTGGTCTTTAGTCAAGGGTATATGAGTAGCTGTGTTCTGATAGAACCTCCAAACAAGCTCTCAACAGAAGGGACAGGAGGGGAAAACAGAGAGAACACTGCCCATAAAGAAATGTAATCTTTAT
->AUSU01004475.1/2209-2114 Genlisea aurea contig_6775, whole genome shotgun sequence. 
-CTTCTGCGGTGATGAAATTAATTTTCGCATGTCAGACTTCAGAGATTTTTCATTAAATCAATGAGATGAATAACTTCACTTTGACCTGAGCAGAAG
->GL896952.1/11483861-11483692 Mustela putorius furo unplaced genomic scaffold scaffold00055, whole genome shotgun sequence. 
-AGCTTTGCGCAGTGGCAGTATTGTAGCCAATGAGGTTTATCCGAGGCGTGATTATTGCTAATTGAAAACTAGTTCATCATATTGGTCACGTGAGCTTCTCTCATCCAGCCTAGGAAATGTGAGATTTTGAGTGTGAGAGAATGCTGTTACCAGTTTTGCCTGGGAGAAGA
->KQ414408.1/749-926 Termitomyces sp. J132 unplaced genomic scaffold C248965, whole genome shotgun sequence. 
-AACAGGCTGATCGCGGACGAGAGTACACATTGTCTCCGCGGATTGGCACCTCGATGTCGACTCATCCTATCCTCTGGGGGAAGAAGCTTGGAAGGGTTCGGCTGTTCGCCGATTAAAAGGGTACGTGAGTTGGGTTTAATACGACGTGAACTACAAAATTTTAATTAAACCCTTAAAT
->CP000593.1/393484-393597 Ostreococcus lucimarinus CCE9901 chromosome 13, complete sequence. 
-TCTTCCTTAACTCAGCTGGTAGAGTGTCAGACTGTTAGGAAAAAGTCTCCGTCGAATATGACGGCTGCTCCGATAGAGATCTGGAAGCCGCGGGATCGAAACCCGCAGGAAGAG
->JFYO01000008.1/890-1 Microbacterium oleivorans strain RIT293 contigs6, whole genome shotgun sequence. 
-GCGACTGTTTACTAAAAACACAGGTCCGTGCCAAGTCGCAAGACGATGTATACGGACTGACGCCTGCCCGGTGCTGGAAGGTTAAGAGGACCGGTTAGCCGCAAGGCGAAGCTGAGAATTTAAGCCCCAGTAAACGGCGGTGGTAACTATAACCATCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGCGTAACGACTTCCCAACTGTCTCAACCGCGAACTCGGCGAAATTGCATTACGAGTAAAGATGCTCGTTACGCGCAGCAGGACGGAAAGACCCCGTGACCTTTACTATAGCTTTGTATTGGTGTTCGGTGTGGCTTGTGTAGGATAGGTGGGAGACTTTGAAGCGGTGACGCCAGTTACCGTGGAGTCATTGTTGAAATACCACTCTGGTCACTCTGGATATCTAACTTCGAACCGTAATCCGGTTCAGGGACAGTGCATGGTGGGTAGTTTAACTGGGGCGGTTGCCTCCCAAAAAGTAACGGAGGCGCCCAAAGGTTCCCTCAACCTGGTTGGCAATCAGGTGGCGAGTGTAAGTGCACAAGGGAGCTTGACTGTGAGACTGACAGGTCGAGCAGGGACGAAAGTCGGGACTAGTGATCCGGCAGTGGCTTGTGGAAGCGCTGTCGCTCAACGGATAAAAGGTACCTCGGGGATAACAGGCTGATCTTGCCCAAGAGTCCATATCGACGGCATGGTTTGGCACCTCGATGTCGGCTCGTCGCATCCTGGGGCTGGAGTAGGTCCCAAGGGTTGGGCTGTTCGCCCATTAAAGCGGTACGCGAGCTGGGTTTAGAACGTCGTGAGACAGTTCGGTCCCTATCCGCTGCGCGCGTAGGAAATTTGAGAGGATCTGACCCTAGTAC
->FWWT01000006.1/33934-33831 Desulfonispora thiosulfatigenes DSM 11270 genome assembly, contig: Dest_Contig00014 
-ATATTTTATATCGGGAGCTTGAAAAGGCTGAGAGTATGATGTTTTCGTAGACCGATTGAACCTGTTGGGTAATGCCAGCGTAGGGAATGTGATTAAATTATTAC
->AWHE01032144.1/18768-18530 Amborella trichopoda AMTR_V1.0_contig_32144, whole genome shotgun sequence. 
-TAGCGAGTGGTTTGAGTTTTTCATTTATTTTTTAATTCCATGGGAAGTGGTGCATGGCCATTCATAGTTGGTGGGGTGGGGTGATTTGTTGCCTAATTCCATTAATGAATGAGACTTTCAGCCTGCTAACTAGCTTCGTGAGATATCCTCCACAACCAACTGCTTAGACAGAGCGACGAAGTATGGCTGTTTAGGTCAAGAATGTTTGAGGTGAAAACAGGTTTGTGATGCCCTTAGAT
->CP014699.1/1893224-1893021 Streptococcus sp. TA 26, complete genome. 
-AAATGTCTTCAGGGCAGGGTGCAATTCCCGACCGGCGGTGACTTTTCGTTTACTGTTCCAGCTTGATGGCCTGCAGAGTAGTTCTGCAGAGCTGATGCTTAAAAATAAGCAGCAGGAATATGAAGCGAGAAGAAGTCCGCGAGCGCAAGCTGATGCGGTGCAATTCCGCAACCGACAGTAAAGTCTGGATGGGAGAAGACGAAG
->JRRC01354587.1/210-1 Gossypium arboreum cultivar AKA8401 contig_360664_1, whole genome shotgun sequence. 
-CTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTTAAGCGCGCGACCTATACCCGGCCGTCGGGGCAAGAGCTAGGCCCCGATGAGTAGGAGGGCGCGGCGGTCGCCGCAAAACCCGGGGCGCGAGCCCGGGCTGAGCGGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTGAAGGCCGAAGAGGGGAA
->LFZV01000001.1/3925782-3925615 Bacillus sp. FJAT-27916 Scaffold1, whole genome shotgun sequence. 
-TTTTCTGTATAAGCGCCAGAACTAAACCCATGTGGTGGGATTTAGTTGACGAGGTGGAGGTTATCGAAATGTTCGGCGGGAGCCTCCCAGCTTACATGTGCGGGCTGCAACTCTTTTTACCAAAACAGTTTGGCGACAAACTGGACAGAATAAAGAGAGAAGCACATA
->JJRU01049126.1/2855-2468 Picoides pubescens contig49126, whole genome shotgun sequence. 
-TATACTCAGTCCAAAAATTTCTTGCAATGCATTTATAGAAGCTTTCTGATGCAGGTAGTTAAAGACTTGTGGCGGTCAAGTGTTCACAGCGACGTTGCTTTTTGATCCTTCATTGTCAGTTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCTACTAATAGGGAACATGAGCTGGGATTAGACCATCATGAGACAGGTTAGTTCTACCCTACTGATGATGTGTTGTTGCAATAGTAATCCTGCTCAGTATGAGAGGTACCACAGGTTCAGATTCTTGGTACATGCGATTGGCTGAGGAATCATGGATTCATAGAATCAAAAAGGTTGGAAAAGACCTCAAAGATCACACAATCACACAGAATCACAGAATC
->NC_009988.1/26865-27149 Bat coronavirus HKU2, complete genome 
-GCATTTTTTTATTAACATTGGCAAATTTTGCAGATTTGTTTGACATACAATCCCTAGCTTTGCTTGTGGATTTAGTCTCATACACAATGGTAAGCACGTAATTATGCTAGTATGAGTAGAGTATAATTATATTGAGTCCTATAGACCAACGCAGTTAACTACATGTCCGGTGTGGCGGAGTAATCAAAGATCCGCTTGACGAGCCTATATGGAAGAGCCGTCACACCTCGTATGTATGTTGCTGCTAGTAGTTGTTAATTAGTTGATTCTTTGACAGTGATACAC
->GG697144.2/73122-72404 Mitsuokella multacida DSM 20544 genomic scaffold Scfld3, whole genome shotgun sequence. 
-TGAGTAGCGAAACGATCCGTGAGAATCGGATCCACCGAAAGCCTAAGGGATCCTGAGCAACGCTCGTCGTCTCAGGGTAAGTCGGGACCTAAGCCGAGGCATAAAGCATAGGCGATGGACAACAGGCGAAAATTCCTGTACTGCATGATGTTGTTTGAGGATGGAGTGACACAGCAAGGAGCTTGAGCGCGCGATTGGAAATGCGCGTCGAAGGCGGTAGGCTGGTACAGAGGCAAATCCCTGTACTAAGGCCGAGAACTGATAGATAGGAGCGTACTTCGGTACAATCCAAATTCAAGCGTACTACACTGTCGAGAAAAGCTTCTAACGAGACATCATGTACCCGTACCAAAACCGACACAGGTAGGCGGGGAGAGAATCCTAAGGTGCGCGGGAAAACCCTCGTTAAGGAACTCGGCAAAATGCATCCGTAACTTCGGGAGAAGGATGGCCGGAGCTGGTGAAGACCCTTGCGGTTGGAGCTGGAGCCGGCGGCAGAAGAGAAGCCCAAGCGACTGTTTACCACAAACACAGGTGCCTGCTAAAGAGAAATCTGACGGTTANNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNCCCATAGAGCTTGCCAGCCGTGCCGTTCAGAGCGATACCCTGATAGTTGGCAGCAT
->CP000482.1/1312853-1313047 Pelobacter propionicus DSM 2379, complete genome. 
-AATTGAATATCTGATCAAGGTGCCCGAGAGGGCTTGATAGGGAAGAGGGGTGCCGCTCTCAGTAACGAGCCATTCCCCCGCGGACCCGCCGCTGTAAGCGATGACGAAGGGCAGTATGCCACTGGTGAATAACCGGGAAGGCGCCCGGAGGATGACTCGCGAGCCAGAAGACCTGCCTTTTGATTATTGCCACAG
->LL238006.1/6014-5950 Echinostoma caproni strain Egypt genome assembly, scaffold: ECPE_scaffold0004910 
-ATTCTGTCTGTGAGGTCCCCGATCAGGTACATTGCTGATGAGACCCAGACAGGTCGAAACAGTAG
->HF952018.1/1220924-1220795 Thermobrachium celere DSM 8682 genomic scaffold, scaffold33 
-GATGTTGTTAAAGGGGAGTAGCTGCCCATTTTGGGTTGATAAAGTCAACATGCTGGCCTTTGGCCTGGCTTTATCGGACGTTTGTCAAGTGAGACCTTTAACACAATGCTTTGCATTGTGTTAAAGGTCT
->JH472210.1/112-1 Nannochloropsis gaditana CCMP526 unplaced genomic scaffold scaffold1650, whole genome shotgun sequence. 
-GGGTTACTCCATTGCGCTACGCGCTAGTTGATAAAAGTTCGCACCTCTATCAAACTGGGTAACCCCACCTCTTGGCAAGGCCTAATTGTCAGATCAAATCGAAACTACTTCA
->AEYP01109460.1/2187-2427 Mustela putorius furo breed Sable contig109460, whole genome shotgun sequence. 
-AAAAAGACACTGTGTTCGGGGATCATTTCTACAGTTTGTTGCTAGAGAAGTTTTTCTGAACATGTAGAGTACCTCAAACCATGTGGAGGAAGAGGAGTGCTCTCTTGTGAGCCTGAAGCTGGATTTAGGTGTTCTTTCCAAACAGCCAATTATGGGTGCCTGGGTTGCTCAGTTTGTTAAACAACTGCCTTTGGCTCAGGTCATGATACTGGAGTCCTGAGATCAAGTCCCACATCAGAGT
->ADNJ02000004.1/3715450-3715582 Metarhizium robertsii ARSEF 23 MAA_Scf_4, whole genome shotgun sequence. 
-GACAGAGTGCCCGAGTGGTTAAGGGGAGTGACTTGAAGCGCTAGGCCTGGAGTGCGAGAAATCGTATGAAGAACCGCCTAGCAATAGATATCACTTGGTTTCGGCCTCGCAGGTTCGAATCCTGTCTCTGTCG
->CCCW010014085.1/4006-862 Brassica napus, WGS project CCCW01000000 data, contig: 30103 
-TATTTTTAATTCTGGTCGAACCAACTCCAAAATGGTCGAGCTGAATTTTTCTCGACCAAAATTTTATCTGCTCGTGAGGGTTATTACAGTCTACGAGTCGGGTTGTTTGGGAATGCAGCCCCAATCGGGCGGTAAATTCCATCCAAGGCTAAATATGGGCGAGAGACCGATAGCGAACAAGTACCGCGAGGTAAAGATGAAAAGGACTTTGAAAAGAGAGTCAAAGAGTGCTTGAAATTGTCGGGAGGGAAGCGGAAGTGGGCTTGCGATGCATCCCGGTCGGATGCAGAATGGAGCAATCCTGTCTGCCGATCGATTCAGGGCGTGGACCGACGCGGATTAAGGTGGTGACCTAAGCCCGGCTTTTGTTACGCCGCTACCTTAATCATTGTCTGCGGCACGAGCCTCACGGCATTCCTTGGCATCTGCGTGCTCAGGGCGTCGGCCTGTGGGCTCCCCATTCGACCCCTCTTGAAACACGGACCAAGGAGTCTGACATGTGTGCGAGTCAACGGGTGAGTAAACCCATAAGGCGCAAGGAAGCTGATTGGCTGGATCCCTCACGGGTGCACAGCCGACCGACCTTGATCTTCTGTGAAGGGTTCGAGTGTGAGCATGCCTGTCGGGACCCGAAAGATTGTGAACTATGCCTGAGTGGGGCGAAGCCAGAGGAAACTCTAGTGGAGGCCCGCAGCGATACTAACGTGCAAATCGTTCGTCTGACTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGGTGGTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGAGCTCGGAAACGAGTTCTATCGGGTAAAGCCAATGATTAGAGGCATCGGGGACGCAACGTCCTCGACCTATTCTCAAACTTTAAATAGGTAGGACAGGTGGCTGCTTTGTTGAGCCATCCCACGGAATCGAGAGCTCCAAGTGGGCCATTTTTGGTATGCAGAACTGGCGATACGGGATGAACAAGAAGCCGGGTTACAGTGCCCAACTGCGCTAACCTAGAACCCTCAAAGGGTGTTGGTCGATTAAGATAGCAGGACGGTGGTCATGGAAGTCGAAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTAAAGCACGCGACCTATAACCGGCCGTCGGGCAAGAGCCATGCCTCGATGAGTTGGAGGACGCGGCGGTCGCTGCAAAAACTAGGGCGCGAGCCCGGGCAGAGCGGTCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGGGAACTTGGAAGGCCGAAGAGGGGAAAGGTTCCATGTGAATGGCACTTTCACATGGGTTAGTCGATCCTAAGAGTCGGGGGAAACCCATCTGATAGCGCTTATGCACGAACTTCGAAAGGGGATCCAGTTAAAATTCCTGAACCGGGACGTGGCGGTTGACGGCAACGTTAGGGAGTCCAGAGACGTCAGCGGGAATTCCGGAAAGAGTTATCATTTCTGTTTAACAGCCTGCCCACCCTGGAAACGGCTCAGGCAAAGGTAGGGTCAAGTGGCTGGAAGAGCACCGCACATCGTGTGGTGTCCGGTGCATTCCCGGCGGCCCTTGAAAACCTGGAGGACCGAGTGCCGCTCACGCCCGGTCGTACTCATAACCACATCAGGTCTCCAAGGTGAACAGCCTCTGGTCAATGGAACAATGTAGGCAAGGGAAGTCACAAAATAGATCCATAACTTTGGGAAAAGGATTGGCTCTGAGGGCTGGGATCGGGGGTCCCAGTTCCGAACCCGTCGACTGTTGGCGGGCTACTTGAGCTGCTAACATGGCGAGAGCGGACCGCCTTGTGTCGGCCGGGGGACGGACTGGGAACGGCTCTTTCGGGAGCTTTCCCCAGGCGTCAAACAGCAAACTCAGAACCGGTACGGACAAGGAGAATCCGACTATTTAATTAAAACAAAGCACTGCGATGGTCCATGCGGATGCTAATGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGGTAAACGGCAGGAGTAACTATGACTCTCTTAAGGTAACCAAATGCCTCGTCATCTAATTAGTGACGTGCATGAATGGATTAACGAGATTCCCACTGTGCATGTCTACTATCCTGCGAAACTACAGCCAAGGGAACGGGCTTGGCAGAATCAGCGGGAAAAGAAGACCCTATTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTGAGAGGTGTAGAATAAGTGGGAGCTCCGGCGGGGTAACAACCCCTTCTTTTAGACCCAAGACTCGCTTTGGCGTGTCGATCCAGGTGGAGGACATTATCAGGTCGGGAGTTTGGCTGGGGCGGCACATTTGTTAAAAGATAACGCAGGTTTCCTAAGATAAGCTCGACGAGAACAGAAATCTCGTGTGGAACAAAAGGGTAAAAGCTCGTTTGATTCTGATTTTCAGTACGAATATGAACCGTGAAAGCGTGGCCTATCGAACCTTTAGACCTTTGGAATTTGAATCTAGAGGTGTCAAAAAAGTTACCACAGGGATAACTGGCTAGTGGCAGCCAAACGTTCATAGTGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAATGTTGGATTGTTCACCCACCAATAGGGAACGTGAGCTGGGTTTAGACAGTCGTGAGACAGGTTAGTTTTACCCTACTGATGCCGGCGTCGCAATAGTAATTCAACCTAGTACAAGAGGAACCGTTGATTCGCACAATTGGTCATCGCGCTTGGTTGAAAAGCCAGTGGCGCGAAGCTACCGTGCGCTGGATTATGACTGAACGCCTCTAAGTCAGAATCCGAGCTAGAAGGGACGCATGCGCCTGCCGCCCGATTACCGACCCTCAGTAAGAGCTTCGGCTCCCAAAGGAACGTGTCATTGGCTAAGTCCGTTCGGCAGAAGCGTCCTTTGGACCGCCTTGAATTATAATTACCACCGAGTGGCGGGTAGAATCCTTTGCAGACGACTTAAATACGCGACGGGGTATTGTAAGTGGCAGAGTGGCCTTGCTGCCACGATCCACTGAGATTAAGCCCTTTGTCGCTAAGATTCGA
->CM001407.1/48474749-48475301 Lepisosteus oculatus linkage group LG4, whole genome shotgun sequence. 
-AAACAACAACAACTTATCTCTTAATTTTTTTCAATCCCTCTCTTACTCAATGAAGTGGCAGAATGACCTCAGAGCAGGCTCATGTTACTGGCATCAGGTAGCCAGCACCTGCCAGCCACAACCTGCTCCAGGAACAGTGGTAGGTAGGAGATTTGACCGAGGAAGTACTATACCCATTAAAACATTATCGCAAGTATCCTAAAGTGAGGTCAAGGAGCACAGAAACCTCCTGTGGAGCAAAAGGCCACTATCTTAGCTTATGAAAACTCATTATGAATATAGATATTGAAAGTGGCAATCCTTTTGGCTTTTGGAAATTTAAGTAGAAAGTGTCAAAAAGTTACCACAGGTATACTGTAACTAGCTTTTGGAAGCCAAGCATTCGTAGAAGCATTACATTTTGATCCTTCAATGTCGGGTGTTTGAATTATTCTTCAACAAGACTTCACCTTCCGTTCAAACATTGGCTTGTTCAACCGCTAATAGGGGGAGTGATCTGTGCTGAGACTGTTGCAAGGCAAACAGGAGTTGAGCATGGGTCAGTTGGTATTAC
->JQCA01000072.1/4381-4571 Lactobacillus paucivorans strain DSM 22467 NODE_100, whole genome shotgun sequence. 
-TTGGTTCTAAGGTGTACGCGTTGTCTCACTACAAGTTGCCGAACAAGTAATTTATATATGGGAATGTTCTATGGTGGAGAAGATGGCAGGCCTTTTCACTTGGAAGTCAGACACTCCAACAGACATTCCCCCCTGCATTGTCATCGCGGGTCAACATGACTGGACAATTAACGGCACCACTTAGATCAACC
->KB018237.1/393050-393252 Camelus ferus unplaced genomic scaffold scaffold2244, whole genome shotgun sequence. 
-ATCGCTTCTTGGCCTTTTGGCTAAGATGAAGTGTAGTATCTGTTCTTATCAGTCAGGGCACCAGCAGATTCGGTGTCTGGTGAGAGCCCACATCCCGGTTCATAGACCTTCCAGCTGTAAGCTCACTTGGCGAGAAGGACCGGGGTTTTCTCTGATCTCTTTTATAAGAGCACTCATCCCATTCATGATGGCTCTGCCCCACC
->APMT01104059.1/10100-10194 Mesocricetus auratus contig104059, whole genome shotgun sequence. 
-GATTGTATGCTGGCACTCCCCCGATCCATTGGAATGATACAGAGAAGATTAGCATGGCCCCTGCACCTACATATTGTAGGGTACCACCTATGTTT
->URS0001A24371_12908/1-89 unclassified sequences L2-Alphaproteobacteria ribosomal protein leader 
-GGGGACCUUCGGGGCCCUAUACCAACGGUGGGCUUCACCCACCCUACAUAAGACGGGGAGACCCGUCUAAGCUAAACGGAAGACAGAAA
->LN907827.1/31808-32053 Erwinia sp. EM595 isolate E_g_EM595 genome assembly, chromosome: 1 
-TATTCACAGCGTCAGGTAGACGAGCTTCCTCAGGAAGCGCTCAGGGATAGCCCGGAAGGCAGCAGAGCAGGGAAAAAGGATGGGGTCTGAAGGAGAGACCGTCAGGGATAAGGAAGCGCTCGGGATGAGTGGACAGCAGACGGGATAAACCGGGATGTTGATTGCATAAAGGGATGTAAAGGATGACTGTCCTTCTACGGAAGGTACGAAAAAAGGCGACAGATTGCTCTGTCGCCTTTTTTCTTT
->FR872580.1/1712617-1713059 Parachlamydia acanthamoebae UV-7, complete genome 
-GGGGGTGTCACGGTTTCGACTGAGAAGTCAAGTATTGATTGCATGCGGAGGATGTCGGTTGGCCTCCTAAAAAAGCCGATAAAACAATAAATGCTAACACAAATAGCAAACTAATTAGTGGTGTTGATTTTGCCGCTGCTGTAGAAGCTGATTCAGTTTCTTACGCTGCTGCTGCTTAACCTGACTAATTGGTCGCTGTATAAAGCCTAACAGCTTTATCAGCACAGCAGTCTGAGACTGGACCAAGGGTCGAGGAGTCTGCTGTCATTGACTTGGTACGGAATAAAGTCCGCCGCTTCTAGGGTTTTATTCTAAGATAAATGAAGCAAGTTAATCATAGTGTGGTGGCTGCAATGTGATTGACTTATTTTCAGCACACTAAGCATGTAGATATTAATATGTAGATTTGCCCAGGACGAGAGTTCAATTCTCTCCACCTCCAA
->JH835313.1/5567540-5567270 Erinaceus europaeus unplaced genomic scaffold scaffold00025, whole genome shotgun sequence 
-GGATATGAGGGTGATCTGGCTGCGACATCTGTCATCCATTGATTCAGCTGATCTGGTTGGCTAGGCGAGTGTTCTCTTCCTCCCTCATTGCTCCATGTGAGTCCCTGCCGATGGCCTTTCCCAAATAGAGAAGGGCGGGCGAGTCTTCAGTTGAGGGTATAGGAATAGCTGCGCTCCCCTGCTAGGACCTCCAAGCAAGCTCTCAAGAGTCATCTTCAACCTTAAGGTCAGCTAGACTTTTTATGTTCTCCTTGTAGATCACCATTTTACA
->CM007648.1/27503544-27503238 Zea mays cultivar B73 chromosome 2, whole genome shotgun sequence. 
-CATTGGTGAGAATCCAATGCCCCGAAAACCCAAGGTTTCCTCCGCAAGGTTCGTCCACGGAGGGTGAGTCAGGGCCTAAGATCAGGCCGAAAGGCGTAGTCGATGGACAACAGGTCAATATTCCTGTACTACCCCTTGTTGGTACGGAGGGACAGAGGAGGCTAGGTTAGCCGAAAGATGGGGCTAGTTTGATAACTCCATTTTCTCAAGAAAAATGAACTAATTGTTCCTGGGGAAAATGAAAATCCTTTACATCACGTTTGGATCATTGGAATCGAATTTCATTCTAATAATAGTAATTTAGGCG
->CCCW010011448.1/3522-244 Brassica napus, WGS project CCCW01000000 data, contig: 32740 
-CATGGTCGGATTTTGATGTTCTAGTGTGTTTTGTTGGAAACTGTTTATGAGAATCTCTTATTTGGGAGTTATCAGAGATTATCATGAATTTTAATTAGTTTTTGGGAATTTATTTGAGTATGTTGGTTTGGACAGGTTATAGATTCTAAGTAGCCGAACCATGCTTATCTAGACTTGATGTTAGGATATCGGCCTTATGAATGTGCATTGTGTCTTGTGTGGTTTCAGGATCGGACATGGACCGTGGTAAGGGAAAGGCACCGTGAAGACTCAGGCCATGAGAAGATGTGTGGTGAATGGGTCATTGTAGATAGATGTGACATACTGATAGCCTATTGTGCAACTTGTGAACTTATGTTTGACTAAGTGTGTATAACTTATTAGGACGAACCTAAGAATGATGTATGAATCTCAGTTTATATTTATACAATTGATTTGCCCCTTATGTTTCCTTGTTTAGATTTTTTGTATTGAACCTCAGTTGAATTGAATTGAATTTACAAAGATAAGAATTAAAACTTGGTTCACTCGGACTTAGATTGAAAGGATAAGGCCGCAGATCAGTTTGAGCAGCCACAAATTTCCTGTGTGTGCTGACGGACACACACGGACGTCCTGTGTTTGCTGACGGACACCCACGGACGTCCTGTGTGTACTGAACAAACAGCCCACGGGACATCACATACAACCCTTGGTAACTAGTGACCTTTGGCCACTCGTGCCTCTTGGGACATGACCAACCGTTTAGCCCAACAGCCCAGTCTATGGTGCAATTCGAACCGACCATCTAACCGACCAGCATCTAGGTTAGCGGTTTGGTTATGACCGGCCAAGTCTAGGGACGTGTTCCTTGGACTGAACCAACACAACCCTTCGTTTATAATCAGAAAGAAGAGAAAGGGCCGGATAGAAACAAGAAGAGGAGAAGCGGTTAGGTCTAATGGACCGACCAGAGCCGCGGTGCGATCACAAGGACCGTCCGTTCGGTCTGATGGAGCCATAGGCCACCACGTACGTTCTGAACCGTGTCAGGTTTCTCCATGCTCTTCTCCTGCTCTCGGTCTCCCATACTTGATCAGAGGTTGCTTCACAAACGATCAGATCGCCGGAAACCTAACCACCACACAATCGGCCTTGCTTTGGCCGGAAACTCTCTCTTTCTTTCTTTCTCTCTCTCTATGATTTTTCTGAGTATTTTACTCTGGAATTGGATGATTGAAATTGACATAGAGGACCCCATATTTAGAGAAAATTAGGGGGTAAGTCTTGCCCAAAGAACAGGCATGACTGGCAAACGGATGGGCACAATCGGCCAAGGGTTACACCCTCTCGGCCGCATACGTCCCTTCGCCAATACCACATGGGATTGGGTCGGATAGAGGGCCACGGCCTTGTCCCAAGCCCCAACGGTCCATGGCCTCATGGCCGGACCCCCATGTCCCGCCACCAGCCCGGACCCGGGCCATCGGACCGAAACCCGAACAGTCCGTCCAGCTGAGTTTAGCTGACTCCCAGCTGTCTCAGCTGAGTGGGCTAGTAGTTCAGCTAGTGGAGCTGACTTAGTAGTGGCCGAGCTGGAGTGAGCTTAACCTAACTCCGTTGAGCTGGTCGAGCTACTTGTTCCATCCGTCCAGCTACCGTCTTACTCGTCCTAGCTGACTCTCGACTTGTATAAGATTAAGTCTAAGTTTCCTTACGTCCTTAACCTTCTTATCTGGCCATGGAACACTTGTCTTGATGTCCTAAGACTAACTAGTACGTTTCCTCGAAACATGGCCGTCCCAATGATCCTATTCAGGATCCGGGATGTTACAACGTCGGCGGGAATTTCGGAAAGAGTTATCTTTTCTGTTTAACAGCCTGCCCACCCTGGAAACGGCTCAGCCGGAGGTAGGGTCCAGCGGCTGGAAGAGCACCGCACGTCGCCTGGTGTCCGGTGCATTCCCAGCGGCCCCTGAAAATCTGGAGGACCGACTGCTGCTCACGCCCGTTCGTACTCATAACCACATCAGGTCTCCAAGGTGAACAGCCTCTGGTCGATGGAACAATGTAGGCAAGGGAAGTCGGCAAAATGGATCCGTAACTTTGGGAAAAGGATTGGCTCTGAGGGCTGGGCTCGGGGGTCCCAGTTCCGAACCCGTCGACTGTTAGTGGGCTGCTTGAGCTGCTAACTTGGCGAGAGCGGACCGCCTCGTGTCGGCCGGGTGATGGACTGGGAACGGCTCTTTTGGGATCTTTCCCCGGGCGACGAACAGCCAACTCATATTTGGTACGGATAAGGGGAATCCGTCTGTTTTATTAAAACAAAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGATGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTGTCTACTATCCAGCGAAACCACAGCCAAGGGAACGGGCTTGGAAAAATCAGCGGGGAAAGAAGACCACTAATTTTAACGTTATTTTACTTACTCCGTGAATCGGAGGCGGGGTAACAACCCCTCCTTTTAGACCCAAGACTCGCTTCGGCGGGTCGATCCGGGCGGAGGACATTGTCAGGTGGGGAGTTTTTCTGGGGCGGCACATCTGTTAAAAGATAACGCAGGTGTCTTAAGATAAGCTCAACGAGAACAGAAATCTCGTGTGGAACAAAAGGGTAAAAGCTCGTTTGATTCTGATTTTCAGTACGAATACGAACCGTGAAAGCGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTTGATGTCGGCTCTTCCTATCATTATGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCCACCAATAGGGAACGTGAGCTTGGTTTAGACCATCGTGAGACAGGTTAGTTTTACCCTACTGATGCCCGCGTCGCAATAGTAATTCAACCTAGTACGAGAGGAACTGTTGATTCGCACAATTCGTCATCGCGCTTGGTTGAAAAGCCAGTGGCGCGAAGCTACCGTGCGCTGGATTATGACTGAACGCCTCTAAGTCAGAATCAGGGCTAAAAGCAACGCATGCGCCCGCCGCCCGATTGCCGACCCTCAGTAGGAGCTTCGGCTCCCAAAGGCACGTGTCGTTGGCTAAGTCCGTTCGGCGAAAGCGCTGTTCGGACAGCCTTGAATTATAATTACCACCGAGCGGCGGGTAGAATCCTTTGCAGATGACTTAAATACGCGACAGGGTATTGTAAGTGGCAGAGTGGCCTTGCTGTCACGATCCACTGAGATTCAGCCCTTTGTCACTAAGATTCGA
->MJHW01000006.1/498708-498411 Roseburia sp. 831b contig000006, whole genome shotgun sequence. 
-GTAAACACGAGGAAAAAGAGAGTACATCCCTTAGAACTTTACAGAGAAGTTTTTGAATGAGATGCATCCGCATACATTCGCTGAGAGAAAACGGGCAAAGAGAGATGGAAGATGGCTTTGGAGTGGCAGAGCTGAACGAAAAGCACTACATTTACAAACGTAGTTGAATTTCGATAAGTTTTGACAGGACCGCCTGTTATAGCGGTAGAACGTAACAACAAATGTTGCGTCAATGAGGCTTTCTCTGCAAAGAGAAGGTAAAGAGAAGTGGTACCACGGGTAGCAGCTCGTCTTCTGG
->JH835659.1/1480072-1479972 Erinaceus europaeus unplaced genomic scaffold scaffold00371, whole genome shotgun sequence 
-AAAAAGCATTATCCAGCTTCCTTCCTACTCTGTCTCCAATATCTTTTTTGAACAAAAAAGATATTGGAGACAGAGTAGGAAGGAAGCTGGATAATGCCCAT
->MHBM01000110.1/8313-8490 Lentisphaerae bacterium RIFOXYA12_FULL_48_11 rifixya3_full_scaffold_2456, whole genome shotgun sequence. 
-AATACCCTGCCTTGTTCGCAAACAGGCTGACGTCTCTGGCCCATTAATTGTAAGTTAGGGAGTTTGAATACGGCGGCAACTGAACGCCCTTTACTGGGACTCAGGAACCGACGGATAAAGCACCCACCTCGATTTCGAGGATCAGAGATAAATGCCTCTACGACAAAGTGGGGTATTT
->CM000379.2/41198104-41197644 Equus caballus chromosome 3, whole genome shotgun sequence. 
-AACAAAAATGTCACGTTTAGTTACTTAATTTGACTCAACACAGGAGACCTCGCTTGGCCTGGCATGGACAAGACTGACAGGTTGATAGCTCTTTCTCTGTTCCATAGGTGGTAGAGTGTGGCCATTCTTAGTTGGTAGAGCCATTTGTCGGGCTAGTTCTGATAACAAACAAGACTCAGGCATGCTAACTAGTTATGGAACCTCCAAGCAGTGGTATCCTCCAACTTCTCAGAGGGACAAGTGCTGTTCAGCCACCCAAGGTTTAAGCAAATAACAGGTCTGGGCTGCCCTTAGATGTCCCGGTTTGCAGGCACTACACTAACTGGCTGAGTGTGGCCTATCCTGAGAATGCAGCTTCAGGTAACCCTTTGAACCCCATTCATGATGGGAATCTGGGATTACAATTATTCCCAAAGAACACAGAATTTCCATTAAGGGCCATAAGCTTGTGTTGATTGGTT
->CM000028.3/22112491-22112645 Canis lupus familiaris chromosome 28, whole genome shotgun sequence. 
-AGCTTTGTGCAGTGGCAGTATCGTAGCCAATGAGGTTTATCCGAGGCGCGATTATTGCTAATTGAAAAGTGAGTGCTGGCCAGGAGAACAGGTGCATGCAGATGCTCAGCAAACTTTCATTGAGCACCTATTGTGCATCACCTTCTGTTTTAGGT
->JH594435.1/493167-492948 Eubacterium infirmum F0142 genomic scaffold supercont1.1, whole genome shotgun sequence. 
-GAATAATAATATCATATTAATCCAGAGGAACGCATATTAGAGAGAACAGGCGCGGAACCCTGTATCGAGTGCCCTTCTTTGCAGATTCATATCAGCAGAGAAACTGTATTGTGGAGTTTTACTTATATGCCATTGGAACGAGGGACAAATTCTTCTTCCGAGAAGGCAAGTAAGACGGTGAAGCATAGCCAGGAGACTTATTAATGAGATATACACCTGA
->LL810796.1/383-1371 Gongylonema pulchrum genome assembly, scaffold: GPUH_scaffold0038229 
-CTGTCGCATTTACGATGAAGTTATTGCACGGTAATAAAGAAATTACGCAGCAAATTACCGTAATTACAGTTAAGTGTCATAAAACCAATATAATGAACTATCCCAGTTACTATAATGATTTGCGTGTAATTTGAATTACTGTAATATTTGGTACCGTAGCATATGTTATTACTGGAATATATTACTGTAACGTAGGGCTACTGTAGTATGTATTAGTTTTTGGCATTCGATTACCGTTTGCCTCAGATCGCAGCCTAGAGTGGGTGGTAAACCTCATCTAAGGCTAAATACGGCCACGAGACAGATAGCAAACAAGTACCGTGAGGGAAAGAACTTTGAAGAAAGAGTTCAAAAAGGCGTGAAACTTTTTTTGCAGTAATGATAGTTTTCAGCAATTTTTCTTAGTTATAATTGAAAAAACAATTGAAATTTCGGCGTTCTCTTCAGGAGTAACTTAGCATTACTACATGTCTGCGATTTGTTACGATGCTCATCCACGACGGTACAGTGGTCTGATCACATCCCACTACTCCTACATATTGCTGTCCTGGGGCTGGATTCATTGCNNNNNNNNNNNNNNNNNNNNTTAGCGTTACTACATGTCTGCGATTTGTTACGATGCTCATCCACGGCGGTACAGTGGTCTGATCACATCCCACTACTCCTACATATTGCTGTCCTGGGGCTGGATTCATTGCGACCCACGATTTGCCGGCACGCTCGGCAGCTTCTCATCAATATTGTTCTTCTTCAAGCCGGTGAAGCAGTAGCCGCCTCACAGCTTTCCAATATTTTATTGAGCAATCAGGTTTGTCTTCGAGTTTTTTATGTTCGAGGTTTTTTCTAAGATCAGATTTTTGAGGTTTTTTTTTTTTTAAAAAACAGTACCTGCGATTTCTAATTTGCGCTTCCCGCGATCCTGGTTTTTTTTTCCAGTTAAAAAGTACCTTTTCACCCATTTCGGCCCTTTTTGGACCGGCCGTTTTTGG
->ALYE01010731.1/119708-119256 Gossypium raimondii Chr08_contig_1147, whole genome shotgun sequence. 
-GTCCTTATACACTGGCAACAATGTCAATGCCAATCGAGTTAATACTCAATCAGCAAAATAGCACAAAATTTCATTAATTTATTTTATGAATAGTTTAGGAACGTGGATACAAGTGGTGCATGGCTATCGTCAGCTCGTGCTGGAAGGTGTTCGGTTAAGTCCCGCAATGAGTGCAACCTTCGTGTTTAGTTGCCACCGTTGAGTTTGGAACCCTGAGTAGATTGCCGATGATAAATTGGAGGAAGGTGAGGATCAAGTCAAGTCATCATACCCCTTATGCCCTGGGTGATACACTTGCTACAATGGACAAGTCAAAGGGTCACGACCCTGCAAGAGTGGGCTAACTCCAAAAACTTACCCTCAATTCGGATTGCAAGCTACAACTCGCCTACATGAAGCTGAAATTGTTAATAATCGCCGATCAACCATACGACGGTGAATTCGTTCCTGGGC
->JOOK01005830.1/289-4 Oesophagostomum dentatum strain OD-Hann O_dentatum-1.0_Cont11200.2, whole genome shotgun sequence. 
-AAAGCGGATACAGGCGCAAAAGAATAATAGAATAATAGATACATAGCAGGAGATAACTGCGGCAATTCCGGAGCTAATATATGTGAATAAACCCTGATTTTCGAAAGGGTGCAATTATGAGAGCAAAACAATCATCTTCGGATGTAGTTTGCTGACTCTAAATAACGCTGCATATCGTCGGCTTGTCCAACGATATTCCGAAAAAGTGTCTGCCCTATCAATCTGATGGTAGTCTACCAGTCTACTATAGTTATTACGGGTAACCGAGAATAAGGGCTCGGTTCCA
->KB016774.1/3281454-3281537 Camelus ferus unplaced genomic scaffold scaffold490, whole genome shotgun sequence. 
-TGGAGTGGGGGGGCAGGAGGGGCTCAGGGAGAAAGTGTGTGCAGCCCCTGGCCCTCTCTGCCCTTCCGTCCCCCGTTCCTAGAC
->CP013118.1/3064815-3064903 Salinivirga cyanobacteriivorans strain L21-Spi-D4 chromosome, complete genome. 
-TGAGAACCGTAGCGAAGCGGAGCTCATGACCGTAGAGAATAACTCAGCCGAAGCCATAGTATCCCGATACTTCTAATTAGGAGAAGGGC
->FXAH01000012.1/80855-80720 Paraburkholderia caryophylli strain Ballard 720 genome assembly, contig: Ga0139045_112 
-ATGAGTTCCCGTTTATTCCGTTTCCGCTGCAGTTGCGCCTTTCGACCGAACACGCCTTTCTTTCGTTCGCCGGGCGCAGCGCTTCGCTCGAAGCCGAGCCGCCAGCTCCGATGCACGAGGAGCGGCGGCTTTTTTA
->LZPO01018772.1/1933-2618 Neotoma lepida isolate 417 scaffold_18136, whole genome shotgun sequence. 
-CTATGACCCTGAGATTAAGAGTCTCATGCTCTACAGACTGAACTAGCCAAGACTGTGGCAGCCAAACATTCATAGTGACATAACTTTTTGATCCTTAAATGTTGGCTCTTCTTATGATTGTGAGGCTGAATTTACCAGGCAGTGGATTGTTCATCCACTAATAAGAATGTGAGCTGAGTTTAGATTGTCATGAGACAGATTAGTTTTTCCCTACTGATGATGATGTATTGTTGCCATCATAATACTGCTCAGTACAAGAGGAACCACAGGCTCAGACATTTGGTGTATGTGCTTGGCTGAGGAGCCAATAGTGTGAAGCTACCATCTGTGGGATTATGACTGAATGCCTGTAAGTCAGAATTCTGGCAGAACAATATGGCAGTGCCAAAGGAGCCTCGGTTGGCCCCAGATAGCCAGATCCCCTTCCAGCTCCATTGGCAGTCTGTCCTGTTCTCGCACATGGCGGGTCCCCACAGTGTGTTGGGACCAGAGTCTGGTATGGACAGCCATTCATACAGAGAAACAGGGTATGGCTGAAAAGGGTGCTGCCCTCTCACCCATCACATTGAACACACATTTGTGTGGAACCTGGTGCTAAACCATCCATAGATGACCTATTTCAATGGTTATAAGTTGTAATAGGGTTGTTGGTGGAACAATGAAGTCTAGACTCAGGATCCTCTTTT
->HF986408.1/139458-139379 Blautia hydrogenotrophica CAG:147 genomic scaffold, scf339 
-ACAGGTATGAGCACGCAGGCATATGCGCCGGAGTGCGAATGCCTGTCGGGATTGCGGGAGTGCGATGCACGGGGCAATCC
->LBYD01000004.1/63542-63156 Parcubacteria (Moranbacteria) bacterium GW2011_GWC2_40_12 UT79_C0004, whole genome shotgun sequence. 
-GGGGATGCTAGGCATCGACAATTTGTTCTCTCAAAATACGCAAGCCGAGCATGACATTAGACTCGTAAAACCTTGTGTCAACGATCATAAGTGCAAACTTATTTTCAAAGGTTAAGCAAGCTTTTCAGCCTGCTTACGCCGTTGTTCCTGCCTAATTCGCGGGGACCATCAGCCTGCTGATGCCTAATAAGCAACCGCTGGTGTCATACATTGGGCTTGATTGATAGTTTTTCTCTGCGGCTATCTCTGACCATTGAGCAAAGAGGACTTTTCAAGGTTTTGTTTACTTTATACTTGAAAAGTTTCTCAAAACAAGTAAACTAAGCTTGTAGAATATTTTGGAAGATATAAATTTGGACATGGGTTCGAGTCCCATCATCTCCACCA
->CP013023.1/5009948-5010143 Paenibacillus bovis strain BD3526, complete genome. 
-CGATGAGGTAGAGGTCGCAGCATGAATCAGTACAACCGGAGCAGGCGTAGAGCCGCCGCGAATCCCGGTTGAAAAGGTCCTGCTGCCGAAGTGCAGATTCCGCTCTGGGAATCCTGTGCTGGGGCTGTACCCGAAAGGGACAGAACTGTCACAATGAAAAAATCCAAGCATTTCATTGTGTTGAGCTATCTTAAAG
->AFEY01018855.1/2775-2892 Sarcophilus harrisii ctg7180001412063, whole genome shotgun sequence. 
-GGATGTGAGGGCTATCTGGCTGCGATATCTGTCACCCCATTGATCGCCAGGATTGATTCGGCTGATCTGGCTGGCTAGGCGGGTGTCCCCTTCCTCCCTCACCGCTCCATGTGCGTCC
->CM000246.2/64301032-64300896 Rattus norvegicus chromosome 16, whole genome shotgun sequence. 
-TATACAAGCAGCTACTCTCTCCCTCTGGAAAGTCCAGTCAAGATTTCAGGGCCATTGCAGGAGAGTGTAGGGCAGTCAGGCGTCTAGAACTGTAGGTCCATCCAAAGGAGGTGCTTCATGGTGGTCAGCCCTTGTTT
->LPNL01000017.1/7001-6356 Hanseniaspora opuntiae strain AWRI3578 Hanseniaspora_opuntiae_AWRI3578_scaffold228, whole genome shotgun sequence. 
-TGCCAGAAGATTCGGTTAGACGATAAAAGCAAAGTTTAATTCAGAGTTTAAAACAGCTGTAGGCAATAAATTATACTTGAATGAATATTAAATAAGAGGTAAAATTCTAAGACTTTAATTAGCATTCCAAATAGTATAATGCTGAGAGCTAAAGCCATTACTTAAGGACTAGGATTAGAGACCCTACTACTGATGGTACTATCTATGATAATTATAGTAAACGAAAGTCAAGAATTATCTACTCGAAGATTAAGCCTTAACGGGTGAAAATCAAAGTTGAAGAGCGTTATATCATCAATTGAGTGGATCGTGCTGTTTAATTTGACAACCCCCAATAAACCTTACCTAATCTTGTATAATACAGGTGTTACATTATCGTCTTTAGGCATTATTGTGAAATTATTGCTGCAGGAGCTATTACTTATGGCCCCGTGACTGATCTACATGACTCTAACGATTAGGGCTACAGGCGCGATATCAAGAATTGAATTATGAAACTCTAATTCATGAATAAATAATCAGAAGTAATATGGTGTTAGAATTACCATATGAATATCAAAGATATAAGCTACTAATTGCCCATCAATCTCCTAGTGAGATAAGTTGACACAAAGTTACGCTAGATGAATTTGGCGTGGGAAATTAA
->LMAW01002579.1/3015099-3014999 Amazona aestiva scaffold_41, whole genome shotgun sequence. 
-TGCTATGATGATGTAATTTGCATCTTATCCAGTGCTCAGCGACAGTTGCCTGCTGTCAGCATGCTGGCACTGCTGAGCTGAAGACCCCTTCGTTCTGAGCA
->GL010075.1/7513268-7513324 Loxodonta africana unplaced genomic scaffold scaffold_48, whole genome shotgun sequence. 
-GATTCAGGGGTAGAATTCTCACCTTCCAAGTGAGAGAGGTTTGGGTTCAATTCCCAG
->APLE01005677.1/5643-4894 Erythranthe guttata cultivar DUN x IM62 scaffold_74_contig_8, whole genome shotgun sequence. 
-CAACGGTTGACCAAGCCGCCTTGAAGAACAGTGCTGTGTAGCCGTCTGGCCCCGGTGCTTTAGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGACGGAAGGGCGAGAGGTACTCCATGCATATAACGAAAAGATAAGGGGATAGCAATTATTTGGGGGTCGACCGGTTTGCACGTTGACTGAGAGCTCAGAAAATTCCGGTAAAAGGACTCGAATTCTTCAAGTACCTCATCCCTTGAGGTAGTAACCGATTCCGTTAACGAACGAGACCTCAGCCTGCTAACTAGCTATGCGGAGGTATCCCTTCGTGGCCAGCTTCTTAGAGGGACTACGGCCTTTTAGGCCGCGGAAGTTTGAGGCAATAACAGGTCTGTGATGCCCTTAGATGTTCTGGGCCGCACGCGCGCTACACTGATGTATTCAACGAGTTTATAGCCTTGGCCGACAGGTCCGGGTAATCTTTGAAATTTCATCGTGATGGGGATAGATCATTGCAATTGTTGGTCTTCAACGAGGAATTCCTAGTAAGCGCGAGTCATCAGCTCGCGTTGACTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTCCTACCGATTGAATGGTCCGGTGAAGTGTTTGGATCGAGGCGACGTGGGCGGTTCGCTGCCCGCGACGTCGCGAGAAGTCCACTGAACCTTATCATTTAGAGGAAGGAGAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTG
->APMT01208959.1/14589-14458 Mesocricetus auratus contig208959, whole genome shotgun sequence. 
-TCAAACCAAAATAAGGTCATAAGGTGTTCTTCCTAGGGACCTAATATGCTGTGGCTATAAACATCAGCAACCCTGGGGGTGTATTCAACCTCTTGCTTAAATGGGTTTCCCTAAGCAAACTTGAAGACAATT
->ALWT01321998.1/3958-4053 Myotis davidii contig321998, whole genome shotgun sequence. 
-TGAAGGTGATGCTGCTATAACATCTATCACCCCATTGATCACCAGGGTTGATTCTGCTGACCTGGCTGGCTAGGTGTGTGTCCCTCTCCTCCCTTA
->AZNC01047644.1/7457-7628 Glycine soja cultivar W05 scaffold3943_7, whole genome shotgun sequence. 
-TTGCACTATGTAGTATCGTAGGTCTCTCTGATTATGTGGAGCGGCCTTTGAGCAATGGTGCATAAAGTGAGAGCTGATTAGTCAGCAGGCAGCCAGACAACTGCCGAGGTGGATCCACAGATGAACGGCTCATTTGTTAATGCTGTTTGTCTACTAATTCCACCTTACATTT
->AWGT02000388.1/78840-78931 Colinus virginianus strain Texas jcf7180006226242, whole genome shotgun sequence. 
-AAGCACAGCGATCACGACTGAACGCATCAATCTTTCGCCTTTTACTAAAGACTGCAGTGTCGTTTCAGCAAATAATGCGCCTCATACATCAA
->CP002637.1/13277-13481 Selenomonas sputigena ATCC 35185, complete genome. 
-CTATGCTACAATCAAAGAACGCAATGGGCGTTTTCTATGTTGCTCTTTTGAGAAGCCTTTTCCAGTTCGGAGCGCGGCGCCTTGGTCTTGCGCAATGGAGTCTCGTGAACCCCGTCAGGTCCGGAAGGAAGCAGCGGTAAGCGAACCGCTTCATGTGCCGCGAGGGCGCCTGGGGGTCGCGCCCCGAAGTGGAAAAGGAGTATTT
->CM000232.2/104162388-104162527 Rattus norvegicus chromosome 2, whole genome shotgun sequence. 
-ACATGGTTCAAACTTATAAATAAAGACTTATCTCATCCTGTGGGCCTCTCATAGTGTCCCGTGCTAGAGCAAACTGGCTCCTAACCATTGCCCAGCCTCGGTGCATGTAGGCTGCTGGCACTGAAGTGGGTCACACAGTG
->HE612865.1/664054-663926 Tetrapisispora phaffii CBS 4417 chromosome 10, complete genome 
-TATTGTGATGACAAGTTGTCGCCCCAGGCGGATCTATTCAGTGTATATTATTTCTATTTAAGTATAAAATAATGTGCAGTCGGAAATGACAGAAATATAACAACAAGCCAAACACTGAAAATTCTGATA
->MEPB01000070.1/175699-175987 Bacteroidetes bacterium RIFCSPLOWO2_12_FULL_35_15 rifcsplowo2_12_scaffold_36, whole genome shotgun sequence. 
-TACATTTGTCAACTTTTTGGTTCCTGAGTTTGATAAAATATCAAACCGGATTAAATGGGAATCAGGTGAAAATCCTGGACATTTCCCGATGCTGTAAGTTCTTATTAGTTTAAAGTTTATTTTTTAATTTTCTGGTTGTTAGACCTGAAAAACAAAAAACAAAACAAAATTCTAATATTTTTTTTAACATTCTTAGCCACTGTCTTGAATCGAATAAAGATTCTTTAAAGATGGGAAGGCGTTAAAAACAGAACAAGTCAGAAGACCTGCCAAAGAAATTAACATTTGT
->AAGB01000009.1/14123-14306 Wolbachia endosymbiont of Drosophila ananassae gdan_434, whole genome shotgun sequence. 
-ACTGATTCCTTTATGATGGTGTCATCCCAGTGCCCAGACACTGGGATCCAGGAAACTTAATTGCAAGTAATGCATTGGATTTGGTGAGTATGGGTTTTGCGTTATAGAATGAAGCACTTTTGGTGAATTTATAAAGAAAGCTGGATCCCAGTGTCAAGCACTGGGATGACAAGGTATAAACCTT
->NATD01000006.1/25331-26764 Candidatus Parcubacteria bacterium 4484_255 ex4484_255_scaffold_717, whole genome shotgun sequence. 
-TAGAGAATTAATTAGAGCATATGGTGGATGCCTAGACACCAAAAGCCGATGAAGGACGTAGCAGCCTGCGATAAGCCTCGGGGAGGCGGCAAGCAACCTTTGATCCGAGGATTTCCGAATGGGGAAACCTAGCGTTACAAAACAGCGCTGCACACCGTTTCACAGTGAATTCAAAAATCAAAAATCAAAGTGCAAAAATAATAAGAAAATTTACAAGAAACAAGATGCAATAACCAAACAATAGTCAATAAATCAATGACCGAATAATCAAACGGTTTGATTATTGAATATTGGAATTTGGAATTTGTTTGTATTTTGTATCTTGGTTATTGGTTGTTTCAAATAATTTTGATTTTTACATTTTACATTTTGAATTTACCGCGAAGCGGTGTGGGGGTACCCGGGGAAGTGAAACATCTCAGTACCCGGAGGAAAAGAGAGAAACCACCGCGCCTCACTATCGTTCGGCACGAATGTCTAATATCTAATGTCTAATTTCTAATAAATGTTTAATGTCAAAATGTCCAATGTCTAATTATTTTAGTCACTTGGTTATTAAGTCATTGGGATTTTATTAGTCATTAGGAATTAGGATTTAGAAATTCCTGTGACGAGCGGTAGCGAGGCACGGTGATATTTCCTTAGTAGTGGCGAGCGAAAGGGAAACAGTCTAAACTCTATAGAATCTTAGTTTTATAAGAGTCTTATCTTCGGATATTTCTTTTATTTAATGAAAGGTAGTAAAGCCAAAATATTCTATAAAGTGTTGTGGGGTAACTAATGTTTTGTTTTTTACTGAACAGAGTTAGGATTTAAATTTTTAGTCCAATAGCATGGAATTGCTAACCATAGAGGGTGAAAGTCCTGTAGATTAAAAAAATTTAAATTTTAATAATTAGTTATGCCCGAGTAATGCCAAACTCGTGAAATTTGGTATGAATCAAGGCGGACTATCGCCTAAGACTAAATACTTTTGGTGATCGATAGTGAACTAGTACCGTGAGGGAAAGGTGAAAAGTAGCCCGGTTAGGGCAATGAAAAGTACCTGAAACCATATGCTAACAAAGAGTCAGAGCCTTGTGCTTCGCACAAGGAAATTCAAAGCACGAAGCACGAAATCCCAAACAATATCAAAATCCTAATGTTTTAAATTCAAAACAAATTCGAGAAATTTCTGTTTTGGTCATTTGGATTTAGAATTTAAGATTTGTTTAGGGTTTCGTATTTAGAATTTTGGATTTTCTCGCGCGGAGCGCGAGGTAGGGTGAGTCTGTCTTAATTGACAGAGGAGGCCCGAACCCGTTGACCGTACAACATCATGGGATGAGCCGTGGATAGGGGTAAAAAGCCAATCGAACTCAGTGATAGCTGGTTCTCCCCGAAATAGCTTTAGGGCTAGCCCGTTCTTTACTCTCTGGGGGTAGAGCTACTGGA
->CM000129.1/18755739-18758932 Oryza sativa (indica cultivar-group) chromosome 4, whole genome shotgun sequence. 
-AAAGAAATCGTTAAGGGCGTATGGCGGATGCCTAGGCTTTCAGAGGCGACGAAGGACGTGGTAAGCTGCGAAAAGCTGCGGGGATTGGCACACACGAATTGATCCGCAGATATCCGAATGGGGCAACCCGGCATATTGAAGATATGTCACCTCGCAAGAGGAGCAAACCCGGAGAACTGAAACATCTAAGTACCCGGAGGAAAAGAAATCGAAGAGATTCCGTAAGTAGTGGCGAGCGAAAGCGGATTAGCCCAAAAGTCTTTTTATGTTTAGAGGAATGTTCTGGAAAGAACAATCATAGAAGGTGATAATCCTGTACTCGAAAGGCATATAGAGATGATAAATGAGTAGGGCGGGACACGTGAAATCCTGTCTGAATATGGGGGGACCATCCTCCAAGGCTAAATACTCCTGAAAGACCGATAGTGAACAAGTACTGTGAAGGAAAGGTGAAAAGCACTTCGAATAGAAGGGTGAAATAGAACCTGAAACCGTACGCCTACAAGCGGTCGGAGCAGCGTAATGCTGTGACGGCGTGCCTTTTGCATAATGAGCCTACGAGTTAATTTTACTAGCGAGGTTAAGGTATTAAGTACCGGAGCCGGAGCGAAAGCGAGTCTGAATAGGGCGCATAGTTAGTAGGATTAGACGCGAAACCTTGTGATCTACCCATGGGCAGGTTGAAGCTCTGGTAACACAGAGTGGAGGACCGAACCGGTTGACGTTGAAAAGTCTTCGGATGACCTGTGGGTAGGGGTGAAAGGCCAATCAAACTGGGAGATAGCTCGTACTCTCCGAAATGCATTTAGGTGCAGCGTCGTATATAAGTTTATTAGAGGTAGAGCTACTGATTGGATGCGGGGGTTTCATCGCCTACCATTCCTGACAACTCCGAATGCTAATAAATGTTCTACGGCAGTGAGGGCATGGGTGCTAAGGTCCATGTCCGAGAGGGAAAGAACCCAGACCCACAGCTACAGGTCCCCAATATATGTTAAGTTGAAGCAACGCGGTTGGACTGCATTGACAGCTAGGATGTTGGCTTGGAAGCAGCCATTCATTTAAAGAGTGCGTAACAGCTCACTAGTCGAGCGGTCCGGCATGGATAATAATCGGGCATAAACATATTACCGAAGCTATGGATTTATATTTTAGATATATCTGGTAGGAGAGCATTCTATTTGCGCCGAAGCAGTACTGTGAGGTATTGTGGAGCGGATAGAAAAGAAAATGTAGGCATAAGTAACGATAAAGCAGGCGAGAAACCTGCTCACCGAAAGACCAAGGCTTCCTCAGCCATGCTAATCAGCTGAGGGTTAGTCGGGACCTAACGCGAACCCGAAAGGGGTAGTGGATGGACATGGGTTAATATTCCCATACTTGCTCACAATAAAAGGGGACGGTTGGATGTAGCTGCTGGAGACTGACGGAATAGTCAAGGCCTAGCCTTCGGGCGAAGCTGCTGTAGTGTAATCTGATCCGAGAAAAGCCGAAGTGAAGCNACCCGTACCAAAACCGACCCAGGTGGTCGAGGAGAGAATCCTAAGGTGCTCGAGTGAGTCGTGGCTAAGGAACTAGGCAAAATAGTCTCGTAACTTCGGAAGAAGAGACGCCACAGCANNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNAATGTAGGCATAAGTAACGATAAAGCAGGCGAGAAACCTGCTCACCGAAAGACCAAGGCTTCCTCAGCCATGCTAATCAGCTGAGGGTTAGTCGGGACCTAACGCGAACCCGAAAGGGGTAGTGGATGGACAATGGGTTAATATTCCCATACTTGCTCACAATAAAAGGGGACGGTTGGATGTAGCTGCTGGAGACTGACGGAATAGTCAAGGCCTAGCCTTCGGGCGAAGCTGCTGTAGTGTAATCTGATCCAAGAAAAGCCGAAGTGAAGCAACCCGTACCAAAACCGACACAGGTGGTCGAGGAGAGAATCCTAAGGTGCTCGAGTGAGTCGTGGCTAAGGAACTAGGCAAAATAGTCTCGTAACTTCGGAAGAAGAGACGCCAACAGCAATGTTGGCCGCAGTGAAGAGGCCCAGGCGACTGTTTATCAAAAACACAGGACTCTGCTAAATCGAAAGATGCTGTATAGGGTCTGACACCTGCCCGGTGCTGGAAGGTTAAGGAAGGTGCTTAGCGTAAGCGAAGGCATTAACTGAAGCCCCAGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGTGTAACGATCTGGGCACTGTCTCAGCCACGAGCTCGGTGAAATTGTAGTATCGGTGAAGATGCCGATTACCCGCAATGGGACGAAAAGACCCTGTGAACCTTTACTATAACTTCGTATTGACTTTGAGTAAGTAATGTGTAGGATAGGTGGGAGGCTTTGAAGCAGGCACGCTAGTGTTTGTGGAGCCGACGTTGAAATACCACCCTTTACTTACTTGGAGCCTAACTTCTTTCAGAAGGACATTGCGTGGTGGGTAGTTTGACTGGGGTGGTCGCCTCCAAAAGAGTAACGGAGGCTTTCAAAGGTACCCTCAGCACGCTTGGTAACCGTGCGTAGAGTGTAATGGCATAAGGGTGCTTGACTGTGAGACCTACAAGTCGATCAGGTGCGAAAGCAGGACATAGTGATCCGGTGGTTCCGTATGGAAGGGCCATCGCTCATAGGATAAAAGGTACTCCGGGGATAACAGGCTAGTCTCCCCCAAGAGCTCACATCGACGGGGAGGTTCGGCACCTCGATGTCGGCTCGTCACATCCTGGGGCTGGAGAAGGTCCCAAGGGTTGGGCTGTTCGCCCATTAAAGTGGCACGCGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCTCTATCTATTGCGGGCGTTAGATGTTTGAGAGGGCTTGATTCTAGTACGAGAGGACCGAATTGAACAAACCTCTGGTGTATCAGTTGTACCGCCAGGTGCACCGCTGAGTAGCTACGTTTGGAAGAGATAAGCACTGAAAGCATATAAGTGCGAAACTCGCCTCAAGATGAGACATCTTTTAAGGGTCGTTGTAGATGACGACGTTGATAGGCTATAGGTGTAAAGACAGTAATGTCATAGCCAAGTAGTACTAATTACCCGTAGATTTATAGTC
->CYGY02000008.1/113318-113432 Burkholderia sp. STM 7183 genome assembly, contig: CYGY01000008 
-TCACCCCTGCGTGACTGGCGATAGAACCCGAAGCTGTCAAGCCTGACGGGTTCAAGGTGGAGCATCCCACCGTGAAGCGCAGGGTGCCGTTTTGCCGTTCGCCTGGGCAGCCATG
->ALWZ044793892.1/3195-2923 Picea glauca, whole genome shotgun sequence. 
-GTCTGTGATGCCCTTAGATGTTCTGGGCCACACGCGCGCTACACTGATGCAGTCAACGAGTTTTTCTCCCTGGTTCGAGAGGATCGGGAAATCTTCTCAAATTGCATCATGATGGGGATAGACCATTGCAATTATTGGTCTTCAACGAGGAATTCCTAGTAAGCGCGTGTCATCAGCTCGTGTTGACTACGTCCCTGCCCTTTGTACACACTGCCCATGGGTGTGTGTTTTTTGGTCCGGTGGGAGTGCTTTGTTGAAACCTGGAGCTCAAGT
->CM000335.3/6839130-6839055 Pan troglodytes isolate Yerkes chimp pedigree #C0471 (Clint) chromosome 22, whole genome shotgun sequence. 
-TGTCCTCTGGGGACTCAGCTTGCTCTGGCTGCTGGATTGAATTAGCTGCAGGACCAAGATGAGCCCTTGGTGGAGA
->AAQR03125679.1/12691-13758 Otolemur garnettii contig125679, whole genome shotgun sequence. 
-GGGGAGTATGGTTGCAAACTGAAACTTAAAGAAATTGACAGAAGGGAACACCAGGGTGAAAACTATGGCTTAATGTGACCCGACTTGAGAAACCTCACCCAGCCTGAACACAGACCGCTTGGCAGACTGACAGCTCTTTCTTTCTTTCCTTTTTTGTTTTTCTTTTTTTCCTGAGACAGAGTCTCACTCTGTTGCTGCTCTGTAGAGTGCTGTGCTGTCACAGCTCATAGCAACCTCAAACTCTTGGGCTCAAGCATTTATTTCTCTTGCCTCAGCCTCCCAAGTAGCTGGGACTACAGGTGCCTGCAACAACCCCTGGCTTTTTTTTTTTTTTTTTTTTTTTCTAGTTGTCATTGTGGTTTTAGCAGGCCTCGGGCTGGAACCCACCAACTCCAGTGTATGTGGCTGGCGCTGTAACCACTGAGCTACGGGCACCATCTGATAGCTCTTTCTTGATTCCTTGGGTGGTGGTATGTGGCTGATCTTAGCTGAGGGAGCAATTTGGTTAATTCTGATAACAAACTCTGAGATTCTGGCATTCTAATTAGTTAGGCAACCCCAAGCGACCCACTGTCTCAACTTCTTTTTTTTTTTTGAGACAGAGCCTCAAGCTGTCCCCCTGGGTAGAGTGCTGTGGCATTACAGCTCACAGCAACCTCCAACTCCTGGGCTCAAGCGAGTCTCCTGCCTCCGCCTCCCAAGTAGCTGGAACCACAGGCGCCCGCCACAACGCCTGGCTATTTTTTGGTTGCAGCCGTCATTGTTGTTTGGCGGGTCTGGGCTGGGGATTCGAACCCGCCACCTTAGGTGTACGTGGCTGGCGCCTTAGCCGGTTGAGCTATAAGCGCCGAGCCACTGTCTCAACTTCTTAGAGGGCAAGTGGCATCCAGCCACCAGAGATTGATGCCCTTATATTGTCCAAGGCTGTAGACGCACTGTGCCTACCCTGTCATGGATAACTTGCTGAGCCCCATTTGTGAGGGAGATCAGGGATTGCAATTACCAGCATGAACAAGGAATTCCCAGTAAGTGCGAGCCATAAACTTGTGTTTATTAAGTCCCTTTAAA
->MKQR01000007.1/110347-110112 Actinokineospora bangkokensis strain 44EHW Scaffold15, whole genome shotgun sequence. 
-ACACGAGAGAGGAGGTGGTCCACCAGTGAGTTCCGGTAGGACGCGTGAGGTGGCTGTCCGCTAAGGACCACCCATCAACGATGGACGCCGGCTCCGCCCACGGCAGACACCGGGTACCCGGTGCCGTAGGCGCGGCGCGTGGTCGGCGAATACCAGGCAGTCACCCGGCCCCTGGGCTTCCGTGGTAGTCCGCCACGGGCCTCCCTCGCGGAGGAGTCGCCCAGGGGCTGTGCCCT
->CM000916.2/23724354-23724270 Nasonia vitripennis chromosome 2, whole genome shotgun sequence. 
-AACGTGTCAAAGTCTGGTAACTCCACCACCGTTGGCGGAATGTTAAAAAGCCAATGGGGTACGAGTTTCCTACCATTGACGCGTT
->JH209564.1/9089797-9089999 Pelodiscus sinensis unplaced genomic scaffold scaffold80, whole genome shotgun sequence. 
-AGCTTTGCGCAGTGGCAGTATCGTAGCCAATGAGGTTAATCCGAGGCGCGATTATTGCTAATTGAAAACTTTTCCCATTCCTTTCCCTTCTCCCTCCGATCCCCCTTTCCTGTCCCTGTTCAGGGACCCTTTCTCATGAGAATCTCTTATGTCTGGAGGTACATCAGCTCATGGTGATAGGAATAATAGAAGTGGTTCCACCA
->DS546278.1/1-991 Physcomitrella patens subsp. patens PHYPAscaffold_3506 genomic scaffold, whole genome shotgun sequence. 
-CAAGCATTGCGATGGTCCCCACGGATGTTGACGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTATCTACTATCTAGCGAAACCACAGCCAAGGGAACGGGCTTGGAAAAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTAAGAGGTGTAGAATAAGTGGGAGCCCTCAAAGCGCAAGTGAAATACCACTACTTTTAACGTTATTTTACTTATTCCATGAGGTGGAGGCGGGACTCTGTCCCTGCTTCTAGTCTTAAGGCGCGCCCCTCGGGTGCGCCGATCCAGGTGGAAGACATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGCTCAACGAGAACAGAAATCTCGTGTGGAACAAAAGGGTAAAAGCTCATTTGATTTTGATTTTCAGTACGAATACAAACTGTGAAAGCATGGCCTATCGATCCTTTAGTCTTTCGGAATTTGAAGCTAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCCACCAATAGGGAACGTGAGCTGNGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGCTCGGTGCCGCAATAGTAATTCAACTTAGTACGAGAGGAACCGTTGATTCACATAATTGGTCATTGCGTTTGGTTGAAAAGCCAGTGACGCGAAGCTACCATGTGTAGGATTATGACTGAANNNNNNNNNNNNNNNNNN
->DS232073.1/119557-119157 Culex pipiens quinquefasciatus supercont3.261 genomic scaffold, whole genome shotgun sequence. 
-TATCAACATGACAAGATTATTCAATTCACGGTGGGAATGATCTGCCAAATCAGCGCTAATCAATTAGCTAATTGACAAAAATCAACGCTAGTTGATTAGCGTTACTATAATTGATTAGGTGTGTCTCACCCCTCGATAGAGGACTACCATGGTTGCAACGGGTAACGGGGAATCAGGGTTCGATTCCGGAGAGGGAGCCTGAGAAATGGCTTCCATTTCCAAGGAAGGCAGCAGGCGCGTAAATTACCCAATCCCGGCACGGGGAGGTAGTGGCGAGAAATAACAATATAAGACTCTTTTATGATGTTTTATAATTGGAATGAACCGAGCATAAATCCTTCGGTAAGGATCAAGTAGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCACT
->LZPO01108083.1/67281-67406 Neotoma lepida isolate 417 scaffold_2510, whole genome shotgun sequence. 
-AATGGAAATCAACTTGTTGGCTATGGCAGCCTCCCATTACAAGCCATGGAACAGCATATTCCTATTTGTTGGCAAGGCTGTCTCCATTTATTTGGTGTCTGTTTCTTATTTGCCCAAATAACTAAC
->JTHE01000287.1/5907-6033 Lyngbya confervoides BDU141951 scaffold_83, whole genome shotgun sequence. 
-GCCTGTCAGGAACGCGGCTACCTCCTCCCAGCCGCCTACTGAAGGTGTTTTGCAAGGGCACCTCCTCCCGCCCTTGCAACTCGTGTTGAGCCGGACCGCTACCTCCTCCCAGCGGTCCGGCTTTTCT
->CM000685.2/62840825-62842378 Homo sapiens chromosome X, GRCh38 reference primary assembly. 
-AGGGAACCATGAAAGAATAATTACAAATACAGAAAGGCAAAGATAATCCCTTCTAACATTTGCATAATGAATTAACTAGTATAATATTACTAAGAGAACTTTTTAGCTAAAATCCTTGAGACCAGAGGAGCTACCCATAGAAAGTCAAGAGAACACACTCATTTATACAGCAAAATAATGAGAAAATCAATGGGTAGAGGTAAAAGGCCTACCGAACCTGGTGACAGCTGGTTTTATCAAGATAGAATTTAAGTTTAACTTTAAGTTTACCTATAGAATTGTCTAATCCTATTGTAATTTTATATGTTAGTCTAAAGGGGGACAGCTCTTTAGATGTAGGAAATCACTTTTTCACTAACGGTAAGACACAAAACTCCTTTAGTTTGCCTAAAAGCAGACACCGATTAAGAAATCATTGAAGTTAAACATTTGAAACCCCTTAATTTCAATCACTACATCTAATTTCTAACACTATACTGGACCAATCTATTTTTAAATAGAAGAAATACTGTTAGTATAAGTAACAATAAATAATTGTCTTTGCATAAGCTTAGTCTTTGCGTAAGCTTAATCTTTGCATAAGCTTATGTCAAACTGGAAAATCCACTGAGAGTTAATAATCCAATACAGATAATCATATTATAAACTTTTTATTGTCCCAATTGGTAACCTAACACACAGATGCATTAAGGAAAGATTTTAAAAAGTAAAAGGAACTCAGCAAAATCAAACCCTGCCTGTTTACCAAAAACATCACCTCTGACATAACTAGTATTAGAGGCACTACCTGCCCAGTGACATAAGTTTAACAGCCACAGTATCCTGACCATGCTAAGGTAGCATAATCATTTGTTCCCAAAATGGGAACTTCCATGAATGGCCTCACAAGGGTTTAATTGTCTCTTACGTTTAATCAGTGAAATTGACCTATCTGTGGAGAGGCAGAAATATTTAAGTAAGATAAAAAAAACCTTATGGAGTTTCAATTTATTAGTAGAAATAAACTTATAAAAAAGCCTTAATAGGTCTTTTTGGGAGTAATTATTTTTATTTTTAAATATCTAGTGTACCACCATGGCATGTATTCTTTAAATTTTATACAAACAAGCACATTTTTTCAGTGTTTTGATGTATTTTCATATTTTTCTAACTTAGACGTGTAGGCAATACATTTTATCTAATGAACCAAAAATTTTGGTTGGGGTGACCTCAGAGCATAACACAACCTCTGAAATGATTTCAGCTAGGACCACACTAGTCAAGGTAATCTATTACACATTGACCCAAGTAGTTTGAGCAATGGAACACGTTACCTTAGGGATAGCAGTACAATCCTATTCTAGAATCCGTATCAGCAATAGGGTGTATGACTTCGATATTGGATCAGGATATTCCAATGATGTAACTACAATTAATGGCTCATATGTCCAATGATTAAAGTCCTATGTGATCTGAGTTCAGACCAGAGTAATCCAGGTAAGCTGCTATCTATTCAATATTTCTCTCAGTACAAAAGGACAAGAGAAACAGGGCCCACTTCAAAAAGTGCCCTCG
->DS022294.1/558139-558315 Mariprofundus ferrooxydans PV-1 scf_1099921033919 genomic scaffold, whole genome shotgun sequence. 
-GCGCCCCTGCGTTGAGCGAATGGCAATCATGTTGCCTGAGCCGATACTTGTTGAACGGGAGCCAAGCTACGATGGCTGTGTGAATCCCTTTAGGGGATACCTGATGCCAGAGTGCTGCACCCACCTCTTGTTAGAGGGTTCGACAACAGATTGCCGCAACGTCAACGCGGGGGCGCC
->AEUN01000020.1/91-28 Staphylococcus simiae CCM 7213 contig00020, whole genome shotgun sequence. 
-CTCAACAAACTTATGATGGGGTGCGCGCTTTTTTATTGTACAAGATAACGGATTTGTAGACATT
->URS0000D66E06_12908/1-81 unclassified sequences freshwater-2 RNA 
-CATATAAATCTTTATATGTTCTTATGCGGAACCAAACCGCGTAGGCCTAGAACGCCACTTAATTTAAGGAGAAACAAAATG
->KV442016.1/37818-37189 Mortierella elongata AG-77 unplaced genomic scaffold K457scaffold_6, whole genome shotgun sequence. 
-TTGAAAATGGTGCAGGAAGAGTTCTATATAGGTTTAATAGCTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTGATCCTTCGATGTCGGCTCTTCCTATCATACTGAAGCAGAATTCAGTAAGCGTTGGATTGTTCACCCACTAATAGGGAATGTGAGCTGGGTTTAGACCGTCGTGAGGCAGGTTAGTTTTACCCTATTGATGAAATGTTGTTGCAATAGTAATTGAACTTAGTACGAGAGGAACCGTTCATTCGGATAATTGTTACTTGGACCTGCCTGAGCTGGCAATGGCCCGAAGCTATTATCCATTGGGTTATGGCTGAATGCCCCCAAGTCCGAACCCGTGCTAGAACGCGAAGATTACCGTCTTTCGATTTTTTTTTTAGTTGAATATGAATAGACCTTCGGCTCCAAGATCATACTACATGGGGTTATGTTTTAGGGCTGAAGGCATTATGATGTTCCTGCTAAAACTTTATTCACGAATATCCCTTCCTCCGTACTTTAATTCGAGACAATATTGTGTCGAAAAATTTTGTGTGCTGGGCTCATGCACTTCCATATGATAACTTGCAAAAAGGGAAGCTAACTTAGTTCAAGGTCCATTTTTCATCCACAAA
->APMT01213728.1/1364-1077 Mesocricetus auratus contig213728, whole genome shotgun sequence. 
-TTTGTTCAACGATTAAAGTCCTACGTGATCTGAGTTCAGACCGGAGTAATCCAGGTCGGTTTCTATCTATTTACAATTTCTCCCAGTACAAAAGGACAAGAGAAATGGGGCCTCCTTAATATAAGCGCCCCTAATTAATTAATGAAACCATCTCAATATAGTAAATCCATACTATATTTACCCTAGACAAGGGTTTATTAGGGTGGCAGAGCCCGGAAATTGCGTAAGACTTAAAACCTTGTCCTCAGAGGTTCAAATCCTCTCCCTAATAGTGCATTTAATTAATAT
->DS028102.1/263782-263910 Coccidioides immitis RMSCC 2394 supercont1.10 genomic scaffold, whole genome shotgun sequence. 
-GGGCTGGTGGCGCAGCGGTTAGCGCGTCGGATTGCGTAAGTGGCGAATTAAGACAGATGCATCTCAGCAGCAAGCTAACCCTTTCATATAGAGATCCCAAGGTCCCCGGTTCAAATCCGGGTCAGCCCT
->CP003614.1/5692256-5692124 Oscillatoria nigro-viridis PCC 7112, complete genome. 
-AGGAGCCGTGTGCGGAGAAATCCGCAAGCACGGTTCTGAAGACGAGTCGCTCCGGTGACGGGGCGGCTTCGTTTAACAAGCTTACGCTGTAATCTTTGATTCAGCATAGGAGGATGTCACCGTCCGAGTTTAT
->AODI01000030.1/8750-8667 Brochothrix thermosphacta DSM 20171 = FSL F6-1036 c30, whole genome shotgun sequence. 
-TAAAGGTATAGAAAAAGACACTAGCGCAAACTAGCGTCCGTGTAGAACCGTTTAAGACGGTGGCTACGCAATTATAATACTAAA
->LBUD01000030.1/9979-10044 Parcubacteria bacterium GW2011_GWA2_38_13 US74_C0030, whole genome shotgun sequence. 
-AGGCGTGTAGCTTAATTCAGTGGTTTCCAAAACCAGGGAGTGCGGGTTCAAATCCTGCCACGCCCG
->HF998384.1/8394-8081 Coprococcus eutactus CAG:665 genomic scaffold, scf48 
-GAAAATGCAATGAAGAGGAGTAGTAGAATCCTGGAGATGTTCAGAGAACTGCCGGTTGGTGTGAGACAGTGATTGAGAGGATTTGAACTCGCCTTGGAGCAGCCCGCTAAAAGATACGACGTTACACAGTAGCGTTGAGCGTATCGAGTAGGATGGGACGGAGGCTGGCCGTTATAGCAGAAGGATATAAGATATGTAAAAGATATGTATTTGAGTTGTATAAGATCTGCATGTCTGTATCTGTAACGAGAGCATATTTTGTAATTATTATGAAGTATGAAATAGAGTGGTACCGCGTAACTTACGTCTCTATA
->LKEX01010032.1/13186-15658 Cyphomyrmex costatus contig10032, whole genome shotgun sequence. 
-CCCGCTGAATTTAAGCATATTATTAAGCGGAGGAAGAGAAACTAACTAGGATTTCCTTAGTAGCGGCGAGCGAACAGGAAAGAGCCCAGCACCGAATCCCGCGGTTCCGCCGCAGGGAAATGTGGTGTTCGGGAGGATCCGTTTATCCCATGGTGTCGCGCCGCGTCCAAGTCCATCTTGAATGGGGCCACTTACCCGCAGAGAGTGCCAGGCCCGTAGCGACCGGTGCGCGTCTCGGGAGGATTCCTCCTTAGAGTCGGGTTGCTTGAGAGTGCATCTCTAAGTGGGTGGTAAACTCCATCTAAGGCTAAATACGACCACGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGTTGAAAAGAACTTTGAAGAGAGAGTTCAAGAGTACGTGAAACCGTTCAAGGGTAAACCTAAGAAACCAAAAGATCGAACGGGGAGATTCATCGTCAGCGACGCTGGCTTCGCGTCGGTGAGCGATGATCCTCGCGGCCCGCAGCGCGGACACGCTGCCGTGCGTCGACGTCCGGCGTACGTCGTCGTGCACTTCTCCCCTAGTAGAACGTCGCGACCCGCTGGGTGTCGGACTACGGCCCGGGTGCGGTGACTGACGCGTCGCCGGTAAAACGGCACGCGTCAAACCCCCGGTCGCCCGGCCGGCTGCCCGGCGGTACACGCACGGTATCAGGCCGCAGACAACGGTCGGGGCGCGGGGCCCCCCACGTCCTCCGTGGCGTGCGGGGGTCTCCACTCCGTCCTGCTTTGCGTCGAGGCCGTCGCAAGCGCGCGCCACGGTACACGGAGGCTTACGGACCTAGCGCCGTCACCGGTCCTGGCCCGCTGTTGGTCGTACGGTTAACCTTCGACCGGTCTACGAACGTTCCTCGCGTTTCCCCCTCGCGGGGCGGGCGCGGGGGACCGATACCGGTCGGCAACGTTACTGCTTTCGGTACTCTTAGGAACCGTCTTGAAACACGGACCAAGGAGTCTAACATGTACGCGAGTCATTGGGACTCTAGCGATACCTAAAGGCGTAATGAAAGTGAAGGTCGGCCCTGGTTGTCGACCGAGGGAGGATGGGCCGCGTCGCGATGCGGCTCCGCACTCCCGGGGCGTCTCGTTCTCATCGCGAGAAGAGGCGCACCCAGAGCGTACACGTTGGGACCCGAAAGATGGTGAACTATGCCTGGTCAGGACGAAGTCAGGGGAAACCCTGATGGAGGTCCGTAGCGATTCTGACGTGCAAATCGATCGTCGGAACTGGGTATAGGGGCGAAAGAATAATCGAATCACCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATACCTGGCACTCGGCCGTTCCGCACGGAACGCGCGCGAGTCTCATCTGGTAAAGCGAATGATTAGAGGCATTGGGCCCGAAACGACCTCAACCTATTCTCAAACTTTAAATGGGTGAGATCTCTGACTTTCTTGAACCGTGAAGTCACGAGTATCACTCGGATCAGAGTGCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGCTGTGGGATGAACCAAACACAGAGTTAAGGCGCCCAACTCGACGCTCATAGGACACCATGAAAGGCGTTGGTTGCTTAAGACAGCAGGACGGTAGCCATGGAAGTCGGAATCCACTAAGGAGTGTGTAACAACTCACCTGCCGAAGCAACTAGCCCTGAAAATGGATGGCGCTGAAGCGTCGAGCCTATACTCTGCCGTCAGCGGCAAGTGGGGCGGCCGTGTGCGCGTCGTCAGACGCGTGCGCGCCGCCACGAAGCCCTGACGAGTAGGAGGGTCGCGGCGGTGTGCGCAGAAGGGTCTGGGCGCGAGCCTGCCTGGAGCCGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATACTCCAGCGAGGCCCTGGAGGACTGACGTGGAGAAGGGTTTCGTGTGAACAGCCGTTGCACACGAGTCAGTCGATCCTAAGCCCTAGGAGAAATCCTATGTCAATGACGGCGTACGATACTCTAGTGTTGTCGTTGTCGCGCTCTCGATCTCCGACTCGCCGCCGCTCCCACGCGCGCGCGCGACGACGGGGAGGGGAGAGCGTGGTGTTTTCTTCTTCAACGAGAAGCGCTCTGACAGGACACACGCCCGTCGGGCGAAAGGGAATCCGGTTCCTATTCCGGAACCCGGCAGCGGAACCGCATACAATTCGGGCCCTCGTAAGAGTGTTCGTCGGGGTAACCCAAAATGACCTGGAGACGCCGTCGGGAGATCCGGGAAGAGTTTTCTTTTCTGTATAAGCGTTCGAGTTCCCTGGAAACCTCTAGCAGGGAGATAGGGTTTGGAACGCGAAGAGCACCGCAGTTGCGGCGGTGTCCGGATCTTCCCCTCGGACCTTGAAAATCCAGGAGAGGGCCACGTGGAGGTGTCGCGCCGGCTCGTACCCATATCCGCAGCAGGTCTCCAAGGTAAAGAGCCTCTAGTC
->ALWZ040927269.1/1-1274 Picea glauca, whole genome shotgun sequence. 
-TTCGAATTGGGAGGGCGATCCTCCCGGTGAACTAACCGTACCCCAAACCGACACGGGTGAACAAGTAGAGTATACTAGGGCGCTTGAGAGAACCATGTTGAAGGAACTTGGGAAAATGACCCTGTAACTTTGGGAGAAGGGGTGCTCTCCCTCCTATCTTTGGGTTGGGAAAGTGGCACATACCAGGGGGTAGCGACTGTTTATTAAAAACACAGGACTCTGCCAAATGGTAACACGATGTATAGAGTCTGACACCTACCCGGTGCTGGAAGGTTGGAAGGAGAAGTGTGATAAGCTTCGAATGGAAGCCCCGGTAAACGACGACAGTAACTCTAACTATCCTAAGGTAGCGAAATTCCTTGTCGCATAAGTAGCGACCTGCACGAATGGTGTAACGACTGCCCCACTGTCTCCGACATGGACCCAGTGAAATTGAATTCTCCGTGAAGATGTGAAGTACCAACGGCTAGACGGTAAGACCCCGTGCACCTTGACTATAGCTTCGCAGTGACAACCTCTTATGAATGTGTGGGATAGGTGGGAGGTGGGGAACTCTCAATCCTGGAATACCACTCTTTCATCTAAGGATGCCTAACCATTTCTTTCTCTAGATTTATTCTCAGGGTGGGACACTACAAGGTGGGTAGTTTATCTGGGGCAAATGTCTCCTAAAGAGTAACAAAGGTGTGCGACGGTAGGCACTTTCTATAAGCAAGCATAATGGTCTAAGCCTGCCTGACTGTGAGACTCACTGGTCGAACAGAGACGAAAGTTGGCCATAGTGATCCGGGAGTCCCGCGTGGAAGGGCTCTTACTCAATGGATCAAAGGTATGTCGGGGATAACAGGCTAATGACTCCCAAGAGCTCTTATCGACGGAGTCATTTGGCACGTCGATGTCGACTCATCACATCCTGGGGTTGAAGAAGGTCCCAAGGGTTCGATTGTTCACCGATGAAAGTGGTATGTGAGTTGGGTTTAGAACGTCGTGAGACAGTTCGGTTCCTATCTACCGCTGGTGTTGAAGGGAGAACTGTGAGGAGCCAACCCTAGTATGAGAGGACTGGGTTGGGCCAACCTATGGTGTACCGGTTGTCATGCCTAGCAGCGTTGGGCAACCAAGTTGGTATGGAAGAACTGTTGAAAGCATCTAAGCGGGAAATCCTTTTCTAGACAAGTTCTCGTACGAGGTGAAAGAACATCACTTTGATAGGCGATAGGTGTAAGCACCGCGAGGTGTGAAATGATATCGTACTAATATTTTTACTTAGTCCA
->AE007869.2/110253-110382 Agrobacterium tumefaciens str. C58 circular chromosome, complete sequence. 
-ATGGTGAAAGGCAGCGTCCATAAAAATAGACGCGCCCTGGAACATCAGACCGTTGAACGCTTTGACCACGGATGTACTGGCACTGACGAAAAACGGATGGAAAGGTCGGGCTCGCCCGGCCTTTTTGTTT
->LGKD01302340.1/501-591 Octopus bimaculoides Scaffold36772_contig_40, whole genome shotgun sequence. 
-TATAGTTTTCAAAGTGACAACTAGTCACTGACCTATAGTAATTTTTTAAATTATAGATCAGTGACTAGTTGTCACTTTGAAAACTATATAT
->AACT01052938.1/746-1 Ciona savignyi cont_52938, whole genome shotgun sequence. 
-AATTCTTGGATCGGCGCAAGACGAACGACTGCGAAAGCATTTGCCAAGAATGTTTTCTTTAATCAAGAGCGAAAGTCAGAGGTTCGAAGACGATCAGATACCGTCCTAGTTCTGACTATAAACGATGCCAACTAGCGATCGGGGGGCGTTACATTGACGACCCCTCCGGCAGCTTACGGGAAACCAAAGTCTTTGGGTTCCGGGGGAAGTATGGTTGCAAAGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGAAATCTCACCCGGCCCGGACACAGTGAGGATTGACAGATTGAGAGCTCTTTCTTGATTCTGTGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGCGATTTGTCTGGTTAATTCCGATAACGAACGAGACTCTGGCTTGCTAAATAGTTACGCGACCATCCCGGTCGGCGTTTAACTTCTTAGAGGGACAAGTGGCGTTTAGCCACACGAGATTGAGCAATAACCCCTATTTCCACAAAGGAATAAATTTTAAAATCCAATCTACGTTCAGTTTCTAACATAACACATTTTTATTTTTGTTTCTTTCGCTGCAGCGTTTATCACCAACAATTAAAAAATACATGTCATATATATATATACCAAAACAAATATGGTGTTAACTGAAAATCCAACAATTAACCAAAGAAATAAAAAATACTACAACAAAACAGGAAGGCACCAAAAAAACC
->CCCW010012867.1/738-403 Brassica napus, WGS project CCCW01000000 data, contig: 31321 
-ACTCTAGTCCGACTTTGTGAAATGACTTGAGAGATGTAGAATAAGTGGGAGCTCCGTGAATCGGAGGCGGGGTTGTTACCCCTTGTTTTCGACCCAAGACTCGCTTCGGCGGGTCAATCCGAGCGGATGACATTGTCAGGTGGGGAGTTTGGTTGGGGGGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGCTCAACGAAAACAGAAATCTCATGTGGAACAAAAGGGTAAAAGCTCGTTTGATTCTGATTTTCTGTACGAATATGAACCGTGAAAGCGTGGCCTATCGATCCTTTGGACCTTCGGAATTTGAAGCTAGAGGCTTCAG
->AFEY01211982.1/140-48 Sarcophilus harrisii ctg7180001785086, whole genome shotgun sequence. 
-ATTGGTTTTCAGCCTTTTGGCTAAGATCAGTATCTATTCTTATCAGTTTAATATCTGATATGTCATCTATATGTATATACATAGGTATATGTA
->GL832959.1/2234038-2236146 Salpingoeca sp. ATCC 50818 unplaced genomic scaffold supercont1.5, whole genome shotgun sequence. 
-TAACTGGTCGATCCTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCCATGCATGTCTAAGTATGAATAGTATTCTTGATACTGTGAAACTGCGAATGGCTCATTAAATCAGTTATAGTTTATTTGATAGTTTGCAACTCGTTTTTCGGAGCGGTGTTGTGCTAGACGGATAGCCGTGGTAATTCTAGAGCTAATACGTGCGACAAGGCCCGAGAGAGGGGTGTGTGTATGCGCATTTTTTCTTCTCGAGGGCTGCATTTGTTAGGTATAAAGCCAGCAGGAACATGACTGGTGAATCAGAATAACTTTGCTGACCGTTACACTTTTGTGTGTGATGGTGTCTCATTCGAATTTCTGCCCTATCAACTTTCGATGGTAAGGTATTGGCTTACCATGGTGACAACGGGTGACGGGGAACATTTGGTTCGATTCCGGAGAGGGAGCCTGAGAGACGGCTACCACTTCCAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCTGACACAGGGAGGTAGTGACAATAAATACCAATGCACGGTGTTTTTTATGCACTGTGCAATTGGAATGAGAACAATGTAAAGACCTTATCAAGGAACAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAAAAGCGTATACTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGGATTTCATGCGGGGTTCACGGTGTGTGGGTGGGGGTGAGACACTGTTTCACGCGCGCCTTCTTCTGCCCCGCACTGTTTGGACTCTGCAGTTTTAATATTCCCTGGTGGCGCCTTTGGCGCGTGCCCTTGATTGGGTGTGTGTCAAGTCACGTAGTGGTGGGGCGCTGTTGGGGGCTTTACTTTGAAAAAATTAGAGTGTCAAAGCAGGCAGTCATTTGATTTGCTTGAATAGATTAGCATGGAACAACGGAAGAGGACTTTTGGGCCTGTACTGTTGGCGTGTGGTGCGGGGTGTGTGGAAGAAGAAACCGCAAGGTTTTCTTATTCCTCCCTCACCACATCGGGTCTGAAGTAATGATTAATAGGGACGGTTGGGGGCACTGGTATTTCGTTGTCAGAGGTGAAATTCTTGGATTTACGAAAGACCGCCGACTGCGAAAGCATTTGCCAAGGACGCTTTCATTGATCAAGAACGAAAGTTAGGGGATCGAAGACGATTAGATACCGTCGTAGTCTTAACCATAAACGATGCCGGCCAGGGCTCGGTGGGCAGCACAAATGTTTCAACGCATGGTGGCGCCATCGGGACCTTTAGGGAAACCAAAGCGTTTGGGTTCCGGGGGGAGTATGATCGCAAGATTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTCACCAGGTCCAGACATGGGAAGGATTGACAGATTGACAGCTCTTTCTTGATTCCAAGGGAGGTGGTGCATGGCCGTCCAGCTTTTGTTGTGAAATCTCTGTTTGATTACGGTAAACGGCGAGACCTTGACTTGCTGATTGGTGTGCGCCTGCGTTAGCAGGCGTTGGAGATTACGCGCAAGCGTGTCTTTTGATACACCACTCAGAGGGACACTCGGCGTTGCTATTGAGCGTAAGCCGAAGGAAGTTTGAGGCGATAACAGGTCTGTGATGCCCTTAGATGTTCTGGGCTGCACGCGCGCTACACTGACGGGGGCAGCGAGTATGCTTTGGGTGTTTGTGGTGGGGAAAGTCTTGTGCTTTTCTGCATTCACAAACATCTATTCCTGCGCTGGAAGGCGTGGGGACTCTTGTGAAAACCCGTCGTGCTGGGGATAGATGCTTGCAATTATTCATCTTGAACGAGGAATTCCTAGTAAGCGCAATTCAACAGATTGCGTTGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTACTACCGATTGAATGGTTTAGTGAGGCCTCGGGATTGGCGCGTGGGCGCTGGCAACAGCTGCCCATGTGTTTCTTTGCTGAGAACCTGGTCAAACTTGATCATTTAGAGGAAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTC
->AGTP01003540.1/18890-19069 Ictidomys tridecemlineatus contig003540, whole genome shotgun sequence. 
-AAGTATTATCTCTATAAAGACTTACTAGAGAAGTTTCTCTGATTGCATAAAGAACCAGAAATCAAGGAGGTGCAGTGTGAACAGGTACTTGGTGTTGTTTTGTTGCAACTACCATTTCCCATTGATGATTGTTGTTCTCTTCCGTTTAGGGAGAGTAAGAGGGAAAGAATGCCAAGTGGT
->CM004282.1/30198321-30198152 Daucus carota subsp. sativus cultivar DH1 chromosome 5, whole genome shotgun sequence. 
-ATACCTTTCTCGGCCTTTTGGCTAAGATCAAGTGTAGTATCTGTTCTTATAATATCTGATATGTGGGCTTATAAGTTCACACGATATTAAGGGGCTGTTTGGTTGAGAGAAGCAGCTTCTGGCTTCTGCTTCTCTTGACCCGTTTGTGTAAAGAAGTAGAAGCACTTTTA
->AACT01036598.1/1017-1 Ciona savignyi cont_36598, whole genome shotgun sequence. 
-TACTCTATTCAGCAGAACAAAAGCTGTTATAGGGGCCAGGCTTACGAAACTAATTGGAGAAGAACCTACCATCAAGACTCTGCAGCAACACCGCATCGAGAGCTTCTCCAAGCAGGTCCAGGGCTACGGATCCAGTCACTTTAGCAACACTCACTCCAACAGCTGGTTAACAGGATCAACCAGGCTAATGACTGGCCGTAACTACGTACAAGCCTGTGCACTCCGGACACAGACCCTGCCAACCCGCGAAGCCGTCTCAAGGGGAAGAGTCGGCGCGAACACCATCTGCCGAAACTGCGGGCTGGCAGAGGAAACACTGTCCCACATCCTGCAGAACTGCCACCGGACCAATAAGATCAGGATTCAACGGCATAACGCGGTTCTGCAGGTACTTGTCAAACATCTACGTAGGAGAAAATGGAAAATCCAAGAAGAACCATACATCCCCACTCCTACGGGCAGTGTCATTAAGCCTGATGTTCTGGCCACGGATCCTGACGGGAACGTGTTTGTCATCGATGCCGCCTGCCCCTACGAGGGTAACAAGAACTCCCTCGTCAATGCAGCAGCGGCAAAGGTGAGCAAATACACACCTTATAAACCCTCCATTCTTCATTATATAGGTGAGACCCCAACAACGGTCACTTTCCTCGGATTCGTGGTGGGAGCCCGTGGCGCAATGCCACCGCAGACACAACACTTCTGCAAGCAGGTAGGTCTTGGTAATGGCCAATTAGATCTAATGTCGGTACGGGCCATAGAAGGAAGCCTAAAAATCTTCCGATTATTTATGGCCCTGTAATATTAACTCGGGTACGCACCCACGAAGTATACGCAAGTGGTACTTCGGTAATGCGAAAAGACACGGTGCTATCGGACCTGACCTTTATGGTAAGGACCCGCGGCACCAAGTCAAACATAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCGCTGTCCCTATCTACTATCTAGCGAAACCACAGCCAAGGG
->MHIF01000055.1/14859-14981 Candidatus Buchananbacteria bacterium RIFCSPHIGHO2_01_FULL_46_12 rifcsphigho2_01_scaffold_5410, whole genome shotgun sequence. 
-GACCTAACCCTTGGGTAATTTATCTAAGGCATGGTCGAAAAACTCATCCTACATAAAGACGGTCTTCCGTCCAGTACTTGTAGGATGAGTCTATGCCCAAAAGGGTATAGTTGGTATATCTAA
->CP002273.2/732628-732803 Eubacterium limosum KIST612, complete genome. 
-TTAATAACTTAATGATGCTGTTTTGTTAGAGGAAAGCGGTTGAAATCCGCTACAGCCCCCGCTACTGTAATTGCAGACAAGATCCTCATAGACCACTGTCAGGCGTATCCTGACGGGAAGGGAGGATGGAGAAGGAAGCAAGAGTCAGGACACTTGAAGCAAAGCAATATAATCAC
->AAGJ05103349.1/43054-43146 Strongylocentrotus purpuratus Contig103349_fixed, whole genome shotgun sequence. 
-CCCGCCAGCCCGATCATTTTTGTGTTTATGCAACTTTTGTATTTTCACCGATCAGAGTAGTTGCATAGTCACAAAAGTGATTGGGAGGGTTGG
->MLAU01031941.1/12573-12707 Lupinus angustifolius cultivar Tanjil contig_31941, whole genome shotgun sequence. 
-CTTGTGGGGAATGCTGTCCGGTTCAAGGACATAACACTATCTTTACAACCTATGATATATATAATTTGCGGATTGTATAATCGATTTTGTGTTATGACTTAGTGTTTCCTCGGACCAGGCTTCATTCCTCTCAAT
->KB096275.1/1122699-1122634 Helobdella robusta unplaced genomic scaffold HELROscaffold_19, whole genome shotgun sequence. 
-TCCTATGATGAACCTGGCTTAGGAAGTGCCGTCAGATACATATATGATGATCGCTATTAGCTGATG
->CM002813.1/58122422-58122133 Capsicum annuum cultivar Zunla-1 chromosome 2, whole genome shotgun sequence 
-TTAATTTGACTCAACATAGGAAAACTTACTAAGTCCAGACATGGTAAGGATTGATAGACTGAGAGCTTTTCTTTATATAATGGGTGGTGGTTCATGGCCATTCTTACTATATGGAGTGATTTGTCTAGTTAATTACTGATACGCCTAAATTACACCTCTTTTTTGAGAGAGTAAGTGATCTCTATCAAATATAGAACTCAACTGGGTTGGGTGTCGAATCACACAAGGAATATTGTGTTCACTAAATATTGTGATTGTTATTAGACTGTTGATCTAAGGTTCCTGAGTAC
->GL378484.1/35805-36021 Volvox carteri f. nagariensis unplaced genomic scaffold VOLCAscaffold_163, whole genome shotgun sequence. 
-ACTTGGACAAGGCGGCTGGCGGTAACGCAAGCGAGCCCGGAGACATCGGCATCGGCCCTGGGAAGAGTTCTCTTTTCTTTTTAACAACCCGAAGGCCCTGGAATCGAATCATTCGAAGATAGGGCTCAGAGGTTGGTAAAGCACCGCACTTCTCGCGGTGTCCGGCGCGCCGTTGACGGTCCTTGAAAATCCGGGGGAGCATTTCCGATCTTGCCAA
->AFSB01153275.1/28776-28952 Heterocephalus glaber contig153275, whole genome shotgun sequence. 
-ATCGCTTCTCAGCCTTTTGGCTAAGATCAAGTGTATTATCTGACTGTCTTCAGGGCTTTGCTCTCAGGGTAGGTTAATGCACAGGAAGTATTCACAAATGTGGAGCTTACCCACTTGAGTAAGCCCCACACACGCTTGAACACTAATCATCTGAAAAGGTTTTAGGATGTAAAAGTT
->EU151723.4/3777-3872 Opium poppy mosaic virus isolate PHEL5235, complete genome. 
-GCAATATAGTGGGAGCCGGGTCCTGGTAAACAGGTTGAGTTGGTCTCGTAATCTCGGGTGGACTGCCAATCCACCGTCGCACCACTCTCATGGGCT
->JMQN01000048.1/178591-178475 Marinobacterium sp. AK27 AUG5_contig_7, whole genome shotgun sequence. 
-CTATCTTGGTCGGGGTGCCCCGTCATTGGCGTTGGAACGCGAATGGTACGGGCTGAGATTAAACCCGCTGAACCTGATCCGGCTTGGACCGGCGTAGGAAATCGAGATATTCCGTAT
->URS0000D69473_1118056/1-77 Anaerococcus obesiensis ph10 skipping-rope RNA 
-AATCATAGAGGTTAAGAAATCTGCCGATAACGCTATTTTATAGAAATGTGGGAGAGGAGGCAGTCCCACCTATGTTT
->JRRC01354207.1/1-1013 Gossypium arboreum cultivar AKA8401 contig_36035_3, whole genome shotgun sequence. 
-CGTAAACCGTGAAAACGGGGTTGTGGGAGAGCAATAAAAGCGTCGTGCTGCTAGGCGAAGCGGTGAAGTGCCGAACCCTAGATGGCGATAGTCCAGTAGCCGAAAGCATCACTAGCTTACGCTCTGACCCGAGTAGCATGGGGCACGTGGAATCCCGTGTGAATCAGCAAGGACCACCTTGCAAGGCTAAATACTCCTGGGTGACCGATAGCGAAGTAGTACCGTGAGGGAAGGGTGAAAAGAACCCCCGTCGGGGAGTGAAATAGAACATGAAACCGTAAGCTCCCAAGCAGTGGGAGGAGCCCAGGGCTCTGACCGCGTGCCTGTTGAAGAATGAGCCGGCGACTCATAGGCAGTGGCTTGGTTAAGGGAACCCACCGGAGCCGTAGCGAAAGCGAGTCTTCATAGGGCAATTGTCACTGTTTATGGACCCGAACCTGGGTTATCTATCCATGACCAGGATGAAGCTTGGGTGAAACTAAGTGGAGGTCCGAACCGACTGATGTTGAAGAATCAGCGGATGAGTTGTGGTTAGGGGTGAAATGCCACTCGAACCCAGAGCTAGCTGGTTCTCCCCGAAATGCGTTGAGGCGCAGCAGTTGACTGGACATCTAGGGGTAAAACACTATTTCAGTGCAGGCCGCGAGAGCGGTACCAAATCGAGGCAAACTCTGAATACTAGATATGGCCTCAAAATAACAGGGGTCGAGGTCGGCCAGTGAGACGATGGGGGATAAGCTTCATCGTCGAGAGGGAAACAGCCCGGATCACCAGCTAAATATCCGGACTATTCTACAGGTTTCCACTTTCCTTCAATCCGTTGAAATTTCAACAGATGAAACTTGTAGATAAAAAAGACTTAGGTACAATGGTGGGAATTTAATGCTTGAACGGGGACAACACTGAACCAATTCCATTGTTTGTCGAGTTAGTCGATCTTGAGCCCATTGAAAATGTCGTTCTATTAAGTAATCAATTAAAAAGCATGATACGGTTTTTATTGACATTTTTTT
->KI545835.1/844-926 Toxoplasma gondii VEG unlocalized apicoplast scaffold scaffold00504, whole genome shotgun sequence. 
-GGATTGATGTCTGAGTGGTCAATAGAAATAGACTGTAAATCTATAGAAGTTATTCTTCATCGGTTCAAATCCGATTCAATTCA
->KQ435742.1/1845933-1846233 Melipona quadrifasciata isolate 0111107301 unplaced genomic scaffold scaffold54, whole genome shotgun sequence. 
-GAGTTCCCTCGAGTAACGCGGCGGAGCCACAATCGGAGTTCTCAGTGACTCTCAATGCTCTGAGGAAAGTCCCTGGACCTTGGACAGAAAGTGTTCGTAGCATCGCCGTTACTAGCCTCTCGTCGTCTTTCTCGAACTTGAGACAGGAAGCTTCGGCCGATCTTTTCGGGTTAGGACGAGAGTGTATTGGTCAGAGGAAAGTAATGCGTTTCAAATCAAAAAATTCTCTCTTTCAATCTCCCTTTGTGGAGAGAGAAACTGAGAATTTGTCCAACTAAACAGGGCTTACTACGAGGGAAAA
->KE148148.1/1651271-1651071 Ophiostoma piceae UAMH 11346 chromosome Unknown scf03, whole genome shotgun sequence. 
-TCAGCTCTCTTTGCCATGACGGCTTAGATCAAGTGTAGTATCTGTTCTTTTCAGTTTAACAGCTGAAAAAGCCTTACTGAGGCTCTTCTGTTACGCTAATTTTTGGCAACTTGGGCAGGGCGGTCGACTGAGCTCGTCTCGCGCGACCATCCGTCCACGGTGTCCCTGGTATTTCACTGCTTCCAGGCGACGCGAACCCAC
->FR887668.1/64445-64618 Firmicutes bacterium CAG:41 genomic scaffold, scf118 
-AAGCAAGGTAGAGGTGCGCTTGTGTATTAGTATGTATACGGAGATATGCAATTATCTTTGATGTATACGGAAAGGACACAGTGCCGAAGTTTGAATATTATTGCGAATATTCATTCTGGGCATATCGTTAACAGCGGTATGACTGTCATCGTAAGGTGGGGAGCTATCGCTGTT
->ASAF01228276.1/12168-11615 Nicotiana sylvestris Nsyl_contig228276, whole genome shotgun sequence. 
-CATAAAAAAGTTTTGAATTCTTAATTAATTGTTTCCGATTCACCGGATCTTACCTCTTTTGAAAGGAGTCAATAAAAAGTCAAAATATGGATTAACTTAAACTAATTTAAAAATTAAATCGAANTCGGCTAACTCTGTGCCAGCAGCCGCGGTAATACAGAGGATGCAAGCGTTATCCGGAATGATTGGGCGTAAAGCGTCTGTAGGTGGCTTTTTAAGTCCGCCGTCAAATCCCAGGGCTCAACCCTGGACAGGCGGTGGAAACTACCAAGTTGGAGTACGGTAGGGGCATAGGGAATTTCCGGTGGAGCGGTGAAATGCGTAGAGATTGGAAAGAACACCAACGGCGAAAGCACTCTGCTGGGCCGACACTGACACTGAGAGAAGAAAGCTAGGGGAGCGAATGGGATTAGATACCCCAGTAGTCCTAGCCTTAAACGATGGATACTAGGCACTGTGCGTATCGACCCATGTAGTGCTGTAGCTAATGCNAGTGATAAAGGAGGTAGGGGTGCAGAGACAGCCAGGAGGTTTGCCTAGAAGCAGCCACCCTT
->CP001097.1/1124998-1125215 Chlorobium limicola DSM 245, complete genome. 
-ATAAGTAATAACAGTTACGGTTTCCGGCGCCTGGAAGGGCGCCGGAATGAAAAGGGAACCCGGTGAAAATCCGGGACAGTGCCCGCTGCTGTGATCCCCCCGTCGGCATCTGCCGGCGGCGCGGTGCTTCCGAAAAGGCCACTGGTCCGCGCCTGCGGACCGGGAAGGCCGGAAGCATGGGGAGAGTCAGAAGACCTGCCGTAACGAAGTAATGCTTC
->KK502588.1/105838-105391 Glossina austeni unplaced genomic scaffold Scaffold188, whole genome shotgun sequence. 
-AGAAGAAAAGATAGGGAAGTGCTGGCTGCAGCCTACTGGGAAGATGGCCAAGGTCCGAATATAAGCGTGTAACACAGATTGATAGCTTTTTCTCAAATCAGCGGATTGTGGTGGATGATCGTTCTTAGTTCTTATTACAAAAAGATGTTTTAAGGGTTAAGGTGTTGAAGCTTTTATGGAATCTGTTTATAAAAGTGGAACCGTATCTGTTAGTTTGTGTTTTTATAGGAGAAAATAATGCGATTAAGCAATGACAGCTCTGTAGCGCCTTTATATGCCCTGGGCTGCACAATGAACGTATTAATATATATTCCCTAGACCTAGTGATCCGGATAAATCGCTGGACCACTTTCAGACTTGGAATTGTGAAATGAAACTGTTCATTTGGAACTTGGAATTCCCAGTAAGTGTGAGTCGTTAATTCACATTGATTGAGTCCATGCTCTTT
->AFSB01210878.1/11034-11234 Heterocephalus glaber contig210878, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGTAGTATCAGAAACCAAACAAACCCCAAACAAGATGAAATCCATAACGAAAAACACAGTACTAAAACTGTCATTTACCAAAGATAAAAGGATGCATAAGAAAAGCAGTCAGAAATTTTTGTAAAAATTTTTGAGCTCACTGGGGATTTAGCTCAGTGGTTTGACCGCCT
->MLAU01024954.1/4432-4362 Lupinus angustifolius cultivar Tanjil contig_24954, whole genome shotgun sequence. 
-CTTTTTATGGTGAATTAGTGTCCCAATCGATTTAAGATTGAATAAAAATGGTTCGAACCCATTTGAGGGGA
->AACT01006374.1/1536-1721 Ciona savignyi cont_6374, whole genome shotgun sequence. 
-TGGTTTGTAATGTTGAGATTGATATATGAGTTTGCAAGAAAGCTGGCTATTTTGTTGGTTTTCGGAGAGCGAGGTAATGATTAAAAGAGACAGACGGGGGCATTCGTACTGTGCCGTTAGAGGTGAAATTCTTTGGATCGGCTCAAGACAAACGACTCGAAAGCATTAGCCAAGAATGTTTTCTTT
->CH990426.1/969-1 Drosophila simulans chrU_M_6102 genomic scaffold, whole genome shotgun sequence. 
-TTAGGGTATTTCCGGGGGGGTTTTTTAATGGGATTAAAATTTGTTTTTTTTCTTATGTTCTTCTTATTAAAAACCTGCATTGGGGTTTTTAAACGAGTGTTTTTTTGGGGCGGGTATTTTTCTTTTGAACAAATTAGAGTGTTTAAAGCAGGTTTCAAATGCCTGAATATTTTGTGCATGGGGATAATGAAATAAGACTTCTGGTTTGTTTTCATTGGGTTTTCAGATCAAGAGGTAATGATTAATAGAAGCAGTTTGGGGGCATTAGTATTACGACGCGAGAGGTGAAATTCTTGGACCGTCGTAAGACTAATTTAAGCGAAAGCATTTGCCAAAGATGTTTTCATTAATCAAGAACGAAAGTTAGAGGTTCGAAGGCGATCAGATACCGCCCTAGTTCTAACCATAAACGATGCCAGCTAGCAATTGGGTGTAGCTACTTTTATGGCTCTCTCAGCCGCTTCCCGGGAAACCAAAGCTTTTGGGCTCCGGGGGAAGTATGGTTGCAAAGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGAAAACTTACCAGGTCCGAACATAAGTGTGTAAGACAGATTGATAGCTCTTTCTCGAATCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTCGTGGAGTGATTTGTCTGGTTAATTCCGATAACGAACGAGACTCAAATATATTAAATAGATATCTTCAGGATTATGGTGCTGAAGCTTATGTAGCCTTCATTCATGGTGGCAGTAAAATGTTTATTGTGTTTGAATGTGTTTATGTAAGTGGAGCCGTACCTGTTGGTTTGTCCCATTATAAGGACACTAGCTTCTTAAATGGACAAATTGCGTCTAGCAATAATGAGATTGAGCAATAACAGGTCTGTGATGCCCTTAGATGTCCTGGGCTGCACGCGCGCTACGAATCCACCA
->CP000682.1/2154080-2154188 Metallosphaera sedula DSM 5348, complete genome. 
-GCCGGGGTGCCCGAGCGGACCAAGGGGGTAGGCTCGAGACCTTTCCAGCGTTAAAGCGTGCGACCTACTGTCTCTCCGAGACACGCGGGTTCAAATCCCGCCCCCGGCG
->CBUU010045831.1/1-300 Eimeria praecox, Houghton, WGS project CBUU01000000 data, contig: Eph_scaff15802_1 
-GAGCAATGCGGAAGACACAGTGAGGTGGGGAGTTTGGCTGAGGCGGCACATTTGTGAAACAATAGCGCAGGTGTTTTAAGGCAAGCTCAATGAGAAGAGAAATCTCATGTTTACCAGAAGGGGAAAAGCTTGCTTGATTTTGATTTTCAGTACGAATACAAACTGTGAAAGCATGACCTATCGATCCTTTAGGTCTGAGAAGCTTTCAGTTAGAGGTGGCAGAAAGGTTACCACAGGTATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGG
->KB016908.1/814362-814466 Camelus ferus unplaced genomic scaffold scaffold638, whole genome shotgun sequence. 
-ATTTCAAAAAATTATCCCCAGGAGGGCTCTGGACCCCTCGGCATTGTATCTTCAGTACCGGCAGCTTGCAGTCCACCAGTTCAATCCTCAAGCGCCAGAACACGG
->JQBS01000032.1/75904-76076 Carnobacterium divergens DSM 20623 NODE_75, whole genome shotgun sequence. 
-ATAAAAAATAGAGGTGCAACAATTATCAGTAATTAGTTGGAGGTTTGACAAAACCTGTGAAGACTAGTGAAAGGAATTTTTGCCGAAACAAAAAACTGTCATCTTTTTGTTGGGTCTTAGGTTGAATAAGCCGAGAACTGTCGCTTATCTTTAAGCGTTGCGCTATCTTACTG
->CM000839.2/46388956-46388601 Glycine max cultivar Williams 82 chromosome 6, whole genome shotgun sequence. 
-CATTAGAGCATTAAGAAGACATTTCCCTAGTACAAGAATATTGGGAAGGACTCACCTTCGGTGTGCCAGTTATCGTGCCCAGCCACGGTAAACGTTGGGTTGCCAAGTGTGGAGTAGATAATTGCTGAAAGCATCTAAGTAGTAACCCTAAGGTGAGTGCTTTCATATTTCAACTTCCCCAAAGCCTCCGGTAGCACAACTGAGATAGTGATGGGTTCTCTGGCCCAACAGGGATGAAGTGAAATTTTTTAAAGAATTCAAGAGAAGGTCACAGTGAGATGAGTTGTTGCTAATTAATGATAGGTGTCAAATAGAAATGCAATGATGTATGTATCTGAGGCATCCTAACAAACCGT
->ALWZ040783527.1/524-606 Picea glauca, whole genome shotgun sequence. 
-TATGGCATAGGATGTTATATCTTATTCTACACACTGAAATTACCGTGTAGATAACTATACACCTCTGACAAGCTGATGCCAAC
->AAYZ01665444.1/416-340 Ochotona princeps cont2.665443, whole genome shotgun sequence. 
-TGCTCTGATGACACAGGTAGCAAATAGGAAGTGCCGTCAGAGCGAGAACTGACGATCCTGGAGACGCGTGTCTGAGC
->AFYH01197597.1/1946-2009 Latimeria chalumnae contig197597, whole genome shotgun sequence. 
-TACACTTTAGTGAAGGCTATATAGAAAACCTTTCAAAGGCATATGTAGTCTGATGTTGTGTGTA
->MHXH01000017.1/67050-63467 Parcubacteria group bacterium RIFCSPLOWO2_01_FULL_48_18 rifcsplowo2_01_scaffold_382, whole genome shotgun sequence. 
-GGGCATATGGTGGATGCCTTGACTTGAGAAGGCGATGAAGGACGTGGCGTGGCTGCGATAAGCTTCGGGGAGGCGCTTAGCAACCTATGATCCGGAGATTTCCGAATGGGGAACCCCCGCCGTGCAAACCACGGCGAGCCGTGCTTTGCACAGAAATCCGAAGTACGAAATACGAAATCCGAAACAAAAAGCTTCGAATTTCGATATTCGAATTTCGAGTTTCCGCGCAGAGCGCGGCGGCGTACCCGCTGAATTGAAACATCTTAGTAAGCGGAGGAAAAGAAACCAACATTCAGCTCTACGCTGTGCTAACTAAGTTACCTGCTCAATTTTTTGGATTTGGAGAATAAAAAAAGAGGACCGTCGCGCGCGGCGGTCCCAGAACTCAAGCACCCCGAGGACAGAAGTCAAGCAAGGGATGCTGATAGTATTATAGCATGCTGGTAGGTTTTGTCAAGAGTCCAAAAATTTGAGCAGGTATAAGGTTGGAACAGTGTTCTACTGAATCATTCCCTTAGTAGCGGCGAGCGAAAAGGGAGGAGCCTAGAGCTCGGGTGTGCAGCATCGGGAAGCTTCAAATTTCAAAGTCCATATTTCTATTTTTTTCGCGAAGCATATTTCAAATTATTTCAGAAATATGTGGAAATATATAGAAACTCAGAAATATGCGGACATATTTTGTCATTTGGAATTTCCGCTGCTGTGCATCTGGGCAGTTGTAAGATAGTAACGTCTTCCTGATTTATCAGAGAGGGGGGGTGTAAGTAAGACTTCGTTAGTAGAACAACTTGGAAAAGTTGGCCAAAGAGGGTGATAGCCCCGTATGCGAAAACGGTCTTATAACCCCAGTTATTATCGACTCTTTAGAGTCGGAGCTATGATATTTTTACATGTCGTAGTTTCTTGAGTACTTCGACGACAGAAAGCGTCGGAGGAAACCGCGAGTACTATCTCGCAAGGCTAAATACTTCTCAAGATCGATAGTGAACAAGTACCGCGAGGGAAAGGTGAAAAGTAGCCCTATTAGGGCAGTGAAATAGTACCTGAAACCATATGCTTACAAGGAACCGAGGCTGAGCATCTCACTGTCGTGAGATGCGGAATATAGAATCTTGAATTTTGAATTTGGAATGATTATTCCAAATTCTCCCGCCAATCTCCGAAGGGCGAAGCCCTAGGCAAGATTGGCGAGGATCCCGTACTGTCCGCGATGAAGATAGGACAAAATCTTCATTCGGAGATTGGCGGGACCCTAGCCAACTGTAGCCGCTCTCCCGCTTTCAGCGGGATCGCGGACAGTTGCGGGACAACTTCTTCCGCCAAAGGCGGATCCGCCTCAGGCGGAAAATTCTGCACCGAACGAGAGTGAGGTGCTTGGTGACGGTGTGCCTATTGAAGAATGAGCCAACGACTTTATCTATGTTGCAAAGTCTAATCCCGAAAAGGGAGAAGGCGCAGGGAAACCGAGTGTTAAAAGCGCGTTACTTTAGCTCGATAGCTTTTTAGCTCAACAGCTCGTTAGTTTTCTATCGAGCTAACGAGCTAATCGGCTAACGAGCTTAAGTTAGCAGCATGGATAAGACCCGAAACCAGATGAGCTTGCCATGGCCAGGATGAACGCCGGGTAACACCGTCGGGAGGTCCGAACCGGTGGGTTGTGCAAAACCCTCGGATGAGCTGTGGTAAGGAGTGAAAAGCTAATCGAATCTGGTAATAGCTGGTTCTCCCCGAAATCGCTTTAGGGCTAGCGGCGTTTTATGTCATGCCGGAGGTAGAGCTACTGGATGATCCTCAAAGGGCGAAAGCTCGGATGATCAATCAAACTCCGAATGCCGGCAGGATTACAACGCTAGTTAGACCGTGGGGGCTAAGCTCCATGGTCGAGAGGGAAACAGCCCAGATCGCCGTCTAAGGTCCCTAAATTCTTGCTAAGTGTAAAAGGTAGTAATCAGCCGAAGACAGGTAGGAGGTTGGCTTAGAGGTAGCCATCCTTTAAAGAGTGTGTAACAACTCACTATCATATCGGCCGCATCTCACTAAGGCGAGATACTTGAATGACCAATTTCTAATTGACCTAATTTCTAATAAATTTCCAATACCCAATTTCGGAATTCGGTTACTGGGATTTATTTAGAAATTAGAAGTTAGGATTTAGAAATTTGAGCACCGAACTTTAGTGAGGTGCGGTTGATTGGCTGGTTGCGCCGAAAATGTACCGGGGCTAAGCAAGATACCGAAGACGCGAATTACCTGCTCAAATTTTTGGACTAATAAAATAATAAAAAAGAGGCCACCCATTGACGAATGACCCCTGACCTGACTCGTGGAAGTTCTTGTTAGACGACTATGGTCGTAACGACCGCGACGATCACCCAAGAGCCGTAGATGAGTGTTCCTTTCATGGGTTCAACTCTCCACGCTTCGATCATGCGGCTTTCCGTAGCTCATGATCATTGAGATCGTTATCGCCCCAAAGACTAATGCCGAAACAAGTGAAGAAGTCGGTTCCACGACAAGCTCCTTGATTGAGGGTTCGTTGCAATTATAGCATAAAGTTAAGTTTTTTGTCGAGAGTCCAAAAATTTGAGCAGGTAGTGGTAGGGGAGCATTTTGTGCGCAGCGAAGGTTGACCCGCGAGGGCGACTGGAGCGCACAGAAGAGAGAATGTTGGCATGAGTAACCAACAATGCCGATGAGAAATCGGCACTCCGTAAGCCCAAGGTTTCCGTGGCAATGGCAATCAACCACGGGTGAGGCGGTCCTAAGCCGATGGCGAAAGCCGAAGGTGATGGACAGACGGTTAATATTCCGTCCCACCGATACTATTTCGATGGAGCGACGGTTGAAATAAGGCCGGGCGTCTTAATGGTTTGACGCTGTTTGCTTGAAGGAATGTTGGACAGGCAAATCCGTTCAACTGTCTTTTATGGCAAATTCCGAAAGCAGACGAAAGTTTTGGTTTTTACCAGGGCAATCCGGCTGAAGAGCGATCCAAGAAAAACTTCTAGAGTTAATAGTATTGGTTCCGTACCGCAATCCGACACTGGTGGGCGGGGCGAGTAGCCCAAGGAGAACGAGTGAGTCCTCGTTAAGGAACTCGGCAAAAAAGCGGCCGTAAGTTAGCGATAAGGCCTTCCCGAGCACCGCAAGGTGCGAGGGACGCAGCGAAAGTTTGCCTGGCGACTGTTTATCAAAAACACAGCTCCCTGCTAACTCGTAAGAGGATGTATAGGGGGTGACGCCTGACCGATGCGAGAAGGTTAAACGATGGGGGTCGTATGCATCTCACTAAGGCGAGATACTTGAATGACCAATTTCTAATTGACCTAATTTCTAATAAATTTCCAATACCCAATTTCGGAATTCGGTTACTGGGATTTATTTAGAAATTAGAAGTTAGGATTTAGAAATTTGAGCACCGAACTTTAGTGAGGTGTGTACGGCTCACTGTTGTAAGCCCTCGTCAATGTCAGCGATAACTATAATCGTTCTAAGGTAGCGCAATTCCTTTCCGGGTAAGTTCCGGAGCGCACGAAAGGCGTAACGACTGGGCAACTGTCTCAACGAGGAGCTCGGTGAAAATG
->ABRO02033478.1/54894-54660 Dipodomys ordii contig_33478, whole genome shotgun sequence. 
-GCTGGGCGCTGTGGTGCGCCTGTAATCCCAGCTATTCGGAAGGCTGAGTCCAAGAGTTCTGGGCTACAGTGCGCTATGCCGATCGGGTGTCCACACTAAGTTCAGCATCAATATGGTGACCTCCCGGGAGCGGGGAACACCAGGTTGCCTAAGGAGGGGTGAACCGGCCCAGGTCAGAATTGTGACTGTGGTTCTGACATAGGAATAGACAGGTAGAACAATGAAACAGACTAGT
->ABGB01001252.1/615-1121 Enterocytozoon bieneusi H348 ctg01_717, whole genome shotgun sequence. 
-CATTAGGTTGATTCTGCCTAACGTAGATGCTAGTCTCTGAGATTAAGCCATGCATGTCAGTGAAGCCTTACGGCGGAACGGCGAACGGCTCAGTAATGTTGCGGTAATTTGGTCTCTGTGTGTAAACTAACCACGGTAACCTGTGGCTAAAAGCGGAGAATAAGGCGCAACCCTATCAGCTTGTTGGTAGTGTAAAGGACTACCAAGGCCATGACGGGTAACGGGAAATCAGGGTTTGATTCCGGAGAGGGAGCCTGAGAGATGGCTCCCACGTCCAAGGACGGCAGCAGGCGCGAAACTTGTCCACTCCTTACGGGGGAGACAGTCATGAGACGTGAGTATAAGACCTGAGTGTAAAGACCTTAGGGTGAAGCAATTGGAGGGCAAGCTTTGGTGCCAGCAGCCGCGGTAACTCCAACTCCAAGAGTGTCTATGGTGGATGCTGCAGTTAAAGGGTCCGTAGTCGTGAATGCAATTAAATGTCGTTGTTCAATAGCGATGATTGCT
->KV453914.1/432734-432532 Candida tanzawaensis NRRL Y-17324 unplaced genomic scaffold CANTAscaffold_6, whole genome shotgun sequence. 
-ATCATCAGTAGTGGTTATACTATATCTAATATATATAACTATTATTTCATAAAGATCTTGGATGGAGGCATGCATATCATAGATGTGTGCAGGCTGACCATTTAACTACCCATAGCTAAGCATTCGTTGACCTAACTAACAATTGGGCCACAACGAGTGTTTCGTTTCGGTCTTTTAGATTATTACGTTTGTTGACGGCATTC
->CM000034.3/40324702-40324549 Canis lupus familiaris chromosome 34, whole genome shotgun sequence. 
-AGCTTTACGCAGTGGCAGCATCATAGCCAATGAGGTTTATCTGAGGCACGATTATTGCTAATTAAAATATGGAGGCAACATCTCAAATTCCACCCTGGTTCATTCAACTTTCTGGAGACATCTAGCTTTTTAGCAATCAGATCATGCTATTCTG
->JYDM01000907.1/879-1 Trichinella sp. T8 scaffold908s, whole genome shotgun sequence. 
-GTATCATTCCTGGGGGAAGTGGCGCGGAAGGAAGGTTACCAGGTCATGATAGAGCCTAAGGTGTCAACCCCGGTCGGCGCGCTCAAGCCCGACCTCCTTCTCATCAAAGCCGACACTGCATTCATTGTGGATGTAGGCATTGCGTGGGAAGGTGGACGCCCACTAAAGCTGGTCAACAAAATGAAATGTGACAAGTACAAGATTGCCATCCCGGCAATTTTGGAAACATTTCACGTTGGCCATGCTGAGACGTACGGCGTTATTCTGGGCAGCCGCGGATGCTGGCTCAAGAGCAACGACAAGGCGTTGGCATCAATTGGGCTCAATATCACACGGAAGATGAAAGAACACCTGAGCTGGTTGACGTTTGAAAACACCATCCGAATTTATAACTCATTCATGAAGAACTGAGGTTTTTGTTTTCTTTTACCTTTTACCATTTTTTATTGTTACATTGTTGTTATTTGCTTTAATCCTGCATTTTACCGTCGGCAATTCCATCGTTATTATTACTGTTATTGTTATTATTATTACTATTGTTATTACTTTTACTTACTATTGTTATTACGATTTATTTCGTATACTTACGTTATTGTTACTACTACTTACTTTGCTCTCGCAAACGTTCGTTGTTGTTACTTTTGGACCAGGTTTAGAGAAATCGCACGCACAGCGGAACTGGACCGCTTAAGCCAGAAACAGTAAAGTAACAATAGCCAAATGCCTCGTCATCTAATTAGTGACGCGTATGAATGGATCAACAAGATTCCTTCTGTCCCTATCTACTATCTAGCGAAACCACAGCCAAGGGAACGGGCTTGGCAAAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCTGACTCTGTGAA
->MEUW01000021.1/52640-49699 Candidate division WWE3 bacterium RBG_19FT_COMBO_53_11 rbg_19ft_combo_scaffold_7, whole genome shotgun sequence. 
-AAGAAGGTCTTTTTATAAGGTAGATGAAGGATGCCTTGGGGCAAAGGGCCGATGAAGGACGTACTAGGCTGCGATAAGCCTCGGTGAGCTGCCACGAAGCGTTATTAACCGGGGATTTCCGAATGGGGTAACCCAATCCGTAAGGATTACGCTTAAGCCAAGTTCCTGCCTTTTGGCGGGATAGTAACTTAAGTGAGGGAACTCAGCGAAGTGAAACATCTCAGTAACTGAAGGAAAAGAAAGAGAAGCGCTTTATGCGCGGGTTCCCTAAGGACTCTCGCGATTTATTTCGCGGGAAACCTTGGGGAATCTTCGATCCTCCGAGTAGCGGCGAGCGAAAGGGGGGAAGCCTAAACTCCGGCGCAAGCCGGAGGGTTGCAGGACCTGCATTAGGAAAATTATTGGTAGGAGAATGCCCTGGAAAGGGCGGCCATAGAGGGTGAAAGCCCCGTAACTTAAACTGGTAATTTTCTGGCGGGAATCCTAAGTATCACGAGAAAAGTGAAAGCTTGTGAGAATCGAGCCAAACCACTGGCTAAGGCTAAATACTCTTTGCCACCGATAGTGAACAAGTACCGTGAGGGAAAGGTGAAAAGAACCCCGGTAAGGGGAGTGAAATAGAATCTGAAATCATCTACTTACAAGCAGACGGAGCCCGCAAGGGTGACGTCGTGCCTATTGAAGAATGACCCGAGGAGTTATCGCCAGCAGCAAGGTTAATCGCGTCAAACGCGGCGAGCCGTAGCGAAAGCAAGTCCTAAATGGGCGAATAGTTGCTGGTGGTAGACCCGAAACCTGGTGAGCTAGCCATGGGCAGGATGAAAGCCGACGAGAGTCGGCTGGAGGTCCGAACCGATGTGCGTTGCAATGCGCTCGGATGACCTGTGGTTAGGGGCAATATACCAATCGAACCAGGTGATAGCTGGCTCTCCCCGAAATGTATTTAGGTACAGCCTTGCAAAGTAACGAAGGGGGTAGAGATACTGGAAGGAATGCCGAGCCCGCAAGGGTATCGCTTCCTACCAAACTCCGAATACCTTCGCGAAATTTGCAGGAGTGAGCAGGCGGGAGCAAGTTCCGTCGTGCTAAAGGGAAACAGCCCAGATCATCGGTTAAGGTCCCTAAGTTGGATTTAAGTGGGAAAGGCAGTGGAATTTCTTAGACATCCAGAAGGTAGGCTTAGAAGCAGCCATCCTTGAAAGAGTGCGTAACAGCTCACTGGTTGAGAAATTCTGCGCCGAAAATGTAACGGGGCTCAAAATCCACACCGAAACCGTGAACTCGCCGCAAGGCGAGTGGTAGGGGAGCGTCGCCACAGCAGTGAAGCTGGATCGTAAGGTCCGGTGGAGCGGTGGCGAGTGAGAATCTCGGGATGAGTAACGTTTGGCGGTGAGAATCCGCCTCGCCGGAAGTTCAAGGTTTCCTCCGCTCTGGTCGTCATCGGAGGGTTAGTCGGTCCTAAGCCGAGGTCGAAAGACGTAGGCGATGGGCAGGGCGTTAATATTCGCCCACTTCCGTCCGGTTCGATGGGGTAACGTTTTCCAAAGTTGCGAGCGTCCGCATGGTTGGGCGTTCGGCGCACCAAGGTGCTTTGTTGGCAAATCCGCAAGGCATAAGCCAAGGTGTGACGGGGAGTCCCGTAAGGGACAACTCGTGAGGCTGGAGAACCAAGAAAAACCTCTAAGTTATGCCGGACGGGATCCGTACCGCAAACCGACACAGGTGAACTAGGTGAGTAGCCTAAGGCGAGCGGGATAACGTTCTTTGAGGAATTCGGCAAGTTGGCCCCGTAAGTTCGCAAGAAGGGGTGCCCCGACTTAAACGTCGGGGTCGCAGCAACAAGGCTCAAGCGACTGTTTAACAAAAACACAGGTCTCCGCTCAACCCGTAAGGGGATGTATGGGGGCTGAAGCCTGCCCAGTGTCCGTCGGTTAAGGAGAGGTCTGAGATTATTTCAAGGATCGAACCTAAGCCCGGATGAACGGCAGCAGTAACTATAACTGTTTTAAAGTAGCGAAGTTCCTTGTCGGGTAAGTTCCGACCCGCATGAAAGGCTTCACGACTTGAGCACTCTCTTAAAGAATGACCCGGTGAAATTGAAATGGCCGTGAAGATGCGGCCTACCCACAGCAGGACAAAAAGACCCCGTGGAGCTTTACTGTAGCTTGACATTGGTTTGATGATCGGATTTGTGTAGCGTAGGAGGGAGCCGCAAGGCGCCAATGAAACACCTCTCGATTTGATCCTCAAATCTTACTTAGGCGGTTAACCCGTCTGGGAACAGTGTCTGGTGGGCAGTTTAACTGGGGCGGTTGCCTCGCAAAGAGTAACCGAGGCGCCCCAAGGTCGGCTTAGTCTCGATGGACACGAGACTGTAAGTGCAAAGACATATGCCGGCTTGACTGCGAGACCAACAAGTCGAGCAGGTGCGAAAGCAGGGCTTAGTGACCTGTTCACTTCGAGTGGCGGAGTGAACAACATCGGACAAAAGCTACCCCGGGGATAACAGGCTGATCTCCTCCAAGAGTCCATATCGACGAGGAGGTTTGGCACCTCGATGTCGGCTCGTCCTATCCTGGGGCTGAAGAAGGTCCCAAGGGTTTGGCTGTTCGCCAATTAAAAGGGCACGCGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGACTCTATCCGCTGTGGGCGTTTAGCTTTTGAGGGGATTTCTCTCTAGTACGAGAGGACCGAGAGGAGCCAACCTCTGGTGTACCGGTTGTCCTACCAAGGGCATAAGATATGCCGGGTAGCTATGTTGGTAAGGGATAAGCGCTGAAAGCATCTAAGCACGAAGCCCACCCCAAGATGAAAAGCAGACCCCTTGTAGACTATAAGGTTGATAGACGGCAGGTGGAAGCGCAGTAATGCGTTAAGCCGAGCCGCACTAATAGGTCGTTTGATCTTCTTTT
->APMT01169783.1/38025-37737 Mesocricetus auratus contig169783, whole genome shotgun sequence. 
-AGATGTGAGGGCAATCTGGCTGTGGCATCTGCCATCTCATGAATCACCAGGGTTGATTTGGCTGATCTAGCTGGCTAGGCTGGTGTCCTTTGTCTCCCTCACCATGCTTTGTGCATCCCTCCTAAGGCTGCACACTCAGTCAAAAAGGACAACCTTCCCCAACTAGAGAAAGACCTATCTTCAGTTAAGAATATACTAGTAGCTGTGTTCCCCTGATAGAACTTCAAACAAGCTCTCAAGGAACTACTTAAGTGGGGCCAGTAAGAACTTCGGTGCATGTAACTCAGTT
->JJRN01037118.1/15094-15301 Fulmarus glacialis contig37118, whole genome shotgun sequence. 
-AATCCAGTGAAGGATTCACTGAAGGAAACTGCTTCAAATCCTGGATTCAAGCAAATTAGGAAGTTTGAACAAGGAAAAGACCTATAGGTGAGTTCAGATCTTCAGATTACCCCAAAATACCTTTTGTTCTAAGTTAGCTTACCTAGAGTTAAAACCTTGCTCTGCTTTCTATTTTTGCTCAAACTGACGTATCAGCAGAAGGTGTGGG
->JJRE01079984.1/1-608 Phoenicopterus ruber ruber contig79984, whole genome shotgun sequence. 
-TTTTCATTAATCAAGAACGAAAGTCAGAGGTTCGAAGACGATCAGATACCATCGTAGTTCCGACCATAAACGATGCCGACTGGCGATCCGGCGGGGGTATTTCCATGACCCGCCGGGCAGCTCCCGGGAAACCCAAGTCTTTTGGTTCCGGGGGGAGTATGGTTGCAAAGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGAAACCTCACCCGGCCCGGACACGGACAGGATTGACAGATTGAGAGCTCTTTCTCGATTCCGTGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGCGGTTAATTCCGATAACGAATTAAGCGCGCCCTCCCTCCATTCCCTCCGCTGCGCGGTGGAGGTTTTGGACTTGCGACCTCAGATCAGACGTGGCGACCTGCTGAATTTAAGCATATTAGTCAGTGGAGGAAAAGAAACTAACGAGGATTCCCTCAGTAACGGCGAGTGAAGAGGGAAGAGCCCAGCGCCGAATCCCCGCCCCACGGTGGGGCACGGGACATGTGGCGTACAGAAGCCCCCCTCCCCAGCGGCGCTCTCGGGGGACAC
->JXUM01141515.1/11783-11841 Aedes albopictus isolate Foshan contig141515, whole genome shotgun sequence. 
-TAGCCTAGTGGTTAAGGCTATGGATTGCCAATCCGGAGACGGCGGGTTCGATTCCCGAT
->JH836770.1/104900-105236 Erinaceus europaeus unplaced genomic scaffold scaffold01482, whole genome shotgun sequence 
-GGATGTGAGGACAATCTGGCTGTGACATCTGTCATCCCATTGATTGCCAGGGTTGATTCAGCCTATCTGGCTGGCTGGGCAGGTGTCCCCTCCTCCCTCACCTCCCTCACCGCTCCACGTGCATCACTCCTTTGAAGAGGACAGCCTTCCCAAATAGAGATGGACCAGTCTTCGGTCTAGGGTATACAAATAGCTGCGCTCCCCTGCTAGAACCTCCAAACAAGCTCTCAAAATTGTCAAACCCTTAGTCAGACTTACTAGAAAAGGGCGGTGGGCTAGAAGATACAAATATATAGAACTGTAAACAATAGAGGAGATACTGCCCTCCTTACTAGTT
->CP003597.1/1039739-1039660 Chroococcidiopsis thermalis PCC 7203, complete genome. 
-ATCGTTCATCTCTCTTAAAAACACTCTTCACCGGATGCTGAGAGAGACGGAAGTAAGGAAATATCCAGAAGGAACGCACG
->APGL01003207.1/3249-3375 Dendroctonus ponderosae Seq01003220, whole genome shotgun sequence. 
-TGAGGGGTTTTTAGTGGGTAGGCAGCCCCACGGGACTGAATCCCACATAACCTAGCCGACAATGAACATCGTCGGCACAAAATCCAGCACAACATCGGCTGGGTATCTTTGGAAGATTTTCCCCTCA
->KK198759.1/5784749-5784536 Eucalyptus grandis cultivar BRASUZ1 unplaced genomic scaffold scaffold_7, whole genome shotgun sequence. 
-TAGCGACTGTTTATTAAAAACACAGGACTCTGCTAGGTGGTAACAGGATGTATAGAGTCTGACACCTGCCAGGTGCTGGAAGGTCGGAAGGAGAAGTGTTATAAGCTTTGAATGGAAGCCCCAGTAAACGGCGGCAGTAACTCTAACTGTCCTCTTTTCTTATTTATTTGACTCTATTTGAAGTATATTTCTTGCATCTTTTTTGTAATTATTA
->KB317698.1/876973-877093 Rhizoctonia solani AG-1 IA unplaced genomic scaffold scaffold3, whole genome shotgun sequence. 
-GTCCTCTTCGGAGTGACATATACAAAAATTGGAACGATACAGAGAAGATTAGCATGGCCCCTGCACAAGGATGACACGCTAGTTCAGAGTGGACGGTCTACGGACCGCAATATTTATTTTT
->MJEQ01005272.1/36510-37593 Nicotiana attenuata strain UT scaffold05272, whole genome shotgun sequence. 
-TACCTGGTTGGTCGTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCTATGCATGTGTAAGTATGACCAAATTCAGAATGTGAAACTGCGAATGGCTCATTAAATACGTTATAGATTGTTTGCTGGTATCTACTACTCGGATAACCGTAGTAATTCTAGAGCTAATACGTGCAACAAACCTGACTTCTGGAAGGGTTGCATTTATTAGATAAAAGGTCGACGCGGGCTCTGCCTGTTGCTGCGATGATTCATGATAAATCGACGGATCGTACGGCCATTGTGGCGGCGACGCATCATTCAAATTTCTGCCCTTTCAACTTTCGATGGTAGGATAATGGCCTACTATTAGACCCTAACTCTCTTTCATCGGGCGTGGCACGCCTATGGCAAGAATTTGGGTGTGATTGCCTTGTCATTGGCCTATGTGCGTGCGAAACGATCATGCGGACGATGGACAAGATATTGTCATTGAGGGCTGTTGTGGGCAAGTATTGGCCAAGGCCTTGGGACAGGCAAGGCGCGCTTTTCAAAGGCTTGACAAAGCAGCGTGGGCAATGTTAGGGCGGCATGGCACGACATGCACGCCAAAGTCAGTGGAACGACACTTTGGGTTGTGGCAGCTAAGTGCGGGCTAAGCTAAGGCAAGGCGAAAATGCGGGATGATGGCAAAGGCTTTCAATAGCTAAGGCAAGGCTTGTGAAGGAAAATACAAGCAATGGCACGAGGGAAATGAAGGTTGACATGGACAAGGCAGAAACTAAGCCAAGGCAGTGCGCGGGCGGCAGCGACGTCGGGCGTGTGTGGCCAAATCATGGCAGCAGGTTGCGGGCAAGTCATTGGCGCAGAGCAATGTCAAATTGAGCTAAGGCTTGGCACAAAGCAAGCCTTAGGCGTGATTCAGCTGGCCAAGTGAAGATGGCACATGCAATGCACATGAAAAGCAGTTTTGGTGGTTACCTTGTCAGTAACCTCTTTGTCCCATGACTGNCGCGACGTCGCGAGAAGTCCATTGAACCTTATCATTTAGAGGAAGGAGAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTG
->CP001848.1/3411853-3411422 Pirellula staleyi DSM 6068, complete genome. 
-GGAGTTGGGCAGACGACCGCTGGCTGCCATTTGGCAGCGAGAGGAAAGTCCGGGCTCCACAGGACAGGGTGGTCGATAACGTCGACCGGTCGTGAGATCAGGGACAGTGCCACAGAAAACAGACCGCCGCTGCGGGCATGAGCCCCCGTCAAGGTTTGATTGTCTGCATGCGGTAAGGGTGAAACGGTGCGGTAAGAGCGCACCAGCAGTCGAGGCGACTCGGCTGGCTAGGTAAACCCCGCCCGGAGCAAGACCAAGCAGAGAGCATGTTGTCGGTGTCACAGCCGACAGCCGGAATCGGTTCGGTTTCGTATGACTCTCGGGTAGGTTGCCGGAGCTAGCGAGCAATTGCTAGCCTAGAGAAATGGTCGTCAGACGTTTTCGATCCGTCGAAGACGCCAACAGAACCCGGCTTATTGCCTGACTCCGAAA
->APMT01097187.1/1014-904 Mesocricetus auratus contig097187, whole genome shotgun sequence. 
-GTGCTTGATTCAGCAGCACATATGTTAAAAATTGGAACAAGACACAAAAGATTAGCATGACCTCTGTGCAAGAAAGTATCCAAGGGGGCTGGAGAGATGGCTCAGAGGTTA
->GG697144.2/1-676 Mitsuokella multacida DSM 20544 genomic scaffold Scfld3, whole genome shotgun sequence. 
-AGGCTACGAAAGCGGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAATGCTAGGTGTAGGAGGTATCGACCCCTCCTGTGCCGGAGTTAACGCAATAAGCATTCCGCCTGGGGAGTACGGCCGCAAGGCTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGTATGTGGTTTAATTCGACGCAACGCGAAGAACCTTACCAGGGCTTGACATTGAGTGAAAGGGCTAGAGATAGTCCCCTCTCTTCGGAGACACGAAAACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTATCCTTTGTTGCCAGCACATAATGGTGGGAACTCAAAGGAGACTGCCGCGGACAACGCGGAGGAAGGCGGGGATGACGTCAAGTCATCATGCCCCTTATGTCCTGGGCNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNCCCATTGCGGAAGATTCCCCACTGCTGCCTCCCGTAGGAGTCTGGACCGTGTCTCAGTTCCAATGTGGCCGTTCATCCTCTCAGACCGGCTACTGATCGTCGCCTTG
->CP000270.1/1720642-1720704 Burkholderia xenovorans LB400 chromosome 1, complete sequence. 
-CCGTCTCTCAGGTTCTAGCACGGCCCTCGGAATGGCTAGAACTTTTGGGTATACGGATTTAAT
->KX552040.1/184526-184806 Kaumoebavirus isolate Sc, complete genome. 
-CCGAGTCTCAGATTAAAGCTGAGGCTAGTTACGCATTAATGAAAAATGCTAGCTACATTCGTAAATTGCGGGAAAATCTCACGATTAATAACACCATTAGCAGCTTGAGAAAGTTGCTGAGAACCTCAGGGAAACTTGAGAACAACGGTAAAAGATTATTAATAGAGACAATCCGCAGCCAAGCTTGTGAAGAAATATCTACACAAGAAGGTTCAGAGACTTTATACGAATGGGCGGTTCTACCGCTTAAGATAAAGTCCATGCCCCACTGTGAAGTGGAT
->LVLJ01001741.1/199221-199340 Marchantia polymorpha subsp. polymorpha scaffold2490, whole genome shotgun sequence. 
-ATCTTTGCGCTTGGGGCAATGACGCAGTTCATGAGGTGAAACCGCGTCAATTGCTGGTTGAAAACTATTTCCATAAACCCAAAATGTTCTGTGGATTGAATTTAAGTAAAATGCGTGCTT
->CYZX01000004.1/41603-41740 Clostridium disporicum strain 2789STDY5834856 genome assembly, contig: SCcontig000004 
-TAGTTTTGTGTTTTCTAGTGTGTAAAAGTCTAAGGAATTTTCTATGACTTTTACGCCTGAATGTTTATCATTCACAGGGCAGTAATTGAAAAGTTATTGTCTCCACGTATTTTGGGAAGGAAAATAAGTAGATTTAAT
->JPGV01000050.1/11129-10707 Chlorobium sp. GBChlB GB_Chlorobi_Contig_4394, whole genome shotgun sequence. 
-AAGCTGCGCGGCGGCGGTCGCTGCTCCGACAGGTCGGAGCAGAGGAAAGTCCGAACATCACAGGGCTGGGCGCCGGACAAGGTTTTGTCGGCAACGATGAAACACAAGTTCGGGCGGGCGAAAGCAATTTCGCTCGACAGATAGCGCAACAGAAAGCAAACCGTCTCGACGCAAGTTGGGATAAGGGTGAAACGGCGGTGTAAGAGACCACCAGTTAACGCAGTAATGCGTTAAGCTCGGCAAGCCTCCCCGATGCAAGACTATGTAGGAAAACTTTTTCCGCGAGGAAAAAAGAGTTGCCCGCTCAATTCATGCGCTTTCGGGCGCGGGAGAGTTTTCGGGTGAGTCGCATAGATAAATGACTGCCTCTCGTTCAAGCACTTGAGCGGGAAACAGAATTCGGCTTACAAGCGCGGCTTCATT
->CM001455.1/27997587-27997665 Oreochromis niloticus linkage group LG12, whole genome shotgun sequence. 
-GGCCTGCAAAATCCAATCACCACCTCCTCGCGGTGTCGGCTGGAAACAAGATCCTCTGGAACTTGGCTAACGGTGATGG
->APLE01000910.1/95410-95331 Erythranthe guttata cultivar DUN x IM62 scaffold_7_contig_2, whole genome shotgun sequence. 
-GCCTGTGATGATGCTTTATTCAAGAAATGCATTTATGCATTCATGTTGAAAACTCCATTTTGACTAGGACGGTCTGAGGC
->JZQY01000031.1/173164-173396 Nitrospira sp. OLB3 UZ03_NOB00100CONTIG000031, whole genome shotgun sequence. 
-GCGTCCCGGTAACGGGACCGTGGGTTCGAATCCCACCCTCTCCGCCATACTAGTGTGTTCGACCTCCGGCCGGTCTCGTAAGAATGTGGCGGCGGAGTCCGCCGTCGATGGTGATAGGGGCCGGGCCCTGTGCAACAGAACTCTGTGAACCCCGCCAGGTCCGGAAGGAAGCAACGGTAAGCGGTCCGTTCTGTGTGCCGCAGGATCACCTGGCCCCGCTAATTCTGGGACGT
->CM000401.2/17156931-17157025 Equus caballus chromosome 25, whole genome shotgun sequence. 
-TATGGAATCGCTGGATCATATAGTGGATGTATATTTTGAGAAATTGCCAAACTTTTTTCCAAAGTGCTTGTACTATTTCACATTTCACTAGCAAT
->CM001002.2/3260960-3260256 Mus musculus chromosome 9, GRC primary reference assembly. 
-GAGGGGTGTGGGTACAAAACTGAATCTTAAAGGAATTGATGGAAGTGCACCACTAGGAGTGGAGTCTGCAGCTTATTTTTGACTCAAAATGGGAAACCTCACCTGGCCTGGATATGGACAGCATTGACAAGATTGTTAGCTCTTTCTCAATACCATAGATGGTGGTTCATGGTAATTCTTGGTGGAGTAATTTCTCTGGTTAATTCTGATGAGAAATGAGATTCTGTCATGCTAACAAGTTATGAGACACCCACACACACACACAAGCAGTCAGCATCCTCCAATATTTTGAGGGACAAGTGGCATTCAGCTGCCTGATGTTGAACAATTACAGGTGCATGATGCTGTTAGATATCTTGAGCTGCACACCCATGACACTGACTGTCTCAGCATGTGCCTACCTTATGCTGACAGGCATGGGTAACCCGTTGAACTCCATTCATGCTGGGTGGATAGGGGATGGCAATTTTCCGTACGAATGAGGAATTCTCAGTAAATGTCAGTCAATAGATTGTGTTGACCAAGTCCCTGCCCTTTGTACACACTGCCCATCCCTACTACCGATTGGATGGTTTAGAGAGGCCCTCAGATCGACCCCACCAGGTTGGCACCTGGCCTGATCAGAAATTTGAGAAGATGGTTGAACTTGACTACCTACAGGAAGTAAAAGTCATAAGAAGGTTTCTGTAGGTGAACCTGCAGAAG
->JH836513.1/219899-219725 Erinaceus europaeus unplaced genomic scaffold scaffold01225, whole genome shotgun sequence 
-AAGACTGTACTTTCAGGGATCATTTCTATAGTTTGTTACTGCTTCCTTCTATGGTATCTAAATACAAACTTCTGTAAGAGCAGGAATTTTTCCTGTTTTAGCAAGCTTTAGTCCCAAGAATAGCAGACAGTAGTTTGCACATACCTTTTAAAAATGAATAAGGGATATTTTCTAA
->DS562880.1/7595309-7595616 Cavia porcellus supercont2_25 genomic scaffold, whole genome shotgun sequence. 
-AAATGCTGTATTAGCTGGCTATGGCTTCTGTCACCCCACTGATTGTCATGGCTGATTCTGCTGATCTGTCTAGGTGGGTGACCCCTTCCTCCTTCTCCCTCGCTGCTCCATGTGTATCTCTCCTGAAGCTATGTACTCAGTGGAAGAGAAAGATCATCACTGATAGAAGAGGACACTTTCCTCAGTCAAAGGTATACAAGTAGCTGTACTCCCCTACTAGAACTTCCAAAAAAGCTCTCAAAAAGTCATATACTTGCCAGGGTTACAGCTCAGCAGCAAGGCACCTGCCAGGCAAGCATGAGGTCCTG
->CCCW010013542.1/2343-2238 Brassica napus, WGS project CCCW01000000 data, contig: 30646 
-AATCCGTGGTGTGGACATTCTCGCTGGAAAAACCTAAATCTAATCCACGTATCTTTGAAGGACTCTCCAGCCTTCTGCGAGAATGTGGAAATTTTGTTCCGAAGTT
->Y11506.1/699-3910 Pamaria palmata 5.8S & 28S rRNA genes, ITS1, ITS2, IGS 
-GGATCTCAAATCAGACAAGATGACCCGCTGAATTTAAGCATATAACTAAGCGGAGGAAAAGAAACTAACAAGGATTCCCCTAGTAGCGGCGAGCGAAGCGGGAACAGCCCAAGATGAAAATCCCTTCGGGGAGTTGTAGTCTGAGTGTCCTTGGGTGGGTCAGTGCGGGCAAGTCTTCTGGAATGAAGCGCCATGGAGGGTGAGAGCCCCGTCCATCCCGCACAGGATCCATTCGTACAAGGACGCTTCAACCGAGTCGGGTAGCTTGGGAATGCTGCTCTAATTGGTGGTAAATCTCATCAAAGGCTAAATAGTGGTGGGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGATGGAAAGAACTTTGAAAAGAGAGTGAAAAGCACTTGAAACCGTCACGGGGGAAGCGGATTGCGTGAGTGATGGTGTCGCTTGTTCAGCGCTTTATTGCGTGCATTCTGGCGGCGCCGTGCCGGCGTGGCTGGCTGGACTGTGATTTTGACAGTCTCGGCTGGTGAGGGCTCCCTCGTATGAGGTGAGGACGCGGGCAAAATGACGCAATACGACCCGTCTTGAAACACGGACCAAGGAGTCTAGCACGGCTGCGAGTCGAAGAGTGATTAAACTCAAGGGCGCAGTGAAAGCGAAATTATAAGCAAATTGGGGAGGCGTTGCGTTTTTAACAAAATGTCCTACCTCGAGCATTTGTGCTGGGACCCGAAAGATGGTGAACTATGCCGGAGTAGGGCAAAGCCAGAGGAAACTCTGGTGGAGGCTCGTAGCGATGCTGACGTGCAAATCGCTCGTCGAACTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCCTCCGAAGTTTCTCTCAGGATAGCGGGCCGACACGCGTTTGTTGTTTTGTGCGGTAAAGCGAATGATTAGTGCATTTGGGGTACGAAGTACTTCGGGCGATTCTCAAACTTTAAATGCGCAAGGGGGTGGCTGCTTAATTGAGCCTACTCTTTGAAAAACGTCGGCCCTGTGGGCCACTTTTGGTAAGCAGAACTGGCGATAAGGGATGAACCTTAAGCGCGGTTAAGGCGCCTCATTACCCGCTTATAGACCCCACAAAAGGTGTTGATTCATATAGACAGCAGGACGGTGGCCATGGAAGTCGGAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATGAATTAGCCCTGAAAATGGATGGCGCTAAAGCGGGTAGCCGACACCGCGCCGTTCCGGCGAGACGAGGCCGGGATGAGTAGGAGGGCGTGGCGGTCAGTGAAGCAGGCTAGGGTGCAGACCCAGCTGAAACGGCCGCTAGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAGCGAGATCCTTGAAGGGCGAAGCGGGGAAGGGTTCCACGCAAACATTGATTGGGCGTGGGTGAGTCGTTCCTAAGCCGAGTGGCAATTGCTAAGTAGCGGCGAAAGGGAAGCGGGTTAAAATTCCCGCACACGGATATGGAGGCGGCGACGCAAGCAGAGGCGAATACGCTGGCCGAGGCGCTGGGCAGAGTTGTCTTTTCTGTTTGACCGGCATCGCGCCGTGTGGAATCCGCTTATCGGGAGAAACACGCGCGGGTATGGGCAGAGCGTCAAGTTTTTTTTGGCGTCCAGCTCGCCTCGGACGGCCCCTGAAAATTCGCCCGCGAACTTTAAAAATTTCATGCTGTGACGTACCGATATCCGCATCAGGTCCCCAAGGTGAACAGCCTCTGCTCAATATGAACAATGCAGGTAAGGGAAGTCGGCAAAATAGATCCGTAACTTTGGGAAAAGGGTTGGCTCTAGTGGGATGAAGGTCTTCAAAGGGGGCTTCGCTGTGCTTGGCGTCTGACGGGAGTGGCTAGCTTTCGGGCTGGATGCTTCTGTTGGATTCCTTGCGTGGGGGATGTTTCTCGCCTTCAGCATATCCCAGACTAGAACTGCAACGGGCAAAGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGAAGGCCGTGGCCGGTGTTGACGCAATGTGATTTCTGCTCAGTGCTCTGAATGTCAAAGTGAAGAGATTCAATCAAGCGCGGGTAAACAGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCTACTGTCCCTATCTGCTTCTAGCGAAACCACAGCCGAGGGAACGGGCTCGGCGGAATCGGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTATTCTAATTTTGTGAAGCAAGTTAGGAGGTGTAGAATAGGTGGGAGCTTCGGCAACCGTGAAATACCACTACTCTTAATCTTGCTTTACTTAGGGCGTGAGGCTGTACGGCCGCAAGGCTTGCTTATTGCATCAAGCGTGATTCGTTCGCGTGAACAGCGCGCCCAACACATTTAGGAGGGGAGTTTGGCTGGGGCGGCACATCTTCTACAAGACAACGAAGGTGTCCAAAGATAAGCTCAGTGAGAACAGAAATCTCACGTAGCGCAAAAGGGTAAAAGCTTGTTTGATTTTGATTTTCAGTGTGAGTTGAAAACGCGAAAGCGTGGCCTATCGATCCTTTCACGATTCGAGATTTGAAGCGAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCGGCCAAGCGTTCATAGCGACGTCGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGCGAAGCAGAATTCGCCAAGTGTCGGATTGTTCACCCGCCAACAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTATCCTACCGATGAGTTGTTGCCGCGGCAGTAATATATGGCAGTACGAGAGGAACGCATATTTCACACCACTGGTTCATGCAGCTGCCTGAGCAGGCAGTGCTGCGAAGCTACCGTGTGAATGATCAGAATAGCTGAGAGAGTCTAAGCTAGGATCGGTTCTGCTCAGCGGCGACTTATTTGTATCCGCCTCGACACTGTGTACAGATAGCCTTCGGGCGAGCACCATTGGGCGTAAGCTTATCGTCGTGCGTTTTAGCGGATGTAAAATCACCTGCAGATGACTGGGTTGGGACTGGAGCGTGTACAGCGTTGAGAGATCTTGTTATCTCGATTCCTTGAGCGTATCTGAGTCCTTACGATTTGT
->GL876983.1/220883-220724 Magnaporthe poae ATCC 64411 unplaced genomic scaffold supercont1.18, whole genome shotgun sequence. 
-CACCGCCCGTCGCTACTACCGATTGAACGGCTCAGTGAGGCCTTCGGACTGGCCCAGGGAGGTGGGCAACTACCACCCAGGTGCCGGAAAGTTGTACGAACTCGGTCGTTTAGAGGAAGTAAAAGTCGTAACAAGGTCTCCGTTGGTGAACCAGCGGAGG
->GL897030.1/4179803-4179625 Mustela putorius furo unplaced genomic scaffold scaffold00133, whole genome shotgun sequence. 
-AGCTTTGTGTAGTGGCAGTATCGTAGCCAATGAGGTTTATCCAAGGTGCAATTATGGCTAATTGAAAATATTTTTACCAGGCCCCAAAGAAATCTTGTACCCATAAACAATCACTCCCCATCCCTCCCACAGACACTTATTGGCATGCAGAGTTTTTAGCTCCATATCCAAACAACATG
->AFTD01079003.1/14897-14834 Cricetulus griseus cell line CHO-K1, whole genome shotgun sequence. 
-TCTTGATGATGCACTTCCAATAGATCCTTCTGACCCTCCACTGTGGACTCTCCATTCCACAAGG
->CM007654.1/638658-638533 Prunus persica cultivar Lovell chromosome G4, whole genome shotgun sequence. 
-TACATAACGAGGGACAGTTTGTGTGTCTCTTGGATTGAGAAGAATAGCGAGGTAGAGTGAAAAGGCCGAGCCATCGTTTCGGTCGTCATTATTTGGATTGGCGATTCGATTGTTTCTCGTCCACAT
->AASG02044696.1/921-990 Ricinus communis cultivar Hale ctg_1100012308131, whole genome shotgun sequence. 
-CGACCCCAGGTCAGGCGGGATTACCCGCTGAGTTTAAGCATATCAATAAGCGGAGGAAAAGAAACTACCA
->KB671965.1/368135-367938 Anopheles epiroticus strain epiroticus2 unplaced genomic scaffold supercont1.71, whole genome shotgun sequence. 
-ATCAATACAACTCTAGTAGCGTAAGGATGCGAGGTCTTTAGAAGTATAAAATAAGCTCGTCTTAGCTACTCCTATTTGTCACCATCGTACAGAGTGGTAACATATCTCCTAACACCTGAGCTTGGGTATAAGGAGAATTTCTTATAGAAGTGCCCGGTAAGGGCAAGCCAACTTAACTAAATGTTTCAAATGAGAGAA
->URS0000D6A915_12908/1-80 unclassified sequences skipping-rope RNA 
-ATTAAATGAGGTGGACAATGGCATCCACGCACCTATATTGGTTAAAAGAGATGAAAGTACAGCCAGACTTTCCATTTAAT
->FR902120.1/11240-11312 Clostridium sp. CAG:914 genomic scaffold, scf4 
-TTGATTGCTCAACCGCACGAAAAAGGTATATAAGTAGATTTTTCTCACCTTATAGGCGAGTCTTAAACAAAAT
->CM000941.1/117493038-117492965 Anolis carolinensis chromosome 5, whole genome shotgun sequence. 
-CGATGATGATGATGATGATGATGATGATGATGATGATGATATCATCATCATCATCATCATCATTATCTTTATTT
->AAGD02001768.1/1-584 Caenorhabditis remanei strain PB4641 contig453.2, whole genome shotgun sequence. 
-TCCGGACTCCAGGGATCCGAACGTCTAATTAAAACAGAAGTGACCAGATGGTCTTGCGGAAGTTGACTTACAGTGATTCTGCCCCAGTGCTCTGAATGTTAGCTCGTATTAATTAGAGTAAGCGCGGGTAAACTGCGGGAGAAACTATGACTCTCTTAAGGTAGCCAAAGGCATCGTCATTAAATTGTCACGCGCATGAATGGAATAACGAGATTCGTACTGTCCCTAACTACTATTTAGTGAAACCACAGCCAAGAGAACGGGCTTGGCTAAAGTAGCGGGTAAAGAAGACCCTGTTGAGCTTGACTCTGGTTTGACATTGTGAAGAGTCATGAGAGGCGTAGCATAGGTGGGAGACTTCGGTAGACAGTGAATTACCACCACTTTCATCGACTCTTTAATTATTGGGTTGAAAGAGAATACATCCGGCCCGTAGTAGGTCACGGACATAGATCTCGCTGAGATCTACATTTTGGTATATTTTTCAGGTCATAACACTGAGTTTGAAGCATTTACGAGCCGGCCCAGGTCGACCCGGTTTGCAAATATGTTTTGAACTAATTTTCAGAATCCAAATGAGCCGT
->URS0000D6BD91_395494/1-79 Gallionella capsiferriformans ES-2 int-alpA RNA 
-GCCGCACCTAGTCCGTGCTTAATTACCACGGGCGAAAGCACAGAAACCCTTGCTGTGTTGGTGCGGCTTCTATTCAGGG
->AZRA01000138.1/15527-15395 Sphaerotilus natans subsp. natans DSM 6575 X805_138, whole genome shotgun sequence. 
-CCGAAGGGTCGCTAGGGTTCCGAGGCCTACCATGCGGCAGGCCTGTCTGGTCCGAGAGCGACCGGCCTCAAGTGCCCGCGGCAGCTGCCGCGACGGCACTCAGGCTCCACGGCGGGACAAAAGCCCGGGAGGA
->MJEQ01005736.1/39329-39916 Nicotiana attenuata strain UT scaffold05736, whole genome shotgun sequence. 
-TTGTGTATTTTGTTAAGCAAAATCGTCTAAGTCATTTCCTAGGGTGGGAAAATCATTTTGGCCAGGGAATCGGGGAATTCTTTGTCTTGGCCATAGGGTTGGCTATTGTGTTCTTGTATTCACATATTAATACGAGTTGGGAAGAAATTCCTGTATATCGTGTGTGCCTTTTTACTGTTTATGCTGCCTATTTCGTTCTAAGTTTCAAACGTCCCTAAAATAAAACTAAGTGTTGGAAAGGCTGAAGTCAAGGCTGGGCTTGACTGCCGCACGGAGGTGAACCTCGAGTAGAAATTTGAGTGACATAAATCACCCCTGTGACACCTACCATGGTGGTGACGGGTGACGGAGAATTAGGGTTCGATTCCGGAGAGGGAGCCTGAGAAACGGCTACCACATCCAAGGAAGGTAGCAGGCGCGCAAATTACCCAATCCTGACACGGGGAGGTAGTGACAATAAATAACAATACCGGGCTCTATGAGTCTGGTAATTGGAATGAGTACAATCTAAATCCCTTAACGAGGATCCATTGGAGGTCAAGTCTGGTGCCAGCAGTCGCGGTAATTCCAGCTCCAATAGCGTATATT
->MHFR01000003.1/41901-41805 Omnitrophica bacterium RIFCSPLOWO2_12_FULL_44_17 rifcsplowo2_12_scaffold_1117, whole genome shotgun sequence. 
-CATGTAGTGTGGCGCAAATCGAAAGGTTAGGACGCAAAGCTTTAGAGCCTAAACCGACCGGGCAAAAACCCGGTAGGCATGGTTGTCAGTTGCCGAA
->AF137379.1/97379-97053 Nephroselmis olivacea chloroplast DNA, complete genome. 
-GGGGTTGTCATGGAATCGACGTCTCTTCTAAGAACGAAAGGTTAAAGCAGGTCGAGGTCGAAGATGGACTCGTACTCTCCACTTCATTGCTTGATTGCATGCTAATCAGATTCTTCCTTTCTCTCGCCGGGTAGCCGTTGCTGCTTAAGCGAGTTTCTAGTGCCACTTTGTCACTAGTTTGTATTATGAGTTTCACACTCACTTCAATGACGGTGATAGATACTACATATCACTCCTGCTTAGAGGGTCATCTAAGCTAAACCATGTGAATATAACCTTTCGGGCCTCGAGAGACGGAAGTGAGTTCAATTCTCACCAACTCCACCA
->FO117623.1/2019842-2020021 Blastococcus saxobsidens DD2 complete genome 
-GACCGAACACCGCCTAATCACCGCGCGGCGTGCAGTCCCGGCGCCCGGGGTGTACCGGGGACCCACCGCAGTTCTGGGGTGAGTTCTCCCGCGGCCGGCTCGCCGGTGCGTGGGGGATAGGGCCAGTCTTCCCAGCCCGAACCCGTCAGCTAACTCGGTCGGCGGTAGCTGAGGAAGAAA
->JH971392.1/893535-893437 Agaricus bisporus var. burnettii JB137-S8 unplaced genomic scaffold AGABI1scaffold_8, whole genome shotgun sequence. 
-CCTATCTGATGATACAAGCGCAATCGCATAGTTCACGCTGAATCAAAAGTGTTGACAATCATGCATCTTTACGTCTTTCGCTCCTATCTGACTCATCTC
->AZIM01000372.1/334250-333937 Ophiophagus hannah scaffold373.1, whole genome shotgun sequence. 
-GGATGTGAGGGTGATCTGTCTGTGACATCTGTCACCCCATTGATACCACAGTTAATTCAGTTGATCTGGCTAGCTAGGCAGGTGTCCCCTTCCTCCGTTACCACTCCATTTTTATTTTTCCATGAACTGTGTGCTCATGGAAGAGACAACTAATTTAGGGAGGAGTGTATCAATCTTTAGGCAAGGGTATGATATCCGTGCTCACCTTCTAGAACCGACAAACAAACCTTTTCCTCCATCCATTTGCCTGTTCGTTTCCCAGGCTTGAGATATAACAATGCATCTCAATGGCTTTGTTTGATCAGCAGTGCTTG
->CAJI01046266.1/316-1 Cucumis melo, WGS project CAJI01000000 data, contig: 46266 
-AATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTGAAGCGCGCGACCTATACCCGGCCGTCGGGGCAAGAGCCAGGCCCCGATGAGTAGGAGGGCGCGGCGGTCGCTGCAAAACCTTGGGCGTGAGCCCGGGCGGAGCGGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTTGAAGGCCGAAGAGGGGAAAGGTTCCATGTGAACGGCACTTGCACATGGGTTAGTCGATCCTAGGAGACGGGGGAAACCCGTCTGATAGCGCGAC
->CP013111.1/5040245-5040340 Bordetella sp. N genome. 
-ACGCTTGAGGAGCGTTGCGACGGATCATTCCGCCAGGCTCAAGCATTCCAGGGTATGCCGCGTTCGCGCGGCACCATGAAACGGCGCTCACCTTAG
->LFJF01027493.1/1808-5852 Macrostomum lignano unitig_27548, whole genome shotgun sequence. 
-TGACCTCGGATCAGACGTGATTACCCGCTGAAATTTAAGCATATTATTAAGCGGAGGAAAAGAAACTAACAAGGATTCCCTAGTAACGGGCGAGTGAACGGGAAGAGCCCAACACCGAATCCCTTGGCGCAAGTCAACGGGGAAATGTGGTGTTAAGGTAGCCCTTCGTGTCAGTCTAGGCGTCTCAAGTCCACCTGATTTGTGTGCTCAAGCCCAGAGAGGGTGTAAGGCCCCGTAGAGACGCTCCGACTGATTCCTGGGGTGTTTACCTACGAGTCGCTTGTTTGGGAATGCAGGCCAAAGCGGGTGGTAAACTCCATCCAAGGCTAAATCTGGCACTGAGTCCGATAGCGGACAAAGTCCGATAGGCGGACAAGTACCGTGAGGGAAAAGTTTGAAAGAACTTTGAAGAGAGAGTTCAATAGTACGTGAAACCGCTTAGAGGTTAAACAACGGACGGATGGAGCTCATAACTGGCCTGAGCTTCAATCAACTGTGACGGTGGCTGGACGAGGCTGGAGCGAGTTCGGATCTCTTCTTTTGGGACGGGCAGATCTGCTCTTTTGGTGACGCTCGGCGTTCGGTTGGCTATCAGCTCCTGACATCGGTGCCAATCTTGTCCCTTGGTGGCCTTCCGCCACGACCACGACACTGGCTACCCGCGGCTGGGGTAAGGTGACAAACTGCTTCGGCAATTTTGTGTATAGACCCGCGGCGTCGTCGGACATGGTTTTGGCCAGGACGTCGAGCTTGGCGGCGCCCGCTCCTTGTGTGGCTCGCATGTTTGGCTATAGCTTGGCTGCCGCCGATGCTTGCACTGGACAACCAGTACAGGTGGACGGTTGTGGTCTATGTCTCTAGTTGGCCTCTGCGAGTTTGGCGCCTTATAGTCTGTGGTGTACTTGTGGGTAGACTATCCGACCCGTCTTGAAACACGGACCAAGAGTCTAACATCTGCGCTGAGTCATGGGGATTTCCTACACGACCAAGTGTGCGCGCGAGTCATGGGGGGATTCTACGAAACCAAAGGCGCAGTTGAAAGTAAAGGCCTGCTTCTCGTAGGCTGAGGGTGGGATCTCGTGCATTCGCGAATTGGCGAGCGCACCAACCGGGCCCGTTCCTATCTGTCTCTGTCAGTGGGGCGGCGCAAGAGCGTACACGTTGGGACCCGAAAGATGGTGAACTATGCTTGCGCAGCTCGAAGTCAGTGGAAAACACTGATGGAGGAGCGCAGCGTTTCTGACGTGCAAATCGATCGTCAAACGTGAGTATAGGGCGAAAGACTAATCGAACCATCTAGTAGCTGTTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGCACTCGGGAAACAGTTTTATCCGGTAAAGCGATGATTAGAGGCATTGGGGTCGAAACGACCTCGACCTATTCTCAAAACTTTAAAAATGGTAAGATGCTCGTCTCGCTTTAATTGGAGGCGGGCTTCACCTCTCTATAAACGTGAATGTGAGTGCCCAGTGGGCCATTTTTGGTAAAGCAGAACTGGCGCTGTGGGATGAACCAAAACGCGCGGTTAAGGCGCCAATGCGGACGCTCATTGAGACACCACAAAAGGTGTTGGTCGATATACTGACAAGCAGGACGGTTCGGCCATGCGAAGTCGGAACCCGCTAAGGAGTGGTAAGCAACTGCACCTGCCGAATCAACAGCCCTGAAAATGGATGGCGCTGGAGCGTCGGGCCTATACCGTGCCGTTGGCAGGCGAAGCAGACAAATAATCTGTGTGGATGTCCCCAAACGAAGTAGGAGGGTCGCCGTGGTGAGCGCAGAAGGTGCGGCCGTGAGGCCGGCTGGAGCCGCCACGGGCGCAGATCTTGGTGTAGTAGCAATTACTCAAGTGTGAGAACCTTTTGAGGACTGAAGTGGAGAAGGGTTCCATGTGAACAGCAGTTGAACATGGGTCAGGCGGTCCTAAGCGATCTCGGTAACTCCGTACACTAGACGAGGGTGACAACTATCACTTGAACTAATACTGTGAAGTGTTATAGCCCTCCGGAGCGAAAGGGAATCGTGTTAATATTTCACGACCCTTACCGTGGAGATCGCCCCTTTCGGGGGGCAAGTGCGGTAACGCAAACGAACACAGAGACGTCGGCTGGAGCCCCGGGAAGAGTTCTCTCTTTTCTTTGTAAGGAGCCGTACCCCCTGGAATCGGCTTGTCCGGAGATAGGGGCGTGGCTTCCGTAAAGGCAGCGCGCGGTCTTGCGCTGTCCGGTGCACTCTAGTCGGCCCTTGAAAATCTGTGGGAGACAGTGTGATTTTCACGGTAGGCCGTACCCATATCCGCAAGCATGCGTCTCCAAGTGAACAGCCTCTAGTCCTAGAACAATGTAGGTAAGGGAAGTCGGCAAAATGGATCCCGTAACTTCGGGCGAAAAGGATTGGCTCTGAGGGCTGGGGTCGGATGGGCTGGCGTAAGAAAGCTGTTCCGGTGGTGAGGACTGGGCGAGGCTTTCGGGCTTTACTCGGACCATGCCGAGACCAGGCAGTAGACGACGTCAGCTGTGCTTGTCGTGTTTCGGCGCGGCGCGGCAGCTTCGTCCGGCAACAAACAGCCAATCTCAGAACTGGCACGGACTAGGGGAATCCGACTGTCTAATTAAAACAAAGCATTATGCGATGGCTCGTGTGCTCGATGTTGACGCAAATGTGATTTCTGCCCAAGCTGCTCTGAATGTCAAAGTGAAGAAATTCAATCAAGCGCTGGGTAAACGGCGGGAGATAACTATGACTCTCTTAAGCGTAGCCAAATGCCTCGTCGTCATCTAATTAGTGACGCGCTTATGAAGGTGGGGTATTAACGAGATTCCACTGTCCTATCTAACTATCTAAGCGAAACCACAGCGCCAAGGGAACGGGCGCTTGGCAGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCCGACCTTTGTGAAGAGACGCATGAAGAGGTGTAGTATAGGTGGGGAGCGTCAGCGACTTTGAAATACCATACTTTTAATCGTTCTTTACTTATTCAGTGAAGCGGGGGGGGGGAGCGGCCTTCACGGCACTCGTTTCTGCGGTGTTTAAACGGCTGGCCCTCGCGGCCGGCCGTGAACCTTGCTCTGAAGTACAGGTCAGGCGGGGGGAGTTTGACTGGGGCGTGTACATCTGTCAAAAGGTAACGCAGGCTGTCCAAGATGAGCTCAGTCAGGACCAGAAACCTGCGTAGAGCAAAAGGGCAAAAGCTCATTTGATTTTGATTTTCAGTACGAATACAGACGTGAAAGCGCGGCCTATACGCATCCCTTTGATTAATCAGAGTTGATGCAAGGCGGTGTTCAGAAAAGTATCCACAGGATAACTGGCTTTCTCACGCGTCTGCGAGTGCGATGGCGGGCAAGCGTCATAGCGACCGTCGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCAATTGTGAAGCAGAATTCACCAAGCGTTTGGATTTGTTCACCACCCAATAGGAACGGTGAGCTGGGTTTTAGACCGTCGTGAGACAGGTTAGTGTTTACCCTACTTGATGTCTTCGGTCGTTGCCTATGGTAATCCTGCTTAGCTACGAGGAGAACCGCAGGTTCAGACATTTTGGTTTATGTGCTTGGTCGAAAGACCAATGGTGCGAAGCTGACCAATCTTTGACGGCGATTTAAGACCTGAAAGCCTTCTTTAAGTCTTGAATCGCCGCCACGAAACGTGCAACGATACTATCGGTGCCCCTACGCCGGGAGGCAACGAATATACTCGGCCCGCAGAATCCGATTTCGGCGGGCGAGCACTGGCTAAAGCACTCGATTACTGCGTGGCCACACCCGCTGTCTTTGTGAAATTTGCAGTCGGAGGCACAGACACGATTACCACTTGATATTGAGACGTTAGGGGTTTCTATAAATCGTTTGTTAGAGCGACTTAGATTCCGGTCGGGGTGCCGTACTTAGTTGAGCAGTTTCACTTGCGATGCTATTTGAGGGCCTAAGCCTTTTGACGGGGAGATATGT
->LMNA01000001.1/561241-561047 Pseudorhodoferax sp. Leaf274 contig_1, whole genome shotgun sequence. 
-CCGCCCGTCTTGGGGGAGTAGCCAGCCTTCGCTTTGTGCGAGAGGGGTTTGCGTCAACAGACTTGTTCGTGCCGTGCCTTGGTGTGCGGTCCGACATGGCGCAAACGGACCACCAGCAGCAGCCTGCAACGGGCGATGCCTTGCCGGGGTTCAAGCGAGACCTTTGACTGCGCAGCTTCTCGTGCCGGGAAGGCT
->ALWZ043544869.1/1192-611 Picea glauca, whole genome shotgun sequence. 
-GGTTTGGCATAATCAACAGAGAAAGAAGACCTTGTTGAGATTGACTCTAGTCCAACTTTGTGAAATGAATTGAGAGTTGTAGAATAAGTGGGAATCATTTTTGACACAAATGAAATACCACTACTTTTAACATTATTTTACTTATAATTTTGTGGGGCGAAGACGGGGCAGTTACCCTATTTTTGGCCTTAAGTCATGTTTCGATGGGTTGATATGGGCGGAAGACATTGTAGGTGGGGATTTTGGATGGGGAAACACATCTATTAAAAGATAACATAAAATATAATTTGTGTAGATAGAACATTTGTATTTGGGAGATCCTAGTGCACAACCACCCTTATTACCTTTCCCTCCTAATTTGTAGTTACATCCAATCATTTCTAAATTGAATCTAGTTTCCTCACTTGCACAATATGGATAGACGTGTGAACCCTATACATTATTAAATATTTCAAAACCCCTATCCATGAGCCTATGGTTACATACAAATGGGAAAAAAAAGGTGGATACAAAAATGACACCCATTCCTCCTCACAGTCCTCCCTAGGATCTTGTTGTATCTCATAATGTTGCACACTCCAT
->ALWZ042080687.1/2737-2632 Picea glauca, whole genome shotgun sequence. 
-GAAGAATCCTTTATAGACGACTTAAATATGTGACGGGGTATTGTAAGTGGTAGAGTGGCCTTTCTACCACAATCCACTAAGATTCATCCCTTTGTCGCCTCAATTT
->ALWT01066045.1/576-1 Myotis davidii contig66045, whole genome shotgun sequence. 
-TGGAGTCCAGGGGGCGTGGGAGGAACGGCCTCTCCAGCTCCCTTTGCTCCGCCGCCGCGTCCCACCGACCCGCCCCCCGAAGAAGCATCGGGACCGCTCAGATTTGCAGTCGGAGCCGCGTCCCGAGGGAGAGAAGGGGCGTGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAATGAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATGAACGAGATTCCCACTGTCCCTACCTACTATCCAGCGAAACCACAGCCAAGGGAACGGGCTTGGCGGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCTGGCACGGTGAAGAGACATGAGAGGTGTAGAATAAGTGGGAGGCCCCCGGCGCCCTTTCCCTCAGCCCCCTCTCGCGAGGGGGCGGGGAGGGGGGCACGCCGGCCTTGCGGGCCGCCGGTGAAATACCACTACTCTGATCGTTTTTTCACTGACCCGGTGAGGCGGGGGGGCGAGACCCGGGGGGGGGTGC
->APMT01039647.1/25991-25874 Mesocricetus auratus contig039647, whole genome shotgun sequence. 
-ATGTTGTATCAGAGAGAATGTCAGCACTCTTCTTGCTAAGTATGAAAAGACCAATGAGCCTAACAGTGTACATTTAAGGCATTGATCCTTACAATGTGGCATCTAACCACTGTTTTTA
->AKHW03004724.1/5683634-5683707 Alligator mississippiensis ScZkoYb_22, whole genome shotgun sequence. 
-CAACAAGAAGATGAATGGTAGGCTGGTCACTTTCCTGGGAAGTAAGAGTCAGGAGTTCAAACCCCTCTAGTTGA
->LGKD01319461.1/278-207 Octopus bimaculoides Scaffold40646_contig_8, whole genome shotgun sequence. 
-TTACTGACCAAGTGGTTGTGAATGTGCTGCTAAATTGGACTTTCATATCACAGCCTGCTTGGATCAGTAACA
->AACY023405062.1/1217-1321 Marine metagenome ctg_1101668212413, whole genome shotgun sequence. 
-AAAGTCGGAATGGGTGTTGAAAGATTACCGACAAGATGAGGGAAACACGCAACCCTCGTTCGATGCGGGTAATTATTCCAACAGTTCCGCATCGATGCCGCTGCT
->BDFN01000945.1/2677-5912 Ipomoea nil DNA, scaffold: scaffold0945, cultivar: Tokyo-kokei standard. 
-CGACCCCAGGTCAGGCGGGATTACCCGCTGAGTTTAAGCATATCAATAAGCGGAGGAAAAGAAACTTACAAGGATTCCCCTAGTAACGGCGAGCGAACGGGAACAGCCCAGCCTTAGAATCGGACGGCCTTGCCGTTCGAATTGTAGTCTGGAGAAGCGTCCTCAGCGGCGGACCGGGCCCAAGTCCCCTGGAAAGGGGCGCCGGAGAGGGTGAGAGCCCCGTTGTGCCCGGACCCTGTCGCACCACGAGGCGCTGTCTACGAGTCGGGTTGTTTGGGAATGCAGCCCCAATCGGGCGGTGAATTCCGTCCAAGGCTAAATACGGGCGAGAGACCGATAGCGAACAAGTACCGCGAGGGAAAGATGAAAAGGACTTTGAAAAGAGAGTCAAAGAGTGCTTGAAATTGTCGGGAGGGAAGCGGATGGAGACCGGCGATGCGCCCGGTAGTATGTGGAACGGTGAGAGCCGGTCCGCCGATCTACTCGGGGCGCAGACCAGCGAGGATTCGGGGGCGGCCAAAGCCCGGGCCTTTGATACGCCCGCGGAACGTCGTCTCTCGGATCGTGGGAAGCAGCGCGCGCCCCTGGCGTGCCTCGGCACCTGCGCGCTCCGGTCGCTGGCCTGTGGGCTCTCCATTCGACCCGTCTTGAAACACGGACCAAGGAGTCTGACATGTGTGCGAGTCAACGGGCGAGTAAACCCGTAAGGCGCAAGGAAGCTGATTGGCGGGATCCCCTCACGGGGGTGCACCGCCGACCGACCTTGATCTTTTGAGAAGGGTTCGAGTGCGAGCATACCTGTCGGGACCCGAAAGATGGTGAACTATGCCTGAGCGGGGCGAAGCCAGAGGAAACTCTGGTGGAGGCCCGCAGCGATACTGACGTGCAAATCGTTCGTCTGACTTGGGTATAGGGGCGAAAGACTAATCGAACCGTCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGAGCTGGCGCGAGAGTTCTATCGGGTAAAGCCAATGATTAGAGGCATCGGGGGCGTAACGCCCTCGACCTATTCTCAAACTTTAAATAGGTAGGACGGCGCGCGGCTGCTTCGTTGAGCCGCGCCACGGAATCAACAGCTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGGAAGCCGGGTTACGGTGCCCAACTGCGCGCTAACCTAGATCCCACAAAGGGTGTTGGTCGATTAAGACAGCAGGACGGTGGTCATGGAAGTCGAAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTTAAGCGCGCGACCTATACCCGGCCGTCGGGGCAAGAGCTAGGCCCCGATGAGTAGGAGGGGCGCGGTCGCTGCAAAACCTTGGGCGTGAGCCCGGGCGGAGCGGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTGAAGGCCGAAGAGGGGAAAGGTTCCATGTGAACGGCACTTGCACATGGGTTAGTCGATCCTAAGGGTCGGGGGAAGCCCGACAGACAGCGCGTTTTGCGCGTGCGCCGAAAGGGAATCGGGGTTAAAATTCCTGAACCGGGACGTGGCGGTTGACGGCAACGTTAGGGATTCCGGAGACGTCGGCGGGGGCCTCGGGAAGAGTTATCTTTTCTGTTTAACAGCCTGCCCACCCTGGAAACGGCTCAGCCGGAGGTAGGGTCCAGCGGCTGGAAGAGCACCGCACGTCGCGTGGTGTCCGGTGCGCCCCGGCGGCCCTTGAAAATCCGGAGGACCGAGTGCCGTCCACGCCCGGTCGTACTCATAACCGCATCAGGTCTCCAAGGTGAACAGCCTCTGGCAATGGAACGCTGGCAAGGAACGGGCGGGCCTTCCCGGGCGTCGAACAGCCAACTCAGAACTGGTACGGACAAGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGATGGTCCCTGCGGATGCTAACGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGGGTAAACGGCGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTGTCTACTATCCAGCGAAACCACAGCCAAGGGAACGGGCTTGGCAGAATCAGCGGGAAAAAGACCCTGTTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTGAGAGGTGTAGGATAAGTGGGAGCCGAAAGGCGAAAGTGAAATACCACTACTTTTAACGTTATTTTACTTATTCCGTGAATCGGAGGCGGGGCATTGCCCCTCTTTTTGGACCCAAGGCTCGCTTGCGGGCCGATCCGGGCGGAAGACATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGCTCAACGAGAACAGAAATCTCGTGTGGAACAGAAGGGTAAAAGCTCGTTTGATTCTGATTTCCAGTACGAATACGAACCGTGAAAGCGTGGCCTAACGATCCTTTAGACCTTCGGAATTCGAAGCTAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCCACCAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGACAGTGTCGCAATAGTAATTCAACCTAGTACGAGAGGAACCGTTGATTCGCACAATTGGTCATCGCGCTTGGTTGAAAAGCCAGTGGCGCGAAGCTACCGTTTGCGGTTCGGATTATGACTGAACGCCTCTAAGTCAGAATCCGGGCTAGACCGACGCATGCGCTCGTCGCGTCCGTTTGGCCGACCCGCCAGTATGGGGGCCATTTGGCCCCCAAGGGGCACGTGGTCGTTGGGCTAAGCCGTCGTGGCGGAAAGGGGTCACGGTTGGGCCGCGCTTGAATATACAATTGCCGATCGAGCGGGGCGAGCTGAATCCTTTGCAGACGACTTAAATACGCGACGGGGTATTGTAAGGGGTAGAGTGGCCTTGCTGGCCACGATCCTCTGAGATTCAGCCCTTTGTCGCTCCGATTCGT
->JARO02002307.1/4880-4968 Scleropages formosus scaffold2307, whole genome shotgun sequence. 
-TTGAGTTTTCAGCTTTGAGAACTGAATTCCAAGGGTTTTTGGATCAAGCTTTGCCCGTGGGACTTAGTTCTTAAAACTGGATGCTCCTG
->BABG01005904.1/1457-1294 Human gut metagenome DNA, contig sequence: In-R_005904. 
-TATCGGACGGTGGTGATATTTTCTCGAAAAGTGCTGAAAATCAGGGTGGAGCGAACAGGACGTTCGCGACAGGCGGACGTTGCCATGGATGGCAACTGGAGCCGTGCCCGTGCGGATTAGAACCGATATCTCACTTTTCGTCAGAAAATTCCCACCGGGAGACC
->MHKX01000006.1/12218-16044 Candidatus Liptonbacteria bacterium RIFCSPHIGHO2_01_FULL_57_28 rifcsphigho2_01_scaffold_11526, whole genome shotgun sequence. 
-ATGGTTGGCATTAAGGGCGCATGGTGGATGCCTAGACATCAAACGACGACGAAGGACGCAGCATAGCGGCGATACGCCACGGTGAGGTGCGGAGCAACCGTTGACCCGTGGATTTCCGAATGGGGCAACCCTGTTGAGTAAACCTCAACAACCTTCGCAAGAAGGAGTCACACCCGCTGAAGTAAAACATTTCAGTAAGCGGTGGAAACGAAAAAAAGTCCGCGCAAGCGGAAAAATTCCCCAAGTAGCGGCGAGCGAAACGGGAGAAGCCTAAACCACATGTTCGCAAGAATGCGTGGGGTTGTAAGGGAGGAACGCTATCACTTATAACCGAGAGCCGGGAGCGATCCCGGCATATCGGTTATGGGTGAAAAGGAGGAGTTACAAATTCATTTGCTAGCCGAAGCGTCCTGGAAAGGACCGCCAAAGTGGGTGATGGCCCCGTAGGCGAAAGCAGATGAACTTCTTAGTTTCTTTTCTTGAGTAGCTCGAGGTAAAACAGCTTCGAGTGAATCCGGGAGTACTATCTCCTAAGGCTAAATACGTTTGATGATCGATAGTGAACTAGTACCGTGAGGGAAAGGTTAAAAGCAGGCCGGTGAGGCCGTTGAAATAGATCCTGAAACCATGCGTTTACAAGGAACTGACGTCTTATGAGCCCGCCGCAAGGCAGGCCCCGGACTACAGTGTGCCTATTGAAGAATGAGCCAACGACTTTAGGTGTGCGGCAAGGATAAGTCCTCTCGGGGACGCATCCGTAGGGAAACCGAGTATTAACGTGCGATTTAGTCGTACACCTAAGACCCGAAGCCGGATGAGCTTGCCTTGGCCAGGTTGAACTCCGTAGAAATACGGAGGGAGGACCGAACCGGTAGGTTGTTCAACACCTTCGGATGAGCTGAGGTAAGGAGTGAAAAGCTAATCGAATTCGGTAATAGCTGGTTCTCTCCGAAACAGTTTTTGGACTGGCGGCGTAAAGTAGCGGGTGGGGGCTAAGCTCCATGTTCGCGAGGGAAAAAGCCCAGACCATCAATTAAGGTCCCCAAGTGCGTGCTAAGTGTAAAAGGCAGTGTTGTGCCATAGACAGATAGGAGGTTGGCTTAGAGGTAGCCACCCTTTAAAGAGTGTGTAACAACTCACTATTCGATCGGCACGGCGCGCCGAAAATGTATCGGGGCTAAGCACGCCACCGAAATTATGGGTTCGTATGTCCTTCGGGACGTATGAGCGGTAGGAGAGCATTCCCTTCTGCTGTGAAGCAGGACCCGCGAGGGCCTGTGGAGCGTAGGGAAGAGAGAATGTTGGCATGAGTAACCACAATCCCAATGAGAAATTGAGAGCCCGAAAATCCAAGGTTTCCGTGGCACTGGCAATCAACCACGGGTTAGGCGGTCCTAAGGCGATGGCGAAAGCCGCAGCTGATGGATAGCCGGTTAATATTCCGGCCCAGCCATGCGATCATAGCGAAGTGCGAAGGAAAAAGACGGGAGTGCCTTATTGGTTTGGCATTTATACTCCAAGGCGCAAGCCGGGAGCGTATGAATGTCCGGTTTTACCGGACAAACTTCCGAGAAGAGCCTTCCGAGAAAAGCTTCGTGAAAGCGAGCGCATGGTTTCCGTACCGTAAACCGACACTGGTGGGTGAGGCGAGAAGCCTCAGGGTAACGAGTGATTCATCTTTAAGGAACTCGGCAAAAAAGCGGCCGTACCTTCGGTATAAGGCCTGCCCATCGCAAGATGGGCCGCAGCGAAAGTCTCCCTGGCGACTGTTTACCAAAAACACAGCTCCCTGCAAACTCGCAAGAGGACGTATAGGGGGTGACACTTGACCGATGCGAGAAGGTTAAACTTGGCAGTGGTGTGCAGCAATGTGCATTGCCGACCGAGCGAAGCCCTCGTCAATGTCAGCGGTAACTATAACCGTTCTAAGGTAGCGCATTTCCTTTCCGGGTAAGTTCCGGAGCGCACGAAAAGTGTAACGACTGGGGAACTGTCTCAAAGATGAGCTCGGTGAAATTGCGATTCCCGTGAAGACGCGGGATACCTGTAGCGGGACGAAAAGACCCCGGAAGCTTTACTGCAGCCTGGTATTGATTTCAGAGTTATGATGCGTAGCGTAGTGGCGAGCCTTTGAAGCGTCCCTTTCGGGGGACGTGGAGGCGACAATGAAACAGCCATCTTCATCACTTTGACGTCTCACCGGGGAGGGACCTTAAAATGGAAACCTCCCTGGGACAGTGCTTGGTGGGTAGTTTAAATGGGGCGTTTTCCTTAACTTGACAATGCTTCCGTGTTGTCAGAAGGGGGACCCGATCCAGTCTTAAGATTGGAGGGAAAAATCTAATGTATATGCTGGAACATCCGCGGTATCAGTTTGTACCTTTGTCGAAAAGGTGAAAATCAAACTGTGGCGTCCGATGAAAATCGGGCCGGCGGACAATCAGCAGGCAACCTCGACGTAAGAATTGAGGAAGTCCTCAGAGACTATCAGTTAGAGCGGCGCACTACCCGCGCGCCGTATGATATAGTCCGAACTGCATGGCGACATGCAGGCCGCGCAAGCGGCACCTAAATACCATGAGATCAAGAATCATTGAAGAGCTTAAGAAACATCTGAAGCTTACTGCAATGCAAAGATCTCTTCTCGTAGGCCTGCTTTTAGGCGATGGCCATCTGGAACTACAGAGTGGTGGCAGAGAATATCGTCTGAAAGTTGAACATGGAGTTAAGCAGAAGGATTATGTGGATTGGTTGTACGAACAATTCAAAGATTTTGTTCGTACGCCGCCGCGTATCAAGACCAGGATTGTAAAAGGAATAACGTGTAAGAGCTACGGCTTTACCACTTATTCCTACGGATCATTTCGTTTTTACGCCCAGCAATTCTACGTTGGGCGAAAGAAAGTGATCCCGAAACTGATCTCCAAAATGCTTGACCCTAGAGCGTTGGCAATATGGTTCATGGATGATGGATCTTTCAAGTCCGTCAGCCACAAGACCTATATAATCCATACGCATGGTTACGAGAAGAAAGATTTGGAGCGTGTAAAAGATGTGCTCCAAAAGAAATTCGGTATTATCGTAGGACTGCATAAGCAATATGATCGCTGGCGAATCTACATAATGAGTGATTCGGCAACGGCGTTCAGAAATCTTGTCAGTGCCCATGTAATACCGTCAATGCGGTATAAGTTAGGGAACATCAAGCCTAAAGAGTAACGGAGGAGTTTATTAAGGTTGGCTAGGCCCGGATGGAAACCGGGCGCGTCGTGTAAAGGCATATGCCAGCTTGACTGCAAGACCTACAAGTCGCGCAGGCGCGAAAGCGGAACTTAGTGACCCGACGATTCTTTATAGAAAGGTCGGAGACAACGGATAAAAGCTACTCCGGGGATAACAGGCTAGTCTGGTCCGAGCGTCCACAGCGACGACCAGGCTCGGCACCTCGATGTCGGCTCGCCCTAGCGCGGGGGTGAAGAAGCTCCCAAGCGTTTGGCTGTTCGCCAATTAAAAGGGCACGTGAGCTGGGTTCAGACCGTCGTGAGACAGGTTGGTCTCTATCTGTTACAGGCGTTTAATCACTTGAGGGGAGTTGACCCTAGTACGAGAGGACCGGGTTGAACATACCTCTGGTCTACCGGCTTTGGCACCTGCTGAAACGCCGGGTAGCTATGTACGGAAGGGATAAGTGCTGAAAGCATCTAAGCACGAAGCCCACCCCAAGATTAGGTGATATGGTCTCGTCGCAGACTACGACGTTGATAGGCTCTAGGTGTAAGGATCGCAAGGTCTTCAGCCAAGGAGTACTAATGACCCGCCAACCATCC
->MDEO01000036.1/702348-702384 Mesorhizobium sp. UASWS1009 41, whole genome shotgun sequence. 
-GGTCTCGCCGGAAGCGAGACCGCCGAACATGAAGGAG
->MEQJ01000121.1/2993-1439 Bdellovibrionales bacterium RIFOXYD1_FULL_53_11 rifoxyd1_full_scaffold_587, whole genome shotgun sequence. 
-AAACATGAGAGTTTGATCCTGGCTCAGAGCGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGTGAAAGGGGGCAACCCCGAGTAAAGTGGCGTACGGGTGAGTAACGCGTAGGTAATCTACCCTGGAGTTCGGAATAACCTGCCGAAAGGCGGGCTAATACCGGATAGAGCGAGGGAACCTGTAAGAGGGTTTTTCGGGAAAGGGAGCTCGCAAGAGCCCTTGCTCCGGGATGAGCCTGCGTCCCATTAGCTAGTTGGCGAGGTAACGGCTCACCAAGGCGATGATGGGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAAACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGACGGAAGTCTGACGCAGCGACGCCGCGTGAGTGAAGAAGGCCTTCGGGTTGTAAAGCTCTGTCACACGGGACGAACGGCGAGTGGGTTAACAGCCCATTTGATTGACGGTACCGTGGAAGGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTGCTCGGAATTATTGGGCGTAAAGGGCAAGTAGGTGGTCTCATTAGTCCGGGGTGAAAGCCTTGAGCTCAACTCAAGAAGTGCCTTGGAAACGGTGGGACTGGAGTCCTGGAGAGGGTCGTGGAATTCCCGGTGTAGCGGTGAAATGCGTAGAGATCGGGAGGAACACCAGAGGCGAAGGCGGCGGCCTGGACAGGAACTGACACTCAACTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGGGTACTAGACTTGGCGGGATTTGACCCCTGCCGAGTCGGAGCTAACGCGATAAGTACCCCGCCTGGGAAGTACGGTCGCAAGACTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGATCATGTGGTTCAATTCGAAGCAACGCGAAAAACCTTACCTGGGTTTGACATCCCCGGACAGCCGTAGAGATACGGTTTTTGTAGCAATACAACCGGGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTGGTGACATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTGTCCTTAGTTGCCAGCATTAAGTTGGGCTCTCTAAGGAGACTGCCGTGGTTAACACGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCTTTATGTCCAGGGCGACACACGTGATACAATGGCCGGTACAGAGGGAAGCGAAGTGGTGACACGGAGCCAATCTCAAAAAGCCGGTCTCAGTTCGGATTGGAGTCTGCAACTCGACTCCATGAAGGTGGAATCGCTAGTAATCGCGGATCAGCACGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGAAGCTGACTCAACCAGAAGACGTCCAGGCTAACCGTAAGGGGGCCGGCGGCGAAGGTGGGGTTGGTGACTGGGGTGAAGTCGTAACAAGGTAGCCGTAGGGGAACCTGCGGCTGGATCACCTCCTTT
->MNFI01000130.1/10369-10188 Gemmatimonadetes bacterium 13_1_40CM_4_65_7 13_1_40cm_4_scaffold_3525, whole genome shotgun sequence. 
-CCGTCCTAGACTGATTCGGGATCCACGTTTGCGAACGGGGATTTACGGAAGCCGGTGCGAATCCGGCGCGGCCCCGCCACTGTAACGGGCTGTTCATCGCGGCTCAGAGCCACTGGGGAAACCTGGGAAGGCGAGCCGCGTAGCCCGAAGCCAGGAGACGTCTTCGTTCGCGCCACCAATCA
->MLAY01000007.1/1262-1155 Marine bacterium AO1-C Bin2_contig__6B_len_915437_cov_89.8812_ID_11, whole genome shotgun sequence. 
-GCCGGTGTGGCGAAAATGGTTTACGCAGCTCAAGTTAGTTTGATTTGCGGCCAAGGCCTTGGGAATCGTGGCCTGTAAGGCGTGGGGGTTCGAGTCCCTCCATCGGTA
->ANKR01270450.1/11566-11419 Myotis brandtii contig270450, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGTAGTATCTGTTCTTATCAGTTTAAAATATTATCTATCTGCTGCAAAGCAAGCTGTCTAGAATGATATAACTAAGGTTATCTATAAAATAATGAGGAGTTTCAAAATAAAATATTT
->DS022282.1/1685882-1685929 alpha proteobacterium HTCC2255 scf_1100007007381 genomic scaffold, whole genome shotgun sequence. 
-TAAGGCTTACAACGGCTACCTGAAGTAAGTTGACATAAAAACGGAGCA
->EU420138.1/1-299 Bat coronavirus 1A strain AFCD62, complete genome. 
-GACTTAAAGATATAATCCATCTACAGATAGAGTGTACTCTTCTAGACTTTTGTCTACTCCCCTCAACTAAACGAAATTTTTGCCATATGTTTATGGCTAATTGAAATTTCAGTCGGTTGTTAACATACTTGCACAAGTGTCGTGCATGTCGCCAGTCCCTCCTTTCAGTTCCGTCTGTTAGGTATACTAGGTGGCTGCCTTTGGTTCAGTTCCGTCTGGCCATTGTGTGGATAGTACGTTCCGTCGTGCTTGAAACCGATAACTAGCAGGTATGTCGTCCAACCTTGTGACATTGGCCT
->LSGP01000020.1/293217-293477 Anaerosporomusa subterraneum strain RU4 RU4_contig_5, whole genome shotgun sequence. 
-GAAATGACGATGAACGGAACAGTAGTTACAGTCTGAGATAGTTTCAGAGAACTGGATTTGGTGTGAACCAGTACTATCTGCTGTCATGAATATCCTCCGTGAGTTGCACACCGAAGAATGTAGTAGGCTGTGCCGGGCCTCGATTGAGGAAACGCCACCCGTTATTGTGGCGAGGTATCGAGTGTAAACTCCGTACCGTTGAGAGACTATGGGCAACTATAGTAATTTGGGTGGTAGCGCGGATTAATCTCCGTCCCTTGT
->MEWZ01000006.1/7057-6737 Candidatus Adlerbacteria bacterium RIFCSPLOWO2_01_FULL_54_21b rifcsplowo2_01_scaffold_18878, whole genome shotgun sequence. 
-TGAGCGCGTTGAGTAGTAGCCCCGACGTAACGTCGGGGAGGAAAGTCCGAACACTCCCTCTGGAAAACTGGAGGAGAAAGGTAGCAGGTAACGCCTGTCGTGCGCTTTTTGCGGGCGCAAGAGGTGCGAACAGAGACGAGTCTTCGACAATTTAGGGTTTACCTTGAGTATGTCGAAGGGTGAAACGGCAAAATCCTTACCCGAGTGCAAGGCCGTGTCCCGAGAGTAATCGAAGGAAGTGCCGCTTGATCCCGACGGTGACGTCAGGACCAGATAAATTACTGCTCACGACAGAATTCGGCTTACAGACGCGCGCGCAGA
->JANL01000037.1/68389-68165 Alkalibacterium sp. AK22 AUG3_contig_1, whole genome shotgun sequence. 
-ACTAAACTGGATCTTGAAACACGTTCATGATTGATGCTTTACAGAGAGTCAATGCAGGCTGAGAATTGACAAGCAAATATCATGGTCATCATTCAAGGAGTTAGAAGCTGAATGTAGTAGGTTTCTACGTCTATCCGCGTTAAGGATACAGAGGATAAGTAGAAAAGCTCTAGTGGGCTGATACTTTTCAAACTAAGGTGGTACCACGAAGATTTCGTCCTTTCG
->LITN01000010.1/54782-54831 Bacillus sp. FJAT-21945 super19, whole genome shotgun sequence. 
-GAGAGATTTGCTCCGCACAAATGTATACGATGAAGCATTGTGTCAGGAGC
->JNFA01000019.1/339474-339242 Listeriaceae bacterium FSL A5-0281 contig000019, whole genome shotgun sequence. 
-ATAAAGACGTTGAAGGAGACAAGTAACGTTACCAAGTCATTGTTAGGGAGAGGTTACCTTAGACTGCAAGTAACCTTAGTGATACGTAATGCGAACATTTCAGCTCTGGAGTCGCTGTCGGGATTTTGTATAATGAAAGACAGATCGGTGTGAAGCCGTTATTGGAATGAAGTGGATAGCTTATTTAGCTGTCTATTAGGGTGGTACCGCGTGATTATAACCTCGTCCCTTTG
->ABLF02007471.1/1-1768 Acyrthosiphon pisum strain LSR1 Contig7649, whole genome shotgun sequence. 
-CATGGAAGTCGGATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAAGCAACTAGCTCTGAAAATGGATGGCGCTGGAGCGTCGTGCCTATACTCGGCCGTCGACGGCATAGTGGGGCCAGTCGTCGCTCGCGGCGGCCGGTCCCGGCAAGCCTCGACGAGTAGGATGGCGCGGCGGTGTGCGTCGAAGGGCAGGTCGCGAGACCGCCTGGAGCCGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATACTCGAGAGGGGCCCTCGGGGGCTGCCGTGGAGAAGGGTTTCTTGTGAACAGCCGTTGTCCAAGAGTCAGTCGATCCTAAGCCCGGGGAGAGATCCTCGTACCACGGGCGAAGGCGTTTTCGAATCGCCCTTGGGGCGAGAGGGAATCCGGTTCGTATTCCGGAACCCGACGCGGAACCGCTCCCTAGTGTTCGGGGCTCTTTTGTCTCGTCTGGGTAACCAGAATGAACTCGAAGAAGCCGCCGGGGGATCTGGGTAGAGTTCTCTTTTCTCTGTGAGCGTTGTACGTCCCTGGAATCCTCTAGCCGGGCGATAGGGACGCGAGCGCGAAGAGCACCGCTCGTTGCGGCGGTGTCCGTGATCCCCACGCGGACCTTGAAAATTCGAGAGAGGGCCACGCGGAGTCTTCGCGTCGGTTCGTACCGATATCCGCAGCAGGTCTCCGAGGTGAGCAGCCTCTAGCCGCATAGAATAATGTAGGTAAGGGAAGTCGGCAAAACCGATCCGTAACTTCGGGATAAGGATTGGCTCTGAGGAGCGTGGCTGCCGGGTTCGGGTCGTCGTAGAAGCGTAGGCGTTTTTGGCGACACCCCGGCCGTCGCCCGTGCGCCCGGTCTTCGGAACGGGAGCCTCGAGGCGGCCGCGGGCCCGTCGCCGTCCGCCGACCGTGGAACCACCGAGCTTCGGTCGCTGGCCGCGTCGCGGCCGGCCGACCGCCTTGGTGTCGGTTCGCCGTCACCGGGCGGTCCGGCCGCCGCGCCGTCGGTCGCGTAGCCGGATCGACAGCCATGTAACGGTCAACTCAGAACTGGCACGGACCAGGGGAATCCGACTGTCTAATTAAAACAAAGCATCGCGATGGCCCGGGACGGGTGTTGACGCGATGTGATTTCTGCCCAGTGCTCTGAATGTCAACGTGAAGAAATTCAAGCAAGCGCGGGTAAACGGCAGGAGTAACTATGACTCTTTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCTCACTGTCCCTATCTACTAGCGTTGCGACAACAGCGACATAGTTCAGACGTGTGTTTCCACGTTCGACGTTGCTCCGAAGGGCGATCCTAGTGGTGATAACTGGCGATTAACTTAACTTCGAAAGTTTACAGGAATTTTTTCAAAAAAGTGTTCAAAAAGTTTTGGTATAGTGCATAGTGCAATCTAAGTCGGGTTTCACGGAAGTTCGCTTAGCCGTTCGTGGTTAAAAGCCGAAAGGCCACTTTTACGTGTTACAGGATAGGACCTTACCGTAAGTGGAGGGGAGAGCTCCGGTCGGCAGTCACGTACACCGAGCAATTCCTGGAATCGGCCGCCCGTCTGGAAATTCGCGACACGTGTAAGTGCGTATCACTGTTCATAAAAGCGCATAAAATAATTAACACGGCCGCCGTGAATATTATTTGGGTAAAATCGTAAATAAAATCGTGTTTTAAGTAAAGCCTATAATTTCGTGATATACGTTAAT
->LQOS01000013.1/108713-108903 Mycobacterium doricum strain DSM 44339 contig_20, whole genome shotgun sequence. 
-GCCGCGCCATGCTTAGGATGTGCGATGTAATCGGCAGGCGTAGGAATCTGGTGAGAATCCAGAACGGTCGCGCCACTGTGAGAGTCAGACCCGACGCCTGCTTCATTCCACTCGGGACGCGAAATCCCGGAAAGGACCCCTGATGACGTCACCGCAAGCGCGCCAGACCCGCGTTCCGGCCATCGACCTGT
->KL543784.1/20050-21792 Capsicum annuum cultivar Zunla-1 unplaced genomic scaffold scaffold9433, whole genome shotgun sequence 
-TACCTAGTTGATCCTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCCATGCATGTGTAAGTATGAACAAATTCAGACTGTGAAACTACGAATGGCTCATTAAATCAGTTATAGTTTGTTTGATGGTATCTACTACTCGGATAACCGTAGTAATTCTAGAGCTAATACGTGCAACAAACCCCGACTTCTGGAAGGGATGCATTTATTAGATAAAAGGTCGACGCAGGCTCTGCCCGTTGCTGTGATGATTGATGATAACTCGACGGATCGCACGACCATCATGCCAGCGACGCATCATTTAAATTCTGCCCTATCAACTTTTGATGGTAGGATAGTGGCCTACCATGGTGGTGACGGGTGACGGAGAATTAGGGTTCGATTACGGAGAGGGAGACTAAGAAACGGCTACCACATCCAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCTGACACGGGGAGGTAGTGACAATAAATAACAATACCGGGCTCAATGAGTCTGGTAATTGGAATGAGTACAATCTAAATCCCTTAACGAGGATCCATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTTAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGGACTTTGGGATGGGCCGGCCGGTCCGCCTATGGTGTGCACCGGTCGTCTCGTCCCTTCTGTCGGCGATGCGCTCCTGGCCTTAACTGGCCGGGTCGTGCCTCCGGCGCTGTTACTTTGAAGAAATTAGAGTGCTCAAAGCAAGCCTACTGTCACGGGCCTAATTTTAACCACGTGCGGACAGCCTAACACTCACTATATTGAGGCTAAACTTCAGTCCTAAACCGCCCTGAACAACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACAAAAGTTGGGGGCTCGACGACGATCAGATACCGTCCTAGTCTTAACCTTAAACGATGCCGACCAGGGATCGGCGGATGTTGCTTTTAGGATTCTGCCAGCACCTTATGAGAAATCAAAGTTTTTGGGTTCCACGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGATGGAAGGGCACCACAAGGAGTGGAGCCTGCGTCTTAATTTGACTCAACACGGCGAAAATTACCAGGTCCAGACATAGTAAGGATTGACAGACTAAGAGCTCTTTCTTGATTCTATGGGTGGTGGTGCCTGGCCGTTCTTAGTTGGTGGAGCGATTTGTCTGGTTAATTCCATTAACGAACGAGACCTCAGCCTGCTAACTAGCTATGCGGAGGTATCCCTTCGCGGCCAGCTTCTTAGAGGCACTACGGCCTTTTAGGCCACGGAAGTTTGAGGCAATAACAGTTTCGTGACGCCCTTAGATGTTCTGGGCCGCACGCGCGCTACACTGATGTATTCAATGAGTTTATAGCCTTGGCCGACAGGCTCGGGTAATCTTTGAAATTTCATCATGATGGGGATAGATCATTGCAATTGTTGGACTTCAACGAGGAATTCCTAGTAAGCGTGAGTCATCAACTCGCGTTGACTACGTTCCTGCCCTTTGTATACACCGCCCGTCGCTCCTACCGATTGAATGATTCGGTGAAATGTTTCGATCGCGGCGACGTGGGCGGTTCGCTGCCCGCGACGTCGCGAGATGTCCATTGAACCTTATCATTTAGAGGAAGGAGAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTG
->CM001659.1/36667298-36667637 Nomascus leucogenys chromosome 13, whole genome shotgun sequence. 
-GCCGGGTGCTGGGGCACGCGCCTGGAGTCCCAGCTACTCCTGAGGCTGAGGCAGGAGGATGCTTGAGCCCAGGAGGTAGAGGCTGCAGTGAGCCATGATCACGCCACTGCACTCCTGCCTGGGCTGTCGTGGGCTATGTCTAGCTGGAGTCTGCACTAAGTTCAGCATCAGCGTGGTGACCTCCCAGGTGCAAGGGGACTACCAGGTTGCCTAAGGAGGGGTGAACCAAATCAGATCAGAAATGGAGCAGGTGGAAATCCTGTGCTAATCAGTAGTGGGATCCCGCCTGTGAATAGCCACTGCACTCCAGGCTGGGTGACATAGCCAGAACCCATCTTTG
->ALWZ041907802.1/9044-8520 Picea glauca, whole genome shotgun sequence. 
-GGGAAAGAAGACCTTGTTGAGATTGACTCTAGTTCGACTTTGTGAAATGACTTGAGAGATGTAGAATAAGTTGGAGTCATTTTCAATGGAAGTGAAATACCACTACTTTTAATGTTATTTTACTTATTCCGTGGGGCGAAGACGGGGCATTGCCCCTGTTTTTGGCCTTAAGACATGTTTCGGTGGGTCAATCCGGGCGGAAGACATTGTTAGGTGGGCAGTTTGTCTAGGGTAGCACATCTATTAAAAGATAACGTAGGTGTCCTAAGATGAGCTCAACGAGAACAAAAATCTCATGTGGAACAAAAGGGTAAAAGCTCATTTGATTTTGATTTTCGGTATGAATACAAACCATGAAAGTGTGGCCTATTATGAAAATGAAGTTATTTTGGCCTTAGATGATGGTGCATGTTTTATCAATGTGTAGCTTCACTTGTAATGCATCTTAAATTAATGCATAGCTTCACGTGTAATGAATAGTAAGAATCACAAGAACTTCCTGCTACATGCCTATAAGTTTAGCTT
->FAOM01433674.1/17830-17492 Triticum aestivum genome assembly, contig: Triticum_aestivum_CS42_TGACv1_scaffold_433674_5DL 
-TCGAATTGTTTGTTGACACGGACAAAGTAAGGGAAAACCTCTGAAAGAATTTCCATATTGACCTTGGACATATAAGAGTTCCGAATCAAATCTCTTTAGAAAGATGATCTTTTGTCTCATGGTAGCCTGCTCCAGTCCCCAAATTCAGAGAAACCTTGGAATTAAAAAGGGCAATCCTGAGGCAAATCCGTGCTTTGAGAAAACAAGGGGTTCTCGAACTAGAATACAAAGGAAAATGATAGGCGCAGAGACTCAATGGAAGTTGTTCTAACGAATCGAGTTAATTACGTTGTGTTTACCAAAAGTTCCTACATTAATGGGAAATGCCCTACCTTTGAG
->CM000916.2/22526794-22526579 Nasonia vitripennis chromosome 2, whole genome shotgun sequence. 
-AAGATCATACTTCACAGGATCATTTCTGTAGTATATCTTCACAGACTCTCTACCCAAAGTAGGAGTCGATGCAACCACGATGAGGAGACGTAGCTCTCCTTCCTGAGCGTGAGGACGACTCGGAATTGCGGCTTCGGTCGGAATACCAGTCATCGATGATCGTTCACCTTCTGCACTTTGTGCAGAAGGCATGGGAGGACGGGCTTTCTGAGTGGC
->MLCN01000008.1/279819-279740 Alkanindiges sp. H1 contig8, whole genome shotgun sequence. 
-GGTCTCGAGGGGTGCTGCAACAGTAAAGTAATATACTGCCAGGCTCGAGCATGTCATTTATTGAACGGCATCCGCGAATT
->JPUK01000002.1/192788-192900 Candidatus Micrarchaeum sp. AZ1 Contig2, whole genome shotgun sequence. 
-CCAAACGGTAATAGGAGCAGGGAAACGCCCGATCCCATTCCGAACTCGGAAGCTAAGCCTGCTCACGATATGTGTGTACTGTCTGCGGATGGGAAAGCATGTTGCTGTTTGGC
->AAQR03163520.1/18142-17999 Otolemur garnettii contig163520, whole genome shotgun sequence. 
-ATCCTTTCACAGCTCATAAGCGGGGCGATTGGGTTTTCATGCGCATGCGTGCGCACACCCCTCCTCCCTCTCCTTCCCCCCTTCCCCCACCCTCCCCGACCCCGCCAAATCTTGTTATGACATTGGCACATTACCCATCTGACA
->ABAV01003903.1/1546-1268 Nematostella vectensis strain CH2 x CH6 NEMVEscaffold_21_Cont3903, whole genome shotgun sequence. 
-TAGAACAATGTAGGTAAGGGAAGTCGGCAAAATAGATCCGTAACTTCGGGAAAAGGATTGGCTCTAAGGGTTGGGTCTGTCGGGCTGAGACTTGAAGCCAGTGGACCCGGCCCGGACTGGCCGAGGCCCTTCCGGGGGTCGAAGCTGGACCGGGAAGGGGCTGTTGGTGGATTGGCCCAGCTATGGTCGCGAGGCCAATTCGGCAGGCAATGAACAACCAACTTGCAATCAGATTTCGAATCGATCAAGAATTGAGTTAGAAGGTCCATGTACCATGTA
->AM910987.1/84270-80099 Plasmodium knowlesi strain H chromosome 5, complete genome 
-TGTTTTCTAAATAGGAGAGCGAATCCGCCGAATTTAAGCATATAATTAAGCGGAAGAAAAGAAAATAACTATGATTCCTTTAGTAACGGCGAGTGAACAAGGAAAAGCTCAAGCGGATAATCTGTGTGTCTTTTCCTTTTTTTTTAAAAGGTTTAGCACAAAGAATTGTCGTGTATAAAAATACTATAGTAACTTTTCGGTATCTGTAAAAATAAAGCATATGTTACGAAGCGAGGTGGAATGCCTCCCCCAAAGAGGGTGAAAGGCCCGTAGGAAAACATTTATGGTTTAGCGTTACTGAGAGACCTCTATATGTAAAAGAGTCGTGTTCTTTGAGATTGGAGCACAAATGCGTGTGATACATTTCACATAAAGCTAAATATGTGTAGGAGACCGATAGCAAACAAGTACCGTGAGGGAAAGATGAAATAGTACTCAGGAATGAGCAATTAAAAAGTACCTGAAATCGTTAAGATGGAACGGATTAAGAGAGAAAAAAAGTAAATGCAGTCAAATAGTGATTTAGCAGCACTATCATAATTTAACTGCTTTATTAAAAGAAACATCAGTAAAAAGTTTTACGACCTATTCGGATAAAACTGTTGATGAAAAAAACATTTAATTTTTTTTTCTTATCCCAGGATAAAAAAAAAAATTAATAGTCTTTTTCACATTATCCTTATTTTAAAATATAGGATAAAAGGTTTTATAGAAAATCACGAAATAAAAGTGATAAGATAGTCCATTTTACTGAGGTTATATAAAAATGTGTATTTGCTTGTAAAAAAAAAAAAATATTCTTTGTGAATATCTTTTTTTTTACAGCTGCGCATTTTAAGTTGTTTCTATAAGATACTTTCTTAACCCACTCGTCTTGAAACACGGACCAAGGAGTCTAGCAAATGTGCAAGTGTATATGATATATTAAACATTAATGTACGTGAATAACGTACTGTTTTTATACGCATAATTAATGTAATATGTTATAATTTGTAGAATTAGTTGATAATTGCAAAATTATCACTAACGCATACAATACCGGTAGGCAAATTATGCCATATTGAGTAAGAGCATATTTGGTAGGACCCGAGAGGCTTTGAACTAAGCGTGGTGAGATTGAAGTCAGACGAAAGTCTGATGGAGGATCGAATTGATACTGACGTGCAAATCGTTCATTTCAATCACGTTTAGGGGCGAAAGACTAATCGAAAAGCCTATTAGCTGGTTATTTTCGAAAGATCTCTCAGGATCGCTGGAGTTGATTGTTATAATTTTACCAGGTAGAGACAATGATTAGAGGACTCAGGGAATTGAATTTCCTTGACCTATTCTCAAACTCCCAATGGGTAAAAAGGGATAAAAATAACTTTATTGTATTTTTCTCTATTCAAATAAAATAACTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGAGGGATGCTCCTAACGCTTGGATAAGGTGCCTAAATATTCGCTCATCAGATCCCATAAAAGGTGTTGGTTCATTATGACAGTAGGACGGTGGTCATGGAAGTCGAAATCCGCTAAGGAGTGTGTAACAACTTACCTACCGAATGAACTAGCCCTGAAAATGGATGGCGCTAAAGCGAATTACCGATACCAGGCCATAGAAGGGCAAGAAAAAGAATTAGTACTTTCGGGTGTTTTTTCTTTTTTAGGAACCTTCTATGAGTAGAAAATCGTGGGGTTTTGTGTAGAAGCGAAATACGTGAGTTTTCGTGGAACATCTCCCTAGTGCAGATCTTGGTGGAAGTAGCAACTATTCAAATGAGAACTTTGAAGACTGAAGTGGAGAAGGGTTTCTTGCCAACTGTGTTTGTACAAGAGTTAGCCGCTCCTAAGAGATAGCTGAAAAGTGTTTATATGGGGAGGATTCTAATCTTTCTATCCCCGTCTCGAAAGGGAAACAGGTTTATATTCCTGTGCCAATACAAATCTATGGGTTAATTTTTAAAAGATGGCAACATATAGACAAATGAACCTCTTTACATAGGTTTTACCATCGGGGTGCGTTATCTTTGCACTTTACCTTTATAGCATACCTTGGAATCAATTTACTTGGAGAAGAGGTATGTTGAAGTCAATTCAGTTAAATTTTTGTATGGTTCTGTAATTCTCATTACAGAATTATATGTAAAAACTTTCCTGTTTTGTAGCAATAGTAATTCGTTTTTATGAATTATTCGATTCGGTATAAACTATCCTTGAAAAAAGGGGGGAACAACAAACCAAAGGGGGAGAAGTAGAATCGCCTACAAGTGATTTTAGTAATCGCAAGATTGCTAGTTCGGTTGTAAAAAGATTCTTTTCTCATTCTTGGTATGTACAACTCTAATTTGTAAAAATGAGCGTACCAACAACCGCATCAGGTCTCCAAGGTTAGTAACCTCTGGTTAAATAGAAAAAAGTAAGTAAGGGAAGTCGGCAAAATAGATCCGTAACTTCGGGAAAAGGATTGGCTCTGAGGACATTAGAATGGAAAGAAATAGAAATATAGTCGAAAGAAAAGTCATTGAGGTGCTTTTACATGTTTTTTTTTTCCACAAAAAAAACGTGTAGGCATTTCTTTTGCACTCTTTTCTCTTCTGTTTTCCTTTTCTGCCCCCATTCGCCGTCATATATATATCTTTTCGCTTCGGCGATTGGCGTACATATGACACTTATAATGTTAACTCAGAACTGAAACGGACAAGGGGAATCCGACTGTTTAATTAAAACATAGCATTGTGACAAGCCATAACTGGTATTAACACAATGTGATTTCTGCCCAGTGCTTTGAATGTCAACTTGATGAAATTCAATCAAGCGCAGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTACTTGCTATCTAGCGAAACCACAGCCAAGGGAACGGGCTTGGCCAAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTTACTCTAGTCTGGCTTTGTGAAACGACTTAAGAGGTGTAGCATAAGTGGGAGTAGAGATCGAAAGGTCTTTACGACAGTGAAATACCACTACTTTTAACGTTGTTTTACTAATCCATTTATTGGAATATATATGTATAAAAGGGATGCTCCTTTTTTTTTTAAGAAAGGGGTTTTATCTTTTACATATTATCGCAGAATTTATAGTTAGGGCTATGCATGTAAAAAATGTGTAGTTTTATCTATAGTTCCGATTTCTTATGGAGACATAGCCAGGTGGGGAGTTTGACTGGGGCGGTACATCTGTTAAACAATAACGCAGATGTCCAAAGACAAGCTCAGAGAGAACAGAAATCTCTTGTAGACTAAAAGGGGAAAAGCTTGTTTGATTTTTACTTTCAGAAAAAGTAGAAAACGTGAAAGCGTGGCCTATCGATCCTTTACATTTGCAAAATGATGGAGTTTATTCTCTTACTGTGCATGTAGAGGTGTCTGAAAAGTTACCACAGGGATAACTGGCTTGTGGCTGCCAAGCGCTCCTAGCGACGTAGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGGGACGCAGAAGTCTCAAAGTGTCGGATTGTTCACCCGCTAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGAATACTATTATTTTTATATACATATAGTATTGTGACAGTAATCCAACTTAGTACGAGAGGATTAGTTGGTTCAGACAATTGGTACAGCAATTGGTTGACAAACCAGTGTTGCGAAGCTAAGTCTGTTGGATAATGGCTGAACGCCTCTTAAGCCAGAACCCATGCTGATTAAACAATATTATTTCGATCTTTTTTGTAACAAATTTTTTACCGTCGATGTAAAAGAGAAATTATATATGCAGTTCTGTGTTTTTAACCGGGTGCATTATTAATCCTATTAACATATAATACTGTGTGTGTATCGTTTGCAAAAACTTACACCAAAACAGTAAAATGTTTAATATTATTTTAACAACAAGAAAGATTATCTGTGTTTGTAGACTACTTACTTGGTCCCGGGGTGCTGTAAACATGAAAGTAAACTTTGTTTTACGATCTGTTGAGGCTTATCCTCAGTGACATAAGAAAAT
->LTWW01000048.1/24870-24711 Staphylococcus sp. HMSC078E07 Staphylococcus_spHMPREF2905-1.0_Cont825.1, whole genome shotgun sequence. 
-AGTGTCTTTTAAAAAGAGTCCAGAGAGGCTCAAAAGACAGGGTGACTAATGATATAAATATGATTAACTTTAATTGTTCGATTGTTATCAGACGAATCATATAAAATATTTTTATATACATTAAACCTCATGTCTTTGTAAAAGGCATGAGGTTTTTTCT
->MTEM01000151.1/7116-7366 Desulfobacteraceae bacterium IS3 Ga0073107_10151, whole genome shotgun sequence. 
-ATACCCGAAATTTGTTCAGGTGTTTTATCGCTTAATAGGGAACCCCGTGAAAATCGGGGGCGGGCCCGCCGCTGTAATCGGGGACGAACGCCGCTTGAAACCACTGACGGAGAAAATGCAAAATGCAAAGTGCAAAATGCAAAGTTAACTTTGCACTTTTAACTTTACATTTTGCATTGTATCTGTCGGGAAGGTGCGGTCAGTAGGATGAACCGAGAGTCAGAAGACCTGTCTGAATGATATACCGGCGT
->JH591489.1/51165-51260 Lepisosteus oculatus unplaced genomic scaffold UNK80, whole genome shotgun sequence. 
-AACCTTTTATTACTTTTTGATAATAAAAAAAAATCTGTTCTTATCAGTTTAATATCTGATACGTCCCCCATCGGGGGACCACATATTAAACNNNNN
->MICY01000022.1/569-1 Tenericutes bacterium GWF2_38_8 gwf2_scaffold_13316, whole genome shotgun sequence. 
-TTTATGGAGAGTTTGATCCTGGCTCAGGATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAACGCACCATTTCGGTGGTGAGTGGCGAACGGGTGAGTAACACGTAGGTAACCTGCCCTTAAGACGAGGATAACCAAGGGAAACTTTGGCTAAAACTGGATAGGAACATCGAAGGCATCTTTGATGTTTTAAAAGACCTAGCAATAGGTATGCTTAAGGAGGGGCCTGCGGCGCATTAGTTAGTTGGTGAGGTGAAGGCTCACCAAGACGATGATGCGTAGCCGGACTGAGAGGTTGAACGGCCACATTGGGACTGAGAAACGGCCCAAACTCCTACGGGAGGCAGCAGTAGGGAATTTTCGGCAATGGGGGAAACCCTGACCGAGCAACGCCGCGTGAATGACGAAGTACTTCGGTATGTAAAGTTCTTTTATCAGGGAAGAATGGCTAGCGGAAAAGCTAGATTGACGGTACTTGATGAATAAGCCCCGGCTAACTATGTGCCAGCAGCCGCGGTAATACATAGGGGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGGGTG
->ABBZ01000577.1/639-936 Beggiatoa sp. PS contig21537_2600-2601, whole genome shotgun sequence. 
-CAAGGGACTTAAACAAATTTGAGCACCTATTGCGAAATCTTTAGGTGAATGGAGTCTAATTCGGCGAAACCTTTAAAATGACAACGCCGAGCTAAGCTCAACGGTGGGGGCAAGGAAAGGGGATAATCATATCCCTTTTCCTTTCCCCTTTATTATTTTTTCTAAACCATTTCTCCTCCGTTGAGAAAGTGTAGAGACCATACGGCTCCTGCCTGACTAAATCCCTTCAATTATTTGATTGCGAGGCATTTAAAGGCAAAGACAGGGTCCAGACCACAAACATTCAATTAATTGAAAA
->MKTL01000001.1/659200-659282 Clostridiales bacterium 38-18 SCNpilot_bf_inoc_scaffold_0, whole genome shotgun sequence. 
-CTATTATCTTGGCAAACTGCTTGAAAGAGTAGGACGCAAAGTTTGAAGTCTAAGGCACTAGCTATGACCGTTCAACTGCAGTA
->CP000680.1/4301122-4301323 Pseudomonas mendocina ymp, complete genome. 
-CGGGTTTACTCCTGGTTTTTACCGTTTCGCCAAACCGAGGTTCGGCGGCGTTTTGGTGTCTGATTCGGTAACGAATCGGGAGCACCATCTGCGTAGGCCATCAGGCGAACCTGACATTTAAAACGCGAGTCACCTACGGTCTTGGATAGCCCCCGCCAGGCAGGGACCCCAATCTTTCAAAGCCGGCAGCGCATGGCTGCCG
->KK198757.1/45732841-45732932 Eucalyptus grandis cultivar BRASUZ1 unplaced genomic scaffold scaffold_5, whole genome shotgun sequence. 
-TGATGATAATGATGATGATGATGATGATGATAATGATGATAATACTAGTAGTAGTAGTAGTAACATCATCATCATCATCATCATCAAAGGTA
->CP000705.1/1964394-1964162 Lactobacillus reuteri DSM 20016, complete genome. 
-TAAAAAACGTTGACCGAGAATCGTCAATTCTGCTGAATTAAGAGAGCCGGTGGTTGGTGGAAACCGGTAGGAGGTAGTTGCGACAAATCCCTCGCGAGTTGTATGCCGAAATAATAGTAGAACATACTGGTAGCAGCCATTATCTTGCCGATTAATTGCCATTGTGGGCAGTTGATTGAGGCAACCCTTGTGTTGTAAATAAAGGTGGTACCACGTTGATAGACGTCCTTTTA
->AHHD01001364.1/1-303 Macrophomina phaseolina MS6 contig01813, whole genome shotgun sequence. 
-GTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCTGCCGAAGTTTCCCTCAGGATAGCAGTAACGTATTCAGTTTTATGAGGTAAAGCGAATGATTAGAGGCCTTGGGGTTGAAACAACCTTAACCTATTCTCAAACTTTAAATATGTAAGAAGTCCTTGTTACTTAGTTGAACGTGGACACTTGAATGTACCGTTACTAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGAACGCGATGTTAAGGTGCCGGAATGCACGCTCATCAGACACCACAAAA
->AFYH01130564.1/25905-25790 Latimeria chalumnae contig130564, whole genome shotgun sequence. 
-TTTGAAACCCAAACCAGCTAGATTTAATTCTATCCACGTCTGATCTCAGAAGCTAAGCAGGATCGGGCCTGGTCAGTACTTGGATGGGAGACCACTGAGGCAGCCCAGGTGCAGTC
->KB944511.1/1034622-1034709 Plesiomonas shigelloides 302-73 genomic scaffold scaffold00012, whole genome shotgun sequence. 
-GTAAGACGCGCTATTTTGTTGTCATCACATCCCTGAAATTACACACGCAGAGATGTATTTCGGCCACCCCACCTTGGAGTGGCCTTTT
->CM002812.1/447709-447914 Capsicum annuum cultivar Zunla-1 chromosome 1, whole genome shotgun sequence 
-TCAGTCATAGTTTGTTTAATGGTATTTATTACTCAAATAATCATAGTAACTCTAAAGATAATACATGCAACAAACCCTAACTTTTTAAAGGGATGCATATATTAGATAAAAGGTAGATGTGGGCTCTTCCCATTTTTTTGATGATTCATGATAACTCAATGGATTGCACGGTCATTATGTTGGCGACACATCATTCAAATTTTTGC
->AZHD01000026.1/410476-410398 Sporothrix insectorum RCEF 264 scaffold_26, whole genome shotgun sequence. 
-AAAGGGGTAGTATAATAATTAAACACTTAAAAGACGCCGTAACGCCGCGACGTCGTAGGTTCGAATCCTACCCCTTTTA
->CM002818.1/23807342-23807451 Capsicum annuum cultivar Zunla-1 chromosome 7, whole genome shotgun sequence 
-TTTTGTATTTTTCCACAGCTTTCTTGAACTGCATCTAATTACGATTTTCACTAATGAGGAAATTAATTCATATCGTTGCGGTTCAATAAAGCTGTGGGAAGATATAGATA
->AYZL01000006.1/155934-155671 Lactobacillus floricola DSM 23037 = JCM 16512 strain DSM 23037 NODE_9, whole genome shotgun sequence. 
-AATTTTACTGAGAAAAGATGAGTAAATATTTATCTTATTTTAACAGAGAGCCATGTTAGGTGAAAGATGGTATTTAAGAAAATATTGAAGATGGTCTTGGAGTAAGTTTAAATTGTGAGCCAGTTAGGTTAGCAATTTACGGGATAACACACGTTACTGTGTTGAAGGATAGCTACCATGAGTGTCCGGATCGAAGATGGTGATAATAGCATTGTATAATTATCACTAATATAGGGTGGTACCGCGTTTAACAACGCCCCTAGG
->ALWT01124023.1/1602-1388 Myotis davidii contig124023, whole genome shotgun sequence. 
-ATCGCTTCTTGGCCTTTTGGCTAAGATCAATTGTAGTATCTGTTCTTATCAGTTTAATATATATTTCCAAATTTTTCAGGTGGATGCCCCAAAGAGGGATTTCTGGGTTATATGGTAGCTCTATTCTCAATTTTTTTTTTGAGGAACTTTCATACTGTTAACATAGCGGCTGTAACAATTTACATTCCCACCAGCAGTGCATGAGGGTTCCCTTT
->JTDY01005470.1/30475-30582 Operophtera brumata OBRU01_Sc05470, whole genome shotgun sequence. 
-TGATGATGATGGTGATGATGTTGGTGGTGGTGGTGATGATGGTGGTGGTGTAGGTGGTGATGTTGGTGACCATCATCATCACCACCATCATCATCATCATCACCTGCA
->LN774769.1/2382714-2382521 Lactococcus piscium MKFS47 genome assembly, chromosome: I 
-GAAGCACTGGAATGTGCGAACTTACTCACATTTTTGACCGACTAAATCGTATTACCTAGGGAGTCTTTGAGACATCTTACCGCGTGCAAGCCATTTTAGATGGAAGCTGCTAAGTAAGAGCGAGACGCCCACCTGTTTAACATTTACAGCGGGTTCAATACAAGAGTGAGTAACGGCATTCAATCAGTGCTTTT
->AYUG01147828.1/3237-3115 Fukomys damarensis contig147828, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGTAAACAACATCTTATTAATTCTGGTTTGATTGTCTTTACCAAAAGAAATCATTCCTGAGGTTTTCTTATGGAAAATGTTTTGGAACTTTC
->URS0000D69AE5_12908/1-140 unclassified sequences RAGATH-24 RNA 
-TTGACAGTCCAAAAACCACCTGCCCTCGGGAGATACCCGAGGTGTGACCTTCGCCGTTTATCGGTCGCCTCCCAGATTCATCGGGGGGCGGGGAGAGAGGGTCAGCGATTCGTTCGCTTGATGACGTGGGAATAGGACAC
->KB095811.1/12337799-12337623 Helobdella robusta unplaced genomic scaffold HELROscaffold_1, whole genome shotgun sequence. 
-TGATGACGATGATGATGATGATGATGGCGACGATGATGATGATGATGATGACATTGTTGTTACATCAAAACAGCGATTTCGAATGCATAATTGGATGTGTTTTTGTTTGGCCCGGCAAATAACTGCTATTAAATGTCATCATCATCATCGTCGTCGTCCTCATCATTATCATCATCA
->LL990082.1/1-981 Schistosoma rodhaini strain Burundi genome assembly, scaffold: SROB_contig0004979 
-GCATTGCGATGTCCACTGATTGGTTTTGACACAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGGTAAACGGCGGGAGTAACTATTACCGACGTTCAATCAGCTGCGTCAACCGCACTGAATTGCATCCTACGTGTGGGGTGAAGCAAGGAGACCCCCTGTCGCCACTCCTCTTCATCATGGTTCTCGACGAAGTACTGGAAGGTCTAGATACAATGACCCACCTAACAGTTGATGGAGAGAGCTTGAACTACATAGCTTATGCTGACGATCTCGTAGTTTTCGCTCCAAATGCAGAACTCCTTCAACGAAAACTCGATCGAATCTCCCTACTTCTACACGAGGCTGGATGGTCGGTTAACCCTGAAAAAAGCCGGACCCTGGACCTAATCTCTGGTGGCCATTCCAAAACCACAGCGCTCTCTCAGACAGAATTCACCAACGCGGGGATGCGTATACCACCGCTTTCTGCCGCCGACACCTTCGACTACCTGGGTATCAAATTCAACTTCAAGGGCCGATGCCCAGTGGCCCATATTGACTTATTGAACAACTACCTCACGGAAATATCGTGCGCTCCACTTAAGCCGCAGCAGCGCATGAAGATCTTGAAAGATAATCTACTCCCTCGACTCCTCTACCCCCTGACTCTAGGAATAGTACACCTGAACACCCTGAAGTCAATGGACCGAAATATCCACACGGCCATAAGGAAATGGTTGCGGCTACCCTCCGACACCCCGCTAGCATATTTTCACTCACCCGTCGCTGCCGGAGGCCTAGGGATCCTCCATCTGTCCTCATCGGTTCCATTCCACCGTCGAAAACGTCTAGAAACCCTCCTATCTTCACCGAACCGCCTACTGCACAAGTTGCCAACTTCTCCAACACTAGCTTCTTATTCACACCTTAGTCAACTGCCAGTTCGAATTGGGCACGAGACCGTAACGTCTAGA
->BDDD01008159.1/30464-30638 Cephalotus follicularis DNA, scaffold: scaffold8159, isolate: St1. 
-ATACCCTTAACTTTTGGCTAAGATCAAGTGTAGTATCTGTTCTTCTGAGTTTATCATCTCATATGATTCACACGATATTTTTTTATATGGGAAAAGACTCATCACAATAGCTTACTATTGGGGTTTTTTAGCGTCCCTTATGTGTTCCATACCGTATGGACCTGACGCACCCCTA
->ALYE01001358.1/3372-2729 Gossypium raimondii Chr01_contig_1358, whole genome shotgun sequence. 
-AATACGAACCGTGAAAGCGTGGCCTATCGATCCTTTAGACCTTCGGATTTGAAGCTAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAGCAGAATTCACCAAGTGTTGGATTGTTCACCACCAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTACCCTACTGATGGCCGCGTCGCATAGTAATTCAACCTAGTACGAGAGGAACCGTTGATTCGCACAATTGGTCATCGCGCTTGGTGAAAAGCCAGTGGCGCGAAGCTACCGTGCGCTGGATTATGACTGAACGCCTCTAAGTCAGAATCCGGGCTAGAAGCGACGCACGCGCCCGTCGCCCGATTGCCGACCCGCAGTAGGGCCTCTGGCCCCCAAGGGCACGTGTCGTAGTGCAGCGGCCGCGGCGGACAAGTCGCGGGCGCCTCCTGGAGCGTAATTCCCACCGAGCGGCGGGTAGAATCCTTGCAGACGACTTAAATACGCGACGGGGTATTGTAAGTGGCAGAGTGGCCTTGCTGCCACGATCCACTGAGATTCAGCCCTTTGTCGCTTCGATTCGT
->CM001740.1/4627691-4627566 Gossypium raimondii chromosome 1, whole genome shotgun sequence. 
-GGGCGTAGGCCTCTTAAAAGGAGTGCAAAGGCAGAAGGGAGCTTGATTCAAGACCCACCTGTCTAGTAAGGACGAAAATCAGCTTTAGTGATCCGATTGTGCCGAGTGAAAGGGTCGTCGCTCAAC
->KB730334.1/190955-191028 Fusarium oxysporum f. sp. cubense race 1 unplaced genomic scaffold scaffold395, whole genome shotgun sequence. 
-GCCAAGGTGGCCGAGCGGTCTAAGGCGCCAGACTCAAGATCTGATTGGTTGGATCTAGAATCCCAACCTTGGCA
->MHLG01000025.1/17211-16820 Candidatus Liptonbacteria bacterium RIFOXYD1_FULL_36_11 rifoxyd1_full_scaffold_658, whole genome shotgun sequence. 
-GGGGGTGAAAGGGCTCGACGGAGTTTCTTTGTTATAAAAGTGGCAGGTAGGTTTGACGAGACCTTAAAAACGTCAAAAAAATAAGTGCCAACTTATTCAACAGACAACCGGCTTTAGCTTACGCTTAAGTTGGTTGTAACCTTAGCTTTTATGCTGAGGCGTCGCTCTACTTTTTGCTTATAGGAGTGGAAGCGGTGTAAAAGTATAAGCTTTTCTTACTCTTTTAAACTTGGGGAGTGGGAGAAAAAAACAGGTTTGGCGGGTAAAAACTTTTTGGTAAATTATAAATTTTTACTCGTTTACCGAAAGGTAAAAAATAAAATTTACCTATATCTGTAGAAACTTTTATGGCTCAACTTCGGACATGGGTTCAATTCCCATCATCTCCACTA
->HF992493.1/15144-15489 Mycoplasma sp. CAG:877 genomic scaffold, scf27 
-AATATATAGACAAACGCTGGGACTCTTGAGGTCCTTGAGGAAAGTCCATGCTCGCACAGTCTGAGATGACTGTAGTGTTCATTCTTAGGGAATAAATAACCTAAGGTAGTACTTGTACTAACGGCGGATACTATATCTAAGTCTTATGATATGATATAGTCCATAAAGTGCCACAGTGACGAATTCTTTGGAAACGAGGAAGTGAAACGCGGTAAACCCAATGAGCGAGAAACCCAAATTTTGGTAGGGGAGTTCCAACTTCGAGAAATGAATTGGAGTGGAGACCAGTAATGGTAGATAAATGTTTGTCGCTTAGGAAACTAAGAACAGAACATGGCTTATTTAT
->CM001498.2/114148093-114148035 Papio anubis isolate 1X1155 chromosome 8, whole genome shotgun sequence. 
-TGACTTATTTGGTTAAAGTACCTGTCTAGTAAACAGGAGATCCTGAGTTTGAATCACAG
->KE356582.1/1391668-1391842 halophilic archaeon J07HB67 genomic scaffold scf_7180000098878, whole genome shotgun sequence. 
-ACTGCAGGCTGTCGCTGAGACATGGTCGCTGATGTGCAGAGTAGGTAGGAGTCGTTACCGAGGCCCGTGCGCCAGCACGGCGCCCAGACACACATGAAACACTACCCGTCAGTGACTGTGACTCTCACTCCGGGAGGAGAACACCGGTAGCCGGGCAGTTTGACTGGGGCGGTAC
->CM000820.5/64985614-64985509 Sus scrofa isolate TJ Tabasco breed Duroc chromosome 9, whole genome shotgun sequence. 
-GTTCTTGCCTCGGCAGTATATAAACTAAAACCGACAATACAGAGAAGATGAGCATGGTCCCTGTGCAAACATAGCATGCAAATGTCCATAAAAAAGAATGCTATTT
->CM000791.1/61008405-61008287 Oryctolagus cuniculus chromosome 2, whole genome shotgun sequence. 
-ATCGCTTCTTGGCCTTTTGGCTAAGATCAAGTGTAACAATGCTAAAACATCAAAAAGATATTCAGTCTAAGTTATATATTATACAAAATATATTTGCTGTTATATATATTTAAACCTCC
->GL637601.1/22009363-22009461 Caenorhabditis tropicalis strain JU1373 unplaced genomic scaffold Scaffold629, whole genome shotgun sequence. 
-TTTCGAAACAGAGTGACCGTCTGTAGTTTTTTTGTGTAGTGCTCCGAGCCAAAATGTGTTCGAAGCACCACGAGAAGCTGCAGATGGAACAACTTGTAT
->MNXL01000222.1/6266-6479 Anaerolineae bacterium CG2_30_64_16 cg2_3.0_scaffold_3852_c, whole genome shotgun sequence. 
-CTCTTATCCAGAGAGGCAGAGGGACCGGCCCTGTGAAGCCTCGGCAACCAGGAGATGGTAAATTGGTAAACTGGTAAACTGGTAAATTGGTAAATTGGTGGTCTGCTCGATGGGCAGCGACTTGCCACCAATCTACCAACCTACCAATCTACCAATCTACCAGGTTACCACCCCATGGTGCCAATTCCGGCAGAGTTGATCTGGAAGATGAGAG
->MEVM01000037.1/1634-1766 Candidate division WWE3 bacterium RIFCSPLOWO2_02_FULL_53_10 rifcsplowo2_02_scaffold_176987, whole genome shotgun sequence. 
-AGTTTATTAAGAGCGGCGGTTAGAGGCCTGGCTCGTTGACCCGCCCAGCAACTTGTTTGCGAGGCGTTGGAGAAACCCTCCGACAATCTTGGGATAAAGTGCTAAATCCAGCCCCGCTTGGGGAAGATAAATT
->ALWT01215141.1/49283-49606 Myotis davidii contig215141, whole genome shotgun sequence. 
-GTTTGTAAGAACGGACATGTCATGTGACATCTGTCACCCCATTGATCGCCCGGGTTGATTCGGCTGATCTGGCTGGCTAGGCGGGTGTCCCCCTCCTCCCTCACCGACCCATGTGCGTCCCTCCCGAAGCTGCGCGATCAGTCGAAGAGGACGACCTCCGCTCCCCCCAGAGGACCGGTCTTCGGTCAAGGGTATACGAGTAGCTGCGCCGCCCTGCTAGAACCTCCAAACAAGCTCTCAAGAAATATCCAGGGGAGACAGAGTAAAATTTAAAACGAGTTTGGCCTATATTCAGTCTTAAAAGTTTCATGAAAATATAAAACT
->AYZV02077796.1/1114-1237 Spinacia oleracea cultivar SynViroflay scaffold18850.con0006.1, whole genome shotgun sequence. 
-TAACCCCGGCACAAGGTTGACACAAAATTGAAATGATACAGAGAAGACATTTTCAAGATTGAAATTAATATGGCCCCTTTGCAAGGATGACACAAATTTAAGAAAACATTTTCAAGAAATCTTT
->FR899405.1/21238-21732 Mycoplasma sp. CAG:472 genomic scaffold, scf68 
-TTGATATAATATTTATGTGGTGCATTATGCTAGTCACAATCACTATTTGAAGATGGGGCTAAAAATCCATTAATTGATACAATTGCACTTTATATATTTGCTGCTTCTGCCCAAGTTGGGGTGAATATGTAATTTAAAATTATAGGGAAATCATAACGGCATATGACTAACCCCCTGTAATTAAGCAAAAAAGGAAGAGTTATTCATGTCGTGCGTGGTTATTAGGGATTTAACGAATAATAATGTTGATGAAATCTTAACTGCAAAAGCGAATAAGAATAGTTTAGATGTGTCAGGGAAAACCTCTAGCGTGTTATTTATTATAAAGATTGAAGTGCGGACTATGTGGCAATCGAGTCATTAGTTAGGCAACTACTAATTATTTTCTTTAAAGAGAAATCGCCTAAGGGTAACCAAGGGAGAGAAAATAGAGAAATTCAACTCGACCAAAGCCGTAAGATTAATTTATAATAAACCATAACATTTTTAATAACT
->AFTD01054950.1/9395-9285 Cricetulus griseus cell line CHO-K1, whole genome shotgun sequence. 
-ATCGCTTTTCAGTCTTTTGGCTAAGATCAAGTTTAGTATTTGTTCTTATCAGTTTAGATTAGTACCCTGTTCTCTTTGAAGTATAAAAATAAGGTGAATTTAAAAAGTCAT
->MNTO01000093.1/21391-21316 Ruminococcus sp. CAG:9-related_41_34 Ley3_66761_scaffold_4291, whole genome shotgun sequence. 
-AGTCCGTGTGATGATGTAGCACCGCTGGCAAAGGGTACGGCTGGATGAGAACCATGCAGGGGTGAGATTCCCATGA
->CP002528.1/2537163-2537236 Dokdonia sp. 4H-3-7-5 chromosome, complete genome. 
-ATAACCAGGAGTTGGTCTATTAGAGAAGTCAGCAGAAGTCATAGTAGCTAAAGCCTGATATTTTAGTGAAGGAC
->AOTI010107864.1/9315-6890 Triticum urartu cultivar G1812 contig107864, whole genome shotgun sequence. 
-TGGACCTAAGCCTGAGACTAAGTGCTTCTACTGCAAAGGGACTGGTCACTAAAAGCGGAACTGTCCCAAGTATTTATTGGATGAAACTAAGCAGAGGTCCGAACCGACTGATGTTGAAGAATCAGCGGATGAGTTGTGGTTAGGGGTGAAATGCCACTCGAACCCAGAGCTAGCTGGTTCTCCCCGAAATGCGTTGAGGCGCAGCAGTTGACTGGACATCTAGGGGTAAAGCACTGTTTCGGTGCGGGCTGCGCGAGCGGTACCAAATCGAGGCAAACTCTGAATACTAGATATGACCCAAAAATAACAGGGGTCAAGGTCGGCCAGTGAGACGATGGGGGATAAGCTTCATCGTCGAGAGGGAAACAGCCCGGATCACCAGCTAAGGCCCCTAAATGACCGCTCAGTGATAAAGGAGGTGGGGGTGCAAAGACAGCCAGGAGGTTTGCCTAGAAGCAGCCACCCTTTAAAGAGTGCGTAATAGCTCACTGATCGAGCGCCCTTGCGCTGAAGATGAACGGGGCTAAGCGATCTGCCGAAGCTGTGGGATGTCAAAATGCATCGGTAGGGGAGCGTTCCGCCTTAGAGGGAAGCAACCGCGAAAGCGGGGGTCGACGAAGCGGAAGCGAGAATGTCGGCTTGAGTAACGAAAACATTGGTGAGAATCCAATGCCCCGAAAACCCAAGGTTTCCTCCGCAAGGTTCGTCCACGGAGGGTGAGTCAGGGCCTAAGATCAGGCCGAAAGGCGTAGTCGATGGACAACAGGTCAATATTCCTGTACTACCCCTTGTTGGTACGGAGGGACGGAGGAGGCTAGGTTAGCCGAAAGATGGTTATAGGTTTAAGGACACAAGGTGACCCTGCTTTTTCAGGGTAAGAAGGGGTAGAGAAAATGCCTCGAGCCGAGGTCCGAGTACCAAGCGCTGCAGCGCTGAAGTATGAGCCCCGTGGACTAGCGATTGCTTCTCCACGAGGCTCATACCAGGCGCTACGGCGCTGAAGTATGTAACTGATGCCATACTCCCAGGAAAAGCTCGAACGACCTTCAACAAAAGGGTACCTGTACCCGAAACCGACACAGGTGGGTAGGTAGAGAATACCTAGGGGCGCGAGACAACTCTCTCTAAGGAACTCGGCAAAATAGCCCCGTAACTTCGGGAGAAGGGGTGCCCCCTCACAAAAGGGGGCCGCAGTGACCAGGCCCGGGCGACTGTTTACCAAAAACACAGGTCTCCGCAAAGTCGTAAGACCATGTATGGGGGCTGACGCCTGCCCAGTGCCGGAAGGTCAAGGAAGTTGGTGAACTGATGACAGGGAAGCCGGCGACCGAAGCCCCGGTGAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCCGCACGAAAGGCGTAACGATCTGGGCACTGTCTCGGAGAGAGGCTCGGTGAAATAGACATGTCTGTGAAGATGCGGACTACCTGCACCTGGACAGAAAGACCCTATGAAGCTTTACTGTTCCCTGGGATTGGCTTTGGGCCTTTCCTGCGCAGCTTAGGTGGAAGGCGAAGAAGGCCCCCTTCCGGGGGGGCCCGAGCCATCAGTGAGATACCACTCTGGAAGAGCTCGGATTCTAACCTTGTGTCAGACCCGCGGGCCAAGGGACAGTCTCAGGTAGACAGTTTCTATGGGGCGTAGGCCTCCCAAAAGGTAACGGAGGCGTGCAAAGGTTTCCTCGGGCCAGACGGACATTGGTCCTCGAGTGCAAAGGCAGAAGGGAGCTTGACTGCAAGACTCACCCGTCGAGCAGAGACGAAAGTCGGCCTTAGTGATCCGACGGTGCCGAGTGGAAGGGCCGTCGCTCAACGGATAAAAGTTACTCTAGGGATAACAGGCTGATCTTCCCCAAGAGTCCACATCGACGGGAAGGTTTGGCACCTCGATGTCGGCTCTTCGCCACCTGGAGCTGTAGGTGGTTCCAAGGGTTGGGCTGTTCGCCCATTAATGCGGTACGTGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCCATATCCGGTGTGGGCGTTAGAGCATTGAGAGGACCTTTCCCTAGTACGAGAGGACCGGGAAGGACGCACCTCTGGTGTACCAGTTATCGTGCCTACGGTAAACGCTGGTAGCCAAGTGCGGAGAGGATAACTGCTGAAAGCATATAAGTAGTAAGCCCACCCCAAGATGAGTGCTCTCTCCTCCGACTTCCCTAGAGCCTCCGGTATCACAGCCGAGACAGCGACGGGTTCTCCACCCATACGGGGATGGAGCGACAGAAGTATGGAAATAGGATAAGGTAGCGGCGAGACGAGCCGTTTAAATAGGTGTCAAGTGGAAGTGCCGTGATGTATGCAGCTGAGGCATCCTAACGAACGAACGATTTGAACCT
->DF157098.1/956789-956946 Plasmodium cynomolgi strain B DNA, chromosome 6. 
-TAACTGGCTTTTGGCTGCCAAGCGCTCCTAACGACGTAGTTTTTTGATCCTTCGATGTTGGCTCTTTCCATCATTGGGACGCAGAAGTCTGAAAGTATCGGATTGTTCACCTGCTAAAAGGGAACATGAGCTGGGTTTAGACCGTCGTGAGACAAGTT
->D90215.1/1270-1191 Nicotiana tabacum par gene, partial cds. 
-CTAACAAGGGGATAAAAAAATTCAAATGTGAAACAACTAATATTCAAATGTACGACGACCTTAAACAGCTCGGTGAAACT
->HG719501.1/1361-1 Eimeria maxima Weybridge genomic scaffold, Emw_scaff1073 
-AGACCTGAAGTCAGTCGAGGTTACTCGCTAAATTTAAGCATATTACTAAGCGGAGGAGGAGAAAATAACACTTCCCTCTAGGGAAGAGCTCAAAGGGAAAATCGTGAGTCCCTTTTGACCTCACGAATTGTAGCCTCTTGAGGCGTTGCCAGTGGGCGGGCAGGCTAAATATTGACGTGAGACCGATGGCGAACAAGTACTGTTAAGGAAATGTGAAAAGGACTTCGAAAAGAGAGTTAAAAGTGTCTGAAATTGCTGAATGGGAGGCGATTGAAACTTTAGTCTCTTCAGGGTGCGGGTGGATATTAGTTGTTCATTAGAAGGTAGCAAAATGCCTCGTCATCAAAATTAGTGAGGTGCATGAATGGATTAACGAGATTCCCACTGTCCCTATCTACTATCTAGCAAAACCACAGCAAAGGGAACGGGCTTGCCGGAATCAGCGGGGGAAGAAGACCCTGTTGAGCTTGACTCCAGTCCGACTTTGCTGAACGACTTGCGGGGTGTATCATAGGTGGGAGCTCCGACGACCGTGAAATACCACTACCCTCAATGTCACTTTACCTATTCCGTTAAGTTGAGATGCATGCTCGGCATCTGTTGAAGTCTTAAGGCACCCTTTTGGATCCGATAAATGCGGAAGACACAGTCAGGTGGGGAATTTGGCTGGGGCGGCACATCTGTGAAACAATAGTGTAGGTGTCCTAAGGCAAGCTCAATGAGAACAGAAGTCTCATGTTGACCAAAAGGGGAAAAGCTTGCTTGATTTTGATTTTCAGTGCGAATACAAACTGTGAAAGCATGGCCTATCTATCCTTTAGGTCTGAGAAACTTTCAGCTAGAGGTGTCAGAAAAGTTACCACAGGGCTTGTGACAGCTAAGCGTCCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGAGACGCAGAAGTCTCAAAGTGTCGGATTGTTCCCCCGCCAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATAAAATTGATACTGCGACAGTAATCCAACTTAGTACGAGAGGAACAGTTGGTTCAGATACTTGGTTAATACGGCTAGCTGAGAAGCTGGTGCCGCGAAGCTACCATCTGTTGGATTATGACTGAACGCCTCTAAGTCAGAACCCATGCTGGCTAAGCAGTGTTTCGCATTGCCCCATTTGTTACTTGCATATGGTTTTAGTGCCTTTTGAGCACAACATCTCATCAAAGCCCTTTGCGTCATGCGCTGGGCTATAATCACAATTTCCCACAATTGAGGCGCTACATCCATTGCAGACGACTTTGGCGCAACCAGGTATTGTAAGTGT
->CP003171.1/2269902-2269995 Oceanimonas sp. GK1, complete genome. 
-GCCCGGCGTCGGGTGTTCTCTTACTAGCGCACGGCTCAGCTAATGAGCCATTCCCCTGAGCCAGGTACACGGAATTTGTACCTGGCTTTTTTTG
->AACT01014037.1/2025-2536 Ciona savignyi cont_14037, whole genome shotgun sequence. 
-TTTGGCCGCCAAACCATTGCAAATACCCGAAAGATGGTGAACTATGCCTGAGGAGGTTGAAGCCAGAGGAAACTCTGGTGGAGGACCGTAGCGATTCTGACGTGCAAATCGATCGTCAAATTTGGGTATAGGGGCGAAAGACTAATCGAACCGTCTAGTAGCTGGTTCCCTTCGAAGTTTCCCTCAGGATAGCTGGCGCTCTGTCGCAGTTTTATCTGGTAAAGCGAATGATTAGAGGTCCTTGGGGGCCGAAACGCCCTCAACCTATTCTCAAACTTTAAATTGGTAAGAAGCCCGACTCGCTCGTTTGGAGCCGGGCATGGAATGCGAGTGCCAAGTGGGCCACTCTTGGTAAGCAGGACTGGCGATGCGGGATGAACCGAACGCCGGGTTAAGGCGCCCGACGCGACGCTCATCAGAGCCCCAAAAGGGTGTTTGGTTGATATAGACAGCAGGACGGTGGCCATGGAAGTCGGAAACCGCTAATGGAGTGTGTAACAACTCACCTGCCG
->CM000236.2/115408586-115408648 Rattus norvegicus chromosome 6, whole genome shotgun sequence. 
-GAATGAACACAGCTCTTTTAGAATTTTCCTAACAAGATTTCTGACTTTGGTCAGAAAACCCAA
->HG417174.1/11014915-11014980 Oryza rufipogon genomic scaffold, chr10 
-AGGCCGATGATGCTAATCATGCTCCTATGGTTTTTCTCTAAGAATGTTTCCCAAGAGCTGAGGACC
->JH835324.1/5005558-5005616 Erinaceus europaeus unplaced genomic scaffold scaffold00036, whole genome shotgun sequence 
-CTCTGTAAAACTTTTCCTATGCTGGGTAGTAAAAGACACCTTGTTACCTGAATGGACAG
->LMQS01000004.1/71000-70919 Methylophilus sp. Leaf416 contig_4, whole genome shotgun sequence. 
-CCTTCTGAGGAACGCTGCGAGAGTTTCATACTCCCAGGCTCAGAGTGATAGCTGCGAAGCTTCTCAACTGCGTTCACTTTTC
->CM001441.1/4265140-4264954 Desulfosporosinus youngiae DSM 17734 chromosome, whole genome shotgun sequence. 
-TGTATATTGGAAAATAAAGGTGCGCGTACTACATAGTACAGCTTAAAAGGGAAGCAGGTAAAATTCTGCACGGTCCCGCCACTGTAATGGGGAAATGTTTTATACTAATAGCCACTAGTCCTACCGGGAAGGCGTAAAGCATTGATGAACCAAAGTCAGAAGACCTGCCTTTGTTGAATGAACCAAT
->JEMT01029493.1/3587-3436 Rhizophagus irregularis DAOM 197198w jcf7180003195098, whole genome shotgun sequence. 
-ATCCTCTCTTGCCTATTGGCTAAGATCAAGTGTAGTATCTGTTATTTTCAGTATAATATCTGAAACTTTACACACAGGAGTTCCTTGGCTTGCCAATACTCCCTCATGAGTGTCCCTATTATTGCACTACCTCTAGGCGACGCTCACATTTT
->URS0000D68632_7029/1-72 Acyrthosiphon pisum (pea aphid) type-P1 twister ribozyme 
-UUUUUAAUCAUACCAGUAGUCUAAUUUUUAGAUUACUGACAGUCCUAAGUCUGUAAAAAAUGAGAAGGGAAA
->LXGJ01000084.1/21313-21202 Bacillus sp. WF146 contig084, whole genome shotgun sequence. 
-CGCCTCTTTAACCGCAATCCCGTGAGGTTGCGAAGAGGTTTACGCGCTTTCCATGCCCATGGAAGGATGGAAGGAGTATGCCTCTTTGTGCCCGCACAAAGAGGTTTTTTGT
->MAVT01008674.1/885-718 Diaporthe helianthi strain 7/96 Scaffold_5759.1, whole genome shotgun sequence. 
-TATTATTCAATGGGCAATCCGCAGCCAAATACTAAGTTTAGGTGTAGTCTTATTTAGTATGCAGTTCATCGACTAAACGGGTGTTGGTTTAATTTAAAATATACTGTAGTTAATAGTAAACCTTAAATTAGGCTTAAGATATAGTCAGTCCTAATATGAAAATATTGG
->MCOG01001818.1/1-185 Neocallimastix californiae strain G1 LY90scaffold_1818, whole genome shotgun sequence. 
-CATACAAGAGGACCCCGGTTCAGGCGTGGAAGTATGTCCTGTTCTCGTCCTTGAATGATAACTTCAAATATTAATGAGGATAAATCCTTTGCAGACGACTTAAATTTATAAACTAGGTATTGTAAGCAGTAGAGTAGCCTTGTTGCTACGATCTGCTGAGATTAAGCCTGTGTTTACTGATTTGT
->GG665194.1/8635-8474 Plasmodium falciparum IGH-CR14 genomic scaffold supercont1.236, whole genome shotgun sequence. 
-NNNNNNNNNNNNNATGTTAACAATAATTCATGATGTAAAAATGTTATCCAGTGATGTTTTTATTAGAGGCTAAAAAAAAATGTTTATGCAATGATAAAACGAGTTAAGCATTTTTTTTTAAGTTGCCGACTCACCTGACATTGGAACAACCAAAATTATTGT
->AYCK01025824.1/19605-19691 Poecilia formosa, whole genome shotgun sequence. 
-ATTTGCTGCACGCAATTTGCGTACAATATAGCATAAAGTTACAGTTAGTATTTATGCTATATTGTACGCAAATTGCGTGCAGTTACA
->JOKI01000015.1/68827-69021 Rhizobium sp. R1-200B2 contig_15, whole genome shotgun sequence. 
-AGTCAGCACAAGGAGGCAGACATGGGACGCGCTTACTCTCTGAATGTCCTGGCAGTTGGTGTAGCATTCGTATTCGTGGCTTCCATGCTCTTCATTTGAGCGCCACAGTTTCACAACTACCGGTCATATCTGGCATCCGTGACAATCATATAAAGATTTGAAAGCAGGAAACGCAGCTCCATCGGGCTGCGTTTC
->URS0000D698DF_12908/1-132 unclassified sequences RT-16 RNA 
-CTAGCAAACCGTTTTTACGAAGTCAGCTAGTTATACGCTTATTTACTATGGGAGTTTACTCTTATAAAATGCAATCACGACACCTAATGTGTGAAGTGGTGGTGAAAACAAGAAGTAAATAAGCTAACTTGG
->AE009948.1/273558-273684 Streptococcus agalactiae 2603V/R, complete genome. 
-GCTGTTTTTTTAGCGAGCTCAAGGTAGTGAAAGTTGGGTAGAATAGGATGAATATTGGCACTTTTTAGTGAGTAAAAGTACAATCAAAAATGAAGTAATAAATTAGGGTGGAACCGCGTCTTTGACG
->GL830965.1/1574-57 Succinatimonas hippei YIT 12066 genomic scaffold Scfld66, whole genome shotgun sequence. 
-ATAATGAAGAGTTTGATCATGGCTCAGATTGAACGCTGGCGGCAGGCTTAATACATGCAAGTCGAACGGTAACATAGCGAAAGCTTGCTTTTGCTGATGACGAGTGGCGGACGGGTGAGTAGTATCTGGGAAACTGCCCTGAAGAGGGGGACAACAGCTGGAAACGGCTGCTAATACCGCATAAACCCTGCGGGGGAAAGGAAGGCAACTTCCGCTTCAGGATGTGCCCAGAAGGGATTAGCTAGTAGGTGAGGTAAAGGCTCACCTAGGCGACGATCTCTAGCCGGTCTGAGAGGATGACCGGCCACATCGGGACTGAGACACGGCCCGGACTCCTACGGGAGGCAGCAGTAGGGAATATTGCACAATGGGGGGAACCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGCGGGGAGGAAATTAAGTTAGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATAACTGGGCGTAAAGGGCACGCAGGCGGGCTGATAAGTAAGGTGTGAAATACCGGGGCTCAACCTCGGGGCTGCATTTTAAACTGTCAGTCTAGAGTATTGCAGAGGGAGACGGAATTCCGGGTGTAGCGGTGAAATGCGTAGATATCCGGAAGAACACCGGAGGCGAAGGCGGTCTTCTGGGCAAATACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGATTAGGAGATTGAGCAGAAGCTTGGTTTTCGGAGCAAACGCGCTAAATCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGACCTTGACATCTGAGGAATGCCTGAGAGATTTAGGCAGTGCCTTCGGGAGCCTCAAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCCTTTGTTGCCAGCGCGTGATGGCGGGAACTCAAAGGAGACTGCCGGTGACAAACCGGAGGAAGGCAGGGATGACGTCAAGTCATCATGGCCCTTACGGTCAGGGCTACACACGTGCTACAATGGGGCGTACAGAGGGAAGCGAGGCCGTGAGGCGGAGCGGAGCCCACAAAGCGTCCCACAGTTCGGATTGGAGTCTGCAACTCGACTCCATGAAGGCGGAATCGCTAGTAATCGCAAATCAGAATGTTGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGATTGCACCAGAAGTGGCTTGCCTAACCCGTAAGGGAGGGCGGTTACCACGGTGTGGTTTATGACTGGGGTGAAGTCGTAACAAGGTAACCCTAGGGGAACCTGGGGTTGGATCACCTCCTTA
->JH835900.1/331024-330895 Erinaceus europaeus unplaced genomic scaffold scaffold00612, whole genome shotgun sequence 
-CTCCATGAATCTTTGAGTCCTGTTGACTGTGGCAAATATCCTTCCTAGACACAGAAGAGCATATTCTTGTATACTGACATAGCTGCCATCAGTTAATTGATTTCAGTTCTAACTTTCACAAGTAACATTT
->AANH01013162.1/16565-16141 Gasterosteus aculeatus cont1.013161, whole genome shotgun sequence. 
-CCTCTTCAGACTCTACCTCGACTAAAGACTAACAAATTGTAGCACTTAAATTGTACTTGTAACGTGACTCATCTATAGCAAATTGTAAATTGGCTTATTTGAGGAAATTGCACTTTCTTGTTTCTTGTTCTCCTTTGTACCCTATGGTTGAATGCACTTATTGTACGTCGCTTTGGATAAAAGCGTCCGCTAAATGACATGTAATGTAATGATGGTGTCAAGCGCCTGGCTCAGACGGTGCGGTACACCTGTCAAACGGTAACGCAGGTGTCCAAAGGCGAGCTCAGGGAGGACAGAAATCTCAGAAGGGCAAAAGCTTGCTTGATCTTGATTTTCAGTATGAATACAGACCGTGAAAGCGCAGCCTCACGATCCTTCTGGCGTTTTGGGTTTTAAGCAGGAGGTGTCAGAAAAGTTACCACAGG
->ABLF02002078.1/866-1 Acyrthosiphon pisum strain LSR1 Contig2110, whole genome shotgun sequence. 
-CCGGCAAGCCTCGACGAGTAGGATGGCGCGGCGGTGTGCGTCGAAGGGCAGGTCGCGAGACCGCCTGGAGCCGCCGTCGGTGCAGATCATAGGTGGTAGTAGCAAATACTCGAGAGGGGCCCTCGGGGGCTGCCGTGGAGAAGGGTTTCTTGTGAACAGCCGTTGTCCAAGAGTCAGTCGATCCTAAGCCCGGGGAGAGATCCTCGTACCACGGGCGAAGGCGTTTTCGAATCGCCCTTGGGGCGAGAGGGAATCCGGTTCGTATTCCGGAACCCGACGCGGAACCGCTCCCTAGTGTTCGGGGCTCTTTTGTCTCGTCTGGGTAACCAGAATGAACTCGAAGAAGCCGCCGGGGGATCTGGGTAGAGTTCTCTTTTCTCTGTGAGCGTTGTACGTCCCTGGAATCCTCTAGCCGGGCGATAGGGACGCGAGCGCGAAGAGCACCGCTCGTTGCGGCGGTGTCCGTGATCCCCACGCGGACCTTGAAAATTCGAGAGAGGGCCACGCGGAGTCTTCGCGTCGGTTCGTACCGATATCCGCAGCAGGTCTCCGAGGTGAGCAGCCTCTAGCCGCATAGAATAATGTAGGTAAGGGAAGTCGGCAAAACCGATCCGTAACTTCGGGATAAGGATTGGCTCTGAGGAGCGTGGCTGCCGGGTTCGGGTCGTCGTAGAAGCGTAGGCGTTTTTGGCGACACCCCGGCCGTCGCCCGTGCGCCCGGTCTTCGGAACGGGAGCCTCGAGGCGGCCGCGGGCCCGTCGCCGTCCGCCGACCGTGGAACCACCGAGCTTCGGTCGCTGGCCGCGTCGCGGCCGGCCGACCGCACATTGGTGTCGGTTCGCCGTCACCGGGCGGTCCGGCCGCCG
->AYUG01116302.1/14860-14978 Fukomys damarensis contig116302, whole genome shotgun sequence. 
-CTCTAGCAAAGTAAGTTTCTTTACTTGTGGATGCACAGTGGCTTCACACAGCAACTCCTTTAGTTGTGTACACAGACTATTGTTTGTATGGGTCGCCCTAAGGGACCTTAAAGAAGTTT
->KK502427.1/433055-433166 Glossina austeni unplaced genomic scaffold Scaffold27, whole genome shotgun sequence. 
-GGCAAGGGCACTCTGTGACACTTGTTATTAATTTTAAAGTGTAAACAATTTGTTACCTTGCCAGAATAAATCAATTACGTAAAACCTTAACCAATGTCGTATTATAGATTGA
->CM000999.2/44792791-44793384 Mus musculus chromosome 6, GRC primary reference assembly. 
-TTCTATAATTCTTTCTATACGAGTACACATTTTCATCTTGCAAGAAACAACCAAAACTAATTTAAGAAATATTATCAAACATGTTAATAAAAATTGAGTGTTAATAAAAATAACTAAAATACAAAATTATTGGATACTTAGATGGTGAACTATGCCTGGGCAGGGCGAAGCCAGAGGAAACTCTGGTGGAGGTCCGTAGCGGTCCTGACGTGCAAATCGGTCGTCCGACCTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCCTCTGAAGTTTCCCTCAGGATAGCTGGCGCTCTCGCTCTTTTCCCGACGTACGCAGTTTTATCCGGTAAAGCGAATGATTAGAGGTCTTGGGGCCGAAACGATCTCAACCTATTCTCAAACTTTAAATGGGTAAGAAGCCCGGCTCGCTGGCGTGGAGCCGGGCGTGGAATGTGAGTGCCTAGTGGGCCACTTTTGGTAAGCAGAACTGGCGCTGCGGGATGAACCGAACGAATTATATTTTATATAATGTATATGAAATATCAAATATTAAGGAATGACATTTGATTTTGTTGTGTAATTGTATCATGCATCTTTT
->MRAE01000082.1/2029-1 Clostridium sp. IEH 97212 scaffold_81, whole genome shotgun sequence. 
-CGCAAATAGGCAGAGATCCAGGGATTTCCGAATGAGGGAACTCACATGGGTAACCCCATGTATCATGCACTGAATACATAGGTGTATGAGGGTAAACCCGGGGAACTGAAACATCTAAGTACCCGGAGGAAGAGAAAGAAAAATCGATTTCCTAAGTAGCGGCGAGCGAACGGGAAAGAGCCCAAACCAGAAACTTGTTTCTGGGGTTGAGGATAGATCATAAAAGAAGAGGTATCTTAATCGAAAAGGGCTGGAACGCCCTACCATAGAAGGTAATAGTCCTGTAGATGAAAAGAGAAAACTTCGAGATCTAATCCAGAGTACCACGAGACACGTGAAACCTTGTGGGAAGCAGGGAGGACCACCTCCCAAGGCTAAATACTACCTAGTGACCGATAGTGAAGCAGTACCGTGAGGGAAAGGTGAAAAGAACCCCGGGAGGGGAGTGAAATAGAACCTGAAACCGTGTGCCTACAACCGATCGGAGCACGTTAAAGTGTGACGATGTGCTTTTTGTAGAACGAGCCAGCGAGTTACGCTATGTAGCAAGGTTAAGTACTTAAGGTATGGAGCCGAAGGGAAACCGAGTCTGAAAAGGGCGAAAAGTTGCATGGTGTAGACCCGAAACCGGGTGACCTATCCATGGCCAGGTTGAAGCGAGAGTAAAATCTCGTGGAGGACCGAACCACGTTGGTGTTGAAAAACCATGGGATGAGCTGTGGATAGCGGAGAAATTCCAATCGAACTCGGAGATAGCTGGTTCTCCCCGAAATAGCTTTAGGGCTAGCGTCGTGTAATTGAGTAATGGAGGTAGAGCACTGAATGGGCTAGGGGCTATAGTAGTTACCGAACCCTATCAAACTCCGAATGCCATATACTTGTATCACGGCAGTCAGACTGCGAATGATAAGATCCGTAGTCAAAAGGGAAACAGCCCAGACCATCAGCTAAGGTCCCAAAGTGTAAGTTAAGTGGAAAAGGATGTGGGATTTCTAAGACAACTAGGATGTTGGCTTAGAAGCAGCCACTCATTTAAAGAGTGCGTAATAGCTCACTAGTCAAGAGATCCTGCGCCGAAGATGTCCGGGGCTCAAACTTACCACCGAAGCTATGGGGTGTACACTATGTGTACGCGGTAGGGGAGCTTTCTGTATGGGTTGAAGTCGTACCGTAAGGAGTGGTGGACTGTACAGAAGTGAGAATGCTGGCATAAGTAGCGAGAAATAAGTGAGAATCTTATTGGCCGAAAACCTAAGGTTTCCTGGGGAAGGCTCGTCCGCCCAGGGTTAGTCGGGACCTAAGCCGAGGCCGAAAGGCGTAGGTGATGGACAATCGGTTGATATTCCGATACCACCTATTTACGTTTGAGAGATGGGGTGACGCAGTAGGATAAGATGTGCGCACTATTGGATGTGCGTCTAAGCATTTAGGCATGCTTGATAGGCAAATCCGTCAGGCTAAGCTGAGATGTTATGGGGAGCCAAATGTGGCGAAGTATCTGATTCCACACTGCCAAGAAAAGCCTCTATCGAGTAAATAGGTGCCCGTACCGCAAACCGACACAGGTAGGTGAGGAGAGAATCCTAAGGCCATCGGAAGAATTGCTGTTAAGGAACTCGGCAAATTGACCCCGTAACTTCGGGAGAAGGGGTGCCTACGAAAGTAGGCCGCAGAGAATAGGCCCAAGCAACTGTTTAGCAAAAACACAGGTCTCTGCTAAAGCGAAAGCTGATGTATAGGGGCTGACGCCTGCCCGGTGCTGGAAGGTTAAGGGGAACACTTAGCGAAGCGAAGGTGTGAACTTAAGCCCCAGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCCGCACGAATGGCGTAATGATTTGGGCACTGTCTCAACAGCAAATCCGGCGAAATTGTAGTGCAAGTGAAGATGCTTGCTACCCGCGATTGGACGGAAAGACCCTGTAGAGCTTTACTGTAGCTTAGCATTGAATCTCGGTATTGTCTGTAC
->KV454051.1/1465-1655 Pachysolen tannophilus NRRL Y-2460 unplaced genomic scaffold PACTA_scaffold_41, whole genome shotgun sequence. 
-ACCTGTTTGCCAACACTCTGGTGCCGAATCAAAAAGATTTTATATATTTCTTTTTCGATATATTCGGTTCCTATTTTGGAGCAAACTAGATTGATTTAGCCAATTACTCACCATAATATTCGTGATTTATTTAAAAAAAATTTTTTTTTTAGATTAAGATGAATATGATGGTCCATTTCAGTGGCGTAAAT
->ACSJ01000007.1/1211646-1211440 Clostridium botulinum D str. 1873 CLG.Contig181, whole genome shotgun sequence. 
-CAATAAAATATAAAAATAGGTGTCAGTTATAATAAAAATTTTAATTATGAACTGGTGAAAAGGGAAGATGGGTGTAAATCCTACACGGTCCCGCCGCTGTAAATGAGGAGCTTTTTTATGTGTAACCACTGGTGTTATTTATACTGGGAAGGATAGAAAAGTGATGATACTTAAGTCAGAAGACCTGCCTATTTTTGTACACCGATG
->ALAR01116409.1/116042-115647 Tupaia chinensis contig116409, whole genome shotgun sequence. 
-AAAAGAGTAATGAAATTTCAAAACAAAATATAGAAGCTACATGGTCACTTTTACCAGCTTATGGTGAAATGAAAGGGAAAAAGGATGATTTCAAGAAAGAATTTATAATGAAAAGGGAATTAGGTTCAGTCCTCTGACTCCAGAGCGACCAAAATGGGCACTGCGGCGGGTCCAGTGCAGTGATGCAATCATCCTGGAGAAGCTGCTTGAGTCCCTGGGGAGAGTTCTCTTTTTTGTGGACATAGTGGGGTCACCCCGGGGAAGGGGTCCATGCCTTTAAAATGCTGTGGTTCCCGTAAGTTCTTACTGGCCCTTAAAAAATACAAGGGAGAAGGTATAAATCTACCACCAGGCCACACACATATCCGCAGCAGGTGTCCAAGATAAACAGCCTCT
->KZ248601.1/687242-687373 Danaus plexippus plexippus isolate F-2 unplaced genomic scaffold DPSCF300057, whole genome shotgun sequence. 
-GCTGGCTTTTATCGAAGCTCTCATATTTTTCCTATAAATATGGAAGTCAAACAAAGCCTATAGTGAAGATCTCTATCGGTCGCGGTCTAGGTAAATCATACCTCTAACGTATCACCAAGGAGGTCAACAGTT
->LRGB01001036.1/60242-60133 Daphnia magna strain Xinb3 scaffold01036, whole genome shotgun sequence. 
-TCCTATTGTACCGCAGCTGCTGAACACTGCCCAAGATTGGCGTGAACAATTCTAACGGAAGGCAACTCTTGTGCGTGTGACAGCGGCTATGGTATTCAGGAAATATCTTC
->AACT01048137.1/180-1 Ciona savignyi cont_48137, whole genome shotgun sequence. 
-TACCTGGTTGATCCTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCCATGCAAGTCTAAGTACGAGCTCTCGTACAGTGAAACTGCGAATGGCTCATTAAATCAGTTATGGTTCATTTGATCGTACAGTTTACTTGGATAACTGTGGTAATTCTAGAGCTAATACATGCGAGAAGCG
->ACJG01011252.1/789-1 Daphnia pulex DAPPUscaffold_852_Cont11252, whole genome shotgun sequence. 
-CGACCTGAGAGCAGGCAAGGTGACCCGCCAAATTTAAGCATATTAATAAGCGGAGGAAAAGAAAACAACCGTGATGCCCTTAGTAATGGCGAATGAAACGGGCAGAGCCCAGCACCGAACCGCCGGCCATCCAGGTCGCGCGGAATGTGGTGTTTGGGGGAGCCTCCTCGCGACGCGTCGGCCGGTCCAAGTCCACCTTGACTGGGGCCACGGCCCACAGAGGGTGATAGGCCCGTAAGACGGCCGATGCGTTGTGCCGGCTTTCCCCTAGAGTCGAGTTGCTTGGGAGTGCAGCTCAAAGTGCGTGGTAAACTCCACGTAAGGCTAAATATGACCCCGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGTTGAAAAGAACTTTGAAGAGAGAGTTCAAGAGTACGTGAAACTGTGTAGTGGTAAACGGAGGGGCTCTCGAAGTGGGTCTCGGAGATTCAGGTTGGCGGCCGGGCGGCCGGGGCGAGCGCGATCCGCGAGGACGCCTCGTTTCGGTCGGCTCGGTCGGCGGCTGCACTTCTCCGGGACTTGACGCGACGAACCGCTGTCTGCGGAACGAGGACCGGGGTGAAGTTCGTCGTCCTCACGGGCGGCGAGCCCCCGGCTCCTGTCTTCGCGGGCGGCGGGTATCTGAGTCGACTTGTATAGCAAGCCCTCTCGCTAGGGCGGTCGGCATCTCTGTCGCGAGTAGGTCGGCGGCCCCTCCGACCCGTCTTGAAACACGGACCAAGGAGTCTAACATGTGTGCGAGCCATTGGGCGGACTAA
->CM000780.4/228503464-228503665 Zea mays cultivar B73 chromosome 4, whole genome shotgun sequence. 
-ATACCTTTGTCGACCTGTTGACTAAGATAAAGTGTAATGTTTGTTCTTACTAGTTTGATATCTGATATGTGGATCGTATGTTCACTTTATTAAATTTTATTTTTTTATGGGTATCAAATATGATTGTGTGTCTATCGGGGTGATAATTAGGGGTACCCAGATTATCCCTCCGAAAAACGCACTCAGGAGAAGTAAACACATA
->KN819335.1/889548-890013 Paxillus involutus ATCC 200175 unplaced genomic scaffold PAXINscaffold_13, whole genome shotgun sequence. 
-ACAGTCCGAAAGTTACGATGCTCACCACACACTGCAAGACATGTCAAAGATCGTGAGTAGACTAAGGTCTGAGTATTCTATTCTCAATCGACTCTTCCTGGGTTCATTCCTAACGGACTGCGCGATGTCCAGAAATGCAATAGCCAGTTTCCCCACGGTTACTGAGTTAGTAGGGACGGACAACTTTGAAAATGCGTCGCAGAGATCGGGTGAGCACCTTTCCTCACTTGATTCCCTGTTGCGGTAGACGTGCCCATCATTGCGCGCAACGTGATCGCGTTCTTCGTTCGCATTCATGTCCGCGTATTAGGACATCGGGTCCGACGAATCAACCGCGGCTCGTACTAGCAGTCATCAATACTACACCCCATCACGCGACTGCAACCAAGTCAACTCGATTATTTTTTCTCGTACGAGATTTTTCAATCATCTTTTGAAACTCGATTCAGACTACTCTTAGGACTGT
->AASG02001279.1/18109-18241 Ricinus communis ctg_1100012357581, whole genome shotgun sequence. 
-TGTCATGCTTTTCCACAGCTTTCTTGAACTTCTTCTTCTTCTTCTTCTTCTTCTTAGATTTCTTTCTCATTGCCTATATCTTTCTTGATGTGGCACAGAATAAGTTCAAGAAAGCTGTGGGAGAACATGGCAA
->JH835358.1/2695321-2695604 Erinaceus europaeus unplaced genomic scaffold scaffold00070, whole genome shotgun sequence 
-GGATCTTAGTGTGATCTGGCTGTGACATCTGTCACCCCATGGATAACATGGGTTGATTTGGCTGGTCTGGCTCGCTAGACGAGTGTCCTCTTCCTCCCTCACTGCTCCTTGTACGTTCAGTCAAAGAGGACAACCTTCCTGAGTCTTGGGTCAAAGGGTATACGAGTAGCTACACTCCCCTGCTAGAACCTCCAAACAAGCTCTCAGTAAGTTTTGCTCTTTATTTTTTTCCCTTTTGTTGCTTATCTTTGTTACTATTATTGTTGTTACTGCTGTCGTTGTTG
->CM001941.2/563785-564154 Chlorocebus sabaeus isolate 1994-021 chromosome 1, whole genome shotgun sequence. 
-GCCGGGCATGGAGATGTGCACCTGTAGTCCCAGCTACTTGGGAGGCTGAGGCGGGCGGATCACTTGAGCCCAGGAGGTCAAGGCTGTAGTGAGGCGTAATCACACTACTGCACTCTAGCCTGAGCGACTGAGACCCTGTCTTGGAAAAAAGAAAAAAAAGGATAAGATGGGACATTTTACATTATTTTTTTTTTTTTTTTGAGACGGAGTCTCGCTTTGTCANNNNNNNNNNAATGTAAAATGTCCCATCTTATCCTTTTTTTTCTTTTTTCCAAGACAGGGTCTCAGTCGCTCAGGCTAGAGTGCAGTAGTGTGATTACGCCTCACTACAGCCTTGCCCTCCGGGGCTAAAGTGACCCGCCCGCCTCAG
->GL018725.1/468056-468262 Oryctolagus cuniculus unplaced genomic scaffold chrUn0027, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGCAGAATCTCTGTTTCAGAGTCCCCCAGCCATCACGGCGCCTGCGGTCCCTTTTTTTTTTTTTTTTTTGACAGGCAGAGTGGACAGTGAGAGAGACAGAGAGAAAGGTCTTCCTTTGCCGTTGGTTCACCCTCCAATGGCCGCCGCGCTGATCCGATGGCAGGAGCCAGGTACTT
->MRDE01000088.1/1-303 Tersicoccus phoenicis strain 1p05MA scaffold90_cov825_read201, whole genome shotgun sequence. 
-GTGACGGCACTTCGCGTGCTCGAGCGGGTGTGGGCCGCAGAGACCAGGGGGAAGCGACTGTTTACTAAAAACACAGGTCCGTGCGAAGTCGCAAGACGATGTATACGGACTGACTCCTGCCCGGTGCTGGAAGGTTAAGAGGACCGGTTAGCGCCCCTCGCGGGTGCGAAGCTGGGAATTTAAGCCCCAGTAAACGGCGGTGGTAACTATAACCATCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGAGTAACGACTTCCCCGCTGTCTCAACCATAAACTCGG
->CM000380.2/94669007-94668751 Equus caballus chromosome 4, whole genome shotgun sequence. 
-TCGAAGTTTCCCTCAGGATAGCTGGCACTCTCACATGTGAACCCAGGCAGTTTTATCCAGTACAACGAATGATTAGAGGTCTTGGCGCCAAAACGATCTCAATCTATTCCCAATGGGTAAGAAGCCCACTGGCATGGAGCTGGGCATGGAACACAAGGGCCTAGTGGGCCACTTTTGGTAAGTAGAAGTGGCACTGCACGATGAACTGAACACCAGGTTAGGCATTGATAACTTGATAACTATAGTTTTATAATAGA
->CM000941.1/92177923-92177799 Anolis carolinensis chromosome 5, whole genome shotgun sequence. 
-ATTTTCCTGACTACTGAAATGCCCTCAATGTACCACATCCCATTTGATCTTGGAAACAATGCAGGATTAGTCCTGATTAGTACTTAGATGGGAGACCACCAACGAATACTAGGAACTGTAAAAAC
->LBBL01000003.1/104201-103670 Ceratocystis platani strain CFO contig_00003 mitochondrial, whole genome shotgun sequence. 
-GAGTTTGGTGATGGCTCTGATTGAACGCTGTCTAAGTGCTTGACACATGCTAATCGAACGATTAATACAGTTAAAAAAAAACTAAATTAATAGTGGTGTACAGGTGAGTATAAGATATTTTTGCCGACCTTAAAGTAAGAGGACAATAAGATCTCTTATAAACAAAAGGGTTGTACCGCTTTAAGAGGATGAGAAATATCATAGAGAGAGGTAGTTGTTAAAGTAATGATTTAGCTAGCCGCAGATTCTCTTAGTCGAAACTGAAAGGTTGATCGACCACATTGGGCCTGAAAAAATCCCAATGCAAAAACGTACAGCAGTGAGGAATATTGGTCAATGGTCTAACGATCGAACTGGCAACTTAGGGAAATGGATGATATAAAATAATTATATAATAAAGTTTATATAATAATTATTAATATGCAATAGTTGTGAAGTTTTGTCTACATATTGATAATGACAATATGTATAAACAGTCTCGACTAATTACGTGCCAGCAGTCGCGGTAATACGTAAGAGACAAGCGTTATTC
->CM000762.3/2300100-2300430 Sorghum bicolor cultivar BTx623 chromosome 3, whole genome shotgun sequence. 
-CTCCCAAGAAACCTCAGGGTCCCAATGGGCCTTCATCATGAATCGAAAAGGGCCCATGGGAGAGGGAAACAGCCCGGATCACCAGCTAAGGCCCCTAAATGACCGCTCAGTGATAAAGGAGGTGGGGGTGCAAAGACAGCCAGGAGGTTTGCCTAGAAGCAGCCACCCTTTAAAGAGTGCGTAATAGCTCACTGATCGAGCGCCCTTGCGCTGAAGATGAACGGGGCTAAGCGATCTGCCGAAGCTGTGGGATGTCAAAATGCATCGGTAGGGGAGCGTTCCGCCTTAGAGGGAAGCAAACGCGAAAGCGGGGGTCGACAAAGCGGAAGCG
->JSZA01002193.1/1101-1450 Candidatus Thiomargarita nelsonii contig_2193, whole genome shotgun sequence. 
-AGATCATTATGAGAATCCCCGTAATGTGGGCACATTGGATAAAGAGGATCCGTCAGTGGGGACGGGCATGGTTGGCGCACCAGCTTGTGGTAAATAACATTGCCACGTAATTCTGCTATATGCAAGAAACTCTCGTTAGGTTGTAGGTACTAATGTTTAACCAAACACGCAAAATAACAAAATAGTGTGCCCAAATACTTGAGTAAAATACTCAAGTATTAACCAGATGGGTTAGTAAAAACCCTACAAATAGAGACAATTTGCAAGGAAGTCGTGGTTGACCCTTCAGAGACTATACGCAGAACATCAATGAGATGAAGACATAGTCCGAACTACACGGAGACGTGTAG
->MKUE01000019.1/22195-22263 Thiobacillus sp. 65-1059 scnpilot_expt_750_p_scaffold_1345, whole genome shotgun sequence. 
-GAACTGAAGAGTTTGATCCTGGCTCAGATTGAACGCTGGCGGAATGCTTTACACATGCAAGTCGAACGG
->URS0000D699AF_12908/1-539 unclassified sequences ROOL RNA 
-AATCAACGCGAAGGATTGTTTCAACCATGTGTATTCACAATTCCATGTGGTCATGGACGTGTTCAAGGAGTTCCACTATGGAGGATACCCCATAGGTAGGCTTTACCAGATAGGTAGAAGAGATGGAAAATCTCAACCGAGCAGGCACGGTGCTGTGATGAAACGCAAGAAAATGGTATTGCTAACTGGTCGCTATCGCAATAGATATGAGGTACGCACCTCATTGAACCAAGTAGAGGATAGTGTGGCAGCTATGTCAATCGCTTGGAGTGCCATAAGATAGTTGTCCAATTGATGCTGGTAATCAGATATAAGACCAGACGCGAGTACGAGTAGCCCAAAGTTGGAATATATTAGAAGATTAATATGCTGAATGGTGGGTGAAAGTTGTTGGTAGCCAATCCAGCCATAGATTGACGTAAGTTGGGATGGAAAGATATGGGGTCGCTCCCTGTGTCTCAGCTCCATTTCCTATGTGACCGAATTACCACTACGTTTTATGAAGGTACGATGAAGATCGGAGACAATCTTTCGCGTTG
->CM001752.1/52724704-52726253 Gossypium raimondii chromosome 13, whole genome shotgun sequence. 
-CAAAAGAAGAGTTTGATCCTGGCTCAGAAGGAACGCTAGCTATATGCTTAACACATGCAAGTCGAACGTTGTTTTCGGGGAGCTAGGAAGAAGGAAAAGAGGCTCCTAGCTAAAGGTAGCTTGTCTCGCCCAGGGGGTGAGAACTGTTGAGAACAAAGTGGCGAACGGGTGCGTAACGCGTGGGAATCTGCCGAACAGTTCGGGCCAAATCCTGAAGAAAGCTAAAAAGCGCTGTTTGATGAGCCTGCGTAGTATTAGGTAGTTGGTCAGGTAAAGGCTGACCAAGCCAATGATGCTTAGCTGGTCTTTTCGGATGATCAGCCACACTGGGACTGAGACACGGCCCGGACTCCCACGGGGGGCAGCAGTGGGGAATCTTGGACAATGGGCGAAAGCCCGATCCAGCAATATCGCGTGAGTGAAGAAGGGCAAGGCCCGCTCGTAAAGCTCTTTCGTCGAGTGCGCGANNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNTGAGACATGCCGCTTAGAGTGAAAAGTCTTTGCAACCGAAGTGAGCCGACGGAGCCGAAGTGACGGGCCAAGCTCTTCTAATTGAGCGCCTGCACGTAAGCTGTGCTGTCAGTAAGAAGGGGAGCCCGCCGCCTTTCGAATTTGAAAGCACTTTTCTAGTGTGCGCTGTTTTTGATTGCAGCTAGCGAGCGAAGAAAACGGATGGCGCGAACGCGGCTTTTCTTTCGCCTTGCTTGTTGTACTAATAACATAGAAAGGGCTTTCTTTTCTCGCTTGTTTAGTAAAGTCAAGTTTTTGGCCTTATCTTGCAGGTGACGACGACGTCGAGTTGGCGGCGGAGAAAGACTCGGCATTCAGGCGAGCCGCCCGGTGGTGTGGTACGTAGTGGGTTTAGTACGCCCCGCCAAAACAACTCCGAAACAAACGAAAAGGTGCATGCCCCCCTTCCGAGGGACTGCCAGTGATATACCTCACGAAGGTGGGGATGACGTCAAGTCCGCATGGCCCTTATGGGCTGGGCCACACACGTGCTACAATGGCAATTACAATGGGAAGCAAGGCTGTAAGGCGGAGCGAATCCGGAAAGATTGCCTCAGTTCGGATTGTTCTCTGCAACTCGGGAACATGAAGTTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATATGTACCCGGGCCCTGTACACACCGCCCGTCACACCCTGGGAATTGGTTTCGCCCGAAGCATCGGACCAATGATCACCCATGACTTCTGTGTACCACTAGTGCCACAAAGGCTTTTGGTGGTCTTATTGGCGCATACCACGGTGGGGTCTTCGACTGGGGTGAAGTCGTAACAAGGTAGCCGTAGGGGAACCTGTGGCTGGATTGAATCCTTC
->MCGO01000050.1/321272-322593 Rhizoclosmatium globosum strain JEL800 BCR33scaffold_50, whole genome shotgun sequence. 
-TACCTGGTTGATCCTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCCATGCATGTCTAAGTATAAACTCGTTTGTACTGTGTGAAACTGCGAATGGCTCATTAAATCAGTTATAGTTTATTTGATATAACCTTACTACTTGGATATCCGTGGTAATTCTAGAGCTAATACATGCAATTAAAATCCTGACTTCTGGAAGGGATGTATTTATTAGATAAAAAACCAACCCGGCAACGGTTCTTTGGTGATTCATAGTAACTTTTCGAATCGCATGACTTTACGTCGGCGATGGTTCATTCAAATTTCTGCCCTATCAAGTTTCGATGGTAGGATAGAGGCCTACCATGCTTTTTACGGGTAACGGCGAATTAGGGTTCGATTCCGGAGAGGGAGCCTGAGAAACGGCTACCACATCTAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCTGATTCAGGGAGGTAGTGACAATAAATAACAATCCAGGGCTTTTGTCTTGGAATTGGAATGAGAACAATTTAAATCTCTTAACGAGGAACAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAATAGCTCGTAGTTGAATCTTGGGCCTGGTTTGGCGGTCGCGCTTTAGGGCGTGTACTGTCGGCCGGGTCTTTTACTTGCGGGGAACGTGCGTGCCTCTCGGGGTGTGTACGGGAACCGTGGCTATTACTTTGAAAAAATTAGAGTGTTTAAAGCAGGCGTAAGCTTGTATACATTAGCATGGAATAATAGAATAGGACTTTGGTTTTATTTTGTTGGTTTCTAGGGCCGAAGTAATGATTAATAGGGATAGTTGGGGGCATTAGTATTTAATAGTCAGAGGTGAAATTCTTGGATTTATGAAAGACTAACTTCTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTCAGGGGATCGAAGATGATCAGATACCGTCGTAGTCCTGACCGTAAACTATGCCGACTAGGGATCGGGCGTTGTATTTCATGACACGCTCGGCACCTTATGAGAAATCAAAGTCTTTGGGTACCGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTCACCAGGTCCAGACATAGTAAGGATTGACAGATTGAGAGCTCTTTCTTGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGATAACGAA
->AP009608.1/824477-824563 Mycoplasma fermentans PG18 DNA, nearly complete genome. 
-CGGTAGTTGCTCGAGAGGCTGAAGAGGTTGGTCTCGAAAACCAATAATGGTGAAAGTCATTCAAGGGTTCAAATCCCTTACTACCGG
->CP001719.1/360474-360390 Methanobrevibacter ruminantium M1, complete genome. 
-GCCATGATGACTGAGTCAGGCTTAAGGTATCCGCCTTGAGAGCGGACGTATGAAAGTACCAGAGGTTCAAATCCTCTTCATGGCG
->LFJF01047615.1/1-2366 Macrostomum lignano unitig_47682, whole genome shotgun sequence. 
-ACTTTTTGAGCCCCGTAATTGGAATGAGTACACTTTAAATCCGTTAACAAGTATCTATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAATGTTGCTGCAGTTAAAAAGCTCGTAGTTGGATCTGAGGACTCGAATTGGTGGTGCACCCATACGGTGTTACTGCCCGATTCGGCCTACCTAGTCGGTGCTCGCTCTTGGTGTTCTTAATTGAATGCCCTGAGTGCCCGGCAAGTTTACTTTGAAAAAATTAGAGTGCTCAAAGCAGGCCATTAGCCGGAATACTTCAGCATGGAATAATGGAATAGGACTTCGGTTCTATTTTGTTGGTTTTCGGAACCCGAGGTAATGATTAAGAGAGACAGACGGGGGCATTCGTACTGCGGTGTTAGAGGTGAAATTCTTGGATCGCCGCAAGACGAAACAACTGCGAAAGCATTTGCCAAGAATGTTTTCATTAATCAAGAAACGAAAGTCAGAGGTTCGAAGACGATCAGATACCGTCCTAGTTCTGACCATAAACGATGCCAACTGGCGATCCGAGATCGTTTGCTTATTTGACCTCTCGGGCAGCCTCCGGGAAACCAAAGTTTTTAGGTTCCGGGGGAAGTATGGTTGCAAAGCTGGAACTGGCAAAAATTGAACGGCAAGTGCACAACCAAGTGGTGGAAGGCCCTTGCGGCTTTAAATTTGACTCAAACCCGGAGTAAGATATTTACTTCACTTGTGTGTCGTTAACTGTTCTCCATAACGAATCAGGACACTCCAGGATCAGCTCCCCTATGAGTGTTAGCAAAGTTCAAATTCAAGAATTATTTGATTGTCCATGAGACAGTTAGAATTGAAGAGCAATTACAAAATTTGTATTATGCTATGATATTCCTAATGGTAGGTTTTAACCCTTCTAAATTGCGGCAGTGGCCTGACTTTGAGTGTAACAGGGTAATCTGGTTAGAAAATGTTTAAAGTCACTGAGACCCAGTTGGCCTTAAGTCTAAATTTCCCCCACGAACCTATTGGCTTACTCAGCGACTATATGTTCAGAGCCGCTGGGCGATTAGATAAATTCTTGCAGGCTATCAACGATCGAAATCCTTTGACCTAAGGCTTCCTACTGCACATGGCGGTACTGGTGCTTGAAGGCGGCTCCAGGTTACGATGATCCAAGACAAAAGAAAGTCTAATTAAAAAAAATACTCTCATCACCTGTTAAGCCTAAAAGACTTTGAACCAAAAAATCCGTGTGTGGAAAGGCAAGAAACTGCCTACGTAGGTACCAAAAGCTGCCCGTACGACCTTTATCTGGCTCCATTACCCGGTTTATTGAGGATTATCTGGGCAAGTGTCTTGGTCGACCACGGCTGGAATTTCGCGAAAGGCCACAAAAAGGATCAAGGGAATTTTAGGGTAATAGAAAGGAATCAAGAACTGTTACACAAAGGAAAATAAGAATTTATCGCGGTTAAAGGCGCAAAAATTGAGGGAAGTCGCTTTTCTTTGATCAGAAGCTGCTCGTTCCAAGTCTCATCGGCTGTCGTGGTGGGAAATCACTGCGATTTCAGCTGCCGTTAAGCCACGGAAGGGCCGGAGTAAACGTGAACGCTCGGCTGCTGGGACATCTAAGCGCTTTTCGTAGCAAGGATTAGGGTCATTATATGAGCCTACGGGGTGAACCTAAGGAATATTGACGGGCCAAGGGCACCACCAGGAGTGGAGCGCGCTGGCGCTTAATTGACTCCCACGGCGGAAAGACTCACGTACCGGAATTAGGACAAGCAGGGACAATTGAGAGCTCTTTCTTGATTTCGCGTGGGTGTGGTGCATGGCCCTTTGGCTCTTTAGTTGCCCGTGGAGCGATTTGTCTGGTTAATCCGTATACGAACGACTCTCTAGCCTGCTAAATAGTACGCCGAATTTGCGTGCACTGACTAGACGGACAATTTGCAAAATTTGACCAATAAAGGTACTGTGACAGTGCGCCTTAGAGTTCGCGCACGGCGAGCAGAAACAAGGTCTTTTTTCCTGGTTCGAAGAGCGCGGGTAATCTGTTGAATTCCCTTCGTGACAGGATTCCGGGTTGCAATTATTCCCGGTGAACGGGAATTCCCTTCCCAGTAAGACGCTCATTACCCTGACCTACTTGAGCCGAACCGGTAACTGCCCTTAGAGATTGTTGACGCCGCCAAGGTCCTCCGGATTGGTTTGCACCCGATGGGCGACTCTCTTGGCCGACTTGGTGCAACACTAGGTCGGATACTGAAAAGAAGATCAAACTTGATCATTTAGAGGAAGTAAAAGTCGTAACAAAGGTTTCCGTAGGTGAACCTGCGGAAGATCATTA
->KZ248836.1/34641-34948 Danaus plexippus plexippus isolate F-2 unplaced genomic scaffold DPSCF300292, whole genome shotgun sequence. 
-ACTGGGAGCGTGGCGCCTCTTGTAATCCGTGCTACTCGGAGGTCGGGGTCGAGGGATGGTTTGAGGTTTGAGGTCCTGGGACTGAGATGGCCACAACAACCGGATGGCCACATTCAAGCCTAGTATGACTTTGATCTTCTGGAAGAGTCTAGACTCTAGAGGGTGCATTCTACGGAGGGATAACAGTTCAGGCCCAGGGAGACAACTCAGGGGCCTAGGAATCCCTTCGTACCGGGCTGGAGTGGAATTTAGCCGGGAGTGAACTAACTCAGTAACAACCTAACCGATATAACCAGACCCTTCCCTAT
->CP001899.1/298032-298087 Ferroglobus placidus DSM 10642, complete genome. 
-GCCGATGATGACCCCTCCCCTAGCTGAAGAGTGATGAATTTGCCGATTACTGAGGT
->FAOM01693974.1/1165-1 Triticum aestivum genome assembly, contig: Triticum_aestivum_CS42_TGACv1_scaffold_693974_U_6BS-0.065204_1BS-0.034861 
-CGGTGCGCCCCCGGCGGCCCATGAAAATCCGGAGGACCGAGTACCGTTCACGCCCGGTCGTACTCATAACCGCATCAGGTCTCCAAGGTGAACAGCCTCTGGCCAATGGAACAATGTAGGCAAGGGAAGTCGGCAAAACGGATCCGTAACTTCGGGAAAAGGATTGGCTCTGAGGACTGGGCTCGGGGGTCCCGGCCCCCGAACCCGTCGGCTATCGGCGGATTGCTCGAGCTGCTCACGCGGCGAGAGCGGGTCGCCGCGTGCCGGCCGGGGGACGGACCGGGAATTGCCCCTTCGGGGGCTTTCCCCGAGCATGAAACAGTCGACTCAGAACTGGTACGGNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNAACGGGCTTGGCGGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTGAGAGGTGTAGGATAAGTGGGAGCCCTCACGGGCGCAAGTGAAATACCACTACTTTTAACGTTATTTTACTTATTCCGTGGGTCGGAAGCGGGGCATGTCCCCTCCTTTTGGCTCCAAGGCCCGATCTTACCGGGCCGATCCGGGCGGAAGACATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGCTCAACGAGAACAGAAATCTCGTGTGGAACANNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCCACCAATAGGGAACGTGAGCTAGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGACAGTGTCGCGATAGTAATTAAACCTAGTACGAGAGGAACCGTTGATTCACACAATTGGTCATCGCGCTTGGTTGAAAAGCCAGTGGCGCGAAGCTACCGTGTGCCGGATTATGACTGAACGCCTCTAAGTCAGAATCCAAGCTAGCATGCGACGC
->AEAQ01007696.1/1567-1612 Solenopsis invicta Si_gnG.contig11298, whole genome shotgun sequence. 
-TTAATTGCTCCTTTTGGAGCAATAAATATTGCAATATAAAAAATTT
->CM003288.1/100477756-100477466 Salmo salar isolate Sally breed double haploid chromosome ssa10, whole genome shotgun sequence. 
-GGATGACGTGTCAGAGTTTGGGGTTCCTAATGGAAGTATCCACTCTGCATCATTTCCTCCTCATATCTTCCTTGTAGGGTACATAGTGGCCATCCTGTAACCAATTAGACAAGATATGCTCAATTTGTTCAGCATTTGGGCCGTGGTGCGGCCGGAAGCTTTGGCCTGAGGATATACGCAGCAGCTCTCGTTAAACTGAGGATCTGAGATAGTTTCTGACTTCACCATCTGGAATTCTAGTCTGGGGTTCTGCTAAAAGCTGCTGACCCACGATTCAACTCTTAAACTCAG
->AAVT01000001.1/231300-231180 Marine gamma proteobacterium HTCC2143 1100111000176, whole genome shotgun sequence. 
-CGCAAACCTAAGGGGTGGCTTTTGCCTGAGATGCCTTGATCTGCTTGTTACTGTCGATCAACAGCGAACCCTTGAACCTGATCCGGTTAATACCGGCGTAGGAATAGGTGTCCCCAACCGA
->MHIN01000011.1/1-803 Candidatus Buchananbacteria bacterium RIFCSPLOWO2_01_FULL_40_23b rifcsplowo2_01_scaffold_14059, whole genome shotgun sequence. 
-GAAGCTCCCAAGGGTTTGGCTGTTCGCCAATTAAAGCGGTACGCGAGCTGGGTTCAGAACGTCGTGAGACAGTAGATTCGTGCTGTCTATAAATTCGGCTATATGCTGGAAAATCCGAGAATCTTATGATACTCATCCATAAAAATTGGGTAGTGAAAATTCATAAGTGCGGACAATCAGCAGGAAACTTAATAATAGTTTGTTATTAATAATATTATTTATGTTATTGCTAACAAAATTGTCGAGAGCGGCTTCTAATAAAAAAATTATATTATTAGAAGCGTTAAAATAGTAGTGATTGTAAATACAGTAGTGGTTTATAATAACCAATCTACATAAATTATTGCCGTAGACTCGAATTATTATGAATCCTCAGAGACTATACGCCGAAATTCCGATAAAAATCGGAAATAAGATATAGTCCGAACTGCATGGCGACATGCAGATTCCGGCAGAAATTGTCGGAACGCCATAGAGCAATTGATGTTTTAAGATATGGTTTTGCAAAGTAACAGATTGTCGGTCTCCTATCCACTGTGGGCGTTGAAATTTGAGGGGGCTCATTTTTAGTACGAGAGGACCAAAATGAATAAACCTCTAGTGTACCAGCTGTCCTACCAAGGGCACAGCTGGGTAGCTACGTTTAGTTTAGATAAGCGCTGAAAGCATATAAGCGCGAAGCTGTCCCCAAGATTAGATTTCGTTATAGGCTCCCGGGAGACGACCGGGTTGATAGGCGGTAGGTGTAAGGCCAGCAATGGCTTGAGCCGAGCCGTACTAATAGCCAATTTCTATTTAACCAC
->AP008230.1/3620544-3621014 Desulfitobacterium hafniense Y51 DNA, complete genome. 
-TTAATGCTAATGACGAGAAAGAGTACACCTTAGCCGGAATGTCCAAGAGAGTCAGCGTTGGTGAGAGCTGATACAAACCGTTTGGTGGAATGGGTCTCTGAAGCGCAAGCTGAACGAATCTGCATCTTGACTATCAGGATGGAGATATCAAGTAGGCAAGCCGGGGGTTTCCCGTTACAGAAACACGGGTATCGAGAGCATGGATCATTCTCTCCGCATCCGGTTAGAGGTATGGGACAGCTTTTTTAATTCCAGCGGCTTGCGCTGACCCATATAAATTAAGGTGGCAACACAGAAGTACTTTCTGTCCTTTACATAGGACGGGAAGTTTTTTATTTTAAAATAAAGTGCCGCCCTCTCCGGATGAACAAGAGATGAAATTATGTTTTCTCCGTACCTGATAGAGGTACTTGTAGATACACTACACAAGTACAAATTAAGGTGGCACCACAGAAGCTTTCTGTCCTTTGG
->CM003280.1/7976717-7976643 Salmo salar isolate Sally breed double haploid chromosome ssa02, whole genome shotgun sequence. 
-TGCCCCCGTGCGAGGAATCTAAGATAGAATTGGACTTTGCTGTGAAATTCTATCTTAGATTCCTCGCACGGGGGC
->MGZN01000446.1/306-243 Hydrogenophilales bacterium RIFOXYA1_FULL_63_33 rifoxya1_full_scaffold_3877, whole genome shotgun sequence. 
-TCGGGGCGCCAGCCCCCGATGTCTGAGCACGATGCTCACAAGACGGTGTCCCGTCCAAGCCTGG
->LZPO01097937.1/23658-23530 Neotoma lepida isolate 417 scaffold_12034, whole genome shotgun sequence. 
-TTTGCAGGCTGATGGAGTCAGCAAGGAAGAGGTTTATGAACAGCAGCCACTCTGCATAGGATGGCTGCAGGGAATGTTCTCATGCTTGCCCAGAGAAGTCTGCCAGGGTCACTGAGATACCTCTGAGAT
->CP011974.1/3783475-3783356 Bacillus endophyticus strain Hbe603, complete genome. 
-AGACCCTTTAACATCAGTCCTGTGAGGCTGAGAAGGAAACGGACCGCAGATGCAGCAGGCGTCTGCAAGCTTACTATACCCGGCATCCTCTCAGTCACGGACAAAGAGGATGCTTTTTTT
->JXSO01000068.1/6302-6422 Achromatium sp. WMS3 contig-199_67, whole genome shotgun sequence. 
-TAATTTTTTTAAATATTTCACATATATACCGACACAAAACGTAGGGTGCCTTAATTACCTTTAAATATTAAAGTGAATACCTGTTAAAAAGGTTACGTTTTGGGGCATATAGAGGCAAAAC
->CM002304.1/542199-542383 Ogataea parapolymorpha DL-1 chromosome V, whole genome shotgun sequence. 
-CACTCCTGTTTCTGCCTCATATTCCCTTGCTCCATGGAATAATGGGTTCTGGTGATGGAGAAGATCAAGCCCGTCGTCGTCTCTGCGATTTGATACTTTGTTGAGTTCGAGGACGGGATCGTGAAAACGCATATACCCAGGGCTGCCAGACAGGTTGGCGGCTCTGAATTGTCGTTTCTACATCT
->ABJB010136869.1/1-805 Ixodes scapularis strain Wikel colony gcontig_1108379663008, whole genome shotgun sequence. 
-CATCCGCAGCAGGTCTCCAAGGTGAACAGCCTCTAGTCGATGGACCAATGTAGGTAAGGGAAGTCGGCAAAACGGATCCGTAACCTTGGGATAAGGATTGGCTCTGAGGACTGAGCCGGTCGGGCTGGGGACCTGAAGCAGGAACGGCACTGCACCGGGACTGGGCGGGGCTCGCCGTTCACGCGGCGCGGCCAAGCCCGGACCAGCGTCGGGACCTTCCTGTGGAAAGCCTCAGCTGCGCGGCGTCTGAGGGCTTCGTGCCCAAAGTGCTATGCTTCGGCCGGCAAAAAACAGTCAACTCAGAACTGGCACGGACCGGGGGAATCCGACTGTCTAATTAAAACAAAGCATTGCGATGGCCGCTGGTCGGTGTTGACGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAACGTGAAGAGATTCATCAAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTGTGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTATCTACTGGGAAGGAAGAAGAAGACCAGACCTCCTAGACCATCAGATTGTAAGCTGTATCGTTCCAGTAATTTTTCTTTAACTTCTAGCCATTATTTCTTAAAAACAACCTAGCGGTAGGATTTCTAAGAACTAGCGATCACCCTGTTATCAAATTTAAGACTGTTAACCCATTAATTTTTCTTAAAATACACCTTTGGAATCACTGTTTACACTGCGGCCATATTGCCACGGTTGTAGATGTTGAACCCCAAATTTGAAAATAACT
->CVUF01000026.1/144661-144885 Staphylococcus capitis strain CR03 genome assembly, contig: BN1517_Contig_4 
-TTTTTATTCATAAGGCATCTCGGTAATTCAGTTTAGTGAAGTTTATTCAATGATAGGAAAGTGCCTTATATTTTAAAGTATATCGATGTGAAATTACATGGTAATATGTAGTATCTTTGACGAGATTCCTGAAGGAGCAGTCCCAGTCCTAAACCTAGATTGAGACGGACACACTGCGACACGAAACCATACTATACGAAGTAATGAATATAAAAGTAGCAGTAA
->KC954775.1/132832-132944 UNVERIFIED: Cronobacter phage S13, complete genome. 
-GGGGTGATCGTCTAGTGGTAGGACGCTTAAAGACGCAAACTGATAAGTTTGTATTCAGCATTTAACTTTCCATTCCAAGGAAGAAACGCGTGGTTCGAATCCCGCTCACCCCG
->URS0000D67EE2_12908/1-83 unclassified sequences c-di-GMP-I-GGC riboswitch 
-AAUAAAAAAGGUACAUCUGUCGAAAGUUUGGGGCGCGAAGCCGCGGAUUUAAUACGACAGCUGCGAUGAGCGGGCUACCGUGG
->KE355093.1/339-1 Streptomyces afghaniensis 772 genomic scaffold STAFG_scaffold694, whole genome shotgun sequence. 
-GCGCAAGCGGCGGAGGCATGTGGCGTTAATTCGACGCAACGCGAAGAACCTTACCAAGGCTTGACATACACCGGAAAACCCTCGGAGACAGGGTCCCCCTTCGTGGTCGGTGTACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCCCGTGTTGCCAGCAGGCCCTTGTGGTGCTGGGGACTCACGGGAGACCGCCGGGGTCAACTCGGAGGAAGGTGGGGACGACGTCAAGTCATCATGCCCCTTATGTCTTGGGCTGCACACGTGCTACAATGGCCGGTACAATGAGCTGCGAT
->ALWS01100951.1/21533-21438 Pteropus alecto contig100951, whole genome shotgun sequence. 
-ATTTTCAGTTATAAGATAAGTAAGTTCTGCTAAGCAGGTTGGACCTGGTTAGTACTTGGATGGGAGACCACCCAGGAAGACCAGGTGCTGTAGGCA
->CP019433.1/1335117-1334970 Jeotgalibaca sp. PTS2502, complete genome. 
-AATATTGAAAGAGGATGCGAAAAAAATCAGTAGGTTTCGAAAGGGTTTTTCGCCGAAATGCAGCTTAGCTGTGTTGGGGTCCGTTTGAATAAGACGGGAACTGCCTGATAGTCTTGCCCAAAGACTATTAAGGAGTGCTGTCATTGTT
->CM001241.2/28956953-28956880 Oryza brachyantha chromosome 1, whole genome shotgun sequence. 
-GTGAGCCGTGTAATAGGCGACTATTTCGCGCGGTTCGGGGGGCACTTGAAATCTTGAATAAGCCGTCAGCCCTC
->ALWZ044178298.1/15950-15905 Picea glauca, whole genome shotgun sequence. 
-TCAAAGGATTCCTTCGAATCCACCATGATCATATTTCGAAAATAGT
->CP012413.1/1770895-1770659 Piscirickettsia salmonis strain PM15972A1, complete genome. 
-AAAGTTCAGCCCTGAAAATGCAGCTCAGCATATCAGGTACCGAGCCTTGAGTAAGTACTGGTAACAGTGCGTGCTAAGCGTAGGCAGGGAAATAATAGGCCGTAAGCCAAAGAGCTGAAGTGATTGAGCCTCGTAAACATAATACTGAGATAGCCGATGGTTTGGAATGTATCAGAAGGCAATATCGAATAGGACGTTAAGAGAAGAAATATTCGACATCTCCGGGGTCTTAGAGCA
->AGTP01050901.1/2323-2414 Ictidomys tridecemlineatus contig050901, whole genome shotgun sequence. 
-GGGGATGTAGCTCAGTGGTAGAGCACCCTTGGGTTCAAATCCCAATACCTAACAGGGGTGGGGGTAATGGTGGTAAGGTCCCTCCATTACCT
->KE346365.1/91830-91967 Capsaspora owczarzaki ATCC 30864 unplaced genomic scaffold supercont2.6, whole genome shotgun sequence. 
-ATCTTTGTGCAAGGGTGGTGCCATCGTGCGTGAGGGAATTCCCGATGCGTGGCTTTTTGCTGATTGCAAACTAAACATCCAAGCCCGCGACATGTGAAGCTTGCTTCCTGTCGCAATTTTTGTAGCTGGCCCAGGTCG
->ALWS01164951.1/7774-7926 Pteropus alecto contig164951, whole genome shotgun sequence. 
-ATCACTTCTCGGCCTTTTGGCTAAGATCAAGTGTAAAATTGCCTAGATGTAAATATGTGTATATGTGCATGTTTGTACCTGTAAATATGTGTATATGTGCACGTTTGTACCTCTATGCGCGTGCGCGCAGGCGCGCGCGCGCGCGCACACACA
->GL883275.1/454-1 Melampsora larici-populina 98AG31 unplaced genomic scaffold MELLAscaffold_189, whole genome shotgun sequence. 
-TTCTACCCACAAGGAATATCCGGGTGGCTCCGCCACCCGGGGCGCGTCTCCGAAAAAAAAAAAAAAATTAGAGGGCTTGGGAATGTAATGTTCTTAACCTATTCTCAAACTTTAAATATGTAAGACGTACTTGTTTCTTAATTGAACTTGTACATGAATAAAAGTCTTTAGTGGGCCACTTTTGGTAAGCAGAACTGGCGATGTGGGATGAACCAAACGCAGAGTTAAGGTGCCGGAATATACACTTATCAGACACCACAAAAGGTGTTAGTTCATCTAGACAGCCGCACGGTGGCCATGGAAGTCGGAATCCGCTAAGGAGTGTGTAACAACTCAACGGCCGAATGAACTAGCCCTGAAAATGGATGGCGCTCAAGTGTATTACCTATACTCTGCCGTTAGTATTCTTTTAAAGATATTAACGAGTAGGCAGGCGTAAAGGTTGCGTAGAAGC
->AYZS02020768.1/14673-14528 Beta vulgaris subsp. vulgaris Bvchr7.sca021.con0307.1, whole genome shotgun sequence. 
-TTGGGTTCACAATATAGTTAGGCAAAAAATGGTGCTGATTAATAAATGGGCATTGTTTTAAAAAGTGGATCCGAAAGTGAATTGTTCCCCTCGCTATCCAGTGTAGAAATTTCTTTGCTACATTTGGACGTTGGGAAACTATATTT
->KE159628.1/947698-947606 Lachnospiraceae bacterium COE1 genomic scaffold acPFN-supercont1.2, whole genome shotgun sequence. 
-AGCAGTTCCTTAAGTGCCTTGTGAACAGGGAGTTGTCACAGGGACGAAAAAGCCCTCTGGGGCTTTGCGGTACGAGGTTCGCATCCCGCTGCT
->MGUZ01000016.1/78253-78409 Elusimicrobia bacterium RIFOXYA12_FULL_49_49 rifixya3_full_scaffold_62, whole genome shotgun sequence. 
-TTGTCCCTGCGATGTTGGTGTGGTATTATCTGATTTGAACCGACAAGTTCCTTTCAGGGAGTTGCAGGTGAGCTATACGCCTTAGGGCTATAGACCCGGACACCCACTTAATGAAAAGGGCTCAATCAGATGAAACTCACGGCAGAGTGGGGATTTT
->AE017283.1/720172-720358 Propionibacterium acnes KPA171202, complete genome. 
-GCTAAAATCCTCGCGTCAGGTTGCTGGTGACCACACCAGCGCTGGAATCCGGTGAAAAGCCGGAGCTGACGCGCAGCGGTATGACTGATCCGCCCCGACTTGAACCACTGGCGCCATGCGCACTGGGAAGGCGCCGGGAACGGAGACGAAGTCGAGCCCGAAGACCACCTGACGACGCCCTGTTGTT
->AOTI010241097.1/1-750 Triticum urartu cultivar G1812 contig241097, whole genome shotgun sequence. 
-TTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTGAGAGGTGTAGGATAAGTGGGAGCCTCACGGCGACGGTGAAATACCACTACTTTTAACGTTATTTTACTTATTCCGTGAATCGGAAGCGGGGCGTAGCCCCTCCTTTTAGATCTAAGGCCCGTTCGCGGGCCGATCCGGGCGGAAGACATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGCTCAACGAGAACAGAAATCTCGTGTGGAACAAAAGGGTAAAAGCTCGTTTGATTCTGATTTTCAGTACGAATACGAACCGTGAAAGCGTGGCCTATCGATCCTTTAGACCTTCGGAATTTGAAGCTAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCCACCAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGACAGCATCGCAATAGTAATTCAACCTAGTACGAGAGGAACCGTTGATTCGCACAATTGGTCATCGCGCTTGGTTGAAAAGCCAGTGGCGCGAAGCTACCGTGTGCCGGATTATGACTGAACGCCTCTAAGTCAGAATCCAAGCTAGCATGCGACGCCTGCGCCCGC
->LADO01000055.1/61648-61600 Peptococcaceae bacterium BRH_c4b BRHa_1001649, whole genome shotgun sequence. 
-GGTTGGCCCCGTGAGGGGTTTCAAGATCCGATTACTTGGGTGGGTAGTC
->AAQR03071181.1/131-221 Otolemur garnettii contig071181, whole genome shotgun sequence. 
-CCCTCAGGAGGACTGTGCCGGTCAGCTCCATGGAGTTTCAGTCAAGGAGTTTCTGAGCCTATGGATCTACAATATTTGACTGCCTGGGGCA
->KE951434.1/4972-1857 Actinobaculum sp. oral taxon 183 str. F0552 genomic scaffold Scaffold35, whole genome shotgun sequence. 
-GTTGTAGGTGTTGTAGGGCGTTCGGTGGATGCCTGGGTACCGGGAGCCGAAGAAGGACGTTGCAGCCTGCGATATGCCTCGGGGAGCCGGCAAGCGGGCTTTGATCCGAGGGTGTCCGAATGGGGGAACCTGGCCGGGGTTGTGCCCGGTCGCTCGTGCCTGAATTCATAGGGTGCGGGTGGTGACGCGGGGAAGTGAAACATCTTAGTACCCGTAGGAAGAGATATTCCGTGAGTAGTGGTGAGCGAAAGCGGAGGAGCCTAAACCGTGGGCGTGTGAGAGCCGTCGGGTGTTGCGTGTGCGGTGTTGTGGGAGATGATCGTGATCATGCCGACGCGTGGTCGCGCAGTGATAAACCGTGGGGATAGGCGAAGGGTCTGGGAAGGCCTGCCGGAGAGGGTGAGAGCCCCGTAGCTGAAATTCTCGTGGCTGTGTGATTGTGTTCCCGAGTAGCATGGGGCCCGTGGAATCCCGTGTGAATCTGGCAAGACCACTTGTCAAGGCTAAATACTCCTGGTGACCGATAGTGGAGAGTACCGTGAGGGAAGGGTGAAAAGTACCCCGGGAGGGGAGTGAAAGAGTGCCTGAAACCGGGCGCCTACAATCCGTCAGAGCCTCCGTGGTGGGGGTGATGGCGTGCCTTTTGAAGAATGAGCCTGCGAGTTAGTGGCATGTGGCGAGGTTAACCCGTGTGGGGGAGTCGTAGCGAAAGCGAGTCCGAAGAGGGCGTGAGTCGCGTGTTCTAGACCCGAAGCGGGGTGATCTACCCATGGCCAGGGTGAAGCTCGTGTAAGAGCGTGTGGAGGCCCGAACCCACCAGGGTTGAAAACCTGGGGGATGAGTTGTGGGTAGGGGTGAAAGGCCAATCAAACTCCGTGATAGCTGGTTCTCCCCGAAATGCATATAGGTGCAGCGTTGCGTGGTTCCTTCCGGAGGTAGAGCGACTGGTTGGCTGATGGGCCTTACCGGGTTACTGACGTCAGCTAAACTCCGAATGCCGGGAGGGTGGAGCGTGGCAGTGAGACGGCGGGGGATAAGCTTCGTCGTCGAGAGGGAAACAGCCCAGATCGCCGGTTAAGGCCCCTAAGCGTGTGCTAAGTGGGAAAGGATGTGGAGTTGCTGGGACAACCAGGAGGTTGGCTTAGAAGCAGCCATCCTTGAAAGAGTGCGTAATAGCTCACTGGTCAAGTGGTTCCGCGCCGACAATGTAGCGGGGCTTAAGCACACCGCCGACGCCGCGGCAGTCCATCGTGGTCCTAGCCTGTCCGTTGGGCGGGTTCAGGGGGTGGGCTGGGTAGGGGAGCGTCCCGCGTTGGGTGAAGTCTCGGGGTGACCCGGGGTGGACGGCGTGGGAGTGAGAATGCAGGCATGAGTAGCGAGAGGCGGGTGAGAAACCCGTCCGCCGATTGACTAAGGGTTCCAGGGCCAGGTTGATCCGCCCTGGGTTAGTCGGGTCCTAAGGCGAGGCCGACGGGCGTAGTCGATGGACAACGGGTTGATATTCCCGTACCGGCGCTTGACCGTTCAATGTTCGCCGGGGTGATGCTAACCATCCCCGATCCTGTGTGTCTCTTTCGGGAGGCGTGTGGGGGAGGGCGTGGGGTCCGAGCCTGGGTGGGCAAGCGTGGTAACAGGTGTGACGCAGAGTGGTAGTCCAACCGTGTCGTATGGCTGAGCACGGCTAAGGGTGCAGCCCGTCTCCCAGGTAAATCCGGGGGGCGTTCGGGTCAGGCCTGATGGGGACCGTTTGACGGGAAGTGGATGATCCTGTGCTGCCGAGAAAAGCATCGACGTCAGGGCAAGCGCCGCCCGTACCCGAAACCGACACAGGTGGTCAGGTAGAGTATACCGAGGCGTGCGAGTCAATCGTGGTTAAGGAACTCGGCAAAATGCCCCCGTAACTTCGGGAGAAGGGGGGCCCGGGCCTTGATGTCCCCGTGCGGGGCGGAGGGGTCGGGGCCGCAGAGTCCAGGGAGAAGCGACTGTTTATCAAAAACACAGGTGCGTGCTAAGCCGCAAGGCGATGTATACGCACTGACGCCTGCCCGGTGCTGGAAGGTTAAGCGGACTGGTCAGCCCTTCGGGGTGAAGCTGGGAAGTTAAGCCCCAGTAAACGGCGGTGGTAACTATAACCATCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGCGTAACGACTTCTCCGCTGTCTCGACCACGAGCTCGGTGAAATTGCAGTACGAGTAAAGATGCTCGTTTCGCGCAGCAGGACGGAAAGACCCCGGGACCTTTACTATAGCTTGGTATTGGTGTTCGGTACGGCTTGTGTAGGATAGGTGGGAGACTGTGAACCGGTCACGCTAGTGGGCGGGGAGTCGTTGGTGAAATACCACTCTGGCCGTGCTGACCATCTAACCTCGGTCCGTGATCCGGGCCAGGGACAGTGCCTGGTGGGTAGTTTAACTGGGGCGGTTGCCTCCTAAAGGGTAACGGAGGCGCTCAAAGGTTCCCTCAGCCTGGTCGGCAACCAGGTGGCGAGTGTAAGTGCACAAGGGGGCTTGACTGTGAGACTGACGGGTCGAGCAGGTACGAAAGTAGGAACTAGTGATCCGGCGGTGGCTTGTGGAAGCGCCGTCGCTCAACGGATAAAAGGTACCCCGGGGATAACAGGCTGATCCTGCCCAAGAGTTCATATCGACGGCATGGTTTGGCACCTCGATGTCGGCTCGTCGCATCCTGGGGCTGGAGTAGGTCCCAAGGGTTGGGCTGTTCGCCCATTAAAGCGGTACGCGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCCCTATCCGCTGCGCGCGTAGGAGAATTGAGAAGGGCTGTCCCTAGTACGAGAGGACCGGGACGGACGAACCTCTGGTGTGCCAGTTGTTCCGCCAGGAGCATGGCTGGTTGGCTACGTTCGGGAGGGATAACCGCTGAAAGCATCTAAGCGGGAAGCCTGCTTCAAGATAAGTTCTCCATCCAGCCTGTGTGCTGGGTGAGGTCCCCCGCAGACGACGGGGTTGATAGGCCGGACGTGGACGCCTCGTAAGGGGTGGAGCTGACCGGTACTAATGGACCGACCGCCTACACCAT
->AAAB01006367.1/1-1388 Anopheles gambiae str. PEST whole genome shotgun sequencing project, whole genome shotgun sequence. 
-TATTCGAACGAGCTCTTGGATGACTGAAGTGGAGAAGGGTTTCGTGTCAACAGCAGTTGAACACGAGTTAGCCAATCCTAAGCCGCATGGGAATCCAGTCGTAACCCATCAGTCGGCGAAAGGGAATCCGGTTACCATTCCGGAGCCTGTTGAGTACCCGTTTGCGCCAGCCTAGTAGGGTTTAGCTCGTCCGCACCCGAACGGTTAGTGTGTAGCTTCATGGCAACATGAATCCTTTTCTTCGAGAAGCCAACGAGAGGCATCGGAAGAGTTTTCTTTTCTGTTTTACAGCCACACCGACCATGGAAGTCACTCACAGAGAGATATGGTTGGACCGGTCTGGTAGAGCACGGCCGCCGCAACTGCCGTGTCGATGCACTCTTCTTGGACCGTGAAAATCGAAGACTGGGGCACACTTTATATGGTAATAACGCACACTCTCAACAGATTGTACCGAATCCGCAGCAGGTCTCCAAGGTGCAGAGTCTCTAGTCGATAGATCAATGTAGGTAAGGGAAGTCGGCAAACTGGATCCGTAACTTCGGGACAAGGATTGGCTCTGAAGGCTGGGTGCGACCAGCCGGGACCGGTGCTCCACCTGCCGCAAGGTAGGCTGGCCCGTGCCCGCGGTCGCACAGCAAACAGCCAATTCAGAACTGGCACGGCTGAGGGAATCCGACTGTCTAATTAAAACAAAGCATTGTGATGGCCCCGGGTGGGTGTTGACACAATGTGATTTCTGCCCAGTGCTCTGAATGTCAACGTGAAGAAATTCAAGCAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCTCTGTCCCTATCTACTATCTAGCGAAACCACAGCCAAGGGAACGGGCTTGGATGCACTAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCTGGCATTGTAAGGCGATATAGGAGGTGCAGCATAGGTGGGAGGGCTTCCTCGTGGAGCTCGCCTCTGAGATACCACCACTCTTACTGTTGCCTTACTTACATGATTGGGTGGTACAAGCGCGGGCCCCAGGTCCGGATCGTGCGCGCACCTCCTCCGGGGGGCTGTGGCGGCGGTTCGCCTGCGCGCGCCCAATGCGCCGTGTTTCTCGCTCAGCGTCCAGTGTGTCGCTGGGTGGTGCCGCCGGGGAGACTGCATCGTAGCATCGTCGTGTGTAGCGTGTTACCCGCTTGTCCGACCGTGAGCCGTGGCCCGCAAGGGTACAAGCTTGCGTACGTCGGTGCATTCGTGGTGCACTGCTTCTGCGCGGTCGATCGTTTATGATGTCACGTTTGCCCCCGGTTCCGCGCGCCGC
->JH835377.1/4969955-4970252 Erinaceus europaeus unplaced genomic scaffold scaffold00089, whole genome shotgun sequence 
-GGATGTGAAGGCAATCTGGCTGTGACATCTGTCACCCCATTGATCACAAGGGTTGATTTGGCTGATCTGGCTGGCTAGGCAAGTTTCCCCTTCCTTCCTAACTGCTCCATGTGCATTGAAAATAGCCTTGCTTGAATCGAGACGGACCGGTCTTCATTGGAGGGTATACAAGTAGCTGCGCTCCCCTGCTAGAACCTCCAAACAAGTTCTTCAAGATATACTACAGAACAATTTGTTTAATAATCAGGAACCTAAAGGCAAAAAATATAGCAGATGAGATTCGGGAGGGTCTTCATTT
->CP014222.1/4334669-4334580 Janthinobacterium sp. B9-8, complete genome. 
-TTCAATGGTGGGGCGTGGTGGGGGCTACCTCGGTAGCGTCGGTTTACTATTTCGCCGATACGCCAACTCTGCCACGTTCCTACCTCCTTC
->FQXP01000006.1/145863-146131 Clostridium collagenovorans DSM 3089 genome assembly, contig: EJ35DRAFT_scaffold00004.4 
-ATAAATGCTATGAAAAAGGAAAGTAGTGTATTGGAGGGTTACAGAGAGAAAGCGATGCTGAGAAGCTTTCACCTATAAGATATATGAAGTGCCCTTTGGAGCATGGATCCGAAATGGAGTTACACAATAGTTGAGTAACTTAAAAGTAGGAGACCACGGGTTCGCCCGTTAAAGCGATAGGGCATTATTATGTGCTTGAAGATAAAGTGAGATTCTTTTTGAATCTAATTAGGGTGGAACCACGGAGTAAACATAGCTTCGTCTCTAGA
->URS0000D6C44C_12908/1-87 unclassified sequences c-di-GMP-II-GAG riboswitch 
-GCGAGGGGUAGGAGCUCGGAACCGCGGCCCGCAAGACGGGCACUGAAGGGGCGCAGGGGGCUAGUGGUGCGACCGGCUACCGCUCCG
->URS0001A235AD_371731/1-41 Rhodobacter sp. SW2 L2-Alphaproteobacteria ribosomal protein leader 
-GGAUCCCAACGAUGGAUCCUUCAACUGACGGAAGACAGAAA
->FQUW01000011.1/34981-34776 Desulfotomaculum australicum DSM 11792 genome assembly, contig: EJ60DRAFT_scaffold00008.8 
-CAATTGAATAATTGAACGGGTGCTCCCTTTTTCAAGGGATAGAGGGAAGTCAGTGCAAATCTGACGCGGTGCCGCCACTGTGAATGGGGAGCTGGCCACACAATGCCACTGGTCGGGCACCTGCATTGGCCGGTGTCCGGTTGGGAAGGCGTGGTTAAAGCGATGATCCATGAGCCAGGAAACCTGCCCGTTCTATTTCACCGTTT
->URS0000D6A184_12908/1-121 unclassified sequences Flavobacterium-1 RNA 
-CGAGATAGGGGTACAAGTTCTGCAGTATTGCGTTCCTCTGGACCTAAGCAACGACCTGAAAGGGTAGCGACGAAGCTCGGCGTTAGTGGAGAGAGTCCCAGACGTGGTGTCTCCACTGACG
->MUNX01000075.1/101357-101431 Flavobacterium sp. A45 NODE_7_length_112147_cov_12.4241_ID_13, whole genome shotgun sequence. 
-TTTTAGCCCCGATAGCAGTGTAAATCCTCTCTCGTTTTTCAACGAGAGAGATTGAAACGGATAGCGGGACTTTGC
->KQ948572.1/3318-23 Streptomyces longwoodensis strain DSM 41677 genomic scaffold PRJNA299227_s024, whole genome shotgun sequence. 
-GGCCAAGTTTTTAAGGGCGCACGGTGGATGCCTTGGCACCAGGAACCGATGAAGGACGTGGGAGGCCGCGATAGTCCCCGGGGAGTCGTCAACCAGGCTTTGATCCGGGGGTTTCCGAATGGGGAAACCCGGCAGTCGTCATGGGCTGTCACCCACTGCTGAACACATAGGCAGTGTGGAGGGAACGAGGGGAAGTGAAACATCTCAGTACCCTCAGGAAGAGAAAACAACCGTGATTCCGGGAGTAGTGGCGAGCGAAACTGGATGAGGCCAAACCGTATGCGTGTGAGACCCGGCAGGGGTTGCGTATACGGGGTTGTGGGATCTCTCTTTCACAGTCTGCCGGCTGTGAGACGAGTCAGAAACCGTTGATGTAGACGAAGGACATGCGAAAGGTCCGGCGTAGAGGGTAAGACCCCCGTAGTCGAAACGTCAGCGGCTCGTTTGAGAGACACCCAAGTAGCACGGGGCCCGAGAAATCCCGTGTGAATCTGGCGGGACCACCCGCTAAGCCTAAATATTCCCTGGTGACCGATAGCGGATAGTACCGTGAGGGAATGGTGAAAAGTACCCCGGGAGGGGAGTGAAATAGTACCTGAAACCGTGTGCCTACAAGCCGTGGGAGCGTCGGANNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNTTCTCGTGACTGCGTGCCTTTTGAAGAATGAGCCTGCGAGTTTGCGGTGTGTTGCGAGGTTAACCCGGGTGGGGTAGCCGTAGCGAAAGCGAGTCCGAACAGGGCGTTTCAGTAGCACGCTCAAGACCCGAAGCGGAGTGATCTAGCCATGGGCAGGTTGAAGCGGAGGTAAGACTTCGTGGAGGACCGAACCCACCAGGGTTGAAAACCTGGGGGATGACCTGTGGTTAGGGGTGAAAGGCCAATCAAACTCCGTGATAGCTGGTTCTCCCCGAAATGCATTTAGGTGCAGCGTCGTGTGTTTCTTGCCGGAGGTAGAGCACTGGATAGGCGATGGGCCCTACCGGGTTACTGACCTTAGCCAAACTCCGAATGCCGGTAAGTGAGAGCGCGGCAGTGAGACTGTGGGGGATAAGCTCCATGGTCGAGAGGGAAACAGCCCAGAGCATCGACTAAGGCCCCTAAGCGTACGCTAAGTGGGAAAGGATGTGGAGTCGCAGAGACAACCAGGAGGTTGGCTTAGAAGCAGCCACCCTTGAAAGAGTGCGTAATAGCTCACTGGTCTAGTGATTCCGCGCCGACAATGTAGCGGGGCTCAAGCGTACCGCCGAAGTCGTGTCATTGCAGCATATACGGCCAACGCCGGCTGTGATGGGTAGGGGAGCGTCGTCTGCCGGGTGAAGCGGCACTGGAAGGTAGTCGTGGACGGTTGACGAGTGAGAATGCAGGCATGAGTAGCGATACACACGTGAGAAACGTGTGCGCCGATTGACTAAGGGTTCCTGGGTCAAGCTGATCTGCCCAGGGTAAGTCGGGACCTAAGGCGAGGCCGACAGGCGTAGTCGATGGATAACCGGTTGATATTCCGGTACCCGCTGTGAAGCGTCAAACATCGAATCCAGTGATGCTAAGGCCGTGAAGCCGCCCTGATCTCTTCGGAGTTGAGGGGAGTGGTGGAGCCGCTGACCCGATCTGGTAGTAGGTGAGTGATGGGGTGACGCAGGAAGGTAGTCCAGCCCGGGCGGTGGTTGTCCCGGGGTAAGGGTGTAGGCCGTGCGATAGGCAAATCCGTCGCACATAAGGCTGAGACCTGATGCCGAGCCGATTGTGGTGAAGTGGATGATCCTATGCTGTCGAGAAAAGCCTCTAGCGAGTTTCATGGCGGCCCGTACCCTAAACCGACTCAGGTGGTCAGGTAGAGAATACCGAGGCGTTCGGGTGAACTATGGTTAAGGAACTCGGCAAAATGCCCCCGTAACTTCGGGAGAAGGGGGGCCACAACCGGTGATGAGTCTTGCACTCTGAGCTGGGGGTGGCCGCAGAGACCAGCGAGAAGCGACTGTTTACTAAAAACACAGGTCCGTGCGAAGCCGTAAGGCGATGTATACGGACTGACGCCTGCCCGGTGCTGGAACGTTAAGGGGACCGGTTAGCTCCATTTCGGTGGGGCGAAGCTGAGAACTTAAGCGCCAGTAAACGGCGGTGGTAACTATAACCATCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGCGTAACGACTTCTCGACTGTCTCAACCATAGGCCCGGTGAAATTGCACTACGAGTAAAGATGCTCGTTTCGCGCAGCAGGACGGAAAGACCCCGGGACCTTTACTACAGTTTGATATTGGTGTTCGGTTCGGCTTGTGTAGGATAGCTGGGAGACTGTGAAGCCTGGACGCCAGTTCGGGTGGAGTCGTCGTTGAAATACCAGTCTGGTCGTGCTGGATGTCTAACCTGGGTCCGTGATCCGGATCAGGGACAGTGTCTGATGGGTAGTTTAACTGGGGCGGTTGCCTCCTAAAGGGTAACGGAGGCGCCCAAAGGTTCCCTCAGCCTGGTTGGCAATCAGGTGTTGAGTGTAAGTGCACAAGGGAGCTTGACTGTGAGACCGACGGGTCGAGCAGGGACGAAAGTCGGGACTAGTGATCCGGCGGTGGCTTGTGGAAGCGCCGTCGCTCAACGGATAAAAGGTACCCCGGGGATAACAGGCTGATCTTCCCCAAGAGTCCATATCGACGGGATGGTTTGGCACCTCGATGTCGGCTCGTCGCATCCTGGGGCTGGAGTCGGTCCCAAGGGTTGGGCTGTTCGCCCATTAAAGCGGTACGCGAGCTGGGTTTAGAACGTCGTGAGACAGTTCGGTCCCTATCCGCTGTGCGCGTAGGAGTCTTGAGAAGGGCTGTCCCTAGTACGAGAGGACCGGGACGGACGAACCTCTGGTGTGCCAGTTGTCCTGCCAAGGGCATGGCTGGTTGGCTACGTTCGGGAGGGATAACCGCTGAAAGCATCTAAGCGGGAAGCCTGCTTCGAGATGAGGACTCCCACCCACTTGATGGGGTAAGGCTCCCAGTAGACGACTGGGTTGATAGGCCGGATCTGGAAGCACGGTAACGTGTGGAGGTGACCGGTACTAATAGGCCGAGGGCTTGTCCTC
->MJAT01000005.1/39405-39606 Firmicutes bacterium MLFW-2 MLFW-2_Contig_13_85X, whole genome shotgun sequence. 
-GACAAGGCTACGATAAGGAAAGTAAAAAACGGAGCATTACAGAGAGTGGGCAAACAGCTGAAATTGCTTACATGTTGAAGTTTTTGAAAATGCACCTTGGAGCCGTGCAGAATGATTCTGCAACGGGGAAACCCGTTATTCGTTTGAGTGATGCAAAGGACTTTGCATAATCAGAGTGGAACCACGAGAAATCGTCTCTGTT
->LBSQ01000033.1/4164-6256 Parcubacteria bacterium GW2011_GWA2_37_10 US35_C0033, whole genome shotgun sequence. 
-GAGATCTTTGGAAAACACCATTAGGTGGATAACTAGGTTTAGTTTACTGATGAAGGACGTGGCAAGCTGCGAAAAGTCTTGGCTAGGCGCATGCAGCCTTTGAACCAAGAATTTCTGAATCAGACTTCTGAATCTCTTCGGAGATATGTTGGAAACAACAGGGAACGCAGGGAATTGAAGCGTCTTAGTACCTGCAGGAAAAGATATCAATAGATATGCTGAAAGTAAGGGCGACCGAAATCAGCAAAAGGCAAACTGAATCTGTTATTGAAAAATAACAGAGATGTGGTGTTTTAGGCTAATATTTAATCTTAACCAAAAGACCTGAAGTTTTCTGGAAAGAAACACTTTAAAGGGTGATAGTCCCGTAGGGGAAATTTGGAAAGATTGAGTTAGTACTAGAGTAGTGCTTACTGGATACTAAGCATGAATTTGGGAGGCATTAACTCCTAACTTTAAATATAAACTAAGTCCGATAGCACATAAGTACTGTGAAGGAAAGTTGAAAAGAACTTTTAATCAGGAGTTAAAAGACTTGAAACCTAATGGTAATAGAATATTACGGCTCTTAGGAGTTGTAATGTACGTTTCGAATAACGGACTAGGAAGTGTATTTGAGTGGCGAAGATAATCTTAATATTAGAGTATCTAAAGGGAAACCAATTTTCCGCAATTTATGAGGGAAAAGGTATGAAAATGCCTTTGAGTCACTTGAGTACGACCCGAAACCAGGCGATCTATCCTAGAGCATGGTGAAGTGAGATTTAAAATCTTATGGAGGCCAGAAGAGATACTACGTGCATGTGTTCTTCTGACTTTAGGATAGGGGTGAAAAGCCAATCGAGCCTGGTGATAGCTGGTTCCTGCTGAAATAGGCCGTAGTCTAGTGTTAGAAGAGATAACTAAGATTGTAGAGCTACGGATAGAGAGTTTAGGAGGAGAAATCCTTCGGCTTTCTGTCCAACTCCAAATGTTTTAGTATCGTAGAATCTAATAAACGGGGATGCGGGGTAAGCTCGTATTCCAAGAGGGGAACATCCCAGACCATAGTTAAGGTCCCTAAATGTTAGTTAAGTGTGAACGGGTGAAAGGTGTTCATAACCATAGACAGAGGGGAGGTTTGCTTAGAAGCAGCAATCCTTTAAAGAAAGCGTAACAGCTCACCCTTCAAGGTTATGTGCCCTGAAAATGGACGGGACTAAACTAACTACCGATACTATGGACTTCTTATAAAGAAGGGGTAAGCAGGCATTCTATTAGGGCAGAAGTTTTTTTGTAAAAGAAAATGGACCTAATAGAGAAGAGAATCCTAGTGGTAGTAGGATCTATATATGGTGAGAATCCATATTACTGAAAGGGCCAGGGTTTCTTAGCAATAAAGTTTAGCTAAGAGTAAGTCGATCCTAACTCAGTTCCTAACAGAAACTGGGGAAAGGGCAAAAGGTTAAGATTCCTTTACTATTTAGGTACTTATGGTAACATAAGTTTGATCTCTGACATTTTGGGTTAGATTGACATTTACTATCGTAAATGCTAATTAGAATAAATCAATAGAGTACTGTAATGGTGAGAAATTGATTAAATCTAAGAATGGTTGGCCTTATGGCTGATTTGATTGATACCTGGGATTGATAAAAAGGAGATTAAACGGATCCTAAATAATCGTACCTAGAACCAACACTGGTGCCCCTAGGTGAGAAGCCTAAAGTATTAGGGTTTAATCTAGTTGAGGGAATTCGGCAAGTTGGCTCTGTGACTTCGGTTTAAAGAGTCCCTGGGATTGTAATCGTATGATTGCAATTTCAGGGTGCAATGACAAGGGACGTCCGACTGTTTAACAAAAACGTAACTTATTGCTAATCTGTAAAGATTTATATAATAAGTGACATCTGCCCAGTACTAGTATCTCAAACTTCTTTTCAAGGAAGCTAAGGACTAGCAAACGGCGGGAATAACTGTAATTCTCTTAAGGTTAATTCGTAGCTTTAAGACCCAAAGTTAAACAGAATAACTAAAAAGATTGGGATAATAATTTGGCTATATGCTGGAAAGTCCGGGTATCTCACACTACCATAAATTTTATTAAGGTATAA
->MTYJ01000241.1/79877-79597 Hypsibius dujardini strain Z151 scaffold0241, whole genome shotgun sequence. 
-GCTTTGCATTGAGAGCAGACTGTGTGACCTAAAAGGCGAAAAAATGGGAGCACGCTGTAAGGATAAATAGGAACAGACAGGGGCATTCGTATTGCGGCGTTAGATGTGCAATTCTTGAATCATCATCGCAAGACGCGCTCCTGCGAAAGCATTTGCCAAGAATGATTTCATCAATCAAGAACGAAAGTTGGAGGCTCGAAGGCAATCAGATATCGCTCTGGTTCTAACCGTAAACGATGCCCACAGCACAAGTGCCCACAAGTTCAGCACAAATTTTGGCT
->CM001380.3/48396693-48396738 Felis catus isolate Cinnamon breed Abyssinian chromosome A3, whole genome shotgun sequence. 
-GCACAGGTTCCACTAGGAACTACACACATAATTTGGGAACATTTGG
->GK000025.2/32398425-32398628 TPA: Bos taurus chromosome 25, whole genome shotgun sequence. 
-GCGGCTTAATTTGACTCAACACGGGAAACCTCACCCGGCCCGGACACGGACAGGATTGACAGATTGATAGCTCTTTCTCGATTCCGTGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGCGATTTGTCTGGTTAATTCCGATAACGAACGATTCATGTGGCATGCTAACTAGTTACGCGACCCCCGAGCGGTTTTACCTGC
->CP003316.1/1347629-1347568 Pyrobaculum oguniense TE7, complete genome. 
-AACACCCTGGGCAACACCCCTGTAGGGGGGGCGAATGAGCCTGGTGGGTTACCCCGGCCATA
->KI628545.1/15615-15455 Sclerotinia borealis F-4128 unplaced genomic scaffold scaffold00005, whole genome shotgun sequence. 
-GGCGCGATAGTTCAATGGTAGAACATCCTCATCCAACTCAGATCACCCCTTCCACAATTTCAGGAGTGCAGTTATGCGAATAACTGCACTATGTTGTATATTAGGAAGATGGTGGTCTTTGGATAGTGAGGGAGATGGAGGTTTGATTCCTTCTTGTGCCA
->URS0000D6D378_443218/1-79 Hoyosella subflava DQS3-9A1 hya RNA 
-TGCGTCACGCAAGTGGGCCGAGGGTCGACTCCTGTGACGAAGGGGCTTCGAGGCACTGTCCCGCCCCGGAAAGTGGCAA
->BDFN01002532.1/3650-265 Ipomoea nil DNA, scaffold: scaffold2532, cultivar: Tokyo-kokei standard. 
-CGACCCCAGGTCAGGCGGGATTACCCGCTGAGTTTAAGCATATCAATAAGCGGAGGAAAAGAAACTTACAAGGATTCCCCTAGTAACGGCGAGCGAACCGGGAACAGCCCAGCCTTAGAATCGGACGGCCTTGCGTTCGAATTGTAGTCTGGAGAAGCGTCCTCAGCGGCGGACCGGGCCCAAGTCCCCTGGAAAGGGGCGCCGGAGAGGGTGAGAGCCCCGTTGTGCCGGACCTGTCGCACCACGAGGCGCTGTCTACGAGTCGGGTTGTTTGGGAATGCAGCCCCAATCGGGCGGTGAATTCCGTCCAAGGCTAAATACGGGCGAGAGACCGATAGCGAACAAGTACCGCGAGGGAAAGATGAAAAGGACTTTGAAAAGAGAGTCAAAGAGTGCTTGAAATTGTCGGGAGGGAAGCGGATGGAGACCGGCGATGCGCCCCGGTAGTATGTGGAACGGTGAGAGCCGGTCCGCCGATCTACTCGGGGCGCAGACCAGCGAGGATTCGGGGGGCGGCCAAAGCCCGGGCCTTTGATACGCCCGCGGAACGTCGTCTCTCGGATCGTGGGAAGCAGCGCGCGCCCCTGGCGTGCCTCGGCACCTGCGCGCCTCCGGTCGCTGGCCTGTGGGCTCTCCATTCGACCCGTCTTGAAACACGGACCAAGGAGTCTGACATGTGTGCGAGTCAACGGGCGAGTAAACCCGTAAGGCGCAAGGAAGCTGATTGGCGGGATCCCCTCACGGGGGTGCACCGCCGACCGACCCTTGATCTTTTGAGAAGGGTTCGAGTGCGAGCATACCTGTCGGGACCCGAAAGATGGTGAACTATGCCTGAGCGGGGCGAAGCCAGAGGAAACTCTGGTGGAGGCCCGCAGCGATACTGACGTGCAAATCGTTCGTCTGACTTGGGTATAGGGGCGAAAGACTAATCGACCGTCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGAGCTGGCGCGAGAGTTCTATCGGGTAAAGCCAATGATTAGAGGCATCGGGGGCGTAACGCCCTCGACCTATTCTCAAACTTTAAATAGGTAGGACGGCGCGGCTGCTTCGTTGAGCCGCGGCCACGGAATCAACAGCTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGGAAGCCGGGTTACGGTGCCCAACTGCGCGCTAACCTAGATCCCACAAAGGGTGTTGGTCGATTAAGACAGCAGGACGGTGGTCATGGAAGTCGAAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTTAAGCGCGCGACCCTATACCCGGCCGTCGGGCAAGAGCTAGGCCCCGATGAGTAGGAGGGCGCGGCGGTCGCTGCAAAACCTTGGGCGTGAGCCCGGGCGGAGCGGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTGAAGGCCGAAGAGGGGAAAGGTTCCATGTGAACGGCACTTGCACATGGGTTAGTCGATCCTAAGGGTCGGGGGAAGCCCGACAGACAGCGCGTTTTGCGCGTGCGCCGAAAGGGAATCGGGTTAAAATTCCTGAACCGGGACGTGGCGGTTGACGGCAACGTTAGGGATTCCGGAGACGTCGGCGGGGGCCTCGGAAGAGTTATCTTTTCTGTTTAACAGCCTGCCCACCCTGGAAACGGCTCAGCCGGAGGTAGGGTCCAGCGGCTGGAAGAGCACCGCACGTCGCGTGGTGTCCGGTGCGCCCCGGCGGCCCTTGAAAATCCGGAGGACCGAGTGCCGTCCACGCCCGGTCGTACTCATAACCGCATCAGGTCTCCAAGGTGAACAGCCTCTGGCCAATGGAACAATGTAGGCAAGGGAAGTCGGCAAAATGGATCCGTAACTTCGGGAAAAGGATTGGCTCTGAGGGCTGGGCACGGGGGTCCCAGTCCCGAACCCGTCGGCTGTTCGGCGGACTGCTCGAGCTGCTACCGCGGCGAGAGCGGGTCGCCGCGTGCCGGCCGGGGGACGGACTGGGAACGGCTCTTTCGGGGCCTTCCCCGGGCGTCGAACAGCCAACTCAGAACTGGTACGGACAAGGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGATGGTCCCTGCGGATGCTAACGCAATGTGATTTCTGGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTGTCTACTATCCAGCGAAACCACAGCCAAGGGAACGGGCTTGGCAGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTGAGAGGTGTAGGATAAGTGGGAGCCGAAAGGCGAAAGTGAAATACCACTACTTTTAACGTTATTTTACTTATTCCGTGAATCGGAGGCGGGGCATTGCCCCTCTTTTTGGACCCAAGGCTCGCTTGCGGGCCGATCCGGGCGGAAGACATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGCTCAACGAGAACAGAAATCTCGTGTGGAACAGAAGGGTAAAAGCTCGTTTGATTCTGATTTCCAGTACGAATACGAACCGTGAAAGCGTGGCCTAACGATCCTTTAGACCTTCGGAATTCGAAGCTAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCACCAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGACAGTGTCGCAATAGTAATTCAACCTAGTACGAGAGGAACCGTTGATTCGCACAATTGGTCATCGCGCTTGGTTGAAAAGCCAGTGGCGCGAAGCTACCGTGCGTTGGATTATGACTGAACGCCTCTAAGTCAGAATCCGGGCTAGACCGACGCATGCGCTCGTCGCCCGTTTGCCGACCCGCAGTAGGGGCCATTTGGCCCCCAAAGGGCACGTGTCGTTGGCTAAGCCGTCGTGGCGGAAGGGTCACGGTGGCCGCCTTGAATTACAATTCCGATCGAGCGGCGAGCTGAATCCTTTGCAGACGACTTAAATACGCGACGGGGTATTGTAAGGGGTAGAGTGGCCTTGCTGCCACGATCCTCTGAGATTCAGCCCTTTGTCGCTCCGATTCGT
->FR877557.1/2581256-2582181 Salmonella bongori NCTC 12419, culture collection SGSC SARC11, complete genome 
-ACCTGAGCTTCCATTTCACGGTCAGACAGGCCACCGCAGATCTGGATAATACGGTCAGACAGCGTCGATTTACCGTGGTCAATGTGAGCAATGATCGAAAAGTTACGTATGTTCTTCATAGAGATAAATTATTATGCCTTACGCCTGGTTGACCAGACTTTAGAGGTCGCTGTTCTGAGCTTAACGTCTGTTTTAACTGAAACGCCGCATTCTACACTACAACGCTAAGGCGAGGAAATGTTCATAATGTAAGGAGAGCGGGAACTGGCAAGCGTCTCACTTTTTACGTAAGTCACTGTAACGCCGAAAAAGCCCCTGATAGCGCAAGCTTATCGGCCCGACATCTCCTGCATGGCAGGAAAAAATGACCTTAGCAGACCAGCTAAACGCAGCGCTATCCGGCACAGCGTCTACTGGCGCGTTTCGATTGATGTGGTTTCGACGCGAACAAGCTCGGACGGGAGGGCAACGCTTAAAATCACCGGTTGCCAGGTATCGCGCTCCGCCAGTTTCCGGGAATAGCCTCGGGCAAGCAAAAAACCGCCAACGCCACCTAAAACAGCGCCGCTTAATGCCGCAAGGTCAGATCCAAACAATACCTGGAAAAGCACTGCAAAGAGAAATAACCCCGCTAAAGGCGACATATAGACCAACAATGCCGACCCTAAGAGGCTTTTTTCGGCGATGCCAAGCTCAACTTTCTGCCCCGGCGACAGCGGCTCCACGCTTGGCACCACAATTGTATGAGTCGTTTGCGGCCCTAATTTATTCAGCACGCGGCTGCCGCATCCCGCCCGGGAGGCGCAGTTGCTGCACGATGTTTTAACATCACAACTCACGACCGCCTGGCCATTCCGCCAGGAGACGACCGTCGCCCACTCTTTAATCATTGTACTGCCCTGAACTTGATACTGTCTGCAATACGC
->MFEL01000009.1/24516-24224 Candidatus Doudnabacteria bacterium RIFCSPHIGHO2_01_FULL_46_24 rifcsphigho2_01_scaffold_3549, whole genome shotgun sequence. 
-ATAAATGCGTATTAGTTTGCGCAAATTGCCACAGAGAATTACATGCAGGAATATCGCAGCTTCCGAGCGAAAGCTCGGTTGAAAAACGAGGTGAATTCGGGGAAGTCCAGCCCCACTTTTGAAAAAAGTGGAGCGGGATAATCCCGAGCCAAGCCCAGCCCCGGTTTTGAAAACTGGAGCTGGGAAGGTGTAGAGACTATCTCGAAAGAGAGTAGCCCCCGCCGCAGGCGAGGTCGAAGCGCCTCGGACCTTAAATGGTCATGATATAGTCCATCCCTAGAAGCAATTTTAGG
->AY765264.1/10602-10676 West Nile virus strain Rabensburg isolate 97-103, complete genome. 
-CAGTTGTCAGACCACACGCAAGTGTGCTACTCTGCGAAGAGTACTGTCTGCGTTAGAGCCCCAGGAGGACTGGGA
->CM007898.1/80153181-80153635 Helianthus annuus linkage group 9, whole genome shotgun sequence. 
-AAAAGGCGTAGCAAAAAGCTGTATTTTAACCATTCAAAGTAAGATATTCGAGAGCAAAAAGGTTGATACATTTTGAAGCAGCCAGGGCTCTTGAAAAGGAGGGACGCCTTCGGGAACGCGGACACAGGTGGTGCATGGCTGTAGTCAGCTCGTGCCCTAAGGTGTTGGGTTAAGTCCAGCAACGAGCGCAACCATCGTGTTTTGTTGCCATCATTGAGTTTGAAACCCTGAAGAGACTGCCGGTGATAAGCCGGAGGAAGGTGAGGATGACGTCTAGTCAACATGCCCCTTATGCCCTGGGCGACACACGTGCTACAATGGCCGGGACAAAGGGTCGCGATCCCGCGAGGGTGAGCTAACTCCAAAAACCCGTCCTCAGTTCGGATTGCAGGCTGCAACTCGCCTGCATGATACCGGAATCGCTAGTAATCGCCAGTCAGCCATACGACGTACTT
->CM000803.1/27767415-27767313 Oryctolagus cuniculus chromosome 14, whole genome shotgun sequence. 
-ATCAATTCTCCTTCTTTTGGCTAAGATCAAGTGTAGTATCTGTTCTTTTCAGTTTGAAATGTGTCATCAAATTACTGATTTCCCTCTTCAGTTCTTACCCCTG
->CM000014.3/49188721-49188634 Canis lupus familiaris chromosome 14, whole genome shotgun sequence. 
-TGGTCGATGATGATTCCCACATACGCATTCTTTGGAAGTCTGAACAAAATGAGTGAGGGGGAAAAAAAAAGAATCACAATTCTGCCCT
->MGNC01000058.1/1340-1465 Chloroflexi bacterium RBG_13_60_13 RBG_13_scaffold_216383, whole genome shotgun sequence. 
-TCTCCGAAAGGGCAAAGGCACGGGAAACCGTGTCGGCGCAAAGCCGCGGATCTAAGGTCTCCCGCTTCGACAGGGACGTTCACAGCGGCAGTAGGAGCGAGAGACTATGGTGGCCGGGCTACCGAA
->CM001394.3/25602295-25602396 Felis catus isolate Cinnamon breed Abyssinian chromosome F1, whole genome shotgun sequence. 
-GCCGAGTAATACTCCATTTTGTGTGTGTGTGTGTGTGTGTGTGTGTGTATATATATATATACACACACACACACACACACACACACACAAAATGTGTATATA
->URS0000D67331_12908/1-219 unclassified sequences RT-2 RNA 
-CGAGGTCATATGGAGTAGCGAAAGTGAAAGACGACCTTCGCAAAAGGAGATATACTTCCCTGGGTGAAAATCCTTAAAACTGCCTTACGACGATCACACACGGACGCTGCTTGCATGGCGAAGAATTGCGCTACCTTCGTTTCATGTGTGGGATCAAAGTAGTTTAGATGCGCACCTACAAAACAACTATGCGAAAGGCGAAAACTTATTATGACAAGC
->LQHI01000015.1/6633-6747 Hadesarchaea archaeon DG-33 contigWOR1_52_54_12788, whole genome shotgun sequence. 
-GCGGGGATAACTCAACCTGGGAGAGTGTCGGTCGTTCGAGTACAATCGAACGGGCAAAACTGAAGTTCCCAGAATAGATATCCGAATGTTGGGGGTTCAAATCCCCCTCCCCGCA
->AFCW01000383.1/1-68 Salmonella enterica subsp. enterica serovar Urbana str. R8-2977 Contig383, whole genome shotgun sequence. 
-CACACACTTAATTAATTAAGTGTGTGNNNGCCGCAATTCAGCATTAGTAACCAAGGGGTCTGCTCGTG
->AAQR03179128.1/9880-9794 Otolemur garnettii contig179128, whole genome shotgun sequence. 
-ATCCTTTTGTATTTCATAAACTACTGACTGTGTTTTCACACTTATGAGCAAACCTTGTTAGGATGTGGATACATTACCTGTCTGATG
->CCCW010025129.1/8929-12059 Brassica napus, WGS project CCCW01000000 data, contig: 19059 
-CGACCCCCAGTCAGGCGGGATTACCCGATGAGTTTAAGAATATCAATAAGCGGAGGAAAAGAAACGAACAAGGATTCCCTTAGTAACGGCGAGCGAACCGGGAAGAGCCCAGCTTGAAAATCGGACGTCTTCGGTGTTCGAATTGTAGTCTGGAGAATCGTCCTCAGCGACGGACTGGGCCCAAGTTCCTTGGAAAGGGGCGCCAGAGAGGGTGAGAGCCCCGTCGTGCCCAGACCCTATTGCACCACGAGGTGCTGTCTACGAGTTGGGTTGTTTGGAAATGCAGCCCCAATCGGGCGGTAAATTCCGTCCAAGGCTAAATATGGGCGAGAGACCGATAGTGAACAAGTACCACAAGATAAAGATGAAAGGACATTGAAAAGAGAGCCAAAGAGTGCTTTAAATTATCGGGAGGGAAGCGGATGGGGCCGGCGATTCGTCCCGGTCGGATGCGGAACAGAGCAATCTCGTCTACCAATCTATTTGTGGCGTGGACTTACGCGGATTAAGGTGGTGACCTAAGCCCAGGATTTTGTTACACTTGCGGAGACGTCGCTGCCTTGATCGTGGTCTGCAGCTCGCGCCTCACGGCGTGCCTCGGCATCTGCTTGCTCAGGGCGTCGGCCTGTGGGCTCCCCATTTGACCCGTCTTGAAACACTGAACAAGGAGTCTGACATATGTGCGAGTCAAAGGGTGAGTAAACCCATAAGGCGCAAGGAAGCTGATTGGATGGATCCCTCACAGGTGCACAGCCGACCGACCTTAATCTTCTGAGAAGGGTTCGAGTGTGAGCATGCCTGTCAGGACCCGAAAGATGGTGAACTATGCCTGAGCGGGGCAAAGCCAGAGGAAACTCTGGTGGAGGCCCGCAGCGATACTGACGTGCAAATCGTTCGTCTCACTTGGGTATAGTGGCGAAAGACTAATTGAACCATCTAGTAGCTGGTTCCCTCTGAAGTTTACCTCAGGATAGCTGGAGCTGGAAACGAGTTCTATCGAGTAAAGCCAATGATTAGAGGCCTCGGGGATGCAATGTCCTCGACGTATTCTCAAACTTTAAATAGGCAGGACGGGGTGGCTGCTTTGTTGAGCCATCCCACGGAATCGAGAGCTCTAAGTGGGCCATTTTTGGTAAGCAGAATTGGCGATGCGGGATGAACCAGAAGCCGGGTTATGGTGCCCAACTGCGCGCTAACCTAGAACCCACAACTCACCTGCCAAATCAACTAGCCCCAAAAATGGATGGCGCTGAAGCGCCCAACCTATACCTGGCCGTCGGGGCAAGAGAGAGGCCTCGATGAGTAGGAGGGCGCGAGCCCGGGCGGAGCGGCCATCGGTGCAGATCTTGGTGGTAGTAAGGGAAATGTTCCATGTGAACGGCACTTGCACATGGGTTAGTCGATCATAAGAGTCGGGGGAAACCCGTCTGATAGCGCTCTTCAAAAGGGGATCCGGTTAAAATTTCGGAACCGGGACATGGCGGTTGACGGCAACGTTAGGGAGTCCAGAGACGTCGGCGGGAATTCCGAAAAGAGTTATATTTTCTGTTTAACAGCCTGCCCACCCTGGAAACGGCTCAGACGGAGGTAGGGTCCAGCGGCTGGAAGAGCACGGCACGTGGCGTGGTGTCCGGTGCATTCTCGGTGGCCCTTGAAAATATGGAGGACCGAGTGCCTCTCACGCCCGGTTGTACTCATAACCGCATCAGGTCTCCAAGGTGAACAGCCTCTGGTCGATGGAACAATGTAGGCAAGGGAAGTCGGCAAAATGGATCCGTAACTTCGGGAAAAGGATTGGCTCTGAGGGCTGGGTTCGGGGGTCCTAGTTCCGAAATTCTCGACTGTTGGTGGGCTGCTTGAGCCGAACAGACCGCCTCGTGTCAGCCGGGGGATGGACTGGGAACGACTCTTTGGGGAGCTTTTCCCGGGCGTCAAACAGCCAACTTAGAACTGGTACGGACAAGGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGATGGTCCCTGCGGATGCTAACACAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCACCCAAGCGTGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATAAGTGATGCGCATGAATGGATTAACGAGATTCCCAGTGTCCATGTTTACTATCCAGCAAAATCACATCCAAGGGAATGGGTTTGGCAGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTCACTCTAGTCCGACTTTGTGAAATGACTTGAGAGGTGTAGAATAAGTGAGAGCTCCGGTGCAAGTGAAATACCACTACTTTTAACGTTATTTTACTTACTCCGTGAATGGGAGGCGGGGTACCAACCCCTTCTTTTAGACCCAAGACTCGCTTCGGCGGGTCGATCCGGGCAGAGGACATTGTCAGGTGGGCAGTTTGGCTGGGGCAGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGTTCAACGAGAACAGAAATCTCGTGTGAAACAAAATGGTAAAGCTCGTTTGATTCTGATTTTCAGTACGAATACGAACCGTGAAAGTGTGGCCTATCGATCCTTTAAACCTTCGGAACTGGCTTGTGGCAGCCATGCGTTCATAGCGATGTTGCTTTTTGATCCTTCCATGTCGACTCTTTCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCCACCAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGATCGTGAGACAGGTTAGTTTTACCCTACTGATACCCGCATCACAATAGTAATTCAACCTAGTACGAGAGGAACCATTGATTCGCACAATCGGTCATCGCGCTTGGTTGAAGAATAGTCAGTGGCGCGAAGCTACCGTGCGTTGGATTATGACTGAACGCCTCTAAGTCAGAATCCGGGCTAGAAGCGACGCATGCGCCCGCCGCCCGATTGCCGACCCTCAGTAGGAGCTTCGGCTCCCAAAGGCACGTGTCGTTGGCTAAGTCCGTTTGGTGGAAGCGCCGTTCGGACCGCCTTGAATTATAATTACCACCGAGCGGCGGGTACAATCCTTTGCAGACGACCTTTGTCGCTAAGATTCGA
->LZPO01045535.1/8544-8610 Neotoma lepida isolate 417 scaffold_13965, whole genome shotgun sequence. 
-GCTGGGGTAGTTCAAAGGCAGAACATTTGCCTGGTATGCATGAGAGCCTGGGGGTCATTCCCCAGTA
->AHJH02011678.1/302-41 Hammondia hammondi strain H.H.34 contig09893, whole genome shotgun sequence. 
-AGCGACAATCCTACCACTTAGAGTTGTCGGATCACTAAGACCGACTTTCGTCCTTGTTTAAGTAGTTACTCTCACAATCAAGCCTTTTACGCAACAGTGTTTTAAAAGATAATTATTGTCTAAAAAAAAACTCATATCTAATTAGCTAGTTGGTGAAGTAATAGTTTTACCAAGGCGAAGATTAGTAGCTGCCTTGAGAGGGGAAACAGCCACATAGAGATTGAAATACAGCTCGGCTTATCACACAGTAGGGTAGCTGCAG
->MTEO01000012.1/38100-38064 Desulfobulbaceae bacterium A2 Ga0073110_1012, whole genome shotgun sequence. 
-GTTTTCCGGGGCGCACGCGCCCCGGCCTCTTTGAAGC
->CP003050.1/1069873-1069696 Halovivax ruber XH-70, complete genome. 
-AAGTACCTCTGAGTCCGTCGGACGATACGTCCGCGGATAGGAGTAACGGCTGGTTGGCGCAGCCATCGACTCACCTGTTCGACAAGTCAACGGGTGGATTCCACCCACAAGAACAGGTTGTGTCGTAGACCTTAATATCCCAACTGCGGTCGGGAATCCTCGCCCTTCAGGACGGGAG
->JMFI01080173.1/8540-8495 Phalacrocorax carbo contig80173, whole genome shotgun sequence. 
-AAAGAGGTCTTCCTAAAGACCACACCAGCCTTTGAAGCACACTTTA
->LDZF01000115.1/1-68 Pluralibacter gergoviae strain JS81F13 contig_136, whole genome shotgun sequence. 
-AAACCCCTTTTGATTTGTTAAAACAGATTGCGGTCTGGCAACTGCAACGTTTAACAAGAAATCAAAAG
->AWGX01000534.1/1451-1535 Smithella sp. ME-1 CONTIG_7599, whole genome shotgun sequence. 
-TAGTAAATTTATTTACTTGACAAAAAAGTAAAGTTTTATTAAATAAAAATCGTTCGCTTGGATCCGTAAGGACTGAGACGAGAGG
->JMFL01092903.1/16205-16066 Opisthocomus hoazin contig92903, whole genome shotgun sequence. 
-CTGCATTCTTAACCCTCCTGGCAGCTCTGTTTATTAGCTTCCAGGATAAGAATGAATGCCAGAGAAAACTGTTGATTAATCCAAAATGAAGAGCTCTCCTCCCGTGGCTCTCCATTATTTCACGTCTTCAACATTGATTT
->JJRE01013351.1/703-1 Phoenicopterus ruber ruber contig13351, whole genome shotgun sequence. 
-AAAACAAGCGAGGTAGTGGTATTTCACCAGGGCCGGGAATGGCTAGCATGCAGGGAAAACAACTGGGCTCGGTAACACGACGCGTCATACGCCTGCCGAAAGACACCAATTGCTGGACTCGTCTAAGGTGGACAGGTCCCCTATGCTTAACCTGGAAAAGGAACATGTATAATTTTATATATGTTTGCTAAATAGCCAAATGCCTCGTCATCTAATTAGTGACATGCATGAATGGATGAACAAGATTCCCACTGTCCCCACCTACTATCCAGCGAAACCACAGCCAAAGGAACGGGCTTGGCGGAATCAGCAGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCTGGCGCTGGGAAGAGACATGAGAGGTGTAGAGTAAGTGGGAGGCCGGGTGCACGCTCAGCAGTGCGACCTGCCCACCAGCACCCCGGCCATCGGTGAAATACCACTACTCTGGTCCTTTTTTCACTTACCCGGTGAGGCGGGGGGGGGCAAGCCCCAAGGGGGGCTCTCACTTCTGGCACCAAGCGCCTGGTGTGCACCGGGAACAGTGGCAGGTGGGGAGTTTGACTGGGGCAGTACACCTGTCCAAGCGTAAGGCAGGTGTCCTAAGGCAAGCTCAGAGAGGACGGAAACCTCCTGCAGAGCAGAAGGGCAAAAGCTCACTCGATCTTGTTTTTTCAGTATGAATACAGCACACG
->MERU01000008.1/32885-32784 Burkholderiales bacterium RIFCSPHIGHO2_01_FULL_63_240 rifcsphigho2_01_scaffold_62, whole genome shotgun sequence. 
-ACTTTCGAGGAGCGTTGCAAGGCCCGTCCCGTCGTTGAACACGGCGCGAACCGCTGGCCCCAGGCTCGAAAGCTTCTCCTTTTGCAACGGCGCTCACCCGCA
->FQTV01000009.1/145137-144950 Bacteroides luti strain DSM 26991 genome assembly, contig: Ga0131163_109 
-TATCTTTGTTTCGGTTTTGGTAACAAAGCTTATGCTTTAGGAGAAAAGGGAATACCGTGAAATCCGGTAACAGTACCCGCTGCTGTGATTCTCGAAGAACTTGAGTAACAAGCCACTGCATTTATTTGTGGGAAGGCACTTTAAGAGAGAGATAAGTCAGAAGACCTGCCAGAACTACACATTATAGA
->HG764815.1/187153-187284 Tetrasphaera australiensis Ben110 genomic scaffold, 2552_scaffold1 
-CGCGTTTTCGCTCAGGCGGAGCTCGACCGCCGACTCAAGTGATCGTGGCCTATATCGACGCCTATCGGGGTCAGTTCGGCGCCCATGCCGATCTGTGCCGTGCTGACCGAGCACGGCATCACGATCGCGCCG
->MIJY01000003.1/25265-25023 Enterococcus termitis strain LMG 8895 11, whole genome shotgun sequence. 
-CAAAACACATATTCAGAACAAGTAGTCATCGTTCATTTCCTGACAGAGACTTTTTCATTCGCTGAGAGAAAAAGCTGGAAACCGTTGACGAACACATCTGTCTAGTCAGCTTCTGAATTTAGTAAGAAGCTGCGGCATTCTCCGTTATCAGAAAAGAATCTCTATTACTATTAGAGACTCTATGAGGTCACCATTGCGAAATCGTGACAAATTGAGGTGGAACCGCGAATCTTCGTCCTCTTG
->CM000999.2/135584192-135584306 Mus musculus chromosome 6, GRC primary reference assembly. 
-TGCTGAGTGCAGTTCCGGGCTGCTTCCATGTTCTGTTAATTAAACATTGAAATTGGCTGAGAGAGATGATTAAATGGAAAGTGTTATTCTGTTCATATACTGATAGCTCACATAT
->JXUM01069429.1/36725-36871 Aedes albopictus isolate Foshan contig69429, whole genome shotgun sequence. 
-TTCAGGCCATATCGAAGCAGGACAAAGGCCATTTCTTATGCCTGTTGTCCTGTCAAAAATTGGCCCAGAGTAAACGCTCCGTCGACGGTCATTGGAAGCCTTGACATCCGTGTGGTTTACCAATAACATATTTGGCGGTGTACAATA
->CM000999.2/123737012-123736886 Mus musculus chromosome 6, GRC primary reference assembly. 
-CCAGCTCCTAGAAGGGTTGCAAGTGTGGCTGCTGTGTCATTTCTGCATCAGGATGTGGCAGAGAAGAGAGAGACAAAAAAAAAAAAAGACCTTCAGTGTTCTGACCTATGATTAATAGCCTAACAGT
->AP012044.1/987471-987303 Oscillibacter valericigenes Sjm18-20 DNA, complete genome. 
-CGCTCAGATAGAGGCGCGAGGTTCATCAGTACCGCGAGCAGCCGGCAGGCAGCCGGCGCGGGAAAGGGGACATCGCCGAAGGGTTTCGGAGCTGCCTGCTCCGAGATACCTGGGCTGTCGGGGAATACCCGTCGGACTGTCACATTTTTTGTGAAGCGCTATCGATGGC
->ACPB03020461.1/16978-17135 Rhodnius prolixus Rhodnius_prolixus-3.0.3-473.8, whole genome shotgun sequence. 
-AGAGTCCTGGCGTCGAGGTTACCATGATCAACAAGGTGGTTCCTCCAGGGTGAGGTCTATTCATTGCACTAAGAATTGGCTGACCCCTGCGAATGTTCCAAAAAATATTTCTAATAGTAGAATTCATTAGTGCTATACTATTTTTGAAATAATATAAA
->AFYH01196721.1/7358-7251 Latimeria chalumnae contig196721, whole genome shotgun sequence. 
-ATGAGTCGGTGCATCCCCAAGAGGGGAGGTTGGGAGGGTATTGGTGTGGCTGTATGGAGTATCCCTAATACCCTCCCAACCTCCCCTCTTGGGGATGCACCGACTCAT
->KQ959571.1/48198-48573 Clostridiales bacterium KA00274 genomic scaffold Scaffold7, whole genome shotgun sequence. 
-GGGGATGTAAAGGCTTCGACAGGGTTGTTGAGATTGGAATAGCGGGTAGAGGATGCGCGTTGGCCTCTTTAAAAAACGGGCAAAAAATTTAGTTGCAAAAACTAATAGATTCGCTGTAGCTGCGTAAGCTTGGCGCACAAACTTGATGAATCTGCTAATTGAGTGATTGTGTTAGACTAGCAGACCTTGATCGTTAGAGGTCAAACTTTCAAATTTCAAGTTAAGCTTTGCCCTTGGAATTATCTATGAAGCTACTTTCATAAGCGATTGTTCAAAGTCTACCTTATGAGGGGAATTTAGAAAATTTGAACTGCACCCGGAGAAGTTCTGATTAAGGCGATTTTGGACACGAGTTCGATTCTCGTCATCTCCATTC
->CM000998.2/25188643-25188361 Mus musculus chromosome 5, GRC primary reference assembly. 
-GGATGTGAGGGAGATGTGGCTACATCTGTCACCCCACTGATTACCAGGGTTGATCACCTGCTTTGGCTAACCCGCCTCCCTCATCCTTCCACGTGTGCCCTTCTGGACTTTCCCTGAATAGAGGACGACCAGTCTTCAGTCAAGAGTACATGAGTAGATACATTCCCCTGCTAGAACCTCCCAACAAACTCTCAAGGGAGCTGAATTCTTATGCCACATGTCTACTACAAGATAGTATGCACATACACGGTAGGCAGGTGGGGCAGGGAGGGGCTTCTTTCGT
->AODH01000041.1/17134-17262 Brochothrix campestris FSL F6-1037 c41, whole genome shotgun sequence. 
-ATAACCTTTAACCTAGTCCAGAGAGACTAAGAAGGCATTGAATCGTATACAGGGGTAAAACTACCTTTGTAGAACAGTAGTTTGGCTACTGTTAAAAACGCTTATGCCCTCGCATAGGCGTTTTTTTTT
->GL010035.1/48904364-48904178 Loxodonta africana unplaced genomic scaffold scaffold_8, whole genome shotgun sequence. 
-TTGAACCGGTTCTTTCTGGTTCGACCCCCTGCTGAGATGTGAATTTCCACCCCAGATATACTGAATCAGAACCTACATTTTAACTATAATTTTAAAATTTTAACTATAATGTAGGTTCTGACTCAGTATATCTGGGGTGGAAATTTAAATTCTCAGCAGGGGTTCGAACCAGAAAGAACCAGTTCAA
->LQXD01000036.1/27026-26945 Anaerobacillus sp. NB2006 Ga0137927_1036, whole genome shotgun sequence. 
-AAAGAGCTATAACCGCTCATTAAAGGGTTTTGAAGTATTTGCTCTTAGCAAAACACCCCTCATGGCGAGTCTGAGTATATTA
->CGIH01000026.1/124551-124798 Syntrophomonas zehnderi OL-4 genome assembly, contig: OL-4DRAFT_scaffold-26 
-TAAAATGTGATGAACAGGACAAGTAACCTGCCGGTAACCTTGCAGGGAGGCCGTATCATGGACTGAAAGTATGGCCAGGGGAAAGCAGTTGAATTCACCTGGGAACAGTAAACTGAAACATAGATATCTTTTTACCGTCTATTCAGTAGGTTTAACCGCAGGTCGGCGTTAAAGACATCAAGTGAACCGGTTGCGTTTGACATCGGTTAATCGGGGTGGTACCGCGGAAGCAAGCTTTCGTCCCTTGG
->CP011382.1/3084471-3084633 Calothrix sp. 336/3, complete genome. 
-AAAATTAAATATACCAAGCCGGAGACAGCAGGTGTCCTTGACTTAAATATCCTGCCTAGGTTTGCACTCCATTTGTTCCATGAAGACTCATAGTGGTTTGACCATGGCAAAAAGAGATTTGTAAAACCCCGGCTTGGTATAGCTGGGGTTTATTAATTGGGGA
->MFFM01000041.1/12342-12480 Candidatus Edwardsbacteria bacterium GWF2_54_11 gwf2_scaffold_564, whole genome shotgun sequence. 
-AAATTGAATCTCCGATCCCGTTTTTCTAAAGCTTAAATGCCATGGATGACGGGACGGTTCCCCCGAAAAGGGCGGACAAGGGTAGGACTGGAAACGGTCTTGCCTCCCGTGTTTGGAAAGGAGAGGTTGCGATTAACTT
->CM000237.2/27621459-27621601 Rattus norvegicus chromosome 7, whole genome shotgun sequence. 
-CCTGCCCCTAGAGGCATTGCAGCTACGACTGCTGTGTCATATGTGTGTCAGTAGGTGGCAGAGATGAGACAGGCTATGTCTATGCTCAGTGTTCGGACCTGGGAAACCCGGGGGTGCAGGTGGCAGGGAGTGAGCCTAAGACA
->CM000780.4/158285691-158285793 Zea mays cultivar B73 chromosome 4, whole genome shotgun sequence. 
-GTGCGAATCACAGTGCAGCTCTCCTCTGGCATGAAGGCTGTGAGAGAGGCATGACAATTTCTGGCCTTGCCCTGCCAAAGGAGAGCTGTCCTGCCATTCATTA
->CM000236.2/108598299-108597972 Rattus norvegicus chromosome 6, whole genome shotgun sequence. 
-GGGTGCAAAGGCAATCTGCCTGTGGTGTCGAGCACCCCGTTGATAACCAGAGTTGAATCAGCTGATCTGGAAAGCTAGACAGGTGTCCTCTTCCTCCCTCACCACGTTCCATGTGCCTCCTTCCTGGGGCTGTGTATTTGATGGCAAAGGAAGATCTTCTCAGATAGAAGAGGGCCAGCCGCTGTTAAAGATATCTAAGCAGCTGCTAGATCCCCTGCTAGAGTCTCCAAACAAAGCCCTCAAAGTCCAAAGGCACAAATGGTAAATTAAATGGCAGTAATGTTGATCGAAACCCTCTGTGTTTGAGGAGGTAGCTCTCAACTCTGAG
->FRBW01000003.1/337999-338120 Labrenzia suaedae strain DSM 22153 genome assembly, contig: Ga0131142_103 
-TCGCGTCTCACCGAGCTACCTCCTCCCAAGCTCGAGACGTGCGACCCGGCGGAGCATCCTCCTCCCAGTTCCGCCAAGTCAAATGCGCCTGCCAGCACCTCCTCCCGCTGGCGGGCGTTTTG
->MNUO01000109.1/8594-8798 Candidatus Desantisbacteria bacterium CG1_02_38_46 cg1_0.2_scaffold_8344_c, whole genome shotgun sequence. 
-CAAGTCCGACTTAGGTAAAGGTTAGCCACCAGCCTAACACTTAATCTCACACTTTATTTGGTAACAAATAAAGTGGTGCGGGAAGCGGGAAATATCGAGCTATAACGCAAGTGAAGGAATTGAGCCCCGAAATAACCAGCGTGTCAGTGGTCGATACTCTTCATTAAGGAGCAGACAATAGTCTCACAACCGATAAAAGGCGAGG
->AAGD02011599.1/18221-19185 Caenorhabditis remanei strain PB4641 contig406.1, whole genome shotgun sequence. 
-AATTATGAAGTAAGAAGTAAGAAAGAAGCGAAACCACAGCCAAGGGAACGGGCTTGGCAAAAATAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTTTGACATTGTGAAGAGTCATGAGAGGTGTAGCATAGGTGGGAGACTTCGGTCGACAGTGAAATACCACCACTTTCATCGACTCTTTACTTATTCGGTTGAAAGAGAATTGGCTTCACGGCCTTTTTTCGAAGCATTAAGCGGAGCCATTTTATGGCACCGTGACTCTCCTCGAAGACAGTGTCAAGCGGGGAGTTTGACTGGGGCGGTACATCTATCAAATCGTAACGTAGGTGTCCTAAGGCGAGCTCAGAGAGGACGGAAACCTCTCGTAGAGCAAAAGGGCAAAAGCTTGCTTGATCTTGACTTTCAGTACGAGTACAGACCGCGAAAGCGTGGCCTATCGATCCTTTTAATCCTGATTGTTTCAGGTAAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTCCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGCGAAGCAGAATTCGCCAAGCGTTGGATTGTTCACCCACTAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGTTGACTTGTTATTGCTAAAAACGACGATTTTCCATGTAAAAACACGTAACTTCCACTACGAACCTTCCTCGTCTATCAATCACTCCTTGTCTCGGATCCATCAGCCCGCCGAGCTTCGGCTTTCCGTTTTCGTAGATCTCTGGGAACTCGACATGAGCGACGGACATTCTTTTCTGCAAAAAACCAAAATCTTAGCCGTGTTTCCCGATTTTTCCGCATTACAATACGGTGCCGGATTTCTACACCGTCAATCGCTCTTCCGAGAGGAGTACACGGCCGGCGGCCTAGGAA
->ABLE03011848.1/1-1240 Caenorhabditis japonica strain DF5081 Contig9538.1, whole genome shotgun sequence. 
-GACTTTTGAAGAGAGAGTTCAAGAGAACGTGAAATCGCTGGAGTGGAACCGGAGACAGTTGATGTTGCTTGGAGACAATCTTGGTGGCTGATCGCTTAGCTGTGATCGCCGCCGGGAGTCGTTTCCTATGCTACGCCGACGGCGTTGGCCGCTCGTTCTGGCCCGACAGTGTTGCCCATCTCGCAAGAGACGGTGTCTTGTTGTCGGTCGTTGGTTCGTGGTGGCTAGCGTTTAGTTACGCTAGTGTGTGTGACGTCGGTGTGAAAGTCGACGACGTTTCCGACCCGTCTTGAAACACGGATTACGGAGTGTTTGTCTGCTGCGAGTCAAAGGGTGTAAACCTTGCGGCGCAATGAAGTGAAGGTTAGTCTCGAACTGACCGACGTGGGATCCGTGCTCTTCGGAGTGCGGCGCACCACGGCCCTATGCGTGTCACTTGTGACTGTGTAGAGGTTGAGCAGTAGGCAAGCGACCCGAAACGATGGTGAACTATGCCTGAGCAGGATGAAGCCAGAGGAAACTCTGGTGGAAGTCCGTATCGGTTCTGACGTGCAAATCGATCGATAGACTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCTTCCGAAGTTTCCCTCAGGATAGCTGGAACTCTTGCAGTTATATTCGGTAAAGCTAATGATTAGAGGCCTTGGGGACGTAATGTCCTCAACCTATTCTCAAACTTTCAATGGATATGGCGTCGCAGTTTCTTTAGTGAACTGCGGCGTGAATGCGAGTTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGCTGTGGGATGAACCAAACGTGGAGTTAAGGTGCCTAACTTCTCGCTTATGAGACCCCATAAAAGGTGTTGGTTGATATTGACAGCAGGACGGTGGCCATGGAAGTCGGTACCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGCCCTGAAAATGGATGGCGCTTAAGCGAGAGACCTATACTCCGCCGTCGCGGCATGTGCGTTGTCTAGCGCCCAGGTCGCGACGAGTAGGAAAGGACGTGGCGGTTGCGTTGAAGGCTATGAGCGTAGGCTCGGCTGGAGCTTCCGTCAGTGCAGATCGTAATGGGTAGTAGCAAATATTCAAGTTCGATCCTTGAAGACTGAAGTGGAGAAGGGTTCCACGTGAACAGTAGTTGGATGTGGGTCAGTTCGATTCCTAAGGTACTGGCGAAAGCTTTG
->JH159154.1/6686760-6686937 Phytophthora sojae unplaced genomic scaffold PHYSOscaffold_4, whole genome shotgun sequence. 
-ATGCTTCCCAGGGTGACTACCGATTGGCCAAGAAATGCATGTATGAAAAATGAGAGCGTTGACATGAGCCGGAGCAGGCCCCTTGCACTCCGGTGCTGTAAGGGTTCAGGAATGCTCTTTTGAGTAATTCCACAGTAGAATTTTTGTCAGCGGGGGTGAGCGCGTGCGCCGCCCCCAC
->AAOX01000007.1/31274-31356 Bacillus sp. NRRL B-14911 1099999053126, whole genome shotgun sequence. 
-AAGAATATAGAACACTGTGATGAGCGGTTTTTATTTGCACTTTAAACCGCTTGGAGTGACTAGTGCAGCCGGCCAATGATCTA
->AZAQ01049668.1/23412-23144 Stegodyphus mimosarum contig49668, whole genome shotgun sequence. 
-GGCTTAATTTGACTCGACACGGGCGAACTTTACGCGGCCCAGACACAGGAAGGATTGAGAGATTCAAGAGCTCTTTCTTGATTCTGTGGGTGGTGATGCATGGCCGATTTTAGTTAGTGAAACGGTTTGTCTGTCCGATAGCGAAAGACTCTAGCTTACTAAATAGACGCTCCGATCCTTCGAGTCGGACGTTCTTAGAGCGACGTTTAGCTGCATGAGACAGAGCGATAAACAGGTCTGTGATGCCCTTAAGATGTCCGGGGCCGCAC
->CP002691.1/7079696-7079516 Haliscomenobacter hydrossis DSM 1100, complete genome. 
-ATTTTATAGAGAAGAGGGGAGAGAACGGGCTCTAAGAACCTCTGGCAACCATGCTTTTTTAAGCGAAAAGTGAAAAGCGAAAAGTGAAAAGTAAGATTAGCTGCTTTTCGCTTTTCACTTTTCACTTTTCACTAAATAAAAGTAACGGTGCCAAATCCCGCCATTAATGGGCATATAAAAT
->AB701766.1/10364-10418 Culex flavivirus RNA, complete genome, strain: Toyama71 
-ACGCGCGCAAGGAAGGACATGGCTGTCCTTGGGTACTAACGACACCCCGCCCCCA
->LFJF01047439.1/12546-13056 Macrostomum lignano unitig_47506, whole genome shotgun sequence. 
-TATCTGGTTGATCCTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCCATGCATGTCTAAGTACAAACCTTAATACGGTGAAACCGCGAATGGCTCATTAAATCAGCTATGGTTCCTTAGATCGTCTCATCCTACTCGGATAACTGTGGAAAATCTAGAGCTAATACGTGCTTACAAGCCCTGACCTCACGGGAGGGGCGCATTTATTAGATCAAAACCAATCGGGGCTTGCCCCGTCTGCTTGGTGACTCTGGATAACTTTTGTGGCTGATCGCATGGCCTCTGCGCTGGCGACGTATCTTTCAAGTGTCTGCCCTATCAACTTACGATGGTAGGTGATATGCCTACCATGGTTATAACGGGTAACGGGAATCAGGGTTCGATTCCGGAGAGGGAGCCTGAGAAACGGCTACCACATCTAAGGAAGGCAGCAGGCGCGCAAATTACCACACTCCCGGCACGGGGAGGTAGTGACGAAAAATAACGATACGGGACTCTTTTGAGCCCCG
->KE124372.1/17462-21459 Plasmodium falciparum UGT5.1 unplaced genomic scaffold supercont1.10, whole genome shotgun sequence. 
-GAGGATAAAAATAGGAGGGCAAATCCGCTGAACTTAAGCATATAATTAAGCGGAAGAAAAGAAAATAACTATGATTCCTTTAGTAACGGCGAGTGAAGAAGGAATAGCTCAATAAGTAGAATCCTTCGAATCTTAATGATATATTTATACATAGAATAAAGAATTGAAGGAATTGTCAAGTTGAATTGTACTCTTGTAGGCCTCACAGGTGAAATGAATATATAGAAGTAAAGTAGGAATACTTCCTCATAGAGGGTGAAAGGCCCGTATCATATATCATTTCGTGGGCTTTGGAGTATTTATATTTTACTGAGTAGTGTTCTTTGAGATTGGAGCACAAATTGGTGTGATACATTTCACATAAAGCTAAATATGTACAGGAGACCGATAGCAAACAAGTACCGTGAGGGAAAGATGAAATAGTACTCAGGAATGAGCAATTAAATAGTACCTGAAATCGTTAAGATGGAACGGATTAAGAGAGAAAACAAGTAAAGAGGGGAATTTTTAATTTTTTTTGTTATAATTCTCTTCTTTATTAAAAGAAACATCAGTGATTAATTTAATTTCAATAAAGCAATCCCCTGAAATTCAAAATTTCTTTTAATTTTGTTTTCACTTTCTCCCCGCACTAATGTGGGGAAAACTGGCTTTATTTCTTCAATTATTTTTTTTGCTGAGGAATTTTAAAATTATTTGAATTTTTCTTCTTATAATTTAAGTTGTTTCTATATAGTACTTTCTTAACCCACTCGTCTTGAAACACGGACCAAGGAGTCTAGCAAATGTGCAAGTGTATATGATTCTTTAAACATTTCTCTTTTTAATATACGCATAATTAATGTAATATGTTTCTTTATTGTAGATTTGTGGTGTTTAATTTTTATTAAATCCCCACTTTGCATACAATACCGGTAAGCAATTATGCTTTATTGAGTACGAGCATATTTGGTAGGACCCGAGAGGCTTTGAACTAAGCGTGATGAGATTGAAGTCAGGCGAAAGTCTGATGGAGGATCGAGTTGATACTGACGTGCAAATCGTTCATTTCAATCACGTTTAGGGGCGAAAGACTAATCGAAAAGCCTATTAGCTGGTTATTTTCGAAAGATCTCTCAGGATCGCTGGAGTTGAGTTGATTATAATTTTATAAGGTAGAGACAATGATTAGAGGGTTTAGGGGATTAAATATTTCTTAACCTATTCTCAAACTTCCAATATGTAAAAAGGGTGATATATCTGAATTGTGTGTATTTCACTCTGTTTTAAATAAAATAACTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGAGGGATGCTCCTAACGCCTGGATAAGGTGCCTAAATATTCGCTCATGAGATCCCATAAAAGGTGTTGGTTCATAATGACAGTAGGACGATGGTCATGGAAGTCGAAATTCGCTTAGGAGTGTGTAACAACTCACCTACCGAATGAACTAGCCCTGAAAATGGATGGCGCTAAAGCGAATTACCGATACCGGGCCATAAGAAGGTAGAAATTATAAATGTTAATTTAGCTCAGATCTTTTTATGAGTAGAAAATCGTGGGGTTTGTGTTGAAGCGAAATACGTGAGTTTTCGTGGAACATCTCCCTAGTGCAGATCTTGGTGGAAGTAGCAACTATTCAAATGAGAACTTTGAAGACTGAAGTGGAGAAGGGTTTCTTGTCAACTATGTTTGTACAAGAGTTAGCCACTCCTAAGGGATAGCTGAAAAGTGTTTAAAAGAAGAAATTCATTATAAGAATTATATAATGAAACTTCATCTCGAAAGGGAAACAGGTTAATATTCCTGTGCCATAAGTAATAAGAGTGCAAACAGAGATGGTAACATACATATAAATGAACTCCTTNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNGTAAGGGAAGTCGGCAAAATAGATCCGTAACTTCGGGAAAAGGATTGGCTCTGAGGACATTAGAAAAGAGAAGAAAAAAAGAGGGTTGAGAATAAAATTGCAGATTTATTTGCTTTTCTCTCTGATTTGCTTGTAAATTTTCTTTTTCTTTTTCTTCTTTTCTTTTTTTTTCTGTCCCTCTTTTCGTCTTCATTTTATTGTAATTTTTGTTACTTTAATTTGATACATATATAATGTTAACTCAGAACTGAAACGGACAAGGGGAATCCGACTGTTTAATTAAAACATAGCATTGTGAAAAACCATAACTGGTATTAACACAATGTGATTTCTGCCCAGTGCTTTGAATGTTAAGTTGATGAAAAATTCAATTAAGCGCAGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTACTTGCTATCTAGCGAAACCACAGCCAAGGGAACGGGCTTGGCAAAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTTACTCTAGTCTGGCTTTGTGAAACGACTTAAGAGGTGTAGCATAAGTGGGAGTAGAAACTGAAATATGTTTTTACGACAGTGAAATACCACTACTTTTAAAGTTGTTTTACTAATCCATTGATAGGGATATATAAAACTTATAAATAATTTTTATTTTAAGTTACTTTTGAATTTAAGATATGTGTGCATTTATATCTATTAAATCCCATTTTGTATATATATATATATTATATATATGTGTATAATACGATTTTTTTTATGGAGACATAGTTAGGTGGGGAGTTTGACTGGGGCGGTACATCTGTTAAAAAATAACGCAGATGTCCAAAGACAAGCTCAAAGAGAACAGAAATCTCTTGTAGACTAAAAGGGGAAAAGCTTGTTTGATTTCTATTTTCAGAACAAGTAGAAAACGTGAAAGCGTGGCCTATCGATCCTTTATATTTGCAAAATGACGTAATAAATTACTTACTACTGTGCATATAGAGGTGTCTGAAAAGTTACCACAGGGATAACTGGCTTGTGGCTGCCAAGCGCTCTTAGCGACGTAGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGGGACGCAGAAGTCTCAAAGTGTCGGATTGTTCACCCGCTAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGAATTTTATTATATTTTTTATATATACATATAGTATTGTGACAGTAATCCAACTTGGTACGAGAGGATTAGTTGGTTCAGACAATTGGTACAGCAATTGGTTGACAAACCAGTGTTGCGAAGCTAAGTCTGTTGGATAATGGCTGAACGCCTCTTAAGCCAGAACCCATGCTGATTAGACAATTCTAAATTTGATCTTTTTGTTAAACGATAAAAATTATATATATATTTTTTTTATCTTTACTGCATAATGTAAAAGAGAAATTATACATATATATATATATATATATTAGAAAAGAAAAAATGATGTAATTAATTATTATTATTATTTTTTTTTTTTTTTAGTATTAATATATAATTATGAATATATAAATAATCCTATATCTTTATATAAAAATTAAATTTTTAATTTTATTAGAATTTTTTTTTTTTATATATATAGATTGTAATTTAACAACAAAAAGTATTAAGCCCAAATCGTAGACGACTTTTCTGTCTCAGAGTACTGTAAACATGAGAGTAAACTTTGTTTTACGATCTGTTGAGGTTTATCTCTTGTGACATTGAGCTAA
->MDLB01000098.1/10133-10486 PVC group bacterium (ex Bugula neritina AB1) isolate AB1-3 AB834_contig000098, whole genome shotgun sequence. 
-AAAGTTGATTGGATCATCGGTGCTGTTGATCTCAAGATATTGATTTAACAGTGCAGGAAAGTCTGGACTCCGCAGGGTAAGATGCTACTGTTATGGTTGTGAGGGTGACCTTAAGGAAAGTGCCACAGAAAAAAAACAGCCTATTGGAAACGACTCGTTTCGATTGATGGGTGATGGTGAAAAGGTGAGGTAAGAGCTCACCAGTTCTGGTTTGAAACCCAGAAGCTAGGTAAACCCCATCTGGAGCAAGACCAAGTAGGAAACGTGATAGTTACCCGCTATATGTTTTCGGGTTGGTTGCATTAGATGAATGATGGTCATAAACAGAATCCAGCTTATAGATCAACTTTGCCT
->JRRC01046601.1/9504-9338 Gossypium arboreum cultivar AKA8401 contig_129_9, whole genome shotgun sequence. 
-ACTTTTTAAGTTTGCTGTCAAATCTCAAGGCTCAACCCTAGACAGGCGGTGGAAACTACCATGCTGGAGTACGGTAGGGGTAGAGGGAATTTTTGGTGGAACGGTGAAATGCGTAGAGATCGAAAAGAACACCAACGACGAAAGCACTCTACTGGGCTGACACTGAC
->JH835603.1/135856-135729 Erinaceus europaeus unplaced genomic scaffold scaffold00315, whole genome shotgun sequence 
-AGCCCCATTCTAGATGAAAATGGGCACTGTTGCTTTTGGTGTTCAGAAACAGATGTGGCTATATTGATACAGGTTAAGCTTTCACCATAGTACCTTACTGTAGTGGTGACAATGAGGCTGCAACATGT
->KV428048.1/4065-3885 Sistotremastrum suecicum HHB10207 ss-3 unplaced genomic scaffold SISSUscaffold_45, whole genome shotgun sequence. 
-TTCGTGCGGCGTCACGGCTATACTTTCCCCATGTTGCTCACTTCTGCTGATCGTGCGGTGGTTCGAGTGTCAAGCCGTGTCCAGAATAATTTTCGTGGACGTCTTAGTGCCTTTTTAACCCTCCTTTTATGGCTCTTGTAGCCTTTTTGGGAGGAGGGTTGGGTCGGTGGTTCTTACACTC
->MGVC01000060.1/14949-14867 Elusimicrobia bacterium RIFOXYA2_FULL_39_19 rifoxya2_full_scaffold_498, whole genome shotgun sequence. 
-ACGTTATCCCGCTACTGGCGGATTTGTGGGCCTAAACCACAAGGGACCGGGATAATTTCAAGCCGACCGCCTGGGCAGAAGTT
->LZPO01057484.1/678881-679115 Neotoma lepida isolate 417 scaffold_0, whole genome shotgun sequence. 
-GGATATGAGGGTGATCTGACTTGACAGTGTCTCCTTTCTCCCTTATTCTTCCATGTGTGTCCCTCCCGAAGGTGCCCATTCACTGTTTTGAAGACTAAAGGAGGATTGGACAAGTACCTGTGCTCCACTGTTAGAGCCTCCAAACAAACTCTCAAGAAGAAAACCAGATGAGAACAGATGGCCAGATAGTTTATTGTTCATCACTCTAAATAGTAGACACAATTCAAATTATTCT
->AAAB01007393.1/1-1983 Anopheles gambiae str. PEST whole genome shotgun sequencing project, whole genome shotgun sequence. 
-ATACCATGAAAGGTGTTGATTGCTAAAGACAGCAGGACGGTGGACATGGAAGTCGTCATCCGCTAAGGAGTGTGTACAACTCACCTGCCGAAGCAATTAGCCCTTAAAATGGATGGCGCTCAAGTCGTTTGCCTATACATTGCCGCTGGCGGTATGGCGCATCGGGGGCTTAACCACCCTGCGATGAGACCCCAGTGAGTAGGAGGGTACGGTGGTGCGCGTCGAAGTGTTTGGCGCAAGCGGCATGGAGCCGCCACTGGCACAGATCTTGGTGGTAGTAGCAAATATTCGAACGAGCTCTTGGATGACTGAAGTGGAGAAGGGTTTCGTGTCAACAGCAGTTGAACACGAGTTAGCCAATCCTAAGCCGCATGGGAATCCAGTCGTAACCCATCAGTCGGCGAAAGGGAATCCGGTTACCATTCCGGAGCCTGTTGAGTACCCGTTTGCGCCACCTAGTAGGGTTTAGCTCGTCCGCACCCGAACGGTTAGTGTGTAGCTTCATGGCAACATGAATCCTTTTCTTCGAGAAGCCAACGAGAGGCATCGGAAGAGTTTTCTTTTCTGTTTTACAGCCACACCGACCATGGAAGTCACTCACAGAGAGATATGGTTGGACCGGTCTGGTAGAGCACGGCCGCCGCAACTGCCGTGTCGATGCACTCTTCTTGGACCGTGAAAATCGAAGACTGGGGCACACTTTATATGGTAATAACGCACACTCTCAACAGATTGTACCGAATCCGCAGCAGGTCTCCAAGGTGCAGAGTCTCTAGTCGATAGATCAATGTAGGTAAGGGAAGTCGGCAAACTGGATCCGTAACTTCGGGACAAGGATTGGCTCTGAAGGCTGGGTGCGACCAGCCGGGACCGGTGCTCCACCTGCCGCAAGGTAGGCTGGCCCGTGCCCGCGGTCGCACAGCAAACAGCCAATTCAGAACTGGCACGGCTGAGGGAATCCGACTGTCTAATTAAAACAAAGCATTGTGATGGCCCCGGGTGGGTGTTGACACAATGTGATTTCTGCCCAGTGCTCTGAATGTCAACGTGAAGAAATTCAAGCAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCTCTGTCCCTATCTACTATCTAGCGAAACCACAGCCAAGGGAACGGGCTTGGATGCACTAGCGGGGAAAGAAGACCCTGTTGAGCTGACTCTAGTCTGGCATTGTAAGGCGATATAGGAGGTGCAGCATAGGTGGGAGGGCTTCCTCGTGGAGCTCGCCTCTGAGATACCACCACTCTTACTGTTGCCTTACTTACATGATTGGGTGGAACAAGCGCGGGCCCCAGGTCCGGATCGTGCGCGCACCTCCTCCGGGGGGCTGTGGCGGCGGTTCGCCTGCGCGCGCCCAATGCGCCGTGTTTCTCGCTCAGCGTCCAGTGTGTCGCTGGGTGGTGCCGCCGGGGAGACTGCATCGTAGCATCGTCGTGTGTAGCGTGTTACCCGCTTGTCCGACCGTGAGCCGTGGCCCGCAAGGGTACAAGCTTGCGTACGTCGGTGCATTCGTGGTGCACTGCTTCTGCGCGGTCGATCGTTTATGATGTCACGTTTGCCCCCGGTTCCGCGCGCCGCCCGGCTCGAAGACTCCTGGACAGGTCCTTTCGGTCCACGTCATGGACAGTGCCAGGTGCGGAGTTTGACTGGGGCGGTACATCTCCAAAACGATAACGGAGGTGTCCAAAGGTCAGCTCAGTGTGGACAGAAACCACACGCTGAGCATAAGGACAAAAGCTGGCTTGATCCCAACGTTCAGTACACTTCGGGACAGCGAAAGCTTGGCCTTACGATCCTTTTGGTTATAACGAGTTTTTAGCAAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCCGCCAAGCGTTCATAGCGACGTGGCT
->LCGI01000002.1/5713-5334 Parcubacteria bacterium GW2011_GWA1_43_27 UV92_C0002, whole genome shotgun sequence. 
-ACGTCAACCCAGGTGATTGCTCCGTATTTTACGGAGAGGAAAGTCCGAACACCACAGTGTTCCCGCTAATTTAAGGGAAGGGTAACTCCTAATTGGAGCCGTTGATCCGAGTAATCGGATCGCAGGACAAGTACAACAGAAAACAAACCCACTTTAATAAAATCATTGAAGATAGGGGTGAAACGGTGAGGTAAGAGCTCACCAGTATCTATGGCAACATTGATGGCTAGGTAAACTCTACCCGGTGCAATACCAAGTAGGTCCGCATCTTGGCGGACGGGTTGGTAGCTTGAATCCTGGTGCGAATCAGGATCTAGATAGATAATCACCGCCCTGCCTCGCGCAGGGTACAGAATTCGGCTTATAAGGTTGAGGTGAGC
->JPVT01000244.1/2256-2451 Tetragenococcus muriaticus 3MR10-3 WGS_Sequence244_061, whole genome shotgun sequence. 
-ATATCAATACACAGAAAACCTAGTACATGATTTTGACCTTTCAGAGAGCTGATGTTTGCTGTGAATCAGTAGGAAAAATGATGGAATCCAGTTTTTAATGTTTCTTTTAATAAAGAACCTATACTCTTTGGTTACAAGAGACAAGTGCGGTTAATAACCGAACTTGGGTGGCACCGCGAACTATTTCGTCCCAAGC
->MHLL01000003.1/8974-8834 Candidatus Lloydbacteria bacterium RIFCSPHIGHO2_02_FULL_50_13 rifcsphigho2_02_scaffold_10435, whole genome shotgun sequence. 
-AGTTTATCGCGAGTGCGGGGGAGGGAATTGGCCCTAGAATCCCGCCGGCAACCATTCTGAATGACTCCTACGGTTTTGGAGAACCGTAAGAACTTCAAAAAAGAGGTGCCAAATCCAAACCCTTAAGGGGAAAGATGAAAT
->ALAR01193235.1/10683-11037 Tupaia chinensis contig193235, whole genome shotgun sequence. 
-GAATATGAGGGCAATCTGGCTATGATAACTGTCATCTCGTTGATGGCCAGGGTTGGTTCCTCTGATCGGGCAGGCTGGATGGATATCCTCTTCTTCCCTCACTTCTCCATACATTTCCTTTCCCAAACTGTGTATCCAAAGAAGATGGCCTTTTCAGGTATACAAGGCCCATTGTTGGGCTGAGCTGCTTGGGTAGCTCAGCCCAAGAATGTGTTCCTCAACCAGAACCTCTGAACAGACTCTTCTACTTAGTACTACCTTTACTCACTCTTGTTTTTTATTCTGTAAAGGAATATTCTATGCTATTTCTTGTATATAGAAAATTTCCACAGCATCATTTGGTGGCATGATAGTG
->ANKR01173204.1/1886-2165 Myotis brandtii contig173204, whole genome shotgun sequence. 
-ACCGGGCGTGGTGGCGCGCGCCTGTACTCCCAGCTACTCGGGAGGCTGAGGCTGGAGGATCGCTTGAGCCCAGGAGTAGGGCTGTAGTGCGCTATGCCGATTGGGTGTCCACACAAAGTTCGGCATCAATATGGTGACCTCCCGGGAGCGGGGGGCCACCAGGTTGCCTAAGGAGGGGTGAACCGGCCCAGGTCGGAGACGGAGCAGGTCAAAGCTCCCGTGCTGATCAGTAGCGGGAAACCTGGAACCCTTCACTTGCAGGCCAATGCTCTATCCTCTG
->BA000039.2/281279-281411 Thermosynechococcus elongatus BP-1 DNA, complete genome. 
-GACAACTCAAGACTAAAACCGAAGACCGCAGGGGTCTGGCTGAGACATAATCTTCCTGCCGAGGTTTGCGAAGTCCATCCGTTGCGATTGGGCGATCGCCCCGGCACCCTTGCTGGGGTTTTTCTTTCACTGA
->ALWT01112214.1/10402-10542 Myotis davidii contig112214, whole genome shotgun sequence. 
-AGCTTTGCGCAGTGGCAGTATCGTAGCCAATGAGGTTTATCTGAGGCGCGATTATTGCTAATTGAAAGAAAAAAAGAAAAGAAAAGAGGGAGATGACTGGCGGTGGCCATCGCCCTGCCCACTGGTCACCCCACAGATGGG
->MHQJ01000053.1/3212-2967 Candidatus Sungbacteria bacterium RIFCSPHIGHO2_02_FULL_49_12 rifcsphigho2_02_scaffold_96412, whole genome shotgun sequence. 
-NNNNNNNNNNAGAAGCAATTCTCTTGTAACAAACTTGGCTATATGCTGGAAAACCCGCGCATGCAGAAGTACTTAAGTACTGTACAGTACTTAAGTGACAATCTTCTGCCGATGCGGACAATCAGCAGGCAACCTATAAGTTCAATAGACCAGTCTATCGAATTCATAGAGAGTCCCCAGAGACTATACGCCGAGCCCCCAAGTTTTGGGGTGATGATATAGTCCATGCCTTATGGCGACATAGGG
->DS989904.1/4377794-4377629 Synechococcus sp. PCC 7335 scf_1103496006895 genomic scaffold, whole genome shotgun sequence. 
-TTGTGTCGCTATGCGCCGTGCTAGGCTAGGTAGCCTGCATGGGGAAAGTTCGGTGAAAAACCGGCGCTGTCCCGCAACTGTGATGGCAATCTCTAACAAAGTTTCTTCAATATAGTTGCTTTCTTTTGCCTGAGCCAGAATGCCTGTGCGGGTTTTCGCTACACTC
->AFTD01105653.1/47017-47121 Cricetulus griseus cell line CHO-K1, whole genome shotgun sequence. 
-GGCTTGTTTGAAGGTAGTGAGTTATGTATTGCTCAAAGGCAGTTGCATATTAGACCCCTTTTCTATACTTTCTCCTGTCACACTATCACACCTGACAAGTTTAAA
->MGYS01000080.1/2479-2377 Gammaproteobacteria bacterium RIFCSPLOWO2_02_FULL_57_10 rifcsplowo2_02_scaffold_5319, whole genome shotgun sequence. 
-TAACTCAACAACCAACGTCGCACATACACCGTCACATGTGTTTTGGGTGCCTTGAAATCCTCGCGGATTCGGGGTTAAACCATGGGGTGTGTGGAGGCTTAAC
->CP003219.1/1938094-1938153 Streptomyces cattleya DSM 46488, complete genome. 
-CGCCCGGTACGGACCCGTGGGGGGATCCGCTTCCGGGGCACGGGGGCGCCCCGCTCCGGA
->LJYW01000001.1/1800734-1800628 Prosthecomicrobium hirschii strain 16 C1, whole genome shotgun sequence. 
-TGCCAGTCCGAGGGGTGCTCCTGTGGGAGCTGAGATGGCGCTGCGGCGTCGGACCCTTTGAACCTGATCCGGGTCATGCCGGCGAAGGGACGGGATCAACCGGCTTT
->JH932293.1/704875-704772 Bergeyella zoohelcum ATCC 43767 genomic scaffold supercont1.1, whole genome shotgun sequence. 
-CGAGATATAAGCATTTTTTATCAATTATAAAAGTACCATTTTTTACCACATTGCCTAAAAATAAAACACCCCAAACCATCGTTTGGGGTGTTTTTATTAATCTA
->GL541731.1/40376-40515 Microbotryum lychnidis-dioicae p1A1 Lamole unplaced genomic scaffold supercont1.89, whole genome shotgun sequence. 
-TCAGTCTCTCTTCTGGACTGAGCTTAATCGGCATGCGTCTCTGGTAACGGGGGGGTATGAAGCCCGAGGATAACGTAGCCTCTTTAGCTTTTTACTCCTTTATTTTCGAAAATAAAGGCCAAAAGAAAAAAAAAGGGAGG
->LHUR01000022.1/308140-307852 Clostridium homopropionicum DSM 5847 CLHOM_contig000031, whole genome shotgun sequence. 
-AAATATATTAAAGCGCCAGAGCTAAGCAGGGAGCCTGAATCAAAGATTGTCTTATAGGAAACTCAAACTAAGGTCTGAGTAAGCTCGAATAAGCCAAATTAGCACTCTGTGTAAGTGACTTGCACCAAATCATAGATTTGGGCAATCTACTTAAGATTTGGATTCTCGCTTAGCTGACGAGGGTGGGGAGTATCGAAAATTCGGCGGATGCCCCACGGTATAGTGCTACCGATAAAGACTGGCAAAACTGAAAAGTAATTTTCAGTACAAATTCAGTCAGGCACTCACA
->CP008889.1/1694819-1694882 Dermacoccus nishinomiyaensis strain M25, complete genome. 
-GGAATGCCGGTGCGAATCCGGCAGCGGTCCCGCCACTGTGATCCCCGACGGGGTAAGCCAGGAC
->HF993839.1/17775-17516 Clostridium sp. CAG:127 genomic scaffold, scf188 
-TAGTAGTTCGATGGACTGAGAAGTGAAGAACGAGGAGTTGGTTATGAATCTGGTAAAAGGAACAAGGATGTTGCGGAAGGATAATAACCCATATGGGGCACAGCCCNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNGTGAACACGAAAGTGGCTTGCCTGCAATTCCCATGTGTACGGGCGATAGAGGGGTTCGGATGAACCAGAGTACACCTACA
->CAJW010074381.1/2720-1779 Hordeum vulgare subsp. vulgare, WGS project CAJW01000000 data, contig: morex_contig_74381 
-ATGGGGCACGTGGAATCCCGTGTGAATCAGNNNNNNNCACCTTGCAAGGCTAAATACTCCTAGGTGACCGATAGCGAAGTAGTACCGTGAGGGAAAGGTGAAAAAACCAAGTGGGTAATAAAAAACATCGTGAAACCTTGTCGAGCTCCCAAGCAGTGGGAGGGGAAAGTGATCGCTGACCGCGTGCGTGTTGAAGAATGAGCCGACGATTCATATGCAATGGCTTGGTTAAGGGAACGAAACCCACCAGAGTCATAGTGAAAGAAAGTCTTAATAGGGCGATTGTCACTTCTTATGGACCCAAACCCCTGTGGTCTATCCATGACCAGGATGAAGGTTGGACGAAACTAAGCAGAGGACTGAACCAACTGATGTTGAGTAATCAGCGGATGAGTTGTGGTGAGGGTTGAAATGCCACTCGAACCCAGAGCTAGATGGTTCTCCTCGAAATGTGTTGAGGCGCAACAGTTGACTGAACATCTAGGGGTAAAGCACTGTTTCGGTGCGGGCTAAACGATCGGTGCCAAATCGAGGCAAACTCTGAATACTAGATATGACCCAAAAATAACAGGGGTCGAGTCGGCCTGTGAGACGATGGGGAATAAGCTTCGTCGTCGAGAGGGAAACNNNNNNGATCACCAGCTAAGACCCCTAAATGAACGATTAGTGATAAGTAAGGTGGGGGGGGGGGGCAAAGACAGCCATTAGGTTTGCCTAGAAGCAGCCACCCTTTAAAGAGTGCGTAATAGCTCACGGATCGAGCACCATCGTGCTGAAGGTAAACAGGGATAAGCAAGGTGCCTAAGCTATGAGATGTCAAAATGCATTGGTAGGGGAGCGTTCCGTCTTAGAGGGAAGCAACCTCTTTCCTAAATATGTATCGGTTATATTTCATGGTCGAGGCTCATTTTTCTATTGTTTTACCATACATGGTTTGTTTCT
->FKLB01000042.1/73555-73404 Pseudomonas sp. 1 R 17 genome assembly PSEFL294_LIB5394, contig: PSEFL294_LIB5394_000042 
-ATCCTTCCCAAGTGCCTGCTGACGTTGTCAGCAACATGCTCAGGGCAGCTTTGATCTAGAAAGCTGCAACGTACATACCGTACGCCGATCACCACCCAACCGCTAAAGCATTCAATTTGTGGTCACACGTCAGCGTTATCGACGTGGAATGC
->CM001665.1/38959911-38959726 Nomascus leucogenys chromosome 19, whole genome shotgun sequence. 
-ATTGCTTCTTGGCCTTTTGGCTAAGATCAAGTGTAGAAATCCATGAACACTAAAGGACTGCATTGACTTTTTCAGAGAGTAGAAAACAACTTAGTTTTTTTTTTTCCTGAATGCGTCATAGGCTTGTGAGTGATTTTTGTCCATTCAATTGTGCCTTCTTTGTATTACAATAAGATGGGGGTACTT
->CP011568.2/2789266-2789207 Pandoraea thiooxydans strain DSM 25325, complete genome. 
-TGTCTCCTCCACCTCCTCCTGGTGGATTTTATGGCCAGCAGATTGCTGGCCATTTTTTTT
->ARZA01000139.1/3294-3076 Caldisalinibacter kiritimatiensis strain L21-TH-D2 NODE_28, whole genome shotgun sequence. 
-ATATAAGCTGTGAAAGGTAATAGTAGATATTTAAGGCTTACAGAGAGGAAATCCTAGGCTGAGAGATTTCTAGCCCTCTGAATATTGAACCCGGCCTGGAGCTTCTAGACTGAAAAAAAGTAAGTTTAGACGGTGTTAGCCGTTATAAAATTAAGTGAGCCAATGAAATGTATTAATTGGTTAAATAGGGTGGTACCGCGGATAAACTTCGTCCCTTTT
->CAGP01000005.1/749-1 Helicobacter bizzozeronii CCUG 35545, WGS project CAGP01000000 data, contig: tsc_c98 
-CTACTACTACACCGATAGCGCACAAGTACCGTGAGGGAAAGGTGAAAAGAACCGTGGGTAACGGAGTGAAATAGAACCTGAAACCATCTACTTACAATCATTCAGAGCACCATAGTGAATCCCCCTGAGGAATTGCGGGGGGGGGCTGTATATAACACTTATACGCCCTCTCCTCCTCCATGATTTCTCGATATCTTTTTTGGTAAGGAGTTTTCATGAAACCCCAAGACAATGCGTCAAACATGCAAAACCCGAATCGTGGGACTAGCGGGACAAATAGGCAATACGACCAAAATCAGGGGAATAGGGGAAGCCAACTAAACCCTAACAACCCCAACAACAGGAAATAGGTAAGGAGAGGTCTCATGGGAAGAGGACAACCAGATAACGACCCTAACGAAGCAGGCTATCCTTCCACGACAGGTAACCCAAGCGGTGGCGGTCGTGGCAATGATGACCCTGATGACGATTAGGTCTAACTAGGTCTCAAACAAGGAGGGGAAAAACTTCAATTCTTCAGTGGGATTCACTGGTGTGATGGACTGCCTTTTGCATAATGATCCTGCGAGTTGTGGTGTCTGGCAAGGTTAAGTGAAAACGAGCCGTAGCGAAAGCGAGTCTGAATAGGGCTATTTAGTCAGACGCTGCAGACCCGAAGCCAAGTGATCTATCCATGGCCAAGTTGAAACGAGTGTAACAGCTTGTGGAGGACTGAACCCGTGCCCATTGAAACGGGCTGGGATGAGCTG
->BDFN01001244.1/2524-2921 Ipomoea nil DNA, scaffold: scaffold1244, cultivar: Tokyo-kokei standard. 
-ATTCAAATGAGAACCCGAAGGCCGGTTCAGGGAAAGGTTCCATGTGAACGGCACTTGCACATGGGTTAGTCGATCCTAAGGGTCGGGGGCGCGCCCGACAGACAGCGCGTTTTGCGCGTGGCCGAAAGGGAATGAGAATAATTCGAGGGCGTTCGACCCGATGTTCTAATCATTGGCTTTACCCGAGAGACGGCGCGGCGCTCAAGAGTTGAGGGAAACTTCGGAGGAACCCCCCTGGAAACGGCTCAGCCGGAGGTAGGGTCCAGCGGCTGGAAGAGCACCACACGTCGCGTGGTGTCCGGTGCGCCCCCGGCGGCCCTTGAAAATCCGGAGGACCGAGTGCCGTCCACGTTCGGTCGTACTCGGTCCCGCAGGTATCCTGGTGAACAGCCTTGGTG
->JH815222.1/1813753-1813619 Clostridium sp. 7_2_43FAA genomic scaffold supercont2.3, whole genome shotgun sequence. 
-ATTGTTAAGAAGAAACAAAGCCGTTTCTCACCTTACGGCAGAGCTTAGTAAGGTAGTATATTCTTATTTTAATTTATTATTTAAATTAAACGTGAGTATTATGAGGACGGCATATTGCTGTCTTTTTTATTTTGT
->AACY023865031.1/116-206 Marine metagenome ctg_1101668672382, whole genome shotgun sequence. 
-CTGAGTTTCTTGCTTTTCTATAAGAGCAAGTGGTGCGCTACATCCGCGTAGTTTCCTAGTTCTACACAAAAACTAGGTGGCGAGCATATTA
->ANKR01167074.1/25401-25567 Myotis brandtii contig167074, whole genome shotgun sequence. 
-ATCACTTTTTGGCCTTTTGGCTAACATCAAGTGAAGCATCTGTTCTTATCAGTTTAATAAAATATTTGCTTCAGAAACTGCCACCTCTGAAGAGTCAAGCTGCCATGAAGCAGGTAAGTGCATGGAGCCACCATCAACAGCAAACTCATTTCTGGAGTGAAAGCTCA
->MHKU01000038.1/195-563 Candidatus Liptonbacteria bacterium GWB1_49_6 gwb1_scaffold_7743, whole genome shotgun sequence. 
-TTGGCAATTCAGATGATCGCTCTTTATCGCAAGATAAAGGGAGGAAAGTCGGGACACCCTGAGCCGAAAGGTTTATAAAAAAGTAGCGGCTAACAGCCGTCGTCCGCAAGGACAGAGGTGCGAGCAGTGACGCTCCGACGCGAAAGTATCGGAGGGACCCTATCCCAAGCTAGAAGGTCCAACTCCGCGATAGGGATAAGAAAGCGGAGGTGAAACGGCTAAATCCTTACTGGGTGCAAGACCGTACTCCAATGCGGAGCATTGGTTTGTGTCGCTTGAGCCCGCGAGCAATCAAGGGCCCAGATAAATGATCGCCGCCGCCGATAACAATCGGTGTGCACAGAATCCCGCTTACGAATTGCCGCAAAC
->MHXM01000167.1/11573-11672 Desulfuromonadaceae bacterium GWC2_58_13 gwc2_scaffold_6790, whole genome shotgun sequence. 
-CTTTGCTCAGAGCAAACCACGGGAAACCGTGGGGCGCAGAGCCACGGGACTTCCGGTTTGCAGGCAGGAACCTGCGACCAAAGTCAGCCGGGCCGCCAGA
->AAPU01011573.1/516306-516391 Drosophila mojavensis strain TSC#15081-1352.22 Ctg01_11574, whole genome shotgun sequence. 
-ATATTTTCTAATGATGATAACTACATAGCAAATCAGAGCAATAATGTTGAAATTTACAGACAATGCACTACCATCTGATTGCTATA
->KB916025.1/11687-8703 Neofusicoccum parvum UCRNP2 chromosome Unknown NP2_03_scaffold_387, whole genome shotgun sequence. 
-CCTGGAGATAGAGTGCACTTCTAGGGTATAATCTTCACAAAACCCCCCCTTGGTTCTAACCAAGGCAGTTGGTTCTACTAAACTCTTAGAGAAATTATATTAATAAACGAAGTGAATTGAAATATCTTAGTAACTTCAGGAAAATAAATCAAACGAGATTCTATGATTAGTGTGAACGAAAGTAGAAAAGCCTAAATATTAAGCAAGTAAAATGGATTAATCTGTTTGAATATAGGGGAACCTTCCTCTAAGGCTAAATATGATATATAAGCGATAGTGAATGAGTACCGTGAGGGAAATGTTTTGAAATAGTAGTTTTATAAGCAGCTCGAGTGAAGTTTAAATAAAAAACAAGAGCGTACCTTTTGTATAATGGGTCAGCAAGTTAATATTAGATGCGAGCATAGCACTATGCCTAGATAAACCGATTATGAAATAATGAATAAGTATCTAGTATTAGACCCGAAGCCTAGTGATCTTACCATAATCAGGATTATAAAAGTCCGAACGGGTTATCGTTGTAAAGATATCCGAAGAATTGTGGTAAGTTAGTGAAAGACAAAACTGACTAGGATAGCTGGTAAAAATTAGTGTGAGCTACTAATTAGGCCAGTAAGTAGAAGTGAACCTTCTGCTATAGACCATCAAATTGACGGGAAAGCCCTAAAGCAAATTCAACCAAACAAATGTGGTAACACATTTGTGGCGCAGGTAATGACTCGCGGTAAGGTAACATCGAAATTGATAGCGAAAGTGAATGGGTAATCCGCAGCCAAGCACCTTATGGGTGTGCAGTTCATCGACTAAATGTTGGTTGGCGCAAGCTTAAGATATAGTCAAGCCTCATCCAAAAGGATGCAGAATAATAAAATACTTTTTTTATTTAATTTTCCGCCTTTAAGGCACATATCTAATCCTTTATTACCTTCAAATAGACTTAGGTTGTACCTTTTGTATAATAGGTAAACAATCCTAAAGGAAAACATATCTTCTAATGTTTTACATTAGAGGTATGAATCCGAATCTTTTTTTTTAATAGCCGATAAACTATCACAAGTAAATACTAATACAGAATTAGAATATGCAAGTTTAACTGATGCAGCTAAGGCTATAGCTGTTAGTAGAACAGCTGTAAAAAAAGCTCTTGACACAGGTAGAACTGTAAAAGGATAATATATAGTAGCCACAAAAAATTAAATAAAAAAAGTATTTTATTATTTGTAAATGGATAGCTAATAGCTATTTAGGGAGAAGGACCTCAGCTCGGCCCTTTAAAGTTTTATTCATATTCACAATAAAAAAAATAAAGGCTAAAGATGGTCATATCTGTTTCCGCGAAACCTATATAAGTAGGTAATTCAAGTAACATCTTAGCAGGTACAGAACTGTGATCTCAGGTAAAATTATATTATTTTAGAAATCTAAAATAATAATTTTGCATACATCGGGGGATCGTGAAGATTTTATCGGTGAGTATTTGCTCTCGGAAGGGCAAAGATGATTATTGAATAATCAGACATAGTACGATAAGGTTGTATGTCTAAAGGGAAACAGCCCAGAACAAGTGTTTAAGGTTCCAAAATTATTGTTAAGTGAAATTAAGGAAGTATTTTTCAAATACAACCAGGAAATAGGCTTAGAAGCGGCCATTTTTTGAAGACCTCGTAACAGAGCACTGGTTCAATTATAAATTAATATAAATTTATACAAGTTAAAAGCGCCAAAAATATAACGGATCTAAAACAATATACCGAAACCTTGTCCATATTTATAAATATATAGGAAGTTAAAGATCTGGGTGAAATCTTTATTTTTTTTTTTGAAATAAAGATTTCACTTTTTATAGTAATAATAATAATTAACAAATCTTTAAGCTTCATGCTTCAATATGTAGCAAAGATATTGTATTTATGGGGTAGCGGAACGTTGGGGAAATCTTAGATTTTTACTTTTTAAGTAAAAAAATTAGATAACCCAAGTGAGAATGCTGACATGAGTAACGAAAAAGGGGAATACCCTCGCCTTAAGCTTATGGAATTTCTTTAAAGTAACGGCCTCTAAGTTTACAGACCTGTCCTAAAGGATTAAACGATGAGAAAATCTTCCTTATGTATGACAACCTTAGAATAATAGTTAATCTGTTTAATAGATAAGAAGATTTTGTATTAACAGTTAATGCATTTGAAGATTTTGTATTAACACTGTTAATGCATTTGAAGGTCATGTTAAATGCGCCATGATATATCAAATCTGGTCTACTAACCAGATTTGATATACCGACCAGTAAAGCTGGATACTCTGTCACTGCTTGCCACAGGGCCTATGATCGTTGCAGGCCTACTGGTTCTTATTTTTTAGTATTGAATTATATGGCAAGTATTTTCAGTATATCCCTTTTCCCTGCAGAGGAAATATCCCCTCTAAAGGAAACTTAGGGAAATAAACTGTATAGTAACAAAGGATGCTAGACAGATATTAAATAGATTAATAGTTGAGAGTACTAAGCGTTCTGGAAAAAGACATAAGGGTAAAACCGTACCTAGAAACTACCACCAGTAAGCAAGTAGAGAATACGAAGGCGTTTGAGCTAACAATCATTAAGGAACTCGGCAAATTGACTCCGTAACTGCGGGATAAGGAGTGCCATTCTAACTGGATAATATCAGATTTAGAAGAGGAGGCACAGAATGGTGTTGTACGACTGTTTAATTAAAACACAGCACTTTGCGTAAGATGACAAATCGAAGTATAAAGTGTGCCGTCTGCCCGATGATGGATGGTTAACGAATTTATTTAGCTGACTAAAATAGGTTAGGTTTTGAAGGAACCCCCATTCAATGGCGGCCTTATCTATAAGGGTCCTAAGGTAGCGGAATACCTTGGCCGTTAAATGCGGTCTTTGCATGTTTTCTCTTTAGTTTAGGTAACTAAAGTAAAGGATTAACCAATAAAAAAAAATAAATAAGGGAGAAATCTCTCCAAGCC
->LJSX01000001.1/215848-215664 Rhizobiales bacterium HL-109 ITZY_scaf_5, whole genome shotgun sequence. 
-TGGCCCCTTGCCGTGGTCGGCGCCCTTTCGGGCCCAACAGGGAAACCGGTGCGAGACCGGTGCTGCTCCCGCAACTGTAATCGGTGAGCCCGTCCGAAAGCCACTGGTGCCCCGCGCACCGGGAAGGTGGACATCGCGGTGATGACCCGAGAGCCAGGAGACCTGCCGACGTGAAGCAACCCTGA
->NATL01000046.1/9039-8946 Candidatus Omnitrophica bacterium 4484_70.1 ex4484_70.1_scaffold_5627, whole genome shotgun sequence. 
-AGCGATAAAGCCAAACCCAGGGAAATCTGGGGGCGGAAAGCCACGGGTCCTCAAAATCAGGATTATTATTGAGGGGATAGCCGGGTTGCCGAAA
->CP000248.1/722861-722994 Novosphingobium aromaticivorans DSM 12444, complete genome. 
-CCCCAACATCGAGAGTTGGGGTGACGCTCCAACGCCAACCTGCCGTTCCGGGCAAGGTGGTACCCGATCCGCAAGGCGGCCCCGGCCGAATTGCGAAAGGGGATGTGGCCGATCCGGCAACCAAACGGACACGG
->DS562862.1/42992321-42992756 Cavia porcellus supercont2_7 genomic scaffold, whole genome shotgun sequence. 
-AATGGCGGTGACCTCTGGTCCCGTCTGTCTCGTTTGTTCAGTCGTCCGTTGGTCAGTCGGTCGGTTGTCCCCCTCCCTCTGAGACGCGAGCTCAGATCAGACGTGGTGACCGGCTGAATTTAAGCATATTAGCCACCAGAGGAAAAGAAACTAACAAGGATTCCCTCAGTAATGGCGAGTGACCAGGGAAGAGCCCGGCGCCGAATCCCCGCCCTGCGGTGGGACAGGGGAAATGTGGGGAATGGAAGACCCGCTCCCTGGCGACACTTGTGGGAGGCCCAAGTCTTTCTGATTGAGGCAAAGCCCATGAACGGTGTGAGGCTGGGAGCGGCCCCCTGCGTGCTGTGTTCGGGGGAATCACGAGATGGATACTTAAATACCATAAGGGAAAGTTGTAAAGAACTTTGGAGAGAGTTCAAGTGGGCTTGAAACTGTT
->CAFZ01000031.1/6993-6912 Piriformospora indica DSM 11827, WGS project CAFZ01000000 data, contig: PIRI_contig_0034 
-CCACTCTTAGCTCAGTTGGTAGAGCGTGCGGCTGTAATTTCCCTAAACCGCAAGGTCGCTGGCTCGAATCCGGCAGAGTGGA
->JPZU01000001.1/1721226-1721354 Lachnospiraceae bacterium TWA4 TWA4_scaffold00001, whole genome shotgun sequence. 
-ACGAAACGATCAGCACCGCCGAAGACAGCAGGTGCCGTATGGCGTAAGGTGTAACGCCTGCCGAGACGATTTTAAGGAATGCCTTATATACCTCTCTGTCTTTGGATAGAGAGGTTTTGTTTATATACA
->LQBR01000004.1/128232-128109 Microbulbifer sp. ZGT114 ZB100003, whole genome shotgun sequence. 
-TAGCTGGTCTGTAAATATGCACGGGCCAGCCGAATCTTCAAAGCATATTACGACGAGGTAATTCGTTATGGCACTGACTGCAAATGAAAAAGCAGCCATCCTCAAAGAGCACGGCCAGTCTGAA
->CP009505.1/1989432-1989301 Methanosarcina sp. MTP4, complete genome. 
-CGGTTGCTTGCAAGCGGACCTCGAAGCCTCATTTCACACACACACACGAGAATCACAACGATTACTCTAGATGGATAGGTTCATCCCTTCTTCCTGTCCGTTCCGTTCGCTTGTGAGTACCACCCCATCATA
->CP021112.1/3034288-3034406 Pseudorhodoplanes sinuspersici strain RIPI110, complete genome. 
-TTTTATTTCGTGGACGCTTCTCATCGTAGGAAGGCGCATCGCTGGGGGTGGTTGAAACCACCTATGCCGGGCGATGCGCTGTTCAGGGGGCCTCACGGGCCCTTTTTTCTTTTCCCGGA
->AYZV02091783.1/3282-3039 Spinacia oleracea cultivar SynViroflay scaffold22748.con0008.1, whole genome shotgun sequence. 
-AGTAGAGTAAGAGAGCTTCCTTCAGCCCACTCATGGATGGAAAAAAGGGGTATTGAATTATCTGCCGACTCATTCATTCAAACACTGAGTAGAACAAACAAGGAATGTACAACACGCATGCGTACAGGGGGTGCAAGTGCAAGTGCAAGTGCAAGTGCTACTGTGATTGCGTGAATGATGCGGGAGATGATTTCATCCTTGTCTCTCCGTGCTTGGACTGAAGGGAGCTCCCTTTCTCTATTCC
->URS0000D6BD70_684738/1-44 Lactococcus lactis subsp. lactis KF147 DUF1646 RNA 
-GGTTGGGCGCAAGCTTCAAGACATATCTCCAAGGGTGAGGAGAT
->ASAF01269073.1/1229-1323 Nicotiana sylvestris Nsyl_contig269073, whole genome shotgun sequence. 
-CGGAGCCGTATGAGGCGGAAGTCTCACGTATGGTTCTCTAAGAAGGGAGTGACTACCTACAGGAGCTTCGACCAAGCACCACCGGTCAATTCCGC
->JNGA01002875.1/199-1 Arabis alpina cultivar Pajares Aa.chr2_contig_422, whole genome shotgun sequence. 
-CGACGGATCGCATGGCCTTTGTGCTGGCGACGCATCATTCAAATTTCTGCCCTATCAACTTTCGATGGTAGGATAGTGGCCTACCATGGTGGTAACGGGTGACGGAGAATTAGGGTTCGATTCCGGAGAGGGAGCCTGAGAAACGGCTACCACATCCAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCTGACACGG
->FP929041.1/559079-558959 Eubacterium cylindroides T2-87 draft genome. 
-ATAATGAGACTCCTGTCCAGCCACAGTCCGAGCGTGATATGCCCTGCTTCAGGGTGATGCCGTCGCAGGCAATGGGGGCAGCCGATTTGTAGAGATCCTACCGGGGGTGCAATTCCCGTGG
->CM001383.3/68159736-68159614 Felis catus isolate Cinnamon breed Abyssinian chromosome B3, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGTAGTATTGTTATAAGTCAAAATTTAGAAGAGTAAATCACATTCAAGCAAAAAGAAGCAAAAATAGATCTTGCTTCATAGATCTACACAAA
->AACT01034500.1/16165-16123 Ciona savignyi cont_34500, whole genome shotgun sequence. 
-GACTTCGAATCAGAAGATGAGGGTTCGAGTCCCTCTGTGGTCT
->CP003005.1/936847-936934 Myceliophthora thermophila ATCC 42464 chromosome 4, complete sequence. 
-GGCCGTGTGGTGTAGTGGTAGCATACTTGCTTTGGGTCGTGAGATTTCAATCTGCAAGTGGTCCCAGGTTCAAGCCCTGGCTCGGCCC
->MCOG01000628.1/21312-21242 Neocallimastix californiae strain G1 LY90scaffold_628, whole genome shotgun sequence. 
-GGAGGGTTGGCGCAATGGTAGCGCGTCCCCTCCAGAGCGGAAGGTTGGGTGTTCGAATCACTCACTCTCCA
->KB319013.1/681-1 Rhizoctonia solani AG-1 IA unplaced genomic scaffold scaffold1318, whole genome shotgun sequence. 
-GCAGCTCGAAAGCCGCATTTGCTCGCCACGCACGTGCCGATTTACTCGGCGTCTCGCGAGCGGGCTAAGGTCTGAGCATTCTAGTCCCCTTGTACGTGTGTCTAGCCGGCACCGGCTCCAACAGGGCCGAGCAGAGTATCAGACATGCGCTCGGTGCTGCTTGTTCCGCCCAGAGACCCGCAAGGGGAGGGCACAGCAGCACGTGAGCTTGGAACAACTCTGCGGGGACAGAGCCGTCTACTTGCCTCCCCGTCCCGAGTCTCTTTTTGTCCTCTTTCCCACCCGTGCGCTAGCCTCGAGAACTAGCGCCCAGTTTTTTCAGAGACTGAGCATCATGCATCTGACTCTTCCCTCGCTCCGCAAGGCACGGAGCAGTGTACGGCCTGGGTTGGCTTCTGGGCGCCGATCGAACCTGGGGATCTCACATCGCTACGACTGGCGCGGCAGCGCTGAGCACTGGGACTCCCCATGCCCGGCAAAATGCTCCGCGTACAGGTAACGAGCTCTTGTTTTCCTTTTATTTCCTGGATATTCCTGGAGAGGCCACGCTGGTGGTTCGATTGGTTGCGGTGATCGAGGAGGACGATCGGTCTTGGACGGGGAACGGGCGGCTCTTGAGTTCACTTTGCGGCTCGCAGTCATTCGCTTTGGCGATTGCGAAACTCGATTCAGACTACTCTT
->AFSB01087678.1/359-79 Heterocephalus glaber contig87678, whole genome shotgun sequence. 
-GAATGTGAGGGCAATCTGGATGTAACATGTTACCCCATTGATGGCCAGGGTTGATTCAGCTGTATGGCTGGTAGGCAGGTGTCCCCTTCCTCCCTCACTGCTCCAGGCGCGACCCTCCCTAAGCTTCGAGCACAGTTAAAGAGGATGACCACTGTTTCCTTGGTCAAGGGTTTACAAGTAGCTGTGCTCCCCTGCTAGAACCTCCAAACAAGCTCTCAAGATTTAAAAACTAAAAGGAGAATGGGAGTTGGGATATAGCTCAGTGCAAAGGCCCAAGATTT
->MKUQ01000060.1/39144-39044 Burkholderiales bacterium 70-64 SCNpilot_expt_1000_bf_scaffold_93, whole genome shotgun sequence. 
-CGATCTGCTCCGGGGTGCGCAGCACGCTGAGACGGGCCCAGGCCTGAACCCGAGAACTTGATCCGGTTAGGACCGGCGAAAGAAGAGCGATCCGTCGCCCC
->CM007893.1/130149511-130149874 Helianthus annuus linkage group 4, whole genome shotgun sequence. 
-TGTGTCGTAGACTAAGCGTGCATGACGGATGAGTCGTGCAGGCCGCCTTGAAGTACAATTCCCATCAAGCGATGGGTAGAATCCTTTGCAGACGGGTGACGGGATAGAATCCCCTATCAACTTTCGACGGTAGGATAGTGGCCTACTATGGTGGTGACGGGTGACGGAGATTTAGGGTTCGATTTCGAAGAGGGAGCCTGAGAAACGGCTACCACATCCTAGAAAGGCAGCAGGCGTGCAAATTACCCAATCCTGACACGAGGAGTTAGTGACAATAAATAACAATACCAGGATCAAACGAGTCTGGTAATTGGAATGAGTACAGTCTAAATCCCTTAACAAGGATCCATTGGAATAAACCATA
->AFEY01266293.1/3612-2555 Sarcophilus harrisii ctg7180002245042, whole genome shotgun sequence. 
-CCACATTCAGGGCCCCAGGTGGGGCAAGATGGCAGCCGAGGTTACACCCAGAGAGTCTTTAGAAATTCAATAGTAAGATATGATCAATTATCCAAAAGGCAATTGGATGGAAGAAGGAGATTATACAATCAATCAGCCAAAGGGCAATCAGAAGGTAAAAGGGGATTGAAATTAGGAAAAACAGAGTTGTATGCAGTAGAGACTACTGAGATATCATCCCCTGGAGAGGTGAAATCTGTTCCTGTCCAGCTTATAGATCCCTTGCCTCCAGGCACAGTAGGCTTGACCATTTCACCTCCTGAGGGTGCTTACAAAACAGTGGCCATGGACATCGGAATCCTCTAAGGAGTGTCTAACAACTCACCTGCCGAATCAACTAGCCCTGAAAATGGATGGCACTGGAGCATTGGGCCCATACCTGGCCGTCGCTGGCAATGGGCACAAAGCAGGAACAGAAACGTGTTGTTTCCTGAGAACAGATTCCGCACAAGGGAGGAAGGCACGAACTCACTCCTCAGGGGCTAGGCCACGATGAGTAGGAGGGCTGCTGCGGTGGGCCTGGAAGCCTAGGGCATGGGCCCAGGTGGAGCTGCCGCAGGTGTAGATCTTGGTGGTAGTAGCAAATATTCAAACGAGAACTTTGAAGGCTGAGGTGGAGAAGGGTTCCATGTGAACAGCAGTTGAACATGGGTCAGTCAGTCCTGAGAGATAGGCAAGCGCCATTCCAAAGGGACAGGCAATGGTCTCTGTTGCTCTCAGCTGATCGAAAGGGAGTAGCGTTCAGATCCCAGAATCTGGAGTGGCAGAGATGGGCCCTGTGAGGCATCCAGTGCAGTAACGTGCCTGATCCCAGAAAAGCCGGCTGGAGCCCCGGGGGAGAGTTCTCTTTTCTTTGTGAAGGGCAGGGCTGCCCTAGAATGGATTTGCCCTGAGAGTGGGCTTGTGGGCTTCTATATCTCCCAGAGTGCTCCTGGCTCTCAGTCTCCCAGAGTGCTCCTCTCTGACTCTTGTTGATGTTTCGAAGTAACTAACCCAAAGCTAAGAGCCTCTTTATACAT
->LGSR01000020.1/1425329-1425226 Escovopsis weberi scaffold00001, whole genome shotgun sequence. 
-GGCAGAGTGGCCGAGTGGTTAAGGCGATGGTCTTGAATCGTGGGTTCCCATGATAAAGCCAACCATTACGTTCGCGTGCGTAGGTTCGAATCCTGCCTCTGTCG
->JENH01053621.1/966-1 Agrilus planipennis Contig53639, whole genome shotgun sequence. 
-TTTAGTATAAATACTCTGTAAATATTGAAATAAAATTAGTCTAACACCAGGCTCACTCTTATTCTGATGCTGATAAAGTGTCAACCCTTGGGATCCTCAAAGATGCAGATAATGTATCCAACGGTATTACTAAATCGGTTCTTCTCAGAACCCCAACTTTGATAGTCACATCTCTCATCATATACGACTACAGAGAGTGGCTACAGTTGTATCATTTATTACTATTTATTATTTTAACGATTGACCATCTCAGGCTAGACCTTTTTCATCTAATAGCTTGACTCTGTGATATAAGAGTTGTGATATTTATGTGTGTGCGCCGTCCTAGTTTATTATTTTAGGTGACAGCTAGTAACCGATACCAGTGATGCGAGTCCTGGGTTTCAGTCCTGTGTGACGTGGGCCGACTCAGGGCGGCGAAGCGGTTGCTTAACGGCGTCCCAGACGTCTCCGGCGAATTCCGCTTTCTCAGCCAGAGAACTTCGCTTAACGATTTTTCCAAGGCCCGTATATGCCGATACTCCCTTTGAACAGGTCAAGTTTGACAGGTTTCCTCGGGCCAGGAGTCGTTAGTTCTATTGGGGGCGAGACTTAGATGACTCTACAAGGCATCGCTTTGGTACTCGAGGCGAAGCAGATGAGCCAAAGCTACTCGGCAAGGCTCATCGGAGCCGGGGTGCCGAATTAGGGCTTATGCTTGTCTAAGCCCTGTGGCAATCACGCCAGACCACCGTGGAAAGTGTGAGATCGCGGTCTCATAGAAATAGCCAAAAGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACCAGATTCTCTGTGACCCTACCCACTATCTAGCGAAACCACTGCCAAGGGAACGGGCTTGGAAAAATTAGCGGGGAAAGAAGATCCTGTTGAGCTTGACTCTAGTCTGGCACCGTAAGGAGACATGAGAGGTGTAGCATAAGTGGGAGACGGTA
->AAPU01006125.1/5918-6168 Drosophila mojavensis strain TSC#15081-1352.22 Ctg01_6126, whole genome shotgun sequence. 
-GGTCCATCAGGATAAGGATTGGCTCTGAAGATTGAGATAGTCGCGCTTGATTGGGAAACAATAACATGGTTTATGTGCTCTCTAAATAGAGATCTATCATTTTATGGTAGTTTCTAGTTCCCCGGATAGTTTAGTTACGTAGCCAATTGTGGAACTTTCTTGCTAAAATTTTTAAGAATACTAGCCGGGCAACCGATTAGTTCTTTTAAATTATAACGATTATCAATTAACAATCAATTCAGAACTGGCAC
->LBPO01000002.1/47954-48343 Parcubacteria (Magasanikbacteria) bacterium GW2011_GWC2_34_16 UR53_C0002, whole genome shotgun sequence. 
-GGTTGTTGGTGGATGATCGCTTTGCCTGTAAAGGCGGGGAGGAAAGTCCGAACACGCCTCTAGCGAAAGCTAGAAAGGATAGCGGGTAACGCCCGCCTGGAGCAATCCACGAGGTGCGAGCAGAGACGTCTAGGCTTGAAAAGGTCTAGAGAGCTAAACCCTGTATTCTTGATTAATCAGGAATAATAGCTTAATCCTGGCCATAGGGAAATAAGGTCAGGGGTGAAACGGCTAAATCCTTATCTGCGTGCAAGAGCAATGTTTCCTGTTGTTTAGACGGGATTCAGAAAGTTAGCTCGCTTTGATTCTAATGGAAACATTAGAACTAGATAAATGATCGTCGCCCAATTTATTGGGATACAAAATTCGGCTTATAGCCAACAATACCCT
->CM000856.1/137442353-137442632 Callithrix jacchus chromosome 1, whole genome shotgun sequence 
-GTCAGGTATGATGGCGCATGCCTGCAGTCCCAGCTACTTGGGAGGCTGAGGCAGGAGGAGTACTTGATCCCAGGAGTTCTGGGCTGTAGTGTAGTATAGCACTGCACTAAGTATCTGCACTAAGTTCTGCATCAATCAGGTTGCCTAAGGATGGTTGAACTAACCCAGGTGGAAACTGGAGCAGGTCAAAACTTCAGTGCAGTGCTGATCGGCAGCAGGATCTCACCTGTAAGTAGTCACGGCCCTCCAGCCTGGGCAACATAATGAGATCCCATCTCTA
->CP009129.1/1068541-1068746 Planococcus sp. PAMC 21323, complete genome. 
-TTAATGACAGCGAAGAGGACTAGTAGTTTGTGTATTTTCCACAGAGAGCCGGCGTTTGGTGCAAGCCGGTAAAATGCGCAACCGAACTCACCTTGGAGTCAGTGTATGTGAAACTAAGTAAGATACACCGTTTTCCGCGTTAAGGAGTCAAGTTGAGCGAGCAGTCGCTAATTTGGGTGGTACCGCGGGAAAATCCCGTCCCTTAT
->JTDY01000669.1/96851-97292 Operophtera brumata OBRU01_Sc00669, whole genome shotgun sequence. 
-GGTCATTATCACCACAATAGATGGCGCTGTTTGCAACTTTATACCAGGCTATACCTATATATATACATATCGACTTTGTTTTATAACTCAAGAAGTGGGCCGACAATTTTACTTTGAACAAATTAGAGTGCTCAAAGCGGGCTCAAAATGCTGCTTGAATATTTCGTGCATGGAATAATAGAATATGATCTCGGTTTTATTTTGTTGGTTTTCAGAACTCCGAGGTAATGATTAATAGGGATAACTGGGGGCATTCGTATTGCGATGTTAGAGGTGAAATTCTTGGATCGTCGCAAGACGAACATCAGCGAAAGGTGTTTTCATCAATCAAGAACGAAAGTTAGAAGTACGAAGGCGATTAGATACCACCCTAGTTCTAACCGTAAATATGTCATCTAGCGATAAAATTGACGCAATTTTGAAAAAAGAAATGAATCTTTAT
->FRBH01000005.1/40291-40383 Chishuiella changwenlii strain DSM 27989 genome assembly, contig: Ga0131172_105 
-AAGTAGCGACAGGGATTGACGTGAAAATCCTTTTTACAACTGAGATTCTCTCGAAGTTTAGTAAAAAGATTGTAACAAAAAGCCCGCTCGGTC
->FQWL01000004.1/126785-126917 Spongiibacterium flavum strain DSM 22638 genome assembly, contig: Ga0070522_104 
-TGGTTATCGAGAAAGGCGGAGGGACTAGACCCTGTGAAGCCTTAGCAACCCTTAGCACATCCCATCATCTGGGATTCTGAGAAGGTGCTACATTCTACCTAACATCGGTACATGATGATGGGATGGATAACGA
->KQ758491.1/45269-45062 Bacillus enclensis strain SGD-1123 genomic scaffold Scaffold10, whole genome shotgun sequence. 
-GGATATTCAATGATGAAGAGAGTAATTCCCGCGTGGATCTAAAAGCGAACCAGGGACGGTGCAAGCCTGGTGTGAAACCCGGAATGAAGCGCACTTCTGAGAAGTCTTTCCCCAAATTTCAGTAGGGAAAGACCGGGTAAAACCGTTAATTTATGAGCGCCCTTTCTGGGAATAAGAGTGGTACCGCGAGTCAAAACTCGTCTCTACA
->AHIQ01000233.1/47283-47180 Brettanomyces bruxellensis AWRI1499 AWRI1499_contig2762_scaffold53, whole genome shotgun sequence. 
-AAACCTAAARATGATGATTGAGAATTAACGCATAGTTCAACTGRTATCTATGAAGAAAATATTTCCATCAATATAGTCTTTCACCCCTATCTGATTTTAGGCTT
->URS0000D685E2_12908/1-80 unclassified sequences type-P1 twister ribozyme 
-AUGUUAAUGCGACCUAGUUACUGGUAACCGUAAUACCUAGUGCUAGAGGGUGGCAAGUCCCUUUAACGCAGAGUCGACAU
->CM000801.1/33200308-33200628 Oryctolagus cuniculus chromosome 12, whole genome shotgun sequence. 
-GTTAGCTCGGGCCGGGAGGAGCCGCCACCGCCGCCGCCGGAGGAGGAGGGGGAGGAGGAAGGAGAGAAGGAAGAGGAGAGGGGGCCGCGGTGACGACTCGGCGCCGGGGAGCCGGGCTCATGGACGGGTGAGGCGGCCGTGTGCGCAGACAGTGCTCCAGCCGCGCGCGCGCCCCAGGCCCTGGCCCGGGCCTCGGCTCCGGGAGCAAGAGGAGCTCGCGGAGGCGCCGAGGAGAGCGGGCCGTCCCGCAGCCCGAGCAGGAGAGGGAGCGCGAGCCGCGCCGGCCCCGGCCGGGCCTCCGAAACCATGAACTTTCTGCTT
->KB456266.1/1688805-1688699 Sphaerulina musiva SO2202 unplaced genomic scaffold SEPMUscaffold_7, whole genome shotgun sequence. 
-GCCCGCTTAGCTCAGGGGTAGAGCGCATCACTCGTATACCTGGATGGCTGTAAATCACCTGGTTTGGTGGGATGATGAGGTCATTAGTTCGATTCTGATAGTGGGCT
->CM001381.3/152175418-152175578 Felis catus isolate Cinnamon breed Abyssinian chromosome B1, whole genome shotgun sequence. 
-ATCGCTTCTTGGCCTTTTGGCTAAGATCAAGTGTAATATTAAAAGTTAATATTTCTGTAGTGCTTCCATTGCACAAGGTACTATTCTAAGTATTTTACATATATTGACATATTTACATTTCTAAAAACCTTAAAAGGTAGTCACCTTTTAAGGAAAGTATT
->AASG02000564.1/14627-14791 Ricinus communis cultivar Hale ctg_1100012361959, whole genome shotgun sequence. 
-GCCTTGGTGGTGAAATGGTAGACACGCGAGACTCAAAATCTCGTGCTAAAGAGCGTGGAGTCCTCGGGTAGTCTCCTCTATAAAGGCATTCCAGCTTCAGAGGTAGGTGAGCCAGGTCAGGAAGGAGTTTGACTGCTGGGATAGGATCGGATCCTATTCGAAGCA
->AZIM01000830.1/116066-116143 Ophiophagus hannah scaffold831.1, whole genome shotgun sequence. 
-CGATCTGGCTGCGACATGTGTCACCCCATTGATCGCCAGGGTTGATTTGGCTGATCTGGCTCCATGTACATCCCTCCT
->MUXU01000055.1/10129-9985 Moraxella caviae strain CCUG 355 355T_ctg_0000055, whole genome shotgun sequence. 
-ATTTGCTTGACGGAGTGCGGTTTGAGACCGCTGAGATTGCGTCTTTGGTGGGTGCGCCATTGGTGTTCCACATGAAACTTATAACGCAAAATCCGTTGAACCTGAACAGGTTAGTCCCTGCGTAGGAATCAAGCACGTCCGCCAT
->FQTY01000030.1/12262-12128 Tissierella praeacuta DSM 18095 genome assembly, contig: EK13DRAFT_scaffold00030.30 
-TGTTAATTAAATAGATTGCCGTAGACAGTAGGTACCTTAAGGTTTAATTTCCTACCGAGGTTGAGATTAATCTAATTTATAAAATTGAAATTAGGATCTCTCTGTGTCTACGGAGGGATCTTTATTTATTCGTCC
->JH835452.1/508250-508573 Erinaceus europaeus unplaced genomic scaffold scaffold00164, whole genome shotgun sequence 
-GGATGTGAGGGAGATCTGGCTGCAACATCTGTCACCCCATTGATCAACAGGGTTGATTCCTCTCATCTGCCTGGCTAGGGGGGTGTCCCTTCCTCCTGCACTGGCAGTGTGTCACTAACAAAGCTGCGGGCTCTGTTGAAGAGGACGGCCTTCCCGGAACAGAGACGGCTAGGTCTTCGGTTGAGGGCATATGAGTAGCTGCTCTCCCTTGCTAGAACCTCCAATAAAGCTCTCAAAATGTGTTCAAAATATTTTCGGATTACAAACAGAATTACTCTTCACTAGCAGACACGCAAAGACAATACATTATAGGAATTTCGTTGT
->HE999757.2/3449466-3449336 Carnobacterium maltaromaticum LMA28 complete genome 
-TTAGGTTAATAAATATTACCGAAGACAGTAGGTGGCGTAAGCCTTAAAATACCTGCCGAGGATGAATATATGTGAAAGCATACAACTATCCCTCTATGTCTAAGGTGACATGGGGCTTTTTGCTTTGAATC
->KZ114138.1/13605-9139 Helianthus annuus unplaced genomic scaffold HanXRQChr00c0817, whole genome shotgun sequence. 
-GCCCAGTCTTTCAGATGGGCTTGGCCCATTTCTGTAAAACGTATTTATACGTAAATGCACGTAACCGGCTGTCATTCTTCAACCCTAGCTCCTTGTGTGTGTGACGGCAGACCCTCACATCCGAAGCCAAATCCCTTTTGTTGATCATCCTTAATCTCGGTTAGTATCTGATATCGTATTACTTTTAATTGATTGCTGGAATGATTGATGTTAATTAGTGTGCTAACCGGCCGGACGTGGCTGTTGATCGGCCGGATACGGTTGATAACTGGCCGGACTTGTAATCATTAACCGATCGGATGTTGTTAACCGGGTATTGCTTATATGATAATCGAATAGTTGTTCGGATTCGTTATATGATGTTTGATTGTTAGTATGTTCATTCAAGATTTCGGTATGTGTTCATATGTTATGTTAATAAGGTTCGATAATGTGACATACTATGTTAATCGGCTTGGTGTACGCATAAATTAGGGATCACGATGGGTATTAGTATTATGATGATTGCATGATGATTTGATGATGATCCTATGATTGCTGCATGATTGTTGTTTGATCGATAATGTTGTTGACGGCTGTTAGCATGTTTAGGGTTTCTGAAATTGTAACTGTTGTTGACGTAACTGATATGTGTCGAAAGATACTTGTAGTCGAAACATAGTTGTCGAAACATAGTTGTAACCGAAAGATATCTGTTGACCGAAGGATAGATTTGACCGAAACATAATTAGGTTGACCGAAAGATGCCATTTGGTCGAAAGATGACTGGTGGTTCGAAACATAACAACCAGTCCGAAAGATAACTGTGAAAACTTGTAAGTGTCGAAAGATTACTGATGTGTCGAAAGTTAACAGTGGATCGAAGGATAGTGGCAATTATAAACATCCTTCGAAGGATGGAATGTATACATGAACTATTTGACATGCCATGCTTGATGATGAATGTTTACATTTGTAATTGTGTGCACTAGCTGATGAGTAACTAGGAAATGGTACGTGTTGCGCCGATGTACAAACTGACTGTTACGTGAACATTATATTGCATGCGAATCATTGTGAACATGAACTGATTTGTTATACATGCATACAATAGGACGTGATTAATTACTTGTGAGTACATAACCTAGCATACCGAGCAAACCAAGGTGAGTTCACACTCTTACTAAGGCATGGGATTCCCGGGTTGTGGGAATGGGTTAAAGGCTTGATGATAAACTAATAACGTACATACACTACGCTTTTCCTAGACTATCACCTATCATAGTCCTCGGATGTCAGGACGGTTCCGTAGGTTGGAAAACACCTACGTGGTTCCGTAGGTTGGGATAACACCTACGTGGTCAGATGCCAATTACTATCCTCGATACAAAGGATACGCACGTAAGACATACGTGTACGCATTACTTACTTCTTCCGTAGGTTGGGATAACACCTACGTGGTCATATGCAAATTACTATCCTCGATACAAAGGATACGCACGTAAGACATACGTGTACGCATTACTTACTTCTTCCGTAGGTTGGGATAACACCTACGTGGTCATAATACGAATAGTCTAGTGGTCACTTAACATGGGAAGCCCCCACCTGTATAACTTACTATTGGCCCGGTAGAGCCACCCGTTACTTACTATTACGCATTTACGTACTGTGAACTCGCTCAACTATTTTGTTGATCCTTTCTTTTACATGCCTTGCAGATCGTTAGGTACTGGGAGCTTGCACTGGAGGCGCGGACGTTGTGGACTTGGATCGTGAACATCATATGGAACCCATATGATACTTGATACACTTTTACATTGGATATTTTTATATATACGCTTCCGCTAAACATTGATAACTGGCTTATGTTTTGGAAACACCTTTCATATGGATTTGTTCTGAATTATACTGCAATTACTTTTACTTTATACAATGTTCTATATGATTGGTGGCTTGGTCCTGGTCAGTCACGCTCCCAAGCGGTGATACTCCGCGTGTGGATTTTGGGGGTGTGACACAACGGGTGAGTAAACCCGCAAGGCGCAAGGAAGCTGATTGGCGGGATCCCCCTCGTGGGGTGCACCGCCGACCGACCTTGATCTTCTGAGAAGGGTTCGAGTGTGAGCATGCCTGTCGGGACCCGAAAGATGGTGAACTATGCCTGAGCGGGGCGAAGCCAGAGGAAACTCTGGTGGAGGCCCGCAGCGATACTGACGTGCAAATCGTTCGTCTGACTTGGGTATAGGGGCGAAAGACTAATCGAACCGTCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGAGCCCGGGTGCGAGTTCTATCGGGTAAAGCGAATGATTAGAGGCATCGGGGGCGCAACGCCCTCGACCTATTCTCAAACTTTAAATAGGTAGGACGGCGCGGCTGCTTTGTTGAGCCGCGCCACGGAATCGAGAGCTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGGAAGCCGGGTTACGGTGCCAAACTGCGCGCTAACCTAGAACCCACAAAGGGTGTTGGTCGATTAAGACAGCAGGACGGTGGTCATGGAAGTCGAAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTTAAGCGCGCGACCTACACCCGGCCGTCGAGGCAAGTGCCAGGCCCCGATGAGTAGGAGGGCGCGGCGGTCGCTGCAAAACCTTGGGCGTGAGCCCGGGCGGAGCGGCCGTCGGTGCGGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTGAAGGCCGAAGAGGGGAAAGGTTCCATGTGAACGGCACTTGCACATGGGTTAGTCGATCCTAAGAGACGGGGGAAGCCCGTCAGATAGCGTGTTTCACGCGAGCTTCGAAAGGGAATCGGGTTAAAATTCCTGAACCGGGACGTGGCGGCTGACGGCAACGTTAGGGATTCCGGAGACGTCGGCGGGGGCCTCGGGAAGAGTTATCTTTTCTGTTTAACAGCCTGCCCACCCTGGAAACGACTCAGTCGGAGGTAGGGTCCAGCGGCTGGAAGAGCACCGCACGTCGCGCGGTGTCCGGTGCGCCCCCGGCGGCCCTTGAAAATCCGGAGGACCGAGTGCCTCCCACGCCCGGTCGTACTCATAACCGCATCAGGTCTCCAAGGTGAACAGCCTCTGGTCGATGGAACAATGTAGGCAAGGGAAGTCGGCAAAATGGATCCGTAACCTCGGGAAAAGGATTGGCTCTGAGGGCTGGGCACGGGGGTCCCTGTCCCGAACCCGTCGGCTGTCGGTGGACTGCTCGAGCTGCTTCCGCGGCGAGAGCGGGTCACCGCGTGCCGGCCGGGGGACGGACTGGGAACGGCCTCTTCGGGGGCCTTCCCCGGGCGTCGAACAGCCAACTCAGAACTGGTACGGACAAGGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGATGGTCCCTGCGGATGCTAACGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTGTCTACTATCCAGCGAAACCACAGCCAAGGGAACGGGCTTGGCAGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTGAGAGGTGTAGTATAAGTGGGAGCCCTCGGGCGAAAGTGAAATACCACTACTTTTAACGTTATTTTACTTATTCCGTGAATCGGAAGCGGGGCAACGCCCCTCTTTTTGGACCCAAGGCCCGCCTCGGCGGGTCGATCCGGGCGGAAGACATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGCTCAACGAGAACAGAAATCTCGTGTAGAACAGAAGGGTAAAAGCTCGTTTGATTCTGATTTCCAGTACGAATACGAACCGTGAAAGCGTGGCCTAACGATCCTTTAGACCTTCGGAATTTGAAGCTAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCCACCAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGATAGTGTCGCAATAGTAATTCAACCTAGTACGAGAGGAACCGTTGATTCGCACAATTGGTCATCGCGCTTGGTTGAAAAGCCAGTGGCGCGAAGCTACCGTGCGCTGGATTATGACTGAACGCCTCTAAGTCAGAATCCGGGCTAGAAGCGACGCGTGT
->FR881992.1/3645-4018 Firmicutes bacterium CAG:238 genomic scaffold, scf351 
-GGGGATGTAAAGGTTTCGACGGGGGTGTAGAAGCCGGATAAGCGAGCGGTAGTTGGCTCAGACTACCTTAAAAAGGGCCCGTTAAATATAAACGCTAAAAATAACAACAATTTCGCATTAGCAGCATAGTTCTGCAGCGCCTAAGGCGCGACGCGCGTCGGCCACAGCTCACCCGTAGGCTGTGATACCGGCGTCGACTATACGGGAAAACCTGCAGGGAGTTCTCGGTACCTCGCAGGGAACAACGAGATAGCCGACATGGCAGCATGTTAATGGGCGGCCACGGAGGCGAAATTTTAAAACATTGACTGCGCTCGGAGAAAGTCCTGTGGAAATGCTTTCGGACGCGAGTTCGACTCTCGCCATCTCCACCA
->AWUE01008835.1/507-1 Corchorus olitorius cultivar O-4 contig08862, whole genome shotgun sequence. 
-CAATAAGCAAAATAAGGGCGCACGGGGGATGCCTGTGGCTCTCAGAGGCGAAGAAGGACGTGATAAGCTGCGATAAGCTTCGGGGACTGGCACACACAGATTGATCCGAAGATTTCCGAATGGGGCAACCCGGTATGTTGAAGACATATCACACCGATAGGTGAGCAAACCCGCTGAACTGAAACATCTAAGTAGGCGGAGGAAGAGAAAACAAAAGTGATTCCGTAAGTAGTGGCGAGCGAAAGCGGATTAGCCCAAACCAGAGTTGTTACGGCAATTTTGGGGTTGTAGGACTGCGAGATTTCATGCAAAGGGAACTGGAATTAACTGGAAAGTTAAGCCATAGAGGGTGATAGCCCCGTATAGGTAACCGATGTAATGGATAGCAGTATCCTGAGTAGGGCGGGGCACGTGAAACCCTGTCTGAATCCGGCGGGACCATCCGCCAAGGCTAAATACTCCTGAGAGACCGATAGTGAACCAGTACCGTGAGGGAAAGGTGAAAAG
->URS0000D6AF63_12908/1-91 unclassified sequences DUF3800-VII RNA 
-GGCAGGCAAGCGCTAGGGGTATCCCCGAGTTACCTTCGGGCAGCAGCTGTCGGTGAGACAGTGGTACAGGGGCCTAGGGGTCTGCCGCTCT
->LL014082.1/6803-6907 Trichobilharzia regenti genome assembly, scaffold: TRE_scaffold0014079 
-TCCAAGTGCTCTGAATGTCAAAGTGAAGAAATTCAATCAAGCGTGGGTAAACGGCGAGGGTAACTATGACACACCGTCGAAAAATTAGTTCATCCTTCTAATGAA
->BAUT01000003.1/65796-65988 Bacillus wakoensis JCM 9140 DNA, contig:contig_3. 
-TTGAATATCGAGCAAATAGGTTTTTAGGAACGTTTCGTTCTAAACTAAGAGGGAAGTTGGTGCAAGTCCAACACGGTCCCGCCACTGTAAACGATGAGGAAGATTAGTATCGTCCACTGTGCGAGTTAGCATGGGAAGGATAATCGACAATGATTCGTAAGTCAGGAGACCTGCCTATTTGTCTTTAAGCTTC
->AF221911.1/108-513 Chelydra serpentina telomerase RNA gene, sequence. 
-TGCGGCGGCAGGTGGGGGCTCAGTCTTTCTAACCCTAAGCGAAATGTGACCCCTCCCCGCTGCAGCCGTCCGCTGTTTTACTCGCTGACTTTCAGCGGACGGGGGGAGCGGGTGGAGACGCCAACCAAAAAACGTCAGCGAGGGGCCCTCCCCTCCCACGCCGACCTGGGCCTGTGGTGGGGCCCGCCAGCGAAGTCCCCGCCGCCCCGCCCCGGTGAGGCCGCGGTCAGCCGGCTCGCGCCACTGCTGCCGCGAAGAGTTCGTCTCTGTCAGCCTCGGGGGCGGCCGGGGTGGAAGGGCGGGTCCCGAGCCCGTCGGCCGGGAGAGCAAACGTGAGCGGCAGCCCCTGCGCCACCGCCCTCCCCTAAGCTGTGGGGCCCGCGGTCGGGGCTGCGCTCAGACACGC
->AFSB01201159.1/18941-18806 Heterocephalus glaber contig201159, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGTAAAGATGTTGATATCTGATTTTAATTTTTAAAAATTCATTTATCTATTTTATTAGTACATGTTTCCAGTACGTAATGATTACATTTATCACAGGGAGTTACT
->AFSB01036238.1/931-791 Heterocephalus glaber contig36238, whole genome shotgun sequence. 
-TTAATGGCTTTGAGGCTATCTCATTTTCATTATACCAGAAGCACAACTGATTAGATACAATCAGCAACACCATAGCATTAAGTACATCTTAGAAAATGACAATTTGTAGTAGTTATTAATCTATCACCTTTAACTCTGTGA
->MFMU01000019.1/4604-5929 Candidatus Kaiserbacteria bacterium RIFOXYD1_FULL_47_14 rifoxyd1_full_scaffold_6810, whole genome shotgun sequence. 
-CATGAGAGACATAAGAGTACACGGTGGATGCCTTGGCCTAGGACGGCTAAGAAGGACGCGACTAACCTGCGAAAAGCTTCGGGGAGGCGGTTTGTAGCCTTTGATCCGGAGATATCCGAATGGGGAAACCCTCCAATTTTAAATTGGAATCCGCGGGGTAACGCCTGCGTGAAGCGAACCCGGGGAAGTGAAACATCTCAGTACCCGGAGGAAAAGAGAACAATATGAGTTGCGTTCCGTCGGCGCGTATGTTCGTGCTGATGGAACGCAACTCGCGTGATACCCTGAATAGCGGCGAGCGAAAAGGGAAAAGCCCAAACCTCATTTTTCGAAATGGGGGGTTGTAAGATATGAACGGCGTACTTGTACGCGAAGAGTTATCAATCGTCTTTATAGCAGAAGCTGCTGGGNNNNNNNNAGGTGAAAAGAACCCCGAGAGGGGAGTGAAATAGAACTGAAACCGTGTACTTACAAGGGGTCGGAGCGGTGAGTTTATTCGAACCGTGACGGCATGCCTATTGAAGAATGAGCCGGCGAGTGTGTGTATCTTGCGCAGCTAAGCCCTTACGGGGCGGAGCTTTAGGGAAACCGAGTGTGAATAGCGCGTCTGTAGGATACATACGACCCGAAGCCAGATGAGCTTGCCATGAGCAGGGTGAAGTTTGTCGAAAGACAAATGGAGGCCCGAACCCGTAGGTCGTACAACGCCTTGGGATGACTTGTGGTAAGGAGTGAAAAGCTAATCGAATCTGGGAATAGCTGGTTCTCTCCGAAACAGCTTTTGGGCTGGCGTTGCCATATCGCGTGCGTGGGGGTAGAGCACTGGAAGGGACCAACAGGGAGAAATCTCGTGGTTCCTATCAAACTCCGAATACCATGCACTCGGGCAGCAGTTAGAAGGTGGGGGCGAAGCTCCATCGATCGAGAGGGGAAGAGCCCAGATCGCCAATTAAGGCCCCAAAATCGACGCTCAGTACATCACAAGGAAGTGAGGACTCATAGACAGTGAGGATGTTGGCTTAGAAGCAGCCACCATTCAAAGAAAGCGTAACAGCTCACTCATCGAGAGTCCTTGCGCCGAAGATGATCGGGGTTAAGCGTCGTGCCGAAATTGCGGGTTTAATCCGTATTTATATAGATTAAGCGGTAGGAGAGCGTTCTGTTCGCGATGAAGCTTAAGGGGTAACCCATGGTGGAGCGTACAGAAGTGAGAATGCCGGTACAAGTAACCACAATGCGGGTGAGAACCCCGCACATCGAAAGACCAAGGTTTCCTCAGCTATGGTGATCAACTGAGGGTTAGTCGGGCCTAAGGGGATGGCGAGA
->CM008309.1/24191905-24191844 Astyanax mexicanus chromosome 10, whole genome shotgun sequence. 
-GATTATGATTGTGCAAGCAACTCTAGTGTATATACACTAGAGTTGCCTGCACAGTCAGAATC
->LODT01000020.1/379504-379185 Dictyostelium lacteum strain TK GAOABQK02G6SYV, whole genome shotgun sequence. 
-TTGTGTTACGTGAAGAATTGATCATAGAAGCCAACAAAACGCCTAGTTGCTCTGTCAACTATAAAACAACCAGATTTTCAAATCAAAATGCTTTTGGAAAAGTCCCCAGACCCTAGAACAGAAAGTGTTGCCCGTTAAGGTTATGATCAAGTTTTAGTTCACTCGACAGAGAAGGTATAAGATTCAAGTTTAAGTATTTGTGCTCTCTACCCGAGTCATTGGTGAAATTACTTGGTCACTGGTCACAGTAAAAGTAATATGAAATTAAGAATTTTAAATAAATATTCTCTACAAAATGGGGCTTACTCTCAACGTACACC
->DS562862.1/33829905-33829809 Cavia porcellus supercont2_7 genomic scaffold, whole genome shotgun sequence. 
-TGTGAGGGTGCCCTGGCTAGGACTGCTGTCCACCACTGAGCCCCAGGGTTGATTGGGTTGATCTAGTTGGGAGGGTGTCCCCTTCCTCCCTCATCAA
->CM002922.1/12055086-12055241 Cucumis sativus cultivar 9930 chromosome 1, whole genome shotgun sequence. 
-GTTTGTATTCTTCCACAGCTTTCTTGAACTGCATCCCTTTCCTGAACTCAATTCGCTCTTAATTTCCCCTTTCTCGATCTCTCTCGATCGATCTCAAAGCGTTTTTTGTTCATCAATTTTGTTGCGGTTCAATAAAGCTGTGGGAAGATACAGTCA
->CAJI01053789.1/175-1 Cucumis melo, WGS project CAJI01000000 data, contig: 53789 
-AATTAGCAAGGACCACCTTGCAAGCCTCTGACGGGGCTCCTGACTGACCTATAGTGAAGTAGTACCGTGAGGGAAGGGTGAAAAGAACCCCCATCGGGGAGTGAAATAGAAGATGAAACCATCAGTTTCCAAGTAGTGGGAGGAGACCAGGACTCTGACCGCGTACCTATTGAAG
->AEAQ01060326.1/1-120 Solenopsis invicta Si_gnG.contig39779, whole genome shotgun sequence. 
-ATGAAGAACGCAGCTAATTGCGCGTCAACTTGTGAACTGCAGGACACATGAACATCGACATTTTGATCGCACTTTGCGGTCCACGTATACAATTCCCGGACCACGCATGGTTGAGCGTCG
->ADWL01010905.1/30966-31223 Oryza glaberrima chromosome 5 Oglab05_0141_29, whole genome shotgun sequence. 
-GTGCCATGCATCTCTCTTATCAAGTTATTTCTGACAGCGGGGAATTCATTGACTGACTTGGCCTTGATTGATGATCCATCAACTCGTGGCTTTGCGCAGTGGGGAATTTTCCGCAATGGGCGAAAGCCTGACGGAGCAATGCCGCGTGGAGGTGGAAGGCCCACGGGTCGTCAACTTCTTTTCTCGGAGAAGAAACAATGACGGTATCTGAGGAATAAGCATCGGTAGTCTCGCCCTGCTTCAAAACTACAGGGCGCA
->LN554852.1/2943365-2943181 Moritella viscosa genome assembly, chromosome: 1 
-CTCCTAAGTAGAGGTGCGCAATTCATAAGTAGTGTTATTTAGGTAGCTCCAATAATAACAACACAAAAGGGAATTGCGCCGAAGAATGAATTTTAAGCTAAAAAAATTCATTCTGGTGATGTGTTCGAATAGAGACATCACTGTCATAGTCAATTTTATATTAACTATGGGGCGCTACTAAATAG
->KB706892.1/31142-31033 Eutypa lata UCREL1 unplaced genomic scaffold EL1_03_scaffold_1554, whole genome shotgun sequence. 
-TGGGAGTGGGACTATGTAACGAACAGCCCTCTTGCCTTTTACCAGATGGCTCCTTGCATAGCCCAAAATACTCCATTCCCTTAATCTTTGGAACCACTTCTCTGGAGCAT
->AEXM01000026.1/37053-36910 Anaerococcus prevotii ACS-065-V-Col13 contig00011, whole genome shotgun sequence. 
-AAAAACAAAGAAGCGCCAGATCCCTAGTGGATGACGAGGAAGACAGTTATCGAAAGTTCGGCGGGAGCTGTCTGGGTTCACAGCCCTAGTATTAGACAAAACATTTGAGCAATCAGATGGACAGAGAAGATACAGTGGCCTCAT
->BARX01000002.1/207412-207105 Agarivorans albus MKT 106 DNA, contig: contig00002. 
-TAGATTCCGTATAGTTGTTTGTGCACGGAGGCACTGACGTTTATCAGGATGAGAAACGTAGCAGGAGCTAAAAAGGAACAGCTACAGGAAGTAGCAAGGGACACCTCCTAGGAAGGAGACGTGCAACTGGTATGGATGACCGGTTATGCCATAGAAGGCTAAAGGACAGCTCAAAGGATTTGAGAAAAGGATAACTACAGGACGTAGTAACACAGTCAAAAAGGATTGCAGGGAGCAACTACCCGTTCACGGATTTGAGCGATATGACTACTAGGGGCGACACGAAAGTGTCGCCCCGACCTTTTTCT
->FR853096.2/50293108-50292759 Gorilla gorilla gorilla genomic chromosome, chr3, whole genome shotgun sequence 
-GCTGGGTGTGGTGGCACGTGCCTGTAGTCCCAGCTACTCGGGAGGCAGAGGCAGGAGAATTGTTTGAACCCGGGAGGCGGAGGTTGCAGTGAGCCAAGATTGTGCCACTGCACTCCAGCCTGGCGAGAGAATGAGACTCCGTCTCAAAAAAAAAAAGAAAAAAAATGTAGGGAAGTTTATGATTTGTAAATCAAACCAGGATGCTTGAAGATGAACCTTGTGGGTTTTTTTGTTTTTGTTTTTTTTTAAGAGACGGAGTCTCGCTCTGTCACCTAGGCTGGAGTGCAGTGGCACGATCTCGGCTCACTGCAACCTCCGCCTCCCAGGTTCATGCAATTCTCCTGCCCCTC
->MFUA01000016.1/12713-12896 Candidatus Nomurabacteria bacterium RIFCSPHIGHO2_02_FULL_37_13 rifcsphigho2_02_scaffold_5465, whole genome shotgun sequence. 
-ATAAGTATATACTAAAAGGGTTCATTAAAAAATCATGAAAAGTGATTGGGGAAACTGGTGACCTACCCGAAATGTTGCGCATAATGTTGCAGGCGGGGATTCCAGTACAGTGCCGCTACGGTAAGCCCACGACGTAAAAAATCGGGGACAAGTCCGAATACCAATCATTTTGTGTGTTTCCCGA
->CP001700.1/9933843-9933644 Catenulispora acidiphila DSM 44928, complete genome. 
-GTCGGGGCACCGCCGAATCCGTGTACGTCGCGGAGCCGGGGAACCAGGTTCGTCGGCGCGGCCCGCGCGGTAAGCGAGGGTGGCGCCAGTGGGGTGAATCGGTCGGCGTGCACTCGCCGTCGTGTGTGCGCGTGCGACCGTAGGGCTACTTCTTCAGTCCGAATCCGTCAGCTAACCCGGTAGGCGGACAAGGAGGAGAT
->JH930370.1/159056-159130 Tolypothrix sp. PCC 7601 strain UTEX B 481 genomic scaffold FDUTEX481_Contig13, whole genome shotgun sequence. 
-GTCCAGGTCGCCAAGTGTTTAAGGCATCGGCTTGCAACACCGACTGCTTCGTGGGTTGAAATCCCACCCTGGACT
->FCNR01000023.1/21709-21816 Eubacteriaceae bacterium CHKCI004 isolate CHKC4 genome assembly, contig: {contig23} 
-CAGCATTACTCTGGAGAGTCTTCACCGGCTTCGGCATACGGTGAAGCGCCGAAGGTGTACGGCAGATAGTTCTGCCAATCTCTCAGGCAAAAGGACAGAACACGTAAA
->KB016992.1/120673-120603 Camelus ferus unplaced genomic scaffold scaffold726, whole genome shotgun sequence. 
-TGGAGCAATGATGACTGCTGTGACATATGGGACCTACAGGATTAATCCCTGTCCGGAACGCTGAGGTCCAG
->CM001006.2/22879507-22879377 Mus musculus chromosome 13, GRC primary reference assembly. 
-TCTGCCCCTAGAGGCATTGTGGATGTGGCTCTTGTTCACCAGTAGGTGGCAGAGAGGAGAAAGGCTGTCTAAGCTCAGTGTTCTGACCTATGACATCTTTAACATTTCCTGAAAGAAACAAGCCTGACACC
->CP002734.1/2242961-2242819 Pseudopropionibacterium propionicum F0230a chromosome, complete genome. 
-GGCCCGCCCCACCGGGCTGGCGGCATTCAACGATGCACAGGGGAACCCGGTCGGATTCCGGGACTGACGCGCAACGGTGGGTGGACGCCTCCGAGGAGACATGCCACGAGTCCGAGCACCTTGCCAGCCCCCGTAAAGAGCCT
->KE695978.1/687932-687680 Alligator sinensis unplaced genomic scaffold scaffold505_1, whole genome shotgun sequence 
-TCAGCATCTCAGCCTTTTGGCAAAGAACAAGCAGTTTTGGCACCAAGGAGAGGGTTTCAGGGCTGGCTCTGGCCTTCCCAGTGCTGACCTGATATTGCAGTACCTCCAGGCCTGGTGCTAGTTCCCTGTGGAAGGAGGTGGGGGAAAGGTTCCCATCAGCATTTTTGGCATCAGCGGAGGGTGTTGAAGCTTGCTCCAGCTTCTCCACGTGCTGGCCTGGTATTGCAGTACCTCTAGGCCTGGTGCTTATTCC
->LL012517.1/9492-9054 Trichobilharzia regenti genome assembly, scaffold: TRE_scaffold0012516 
-CTGGTTGATCCTACCAGTAGTCATATGCTAGTCTCAGAGATTAAGCCATGCATGTCTAAGTACATACCTTAAAACATGAAACCGCGAATGGCTCATTAAATCAGCTATGGTTCCTTAGATCATATATACTACATAGATAACTGTAGTAATTCTAGAGCTGTTACATGCAATTATGCCCTGACCCGCAAGGGAACAGGTGCATTTATTAGAACAGAACCAACCAGGGGCAGTTTCGGCTGTCTCAGTCGGCCTTGTGTCGGTTACGGATCTTTCAAATGTCTGTCCTATCAATTTGTTGGTAGGTGATCTGCCTACCATTACAATAACGGGTAACGGCGAATCAGGGTCAGACTCCGGAGAGAAGACGGCAGCAGGCGCGAAAAATACCCACTGCCAGCACGGGGAGGTAGTGAAGAAAAAATATTGTAAAGTGTAGTCG
->NNAY01029724.1/129-174 Trichomalopsis sarcophagae strain Alberta scaffold29957, whole genome shotgun sequence. 
-CCATCGGCCCTTTTCAGGGCCACAAAAACATCCATACGTATCGCAT
->CM002290.1/17870538-17870716 Phaseolus vulgaris cultivar G19833 chromosome 3, whole genome shotgun sequence. 
-TGTTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTGAGAGGTGTAGGATAAGTGGGAGCTGGAAACAACGAAAGTGAAATACCACTACTTTTAACTTTATTTTACTTGTACCGTCCCGTATCCGGGCGTTGACAAAGTCAAGGTCAAAGTCAACGTCGGGGTCAAAGTCAACATA
->MKTJ01000058.1/456830-456745 Chloroflexi bacterium 54-19 SCNpilot_cont_500_bf_scaffold_42, whole genome shotgun sequence. 
-GGGCCGGTGTCAGAGCGGTTAATGTGCCTGTGTGCTAAACAGGTGTGGCCGAAAGGCCACCGGGGGTTCGAATCCCTCCCGGTCCG
->JH815307.1/89016-89141 Simonsiella muelleri ATCC 29453 genomic scaffold supercont1.8, whole genome shotgun sequence. 
-AAACAGCATTCAGAGTTGGATTTTCCATGCCAACCTGCCAACATTCAATCATGCTGGTAAGGTGGATAACGGTTTTAAGATCGTTGATGTGGTCTATTTTTAAAATAGGCAATCATGACGAAACTC
->HG917868.1/2308269-2308036 Clostridium bornimense replicon M2/40_rep1, complete genome, type strain M2/40T 
-TAATAAGCTATGAAAAAGAAAGTAGATTTAAGGAATAAAGTAGGGAGAAAAAGCCAAAGACTGAAAGCTTTTTTATTAGGAATTAAATCGAAGTTCACTTTGGAGCTCTCTAGGGGAAGTTATAGTAGTCTAGAGCGGTATTATAAAAGCCGATATTTTTTAATGAAGTGGATAAGGGTATGGATTATGCTCTTATCAACTAGGGTGGTAACGCGGATATACTCCGTCCCTTTT
->MNDT01000042.1/12913-12775 Archaeon 13_2_20CM_2_53_6 13_2_20cm_2_scaffold_3200, whole genome shotgun sequence. 
-GGGGCCGTCGTCTAGCTTGGTCAAGGGATTAGCCCCGCCCAGAGGATACCAGAGTCCGATTATGGACGGTGACCCTGGGGCGCTGGCGACCTCGAGAAATCGAGGCCAGAGGTCGTGGGTTCAAATCCCACCGGCCCCA
->JH210461.1/2478657-2478034 Pelodiscus sinensis unplaced genomic scaffold scaffold75, whole genome shotgun sequence. 
-ACCACTGAATTTAAGTATATTACTTGGTGGAGGAAAATAAACTAACCAGAATTCCCTCAGTAACGGTGAGTGAACAGGAAAGAGCCCAGCGCTGAATCCCCATCCCGCAGTGGGGTATGAGAAATGTGGTGTACAGAAGGCCCACTCTCCCCAGTGCCACTCTCAGGGGCCCAGGTCCTTCTGATAGAGGCACACCCTGTGGACAGTGTGAGTCCGGTAGCAGCCCCTGGCTTACTGGGACCAGGTCTTCTCGGAGTCAGGTTGCTTGGGAATGCAGCCCAAAGAGGGTGATAAACTCCATCTAAGGCTAAATACTGACATGAGACCAATAGTCAACAAGTACCATAAGGGAAAGTTGAAAAGAACTTTGAAGAGAGAGTTCAAGAGGGTGTGAAACCATTAAGGACATATAGGTGATCTAAATCTTTAATGCTTGAATTGGGTTGAATAAATGAATGGTACATTGACTAATACATAATAAAGGCATAGGAAAATGCATATTCATGCACTGAGAGTGAGACAGTCTTGTCACTTTTTATTTTCAAGATGGGAAATGCTATTCCCCTCCCTCAATTACTGGACTAATTCATACTTTTAATTAGTTTAACAATTTTTCAAAGAACT
->JHTR01000147.1/10830-11400 Villosiclava virens strain UV-8b Sca_147, whole genome shotgun sequence. 
-AAAAGCTCTTAAGGTAGCCAAGGGTAAGTCACGTGGGTATCTAGAGGTCACGTGACATTGGGCAAGTCACGTGGGATTACAGAAGGAAGACATAGGCCCACTGTCCCTATCTACTATCTAGCGAAACCACAGCCAAGGGAATGGGCTTGGCAGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTTTGACATTGTGAAAAGACATAGGAGGTGTAGAATAGGTGGGAGCTTCGGCGCCGGTGAAATACCACTACTCCTATTGTTTTTTTACTTATTCAATGAAGCGGGGCTGGATTTTCGTCCAACTTCTGGTATTGATTAATAGGGACAGTCGGGGGCATCAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAGGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGACGATGTTATTTTTTGACTCGTTCGGCACCTTACGAGAAATCAAAGTGCTTGGGCT
->MEPC01000031.1/22924-22691 Bacteroidetes bacterium RIFCSPLOWO2_12_FULL_37_12 rifcsplowo2_12_scaffold_5312, whole genome shotgun sequence. 
-CCTTTGCAGGCAATCAAAGGTGACATCCTATTTCTTTTCCAAGAAATTATTTGTCATAATAGGGAACCGGGTGAGAATCCCGGATAGTACCCGCTGCTGTAAACTCTAAAAAGTTTTATGCTTACGCTGGATGCTCAATCCGGTAGCCACTGTTAATCCTTTAATTTAAAGATAACGGGAAGGTGCAGAAAACGAGAGTAAGTCAGAAGACCTGCCTTTGAATTTATTTTTATT
->JXRR01000017.1/5494-5709 Jeotgalibacillus campisalis strain SF-57 contig00017, whole genome shotgun sequence. 
-CCTAATGCAATGATAAGGACCAGTAGATAATGCTGATACGAAAGAGATCGGAGTTCAGCGGCTGAAAGACTCCGACGTGCCTCACATTATTGAACCTGCCTTTGAGCGACAGGAAAACCTGTCCGTTCTCCCTCGTTACGGGTGAAGAAGAGTGCCGGATTATTCATGTTCGGCAAATTAAGGTGGTACCACGGAAGCAGCCCTTTCGTCCTTTTA
->DS544962.1/17936-20730 Physcomitrella patens subsp. patens PHYPAscaffold_73 genomic scaffold, whole genome shotgun sequence. 
-ATTTAGGATTTAGGATTTGTTTAGGATTTAGGATTTAAGATCTACTTAAGGTTTAGAATTTAGGATTTTTTTAGGATTTAGAATTTAGGATTTGGCCTAAGATTAGATTAAAGTCTATTAAGGTTTTAACCAAGATTAAATTAAGACTTGGTTAAGATTTATTTAAGATATATTTTTTATTATTCTAATAATTTTTTAGGATTTCTTAGGGATTCTTTTAAGGTTTATTGTAGATTTCTTTTGATTGCTTTTAAGATTTCTTATTCTTTCTTTTATGTTTTCTTTAAGATTTCTTTTGAATTTGATTAAAGCTTATTTAACATTGTTAAGATTTAATTAGAATTTATTTAATATTCTATTAGAGTTAAGATTTTGTTATTGTAATTTCTATTCTACTTTCTACAACTATGAGCCTAGTACATTCTTTAGCAAGACTTTATGTAATATAACAATGTTTTCAAAAATCTTCATACAAATTGAATTTTCTTATCTAATATAATATCTTTAGATGGTGAACTATGCCTGAGCAGGACGAAGCTAGAGGAAACTCTAGTAGAGGCTCGTAGCGATACTGACGTGCAAATCGTTCGTCAGACTTGGGTATAGAGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATAGTTAGAGCTCGTATAAGAGTTTTATCAGATAAAGCGAATGATTAGAGGCATCGGGGGTGTAACACCCTCGACCTATTCTCAAACTTTAAATAGGTAAGCCGACGGGGTTGCTTGGTTGAACCCCGGCACAGAATGAGAGCTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGAAAGCCAGGTTACGGTGCCAAATTGCGCGCTAACCTAGATCCCACAAAGGGTGTTGATTGATTAAGACAGCAGGACGGTGGTCATGGAAGTCGAAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGTCCCGAAAATGGATGGCGCTTAAGCACGCAACCTACACCCGGCCATTGGGGCGAGTGTGAGGCTTCAATGAGTAGGAGGGCATGGGGGTCATGGAGCAGCTTTGGATGTGAGCCCGAGTGAAATGGCCCCTAGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTGAAGACTGAAGTGGAGAAAGGTTCTATGTGAACAGCAATTGGACATGGGTTAGTCGATCCTAAGAGATGGGACAATCCTGTGTCAATGGCGCAATGTGCGTCGTGCATCGAAAGAGAATCGGGTCAATATTCCTGAATCGGGACATGGCAGTGGACGGTGACGTGGCTGAATCCTGAGACGCCGACGGGGGCCCCTGGAAGAGTTCTCTTTTCTTTTTAACAGCCCGCCCACCCTGGAATCGGATTACCCGGAGATAGGGTCCAGCGGCTGGTAAAGCACCGCACGTCTTGCGGTGTCAGGTACATCCTCGGCGGCCCTTAAAAATCAGGAGGAGCGATTATTGATCATGCTCGGTCGTACTCATAACCGCATCAAGTCTCCAAGGTGAACAGCCTCTAGTCGATAGAACAATGTAGGTAAGGGAAGTCGGCAAAACAGATCCATAACTTCGGGAAAAGGATTGGCTCTGAGGGTTGGGCCTAGGGGTCTGTGCCTTGACCCCGTAGGCTGTCGGAGGTCTGCCCGAGCTGCTCTCGCCGCGATGGCGGACCCCTGCGTGCCGATCAGGCGACGGATACAGAATGAGGTCTAGAGGGTGGGTGACTGCCCCCCTGCCTCGCTTTTCCCTAGGCAGTGAACAACCGACTCAGAACTGGTACGGACAAGGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGATGGTTCCCACGGATGTTGACGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACGAAGTGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTATCTACTATCTAACGAAACCACAGCCAAGGGAACGAGCTTGGAAAAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTAAGAGGTGTAGAATAAGTGGGAGCCCTCAAAGCGTAAGTGAAATACCACTACTTTTAACGTTATTTTACTTATTCCAAGAGGTGGAGGCGGGACTCTGTCCCTGCTTCTAGTCTTAAGGCGCGCCCCTCGGGTGCGCCGATCCAGGTGGAAGACATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTTAAAAGATAATGCAGGTATCCTAAGATGAATCAACGAGGACAGAAATCTCGTGTGGAACAAAAGGGTAAAAGTTCATTTGATTTTGATTTTCAGTACGAATACAAACTGTGAAAGCATGGCCTATCGATCCTTTAGTCTTTCGAAATTTGAAGCTCATGAATATCTATAATAGTTATAAATCTATTTTTACTTCCATTAAAAGTAGCATTTACAATCTTTCCTTCTATAGACAACTCAAACAACTTCAAAAATTTAAATTAAAAGAAGATAATCTACAACCTTTAATATCAAATGAAAATTTCTACAAAGAGAGATAATCTATTTTTTTAAGAAAAAAAATAGTGTTAAAAAAACTACACTATTTATTTAAAGGTGAGTAGTCTACAACCTTCAAAATATAATAATAGAAGTAGAATAATCCACTCACTTCTAAAACAAG
->LOEY01000035.1/5228-5158 Lutibacter sp. BRH_c52 BRHa_1002952, whole genome shotgun sequence. 
-TATCTTTGCCAACTGCAAACCAAAAGGTTTAGCAATACATAAAAATTATTAATAAAATTAATGTTAGCATG
->MEEQ01000424.1/3292-3474 Bacterium SCN 62-11 ABS71_C0424, whole genome shotgun sequence. 
-GGTCGCCTGCAGAGTAGGTGTTGGAGCTTACAATCCTGGGCCAATGTAACAACCTCGGATGTGATGAGCTATCCCTGTGTCGAGTGCCGCGGTGCGGAGTCCTGACGGGGTAGCCCAAGGTCGCGTCCACCTGCTTTGAGCAGGTCCAGGGGTTCAAGCTCGCCACCGCTCAGGTGGGTCCCT
->CM003505.1/6777488-6777685 Vigna radiata var. radiata cultivar VC1973A chromosome 2, whole genome shotgun sequence 
-TCCAATATGCTGCCTTTGCCTGCATTTGCACCTGCACTTTACTTGCTTTTCTCTCTTCAACTATCTACCTGAATTAGTCCCTACAAAACACACATTTTCATGGAAAAAAACACAAGATTACGTTGTGTATGTGTGTGGGAATGGATGAGAAACCAAGCACGAGGTGCAGGTGCATCTGCAGGCGAATGACATCTTGGA
->KQ435782.1/726561-726383 Melipona quadrifasciata isolate 0111107301 unplaced genomic scaffold scaffold99, whole genome shotgun sequence. 
-ATTGCTTGACGAGAATAAAAGTTATCTGTTCTTATCAGCTTAATATCTGATATATGTACTTCCCATAGAAAAGTCAGAATATTAACCTAATTTTTAAAAACCGGTGGAATTGGCCAGGCTCGCTCTTCTTCTGTCATAGATTGGCCCAGTATTGCAGTGCCATTGCCAAGCTGTGTTTT
->ADNT01000040.1/13066-12970 Aerococcus viridans ATCC 11563 = CCUG 4311 strain ATCC 11563 contig00050, whole genome shotgun sequence. 
-ATAAAAAGAGGGAATGAGGTTCTCCCTGGTCAAGTAGATGGTGATTTTAGGCCATCCCATACCGAACCGCTGAAAAGCTGATGACTTCTGCAAGTAA
->LK941638.1/22456-22528 Angiostrongylus costaricensis strain Costa Rica genome assembly, scaffold: ACOC_scaffold0001535 
-GCCTCATTGTCTCAGAGAGTAGAGGGTCAGCCTTTTGAACAGGAGGTCTCTGGTTCGATTCCAGCAAGAGGCA
->NBLS01000022.1/6421-6598 Desulfobacteraceae bacterium 4572_19 ex4572_19_scaffold_9363, whole genome shotgun sequence. 
-ATCATTATATTATCATTCAGCAAACGGAACACGGTGTAAATCCGTGGCATATCCCGATGCTGTAACCCTTTTTGTTTTCTTTGGCATTTTTTAGTCACTGTTGTAATGTTTTTTTACAATGGGAAGGCTGTCTAAAGATGGGGAAGCCAGAAGACGTGCTGAATGATTAAAACAAGTT
->CAGS01000178.1/3560-3832 Nitrolancea hollandica Lb, WGS project CAGS01000000 data, contig: 00259-1568 
-GCAACGGCTATGACGGAAACGAGTACGCGGAACACCACGTTTAGCGAGTCCGGGGCCGGTGGAAGCCGGATAATGTCGGGTTTCGCGGAAAATCCTTCCCGAGCCGCCACCTGAACCGTCTGATTTGGACGTAGTAAGCATGGCCGGGGTCGTCGCCCGTTATCGCGACGGAGATGCCGGAGCATCCTTCATCACATCGCGCGGCATCTCGGAAAGTGGGTTCCGTTTACCGGACCAACTGAGGTGGTACCGCGGGTTATCCCCGTCCTCAAC
->AADN04003456.1/8626-12973 Gallus gallus breed Red Jungle fowl, inbred line UCD001 Contig3860.1, whole genome shotgun sequence. [11-NOV-2016] 
-ggacctcaggtcagacgtgcgacccgctgaatttaagcatatagtcagcgggaaaagaaactaacgaggattccctcagtaacggcgagtaagagggaagagccccagcgccgaatccccgcccccgccgtggggccgcgggaggtgtggcgtaccggaagccccccatccgccgcgcccgctctcggggggcccaagtccttctgatcgaggcccagcccgcgacggtgtgaggccggtagcgccccccggcgcgccgggcccggggcttctcggagtcgggtgcttgggaatgcagcccaaagcgggtggtaaactccatctaaggctaaatacccggcacgagaccgatagccaacaagtaccgtaagggaaagttgaaaagaactgtgaagagagagttcaaagagggcgtgaaaccgttaagaggtaaacgggtggggtccgcgcagtcgcccggaggattcaacccggcgggccaagtcggccggcgcgggcgccgtcgatccccgcctccgcctccccctccgtccctccccttcgccgggcggggcgggcccaggggggcgggcgggccggggaccgccgcccgccgcgtccggccccgtcggcgcattcctccgcggcggtgcgccgcgaccggctccgggacggctgggaaggctgccggcgggcaggtgcccggcgccggcgcgagcggccgccgggtgttaagccgccgggcccggatcgtcgccgaatcccgggccgaggagaggaccgccgccgcccctcccccgagggcggccccccggagggccccccgcgccgaccgcgtcgggccggccgcgccgcgcgcgcgtccgcgccgccgccgtacgccgccgccgctctctctccgttccccgccccgggtccgtccgggcgcggggcgggggggtcgggtgccggcgcggctcggcgcggcgccgcgcgtgtggcgcgcggcctccagcccggcgcgggcgaggccgcgggggcgccgggggggaaccttcccccttctgtcgggccgcctccgttcccgcggggcggcccgttcgggggacgggcccgccgccccgcgcgctgtccgaccaggggcggactgcgctcagtgcgcccgaccgcgcggcgccgccggccgggccggccacgccagcgcccgggtccgcggcgacgtcgctaccccccgacccgtctgaacacgaccaaggatccagcacgcgccgcgagtcgcggctcgcgcgaaagcccgcgcgcaatgagggagggccgcgcgcgccgctgagtgggatcccgggcggcaggccggaaggcccggcgcaccaccggcccgtctcgcccgcctcgccggggaggtggagcatgagcgcgcgtgctagacccgaaagatggtgaactatgcctggcagggcgaagccagaggaaactctggtggaggtccgtagcggtcctgacggcaaatcgtcgtccgacccgggtataggcgaaagactaatcgaaccatctatactggttccctccgaagtttccctcaggatagctggcgctcgggcggcggtgcagtttacccgtaaagcgaatgattagaggtcttggggccgaaacgatctcaacctattctcaaacttcatgggtaagacgcccgctcgctgcgtggagccggccgtgaatgcgagcgctcagtgggccacttttggtaagcagaactggcgctgcggatgaaccgaacgccgggttaaggcgcccgatgccgacgctcatcagagcccagaaaaggtgttggttgatctagacagcaggacggtggccatggaagtcggaacccgctaaggagtgtgtaacaactcacctgccgaatcaactagccctgaaaatggatggcgctggagcgtcgggcccatacccggccgtcgccggcggtgcggagccgcggggctaccgccgcgacgagtaggagggccgctgcggtgcgcctggaagcctggggcgcggccgggtggaggccgccgcaggtgcagatcttggtggtagtagcaactattcaaacgagagctttgaaggccgaagtggagcagggttccatgtgaacagcagttgaacatgggtcagtcgtcctaagcgataggcgagcgccgttccgaagggacgggcgatggcctccgttgccctcagccgatcgaaagggagtcgggttcagatccccgaatccggagcggcggagacgggcgccgcgaggcgcccagtgcggtaacgcaagcgatcccggagaagccggcggggagccccgggagagttctcttttctttgtgaagggccgggcgccctggaacgggttcgccccgagagagggggcccgcgccttggaaagcgtcgcggttccggcggcggtccggtgagctctcgctggcccgtgaaaatccgggggaggagggtgtaaatctcgcgccgggccgtacccatatccgcagcaggtctccaaggtgaacagcctcttggcatgttggaccaatgtaggtaagggaagtcggcaagccggatccgtaacttcgggataaggattggctctaagggctgggtcggtcgggctggggcgcgaagcggggctggcgcgcgccgcggctggacgaggcgccgcccgcccccgccccccctttccccgctcccgctcgccggggcgccgggggggggtcagcgggcggcgcggcggcggcgactctggacgcgccgccgggcccttcccgtggatcgccccagctgcggcgggcgccgctcgcccccctccttgcccctccgcccccccgctcccggcgcccctcccgtcggccgtcgtcccggccgccccccgtcccgagcgccctcctccgcgaggggcgcgaggggcggcggcggcggccgcgggcgcggcggcggcgggggggggggccgccggcggcgccgggcggggcggtcccgggcggggggggtctccgggccggcgccccgctcggccggcgcctagcagccggcttagaactggtgcggaccaggggaatccgactgtttaattaaaacaaagcatcgcgaaggcccgcggcggtgtgacgcgatgtgattctgcccagtgctctgaatgtcaaagtgaagaaattcaatgaagccgggtaaacggcggagtaactatgactctcttaaggtagccaaatgcctcgtcatctaattagtgacgcgcatgaaggatgaacgagattcccactgtccctacctactctccagcgaaaccacagccaaggaacgggcttggcggaatcagcgggaaaagaagaccctgttgagcttgacctagtctggcgctgtgaagagacatgagaggtgttagaataagtgggagccccgcggtcgcgcgacccgcgccgcggcccggccgccggtgaaataccactactctgatcgttttttcacttacccggtgaggcggggggcgaccccgagggctctcgcttctggcgccaagcgcccggcgcgccggcgcgacccgctcccgggacagcgtcagtggggagtttgactggcggtacacctgtcaaagcgtaacgcaggtgtcctaaggcgagctcagggaggccagaaacctcccgtggacagaagggcaaaagctcgcttgatcttgattttcagtacgaatacagaccgtgaaagcggggcctcacgatccttctgactttttgggttttaagcaggaggtgtcagaaaagttaccacaggataactggcttgtggcggccaagcgtcatagcgacgtcgctttttgatccttcgatgtcggctcttcctatcattgtgaagcagaattcaccaagcgttggattgttcaccccactaataggaacgtgagctgggtttagaccgtcgtgagacaggttattttaccctactgatgatgtgttgttgcgctagtaatcctgctcagtacgagaggaaccgcagttcagacatttggtgtatgtgcttggctgaggagccactggagcgaggctaccatctgtgggattatactgaacgcctctaagtcagaatcccccctaaacgtagcgataccgcagcgccgaggcgcctcggtgggcctcgcgatagccggccgccgcccccctcggcgggcggtcggtgcggagcgccgctcgtggtcgggacccggagcgcggacagatgtggcgccgcctctcccccgccgcgtaccgccatgttcgtggggaaccccggtgctaaatcattccgtagacgacctgattctgggtcggggtttcgtacgtagcagagcagctccctcgctgcgatctattgagagtcagccctcgacacaaagctttgt
->KE695965.1/2672926-2673057 Alligator sinensis unplaced genomic scaffold scaffold337_1, whole genome shotgun sequence 
-GCATCTAAATCTTTCCTGTTCCTTGCAATACAGTGCAGGATTGGGGACACATGGTGCTACAGCAAAGCAGAGTGAATCCAGACAGGTTTCTTCACTTATACTGGGACTTGTCTCTACAACTCTGCAACATTT
->LNAL01000007.1/177069-176668 Cytophagales bacterium MC1A Contig_23, whole genome shotgun sequence. 
-GTGATGCGCCGCCCCACCGCTGCGCCCGCAAGGGCGGAGAGGAAAGTCCGGGCAACGCAGAGCACCCTGCTTCCTAACGGGAAGGACGACGGCGGGAGACGGCCGCCGGACAGCCAGTGCCACAGAAAACTACCGCCTAAGCTGCCCTCGGGCAGCCGGTAAGGGTGAAAAGGTGCGGTAAGAGCGCACCAGCGGGCGGGCAACCGTTCCGGCTGGGTAAACCTCAGGGGTTGAAAGGCCAAATAGGCCGGCAGGCGGGGCTTCGGCCCTGCAACGGGCGGCTCGTTCGTTGTCGGCGGGTAGGCTGATGGAGCCCACGCGCGAGTGTGGGCCTAGATAAATGGTGGGGCCGCTGCCCTTCGGGGTGGCGGACAGAACCCGGCTTACAGGCGCATCACCAAA
->ACPB03012429.1/2213-2327 Rhodnius prolixus Rhodnius_prolixus-3.0.3-164.10, whole genome shotgun sequence. 
-ACTAACTTTAGAACTGTATTTACTATCTTTGTGGGAACGATACAGAGAAGATTAGCAAGGCCCCTGAGCAAGGATGACACCGGCAGACGGAACTCCCATGCCGCAGAATGTTTTT
->GK000028.2/19825245-19825332 TPA: Bos taurus chromosome 28, whole genome shotgun sequence. 
-GAGTTGGACACGGCTGAGCAACTTTCACTTAAATTACTCTAAAAGAAATGAATCCTAGATGGTTTTCCATCCAAGTCAAGTGTCTTGT
->JJRV01059395.1/8054-8163 Calypte anna contig59395, whole genome shotgun sequence. 
-AGTATTGATTTCTTAAAACAAAAAGCAGTGCTGCAGTAATTTCAGCAGCTGGCATTGTTGGTTTTCATGCAGATGTGCTGGTTAAACTTGGTATCGCTGCTGAAACAATT
->MGZC01000016.1/20791-20922 Gemmatimonadetes bacterium GWC2_71_10 gwc2_scaffold_12486, whole genome shotgun sequence. 
-GGAAGCCGGTGGAACTCCGGCACGGCCCCGCCACTGTAACGGGTTGGGAGCAGTTGCTCCCCACGGCGCCTCACATGCCACTGGCCTCAGGCCGGGAAGGCGAGGCGGCCGCGACACCCGAAGTCAGGAGAC
->KB915673.1/27675-28419 Neofusicoccum parvum UCRNP2 chromosome Unknown NP2_03_scaffold_35, whole genome shotgun sequence. 
-GGAGCCTGCGGCTTAATTTGGCTCAGCACGGGAAGATTCACCAGGCCAAGACACAGTAAGGACTGACAGATTGAGAGCTCTTTCCTGATTTTGAGGAAGGTGGAGCATGGCCGTTCTTAGTTGGCAGAGTGATCTGTCTGCTTAATTGCGACAACGAACGAGATCTTGACCTGCCAGGCCCGTTTTGGCGGATCGTCGGCTTCTTAGAGGGATGATCGGCTCAATCTCATGGAAGTTTGAGGCGATAACAACTTAACCATTACACGCATGTGATAACGGGGCCCCGACTTACTTTCGTGGGATTTTCCGCCAGTCGATCGTCCGTGACCGTTGGGCAAGCGCCCTAGTATCCAGCAGTCGGGCTGCTGAAGGGCAGCCTAGGATACAGCAAGACAGCCTGGTTTTGGGACTCCAGTTCAGGCTGATCAATCCCGAGGCAAGTTACTATAGCGAGCACCCGTTATAATGCTAAATCCTTATTAATAGAGCTCGTAAGAAAAGGCCTGATACATCGAAGCGTACGGGAGTCACCGAGCAAGGTGGCTGACATGAATTGTTGTTAAGCTCTTAGATTTTCAGGGCCGCCTGCACGCTACGCCAACAGAGTAAACGAGTTTGCTACCCTGGCCGGAAGGTCCGGGGGATTTTTTGAAACTTTCCCGTGCTGATGATACAGCACTACAAACTTCTCAGAGTGTCTGGTGTGCTATAGCCGGCCCTGAGATTAGCGGCACTTGTGTAGAAT
->KB822693.1/397760-397927 Marinobacter nanhaiticus D15-8W genomic scaffold super1, whole genome shotgun sequence. 
-ATCTCCATAGACTCAATAGCAGAGGAGACTCTGACATGTATATGGATGCTGTCGTTTTCGCAGGTATCGCTACCGTCGTCCTGATATTCGGCTTCTTTGGCGGTGTGGGTTATTTCATTTACAAGGACTCCCACAAGAAGTCAGACGAGAAGCACTAACCGGTTCCAG
->ALWS01089583.1/31226-31330 Pteropus alecto contig89583, whole genome shotgun sequence. 
-ACATATGATTTTATTTTCTTCAGAAAAACTTAATTTTATAAGCAGGGTCGGGCCTGGTTAGTACTTGGATGGGAGACTACCTAGGAAGACCAGGTGCTGTAGGCA
->FRAG01000030.1/20374-20550 Clostridium caminithermale DSM 15212 genome assembly, contig: EJ27DRAFT_scaffold00030.30 
-TTAAGCCTAGGATGTTCGTTAAAGCCTTGAAATTCAACCACCAATAAGCATCCGGGAGTCCAGGTTTTTATGGCGATGACGGGCCTCAATATAGTGGAAGTCAGAACTATAGAATAGGACACCCACCTAGGTGATACCGGGTGTGAATTTACAAGGTAACGACATCTTGGGTATATA
->LM154274.1/11133-10866 Schistosoma mattheei strain Denwood, Zambia genome assembly, scaffold: SMTD_scaffold0004766 
-TGTGGTCGCACATAAATCGGGTATGATAATCCAAACATTTCATCATCTAAATACCTGAGAGGGAGCCTGAGAAATGGCTACCACATCCAAGGACGGCAGCAGGCGCGAAAATTACTCACTCCCGGCACGGGGAGGTAGTGACGAAAAATACAAATACGGGACTCAGTTGAGGCTCCGTAATTCGAATGAGTGCAATCTAAATCCTTTAACGAGGACCAATTGGAGGGAAAGTCTGGTGCCAGCAGCCGCGGTAACTCCAGCTTCAAAA
->GL378999.1/3793-3024 Volvox carteri f. nagariensis unplaced genomic scaffold VOLCAscaffold_724, whole genome shotgun sequence. 
-NNNNAATGTATGCGAGTTGGCGGGTTGAAAACCCGTAAGCGCAAGTAACCTGACTGGTGGGATGGCCTGTGCCTGCACCATCGACCGACCATGTTGCTTTTGCGAAAGGTTTGAGTGCGAGCATACCTGTTGGGACCCGAAAGATGGTGAACTATGCCTGAGCAGGGTGAAGCCAGAGTAACCTCTGGTGGAGGCTCGTAGATGTGCTGACGTGCAAATCGCTTTTCAGACTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCCTCCGAAGTTTCCCCCAGGATAGCTGGAGCTTGATCAGTTTTATCGGGTAAAGCGAATGATTAGAGGTTCGGGGGATGAAACATCCTTCACCTATTCTCAAACTTTAAATAGGTAAGACGTGTCGGTTGCTTAACTGAACCGTCACATTCAATGTGAGCTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGATAGTCGAGTTAAGGTGCCAAACTGCGCGCTAACCTAGATCCCACAAAGGGTGTTGATTGATATAAACAGCAGGACGGTGGTCATGGAAGTCGAAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAATTAGCCCCGAAAATGGATGGCGCTTAAGCGCGCGACCTATACTCGGCCATGGATGCAAGTGCGACGCGTCCATGAGTGGGTGGGCGTGTCTCAAAGATTAAGCCATGCATGTCTAAGTATAAACTGCTTATACTGTGAAACTGCGAA
->LWSG01000002.1/200085-200211 Bacillus litoralis strain C44 Scaffold10, whole genome shotgun sequence. 
-TTAAACAAGTAGAGGCACCCGCTTCTCACCTGATTGACACATCCGTTTGTAGTTGGCAGGTTACGATGATCTTTTATGTATACAATCGTAGTGTGGGTGTCTAAGGCATCCACACTTTTTTATTTTC
->URS0000D696C4_12908/1-84 unclassified sequences c-di-GMP-II-GAG riboswitch 
-GGGAGCGGGGGAUCCAGGGCACGACGCCCAAAACGGUCGCCUGACCGUCGUGCCUAGCGAGCGGCGAGACCGGCCCCACCGUGC
->MNYX01000050.1/4741-9257 Candidatus Nomurabacteria bacterium CG2_30_43_9 cg2_3.0_scaffold_4245_c, whole genome shotgun sequence. 
-TAACAGGAAATATAAGAGCATATGGTGGATGCCTTGGTTCTAAGAGGCGATGAAAGACGTAGCATGGCTGCGATAAGCTTCGGGGAGGTGCCTAGCAACCTTTGATCCGGAGATTTCTGAATGGGGAAACCCCATAACCGTAATAGGTTATGACCTACATTTAAATGTAGGAGTATACCCAGGGAAGTGAAACATCTCAGTACCTGGAGGAAAATAAAAAAAGCCGCCGAATGGCGGAACATTTCCTGAGTAGCGGCGAGCGAAACGGAAATAGCCCAAACCTACTATTTATAGTAGGGGTTGTAAGGCAGAGACGTCGTATTTATACGAGAGGAGTTACAAAATGTAATGTTAGTTGAATATGCTGGAAAGCATAGCCCTAGACGGTGATAGCCCAGTAAACGAAAACCTTACATCTTCTTTGTCTTTGTTCTTGAGTACTTCGAGACACGAATAGCTCGGGGGAATCTACCAGAACTAACTGGTAAGGCTAAATACTCTTAGAAACCGATAGTGAACTAGTACCGTGAGGGAAAGGTGAAAAGAACCCCGGTGAGGGGAGTGAAATAGAACTGAAACCATATGCTTACAAGGAGTCGGAGCCCCCCACCACTCGTGGTGGGGGGTGACGGCGTGCCTATTGAAGAATGAGCCAACGAGTTAATGTATACAGCGTGGCTAAGCCCTTGTCGGGTGGAGCCTTAGGGAAACCGAGTGTGAATAGCGCGTTTGTTGTATGCATTAGACCCGAAGCCAGATGAGCTTACCATGAGCAGGGTGAAGTTTGTAGAAATACAGATGGAGGCCCGAACCGGTTGGCCGTGCGACACCATCGGATGACTTGTGGTAAGGAGTGAAAAGCTAATCGAATCTGGTAATAGCTGGTTCTCTCCGAAATATGTTTAGGCATAGCGTCTAGCGTACCCTCTGGGGGTAGAGCACTGGAAGGACTGAACAGGGAGCAATCTCGTCAGTCCTATCAAACTCCGAATACCAGAGATAGGCCCACCACATAATAATTTTTCGTTGCGAAACGAAAATTTTTAGCGGAAATCATGAAGCGTGATGAGCCTATGCGAGCATAGGCGACGAGCGATGAATGATTTGTAGCAAAAATTTTAAGTTGTAGCAGAAAAGATTGTTGTGTGGTGGGCCCAAATACTAGGCAGTAAGACTACGGGGGCGAAGCTCCGTCGGTCAAAAGGGAAACAGCCCTGATCTCAAGTTAAGGTCCCAAAATTTACGCTAAGTGTACTTAAGGAGGTGGAGTTTCTCAGACAGTGAGGATGTTGGCTTAGAAGCAGCCATCATTTAAAGAAAGCGTAACAGCTCACTCACTAAGAGACTCTGCACCGAAGATAATCGGGGCTAAGCGTAGTACCGAAACTGAGGGTTCTCTCGTCTTTCGAGATGGGGGAGCGGTAGGAGAGCGTTCATGTCTGCGCTGAAGGAGAAGTGTGAGCAACTCTGGAGCGGCATGAAGTGAGAATGTTGGCACAAGTAACCACAATGCGGGTGAGATCCCCGCACGCCGTAAGAGCAAGGTTTCCTTTGCGATGTTGATCAGCGAAGGGTTAGTCGGGCCTAAGGTTATAGCGAAAGCTGAAGCCGATGGACATAGGGTTAATATTCCCTAACTTTTTATTTGTGCGATGGAGTGACGAAGGTTAGTATGTCTTGCGCATTATTGGATTTGCGTTTGTGTCATCAGTGTGACTCTTAGGTAAATCCGGGAGTCTGGTTTTAATACCGACCGCAAGTGAAGCAGAAATGCATGGGTTCGCCCAGTGCAGATAAGGCAAAGCAATTTTCCGAGAAAAGCTTCTAAGCATAACAAATAAAAAACCGTACCTAAAACCGACACAGGTGCTCGAGTCGAGTAGACTAAGGCGAACGAGTGATTGCTTCTCAAGGAACTCGGCAAAAAAGCAGCCGTAACTTCGGGATAAGGCTTGCCTCCACCACTTTGTCTTTAAAGACGCATAGATAAAATTACTTCATTAGCGACGTAGAGCGAGAGAAATGAAAAGGTATTTTTTCATTTCCAAGCCGAGGAGCTAATATAAGAGGTAACCCTGCTTTTATTTGCATCGTTGAGAAGAATTTTTTCCTCCACGCAATGTACACTTGTACATCTTGGTCGTAAAAAATTCTCCCCGCCTCGCAACTAAAGCAATTTAATCAATGCTTATGCAATAGTGATGGAGTCCGAAGAATTGAGTGTATCGAGACCGTGTTTAGTATCAGAGCTGATACTAAACACAAAAAAGTATTTGAGAAAGTGAGTGATTGTGGGTTTCGTAGAGGGGGGATTCTGGATTTAAATAGAGAAGATAAGATTCGCAAGAATCAAACGACACTCAGGTGTCAACTTCGTTGGGTGCTACCATCCACTATTTCTTTGAATAATCTTGTCAGACGGGAAACCGCATAGACTAAAAGATCGTAATTAGATCGATTCGAAGGTTAACCATGAACTCTCTCCATTCTATGAAACTCATAATCATAGATCGTATCAAATACAAAAATGTTGACTAATTTTTCTAGGACTTAGACATCATCTCTCAAAAATCATTTCGCATATCATCAGTAAATTTCTGCTGTGACTTTGAGAAAAATTTTATTCGAACCTCGGTTCGAGTCAAATTTTTCTCTTCGTCTCGCTAGAAATTTCCCTGAAGCTAAGCGAAGCATTTTATGAGAAATGATGTAGCACCGCTTTGAAAATAAAGTGGTGGAGGCCGCAGCGAAAGATTTCCTGCCAACTGTTTACCAAAAACACAGCTCCATGCGAACTCGTAAGAGGATGTATATGGGGTGACGCCTGACCAATGCCAGAAGGTTAAATACGGGTGGTGCCGAGCACCATGAAGTTAAGTAGAATTTCGTTGAATATTTTTGTTCAGTGGTTCTATTTGAAAGCATGGTGCTCGGTGCTGGCTTGTATAAGCCCTGGTGAATGTCGGCCGTAACTATAACGGTCCTAAGGTTCCCTGCTTATCAATGATGAGCAGGGAAGGACTAGGACTGTTATAGAAAAAAGTAAACAATTAATTTAAATTCATTACATGTTTAAGCTACCTGGCACGCAGTAATGTGTGTTAGTCCAATCATGATAAACGAGAGACCAACGTCATGGACCCTACTTTTAAGGAAGAGGGTAAAGATAGAGTCCAACTGAGAGGAATAGTTGAGCGTAATTCCTTGTCTGGTAAGTTCAGACGTGCACGAATGGCGTAATGAGTGGGAAACTGTCTCGAGAAGCAGCTCGGTGAAAATACAATACCGGTGAAGATGCCGGTTACCTGCAGATAGACGAAAAGACCCCGTGAGCTTTACTATAGCTTAATATTGAACATGTTTTGTTTCTGCGTAGCATAGGTGGGAGGCTTTGAAGCGACCGTTTCGGTGGTCGTCGAGCCAACAGTGAAATACCACCCTTAATTGAGGCATGTTCTAATCTGTAAGGAAAAAACTTACGGAGACAGTATTTGGCGGGTAGTTTGAGTGGGGCGCTCTCCTCCTAAAAGGTAACGGAGGAGTCTATTAAGGTCCTCTAGGCGCGAATGGAAACCGTGCCGATAGCGTAATGGCAAAAGAGGGCTTAACTGCAAGACGGACATGTCGAGCAGGTGCGAAAGCAGAGCATAGTGAACCGACGACACGCTTTAGATGCGGTCGAAGATTAACGGATAAAAGCTACCACGGGGATAACAGGCTAGTTCTGCCCAAGAGTTCATATCGACGGCAGAGTTCGGCACCTTAACATAATCGGGGTGCGTCAGGAGTAATCCTGTAGCGACAAATTTATAATCGTCAATAAATAATATATAAACAAGAAATCTTGGCTTATAACGGTGAAACCCATTTGCATGAACAATAAATGGGCAATACCGTGGGAAGTTTGCGTGTAAGAAAGCGATCACTCTAAATTTTTAGAGAGCTGCTACATCCTTTGTGGATGTGATTATACGTATAACCCTGTAGAGACTTGTCACGTTAGCGCGTAGAGATGCAACTAACAAAGTGACGGAGTTATGAGAAAATCATAGCTAATACGCCAACGCCTCTTTTGATCGAGAGGGTGAAGATATAGTCCGATCCTCGCAGTAATGCGAGACAAATACGACAGCGATGTCGGCTCATCTTATCCTGGAGGTGGAGAAGCTTCCAAGGGTTTGGCTGTTCGCCAATTAAAAAGATACGTGAGCTGGGTTCAAACCGTCGTGAGACAGGTTGGTCTCCTATCTTCTGCAGGCGTTGAATTTTGAGGGGATTTGCTCCTAGTACGAGAGGACCGGAGTGAACTGACCTCTGGTGTGGCTGCTGTCCTGCCAAGGGCACCGCAGCGTAGCTATGTCGGGAATGGATAACCTCTGAAAGCATCTAAGAGGGAAACCAACCCCAAGATCAGAATTCGTTTGAGGCCCGTAAGAGATGATTACGTTGATAGGCTCTATGTGTAAGACGAGTAATCGTTTCAGCAGAGGAGTACTAATACGCCGATTCCTGGTGGG
->AYYY01000070.1/37374-37142 Lactobacillus vaccinostercus DSM 20634 NODE_168, whole genome shotgun sequence. 
-TAAAAAACGATGAAAAGATGAGTAGCAGTTAACACCTTTTTAGAGAGCCTCTGGTTGGTGAAAAGGGGTAAGGTTGGTGATTGTGAATATGGTCTTGAAGTGAGGAATGTTGAGCGTATGCGAGGCATTCATGGGGACGCCCATTACCGCGTGCGAGTATGATTGTACTCAGCGAGGGAGTGTATGTGAATACATTCTAAATTAAGGTGGTAACACGAGAGATCGTCCTTACT
->AAQR03042857.1/1-1187 Otolemur garnettii contig042857, whole genome shotgun sequence. 
-GCCCCAGTGCTGCCAGTCCCTGTGCTGTAAGCCCATCTGCTGCCGCCCCAGCTGCTGCCAAACCACCTGCTGCAGGACCACCTGCTGCCGTCCCAGCTGCTGTGTGTCCAGCTGCTGCAGGCCCCAGTGCTGCCAGTCCCTGTGCTGTAAGCCCAGCTGCTGCCAAACCACCTGCTGCAGGACCACCTGCTGCCGCCCCAGCTGCTGCTAGGGACCTGCTATAGAACAATCTGTTGTTGTTCCACCTGCCAGACCACCTCTTGCTGCTGAGTGTCCTGCTCCAGATCCATGAACTTTCATGACCCTTCCTTTAGTCTAGTTAGAGAGGATCTAGTCACTGAAGACATGAACTTCCTGGGGCTATGGACTTAACAAACAGACCCATGGATGAATTTGCAAAACCCTGGTTTCTATATTAGTATTTTCTCTATTCTGTAGGTATATTTCATTATTATAGCAAATCAGTATTTACAGCCAGATTCTGCATCAAATTGCTTTAGTATTCCTAGTTCTGATTCAAAATACAGGAGTCTTCAAATGTTCTCTTCATAGATATTTTTATAACATTTTCAGTAGAATCCATTGTCATGTGGAATTATTGCTCAATGTTGCCAAATAAAAGTTCTTAGCATCCAAATGCACCCAAATTGGTCATTTCTCATTATTAACAAAATGTTCCTGTCTCTTTTCTGCACAACACTAGAGCTCATGTTTTCAGGAGAACACACAATGGAAACATTAAATTGGTCTTCTCCAGTGACATTGTTATCAAAACCTGAATTCACCCCCCAACTTCTAAGAAGGACAAGTGGTGTTAAGCCACCCAAGATTGAGCAATAACAGGCCTGTGATGCCCTTAGATGTCTGGGGCTTCAATGACTGGCTCAGCATGCAGGCACTGGTAACCCGTTGAACCCCATTCATGATGGGGATCAGGGATTGCAATTATTCCCCATGAACGAGGAATTCCCAGTAAGTGCAGGTCATAAGCTTGCGTTGATTAAGTCCCTGCCCTTTGTAGACCCTGCCCGTCGCTACTACCAATTGGATGGTTTGGTGAGGCCCACGGATTGGCCCCAGTGAGGTTGGCCCTGGTGGAACGCTGAGAAGATGATCAAACTTGACTATCTAGAGGAAGTAAAAGTCATGACAAGGTTTCCATAGATGAATCTGAAGAAGGAAAAATT
->KQ042022.1/603975-604625 Larimichthys crocea isolate SSNF unplaced genomic scaffold scaffold95, whole genome shotgun sequence. 
-CCTCACGCTTAAGCCCGGCTTCGGGACCCCCCCACAGCACCCAATGCACACCGCGGCTACCGCGGTGTGCATAGTGACGAAAAATAACAATACAAGACTCTTTCGAGTCCCTGTAATTTAAATGAGTACACTTTAAATCCTTTAACAAGGATCAATTGGAGGGCAATTTTGGTGCCAGCAGCCGCGGTAATTCCAGGTCCAATAGCGTATCTTAAAGTTGCTGCAGTTAAAAAGCTCATAGTTGGATCTCGGGATTGAGCTGACAGTCTGCCGCGAGGTGAGCTACTGTCGGTCCCAGCCCCTGTCTCTCGGTGCCCCCTCGATGCTCTTAGCTGAGTGTCCTGCGGGGTCTGAAGCGTTTACTTTGAAAAAATTTGAGTGTTCAAAGCAGGCCCGGTTGCCTGAATACCGCAGCTAGTAATAATGGAATAGGACTGGCCAGGGGAGGTGCCGCTAGAGGTGAAATTCTTGGACCAGCGCAAGACGGACGAAAGCAAAAGCATTTGCCAAGAATGTTTTCATTAATAAAGAATGGAAGACGATCAGATACCGTTGTAGTTCCGACCATAAACGATGCCAACTAGCGATCCGGCAGCGTTATTCCCATGATCCGCCAGGCAGCATCCAGGAAACCAAAGTCTTTGGGTTCCG
->GL897038.1/2640067-2640202 Mustela putorius furo unplaced genomic scaffold scaffold00141, whole genome shotgun sequence. 
-AGCTTTGCGCAGTGGCAGTATCGTAGCCAATGAGGTTTATCCGAGGCGCGATTATTGCTAATTAAAGCAGCAAGAGAGAAATGAGACCTTATTTATAAGGCAAAAAAATTAGAATGACAGTGAATTTCCCATCAAA
->AWHE01044218.1/1319-1427 Amborella trichopoda AMTR_V1.0_contig_44218, whole genome shotgun sequence. 
-GTGCCTTAGGGTTGAACTAGTCCCGGATATTTAATCATTCCCACCAACTTCACATTCTCAGTGAAGTTTTTCCTTGTTGTCTTATCTGATAATTCAAGATGGAAATATA
->AFSB01019533.1/7909-8012 Heterocephalus glaber contig19533, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGCAGTAGGAAGAAGGATCCAGTGTGGAGTCATAAATATATAAATTTTATTATTTATCAATACATTAATTTAT
->AYUG01084532.1/52955-52729 Fukomys damarensis contig84532, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGTAGGAAAATAGAAAATTTCATACGTAAGCAAAACAATTTCTCCTAACCCTATCTCACCAAAACAAAAACTTCTCACATTTTTTCACAAGTATTTCAATTACGTGCCTCTATTTATCCTAGAGCTCTCTTGCAAAACAGGAACAGATCCAAACTGAGAAAGAATTGCTTTTCAGTTTTAGTGCAGTTGACGTTTA
->LLXS01000009.1/35786-35931 Stenotrophomonas maltophilia strain JCM 9942 contig_17, whole genome shotgun sequence. 
-CTTGGTGTGTGACCACCAATAGCCTGAAGTGGCGTGCGTCTCTGGCAACGGAGGGGTGCGAAGCCCACTGAACAAGTCCCCCGCAAGGGGCGCAACAACCGCGAGGTTTTCGCGCAGATTCCGGTAGCAGCAGACCGGATGAGGGG
->CCCW010015579.1/1-2359 Brassica napus, WGS project CCCW01000000 data, contig: 28609 
-ACGGACAGCCACAGACGTCCTGTATCTGCTGGCGGACACCCACGGATGTCCTGTGTGTACTGAACAGACAGCACACGTGGGCCAAAATCTCCGGAACAGTCCACGGGAAGGGTCAGCGTGCTAAGTCCAAGGACCAATGTGCTGATATGTGTACTGATGGACAGCCACGGACGTCTTGTGTGTGCTGACGGACACACACGGACATCCACGGACGTCCTGTGTGTGCTGATGGACACACACGGACGTCATGTGTGTGCTGACGGACACTTGGTCGATTAAGACAGCAGGACGGTGGTCATGGAAGTCGAAATCCGCTAAGGAGTGTCTAAAAACTCACCTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTGAAGCACGCGACCTATACCCGGCTGTCGGGGCAAGAGCCAGGCCTCGATGAGTAAGAGGGTGTGGCGGTCGCTGCAAAACCTAGGGCACGAGCCCGAGCGGAGCGGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATATTCCAATGAGAACTTTGAAGGCCGAATAGGGGAAAGGTTCCATGTGAATGGCACTTGCACATGGGTTAGTCGATCCTAAGAGTCGGGGGAAACCCGTCTGATAGCGATTATGCGCGAACTTTGAAAGGGGATCCAGTTAAAATTCCGGAACCGGGACATGGCGGTTGATGGCAACGTTAGGAACTCCGGAGACGTTGGCAGGAATTCTGGAAAGAGTTATCTTTTCTGTTTAACAGCCTGCCCACCCTTGAAACGGCTCAGCCGGAGGTAGGGTCCAGCGGCTGGAAGAGTACCGCACGTCGCGTGGTCTCTGGTGCATTCCCGGCAGCCCTTGAAAATACGGACCGAGTGACGCTCACGCCCGGTCGTACTCATAACCGCATCAGGTCTCCAAGATGAACAACCTCTGGTCGATGGAACAATGTAGGCAAAGGAAGTCGGCAAAATGGATCCGTAACTTTGGGAAAAGAATTGGCTCTGAGGGCTGGGCTCGGGGGTCCCAGTTCCGAACCCGTCAACTGTTGGCGGGCTGCTTGAGCTGTTAACGTGGCGAGAGCGGACCGCCTCGTGTCGGCCAGGGGAAGGACTGGGAACGGCTCTTTCAGGATCTTTCCCTGAGCGTCGAACAGCCAACTCAAAACTGGTACGGATAAGGGGAATCCAACTGTTTAATTAAAAGAAAGCATTGCGATGATCCCAGTAGATGCTAACGCAATGTTTTTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGTGCGGGTAAACGGCAGGAGTAACTATGGCTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTGTCTACTATCCAGCGAAAACACACCAAGGGAACGGGCTTGGAAGAATCAGCGGGGAAAGAAGACCCGGTTGAGCTTGACTCTAGTCCGATTTTTTGAAATGACTTGAGAGGTGTAGAATAAGTGGGAGCTCCAGCGCAAGTGAATACCACTACTTTTAACGTTATTTTACTTACTCCGTGAATCGGAGGCGGCGTAATAACCCCTTCTTTTAGACCCAAGACTCGCTTTGACGGGTCAATCCGGGCGGAGGACATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTTAAAAGATAACGAAGGGGTCCTAAGATGAGCTCAATGAGAACAGAAATCTCGTGTGGAACAAAAGGGTGAAAGCTCGTTTGACTCTTATTTTCAGTACGAATACGAACCGTGAAAGCTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCCACCAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGCTCGTGTCGCAATAGTAATTCAACCTAGTACGAGAGGAACCGTTGATTCGCACAATTGGTCATCGCGCTTGGTTGAAAAGCCAGTGGCGCGAAGCTACCGTGCGCTGGATTATGACCGAACGCCTCTAAGTCAGAATCTGGGCTAGAAGCAACGCATGTGCCCGCCGCCCGATTGCCGACCCTCAGTAGGAGCTTCGGCTCCCAAAGGCACGTGTCGTTGGCTAAGTCCGTTCAGCGGAAGCGCCGTTCGGACCGCCTTGAATTATAATTACCACCAAGCGGCGGGTAGAATCGTTTGCAGACGACTTAAATACACGACGGGGTATTGTAAGTGGCAGAGTGGCCTTGCTGCCACGATCCACTGAGATTCAGCCCTTTGTCACTAAGATTCGA
->MNRN01000197.1/5697-5757 Clostridium sp.CAG:217_53_7 isolate CAG:217_53_7 Ley3_66761_scaffold_9517, whole genome shotgun sequence. 
-GGAGAGGTACCGAAGTGGTCATAACGGAGCGGCACCGTGGGTTCGAATCCCACTCTCTCCG
->LIZX01000155.1/9306-9787 Candidate division WOR_1 bacterium DG_54_3 WOR1_52_54_19713, whole genome shotgun sequence. 
-AGAGCAGGCCAGATGATCGTGCCTCGACTCACTTCGTTCGCTCGGCACAAGCCCCTTAGTCTGAGGGGTTTATACCGAGCGAGGCCGAAGGCCGAGTCGAGGTAAGGAAAGTCCGGACTCCGCAGAGCAGCGTGGTTGCTAACGGCAACTGAGGGCGACCTTAAGGAAAGTGTCACAGAAATTACACGGCCCACTCTGACCCTAAAGGTCAGAAGGCAAAGGTGAAATTGGGAGGTAAGAGCTCCCACAGGACTGACCGGTGACGGTCGCTGCGGTAAACCCCACGCGGAGCAAGACCAAATAGGGAAATGGGTGGCTCGCCCGCCCTGCCCGCAATGCTACGCATAGCGTTGCAGGCGGGTATAATCCCGAGTAGGTCGCATTGAGGCAGTCAGCAATGGCTGCCCCAGATAGATGATCATCGAACCCAGCACGGTATGGTGCTGGGTGAACAGAATCCGGCTTACCGGCCTGCTCTTTTT
->MFJD01000004.1/58273-58056 Candidatus Gottesmanbacteria bacterium RBG_16_52_11 RBG_16_scaffold_141, whole genome shotgun sequence. 
-ACAGAAGGCTCAATTTGGGCTCACTGAAAACTATTTTAGTGATAGTCCGGCTGTATCGGTGAAATCCTGAGCTAGCCGAAGGACAACACCGAGGCAATCCCCCTTCCGCATAAAATATGGGGGCGAGTCCGTAGAGACTATACGCCGGACCCCGCCTACAGTTGATAACTCAATTGTTGGCGGGGAAGATATAGTCCGACACTCTCAGTAATGGGAGA
->GK000003.2/42786018-42786224 TPA: Bos taurus chromosome 3, whole genome shotgun sequence. 
-ATCACTTCTTGGTATTTTGGCTAGAATCAAGTGTAGTTTCTGTTCTTATCAGTTTAATATCTTCTCCCACTGAAAAATGTGGCTCTGCTATGTTGGGGCCAGGAGTAATTAAACCAGTGTTAGGAGGAAAGAAAGTGAAGTCACTCAGTCGTGTCTGACTCTTTGTAGCCCCATGGACACCGGGCTCCTCCGTCCATGGGATTTTCT
->LFZU01000001.1/2811527-2811462 Bacillus sp. FJAT-27231 Scaffold1, whole genome shotgun sequence. 
-CAAAAAGGAACGACGGCTAAAGACGCGACACCGTGTCGCAACGCCCTCACTAGCACATCATGTGCG
->GL637602.1/252614-252701 Caenorhabditis tropicalis strain JU1373 unplaced genomic scaffold Scaffold630, whole genome shotgun sequence. 
-TGTCCACTGATGACAACCTTACATACACCATTACGATCTCTGAAGACTTCGTGCTGAACATGTTTCCATGCAACACCAACTGAGGACG
->LL029687.1/1-1177 Trichobilharzia regenti genome assembly, scaffold: TRE_scaffold0029590 
-CTCCTTGTGTTTAAAGTTAGTGCTTACAAGAAACAAATGATTATCAGAACAGAACTGTAGGAGATCAGTATCAGTTCTTTATTAATCAGCTTCAACAACAATACATCTCATCCAGTTCTGCTTTAATATTCTCCGTAGGCAAATGAGACAAGTACGCTAAGTATCCCAAAAATGCCTAAGCCCAGTAAGAATGCTAAAGCACCGACGGCGGTGCTGTGCAGTCTACAAACAAACAAAAAGTTGTATTCAAATACCACCAGAAACTTTTCACTCAATCTATTCCACATTCTCAAAATACTTCCGAAGGTTGCAGAACCAGTGCCATTCAATCATTTCACAGAGATGGACACTCCACATTAAGTTGTACAATAATTCCTATCCCTAAATTAACTTAAACTCTGAGATATGCACTGAATGAAGCTAATTTGATCATCAAATGTGNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNCCCGACAAGAGCATTGATATGACAGACTTATCTCCTGTAATTTCTGTTTCTGCGAATGGTGAGCGGACAAAAAGACTGAAACTCCAAGAACTTCATTATTCGCGTTAAAAACACCACGTTAGCGATTTTAGATAGAACGTACGGACAACTATTGTAAAGTGTGCAAACAAGGTGAAAAGAAACGGGAAATCGGGGTTCGATTCCGGAGAGGGAGCCTGAGAAATGGCTACCACATTCAAAAACCGCAGCAGGCGCGAAAATTACCCACTCCCGGCACGGGGAGGTAGTGACGAAAAATACGAATACGGAACTCAATTGATGCTCCCTGGTTCGAATGAGTACAATTTGAATCCTTTAACGAAAACCGATTGGAGGGCAAGTCTGGTGCCATCAGCCGCTGTAACTCCAGCTCCAAAAGCGTAAAGTTGCTGCAGTTAAAAAGCTCGTAGTTGTGTGGTCGCATGCCATTGGTTCTTCGCGGCTTTGGTTACGATCAGAACTTGTGTTCGGCTCGGTGTAGTGGCTGTGCAGCCTTTCAGTCATATCTGTGTAAAGGGGTGCTGACGGAGATGGGTGAGCTTGTCTTGCCCGCTATCTGTTGGCATGCTTCCGGATGCCTTTAACCGGGTGTCGGGAGCGGACGGCATCTTTC
->JYDL01002072.1/1-274 Trichinella nelsoni scaffold2457s, whole genome shotgun sequence. 
-TTGAAACACGGACCAAGGAGTCTGACATGTGTGCGAGTCAACGGGTGATTAAACCCGTAAGGCGCAAGGAAGCTAATGCGCGGGATCCCTTTACGGGTGCACCGCCGACCGACCTTGATCTTCTGAGAAGGGTTCGAGTGTGAGCATGCCTGTCGGGACCCGAAAGATGGTGAACTATGCCTGAGCGGGGCGAAGCCAGAGGAAACTCTGGTGGAGGCCCGCAGCGATACTGACGTGCAAATCGTTCGTCTGACTTGAGTGTAGGGGCGAAAGA
->DS562881.1/23395652-23395568 Cavia porcellus supercont2_26 genomic scaffold, whole genome shotgun sequence. 
-AAATCATAATCCAACTCTAGCATTAGCCATGGGTTTAGCATTCCTCTTGAGGAAAGCAGGGGTTCCTCTTTTGCCCCCCATTGGC
->FAOM01514816.1/33945-33090 Triticum aestivum genome assembly, contig: Triticum_aestivum_CS42_TGACv1_scaffold_514816_6BS 
-CTGTATGATCCTGCTAGTAGTCATATGCTTATCTCAAAGATTAAGCCATGCATGTGCAAGTATGAACCAATTTGAACTATGAAACTGTGAATGGCCCATTAAATCAGTTATAGTTTGTTTGATGGTACGTGCTACTAGGATAACTGTAGTAATTCTAGAGCTAATACATGTAACAAACCCCGACTTCTGGGAGGGGGCACATTTATTAGATAAAAGGCTGACGCGGGCTCTGCTCGCTGATCCGATGATTCATGATAACTCGACGGATCGCACTGCCTTCATGCCAGCGACACATCATTCAAATTTCTGCCCTGTCAACTTTGGATGGTAGGATAGGTGCCTACCATTGTGGTCACGGGTGACGGAGAATTAGGGTTCGATGCCAGAGAGGGAGCTTGAGAAACGGCTACCACATTCAAGGAAGGAAGCATGCGTGTAAATTACCCAACACTGACATGGGGAGGTAGTGACAATAAATAACAATACCGGGCGCATTAGTGTGTGGTAATTGGAATGAGTACAATCTAAATCCCTTAACAAGGATCCATTGGAGGGCAAGTCTGGTGCCAGCAGTCGTGGTAATTCTAGCTCCAATAGCGTATATTTAAGTTGTTGTAGTTCAAAATCTCATAGTTGGACCTTCGGGCCGGTCGGCCGGTCCGCCTCACAGCGAGCACCGAAATACTCGACCCTAGCCTTAATTGGTCGGGTTGTGTTTTCGGCATCGTTACTTTGAAGAAATTAGAGTGCTCAATGCAAGCCATCGCTCTAGATACATTAGCATGGGTGTCACGCCCAAGATGCGACCCTATCCTAAAGGAACTCGAAGGTCCCACTAAGGATAGAAGCACATCTT
->GG700527.1/116493-116761 Anaerococcus vaginalis ATCC 51170 genomic scaffold SCAFFOLD1, whole genome shotgun sequence. 
-AATAAAACTTTGATCAGAAGTAAGTAAGTTTTATAAATCTTTTATAGAGAGCTTGTGTGTGGTGGAAACAAGCAAAGAAGTAAAACCGAATGGATCTGAGAGTGCTAAGGTGAAAAAAGTACCCGAGGCCGTCTTCCCACGTTATAGGGATATGATATGAAATTATTTTAAATTAGTATCAGAATAAAGATATGTAGGATTTATTAATTTATTGAAATTTATTTTACATAAAAAGGATGGCACCGCGAATTCAACCATTTGCTCCTTTG
->CM007396.1/65217892-65218035 Nicotiana attenuata strain UT chromosome 6, whole genome shotgun sequence. 
-TGTAAAGGTTTCCTCGGGCCGGACGGAGATTTACCCTCGAGTGTAAAGGCAGAAAGGAGCTTGACTGCAAGACCCACCCGTCGAGCAGGGACGAAAGTCGGCCTTAGTGATCCGACGGTGCCGAGTGGAAGGGTCGTCGCTCAA
->AFSB01270989.1/241-552 Heterocephalus glaber contig270989, whole genome shotgun sequence. 
-AGATGTGTGGGACAATGTGGCTATGACATCTGTCACCCCATCGATCACCAGGGTTGATTCGCCCGATCTGGCTGGCTAGGCAGGTGTCCCTTTCCTTCTTCACCACTCCACGTGTGTCCCTCCCAAAGATGCACAATAGGTCGAAAAGAACGAACACCCAAGCTACAGGAGGACAATTTCCTCATCAAGGGTATATGAGTAGCTACACTCCCCTGCTAGAACCTTCATACAAGAGCTCAAGAATACTCCACTATAGGACCCGGATGTAGCTCAGGGGTACAGAACTTGCCTAAATGCACAGGTCTTGGCTTT
->FN543502.1/2725931-2725592 Citrobacter rodentium ICC168, complete genome 
-TTTGGCGACGTCCACCTGCTGGATTTGGGCATACAGTTTGCCGACCACTTCGGCGATCGACGGATGCCAAGAGACGGCGCGATTGACCGCCTGAGAAAGTGTAAGTTCGCCGGGGGCGGCGCTGTCGCCGGTTAGCGGCATTGGTCCATTCAGCGAGGGCAGCTCCTGCTGCTCAACCCACTGCTGCGGGGCGATGCGGGGTGACTCTTCGGCGGCAATGGCCGGAAACGCGCACAGGTTTCCAGCCAGCCACCAACAGGTCAGCTGTCGTTTTCCCATTTTTTACTTCCCTAAGCTGGCTTCTTTTCGCCCCGGGCGAACGTGCGCCCGGGGTCGTTGT
->CM000685.2/82594813-82595002 Homo sapiens chromosome X, GRCh38 reference primary assembly. 
-AGGCATGTGATCAATCAGGCTGAGACATCTGTTACTGCATTGATTGACTTGGATGATCAGGCTTGTGAAATAGGTGGCCCCATCCTACTTTGCTGCCCCCAAGTACATCTGTCTCAAAGCTTACACTGCTGGAAGGGGATGACCATCCCTATTAGAGGACAGTCATTCTCTGGTCAGGAGTAGAGAAATA
->DS995940.1/1722-1546 Penicillium marneffei ATCC 18224 scf_1105668340736 genomic scaffold, whole genome shotgun sequence. 
-GCTGGCGACGGCGACCCGGGAGAAGCCCTGGGCCGCTGGCTGGCGGATTGCAATGTCACCACGCGCGGGGATAAATCCTCTGCAGACGACTGAAGTGACCAAGCGGGTCATGTACGCGTACGAGTAGCCTAGTTGTTACGAGTCGCTGAGTGTCAGCCCGACCTTGGCTCGATTTGT
->MLHJ01000044.1/15422-15261 Rodentibacter rarus strain CCUG17206 contig_44, whole genome shotgun sequence. 
-TTTATCGCATAACTCCGAGCTTGTTTAGTCTAAGTTCCTCTTTGGTGAAAATACTTGGGTGAGGAATATGACGGCAATGCCAATAACGCTATTTGTTATTCAGGGATACGCTGGAAACGGCTTGTCCTCTCCATTTTAGAAAGGTGTCACATGCAATCTATT
->MAVT01007669.1/869-1028 Diaporthe helianthi strain 7/96 Scaffold_4854.1, whole genome shotgun sequence. 
-ACACGCATGAGCCGGTGCCAATCCGCCCGTGCCAGGTCCGAGAGTCCTGCTTCAGCAGCACTCAAAGTGATTTCGGCGCGACGGCGGAGTTGCTGAGATTACACGGCTTCGGAACTTGATCTTGGATAATACCAGCGAAAGGATCATGCGTCTCCCCCCC
->CDMY01000201.1/99855-100012 Vitrella brassicaformis CCMP3155 genome assembly, contig: scaffold135 
-AAACTTACCTGGCTGGGCCTCGGGGGCGCTCACGAAGGTCCCTGTGCTGTCGTGGAGCTCCCATTGCATTCGGGGGTACGTGAAGCGGCATGGGGGGGCTATGCTCCTGCCAACAGCGGAATTTCTGGCAGAGCTGGCTTGCGTTCGCGCAGCCGGCA
->CM002822.1/201709819-201709930 Capsicum annuum cultivar Zunla-1 chromosome 11, whole genome shotgun sequence 
-GTACACCCCAAAGGAGTGTACATGAGAACACAAGTGTATTTTAGTTTTTTACAATTTCAATTTCTATATCTAAAATGTACTTGTGTTCTCAGGTCACGTCTTTGAGAACACC
->MGVN01000036.1/14680-14207 Elusimicrobia bacterium RIFOXYB2_FULL_49_7 rifoxyb2_full_scaffold_1450, whole genome shotgun sequence. 
-CTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTTCTGTGTTACCAGCGGATAATGCCGGGGACTCACAGAAGACTGCCTCTTTTTTGAGGAGGAAGGTGAGGATGACGTCAAGTCCTCATGGCCCTTACGTCCAGGGCTACACACGTGCTACAATGGCCGGTACAGAGGGTCGCAATGCCGCAAGGTGGAGCTAATCTCAAAAAGCCGGTCTCAGTTCGGATTGGAGTCTGCAATTCGACTCCATGAAGTTGGAATCGCTAGTAATCGCGGATCAGATACGCCGCGGTGAATACGTTATCGGGCCTTGTACACACCGCCCGTCAAGCCATGAAAGCCGGGAGTACTCAAAATGGTTGCCTGAACCGTAAGGAGGGCGCCCCTAAAGTAAAACCGGTGATTGGGGCTAAGTCGTAACAAGGTAGCCGTACCGGAAGGTGCGGCTGGATCACCTCCTTT
->LVVY01000041.1/1-81 Devosia sp. S37 DIN_R1_(paired)_trimmed_(paired)_contig_135, whole genome shotgun sequence. 
-TATGCCACTGGCGCAAGCCGGGAAGGCGCCCGCCGGGGATGATCCCAAGTCAGAAGACCGGCCAGATGACCTCTTGAAGCT
->ANKR01162454.1/9860-9985 Myotis brandtii contig162454, whole genome shotgun sequence. 
-TAACCTCCGCAGGCTGGCTGGCCCTCAGGCTGAGCTGGGTGAGTATCTTTTCTGTTTTGGGAGGACGGGGAAGAGGGGGGACCCAATATCTTTTTGAGAGGCTCGCCCTCAAGCACAACTAAGAGC
->LGPB01000006.1/253-1 Bacillus galactosidilyticus strain PL133 scaffold000006, whole genome shotgun sequence. 
-GATTAAGTTGTTAAGGGCGCACGGTGGATGCCTTGGCACTAGGAGCCGATGAAAAGGGACGGGGACTAACACCGATATGCTTCGGGGAGCTGTAAGCAAGCTTAGATCCGAAGATTTCCGAATGGGGGAACCCCCTACCTTTAATGGGGTAGGATCCAATTCTGATTCTGAATACATAGGAATTGGAACCCGGGGAACTGAAACATCTCAGTACCCGGAGGAAGAGAAAGAGAAAGAAAAATCGATTCCCTAA
->CAQQ02314174.1/33-1 Megaselia scalaris, Durham, NC isolate 2 -- Noor lab, WGS project CAQQ02000000 data, contig: ctg0000314174 
-AAACCGGTTCTTTTCAGAACCACCAATTTTTTT
->LL082930.1/890-2011 Trichobilharzia regenti genome assembly, scaffold: TRE_contig0003919 
-GACTGATGAGCAGGTTTCTTTTAAAGTGAGTTCATTTAACCTCTTTTTGTATTCTATTCTATATCCGCCATTTTTCTGAAAAATTTTTGAGTAATATCACCATTCATCTATTCGTTTTATTATTATTATTATTGTTAATATTAACTCACCTCCATTTCAAATTTATTTAAGCGAAAGTGTTCATACTACTAACATAGTCTATTCAGTAGTATTCATTTTAAAATGTATATTTTTCGAATTGAGGTGCATTAAAACAACAGGTGTTATAGTAAAGAAAAAGAAGAAGTTTTGAAGGGAGGACGAATAACTCAGTGGTGATGTGATTTATATCAGATGTCTTTGTATTACCGTCGTTGGATAGACTTTATCGAAAGCATTTGCTAAGAATAATTTCATTGATCAGGAACGAAAGTCAGAGTTTCTAAGACTATCGTTTCAGTTCTACCATTAAACAATGCCAACTGACGATCTGTGTTGGTTCTTTAATTGTCAATGAACGCACTATCCAGGAAAACTTCAAGTCTTTCAGCTCCGGAAGAAATATGGTTAAATAGCTGAAATTTACAGGAATTGAAGGAAGGGTACCACCAGGAGTCGAGCCTGTGGTTTAATGGAACCCAACATGGGAAAAATCGTTCGGCACGGACATATTCAGGATTAACAGATTGAAAGCTGTTTCTTGATTTGGTTGATGGTAGTGCGCGGCCGTTCTTATCTGCTATCTGTTGCTTCTTAGTGGAGTAGTGTGATCGTTAACTGGAGAGTATGGTACCAGCTTTTGTCTCTTAAACAGACAGACTGCACACTGAAGTCGTACGACATTGAGCAACAACAATTCTGTGATGCCCTTAGACGCCCAAAGCTACACCTGCGCTACAATGACGGTGCCAGGGTTAAGCCACCTGTTTTATCACCGTCGTGACTGGGAACGCTACCTGCAATTGTTCTCTGTGGAAGTCATAAACATCTACTGATGACGTCACTGCCCCTTGTACACACTGCCCGTCTCTATTACCGATTGAATACTATTCATAAACATGAACAATTGAGAATGGTTGGCGTTAATGTTTAATATATCGCCAAATTTGTCTTGATTGATGAGTAGACAGAACGAAATCAAAG
->FWFV01000002.1/64217-64338 Palleronia marisminoris strain CECT 7066 genome assembly, contig: 0002 
-GTGACATACGAGCACCCACCTCCTCCCGGGCGCCTCGTATTCGGCGACGACACCGACCTCCTCCCCGGTGTCGTCGCCACAGATTACGCAGCGCCGACCTCCTCCCCGGTGCTGTGTTTCAG
->MNVI01000024.1/6358-6450 Candidatus Micrarchaeota archaeon CG1_02_55_41 cg1_0.2_scaffold_10394_c, whole genome shotgun sequence. 
-CCCGCAGTAGCTCAATTTGGCAGAGCACCTGACTGTAGTTAGAAAATCCGAGTGGACATCAGGGGGTTGCCAGTTCAAATCTGGCCTGCGGGA
->AAGJ05017846.1/1565-1174 Strongylocentrotus purpuratus Contig17846_fixed, whole genome shotgun sequence. 
-GAGACACTGGCCGGGGCCCCGGGAAGAGTTGTCTTTTCTTGTTAAGGAGCGGGATCCCTGGAATCGGTTCGACCGGAGAGAGGGTCTGCGGCTCCGTAGAGCGCCGCGTCTACGGCGGCGTCCGGTGCGCTCCGGCTGGTCCTTGAAAATCCGGGGGAAGTGTTGGGACTCTCGCCTCGGGTCGTACCCATGACCGCAGCCGGTCTCCAAGGTGAATAGCCTCTGGCCGATAGAACAATGTAGGTAAGGGAAGTCGGCAAGCCGGATCCGTACCCCCCGCAGGGATGGATTCCACCCCTCTGTCACATCATCTCTCTTTACTATAATACCCTCCTCTCCCTTTTCTTTTAAAACCAATGGATGATGTATGGGTCCCCTCCCCTTCCCCTCGT
->MOOB01000036.1/196011-195921 Penicillium nalgiovense strain IBT 13039 PENNAL_contig0036, whole genome shotgun sequence. 
-ACTACGTGATGATCAATTTTGAATTTGCAATCCTGACAACCACCTATCATATGTGAGGTTGTGTGTTGACTCTTCTACACTTGATCTGACC
->CP002770.1/704081-707325 Desulfotomaculum kuznetsovii DSM 6115, complete genome. 
-GGTCAAGCTGGTAAGGGCATACGGTGGATGCCTGGGCGCTTTGGGCCGATGAAGGACGTGGCAAGCTGCGAAAAGCCACGGGGAGCCGCAAGCAGGCGTAGATCCGTGGATCTCCGAATGGGGCAACCCGGCGGGGGTGAACCCCCGTCATCCCGTACTGAACACATAGGTACGGGAGGGGCACCCGGGGAACTGAAACATCTTAGTACCCGGAGGAAAAGAAAGCAAAAGCGATCCCCGTAGTAGCGGCGAGCGAAAAGGGGACAGCCTAAACCCGGCACTCAACTGAGTGTTTATGTTATGCATACAACAAGCTGATGCATCCGGGAAGTGAAAGTTGGGGTAAGAGCATAGCGTAAACACCGAGTTGAGTGCCGGGGGTTGCGGGACTCCCGTTGACGTACTGCGGAACTTAGCCGAAGCGGGCTGGAAAGCCCCGCCGCAGAAGGTAAAAGCCCTGTAGGCGAAAAGGGAAGCAGTGCGGGGAGGATCCCAAGTACCGCGGGGCACGTGGAATCCTGCGGGAATCAGGGAGGACCACCTTCCAAGGCTAAATACCCAAAGCGACCGATAGTGGACCAGTACCGTGAGGGAAAGGTGAAAAGCACCCCGGGAGGGGAGTGAAATAGGACCTGAAACCGTATGCCTACAAGCAGTCGGAGCCCAGCACTCAACTGGGTGCTTACCTTAGGCTTTAGAGGGGCTGATACATTCCGGGAGGGAAGGGCCTGTTTAAGGCAACCGTAAGCACCGAGTTGAGTGCTGGGTGACGGCGTACTTTTTGTAGAACGGACCGGCGAGTTACGTTCAGCGGGCGAGGTTAAGGCTGGGAAGGCCGGAGCCGTAGCGAAAGCGAGTCTGAAGAGGGCGATAAGTCCGCTGGAGTAGACCCGAAACCGGGTGAGCTACCCATGTCCAGAGTGAAGCGTAAGTAAAGTTACGTGGAGGCTCGAACCAACCGTCGTTGAAAAGGCGGTGGATGAGGTGTGGGTAGGGGTGAAATGCCAATCGAACCCGGAGATAGCTGGTTCTCCCCGAAATAGCTTTAGGGCTAGCCTCATACGAGAGTACCGGAGGTAGAGCACTGACTGGGCTAGGGGCCTTCGCGGGTTACCGAACCCAATCAAACTACGAATGCCGGTTACTTGATGTATGGGAGTCAGACTACGAGTGCTAAGATCCGTAGTCGAGAGGGGAACAGCCCGGACCGCCGGCTAAGGTCCCGAAGCGGTGCTAAGTGGGGAAGGATGTGGGGCTGCGAAGACAACCAGGATGTTGGCTTAGAAGCAGCCATCATTCAAAGAGTGCGTAATAGCTCACTGGTCAAGTGGCCCTGCGCCGAAAATGAAACGGGGCTCAAGCACCGCACCGAAGCCGCGGATCTGAGAGGTGAGAGGTGAGAGGTTGGAAGTGGGAATAACGATTCTCACATCTCACTTCTCACATCTCACCTCTCAGGTGGTAGGGGAGCGTTCCCACCGGGTAGAAGTCACACTGGGAGGTGTGGTGGACTGGTGGGAAGTGAGAATGCCGGTATAAGTAAGCGAAAAGGCAGGTGAGAATCCTGCCCGCCGAAAGCCTAAGGGTTCCTGGGGAAGGCTCGTCCGCCCAGGGTAAGCCGGGGCCTAAGCCGAGGCCGAAAGGCGTAGGTGATGGGGAATCGGTTGACAATCCGATGCCACCGGTAGGCCGATTGAGGATGGGGTGACGCAGGAGGGTAGGCCAAGCGCGCGGCTGGAAAGGCGCGTCCAAGCCGGTAGGGTGTGGGGCAGGCAAATCCGTCCCACGGTAAGCCCGAGAGGTGATGGGGAGGGAAATAAGAGTACCGAAGTGGCTGAACCCAAACTGCCGAGAAAAACCTCTAACGAGGAATACCGGTGCCCGTACCGCAAACCGACACAGGTAGGCGAGGAGAGAATCCTCAGGCGCGCGAGAGAACCCTCGTTAAGGAACTCGGCAAACTGACCCCGTAACTTCGGGAGAAGGGGTGCCCCGGTAGCGTGAAGGTATGAACTGCTGGAGCGCGAGGGGGCCGCAGAGAAGAGGCCCAAGCGACTGTTTACCAAAAACACAGGTCCCTGCGAAATCGAAAGATGAAGTATAGGGGCTGACGCCTGCCCGGTGCTGGAAGGTTAAGGGGAAGGGTTATCCGAGAGGAGAAGCTCTGAACCGAAGCCCCAGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCCGCACGAAAGGCGTAACGACTTGGGCGCTGTCTCAACGAGGGGCTCGGCGAACTTGTAGTACCCGTGAAGATGCGGGTTACCTGCGACGGGACAGAAAGACCCCGTGGAGCTTTACTGCAGCCTGACATTGGACTTCGGTATTGCATGTACAGGATAGGTGGGAGGCAGGGAAGCCGGGGCGCCAGCCCTGGTGGAGCCGACCTTGGGATACCACCCTTGTGGTATTGGAGTTCTAACAGGGTACCGTGGAGCCGGTACATGGACAGTGTCAGGTGGGCAGTTTGACTGGGGCGGTCGCCTCCTAAAAGGTAACGGAGGCGCCCAAAGGTTCCCTCAGCGCGGTTGGAAATCGCGCGTAAGAGTGCAAAGGCAGAAGGGAGCTTGACAGCGAGACTGACTGGTCGAGCTGGGACGAAAGTCGGGCTTAGTGATCCGGCGGTAGCGAGTGGAAGCGCCGTCGCTCAACGGATAAAAGCTACCCCGGGGATAACAGGCTTATCTCCCCCAAGAGTTCACATCGACGGGGAGGTTTGGCACCTCGATGTCGGCTCATCGCATCCTGGGGCTGGAGTAGGTCCCAAGGGTTGGGCTGTTCGCCCATTAAAGCGGTACGTGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCCCTATCCGTCGCAGGCGCAGGAAACTTGAGAGGAGCTGTCCCTAGTACGAGAGGACCGGGATGGACAGACCGCTGGCGTACCAGTTGTCCCGCCAGGGGCAGCGCTGGGTACCCAAGTCTGGTGGGGATAAGCGCTGAAAGCATCTAAGCGCGAAGCCCTCCTCAAGATAAGGTTTCCCACCCGGCACTCAACTGAGCTTGTCAGGCCAATCCACTTTAAGGAGAGATTGGCACGCTCAGTTGAGTGCCGGGGTAAGACCCCTGGAAGACTACCAGGTAGATAGGCCGGGCGTGTAAGCCGGGTAACCGGTTGAGCGGACCGGTACTAATAGGTCGAGGGCTTGACCAG
->CM002293.1/9210050-9209896 Phaseolus vulgaris cultivar G19833 chromosome 6, whole genome shotgun sequence. 
-ATACTTACCTAGATAGGTCAATGGATTATCAAGAAGATTCATGGTTTATGAAAGTAACTTTCATTGCAATTTGGATGGATGCGTTTCTGATTTTGTCAATCTTCATATAATTTGTGACCGATGAAGTCTGAACTTTTGAAAGTTTCACTTTCATT
->FP929055.1/3038167-3038356 Ruminococcus torques L2-14 draft genome. 
-TGATTATGAATGATCAGAGGAACGACGTGGGAAATCTGGACTGGTGAAAAGGGAAACAGGTGAGAATCCTGTACGAACTCGTCACCGTATTTCGTGAGCTTGTGTTTTGAGACCACTGGGAGACCGGGAAGGTGAAGCAGAAGCATTTGAACGATCAGCCGGGAGACCTGCCTTTCGCAGTACAGGAATG
->ALWZ042737980.1/1504-1133 Picea glauca, whole genome shotgun sequence. 
-TGAAGCTTTACTATTTCCTGGGAATAAATATGGATTCTTCTTTACATTTTTGGTGGACAGCAAAGAAGTTCCTTTAATGTGGGGCTTGAGCCATAACTGAGATACAGCTCTAGCAGAGTTAGAATTCCAACCTGTATTAGGACCCATGTTCCAAGGGGATGATCTTGGGTAAATAATTTCTATGGGGCGTAAGACTCAAAAGGTAATGGAGGCATGCAAAGGTTTCTTTGGGCTGCGCAGAAATTGACCCTTGAATGTAAAGCAAGAGCTAGCTTGACTGAAGAACCCACCTGTCAAGCAGAAGCAAAAATTGGCCTTAGTGGTTCAGCAGGATTGAGCAGAAGTGTCATTGCTCAATGGTAGAAGGTACTC
->CM001000.2/104264790-104264683 Mus musculus chromosome 7, GRC primary reference assembly. 
-GTGTTCTTGCTCAGGCATCATATGTGCCCAAAGTAGAATGATCAGGGAATGTTAATATGGCCCCTGCTCATGGATGACATGCGAGTTTATGAAGCATTCCATATTTTT
->ACTA01010209.1/17005-16720 Ailuropoda melanoleuca scaffold917_80, whole genome shotgun sequence. 
-GAGTGTGTTGAGGATCTTTCCACATCAGTTACCCTCCTAATGGCTGGAGTTGACTCGGCTGATGGGGATGGCTAAGTGGTGTCCCCTTCCTTTTTCACTACTCCATGGACATCCCTCCTAAAACGAAGTGCTTTTGGATGCAGAGGACAGCCCCATCGAAGTTGTTTTGTCAAGAGAAATTGATAGCTACACTCTGCTATTTGAATCTTCAAATTTAACACTTGCTTTTCTGTGCTTTCTCTTTGTTTCTCTTAAAAATATTATATATGATAACACATTTGGAAAG
->CM001415.1/8836720-8836132 Lepisosteus oculatus linkage group LG12, whole genome shotgun sequence. 
-AAGGAGCAATGACACAAGAGTTCCTGTCACAAGTCAGACTCGGTCCAGGGATAATGCTGGGTGGGGAGGGCTAGTATTAAGGACAGTGGGCTGCACAGGGCGACATCACTTTTTGATCCTTTGATCCTTCCTAGAACTGTGAAGTAGGATTCACTTAGTATTGGATTGTTCACCCTCTAAATGGGAATGTGAGCTGGGTTAGACACTCATGAGACAGATTAACTTTACCTCATGGCTTTACCGATGATGCGATGTTGCGATTGCTGTTGTGATCTGCTGCTCTTTATGAGAGGAACCACAGGTTCAGACACTTGATGTCTGTCTGTGCTTGGCTGAGGAGCCAATGACACAGAACCCACAATTTGTGGGATTATGGTTGGATACCTTCATGACAACCCCAACGCCTTAAAAGGTGTAAATGTTCTGCGACACAGAGTTACAAAGCAGATTAAGATTTCACAGCAAATCACCAAAGAGACACCTTCTTCACCGTTCTAGAAAATCCTTTTCTACATTAAAGTCCCTGAAATAAGGAAGATCCTTGAAGGTGCTAATTCTTGCACAACAGACACTAGTGCAGTCAATAAGG
->FR799005.1/397220-397284 Leishmania braziliensis MHOM/BR/75/M2904 complete genome, chromosome 30 
-CCGCTGCATCAGTACAGCGACATCATCTTTTCGAGTGGTGATGCCTGCTGGCGATGTCAGCAAGA
->AUSU01007329.1/5457-5644 Genlisea aurea contig_12937, whole genome shotgun sequence. 
-TAGGGGTATAGAGAGCTTTCTTCAGTTCAACCACAGGAGAATTAGGATTCAATCTGCTGCCGATTCATTTAAACAAACGATGTACGGATTTATCGAGTACTTCGATTGAACGAATGATGCGGGAGTCAAGTTGAATTCCATTTGCTTTTCTTGTGTTTGGACTGAAGGGAGCTCCCTTTTTTCTTCTT
->GL871722.1/1-494 Dictyostelium purpureum unplaced genomic scaffold DICPUscaffold_800, whole genome shotgun sequence. 
-CTCTGGGGTTAGAGTGCGGCAACGTATCTTTGCTTCAAGGAGTGTGTAGTCTGACTTGATAGGTACGTTAACAAAAAACTTCTTAGAGGGACTACCTGCCTCAAGCAGGCGGAAGTCCGAGGCAATAACAGGTCTGTGATGCCCTTAGATACCTTGGGCCGCACGCGCGCTACAATGCAGATAGCAAAAAGGTTCCTGGTCTGGAAAGATTGGGTAATCAATTGAATTTTCTGCGTAACTGGGATTGATCTTTGTAATTATTGATCATCAACGAGGAATTCCTTGTAAGCGTAAGTCATTACCTTATGCTGAATATGTCCCTGCCCTTTGTACACACCGCCCGTCGCTCCTACCGATCGAATGATACGGTAAAGTTAACGGATAGTTTTTTTGTGGCAACACAATTAAAATTAAAAGTTATTTAAATCTCATTGTTTAGAGGAAGGAGAAGTCGTAACAAGGTATCCGTAGGTGAACCTGCGGATGGATCATTT
->CM002821.1/68112919-68113024 Capsicum annuum cultivar Zunla-1 chromosome 10, whole genome shotgun sequence 
-GACCACGTGATTAGGGAATTGATTAATTTATCATTCAATCATTGCCATACTTCATACAAAGGTTCACCATTGAGTTGGCAGAACTTTATTATTCAATCTCTAGGTT
->AYYE01001153.1/1824-2049 Tannerella sp. oral taxon BU063 isolate Cell 1/3 contig_2519917771, whole genome shotgun sequence. 
-ATTTTTGCCGCCGTTTTCGGTGACGCCAGGTCGGACGGTCCCGTCCGCGACGTGAAAAGGGAATCCAGTGAAAGACTGGAACAGTGCCCGCTACTGTAACACCCCACCTATCGAACGAAGGAGAGCACCCGCAAGACGTGCCACTGCCGCCACTGAGGCGGTGGGAAGGCCCACAGCCCTCCTTCAGGGTGAAGTCAGGAAACCTGCCGGAAACAACAACGTATAC
->AZNC01074805.1/442-855 Glycine soja cultivar W05 scaffold3126_15, whole genome shotgun sequence. 
-GACTCTGATGCTATATCAATAAATGTCCATATAGGAAATGGCTATCCTAATGGCTCGAGTGGCATAAACGAATGAGAGGTAACAAAGGCTTGCAAGGGTTTCCTCGGATCAGATGGAGATTAGGCCTTTAGTGTAAAGGCAAAACAAAGTTTGATTGTAAGACCCACCCATCGAGTAAAGATGGAAGTCAATCTTAGTGATCTGATGGTGCCAAGTAGAAGGATTGTCCCTCAATGGGCTATAGGGATAACAGACTCATCTTCCCCCAAGAGTTCAGATCGACAAGAAGGTTTGGCACCTCAATGTCGGGTCTTCGACATTTGAGGTTGTAGTATGTTCAAAGGATTAAGTTGTTCGCCCATTAAAGCGGTATATGGAAAATGCAAGTTCTGTAAGGCACATAAGATTGTGTTA
->MCGE01000002.1/764806-764528 Absidia repens strain NRRL 1336 BCR42scaffold_2, whole genome shotgun sequence. 
-AGCAACGAAGAAGATCTGCATGTTTGACGCACCACACACACGGGGGTTTTATACTCATTATAAATTGCGTTAGGGAAGTTCTCCAGACATGTGTACCTGTAATGGGTTATTGAAAGCAGCCTTTCTTAAGGTTGTGGTATTCAATTATGCCAAATTATCAGCTAAGATAGCTGTGGTATGGTTGGGTATCCAATAGTTCTTGTCATAGGAATAGGTATTGCGGATCTTGGTAAAATTTATTTTATCATGAACTCAATGGAGGCTACTCTCTTTTGTTGC
->ASAF01079751.1/2035-2138 Nicotiana sylvestris Nsyl_contig79751, whole genome shotgun sequence. 
-TACGCAGGAGAGATGATGCTGGATAATGGACCATCCCTGCTTAGCTATCTCAAGAGATTGGAGGGAGCTTTGATTATTTAGCCAGCATCATACTCCTGCATATT
->JXLN01013749.1/1932-192 Sarcoptes scabiei Contig13748, whole genome shotgun sequence. 
-TATCTGGTTGATCCTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCCATGCATGTCTAAGTACATACCGCATTAAGGTGAAACCGCGAATGGCTCATTAAATCAGTTATGATCTATTGGATGTTGACCAATTACATGGATAACTGTGGTAATTCTAGAGCTAATACATGCCGAAAAGCTCCATCGCAAGGTGGGGTGCATTTATTAGACCAAGACCAAAAGGTGGAAACACCTTGTTGTGGTGACTCTGAATAACTGCAGCTGATCGCATGGCCTCGTGCCGGCGACATATCCTTCGAGTGTCTGCCTTATCAACTTTCGATGGTAGGTTATATGCCTACCATGGTTGTAACGGGTAACGGGGAATCAGGGTTCGATTCCGGAGAGGGAGCCTGAGAGATGGCTACCACATCCAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCTTGGAACAAGGAGGTAGTGACGAAAAATAACAATACGGGCTTCGCTTACGCGTTCTCGTAATTGGAATGAGCACAGTTTAAATCCTTTAGCGAGGATCAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGTGGTTAAAAAGCTCGTAGTTGGATCTCAGCCCAAGTGCATTGGTCCATCATGACGATGGTTACTGGTGTGCTGGGCACTTTACCGTTCACGTGCTATGGTGTTCTTAACCGGGCGTCATAGTCGTACGGTAGTTTTACTTTGAAAAAATTAGAGTGCTCAAAGCAGGCATCATCGCCTGAATACTGTTGCATGGAATAATAGAATAGGACCTTGGTTCTGTTCTGTTGGTCTTCGGATCCGAGGTAATGATTAAGAGGGACGGACGGGGACATTAGTACTGCGGCGATAGAGGTGAAATTCTTGGACCGCCGCATGACTAACCAAAGCGAAAGCATTTGTCAAGAACGTTTTCATTAATCAAGAACGAAAGTTAGAGGTTCGAAGGCGATCAGATACCGCCCTAGTTCTAACCATAAACGATGCCAACTAGCAATCAGCCAGAGTTCGTTTATGACTCGGCTGGCGGCTTCCGGGAAACCAAAGTTTTTCGGTTCCAGGGGAAGTATGGTTGCAAAGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTNNNNTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGCGATTTGTCTGGTTAATTCCGATAACGAACGAGACTCTAGCCTACTAAATAGCAATCGGAATTCGTTTCGACTTCCGATCCAAGCTTCTTAGAGGGACAAACGGCGTTTCAGCCGTATGAAAAAGAGCAATAACAGGTCTGTGATGCCCTTAGATGTCCGGGGCCGCACGCGCGCTACACTGAAAAGATCAGCGTGCATATGTTACCTACTCCGAAAGGAGCGGGCAACCCAGTGAAACTTTTTCGTGATTGGGATTGGGGATTGTAATTATTGTCCATGAACGAGGAATTCCCAGTAAGCACAAGTCATCAGCTTGTGTTGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTACTACCGATTGGATGTTTTAGTGAGGTCTTCGGACTGGCCAACGTAGCCATCCTCGTGGTGGCCATGTTGTGCGGGAAAGATGACCAAACTTGAACATCTAGAGGAAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTA
->CM001648.1/54674393-54674536 Nomascus leucogenys chromosome 2, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGTAGTATCTGTTCTTATCAGTTTAATCAAGAAATGAAGATGGAATATTATTTTACAATGTCTTGATAAGTTGGGGAGCCTCATTATGAAAATATGGGAATCATAGAATCTCT
->CP001720.1/2579904-2579665 Desulfotomaculum acetoxidans DSM 771, complete genome. 
-TCACAAGTGATGATAGGGAAGAGTAAACCTGTACTGTTTACAGAGAGAAGCCGCCTTGGTTGAAAGCGTCTTTAAAAGAAGGCAGGTTAAAAACCACCCTTGAACTGCATAGCCGAAAATTTTAATCCTCAGGGGATTATAGATCAGTAAGCTTAGCCGGCGGCAAACGTTAATTGCTCTGAAGTGAGGAAATTTTATTTCCTAATTTGGGTGGAACCACGGAATAAGACCGTCCCTATT
->JMCC02000032.1/46273-46035 Enhygromyxa salina strain DSM 15201 ES-Contig_32, whole genome shotgun sequence. 
-ACTCCGAGGTCGAGGCTAACAATGGCCCTCCGGCGCGCGAGCGCCGGCTGAAAATCGGGTGAATTGCCAGAAACTCCGGGGACGGACAACCGGCAGCCAAGGTCGAGACGGCGGTGCAGCGATGCCCAAGGGCTCGGCAAGGTTCAGAGACTAGGGCCCGAGCGAAAGCGGTGATGGCCCCACGAGCGCCCGACATCTCCCGCGGGAGATGATGAGATAGTCCGTACTGCCGCGATAAT
->LPNI01000102.1/691-2685 Bacterium P201 scaffold_101, whole genome shotgun sequence. 
-GCGAAAGAAAGTTAGGGCGTCTGGTGGATGCCTTGGCTCTCGGAGGCGATGAAGGACGTGATAAGCTGCGATAAGCCATGGGTAGGTGCAAATAACCTTTGATCCATGGATTTCCGAATGGGACAACCCAGCCGGCTGAAGGCCGGTTATCTCTGCCTATGCAGAGAGGCAAACCTAGGGAACTGAAACATCTTAGTACCTAGAGGAAGAGAAAATAAACAATGATTCCCCCAGTAGTGGCGAGCGACCGGGGAAGAGCCCAAACCGCATGTGTAGCAATGCATATACGGGGTAGTAGGACCACGTCGTGGCATGCTGATCGTGAGAAGAATGTTCTGGAAAGTTCAATCATAGAAGGTGACAATCCTGTAGTCGAAGCGTGATGCAGCCTAGTGGCATCCTGAGTAACGCGGGGCACGAGTAATCCTGCGCGAATCCGCCGGGACCATCCGGTAAGGCTAAATACTCCCGAGAGACCGATAGCGAACCAGTACCGTGAGGGAAAGGTGAAAAGCACCCCGACGAGGGGAGTGAAAGAGTACCTGAAACCAGTCGCCTACAAGCGGTCGGAGCATGTTTATCATGTGACGGCGTGCCTTTTGCATAATGAACCTACGAGTCACCATCACAGGCGAGGTTAAGTCACTAAGTGACGCAACCGCAGTGAAAGCGAGGCTGAAGAGGCCGTTTAGTCTGTGGGGGTGGACGCGAAACCGAGTGATCTACACATGGTCAGGGTGAAGTCCCGGTAACACGGTATGGAGGCCCGCACCAATAAGCGTTGAAAAGCTTCTGGATGAACTGTGTGTAGGAGTGAAAGGCCAATCAAACTCGGAGATAGCTCGTACTCCCCGAAAGGCATTTAGGTGCCGCGTGCTGTGTTCACCCTGTGAGGTAGAGCGACCGATAGGTCAAGAGGGCTTCACCGCCTATCGCGACCTGACGAACTCCGAATGCACAGGGTCCGTAGCAGTGCAGTAAGGGTGCGGGTGCTAAGGTCCGTGCCCGAGAGGAGAAGAATCCAGACCGCCGTCTAAGGTCCCGGAGTTCTGCCTGAGTTAGTCTAACGAAGTCTGGTCTCGATGACAGCTAGGATGTTGGCTTGGAAGCAGCCATTCATTCAAAGAGTGCGTAACAGCTCACTAGTCGAGAGACCGGGCGTGGATAATAATCGGGTATAAGGCAGACACCGAAGGCGCGGGATAGCAAATAATAAAAGTATCGGTAGGGGAGCATTCCATCTGCGCCGAAGCAGACCGGTGACGATCTGTGGAGCGGATGGAAAAGCAAATGTAGGTATAAGTAACGATAAGGGGCGTGAGATCCGCCCCCGCCGAAAGACTAAGGTTTCCCGGGCGATGTCAATCAGCCCGGGGTCAGTCGGGTCCTAAGGCTCAGCCGAACGGCGAGGCCGATGGCTGACACGGTTAATATTCCGTGACTTCCCATTGGGGCGATGTGGTGACGGAGCAGTGGAACTGCCGCGCGGCGACGGATGTCCGCGTTAAAGGGTGTAGGCGTTGATTGGGGCAGGCAAATCCACCCCAAGAGCTGAAACCTGAAAGTACGGGACTCTCTTCGGAGAGACCTGACAGAGCAGGTAATCATACTCCCGAGAAAAACCGCTAAGCTTAACCTTTTGGGAACCCGTACCGCAAACGGACACACGTAGTCGGGTAGAATATACTAAGGCGTTGAGAGATTCGTGGCTAAGGAACTAGGCAAACTGACCCTGTAACTTCGGGATAAAGGGTCCTCGCTTATAGCGAGGCGCAGAGAATAGGTCCAGGCAACTGTTTAACAAAAACACAGGGCTGTGCAAACTCGAAAGATGATGTATACAGCCTGACACCTGCCCGGTGCCGGAAGGTTAAGAGGAGACGTCAGCCTTAAGGTGAAGCGTTGAATTGAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGG
->LXWF01000040.1/121949-121803 Rothia nasimurium strain PT-32 scaffold4_size309601, whole genome shotgun sequence. 
-ACAAAACAAAAATTATCAGGCAGAAGCGGGGGACCCACCTTTCGGGCTCACCACCTAGGAGCCCTTGGGGTTAAGTTGCAGGCAACTGTGACCGAGTGACTTCATACTCGAACCCGACAGCTCACCTCGTTCGGCAATGGAGGAAAA
->AFTD01062031.1/43354-43570 Cricetulus griseus cell line CHO-K1, whole genome shotgun sequence. 
-AATCAGTTGTATGTATGTACTCTTTTGCATGCATGCACACGCGTGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCGCCTTTACAAAACTTGGATTAACAAAATCTTTTATGTATGTTGCTTGTTTGGTTTGGTGTTTGTTGAGACAGGGT
->CM000665.2/44861892-44861973 Homo sapiens chromosome 3, GRCh38 reference primary assembly. 
-CAGCGGGTGCCAGGCACGGTGTCAGCAGGCAACATGGCCGAGAGGCCGGGGCCTCCGGGCGGCGCCGTGTCCGCGACCGCGT
->GL010031.1/37115110-37115156 Loxodonta africana unplaced genomic scaffold scaffold_4, whole genome shotgun sequence. 
-AAACAGGCTCTCTAACAGAGCCACAGAATGTTAAAAAAAAAAAAAAA
->FQXS01000031.1/44397-44023 Desulfofustis glycolicus DSM 9705 genome assembly, contig: EJ46DRAFT_scaffold00031.31 
-CGCCGCCGGATAACAGGCGCATCGTATCTGGTTATTAAGAGGTCCGGTCGAAACATCACATGATGCCTCGGCTCTACCACAAAAGGGGTTCACGAAAGAACCCTGCAAAAAGGAGTAATTCAACATGGCTGAAGGCACAGTAAAGTGGTTTAACGATGCGAAAGGTTTTGGTTTTATCGAGCAGGATGGCGGCAAGGATGTGTTCGTGCACCATTCGGCCATCCAGGCTCAGGGCTTCAAGTCCCTGACCGAGGGTGCTCGCGTATCCTTTGACGTTGTCGACGGCCCGAAAGGACCGGCGGCAGCCAACGTCGTCCAGCTCTAAGAGCCGGATACGGTTGTTGTGGACCCCGCACCCTGGGTGCGGGGTTTTCT
->LCFB01000050.1/5945-6029 Microgenomates (Gottesmanbacteria) bacterium GW2011_GWA1_43_11 UV59_C0050, whole genome shotgun sequence. 
-GCCGAGGTGATGAAATGGTAGACATGCAGGGCTTAGGACCCTGTGAGCCTTAAAACTCGTAGAGGTTCAAGTCCTCTCCTCGGCA
->AFOY02000015.1/191187-190961 Pseudomonas fluorescens HK44 Contig15, whole genome shotgun sequence. 
-CCTACACGCCTTGTTACGGGTGCCCTTCACAGGGTGAAACGGGAAACCGGTGAATCATGTGCTTTACTCAAAAGCCATGTCAGTCCGGTGCTGCCCCCGCAACGGTAAGCGAGCGAAGAATCAGATCCACTGTGCCAGAAGTTCGGCATGGGAAGGCGATTCTTGCAGGTTCGGCGAATGCCAGCCCCTCGTGAGCCCGGAGACCGGCCCGCAACACATAGTGCCTT
->AAAB01000498.1/1506-345 Anopheles gambiae str. PEST whole genome shotgun sequencing project, whole genome shotgun sequence. 
-TGGCGGCGGTTCGCCTGCGCGCGCCCAATGCGCCGTGTTTCTCGCTCAGCGTCCAGTGTGTCGCTGGGTGGTGCCGCCGGGGAGACTGCATCGTAGCATCGTCGTGTGTAGCGTGTTACCCGCTTGTCCGACCGTGAGCCGTGGCCCGCAAGGGTACAAGCTTGCGTACGTCGGTGCATTCGTGGTGCACTGCTTCTGCGCGGTCGATCGTTTATGATGTCACGTTTGCCCCCGGTTCCGCGCGCCGCCCGGCTCGAAGACTCCTGGACAGGTCCTTTCGGTCCACGTCATGGACAGTGCCAGGTGCGGAGTTTGACTGGGGCGGTACATCTCCAAAACGATAACGGAGGTGTCCAAAGGTCAGCTCAGTGTGGACAGAAACCACACGCTGAGCATAAGGACAAAAGCTGGCTTGATCCCAACGTTCAGTACACTTCGGGACAGCGAAAGCTTGGCCTTACGATCCTTTTGGTTATAACGAGTTTTTAGCAAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCCGCCAAGCGTTCATAGCGACGTGGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAAAATTCACCAAGCGTAGGATTGTTCACCCTTTCAAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGGTGTGTGCTTATAGTCGCTATCTTAACGGAATTCCTGTGCAGTACGAGAGGAACCACAGGTACGGACCACTGGCTCATACTAGTCCGACCGGACTTTGGTATGACGCTACGTCCGCTGGATTATGCCTGAACGCCTCTAAGGTCGTAGCCAATCCGAGCTGATAGCGCTTCTCAAACCCATTAGGTGTTCGGAAGCTAGCGGGCCTAACAACCCTCTGAGATCCGTTGGAGTCTGCGTCTGCAGCCCGGCGTCTCATCCCGCTATACCTAGGCCGCAACGAGTGGAGTTCGCTGCACGTGTTAGTACCGTAACTGGGAACGCCGTTGGCTTGAGCTCTGCCCAACGTGGATATACCTAGTTTCGACACCTATCAACCGCCCGCAAACGACGGGACTTCAGGCTGGGAGCTGCGAGTTGTAGAGATGCGTTCGCATCGATCCTCTCAGGCGACCCATGCTTGGTGGTTTGTC
->URS0000D6AEAC_12908/1-95 unclassified sequences Rhodo-rpoB RNA 
-GGGTCGGAGGGCGGCCAGTGGGACGGCCGCCTCGGATGGACCCCTCGACGTCCGCTCTCATGGGGGAAGGCGCCGCGGCCCCGGCGGCGCCCGCC
->CYSP01000003.1/255745-256067 Propionispora sp. 2/2-37 isolate 2/2-37 genome assembly, contig: 2/2_contig3 
-GTATACGAGGGAACGCTGTACATTGTGCAGAGGAAAGTCCGGACAGGCACGGGCTGCGATGCCCGTAGTGATTGCGCGTGACCTAAGAAGTCACGGAAGGAAGCTCATTCCTTACGGCGGCAAAACCGACTCTGTCTGAGTTGGCGGTAGCCTGAAAGTGCCACAGAAACGAAACGTTCCGGCGACGGAACGATGCAAGGGTAAACCCCGCAAGCCTGAAACTCAAATTACGGTAGAGGAACCCTAGGAAGGGAATAAAACCAGATTAGGGCGCATGAAACTGCGAGATAAATGTTTCCTAAAACAGAATCCGGCTTACGGTA
->KI669466.1/623363-623809 Kwoniella mangroviensis CBS 10435 unplaced genomic scaffold supercont2.9, whole genome shotgun sequence. 
-AGTCCAATCTCATCTCACACTCGCGAGCGGGCCAAGGTCCTGGAATTTCAACCCCCCTTTCATCTTATTTCCTTATGGAAGAAGATGTCTGACCGATCTTAGCGGATCCTTGAGTTAATTTCAAACCAAGTAATTCCCGACCAGAAATGCGTCCTCTCCATCTTATCCGTAAAGGAAACCCATAGAAGCGTTTGACGTGGAGGGTATGGATGGAGATATTTTGGACTTGGTATGGGAATGGTGAGGTAGCCTTATATCGATGTTCTCTATCCTCGATGCCTGGATAAAGAGTCTCTGAAATCAAAGAGAAGTGTTTTGGTCATAGACCAAACCCCGATATACATAAAAAGGCTTTAGTGCAATTTGGTGACGTCCTCATACTCAAAAACCTTCTTTGATCTCAAGTTGAAGAAGGGAGGATAACTCGATCAGGACTACTCTGGGACT
->LT629734.1/2109114-2109055 Agrococcus carbonis strain DSM 22965 genome assembly, chromosome: I 
-GCCGCCCGTCCTGACACAACGGATCGTCCGGCACGTGCCTGCCGGTGGAAGGAAAGAGAC
->X51710.1/1-45 Dengue-2 virus RNA for capsid protein, partial, from a case of dengue fever (M3) 
-ATGAATAACCAACGAAAAAATGCGAGAAAAACGCCTTTCAATATG
->JH835393.1/4707706-4707998 Erinaceus europaeus unplaced genomic scaffold scaffold00105, whole genome shotgun sequence 
-GGATGTGAGGGTGATCTGACTACGAAATCTGTCACCCCATTGATCACCAGGGTAGATTCGGCTGATCTGGCTGGCTAGGCGGATATCCCCTTCCTCCCTCACCACTCCATGTGCATCCCTCCTGAAGCTGTGCACCGGTCTTCAGTCGAGGGTATAGGAGTAGCTGCGCCCCCCTGCTAGAACCTCCAAACAAGCTCTCAAGAAAGAGCAGAGCCCTACTCAGCTCTGGCTTATGGTGGTGCTGGGGATTGAACCTGGGACTTCAGAGCCTCAGGCATGAGAATTCTTTGCAT
->AWUE01002803.1/746-1 Corchorus olitorius cultivar O-4 contig02805, whole genome shotgun sequence. 
-AGCTTACCGACTCAAAGCTTTAAGGCCTTAAAGCCCGTTCGCCCTGGATGATTCTGAAAAAATTGAGGATTTTGGTCTTGAAAAAGAGTAGTCGATGATTAACGTTGGATGATTGGAGTCGCGCGAGTACCGTGTGGAAGGGTGAAAAGAACCCCCGTCGGGGAGTGAAATAGAACATGAAACCGTAAGCTACCAAGCAGTGGGAGGAGCCCAGGGCTCTGACCGCGTGCCTCTTGAAGAATGAGCCGGCGACTCATAGGCAGTGGCTTGGTTAAGGGAACCCACCGGAGCCGTAGCGAAAGCGAGTCTTCATAGGGCAATTGTCACTGCTTATGGACCCGAACCTGGGTGATCTATCCATGACCAGGATGAAGCTTGGGTGAAACTAAGTGGAGGTCCGAACCGACTGATGTTGAAGAATCAGCGGATGAGTTGTGGTTAGGGGTGAAATGCCACTCGAACCCAGAGCTAGCTGGTTCTCCCCGAAATGCGTTGAGGCGCAGCAGTTGACTGGACATCTAGGGGTAAAGCACTCTTTCGGTGCGGGCCGCGAGAGCGGTACCAAATCAAGGCAAACTCTGAATACTAGATATGACCTCAAAATAACAGGGGTCGAGGTCGGCCAGTGAGACGATGGGGGATAAGCTTCATCGTCGAGAGGGAAACGGCCCGGATCACCGGCTAAGGCCCCTAAATGACCGCTCAGTGATAAGATAAAGGAGGTAGGGGCAGAGACAGCCAGGAGG
->AZST01000551.1/9313-8979 Rhizoctonia solani 123E scf_551, whole genome shotgun sequence. 
-CTCTTGCCATTGTTGTGGGCAGATATAGTGAATGTGGGCGTCGACCCCCCCAGCTGTGATGATCAGTTTCTCGCCTGCGATCACTTCCGTGTTGGCTCCAGCTACCAAGTCAGGGTCGACTCCGTCCATAATGTCAGGATTCCCCGCTTTTCCAATTCCAACTATCTTCCCGTGTCGTATTCCAATATCAGCCTATGCACGTCGTGAGTATTGACGCAGGGAAAACTGAGCGATGCGAATACCTTGTAAATTCCGGACCAGTCGATGATGAGTGCATTGGTGATTAAGAGATCAAGGACCTCGTATCGCTCTCCGCAAGCCCGGCCCTCTCCGTG
->LGUE01000001.1/1373798-1373578 Bacillus marisflavi strain JCM 11544 scaffold1, whole genome shotgun sequence. 
-CAAAAGGCTGTGACAGGGAGAGTACGTTTCAGCAATAACCTTTATCAGCGAATCGGGGGCGGTGCAAGCCCGGTAGGGAAATGAAGCGGAAGATCACCCTTGAGCCCTGTCTGTGAACAAATGCTAGCAGACGGCGACTGATCCATGTTACGGATTTTCGAGTGAGGGCAATTATGCCCTTATGAGGGTGGTACCGCGGGAAAAGCTTTCTCGTCCCTTTC
->AEDQ01000029.1/68978-69146 Atopobium vaginae PB189-T1-4 contig00020, whole genome shotgun sequence. 
-ACGTAGTTTCAGGGCGGGGCGAACATCCCCACTGGCGGTAAATAAACGCACTAGCTGCACTAGCTGTACTAACTGTAATAAACGCGTTTACAAGCCCGCGCGCCACACTGTGGCTGATTTGGTGAAAGTCCAAAGCCAACGGTTATAGTCCGGAAGAAAGAAACGAGGA
->JMFP01072321.1/1087-1 Pygoscelis adeliae contig72321, whole genome shotgun sequence. 
-AACGCACGCTGGAGTAGAGGAAACAAGAAAGATGCAAGGAGAATTGGAGGAAGAGACTAAGAAGCAAGGAGTAGCAGAAAGAAACCATTATGCACTGACCCCAGCCTCCTGCACATTGCCTCACCAAGGGGACTGAGTGTGATGTGCGGTGTTGGCCTGAAGTCAAGCCTGGGAAAGAGGAGGAAATGCATTTCCCTAAGTGTTTGTCTAGTTATCTTCGTGGGAGTTTGGGTTTTTTTTTCTCAATACCCAAATAGGTAATTAAAAGTTTATGTTAATTTGCAATACATTAAATTAGCTGAAATTCCCTGAGTCGAGACTGTTCTGCCCATGACACCTACCCATCCCAGAAAATAACAAGAAGGTTTGACCAGTGATTAGTGTTAAGAGCCTGCTTTGTGCAGCCTTTCACTTTGACCATGATGAAGTTACTTGGTCTCCCGGAGCTGCATTTTCCCATTTCTAAAATGAACACGTCTTTCAAAAGAGACATTGTAAATCTATTTCATTTTTGAGATGCTGAGGTGGAATGGGAAATCATCTGACAATAGAGTGGGGGAAGACCCCCAAGTTGGTCGGCGTCCAACTTCTTAGAGGGACAAGTGGCGTTCAGCCACCCAAGATTGAGCAATAACAGGTCTGTGATGCCCTTAGATGTCCGGGGCCGCACGCGCGCTACACTGACTGGCTCAGCTTGTGCCTACCCTCCGCCGGCAGGCGCAGGTAACCCGTTGAACCCCATTCGTGATGGGTATCGGGGATTGCAATTCTTCCCCGTGAACGACGAATTCCCAGTAAGTGCGGGTCATAAGCTCGCGTTGATTAAGTCCCTGCCCTTTGTACACACCGCCCGTCGCTACTACCGATTGGGTGGTTTAGTGAGGTCCTCGGATCGGCCCCAGCGGGGTCGGCCCCGGCCCTGCCGGAGCGTCAAGAAGACGGTCAAACTTCACTATCTAGAGGAAGTAAAAGTCATAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTACCGGGGGTCGGGGTCGCGCCGGGCGTCCGGCCGCGCCGCCGACTCGATTCGCCGCTCACCCGCGCCCCGCCG
->LHQN01016515.1/4388-3427 Habropoda laboriosa contig16515, whole genome shotgun sequence. 
-GAACATATGGAGAATGTCTACTCCGATGCACTTACGACCATCGTGTCTAGGGAATCCGGTTCCTATTCCGGAACCCGGTAGCGGAACCGAAATCCATTCGGGCCCTCATTGAGTGTTCGTCGGGGTAACCCAAAATGACCTGGAGACGCCGTCGGGAGATCCGGGGAGAGTTTTCTTTTCTGTATAAGCGTTCGAGTTCCCTGGAAACTTCTAGCAAGGAGATAGGGTTTGGAACGCGAAGAGCACCGCAGTTGCGGCGGTGTCCGGATATTCCCCTCGGACCTTGAAAATCCAGGAGAGGGCCACGTGGAGGTGTCGCACCGGTTCGTACCCATATCCGCAGCAGGTCTCCAAGGTTAAGAGCCTCTAGTCGATAGATTAATGTAGGTAAGGGAAGTCGGCAAATTGGATCCGTAACTTCGGGATAAGGATTGGCTCTGAGGAGCGGGGCGTGTCGGGCTTGGTCGGGAAGCGGGTCTGGCTGACGTGCCGGGCCTGGGCGAGGTGAACCTGTGGTGTCTCCGCATGGGATCCGAGCTCGGTCCCGTGCCTTGGCCTCCCGCGGATCTTCCTTGCTGCGAGGCTTCCGTTGGCGGCCTGCCGTCGGCGGTCGTCCTCTTCGGCCGCCATTCAACGCTCAGCTCAGAACTGGCACGGACTAGGGGAATCCGACTGTCTAATTAAAACAAAGCATTGCGATGGCCCCCACGGGTGTTGACGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAACGTGAAGAAATTCAAAAAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTTGCAAAGACTTTCGCTCTCCGAGGTGGCGTCATCTGTTCGTCCTGGGGACTATCTTGCCCTCCAGATTGCTAGGGCACGTAGGTGCCTTAGCGATCACGGCGAACCCATCGACACCCCTGCGAAGGAGTCGCGCCGTTGGGCTGCGGC
->AEWC01017985.1/26701-26812 Solanum tuberosum cultivar DM 1-3 516 R44 scf00126_13, whole genome shotgun sequence. 
-ATTCCATGAACAACCAGGAAATAACAAATAAAACTGGAATGACATAAAGAAGATTAGCATGCCTATGGGCAAGGATGACATGCCCAAATCAAGAAATAACAAATAAAATCTT
->CCCW010003393.1/857-2271 Brassica napus, WGS project CCCW01000000 data, contig: 40795 
-AACCCGTCCTGGAGGAGTGTTGTTAAAGGGTGAAGACCTGGGTTCGAGTCTCACCAACAACCTAATTATGGAGTCAGAGAGGACTCATAATGGAGGGGTTGGGGTCGGTGCGCTGCAGCGCTGTGAACCTAGGTTCCTAGTGAGAGGATGGGTTGTCACACTCTGCCCGTTGCTCTGATGATTCATGATAACTCGACGGATCGCATGGCCTTAGTGCTGGCGACGCATCATTCAAATTTCTCCCCTATCAACTTTCGATGGTAGGATAGTGTCCTACCATGGTGGTAACGGGTGACAGAGAATTAGGGTTTGAGTCCAGAGAGGGAGCCTGAGAAACGGCTACCACATCCAAGGAAGGCAGCAGGCGCGTAAACTACACAATCCTGACACGGGGAGGTAGTGACAATAAATAACAATACCTTAACGAGGATCCATTGGAGGGCAAGTCTGGTGCCAGTAGCCGCGGTAATTCCAGCCCCAATAGCGTATATTTAAGTTGTTGCATTGAACCTTGGGATGGGTCGCCCGGTCCACCTTCAGTGACCACCGGTTGGCTTGTCTCTTCTGTCGGCGATATGCTCCTGGCCTTAACTGGCTGGGTCGTGCCTCCGGTGCTGTTACTTTGAAGAAATTAGAGTGCTCAAAGCAAGCCTACGCTCTGTATACATTAGCATGGGATAACTTCATAGGATTTTGATCCTATTGTGTTGGCCTTCGGGATCAGAGTAATGATTAACAGGGACAGTCGGTGTAGAAACCCGTTAAAAAAAGAGAGAATGGTTGAGTATCTTTGTGTTGGTCGAGTCGCGGGTGATACTTATCGATCGAGAAGTTTTGAAGTACGAGGTGGGCGAAGAAGTGATCGTGAGTGAACTGTGAGTCGAATAAGTTGCTCGACCATAGTTACAAAATGTCTTAGATTAACGAGACAGACGTTTTGGAAGCATAACATTTTTGGAAGTACGACGGTTTAGAAGCTCGACGTTTTGGAAAAATGACGTTTCTTCAGCACGAAGTTTTCCGCGAAAACTCGTATCAGCGGAATATTATTTCGAAGACATTGGAAGGAGGACGGGAATTAAGCACGATGGGCAGCAAGCACGACAGGATCGAAGCACGACGGGAAAACCCAAAATTGGACGAAAACCCTAATTTCGGTATTATGAAAGTTTTCGATGAAGCCAAAGGATCTAGAAATGTTTACTGCCAAGGTCATAGTTCAGATTGGAGTTTATTAAAAATATTCCGCTCATCAGAATGGGAGCAGAAAGTATTCGGGATTAATCGCGGGTCAGAAATTTACCGGAATGACCGTAATCAGACAAATAGACCGAGAAGCTCGAGGTGGCTCGTTGCATGGGTTCAGAACGTGGTGTCAACCATCTAAAATGCTGAGTGTCTCCAGAAGCTCGAGG
->GL637601.1/12317752-12317884 Caenorhabditis tropicalis strain JU1373 unplaced genomic scaffold Scaffold629, whole genome shotgun sequence. 
-ATCCCACTGATTACAAATTTCGCTGATACCTGCCCACCCGAAAGCCTGGAGGCCACAGGGAGTGGGGTCCCGCCGGTCGATGAATGGCTGACAACGGTGGGAACCATGATACAGATTATGAGAGATGAGGGTT
->AARH02006624.1/20544-20687 Populus trichocarpa scaffold_19_contig_351, whole genome shotgun sequence. 
-AATAACCAAAAATAAAACTTGGGCTAAGGGTAACGTTGGTAATTGTTCTTACATCTCCCACCCCTGGAAACCAGGTATCATATACGGGCCCAAAATAAGGAGCTTTGAATATCTAAAATTGTCGTAATTTTATTTCTCTTTCCA
->JRES01001669.1/266737-266612 Lucilia cuprina strain LS Scaffold353, whole genome shotgun sequence. 
-TAACAAAAAAATAAAAATAAACAAACTAAGTACTGGTGCAGCAGGAACTATATGGAGCTAAATGCTGTTGCTCCATTTAGTTCCTGCTGTACCAGTACTTAGTTTGTTTATTTATAAGAACAAAAC
->DS981450.1/8754-8822 Bacteroides coprocola DSM 17136 Scfld_02_23 genomic scaffold, whole genome shotgun sequence. 
-ATGCAGACGCTTAAAACACTTGGATGTATGTGAATATGTGTAAGTGTTACCTGTTCCAGAAGTGGAAAA
->AJXZ01000015.1/19268-19422 Nitratireductor aquibiodomus RA22 Contig15, whole genome shotgun sequence. 
-ATAACAAGAGGGTGAAGCTGAAAATTCATCCTCACCACGCGGTCAAAGTCTTGGGAGGATGCGGTCCAGGCGCGGTTACACGCAGCCGCCGACGATGATACGGTAAAGGATCGGACGCGTTGAGTTAGCAAGGCCTCTTGGCCTTGCATTTTTTT
->KQ034000.1/288106-288014 Lactobacillus apis strain Hma11 genomic scaffold Hma11_scaffold2, whole genome shotgun sequence. 
-GGTCAAACATAAGACATGCGAGATTGTAAATAACTTTTGAATCGGAATACTATTATTTAGTTAATAGGATCCATATTCATTGCGATACGTCTC
->GG729934.1/356366-356523 Oribacterium sp. oral taxon 078 str. F0262 genomic scaffold Scfld1, whole genome shotgun sequence. 
-AAATTCCAGTGTCATAAGGAGCTGTCCCCCCATCGTGCTTGCACGAAGGGGGGACAGCTCCTTATGACACGCCCCCTTATGAGCATGCAGCGGAGGTTTTTCCCGCGGAATGCGAATAAGGGACAGCATGGCGAGCTCAGCGATGCCATGCGGAATTT
->ALXA01000123.1/6897-6525 Pseudomonas putida S11 PPS11_c212, whole genome shotgun sequence. 
-CCACCCAATGCGCCACCTATACCTGCTCCGGTATTGCCGCCTGCCGACGCAACGCCGCTCAGCAGGCCAAGTGACAACAACAGAATCGAGGAGTACTTCATTTGTAAAAAGCCTCAAAGGGATACGGAGGCGATCCTGAGGCTCTGGACAGGGCCTTACAATGGAAATCCGACGAGTGACACGACTTGGAAAAATTCTCCAAGTTATTGTTTTCCCGATGGAAACTTAAGGGATTTTCAACGGTCACAGGCTGATTGCAAAAAGCCTTTCCAGTGGTGGAGAAGCCTTTTATTTCTACCCGTCACCCCGTGCCTTCCCCTCCAAACTCACTACCCTTCTGCCCCAGACCTTGCTTGCCCCAAACCGCTGGATC
->AFSB01219390.1/2517-2353 Heterocephalus glaber contig219390, whole genome shotgun sequence. 
-ATTCCTTCTTGGCCTTTTGGCTAAGATCAAGTGTAATATTCTAGTTCCTAAAGTAACTATATGCTTATAAAAAAATCTTGCCTTTTGGGGGTCTTAAGAGAGTCTAATGATCTTGTGCAGTGTAAAAAATGCATTATGACTTCCTTGTTATGTTTTGCATTCTCT
->FR892523.1/19058-19295 Prevotella sp. CAG:592 genomic scaffold, scf208 
-GCAAAGTATATCGCAAGCGGTTTGCCCTCACGGGTGATTAAAAGGGAATCGGGTGGAAATCCCGGACAGTCCCGCTGCTGTGAGCCGCCCCTTATGAAAGGGTCGAACAATAGCCACTGGAAATTCTTATAGCTCCAATCTGTTATTATGAAATGTCTAACGATTGTTGGAGGTTAACGGGAAGGCGTTCGATACCGGGCGGCAAGTCAGAAGACCTGCCATTGCGACACATGGCGTA
->KB202646.1/8509-7967 Lottia gigantea unplaced genomic scaffold LOTGIsca_5069, whole genome shotgun sequence. 
-NNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNTCGCGGTCCTGCCTCGTTTTTCTCCTTCCGGGAGAGAACCCGCCGCATTTTCTGTCTACCTTGAAAAAATTAGAGTGCTAAAGGCAGGCTAAAACCCCGAGCCTGAATATTTCGTGCATGGAATAAGCGGGGATGCTCTTTTCCGGAGGGCGGTCCGACCGACTGGCGACGTCGCTTTCGCTGTCGGTTTCGCCGGAGAGCTAGGATTCGAGAGGAACGGTGGGGGGCGAGCGTACCGGGCGGGGAGAGGTGAAATTTTGTGATCCGCTCGGGACGACTCGAAGCGAAAGCGCTGGCCCCGGACGTCTTCCTTAATCCAGAACGAAGGTGGGTGGAGCAAAGACGATCAGATACCGTCGTAGTACCGACGGTAAACGCTGCCGACCGGGCCGCGGACGAGGCTCGAGAACAGCGGTTATGGACCCGTCCGTGGCGGCTTCGGGCAACCTGAGAGTTTACGGGT
->AZGB01000027.1/63184-62919 Lactobacillus ghanensis DSM 18630 NODE_73, whole genome shotgun sequence. 
-TAAAAAACAGCAAGAAGAGTAAATGGAAAAATTGTTTTAAGCGAGTCGTTGGTTGATGAAAAACGATAACAATTGACTGTTGAAGATGGTCTTGTTGAGAAGTTCTATTGCTGAGTTGTGCTGAATAATAAGGCAATAGCGGGAACTCCCGTTAGCGAGTCGAAGTATCTTCTGGAGATAAATAAGAATGTACTTTTGAAGGAATAGTTTGTGAGAACTATTTAAATTAAGGTGGTAACGCGAAAAGCAGTCTTTTCGTCCTTAGC
->CM001425.1/10442330-10442236 Lepisosteus oculatus linkage group LG22, whole genome shotgun sequence. 
-CCCAGCAGCCATGTCGCTCTGCCACTCAGCGGGTGTGAGCCTGGGCAGTACCTGGATGGGAGACCTCCTGGGAAAAACTGAGGTTGCTGCTGGAA
->AP013066.1/2828303-2828212 Sulfuricella denitrificans skB26 DNA, complete genome. 
-AGAACCCATGCGGGAGAGCGTGCGATTATTTTCGCACCACCGAAGGCGCAACCACCCGTAACCGCTCAGGTATCAGGAACCGCATGGAACAC
->CM000251.2/46867717-46868010 Rattus norvegicus chromosome X, whole genome shotgun sequence. 
-GAGTTTTCTGGCTTGGATATCTGACATCCCATTGATTGCCACAGTTGATTTAGCTGATCTTGCTGGTCGGCAGGTGTCCCCTTCCTCCTTCACTGCTTCATGTGCATTCCTCCTGATGCTGCGCACTCCGTTGAAGATGATGAACCTTCCCTGAAGGGAGAAGGTCCAGTCTTTGGGCAAAGATATTCGAGTAGTTGTGTTCCCCAGATAGAACCTCCAAACAAACTTTCAAGGAAGAAAATTTTAGTTTGGTTTCTGGTTCCAGATGGTGGGCATGCTGGCATGACAGCAAAC
->FNHO01000002.1/3411-3594 Pseudomonas balearica DSM 6083 genome assembly, contig: Ga0056079_102 
-CAGCTAACGGAAAAGTATTCCAATTCGGTTTAACGGCCCGGCAGATCCGGTCGGCAGAATCCGAAAAACGGACTAATACTTGAAATCACTGGCGAGACATTCCCCCCACTGTCTGGCCAGTCGAGACCGTGAGGACCGCGTTCTCGAAACTCCTAATGGTCTTGACCCGGCTCCCTCAGGCCGG
->JH836242.1/293875-293781 Erinaceus europaeus unplaced genomic scaffold scaffold00954, whole genome shotgun sequence 
-CTCCGGCGCAGGGCGGCCACTGCCCCCCGCACACTGCGCTGCTCCGACCCACTGTGCGTGTGACAGCGGCTGTCCTGTCCTGGCAGCGCGACCGG
->CH672395.1/1696787-1697001 Leeuwenhoekiella blandensis MED217 scf_1099517004314 genomic scaffold, whole genome shotgun sequence. 
-ACTTCGCAAACGTATTTTGGTGGTGTTTTTTGTTTTTAAAAACACCTTAAAAGGGAATCAGGTGCTTCTTTGTAAAAATCCTGAGCTGTTCCCGCAACTGTAAGCTTAGTTCGTAAAAGAACGGTAAAGATCGTCTTACACCACTGTCAATATTGATGGGAAGGTTTGATCTTTATACGCGAGCCAGGAGACCTGCCAGAAGAAACTAATAACTA
->AZAQ01029315.1/12443-12290 Stegodyphus mimosarum contig29315, whole genome shotgun sequence. 
-ATACTTACCTGGCACTGGGAACGCCTTGATGAACAAAGAGGCTTCCCGAGCAGAGGGCTCCCGTTGCACAGCGAGAGGTTGACGTTCGCTACACTCGCCGTAAATTGGGCAATTATTTCCTAGCGTACATGGAGTAGCATCAGATGCCAATGGA
->ALWZ045079265.1/261-1397 Picea glauca, whole genome shotgun sequence. 
-AAGATTTTGTGCGTTTCTCTCTCTACGTTCCGGATTTCGTAGTGACGGATTTATGAGTAGATTCGATCGAAGAAGTTACAAATTGTATGATGGAAAAACCAAAGTGAACCCTAGGTACACCTCATTTCGGTGGTCCCGAAATCAATAGGGTAGTCCCGGGTTATCACTGATAATTTCGAGATGAATTCTCCGTAATTGTGTGTTCATCGGAAATAGCTGGTTTTCCGCGAAATCCATTTAAGTGGAGCGTCTAATGTTCAGGCCCGAGGTAGAGCACTCAATGGGCTAGGGTGGCCAAAAGCTTTACCAATCCCAACGAAACTCCGAATACAGGTCTCTGCAGTTAGTACAGACAGACTTTGGGTGCAAAGATCCAAGGTCGAGAGGGAAACAGCCCAGATCGTGCGCTAAGGTCCCAATGCAATTACTTAGTGTCAAAGGTAGTGATCGCGCGATGACAACCAGGAGGTAGGCTTGGAAGCAGCCAGCCTTTGAAGAAAGCGTAATAGCTCACTGGTCCAGCTCCGTAGCACCTAAAATGTATCGGGGCTAAAGTAATTCACCGAAGCGACGAGACTAGTCTCCGAGATTGATAGCTCGGGAAAGTGAGAACCTTGAAAGCACACAAGTAGCTCACGTAGTCTATATGGTCCAGATAGTGTCTAACTAAGCTTATTCAAGGGTCAGTAGCGGAACGTTCCGTATATCGGAGAAGGGGCTACACCTGGAGGKATCAGAAGTGAGAATGCTGACATGAGTAACGATTAATCGTGTGAAAAACACGATCAGTTCACGGGTTTTCACGTTCAGTCAATCTACGTGGAGTGAATCGGTCCCTATAGTGGGAGATGTAAGCACGAGTTACTCCGGCAGCTGTTTTATGGCCCCCGCTGATAGACTAGGGGCTAACCTGATCTTTCTACTGTTGCCACCTATACGCAATTGTTTATTAAAAACACAGGACTCTGCTAAGTGGAAACACAATGTATAGAGTCTTACATCTGCCCAGTACTGGACATCGTATTATGGGTTTCTGTCACTTTTCCCTAGGGAATAAAACTAGATAGGTCAGTTATTATAAGTAAATTCTTGGAGATTTCCTGATTCCGAAAGCTGCCGGTGCACTTGGCCACCTTC
->GL945483.1/1284982-1284843 Serpula lacrymans var. lacrymans S7.3 unplaced genomic scaffold SERLA73scaffold_10, whole genome shotgun sequence. 
-GGCCGACTAGCTCAGTTGGTTAGAGCGTCGTGCTAATAACCTAGGCACAATGGATCAGACCACCATGCATTTGCATGGTGGTCTGATCGCTGGCCTTGTGTCATACGCGAAGGTCTTGGGTTCGATCCCCACGTTGGCCA
->URS0000D6AED6_12908/1-65 unclassified sequences c-di-GMP-II-GAG riboswitch 
-CGGGAAGCUCUGACACGCGGUCCCGGCCGCCGGGACCGCGCCGAGCCACUGGCGAGACCGACCCG
->ALWT01224760.1/3828-4038 Myotis davidii contig224760, whole genome shotgun sequence. 
-ATCGCTTCTCTGCCTTTTGGCTAAGATCAAGTGTAGTACAAGTTCTGGTACATAGTAGGGTTCTGCAAGATAGCAGTGGCCATTACTATTATTATGATTAATCATGACCATTGCTATTAAGTTTTCATTGCAAAGTAATGGTATTAGGTGATGAGGAAAGGTGTGTATCTGGTGTGGGAAATGGGTGGGACTTACATTTATTATATGCCTA
->KV453843.1/252671-252748 Tortispora caseinolytica NRRL Y-17796 unplaced genomic scaffold CANCAscaffold_3, whole genome shotgun sequence. 
-GACAGTGATGAAAAAAATTACTCACAGACCTGTACTGAACATTTCATGTGGATAAAGCAATATTGCCTTTTTCTGAGT
->ABCM01000001.1/368790-368897 Pedobacter sp. BAL39 1103467000516, whole genome shotgun sequence. 
-TACTTATAAAGAAAGACTGAGGGAAAGGCCCTGTAACGTCTTAGCAACCTGTACTAGCCGGAAGTAAAAGGTGCTAATTCCTACTCTGTAGAAAGAGAAAGATAAGTT
->CP002512.1/771378-771640 Aerococcus urinae ACS-120-V-Col10a, complete genome. 
-ACACACCCATTGATAGGGAGAGTAAGTGTTAAACACTTTGAAGAGAGGTTCCGTTTGGTGAGAGGAACCAAGTGAAAGGCGCTGAAGATGGCCTTTGAGGGTATCTTGTCAATAAGTAGACAAGGTCGGCTGGGCTCGGTCGATAGAAAGAGCGCTAGTCTAGGCATTATCGCCTATGGCTAGGTCGAGGGAGTAGCTACTACTATACTTATTAACAGTAGTACTCTGAACAAAAGGTGGTAACACGATGCGTCGTCCTTTAC
->CP017623.1/2830701-2830798 Candida albicans SC5314 chromosome 1 sequence. 
-TTGGCTATGATTATTTGCATTATATTACCAATTGTTCCAACTGAATATCCCGGGTTGACAACCGCATTATCGTTAAGTTTCAGCCTTGTCTGAGCCTT
->ALWZ041464526.1/1-432 Picea glauca, whole genome shotgun sequence. 
-ATAACCGTAGTAATTCTAGAGCTAATACCTGCACCAAGTCCTGAATATTTGGAAGGGATGCATTTATTAGATAAAAGGCCGGTGTGGGCTTGCCTGCTTCTCCAGTGAATCATGATAACTCGACGGATCGCACAGCCATTGTGCTGGCGATGCTTCATTCAAATTTCTTCCCTATCAACTTTAGATGGTAGGATAGAGGCCTACCATGGTGGTGACGGGTGATGGAGAATTAGGGTTCGATTCCGGAGAGGGAGCCTGAGAAATGGATACCACATCCAAGGAAGGCAGCAGGCGTGCAAATTACCCAATCCTGACATGGGGAGGTAGTGACAATAAATAACAATACTAGGCTCATCGAGTCTGGTAATTGGAATGAGTACAATCTAAATCCCTTAACGAGGATCCATTGGAGGGTTCACTGTCCCCTCCTCT
->ABDH01025731.1/1497-1292 Termite gut metagenome tgut2b_Contig26382, whole genome shotgun sequence. 
-TCCATCGTGAGGTGGAATCTGAAGGAAGCCGGAGGCAAAGTCCCGGGCCGACGAACAGAAACCGCATATAAGGCAATGCAAGGCGGACGAGTTTGCATAACAAAACGAAGTCCAAAAAGGCCGGGGAGGAAGAAAACAGACTCCGGTTTTACTGCCCGAACCTTGCAGTGTAGATGCGGCGGCTATATGGGATGAAGGTTATCAGC
->AFFK01018367.1/6133-5846 Strigamia maritima strain Brora ctg7180001228879, whole genome shotgun sequence. 
-AGGCGTGTGTCTGAGACACATCTGAACATTGATCGCTGTTATTAGGCAGATCTGCTCAGAGGTAGTGTCCCTTAACCACACAAGACCATATTGAGTCGGTATTCCCGCTGCCACAGTACGCACGGTACGAGTACCTTCTCACACAGTTGCGCCCCAAGCGCATATCAGGGTATAAATCTGGCCGTTCTCCTAGCTTAGCTGTTTCAAAATTGGGGAAGTTTGCTAGCATCTTCCATGATTTAAGACGCCACCAATAAAGGCGCTGAGTGTGTCAGCCTGCCTTTTAAT
->CCCW010037878.1/9850-6604 Brassica napus, WGS project CCCW01000000 data, contig: 6310 
-TCTTTTCAAGTTTCATGTGATCAAAACTCAACATTCCTCCAAATACGTATTCTCCCAAAAGCTTGGTTTCAGATTCTGACTTTTACACTCTTGACAATTTTATTCCGAAGGGCGGGGTAATACAGACTGGGCCCTAGTTCCCTGGAAAGGGCGCCATTGAGGGTTAGAGCCCCGTCGTGCCTGGACCCTGTCGCACCACGAGGAGCTGTCGACGAGTCCAAGTCTGCCGATCGGGCGGTAAATTCCGTCCAAGGCTAAATATGGGCGAGAGACCGATAGCGAACAAGTACCGCGAGGTAAAGATGAAAAGGACTTTGAAAAGAGAGTCAAAGAGTGCTTGAAATTGTCGGGAGGGAAGCGGATGGGGGCCGGCGATGCGTCCCGGTCAGATGCGGAATGGAGCAATCCGGTCTGCCGATCGATTCGGGGCATGGACCTACGCAGATTAAGGTGGTGACCTAAGCCCGAGCCTTTTTTACGCCCGCGGAGACGTCGTTGCCTTAATTGTGGTCTGCAGCACGTGCCTCACAGCGTGCCTCGGCATCTGCATGCTCAGGGCGTCGGCCTGTGGGCTCCCCATTCGACCCGTCTTGAAACACGGACCAAGGAGTCTGACATGTGTGCGAGTCAACGGGTGAGTAAACCCATAAGGCGCAAGGAAGCTGATTGGCTGGATCCCTCACGGGTGCACAGCCAACCGACCTTGATCTTCTGAGAAGGGTTCGAGTGTGACCATGCCTGTCGGGACCCGAAACGTAGTGAACTATGCCTGAGCGGGGCGAAGCCAGAGGAAACTCTGGTGGAGGCCCGCAGCGATACTGACGTGCAAATCGTTCGTCTGACTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGAGCTCGGAAACGAGTTCTATCGGGTAAAGCCAATGATTAGAGCCATCGGGGATGCAACATCCTCGACCTATTCTCAAACTTTAAATAGGTAGAGCCATCGGGGACGCAACATCCTCGACCTATTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGGAAGCCGGTTACGGTGCCCAACTGCGCGCTAACCTAGAACCCACAAAGGGTGTTGGTCGATTAAGACAGCAGGACGGTGGTCATGGAAGTCGAAATCCCTAAGGAGTGTGTAACAACTCACCTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTGAAGCGTGCAACCTTTACCCGGCCGCCAGGCCTCGATGAGTAGGAGGGCGCGGCGGTCGCTGCAAAACCTAGGGCACAAGACAAGGCAGAGCGGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTGAAGGCCGAAGAGGGGAAAGGTTCCATGTGAACGGCACTTGCACATGGGTTAGTCGATCCTAAGAGTCGGGGGAAACCCGTCTGATAGCGCTTATGCGCGAACTTCGAAAGGGGATCCGATTACAATTCCGGAACCGGGACGTGGTGGTTGACGGCAACGTTAGGGAGTCCGGAGACGTCGGCGGGAATTCCGGAAAGAGTTATCTTTTCTGTTTAACAGCCTGCCCACCCTGGAAACGGCTCAGCCGGAGGTAGGGTCCAGCGGCTGGAAGAGCACCGCACGTCGCGTGGTGTCCGGTGCATTCCCGGCGGCCCTTGAAAATCCGGAGGACCGAGTGCCGCTCACGCCCGGTCGTACTCATAACCGCATCAGGTCTCCAAGGTGAACAGCCTCTGGTCGATGGAACAATGTAGGCAAGGGAAGTCGGCAAAATGGATCCGTAACTTCGGGAAAAGGATTGGCTCTGAGGGCTGGGCTCGGGGGTCCCAGTTCCGAACCCGTCGACTGTTGGCGGGCTGCTTGAGCCGCTAACGTGGCGAGAGTGGACCTCCTCGTGTCAACCGGGGGACGGACTGGGAATGGCTCTTTCGGGAGCTTTCCCCGGGCGTCGAACAGCCAACTCAGAACTGGTACAGACAAGGGGAATCTGACTGTTTAATTAAAACAAAGCATTGCGATGGTCCCTGCGGATGCTAACACAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGGTAAACGGCGGGCGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTACCACAGCCAAGGGAACGGGGTTGGTAGAATCAGCGGGGAAAGAAGACCCAACTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTGAGAGGTGTAGAATAAGTGGGAGCTCCGGCGCAAGTGAAATACCACTACTTTTAACGTTATTTTACTTACTCCGTGAATCGGAGGCGGGGTAACAACCCCTTCTTTTAGACCCAAGACTCGCTTCGGCGGGTCGATCCGGGTGGAGGACATTGTCAGGTGGGGAGTTTTGCTGGGGCGGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGCTCAACGAGAACAGAAATCTCGTGTGGAACAAAAGGGTAAAAGCTCGTTTGATTCTGATTTTCAGTATGAATACGAACCGTGAAAGCGTGGCCTATCGATCCTTTAGACCTTCGGAATTTGAAGCTAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCACTGTGAGACAGAATTCAACAAGTGTTGGATTGTTCACCCACCAATTGGGAACATGAGCTGGGTTTAAACCGTCGTAAGACAGGTTAGTTTTACCATATTGATGCCCATCTCGCAATAGTAATTCAACCTTGTACGATAGGAACCGTTGATTTGCACAATTTGTCCTCGCGCTTGGTTGAAAAGCCAGTGGCGCAAAGCTGCCACTAAGTCAGAATCCGGGCTAGAAGCGACGCATGCGCCCGCCGCCCGATTGCCGACCCTCAGTAGGAGCTTCGGCTCCCAAAGGCACGTGTCGTTGGCTAAGTCCGTTCGGCTGAAGCGCCGTTCGGACCGCCTTAATTTATAATTACCACCGAGCGGCGGGTAGAATCCTTTGCAAACGACTTAAATACACGACGGTGTATTGTAAGTGGCAGAGTGGCTGATGTGCCCCAGTCCATGGACCAGACCGATCAGAACGTTCTAGACGTCCCA
->ACJG01006097.1/11398-11489 Daphnia pulex DAPPUscaffold_154_Cont6097, whole genome shotgun sequence. 
-GCCTGGCTAGCTCAGTCGGTAGAGCATGAGACTCTTAATCTCTCGCATGAGAATCTTAATCAGGGTCGGGGGTTCGAGCCCCCCGTTTGGCG
->CM000231.2/255777208-255777080 Rattus norvegicus chromosome 1, whole genome shotgun sequence. 
-CAGCCTATTTCCAAGGATAGAGCTGGGTGTGGCTATGGGATCTCCAACTGCAGGCCAGAGTAATTGGAGAGACTTTAACAGCAGAGGTCAACACAGTGCCTGCGGCTGCCACTTGCTTTTCCTGTATGT
->CYZX01000011.1/96755-96903 Clostridium disporicum strain 2789STDY5834856 genome assembly, contig: SCcontig000011 
-AACTAAATCAAAGATTTAGGATCTCACTTAAGTTGACGAGGATGGGGAGTATCGAATTCTTCGGCGGGTGCCCCACGGTATCGCACTACCGTTAACAGTTAGTAAATCTATGAAGTGATTTGTAGGACAACACTAACTTGGTGTTAAAA
->KN838613.1/75725-74394 Laccaria amethystina LaAM-08-1 unplaced genomic scaffold K443scaffold_78, whole genome shotgun sequence. 
-TACCTAACAGAATTTACAGGTATTCAAGTAGCGTTGATTCAGTCAGATGGTTGGGGTTTGGTATGTCGGCTGGACCGATTCACCATGGTCGTGGCTTTGTATGTCAGCTGGGCTGATCATCACACATGCATACTAGGTCTTATTAGGAGTTATATGTGGTATACTACATTCCAAATGACCGGAAACTGGCCTGGGTGAATAACTTTTCTACCTGGCATAAGTCTGGCGCGGCCTCTGGAAGGGCCTGAATTCCCCTGGTAACAGACGGAAATGTCTGAATTCAGAGGGGACACCTCATGTAGCCAGGTACGAAATCTTGGTGTCTGTCGTACCTGATTCATCTTGTACCAGGTAAGCCAGACACGTGCACATTTCCTGATGCTCTTGGTGAGCCGGCGTGCCCTTTATTGGTGTGTGTTGGGGAACCAGGACTTTTACCTTGAGAAAATTAGAGTGTTCAAAGCAGGCATTTGCCCGAATACATTAGCATGGAATAATAAAATAGGACGTGTGGTTCTATTTTGTTGGTTTCTAGAGTCGCCGTAATGATTAATAGGGATAGTTGGGGGCATTGGTATTGAGTCGCTAGAGGTGAAATTCTTGGATTGACTCAAGACCGACTATTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACAAAGGTTAGGGGATCGAAAATGATCAGATACCGTTGTAGTCTTAACAGTAAACTATGCCGACTAGGGATCGGGCGACCTCAATTATGATGTGTCGCTCGGCACCTTACGAGAAATCAAAGTCTTTGGGTTCTGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGATGGAAGGGCACCACCAGGTGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTCACCAGGTCCAGACATAACTAGGATTGACAGATTGATAGCTCTTTCATGATTTTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGATAACGAACGAGACCTTAACCTGCTAAATAGCCAGGCCGGCTTTCGCTGGTCGCCGGCTTCTTAGAGGGACTGTCAGCGTCTAGCTGACGGAAGTTTGAGGCAATAACAGGTCTGTGATGCCCTTAGATGTTCTGGGCCGCACGCGCGCTACACTGACAGAGCCAGCGAGTTTTTTTTCCTTGGCCGGAAGGTCTGGGTAATCTTGTGAAACTCTGTCGTGCTGGGGATAGAGCATTGCAATTATTGCTCTTCAACGAGGAATACCTAGTAAGCGTGAGTCATCAGCTCGCGTTGATTACGTCCCTGCCCCAACCGACCACTC
->AFEW01015811.1/2627-2450 Jatropha curcas cultivar GZQX0401 scaffold191_29, whole genome shotgun sequence. 
-TGTCATGTTTTTCCACAGCTTTCTTGAACTTCTTTTTTCTTTTCTTTAATTTTTTCTTTCAAGAATCTCCCTCATTTTAATATGTATGAAAGAGATTCTTAAATGGAAGAATTAAAGAGGAGGAAATGTATACGTGTATTGTATAGGAGTTCAAGAAAGCTGTGGGAGAACATGGCAG
->JH226135.1/756984-757073 Exophiala dermatitidis NIH/UT8656 unplaced genomic scaffold supercont1.6, whole genome shotgun sequence. 
-GCTCTCTTAGCTCAGTGGTAGCAGCGCCACACTAGTAGTTCCTAACATTACGAGATGTGGAGGTCACAGGTTCAAGTCCTGTAGGGAGCA
->AZGY01000051.1/130-3252 Aschersonia aleyrodis RCEF 2490 scaffold_51, whole genome shotgun sequence. 
-TACCTGGTTGATTCTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCCATGCATGTCTGAGTATAAGCAATTATACAGCGAAACTGCGAATGGCTCATTATATAAGTTATCGTTTATTTGATAGTACCTTGCTACTTGGATAACCGTGGTAATTCTAGAGCTAATACATGCTAAAAATCCCGACTCCGGAAGGGATGTATTTATTAGATTAAAAGCCAATGCCCTCTGGGCTCTCTGGTGATTCATGATAACTTCTCGAATCGCACGGCCTTGCGCCGGCGATGGTTCATTCAAATTTCTTCCCTATCAACTTTCGATGTTTGGGTAGTGGCCAAACATGGTTGCAACGGGTAACGGAGGGTTAGGGCTCGACCCCGGAGAAGGAGCCTGAGAAACGGCTACTACATCCAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCCGACTCGGGGAGGTAGTGACAATAAATACTGATACAGGGCCCTTTCGGGTCTTGTAATTGGAATGAGTACAATTTAAATCCCTTAACGAGGAACAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGTGGTTAAAAAGCTCGTAGTTGAACCTTGGGCCTGGCGGGCTGGTCCGCCTCACCGCGTGCACTAGTCCCGCCGGGCCTTTCCCTCTGCGGAGCCCCATGCCCTTCACTGGGCGTGGCGGGGAAGCAGGACGTTTACTTTGAAAAAATTAGAGTGCTCCAGGCAGGCGTATGCTCGAATACATTAGCATGGAATAATGAAATAGGACGCGCGGTTCTATTTTGTTGGTTTCTGGGACCGCCGTAATGATTAATAGGGACAGTCGGGGGCATCAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACAACTGCGAAAGCATCTGCCAAGGATGTTTTCATTAATCAGGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGACGATGTTATTCATTGACTCGTTCGGCACCTTACGAGAAATCAAAGTGCGTGGGCTCCAGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGAAATTGACGGAAGGGCACCACCAGGGGTAAACGTGCACTGTCTAAGCCGCAGTCAACTCTGCTCCAGAAAGCCGCCCGAAAGGGTCGGTGGTCGCCCCCCAACGCTGGCTAGTCCCGTCCGCCACCGCGCGGCGGGGCAACACCCTCAAACTGCCGGGGAACTCCTAAAGCCCTCGCTCCGGACGGCGCTGGGAAACCAGCGTCCGCTCACCAGGTTAACGACCTCGGGCATCGGAAGCAACGCGGGGGATGCTACAATGGACGATCCGCAGCCAAGCCCCTACGTGCGACAGCATACGGGGAAGGTTCAGAGACTTGACGGGGGTGGGTCGGGGACGCATGTCGGGACGCCTGAAGGCGCTGGAACACCGGCACGAGGGCGCTGGAGTCTCGCCCGCGAGGGGCTGGCACCTCCGCCTGAAGAGCGCTGGGATCCCGGCGACCGAGACGCCCGCATCGCCCACCGGCTTGAGGTAAAGTCCGCTGTCGCGCCAAAAGCGCGCCCCATGCGATGGATCATCGCTCGGCAACCACAACGGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTCACCAGGTTAACACAGCGGGCAACGCTTGTTGCGTGTCTGGGCCTGGAATAGTGAGAGCCCGCCAGGGGGCGGCCTCGCTAGTATTCGTCCTTAACCCGCGCGGGGGGAGCCCCCCTACTCTGGGCGCAGGGAGCGGTCGCGCTACGGCGCGCCGCTTGGGCGGTGCAACACCAGCTGGTACAGGGAACGCCGACTACCCCTCGGGGGGCAAGGGCCGATCCTGTGGCGAGTCCGGGCTGCGCCGGACCGTCGCAACGCACGCCAAGCGGTGGGCTGGCTCAGGCTGGCTTAAGGTACGTGCTAATCCCACGGGGCAACCGTGGCCGCCCTGAATAGTTCCGAGTTTTACGAAGCAGGGCGGGGGCGCACCTCCGGGTGCGCTCGTCCGAGTCCACAGCGGGCTCGAGTGCCAGACACAATGAGGATTGACAGATTGAGAGCTCTTTCTTGATTTTGTGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGCTTAATTGCGATAACGAACGAGACCTTAACCTGCTAAATAGCCCGTATTGCTCAGGCAGTACGCCGGCTTCTTAGAGGGACTATCGGCTCAAGCCGATGGAAGTTTGAGGCAATAACAGGTTGACCTACACAGGCCTGTAGTAGTGGCGCCTCCGGTGGGACAGAGGGAAGAAGACCGCTAGTCCAACAGCATAACCCCCGTGAAGGGAGCCCTTCGGAATCGGGCGGGGGGGCGGCCACTGCCCGTGGCCGCTCGCTGTGGGCGACACCACCTGGTACAGAAGACGCCCACGGGGCCAATTCTGTGGCGAGTCCGGGTTGCGCCGGACCGTCGCAACGCGCGCTAAGGGGTGGGCCGGCGTCCTCTGCGGAGGCCCGGCTTAAGGTACGTGCTAATCCCACGGGAAGGAGAAACCGTGCCGACACACAGAGCCCCGATCGGCGAAGTGTGCCGGGGCGTCCCTGCGCAGCGTCGCAGGGCGCCGGTCTCGGGGGCACACAGGCTGCTTCAGCATGTCCTGGCCCCCCGAGGAAATGCTGTGATGCCCTTAGATGTTCTGGGCCGCACGCGCGCTACACTGACGGAGCCAGCGAGTACGCCCTTGGCCGGAAGGCCCGGGTAACCTTGTTAAACTCCGTCGTGCTGGGGATAGAGCATTGCAATTATTGCTCTTCAACGAGGAATCCCTAGTAAGCGCAAGTCATCAGCTTGCGTTGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTACTACCGATTGAATGGCTCAGTGAGGCGTCCGGACTGGCCCAGCGAGGTGGGCAACCACCACGCAGGGCCGGAAAGCTCTCCAAACTCGGTCATTTAGAGGAAGTAAAAGTCGTAACAAGGTCTCCGTTGGTGAACCAGCGGAGGGATCATTA
->CP022437.1/2870568-2870713 Virgibacillus necropolis strain LMG 19488 chromosome, complete genome. 
-GTTACCTTTAATTCAGTCCTGTGAGACTGGCAAGGTGGAACAGATGAAGATCTGTTTTATAAATAAAACTCGGAAAGGTTTCTTCCTTTTGCGAGCCTTTTATTTGTACACTACACCTTGCCAGAATAGGCAAGGTGTTTTTTTGG
->GL385398.1/3795320-3795665 Gaeumannomyces graminis var. tritici R3-111a-1 unplaced genomic scaffold supercont2.4, whole genome shotgun sequence. 
-ACATACGACCATACCCACTGGAATATACGGGATCCCGTCCGCTCTCCCCTANNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNCAAACCAGTGAGGGCCGAACTAGTACTCAGGTGGGTGACCACTGGGGAATCCTCGGTGTTGTATGTT
->AFEY01233609.1/1-1134 Sarcophilus harrisii ctg7180001910850, whole genome shotgun sequence. 
-CCAGCCCCTGCCTCTCGGCGCCCCCTCGATGCTCTTAGCTGAGTGTCCCGCGGGGCCCGAAGCGTTTACTTTGAAAAAATTAGAGTGTTCAAAGCAGGCCCGAGTCGCCTGGATACCCCAGCTAGGAATAATGGAATAGGACCCCGGTTCTATTTTGTTGGTTTTCGGAACTGGGGCCATGATTAAGAGGGACGGCCGGGGGCATTCGTATTGTGCCGCTAGAGGTGAAATTCTTGGACCGGCGCAAGACGGACCAGAGCGAAAGCATTTGCCAAGAATGTTTTCATTAATCAAGAACGAAAGTCGGAGGTTCGAAGACGATCAGATACCGTCGTAGTTCCGACCATAAACGATGCCGACTAGCGATCCGGCGGCGTTATTCCCATGACCCGCCGGGCAGCTTCCGGGAAACCAAAGTCTTTGGGTTCCGGGGGGAGTATGGTTGCAAAGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGAAACCTCACCCGGCCCGGACACGGAAAGGATTGACAGATTGATAGCTCTTTCTCGATTCTGTGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGCGATTTGTCTGGTTAATTCCGATAACGAACGAGACTCTGGCATGCTAACTAGTTACGCGACCCCCGACGTGGTCGGCGTCCCAACTTCTTAGAGGGACAAGTGGCGTTCAGCCACCCGAGATTGAGCAATAACAGGTCTGTGATGCCCTTAGATGTCCGGGGCTGCACGCGCGCTACACTGACTGGCTCAGCGTGTGCCTACCCTACGCCGGCAGGCGCGGGTAACCCGTTGAACCCCATTCGTGATGGGGATCGGGGATTGCAATTATTCCCCATGAACGAGGAATTCCCAGTAAGTGCGGGTCATAAGCTTGCGTTGATTAAGTCCCTGCCCTTTGTACACACCGCCCGTCGCTACTACCGATTGGATGGTTTAGTGAGGTCCTCGGATCGGCCCCGCCGGGGTCGGCCCACGGCCCTGGCGGAGCGCTGAGAAGACGGTCGAACTTGACTATCTAGAGGAAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTA
->MEQV01000070.1/1472-1355 Betaproteobacteria bacterium RIFCSPLOWO2_02_FULL_62_17 rifcsplowo2_02_scaffold_16404, whole genome shotgun sequence. 
-TAGCGGGTTGAAGTCCCGTCCGGGGAGTTGTCCGTACGCCCCGGTAGCTGAGGAAGCGGCGCCGTGGCAACACGGGGTCGTGAGTTTGCAAACAGCAAGAGAGCAGGCCGTAACGCAA
->GG738884.1/92380-92084 Naegleria gruberi genomic scaffold NAEGRscaffold_40, whole genome shotgun sequence. 
-CTGGGCTACTGTAGGGAGGTAGCTGTTATGGTTCTCTGCCACAGCGTCAGGCAAAGGGATGGTTCTTCAGACTCATTCCTTTGTTAGCAATATGGTGACGATGTTCTGTCTGACCAATAGCGGTGTGACCATAGTATCTCCCCATGAATAAGGAGAAACTAGGGTCCTAATGAAAGGTGAACCGGTTGAGGCAGGATAACTGAGCAAATCATAGCCTTCACACTGTAGGATGGTCAGATTGCAGAACTGAGCATGAGCTATCAGAGAGTGAAATCTGGGAGTCAGACTAATGTTTTT
->GL349550.1/1-552 Thecamonas trahens ATCC 50062 unplaced genomic scaffold supercont1.118, whole genome shotgun sequence. 
-TTTTGATTCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGCGTCGGATTGTTCACCCGCAAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACCGATGGAGCGTTATTGGGCAAGTAGAGCAACTCAGTACGAGAGGAACCGTTGTTCGACAGAATTGGTCTTGCGGTTGGTCGAGGGGCCACGCCGCGCAGCTACCCTGTCTAGGATTACGGCTGAACGCCTCTAAGCCGGAAACCATGCTTAGGCAAGCAGTAACGGGAAACTGGATGCAAGTGGCGAGCGGCGCAGAAGCGCAGAGTAGGGCAGTGCAAGCTGTCGGCAACGCGGGGGGGAGACTCGGTCCTTGCCTTTTTCATGAAGCTGTGGGGCAAGGGCTGGTCTTTGAGATGTGGAGTACGCGGTAGTCACTTGCGTGGATCCTCTGTAGATGACTTTGTTCGCATGGGGAGTTGTAGGAAGCTGAGTGGCCGAGTTTGCCACGAACTTTTGAGACCTTGCCCTATCTTTTTAGAGT
->MJEQ01002762.1/109736-109880 Nicotiana attenuata strain UT scaffold02762, whole genome shotgun sequence. 
-AAAATAAGTGCCTCTTAGAAAGCCTCGGATGATGCCTACAATACCATTTTGTAGGATCATAAGCCTTTTAATTTGAAGTTTAAAACCCTACATAAATTAAGGTTTTAGGCAAGTCATCCTTGGCTATCAAAGCAAGCTCTTTATT
->FAOM01049750.1/126257-125942 Triticum aestivum genome assembly, contig: Triticum_aestivum_CS42_TGACv1_scaffold_049750_1BS 
-TTTTTTTTAAATGTGCCATGTCATGCACATGTATTTTGTAAAAAAGAATGTCAGCATTAAAAATGCAATGTGTGTGATGCCTTGAACGTGATTATAAAAACACTATTGTTACTGACATGTGGTGACGGGTGACGGAGAATTAGGGTTCGATTCCAGAGAGGGAGCCTGAGAAACGGCTACCACATCCAAAAAAGGCAGCAGGCGCGCAAATTACCCAATCCTGACACGGGAAGGTAGTGACAATAAATAACAATACCGGGCGCATTAGTGTCTGGTAATTGGAATGAGTATAATCTAAATCCCTACATCATCATAA
->AFYH01012672.1/16268-15971 Latimeria chalumnae contig012672, whole genome shotgun sequence. 
-ACTCAATCTGTTATCATTTTTTCACTTACTTGGTGAGCCAAGTCCCAAGGGGCTCTCAATTCTGGTAACAAGTGCCTGGCTCAGCAGGGTGCGGCCCACTCCAGGGACAGTAGCAGGCGGAGAGTTTCACCAGGGCAGTACATCTGTCAAACAATAACACAGGTGTCCTAAAGCAAGTTCAGGGAGGACAGAAACCTCCCGTGGAGTAGAGGGTTTTGCCTCTGAGTCGGAGGGTTGCAGGTTCAAATCCACCTGGGGACCTTGGGATCTGTCAACTCCCCAGTATGGTATCTGGGGG
->KB846873.1/2237147-2237221 Nelumbo nucifera unplaced genomic scaffold scaffold00090, whole genome shotgun sequence 
-GTCTTACACTTGATCTCTAAGGTAAGTTCATGTGTTGACAAGTACATAGAATAGAAAAAGCTCTGAAAGGTTGCT
->LKHD01000187.1/27860-29827 Candidate division Hyd24-12 bacterium Vib_1 contig65, whole genome shotgun sequence. 
-AATGAAGCTACCAAGGGCATACGGTGGATGCCTTGGCACAGGCAGGCGATGAAGGACGTGGTAAGCTGCGATAAGCTCCGGTGAGGTGCAAGCAACCTTTGACCCGGAGATCTCCGAATGGGAAAACCCACCTGGAATAAAAGACCAGGTATCTCCTTACTGAACACATAGGTTTGGAGAGGCTAACCCGGGGAACTGAAACATCTTAGTACCCGGAGGAAGAGAAAGCGAAAGCGATTCCCTGAGTAGAGGCGATCGAAACGGGAAGAGTCTAAACCGAGCGGTGCGTGATAGCTGCGCAAGCGTTGCACCGCCGGGGTAGAGGGAAGTGTCCGGAGGATGCGTCACCTCGGATCGAAAAGCATGCTAGCAGAAGCTTCTGGAAAGTTGCTCCAAAGAGGGTGAAAGGCCCGTACGCGAAAGCATGCTCTGGATCTGGGACACTCTCCCAAGTAGCACGGGGCACGTGAAATCCTGTGTGAATCCGGGCGGACCACCGCCTAAGACTAAACACTCGCCTGTGACCGATAGTGAACTAGTACCGTGAGGGAAAGGTGAAAAGCACCCCTGGCGGGGAGTGAAATAGTACCTGAAACCGTGTGCCTACAAGCAGTCGGAGCAGACTTGTTCTGTGACGGCGTGCCTTTTGCATAATGAGCCGGGGAGTTGCTCGTACGTAGCGAGGTTAAGGCCGGGAGGCCGGAGCCGCAGGGAAACCGAGTCTGAACAGGGCGATTCAGTTGCGTACGGCAGACCCGAAGCCAGGTGATCTATCCATGGCCAGGCTGAAACTTGGGTAAAACCAAGCGGAGGGCCGAACCCACTAACGTTGAAAAGTTAGGGGATGAGCTGTGGATAGGGGTGAAAGGCCAAACAAACCTGGAGATAGCTGGTTCTCCTCGAAATAGCTCTAGGGCTAGCGTCGATGCAGTGTTCCGGAGGTAGAGCACTGGATGGGTTAAGGGGCCTACAAGCTTACTGACCCCAACCAAACTCCGAATGCCGGAACATGGTCTACGGCAGTCAGGCCGCGGGGGCTAAGCTCCACGGCCGAGAGGGAAACAACCCAGACCGCCGGCTAAGGTCCCCAAGCATACGTTAAGTGTATCTAAGGAAGTGGAGTTGCTTAGACAACTGGGATGTTGGCTTAGAAGCAGCCATTCATTTAAAGAGTGCGTAACAGCTCACCAGTCAATGCGATTCTGCGCCGATAATAATCGGGGCTCAAACGTATCACCGAAGCCGCGGACTGTCGCCTTGAGCGACAGTGGTAGAGGAGCGTTCCGTATGCGCTGAAGGTGTCCTGTGAGGGATGCTGGAGTGTACGGAAGTGATCATCCCGGCATGAGTAGCGATAATGCAGGTGAGAAACCTGCACACCGAAAGCCTAAGGTTTCCTGGGCAAGGCTGATCCTCCCAGGGTAAGTCGGGTCCTAAGCACAGGCCGAAAGGCGTAAGCGATGGGAAGCAGGTGAATATTCCTGCACCATTGTGTGTGCGTTCGAGCGATGGGGTGACGCGGAAGGTAGGGCCATCCGGGTGATGGATGTCCCGGTTTGCACCTGTAGGAGGGAGCGGCAGGCAAATCCACCGCTCCAACTCCGAGGGGTGTGACGAGAGCTTCGGCTCGCAAAGTGGTCGTGTCCATGCCGCCNNATCCTCAGGTGTTCGAGCTAACCCGGGTTAAGGAACTAGGCAAAATGGTCCCGTAACTTAGGGATAAGGGACGCCCGGTCTGGTGACGGTGTACAACCTGAGCCGGGCTGGGCCGCAGAGAAATGGCCTGGGCGACTGTTTACTAAAAACACACGTCTCTGCCAAGTCGTAAGACGACGTATAGGGACTGACACCTGCCCGGTGCTGGAGCGTTAAGGGGAGAGGTCAGAATACGCCTAACCGTGTATTCGAAGCTTTGAACCGAAGCCCCAGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGA
->AMYB01000001.1/3357429-3357616 Mucor circinelloides f. lusitanicus CBS 277.49 MUCCIscaffold_01, whole genome shotgun sequence. 
-CGTATCTGCCTTAGATCCTTTGTCAAGGTTTTGATGTTTATCATCCTAATCTACAGAGCTTATGTTTTGCTTTTCGTTGACAAAGCTTGAGTCATTCAGATACAAGATTACCTATACCTCCATCTCGGTCCAGTTTTATGGCTTCTTGGCTGTCTGTACTCTGTAGATTTTGCTTATATGGATACTTG
->BBIW01000001.1/9239-9376 Paenibacillus sp. TCA20 DNA, contig: PspTCA2nb01. 
-GACTGATAACTGCCGAATTCTCGCACCAAGAAGCGGGGGACCCGACCATTTATGGGTGAATTGATCAATATTAAAGTGATCATAGGGAACCTTCAACCGAATCCTTAGCTAACCTCGCAGGCATTGGAAGGAGTATTA
->ALWS01013471.1/7379-7260 Pteropus alecto contig13471, whole genome shotgun sequence. 
-TCATACGGATAACTTCCAATTAAAATTCAGGACTACAGCCTGATCTCAGAAGCTAAGCAGGGTTGGGCCTGGCTATTACTTGGATAGGCGACCACCTAGGAAGACCAGGTGCTATAGGTG
->LOER01000038.1/6182-6000 Desulfitibacter sp. BRH_c19 BRHa_1005201, whole genome shotgun sequence. 
-ATAATCCTGCTAAGTTCGTGTTAGGGCCGGTTATTTTGAAACCAACACTAAAACATTGGGAATTCGGTGTCTGGTTGAGTATGAAAAGCCTTCTGGGAAAGGAATTCAAAACCAACTAGCAGAGTACCCACCTGCGTAGGCAGGTTTCTCAAAATTCCGGCAAACGGCTAGAGCGGGAGATGC
->GL378346.1/56514-56307 Volvox carteri f. nagariensis unplaced genomic scaffold VOLCAscaffold_25, whole genome shotgun sequence. 
-TGCATTCACCGTTTTCGAAAACTCGCAGGCCGACAGCCCCAAGCAGGCCATCAGCAATGCGAACATTGTTCACGACTAAAATATCTGCCCTATCCACTTTCAATGGGAGGATTGAGACCTACCATGGTGGTAGCGCGTGACGGAGGACTAGGGTTCAATACCGGAGAGGGAGCTAGAGAAATGGCGAACACAACCAAGGAAGGCCGCA
->CM000392.2/29331781-29331980 Equus caballus chromosome 16, whole genome shotgun sequence. 
-AAGGACGGAAACAGTGTCTTCTGCTTGATCCAGAAAGACGTTCCTCATAAAAGTCCGTAGAAAATTAAAATCTTCCACAAGAAGGAGGGGCGGCGTTCTCTCCTGAGTGTGAAGCCAGCTCTTGGTGTTGCTTCACTGCAACTGCCATTTGCCATTCATGGTCTTGGGGAATAAGAGAGAGAGGACAGAGTCTGAGTGAT
->MNYG01000183.1/3075-2991 Deltaproteobacteria bacterium CG2_30_63_29 cg2_3.0_scaffold_12261_c, whole genome shotgun sequence. 
-CTTGCCCTCCGCCACGACCAGCAAACAGAAGACGGCGCCGAATTCGGCGCCGTCTTCTGTTTGCTGGCTGACGCGGCACGTCAGC
->LJSX01000027.1/46243-46357 Rhizobiales bacterium HL-109 ITZY_scaf_197, whole genome shotgun sequence. 
-CACTCTGGAAAGAGGCAGGTCGAGACAGGCCTGCCCACCGAAGGGCGTAACTCGGCAGTTTCGAAACCTGGTTTCGAGGGTTCCGAGGAAATCTCTCAGGTTACGGGACAGAGGG
->KL543181.1/848-2043 Capsicum annuum cultivar Zunla-1 unplaced genomic scaffold scaffold24819, whole genome shotgun sequence 
-CGACCCCAGATCAGGATGGATTACCCGCTCAGTTTAAGACTATCAATAAATGGAGGAAAATAAACTTACAAGGATTCCCTCAGTAACGAAAAGCAAACCAAGAATAGCCAACCTTAGAATTGAGCGGCTTCATCATCCGAATTATAGTCTGGAGAAGCTTCCTCAGTGGCAGACCGGCCCAAGTCCCCTGGAAGGGGTGCTAGAGAGGGTGAGAGCCCCATTGTGCTCGGACCCTATCGCACCACAAGGCGCTATCTATGAGTCGAGTTGTTTGGGAATGCAGCCCAAATCGGGCGGTGAATTCCGCCCAAGGCTAAATACGAGCGAGAGGCCGATAATGAACAAGTACCGTGAGGTAAAGATGAAACTGAATTTGAAGAAAGAGTCAAAGAGTGCTTGAAATTATTGGGAGGGAAGCGGATGGGAGACGATGATATGCCCCAGTCAGATGTGGAACGGAGATGAGCCGGTTCGTCGTTCGACTCAGGGTGTGGACCAGCATGGATTGGGGGAGGCCAAAGCCCGAGCTCTTGGTACGCTCGTGGAATGCCGTCTCCTCAATTGTGGCAGGTAGTGCGTGCCTCCGATGTGCTTCAACATCTGCGCACTTTGGATGCTGGCCTGTGGGCTCCCCATTCAACCCGTCTTGAAACACAGACCAAGGATTCTGACATGTGTGCGATTCAATGTTCGAGTAAACCCATAAGACGCAAGGAAGATGATTGGTGGGATCCCCCTGAGGGGTGCATCGCCGACCGACCTTGATCTTCTGAGAATGGTTCTAGTGTGAGCATACTTATCGGGACCCAAAAGATGGTGAACTAGGCCTGAGCTGGGCGAAGCCATAGGAAACTTTGGTGGAGGCCCACAGTGATATTGACGTGTAAATCGTTCGTCTGACTTGCGTGCACCACATGCTAAGTGCACGGATTCACCAATGAACCATGGGCAAAATGGCCACTAAGGATTATGTGCTTGGCACCCGTATGCCCGTGCACCCACTGTGAGCACACTATGTATTCGGCACTCGCACACCACAACACCAATAAAACACCATGCCACATGCCCCAAAATGGATCGGCGACCCCTGCACCATGCAAAAATAAAAGGAACATAAACATGTGAGGGTTCATAACTAGTAACTTCGACAATTACAAAATAAATGCTTCCACCAAGGTTCGTTCATCCTAATACTT
->LQOK01000039.1/11515-11571 Mycobacterium bohemicum strain DSM 44277 contig_44, whole genome shotgun sequence. 
-CCGGGCCCGGTTCCCGCTGGCCGACCAGGTGCAGCTTGCTGCCCGCGACCCGGCCCC
->CP010951.1/2115046-2114927 Ramlibacter tataouinensis strain 5-10, complete genome. 
-GCCGCTGCTCCGGGGTGCGAGCGGCCCTTCGAAAGAAGGCCGGTATCGCTGAGATGGTGAGTCCAAACCCGTGAACTTGAACCGGTTCGTACCGGCGTAAGAAGAGCTGACAGTGTCCCT
->JH835735.1/956530-956203 Erinaceus europaeus unplaced genomic scaffold scaffold00447, whole genome shotgun sequence 
-GGATGTGAGGGCACTCTGGCTGCGACATCTGTCCTCCCATTGATCGCCAGTGTTGATTCGGCTGATCTGGCTGGCTAGGTGGGTGTCCCCTTCCTCCCTCACTGCTCCATGTGTGTCGGTCCCGAAGCTGCGCGCTCGGTCGAAGAGAAAGAGGACAGCCTTCCCCGAATAGAGACAGACCGCTCTTCAGTTATACGAGTTATACGAGTAGCTGCACTCCCCTGCTAGAACCTCCAAACAAGCTCTCGAGAAACCTTGGGGCCTGGCGGTGGTGCACCCAATAAAGGACACATGACACAGTGTGCAAAGAACCTGGTTTGAGCTCCTG
->CP000517.1/489591-489403 Lactobacillus helveticus DPC 4571, complete genome. 
-TTGGATTTAGTATAATTTTATCCGTAGAAAAGCTGAAGCGGTGGCTATCCCTCAAGGAGATGGTACTTATGAGTATTTTTTAACTCGTATTCCTATCTTAAAAGAAAGGAGAAGCCCTCGTGTCTGTATCAGATGCGTTACAGCTAATACTAGATTTCGGCTCATTTGTCGTTATACTAATCTCATTAA
->CM000798.1/58059981-58060079 Oryctolagus cuniculus chromosome 9, whole genome shotgun sequence. 
-ATCACATCTTAGCCTTTTGGCTAAGATCAAGTGAGGAATTTTTCAGATTTAATTTTCATTACTACTATAAGTAGTAAAACTATTAAACTTGTAGCCTTC
->LM151543.1/11334-11803 Schistosoma mattheei strain Denwood, Zambia genome assembly, scaffold: SMTD_scaffold0002192 
-ATGTTAGTAGTACAAAATAAGATGACGAATTCCCAACTGTTATTCAGGCTTGACTACTCGTATGATCCCTCGTTCAATAACTTATCGTCATTAAGTGTTAAATTTTCATCGATCTGTAAGCATCTGCTACGAAACCAGTATTTTTTTAGTGAAGTATAGTTTCGAATTGTTGTATTGTGCGGTTTGGGATACGCTGTTTATTTCATTTATTTATTTGAACACATAAATATTAGTTTAAAAGGGTACCGAATACATATGCGCCACACAAGTCAATTGATTTGTGTGTGAGCTGTGATACTACCCAGGTGCTCAGACCGAATGTTTTCATTGATCAGGAGCAAAAGTCCGAGTTTCGAAGACGACCAGATACCGTCGTAGTTGTGACCATAAACGATGCAAACTGACGATCAGCGTTTGTTCTATGATTGACATCGCGGGCAGTCCCCGGGAAACCTTTAAGTCTCTGGGCT
->EU622808.1/288-49 Bacillus phage Nf, complete genome. 
-CAAGGTGCAACACTTCCTATAGTATGGCACATGATTGGGGTATATCCTGATTGAGTTCAGCCCACATGTCACGGGGATTGATAACCCTCTTACTAAAAGTGATTGTTTCTTTGTCCTTTGTAACAATGCCACTGACGAAACGTTAAAGCGTGGGTTTCAGTGGTATTTTAATTTGTTCACAGATGTAGTAAATTATAGGTACATAGATGTATAAATATGCAGTTACAACCCTGCCCTAAT
->FR853100.2/134335079-134334871 Gorilla gorilla gorilla genomic chromosome, chr7, whole genome shotgun sequence 
-GCTGGGTGTGGTGACACGCGCCTGTAGCCCCAGCTACTTGGAAGGCTGAGGTGGGAGAATTGCTTGAACCTGGGAGGGAGAGATTGCAGTGAGCCAAGATTGTGCCACTGCACTCCAGCCTGNNNNNNNNNNCAGGCTGGAGTGCAGTGGCACAATCTCGGCTCACTGCAACCTCTGCCTCCTGGGCTCAAGCAATTCTCCTGCCTCAG
->CM000316.3/76140660-76140798 Pan troglodytes isolate Yerkes chimp pedigree #C0471 (Clint) chromosome 2B, whole genome shotgun sequence. 
-TTATCAGCTTGGGATAATCTTTACCTGTTCCTTCTTTTGGAGGGCCAAATTAAGGACATGATTGGCGGTCTCACATCAGTATGCGATTAACGTCTCTGAGTAGATCAGGAACTTCCAGTACCCTATTGTGCTATCTGAT
->KE713303.1/22354-22189 Biomphalaria glabrata isolate BB02 unplaced genomic scaffold LGUN_random_Scaffold3540, whole genome shotgun sequence. 
-ATACTTACCTGGCATAGGCGGACAATGATCACAAAGGTTGTCCTCCCAGGTCGAGGCTCGTCCATTGCACTTAGGGCGGGCTGAAGCCTGCGACCACCCTTATCTTTTTTTATTCAAATTAAAAGCGCTTTTTTTTAATAATGATATCTTTTGAATGTAAATTTGC
->CM001013.2/117960327-117960221 Mus musculus chromosome X, GRC primary reference assembly. 
-GATGCAGTCCCGGGCACCATCTTGGGACTGCTGCTGTAAGACCCCCTTTCGGGGACCCCCACTCTAGTATTGGGAGTGAGAGAGCACTCAAAGAAACATGAGAATCC
->MHZW01000213.1/12164-11957 Rhodocyclales bacterium GWA2_65_20 gwa2_scaffold_6804, whole genome shotgun sequence. 
-ATGAATACAACAGACAGCGGCCCGGCTATAATCCGCCCCGATTCGGCCAAGAGAACACGGTGCAAATCCGTGGCGGGCCCGCCGCTGTAACCGGGGACGAACGCCGCCTGTCGCGAGACGGCCACTGCCGGGGACCACCCTGGCGGGAAGGCGCGGCGCTTCGGACGATCCGGGAGCCAGAAGACCTGTCGAGTCCTTTTCTCGAAAC
->LMSD01000007.1/142068-141895 Paenibacillus sp. Soil750 contig_15, whole genome shotgun sequence. 
-TGTGCCTTTAAAAACAGTCCAGAGAGGCTGGCAAGGTAAAACGATAAGAAAAGTCGGGTAATGCTGAATCGAGAATTCAGTAAGCTTACGGATGTGCGCATCCTACAGCCCCGCTCTATCTCTTTATGCACTCGTAAACTCCTTGCCAAGAATTGGGCAAGGAGTTTTTTGGTT
->FWYF01000005.1/72068-71837 Reichenbachiella faecimaris strain DSM 26133 genome assembly, contig: Ga0069982_15 
-AGATTTGCGGCAATTATTGGTTTTCGAAGGAAACGTATCCTGAGAAATTAAAAGGGAATTCGGTGAAGTGCTTAGCGCTCATTCCGAAGCTGTTCCCGCAACTGTAATTCGAAGATATCCTTGTGATATCATTTTTGATCTACCATTGCCACTGTCCTAATGAATCGGGATGGGAAGGCCGATCAAAAGATTTCGAAGAGCCAGGAGACCTGCCAGTAGTTATTATTTATCT
->CBUT010022175.1/1809-1930 Eimeria mitis, Houghton, WGS project CBUT01000000 data, contig: Emh_contig2519_2 
-GCTGCTGCTGCTGCTGTTGCTGCTGCTGCTGGTGCAGCAGCAGCAGCAGCAGCAGATGAAGAAGGAGATAGGCTTCGGCTGCTGCAGCTGTGTGACCATTTGCTGCTGAAGAGACACACAGA
->CM001945.1/16929330-16929657 Chlorocebus sabaeus isolate 1994-021 chromosome 5, whole genome shotgun sequence. 
-GCTGGGTGTGGTGGTGCACGCCTGTAATCCCAGCTCCTCAGGAGGCTGGGGCGTGAAAATAGTTTGAACCTGGGAGGCGGAGGTTGCAGGGAGCTGAGATTGCACCACTGCACTCCAGCCTGGGTGATAGAGCAAATGCTCTGGCTATTGTGTTGGCAGCAGATTGGAGGAAAACAAGAGTCGGAGGGTGAGACCTCTGAGCGAGTTACTTATGTTCAGACAGCAGTCCTGTCCTGAACTGCTGGAGTGCCCAGGCTGGAGTGCAGTGGCGTGATCTCTGCTCACTGCAACCTCTGCCTCCCAGGTTCAAGCTATTCTCCTGCCTCAG
->MTYJ01000796.1/4174-1035 Hypsibius dujardini strain Z151 scaffold0796, whole genome shotgun sequence. 
-AGATAAAGCTACTAAGGCATAGGTGGTACCTTGGGGAAGTAGAGGCGATGAAGAGACGTCGGTGTACATCTGCGGATATTTGCTTCGGGGAGCTAGGTAAATAAGCTTTGTATCCGGAGATTCCGAAGTGGGGCAATCCCCTTTACATGAGATGTTGTAAATGACACTGCATGAGTTCAAGTAGTGCTGATGAGTCGACGCAGGCGAATGAAACACTCTAAGTTACCTGCAGCTGAGTAGAATCAAACGAGATTTTCTTGCAGTAGCGGCGAGCGCAGAATCGCAGAAGAGCCCAAAACCATTTGTGCGTGCACATTGGGGTTGTAGGATCTCGTATCAAGGGGAGTTAGTTAGCAAGAACGGTTTGGGAAGGCCGGCATAGAGAGTGAAAGCTCGTATAATACGAAAACTAACAACACCTGGCACGAGTATTCCCTGAGTAGAATCGGGGCACGTTGAAAACCCTGTTTGAAACTGGGGGGACCACCCTCCAAGCTACAAATACTACCTTACTACCACCGTAGTGGAGCTAGTAAACGGCGAGGGAAGGTGAAGAAAGAACCCCGATAGAGGCGGAGTGAAATAGATTTTTTGAAACCGTATGCTTACAAACAGTCAGGAGGGCTATTGTTAAAGCCTGATGACGTAACCTTTTGCATTTGATTCAGCGAGTTTATGGCTATGTGGCAGGTTAAGCCGTTGCGAGGGTGTAGCCGTAGGGAAACCGAGTACTGAAGTAGGGCGTTAAGTCGGCAGTGCTTGTAGAGCCCGAAACGGGATGACTGCTATCATGTTGCGGCAGGCTTTTTGAAGCGGAGGGTAAAACTTCGTATTGGACCTGGGACCGAACTCTTTGAAGGTTAAACTTTGGGATGACTGTGGATTAGGGAGTGAAAGGCTAATACAAACTTCGGAATAGCGGTTCTCTCCGAAAATCTATTTAGGTCATGCGTTCTAACGTATTTTCGGGGGTACAGCACTGACTATGGATAGAGGGTCACGCGTAGCTTACCAAACCTATTCAAACTCCGAATACCAGACGAGTCGAGCAGTGAGACAGATGCGGATGCTAAGTCCGTGGTCAAGAGGGAAAGAAACCCAGCCGCCAGTAAGGTCCCAGAAGATACATACTAAATCTGGACATGAAGTGAGCGAAGGTTGAAACTGACAGTCAGGAGGTTGCTTAGAAGCAGCCCACCCTTTAAAGAAGCCTCGTGAATAGCCACTGGACTTGTGGTTCTGCGGCCGAAAATGTAACTGGGCTTAAGTGTTCGTACGAAGCTACTGGACTTTTTTAAGTGGTAGGAGCACTTTGTGTGTGCCTTGAATGAAGGCGTACCGTACAGGAGCGTTGGGTCTCCACAAGAGCTTGATGCTGAATGAGTAGCGATTAAGGACGAGCGAGAATCTTCTCCCCCGTAATAATCTGGAAGGGTTCCTGGGCTCAGGTGGAATCCTCCCAGGGTAAGTCGGTTTCTAAGGCGAGCGCCGAAAGGCGTAGTTTCGCATGAACCATCAGGTTAATATTCCTGAACTTGTATGGTAAACGTTTGACTGGAAGGAGTGACGGAGAAAGATAGCAGATCTGGAGCATTGTTGTTCCAGATGTGAGGGTAGTAGGTGTGTGAGATAGGCAAATGCCGTCACAGTATATCACAAGGCCTTTGATTGCCGAATGCGCAAGCAGAGTCTGTTACTCTACGCCTTCCAAGAAAAAGTTCGCTAGGGAGTTATGTATTAATCCGTCGCTTAAACCCGACACATGGGTTATAGATGAGGAGAAATCCTAAGGTGATTGGATGAACTCTACGTTAAGCCCGCCCCTCTGGCAACTTAGATACTGGTAACTTCGGGAGAAGGCGCTGAATGTGAAGTCACTTGCTGACGTAGCATTATGAGGGTTGCAGTAAATGGGGTGAGCGACGTGTTTTTACCAAAAACAAGGGCCTTACTGCAACACGCAAGTGGAAGTATATTGGGCTGAGCGCTGCCGCGGTGCTGGAAGGTTAATGAGGTGGGTTATGCGCAAGCGCGCAAGCTTTTAAATTTTTGACAGTCCCAGTAAAACGGGCGGCGTAACATATACGGTTCCTAGTAGCGAATTTCGTTAGTCGGGTAAGTCGACCTGACGAATCGGCGTAACGGACTCCCCCTGTCGTCGAATCTGCGAGATCCAGCGAAATTTTGCGGTTGTGAGCGTCTGTGAAGAAACGCGCTTCGACCGCGCGGAGGATCCGAACAGAGGACCCCGTGAGCCTTTACTTGGTAAAAAAACCTTTTTGGTGGGGGCATTTGGGTTTATTCGGGAAAATAAAGGGGCCATGCGTCTAGGATAGGTGGGAGTTTTTGATCGTGCGTTCCGGCGAATTGAGCGTTCGGGGAGAACCAACCTTGGAAATACCACCCTTGCTTATTTTGGTAAGTCCATAACCTGCGGTCCTAATTCGCGGGCCGGGGGACAAATTGTCTGTGTGGGCACGTTTTGACTGGGGGGCGGTCGGCCTCACTAGAAAGAGTAACGGAGGCGCCGAAGGTCCTCTGAGCAGTTGGAAATCCGGCGAAAGGAGTGTAAACGCATTAAGGGAGCTTGACTGCGAGACAAACACGTCGAGCAGGAACGAAAGTCGCGGCTTAGTGATCCGGTGAGTTTGCCGAGTTGGAAGGGCCATCGCTCAACGGATAAAAGGTACTCCGGGGATAACAGGCTGATCTCCCCCAAGAGTTCACATCGACGGGGAGGTTTGGCACCTCGATGTCGGCTCATCACATCCTGGGGCTGAAGCAGGTCCCAAGGGTTTGGCTGTTCGCCAATTAAAGTGGTACGCGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCCCTATCTACTGTGGGCGCAGGAAATTTGAGGGGGTCTGTCCTTAGTACGAGAGGACGACCGGAGTGATGAACGAAACTCTGGTGTACTCGGTTGTCACGCCAGTGCATGCCGGTAGCTAAGTTCGGAAGATAAACCGCTGAAAGCATCTAAGCGGGAAGCTAGCCTAAGATGAGTTCCCTAGCACCCTTGAGTCCTAAGGCCGTTCGAGACCAGACGTTGATAGGTGGGGGTGGAAGCGCTAGTGTGAGCTACCATACTAATTCCGTGAGGCTTACCTAT
->KQ483358.1/2572342-2572106 Curvibacter sp. PAE-UM genomic scaffold Scaffold1, whole genome shotgun sequence. 
-CGTAAAATCTACAACGTTGGTGCTCGCGGTGTGGTTCACATGCCGCAGTTCAACGGGAAGCAGGAAGGTGAGCCGTCATGGCGAGCCCAACCTGCGCTGCCCCCGCAACGGTAAGTGGACGAGCCGCAAGGCTCCGCTTTCATCACCCAGCCACTGGATGCCCTGAACAAGCGTCCGGGAAGGCGATGAAGGTTGTTTCCATCAGCCCGGATACCGGCCAATGAAGTGGTGTCGCGC
->AOLZ01000036.1/1-202 Halobiforma lacisalsi AJ5 contig_36, whole genome shotgun sequence. 
-GTACCGGTTGTTCGAGAGAGCACGTGCCGGGCAGCCACGCACCACGGGGTAAGAGCTGAACGCATCTAAGCTCGAAACCCACCTGGAAACGAGATACCGCCGAGATCTCTCCTAGAAGAGGAGTTCGATAGACTCGGGGTGTACGCGCCAAGGCAACGAGGCGTTGAGCCCGCGAGCACTAATCGATCGAGCCACACACTCA
->AYZS02054104.1/146-603 Beta vulgaris subsp. vulgaris contig144508.1, whole genome shotgun sequence. 
-GCATAAACCAGTTACAGCAATTGATGGATGCCTTGGCTTCATCAGGCGACGAAGGACGCAGCAAGCTGCGATAAGCTTCGGGGAGCGGCACGCACGCTATATATCCGAAGATTTCCGAATGGGGAAACCCGGCACCTCTCATAGGGTGTCACTTCGATCTGAATACATAGGGTCGATAGAGCAATACGTGGAGAAGTGAAACATCTCAGTATCCACAGGAAAAGAACGAGAATCGATTCCGTAAGTAGTGGCGAGCGAAAGCGGAAGAGCCCAAACCGCCGGGATTTATCCTGGCGGGGTTATAGGACCATAATGTGAGACCACAGAAGTTAGACGAACACTCTGGAAAGTGTGACCATAGCGGGTGACAGTCCCGTAGTTTAAAACTCGAGTGGCTCTATTGGTATCCTGAGTAGCACCGTACACGTGAAATTCGGTGTGAATTCGTGGCGACCACG
->JPJR01003066.1/1-928 Pseudogymnoascus pannorum VKM F-3808 contig_3066, whole genome shotgun sequence. 
-GACTGTGAAGGAAACCCCGATCAATGGCGGCCTTATTTTGAGGGTCCTAAGGTAGCGGAATACCCTGGCCGTTAAATGCGGTCTTGCATGAATGATTTAACGATACAACAGCTGTCTCAATGATTGGCTCAGTGAAATTGGAATAACTGTGCAGATACAGTTTACCTCTAGTTAGACGAGAAGACCCTATGCAGCTTTACTGTTGCTAGTTATTGGATATGATTGAATTAATTTTAGTAGTATAAGGTAATTGGTTAGATATAATTGAAATACCTTTATTGTGTTTGTCATATTGATAGATTTAATCTATTTTCTTATCTAAAGATAGGAAATGACCCCTACTATGTTAGGGGAACAATGGCTAGGAGGCAGTTTATGCGGGGCACAGATCCCATAAAAAGTACCTGGGTGTATCCAAAGTTAATTTTGTAAAATTGACATGACTTACTTCTAAATTTATAATTTGGAAATAAGTTTTCATGACTAATAATACATTATATATTTAATGTATTTATTTTTAGTTTGTTATTTGGTATAGCTTATGCTATAACTAATCCAGCTATTTATCTATTAAGTTAGAAATATTTTTTTATCCAAGTAAGATTTTATCTATATGGAAAATAGATGTAATTAAAACATTGACGTAGATATCTTTCCAATGTTTTTTAATTTTTTTATTAGGTGTATTTGGTGAAACCAAACTACAAATTGCTAATAAGACAATTATGTTTATTACTTGTCAAGTTTAATGGCTTAATCTTGCTTTACTGTTTGACTTACACGTCTATCAGTCGCGTAAGCGGGGCATATGATCACAAGATGCAGAAAGGAAAGGTCTTGGATTTATGAAAAAGCTACGCTAGGGATGTTAGTCCTCCAATGTTTAAGTCTACTAATATTTATTATTGGGTTAATTAGACTTAAACTC
->CP009129.1/1242075-1242156 Planococcus sp. PAMC 21323, complete genome. 
-TCATTGCTGCAACCGCTCGAATCAGGTTACGTTAAGAAGATGCTTCGGCAGATCACCTGAATAGGCGAGTCTTAATCTAGAG
->KM349742.1/1-304 Betacoronavirus HKU24 strain HKU24-R05005I, complete genome. 
-GATAAAGTGTGAATCGCTTCCGTAGCATCGCACCCTCGATCTCTTGTTAGATCTAATCTAATCTAAACTTTATAAAAACACTAGGTCCCTGCTAGCCTATGCCTGAGGGTTTAGGCGTTGCATACTAGTGTCTTAGGAATTTGACTGATAACACTTCCCTGCTAACGGCGTGTTGCACTCTCAGTCTAAGCCTCCCACCCATAGGAGGTATCATGGCTAAGCGAGTCAACAAATACGGCCTCACGCTAAAATGGGCCCCAGAATTTCCGTGGATGTTTGAGGACACAGAGGAGAAGTTGGGTAA
->MFFM01000046.1/175782-172748 Candidatus Edwardsbacteria bacterium GWF2_54_11 gwf2_scaffold_695, whole genome shotgun sequence. 
-GGTCAAGCTACAAAGGGCACATGGTGGATGCCTTGGCAGATGAAGGCGATGAAGGGCGTGGTAAGCTGCGATAAGCTTCGGGGAGGTGCAAACAACCTTAGATCCGGAGATGCCCGAATGGGGGAACCCGTTCCGAGTCATATCGGAACACGCCGGGATGAAAACATTAGGAAGTAATCCTGGAGAGCTAACCTGGCGAACTGAAACATCTAAGTACCCAGTGGAAGAGAAATCAACCGAGATTCCCAAAGTAGCGGCGAGCGAAATGGGAAGAGTCTAAACTCGGTCCTGCGTGATAGCTGATACGCGTTGCAGGACGGGGGTATCAGGGTCGTTACGGATCCCGTGTATCAACCGGGGTCGGGGAGTCAAAAAGTCGTTCCTTAGCCGAAAGGTCTGGGAAGTCCTACCATAGACGGTGAAAGTCCGGTAGGCGAAAAGGAAGCGATCTCCCTGGTTGCGATTCCTAAGTACCATGGGGCACGAGAAACCCTGTGGGAATACGGGGGGACCACCCTCCAAGACTAAATACTCTCATCTGACCGATAGTGAACTAGTACCGTGAGGGAAAGGTGAAAAGCACCCCTGGCGGGGAGTGAAATAGTACCTGAAACCATGTGCCTACGATCAGTCGGAGCCTCGATTTATTCGGGGTGACGGCGTGCCTTTTGCATAATGAACCGGCGAGTTGCTTGTATGCAGCAAGGTTAAGTCCTTCTGGGACGTAGCCGAAGCGAAAGCGAGTCTGAATAGGGCGATTCAGTTGCATGCAGCAGACCCGAAACTGGGTGAGCTACCCATGGCCAGGCTGAAGTGACGGTAACACGTCATGGAGGGCCGAACCGGTGAATGTTGAAAAATTCTCGGATGAGCTGTGGGTAGGAGTGAAAGGCCAACCAAACCCAGGGATAGCTGGTTCTCCTCGAAATATATTTAGGTATAGCCTCGGAAAGTATGTGGCGGAGGTAGAGCACTGACAGGGCAAGGGACCTTACCAGGTTACCAACCCCTATCAAACTCCGAATGCCGTGCACAGGAATTCCGGGAGTCAGGCAGTGGGGGATAAGCTTCATTGCCGAGAGGGAAACAACCCAGATCGTCAGCTAAGGCCCCTAAATATCAGCTAAGTGAGAAAGGATGTGGAATCTCATAGACAACCAGGATGTTGGCTTAGAAGCAGCCACCATTTAAAGAGTGCGTAATAGCTCACTGGTCAAGTCATTCTGCGCCTACAATACACGGGACTATTAAGCTGATTGCCGAAGCTGCGGACTTGATTGATGTTCGCATCAGTCATTTGGTAGAGGAGCGTTCCACAGTAGGATGAAGCGGTGCCGTAAGACACCGTCGACGAGCTGGAAGTGAGAATGCCGGTATAAGTAGCGATAAACCAGGCGAGAAACCTGGTCACCGAAAACTCAAGGGTTCCTGGGGAAGGCTAATCCGCCCAGGGTAAGTCGGGCCCTAAGCCGAGGCCGAAAGGCGTAGGCGATGGAAATCCGGTTAATATTCCGGAACCACTGGTAAAGCGTTATCACCTAAGGGGGGACGCAGGAGTGAGATCCCATCCGCGATTGGAAGTGCGGGTCTAAGCTGGTAGGGGGATCCTGTAGGCAAATCCGCAGGGTCGTTAACCCCGAGAAGCGATGGGGAGTCCGTAAGGACATAAAAGGGATCGAATCACGCTGCCAAGAAAAGCCTCGTAGGGAGTTTTGCCGGTGTCCGTACCGTAAACCGACTCAGGTGAGTGAGAAGAGTATTCTAAGGTGCTCGAGATAACCTCCTTTAAGGAACTAGGCAATTTAGCCCCGTAACTTCGGAAGAAGGGGTCCCCGATTCTGTTAGGTAAATTCTTGCTGAAGCAGATTTGGGGCGCAGTAAATGGGCTCGAGTGACTGTTTATCACAAACACACGACTCTGCTAAGCCGATGAGGCGAAGTATAGGGTCTGACACCTGCCCGGTGCCGGAAGGTTAAGAGGAGAGGTCAGCCGCAAGGCGAAGCTTTGAATTGAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGTGTAACAACTTGAGCGCTGTCTCAAAGGAGGACTCGGCGAATTTGTAGTGGCGGTGAAGATGCCGCCTACCCGCAGATGGACTAAAAGACCCCGTGAACCTTTACTGTAGCCTGGCATTGAATTTTGGTAAGGCATGTGTAGGATAGGTGGGAGACACTGAAGCTGGGGCGCTAGCCTCGGTGGAGTCGACGTTGAAATACCACCCTTGTGTTATTGGAATTCTAACCTAAATCAGTGAATCCTGGTTGGGAACCGTGTCAGGTGGGCAGTTTGACTGGGGCGGTCGCCTCCTAAAGAGTAACGGAGGCGCGCAAAGGTTTCCTCAGCGCGGTCGGTAATCGCGCTTATAGAGTGTAAAGGCATAAGGAAGCCTGACTGTGAGGGAGACATTCCGAACAGACACGAAAGTGGGCCTTAGTGATCCGGTGGCTACACGTGGAAGCACCATCGCTCAACGGACAAAAGGTACTCCGGGGATAACAGGCTGATCTTGCCCGAGAGTTCACATCGACGGCGAGGTTTGGCACCTCGATGTCGGCTCATCGCATCCTGGGGCTGGAGAAGGTCCCAAGGGTTGGGCTGTTCGCCCATTAAAGCGGTACGCGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCTCTATCCTCTGTGGGTGTAGGAGATTTGCGAGGATCTGTCCTTAGTACGAGAGGACCAGGATGGACAAACCTCTAGTGTACCAGTTGTTCCGCCAGGAGCAATGGCTGGGTAGCTATGTTTGGTCGGGATAACCGCTGAAAGCATCTAAGTGGGAAACCCACCTCAAAACTAGATCTCCCTTCCTGTTTATTCAGGACTGAAGGCTCCCTGTAGACTACAGGGTTGATAGGCCACCGGTGTAAGATCCGTAAGGATTTCAGCCAAGTGGTACTAAATTGGCCGTGCGGCTTGATCAT
->CM001436.1/1586328-1586399 Methanoplanus limicola DSM 2279 chromosome, whole genome shotgun sequence. 
-GTCCCGATAGGGTAGTGGATATCCTAGAAGCTTGCGGAGCTTTTGACCCGGGTTCGAGTCCCGGTCGGGGCG
->HG764817.1/91383-91181 Clostridium ultunense Esp genomic scaffold, CULT_3033 
-AACTTCATATCTCTTTTAGGTCACTTAGTTGACTCGCTAAGTGTTAATAGGGAAGTCCGGTGGAAATCCGGCGCGGTCCCGCCACTGTAAGCAGGGAGAGACGTTTAGGCCGAAAGGCAGCCACTGTGTACCGTCGTGCATGGGAAGGTGAACGAATCGAGGAACTGCAAGCCAGGAGACCTGCCTAAAAGAACGGCAAGTTC
->FOGW01000010.1/58334-58502 Lachnobacterium bovis strain S1b genome assembly, contig: IE07DRAFT_scaffold00007.7 
-TAAAGAGATAGAGGTTGCGCAAGTCAAAAGTACTTTGCTAGATGAAGCAAATCAGATGACAGTAGAGGAAAGGGGCAAGCGCCGAAAGGGTTATTTTTGCAGAATAATTCTTGGGCATAAAGTTAATAGCTTTATGACTGTCATCGTAAGATGGAGTGCTATCATATAA
->FR883370.1/19793-19582 Clostridium sp. CAG:221 genomic scaffold, scf18 
-TATTGAAGGAATTAGTATGGTGCTTTTAGTTTATAAATATAAATAGGCAAAAGTTAAAAGGGAATGTGATGAAATTTCACAACAGCCCCCACTACTGTGATAGAGGATGAAAGCTAAAATTATAAATTCCATTGAGAGATTTTCTTGAGAAGGAGTTTAGTGAGTAAAGAGATTCTTAAGTCAGGAAACCTGCCATAACTTTAATAGTGTTT
->CP013068.1/4601278-4601164 Pannonibacter phragmitetus strain 31801, complete genome. 
-ATACCCTACGGAGCGCCTGGGTCCGCCGCATCTCCTGGGTCCGTGGGGCAAGGCCGGCGCGGTGTCTGCCCGATGAGTGGCCTCCTCGGATTGGCAGTCCCGCGCCGGCCGCCAC
->AOCG01000006.1/51721-51599 Listeria aquatica FSL S10-1188 c5, whole genome shotgun sequence. 
-AGATCCTTTAAATGTAGTCCAGAGAGGCTGAAAAGGTTAACGCTCATTTTGGAGAAGGTTCTCCATTTTAATTCGTGAGGTACGTCTATACCCTTTGCCGCTTTGGCAAAGGTTTTTTTTGTA
->AQHR01000110.1/102878-102980 Lunatimonas lonarensis strain AK24 S14_contig_28, whole genome shotgun sequence. 
-TGCCCATCGGGTGATGGGGTGCCACCCAAATATCAGGGACTTATCCGAAGTTTTCTGATTTTTTGAACCGCTTCGCAAGAATGCTGATGACTCCTACTTCAAC
->FXAQ01000027.1/27875-27818 Paracoccus sp. J56 genome assembly, contig: M511DRAFT_scaffold00027.27 
-CATGGAGCAGGGTGAAATTTCCGGCTGGGTTTTCCGGCCGCCTGTCCGCCGGACAACC
->HF986872.1/13619-13817 Firmicutes bacterium CAG:555 genomic scaffold, scf18 
-CAAAACCGATAGGTATTCGGCTCTGGGCCAGCTCGATTAAAAGGGAATCCGGTTCGAGTCCGGAACAGCCGCCATTACTGTATTTGACACAACGGGAGTCCATTTTGCCATTGGTGCGGCCTGTCCTTCGGCGGGCGCATCGAGAAGGCGGGCTTTCCGGTCATAAGTCAGGAGACCTGCCGTGCTTTTTAGGTTTACA
->CM009307.1/3068679-3068534 Populus trichocarpa isolate Nisqually-1 chromosome 18, whole genome shotgun sequence. 
-TTCAAAAGCTATTGGGTGTGACTGAGCAGCCGGATCCAACACTATTGGATCTTGTCATGTAGACCCTAAGCGATTGGGTTTTGTTGGGCAGCAGATTCCAATGTTGTTGAATCCTGCCAAGCTAGACTTAATAACACTTTTTGACT
->JSDP01000122.1/5559-5705 Aphanizomenon flos-aquae 2012/KM/D3 spades_262_len_T:9526, whole genome shotgun sequence. 
-CACTCTCTACAGTCAGAGTTGATAGGAGGGATTCTATCAAGCGTACACCAGAGAGTCCAAACTCAAACCCAGTGATGTGGGTGACTATATCCAAATATAAAACCGAGCCAGTTAGCTTGGTAGGGAAACCGAAGACTTAACTGGCTC
->AYZS02017825.1/46586-46515 Beta vulgaris subsp. vulgaris Bvchr6.sca027.con0066.1, whole genome shotgun sequence. 
-GTCTCTTCAAAGACATCTGATAAAATTGGAACGATATAGAGAAGATTAGAATGGCCCCTGCACAAGGATGAC
->CCCW010005528.1/2486-80 Brassica napus, WGS project CCCW01000000 data, contig: 38660 
-CGGCCAAAATCACCCAAACAGTCCACGGGAAGGGCCAGCGTGCTGAGTCCAAGGACCAACGTGCTGATATGTGTACTGATGGACAGCCACTGACATCCTGTGTGTGCTGACGGACACACACGGACACACACAAACAGCCACGGACGTCCTGTGTGTGCTGACGGACACACATGGACGTCGTGTGTGTGCTGACGGACACCCACGGACGTTGTGGCTGCTTTGATAGCTGGAGCTCGGAAACGAGTTCTATCGGGTAAAGTCAATGATTAGAGGCATCGGGATGCAATTTCCTTGACCTATTCTCAAACTTTAAATAGGTAGGACGGGGTGGCTGCTTTGTTGAGCCATCCCACGGAATCGAGAGCTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCCATGCGGGATGAACCGAAAGCCGGGTTATGGTGCCCAACTGCTCGCTAACCTAGAACCCACAAAGGGTGTTGTTGATTAAGACAGCAGGACGGTGGTCATGGAAGTCGAAATCTGCTAAGGAGTGTGTAACAGCTCACCTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTAAAGCGCGCGACCTATACCCGGCCGTCGGAGCAAGAGCCAGGCCTCGATGAGAAGGAGGGCACGGCGGTCGCTGCAAAACCTAGGGCGTGAGCCCGGGTGGAGCAGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTGAAGGCCGAAGAGGGGAAAGGTTCTATGTGAACGGCACTTGCACATGGGTTAGTCGATCCTAAGAGTCGAGGGAAACCTGTCTGATTGCGCTTATGCGCGAACTTCGAAAGGGGATCCGGTTAAAATTCCAGAACCGGGACGTGGCGGTTGACGGCTACGTTAGGAAGTCCAGAGACGTCGGCGGGAATTCCGGAAAGAGTTATCTTTTCTGTTTAACAGCCTGCCCACCATGGAAAGGGCTCAGCCGGAGGTAGGGTCCAGCGGCTGGAAGAGCACCGTACGTTGCGTGTTGTCCGGTGCATTCCCGGCGGCCCTTGAAAATCCGGAGGACTGAGTGCCGCTCACGCTCGGTCGTACTCATAACCGCATCAGGTCTCCAAGGTGAACAGCCTCTTGTCGATGGAACAATGTAGGCAAGAGAAGTCGGTAAAATGGATCCGTAACTTCGGGAAAAGGATTGGCTCTGAGGGCTGGGCTCGGGGGTCCCAGTTCCGAACACGTTGACTGTTGGCGGGCTGCTTGAGCTGCTAACGTGGCGAGAGCGGACCGCCTCGTGTTGGCCGAGGGATGGACTGGGAACGGCTCTTTCGAGATCTTTCCCCGGGCGTCGAACAGCCAACTCAGAACTGGTACGGACAATGGTAATCCGATTGTTTAATTAAAACAAAGCATTGTGATGGTCCCTGCGGATGCTAACGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGGTAAACGGCGGGAGTAACTATGAATCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCACATGAATGGACTAACGAGATTCCCACTGTCCTTGTCTACTATCCAGCGAAACCACAGCCAAGGGAACGGGCTTGGCAGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCCGACTTTGTGAAATGACTTGAGAAGTGTAGAATAAGTGGGAGCTCCGACGCAAGTGAAATACCACTACTTTTAACGTTATTTTACTTACTCCGTGAATCAGAGGCGGGGTAACAACCCCTTCTTTTAGACCCAAGACTCGCTTTGGCGGGTCAATCCGGGCGGAGGACATTGTCAGGTGGGGAGTTTGGCTGGGGTGGCACATCTGTTAAAAGATAACGCAGGTGTCCTAAGATGAGCTCAACGAGAACAGAAATCTCGTGTGGAACAAAAGGGTAAAAGCTCGTTTGATTCTGATTTTCAGTACGAATACGAACTGTGAAAGCATGGCCTATCGATCCTTTAGACCTTTGGAATTTGAAGCTAGAGGTGTCAAAAAATTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGTGTTCATAGCGACGTTGCTTTTTGATCCTTCAATATCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTTGATTGTTCACCCACCAATAGGAAACGTGAGCTGGGTTTAGACCGTCGTGAGACACGTTAGTTTCACCCTACTGATGCCCGCGTCGCAATAGTAATTCAACCTAGTACAAGAGGAACCGTTGATTCGCACAATTGGTCATCGCACTTGGTTGAAAAGCCAGTGGCGCGAAGCTACTGTGCGCTGGATTATGACTGAACGCCTCTAAGTCAGAATCTAGGCTAGAAGCAACGCATGCGCCCGC
->ALAR01193061.1/17763-17860 Tupaia chinensis contig193061, whole genome shotgun sequence. 
-ATCCTTGGGTGGTTTATGAGTGTGATGGTTGGGCGTTCACACCATGTGTGAGATGAGTTCCTGAGCCTTGTTATGATGTGGCGCTGTCACGTCTGATG
->AAIZ01015480.1/2116-801 Drosophila persimilis strain MSH-3 cont1.015479, whole genome shotgun sequence. 
-AGTCGGGCTTGATTGGGAACAATAACATGGTTTATGTGCTCGTTCTGGGTAAATAGAGTTTCTATCATTTATGGTAGTTACTTGTTCCCCGGATAGTTTAGTTACGTAGCCAATTGTGGAACTTTCTTGCTAAAATTTTTAAGAATACTAATTATGTTAAACCAGTTAGTTCTTATTAATTATAACGATTATTAATTAACAATCAATTCAGAACTGGCACGGACTTGGGTAATCCGACTGTCTAATTAAAACAAAGCATTGTGACACAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAAGTAAGCGCGGGTCAACGGCGGGAGTAACTATGACTCTCTTACGTGAAGCGGAACTTTTTCGTCCCCAACACGGCTGGGTGTGTCAGCCCACGCGTTTGCTAACAGGTCAAGATTACCGAAACGGTATCAAGCTGCGAATAAATGTCCTACCATCGAGGTCTCGTACCACGAGGGGCAGAAATGAATTGGAACGGCAATGTCGTGCAGGTTGTGATGCTCCCGAAACAACAAACCACATCCTGCAAAATTGTTACCGTACGCATGGGAGGCGGGTAGCAGGACATAACTGTGTAGTCAATAACCTTCAGAGGATTCTTGAGGAGAAGGGCCACACAGTGCACGTCGAACCAAGTTTGCAGCTGGAAACCTCGGTAAGTAAACCAGACCTGGTGTGTATCCGTGACAATCACGCTTGCGTGATTGATGCGCAGATTATAACAGATGGACTGTTTCTCGACGATGTGCACCATCGCAAAGTTGAGAAATATAAAAGACCTGAAGATATTTCTGCACTGCGGAGAGAATTCGGAGTGTCGGGCAACGTTGAAGTCCTAAACGCGACGTTAAACTGGCGTGGGATCTGGAGCAATCAATCCGTTAGAAAATTGATAGCAAAGGGTCTCATCTCATCCGGTGACAGCAATGTCATCAGCGCCAGAGTGGTAACAGGCGGACTATATTGCTTCAGACAGTTCATGTATCTCGCAGGTTACACGCGAGATTGGACTTAGCCTATACACTATGTTGGAGAGAAGACGCTTGCTACCTAGGCATAATGTGAAATTAGGTATAAACATCGTGGTTGTAAAACTTGAGGTGGGTTTTTAGTACGTATGCGTGATTACTTCGTAATCATGAATCGTGCATGCTAGTGGGGTTTGGCCTCCACTACTATCTTTGAAGATTTTCCTTCCTCAGCGATAAAAAAAAAAAAAAAAAATAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAATGAGATTCCTACT
->CP014135.1/3524579-3524757 Pseudomonas agarici strain NCPPB 2472 genome. 
-ACCCCGGTATTATTGCTGTCATGGGTTTTAATCGAGCTTAGCCTTGTTCATTTTTTTACACAACACCCCATAAAAGATCCTACACGGCCCGCTCAAGCCTGCAGGACCCAAAGAGACGCAGAGGCAAAAAACGCCCAAAAACGCCTGAAAAAAGGCTCTGCGGTGCTTTCTCAGCACAA
->AFFG02002037.1/1014-1 Drosophila ficusphila Contig2037, whole genome shotgun sequence 
-AGATCAGAAGAGATTTTAGATAGATCTCGCTCCTCAGCAAGGGGGAGTGTTTGCCCGACAAGCACACACTCGAATTGCTACCGGGATAGTTGCTACGTACATAGCTGTAGCTTCTATTTTGGGGCGTTGGTCTGGCGCTTAATCTAGACACATGCACTATATACATGGGTATATAAGAGTGTCGTGGCTGTACTCCCTTCAATGTGGAACACGCCACGTTAAATAAAACTCGGAGGGATCCGATCCACACCTGTCCCTATCTACTATCTAGCGAAACCACAGCCAAGGGAACGGGCTTGGAATAATTAGCGGGGAAAGAAGACCCTTTTGAGCTTGACTCTAATCTGGCAGTGTAAGGAGACATAAGAGGTGTAGAATAAGTGGGAGATATTAGGCTTCGGTTTGATATCGCCAATGAAATACCACTACTCTTATTGTTTCCTTACTTACTTGATTAAATGGAACGTGTATCATTCCTAGCCATTATACGGATATATTTATTATATCTTATGGTATTGGGTTTTGATGCAAGCTTCTTGATCAAAGTATCACGAGTTTGTTATATAATCGCAAACTAAATCTTTAATAAAACGATGCATTTATGTATTTTTGATTTGAAAATTTGGTATAACTCCAATTACTCAGGTATGATCCAATTCAAGGACATTGCCAGGTAGGGAGTTTGACTGGGGCGGTACATCTCTCAAATAATAACGGAGGTGTCCCAAGGCCAGCTCAGTGCGGACAGAAACCACACATAGAGCAAAAGGGCAAATGCTGACTTGATCTCGGTGTTCAGTACACACAGGGACAGCAAAAGCTCGGCCTATCGATCCTTTTGGTTTAAAGAGTTTTTAACAAGAGGTGTCAGAAAAGTTACCATAGGGATAACTGGCTTGTGGCGGCCAAGCGTTCATAGCGACGTCGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAAAATTCACCAAGCGTTGGATTGTTCACCCATGCAAGGGAACGT
->URS0001A23A8E_12908/1-67 unclassified sequences L31-Actinobacteria ribosomal protein leader 
-GCGGUUCCGGUUCACGCCACCAAGGGUCGGCCCGCCCCAUGACGGGUGACCUGGCGACCCGGCGACC
->URS0000D6C5EB_12908/1-87 unclassified sequences GA-cis RNA 
-GACAGGCGAAATATAACAGCTCGAAGAGCTGTATTGTAATACATTTCGCCGCACAGCCGCCGAACGAAGTGAGGGGCAATACCGCTG
->MEDQ01000009.1/7811-8223 Bordetella sp. SCN 67-23 ABS43_C0009, whole genome shotgun sequence. 
-AGAGCAGATCAGGCAGTCGCGGTGCCTTCGGGCATCGAGGAAGGTCCGGACTCCACAGGACAGGATGGCGGCTAACGGCCGTCCGGCGATCGCTGGGGCGCAAGCCCGGGCGCGAAGCCGAGGAATAGGGCCACAGAGACGAGTCTGCGGCGAGGGCGGACGATGTTCGCACCGGTACGGCCACTCCGTACCGTTCGCACGGGCAACCGTGCGAGTCGCGGCAGGGTGAAACGCGGCAACCTCCATCCGGAGCAACACCAAATAGGCATGCGCGCGGCTTCGGCCGCAATAGGGCGGTCCGCCCGAGCATGCGGGTAGGTGGCTAGAGCCGTCCGGCAACGGCCGGCCCAGAGGAATGACTGCCCGCGGGCGACGCCCGTGTACAGAATCCGGCCTATCGATCTGCTTTGCCT
->URS0000D69D6E_12908/1-58 unclassified sequences RAGATH-30 RNA 
-GTAAAAATAAGATTTTGCCGAATATATTCATATAGATGAATCTGTTATGAAACAGAAA
->JH835302.1/8483619-8483740 Erinaceus europaeus unplaced genomic scaffold scaffold00014, whole genome shotgun sequence 
-AAGACAGAGAAATAGAGAACATTAAAAACTAATCTGTATTTTTTGTAACTGGCGATAGCAATGCCATATTACAAGCCTTAATGACATTGGGGTCTTTAAGGTCCCTGAAAGTGGCTATATGA
->URS0001A239EB_186490/1-52 Candidatus Baumannia cicadellinicola L31-Gammaproteobacteria ribosomal protein leader 
-CGUGUGGCUUAUAGUUAAAAUCGUCGAUAGCGACACAAUCUGACGAAUAGGU
->JH417673.1/4548-4310 Flavonifractor plautii ATCC 29863 genomic scaffold Scfld77, whole genome shotgun sequence. 
-TTAAACGCAATGAGGGAGAAGAGTACTGCGGGGACTCAGTCCCAGCGAGCGGGGGATGGTGAAAGCCCCGCACAGGAGGCCGCGGGAAGAACGCTCCGGAGCGGAAACCCGAACGCACCGCGCCAGTAGGGGGAACGGGCTGCGACCGTTACATCGCGCCGACTTGTCAGAGCCGGAAAAGGGGCCGCCGTCCGGCGGCAAATTAGGTGGCACCGCGGAGCGCAGCATTCGTCCTAATC
->MHBP01000260.1/25988-25933 Lentisphaerae bacterium RIFOXYB12_FULL_65_16 rifoxyb3_full_scaffold_468, whole genome shotgun sequence. 
-GGGTGTAACGGCACGGGGGTTCGTTACAGGCGCTCTGGGTGGTCGGGCCGCCATCC
->URS0000D65EAA_12908/1-173 unclassified sequences malK-I RNA 
-TCCAACCCCCGCGTCTTACTCCACCTATGTAATCCACGGGGGAAATAAAGAAGGAGGAAAGTTTTTCCGCCTGACCGGCGGTGCGGCAGTGTGGAGACCTGTCGTAAGGCAGCGTGGCGGCTGCGAGGCTCCGTTTCGCGGAGGCGGCGGGGCTACGGTCAAGCATTATGGCA
->CAJW010157214.1/4791-4634 Hordeum vulgare subsp. vulgare, WGS project CAJW01000000 data, contig: morex_contig_157214 
-AAGGAGAAGTGTGATAAGCTTTGAATGGAAGCCCCGGTAAACGGCGGCAGTAACTCTAACTGTCCTAAGGTAGCGAAATTCCTTGTCGCATAAGTAGCGACCTGCACGAATGGTGTAACGACTGCCCCGCTGTCTCCGACATGGACCCGGTGTCGTTT
->CH966573.1/1-1154 Drosophila willistoni strain TSC#14030-0811.24 scf2_1100000007260 genomic scaffold, whole genome shotgun sequence. 
-GAAGTATTTAGGTATCCGGTTCGCTGTGGATGGGCGGGCTCGGTATAGTCCAGCAGACGACCTCGGTCCGAAGCTGTTAAGATTAATAAGAGCCCCTCTGAAACCACAACAGAAGTTATTTGCACTTAGGACTGTCCTTATCCCACAACTCTATCACCAACTAACACTTGGGAATTTGATGATAGGCGTCCTAAGAAAATGTGACAGATTGGTACGGCAATTCGTAAGGAGATGGTTAGATCTCCCACTGGATGTACCAGTTGCGTACTTTCACGCCTTCCACACTTGTGGGGGTCTCGGGATTCCGTCAATTAGATGGATGGCACCGATGCTGCGTCTGACGCGATTGAGCATGATTAAATGGCCCCACCTCGAACAACCCGAGGTAGCTAGCTCTTACATTGACGACGAATTGCAAAGGGCTTGAGATAGATTAAAGGCGGAAAATGTGCAGTTGTGTTCGCGTCCAGGCAAACATTGCCAGGTAGGGATCGGCCTATCGATCCTTTTGGTTTAAAGAGTTTTTAACAAGAGGTGTCAGAAAAGTTACCATAGGGATAACTGGCTTGTGGCGGCCAAGCGTTCATAGCGACGTCGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAAAATTCACCAAGCGTTGGATTCTTCACCCATGCAAGGGAACGTAAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTAATGACAAAACGTTGTTGCGACAGCATTCCTGCGTAGTACGATAGGAACCGCAGGTACGGACCAATGGCACAATACTTGTTCGAGCGAACAGTGGTATGACGCTACGTCCGTTGGATTATGCCTGAACGCCTCTAAGGTCGTATCCGTGCTGGACTGCAATGATAAATAAGGGGCAATTTGCATTGTATGGCTTCTAAACCATTAAAAGTTTATTTTATAAACGACAATGGATGTGATGCCAATGTTATTTGTAACATAGTAAATTGGGAGGATCTTCGATCACCTGATGCCGCGCTAGTTACTTATTAAGACATTATTTAATACAATGACAAAGCCTAGAATCAATTGTAAACGACTTTTGTAACAGGCAAGTGTTGTAAGTGGTTGAGTAGCTGCCATACTGCGATCCACTGAAGCTTATCTT
->JXUM01182853.1/1550-1 Aedes albopictus isolate Foshan contig182853, whole genome shotgun sequence. 
-ACTGGAGAGTTCGTTATCTGCCGTAACCGGTCGCTGGTTCAAGTTCAACTAGAATGTGGCTTTTACTCCCAGAGAGGGTGATAGGCCCGTAGAGCGGAGCACCGATGGTAGAAGATCTTTCCATGGAGTCGTGTTGCTTGATAGTGCAGCACAAAGTGGGAGGTAAACTCCTTCTAAAGCTAAATATCACCACGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGTTGAAAAGCACTCTGAATAGAGAGTCAAAAAGTACGTGAAACTGCCTAGGGCTCAAGCCCGTTGAACTCGATTATCCGAGCGGAGACATTCACCTGCGGTTGGCCGGCGACGGCACGGCCGCAGGGCACTTGTCTCTCGCACTAGCCAAGAGGACACTGCGATCCATTACGAAACAGCTTTCGCGCCGCAAGGCGCAAGGTCGCCCGACAACTGCCCCTGGTGCTGGTTGCTTGCCCCACAGTAGCGACGCTCAGTTCTGAAGGCCTGTGCCGCGAGGTGGGGCTTACTGCACGTGGTGTTTTGCAGTCGGGCGCGTGATGGATTCCCCCGGACACCGGGTGGTCTTCCCGTAAGGGGCCACCGGACTGTCGATCGGCAGTGAAAGAATCGAGGTACCTTCGGGACCCGTCTTGAAACACGGACCAAGAAGTCTATCTTGCGCGCGAGCCAATGGTCGTCCTCCGGAGCACCAAAGGCGCAGAAAACATAACTTGAGTTGTGCGGGATTACGGGCGCGGCTCTCTGCTCGTCCCTCCATCCCCGGGTGTTGTAATCGGCATGCGGCTACCGGGACCCAGGCTTCACGGCCCCCGGCACCGTGCCACAACATACCGTGAGTGTGCAGGATGTGACCCGAAAGATGGTGAACTATGCCTGATCAGGTTGAAGTCAGGGGAAACCCTGATGGAGGACCGAAGCAGTTCTGACGTGCAAATCGATTGTCAGAATTGGGCATAGGGGCGAAAGACCAATCGAACCATCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGAGCACGCAACGTTTCGAATGCTATTCTTATCTGGTAAAGCGAATGATTAGAGGCCTTAGGTTCGAAATGATCTTAACCTATTCTCAAACTATAAATGGGTACGTACCATAGCATTCTTGCATGATGCTGTTGCAAACGTTGGTAAACGCCGGGCCGTCCCCTGTCAGGGCGTGCCACGGCGTAGAAGATATCTGTGTGCTTAGTGGGCCAAGTTTTGGTAAGCAGAACTGGTGCTGTGGGATGAACCAAACGTAATGTTACGGCGCCTAAATAAACGACGCATCATAGATACCATGAAAGGTGTTGATTGCTACAGACAGCAGGACGGTGGACATGGAAGTTGTCATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAAGCAATTAGCCCTTAAAATGGATGGCGCTTAAGTCGTTTGCCTATACATTACCGCTGGCGCACAAGTGGGGCAGCGCCCCTGTAGCGCGTCTGCCCTTTGAGGCGCCAGCGAGTAGGAGGGTCTGGTGGTGTGCGTTGA
->CP009227.1/527376-527281 Treponema sp. OMZ 838, complete genome. 
-GGCGGCATGGATGCCGCTCGTATTAAGCAGAAGCAAGTTTGACACCGGTCAAACTTGTGTTCAGCGAAGTACATGGATGTGCTTCGCTGAACGAGT
->FQVI01000001.1/71074-70885 Lactonifactor longoviformis DSM 17459 genome assembly, contig: EJ64DRAFT_scaffold00001.1 
-AAAAAGAATAAACGGTATGGTCTGTGCTCAGCAATGAGTCAGTTTACAGGGAATCCGGTGAGAATCCGGAACAGCCTTTCTCTACTGTGTGAGGGACGAAAGCAGCGTAAAACCACTGGAACTATCCGGGAAGGTGCTGCTGGTAGGAAGAACTCAAGTCAGGATATCTGGCATACTGCGTGAAAAAAGC
->MTEJ01000117.1/16469-16381 Thiothrix lacustris isolate A8 Ga0073116_1117, whole genome shotgun sequence. 
-ATCGGGTTAAATAAACGACTGACTAAACATGTAGTAGCCTTCAGATGGAGGGTTTGCGGACGCGGGTTCAATTCCCGCCGCCTCCACCA
->LJIY01000004.1/279997-280249 Psychrobacillus sp. FJAT-21963 super7, whole genome shotgun sequence. 
-ACATCAAATTTTGAAGGGACGATGGGTGGCCGATGAAGTTTTAATCTTATTTCTCAGTAGAAGTTTTTCTGCGATATATTTGCGCAGTAACAAAATAAAACTTTACGAAACCGGAAATAGGATTAGTCTGCCCATTTTTCAAAATTACTGCAAATAATTCTCTACAATACGCTAACGCTTTGTAGTGGTTTTTTGCATATTCATTTAATGGTCAGTATGTAATCCTACCGTTTAATATCGGAGGGATTTTTTT
->CP011058.1/4424379-4424646 Paenibacillus beijingensis strain DSM 24997, complete genome. 
-GCTATCGCTATGACGGGCACAAGTAGTACTGCGAACGACGCTTTCAGAGAACCGGTGGACGGTGCGAACCGGTACGCGGCGCAGCATGAATTACCGCCTTGAGCTGAACGGGGGAAAGCGGGCCGGTCCCACTGGGGGCAGTGTCCGGCCGGTAGCCCGTTTCCGGAAGCATCCGCTTCCGTTATCAATAATGAAGTGAGAGCCTAATCTGCCCCGGCAGCGGCTCTAACGAGGGTGGTACCGCGAGCAAATCCTTCTCGTCCCTTGA
->LL009840.1/12805-13384 Trichobilharzia regenti genome assembly, scaffold: TRE_scaffold0009840 
-CTCCTGGAAAAACCAATATCCAGCCAATGCTTGTGTCAGAGATTAAGTCGTGCATGTCTAAGTACATACCTTAAAACGGTGAAACAGCAAATCGCTGATTAAATCAGCTATGGTTGCTTAGACCACATATGCACTACATGGATAACTGTAGTAATTCTAGAGCTAATAAATGAAGTTATGCCCTGACCCGCAAATCAACAGAAAATTTATTAATACAGAACCAACCGCGGGTGGGGGGGGTAGTTTCGCCTGGATAGCTTTAATGTGATCGCGATCGGCCTTCCATTGGCGATGGATCTTATCGTAGAAGGAAACAACACAGAGATTCTGTTTCACCGATCAATTTAGAAGGTTAAACAACATTGGAATAAACACAGGAGTCAGACAATGGTGCTTATTATCACCAATTATACTTCATTCACTTACTTATCTAGGGAGCATTGTCTCAACTACAGGAAGTCGGAGAGGACGAGGATGTCAAATCGAGCTAGAATCGGGAAGGCAGGCGAGAAACATATTCATCAACCTGAAACAACCAATCTGGAAATATTCGTCACTCAGCCAGAATCAACAACAAAAT
->JRRC01447532.1/91-1 Gossypium arboreum cultivar AKA8401 contig_57480_1, whole genome shotgun sequence. 
-GCTGTCTACGAGTCGGTTTGTTTGGGAATGCAGCCCTAATCGGGCGGTAAATTCCGTCCAAGGCTAAATACGGGCGAGAGACCGATAGCGA
->GG692400.1/806114-806247 Candida tropicalis MYA-3404 genomic scaffold supercont3.6, whole genome shotgun sequence. 
-GCCCCCTTGGTGCAGCCGGTAGCATGAACGATTCCGGTTCGACTCCTGTTTCGAAGCTTTAAAATACTTTAAAGGTTTTTGAAAGGAGAATTGGAACTAGCGTTTGGTCGCGGGTTCAAGTCCCGCAGGGGGCT
->FOVK01000004.1/141686-141486 Proteiniclasticum ruminis strain ML2 genome assembly, contig: Ga0073291_104 
-ATATAAACGATGAAAAGAACCAGTATGGAAGTCCTGCCTTCATAGAGAGAGGGGATTGGTGAAAGCCCTCAAGGAAAGTTTCCAGAACCTGTCTTGGAGTTTCTCAACCATTTGAGCGGGGAAAGCCGTTATACTTTAGAGTGGATACGTTAGGAGAAGTATCAATAAGGGTGGTACCGCCGAAGAGATTTGGCCCCTTTT
->LAKY01000004.1/16245-16356 Clostridiales bacterium PH28_bin88 ph28_547, whole genome shotgun sequence. 
-TGATCCTTTAAGCCGGTCCCGCGAGGCCGGTAAGGAGCTACGGTCAGGGTATGCCCGTGTAGACGTGGGATATCAAGGCCTCCTTGCCGCTGGGACAAGGAGGCCTTTTGTT
->CM000878.1/138264228-138264130 Callithrix jacchus chromosome X, whole genome shotgun sequence 
-CTGCCTCGAAGTCTGNNNNNNNNNNGCAATGGCTGCAAACAGCAGCTTCCTTGGTAGTGTTCTTTGTATGGGTTGCTCTAAGGGACCTTGGAGACAGGC
->FAOM01307123.1/40010-39638 Triticum aestivum genome assembly, contig: Triticum_aestivum_CS42_TGACv1_scaffold_307123_4AS 
-TTTTGCAGTTTGCGAGAAAGTTGAAAGTAAAGGGAGAACAACATATAATGAGGTTAGTGCTTTATTAGTTTTTAGCTCAAAATTCCTGTTGTTATTTTTTCATCATTTGTGTGGGCTGCATGCGTTTTGCCATATATTAACCAGAAACCAGGCTGCAACTCGCCTGCATGAAGCAGGAATCGCTAGTAATCGCCGGTCAGCCATACGGCGGTGAATCCGTTCCCGGGCCTTGTACACACCGCCTGTCACACTATAGGAGCTGGCCATGTTTGAAGTCATTACCCTTAACCGTAAGGAGGGGGATGCCTAAGGCTAGGCTTGCGACTGGAGTGAAGTGGCCATAGTTTGATATGTGACCCTATTCCTTCGCATA
->JMFQ01059681.1/962-834 Aptenodytes forsteri contig59681, whole genome shotgun sequence. 
-TAGGCCCTGAATGAAGACCACCGGTTTGCTGTAGCCGTTGGTTTCAAGCAGGAGCCCAAAGGAAACGTCTCCCGGTCTGTGGGCGCTCCCATCCCTGTGGAACGGCCAATTCGTGTGGGAGCGACACTA
->LFJN01000024.1/399316-399149 Phialophora attae strain CBS 131958 Contig24, whole genome shotgun sequence. 
-GGTGAGATGGCCGAGTGGTTATGGCGCTAGTTTCAGGAATACCTGGAGCCTTCGCTTTCTGGTTGAAAGTACTAGTGGGTGTACGTAAAACCATCCTACAGTACCCTCAAGAGCACTACTGACAATTTCCTTTAGAAAACCGCGTGGGTTCGAGTCCCACTCTCATCA
->AFSB01069799.1/15973-16145 Heterocephalus glaber contig69799, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGTAATAGTAGCTGCCGTGATTCTGTTAATACAAGTTAGATTGTTTCTTTTCTCTGCTTAAAACCCTCCAATGGCTTCCCATGTCTCTTAGCAAAGCCAAAATTTCTCAAGACTTATGACGTGTGAGTGATTCTGAACCTCT
->GL378325.1/524376-524459 Volvox carteri f. nagariensis unplaced genomic scaffold VOLCAscaffold_4, whole genome shotgun sequence. 
-GAGGTGTGATGATTTGAAACTTTTGGTCCGTGTTTCTGAGTGCCTAGCGCACCTCTGACGACTACAGTTTCTTCGTCTGACCTC
->GG749280.1/539059-538827 Selenomonas noxia ATCC 43541 genomic scaffold SCAFFOLD3, whole genome shotgun sequence. 
-TCATATTGAATTGGATCAAGTGCAGGGGTTTTGACATCATCAAAGCCTCAATGCTTCATAGGGAATCCGGTATAGGAATCATTGATTTCATAAGCCGGAGCGGTCACGCCACTGTAACAGGGAGTGATTCCGCACGCCAATTGAGTTGGCAGTCACTGGAGAGCGATCTCTGGGAAGATGCGGAAGAACGATGAACTGGAGCCAGGAGACCTGCTTGATTAACAATCACCGAT
->GL988045.1/3052953-3052577 Chaetomium thermophilum var. thermophilum DSM 1495 unplaced genomic scaffold scf7180000011820, whole genome shotgun sequence. 
-TCCTCTTCAACGCTGCGTTTCTATGCCACAAACGGAGAGCGCTTGCGCAAGCAGCGCTTTCAAATCCATCTTTCTCTGGCATATGAGAAATTCGGAGAATCGGCTTCACTCTTGGTTTGTCCATTCCTCACTCTCGGGTGTTGGATGGGTTACGAGCTCTGCCGGTGACGGCTTGGCGCGAATTCGCGTCTGTAATTGGCATCAGAAAAGCAGGGCTTAGAGGCCAACCTTGTGCTTTTGCGAGGGGAATTGGTCATCTAGGTTCCTCTGGGAGGGCCGTTACGAAGCTTGTGAGCAATCACTTGAGTGCAATACGCAGCGTGTGGCCTGCCTTCTGGGCAGATCACACAATTCGATTCCGATTATCCTGTTGAGGA
->CM002820.1/173650899-173648878 Capsicum annuum cultivar Zunla-1 chromosome 9, whole genome shotgun sequence 
-AGGCTTACGGTGGATACCTAGGCACCTAGAGATGAGGAAAGGCATAGTAATCGATGAAATGCTTCGGGGAGTTGAAAATAAGCATAGATCCGGAGATTCTCGAATAGGGCAAACTTTCAAACTGCTGCTGAATCCATGCGCAGGCCAGAGACAACCTGGCGAACTGAAACATCTTAGTAGCCAGAGGAAAAGAAAGCAAAAATGATTCCCGTAGTAGCGGCGAGCGAAATGGGAGCAGCCTAAATCGTGAAAACGGGGTTGTGGGAGAGCAATACAAGAGTCGTGTTGCTAGGCGAAACAACCTGAATGCTGGCGAAAAACCAGTAGCCAAAAGCATTACTAGCTTACGCTCTGACCCGAGTAGCATGGGGCACGTAGAATCCCGTGTGAATCAGCAAGGACCACCTTGCAAGGCTAAATACTCCTGGGTGACCGATAGCGAAGTAGTACCGTGAGGGACGGGTGAAAAGAACCCCCATCGGGGAGTGAAATAGAACATGAAATCGTAAGCTCCCAAGCAGTGGGAGGAGCCAGGGCTCTGACCGCGTGCCTATTGAAGAATGAGCTGGCGACTCATAGGCAGTGGCTTAGTTAAGGGAACCCACCGGAGCCGTAGTGAAAGCGAGTCTTCATAGGGCAATTGTCACTGCTTATGGACCCAAACCTGGGTGATCTATCCATGACCAGGATGAAGCTTGGGTGAAACTAAGTAGAGGTCCGAACCGACTGATGTTGAAGAATCAGCGAATGAGTTGTGGTTAGGGGTGAAATGCCACTCGAACCCAGAGCTAGGTGGTTCTCCCCGAAATGCGTTGAGGCACAGCAGTTGACTGGACATCTAGGGGTAAAGCACTGTTTCGGTGTGGGCCACGAGAGCGGTACCAAATCGAGGCAAACTCTGAATACTAGGTATGGCCTTAAAATTAAAAAAGAGGGGTCAAAGTCGGCTAGTGAGACAATGGGGGATAAGCTTCATCATCGAGAAGAAAACAGCCCGGATCACCAGCTAAGGCCCCTAAATGGCCGCTCAGTGATAAAGGAGGTAGGGGTGCGGAGACAGCCAGGAGGTTTGCCTAGAAGCATCCACCCTTGAAAGAGTGCGTAATAGCTCACTGATCGAGCGCTCGTGCGCCGAAGATGAACGGGGCTAAGCGATCTGTCGAAGCTGTAGGGTGTAAAAATACATCGGTAGGGGAGCATTTCGCCTTAGAGGGAAGCCTCCGCATGAGCGGTGGTGGACAAAGCAGAAGCGAGAATGTCGGCTTGAGTAACGCAAACATTGGTGAGAATCCAGTGCCATGAAAACCTAAGGGTTCCTCCATAAGGTTCGTCCACGGAGGGTGAGTCAGGGCCTAAGATCAGGCCGAAAGGCGTAGTCGATGGACAACAGGTGAATAGTCCTGTACTACCCCTTGTTGGTCCCGAGGGACGGAGGAGGCTAGGTTAGCCAAAAGATGGTTATCGGTTCAAGAACGTAAGGTGTCCCTGCCCTTTTTTCAGGGTAAGAAGGGGAAGAGAAAATGCCTCGAGCCAATGTTCGAATACCAGGTGCTATGGCGCTGAAGTAACCCATGCCATACTCCCAGGAAAAGCTCGAACGGCTTTGAGCAAGAGGGTACCTGTACCCAAAACTGATACAGGTGGGTAGGTAGAGAATACCTAGGGGCGCGAGACAACTCTCTCTAAGGAACTCGGCAAAATAGCCCCGTAACTTCGGGAGAAGGGGTGCCTCTTCACATTACAAAGGGGGTCGCAGTGACCAGGCCCGGGCGACTGTTTACGAAAAACACATGTCTCTGCAAAGTCGTAAGACCATGTATAGGGTCTGACGCCTGCCCAGTGCCGGAAGGTCAAGGAAGTTGGTGACCTGATAACAGGGAAGCCGGCGACCGAAGCCCCGGTGAATGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCAGGTAAGTTTCGACCCGCACGAAAGGCGTAACAATCTGGGCACTGTCTCGGAGAAAGGCTCGGTAAAATAG
->URS0000D6A535_12908/1-73 unclassified sequences RAGATH-1 hammerhead ribozyme 
-AAGACAGUCUAGGAGUCUAUAAAAUUGUUACUGAAGAGACUAGAACGAAACUUCUUUAAUUAGAAGUCUAACA
->AYMY01S001259.1/103935-104737 Nicotiana tabacum cultivar TN90 Ntab-TN90_scaffold1259, whole genome shotgun sequence 
-ATTTCAAAATTTTGTAGCTTGTTTCGGGCAATAAAATGACTGGTACCATCCTAGTCAAATTAGAAAAACTTTTTGATGAAGGTGCCATTATAAGGCGGACCGGGCCCAAGTCCCCTGGAAGGGGGCGCCAGAGAGGGTGAGAGCCCCGTTGTGCCCGGACCCTGTCGCACCACGAGGCGCTGTCTACGAGTCGGGTTGTTTGGGAATGCAGCCCAAATCGGGCGGTGAATTCCGTCCAAGGCTAAATACGGGCGAGAGACCGATAGCGAACAAGTACCGCGAGGGAAAGATGAAAAGGACTTTGAAAAGAGAGTCAAAGAGTGCTTGAAATTGTCGGGAGGGAAGCGGATGGGGGCCGGCGATGCGCCCCGGTCGGATGTGGAACGGTGNTACCGCGAAGGAAAGATGAAAAGGACTTTGAAAAGAGAGTCAAAGAGTGCTTGAAATTGTCGGGAGGGAAGCGGATGGGGGCCGGCGATGCGCCCCGATCGGATGTGGAACGGTGTTGAACCGGTCCGCCGATCGACTCGGGGCATGGACCAGCGTGGATTGGGTAGACTTTTGATTTGGGTGAAGTTACTTGTTGATTGATAGAGCTTAGCTTCTTAATTAGCTTATTCCTAAGACATTTCCTTTTCGGACTTCTTAAATTCTAACTATGTTTAGTTGAATGTTCTAAAGCATACATAGAACAATTTGTTGCTAAGTAGAATAATCCCCTGCTTCACACTTTACCCACAATTCAGTTTGCATTCCATAGTAAAAGTACTATTTTGGGGTTCAAGAAAAAATTTGAAACCTTT
->CM000024.3/41982868-41983007 Canis lupus familiaris chromosome 24, whole genome shotgun sequence. 
-ATCGCTTCTCGGCCTTTTGGCTAAGATCAAGTGTAAATAAAAAAATACATTATTTTAAAAATCTGATATGAAATGATATTTATTGGGGCTTCTGGGCAAATCAATCACCCTTGTGCTAGAGTGTTAGGATATGTAGAGTG
->CM000400.2/42839630-42839710 Equus caballus chromosome 24, whole genome shotgun sequence. 
-TGGACCTCTCATGAACCCACCATGACGCCTGGTGGCAGATGTCATAGGTGATGAACATGTGTCTGGAACCCTGAGGTCCAA
->MNVL01000027.1/1734-2078 Candidatus Hydrogenedentes bacterium CG1_02_42_14 cg1_0.2_scaffold_12826_c, whole genome shotgun sequence. 
-GGGGGCGCAAGGTTTTGACGGCGACGGAATTGTCGAGGTGGCGCGCTGGGGCATGCTTAGTTGCCTCGTAAAAAATACTGAGCAACTTTTAACTGCCAACACTGAATTGGCTCTAGCCGCGTAAGCGGCAGACTGCATAGGCGACGCCCGCTGACTCTTGCAGTCCTCATAGCGGGCTGGCTTTCGGTTATGTACCGGGGATCGGGAGCGAGGAGAACACTCGGACTAGCGGAAAGGGAAGCCTGTCCATGGGCCATCTTTTTGCGAAATTAATACACGGACTACGCGCGTAGAAACCCGATGAAACAGTTGTTCGGACGTGGGTTCGATTCCCACCGCCTCCAA
->JRRC01272952.1/16470-12774 Gossypium arboreum cultivar AKA8401 contig_2968_9, whole genome shotgun sequence. 
-TCACTTACTTAAATACTTACTTACTTAATCAAATTTATTAATAAATTTTACTTACCTTTTTTTTTATCAAGCATACATGAACATTATATACTTACCTTTGCTCTTCTAGCATGAACTTGTCTTACCTTTTTAGTATAACTCGTCTTACCTTACCTTACCTTGATATTCTCTTTAAATTATTTCCCGTTGAACCACTTGGAATACTAAGGATACATGGGTACCTTACCATTGCCATGACTTGTCATGGTCTTACGTGGTGTCCTTTTGAAACTTACCATTGCCATGCCTTGGTATGGTCTTACATGGGACTTTTGCCTTATAGTAACTTATTAATGCCTTGTCTTGACATGGTCTTACATGGTATCCTTACCTTAGAAACCTTACCAATTGAGATGCCTTGGCATGGTCTTACATGGTATCCTTAAACCCTAATGTCATGACATTTGTATCCTACACATTCCTAAGGTTCAACCAGGACTTTCTGAAATTACTTCTCCGTCAATTCATGCTTAAGTCTTCTTCGAATAATTTCATAAAATAAATATACACATGCTGGAAATTAGCAAAATTAACATAAAATAATAGAATATTGCATTTATTTACCGCAAACTTACCTCGAAACAAAATACGATCAATTATATCGATTTAGTCCACTATCTTTTTCTTTCCCCGATCTAACTCCGAATTTTTTTCTTCTTGATCTATAATAACAAATTTAGCTTATTTAATACTCACATTTATTAAAACAGTCATTGACTCAAACTTTGGCAAAATTACACTTTTACCCTAAACTTTTACATATTTATACTTTTTTCCTAAGGCTCGGAAATTAAACTTCATCCTATTTTCTTATGTTTTATGACATTCTAATCATTTTTCCCTTCTATGGAAACATAAAATTCTCACTCTAACATGTAGTTATGAACATTAGGTATTTTTACCGATTATGTCGTTTTACTCGTTTTCACATAAAATCGCTTAGCAAAAGTTGTTTAACATAATTTCGAGCTTCATATTCTACCATAAAATATCAAAATAAACACATTTCACCTATGGGTAGTTTTCCAAATATAAACCCTAGGTTAAATTATTGCTAGAATAAGCTTAATCAAGTTATCGGGACCCTAAAAACGTAAAGAACATTAAAAACGGGGCTTAGAATCACTTACTATAGAGCTTGGAATCTTGAAACAAATCCTAGCTACGGGGAACCCTTGAAGATGAGCACATTTTTGCCATTTTTTCCCTTTTTAATTCTTTTATTTGACACTTTACTAAAATGCCCTTTATTAAAATTTTTTAGTTATTTTTACCTATGTATATCCATTTTTGTCCATGAAAATATAATGGTCTAATTCCATTTAAGGACCTCTACTTCAATTATGCAATGACCAGGATGAAGCTTGGGTGAAACTAAGTGGAGGTCCGAACCGACTGATGTTGAAGAATCAGCGGATGAGTTGTGGTTAGGGGTGAAATGCCACTCGAACCCAGAGCTAGCTGGTTCTCCCCGAAATGCGTTGAGGCGCAGCAGTTGACTGGACATCTAGGGGTAAAGCACTGTTTCGGTGCGGGCCGCGAGAGCGGTACCAAATCGAGGCAAACTCTGAATACTAGATATGACCTCAAAATAACAGGGGTCGAGGTCGGCCAGTGAGACGATGGGGGATAAGCTTCATCGTCGAGAGGGAAACAGCCCGGATCACCAGCTAAGGCCCCTAAATGACCGCTCAGTGATAAAGGAGGTAGGGGTGCAGAGACAGCCAGGAGGTTTGCCTAGAAGCAGCCACCCTTGAAAGAGTGCGTAATAGCTCACTGATCGAGCGCTCTTGCGCCGAAGATGAACGGGGCTAAGCGATCTGCCGAGGCTGTGGGATGTAAAAATGCATCGGTAGGGGAGCGTTCCGCCTTAGGGGGAAGCACCCGCGTGAGCGGGAGTAGACGAAGCGGAAGCGAGAATGTCGGCTTGAGTAACGCAAACATTGGTGAGAATCCAATGCCCCGAAAACCCAAGGGTTCCTCCGCAAGGTTCGTCCACGGAGGGTGAGTCAGGGCCTAAGATCAGGCCGAAAGGCGTAGTCGATGGACAACAGGTGAATATTCCTGTACTACCCCTTGTTGGTCCCGAGGGACGGAGGAGGCTAGGTTAGCCGAAAGATGGTTATCGGTTCAAGGACGCAAGGTGCCCCTGCTTTTTCAGGGTAAGAAGGGGTAGAGAAAATGCCCCGAGCCAATGTTCGAGTACCAGGCGCTACGGCGCTGAAGTAACCCATGCTATACTCCCAGGAAAAGCTCGAACGACCTTCAACAAAAGGGTACCTGTACCCGAAACCGACACAGGTGGGTAGGTAGAGAATACCTAGGGGCGCGAGACAACTCTCTCTAAGGAACTCGGCAAAATAGCCCCGTAACTTCGGGAGAAGGGGTGCCTCCTCACAAAGGGGGTCGCAGTGACCAGGCCCGGGCGACTGTTTACCAAAAACACAGGTCTCCGCAAAGTCGTAAGACCATGTATGGGGGCTGACGCCTGCCCAGTGCCGGAAGGTCAAGGAAGTTGGTGACCTGATGACAGGGGAGCCGGCGACCGAAGCCCCGGTGAACGGCGGCCGTAACTATAAGGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCCGCACGAAAGGCGTAACGATCTGGGCACTGTCTCGGAGAGAGGCTCGGTGAAATAGACATGTCTGTGAAGATGCGGACTACCCGCACCTGGACAGAAAGACCCTATGAAGCTTCACTGTTCCCTGGGATTGGCTTTGGGCTTTTCCTGCGCAGCTTAGGTGGAAGGCGAAGAAGGCCTCCTTCCGGGGGGGCCCGAGCCATCAGTGAGATACCACTCTGGAAGAGCTAGAATTCTAACCTTGTGTCAGGACCTACGGGCCAAGGGACAGTCTCAGGTAGACAGTTTCTATGGGGCGTAGGCCTCCCAAAAGGTAACGGAGGCGTGCAAAGGTTTCCTCGGGCCGGACGGAGATTGGCCCTCGAGTGCAAAGGCAGAAGGGAGCTTGACTGCAAGACCCACCCGTCGAGCAGGGACGAAAGTCGGCCTTAGTGATCCGACGGTGCCGAGTGGAAGGGCCGTCGCTCAACGGATAAAAGTTACTCTAGGGATAACAGGCTGATCTTCCCCAAGAGCTCACATCGACGGGAAGGTTTGGCACCTCGATGTCGGCTCTTCGCCACCTGGGGCTGTAGTATGTTCCAAGGGTTGGGCTGTTCGCCCATTAAAGCGGTACGTGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCCATATCCGGTGTGGGCGTTAGAGCATTGAGAGGACCTTTCCCTAGTACGAGAGGACCGGGAAGGACGCACCTCTGGTGTACCAGTTATCGTGCCCACGGTAAACGCTGGGTAGCCAAGTGCGGAGCGGATAACTGCTGAAAGCATCTAAGTAGTAAGCCCACCCCAAGATGAGTGCTCTCCTATTCCGACTTCCCCAGAGCCTCCGGTAGCACAGCCGAGACGGCAAGGGGTTCTCTGTCCCTGCGGGGATCGAGTGACAGAAGTTTTGAGAATTCAAGAGAAGGTCACGGCGAGACGAGCCGTTTATCATTACGATAGGTGTCAAGTGGAAGTGCAGTGATGTATGCAGCTGAGGCATCCTAACAGACCGGTAGACTTGAACCT
->JPUW01000003.1/58274-58063 Lysinibacillus sp. BF-4 contig00003, whole genome shotgun sequence. 
-AACGATGCAATGATAAGGAAGAGTAAAAAGTACGCGTAGGCAAGAGAGGGAACGGTAGCTGAGAAGTTTCTACTAAAGCGCTTTTGAAGGTAGCCTTGGAGCAACATTTGTGAACAACAGTAGCAAATGTCGGCAGCTAAGCCGTTATGTATTGAGTGCTAAGCTTCGGCTTGGAATAAAGGTGGTACCGCGAAAGCTCCTTCGTCCTTTTT
->ABWE02002692.1/6421-6661 Hyaloperonospora arabidopsidis Emoy2 Contig279.1, whole genome shotgun sequence. 
-TTTAAAAAATGAAAGAATCTAACTCTAGTACGAGAGGACCGAGAAGGGTAAATCTCTGGTGTATCGGTTGTTGAAAAGCATCGCCGAGTAGCTAAATTTATTTTGGATAATTACTGAAAGCATCTAAGTAAGAAACCATTCTTAAATTTTTTTTATATAAAAACTGTAAAAGATCATTACATTGATAGGTTTAAAGTGTACGTATTGTAAAATATTTAGCTTAAAAATACTAAAAGTTTAA
->CM000842.2/19036600-19036948 Glycine max cultivar Williams 82 chromosome 9, whole genome shotgun sequence. 
-GCTTGTGGTTTAATTTTACTTAACATGAGAAAACTTACCAGATCTAAACATAGTATGATTGACAGAATAAGAACTCTTTCTTGATTTTATGGGTGTTGTTACATGACCATTTTTAGTTGGTGGAGTGACTTGTCTAATTAATTTTGTTAACAATGAGAACTCAGTTTGCTTAAAAATGTTTTTGTTGAATAATTGTTCTTAAAAATGTTATGATTCAAGACAAATTCAGATTTAATTTAGAAGTAAATAGTAACTAAATGTTAAACCAGAAAACAAAAGGAATGCATTCAGCAAAATAAAAATTAATGCAAACAGAATGGGCCTCAAATTTTTTAGGTTACATGAGGAC
->MNRE01000021.1/40-1 Clostridiales bacterium 41_21_two_genomes Ley3_66761_scaffold_14658, whole genome shotgun sequence. 
-GGATCACTCCATTTGGGGTTAAGGCCATACGGACAGCCGG
->KI927239.1/392135-395996 Plasmodium falciparum Palo Alto/Uganda unplaced genomic scaffold supercont1.2, whole genome shotgun sequence. 
-GAGGATAAAAATAGGAGGGCAAATCCGCTGAACTTAAGCATATAATTAAGCGGAAGAAAAGAAAATAACTATGATTCCTTTAGTAACGGCGAGTGAAGAAGGAATAGCTCAATAAGTAGAATCCTTCGAATCTTAATGATATATTTATACATAGAATAAAGAATTGAAGGAATTGTCAAGTTGAATTGTACTCTTGTAGGCCTCACAGGTGAAATGAATATATAGAAGTAAAGTAGGAATACTTCCTCATAGAGGGTGAAAGGCCCGTATCATATATCATTTCGTGGGCTTTGGAGTATTTATATTTTACTGAGTAGTGTTCTTTGAGATTGGAGCACAAATTGGTGTGATACATTTCACATAAAGCTAAATATGTGTAGGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGATGAAATAGTACTCAGGAATGAGCAATTAAATAGTACCTGAAATCGTTAAGATGGAACGGATTAAGAGAGAAAACAAGTAAAGAGGAGAATTTTTTACATTTTTATTTTTGTTTTATAATTCTCTTCTTTATTAAAAGAAACATCAGTGATTAATTTAATTTCAATAAAGCAATCCCCTGAAATTCAAAATTTCTTTTAATTTTGTTTTCACTTTCTCCCCGCACTAATGTGGGGAAAACTGGCTTTATTTCTTCAATTATTTTTTTTGCTGAGGAATTTTAAAATTATTTGAATTTTTCTTCTTATAATTTAAGTTGTTTCTATATAGTACTTTCTTAACCCACTCGTCTTGAAACACGGACCAAGGAGTCTAGCAAATGTGCAAGTGTATATGATTCTTTAAACATTTCTCTTTTTAATATACGCATAATTAATGTAATATGTTTCTTTATTGTAGATTTGTGGTGTTTAATTTTTATTAAATCCCCACTTTGCATACAATACCGGTAAGCAATTATGCTTTATTGAGTACGAGCATATTTGGTAGGACCCGAGAGGCTTTGAACTAAGCGTGATGAGATTGAAGTCAGNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNTATTCGCTCATGAGATCCCATAAAAGGTGTTGGTTCATAATGACAGTAGGACGATGGTCATGGAAGTCGAAATTCGCTTAGGAGTGTGTAACAACTCACCTACCGAATGAACTAGCCCTGAAAATGGATGGCGCTAAAGCGAATTACCGATACCGGGCCATAAGAAGGTAGAAATTATAAATGTTAATTTAGCTCAGATCTTTTTATGAGTAGAAAATCGTGGGGTTTGTGTTGAAGCGAAATACGTGAGTTTTCGTGGAACATCTCCCTAGTGCAGATCTTGGTGGAAGTAGCAACTATTCAAATGAGAACTTTGAAGACTGAAGTGGAGAAGGGTTTCTTGTCAACTGTGATTGAACAAGAGTTAGCCGCTCCTAAGGGATAGCTGAAAAGTGTTTAAAAGAAGTAAGATATTATATGGAAATATATAATTAGATCTTCGTCTCAAAAGGGAAACAGGTTAATATTCCTGTGCCATAAGTAATAAGAGTGCAAACAGAGATGGTAACATACATATAAATGAACTCCTTAACATAGATTTTACTCATGGGGTGCGTTATCTTTGCACTTTAATTTTATAACAAACCTTGGAATCAATTTATTTGGAGAAGAGGTTCGTTGAACTCAATTCAAAAAAAAAAAAAAAAAAAAAAATTAATTATAGAAGGAAAGGATTTTCGGATCCTTTGTACTTTTTTTTTTTTTTTTTTTTTTTTTTTATGTTTTGTAGCAATAGTAATTCATTTCTTTTGAATTATCCATAGTGGTAAAAACTATCCATGAAACAAGGAGGGAACAGCAGCAATTATATAATTTTTGGGGTTCTTTGAATTCCTTATTATTTTTGCAATATTCTTAATACTTGTACGAGCGTACCAATAACCGCATCAGGTCTCCAAGGTTAGTAGCCTCTGGTTAAATAGAAAAAAGTAAGTAAGGGAAGTCGGCAAAATAGATCCGTAACTTCGGGAAAAGGATTGGCTCTGAGGACATTAGAAAAGAGAAGAAAAAAAGAGGGTTGAGAATAAAATTGCAGATTTATTTGCTTTTCTCTCTGATTTGCTTGTAAATTTTCTTTTTCTTTTTCTTCTTTTCTTTTTTTTTCTGTCCCTCTTTTCGTCTTCATTTTATTGTAATTTTTGTTACTTTAATTTGATACATATATAATGTTAACTCAGAACTGAAACGGACAAGGGGAATCCGACTGTTTAATTAAAACATAGCATTGTGAAAAACCATAACTGGTATTAACACAATGTGATTTCTGCCCAGTGCTTTGAATGTCAAATTGATGAAATTTAATTAAGCGCAGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTACTTGCTATCTAGCGAAACCACAGCCAAGGGAACGGGCTTGGCAAAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTTACTCTAGTCTGACTTTGTAAAACGACTTAAAAGGTGTAGATATAAGTGGGAGTAGGAAAATGAAATACGTTTTTTACAATAGTGAAATACCACTACTTTTAAAGTTGTTTTACTAATCCATTGATAGGGATATATAAAACTTATAAATAATTTTTATTTTAAGTTACTTTTGAATTTAAGATATGTGTGCATTTATATCTATTAAATCCCATTTTGTATATATATATATATATTATATATATGTGTATAATACGATTTTTTTTATGGAGACATAGTTAGGTGGGGAGTTTGACTGGGGCGGTACATCTGTTAAAAAATAACGCAGATGTCCAAAGACAAGCTCAAAGAGAACAGAAATCTCTTGTAGACTAAAAGGGGAAAAGCTTGTTTGATTTTTACTTTCAGAATGAGTAGAAAACGTGAAAGCGTGGCCTATCGATCCTTTATATTTGCAAAATGACGTAATAAATTACTTACTACTGTGCATATAGAGGTGTCTGAAAAGTTACCACAGGGATAACTGGCTTGTGGCTGCCAAGCGCTCTTAGCGACGTAGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGGGACGCAGAAGTCTCAAAGTGTCGGATTGTTCACCCGCTAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGAATAATATTATTATATTTTTTATATACAATATATAGTATTGTGACAGTAATCCAACTTGGTACGAGAGGATTAGTTGGTTCAGACAATTGGTACAGCAATTGGTTGATAAACCAGTGTTGCGAAGCTAAGTCTGTTGGATAATGGCTGAACGCCTCTTAAGCCAGAACCCATGCTGATTAGACAATTCTAAATTTGATCTTTTTGTTAAACGATAAAAATTATATATATATTTTTTTTATCTTTACTGCATAATGTAAAAGAGAAATTATACATATATATATATATATATATTAGAAAAGAAAAAATGATGTAATTAATTATTATTATTATTTTTTTTTTTTTTAGTATTAATATATAATTATGAATATATAAATAATCCTATATCTTTATATAAAAATTAAATTTTTAATTTTATTAGAATTTTTTTTTTTTATATATATAGATTGTAATTTAACAACAAAAAGTATTAAGCCCAAATCGTAGACGACTTTTCTGTCTCAGAGTACTGTAAACATGAGAGTAAACTTTGTTTTACGATCTGTTGAGGTTTATCTCTTGTGACATTGAGCTAA
->KI925462.1/351230-352057 Heterobasidion irregulare TC 32-1 unplaced genomic scaffold scaffold_09, whole genome shotgun sequence. 
-ACAGATCCAAGGCCACAATGCTCGTCCCGCACAGGACGTCTGAACGACAGTTCTGGCTTCCATCTTTGCGAGCGGGCTAAGGTCTGAGTGTATAGCTCCCTCGATCGACTCTCGCAGGGTCCGAGTCTAACGGCTCGAGCAACATACAAGAAATCCGTCTGCTTCACCTTGTCCGAAGACACGCTATCTGTTTCTCTAGATTCGGCGGCGTCGAGGGTGGTGAATGTAGGCTTGAGATATGTTGCGGAGTTTGGGCAGTACGTTTTGTCTCATCTATCCTCCGAGTCGTGGGTCGGAGTGCCCTCGATGCCCTATCGCACCTTTCGTCTGTGTCAGACGATCAGACATCAGGCAGTGTCTGAAGTGTTGTCAACTCGCTTCATTGCGACACAGACAGGAGTATATGACTCTGGGAGCACACCACTCCGATCAGAGCCTCCGGGAGAACACCACTCCAGTCTGATTAGGGAACACCCTTCTCCAAGTCGAACCTCTTTCCTGGACGAATGTTAGCCCTTCAGTCATGATCCGTGGCGAGAAGCGGGGGTCATAACTCACACCTGCCGCCTTTACCCAACGAGATCAGAAGACATAACCTGTCGCTGTTGTGGCTAATACAGGAAAGAGTGTCTGCCAAACCCTGGTGGGACGTGGACCTTGTCCAGTTGCGTTTCGATGGTCATGAGTTGATGACACTGGTGTATGAGGGGTTGGGAGTTTGTGAGGTGCACATCGGTACTGTCCTTCAGTGCAATTTGTGGCTCGCGCCTTTCGTTCTCCTTCTGGAAACGAAGGCGTGAAACTCGATTCAGACTACTCTGGGTCTGT
->ALWZ046142499.1/4049-4180 Picea glauca, whole genome shotgun sequence. 
-GGTTCCTTGGTCTAGTGTTCAGGACATTGGACTCTAAATCCATTTTTGAATGTTGTGTACAAATCCATGGTCTAGTGTACATGACATTGGAATCTGAATCCAATAGCTTGAGTTGTAATCTCGATGGGACCT
->LATL02000069.1/39931-40100 Limnoraphis robusta CS-951 contig069, whole genome shotgun sequence. 
-GTCAAGAACTCGCCGCTAAACCCTATGCGCTTTTCGCGCAGCAGGCTTCGCCAACGGGTTAAGCGCGGGAGCTTGTAAAAAGGCTCTAACTTGACCAGACTCAGCCCTTTTTGGGGCTACGTTATTTGGCTCACGAAACCCATGAATGCGTGCCAGTTTGCGGCTCTTTC
->CM003279.1/134475214-134476476 Salmo salar isolate Sally breed double haploid chromosome ssa01, whole genome shotgun sequence. 
-AACTCTTATGATTCAGAGTGGTTGGGTTAAATGTGGAAGACACATTTCAGTTGAAGGCATTGTTGTACAACTGACTTGGTATCCCCCTTTCCCTTGTAAGGAGAGACGATGATCCCTCTCATTTGCAAAGAGTTGGGATATGATAATATTCATAAATGGGGAATCAGGGTTCGATTCCAGAGAGGAAGCCTGAGATGCACCTACCACATCCAAGGAGGGCAGCTGGCACGCAAATTACCCACTGCTGACTCAAGGAGGTAGTGATGAGAAATAACAATACAGGACTCTTTAGACGCCCCGTAATTGAAATAGGTACTCTTGAAATCCTTTAATGAGGATCCATTGGTGGGCCAATCTGATGCCAGCAGCTGCGGTAATTCAACCTCCAATAGTGCATCTTAAAGTTGCTGCAGTTAAAAAGCCAGTAGTTGGATCTCGGGTATAAGCTGACGGTCTGCCGCAAGTTGAGCTACGGCCTTTCTCAGCCCCGGTACGCTTAACTGACTGTCCCTTGGGGTCTTAAAAAGTGTTCAAAGCAGTCTGTCGCCTGAATACCGCAGCTAGGAATAATGGAGAAAGACTCTGGTTCTATTTTGTTATTGTTTTCTTCTGAACTGGGCCAATGGTTAAGAGGGACTGCCGGGGGCATACATATTGTGCCGCCTGAGGTGAAATTCTTGGACTGGCGCAAGAATGTTTTCATTAATCAAGAATGAAAGTCGGAGGTTTAAAGACTTTCAGATACCGCTGTAGTTACGACCATAAGCGATGACAACTAGCGATCCGGCGGCTTTATTCCCATGACCCGCCGGGCAGCGTCCGGGAAACCAGATTCTGGGTTCCAGGGGGGAGTATTGTTGCAATGCTGAAACTTACAGGAATTGACGGAAGAGCACCAGCAGGAGTGGAGCCTCCGGCTTAATTTGACTCAGGAAACCTCGCCCGTACATGAAAAGATTTGACAGCTCTTTCTCGATTCTGTGGGTGGTGGTGCATGACCGTTCTTAGTTGGTGGAGTGATTTGTTTTGTTAATTCCAATTACGGACATGACAACTAATAAACTTTAAACTAGTTATGCGGCCAGAGCGGTCGGCGTCCAACTTCTTTGGGGGACAAGTAGTGTTCAGCCACACGAGATTGAGCAATAACAGGTCTGTGATGCCTGGGGCTGCACGCGCGCCACACTGAGCCGGTTGGCGTGTCTACCCTTCGCCGAGAGGCGTGGATTGGTTTCCGTAGGTGAACCTGTGGAAGGATCATTA
->HE978326.1/163659-163887 Kazachstania naganishii CBS 8797 chromosome 13, complete genome 
-ATCCCCCGTGCCTCGCTCGGCCAGCTGCGTGTCTTCAGGGACACTTTGATCTGCTGGTCTTGAGCTGGACGTGTTTCCCCTCGCGGGAAGCTGGTGGGGGGATACTGAACTTCAGTGACGACTTTTTGAGTACAAGGGCGCCCGGGATACTTCGTATCCCGCACAATGGTGTCTTCAAGATTTAATACTTCATTTTAAATTGTATTGTAATTAGTACGTTCATACATGT
->LCMH01000002.1/67321-67516 Microgenomates (Amesbacteria) bacterium GW2011_GWC1_46_24 UX46_C0002, whole genome shotgun sequence. 
-ACGGAAGGCTAGTAGTATGGGCCCCGCCGGTAGTAATACCGGTGCGCAAACTTGGCTATATCGGTGGACATCCTGAGCTTGTCGAAGGACAATACCGAGGCAACCTCGAAAGAGAGAGTCCGTAGAGACTACACGCCAAGCACCCCGACGTTATGTCGGGGTGATGATATAGTCCGACTCCCCGAGTAATCGGGGT
->GL636099.1/5798-5944 Serratia symbiotica str. Tucson genomic scaffold scaffold00192, whole genome shotgun sequence. 
-TAACAAAAAAATACCGAATACGATTCCTATATTCGGTCTAGGGAAATGGCTCCTAGGAGAGCCATGCGCTAAAAGTTAGCGTTTAGTGCATAATTTATCCAGTCATACTGCACTAAGCGTAGCCTATCACACTATTTTTGCCAGCTA
->JH711579.1/1959477-1959901 Coniophora puteana RWD-64-598 SS2 unplaced genomic scaffold CONPUscaffold_7, whole genome shotgun sequence. 
-ACGTCGTCTGAAGAATCGCCATCGCAGCACACGCACAAGAAACGTCCTCATACGATGCTTTCTACCCTACGCTGTGGGAAAAGTCCCCGGAGACACAGAGTCCCCCTCGTGGGGCCGGCCCCCGTTCGCTAACGGAAAGCCCTGGCTGCAACCACGCCGAGGAAGGGCGGGGGATCGGTCGGGCGAGTTCACCCTGCTTGCTTCTCTATTCCTCTCGGATGGGAATGCAAGCTCGGCTCGCCCAGCTCTGTTGCGCTGCCCGACGTCCCGCGGTCTATCGCGAAGACACGAGCCTTGGCCGCGCTTTTGTGGGCGGAGGGCGCGCACGTCGTTGCTCATAGACATAGTTATGCGATTGTCGGCTTTCGCGGTTCATTCTTGTGGATCGCGGCCGTCATCTCAATGGGGCTTACTCTCATTCGACG
->ABLE03011845.1/1131-1 Caenorhabditis japonica strain DF5081 Contig9535.1, whole genome shotgun sequence. 
-TACCTGATTGATTCTGTCAGCGCGATATGCTCAAGTAAAAGATTAAGCCATGCATGCTTTGATTCATAAATGAAATTGCGTACGGCTCATTAGAGCAGATATCACCTTTCTCGGAATCCTGAAAAGGATAACTGCGGAAATTCTGGAGCTAATACATGCGACTATACTCCAACGCAAGGCGGGGTGCAATTATTAGAACAGACCAAACGTTTTCGGACGTTGTTTGTTGACTCTGAATACCGTCGTTTACTGTCAGTTTCGACTGACTCTATCCGAGAAGGGTGTCTGCCCTTTCAACTAGATGGTAATCTATTGGACTACCATGGTTGTTACGGGTAACGGAGAATTAGGGTTCGACTCCGGAGAGGGAGCCTTAGAAACGGCTACCACGTCCAAGGAAGGCAGCAGGCGCGAAACTTATCCACTGTTGAGTATGAGATAGTGACTAAAAATATAAAGACTCATCCTTTTGGATGAGTTATTTCAATGAGTTAAATATAAATTATTCTTCGAGTAGCAAGGAGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCTCCTAGTGTATCTCGTTATTGCTGCGGTTAAAAAGCTCGTAGTTGGATCTAGGTTACGTGCCGCAGTTCGCAATTTGCGTTAACTGTGGTCGTGACTTCTAATTTGCTGGTTTGAGGTTGGGTTCGCCCTTCAACTGCCAGCAGGTTTACCTTGAATAAATCAGAGTGCTCAATACAGGCGCTTGCTTGAATAGCTCATCATGGAATAATGAAACAGGACTTCGGTTCTTTTTGTTGGTTCTAGAATTGATCTAATGGTTAAGAGGGACAAACCGGGGGCATTCGTATCATTACGCGAGAGGTGAAATTCGTGGACCGTAGTGAGACGCCCAATAGCGAAAGCATTTGCCAAGAATGTCTTCATTAATCAAGAACGAAAGTCAGAGGTTCGAAGGCGATTAGATACCGCCCTAGTTCTGACCGTAAACGATGCCATCTCGCGATTCGGAGGGTTCATGCCCTACCGAGGAGCTACCCGGAAACGAAAGTCTTTCGGTTCCGGGGGTAGTATGGTTGCAAAGCTGAAACTTAAAGAAATTGACGGAAGGGCACCACAAGGCGTGGAGC
->MELN01000046.1/18551-19023 Actinobacteria bacterium RBG_16_64_13 RBG_16_scaffold_3124, whole genome shotgun sequence. 
-GCAGCTCGGGTAGCCGCAGGGGCTCACCAACCGTGAGTTCTTGAGGAAAGTCCGGACACCATAGAGCAGGGTGCTGGATAACGTCCAGCGGGGGAAACCCCAGGGAAAGCGCCACAGAAATTACACAGCACGCCGGCGCAGCCGGTTGCAAAGGTGAAATGGTGCGGCAAGAGCGCACCGGCGTCGTGGTGACACGGCGGCCAGGCAAGCCCCACCCGGTGCAAGGCCGAATAGAGAGGCGTCTGAGGGCTGCTCGCCCGAAGCCTCCGGGTTGGCCGCATGAGCCGTCCGGCAACGGCCGGCCATAGATAGATGGCTACCCAAGAGGCTGCTGGGGAATGAGGCTCGCCGCCAGGGTGCGATTGGCATGCGCGAGAGAAGGACGCACTATCGGGCCGCCTAGTGCGGTCCGGCGGCCGGGGCCTTATTTCCCAGCAGCCTCAGGACAGAATCCGGCTTACAGGGCTGCTACC
->CP009284.1/1108194-1108485 Paenibacillus sp. FSL R7-0331, complete genome. 
-TCACACGCAATGAACGGGAGCAGTAGATGATGAAGGTGTGCAGAGAGCTGCGGGCTGGTGCAACGCAGTCACCTGATAGGCATTGAATCTCGCCCGGGAGCGGAGCGGCGGAAACAGGAAGTACGCCGCAACGGAAGTCCCCGTTACCGGACATCTGTATTTGCCGGACTATACCCGTATGGGGATGAGCCGGATACGGGGTGAGCTGGGCGCAGCTTGCGGTTTATCAGGAAGGTAAGCCGGATGCGTCAACAAGAGTGGTACCGCGGTGGGGTGACCCGCCGTCTCTTAT
->KE695927.1/3217556-3217637 Alligator sinensis unplaced genomic scaffold scaffold391_1, whole genome shotgun sequence 
-GCATGGAGCTGGCTGCTCCAGGGAGCAGGTGGGAGCTGGATTCCCAGCCTCTGTCTGCTCCCTGGAGCAGCCAGCTCTGACT
->KQ414443.1/2085-2243 Termitomyces sp. J132 unplaced genomic scaffold C252961, whole genome shotgun sequence. 
-ACACTGATGGTGAAGTGGTTATCATGCTTGCCTTCCATTGCATAGAAGCTATTGCATCTGTCTGAAGCAAGCGGCAGGGGTTCTGCTTGCCTTCCATTGCATAGAAGATATTGCATCTGTCTGAAGCAAGCGGCAGGGGTTCGATTCCCCTTCAGTGTA
->FJ872372.1/9644-12466 Uncultured Verrucomicrobia bacterium clone 106 genomic sequence. 
-ATTCAAGCAAACAGATGGCACATGATGGATGCCTTGGCGTTGATAGGCGATAACGGACGCGACAAGCTGCGATAAGCCATGGATAGCGGCAAATACGCTTTAACACATGGATCTCCTATGGGGTAACCCGAGGGCTCAGCCCTCATCCTGCCTTTTACAGGCAGTGAAGCGACACTCGGTGAAGTGAAACATCTCAGTAACCGAAGGAAAAGAAAGCGAAAGCGATCCTGTGTGTAGCGGCGAGCGAAAGCAGGACAGCCCAAACCGGCGTTAAACCCGGGGTTGTAGGACCAGGCATAAGCGATGTGATCAGGTTGGTTCAAAAGGCTGGAAAGCCTTCCGATACCGGGTGAAAGGCCCTTAAACCGACTCGGCCCACATTGCGCCTGGCTCCTGAGTAACGCGACATAAGTGAAACTTCGCGTGAATCAGCGCGGACCACCGCGTAAGGCTAAATACTCATCAACGACCGATAGTGAACAAGTACCGCGAGGGAAAGGTGAAAAGAACCGCTACAAGCGGAGTGAAATAGATCCTGAAATCATGTGTCTACAAGGTGTCAAAGCCCTTCGGGGCGATGGCGTGCCTTTTGCTTAATGAGTCTGCGAGTTATCTTCAGTGGCCAGCCTAATGTCATTTGACAGGAGGCCCAGCGAAAGCGTGTCCGAAATGGGCGTCAATAAGTCGCTGGAGATAGACCCGAAGCGGAGGTGATCTACCCATGGTCAGGATGAAGCGCGGGTAAAACCGCGTGAAGGTCCGAACTGGTGGACGTTGAAAAGTCCTCAGATGAACTGTGGGTAGGAGCGAAAGACTAATCAAACCCCGTGATAGCTGGTTCTCCCCGAAATAGCTTGAGGGCTAGCCTCTTGTTCCTCCTTCCGGAGGTAGAGCACTGGATGAACTAGAGCCCATACCCGGGTATCGAACTCAATCAAACTCCGAATGCCGGAAGATTTAAACAAGGGAGTCAGTCGGCGAGGGATAAGCTTCGTCGGCGAGAGGCAAACATGCCAGACTAGCAGCTAAGGTGCCCAAATGCCGCGTAGTGCAAAGGCTGTGGCGATACACAGACAATGAGGATGTTGGCTTAGAGGCAGCCACCATTTAAACAGTGCGTAATAGCTGACTCATTTAGTGTCTCCGCGCCGATAATGATTGGCGATCAGCGGTATACCGAAGCTCTAGGATAGTACGTCCGAGAGGATGTGCGATCGGTAGGGGAGCATTGTTGTCTGTATTGCCGTGGCGTAAGCCGCGGTTTAAGAACAACAAGTGAGAATGCAGACATGAGTAACGATAGCCCTGTTGAATCCAGGGCCGCCGAATACCCCAAGGTCTCCTTGGCAAGGATTGTCCGCCAAGGTCTAGTCGGATCCTAAGTTGAACCCATACGGCTACAACGATGGAAACCAGGCTAATATTCCTGGACCGCCGATATTTAACCCATCCTTGGTGCGCAGGTGCAAGCAGGCCGTCGAATGCCTGTCCCGAGAGGGCGAGTTCCAGCTCTGCTGGAGCGAAGTTGTCATGACGCGCACCGCAAGAAAAAGATGGCGTATAATCAGGTGTCCGTACCAAACCGACACAGGTGGGGTCGCGCAAGAGCGCGAAGGCGTAAGAGTGAAACCTCGTTAAGGAACTCGGCAATCTAACCCCGTAACTTTGGAATAAGGGGTGCCCTCGCAAGAGGGTCTCAGTAACCGGGTCAACCGACTGTTTAACAAAAACACAGCACTCTGCCAAGTCGAATACGACGTATAGGGTGTGACACGTGACCAATGCGGAAAGATTACGGTAAGGGGTTAGCCGCAAGGCGAAGCTCTGAGCCCAAGTCCCCGTGAATGTCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATCGTGTAACGAGTTGACCGCTGTCTCGACGAGGAGCTCAGTGAAATTGTAGTGGCGGTGAAGATGCCGCCTACCCGCAGCAGGACGGAAAGACCCTATGCACCTTTACTGTACGCTGTAACTGTGGTCCTTAACCCTTTGCCTAGAGTAAGTGGGAGACTGTGAACCTGTCCCTCCGGGGGCAGGGGAGTCGCCAATGAAACACCACCCTTAGGGTTGAGGGCCTCTAATCTGGATTTTTCTCCAGAGAACATTGCAGTCGGTCAGTTTTACTGGGGCGGTATCCTCCTAAAGAGTAACGGAGGAGTGCGAAGGTTGGCTCAGCCCGGTCAGCAATCGGGTGACGAGTACATGGATATAAGCCAGCCTAACTGCAAGACCTACAAGTCGCGCAGATGCGAAAGCAGGCCCAAGTGATCCGGTGACGGAATGTGGAATCGTCATCGCTCAACGGACAAAAGGTACGCTAGGGATAACAGGCTGATCCTGCCCAAGAGCTCATATCGACGGCAGGGTTTGGCACCTCGATGTCGGCTCATCACATCCTGGGGCTGGAGAAGGTCCCAAGGGTCCGGCTGTTCGCCGGTTAAAGTGGTACGCGAGCTGGGTTCAGAACGTCGCGAGACAGTTCGGTCCTTATCCGCTGTGGGCCCAAAAGAAGTGAGAAGTTTAGATTCTAGTACGAGAGGACCGAATTTAACGGACCAAGGGTGTTAGAGTGGCCGTGTCAACGGCCCGGCTCTGTTGCTATGTCCGGAACGGATAAACGCTGAAAGCATCTAAGCGTGAAGCCACTTTCAAGATTGCTTCTTTATTGTAGGCGTGGGAGACCACCACGTTGATAGGCCAAAAGTGCAGATGCAGCAATGTATCGAGCTAACTGGTACTAATCCGACAAATGCTTGAATGA
->CP001720.1/3486540-3486319 Desulfotomaculum acetoxidans DSM 771, complete genome. 
-GAAATCCCGTCTGGTAAGACTCTAGCCAAGTCACCAGTAGCGAGTCTTGGACTCGATGGAGTAATTCATAGAGTTAAGCGTAGACAGGTAGGTAGTAGGCCTGAATGTGATTGAGCCCCGTAATGGGCAAACGGGAAGGTTGACGGTTTCGAAACTCCGGAAAACTATATCTTGGTACGCGATATGGCGAGTGTATTGAGACTTCCTCGGGGTCTAAGAGCC
->AFTD01223909.1/154-1 Cricetulus griseus cell line CHO-K1, whole genome shotgun sequence. 
-GAATGTGAAGACAATCCTGTGACGTCTTTCACCTCATTGGACTTCAGGGTTAACTTGATTGATGGGGCTAGAGGGCGTGTCCCCTCCTGCATCACTCCAAGTGCATACTTCATGGTGCTGTGCACTCAAACAGGACAACCTTCCCTAATGGAGT
->MGPA01000055.1/20568-20297 Coxiella sp. RIFCSPHIGHO2_12_FULL_44_14 rifcsphigho2_12_scaffold_6640, whole genome shotgun sequence. 
-CCCGATCACTCATTGAGAGGTTTCATTAAGTTGAATTAAAAGGGAATCCGCACGCTTTGATACAAAATCAGAATGAAAGCTAATGCCATACAAAACGGCTGTGTATTTATTCTGCATCATGCTAAAAGTATTAAAGCAATTGGAGCTGTCCCCGCAACTGTATGCAGCAAGTGCTGTTCTATAAACCACTGGCACCCTTGGACGGGGCTGGGAAGGTGGATGGCACGTTTGAGCTGTTAGCCAGTAGACCTGCCTTCGATGAATAATTAGCT
->CP001472.1/654493-654256 Acidobacterium capsulatum ATCC 51196, complete genome. 
-TATTCGTAAACGCTTTGGGATGTTCGGGAAGGCGGTGAAAATCCGCCACTGCCCCGCAACTGTAAGCGCGTTCGTGTGCTTTCTCGTCTGTTGAATACAGAGGGCACACAGAGGTCCGGGCGTAGGATGCCACTGGAGCAGATGCTCCGGGAAGGTGATTCCGCGATGCCGCCCGGCTTCGATTCCACAGGGAATGAGCGCCTAAGTCAGGAGACCGGTCCCATGCGCCTTTTTCACC
->JRRC01082395.1/3124-5153 Gossypium arboreum cultivar AKA8401 contig_15521_1, whole genome shotgun sequence. 
-GTTCAAACGAGGAAAGGCTTACGGTGGATACCTAGGCACCCAGAGACGAGGAAGGGCGTAGTAAGCGACGAAATGCTTCGGGGAGTTGAAAATAAGCGTAGATCCGGAGATTCCCGAATAGGTCAACCTTTCGAACTGCTGCTGAATCCATGGGCAGACAAGAGACAACCTGGCGAACTGAAACATCTTAGTAGCCGGAGGAAAAGAAAGCAAAAGCGATTCCCGTAGTAGCGGCGAGCGAAATGGGAGCAGCCTAAACCGTGAAAACGGGGTTGTGGGAGAGCAATAAAAGCGTCGTGCTGCTAGGCGAAGCGGTGAAGTGCCGAACCCTAGATGGCGATAGTCCAGTAGCCGAAAGCATCACTAGCTTACGCTCTGACCCGAGTAGCATGGGGCACGTGGAATCCCGTGTGAATCAGCAAGGACCACCTTGCAAGGCTAAATACTCCTGGGTGACCGATAGCGAAGTAGTACCGTGAGGGAAGGGTGAAAAGAACCCCCGTCGGGGAGTGAAATAGAACATGAAACCGTAAGCTCCCAAGCAGTGGGAGGAGCCCAGGGCTCTGACCGCGTGCCTGTTGAAGAATGAGCCGGCGACTCATAGGCAGTGGCTTGGTTAAGGGAACCCACCGGAGCCGTAGCGAAAGCGAGTCTTCATAGGGCAATTGTCACTGCTTATGGACCCGAACCTGGGTGATCTATCCATGACCAGGATGAAGCTTGGGTGAAACTAAGTGGAGGTCCGAACCGACTGATGTTGAAGAATCAGCGGATGAGTTGTGGTTAGGGGTGAAATGCCACTCGAACCCAGAGCTAGCTGGTTCTCCCCGAAATGCGTTGAGGCGCAGCAGTTGACTGGACATCTAGGGGTAAAGCACTGTTTCGGTGCGGGCCGCGAGAGCGGTACCAAATCGAGGCAAACTCTGAATACTAGATATGACCTCAAAATAACAGGGGTCGAGGTCGGCCAGTGAGACGATGGGGGATAAGCTTCATCGTCGAGAGGGAAACAGCCCGGATCACCAGCTAAGGCCCCTAAATGACCGCTCAGTGATAAAGGAGGTAGGGGTGCAGAGCTAAGGATACATGGGTACCTTTCCTTTTTAAACTTACCATTGTCATGTCTTGACATGGTCTTACGTGGTATCCTTGCATTATGAACTCACCATTGCCATGCCTTAGCATGGTCTAACATGGGATCTTTGTCTTATCGTAGTTTATCAATGCCATGTCTTGACATGGTCTTACATGATTTCCTTGCCTTGTAAAACTTACCAATGACATGCCTTGGCTTGGTCTTATTTGGTATCCTTAAACCCTAATGTCATGACATTTGTATCTTGCACATGATATTTCGTACGGCCCTATGAACCTCGGACTCAGTTTGCCCTTACGGCCAAATCTGAGTATCTTTTTCAAAGGTGAAACTTTAAGAAACACTTTGTCTCCCACCTGATACTCAATATCTCTTCGTTTTAAATCCGTGTACTACTTCTGATGATCTGATGCTGCCTTCAGACTTTCACAAATTATTTTTATTTTCTGCTCAGTATCTTTAATCAAATCAACTCTGAAATTTTACTTTCACTGAGCTCAGTCCAAAACAATGGTGTACGGCATTTACGACCGTACAAAGCCTCGTAAGGTGCCATCTTAAGACTTGATTGAAAACTATTGTTGTAAGCGAATTCAATCAAAGGTAAATACCGCTCCCATGAACCACTAAACTCAAGGATTCAACATCTCAACATATCCTCGAGTATCTGAATTATTCGTTCGGATTGACCATCGGTCTGAGGATGAAAAGCGGTGCTAAAATGCAACTTGGTACCCAAAGCTTCTTGCAATTTCTTCCAAAATCGTGAGGTGAATCTCGGATCTCTATCCGACACAACAGAAATCGGTACCCCGTGGAATCGCACAATCTGAGAAACGTACAATTCAGCTAGTTTATCCAATCAAAAATCCGTACGCACGGGGATAAAGTGAGCCGACTTAGTCAGTCTATCAACAACAACCCAAATCGCATC
->MEZX01000002.1/385086-385203 Candidatus Berkelbacteria bacterium RIFCSPLOWO2_01_FULL_50_28 rifcsplowo2_01_scaffold_16, whole genome shotgun sequence. 
-GTTGGTGCTTTTTGCGGTTGGGGTACACCTCGTTACATTCCGAACCGAGCAGTTAAGCCAGCCAGCGCCGATGGTACTTACGGCATTCAGCCGCCGGGAGAGTAGGCCAGCGCCAACA
->LNFO01001542.1/1-433 Phytophthora nicotianae strain race 0 contig1542, whole genome shotgun sequence. 
-AACAGGCTGATGACTCCTAAGAGCTCCTATCGACGGAGTCGTTTGGCACCTCGATGTCGACTCATCACATCCTGGAGCTGAAGAAGGTTCCAAGGGTTCGGCTGTTCGCCGATTAAAGTGGTACGTGAGTTGGGTTTAGAACGTCGTGAGACAGTTTGGTTCCTATCTTCTATAGATATTTTGAAAAATGAAAGAATCTAACTCTAGTACGAGAGGACCGAGAAGGGTAAATCTCTGGTGTATCGGTTGTTAAAAGGCATCGCCGAGTAGCTAAATTTATTTTGGATAGTTACTGAAAGCATCTAAGTAAGAAACCATTCTTAAAAATTTTTCATATAAAAACTGTAAAAGACGATTACATTAATAGGTTTTAAGTGTAAGTGTTGTAAAATATTTAGCTTAAAAATACTAAAAGTTTTAAAAATTAAAATAT
->CP012602.1/5017483-5017399 Bacillus sp. FJAT-18017 genome. 
-ATCTGACAAAGGCAAACCTGTCTAAAGGCAGGGACGCAAAGCGATGGGCCTACCCGGGAAACCGAACGGCTGCCACGCCGCCGGA
->KI391971.1/1387979-1387852 Granulicatella elegans ATCC 700633 genomic scaffold supercont2.1, whole genome shotgun sequence. 
-TGAGCGTCATGATGGTAATAATCATCTTGCGGTTGTGAGATGAGAAGTCTGAGGCTACTGTAAAGTAGCCTTATTCTTTCTCATGATTATTTAGTCTAGCTCGCTGTCTCCCCGCCAGCGTTGGCGGG
->CAIX01000365.1/7381-7448 Albugo candida, Ac Nc2, WGS project CAIX01000000 data, contig: AcNc2_CONTIG_365_length_25035 
-AGGGATGTAGCTTGTCGGGAAGGCGTTCGCTAATCGAAAGGACCCGGGATCGAAACCCGGCTTCCCTT
->HG322950.1/5060379-5060502 Pseudomonas knackmussii B13 complete genome 
-TCTGAGATGGCGCAGGACGCGCCATCCGCGCAAACGCGCCGCCCGGGCAGCGGTTGCGGACGGGGCAACGTGGAGCCCCGCGGCAGACCGTGGCGACCAGGGACGGCCGCCTCGGAGTGCACTT
->DS562870.1/37046228-37046111 Cavia porcellus supercont2_15 genomic scaffold, whole genome shotgun sequence. 
-TTGTGTCTAGATGTAGCCCCAAAACCTTATGCTCAAACTAAAGAGATGTCTTTCTATGGTCTGTTGGCCATTTCAGAACTTGGGCGTGAAGTGGTCAATTCATCAGAAAGAAACAGAT
->AGTP01080057.1/11891-11451 Ictidomys tridecemlineatus contig080057, whole genome shotgun sequence. 
-TCTGTTGAAGTGGATGCTCATCAGGGACCCCCTCCTTAGCCAATGGCACAAGCCATCGTGGAAACAGTGCCAGGTGGGTGGTTTGACTGGGGTGGAACACCTGCCAAACAGTGATGCCGGTGTCCTAAGCCAGCTCAGGAGGGCAGAAACCTCCTGTGGTGCCGAAGGGCAAAAGCTCACTAAGTCCTGGTTTTTCAGGATGAATACAGGCGGTGAAAGCAGAGCCTCATGATCCTTCTGATCTTCTGGCTTTCAGCAGGAGGCATCCGAGAAGTTGCACAGGGATAAGTGGCTGACGGCAGCCAAGCCTTCATAGAGCTGTCACTGTTGGACCTGGCCGTCTGCTCTTCCTTTCGATGTGCAGCAGAATTTGTCAACCACTGGACTGTGTGTCTAGTGACCGTGAATGTGAGCTGGGTTTAGACCATCCTGAGACAGGAC
->BDFN01001543.1/367-1030 Ipomoea nil DNA, scaffold: scaffold1543, cultivar: Tokyo-kokei standard. 
-TATGGGGTGTGTGCATGGCCGTTCTTAGTTGGTGGAGCGATTTGTCTGGTTAATTCCGTTAACGAACGAGACCTCAGCCTGCTAACTAGCTATGCGGAGGTATCCCTCCGCGGCCAGCTTCTTAGAGGGACTACGGCCTTTCAAAGCCGCGGAAGTTTGAGGCAATAACAGGTCTGTGTCCTATTACGTTGGCCTTCGGGATCGGAGTAATGATTAACAGGGACAGTCGGGGGCATTCGTATTTCATAGTCAGAGGTGAAATTCTTGGATTTATGAAAGACGAACAACTGCGAAAGCATTTGCCAAGGATGTTTTTCATTAATCAAGAACGAAAGTTGGGGGCGAAGACGATCAGATACCGTCCTAGTCTCAACCATAAACGATGCGACCAGGGATCGGCGGATGTTGCTTTTAGGACTCCGCCGGCACTTATGAGAAATCAAAGTCTTTGGGTTCCGGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGACGGAAGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTTACCAGGTCCAGACATAGTAAGGATTGACAGACCTGAGAGCTCTTTCGAGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGCGATTTGTCTGGTTA
->HE616749.1/573542-573633 Torulaspora delbrueckii CBS 1146 chromosome 8, complete genome 
-AATAATGATGAAAAAATGGTCGCTTATCAATGCTTCAGATCTATCTGTGATGGAAACAAATAAATTAACCATTCAGAACCGCTACACTGATT
->CP022657.1/1323203-1323416 Tumebacillus algifaecis strain THMBR28 chromosome, complete genome. 
-AAATAGGCAATGATGGAGCGAGTAGCGTTTTGTAGGATTGTGCAGAGAGCCGGTGGTTGCTGTGAACCGGACAGTCCGATCACGTGAAGTACACTCCGGAGCCGCTTGGAGGCAATGCCAAGCCGGTCGCGCGAGTGATCGTTACGTCAATGAAGGAGTTTCTATTTTTGAAACTGCTTAGGGTGGTACCGCGAGTTCAAACCTCGTCCCTATT
->CP011601.1/33522-33359 Kluyvera intermedia strain CAV1151 plasmid pCAV1151-296, complete sequence. 
-TGGTGCTGGAGGCTTTTGCCCCAGCCAGCGGTAACACTGTTTGACTGTGGTAAAAGCAGAAAGCCCCGAGTAATTTTTCAATTAACCTGTACTGCACCCATTTTGTTGGACGATGAAATGGAATAGTCCCTGATATGTCAAAGCCAAAATACCCCTTCGAAAAG
->AMPR02000442.1/14789-14883 Cupriavidus sp. HPC(L) contig68, whole genome shotgun sequence. 
-CACTCCGAGGAGCGTTGCAACGGACGGCGCGCGGGCCCAACCCCGCATTCTGCCATCCGCCAGGCTCGGAATGTCTTCAACGGCGCTCGCTGAAC
->CM000811.1/53837939-53838120 Oryctolagus cuniculus chromosome X, whole genome shotgun sequence. 
-ATCACTTCTCGGCCTTTTGGCTAAGATCAAGTATAGTAATCTTAGGAAATGTCCCTGTCAAATAGCAAGAACTCAGAAATTATAACAATGTTTAGTGATATTAAAGGTTCTAATGTACCTGTCTCATACCTAGGGAGCTTGTATGCTTTTTCTACTTTTGCAAAATTTCTCTAAAGACTTCT
->KQ059250.1/49614-45799 Gossypium hirsutum cultivar TM-1 unplaced genomic scaffold scaffold2565.1, whole genome shotgun sequence 
-CGACCCCAGGTCAGGCGGGATTACCCGCTGAGTTTAAGCATATCAATAAGCGGAGGAAAAGAAACTTACCAGGATTCCCCTAGTAACGGCGAGCGAACCGGGAAAAGCCCAGCTTGAGAATCGGGCGCCATCGGTGTTCAAATTGTAGTCTGGAGAAGCGTCCTCAGCGGCGGACTAGGCCCAAGTCCCCTAGAAAGGGGCGCCGGAGAGGGTGAGAGCCCCGTCGTGCCCGGACCCTGTCGCACCACGAGACGCTGTCTACGAGTCGGGTTGTTTGGGAATGCAGCCCTAATCGGACGGTAAATTCCATCCAAGGCTAAATACGGGCGAGAGACCGATAGCGAACAAGTACCGCGAGGGAAAGATGAAAAAGACTTTGAAAAGAGAGTCAAACAGTGCTTGAAATTGTCAGGAGGGAAGCGGATGGGGGCCGACGATGCGCCCCGGTCGGATGAACAAGTACCGACGCGGGTCGTGGCGGCGGCCCAAGCCCGGGCCTTTGATACGCCCGTGGAGACGTCGTCGCCTCGATCGTGGGATTCAGCACGCGCCGCCTCGGCGTGCTTCGGCACCTGCGTGCTCCGGGCGTCGGCCTGCGGGCTCCCCATTCGGCCCGTCTTGAGCCCCGGTCGGATGTGGAACGGCGAGAGCCGGTTTGCAAATTGGCTCGGGGCGTGGACTGACGCGGGGCGTGGCGGCGGCCCAAGCCCGGGCCTTTGATACGCCTGTGGAGACGTCATCGTCTCGATCATGGGATCCAGCACGCGCCGTCTCGGCGTGCTTCGGCACCTGCGTGCTCCGGGCGTCGGCCTGTGGGCTCCCCATTCGGCCCGTCTTGAAACACGGACCAAGGAGTCTGACATGTGTGCGAGTCAACGGGCTGGAAAACCCGTAAGGCGCAAGGAAGCTGATTGGAGGGATCCCTCACGGGTACACCGCCGACCGACCTTGATCTTCTGAGAAGGGTTCGAGTGAGAGCATGCCTGTCGGGACCCGAAAGATGGTGAACTATGCTTGAGCGGGGCGAAGCCAGAGGAAACTCTGGTGGAGGCCCGCAGCAATACTGACGTGCAAATCGTTCGTCTGACTTGGGTGTAGGGCCGAAAGACTAATCGAACCGTCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGAGCCCTTAGTGAGTTCTATCGGGTAAAGCCAATATTAGAGGCATCGGGGGCGCAACGCCCTCGACCTATTCTCAAACTTTAAATAGGTAGGACGGTGTGGCTGCTTCGTTGAGCCGCCCCACGGAATCGAGAGCTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGGAAGCCGGGTTACGGTGCCCAACTACGCGCTAACCTAGAACCCACAAAGGGTGTTGGTCGATTAAGACAGCAGGACGGTGGTCATGAAAGTCGAAATCCGCTAAGGAGTGTGTAACAACTCCCCTGCCGAATCAACTAGCCCCGAAAATGGATGGCGCTTAAGCGCGCGACCTATACCCGGTCGTCGGGGCAAGAGCCAGGCCCCGATGAGTAGGAGGGCGCGGCGGTCGCCGCAAAACCCAGGGCGCGAGCCCGGGCAGAGCGGCCATCGGTGCAGATCTTGGTGGTAGTAGCAAATATTGAAATGAGAACTTTGAAGGCCGAAGAGGGGAAAGGTTCCATGTGAACGGCACTTGCACATGGGTTAGTCGATCCTAAGAGACGGGGGAAGCCCGTCCGATAGCGCGTTCAGCGCGAGCTTTGAAAGGGAATCGGGTTAAAATTCCTGAACTGGGACGCGGCGGCTGACGGCAACGTTAGAGAGTCCGGAGACGTCGGCGGGGGCCTCGGGAAGAGTTATCTTTTCTGTTTAACGGCCTGCCCACCCTGGAAACGGCTCAGCCGAAGGTAAGGTCCAGCGACCGGAAGAGCACCGCACGTCGCGTGGTGTCCGGTGCGCCCCCGGCGGCCCTTGAAAATTTGGAAGACCGAGTGCCGTCCGCGCCCGGTCGTACTCATAACCGCATCAGGTCTCCAAGGTGAACAGCCTCTGGTCAATGGAACAATGTAGGCAAGGGAAGTTGGCAAAATGGATCCGTAACCTCGGGAAAAGGATTGGCTCTGAGGGCTGGGCACATCGTGTGGTGTCCGGTGCGCCCCCGGTGGCCCTTGAAAATCAGGAGGACCGAGTGCCGTCTGCGCCCGGTCGTACTCATAACCGCATCAGGTCTCCAAGGTGAACAGCCTCTGGTCAATGGAACAATGTAGGCAAGGGAAGTTGGCAAAATGGATCCGTAACCTCGGGAAAAGGATTGGCTCTGAGGGCTGGGTACGGGGTCCCAGTCCCGAACCCGTCGGCTGCCGGTGCACTGCTCGAGCTGCTTCCGCGGCGAGAGCGGGTCGCCGCGTGCCGGCTGGGGGACGGACTAGGAACGACTCCTTCAGGGGCCTTCCTCGGGCGACGAACAGTCGACTCAGAACTGGTACGGACAAGGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGATGGTCCCTGCGGATGCTCACGCAATGTGATTTCTGCCCAATGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTGTCTACTATCCAGCGAAACCACAGCCAAGGGAACGGGCTTGGCAGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTCACTCTAGTCTGACTTTGTGAAATGACTTGAGAGGTGTAGGATAAGTGGGAGCTCTCGGGCGAAATTGAAATACCACTACTTTTAACGTTATTTTACTTATTCTGTGAATCGGAGGCGGAGCACGACCCCTCTTTTTGGACCCAAGGTTGGCTTCGGCCGACCGATCCGGGCAGAAGATATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTTAAAAGATAACACATGTGTCCTAAGATGAGCTCAACGAGAACAGAAATCTCGTGTGGAACAAAAGGGTAAAAGCTCGTTTGATTCTGATTTCCAGTACGAATACGAACCGTGAAAGCGTGGCGACGATCCATCCTGGCGATGATCTGGCGAGCCATCCCAGGATATACAAAACGGCGCAACGAGTCCCCCCCCGGAATTTGAAGCTAAAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCAATCATTGTGAAGCAGAATTCACCAAGTGTTCGATTGTTCACCCACCAATAGGGAACGTGAGCTGGAGTTAGACCGTCGTGAGACAGGTTAGTTTTACCTTACTGATGGCCGCGTCGCAATAGTAATTCAACCTAGTACGAGAGGAACCGTTGATTCGCACAATTGGTCATCGCGCTTGGTTGAAAAGCCAGTGGTGCGAAGCTACCGTGCGATGGATTATGACTGAACGCCTCTAAGTCAGAATCCGGGCTAGAAGCGACGCACGCGCCCGTCGCCCGATTGCTGACCAGTAGTAGGGGCCTTTGGCCCGCAAGGGCAGTGTCGTAGGTGCAGCGACCACGACGGACAAGTCGCGGGCGCCTCCTTGGAGCGTAATTCCCATCGAGCGGCGGGTAGAATCCTTTGCAGATGACTTAAATACGCGACGGGGTATTGTAAGTGGCAGAGTGGCCTTGCTGCCACGATCCACTGAGATTCAGCCCTTTGTCGCTTCGATTCGT
->ATMG01007873.1/439-612 Angomonas deanei Cont7876, whole genome shotgun sequence. 
-CCCGGGGGGTACCCCCCGGGGGGGGGGGTAAAAAAACCCGGGGGGTTAAAAAAAACGGGGGGGGGGTTAAAAAAAAACCCCCCGGGGGTTAAAAAAAAACCCGGGGGTTTTTTTAAAAACGGGGGGGTTTAAACCCCCGGGGTTTTACCCCCGGGGGGGGGGAAAAACCCCCCC
->GL010040.1/62122050-62122364 Loxodonta africana unplaced genomic scaffold scaffold_13, whole genome shotgun sequence. 
-GGATGTGAGGGCAATCTGGCTGAAACACCTGTCACCGCATTGATTGCCAGGGCTGACTGGATGATGCTGCTCACCCTCATCCCTTAATTTCTCCTTCTGTGTCTTTCTGGAAGCCTTGGGCTTGGTGAAAAGGGAAGACTTTCCCAAAGACAGGAGGCCATTCTGCAATTATTAAAGATATGTGGGTAGTAGGTTGACCAGCTTTCCCTTTTTACCTGGGACTGAGGGTTTCCTGGGATGCACGACTCTAGTGCTAAAACCAGGAAACCCAAAAAACCCAGTGCCATTGAGTTGATTCTGACTCATAGTGACCCT
->LFJF01048753.1/46-1 Macrostomum lignano unitig_48821, whole genome shotgun sequence. 
-ATACTTACCTGGCGCGGGGGATACCGTGATCAAGAAGGCGGTGCCT
->URS0000D694FA_12908/1-95 unclassified sequences DUF3800-IX RNA 
-TTCCCCTCGGCGAAAGAGTGCCCTCATTGGGCGCGTGCCAGGTGGTTGAATGCTCTGCATAAGAGCCATAACCTGGATAGCCGAGGCGGTTTTAT
->GL896944.1/3131193-3131114 Mustela putorius furo unplaced genomic scaffold scaffold00047, whole genome shotgun sequence. 
-GGAACTTCAAAAAGGGTCGTCCTTCCTGTGCTTGCTTTACTGATGGTGCATTTTTGAAGTGCGTCCCATTTTTCAGAATC
->AZAF01012014.1/4245-4334 Dictyocaulus viviparus strain HannoverDv2000 D_viviparus-1.0_Cont414.7, whole genome shotgun sequence. 
-TATATTCACACAATCGGCGAGCGGTTTTCACTGTGATCTGAGAGTTCATACTTCTGAGATCATTGTGAAGGCCACTTGCCTTGTGCCGAT
->AP006878.1/1476852-1476910 Thermococcus kodakarensis KOD1 DNA, complete genome. 
-ACCGATGAGGAGTGTCATCCCTCCTGATGTCGAGATGATGACATTATCCCCACCTGAGG
->CP004044.1/1196775-1196896 [Clostridium] stercorarium subsp. stercorarium DSM 8532 chromosome, complete genome. 
-ACAACAAAGTAGAAGTGTCCACTTCTCACCCTGTGTCCTGTTGACTTCAGGGTTTAAATCGTAGCAGTATGTTGCTGTGATTTAACGCAGGTGAAGTGGCTTACCTGCTTTTTTATTTGTCA
->JMSN01000007.1/154622-154723 Tilletiaria anomala UBC 951 K437scaffold_7, whole genome shotgun sequence. 
-GGCCAATTGGCGCAATGGTAGCGCGTTGCTCTCCTACATGTGATGATTGCTTCATGCGCTTGGGGCAAGCAGAGGTTGCAGGTTCGACCCCTGCATTGGTCG
->LOHF01000026.1/9999-9927 Pseudomonas caspiana strain FBF102 scaffold00026, whole genome shotgun sequence. 
-TGGCCTGAAGCATTGGCGGTTGATGCACTGGCCTCATAAGCCAGCGAAGGGGGTTCAAGTCCCCACAGGCCAA
->AFTD01049056.1/8014-8294 Cricetulus griseus cell line CHO-K1, whole genome shotgun sequence. 
-GGACAGTGTGGCTGTGATATCACCCCATTGATTGCTAGGGGGTGGTCCTGATGTCCTTCTCATCACAGCTCCATGTATGTTCCCTGAAGCCACTTGCTGGTTTGAGGAGGACCTTTTTAGGGGAGGACCAGTGTTTTGTCAAAGATGTACAAATAACTACACTCTCCAGCTAGAACCTCCAAACCAGCTTTCAAGGTCCATTTGTAGGGAAATGTGGTGGTCGAGCTTCGAAGACTCAGGGCATACCAAGTGAGGCAATGCGTGGCAGTCTGCCTTCCTTT
->CP000102.1/1672674-1672743 Methanosphaera stadtmanae DSM 3091, complete genome. 
-AACAAATAAGGTGATGAGGTTCCACCTATTTAACTGCCAGTGATTACTGGATGATGACTTCTATTTTTAA
->LM433890.1/66331-66460 Nippostrongylus brasiliensis genome assembly, scaffold: NBR_scaffold0000505 
-ATGCGTGATCTCAACACGCGTACTGCCTCCTACGGCGTACGTGTCTGTAATGCACGCTAGAACGAATGCGCCGGATTTCGCTAGCACCGCGTCCAGTGACCGGAGTTTGATAGTAGACCGGGGCACATTA
->KV440972.1/762318-763371 Phycomyces blakesleeanus NRRL 1555(-) unplaced genomic scaffold PHYBLscaffold_2, whole genome shotgun sequence. 
-GGTCCGTACTTTGAGCGATTCTACCTGCATTTACTGCAGTGGAAAAGAAACCAAAAGGGATTCCGTCTTGGACTTTATTGTTTGAGATGGAGAAGCTCCAATGTTTGAACCGGAGTAGTCTTTTGACTGCTCCGGATTGTGAACTAGTGAACTGCTTTTCCAGACATACCAACAAGTCAGTAGCCTTCACTCCCTGGAAAAGGTTACTGGAGGGTGCAATCCCCTCACCTTGTCTTGAGTTCTTGTCTTTGTGTTAAGTAGCTTCCGATGAGTCGGGTTGTTTTACAAACTCCCTAATCCTGGTGAAAAGTTTCATCGAAGGCTAAATATACTTATAAAAAACCAACTGAACACAAGTACCGTAAGGGAAAGTAGCTCTTAGTGTAGAGCATACTGGACGTTAAAGACCTTCCTGAGCCACTCATATGAAGGCGAAAGCCGGATGAAATCCACGTCAGTTTTTTCTGTGTTGTGCGGCACATAACATGGAGAAGACTGAGGAACGCAGAGGTAGCTTTATGCTATTTTCTTAGGACGTTGGATATTGGCTCTCCAGATTTTGTCCTTTGGGGCATGTCAAGATTGTCACATAAAGGTGCAAGTATAAGGGTGTATCACCTGGATGCGTAGAGTTTTTTAAATTCGTTGAGCACCTGGACGTGAGGTAATACAGGTAGATTCCAGCAGAATCGACAGATTACCCAGTACAATCGCCTGTATTTTACTGCTTCCTGTTGAAATGATCCCTGTGCTTTTCAAGTCCCTCATTGCTTAGACTTTGATACTTGTAACCCACGCTCTGGTAAACAGAACTGGACATGAGGGACGAACCCGAAGCAAAGTTAAGGTGCCTAAGTAAATGCTATGCTGTTCACTTGGGTGTCTCAGACACCTGTCCCGAGCAGTTTGGCATTAAAGCATTTCACCGATACTTTGCCGTCATGGTAAATTTGATGCCATGCCGAGTAGGCAGGAATGAGGGTTGTTGAGAAGCTTGGGTGTAAACTTGAGTGGATCGGCCTTCAAGCGCAGGTCTTGACAAAAAAATCTTTGT
->GL010085.1/8876859-8876953 Loxodonta africana unplaced genomic scaffold scaffold_58, whole genome shotgun sequence. 
-TAGCCTGGGCGGCGGCGGGAGCCTGCGCGGCCAGGTGGGGAGGCGGCAGGGCCCGGGCGGGCGCCTGCTGTCTGCCCAGAGCCGGCCTTTGTACA
->HF997045.1/49466-49290 Roseburia sp. CAG:50 genomic scaffold, scf107 
-ATATCAAATAGAGGCGCGGTTTACCGGGTAGCAGCAAATGATAAGGAACATTATTTCCAAGGTTGTCTGTGAAGGGGTGGATCGCCGAAAGACCGGATCTGTAATGGGAGAAGGACTTGGGGCAAAGGCGGACAGCTTTTGCACTGTCATGTGAAAACGTGGGGCGCTATTCATCAG
->CP002734.1/423330-423196 Pseudopropionibacterium propionicum F0230a chromosome, complete genome. 
-AACTGGCTAGGCTGTCCCGCGACGACTGACCATTCAGCTTGCCGACAACGAAGGAATCCGGTGCGAATCCGGAGCGGTGCCGCCACTGTGACCACCCGGGTGGGAGCCAGATACTTCGGGCCAGCCAAGACCGAA
->AFYH01035016.1/408-649 Latimeria chalumnae contig035016, whole genome shotgun sequence. 
-GTGCCGCACCAGAGACTGAAGTCCTCTGTTTATCCACAGAACAGGTACAGCAAGGGCAGCGGCTGTGCAGGCTTCCCCTCGTATTGTAGAAAAGGCTTTCTCTCATTTTGTACTTATGGCCAGATCCTTTCTGCAGTAGGGCCCATTGCCCTGGCAGTGTGCCTCAACCCTGTCCTGGTGGGACTGCCTCTACAGGGTGAGAGGATAGTTCAGTCTCTATGCCCATTCACTCCTTGGCCTCT
->AAQR03046981.1/275629-275572 Otolemur garnettii contig046981, whole genome shotgun sequence. 
-CAAAAGGCTCTCTCTTTCCTCTTTGCAGAGAGCCACCCAAATTGTAGTAAAATTATAT
->CM000866.1/73130079-73130313 Callithrix jacchus chromosome 11, whole genome shotgun sequence 
-GAATGTGAGGGTGATCTGGCTGTGACATCTGTCACCCCATTGATCACCAGGGTTGATTTGGCTGATCTGGCTGGCTAGGTGGGTGTCCCTTCCTCCCCCACCTCTCTGTGTTCATCCCTCCCAATGTGACCATCCTTGATACAGGGCATATGAGTAGCTGTTATCCCCCTGCTAGAACTTCCAAACAAGCTCTCAAGGTCATGAGAGAATGGGGCAGATCTTGTCCAGTATAGTT
->AKKU01000011.1/303476-303556 Alishewanella agri BL06 contig011, whole genome shotgun sequence. 
-GGATTTTTAGCTCAGCTGGGAGAGCACCGCCCGCTTTTTACAAAAATACGGTTGCCACTGGTTCGAACCCAGTACAATCCA
->JPDO01000048.1/47729-47855 Acidomyces richmondensis BFW scaffold_48, whole genome shotgun sequence. 
-GCTTCGATGGTTTAGTGGTAGAATTTCACCTTCCCAAGGTGGAGGCACGGGTTGTAGGTTGCTCACCTGATTCTCGTAAATTTCCGCATCATACTTATCAATGTTGCAGCGATTCCCGTTCGAAGCA
->URS0000D6D023_12908/1-115 unclassified sequences EGFOA RNA 
-GACTGCCCAGATGTGCGAAAGCGACCGTCCTAGTCCACGAAAGTGGAGGATAATGCCCTGAAAGGTGAAAGTCCTTGCTCTGTAAAGCTAGACCTGGGGGAGTTAGAGGGGTAGC
->CM002905.2/43709859-43709995 Danio rerio chromosome 21, GRCz11 reference primary assembly. 
-AGCCAAAGCGTTGAGTTCAGCTCTGGGTTTCTCCCCAGTTCTGCTAATTAATCTTTGGTACAGAAAATGGCTGAGTGGTGATCAACATGAAGGGGTTATACTTTGACCTCCTTTATTAAACCCTTCAGCCGACATGA
->FWFW01000005.1/209292-208875 Pacificibacter marinus strain CECT 7971 genome assembly, contig: 0005 
-ACGGATGGCTGGATGACCGCGGGTTCTGGGCGCGCAAGCGTACTGGGACGCGAGGAAAGTCCGGACTCCATTGAACAACAGTGCCGGGTAACGCCCGGCGGGGGCAACCCTAGGGACAGCGCCACAGAGAACAGACCGCCCTACGCGCGCGCAAGCGCACGCTGGGGTAAGGGTGAAACGGTGGAGTAAGAGCCCACCGCGCGAGCGGCAACGCAAGCGGCACGGCAAGCCCCACTGGGAGCAATGCCAAATAGGGGTTTCGTGTGAGGCACTGCGTTCGCGCAGAGTGATCATAGGGAGGTTCAAGCCCGAGAGACCCGGGTTGGCAGCTTGAGCGTATTGGTAACAATGCGCCTAGAGGAATGGTCATCGAGGGGGCAACCCCAGACAAAATCCGGCTTATAGGCCATCCGTGCAT
->AGTP01074074.1/1268-1332 Ictidomys tridecemlineatus contig074074, whole genome shotgun sequence. 
-TCCTTGTTCAGATCTGTGTCCAAATGATTTCCTGTACTTGCAGGGGACAGGTGGGGTTTCAGAAG
->FRCC01000012.1/1582-1684 Flavobacterium flevense strain DSM 1076 genome assembly, contig: Ga0131122_112 
-TTTGCGTTAGGGATGGAAGCGGCATCCTTTTGTGAGAGCAGTAATTTTCAGGTTTAAACTACTATTACCCGAACAAAAGATACAGCGTACAGCCCGACCTTGT
->CM002818.1/210608794-210608329 Capsicum annuum cultivar Zunla-1 chromosome 7, whole genome shotgun sequence 
-AAGGTAGACGTTTATGACATTTTAAGACAATGAACCTGTACAATTGACCACTCTAAAAGGGCTAGAATTCTAACATTATGTTAGGACCTGAGGACCAAGAGATAGTCTCAGATAGACAATTTTTATGGGGCGTAGGCCTACTAAAAGGTAATGGAGGCATGCAAAGATTTCCTCGGGCCGAACAAAGTTTGTCCCTCGAGTTCAAAGGCAGAAGGGAGCTTGAATGCAAGACCCACCCATTGAGCAAGGACAAAAGTCTGCCTTAGTGATTCAACGGCGCCGAGTATAAGGCCCGTCGCTCAACTGATAAAAGTTACTCCTACAGATAGCAGGTTGATCTACCCCAAAAGCTCACATCGATGGAAAGATTTAGCACCTCGATATCGGCTCTAAGCCACCTAGGGTTGTAATATGTTTCAAGGGTTGGGCTGAAAATCAAGACCGGGCCGCTTTGTGGGACACTAGG
->AGTP01053200.1/11304-11443 Ictidomys tridecemlineatus contig053200, whole genome shotgun sequence. 
-GGGGATGTGGCTCAGTGGTTGAGTGCCCCTGAGTTCAATCCCCAGTACCAAAATTAATTAATTAATTAAAATAAAAAATAAAGGACTATGGATGTAGCTCAGAAGTAATGCACCCCTGGGTTCAATCCCCAGTACCCCCA
->AYUG01121489.1/14996-14569 Fukomys damarensis contig121489, whole genome shotgun sequence. 
-TTATTGGTTGATGTCATGATAGCAGCCATTCTTTCTAGGGTGAGGCGGAATCTCAGAGTTGTTTTTATCTGCATCTCTGGAATGAATGACTAGTAACTCAAAAACAGCTCATTGAACCCTGCCCCCTCAGCCTGGTGGAAGGGAGGGGGAGCAGGAGCCTGCAGCTTGGGTGACTCTAGATAACTTCAGGCTAATTGCACAGTGTGCACAGACACACACACGCGCACGCACCCCGAGGTGGCATCAACCCATTTGAACATCAGCCCTATCAACTTTCCATGGTAGTCATCATGCCTACCATGGTGACCTCGGGTGATGGGGAATCAGGGTTCAATGCCGGGGAAGGAGCCTGAGAAATGGCTACCACATCCAAGGAAGGCAGCAGGCATGCAAATTACCCACCTCTGACCCGGGGAGGTAGTGATGAA
->JJRU01010803.1/22820-23049 Picoides pubescens contig10803, whole genome shotgun sequence. 
-GTGCATGCTGGGCTACACTTCATGAAATGGAGCTCAGGAGCAACCAATTGCTTAGCTCCTCCTAACATGTCCAACTGGCTATGAAAAGCTGGAGGTGCTGCACAGAACAATGAAGAGGAGCTATCCCACATATTAATCTGCTTATCAAGGATTGCCTTCTGTATAGGTTAATGGGAAGCATGTAAAAGGGGGGGGGGGGGGGAAGAGGGGGGGAAAAAAAGGGGGGGAAA
->LM550152.1/1576-1768 Onchocerca flexuosa genome assembly, scaffold: OFLC_contig0009332 
-AATGTTGTTGCGATAGTAGTCCTGCTCAGTACAAGAGAACCGTCAGATCATTGGGTCATTGGGTTCATGTGCCTGACCGATTGGAAAATTGTACGAAGCTACCATCTGAGGGATTATGACTGAACGTCTCTAAGTCAGAATTCCTTTATCAAATTTTGTATTTTGCGTTACAAATAAAACCGAAAAAAAAAAA
->AAIZ01025588.1/144-25 Drosophila persimilis strain MSH-3 cont1.025587, whole genome shotgun sequence. 
-CGACGATCGGGTCTTTCGAGTGGAGGGGAGAGTGTTGGAGTTGGCGGACATGGAGTGTTCCACCATGAACCTCGTCTGCCACTCTCATCTCGTCCACCCGCTCGAGAGGTTGCGATCGTC
->BX284602.5/14617143-14617209 Caenorhabditis elegans chromosome II 
-GTGCGATGAAGGTTAATGATAAGTTTCGGCTGACTCAAATTGATGACACCTTTAATATGCTGAGCAC
->NHBU01000111.1/1-68 Bacterium TMED15 isolate TMED15 146485, whole genome shotgun sequence. 
-TGACAAACATGTAGTAGCTTTTTTTGAGATGTTTTCGGACGCGGGTTCGACTCCCGCCACCTCCAATT
->AACT01044066.1/1177-1 Ciona savignyi cont_44066, whole genome shotgun sequence. 
-AAACTTTGCATTAATCCTGAGAATTTGGTATTTTTGTATGATTATGACTTTAAGAGCTTTAAGAATCTTAGCAAAGAACAATTGACAATTACACTTGTGGATCATCATCACATACAAAAGTGAGTATTTGTCGTCAAAAAAATCCTGGGTTGAACTACAACAATAGTAATGTCTCAACCATGCAATAAGCTGCAATAGCTCTGGTAATCATGCAGTAAGCACTAGGTATTTTTGACTTGCTGTGTGATAATGCCTCTTGTGTTTTTTCATTTACATTCTTTTAATTATTCCTTTTAATAAAGAGAAAACTCATAAAGGTTTTTTCTAATTTTTTGTGTTATGTTAATAGTTCCCATGTGCTTCATGGGTGTGAGATCACACATGACAGAAATATTGGATCATCGCCCACAAGAATATGCTACTGCACCTGGCGTTGAAGTTTCTATTTGTAAAGTGGGTTCATGCAGTACTCTAATTGCTACGAGGGTTTTGCAGAATTTGAGAGAAGATCAACTTCTACCCGAAGTCGTCACTTTGCTGTTAGGTTGGCGCACTAGCGTCGGACGAGGGCCGCGACCGGCTGGGCGGCGGGCAAACGGCTCCGGGCAAGGTAACCCCGCTTCGGCGGGGTGCTACAGGCCCGGTGCGCGCAAGGGTCGCCGCCCGGTCGAGGAGAGATGCGCGCCGCACCTGCCCCGTTCGCGGGGCCGGGGAAGCCGTTCGAGCAGCGTCGTGTCGCGGTCCGGGACTGTCCTCAGTCCCGGGTCGTCTCGGCGCGGTTCCGAGCGGTCGCTCCCTCGCGAGGTGCCGCGGGTCAGCGGCTGACGCCAGCCACCTTCCCGACCCGTCTTGAAACACGGACCAAGGAGTCTAACATGTGCGCGAGCCGCGGGGCAGTACGAAACCCGTAAGGCGAAATGAAGGTGAACGCCGGCGCGGTCCGGCGGAGGTTGGATCCCGTCCCGTCGGGGCGGGCGCACTACCGGCCGATTTTTTCCGCCCTGTCGGCGAGGTCGAGCGAGAGCGTGCAAGTCGGGACCCGAAAGATGGTGAACTATGCCTGAGGAGGTTGAAGCCAGAGGAAACTCTGGTGGAGGACCGTAGCGATTCTGACGTGCAAATCGATCGTCAAATTTGGGTATAGGGGCGAAAGACTAATCGAACCGTCTAGTAGCTG
->KV454486.1/94097-93978 Ascoidea rubescens DSM 1968 unplaced genomic scaffold ASCRUscaffold_12, whole genome shotgun sequence. 
-GCAATATTCTACGGGTGCCTCATGATTTTAATTTCTAATTATGATCTATGGCTGAGATTATACCGTCTACTGGAACTCGATCAAGTTAATACTTGCGTGAGGAAGTAATATTGTTATATT
->URS0000D69B4B_12908/1-89 unclassified sequences c-di-GMP-II-GAG riboswitch 
-CGGCGATTGGACACTTTGACCCCCGGGTGCGGGCAGCAGCGGTCACCAGGTTCCGGGGCGAGTGAATGGTGAGACCGGCCAATCTGCCG
->JH835753.1/1489368-1489540 Erinaceus europaeus unplaced genomic scaffold scaffold00465, whole genome shotgun sequence 
-GGCTGGGCTGTTCGCAGTGCAGGAAGCCAGCTGTTCTGAGGGAATCGAGGTGTCACCAGGAGCCTTGCTATTGCAGTGGGTTGTGGTCACAGGCTGAGTCCCAGGGCAGCCTCCATCCAGGCCTCTTGTGCTGAACTGGAGAGCAGCCTGAGGACTGACTGGGGCTCCCAAGG
->CP004349.1/2893589-2893441 Polaribacter sp. MED152, complete genome. 
-AACTAGCTTGCATGAGCGATAGAAACGACATCCTTTTTATGTATAAATTGGTTCTAAACTTTTTTTAGATAGCTTTAACCTTATAAAAAACCAGATACTGATACAAGTTCTGCATAAATAAAAAGATACAGTGAATAGCGCAGTTTTTG
->LAZP01002266.1/658-335 Ophiocordyceps unilateralis strain SC16a Contig_2342, whole genome shotgun sequence. 
-AATTGGGCGAAGCTACCATCTGCTGGGTAATGGCTGAACGCCTCTAAGTCAGAACCCGTGCTAGAAGCGTGGACGATTTTTTCTTGCTTTGCAATTAGAAGTGCAGAAATAGGAAGTCTTCGGGCTTTCGTGTGCCATAAATTTGAGGGTCCTGGTATCTTGAGCGGAAAGGCTTGGGGTACCTGCCTTCGTAATTACAACGAAAATATGCGGGCAAGGGAGGATCTCTTGCAGACGACTTGAATGGGAACGGGGTGCTGTAAGCAGTAGAGTAGTCTTGTTACTACGATCTGCTGAGGCTCAGCCCTATGTTCTTAGATTTGT
->MTEJ01000052.1/21539-21679 Thiothrix lacustris isolate A8 Ga0073116_1052, whole genome shotgun sequence. 
-AGTTTGCAGCGCTGTTTAGGTGCGCTCATTGCGGTGAGCGTTAAACGGGAAGTTGGTGCAACACCAACACTGCCCTCGCAACGGTAAGCAGGTTATGCCAATCTGATAAGTCCGACACCGGCCTGACAAGGCGCGACTCTA
->LGKD01099238.1/4615-4769 Octopus bimaculoides Scaffold8256_contig_7, whole genome shotgun sequence. 
-ATAGTTTTCTTGAATTCCTGGGGTTTGCTGAACCCAATCAGAGACCATCGATATTAAACTGATTTTTAGAACGAGGCGAAGAGTTAGGGGCTTGCTCCGCCTTTGTCACGGGTTGGCCTGGTATATCAGTACTTCTAGGATTCAGCCCATCTCCC
->MKVI01000100.1/16871-16982 Legionella sp. 40-6 scnpilot_expt_750_p_scaffold_1464, whole genome shotgun sequence. 
-TGCCTTGGTAGAATGATCGCCTTTAACGAATACTAAGTAGTTCCGGGAGTGAAGAATGTCGCTAAGTAGCGCAGATAAAGCAGCAATTGTAAATGAGTTCAAGCGTGATGAC
->LBRP01000004.1/36699-35151 Parcubacteria (Nomurabacteria) bacterium GW2011_GWF2_36_19 US08_C0004, whole genome shotgun sequence. 
-AAAGTATCTCTGGCAACTGTTTATCAAAAACACAGCTCCCTGCGAACTCGCAAGAGGATGTATAGGGGGTGACACCTGACCAATGCCAGAAGGTCAAATATCGGTGGTGCATGGTCGCAAGATTGTGTGCTGGCTGATATAAGCCCTGGTGAATGTCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAGTACCTTGTCGGGTAAGTTCCGACGCGCACGAATGGTGTAATGACTGGAGAACTGTCTCGAAGACCTGCTCGGTGAAAATACAATACCGGTGAAGATGCCGGTTACCTGCAGATAGACGAAAAGACCCTAGAAGCTTTACTGCAGCTTGATATTGAGTATATTGTTTTAATGCGTAGCATAGATGGGAGAGGTTTGATGGTTAGGGTCTCGGCTCTGATCTACTCGTCAGTGAAATACCATTCTTTACAATAATATGCTCTAATCTCTAAGGCAAAAACTTAGAGAGACAGTATCTGGTGGGTAGTTTTACTGGGGCGGTATCCTCCTAAAGAGTAACGGAGGAGTTTATTAAGGTTAGCTAGGCGCGAATGGAAACCGTGCCGATAGTGTAATGGCACAAGCTAGCTTAACTGTAAGACGTACATGTCGAGCAGATACGAAAGTAGAACATAGTGAACCGACATTTCGCATTAGATGCGGATGAAGATTAACGGATAAAAGCTACTCTAGGGATAACAGGCTAGTTCCGCCTAAGAGTTCATATCGACGGCGGAGTTCGGCACCTCGATGTCGGCTCACCTTATCCTGGTGGTGGAGAAGCTGCCAAGGGTTTAGCTGTTCGCTAATTAAAAAGGTACGCGAGCTGGGTTCAAACCGTTAAGATCATAAACGATTGTGATTTTAACAGTTTGAACCGTCGAGGAAAGTAAAGAAATCTCGTATATTTCTTTCAATGTTTTAATCTGAGATTAAGACCGCTATACACAGTTGTGTATATCACGGCGGCCCCGCCAATAAAACGACGGGGAGAATTTCACTTATATCGGTGAAGTCCTACTTTTATAAAAGAGGATAATACCGAGGGAAGCGTAAGCACCCGTAGAGACTAAATGTGAAATATTTTTTGAGAAATCAAAAGAGAAAGTTATAGTCCAATCCCACAAGTAATTGTGGTTCCCATTTTTGTATTTAAACGCGCAAAAATGAAGAGACTAAATCATTTTTAGTAAAAAATGATCGTCCGAACTTTTGTTTACAAAAGTTTTAGGAAGTAAAATATAGATGCGTGAGACAGGTTGGTCTCCTATCTACTGCAGGCGTTGATTCTTGAGAAGATCTGCTCTTAGTACGAGAGGACCGGAGTGGACTGACCTCTGGTGTGTGGGCTCTACTGCCAAGTGGACTGCCCAGTAGCTATGTCGGGAATGGATAAGTTCTGAAAGCATCTAAGAACGAAGCCAACTTCAAGATGAGGAATCGTTTGAGAAACCTAAGAGATGATTAGGTTGATAGGCACTAGGTGTACAGACAGTAATGTCTTTAGCCGAGGTGTACTAATCGTTCGATTCCTATTAGGAA
->CM000244.2/78118522-78118698 Rattus norvegicus chromosome 14, whole genome shotgun sequence. 
-AGCTTTGCACAGTGGCAGTATCGTAGCCAATGAGGTTTATCTGAGGCGCGATTATTGCTCATTGAAAACTTGCTCACAACCTCCGGTTCCCCCACACACACATACACACTATAAGCCCAGTATCGATGAGCTGTGCCCTGTCCCCTGCGTGCCTCATTTTCTGGCCCACAGCTCTGT
->CH476646.1/112655-112774 Sclerotinia sclerotiorum 1980 scaffold_26 genomic scaffold, whole genome shotgun sequence. 
-GGTCGTGTGGTCTAATGGTTATGATATCTCGTTCACAAACATGTGTTCATCAATTCTGATTTCGATTGTACCCGTTATCTGATTCCGAGATGGTTCCCAGTTCGATCCTGGGCACGATCA
->MLBF01000159.1/890-1 Desulfosporosinus sp. OL contig00159, whole genome shotgun sequence. 
-CGACTGGAAGAGCACGTCCAAGCAGTGAGGCTGAGTTTACAGGCAAATCCGTAGACTTAAGGCTAGGCTGTGATGGCGGGAAGGAATTATAGTACCGAAGTCACCGATCTCATGCTGCCAAGAAAAGCCTCTAGTGAGGAATGGGGTACCCGTACCGTAAACCGACACAGGTGGGTGAGGAGAGAATCCTAAGGCGCTCGGGAGAACTCTCGTTAAGGAACTCGGCAAAATGACCCCGTAACTTCGGGAGAAGGGGTGCCTCGATAGGGTGAAAGCCCGAGGAGGCCGCAGTGAAAAGGCCCAAGCGACTGTTTAGCAAAAACACAGGTCTCTGCAAAACCGTAAGGTGAAGTATAGGGGCTGACGCTGCCCGGTGCTGGAAGGTTAAGGGGAGAGGTTAGCGTAAGCGAAGCTTTTGAACCGAAGCCCCAGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCAGGTAAGTTCTGACCCGCACGAATGGCGTAACGACTTGGGCACTGTCTCGACGAGAGACCCGGCTGAAATTGTAATACCTGTGAACGATGCAGGTTACCCGCGACAAGACGGAAAGACCCCATGGAGCTTTACTGTAGCCTGATATTGAATTTTGGTACGATCTGTACAGGGATAGGTGGGAGCCAGAGAAGCCGGACCGCTAGGTTCGGTGGAGGCAATGGTGGGATACCACCCTGATCGTATTGAAATTCTAACCTACATCCCTAAACGGGATGAGGGACCGTGTCAGGTGGGCAGTTTGACTGGGGCGGTCGCCTCCTAAAGAGTAACGGAGGCGCCCAAAGGTTCCCTCAGAATGGTTGGAAATCATTCGCAGAGTGTAAAGGCAGAAGGGAGCTTGACTGCGA
->DF087494.1/2012-1880 Oryzias latipes DNA, scaffold4344, strain: Hd-rR. 
-GGCTTAATTTGACTCAACACAGGAAACCTCACACGAAGGATTGACAGACTGATAGCTCTTTCTCAATTCAGTGAGAGGTGGTGGAGTGATTTGTCAGGTTAATTACCCCTTGTGCTATCTTAGATGACCCCAC
->BA000039.2/1466104-1465982 Thermosynechococcus elongatus BP-1 DNA, complete genome. 
-TTGGCGACGTTCACTGTGAGAAGCAGCCTGTAGGGAAAATCCAGTGCAAGTCTGGTGCTGTGCCGCAGCTGTGATGGGAATCTTCCCTCAGCCAGAATGCCTACTTGCTGTGGTTCACTCTAT
->LCPG01000034.1/4881-5287 Parcubacteria bacterium GW2011_GWA1_48_11b UY24_C0034, whole genome shotgun sequence. 
-TGAGGGCGTAATAAGAGCGTATGGTGGATGCCTTGACACAAAATGGCGATGAAGGACGTAGCGTAGCTGCGAAAAGCCCCGGGGAGGTGTGTAGCAACCTTTGATCCGAGGATATCCGAATGGGGAAACCCTCCGCGGTAAACCCGCGGAACCAGTGCGTTGCACTGGAATGACTAATTCCTAATTGACCTAATTCCTAATCAATTTCTAATGCCGAAATGTCCAATGTCTAAAATTATTTTAGTCATTGGCTATTAAATCATTGGGGGTTTATTTAGAAATTAGAAATTAGAGCTTAGAAATTCCACTGCAGCGCAGTGGCGTGGTAGGAGAGCATTCTTAATGCTGCGAAGGAGGATCCGCGAGGACCTCTGGAGCGTTAAGAAGAGAGAATGTTGGTATGAGTA
->JPKY01000002.1/344887-343367 Acremonium chrysogenum ATCC 11550 scaffold2, whole genome shotgun sequence. 
-CAATGCGCGTCGCCTCCCCCACAGTCCTCCGATTCTCGTTTTCCGCAAGGAATGTCTATCGTAGACCCCCCTCACAGGCTGGTTTGCCCACGGTGTGCCGCTCTCGAGCCTGTATCAGGACCTCGCTGCCAGCCGCATTTGGATTCACCGTGGTCTCTTGCCGTCGATTCCTCGAGGTCCAGCCTAGCCCGGGGGAACGATGTTTCGGAACTTAACCCTAAGTATACACGTGGTTTTCAGTTTTGCGCTCTTGTCGTTCGAACCGCCTTCTAAGTTGGCCGGGTTGTACCAGGAGACCGACACCGCTGAATAAGCGGAAGGCTGAACGGAACACCTACGCCGACGGACTGCCGGGGAGGACAGCCCAGTCACCTCACGGTGCGCAAGAGGGGGGATGCCATGAGCCGTATCGGTAAGAGCCTCTGGTCTGAGGACGCTCGTCGGCCCTGCCCGCTGGAACTAGCACAATGGTCAAGAGTAGGCCGTCCAGGAGGTGCTGTCGGTTTGAGGGTGCGGAAGTTGCTGGTCTGCTATGAGCTTGACCTCCGGGTCGAGCCTTGGCGGCAAAGGCGTCGGAAGTACGAGAAGAGAGGGTTTGAGCACAGAACTGGCCACAAACAATCAGCCAAGCGTTTCGACATTCTCCGCCCTGAAATGCTGCTTTGCCGGAAAGCCCACTTGCCCGCGAGCCAGTTGGGTTGCAAGGACTTCAGGCTACACACGGAAACGAAAACGGCTGATCATATCCTTCGCCATTCTGCGAAAGCTCTCGGTACCCTCAAACTCGTACAAGTCCCGTCGTCGCTGTTCATGGCAACCACTGCAACCAACCTGCACTTCTTCCCGTGGCTCCCTGTACCGCACCACAGCAGTAGCTACCGGTGTGTGATGCTGGTTGCATCTGGCCTGGCCAAGCGCATTAACGTCCGGCCGTAGGCTCCGTCCTGCGGCTCAGGAAGGCGCCAGTCACTTGTCGCGGTCGTCCCGATTTGCGACAGCTCCCTCCGGTTCGCACTCTTGTGGTGTACCTGGAGACGATAGCTCGGCTTTTATGGATGTCTTTTGGCCGTGCGGAATGCCCTCCTTGCTCGCTCTGTGAAGAGCATCTGGAGAGGAAATCAAAAACCAATCCTTGTTGGCAGCGCAACACAAACAGAAGGAGCTCTCGGTACCGGTCCTGGACTCTTGGAAGGCTATGGCGCGACTGCGCGGAAAACATACGACGGCATCGGGATTTTGCGATACTTGTTTGGGAGAGGCGATACCGGTACATAGGCACTGGCGTCTCTGGGTGCTTATTCCTCGTCACGATTGCTTGCATCACTGGGACCCATCTCGTGTTGGAGTCAAAGTTTCGTACTTGTCCGGCGGTGTTGGTACTGTGGCGTAAAGGACCTGCTCCCAGGATCCTAAGCCTCGTCCCGTCCTTTCATATTGGATCAAGGGGCAAGCCAAGCAGGGAGGCAGCCCCGGCTGTCCTCGTGCCTGAAATGGTGGGAGGACAGCCCCCCTATGGTGAGG
->CP010557.1/4001542-4001177 Raoultella ornithinolytica strain S12, complete genome. 
-TATGGCCGGAGCAGGGGTGCGAGCAGCAAACCTGTCGCAGTTCCTCGAAGCCGGCGTAAAAGAAGTGCACAGCTCCGCCGGCCAGTGGCTGCCTTCGCCGATGCGCTTTCGTAATTCCAGGCTGTCGATGTCTACGGATGCCGAAGCAGATGAATATTCACGCTATGCCGTTAACGGCGCAGCGGTGGCGGAAATGAAGAGCATTATTTCCGCCTGAGTGCCCGCATTGTTTGCGCGCAGCCTGCGGGCTGGTCAGCACAACGGCTGCGGGCAGAGAGAGAAAACCGTTTTTTGCTGCACATCATGTCGCCCAATATGATGATTGCCCGTACCAGGCCCCTGCAATTTCAACAGGGGCCTTTTTTT
->ALWZ043173632.1/1-308 Picea glauca, whole genome shotgun sequence. 
-GATGGGGAATCCTTGTATCAAGGGTGCACTCTGCATGAACATCGAAAGAGAATTGGGTTAATATTCTCGAACCGGGACATGGTGGTGGACGACAATGTTAGGAAATCTAGAGATGTCATCGGGGGCCTGGGAAGAGTTATCTTTTCTTTTTAACGACTTTCCCACCCTAAAATCAGTTCAAATGGAGATAGGGTCTGTAACCTACCCACTACTTAAATCAAATTTTTCCAGTCCTCTGTCAGACTCGATCTCCTAAATAACCACAGAGATCCAACGTAAACTAGCTCTTTCTATTTTCTTCCCCATTC
->JJMO01001155.1/572062-572450 Vigna radiata var. radiata cultivar VC1973A scaffold_43, whole genome shotgun sequence 
-ACGAGGAAGGGCGTAGTAAGCGACGAAATGCTTCGGGGAGTTGAAAATAAGCGTAGATCCGGAGATTCCCGATATAGGTCAACCTTTCGAACTGCTGCTGAATCCACGGGCAGGCAAGAGACAACCTGGTGAACTGAAACATCTTAGTAGCCAGAGGAAAAGAAAGCAAAAGTGATTCCCGTAGTAGCGGCGAGCGAAATGGGAGCAGCCTAAACCGTGAAAACGGGGTTGTGGGAGGGCTATACAAGTGTCGTGCTGCTAGGCGAAGCAGCATAGAATGCTGCACCCTAGATGGCGAGAGTCCAGTAGCCGAAAGCATCACTAGCTTACGCTCTGACCCGAGTAGCATGGGGCACGTGNNNNNNNNNNNNNNNNNNNNNNNNNNNNNN
->HG722747.1/1-1525 Eimeria necatrix Houghton genomic scaffold, Enh_scaff2711 
-AGTGACTGACTATACTCCCCGAGGAAGGTAGGCTTTTCGTGGGCTGTTATAGCCTCTGGGTTTGTGTTCAGTTGTTCACTGAGGTGTGTTTTGTTTGCGTTCGTCAGCTGCACTTTCGAGTACTGGCGTTCTGCGATGCTGTCCTTAACGGTTTCAACCGACCCGTCTTGAAACACGGACCAAGGAGTCTAACATATGTGCGAGTATGCGGGCAGAACCCCTGTATGCACAATGAAAGTGAGAGTAGGGAGAGGTTTTGTTTTTTTGGCAGGCCTCGCACCTACGACCGACCACGAGCTTTGCGAGAGGTTTGAGTTGTAGCACATCTGTTAGGACCCGAAAGATGGTGAACTATGCCTGAGTAGGGTGAAGTCAGGCGAAAGCCTGATGGAGGCTCGTAGCGATACTGACGTGCAAATCGTTCGTCAAACTTGGGTATAGGGGCGAAAGACTAATCGAACCGTCTAGTAGCTGGTTTCTTCCGAAGTTTCTCTCAGGATAGCTGGAGTTCAGTTAGTTTTATCAGGTAAAGCGAATGATTAGAGGCCTCGGGGGCGCGTTGCCCTCGACCTATTCTCAAACTTTAAATGGGTAAGATCCAGCGGTTACTTCACTGAACTGCTGGGGTTAATATGAACTCCANNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNTAGGGTTGACTGGTTGGTAAAGCTTCCTGGCTTCCAGGGAGTCCGGTGCGCTCCTGACTGCCCTTGAAAAGAGGAGGGAAAGTTGTTATTTGCACCCCTGGCCGTACCATTAACCGCATCAGGTCTCCAAGGTTAGCAGCCTCTGGTCGATAGAAGAAAGTAGATAAGGGAAGTCGGCAAAATGGATCCGTAACTTCGGGAAAAGGATTGGCTCTGAGGGCTGGGTGCATAGCGCCAGTGCGTTCTTCGTTGGTCGGAGCTGTGCGGGCCCGTTCGTGCTTCGCGGCGCGTCTGTGGACCGCCGGCACTGACTGCGTTGTGACCCTTGGTCTGCGTGCACAGTGAACAGCTAACTCAGAACTGGAGCGGACAAGGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGATGGCCGCAAACGGTGTTGACGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAATGTGATGAAATTCAACCAAGCGCGGGTTAACGGCGGACGTAACTATGACGTGGAAAATTTTGCTTGCTGGGTTTTTGGAGTGAGTGGTCCTCCCCAAAGAAAAAGGAAAGAGATAGTTTGTAGGGAGCCTCAGCTCCTACGGCACGCCCAAAGTCTAGGGCCAACCGTTTTCACTCGCCATAACATACATCTACTACCGAGAGTGACTAAGTATAAGTGCATCATTTGTGTACTATTCACTGCATGTTGGCTGTGCGAGAGCGATTTCCTCCTCGCGCCCGCCTTGATCCATTGTCAGCCACGTGAAAACCCCAGAT
->AVBC01000026.1/54293-54503 Halomonas huangheensis strain BJGMM-B45 contig41_scaffold4, whole genome shotgun sequence. 
-TGAGCGCACACCGTCTCGGCTTTCCCGCAGATGTGTTGGGGTGAAACGGGAAGTCGGTGATATTCCGACGCTGCCCCCGCAACGGTGATCGAGTTAAATACGGCCCATGAACGCCACTGTGTACTGCATGACAGTCACGGGAAGGTGGTCGTATCCAACACCCTGTGTTGACTCGTCAGCCCGGAGACCGGCCTGAGATTCCATGCCAGGG
->URS0000D67C52_12908/1-206 unclassified sequences RAGATH-7 RNA 
-ACUAUACCGCUUUAUUAUGCACAAAUAAAGUUAAAGAUUGUAUAGUAAUCCACGUGGUAGAGGCACAGUUAGGUUCGCUGUGGUGCAACUCUUAGUAGCAACUAAUCUAAAGCAAGUAUGGGAGAAUAGGUUUAAACUAUUUUUAGGUAGUUAAAAAUACGUAAAAUCCGAUCCUAAUAAGGUAGCAUGAUAGUAUUAGUGCAGAU
->CM000812.5/30921558-30921482 Sus scrofa isolate TJ Tabasco breed Duroc chromosome 1, whole genome shotgun sequence. 
-GCTGTACATGATGACAACTGGCTCCCTCTACTGAACTTCTATGAGGAAACTGCCATGTCACCCTATCTGACTACAGC
->HE717023.1/2219309-2219667 Halobacillus halophilus DSM 2266 complete genome 
-TTCCCATAGAAGTACTCTGGAGTTTATTTTTCCGAGTTTCTATGGATTTTTTATGTTCTTATCATCATTTGTGAATTATCACGTATTACGTGTAAGAAGTTTTTAGGAGGATTCATATCATGCAAAACGGTACAGTAAAATGGTTTAACGCGGAAAAAGGTTACGGCTTCATCCAAGTAGAAGGTGGAAATGATGTATTCGTACACTTCTCTGCAATTCAAGAAGAAGGTTTCAAATCTCTAGAAGAAGGTCAAACCGTTTCTTTCGAAATTGTTGAAGGCGACCGCGGACCACAAGCAGCTAATGTTGAAAAACAATAAATAAAATCCAAAGCAGCCTCTATAGAGGCTGCTTTTTTT
->CM002888.2/48184797-48184945 Danio rerio chromosome 4, GRCz11 reference primary assembly. 
-AGACAATCGCGGCTTCTCGTTGGACAAGAGTCTACAGTCTACAGTTACCATTGCACGTTCCCTGGGCAGATGTCTGCGAACTCCCCAAATGTGGGAATCTCGACTGCATAATTTCTGGTAGTGGGGGACTGCGTTCGCGCTCTCCCCTG
->LXTC01000002.1/1795932-1795468 Metschnikowia bicuspidata var. bicuspidata NRRL YB-4993 METBIscaffold_2, whole genome shotgun sequence. 
-ATGCCAGTATCAATACCAACACCAGTGTCGAATCAATTAATACCAACACTGAATACCAACACTAATGAATAGCTAAACCAGGATAGACACCAACAAATACCAACACTAAAGACCAAAACTAATAAATACCAATACAAGTATCAATACCGATAAATACCAACACCAATAAAAACCAATACCAATAAATACCAATACCAGTACCAACACCAATATCAATACCATTACCAATTCAACACCATTATTGGTATTCAGTTGTAAAAGGTGAAATTCTTAGATTTTCCAAAGACTAGCTACTGCGAAAGCATTTGTCAAGGACGTTTTCATTAATCAAGAACGAAAGTCAGGGATCGAAGATGATCAGATAGCGCCGTAGTCTTAACCATAAACTATGCTGACTAGGGATGGGGCGACGCCTCATGTAAATGACAGGCCCAGCACCTTACGAGGTATCAAAGGTTTTGGGTT
->AVOS01044062.1/5145-5403 Chaetura pelagica isolate M959 contig44062, whole genome shotgun sequence. 
-CATTAGGGAGGGAGAAGATCATGCTTCATTTCAGACCTGCTTCTCGGTTCAGGATTTTGTGAGATTTGGTAGTTTAAATTTTTTTTTATGTCTTATTTGTCAGCTACACTGACTGGCTCAGCTTGTGTCTGCCCTCTGCCGGCAGGCATGGGTAACCCATTGAACCCCATTTGTGATGGGGATTAGGGATTGCAATTCTTCCCCTTGAACAAGGAATTCCCAGTAAATGCGGGTCATAAGCTCGCATTGATTAAGTACC
->GL433863.1/231672-231585 Chlorella variabilis unplaced genomic scaffold CHLNCscaffold_29, whole genome shotgun sequence. 
-GCACCTATGGTGTAGTAGGTTATCACACTCGCTTAGTAGTGCTCTGTTGAGTAGCGAGAGGTCTGCGGTTCGAATCCGTGTGGGTGCA
->LCQF01000020.1/16551-16970 Parcubacteria bacterium GW2011_GWA2_49_9 UY50_C0020, whole genome shotgun sequence. 
-CTGATGGGAAACAAGGGCGTATGGTGGATGCCTTGGCTTAAGAAGGCGATGAAGGACGCAGCGTGGCGGCGATACGCTCCGGGGAGGTGCCGAGCAACCTTTGATCCGGAGGTCTCCGAATGGGGAAACCCTTCCGTGTAAACCACGGAAGCCGTGTCTTACACAGAATGTCTAATTTCTAATTAACCTAATTCACCTAATAAAATTCCAAATACCAATACCAAATATCCAAACCGGACTTTGTGATTGAGCATTTCTTTACTTTGGGTTTTTATTAGAAATTAGAATAATTAGATGAATTAGGAATTCCGCGTAGGACGCGGCGCGTACCCTGGGAAGTAAAACATTTCAGTACCAGGAGGAGTAGAAACCAATAAGTATTCCGTCAGTAGCGGCGAGCGAACGCGGAGAAGCCCAAAC
->LCPW01000021.1/2447-2376 Candidate division CPR1 bacterium GW2011_GWC1_49_13 UY40_C0021, whole genome shotgun sequence. 
-AGCGCGGAAGCCGAGTGGTGAGGCGGACGGGCCGCAACCTGTCGGATGAAGGTTCGAATCCTTCCCGCGCTT
->JXRR01000014.1/312777-312893 Jeotgalibacillus campisalis strain SF-57 contig00014, whole genome shotgun sequence. 
-AACCTTTTTAATTAAAGTCCAGAGAGGCTTTCAAAAGGGAAGAGCAGCTGCCGCTAAATGTGATGCAGTGTATCTTTTGAACACCTTTTGAGGGCTTTTCTCAAAAGGTGTTTTTTT
->JH207677.1/46913-46403 Pelodiscus sinensis unplaced genomic scaffold scaffold782, whole genome shotgun sequence. 
-GTTTTCACTTTTTTTGATTGTATCCCTTTCGTATATACGGTCATGCCAATTTTCTTCCACAATTTCATCTGAGGAAGTGGGTCTGGCCCACGAAAACTCATCACCTAATAAACCATCTTGTTAGTCTTTAAAGTGCTGCATAGTCCTGTCTTTTGTTTGAGAAAAAAAAAACAGGTTCCAACTAAAGTAAAAAGTTTGGGAAACCCTGGTCTAGCCAGCTTTCTCTCCATCTTACAGTCCATTTATCCAATCCATACTCCCTTAACTTGCTGGCAAGGATATTGTGGATGACCGTATCAAAAGCTAGAGGTGAAATTCTTGGACCGGCACAAGACGGACCAAAGCGAAAGCATTTGCTAAGAACGTTTTCATTAATCAAGAACGAAAGTCGGAGGTTCGAAGACGATCAGATACCATCGTAGTTCCGACCATAAACGATGCCGACTCACGATCCGGCGGCGTTATTCCCATGACCCTCCAGGCAGCCTACAGGAAACCAAAGTCTTTGAGT
->URS0000D6955D_12908/1-88 unclassified sequences c-di-GMP-I-GGC riboswitch 
-GUUGAAAAAGGUACACUAUCCCAAAGGGUAGGCCGCGAAGUUUUGGGUCUAAAUCACUUUUAGUGACAUGAUUGCCAAGCUGCCGAUU
->CAWC010010349.1/2261-2560 Onchocerca ochengi, WGS project CAWC01000000 data, contig: 07842_10349 
-TAGCATAGATCCGAAAGATGATGAACTATACTTGAGCAGGATGAAGCCAGAGGAAATTCTGGTGGAAATCCGAAATAATTTTGACGTATAAAACGATCGTCTAACTTTGGTATACAGGCGAAAGACTAATCGAACAATCTTAGTAGTTGATTCCTTTTGAATTTTCCCTCAGAATAGCTGGAATATGTAATGAAGCTGTTATATTCGATAAAGTGTTTGATTGGAGGAATAGTGGGACGAAAAATTTTCAGTCTGTCCCCAAACTTTCAAATGAATATGATATTTCGTTTGCTTGAATGA
->URS0000D6BF5F_12908/1-247 unclassified sequences ARRPOF RNA 
-CTAAACCCTACAAGAATATTTTCAAAAAATTTCATCATACAATTTGTGATGAGCTGATAGGCACTAATCAGTCCAAGTCTTTTAAAGGTTGGTAGGAATTGTTGCAACGTGAGGACAACGGAACAAAGGTCAGGTGGTTTATTGTTTTGGGGTGTCTTTTATACCTTTATAAAACTGAATGTAGGCAGTTAAGGTCGAACACGTGGGCAATAAAGCGTGGATTGTATCAAACAAGTAAAAGGCAAGT
->CAWC010018757.1/493-342 Onchocerca ochengi, WGS project CAWC01000000 data, contig: 15636_18757 
-TCGTTGCGATGGTAGTCATGCTCAATATGATAAGAACCATTGGTTTAGACATTTAGTTCATATGCTTGGCCGATTATACAATGGTGTGAAGCTATCATTTTCGGTACTATTACTGAGTGACTCTAAGTTAGAAATCCTTCTGCACATGATGA
->AASG02003498.1/19751-18974 Ricinus communis cultivar Hale ctg_1100012349913, whole genome shotgun sequence. 
-TACTTGGTTGATCTTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCCATGCATGTGTAAGTATGAACTAATTCAGACTGTGAAACTGCGAATGGCTTATTAAATCAGTTATAGTTTGTTTGATGGTATCTGCTACTCGGATAACCGTAGTAATTTTAGAGCTAATACATGCAACAAATCCCAACTTCTGGAAGGGATGCATTTATTAGATAAAAGGTAGACGCGAGTTTTAAGAAACGGCTACCACATCCAAGGAAGGCAGCAGGCGCCCAAATTAGCCAATCCTGACACGGGGAGGTAGCGACAATAAATAACAATACCGGGCTCTTTGAGTTTGGTAATTGGAATGAGTACAATCTAAATCCCTTAACGAGGATCCATTGAAGGGCAAGTCTGGTGCCACCAGCCGCGGTAATTCTAGCTCTAATAACATATATTTAAGTTGTTACAGTTAAAAAGCTCGTAGTTGGACCTTGGGTTGGGTCGACCGGTCCGCCTAGCAGTGTGCACCTGTCGTCTCATCCCTTCTGCCGGCGATGCGCTCCTGGCCTTAACTGGCCGGGTCGTGCCTCCGGCGCTATTATTTTTGAAGAAATTAGAGTGCTCAAAGCAAGCCTAAGCTCTGTATACATTAACATGGGATAACATCATAGGATTTTGGTCCTATTCTGTTGGCCTTCGGGTAAAAGAAATTATGGCACAGCTAAGAGTTGATTGTACTTCGTCAATTAAGAGCATCAGATCTTGCAGTCTAATGAAACCTTAGCAGAACAATG
->ABGB01000728.1/1246-78 Enterocytozoon bieneusi H348 ctg01_1523, whole genome shotgun sequence. 
-TGTGTGGAAGTTCCGGAGCAGATCTTGGAAGTAGTAGCATCATTTGTATGTGCCAATGGAGGCGGGTTTGTCCTTTTAATAGAAGGAAGTGATACGAGCCTAGTAAAAGGGAATATAGTAGATATTCTATATAGATGTACCTATGTGGCGACACGACAGCGACCCCAACGACGTGTGCCGGTGAGAATTTTCCGGGACACCCAGATCTTATGAGCGTCACGCTGAGACTAAGAACGAGTTGGGCGGTGAAAATGAAGGAACATCCTCGTACCGAACCGCAACAGGACTCCTAGGTGAGAAGCCTAAGGCATAATTGTAATGTGAGCAAGGGAAATCGGCAAAATGGATGAAAAACCTCGGGATAATCATTGGCTCTAGCATGCTAGAACTGGGCTTACAAGGGGAATCTGACTGTTTAATAAAAACATAGCTTTGTGTGTACGCAAAGTGAATTCTGCCCAGTGCTTGGGACGTTAAGGAAGTAATTTTAAGTACGCACCTGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCGCCTAATTAGCGACGCGCATGAATGGAGCAACGAGATTCCCACTGTCCCTGCTCACAGATTTGCGAACCTACAGCCAAGGGAACGGGCTTGGGACATGCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGCCAAGCACAGGCCTCTGTGACTATATCGTAGCGAGGTGGGAGAAATGTGTGAGACCACTGACATAGTCGGCGGGGGCACTCGCAAAGCTTGGTGGGGAGTTTGGCTGGGGCGGCACGACTACTAAAACATAACGTAGACGTCCAAAGGTAAGCTCCGAGGGGATGGAAACCACTCCGAGAGTATAAGGGCAAAAGCTTGCTTTAGTTATTAATGTAAATTAATAATACTGGAAACAGGGGCCTAGAGATCCTCTATGAAACTAAGCATAGAGGTGACGGAAAAGTTACCACAGGGATAACTGGCTTGTGGCGGCCGAGCGTCCATAGCGACGCCGCTTTTTGATTCTTCAAGGTCGGCTCTTCCGAGCATGGGGGAATATCAGCCACCAAGTGGTGTGATTGTTCACCAACTTACAAGGGAACGTGAACCTGGGTTTAAACCGTCCCGAGAAAGGGTAATTTTTACCCTACGGCATTCCCTT
->CP006019.1/170272-170332 Palaeococcus pacificus DY20341, complete genome. 
-ACCGGTGATGACTTTGCAGGGTAGCTACTGAAATTGATGAAGAAGTCGCTCCAGTCTGAGG
->LDJP01000070.1/64830-64953 Stenotrophomonas daejeonensis strain JCM 16244 contig_70, whole genome shotgun sequence. 
-CGATGAAGGCGAACAGCTTCCAGCACGAATCCAGCGCCGCCCGGCAGGCCACCGGCATGACCTCGCGCGCGCGTCGACCGGAACCCCACATCCTCGCTGGGTAACCGGAGCTTCGTGCTGTCTG
->CP001043.1/1023491-1023327 Burkholderia phymatum STM815 chromosome 1, complete sequence. 
-ATGAGTGCCTGTTCACATACTTTTTTCCGCAGTTGCGCTGCAGATCGCGTAGTCGTCGTCGCTGACCACAAGGCAGTGACAACGGCAATGAAGCGAGCCACGAGGCGCCATGCGATGACCGAAGTCGAGCCGCTTGCCCCGGTTGCCGGGGCGGCGGCTTTTTTA
->URS0000D6A032_12908/1-68 unclassified sequences type-P1 twister ribozyme 
-AAUUUAACCUCGCCUUAUUAUUUAAGAUAAUAUGCUGGUGACAAGCCCAGAUAAAGAGGGAGUCAAAU
->MHIB01000050.1/15016-14517 Candidatus Buchananbacteria bacterium RIFCSPHIGHO2_01_FULL_39_14 rifcsphigho2_01_scaffold_9139, whole genome shotgun sequence. 
-CAAGTAAGCAAGGTGGTCGCCCCCTCACTTGGTCCGATGATTAGTATTTAGGAAACATAAATACCTTATATATTTAATCATTAAGCCAAGTGAGGGGGAGGAAAGTCCGAACACCATTCCCGATTTAATGTCGGGGTAAAATGGCAACTCCTAACGGGAGCCGAGAGTAACAAAAGAGTAGAAGCGCTTAAGACTTCTGCACTTTTGCCAAGCTTAGGGCAAGTGCAACAGAAAATATACCGCCTAAGTCCTCCGCAGTTGCGGTGGAACGGTAAGGTTGAAATCGTGGGCCCACCTTTGGGTGGGATACCCTCGCTTCGGCGAGATAAAGTAAGAGCCCACGGCCGACAGACTGGTAACAGTCGGGTTGGTAAACTCCTGCCTGGTGCAATGCCAAATTAGGTAGGCAGCTTGATCCCGACGGCAACGTCGGGACCAGATAGATGACCACCCCCCTTAAAAGTGGGTGACAGAATTCGGCTTATTAGCTTACTTGGATA
->AFTD01027444.1/26113-25813 Cricetulus griseus cell line CHO-K1, whole genome shotgun sequence. 
-GGATGGGAGGGCCATATAGCTGTAGCTCCTTTCATCTCATTGACTACCAGGACTGATTTGGTTGGTCTGACTGGATTGATAGGTGTCCCCTTCCTCCCTTGTTGTGCATCTCTCTGGAAGCTGTTTGCTCAGCTGGTCAAAGAGGATGACTTTTCCCTTAATAGAGGACCAGTCTTTGGTCAAGGGCATACAGGTAACTACCACCTCTGTTAAAAGCTCCAAACAAGCACTCAAGAGCCTGCCTATATATTTGAAAGAGATCAGACTTTGCCTCTAGGTGGTGCCTTGAATGGCTGTAAGA
->NGMM01000004.1/415496-415725 Enterococcus sp. 9E7_DIV0242 scaffold00004, whole genome shotgun sequence. 
-AAATAGACAGAGAGCAAGAGGAGTACTGTCAGCGGGATTTTTAGAGAGAAAATCGGCTGGTGAAAGATTTTACGATCCTGACAGGAAGGTAGCTTGTGAGTCAATCATTTGAACAATTTTCAGTAGGGTGGTTCGAGTCGTGATCGTTATCTCACGTTGAATGAAGAGGTAATTGATTTATTTGATCAATTACAAATTAGGTGGTACCGCGTAGTATTTACGTCCTAAAA
->HF991826.1/221174-221022 Clostridium sp. CAG:678 genomic scaffold, scf125 
-ATCAACTACTCAGTACTAAATAATTGAGCCTATCTCAGTAACAATGGTGCGTTCGTTTGAACAAGTTGACTACCCTAAGTCTTGAAACAGAGGCTACGTTATACAAGAATATATAGTCACCGGTGGGCATTTGCCCTAACCTGCCGCTCTGAG
->LK878649.1/3737-3610 Ascaris lumbricoides genome assembly, scaffold: ALUE_scaffold0006683 
-TTACTAACCTTCATGGCGAGGCTTGGTCATTGCACTTTCGACCAGGCTGACCCGTGTGGCAGTCCCGAGTTGGGATTGGCCAACAGCATAATTTTTGCGTTTGGGGACAGCGTTCGCGCTTCCCCGCT
->ALWZ041214672.1/20-119 Picea glauca, whole genome shotgun sequence. 
-ATATTTTTAAAAATTAACGTGATAGTACAATTAAGCATGCTCGAGACAGAGTAGTATTAGGATGGGCGACCGCTAGAGAAGTCCTAGTGTTTTACATGTC
->JH601103.1/54151-54248 Dolosigranulum pigrum ATCC 51524 genomic scaffold supercont1.1, whole genome shotgun sequence. 
-GAAGCACAAATCTGAGCAAGCGGTGAATAGGTGACTATTCATGCAGCCCGGCTACTAAACGTAGCAGCAGAGTGTTAAGGCACATCTGTGAGACAGTT
->LVLJ01000773.1/73947-73799 Marchantia polymorpha subsp. polymorpha scaffold3569, whole genome shotgun sequence. 
-ATCTTTGCGCGTGGGGCAATGACGCAGTTAGTGAGGTGAAACCGAGAGACGCGTCAATTGCTGGTTGAAAACTATTTCCAAACTATTTGCATACTACGAGTTCGTTTTAGTGCAATTTCTTCTTTTCTCCCTTACAAAAGCGTAAGAAA
->AGUA01000030.1/104638-104479 Staphylococcus pettenkoferi VCU012 contig00012, whole genome shotgun sequence. 
-GTAACAAGGGGATAACGAATAAGGTGATTTAGGGGTAGGCTATTACATAATATAATAGTTACAATCTCTTGTTCGTATGCGTTACTATTCAAACATCTTCAATATTTATTACTTACTTTCCTTTCTATTTGCCGACTAGCGATGACTAGTCGGTTTTTTA
->JH205222.1/90660-90343 Pelodiscus sinensis unplaced genomic scaffold scaffold192, whole genome shotgun sequence. 
-GTCTAAGTAAACAAGGGCGTTACAGTGAAACTGCAAATGGCTCATTAAATTAGTTAGGGTTCCTTGGATCGCTCCAAGCCTTACTTGGATAACTGTGGTAATTCTAGAGCTAATACATGCTGACGAGTGCTGACCTCCGGGGATATGTGCATTTATCAGACCAAAACCAACCCGGGCTTGCCCAGCTGCTTTGGTGACTCTAGATAATTTCGGGCCAATCGCACACCTCCATAGCAGCAACGATGCATTCGAATGTCTGCCCTATCAACTTCAAGAGATGTCCCCATGGGTACTTCACATCTAAGGCTTCATTTTGTT
->GG700633.1/173169-173635 Leptotrichia hofstadii F0254 genomic scaffold Scfld1, whole genome shotgun sequence. 
-GGCGGGCGAGAATCCCGCCGGCCGGAAGTCCAAGGTTTCCAGGGGAAGGTTTGTCCGCCCTGGGGAAGTCGGGACCTAAGCATAAGCAAAATTGTGATGGCGAATGGAAAACAGGTTAATATTCCTGTACCGCTGTTATCGCCTGAGAGACGGAGTGACGCAGGAAGGTATGCGGGAAGGCTGACGGAATAGCCTTTCTAAGGGCGTAGCATGGGCATGCAGGAAAATCCGCATGCCTAAATGTGAGACCTGACGGGTAAGTGCATCTTGCATAAGCCGCAGATCCTACACTGCCGAGAAAAACTTCTATCGATGAGAGCCAGCGCCCGTACTGTAANNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNTATAGCGGAGCCGAAGGGAAACCCGAGTCT
->DS990197.1/12350-12464 Ruminococcus lactaris ATCC 29176 Scfld_02_34 genomic scaffold, whole genome shotgun sequence. 
-GGATGCCAGGGTCAAAAGGTCTAAACCCACATGAGCTTGCTCATAGGTGGGTGAAAGACCTTAGGACCCGCCCCGATATGAGCATCAAAGTCGGGGGCTTTTGACCCCGACATCT
->CM003380.1/18255055-18254968 Vigna angularis cultivar Jingnong 6 chromosome 10, whole genome shotgun sequence. 
-ATGAATGCTGATGCATGCACTGGGCTCTGAGAAGTTTTAACCTCAACTTTTGATGAAAATGCACGGCCTTGAAAGCTATTTCTGATAC
->CP000673.1/1358718-1358907 Clostridium kluyveri DSM 555, complete genome. 
-TATGTGGCAGTGAATAGAAGAAGTAAATATATTCTTATATGTAAAGAGAGGAAGTAGAGGGTGTAAAGCTTCTCATATGAGGTTTATTGAAGGCTGTCTAGGAGCCTATTATGGTGTTTGAGAGATATGGATTTTATAATTTTAAATCTATATAATTAGGGTGGTACCGCGAAAAACTTTCGTCCCTTTT
->MKSM01000113.1/13291-13495 Nitrobacter sp. 62-23 SCNpilot_cont_300_bf_scaffold_662, whole genome shotgun sequence. 
-CTTGTTTGCGGCGTCATCGGTGCCTCCCGAGGGAGGTGAAACGGGAACGCGGTGCGGGGATATGACCCCAACGCCGCGGCTGCCCCCGCAACTGTAAGCGGCCATCCGCGTCCATTCCGCTGCCGAACATGCCGCGCATGTGAGGAAAATCGGATCCGGATAACGGCCGCGAGCCAGGAGACCGGCCGGCGACGCCTTCGGAGCA
->CP011125.1/5773983-5773818 Sandaracinus amylolyticus strain DSM 53668, complete genome. 
-AAGAGGGAAGCCGGTGAGAAGCCGGCGCGGCCCCCGCCACTGTGACCGGGGACGGCGCGGACGCGGTGCGAGCGCACCGAGTCACCACTGCGCGTGCTCGTCGTGTGAGCGGCGGGGCGCGGCGGGAAGGTGGTCCGCGACGGACGATCCGGGAGCCAGGAGACCT
->CM009294.1/24125792-24125654 Populus trichocarpa isolate Nisqually-1 chromosome 5, whole genome shotgun sequence. 
-TAATTTATTTGGGGAAGATTTTCATCTAGTTGTAATATATTTATATTTGATTGCTCAGAATCATCAGTTATTATAAAATTAACTATATCATTGACCCTTATAAAATATATTTAGAAAAAATTGTTTATAAAATCATGAT
->ALWZ044874107.1/2364-1677 Picea glauca, whole genome shotgun sequence. 
-GGGTTTTTCCTTTTGTGGAATTTGAATTTTTATGTTTTTTAATTTTTTATTATGTTATAATATATATAATTATAACACACACACACACACACACACAATATAACCTTATAATAGTCGACTCAGAGCTATTTCAGACAAGGGGAATCTCACTATTTAATTCAAACAAAGAATTGTGATGGTCCTTGTGGATGTTGACGCAATGTGATTTCTGCCCAATGCTCTAAATGTTAAAGTGAATAAATTCAACCAAGCACGGGTAAACGACGGGGGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGCCATCTAATTAGTGATGCACATGAATGGATTAACTAGATTCCCACTATCCCTATCTACTATCTAGTGAAAACACAACCAAGGGAATGGGCTTGGCATAATCAACACGGAAATAAGACCTTGTTGATATTGACTCTAGTCCAACTTTGTGAAATGAATTGAGAGTTGTATAATGATCCAGATTATTTTTGGCACGAAACGAGAGCGGAGATATAACACAAAAATATTCAGAGATATTGCAAGAGAGACAAAAATATAACAATGATATATCATAAATATAACAAGAGTCACATATATAAAGTAATACATGATTTCTATTAATGAAAGAAATGTACAGAGATTGTAAAAATATAGAGTGAAAGACTTGCTAGAATGGTGGCAGCTT
->JH835382.1/3324878-3324510 Erinaceus europaeus unplaced genomic scaffold scaffold00094, whole genome shotgun sequence 
-GGATGTGAGGGCGATCTGGCTGAGACATCTGTCATGTCATTGATCATCAGGGTTGATTTAGCTGGTCTAGATGGCTAGGCAAGTGTCCCCTTCCTCCCTTGCCACTCCATGTGTGTCCTTCCTAAAGACTTTGGGTCTTTGGGACCTATGTGTGCTGGGTCGAAGAGGAAGGCCTTACCAGAATAGTGACTGACCGGTATGCTCGGTAGAAGGTATACAAGTAGCTGTGCTCCCCTGCTAGAGCCTCCATACAAGCTCTCAAGAAAGTTGCAACTGTACTGAGTTTGTAATTGCTTTGATTGATGGCTACTATCTCTGGCAACATTCTGCCTCACCTCAGGCTGGGCTCTCACACAGATGCTCTCTCCT
->KI930470.1/1116-1201 Candidatus Entotheonella sp. TSY2 genomic scaffold TSY2_scaffold00655, whole genome shotgun sequence. 
-GAGAGCCGGATGCAGCGACAAGTTGCATGTCCGGTTCGGAGGGGGTTTGACGCCTAACCTCATGGGCTAGTCGCTTACTACCCTAC
->AZIM01000385.1/98908-98846 Ophiophagus hannah scaffold386.1, whole genome shotgun sequence. 
-AATGGTGTTTATGACATAGTTAGATTAAAGCCTTTGGGAAGTCTAATTGCTGATGTTGCCATT
->AZFW01000017.1/10903-10974 Lactobacillus harbinensis DSM 16991 NODE_20, whole genome shotgun sequence. 
-GCGAATGTAGTTCAGTGGTAGAGCAACAGGTTTTCCAACCTGTGGATGTAGGTTCGACTCCAACCATTCGCT
->AACY023338535.1/830-742 Marine metagenome ctg_1101668145886, whole genome shotgun sequence. 
-TTTCCTTTACACTTCTCAAACCGGGATCAAGAGAAGCAAAGCATCCCTCATATCCACGATGGAGGGTGTCGTGGAGTATACTGTACCAA
->CAJW011240374.1/263-1 Hordeum vulgare subsp. vulgare, WGS project CAJW01000000 data, contig: morex_contig_1240374 
-CTCGAGCCGAGGTCCGAGTACCAAGCGCTGCAGCGCTGAAGTATGAGCCCCGTGGACTAGCAATTGCTTCTCCACGAGGCTCATACCAGGCGCTACGGCGCTTAAGTATGTAACCGATGCCATACTCCCAGGAAAAGCTCGAACGACCTTCAACAAAAGGGTACCTGTACCCGAAACCGACACAGGTGGGTAGGTAGAGAATACCTAGGGGCGCGAGACAACTCTCTCTAAGGAACTCGGCAAAATAGCCCCGTAACTTCGGG
->ACTA01130975.1/19881-19796 Ailuropoda melanoleuca scaffold1408_79, whole genome shotgun sequence. 
-GATCACGGTGATGGCTGACCAGGGCTCCTTGACCTATACAGACCTCTGCTATGGGGGTGATGGCCAGTCCTGGTGTCTGAGTGATT
->ABAV01023618.1/749-1 Nematostella vectensis strain CH2 x CH6 NEMVEscaffold_317_Cont23618, whole genome shotgun sequence. 
-ATTGCTGACTCTATGGGAGACAAGGATGACCTAAATTTTAACAGATTAAGAGTACTGTAAGTAATATTTGAAAGGTTTACTTCTAAAACTTGTGATTTAGACTCATAATATATATTACAGAATGGCAAAGTTAAATTAAGAAACAGCAGGAACTTGGTTCCATTGCATCAATAAATTATGCTCAATTCATTTTCAGACAGTCTTGAGGGCCCGTTTCTTGTCAAGAGAATCAAAACTCTTCCAAAGACTGGCCTTCTCAAAACCTTGGTAACCGAAGCCGGACAGTGAATGCGAGTTCCTAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGAACGCGCGGTTAAGGTGCCAAAGTCGACGCTCATCAGACCCCACAAAAGGTGTTGGTTGCTCTAGACAGCAGGACGGTGGCCATGGAAGTTGGAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAAGCAACTAGCCCTGAAAATGGATGGCGCTCAAGCGTCGCACCTATACCGTGCCGTCGGAGCAGATGCGAAGCTCCGACGAGTAGGAGGGCGTGGGGGTCGTGACGCAGCCTCTGGCGCGAGCCTGGGTGAAACGGCCTCCAGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAGCTTTGAAGACCGAAGTGGAGAAAGGTTCCATGTGAACAGCAGTTGGACATGGGTTAGTCGATCCTAAGAGATAGGGAAATTCCGTTGCAAGCG
->AWWV01004333.1/1226-446 Corchorus capsularis cultivar CVL-1 contig04341, whole genome shotgun sequence. 
-GGGCCAAGGGACAGTCTCAGGTAGACAGTTTCTATGGGGCGTAGGCCTCCCAAAAGGTAACGGAGGCGTGCAAAGGTTTCCTCGGGCCGGACGGAGATTGGCCCTCGAGTGCAAAGGCAGAAGGGAGCTTGACTGCAAGACCCACCCGTCGAGCAGGGACGAAAGTCGGCCTTAGTGATCCGACGGTGCCGAGTGGAAGGGCCGTCGCTCAACGGATAAAAGTTACTCTAGGGATAACAGGCTGATCTTCCCCAAGAGCTCACATCGACGGGAAGGTTTGGCACCTCGATGTCGGCTCTTCGCCACCTGGGGCTGTAGTATGTTCCAAGGGTTGGGCTGTTCGCCCATTAAAGCGGTACGTGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCCATATCCGGTGTGGGCGTTAGAGCATTGAGAGGACCTTTCCCTAGTACGAGAGGACCGGGAAGGACGCACCTCTGGTGTACCAGTTATCGTGCCCACGGTAAACGCTGGGTAGCCAAGTGCGGAGCGGATAACTGCTGAAAGCATCTAAGTAGTAAGCCCACCCCAAGATGAGTGCTCTCCTATTCCGACTTCCCCAGAGCCTCCGGTAGCACAGCCGAGACGGCAAGGGGTTCTCTGTCCCTGCGGGGATCGAGCGACAGAAGTTTTGAGAATTCAAGAGAAGGTCACGGCGAGACGAGCCGTTTATCATTACGATAGGTGTCAAGTGGAAGTGCAGTGATGTATGCAGCTGAGGCATCCTAACAGACCGGTAGACTTGAACCT
->LWDE01000750.1/11196-11290 Tilletia controversa strain DAOM 236426 scaffold_750, whole genome shotgun sequence. 
-GACGACGTGCCGGAGTGGTTAACGGGTGCGCCTGCTATTCTTAGCATGTCAGTGTATAGGCTCTGCCTGCGTGAGTTCGAATCTCATCGTCGTCG
->MGWF01000052.1/10424-10220 Firmicutes bacterium GWF2_51_9 gwf2_scaffold_5678, whole genome shotgun sequence. 
-GCATAAGCTGTGAACGGGAGTAGTAAACGTCACGCTTCATTCAAGAGAGCCGCTCCTTGGTGCAACGCGGTATGAAGCAACGTCGAACGTGTCCGGGAGCTGGTCGTGCGAAAGTTGAGTGCGATCCGTCGTCGGCGTTAACGAACAGAGTTGCCGGGAGAAATTCCCGGAAGTTAGGTGGTACCGCGTCAATCACGTCCTTTCA
->CM001219.2/34740290-34740361 Medicago truncatula strain A17 chromosome 3, whole genome shotgun sequence. 
-GTGAGTTTAGCCCAGTTGGTAGGGATATTGCATATTATATGCATGGGCCAGGGTTCGAACCCTGAACTCTCC
->CBUS010004920.1/7915-7704 Eimeria acervulina, Houghton, WGS project CBUS01000000 data, contig: Eah_scaff963_1 
-TGAACGATCCTAAGTATTGCTCCACGAGTGGCAGTTACTCTAGGGATAACGCGTTGATCTCCCCGGAAAGTTCGTACTGGCTGGGAAGGTTGGCACCTTAATATCGGCTCGTCGAATCGTGAGGCTAAAGTAGGTGGGAAGGCTTGGCCTGTTCGCCCAATAAAGCGCCACGTGAGCCGGGATCAGAACACCGCGGAATAGCTCGGTCCATA
->DS563006.1/382953-382865 Cavia porcellus supercont2_151 genomic scaffold, whole genome shotgun sequence. 
-GGGTCAACAATGACACCCCAGCTGCATTCCCTGGAGCTGAATAAAATGGTGCGAACACTAAGCCATCATTCCCAGCAGGCCTGAGGTCC
->LMSO01000009.1/146994-146864 Arthrobacter sp. Soil782 contig_4, whole genome shotgun sequence. 
-GGTAACGAGTGACAGTGCGGCAGGTTCCACCCGCCATCAGCCCCGGCTTGCTGTCCGGCAACCCTCCCTCGCGGCGGGGTGCCCCGGGTGAAGACCAGGCCCTGCATGCAGTGCAGGAGCAAGCGCGATTC
->BBWW01000001.1/3012297-3012404 Leptolyngbya sp. NIES-2104 DNA, contig: contig1. 
-GGAGAGGTTGCTATAGGTAGGGCAAATCGTTTGCTAAACGAACACCTTCGGTGCAGCGAAGCTAGCGAGGATTAATCCCCTCTGTGGGTTCGATTCCCACTCTCTCCG
->LCQR01000039.1/11318-11692 Parcubacteria bacterium GW2011_GWF2_50_9 UY62_C0039, whole genome shotgun sequence. 
-ACGCTGAAATAAGCGTCTTGTTGTCCCTTCTATCAGTAATGATAGAATTAGTATGCGGCTTATAACGGTGGAGCGAGAATCGGTCTTTCCTCAAAAGAGGTTTTCGTATTCTCGTAATACCGTGGGAAGTCCCACTACTTAAGTAAAGTGGGACCCCGTAACGACTGGATTCGAGTCCCGCCAACAGGCGAGATAAGATGAAGATAGTGGATGCCCGAGTGCTCGATGTTCGAATAGCACCGCTATAATACGCCGCCTCCAGCCGTAATTTTTGATTGGGCTTTAAGGTTCAACCTTCTTCCCGATTCAAGATTGAACCTTGGAATCAAAAATTACGGCTGGATGAAGATATAGTCTAATTATCGAAAGATAAAT
->CM001001.2/99651431-99651489 Mus musculus chromosome 8, GRC primary reference assembly. 
-TGACTCAGTGGTCTGGAGTGATTGCTTTACAAGCAACAGAATCTGAGTTTAGATCTCAG
->KN847319.1/4624885-4625042 Exophiala xenobiotica strain CBS 118157 unplaced genomic scaffold supercont1.3, whole genome shotgun sequence. 
-GGGGATGTGGTCTAGTGGTATGACGTGTAAGCATCGCACCACACAATTGAACGAAGCACTCATCTAATATGACAACAGTTCCTTAGCAGAAGTTGAATCCTGAAAGGATTGCCCACAACATCTGGAAAAGGTTCTGGGTTCGATTCCCAGCTTCTCCA
->JARO02016333.1/3903-2330 Scleropages formosus scaffold16338, whole genome shotgun sequence. 
-TGGTTTTAAGGTGGCGGGTGGACTGGGCCCTTGTGTGCAGCCGTTGAAAAATACGCACAGGGTATAACATCTTTTCCTGTGTCTCTTGAATTTAAATGTCTATTGGCTGGGTCTCTCCAAAGTTCCCCCTCAGAAGAACATTCACTATCTTGTTGTTTTACCTGGTAAAGCAAACTTCTTGAGGTGCTGGGGCCAAAATGGCATGAAGGCTTATTCACATCACCTGAGACTAAGATCTCAATTTTATTCTGATGAGATCCCAGAAGATCCCATAAGATCTCATCTTTATCCAAAATGTTGACATACTCAAACACCTGAGAATCCTCAACAGTTTAGCATTAGTGTCTTATTGCTCTCACCCAGACTCCCCCCCCCCAATCATTTGCCAAGTTGGGCTCCAGAAATGGTTCCCTAAAGGGTTGTTGGAGATATCATTTTTATTTGCAGATCAATCATTGTTGAATTTGTCTTTTAAGAAATAATTTTAATCTACCCAATGCAAACTGTCATTTAAGGGGATGTGGTGGCGCACTGGGTTTGGCCAGGGTCTGCTCTGTGGTGGGTCTGCGGTTTGAGTCCTGCTGGGGGTGCCTTGTGGCAGACTGGCGTCCTGTCTGGGGTATGGTCCCCCCCGCATCATTTAACTTCTGCCCTAGAAAAAGAAGATTATGGTCAGAATTTTAAAAAGTTCAGTAGGTAAGCTAACTAGTCTTGCATATTTGGCAAAGAAATGTACTTTGTGGAATGCAAGTCACCTAGTGGGCAATCTTTGGTATGTAGAACTGGTGCTGTGGGATGAACCAGATGCTAGGTTAAGACACTCAATGCCAATGCTCATCAGACTACAAAAAAAGGTGTTGGTTGGCATAGACAGCAGGACGGTGGCCATGGAACTCAGAATCTGCTAAAGTGTTTTAACAACCCACCTGCAGAGTCAACCAGCCCTATAACTGGATGGCACTGGAGAGTGTCAGGTCCATCGTGGCAACAGGAGCCGCAAAAGCTAGGACATGACAAATAAGACAGCTGCTGCGGTGAGCTATCCTAGAGTGTAGGCTTCAGTGGAGCCACCACAGGTGCAGATGTCGGTGGTGGTAAGAAATATTCAAACAAAAACTTTGAAGGCTGAAGTCCATGTCAACAGCAAGTGAACACGAGTCAGTGGTTGTAAGATGCAAATGATGGTCAGAGGGGGCCGGCAATGGCCTCTATTTCCCCCTGCTAATTGAAAGAGAATCAGGTTGGGACTCCTGAATCTGGAGTGGTGGAGACAGATACCATGAGGCATCCAACAGAGTAACGTGAACAATCTCGGAGAAGCTGGAGAGAGCCCCAGGGAGAGTTTAGCCTCCTTTGTAAAGGGTAGGGTGCCTCAGAAGGAGTTTGGCTGGAGAAAAGGGCTCCAGCCCTGGAAAGCATTACAGTTTCAACAATGTCTAGTGATCTCTTATTGATGTTAAATCTGTGGACATAGTGTAAATCTTGCACCAAGTTGTACTCATATCTGCAGCAGATCTCCCAGGTGAGCAGTCTCACATGTGTAATGTCAGATCTGTAGCTTTGGGATAAGGATT
->URS0001A24131_12908/1-50 unclassified sequences eL15-Euryarchaeota ribosomal protein leader 
-ACGGGAUCCGUCCCGGAGAGGAAUGUGGUCCUUCUGGACUGAACCUAGGU
->FAOM01224274.1/16511-16416 Triticum aestivum genome assembly, contig: Triticum_aestivum_CS42_TGACv1_scaffold_224274_3B 
-AGGAGCCGTATGAGGTGAAAATCTCATGTACGGTTCTTCGTCGTCGTGGAGCTCGTTATGCCAGGGCTCCGGGTGAAAATCTTTGTCTACACGGAC
->JH835471.1/1830309-1830596 Erinaceus europaeus unplaced genomic scaffold scaffold00183, whole genome shotgun sequence 
-GAATATGAGGGTGATCTGGCTGTGACATTTGTCACCCCATTGATCACCAGGGTTGATTCAGCTGACCTGGCCGGCTAGGCAGGTCCCTTTCCTCCTTCACTATTCCATGTGTGTCCCTCCCAAAGCTTTGAGCTCAAAGATGACTGAATAGAGACAGGCCCAGTCTTCAGATGAGAGTCTACAGGTAGCTGTACTCCTCTGCTAGAACCTCCAAACAAGCTCTCAAAGCCCCTAATCTCAGGATGTTTCTTCATATGACGCTATATACTCTTGGGGTAAATCTTCTGA
->HF997179.1/95514-95443 Ruminococcus gnavus CAG:126 genomic scaffold, scf59 
-GGATACATAACTCAATCGGTCAGAGCGGCAGCCTTATAAGCTGTGTGTCACGGGTTCGATTCCCGTTGTCCG
->AKWO02000047.1/149928-149814 Leptospira borgpetersenii str. 200701203 ctg1130286793315, whole genome shotgun sequence. 
-AAATAGATCAGTATGGACATATCTGGGAGCAAAATGTATTTACTCGAAGAAAAACAAACACAACTGAAAGGGGATCAAACCTTGACTTGCGCAGGATGCAGATCAAAAGTCACGC
->LFJF01019852.1/9646-11555 Macrostomum lignano unitig_19906, whole genome shotgun sequence. 
-CCCGCTGAATTTAAGCATATTATTAAGCGGAGGAAAAGAAACTAACAAGGATTCCCCTCTAGTAACGCGAGTGAACGGGGAAGAGCCCAACACCGAATCCCTTGGCGCAAGTCAAGCGGAAATGTGGTGTTAAAGGTAGCCCTTCGTGTCAGTCTAGGCGTCCTCAAGTCCACCTGATTGTGGCTCAAGCCAGAAGAGGGTGTAAGGCCCGTAGAGACGCCTCCGACTGATTCCTGGGGTTTACCCTACGAGTCGGCTTGTTTGGGAATGCAAGGCCAAAGCGGGGTGTAAACTCCATCCAAGGCTAAATACTGGCACGAGTCCGATAGCGGACAAGTACCGCCGTGAGGGAAAGTTGAAAAGAACTTTGAAGAGAGAGTTCAATAGTACGTGAAACCTGCTTAGAGGCAAACGGATGGTGGCTCATACTGGCCTGAGGAATTCAACTGTGACGGGGCTGGACGAGCTGGCGTTCCGATCTCTTCTTTTGGGACGGGCGTCGGTTTGGCTATCAGGACTCTGACATGGTGCACTTTCCTTGGTGCCTCCGCCGACGACCGACGACACTGGCTACCCCGCGGCTCGGGGTAAGGTGACAAACCTGCTTCGGCATTTGTGTTATAGACCCCGGGGCGTCGGACATGGTTTGGCCAGGACGTCGAAGCTTGCGGCGCCCGCTCGCTTGTGGCTCGCATGTTGGCTACTTGGCTGCGCCGATGCTTGCACTGGAGACAACCAGTACAGGTGACGGTTGTGGTCTTGTCTCTAGTTGGCCTCTGCGAGTTTGGCGCCTATAGTCTGTGGTGTACTTGTGGGTAGACTCTATCCGACCCGTCTTGAAACACGGACCATTGAAGGAGTCTAACATGTGGCGCGAGTCATGGGGATTCTACGAAAACCCAAAGGCGCAGTGAAAGTAAAGGCCTGCTTCTCGTAGGCTGAGGTGGGATCTCGTGGCATCGCATCGCGATTGGCGAGCGCACGCACCGGCACCGTCCTATCTGTCTCTGTCAGTGGGGCGGCGCAAGAGCGTACACGTTTGGGACCCGAAAGATGGTGAACTTATGCTTGCGCAGCTCGAAGTCAGTGGAAACACCTGATGGAGGAGCGCAGCGTTTCTGACGTGCAAAAATCGATCGTCCAAAACGTGAGTATAGGGCGAAAGACTAATAAGGGGGCGAGACGTCATAAGTAGCAACCATCCTTGAGCTGGATTCCCTTCCGAAGTTTCCCTCAGGATAGCTGGCACTGCGGGGAAAACAGTTTTATCCGTAAAGCGAATGATTAGTAGGCATTGGGGGTCGAAAACGACCTCGACCTATTCTCAAAACTTTAAATGGGTAAGGATGCTCGTCTCGCTTAATTGGAGGCGGGCTTCACGCTCTCTAACGTGAATGTGAGTGCCCAGTGGGGCCATTTTGTTGTAAGGCAAGAACTGGCGCTGTGGATGAACCAAACGCGGCGTTGAAGGCGCCCAATGCGGACGCTCATGAGACACCACAAAAGGTGTTGGTCGATACTGACAGCAGGGACGGTGGCCATGGAAGTCGAACGGCCGCTAAGGAGTGTGTAACAACTCACCTGCGCGAATCAACCAGCCCTGAAAATGATGGCGCTGGGAAGCGTCCGGCCTATAGGATCGGGTTGACCTGGTGTGACTCGATGTGGGGATAGGATAGCAGACAAACTAATCTTGTAGGTATGTCCACTAACGAGTAGCGAGGGTAGCCGTGGTGTAGCGCAGAGTGATGTCAGCCGCACGTAATTGTGAGGCCAGTGACTGGAGCCGTCCAACGGGTAAATATTCCGCGGCGGCAGATCTTGCGGTGGTCAGTACAATACTCAGCAAGATAGAAAGCGTTGAGGACTGTAAAGTGTTTGAGAGAGGGTTCATGTGAAACAGCATAGTT
->JSYM01000001.1/27642-27547 Flavobacterium sp. AED Contig01, whole genome shotgun sequence. 
-TTTTAGCCCCGATGGGAGCGATATCCTTTTCGAGTCTTTTCTCGTTCCTAAAACGAGAAAAGACTCGAAAAGATAAAGAGGACAGCGGGACCCATG
->AP014808.1/1488830-1488748 Lactobacillus acetotolerans DNA, complete genome, strain: NBRC 13120. 
-TAATATAAAAAGAAGCCCTGTGAATAACAGAACTTCTCATGTAGAGCCGTAAAAGACGGTGGCATGATAATAATTACTAAAAA
->FR889406.1/108529-108414 Firmicutes bacterium CAG:449 genomic scaffold, scf101 
-TTTAATAGTTCCAATATACCAAAGACAGCAACGGCTATTAGCTTAATAATGTTGCCGAGGTAAAGTAAGTTATTTATAAATAATGACAAGCATTACTCTTGTATATTGTTGACTAT
->AGTP01109286.1/18627-18514 Ictidomys tridecemlineatus contig109286, whole genome shotgun sequence. 
-GTGTTGTATGAAAGAAGACAAGGTTATTCTGTTTTGTCAAGGATGGAAGAAACCCTTAGGCCTGACCACACGCATATTGTTAAGATATCACATAGCATCTAACCATTGACTTTT
->CP001014.1/1643612-1643672 Thermoproteus neutrophilus V24Sta, complete genome. 
-CGGCGGCGGAGAGCCCCGCGCGGGGCGCCGTGAAGCTACCGCAGTCGGTCCCCCTTGTACA
->MNDA01000091.1/220-1 Ktedonobacter sp. 13_2_20CM_53_11 13_2_20cm_scaffold_5687, whole genome shotgun sequence. 
-GGGGATGTCGGGTTTCGACAGACGAACAGATTGTTGAATTGCAGGCCGAGGTGTCGGTATGCACTCTCGTTAAACAACCGACAAAACAATAGATGCCAACAAACAGGCACCTGCTTACGCTTTCGCTGCTTAATAACCAGTAGGCGTCGTCCGCCCAGTTTTTTCTCGTGGGATTGGAACCGGGCGTCGAAAACACGAGGTGCTATGACGGTGACCGCCC
->ACTA01034202.1/35881-35939 Ailuropoda melanoleuca scaffold919_18, whole genome shotgun sequence. 
-TGCTCTGATGAAATCACTTATAGGAAGTGCCGTCAGAAGCGATACTAGCCATTCTGACA
->DS028111.1/11289-9911 Coccidioides immitis RMSCC 2394 supercont1.19 genomic scaffold, whole genome shotgun sequence. 
-GGGCACATGGTGGATGCCTTGGCATCAAGAGCCGATGAAGGACGTTGGAGCCTGCGATAAGCCCTGGGGAGTTGGCAACCGAGCGTTGATCCGGGGGTGTCCGAATGGGGAAACCCAGCACGAGTCATGTCGTGTTACCTGCGCCTGAATCTATAGGGCGTTTGGAGGGAACGCGGGGAAGTGAAACATCTCAGTACCCGTAGGAAGAGAAAACAATAGTGATTCCGAGAGTAGTGGCGAGCGAAATCGGATGAGGCTAAACCAACTGCGTGTGATAGACGGCAGTCGTTGCGTAGTTGGGGTTGTGGGATATGTCTGTCATCGTCTGCCGGCGGTGAGCTCAGTAAGAAACCAAGCATGAAGGTGAACCAGTTGGGAAGCTGGGCCGTAGCGGGTGATAGCCCCGTAATCGTATGTGTTTGGCTGGGTTGATGTACTCCCAAGTAGGACGGCACTCGTGGAATGTCGTGTGAATCTGGCGGGACCACCCGCTAAGCCTAAATACTTCTTGATGACCGATAGCGGACCAGTACCGTGAGGGAAAGGTGAAAAGTACCCCTGGCGGGGAGTGAAATAGTACCTGAAACCGTGTGCCTACAATCCGTCAGAGCCCGGCCGGCTGTTTACAGCAGTGGGGGTGATGGCGTGCCTTTTGAAGAATGAGCCTGCGAGTTAGCGGTGTGTGGCAAGGTTAACCCGTGTGGGGTAGCCGTAGCGAAAGCGAGTCCTAATAGGGCGATTGAGTCGCGCGCTCTAGACCCGAAGCGAAGTGATCTAGCCATGGGCAGGTTGAAGCGCCGGTAAGACGGCGTGGAGGACCGAACCCACTTCAGTTGAAAATGGAGGGGATGACCTGTGGTTAGGGGTGAAAGGCCAATCAAACTTCGTGATAGCTGGTTCTCCCCGAAATGCATTTAGGTGCAGCGTTGTGTGTTTCTTGCCGGAGGTAGAGCACTGGATAGCCGATGGGCCCGACCAGGTTACTGACGTTAGCCAAACTCCGAATGCCGGTAAGTGAGAGCGCAGCAGTGAGACAGTGGGGGATAAGCTCCATTGTCGAGAGGGAAACAGCCCAGACCATCAGCTAAGGCCCCTAAGCGGTAACTAAGTGGAAAAGGATGTGGAGTCGCAGTGACAACCAGGAGGTTGGCTTGGAAGCAGCCACCCTTGAAAGAGTGCGTAATAGCTCACTGGTCAAGTGATTCCGCGCCGACAATGTAGCGGGGCTCAAGTTATCCGCCGAAGCTATGGCACTCCGGTTTTCCGGGGTGGGTAGGGGAGCGTCGTGTATCGGGTGAAGCAGCGGAGTGATCCAGCGGTGGACGGTACGCGAGTGAGAATGCAGGCATGAGTAGCGAATGATGTGTGAGAAACACATC
->LN902847.1/6110633-6109254 Echinococcus multilocularis genomic scaffold, pathogen_EmW_scaffold_07 
-TAAAATACTGCAGATGGGGGAAGTCGGGATTCTTAATCCATAACATCGGAAAGAGGATTGGCTCTGAAAGCTGAGCGGAACAGGCTAAGGAAAGAAACAAGCTAACTCAGTTTGCTGATGGACGGGCTGGCTAACTGTTGATACACCGCCTCCACCGCCGTCGTTGCGGTGGTGGGTGGGTGTGGAGCATGCAGTTGAGCCCATCCCTTGGCTGGAGGCGAGTAGGGTGAACCGTGGGCGGACCCAGATAAATGTGCACCTCGGTCGATTGATTGGTTAGTTAGTTGTCGATGATGCTGCTTGTTGGCTGTTAGTTGGCGAGTGTTGTGGTGCTCGGCACTGCTACTGGTTAGCCTCGTTGGGGGGTGCTTGTTTAGTGCCAAACACCCAACCCAGAACTAACATGGACCTGAAAAATCCGACTCTCCAATTAAAACGTAGTTTTGTGATGTCCGCTGGTTTGTTCTAGTGCAATGTGATTTCTGCCCAGTGCTCTGAAGTCAAAGTGAAGATTTTCAACCATACGCGGGTAAATGGCGGGAGTAACTACGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAACTAGTGACGCGCATGAATAAAATTAATGAGATTTCTATTGGCCCTGGCTACCATCTAGCGAAATCACAGCCAAGGGAGCAGGCTTGGCAGAATCAGTGGGAAAAGAAGACCCTGTTCAGCTTGACTCTAGTCCGACTTTGTGAAGAGATATGGTGGGTGTAGCAATAAGTGGTTCAACTGTGGCTTTCTATGAGATAGCTGTGCTTTTCATCTTTGTGCTCAGCATGCACATCACCTTGTTAGCCCGCCAAATCTAACATTTACTCTTTTGCGCTTTTACATTCCTGTCATCAGGAGGTAGATAGAATGCTCGTAAATGCTTAAATAGAAAAATGATTTAAGACAAGGAAAATTGGTTTGGGCATTTCCAGTTCATGTTGTACCTAGTCATTGATTTACTTCCTTTAATGGAAGCTGCGAAGAGGTGGTTTGAGAGCACTAAAAACCTCTAATTTTGTCTCATCAACTGGGCATATAAGCATTCGTTCATTTCCAAAACTTCTGACAAGCCCGCTTGACGCCTCATGTTATTAATGGGTTAGTGTTTGCAATCAGTGGTAAATGAAGTTGATCCATGAAGGTTAAATATGCTTTGCAAATTGCAGTATAGTCACCACAATTGAACAAATTTCACATGCCAAAAAGAGGGGTCACCCATAAATCATGCGATTCATTACAGTCTACAAGGTTAGTAGAACTACTAATTTATCGAAGCGTATGTTTTAGAAAAGGTTGCAGACTAATGTCCATCCCATTCATTCTGCCAATTTTAAAGCATTTCTCTTTTCGTCTGC
->LZPO01055098.1/393046-393292 Neotoma lepida isolate 417 scaffold_519, whole genome shotgun sequence. 
-GGACGGCTAGGCAAGTATCCCCTTCCTCCTTCACTATTCAAGTGAGTTCCTCTCAGAGCTGCATGTTCTGTGCAAAACAATGATTTTCCCCAATAGAGGAGCACCATTCTTGGGTCAAGGGGATCTGAGTAGCTGTGCATCCTTGCTAGAACTTCCAAATAAGCCCTCAGGTGCTGGTGGCCATGTCAGAGGAGTAGCAAGTAGCAGTTGAAGTTCAAGGTGTCAGCCCACCAGGAGGAAACTCTCT
->AURB01000101.1/106632-106430 Alicyclobacillus acidoterrestris ATCC 49025 contig_19, whole genome shotgun sequence. 
-TGAACGGCGTTGAAAGGGAGGAGTAAGGCGGTTTCGATTGTCCAGAGACGGTGCAGCGCGCTGAAATGCACCGCTTTCGTCCGTCTGAAGGTCGCCCTTGAGCTGCTTACCCCGGGTCATTCCGTTATCGATGTCGAGTGTTTCGTTCGTCTCGCGATGAGCGGAAAATTCAGGTGGTAACGCGGAGCCTATCCGTCCTGAGG
->CM004482.1/68495215-68495614 Xenopus laevis strain J chromosome 9_10L, whole genome shotgun sequence. 
-TGATGACTAACATGTCCACGAGAAGGAATTTCATATATGAATGGAATGCCGATTGCCCTGTCCAAAACCCCAGTGTTAGGACCATATTAACCAGCAAGAAAGAAAAAATTGCCTATATACTTGTCAGATTTGCAGTAGTGAGGGGACAACAGCACAAGTACAGTATGATTAACTGCATCATCAACAGTGCCATGGGCAGCACCAAAACCTATAATTGTGACAATACATTCGGATGTCTGCCCCATGAACATTCGATGGTGCTTTCTGCAACTACCATGTTGACCACAGGTAATGGGGAATCAGGGTTCAATTTCGGAGAGGAAGCCTGAGAAACTGCCACATCCAAGGAAGGCAGCAGGTGCGCAAATTACCCACTCAGAACCTTCTGTGAATAAATATG
->AJMR01000139.1/797-1134 Pseudomonas pseudoalcaligenes KF707 = NBRC 110670 strain KF707 ctg1510, whole genome shotgun sequence. 
-CCGCCCAGCGCGCCACCAATACCGGCATCGGTATTGCCGCCGGCAAAGGCGCTGCCACTGGCGAGGCCAAGAGACAGGAGAAGGATCGAGGTGTACTTCATGGTGAGGATCGCCTCAGTGGTTTTGGTGAGGCGATATTTACTGTGGGATTTGTCTTACGCAAGTGTCTGACGACGAAAAACACGAACTTTTATTATTTTTTTTATTGGGCGATTCGACAGAAGAACTTTTTCCCTTCAGGGGAGTCAGAGGCTGGTTGAAACCCCCGCTCCATGCGCGTCTTGCGCTTTCTGGTACTGGCACTTCGCCTAATAAGTTCCCTTTGAAGTTGGAACTTT
->MNIQ01000128.1/3562-3838 Ktedonobacter sp. 13_1_20CM_4_53_7 13_1_20cm_4_scaffold_29355, whole genome shotgun sequence. 
-TTATAGGCAACGAAGGAACGAGTAGGTCCCCATATCTTGTCGAAGAGAGCCTGGGGGTGGTGTAACCAGGTCAGGATCGTGAGCCGAAAATCATTCCAGAGCCGCTAGCCGAAACAACAAAGTAGACCTGGCCGGGACCTTCCCGTTATCATGAAGGGCTGTATGGATCCTCTCAATTGGGGAGTTACAGCTAAACCAAGTGAGCCATATCTATCTCACACCTCGTGAGAATGTGGCTAATAAGGGTGGTACCGCGGGAGTTCCTCTCGTCCCTATG
->BARX01000007.1/79604-79779 Agarivorans albus MKT 106 DNA, contig: contig00007. 
-CAGCGCGCTTTTGGGGAGTAGCTGCCCATATCAATAAGGTATGGGGCATTTATCAACATACTTAGTGCTCATCACTATGGTAAATGCAGCCTTTATTGGCCTAGCAAGACCAAATGCACATTAACGCCATAAAGAGGTGAGCTGCGTTGTGTGCATTGGTTTATTCGCTCGCCTCA
->CM001383.3/74376359-74376250 Felis catus isolate Cinnamon breed Abyssinian chromosome B3, whole genome shotgun sequence. 
-CCTCGATGATGAATTGCCATGCTAATACTGAGTCACCAGGTGGGGCAGTGTTGCCCTGGTTTGGGTGCCAGTGAGTTTAACAAAACTTCTCACATGGAGACCTGAGGGGC
->AOKF01002516.1/2805-2760 Pseudomonas syringae pv. actinidiae ICMP 19096 scaffold552, whole genome shotgun sequence. 
-TTGGCTTTTAACCAATTGGTCGTAGGTTCGAATCCCACACGACCCA
->AWUE01016600.1/22634-22748 Corchorus olitorius cultivar O-4 contig16633, whole genome shotgun sequence. 
-GGGTGCAATCATACCAGCCCTAATGCACCGGATCCCATCAGAACTCCGTACTTAAGCATGCTCTTGGAGTTGGCTATCATCAAAAGTGTCATTATTCTAACTACTTTTGCAAATG
->JH835377.1/3849674-3849364 Erinaceus europaeus unplaced genomic scaffold scaffold00089, whole genome shotgun sequence 
-ATGTGAGGGTGCTCTGGCTGTGACATCTGTCACCCCATTGATTAGAAGGGTTGATTCAGCTGATCTGGTTGGTTAGGAGGTGTCCCCTTCCTCCCTCACCACTGAATGTGCTTCCCTCCCAAAGCTGCAGTGCTTGGTGAAGAAGACAGCCTTCCCCAACAGAGATGGACAGGTCTCGGTGGAGGGTATCAGACTAGCTGTACTCCCCTGCTAGAAATTCCAAACAAGCTCTCAAAATGTCTCTTGGAAATTTGCCAGATTTCATATGAAAAGAGTCATTCTATATTTTTCCTATAGAAAGAAGATCATTT
->URS0000D6B09B_12908/1-98 unclassified sequences skipping-rope RNA 
-CATGCCGGAGGTGGGAAATTGTGTTGCACCCACGCACCTTGCGTACATGACGTAACGGTTAAAAGAGATGGAGCAGATTGCAACGGCTCCCCGGCATA
->CP000108.1/2027693-2027787 Chlorobium chlorochromatii CaD3, complete genome. 
-CGGCATCCCCATTACCTATGGTCACGGTGCTGGAAGCTCTGGGAAGGGTTACCCTTCCAATGGTGAATTGATCAGGAGAGCTTTTCCGTGTCCCA
->LCZI01000091.1/60703-61080 Emmonsia crescens UAMH 3008 supercont1.108, whole genome shotgun sequence. 
-GCGTAGGCGAAAATCATTTTACTACATACATATAAAATTCAATTACCCCAATTTGTATAATATTAAATTATGGCTATCTGCAGTTAATGCCGTGAGACATGGTTAATTCTTTTAATGAACCCAAACCCTAACTTTCTTTATTTCTCTATATAAAGTAACTTGCTAAAAATTGGTTAGAGAATAGGGACCAAGACAGGTCATCATGACCATAAATAATATTATGGGCTATAGACGTACCACACACGCCTTAACAAAAGGATGCTATATTGTAAAATGGAGCTAATCCTTAAAACATAATATAATATGAGGTGTTGTCTGTAACTCGACAACAGGGACAAAAAAGTACTAGTGATCGTGAATCATCACGCCACGGTGAGT
->CP016199.1/1032825-1032926 Mogibacterium pumilum strain ATCC 700696 genome. 
-TCCTTATTAAGAGCGAGTGAGGGAATGGGCCCGGCGAACTCGCGGCAGCATCGCATATTGCGGTTGTGCCAAGTCCCACAGGCAAAGCCTGAAAGATGAGGA
->DS562928.1/6888831-6889130 Cavia porcellus supercont2_73 genomic scaffold, whole genome shotgun sequence. 
-GATTCCAGCAATCTGCCTGTGACGTCTGTCACCCTTGTCATTGTGTGGGCTGGTTTGGTTAATCTGGCTGGGGAGGTGGGTGTCCTCTTTCTCTTTCACAGCACCATGTGCATCTCTGTTGAAGCTGTGTGCTTGGTGGAAGAGGAGGACCTTCCCCGAAAGGATCAGGACAAAGATACATGAGTAGCTTCACTTCCCTGCTGGAACCTCCAGACAAGCTCTCGAGGATAGGATTTACCATGTGACACAGTAGTGGAGAATTTGAACAAAAGTCTATGTTGCTCATCATGGTAATTCAGG
->CM000236.2/126073376-126073451 Rattus norvegicus chromosome 6, whole genome shotgun sequence. 
-GAGGGGCTCACAGCTCCGGTCCTTGGAGCTCCAGAGAAAATGTTGCTCCGGGACTGAGTTCTGTGCACCCCCCTTG
->APWO02002148.1/5885-5949 Astyanax mexicanus Unplaced_Scaffold4491, whole genome shotgun sequence. 
-GTGTTTTTCTGCAACTGAAAAACTCCTCTGTAGCTCAAAAATGAGCTTTTTAAGACTGAAACACA
->CM001883.1/35529231-35529093 Theobroma cacao cultivar Matina 1-6 chromosome 5, whole genome shotgun sequence. 
-AATGCCTCCAGAATAACCAGAAGGTTAGAATATGATCCGACGCCGTCTTGGTTCAGACAGAGGCTTAGAGCAATTCGAATCCGTTTGAGGGTAAGGAACGATTTTCCTCCGTTCCTTTCCTAGATGTCTTCGAATATTT
->JH711575.1/1398613-1398696 Coniophora puteana RWD-64-598 SS2 unplaced genomic scaffold CONPUscaffold_3, whole genome shotgun sequence. 
-GGGCGTTTGGCACAGTGGTAGCGCGTATGCTTTGCATTTAAGCAACTTGCATAAGGTCGTGGGCTCGAATCCCATTCATCTCCT
->FQVZ01000030.1/1153-1 Fibrobacter sp. UWB8 genome assembly, contig: Ga0136280_130 
-TGGAGGTCGCAGGGAAACGGCAGAAGCGACTGTTTACCAAAAACACAGGGCCATGCTAACACGCAAGTGGACGTATATGGTCTGACACGTGCCCGGTGCCGGAAGGTTAACAGGAGGGGTCAGCGCAAGCGAAGCCCTGAATCGAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATCGTGTAACGACTTCTGCACTGTCTCCTCCCGGGACTCGGCGAAATTGCAGTGCCGGTGAAGATGCCGGCAACCCGCACCTGGACGGAAAGACCCCATGAACCTTCACTGTATTTTGACATTGGTTTTAGGGCCCGCATGTGTAGGATAGGTGGGAGGCTTTGAAACGGCGACGCCAGTCGTCGCGGAGCCGCCCTTGAAATACCACCCTTGCGCGCTTTGAGATCTAACCTCGTCCCGTCATCCGGGACAGGGACCGTGTCTGATGGTCAGTTTGACTGGGGCGGTCGCCTCCTAAAAGGTAACGGAGGCATCCAACGGTTCCCTCAGCGCGGTCGGCAATCGCGCGTAGAGCATAAAGGCATAAGGGAGCTTGACTGCGAGGCGGACACGCCGGGCAGGTACGAAAGTAGGGCTTAGTGATCCCGCGGTACAGCGTGGAAAGGCCGTTGCTCAATGGATAAAAGGTACTCTGGGGATAACAGGCTGATCTCCCCCAAGCGTTCATAGCGACGGGGAGGTTTGGCACCTCGATGTCGGCTCGTCGCATCCTGGGGCTGGAGAAGGTCCCAAGGGTTTGGCTGTTCGCCAATTAAAGCGGCACGCGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCCCTATCCGGTGTGGGCGTTCGAGACTTGAGGGAAGCTGTCCTTAGTACGAGAGGACCGGGACGGACGTACCTCCGGTGTACCGGCTGTCGCGCCAGCGGCATTGCCGGGTAGCCGTGTACGGATCGGAGAAACGCTGAAGGCATCTAAGCGTGAAGCCGTTCCCAAGATCAGGTCTCGCGGGGGCAACCCCATGTAGGGCCGTCGTAGACTACGACGTCGATAGGCCGCAGGTGTGAGCGTGGCGACACGTTGAGCCGAGCGGTACTAATAGCCCGGTAGAGCTTTT
->AAPE02046865.1/69583-69781 Myotis lucifugus cont2.46864, whole genome shotgun sequence. 
-GAATCTGATAATCAACAGGGTTAAAAGACAGTTGAACACCTGAAGTACATTATGATGATTTAAATAATGTGCAGTTTGCCCAAAAACGTTCGGTCCCTGGCGTATGTCTTAGAGATTTCTATGCGGTATGCAATGTGTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACTCGCATGAATGAATGAACGAGATTC
->HF998428.1/32618-32277 Coprococcus eutactus CAG:665 genomic scaffold, scf147 
-GGGGTTGACTGGTTTCGACAGGGGTTTTGAAGCTATGGAAGCCATCCGTGGACCAGAGCCACGCTAAAAGCTGGACAAAAAATAAACGCTAACGATAATTTAGCATACGCTGCCTAGTTGCAGCCGTCATCCTTTAGGAACGCCGAGCCTTTAGGAATGGCGTCGACTTTCGGCAAACTCCTGCATCTAAGCTTTGCGATGTAGGAAAATCCATGAAGCTACTAAGGTCTATAGCATGTTAGTGGGCGATAGGCTGAGGGAATGTTAAAGCACTGACTGTGATGGAAGAAACTGTAGTGAATGAGCTTTTGGACGGGGGTTCGACTCCCCCCAGCTCCACTA
->FJUW01000012.1/748132-747973 Rhynchosporium commune strain UK7 genome assembly, contig: RCO7_scaffold012 
-GGCCGAGTAGTGCAATGGTCAGCATCTCACATCCATAATGTTCTGGATTGCGAGCGCGCGTGCGTGTCATCGGATCTTGTATCGTTTACTGTATTCTTATTGCTTCGGCGTTTGGGTGTAGGATTATGTGAGGATGGAGGTTCGATTCCTTCCTTGGCCA
->CM001586.2/2047421-2047222 Ovis aries breed Texel chromosome 5, whole genome shotgun sequence. 
-ATCACTTCTCGGCCTTTTGGCTAAGATCAAGTGTAGTATCTGTTCTTAACAGTTTAAAATAGTATGTTCCAGACCCTGGCTGCTGAAATGTATCTCTCAATCTCTAAAATCCCTGTGGGTTGCTGAATCATAAGGGCTTGGTTCCTGGTGCATTTTAAATTTTGTCTTTGTTTCTGACACCGGAGGATGACTCACTCTTT
->AP008955.1/1357281-1357003 Brevibacillus brevis NBRC 100599 DNA, complete genome. 
-TTGATGGCAATGAGGAAGAAGAGTAGTCATTTTACGAGACTTCAGAGAGCTGATGGTTGGTGCGAATCAGTGTTAAGGAAATGATGAATGGGCTTCCGAGCTCCAAACCAAACCCGCTACTCATGGCGGCAGTAGGCTTTGGCGTTACGTCCGTACGTTACAATGGACACCGTATCAAGCTGTCTTACACAGAAACGGTACGGATTAAAGAGATTTTGCGTATGGATGATTCCTTGCGCGAAATAACAAGGGTGGCACCACGGTTCATTCGTCCCTGTC
->ADKL01000252.1/892-837 Hot springs metagenome ctg_1106426166129, whole genome shotgun sequence. 
-CTTGATGAGTACACTCTTTGCTGATTCAATGAGGAGAGTGGCCAGGGCTGAAGAGG
->MIDV01000105.1/1073-1170 Xanthomonadales bacterium RIFOXYA1_FULL_69_10 rifoxya1_full_scaffold_59073, whole genome shotgun sequence. 
-ATCCCCCAGACATGCCCGCCGGCGTTGCCGGTGACATGCCCAGGTAGCCATCGATCTTCAAGGCTGCGGCGCGGCTTGTCCGCGTTGATCGAAACCCG
->FPAA01000006.1/128109-128175 Marininema halotolerans strain DSM 45789 genome assembly, contig: Ga0104500_106 
-GTGTTGGTAGTTTAATTAAAATTCCGACCTTTCAAGTCGGCGATGAAGGTAAAATCCTTCCCACACG
->MJEQ01037189.1/69339123-69338966 Nicotiana attenuata strain UT chromosome 7, whole genome shotgun sequence. 
-ATACTTACCTAGACGAGGTCAATGGACGAACGATAAGACTCATGGCCTAGGTTGGGGACTTCCATTGCACTTTGGAGGTGCCCGCCTATGGTCGACCCAAGTGTCTGAACCTACGTCATAATTTGTGGTAGTTGGGGCTTACGTTCGCGGGCCCCTAC
->KV423970.1/63913-63812 Calocera cornea HHB12733 unplaced genomic scaffold CALCOscaffold_57, whole genome shotgun sequence. 
-GGCAACTTGGCGCAGTTGGCTAGCGCATCTGTCTAACAAGTTGCCTCTCCAGGCAGGTCCTTTGTACACAGAAGGTCGCAAGTTCGAGCCTTGCAGTTGTCA
->ALWZ040150818.1/688-1 Picea glauca, whole genome shotgun sequence. 
-CATCGAAAGGAAATCGGGTTAATATTCTCGAACCGGGACATGGCGGCGGACGACAACGTTAGGAAATCCGGAGACGTCGTCGGGGGCCCCGGGAAGAGTTATCTTTTCTTTTTAACAACTTGCCCACCTTGAAATTGGCTCAACCGGAGATAGGGTCCAGCAGCTGGAAGAGCATCACACGTCTTGCGGTGTCTGGTGCGCCCTCGACGGCCCTTGAAAATCTGGAGGACCGAGTACCGTCCATGCCTGGTCATACTCATAACTGCATCAGGTCTCCAAGGTGAACAACCTCTGGTCAATAAAACAATGTAGGTAAGGGAAGTCAGCAAAACGGATCCATAACTTCAGGAAAAGGATTGGCTCTGAGGGCTGGGCCTTGGGGTCTGCGTCCTCAACCCGTGGGATGTCGGCAGTCTACCCGAGCTGCTATCACGGCGAGGGCGGGCAGTCGCGTGCTGATTGGGCTACGGACGTAGAATGTCCTCTCGCGAGGGCTTTTCCCTAGGCGACGAACAGTCGACTCAGAACTGGTACGGAAAAGGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGATCGTCCCTGCGGATGCTGACGCAATGTGATTTCTGCCCAGTGCTCTGAATATCAAAGTGAAGAAATTCAACCAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTT
->AYUG01104772.1/8786-9026 Fukomys damarensis contig104772, whole genome shotgun sequence. 
-GGATGTGAGGGCGATCTGGCCGATCTGGCCAGCCAGGCAGGGGTTCCCTCCCTCCTGCGCTGCTACAGAAGCTGCATGCTTGGTCGAAGAGGATGACCACCCTGATGGGGGAGACCGTGTCCTCTGTCAGGGAATCTGAGTAGCTGCACTCCCCTGCTAGAACCAAACAAGCTCTCAAGGAAAGTGAGCCACAGCACTCACCAGAGGCAGAGCTGGGATTTGAACCCCGGCCTCCTGGCTC
->GL344173.1/24246-24358 Anolis carolinensis unplaced genomic scaffold chrUn0991, whole genome shotgun sequence. 
-ATCTAGGAGTACAGGGTTGTTGTATGTCTTTTGGGCTGTGTGGCCATGTTCCAGAACATCAGAACTTCTGGAACATGGCCACACAGCCCGAAAGACATACAACAACCCTGTGA
->URS0001A24820_12908/1-49 unclassified sequences eL15-Euryarchaeota ribosomal protein leader 
-GCGGAUAAUAAUCCGUAGGGAUGUAACCCAAACGGGGUUGAACCGCAAA
->MNWA01000007.1/20574-20446 Candidatus Pacebacteria bacterium CG1_02_43_31 cg1_0.2_scaffold_487_c, whole genome shotgun sequence. 
-ATATGTTAATTTAACAATGCTGTGGAATGTAGTGAAAATCTACAACTGTGCCGCAACGGTGTATTTTTGGTATTTTCCAAAATAAGTCCGATCTTCAGCAAAAAATTTTTAAACTTGCTTAGGCAAGTT
diff --git a/src/alphafold3/test_data/miniature_databases/rnacentral_active_seq_id_90_cov_80_linclust__subsampled_1000.fasta b/src/alphafold3/test_data/miniature_databases/rnacentral_active_seq_id_90_cov_80_linclust__subsampled_1000.fasta
deleted file mode 100644
index 17e54473d795a5b55af4211c76b85dfcad99f0ce..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/rnacentral_active_seq_id_90_cov_80_linclust__subsampled_1000.fasta
+++ /dev/null
@@ -1,2000 +0,0 @@
->URS000254B5FC rRNA from 1 species 
-ATGGAAGTCGACAGAGCCCCGGCCGCTGCCGCGGGAGGAGGATCCTCCTCTGGCGCGATGGCGGTGGACGCGGCCGGCGGCGTGGAGAAGCCGCGGTTCGACGCGCTGATGCCAAGCGAGATGAGCGGCGGGAGGCCACAGTACCGCAAGGTCCAGGTGCCGCCGCACCGCTTCGCGCCGCTGAAGAAGGCGTGGCTGGAGATCTACACCCCCGTCTACGAGCACATGAAGGTCGACATCCGCATGAACCTCAAGGCAAAAAGGGTCGAGCTGAAGACGAGGCATGATACACCAGATGTGAGCAACCTTCAGAAGTGCGCGGACTTCGTGCATGCTTTTATGCTTGGATTTGACATTGCCGATGCCGTTGCCTTGCTTCGTCTTGATGACCTGTATGTGGACTCCTTTGAGATCAAGGATGTGAAGACACTCAGAGGGGAGCATCTGTCACGTGCCATTGGGCGCCTGTCAGGGAAAGGAGGCAAGACCAAGTATGCCATCGAGAACTCTACGAGGACTCGCATAGTTATCGCTGATACGAAGATCCACATACTTGGATCCTTTGTTAACATCAAGGTTGCCAGGGATTCACTCTGTAGTCTTATCTTAGGTTCTCCTGCCGGCAAGGTCTATTCTAAGCTTAGGGCTGTATCTGCTAGGTTGGCAGAAAGGTATTAG
->URS0000B78375 rRNA from 1 species 
-GTGGGGAATATTGGACAATGGGGGGAACCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGCCTTTTGGTTGTAAAGCACTTTAAGCGAGGAGGAGGCTACCGAGATTAATACTCTTGGATAGTGGACGTTACTCGCAGAATAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAATACAGAGGGTGCAAGCGTTAATCGGATTTACTGGGCGTAAAGCGCGCGTAGGTGGCCAATTAAGTCAAATGTGAAATCCCCGAGCTTAACTTGGGAATTGCATTCGATACTTGGTGGGTAGAGTATGGGAGAGGATGGTAGAATTCCAGGTGTAGCGGTGAAAAGCGTAGAAATCTGGAGGAATACCGATGGCGAAGGCAACCATCTGGCCTAATACTGACACTGAGGTGCGAAAGCAAGGGGAGCAAACAGGATTAGATACCCCTGTAGTCC
->URS0001CC990C rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACGGACGAGAATCTTGCTTCTCTGATGTTAGCGGCGGACGGGTGAGTAGCACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATTTTGAACCGCATGGTTCAAAAGTGAAAGACGGTCTTGCTGTCACTTATAGATGTATCCGCGCTGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCATAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTACAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGAACTGGGCGGAAGACTGACGGAGCAACGCCGCGTGAGTGATGAGGGTCTTCGGATCGTAAGACTCTGTTCTTAGGGAAGAACATATGTGTAAGTAACTGTGCACATCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTG
->URS00013D39E1 rRNA from 1 species 
-TACGTAGGGGGCAAGCGTTGTCCGGAATCATTGGGCGTAAAGAGCGTGTAGGCGGGTCTTTAAGTCAGGGGTGAAATGCCAAGGCTCAACCTTGGAACTGCCTTTGATACTGGAGATCTTGAGTCCGGGAGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGGAACTGACGCTGAGACGCGAAAGCGTGGGGAGC
->URS00023ED20D lncRNA from 1 species 
-TCAGAATAAGCATAGCTAGGAAGGAATGTTTGAATAATGCACTATTTTTTTCCTCATGAGATAAAAAAAGAAGAAGAAAATATTCTTTTAGAGTAGCAGCAGTGGATGAAAAAAACTCAAAAAAATTGGAAACGTGAAAAAGTGCAAAACCAGAGGGTGAGGAACGTGTCGGTAGAAGAAGGGCTGGCTCGCTCTCGTTCGATCAGATCAAATACTACCGGAG
->URS00017AA725 rRNA from 1 species 
-TACGGGGGGAGCAAGCGTTGTTCGGATTTACTGGGCGTAAAGGGCGCGTAGGCGGCCACCGCAAGTCGACTGTGAAGTTTCCGGGCTTAACCCGGAAAGGTCAGCCGATACTGCGGGGCTAGAGTGCAGAAGGGGCAACTGGAATTCTCGGTGTAGCGGTGAAATGCGTAGATATCGAGAGGAACACCTGCGGCGAAGGCGGGTTGCTGGGCTGACACTGACGCTGAGGCGCGAAAGCTAGGGGAGCGAACGGG
->URS00023C6B8F lncRNA from 1 species 
-GTCATACTCAATATAAATTAATAGTAATGGATGCAAATGACAACGGTGCTCTCCAACAGGTGCTTTTTAATAAAAGGATGATGACTCAACATAAAAATAAATAGATAGGCCCTACGCAGAGGGAAGCAGGGATTTGTAGAGGTGCCAGAGCTCGATTTTTGAATAGAGATAAATAATATTTTGAGCGGCATACTTTCATTGTTAACATAACAACCGAGAGATCTCGATATCTTCCATGCTACACACATTATAGGCGGTTCCCAAACATAATGGTAAAGTTTATACTCCCCCTCCACCAACAATCATCAATTCATGGCTTTCCCGAAACAACGGGTGCCTCCAACTAACAACAATCCTAGGGGAGTTTTGTTTGCAATTATTTTGATTTGATTTGAGCATGGGACTTGGCATCCGATGACCAGCCATTTTCTCGTGAGTGAGGAGCGGAGTCCACTCCTCTTGAGAATAACCCATCTAGCATGGAAGATACAGACAACCCTAGTTGAGACATGAGCTGTTAAAGCATACAAAATAGAATTTCATTTGAAGGTTTAGAGTTTGGCACATACAAATTTACTTGGAACGACAGGTAGATACCGCATATGGGAAGGTATGGTGAACTCATATGAAATAACTTTGGGGTTTATGGAAGTGAATGCACAAGCAGTATTCCCGCTTAGTACAAGTGAAGGCTAGAAAAAGACTGGGAAGCAACCAACTAGAGAGCGACGACAGTCATGAACATTCATTAAAATTAATAGACATTGAGTGGAAGCATGAGTAGGATATAATCCACCATGAACATAACATCGTGGAGGCTATGTTGATTTTGTTTCAACTACATGCGTGAACATTTGCCAAGTCAAGTCACTCGAATCGTTCAAAGGAGGATACCATCCTATCATACCACATCACAACCATTTTAATAATATGTTGGCATGCAAGGTAAACCTTTATAAACTCCTAGCAAATTAAACATGTCATAAGAAACTATAATCTCTAATTGTCATTGCAAACATGTTTATTCATAATAGGCTGAATCGGGAATGATGAACTAATCATATTTACAAAAACAAGATAGGTCAAGTTCATACCAGCTTCTCTCATCTCAATCAGTCCATCACATATCGTCATTATTGCCTTTCACTTGAACGACCGAACGGTGTGGATAATAATAATAGTGCACGTGCATTGGACTAAGCTGGAATCTGCAAGCATTTGATACAAGGGAGAAGGCAACGTAATATGGGCTTTTGGTTAAATCAACAATAATGCATATGAGAGCCACTCAACATTTTCATCATGGTCTTCCCCTCTCGACCTCCAAAGAAAAGAAAAGAAATAAAACTATTTACACGGGAAAGCTCCCAACAAGCAAAAGAAGAACGGAAAATCTTTTTGAGTTTTCTTTTAATTACTACTACTACAGGAATGGAAAGTAAACTATCTAATAGCTATAACTAATTTAAATTTTTGGTTTTTTCTTAAAGTTTTTCAAACACACAAGAAGAAAGCGAGAAAAAGAAAATAAACTAGCATGGATAGCACAATGAAAAAGTATGAGCACCGACAACTGGAATGAATGTGTGAACATGAATGTAATGTCGATGAGAAATACGCACTCCGCCAAGCTTAGACTTTTGGCCTAAGTTGGTCTATGCCCATGGATTGAAGCTACTCTCTCCGGTGTACTGAGGAATGTCATCAGGGTGCCACTGGTTGGCAATCTCCTCCGAATACCACTTATAAATGGAGCGTCGATAAGGGTCCAGTGGTGGTTCCGGCTCAGGCTCTGGAGCTGGTGTTAGGCTCCGGTATGCGTAAACGGCCTCCGGCAAGATGAGGTACGTGCCTGAAAATATGTTAAGCAAAGATGGTGCAGGCAAGATAATAGTCTCACTGTGAGTTTTATTAAATCCCAAATTATACTCAAGCATCATCTTCTTATTTTTAACAATAAATTCATGTGCTACCATACTCTTATAATCTAGAAAATAGGGGGC
->URS0001774F8E rRNA from 1 species 
-CCTACGGGCGGCAGCAGTGGGGGATATTGCACAATGGGGGGAACCCTGATGCAGCGACGCCGCGTGGGTGAAGGAGTGCTTCGGCATGTAAAGCCCTATCGGCAGGGAAGAAGCAAGACGGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATCCGTAGGGGGCGAGCGTTATCCGGATTCACTGGGTGTAAAGGGAGCGTAGACGGCCATGCAAGCTAGGGGTGAAACCCCGGGGCCCAACCCCGGGACTGCCCTTGGAACTGTGCGGCTAGAGTGCGGGAGGGGCAGGCGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCGGCGGCGAAGGCGGCCTGCTGGACCGCGACTGACGTTGAGGCTCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCCGGTAGTC
->URS00018E4F15 tRNA from 1 species 
-ACACCAGTGGTGAAACGGTTATCATGCTTGCCTTCCATTACCGTGAGCAAGCGGCGGGGGTTCGACTCCCTCCTGGTGTA
->URS0000B64D6B misc_RNA from 1 species 
-TGAAGATCTCTCCCTACACACCTCAGCAGTTGCAGATCAAATCTCTGGTTCAGCTAACCAAAGAGTTGAAATTGAAATGGAGATTCTTTCTCTTGGTCAAATGTTTGGGCCTTTGACAAACGGTTCCATCGGTGAAAAAGAGAATTCTTATCATGCTAAGGCTGAATACACAGAAAAACAGCTTCTCTTAAATGTTTCTGCTCAACTTAG
->URS00011ACD89 rRNA from 1 species 
-TACAGAGGTGGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCTTGTAGGTGGCCAACTAAGTCAGACGTGAAATCCCTCGGCTTAACCGGGGAACTGCGTCTGATACTGGATGGCTGGAGTGTGGGAGAGGGATGCGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAACACCGGTGGCGAAGGCGGCATCCTGGACCATTACTGACACTGAAAAGCGAAAGCCAGGGGAGCAAACGGG
->URS0001176963 rRNA from 1 species 
-TACGTAGGTGGCAAGCGTTGTCCGGATTTATTGGGTTTAAAGGGTGCGTAGGTGGTCTATTAAGTCAGTGCTGAAATATCCCGGCTTAACCGGGAGGGTGGCATTGATACTGATGGACTTGAGTAAAGTTGAGGTAGGCGGAATTGACGGTGTAGCGGTGAAATGCTTAGATATCGTCAAGAACACCGATAGCGAAGGCAGCTTACTAAGCTTTAACTGACACTGAGGCACGAAAGTGTGGGGATCAAACAGG
->URS000182FF44 rRNA from 1 species 
-TGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGAGGAGGAAGGCGTTGTGGTTAATAACCGCAACGATTGACGTTACTCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTCTGTCAAGTCGGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCCGAAACTGGCAGGCTAGAGTCTTGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACAAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACA
->URS0000745C0A rRNA from 1 species 
-CCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGAAAAGCCTGATCCAGCCATGCCGCGTGCAGGATGAGGGCCTTCGGGTTGTAAACTGCTTTTGTACGGAACGAAAAGACTCTGGTTAATACCTGGGGTCCATGACGGTACCGTAAGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTATATAAGACAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTTGTGACTGTATAGCTAGAGTACGGCAGAGGGGGATGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAANCANCCGATGGCGAAGGCAATCCCCTGGGCCTGTACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGTCAACTGGTTGTTGGGTCTTCACTGACTCAGTAACGAAGCTAACGCGTGAAGTTGACCGCCTGGGGAGTACGGCCGCAAGGTTGNAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGATGATGTGGTTTAATTCGATGCAACGCGAAAAACCTTACCCACCTTTGACATGTACGGAATCCTTTAGAGATAGAGGAGTGCTCGAAAGAGAGCCGTAACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGCCATTAGTTGCTACGAAAGGGCACTCTAATGGGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATG
->URS0001C47DC8 misc_RNA from 1 species 
-AAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTAAAGTGTTTCGGAGCCTGGCTCGGGCATCTCACCTCGAGGTGTCGGTGTCAGCGCCCCCACACGTGTTTACTCAACTTGGTTGCCTTGGTGAGCCTGCCCTCGTGGCTGCCGGGGATGCCTCACGGCGTTCCGGGCTCGTGCTCACCAGTGGATCATTTGAACTCTTCTGTGAAAATAGCCAGTCTGAGCATTATGCAAATTAAATAAAACTTTCAACAACGGATCTCTTGGTTCCG
->URS0001C9BECE rRNA from 1 species 
-GATGAACGCTAGCGGCAGGCTTAATACATGCAAGTCGAGGGGCAGCATGAAGTAGCCATACTTTGATGGCGACCGGCAAACGGGTGCGGAACACGTACACAACCTTCCTTTAAGTGGGGAATAGCCCAGAGAAATTTGGATTAATACCCCGTAACACAACTAAGTGGCATCACTTTGTTGTTATAGTTTCGGCGCTTAATGATGGGTGTGCGTATGATTAGATAGTTGGCGAGGTAACGGCTCACCAAGTCTACGATCATTAGCTGATGTGAGAGCATGATCAGCCACACGGGCACTGAGACACGGGCCCGACTCCTACGGGAGGCAGCAGTAAGGAATATTGGTCAATGGACGCAAGTCTGAACCAGCCATGCCGCGTGAAGGATTAAGGTCCTCTGGATTGTAAACTTCTTTTATATGGGACGAAAAAAGGTCTTTCTAGACCCCTTGACGGTACCATATGAATAAGCACCGGCTAACTCCGTG
->URS0000FFB7EB rRNA from 1 species 
-TACGTAGGTGACCAGCGTTGTCCGGATTTACTGGGCGTAAAGAGCGCGCAGGCGGTCGTTCAAGTCGAGTGTGAAAGCCCCCGGCTCAACTGGGGAGGGTCACTCGATACTGATCGACTTGAAGGCAGGAGAGGGAAGCGGAATTCCCGGTGTAGTGGTGAAATGCGTAGAGATCGGGAGGAAGACCGGTGGCGAAGGCGGCGCTCTGGAACATTTCTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGG
->URS00002FFC52 rRNA from 1 species 
-TTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAATTTCGGGATCAATATAACGGTCATGCCGTTGGTATGCACTGTTATAATTGATTTCTCACCTTCTAAAGAACCGTAATGCCATTAATTTGGTGTCACGGGGAATTAGGACTGTTACCTTGAAAAAATTAGAGTGTTTAAAGCAGGCTCACGCTTGAATACATTAGCATGGAATAATGAAATAGGACATCCGATTCTATTTTGTTGGTTTCTAGGATCGATGTAATGATTAATAGGGATAGTTGGGGGCATTAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGGCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGATGATGTTAATTTTTTAATGACTCATTCGGCGCCTTACGGGAAAC
->URS00002B11A3 rRNA from 1 species 
-TGGAACTTGTTCTGGTGGATTAGTGGCGAACGGGTGAGTAACACGTGAGCAACCTGCCCAAGACTTTCGGGATAAGCCTGGGAAACTGGGTCTAATACTGGATATGACCTTTCATCGCATGGTGTTTGGTGGAAAGATTTTTTGGTTTTGGATGGGCTCGCGGCCTATCAGCTTGTTGGTGAGGTAATGGCTTACCAAGGCTTCGACGGGTAACCGGCCTGAGAGGGTGACCGGTCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCGACGCCGCGTGAGGGATGACGGCCTTCGGGTTGTAAACCTCTTTCAGTCAGGAACAAGCCACTTGTGGTGAGGGTACTGGCAGAAGAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCGAGCGTTATCCGGAATTATTGGGCGTAAAGAGCTTGTAGGCGGTTTGTCGCGTCTGCTGTGAAAGCCCGGGGCTTAACTCCGGGTCTGCAGTGGGTACGGGCAGGCTAGAGTGATGTAGGGGTAACTGGAATTCCTGGTGTAGCGGTGGAATGCGCAGATATCACGAAGAACACCGATGGC
->URS0000D07B33 snRNA from 1 species 
-ATACTTACCTGGACGGGGTCAATGGGCGATCAAGAAGACTCATGGCCTGGGCTAGTGACCTCCATTGCACTTCGGAGGGGTGCTTGCTTAAGGTCTCCCCAAGAGGGAGAGCCTACGTCATAATTTGTTGCAAGGGGGTTTGCGTTCGCGCAGCCCCCAC
->URS00007AB434 rRNA from 1 species 
-CCTACGGGGGGCAGCAGTGGGGAATCTTGCGCAATGGGCGAAAGCCTGACGCAGCCATGCCGCGTGAATGATGAAGGTCTTAGGATTGTAAAATTCTTTCACCGGGGACGATAATGACGGTACCCGGAGAAGAAGCCCCGGCTAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGGGGCTAGCGTTGCTCGGAATTACTGGGCGTAAAGGGAGCGTAGGCGGATAGTTTAGTCAGAGGTGAAAGCCCAGGGCTCAACCTTGGAATTGCCTTTGATACTGGCTATCTTGAGTATGGGAGAGGTATGCGGAACTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAAGGCGGCATACTGGCCCATTACTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGAGTGCTAGTTGTCGGCATGCATGCATGTCGGTGACGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGGTCGCAAGAATTAAAACTCAAAGGAAATTGACGG
->URS0000128881 rRNA from 1 species 
-TTGACGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGCCTTGACATGCAGAGAACTTTCCAGAGATGGATTGGTGCCTTCGGGAACTCTGACACAGGTGCTGCATGGCTGTCGTCAGCCCGTGTCGTGAGATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCTTGTCCTTAGTTACCAGCACGTTATGGTGGGCACTCTAAGGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGGCCTGGGCTACACACGTGCTACAATGGTCGGTACAAAGGGTTGCCAAGCCGCGAGGTGGAGCTAATCCCATAAAACCGATCGTAGTCCGGATCGCAGTCTGCAACTCGACTGCGTGAAGTCGGAATCGCTAGTAATCGTGAATCAGAATGTCACGGTGAATACGTTCCCGGGCCTT
->URS0000FA1FD2 rRNA from 1 species 
-ATTGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGATCGGTAACGCGGGGGCAACCCTGGCGACGAGAGGCGGACGGGTGAGGAACGCTTGGGAATCTGCCTATCAGCGGGGGACAACACGGGGAAACTCGTGCTAATACCGCATACGCTCTACGGAGGAAAGCCGGGGACCGCAAGGCCTGGCACTGATAGATGAGCCCAAGTCGGATTAGCTAGTTGGCGGGGTAACGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGACGATCAGCCACACTGGAACTGAGACACGGGCCAGACGCATACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGGGAAACCCTGATCCAGCGACGCCGCGTGGGTGAAGAAGGCCTGCGGGTTGTAAAGCCCTTTCGGTAGGGACGAAAGCTCTCGACCTAACACGTCGGGAGGTTGACTTAACCTACAAAAGAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAAGAC
->URS000258AA4F rRNA from 1 species 
-ATGGCCGCTCGTGTTAGCGGGCTCGCGGTGGGCTTCCTCTGCCTGCTTGCAATGTTGTCGCCGTCCGCGCAGCAATCCCCGCCCCCAGACTCCCCAGATTTAAAGTCGTCAATAGACACAGACACCCCACCTCTCCCTGACATACGCCCGCCCCCGAGCTCCCCGCGCGGCTACGAGTTGGACGTGCCCCCCAGGAACGTCACGTGCAAGGATACCGACGGTAAGCGGCCGGGGTGCACGGGAACTTGCCCTCGCCGCTGCCCCCAGTGCATCGTCCTCTGCCCCGACTGCAAGACATTATGCCATGACGAGGTACAGATGCCAAGGCCCGTGCCGCCACCTGCCATGTTGGTGTTCGGAGATGGGCAGTTCGACAACGGTAACAACGGATACTTGGAGCCCCCTAACTACCCCTACTCTGGCACCGGCAGGCTTAGCAACGGGGCCAACCTTGCCGATGCCATTGCATACACTATCGGATTCCCGCAAAGTCCTCTACCCTTCATGTCGTTGCGCGGCCGGATCAGCATGTGGGGCGCCAACTACGCTTCCGTGGGCGCTGGGATTCGGAACTCCACGAACGGAGAGCGGAGCATCCCTCTTTCGCAGCAGCTGGAGGACTTCAGGACGACGAGGGCCCTTATGGGGATAATGCTAGGGGGTGAAGCCAAGCTGCGCGCGTACCTGTCCAAGTCCATCTTCCTCCTCGGCATCGGCAGTCAGGACCTCGACCCAAGATGGAACATACACCTCGCAAATTCGACCGAGATCCAGAGCCTCGTTGCCCTATACGGGGAGGCCGTCACGTCCCTCTACGACATGGGCGCTAGGAAGCTGGCCATCGTCAACGTTGGGCTCATCGGCTGTGCGCCCCAGATCTTTGACTACAGGTACGGTTGCGACGAGAGCCTGAACGACCGCGCCGCCGCGTTCAACGCCGCCCTCAAGCCCCTCATGGCTGGCCTTGCGTCAAAGAAGAAGGGCCTTTTCTACTCCATCGGCGACTTTCATAGCTTCACCACCACCGTCTTCGCCGACCCGTCAGCTTATTGGATGGTGAACATCCGGGACTCGTGTAGCTTCACGGACCACCCAGAGAGGACGTGCTCTCCCCAGGAAGAGCACTGGTTCTGGGATTCAGAGTTCATGACGGATCAGGCATGTAGGCTGACGGCCACTGCATTTTACTATGGACCGCCTCAGTTTACCGCCCCCATGACCTTCAAGGCACTGCTGGAGAAATAA
->URS0001D7E6BA misc_RNA from 1 species 
-GATGAAGAACGCAGCGAAATGCGATAAGTAGTGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCCTTGGTATCCCGAGGGGCATGCCTGTTCGAGCGTCATTTCAACCATCAAGCCCCAGCGCTTGTGTTGGGGGCCTGCGGCTGCCGCAGCCCCCTAAAAGCAGTGGCGGGCTCGCTATCACACCGAGTGCAGTAGTTCATCTTCTCTCCGGTCTTGTGAGGCGGGTTCCGGCCGTGAAACACCCCACTACATTCAAGGTTGACCTCGGATCAGGTAGGAATACCCGCTGAACTTAAGCATATCAATAAGCGGAGGA
->URS0002341CEB lncRNA from 1 species 
-GGCAACGTGTTCCGGTCCTCTTCCACATCACGGAAGATTTGCTCTTTCCTCTTTGCGATGAATCTTGCTGCTGGTCACCCTTTGGGTCCACACAGCATTTATGAGCTGTAACTTTCAGTGCGAAGGTCTGCAGCTTCATTCCTGAAGCCAGCGAGACCACAAACCCACCGGGAGGAAAGAACAGCTCCAGGCGCGCCGCCTTAAGCGCTGTAGCACTCACCGCGAAGGTCTGCAGCTTCACTCCTGAGCCAGCGAGACGACGAACCCACCGGGAGGAACGAACAACTCCAGGCGCGCCGCCTTAAGAGCTGTAACACTCACTGCGAAGGTCCGCAGCTTCACTCCTGAGCCAGCGAGACCACGAACCCACCAGACGGAAGAAACTCTGAACACATCCAAACATCAGAAGGAACAAACTCCGGACACGCCTCCTTTAAGAACTGGAAAGACTCACCGCGAGGGTCCGTGGCTTCATTCTTGAAGTCAGTGAGACCAGGAACCCACCAATTCCGGACGCACTTCCTCCGGACTGTTGGTGCACTGAGTGATCTGAAGTGCTCCCTGGCCACCATGAATGTAAGCAGAGATGGTGTCTCACTTTGTTGTGCAGGCTGGAATGCAGTGGCACAATCATAGCTCACTGCCGCCTCGAACCCTTGGACTCAAGCAATCCTCCTGCCTCAGCCTCCCAAAGTACTGGGATTACAGGTATGA
->URS0000160626 rRNA from 1 species 
-TCTAACACATGACACGTCGAACGGTAACAGGAATTAGCTTGCTAATTTGCTGACGAGTGGCGGACGGGTGAGTAATGCTTGGGAATTTGCCTTTGCGAGGGGGATAACAGTTGGAAACGACTGCTAATACCGCATGATGTCTACGGACCAAAGGGGGCTTTTAGCTCTCGCGCAAAGAGAAGCCCAAGTGAGATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCGACGATCTCTAGCTGTTCTGAGAGGAAGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGTTGTGAGGAAAGGTTGGTAGTTAATACCTGCCAGCTGTGACGTTAACAACAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTCAAGCGAGATGTGAAAGCCCCGGGCTTAACCTGGGAATTGCATTTCGAACTGGCAGGCTAGAGTCTTGGAGAGGGGAGTGGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAACATCAGTGGCGAAGGCGACTCCCTGGCCAAGACTGACGCTCATGTGCGAAAGTGTGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCCCACCGTAAACGCTGTCTACTAGCTGTGTGTGC
->URS000188CCB0 rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGCTCGGAATCACTGGGCGTAAAGGGTGCGTAGGCGGGTCTTTTAAGTCAGGGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTTGATACTGAAGATCTTGAGTTCGGGAGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGATACTGACGCTGAGGCACGAAAGCGTGGGGAGCAAACAGGATTAGATGACCTTGTA
->URS00019B19CC lncRNA from 1 species 
-GTCAGTATGAGCATGGAACTTGCTTTAGCCAGTGAAATGTGAACCGTGTACCCTGTACCACTCTCAGGAGGAAGATTTGCAAGCCACTAAGTGGACCTGCCTGACCCCTCCCTTGATGAAGTTACCTTTGCCCCACGTTCTAATCAACCTATACCCCGTAGGCCATCCTTACACTTCTGCTGGGGGTCTGGGTGGACCCCAGGTCAGACAACAATTCATGCTAAGCTGCTTATGAACAGCAGACCACCTGCTGCAGAATCAGGCAGGACATGTGTAGCCTATTTCCATCAAACCTTCTGAAATGGAAACCCCAGGAGTAGAGTCCAGCATCCAGGCCCACAGGATTCCCAGACATACTCAGGTATAAAAATGCCACTGAGTCCTCTGTTAATTATTGACTCCAAAACATTTCTTTGCAGAAGATGATGTTTTCTAAGACAGTGATCTGATTTTAAATTACCAAGACACTGAGTCCTTATTTTATATTCTTTTTCATCTTTACACAAATTTTCTTAAATTAATGCTCTTTAAAATAAGCTCATTTAAAAAAAATGGTGATAAATCTCCAGGTTCTACAGATGGAAAGACTGAAAATAAGACACAGGTATCAAAAACAGAATAAGTGGATCTAATGCAGGGATGTCAGGTGTGCCTCTGGGCCCTCATCCATTCCAAATCCCACTCCACACCTACCTGTCCATTCTCAGATTAAAGAACAGAATGCCCAGACTGCAAAGAAATTAACATGCCCCTTCGTTTTTATTAGCTTTTATTTTAGGCTCATTATCCATACCTCTGTGCATCCCTATTCTGTGTCTGCACTCATTTAGAAGCCAAATACCAGTAGGCCAATCAGCACATT
->URS00021FE078 rRNA from 1 species 
-GCAGCCCCCTGGGCCAATACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGTCAACTAGTTGTTGGGGATTCATTTCCTTAGTAACGTAGCTAACGCGTGAAGTTGACCGCCTGGGGAGTACGGTCGCAAGATTAAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGATGATGTGGATTAATTCGATGCAACGCGAAAAACCTTACCTACCCTTGACATGGTCGGAATCCTGCTGAGAGGCGGGAGTGCTCGAAAGAGAACCGGCGCACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCCTTAGTTGCTACGCAAGAGCACTCTAAGGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTATGGGTAGGGCTTCACACGTCATACAATGGTCGGAACAGAGGGTTGCCAACCCGCGAGGGGGAGCTAATCCCAGAAAACCGATCGTAGTCCGGATTGCACTCTGCAACTCGAGTGCATGAAGCTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGTCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTTTACCAGAAGTGGCTAGTCTAACCCGCAATGAGGACGGTCACCACGGTAGGATTCATGACTGGGGTGAAGTCGTACAGGGTTAGCCCGTAATG
->URS0000794101 rRNA from 1 species 
-CTGATAATTGGAATGAGAACAATCTAAATCCCTTAACGAGGATCCATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGGATTTCTGGCAGGAGCGACCGGTCACACACTCTGTGTGTGAACTTGTGTTGTCTCTGGCCATCCTTGGGGAGATCCTGTTTGGCATTAAGTTGTCGGGCAGGGGACATCCATCGTTTACTGTGAAAAAATTAGAGTGTTTAAAGCAGGCTTATGCCGTTGAATATATTAGCATGGAATAATAAGATAGGACCTTTGTTCTATTTTGTTGGTTTTTAGAATTGAGGTAATGATTAATAGGGATAGTTGGGGGCATTCGTATTTAACTGTCAGAGGTGAAATTCTTGGATTTGTTAAAGACGGACTACTGCGAAAGCATTTGCCATGGATGTTTTCATTGATCAAGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCCTAGTCTTAACCATAAACCATGCCGACTAGAGATTGGAGGTCG
->URS0000E403FD rRNA from 1 species 
-TAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGCGATGAAGGCCTTCGGGTCGTAAAGCTCTGTTGTTAGGGAAGAACAAGTGCTAGTTAAATAAGCTGGCACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAGGGTCATTGGAAACTGGGAAACTTGAGTGCAGAAGAGGAAAGTGGAATTCCAAGTGTAGCGGTGAAATGCGTAGAGATTTGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGTCTGTAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCCCGTAGTCC
->URS00003FB220 rRNA from 2 species 
-TTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGCAGAACCTTACCAGCCCTTGACATACCGGTCGCGGACACAGAGATGTGTCTTTCAGTTCGGCTGGACCGGATACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGCCTTTAGTTGCCATCATTTAGTTGGGCACTCTAAAGGGACTGCCAGTGATAAGCTGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTACGGGCTGGGCTACACACGTGCTACAATGGTGGTGACAGTGGGCAGCAAGCACGCGAGTGTGAGCTAATCTCCAAAAGCCATCTCAGTTCGGATTGCACTCTGCAACTCGAGTGCATGAAGTTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTTGGTTCTGCCCGAAGGCACTGTGCTAACCGTAAGGAGG
->URS0000583501 sRNA from 1 species 
-TCAAAGTGATCTCCCGCAGGCGGACTGCCA
->URS0001BC1447 sRNA from 18 species 
-CCGCGCCCGCUGCUUGAGGGUCAAGGCCCUCUUGCCUGUGCGCAAAAUCUGGUCGAGCCGCUGACUUCUGGGUCACCGCCAUGCGCACAACAGAUACCGCCGGUCUAAAGCGUCCGCGUAGGUCUCGCGCAGUUUCCGAACUGAUCGGCAAUGCCUUCGGUUUGGCGAUGUAGAUAGCUCGACAGGUCG
->URS00018C39BD rRNA from 1 species 
-TACGGAGGGTGCAAGCGTTATCCGGATTCACTGGGTTTAAAGGGTGCGTAGGCGGATAGGTAAGTCCGTGGTGAAATCCTGCAGCTTAACTGCAGAACTGCCATGGATACTATCTATCTTGAATGTCGTGGAGGTTAGCGGAATATGTCATGTAGCGGTGAAATGCTTAGAGATGATATAGAACACCCATTGCGAAGGCAGCTAACTACGCGATAATTGACGCTGATGCACGAAAGCGTGGGGATCAAACAGG
->URS0001C413C7 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACGGACGAGAAGCTTGCTTCTCTGATGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATTTTGAACCGCATGGTTCAATAGTGAAAGACGGTCTTGCTGTCACTTATAGATGGATCCGCGCTGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCATAGCCGACCTGAGAGGGTGATCCGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTGGGGAAGAACAAATGTGTAAGTAACTGTGCACATCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTG
->URS00023022DC rRNA from 1 species 
-TGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGCCTTATGGTTGTAAAGCACTTTAAGCGAGGAGGAGGCTACTTTAGTTAATACCTAGAGATAGTGGACGTTACTCGCAGAATAAGCACCGGCTACTCTGTGCCAGCAGCCGCGGTAATACAGAGGGTGCAAGCGTTAATCGGATTTACTGGGCGTAAAGCGCGCGTAGGCGGCTAATTAAGTCAAATGTGAAATCCCCGAGCTTAACTTGGGAATTGCATTCGATACTGGTTAGCTAGAGTGTGGGAGAGGATGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGATGGCGAAGGCAGCCATCTGGCCTAACACTGACGCTGAGGTGCGAAAGCATGGGGAGCAAACAGG
->URS00003F74AF piRNA from 1 species 
-TCTGACCTTCACACCTACACCGT
->URS000219B0C7 rRNA from 1 species 
-TGGTGGGTAGTTTGACTGGGGCGGTCTCCTCCTAAAGAGTAACGGAGGAGCACGAAGGTTGGCTAATCCTGGTCGGACATCAGGAGGTTAGTGCAATGGCATAAGCCAGCTTGACTGCGAGCGTGACGGCGCGAGCAGGTGCGAAAGCAGGTCATAGTGATCCGGTGGTTCTGAATGGAAGGGCCATCGCTCAACGGATAAAAGGTACTCCGGGGATAACAGGCTGATACCGCCCAAGAGTTCATATCGACGGCGGTGTTTGGCACCTCGATGTCGGCTCATCACATCCTGGGGCTGAAGTAGGTCCCAAGGGTATGGCTGTTCGCCATTTAAAGTGGTACGCGAGCTGGGTTTAGAACGTCGTGAGACAGTTCGGTCCCTATCTGCCGTGGGCGCTGGAGAACTGAGGGGGGCTGCTCCTAGTACGAGAGGACCGGAGTAGACGCATCACTGGTGTTCGGGTTGTCATGCCAATGGCACTGCCCGGTAGCTAAATGCGGAAGAGATAAGTGCTGAAAGCATCTAAGCACGAAACTTGCCCCGAGATGAGTTCT
->URS0000670AD8 snoRNA from 2 species 
-CCTGCTCCTGGAAGTGTTGCTGGTGTGGCTGCTGTGCCACATGTTCGCCAGTAGGTGGCAGATAGGAGAGAGGCTGTGTTTATGCTCAGTGTTCTGAACTGTGAACTGTGAATGATTCGTAGCCTAACAAT
->URS0000C73CE8 ncRNA from 1 species 
-GTGTCCGAGGAGCGTTGCAAGGCCGGTCGATTCAGGCGACCGCCCCAGGCTCGGACCCCTTCCCACAGGCAACGGCGCTCACCCGTC
->URS00002A852C rRNA from 1 species 
-AGGACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAGCGGAAAGGCCCTTCGGGGTACTCGAGCGGCGAACGGGTGAGTAACACGTGAGCAACCTGCCCTTAGCTCCGGGATAGCTCCGGGAAACCGGAATTAATACCGGATATGACCTAGGCCGACATCGGCTGTGGGTGGAAAGTTTTTCGGCTGGGGATGGACTCGCGGCCTATCAGCTTGTTGGTGGGGTAATGGCCTACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGCGACCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATCTTGCGCAATGGGCGAAAGCCTGACGCAGCGACGCCGCGTGGGGGATGAAGGCCTTCGGGTTCGTAAACCCCTTTCAGCAGGGACGAAGCGAAAGTGACGGTACCTGCAGAAGAAGCGCCGGCTAACTACGTGCCAGCAGCCGC
->URS0002550A56 misc_RNA from 1 species 
-TCCGGTTTAGCACCGGCAGTCTCCCTAGAGTTCCCGGCTTTACCCGCTGGCAACTAAGGACAAGGGTTGCGCTCGTTGCGCCACTTAAGGCAACACCTCACGGCACGAGCTGACGACAGCCATGCACCACCTGTGCAGGCTCCGTAGAGCGCCGGCTTTCACCGGCTTTTCCCACCATGTCAAACCCAGGTAAGGTTCTTCGCGTTGCGTCGAATTAAACCACATGCTCCGCTGCTTGTGCGGGCCCCCGTCAATTCCTTTGAGTTTTAGCCTTGCGGCCGTACTCCCCACGCCGTAAACGATGGGCACTTATCGCGTTAGCTACGGCACGGAAGGGGTCAATACCTCCCACACCTAGTGCCCAACGTTTATAGCGTGGACTAC
->URS00023AAB80 lncRNA from 1 species 
-TTTTTTTTTTTTTTTTTGCAGCGCCCCGTGGTGCACCTATTCCTGCTCCAGGTATAGATATATTCATAAATCCTTTGAAAATATAAACCATCAATACAAACTGAATTCTATTTGCTTATTAGTTTATTTATTCGTTTGACAGGTCCAGTCTCTCTAGCACCCAAACTCTCCCCTGGAGCTTCACCATCTTTAAGCCCCCAAAGTCCCATTGTGCCGGAACCGACACCATCTGCCGAGGTGCCTGATTCCGGCACCACACCGGCTCTAACTCCACCATCGTCCACAGCAGGTTCGGGAGCCCCGACGGCCGCAACGGGGAGCCGCCCTGTTCTCACCCCATCAGCTGCCAACCCCGCTTACAGTTTCTCACCATTCCTTTTGGTGTTCACATTGGGATTTGTGATTTTCAAGTACTAATTATATAATATGTATTGATTGATTTGTTTGGCGAGCGGTATTCTTTTAGTGGCTTGAACTGAAAACCATTGTTTTGCCTTTTAAGAGCTAATATTGGGTGACTTTACATTTTATATAAAATATACATATTAGTGTAATTTTTATTTATTGAGTAATAATTTTTTTTTATTTCTGCAATGATTATTTTTTAGGGTAAACTACACATATAGTCACTTTTGTTTACTTTAGGTTACATTTTGGTTACTTATGTTTAAAATATTACGTTTTAGTCACTTACGTTATCGTGTTGTAACATTTTAATCACTGAGCCGTTAATTTCCGTTAACGGTGTGACGGTAAGCTGACGTGGCACGTTAAATCATCATTTCAAACAAAAATTTTAGGTTAAATTATACAACTGATCCCCATATTTTTTTTGGGCAATTTAATTTTTTTCTTTTATATTCTTTAAACCTTACTCTCTCTTTTTCTCTTTATTTTCCATTATCTTCTGTTTCTCCTTCTATTTTCCTACCTTTTCCATGTCTTTTAACATATTAAGAAGTCGAATTGGCAGTGAAGAAAGAAGTAGGAAGCCGAAAGCCATCATTGCCTATAATCAAAACCCATAAACCCGTACCATGATTCTTTCTTCACTGCCAATTTGACTTCCTGATATGTTAAAAGAAATGGAGAAGGTAGGAAAACAGAGGGGGAAGCAGAAGAAAATGGAAAATAAAGAAAAAAAGAAAGTTAAAAGAACATAAAAGAAAAACTTAAATTGCTCAAAATGACAAAAATATGGGGACCAATTGTATAATTTAACCTAAAATTTTTGTTTGAGATGATAATTTAACGTGTCACGTCAGCTTACCGTTACAATGTCAATGGCAATTAATGGCTCAATGACTAAAATGTTACAACATGAAAACGTAAGTGACAAAAATGTAACATTTCAAACATAAGTGACTAAAATGTAACCTGAGATAAACAAAAGTGACCATAGATATAGTTTACCCTATTTTTTATTGGTTAATTTGATGTGAAAAATGGGAAAAGATCATAAATTATTGGTACATTACTGATCTTCTATTATTAGCAAATTAAGTTGTTTATTAATTCCATTTGAGTAATTCTCAAGGAATTCAATATGAGATCCCAGAGGTTTTTTTTTTATCATGTTATTTTTAAGTTTTTTAGAATCAAGATTAAATAGATAGAATGCATAAATTTAAGGGTTAAATTTGTTGAATTTTTAGAATTAGGACCAATTTGATAGAATTTGTAAACATTGTAGGGTTAAATTTGTTGATTTTTTTAGAATTAAGACCAAATTGATAGAATCTGTAATTATTGTAGAGCTAAATTTGTTATTATGTAAATAAAATAGATCACGTCAGCATCCAAATAATAATTTAACAAAGGAGTGATCAAAATATTAAATGTCAATAATGTTAATGACTAAATCTGAAATTTTTGGAGATGGGTGACCAAAACATAAATATGCTAATAGTTGGGTGATTGCGAGTGTGGTTTACCCTAAGATTAACAGTAATAAGAGGATCAGATTGTGATAAATTAAAGTATAGAGACTAAATATCCAAATTGAGTATACAATAAGGATGTAACCGCAATTTAACCTAATTAACTAAAATGATTTATTAGGCCCCTCACTAACGGCCATTCCCGCCATATTCATTTCCAATTTACTTAAATACCCTCTCCCTAACAGATTTTTAACTACCATAATCAACCGTCTCTCACTTCCTCTCACCGCCATGGCAGCGAACATCTTCATATTGCTCCTCCTTGGTGTGGCGGCGCAGCCACTTCCACCAGCACCCCAGCAACCAGGCTGCGTGGAGGAGCTGGTGGCGTTTTCGCCTTGCCTGCCCTTTGTATCAGACCCACCAAACAACGCCACAGACTCAGTTGCTCCACAGTGCTGCGACGTCTTCAATTCTGCTTTCGAATCCGGCGACGGTTACTGTTTCTGTTACATCCTCCGGCAGCCGCGGATCTTTGGGTTTCCGTTGAACAGAGAAAGGGTTGCTTCACTGTCTTCCTTTTGCATGGCCAAGAACGGCGTTGCTTCTCTAGACTCGCTCTGCTCTTCAGGTTTTTCATCTTTTCTTAAACCCAATTGTTTAATTCACGGATTTCCGGATTAAGAATTTCATCAGGTTCAAGGCCATTTTAATCTTTTGATTAAAAGAAAAAATAGTTATTTAACGCTTTGATTGATGTAATTATGCAATTCTTAATTAGTATTATGCATTAGGTGCACCAGCGCTGCCGCCATTGCCAAGCACCACAGATTCAGGGATATTGAAACCATTCAATTCTCGTAAGTAAAGTCCGAATATCTTTTCTTTTTTATTTTTTCTCCTTTCGGAACCGAATCGGCGGTCAAACCTTACTACCTTAGTAGTTCTCGATCAGACTAATTCAATGATCAGACTGGTTTTAATTAAATAAATCATTTAAAAATTTATAAAATTTTTGAAAAGTAAAATATATTAAAAAAGTATAAAACTTGGTTCAACCGGTTTGCAGGTCAGTCAGTTCTTTCCCTTACTCTAGACTAGTGTACCAGCTGGTTCCCGTCCAACCGGCCAACCTTGCATTTTGTTCTTCCATGGCTGTAATAAAAGATTACCTAAAAGGAAATGTTCATTTGCAGCGTTCTTGCTTGTAGATTGACCAAATATAAGCCTAAATTATTTGTTTTAAAGATAGACCGGATTTTAAAACTCGTAAAAGGCCGATACCAAAAGCATATCAAGGCAATGGCATTATCAGTGATCTGTTATTGGTGGTAGAATCCTTATGAAAACTATTCTACAGGTTTAGATAATGATTCAACAAGCTCACCCCCAGAATCTGCGGTCAAGTCGCTAACTCCGCCAAGTTCCTCAGCAGAAGAAGCTGTTTTTTCTTCTGCAACAAACCAGATTTACAAGCATATCACTTGGTTCCTACTTGGAATGGTGATTTTTCTGCTTAATCTACATTCATTCTTGGTCTGACAGTAGCTAAGATTTTCCCGATTTCATTCGATTATACTTACTGATACGATAAACACTTTGTAATCAGCAAAATGATATGATGGAAAGAGTTTTATTAGCAGAAAAACATCATCAAAAACAGATGGTAACAGTGTACGAAGATCTCTCCTCTTTTCGTTTGCTTTTACCACTATGCCGTCGTACTGTCTCTTGAAGTGAACAGGTAAGTTCATCACATTCGCTACTGTGAAAACAAAAGCATAAAAAAGCAAAAGAATCATTGTAGGATGCGTGTATTTCATTTCCACCCATCGGACCACTCAGCTTCATCCGTGAAAGGAATGAGATTTCCAATTTCCTTGGTATCTTCACCCCACATTTCAGCAATGCTGTTTTCATCATCGACCCGACAATCCTCCGGAGTTGAAACTTCTGCATCATCTTCATACTCTTGCCTTTCAGGCAGAGCACAACCCAGGTAAGAGTTATGATCGGCACAACGCCATATAAGCTGACTCCAGTAAGGGTCCTGCCATTCATTTATTATCAATGATTAAAAGCCTTTGGTTGTAGACATTAGATGATAATCACAAGTGAAGATTGGTACCTTGGAAATTATGTGAGGATTTCCAACAATAACAAGTAAAGCTATGGCGCGAGTAACCGCCACATTAAACCTTCTAGGATTGCTCAAAAACCCGAGACAGTGGGTTCTGTCGAACTCATTGTGTTTGATTGTTGATCGGACGGTAGATATAACGATAACTTTTCGTTCTTGGCCTTGAAATTGTTCGACGGTGCCAACCTTGACATCTGGTATGTCGAGATTCTCGAAGGCCTTCATTAGTTTAAGGACTTGCTGCCTATAGGGGGTTATCACCCCGATATCTTTCTCGTTCAGAATCCCACTTGCTGTCAAACTACTAACAATTTCTACAACCTTGCTGGCTTCAATCCGATTGAACCATGACGGATTACTTCCTTCCCTCTCATCACAACCTTGTATACCAAAGAAAAAAACAGGGTAGTCCTTATTAGGAAGAAACTTTACTGAGTTCAATAATGAACCTATGTCATCTTTGCAAGGGATCAATTCATCATTGTAGAAGAGAAGTGAAGGGAGATAGAGGATCTCCGGGTGACATCGATAGTTTCTAACCAGTTTTGTCACATAGTTTTCATTGCCATTAGAATAAAACTCGTGTTCAAACAACCTTTCTAAGTATGACTTCCCCAGTCCAAAATTCTCGGCTTCTTTGGAGTATATAACTGGACCTAACTGCTTTGGATCCCCAGCAAGAACAACAACAGTCTCTCTTCGGCAAAGGTTCGCTACAGGGATCATGCTTTCTGGCTCTGAAGCTTGACCTGACTCATCCAAGAAAATATGAGAGAAATGGCCTTTACCAACACTTTCTGCATACAGAAGGGAGGAACTCATGTAAGTTGAGATGATGATTCTGTAGCAGGCGAGAACACTAAGTGGAGGACATTTGAAAACAAGCTCATCAAAGAAGCAAAACCGGAGAAAATCCGGGTTGACGTCGTAATATGGTCGTGTAGCTGCATTTAGTCTGAATATTTCATTCTCTTTAATCTCAACAGACTCCTCATTAAGGAGTCTCTCTAGTATGAAATCAGCCGCGCTATTTGAAGGTGCACACACAAGAATTCGAGAAGATTTTTGGGTTGAGTAGAGCTGGAGGATTGCCTCCACTATTGTCATGGTCTTCCCTGTACCTGGTGGCCCAAAAATCACATAAGGAGGTCCTCCTTTGCAGCCAAGGATCATCTCAATTGAACACATCTGCTCCTCGTTAAGTGTACAACATATGGGCACTAGTGGAGTGGTTTCAATCACCCTACTTTTGGGTGACCCAGATGGAAAAAGGAGACTTACATTTAGGCTTTTTGCTGCATCAATGGCCTGGTATTGCCTCCGCATATTGATTCGGTTATAGGTGAACTGCACATTATAAAGATTCTCATCTATGTGATTCGAGTGAAATTCTGGTGCAAACTTCAAGTACACTTCATCAGCTTCTACCCGATGGATACAACCCTGAAAATCACCACATTCACTTGTCAGAAAGACAGAAATTCTCCAAAAGAAATAGAGGCCATGGGACTGGAAAGACTAAAATGAACACAAGGGAAAGAGTATACAACAGAAGATACCGAGATAAATTTAAGCCAAAGAGGAAGTACTTCAATGATAAAAGGATAAAGCATATAGTATTTTTCGTGTAAAGCAGACCTCATAAACTCTGTCTGATCCACTAGCATCTTCACATGCAAGTTTAGCAAAAATATGATCTCCATGGACAAGGGAAGGCCTTTTTTCAGCGAGCCCAGGGACCTGAAGTGATAAATAATTCCCTCTCTTCCTCATGTTGATATTCTCCATGTTATAGGCCCTCATGTCCTCCTGAAGCCAAAAAAAGGGAATTTCTCAGTTTTGTAACACGAATATCAACCATCTAAGCTACCGAAGGTTAGAATTACCTCGAGTTGTAACTCTTCCAAGATTAAGAGATGTTTGAAGTAAGATACATAATTATCCCTTGTAAGACCTGCTTTAATAGCATCAGTAGTCTGCTTATTCTCAACCAGTTCTCTAATATCCTTCGGAATGTCATATGGGAGAAGCCTGTTTCGAACACCTCGACCCATTGCCCTTACCGGGCGTGGCCCTGTAACAAATTCATCCACTGGAAATTGCTTCTTTCTTTGAGCTCTGGAATATGGCTTCTTAGAAGCCAAAGATTGTGAGATCTTATCTTCAACCAAGAGAAAGACCATTCTTTCCAATCTTTCACCCTCCACATCAAAATGCACTATGGTAGTATGCAACCCAATTTCCTTTGCTTTGCAAGACAACCAAATGGTTAAAGTCTCTCCAGGCTGTATCATTCGGTCCTCTAAATCGAAAAGCTCGACAAACCCTTGGCTCATATCGTCTTCAGAATTTGCCGATGGGGGTTTCATCAAAGAAAGAACGAAAGAATCCTTAGGCGTTGATGCGTAAATTTTAGTCCACAACTCAACCGGTTCACTAGTGGTGTTTTCGATACTGATCAAATCAAATGCAGTTGCTCCCACGAATACAGATTGAGGATTCCCTTTCGAAAATGGGAATGGTGCAGAAATTATGAGAGGACCCCCCTCATGATTGTAATCACAAACAGATTTGTTGTTTGCATAATCGATGAAATTGATTTCGCGTTTGTCCCCGATGACCGAATACTCATCATCGGATTTGTCACCAACTGTTCCCATCACTAACTAGAAAGGGAAGAACTGCTTTGCAACAAAATCCACAAATATGCAATCATTAAAAAACCCTTATACAAGCAGGAACACACTTGTAAGATACAGTACACCACCATATATATATACCGATAAAATAACACTTTTAAACACGATTATGACGCAACAAAATACACGAAATTAACACGAATGCATAAATAAAGCAGGATGATAATCAAGTTTAAGCATTTTCAAATGTCATAAAAAAAAAGAGAAAAAGAAACCCAGCATTTCAATTTTTGCAATGCAACATAATACAATCATAGATAGATAGATAGTACAATACGTGAATCATAGGCAATAACGATCATTTAAAATTCATGATCAAAAGCAAAAACAAGGTCACAAAGCAGAAATTAACAAAACCCAGAAACAAGATAGTGACAATGTAGAAAAAATTAGAAAAAAATATTATTCAAATTCACTGTGCCAAAATTATAAACATTTAGAGTACGTTAGCATGAACTACTCTATGGGTAAAAAAAAAAAAAAGGAAAAAGAACTCACCTCAGTGAATCATAAACCAAAGCTAGAAACTACCATATGAATGAGAGGTTTTCCTTTTTTTTAAATGCAGAGAAATCAAATGAACCTTGAATTCAGTTTTTTAAAGTTTTTTAATTAAAATCAAATGAAAGAGACAATTTTTAAAGAAAATAAAAATAATATGACCCATCACAATCAGCAGATTTTGCCCTACAAGCTGCAAATAAAAAAAAAAACACATAGGTTCATATATTTCATTTTTTTGGCAAAAACAGGGAATTCATAAACAGACGAGGAAGTTAGTTTCACTTATCTATCACTTAAAATAAAGTATAAAAAATGTAAATTTTAATTAAAAATGGTATAAACAATTTAGATATTAAAGGTTTAATTTTTCTTTCAATCCCTCTAGTTTTTAGTTTTTTTTAATTTAATCCCTTTATTTATTGGATTTAAATTAACTTCAACAAAAATAAATTAAAGTTGTTATTAATTTAATTTTAATTTTTAAATCAAATAAGATACTAAAAAGAGAATGATTAAATTTTAAAAATATTGATAATGGGGAAATTGAGAGTACAATTAGAATTAGGGGTGAGAGTTCGATCGAATCAAGTGAAAAAATTTTGAGTTAATCAAGTTCACAAGTCCTATTTTATCATCTTAACTCAATTTAAATTTTTTCAAATATAGTCAAATTGAGTGAAATTATTCAAGTTAAATTAAAAAAATTAAACATGTTAAATAAAAATATTGTTACAGAATGACTAATTTTATGTTAGAGCATATAAATTTGAAACCATATATATTTGAAATAATTTTCAAAGCAAAATAATAATAATAATAAGATACTTGAGTATGATAAATTTGAATCATTAATTAGGTCTCTAAAATTATTATTTTATAAAATTTTTAGAATTTTTTAAAACTTTTATAATTTTTTAAAAAATATAAAATTTGAAATTTTTATAAATATTTTGAATTATTTTGTAATTTTTGTTGAGAGAAAAGCCAATTTATTTATTTCCAAAGTTGATAGGGACTAAAAGGTATTTACACCATTATTCGAATTGTGAAATTCAACTAACTTGAACTCAAAATTTGAATCGAGTTATTCGTGTTAATGCAAATCATTTAAAATTCAAAATTAACTCGATTCAATTAATTTGAAATTTAAAATTCTTTTCGATATTTTTAAATACCCTGATTCAAACTATTAAAAAGGAACTCATAAATATAGTTGAAAAAATTTACAGAGAAAATTTCTTCTTACATATTTTTATTTATTCTTACTAATAAATCCCATTGGCTTATATGACTCTTTTAGCCAATTGGCTTTCTCAGTGATAGAGACAGTTAATTTCCATTTTGATGAATGTATTAACTAATAATTAGAACTGACGTGGCTAAACCCTATTGGTTATTATGACACTCACCAATTGGCTTGTGAAGGGGTCCAAAAAATTTTCTATTTTTTAGTAATGAAATTAAAATAAAATGAGTTTTAAATTTTCTTTGATTTTTAATTGTATCTATTTTTTTGTAGGGGAAATTTATAGGAGTTTCTCTCCTAGTTTTTTTTAATAAATAAATTTTCTTTTTAATTTTGTTCTTTCATGAAATTGAAATCTTTTTAAAAACCGAATTCATCCAATCCGCTCCTATTCCTGTTGTGATCTTAACATAAATAGTGAGACAAATAACATGCCAAAGCTTCTCTACCTTTATGCAATAATCCTTTGTCTACCAAGTCCGGGGCGTAGTTAGGGGCTTCCCTCCTTTAAATTTTTTTAAATTTTAAATTAGTAAAGATAAAATTATATTTTAATCCTCTAAAATTGATAAAAATTTTTATTTAATTCTTTAAAAATTATAAAGATATAGGTTGTGAAATTATATTTTTACTATTATAAAAATTACAATTTAATTTTGACCCTCCCTAAAATAATTTTCTGGCTTCGTTCCTGACCAAGACCCTTATAAGATTCCAATTATCAAAAATTAAATTTCAGCCCCTCAAAAACTCGGTACTTTATTATTGGATTCAGATATGAAATATGCATATATTATTCTACTAGCTAAGATATATCAAAGCAAGTTAAAAAGGAATAAATCTTAAAAAATACATACCAGAATGAGGGAGCTATATAACCTTTCAGGGAGATCCTTGGAAGAGATGATCTTCAAATATACAAAAAAAAGGGTTGTTTTTTTCTTTTTCTTTTAACACCTGGGTAATTAGCATAGAAGTTTAATATATGTAAGTGATATTTTCGAGCGCGTGAAAATAATCAATTTATATAGAAAGCGAGAAACTTAATTTGGTATGTCCAGTAAGTAACCAAAAGTAATATAAATGAATAAATTTAGAATATTGGGATATTTTTATAATTAAAATATAAATTTAAATGATTTTAAATATGGGTTGTTGAAGCCTCCTCATTTTAAAATATTAATAAAATTATTTGTATATGTAATATATAACTGTAAAAATTATATTATATTGATAATAATGTTATTAATAATTTGTAAAAAAATTTGAATCTAATTATTTTAAACTTTAAATTTTTTTTATGTGAATCTATAATTTCAAAATAACAATTGAATAATCTATTTTATCTAATTTAATAAATAAAAATGTGTGACAATCCTTTTCTTTTACCAATAAATTAATAGAACTCAAATATAAAAAATATGCTACTAAGAGATTAGAAACATAATTCAAAGATCTTTTGCTCTCCATAAAAAATTTCCATCTCAAAATACATTGGTTAAGATGTGGCAGCCACAAATTGCTGTACTCTTTTGAAAGTTTAAATGTTAACTTCTTTATTTTTATTTTGAACAACTTTTATTTAAAAATAATAATTTTTCTATTTTTCAAATTTTAAAGTTCAAGTCTAACCATTAATATTAATATTTTTAAAATTCAAATTAATTATATCTTTTTTTTTAAATTATATGGCTATCAAGTAAGTTTTTTTTTATTTCATAATATCACACTAACAAATTTTAAAAAAAAAGTTAAACAATATTTAATAGTAGAATTTGAATTGTGAAATCTGAAAGGTAAAAAAACTAAATTCCTGAAAAAATACAAAGCTTAAATTTCAATTTTTTGAGAAGTATAGAGACTAATGGCATACTTTAATCAAATACAGTATCCCTACATCCCCAGATTTCGAACACCATCACAGCAACAACTTAGTTTTTAATATAAAAGGTTTGGCTGCTCAAGTCAAACATACTGTTTCCTGTCGTTAAAATGCAAATTAAAACATTCATTATGAAAGAGCAATCAAGGATAAAAATCTTTCAAGCTGAAGCAACTGCAGCATCCTTGACCGATTCACGCCAGGCATACTGCCTCGCTCCATCTTTGTCGACGATCTTGATAACAAAGTTTGGAGGTGCCACAACAAGTCGTGACCTTATCTCCATTATGCATTTATCTACCAAGTCGATGGCTTCTTCCACAGTCATGCCGCTGTGGTAGTGCCTGTCCATCATAGAGAGAGAAAAATAGGATCCGTACCCGAATGCTCCCTTATCAACTTTGTGAAGTGTAGCGATGTAGTCAATGTAGTAAAGTGAGGGGCCTGTCTCTTTGTCGTAGCCAGCAAGAAGAATGTTCACGAAGTATGGGTTCTATAAAAAACCAAATGCCATTGTTAATAATAATGATAGTAAGACGAACACGCGGGTGAGCAGAGACCTTAATTCAGCATTCTCATGTCAGACAGGACAAGAAATAAATAATAATAATAAACTCACTGCTAGAAGGAAAATATGCATAGGCAACCTAATAAGGAACTTCAAAACTAGATTTGCAAGATCCAAGAACCGCAAAGACCAATAAGTGCATTGAGCATCAAGCATGGCAGCAACAAAGATCAACAGAGATTTGAAAAGAAACTACATGTGCCAAGAGTCATCATCGGAACTCCAAAAAAAAAACACAGAGTATTGTAATTGTACTTTCAAAATTCCTTGGCCTTATTCTAATCTGATCTTCCTATCCAAAACAACAGCAATTAATCCATAAAGCTTGACAAGAAGTTCTATCAGAAACTACACCTTAAATTGAAATAAAATGTCATATGGTAATGGTCTCGTGCCATAAAAGCATCAACTCCTTTTTGAATCCTATAACAAGCTTACATATTTCATTATAAATTTCAAGCTCAAAAAATTTTAGTTCGAGCAAGCACAGCTGATTGTCTAGTGGAAATCTGAAGGAATATTTTCCTAGATTGTTTAATACAAGATGTAACCCATCTTTTCTCGGCTGAAAAGAATACCTTTACAGGAATCTCATTCAAAAACATATGGAATGGGAAACCACTAACTAGAAGACCCACAAACCAGACACAAAATCTCAGTGAAGGTACCACTAGTATTGCCAAGGGATGGACCTAGGCATTCCATCTTAGCGTCAAAAGATAAAAGAGCCTCAGATCTCTTCAGGCCAGGTGCATTTGATCAGGCACATGCTTGATGTGCATAAGCATACTTTTAAAGTTCCCTTTAATTTAACTTTTTTTAAAAAACATTTTCACTGGATATACATTTATTAGTAAGAAAAGGGAATTAATCAAGGGCTAAGATCCACTCCATTACTTTTTCATCCATTAATATCCAATACAATGATTATCACCATTCAAATGGTAGGACCCATCTATTAAATGTGAAAATCAACTTGTGAATGATGATTAAACGTGCATTGGATATTAATAGATGAAAAAGTAATTGAGTGGAGCCAAACCCATAAATCAAAACCTCTACTTCCCAGTATTGGAGAACTCGACAACAAATATGGGACCGTAAGGGAATCAAGCATATTGGCCAATAAAAATAAAAGAAAGCTTTGCATGTTTTATAGATAAATTGCATCAATCTTTAGAGTTTATTATCATAATTACATGCCTCAAGCTTTATATATACACAAAGACATAAAATTGCGCCTTTACTCAGTCAAGTGCTTTTTTTGTGCTTTGTGTCTTGGGCAATATAAGGGTTCTAACACTAGAGTGCCCCATGTGCTCTTGACAACACTGGGTAGAGATAGAAGGCCAAATAAAACCTTGAAGCCAAGATGAATAAGACAGTCTCTTAGTGAGGTAGCATCCAAACTTTGCACCAAAAAACAAATCCACAGGTTAACACTAAATGTTTAAGTAAGCAAAGGAAATGATAGCCCAGCAACTTCAAAACTTCCTGTGGTTTAGCTAAGCACTCAATAACTCAGCTGGCCCCAAAAGTGGTTACCATCACCCAGGAATCCCAAAAAAAAAATCGGCTTTAACATAACATATGCTTATCTTAGGTACTAGTTCAATGTCCTATGCTGTAAATCAAGCAAAGAAGTGATTGCAATCGGTTCTGGTAAAAGAGGGACCAAAGCACATATCAAGCTACACCAATCGTCGCACATTTCAGGGCATGGTAAAGCTATATCAAACCACTTTGCTTCCAATTCTAACTCATCTAACCCTTCCAGCATTGCTCTATACAAATAGTTTCCAAACCGGAAGCTTCTTCAATTATCGAATATCACCATAATGAGAAATCAAGCAGAGGTAAAACACAGATTATAGCTAATATTTCAATCCCAACGCACAATACATCATTTGAAACTAGTGCAAACCCTAACAAATATTGTATTCCACATAGATTCATTACTCTTCGCCGGTAAAATTTCCACAAGCAAGTAAATTGCAATTAAAGAGCATAACCCTTAATTGAAACTATATAATTGAAACTATATATATGACTAGTATCGATACCTTCCTTAATGCAGTGGCAAGCTCACCGCGAGTGAAATTGGCAGCGGCGGCAGTTGTCAAAGGAATACCATTGCGAAACTGATACAAAGCCACGTTTTTCTGTATATACTCCGTGAATTGCACTCTAGGGAAAAGGAAAAAAGGTTATATAGGAGGAAAAGAAAACAGGGAAGTATATACGTAGATTTATAGGGAGAGAAAGAAAAAGGGGGAAACCTGTCACCGGATTCACCGCTGGCGGCGATGAGTTTGTGAGAATCGAGGACCATGATCTTGTCTTCGTTGGATTTGTGGACGAGGATGCTGTGAACCGCCGATGTGTCCGCCGCCACTACGGCAAAGCCATTGCCTACGAAGCCGAACACGCACTCCATTTTCACTTTTTTTTTGAGGTTTGATTTTGAGGCTTTTGATTTTTTTTTTTTTAAAGCTAATATAAGTTAGTAGAACTGCCTTGAAGAAAAAGTTGTTCTTAGAGTGGGAAAATGGGGAATTTTGGGGAAAGATCGAGGGCTATTTTGTCATAGAAAGAACACTTGGTTTATTGTAACACGCGGTGCTATTTGCAAGGTCGGATTAAGACTCGATTTTAAAAAGATCCCAAGCCTAGCTCGACTAAGCGAATTCAAAATTTTTATATTCTTTTTTTAAAAAAATAATAAAATAATAAAATATATTTATATTTATATATTTTATAATTAAATTTAAATGAAGATATTTAAAAATCATTCTATTAACAATAAATATATTACTATAGTTTTCAACAAGTAGCATCTTATATTTCATCAATAATACATAAACTTAGGAAACTTATATCCTGATGTTGTCAACTTCAAGTATCAGTCATTTGTTCCAGCCTAGTTTTTAAACCTTCATAGACACAACCCCATAACTCCAAGCTCCAATGCTACGCTGCGTGAGAAGCCCATGATCCAAGTTCCATTTCTGTCTCGAAGCAAGCCTCCAATTACAGCCATCCATATTCAATTTGGTCCAGCAAATCTTTCTTCTCGCCACCCTCCAAAGTGTACTTGCCTAGATCCAGCATTAAAATCACCTGAACTGACAATAATGGAGTTCCTTTGTTCCCAGATTTTCCATACAATAATGTGCATTGTTAAACAATAGCCCATGCAGTCTTTAAATAAAACCAACTTTAATCTGAATTTTATCACTCTAAATGTAATCTATCTGATTATTTATTTATGTACTTCACTCACTCATATTTTATTTTAATAAAAGGGAAAACACAAGATTATGTTAAAGGAAAAAGTAAAGATTTCCCTCTTATTTTATTCCTTAAAACCAAAGGACTCCAAAACACACAACAAAACAAGGCTCTTCCTCTTTACATAGGCCACCCTTATTTTATTCCACCATTACATGCCTTACAAAACTACTACTTAGAACAAGCGTGCAAAGTCCAGGAACGGCGATAAGGGGTTATTACTTCCCCTCCTCTCATCAAATCCACGCCGACTCTGTCCAGACACGAAGTAAGATTCTTGCGGGTTGTTGTTGAATACCTCATCCACCAACCTTGACTCCACCCCAAACGCCAGCTCCTTGGCCTGGCGATCCCATTGTCTCACATTGTTGGTTTTCCCAGCCACGAAGATCCTCTTGTTGTCTTGGCCGTTGTAGAGTCCGAACCCGAGCAATCCTAGGTCCTCGTTTTGGGAGGCAACGAATGTGACTGGATGGCCTGCTGGGACTACAAATAGGTCACCGGTTGATAACTGGGCTCTCACTCTCTTGTATTGTCCACTTCTCCTTTCAACTTCTTGTTCTTCTTGTTCTTCTTCCTCTCGGGAGGACCAGTGTGAGCTCTGCCTAGAAAGGTGAGGGCAGACCATTTCGACGTGGCCGTTTCCTTCG
->URS0001836490 rRNA from 1 species 
-TGCGTAGGCGGATTTTTAAGTCAGTGGTGAAAGCCCGGAGCTCAACTTCGGAACTGCCATTGATACTATTAATCTTGAATACAGTTGAGGTGGGCGGAATGTGTAGTGTAGCGGTGAAATGCTTAGATATTACACAGAACACCGATTGCGAAGGCAGCTCGCTAAACTGTTATTGACGCTAAGGCACGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCC
->URS000010477A piRNA from 1 species 
-GAATATCCCTTTTGAGCTTGCTTG
->URS000188E1BA rRNA from 1 species 
-ATACGTAGGGTGCGAGCGTTGTCCGGAATTACTGGGCGTAAAGAGCTCGTAGGTGGTTTGTCGCGTCGTCTGTGAAATTCCGGGGCTTAACTCCGGGCGTGCAGGCGATACGGGCATAACTTGAGTACTGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCAGTAACTGACGCTGAGGAGCGAAAGCATGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCATGCCGTAAACGGTGGGCGCTAGGTGTAGGGGTCTTCCACGACTTCTGTGCCGTAGCTAACGCATTAAGCGCCCCGCCTGGGGAGTACGGCCGCAAGGCTGAAACTCAAATGAATTGGCGGGG
->URS00023A7F2B lncRNA from 1 species 
-CCGGCTATACTAGTTAGAAATTTTCCAACAGTATAGTCGCACGGATATACAAAATTGCTTTTCTCATCCAACGAAGTAGTTTTTCATTCTTATTTTTTTCGTAATGGGGCGGGTCAGGGAACTAATTCTGCAATGAAGGCTGGTATGGGCCAATGGCGGATTGAAGACCGGCATATTCTGAATATGGGCACCAATATACCGGTCGACTAGTTCTCCAAGCCAGTGGCAGTGGTTGCAGTTGATTTCCCCCATTATCACCTATTGGACAACCTTTGCCTTTTCTGTGTCTTGGTGTTTCACCATTTTGGCCAACCATAGTCTCCAGTACCTCGGCCATACTTAATTCCAGTCACCTTAAATGTAACCGAAAATACTTGCTCGAACTCATTCATTTTGGCCCGCCCTAGTTGACTCCCATTTATTTGTCTGCTATTCTAGATCTAGTCATTATCAATCACCATAATAAAGCTCCACTCTTGTAGTTTCAGTTTCACCTGTGCCTTTGATTATTTAGAACAATTTAGACTTTAATGATATGGTCACGGTTACAGCACAAAAGACAAATACCAAAAGCGGCCCTCGTGAAGAAGGGTATGGTCATTGGTCACCCTCAGTTTCACCTGTGCCTTCTCATCACTTTCATTCTCGCCTCCTCATCACTCTCTGTCGTCTGTGGTGCTCAGGAGCACCACCACCACAACGGCATTATCAGCCATGGAGCTCTCTCCGACACCGAAGCCCTCTACATCAAGCAGCGCCAGCTTCTCTACTACGGGGACGAGTTCGGCGACCGAGGCGACCTAGTCACGGTCGACCACCATCTCTGGTTTTTGAGAACCAGAGAATCAGAAATGCTTACATGGCTTTACAAGCTTGGAAGCAAGCCATTCTCTCCGACCCGCTTAATCTCACGGGTAATTGGGTCGGATCTAATGTCTGCAACTGTATTCAATTTAATCAACTGTAGGATTCATTTACAAGGCGAGTGGAAGGAGTCATCAATTTTGAATTAACAAGTTTCTACTTTAACGTATAACAACTATGTTCATATTTATTGGCTGGATAACTTGTTATATTCAGCCAATTACTTGGATAACGTATGCACTTAAGGTGCAAGTGCTTTGACATTTGTGCCACATAGAATTACATTCCTTTTTAAATATTTTATGATATAATTTTTTTTTTATTTTTAAAATTTTGAAATCATTTTTTGGTCCAATGTTACCCCTTATGACTTGAATTGGGTAATAGTCATTTATGTCATATTGCCTACTACCTATTGCATAGGTATATATATATATATATATTTTTTTTTTTTCATATTTTCGACAATGTGTCATAGTATTTTATGTACCTTTTTTTAATAGGTAACATATAATTTTATTTTGTCTATTTTTGTATCTGACTTATGGGTAGTCTTCTAATTTATGTTCCTAACTTATAGATAACACGATTTATCACTAAATATTTTTCGTTGCTAATAATAACACTATTTACTTGTATGTCATGTACATAATTTAATATGGGTGCTTGTCTGATCGATTGGTATAATATGTGGGTCTTTACTTTTTATTAATTAAATCGTATTTTATCCATATATTAGGAATATTATCAAAGAAAGAATTTAAATTTTAAATTATGAAATTCAATTACAAGGAAATAATGCATTAAATTTAGATTTTCAATGTGGTTTCCTTATTTGCCTCAAAGGGTAAAATTGACACAACAAAAAAAAGTAATAAATGTCAAAGGACTTACGTCTAAAACCAAAAACGCGAGCACTAAACCCAATGATAGCTAATCGTTTTGGGCCTAGATCTAAGAAGCCCTTTTATTTATTATCTAACATCGTTGCATGCCATTGATAGTGTGCCTATGGATGAGGAAGAGAAAGTTGTGCTTGACTGATGATTGACGGAAACTTTCGCAAGTAAATCCTCGATGCTACTGGTTGAAGGCCCTTTGATGTTAAAGTTAGCTTAAGGGGATGAGCGCAAGCTATCGACAATGCAAGGGCATAAGTGTCAAGTAGCAAGTCTTACCCTGTATCTAGGGTAAGGAGTTATATATATAGGGAATTCTGGGTTTTTTTGGGTGCTTAGTTTCGATGTGGGACTCGTGGGAGTGCCTTCCAAGGCTAACACGCGTCCCAGCAAATATCCTAGCGATGAACTCAAGAACATCCTGCAAGATGCCTTCTAAGGCGTAGAATTTGGCAAGGCATGCCGAACACACTTACCGGTCGTGGGCCGATCAGTGAACAATTGGCGAATGGAGCTAGAAGCGTCTGCCGTTTGTAGGATTAGACCTACCAGGATGGGTTACAGGGCCATGTTGTGCGTAGAATCGGTCGTGGGTGCCGAAAAGACCTACCGATTAGTACTACTGGGCTTGCCAGGGCGGGCCATGGAGCCTTCCTTCACGTGTCATGGCATGAGATGCGGGTCAGGTATGATACAAACAAACTTAAATTAATTAAACCCATCATGCAATGCATTCCCTTTCAATTTTTTGTGATAAACTCATAGATAATTGACTAAATAAACATCATCCAAAGTTTCAATAAAAATTACCAAGTTTTTTTTACAATTTCCGTAGTTTTTATTCAATTTTTATCGATATCGATAATATCCCGATATTTCCATCAAAATTTCCGTGTTTTTGAACTATCGATATTTTTAATACCATCAATATTTTATACCTTGGCTGTAGGCATTGATTATCAAACTAATTATCAGGGGACCAGTTGTTGGATGACACTTGGGCCAGATTAGAAGTGCATTAAATGTTTCCTTTAGTAATTCTTGGAAACCTGTGCAAGCTAGATTGCTTATAGAGGCGATCTGTGGTGGATTTTCCAGTTGTTTTTTATTTTCTTATGCTTGATTTAATCAAGAAGTGTGAAGGAGTTATTATCTAACATCGTTGCATGCCATTGACTATGGATGAGGAAGATAAAGTTGTGCTTGACTGATGATTGACGGAAACTTTCGCAAGTAATCCTCTCTAGCATTGCTCGTGCCGGAAGTGTAATTGAGGAGCTGTATGGGTTTGGTGTTGTGTGATGAGTATATTAAGGCGTATCAAGGGTATTTTTGGTAGTTAAATAGGATGTACTTAGTTAATTTTATATTTTAATTTAAATATTTGGGTGTACTTAGATCATAAGGTGTACTCAGTTAATTTTAGAATTCGTTTAACCACACTATATTATTATTAATAGTTTTCTATCAAAACAAACCCTTAAGGTCCTTAACTATTGGCTTGCAGCCACATATAATTACTGTGGTGACCTTCTCGAATCATCAATTTTTATTCATTTAAGTTGTTGATCAACTGCTGCAGGCAAGTTATTCTCCTGAACTCGAGTCCCATCAAGAGCGGGTCAAGGGGGTGAGTAATTGTCTCAATTCCACACGTAAACAAACAAAGGCTCACAAAACTCTCCAAAATATACGCATTAATTCTTTGCTTCTTTTCCCTTTATAAGAAGAAGAAAGCCGTCTAATTCATCATCACCAACACAAGCAAACTCAACATCAACAATGTCGACAAAGTCTAGCATTACCGTCCTTGCCTTTGCCTTTTGTTTCTTGTCCCTCCTCAGTTTCGCTTACTCCAACACCACCGACGACAAAATCTCTACCTCACCGGCCTGGTCTACTGTGACAACTGCCAATTGAAGTCTATGACCGAGATGAGTAAGATGATAAGATTTGAATATGAGATTTATGCATGCATGCATGCACATTGCCCATTGATCAGGTGCACATCTTTTTATCTTTTACTTTACTAATTCTTAATTAAGATTCAATTTAGGACCTATTTAAAGAGAAGAAAAATACGATTTAAAATATATCTTATAACCTAATAATCTCCTAATCAAAATATTAAACTTTTAAAATGTCACATATCAATTTAGCCCTTAATTATACTAAGCTTAAATTCCATGGTCCATACTAGTTTGATTTTTATTTTTTATTTTGGTGTGAAAATTTGGTATTTTCTTTAAAATAATGTGCTTGATAGCGTGAAAGTAGCAAATAAATAATGATGTGTTCAAATTGGATTTGAACACACATCACAACCCATATCATCATTAAGGCCCTAAAAATTAAATCATTATGTGCTTGGTTAATACGTTAAGTAGTTTATGAAGTGATTAAGATCAAAGAGGATCCATGACTTGTAATGGATCACTTGTTCATTTACTTAAAAATAAATAAATAAATAAATAAAAGCAAAGGACCCACTAGTGTAGTGGTTTGGAGTATTTACTCCCTTAGGTAAGGTCCTGGGTTCGAGTCCTAGCATCCGTGTTGTGTGTGTGAGTTTAATATGCTATCGCCCCTTTCAATAGGAAAGGACCTCAAAAAAAAAAAAAATAAATAAATAAATAAACTCGCAATACCGACTCCATTCGTAATTCCATCAATTACGCGACCAAAACTTCGTCGCTCAAAGTCTTGCGCGACGAAAAACAATTCGTAGCGCAAAGTCACTTCGCGCGACAAACTTTTGCGCGACGACAATACATCGTCGCTCAAAGTCTTGCGCGACCAAATTTTGCTCGACGAAAAAAATTCGTCGCGCAAAGTCACTTCGCGAGACAAACTTTTGCGCGACAACAATACATCGTCGCTCAAAGTGACTTTGCGCGACGAAACAATGAACTTCGTCGCGCAAAGTCCTTATAAAAATAAAATATATATATTTTAAAATCTTTGCATGACGTAATCCAAATATTTCGTCGCCTAAACTAATTTATTTTTGTTTTTTATTTTGTATGCATAACACTTAAGAAATTAAACAGTATATATATTTATTAAGTAGCTTTAAATTTATTATTTTAGATCAGATCGGATTTTTGTTAGAAAAATATATTATTGTTGTTCAGATTGGGTTTTTGTTAGAAAATATATATTTTAAATTGACGATCGAATTAGTTCATTGTATTCATATATGGTCAAGGAGTGTAGCTATAAAAAGCATCAAAATTGGAGTTAAAATAACCGTTAAATCGTGATTTTTCATTATAACCGTCGAAAAGTTTTGTCCCATTACTTGATCTCTGAATGTTTATTTTTTCTGATTTTTGGCGTATATGATCTCGAAGTATAAACAAACAAGTTTGACGGTTGGATCGTTGAAACTAGTTTTGGTGAATGCATATGCCATCAAAACAATATATTCACTAACAGTTAAGAGTTTATTTATACGTTCGTTAAATATAACATAAGATTTTGTGGTATCCACTAGTGTAAATATTTTAAATTGAAGATCAAATTCAGTCGTTGTATTCACATAGGGTCAAGGAGTGTAGCTGTAAAAAATCATCAAAATCGGAGTTAAAATAACCGTTAAATCGTGATTTTTCATTATAACCGTCGAAAAGTTTTGTCCCATTACTTGATCTCTGAATGTTTATTTTTTCCGATTTTTGGCGTATATGATCTCGAAGTATAAACAAACAAGTTTGACGATTGGATCATTGAAACTAGTTTTGGTGAATGCATATGCCATCAAAACAATATATTCACTAACAATTAAGAGGTTATTTATACGTTCGTTAGATATAACATAAGATTTTGTGGTATCCACTAGTGTAAATATTTTAAATTGAAGATCAAATTCAATCATTGTATTCATATATGGTCAAGGAGTGTAGCTGTAAAAAAAATCATCAAAATCGGAGTTAAAATAACCGTTAAATCGTAATTTTTCATTTATAACCATCGAAAAGTTTTGTCTCGTTACTAGATCTCTGAATGTTTGTTTTTTGCGATTTTTGGGGTATACGATCTTGAAGTATATACAAATAAGTCTGACGGTTGGATCGTTGAATGGTGTGTGTATATATATTTATTTATTAAGTAGCTTTAAATTTATTTATTTTGTACGTATAACACTTAAGAAATTGAATAGTATATATATTTATTAAGCAGCTTTAACCTTATTTATATTTTAAATTGTAAAATAAAATAATTTTATTTTTATTATTCCTAACAATTATTTTTATAAATATTGTGTTACGAACCAATTTTTCGTCTCTCAAAAGTTTGCGCAACCAACAGTTTGTCGCGCAAAACTCTAAAAATTTGGACGGGTACCAAAAATGGGACGCGGGATTTTTAAAAAAAATAAAAAAAATTTAGACTTTGTGCGACCAATATTTTTTGTCGCTCAAAACTTTGCGCGACCAATATATATTTTTCGTCTCTCAAAAATTTGGGCAGGTACCAAAAATGGGAAGCGGGAATTTTTTTAGACTTTGCGCGACTAGTATGTATTTTTCGTCGTGCAAAAATTTAAAAATTTTGGCAGGTACCAAAAATGGGACGCGGGGATTTTTATTTTTTTAAATAATTTTTTTAGACTTTGCGCGACCAATATTCCTATATTCGTCGCGCAAAAATTTAAAAATTTTGGCGGGTACCGAAAATGGGACGCGGGGATTTTTATTTTTTTAAATAATTTTTTTAGACTTTGCGCGACCAATATTCCTATATTCGTCGCGCAAAAATTTAAAAATTTTGGCGGGTACCGAAAATGGGACGCGGGGATTTTTATTTTTTTAAATAATTTTTTTAGACTTTGCGCGACCAATATTCCTATATTCGTCGCGCAAAAAATTAAAAATTTTGGCTGGTACCAAAAATGGGACGCGGGGATTTTTATTTTTTTAAATAATTTTTTTAGACTTTGCGCGACCAATATTCCTATATTCGTCGCGCAAAAATTTAAAAATTTTGGCGGGTACCAAAAATGGGACGCGGGGATTTTTATTTTTTTAAAATATTTTTTTTAGACTTTGCGCGACCAATATTCCTATATTCGTCGCGCAAAAATTTAAAAATTTTGGGGGGTACCAAAAATGGGACGCGGGGATTTTTATTTTTTTAAAATAATTTTTTTAGACTTTGCGCGACCAATATTCCTATATTCGTCGCGCAAAAATTTAAAAATTTTGGCGGGTACCAAAAATGGGACGCGGGGATTTTTATTTTTTTTAAATAATTTTTTTAGACTTTGCGCGACCAATATTCTTATATTCGTCGCGCAAAACTTTGCGCGACCAATATGTTTCGTCGGGCAAAAGTTTGCGCGATCAATATTCCAATATTTTTCGTCGCACAAACCTTTGCGCGACCAACAATATTTTTCGTCGCGCAAAGTGATACGGTTTTTAAAACCGAAATAACTCATCCACCATTTTCTCAATGCCTTTCTCTACTCTTACCTCTCCTTTCTCTTTCCCTCTCCCCAAATCCCACCATTTCTCTCACTTACTCCTCTCACTTAATCTCTCATCTCTCTCTCACTCACTCTCTCATCTCTCTCACTCACTCTCTCATCTCTCTATCACTATCTTCTCTAATTCTCTCACACTCACTTCTCCCTCTCATTCTCATTCACTCTCAATCTTGCCAAAAGGTATATTCTCTCCAAATTTTAAATTTTTTTCATTAATATGTGTTTTTGGAGTTAATTTTGAGTTTGTGTGGGTTTTAGGGTTGAGTAAAGGGGAGGGATTGGAGTTTGGGTTGGATTTGTGGTATAACAATTTTAGGGGAGATTATGCCTTCTTTTTTTTTTTTTTTGTGGTTATTTGACCATATTTATTTTTTTTGTAGGGAATCATCGAGACTTTGACGGCTAAAGTTGAGGATTAGGAAGCTATCAAAACATCTCCTCTGCCACTACCACCACAATACGCTTGTATTAGGGTTTTATTATTGTACTTTGTTAATTTATGTGAACATTTTGAATATTATATATATATATATATTTATTGGATAATTTAATCACTATTTTTCATATGTAATTTTATTTTGAATATGTCAATTTAAATTAAAGTAATTAAAAAAATCATACAATTAAATTAAATTTAAAAAGTAAAAATTAATATCAATTTAAATTAAAGTAATTTTAAAAAGAAATCATACAATTAAATTAAATTTAAAACGTAAAAATTTGAAAAAATTCATATAAATAAATTCATATTAAAGAAATAATAAAACAAAAAGTCAAAAATCTTGCGCGACAAAATATTTCGTAGCGCAAACTATTAAATTAGTTTATTTTAAATTAAAAACATTTAAAACAAAAAATATTTCGTCGCGCAAAACTCAAAAAATTTGGGCAGGTACCAAAAATTGGACGTGGGAATTTTTTAGTTTTTTAAAATTTTTTTTAGACTTTGCGCGACCAATGTTTTTCGTCGCGCAAAACTTTGAGCGACCAATATATTTCGTCGCGCAAATCTTTGCGCGACTAATGTATTTCGTCGTGCACAACTTTGCGCTACCAATATTTTTCGTCGTGCAAAGTCACTTTGCGCGACCAATCTTTTTCGTCGCGCAAAGTCGCTTTGTGCGACCAATATTTTTTCGTCGCGCAAAGTCACTTTGCGTGACCAATGAAAAAATTCGTCGCGCAAAGTCTTTCTTCACGATCTTTGCGCGACGGATTCTGCGCGACGAAGTTTCTGTCTCGCTGAAATTTGTGCGACTACAATGTATTTTGCGCGACGAAATTCTCTTCGTCGCGCAAAGTGTAAAATGTAGTAGTGGTACCAGTTGTGCTTATTTACTTTTTACCATGGCTCTCACAAATCAAGAGACCTCTGCTTAGCTTTTCTTTTTATTTTGGCCATTTGCTCCTCTCAAGCATCATCTCACTAAATTTATGATGAGACTGGATGGCTCAATTTGGGCCAGTTTTTTTTATAAGGATGCTGAGGAGAAGGAGAGGCGATTCATGATAGTCAAGGCCAACTTGGAGTTCATTAAGGCTTTTAACAAACACATGAGCCAGAACTACTTCACACTAAGCTTAAATGAATTTGCAGACCTAACCAATGAGGAGTTTCGGGAAATTCGTAATGGTTACACGAAACGATCCTCCAAATCGATCATGTCCAATTCCACGAAAGCTACATGTTTTAGATATTGAAATGTCACTGATGTGCCACCTTCAGTGGATTGGAGAGAAAAGGGTGCAGTGACACCTATCAAGGACCCAGGCAAATGTGGTAAGTATTAAACAAGTTGTTAAATGATGACGCATTCACTGTTTCACAACCTAACATGTTATTGAATGATGAGGCATGTTATTTCAATTTTATAGGGTGTTGTTGGGCATTCTCAGCAGTGGCAGCTACAAAAGGGGTTAACATGCAAGCTCAAAGCCAGAAACTTAATCTCACTATCAGAGCAAGAGCTTGTGGATTATGACACTACAGGTCAAGATCATGGCTGTGAAGGTGGTCTAATGGATGACGCTTTTCAATTCATCCACGCAACAAAGGCTGACAACTGAAGCTAATCACTTCTACCAGGGTTACAACACTCAGAAGGCTGCATCCCAAACAGTGTCCATAAATGGGTACGAGGATGTGCCTAAAAACAACCAAAATGCTATGTTGCAAGCCGTCGCTAACCAACCAATTTCTTTTGGAATTCAGACTATGATCTGAATTATAACTTGCCTTCTACAAATACTACTGAATGAGTAAAGGTTTCAGAGAGATTTTCAGAATGAGAGAGAGCTCGAGGAAAGAGCAAAAAGATGAATTCTATTCTTCTTCTCACGCACACACTGTGCACTAATAACAGTTGGAACAGGAAATTCCCAAATTACATCATTCAAATCTAGCCATCCATTCTTCTATTCTAAGATTACATCTTAGCTGTCCACTTGGATTGTAATCCAAGGGCTCACATTTAAATCTGTAAATTTGAACTAAATACAACATCATATCAGCAAAAACAGTTATATTTCAACACTCCCTTCTAAGTGTTTAGCTGAGATTACTCCAAGCTTTCTTCTCAGGTATTCAAACCAATCTCTTGCTAGAGCCTTAATAAAGATGTCTGCAGTCTGCTCTTCAATTTTGCAACATAGTAAATCAATCTCTCCATTTTGCAAAGCATCTCGGATGAAGTGAAACCTCCTGTTTATATGCCTTGTCTTATGATGATGCACATGATTCTTGGTTATGGCAATAGCAGAGGTATTATCACATAGAATTGTAGTAGCACCCACATGTTCTTCACCAATGTCTGAGAGAATGAAGCGCAACCAGATTGCTTGTGCAGTAGCTTCTGCTGCACTAACATACTCTACTTCTACTGTAGACAGAGCTACACTACTTTGCTTGACTGAAGCCTAGGAAAACATACCTGATCCAAGATTAAATGCAAATCCAGAGGTGCTTCTCATGTCATCCTCGCTCCCCGACCAATCACTGTCACAGTAGCCAATGAGCCTTGCTTCTTTGCCTTTCTCATATGCTATGCCACAATCAAATGTGCCTTGAATGTACCTCAATACCCTTTTGGCAGTTCCCATATGTTTTCTAGTAGGTCCATGCATAAATCTAGCCAAAAGACTTGCTGCAACCATGATGTCTGGCCTTGTTGCAGTCAAGTACAACAGATTTCCAACTATCTGCCTATAAACCCCTTCATCAGCTTGTTCACTTCCATCTTCCTTGGATAGCTTTTCATTCATTGCAAGAGGAGTAGCCACTGCTTTATAGTCCTTGAAGCCAAATTTGTCTAGCAATGTCTTAGCATATTTCTTCTGGTGCAAGAAAATGTAAGACTCAGTTTGTATCACTCCTAACCCCAAGAAATGGTGAAGCAAACCAAGATCAGTCATTTCATACTGCATCACCATTTCAGTTTTGAACTCCATGATCAAGGCTTTTGAGCTTCCAGTGTAGATAATATCATCTACATATAAAGAAACAATAATAATACTACTTTCTGCAGCCTTTACATATACTGTTGCCTCACTAGGACTTCTCTGGAAACTTGCCTTGATGAAGTAAGAATTGATTTCTTCATACCAAGCTCTTGGAGCTTGTTTAAGTCCATATAATGCCTTCTTGAGTCTATACACTCTATCCTCTTTGTTCTTAATCATAAAACCAGGAGGTTGATCCACATACACCTCTTCATGCAATACTCCATTCAAGAATGCAGACTTCACATCTAACTGAAATAGTTTCCACCCCTTTTGTGCAGGCAATGCCACCAATGTTCTAATGGTATCCAGCCTAGCAACAGGTGCAAATGTTTCATTGAAATCTATCCCTGGCTTTTGAGAATAGCCCTTTGCCACTAGCTGAGCCTTGTCTTTTTGAACTGTACCATCTAAATTCAGCTTGGTTTTATAAATCCATTTGACACCAATTACTGGTTTATCAGTTAGTCTATCAACCAACTCCCAAGTTTTGTTCTTCTCTATAATTTCTATCTCATTCTCCATTGCTTTCTGCCATGCTTCATCCTTAACAGCCTCTTCAAAGGTCTCAGGCTTGATAATACACAAGTTACATCTTGCATACACTTCTGCAATACTCTTGTATTTCAGAGGTGTGTGATCAACATCCAGTGATCCTGAGTCAGGATCAACATGCCCCTCTTCTGAAATCTCTTCTTGACTCAGGCTAGAATCATTAGATTCCTCTTCTCTCTCAGTGAGTGTCTCATTAAGAGGTATTGAGATATCACATTCCTTTTGTGCATTTCAATCCCAAATAGATGCCTCATTGAATATCACATCCCTGGAAATAATCATTTTTTTCAGATGCAATGTTATATAGTCTGAAGCCTTTTCACAGTTGCCATACCCTTCTGCCTTTGTTGATTTGGAACATGTGCATAGCACAAAGAACCAAACACTCTTAAATGCTTAACTCCTAGCTTTCTACCACTATAAGCTTCAAATGGAGTTTTCTTGTCTAAGGCCTTAGTTGGACATCTATTCTGGACATACACTGCAGTGTTTACTGCCTTAGCCCAAAATTCTAGAGGCATCTTCTTCTCAATCATCATGCATTTAGCCATCTCCATAATTGTTCTGTTCTTTTGTTCTGCTATTCCGTTTTGCTATGGTGAATATGTCACAGTTAGCTGCCTTTCCATTCCCATGTCTTCACAAAATTTGTTGAATTCATTGGAAGTATATTCGCCCCCCTGTCACATCTTATTTTCTTCAATTTATATCCACTTTGCAGCTCAACAGTGGCTTTAAATTTCTTAAAGACATTAAGGACTTTTGATTTGTATCTCAAGAAATAGATCCAACACATACGAGTACAATCGTCTATGAAGGTAAGAAAATATCTATTTCCAGCTTTGGTAATAGTCTGCATTGGTCCACATACATTTGTGTGTACCAACTCGAGTGGGATTCTGGCAATCCAAGTACCATTCCCTGATCTTGCAGCAGCTTCAAACTGGTGAAGTTTAAATGCCCCATTCTTCTATGCCAAACTAAAGTTGATGACTCTACATTTGCTCTTAATGCAACCTGTAAAGTTGTGTGAAGCTTCAAAGGAAAACTTATGTCGCCTTTCAGTTGCACCTTAGCAACTAGATTTGATAAAGAACAATCATCATAAATTTCAACCTTATTAGCTCCAAAAATCAGAACATATCCATGCTTCATCATTTGCCCTACACTGAGCAAATTCTTCTTGAGACCAGCAACTAACAGCACTCCTTTGACATACCTTCTTCCCATCTTAGTGTCAACAACAAGATTTAATTTCCTTTTCCAACAACATTAACCAATTGTCCTGTCCCCATTGCAACTTTTGCAATTATATTCCTATCAACATCAACTAATACATCTTCTCTCCCAGTCATATGGTTGCTAGATCCGCTATCCAAATACCATATTGTTCACCCGTTTTGTGTTTGTTCCTGTGATGGTAGGGCAAAATTCCCCATTGCCTTGAAAATCATTGACTGGTCAACAAGTCAACTTTCTTTAGTGTGCGAGCGTGCCACTACTAGCAATGAGAAATCCTAGAAGACTTTAAAAATAGATAACTTGCACCCCAAGTTACTGATTTCTAATCAAACAGTTGTGAATTTGGGTGAGGAATATCTCCCAAGTAAGTTCTTTTCTTGCCTCAGACTGGTGAGTACTTCATAATTTTTCACAGTATAAAACTGGTAGTTCTGGCCAGAATAAATGATGAGAAAATGAACTGTTTTGAGGTAGAATTGCCTTTTACAAAACTCAAAAGGGAAAAGCCAACTCTAGAAAGACAAAAAGAAGGCTGGACTTCCATTTCTGCATGGATAGATGCTTCTGATCCAGGCTGGACTAGACTATCAGCAACTTCAACTGTCAAGTTTCAGCTGTAAATCGATACCAACGTTCGAGTTTGGCAGAGCTTTAATCTATTTCAAGCCCTGGAAGGCTTTTTGAACGGACAGAATTACGGCCTATTCAGTCTGAAGGGTGCAGAAGTGGCTGGACTCAAGGATTATTGAGCTGGAACTGCATTGTGATACTTGTTCTACTTGATCAGGGTTCTCCATAAATTTGTTGAGGTTTTCATTTTTGTGAAAACCCAAGCTCTGCTTGTTTTGGCTTTTGCTGAACCAAATTTGTAACAAGAGAAATCTCATTTTAAATGACTTTTCTCTAAGTCTGAAATTGATTTGTAGTTGGCTTCTTTCTTCTTGAAATTGATTTGTAGTTGGCTTCTTTCTTCTGGCTCAATGAGCTTTTGGTTGCTTCAGTTTGTTTGAAGGTTCTTTGAGATCAAGTGATCATTTTGAGTTTTTGTCTTTTGACTGATTTTTTGGTTGTTTGATTGATTGTCTGATCTTTTGCTCTGTTCACCCTCTCCTATATTTATAAGAGATGCTTTGTAGTGGTGCTTCTAATTCTTTTAATAATGGGCGGAAAAATTTCTCAAAAGATCTTTCATTTTTAAATGCAAAGAAAAAGGGTTTTTATCAATTCTGGCAGATAAGCTTTCTATAGTCAGTTCCTAAGGCAGTCACTTCCCTGTATTTCTTGAAAAAGAAACCTAACCCTTCTTCCAATTTAACTGCTCTTTGTAAGAGTTCAAACTGTGATGGTTTAGTTTTGATCTTCCAGATGAACAACTCCCTGCTTCCCACTTATCTTTTTAGAAAATATGGCCTGCTTATCCCTTGGAAATGATATCTAACGAATTTTTTTGGATATAGAAAAGGATTCTGATCTTTTAGCCCCAAAGTTTCAGGGAAGTCTCTCTGCTAATGACCTGCTTTCATTAATTACCAATCTACTCTCTTGTGACAGTTGAAATTGTTGACTTTTTAAAGTCAGGTATTCACGTGGGCTCTGAGAATAGACTTTCCAAAAATCAGCTGATCTTATACTCCGTGTTTTGAGATAAATGGTGAGTACTTAGATGCTGGGCCCAATCCAATTCTTTTTTATCTACTTTAGTGGTCAATTGCCACTTAATTTGGCCTTCTTTTTTTTTTTTTACAACTTTGCCATTTCGTAAAAGACGTGGGCCTTTCTTCTTTTTTAATTATGCCAAGCCCAGTTTGAGTTGAGCTATGGGCTGATTTCTTTCTTTTCTTCCTTTTCGAAGCCCAAGTTTATTGTCGTGGTTTCGATAGATCACGGGCTGGGCTTTTTTGAATTTTGGGCCCTCGATTCCTGTTTATTTTGCAAAGCCCAGACTGCTTGGGCCCTGTGGCTTTATTCTGGGCTCTATAGTGTTGGGCTAGGTGCACAGGATTTTGGCCCCAACACATACATCATCACATCCTTTTACACTAGCAGAACCTTTATTACTAGCATAAAACATGGTTGGTGTGGATTCGGTCTGAGTAGCATAGTTGAGCTGTTGTGCTGGTTTCTTGCTATAGCAATCTTTTGCAATATGACCAAATTTGTCACAGTTGTAACATTTTGGTTTTCCCTTAAACCGAAAATCACCAAAATGTAGTTCGCCACAATGTTTGCAGGGGTTTCTGGCTCCATCAGTTGATATATTATCCCACTTTTTGCCTTTTGTCCTCCAATTCCTTTGATCCCTAAAACCACTTTGACTTCCACTGTAATTTTTTGATTGGGATTCACACAAAGACTAGCAAATGCTTTCTCAGTCTTATCTCCAAAGTGCCTATCTAGCCATAATTCAAAACTCTTCAAAGAGGTTACCACTTCTTGTACCTCAATTTCATCCAAATCCTTAGAATGCTCAATAACAGAACAGATTGAATCATAAGCTGATGGCAAACTGATTAGTAATTTTTGAACAATCCTTGCTCTAGCTAAATCCTTTCCATAGCTCCTCATTTGGTTTATCAGATCAAACGGTTTGGTAAGATAAGCAGAAAGGGACTCATCATCTCTGATTCTTGTATATTCAAATTCTCTACATAGACCTTGCAATTTAACACTTCTAACCTGTTTATCACCATGGAATTCCTTCATCAAGATATCCCAAGCTCCCTCAAAGGTTTCTTCATGAGAGAATCGAGGGAAGATCTCATCAGACGCTGCTCCTTGAATAAGACCCAGAGCTTTAGCATTCTTCATGAGTAGCTCAGTGAGAGTCATCTTCCAAGCACCACTCGATTCTTCCTTTTCTTTCTTCTTTGCATCAGATTCTCCAGCTCCCTTCGAATTTGAGCACTCTATTCCCTTCTCAACCAATTCCCAAAGCCCATGAGATTTGAAAATGGTTTTCATTCTTATGCTCCAATTTTCGTAGTTATCACCGCCAAAGATCGGCACTCTCAGCTCACCACCTCCATACCCTGCCATGTTAGACACAAATCGCGAAACCACTTTTCCAAATTTCAGCTAGTTTTCTTCACAGATTTAATCGCCCAAAGTTAAACAATAGAACCTGGCTCTGAGGCCATGTTAGAATTCAAACTATGATCTGAATTATAACTTGCATTCTACAAATGCTACTGAATGAGTAAAGGTTTCAGAGAGATTTTTAGAATGAGAGAGAGCTTGAGGAAGGAGCAAAAAGATGAATTCTATTCTTCTTCTCTCGCACACACTCTGCACTAATAACAGCTGGAACAGGAAATTCCCAAATTATATCATCCAAATCTAGCCATCCATTCTTCTATTCTAAGATTACATCTTAGCTGTCCACTTGGACTGTAATCCAAGCGCTCACATTTAAATCTGTAAATTTAAACTAAATACAACATCATATCAGCTAAAACACTTATATTTCAACATTTCGGTTGCCATTGACGCAAGTGGCTGTACATTCCAGTTTTATTCAAGTGGTGTGTTCACTGTGGTATAAACTTAGATCATGGTGTTACCGCAGTTGGATACGGGACTAGGACTAGTAGTGATGGGACTAAATACTGGCTGGTGAAGAATTTTTAGGGCACATGGTTGGGGGAGGATGGATATGTGACGATGCAAAGGGGCATTCCTGCCAAGGAAGGACTCTGTGGCATTGCTATGGAAGCTTCTTATCCAACCGCATGATTAATTAAAATGCATATATGTCATAATATAGTGTGGTGTATAAAATATGTATAATTGAATAATATAGAAAGACGCTAGCTATGAGCTGCTATCCTTCCACTTTGAAATCCATGCCTCAAAACATAGAAACAATTAACCCATGACGTGGATTTGCTCTTAAAATCTCACTCAATGAATTAGCAGCTATAGCTATGAGGTTGACATGTTTTCATTACCATTGCAAGGTTAAATCAAGTTAGATTAAGGGTGCATATTTTTGCTCACCATCATTCTTAATATTTGACATGTGTCTATGGGTATAACCATATAGTTCTATAAATATATAACTATGATTATGTCAATGAACACGTGTCAAGTGTTAAAATGGGTAGTGAGAGTACACATTTGGTTAAAGTGGTGAGTAAATATATTCCCTTAGAGTAATCACATGATCATGTCACTGATCCTACAAGGTAAAACTGTGAAACGACGTCATTACACTTGTTCGGAGGTGGCATGGATTGGAAACACGTAATTAACCATATATATAACATCAATTTACAACTTAATTATACTTATTCTTAAAGCCATTTCTGATCGGACATTTTTGGAGAAATTAATTTCTCAGGCAAGTAAATGGCAGCAGAAGAGGACCGGAAAATTTAGGTGCCAGTAGAAGAGAAAAACTCTCTCGCACGTACCTGGTTTATGGAAGTTTGCTGTAACAGGAGAGCTAGATAAAACTTAATTTGAAAAATTCTAGGATACGTAACTAGAGCTTACAAGGTGGTGTTGTTGACTGGCTACAACTTCAAATACAAACCGTTGAGCTAGCTTGCTGTGCGCAGTATATAAAGATTATTTAGGACTAGCTAGGCTCATAATTAATATATACATATATATATAATTACTTTATATTTTTAAAGAGGGGGAAGTACAATATTATGATGAAGAGATGAGTCTTTTTGCCAATTAAAATGCACCATTTATATATTCTGTATCCAGATTACCTTTTGCATGATCTTGCCATGAACATCCAAAAATGCACCAATCTAGTTAAAATTCAAAACAAATTTAAAGATTTTTACATCGTAGTTAAAGGAAATTCATTGTTCCTATAACTTGTGCTTCCTATACACACACAAATTCCATGAATCAATTGACAATGTGATATTAATATTACCATATAACATTTTCAACATTTTCATCTCGTCCTAGCATTCAAGTAAAGAAAAGAATACACGTATACTTGGATTGTTGATGTCTAACTTTGACTCAACGGATTAAGATCGTAAAAACGACACATTCACATCATGACACACACTCAAGTCAGGCTACGTCCATAATATACAATTAGTGAACTGAATTACATGAATCTACAAGTACGGGATATAAAAGCTACAAGCCCTACATGCTACAATATCTGTCCTATTTTTGGGTCAACTGTTCCTTATTCTCTTTGATAGTACAATCGAGTTTACATGTTAGGATCCTAACGGGGATATTAAATGCTGAAAAGGAAATAATCAATTCCCAATAAGCCCTTAAGATCGTCTAACCAAGATACAAGCCTCATATATATCTTAACAAATCTTTCTAGTTCTTAAAGGTTATAGCATCCATCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTCTATATATATATATATATATATATCCTCTCATATAAGTCCAAATTATCATGATATTTGTCTTTAAAGAATTAATTAACATACTTATCACCGCGCAGAAAATTAATTTATGTCTTCAAGATGTCTATAGAGCATTATTAAACTAATCCTAAAATAAATAAATATTTTTATTCTTAGTGCAATGTGGAAATATCTTTAAAGAATAGAATATTTCACCAATATAGAAGAGCGGCTATACTCAACAAATATAAATTTTCAATAGTCTAGCCGAGTGGCTGTACTCTATAAATATAAATTTTTTAACAGTACAACCGCATGGCTATACTCTTTAAATAGAAATTTCAAAATTATAGCCGTCCGGCTATACTAGTTAAATAGAATTTTTCCAACAGTATAGTCGCACGGATATACAAAATCGCTTTTCTCATTCAACGAAGTAGTTTTTCATTTTTATTTTTTCTGTAACGGGGCGGGTCAGGGAACCAGTTCCTTAATAAAGGCTGGTATGGGCCAATGGCGGATTGAAGACCGACATATTCTGAATATGGGCACCAATATACCGGTCGACTAGTTCTCCTAGCCAGTGGCAGTGGTTGCGGTTGATTTCCCCCATGATCACCTATTGGACAACCTTTGCCTTTTCTGTTCTTGGTGTTTCACCATTTTGGCCAACCATAGTCTCTAGTACCTCGGCCATACTTAATTCCAGTCACCTTAAATGTAACCCAAAATACTTGGTCGAACTCATTCATTTTTGCCCGCCTTAGGTGGCTTTTGGCAGCGCTTAATTTTTTTTAAAAGCAACTTTAATACAAATTTGGCATGAGTTGGGTGTTTGGTAAACCCAAAAAAACACGCTTATTTTAAAAACACCCATCATAAAAAGCAAAAACTCAACGTCAGGTATATGGAGCTTTCAAAAGCTGTTTAAAAAAAGAGCTGGTTTTCTTGTTAATGAAAGTTTCATTATCCCTATAGTACCCCTAAGTATTTCACAAAATGACAACGTTTGACCCTCTCACAAAATAGATCTCGCGACCTTCACACTTTCTGACCTCACTCTCAGACTGCTCTTCTCACTATTCTTCTTCTTCCTCCCCCTGCATCTCAAAACTCCATCTCAATCAAGGACTTTAATTGCCAACAACAATCAGCTACTTATCAGTGAGTTCATCTTCCCATTACATTTATGATTTTTGGGTTTATATATGTTATGAAATTAGGTTTTTCATTTGGTTCTATGCAATTGGGGGCTTTGTGTTCTTGAGGCTTTAAGGGGAAAATACGGGAGAGACAGAGAGAGAGTTTTGCTGCAAGTTTTGTACTGGGTTTGTCTCTCCTTGCTCTTTGACAAGGAGAGATTTCTCCCTAGCTTGGTTCAATTGGCCTTTGGGTCAGATACTTCTCTCTCTGTTTCTATTTCTCTGAAACATGTCTGTCCTGGATGCTTTTTTTCTATAGATTACACAACCATCATTGTTCATAGATTTACTCATTGTATAGTTTGGTACAGTTCCAAAATATCAAGAACAAAACCCGTTATGCTAATCTGGTTCTTTATATACATAAATATAAATATAAATAAATATATATATATATATATACAGTCCCCTTCTATTGAGAGATCTCTCAAATAATTTTATTTGAGGGACGCCCTTAGGGTACCCTACAATTTTCTTTCCAATGATCCAAACCATCTATTTTTTAGGTCTTCATTCATAAATCATCCTTACAAAAAATTAGATAAATCGGAAACCGTTTTGACATCCAATTGTATCTTACAAAATCAATGAACACGTTCCTTCAAGAAAGTACTAAAATTTCAATAACTCAAATGAGTGGTCAAATGATATCATATTCGAGTAATTTTTTTGTAGAGATGATCTTTGAATGAATATCTACAAAATAGACTGTTTGGATTAGTTAAATACAATTCGGAGTGGGGCCTATAAGGAGTGTCCCTCAAATACTTATTTGAGGGATCCCTCAATGGAAACTCTCTGTATATATATATATATATATATATATATATATATGATTGCAACCCAAGTCCCCAAGTCAGGTCCGTGTTGATTTTTCCATTGTCCTAACCTTGTTGTCTTCAAGCTCAAACATAATTCCTTTGGACTTTAGTTTTAGTTCTCTTTTAGTTAGAAGACAAGAAAAGAGTGAAGAAGCCATTAGCTCCAGATCTGGGGCTTCTGTTTTCTCAAGAATTTTTTTAAAAAAAAAAAAGATCCTATTATGTGAAACTGCTGTTCCATCTAAGTTGTCATCCATTATTGTGTTAGAAGATTTTTGGTAAACAAAGCTTTTATTTTTTAGTGGTCATAGTTTCAAGTTCTTCCTTATTATTATTTTTCAGTGTCGGTGGACTTTATTATTGTGTTAGAAGATTTTTGATTGGGTAATGGTTTGAAGTTCTTCCTTCTATTTATATTTTTTTGTGTTGGTGGGCTTTATCAAAAGTGATTGTAGCATGCTGGTCATTGTGGTGGGGAACTCATAAACTGACATATGGTTGAAATATAAAAATTTTGTAAATTGGTATGAAATTGCATTCTCAGTAAATTATGGGAATGCAATATCATCTTGCCTTAGAACATATGATAGAAACAAAACATTTTAACCACAACACAGACTTAAGAGATTCAATAAACTGTTCCCTAGTAAGCTGGAAATATTGGCTAAGACTTTATGTTATCTTTGTCTCCTCTTGGCAGAATAGGCTTGCTAGTTCCTCAAGTAATATATGTTAAAGATTAGGAAAATTATATAGTTCTTGTTCTTAGGTCAATTGTGAAGGTGATCAGTTTATTTTCATGTGTGGATTCTTTTCGTTCTTGGTTTTCTTTCATGAATCATTAGGAATACTCTATGCTTGGACTCTTTGTCCCTTGTTGAGAATGAGAAGTGGGTTTAAGGAAGTTTTGTTGGGAGCCATCATCATTTTTAAACATATAGCATATAGTGGATAATATAGATGAATATTCATACCTGTGGGAAAAGGAAAGTTTGTTATTTTTATGCTTTTAGTATAATGTATATCTTGGGACAATTATTTGCTATTATCTATTTCTCATACTCAACACATATTGCTTTAGTAAGGATGGGAAAGAATGTGAGAAGTTCATCAAAAGCTCCAGCGACATGGAATAACCATAATATATCCATATTCTGTGATTTGTGCATCAAGGAGATATGCCTAATTATCCATTCAACAAGCAAGTGAAGATAGTCATTGCTACAATGACACTTCATAATTATATAAGGAGGCATGCCCAACGTGATAGACATTTTGATGCTTCAAATGATATCTTAAGTGAAGAGATAGGTGAGGATGTTGATGTACAACAAGAAGTTCATAGTCTTAATGACAATGGAACACAAGAGATGGAAGCATTGAGAAATAGCATCGCTACAAGTTTCATGAATGCATCTAATTAGCTTCTTTTATATTGTAGTGATCCATTTTGGCATGTTAAAATTGAACAATTTTTGTATATTTGTTATGCTAACCCTCTCCGAAGCCCTCAAAACACATTGTTATTATTAATATAACAATATTTAGAACTACTTTTGTTACAATATTAATTTATAATTTATGGTAATATATGTGTGCTAATTGTAGATTACAAATTTTGATAAATTAAAAATGTGTAAATTAAAAAAGAAAACAAATTTATGTAGTGAAGTTTGTTTTCTTTTTTTTAAAGTAGAAAAAGAATGAAGAAAAAAAGAAACCGTTTCATCATCATGTCCTTTTCGTTCATTATACATACTAAAAGCACTTCTGATAAAAATTTACCGAACACTTCGACTACTCACAGCCTTTTTTCATATACAGTTTACCAAACGCCTAGCTGTTTTTTTTTCATAGCTGATTATTTTCGCAGCACAGCAGAAACAGTTTTTTTTTAAAGCACAACAATGCCAAACTAGCCCTTAGTTGACTCCCATTTATTTTTCTGCTATTCTAGATCTAGTCATTATCAATCACCATAATAAAGCTCCACTTCTTGTAGTTTCAGTTTCACCTGTGCCTTTGATTATTTAGAACAATTTAGACTTTAATGATATGGTCACGGTTACAGCACAAAAGACAAATACCAAAAGCGGCCCTCGTGAAGAAGGGTATGGTCATTGGTCACCCTCAGTTTCACTTGTGCCTTCTCATCACCTTCGCTCTCGCCTCCTCATCACTCTCTGTCGTCTGTGGTGCGCAGGAGCACCACCACCACAACAACATTATCAGCCATGGAGCTCTCTCCGACACCGAAGCCCTCTACATCAAGCAGCGCCAGCTCCTCTACTACGGGGACGAGTTCGGCGACCGAGACGAGCTAGTCACGGTCGACCCATCTCTGGTTTTCGAGAACCAGAGAATCAGAAATGCTTACATGGCTTTACAAGCTTGGAAGCAAGCCATTCTCTCCGACCCGCTTAATCTCACGGGTAATTGGGTCGGATCTAATGTCTGCAACTGTATTCAATTTAATCAACTGTAGGATTCATTTACAAGGCGAGTGGAAGGAGTCATCAATTTTGAATTAACAAGTTTCTACTGTAACGTATAACAACTATGTTCATATTTATTGGCTGGATAAGTTGTTATATTCAGC
->URS0000B8F910 rRNA from 1 species 
-GTGCCAGCCGCCGCGGTAATACGTAGGGGGCCAGCGTTGTCCGGAATCATTGGGCGTAAAGCGCGCGTAGGCGGCCAGACAAGTCCGGTGTGAAAGTCACAGGCTCAACCTGTGAATGCCGCTGGAAACTGTCTGGCTAGAGTCCGGAAGGGGCGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCTATGGCGAAGGCAGCTCGCTGGGACGGTACTGACGCTGAGGCGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCCTGTAGTCC
->URS0000C2AFAE pre_miRNA from 1 species 
-CAAGTACTCCCTCCGTCCAAAAATACTTGTCGCAGAAATGCATAAAAATGGATGTATCTAAAACTAAAATATGTCTAGATACATTCATTTTTTCCGACAAGTATTTCCGGACGGAGGGAGTACAAC
->URS00023A1339 lncRNA from 1 species 
-CAGCCTATAAACGGACGCAAGTTAATATCGGTACGGCCGACCATCGAATCACCGTCGAAACCAAATTCTACGGCGCAGGACCAGGTTTAAGAGAAGTAGTCATCATCGAACGAAACTCTTCAAAATTCACATTGCCATCACCATCGGCATCCACCGGCTTAATCATCGCCACACATCCATCAACCGAGCACTTAATTCCGAGCCTGTTCAACACCAAATTCAACTCCTCCGCCGAAATCAAGCCGTTCTTGTCCTGATCGTAGAGATCAAACGCCTCGCGGAGCTCGGCCTCGCCGGCGGCACCAGAGGAGGTCCGGC
->URS000118CADB rRNA from 1 species 
-CCTACGAGAGGCAGCAGTGAGGAATATTGGTCAATGGGCGCGAGCCTGAACCAGCCAAGTAGCGTGAAGGATGACTGCCCTACGGGTTGTAAACTTCTTTTATAAAGGAATAAAGTGAGGCACGTGTGCCTTTTTGTATGTACTTTATGAATAAGGATCGGCTAAATCCGTGCCAGCAGCCGCGGTAATACGGAGGATCCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGAGCGTAGATGGGGTGTTAAGTCAGTTGTGAAAGTTTGCGGCTCAACCGTAAAATTGCAATTGATACTGGCAGCCTTGAGTACAGTTGAGGTAGGCGGAATTCGTGGTGGAGCGGTGAAATGCTTAGATAACACGAAGAACGACGAGTGCGAAGGCAGCTTACTAAACTGCCACTGACATTGAGGCTCGAAAGTGTGGGTATCAAACAGGATTAGATACCCTTGTAGTA
->URS000006351C rRNA from 1 species 
-GCGGGGTAAAGGCCCACCAAGGCAACGATGGGTAGCCGGCCTGAGAGGGTGATCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATTTTGCGCAATGGACGAAAGTCTGACGCAGCAACACCGTGTGAGGGATGAAGCATTTCGGTGTGTAAACCTCTGTCGATGATGAATAATGTTTCGGGGAGTGGAAAGCCTCGGAATTGAAGGTAATCATGAAGGAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAATACAGGGGGTGCAAGCGTTGTTCGGAATCACTGGGCGTAAAGGGAGCGTAGGCGGAACTACAAGACAGAGGTTAAATCTCCGGGCTCAACCTGGAACTTGCCTTTGTGACTGTGGTTCTTGAGTATGGTAGAGGTTGGCGGAATTTCCGGTGTAGCGGTGGAATGCGTAGAGATCGGAAAGAACACCAGAGGCGAAGGCGGCCAACTGGACCAATACTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGAACACTAGATGTCGGGAGGGGTTCCTTCCGGTGTCGTCGCTAACGCAGTAAGTGTTCCGCCTGGGG
->URS0000ECDE64 rRNA from 1 species 
-GGGCCCGCACAAGCAGCGGAGCATGTTGTTTAATTCGACGCGACGCGAAGAACCTTACCAAGGCTTGACATGCACGGGAATGTCGTAGAAATATGGCAGCCCTTCGGGGCTCGTGCACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTGTCCCATGTTGCCAGCGTGAAAGACGGGGACTCATGGGATACTGCCGGTGACAAATCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGCCCCTTATGTCTTGGGCTACAAACGTGCTACATTGGCCGGTACAAAGGGCTGCAAACCTGCGAGGGTGAGCGAATCCCAAAAAGCCGGTCCCGGTTCGGATTGGAGGCTGAAACTCGCCTCCATGAAGGCGGAGTTGCTAGTAATCGCGGATCAGCAACGCCGCGGTGAATATGTTCCCGGGCCTT
->URS0000175B41 rRNA from 1 species 
-AGTCATATGCTTGTCTCAAAGATTAAGCCATGCATGTCTCAGTATAAGCAGTCAAATGGTGAAACTGCGAATGGCTCATTAAAGCAGTTATAGTTTATTTGATGGTTGCTGCTACATGGATAACTGTGGTAATTCTAGAGCTAATACATGCATCCAAGCCCGACTTTGCAGAAGGGTTGTGTTTATTAGATCCAGAACCAACCCAGGCTCCGCCTGGTCATGTGGTGATTCATGATAACTTGACGAATCGTGCGGCCTTGCCGACGATGCGTCATTCAAGTTTCTGACCTATCAGCTTCCGACGGTAGGGTATTGGCCTACCGTGGCAATGACGGGTAACGGAGAATTAGGGTTTGATTCCGGAGAGGGAGCCTGAGAAACGGCTACCACATCTAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCTGACACAGGGAGGTAGTGACAAGAAATAACAATACAGGGCATCCATGTCTTGTAATTGGAATGAACAGAATTTAAATCTCTTTATGAGTATCAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCGGTTAAAAAGCTCGTAGTTGGATTTCTGTTGAGGATGACCGGTCCGCCCTCTGGGTGAGTATCTGGCTCAGCCTTGACATCTTTCTGAAGAACGTATCTGCACTTGACTGTGTGGTGCGGAATTTGGGACATTTACCTTGAGGAAATTAGAGTGTTTCAAGCAAGCGCACGCTTTGAATACATTAGCATGGAATAATAAGATAGGACCTCAGTTCTATTTTGTTGGTTTCTAGAGCTGTGGTAATGGTTGATAGGGATAGTTGGGGGCATTCGTATTTAACTGTCAGAGGTGAAATTCTTGGATTTGTTAAAGACGGACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTGATCAAGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCCTAGTCTTAACCATAAACCATGCCAACTAGAGATTGGAGGTCGTTACTTGCATGACTCTTTCAGCACCTTATGAGAAATCAAAGTCTTTGGGTTCCGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTTACCAGGTCCAGACATAGTAAGGATTGACAGATTGAGAGCTCTTTCTTGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGTTAACGAACGAGACCTTAACCTGCTAAATAGTTACATGTAACCTCGGTTACATGGGCAACTTCTTAGAGGGACTTTGTGTGTCTAACGCAAGGAAGTTTGAGGCAATAACAGGTCTGTGATGCCCTAGATGTCCTGGGCTGCACGCGCGCTACACTGATGCGCTCATCAAGTTTTCGATCTTGCCCGAAATGGCTGGGTAATCTTTTTAAAATGCATCGTGATGGGGATAGATCATTGCAATTATTGATCTTCAACGAGGAATTCCTCGTAAGCGCGAGTCATCAGCTCGTGCTGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTCCTACCGATTGAGTGATCCGGTGAATAATTCGGACTGACGCAGTGCTCAGCTTCCGGACGTTGTGTTGGAAAGTTTCATGAACCTTATCACTTAGAGGAAGGAGAAGTCGTAACAAGGTTTCC
->URS0001B743B1 rRNA from 1 species 
-CCTGGTTGATTCTGCCAGTAGTCATACGCTCGTCTCAAAGATTAAGCCATGCACGTCTAAGTATAAATACTTTACTTTGAAACTGCGAATGGCTCATTATATCAGTTACAGTTTATTTAATAGTCCCTTACTATTTGGATAACCGTAGTAATTCTAGAGCTAATACATGCGTCAATACCCTTCTGGGGTAGTATTTATTAGATTGAAACCAACCCCTTCGGGGTGATGTGGTGATTCATAATAAGCTTGCGGATCGCATGGCTTTGCCGGCGATGGATCATTCAAGTTTCTGCCCTATCAGCTTTGGACGGTAATGTATTGGATTACCGTGGCTTTAACGGGTAACGGGGGATTAGGGTTTGATTCCGGAGAGGGCGCCTGAGAGACGGCTACCACATCCAAGGAAGGCAGCAGGCGCGTAAATTACCCAATCCTGACACAGGGAGGTAGTGACAAAAAATAACAATGGCGGGCCTTTCTAGGTCTGCCAATTGGAATGAGAACAATTTAAAAACCTTATCGAGGACCAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGGATTTGTGGTGGCGCCCGAGGTCCAATTGTTGGTACTATCGGGTGCTGCCATCCTTGGGTGGAATCTGTGTGGCATAGGTTGTCGTGCAGGGGATGCCCATCGTTTACTGTGAAAAAATCAGCGCGTTCAAAGCAGGCTTATGCCGTTGAATGTATTAGCATGGAATAATAAGATAGGACCTTGGTACTATTTTGTTGGTTTGCGCACCGAGGTAATGATTAATAGGGACAGTTGGGGGTATTCGTATTCCATTGTCAGAGGTGAAATTCTTGGATTTCTGGAAGACGAACTACTGCGAAAGCATTTACCAAGGATGTTTTCATTAATCAAGAACGAAAGTAAGGGGATCGAAGATGATTAGATACCATCGTAGTCTTTACCATAAACTATGCCGACAAGGGATTGGTGGGGTTTCGTTACGTCTCCATCAGCACCTTATGAGAAATCACAAGTTTTTGGGTTCCGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGAAATTGACGGAAGGGCACCACCAGTAGTGGAGCCTGCGGCTTAATTTGACACAACACGGGAAAACTTACCAGGTCCAGACATAGTGAGGATTGACAGATTGAGAGCTCTTTCTTGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGTTAACGAACGAGACCGCTGCCTGCTAAATAGTCCAGTCAGTGAATTTCACTGGCGAGGACTTCTTAGAGGGACGTGCATTC
->URS0001EA0CFC rRNA from 1 species 
-ATAATAATCGGGCATAAGTATACCACCGAAGCTATGGACTTATTTTATAAGTGGTAGGGGAGCATTCTAGTTACGTTGAAGGTGCATGGCAATGTGTGCTGGAGTGGCTAGAAAAGAAAATGTAGGAATGAGTAACGATAATGCGGGCGAGAAACCCGCACACCGTAAGACTAAGGTTTCCTGAACAACGCTAATCGGTTCAGGGTTAGTCGGGTCCTAAGGCGCACCCGAATGGGGAAGTCGA
->URS0000169475 rRNA from 1 species 
-AACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGGGAAAGTGGAGCAATCCACGAGTATAGTGGCGACCGGGTGAGTAACACGTGACTACCTGCCCTTGAGTGGGGGATAACCTTGGGAAACCGGGGCTAATACCGCATAAAATCGAAAGATCAAAGGAGCAATCCGCTTTTGGAGGGGGTCGCGGCTGATTAGCTAGTTGGTGAGGTAATGGCTCACCAAGGCGAAGATCGGTATCCGGCCTGAGAGGGCGCACGGACACACTGGAACTGAAACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGCGCAATGGGGGAAACCCTGACGCAGCAACGCCGCGTGGAGGATGAAGCCCCTTGGGGTGTAAACTCCTTTCGACCGGGAAAATTATGATGGTACCGGTGGAAGAAGC
->URS00003DDD0E piRNA from 1 species 
-TNGGGCCTTAGTATCACTCTCAGTTACC
->URS0002242497 RNase_P_RNA from 1 species 
-GCAGTTGGACGGTCTGTCGCCGGCTCCTTTCGAGGGGCTGGAGGAAAGTCCGGGCAACGCAGAGCGTTCCACTTCTTAACGGAAGTTGTCGGCGACGGCAGGGTAACGCAGAAGAAAACAACCGCCGGTGCGACGTTGCGGGCCCCCGTTTCAAGTAATGTCCATCGGTAAGGGTGAGAAGGTGGGGTAAGAGCCCACCGGGCGACGCGGTGACGCGCCGTGCCGTGCGTCCTGGAAGTTGCAAGTTCATGTAAACCGGCGTCAGAGGGCTGCTCGTCCGAGCCGGAGGGTAGAACGCGTCAGATAAATGACAGACACCTCGCCTGCGCGGGGCACAGAACCTGGCTTACAGACCAACTGCCGTT
->URS0000AF82F7 rRNA from 1 species 
-TGAGGGAAAGGCGAAAAGAACCCCGGCGAGGGGAGTGAAAAAGAACCTGAAACCGTGTACGTACAAGCAGTGGGAGCACAGGTTTACCTGTGTGACTGCGTACCTTTTGTATAATGGGTCAGCGACTTATATTCTGTAGCAAGGTTAACCGAATAGGGGAGCCGGAGGGAAACCGAGTCTTAACCGGGCGTTAAGTTGCAGGGTATAGACCCGAAACCCGGTGATCTAGCCATGGGCAGGTTGAAGGTTGGGTAACACTAACTGGAGGACCGAACCGACTAATGTTGAAAAATTAGCGGATGACCTGTGGCTGGGGGTGAAAGGCCAATCAAACCGGGAGATAGCTGGTTCTCCCCGAAAGCTATTTAGGTAGCGCCTCGTGAATTCATCTCCGGGGGTAGAGCACTGTTTCGGCTAGGGGGCCATCCCGGCTTACCAACCCGATGCAAACTGCGAATACCGGAGAATGTTATCACGGGAGACACACGGCGGGTGCTAACGTCCGTCGTGAAGAGGGAAACAACCCAGACCGCCAGCTAAGGTCCCAAAGTCATGGTTAAGTGGGAAACGATGTGGGAAGGCCCAGACAGCCAGGATGTTGGCTTAGAAGCAGCCATCATTTAAAGAAAGCGTAATAGCTCACTGGTCGAGTCGGCCTGCGCGGAAGATGTAACGGGGCTAAACCATGCACCGAAGCTGCGGCAGCGA
->URS00019A0A0A lncRNA from 1 species 
-GGGGGATGTAGGGATTCATCTTTGTCACATTTTCTCTCTAATTTAGCTGTCTAGGGAGCCTCCCTTGTTTTGCAGAAGTGGAAACATCCAGTTTAATTTCATCTTTTCTCAGACTGCAGTAGCTTGCTTCCTCAGAAGCCAGGGTCTCTCTCCATTTATTCTTAGTGTTTATCCCTTTAATTCTCCTACAGTTTCACAAGTGCTTCTGGTATATTTTGTAATTTTAGCTTATAATCACATTTTTCGAAGAGGCACCATCTGGTTCCTGACATGGCTTAAAATAACAATCTAACTAACACGAACCCTGCAGCAATGCTTTGCGCCCTTCCCAACCCAGTGTGAGAGTGTCCCCACCTATATTTCTTCACAAATGCTCCACTGTTAGGTTCCATCCCTTCCGATAGATCTCACAGAAAGCGGGGCCTTTTACCTCTTTCATCTCGAACCCAGTCGTTTCAGGCAGTCAAAATGGATGCGTTAAAAAAAAAAAAAAAAAACCTTGCAGCTAGGACAGCAGAGGATCTGCTGTGAACTGCTCAGTCAGAGACTTGGAGCTGGAGCTCACGTCTGTATTTCAGCTGCCCTCTGGTGCTTAGCACTGCAGCAGTACACGCCATCATCATGGCCCCAGTGCTTGGAGGTCCCTGCGACGGAGCAGCGGAAACCAAGCACAGCAAAAATTCCTTTGAAGACAGAAAAGTGGCCCAGTGCTGTGCAGCAGGGCTACGGTGCTGGAATCCAGCCCGGCCCAGTGCCGGCGTTGGCAGCGGCCTTCCCATTATATCAGGAAGGGCTGTATCCCGTCGCCACCATGCCCCAACCCCCCCGGCTCGCCTCAGCTGTCTGCGGGACGTGGAGCCAGGCAGAGGGTGCCCTGCAAGAAGCAGAGCTGTTGGTTTGAGGTGCGGAAAGCCGGCCAGTCTGGATGCGACTGCTGCTGCGTGGCGGACAGGAACTGACATACAGCTTCAGTGCTTCCCACCGCAAGGGCACTCCAGGATCCAGACTCTGGAGGAGAAGCTGTGGCTGTAGGATTGCTAATTGCAGCCGGTGCCAACGCTGCTGCCCGTTTTCAGGTGAGTGTGGTGGAGGGCACTGTAGAGACGCACGGCTATTCACAGAGCGTGCACTTCCAGCACCTGAACTGCTGGATCCGCTCTGACCGATGTACGGCAATTACATTTGGTGCTGCACTGCTATAATTTCACTGCACGTTAATAGCCACCTAGTGCAGAGGTAAAGGCCCTTCCCTCGCCCGGTGCAGAAGGAATGCCTGGATTTATTCAGCTGAGTAAAACGAGCTGTGATTTTCGGAGCAGATGGCAGAGGTTTTGTGTGTTGGAAAAGCGTTTGCCGGTGCAGTGCTGTTTCCCTGCACCCTGACGGGTGTGCGGGAGGCTCCTGGAAAAGTCCCATCCTCGGGTCCTGGCAGGGGGAGGGGAAGAGATGGGGATCATGTGCCCCATTTTGAGTGGCTCATCTGCTACCACCCAAACTCTGCTGCAGTCCCCCCCCCTCCCTTCAGCAGCTCGGCTGAGCACTGCAGGCGCTGTCAGATTTCTCTGGCAAAATTAGTGATCAAAACACCCCCCCCCCCCCACACACACACGCACACCTTCACTAAGGCTGGTGTTTTTAAGGTTGGGGGGGTGATGGGGCGCGGGTGGGAGCGCACGGCGAGGGTACGAGGAG
->URS0000B155C2 tRNA from 1 species 
-GGCTTCGTAGTTCAACTGGATAGAATGACGGATTTCGGCTCCGTTGGTTGCAGGTTCGAACCCTGCCGAGGTCACGA
->URS00025AB7F7 tRNA from 1 species 
-GCTGGTGTAGCTCAGTTGGTAGAGCAGCTGATTTGTAATCAGCAGGTCGCGGGTTCGACTCCTGTCACCAGCTCCA
->URS0000328ABF rRNA from 1 species 
-ACGCTGGCGGCAGGCTTAACACATGCAAGTCGAACGGTAACATAAAGAAGCTTGCTTCTTTGATGACGAGTGGCGGACGGGTGAGTAATGCTTGGGAATCTAGCTTATGGAGGGGGATAACTATGGGAAACTGTAGCTAATACCGCGTAGAATCGGGAGATGAAAGTGTGGGACCTTCGGGCCACATGCCATAGGATGAGCCCAAGTGGGATTAGGTAGTTGGTGAGGTAAAGGCTCACCAAGCCGACGATCTCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGGGGCAACCCTGACGCAGCCATGCCGCGTGAATGATGAAGGCCTTCGGGTTGTAAAGTTCTTTCGGTAGCGAGGAAGGCATTTAGTTTAATAGACTAGGTGATTGACGTTAACTACAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATAACTGGGCGTAAAGGGCACGCAGGCGGTGACTTAAGTGAGGTGTGAAAGCCCCGGGCTTAACCTGGGAATTGCATTTCATACTGGGTCGCTAGAGTACTTTAGGGAGGGGTAGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAATACCGAAGGCGAAGGCAGCCCCTTGGGAATGTACTGACGCTCATGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGTCGATTTGGGGGGTTGAGCTTTGAGCTTGGCCGCCCGTAGCTAACGTGATAAATCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAA
->URS00021F8B86 rRNA from 1 species 
-AGAGTTTGATCCTGGCTCAGGACGAACGCTGGCGGCGTGCCTAATACATGCAAGTTGAGCGCTGAAGGTTGGTACTTGTACCAACTGGATGAGCAGCGAACGGGTGAGTAACGCGTGGGGAATCTGCCTTTGAGCGGGGGACAACATTTGGAAACGAATGCTAATACCGCATAAAAACTTTAAACACAAGTTTTAAGTTTGAAAGATGCAATTGCATCACTCAAAGATGATCCCGCGTTGTATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCGATGATACATAGCCGACCTGAGAGGGTGATCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGACGAAAGTCTGACCGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAACTCTGTTGGTAGAGAAGAACGTTGGTGAGAGTGGAAAGCTCATCAAGTGACGGTAACTACCCAGAAAGGGACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTCCCGAGCGTTGTCCGGATTTATTGGGCGTAAAGCGAGCGCAGGTGGTTTATTAAGTCTGGTGTAAAAGGCAGTGGCTCAACCATTGTATGCATTGGAAACTGGTAGACTTGGGTGCAGGAGAGGAGAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAGGAACACCGGTGGCGAAAGCGGCTCTCTGGCCTGTAACTGACACTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAGATGTAGGGAGCTATAAGTTCTCTGTATCGCAGCTAACGCAATAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATACTCGTGCTATTCCTAGAGATAGGAAGTTCCTTCGGGACACGGGATACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTATTGTTAGTTGCCATCATTAAGTTGGGCACTCTAACGAGACTGCCGGTGATAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGATGGTACAACGAGTCGCGAGACAGTGATGTTTAGCTAATCTCTTAAAACCATTCTCAGTTCGGATTGTAGGCTGCAACTCGCCTACATGAAGTCGGAATCGCTAGTAATCGCGGATCAGCACGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGGGAGTTGGGAGTACCCGAAGTAGGTTGCCTAACCGCAAGGAGGGCGCTTCCTAAGGTAAGACCGATGACTGGGGTGAAGTCGTAACAAGGTAACC
->URS0002423514 lncRNA from 1 species 
-AGTGCTTAGGTCCTTTGACACCGTTGGCGGGAGACTTTTCGTCGTTTGGGGTGGGGATGAAAAACATCAGCGTGTTTATTCCTCAGGCAGCCCAGAAACCTTAGGTTTGCACCACCAGTAGCTTGGCAACGCGGTCACGGGTACACAGCACTGGCACAACATGACTGTGTGTGTGTGTGTGTGTGTGTGTGTGCTATGCTGTCCTATGCTCATGATGCTCTCATGGCCTTTCGCTACAACAGGTCCAAGGCCTTATCATTGCCGTCATGTACGAGAAATCCCGGGGAAGGCAGTCACGATGGGCGCCGTACTTGAACCTGATCCCGGACGACATGACCCACATGCCGCTGTACTGGAAGGTACGGTAATGTACGGGAAAGGTGGATCGTACCGTGGACACCGTGCCACTCGCCTCCCAAACTCTATGCGCCGTGGCGAGAGCTCATCTTCACGCACTCAGCGAGTTCTGGTCCCCCGCCCTTAAACCCCGTCTACGGACAGCATAGGGAGTTCAAGGAGCTGCGTGGTACGGCAGCGTACGACAAGATGATGGGCAAGGTGCAGTGTCCCGCCGACGCACCCACGCAGGTCGGTTAACACTTTGTATTGTATGGGGTTGTCATGTGCGTCGCATCACTGCTCTTTTGCGGATCGTGGTACGACACATCACTGCTTTCCCCCCTCCCCGTTGACCGGGCGATCTGCAATCCTCCGCTGTACTGTGCAGGTCCCCGTTCTGTGGAGTGAGGTGGTGGAGCCCTTCATCCAGGAGCACCCGGAATTAGAGCTGCCGGAGGGGAAGGCGGGGTATGACTTATACCGCTGGGCCACGTGCGCTGTGGCGTCGTACAGCTTTATCTTGGGTGATGACAAGTACCAGGTGGGCATTCCAGTCCTGTACGGCCGGGGGCTCGTGACTGCGGCTGCTGCAAATGATGTCGTACCATGAGCACCTTATCCAATCTAACTACGAAAGCCCCCTTCATTCTCTCCCCCCTCTTTTCCTCCCCCTCTCCCCCTCTCCCCCTCTCCCCATCTCTCTCCTTTCCTCCTCTCATTTCTTTCCCACATGCGTATGAAGCCCACCTCTAGGCGCCCTCCTGCTCACCCAGCACCCTCCTCCCCCTCCCCCTCCGTCCCCGCGCTGGCGGCCGCCCCAGGCGATGGTCCCCGTCTGGGACCTGCTCAACCACATCACAGGTCGGGTGAACGTCCGACTGCACCACTGCGCCAAGAGGTAAAGAAGAAGGGAGGAAAGGCGATATTCGGGGTGGCTGCACCCCGTAGGGCCCTCCTGGAGTGGGTGGACGGGTGGCGTCGCGGGCCCCAGGGGAGTGAGTACGACCGCTCGCTGCACGGGGCGAGGCCATGCAAGCCAATCGCCAAGCGTCCTTGCTAGGTTGGGGATAACCCAACCAACCAACCAACTCCGGGCCCTATATCAGTTGGCAACTTGCTCATTGGGTAACCGGTATATATGTATGTATATATATTATATAACCCCCGGACGACTGCTGAAGCCGGAAGGGCGGACATGGTGATCTCGTCGCATGGCAGCTGTCCCGTGAGCCCACGGAGTTGTGTGGGATGTGCCGATGAGGCGGCGGCATTTGGGGCGTGGCGTGAAGCGTGTATGAGGTTGGCTGATGTCGGCGCCTCACGCACCAAGAGCGCCGCCAGGAACGTACCCGCACCGCACGGGAGAGCGGGCGGGGAGCCGTGTCCGCGTTCTTATCCGGCGGGTCTGTCCTAACCCGCCTAACCTTACCCGTCCTAACGGGGCACCGTGCGCCACCCTGCTGGGGATGGAAGCACCCCCCAGGTCTCAGCAGCCACTGGATTGCGCTTCCCGCTTGCGGCGTTGTTTGTTGCGCCGGTACTGCAGGCACGTGCTTCACATGATTGCCACTCGGGACATCCTTCGCGGTGAGGAGCTGGTCAACAACTACGGTGAGCTTTCCAACGCGGAACTTCTGCGGGGGTACGGCTTCGTGGAGGCACGCAACCGGAACAATCACGTACAGGTCGGTTGGGGATTGAAGGAGGCTGCTGGTTTGGGAGGAGAGTTAATATGGCTGTGGAGCGGGTGCTGGAGCAAAGCGCGCTTCGCACATGACGAGGAGGTAGCGGGTGACAAGAAAATGAGGCGGGTCGGGGGCGGGTAAGGGGTGGGCCTCCCTCCCCCCAGCGTGCTGAGCCCGGGTAAACGCTAAGCCGCCAACCCCGTCACCAATGCCTACCACTATAGTTACCCAGTTACCGCCAGGCAAGGCTTGTCCGTTGAAGAGGGGCGGCTGCGGGGCCGACGGGGTGAGGGTGGGGATGCTGGCACCTGCGTTTTGGTTTTGGGAGGGGAGCCATACCCAGCCGCTGCCATTGGACTCCGGCTCGCCCACGTGGCCCTCCGCGCAACCTGCCTAGGTTCCACTGGGCTTTGTGGTCCGTGCGGCGACGGAGCTTCTCCGAGAGGACATCACGGCAGCGGCGGGTGCCGGCCCTGGACCCGGTCCTGGTAGTCAGTCCGACCAGGGGGAGATACGAGCCCGCGCATCTGCGCGGTTGCGCCTGGCTCGCCGGTGCGACCTGTTGCCACAGCACCATGTGTTCAAAATTTTCGAGGGGCGGCCACCTCCGCCCCCCATGACTGCGCTCATCCATCTGCTGCTGGCGTCGGATGCCGACATTCCGGCTGTGCGGGGTGCTGTCCGCCGTGCAGCCGCGGCCGTAGTGGAAGGTGAGGATGGCGCGGATTGCGGCAAGGATAAGGGCAAGGCCCGGCGGCGTAATGTCGCGGCAGCTGGGGCGGTTCTACAAGCACGCACAGCGGCTGCGGTGGCGGCAGCCTTGGCTGGGAACGAGACGGCGCTGGCGCGGGTCGCGAGGGTGTACGACATGATTGTGCAGCGCATGCTCGGCCGGTACAGCTGTGACCTCGCAGAGGACGACAGGTTGCTGGCGGAGGCGGAGGCAGGACGCCGAGTACTTCCGCCACGCTTACATGCGGCGGTGTTGGCTCGGAAGCCGGAGAAGGACGCGTTGCTGAGTTTGCGGAAATTCATCGGTCAGGAAGGAGCTTTGCGTCAATCCTTGGCTGTCAATTCCGGCAAGAGCTTGTCGAAGACAGTCTTCGGAATAGCAGGAGCAAAGGGGTCAGAGGAACAGCTCTCTGAACCGCTAAAATACAGTCGTGCCATGGCTAAGAGCTGTAGCGCTGCTCCTGTCAATAAGTTTGCCCCTGCTTCGTTTTCGTTCGGTTTCTCTCTGTAAGTTTTGAGTTCGACTTGCTTCAGTTCGCTTTAATATGTGAGGATTCAGCAAAACTGGGAGGATCTAGTAAAACCATTGCATCTCAGGGATAGCCGCTTCTGTTCAGTGCGTGCCATTACAGATTTTCGTATCCCCGTCGGCAAGCGCATGTTCCCATCTGCAATGGTACCCAACGCCCTCTTAGTGCTTAGCTGAGGATGACGGTCACAATCCATGGATCGCAGGTTACAGTGGCCAACGTGCCCGCAGGTATAAAGGTGTCACTCTTCTCCTTCAAACGGCCTACCGAACCGCCACGGCTCCAAAAAATGCTGGCTGTCCGAACCCGCAAAAAGACAACGAGGGCATAGCACCCGGCAACCTTAACCAGGACATAGCAGTCGGTCACAAACGCCAGAGCGACAGGCGCACATTCACGTATGACCGTGAAGACGTGCCGATATTGAACCGTCAGGTCGGGAACAGCCTCCCCATACCGCCTCAAATTGCTATTTGTACAGAGACTCAGGCCCAGACATCATCGCTAAGCACTTCCCTCGATGAAGCAGCAAAACGAGAGCCACAGGCGTGAGCGTCACGTGCAAGCACACGCTTCGGCGCATTTACGAGGAGGGAGCCTCCTTCTCAATGTACCTGAGCACGCAGAGATGGGGGCAATGAGGGGGGAAAAGAGATTACGGGGAAAGGAAATAGTTTTGTACACAGTAATAGTCGCATACATACAACTTCAAAAATCAAAATGTGTGGCGTCCCGACACCATGCTCCCAGCTACACCAGCACTCACACGAACAGCGTAGCCATTCCGATGGCTGGCAGAACCAGGCCAGTCAGGGGCACGAACAGCGAGGGAGCCCAGGCCGGGGGCACGAAGGGGTAGCCCTCAGCAGCGCTAGCAACGGTGGCGATGACCTGCGAGGCCTCAGCCTGCAAGCATACAAGTGGACGACGAAAGATCGGTAGCCTGGGAGAGCCTCCGCTGCACTTCAGCATATTCCCAGACAAAGATGCAAAATCTGATTGTGCAAACAGTACGCAGCCATATCTCTGAAGCTTGTAAACAGGACTGGACGGAAGCGCCTTCCCCATCAAACATAAACACATAAACCAAAATTAAGCGCTGAGTAGGAAATGTCAGTTGCCCTC
->URS0000054DFE rRNA from 1 species 
-GTAGTCCTGGCTGTAAACGATGTCGACTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCACGGAAGTTTTCAGAGATGAGAATGTGCCTTCGGGAACCGTGAGACAGGTGCTGCATGGCTGTCGTCGGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTCCGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGACCAGGGCTACACACGTGCTACAATGGCGCATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCATAAAGTGCGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTGGATCAGAATGCCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTTACCACTTTGTGATTCATGACTGGGGTGAAGTCGTAACAAGGTAACCGTAGGGGAACCTGCGGCTGGATCACCTCC
->URS000187D73E rRNA from 1 species 
-TACAGAGGGGGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCGCGTAGGCGGCCTGCTAAGTCGAACGTGAAATCCCCGGGCTCAACCCGGGAACTGCGTCCGATACTGTCGGGCTAGAGTGTGGAAGGGGCTACCGGAATTCCGTGTGTAGCGGTGAAATGCGTAGATATACGGAGGAACACCAGCGGCGAAGGCGGGTAGCTGGGCCAACACTGACGCTGAGGCGCGAAAGCTAGGGTAGCAAACGGG
->URS0002587220 misc_RNA from 1 species 
-TCCGGTTTACCACCGGCAGTCTCCCTAGAGTGCTCGGCTTTACCCGTTAGCAACTAAGGACAAGGGTTGCGCTCGTTGCGGGACTTAACCCAACATCTCACGACACGAGCTGACGACAGCCATGCAGCACCTTGCACTCTGCCTAGGTTTCCCTAAGAGGCTCCATCTCTGGAGTTGTCAGAGGCATTCTAGCCCTGGTAAGGTTCTTCGCGTTGCGTCGAATTGAACCACGTGCTCCACCGCTTGTGCGGACCCCCGCCAACTCCTTTGAGTTTCAATCTTGCGATCGTACTTCCCAGGTGGGATACTTAATGCTTTCGCTCAGACACACACTGTGTATCGCGTATGTCGAGTATCCATAGTTTAGGGCGTGGACTAC
->URS0000A3D8A0 misc_RNA from 1 species 
-AATGTGATTGGAAAAGAAAATGAAGGAGAACTAATTAGTGGAGGGTTGAGGGTAAAGTGCTACAATTAGAGACTACAAAGTTAAATGTACAATGAACTAATGTTAAGATTAATGGGTCAAAGTTGTATGTAATGTAGATCCGGTAAACTATAATTCTTCTTTCAGATGCTCAACAGTATCATGTCTTGTCGTTACATTGAAGCTTCTCAATAACTTCCTCCAAGGGAGGATCTCCAGGTCTACGGAAGACTTGATCCCC
->URS000015B95D rRNA from 1 species 
-ATGGAAAGTCCGGCCTGCCCGGTGAGAGATTCTCTTAAACGGCAGTAGTAAAGTTCTTTAATCGTAGCTCAATTTTCTTGCCCTTTAATTGTGGAGCGATGTGAATGGTAAGACGAGGGTTCAACTGTCTCGCTGTTACGAAGTGAAAACGGAGTGTAGGTGAAAATACCTACATGGATTATAGGGACGACAAGACCCCGTGGAGCTTTAGTGTGCTATTTTCTAGCTGAATTTAGGTTACTTAGGCTGGGGCAGCCAGATGGGAAGCAAATACCATTTGAGAGACGCTTGAGGCGTGCGGGCTTTTAACGATCCACCTCCCTTGAAATAATGGGGAAAATTGTGTGTATGTATGCAGAAAGAGGTGAAAGACGGAACAACGTTACCCCGGGGGTAACAGGCTAATTTCGCTCTGAGAGATCCTGTCGATGAGCGGGTTTGGCACCTCGATGTTGGCTTAGGGTATCCCGAAGATGCAGGGGTCTTCAAAGGTTGGTCTGTTCGCCCATTAAAACCCT
->URS0000B01B68 rRNA from 1 species 
-TGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCCACGCCGCGTGGGTGATGAAGGCCTTCGGGTTGTAAAGCCCTGTCGGGAGGGACGAATACTGACGGTACCTCCAAAGAAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTGCTCGGAATTATTGGGCGTAAAGCGTACGCAGGCGGCCGTACAAGTCGGGTGTGAAAGCCCGGGGCTCAACCCCGGAATTGCGCCCGAGACTGTACAGCTTGAGTGCGGGAGAGGGAAGCGGAATCCGTGGTGTAGAGGTGAAATTCGTAGATATCACGGGGAACACCAGTGGCGAAAGCGGCTTCCTGGCCCGACACTGACGCTCATGTACGAAAGCGTGGGGAGCAA
->URS000211E027 rRNA from 1 species 
-AGTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGGCAGCACAGTAAGATCTTGCTCTTACGGGTGGCGAGTGGCGGACGGGTGAGGAATACATCGGAATCTACTTTTTCGTGGGGGATAACGGAGGGAAACTTACGCTAATACCGCATACGACCTACGGGTGAAAGCAGGGGATCTTCGGACCTTGCGCGATTGAATGAGCCGATGTCGGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATACCGCGTGGGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTGGGAAAGAAAAGCAGCAGGTTAATCCCCCGCTGTTCTGACGGTACCCAAAGAATAAGCACCGGCTAACTTCGTG
->URS00004A1422 rRNA from 1 species 
-AACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGAGACCTTCGGGTCTAGTGGCGCACGGGTGCGTAACGCGTGGGAATCTGCCCTTGGGTTCGGAATAACTCAGAGAAATTTGAGCTAATACCGGATGATGACGAAAGTCCAAAGATTTATCGCCCAGGGATGAGCCCGCGTAAGATTAGCTTGTTGGTGGGGTAATGGCCTACCAAGGCGACGATCTTTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGAGTGATGAAGGCCCTTAGGGTTGTAAAGCCTTCTTACGA
->URS0000110120 piRNA from 1 species 
-TGAGAAAACAGATTTTGAAACTGTCAGTCTT
->URS0000B33149 rRNA from 1 species 
-GTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTATCCGGATTTACTGGGTTTAAAGGGTGCGTAGGTGGGCAGTTAAGTCAGTGGTGAAATCTCCGAGCTTAACTCGGAAACTGCCATTGATACTATCTGTCTTGAATATCCTGGAGGTGAGCGGAATATGTCATGTAGCGGTGAAATGCTTAGATATGACATAGAACACCAATTGCGAAGGCAGCTCACTACGGGGTTATTGACACTGAGGCACGAAAGCGTGGGGATCAAACAGGATTAGATACCCTGGTAGTCC
->URS00002664CE rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGTGACCCAGGGCTTGCCCTGGTGATCAGTGGCGAACGGGTGAGTAACACGTGGGGCAACCTGCCCCTGACTTCGGGATAACTCCTCGAAAGAGGAGCTAATACCGGATACGACCACTTCGGACATCCGATGGTGGTGGAAAGTTTTTCGGTCAGGGATGGGGCCCGCGGCCTATCAGCTAGTTGGTGGGGTAATGGCCTACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGCGACCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCGACGCCGCGTGAGGGATGAAGGCCTTCGGGTTGTAACCTCTTTCAGCAGGGACGAAGCGAAAGTGACGGTACCTGCAGAAGAAGCA
->URS0000049829 rRNA from 1 species 
-GCCAGACTGGAACCGGGAGAGGTAAGAGGTACTACAGGGGTAGGAGTGAAATCTTGTAATCCCTGTGGGACCACCGTGTGGCGAAGGCGTCTTACCAGAACGGGTTCGACGGTGAGGGACGAAAGCTGGGGCACGAACCGGATTAGATACCCGGGTAGTCCCAGCCGTAAACGATGCTCGCTAGGTGTCAGGCATGGCGCGACCGTGTCTGGTGCCGCAGGGAAGCCGTGAAGCGAGCCACCTGGGAAGTACGGCCGCAAGGCTGAAACTTAAAGGAATTGGCGGGGGAGCACAACAACGGGTGGAGCCTGCGGTTTAATTGGACTCAACGCCGGACAACTCACCGGGGGCGACAAGCAATATGTAGGCCAAGCTGAAGACTTTGCCTGAATCCGCTGAGGGGTGGTGCATGG
->URS00022BB341 rRNA from 1 species 
-CCCAAAGGTGGGTGGTAAACTCCATCTAAGGCTAAATACGTGCACGAGTCCGATAGCGGACAAGTACCGTGAGGGAAAGTTGAAAAGAACTTTGAAGGGAGAGTTCAAGAGTACGTGAAACCGCATAGAGGTAAACGGGTGGACCCGCAGCAGTTCGACCCGGGGAATTCAGCTCGGCGGCTAGCGGCGCCGCGGCCGGTACTCAAGGGGATACTCCCGTACCCCGCCGGTCGTCGACCGCGCCTGCCGCCGGGTGCACTTTCTCCGGGCCGAGAGCCACGACCGGCTCCGTCGGCGGTCAGAAGCCCGGCTGGGAAGGTGCCCCGAGCCCGGACGCTTGCGTCCGGCGCGCCGGGAGTTACAGCCCGCCGATGGTGGACACGTCGCGGGGCCGAGGAAGCCTTGCGCCGCCGGTCTCGGTCCTCCGGTGCCCCTCGCCCGTCCCGACCTCCGCGTCACTGCCTCGTCAGTGCGCGGAAACCGCGGAGCGGGGGCCACGCCGGGGTGTGCCAGGCCTGTGCGAAGGGTCGGTGGCGAATCGGTCGGTGCTCCACCCGACCCGTCTTGAAACACGGACCAAGGAGTCTAACGTGTGCGCGAGTCACGGGGACTCGACAAACG
->URS0002354398 lncRNA from 1 species 
-CCAAGTTCAAGCCTTTGCTTGGGTATATTTTTGTTTTTAATTGAATAAACCCCTATCTCTAGTCAGTAGGCTTAAAATAAATATTGGAAAAATATGTCAGAATGGTCCTACTGGTCTGGTGGTTAAGTGGTGTGTTGGGGTCTTGAGTTTGAATCTCTATACGTGTTAGGGGGTTTTTTTGTACATGTGTCGTGAAGGAGTTTGAAATGTGGTAAAATTCTGAGTATTTGAGGAGTGTGAGGATGTTGTGGCCGAT
->URS00025EA52A lncRNA from 1 species 
-GTCTAGCATTGTCTTGCATTAGGAGGAACCCAGGGCCAACCGCACCAGCATATGGTCTCACAAGGGGTCTGAGGATCTCATCTCGGTACCTAATGGCAGTCAGGCTACCTCTGGCGAGCACATGGAGGGCTGTGCGGCCCCCCCAAAGAAATGCCACCCCACACCATGACTGACCCACCGCCAAACCGGTCATGCTGGAGGATGTTGCAGGCAGCAGAACGTTCTCCACGGCGTCTCCAGACTCTGTCACGTCTGTCACAGCGTCGTGTAG
->URS000112801C rRNA from 1 species 
-TACAGAGGGTGCTAGCGTTGTTCGGAATTATTGGGCGTAAAGGGCGCGTAGGCGGCGCCACAAGTCACCTGTGAAAACTCTGGGCTCAACCCAGAGCCTGCAGGCGAAACTGTGGTGCTGGAGTATGGGAGAGGTGCGTGGAATTCCCGGTGTAGCGGTGAAATGCGTAGATATCGGGAGGAACACCTGTGGCGAAAGCGGCGCACTGGACCATAACTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACAGG
->URS0000474C22 rRNA from 1 species 
-GAGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAGCGGGGTTGAAGCGAGGGGTAACTCGAGTTTCTACCTAGCGGCGGACGGGTGAGTAACGCGTGGGCAACCTGCCTCAAGGACTGGGATAACAGCTCGAAAGGGCTGCTAATACCGGATAAGCCTATGGCCTCGCATGGGGCCATGAGCAAAGGGGAAACCCGCCTTGAGATGGGCCCGCGTCCCATCAGCTAGTTGGTGAGGTGAAGGCTCACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGGGGCAGCAGTGGGGAATCTTGCACAATGGGCGAAAGCCTGATGCAGCGACGCCGCGTGAGCGAAGAAGGCCTTCGGGTTGTAAAGCTCTGTCTGGAGGGACGAAGGAAGTGACGGTACCTCCGGAGGAAGCCACGGCTAACTACGTG
->URS00019BDD9E misc_RNA from 3 species 
-TAACCCTCAAGCCTAGCTTGGTATTGGAGTCGCTATACAGCGGCCCCTAAAATCAGTGGCGGTGCCTATAGGTTCTACGCGTAGTAATTTTTCTCGCTATAGATCCCTATAAGTGCTTGCCAACAACCCCAATTTTTTCA
->URS0002519978 rRNA from 1 species 
-ATGTCTGGAAGCACGGGAGAACGTTCTTTTGCTGATATTATTACCAGTATTCGATACTGGGTTATTCATAGCATTACTATACCTTCCCTATTCATTGGTTTGTTATTTTTCAGTACATGTTTAGCTTATGACGTGTTTGGAAGTCCTAGGCCAAACGAGTATTTCACGGAAAGCCGACAAGGAATTCCATTAATAACCGACCGTTTTGATTCTTTAGAACAACTCGATGAATTTAGTAGATCCTTTTAG
->URS000071DEB1 tRNA from 1 species 
-GGGGGTGTAGCTCAGTGGTAGAGTGCTTGCCTGGTATGCATGAGGCCCCGGGTTCCAGCCCCT
->URS0001088F60 rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGCTCGGAATCACTGGGCGTAAAGCGCACGTAGGCGGATCGTTAAGTCAGGGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTTGATACTGGCGACCTTGAGTTCGGGGGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGATACTGACGCTGAGGCACGAAAGCGTGGGGAGCAAACAGG
->URS00008DF95F rRNA from 1 species 
-CGCAGGGCCTTGCGCTGGSGATGTTTCATTCAAATTTCTTGCCCTATCAACTGTCGATGGTAAGGTATTGGCTTACCATGGTTACAACGGGTGACGGAGAATTAGGGTTCGATTCCGGAGAGGGAGCCTGAGAAACGGCTACCACATCCAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCTGACTCAGGGAGGTAGTGACAAGAAATAACAATACAGGGCTTTTCTAAGTCTTGTAATTGGAATGAGTACAACTTAAATCCTTTAACGAGGATCCATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGGATTTCGGGACGGGCCGGCCGGTCCGCCGCAAGGCGTGTTACTGACCGGGCTGTTCTTCTTCGCAAAGACTGCATGTGCTCTTAGCTGAGTGTGTGTAGGACTTGTGACGTTTACTTTGAAAAAATTAGAGTGTTCAAAGCAGGCCAGCGCTTGAATACATAAGCATGGAATAATGGAATAGGACTTTGGTTCTATTTTGTTGGTTTCTGGAACCGAAGTAATGATTAAAAGGGACAGTTGGGGGCATTCGTATTTCGTTGTCAGAGGTGAAATTCTTGGATTTACGAAAGACGAACTACTGCGAAAGCATTTGCCAAGAATGTTTTCATTAATCAAGAACGAAAGTTAGAGGATCGAAGACGATCAGATACCGTCCTAGTTCTAACCATAAACGATGCCGACTAGGGATCAGAGAGTGTTATTGGATGACCTCTTTGGCACCTTATGGGAAACCAAAGTTTTTGGGTTCCGGGGGAAGTATGGTTGCAAAGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTCACCAGGTCCAGACATAGGAAGGATTGACAGATTGAGAGCTCTTTCTTGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGTTAACGAACGAGACCTTAACCTGCTAAATAGTTACGCGAATCCCGATTCGCGGCTAACTTCTTAGAGGGACTGTTGGTGTTCAACCAAAGTCAGGAAGGCAATAACAGGTCTGTGATGCCCTTAGATGTTCTGGGCCGCACGCGCGCTACACTGACGATGTCAACGAGTCTCTCCTTCGCCGAAAGGCGTGGGTAATCTTCTGAAACATCGTCGTGCTGGGGATAGATCATTGCAATTCTTGATCTTGAACGAGGAATTCCTAGTAAGCGCGAGTCATCAGCTCGCGTTGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTACTACCG
->URS00023E717A lncRNA from 1 species 
-AGTCCAAGCTACATTATTGGCGCTGGCAGGGCTAAAACGCCTAGATATGACAGAAAATGTCACTTCCATTCTTCCTATAGAGGATATGCTACCGGCAGTTGCTCAGGGAGCCATTGGTATTGCATGCAGAAGTGATGATGAGACAATGGTATTCACATCGTTTCTTCCATAAATATAGTTGCTTCTATTGCAGTTCTCTATTCGATGACGAGACAATGGTATTCACATCGTTTCTTCCATAAATATAGTTGCTTCTATTGCAGTTCTCTATTATTCTTTAATGAAAAACTTCAATCACAGGCCAATTACATTGCCTT
->URS00007532CF rRNA from 1 species 
-TGCTCAGGATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAATGGATTAAGAGCTTGCTCTTATGAAGTTAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCCATAAGACTGGGATAACTCCGGGAAACCGGGGCTAATACCGGATAACATTTTGAACCGCATGGTTCGAAATTGAAAGGCGGCTTCGGCTGTCACTTATGGATGGACCCGCGTCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGCTTTCGGGTCGTAAAACTCTGTTGTTAGGGAAGAACAAGTGCTAGTTGAATAAGCTGGCACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGCGCGCGCAGGTGGTTTCTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGGAGACTTGAGTGCAGAAGAGGAAAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGAGATATGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGTCTGTAACTGACACTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGAGGGTTTCCGCCCTTTAGTGCTGAAGTTAACGCATTAAGCACTCCGCCTGGGGAGTACGGCCGCAAGGCTGAATCAG
->URS000255B89B rRNA from 1 species 
-ATGGCGCCATCGACCAAGCTCTTCCTCCTGCTCCTCGGCTTGAACCTGATGGTCGCCGATGTGCACGGTGGCTGCGGAGCCCACTGCCCGACTCCGCCGCCACCGTCGACGACCAACGGCTCGTGTCCGATCGACACGCTGAAGCTGGGCGTGTGCGCCAAGGTGCTGAACCTGCTAAAGCTTGGGCTCGGTGTGCCGCACAGCGAGACGTGCTGCCCGCTGCTGGCCGGTCTGGCCGACCTGGACGCCGCGGTGTGCCTCTGCACCGCCACCAGGGCCAAGGTCCACGGCGTCATCAACCTCAACGTCCCCATCGACATAGTGCTCCTGCTCAACCAGTGCCACAAGACCTGCCCGCCCGGCTTCACCTGCCCGCTCTGA
->URS00017EA271 rRNA from 1 species 
-TACAGAGGTCTCAAGCGTTGTTCGGATTCATTGGGCGTAAAGGGTGCGTAGGTGGCGTGGTAAGTCGGATGTGAAAGCCCCCGGCTCAACTGGGGAGGGTCATTCGATACTGTTCGACTCGAAGGCAGGAGAGGGAAGTGGAATTCCCGGTGTAGTGGTGAAATGCGTAGATATCGGGAGGAACACCAGTGGCGAAGGCGACTTCCTGGCCTGTTCTTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACGGG
->URS0001FED583 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACAGACGAGGAGCTTGCTCCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACATCGGGAAACCGGAGCTAATACCGGATAATATATTGAACCGCATGGTTCAATAGTGAAAGACGGTTTTGCTGTCACTTATAGATGGCTCCGCGCCGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCGACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACAAATGTGTAAGTAACTATGCACGTCTTGACGGTACCTAAACAGAAAGCCACGGCTAACTACGTG
->URS0002417CDE lncRNA from 1 species 
-AGAGACAAAATCATTGGGACACCAAATCTGTTAAAGCAGGCATCACTCTTGTTTCAATGTGGTTTTCACAGCATCTCAATGCCGTTTCATGCTGTTTAGAAATCATAAACAGCTCTGGAGACGTGCCTCACTCAGTCGTGGGAATCTCCAGTCATCAATTCAGGAGACAATAACACCAAATTTGTTCAATGTGCGTTTAACAACATTCTGAAACGTCATAAGTAATGCAGGCTGTCTCGCATGCAGTCTTTCAGCACTGAAACGTTGTAGAGTCGAAGTGTATAGCGCTGCCTTAGTCCAGACAGCATGCTATTGTGAACTTGTCTCCAGTCAATTGGCTCGATAATTTTGAGCTCTCGTGCATGCAGCGGCATACATCTGAGGGACATGGACTTCCATGGGCCAACGATGAATATTACTCTATTTTCTCATAGGTCACAGCCACGGAAGAATGCGATGCCGCTCAATACGACCTTGGCCAACGATGAATATCACTCTATTTTTTCATAGGTCACAGCCTAGGAAGAACGCGATGCCGCTCAATACGACCTCTATGAGTGGTATTAGCACTTGGTGCTCATTCCCTTGAGGAAGGAAAGGTGACATTGCAAGGGCATATTGGCAAGCATATCGATGGCCATCAAATTTTCATTTTAAGGTTGCATTGCATTATATGATTTCAAGA
->URS0002158408 rRNA from 1 species 
-GGTTTCCTGGGCAAGGCTAATCCTCCCAGGGTCAGTCGGGGGCTAAGGCGAGGCCGGGAGGCGTAGCCGACGCGCAGCAGGCAGACATTCCTGCACCGCGCACGCGGCGCTACGACCGACGGGGCGACGGATGGGGGTGGCTCGGCGGGGTTCTGGACGTCCCCGTGATGGAGCGCGGCCCGCGGACCAGGGAAATCCGGTCCGCACGAGGGCGAGGCTCCGGACGAAGCGATTGAGCGAAGCGAGTGAGCCCGAGGTCCCTAGAAAAACCCCTAGGCAGGCGCGTGCGCGCCCGTACCGCAAACCGACACAGGTGGGTGGGTAGAACATACCGAGGCGATCGGGTCAACCATGGTCAAGGAACTCGGCACAATGGCCCCGTAACTTCGGGAGAAGGGGTGCCCGCGCGTACGTGAACCGGCTTGCCCGGGGAGCGGAGGCGGGCCGCAGTGGAGAGGCCCAAGCGACTGTTTACCAAAAACACAGGACTCTGCAGAAGCCGCAAGGCGACGTATAGGGTCTGACGCCTGCCCGGTGCCGGAAGGTCACGCGGAGGAGTTAGCCGTCAAGGCGAAGCCCCGAAGCCAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAAAGGCGCAACGACTTGGGCGCTGTCTCGACCATGGACCCGGTGAAATTGCACTGGTCGTGAAGATGCGACTTACCCGCGGAAGGACGGAAAGACCCCGTGAACCTTCACTGCAGCTTGGCATTGGCCGCTGGTCCCGCGTGTAGAGGATAGGCAGGAGGCACAGATCCGGAGGCGCCAGCCCCCGGGGAGCCGCCCTTGGAATACTGCCCTCGCGCGACCGGCGTCCTAACCCGAGGCCGTCAACCGGCTCGGGGACCGTGCCAGGCGGGCAGTTTGACTGGGGCGGTCGCCTCCTAAAGGGTAACGGAGGCGCGCGAAGGTCCGCTCGGGACGGTCGGCAACCGTCCTTTTGAATGCAAGAGTACAAGCGGGCTTGACTGCGAGGCCCACAAGCCGAGCAGGTGCGAAAGCAGGCTCTAGTGATCCGGCGGCCCCGAGTGGGTGGGCCGTCGCTCAACGGATAAAAGGTACTCCGGGGATAACAGGCTGATCTTGCCC
->URS0000E09CF4 tRNA from 1 species 
-GCCGGTGTAGCTCAATGGCTAGAGCACTTGACTGTGGATCAAGGGGTTATGGGTTCAAGTCCCGTCGCCGGTA
->URS0000BDAE45 snRNA from 1 species 
-GAATGTTGGGCTAATTTGGCTGAAGCACCTGTCAGCCTACTGATTGCCAGCATGGATTCAGCTGATCTAGCTGGCTAGGTGGGCGTCTCCTTCCTCCCTCACTGCTCTATGTGTAACCCTCCTGAAAGTGGTCAGAGGACACCTTTGTGGAATTGGTTCTTTCCTCTTTCCTTGGGTTCCAGGGGTCAAACTCAGGTCAGTAGGCTTACACAGAAAGCTCACCATCTCT
->URS0000B28382 lncRNA from 8 species 
-TGTAAACAAAACCAAAAAAAAAAAGGCATAAGATTAATAAAGATGTATTAAATACATAAGATTAACACATAAATTTCGTTATACAAAAGCATTTTGATAAACCGAACCAAATCATCTAGATAGGAAAATTGAAAACATGTGATTGAATATCTTGTTTTATACTTTATTTACATATAAAACTTTAAGAAACATGAAAGAGATATTTGGCAGATTTAATCATGCCAACAAAGATTGATTTATCTAATAAATATCTATTGTGTCCCTGGGTACTGGACATTGTTATTAGAGAAAAGAAATAATATGAAACCTCTACCGTAATATCATAGAGTCTAGGAAAGAAAATTCATCTATTCTTCTATCCAGATTAGACTAAGAG
->URS0002201BE9 tRNA from 1 species 
-TCTCCTTTAGCTCAATAGTCAGAGCGTCCGGTTGTTAACCGGAGGGTTCTGGGTGCAAGTCCCAGGGGGAGAT
->URS00014BEA7C rRNA from 1 species 
-TACGGGGGGGGGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCTCGTAGGTGGCCAACTAAGTCAGACGTGAAATCCCTCAGCTTAACTGGGGAACTGCGTCTGATACTGGATGGCTTGAGTTTGGGAGAGGGATGCGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAATACCGATGGCGAAGGCAGGTCTCTGGGCTGACACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGG
->URS00023B1992 lncRNA from 1 species 
-GACTACGAATCGACATTGTAGCTTAGGAAAGTTTCATTTCATCCGTGGATCCTGAAGAGCAAGGTATCCTCTCTCCGTCGTACCTTTTTTCACATCGATTCGTTATATATTTCTTGCATTTTTGAACTTAGGGTTTTCATGCAAATGTAGGATGCCGAGGCGTGGAAAAGCTAAGAAACTAAGGTAATCTCAACGCCCGTAGTTATGTTATATACTCATTGTTGTGTATCAAATGAAAAAACCTTAAATGTAGGTTTATTCCTAAGTGCGTTTGATTCATAGAACCAAATAAACAAAATTGTAGTTATGGCGCTAAGAAGACCGGAAATGCGTTCGATCCATTGCCTCTGCCTAGTGGTGTTCCAGTGCCGATGTGCTTTTGCGGCGATCCTTGCAAGGTAGCCAAGTCCGAAGAACATGCC
->URS0001EBED66 rRNA from 1 species 
-CCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGGGGAGGAAGGGAGTAAAGTTAATACCTTTGCTCATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCTGATACTGGCAAGCTTGAGTCTCGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACGAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGACTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCACGGAAGTTTTCAGAGATGAGAATGTGCCTTCGGGAACCGTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTCCGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGACCAGGGCTACACACGTGCTACAATGGCGCATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCATAAAGTGCGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTGGATCAGAATGCCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTTACCACTTTGTGATTCATGACTGGGGTGAAGTCGTAACAAGGTAACCGTAGGGGAACCTGCGGTTGGATCAC
->URS00006566BF snoRNA from 5 species 
-CTGCATGATGAACTCTTAATTTCGCTGTGTTCTTACCGAGGCACACTTTGAAGAAACAAAATATCACCTTGGAGAACTGACAC
->URS00006E3F2F snoRNA from 1 species 
-TATGCTGTGATGAGATTAAGCACCATAGGGTGTATTGGGCAGTGGAAGAAGGTTTAAAAGCCTTCTCCGTGAGCTTATTAATTAACGACTTCTCCTTCCACTGAGCATC
->URS00000BBF13 rRNA from 1 species 
-AGAGTTTGATCCTGGCTCAGGATGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAGCGAGATTTTATAAAATTACTTTTCGAAGGAAGTTTTATAGATAAAGCGGCGGACGGGTGAGTAACGCGTAGGCAACCTACCTTATACAAAGGGATAGCCTCGGGAAACTGGGATTAATACCTTATAATACTTTGGGATCGCATGATCCTAAAGTCAAAGATTTATCGGTATAAGATGGGCCTGCGTCTGATTAGCTAGTTGGTGGGGTAACGGCCTACCAAGGCAACGATCAGTAGCCGACCTGAGAGGGTAATCGGCCACATTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCAACGCCGCGTGAGCGATGAAGGCCTTCGGGTCGTAAAGCTCTGTCGTGAGATGGGAAAGAATGACGGTACAATAAGAGGAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAACGTTGTCCGGAATTACTGGGCGTAAAGGGCGAGTAGGTGGTTTGCTAAGTCAAAAGTGAAAGGCTACGGCTTAACCGTAGTAAGCCTTAGGAACTGTAAGTCTTGAGTGCAGGAGAGGAAAGCGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGACTTCCTGGCTTGTAACTGACACTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAGGTGTAGAGGGTATCGACCCCTTCTGTCGCAGCTAACGCAATAAGTATCCCACCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGACGCAACGCGAAGAACCTTACCAGGGCTTGACATCCTACGAATCCTTAGGAAACTAGGGAGTGCCCTTCGGGGGAACATCTAGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCATTAGTTGCTACGCAAGAGCACTCTAATGAAACTGCCGTTGACAAAACGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCAACACACGTACTACAATGGCCGATAACAACGGGAAGCAATACAGCGATGTGGAGCCAATCCCAAAAATCGGTCTCAGTTCGGATTGCAGGCTGCAACTCGCCTGCATGAAGCCGAAATCGCTAGTAATCGCAGGTCAGCATACTGCGGTGAATACGTTCCCGGGCCTTGTACACACC
->URS0001DD25E8 rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCTTTACACATGCAAGTCGAACGGCAGCACAGGGAGCTTGCTCCTGGGTGGCGAGTGGCGAACGGGTGAGTAATGTATCGGAACGTGCCTGGTAGTGGGGGATAACTACTCGAAAGAGTGGCTAATACCGCATGAGATCTTTGGATGAAAGCGGGGGACCTTCGGGCCTCGTGCTACTGGAGCGGCCGATATCAGATTAGGTTGTTGGTGGGGTAAAGGCCTACCAAGCCTGCGATCTGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATGTGGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGCAGGACGAAGGCCTTCGGGTTGTAAACTGCTTTTGTACAGAACGAAAAGTCTCTGGCTAATATCTAGAGATCATGACGGTACTGTAAGAATAAGCACCGGCTAACTACGTG
->URS000170AD9B rRNA from 1 species 
-TACGTAGGTGGCAAGCGTTTGTCCGGATTTACTGGGCGTAAAGAGCGCGCAGGCGGCTGGGCAAGTCCGATGTGAAAGCTTCCGGCTTAACTGGAAAATTGCATCGGAAACTGCTCGGCTTGAAGGTGGGAGAGGGTAGCGGAATTCCCGGTGTAGTGGTGAAATGCGTAGATATCGGGAGGAACACCAGTGGCGAAGGCGGCTACCTGGCCCACTCTTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACGGG
->URS000204CED6 rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGATGAAGGGAGCTTGCTCCTGGATTCAGCGGCGGACGGGTGAGTAATGCCTAGGAATCTGCCTGGTAGTGGGGGATAACGTCCGGAAACGGGCGCTAATACCGCATACGTCCTGAGGGAGAAAGTGGGGGATCTTCGGACCTCACGCTATCAGATGAGCCTAGGTCGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCCGTAACTGGTCTGAGAGGATGATCAGTCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGTCTTCGGGTTGTAAGGCACTTTAAGTTGGGAGGAAGGGCAGTAAGTTAATACCTTGCTGTTTTGACGGTACCAACAGAATAAGCACCGGCTAACTTCGTG
->URS0000E460B3 rRNA from 1 species 
-CGGCGAGTGAAGCGGCAACAGCTCAAATTTGAAATCTGGCCTCGGCCCGAGTTGTAATTTGCAGAGGATGCTTTTGGTGCGGTGCCTTCCGAGTTCCCTGGAACGGGACGCCACAGAGGGTGAGAGCCCCGTATGGTTGGACACCAATCCTGTGTAAAGCTCCTTCGACGAGTCGAGTAGTTTGGGAATGCTGCTCTAAATGGGAGGTAAATCTCTTCTAAAGCTAAATACCGGCCAGAGACCGATAGCGCACAAGTAGAGTGATCGAAAGATGAAAAGCACCTTGAAAAGGGGGTTAAACAGTACGTGAAATTGTTGAAAGGGAAGCACTTGTGACCAGACTTGGGCCGGGCGGCTCATCAGGGGTTCTCCCCTGTGCATTCCGCCCGGTACAGGCCAGCATCGGTTCTTACCGGGGGATAAGAACGGCAGGAACGTGGCTCCCCCTCGGGGGAGTGTTATAGCCTGCCGTACGATACCCTGGCGGGGACCGAGGTTCGCGCTTCCGCAAGGATGCTGGCGTAATGGTTACTAGTGACCCGTCTTGAAACACGGACCAAGGAGTCGTCCATTAGAGCGAGCGTTTGGGTGTCAAACCCCCACGCGTAATGAAAGTGAAATTAGGTGAGAGCTTCGGCGCATCATCGACCGATCCTGATGTTCTCGGATGGATTTGAGTAAGAGTTTTAACGGACGGACCCGAAAGACAGTGAACTATGCTTGTATAGGGTGAAGCCAGAGGAAACTCTGGTGGAGGCTCGCAGCGGTTCTGACGTGCAAATCGAT
->URS0000657173 tRNA from 1 species 
-GGGGATATAGCTCAGCTGGTAAAGTGCTTGCCTTCCATGCATAAGACTCTGGATTCTATCCCCA
->URS0001FC8B0A rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTAGAACGCTGAAGGAGGAGCTTGCTCTTCTGGATGAGTTGCGAACGGGTGAGTAACGCGTAGGTAACCTGCCTGGTAGCGGGGGATAACTATTGGAAACGATAGCTAATACCGCATAAAATTGATTATTGCATGATAGTCAATTAAAAGGTGCAATTGCATCACTACCAGATGGACCTGCGTTGTATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCAACGATACATAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGACGGAAGTCTGACCGAGCAACGCCGCGTGAGTGAAGAAGGGTTTCGGATCGTGAAGCTCTGTTGTAAGAGAAGAACGAGTGTGAGAGTGGAAAGTTCACACTGTGACGGTATCTTACCAGAAAGGGACGGCTAACTACGTG
->URS00009B8067 lncRNA from 7 species 
-TTTGTAGCGGTGCCAGTGAAGAAGAGGACACATGAAGACTTAGCATTCCCTGCAGAAAACGCCCCTTCCCCGTGTGTGTGTGACAGCGTGTATGTAATGGCTTCTGATATCTGTGAAAGCTGCCAGGCAACAAACTTCTTCTACTGGAAATGTCCCCAGATCCACAGCAGGCACACATGTTCCCAAGGGACCAGGGGTTGTATGCATTCTGACTGTGTGCTTCTTGTTCTCTGTGGTAGGTCATGGGAAGAGCCCTTTTGATCAACTTGGAGGGCTCTTCAGCTAACCCCCCAATGGCTGCTTTGAACTTACTCAGGAAAGCCAGCCCCTGGAATATTGTGCAAGTCAACACTATCACTTCCTTAGGAAGGTTCTAGAACATCTCGAAAGGATATCAGTTTTCCTTACCTGCAAACAGAAAACAAACCCACTTTGTTTGTACTGAAGCTTAAAGCAAATGTGGCCAAGTGGGGCCAAACTGACTCAATAGGCAGTCTGTCATAGTCCAGTTCTGCCTCTGTGAAAAGTGTTAGGGCAACTGGGTTAAAATAGGGTTGGAGAAAGAGTCCAGAGCTAGAAAGAAGATATTTTTAGTATGTGAGGTTATCTAGGACTTAAGTTTCATAATTCAGTGCTGTGGAAATGGGAAAATGATTGAAAAGGTAGAAAGGAAATGACCTTAAGGACTGGGGTGAGGCACAGAAATCTGATTAAAGGTTGAAATCAGTGTTTCAGAATTCAGATTGCCTCAATTTTCCAAAATGGTCACTAAAGCATCTGATAAAACCCAGAATTCTTCGGCCAGCTGTGTGGATTAACAGGCCTGTCACAACATAAAAGGCTGGCATGTATATTGGCAGGTGGAGATTGTCACTGTAAAACTTAGCAGTTTCACTCCGAGGTTAGTCTATGGTGGTCAGTGCACTGTGAGGGGAATCCTTGTCCCTCCCTGGCAGCTAGCAAACATTCCTCTATTTACTATAATTGGAATCCTCCCTTCCCCTGCAGCAGGCCGTCAGCTCACCTCACACAGCCCAGTTTTCTCTTCATGTAGCATGTCCAGGCATGCTCCAGAGCTGGGTTTCCTGGCCTTCCCACACTCCCAGATCACAGTCTCTTACAACCATGCTTTTCAGGATCCAGGAAGTAGTAAGTGTGCTGGGAGATACCCAACTAACTGCAAGCTCACAAGCACCACATCTTCTTGAGACATCAGTTTTTCTTTCCAAATGATTTGAAGTCAAGAGATGACCATATTTTTTAATGGAACAAATGCTTATGTTATACAAGAGAATGTTCATACACCTAAAGTGCTAAACTAAAATAGGAAACTTGGAAGGAAACTCATATTTGTAAGTGGACAGTGATTCTATCTCCTCTGCTTGTGTGGTATTTCCATGTTCACTTTGAGATTTTGTCTGAACTGGATTCAGGCAGCCTTGGGGTTGCTGTTGATCAAGGTCTAGACTTCCAGATCCAAGGAGTCCACCTTGGAGTAGTACATCTCCCTTTTCCTGTCAGCCAGCTTGCCTGTGTACTTATCACAAAGCTTTAGGGGCAGCTAACATGTGTATGTACAGGATAGTTCTGAGGCAGAAACAGCATAGACTTATTGTAGGAGTCCTATTTATGTCATTGTTCAGCCCTGTGCATGCTAGAAAATGATTTATCCCTTTGAGGCCAGGAAACTGCCAAGCCACTCTGCTGTAGGCTAGGATTACTGAAACTCACCACACATACAAGGATATTGGGGCAGAGCGGAGTGTGAGATCTAAAAATATGTATACTTTCCCCAGCTGGTGGCTAGTAGATGGCTTAGACAATTTTGGTGTCTTACCATCTGTCTGCAAAGACTGGAGAATTTAATACATCTTGAGTTGACAACCTCCAGTGATATCCTGTTCTGCCAAAATTTTAAAAGAAGGGCCACTGTAGAAAGAGTGTAAACTATCACAAGATTGAAAAGACTTGACAGTTTGGAAGCTTGTCTTGTCTTTCTCAGTAATCATTGATCTTTACATGTTGACCTTATATTAGCAATGAACAGATCATTGCCTCTCCACCCAATCATGCTATTTCTTTAAATCAGTATTTGGGGAATGCAAGCATTTATGCAGTGGTTATAAACAGAAATATAAGATTTGCCAACCTGTCTCTTTAAATTACCATCTCTCTGAAATCCTCAAGGAAAGCATTTTCCCTTTACTTAGTAAGGGTTTCAGATTCACTTTATGGGCTCCTGCTGTCTTCAACACTGATAAAACTTTAACCAGAAAAGCATTAAACACAGCACAGCAGCCCCTAGCCCAGATCCCTAAGTTCCTAGTGGCAGCATTTATCAATGTAAGAACAAGAATACTTTCTGTACTGGTATCAGCTTCGTCCTCAAAGCTATGACCTCTTACTTGGCCTTGTGCCCCATAGTGAACGAAGCTTCTTGCCTTTCCAGGTCAGTGTGAGTTAAGATTGTCAGAGTTGTATGTGTCCTGACAGACTGTGGACAGCAGGGTTTGCCCAAATCATCAAGTGATACAGGTAATGAATGTCTCTAAAATAAGTTGGGTCCTCCAAACAAGTCCTGGATACCTTCTGAATGTTAAGTTTCTGAGTGCTGAGAGTAATTTGTTCATTGGTTTGGTTTGATACCGTTATATCTATCTAGGGCAGTTCCAAGAAGTGCTTGACTTCTCAGCTCTAACAGCCAGTAAGAGTAAGTAACCTTAGTACAGGCAATGAGCCTCTGTAGATGTGCAGAGGACAAGTCACTTGTCTGTAGTTGCTAACAAACAATGGAACCAGTTTTGAGCACAGCACTCCCTGCTCTGCAGTCAGCCCTCTGCCCCACACCATGACTCACCTACAGATTGAGAGAGAGAAAGGCTTTCAGTTCCCCCAGTGTAGTATGCCCATTCACACTCGGAATTCTTTTTCAAAGACATCAAGATGGCCTTAGTACTCTGCTCTAGTAGATGTTGTAAGTATTCATTGTTCCTTCCAGGAGCTGGATTTTTGGTACAGTCCCCACAAAGGAAAATAAAGGCCTTCAAGAGTGTAAAGTTTTTAGACAGAGTTGGAGGTAATGGTAGTCTTCTAACATTATCTAAATATCTCCTGCTTCATTACTATAGAAAGCAACTCTTCATGTTTTAGGAAACCCAGCTACCATGTTTGTACTCTGAGAAGGTGCCAATACAAATCACTAATTTTGGACTCCCTTCCTGGAGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTAAATGAGAATGAGATTTGTACACACCCACATATTCTATACCACTTAATTAAGAGTTAAGTGAAGTTCAAAGCAGCCCCTGGTGATCTTACTTAACACCACAAAGTTTTCTACTAGGTCCATGAAAGTATAAACAGATAATTGGAGTGTGACTGCTGGCTTTCCAGAATAACCCACTTGTGGTAGATGTCAACTCTTACAGCTCCAAGCCAAGGTGACGACAACCCAGCCCTCTTCCACCATGTCTAATAACATGGGACATGGTAGATGCCTTGTCATTTGGTGACCTGGATCTGGGCCCGAGTTTAGAGCTGCAGAATTTATAACCTTGTAGTAGTCAGTGGTCTAAGAAGTCCTCTCTCCCCACAGAGAAAATGTCTTGCTGATTCCTGATATTCTACTCTCATAAGCTGTTCAGTACACACTTCTCAGTCAATTGGTTGCTTGTTTACTATGTGCTGAGCACATCTAGATTTTTTGTTTGTTTAAAGTTAAAAGTCCCATTATAAATCAAGTCTAACCCTGCCCTAAGAGAAAAGACCCACAGAGACTGCACATCTCACTGACGCTGCCTTCACCCATTAGTGTTTGAGGCCCACCATCCTATGGAGCCAGGTATTCCCACATCATTCAGATCACTGGTGTTTCCCATTACTGTTTGAGGCTGAGCAGAAACACTAACAAGGACCAGAGCAGGAACGGGAAAATAAATGAAGACACTTGGAGTGCACTGTTGAGAAAATAGCCAGAGTCCATGCTGGGCTTGATGTGGCTTTAGGGGACCAATCATATATACTTTATGGAAGTTAAACCTGACCAGTCTTTACAGTGACAGGCCACAGCGCGTGAGTGGGTAGAACCAACAAATCCATTGTCTTCTGCCTGTTTTTGTGTGCACAGTCACATTCCCTCCTTAGTCATCTTCCCCTTCCACTCTTTACACTAAACAAGGGAACACTCAATCTTTCAAGGGAATTACATATCTGAGTTAATGTTTCAGTATATCATTTTCATACTGTAAATTATTTTGTAAGAGAGATTTACTGCTATCCCAGGATGTTCGGACTTGGCGCCCCTGTGCATTTGGAAATCAATAAACTATTACTGGAAATACC
->URS0001E92C0D rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAGCGACGCTCTTCCTTCGGTGAGGTGACGGAGCGGCGAACGGGTGAGTAACACGTGGGCAACCTGCCCCTAGCTCTTGGACAACACCGGGAAACCCGTGCTCATACCGGATACGGCATCGAGCGGCACCTCTCGGTGGGTAAAAAGTTTTCGGGTAGGGATGGGCCCGCGGCCTATCTGCTTGTGGGGGGGGGGTTGTCGCACCCAGGGGCGGACGGGGGGCCGGGCTGGGAGGGCGGCCAGACAGACAGGGACTGAGACACGGCCCAGCCTCCGACGGGAGGAGGGAGGGGGGAAGATTGAGGAACGGGCGAAAGCCGGACGAAGCGAGGCCGCGGGAGGGATGCCGGCCTTCGGGTTGTAACTCTCTTTAAGCAGGGACGAATTCAGACGGTACCTGCAGAAGAAGCACCGGCCAACTACGTG
->URS00002FCF40 rRNA from 1 species 
-TAAGTCACTTTGTCTTAATGGCAAATGTGAGATGCAGTGTATGGAATATCTTAATATCTAGTATGAGAAATTAACGATTTAAGTCCTTCTTAAAAGAGGCCATTTACCCATAGAGGGTGCCAGGCCCGTATAACGTTAATGATTACTAGAAAGATATTTCCAAAGAGTCGTGTTGCTTGATAGTGCAGCACTAAGTGGGTGGTAAACTCCATCTAAAACTAAATATAACCATGAGACCGATAGTAAACAAGTACCGTGAGGGAAAGTTGAAAAGAACTCTGAATAGAGAGTTAAATAGTACGTGAAACTGCTTAGAGGTTAAGCCCGATGAACCTGAATATCCATTATGAAAAATTCATCATTATATATGTAATATTAATTGATTAATATTATAATAATAGTGTGCATTTTTTTCATATAAGGACATTGTAATCTATTAACATAAAAAGTATTTATCAAAAGATCATTGGCTTTAAGTTTATTTTAATTAATTTGCTTTATTGCTTTTTAACATTAAATAAATGCCTAATGATTTGATAAAGTGTTGATAGATTTATTATATATAATGCTTAAATTCATTTTGAATTTTACAATAATGTTATAAACATTGATTTAAAAATTAATGTACGTNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNCTTGAAACACGGACCAAGGAGTCTAACATATGTGCAAGTCATTGGGTTATATATATAAACCTAATGGAGTAATTAACTTAACTAATTTAATGGGATTAATTTTTAGTCTATTTATAATAGTCTATTAATTCAATCCCGGGGCGTTCTATATAGTTATGTATAATAATAATTTATTATTATTTATACCTCTAACTGGAGCGTACCTTGAGCATATATGCTGTGACCCGAAAGATGGTGAACTATACTTGATCAGGTTGAAGTCAGGGGAAACCCTGATGGAAGACCGAAACAGTTCTGACGTGCAAATCGATTGTCAGAATTGAGTATAGGGGCGAAAGACCAATCGAACCATCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGTGCATTTATATATTATGTAAAATAATCTTATCTGGTAAAGCGAATGATTAGAGGCCTTAGGGTCGAAACGACCTTAACCTATTCTCAAACTTTAAATGGGTAAGAACCTCACCTTTCTTGATATGAAGGTTGAGGTTATGATATAATGTGCCCAGTGGGCCACTTTTGGTAAGCAGAACTGGCGCTGTGGGATGAACCAAACGTAATGTTACGGTGCCTAAATTAACAACTCATGCAGATACCATGAAAGGCGTTGGTTGCTTAAAACAGCAGGACGGTGGACATGGAAGTCGTAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAAGCAACTAGCCCTTAAAATGGATGGCGCTTAAGTTGTATACCTATACATTACCGCTAAAGTAGATGATTTATAATACAATTTCGATTGAATTATAAATTTTGAAACTTTAGTGAGTAGGAGGGTACAATGGTGTGCTTAGAAGTGTTGGGCGTAAGCCTGCATGGAGCCGCTATTGGAACACATCTTGGTGGTAGTAGCAAATAATCGAATGAGACCTTGGAGGACTGAAGTGGAGAAGGGTTTCGTGTGAACAGTGGTTGATCACGAGTTAGTCGGTCCTAAGTTCAAGGCGAAAGCCGAAAATTTTCAAGTTTTAATGCAAAGAAATAACCAAACAATTAAAAAAAAAAAAAGAAAAAAGTAAACTTAAAGAAAATGAAAAGAACAATTTTAAAACTTTATTAATAAAAAAATAATTAATTACTACTATGTTTTTTCATTTTTTGTTTAACTTTTTTTCTTTTTTTTTAAATTGAAATTTTTGAATTTTTAAACACTTGAATAATTTTGAACGAAAGGGAATACGGTTCCAATTCCGTAACCTGTTGAGTATCCGTTTGTTATTAAAAATGGGCCTTGTGCTCATCCTGGCAACAGGAACGACCATAAAGAAGCCGTCGAGAGATATCGGAAGAGTTTTCTTTTCTGTTTTATAGTCGTACTACCATGGAAGTCTTTCGAAGAGAGATATGGTAGATGGACTAGAAGAGCATGACATTTACTGTTGTGTCGATATTTTCTCCTCGGACCTTGAAAATTTATGGTGGGGTCACGCAAACTTCTCAACAGGCCGTACCGATATCCGCAGCTGGTCTCCAAGGTGAAGAGTCTCTAGTCGATAGAATAATGTAGGTAAGGGAAGTCGGCAAATTAGATCCGTAACTTCGGGATAAGGATTGGCTCTGAAGATTGAGATAGTCGGGCTTGATTGGGAAGCAATACCATGGTTTATGTACTCGTTCTGGGTAAATAGAAAATTTCGATTTTTGTTCCCCGGATAGTAGTTACGTAGCCAATTGTGGAACTTTCTTGCTAAAATTTTTAAAGTTATATACATTTAATAAAATGTATATTCTTTTTAAATTATAACGATTATCAATTAACAATCAATTCAGAACTGGCACGGACTTGGGGAATCCGACTGTCTAATTAAAACAAAGCATTGTGATGGCCCTAACGGGTGTTGACACAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAAGTAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCACTGTCCCTATCTACTATCCAGCGAACCACAGCCAAGGGAACGGGCTTGGAATAATTAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCTGGCAGTGTAAGGAGACATAAGAGGTGTAGCATAAGTGGGAGATATATAATTTCGATTATTTATCACCAATGAAATACCACTACTCTTATTGTTTCCTTACTTACTTGATTAAGTGGAACGTGTATCATTGCTTAGCCATATTAAGGATTTATTTATAAGTCTTATGGTATTGGGTTTTGATGCAAGCTTCTTGATCAAAGTATCACGAGTTTGTTATATAATTGTAAACATATTTTAATGAAATGATAACATTTCGGTGTTATTATAATAATTAAAATTTGGTATAACTCCAACACTCAGGTATGATCCAATTCAAGGACATTGCCAGGTGGGGAGTTTGACTGGGGCGGTACATCTCTCAAATAATAACGGAGGTGTCCCAAGGCCAGCTCAGTGCGGACAGAAACCACACATAGAGCAAAAGGGCAAATGCTGACTTGATCTCGGTGTTCAGTACACACAGAGACAGCAAAAGCTCGGCCTATCGATCCTTTTGGTTTAAAGAGTTTTTAACAAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCGGCCAAGCGTTCATAGCGACGTCGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAAAATTCACCAAGCGTTGGATTGTTCACCCATTCAAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTAATGACAATTATTATTGCGACAGCATTCCTGCGTAGTACGAGAGGAACCGCAGGTACGGACCAATGGTACAATACTTGTTCGAGCGAACAGTGGTATGATGCTACGTCCGTTGGATTATGCCTGAACGCCTCTAAGGTCGTATCCGTGCTGGACTGCAATGATAAATATGGGGCAATTGCATTGTATGGCTTCTCTAAACCATTTAAAGTTTATAAATTTTATTTATAAACGACAATGGATATATGTGATGCCAATGTTATTTATAACATAGCAAATGCGGGAGGATCAAATATCACCTGTATGACGCGCTAGTTATATATAAAAACATTATTTAATACAATGACAATGCCTAGAATCAATTGTAAACGACTTTG
->URS0000ADD968 rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCCTTACACATGCAAGTCGAACGGCAGCACGGGAGCAATCCTGGTGGCGAGTGGCGAACGGGTGAGTAATACATCGGAACGTGCCCAATCGTGGGGGATAACGCAGCGAAAGCTGTGCTAATACCGCATACGATCTACGGATGAAAGCAGGGGATCGCAAGACCTTGCGCGAATGGAGCGGCCGATGGCAGATTAGGTAGTTGGTGAGGTAAAGGCTCACCAAGCCGTCGATCTGTAGCTGGTCTGAGAGGACGACCAGCTACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGCAGGATGAAGGCCTTCGGGTTGTAAACTGCTTTTGTACGGAACGAAACGGCCTTTTCTAATAAAGAGGGCTAATGACGGTACCGTAAGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTATGTAAGACAGTTGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCTGTGACTGCATAGCTAGAGTACGGTAGAGGGGGATGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAACACCGATGGCGAAGGCAATCCCCTGGACCTGTACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGG
->URS0001CBEDC2 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACAGATGAGGAGCTTGCTTCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATATTGAACCGCATGGTTCAATAGTGAAAGACGGTTTTGCTGTCACTTATAGATGGATCCGCGCTGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACATATGTGTAAGTAACTGTGCACGTCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTG
->URS00020C5C01 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTTGAGCGATGAAGATTGGTGCTTGCACCAATTTGAAGAGCAGCGAACGGGTGAGTAACGCGTGGGGAATCTGCCTTTGAGCGGGGGACAACATTTGGAAACGAATGCTAATACCGCATAACAACTTTAAACATAAGTTTTAAGTTTGAAAGATGCAATTGCATCACTCAAAGATGATCCCGCGTTGTATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCGATGATACATAGCCGACCTGAGAGGGTGATCGGCCACAGTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGACGAAAGTCTGACCGAGCAACGCCGCGCGAGTGAAGAAGGTTTTCGGATCGTAAAACTCTGTTGGTAGAGAAGAACGTTGGTGAGAGTGGAAAGCTCATCAAGTGACGGTAACTACCCAGAAAGGGACGGCTAACTACGTG
->URS00025F86BA lncRNA from 1 species 
-TGCGAATCATAGACGGCGCGACATCATAGTCTTCCCTCATGGCAGCCTTTTGGCGCGAAGAAAAGGAAAGTTTGAAAAAATTACCATATCTTTGAACTGTTTTAATAAAGCAAGAAATTATATTGTGCAAATCTGGATGCAAGATAAAGAAACTCTTTGATTTTGTTCATTCTACATTATTTATCAGTTGAAGATCTGTAGTATGATGACACCGTCGATGGAATGTTCGATCAAATCTTTCTGGGTCTTGTCCGTTAACAGGAGCACGGAGATGTGAAGGCATGGAAGTGGGGATGATGTCCTTAAAGAGGCACGGTATTAATCCTGGAGGACTACTTTGGTGGACGGACGTTGGAAGACAACTGATTTCAGGTGTTTTTTCCGTTTTCTCTTGTTATTCCTCTTGGGTTTTTTCCATGAGGTCAGGTGGTTGTTGTTAATGGTCTGGCGTCCAATATGAGCACTCTATCGAAAGTTCCGGGTGACACATCGCTGACTAGCTGGATCCTCCTCAACAAGGAAACAACTCCGTGGGAAATAAATTTTATGGCTTTTAGCCTAACTTGATAAAACGCTCAAAGTTAAGAATTTTTTTAATAATGAAAGTTTAAAATAACACTTTATGGGGAGTCTGTCCCTCACATATATTTAATAATATATTAATTTGTTTAGAGACAGATTAACAACTTGCCTATGATAGAGATTAAAGTATAAATAACTGGAATTTTCATTTTACTTTCATCATTGAAAAAAAACACTATATACATCATGAAAACATTTATCATGGTTGATTAGATTTTTCTATTAATTAAATATTGAAAAATTACTCTTCAAAGCTTTTCCTTAACATATGATTAGTAGCAGTGGTTATTTTTGTGTTACTTGAGTCATTATCAGTTCAGTTTATGTTTAATTCATTTACCTTTCTTATTTTGCTGACAATTAAGTTATCTCTAGGAATGGATCATTTTCATTTTTCTGCTAATTCAGCTTTCTTTGGAAATGAAAATCCTTGTACTTTCGGTCCAGTCAGATAGTTGCCTTTACGCAGGGGCGCCACTAGCTGTTTGAACGCCCGCGTGCAATACCGATTATGTTGCCCCCTGTTTAACTACGATTACTTATGCTGAGCTTGCCAGAAAGGCTCTTTGCCGCCCCCTGGACGTGCCGCCCGCGTGCGGTGCACGTCTTGCACGCCCGCTTACGGCGGCCCTGCCTTTACAATCGGTTATACAGCACTTGTATGGGCATTTTGCATGACCTTATCACATTTACAAATCCCTAATATTTATAAAATGCTTTTGTAACACAGTCAACAAACAAAAAAACCCAAATATTCTAAGAAAATTATCCAATATTTCAATTTAATTACAATAATTGAAAGCATGAGAACTTAACAGCATATGGCTACTATTGTAATAGACAACAATTACCCCATGAGCACTCAGGCCTGATTATGTAGGTGGCATTAATTAGTTTTACCTTTAACATGGAGAAGACCTCATGCGTCCACTTTTGTTAAAGACATGGTATGCACCTTGATCCTGAAACTCACTGAAATGGGATTAAAATTCCAATAGTCAATGAGGCCATGGCTATCAAGGCCTGTTCTTAGCTTCTTGATCCCATTGGAGTGTGTCAAGGCAGTTTCATGATAATGTTGATTAGGGGCTGTTACAGACCATGGAATATCATTTATTACGTATGAGTTAGAGTGGAAAAAAATAAAAAATAATTTATTGTCACACTTATCTTTCAAAAGTCTATGTCATATCTATAAGACTGTGATTTTATTTAACTATTCTTGAGAAAATTTATTATTTTTTGCTATTAAAAATATAAAATAGTAAAAATATGCTTTACTCAAAAACTCATTTGCACATGTATGAAGCCAACTGCATTTAAAGGAAAAAAGCTTCATTGTTTTTTTAAAGGAATAATTACATAATAGATTAAGATATTTTTAATATCTTTCTTGTTACAGGTGTATGGTTTGTTTACACTTTTATTTATCTTGTCACTATTTTTTTGGCAGTGGTTAAGAAGTAATATTTTACATAATCTTGAAATTAATAGATTGGTGATTTCTTTTGGGTGAGTCTCCCTGCCACATCCACATTGAAGCCAAGGGATGAGACACACACAATGCTTTAGTTGCATTCTCAATTTAAACAAAATTTTTTGTTGCATTGGTAATTTGTCTATGTGATTTTTCACAGCTAGGACCATTCCAGTAAGTCTGAGTTGAGGATAATGGAAGCTTCTTGTCCTGAAATCTAATCATGTCGTTTGTTGATGATGATGTCTGGCTCTCTATAAAATTTTCTGTAGCCTGTCTGCATTTGTGTGTCTAGCACAACATGACACAGATAGCCTGCTACTATACCAGTGGCCCAGAAAAGTGAGATATAGGGAAATAACATTGAAAATCAACCAATATAAAATTACAACTGCCTGACTATTTAAAAGGCTACTGATGTTCAGCTTGCATTAATTATGAAAATTGAAACTTATTGGTTCAAGAATTATTAAGTTTCAATAGGTAAATGTTAAAAACAAAAAAAAATCTACTAATCCATGGATATAAAAAAGAATTTATTTTAAA
->URS0001859E2D rRNA from 1 species 
-TACATGGGGTGCAAACGTTGCTCGGAATTATTGGGCGTAAAGCGCGCGTAGGCGGTTACTCAAGTCGGATGTGAAAGCCCTCGGCTTAACTGAGGAAGTGCACCCGAAACTGAGTAGCTAGAGTACCAAAGAGGGTCGCGGAATTCCCGGTGTAGAGGTGAAATTCGTAGATATCGGGAGGAACACCGATGGCGAAGGCAGCCCCCTGGGTCAACACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGG
->URS0002165809 rRNA from 1 species 
-GGGGAACCGCCTGAACTGAAACATCTAAGTAGGGCGAGGAAGAGACATCAAACGAGATTCCGTAAGTAGTGGCGAGCGAACGCGGAAGAGGGCAAACCGAAGGTAGAAATACCTTCGGGGTACGGAGCGCATTTAAGACTCAAGTTGTTAACCGAACGGCATGGGAAGGCCGGTCAGAGAGTGTGAGAACCACGTAGGTGAAAACGGAAAGAGCTGCGCAGATTCCAGAGTACGGCCAGACACGTGAAACCTGGTCGGAAGATGGGGGGACCACCCTCCAACCCTAAATACTACCCAGTGACCGATAGCGTATAGTACTGTGAAGGAAAGGTGAAAAGCACCCCGGGAGGGGAGTGAAAAAGAACCTGAAACCCTGTGCCTACAAGCACCTAGAGCACGTCAAAGTGTGATAGGGTACTTTTTGTAGAACGGTCCGGCGAGCGATTGTATGCAGCAAGGTTAAGGACTTAAGGTCTGGAGCCGAAGCGAAAGCGAGTTTGAAAAGGGCGTTAAGTTGCATATAATGGGCCCGAAACCGGGTGACCTACCCATGGTCAGGTTGAAGTGGAAGTAAAATTCCATGGAGGACCGAACCGACCTCCGTTGAAAAGGCGGCGGATGAACTGTGGGTAGCGGAGAAATTCCAATCGAACCCGGAGATAGCTGGTTCTCCCCGAAATAGTTTTAGGACTAGCCTCAAGTTAGATACCTGGAGGTAAAGCACTGAATAGCCTAGCGGCCGAGAGGTTAGCGAAGCTTATCAAACTCAGAATGCCAGAGTATTGATGCTTGGGAGTCAGACAGTGTCAGATAAATGTCATTGTCAAAAGGGAAACAGCCCAGATCTACAGCTAAGGTCCCAAAGTCAGGTTAAGTGGAAAACGATGTGAAGATACGCAGACAACCAGGATGTTGGCTCAGAAGCAGCCACTCATTCAAAGAGTGCGTAATAGCTCACTGGTCGAGCGTCTTTGCGCGGAGAATTTAACGGGGCTAAACCTGACACCGAAGCTTAGGCAATCCAGTAATGGATTGGGTAGGGGAGCGTTGTATACGCGGAGAAACAGTAGCGTAAGCGGCTGTGGAGTGTATAGAAGTGAGAATGCCGGAATGAGTAGCGCGAATGCAGTGAGAATCTGCATGGCCGAAAGCCTCAGGTTTTTGGAGGAAGGTTCGTCCGCTCCAAGTTAGTCGGGAGCTAAGGTGAGGCCGGAAGGCGTAGCCGATGCACAGACGGTAGAGATTCCGTCACCACCAAAAGAGTTAAGCACAGGGACACATTTGAAGTCTCAGAGCCGGGTGTTGGTTCCGGTAGAGATCGAGGGAAGTTAGTACCGAAGTCTGGGATGGAAGATGGCGAGAAAAGCTGTGTGTATTTCTGAGGTGCCCGTACCGCAAACCGACACAGGTAGGTAGGAAGAAGATTCTAAGGCCAACGGGAGAAGGGTTGTTAAGGAACTCGGCAAATTGACCCCGTAACTTCGGGAGAAGGGGTGCTCCAGAGATGGAGCCGCAGAGAATCGGCCCAAGCAACTGTTTACCAAAAACACAGGTTTGTGCTAAATCGAAAGATGACGTATACGAGCTGACGCCTGCCCGGTGCTGGAAGGTTAAGAGGAGATGTGCAAGCATTGAATCGAAGCCCCAGTGAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCAGGTAAGTTCTGACCCGCA
->URS000003CBAA rRNA from 1 species 
-GTTTCTGCTCAATGGAACTCTAAATAGCCGCAGTACTCTGACTGTGCAAAGGTAGCATAATCAATTGGCCTCTAATTAAGGTCTGGAATGAACGAACTTATGGGTAGCAACTGTCTTAAAATAGTTAATTAAATTGATTAATAAGTGCAAATACTTATTCAGTTACATTAGACGAGAAGACCCTAGAAACTTATAATTATTTTGTTGGGGCGACAGAATTACATAAAAACTAATTTTATTTTACAAGACGTAAAGCAGAAAGAAAAAGTTACTCTAGGGATAACAGCATAATTTTTAATAGCTTGTGACCTCGATGTTGGACTAGGTAGATAGTTTTTTAGAAGAAAGCTTTCTTGGCTCTGTTCGAGCAATTTTAACCT
->URS0001415BDF rRNA from 1 species 
-TACGGGGGGGGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGTTCGTAGGTGGCTTGTTAAGTCAGACGTGAAATCCCTCGGCTCAACCGGGGAACTGCGTCTGAGACTGATGAGCTCGAGTGCAGGAGAGGAACGCGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAACACCGGTGGCGAAGGCGGCGTTCTGGACTGACACTGACGCTGAGGCGCGAAAGCTAGGGTAGCAAACGGG
->URS00008DF9B1 rRNA from 1 species 
-ATACGTAGGGAGCAAGCGTTATCCGGATTACTGGGTGTAAAGGGAGTGTAGGCGGGAGTTACAAGTCAGATGTGAAAACTGTGGGCTCAACTCACAGATTGCATTTGAAACTGTAGTTCTTGAGTGAAGTAGAGGTAAGTGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACATCAGTGGCGAAGGCGACTTACTGGGCTTTAACTGTACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGATTACTAGGTGTGGGGGGACTGACCCCTTCCGTGCCGGAGCAAACGCAATAAGTAATCCACCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAAGGAATTGACGGGGCCCCACAAGCAGTGGAGTATGTGGTTTAATTC
->URS0001F9E606 misc_RNA from 1 species 
-AAGTCGTAACAAGGTAACCGTAGGTGAACCTGCGGTTGGATCATTAAAAAAAATTGAAGCTTCAACCCTTTCAAGGGTAGAAGCGTCAGTGCTCCTCTAACAAGGAGCTTGACTACTCCAATTTTGTGAACTTGCAACCAAAAAATGTTTTGATAGTGGTGAAAGATTTGGGCATTACCCGCCCAAGTTTTTCCCTTCTTGAAAAAATTGTTAACCCTGAAGAAATAACTTGTCTTTACCGTTTTTTATAAATAAAAATTAATAAACAACTTTTGACAACGGATCTCTAGGCTCTC
->URS00023BEA17 lncRNA from 1 species 
-GTAAAGGCTGCACAGGAATCGATGGAAGATGCTTGAAAAGCCTCATTCCCAGAAACATCTCCAGCTGCTTTTGCCGTGAACTATCAACCATTGCATTTTTATATCTTCTCTGTAAGGTAATTTTCATGTTTTTCTGTGCTGCAGAAAACTGTTTAAACGCTCCTGACTCTTCACTGAAGATATTGAGAACTTGGCTGTGCATAGCTTTTGAGCCAGTATAGAGAGTTGCATGGATATCACCTTGTTGCAGAAAAAGATCTGCGAGCTCAGACACAGGAGACAAGATAGTTGATCTCTTAAACTCCTCAAACCTCATGTCAAGTCTCTTCCATGGTTTATCAGGACATGGATGACTCCATGTTGTTGTCTTAGTATTGTGATCAATAAAATAAGATTTTCCAGTGACTGCATCAGCTCTTTTCTCCCATCCCGGTGGAAGCGGAGCAGTATAGCTACTCCCAGAATTATAACCATATCCAATATCAGTATCAAGTGATATCCCCAGCCTTCTACATTGCTCAACGAACACTTGAAGACCTATAGAAGTAGCAGAGCCATCAGCAAGACTTCCACCTCCATTCGCGTTGTCCCTGGAGTAGGATTTTGAAAGCAGAACCGCTCCTCTTCCGGCACAACAAGACTTGCAAGCTTTCTTCCTACACTGTAAACATAAGAACACTGAGCCTGGCTCTCCCCCCAAACTCTTGGTAGTAGATCCAACTGAATTTTTGTTGACCTCGGCTCTGACTTGACACACTCCACCGTTACAACCCTCACCAATTCCGTTAATATTCCAGAAATCTATCACACTATTTTCCAGCTTCTCTAAATCAATAGAAGCTATAAGTTTATCTTCAAGAGAAGCCTGGCCAAGAACTGCAAGTGCATTTGCTATTCTGCATAATCTTCCAATATATAACTCGTCGTGTGAAGAGTTCGGATTAATTGTAGCAGGATCAATTCCAATTGATAACAGTGCCCTATCTCTTTCTGCTGCAGAAATATTCAGACGTAGCCGTTCAATTTCAAGTTTAATAGCTTCTATAAACTCAAGCTTCCTTCCCTGTATTATAATAGACATGCAGAAATTAAGTTTACAATTAAAATGGCAGTTTAAGAGGACATATAACATCTGAGATGAATAGCTGAACCAAGAAAGGAGTCATAAGATCAGAAATGGTATGTGACAAGATGAAGTAACATACCATGTTTGGACCCATAACGGACTTCAGACAATTTAAGTACAGATGAGAACCACTCTCTCTAGAACTTTTATCTTGTGAAGAAGACATGCTGGGAACAGTTTCAGGACCACTATATTGAACAACTGCTTGGTCTAAGAAATCAAGCATGTCATTTCCTCCACTTGCAACACATTCCACCGCTGGTTGTGGGAAGGGGTCAGAAGCAGAAACCTCTCCTGTCAAAAGGTCAAGCAGATTACTAGGAAACGGATCATTCTGTTGTACTGGTGTGGACACAGTTTCAGCCTGTAAAGATTTTGCGGCAAAAGGATTCGAGTCAGAACAAGATGAAAAAGGAACTTCATCTTCTTTTGTTTTCCCTGCAATCTCAGCCAATCTTCCTCCGGTACGTTCGCTAGTAAACATTCCTTTCCATGGAAGAGAAACTCCAAGGACTTCTATCTGTATCACAAACACAATGCAGAAGAAGTTTTGTTTTAAACTGTTTTGCTTTCATGTTGGCTAGTCATACTATTAGATAAATCATTAATTTTAGTCCAGAAAGTAGTTATTACCTGACCAAGAGTCATGGGGATTTTAAGAGAACCAGCTGGATAAAATGTAACAGAAACTACACGGGTCAAGAAATCCAGTTGTCCTTCTAGTTCTTCAAAATCATACAGCAGTGAAAGACTTGACGTATCTTTTTCATGGAGACGCGCACCAGCTCCAGTAATAGCAATATCCTCATCACGAATTGGCCCTGGTAAGGGTATCAGAAGATTTGTACCATTCGCACACCGCGGTATCGAAGCATCCTGTCCAAAAACCAGAAATACAGACAATCGTCATCCAGTTGAACTAGCTTGCATGCACGTCTACATGATACAATAAAAGAGAAGGGACAAGAGAGTCAGTCAACCTGAACAACTAATTTAAGGTCCTCTAAGTGGCGTCCAGTTTTCACGTTCACAGTGGATGGACATGTCAAATCATCCGCACCGTGTGATATTGTCAGTACAAGTTGACATACATGGCAAGGCTCACTGAGGTAGATAACTAACTCAACAGCATCTGCAGCTTGTGGACATAGCTGCAAAGTATATAAAAAGCAGGGGAAACTTTTAGCTCAAATTTTTGAGGGATGAGAACAAAGAGGTAATGTTTTATCCAAAAGGAGGTACCCAAGTTATGTCCTTCGTCTTGATACTCAGCAGACTGGACCCATCATTGGAAGTCTCAGACATGCTCGGTACAGGTTTCAGAAAGAAACCACCTGGCCGAGAAAGTACCTGACATGAAAAAAAGTTCCAGTGAGCAGTAACATTAACATAGCTGCAGTGAAAAATTGTATTAGTTTGCTTACATGTAAAGGCTGCACAGGAATCGATGGAAGATGCTTGAAAAGCCTCATTCCCAGAAACATCTCCAGCTGCTTTTGCCGTGAACTATCAACCATTGCATTTTTATATCTTCTCTGTAAGGTAATTTTCATGTTTTTCTGTGCTGCAGAAAACTGTTTAAACGCTCCTGACTCTTCACTGAAGATATTGAGAACTTGGCTGTGCATAGCTTTTGAGCCAGTATAGAGAGTTGCATGGATATCACCTTGTTGCAGAAAA
->URS00000FB6E5 piRNA from 1 species 
-TAATAACAGGTCTGATTGCTTCATTAAC
->URS00021C6D14 lncRNA from 1 species 
-CTAGATTTAGTTTTATCTGATATTAACAAAATTTCTGATAATATTATTTGTTGTTTGAATAAAGCACAAAAGTGCTGATTTTATGAGAAAAAAAATCCATGTAAATATCTTATTGAATTTAGATTCATTTGAAATCGAAGTGAAACATAACTGATGTTTACATTTGTGAAATTAGCTTTTGTGCATAACTGAAATTCACAAATTAATGTTTATTAAGTAGATGTACACAGTTATGTGGATATATTTGATTGGGCGAGTATTCATATTGACTTGACATGCAGATAATTGTTTGAACGAATTAATGTATTGACCGGAGATGTAGATAAATGTTAGGACGACTATTTAATGATTGGACGGATCTATAAATGAATTGACGAATGTATATACTGATTGACATATACAGTATAATTGGATGAATATATAAACGAATTGAAAGATATTTGAACGATTGACAGATGAATAAACGATAGACTGATATATGTATGATTAACGGATACGTTCATGATTGACGGATATATACATGGATAGACGGATATATAAATGATTGACAGATACATGTATATGCATGGCTAGACCGTTATATAAATGATTGACGGATATATGCATGGATAGACGAATATATAAATGATTGACGGATATATGCATGAATAGACGGATATGAAATTGATTTGAATGGTTTTTGAATGATTTGACGAGTATATTAAAAATGATTGAATGGTTTTTGAATGATTGGACGAGTATATTAAAAATAATTGAATGGATATATTTTTGATAAGATGGATATATGAATGGGAATTTGACGGATATATGACTTGACAAATAGATGCATGATATAACGGATATATGATTAATTTGACGGATACATGATTAATTGGACGATTTATAAATAATCGGATAGTATAAACCTCGATATGGGCGATATATTCATATACATATATTTGTTAAATGCTAGATATTATATATCATTCATCGGATGGATATTTTTTGTTTGCAAGGACTCATGATTGAGTAAATGATATTTGGTTATTTGTAAGAAATCCTTTTTTTATTTTTACGTTGTACGAGGTAGTTGCTTATAGTTTTAATATGTTTTTGTATGTTTTTTTGTTATGTTTTT
->URS00000D240F rRNA from 1 species 
-CGTGTAGGCGGCCAGGTAGGTCGGTTGTGAAAACTGGAGGCTTAACCTCCAGACGTCGACCGAAACCATCTGGCTAGAGTCCGGAAGAGGAGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCCGTGGCTAAGGCGGCTCTCTAGTACGGTACTGACGCTGAGACGCGAAAGCGTGGGGAGCGAACA
->URS000210495B rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCGAGTCGAGCGAACAGACGAGGAGCTTGCTCCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATATTGAACCGCATGGTTCAATAGTGAAAGACGGTTTTGCTGTCACTTATAGATGGATCCGCGCCGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCTTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACAAATGTGTAAGTAACTATGCACGTCTTGACGGTACCTAAGCAGAAAGCCACGGCTAACTACGT
->URS00023FD586 lncRNA from 1 species 
-GGAAGATCCAGCCTCGACAACGGTGGAATTCGGTAGAAGGTCACGGAGGTCAGTGAAGCTTCGCCGGTAGTTAAAACCAGAGGAATGTTCTAGAAACTGCAGAGGAGACGAAGGAATCGAATCCGTCTTGTGAACTTCCTCTTCCTTAACACCCTCCGTAATAGCTTTGTTGTTGTTGTTATCTTCTTCACCGTTTACCTTAGCTTTGATTTTACTAATCTGCAACCAAAAACTTTAAAAATCAAACCTTTTTGCATTTTCGTCTCTGAAGTTTCAATTTTTATGGTTTAAAGTCTCTAATATTGTACCTCTTGGAGAAGGGAATCATTGTCACGGCGGAGAGAATCGAAATTGTGGCGGAGAGAATCGTATTGACCCTTAAGAACACCGTAATCTTTTTCAAGCTGTTTTGTTTTCCACCGTGCACGACGGTTCTGAAACCAAACAGCTACTTGACGAGGTTGAAGTCCAAGCTCTTGTGCTAATTTAGTTTTCCTCTCAGGTTCGAGTTTATTCTCAAGTTCGAAATTCTTCTCAAGAGCTTTGACTTGGTCAACTTTTAATCTTCTCTTCTTCTCCGATAGACCCATGTGGTGGTGGTTGCCGGAATATTCCTCGATTAGTGTAGCATCTTCATCGTAACCTTCAAGCATAGATTGGTAATTACTTCCGTACCCTCTTGGACTCTGTTCATCTGTTGTGTAACCAAATGAATCTTGTCAATAAAAGAAACAGTGGAAAGTGAAGAAAGGATCACATGGGTTTTGTCTGACATTAGCAAAAAGTAGAAAGAACAAAGATGGTAATAAGAACCTGTAGAAGTGGAGATTAGACCACACATTGAATCTGAGCTGCTTAGTCTCTTCATGATGACACTTTAAAATAGTTCTACTCCAGCTTTTTCTTTATTATCAGAGAAATTCTTATGAAGTTTTGAAATTACAACAATGTTGTAAACATAATTGAGCTTCTTCACTTGAACAACAACATGAACAAAACGAGGAGACTTTAGAGGCTCAAATTAGAAAAAACAGAGAGAGGGATATGGATTGAGAAAGTCCAAAAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAAGCTTTTAATCTAGAGAGCAATGGTTCTTTTCAATATGAACAAGTTGGTTTCACACTTTCTCTTTCTTTAAATAAACCAAACTTATCTTTCTTTAAATAAACCAAACTTAGAGAAAGGGTTAAAATGTAACTAAGGTTAAGTTTGAACCAATAGTTATACGGCTTGGCTCGGCTCGGCTTAGAACAAGTGGTGGAGTCTGTGATACGTCACCGTATGGGTTTATTTTTGGTAATGCTTAACCTTATTTTTTTTAAGGGTGTTTCTATTTTCTTAAACTTAAAAATTCAGAGAAATTAATAAACAGCGGATAGTAGAGAGATACGTAAGATGCATTTAAAAAGTAGATTTTTAAAATATAACATCCTCTGAAAAACGTCAGAAGGTACGTCACAGAAGATTTGATGACAAAATGATAAACTATAATTTGTTTGTTGATTAATGAAACCAAATGTAATTTTCCTGAGCAAACTTAAAATTCGATAGGATAAGTTATAAAATTATACGGATGGCATATTTAATCCCATATATTAGATGTGGGATATATTATTAAAAACATTAGTGTTATATGTTATTGTTGGCAACGCAGGGGAGTGGAAAGAAAGACTTGTGGGTGGGGGAACAAGACTGACGCAATTTGGGTTTGGTTCATTGAATTGTCCAAAAACTATGGGCTCGAACGGCACCGTCAAAAAATATCAATTCTTGTTTTGAA
->URS0000538100 piRNA from 1 species 
-TGCTGGCTGCTGGGTGGAGCATGTAGGG
->URS0000D6DD09 lncRNA from 1 species 
-AACTACGAGTCCCGACGTGCCGCGCGCGGCATGCAGAAGCTTCACTGAGCGGGCACTGGAGGTCGCGAGCACGTTGCTAGTGGGCGCGGCTGGCGGGGCCGGGGGCGGCAGGGGGCTAGCGTCCGGCTGAGCCCGGCGGGTTCCTGCACGCGGACCCACGCTTTGTCGGGCTGCTCTGCTGAGTGACACCGCCGTGGCATCCGAGGAGCTGTGGTCCAGCCTGCGCGGCGGGAAGCGGCGGCGGCGGCTCCAGCGTCCTAAGAGATTGCAACACCTGCTCGGTATACCGTGACTTTGGGAGGAACATCTGTCACTGTGAAGTATCTGCGCAGTCATGGCTACATGTCCACGCCGCCACCCGTCAAGGAGTATCTGCAGGACAGGATGGAAGAGACAAAGGAGCTTATCACAGAGAAAATGGAAGAAACAAAAGATAGACTCACTGAAAAGTTACAAGAAACCAAAGAAAAAGTTTCCTTTAAGAAAAAAGTGGAATAAGGTGCCTTATATAGCAGTATAGAAAATTCCTGCACTTTAACCCTTTGGAAACTATGGGCAAAGATACATGTGTCTGATTATTTTTTTGGTTAGTTGCCGAAATATACTAGTTCTCTGAGGGTTAAAGAAGTAAAATACCTTTTTAAAGTTAAATATCACTAGAAAAATCAGTGTTATTACAAGGGAAGAAATGAACCCAGTTTAAGAATTTGCCATCAGTAGCAGTATTAAGCAGTGGTTAATGTCTTAGAAGTCAGACTTCTTTTTCAAGGTCTTCAGAACCACACTTGATTTCTGTTTTGTTGCAGCTGTAATTGACACATACTAGGCAGCTGACTCCTTGAATATCCAGTGTGACCCATAAAATAGTCTGTTAATACCGGATCTTAATTTTTATGTTATTCATTAAGATTTTAACTATATTCAGTACGTAATTTGGAGACAAACTAGCATCATCAAAACTGCCTGTAAATAAGGTGTTTAGTCTTTCTATAAAAACAGAATAGAGCAGTTACCTACCAGTTAAAATATCTTATATGAAGAAAATAGAATAAAGATCCAGTCATATATGTAAATAAGATGTACTGATTGTACGTA
->URS000037851E rRNA from 1 species 
-TTCAGAGGGGGACAACAGTTGGAAACGACTGCTAATACCGCATACGATCTGACCTCGGCATCGAGGATGGATGAAAGGTGGCCTCTATTTATAAGCTATCACTGAAGGAGGGGATTGCGTCTGATTAGCTAGTTGGAGGGGTAACGGCCCACCAAGGCGATGATCAGTAGCCGGTCTGAGAGGATGAACGGCCACATTGGGACTGAGACACGGTCCAA
->URS00003C52C3 rRNA from 1 species 
-ACCGGGGCGACGATCAGTAGGGGTTCTGAGGAGGAAGGTCCCCCACATTGGAACTGAGACACGGTCCAAACTCCTACGGAAGGCAGCAG
->URS0000E650A4 rRNA from 1 species 
-GGTTGTCACAATACCATGTGCTGAGATCCTCTAAGCTAAGTAGCATTGGATCTGGTTATTACTTGGATGGGAGACCTCAAAGGAGCATGTAGGATTACAAGTA
->URS00007CE4A8 rRNA from 1 species 
-ACATGCAAGTCGAGCGGGGTCCAACCGGTGGCAACACCGGGGACGGCCGAGCGGCGAACGGGTGAGGAACACGTGAGCAACCTGCCCCGAAGTCCGGGATAACACCGGGAAACCGGTGCTAACACCGGATGTCCTCCCTCTGGCGCATGCCAGGAGGAGGAAAGGTTACGCTTCGGGAGGGGCTCGCGGCCTATCAGCTTGTTGGTGGGGTCACGGCCCACCAAGGCGACGACGGGTAGCTGGTCTGAGAGGACGGCCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATCTTGCGCAATGGGCGAAAGCCTGACGCAGCAACGCCGCGTGCGGGACGAAGGCCTTCGGGTTGTAAACCGCTTTCAGCAGGGACGAAACTGACGGTACCTGTAGAAGAAGCCCCGGCCAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCTCGTAGGCGGCTGGGCAAGTCGGGTGTGAAAACTCCAGGCTCAACTTGGAGACGCCACTTGATACTGCCCTGGTTTGAGTCCGGTAGGGGAGCGCGGAATTCCTGGTG
->URS0001630D6F rRNA from 1 species 
-CCTACGGGAGGCAGCAGTGGGGAATATTGGGCAATGGGCGCAAGCCTGACCCAGCAACGCCGCGTGAAGGAAGAAGGCTTTCGGGTTGTAAACTTCTTTTGTCAGGGAAGAGTAGAAGACGGTACCTGACGAATAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGATTTACTGGGTGTAAAGGGCGTGTAGCCGGGTTGACAAGTCAGATGTGAAATCCTGCGGCTTAACCGCAGAACTGCATTTGAAACTGTTGATCTTGAGTACTGGAGAGGCAGATGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGTCTGCTGGACTGTGACTGACGTTGAGGCCCGAAGGCGTGGGGAGCAAACAGGATTAGATACCCCAGTAGTC
->URS0000B3F91B rRNA from 1 species 
-GAGACCCTACGGGGGGCAGCAGTGAGGAATATTGGTCAATGGGCGCAAGCCTGAACCAGCCACGTCGCGTGAGGGATGACGGTCCTATGGATTGTAAACCTCTTTTGTCGGGGAGCAAGGCCCGCCACGTGTGGCGGGAAGGAGAGTACCCGAAGAAAAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATGCGAGCGTTATCCGGATTTATTGGGGTTTAAGGGTGCGTATGCGGAAGGGTAAGTCAGC
->URS0000D2A1B2 rRNA from 1 species 
-ACGATGAAACCGCGAATGGCTCATTATATCAGACATAGTTTATTAGATCCCCCTCCCCCTACTTGGATAACTGTAGTAATTCTAGAGCTAATACATGCACCAAAGCCTTTACTTTTCGGTAAAGGCGCAGTTATTAGATCAAGACCAACCGAAGCTTGCTTCGTTGTTTTGATGACTCTGGATAACATTAGCCGATCGCATGAGCTTGTCTCGGCGACGTATCTTTCAAATGTCTGACCTATCAACTTTCGATGGTAGGTGATATGCCTACCATGGTTGTAACGGGTAACGGGGAATCAGGGTTTGATTCCGGAGAGGGAGCCTGAGAAATAGCTACCACATCCAAGGAAGGCAGCAGGCGCGTAAATTACCCACTCCCGGCACGGGGAGGTAGTGACGAAAAATAACGATACGGGACTCTTTCGAGGCCCCGTAATTGGAATGAGATCACATTAAACACTATGTGGAAATCTATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAACTCCAGC
->URS00023D0B22 lncRNA from 1 species 
-TATTACAGATCGTGCCCATCCCACTTCTCTCTATCATAACCGAACATAACAACCTCAATCACAGCCTGGCATGCCCACCCCAGCTGGGGGTCCTCTGTCCATGCCTGCCCCGGCGGGGGTTTGCAGGCTAAAGGAGCCCGCCCCGATGGGGGTATAGGAGTTTAGTTTTTTAAATCCTATTACAGATCGTGCCCATCCCACTTCTCTCTATCATAACCGAACATAACAACCTCAATCCCATGAATCCTCTCCAAATCGCCCACTTCCCATAGAAATTGGCCCACTTACACTCCCATATAAATCCAACTCCAATCTCTTCCATTCTATACCAAATCCACATCACACTTCAGATTTCCATCAAAAACCTAGGGTTTCTCATC
->URS00009F6D70 rRNA from 1 species 
-GGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGAGTGATGAAGGCCCTAGGGTTGTAAAGCTCTTTCAGCTGGGAAGATAATGACGGTACCAGCAGAAGAAGCCCCGGCTAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGGGGCAAGCGTTGTTCGGAATCACTGGGCGTAAAGCGTACGTAGGCGGATATTTAAGTCAGGGGTGAAAGCCCGAGGCTCAACCTCGGAACTGCCTTTGATACTGGGTATCTTGAGTCCGGGAGAGGTGAGTGGAATGCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGCGGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGGTACTGACGCTGAGGTACGAAAGCGTGGGGAGCAAAC
->URS0001120C71 rRNA from 1 species 
-TACAGAGGTCTCAAGCGTTTGTTCGGATTCATTGGGCGTAAAGGGTGCGTAGGCGGCGCGGTAAGTCGGGTGTGAAATCTCGGGGCTTAACTCCGAAACTGCATTCGATACTGCCGTGATTGAGGACTGGAGAGGAGACTGGAATTTACGGTGTAGCGGTGAAATGCGTAGATATCGTAAGGAAGACCAGTGGCGAAGGCGGGGTCT
->URS0000F57DDE rRNA from 1 species 
-GTGTCAGCCGCCGCGGTAATACGAAGGGTGCAAGCGTTACTCGGAATTACTGGGCGTAAAGCGTGCGTAGGTGGTTCGTTAAGTCTGATGTGAAAGCCCTGGGCTCAACCTGGGAATTGCATTGGATACTGGCGGGCTAGAGTGCGGTAGAGGATGGCGGAATTCCCGGTGTAGCAGTGAAATGCGTAGAGATCGGGAGGAACATCTGTGGCGAAGGCGGCCATCTGGACCAGCACTGACACTGAGGCACGAAAGCGTGGGGAGCAAACAGGATTAGAAACCCCTGTAGTCC
->URS0000092071 rRNA from 1 species 
-CAAGTCGAGCGGCAGCGACAACATTGAACCTTCGGGGGATTTGTTGGGCGGCGAGCGGCGGACGGGTGAGTAATGCCTGGGAAATTGCCCTGATGTGGGGGATAACCATTGGAAACGATGGCTAATACCGCATGATAGCTTCGGCTCAAAGAGGGGGACCTTCGGGCCTCTCGCGTCAGGATATGCCCAGGTGGGATTAGCTAGTTGGTGAGGTAAGGGCTCACCAAGGCGACGATCCCTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCAGTGAGGAAGGAGGTATCGTTAATAGCGGTATCCTTTGACGTTAGCTGCAGAAGAAGCACCGGCTAACTCCGTGCCAGC
->URS0002572490 rRNA from 1 species 
-ATGGCGGCGGCGGTGGACCTGGAGGATGCGTTCGGCGCGGTCTTCGGCGAAGCCAAGCCGGAGGGCCACCCCACCGCGCGCCCCGTCCTCTTCCGCGCCCACGCCCGCTCCGCCGCCGCCCTCCGTGTCGTCGCCACCGACTGCCACTCCCTCGCCTGGGACTGCTCCCTCTCCGTCTCCGACCTCGACGACCTCAGAGACGATGTTGGAATCGGGGGCTCCTGGGCCGACTTTCTAGATTATCTCAAGTCCTCCTTGTCCTCCGGCGAGGTGAAGCTGCTCTTCGCCACCGACAAACTCCGCAAGTCAACCGGTTCTGATGGTGCAAAGCTTGTGGCTACCAAGGCAAAGGGCCTGCCTCGCATCACCATTTCTCTCCATAGTGTTACTGGCGCTACGACGAGTGATATCATAGCCGAGTTCTCGCTAGCGCTCTATGGAGCTTATAGGACTGCACGGGAGCTTGTATCCAAAGAACAAGAACAAATGTCACAGCTGATGGGAAATCTGTCAACTGAAAGAGAAAAGAACGAAATCATGCAAAAACAACTCGAATCTCTTTCTTTCCTAGACAAAAGAAAGGCAACAAAGCCAAAGCTGTTGGCTGATCAGGTTCCAAGTGTGTCTGCTGTGACTCTGGTCTCTGACCAAGTTACAGCTCCTGTGCAGCAGCAAATATCAGTACCTTCACCTAGTAAAGCCCCTCCTGCTAAAGTCACGAAGAGGGTAGCCCCCACGTCTCGGAGGGCAAGAGTGCGAGGAGCTCTGCTGCAAGATAATGAGGATGAGGATGACAACTGA
->URS00013FFE9F rRNA from 1 species 
-GTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTCACCGGTGAAGATAATGACGGTAACCGGAGAAGAAGCCCCGGCTAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCACGTAGGCTGATATTTAAGTCAGGGGTGAAATCCCGGGGCTCAACCCCGGAACTGCCTTTGATACTGGGTATCTTGAGTATGGAAGAGGTCAGTGGAATTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAGGAACACCAGTGGCGAAGGCGGCTGACTGGTCCATTACTGACGCTGAGGTGCGAAAGCATGGGAAGCAAACAGGATTAGATACCCCTGTAGTCC
->URS00004AF1E8 rRNA from 1 species 
-ACAAGCGGTGGAGCATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCTGGGCTCAAATGTATGTTGACGTATTCTGAAAGGGTAATACTTCTTCGGACAATATACAAGGTGCTGCATGGTTGTCGTCAGCTCGTGCCGTGAGGTGTCGGGTTAAGTCCCATAACGAGCGCAACCCTATCATTAGTTGCCATCAGGTCAAGCTGGGGACTCTAAGTGAAACTGCCTACGCAAGTAGTGAGGAAGGTGGGGATGACGTCAAATCAGCACGGCCCTTACGTCCAGGGCTACACACGTGCTACAATGGCCGGTACAAAGGGCAGCTACCTGGTGACAGGATGCTAATCTCAAAAGCCGGTCTCAGTTCGGATCGGAGTCTGCAACCCGACTCCGTGAAGCTGGAATCGCTAGTAATCGCGCATCCGCCATGGCGCGGTGAATACGTTCCCGGGCCTT
->URS0000EEE034 lncRNA from 1 species 
-GGCTTAGGGGAAAGTCCCCTTAGGGAAGTCCCTATTGACCCAGGAAGTCCAGCCAACTTAGCCACTTAGTCCCTCAGCCCTGGCTTGTGGAAGCAGAGATTCCTAATACGGCCCTCACTTCTCCACTTTCTCCACTGGGGTTGGAAGCAGTAGGAGTAGCTATAGAGGATGTATTAACACCAATTTACAGAGATCCTATTGAATTTACATCTCTCCAGCAGGTGTGATGCAAGGAAAACAAAGCTAATACCCAAAGTCTTTGAGCGTGGAAAGAGAGAAAGTCCACTTTAAGCGATGGAAAATCAGCCCCAATTCTGAAGGAACAACCATGAACAGATGATTTAAGGAGAATCAATTCTTTGCTCTTTGCAGAAGGAGCCAACAGAGTGAGATGAAGGGGACAACTTCAGATACTCAGGCAGAAGCATAAGTCCCCACCTGCTGACCTGCTGCCTGCTATCTTAACACGAATTCTTCATCTGAATGGATGAGCTTTTCACAGAGTTCCAAACTAAGGAATCCAGGAGTGGCCAATCCAGAGATTCATTCCTTATCTTTGACGAACATCTGAACTCCTGGCTCATCCTGTGGAATTCAGGCCATACAGGAGATCAAGGTCATTTGCTTTGGGTTAAATGAATGTTGCCAGGTGGAGGTTGCTAGAGGGAGAGTGCTATGTGAAAGTGCTGTATAAACTGCTTGCTTTTCACAAACAGTAGTGATTCTTTATCCTGTCCAGCCTGCCACAACTGGACCATCCTGTATGTAAGTCCCCTTAATAAATCCTGTGTCTCATTCACTGGCTTCAAGTCTCTTCCTGGGCCTCTTGAACGTGGTGCCACCTGTATTGAAGTCAACAGAAGTTCAGCACAACACAGGTCAAAATGAAGATTCTGACTCAGTAGGTCAGGATGTTCTAACGAGCTCTAGCTGACATGATACGTCAGGGCTGCAGACTAGCTTTGAGCAACAAGGTGCTAGAGAAATACCTATAGAACAACAGAGATGCAAGACAAATGAGTTGGAAGTTAAAAGATTTAAATTCTTGTCTTAGTTTTCTCATTAAAGAAAAGCTGTGTGACTATGAAAAAAAATGGCTCTCTGAGACTTTTGTTTGCTCATCCAAGATGAAAATATTGAAATGTATTATACAATAAACATTTGCAAACAG
->URS00017D46D8 rRNA from 1 species 
-TACGAAGGGGGCGAGCGTTGTTCGGATTTACTGGGCGTAAAGGGCGCGCAGGCGGCTCATTTTGTCAGGCGTGAAAGCCCCGGGCTTAACCTGGGAGGTGCGTTTGATACGGATGGGCTAGAGTTCGGGAGAGGAGCGTGGAATTCCCAGTGTAGAGGTGAAATTCGTAGATATTGGGAAGAACACCGGTGGCGAAGGCGGCGCTCTGGACCGAGACTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACGGG
->URS000151634F rRNA from 1 species 
-GTTGTATGGTTAAGTGACTAAGCGTACACGGTGGATGCCTTGGCAGTCAGAGGCGATGAAAGACGTAGTAACTTGCGATAAGCCCAGATTAGGTAGTAACAACCATTTGAGTCTGGGATTTCTGAATGGGGAAACCCACGTGCATAAGCACGTATCCTTACCTGAATACATAGGGTAAGGAGGCGAACCGGGGGAACTGAAACATCTAAGTACCCCGAGGAAAAGAAATCAACCGAGATTCCGAAAGTAGCGGCGAGCGAAATTGGACTAGCCCTTAAGCTTTACACGCGTTAGACGAACGGTCTGGAAAGTCCGACGATACAGGGTGATAGTCCCGTAGTTGACGACGTGTGTTCAGTGAAATCGAGTAGGGCGGGACACGTGATATCCTGTCTGAATATGGGGGGACCATCCTCCAAGGCTAAATACTACTGACTGACCGATAGTGAACCAGTACCGTGAGGGAAAGGCGAAAAGAACCCCTGTGAGGGGAGTGAAATAGAACCTGAAACCGTGTACGTACAAGCAGTAGGAGCACCTTCGTGGTGTGACTGCGTACCTTTTGTATAATGGGTCAGCGACTTATATTCAGTGGCAAGGTTAACCATCTAGGGGAGCCGTAGGGAAACCGAGTCTTAACTGGGCGTTCAGTCTCTGGATATAGACCCGAAACCAGGTGATCTAGCCATGGGCAGGTTGAAGGTTGAGTAACATCAACTGGAGGACCGAACCGACTAATGTTGAAAAATTAGCGGATGACTTGTGGCTAGGGGTGAAAGGCCAATCAAACCTGGAGATAGCTGGTTCTCCCCGAAAGCTATTTAGGTAGCGCCTCGGACGAATACTACTGGGGGTAGAGCACTGTTAAGGCTAGGGGGTCATCCCGACTTACCAACCCTTTGCAAACTCCGAATACCAGTAAGTACTATCCGGGAGACACACGGCGGGTGCTAACGTCCGTCGTGGAGAGGGAAACAACCCAGACCGCCAGCTAAGGTCCCAAATTACTACTAAGTGGGAAACGATGTGGGAAGGCTCAGACAGCCAGGATGTTGGCTTAGAAGCAGCCATCATTTAAAGAAAGCGTAATAGCTCACTGGTCGAGTCGGCCTGCGCGGAAGATGTAACGGGGCTAAGTAGTAAACCGAAGCTGCGGCAATGTGCTTTTGCACATTGGGTAGGGGAGCGTTCTGTAAGCGGTTGAAGGTGTGTGGTAACGCATGCTGGACGTATCAGAAGTGCGAATGCTGACATGAGTAACGATAAAGGGGG
->URS000043C123 rRNA from 1 species 
-CTACGTGCCAGCAGCCGCGGTAATACGTAGGTCCCGAGCGTTATCCGGATTTATTGGGCGTAAAGCGAGCGCAGGCGGTTAGATAAGTCTGAAGTTAAAGGCTGTGGCTTAACCATAGTACGCTTTGGAAACTGTTTAACTTGAGTGCAAGAGGGGAGAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAGGAACACCGGTGGCGAAAGCGGCTCTCTGGCTTGTAACTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAGGTGTTAGACCCTTTCCGGGGTTTAGTGCCGTAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTACTCTTGACATCCAGA
->URS0001C76D33 rRNA from 1 species 
-AAATTGAAGAGTTTGATCATGGCTCAGATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGGTAACAGGAAGAAGCTTGCTTCTTTGCTGACGAGTGGCGGACGGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACTGGAAACGGTAGATAATACCGCATAACGTCGCAAGACCAAAGAGGGGGACCTTCGGGCCTCTTGCCATCGGATGTGCCCAGATGGGATTAGCTTGTTGGTGGGGTAACGGCTCACC
->URS00012CC989 rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCTTAATACATGCAAGTCGAGCGAGCGGCGGACTGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACTGGAAAAGGTAGCTAATACCGCATACCATCAGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAATGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGCGGGGAGGCGTTACTCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATTC
->URS000186D9C0 rRNA from 1 species 
-ATTGAACGCTGGCGGAATGCTTTACACATGCAAGTCGAACGGTAGAGGGGGCAACCCCTCGAGAGTGGCGAACGGGTGAGTAATATATCGGAACGTGCCCAGTCGTGGGGGATAACGTAGCCAAAGTTACGCTAATACCGCATACGATCTAAGGATGAAAGCGGGGGATCGCAAGACCTCGCGCGATTGGAGCGGCCGATATCAGATTAGGTAGTTGGTGGGGTAAAGGCTCACCGAGCCAACGATCTGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTGCGGGAGGCAGCAGTGGGGAATTTTGGACAATGGACGCAAGTCTGATCCAGCCATTCCGCGTGCAGGATGAAGGCCCTCGGGTTGTAAACTGCTTTTGTACGGAACGAAAAGGTCTCTCTTAATACGGGGGACTCATGACGGTACCGTAAGAATAAGCACCGGCTAACTACGTGCCAGCCGCCGCGGTAACAC
->URS00000166F6 tRNA from 1 species 
-CCTGGTTAGCATAATTAGTAATGCGATTGTTTTGTAATCAATAGACTGTAAGTGCAAGTCTTACACTGGGCTA
->URS000226E0A8 rRNA from 1 species 
-TGGCAGGTCGAGCGAACAGGATAAGGAGCTTGCTCCTTTGAAGTTAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTACCTATAAGACTGGAATAACTTCGGGAAACCGGAGCTAATGCCGGATAACATATAGAACCGCATGGTTCTATAGTGAAAGATGGTTTTGCTATCACTTATAGATGGACCCGCGCCGTATTAGCTAGTTGGTAAGGTAATGGCTTACCAAGGCGACGATACGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTTTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACAAATGCGTAAGTAACTGTGCGCATCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGCGCGCGTAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGGAAACTTGAGTGCAGAAGAGGAAAGTGGAATTCCATGTGTAGCGGTGAAATGCGCAGAGATATGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGTCTGTAACTGACGCTGATGTGCGAAAGCGTGGGGATCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAAATCTTGACATCCTTTGAAAACTCTAGAGATAGAGCCTTCC
->URS000163AA4F rRNA from 1 species 
-TACAGAGGGTGCTAGCGTTGTTCGGAATTATTGGGCGTAAAGAGCGTGTAGGCGGTCAGGTAGGTCCGTTGTGAAAACTCGAGGCTCAACCTCGAGACGCCGATGGAAACCATCTGACTAGAGTCCGGAAGAGGAGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCCGTGGCTAAGGCGGCTCTCTAGTACGGTACTGACGCTGAGACGCGAAAGCGT
->URS00008DBA8C rRNA from 1 species 
-AACAGCCAGAAATGGGCTGCTAATACCCGCATAAGACCGAAGCGCCGCATGGCGCGGCGGCCCAAAGCCCCCGGCGGTGCAAGATGGGCCCGCGTCTGATTAGGTAGTTGGCGGGGTAACGGCCCACCAAGCCGACGATCAGTAGCCGACCTGAGAGGGTGACCGGCCACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGAAGGATGAAGTATTTCGGTATGTAAACTTCTATCAGCAGGGAAGAAGATGACGGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGTAGACGGCGATGCAAGCCAGATGTGAAAGCCCGGGGCTCAACCCCGGGACTGCATTTGGAACTGCGTGGCTGGAGTGTCGGAGAGGCAGGCGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCCTGCTGGACGATGACTGACGTTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTA
->URS0001561C6B rRNA from 1 species 
-CCTACGAGAGGCAGCAGTGGGGAATCTTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGAGTGAAGAAGTATTTCGGTATGTAAAGCTCTATCAGCAGGGAAGAAAATGACGGTACCTGATTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTCCTGGGTGTAAAGGGAGCGTAGACGGCAGCACAAGTCTGGAGTGAAATGCCGGGGCTTAACCCCGGAACTGCTTTGGAAACTGTGCAGCTAGAGTGGAGGAGAGGTAAGTGGAATGCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCTTACTGGACTGTAACTGACGTTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCCTGGTAGTC
->URS0000A47F93 rRNA from 1 species 
-CAGAGGGCGCGAGCGTTGTCCGGAATCACTGGGCGTAAAGGGCGCGTAGGTGGCCAGCATAAGGCCGCGGTGAAAGTCCGGAGCTCAACTCCGGATCTGCCGCGGCGACTGTGCGGCTTGGGCACTGTAGAGGCAGATGGAATTCCGGGTGTAGCGGTGGAATGCGTAGAAATCCGGAAGAACACCGGTGGCGAAGGCGATCTGCTGGGCAGTGGACCGCAAGGTCCAATAGCCGACACTGAGGCGCGACAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGGGCACTAGGTGCTCCGGGGAGCGACCCTTGGAGTACCGGCGCTAACGCATGAAGTGCCCCGCCTGGGGAGTACGGCCGCAAGGCTG
->URS0001DD09C6 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGTTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGCGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGCCGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTG
->URS0000594F9C rRNA from 1 species 
-GCAAGTCGAGCGAACGGACTAGAATCTTGCTTCTCTGATGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATTTTGAACCGCATGGTTCATAAGTGGAAGACGGTCTTGCTGTCACTTATAGATGGATCCGCGCTGCATTAGATAGTTGGTAAGGTAACGGCTTACCCCGGCAACGATGCATATCCGACCTGAGAGGGTGATCGGCCACGCTGGATCTGAGACGCAGGATCCAGACTCCTACTGTAGGCAACAGTAGGGAATCTTCCTCAGTGGGCGGAAGCCATGAACCGAACAACGCCGCGTGAGTGATGAAGGTCTTCGCATCGTAAAACTCTGTTATTAGGGAAGAACATATGTGTAAGTATCTGTGCACATCTTGACGGTGCCTAATCAGAAAGCCACGGCTCAGTACGTACCAGCAGCCGCGGTAATAGGTAGGTGGCAAGCGTTATCCGGAATTATTGGTCGTAAAGCGCGAGTAGGCGGTTTTTTAAGTATGATGTGAAAACCCACGTCTCATCCGTGGAGGGTCATTGGAATCTGGAAATCTTGAGTGCAGAAGAGGAAAGTGGAATTCCATGTGTAGCGGTGAAATGCGCAGAGATATGGAGGAACACCGGTGCCGAAGGCGACTTTGTGGTCTGTATCTTCCTCTGATGTGCGAAAGCGTGGGGATCAAACACGATCAGATTCCGTGGTAGTGCTCGCCCTAAACGATGAGTACTAAGTGTTAGGTGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTC
->URS000230E4F6 sRNA from 1 species 
-GACCAATATGATCATCACAATAAATTAGTATACGCAGTAAGGAAAGTGACCGATGATCAAGTATATCACTTCGACTCTAATCAAGGAAAACACAATAAAGTAGTTTAAGCTACCGGCTGTAGCACTGAGAATTCTTTATTAAGAAAGAGGCATTATTTAGCGTTCTCTTTCAATCCACTTCAACTTGCGAAATATCTCTTAACAATCTCAATTTTTTCTTCTTTTGTAATAAAAACATACCAGATGTACCAAATCCAATCCTTGGATGCATAATTTGCTTGAGGGTGGCATAATCTTCAGCCTTAATCAATTGTGAAACTTCATTCCTCGTAGTTTCATCCTAATGCGTTCAATCTGTTAGTTCCACAGTACTTCCATAGTAAATATAGTCCTAATACTTACTTGATCTAATTTGAACCACTCATCTACTAATTCTTGCAAAATCGGATCCATCTTGCCAAATGGGAATTGTTACCATTTGTTTGCTACACACACAATACACGTATCTCATCACCTCGTTTAACGCGTCCTTACGCCGTGGTATTTCGTATCCGTTTTCTTACAAAAATGATTTTAATAAAATAGACTCAAAAACAAAAAGTAGTAATAATATTATACTCATGACCTCCAATTATTCTAGAGAATTTCTTAAAACATTAGCTGCAAAAAGAAGCCTAGTAATTTGAAAGCAGCAGTTAATTACGATATATACCGCTTACAAAAAGGAGAAATTGGAAGAATTCAAGACCTGACGTCAATTCGCAAGCTGAATCGTTTTAATTAATAGGCGTCGGACAATGGGATTCACTTAGGCTTGGCGACGTTCTTGTCTAAAAATTGCTTGTCGGAATGTGTCATTGAACCGAAAAGGTTTGAAGCTCTTGACTAATAAACAACAGTAACTGATGTTAACTTTTTATAGAATATCCCAGGTTTCAATTCAACACGTTTATTCATAAATCTCAATCTATGTTATGCAGATGAGATTGAAAATCAATACCATCAAGTACAACTTCTCTAAACTGAACGGGTTAAGTATGGAATGGTTTAAAGTTTTAAGTACTGGATCACTCCAAGCTTTGAGATACGATAAGAAAATTAGTGTTAGTACATTTGTGGCTTTAATCACACCTTTTCCATAACCAGGAACTAAGTTTTCAAAGATCTACTATTCGATGATGAAAAAATAGCATTCATAAAGTTGATAACAGCATACATAAATGAAACTGAAATATTGAGGAGGTAAGGCAAACATGATGACCATAGTTTCAATTGACTATGTAATACGTACTATGGCTCATTAAAACCTATCAAAGAAAGAGAAATACGAATAAGAGGAAATTCAAGCCTGTTTAGAATGAGAAGAGAATAAAGATTGGGTTTTGGCGAAGGATACGCTGTTGCATTAAAACAGCCTTAAATAGGTTCTATAAATGGTTAGCATGTAAAAAAAATTAAAATTGAATCATGAAAAAATATTAAAAAATAATAAAAAAACCTACCACTTAAGAGCTTGTTCAAATTGTTGAGACGAGAACCAACACTGACATCAAGAATATTATCACCAATTTCAACAAT
->URS000119B5B9 rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGCGTGGCGGACGGGTGAGTAATGTCTGGGTAACTGCCTGATGTAGGGGGATAACTACTGTACACGGTAGCTAATACCGCATACCATCGGATGTGCCCAGATGGGATTAGTTAGTAGGTGGGGTAAAGGCTCCCCTAGCCGACGATCCCTAGCTGGTCTGCCAGGATGACAAGGCAAACTGGAACGGAGACACGGTCCAGACTACGACGGGAGGCAGCAGTGGGGAATGTGGAACAAGGGACGCAAGCCGGATGCAGCCATGCCGCGTGGAGGAAGAAGGGCGTCGGGTTGTAAAGTACTTTCAGCGGGGAGGCGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATAC
->URS00021073CB rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACGGACGAGAAGCTTGCTTTTCTGATGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATTTTGAACCGCATGGTTCAAAAGTGAAAGACGGTCTTGCTGTCACTTATAGATGGATCCGCGCTGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGGGTAGCCGGCCTGAGAGGGTGACCGGCCACAATGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATAACGGCCTTCGGGTTATAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAGTGGGTAAAGAAGCACCGGCTAACTACGTG
->URS0000A0DC81 rRNA from 1 species 
-TAGTCCACGCCGTAAACGATGGATACTAGCTGTATGTCTACTTCAGGTAGATGTGTGGCTAAGCGAAAGTGATAAGTATCCCACCTGGGGAGTACGATCGCAAGATTGAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCAGGGCTTAAATGTACGTTGCATGATTTAGAGATAGATCTTTCTTCGGACTACGTACAAGGTGCTGCATGGTTGTCGTCAGCTCGTGCCGTGAGGTGTCAGGTTAAGTCCTATAACGAGCGCAACCCCTATCGTTAGTTGCCAACAGGTTAAGCTGGGAACTCTAACGAGACTGCCTGTGACAAACCGCGAGGAAGGTGGGGATGACGTCAAATCATCACGGCCCTTACGTCCTGGGCCACACACGTGCTACAATGGCCGGTACAGAGAGCACGCCACTCCGCGAGGAGGAGCGAATCTAATAAAACCGGTCTC
->URS0000C91A8A tmRNA from 1 species 
-CAGGTTTATATCCATTACAAATAGACTTATATTCGTGCTGCCGGCTTGCCGGCTATAGCGCTAAACGGTTTGCGGAATAAGCGTTGCGGACCCGGGGGCGGTACCCGGCGCCTCCACCAGTTTTGTGGCTTTCAATACATCACTGGGGTATTTTTGGGGGCGAAACAGGATCGACGCGCGTGGTAAAGGCAGACTTTGTGCTCGGCATGGTACCACCGTTATCGGGCTATAGTCGTTAAATGCCAACGACAACTTTGCGGGCGAAGCCCGCCTCGCTGCTTAACTTAGGTTAGGTAAGCGCGGTTCGGGGGGCACCGGGCAACAGAAGCCCCCCACT
->URS000232319A pre_miRNA from 1 species 
-GGGGGGAGGTCGGATTCTTGGCTATGTCCCCGGCGCCCTGTGCTCCTGGGCCTGTGCTGTTGGATTCGTGCTCCTGGCCGGACAGCCCCCT
->URS000259C9B7 misc_RNA from 1 species 
-GTGAATCATCGAATTTTTGAACGCAAATTGCACTCTCTTCTGTGAGTATGCCTGTTTGTGGTTCAGCCTAAGAAAAATCGACATATTCGCTGTTTCGCGGTTTCTTTCGTTTGCAGTTTTGTCATCTTAAACCTTTTTGTTTTAAGCGGCTTAAAATTTTCTTTACGTTTCCACTAACTTTTCTAACATTTACTTACTCTTTTAATGTATCGATCTTTATTAGACGTGGCCGTTTCATCGGATCGCGTCCATATATATTTCGTTAACTTA
->URS00009D7A85 rRNA from 1 species 
-GATGAACGCTAGCGGGAGGCTTAATACATGCAAGTCGAACGGTAACAGGTCTTCGGATGCTGACGAGTGGCGCACGGGTGAGTAACGCGTACGTATCTACCTTGTACACGGGGACATACACTGGAAACGGAGTAAATACCCGATAGTCTGGAAACAGTAAAGCTACGGCGGTACAAGATGGGCGTGCGTCTGATTAGCTAGATGGTGAGGTAATGGCTTACCATGGCGATGATCAGTAGGGGGCGTGAGAGCGTGATCCCCCACACGGGTACTGAGACACGGACCCGACTCCTACGGGAGGCAGCAGTAAGGAATATTGGACAATGGGCGGAAGCCTGATCCAGCCATCCCGCGTGTAGGATGACTGCCCTATGGGTTGTAAACTACTTTTATATGAGAAGAAGCGCCTTTCTGCGGAAGGGTTTGACGGTATCATATGAATAAGCACCGGCTAACTCCG
->URS0001E0D339 rRNA from 1 species 
-TACGGAGGGTGAGAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGCTAGATGTGAAAGCCCCGGGCTCAACCTGGGATGGTCATTTAGAACTGGCAGACTAGAGTCTTGGAGAGGGGAGTGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAACATCAGTGGCGAAGGCGTCTCCCTGGCCAAAGACTGACGCTCATGTGCGAAAGTGTGGGTAGCGAACAGG
->URS000061A91B rRNA from 1 species 
-TAGGGTTTGATCCTGGCTCAGAACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGATCCCTTCGGGGATAGTGGCGCACGGGTGCGTAACGCGTGGGAACCTGCCCTTAGGTTCGGAATAACTCAGAGAAATTTGAGCTAATACCGGATAATGTCTTCGGACCAAAGATTTATCGCCTTTGGATGGGCCCGCGTTGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCCATAGCTGGTCTTAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCAATGCCGCGTGAGTGATGAAGGCCCTAGGGTTGTAAAGCTCTTTTACCCGGGATGATAATGACAGTACCGGGAGAATAAGCTCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGAGCTAGCGTTGTTCGGATATACTGGGCGTAAAGCGCACGTAGGCGGCGCCGTAAGTCAGGGGTGAAATCCCGGAGCTCAACTCCGGAACTGCCCTTGAAACTGCAGTGCTAGAATCCTGGAGAGGCGAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAANGCGACTCGCTGGACAGGTATTGACGCTGANGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGATAACTAGCTGTCCGGGCTCAT
->URS00023F57E9 lncRNA from 1 species 
-GGATCTGAATCCTAGACCCTTTTAGAACGCCAGGGTCGTAGCCTTTCCGCCAAGTCACCGGAGGAGAACCCATTCCCCCGCCCTTCTCTCCACCGGCCTCCTGCTCCAAACCTCTCTGCTCTGCGCTCTGGGCGTCACCCACTCGATCGATATGAAGAGGCCGAGATGTGTTCTTCTTCCCGGGATCTCGATTTTTCGTCTCGTCCTCATTTCTTGCGTCTTTCTGTGCTCTATTCCTAGTAAAGCAAACCAATTCTCTTCTTTTTCTTTAAAAAAATGTTATTTGTAAATATTTTGCATGGATTTCCCTCTTATTTAAAGACAGGAAAGAGAATAAATTGACTGCATGCATTTGGAGAAGTCTATCAAATTTTCTTGGGAACAGTTGGGAGATTTCACAGGTTTCTAATTCATATCGTGAGAGAGAGTAAGAAAGGATAGAGGTTGGAAACTGCTAAAATCTAGTTGAATTTTAGATATGATTTGCAGGAGTAACAGAAATAATTAAGAAAATAAGAGTTGGCTGCCAGTTTGGATAATAATGGTAAGAGGACAGGTTTTGTTTAGGATAGGTGTGAAATTATTATCGTTCATCAGATTCTTTATTGTTCATGAGTTTTTTTCTCCTCCGAAAAAAAACTTAAATATGAGCTGGAGGGTGTTTCCTAGGTTTGTTTTTTATGAATTGTTTTTCGTTTTCTTTGTGCTATTGCAATGGTTGATTTTGTCCCCCAATTGCAAATACATTATTTTCAGTTCCTTGAAAATTAATATAGGAATTTGAAGCAATGAGTCAGAAAATGAAGATCAGCTAAAATTTTTTGGAGCATGCTTTTCAGAGTCAAAGCATACGACTATGCATGTTGACCTACAGTGCTTGATTGTTGCATGGGTAGTTTCTTTACCTAGAGAAATTTGTGGCTTACTATATCAACTACAAACATTATGGAAGTTACATCCAATCCAAGAGAGAGAGAGGGGTCATGGAATACTAGGAAACATTTGGATATTGAGTTATAAAGGAATTTGTGGTAGTTGATAGAATAGACGAAATAATTCAGTGCAAATGGAAAAGGATATTTGCTTTTATTTTTTTTTGTTCTTGCCATATGTATCTGTTGATTTATTAAAAGGTTAAAATTTGCAAGCACAATAAAGATTCATGGTTCGTGTGGTTTGATATCTTTCCATAAAATGCTCTCAAGTTGTCAACTTTAATAGTATTGGCTTCTATGATCATGGGTGAAGGTTTTAGAGTTTTCAGATTGGGG
->URS0000642F76 tRNA from 1 species 
-GGTGGCTCAGTGGTAGAGCGCTTGCCTTGCATGCATGAGGCAGGCCCTGGGTTCGATTCCTCAGCACCA
->URS0000D63273 lncRNA from 1 species 
-CTGTCACTTAAATCTTTGAGCTGTGTAGCCCACAAACTATTGCTAGAAACCAATGACGTTGTAAAGCAACTTTGAATTGGGCTTCCAGGTGGTGCCTGTTAGAAGGGCCTAAGAGCAAGGCATCATGGGAGACCGGGCGCCATGAATGTCTCGCTGTCGACTGGGAGGTTGCAAAGCGGCTGCTGCTGTTTTCCTTCCAATCCCGGAGCCAGCTGTCTGGCCCACAGCTCCAGATATATCAAGATTGAGACACATTTCCAAGCACCAAGAGACTGCTGGGATCTCTCTCTGAATTGGTACCTAAGTACTTTGGCCACCTCAAGCGAAGAGTTGACTGATTGGAAAAGACCCTGATGCTGGGAGGGACTGGGAGCAGGAGGAGAAGAGGACGACAGAGGATGAGATGGCTGGATGACATCACTGACTCGATGAACGTGAGTCTGAGGGAACTCTGGGAGTTGGTGATGGACAGGGAGGCCTGGCGTGCTGCGATTCATGGGGTTGCAAAGAGTCGGAC
->URS00007413E9 rRNA from 1 species 
-TACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGGCCTTCGGGTTGTAAAGTACTTTCAGTCGTGAGGAAGGTGTTAAGGTTAATAACCTTAGCAATTGACGTTAGCGACAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGGGCACGCAGGCGGTTAATTAAGTTGGATGTGAAATCCCCGGGCTTAACCTGGGAATGGCATTCAAGACTGGTTAGCTAGAGTCTTGTAGAGGGGGTAGAATTCCATGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAATACCGGTGGCGAAGGCGGCCCCTGGGACAAAGGACTGACGCTCATGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACC
->URS000236D244 lncRNA from 1 species 
-AGGCGGTTAGTGAGGTAAGCGCTAGCATGTAACTCAAGGGATATGATAACATAATGACATGTCCAAAAACCAGTCAAAACCATAATGTACACATTTATATACATATATATAAGTTTTCATGATAGGGAACAAGGTTAAAGCATGAGGTTATCATTAACTTGGACTGTGTAGCTCTAACCATTCTAAAAACACCTATGAGCTATATGGGTCTGGATCACCCCACTGAAAGGGCCCTAGTGTATGTTATCCACATGAGCCAGAGAATTCTAAGGAAAGCCCAGGGAATCTATGACCCTACTCTAATCATACGTATATATATATATATATATCAAATAAGAACTATGCACACAGTCATGAAGGCCCCCACACGGAAAATATGGTTTCTAGTATAGGTCGCCCCTAAGGCCTCC
->URS0002273E9A tRNA from 1 species 
-GTTTATGTAGTTTATAAAAACATTACATTTTCAATGTAAAAATAAAAGGAATCTTTTCATAAATA
->URS00015EFEAA rRNA from 1 species 
-CCTACGGGTGGCAGCAGTGAGGAATCTTCCACAATGGGCGCGAGCCTGAACGAGCCACGTAGCGTGAAGGATGACTGCCCTACGGGTTGTAAACTCCTTTTATAAAGGAATAAAGTGAGGCAAGTGAGTCTCTTTTATTTGACTTTATGTATTTGGATCGGCTAACTCCGTGCCAGCAGCGGCGGTACTACGGAGGGTCCGAGCCTTGTCCGGATTTATTGGGTTTAAAGGGAGGGTAGATGGGTTGATAAGTCAGTTGTGAAAGTTTTCGGCTCAACCGTAGAATTGCATTAGATACTGGTGGACTTGAGTACAGTAGAGGTAGGCGGAATTCGAGGTGTAGCGGTGAAATGCTTAGATATAACGAAGAACTCCGATTGCGAAGGCAGCTTACTAAACTGCCACTGACGTTGAGGCTCGAAAGTGTGGGTAGCAAACAGGATTAGATACCCGAGTAGTC
->URS00016A3A0B rRNA from 1 species 
-TACAGAGGTCTCGAGCGTTAGGCGGAATTACTGGGCGTAAAGCGCGTGTAGGCTGCTCAGCAAGTCGGATGTGAAAGCCCTGGGCTTAACCTAGGAAGTGCATTCGAAACTTCTGAGCTAGAGTTCTGGAGAGGAAGGCGGAATTCTCGGTGTAGAGGTGAAATTCGTAGATATCGAGAGGAACACCGGTGGCGAAGGCGGCCTTCTGGACAGTGACTGACGCTGAGACGCGAAAGCGTGGGGAGCAAACAGG
->URS0001B06EC2 rRNA from 1 species 
-AGAGTTTGATCATGGCTCAGATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGGTAACAGGAAGAAGCTTGCTTCTTTGCTGACGAGTGGCGGACGGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACCGGAAACGGTAGCTAATACCGCATAACGTCGCAAGACCAAAGAGGGGGACCTTCGGGCCTCTTGCCATCGGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAACGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCTGGGAGGAAGGGAGTAAAGTTAATACCTTTGCTCATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCTGATACTGGCAAGCTTGAGTCTCGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACGAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGACTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTGAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCACGGAAGTTTTCAGAGATGAGAATGTGCCTTCGGGAACCGTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTCCGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGCCCCTTACGACCAGGGCTACACACGTGCTACAATGGCGCATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCATAAAGTGCGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTGGATCAGAATGCCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTTACCACTTTGTGATTCATGACTGGGGTGAAGTC
->URS0000A96D3A lncRNA from 14 species 
-CAATTCCCAATGTCCTCTGAAACCTTGAATACTCCTTTCTGCCTTACACACTTCTTCTCACACAGGTCTGCAGTATTCCCTCCAAAATGGCCCAGCAAGCTTTGATTACAGCTTCAAAGTGTTGCTCTGCTAGCTGCCCCCCCTCCCCATTCTTCCAGTCCCTCCATAAACCAGACCTCAAGGCCTGTGGACCAGATGTTCAGGTTTCTCACAGGGAGTGGCCCACTCCCAGGACTAATTATCCATATTAGTGCAAGTTTTCACTGCTTTGAGACAATATCGACACCAAGCGATTTACGGGAGGAAAAGACTTTTGTTTTGTTTCCACAGATTGAGGAGAATGAAGTTCATCATGTCAGGGAAGCCGTGGCAATGGGCGGCTCTGCTGGGCTTGCGTGTCTGTCAGAGAGGAGGGAGATTTGGGCTGAGACCAGCGATAGATTGGTCGAGCGCGGGAAGAAAAGGAAGAGGAGCGAATTAAATAGGAGCGCCG
->URS0001F14516 rRNA from 1 species 
-GATGAACGCTGTCTACAGGCTTAACACATGCCAGTCGAGGGGAAACGACGGGGAAGCTTGCTTCCCCGGGCGTCGACCGGCGCACGGGTGAGTAACGCGTATCCAACCTGCCTCTGACTGAGGGATAACCCGTCGAAAGTCGGCCTAATACCTCATGGCATCGTCTGCGGGCATCCAACGACGATTAAAGATTTCATCGGTCAGGGATGGGGATGCGTCTGATTAGCTTGTTGGCGGGGTAACGGCCCACCAAGGCTACGATCAGTAGGGGTTCTGAGAGGAAGGTCCCCCACATTGGAACTGAGACACGGTCCAAACTCCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGGCGGGAGCCTGAACCAGCCAAGTAGCGTGCAGGATGACGGCCCTATGGGTTGTAAACTGCTTTTATGCGGGGATAAAGTGAGGGACGTGTCCTTCATTGCAGGTACCGCATGAATAAGGACCGGCTAATTCCGTG
->URS000021B5FE rRNA from 1 species 
-GAGTTTGATCCTGGCTCAGATTGAACGCTGGCGGCATGCCTTACACATGCAAGTCGAACGGCAGCATGATCTAGCTTGCTAGATTGATGGCGAGTGGCGAACGGGTGAGTAATACATCGGAACGTGCCCTGTAGTGGGGGATAACTAGTCGAAAGATTAGCTAATACCGCATACGACCTGAGGGTGAAAGTGGGGGACCGCAAGGCCTCATGCTATAGGAGCGGCCGATGTCTGATTAGCTAGTTGGTGGGGTAAAGGCCCACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGACGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGAAAGCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGCCTCCGGGTGTAAAGCACTTTGTCCGGAAAGAAATGGCTCTGGTTAATACCTGGGTCGATGACGGTACCGGAAGAATAAGGACCGGCTAACTACGTG
->URS0000E81CC4 lncRNA from 1 species 
-TTCCAATTTCTGTCTTGCGTCTCTGTCCACTTCACACTACTCGTCTATAACTGCCAGTGTTGGAGGAAGCAAGTAAAGGAATAGGGAAGGCCTTACAATTTAGAGTATGAAAAGTATGACCCCCAAGCTGATTATGAGGATCATCTCTATCTCTCATCATCCCCACTCTGTTAAGTGACAAAGAATTTTAGGGGAGTTGTAATTCATGGCACCTGAAGGATCAGAGGAGGAAAAGGAGGAAGAAGGACATTTGAATTCACTTACTTCAGAGAGAAAATGGTTTGAAAACTTCCTAGGCACTAAGAAAGCTTTCAGTGACATCCTTTACCCTTGGAGGACATGCTGCCAAACTCTGAATTCATGGAACATTTATATGGTTCCATTAATTACAAATTAATATGACCTGTACATGGAGTCAGTCTGGAGCATCTCAAGGTAT
->URS00004DE10A rRNA from 1 species 
-GAGTTTGATCCTGGCTCAGGACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTTTCGGGGGTACTCGAGTGGCGAACGGGTGAGTAACACGTGGGTGATCTGCCCTGCACTCTGGGATAAGCCTGGGAAACTGGGTCTAATACTGGATAGGACCATGGGATGCATGTTCTGTGGTGGAAAGCTTTTGCGGTGTGGGATGGGCCCGCGGCCTATCAGCTTGTTGGTGGGGTGATGGCCTACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGTGTCCGGCCACACTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCGACGCCGCGTGGGGGATGACGGCCTTCGGGTTGTAAACCTCTTTCAGTATCGGCGAAGCTTGCGGGTTTTCTCGCAGGTGACGGTAGGTACAGAAGAAGCACCGGCCAACTACGTGCCAGCAG
->URS0001FF2370 rRNA from 1 species 
-GACGAACGCTGGCGGCGCGCCTAACACATGCAAGTCGAACGAGCGAGAGAGAGCTTGCTTTCTTGAGCGAGTGGCGAACGGGTGAGTAACGCGTGAGGAACCTGCCTCAAAGAGGGGGACAACAGTTGGAAACGACTGCTAATACCGCATAAGCCCACGGTGCCGCATGGCACAGAGGGAAAAGGAGCAATCCGCTTTGAGATGGCCTCGCGTCCGATTAGCTAGTTGGTGAGGTAACGGCCCACCAAGGCGACGATCGGTAGCCGGACTGAGAGGTTGAACGGCTACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGGGAAATCCTGATGCAGCGACGCCGCGTGGAGGAAGAAGGTCTTCGGATTGTAAACTCCTGTTGTTGGGGAAGATAATGACGGTACCCAACAAGGAAGTGACGGCTAACTACGTG
->URS0000F8DDB5 rRNA from 1 species 
-TACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGTGGTTTCTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGGGAACTTGAGTGCAGAAGAGGAAAGTGGAATTCCAAGTGTAGCGGTGAAAATGCGTAGAGATTTGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGTCTGTAACTGACACTGAGGCGCGAAAGCGTGGGGAGCGACAGGA
->URS0001627BDD rRNA from 1 species 
-CACGGGGGGAGCAAGCGTTGTTCGGAATCACTGGGCGTAAAGGGCGTCTAGGCGGTCAGATAAGTGGGATGTGAAATGCCCCGGCTCACCCGGGGACCGGCATCCCAAACTGTCTGGCTTGAGTATGGGAGAGGATGTGGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCGATACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS0002226441 misc_RNA from 1 species 
-AACAAGGCGTACCTGCGGACCTGCGGAAGGATCATTACGAGAGTGTCACCACTCCCAACCCATTGTTTACCTACCCGTCCACCGTGCTTCGGCAGGCAGCCCTGTGGGACAGAGCCTCGCCCCCTTTCGCGGGGGGTGCCTGCCGCTTGCCAACCAAAACTCTAGCTGTTTTAGTACCATCTGAGTCTTCCACAAATGAACAAAACTTTTAGCAACGGATCTCAGATCGGAAGAGCACAC
->URS00002E10EA rRNA from 1 species 
-AGGATGAACGCTGGCGGTCTGCTTAACACATGCAAGTCGAACGGAGTAGCAATACTTAGTGGCGGACGGGTGAGTAACGCGTGAGAATCTACCTTCAGGACGGAGACAACAGTTGGAAACGACTGCTAACCCCCGATGTACCGAAAGGGCAAATATTTATAGCCTGAAGAAGAGCTCGCGTCCGATTAGCTAGTTGGAGAGGTAAAAGCTCACCAAGGCGACGATCGGTAGCTGGTCTGAGAGGACGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTCCGCAATGGGCGAAAGCCTGACGGAGCAAGACCGCGTGGGGGAAGAAGGCTCTTGGGTTGTAAACCCCTTTTCTCTGGGAAGAACACAATGACGGTACCAGAGGAATCAGCATCGGCTAACTCCGTGCCAGCAGCCGC
->URS000137F4FF rRNA from 1 species 
-CCTACGGGTGGCAGCAGTGAGGAATATTGGTCAATGGCCGAGAGGCTGAACCAGCCAAGTCGCGTGAGGGAAGACGGCCCTACGGGTTGTAAACCTCTTTTGTCGGGAAACAAAGCGAGTCACGTGTGCCTCATTAAGAGTACCCGAAGAAAAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGAGGGATGCGAGCGTTATCCGAATTTATTGGGTGTAAAGGGTGCGCAGGCGGAGGTGCAAGTCAGTGGTCAAATTGCGGGGCTCAAACCCGTACTGCGGTTGATACTGCATCCCTTGAGTGCGCGAGAGGTATGCGGAATGCGTGGTGTAGCGGTGAAATGCATAGATATCACGCAGAACTCCGATTGCGAAGGCAGCATACCGGCGCGCAACTGACGCTCATGCACGAAAGCGTGGGTATCGAACAGGAGTAGATACCCGAGTAGTC
->URS0000A3AF07 rRNA from 1 species 
-TACGTAGGTGGCAAGCGTTGTCCGGATTTATTGGGTTTAAAGGGTGCGTAGGCGGTCTTTTAAGTCAGTGCTGAAATACTCCAGCTTAACTGGAGGGGTGGCATTGATACTGGAAGACTTGAGTGTAGTCGAAGTAGGCGGAATTGACGGTGTAGCGGTGAAATGCTTAGATATCGTCAAGAACACCGATAGTGAAGACAGCTTACTAGGCTACAACTGACGCTGAGGCACGAAAGTGTGGGGATCAAACAGG
->URS00010B2DDF rRNA from 1 species 
-TACGGGGGGAGCAAGCGTTGTTCGGATTTACTGGGCGTAAAGGGCGCGTAGGCGGCGTGACAAGTCACTTGTGAAATCTCCGGGCTTAACTCGGAACGGTCAAGTGATACTGTCGTGCTAGAGTACAGAAGGGGCAACTGGAATTCTCGGTGTAGCGGTGAAATGCGTAGATATCGAGAGGAACACCTGCGGCGAAGGCGGGTTGCTGGGCTGATACTGACGCTGAGGCGCGAAAGCCAGGGGAGCGAGCGGG
->URS0002390407 lncRNA from 1 species 
-GACAAGAAAACAAGGGGAAAGAAGTACCTAATGAGATTATGAAGGAAGAAACTGACCGTGGACTTGCACAAGACCGACTGGACTCTGATTGCTTCGAGGTGGGTAAAAAATTACATTAAGAAATCGTCCCTACTAGGAACGATTAGTTAATGTAAATTTTGGGCTCAACTCGTACCTTGAATCCAAAATTTTGGATTTGGAATTAACGGAATTGGGCAGGTTTTTTGGGGGAAAGGTTACTAAATTGGTATAAAGGGGAGGGTGGAGAGTGTATATGGTGAACTTGGGTTAGTTTAGAGGAGTTATGATTTTTGGTTTGAATCTTAGATCCGAAATATGAGCAATTTAGCGGGGATTTGGGAAAAAATAATTGGGGATCTAGGATGAGGAGGGGGTGAGGAACCGCCATAGGGCGATTTCCAAAAACTAATTTGGAGCATGGGAACCGTCGTGGGGCGATTTTCGGCGGGTGATTTGTGGCGAGGCAGCAGGGGAAATCCTAGGCGGCTAGAGTTTGATCTGTTTATAGAGATGAGAGTAAAAT
->URS000226779B rRNA from 1 species 
-AAACTGGAGAGTTTGATCCTGGCTCAGAACAAACGCTGGCGGCGTGCTTAACACATGCAAGTCGTACGAGAAAGTCCGCTTCGGCGGATGAGTAAAGTGGCGCACGGGTGCGTAACACGTG
->URS0001472A94 rRNA from 1 species 
-TACGTAGGGGGCTAGCGTTGTCCGGAATCATTGGGCGTAAAGCGCGTGTAGGCGGTCCGGTAAGTCCGCTGTGAAAGTCGGGGGCTCAACCCTCGAATGCCGGTGGATACTGTCGGGCTAGAGTGCGGAAGAGGCGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGAGTGGCGAAGGCAGGTCTCTGGGCCGACTACTGACGCTGGAGAAGCGGAAAAGCATGGGGGAGCGAAACGGG
->URS00006461F6 tRNA from 1 species 
-TCCCTGTTGGCTCAGATGGTAAAGCATCTGCCTACAATGCAGGAGAACCAGGTTTAATCCCTGGGTCAGGAA
->URS000199F6C3 lncRNA from 1 species 
-GGAACCGCGGGCACGGCGGGGCAGGGAGCGCGCCCGGGGCTGGGAGACTCAGGGGCGGGGCAGCCCCGGGACAGCGCCGGGACAGCGCTGGGATTGGACTGGGATAGCCCGGGACAGCGCCGGGACAGCGCCGGGACAGCGCTGGGATTGGACTGAGGAGGGCCAGAAGGAATGAAATCCATCGTGGCTCAGCCTGGGCTGGTGAAAGCGAGCTGGGAAAGGCAGGAGCAGGGATTCCAGCATTTCCCTGAACCACAGGAAAATCCTGGGAACGGAGAGGAGCAGAGAGGGGGAGATTCCGAATGGGGATTTGGAGCATCCAGCCAGTTTTACTGGGACTCCTTTCAAGGGCTGCCCGGAGCCCCCCGCGGTAAATAGTGCACAGCTCGGGCCAGGAGGATTTCCTCACCGCTGGGACTCTTAATGTCGAAAGCAGAGGTGTCAAACAAGGGGCTCAAAGCCCCGTGGTGGCCCCGGAGAGTTCCACATCTGGCCTGGATCTCGGTGCTTAACACGTTTTAACTCTTGCCCCGAGCAGCTCCGGATTTCCCTCGGCAGCCCGGGTTAGGTTTGATTTAAGAGGCTGCAAGGAAAAGCCAAAATAAAAA
->URS00021F6806 misc_RNA from 1 species 
-CGGAACTTCATTTCCCAGCCATGGATGTGGACGTCAATCCCTATCCTGGTGCACGCATTCCTGCTGCCTCACACGCTCGCCCACCAGTGTCGTCTTCACCTAGCGCTCGACCTCCAGCTCACCTCTGCCCTCTCATGCTTGCCGAGCTGCTCTCAGATGGTTGCTCGCGAGTTTCTTCCTCCCCAACACCGTCAGCTTGCCGCGTCTCTGGTCCAGCTCCAGCTCGTCGAGTCCCTCTCTGTGTGCGCCATGCAGCTCGCTCGGCCGCGACCTTGCCGAGCTCCGCCCCTGCTCCACGTCTCCTGGTCGGGCTCTCGTTCTGCGCGTGACGCCGCTGTTCCCTGGTGCTCCCTGCTCGACCCTGCTTCTTCTTCCTTGAGCCTCGCCGTGCGAGTTCTCCCTGGCTCATGTGCCTACCGCCGTCGGCCCCAGTCTCTCGCTCGCAAGGTCTTCCCAAGCCGTCGTCTCCTGCCTCTGGCTGTCAAGCGCGACGAACTCGTCCCGAGCTCGTCACAACGTCTCAGCCCTGCGTGTCGCGCTAGCTCGCGTCTATGGTCGCGTCCGCTGAACTCGCCAACGCCCTGTTGCCAGTCCGACTATCGTCGCTACTGCGTGCCTCGCTGCGCGCTCGTTGGTGGTGCCGTCTGTTGTGCCCCTGCATCCGCCCTTGTCGCTAGTGCCAACTCCGGCCGTCGCGGTATCTGCTCCGTCCTGGCGCCCTGCGCTAGTGCTCTGCTTCCTGGCCCCGCCTGGCCTCCAGCTTGCTCAACAGTACTATCCATTTCGTCGTCATACGTCTCCGCGTCATGTACAATAACGTCGTCGACCATGCCTTCGCCTGCTTTGACGCGTCGAGCTCCTTCCCGTTGTGACTCGCGCACCATCTATTCATCAAAATGGAATACTAATGAGCTCCTCGCGACGCAGTTTCTCTGTGTCGTCGTTCGCGCCGGTAAGATCCACGGTTCTGCTTTGTTCCATTAAATTCTCTTCTAGCACTATTTTGGCTAGGTGTGGATTTATGTGTATATGTGTGGATCTGTAAAGGAAGACGAAAGGGAAGCGCCAGTGCAACTTGTAACACCCCAGGTGTTTGCCTTAAATTAAACTGCAATTATGGATCCTTAAGAAAAATATCAGTTTGGATCACTCGAATTAGCGAATGTAAATTTAGGAAGCACTTGTATTTATAATTCGGACCTCACTAGTTTGGATCGACGTGTATTCAATTCAAATTAAATTTAAAATTAAG
->URS00014751E2 rRNA from 1 species 
-TACGTAGGGTGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGTTTGTCGCGTCGAATGTGAAAACCCAGGGCTCAACCCCGGGCCTGCAGTCGATACGGGCAGACTAGAGTGCGGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS0001C1925D rRNA from 1 species 
-AACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGAGACCTTCGGGTCTAGTGGCGCACGGGTGCGTAACGCGTGGGAACCTGCCCTTAGGTTCGGAATAACTCCCCGAAATTGGTGCTAATACCGGATAATGTCTTCGGACCAAAGATTTATCGCCTTTGGATGGGCCCGCGTTGGATTAGCTAGTTGGTAGGGTAAAAGCCTACCAAGGCGACGATCCATAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCAATGCCGCGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTTACCCGGGATGATAATGACAGTACCGGGAGAATAAGCTCCGGCTAACTCCGTG
->URS0001957C9E lncRNA from 1 species 
-CCCACATTGTCCATAACAACTGACTGAGGTTCTTGTACCCAGGGCTCTAACCTGAATTTTTTGCCTGACTTTCTGTCTTCCCTAATCATTTTATATTTGCTAAAGTGGGTCTTAAAGACTTGCTTGTTCCTTTCTTACTTTAAATTCTCAACCTCCAAGATTCCTTGTGCATAGATGCTGGGTTATGCATTCCTTTTTCCAATTTTTATTTTGTTTTTCTAAGTGATGCTATTTTACTATCCTTCCATGACAGGATCCCATCAGGCCTCTACTGCACAAATAACAAGAAAAAAAAGAAAAGAAAAGAAAAGAAAGCAAACAAGTGTAATTTGTAAATCTAATATTCTTGCACAAGGAATCCACTGGATATTGTAGGCAATGGCCTTGTCATCTTAGCCACTAGAAGACTCCATCTATCAGAAGCTGGCAATTCTGAATTTTGTACAGCAAGCCGTGAGTATGGAAATGCAAGTAAGAGTTGACATTGCAGTTTTGATTCCAAATTCCATAGCTAAGCAAGTTAGAAACTCAGGTAGTATTTCTATGTTGCAGTTTTGAGGCAGATTCCTCTTCCTTCAGGAAACCTCAGTGTTTGCTCTTTAGACCTTCAGCTAATTGGATGTGACTCACCCACATTATGCAGGGTATCTAGCTTATTGCAGGTCTGCTGATTAAAAAAAGTGCCTTCATAGCATCAAGACATCTTGTTGTTAATGAAACAACTAGATATCATAACCTCGTCAAGTCGACACACACAATAAACCTTCAAAGGAATATTTTATTTAATAACCT
->URS000133998B rRNA from 1 species 
-TACGTAGGGGGGCAAGCGTTGTCCGGAATCATTGGGCGTAAAGAGCGTGTAGGCGGTCCGGTAAGTCGGCTGTGAAAGTCCAGGGCTCAACCCTGGGATGCCGGTCGATACTGCCGGACTAGAGTTCGGAAGAGGCGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCAATGGCGAAGGCAGCTCGCTGGGACGGTACTGACGCTGAGACGCGAAAGCGTGGGAGCAAACAGG
->URS00011EADB4 rRNA from 1 species 
-TACGTAGGGGGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCGTGTAGGCGGCCATACAGGTCAGCTGTGAAAACTCGAGGCTCAACCTCGAGACGTCGGTTGAAACCGTATGGCTAGAGTCCGGAAGAGGAGAGTGGAATTCCCGGTGTAGCGGTGAAATGCGCAGATATCGGGAAGAACACCCGTGGCGAAGGCGGCCTGCTGGGCAGTTTTGCTGACACTGAGGCGCGACAGCGTGGGGAGCAAACAGGG
->URS0001797414 rRNA from 1 species 
-TACGAAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGTAGGCGGTTGTTTAAGTCTGCTGTGAAATCCCCGGGCTCAACCTGGGAATGGCGATGGATACTGGCGAGCTAGAGTGTGTCAGAGGATGGTGGAATTCCCGGTGTAGCGGTGAAATGCGTAGAGATCGGGAGGAACATCAGTGGCGAAGGCGGCCATCTGGGACAACACTGACGCTGAAGCACGAAAGCGTGGGGAGCAAACAGG
->URS00012E3FAA rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCTTTACACATGCAAGTCGAACGGTAACAGGTTAAGCTGACGAGTGGCGAACGGGTGAGTAATGCATCGGAACGTGCCCGATCGTGGGGGATAACGCAGCGAAAGCTGCGCTAATACCGCATACGATCTGAGGATGAAAGCGGGGGACCGTAAGGCCTCGCGCGATCGGAGCGGCCGATGTCAGATTAGGTAGTTGGTGGGGTAAAGGCTCACCAAGCCAACGATCTGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGAGACGGCGCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGAAAGCCTGATTCAGCAATGCCGCGTGCAGGAAGAAGGCCTTCGGGTTGTAAACTGCTTTTGTACGGAGCGAAAAGGCTCTCTCTAATACAGGGGGCTCATGACGGTACCGTAAGAATAAGCACCGGCTAACTACGTGCCAGCCGCCGCAGTAAGAC
->URS000218DCF5 lncRNA from 1 species 
-TATACTAAACCTCATCTAATAACCCACTCAGGAAACTACATGAAAAAAGTCACTACTGACGTGTAAAGTCATATACATACATACATATATACTAACCTCATCTAACAACCCACTCAGGGAAACTACATGAAAAAGTCACTAATTGATGTAGTAAGATCATATACTACATACATATATACTAAACTCATCTAACTAACCCAACTTCAGGAAAACTAAATGAAAAAGTCCTACTGATTGTAGTAAGTCATATACATACATACATATATACCTAAACCTCATCTAATAACTCACTCAGAACTACACAAAACGAAAAAGTCACTACTGATGTAGTTAAGTTATATACATACAAGACATATATACTAAACCTATCTAAACAACCCATTCAGGAAACTACAAACGAAAAGTCAACTACTGACGTAGTAAGTCATATGCCTACATAAAATAATATACTAAACTCATATAAACAACCCACTCACGGAAACTACAATGAAAAGTCACTACTGACGTAGTAAGTCATATACATACATACATATATACTAAACTCACTACCAACCCACTCAGGAAACTACATGAAAAAGTCACCTACTGACGTAGTAAGTCAATATAACATACATACATATATACTAAACCTCATCTAACAACCCACTCAGGAAACTACATGAAAAAGTCACTACTGATGTAGTAAGTCATATTCATACATACATACTGTATTACATATATGTTAGAAATGAACTAATTTTTTCGACGTATTTGTTCATGTGAATTTTGCAATATAAAGAGTTGTTTCAAATGTGGCGGTATTGAATCTTCTTTTATATACTGTGGATTCATTATGATTATTGGGATACCAATTTTCATAGAATTTGTGGGTATTTGTAAACCACAAGGAAATGTGATATAATTGCCAATGAGACAACTATCCAATGCTGGCAGACAGTTAACATGGGTTGATTCAATGGTTACTGCCTAAGATTTAAGATGAACACTTTATTCATTTATCCAAAAAAGGAGAAAGAGGATGGTTAAGACTTATACAAAAGACTTTTTTAAGTAGTAAAGTACTCCTTAACTAGCACAATAAGAAAAGGCACAAATATCAATTAAAAAAAACTGTTAAATTTTAGTGAAAATTAATTAGCAATTTTAATAGAAATTTTATTTAACATCATGAATCAAAATTTTTAAAAAAAGTAACGCTCATGTATTCTTGTTTAAAAGTATGAACAATTTGTATCTTCCAGGCAGTAGATCTGTTACTCCAGCAGTTAACATCTTCACTGGATGAAGACTTGGCCGATGTTGATGAGTATGAAAGAGGCGTTGATGATGTGAAAAATACGATAAAAACTCCTATCATACCCAGGACTATACAGAAATATTGAG
->URS000051BDF4 rRNA from 1 species 
-ATAGCGTATACTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGGATTTCTAATCTCTCTTGGGGTTCCTTTTCTAAAGAAATGTGCGACCATTCAAGAGAGATTATCCTCGTGCCTAGCCTTTCTCACTTTCATTAGTCAGGAAGGGGACGCACGTCATTTACTGTGAGCAAAATAGAGTGTTCAAAGCAGGCTTAGGCCATGAATATATTAGCATGGAATAATAAGATAGGACTTGGGTCTATTTTGTTGGTTTGCAGACCGAAGTAATGATTAATAGGGATAGCTGGGGGTATTTATATTCCGATGTCAGAGGTGAAATTCTTAGATTTTCGGAAGATAAACTTATGCGAAAGCATTTACCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCGAAGATGATTAGATACCATCGTAGTCTTAACCATAAACTATGCCGACTCAGGATTGGTGAACGTTGATTTAATGACTTCATCAGCACTGTATGAGAAATCAAAGTCTTTGGGTTCCGGGGGGAGTATGGTCGCAAGGCTGAAACTTA
->URS00021995E3 rRNA from 1 species 
-GGTTAAGCGACTAAGCGTACACGGTGGATGCCCTGGCAGTCAGAGGCGATGAAGGACGTGCTAATCTGCGATAAGCGTCGGTAAGGTGATATGAACCGTTATAACCGGCGATTTCCGAATGGGGAAACCCAGTGTGATTCGTCACACTATCATTAACTGAATCCATAGGTTAATGAGGCGAACCGGGGGAACTGAAACATCTAAGTACCCCGAGGAAAAGAAATCAACCGAGATTCCCCCAGTAGCGGCGAGCGAACGGGGAGCAGCCCAGAGCCTGAATCAGTGTGTGTGTTAGTGGAAGCGTCTGGAAAGGCGTGCGATACAGGGTGACAGCCCCGTACACAAAAATGCACATACTGTGAGCTCGATGAGTAGGGCGGGACACGTGGTATCCTGTCTGAATATGGGGGGACCATCCTCCAAGGCTAAATACTCCTGACTGACCGATAGTGAACCAGTACCGTGAGGGAAAGGCGAAAAGAACCCCGGCGAGGGGAGTGAAAAAGAACCTGAAACCGTGTACGTACAAGCAGTGGGAGCACGCTTAGGCGTGTGACTGCGTACCTTTTGTATAATGGGTCAGCGACTTATATTCTGTAGCAAGGTTAACCGAATAGGGGAGCCGAAGGGAAACCGAGTCTTAACTGGGCGTTAAGTTGCAGGGTATAGACCCGAAACCCGGTGATCTAGCCATGGGCAGGTTGAAGGTTGGGTAACACTAACTGGAGGACCGAACCGACTAATGTTGAAAAATTAGCGGATGACTTGTGGCTGGGGGTGAAAGGCCAATCAAACCGGGAGATAGCTGGTTCTCCCCGAAAGCTATTTAGGTAGCGCCTCGTGAATTCATCTCCGGGGGTAGAGCACTGTTTCGGCAAGGGGGTCATCCCGACTTACCAACCCGATGCAAACTGCGAATACCGGAGAATGTTATCACGGGAGACACACGGCGGGTGCTAACGTCCGTCGTGAAGAGGGAAACAACCCAGACCGCCAGCTAAGGTCCCAAAGTCATGGTTAAGTGGGAAACGATGTGGGAAGGCCCAGACAGCCAGGATGTTGGCTTAGAAGCAGCCATCATTTAAAGAAAGCGTAATAGCTCACTGGTCGAGTCGGCCTGCGCGGAAGATGTAACGGGGCTAAACCATGCACCGAAGCTGCGGCAGCGACGCTTATGCGTTGTTGGGTAGGGGAGCGTTCTGTAAGCCTGTGAAGGTGTGCTGTGAGGTATGCTGGAGGTATCAGAAGTGCGAATGCTGACATAAGTAACGATAAAGCGGGTGAAAAGCCCGCTCGCCGGAAGACCAAGGGTTCCTGTCCAACGTTAATCGGGGCAGGGTGAGTCGACCCCTAAGGCGAGGCCGAAAGGCGTAGTCGATGGGAAACAGGTTAATATTCCTGTACTTGGTGTTACTGCGAAGGGGGGACGGAGAAGGCTATGTTGGCCGGGCGACGGTTGTCCCGGTTTAAGCGTGTAGGCTGGTTTTCCAGGCAAATCCGGAAAATCAAGGCCGAGGCGTGATGACGAGGCACTACGGTGCTGAAGCAACAAATGCCCTGCTTCCAGGAAAAGCCTCTAAGCATCAGGTAACATCAAATCGTACCCCAAACCGACACAGGTGGTCAGGTAGAGAATACCAAGGCGCTTGAGAGAACTCGGGTGAAGGAACTAGGCAAAATGGTGCCGTAACTTCGGGAGAAGGCACGCTGATACGTAGGTGAAGCGACTTGCTCGTGGAGCTGAAATCAGTCGAAGATACCAGCTGGCTGCAACTGTTTATTAAAAACACAGCACTGTGCAAACACGAAAGTGGACGTATACGGTGTGACGCCTGCCCGGTGCCGGAAGGTTAATTGATGGGGTTAGCGCAAGCGAAGCTCTTGATCGAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGCGTAATGATGGCCAGGCTGTCTCCACCCGAGACTCAGTGAAATTGAACTCGCTGTGAAGATGCAGTGTACCCGCGGCAAGACGGAAAGACCCCG
->URS0000E9EAA2 lncRNA from 1 species 
-CCCATCTCCGTGGCTGAGGGCCTAGGGAGGAGGGAAAATCCATCCTCAGACACACTAGATCCTCAGCGAGACCTGCTGTGGAGAGCATCAAACGGACCGCACGCGGACCCACCTGCCTTCCAAAGTTTGGGGCGTGAGGAAGCTGAGGCACGTGGCGTTTGGTTATGGCACAGCTGAGGGGTCTGCAGGAGACCCCAGAAAATGCCGCTGAGGACGGATTCACCGACGTCATCAAAAGCCGCGCTGGTACTGACAAGACATTGAAATTGCTGCCGAAGTAAATGACTAGAGGAATAGGTAACTCTTTTTATTTTGTAACCTATTATTTTTCTACCTTTCCTAATAAAGAGAGAGAATTGACAAATACTGATTTAGGAACTGTGGGCTAGTCTAATGTGTTGTTGACAGAAGTTGAAGAGGGTAGTGAAAAAATGATCACGAATTATCGCTAAAGTTAAATTCAAAGTAAATTATTTTCTAACTTCAAAACAAAACTTTATAAACATCTCTAGAAAATGTTCTCTTAGTTATGCCCATTTTGTTTACAGTTGATTAGAAGTAGAATAGAAAAATGACAGAGT
->URS0000292678 rRNA from 1 species 
-GCCTAACACATGCAAGTCGAACGAAGGCTTCGGCCTTAGTGGCGCACGGGTGCGTAACGCGTGGGAATCTGCCCCTTGGTTCGGAATAACAGTTGGAAACGACTGCTAATACCGGATGATGACGTAAGTCCAAAGATTTATCGCCGAGGGATGAGCCCGCGTAGGATTAGGTAGTTGGTGTGGTAAAGGCGCACCAAGCCGACGATCCTTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCAATGCCGCGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTTACCCGGGATGATAATGACAGTACCGGGAGAATAAGCTCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGAGCTAGCGTTATTCGGAATTACTGGGCGTAAAGCGCACGTAGGCGGCTTTGTAAGTAAGAGGTGAAAGCCCAGAGCTCAACTCTGGAATTGCCTTTTAGACTGCATCGCTTGAATCATGGAGAGGTCAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAAGGCGGCTGACTGGACATGTATTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGATAACTAGCTGTCCGGACACTTGGTGTTTGGGTGGCGCAGCTAACGCATTAAGTTATCCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCTGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGCAGAACCTTACCAGCGTTTGACATGGCAGGACGACTTCCAGAGATGGATTTCTTCCCTTCGGGGACCTGCACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGCCTTTAGTTGCCATCATTTAGTTGGGCACTTTAAAGGAACCGCCGGTGATAAGCCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTACGCGCTGGGCTACACACGTGCTACAATGGCGGTGACAGTGGGCAGCAAGCACGCGAGTGTGAGCTAATCTCCAAAAGCCGTCTCAGTTCGGATTGTTCTCTGCAACTCGAGAGCATGAAGGCGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCAGGCCTTGTACACACCGCCCGTCACACCATGGGAGTTGGATTCACCCGAAGGCGTTGCGCTAACTCGTAAGAGAGGCAGGCGACCACGGTGGGTTTAGCGACTGGGGTGAAGTCGTAACAAGGTAGCCGTAGGGGAACCTGCGGCTGGATCACCTCCT
->URS00013010D6 rRNA from 1 species 
-TACAGAGGTCTCAAGCGTTGTTCGGATTCATTGGGCGTAAGGGGTGCGTAGGCGGCGCGGTAAGTCGGGTGTGAAATCTTGGAGCTTAACTCCGAAACTGCATTCGATACTGCCGTGCTTGAGGACTGGAGAGGAGACTGGAATTTACGGCGTAGCGGTGAAATGCGTAGATATCGTAAGGAAGACCAGTGGCGAAGGCGGGTCTCTGGACAGTTCCTGACGCTGAGGCACGAAGGTCAGGGGAGCAAACGGGG
->URS00004F080A rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACGGACGAGAAGCTTGCTTCTCTGATGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGTAGCTAATACCGGATAATATTTTGAACCGCATGGTTCAAAAGTGAAAGACGGTCTTGCTGTCACTTATAGATGGATCCGCGCTGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCATAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACATATGTGTAAGTAACTGTGCACATCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGCGCGCGTAGGCGGTTTTTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGAAAACTTGAGTGCAGAAGAGGAAAGTGGAATTCCATGTGTAGCGGTGAAATGCGCAGAGATATGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGTCTGTAACTGACGCTGATGTGCGAAAGCATGGGGATCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAAATCTTGACATCCTTTGACAACTCTAGAGATAGAGCCTTCCCCTTCGGGGGACAAAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTAAGCTTAGTTGCCATCATTAAGTTGGGCACTCTAAGTTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGATTTGGGCTACACACGTGCTACAATGGACAATACAAAGGGCAGCGAAACCGCGAGGTCAAGCAAATCCCATAAAGTTGTTCTCAGTTCGGATTGTAGTCTGCAACTCGACTACATGAAGCTGGAATCGCTAGTAATCGTAGATCAGCATGCTACGGTGAATACGTTCCCGGGTCT
->URS000069B5BC tRNA from 1 species 
-GCCTGGGTGGCTCAGTCGGTTGGGCGTCCGACCTCAGCTTAGGTCATGGTCTCATGGTTCATGGGTTCGAGCCCCACCTCAGGCT
->URS000209731F rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTGCAGGGTACTCGAGTGGCGAACGGGTGAGTAACACGTGGGTGATCTGCCCTGCACTTCGGGATAAGCCTGGGAAACTGGGCCTAATACCGGATAGGAGCCATTTTTAGTGTGATGGTTGGAAAGTTTTTTCGGTGTAGGATGAGCTCGCGGCCTATCAGCTTGTTGGTGGGGTAATGGCCTACCAAGGCGGCGACGGGTAGCCGGCCTGAGAGGGTGGACGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAAGATTGCACAAGGGGCGCAAGCCTGATGCAGCGACGCCGCGTGGGGGATGACGGCCTTCGGGTTGTAAACTCCTTTCGCTAGGGACGAAGCTTTTTGTGACGGTACCTAGATAAGAAGCACCGGCTAACTACGTG
->URS0001E64AC9 rRNA from 1 species 
-AGCGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGAACCTTTCGGGGTTAGTGGCGGACGGGTGAGTAACACGTGGGAACGTGCCTTTAGGTTCGGAATAACTCAGGGAAACTTGTGCTAATACCGAATGTGCCCTTCGGGGGAAAGATTTATCGCCTTTAGAGCGGCCCGCGTCTGCTTAGCTAGTTGGTTGAGGTAATGGCTCACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGATGATCAGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTGGGGAATCTTGCGCAATGGGCGAAAGCCTGACGCAGCCATGCCGCGTGAATGATGAAGGTCTTAGGATTGTAAAATTCTTTCACCGGGGATGATAATGACGGTACCCGGAGAAGAAGCCCCGGCTAACTTCGTG
->URS0000A2C0F7 rRNA from 1 species 
-CACCGCGGTTATACGAGAGGCCCAAGCTGACAGCTACCGGCGTAAAGAGTGGTTAATTCACCCCCACAAACTAAAGCCGAACATCTCCAAAGTTGTAAAACGCACTCGAAGGTATGAAGATCACCCACGAAAGTGGCTTTATAACCCTTGAACCCACGAAAACTAGGGAA
->URS0000BA4FCD rRNA from 2 species 
-CGTGGGAATACCTGCCCAGTATGCGGGGGATAACTATCTGAGACTCAGATGCTAATACCGCATAACAACTTCGCCCGCATGGTCCGAGTTTGAAAGATGGCTTCGGCTATCACTTCTGGATGGTCCCGCGGCGTATTAGCTAGATGGTGAGGTAACGGCTCACCATGGCAATGATACGTAGCCGACCTGAGAGGGTAATCGGCCACATTGGGACTGAGACACGGCTCAAACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCACAATGGACGAAAGTCTGATGGAGCAACGCCGCGTGAGTGAAGAAGGGTTTCGGCTCGTAAAACTCTGTTGTTAAAGAAGAACATATCTGAGAGTAACTGTTCAGGTATTGACGGTATTTAACCAGAAAGCCACGGCTAAGTACGTGTCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGCGAGCGCAGGCGGTTTTTTAAGTCTGATGTGAAAGCCTTCGGCTCAACCGAAGAAGTGCATCGGAAACTGGGAAACTTGAGTGCAGAAGAGGACAGTGGAACTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAAGAACACCAGTGGCGAAGGCGGCTGTCTGGTCTGTAACTGACGCTGAGGCTCGAAAGTATGGGTAGCAAACAGGATTAGATACCCTGGTAGTCCATACCGTAAACGATGAATGCTAAGTGTTGGAGGGTTCCGCCCTTCAGTGCTGC
->URS00004CE42D rRNA from 1 species 
-GATCAGGCTCAGGATGAACGCTAGCTACAGGCTTAACACATGCAAGTCGAGGGGCAGCATGGTCTTAGCTTGCTAAGGCCGATGGCGACCGGCGCACGGGTGAGTAACACGTATCCAACCTGCCGTCTACTCTTGGACAGCCTTCTGAAAGGAAGATTAATACAAGATGGCATCATGAGTCCGCATGTTCACATGATTAAAGGTATTCCGGTAGACGATGGGG
->URS0000251C9B rRNA from 1 species 
-GACCAAGGAGTCTAGCATGTGCGCGAGTCATTGGGACATAACTAAACCTAAAGGCGTAATGAAAGTAAAGGTCTGCCTTGCGTAGACCGAGGGAAGATGAGCGGTTTGCCCATAAAGTGGCCGCTCCGCATTCCCGGGGCGTCTCGTTCTCATTGCGAGAAGAGGCGCACCAAGAGCGTACACGCTGGGACCCGAAAGATGGTGAACTATGCCTGGTCAGGACGAAGTCAGGGGAAACCCTGATGGAGGTCCGTAGCGATTCTGACGTGCAAATCGATCGTCGGAACTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCCTCCGAAGTTTCCCTCAGGATAGCTGGCGCTCGTTGCGTACGAGTTTCATCCGGTAAAGCGAATGATTAGAGGCATTGGGGTCGAAACGACCTCAACCTATTCTCAAACTTTAAATGGGTGAGATCTCCGGCTTGCTCGAACTCATGAAGCCGCGAGACTCGAATCAGAGTGCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGCTGTGGGATGAACCAAACGTCGAGTTAAAGCGCCTAAATCGACGCTTATGGGATACCATGAAAGGCGTTGGTAACTTAAGACAGCAGGACGGTG
->URS0000A30B64 rRNA from 1 species 
-CTGGCGGCGTGCCTAATACATGCAAGTCGAGCGGAATGATGAAGAGGCTTGCTTCTTCTGATTTTAGCGGCGGACGGGTGAGTAACACGTGGGCAACCTACCTTGTAGATTGGGATAACTCCGGGAAACCGGGGCTAATACCGAATAATCCATTTTGCTTCATGGCGAGATGTTGAAAGACGGTTTCGGCTGTCACTATAAGATGGGCCCGCGGCGCATTAGCTAGTTGGTAGGGTAATGGCCTACCAAGGCGACGATGCGTAGCCGACCTGAGAGGGTGGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGGCAGCAGTAGGGAATCTTCCACAATGGACGAAAGTACTGATGGAGCAACGCCGCGTGAGTGAAGAAGGTTTCGGTATCGTAAACTACTGTTGTAAGGAAGAACACGTACGAGAGTAACTGCTCGTACCTTGACGGTACCTTATTAGAAAGCCACGGCTAACTACGTG
->URS00015CBD71 rRNA from 1 species 
-TAGGGAATCTTCCACAATGGACGCAAGTCTGATGGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGACCGTAAAGCTCTGTTGTTGGTGAAGAAGGATAGAGGTAGTAACTGGCCTTTATTTGACGGTAATCAACCAGAAAGTCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGCGAGCGCAGGCGGAAGAATAAGTCTGATGTGAAAGCCCTCGGCTTAACCGAGGAATTGCATCGGAAACTGTTTTTCTTGAGTGCAGAAGAGGAGAGTAGAACTCCATGTGTAGCGGTGGAATGCGTAGATATATGGAAGAATACCAGTGGCGAAGGCGGCTCTCTGGTCTGCAACTGACGCTGAGGCTCGAAAGCATGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCATGCCGTAAACGATG
->URS0001547F59 rRNA from 1 species 
-TCGGGAATTTTGCTCAATGGGGGAAACCCTGAAGCAGCAACGCCGCGTGAGGGATGACGGCCTTCGGGTTGTAAACCTCTTTTCTCAGGGACGATGATGACGGTACCTGAGGAATAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGATTTACTGGGCGTAAAGAGCGCGCAGGCGGTCGTGCAAGTCGAGTGTGAAAGCCCCCGGCTCAACTGGGGAGGGTCACTCGATACTGCTCGACTCGAAGGCGGGAGAGGGAAGTGGAATTCCCGGTGTAGTGGTGAAATGCGTAGATATCGGGAGGAACACCAGTGGCGAAGGCGACTTCCTGGCCCGTTCTTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACG
->URS000083C0E2 tRNA from 1 species 
-CAGAACATAATTAAATTAGAATGCTGGCTTTGGGGGTCAGTTGTGGGGGTAAGAGTCCCCCTGTTCTGA
->URS0000ABDE67 miRNA from 1 species 
-TTTGGTTTGAAGGGAGCCCCT
->URS000003005D rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGGACAGATGGGAGCTTGCTCCCTGATGTTAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCTGTAAGACTGGGATAACTCCGGGAAACCGGGGCTAATACCGGATGCTTGTTTGAACCGCATGGTTCAAACATAAAAGGTGGCTTCGGCTACCACTTACAGATGGACCCGCGGCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTTTTCGGATCGTAAAGCTCTGTTGTTAGGGAAGAACAAGTACCGTTCGAATAGGGCGGTACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGCAGGCGGTTCCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAGGGTCATTGGAAACTGGGGAACTTGAGTGCAGAAGAGGAGAGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCTCTGACAATCCTAGAGATAGGACGTCCCCTTCGGGGGCAGAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGATCTTAGTTGCCAGCATTCAGTTGGGCACTCTAAGGTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGACAGAACAAAGGGCAGCGAAACCGCGAGGTTAAGCCAATCCCACAAATCTGTTCTCAGTTCGGATCGCAGTCTGCAACTCGACTGCGTGAAGCTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAGAGTTTGTAACACCCGAAGTCGGTGAGGTAACCTTTATGGAGCCAGCCGCCGAAGGTGGGACAGATGATTGGGGTG
->URS00020EF123 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCATTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTCGACTTTGGGATAACTTCAGGAAACTGGGGCTACTACCGGATAGTAGCTCCTGCTGCATGGAGGGGGGTGGAAAGTTTCGGCGGTCGGAGATGGACTCGCGGCTTATCAGCTTGTTGGGGGGGTAGTGGCGTACCACGGCTTGGACGGGTAGCCCGCCTTGGAGGGGGAGCGGGCACATGAGGACTGCGATACGGCGCAGTGTGGAACATGGGGCAGCAGGGGGGAATATTACGCAGCGGGCCGGCGCGTAATGCAACAACGCCGCGTTCGGAATGACCGTCTACGGGTTGTAAACCGCTTAAGCCTGAGACGAAGCGTGATTGACGGTAACGGGTAAAGAAGCACCGGCTAACTACGTG
->URS00000CB0F4 tRNA from 1 species 
-ATTAAAGTGGCAGAGTAGTGCATTAGATTTAAGCTTTAAACATAGAGAAGTTCTCTTTAATA
->URS0000AF4368 rRNA from 1 species 
-AACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGAAGATTTATCTTAGTGGCGAACGGGTGAGTAACGCGTGGGAATCTGCCTTTCAGTGGGGGATAACTCAGAGAAATTTGAGCTAATACCGCATACGACCTTCGGGTGAAAGATTTATTGCTGAAAGATGGGCCCGCGTTAGATTAGGTAGTTGGTAGGGTAAAGGCCTACCAAGCCTACGATCTATAGCTGGTTTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGGGAAACCCTGATCCAGCAATGCCGCGTGAGTGAAGAAGGCCTTCGGGTTGTAAAACTCTTTCAATGGGGAGGATGATGACGTTACCATAGAAG
->URS000012F352 misc_RNA from 1 species 
-TGTACTCGATCCAGAATCATTCCCAAAAGGTCGGAACGAGGTATGTGGCTTTCAAACTAGGTTCTGGGTTCATAAAAGACCTGAATCAGGAACAAGGGATATTAGCTCAGGTGGTTAGAGCGCACCCCTGATAAGGGTGAGGTCCCTGGTTCGAGTCCAGGATGGCCCACCTGCACAGGTGGCAAAAACAAAAAAAACAAGCGAGGAATCCCCACCTTATCTTACTTATATAGTAAGAAAGAATGCTGGCTCTGAGTACAGAGTCCGAAGGAACCTTGAAAACTGCATAGAGCTAGGTGAAAAAGCCAAAAAAAAGGACCGCAAA
->URS000182AB58 rRNA from 1 species 
-TACGTAGGGGCCTAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCTCGTAGGCGGTTCGGTAAGTCAGGTGTGAAATCTCCACGCTCAACGTGGAGGCGCCACCTGAAACTGCCGTGACTCGAGTCCGGTAGGGGAGTGTGGAATTCCCGGTGTAGCGGTGAAATGCGTAGATATCGAGAGGAACACCTGCGGCGAAGGCGGGTTGCTGGGCTGACACTGACGCTGAAGTGCGAAAGCTAGGGGAGCGAACGGG
->URS0001D66A4A rRNA from 1 species 
-AACGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGCCCTTTCGGGGGAGCGGCGGACGGGTGAGTAACGCGTGGGAATATGCCCTTCTCTACGGAATAGCCTCGGGAAACTGAGGGTAATACCGTATACGCCCTGTGGGGGAAAGATTTATCGGGGAAGGATTAGCCCGCGTTGGATTAGGTAGTTGGTGGGGTAATGGCCTACCAAGCCGACGATCCATAGCTGGTTTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATCTTAGACAATGGGGGCAACCCTGATCGAGCCATGCCGCGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTCAGCTGGGAAGATAATGACGGTACCAGCAGAAGAAGCCCCGGCTAACTCCGTG
->URS000233F9F7 lncRNA from 1 species 
-CAGCTCAAGGCTGTAGGAGGAAGAAAAATCTAGTCCCTGGGGGTACTGATGAATCAGTTGGATGGTGGGCGTTGGACTGTGAATTCCTGATGCCTCTGGGTAAACTCTGGAGGAAATTCTGTTTCATTACTTGCACTCAGCCCTCCTATTTTGTACTAAGGTATTCTTGAATACAAGTGCACCGGCCAAAAAAGTAAACTTACGCATAAAAAGAAAGGCTCTCTTCCTTCCAAGAATGCTGAACACCTTTGAAGTCTCTGTTGCTGCCTCATCTTTTAGATACAATCATTGATTATGTATTTTTGGCATCGTCCTGAACTTTGTTTCATTTCCTTCACAGTTGAATGTGCAGTTGGCTTTGTCCACTCAGTGATGGTCCTTGTGACTGTTCTTGGCTTTTCTGTTGTTTTTCCATCTTTCTATAGGAAGCTTGAGACCGATACTCATCGTTTGCTTTCAGCACCTTAATTTTGCTTTGTTCATTTTTGTAAAGTAAGGGCAAATGGCCACCGGAATGTACAGTGATTAAAGAAGCAAACTCTGTCAAAGATGGTGATTAGTGGCCAGCCAGTCCCTCTCAGGATCACTGTATTAAAAAGTGCTCATTTGCCAGTGACATTTTTTTTTGGTTTTGGTTTTTTTTTTTTTTTTTTTTTTTGAGACTGAGTGTCACTCTGTCGCCCAGGCTGGAATGCAGTGGCCTGATCTCAGCTCACTGCAACCTCCACCTCCCAGGTTCAAGTGATTCTCGTGCCTCAGCCTTCTGAGTAGCTGGGACTACAGGCGCCCAATACCATGACTGGCTAATTTTTTTTTTTTTAAATTTTAAGTAGAGATGAGATTTTGCCATGTTGGCCTGTTTGGCCTTATACTCCTCATCTCAGGTGATCCACCTGCCTCGGCCCCCCAAATGCCAGTGACATTTGTAGGTGGATTCAGATTAAGGTGGGTAGCTTAGTTGAGGCGTCTCAACCCTTTTCTGTGCACTCTCTCAAGATGATTTCTGAACACACAACTATAAGTGCATGAGAACTTAAATACGTGTGCTCTTATGCTAATTATACACAAAGTAAAAGTTTTTTCACAAGGAGAATTTTTTTCTCCAGCAAATAGCTCGCTCACCCTAGGGGTACATACACCCCACTTTAGAGACCCTCAAGTTACAGTGGTATCATTAAACGATCCATAAAGGAGTGGGTTTAAGAAAGCTGATACAGGAACATGTTTGAAATAATACATTTTCTCAAGGGTGTCCTCCAACCATTTTCTTTGATAAATTATATTTCTGCCCATTGTTGACTTGAAATTGTCCTCACCCCTCTACCAAGTTCACCCAGTGTATTCTGAAGGAAAATGAATGAATATGGAAACCTCTCTCATCCTAGGCAGTAGAGCGAGGGAAGCTGCACTGGCTGAGAGGCTGTGGAACCGGATGAAAAAGCAGCCCCTGAGTCCTGTGGCGTTGGCTGTGAGTCGGCCACGTGCTTGCTGTGTGCTTTAGGAAAGTTACTTAATTTCTCTGAGCTTTAGTTTTCTCCCTCATAAGTAGGCTTGCTGTGAAAATGAAGTGAAATCACATTAATCTGCATGAGCATTTAACACGGTGCCTGGTGTACATCAGGGGTGTGACAGTGAGTGCTGGCTGCTGTAGTAATTGAATGCTTAGCTACGTGCCGGGCCCTTTGCCAGCTACAGCTCATGTGAGACCTCATGTTCAGTCTTGGCAGTAACCCAGCAAGGTAGGCATTTTACATGTGAGGAGCCTGAGAAATTCAGTCTTGGCCTGGATCACAGAGCTGGTATCCAAATTCAGGTCCGAGGCCAAAGCCCAGATCTTTGCACTACACCTTGTTGCCTGGCACAGGTGAGAGTGCCCAGCCCATAGTGGGTGCGCAATATCTGTTTCTATTTGAATGACCCAGGCAGGCGGTTAATAATGCTTGTGATTTCTTTGAGAGAGAAGTAAGTTCTTGTCTTTGGTGGGGGAAGCATCAGGTGACCAGCATTTGTCCAGAGCCTGGTACCCATCCTCTCCCAAGCCCAATCAGTGGTGCTTTCTCAAAAAGAAACCATCTCCTGACCACTTTGGCCATATTGGGCCTTTGCTCCTCTTCTGTAGCTATTGATAAGAGGGCTGTGGGCAGTTAGTGATAATCAAGGTCGTATCCCAACTAAGTGACAGAGCTGAGACAGTTAAGTTCCAGGACAAGTGTGTTGATCTCTGTACCCACTTGTGCCAGGTGCCTGGGGAGGTAGGGGCATGGCTGTCTGAGGGTGGAGGGGTGAGTAGGGGGCCTGCAGTGTGCTGTGACGCCTGGGAAGGGGATTCTAAGCCATTTCCCATCAGCCGTTTACTAAGTAGCCTGGGGATCTTGTTAAAATGCAGATCCTGATAGATTAGGGCTGGGGTGCTGCCCAAGATTCTACATTTCTAAGAGTCCCTGGATGACGGTGGCATTCACAGACCACAGCTTCTATGTGAGGGAGAGCAGTTGGGTTTCTGTCTGCCTGCCGCACCTGATCAGTAGTTAGTGCCTGCATGTGTGGCGGCCAGAATTTTACTTGGGGAGACGCTCGGCTCCTAGCACCCTCTGTGGTAGGGGTTTTCCAGAGTGTGGGCATTACCCCAACTGTCTCTGCAGACGGCTTCCTGCATGTTTCCCACAAGCGCTCAGATGGCTGAATTGGCAAGTCTGTGGTGCTGCTCTTTGGGGCCACCTCGTTCTTTGCCTTTCCCTCCCCTTAGCGATGTGTCCCATCCGTTGCCTACAGTCAAGTCAGTCCACATGTTTAGGCTAAGGTGGGCATGACCGAGTGGCCTTCCCCCGGGAAGACCAGTGTCGTAACTGGAATTAAGTTGTGGAACATAAGAGTCAAGGCTCGTGTCTGCTGTGAACTGGAGTTGAGGGAATGTTTGGGGATCCCACCTGGTATCAGTAAGGGAACCATGGCGACGGCCAGCCTTGCCCATGTGAGGCATTTGCTTTGTCAGGCCTTCTCAGTAGTGGAGAAGGGAGGAAGGAGAATGCAGCTCTTTCAGTGCTGTCTAGCAGTGCCCAAGAGCCGTGATTGGGCACCTCACTTAACGTCTAACTTCAGATTCACTCTTGGGCATTCCTGTCTTCCTCTCCAATCTTGAATGGATGTTGGCTTCGATAATGTCATCCTGAAGTTTCTTTGTCCACACAGCCCTGGCTGGTTGTTAATAAGCTGTTAATGCAGCCTTGCACTCAGGAAGCCCTGATGTTTAAAGGAACTGTGTCTTTGTTCTTCCTCTCTTCCCTCTTTCTCTTAGTCCCACTTTATCTCTTCTTTCTCTTCCTCTCCCTCCTCCTTTTCCCCTCTCCCTCCTACTCTCCCCCTTTCTCTCCTCCTTCTCTAAGAAACCCAGTCTTAATTCCACACAATGCATGCACATGCAGTAGCTTCTCTGCTTGAGTGAGCTGGTGTGATTAGGTTTTCTAAACATGCACATTGGCCTTGCTACTTGTCCTTTTATTCCCTTCCCACAGACCATAAACCAAGAATTATTTTTATTTGTATTATTTTGATTTTTTTAAAGTAAAATATTAACTTTTCCTCTTTGAAATAAATTCCCATTTGGAACATCAGCATACAGTTTGAACATTTATTCGCCTCCTGAGCTTGTACAACAGTCGTGGGAGTTGCTGCAGAAGCAAGCGAAAAGCCAGATGAGCGCTTCTAAACTTAGAGAGAGGGAGAGCGCCTCATCTCTTCCATTTTCCAGGTATTCCTGAGATGATTTATTGGAGCTCAAAGCTTTGGGAGAGTTGGGGCCTTCCATTCCCTCCAGTAAATACTTGTTTTTCTTCCACCGCTGAGGCAAATGCGGGGTGGCTGATCACCTGGCAGACATCTTAGGAAACAGGAGCACCGGTCTGGGAAACTGCTGGCCTGGCCTAACACCTGGCGCTGTGGTGCAGGCAAGAGGGCAGCCACTGAGGATTCTTGAGGAGAGAGAGACCATAGAATGAATGAAAGAGTTGGAAAGACTTTAAAGCTCTGGGAGGCTGAATCCTTTATTTCGCTGGAAGAAAAACTGAATGCCAAGAGGGCCTCACTTTCCCCAAAGCTATACAGCCATCAGGGGCAATGCTGGGATTCCCCCATGGATCTCTTGACTCCTAATACAGTGCTCTTTCTGATATGCCATCTGGCTCCATAATGAACATTGTGTTCCAGGAAAATCAGTCTGCGCTGAACAGGATGGAATTGGGGCAGGACGTCCAGTGAGGAGGACATTGAGGCAGTAGAGCAGTTGATTGCCGAATGACCACCTACCCTGACTTAAAAGATCAACCTCAGGGAGGATTGGAGCTTTCTAGAGTCTCTTGGGACAGCAGAAGCACAGGCCGGGTTGGACTGAATCTTTAAGTGGACATGAGGGACAAAGTACCTCCTGTTGGTAAACATCTCACCACCAACCCACTGTGGTGGCTAAAATCCCACCTTTAGTCCCAGCAACATATGAGCATGTCACCAGGAGGTCTTCACAGGCCTGTCTGCCACCTGAGTGTAGACATCTTTTGGCCCTGGAGCCCAGAGAGGCTGAATGTGGAGAGGGTGGAGAGAGGTCTGTAGTCCTCAGAGAAGACTTGCAGCTTTTTCAGAGCCACCAACCCATAAAAAAAAAAATCCCCAAACAGAAAAATCCTAACTGTGGTGACCAGGTACCTCCTGAGACATGAAGCCTCCACTTACCTGGACCCTGGAGGCCTCTCCGGGCACAGCTGCCAATGTTGATCTTAGATAAGACCACCAGCAAGTAAACATCCACTGTGCAAAGCTGTGTTATCTTTGGGGAACTGAAATGTCCCCTGGGAGTTGGAAACTCCCCTAGCCACATACCACAGAGTTGAGGAAGGAAGAGCTGATGGACGGAAGAACCATGGCGGGAGGAGTCATCCGGAAGCTACCTCGCTGCCCTGTCAGTTACGGAACAGAGGAGAGATGCCGGCTGGAGGACACAGCAAATTTGAACCAAGAGGAGCTTGGAGGAAGCCCGAGCGACCTGGAGGGGACTGGCTGACCTTCCTCATTCTTTTCAAGTGTGAATAATAACCAAGCCCAGTTTGGCAACTCCTTGAGGGTGAGGACGAAGCCCCATTCTCCTTTTTGGAACTTGGTGGGGCTCAGGAAGCAGGTTCTCTCCAGTCGGTGGCTTTCCTTTCTGTTGCGGGTCTCTTGAGGGCCTGCCTTCATGAAGGCACATGAGTGACTCATCATTTGTGAATTAATTGCTATATGTGAAGGGCATCTGAGAACAAATTATCTTCATAGACTTTTCATTATAATTTTATTTGTACTGATAATTAGTTGGTTTAGCAAGCTCTTTTTTCATAGATTTGGCTAAACTTCAGTCTGAAAGAGGCAAATTCTGGGGTTCTAGAAAGAGATTTTATTCTTTGATATAGGGCTATTTGGTGGGGTTGCTTTTTGTCCTAGTTGTAGCTTTTATAATTTCGAGATTCACATTTTGCAATAGAAATATACAGGCATACCTTGGAGGCATTACAGCTTTGGTCCCAGACCACAATGAAGCAAGTCACACGAATTTTGTTGGTTTCCCAGTAAATATAAAACGTATGCTGATACCATACTATAGTCTAAGTGTGCAACAGCATATGTCTAAATGAATATACATATATATTTTTTTGAGACAGGTTCTTGCTCTGTCACCCAGGCTGGAGTGCAGTGGCACTATCATGGCTCACTGCAGCCTCCACCTCCCTGGACTAAGATGATCCTCCCACCTCAGGCTCCCAAGTAGCTGGGACTACAGGTCACACCACCACACCCAGTTAATTTTTGTATTTTTTGTAGAGACAGAGTCTTGACATGTTGCCTAGGCTGGTCTTGAACTCCTGGCTTAAGTGATCTGCCTGACTTTGCCTCCCAAAGTGCTGGGATTACAGATGTGTAGTCTTTGAAATCCAGTGTGTGTTCTTACAGTGCATTTCAATTTGGACTAGCCATGTTTCAAATGCTCAGCAGCCACATGCGGCTCATTCTAGATAGGCGGCCATCGCTCTTAAATCCTCCCTGACCTTAGCCATGCTCTCTCATCCCTCCTCTTCGCCAAGCTCTGCCTCTCTCACTGGGGCTTCCCTAGCCTCCGGCCATCTTGGGGCCAAAGCTCTAACACTTTGCCTCTCTCGTGTCTTCTGTTCCCCTCCAGTGGCTTCTGCTTTCTGCCTTAAAATACACCCAGGTTCCTAATCCTGAAAACGTCTGTTGTGCACCGATCCCACCCTCCCCTCGTGTTACCATCTCCATTTCCTTCCCCTTTCCTTGTGTCCTCTTCTTTGCTGTGTCCTGGCCCCTCAAAACTTGACCTTGCCTCTCATCCCCACTGCTGTACTGAAACTGTTGTCTCAGCGTTGCTGATCATCCAGCCTTTTAGTCTATGGACCGCTAAGAGCCATAGGACGACCTCAGGGTGGGACGTGGCTTGGAGGGCCATCTCGTCTCAATTTCCAGATACAGACCTGTGTTGGGTTGTGTTGGATTCATGAGGAAAGCTTCATAAGTTTTATGCACGTTTATAAGACTCCATCCTTGGATTCTGATCCAGTAGCTCTGGCGTGGGGGCTTTAGAATCTGTTTCAAGTATCTCAGGTAATTTTGATTATAAATTACCAAGTATCCCAGGTAAATTTTGATTATAAATGCTTGCTTCCAGCAGAAAATATAAACATATGGAAGATGAAATCTTTCTCTCTGAATAACCCAATTCAGTTTCCACTCGTGAATATCTTATATAACCGTAGTACATTTATCAAAATTAAAACACCAGTGTTAGCACATTACTGTTAATCTCCAGACTATTTGTAAGTCACCAATTTTTCCATTGTCCCATCTGTTCTTCCTTTTCTTTCTCTTGTCATAACCACTTTTAGAGGGTTTTGAATGGTATCATTTTGTCTTCACCGTCGGCTTATTAGCTATACTGTACTGTTCTATTCTTTGAGTGGTTGCTCTAGGATTTACAAATATGACTTCAACATATTGCAGAATACCTTCAACAACTACGATATCCTTTCACAGATAGTGTAAGAACTGCACCACAGAATGCTTTCATTTCCCCACTTCTATTCTTTGTGATATTATTGTCACACATTTTATTTTTACTTAAGGTATGAGCCCCACAATGCATGTTAAATAGCCAAAGTTTTTAGACAGATTAAAGAAATTAAGAAAAAGTCTTATGAACTCAGGTATTTACTATCGTGTTGCTCCTTATTCCTTAGTGCAGATCCATTTTTCTTTTCTTTTTTATTTGAGACAGGGTCTCACTGTGTCACCTGTGGTTGAATGCAATGGCGTGATCTCAACTCACTGCAGCCTCCACCTTCTGGGCTCAACTGATCCTCCCACCTCAGCCTGTAAAGGGATATTTGCAAAGGGATATCGGAGTTGTTGAAGGTATTTGCAATATGTTGAAGTCATATTTGTTTTTTTTTTTTTTTTTTTTTTTTTTTTGAGATGGAGTCTTGCTCTGTTGTCCAGGTTAGAGTGCAGTGGCGTGATCTTGGCTCACTGCAACCCATACCTCCTGGGTTCAAGCAATTCTCCTGCCTCAGCCTCCTGAATAGCTGGGACTACAGGCATGCGCCACCACACCCAGCTAATTTTTGTATTTTTGCTAGAGATGGGGTTTTGCCATGTTGGCCAGGCTGGTCTTGAACTCCTGACCTCAAGTGATCCATCTGCCTTGGCCTCCCAAAGTGCTGGGATCACAGGCATGAGCCACCGCGCTGGGCCTGAAGTCGTATTTGTAAATCCTAATTTTTGTATTTTTTTTTGTAGAGACAAGGTCTCACCATGTCGGTCAGGCTGGCCTCACACTCCTGGGCTTAAGCAATCCTGCTGCCTCAGCATCCCAAAGTGCTGGGATTACAGGTGTGAGCCGCTGTGCCCAGCCTGTTTTTCATCTAGTATTTTCCTTCTGCCTGAAGGAAACTTCTTTGACATTTCTTGTAATGGCAGCTCTGCTGGTGATTAATTCTTTCAGCTTTTATTTGAAAGAGTCTGTATTAAAATATATATATATTTTCACTAGGTATAGAATTTGAGGCTGACAGGTTTTTTTTTTTTTAATTTTTTCAGTACTTTAAAGATGTTAATTTTCTTATGGTTTGCCTACTTTCTGATGAGAAGTTGGCTGCTGCTCCTTTTTTTTTTTTTTTTTTTTTGAGACAGAGTCTTGCTCTGTCGCCCAGGCTGGGGTGCAGTGGCGTGATTTCGGCTCACTGCAACCTCCACCTCCCGGGTTCAAGCAATTCTCCTGCCTCAGCCTCCCGAGTAGCTGGGATTACAGGCACCTACCACCATGTCTGGCTAATTTTAGTAGGGATGGGGTTTCACCATCTTGGTCAGGCTGATCTCGGACTTCTGACCTCGTGATCCACCCGCCTCAGCCTTCCAAAGTGTTGGGATTATAGGCGTGAGCCACGGCGCCTGGCCTGCTGCCACTCTTATATTTGTTCTTCTGGATGGAATGTCTCTTTTTTTTCTGGTTGCTGGGAACATGGGCTATTCCCACCCCTATGTGAGCTCCAGCTGCTTGGTCTATTGGTTTCACCCTTCATATATGAAGGTTAGTACTTGTCCAAAGACTCCAGGAGACTCTTCAGCTCTCAGGAGCTTGCTCTGTGCAGCTTCCTCCTCTCGTCCTCTTCTGCCTTCAGTTCTGCCTTGGTCTTTTTTGTTTGTTTGTTTGTTTTTTGAGACAGAGCCTTGCTCTTTCGCCCAGGGCAGAGTGCAGTGGTGTAATCTTTGCTCACTGCAACCTCCGCCTCCCTGGTTCAAGCAATTCTCCTGCCTCAGCCTCCCGAGTAGTTGGGATTACAGGGGTGCAACACCACGCCCGGCTAATTTTTGTATTTTTAGTAGAGACAGGGTTTCACCATGTTGGCCAGGCTGGTCTCGAACTCTTGATCTCAGGTGATCTGCCCGCCTTGGCCTCCCAAAGTGCTGGGATTACAAGCGTGAGCCACCGCGCCCGGCCTGCCTTGGTCTTCCTGAACTCTGACTTCTGTCTCTTCAACTCCTGGAGACTACTAGACTCTGGAGTCTCTCTTTACCTTTTGGCCCAGAAACTGCTTCTGGGTAGTAGTAACCTGGTGCATTTGTTG
->URS000117373B rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGAGCGGCGGACGGGTGAGTAATGTCAGGGAAACTGCCTGATGGAGGGGGAGAACTACTGGAAACGGTAACTAATACCGCATACCATCAGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAATGGCTAACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCAACCTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGAGGAGGCGTTACTCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATTC
->URS000199CEE7 lncRNA from 1 species 
-ATGAGCCTTGACAAAACTGTGGACAGCATACTGCTAAGCCTCACATTGTTCAGCCTTCTGATTTTCCTTGGAAGTTTGCTGATATGTGCGTGTAGAAGGTATAGATTCCTGGAAGTTATAACCATGCCCTTTCCAGCTCCTACAGATAAAGTTACAACGTGGTTAGCTACAGATGAGACTCACCATCAGAAACAAAATTCAGTGCAAATGGAGATGCAGTCAGAGGTCATACTGAGAATATCAGAAGATAATGGAGATGAGGACATTCAACAACATACACATTTGAAAGAATCTGAAGACCTGAATTAATGCCTCCTTAGAGGAACTTGGTCAAAGCAGGGACTAGACAGGCAAAAGAGTAATGCATGTGTGTCAGACTGGAGTTTCCAAGACTTGCTGAAATTTTAATAGATCTTCCTGGCATGTGTAATGGATAAATGAGTGAAAGAAGCTAACCCAAGAAAAGTGAACAGACAGATCAAAACTGGTACCACATCATCTGGCTGGGGACTTTGCTAATGTGACAAAACTGATAAGAGTCTATAGCAGCATATAGATGTCCAGGTAATACAGGAGGAAATACATTCTAGTGCTACCTCTTGTGTAACAGCCTCCTCACCCACTTTTCTCTGCCACAGAAGGCCCGCTACTTCTGCCTCTGATGTGCGGACAGAGGTGGCTAATGTCATGTGAGGTGCACCAAGCATGCGGAGTGACAGGAGCAGGTCTTATTAGTAAGTGGGGAGGAGGCAGGC
->URS000005DFD5 sRNA from 1 species 
-CGGCGCTGTGGCGCCGGTTCGTTGCGGAGGATGCCGGCCGAGCGATCAGCCGGCATTCTCCGTTTCTG
->URS00017CC290 rRNA from 1 species 
-CACGTAGGGTCCGAGCGTTGTCCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTGGGTCAGTCGCTGGTGAAAGCCCCACGCTCAACGTGGGAATGGCCAACGAGACGGCCCGACTGGAGGCAGGGAGAGGCCGGTGGAATTCCGGGTGAGTGGTGAAATGCGTAGATATCGGGAGGAACACCAGTGGCGAAGGGCGGTTAGCTGGCCTGTAACTGACACTGGAGGCGCGAAAGGCTAGGGGGAGCGAACAGG
->URS0002351B0D lncRNA from 1 species 
-CTTGTGTTCGATTGATTGATAGATGTCTCATTACAAGGCCCTAGGGTCTACATTTATACCCTGCTCAAAGAGCTATAATCAGACTCGACTAGGACTCGAATTCCAAATTAAACAGAATCCATATACAAAACAAATTTAAATAACTAAGAAAAACATAAAACCACCACTTCGTAACCGACCGGAACACCGCCACAGATCAATCGGCAACCTCCACGCTTCCCTTCAGATTCATCGGCAGTCTTCCTGTTATAGCCATCGGCAAACACCAATATTAATCATCGGC
->URS0002307C0E misc_RNA from 1 species 
-AAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTAACGAGTTCTGAAAGGGGTTGTAGCTGGCCTTCCGGGGCATGTGCACACCCTGCTCATCCACTCTACACCTGTGCACTTACTGTAGGTTTGGCGTGGGCTTCGGGGCCTCCGGGTCTTTGAGGCATTCTGCCGGCCTATGTATCACTACAAACACATAAAGTAACAGAATGTATTAGCGTCTAACGCATCTAAATACAACTTTCAGCAACGGATCTCTTGGCTCTC
->URS000259D3E0 sRNA from 1 species 
-GTCCCAAGTTACCCCAAGGACGCCGGTGGGCATTCGCTCCCTCCTCACCCAGCTGTCAGGGCGCCGCGAAGCCGGTGCGAACCTGCGGAGGACGTTTTCAACGTGCCAGAGGGAGCGCAAACTCCATGGAGATTCCTAGCGCAGAAGGAATTCCTGCGGTCGGGAATTTCTTGAAAAAGATTCTTCGCAGGGGCCCTGAGCCGATAATGCTGAAATTAACATCTTTGGATATACAATTCTCTGCTTCTGAAGAATGAAAAGATAAATAACAGAGCTAAGAAAGGGACTGATGAAACAACAGCAGGTCTCAAATTTTTGGTCTCAGGACCCCTTTATGCTCTTAAAAATGATTGACAGCCTCCAAGAGCTTTTGTTCATGCTTTGGTAAGGCTGTGAGAGCACAGAGCTGAATTAGGGATCTTGGACTTCAAGTTACTGACTAGCCCCAGCACTCGCCAAGCTCACAAAGAAGACAGAAACGAGGTAAACATCCAACCATGTTTATGGAAGAGTTCATCTCTCTGTCAGCATTACGT
->URS000094A37D SRP_RNA from 2 species 
-GCCAGGCGTGGTGGCTCACGCCTGTAATCCCAGCACTTTGGGAGGCAGAGGCAGGTGGATCACCTGAGGTCAGGAGTTCGAGACCAGCCTGACCAACATGGAGAAACCCTGTCTCTA
->URS00004E1280 rRNA from 1 species 
-TCATGCGTCGCATTAGCTAGTTGGCGGGGTAACGGCCCACCAAGGCGACGATGCGTAGGGGTTCTGAGAGGAAGGTCCCCCACACTGGTACTGAGACACGGACCAGACTCCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGCCGCAGGGCTGAACCAGCCAAGTCGCGTGAGGGATGACGGTCCTATGGATTGTAAACCTCTTTTGTCAGGGAGCAAAGGGCGCCACGTGTGGCGCTTTGCGAGTACCTGAAGAAAAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATGCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGTGCGCAGGCGGAATGTCAAGTCAGCGGTAAAATTTCGGGGCTCAACCCCGTCGTGCCGTTGAAACTGGCGTTCTTGAGTGAGCGAGAAGTATGCGGAATGCGTGGTGTAGCGGTGAAATGCATAGATATCACGCAGAACTCCGATTGCGAAGGCAGCATACCGGCGCTCAACTGACGCTCATGCACGAAAGCGTGGGTATCGAACAGGATTAGATACCCTGGTAGTCCACGCAGTAAACGATGAATACTAACTGTCCGGGCAGAATGATGCCTGG
->URS0000355545 rRNA from 1 species 
-TTCCGGTTGATCCAGCCGGAAGCTACTGCTATCGGGATTCGATTAAGCCATGCGAGTCGAGAGGGTTCGGCCCTCGGCTGACGGCTCAGTAACACGTGGATAACCTGCCCTCAGGTAGGGGATAATCTCGGGAAACTGAGGACAATACCCTATAGACATCCTTTGCTGGAATGCTTGGATGTTCAAAGGCAACGCCTGAGGATGGGTCTGCGGCCTATCAGGTTGTAGTGGGTGTAACGGACCCACTAGCCTACGACGGGTACGGGCCTTGAAAGAGGTAGCCCGGAGATGGACTCTGAGACACGAGTCCAGGCCCTACGGGGCGCAGCAGGCGCGAAAACTTCGCAATGCGGGAAACCGTGACGAGGGAATCCCGAGTGCTCATACAATGTATGGGCTTTTATGATGTGTAAAAAGCATTAGGAATAAGGGCTGGGTAAGACCGGTGCCAGCCGCCGCGGTAATACCGGCAGCTCTAGTGGTAGCCACTTTTATTGGGCCTAAAGCGTTCGTAGCCGGTCAGGTAAATCCTTGGGTAAATCGTACAGCTTAACTGTGCGGATTCCGAGGAGACTGCTTGACTAGGGACCGGGAGAGGTTGGAGGTACTCCTGGGGTAGGGGTGAAATCCTGTAATCCTAGGTGGACCACCGGTGGCGAAGGCGTCCAACCAGAACGGCTCCGACGGTGAGGGACGAAGGCTAGGGGCGCAAACCGGATTAGATACCCGGGTAGTCCTAGCTGTAAACGCTGCAGACTTGGTGTTGGAGATCCTACGAGGGTGTCCAGTGCCGAGAGAAGTTGTTAAGTTTGCCGCCTGGGAAGTATGGCCGCAAGGCTGAAACTTAAAGGAATTGGCGGGGGAGCACGCAACGGGAGGAGCGTGCGTTTAATTGGAATCACGCCGAAATCTC
->URS0000A75A1F rRNA from 1 species 
-TACGGAGGGAGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCGCGTAGGCGGTTATTCAAGTCAGAGGTGAAAGCCCGGGGCTCAACCCCGGAACTGCCTTTGAAACTAGATGACTAGAATCTTGGAGAGGTCAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAAGGCGACTGACTGGACAAGTATTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGATAACTAGCTGTCCGGGTACTTGGTACTTGGGTGGCGCAGCTAACGCATTAAGTTATCCGCCTGGGGAGTACGGTCGCAAGATTAAA
->URS00009F80D5 rRNA from 1 species 
-GACGAACCGAGCGAACGTTGTTCGGAATCACTGGGCTTAAAGGGCGCGTAGGCGGGCTGTCAAGTCTGGGGTGAAATCCCACGGCTCAACCGTGGAACTGCCTCAGATACTGACGGCCTCGAGGGAGGTAGGGGCGAGCGGAACGGGTGGTGGAGCGGTGAAATGCGTTGATATCACTCGGAACTCCGGTGGCGAAGGCGGCTCGCTGGACCTTTTCTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACGGG
->URS00007B79EE rRNA from 1 species 
-AAAACGACTCTCGGCAACGGATATCTCGGYTCTCGCATCGATGAAGAACGTAGCGAAATGCGATACTTGGTGTGAATTGCAGAATCCCGTGAACCATCGAGTCTTTGAACGCAAGTTGCGCCCTAAGCCTTCTGGCCGAGGGCACGTCTGCCTGGGTGTCACAAA
->URS000123EF67 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGAAGTGGCGAACGGGTGAGTAACGCGTAATCAACCTGCCCTTCAGAGGGGGAAAACAGTTGAAAACGACTGCTAATACCGCATACTGAAGGAGGGGATTGCGTCGGATTAGCTAGTTGGAGGGGTAACGGCCCACCAAGGTGATGATCAGTAGCCGGTCTGGAGGGATGGACGGCCACAATGGGACTGGGACCCGGCCCAGACTCCTTCGGGAGGGAGCAGTGGGGAATCTTCCGCAAAGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGACGGCCTTCGGGTTGGAAAGCTCTGTTAATCGGGACGCGGTACCGGAATAGAAAGCCACGGCTAACTACGTGCCAGCCGCCGCGGTAATTC
->URS0000638341 rRNA from 1 species 
-GTCTACGGCCATACCACCCTGAACATGCCCCATCTCGTCTGATCTCGGAAGCTAAGCAGGGTCGGGCCTGGTTAGTACTTGGATGGGAGAAATGTTAACTAAAAATA
->URS000020D105 rRNA from 1 species 
-AATACGAAGGGTGCAAGCGTTACTCGGAATTACTGGGCGTAAAGCGTGCGTAGGCGGTTCGTTAAGTCTGTCGTGAAAGCCCTGGGCTCAACCTGGGAATTGCGATGGATACTGGCGAGCTAGAGTACGGTAGAGGATGGTGGAATTCCCGGTGTAGCGGTGAAATGCGTAGAGATCGGGAGGAACACCCGTGGCGAAGGCGGCCATCTGGACCAGTACTGACGCTGAGGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGCGAACTGGATGTTGGGCACACTTAGGTGCTCAGTGTCGAAGCTAACGCGTTAAGTTCGCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGTATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGCCTTGACATGTCCGGAATCCTGCAGAGATGCGGGAGTGCCTTCGGGAATCGGAACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCCTTAGTTGCCAGCACGTAATGGTGGGAACTCTAAGGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGGCCAGGGCTACACACGTACTACAATGGTCGGTACAGAGGGTTGCAATGCCGCGAGGCGGAGCCAATCCCAGAAAGCCGATCTCAGTCCGGATCGGAGTCTGCGACTCGACTCCGTGAAGTCGGAATCGCTAGTAATCGCGAATCAGCATTGTCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTTGGGTTGC
->URS0002194E4A rRNA from 1 species 
-AGAGTTTGATCATGGCTCAGATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGGTAACAGGAAGAAGCTTGCTTCTTTGCTGACGAGTGGCGGACGGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACTGGAAACGGTAGCTAATACCGCATAACGTCGCAAGACCAAAGAGGGGGACCTTCGGGCCTCTTGCCATCGGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAACGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGGGGAGGAAGGGAGTAAAGTTAATACCTTTGCTCATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCTGATACTGGCAAGCTTGAGTCTCGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACGAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGACTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTATTGACATCCACGGAAGTTTTCAGAGATGAGAATGTGCCTTCGGGAACCGTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTCCGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGACCAGGGCTACACACGTGCTACAATGGCGCATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCATAAAGTGCGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTGGATCAGAATGCCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTTACCACTTTGTGATTCATGACTGGGGTGAAGTCGTAACAAGGTAACCGTAGGGGAACCTGCGGTTGGATCACCT
->URS0001BA8378 rRNA from 1 species 
-ATTCCGGAGAGGGAGCCTGAGAAACGGCTACCACATCCACGGAAGGCAGCAGGCGCGCAAATTACCCAATCCCGACACGGGGAGGTAGTGACAATAAATAACAATATAGGGCCCTTTTGGGTCCTATAATTGGAATGAGTACAATTTAAATCCGTTAACGAGGAACAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAACTTCAGACCTGACCGGGCGGTCCGCCTAACGGTGTGTACTGTCTGGCCGGGCCTTACCTCTTGGTGAGCCGGCATGCCCTTCACTGGGTGTGTCGGGGAACCAGGACCTTTACCTTGAGAAAATTAGAGTGTTCAAAGCAGGCTTACGCCGGAATACATTAGCATGGAATAATAAAATAGGACGTGCGGTTCTATTTTGTTGGTTTCTAGAGTCGCTGTAATGATTAATAGGGATAGTTGGGGGCATTTGTATTGCGTTGCTAGAGGTGAAATTCTTGGATTTACGCAAGACAAACTATTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAGGTTAGGGGATCGAAAACGATCAGATACCGTTGTAGTCTTAACAGTAAACTATGCCGACTAGGGATCGGACGACCTCAATATTATGCGTCGTTCGGCACCTTACGAGAAATCAAAGTCTTTGGGTTCTGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGACAGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACCCAACACGGGGAAACTCACCAGGTCCAGACATAACTAGGATTGACAGATTGATAGCTCTTTCTTGATTTTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGATAACGAACGAGACCTTAACCTGCTAAATAGCCTGGCCGGCTTTTGCTGGTCACCGGCTTCTTAGAGGGACTGTCAGCGTCTAGCTGACGGAAGTTTGAGGCAATAACAGGTCTGTGATGCCCTTAGATGTTCTGGGCCGCACGCGCGCTACACTGACAGAGCCAGCGAGTTTTTTTTCCTTGGCCGGAAGGTCATGGGTAATCTTGTGAAACTCTGTCGTGCTGGGGATAGAGCATTGCAATTATTACTCTTCAACGAGGAATTCCTAGTAAGCGTGAGTCATCAGCTCGCGTTGATTACGTCCCTGCCCTTTGTACACACCGCCCATCGCTACTACCGATTGAATGGCTTAGTGAGACCTCCGGATTGGCTTTGGGGAGTCGGCAACGACACCCCGTTGCTGAAAAGTTGGTCAAACTTGGTCATTTAGAGGAAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAG
->URS0000DCA084 rRNA from 2 species 
-TGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCGACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTTGACTGGGAGCAAGCCCTTCGGGGTGAGTGTACCTTTCGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTATCCGGAATTATTGGGCGTAAAGGGCTCGTAGGCGGTTCGTCGCGTCCGGTGTGAAAGTCCATCGCTTAACGGTGGATCCGCGCCGGGTACGGGCGGGCTTGAGTGCGGTAGGGGAGACTGGAATTCCCGGTGTAACGGTGGAATGTGTAGATATCGGGAAGAACACCAATGGCGAAGGCAGGTCTCTGGGCCGTCACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACA
->URS0001D81814 misc_RNA from 1 species 
-ACAAACTTGGTCATTTAGAGGAAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTACAAAGCATGGCGAACCTCGTGTTTCGCGAGGTTTTTGCGTCCATTTTTCGTATTTAAAACATCCACTCTTTTAAAAATTTATCTAATGATAAAATAAAAAAGATCACTTTCAACAACGGATCTCTTGGCTCTCAGAGACAGACAAACTTGGTCATTTAGAGGAAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTACAAAGCATGGCGAACCTCGTGTTTCGCGAGGTTTTTGCGTCCATTTTTCGTATTTAAAACATCCACTCTTTTAAAAATTTATCTAATGATAAAATAAAAAAGATCACTTTCAACAACGGATCTCTTGGCTCTCGCATCGATGAAGAACGCAGC
->URS00022FF30A rRNA from 1 species 
-TGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGAGCGATGAAGGCCTTCGGGTTGTAAAAATCTTTTGTATGGGAAGAAAATGACAGTACCATACGAATAAGGACCGGCTAATTACGTGCCAGCAGCCGCGGTAATACGTAAGGTCCGAGCGTTATCCGGATTCATTGGGCGTAAAGCGCGCGCAGGCGGCTCTTCAAGCGGAACCTCTAACCCCGGGGCTCAACCTCGGGCCGGGTTCCGAACTGGAGGGCTCGAGTGCGGTAGAGGCAGGCGGAATTCCCGGTGTAGCGGTGGAATGCGCAGATATCGGGAAGAAAACCGATGGCGAAGGCAGCCTGCTGGGCCGGCACTGACGCTGAGGCGCGAAAGCTAGGGGAGCGAACAGG
->URS00012276C6 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAACGCAGTGGGGATGGGTGAGTAACCCGTGGGTAACCTCCCCTCAGACGGGATAACACTTGGAAACAGGTGCTAAACCGATATTGATTGATGGACTCGCGGTGCATTAGCTAGTTGGTGAGGTAACGGCGCACCAAGGCCACGATGCATAGACGACCTGAGAGGGTGAGAGGCCACACGGGGACTGAGACACGGCCCAGAAGCCTACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGACGAAAGTCTGACCGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAACTCTGTTGGTAGAGAAGCGGTATCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATAC
->URS00022361F8 tRNA from 1 species 
-CGGGGCTGTGGTAGCCGGCCATCCCGGCACCGATGCCGACGGTGGGCAGTCCGGCGGCGGCGTAACGGCGGTTGTCCGAGGCGACCGGCCCCGCC
->URS0000016AA7 rRNA from 1 species 
-GGGTCTCGAGCTGATCGGGCTCCGGCCCGATCCTCCCACCCTTTGTGTACCTACCTCTGTTGCTTTGGCGGGCCGCGGTCCTCCGCGGCCGCCCCCCTCCCCGGGGGGTGGCCAGCGCCCGCCAGAGGACCATCAAACTCCAGTCAGTAAACGATGCAGTCTGAAAAACATTTAATAAACTA
->URS00023DAE2E lncRNA from 1 species 
-GTCTATGTCAAAAGTTTGCATATAGATAAACTTGTTTCTTGGTCCATAGTTGTTTAAAGGTTACTGATTCTATCATGCTGAAGAACATAAGATGCTCATCAACAGTAGGGCATTCCTTTTGGAAAGAAGTTTCTTAGAGAAGGAACTGATACCTATCAAGTTGAACTTGAAAGTTTGACTTGTAAAAAATGAACTGACATAATCTAGTAAACCTACAGAATCGGATTTGATTAGATCAAACTCGGAGCCCATTAAAGTAACACCTTTAAGG
->URS0001703742 rRNA from 1 species 
-TACGTAGGGGGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCGTGTAGGCGGCCATACAGGTCAGCTGTGAAAACTCGAGGCTCAACCTCGAGACGTCGGTTGAAACCGTATGGCTAGAGTCCGGAAGAGGAGAGTGGAATTCCCGGTGTAGCGGTGAAATGCGCAGATATCGGGAAGAACACCCGTGGCGAAGGCGGCTCTCTGGGCGGTACTGACGGCTGAGACGCGAAAGCGTGGGGAGCGAACAGG
->URS0000241E50 rRNA from 2 species 
-TTAGAGTTTGATCCTGGCTCAGGACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTGATACGTAGGGTGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGGGCTCGTAGGTGGTTGATCGCGTCGGAAGTGTAATCTTGGGGCTTAACCCTGAGCGTGCTTTCGATACGGGTTGACTTGAGGAAGGTAGGGGAGAATGGAATTCCTGGTGGAGCGGTGGAATGCGCAGATATCAGGAGGAACACCAGTGGCGAAGGCGGTTCTCTGGGCCTTTCCTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGCTTAGATACCCTGGTAGTCCACGCTGTAAACGGTGGGTACTAGGTGTGGGGTCCATTCCACGGGTTCCGTGCCGTAGCTAACGCTTTAAGTACCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGCCCCGCACAAGCGGCGGAGCATGCGGATTAATTCGATGCAACGCGTAGAACCTTACCTGGGTTTGACATGGATCGGGAGTGCTCAGAGATGGGTGTGCCTCTTTTGGGGTCGGTTCACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTTCACTGTTGCCAGCACGTTATGGTGGGGACTCAGTGGAGACCGCCGGGGTCAACTCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGCCCCTTATGTCCAGGGCTTCACGCATGCTACAATGGCTGGTACAGAGAGTGGCGAGCCTGTGAGGGTGAGCGAATCTCGGAAAGCCGGTCTCAGTTCGGATTGGGGTCTGCAACTCGACCTCATGAAGTCGGAGTCGCTAGTAATCGCAGATCAGCAACGCTGCGGTGAATACGTTCCCGGGGCTTGTACACACCGCCCGTCAAGTCATGAAAGTTGGTAACACCCGAAGCCGGTGGCCTAACCGTTGTGGGGGAGCCGTCGAAGGTGGGACTGGTGATTAGGACTAAGTCGTAACAAGGTAGCCGT
->URS00009FA0E6 rRNA from 1 species 
-GTCCACGCCATAAACGATGAGGACTAGACGTTGGAGGCTTTAGGCTTTCAGTGTCGTAGCTAACGCGCTAAGTCCTCCGCCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAAGGAATTGACGGGGACCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCATGGAATCCCGCAGAGATGTGGGAGTGCCGTAAGGAACCATGAGACAGGTGCTGCATGGCTGTCGT
->URS00023F6A50 lncRNA from 1 species 
-CTTATCCTAAATAAAGAAAAATTTGATGTCGACGTCATGCCCGACACAATATTTACAGACTCAATATTATTGGCAAAATTAGGACTGTTGACAACCAAAAAGAATCTTAACAAAGTGGTAAAGGGTTTGGTGGATGATTCTTGAGCTCCCAAGGTCGAATGCTAGTTGATTCATATTTTCAACTAAGTTTATTTTTTTAAAAAAATAAATGAAAGAGATAGAATGCTATCATTCTCTCTACAAAAAAAGAAAAGAAAAGAAAATTTA
->URS0000783EF6 rRNA from 1 species 
-TACGTAGGTGGCAAGCGTTATCCGGATTTATTGGGCGTAAAGGGAACGCAGGCGGTCCTTTAAGTCTGATGTGAAAGCCTTCGGCTTAACCGGAGTAGTGCATTGGAAACTGGGAGACTTGAGTGCAGAAGAGGAGAGTGGAACTCCATGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCGGTGGCGAAGGCGGCCTGCTGGACTGCAACTGACGTTGAGGCCCGAAAGCGTGGGGAGCAAACAGG
->URS0000768CC5 rRNA from 1 species 
-GCATATCAATAAGCGGAGGAAAAGAAACCAACCGGGATTGCCTTAGTAACGGCGAGTGAAGCGGCAAAAGCTCAAATTTGAAATCTGGCGTCTTCGACGTCCGAGTTGTAATTTGAAGAAGGCGACTTTGTAGCTGGTCCTTGTCTATGTTCCTTGGAACAGGACGTCATAGAGGGTGAGAATCCCGTGTGGCGAGGATCCCAGTTATTTGTAAAGTGCTTTCGACGAGTCGAGTTGTTTGGGAATGCAGCTCTAAGTGGGTGGTAAATTCCATCTAAAGCTAAATATTGGCGAGAGACCGACAGCGAACAAGTACAGTGATGGAAAGATGAAAAGAACTTTGAAAAGAGAGTGAAAAAGTACGTGAAATTGTTGAAAGGGAAGGGCATTTGATCAGACATGGCGTTTGCTTCGGCTTTCGCTGGGCCAGCATCAGTTTTAGCGGTTGGATAAATCCTCGGGAATGTGGCTCTGCTTCGGTAGAGTGTTATAGCCCGTGGGAATACAGCCAGCTGGGACTGAGGATTGCGACTTTTGTCAAGGATGCTGGCGTAATGGTTAAATGCCGCCCGTCTTGAAACACGGACC
->URS0000555B9E rRNA from 1 species 
-AGAACGAACGCTGGCGGCATGCCTAATACATGCAAGTCGAACGAACTCTTCGGAGTTAGTGGCGCACGGGTGCGTAACGCGTGGGAATCTGCCCCTTGGTTCGGAATAACAGTTGGAAACGACTGCTAATACCGGATGATGACGAAAGTCCAAAGATTTATCGCCAAGGGATGAGCCCGCGCAGGATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCAACGATCCTTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATATTGGACAATGGGCGAGAGCCTGATCCAGCAATGCCGCGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTACCCGAGATGATAATGACAGTATCGGAGAATAAGCCCGCTAACTCCGTGCTAGCAGCCGC
->URS000075F11E ncRNA from 2 species 
-GTGAGTGCTGGGTAGAATGGGAAATGAGGGATGGAAGCTGCAACCGAGGGGCTATAGGCTCAAGCTGGGCTTGTGATGCTCTCTGTAGAGCATCCTCCTCTCGGCCCCTGTCACTTTCTACTCTACCTTCTACTCAG
->URS0002564330 rRNA from 1 species 
-ATGGCTGTCAGCACTGGTAGCTTCTTGGCCATTGCCATGGCCCTCGCTCTCCTTAGTGGCGACATGGCCCACGCCGGCCGCCTCCTGGCCGACACCACGGAGGCAGCAGCGCCCGCTGCAACGCCTGCCGCTGTCCCAGGCATCCCCGCGCCGAAGCCGCCCGTGCCCACCATGCCTACAATGCCACCCGTGCCCGCGCTCGCCGTTCCCCAGTTCACGGTACCCCCCATGACGGCCGTGCCCGCGATCACCGTGTCCCAGGTCACGTTGCCGCCCATGCCGGCCGTCCCTGCGGTCACCGTGCCCAAGGTCACGTTGCCGCCCATGCCCGCAGTTGTTGTGCCGAAGGTGACGATGCCGCCAATGCCTGCAATTCCATCCATCTCCATACCCAAGGTGGCATTGCCTCCGATGCCTTCCATTCCCACTGTGAACGTGCCGATGCCAACCCTTGCGCCACCTCCTTCAGCATAG
->URS0000DAC67E ncRNA from 1 species 
-ACACGCGATGCGGGAGAGCTCGGTTCGCCGAGCACCGAAGGAGCAAGCCTCCCCGCCAATCTCTCAGGTTCTGTACCGCATCGAACTG
->URS00004A01BA rRNA from 2 species 
-ACTGCTCAGTAACACGTGGACAACCTACCCTTGGGTCTGGCATAATCCTGGGAAACTGGGTATAATTCCGGATAGGTCACAGATGCTGGAATGCACTGTGGCCGAAAGCTCCGGCGCCCAAGGATGGGTCTGCGGCCTATCAGGGTTGTAGTGGGTGTAACGGACCTACTAGCCTACGACGGGTACGGGTTGTGAGAGCAAGAGCCCGGAGATGGATTCTGAGACACGAATCCAGGCCCTACGGGGTGCAGCAGGCGCGAAAACTTTACAATGCGGGAAACCGTGATAAGGGAATCTCGAGTGCCAGCATATAATGTTGGCTGTCCAGATGCCTAAAAAGCATCTGTTAGCAAGGGCCGGGCAAGACCGGTGCCAGCCGCCGCGGTAACACCGGCGGCCCGAGTGGTAACCGCTTTTATTGGGTCTAAAGGGTCTGTAGCCGGCCAAGTAAGTCCCTTGGGAAATCTGGCAGCTTAACTGTCAGGCTGCTAGGGGATACTGCTAGGCTTGGGACCGGGAGAGGTGAGAGGTACCTTGGGGGTAGGGGTGAAATCTTGTGATCCTCGGGGGACCACCAGTGGCGAAGGCGTCTCACCAGAACGGGTCCGACGGTAAGGGACGAAAGCTAGGGGCACGAACCGGATTAGATACCCGGGTAGTCCTAGCCGTAAACGATGCTCGCTAGGTGTCAGTCACGGTGCGACCGTGATTGGTGCCGTAGGGAAGCCGTGAAGCGAGCCACCTGGGAAGTATGGCCGCAAGGCTGAAACTTAAAGGAATTGGCGGGGGAGCAC
->URS00021D2EAF rRNA from 1 species 
-GCGATAGTACCAGCACTAATGCACCGGATCCCATTAGAACTCCGCAGTTAAGCGTGCTTGGGCGAGAGTAGTACTTGGATGTGTGACCCCCTGGGAAGTCCTCATGTTGCACCCC
->URS0000A1EE98 rRNA from 1 species 
-CGGAGGATCCAAGCGTTATCCGGAATCATTGGGTTTAAAGGGTCCGTAGGCGGTTTAGTAAGTCAGTGGTGAAAGCCCATCGCTCAACGGTGGAACGGCCATTGATACTGCTGAACTTGAATTATTAGGAAGTAACTAGAATATGTAGTGTAGCGGTGAAATGCTTAGAGATTACATGGAATACCAATTGCGAAGGCAGGTTACTACTAATGGATTGACGCTGATGGACGAAAGCGTGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGGATACTAGCTGTTGGGAGCAATCTCAGTGGCTAAGCGAAAGTGATAAGTATCCCACCTGGGGAGTACGTTCGCAAGAATG
->URS00008B5885 lncRNA from 1 species 
-GCAGTTGAGCAAGATCACGCAAAAACCTCTGCCAAGACAGAACGTGCATCAGCTCAGCAGGAAAACAGTTCAACGTGTATAGGGTCGGCCATCAAATCAGAGAGTGGGAACTCAGCTCGGAGCTCTGGCATCTCCAGTCAGAATAGCTCTACAAGTGATGGAGATCGATCTGTTTCCAGCCAAAGCAGCAGCAGCGTTTCCTCTCAGCTGAATAAACCACATCAAAGGAAAGGGACCACAGTATTTGAATGTTTGAAAGTCTGTAAAGCTTAAGGTTTTAAAAATGTTGCCCGTAATGTTGAACGTGTCTGTTAAAAAATAAAAGAAAAAATAGTTGCTTCAAACTA
->URS0000F1E2A3 rRNA from 1 species 
-TACGTAGGGTGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGTCTGTCACGTCGACTGTGAAAACCTGGGGCTCAACCCCGGGCCTGCAGCCGATACGGGCAGACTAGAATTCGGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCGATATTGACGCTGAGGAGCGAAAGCGTGGGGAGCAAACAGG
->URS0000D90CA0 rRNA from 1 species 
-AACTTTTAATAATAGATCTTTTAGTTTTAATATTAATAAAGAATATAGTAAAATATAATAAGTAATATAAATTATAGAATTTAATAAATTATTAAATCTTTAAACGTATATTACGCTTATTAGTATTTTAATAAGTATACCTATTTAAGCGTTA
->URS00023A597C lncRNA from 1 species 
-TTGTTTTTTTTATTTTCTTTTTAATTTCAGAATTTATATTTAATTGCTTTATTTTGTTTAATTCATAATAATTTCATTTTTAATCCAAAAAATATGGGACTTTCACCAAAAATATTTTTGGATTTTTCTCTTTTATATTCTGAATTAAAATTATTTTTCGGATTAATTTTGATATTTTTCATGAATTAAATATTTTTGTGTATGTTTTTAATTGATTAAAAATACTTCTGATTTTTCAAAAGTGATGATTTTTT
->URS0000BE2407 tRNA from 1 species 
-GCCTTCGTGGTGTAGTGGTCAGAACGTATTCGAGAGGTCCGTGGTTCGAGTCCCGGTGAGGGCA
->URS0000E01B97 lncRNA from 1 species 
-AAAAAGTTTCAGAGAAGTTCAAATTGTGAAAATTAAGGTACTGAGAAATGTTGCCAGAGGTTATGAACTGCATTTTTTTTTTTTTTTAGCGTGTTTGGAGTAAGGATTGGAATGACTGTCTTTTTCCTTGTAGCTGATGAAACTGAATGGTTTGAATGGTGTCCAGGTAACAACAGACAGATGCTGACTCCAGAATGAATGACTGCAGTGATGGAATACTCAAGCAAAGACTGCCAAGCCTCCACACGGGAGTCCGTGCCTGAACGCGAAATAAAGAGGGATCCATGGAATGATTGTCCCACGATGGTAACTTCGTGATCATCTTTACAAAATACGAACATAGGCCCATGGAGAGAGGAAATCAAAC
->URS0000762E71 miRNA from 1 species 
-CGTTTGTGCGTGAATCTAACA
->URS0001E5F21C rRNA from 1 species 
-AACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGAGATCCTTCGGGGTCTAGTGGCGCACGGGTGCGTAACACGTGGGAATCTGCCCTTAGGTTCGGAATAACAGTTAGAAATGACTGCTAATACCGGATGATGACGTTAAGTCCAAAGATTTATCGCCTGAGGATGAGCCCGCGTAGGATTAGCTAGTTGGTGTGGTAAAGGCGCACCAAGGCGACGATCCTTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTTACCCGGGATGATAATGACAGTACCGGGAGAATAAGCCCCGGCTAACTCCGTG
->URS0001C02308 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGTGAAGCGAGTGCTTGCACTCGTGGATCAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCATCACTCTGGGATAAGCACTGGAAACGGTGTCTAATACTGGATACGACCAACCCTTGCATGGGGTGTTGGTGGAAAGATTTATCGGTGATGGATGGACTCGCGGCCTATCAGCTTGTTGGCGGGGTAATGGCCCACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGTGAAAGCCTGATGCAGCGACGCCGCGTGAGGGATGACGGCCTTCGGGTTGTAAACCTCTTTCAGCAGGGAAGAAGCGAAAGTGACGGTACCTGCAGAAGAAGCACCGGCTAACTACGTG
->URS0001E5A028 rRNA from 1 species 
-AGTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGGCAGCACAGTAAGAGCTTGCTCTTACGGGTGGCGAGTGGCGGACGGGTGAGGAATACATCGGAATCTACTTTTTCGTGGGGGATAACATAGGGAAACTTACGCTAATACCGCATACGACCTATGGGTGAAAGCAGGGGATCTTCGGACCTTGCGCGATTGAATGAGCCGATGTCGGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATACCGCGTGGGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTGGGAAAGAAAAGCAGCAGGTTAATACCCCGCTGTTCTGACGGTACCCAAAGAATAAGCACCGGCTAACTTCGTG
->URS00012AECC2 rRNA from 1 species 
-AGCGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGAAGTCTTCGGACTTAGTGGCGGACGGGTGAGTAACACGTGGGAACGTGCCTTTAGGTTCGGAATAACTCAGGGAAACTTGTGCTAATACCGAATGTGCCCTTCGGGGGAAAGATTTATCGCCTTTAGAGCGGCCCGCGTCTGATTAGCTAATTGGTGAGGTAAAGGCTCACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGATGATCAGCCACATTGGGCACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTGGGGAATCTTGCGCAATGGGCGAAAGCCTGACGCAGCCATGCCGCGTGAATGATGAAGGTCTTAGGATTGTAAAATTCTTTCACCGGGGACGATAATGACGGTACCCGGAGAAGAAGCCCCGGCTAACTTCGTGCCAGCCGCCGCGGTAAGAC
->URS00015A0908 rRNA from 1 species 
-TACGTAGGGTGCAAGCGTTGTCCGGAATTATTGGGCGAAAGAGCTCGTAGGCGGTTTGTCGCGTCGAATGTGAAAACCCGGGGGCTCAACCCCGGGCCTGCATTCGATACGGGCAGACTAGAGTTCGGTAGGGGAGTCTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGACTCTGGGCCGATACTGACTGAGGAGCGAAAGCGTGGGGGAGCAAACAGGG
->URS0002375287 lncRNA from 1 species 
-GCGCAAAACCAAAATTGAGTGGGTCAGTAAAACAATTCTTTTCCAAATCCAAACATTTCTCAAAACGTTGTAACCCCTCTCCGTAAAACCTGTATACTTTCCCAGAAATATAAAATATAAATATACATATATATATTCTCAATACTTCAATTCATTAACTCAACATTTTCATCATAATTATGCCATGCCACATCATCTCAACATTTCTCATATTAATTATGCCATGCCACATCATCTCAACAGTAATAAGGTATGAATGCATCAACATAAATCATATCAGGTGCAATAAAGTAATCAACCGGAGGCCCTCTAATAGCCCTGTACGGTTGAACCTAGAGCTCAAAATCTATCACTCTCACACTCTGCCGGAGTCACTCCGCGTGACCTGTACGGCCTTCTGCACATAAGTTACGCTCTAGTGCTTCTCATAAATCATCTGTGCACATAATCTAAGGTTACCCACCAGTCGGAATCTCACTAACACTCTCGCGACTGGCCTGTCGTACCCACTCCGCGTGGACTGTACGACTAGCATCTACTTGGATCCAAGGCGAGCGTGCGATGCGGTGAATACTATAAGCACTAAACTATGGTGCAGGATTTGAGCTCAATATACATCAACATCATCATAACAGAAATAACTACTCACCTGTGCGTCCATCGCACCATTTCATACATATGCATCATATCAATTCTTACCTGTGCGTCCACCGCACCAATTCATACATATGCATCATAAATCAATTCTTACATGTGCGTCCACCGCACCAATTCATACATATGCATCATATATTAATTCATGCATGGCATTTCAACTCACATTTCTATATACTTTTCATATCAATTCTATGCATGGTATTTCACTTCCCGTTTTTCCACATAACTCATATGCATTTCATTTTAAACATATTTTCATTTCAATTCAATTTCTGGGAAACGTCAAGTATATATATATACGGAAAACAAAACTGCCCACTCACCTGGAGTTCATCCAACAACTCCCTAGCACCACACATCAAGGCGTCACGACGATCGCCGCCTAGAATAGTAATCAAATCCAACCTCAGAATTCATATCGATAGAATATATAACTTATATAAAATACGTCCCTACGTAGATC
->URS0002362E6B lncRNA from 1 species 
-AGTCAGGTCCAACCATTAAATGATAGGGTTAAGTCTAATCAACTAATAGATGACCAAGCCCGAGTGTAGCTCGACTCACCTGACCGCCTATTGAAGGTACACTTAACTCATCATATATTGAATGACAATTCCAATGCTTGATAAGTACCAGGCGTGTAGCACCTCCAATAATTATCAAAACATTGGACCCATTATCACCCAACTTAATGGAAGGCTATGATCTAGTTATCTCCATAACCATTCATTTTAAGAACCTAATAATTTTAGAGGATTTCATAATTAGGATAGATGAGAAGATCCGGTTAGTC
->URS000199E9B9 lncRNA from 1 species 
-GGTGTCATGGGAAAGGAAGTGGTGTAATGCAATATATTCACCATCTCCTGACAGTACCACAATGAGATACCTTTTTCTGTAGGTGGTTCAGATGTATGTCAGTAGATAGTGCCGATAAATGCTCTTCCAGCCTGATCCTGCTCGACCTGATGTGCAAATAGATGCAAAAGATATCCAAGCCCATGGAGTGAAACAGTGGTGCTTGCTGCTCGACATGAAAGATGTATCTTCTGTGGGAGCTCATTTCTTTTGTTACAGCAGAAAATAAAAAGATTTTCATAAAAGTGAAGATAAAACACTTGATAATATGTCTGTGAACATAGTTCCATTTTACCTCAGCTGTGGCATGAAAGACCATGAAATATCTTCAACTGGCTCTTCATTAAATCACACTATCTTTAAACATATTTCAAGGAAAGTAAGGAGTTTCAGATATTAAAAAACATATACAAATATTTCATAGGTACTGTATGTGAAGGTTCACTCAATCATCCAAGGCCAAATTACTTGAAGAACTGTTAAATTATTATGATTTTAAAAATAATTACTGTAATACTTTGGGGAATACATTTGTCATAACAAATACAGAACATATTTTCTAATTTCTATTATGGCTGTCAAGGTCATTCGGTGACAGAATGCAAAATCTTATTTTTCTCATTCAGATATTGTTAGATGCATAAATTCTTTAGCTAATGTAGAAAAGCATTTAAAAATTTAAATTAATTAATGAAGAAATTGTCTTTGCCTGATATCACACAACCATTTTTTTATCTTGTGAACAGAATTTAACAATACACAGGCTCAGGCTGGCTTTATTCCACTAATACATGCCATTTCCAAAAGTGTGTTGCCTATGTATTAAACACCATGCACACACAAGTATTTTAGCATTCCTTGAAAATGATTTTTAAATCCACATTTATTGTAAGTGCTTTGGAGGCAAGAACCATCTTTTGTTATTGAACAATGCAAATGGGATCTTGGTCCATAATTGGGGCTTCTAAGCACCGTGAATTCTTTCACTAATGTTTCTCATTCTCTTTTTCCCTCTCTTTGTCCCTCCGCAGATTTGCTAGTGTTTAAAAAAGTTAGGATCCCTTGCATCCTCACCAGTCTTTACATTTGCCCAAGAATCAGATTCAGTTTAGCCCAGCATTCTTCACAAAGATAAAAGGGTGACAGATCCTGACACACTTGTAATTTTCAAAACCAGAGAAGCTGATTCCTAAAACAGCATCCAAACTGAAACTGTACCAGTGTTGGTA
->URS00023F5E43 lncRNA from 1 species 
-TTTTTTTTTTTGGTAGGTCACGGGGAGAAAAGCTCTCCCCACAATTTATTAAGAAACTAAAAAACAAAAATCAAATTCGGATATGCTTTGGAAACGCAGTTTCTCAGTCATCATCCTCTACAAATGACGCCACAAAGGGTGGAGCAACATCTAACAAATGAAACCATAAAGGGAAAGAAAATGCATAGTTCGCTAACCCGTCCGCAAGACGGTTAGCTTCTCTATAAACATGAGTAACATGGACTAACCAGTCTCTTGATAAGAAGCCATGGCACAATCGCACCAGGAACGATAAAGGATGAGTATCACTAATCCCCCTCGTTAAAAAACCCACCACCAACTCTGAATCAACCTCCAACTCCACTCGCCTAAACCGCCTCTCCCAAGCAATATAAAGCCCGTAACAGACACCAATATTCAAGGCGAACCCACCGCACCAACGACCTTGACCATCACGCACAACTCCTCCTACTGTAGCCAATCCCGGATTTCCCCGTGAAGCGCCATCAGTGTTAAGCTTCATCCAATCTTCTTTCGGTCATTTCCAGGCCACCATTCTCTCCATTTGAGTATTCGATCTGCCCGTATAGCGATTCAGTTTGTGAGCTTGACTTACTTGAGAAGCGAAGTCCTTAACAAACTGAACTCTATCTCTACATTTACCAATCTCGCCAAAAACGTAGCCACACCGCCACTTCCAACTCCACCAAACCACAATGGAGAACAAGGTTGCCCATGAATACCCGACCTCATCATTCACCATTCCCAGATTCAAATATAACCAACCAAGAAGAGACCCATTGAAAAAATCATGTCTCCTGCGAACCGGCACTAACCTTCTCCAATGCAAGACTCGGGGTGAGTCTCACACGGGGATAGATATGGTGGCTTCACAAGCTGGCGATCGCTTCTCTCTTGTGAAGGAAAGATGGTCGAAGGTGGAAATCTGACACGCTAGCGGTCGCTTCTCTCGTGTGAGATCAAATCAGGGTTTTGATGGTGGATTGATGATCGCCACTCAAAAGTGTGAAAGCCTTTGTGATAAGATCACGAACCTTTGTCTCAAGGAATCCACACAAGAGACATTGATTCACACGTTTACTAAGTAAAGGAATCTACCTAACTTAAATAAACAAAAACAAAGCCTAAGCTTTAGAGAAAACTCTTTCTATTACTTTCAAATTTCGTGGTCCTTTACAATGAAACAAATGAGCTTTTTATAGCTCTTACATGACTAAGCTACATTAAAAGAAAATATTCTAAGTTAAATACAAATCAATCGATATAATAGAGAAAGCGTGATTGGTGGTGACGATGAGGAACAAATCGTGGGCATTGATGGAGCTTTATCTCTAGATGCATTCTCTGGATTAAATGGTGGATCAAGGATTTCGAGCAAGCAATACTCCTTAGCAATTAATGCTAATTTAATTACGTCGAATAACGAAAGTTTATTTCCTTTGAATTTCTCTTTGATTCCTTTTGATATTCCGGCCAAAGATGTTTTGCAAGCTTCTTCTTCATTTGGAGGGTTTGAAATCTCCAACATAAACGATCCAAGGTTGATGGATGATTCACTTTCCTTGCTTGGTTCGACGTGTAGTAGTTCAGGAAGTCCTTCAGCAAGTCTTTCAGGAAGTTCGTCAGAAAGTCCATCAATCAGTACATCAGCAAATGTGATGTCCGCATCATACTCTCCTTCTTGAGAAAGTTTTGTCCTCAAAACTAATTTCATTTTTTTTTTTTTTTTTAAATCACAGAACAAGAAAAAAAAAATTTAATCGAAGAAAACAAAACAGAAGCAAAAACGATTGATGATATAGGAGCTTTGAGCTCTGATACCAAATGATGCAAGACTCGGGGGTGAGTCTCACACGGGGATAGATATGGCGGCTTCACAAGCTGGCGATCGCTTCTCTTTTGTGAAGGAAAGATGGTCGAAGGTGGAAATCTGACACGCTGGCGGTCGCTTCTCTCGTGTGAGATCAAATGAGGGTTTTGATGGTGGATTGATGATCGCCACTCAAAAGTGTGAAAGCCTTTGTGATAAGATCACGAACCTTTGTCTCAAGGAATCCACACAAGAGACATTGATTCACACGTTTACTAAGTAAAGGAATCTACCTAACTTAGATAAACAAAAACAAAGCCTAAGCTTTAGAGAAAACTCTTTCTATTACTTTCAAATTTTCGAGGTCCTTTACAATGAAACAAATGAGCTTTTTATAACTCTTACATGACTAAGCTACATTAAAAGAAAATATTCTACAAATTACATACAAATCAATCGATATAATAGAGAAAGCGTGATTGGTGGTGATGATGAGGTACAAATCGTGGGCATTGATGGAGCTTTATGTCTAGATGCATTCTCTGGATTAAATGGTGGATCAAGGATTTCGAGCAAGCAATCCTCCTTAGCAATCAATGCTAATTTAATTACGTCGAATAAGGAAAGTTTATTTCCTTTGAATTTCTCTTTGATTCCTTTTGATATTTCGGCCAAAGATGTTTTGCAAGCTTCTTCTTCATTTGGAGGGTTTGAAATCTCCAACATAAACGATCCAAGGTTGATGGATGATTCACTTTCCTTGCTTGGTTCGACACGTAGTAGTTCAGGAAGTCCTTCGTTCAGCAAGTTCTTCAGGAAGTTCGTCAGAAAGTCCATCAACCAGTACATCAGCAAATGTGATGTCTGCATCATTCTCCAAATGCCCGCTATTGACGGACAATCCCTTCGCACATGCAAGATTGGTTCGTCCCCACCTTTGCAGACCTGACAAACACTTGACTCTCCAATATGACCTCGAACTCGTTCCACATTCGTCATGATAACCTGTTGAGTAACCAACCAAAGAAACGTTCTAACCCTTTCCGGAGCCATCACCTGCCACAGTCTAGCAAAAAAGGAAGACATATCTGTTCGGCACTCAGAATTTTCCATCAACATCTCATAAGCCGACGTAACCGTAAAAGCACCATCGGCAGAGTACCCCAAGATAACCTATCCCGCACGCCAGTCACGTTATCTAAAGCAATAGAGGCTAACTCCAACTGAGTATTATGAGAAACGTAGGGCAAAATTCTGTCAAGTCTCCAACCCATGCCATCCACCCATAGATTGTGAGCTCGCAACTCCTTATCTGTATTTGGTATCTCTAGAACTGCTCTTTCAGAGACTGATACGATAACCATTTATCCGCCCAAAAACGAATTTCTTGCCCATTACCAATCACCCATCTACTACCCCGAGTAGCCACTTCTCTTAACCCTGCCACGATGCTTCTCCAAGTTGACGAGCATGGCCTTTTTTTCTCCATCCAAGTTCGATCATGAATCTCTCCCACTTTATACTTTTTGCGCAAGATTCTAGCCCACAAACTCTGCCGATCATGAATAAGCCTCCAGCCAATTTTAGATACTAGAGCTTTGTTCATAAACTTTGACTTTTGAATGCCAAGACCCCCCTCTCTCTTTGGCAAACAAACTCTATCCCAAGCTACCAAATGCATCTTCTTTTTCTCTAACGAACTACCCCACAAGAAAGCTCTCGCCAGCTTATCTAATCCCTCCAACGTTGACTGTGGTAAAGAGAGAGTACTCATTGTGTGTATCAGAATAGAGGAGAGAACCGACTTGGTTAGAGTTAATCTCCCCGCAAAGCTTAAAGAACGGCCTTTCCAACCCGCTAGCCTTGAAGCCACTCTTTCAAGAACCTCTCCAAACGTATCTTTATTTATCCATCTTTCGAGAATAGGCATTCCAAGATACTTCCCCAACTCTCTTGTTGATTTAATCCCACTCTCATTACTAATCAACTTTTCCAAGTCTCATGAAACATTCTTTGAGAAAAATATCTTATATTTCTCCAAGCTCACTTTTTGTCCAGAAGCTACACAAAACGTTTCCAAGATTCTTCGTATAACCCTTATTTGAGAGACCGTTGCTTCTGCAAATAGAATTAGATCATCGACAAAACAAATATGTGAAATCTTCGGCCCTCCCTAAGACAGACCAATAGGCTTCCACTCTTTTGCAGCTACAGATCGATCGATCATGTGACAAAGTCGCTCAAGATAGAGAACAAATAAGTACGGAAACAATGGATCTCCCTGTCGAAGCCCACGTGACGGTTTAAAGCTAGCAGTCTTCTCTCCGTTCCAAAGGATACTCATAGACAGACCAGTGATGCATTGCAAAATCCATTGGACCCATCTCTCCTCCATACCCGCAGCCCGTATCGTATCCTCCAGGAAGTCCCACCGAATACGATCATATGCCTTCTTCAAATCCAGTTTCAAAAGCATCTACCCTTTTCTCCCTTGTTTCCTTCTCATCGAGTGAACAGCTTCTTGCACCACAATAATGTTGTCTAAACTGAGCCTCTCCGGGATGAAGCTAGATTGTGCTGGACCAATTAGCTTTCCAATAACTTGCTTTAAGAGTAACACTAACATCTTAGTAAGCATCTTAAAAAGAGCATTGCGCATCTTAGTATGTGCCAAACTTCAAGACTTGTAGAGTTTTGACGAGTGGAGTAGAAGACTTGGATTTTAGGATCCTCCAGACAGTAGAGACCTTCAAGTGTTCTTCCCATTATCAGCAGCTTCTTGGTTGCCTTATCATTTATACGAACACTATCAACATCAAACTCAATAGAGCACGGGTAGTCACTTGTGAGTTTTGAAACAGACAAAAGAGATTTAGCAATATCATGGCAAGCAAGAACTTCTTTTAAAGGTATTTTACCTGAAGAGGAAGCAATACTACCTGAACCAGTGTGAGTAATGGGCAAGAAGTTACCATCAACTACCATTATAAAATCAGAACCATGATAGGGTTGAGACTATTGCAAAACTTGGTGATTATTGGTAACATGAGCTGTAGCTGCTGAATCTGGAATCCACTTGTGGCCATGATGGTTTGTAACATTTGTAATGCGCATTGTACCAAGAGTCATTGGTAAGTCTTCGTATTGATAGTTGTTGTCAAACCTATGCCAACATTTCAGAGCATGGTGACCAGCTTTACCACAGATTTGACATACCACACTTGAGTTTTCCGACTGAGAAACAGATGAAGATAAAATTTGTTGATGAAAATCATGTCCTCTAGTCGAGAATGAACTCCTGCCACGGCTAGAGTTTGACCTTTCTTTTCCTATGTTGTTGCGAAATTAGCCATTGTCTGAGTGAGTGACATTGAAAGCAACATGAGGAGAGATAGATGCTTCAGTCACATAGCTTTGAAGACGGTCATCATAGCCTTTTAACTTAGAAGCAACTTCATCAAGAGAAAGACTTGGAGTAGAGTCAACAGAGTTTTCAATATTTGTTTTAATTGGCTCATACTCTCTTCCAAGACCATTCAAAGCAGAAAAGATTTTCATTTTCTCTGGAACATGGTTACCAATAGAGGCTAACTGATCAAATATATATTTCAGATCTTTGAGAAAAGTTTCCATGATGTTATGTTTCTTTTCCAGAGTTTGCAATCTTCTTTGCAGTTCAAACAAGCGAGAGGATGATACTCTATTAAAGTGATTAGCAAGAGTCATCCATACCTGATGAGAAGCGAAGCAGTTGACCACCACACTTAAGATATCTTCAGCAAACGAACCAAGTAACCAAGACTTAACAACTTGGTCTGGTTGGTGCCAAGTGTAAAACTCCTGAATTTGTTCTTCAAAGGTGACACTGTTGTGAGTAGCAGTCCGAGTTTGCGTCAGAGCAAAGATAGAACCAATGACAAAGCCGACCAGCCCTTGACCAGATAAAAAATTCTCGAACTAGCTCTTCCTTCTAGAGAATGTAGTTTTGTTGGTAAAGAGTAATGGTGAAACAGTTGGAAATATTGAGAACTGGGTGGAATTGTATAAGGTGCCATGGATCTTACTTCTATGAGATCTGATACCATGTTGACATTTCTAAACTAAGAATGGTTTATGCTCAAATGAGCTTATTAACATAGAAATCTAAAATTGGAAAATACAATAGTTCAATGAGCTTTATTGAAATATAAAGAAGAAAAAGAAGCTTTAGGTTTTGTCACCAAGAACACTTAGAAGAAAAATCCACCATTTTCAATGGAAGACAAAAATCCAATCAGATTTCCCATAAAAACCTAACTCTTCCTCAAGTCATTGAAGAGCTAAAAGAGCTCTGGGCTATGGTTTTACCAATCATAGCAATAATTTTTATATGTATTAGCGTTCTTGGTGAAATAAGAATGAAGCATAATTGTTGTAAATCAGTGACAAATCTAATATACTTCATTCTTTTTTCTCCAAGAATGCTAATATATATATAAACTCGTCAAACAATCTAAACTATTGTTTGTTAATTGAACTTCAAGCAAGCATTATGTATAAGTTTGACATGTTCACAAAACATGTTAAATTCATTTGGTGGTTGGTTGAGGAAGTTTTGCTCACCTATGTTCTTTCAAACAATTTCAACAACACATTTGATGGCACGTTGAATTAAATCTAAGATCATAATCTCGGTGATCAATCTACACTACGCAATAAGAACCACCATAGATGTATAACCATATATGTATTTAATATTAATCTTATTAATTCTGAATTTTGTTGCTTTCAACTCATTACCCCGATAGTATTTAGAAAGCGATGTTGTTTAAACATGAATTAATTGATTCAACATCAAAATTCTGGTAAATATTGGTTGGTAAATTGTTCAAAATCGTGGGTAGAAAATTAACAACATTTCTTCGTTTATAAACTAAATTGCACGTTTTTATTAGTATGTGTTTTATTTTACATAATATAGTTTGTCATACTTTTATTATATACACTATACATTATAACCGTAATTCCATACGAAGAAAACACATATTATAACCGTAAACCCAAATACATAATCTATTATTCAACTATACGAATTTCATTCAATATATAAATTTTATTAAAAAATTGTCAAAATCTAGTTATTAATATTAGAACTTATAAGATGAGGACCCAAATAAGGGTATTAGAAAGTGAAGATCACTTAAACTCTCTCATACACAATGATCGAGGCAGCCTTATCGAACCCTTTCTCCGACGTCGATGAAGCCATGGCTCGCCGGCGTCGGGATTTGTCTTCCCTTTACTACGTTGTTTCTCTCCCAACACATCCAAATCCTTTCTCGGCCCATGTCCCACGATCTCCCATGCCCACTCCTTGCGACGATTCCTATATATCTGAATTTCTTCAAGTTACAATCGTCTTCCTCTGCTATCAAACAACACCGTTTGATGCGGCTCAGCCCACTCCTGAAACAAGATCTTCTCCCTCTAAACCTTTTGTGATTCCTGTAAATCGTCCCTCTCAATGGCTCCCCTTGAAGTCAAGACCTGCATCTCACAACTCCTTTCTTTGGGATTCAATTCCCCCCACCTAGTGTTTTTCTTGGTTTCGTTTGGACCGGAGCTCTGCTTTGACGCCGGAGCCGATGAGGATTTCGACGACGGAATCTTCAACCCACTCCTCAGCTTTGGCAACGCTGACTCGACTAGCTCTATTACCAAGAAAACTCACCGTCGGCGTGCGGCCACCGTTGACGAATAAGGGAGGTAGCTTCCTAACCCTAATGTTGCTTTTCCTTATTTGGTTTGGGCCTAGCCCAAGAACTGTTTACCCTCCCTCCAATCCATTTTTCAAGTCCTCGAAGCCCATGAACAGTTTTTTTAGGTTAAGCCCACATCTTGTTTGGCCCAGGTTAGGTCTTTATTTCACTCTAGCAAACCCAAACGTTTTGATTTCTTTCTCGTCTTTGGAGAGTAGCTACCTTCCGAGATTAGTTGTGATGGTCATTGTTTGGTTTTGGTTTTCTCTCCCACAAAGTTTGGCAAATAGGTTAGCTCGTTGGTTTTATGTTACAAATCTGATCTCAAAAAGCTTTGGGCTAACTCCACTTTTGAAGTGTTTTAGAGTCTTGATGCCCATGATCCGTATTGTTATGTTTCTGTCAATTACAACCCCTATAGCACCCTTTAACTTTGTTTTGGCTGGTCGTGGACTCCACGCTAACAGAGTAACAGTTCTTTTAGGCTGTTTTGATAGATACTTTTGTCGAGGTCATTTGTTAATTTTGTTTCGAACCCTATTTGAGACTATCATCCCAAACCTTTGGCAATGTCCAAAAGAGTGAAGAAGAACGCCATTATGATCCCATCTCCACGGAGCGGTGGTTACCGAAGCTTCTTCAACTCTCTACCTCCTTACCCGCCAATTACCAAGCTCCTTCAAGGTATCTTCAAGTATACGGATAAGTTGCAAATCTGTGAAAGCTTGGCAAAGAGCGGCGTTATGATCTACCCTTTATTTTCTCCCGTGGAGCACCTTTTCAAAGGCTCATATGCATTGTTTGCAATAGCCGTTTATGACCACACGTTGGTCGAGGATTTCGCGAAGCCCGTCTTCATGGTCGAATCCGCCAAAGCCTCAACAGATTTTTCAAACCTTGTAAACTTTTTTAAAAGTGAACACCTCTTTGCAAAACTCATGAAGCCTCTATCTTCATTTTCTTGTACTATCTTAGTTCTAATTTGTATGAACTTCCCTTTTTTTAGGCTTAAGTGAATGAAAATTATTGTTTGAGAAAAAAAAAAAATAAGATGAGGACCCAAAAGCTCATAGTTCGTCATCTGTAACATGCTGCATTTTTCAGGCAAAGCAATCCGACTAAAATCAAGGAGATGTGGAGGGGAGAAGCTTCCGCCTGATACCAACGGTAAGAGCTCCACATGCGGTGTAGCGATGCAGAGTAGAAAAGGGAGATCTACGGCGAAGAACGAGAGAGACAAGTAGATAGATCTGAGACCGAAAATTGTGGCGGTTCCACGAGATCTTTGTCGATGGGGGAGGTATATTTGATCCGGCAAAGCGAAGCCAACGTCGAAGGTCTCTGTTTTCTATTCCCTACTATTTTCTCTCTTTCATGACTGAGCAAGGATCTCTTCAACAAAAACGAGATCGGCTCTCTTCCTCCTTCTCAAAACAACTCTACAGTGGCGGCATGGCAACAAATTTTGGATCACCATCTCGTTTGGCTGTCCTATTTCAGCGAGAATCTGCAGTTTTGGACGGCGGCTCGATCATGTTTTTTGATTGAGATTAGGGTTTTCAATCTTGGTTAGTTAAATTCGGTTTGTAAATTTGAGATGGCTTTAGTTTTGAGCTGCTTTGTTTATTGTATTGAAGTTTGTGGATTGGGTTTTTGCGATTTTGTATATGCTCTATCTAGAAATAGCCCATTAGACATTATATATAACAAAAAAAAAACATGAAAAACACTAGAAATCATACAATCAAATCCGCATACCTGAAACTTAAAAGACTGGCACATTCGCTAATAATGAAACATGCATCAATGGTCTCTCAAGAGTCATATTATTTGCATAAGTTGATTTGTCCCTGCAAATTCCAATACAAAGCCTTGTGGACTTAATTAAGATAATAGATGTGAAAATTCAAACACATGAATCTGTTTAAAAGACAAAATAAACGTGGCATTATATCAAACATCTTGTAATTTCATATACATAAATATCAAATTGATATTTCCCTCTCTTTGAGAACTGTCCTTACGAATTCGTTTCTAAATAACATGTTTTAGATCCTAACTGTTTGTGTTCTTATGTGATGGTTTTTTAGGGACCGGTAGGTACAACGTGACTCATTCTTGTGAGAATCCAAGTTTTGAACTATGATTTAAAGTCACAATATATGGTTACCATCTCAAATTTTATGTAGAGTGCAACTTTTTCTTGAATTGGCGTGTGTTTGGTCTTCTCGAACTTGCTTCTAACGCTATTTCAAACTTGGAAAATTTTGATTTTCACTCTTTATCATCTTGTTTGTTCAATGAGATTAGCCGTTTTGTTTGTATATTGGGTGTGTCCAATTATGCTCTTTTCTTATGTTATTGTTTATGAATAACTTGTTGAACATTTTACTTATCAATTCACTCCAATATATCCTAAAATTGGGATATGCTCAAATCACATCTAGATCTCATGATTCATATTTCTATACCATTCTTTCGATTTTGATCTTGTTTCTGTCTACACCTCCTGTAAAATATATTTTTTACACAAAATGTATTTAAAACCCATTATACAAAATAATAAACTCCAGTAAAGTGAAGAATTACAAGTAGAAGAAAAAAAAAAGACATCTCGTACAAAGTCAGAATTGAGAGAGCCCTAAACACAAGGAAAAAAACAAGAACAACAAGAAAAAGTCCACTTTGTTTGGTTTTAGACAAAAACAGTAACTTACTTTTTTGGTCAAACTCTGTAGAAAGAATCAATCTCCCTTGTAAATCTCACCCTCCTGTCACCATCTTCCCTCCGTCACTTTCCCAATTTAATTTATAATCAGAAACCCTACATATACACCTAGGTTTAGGGTTTCGCTTTTTCAGAGAAAAATAGTTTCTTTTTCTTCAAGTTAAAAAAAAAAAATTATTAATCTGGTACGCTACAGTGCACCGAAATCCCATAGATGTATAATACTCTGAGCCGTTGATGAAGCTGACGCAACCGCCACATGTCTATCATCGGCAACAATGGCGTCAACTTCTCCTACTCTCTCCCTAATACTGTACAGATACTCTCCTCTCTCTACCTCCCACACGCGCATTATACCACCTGCGCACATTAGCGCGTGCAGTCTATTAACACAACCCATTACTCTTCTCTGCGCCGCTCCACTAACACGGAACTCACACACCGTTTGTTGCGTGTTCACCCTTCGCACGCTAGCGTTTCCTCTACTGTCCAATCTAACGTACGCTTCGTCGTTGGCATCGAAGCCTGTCACTATTAGTCCTCTACGTTGCTCTTCGTCTTCTCCGATGATCACTCCTTGGTTTCTTAGATCGATCACCATGATTCTCCATCTCGTGCATGCTACCGCCGTCTCGTTACCGGAGATTCTGAGACGGCCAAGGGACGTTGTTAGCTCTGTTAACGTGTGCCATCCCATGACAGCTTCAGGGTCGGTGAGTGTACCACCGACGAATGTTGTCTCTTCGCTGTTACAGTCCCATATGTGAAAGGCACGACCTGGCACACCCGCGAAAAGACCGACCCACCAACGTCCACAGCCAGTGAAATCTACCAACGCACCGTCGTTAACTATATCTCCTGCGTAAGCCGTGCGTGTGTGACCAACACCGTCTATTTCCGCCACGTGGATGTCTCCGTCCATCGTAGCGAACGTGAGCCTTGAGTCGGAGATAACAATGCCTGAGACGGCTCGTGAGAATCTACCAAAGCGGTCACGTAGAGGTGGCCGTAAGGTCCTGACGTGGAGTCGGTTGTTTAAAAGAAAAAGCCGGACGGTTCCGTCGGCGAACCCTGCGGCTAAGTAGAGGTCTGAGAGGGTGAGACAACGGCAAGAGAGACTATCAGGCTCGTCCACATCAGACGGGTCAAATTGGAGAGTGAAGTAGGTGTGAGTACGCGTCCGGAAGTTTCTAGCCGTCCGATGACGGTAGATGAACTCGTCCCGCCACGTGTCGTGCATCAAATGTGTTCTTGCCCAAACTTGGCGAGATAGTAGTTGCCATAGATGGTCGGAGCGAGAGACAGCGTGCCACGTGGTGCAAACCTGCGATTAAGAAAAATTATTATAAGTTTTAACAAATATTATAATTAGTAGCTTAATTAATAAATGTATAAATAAGGGAGAGAGTAAAAAAAGACATAGAAAGAAGATAAGTAGGCCTGCAACGAAGCATGAAAGACTCTATATATAGGGACTAGGAAGATGGAAAGACAACGACAGACTCAGACACAAGCTCTGCGTAATATTTGTCTTACTCATCGAAACACACAACTCATTTTTATAAAAATCTATTTTATGACATATGTTCAATTGACGGGACTAATCAATCTCTGGAAGCTATAGATAGAGATATAACAACAGAAGCCCTAGTGTAAAAGGAATAATGAGAGGAAGCCCTAGTCCCATGTCAAAAGAACAAAAAACAAATCAATGTGACAATAATACAAAACAGATGATATGTTAATTTATTAGGACAGATGAGAAGACTTTAAATGAGTTAAGCTGAACATGAGATTCCGACTTTGCCAACAAGCGTGCCCTTCTCTCTTTCATTTCCAAGAAAGGATAGCTTTTAAGCCTTTGGTCTTGTTAAAAGTAGAGCTTCCCATAAATACACAAATATTACACTTATATATAGTAGATGTTTCTCTGTCTCTCTCATCCCTCTCCAACAATCCGTGGACCTACATTCTCTACATTTACGTTTATATTGTTATTTATTGTACATCTTTATTCCTCATTAAACGCAAAGTAATGTATTTGACTTCGTACTCTAGCTCTATAGTACAACCTAAAATCAAATATTTCGAATTCTATACGAAAAGAAAAGATATCTTGTCAAACCAAAGGTTTAATGTCTATTAGTCAGATAATCATTATAAAAAAAGAATAATCTAGGCACTAGGGCACGAAATGTAACATAAAATAGATTAGTACAACAAATAACATATGATGGAATGGCAAATCCTATTTATTATTATGCAAATTACCAATCACATCAATATGATATACTTCAAATAAGAAGGGAAAGAAAGTAGTTCAAATATTCCTGAGTTCTAAGATGACCAGATTCAGAATATCACTTTTGTATTTTAATGTGTGATATATCAAATGTAAGAACATAGTATATAATCTATAGACACCACTGCACGTGCTCTAAGAGACCCTTAACATTGGGTTCCATGTGCTTTTCGGCATATGTATGCCCATAATGTCGTCTCTTTTGACTGAAAAAAATTAAGGAAAGAAAAAAAAAAGATAAAAACCCACTTCAATGGAAAAGATGAATCGAGTCAGGAAAAAAGATAATTCCATGATCAATTTCAAAGTAAAAAACAACAATGAAAACTCTAGACTTATAGCCTTAATTCTCTGACAAAAGTGTTATGCTGTAACTACACTGCAGTTTCTTAAAATTTTAGGGCAAATTTGAAAATTCAATTAATTAGAAAATATTATGGGATTTAATAATGATTTAGAATTATCATGTATACATAGAGAAGTGAGATAAAATAAGAGAATGAGAAGTTGTCAGAAGCTCTGCATGCATTACTCAGTGGATCATAATATTGGCAGAGAAAAAAATAACAAAAGCAGGACGCAAAAAATGTACATATGTACTTATATACTATTCCTCGTTACTATATATGAGAAAAATCTTCAGCATAATATATATATGTATTATTTGTTTTTTTATGAACAAAAGAAAAAACAGCTATTTTCATATATAACATAGGATTATTAAAAAGAATAATATGAATGCCTGATATAATACATGGATCATATATCTGTTGATGAATAGAGTTTTCATGTATGTAGAAAATAACCTAATGTGGTAATATAGGACTAACATTGGCAAGGCAAAAAGACAGGACCTTACTTAGGTTTCTTTTCATTCTCTTTTTAGATGTTGTTAAATGTGCAACGACATTTTCTAGTTTTATGAGTCTGTCGTGAGAGGTCACTTTCTATTATTATAATTTTAAAACAATTAGCAGATAAATACCGTTATAATTATAATTCTAAAAAATATTAAATCTATTGGGCATTGGACTAAAGACTGTGCCTAATGTCTATCAACCAATATTTGGAGACAAGAAAGTGTTTAATTTGATTATTATTGTAAGAACTTTTGAGTCAAAAAGTGGATTTCTTGATCTTAAAAAAGGGCTTTCTACATGCCAAGAAAGGAAGATTTAAAGCCAATAAAATAAAATAAAACCTTGATTTTGTGCCCTAAGGGATCCAATTCATAATATAATATTAATATTAGAGTTACTATGCCCAAATGTTGTACAAAGATTACACAAACGAGATGGGGTTGTATGGTCTCCTTAGAGGATCCAAAAATAGACATTAAAAGGTATCAAAAGTAGACGAGAGAACAATGAAAAAGAAATAAACTTATTGGGTAAAAATGGAAGACAAAAAGTTTCTAAATACATAAAAGAAAAACAAAGTCCCCAAACTATATGATATGTGAAAGAGACATCAAATTAATGTCGTCTTGTTAGACATAAAAGTTGGACTTGGACCCATCATAGAAACACAGAAAGGGCGGTTACCTTTCCAAAGGTCAGTTTTTTTTTTTTTTTGTCTCTTCAGAATCCCAACCTTACAAACTAATATCACATTCAATCGAATTGAAGTAACATCATCACTTAATTATGATCTAAAGAGTAAGAATTCGTTATACCAAAAAGAATTAGAACGGCAGAATCAAATCTAAGCTTAGAAACAACTAAAGTACAAGACACTTGAAACAAGCAGTACATTTGACTAGACCAAGATTGTGTCCCTCCACTTAAGTTATTATAGACCCACGACTACTTTGACTTTGTTTTGTCTGCATAAGATCTATGTCTCACTATTTTCAAGTTCAAATATAAGCTAATAAACGAATTCAGATAGTGTAACGAAAATATTACTTTACTACCTGAAGTACATATATATATAGAGAGACACGAGATAATTGATGTGTCTCGACCGTTACAAAACTAAAAGAAGGTATTCAAAGAACGTTAGAACTGACCCGAAAAACGTTGGCAAGAGCCGGAGCTGCGGCGAGGAGGCCGGCGGATGTGGAAGCGTTAACGGCAACTTGAACGGCGAGAGATTCAAGAAAAGGCTCCGGCCAAACATCGTTGGCTCCGCGGCGAGGGCGGGATGGAGATGGGGCCTCGAAAACGCCGCCGCTTCCACCGGCTCCGTTGTCGGAAGAAGAGGAGGAGGTAGACATGAGACGAGAGGGGTTATAAGAGGAACAGGGGAAGAAGAAGAAGCGGAGAGAGGAGAAAGAATGGTGGGGGAGAGAGGAAACAAAGGACAAAAAGTGTAGATAAAGACATACTTCTCCGAGGTGGGGGACCCAGGTTGTGAAGGTATGTTTTTTTCCTATTTTTATTTTCTTTTGTCAAGATTTGTTATTATTTGTTTTTGTTTATTCTTAATAGATGCAGATTTGTTTGTGAAATAGCTTCAATTTTATATTTTTTAGGAAAAGTATTGGTTCAGTATGGTGACATATTTCAAAATTTCTTTCTTTTGATATGCAGATTTTGAATTATAATGGCAATATAACAGCTATATTATTATAAATCACTAGATTTATATTTTGACGATTTTTTATATTTAAAATAGTGTTATATATCATTAAGAATTCAACAATATATTTGCTAAGTTTATTTCCTTCCGCGAACATTAGTAAATTTTTTGTATATGGTAAACTATTGGCTAAACACAAATATTTGTAGATCGATCCATTTTAAAAATGAGAAATAAAATAATATGTATACGCAAAAAATTTGTCAGAGAGATCAAACTCGTAGCACCAAATCTCGACTTTCATACCAGTAGTAAAAACTTTTAAAGCATAGTTTAACATATTTTTTTTTCCCAACATACTATTGTCATTATAAGTAAATAATTTTTGGAAATCTGGTTAAGCATATTCTTATCATTACAATCCTCAAACCTAGAATTCGCCATATTCTGTCATCACAAAACTTAACCCTACTTTTTCTCATATTGCAGCTATCACGATCCTCAAAACCACGGTTCATCGTGAACTTTAGTCCAAACTCATCACAAACCAACACATGAGCATGCGATGCTTTTAAGTTTATTCCTCAATCTAAATATAGAAATATTTACATTTTCTGAAAATTATTCATATATATAGTGCTTTTATATAATTACAATTAACATTTTTGATTAGTATTTTTTAGTTAAAACATTTTTATTCTTTTTTAATTAAAAATAATTAACGAAATAATGATGAATCACGTTATTAAGAGAGAAAAAAAAATAAAGCCACATTATTAACGTCACTAAGAGGAACATTTTGGTTTTCCTCCCAGACATTGTTCATCTTGGGAAAAAAAAATGTCTTCTCTTTTACTAGGTGTTTATCCGAAAACGAAGAAAACCTATTTCTCGTGGCTATTCTCTCTTTCTCTCGTCTCTTCCGCCCGAAACTTTTAACGTCGTTGTCATCGAGTCACATTTCGTCTCAACTCAACTTGTTTCGATATGTGTCAAATCTTTATTTCGATTTTTCCGACAATAATCAGACATCTAAGTTCAATAGCAAGTGATTCCCATGATTAAAACCATTTTCTAAAACCACTGTTATGATATTGATGGTTTTTATCGACGCTTATTACGGCTGATTTTTGCCGTCGATTTACATATGGTGGCTGATTTGTTATTTCTATTCGATTTGATGGCTGAGTTATTGTATGCTTTAGGACTGATTTATGATTTATTAATGCATATGTGGTTGAGTTTGTTTTGTGTTGTGGCTTGGTTACTGTATGTTTTATGACTGATTTATGATTTATCAATGCATATGTGGCTAGGTTTGTTTTATGTTGTGGATGAGTTATTGTATGTTTGACTGAGTTATGATTTATCAATGCATCTGTGGCTAAATTTGTTTTATGTTGTGGCTGAGTTAATGTATGGTTATGGCTGATTTATGGTTTATTAGATGGCTAAGGTTATTTCTGAAGAACAAGCAAAGGATTACCCTCTAAGAATTTACGCAGAAGGAGAGTCTAATCTAGAGAATAAACTCATTAATCACAATATCAAGATGACATATTTCTATGGGATTTAGAGAATTAGTATGATAAGATGTGTGGGATCAAATGAAGGAGGCACCTATTGGAATAATTACTAAGTTATCGAATAGTCAATTCGTGTGGTCTCGTAAGACTGTACATTTTCTATTAAGTAGACAGTTAATAATACTTTTGAAGGAGATTTGGTGTCTCGTTGGTTAATGCTATAAAGATGTTGAGGCCTATTGGAAAGTCGTACACCATCAGTGGTATGGTTTTCATGTTACAGGCTTGGGCATATGATTCAGTCAAATGCTTTGGAGAGCGATATAGGAACGTAGTCAATAAGGATGAAATATCGTTGCTTAGATGGGGTGGAAACCGTACACGTACAACAATGGAATTTGATGTAGGTCAAATTGCTCTAAGTTTACTCCCTCAAATAAGAGATCGTCGTTAGTACTTAAGGGTAAAATTCCACAAAACTCTTTTGTTCACACAATAGGCTAAAGTATCAAAATCAAGCTAGATAGATGATAAGAAAATAAAAAGAAAGCAAGTAAGTAGATAGTGGATTGTGAAGTTGTAAGACAAGATAATAAAAACGTTAGGTTTAGGGTATTCTCAGGAAATAGATGATAAGAGATATAGAAATAGCTAGGATGTTATCGAATCGTTCTTAAACTCAAACCCTAATTACAGAATAAGCGGTGGTTCGCCGTGCTACTCAATATGCCTAGGGCTAAAGATTCCCAGCGGTCGCTTGGCAAATCCCTATATTAAGACATGCATGATAAACGAGTTTGATAAGTTCACCTAAATAGATAGGCCGATTCTTATTTCACATCTATAAACTTGGCTCATCAAATAGTATTTCTGGTAACATATACCTTTTTGGGCATACCTATTATTTAAGATTAAGTTCTAATTAGTTACTCTAGAACTAGCATTAAGAATAACCAAAGATGAAAAATCCTACATATATCCTAGCAGGTGAACAATCTACTAAATCATCTAAATCCCTAATGAGAAACCCTAACCCTAACAAGTAGACTACTCATACATGATGGATGAAACAAACAACATTTATGAATGAGAAAGCATAAACAAAATCAATAAGAAGAAAGAGTTAGAAAATATCTCTTCGGTATTATTGAAATCTCTGATAAAACTCAGAAAAATGAATCCAATGTATAAATAGCTTATAAAATGCTTTAGAACAAGTTAGGTGGCTAAAAACTTGTTAGGTCACAACAATGACCTTAAAACTATATATATATATATATATATATATATATATAACCTAAAAACGTGTAGGTTACATTATTAGGGCGCAACTGGTGTCGATCGACACCAAGAGTGTGTCGATCGACACTCTCGACTTGATCTGAAACTAAATTCGTCATTTGGCTTAGTTTCTTTAGCATTTGCTCCAAATTGTCTCCTTAACTCCATTCTTGTCCCAATCCAAAGAATACCTTAAAAGACTCTAAAAGGACTCTAAAACCTATATTTAAATCATAGTTAATGTTGGTGTCGGATCCCGCATCATGGGCTCGGATCCGGCCAAAGATTGCTACGTGGGTAAAAGAAGCCCATAAGAGAAAGGCCCATAAACGTCCTCGAGGTGAGAGTATGGATGAGGTGTTGAGTTGCGAAGTGAATACATCATCGAAGTCAAGACTACCCGGATTGAAGAGGCCGAATGGGCCGAAAGGTGAAGTCAAGAAAAGCTCGGAGTGGATTCAAGTTCCAACGTTCAAATAGTTAATTCGAAGGCTAGAAACGGACACATTTAAGATAGAATGATTGTGAGTAAATAGGTATTAAATGTATTCTTTGGGTATAAATTGTGGGTCAAAGACCATGTAAAGACAGACGCATTTCTTGGTGCAAATTAGCTATACACACTCTTTTACAATACTCATAGTTTTCTCTATAGTCACTTGTCTATTTTCTAGTATATTTGTCCTCAAGAATAATCCTTCCCACTAAATAAATAAATACTTGAGTGTGCGAATCCGACATCCACAGTTAAAAACAGTAAAAATAGGGTTATATCAGAATCGACCATTGCTAAAGATATCTAAGTGCATGGTGAGATAAGGTTTTGGCTGTGTTGTGATAGTTACTGATTGAGTTATGATTTGAAATGGCTGATTTATGGTTTGTGATGGCTGATTTATATTTTATGATGGATGATTTATGGTTTGTGATGGCTAAGTTATATTAGTGATGGTTTAGTTTTGATTTATTGATATTTGAGTTATATTTTAGTGATGGCTTAGTTATGGTTTAGTGATGGTTGAGTTATGGTTTAGTGATGTCTAAGTTATAATTATTGATGATAGAGTTTAAACTAACTAATGTGTTTTATTTTGTTATAGTTGCGTGTGAGTAAAATGGTTATGAAGGATGATGTAAGAGAGTTATTTCATACGTGGCCAAATCAAGTAGAAGACCCAACACTTGATCACTTGATCGAAAACATACATGAGAATAAGTTTGTTAAAGGTTATAGGGATGTGAAGAGAAATGAGAAGAAGAACAAACATGTAAATGGTAAAGTAGCGGTTGAGTCTGAATCTCACGCAAAGAAGCAGAAAGTCTCCCACAGTGAGGGTGGTGAATATTATGAAGGACATGCACAAAGGAAGAAGAAGAAAGAAAGAAGCAAAGGTAGTGATTTGTGAACAAAAGTGAGGCTGGTGAATCTGGTGAAGGAGATGCACAAAAGATGAAGAAGAAGAAGAAAGAAGCTAAGGTAAGTTATATGGTCTATGGTGAGTTTATATTTTATGTAATGTTTGGCTAGCTTGTTAGTGTTTGTTTTTTTGTATGTATTGCATGGTGTTAGTGAGGAGGATGATGTTCTCGAAGATGTGTTGGTTAGAGCAGTCGTGGATATGGTGTCCAAATTAACTTCAAGTTTTAACACTGTTGATACAAGCATTAGAGAAATGTCTTCAAATCTAGAGAAGGTGATTGGAGATAGAGTGGAAGCGAAGATGGATGCAAAGTTGGAAAGCGGATTTGGATATATTGATAGTGAGTTCAAACAGAAGAAAGAGCATTTGAATGTCATGGCCATGGGGGTAGAGCAAACTGACCAAAAAGCTAATGATTACGAGAACTCAGAATTCAAAATTACAGATCTACTCAGTATTTAGAAGCAGCGAGATCAGCTACTATGACAACAACAACAACAAAAAACACCAAAAGGTTCAAGAAAACCTCGACAAAACTACTATGTTACTAGTCCTCCTCATGTAAGCTAATAGTGCAACACATATGTTTGAATTATAAATACATTGCGGCTGATTAATAATTTTCTTATTTACTTACGGCTGAGTTATCATTATCTTATGACTGAGTTATCATAATGTTTATACAGGCGAAGGATATTGTCGATGTAGTAGAGAAGGATAATGGTATTGATGAGGTCAATAAGAATATGGATAAAAAATTTGTGAAGGCCATTGATGGGGTCAATAAGAATATGGATAAAGAATTTGTTAAGGCCATTGATGAAAAACGATGGTGATATTGGTTTCATTGAGAAGTCTCTTGGTTATAGGAAATTACGCCCTACGACGAGGAGAAATAACAAAGAGAATGAAGAGGTAAAGAAGAAATCCGTCAAAGAGCAAATCATCAAAGAGCCAACCGTGAAAGGTAAGAGAGGTAGAAAACCTGTAGAGGCGAAAAAGTTGACCATATAACTACATCCTGCTCTTGTTATTAATGAGAAGGGAGAAGCTGATGAAACAAAATTACCTGCTCTTAATGTGAAGAGAGAGTGTTGTTGTCTCCAAAAAAGCTGAGGAAGTCACTGACAATGATGGTTAGAAGGAAGGTGACAGTGACGTATGAGATGTCACATACCAGTTTATCGGTGAAAACGGAAGCACGTTCCCTGAGTCTGATGATGATGAGGATTGATATAATCGAAGCTTTAAAGACGCAGAGTATTAAGCTGTCTACGGATGGTAGTGCATTGAATCCACTCTTTAATCTCTCAACACGGGTTTTTCCTAATACTGGAGACAACAGACTGAAGTGCATGAGGAAGAATTGTGTGCCTTCAGCTGGAATATATGATCCTCTATCACCGGCTGATACAGCCAAATTGTAGAAACTTAAGGATTACTTATCCCCATTCTAGTATGACCCTTTATACCTTATTAAGTTGTTAATTACAACTTGTTAACATTATTTCTGTATATTAACTTGTGTTTATTTGTTAGGAATCTCCCATTGGGCAGGGCAACAAACGATGTTGATTTCTACAGGGTTATCATCTCCGAAAGAAAGCACTGACCAACCAGAGAATATGGATGGTTGTTCGATAGTGTAAGTATTACATTAGCAGAGTTATTAGTGTGTTTTGTCAGAGTTTTACTACATTATGGCTGAGTTATTGGTGTGTTATGCTACATTATGGCTGAGTTATTAGTGTGTTTTGTCTAAGTTATGTTATATTGTGTCTGGGTTATTATTTTGTTTTGTCTGAGTTTTTTTTTTGTACAACATGTGGCTGCGTTATATAGAGTCCTCAGGAATAGGTACAAGCGAAATCTCTGCCCATTCCACAACAAACGCATTGCATTTCTAGACACGTGATTCGTGTCTTTTTGGGTTAGAGAGTATGTACAGTGCAAAATATAAAAGAAGATGTTTAAATTCAAAGACACCCCGTATGAAAAGATAGTTAATGGTTTGCTTCCAGATAATCAACAGACAAATATGAAGTGAATAGAAGATGTGAATCACTTGTATTTGATTCCCCAAACCAGAGGCGATCACTAGGTGGCACTACACATGGACCAGATTAAGGGGCACATTGATTGCTATGATATCATTGTGGGATAAGTTACAAGAAACTGAATAGAATTGATTAGAATGTTGTAGGCCGTTTACGAGAATGATTCCAGCAATGATGAACGTGCTAATTCCTACTACAATCGGTGAACATAGGTTTGAGCAGTTTACATTCAAAAGGAGTAGTGTCTCCAGGGTCCCTCAAAACGTACAAGTTGGAGCTGCGGCGTGTACTCGTGTTAATTTTTTGAATGTCTAACGCTTGGTATAACTTTCAATGACATATGTGATTTCAACCTATACAGGTTAAGATGGCAGCATATATCTACAATAAGGCACCTAATCTGCTTGGACAGTTTAGGATTTTGACTTGGGATAATTATATTAACTTTTGAATCGTATTTTTTTCAACAATCCATAAGACCAATGAATTTTGTTTTCTTTATAATGGTTTGATTTCAAACTAATTTTCATATCTTGGCATTTTCAGATAATTAAATTGGAATTTTACATTACAATTATTCTTCTCATAGAATCAAAATGATAAATCTATATTAAATATGTTACTATATTCCAAACTTTTTTGGTTTAGTTTTATGGACTTACTATATTGTGCATAACTCAAATTAAATTAAGACATTTTCACTTGGGATCACTATATTAATTTTTGAACCGTATTTTTTTCAACAAACTATAAGGCCAATGAATTTTGTTTTCTTGTAATGGTTTGATTTTAAACTAATTTTCATATCTTGGCCTTTTTAGATAATTTTATATTAGAACTATTCTTCTCATAAAATCCAAATGATAAATCTAAATTAAATATATTGCAAATCTTCCGAACTTTTGTTTGGTTTAGTTTTATAGACTTGCTATATTATGCATAACTCAAATTACATTTAAAAACTCCATTTGTCAAACATTAGGTTTTAACAAATACCTCCATAATCCCCATGTGGCTTTCTAGTACAATTATTTGTCAAACCTACGATCTATCTTCATTTTAGAATTTCTGAGATTTCTCTCACAGCCTATAAATCAAGTACAACATTAGGTTTATAGCATGATCTCCAACATTAAGAATAATCAAGTTTTTACCATTTGTTGTTATTTCCAACTTAACATGATCAAAACTAAATGCGTGGAGTCTTTATGTCCTCGACATAACATTATGTAAATACTTTTTGACTAAAAATAGTACCATTCACCCTTCTAACTCTATGTCAATTTGACTACAAAAACATTTTGACAAAAAAATGAACGATTACAAATTACACTGATGGAAAATATACTTAGTCGAATAACCACCAACGGTTGAATGTAAATGTGGAGTTCCAATTATTAATCATTTTTTTCGGCACTCAATTCACGAATGTGAATCACCACTAACGCATCTAGGAATATATATAGTAAGGTATACAACTTATTTTTTAATCAAAACAAAAAAATATTTGTAGATTTTTGGGACCTTTGGTTTTCCTTAAAATAGATAAGGGAATATTGGAGGATAGATATGAATCTATATGAATTAGAATTTAAGGTCTTAAATCCCTTTGTGATAAGGTTTGGGATACCTATATTTTAGGATCTGTGTTTATCTCCTGTGGAAACTCTCTTGTATAAATACGAACGTGAGTTCATCAATAAAAGCAAGTCACTTTGATAACCAATTCTACATGGTATCAAAGAGCTGAGATCATCAAAATCATCTTCAAAAATTTTGTGTTCTTAAGTTAAGAATTCTTAAATTGTTTCCTTTCTCTGTTGAGTTGATAGTCTTGTGTGTCAAGTAACAATGACAAACCCAACGTCTGGTGATGGATCTTTGTCAACCATGTCGAGTTCTATCGGAAAACAACCAGAGGTGGTGACGTCGGCGGTGACAGTGTCACCGTTCACTCTTTCTAGCTCCGATAATCCGGGGGCTATGATTCCATCGGTCATGTTGACTGGTGACAACTACAATTCTTGGTCGACAGAGATGCTAAACGCTCTTCAAGCCAAACGAAAGACGGGTATCATTAACGGTGCAATACGTAAACCACCTGCTGATGATCAAAATTTCGAAAATTGGACAGCGGTGAATTCTATGATAGTTGGATGGATCCGAGCTTCCATCGAACCAAAGGTGAAATCCACCGTGACTTTCATCTCAGATGCTCATCAATTGTGGATTGATTTGAAGCAAAGATTTTCTGTGGGCAACAAAGTGCGTATTCATCAACTCATAGCACAGCTCGCGACATGCCGTCAAGATGGACAATCTGTTTTAGATTACTATGGACGGTTGAGTTCGTTGTGGGAAGAATACCAAATTTACAAACCCATCACTACGTGTACGTGTGGTTTGTGCACTTGTGGTGCCACATGACAACCATCCAAAGAACGAGAAGAAGAGAAGATTCATCAATTTGTGTTGGGACTTGATGAATCTAGGTTTGGAGGAGTTAGTACCAATATCATATCTATGGATCCTCTTCCAACTCTTGGTGAAGTATATTCGAGAATCATAAGAGAGGAGCATTCTTCTCGCAACAACGAGCAACATCGAGAGTCAGTTGGTCTGTTTACTCGACATGACCAGTCTGCTTCAGATGTCGCTGCCTACTTTGGGAAATCAGATGTGACTGCTTTAAACAGACCTGAATCCTCAATCATCAAACCCCGAGATTGTAACGTGCTCTGTTCGCATTGTGGACGAGCTGGGCATGAAAAACAGGAGTGTTGGCAGATCGTGGGGTTTCCTGATTGGTGGAAGGAACGAGAACGTCTTCAAAAGGCTAGTGGTCGTGGAGGAGGAGGACGAGGAGCAGGACGAGGAAGAGGACAAGCTTTTACAGCTCATGCCACAAGCTCACATTCCTCTGTTTTTCCTGACTTTACACCGGAACAAATAAAGGTTCTTCAACAAATGGTCACCGAAAAATCAAGCACCAATAACGTCGACAAGTTGTCGGGTAAGAGAGCTCTTGGTAATGTGATACTTGATACAGGGGCTTCTCACCACATGACGGGAAACCTTTCTCTATAACATAACATCAAAAATATTTCGCCATGTTCGGTGGGATTCGCAGATGGAAGTAACACATTTGCCTTGAGTATGGGAGTGTTCCCATTGTCTGACACGGTTTCGTTAACCGATGTCCTATACGTACCATCTTTAAATTGCACACTTATCTCAGTTGCTAAGTTCATAAAACAAACCAAGTGTGTAGCTTTGTTTACTGAGACCTTGTGCGTTTTGCGGGACCAATTTTCGAAGACTTTGATTGGAAGCGGTGAAGAGCGTGATGGGGTTTACTACTTTACGGATGTTGTTTCACCAAAGATACATAGCGTGGATGTTGTTTCTGACAAAGCGTTGTGGCATCGGCGATTGGGACATCCATCATTTTCTGTTCTTTCAACTTTGCCTATGTTTCTAGTTCTTCGAAATCTGCTACTCCAAGTCCTTGTGACATTTGTTTTAGAGCTAAGCAGACTAGAGAGGTTTTTCCAGAGAGTTTTAATAAAGCAAACGATTGTTTTTCTTTAATACATTGCGATGTTTGGGGGCCTTATCGGGTTCCATCTTCATGTGGAGCAGTTTACTTCTTGACTATTGTTGACGATTATTCAAGAGCGATGTGGACATATCTGCTTCTTCAAAAGTCAGAGGTACGAAATGTGTTGACAAACTTCATTGCATATGCAGAGAAACAATTTGGAAAAACAATAAAAATCGTTAGGAGTGACAACGGGACTGAATTTATGTGCCTCTCTTCTCACTTTAAGCAGCAGGGTATCATACATCAAACATCTTGTGTTGCGACGCCACAGCAGAATGGTAGAGTTGAGAGAAAACATCGCCACATTCTTAATGTTGCTAGGGCATTGTTGTTCCAAGCTAGCTTACCTATCAAGTTTTGGGGAGAAGCAATTCTTACTGCAGCATATCTCATCAATTGCACACCCTTTTCAGTTAACAATGGTCGTTCCCCATATGAAATTCTACACAACAGCAAGCCTCCCTACGATCAACTCCGAGTGTTTGGTTCAGCTTGTTATGTTCATCGTATGGCTCGAGACAAAGATAAATTTGGAGAAAGAAGTAGACTTTGCATTTTTGTTGGTTATGCTTATGGAAAGAAGGGATGGAAGGTTTATGATTTGGAGAAAAATGAATTTTTCATATCTCGTGTTGTTATTTTCCGGGAAGATGTTTTTCCATATGCAGCTGGTGATGTTAATTATGTGCATGTTTCTTCAATACAAGTCATTCCTGATGAAGACTGGCTGGTACCTCCGTCTATAGTTGTAAGGGGGAGCTCAGAGTCTCAAATCGACTCTGTTCCAGCAACTCAAGCGGCTCCTCAAATCGACTCTGTTCCAGCAACTCAAGCGGCTCCTCAAATCGACTCTGTTCCAGCAACTTTAGCGGCTCCTCAAAACGACTCTGTTCCAGCAAGTCCGGTTTTGCTTGAAAAATCCACGAGTTCGTCTCCTGTTACAATTACACCACCAGCTTCTCCGAAAATAAGAACATCGTCTTCTTCACCAACACTAGCGCCACTTGTTGATGTTTTAAAACCTGCAGATTCGCCTCATCCTATTGTGGAATTGCGTCGAAGCAAACGAGAACGACAGGAATCTGTTAGACTCAAAGATTATGTGGCTCATAAAGTAGTATGTTCTTCAGAAACCCATCACGCTCTGCCCATCACTGCCTCTCCATCATTGTCTTCGTCAACGGTCTAAGGTACGTTTTCATCTGAATATGAGTCTCTGTATTCGTTAACAGATTTTATCTCGGATGAACAATTCTCACTAGGACATCGTGCGTTTTTGGCTACCATTACAAAATCGGTTGAGCCTAAGCATTTCAAGGAAGCTGTTCAAATAAAAGTTTGGAATGATGCTATGATCAAGGAAGTTGATGCTCTTGAAATTAACAAGACGTGGGATTTGGTTGAGCTTCCTCGCGGAAAAATTGCACTTGGAAGTCAGTGGATTTACAAGACGAAATACAACTCGGATGGTACGATAGAACGGTATAAAGCTCGTCTAGTAGTCCTGGGTAATAATCAGATCGAGGGAGAGGATTACAAAGAAACTTCCGCCCCTGTCGTGAAAATGACTACGGTTTGTGCTCTTCTTCGACTCGTTGCTGCTAATCAATGGGAGGTATACCAAATGGATGTCCATAATGCATTTCTCCACGGAGACTTGGAAGAAGAGGTATACATGAAACTCCCTCCAGGCTTCCGTCATTCACACCCCGATAAAGTTTGTCGACTTAAAAAGTCTCTATACGGACTTTAACAGGCTCCACGTTGTTGGTTCAAGAAGTTGTCTGATTCGTTACTTCGATTCGGGTTTGTTCAATCATATGATGACTACTCTTTATTCTCTTACACTCGTGAAGGTATGGAGATCCGAGTTTTGATATATGTCGACGATCTCCTCATTTGCGGGAATGATAATTATATGCTTCAAAAGTTTAAAGAATATTTGAGTCGTTGCTTTGCAATGAAAGACTTGGGGAAACTCAAATATTTTTTGGGGATAGAGGTGAGAAGAGGACCAGAGGGTATTTTTCTGTCACAGCGCAAGTATGCTTTGGATATTGTGGCGGATTGTGGAACTCTCAGTGCTACAGCTGCTGCAACTCCTCTTGAACAAAACCATCACTTAGCTGATGACGATGGTCCCTTACTGGCTGAACCAAAGAAGTATCGAAGGCTGGTAGGACGCTTGATCTATCTCACTCACACACGACCCGAGTTAAGCTATTCGATACACGTTTTATTTCAATTCATGCAAGTTCCACGTGAGGCTCATTGGGATGCTGCTCTTCGTGTCGCTCGTTATCTAAAGGGAGCTCCTGGTAAAGGCATTTTGCTCAAAGCTAATCCGGATCTTACTCTTACTGTCTACTGCGATTCAGATTATAATTCTTGTCCTCTAACAAGGCGCTCTTTGAGTGCTTTTGTTGTTTTGCTTGGTGGCTCTCCTATTTCTTGGAGAACAAAGAAACAAGACACTGTCTCTCACTCTTCCGCTGAAGCTGAGTATCGCGCAATGTTTGTCGCTCTCCGTGAGATAAAATGACTTCGAAAACTCTTGACAGGATTGGGTATCAAACTCACTGCGCCAGCTCGTTTCTTTTGTGATAGTTAGGCTGTGATTCACATTGCGGCAAACCCAATGTTCCACGAACGCACCAAGCACATCGAATCAGACTGTCACTTTGTCCGAGATGCTGTCCGAGATGGACTTATCACTACTTGTCATATTGGCACTACGGAACAGCTAGCAGATGTCTTAACCAAGGCCCTTGGACGTGTTCAATTTCTTACCTTAATGTCCAAGTTGGGCATTCAAGACCACCATGCTCCAACTTGAGGGGGAGTATTGGAGGATAGATATGAATCTATATGAATTAGAATTTATGGTTTTAAATCCCTTTGTGATAAGGTTTGGGATACCTATATTTTAGGATCTGTGTTTATCTCCTGTGGAGCTCTCTTGTATGAATACGAACGTGAGTTCATCAATAAAAGCAAGCCATGATAACCAATTCTACAGGGAATTTTAATAAAATGTCAAATCTCTCAAATTCATTTTGTTTTGTGGGTACTTGAATTCAGCAAACGATTTGTCATTTAAAAAAAAAATCCTAAGCAATCAAAATTTATGGTTTTTAGCTAATTTGATTTGCGTGGCAACATTGTATTTACCGATTCTGTGCAAATTTGACTTAGGCCTTGTGAAACCCCAAACAAATAGGATGGCAAATAATGACAAGAAAACCTCATTTTGCTGTATGATTGATACATTTATTTTGCAAATGTCTTTGTAGTCAAACCCGACCATACAACTAAATATAAAATTTGATTGGATCAGAAACCATATATTCTCTCGCTGGACTCTTGTAAGAAAACTAAAGATAATCTAATACGATTCAGGTGAAAAAAACTAACATCACATTATTTTTGTATAAGTTAATATTGAACTATATATATATATATATATATATATATATATAATCCTTTTACAAAAAATATATTTTATATATATATATATATATATATATATATATATAAATCTAAAGAAGAAAAACACATGCCTCTTTTCTCGAAATATAGATGAGTGTTGCCATAAAACAAATATGCAAATAAGTATGTACAAACTTAAGTATTTTTTACCAAAAAAAACATAAGTTTTTTGGTCAATTATTTATAATAAAAGATTTTCTAGTTCATATCATTGTGGAGGATGGGCTTTAAAAAGTATTAAAAAGATATTTAAGAAATGAAAAATAAATGGCAGTAGAAAAAAAGAAAAAAGAAAAATAAATGATGGCAAATATATCTAATGAAGAGGAGGATTTAACAAGATTTATGAAAAACTATAAAACGTTATATAGTGTGTAAAAAGGTAATAAATAAGTAATTTTTAAAATTAGTGAAATTTATAATAATAATTTTTAAAATTAAGATTAAATTCTATTATAATTATAAGAGGATAATATAAATCAATTCTTAAGAAATTATCAGAATTGGCAATGGATTCTGTGTATTATAATTATAAGAGGATAATATGATTCATTTAGATTCAGTCAGCGACTCTAAAAAATTATACTTTACAACAACATAATAAATCATAAGAATTGGCAATGGATTCTGTCTACCGAAAGATGTGGGGTGAATTCATATGACGAAATAAGTGGTGCAATTTCGTAATAATCGAAAGATATGGGGACTAAATCTTAAATAGAAACGTTAACTTGATCACAACGGCTATAATTAGTTACTAATCACAGTAATTAAACCACTAAACTCAAAAGAAAAATGGAAACAACAAAAAGCCCTACCCTCTTTCCTTAAAGAGAAGGCAACTTTTTTCTGCATTATTCGATCAGCGGCTCTCCATCTTTCTAATTTCCTTGTTCCTCACGACTTCATTCTCAGAGCTTTCGAGTCTTTCGGTTCCATTACAATGACTATGTACGATCTCACGGATTCAGGGAAGGATATGTGTTCGAGTCTTTGTTTACTGGCCGAAGTTGCGGTTATGGTTGCGGAAGAAGAACAATTTCGTCGTCTTCTAAAGACTGTCTCTAAAGAAGAAGATAGCGACAAGAGTTTCTTCTATCGTTTCCCGAGAAAAATCAGATCGTCTTTGGTGAAGAGAAGATACACGCAGCAAAACCCTAACGGGGCTTCTACTTCTTCAGCGGTTCTCGATCTGAACCTAATCACCACTGATTACGACTTGAAAACCCAACAAAACCCTAGTTTTGATGAGCCGTTAGTTGGTGTATAATGGGGCTTCTGCGTCTTCATCGTTCTTGAACCTTCGTTGTTATGATCCTTCGTTACCCTTGGATTACAACACGGCTAAGTTGGGGAAGACAGAGAAGAAAAACCTAACAAACCCTAATTACCAATCTTCATCTTCGTCTTCATGCCTAACGGAGAACAAAAGCCGCAAGAGGCGTGCCGTGCAGCAGAGGAAGAGTGGTAAACTCAAGAAAGCGAGGGTTGTTTCTTTGCCAAGGATGTCTATAGAGACGCCAGAGTGGGTTTTCCAGGTGATGAGATACATGAACGCTGATGCTGAAACCCCGAGGCTGATATTTGAGAGGACTCTGTTCAATAGTGATGTCAAATCAGGCCTGAGCCGTCTCTTAATCCCTTTCCAGCAGCTAATCAGAAACGACTTCTTGACGCCTGCGGAGTGTAGAGCCATACAGAAAGACGAAGACAACGAAGATGACAAGAATATTGGTGTGGGAACGATTCTTGTGAACCAAAGATCTAAAATGTGGGGTTTGCGTTTCAAGATATGGGCGATGGAGAAGGACTCTGGACACGGAACATTGAATTACATTTTGAATTGGGGTTGGAACGATGTAGTCAAAGGTAACGGCTTAAAGGCTGGCGACAATATCAGTCTTTGGACTTTCAGGTGCCGTGGAGTCCTCTGCTTTCCTCTTGAGACATAGTAGCTCTCTGATATTTTCATTTGTCTCTTGAGGTTTCATTTATATAGTTTCAAGTGATTCTTGAGGTTTTTGCCTTTTTAGCATAGTAGTAACTTGTTGGAAGTGTTAAGTAACTTGTCTGTCTCCTCTGTTGTCTCAGTTCTTTATCATTGTTTGAAAATAAACTATTTTGTCATAAGTATGGTTTGTTGTTTTGTCTACTTAAGTTACTGCATTGTTCAATATACCTTTGTGTTATCTCAGATCTCTCCTCTAAACCTGTTGCAATGATGGAAATGGTCTATTCCTGCAAGAGTTTTGGTACATTCCTCCGAAATGCTCGATTTAGAACCAAAAACAATCAAAAAATGTCAGAGAAAAAGCAAGTTTTGGTAACAAGGATTTATCTACGCATTGATAATATCGACAAGTTAGTTTACTCATATTAACACCAAATCATATTGTTTCTGTCGAAAGCTTAAGCTTCTCCAAGATCTCCCCATCTCACATTGTACTTAGATGCAAGGTAATGTGCACCAACAGGACCTCTGCTTCCATATGGATAGAGCTCAGGAATGATTTTCTTCTCCTCTAGTTCCTTCAAAGCCGGTGTGAATAGATCCCATGCTGCATCTAGCTCATCACTTCTGATAAACAACCTCCTCTCTCCTTCGATTGCATCGAGAAGCAGTCTTTCATATGCATCTGGTATCTCTCTTGGATACCTATCAACCCCAAAAGAATATAAATAAATAATCTCTATAGGAAAACTAGAATCAGTAGTATGCATTGTTGTACCTGGATCGATATAGAAGGTTAAGGTCGCTGCGATCTAGTCTCATTCCAAGACCAGGAACTTTGTTGTTGATCCTCAGGTATATCCCTTCATCAGGCTGAACTCTAATCACTAGTTCATTTGTTGCATTGTCTAAATTAGTAGCAAAACTTTTCTTGTACAAGTTTCCTGGGACATGTCTGAACTGAACTCTGATCTCTGCTCCTCTGGTATGGAGAGCTTTTCCAGCTTTCATAAGAAAAGGAACACCGTCCCATCTCGCATTGTTGATGAACATGGCTGCTGCAGCAAATGTAGGAGTGAGACTGTGATTTGGAACCGTTGGATCGTCTGTATAACCTGGATAAGTTTTTCCTCCCTTGTTATGGCCTTTGTATTGACCAACAACCACATCTTCAAGCCGCAACGGTTTCATTGATCTCAAAACTTTCACCTTACAGGAACACATAATCATCGGTATAGTATTTTATAACCAACCTAAAGCTTTTCTTCTTAGTGAAAAAAGTCTTACCTTTTCACTTCTTATGTCCTCAGCATCTAAGCTCACTGGCGTCTCCATTGCAAAAAGTGCAAGTATTTGCAAGAGATGGTTTTGCATGATGTCTCGTATGATTCCATATTGATCAAAGTAACTGCATCGATTTAACATTAGTAAGGTGTTCAGTGTCATACTGATCAAAGGTGTTCAGTGTTCATGCTTTGTAAGTTGTTTATGAAAGCTTACCCTCCACGCCCTTCTGTTCCGAAATCCTCAGAAAAAATCAGCTGAACGTTGCGTATGTAATTTCTTGACCACAGAGGCTCGAAAACAAGATTTGAGAATCGGAGCACTGAAAGGTTCTCAACAAGCTCCTTTCCCAAATAGTGATCAATCCTACGTATGTCACATAACATTGCAGTTAAGTTCCAGCTTAAAAATGAATGGCAGTGATGGCTGTTGGGCTAAGGAAATGGCTAACCTGAAGATTTGCTCCTCTGTAAGATACTGTTTCAGACATCTAGTTAACTCTCCGGATGATTCAGAGTCACGACCAAATGGCTTTTCCACAATGACCCTTGTCCAGCCATTCTCTGAGGAGGCTCTAAGACTTGCACACCTAACCACATCAACGAATATGTTTGGGGGTATCGACAAATAGTACAGCCTGTTTGATATCTTTCCTGCCTACAAAGCAGAAAGGAATTAGAAATGTGCTTCGTGCCATTGGTACAAGAAATAAGCATAGAGAGAGTGAAAGAAAATTACCTCTTTCTCTTTGAGCTTCTTGTTTAGTTCCGCAAAATCCTCTTCCGAGTTATACTGACCCGAATGGTAAAAGCATCTTTTCAAGAACTGCTCCATCTTATCCCCACATTTTTCCCTGTTGATTCCAACTTTTGTTCATATAACCAAAGCATAAACTTTAACTAAAACATACACTAAAAACGTATAGCAGAATATACCTCTGATCAATCCGGCAAGTTAAAGTACTACTAATCATGTCACGAAGCTCTTCATGAGTGAGTTTAGTCCGAGCATAACCAAAAACAGAAAAGTCCTGAGGAAGACAACCCTCATAAAAGAGAGCAAACAATGCAGGAAATATCTTCTTCTTGGCTAAGTCCCCTGACGCTCCAACAACTGTAATACTAAGAGTAGACTCTCCTTTTGTAACATGTTCCTCTGTAAGTTGATCTCCAGCTGAAACAATTTGGTAAAAACCATCCTCCAAAGAATCAAAAACACAAACAAAAGCTACAAAACTACTTCAATTCATAAAAAGAGAGACTTTATCAACCAAATTGCTAAACCAAACCCTCACTACCTCACAATCACTCTAATCTACTACATTCAATCCTAGAATACTCAAAGACATAATCCTTAGATGAGAAATGGTATCCTTGAGTACAAAAGATACAATCTTGAACTACTTTCTTCAATCGTCAAAAACACAGACAGAGGCTACAAAACTACTTCAGTTCATAAAGAAAGAGACTTTATTAACCAAATTCCAAAACCAAACCCTTACTCATTGCTATCTAACCAACTCACAATCACTCTAATCTTCTACATTCAATCCTAGAATACTCAAAGACATAAACTTTACAATCAAAGATGGTATCTTTGAGTATAAAAGGTCATAAAGATACAATCTTGAACAACTTTCTTCAATAGACATAAAACTGTTACAATCCTAACAACACAATCAACGACAGGTACAAGAAACTTCATCAAGAATTCTATCAAAAACTAATCTAGTCACATAGAAACTGGAGAAGAAACTCACAATCTTGTAAAGAAGCGAAATTAGTGGCACACCCATTTGAAGTATCAAGCTGAGAATGTTTCTCGGCGAAGAATCTCAAGCGAACCTGAGAAAACAAGGATTTTCTCGGGAATGTGAGAGATCTACTAAAGAGTGGTAGAGTCTCTTTAAACGGAGACGCAGCAGTAGCGAGAGACGAGGAAGAAGAAGAAGGAGAAGGAATGATCATAGAATGTGTCGCCATGCAAATTTTCTTGGAGCGTCAAAACAAATGTGATGATGATGATGATGCCATTGTTTTTTGCCTTATGAGGCTATTTGTATCGTCTCTTACATTATCCACAACAGTAGTTTTATTATATAGTTTTCGATATTTCTTATCTCTCACATTATCCACATATCTTATTTGTCAAAAAAGTTTTATTTTTCTTTGCATAAATTCTTTTTTTCTCAAGAAAGTAAACCGTATTAACATCCATCTCTGGTATAGCTTAACCGGATTATTCCATTCGAACGACCACAATTCGCTGGAAAGGTGATTTTGGTTTAGCAGTAAATTTCATACTTTATTCATTTTAGTACTCTCTTATGCACACTTTATTAATTTACTAGGTGAATATCCGGGATTTTTCGTAAATGTTTTACTTATAACAACAACAAAGGAAAGTTGTTTTATGTTATCTCTTTCTAGCCTTTTTGGCTTTTTCTAAATATACTGCATAAGCTGACTTCTCTGATTAACAAAGACTCCAATTTAGCATGATGAATAATGAGCATCATTTATACAAATATTATTTCTAAGATTCTATTTTCACCTAATTTAACCACATTTTGTAGAATTACTTACAATAAAAATTTAAAAAACCTATTCATTTTGTTTAAAATATTTTACTTAATTAAAATTTTATCATTAATCTTTCTGTCATTTACTTTTTGAGTATTATTGATTTTTATAAATCATATCAAAAAAGTTCAAAATATTTTTAATCTAAAAAAAACAAAGTATAAGAAAAATTTTAATGCCTAAAACTTATGAATACTTAAACTTTTTCACATTTATTTAACTACTTTAACTATCTTAAAATTACATACAAACTTATTAAATAGTACACATGCTTGACGACATTAAAATATATTCTCCTACTAAATATACAACAATCACCCAAAATAATAAAACACAGGTTGAATCCTAGTCATTATTTAGAATGATCATCTCTTGTGTCCCTTTTGTGGGACAACTAATCTGCAAAACCACTTTAGAGTCTTCCTATCTCCTTTGAGTTAATGAATTGTGTTAAGACGAATTTACCCCTGTATTTTATTTTGAATGAATAATTAATATTTCTAGAAAACATTTTGAAAAAAAAAAAAACGGAAAAAAAAAAAAAGCTCGAGCTCGTTCTTCTTCGGGCTTCTTCCTCCGGCGAGCCGCATTGTCGTTTTTCTCCTCCTGCAAGCTGCATCAATCTACTAAGTCCAGGTATGGAGAGAGCTTCAAAAGCTTTGAATTACATATTTTGAGGATTTTGAAATTCAATCAAATTAGATTTGGATTATTGTGTTTTAGCACCTACATTAGAAGTTTAAGTATAGATTTAGGCTTCATTTGGTCTGTTAATGGGTAAGCAATTGATTTCACATGCTGATTCATACTAAATTGAACTCAAATCGAATATTTGTTCTTGTCGCGAAAATAATACTGGTCGCACTAACTATAGTAGTACCGTAATTTATATAGATAGTATGTTTTAATAGCACCAATATTACTTAGACACGTAGTATTTCATATATGTAATAGTATTACTCACACATGTAATATTTCAGAATTAGTAATAGTATTACTGAAAATGTACTAGAATCGATAATACTAGTAATATTGACTGAGTATGTGTATTGTTTTGGCAGGTTACAATGAAAGAGAACGTGATCATATATTTTAAATTCCAAGGTCGCATGTATAATGTGATGATGAAGACATTAGGGGAGAAGATTACTCTCTCAATGTTAGAAGATAGGATAATGACGAAGCTTGGATTAGATGCAAATAAGGTAAAATTGCATATGAGGTACAATCCACGGTTGTTCGGAGTAGAGGAAGAAATGAACGTTTGTGATGATGAGGATGTCTTTGTTTATGTAACATCCGCAAAAAATAACTGAAGAAGTGTTTTGGTTGTGGAGGAGATCTCTAAACCGCCCGAGCCGGAGCAATTGCCCGAGCAATTGTCTAGAGTTGGTAAAAGTTCTGTTGGTAAGAACTATACAGAGGAGGATGAAATGAGAGTGGATGATGGTGCACTCATCGTCTTATTAGAAGAGGAACAAGGAACTCAACATCAACTTGAGGCAATAGTGGAGGATCACGGGACTCAACATCAACTTGAGGCAATAGTGGAGGATCACGGAACTCAACATCAACTTGAGGCAATAGTGGAGGATCACGAGACTCAAGAAGATGAAACACGCTATGATGAGTCTATGGATGATTCTGATAGGGGGGAACAGTATGTTGAGTCGCCACCTGTTGTAGAACCGGGTATGTTTAAGAAAGAATGGGAAGACGGAATTGGGTTGACCTTACGTCAAGAATTTCCAAACAAGGCGGCATTGCACGAGGTGGTGGATAGAGCTGTATTTGCTACCATTTTTGGTTATGTGATTAAGAAGTCGGATAAGGAGCGCTATGTCCTAAAGTGTGCCAAAGAGAGCTGTTCTTGGCGTTTACGAGCGTCCAATATCAGTAATATTGATATATTCTCGATTAGAAGGTATAATAAGATGCATAGTTGCACTCGGCTAAGTAAAGGTAGTAGTAGGCTCAGGAAAAAAAAAGGCAACCCACAATTAGTCGCAGCTCTCCTTCATGATCATTTTTCGGGACAGTTGGAAACTCCGGTTCCAAGAATTATCATGGAGCTAGTTCAGACGAAATTAGGTGTGAAAGTATCATACTCGACAGCGCTAAGGGGGAAATATCATGCGATTTATGATTTAAAAGGTAGCCCGGAAAAAAGCTACAAGGATATCAATTGTTATTTATACATGTTGAAGAAGGTAAATGATGGTACAGTTACTTATCTGAAATTGGATGAGAATGATAAATTTCAGTACATATTCGTAGCTTTGGGAGCTAGCATTGAAGGTTTTAGAGTGATGAGGAAAGTTTTAATTGTGGATGCAACACATTTGAAGAACGGATATGGCGGAGTGCTAGTGTTTGCCTCGGCTCAAGATCCTAACCGTCACCATTACATCATAGCGTTTGCCGTACTCGACGGTGAGAATGATGCTAGTTGGGAGTGGTTTTTCGAGAAGCTAAAAACGGTTGTACCCGATACTTCAGAATTGGTTTTCATGACGGACAGAAATGCAAGCCTCATAAAGGCCATACGGAACGTGTATACCGCGGCTCATCACGGGTATTGTATTTGGCATTTGTCCCAAAATGTGAAAGGTCATGCTACTCACACCAACCGAGATGTACTCGCATGGAAGTTTCAGGAGTTAAGTCGGGTCTACGTCGTGGCAGACTTCAACCGAGCGTATGACGGGTTTAAGTTGAGATATCCTAAGGCGACCAAGTATTTGGAGGATACAACCGTGAAAGAAAAATGGGCAAGGTGTTGTTTTCCCGGAGAAAGATACAACTTAGACACAAGCAATTGTGTGGAATCTTTGAACAATGTGTTTAAAAACGCAAGGAAATACTCGTTAATACCAATGCTTGATGCGATCATCAAAAAAATCTCCGTTTGGTTTAATGAACATCGGATGGAAGCCGCGTCTGGATCCTTAGAAAATAAGATGGTGCCTTTGGTCGAGAATTATTTGCATGATTTGTGGGTTTTTGCCGAGAAGCTAAAAGTGGTGGAACTAAACTCATTCGAGCGTGAATATGTAGTCACATGCGACAAAGGAATAGATTATACGGTGAGCTTGCTTTTGAAAACTTGCAGTTGCAAGGTTTTCGATATCCAAAAATATCCTTGTATTCATGCATTAGCCGCTTTCATTAACATTATGGATGATGAAGATCGGAGAAGAGGTTTGGAGTAACATGATTTGGTTACAAAATATTATTGGGCGGAGTTGTGGGCATTGGCCTATTATAGGACTATTTATCTTGTTCCGGATAGGTCGCAGTGGGAAGTACCAGATGAAGTAAAGGCGTTGAAGATAGTTCCGCTGTCTAAAAAACCGAAGAAAGGAAGCAAAAAAATGCTAAGGTTTCCATCAACCGGGGAAAAGCGGCCAAAACGACAAAGGACGCAAAACAAAAGGCGTCCAAGGCAATCGTGTCAATGGTTATTATTTGGGAATACGCCTATCTGAGTTTTTTACTTTGTTTTTGCAGTGATTTGTTGTTTTTATGGTATGGACTTACTATGTAATACTGTATTTCCCCTTCTATAGTACTATGTCTGTTTCTATTGTTTTTTTGTAATACTGGTTATAACAAGTAATATCATGTCTGTTTCTGTCGAATTTGTGGTCATATTAGTACTACTGGTAATACTAAGTTGGTGTTATGGAGTTCGAATTTGTTTACCTCAAAAGTCAATGAAAATGAATACAGTGAGTTATTAACAGATAAAAATGTATTATTAATCATTTATACTTAATTAAATTAGAAATTTTAATATTAAATCGTTTTAACTTATCTTTAGTAGACTCAATACAACATTTCCCTTATACTTTTAAGCTCACTTTTAATATTATCACCAACTTAAAATGAAAAATTCATATTGCTACATATATTTAATTTATAATTACACAAAATATTTAAACCTCTATATTTATAAAGTTCAATCCAGTGTACTACTAAATAAATAAATTATAAATATAGGAAATACTGCTAAACATGAAAAACATGGAAAGTAATACTATTTGAGAAATTGGCACTACCAAAACCTTAGGAAATACTATGCTGTAAAAAGGCTGCGCACATGTCAAAAATCTCCAAAAAACGGCGCACACGTGGGAAATTAATTTTTTTGGTTTTCCTCCAAATTTTTTGGCGCCTAACAAATTTTGAGATTCCCTCCAAAACCAAAAATTTAACTTTTTTCTTTTTCCTCTTTCTTTTTCGATCTCTTCTTACAACTTTCTTTCATCTCTCATCTCTCTTCTCCCACATCTATCATCTCTCTCTTCGACTCGAATTCTCTCACATCTCTAATCTCTCTTTCATCTTTCTACCATGGATAGACTGTGTGAGAGAGACCCCTACTACGTTGATATAAAAGTGGCGAAGAGAGCCATTGAGCAAATGGAAATGGTTGCGATGATGGAAGGGATTCCTAAGTTTTGTCCATGTGGTGGTAGCATTGTCGACACTCGAAAGGATGAAAAGAGATACTATCAATGCGAGAAGTTTAAGGTATGTTGATGTAGAGCACAAGTATTTCAAGTTTGTGTAGATCTAGATCTAGATATATTTGGTATTCCAGAGTATTTCCCGTTTTGGTAATACTGCCTAGAACAAGTAATACTGCACAAGTTTTTCTAGTTTTTGTAGATCTAGATCTATATTTGATAAATATTTGGTACTTTGTAGGATAATAGAACTGATTGTATGCACATCCGTAAACTTTGGGATAAGGCTATAGAAGAAGAGGTGAGTAGCTTAAGGGAGAGTGTTGATTACAATCAGAATAAAGTTCTAAGTCATGAGTATCTCATAGAAGAAATGCAAAAAGAATTGAAAGCCCACCGTGCAGAGATTGTGAACGTGAGCAAAGTGGTATTCCGTAATCCTATGGCTCCCAAGAAGTAATGTGTTATCCTATTGTTCCTTAATCTTATTGTTAATTTGCTTGTAAGACTTTCCCTATGCTTTATAAGACTTTCCGTATGCTTTGTAAGACTTTCCCTTCGATTGTAAGACTTCTCTTTGATTGGTAATACTATGGTTGTTCAGTTTGATATTTCCAGTATATCTCTTAGTAGTAATAGCACGAGGTATTTCCCGTATTATTGTTAACAATATCATAAAATATCCTAATACATTAATTGAATCCAAACATAGTCTTACGAGTACTTGCGAAATCCTAAAACAAAGTCAAAGTACAAGAAATCAAAATACAAATCCGGAGAAGTTACACGAATAGTTTTCACACGTCACTAGACTTTGCACGGGTTGAACGGCTCACTCGTTTGGGCACAACAGGAGCAGCCGCATTTTCCTTGATTGTTGATTCCTCCTCATCTGGTGGGTTCTGAGACATCTGCATTGTTAATTTAGTTAAACCTTGGTATTACGCGATATTACCAATTATGGAACAGTATATCCGGTATTACCCAGATTTACCTTGGCTTTCATCTCATCCATAAATGCTTCGAACGTTGCTTGTTTTTCCTCCATTTCCATAAGCGCCAACAAAGCTTCATTCAGCTTGTCATTGATGGAATGAAGCTTCTCCATTACATCAACTAACGTCGGGTCTCCCGGTCCAACAGCTGTGGGAACTTCCTCTTCATTTGGGGCTTCCATTCGTGCCTGCACATCCTCGTTGTACACCTCTTCAAATCTAATTTAACGCCCTTGACCAAGACGCTTCATCCAACTATCAATTACAACATCGTGCTTATCAACATCATCCTCTACTCCCGTGATTTCAGCCAAAAGAGGTACTTCTTCAGCCTTCTCTCTAATTATACTCTCAATGACCTATGGAAATAATAGACAATGAAATATTAGAAAGAAATAAAATCATATTTGCTCAAGGAATAATAGGAAATACTAACCTCAGTTGTTCCGAGTACATGGTTGATTTGCTCAAGGGTAAACCCTTTCATCTCGGTCCTCTTGAAATTCACCTTGCACATCCTTGGACAACCGGCATGTGCACCATCTTTTTCTTCTATGAATCTTTCCCTAAGTGATGGAATGGCCTCAAATGCTAAAAGCTACACAAAACACATGAAATTTAATTGTTAGCTTCAATTACGAAAATGTAACAAGGATAAACATGTGACTTACCTCAAGCGGCACACAGAATCCGGGAACAGGCCATGGTGACTGAGTGTTCGGGACGACACCGTTAAAATGATCCAATGTGTGTGAGATCGATTTTAACATGTACTCAAATGAATATCTCCCCCATGGAAATGTCTTACAAAACGTAAGATCACTTGCAGCCCTAACACAGAAATCATCAATTGGACTAGCCCTTTCTCCAGTCTTAGTAGGCACGGCAATGATGCTTGTTAGAAAATAGAGGACCGCCATCCGCAACCTATCCTTTGATCTAGCCGGTTCCATCTCCATTAGCTTGGTTTTCACGTCTTCACGTCTAATTACCCCGGTTTTGAAGTACCTGTTGGCGAAGTTCATATTACCAGCGCTCTGATAATTAGCTGGATGGGCCTTGCAGTTGAAACTAAAGATCAAAGCATGCTCCCTAATACCATAGCGGATGGGAACTCCATTAACAACGAACCAAACCTCCTTCTTCTTCTCAATAGATGCCGTTTGAAGAAAAAACATCCACATCCCCATTAACTTGTGGGTATATCCGAAAGGCAGGTGGTAGATGTGCTTGAAACTCGGATGCTCCATAAAATAATTCTTCTCAACATGCGTTAGAGGATGTTCCAAGTCAGCGAAGGTCTTCAACACCTCCGAGATATAACACCTCGTTGCTAACTTCATCTTCTTGGTATACTCCGACGCCGGGAAGTACATACCAAGTGGCTGCATTGCCATCGCTTCCTCCATATCCTGAAAAAAAAAAACATTCATTCATATATCACTCAATTGTAAATAGTACTGCACAGTATTACTCTGTATTTCTCAGAAGTATTCCCCGTAATTACCAGTATTACACAGATACTCCTATTTTACTATGTAGTATTTCTCAAAGTTACTAGTACTAACTATCGATAAATCACAATTATAGTATTACTCTAAGGTATTACCCACATCCGCCAATATTACCTAAATATCAACATAGCATTTCCCAATGTTACTAGTACTGTCCACAGTTCACAATTGCATTATTACCCAATTAGATCGGTATTACGAAATGGAATACTTACCACATTTGCGATGTCCTCGTCTATGGTCCTCTCCTCCACGGGTTTTGCCACTATCACGTCCTTGTCTCTCTCGTCCTCGTTTCCCTCCTCCTCCACGGACTTTTCCACATTGACGTCCTCGTCGCTCGCGGAGCTCCTCTCCTCCTCCTCCTCGATAACGGCTAGGCCGTCATCTTGTCTCTCCACCTCTTCCACGGGATTAGCACACGCGAGTTCTTTGTTTGTCTCCGTCTCCTCTGAATCGGAATCGGAGCCCAAGGTTCGGCTACTCTTCCCTGATTCTTCTTCTTCACTTGCTTCTTCTTTTTCATTTTCATCTTCCACCTCATCAGTTTGCATATTCTCTTGAATTTCTTCAGTAGGAATATGCTTCAAAGCATCATAAAACGTAGAATCATCAAGCATCGGGCTCTCTGTCGTTGGAGCCGTCGTTGGAGCCGTTGTCGTTGGAGCCGCTGTCGTTGGAGCCGCATTGGTTGCCATCGCCGTCGCAGTCGTTTGTGCCGGCGCCTGCTCCTCAGCCGGCACTTTCTCTTTATCTTTCTTCGCCGACGCCTGAACCTTCGCTTTCTTCGCCGGCACCTTCTCCTTCACTTTCTCCGCCGACGCCTTAACTTTCTCTTTCTTCATCGGCGCCGACGCTTCTATCTCCTTTCTTTTCCCTACCTCCTCCACGCGTCTTAGGCGGCATGACTGATTTCGAATCGGAAATAGAACGGAAATACTGGTGAAAGGAAGAAGAACGGTCGATTGAATTTAAAGAAATATGGAATGTTGCGGTTAATTTCAGCGGTTACTAAGGAGAAGAAGAAGAAAAATCGAAAACGGTTGTAATGAGAAAAAGAATGAAATTCGAATAAAGAGTAAAGGTTCCCTAGGCCCTGGAAATATTAGGTTTTTTTTTGGATTTTCAAATAAAGAGTAAAGGTGGTTCGGGTGGTTTGGTTCGGAAACGAACCATGGTTTTTCTGGTAATTAATAGGTTCAGATGGGGATATACTAGTAATATCCATATATTTCAAATTAAAAAATAAATAAATTATTTTTGTTTTTTACAAGGATTTTTTGGCTTCCTCTTTGAAAAAAAGGGACTGGCCAGACGACCATCATAACTACAACATATTTATAAACACAACAACAAAAATGAAACTTGATAATGTTGTAATACGAACAAGAATCGAAGTTATTTTCAGCACATTCTTCGATTTTTTTTCCTGGAAAACCGAAACCAACTCAACATAACCCATTGAAACATTTTGTACCTGGCAGGCACTTGGTAGCAATGCCTTTGTGTGTTTTAAGTCTGGTTTGAGAGGACCACTGTGGAAGAAATGTCTTGGGCAGAGTTGAATTGGGTTTGACCTGAAGAAAGAGAAGAAGAGTCGTTAAAAAGAGATCTTTGGATTTTCTTTAGTTCTTTGACAACTTCCACCATCGTTGGAACTTCTTCACTAGGACCCATGCATCTCAGTGACAACATTCGGAAAGCTTTCATTTGACAAAGCTCTTCTTCGGAAATTTGACCCATCTTTTCTATCATCTTTGGATCTGCAATCTCTTCCATTGATCGGTCTTCCTTTAATGTTGACAGCAAATTTCGAGCATGTCTTTTCATCTTCCTGTCAAATCCACCTTCACTTTCTTCTTCTTCTTCTCCTCGATAATGCTCGAAAAAGCTTTCCTAATAGAAGCCTTATACCCATAAACATTCCAAAGCCAAAGACATCTGTTCTCTCTGAGACTACGCCACTGCTAATGTAATTATCGGCAAAGTAACTATAGAATCCCTCTGCTGCCTCAACCTGGACAAATGTGTCTCCTTCTGGAATTCAGACGCAGTGAGAAAAATCAGTCAGCTTCGCGACCCCATCTTCATCCAATAAAATATTCCAATGAGACAAAATCCTATATACAAAGAGCCTAGGGAACGCAGTGTGAAGGTAAGCTAAAGCAGTAGCAATATCTTCAACTATCTTCATTCTCCTTTTCCATGGATGTTCACTTATTTCTAATTTGTAATGTTTCTTAACACCATGATAAACTTTGACTGAATCTTCAAACTCAAGACAACATCCAACCAATTTCAAAAAGGTTTTGTGACCACTCACCATCGATGAAACTGCTATGTCGCGGCTCAAAAGATCTACTTTGAAGAGACTCGACAAGCCAAGATCTTTCTTAATGAGAATCATGGGATGGTTCTCGTTCTTACCTGAATACCAGTGGTAGTAAAATTCTTTTCGAGAAACAAGATTAGTCGCTGAAATTGTTGGTGGCATTGCGGATCTCATCACCAGAGAAGAATTTGATGGGATTGGATTTGCCATGGCCGAATTCGATGAGCTCTTCTAACAACTTGGCCCCTCTCTTGGCCACTCTACCGGAAAGAAAGCTTTATTTTTCACATAACTCAAAATCTAAGAATTAACGGAAAGAAAGCTTTATTTTTCAATCAAGTGAGCAAAAGTTTCGAGACGACCTCACACTTTCTTGATAACTAAATTCTTGTTGAGTGTTGACTATTCAACACAGATGTCCTTCTGCGAAAATCAGAAATAAACATTTTAATGGATTTTGTGGAAGTTAGAGTTGGAAGAATTGATATCATCCTATTATAATAAATCACCAGTCACTTCCCAAATAACTGCAGCTCTATATATTTGACACTTGTCCTAACTCCTAAGTCTCAAATTCTATTATTTTACTTTCTTTTATATCCTAATTTATGACAATTTTATTATAATAAATCACAAATAACTTCTCAAAGAATTGGCTCTATACCTTTAACACTTGTCCTAAGTCTCAATTTCTATTATTTTACCTTTTTTTTTTCTTTTTATCCCAATTTACGACAATAAAAAAAAAAAATGTTATTCTTCCCCATCTTCTCCACGATCACTATAATATCCAAGCAAACAAAATACAAAATTTTTAAATCTCAAAACTACAAATTATAATTGGTTATTTTACAATTGGAACAGCCATTCAAGCATCTTCAACGTCTCCTTTAAGTTTTTTTAACAAAAATTCTCAATCACAAAAATCATCATCATCGTCACCAAATAATTTTGCAAAATAAATTGTTACACTGATTTGACCGCGTAAAGCGCAGGTTATTAAACTAGTTTTATGATATTAAGGTGATTTTCTACGATTTTTTGGCCATGCTTTAGTTATCAATTCAAAATTATAAACGGTTGTCTTTTTTTTTTAACCGTTGTTATTAATTGTTTAGTGAATGGTCTTCAAAAGCTCACACACTCGGCTGGGATTAGATCATCAATTATTACTATAAATCAATCGTTAAGATTCTCGGTTGCTACCTTTTCCAAATTAAGAAAATATGTTCCGTAAATTTATTCCTCTTCTCTTTTTACCAAATATTTTTCAGCTTTACTGATACTGAGGTAAGCGATTTTTTTCTTATTTGATATAGCATCTGTGTAGTATATGCTAAAAGAATGACGATTTTAGGCTGTGTTGTGTGATTTTAGGATTTTATTGTTTGTGAGTTGAGTCTCATGTATTAATAAAGTTATGTGTATTTATTATTAATTCTGTTGTGTTTATTATTAATTGTATTATGTGTTTATATCATATTGTATTTAAAGGCTTTTTAAATGTACTTCCTCCGTCCCATTAAGATAGATTTTTAAAGAAAAAACTGTCCTACAAAGATAGACATTTTATGTTTTCAATACAAAATTTAGAGTTTTTTTCATATTTTTCTCATTCGTGAGACTGGTCTTCTCCATTAACTAAAAGTACATATTCCAACATTCTCCTTCCTCCATGCACCGAGATTATATAAGTACAACATTTTGTGTCATCATTTTTTTTATTTTCAAAACTAAAAGAAAAATGTCTTCTTCTTCAAATTCATTAAGTCTTTGGGAAACGTGAAAAAGGAAGAAAAAAACAAATGAAGAAGGAAGAAACACATCGTGAAGTTTATATCAATCATGAGCTGGACTTGAACCAACTTTCTATCGAAACCACTATATTAACCATGCTCAAGATAATGTTTCCAAAATATTTTTAAATTTGTGTAAGTTATTTTAAGAATATGGCGTAAGCCTTTTTTTTCTTTGTAAGTTGGCTTAAGATTTTTGTAGTCATGATTTTAATTTTCTAGTTCTAATACAATGATCATGATAATGCTATATTTATTCAGATCTTATTGTAAGATTAATATTTTTGGTTTGAAATCTAAACCTTTTATTTCGGAGCATAGAGGCAAAGCAAAGAATATTCTTATTGATATACATTAACAATCATTTCTTTTTTCATGAACTATTCATTTTTTTGTGGTGATATTGATCTTGTTTTATGTGTGTGTATTTTTAGATGTTTTGACTATTAAATATTGTAAGTCAAAAATAAATTCTCATAAAACAAAATAATAATAATAAATTCTAAAACAACAGATACAATCATTGAAATAAACTCGATTGACCAAATTCAATTAGGAAAAAAACAAACACACAAATCTAAACATAACATGTTCTAAAATAATAAACTTGCTAAAAATTCCATTACACCTCTCACCAAAAATAGATCACAAGAGATTTGTATAGGTAGACGACCTTCTCTTTCCAATGAACCCTTCTTCATATGTAGAATTTTGTACTTATTTGAGCCTTTGGCTTTCATGATCTCTAACATGCAAGATTGCAAAGTTAAAAAGATCTGATTCACCTGTTTGCGGGGTATTCGTCAAATGATGTCTCTGCCGCCGACACAAGTTCTTCTACCGTTGTTGGACATACATTGTGTTGTAGTGATTGGATAGCATTAAAAAATCCAAGATCCAATATATTCAAATCCGGTGAATTCAGTGGTTGACACATCAAGCGTATATCAAACCCAAACTGTGAAGCAATTGCTTGAAATTGTGCATCTCTCGTATCCACATGCGTTCTTGCATTATCTTGTTGAACGAAAATAGTTTTCCCAAAATCTTCTCTTGACCACTTTTCGCGAATTTTTGAGATCACTTTTTCAATCAAGCATCTCTTTATATCCTCTCTCTTGATGGAGACCATCGGTTTCAATTCCAACATTCCCGCTTCTCTATTTATGCTTCGTCGCTTAGACAATGAAGCACAAACCAAGCCCGCTAGCAACTTAAACCCAAGTAAAACTTCATTGGGTGTTGATTGTTAATTATTAGGAATTAATTGTTAAAATATTATAAGATGTGTTGTGTGATGTTATGCGTTAGGTTGTTAGCGTGATATACATGTTGATTTGCTTGACGTCTTTAAGACGTATTTTTAAATAAAAATATAAAGATAAATAAAAGAGAATAATGATATTAAAGAAAGGATAAGATTGAGGATGTTGGACTGTAATGGAACTGACGGGTTTATTACAGGTCATTAATCGCTGACGAGCAATGAGAGGAAGGATCGAGCTACGGGCCGTGGTCTTCCATAATTAGGCTTGAGGAGCCATAAGTTAACGTATGTTAAAAACTAAGAAAAGAAAGTAAAAGATCTTGCGGTGAGCAAGACGGAAGCTTGTCTGTTATAGCTTACTAGGAAAGTTTAAGCTATATGCTTGTTGTTTGAGTCTATGCTTATGAAATAGAAATTGTGTGAAAGTATAATCGTGTTATTGTGATTCGGTGGACAGTTTTGACTGCCTTCACTGAATAATTAATTACTCACCCCCTTTTCTTTTCCCTCAGGTGAGGAAGAGAATGTTGAGTAGCTGCTCGCTTGGTGTTATTTCGGGGACTTTGGGTTTTATTTGATTTATCGTTATTTCTTATATTTCTAAACATGGTTTCTTTATTCATTTTTATCCAACGATTTTAATTTATTTATGCTATTATTTTGAGACAATTTATTTCTGATTCTTAATAAAAGAAAGTTTCCCAAAATTTTGATATTTTATTTCAAGATTTGTTTTGAAGAAATTGAATAAATGAATGGAAAGGATGAAAGTACGCCGTCTCAAGGTTGAGAGAGACGGGTATTATAGAGGGACACCTCTGAAGACACTTTACACCAAATGAGTAGTCGTATTCATTATTTATAACTAATATATTTATATCAATATTATGAGATGTCATCAGTAGCGGAGGCAGAATAGTTAGTCATAGGAGTCATATTTTTTTCTAAGCCAAATACAAAAAAAAAAGTTGAGAAAAAATGACAATATCATAGTTTAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAGAAGATAAAATGAGAAAGAAAAAAATTGTTCTGGTAAAGTAAACACTAAAACTAAGGTAATTTATAATGTGTTAAACAATAATAATGAGATTAACCTAGTTTAATGGACTTATGTTTTTATTTATAAAATTAATTGGGTTAACATGCTGTAGGTTTTATTTTTTTATTAGACTATATTTGGATATATATATTTGATGGGGGTTAATAATACTTTAGGAAAAGGGTCAATCTATAAAAATTAACAAAAAATAAACATATTTTCTAAAATCCATGGAGTCAATTGACCTCCATGGTTAAACACTCCCTCCGCCACTGGATGTCATTGATAATTTATTTTCTACCATAAAAGTTTTGTAACAATTTATAGCCACGAAGACTTTCACGTTTTCGCTCAATTCTCAATATTTCAGTTTTATATTATTCTGATTTTGGGTCCAAATGAAATTTAAGATCACAATTTATGGTGTTACAATTGACTTCTAGGTGTAGTTTTCAAATAAATTTGGAAAGTGTTTCACTTAAATACCAAAGAAACGTACATGCATGATGTTTTGAATTCCTTCTTTTATCAAACATGTTCAGCTTGTCATTAAATTCATTGAAAAGTTCACGTATCCTTTTATGTATTTAAAGTTTAATTTATTTAAAAGTAAATAAGTAATGTTAAAATTGTCATTATATATTATCTCTTAAATAACGTAAAATTTCTAAAAATTCATATTTGTGGGACGGAAGAAGTTTTTTTTTATAATAATAATTGTTTTTATTTTCTTATTTCAAAATTTTTACTAAGAACATAAATAACTAAAAATAGTTATTAAAAATTATGTCAATTTTTGTTAAGTTAGTTTAATTATAGTTGATATTTTAACAATTTATCTACAGTTATTATTAATATGCAATCACAAAAATATAAATATATAAAAAAATATAAAATTGTAAAATAATTAAGATAGAGTGTTGAATTTTATTAAACAAAACTAGTGTAATGTTTTAAAAAGTAAGTGGGTGTTGAATGATAATGTGGAAGAAATAGAAAATGATGTGGAGTCTTAAAAAATGAAGCTTGAAAATATTCTAACGGAATGTAAGAGTAAGACCATCTTCTGTTAAAGTTTGGTTGTTTGTTGTTAGCTTCCAGCATCTTCCGGCACATCTACAAGTAAAAAATAGAATGTTTACGATTAAGTTAGGTTTCATCTCTTATTAAAAGAAATGACCTTTAGAGATAAAGTAAAAAAACGGTAATGTTATTAAGTACCAACAAATATCACCTGTTCATCGGCCAACACCAACTCAAGCTTCTCGCTGGTACTCATGGTATATTAGCACCACAATTATAGGATTTATACTTGCACTCAGCCACGCAGTTTTGTATGGGTGTAAGTCCAGATAAACGAAAGAAGCAACCATAAAAATGATAAATGTTTGTTTGTTGGTTATATGCAATAGTTGCTTTCAGATTTGGTGATGTTAGAAGATGCAAATGATGGGATTATTTATAGTGGTTTAGAAGTCGATAGGGGATGGACATGAGTTAGTAGAGAAAATCTTGGTGAGCAAGCAAAAAAAAGAAAAAAAAATCACCATTATAAAATAAAATAAATGATTTAGAGACATAAAAATCTTTTTAATCTCATAAATTTCTGAATTTCGTCCAGATGTATTTTACTAGACCTGCTTGTAATTCATGATGTAAATTTGAATCACGTAACTCGGATCTAGCACGCACATGACTTGCAAATTCTGGTAACACCTCAATTGAGAATGGTTGTGGTGTACTAGAACCACTTGCCTCAGATTGATTATAATCGGACCAATGTTGAGCATATGTCTCTCGTTCATCATTAACAATCATATTATGCAATATGCAATGTTGAGCATTAGGTGAACGATCTAAAACATTTAATTATATCATTCAATGTGCCTGGACACCTAAAAAAGGCATGCCAGATCTTTTGATCATGAGATGCAACTCCTTCAAAAATAACAATGGTGGTTCCCTTATCTCCCTGAGTAAATTGGTCTTCCCACGCTGTATGAAATTTTTTCTACTCCTAGTGCATGCAATCAATACTCCCAATCATCCTTGAAAACCCCCACAACTCGCTAACACGCAGAATTCTTTGCAGGTTGTCTTGAGGCGGAGCTCTAAGATAATCTTCTTCAATTTTGTTGTGACACACTCTAATCCAGTTGATGATATACCTCACTTCAATATGAGATTATCTTTTATAAGCTTCGATATTGAAAGGAAATTCTGATTGATCCATTGGATTTTTTATTTTAGTAAGATGATCTTTGTGATATTAATTCATTAATAGAAGAATGAGTTTTCATTTATAAAAAATAGAGTGGTTGAAAGAGAAGGATAAGAGAAGGATTTGATTAAAAGATCATGTGGTTGAAATCCAATACTCAACAATTTTACCCCAGTATGATTCACTTTTTTGGTTTTTGCCAACAATGATGTATGTTCCATAATACATCCACTTAATAACACTCAAATTTTGCTCAATTCTCCATTTGAGGCTTTTCCGGCGAGTAGAAGTTGATACATCATTATTTGGAGTATTTTCATTAGCACTGGTCATACTTCCAAGAGTCATTTGTGTTGAAAATCCATGAAATTCAGGAGGCAGTTAAGATGAATATGTCATCATCGATCCATAATATGGATGATATTTTGGAACAGATGATGACATAGAAAAATTTGGTGGTAAACTATAATTTGGGACATTTTGAGATTGGTTGAAAGATGGACTTTGAAATTGATAATTATTGGGATTTAAATAGGGAAAAGGATAATTGGTAGAATTTTGGATAGAATTATTGTTGGAATTTGGATAGGAAAATGGAAAATTTATAATATTTGTGAAGGATTATTTTAGAATCTATTTCACAAAATAAAATAAAAAATAGAAGCAAGAGTTTATTAGAGGATAATAAAGATATTATGATAGAAATGGTGTTTTTTGTATGTATCTGAATGAAATGAATCAAGTTTCCTTTTATAGAGCTTAAAAAGTAATAAATATCCATATAAATGTTTTAAATTTTTTTTTATTATCTATATATTCATTTACATGGGATTTTTGCGTTAATTCCCTTAAACCCGGCTTTAATTCATTTGGGTTGGGTTTCGATCCGGTTTTATCGTATTCAGATCTTGAATAGGATATTTGGGTCGAGATTTCTTTTGTTCGGATCGTGTTTAGGAATAACATGTGCATCTTTAATCGAGTTAAATTCTTCTTTTAATCCACGTAATTATTTCCTTAGATTCTGTCCACCATATTCGGCTTACTACGACTTATCCTTATATATTTGCAATCTTAACAATTATATTGCTACCTACTGAATCTACATATACATTTTTACAGGAATTTTAGCAATTAAATTCTCAAGTTAGAACTTATTTACAAGGAATACCATTGACATTAATTATTATCATTTAATTAATATTCCTAATTATTAGCATTTTCTTATTTAATATATTTCCATCAATTCTAATTACTTTTAAAAAGGAGAAATCTTAGGACTTTATTAATATTATACTTTATTAAAGATAAATACTATAGTTATTTAAAGTTTATAAAATGTTTAAAATATTTAACGAAAAAACTTTTAGAATATATATATTATATAAAATCTATAAAATTAAATAACCATTTCAAAATAAAACTTTTAAATTGATTTGAATTATAAATTTTTTGATAAAAATATTATTAAAACAAACAAAAAAATGTTTAATTTTACGGAACTGGATTAGATGGTGGAACGGGTTTAGAATATTATAATGTATGTATTTTATAACAATTAAATAACCATTTGAAAGAAAAAATTTGTATTAATTTGAATTATATGTTTTTTAAATTAAAATATTATTAAAACAAAAATAACAAAAACAAAATGTTTAATTTCATTGCACGGGGTTAGATGGTAGGACATGTTTGGGTCGACAGTAATACGAGACGGTATACCACGAGTGAAATCCATTAGATATGTTTAGTTTCACTCAACGGGATTAAATGGTAGGACGTGTTTGGGTCGATAGTAAAAAGAGTCGGTATATCACAGGTGAAATCCTAGATATAACAATCAAAATACAATTATATTATCTTAAGAACTAAACAAAACAAATAATATTAATAAAATAAAGATAATTAAAATTTAAATTATTTAGTTATAATCTAGATTTTAAATTAATGAACTGTACATTATTGTTCATATATTTTTAAACAGTAAAAATCAAACATATTAATTGTATATTGAATAATATACATATATAAGAGTTGTACATACATAAAATACAAAATATGAAATCATATATATTCTTAATCGACTAAATAAATTAAATTTTTATTCTTAAAAGAACAAAATCGTCATGCAATACATCGCGGGTTAAAATCTAGTCTTTCTATATTCTCGTTATACTCTGCAACTAAATATACTCCCTCCGTCCCACTAAGATGAACTTTTAAAAAATTTCACATTCTTTAAGAAATATTGTATAAAGATAATTTTAACCTCTTAATATACTTTAAAAATAATAATAAATATTTATCTAATTATTAGTAAGGGTAAAACGGGAAAACAGTTTTAAAATTTGCATTGGAAATATAAAACTTCTATCTTTGTGGGACAAATATTTTTCCTAGAAAATTTATCTTTATGGGACAGAGGGAGTATTTTCTATCATTCTAAAAAGTTTAAACTATCAGAAATCTTTGTGCCACTTATCATATTAGAAAGAAGTAGCCTGTCCATTTCCCACTGCCACCTTACAAAGCTTGTCTATCTCCCTTATGCATGCACGAGGTAGTCTACAAGCTGCAAGCCAAAAATTGCATATGCTCCACAAAACCCAACTGATCAGATTTAAACGTCCAGCAAAAGAAAGAAATCGGGACGTCCAAGATTCAATTTTCCTTGTAATCTTTTATAACAGGGGAAGACAGCCAGATGCTGTGAATCGCTTAGTGACCAGAGGGAGTCCGAGATACCTCACTGGTAACTGACCAACTTCGAAAGGGAACCTTTGGGTTATCTCATGGTGGACTGAATCTTAAATTCCCGTCAGATACATTGTCGACTTTTCCTTGCTTATTTTTAGTCGTGATAATTTTTGCAAAATCGTTTAACACATGAACTATTCCTCCTATTGATATGACCTTTCCATCGGATAGGATCTTAAGGTTATCAGCAAAGCTCAAGTGAGTTAAGCCAAGACTTCCACATTTCAGATGGTAACCAAATTGTCTAGCACCTGAAGCTTTATCCAACATTTTAGAGAGAACATCCATACTAATGACGAATAAGTATGGAGAGAGAGAGCATCCCTGTCTTTAACCTCTTGCACTGTTGAAAAAAACAACTAATTCCCCATTAACTTGAACCGAGAAGGAAGACGTAGCTATGCAGAGGGTAACCCAATGAATAAAGACTGAGGGAAAGTCCATGGCTGTGAGAACTTTGGTGAGGAAGTCCCACTGTACCGAGTCAAACGCTTTTGATATATCAATTATTAGAGCGCAACGGCTAGAAATTGAGTCATTATGGTAGTCCTTGACTAATTCTGTCGCCAACAACACATTCTCTATCAATAGACGGTCCTTTACAAACGCTGACTGATTTCCCGCTATGAATTGAGGAAGAACCAATTTAAGCCGGTTTGCAATTATCTTGGAGATAACTTTATATGTCACATTGCAGCATGAGATAGGCCTATAGTCTTTAATCTCTTTCACATTTTTCTCTTAGGAATAAGTGCTAATATCGTGGAGTTGATGCCTTTAGGTAAGAAGCCTTCAACAAAGAAAGACTGAATCGCCAATACAAACTCATCTCTGGTGATTTCCCAAGCTCCTTTATAGAATTCTGAGGTAAATCCATCTGGTCCCGGAGATTTATCATTAGGCATAGAGAACAAAGCCTTTTTAATCTCAGCTGCAGTGACTTCATTGGTAAGCATCTCTTTTTCTATTTCCATACAACAAAAGGGTAGTAACTCTTGAAGCTCAGCCACTGAAATACCTTCGAAATCATTAGGAACTAGCTGCAAAAATTCTCTAAAGAACCGTTCAGCCTCTGTTGTGATTTCCTCCTCTTGTGCCGTCACAGTCCCATGTTGGCATTGAATCTCTCTAATTGTGTTCCGTGCCTCCCGCGTTGTAACAGCTCTATGAAATGCTTTATTGTTTCGATCACCAATCTTCATCCAATGTAATTTTCATTTCTGCTTCAAATATATTTCTTCCAGAGCTGCGACCTTGTCCCAAGTGTCATACGCCTCATTTTCTTCTTGCATTGAGCTTGTGGTGGGGTTAGACAAATTGGCCTCCTGCTTCTGACACAATTTCTCATACGCATCTTTTGTTAAAAAACACATTTTGATTTTCTTATAAGAAGTTTAAACATTATAAATACTAAAACTTTATATTACGGGTGAAATCTTAGAATTAACGAGTATGAGTCAATATTAATATAGGATGATATACCACCTGTGAGATCCTAAAATTAATAATTAAAATACAATTATAAAATCTTAAAACACTAAATAAAGTAAACATTATTAACAAGACAAATACAACTAAAAATTTCAAATATTTAGTTATAAAATATAGTCTATCTTACATTAAAACCAAACAAAACAATAACATATATCTACAGAATTTGTTTTAACTAAAATATATGCATGCGGTGTATCACGGGTTCATATCTAGTATGCTACATAATAATTGATTGTAAATAAATAAGGTGAGATAAAAATCTCCAAAATCTCAATTGCCAATAACATTACAACAAGTGTGTCTCTCAATAATTTCTTTCTTTTTTGAACAAATAATAATAGAAAACGCTTTACTTGCGAGCTAGGTGTGTGAAACATCTTCCAATCATATGGTGATACGTGGCATGGGCGAACCCAAATAAATTTTTTTCTATATGTTGAATAGATTCAACACCTAAAAATCTAATGCAAATTTTTTTTCAACAGGTCCAATGCAAGCAGTTTTAGTCACATGCAGTTAAAGTATTAAATCCTTCTACTTATAAATATTTTATTCCTACTTAATAGCATGTATGTATTTTGGCAAAAAAATGCTAAATCGGAGATGAAGTTAAAATATATATTGTGCGCTCTAATATCAAATTAAGAATTATATTTCGTCCAAGCTACTTAGTACGTACATGTTGTATTCACTAGTTGTCCTTCCTTTCTTCTTTTCCATGGTCACAATTTGGTTCATTGTTTCTTCTAAGGGATTGAGCAATCACGGTTTTTCGGGAGAGTGTTTTTTGGGCAATATCTCTTTATATATTTAAGAATGCTAAAATGTAGTATTTTTGTTGGTTCTTGTTTCATTGCCAACATTGTACGAGGCGTGATGAAGGCAGTGAAGAGAATAAGGGTAGTTTCGTAGACATAGTAGTTGAAGAGCTAAAGCTAAGAGAAGACGAATAACACACATACATGTTGCTAAGAAAGGAGCGTCTTCGCAAGGGAGAAATCCGAGGTGATTCGAGCTAGGCAAAGAGGATGGAAAGATGTAATTGTGTTTTCAAATCATATATATGAAAGGAGGTGACCTATCTCCATATGAATGACATGTTACACCATAGAGATGATATTTTCTGTATTCTCTCATCTTATTCGGAAACCTAAAAAGGTATGGTGAAAAATATAAGAATAGAAGAATGAGAAAATGGAGGCTTCTTAAACTAATTTTAAATTGTATTTGCTTAATTTAGGACTTGAAAATATATTCTGTATATTTTGAAGATTAGTGAAATTAATGGGTAATTTTCTCAGACATGGAAATCTTGTTTTATTGTTTTTCCTTTATGACTTTGCAAATATAGTAGGTTTCAGGAATTTTTATGAACTATTTTATCTTCAACTAGAATTAATACTCCAAGTACTTATATATATATATATATATATATATATATATATATATATATATATATATATCATATTTAAATTCATATTAATTTGAAAGTGTTAAAAATGCCCTTGAAGATGACAAACAACTGAAACAAGACATTTGAGCAAACAACTTGAGATGCTAACAAATGGTTTTAGTAGACATCTAAACAAATCCAAATTCTAATAAGATTTATTTTGTTAGTCATGTACATATACCCTATAACCCTAATATGGAAACCAAATAAATAGGTCACTATGGATTATGTATTTTGACCAAAAAAAAAAAAAGAAGAAGATGAATAATGTATTTTTCTGTCTCTACATACAACGAAACATAGTTAAATGTTTAAAGTTCAAAATCTACTAGAATTTGGCTACTCAGAATTATAAAAGAGATTCAAGACATTTATGTAGTACCTCTGTTGAAACATTTTTTGAGAATTTATAGTGAAAAGTGTAGTCATTTTGTGATCTTTTCCAGCTTCCTATATTTCATGCGTTTTAGCTATATACTATCCTACTATATTATTTGGGAAGTACATTTTAAAATTTAACCTTAATTTTTATAACTAATTACATGACAATGCCATTAAAAAAATCTAATCAAAGACAAAATTGTTTCAAATCATTAAGGTTAGTAAAATCATTTAACGATAATATCCATCTACTAATCACACAAGTTAATGGATATATAAACGGGTTAAATATTTTTCTGCCATTTATTAAAAATTTTCGTCAATTCATATTTGTAAGATTTTTTAAACAATAAGATCTTTTTGTTACCAGGTGGAGAATAAGTTGGAACACACTTATATAGTTTCCTTTGAAAATCAACAAAATCTTAGCCACTATATCGATTCCTATCACCATATCTCGCTGTTATAATATTTCTCATCACTATATTCCGGTTAACAAGTAATATTCCTTGAGCTACAATTTTTTTAAATAATCTTCTTTCTATCAAATAATCTATCTTAAACAATTAACTACTAACTGATTTAATTAGATCTTCAATCTATTGAATTCACCCATCAGTATTATAAATAAGCAGATAACCATCATGATGTCTGTACCTTCTCACATACACACCTATCAAAAACTTAAAACCTTTCAAAACCTCTTGGTATATTCATATTAGGATTCTTCATTCATGGAATCATTATTCCAAGGGTTTTGGGATGTCTTATGAAATAATTTTGGCAGAAGAGTATGTAAAATTTTTTGAATAAAAAGTAGTCAGCAAAACTTTTCTTTTTTTGGACTTTTTAGATAATTAATTTAGAGAATAGGGTTGGGCATATGATTAACCCATTCGAGTTCGGGTAGAACCCGTTCGAGTTTGGGATTAATGGGTATTGGATTTACTACTTAATACGGTAATTCTAAATATTCGGTTCGGTCGGGTCCAGTCGGTTTTCAGTCAGTTTGGATAAAAAGTTTCAGGCCATAAAAATACCCAAAAAAATAGAAACGGGTATTTTGTATGTAGATAGCGGATCCCCAAACAAAAAAAACTTTTAAATTTGTTAAGTTTTAAGAAATTTAGTTATATTTGAATATATTTTACTAAATTTTGACAAACATAACAAATGATTTTTGAATAGTTTAGTTGTTTTGGATATTTAGGTCCAACATTAATTGACATATTTAAATTTTTTTTTTTTTTTGTCAACCGATATAAATTAAAACTCAAAAGAGCCAATCCCGAGGGATATTGTTTACATACGTGACATGATGCGGTACGGTACGAATCTTTCGTGCCAACTTATCCGCTTTTACATTTGCACTACGAGAAATTAAAGATAAAGAGAAATTTGTGAATTCTTCCCTATCACTCTGCAACTCCTCCAAATACACTGAAAACGCCGGCCATTCGGTTGGAGAAGACACCATCTTCACCAAGTCTGAACAGTCTGTAAAGAAAGCTACGTTCTGGTTATCTGCTCCAATCATGCACTTCATCGCCCAAAGAAGAGCTTCCATTTCGGTATGTAGAGGAGATAGACTTCTACGAACGTTGGCGGCTCCCATGGTTGGCGACTCTCCAAGAGATGATAGACAGAACGTTGGAGACATATTTAGATTTATAATTATAATCTTAGATAATTAGATTATATTAAGATTAAATATATTAATATTTTGGATATTAAATAAATGTTTGGGTTTTCGAATACCTTTTTGGGTAACGGGTAATCTCCGGACCAATCGGATACCCACGGGTTTACTAAAACTCTATCCAATAAGGAAAATTTATTAAAATTCTAACCTGCCCTAACCCGATTTTTTGGTTCGGGTATTGGGTTGGTTATCTGGTCTGTTTTTTTGTCAGCCCTATTAAAGATAATCTAATATAGGGCCCAATTAGGCCACAAATATAACCAAAATACTATACAAATACTAATTCTAAGTTAGGCCAAAAATTAGATCCTCTATTACAAACGAAACATGTTTCTTACCAAAACAACTTGTATACAAATTTTACACATTTACTTAAAACTACATATGTTGTATTTATTATAAAAATGACATTTTTAAACAAAGTTAATCCAATGCAGCATTATATCCAAATAGCAAAAAACATTGAAAAATATTATGGCATCACTTTTACACTATACTATTTTTTATGTAATTCAAACAAAGTATACAATTTAGTTTATACAAAATATTAATGCCTGTGCTATATAGCACGGGTTATGATCTAGTCTACTTAACATTTTTGAAGTACAAAATAAAGAATTTTTCGGGTCGGTTTTTTTTTTTTGTTTTACCCGGTTTTTTTGACCCACATCCTATTATTTTAAATGCTAATCAAATCTTACCAAAATTAATCGCTTTAAATACGATTTAGTTACAATTAATTATTTCCGTTCAGCAAAGTAAATCCGACTTATATGGAATGAATATATTAACATTGCAAAACAAATCCGACTTAGGTAACTTAGTATTTATCCGTTCAGCAAAGTAATTACTCGAGTAAATATTCTATTAACTACGAAATCTTCAAGTTAAACGAAATCAAAATCTGCATTCCACTACATAATTTTCGGAGATCTTAAGAACTAAATTAAAGCATATTCCTAAGCATAATTTAAAAAATCTCGCTACACAATTTCCTAATATCGCAATAGTCAAATCATGGGCGAAGATTGTGATTATCATATGTTCTCTATATAAATAAGGAATTTGAATTGAATTTCTATGCTAAGCCATTTGCCATAAAAATCTCAACAAAATATTGAATTCATTATCTCTACAATCTCGACAATAGAAACTATATGATTGTATTAAAAAACGGATTTGGTGCATATTCCTTGAATATTCGATTAAGAAGATTTGATTTAATTTAGTTAAGGTGCAAATAATTTGTTATGGCCCCAAACCTAATCAGAACTCGCCTATATATATTCTCTAGCTTTACCTCTCATCACATTATCAAACACACAAAGCTCATCACATATCTTTGGATTTTGAGACAGAAAATAAAAAATATGATTCAGGTTGAGAGAGTTACTGAATTCATCACGGAACCACAGAAGCGATGCAGTGGTTCATCGGAGAAGCCTGAAACGGCTTCAAAAGTTTCTAGAGAATATCAGAAGATCCCAATCTCTAATCTTCATAGTGAAGATTAAATAGAGAGAGAGAGAAAGAGAGATTAGATGTACATCACGTAAGATTGGCGACAAAGGAATCGCTAAGGGGTCGAGTGGTTTAATCGGAAATCGTATTCGATAATATCAATGAAGCAAAATGAAAGTAGCACACATAGGTTTGTATGGTGAGACTTGAGAGCATCTTCGACCATCAGAGAGGGACAACTTCATGAGAATCGATGGAAAAAAAAATTAGCTTCGAGGAAGAAGCAATGGTTTGACGAAAAACTAGATGGTCACAAATGATTGGTAGGCATCATGTTCAAAAGCTTAGCTTGCTCGAGAAGTCACCGACGAACGTGGAGTTGGCCGGAGTTTCTGTCATCAAAACCGCGTTCAGTTTTGCATTGCAGAAATCAAAGAAGATGCTTCGTTATTATCGATGGGGAAGAAGCATAAAAAAAAGTCTTCCTCTGATGTTAAAACTAGGCCAAGTATTTGTCATGCCCATAGAACTTGCAACAGAAAGCAACGTTAGTCTTTGGATAGAAAACAATTACGGTATTTTTTTATGTGGTTTATACATTACACTAATTATGTTAAATATTTTTCAATAGTATTAACGAGAAGCACAATCTATATATATATATTTTTGGAGAAACTTTGGGTCAAATCCTTTTATAATTTCTTATTTATACATTTAGTCCTTATAAAATAATCTGATAAAAATATTGTCTTAAGCAATTTTGACAAATAAAATTTAAGTAAATAACATTAATTAGTTATAGATGATTTACGGCAATATTTCCTAAGAAATAAAAAATTTGCGACATTAATGCTATTAGAAAAGAACTAAATAAAAATCTTCAATGGTATATTTCATTATTAATTCGCTTTATTCCTAAAAATATTTAAACAAAATTTAGTCATTGATTTGCAAATACAGAAATTGTATATGTAGTTATAACAAACAAATATTTTCAAATCAAATGATTTTCTATTTAAATGCTAGAAAAAACATAATAAGTTTTTAATGTCATATCTAAGAAAATCAATAAATTGATATATTATTTTAACAAATCAATATCTAATGCTAACAATAAATTAATTTGATACACGTTTTTAATTTAATGCTAATAAAAAAATAATTTGTTCTAACGCTTCCTATTTAAATGCTAGAAAAACGTAATAATTTTTTTAATGTCATATCTAAAATAAACAATAAATTGATATATTGTTATAACAAATAAATATTCAATGCTAACAATAAATTAATTTGATACACGTTTTTAATTTAATGCTAATGAAAATTAATTTGTTCTAACGTTTTTAATTATGGCATTAAAGATTTATTGTCAAAAATAAAATTAAAGTACTTGATAGTTTGTATATATATTAAATTACTTAAAAGTTAAAATTAATGTATATATAAATATAATAACAATTAAAGTACATAAACAAACAATCTTTAGTTGTTATATACTATTAGTAAAAAGAAAAATGACAAAATGATTTTTATTTTAACAGACGGGGTTATATGGTAATACGGATTTTAGTCGATATTAATAAGAGACGATATAGCACGGGTGAAATCCTAAAATTGATAGTCAAAATATAATAATAAAATCTTAAAAAAGAAAACAGACAATTATTTAATTATATAATTATACCGGACAAGGTTATATAGTATGACAGCTTTTGGTCGATATTAATACGAGATGGTATACAACGGGTGAAACCGAAGAATTAACAATCAAAGTACACTTATACAATCTTAAGAATCAATTGCCGGACAATAAACAATATTAGTAAAACAAATACAAATAAAATTTAGTTATAAATTAACCCGCGGACTGGAGCACACCGCGGGTCATATCCTAAACAATAATTTCTTTAGGATAACTACAATTCCATATAAAAAACTAAATTTAAAACAATTTTTTTATAATAATGTTATTTTAAACAAAACAAAAAACAATATAACAAAAATGTAATAATGCACCATAAAATACACACTCTATATAATGATGCGTATAATAAATATGTTTTCTTAAATAAATAAAATTAAATCAAACACATACTAATATAACATCAAAAATGAATAGATATAAAAGGTAAGGTGATAAATTAAAAATATAACTTGATTATTTAGATAAAAACGATATCGAATTAAAAAAATAATTTAATTTCTAACACAAATAATCAACTCGCGGTACACCGCGGGTCAATATATAGTTAAATTAAGGTTAGAAACTTAGAATTAAGAGATTTATAATTATAACCGGTGCCGTGGTCATGGACTCATGCGTATATATCGGTATTTTAAAGACAAAAATAACGAAAACGGCACGCAGTTTATCCCTCAACACCCGAGACAACACTTCTCGTAGTCCGTGCTTAAATTCGCCACGTAGTTCACTTTATTCAACTTAAAAAAGCATGACGTTTTGGTGCATCTATCTTCTTCTTCCCCCTTCCTCTCTTAGCTTCTCTCCCACCACTAAGGAGAAACGTTCCAAAGATCCCTCTCTCAGAAAAATCTCCAAGAAAACGAAACCCTAATGGAGAATCATTCTGATCCCTGAAACTTTTGGCTTGCGGCTGAATCGATTTCAAGATTGCAAGTATTGCCTAGTGTGAATATGCTGTTGCTGTGTGATGCTTTGGTTAAGGAAGTGACTGTTGAATGCTGAAAGGACGACTTGGAACCTTATCTCGGGTTGCATTACTCGGCAAACTTCGATATTTCTTTATATGAGAAACAAGGTTACGATGATTTCAAGAACTGTGCTAATCTTTGCCCAAGATTTACATGTAAATGGTACTGATTGAGTGTTAAAAGGAAGAAGCTTCATACATACAATATACATTGATCGGATATAGTTTTAGAGTAGGTTCCGAGTTCCAAAACAAAGTGAACTATACTGAGTATTTCAACATAGAAAAGTTATAAAATTGACATCCTTTGCAAAGTAAAAGCCATATCATAACAAAAAAATCGGAACATTTAACCGAAAACAGAGACAACCCACAAAAGAAGAAGAAGAATGCTAAAATTGAGAAGCACTGATGGAGTTGGTCGAAGGGGACCAAACGGAAGGGAATATATCTTCTATAGACTGCTTACGAGTTATGAATTGAGTTGCGTCAACGTGTGATTCTGATCCGGCTGAAGGAAAGGCCGCTTCATGTGAATACGCACATGGTTCCTTGTACGCCTCTCTTTCCGAAACGTTGGCTGCAACTTCGTATGATTGTATTTGTAGCGGGCCTAGCGGCATTAGTTTCAGATGGCTGATGATTTTCTTGAAATTTTTTGGTGGAAGCGAATTAGAGATAACATACTTCGGAGGATATGCATTTTAATAACATATTTATAAGTTTTGAGTATCGCATATTACGAAAACGAAAGCATTTGAAAGATTCGAGATTTCACTATCGAAAGTGGGGGAAGACACGC
->URS00006236D2 tRNA from 1 species 
-CTCCCCATAGCTCAACAGGATAGAGCAGCCGCCTCCTAAGCGGCCGATAGAGGTTCGAGTCCTCTTGGGGAGG
->URS0000187CC4 rRNA from 1 species 
-ATTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGCGAAAGCCCTTCGGGATGAGTAGAGTGGCGGACGGGTGAGTAACGCGTAGGAATCTATCCTGTAGTGGGGGGATAACGTTTCGAAAGGAACGCTAATACTGCATACGCCCCAAGGGGGAAAGCGGGGGATCTTCGGACCTCGTGCTATAGGAGGAGCCTGCGTCGGATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACCGGAACTGAGACACGGTCCGGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCCATACCGCGTGTGTGAAGAAGGCC
->URS00023B9165 lncRNA from 1 species 
-GATAGAACACACTTCAAGCATTAGATTTAAGAAAATTTATATCTTCTCTCATCTTTTGATTTTCGGTCTTGAATTCGAGTTTGAGAAAGTTGGAAGTTAGAATCTTGACGTCGAAGTTCTAGTTTGCTGCTCTACACAAGGTCAGTAATCTCGTTCATTTGGTTCGTTTTCAAGGATTGGTTATTATAGTATGGAACATTTTTGTGTTGTTATTCTCTGATTTAAATATGCACTGAAATATGTCTTGCTGTATTTTAGTTAGAAATCAGCTTGCAACAGGTTAAATGAGTTTCTTAGATTAAGAGAATTGACT
->URS0000F2E397 rRNA from 1 species 
-CCTACGGGTGGCAGCAGTGAGGAATATTGGTCAATGGGTGGGAGCCTGAACCAGCCAAGTCGCGTGAGGGAAGACGGTCCTACGGATTGTAAACCTCTTTTGCCGGGGAGCAACGGGGTCCTTGCGAGGTCCCAATGAGAGTACCCGGAGAAAAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATGCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGAGCGTAGGCCGGTCTTTAAGCGTGCCGTGAAATTTTGTGGCTCAACCATGAGAGTGCGGCGCGAACTGGAGACCTTGAGTGCGCGGAAGGCAGGCGGAATTCGTGGTGTAGCGGTGAAATGCTTAGATATCACGAAGAACCCCGATTGCGAAGGCAGCCTGCCGCAGCGTTACTGACGCTGAAGCTCGAAAGCGCGGGTATCGAACAGGATTAGATACCCTTGTAGTC
->URS0000620B57 rRNA from 1 species 
-AGAGATCATGGCTCAGAGTGAACGCTGGCGGCAGGCCTAACACGTGCAAGTCGAGCGGCAGCGGGTCCTTCGGGATGCCGGCGAGCGGCGGACGGGTGAGGAATGCGTCGGAATCTGCCTCTTTGTGGGGGATAACGTAGGGAAACTTACGCTAATACCGCATACGACCTACGGGTGAAAGCGGGGGACCTTCGGGCCTCGCGCAGGGAGATGAGCCGACGCCGGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGAGTGAAGAAGGCCTTCGGGTTGTAAAGCTCTTTTGTTGGGGAAGAAAAGCACTGGTTTAATACGCTGGTGTTCTGACGGTACCCAAAGAATAAGCACCGGCTAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGGTGCAAGCGTTACTCGGAATTACTGGGCGTAAAGCGTGCGTAGGTGGTTCGTTAAGTCTGATGTGAAAGCCCCGGGCTCAACCTGGGAACTGCATTGGATACTGGCGATCTGGAGTGCGGTAGAGGGTGGCGGAATTCCCGGTGTAGCAGTGAAATGCGTAGATATCGGGAGGAACATCCGTGGCGAAGGCGGCCACCTGGACCAGCACTGACACTGAGGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGCGAACTGGATGTTGGGTGCAACTTGGCACTCAGTATCGACCTAACGCGTTAAGTTCGCCGCCTGGGAAGTACGGTCGCAAGACTGA
->URS0000D14622 rRNA from 1 species 
-AACAGCTCAAATTTGAAATCTGGCCTCTTCGGGGTCCGAGTTGTAATTTGTAGAGGGTGTTTCGGGCGCGATGCCGGTCTAAGTTCCTTGGAACAGGACGTCGCAGAGGGTGAGAATCCCGTACGCGACCGGTGATCAAGTCTGTGTGAAGCCCCTTCGACGAGTCGAGTTGTTTGGGAATGCAGCTCAAAATGGGTGGTAAATTTCATCTAAAGCTAAATATTGGCCAGAGACCGATAGCGGACAAGTAGAGTGATCGAAAGATGAAAAGCACTTTGGAAAGAGAGTCAAACAGTACGTGAAATTGTTGAAAGGGAAGCGCTTGCAATCAGACCGGTCCGGAGGCGATCAGCCGCTGCTCGTTCAGCGGTGCACTCGCCTCCGATCCGGCCAGCATCGGTTTGGGCGGCGGGATAAAAGTCCCGGGAATGTAGCTTCTCTCGGGGAGTCTTATAGCCCGGGTCGCAATGCCGCCCGCCTGGACCGAGGACCGCGC
->URS0001D2993E rRNA from 1 species 
-GCTAAGGCCCCCAATTCATGGCTAAGTGGGAAAGCAGGTGGGACGACCAAAACAACCAGGAGGTTGGCTTAGAAGCAGCCATCCTTTAAAGAAAGCGTAACAGCTCACTCATCAAGCGATCCTGCGCCGAAAATGTAACGGGGCTAAAGCCATTTACCGAAATTGTGGGCTCGAAAGAGCGGTAGCGGAGCGTTCCGTAAGCGGATGAAGCCGAAGGGTAACCGACGGTGGACGTATCGGAAGTGCGAATGCTGACATGAGTAGCGACAAA
->URS000241757C lncRNA from 1 species 
-CTACTAAAAGCATACTGCATAAACAGCTTGAGAGCATCATTGTTGTTTAAAAACTCGGGCTCATATATCTCATCACCAAGTCTGCTTAGTGACTGTTTATCTCTAGTTGTTATAATGATTCGACTTCCGCCACCAAATGAAGGTTGCTTTCCAATTAAGGCTTCAATTTGGGATGAACTCTCCACATTATCCACAACAACAACAACAACAACAAAGCCTTTTCCCACTAAGTGGGGTCGGCTATATGAATCCTAGAACGCCATTGCGCTCGGTTTTGTGTCATGTCATCCGTTAGATCCAAGTACTCTAAGTCTTTTCTTAGAGTCTCTTCCAAAGTTTTCCTAGGTCTTCCTCTACCCCTTCGGCCCTGAACCTCTGTCCCGTAGTCACATCTTCAAACCGGAGCGTCAGTCAGCCTTCTTTGCACATGTCCAAATCACCGGAGCCGATTTTCTCTCATCTTTCCTACAATTTCGGCTACTCCTACTTTACCTCGGATATCCTCATTCCCAATCTTATCCTTTCTCGTGTGCCCACACATCCCACGAAGCATCCTCATCTCCGCTACACCCATTTTGTGTGTACGTGTTGATGCTTCACCGCCCAACATTCTGTGCCATACAACATCGCTGGCCTTATTGCCATCCTATAAAATTTTCCCTTGAGCTTCAGTGGCCTACGACGGTCACACAACACGCCGGATGCGCTCTTACACTTCATCCATCCAGCTCGTATTCTATGGTTGAGATTTCCATCTAATTCTCCGTTCTCTTGCAAGATAGATCCTAGGTAGCGAAAACGGTCGCTTTTTGTGATCTTCGCTAGATTGCTCCGGTCATTAGTGTGGATAAGTATATATAAATGGATAGAGATAGGAAAGCAAACACAAGATGTACGTGGTTCACCCAGATTGGCTACGTCCACGGAATAGAAGAGTTCTCATTAATTGTGAAGGGTTTACACAAGTACATAGGTTCAAGCTCTCCTTTAGTGAGTACAAGTGAATGATTTAGTACAAATGACATTAGGAAATATTGTGGGGGAGAATGATCTCGTAATCACGAAACTTCTAAGTATCGGAGTGTGGTGTCGTCTTGACTTGCCTTATCTGTCTCATAGGTAGATGTGGCATCTTCTCTGGAAGTACTTTTTCCTCCATCCAGGGGTGGTATCTTTAACTGGTGGAGATGCACAAGGTAATGTATCAATTTCACTTGAAGCTTACTTGTAGTTTCAGGCTTGGTCAAGCGCGATACAAACCATGTAGTAGGAGTCCCCCAAGTCGCCGAGCTAGGGGGTCTGCTGAAAGAGGTGACAGACAAGGTAAGCAATCAGAGCTCCGACTGATTGTTCACCTTCTCCCCATCTTGCAGCAGCATGAAGGATAAAGAGAAGAAAAATGAGAAGAGATGATATGAGATACTTTTGCTTTTGAAGAAGTAACTTTTCCACAGGCTTATTCTTGAACTGAGCTGGAGGGTTTTCTGGTTTCCTCCAGAGTATAAGGCCGACTGAAGAATTTGAGGGTCAAAACAAGTCCATCAAATCTAGAGTACGTTCCACCCTGCTGATATGGGATACTTTTGCTTTTGACAGAGTAATGGATGTATCGGCACGTGTGCTGTTACGCTTGTCTCCACATGCTTCCTTGTATCCTTCGCACTTGCCCTATCTGTTCCTCAAGCAGATGCGGAATCTTCCCTGGAAACATAAGATGTTGAAGATGAGTACTCGAGAGCAATGCCAGGTAAGTAATCAGGTAAGGGGTTCCAGGCAGTCAGTTCCTGGCTGGAAGCTTGATTCCAAGTGCTGACTGATTGCTCTCTTTCTCCTTGTCTTGCAGGTAAAAACAAGGCCAAAGGAAAAGACAGGGAAAAAGCATGATATGGGATACTCTTGCTTTTAACCCTGATGATATGAGATATTCTTGCTCTAGTATAGCTTGTTTGCAGAGGTATTATCGGGGGGAAAGAAAGCTGAATATTTCGAAAGGCTTCGTTGGGAGTGCCCTCTCAGATATGATGAAGGGTTGAGCATTTTTGCAGGTCTGCCTGTCCGTTGGGGATGGAGGTCGACATATATAGGAGTCTCCCTAACAACAAGTAGTAATGCTATTCCTTTACCCTGCTTGGTCATAGCACGGTAGTGGGAGCTGCCAGTTTCACATGTTTTAACTCTGTCAGAGCACTTTGAAAAAGTGGTCTGTGGTATCTGGCTCTCGAGATTCGGAGAACGATGCCTCTTCGATTTTTGAGAAAGCAATCATGCTGGGGGTCTGGCTCTCGAGATTCGGAGAGCAGTGTCTCTTCGATTTTTGAGGAAGTAATCATGTTGGGAGTCTGGCTCTCGAGATTCGGAGGGCGGTGCCTCTTCGATTTTGGAGCAAGCAATCTTGTTGGGAGTGTTGTCTCGAATGTGAGTAAAGGTTGGGCATGTTTGCTAGTCTACCTTGCCACGAAGCACAAAGGTTGACACACAGGGACTTTCCAATTATCCAGCAATGGTACTGTTCCTTTACCCTCTCTTCGATTTTGAGAAAGTAGTCATGTTGGGAGTCTGGCTCTCGAGATTCGGAGGACGGTGCCTCTTCGATTTTGGAGCAAGCAATCTTGTTGGGAGTGTTTTCTCGAATGTGAGTAAAGGTTGGGCATGTTTGCTAGTCTACCTTGCCACGAAGCACAGAGGTTGACACACAGGGACTTTCCAATTATCCAGCAGTGGTACTGTTCCTTTACCCTTGTGGGTAATAATATGGTAGCTAGACCTTCAAAATTTATGTGTCTAAACTTTGTTAGTGCTGTTTCTTTGCTATTCTTTTACCTTTCTTGGTCAGAGCGATGTAGTGGGAGCTGCAAGCTTCACGTGCTCAACTTTGGCAGAGAACTTTGGCAAAGTTATCTGTGGTACCCATGAGCTATTGTTGCGTGTGGGAAGTGGGTGATTGAACAGTAAGATTCATGTGCTTTCTACTTCACCAGAAGTCTTCGACAGAATGCCCATAATTTCTGCAAAGCTGAGTGTGCGTGTGACAGGTGCTGACAAGGCTAGAAAAGTAGGTGCCTCTTCGATTTCTGAGATCGGCCCTCGTGGTCTCTGAGCAGCCCAGCTTTTGAGAAAGCGAGCGCCTCTTCGATTGATTCGGAGAACGATGCCTCATCGATTTTTGAGAAAGCAATCATGCTGGGGGTCTGGCTCTCGAAGATTCGGGGAGCAGTGTCTCTTCGATTTTTGAGAAAGTAATCATGTTGGGAGTCTGGCTCTCGAGATTCGGAGGGCGGTGCCTCTTCGATTTTGGAGCAAGCAATCTTGTTGGGAGTGTTTTTCTCGAATGTGAGTAAAGGTTGGGCATGTTTGCTAGTCTACCTTGCCACGAAGCACAGAGGTTGACACACAGGGACTTTCCAATTATCCAGCAATGGTACTGTTCCTTTACCCTCTCTCTTCGATTTTTAAGAAAGTAGTCATGTTGGGAGTCTGGCTCTCGAGATTCGGAGGACGGTGCCTCTTCGATTTTGGAGCAAGCAATCTTATTGGGAGTGTTTTCTCGAATGTGAGTAAAGGTTGGGCATGTTTGCTAGTCTACCTTGCCACGAAGCACAGAGGTTGACACACAGGGACTTTCCAATTATCCAGCAGTGGTACTGTTCCTTTACCCTTGTGGGTAATAATATGGTAGCTAGACCTTCAAAATTTATGGGTCTAAACTTTGTTAGTGCTGTTTCTTTGCTATTCTTTTACCCTTCTTGGTCAGAGCGATGTAGTGGGAGCTGCAAGCTTCACGTGCTCAACTTTGGCAGAGAACTTTGGCAAAGTTATCTGTGGTACCCATGAGCTATTGTTGCGTGTGGGAAGTGGGTGATTGAACAGTAAGATTCATGTGTTTTCTACTTCCCCAGAAGTCTTCGACAGAATGCCCATAATTTCCGCAAAGCTGAGTGTGCGTGTGACAGGTGCTGACAAGGCTGGAAAAGTAGGTGCCTCTTCGATTTCTGAGATCGGCCCTCGTGGTCTCTGGGGAGCCCAGCTTTTGAGAAAGCGAGCGCCTCTTCGATTTCTGAGATCGGCCTTCGTGGTCTTTGAGCAGCCCAACTTTTGAGAAAGCAAACGCCTCTTCGATTTCTGAGATCAACCCTCGTGATCTCTAAGCAGCCCAGCTTTTGAGAAAGCAAACGCCTCTTCGATTTCTGAGCAGGCGCCTCTTCGATTTCTGAAGCTCCGTCGAGTGCAGATTTTTATATAGGGGCTGGCATTAAGTTCCAAAGCACACTTGAATCTCCACCAGTAGAAGCTTCATTCTTGCACTTCTAAGATCTTGATTTGTCCGACCTCTTCTCTCTTCAACACCTTTGAAAATGTCTGGCCCCTCCGACCGTCGTTTTGACTTGAACCTTGTTGAAGAGGCAGCCCCGCCTTCTCCAGACAACATATGGCGCCCATCCTTCGTCTCCCCTACTGGTCCTCTTACCGTTGGGGATTCCGTGATGAAGAATGATATGACCGCTGCGGTGGTGGCCAGGAACCTTCTCACTCCCAAAGATAACAGACTACTTTCCAAACGGTCTGATGAGTTAGCTGTTAAGGATTCGCTGGCTCTCAGTGTTCAGTGTGCAGGTTCTGTGTCTAATATGGCCCAACGCCTATTTGCTCGAACCCGCCAAGTTGAATCATTGGCGGCTGAAGTGATGAGTCTCAAACAGGAGATTAGAGGGCTCAAGCATGAGAATAAACAGTTGCACCGGCTCGCACATGACTATGCTACAAACATGAAGAGGAAGCTTGACCAGATGAAGGAAACTGATGGTCAGGTTTTACTTGATCATCAGAGATTTGTGGGTTTGTTCCAAAGGCATTTATTGCCTTCGTCTTCTGGGGCTGTACCGCGTAATGAAGCTCCAAATGATCAACCTCTGATGCCTCCTCCTTCTAGGGTTCTGTCCAGTACTGAGGCTCCAAATGATCCCCCTCCGGTGCCTTCTCTTTCTGGGGCTCTACCGACTGCTGAGACTTCTCCTAAGCAACCTTTGTGAAGGCTCCCTCTTGTGTGTTTATTTTGACTCATGTATATGTACATATTTGTAGCTTATCGGGGATATCAATAAATAAGCTTTCCTTCATTTCAACGTATTGTGTTAAATACACCAAAGCCTTCTTCGCTAAGTTCTTTGAATTTTCTTTTGTTGAAGCTTGTATGTTGAAGCTTTCTGAGTGGAGCATGTAGGTTGGGGTAGTGTTCCCTTAATTTCCCGAGTGAGGAAAACTTCTCGGTTGGAGACTTGGAAAATCCAAGTCACTGAGTGGGATCGGCTATATGAATCTTAGAACGCCATTGTGCTCGATCCTGTGTCATGTCCTTCGTTAGATCCAAGTACTCTAAGTCTTTTCTTAGAGTCTCTTCCAAAGTTTTCCTAGGTCTTCCTCTACCCCTTCGGCCCTGAACCTCTGTCCCATAGTCGCATCTTCTAATCGGAGCGTCAGTAGGCCTTCTTTGCACATGTCCAAACCACCGTAACCGATTTTCTCTCATCTTTCCTTCAATTTCGGCTACTCCTACTTTACCCCGGATATCCTCATTCCTAATCTTATCCTTTCTCGTGTGCCCACACATCCAACGAAGCATCCTCATCTCCGCTACACCCATTTTGTGTACGTGTTGATGTTTCACCGCCCAACATTCTGTGCCATACAGCATCGCCGGCCTTATTGCCGTCCTATAAAATTTTCCCTTGAGCTTCAGTGGCATACGGCGGTCACACAACACGCCGGATGCACTCTTCCACTTCATCCATCCAGCTTGTATTCTATGGTTGAGATCTCCATCTAATTCTCCGTTCTTTTGCAAGATAGATCCTAGGTAACGAAAACGGTCGCTCTTTGGCATTTCTTGATCTCCGATCCTCACCCCTAACTCGTTTTGGCCTCCATTTGCACTGAACTTGCACTCCATATATTCTGTCTTTGATCGGCTTAGGCGAAGACCTTTAGATTCCAACACTTCTCTCCAAAGGTTAAGCTTTGCATTTACCCCTTCCTGAGTTTCATCTATCAACACTATATCGTCTGCGAAAAACATACACCAAGGAATATCATCTTGAATATGGGGTATGGGCGGTATAAACTATTTTAAAATGTAAAATATAAAATATAAAATTAATAAATAATAATTAATAAAAATTGACTGTATTATGTACGATGAATAATTACGATCACGGAATCCCTAGGATCCCAAAAGAAAAATTCGGTGAGAATCCTTTTCCAGAATTTTTAATCCAACCGTTTCTTGTGTTAAATTTATCCCAAAAATTAGTTTTGACCAAAAATTGATTTTTAGTCCAAGGGTTGGAGCAAATTGAGAGAGTTAAAAAACTAAAATTTAAGCTAAAGTCCAAAGATTTGAGTTAGTCTAACAAATACAAATGAGAGAAAGTAACATTCATATTTTATTGCGGCTTTTAATTTTTATTTAAAATGGTATCTAAACTTGGTATAATTACTTACTTTTAAAATTGATAAAAATGGTCTTTGAGATTGTCTACCATCAATCATTTTGGTCATTCTGTGAAAAATCTTAATTAAATTAGAGGTATTTTTATCAATACCTTTGAATTGATGATTTCTTCAATTTAATGAAATATTTTCACAAATCATGGTGCATATTATTGGTGGTCCTAAGCTCCTTTATATGTGTAGCGTATGCTTATGTCATGATCTTTCTGCTTCTACTAAATATCAGATGATTTTGTTTTTACTATTTGTTTTACTTTGTACATGGGGTGGCTTTTAGGTTCCCCTGTTGTCTTACTTGCTATGTTATTTCCTCAACAAGGTTTGCTTTTATGTTTCCCTCATTTGTAAATTTCCTTTTTTTTTGTTTTTACTTTAATATGATAATGGGATGCTCGGTGAGCACTATTACCCCATGATTTTCACGCATGCACACAAAAAAAAAAAAATTTATCGTCACAACTAGCATATTTATCAAAATACTCGAAAAGTTAGAGTTTCTAGTCACAACTAACATTGCCATATAGTCAAAATGCTCAAAGTATAGAAAAGAAATATAAAGAAGATATCAAGTTAGATCAGTTACATAGAGAGAGTCATTCCCATGGGATTGCATGATTTCTCTATCATTGCAATGTATTTTTCATAAAACTTCCTTTTCATGATTAGGGACTACGATCCTTGGTGCTATAAATTCAGCAGTTGACTCAAGCACAGAAGTTATCTACAGTGAGAATCCTGATGGTAATTTTGTAAAGTCAAACAACTTTGCATATGCCATTGTTGTGGTTGGCGAGTACCCTATGCTGGGACTGCGGGAGACAGCCCAAACCTTACGATGGCGGAACCTGGCCCAAGTGTCATCAGCAATGTGTGTGAAAGTGTAATGTGCATTGTTACCATAATAACTGGAAAACCTATTGTAATAGAACCATACTAGAAATTACGCCCGTTGTTGCGGAAACCAACTGTTACAGGCGTAATCGAATTAATAAAACACATTTAAGTTGAATAAGAATGTCCCCATGATTAGTCTTCTCGTTTATTTTTCACAAACCAATCACATATTAAAAATCCAAGTACGAAAGCTTTGCAAAGATAAATAAAAAATTTATATAACTAATTAGACTTTGAACATGCAATCAAGGCACATACTCGTATACCTAAAAATAGCAAGGAACCGGCTTCTTCCTCCCACAACCAGAGTTCCTGAAATTTCCAAAGAAAGTAAATCCGTTAGCAATTCAGAGAAATTGGAAGACCAAATCGTATTACATTTGAGTTAAATGAGCAAAGGTAAACCAATTAAATGAGATACTAAACACATTTCGAATCTATGAAATAGAAGAATAATCATGTTAGGACTCCCAAGATGGTGTCCTAAGCACAAAATTATAGGTTAAGAAAGGTAAATCCCAATCCAAAGCTCCAACCTTTTAACTGAAAATGAAACAAAAAAGCATGGATCATATATTTCAGTTTTATTATTAGATTTTCTAAATCCCCAATTTGAATGTGTTGTAAAGACCTGCTAAAGATAATACCACCAACTAAGGGTGGCAATCTGACCAGCGTTGTGCATGTCATGTCGACTCTATGCAACTTAATATATAACATTTAAGCAGCATTAGACGGTCTCCTAAGCATCTACAAACCATTTAACATTATTTCCCCAATTTTATTTCCCAATTTTATCAAATGCTGCATAAACGATCACAATTTACTCCCTTACAATTTCCACCTAACTCCGAACAAACAATATTGATAAATCTTTATCATCACCTTTAACGAAACAGATTACAGCGAAAAGAAAAAAAAAGTTACTATGAAATCAAATTCTTCTAGATGTCCAACCTAACCCATCTATGGGAAGGCAAGCAATCGGACGTGCATTTAGACCAAGCAAAATAAATTTTACAATTTATCAAAACAGCAACTGATTCTCCCAAAGAGAACACAACATACCAACATATTATTCACCATATTCTAAGCTTTCATTTTCGTTCTATCTCTTTCGTTATCTAAACTTATAGTTATCAAAACAGCAATAAAATCATAGACAAACCTTCAATCATTTATCAAAACTGAATTAATTAAACTTCTGCTCCGCAGTCCGTTAATTTTAATTGCAACTCTCATTCTAAAAATTTAAAATTTTGCATTGAATAATCAAACGCACTTGCACGTTACATTCCTTTTATTGGTTCTTGACATAATACATTTTAGGATTGATGTAATAATATCACTACAAACATGAATTGCGATAGATATAGAAACCAAACTTGCACACAAATGTTTGACTGAATTCAGAACCACTTAATTCAACATAAAAAATTACCTCACATGCTTGCTCCCCTTCTGCTCTCGCATCGTCGGCTCCGCTACTAAACGATTAATGAAGTCCCAAAGCAAAAACAGAACAAAAAACATTTACCAATCCAACATTTCAACACATGGTTTTGGCAGGTATAACATTTCAACATAAGCATGATATAGAAAGAAAGAAATCCACATGTCACTTTGTTTTTTCAGAATCAACAAAAAGGGCAACTAGAAGAGAATGTAACCAATTTTAAAGAGTAAATCAGTCTCCCAATAAAGGAGAACAATGCTGGCGGTAGACCAAGAGTAAGTACAACCCGACTGCAGCAACAAAAACACAATTGACTTTCACACTACAGAAATAAATAATAAAAAAACACATACCTGCACCCAATGCATTGTTTTTTTTTTCCTCTGCAGTATAAGAATAAAAAAGAATAACATTCCCCTGAAACCAAATTCATCCCCCAATTTCTTGCAACAAAGAGGGAGACCAACCTTGTGTTCTTGGAGAACAGTATAACAATTAGACACAATCAGACTAATCCAAGTTCCCACTATGATAATGAAAAATTAAAATTAATAAAATAGCTCAAATCATATCACAGTATGTCACAAAGTACACCATTTGATAACCAATAAATTTAACAAAAATAGATTCAATAGTCTATATCAATTAATCAATAGTCTAAAGTATGAAAAAAATTGATTTCAAAGCCTTCCTTAGGAACTTCACAACGTATCAACAGACATTATGATATCGATGATGGTATCCATGAAACCCCAAGCTGCAAGCAAATACTGCCTTTGGAAATTTTCAATATAAATGGTTTTGCAAACCAGCCACTAATGAAACATCTAATTTCAAACAAATAATAAAAGCTTTCTTTAACTGACACATTATCCTTCTTCTTTCCTCCCATTTACTTCCCACCCTCCCTATTAATCCCTCCATTTTGAAACTCCTATATTCTTCCTATTCTGTACAAAACCTGCCAAATCATTTCCTCACTTCTCAAAACCCAAATAATCACTTAAAATGCACAAAATTACAATTAAATCAATATTACATTACACAAAATGACATTCAAAACCACAATACACTAAAACCAAGCGTGAATTCTACACCCTCAATAAGTGGAAGCATTCGTACCTCAAATGAATTTGCAACTTAATTTTTTGCTGAAAAACCTTGACCTACAAAACCAAATTACATTTAGGGTAAATTACAAAAAATTATCTCAACTATTGGTGGCACGACACTTTCATACCTCATCTTTTAAAATTGACAATGTCATACCTCATTTTACGAATTTATGCCAACGTTATACCTTCCGTTAGCTTGGCATAAATTTCTCAGTTAAATGTTGATGTGGCTTGATCTGGGGCCCATTTTCTGTTAAAAAAATTATTAAAAACTAAAAAAAATCATTTAATTTTTTTTAAATATTAAAATAATAAAGAAAAGTTATATAAAATAAAAAAATAAAAAAACCAACCAACACCCAGTTCGTCCCCTTCCCCCCCCTTTCTCTCTCCTCCCCATCTTCATCTTCTTCCCCCTTCTTGCAACTGCAACCCAGAAAAAAGAAGAGAAAAAAAAAACCAATTTGTCTTCCCCACACCCACTCTCCGCACCCATCTTCATCTTCTTCCCCCTTCCAATTGCAACCCAGAAAAAAAAAAAAAAAAAAAAAAAACCAATTTGTCAATTTTTTTTTTCTTCCTCCTTTCTGGGTTGCAGGAAGATGGGGAAGAGAGAAGGGGGAGGGACAAACTGACCTAAGGTTTTATTTTATTTTATTTTTATTTACTTTTCTTTATTATTTTAATATTTAAAAAATACTAAATAATTTTTTAATAGAAAGTGGGCCCCGATTCAAGCCACGTTAGCATTTAACTGAAAAATTCATGGTCAAGTAACGGAAGGTATAACATTGGCACAAATTCGTAAGATGAGGTATGACATTATCAATTTTAAAAGATGAGATATGAAAGTGTCGTGACACCAATAGTTGAGTTAGTTTTTTGTAATTTACCCTTACATTTATCAACAAAAAGGAATCAATGTAAGAAAGCAAACACAATACAGAAAAAATGGCCATTCAAGTCAGCTCTATTTAGATTATAATAACTCTCAATTTAAGAAAGCAAATGCAATACAGAAAGCAAATATAATCCAAATTACCTTGAACACCACCATCATATTTTTACTCCGTTACGTATACATGTCCTTTTCTTTCTAGATAAACTTTATTTCTTTGAAGTTTCTGCAGGGTGCATTCCAATTTAACCCTTTAAATGTTTGTATAAAACTTAGGGTGCGATGGCAAGTGCCTTCGCCCATAAACGGTAGATCTCGGGTTCGAGACTTGGGAGCAGCCTCTCCATAAATGGGGATAAGGCTAGCCGACATTCACCTCTCTCAGACCCTGCGTAAAGCGGGAGCCTTGTGCACTGGGTACGACCTTTATATTCTCGCCTGCTTGCAAGTCAACTAAGTCAACTATTCAACCTTCACATATTGTTTATTAGTTTTCTTGATACTAATGTATGGAAAGGGCTTAAATCCTTCAATGTATGGAAAGGGCTTAAATCCTTCAATTATGGATATACTAATGTATAATCCTTTGTTCTAGACCAATTTTGTTCTTAGTTCTTAGTTTTCTTGATACAAACTTTTTTTTTTGTATTAATATAAATTTGTTTGCACCAAGGGATGGGGTGGGAACATATCTTGAAATATGGCCACGTCCACATTTGCAGCTGAAGAACACTTCAATATAAGTTTAATTTGGTGCAACTTTAGGTTTAATTTGGGTATGTTCCACCACTTAAAATTTGCAATACTAATTTTGAACAATGAATAAGAAAATTCTACCAAGAGAGAGTAAAATAGTAAATCAACTTAATTTCTGTAAAAAAAAAAAAAAAAACTTGCAAAAATTTCATGAAATTTTGGTAAAAACGGAAAAGAAAAGGGTTAAGACAATCAAGACTAATGGAAAATTTGATATTGTTTTAACATTAACTTAGGTTGATTTTGTTCACCAGCATTAATAAAACGAATGACTTTAACTTGGGCAAGCAAACAATTAAATTAGACGTAAGCCAAGTAACTTAGAAGTTAACCATATGAAAAAAGGAAAACTAATGAAAAAAGCTTGAAAACTTTGAGTTTTAATGATAAGGACAAAATAAAGGGTAAAGTGAATAGTACCATGATTGACTTTTTAGTGTAAAAATGTGGTTTTTCGTTAAAGTGAATAGTACCGAGTGCTTTTCGTTAAAGTTCCCTATGAAAAAAAGCAATGACAATCAAACTGACCTCTTCTTTCATATGAAGTATAATCTGTTCTCTATTTTGCCTTTGTGAAGAATGCACTTTTCACTTCCTACACACAAAATAGCATACATTGAAAATGCTCCGTAGCATTATAAAAACTATAGATATACAGTACTGTATATGTATCATATACTATATTGTGTACGTAGTTGGACATAAGGTATAAAGATTTACTAACATAATTAAGCTTAAATTTAACAAAAGAAGTAATTACAAATTGAAATCAAACGATATTCTAGTTATTCAAAAAAATTCTGGCTAAATTTTACAAATAGTATTATAAATTGTTAAAAAAAATAACACAATTGAAAAAACTCACCACTCAAATCTGCAATTCTATTAAAAACACATCACTAAAAATTAACTCCAACAAAAGGGGATTAACAAATTATACCTTTTTAAGAGTTGGAATTGTTTATCTATATCTTGAGCTGGACCCGCTGGATTTGAATCCTCAGTTGACTTAGAGGGAGGATAGGCATGAAAAGAAGTGTAAGGTTCACTGGATCATATTTTTAAGAGATAGAGAGAGTTCTACTTTTCAACAGCGGAGAGAACATATTCAATCTTGGGCATAAAAAGAAAAAATAGAAGCTTCATAGCACAATAATTAACCACAATCCTCTGTTTTTCTAAATGCAAATAGAAAAAAGGAATCAAAATATTCAACACAAAATCTTCACATTAGCTCAAGAACTATATTATTTCCAGTGCTTTCCAATTTTCCAGCACGGAACAACAAACATAAAAGCATTAAAAATATATAATTGCAAAAAAAAAAAATAGCAATTCCAAGAAACTAAATGCGAAGTTAGCCAGATCTGCACAGTAACACAAACCCATTACTTGAATTAAGAGCATTGTGGCTCACCCTGAAAACACCCATTTTGCAATGAGGAAGAGAGACACTGCTGCTCTGGCTGCTGAGTGCTGCTGGCTCCAAAGCAGTTTGTCTACCAGAACTTTATAAGAGCAAGTCCAACCCTTCAAAGCCACTGTAAATCGCCAAGGATTTACATCATTCTGCTTGCCTAAAAAAAGCAAACAAAAAAGAAAAAAATGGAAAGTATAAAATTCAAATGACCCTTGATGAACATAACCCATAAATTTTCCTTGTATTCCATAAATGCAATAAAACAAAAGTCAGTGTCTCCATTTTCCAAAAAACCAAGCAAGCAAGCAACAAATTTCGAAAACCCTAATTCTAACCAATTTAGAACTATAACCAAGTAAACCACTTAATCAACAAAACTCACTAATTTTCTCAAAAACCCAACAAATTTAAAGGATATCCAGATGATAAATCCCAGTAAAATCCCAAATTTGAAAACCAGAAGAAAAAAAAAGACAAAGAGGCTTATCTTTCTTCACTAATCGGGCACTAACAGAAAAACCTTAATTCATATTATTCAGATTACAAATACACAGGGACCAAATAGCTAATAATGCTGGACAATTTGTCCCCAATCCAACACAAAAATTGTTCTTGTTATACATACGATACCCGCCTAAAATATCAACCAATTCCAAATTAAAATGGAAAATGAAACGGAGCATCATAAATTGAATACAATTTGGAGAAAATTATCTCACTTGGGGCGCCGAATCTCCAAGAGGTCCCAATCCGAGCAGGCTCCAAATTGGGTTGTTGAAAATGGTGATCAAGGAAGGGTTTTGGAGGTGGGTCTGATCAGAACAAAGCCGAAGCCATTAGGTTTGGGGGGAGAGGAACAAAGAGCCACTGAGAGAGAGAGAGAGAGAGAGAGAGAGCATGCGTTGTCCTTTTCTTCTATCCGGCCACTGGATCGCAGTTCCTTCACAAAAATTATACACGTGTGTTACTTTTTCAAGTTCTAGTTTTGTAATCACCTAATCGATCATAACACCATTCGCAAATATGACAAACATAAACAATTAAGTCAGCAACATGATATGCCATTCCTTTCATATTGCACATATAAAGAAAAAAGAAATGAACCAAAATAAAATTATACTATAATCCAATTATATGAAGGCCAAACTTGAGTTGGGGCTGGTGGCCGTTGACCACATCATCGCCTCCATTTGAGAGAAAAGGGTTTGTTTGGCTTTTTTGTCCAATTATTTACACTAACCATATATAAATGAAGAAGGACAACATCTATGTTGCTCCCTTCTTGTGATCCAAATTTGAAGAGGGCCGATGGGGAGGGGCAGTTATAAGTGTCATCCTCTTTGTTTCTCCTATCCCTGCATTATCAACCAAAAAAACATCAAACCAAGTGCAATACAATCCAATTTAATGCTCACAAAATTTGAGCTCCAAACAAGGTCACAGGTCAGCAATCGCCTAATCGATCATAACACCATTCGCAAACATAAACAATTAAGTCAGCAACTTGATATGCCATCCCTTTCATACAAACACAGATTGCAATTCATATATGCCGCATTATTTACAAACAATTACAAATCAAGAAACAATTAAATCATCATCATGAATTATAGTGTAATAACAGCATCATCAATTAGAAGAGACAGAGCTACATGGCAATAAACATATAGAGAGTAAACATACAGAGAGGAACTGCTTCATATCCTTCCCAAAAGCAATCTTCCGCAGGATAACAAAAGAGCGGTTGATCTCTGATCTAATTGCAGACGCAATCTGCAGAACCGACTTCTATGGAATTTTAACTTGTGAAATGTGGGGTGGAGATTTGAATGTAACAAATTGGTGTTAAGTGAATAATTCCAAACATATGAAATTTAGATAATCACATCCGAACGCAAACAGAAGAATTAAATAAAGAATCAAAGGCATATGCAATCTAATTAGACAAATAAGTGAACTTTCCCATGCCAAAATCCGAAAGGCCAACAGATATCTCTCATTACAGGACTTAATACATATCTTAAAAGACAAAACTTAAAATAACAAAAATTAGGTGAAACAATTGAAGAGAACATAATCCTTGTAACCAATCCGGAAAAGATGCTTTTAAATCCCAGAAAACAAATTATGAGAAGTTTTTAAAAAAACCATCATTTCAATTATTTTCCAGTCTTACATTTGGGAATAAACAGAAAATATAACTAAAATGCCAACTTTCTCAAAAAACTACAACTACTTTAACAAATTTCCATCACTCAACACTGAAAAATGAGAATCACGAAGCAACGAAGAACGGAACACGCTAGAAATAACAACAAAGCCTTTTCCCACTAAGTGAGGTCGGCTATATGAATCCTAGAACGCCATTGCGCTCGGTTTTGTGTCATGTCCTCCGTTAGATCCAAGTACTCTAAGTCTTTTCTTAGGGTCTCTTCCAAAGTTTTCCTAGGTCTTCCTCTACCCCTTCGGCCCCGAACCTGTCTCGTAGTCACATCTTCGAACCGGAGCGTCAGTAGGCATTCTTTGCGCATGTCCAAACAACCGTAACCGATTTTCTCTCATATTTCCTTCAACTTCGGCTATTCCTACTTTACCTCGGATATCCTCATTCCCAATCTTATCATTTCTCGTGTGCCCACACATCCCACGAAGCATCATTATCTCCGCTACACCCATTTTGTGTACGTGTTGATGCTTCACCGCCCAACATTCTGTGCCATACAACATCGCTGGCCTTATTACCGTCCTATAAAATTTTCCCTTGAGCTTCAGTGACCTATGACGGTCACACAACACGCCGGATGCACTCTTACACTTCATCCATCCATCTTGTATTCTATGGTTGAGATCTCCATCTAATTCTCCGTTCTCTTGCAAGATAGATCCTAGGTAGCGAAAACGGTCGCTTTTTGTGATCTTCGCTAGATTGCTCCGGTCATTAGTGTGGATAAGTATATAAATGGATAGAGATAGGAAAGCAAACACCAGATGTACGTGGTTCACCCATATTGGCTACGTCCACGGAATAGAGGATTTCTCATTAATTGTGAAGGGTTTACACAAGTACATAGGTTCAAGCTCTCCTTTAGTGAGTACAAGTGAATGATTTAGTACAAATGACATTAAGAAATATTGTGGGAGAATGATCTCGTAATCACGAAACTTCTAAGTACCGGCGTGTGGTATCGTCTTGACTTGCCTTATCTGTCTCGTAGGTAGATGTTGCATCTTCTCTGGAAGTACTCTTCCATCCAGGGGTGGTATCTTTAACTAGTGGAGATGCACAAGGTAATGTATTAATTTCACTTGAAGCTTACTTGTAGTTTCAGGCTTGGTCAAGCGCAATACAAACCATGTAGTAGGAGTCCCCCAAGTCGCCGAGCTAGGGGATCTGCTGAAAGAGGTGACAGATAAGGTAAGCAATCAGAGCTCCAAGCAATCAGTCCTAGATCAGAACTTTGATTTCGAGTTCCGGCTGATTGTTCACATTCTCCCTATCTTGCAGGCAGCATGAAGGATAAAGAGAAGAAAAATGAGAAGAGATGATATGGGATACTTTTGCTTTTGAAGAAGTAACTTTCCACAGGCTTATTCTTGAACTGGGCTGGAGGGTTTTCTAGTTTCCTCCAGAGTATAAGGCCGACTGAAGAATTTGAGGGTCAAAACAAGTCCATCAAATCTATAGTACGTTCGACCCTGCTGATATAGGATACTTTTGCTTTTGACAGAGTAGTGGATGTATCGGCACGTGTGCTGTTACGCTTGTCTCCACATGCTTCCTTGTATCCTTCTCACTTGCCTTATCTGTTCCTCAGGCAGATGCGGTATCTTCCCTGGAAGCATAAAATGTTGAAGATGAGTACTCGAGAGCAATGCCAGGTAAGTAATCAAGTAAGGGGTTCCAGGCAGTCAGTTCATGACTGGAAGCTTGATTCCAAGTGCTGATTGATTGCTCTCTTTCTCCTTGTCTTGCAGGTAAGAACAAGGCCAAAGGAAAAGACAGGGAAAAAGCATGATATGTGATACTCTTGCTTTTAACCCTGATGATATGAGATATTCTTGCTCTAGTATAGCTTGTTTGCAGAGGTATTATCAGGGGGAAAGAAAGCTGAATATTTCGAAAGGCTTCTTTGGGAGTGGCTCTCAGATATGACGAAGGGTTGAACATTTTTGCAGGTCTGCCTGTCCGTTGAGGATGGAGGTCGACATATATAGGAGTCTCCCTAACAACAAGTAGTAATGCTATTCCTTTACCCTGCTTGGTCATAGCACGGTAATGGGAGCTGCCAGCTTCACATGTTTTAACTCTGTCAGAGCACTTTGAAAAAGTGATCTGTGGTATCTGGAAAGCTGATGTTGCGTGTGAAGATTACAGACAAGCTTTATCCAAGGAGATCCAGCTCTTGAAGTTGGGAAAGTGGTGCCTCTTCGGTTTTCGAACAAGTAATCCTGTCGGAGATCTGGCTCTCGAGATTCGGAGAACGATGCCTTTTCGATTTTTGAGAAAGCAATTCTGTTAGGGGTTTGGCTCTCGAGATTCGGAGAGCGGTGTCTCTTCGATTTTTGAGAAAGTAATCATGTTGGGAGTCTGGCTCTCGAGATTCGGAGGGCGGTGCCTCTTCGATTTTGGAGCAAGCAATCTTGTTGGGAGGGTTTTCTCGAATGTGAGAAAAGGTTGGGCATGTTTGCTAGTCTACCTTGCCACGAAGCACAGAGGTTGACACATAGGGACTTTCCAATTATCCAGCAGTGGTACTGTTCCTTTACCCATGTGGGTAATAATATGGTAACTAGACCTTCAAAATTTATGTGTCTAAACTTTGTTAGTGCTGTTTCTTTGCTATTCTTTTACCCTTCTTGGTCAGAGCGATGTAGTAGGAGCTGCAAGCTTCACGTGTCTCAACTTTGTCAGAGAACTTTGGCAAAGTTATCTGTGGTACCCATGAGCTAATGTTGCGTGTGGAAAGTGGGTGATTGAACAGTAAGATTCATGTGCTTTCTACTTCACCAGAAATCTTCGACATAATGCCCATAATTTCCGCAAAGCTGAGTGTGCGTGTGACAGGTGCTGACAAGGTTGGAAAAGTAGGTGCCTCTTCGATTTCTGAGATCGGCCCTCGTGGTCTCTGAGCAGCCCAGCTTTTGAGAAAGCAAGCCTCTTCGATTTCTGAGATCGGCCTTCGTGGTATTTGAGCAGCCCAACTTTTGAGAAAGTAAACGTCTCGTGGTCTCTGAGCAGCCCAGCTTTTGAGAAAGCAAACGCCTCTTCGATTTCTGAAGCTCCGTCGAGTGCAGATTTTTATAGAGGCTGGCATTAAGTTCCAAAGCACACTTGAATCTCCACCAGTAGAAGCTCCATTCTTGCACTTCTAAGATCTTGATTTGTCCGACCTCTTCTCTCTTCAACACCTTTGAAAATGTCTGGCCCCCTCCGACCGTCGTTTTGACTTGAACCTTGTTGAAGAGGCAGCCACGCCTTCTCCAAACAACATATGGCGCCCATCCTTCGTCTCCCCTACTGGTCCTCTTACCGTTGGGGATTCCGTGATGAAGAATGATATGACCGCTGCGGTAGTGGCCAGGAACCTTCTCACTCCCAAAGATAACAGACTACTTTCCAAACGGTCTGATGAGTTGGCTGTTAAGGATTCTCTGGCTCTCAGTGTTCAGTGTGCAGGTTCTGTGTCTAACATGGCCCAACGCCTATTTGCTCGAACCCGCCAAGTTGAATCATTGGCGGCTGAAGTGATGAGTCTCAAACAGGAGATTAGAGGGCTCAAGCATGAGAATAAACAGTTGCACCGGCTCGCACATGACTATGCTACAAACATGAAGAGGAAGCTTGACCAGATGAAGGAATCTGATGGTCAGGTTTTACTTGATCATCAGAGATTTGTGGGTTTGTTCCAAAGGCATTTATTGCCTTCGTCTTCTGGGGCTGTACCGCGTAATGAAGCTCCAAATGATCAACCTCTGCTGCCTCCTCCTTCTAGGGTTCTGTCCAGTACTGAGGCTCCAAATGATCCCCCTCCAGTGCCTGCTCTTTCTGGGGCTCTACCGACTGCTGAGACTTCTCCTAAGCAACCTTTGTGAAGGCTCCCTCTTGTTTGTTTATTTTGACTCATGTATATGTACATATTTGTAACTTATCGGGGATATCAATAAATAAGCTTTCCTTCATTTCAACGTATTGTGTTAAATACACCAAAGCCTTCTTCGCTAAGTTCTTTGAATTTTCTTTTTGTTGAAGCTTGTATGTTGAAGCTTTGTGAGTGGAGCATGTAGGTTGAGGTAGTATTCCCTTAATTTCCCGAGTGAGGAAAACTTCTCGGTTGGAGACTTGGAAAATCCAAGTCACTGAGTGGGATCGGCTATATGAATCTTTGAACGCCATTGTGCTCGGTCCTGTCATGTCCTCCGTTAGATCCAAGTACTCTAAGTCTTTTCTTAGAGTCTCTTCCAAAGTTTTCCTAGGTCTTCCTCTACCCCTTCGGCCCTGAACCTCTGTCCCATAGTCGCATCTTCTAATCGGAGCGTCAGTAGGCCTTCTTTGCACATGTCCAAACCACCGTAACCGATTTTCTCTCATCTTTCCTTCAATTTCGGCTACTCCTACTTTACCCCGGATATCCTCATTCCTAATCTTATCCTTTCTTGTGTGCCCACACATCCAACGAAGCATCCTCATCTCCGCTACACCCATTTTGTGTACGTGTTGATGCTTCACCGCCCAACATTCTGTGCCATACAGCATCGCCGGCCTTATTGCCGTCCTATAAAATTTTCCCTTGAGCTTCAGTGGCATACGGCGGTCACACACAACACGCCGGATGCACTCTTCCACTTCATCCATCCAGCTTGTATTCTATGGTTGAGATCTCCATCTAATTCTCCGTTCTTTTGCAAGATAGATCCTAGGTAACGAAAACGGTCGCTCTTTGGTATTTCTTGATCTCCGATCCTCACCCCTAACTCGTTTTGGCCTCCATTTGCACTGAACTTGCACTCCATATATTCTGTCTTTGATCGGCTTAGGCGAAAGACCTTTAGATTCCAACACTTCTCTCCAAAGGTTAAGCTTTGCATTTACCCCTTCCTGAGTTTCATCTATCAACACTATATCGTCTGCGAAAAGCATACACCAAGGAATATCATCTTGAATATGTCCTGTTAACTCATCCATTACCAACGCAAAAAGGTAAGGACTTAAGGATGAGCCTTGATGTAATCCTACAGTTATGGGAAAGCTTTCGGTTTGTCCTTCATGAGTTCTTACGGCAGTCTTTGCTCCTTCATACATATCCTTTATAGCTTGGATATATGCTACTCGTACTCCTTTTCTTCTCTAAAATCCTCCAAAGAATGTCTCTTGGGACCCTATCATACGCTTTTTTCCAAATCTATAAAGACCATGTGTAAATCCTTTTTCCCATCTCTATATCTTTCCATCAATCTTCGTAAGAGATAGATTGCCTCCATGGTTGAGCGCCCTGGCATGAACCCGAATTGGTTGTCCGAAACCCGTGTCTCTTGCCTCATCTATGCTCAATGACTCTCTCCCAGAGCTTCATTGTATGACTCATTAGCTTAATACCCCTATAGTTCATGCAATTTTGTACGTCGCCCTTATTCTTGTAGATAGGCACCAAAGTGCTCGTTTCGCCACTCATTTGGCATCTTCTTCGTTTTCAAAATCCTATTGAAAAGGTCAGTGAGCCATGTTATACCTGTCTCTCCCAAAACTTTCCACACTTCGATTGGTATATCGTCTGGGCCCACTGCTTTTCTATGCTTCATCTTCTTCAAAGCTACAACCACTTCTTCCTTCCGGATTCGACGATAAAAAGAGTAGTTTCTACACTCTTCTGAGTTACTCAACTCCCCTAAAGAAGCACTCATTTCATGTCCTTCATTGAAAAGATTATGAAAATAACCTCTCCATCTGTCTTTAACCGCGTTTCTCTGTAGCAAGAACCTTTCCATCCTCATCCTTGATGCACCTCACTTGGTTTAGGTCCCTTGTCTTCTTTTCCCTTGCTCTAGCTAGTTTATAGATATCCAACTCTCCTTCTTTGGTATCTAGTCGCTTATACATATCGTCATAAGCCGCTAACTTAGCTTCTCTCACAGCTTTCTTCGCCTCTTGCTTCGCTTTTCTATACCTTTCACCATTTTCATCGGTCCTATCCTTGTATAAGGCTTTACAACATTCCTTCTTAGCCTTCACCTTTGTTTGTACCTCCTCATTCCACCACCAAGATTCCTTTTGGTGTGGGGCAAAGCCCTTGGACTCTCCTAATACCTCTTTTGCTACTTTTCGGATACAACTAGCCATGGAATCCCACATTTGGCTAGCTTCCCCCTCTCTATCCCACACACACTGGGTGATTACTTTCTCTTTGAAAATGACTTGTTTTTTCTTCTTTTAGATTCCACCATCTAGTCCTTGGGCACTTCCAAGTCTTGTTCTTTTTTCTCACTCTTTTGATATGTACATCCATCACCAACAAGCGATGTTGATTAGCCAAGCTCTCTCCTGGTATAACTTTGCAATCCTTACAAGTTATACGATCCCCTTTCCTCATTAGAAGAAAATCTATTTGTGTTTTTGACGACCCACTCTTGTAGGTGATCACATGTTCTTCTCTCTCTTCTTAAAGAAGGTGTTGGCTAAGAAGAGAGATCATATGCCATTGCAAAATCCAAGATAGCTTCCCCATCCTCGTTTCTCTCCCCAAAACCATGGCCACCATGAAAACCTCCATAGTTGCCTGTCTCCCTGCCCACGTGTCCATTTAAATCTCCTCCTATAAATAACTTCTCCGTCTGAGCAATTCCTTGCACCAAGTCTCCAAGGTCTTCCCAAAATTTCTCCTTCGAACTCGTATCCAACCCTACTTGAGGTGCGTACGCACTAATCACATTGATAAGTTCTTGTCCTATTACAATCTTGATTGCCATGATTCTATCTCCTACCCTCTTGACATCTACAACATCTTGTGTCAAGGTCTTGTCCACGATGATGCCAACACCGTTTCTCGTTCTATTTGTGCCCGAATACCAAAGTTTAAACCCTGAGTTTTCTAGATCCTTTGCCTTAAGACCAACCCACTTAGTTTCTTGTAGGCACATAATATTTATCCTTCTCCTCACCATAACTTCCACTACTTCCATAGATTTTCCCGTTAAGGTTCCTATATTCCACGTTCCTAAACGCATTTTGCTCTCTTGAACTCTACCCTTCTGTCCTAGCTTCTTCACCCTCCCCCATCTAATAGGATCAAAGTACTTCTTTTGTGTGTTCCGTGTAAAGTTGATAGGAGCATATGCTTCTAAACAACTTTGAGTGGAGTCGTTCGAAAAGAAGTTTCTATGGCCCCCTTGCTCATTTAACACTGCATCCGGGTGCCGATGGAGATACAACGACCCTTGCTCACTTATCACTGTGCTCGGGCCACACAGCGCGCCACTTACTGGTGACACCCTAGCTTTAGCGCAATTTCGTTCTGGATTCATTTTCATAAGGATTCGACGTAATCATGGAGTGCCGGCTGTCGACTACCTGACGCCCTCCCCCTCCTCCTTTATCCAGGCTTAGGACCGGCAATGTAAGATAAACTTACACAGGCGGAGTTAACGGAACACGCTAGAACTGAAACATTAAAAACAACATGTACCCATTTCAAAGACCAAAAATCCTGCAAGGACAAAAAAAAAATCCGAGAAAATCAGTACATCAGTACTCCCTGCAAAACCCCAAAATCAGAAAATTAGAAAAAGAACCCAAATCAGTGGCATGGTCCTTGTTTCTCCATTAATCAGTAGGTAATGACCTAATGAAAAAGAACCCAAAACAGACGGCTTAAATTATGGAAAGTGCTTATAAAGCTCATGAATAACTTTCAAAGCCTGCATTCCACAGTGTGCACACGCACAAACATAAAATATACATGCATAGTTAATTTTAGACAATAATACCTCAGAACATAAGTTGCAATTTGGGACTATTTGGTTGACTCAAAAGAAATTGATGGGTTAGAAAACCACAAAAAAAATACAAAGACGGATGTTTTTATGTCGTTCATTTCTTACGTCGACAAAACACACACACCTGTGTTTTAATGCTCCTCCAATACTCAATGAGAAGGCACCAGGCAAAAAGAAGGTCAAGGCTGGAAAGAAGCTTCCAAAGAGAACAATATATAAAGCAGACCACAAAAATTAGACAAAACCCAAAAACTAAACAGTAGAAAAACCTCTAAAATATATAAATATATATATAATTAAATAATTTAAAAAAAAACTAAACTGCAAATACTCTAGAAATCGTAAAATGAACTGCAAACCCGTCAATCATTTCCCAAAACCACATAACCAAAGAGTAAAAAAGGGAGTACGGGAGAGAGAAGCAGCCAAAATACAGAGAAGATGGCAAGAGAGAGAGAGAGAGAGAGAAAAATGAATTATTTTGGTGCCTCTGGTTCCTGCCTTTGTTCTTTGTTTTTCATTTATTTATAGGTAACTTGCTCAAGTCCAAAGGCAATTAAACATGATTAGTAAAGCACCATAATAAAGCATGAGAGATATCTATTTTAATTAAATCTGTTGTGGGCTCACTGTGATTGTACATCATCATCATAAATAATGCATGCTTGAACCCCATTTTAGTTTCATGCCTATCATAATTAAATCATGGATGGTCAAGAAGCATAGGACTGAGAAATCAGAGCCTAATTTCCAATATCAAAAGAGTACAAATTATTCAACTTAAACGCTAATTTCGTTAACGAAGATTAAAATAGGCGTGAAATCCATACAATTTATACGTTACCATTGATTCAAGTTCTGGTAGGTATCCATGGAAACTATCCGTTGCCACTCTCTCAGTTCCCATATTTTCTGTATGTTTCATTAAACAATATAAACTTTTGATGCTCTTCCATCTGGAGCTAAAACAGATTACCAATAATAACAAAGAGGTCTAAATAATAGAAATCAAAATTTTGATTTTTGCGGACTTTAGAGAATCTGCAAACTTTAGCCTAACATTATGTGATTGCCTCACTTCTTCAGTAACTCAGAGGAGGTGAATTACTCAAAGTATGGAGGACTTCTGCTAACATATTTCAAGCACTTGTAACATTAAATGTAATGACAGGTTGACATTATTATTATTTTTTTTTTGTAAAGAATTGTTGCAAGAAGTTTGACCCTTTGTCTTTTTATTTCTGTAAGGATTTATAGGTACATATAAAATCCATATTATATATGGTTCACAGATGAGAGTACTTCAAACACCAAATATTCATTCATGATTGGAGATAAGAAAGCTTACTAAGAGGCAATCGCCTTTGTGATGTTTACTTTTGTGCTTATCCTTTGTCTTCTTTTCTGAGGCAAAATATGTCAATGTGATAAGTAATTTCCCATAAAGAATATCATCCTCAATAGGCTAAACAACTACAATGGTTAGTCAAATAATGTACTTTCATGTAGTTAATCTCCTCGGTTTGTGTTTACTTTTTCAATATCAAAACATCTCGAAGAAACAACGTTTTCCCTTACTCTACAAACACCGAATGTGCCCGATAAACCACTAACAACGCCATTACTCTAATTCGACTGCAGAGTGAGAGTTAAGATAAGAAGATACTCACAGGCCAAAACGGATGACATCACCAACACATAAATCCAAAAGCCACAACCAAATTTAATTTTGTTTTTACGTTGAATTTTTTTTTCTTGAATCCGTTTGGATGCTGAGAACGTGTGGTATGGGATTATTAATTACCGGCAGGGAAAATGACGATTTCTCCTATTTGCATTTGCAGGTGGAGGAATCATAGCCGAGGGATTGCAGTTCGTCGGTGACCATCTTCCTCAAATCGTCTTTTTGTTTGAGATTCTTGTTTGCTTCGACGATCCTCGCCGTATCAGCCAGGAGGTTTCTCTCCGAGACGCTCACGCATGGAATCAGACTCTGATTAAACAATAATTAAGCAAACAATCAATCACCCATATTCATATTCTGTGTTTGGTTGCCAAGAAACCGCGAGAAATGCAAAAACAATTTACTAATAAAAAAGTGTAATCAAAGCAACCATTATTTATACTTTTGTACCTTAAGAATATCTGAGGCGTCGCCACCGAACGAACCGGAGGAGATTGAATCACCGAAACCTCCACCGAATATATCGAACTCGTCGTCGGAGCTGTCATTGCTGTTGCCGTGAAAGCAATTGCAGCGGTTCCGTCCACATTTCGGCGGAGGTTGCTTCTCGTTGCTTTCTTCGATGAAATTCTGAACCATCTTCGCCAAGCAGACCGAACTTGGCTTGAACTCAGGCCGCGGCGCTGACGGTCCCTTCATCCTTGCTGATATTGAGGCCGCAGGAGTGGCGAGTTGTGATGTGGACTCAGGCCTCTCGGCCTCTGGGTTTTACGGAGAAGGGGAAGATGGTGAGGGTTGAGAGAGATGCAGAGTCTGAAAGAGAGTGAAAGAGAAAGGGTTATAAGAGAGGTTGAGTGTGACAGAGACGATTGAAGCAAAACGCACGATGATAAACGCGTGTGCTCGGTTCAGAATGGCAAGCCCGTAAATACCCAATGACAGATTTGTAAATAAAATGAAATTCACTTCAAAATACTGTTCATTTTAATAGTGCCTATTGAAAACCTTACTTTAGACTAAAGTAACTAAAAATTATGTTTGCGCGTTGCTACTAGAACCAACTGTTTCAAACGTAATTGGATGGACAAAACACATTTAAGTTGAATAAATTCAAAACAATTACGAACAAACAGAAGGATACATGAGTGCATGAGGCCGGTAAGATCAGCAGTTTTGCTTTTGTACACTTGTAAGTGAGTTGACATATAAACACATTGCACAATGAGTGAGAATAAACTCTACGTGTTTGAAACTTCATTTTAAACTAACATTCACACAATCCTAATCATTTGTGAATTACCATATTCTTATCATTATTCCAATATCTCTTCATGTAGATGGGGTGAGCTCATACCAGTCACTAAGAGCATTTTTGATACTCTACTTGAATCCAACTTTTTAAATTCAAAAACAATTTTCAAGTTTTAAGCCTTAAAAACTTGTTTGGTAAGATTATTTTCAAAAATTGAACTTAAGATTAACTCAAAACTATAGTTTACTCTCTAAAAACACAAAATGTAAATTTTTAGAGTTTTTAAACTTAAACTCACTCATTTCTTTTCTCTCCCTCCTCCTCTCTCACTCCAAATCTATCTCTCTTTTCTTCTTTCTATGTCCCCCTTTTTTTTTTTTTTTTTACCTTTTTCGTCTCTCATCCAATCCGCTCTCTTCATTATCTCGATTCTTTTTCTCACTTATCTTCCTCTATATCTCCTCCGATCCTCTCTTCTTTCTCTTTCCTTCAATCATATCTTACTTTCTTTCCTCCTCTTTCCTCTTTCTCCCTCGACCCCCTCTTTTTGGATCTCTTTGTCCAGTTTAAGTTGTAAGATTTAAAAATTTTAAATTACATACCAAACAAGTTTTTTAGTCTTAAATAAAATTATTTTTCAAGAAAAATTCTTAAAAAATGTTTTGAGAAATGATAAAAAATTTCAAATAGGATACCAAACAAGCATTAAAATTGCTAATGTATTTAGTGATTATACAGAGCAACTTAACTATAGAAACGCTCCTCAAATCACTCTATACGTTTCCATTTTGCTTTTCAAATTAGCATGTTTATATATTGACATTAGAGAAAACGAGAATGCTGATGAAAATTGGATTATTAGAGGTTAAACGGCAGCGACCCCCCCCCCCTCCCCCCCCCAAATCCATTTTTGTTGGTTGACATTCTGAATATTGACGGTTTACCTTGTCCTCCTTAATTTCCTATAATCGGTAGTATAGGGGCGACATCTTGGCATTTGTTGCAGTGTCGTATCCATCTGTACCCCCCTCCACTACCTTGCTTGTCTCCTTTAGTTTATCTGTTGCTTGCCTCCCTTAACGAGCAGAAACCAAACAAGAACACCCAATTTTGACACGTGTACAACACACTCAAACATCATCAGCGTCCAAGAAGGCTAGGCGCCATATCACAGAGATCCATCTTGGCCTAGGTCCCTCTCTAGTTTCTTGCTAATCAAAATTCAAACCCAATTTTTTATTCGGAAATAAATTTCAAAATTTAGGAAATTTTATTATCTGAAAAAGAAATAATTTTCAAGGGTTACACTGTGACTGTGCTGATAAACACATGGATACCAAGCTCTGTTGTGATTGCTTCCCTTTACGTTTTTTCGCCAATCTTTGTGCACCATTTAGACATTGATAGTGATGCCAGTTTTAGCTGTATCCTCACATAAAAATTGCCAAATATACACAGATGTCAAAGATCTTGAAGTTTGGTTCACATGCTTTGTCAGGGAAGATCAATGTATGCGATTGGGTCGTCTGGAATTAGCAGTGTAAAAGGTGTTGGTATACGGTCCAGCCCATGATCAATGTTCTAGATTATTCTAGTAAGCAAGAGATGAGGCTGGAGCTTGCTAGACAATTCTAGCATGTTATTAAGTTGATGGAAGAAGCTAGAGAGTACTAGCTTCCTTGGTTGCAAATGGAAAGATCTAGAAGCTACAAGTATGTGGCTAGTCTAGATTTTTCTATACTAGAGGTTTGAAGAAGGAACTAGAAACTAGTAGAATGCCAAGCCCTCACCTATAAATATGGGTGTGATGTAACCAATTGAAAATCAAGAAAGAGTGAGTAGCAAAGGATCAAGTCCAAAGCTAGAGTTCCACTCCAAGAGTGAGAGTGAGAGTGTTCCACTACACATTGTGTGAGTGAAGTTTAGAGTGATAGAAAGTGTGTGTTATACTTTCTTGTATCCATCAAGCCTTGTCTTTGGCTTGGTAAGACTACTCTTGTTGTATTCATTTTTTTCATATAGTGAAGATTGATCCTTGTTTGGTGGACGTAGGCATAAATTGCCGAACCACATAAATTCTTGGTGTCCATTTTCTACTTTACCTTGTGCATTCTCTATCTTGTAGTACTGACATTCCTAACAAGTGGTATCAGAGCCCGGTTGGCTCGTACTACGAGATGGAAGGAAGTGGCACTATGATCAAACTCACCAACTCCAATTGGGTAACATGGAAGCCAAGGATGGAGGACATTCTCTATTGCAAGGATTTGCATGAGCCAATTGAAGGAGATGCCGCTAAGCCCGAGAGCATGTCCGATGCCGAGTGGAAGAAGATGAATCGCAAGGCTATTGGCACAATTAGACAATGGGTGGATGATAGTGTTTTTCACCATGTGTCTAATGAAACCAATGCTCGCGAGTTTTGGACGAAGCTTGAGTCCTTGTTCGAGAAGAAGACCCCAGCCAAGAAAGCCTTCTTGATCAAAGAGCTCATCAATGTGAAGTACAAGGATGGTTTAAGTGTAGCAGAACACTTGAACAATTTCCAGAATATCATCAACCAGTTGGCTACTATGAAAATGACGATCGAGGACGAGCTACAAGCGCTCTTGTTACTTGGATCCTTGCCAGACAGTTGGGAGACCTTTGTGGTGAGTATAAGTAACTCTGCTTCTAATGGTGTTCTTACTCTTGATAATGTTAAAAATAGCATGCTCAATGAAGAAACAAGGAGAAAGACTTCTGGCACAGATAGCAGCCAAGTATTTGTCACAGAGAACCGCGGAAGAAGCAAGAGTAGAGGGCCTAGAGGTCATGGCAGGAGTCCTAGCCGATCCAAGTCAAGGTTCAGGGGTGCATGCCACCATTGTGGCAAAGAAGGCCATATGAAGAAAAATTGTCGAGTTTGGAAGAGAGAGCAAAAGGAAGGAAACAATCAGAAGAAAGATGATACTGGCAATACCACTGCTGTCATATGTGGTGATGTACCAGAAATATTGTCTGTTGGTGAATGTCTGCATATGGGCAACTCTGACAGAGACATTGAATGGATCTTTGATAATGGAGCTTTCTTCCATGCTACGTCCAAACGGGAGTTCTTCAGTACATACAAAGAAGGTGACTTTGGCATAGTGAAGATGGGGAATGAAAGCTATTCCAAAATTCTTGGAATTTGGTGATATCTGCTTAAGAACTAATCTCGGCTGCCAATTGATGTTGAAAAGATGTGAGACATATTCCTGATATACGTCTCAATCTGATATCCATCGGTACCCTTGATCGACAAGGATATTATCACCATATTGGCGAAGGAAAATTGAAGCTTACTAAAGGCTTAATGGTGGTAGCAAGAGCACGACTTTGTTGTACGTTGTACCGGTCAAATGCCAAGGTTTTGAAAGGTGAGTTGAATGCTGTGGAAGACTCATCTCTAGACTTGTGGCATAAGAGGCTAGGCCACATGAGCGAGAAAGGCCTACAAGTTTTGGCAAAGAAGTCTCATATTCCCTTTGCCAAAGGTACGTCGTTAAACTCTTGTGAGCATTGTTTATTCGGAAAACAAAGAAGAGTTAGTTTTTCTGTTCCATCTACAAAGAAAGGAAACTTGTTAGATCTTGTTTATTCAGATGTGTGTGGTCCCATGGAAGTCGAGTCACTTGGAAGAAATAAAATATTTTGTTACTTATATTGATGATGCTTCACGAAGGGTGTGGGTGTATTTGTTGAAATCCAAAGACCAGGTGTTTCAGACATTCCAGGAGTTCCATGCCATGGTGGAGAGGGAAACTGGGAAACCTCTCAAGTGCCTTCGTAGCGACAACGGCGGCGAATACACATCTCACCAGTTTAGAGAGTATTGTGTAAAACATGGCATACGTCATGAGAAGACAGTTCCTGGAACTCCACAACATAACGGTGTTGCTGAAAGAATGAACCGAACCATCATGGAGAAAGTCAGGTGTATGTTGAGGACTGCAAAGTTATCTAAGCAGTTCTGGGGTGAAGCTGTAAGGACAGCCTGCTATTTGATCAACCGATCTCCATCAGTACCATTAGGTCTTGATGTTCCAGAGAGAGTATGGACTGGTAATGATGTGTCTTACTCTCATCTGAAGGTGTTTGGTTGCAAAGCTTTTGTGCATGTGCCCAAAGAGCAGAGATCGAAGTTAGACTACAAAGCTACACCGTGCATCTTTCTTGGTTATGGCGGTGAAGATTTTGGTTACAGATTATGGGACCCATACCAGAAGAAGTTTATCCGAAGTAGAGACGTGGTCTTTTATGAAGATCAAACAATTGGGGATTCGGATAAAGAGGCACAACCAGATGGCGCAGTCAGAGGAGTTGATCCATTAGTTTCAGATGAAGAAAGTCACGATGACATCCCTGAAGCAACTGCCAATGAAGTGCCTGCAGAATCAGATAATGCTGATCAAGAGGAGCCTGATCAAGATGTGCCAGACCATGAGATTGCTGATCAGGGGGAGCCTAGTCAAGAAGAGCAGATTCAAGGAGAATCCAATCAGGGGGAGCCTCTAGCCCCGCAAGAGAATGAAGATCAGGTCAGAAGATCCAGCAGAAGTCGAAGACCGTCTACCAAGTATTCTTCATCAGAGTATATCATGTTGACTAATTATGGAGAGCCCGAAACTTATGAGGAGGCCAGAGCTCATAACGACAGTGATAAATGGATGAAGGTAACTTGGAGTCATGATCGGAATTCCTCCCTCATGGACTGGAGGGGGAGATTGTTGGTATACGGTCCAGCCCATGATCAATGTTCTAGATTATTCTAGTAAGCAAGAGATGAGGCTGGAGCTTGCTAGACAATTCTAGCATGTTATTAAGTTGATGGAAGAAGCTAGAGAGTACTAGCTTCCTTGGTTGCAAATGGAAAGATCTAGAAGCTACAAGTATGTGGCTAGTCTAGATTTTTCTATACTAGAGGTTTGAAGAAGGAACTAGAAACTAGTAGAATGCCAAGCCCTCACCTATAAATATGGGTGTGATGTAACCAATTGAAAATCAAGAAAGAGTGAGTAGCAAAGGATCAAGTCCAAAGCTAGAGTTCCACTCCAAGAGTGAGAGTGAGAGTGTTCCACTACACATTGTGTGAGTGAAGTTTAGAGTGATAGAAAGTGTGTGTATACTTTCTTGTATCCATCAAGCCTTGTCTTTGGCTTGGTAAGACTACTCTTGTTGTATTCATTTTTTTCATATAGTGAAGATTGATCCTTGTTTGGTGGACGTAGGCATAAATTGCCGAACCACATAAATTCTTGGTGTCCATTTTCTACTTTACCTTGTGCATTCTCTATCTTGTAGTACTGACATTCCTAACAAAAGGAGGATTGATGAATCTGAGAAAGAGGATTGAAAGCAAAAGAGATGAGAAGCTGAATGGAAAACGTCGCTCCAGCTTCCTCTTTGATTCAATCTCGCCCACTGAATAAAAATGAGAGAGACAACGCAAGAAGGAACCGTTACAAACTTCACATGCATTACACACCTCTCATACTCGCAAACCTCTATCCAGTCTAGTAAGGGCTTTGAAGCAGCTTCTAAAACGGACTAAGGGCTCGTTTAAGCATAATAAAAAATTGGGTTTACACCCCCCTTGTGTACCTGGTAAGCCCCTCTTCACATTGGATCTAAGCATATATTCTTAGCTTTTGAAGCATCCGACAAATAAGGAGGATAGGTTTTTTTAGAAGTTTCTGACTCTTCTTCAAATAAATCCATTTTATCGGGATTAAAAATAGGAATTGGTAAAAATCTCAAAGACAACACAAGAAGGAACTGTTGCAAACTTCACATGCATCACACACCTCTCATACTCACATGTCTTGCATGTGTATATCTAAGACAAAGTCCGCTACTATGACAGCTGGCACAATCCGAACCTATGAGCTAGTCTAATCTCAACCATTTAATTTCAATTCAAACAAATAAGGACAAGACTATGGAACTTGAATTCTAAGAAATCAGCTTCAAGGCTTAATCACTAACAATACATACCTGATCAAAAAAGAAAGAAAAAACACAACTTTACAATACATACGGATAAGTAAATACTGTCCACGTACTAACCGCAGGTGAAGAAAGAAATACGCGAAAAAGCAAAAAACTAAATAGAAGAGCTCTCAGAATAAAGAAACCAACTCAAAACACAAAAGAGTGATAAACTCTACCACACAAAATCACCATTTATTCCACCTCCCATGTCCCCAGTCTTACTACATATCAGTGATGATGCGCCAAATACCTCAATCCCCATTACCCCGTGACCCACAGATACAACCCCATATTCTCCCACCTCTCCTTGATGCTGCCACCGCCTTCTCCTTCTCTTCCTCATGGCTCGACTGCTTGAGATAACTCAAAATTGCCTCAACAGCCACCGCCTCCTTTTCCTCGCAGCTTGAGTCCACCGTCACAGTCAACGGTGCGGTGCTCTGATTCTGATCCAAATTCCCAGAAGTGCTGAAACTTTGTCGTTTTGGGTGGGAACCCTTTGATCCATGATTGCTGTCCTGATGTATACTAGTTCCCTCTAGTGTACTCTCTGCCTCAAGGAACTCCAAATCTCGCAGCCTCATCTCTTCCCCATAACTTGACTCCTCATGATCTGTCAAAATTTCTGAACCATCGCTCCAGGGGAGGAGGGATTCCCCATCAGCCACCGCTTCATTTTGCTCATTGTTTGGGACCATGGCAATGATGGCATTAATCATAGGTGCAGTGCTTCGAAACTGAGCCAAATCCGCCAAAGTGATGAATTGTTGTTTAGGGCGGTAACCACGTATACCAGTTCCCCCTATGTGAAGGTTCTTCAAATACCGTAAGTCTTCAGGCAACTTCGAAAGTTCTGAGCACCCATGGAGATTGAGCCATTCGAGACTCAACAAATTGCAGATACTGTCCGGAATATAGACCAGGCTTTTGCACTTTTTCAGATTTAACGACACTAGCCCCTGAAGCCGTTCAATTGATGCAGGAAGCTCTCTGATAGATGTTCGATCCAAATCAAGGCTGGCTAACCTTTCCATATTTTCTAATATGTCTGGAAACACCTCAAACTTTGTACAACCAGAAAGAGAGAGATAATTTAGGGACTTGAGTTGACAAATGTTGCTTGTAAGACTCTTAAAGTCTTTGCTATACCGTAGCGTCAAAGTAGCAAGTCCCGTAAGACTATAAATTATGGATGGCAATTCTTCAATTGCAATCCCTGAAAACTCAACAATTTTTCGGCGGCGAGAGGCTTGCTCACGTTCAAGCTCTGTAAGATTTTTGAATGTTGATGAATCTTCTGTAAATATAGTCCAATCGAAATTAAGCTCTGTTAGGTTCTCCATACCTTCTAGAAACTCTGGAAAATTCTTCAGATTTGAGCAGCCAGAAACATTCAGGACTTGAAGAGATCTCATATGAATGCTGCCTGGAAAAATCTTTAATCTTCTGCAATCCTTCAGGCTCAGGGTAACGAGTCCTGTAAAATTTTTTATGGACGAGGGCAGTTCTGAAATTGCAGTCTCATCTAAATTAAGCTCTAATAGGTTCATAACTTCAGGAATTTCTGAAAAATTATCCAGATTTGAGCAGCCGGAAAGATTAAGGGTTTGAAGAGATCTCATGTGAATGCTGCTTGGAAGGCTATGAAGTTTCTTGCACTGCTTTAGACTCAAACTCTCAAGGTTTTCAAGAGAATAAATTGATGGGCAAAGGTCTTCAACAGATGTCTCATCCAAGCGAAGCTCTCTTAATCCTTCCATATTTCCGCCATTTTCTGGAAAGGCTTTGAGCTTTGAACAACCAGAAAGATTAAGAAATTGCAGGGACTTGAGTTGAACAATGCTGTTTGGAAGAATCTCAAGTTCTCTGCAATATTCAAGATTCAAAGTAACAAGCCCCGTAAGATTGTTAATTGATCGAGGCAGTTCTTTTATTGCAGTCCCTTGCAAATAAAGCTTTGAAAGCTTCTCCATAATTTCTGAAATCTCTGGAAACTTCTCAAGTATTGAGCAAAAAGAGAGATCAAGGGTTTCAAGAGATTTCATACAAATGGTGCTTGAAAAGGTCTTGAGTTTGCCGCACCAACTTAGATCCAAGAGGACAAGTTTTTCAAGGGCAGAAATGGATGGGTGAACCTCATATAAACTTTGTGCATCCACCAAGAATTAGGTTCTCAAGATTCTTTGCCTCAGTGAAGTCAGGTGTTTCCTTAAGACGATAAGAGCCTTTTAAGTTGATAATTTTCAACTTTTCCAGAGGCTGTCAATATACAACAAGGAAAATATGTGTTACCTACATAATAAGGCATTTAAAAACTAAACAATTTAAAAGCAGTATATAGGCAAATGATGAACGTACCTGAGTTCCTTTCCAGAGGTGTTCAACCCAACTATATTGCATGTCAATGTCAACAAGATTCTCTGGGTTAAAATTGGACGATAAAGACTTTAGAGGACATTTGTGCCAGAACAAATAACTTAATTTTTCAGAGAGAAACTTTAGATCCTTGTATTTCCATTCATCATCGGATTCCCTGCCCGGTGGTTGTAAATAGTGGGTATGGACTCTGAGTAGTCTTAGTTTTATCATTTTAAAAAAAGCGGTGTCTAATTCCACCACATTGTTTGAGTATGGCCAACGCACAATTATGCTTTCAACTGCTTCTGTAGCCTGGATAACCAAAATTGCAAATTGAATGAGTACAAAACTTAAGATTATAACTTCTAAATGCACATGTTTCTCATTAATTGGATTTTGGTCAAAGTTGAAGCTTTATACTTTTTATTAATATTAATAATAATAATATTATTATTAACATTATTATTATTATTATTATTATTATTATAATTATTACTATTATTAAATTTACTAATATTAATGTGAGAGAGAAGATTCAAAGCAATTACATTAATGGAAGGGAGGGAGTGCGTTTCTCACCGTTTCTCGACTTAACACATGATGAACATCTTCATAGCTCCACAACCTACTGCGCCTCCCAGGCTCTTTTATAGATTCCTGGCGTACGATTTCGCGACCCATTTCCTCTAGTAAATCATGCATCTCGAGTACACCATCAGATGAGACAGTGACAAGAGCTCTACCAACTAGAACGTCTAATCCGGTATGGGGATGGAAGTCACAACCCTCCATAATCCTTGTTGCAAAGTCTTTCTTCATTTGTTTAAAGAAACATGCAATATCAAGAAATATTTCCTTCTGCAAACCATCTAGTCCATCAAAGCTTGTTCTAAGGACTGTCTGGATTCCCAGGTGCGGATTTCTCGCTATTTTCTTTAACTCATCTTTCCACACAAGTACACTTTTGTTATCGAGGAATGCTCCCAAGACTTTGAGTGCTAAAGGCAAACCTTGAGCATATTTTATGAAATGGCCTGACAAATCAACGTATTCTTCTGTGGGTTGCTTTGTACTGAAAGCATACTGCATAAACAGCTCGAGAGCATCATCGTCATTTAACAACTCGGGCTCATATATCTGATCACCAAGTCTACTTAGTGACTGTTTCTCTCTAGTTGTTATAATGATTCGACTTCCGCCACCAAATGAAGGTTGCTTTCCAATTAAGGCTTCAATTTGGGATGAACTCTCCACATTATCAAGAACAAGTAAAACCTTTTTCCTACCAACTCTTTCCATCATCTTCTGAAAACCATTTCTCAAAATCTCTGAACTCCCCACCTTCATAT
->URS0000222F4A rRNA from 1 species 
-ACGGGGTGCAGCAGGCGCGAAAACTTCACACTGCGCGAAAGCGCGATGAGGGAATCCCAAGTGCTTGCACGTAAGTGTAAGCTGTTTCTATGTCTAAAACGCATAGAGAGTAAGAGCTGGGTAAGACGGGTGCCAGCCGCCGCGGTAATACCTGCAGCTCAAGTGGTGGCCGTTATTATTGGGCCTAAAACGTCCGTAGCCGGTTTATTAAATGCCTGGGTAAATCGGGCCGCTTAACGGTTCGAATTCCGGGTAGACTGATAGACTTGGGACCGGGAGAGGCTAGAGGTACTCCTGGGGTAGAGGTGAAATTCTGTAATCCTAGGGGGACCACCAGTGGCGAAGGCGTCTAGCTAGAACGGGTCTGACGGTGAGGGACGAGGCCCTGGGGCGCAAACCGGATTAGATACCCGGGTAGTCCAGGGTGTAAACGCTGCTTGCTTGATGTTAGTCGGGCTCCGAGCCCGATTAGTGTCGGAGAGAAGTTGTTAAGCAAGCTGCCTGGGAAGTACGGCCGCAAGACTGAAACTTAAAGGAATTGGCGGGGGAGCAC
->URS0000E1B154 rRNA from 1 species 
-TGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGAGTGATGAAGGCCCTAGGGTTGTAAAGCTCTTTCAACGGTGAAGATAATGACAGTAACCGTAGAAGAAGCCCCGGCTAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGGGGCTAGCGTTGTCCGGAATTACTGGGCGTAAAGCGCACGTAGGCGGATATTTAAGTCAGAGGTGAAATCCCGGAGCTCAACTTCGGAACTGCCTTTGATACTGGGTATCTTGAGTATGGAAGAGGTAAGTGGAATTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAGGAACACCAGTGGCGAAGGCGGCTTACTGGTCCATTACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACA
->URS00022EEFAF misc_RNA from 1 species 
-TGGCTCTCCCATCGATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACCTTGCGCCCTCTGGTATTCCGGAGGGCATGCCTGTTTGAGTGTCATTAAATTCTCAACTTCAAAAGTTTTTATTGAATTTTTGAAGCTTGGATGTTGGGGGCTTGCTGGCGTCTTTAGATGTTCGGCTCCCCTTAAAGTTATTAGTGGGAATGTCTTTTATTAGGCAATCCTTGGTGTGATAATTATCTACACTTTGGATGGTTTAATGGTTCCAATGAGGCTATTGGTATTGCAATTAAGTTTGCTGTACCTTGGGTCTTAGGGGAAAAGATAAGTCTTGCTTTCTAACCGTCTGTGTTACATGGACAATTTATTGACTATTTGACCTCAAATCAGGTAGGACTACCCGCTGA
->URS00001F1239 rRNA from 1 species 
-TAAAGGTATTCCGGTAGACGATGGGGATGCGTTCCATTAGATAGTAGGCGGGGTAACGGCCCACCTAGTCTTCGATGGATAGGGGTTCTGAGAGGAAGGTCCCCCACATTGGAACTGAGACACGGTCCAAACTCCTACGGGAGGCAGCAGTGAGGAACATTGGTCAATGGGCGAGAGCCTGAACCAGCCAAGTAGCGTGAAGGATGACTGCCCTATGGGTTGTAAACTTCTTTTATAAAGGAATAAAGTCGGGTATGGATACCCGTTTGCATGTACTTTATGAATAAGGATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATCCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGAGCGTAGATGGATGTTTAAGTCAGTTGTGAAAGTTTGCGGCTCAACCGTAAAATTGCAGTTGATACTGGATATCTTGAGTGCAGTTGAGGCAGGCGGAATTCGTGGTGTAGCGGTGAAATGCTTAGATATCACGAGGAACTCCGATTGCGAAGGCAGCCTGCTAAGCTGCAACTGACATTGAGGCTCGAAAGTGTGGGTATCAAACAGGATTAGATACCCTGGTAGTCCACACGGTAAACGATGAATACTCGCTGTTTGCGATATACGGCAA
->URS000107D7B1 rRNA from 1 species 
-TACGTAGGGGGCTAGCGTTGTCCGGAATCATTGGGCGTAAAGAGCGTGTAGGCGGCCCGGTAAGTCCGCTGTAAAAGTCAAAGGCTCAACCTTTGAATGTCAGTGGATACTGCCGGGCTAGAGTCCGGAAGAGGCGAGTGGAACTCCTGGTGTAGCGGTGGAATGCGCAGATATCAGGAAGAACACCGATGGCGAAGGCAGGTCTCTGGGCCATAACTGACGCTGAGAAGCGAAAGCATGGGGAGCGAACAGG
->URS0001943432 rRNA from 1 species 
-GTGAGGAATATTGGTCAATGGGCGAGAGCCTGAACCAGCCAAGTAGCGTGCAGGATGACGGCCCTATGGGTTGTAAACTGCTTTTACACGGGGATAAAGTGTGCGACGTGTCGTTCATTGCAGGTACCGTGCGAATAAGGACCGGCTAATTCCGTGCCAGCAGCCGCGGTAATACGGAAGGTCCGGGCGTTCTCCGGATTTATTGGGTTTAAAGGGAGCGTAGGCCGTCTGTTAAGCGTGTTGTGAAATGTAGATGCTCAACATCTGAATTGCAGCGCGAACTGATAGACTTGAGTGCGCAGGAAGTAGGCGGAATTCGTGGTGTAGCGGTGAAATGCTTAGATATCACGAAGAACACCGATTGCGTAGGCAGCTCACCAGACCACAACTGACGCTGAGGCACGAAGGTGCGGGGATCAAACAGGATTAGAAACCCTTGTAGTCC
->URS00007057CD snRNA from 1 species 
-AAAATGAGGGCAATCTGGTTGCGACATCTGTCACCCCACTGATCACCAGAGTTGATTCGGCTGATTTGGCTGGCTAGGCGGGTGTCCCCTTCCTCCCTCACTGTTCCATATGCGTCTCTCCTGAAGCTGCATGATTGGTTGAAGAGGACAACATCCCAGGTATAGAAGGAGTGTACTGAGGTCTCCAGTCTTCGATCCCAGATATACTATAGCTGCACTCCCCTGCTAGAACCTCCAAACAAGCTCAAGGCCCATATCAAAGTCCATAATGGTGGCCCCTAAGTTTGTCCTCAACTTATACATGTGGTGGACTTATA
->URS0000B96F2F misc_RNA from 1 species 
-TTGTTATAAATAATAAGCAGAAGAAAAATATATTGTTTACCTAGTTTACTTTTAAACGATGAGAATTGCAAAATTTGGATAAAATTGTGAGATTTGAATTGCAAATCATCAATTTGCTTATGATTTTGATCAATTTCAATTTGCTTATGATTTTGATCAATTTCAATTTGCTTGGTTTGAATTGATTGAGACTTGATTTGGTTCAATTTTAATTGTGAACTTTACAATTCTTGTAACTGTGCCATGTCAATATGTGGATCTCTCTTTGCTGAGCCCTTCTATGCGGCTATGCTAGAGTATGCTAGAGTTTCATCATCATAAAGGTGTGATACTTGGGATAAAAACTACACTTGATACCTGCACGTTAGTCGAGTAACATATATCACCTTTTGACAAAGCTTGTTGTTTCTTTATGTGAAACAAGAAAATGGAGTGGCTGAAGCTCTTTTAGTGGGTGCCACTGCTTCACCCTAAATTAAGTGATTAGCTTTTTCCATTATATCCTATATATCAGTAGCTTTATGTCTTCAGAATCTATTCCCAACATTTGATGTTGTTTTGAGTTTAGAATAGGGGATGGAAAACTATGTGCCGCTTGTTGCTTGTCGCTTGATGTAACAAACTATAAGGTTAAGTGTTCTCAAATCTCAATTTATTGGATTCCATGGCTTATGTTGCTAGGCATTGGCATGAATGGAAAGCGGTCTTTGTACCATAATACATATGGGTACTCCCAATATACATATAGCCCCTTTGGGACTGGTGACTGGTCATATTATATGGTCTTCATGTTCCCCTTGTCATCATTACTGGAAGTCTGGAATGAATGCACAAGCAATGCAATTCTAAGATCAAAATTCTGTCCTTTTTTTCTTTAGTAATAAGTTGACTTAAGTGAAGCCAATTTATTTTTCTCAGTATAATTTTTTGAACTTGGTTAATTTTGCAAATGAGCCCATTGCCACCAATCATTATTCACTATTGGTGTAGAGATTATTGCACATGCTTGATTATCTTGATTTTTTTCTCAAGTGCAAGTGCTTTGGATTCTTTCCTATTAACAGCTTTTCATCATGGATGAAAGAGAATTTCTCTGTTTTTTATTTGATGCATTGTGCCTGTCTTTCTTCTTCTTTTTTAAACTGAGCCAATCTGTATGCATTCGAAAATTGTATTGTAGGCTATAAAATGGAGAATTTTCACATGCTAACTTGCAACATGTGTTTTTATTAAGCGCTGCCAGCTAAATTATGATCTTGCATAAATTTTGTCCTTGTTTATGACATCATATGGCCATTAATTTTTTTTTCTTTTATAATTAACCCTGTTTTTGTCAATAATCTTTTTAGACGGTCTCTCCTATGTGGTCGTTGGTGGTTTTTCTTTCTTTTTAAAGCAGCTTTGAAGTTTTCAGGGATTCTTTGATTTATATCTTAAAGTATCCATATTCTATCTATCCTAATCTATGCTTTGAACAAGTTATGCCATCCAATACTGTCATTACAGGCAAAGTGGAGGCAAGAAGTGA
->URS0000D729CC rRNA from 1 species 
-GGATGCGATCATACCAGCACTAAAGCACCGGATCCCATCAGAACTCCGAAGTTAAGCGTGCTTGGGCGAGAGTAGTACTAGGATNNNNNNNN
->URS00003FE27D rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGAGGTCCACCGCGTAGCAATACAAGGGAAGACCTAGTGGCGAACGGGTGCGTAACACGTGAGGAACTTGTCCCGGTCTCTGGGATAACAGTTGGAAACGACTGCTAATACCAGATGACGTCGGAATCTCGCATGGGATACTGACGAAAGGGTTACTGGATCGGGAGAGCCTCGCGGCCTATCAGCTTGTTGGTGAGGTAACGGCTCACCAAGGCGTCGACGGGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATCTTGCGCAATGGGCGAAAGCCTGACGCAGCAACGCCGCGTGCGGGAAGAAGGCCCTCGGGTTGTAAACCGCATTCAGTAGGACGAAAATGACGGTACCTGCAGAAGAAGGTGCGGCCAACTACGTGCCAGCAGACGCGGTAAAGTAGTCGTGT
->URS00023E9193 lncRNA from 1 species 
-CAATGTTGGAAACGAAGTTGGATTTGCTCCTAACATCCAGGTTAACCATAGTTCTTGCGGCTTCTCCGGCATTGCACCACCGCCTCCAAACAGACCCCAGTTATGGATCTTGTGATTACCCATCTTCCACAAGGAACAGAAACATTTGGTCAAGTTTCTTGCTCTGCATCTGCGATTACGTCAGCAATGTTTAAGTTATCCTTTCTCAGTGCAGGGAATAAAAAAAAAAACAAAAAGTCCAAACAATTCAGTCGAAGAATACTCGCAGAGAGAGAGACCTAATGGAGGAAGGGCTCAACGGAAAGGAGTACTTGCTCAAGGTGGTGCTGATAGGCGACTGAGATCTGGGACACCGCCAGCCAAGAACGCTTCAGGGCCGTCACCTCTGCTCACTCTCTCTCAAAGCCCTAATCTTTAACCATCGGCCGTCACCTCTGCTCACTCTCTCTCAAAGCCCTAATCTTTAACCCTAAAAAATCCCCAAATCTCTTCATCTCCTTTCCCCCGCACGTACAACGATGGCTCTAATGAGACCCTAATCCGGAAACCAACCCCC
->URS0000805F26 rRNA from 1 species 
-AATAGATACCCCGGTAGTCCATGCCGTAAACGATGAGTACTAGCTGTCTGGGGTATCGACTCCCTGGGTAGCGCAGCAAACGCGATAAGTACTCCGCCTGGGGACTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCAGCGGAGCGTGCGGTTTAATTCGAAGCTACGCGAAGAACCTTACCAGGGCTCGACATGTCCCTGACCGCCGATGAAAGTCGGTTTCCCTTCGGGGCAGGGTCACAGATGCTGCATGGCTGTCGTCAGCTCGTGCCGTGAGGTGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGTCGTGTGTTGAATTTTTCACACGAGACTGCCCGGAGCAACCGGGAGGAAGGCGGGGATGACGTCAAGTCAGCATGGCTCTTACGTCCTGGGCTACTCGCACGCTACAATGGGCAGTACAGACCGTTGCGATATCGCGAGATGGAGCTAATCGGACAAAGCTGTCCTCAGTACGGATTGCAGGCTGC
->URS0000ACA7F0 rRNA from 1 species 
-AATGAACACTGGCGGTAGGCTTAACACATGCAAGTCAGACAGAAACGATGAAGTGCTTGCACTTCAGGCGTCAAGTGGCGGACGGGTGAGTAACACATGGGAATCTACCTATAGTTGGGGACAACATATGGAAACATATGCTAATACCGAATGTGCTCTAAGGAGTAAAGGAGCCCTCTCTTGAAAGGTTTCGCTATAGGATGAGCCCGCGTGAGATTAGCTAGTTAAGGTAATGGCTTACAAGGCAACGATCTCTAGCTGGTTTGAGAGGATGATCAGCCACACTGGGACTGAGACACAGCCCAGACTCCTACAGGAGGCAGCAGTGGGGAATATTGCACAATGAGCGAAAGCTTGATGCAGCCATACCGCATGTGTGAAGAAGGCCCGAGGGTTGT
->URS00012146AA rRNA from 1 species 
-CCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGACGAGAGTCTGAACCAGCCAAGTAGCGTGAAGGATGACTGCCCTATGGGTTGTAAACTTCTTTTATATGGGAATAAAATGTTCCACGTGTGGGATTTTGTATGTACCATATGAATAAGGATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATCCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGAGCGTAGGGGGATTGTTAAGTCAGTTGTGAAAGTTTGCGGCTCAACCGTAAAATTGCAGTTGAAACTGGCAGTCTTGAGTACAGTAGAGGTGGGCGGAATTCGTGGTGTAGCGGTGAAATGCTGAGATATCACGAAGAACTCCGATTGCGAAGGCAGTTCACTGGACTGCAACTGACACTGAGGCTCGAAAGTGTGGGTATCAAACAGGATTAGATACCCGAGTAGTC
->URS0000767CA2 rRNA from 1 species 
-GATGAACGCTGGCGGCATGCTTAACACATGCAAGTCGGACGGGAAGTGGTGTTTCCAGTGGCGGACGGGTGAGTAACGCGTAAGAACCTGCCCTTGGGAGGGGAACAACAACTGGAAACGGTTGCTAATACCCCGTAGGCTGAGGAGCAAAAGGAGGAATCCGCCCGAGGAGGGGCTTGCGTCTGATTAGCTAGTTGGTGAGGTAATAGCTTACCAAGGCGATGATCAGTAGCTGGTCCGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTCCGCAATGGGCGAAAGCCTGACGGAGCAATGCCGCGTGGAGGTAGAAGGCCCACGGGTCGTGAACTTCTTTTCTCGGAGAAGAAACAATGACGGTATCTGAGGAATAAGCATCGGCTAACTCTGTGCCAGCAGCCGCGGTAAGACAGAGGATGCAAGCGTTATCCGGAATGATTGGGCGTAAAGCGTCTGTAGGTGGCTTTTCAAGTCCGCCGTCAAATCCCAGGGCTCAACCCTGGACAGGCGGTGGAAACTACCAAGCTGGAGTACGGTAGGGGCAGAGGGAATTTCCGGTGGAGCGATGAAATGCGTAGAGATCGGAAAGAACACCAACGGCGAAAGCACTCTGCTGGGCCGACACTGACACTGAGAGACGAAAGCTAGGGGAGCAAATGGGATTAGATACCCCAGTAGTCCTAGCCGTAAACGATGGATACTAGGCGCTGTGCGTATCGACCCGTGCAGTGCTGTAGCTAACGCGTTAAGTATCCCGCCTGGGGAGTACGTTCGCAAGAATGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAAAGCGAAGAACCTTACCAGGGCTTGACATGCCGTGAATCCTCTTGAAAGAGAGGGGTGCCTTCGGGAACGCGGACACAGGTGGTGCATGGCTGTCGTCAGCTCGTGCCGTAAGGTGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGTGTTTAGTTGCCACCATTGAGTTTGGAACCCTGAACAGACTGCCGGTGATAAGCCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGCCCCTTATGCCCTGGGCGACACACGTGCTACAATGGCCGAGACAAAGGGTCGCGATCCCGCGAGGGTGAGCTAACCCCAAAAACCCGTCCTCAGTTCGGATTGCAGGCTGCAACTCGCCTGCATGAAGCCGGAATCGCTAGTAATCGCCGGTCAGCCATACGGCGGTGAATTCGTTCCCGGGCCT
->URS0000BE21C0 hammerhead_ribozyme from 1 species 
-GTACTGCTGACGAGTCCAAAACAGGACGAAACAGCTGTGCAGTGC
->URS00023CDC16 lncRNA from 1 species 
-GAGATGATTCTACTTTTCAGCTGGAGAACTTAGCAATAAGTTGTGGTAAGGAGATAAAAATTCCTAAGCAATGGCTACTTCAATTAGATAATCTGGAAAGCTTGTCACTGCATCGCTGTTGGTCAGATGAGCTGAAATCTCTACGTTTCCAGAGATTGAAGAAACTCACACTTGGTCAACTTAGTTGCTTCACTGTTTTCTCATTCCCAGACTTTGAAAGACTTCAACAGCTCAGAGAATTACGAATAGCACATTGTGATTCATTGGAACATATCGTGGAGGTTGTTAATGGTGAAGAAGCTTCTGGCATGGATACGGAGACTGCTGCACTAGTTCAGCTGGTAAAAGTCTATCTTGAGGGTTTGCCAAAACTCAGAAGTTTTACACACACAAAGTCTAAGAATCTTATGGCCAGTTTAGAGCAGGTGGAAGTGGAGCCCTCGATTCTTTTCAGGTGCCCTGTCGTTGGAAATCTCCAACAGCTCAGATGGTTAGACGTGACTGATTGCAGATTGTTGGAAGGCATTGTGGAGGTTGCAAGAGGCTATCAGACTTCTCACAGGAATGACCACATTATCACATTCCCTCAGCTCTATTCCATTAAACTTAGAAATTTGCCCAACCTCCAAAATTTCAGTCCCACTAAAAGCTATAGTTTCAAGATGCCCAAATTAACAGGTTTCGGTCTGTTCTATTGTCCCCGGATGGAGAATAAACCCTTCATGCAAATAATCGCAGAAAGGGTACATTTTTCTTCCGAGGAGCGTCGACGACTGATAATAGTTGAAAACCTCAAGGACTACACACTTAGAAAAATAAACAAGCTCGAAAGCGTGGGGGAATCAAGTAACAGCAATCAGGATGTGGAAACAGAAACAATGAGAGTTGAACAAGCGGAAGCCATAGTTGTTCAACAACGGGAAGAGGGAGTTGGTGCAGAAGAAGACGACTTTTTCTTCTTAAGAAAGTCTCAGACTTCATTGTTTTTCATTTTGTTTTTGTTTTTGGTTTTGGTTTTGTGTTTGAAGGAGGTCTGAGCGTCTGACACTGAATTGTAAGTTGTGAAAAGCGACAACTGAGGATGCGGGCTGATTGGAGGCCCAGTTCCAGTAATACAATTTCAGGTCCAATATCTATGGCCTGCATAATTTTTAAGAGTTAAGTTCCATGTAGTATATTTATGTAGTACTGTAGGCCACGTATATTCTGCAACTATAAAATGACATAAAAACATTGCAAAATATATGAAACTTGTTATTTTGTGAAATACATTCTATAAATATCACTATTTCATGAAAAATATTGAAAATCATTTATGTTCGACAAGTATAACACATATGTTCAGTAATATGTAAATATGTTCTGCAAACCTAACATGTGTTGCAGAATAATGTGTTTTTCACTATTTAACTTGTGGAATGTTTAAGATTGTCAAAAATTTTAACAAAATAATGATATTTATAGAACATGATTTGCAAAATAACACAGTTTGCAATGTTTTTATGTCATTTTATAGTTGCAGAACATACGTGGTCTACGGTACTACAGTAAATATGTGGATTACATGGAACTTTGTTCTAATTTTTAATGTATATATTAATTTCAAAGCACTTCATCCAAATTATGTATACACACAATATATATTACATTTTATTATTTATTTTATTGATCTGTTAATTAGAACCTATAACCTAGACTGCAATCGTCAACCTTCAATTTTGATTATTTTTCTGCCAAAAAAATAAATTTTATCAAGTTCAAAATTTGTCAACTTTTATCATGGCGATACTAAATACTCCCTCCGTCCCAAATTAATTGTCCAGTTTGACTTTTTGATGGTCAATTTGACCCAACTTTGATTGGAAATTAAAAATTATCCTTTTACAATTTTACAAAACTGAAAAATATATTCAAAAATAGATTTGATAATCTTTTCAATGATATATATTTCATAATTTTATTCAATTATTTAATATACATATTTTTCAGTCAAAGTTGAGTCAAATTGACCATCGAAAAGTCAAACTGGACAGTTAATTTGGGACGGAGGGAGTAGATATTAAGCAGTTTCTTGATTTGATTATGCCTATAAATTATTTGTTTTTTCATTTAATGATTCCTTCCGTTAATTAGAGGCTTTAATTTAGAATGTATTATTAAATTTTTATTTCTCAAATATTTCTTAAATAAACAATTGAATAATGTTTTTTTTGAGAGAATTGAATAATGTTATGTATCCCAAATTTTATTCTCAAAATTTTTATCAAGTGGAGAAGAACCAATCAAACAGAATTTGGAAACACTTTTTCAAATACCTAATATTTTCCAGTTTCAAAAAAAATACCTAATATTTCCTAAATAATTTATGGGCCAATATACCTCTTTTTAACATTTTTATTGCAATAATACAATTTTCTCCCAAAAATTGCATATTTACTTTTTTTTTTTAAAAAAGCTACAAAGTATTTGCATATATACGACTATGACTATGAACTGCTTCCTGGAGTAAGTGAGAGAGAGAAACAAGCGAACCCGTTCTTTGTTCTTGCCTCACCCTTCCTCCTCTGTGGCTCATTTTGATCTGTCTCTCTCTTTAATTCCCTCTCTCTTCTGCCTCCATCTCTCCTCGCTCTCTCTATCTTTTTCTTCGATCCATTGATTATGTCAGCCGTACATTCTCCGATCACGAAGCCCTAGGTACTCATAGGGAGTACAATCTTAGTGGTGTTCTTGATGATTGTTGGATCGGTGATTATAGCGGATACACACAAGATGACTTTAAAAGAAGGGAGAAACGTCGAAGTAGAAACTCCTAAACATGGCTGCTGATGTTGATTTTATGTGAATATATTTTTGTTTTTTGTTATGCTTCATCTCTGTAGAAGTTTTGGTTAGCGCTGGTTACTTGTGGTTGCAAAACTTGTTGATTCTTTTGGCCCCGCAGGGGCATTTATTTTTCTGTCTTTGCAACTAGTTGCAACTTATTATGCAACCTAATATAATTTTAGCATTTTTTAAAAAAAAAGTTACATATGTAGTTGAAAGTATGGTTGCTCGCAGTTGCAGATTTGGTTACATATGCAAAATCGTATTTTTGCAAAAAAAAATTGAATGATAGAGTTTTTTTTATTTTAAAAAATGATAGTATTTTTGCAAAATTTCTTTTTGACTTGGGTATTTATTAAAAAAACCCATAATTTATTCCTATAAATAAAGAATGTCAAACACATAAATATTTAATTCTCAGGTAGCAAAGAAAGGTTACTCGCAATTATTTAGGAGCCCAAACTAAACCAAGGCACAATTGACAATACCAAACAGCAAAGAACACGCTCCCAAACATAAAAGCGCAAAGGAGCAAATAGCAATTCAAGATCATATTGTACTCCAACCATTGACTAGCTAGTCAGACAAAAACTATCTAAACTTCAACCAATATACAGTATACTTGGGACATAAACATCCACTTAACAAGATCAAAAAGGTCCTGGTTGATATTACTCCTCTTTCTCGACTCTCGAGGAAGTTGGGGTTCGAGTTAGGGTGATTCCATGTTTCCATTGTTGTTACTCCATTAACCATTGATGCAAAGCTGAAGCTGTGGTATTGCTGAATTTATTACATTAAATACTAGTCAGTATTTACTGTATGCCTTAACATGGCTTGATGCAATCAAATAAACGAAATCCTTGCAACACAAACGAATTCAGTGATACAAAACCATAGCTACTAATATATGGGCAAGGCAGACAAAAATAGATGCTACAAACAGTTGGAATACGTCGGTTCTTTATGAACTACCTAAACCAATGACTAATTGTGCAGTCGCATAAAAACTGAAACCGCGTCATTCAAACACAACTGGTGCCAACTCCTACCAGAGATAAAACATGATATATCTATATTAATGAGCTCATGATGCAACTATTTAGTAGTTCCCGAGCTATATTGTTTTGAGATGCACAATATTATTGTAAGAGCTTAGCTGGATTTCATAAAGATCTGCACGTTGAGCCACAGTACAACTTACCAAGCTCTCAATTTCTTCGTGCAATGCTGATTAGCCCAAGGATGTTCTTTCAAATTTTTTAAACCATCTAGTTTCACTGATGAATGATGATAGAATATGGAAACAACTTCTTGTATTGGTTTGGGCCGAAGCCCAGGATCGCTGTACCTGATCCAGATCTTATTAGAGAGGTTTTGATGAATTCCTTAGGCCGAGTTGTTGCTTGGAGATGGACTTGTTGGATATATTGACCGGTGAGAAATGGCCTGTTCTGTATTCTTTTTTAAGATTGCATAGTGGCTTGTTTTTATGGTGTGTGTGTGTGTGAGAAGTGTGTGTTCTGTTTTAATGTCAACACTCCTAAAGTACCAGAGCCCAGGTTAGAATTCAGTACTTAGTTCAGGGAGATGGATTTCCAGACTCTGGAGCTAAATGACAATCAGCTAGGCAGTTTCTGAAACAGTTTCCTGTAGTTCTAATCTAGTTATGTGGCATAGAGGGCAACTATTGCCTGTGATCTCACTTGATCACAAGTCTATTTTAAGAAGGGGAGCTATGTTATATTTTCATTTATATTTTATGTATGTCATGTCAACTCTTACAATTTTGCTGGATAATTAATTAAGTACTCCCTCCGTCCTTTTTTACATGTCCATTTTGATTTTTGACCAGTCAAATTAACTATATTTTGACTGAACTTTACACGTATTAGATAATTGGAAAAATTAATAAAAATTATATTACTAGAAAGTATATTTAATCTATTTTAATATGCAACTTTCAGATTATAAAAATAACGAGTAGATAATTTGTAATGTTTAGTCAAAAATTGGTGAATTTGGCTTCTCGAAAAGCAAAATAGACATGTAAAAGGGGACGGAGGGAGTATTTATTTGCATCTCGGTTTAGTTGGATCGCCATCAATAGAATTTATTTTATACTTCTTCCGTTTCAAAGTAAGTGCCGTTTTAATTTTTGTCACGTGACTTGAGGTGGAATATTTATTTCGTTTACCAAAGACTTTGACCTTTCACCCATGCATACCGGGTAGTTGTTGTTGACCGTTCTTATAAAAAATAAAATATCAACATTGTCACCTCTATTTTTGATTTTTTTATTTATTTCTGACCTATGATCGGTATCTTAGTATTTTAAATTTCACGTGTATCATTGTATCTTATTTGCAATTTAAATAAATAAATTAGTTAATTATTGAAACCTCATTTTTTTTTGCACTTTGGACATCTATAATGATTTACTACTTAAAAGTTGCAATCATAAACTATTTGAATAAATTGAATTTTAAAAATCCAGAAAGTATTTTAAAGAATATTCTTCATTATACTTTGTACTATCAATTTTTTTAGTAAACTTTTTATGTGATATCCTTACCATTGAAGTATGACTAATATTAATTAGTATATTAAATTTGAAATACAATAATATCACCGAAAAATTTAATGAATAAAAAATGATAAGAAAGTCAGAGGCAGAAGGAGTTTTCTTTAAGAAAATTTAATCCTCTTGTGCATGACTTTAAATCTTCATATATCACGTAAATTCGACATGTTTGAGCGACACAAATAACATGCATCGAGCACGATTGGATAGCTCAAGTGGTGGGTTTATCCTCTGTTGTCCCGGAGACCCGAGTTCGACTCTGCCTCATCCGAACAGTATTAGAACGGATACTCATTTGTAAGGCATATAAGATTCTATTATCAAAAAAAGTAAAAAATAAAAAAAATTAACATGCATCATTGCCAGTCGCCCTGAGTGAGGGATGCGGTTGTTATTCTTTGTGAATCATATACGTAAGCTTTTAGTTTCTTCTTTGTCAAATTGATTTCAGTTTTTCTTAATGTTATTGATTTTCTTTTTATTGTTTTGATTTTTTCAATATGTTAAATGAGTTCTCTACTTCTCTTGCCTTTTTATCATGTTAAAATGATTTTTTCAATATATTAAAATGAGTTCTCTTGTGCACTTTAGCGTCGGTTAGAAAAACCGACGCAATAGAGACTACTCTATAGCGTCGGGTTCATATACTGCGCTGGACTGCCGACGCTAAAGGTCTTATTTGACTTAGGCATTTTTGTACTAGTGTAAAATAATAAAAAGTAAAATGATTATTCTACTTTCCTCAGCTTTCCACAAATGGGGACATTTTTTTAGTAATACGAAAAACTCATTTCCAAATATATATATTTCAAATGGACATAATATCGGTTGTCATTTTAAATTTTCTAACTTATTCAAACAATATAATATTCGTGAAAATAGTATACTAGCATTTGGATTGTCATTTGAGATTTTAAATTAAGATTAAATTCCTCATTTCTTACCTAACATATCATGCATCTGGCTAAATATATAATTTGGAACAAACTGTAATTTCCAAATAAGTACTAGAATTTCTTTCTTTATTTTCTTTCCAAACTTTTATCGATGATTTTGTCTGCCCTCTCCGTCAAATTGATTTCTTTCTTTCCTTTTATCTCAGGTTAAAGATTGACCTTCTCATGTGAAATACTTACAGTATGTTACTATGTTAGTATTGAACTGATTTCGTAACAAGTGAAATTTCTTTTTGTGTTTACAATAATATTTGATAATTTAGCACTGAGAAAATGTTTTATCACATGTGGTGATAGGACTCGTATTAAAATATTAAATTAAATATCTGAAAGTAACTTGTCCAAAAGTCAATCTTTCTATAGGCCAATCAAATACAAACAAGTGACACCGACTATATGTGCTTGTTGGTGACAGTCTTTCTGTGATAATTACACCTTTCCTACTACCATTAGTCACATTGACGACTATATATGAAGGTATCAGAGATGACTGTTGAATGGAGGTTGTTTTTTTTTCATAGCAAAAGACGTTAGAGCAAATCCAATGCAAGATGTAAAATAGTTATAGATATTGTTATAAATTAGTATTAAAAAGTGTTTTTCATTGTTGAAATAGAACTTCAACTCCAATGCTAGATGCATTTTGCATCCAAATAATTCCAAATTTAAGTAACTTTAGTCCCTCTCTCTTAAATTTTATTTAAAGTTCACCATTATATATACCAATTATAGTTAATTGATGATGTGTCATGGATGCATAAATGCATATTTGGTTTCAAATTTAGAATTAAAAAGTGTTTTTCATTGTTGAAATAGAACTTCAACTCCAATGCTAGATGCATTTTGCATCCAAATAATTCCAAATTTAAGTAACTTTAGTCCCTCTCTCTTAAATTTTATTTAAAGTTCACCATTATATATACCAATTATAGTTAATTGATGATGTGTCATGGATGCATAAATGCATATTTGGTTTCAAATTTAGAACCAAAGATGCATAAATACATATTTGGTACGAGTAAAGGCCGTTTGACGTGATTTAAAAATAATGTTTATTACTTATAAATGAGAAGTTAATTATAAGTAAAAAGTAACTTTTATCTTATGAGTTGGGATATATTTTTTGGTGTTTATAATTAAGTGGGTATAAAAATTATTAATATAATAATAAATTATCTTTTAAAATGATCTTGTACATATTTGTAAAATCAAGTAAAAAAAATAAAATAAAATTATCAAAAAAAGTTGAGATTTCCAACTTCTCAGATTATGACTTATAAGTTGGAAATGAACTTATAAATTCGTCATACAAATAATAGGAACAAATAAATTCAAAAACTGGGTTTATAAGTGGAGTCAAACACAACCTAAGTCGCTTGTGATTTATAAGTCAAAAAACTGACTTTTAAAATACAGTTAAACTGCCTCTACTATTCAAATTAGGTTTAAAATAATCCATTGACCTAATATAAATACTAAGTTTCCCTAATATAATTGAAATTAGCTGTACTAAGCTGAAATATGTCAAATTCATTCTATTTTACTAAAGAGCATGACGTTTCTCCAATGCATAATTGTTTGAATAACTTATCTTTTAATATTATAAAGAAATAATCCTTTGTACGCGTGAGTTACTTCTTCAAATAGTTTTTGATATTTTTGCACCCCGGGCCTGGGATCGTCTCAGACTCCTCAAGGGGCGGCTAGCATCTGAGGGTTTTCAGTAGATGTTCCCTTTTGCTGTTTTTATATCCTTGATGTCTAAATACTAAGTACTAAGTAGCAAGCTTTTGTTTTCCTAGGTTTGTCTACATGCTTGCATAGTTGCATGACTTTCTTGGAGTCTCTTTCATTTCTATGTAGTTTGGTGCTCTATGACTGGTTCTATGCTTTTTTGTATTGGCTTTGCTAAGTCAATATGTAAGATGTTCCGAGATTGATTTATAAACAGATGTATGGCTGGCTTTATGCTTTTTTGGGTTTTTTTACAATCGGAAAATATTTTTGTAAAATTTTTGTAATTTTTGAAGAAAATTTGCAAAAATATAATTTTACAAATAAAAATTGAAACGATACTAATTTCTGAATTCAATTTTGCAGAAATACGGAAGTTTCATTTGATAAAAAAAAAGAGTTTGTTGACATGATTTCAAATGAAACTTTCGTATTTCTACAGAATTGTTATATACACAATCGTAAATACATAGAAATTTATATTTGCAATTGATTGGAAAAAAGGAAAAATGAGTGTACAAGGTCAATGCTCATATCACATAAAAAATCACAAAATCAAACAGCAGTTGTTGAACTCACAGTTTGTTAAGCTAACATGGAGAGAGAGAACAGAAAAGTAAAACTTGTATTCAACTAACTGAGTCTTACAGAGTGGCTTCACTACAATATATACAAGCAAGCTAACTAATTCTCTAACAAACTATATGCTGTTGACAGGCTGTATGTACACGTGTAGTATAGAGAATAAATATTAATCATGTAATGCCAACACCCCCCCGCAAGTTGGAGGGGAGCACACCCAACTTGGACATAATGTTCTGATGTTTAACACCATTCAGGGCTTTGGTGAACACATCCGCAAGCTGTAATGTAGTAGGAGTGTAGGAAAGTGAAATAAGACCAGAACTTAGTTTTTCACGAACGAAATGGCAGTCCAAATCAATGTGTTTCGTTCGCTCGTGGAAAACTGGGTTCTTAGCTATGTATATTGCAGATTGACTATCACACTTCACTGGAATAGGTGTCACATCTGGAACAGAAAGTTCATTTAGAAGACGAGATAGCCAAGCAAGTTCAACAGTAATGCGGCGGATAGAACGGTATTCAGCTTCTGCTGAAGATAAGGAAACAGTGTGCTGCTTCTTTGATTTCCAGGAAATAATGCTGTCACCTAGCATAACAACAAAACCACTCACAGATTTTCGAGTATGTGGGCAAGCAGCCCAGTCTGCATCGCAATAGGCAGTAAGATTGTATACTGGATTTGAGTTGTAAAATAAACCTTGACTGGGAGTAAGCTTAAGGTATCTGAGAACATGTAAAGCTGCTTCCCAATGTGGAACTCGAGGAGAACTCATGAATTGACTAAGGTGTTGGACAGCAAAAGATATATCAGGACGTGTGTTAGTGAGAAAATTCAGTTTGCCAACCAACTTTCTGTATGAAGAGAAGTCAGAAACAGGATCGCCTTGATCATGGATAAGTTTAATAGTAGGATCGAGGGGACTGACTGCAGGTGGAGCATCGAGACAATCAAATTCTTTGAGTAAATCTTGAGTAAATTTGGTTTGAGACACAACCATACCAGATGAAACATTCTGAAATTCAAGGCCTAAGAAATAACTCAGATTTCCCAAGTCTTTGATTTTGAAGGTGTCGTTGAGAAAGGCTTTTACAGCAGTAATCTCAGTTAAGTCATCCCCAACCAGTAAGATATCGTCAACATAGACAGCTAGAAAAACAGTAGAAGATCCTGTTTTCTTGTAGAAAAGTGAGTAGTCATTCTTGGAATAAGAATATCCCCGTGACAAGAGAGCACAACAAAGTTTGTAATTCCAATTTCTGGATGCTTGACGAAGTCCGTAAAGGGATTTAATGAGTTTGCAAACTAATGTGGAATCACTAACTTCAAGACCTGGAGGTAATTGCATATAAACATCTTCAAATAAATCGCCATGTAAGAAGGCGTTGTTCACGTCTAGCTGGTACATGTGCCATTGTTTCTTAACTGCAGTAGCAACAAGAGTTCGAATAGTTGTCATCTTAACAACTGGAGAAAAAGTTTCAGTAAAATCAATACCAGCCTTTTGAGTGAACCCTTTAACAACTAGTCGAGCTTTGTAACGCTCGATGGAACCATCAGCATTATGTTTTACTTTGAAAACCCAACGACAGGAGATTGCCTTTTTACCAGGAGGCAAGGGGACTAACTTCCAGGTATTATTGGCTTCTAATGCAGAAAACTCAGCAGCCACAGCCTGCTGCCATTCTGGGTAGATCATTGCTTCTGCAAAAGATTTAGGCTCTGCAACTGGTATTTGGAGAGGAAGTGGTGTGGGAATAGCACAGCAAACAGATTGAGGAGAAAGCAATGAATTAAGAGGAATACAATTTGAGGTAATGGTGCATGAACACAAAGAATCTGAACAAGCATTATGTACAGAATGAACATAATCTGTTAGATAGTTTGGCAGTTTTGAAGTTCTGGTTGATTTTCTGAGAGGTGGTGGCTGTGGTGAATCTGAGACAGAACTTTCAGATTGTTGAAATGAAGAGGAGGACTGTATAGGTGTATGAGAGACTGTAGGAGTAGAAGAGTGTATGGGAGACTGTGTAGAAAGTTGTGAAGGGATAGACTGTGATGATGACTGTGATGGTGACTCAACAGTAGGAGTAGATTGATCAGGAATAGGAAAGTCAGGGACAGGTAAGGGAAAGAATGTAGAGGAGTTAACATCTACATATGGAAAATGGTTTTCATAGAAAACAGCATCTCTGGAAATTAAAATTTGCTTTGTTTCCAGACTGTAAAATTTATAGGCTTTCTTGCCCTGTGGATAACCAAGAAAGACACAAGTGATTGCTCTGGGGGTGAATTTATCCCTGACAGCATCTCTGGAGATTAAAATTTGCTTTGTTTCCAGACTGTAAAATTTATAGGCTTTCTTGCCCTGTGGATAACCAAGAAAGACACAAGTGATTGCTCTGGGGGTGAATTTATCCCTATGAGGTTTTGGAGTAGTCACCAGGCTTAAACAACCAAAAGGTTTTAAGTGATCAAAACTGGGTTTTTCCTTGAGTAATACTTCATAAGGGGAAAGATTATTTAAAACTCTGGAAGGAAAGAGATTAATAAGGTGAGTGGCTGTAAGGATGCAATCACCCCAGAACTTAACAGGAAGCTGTGATTGGAAGAGAAGAGCTCTGGCTGTCTCTAGTAAATGCTTGTGTTTTCTCTCCACAACTCCATTTTGTTGTGGAGTAAAAGCACAAGAAGTCTGATGTTGAATGCCTTTAGATTTAAAGAAATCTTTAGCAGCATGACTGAGACCAATTTCTAAAGCATTATCAGACCTTACTGATTGTACAGGTAATTTGAATTGTTTCTCAGCTAAGATAATGAATGATTTAAGGAAGTCAAACGCAGAGCTTTTGTTAGCAAGCAAATAGGTCCAAGTAGCTCTAGAAAAATCATCTACTATGGTAAGAAAATATCTGAATTTGTTGTAAGTGGGAACCTTGTATGGGCCCCAAACATCAACATGAATTAATTGAAAAGGACTTTTACTGTGAATATGACTGACAGGAAATGGCAACCTTTGTTGTCTTGCCTTAGCACAAACAATACAAGGTACATCAAGCATAGAGTCAACATTACAAATATGTAATGATTTAAGTTTGTCAAAAGGTAAATGACCTAATCTGGTATGCCACATCATGCATTCTTTATTATTACTAGCAAAAGTCTTACTAGTATTAGCAATAGAAGCAGAAATGACATTTGGAAAGGTGACAGAAGTGTCTGATGAAGATGATGAAGGTGCAGAGCTGGAATATGAAAGAAGATACAAGCCTTTAAATGCTTTACCAATTTCCAGTTGTCTCTTCTGTGAAGAGTCCTGCAAATAACAAAAGTCATTAGTGAATTGTAAGGTACAATTCAGCTGACTTGTTAATTTGCTCACAGAAAGAAGATTGAACTGGAACAGTGGAACATATAAGACATTGGCAAGAGTGATATCATGTGATATTGGAACAGTGCCAATGGAAGTGATGTGTAAAATGTGACCATTAGGCAGAGATATGGTTAGAGGTGTGTTTAAGATGGTAAGTGAACTGAATAAATGTTTCTGTGAACACATATGATCATTAGCCCCACTATCTATGATCCAAGTAGTAGAGTCAGATTGTGACATACAAGCAACTATAGAGTCTGAACAGAGAGAGTTACCAGCAAAGTTTGCATAAGAAGTATCTTGATCTGGTGGCTTAGTAGTTTTGAGAAGCTGGAGCAATTGAGAGTACAATTCTGGAGTCATAGCTGGAGCAGAATTATTTGATGAAGTTGTAGAATCTGCAACTGTGTCAGGAGTAGAATCATGTTGGAGGACATCAGCATTTGCAGCAAACCTTTTAGTAGACTTTGTGAACTTGAAATCAGATGGGAAGCCATGAACTCTGTAACATTTGTCAATAGTGTGCCCTGTCTTCTTGCAGTATTTGCAAGTAAGATTAGATTTCTTGAATTGACCCTGAGAAGCCTGAGAAGTCTGAGAAGAAAATGGCTTGGAATTGACATGAAGTGATGTAGAATCTGTTATCAGATTGTGAGAAGAATGAATTTCTCGTTGAGCTTCTTCCTGTAGAAGAAGATTGTACACTTGACTGATGGATGGCAGAGGATTGGACATCAGAATAGAACCTCTCATCACATTGTAAGATTCATTTAGACCCATAAGGAATTTGACAACTCGTTGATTCTGACGCAAAACAGCATTCTTAGGTGCTGCTTCACAGGTGCAAACAGGAGTGAGGCAAAGAGAATCAACATCATCCCACAAGACTTTCAATCTAGTGAAGTAATCAGCAACAGTGCTATTTCCTTGACGTATTTCACAAAGATCCTTTTGCAAAGCAAACAGTTGTGTTCCATTAGAGACATTATAGCGCTCATCAAGTTCTTTCCACATTTGATAAGCCGAATCAGCACGACTAACACTACGAGCAATGGTCTTGTCCAAGGCACCAAGAATCCATGAAATTACCATGTCATTACAACGAGACCAGCTGGTAAACGAAGGAGAAGAAGGATCTGGTTCTGGAATCCTTCCATCAACAAACCCTAACTTGTTGCGAGCAGATAAGGCAATTCTCATTGATCTTTTCCAACTACTAAATCCAGTTCCATCAAAACAATCACTCACAAGTTTCATTCCTGGACTGTCTGATGATTGCAAATGCAGTGGATTATCTTGAAGAGTGGTAGAATTGTGATCGAAAACATGATTGTTTGAAGAACTCATGATGTTACAACTCAAAACAATCAATCAATTAAGAAGGGAAGACTAAATCTCTGAATTAATCGCTATGGTAACGAACAATCACCAGAGTAAAACGAGCAAGATTGAACAATCACGAATCAACAAAACAATCTAAAGATGTTTACAAACAAATATGTACAGTAACAGAGAGGAATAACGAAGTAAAGTGAGAAACGAAATCACCGGAGAAATCACCGGAGATGAACAAGCAGCGGAGATGAAGGAACAAGCAGCGGAGTTACAGCGGAGATGAACGGAGATGAGTAGATCGGTGTCGCTCTGATACCATGTTGAACTCACAGTTTGTTAAGCTAACATGGAGAGAGAGAACAGAAAAGTAAAACTTGTATTCAACTAACTGAGTCTTACAGAGTGGCTTCACTACAATATATACAAGCAAGCTAACTAATTCTCTAACAAACTATATGCTGTTGACAGGCTGTATGTACACGTGTAGTATAGAGAATAAATATTAATCATGTAATGCCAACAGCAGTAAATCAGATCTTCAAATCTGAGATTATATTTTTGTTATTTATACAAATATTTGAGATATAATCAAAAAGAAAATTTGATATATTTTAATAATAAAACTTGTTAAACTTGAAAACTAGCGCTTGATTTCTCTGAATTTTAATAAATTTATAATAATCAAAAAGAAGTTTTAATAAATTCTAAATTTGTCAAACAGAGTTTTATCGTCTACCTAAACTATTAAAAGAATTTAACCATTTCATTCTCGTACTATAAATAGTATTCTGCAGGAGCAAATAATTCACCATCTCGACTTTGCAATTCCACTCATTGTATTCTCAAACTCTTCCCTTTTCTTTTTACTATTCATAACATATATACAAAAACAGAAGTTGAAAAAATCATTATGGATCCAACTAGCATTCCCGTTGTGGGAAAAATTGTGGAGAAAATATCCGATATAATCGTGGCAGCTTTGTTTAGCCATCTAAACTATATGTTTTGCTCCAAGTCTCTTGTTGAAGATCTCAAATCTGAGAATGAAAAACTTGAGATCGTGGAGAATGTGATGTCCAGAAAAGCTGATGAAGAAAGTAACAACAGCAGAATAATGGAGAAGCATGTGGTGGACTGGAAAAAAGCTGCCAGACAAAACCAGGAGAGTGTTAAAAGCTGTTTGGAAAAATACGATAACCGTCCTTCAGGGAGGTGCTTCCGGGGCTCCTTCAAATTACTAACCACCCGGAACAAAATCTTTACAAAACTAACCACCTTTTTTTTCACTTCACAAAACTAACCACCCTAATTCATAATCATCCAGAGGCGAACACCACACAAAATATTTTTGCAGGAGGCCCTTCCCAGGGGCGAACAACAAAGAATTTTCCTTATATGTTCGCCCCCCCCCCACGGGCGAACATAGTAGGGAAATTTTTTGTTCGTTTGCTCAAAAATTCTTCACTTTTCAGTTCGTTTATTTAATTTATAAAAAATTCAAAAAAAGGGAAAATTGTGATAATTTATATTATTATATTTTATAATATTATATTATATAATGATATAATATTACAAAATTATTTTATATTAAAATATAATATTTTAATATTTAAGTTCATATTTAAGCTCATAAAAGATAAATAATATTGTTATTGTTTTATTTTTGTTAATCCGAAAACGTCATGTAATATCTTGTCCCGAATGCATTTGATCAAACACAGCACTTTTATTCATAGAAGATATTAAAACAACGATAACACGACTTAAATTGAAAAGCAGAAAACAATCACGACGAAACTACAGACCACTTAATCGTCCTCGGACGACATTACACTATCAGAATAATAATCCGGAGTGGTGACCAATGCAAGGTATTGTTGTTCCTTAAACCGGTCCCCTTCTTCCCGAAACATCCTAGCATCATCGTATAGACTATGACGATGCAGTCGCAGATTCATGCGATTCTCCTCTTCTCTCGCTCTGAGAGGGCGGCCGTCCACGCTGCTGCGGCNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNTCCCGAAAGGACGGGTCCTGGGTGAAGTGGGGGAGGTGTGTGATCCTCTAAGAATGACATGTCAGGACGATATACATATGACTCTGACAAGTGATCCTGTGACGGACCCTCATCGTCCTGTGCCTCATCATCCCCTAATCTGCTCCTTTGGGGCCATGGAACCCCCTCAGATGTAGAAGGCTGAATGAATGGAGACCAACCACCAGCCTCAAAAGTACCTGCTCCATCATGACCTGCAGAATGTGAGGTGCCTGCAAGGTGTGAGCTACCCACATGGGTGTAGTAAGTGCCCTCTTCGGGCACTACCGGTGTGACTGGTGGTCGTCCCCTACGCCCTGCAGGAGCCCGTGCCCTAGGTCTGGCAGGGGCCTGTTCCGTAGGTCGACGCTGTACACGAGTAACCATATCCTGTAAAATATGGTTTGCCAGACCCAAATCAGGAGCATAAGGGTCAATGGCACGCTGCATAGCGGATAACTGCTCCTCCTGTTTACAAACATGTATATTTAAGTCAGAACAGTGTACAAAACAAGCTGAGAACATGTATATTTAAGCATGTATATTTAAGCATGTATATTTAAACATGTATATTTAAGCTGTATATTTACCAGTTCCGGTGTCGAGAGCTGTGTTCCCTGGAAGGCACCCTCCTGCTGTGGCCAGTGTAAGGGGTTAATGATGATTCGACGTGTGACCCTGTGGAACCATGGCAGGTATGAGGCAGTGCAACCCTCGCCATGCATAAGTGGAGGAGATGCGAGGGCACGCTCCATGCGCGAATCCCAAAGATCAACAAATGGCTCCCTCGCGTACATCCAATCAACCTGCTCGTTGTAGTGGTCGTGCGATTTGCAAAAATAAAAACTGCAAATAAAAGTACATTTGATAAGTTCGAGGTCTTTAATATTCTCAATCCTGAGTTATGTCGACATAATAGTCGGAATCATAATCTTCATCATCATCTTCAGCATCAGCGGCCACCGAGGTATGCTTTTCATAGGTAAATCAGCATATGGCCTCCATCGAAACTGTCGGGGTGTCAACGCATCCAACTCATATTGTGTCATGCGGCTCTGCGCATGCGGCACCTGACAACGCCTAAGTGGCGCCTTCCACCTACAGTGGAAGTTGGCATAAGTGCTCAGAGGTTATACATGCAACAAATATGAATTGAAGTTAATCAACAAAAGGAGTGACAACATACCTCAGCGCCAGCGGGTACTCGAACAAGGGTTGACCCCTGTGCCTAGGCGCTAGTGACGGAAAGCGCTCGTAAATCCACACCTAGCGGCAAGGTTAGTACAAGTGCACATGATGAATAAATAATACAACAATAAAGACGAGAAATAAATATTACTTAATTTTAAATTCGAAATAATTATCTCTAACTATTTTTACAAATCTGATTTTTTTAATTTAAACTAGTAATCTAAACTAAAATTAGCACTACCACTACTAATCAACAACAATCATCACCAACTACTAATCTATTTAATTTAATGGTGTCAAGTTTACTTTTAAATTCGATTTAATTTAATTTCATTAAATTCAATAAAAGCTAAAATTAAATTGATTACTGATGATTAGGGTAGGGAGAGGAATATGGTACACCCTGCATAAAACCAAACTGCCTCGTCACCCTGTCCGTGTAGCACCACTCGACGTAGGACATGTACATCATGGGGGCGGGAGCCGTCCAACGCAAGTACACAGTGGCCTCCGGGTGATGCTCTGCAGGTAAATCAGCATATGGCCTCCATCGAAACTGTCGGGGTGTCAACGCATCCAACTCATATTGTGTCATGCGGCTCTGCGCATGCGGCACCTGACAACGCCTAAGTGGCGCCTTCCACCTACAGTGGAAGTTGGCATAAGTGCTCAGAGGTTATACATGCAACAAATATGAATTGAAGTTAATCAACAAAAGGAGTGACAACATACCTCAGCGCCAGCGGGTACTCGAACAAGGGTTGACCCCTGTGCCTAGGCGCTAGTGACGGAAAGCGCTCATAAATCCACACCTAGCGGCAAGGTTAGTACAAGTGCACATGATGAATAAATAATACAACAATAAAGACGAGAAATAAATATTACTTAATTTTAAATTCGAAATAATTATCTCTAACTATTTTTACAAATCTGATTTTTTTAATTTAAACTAGTAATCTAAACTAAAATTAGCACTACCACTACTAATCAACAACAATCATCACCAACTACTAATCTATTTAATTTAATGGTGTCAAGTTTACTTTTAAATTCGATTTAATTTAATTTCATTAAATTCAATAAAAGCTAAAATTAAATTGATTATATTTAATCTACTCTTAACGTAAATAATACAACAATCATCACCAACTACTAATCTATTTAATTTAATGGTGTCAAGTTTACTTTTAAATTCGATTTAATTTAATTTCATTAAATTCAATAAAAGCTAAAATTAAATTGATTATATTTAATCTACTCTTAACGTAAATAATACAATAATCATCACCAACTACTAATCTAAACTAAAATTATCACTACCACTACTAATCAACAACAATCATCACCAACTACTAATCTAAACTAAAATTATCACTAACATAAGCTACTACCAAATACCAACTAACAAAACCCATTATAAATTATCAAACAAATTACTAATCAAGTCTAATTTTTAATTCATTCAAAATATGAGATCTACACTAATTTTCCCAATTTTATAATTCGAAAAAATTGTACTATATTTAGGATTTTTTTATGCAATATTTGTTATTAAATTCGAAAATTATTTTAATTAAATCAAATAATTAAAACGCTAGTGACGGAAAGCGCTCGTAAATCCACACCTAGCGGCAAGGTTAGTACAAGTGCAAATGATGAATAAATAATGCAACAATAAAGACGAGAAAGAAAGTTGTGGTTGGTTTAGTATTACCTGTACCAATGTGGCGTAGCCACAGAAATCAGTACAGTTAGCCCTGCTAGAAGAACATAGCTTCTGGTATAGGAAGCCAAGAACAGCACTACCCCAGCTATACCGACGCAGCTGGTCCATGTCCCTCATTAACCATAGAAGGTCAAGCTGCACGCGGTTCCCGCTGCTGTGGGGGAACAATGATCCAATAACGCATAGTAGGTGCGCCCGAATATGGTAGGTAACCTGTACACCATAACCTATATCCTCTGGATCCAACTGCTCCAACCGCTCACAAGACCCGAAGTTATCCACAAGCCATTTGATCTTTAAACCACCTCGGTTAACATCGTCCTTGGCTTCTGGTAATAGCCCAAGAAATTCGCCTACTAGCACGCGCCTTTCCTCCACGCTGGTACTCGCTCCACGGAGGATCAGTGGATCCACCCTCAGGTACGGGTNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNAATTCCAAAATCGAAATAATTCAAATTAAATTCGAAAATGTGAGATTGCTTATTTTTATTCTATTTTTTAACGTAAAACACCCAAATTTAATCTACTAACCTAATTTCTAAATTTAATCTACTAACCTAATTTCTAAAATTAACATAATCTACTAACAAATACCAACTAACAACATTCATTATAAATCATCATACAAAATTACTAATCAAGCTTGTCATATAATTTGTAGCTACTAGCAACTAAGAACAATCATTATAAAATTTATAAAAATACATGCATGCAATTTGATGAGATTGAGAATGGTGGAAAAACCTTGAAAATGGGTGAAATTGATTAATTTGATCCGGTGAAAGTAGCAAAGCAAGCTCCTTTTTCCCCCCTTTTCTCTGTCCGGATCACCCTTTCTTCTAGAAATTGAAGCTTGCAATGTGTGAAAATCTGAGAAGAAGCTGTTTGCTGCGGCGAAGATGAAGAAGAAACAAAGGGGTTGGGGTTTTGAGGGGTAAAAGGGACACGTGGCCGCCCCTGACTGGGCCGGACACGTCAATGCTTCACAGGTATGTTCGCCCGTGGCAGGGGCGAACACACTTGCCTGGAGTTCTTCTGTTCGCCCGTAGCAAGATCTGGGCTTAAAAAAAAATTTCAGCTGTGTTCGCCCGAGGGGTGTATGAATTAGGGTGGTTAGAAATGTGAAGTGAAAAAAAAGGTGGTTATATTTGTAAAGCTTTTGTTCAAGGTGCCTAGTAATGTGAAGGAGCCGTGCTTCCGGTGTCTCCCAATTCCTCATCCCTTCTCCCGTTACAGATTAGGCATGGAGGCGGAATCGATAGCCAAGACAACAACTGAATTAGCTACTTCCGGAAATGGCTACCTGGCTCACCCAATTGCATATCTCCCACTGGATATGAAAGCACCAGTAACTGAATTTCATGAATTCAAATCTAGAGAAGAGGCTTATCAAAAGCTGGAAGGGCTAGTCACCGATTCTAGTTCTTCAATCCTTGGGATATACGGAATTCCAGGAACAGGAAAGACTCGATTAATGGAGCGAATCACGACAGAAGTTGGTAAGAAGGGAACCTTTGACAAGGTCGTACGAGCCAATGTGAGGAACGCGAAGTTGGATGTGATAGGCATACAACAACAGCTTGCAGGGAAGCTAGGTTGCGACTTTGAATCTGAAACTGATGTGGAACGTAGAGCTGGTCAGCTGAGATCTAGTTTAAGGCAGGGAGGTAAGGTACTCGTCATACTAGACGACCTATGGAGTGAAATTCCTTTAGATAGAATCGGAATTTTGTCTGAAGATGGTATGAGTTCCAAGGGCGGTAAGATTCTGTTGACATCACGAAGTGAGGAGGTATGCAAGAGCAACAAATGCAAGCATCCAGTCAAAATACAACCTCTTACATTTCCCGAAACTTGGGATATGTTCAGCAAAACAGTTGGTGCTGATACAATCAACTCTTTGCAGAATAGATCCCTTGCCTAGGACATCTGTAAGAGATGCGGGGGTTTACCACTAGTCGTTCTTGCTATAGGTAAAGCGCTCAAATTTAAGCGTCTTGCTTCATGGATGGATGCACTCAATCAACTTAAAAATTCCAATATTGAAGAAGTTCCTGGAATAGGTAAAGAAGAGTATGCGTGTTTAGAGTTGAGTTTTGATAACTTGGAGCACGACGATGCAAAGAAATGTCTCTTGTTGGCTTCTATGTGCCCTGAAGATGCTGACATTCCTACGAGGATGGTGGTTCAGTTAGCAAGAGGCTCCCAGCTTGTGAAGGGTGATGAAATAAAATTAAGAGTACATTCAATGATATCTATACTGCAGTCAGCCTCGTTGTCGCTTCAAGGGAAGGATGGTGATCATATCAAACTACATGACATCATAAGGGACATGGCAAGATCCATTGCCAAGAAACACCACGGATTCTTATTCGCAAGAAGTAGGTCGTTGCCCAATGATTCAGCTGAGTACTCTGGTCTGAAAGTTCTGCATTTAGATGTAGAGGAGACTCATTCACGTTTTCCAAGTGATGTGGAGTGCCCAGACCTGCATCTACACTGTCACTACATTCATCATCATCTACATATATTGACCCAACACCGATGCAGGTATTCATAGACTGTTTTACATATTCACTCAATTGATGATAACTATGATGATTAGTGTTATAGAACGTAAATTGGGACCTTGTAGCACTTTTAAGCGGTTGAGTGAACGTTTAAGTAGAATTTTGAGGCGCTCAATAGCGGATCAATAATATATAATTAAATATTTAATTGCAATATTAATTTAGTTAAAACTAAAGTTATCTATTGGTTAGAATTTAAATTTATAATATTTTTTATAATATATATATATATATATTTTTAATTTTTAATATGACTATAGTTATATTGTAAAAATTATTTTAAAATTAAAAAATTAACAAGTCAACATCATTTTGACCGCTTAATGATCGTTTAATCAATTTATTGTCCGCTTAATTTTCAAAACCACGTAATCACTTTCATACAAAAAATTAGGCGGCCTCTTAATGTGACACAACTGACGATAAAATAAAAATAAATGATTTTTACGGTTCATCAATCAATGCTATCGTCTAGTAATATTAGCTGTATCAATATTTTATAATTGTTATAATATAATTATATATAATTTTACTAAAATATAATATAAACAATAAGTTATAAATCAAGTCATGTTTTAGTGGAATTGTATAATATCAAAAATTAAATATATTTTTGAGTGTATAATTTTAAATATGAACTAAAAATAAAATAATATGTGATACATAATATTTGAATCGGTTTAGTTGTTTATATTAAAAAATTTATTTATTTTAATCATGATCAATTATCAGGTTAAATAATATATATCTGCTACTTAATATATCAATAAAATTAATTTTATACAAAAAAATAATTATTGAAAAAGTATTTCAGTTAAAGAAAAGATTTTATCTTGTACAAATCCCTCTAAATTAAGTTACATACGAACTAAACACAAAATATTAAATCTTGTAATATTTATTTATAAAATATTAAAGTTATAAATAAAGAGTGCCAGTTAATATTTATTTATAAAATATTAAAGTTATAAACCGTATAGAATTGATTGGGACGGAGGGAGTATGAATTAGACTTGTTCATTGAATGACCGTTCAAGGATTAATCAAATAATTGAATCATTAATCAGAACTAATTAAATATTATTTATAAAATTATATATAATTTGGAAGTTAAAATTTAATAAAATAACTTAAATTTATATAGGATAAGTTTTTTTTATTATATATACAATTATCATCAAGAAAATTGACCAAAAATAAAAAAAATTTAACAAAATCATATATGTATATTTAAGCTTATTTAAATTAAATTAATTTTAAAATTTCAATTTTTTATTTATAATTGATCAACTTTTGATCAATCAGATTTTTTAAAAATTATTTTTCGACACGATTACTCAATTCAATCAAGACAGAATCGGTCAATTAAACATCAACTCTAGAAGTTTAAAGGAACGCCTCCAACACACAACTATATTTTCCACATTCACTTTTATGATTTTTTTTATATGTCACTTTTGACTTGTGTATCTAGGTGTATTGACTTGATAGTAAAAAATTATTATTTTTAATTGATTCTTTTTTGAATTAAAATTTTGATTACGTATTTTTTTTCAAAAAAGAAAATTTCAAAAATAATATTTTTAATTCTCCGGTCAAAATACTTAAAAGTGTGTGCTAAAAAATTAAACGTCATATATTAAAAAACATAGGGAGTATATTCATAATGTGTTGTTCAAACGATATTCATCCTCGTCCTTTTTATAAGTCACTTGGACTTTTTACACATAATTTTATATTTTTACCACTTATTTAAAATTATCTTTTCTAATTTTTTTCTTAATTAAAATATGAAACTTATACTTTTATTAAAAAAATTAAAAAATATTAATTCGAAGTATGTGGTCAAAATCAAAAAAGAAAAGAAGTCAAAGTGACTTATATATAAAATTAGGAGGAGTACATGTAAATAAAAAAAAAATAAAAATCACAATTCTTTACAAAAATTTCAGGAATGGATTGGTCAAGGTCAGCAGCTATTTGCAAATCTCAGGTTCTTGGTGCTTGTGGAGTTTAGTTGGCCGGAGAAGTTCTCTCTTGAATCCTTAGACAATCTTAAAACTCTTTGGTTCATCACATGTGACCTTGTCCATTTTGGGAAGAGCGAAGTTGGATTGCTTCCGAAAAAAACTAGAAAATCTTTGTTTTTGGGATTGTGATTTTTCAAAAGAGCTGAATTTAGCAAAACTAAATCATCTTCGCAAGTTAGAGATCTATATCAACACGAGACCTTGGTTGTGGGAAGATAAAATCATTGTGAAGCAGAATACAATATCAAGACTATCCGATCTAGAAGAATTAAGTTTCCCACTGAATTCTACATCCGTGAAGAATGTGCAGAAGATGGATCATTGCCGATATTAGACGAGGTCTGTAAATTGTCACGCTTGACAAGTTTAAATATTTGTTCCCGAGAATCCAAGTCAGGTAAACTTGCAACTATATTTTGCAACTTACGTGAATTCCATTTGTTTGTTGGTAAAAGACCAGATTTTTGGTCTCCGGGAGTGTCTTCGAGGACCAATTCAATTACATTGTCCAACCACGATCTCATAGAACACTACAAGCCTCTGTTTGAAAAGGCTGAAGAGGTGATATTGTGTGGTACTAACTTCACAGGGAGTAGCATTGATATTAGAGACACTAAAGAATTTATCAACTTGAAGTACATGAAGATTCAGGATTGCCGGTTCATTGAGTATTTGGCTAGGATGTCACCGGGTAATAAGATTGGTGGAAGTCTTCCCCAGTCAATACCTTTTTCTAACCTTACCAAATTGAAAATCAATAATTGTCACAGCTTAAAATACCTCTTCTGCAACTCTGTTGCAAGATGTCTTAACAAAGTGCAAAAGCTCAAGATAGAGAATTGTCATATGATGGAAGAAGTCGTGCTCGGAGAAGGCACAAGTGATGGAAATATGAGTATGCCCGAATTACGAAAAATGACCTTAATTGATCTGCCAAGACTCATACATTTTTACAAGGATAACACTTTCTCCGGGCAAATTCAACCTCTCTTTAATCAAACGGTATGCTTGCTTAACCCTTAAATATGTTATAATTGTATTCAAGCGAAATTAGTAAATTATATTTTCAAATATTTAAGCTACATTTATTTCATTAAAAATAAATCATTTTGTTTACTTCATTGAGGCAATATATTTGTTTTCTAGGGATTAAAGTTCAAATTGTCCACCTCAAATATTAGTAATTGCCCATTCTTGATATTTATATAATTTTCATAAACATATGAAATCATTGGCTTAATTAACTTTCTACTAAGCTACATATGAAATATTAGTAATTGTAAATATTGTACAAAATTGGGATAGGGCCACTGTGTACAAAACATGTGAGAAAATATGATTCCCTCCCCTTCGAAAATATCTACTTTCTTATATAGACTAGTACTCTCTGCACAGAGATGAGTACTGGAGTATATACTCTCAGGAGTTATACTTATACATGGCACTTGGAGTGAGTTAGAAATAAGAACCGAACCAAATACCCCTTTCTCTGATGGTATGTTTTGGTTGACTATTTGAGCAGGTTGAATTCCCTTTATTGGAAGAGTTGGATATTAGTGGTCTGGAAGATATAACTGATATTTGGGGAGATAATAATGGCAATGCCTTCTCCTTTTTCGAGCTTAAGAAGTTGAATGTATGGAACTGTAATAAGCTTAAAAATGTGATCCCACCTGCCAAGTTGCCTAGTTCACTCACCTCTGAAGTTGACACTCTTGGAAGCAACACAGATTCGGTCGCTGGCAGAGCTTCTGAAGGACAAGTGAAGGCCATGAATTCTCATAATCCAAACAAAAAATTACAAATTTTTTTGAAGAAAACTGTGCTTGTGTCGAAATCTGTATGCAGGAGGACCCCGACGATAACAGAAGAAAATTTGAATGATCCCTCTGATATTTTAGTTCAAGTTCCGTCACAGAACACAAGGGTATGTCCATTGGTTGAAATGAGTTTACAGAAATTGCCTTGTTTGGAAAAGACAGGGTTGAACTTTGAGGATCCATCTGGAGTAGTGAGTACTTACCCATATCTTGAAAAATTAAATATATGTGAATGCAACAGATTGGAAAACGTGTTCATATCTTCTCGTGATGCAAATTTTAAGAATCTTGAGGACATGTCCGTCACTAATTGCATTATAATGAGAGAGATAATCGGGGCAGGTGACCAAAAAATTGCCAATGGCATTGTGTTCCCTAAGTTATGTTCTGTTAAACTAACGGAGTTGTTAAGTTTGACCAGTTTTTGGGGGTACCCGAGTGAAGAAGCTAACAGCCACAAGGTATATTTACATTTACTGCCAAATGAGTAACATTGATAACATGCATTTGTTTGTGTGCTTGAGTATATATATAAATGCTTAATTCTCTTATGTATGGCTGATAAAACGCGATATTCAGGACCTGATTTTCATGTATATATACTTAAAATCTTCATCTAGTTAGAGCTCCTGTTTGCTGTAAAAGTTTTTAGGTAAAGATTTTCTAAAGTTAGGCATATGCATTATCATAAAGAATGACATTGTTTTGTGTAGGTTGAATTCCCAAATTTGAAGAGTTTTGAACTCAGCTGTGGCAAAATTACTAGCTTGGAAATGATAGAGTTTGGCAGCAGAGATGGCTCTATTTTTCGGCTGGAGAAGTTAGATATAAGTTGTGATGAGGAGATACAAATTCCCAACCAATGGCTACCTCATTTGAATAATCTGGAAAGATTGTCACTGAGACGCTGTTGGTCAGATGAGCTGAAATCTCTACATTTCGCAAAATTGAAGGTGCTCTTACTTCAAGAACTTAGTTGCTCAACTATTTTCTCATTCCCAGACTTTGAAAGACTTCAACAGCTCCGAGGATTAGTGATAACAAAATGTAATTCATTGGAAGCTATTGTGGAGGTTGTTGAGGGTGAAGAAGCTTCTGACATGGATACGGAGACTGTTGCACTAGTTCAGCTGGAATCAGTCCATCTTGAGGGTTTGCCAAAACTCAAAAGTTTTATGCACACAAAGCCTAAGAATCTTATCCCCAGTTTAGAGCATGTGGAAGTGGAGCCCTCCATTCTTTTCATGTGCCCTGTCTTTGGAAATTTCCAACAGCTCAAAAGGTTACAAGTGATTGATTGCAGATTGTTGGAAGGCATTGTGGAGGTTGCAAGAGGCTATGAGACGGATGACAGGATTATCACATTCCCTAAACTCTCTGACATTCATCTTAGAGATTTGCCAAACCTCCAAAATTTCAGTCCCACTACAAGCTATAGTTTCAACATGCCCAAATTATTTCATTTTCATATGTTTCGTTGTCCCCGGGTTGAGAATAAACCCTTATTACAAATAATCGCACAACGGGTACTTGTTTATTCCGATGAGCATCCACAAGGGATTGTCATTCTAAACCTCAACGAGTACACAAGAAGAATAAAAAACCTCGAAAGCGTCGGGGAATCAAGTAACAGCCATCAGGATGTGGAGATGGAAACCATAACAGTTGCAGAAGAGGAAGACAGAGTTGTTGAACAAGAGGCAGAGGTAGTTGTTGTAGGAGAAGAAAGAGGAATAGAGGAAGATTCGTAATTCAATTGTTTTTCATCAACTCAGCTTTCTTTTCCTTTCTTTCTCAAATGTCTCAGACTGTGCATTGTTTTGTATTTGTTTTTCAAGGAAATCTGACGCTGAATTGTGAGATGTGAAAAGTGTCAAGCTCTTAGCTATTTGAATTACAAGATCAACAGACAGGCCTTGTCTTGGAGGTTCTTCGACTCAAGTAACACATTCTTCGTTACTACTTTATTCACATAAGTCATTACTTTTTTTATCTTTTGATAGCAACATATAAATCACTGGATAGGTTTGTCATTAGGTTAGGTTCTGCGTTTTTAACAGGTATGACAGATTTAACAGGTTAGGCTTATTTCCAGATTTCCTCCCTTGCAACTTTTTTAGGCCTCCCTGAAAAGTTACGGTCCGAAATGTGTACTTACTTACTTTGTTGATGTCTCGATATAAGAATCAAGAAAGTAAGGAACAGAAACTGAGCTCCGAAAAAATATTCAATGATGAATGCAAGACATTCTACTTTGCGGGTAAGGAAACGAATGCTAAACAATCTTGTGTCTGTGGAGAGAGTTCATCTCCAAGTGCTGATAATTTAACCGACTTAAAGATTGTAAGTCATATTTTCATTTCATACTGCTTTTTTTAAATTTGTTGTTTTCATAGAATTAACGACCTTTTTGAACTTCTAAAATTAACTAGAAGTGATAAATCTAAATGGATATCCTTGCATTCAACATTGGGAGAGTGATAATTAGTAATACCCGAGTGGATAAAATGCCTGAATTGTGTGTGTTTGTTGGCAGATAAACATGATTCTGAATGAAACACTTCGACTCTACCCACCAGATGTGATGCTAACGAGGGAGACGAATAGAACTGTAAAGCTAGGCAACCTCCAAATTCCAGCTGAAACGCAGCTCTATTTGCCTATGACTGCAATTCATCATGACACTGACATATGGGGAGCAGATGCAAAAGAGTTCAATCCTATATGTCCATGCTCCAAGGCAGTTGATGACCATGCAACCTCAATTTGGGGCACAAATACTTTTTACTAGAATTCCCTGAGTGAAGCCTATAAAACAGACCAGATTATTGTTTTCGACTAATACTTTTGTCTTGTAGAATATTATGACAGGTCAGCTCAATATGTATGTATAACACAATATGAGTGGCAACAAGCCTTCTAATTATATATTTCAAGATTTTTTAAAATGCGAGTTTGAACGGTCTTCTACCAAAGGCACAGGAAAAACGAACCTAAAAAGTCGATCTTCATTTATATTTTGACCATGTAATGTTGATCTTACAAACTTTGTCAGATCATGTGTTGTTGGATTGAGGTCTAGTACGGTGGTCATCACTAAAATTTACTTTAAAGAGAGATTTTAAAGAATTCATCTGTTCCCCAATGAACTCTGGAAAACCCCTGCCGGGATTCTGTTATATTTATTGTTGATGAACAAATCTTTGTTCTTTTGTACTTGAGGGTTAAATTTTATGCGGTGTTTTAGTATGATATCGGTCCTGGTTCTATGGAGTTGGCGGAAATTTCTTATCTTTTTGGATCTATAGGGACTCAGCGCTTGTTGGTGACACTCTTTATTCTATGGTCTGTGGAAGTTACTCACATTGAAGATGGAGGTATGAGATCAGTGTTAAATGGAGGTTGTTTGATACGGTTCGAATGCATAGAGAATAGGCCCATAAATGTCAACAAAAACAGTGACTCCACGTCCACGAGACGGAAGTTCCTGACTATGAAAAATTGATTTTTTTCCCTTTTTCTATAAATCTTTGTGAAGGTGGGGAATCTCTTTTTACTTAAAAAAATACGGTTGTTTTATGGTGGGCACACACTAAACACTAATTTTTATGATTTTGGTGCATTCTTATTGGTCATGTAATCATAAATATGAATGCCTCCTACATTTACACCAAATCCACCAATTAAAATCCACTAAACTCATCAAATTTAGTGCTTAATGTGTGCTCTTGGACACACACTAGAAAGATCCCAAAAAAATATACTCCCTCCGTCTCGTTAAACTTTTCCTGTTTCAAATGTTGGGACTGTTCATAACATGAGACAAATTATTAATTTACGTCTAATCTATAAGACTAAATATAGTCATGAGTGATCTTGTTGGATTCGTATTTACGAGTACTTTAATACAGTGAAATTTTTATATTTAATGCTAATACGAAATTAAAGATATTAACGATTAAAAATGTGCGTTGGCAAACGTGTCCGGTCAAAACAGGAAAAGTATTTAGAGACGGAGGGAGTACAAAGTTGGTTTGGATGTTTGGCGATACCGCCGCGAAGCACGACCTTGACAATTAGTTTATTATAACATAAAGATTCTAATATTATTATAGAAATGATACTCCAATGCTAAATATGCTTTTCATCTTATAAACACTATAAATTATTAATCCTTTTTAATTTATAGTAAAGTAGCTGTATAATGTATAAAATAATTACTAATGATTCGAAAGGCACTAATAATTCTAAAGGCGCCCGCCATAGTTGAACTGCCCACTTTAGTCCAGAGAGCATTCAACAAACAATACACCAATGCATTGAATAAACTCAGCCGGCTGATTCCTTTTTCTTAACCTTTAGAATTATTAGTGGTTTTTGAATCATTAGTAATTATTTTATAAAAGACACCCACCCACTAATGACCAATCAAATACAAAAGACGCCAACTAATCTTCCACTAATGTCAGTTTACCAACCCGGGAGCATCTTCTGCTTATTTCCTGTCATCTAAAAAAAAAAAATATTTTCATAATTCTAAAATATAAAAACTAGGAATTAATGATCAGAACAATTATATTGAATAATTATTTAGTTTTACGAAGTTTCCTATCAGTCTAATCGCAATCTCCTTCCCTTGATAACTGTTATCGTCTCCCATTATCATTAACTTCAGCCTAGAAACTGGAAAATAAAATATTAATGATTATTCAATTCTATTCCAGCCTCTATCCTAATTTTACATACAGATTTTATAGTGTGTGCTGAGCACATATTAAAATCCACTTTTTAATTAGGTGTTGTATATTGACTCGCATCCCTTTAACAATGATGGTCATCTTCCTCTTAATTAAAAAGTGTACCGACCCTTTTCCATACTCCTTCCGTCCTATTTGATTGTATACAGTTTCTTTTTTGGATGTCCCATCAATTGTATACATTCCAAAAATGGTAAATTTTTATAATATAAAAAACTTAACTACACTCACTGCCTTCTTCCACTACACCCGCTTTATACATTAAAAATTAGTAGGTTCCACCATTTTACTAACCCTACACTTATTTTACACATTAAATATTAATGGGTCCCACTATTTCATCCACTTTTCTTACTTTCGTGCCACTTCCCATACGTATACTAATTACTGGGACGGAGGGAGTATAACTCTTGTTAATAAGCCAGGCATACGCAAGGGTCATACGTACCTAACCTTGCTATCTACTCCAATATTCTCAGTCTAAAGACTCCAAACGGAACCTTTCAAACATAAACTGTTACATACAGATATAATATATATTTGATCATAGTTAAAAATTCTAAACGCTACTGGTGAGTGGTGATTGGAGAACTTGTACGATAAATACTGCACACTAAGGGAGAATTCTGAAATTCTTTTTCCCACTCATCTTATTGTCTGATCATCAACTCGCTTCTAGCTTTCCTCGCTATATTATTGCCGCCCAGCTCTTTTCTACTTCTCTCTTGTTAGTCATTGTTGAAGTTTAAGCAATTTCATCAGCATCTTTCCTCTCTTTTCACCATAAAAAAAATTTGAAAAAATCATGATAGATCTGAATTCCATTCCATTTGTAGGACCGTTGGTAGCTAAAATTTCCGACAAGACAATAGAAGCACTGTTCCGACATGTAGAATATATGTTCCGTTACAAGGGTCTTGTTAAGGATCTGAAATCTGAAAATGATAAACTTCTGGCTGAGGAGACGAAGATGTCCAGAAAAGCTGAGCAAGAAAGTAACAATGGTAGAATACTGGAGAAGTATGTGGTGGAGTGGCAGAAAGAAGTCCAAGAAGAGCAGGAGAAAGTCACGAGGTGTTTGCAAGAAAATGAGAAGCTAAAGAGCCAACAGCAAAACTGTCCTCGCTACATCCGCTATATCCCACTTCCTCATCCCATCTCTCGTTATAGATTAGGCAAGGAGGCGGCCAAGGTGGCCAAGAGCACAACTGAGCTTACTGCAACCGGAAGTCACCACCTGGCAAGTCAAATTGCATATCTTCCTCTGGATATGAATGTACCTGTAACTGCATTTCAAGAGTTCAAATCTAGAGAAAAGGCTTATGAAAAGCTGGAGGAGCTAGTGACAGATGGAAGCTCTTCAATCCTTGGGATATATGGAATTGGAGGAGCCGGGAAGACTCGATTAATGGAGCGAATCACCACAGAAGCTGGTAAGAAGGGAACCTTTAACAAGGTCGTCCGAGCCAATGTGGGGAATGAGAAATTGGAGAACAAGACCATCATAAGCATACAAAACCAGATTGCAGGTAATTTAGGTTGCGTTTTTGAACGTCAAGATGATGTGGGACATAGAGCTGGTCAGCTGAGATCTAGTTTAAAGCAGGGGGGTAAGATACTCATCATCTTAGATGATGTATGGAGTAGGATACCTTTAGGTACTATCGGAATCATGTCTGCAGATGGTATGAGTTCCAAAGGAGGTAAGATTCTTTTGACGACACGAGATCACGAGGTATGCCAGCGTAACGACTGCGGGGATCTAGTCAAAGTAGAACCTCTTACACCTGCCGAAGCTTGGGATATGTTCAGTGAAACAGTTGGTGCTAAGATAATCGACTCTCTGCAGAATATATCCGTTGCCGAAGACATCTGTAAGAGATGCGGGGGTTTACCACTAGTCATTCTTGCTGTAGGTAACGCCCTCAAATTTAAGCCTCTTGATTCATGGAAGGATGCACGCAATCAACTTAAATTTTTCAAAATTCAAGAACTTCCTGGAATAAGCAAAGACGTGTATGCGTGTTTAAAGTGGAGTTTTGATAACTTGGTGGACGATGCGAAGGCATGTCTCTTGTTGGCTTCTATATTCCCTGAAGATGCTCACATTTATGTTAGCGAGTTGGTTGAGTTAGCAAGAGGCTCCCAGCTTATAAAGGCTGATGATATAAGAACAAGAGTATATTCAATGATTTATATTCTCAAGTCAGCCTCGTTGGTGCTTCAAGTCCGTTGGGGTATTATTGAACGTATCAAACTACATGACATAATAAGGGACATGGCAAGATCCATTGCTACCAAAGACTACGCATTCTTATTCGCAACAAGTAGCTCGTTGCCCAAGCATCCTGCTGATTACTCCGGTCTGAAAGTTCTGCATATAGATGTCGAGGAGGAGACTAGTCTACGTTTTCCAAGTAATGTAAAGTGCCCAGAACTGCATACACTGTCGCTATATTCATCATCATGGACATCATCATGGAAAACACCACGTACACTGATACAGCAGGTATTCAAAAACTGTTTTACATATTCGCTCAATTTTTGATTTATGATAACTATATATCTGATGATAGAATAAAAATAAGTGATTTGACGACAGATAAGTTTAAACGATATGAATTGTTATGAAACAGGATTTATGAGTCACATTTCATTAATTAATGCTATCGTCTAATATAAGCGTTATTTAACTTTTATAATTATTATATTATAATTGCTATAAAATTTTACTAAATTCTGATGTAAATAATAAATTAAATATTGAGTCATACATTAATCAAGATTGTGGAATTGTATAATATCAAAAATTAATTATATTTTAGGTGTCTAATTTTTAATATAAATTAAATTAAGTAATATGTGATTTATAATACATGAACCCGATCCACTTGTTTATTCTAATGAAAAAATATTTATTTTGATCTTGATTAATTAACGAGATAAATAAAAATATATACTAATTTAAATATATTAATTAAATTAATTTTTTTATTTATGCTAAAAGATTAATTATTTAAAAAGTATTCCAGTTAAAGGGAAAATTTTATTCTTGTACAAATACCTTTAAAATAAAGTTACATATGAACTAAATACAAAATATTAAAGTCTATAATATATATTTAAAATATGAAAATTATAAGTAAATATTAAAAATTTGTACAGGGAAATACTCAGTTTAAAAGGAAGGCCTCCAACAATTGACAAAGGCCAGGTATTTTGGACATTCTCAAACATACTCGTATGATGTTTTTTGAACAAAAAGAACAATCTTATAATAACATATTATTAGACAGTGTTATTTGATTTGAAAATTATATATGATTGAATTTTTGGAATGATATATATTTAATATCCCGTGAAAACTTCTCACTGTTAATATTGTTGTACTGATTTTTACAAAGATGACTTATAATACATATCATAAAAAAGTTTAGTTTGATAACTAAAAAATTTATGAATTTTTTATAGTCTTCTACTATAAATTTGAAATCTTTTATATTTATTTTCGATTATCGGATAACTCTCTCTCGTAGGCTTTTGTTTATCAATGTTTCTAGATTTCTTAATCATTCTCTCACAGTAGTATGGATCGATGATTATGTATTTTATATGTATTATAGTTTTAAAAATTTTGTTTAGCCAAATCTTTAATTTATCCTCAGTTTTCATGGTACCTCTGTGCATGAGGTATTTACCTCAAAACAAATTTGATTAAAAATAGATCTAATTTTATTGTTTGGTTCAAATAGGTATTTTAAATTGTTTATTTTGCATATAGCTAAGTTTAGAGTGTTGTTTATAATTGGGTGCCGGCCCACTCTAAATTTATTTATATTATACATATTCTACATCCTCTTTTATATCAAATTGTGCATGTCTTTTATTATTTCAATTCACCAACTATCGGATAATTTAATACAAAGTAGATGTAAGGGAATGCATAAATCACCACCCTTGTTATTTTTATAAGAAAATAATACAAAAAATAAATATGATTACTCTAATGTTAAATTTGAAGAACATGTACGAGTTCTTTAAAATTTAGTTGTTGTATTTAAGAGCATTCACATCCGGACCCAACCCTCAATCCCAAAAATTTACTAAAAATATTAATTCCTCAAAAAAATTACAAATTTTTAAAAGTTTCTTACATCCCATTCCCTATATTCAATCCCTATTCTCATAGAAGTATAAGATAAGAATTGATATTTAATAAAATTATAATGAAATGATAATGAAATGGAGGATGAATAATGTATGAGGTACAAATAGTGAAACTCCAAATATGGGGATTTATTTCTAGTCCCAAAACCAAACCTTATTTTGGGATCTGAATGTAGACTACGTTTTTACAAAAAATAGTAGATTTCTTTAAAATAAATTATGGAGATGCGGTTGGCTTTGGGGGTTAGGGATGTGAATGCTTGATATGATTGATCCAAAATTTTGTTGTGGAATAATTGATATGGTTGATCCAAAATTTAGTTTTGGAATGATTGATATGATGATTGCTCCAAAATTTAGTTTTGAAAAAATTAGTACTATTGATTTAAAATTTAGATATTAGCTTTAATTGATTAAAAATGAATTAAATTTAACCGGAAGTTAGTTAAACTCAATAAAAGACAAGATCCAACCAATAAATTTGATTGGTCTAAAATTTAATTATGATAGTTTAAAATTATTTCAAAAATGGGTCTAAAATTTAGGTGTGAAGATTAAAAATAAATCAAAATTCACGGTTATATATCTCAAAAGATGAAGACTTAACATTATTGATCTAAATTTAACCGTCATATCAAATTATCTCAAAAATCACTAATCGGTTAAGTCAATGATTCAGGAGACTCGTGTCTTTGTAATTATCTTCCTATAATTTTGATATGAATAAAATGATTATTTATTCTTTTTTTAAGCAACATATACAACACATAACACATTTCATCCTTATTATTGGTTAGCTTCCTGAAAAAGCGAATCAGCGTGATCTTTGCAAATATGATAACTACACAGTTATAATATTTGTTCGTAAAATTTATACCTTTAAACATTTGATTAGACGTATATGTGAGGTAGAGTTACCTATCAATCCTTATATTTGTTCCCATATTATTATTTTAATAATAAATTTGAGAGACAAAATAGAAAATAGACAAAGACCAAGAAAGAAGAGGAGAGATGAATTTTTTATTCATAAATATTAAATATGTAATGACCAATAATTATTTAAAAATAGATAATGGATACCGTATCTAAATATGAGTTTAAGAACTTATTTAACTAATCTATTGGACTCTTTAAGATCTCATCCTCTTCTGTAAGGCCATAAGTAGTCATATTTGTCAAAGAAAATAAAAAAGCTGTTATTTTGAAAATTCTAATTATGTCTGCACTTGATGCATGTTATATGCTGGTGAAATAAAACACAAAAAATAACGATTCTTGCTTAAATTTCAGGACTGGATCAACGGTAAAATATTTACAAATCTCATATTTCTGGTGCTTGTGGGGTTTTCCTGGCCAAAGAAATTGTCTCTCAAATCATTGGGTGAACTTAAAACGCTTTGGTTCGACAATTGTGACCTAGAGTTCTTTGGTGAGACGGATGTTAAAATTCTTCCAGAGGGACTGGAAAATCTTTGTATTTGGGGGTCTCGTATGCCAAAACAGTTGAATGTACCAGAACTGAGCCATCTTCGAAAGCTAGACATCTATTCCAGTTCCGGAGGTAGATTATGTATGGTGCCAAATACCATATCAAGACTATCCACTTTAGAAGAATTACGTTTGCCATCTAATTTCTACATCAATGAAGAATGTGCAGAAGGTGGATCATTGTCGGTATTGGACGAGATTAGTGAATTGCCACTGACAAGTTTACATATTCGTTCCCGAGTATCCAAGTCAAGTAAACTTGCAACTATGTTTTCCAACTTACGTGAATTCCATTTGTTTGTTGGTGAGCCGCCGGCTAATAATCGGTCTATGAATCTGTCACCTGTTTCAGTGACGAAGTCAATTAAGTTGGTCAACCACGATCTTGTAGAGGGCTACCAGACTCTATTTCAGAAGGCTGAAGAGGTGATATTGTATGAGACTGATTTCCCAGGGAGTAGCATTGGGATCAGAGACACTAAAGAATTTATCAACTTAAGGTACATGCAAATTGAAAATTGCAAGGCCATGGAGTATCTAGCAAGGATTTCATCACCACAGGGTGAGATTCAGGAAAGTCTTCAGCGATCAACACCTTTTTCTAACCTGATCAAATTGGAAATTAAGTGTTGTCTCAGCCTAAAATACCTCTTCTGCGACTCTATTGCAAGATGTCTCCTCCTACTGGAAGAGCTCCACATAAGGGACTGTCCTTTAATGGAAGAAGTTGTACGTGAGGAGGGCAAAAGTGATGGAAATATCATTAACATGTCCAAATTACGAAAAATGAGCTTAATTAAATTGCCAAGACTCGTACATTTTTACAAGGACAAGATTCCCTATGCGCAAATTCAACCTCTGTTTGACAGAATGGTATGCTTTGCTTACCCCTCATCAATCATCATCATCATATTAATAATATTACTTACACTGTGTAATGATTTCAGGCAAAGTCAATAAACTATTTTGCACATAATTGATTCTTTTTGGTTACTTCTTTATGTCAATATATTTGTTTTAAGGGATTAAAGTTCGGAACTTGTAATCTTTACATTGTATCATGTACTCTCACAAGTAATAATGGCACTTGGAGTAAACTTTGGAAATAAGAACCTAAACAAACACCCTCGGAACTTGTAATCTTTACATTGTATCATGTACTCTCACAAGTAATAATGGCACTTGGAGTAAACTTTGGAAATAAGAACCTAAACAAACACCCGTCACGTATAAAAAAATATGTTTACGCTGTTCATGTAATATAATTTTAAGATTTTTAATACAGTAGTAACTTTTTATTACAAGTAGCACTTGGTTACAGTGTCCTTTCTGTTCTCTGATGGTATGCCTTTCACTGACTATTTGAGCAGGTTGCATTCCCTTCCTTGGAAATGTTGGATATCAGTGGTTTGGAAGACATAACTGACATTTGGGGAGATAATCATGACAATGCTTCCTCCTTTTCCCAACTGAAGACCCTGAAAGTAAAATTCTGTAATAAGCTTAAAAATGTGATCCCACCTGCCACGTTGCGTAGTTCACTCACCTCTGAAGTTGACACTCATGGAAGCCACACAGATTTGGTTACTGGCAGAGCTCCCGAAGGACTTGTGAAGGCCGTGGTTTCTCATAATCCATACAAAAAATTACAAATTTTTTTGAAGAAAACTGTACGTGCGTCGAGATCTGTATGCAGGAGGACCCCCACAATAACAGAAGAAAATTTGAATGATCCCTCTGATATTTCAGTTCAAGTTCCGTCCCAAAACACAAAGGTATGTCCATTGGTTCAAATGAGTCTAGAATGGTTGCCTTGTTTGGAAAAGACAGGGTTGAACTTTGAGGACCAATCCGGAGCAGTGAGTTTGTACCCGGATCTTAAAAAGTTAAATATAAATATATGCGAAAGATTGGAAAACGTGTCCATCATACCTTGTACCAACGGACATTTGATGAACCTTGAGGAAATGTCCGTGAGGCAATGCATTACGATGAGAGAGATAATTGGGGCAGGACCGGCAGGTAAACACAAAATGGCCAATGGCATTGTGTTCCATAAGTTGTGTTCTCTTCAACTAAGTGACTTGCCAAGTTTGACCAGTTTTTGGGGGGAGGCCAGTGGGGAAGCCAACAGCCACAAGGTATATTTATATTTAATTGCCAAATGAAAAAAATTTAAGATTCATAACATGCATCTGTTTTTTTTTTCGCGCGAGAGTGAGAGTATAGATCTATTATTGCTTTTATATCAAACTGACCACTCGTTTCGTCAAAATTTCTCACTTGACCCATCCATTTAATTTCAAACTCAAGCCACTATAAACCAAATACTATATATATTATTTTACCCACATTATTATTCATATTTCTTCACTTAATCATTTATCAAAAATCAAATGTTTGTTTTTTTTACCACAAAATCACTTCGAGTACTTTCATAATTGTCTCTAGTATATATCAAAATAATTTGGAAATTTTTAAAACAACATTACTATGTAGTTTAAAAAATATAAAGTTATAAATATATAATTATATGATCACCTTAGCTATGTTATTTTAAAAATTCCCAAATTATTTTGATAAATACTAGAGACAGTCATGAAAATACTCGAAGTTGTTTTGTAGTAAAAAAACAAACGATTGATTTTTGATAAATGATTAAGTGAAGAAATATGAATAATGATATGGGTAAAATGATATATATTTGGTTTATAATGACTTAAATGAGTCCGAAATTAAATGTGGGTCAAATGAGAAATTTTGACGAAATGAGTGGTCAGTTTGATATAAAACCCGATCTATTACTGTATCAATTTAACATTTCTGAGGTAAAGACGTTAAAGTGAGGAAGGCGCATTCACCGAGTCAGATTGACATAATGTATGGGATTGTTTTTTGTAGGTTGAATTCCCAAACTTGAAGAAGCTTCAACTCCGTTGTGGGGAAAATACTAGCTTACTGGAAATGATAGAGTCAGGCAGAGATGGTTCTACTTTTCAGCTGGAGAACTTAGCAATAAGCTGTGGTAAGGAGATACAAATTCCTAACCGATGGCTACTTCAATTAGATAATCTGGAAAGCTTGTCACTGGAACGCTGTTGGTCAGATGAGCTGAAATCTCTACGTTTCCAGAGATTGAATAAACTCACACTTGGTCAACTTAGTTGCTCTAGTATTTTCTCATTCCCAGACTTTGAAAGACTTCA
->URS0000AE3A4B tRNA from 1 species 
-GCTCCGATCGTCTAGCCCGGTCCAGGACAATGGCCTTTCGAGCCATGAACACGGGTCCGAATCCCGTTCGGAGCA
->URS0001D9EE47 rRNA from 1 species 
-AGCGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGAACCTTTCGGGCTTAGTGGCGGACGGGTGCGTAACACGTGGGAACGCGCCTGTAGGTTCGCAATACTTCAGGGAAACTTGTGCTAATACCGAATGTGCCCTTCGGGGGTAGGAGTTATCGCCTGTAGAGCGGCCCGCGACCGATTAGCTAGTTGGGTGGGGTAATGGCTCACCACGGCGTGGATCAGTAGCTGGTCTGAGAGAATGAGTAGCCACATTGGGACTGAGACACGGCCCACAATCCTACGGAAGGCAGGAGAGGGGGATCCAGCGCGATGGGGGACAGCCTGACGCAGCCATGCCGGGTGAATGATGAAGGTCTTAGGAAAATGAATTTCTTTAACCGGGGGCGATAATGACGGTACCCGGAGAAGAAGCACCGGCTAACTACGTG
->URS000212D443 rRNA from 1 species 
-TCAAGTGAAGAAGCGCATACGGTGGATGCCTTGGCAGTCAGAGGCGATGAAAGACGTGGTAGCCTGCGAAAAGCTTCGGGGAGTCGGCAAACAGACTGTGATCCGGAGATGTCTGAATGGGGGAACCCAGCCATCATAAGATGGTTATCTTGTACTGAATACATAGGTGCAAGAGGCGAACCAGGGGAACTGAAACATCTAAGTACCCTGAGGAAAAGAAATCAACCGAGATTCCCTTAGTAGTGGCGAGCGAACGGGGACCAGCCCTTAAGTTGTATTGAGATTAGCGGAACGTTCTGGAAAGGACGGCCATAGTGGGTGATAGCCCTGTACGCGAAAATCCCTTTGCAATGAAATCGAGTAGGACGGGGCACGAGAAACCTTGTCTGAATATGGGGGGACCATCCTCCAAGGCTAAATACTACTGACTGACCGATAGTGAACCAGTACCGTGAGGGAAAGGCGAAAAGAACCGCGGAGAGCGGAGTGAAATAGATCCTGAAACCGTATGCGTACAAGCAGTGGGAGCCCACTTTGTTGGGTGACTGCGTACCTTTTGTATAATGGGTCAGCGACTTATTTTCAGTGGCGAGCTTAACCGAATAGGGGAGGCGTAGCGAAAGCGAGTCTTAATAGGGCGTCTAGTCGCTGGGAATAGACCCGAAACCGGGCGATCTATCCATGGGCAGGTTGAAGGTTGGGTAACACTAACTGGAGGACCGAACCGACTACCGTTGAAAAGTTAGCGGATGACCTGTGGATCGGAGTGAAAGGCTAATCAAGCTCGGAGATAGCTGGTTCTCCTCGAAAGCTATTTAGGTAGCGCCTCATGTATCACTGTAGGGGGTAGAGCACTGTTTCGGCTAGGGGGTCATCCCGACTTACCAAACCGATGCAAACTCCGAATACCTACAAGTGCCGAGCATGGGAGACACACGGCGGGTGCTAACGTCCGTCGTGAAAAGGGAAACAACCCAGACCGTCAGCTAAGGTCCCAAAGTCATGGTTAAGTGGGAAACGATGTGGGAAGGCTTAGACAGCTAGGAGGTTGGCTTAGAAGCAGCCACCCTTTAAAGAAAGCGTAATAGCTCACTAGTCGAGTCGGCCTGCGCGGAAGATGTAACGGGGCTCAAACCATGCACCGAAGCTACGGGTATCATCTTTTGATGATGCGGTAGAGGAGCGTTCTGTAAGCCTGTGAAGGTGAGTTGAGAAGCTTGCTGGAGGTATCAGAAGTGCGAATGCTGACATGAGTAACGACAATGGGTGTGAAAAACACCCACGCCGAAAGACCAAGGTTTCCTGCGCAACGTTAATCGACGCAGGGTTAGTCGGTCCCTAAGGCGAGGCTGAAAAGCGTAGTCGATGGAAAACAGGTTAATATTCCTGTACTTCTGGTTATTGCGATGGAGGGACGGAGAAGGCTAGGCCAGCCTGGCGTTGGTTGTCCAGGTTTAAGGTGGTAGGCTGAGATCTTAGGTAAATCCGGGATCTTAAGGCCGAGAGCTGATGACGAGTGTTCTTTTAGAACATGAAGTGGTTGATGCCATGCTTCCAAGAAAAGCTTCTAAGCTTCAGGTAACCAGGAACCGTACCCCAAACCGACACAGGTGGTTGGGTAGAGAATACCAAGGCGCTTGAGAGAACTCGGGTGAAGGAACTAGGCAAAATGGCACCGTAACTTCGGGAGAAGGTGCGCCGGTGGAGGTGAAGCATTTACTGCGTAAGCCCCTGCCGGTCGAAGATACCAGGCCGCTGCGACTGTTTATTAAAAACACAGCACTCTGCAAACACGAAAGTGGACGTATAGGGTGTGACGCCTGCCCGGTGCCGGAAGGTTAATTGATGGGGTTAGCGCAAGCGAAGCTCTTGATCGAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGCGTAACGATGGCGGCGCTGTCTCCACCCGAGACTCAGTGAAATTGAAATCGCTGTGAAGATGCAGTGTATCCGCGGCTAGACGGAAAGACCCCGTGAACCTTTACTATAGCTTTGCACTGGACTTTGAATTTGCTTGTGTAGGATAGGTGGGAGGCTTTGAAGCGTGGACGCCAGTCTGCGTGGAGCCAACCTTGAAATACCACCCTGGCAACTTTGAGGTTCTAACTCAGGTCCGTTATCCGGATCGAGGACAGTGTATGGTGGGTAGTTTGACTGGGGCGGTCTCCTCCTAAAGAGTAACGGAGGAGTACGAAGGTGCGCTCAGACCGGTCGGAAATCGGTCGTAGAGTATAAAGGCAAAAGCGCGCTTGACTGCGAGACAGACACGTCGAGCAGGTACGAAAGTAGGTCTTAGTGATCCGGTGGTTCTGTATGGAAGGGCCATCGCTCAACGGATAAAAGGTACTCCGGGGATAACAGGCTGATACCGCCCAAGAGTTCATATCGACGGCGGTGTTTGGCACCTCGATGTCGGCTCATCACATCCTGGGGCTGAAGCCGGTCCCAAGGGTATGGCTGTTCGCCATTTAAAGTGGTACGCGAGCTGGGTTTAGAACGTCGTGAGACAGTTCGGTCCCTATCTGCCGTGGACGTTTGAGATTTGAGAGGGGCTGCTCCTAGTACGAGAGGACCGGAGTGGACGAACCTCTGGTGTTCCGGTTGTCACGCCAGTGGCATTGCCGGGTAGCTATGTTCGGAAAAGATAACCGCTGAAAGCATCTAAGCGGGAAACTTGCCTCAAGATGAGATCTCACTGGAACCTTGAGTTCCCTAAAGGGCCGTCGAAGACTACGACGTTGATAGGTTGGGTGTGTAAGCGCTGTGAGGCGTTGAGCTAACCAATACTAATTGCCCGTGAGGCTTGACCAT
->URS0001E7BB53 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCATGTCGAGCGAACGGACGAGAAGCTTGCTTTTCTGATGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATTTTGAACCGCATGGTTCATAAGTGAAAGACGGTCTTGCTGTCACTTATAGATGGATCCGCGCTGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCATAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACATATGTGTAAGTAACTGTGCACATCTTGGCGGTACCTAATCAGAAAGCCACGGCTAACTACGTG
->URS0001963736 lncRNA from 1 species 
-GTCCAGCCTTCAGCCCGGTTCGGTTTCTAGGTTGGACCCAGGGCAACTCCAGCCGTTTCCAGACCCGGTTTCGGAAAAGAAATGATCAAATAAAGCCTCGAAAGCTCCTGAGGTAAAAGCCGCAGAGGATCTGAGCGGGACGGCCCAGCCCCTCCGGAGGCAGCGAGCGCGTGGAGGCGGTGGCTCCGGCTCAGGAAAGAGAGAAGCTAACAAGAAAAGCCACTCTTCTTGTTTCCATCTCCACAGTGGAAGAAATGCCCTCTTTTTTAGTTAAGAAAACAGAGAGTCAAAAGAAGATGGGAGACCTCTGCACACTCAATCAGGAAATTCCTGGAATACCAGACTGTTTCCATCAATGGTAGGTCATTGCTTTTATCAGCTTGTATTGCTGAAATGCAGTAAGCACTGATTACACAAGCACTAAATGCCAAGCAATGCTCATAAATCTTGGTAGGAACATGAGCTTTAGAGTTGAGGTCTCGGATTTTCTTTTTACCTTGGTACTGAGTCAAAAAGAAAGATTTTAGAATCAGGGTCTTCTTCCACCCCTAATAAAATGCTCTCTTCACTCTCTTTGTGGAGTATT
->URS00015412A1 rRNA from 1 species 
-TACGTAGGGTGCAAGCGTTATCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGTTTGTCGAGTCTGTTGTGAAATCTCGAGGCTCAACCTCGGGTCTGCAGTGGGTACGGGCAGGCTGGAGTGCGGTAGGGGAGAGTGGAATTCCTGGTGTAGCGGTGGAATGCGCAGATATCAGGAGGAACACCGATGGCGAAGGCAGTTCGCTGGGCCGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS000242BE45 lncRNA from 1 species 
-CTAGAGAAAAATCAGAAACAACGCCCTACTGTTCCTTCATCTTCCTCAGATTTCAACTCACCTCAACTCGCCCGAGTTCACTCAAATGGTCCCCTTCCCTCCACGTTATTTGATTCCCAACAGTTTTTGTTAGAAAGAATTCGAATATTCTCTCAAAATCGCACAATTTTGGGTACGAAAGAACGATTTGTTGGATGAATGGGAGCTGTGGATAGATGTAAGTCGATCCACGCCCTCCATTTGTCCCAAAATTGTTCAAAAAACTCGAAGATATTTGGATTTTTGGGCAGATTTTTGAGATTTTTTGAAGGCTATATATATGAGGTAAGTTCTATGTGCTAGGTTAGAGGGAGATCAGAGAAAAATCTTCAGAACTTAGCCGAGTAATTTTCTAGGGTTTTAGTTGTTATCGTCTTCAAGTCTACTTTTTCTTCAAAAATAAAACATACCAAAAAGAGCACAATGGTCTGAGTTCAATTTTTCTAGTCGAGTTTACTTTATTTTTTAGAGAAAAATAAAAAAAAAAATCACTGAGCACAGATATGTCTTAGTGCTTGTTCTTTCTTTTGAAGTTCTGTTTTTCTCAAGAGAACTTGATTTTGAAAATTCAAGTTATAGTCGAGTTTGTTTTGGAGTTCAAAATTTCGGTTAGTGGCTCAATTCAAGTTGGTTGATTCTTGTCTTCTTGTTGCTGTTCGTTTCAAGCTCTAAGCCGCGGTTTTGCTCGAGTCGATCTAGTTGCTGTAATCCCTGAAGTTTTTTGTTAATTAAAAGGTTCATCTCTTCACTCCTTCTTAATTTGTTCTGGTATTGATCAAAATGTGATGATGGCTGAGACTTTGCTAGATTGGAAGTGTTTATGAGCTGGTTCATGAGAAACCAGTCTGTGATGCAGTTTTTTTTTGTTTTCTTTCTTGGCTCCGGATACATCTCCCTTATTCTATTCGTTCTGTGTGCTCCAATTCATTCGGGTTATACCCTGTGTTGCCTTGTTATTTACTGGTGAATGGTGTATAAATTCATTTTTCTTTACCATACAGAATTCATGTCTGTTCTTGAATTGATTAAAATTTCCAAACATTGAATGCTAAGGTTGGGTATGGTCTGGATAAGCCAACAGCTTTATAAAATATGAGTGTCACACAGTTTTTAATGAAATACACTAACTTCCACAAGCAGCTTGTATTTAGTTGAGATCCACATTGTCCTTTTAAGAGATACTGTTGATGTTAGTAAGTAGTTAAGAAAAAAAACTTTTAAGTCATGAATCATGATTCTTTTAATTGCATTTGAAGCAAAAACATCAATGGTGAATAATGAAACAAAACTGGAAAGCAGAGAACAACTAGAGCAGTTAGCTTCACTGATTCTCTTTGAGCTCGAAATGTACATGTGAGAGAATGCAAAGCAATGACTACATCAGAAGAAAATTGTTCTAGAGTTAACTTTCTTTCCTTTTTGATGTATTGGCTATCTGTGTATGGTGAACGTGATATCAGGAAATGTGTGTCTTCTATCACTATTACTCCTTGTTAAGTCATATGTAATTGACTTGTTATGATATCAGTAGACTTACTTATGTTTAGACATAGTTTAAATGTTTTCTTTTGTGCTGTTTTGTTGCCTATACGGCCCTGCCATTCAAGAGAACATGGTGATTTCTTAGGCTTGCATATCACTGTTGAAATGCATCTATCTTAGTGTTTGACAAAAGAATATGTCACACATAGGATTAACAAGATGACTGAAGTTGGTTAAAATTAAGTCAAATTGAATGTTAGTTTAAAGTCATTTACCTGCTACATGCTAATATTTTTATATAACAGTGTGACGACCCGACTAGTCATCGCATGAATTACCGCCCTGTTTTTCCTATTTTTGCTTCTTTATGCTTCGTTATTCGTGTTTTATGTGGTCGAGTTGATTGGTTTGCATTTGGTGTGATTTTAGTAAGAAATGAGACACTTAGTCTCTTTTAAGAAGGCTTAAGTTGGAAAAGTCAACTAGATGTTGACTTATGAGTTAGAGGGCTCGGATGTGAGTTCTTATGGTTCGGTTAGCTTCGGGAGGTGACTTGTGACATAGGAGTGTGATCGGAAGTGGTTTTGGAGGCCCAGTGTAGAATTAGGCTTGAATTGGCGAAGTTAGTATTTTGGCAATTTCTGGTTGATAGGTGAGATTTTGATCCGGGGATCGGAATGAAATTTCGAGAGTTACTGTAGCTTTGTTATGTCATTTGTGATGTGAGTGCAAAATGTTAGATCATTCGGACACGGTTTGGTTGGGTTTTGATCAAAAGTGTGTTTCAGAAGTTTCTAGAAAAGCTAGGCTTGAATTCGATGTGAACTGATGTATTTGGTGTTGTTTGAGGTGTTTTGATGATTAGAACAAGTTTGAATGAGGTTTTAGGATGTGTTGGTACTTTTGGTTAAGGTCCCGGGGGCCTCGGGTGGTTTCGGATGGCTAACGGGAAGTTTTGAGTCATTGGAGATTGCAGAAAATGCAGCAGCAGTTGCAGAGGATTTTTGGCCTTCGCGATCGCGTGAGGTCCCTCGCGATCACGTAGAAGGAAGTTGGGTGGCCCTGCATTTGTGCTTCGCATTAACGTCTGCTGCCTCGCATTCGCGAAGGGGCCTTGAGGTTATGCTTTGCGTCCGCGTGATGGGTATCGCGTTCTCATAGTGGAGATGGGCACGTGAAGGTCGAGGAGCTATTGCTCTTCGCGCTCGCGTAAGTGGTATCGCGTTCGCGTAGGTTCAAAGTTCCAAAGCATCGCATTCACGGGTGTGGTGCCGCATTCGTGAAGGGTTATTTGTGGTTCAAGGAAAATTGTGCATCACGAACGCGTGGGTTTGACCGCGTTCGCGAAGGAGGGATTTCCAAAACTGAACAGTGAAGTTTTTAAACATTTCCTCCGTGAGTTTTAGTCTTTTTTCCACCATAGTTGAGTATTTTGAGAGCTCTTTGAGGGGAATTGAAGAGGGATTCAAGGAGAATTGGTTGGAGGTAAGTTCTATGAACCACAAACGTGATTATATTGTGAAGTTAACCTAGAAATTCATGGAAATTTAGCTAAAAATAGAAGAACTAGGGCCTGGGATTTTGAGATTTTAAATTGGGATTTGAAGGGACATTTGAGGTCGGATTTGAGAAATTTTGATATGTATGAACTCGTGGCGAGATAAGGAACCCGTTGATGTGAAAATTTCTGAGTTTCCAGAAGTAAACCCGGGGCTCGGGTTTTGCTAATTTCGGGATTTTTGATATTTTTCGATTGTTTTCGCTTGGCCTTTTTCCCCTTAGCATATTGTGACGTATTCGCTCTGGTTTTGGTTAGATTCGATGTCCGAGAGGCTGATTTGAGAGGCAAAGGCATAGCGAGCTAGAGCTTTAGCCGGTTCGAGGTGAGTCATGAATGTAAATGATATCCTGAGTGTTTGAAACCCCAGATTTGCACATCGTAGTGCTATATTGAGGTGAGACACGCGCTTGATGATGAGAGTGGGGTCATGTACTATTGAGGATTGGGACTTGGTCCGTCCTGAGTGTTGTTTTTACCGTGCATTTTGATTGAAGCTTATTTGTTATCATCATTGTTTGGACTAATTGCCATACTTGGACTTCGTGCCAACTATTTGAACCCTTCGGGGAGTTTTATCACTATTTCCTCACTGTTTTGACTTACTACTTGAACTTACTCGTACCGTTTTCCACTGTTTTACAACTCAACCACTTTTTACTCGGTTTTGAAACTAAAATGATACATATTAAATGATATTTTGGGCTGAGAACTACTGTTTTACTAATGCCCGAGGGGCTTATATGATTTCTGGACGGAGTACGGCCAAAGGCCAGATGGGAGGATACTATGGGATCGGGCTGCGCGCTGCAACAGTGTTATACTGATATTGATACGAGGCTGAGGGCCTAGATTTGATGCCACGAGATGACTTGATATTGTGCTTGGGCCGTAAGGGGCCCCTCCCGGAGTCTGCACATCCCCAGTGAGCGCCGTCAACGATAAATGTATGGATCGGGTTACACGCCGTAGCAGGTACTATAGGGTACCGTTCTATGTGTTGATTTTCTTTATATGTCTGTCACCTAACTGCTTATTTGTGGTAGCATTTCCACATTTCGTTTCCATTGGTTTATTACTTTCATATTACTTATTTAAAATGCTGCATTATAGATTACTCTGTGTTTCTTCGTGATTTCTTATTCTCAGTCATTATTTATGCTTATTACTCACTGGTTCGGAGTACTCACATTACTCCCTGCACCTTGCGTGCAGATCCAGGTGCATCTGAGGCTAAGTGAGGATTTTTAGTTGAGAAGCGCATATCCGGGAGCATCGAGGTAGCTGCATGGCATCCGCAACCCTGATCTCTCCTTTCTATCCTTTTGTTTTATN
->URS0000BE1683 snRNA from 1 species 
-TAACTTACCTGGAGGGTAAGTCCAGTAGTCAACTTCGCTGGACTTATTGGGCATGATGGGGCATTGCACATCCCGTCCGGTCGTGTTCAACGAATGTCATTACGGCATCTCGGCCTTATAATTTCTGGTTTGGATTCCTCTGGCTTGCCGGGGAATCCC
->URS000002E6E7 rRNA from 1 species 
-AACGAACGCTGGCGGCGTGGATAAGACATGCAAGTCGAACGGGATTATTTTTGTAGCAATACAGAAATAATTCAGTGGCGAACGGGTGCGTAACACGTGGGCAATCTGCCGAAAAGTGGGGGATAGCTCGCCGAAAGGCGAATTAATACCGCATGTGGTGAGGGACGACATCTTCCTGAATCCAAAGCCGGGGCAACCTGGCGCTTTTTGTAGGAGCCCGCGGCCTATCAGCTTGTTGGCGGGGTAACGGCCCACCAAGGCTATGACGGGTAGCTGGTCTGAGAGGACGACCAGTCACACTGGAACTGAGACACGGTCCAGACACCTACGGGTGGCAGCAGTCGAGAATTTTTCTCAATGGGGC
->URS0001E82C61 rRNA from 1 species 
-AACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGAGACCTTCGGGTCTAGTGGCGCACGGGTGCGTAACGCGTGGGAACCTGCCCTTAGGTTCGGAATAACTCCCCGAAAGGGGTGCTAATACCGGATAATGTCTTCGGACCAAAGATTTATCGCCTTTGGATGGGCCCGCGTTGGATTAGCCAGTTGGTAGGGTAAAAGCCTACCAAGGCGACGATCCATAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCGACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATACAGCAATGCCGCGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTTACCCGGGATGATAATGACAGTACCGGGAGAATAAGCTCCGGCTAACTCCGTG
->URS0001712CA9 rRNA from 1 species 
-AGAGTTTGATCCTGGCTCAGAACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGCGAACGTTTCTTCGGAAACAAGTAGAGTGGCGGACGGGTGAGTAACGCGTAGGAATCTGCCTAAGGGTACGGAATAACGCCGGGAAACCGGTGCTAATACCGTATACGCCTTAAGAGGGAAAGCGCTATGTAGCGCCCTGGGATGAGCCCGCGTTAGATTAGGTAGTTGGTGAGGTAATGGCTCACCAAGCCTATGATCTATAGCTGGTTTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGGGAAACCCTGATCCAGCGATGCCGCGTGAGTGAAGAAGGCCCTAGGGTTGTAAAGCTCTTTCAGTAGGGAAGATGATGACGGTACCTACAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGAGTACGTAGGCGGTTTGATAAGTTGGGAGTGAAATCCCGGGGCTTAACCTCGGAATTGCTCTCAAAACTATTAGACTAGAGTATGGTAGGGGACAGTGGAATTCCCAGTGTAGAGGTGAAATTCGTAGATATTGGGAAGAACACCAGTTGCGAAGGCGGCTTACTGGTCCGGATCTGACGCTGAGATGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGGGTGCTAGGTGTTGGGTAGCTTGCTATTCAGTGCCGAAGCTAACGCGTTAAGCACCCCGCCTGGGGAGTACGGTCGCAAGATTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGCAGAACCTTACCAGCCCTTGACATACCAATCGCGATTTCCAGAGATGGATTTCTTCAGTTCGGCTGGATTGGATACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGCCTTTAGTTGCCAGCATTTAGTTGGGCACTCTAGAGGGACTGCCGGTGATAAGCCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTACGGGTAGGGCTACACACGTGCTACAATGGCAGTGACAATGGGTTGCGATCCCGCAAGGGCTAGCTAATCCCCAAAAACTGTCTCAGTTCGGATTGTTCTCTGCAACTCGAGAGCATGAAGTTGGAATCGCTAGTAATCGTGGAACAGCATGCCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTTGGTTTTACCCGAAGGTGGTGCGCTAACCGCAAGGAGGCAGCCAACCACGGTAAGGTCAGCGACTGGGGTGAAGTCGTAACAAGGTAGCCGTAGGGGAACCTGCGGCTGGATCACCTCCTT
->URS0000F24664 rRNA from 1 species 
-TACGTAGGGGGCAAGCGTTGTCCGGAATCATTGGGCGTAAAGCGCACGTAGGCGGCTTCGCAAGTCCCATGTGAAAGCCCACGGCTTAACCGTGGAAGTGCATGGGAAACTGCAGAGCTTGAGTACTTAAGAGGATCGCGGAATTCCCGGTGTAGAGGTGAAATTCGTAGATATCGGGAGGAACACCAGTGGCGAAGGCGGCGATCTGGGAAGATACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGG
->URS00003B973F rRNA from 1 species 
-CGACGAGTTTGATCCTGGCTCAGATTGAACGCTGGCGGCATGCTTTACACATGCAAGTCGAACGGTAACGGGGACTTCGGTCTGCCGACGAGTGGCGAACGGGTGAGTAATATATCGGAACGTGCCCAGTAATGGGGGATAGCTCGGCGAAAGCCGGATTAATACCGCATACGCCCTGAGGGGGAAAGTGGGGGATCTTCGGACCTCACGTTATTGGAGCGGCCGATATCAGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCTGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGAGTGAAGAAGGCCTTCGGGTTGTAAAGCTCTTTCAGCCGGGAAGAAAACGCATGGGTTAATACCCTGTGTGGATGACGGTACCGGAATAAGAAGCACCGGCTAACTACGTG
->URS00019E32A1 tRNA from 1 species 
-GGATATAGTTCAGCTGGTAGAATGTGTGCCTCACATGCACAGGCCTGGGGTTCAATACCCAGCACCA
->URS0000ED2EE6 rRNA from 3 species 
-CAAAATGGTGCCGTAACTTCGGGAGAAGGCACGCTGACACGTAGGTGAAGTGATTTACTCATGGAGCTGAAGTCAGTCGAAGATACCAGCTGGCTGCAACTGTTTATTAAAAACACAGCACTGTGCAAACACGAAAGTGGACGTATACGGTGTGACGCCTGCCCGGTGCCGGAAGGTTAATTGATGGGGTCAGCGCAAGCGAAGCTCCTGATCGAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGCGTAATGATGGCCAGGCTGTCTCCACCCGAGACTCAGTGAAATTGAACTCGCTGTGAAGATGCAGTGTACCCGCGGCAAGACGGAAAGACCCCGTGAACCTTTACTATAGCTTGACACTGAACATTGAGCCTTGATGTGTAGGATAGGTGGGAGGCTTTGAAGTGTGGACGCCAGTCTGCATGGAGCCGACCTTGAAATACCACCCTTTAATGTTTGATGTTCTAACGTGGACCCGTAATCCGGGTTGCGGACAGTGTCTGGTGGGTAGTTTGACTGGGGCGGTCTCCTCCTAAAGAGTAACGGAGGAGCACGAAGGTTGGCTAATCCTGGTCGGACATCAGGAGGTTAGTGCAATGGCATAAGCCAGCTTGACTGCGAGCGTGACGGCGCGAGCAGGTGCGAAAGCAGGTCATAGTGATCCGGTGGTTCTGAATGGAAGGGCCATCGCTCAACGGATAAAAGGTACTCCGGGGATAACAGGCTGATACCGCCCAAGAGTTCATATCGACGGCGGTGTTTGGCACCTCGATGTCGGCTCATCACATCCTGGGGCTGAAGTAGGTCCCAAGGGTATGGCTGTTCGCCATTTAAAGTGGTACGCGAGCTGGGTTTAGAACGTCGTGAGACAGTTCGGTCCCTATCTGCCGTGGGCGCTGGAGAACTGAGGGGGGCTGCTCCTAGTACGAGAGGACCGGAGTGGACGCATCACTGGTGTTCGGGTTGTCATGCCAATGGCACTGCCCGGTAGCTAAATGCGGAAGAGATAAGTGCTGAAAGCATCTAAGCACGAAACTTGCCCCGA
->URS00025C3F13 lncRNA from 1 species 
-CTTGGGGATTTGCAGCTAATGTAAGAACCAAATGCTATTTAAAAAAAAAAATGTTTTTTAATACTTTTAAGTGTTTTTTGCACACTTTTGAAATATATTTTTACTTTATCTGCACATGCAAAGATAGGTCACGTGTAATAATGATTTCCTAATATAAATAAAGAGGGAACTAGTTAAAAAAAAAATTGAATAAGAATTCCTTGAGAAGGGGAGATGATTAGTCTGAAATGGGTCCACGTATAATGAGCAAAAACCTCCCAGGCGAGCAGCCCCAGGGCCAGAGAATGGGAGACAAGCCTTAAAGTATAGCTGTAGTTGAGACGGTCCTATTTGGGCAGGGGTGAAAAATGCTCCATCGGGAGATCTATATTCAGAAAAATCATGAGATGTATTAAGATAAACAAGACTAAAACTGAAAATATGTTAACCTATCTTTGATCATTAGTCCTTAAACAACAGAGAAGTACTTCTGTTGTCAAAAGTTCAATCAGGTCACAAGCACACCAGCTGCATTTGCTGTCAATCGTCACTGGAATGAATGATTTGAGTTTTCTGGGCCAATGAATGTTTCAGTAGAGTCGGCGAAAACTTAGATAGTCCAGAGATATGCCTAGCTTAAACACAGTGGCATCGCTAAGGGAGCCATGGTCCACCGATCATCATGCCGTGCCTCCAAGTGACGACGCTGTTTCATGGGCCGGCCTTAGGGTTGAGCTCACACAGCTACCCGGTGGAAGATTTCATTATTCTCCACCCGGGATTATTAAAAAACCCAAAACATTGTGACAGGGGCGGTGCATACCAGGAAGCAGAGGTGTGGCTAAAAG
->URS0000978C1D SRP_RNA from 2 species 
-GCTGGGCATGGTGGCGCATGCCTGTAATCCCAGTTACTCTGGAGGCTGAGGCAAGAGAATCGCTTGAACCCGGGAGGCAGAGGTTGCAGTGAGTTGAGATAGCACCACTGCACTCCAGCCTGGGTGACAGAGCCAGACTCTGTCTCAA
->URS000131FCF1 rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCCTTACACATGCAAGTCGAACGGTATCAGGTCTTCGGATGCTGACGAGTGGCGAACGGGTGAGTAATACATCGGAACGTGCCTAGTAGTGGGGGATAACTACTCGAAAGAGTGGCTAATACCGCATGAGATCTACGGATGAAAGCAGGGGATCGCAAGACCTTGTGCTACTAGAGCGGCCGATGGCAGATTAGGTAGTTGGTGGGATAAAAGCTTACCAAGCCGACGATCTGTAGCTGGTCTGAGAGGACGATCAGCCACACTGGGACTGGGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGCAAGCCTGATCCAGTAATGCCGCGTGCAGGATGAAGGCCTTCGGGTTGTAAACTGCTTTTGTACGGAACGAAAAGCCCTGGGTTAATACCCTGGGGTCATGACGGTACCGTAAGAATAAGCACCGGCTAACTACGTGCCAGCCGCCGCAGTAATAC
->URS00013B03C6 rRNA from 1 species 
-TACGAAGGGTGCAAGCGTTACTCGGAATTACTGGGCGTAAAGCGTGCGTAGGTGGTTGTTAAGTCTGATGTGAAGCCCTGGCTCAACCTGGGAACTGCAGTGGATACTGAGAAGCTAGAGTGTGTCAGAGGATGGTGGAATTCCGGTGTAGCGGTGAAATGCGTAGAGATCGGGAGGAACACCAGTGGCGAAGGCGATCACCTGGGATGTTCTGACGCTGAGGAGCGAAAGCTAGGGAGCAACGGGG
->URS000157F4D5 rRNA from 1 species 
-AGTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGAGTGGCGGACGGGTGCGGAATACATCGGAATCTACTCTGTCGAGGGGGATAACGTAGGGAAACTTACGCTAATCCCGCATAAGATTGTATGAGCCGATGTCGGATTAGCTAGTTGGTGGGGTAAAGGCGCACCAAGGCGACGCTCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGTAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAAGGGGCGCAAGCCTGATCCAGCCATGCCGCGTGGGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTGGGAAGGCGGTACCCAAAGAAGAAGCACCGGCGAACTTCGTGCCAGCAGCCGCGGTAATAC
->URS00000C806B tRNA from 1 species 
-TTTTAAGTAGTTTATGGATAAAATATTAAGTTGTGGTCTTAGAGAAAAAGATTGCTTTCTTAAATG
->URS00008F77FE rRNA from 1 species 
-TACGGAGGGTGCGAGCGTTGTCCGGAATCACTGGGCGTAAAGGGCGCGTAGGTGGCTTGGTAAGCGTGTGGTGAAAGCTCGGGGCTCAACCCCGAGTCGGCCATGCGAACTGCCGAGCTTGAGCACTGTAGAGGCAGACGGAATTCCGGGTGTAGCGGTGGAATGCGTAGAGATCCGGAAGAACACCAGTGGCGAAGGCGGTCTGCTGGGCAGTTGCTGACACTGAGGCGCGACAGCGTGGGGAGCAAACAGG
->URS000080C6B8 rRNA from 1 species 
-TACGGAGGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCGCGTAGGCGGTTTTCCAAGTCAGAGGTGAAAGCCCGGGGCTCAACTCCGGAATTGCCTTTGAAACTGGGAAACTTGAACACGGGAGAGGTGAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAGGAACACCAGTGGCGAAGGCGGCTCACTGGACCGTTGTTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGG
->URS000134990F rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCCTACCACATGCAAGTCGAACGCGTGGCGGACGGGTGAGTCATGTCTGGGAAACTGCCCGATGGAGGGGGATAACTACTGGAACCGGTAGCTACTACCGCATACCATCGGATGTGCCCCGATGGGATTAGCTAGTAGGTGGGGTAACGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAAGGGGCGAAAGGCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGAGGAGGCGTTACTCGAAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATTC
->URS0000B4737C rRNA from 1 species 
-TTGCCTACGGGGGGCAGCAGTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGAGCGATGAAGTATTTCGGTATGTAAAGCTCTATCAGCAGGGAAGAAAATGACGGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGTAGACGGTCCTGCAAGCAAGATGTGAAAGCCCGGGGCTCAACCCGGGGACTGCATTTGGATCT
->URS00000D2088 rRNA from 1 species 
-AACTCCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGGCGAGAGCCTGAACCAGCCAAGTAGCGTGCAGGATGACGGCCCTATGGGTTGTAAACTGCTTTTATGCGGGAATAACGTTCACTACGTGTAGTGTTTTGCATGTACCGCATGAATAAGGATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATCCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGAGCGTAGGCGGAGGATCAAGTCAGCTGTGAAATGTAGACGCTCAACGTGTGCACTGCAGTTGAAACTGGTTCCCTTGAGTGCGTAAGAGGCAGGCGGAATTCGTCGTGTAGCGGTGAAATGCTTAGATATGACGAAGAACTCCGATCGCGAAGGCAGCTTGCCGGGCCGCAACTGACGCTGAAGCTCGAAGGTGCGGGTATCGAACAGGATTAGATACCCTGGTAGTCCGCACAGTAAACGATGGATACTCGCTGTCGGCGATATACGGTCGGTGGCCAAGCGAAAGCGTTAAGTATCCCACCTGGGGAGTACGCCGGCAACGGTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGAGGAACATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCCGGGCTTGAATTGCTAACGACGGTTACTGGAGACAGTTTCCTTCCTTCGGGACGTTAGTGAAGGTGCTGCATGGTTGTCGTCAGCTCGTGCCGTAAGGTGTCGGCTCAAGTGCCATAACGAGCGCAACCCTTGCCGTTAGTTGCCATCAGGTCATGCTGGGCACTCTATCGGGACTGCCATCGTAAGATGTGAGGAAGGTGGGGATGACGTCAAATCAGCACGGCCCTTATGTCCGGGGCTACACACGTGTTACAATGGGGGGTACAGAGGGAAGCCACCTGGCGACAGGGCGCGGATCCCGAAATCCCTTCTCAGTTCGGATCGGAGTCTGGAACCCGACTCCGTGAAGCTGGATTCGCTAGTAATCGCGCATCAGCCATGGCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCAAGCCATGAAAGCCGGGGGCGCCTGAAGTCCGTAACCGCGAGGATCGGCCTAGGGCGAACCTGGTAATTGGGGCTAAGTCGTAACAAGGTAGCCGTACCGGAAGGTGCGGCTGGAACAACTCCTTT
->URS00016E4775 rRNA from 1 species 
-TACGTAGGGTGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGTTCGTCGCGTCGGCTGTGAAATCCCGAGGCTCAACTCCGGGCCTGCAGTCGATACGGGCAGACTGGAGTTCGGCAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGGTCTCTGGGGCCGATACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS0002360704 lncRNA from 1 species 
-TTTTTTTTACTTTTTTCTGTATTTCTTTTTTCTTTTTGTTTCTTCACTCGTTTTCTTCTGTTTTTTATATTCTTTGTTTTTTCACTGGGTTTCTTCATCTTTTTGTTGGGTTTTATTGTTTTTCTTTTATTTGCTTTTGCACGATTTTCTGTGTTTCTTTCTCGATTTCATTTTTTTTCCTGTTTTCTTTAGTTTGTTTTTATTTTATTTGTGTGGTTTCATTTGTTT
->URS00018D31DC rRNA from 1 species 
-TGCCAGCAGCCGCGGTAATACGAAGGGACCTAGCGTAGTTCGGAATCATTGGGCGTAAAGAGAATGTAGGCGGAATTATAAGTCTGGTGTGAAATCCCACAGCTCAACTGTGGAACTGCATCGGATACTGTTTTTCTTGAATTGTAGAGGGGGTCGCGGAATTTCTGGTGTAGAGGTGAAATTTGTAGATATCAGAAAGAACACCGGTGGCGAAGGCGGCGACCTGGCTATTAATTGACGCTGAGATTCGAAAGCGTGGGTAGCGAACAGGATTAGATA
->URS0000E7B100 lncRNA from 1 species 
-ACATAAGCAGTAGGTGTCTGAAGGCTGGATTTTCAATACAGGCATAAAAGATAGTATTTAAATAAAACAGAAAGCAGAATTTGAATTGTCTTGGCTCAGGTTGGGACATCCACTGAATCTGATGTTCCTGGTACTGAAGACCCTTGGACCCACCTAGCACGGCTGTAGACTTTGCGGTCTGGCATACACTGGGATATCTGTGGACAGAACTCCCCTGCATGGTGAAGCTTTTTTGTTGGCTGCACAGGAGAGTGACTGTACAGTTGGCTCTAGTGTGGCTGCACACTAGACTGTCTCTCGAAAGGAGCTGAGCTTCATTCCTATCCCTAGGAAAACTTCAGCTAAAGTTAACTTGGTTGGATGCCATGTCTGCTTCCTTTCATTTCAAAGTAGGAAAAGTCAGAATGAGAACACTAGTTCTTCACTTCAGTTCTGCTGTCATGAGGATCGAGTACCTGTAGAGCTCTATCATAGGGCTACAGGTAACACTCTTGTATAAACTGGAGCAAAAATGTTTGCCACAGTCCAGACCCTGAAATAAAATGGACATTTAGCAAAAGATGACCATTTTCAAGGTTACATCCGGAGTGGGAAGAAAACACCACAGATTTTGCATCTTTGTGGCGTATCTTGAAGATGTTCCAGCAAAGTCATCAGTTTGGACTGTGCCCAACAGATTTGTACAAGGGGAAAGAATAAGAGGAAAGAAAATGAACTCCTTATTCTATCCCACTCCACCAAAATGCAATCACATCCATGGATTTTGTCAGAGG
->URS0001BF4730 lncRNA from 10 species 
-ctggtccctaagcccttccagcccaggagccagacctgtgagcaaacaagcctttagtgattccaggctctggctggaaccttgagtcttctcagctTGGGGCATGCACCTCAGGGGGAGCCAGCATCAGTGTCCAGCCCCAAGAGCTTCCCTGTACGTCTCAGTGAGTCTTCACATGCCTCCAACTGCCTGGACAACCACACGTGATACCTGTCCTGCCAAACGTGtcctgaacccataaaatccagagaaaagaaaatcgttttaaactgctgaggtttggggtctttcctgtgctgttttcgtgatagtgaatgagtgtcacgagatccgatggttttaaaaacgggagtttcctgcataagctctctctctgcctgctgccatccatgtaagatgtgactcgctcctccctaccttccgccgtgattgtgaggcgtccccagccatgtggaactgtaagtccattaaaccttcttcctgtgtaaatta
->URS0000115D96 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAATGGATTAAGAGCTTGCTCTTATGAAGTTAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCCATAAGACTGGGATAACTCCGGGAAACCGGGGCTAATACCGGATAATATTTTGAACCGCATGGTTCGAAATTGAAAGGCGGCTTCGGCTGTCACTTATGGATGGACCCGCGTCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGCTTTCGGGTCGTAAAACTCTGTTGTTAGGGAAGAACAAGTGCTAGTTGAATAAGCTGGCACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGC
->URS00009CA41E rRNA from 1 species 
-GGCGGACGGGTGAGTAATGCTTAGGAATCTGCCTATTAGTGGGGGACAACATTCCGAAAGGAATGCTAATACCGCATACGTCCTACGGGAGAAAGCAGGGGATCTTCGGACCTTGCGCTAATAGATGAGCCTAAGTCGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCTGTAGCGGGTCTGAGAGGATGATCCGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGGGGAACCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGCCTTATGGTTGTAAAGCACTTTAAGCGAGGAGGAGGCTACTGAGACTAATACTCTTGGATAGTGGACGTTACTCGCAGAATAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAATACAGAGGGTGCGAGCGTTAATCGGATTTACTGGGCGTAAAGCGTGCGTAGGCGGCTTTTTAAGTCGGATGTGAAATCCCCGAGCTTAACTTGGGAATTGCATTCGATACTGGGAAGCTAGAGTATGGGAGAGGATGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGATGGCGAAGGCAGCCATCTGGCCTAATACTGACGCTGAGGTACGAAAGCATGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCATGCCGTAAACGATGTCTACTAGCCGTTGGGGCCTTTGAGGCTTTAGTGGCGCAGCTAACGCGATAAGTAGACCGCCTGGGGAGTACGGTCGCAAGACTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGT
->URS0000EF3AE3 lncRNA from 1 species 
-CCCTGATGGTGCAGAGACTGTCACGTAAACTGCCTCAGCTTTCTGGGGACTGTTCTGGAGTGCTCACCTACACTAGGCTTGGGGACCATGTTGGTGCCATTTCCCCAGACTGGGTACTGACCTCTTCACAGTTCCCGTGGCGCCTGAAGGACTGGAGAGTTTATGTTCCCATGTCTCCTCTGGGTGTTGGCCAGAGCTGTGATCACCATGACGGGAATCCTCCTTATTTGCTCCTTAAGCAAATAATCCTTGTGTTTTTGATTATGCCCTTAATCTTTGTCCTGAACTGCTGATCTTCAGAGGGACCCAGGAGAAGATGAGTCCAC
->URS000081BA44 rRNA from 1 species 
-ATTGAACGCTGGAGGCATGCTTAACACATGCAAGTCGAACGGCAGCATGATGTGTAGCAATACACATTGATGGCGAGTGGCGGACGGGTGAGTAACGCGTAGGAATCTGCCTTGAAGAGGGGGACAACCCGAGGAAACTCGGGCTAATACCGCATAATATCGAGAGATTAAAGTCTGGGTGGTAACACCTGGAGCTTCAAGAGGAGCCTGCGTCCGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGATGATCGGTAACTGGTCTGAGAGGATGACCAGTCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATCTTGGACAATGGGGCCAACCCTGATCCAGCGATGCCGCGTGTGTGAAGAAGGCCTC
->URS0000CE0126 antisense_RNA from 1 species 
-TCCTTCCCTTCCGGAGCCCGGGGTAGGCGAGAAGCAGGCAAGGGCGCGGAGGATGGAATCTCGCTCTGTCTCCCAGGCTGAAGTGCAATGACGCAATCTCGGCTCAATGCAGCCTCCGCCTCCCAGGTTTAAGCGATTATCCCGCCTCAGTCTCACAAGTAGCTGGGATTACAGGTGCCCACCACCACGCCCAGAAGTGCATTTCGCCTCCCGCCATGATTCTGAGGCCTCCCCAGCCCTGTGAAACCGTAAGTCCAATTAAACCTCTTTTTCTTCCCAGTCTCAGGTATGTCTTTATCAGCATCATGAAAACGGACTAATACACTATTCTTAATTGATATGCCAACACAAATATAGAGACACATAGCAACATATATACACAAAATGCAAACAAAATTACTTGCAGCTTTAAGTAGATCTAAGTATACTTTTCCTTCTTCAGTGGGAACAAAGGTGTTGTAATTG
->URS00006C0526 Y_RNA from 2 species 
-AGCTGGTTCGAAGATAGTGTTATCTCAATTAACTGTTCACAGTCAGTTACAGATCAAACTCCTTGTTCTACTCTTTCCCCCTTTCTCACTACTGCGCTTGACTAGTCTAGA
->URS00015EBCF0 rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCACGTAGGCGGATTGCTAAGTCAGGGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTTGATACTGGCGATCTTGAGTCCGGGAGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGGTACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS00016A2BA6 rRNA from 1 species 
-CCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGGGGAACCCTGATCCAGCGACGCCGCGTGAGTGAAGAAGTATTTCGGTATGTAAAGCTCTATCAGCAGGGAAGAAAATGATGGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGTTGGCAAGCGTTGTCCGGATTTACTGGGTGTAAAGGGCGTGCAGCCGGGAAGACAAGTCAGATGTGAAATACCGCGGCTCAACCGCGGAACTGCATTTGAAACTGTTTTTCTTGAGTATCGGAGAGGTAATCGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAAGAACACCAGTGGCGAAGGCGGAGTACTGGACGACAACTGACGGTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTC
->URS000112369F rRNA from 1 species 
-TACGGGGGGAGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCGCGTAGGCGGCAAGGCAAGTCAGGTGTGAAAGCCCCGAGCTTAACTCGGGAATTGCATCTGAAACTGCTGTGCTTGAGTTCTGGAGGGGGTAGTGGAATTCCCAGTGTAGCGGTGAAATGCGTAGATATTGGGAGGAACACCTGCGGCGAAGGCGGCTACCTGGACAGAAACTGACGCTGAGGCGCGAAAAGCTAGGGGGAGCGAACGGGG
->URS00022A0584 misc_RNA from 1 species 
-GAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCGCCAGTATTCTGGCGGGCATGTCTGTCCGAGCGTCATTTCAACCATCAAGCCCCCGGGCTTGTGTTGGGGACCTGCGGCTGCCCGCAGGCCCTGAAAACCAGTGGCGGGCTCGCTGTCACACCGAGCGTAGTAGCAATCACCTCGCTCAGGGCGTGCTGCGGGTTCCGGCCGTTAAACAGCCTTACAAAACCCCAGGTTGACCTCGGATCAGGTAGGAAGACCCGCTGAACTTAAGC
->URS0000E790F2 lncRNA from 1 species 
-ATGCAAACTTTGCCCGAATTTTGCTACTTAAAATGCCTTAGCGATAAAGTAAATGTTACTAAAATTATTAACCGAAATATAACAAAACTAAAGCTAGATGGATTTATCGAATTGGATCGTGAGATAGAGGATTTTACGAAATTAAGAAATTCAATTGTTAATGAACAATATAAAGGGTTGACAGAAAAATTATTTCAAGCACACAAAGAATATTTATTTTATTTTGATACTTTTTTAAAAAAAAAACTATTAAAAGATGAAAATAAAGTATTATATACTAATGATTGTTTTGATAGAACAAAAAAGGTTGAATACAATTTTGAAAACGAAATAGTTATTGTTATATATAATATAGGTTTTATTACTACAGCTATATTAAAATCTAAAAAAAAAGACAAGGATGTAAAATTATTAAATAAATTGTCACAAGAAGCAATAAATATTTTTAATTACTTATTCCAAAGTATTATTAATGAAACTTACAATGACTTAAGTGACATAAATTGTTTAAGTTGTTATGTATTTTTAAATTTATCATTAGCTTATCATGAACATTTATTTTATAATACAGCTTTGGCAAAAAAATATAAAAGAAATTTATTAGCAAAAATATCATATAATATATATAGTTATTTTAATAATATGTTAAATTGTTTAGATGGTAAAAAATTAGATGTATTTACAAAAATGGATGCATTTGTTAATGCAAAAAATAATCTTATATTAACTCTTCGAAATAGTAATAGTCTTCTTTATAACTTTATATATGTAAATAAATTAATTTTTTTAAGTATTACCAATTATCAAACAACTTTAAAATACTGTCAATTAAACCCAAATAGTGAAGAAGTAGTAATACAAAAATATGAAGAAGAAAAAATAGGAGAAATTATATCTAGATTACAATTTAGTACAGAAAATATAAAGAAAGCAGAAGATTTAAGTAAAAAATATAATTTACATATTAATGCTGAAATGTTGAAACAAAAAATAAACAATGCTTTAGTTTTTTTTGAAAAAGATAATAAAAATATATATTTTGAGTCAATACCAGAATATAGTACCTTAGACAGTTTAAAAGGAACAGAAATTGTAAAAATACCAGATCCTAATATATCAACTATTTATTTGAAAAAAGAAATCAGTAATAATTTAAAATTATTATTTAATGAAAAAGCAAAAAATATATTTGACGAATATAATACAGAGGCTTGTAAAGTACATGATTTATATGAAAAACATCTTAGCAGTTTAAAAGATCAATATAAATTAATTAATTTATCTTATCGAAAAAATATATTTACAATTCTTAATAATGTACTTTTAAATATATATAATACATTAAAACAATCATATAATCCTACTATATATGATAAAAATTTACATTTTTTAATGGATGTTGAAAAAAATTTAAATTTAACACTAAACCAAATCGAAACAAGTTTAAACACAGAAAATTCTAATCACTTGAATTTCCAAAAAATGTATACCAATATAGGCGTTAACCAAGACTCGTTAAATTCTTATAAAAAATATGTTTACCATTTAAATAACTTTAAAAAAATATTAACCGAAATAACAACTAATATAGTTGAATTTAAAAGTTTTCTTGAAAATAATTATTATTATTTACAACTATGTGAAATGAATGTTTCTAATTTTTTTAAACATATGATAGACGAACTTAACTCCAATTCAAATACATGTGTTGAATCCTTTGATAGCGATTATACATTTTATAAGAACTTATTATCAGAAGAAAAAGAAAAAGAAAACGAAGAAGAAACAAAAGAAGAAACAAAAAAAATGAAAAATAATACATCATCAACAACAACAGCAGCAGAAGCAACAACAACAGCAGCAGCAACAACATATATGAACGAACAAAAAGTAATACTACCAGCTTCACCACCACCATCACTTACCAATAATATTCCTAAATTAACATATTCTAACTTTCACAAATTTTTAAAAAAAAACAATATATCAGTTACTGCGTCAAGTAGTATTAATAATAGTAGTAATATAAAATATTTTGAAATTTTAAAAAATTATATAAATATACATTCAGAAGAAAAATTATATTTTACAATAAATGCTATTTACTTTTCTATGAATATCCAATTAGAACAATTTTCAAACGACCTTGCAGAGATTAAAGGATATATGCAAAATTCATTTTTAAATTTAATAACGGTAATGATATAA
->URS0001C1D8E2 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGATAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGACGCAGCAACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTG
->URS000183E284 rRNA from 1 species 
-TACGAAGGGAGCTAGCGTTGTTCGGAATCACTGGGCGTAAAGCGCACGTAGGCGGATTTGTTAGTCAGGGGTGAAATCCCGGGGCTCAACCTCGGAACTGCCTTTGATACTGCAAATCTCGAGTCCGGAAGAGGTGGGTGGAATTCCTAGTGTAGAGGTGAAATTCGTAGATATCAGGAGGAACACCGGTGGCGAAAGCGGCTTCCTGGCCCGACACTGACGCTCATGTACGAAAGCGTGGGGAGCGAACAGG
->URS0000164332 rRNA from 1 species 
-CCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCAATACCGCGTGTGTGAAGAAGGCCTGAGGGTTGTAAAGCACTTTCAATGGGAAGGAATACCTACCGGCCAATACCCGGTAGACTGACATTACCCATACAAGAAGCGCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAGGCGTGCGTAGGCGGCTTGTTCAGTCAGATGTGACAGCCCCGGGCTTAACCTGGGAACTGCATTTGATACTGGCAGGCTAGAGTTTAGTAGAGGGGAGTGGAATTTCAGGTGTAGCGGTGAAATGCGTAGAGATCTGAAGGAACACCAGTGGCGAAGGCGGCTCCCTGGACTAAAACTGACGCTGAGGTACGAAAGCGTGGGTAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCAACTAACTGTTGGGTTCTTAAAGAACTTAGTAGTGGAGCTAACGTATTAAGTTGACCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTACCCTTGACATGTAGTGAACTTTCCAGAGATGGATGGGTGCCTTCGGGAACACTAACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCTTATCCTTAGTTGCCAGCGGGTAATGCCGGGAACTCTAGGGAGACTGCCGGTGATAAACCGGAGGAAGGTGGGGACGACGTCAAGTCATCATGGCCCTTATGGGTAGGGCTACACACGTGCTACAATGGTCGGTACAGAGGGCAGCAAACTCGCGAGAGCCAGCAAATCCCAAAAAGCCGATCCTAGTCCGGATTGCAGTCTGCAACTCGACTGCATGAAGTCGGAATCGCTAGTAATCGCGGATCAGAATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGT
->URS00013EF64C rRNA from 1 species 
-GACAGAGGATGCAAGCGTTATCCGGAATGATTGGGCGTAAAGCGTCTGTAGGTGGCTTTTTAAGACCGCCGTCAAATCCCAGGGCTCAACCCTGGACAGGCGGTGGAAACTACCAAGCTGGAGTACGGTAGGGGCAGAGGGAATTTCCGGTGGAGCGGTGAAATGCGTAGAGATCGGAAAGAACACCAACGGCGAAAGCACTCTGCTGGGCCGACACTGACACTGAGAGACGAAAGCTAGGGGAGCGAATGGG
->URS00016C3B12 rRNA from 1 species 
-TACGAAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGGGTGCGTAGGCGGTTCGGTAAGTCGGATGTGAAAACTCAGGGCTCAACCCGGAGACGCCATCCGATACTGCTGTGACTTGAGTCTGGTAGGGGAACACGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGATGGCAAAGGCAGTGTTCTGGGCCAGTACTGACGCTGAGGAGCGAAAGCGTGGGGAGCAAACAGG
->URS0000F147F0 rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTTTGTAAGCCAGATGTGAAATCCCCGGGCTCAACCTGGGAATGGCATTTGGGACTGCAAGGCTGGAGTACGGCAGAGGAGACTGGAATTCCTGGTGTAGCAGTGAAATGCGTAGAGATGTGGAGGAACACCGATGGCGAAGGCAGCCTCCTGGGCCAGCACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGG
->URS0000104AE7 rRNA from 1 species 
-GAGCTCGTAGGCGGTTTGTCGCGTCTGCCGTGAAAGTCCGAGGCTCAACCTCGGATCTGCGGTGGGTACGGGCAGACTAGAGTGATGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGATGGCGAAGGCAGGTCTCTGGGCATTTACTGACGCTGAGGAGCGAAAGCATGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCATGCCGTAAACGTTGGGCACTAGGTGTGGGGGACATTCCACGTTTTCCGCGCCGTAGCTAACGCATTAAGTGCCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGCGGAGCATGCGGATTAATTCGATGCAACGCGAAGAACCTTACCAAGGCTTGACATGTTCCAGACCGCCTCAGAGATGGGGTTTCCCTTCGGGGCTGGTTCACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGTTCCATGTTGCCAGCGGGTTATGCCGGGGACTCATGGGAGACTGCCGGGGTCAACTCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGTCTTGGGCTTCACGCATGCTACAATGGCCGGTACAATGGGTTGCGATACTGTGAGGTGGAGCTAATCCCTAAAAGCCGGTCTCAGTTCGGATTGGGGTCTGCAACTCGACCCCATGAA
->URS0000D394E6 rRNA from 1 species 
-CACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGAGCTTAACTTGGGAACTGCATTTGAAACTGGCAAGCTAGAGTCTTGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACAAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGTCGACTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAAGAAAATTTGACGGA
->URS0002160948 rRNA from 1 species 
-TGCTGGAGGTATCAGAAGTGCGAATGCTGACATAAGTAACGATAAAGCGGGTGAAAAGCCCGCTCGCCGGAAGACCAAGGGTTCCTGTCCAACGTTAATCGGGGCAGGGTGAGTCGACCCCTAAGGCGAGGCCGAAAGGCGTAGTCGATGGGAAACAGGTTAATATTCCTGTACTTGGTGTTACTGCGAAGGGGGGACGGAGAAGGCTATGTTAGCCGGGCGACGGTTGTCCCGGTTTAAGCATGTAGGCTGATTGTCCAGGCAAATCCGGATAATCAAGGCTGAGGTGTGATGACGAGGCACTACGGTGCTGAAGTAACAAATGCCCTGCTTCCAGGAAAAGCCTCTAAGCATCAGGTAACATCAAATCGTACCCCAAACCGACACAGGTGGTCAGGTAGAGAATACCAAGGCGCTTGAGAGAACTCGGGTGAAGGAACTAGGCAAAATGGTGCCGTAACTTCGGGAGAAGGCACGCTGGTGTGTAGGTGAAGTCCCTGCGGATGGAGCTGAGACCAGTCGAAGATACCAGCTGGCTGCAACTGTTTATTAAAAACACAGCACTGTGCAAACACGAAAGTGGACGTATACGGTGTGACGCCTGCCCGGTGCCGGAAGGTTAATTGATGGGGTTATCCGTAAGGAGAAGCTCTTGATCGAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGCGTAATGATGGCCAGGCTGTCTCCACCCGAGACTCAGTGAAATTGAACTCGCTGTGAAGATGCAGTGTACCCGCGGCAAGACGGAAAGACCCCGTGAACCTTTACTATAGCTTGACACTGAACATTGAGCCTTGATGTGTAGGATAGGTGGGAGGCTTTGAAGCGTGGACGCCAGTCTGCGTGGAGCCAACCTTGAAATACCACCCTTTAATGTTTGATGTTCTAACGTTGGCCCCTGACCGGGGTTGCGGACAGTGTCTGGTGGGTAGTTTGACTGGGGCGGTCTCCTCCCAAAGCGTAACGGAGGAGCACGAAGGTTAGCTAATCCTGGTCGGACATCAGGAGGTTAGTGCAATGGCATAAGCTAGCTTGACTGCGAGCGTGACGGCGCGAGCAGGTGCGAAAGCAGGTCATAGTGATCCGGTGGTTCTGAATGGAAGGGCCATCGCTCAACGGATAAAAGGTACTCCGGGGATAACAGGCTGATACCGCCCAAGAGTTCATATCGACGGCGGTGTTTGGCACCTCGATGTCGGCTCATCACATCCTGGGGCTGAAGTAGGTCCCAAGGGT
->URS00025841D4 rRNA from 1 species 
-GCGCAGATGACTCGCTACTGAATCAACTAAAACATAAAACAAAATATTTAGTTGATAATGTAAGAAGAAAATAATGATATTATCTTATGTTTAGTGTCGTCTAAAACTGGTGCCAGAAGACTCGGTAAGGCCGGAGACGCAAACGTTAGTCATCCTTATCAGGCGTAAAGGGTTTGTAGGCTGCTTTGAAAGTTTCTATCTTTTAAATTAATTAAAAAATGGGGCGAAGCTCGGTTATAACTAATTATCTTTAAAATATAATAAAATAGAAATAAATTAAAGCTAGAATCTAATAGAGGTTATATTGAATAATACTTAGTTTAGGTCTAATATCCTAATAGATTAAGGGGAATATTAAAAGCGAAGGCTTCTCTCCACTATAGATTGACGCTGAGAAACGAAGGTGAGGAAAGGAAATAGGATTAGATACCCAAACTACCCCTCACTGTCAACGATGAATGGTAGTCATTAGTGCATATTAGTGACGTAGTTAACACAATTACCATTCCGCCTTGTTAGTAAGACTGCAAAGTTAAAAACAAAAAAATTAGTCGGTTTCGGAGTAAACGAAGTGAAGCATGTTATTTAATTCATTAAATCCGCAAA
->URS0001424B59 rRNA from 1 species 
-CTACGGGCCGCAGCAGTGGGGAATATTGGACAATGGGGGAAACCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGCCTGCGGGTTGTAAAGCACTTTCGGTTGGGAGGACTGCTTCTAGCACTAATATTGTTGGAAGTTGACGTTACCTTCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCGCGTAGGCGGCTAGATCAGTCGGGTGTGAAGGCCCCGGGCTTAACCTGGGAACTGCATCCGATACTGTCTAGCTAGAGTACAGGAGAGGAGAGTGGAATTCCACATGTAGCGGTGAAATGCGTAGATATGTGGAGGAACACCAATGGCGAAGGCAGCTCTCTGGCCTGATACTGACGCTGAGGTGCGAAAGCGTGGGGAACAAACAGGATTAGATACCCCTGTAGTC
->URS0000AE892D rRNA from 1 species 
-TCGAGAATCATTCACAATGGGGGCAACCCTGATGGTGCAACGCCGCGTGGAGGATGAAGGTCTTCGGATTGTAAACTCCTGTCATCTAGGAGCAAGACCTGGCGCTGAATCGTCGACAGGGTTGATAGTACTAGAAGAGGAAGGGACGGCTAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGTACCGAGCGTTATTCGGAATCACTGGGCGTAACGGGAGCGTCGGCGGCGTGGGCAGCAAGATGTG
->URS0000ECDF55 rRNA from 1 species 
-TAGATACCCTGGTAGTCCACGCCGTAAATGGTGAGTGCTAGGTGTCGGGAGTCAAATCTCGGTGCCGACGTTAACACATTAAGCACTCCGCCTGGGGAGTACGCACGCAAGTGTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCAGCGGAGCATGTGGTTTAATTCGATGCAACGCGAAAAACCTTACCAGGACTTGACATATGGATGCCCGGTATAGAGATATACCCTTCTTCGGAACATTCAT
->URS000188AE03 rRNA from 1 species 
-ACTACGGGTGGCTGCAGTGGGGAATATTGGGCAATGGGCGCAAGCCTGACCCAGCAACGCCGCGTGAAGGAAGAAGGCTTTCGGGTTGTAAACTTCTTTTCTCAGGGACGAAGAAAGTGACGGTACCTGAGGAATAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGATTTATTGGGTGTAAAGGGCGTGTAGGCGGGAGCGCAAGTCAGATGTGAAAACTCAGGGCTCAACCCTGAGCCTGCATTTGAAACTGTGTTTCTTGAGTGCTGGAGAGGCAATCGGAATTCCGTGTGTAGCGGTGAAATGCGTAGATATACGGAGGAACACCAGTGGCGAAGGCGGATTGCTGGACAGTAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCGTGTAGTC
->URS000107BACB rRNA from 1 species 
-TGGGGAATTTTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGCGGGAAGAAGGCCTTCGGGTTGTAAACCGCTTTTGTCAGGGAAGAAATCTTCTGAGTTAATACCTCGGGAGGATGACGGTACCTGAAGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTTTGTAAGACAGAGGTGAAATCCCCGGGCTCAACCTGGGAACTGCCTTTGTGACTGCAAGGCTTGAGTGCGGCAGAGGGGGATGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAACACCGATGGCGAAGGCAATCCCCTGGGCCTGCACTGACGCTCATGCACGAAAGCGTGGGGAGCAAAACCAGGATTAGATAGCCCCTGGGTAGTCCACGCCCTAAAACGATGTCAACTGGTTGTTGGGAAGGTTCCTTCTCAGTAACGTAGCTAACGCGTGAAGTTGACCGCCTGGGGAGTACGGCCGCAAGGTTGAAAC
->URS00003DBB63 rRNA from 1 species 
-AGGGAATCTTCCACAATGGACGCAAGTCTGATGGAGCAACGCCGCGTGAGTGAAGAAGGGTTTCGGCTCGTAAAGCTCTGTTGGTAGTGAAGAAAGATAGAGGTAGTGACTGGCCTTTATTTGACGGTAATTACTTAGAAAGTCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTTGGCGTAAAGCGCGCGCAGGCGGATTGGTCAGTCTGTCTTAAAAGTTCGGGGCTTAACCCCGTGATGGGATGGAAACTGCCAATCTAGAGTATCGGAGAGGAAAGTGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAAGAACACCAGTGGCGAAGGCGACTTTCTGGACGAAAACTGACGCTGAGGCGCGAAAGCCAGGGGAGCGAACGGGATTAGATACCCCGGTAGTCCTGGCCGTAAACGATGGGTACTAGGTGTAGGAGGTATCGACCCCTTCTGTGCCGGAGTTAACGCAATAAGTACCCCGCCTGGGGAGTACGACCGCAAGGTTG
->URS0002247035 tRNA from 1 species 
-GCACCGGTCGTATAGTGGCTAGGTATTTAGTACCACACAAATTATCTCGGCCTTCCAAGCCGATAACCCGGGTTCGAATCCCGGCCGGTGCA
->URS0000B6A44E rRNA from 1 species 
-GTGTCAGCAGCCGCGGTAATACGTAGGCAGCGAGCGTTGTTCGGAGTTACTGGGCGTAAAGCGTGCGTAGGCGGCAGTCCAAGTCTGGTGTGAAATCTCCCGGCTCAACCGGGAGGGTGCGCCGGAAACTGGGCTGCTGGAGTGCGGGAGAGGTAAGCGGAATTCCCGGTGTAGCGGTGAAATGCGTAGATATCGGGAGGAACACCTGCGGTGTAGACGGCTTACTGGACCGCCACTGACGCTGAGGCACGAAAGCGTGGGTAGCAAACAGGATTAGATACCCTGGTAGTCC
->URS00008315DC rRNA from 1 species 
-GTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCAACGCCGCGTGAGGGAAGACGGTTTTCGGATTGTAAACCTCTGTCTTTGGTGAAGAAAAAAATGACGGTAGCCAAGGAGGAAGCTCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGAGCGAGCGTTGTCCGGAATTACTGGGTGTAAAGGGAGCGCAGGCGGGAAGACAAGTCAGCTGTGAAATACATGGGCTCAACCCATGGACTGCAGTTGAAACTGTTTTTCTTGAGTGGAGTAGAGGTAGGCGGAATTCCGAGTGTAGCGGTGAAATGCGTAGATATTCGGAGGAACACCAGTGGCGAAGGCGGCCTACTGGGCTCTAACTGACGCTGAGGCTCGAAAGTGTGGGGAGCAAACAGGATTAGAAACCCTAGTAGTCC
->URS00014517AB rRNA from 1 species 
-TACGTAGGGGGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCTCGTAGGCGGTTGGGTAAGTCGGGTGTGAAAACTCAGGGCTCAACTCTGAGACGCCACTCGATACTGCTCTGACTCGAGTCCGGTAGGGGAGCGTGGAATTCCCGGTGTAGCGGTGAAATGCGCAGATATCGGGAGGAACACCAGTGGCGAAGGCGGCGCTCTGGGCCGGAACGGACGCTGAGGAGCGAAAGCGTGGGTAGCAAACAGG
->URS00009B6ECF lncRNA from 8 species 
-GATCATCTGAGGTCGGGAGTTTAGACCAGCCTGGCCAACATTGTGAAACCCCATCTCTACTAAAAATACAAAAATTAGCTGGGTGTGGTGGCGCACACTTGTAATCCCAGCTACTTGGGAGGCTGAGGCAGTAGAATCACTTGAACCTGGGAGGCGNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNTGCACTCCAGCCTGGGCAACAGAGGGAGACTCCATCTCAAAAAGAGAAAATAATTATAAAAGTTGCTTTAAAATCCTTGCTGCTAATTCCCAAGATTAGAAATTCCAACATCTGAGTCATAACTTTTTCTCTTTGGGAGTGAGTTTTGAGTATGATTCCATTTTCTGTTTCTTCATATGCCTAGTACTTGTTTATTGTAGCTGGACATTGTCAAGACTATGGATTTTGTTATGTTCCTCTGAAGAGTGTTAATTTTGTTCTAACAGGCAATTAACCTGGTTGGACTGAAACTCCAATCTTTGTGAAAGGCAGTAGCTGGAATTCCTACTCTGTTCTTGCTCCCAGCTGCTGATTTTACTGGGACTCCTGGAGACTCCTGCGCATATGTGCAGTTGGACAACCAAGGATTTGGACAGAGTTTATATACAGATTTTGGGACTTGTTTGCTCTATAGAATTTCTTTCTGTGAGTTCCCTCTTAATTTTCCAGCCACACTTCTCGCCTAGAACTCTGTACTCGGCACCTCAAACCAGTAAGACCGTAGCTTTCTATGCATTTCCACCTCCCACACAAATTACAGAGTGCCCTCACACAAATAACCACAAAAATATAAGTCTAGTACAGGGCAGCTCCCACCTTTCAAGAGTTGATTTTCCTCACATTTCTAATTGCTGTTAGGTGTTCTTTAGTGCCTTCAAATATTTGGGTTTGGTTGTTGTTTATTTTATTCAGGTTTTTGGTTTTTTGTTTTGGTTTTGTTTTGAGATGGAGTTTTGCTCTTGTCGCCCAGGCTAGAGTGCAATGGCACGATCTGAGCTCACTGCAACCTCTGCCTCCCAGGTTCGAGTGATCCTCCTGCCTCAGCCTCCTGAGTAGCTGGGAATACAGGCATGCACCACCACGCCTGGGTAATTTTTGTATTTTTAATAGAGACAGGGGTTTCACCATGTTGACCAGGCTGGTCATGAATTCCTGACCTCAGGTGATCCACCTGCCTCGGTCTCTTAAAGTGCTGGGATTACAGGTGTGAGCCACTGTGCCCAGCCAGGTTTTTTGTTGTTGTTGTTATTGTTTTGTTTTTAAGAGACAGGATCTTGCTTTGTTGCCCAGGCTGGAGCACAGTGGTATGATCATAGCAAACTGCAGCCTTGAACTCCTGAGCTCCAGCAATCCTCCTGCCTCAGCCTCCCAAGTAGCTGGGACTACCAGCGCATATCACCATGCCTAGTTAATTTTTTGAAAACTATTTTGATAGAGATGGAGTCTTGCTGTGTTGCCCAGGCTGGTCTTGAACTCATGGCCTCAAGCGATCCTCTCACCTAAGTCTCCAAAGGTGCTAAGATTACAGGCATGAGCCACTGTACCTGGCCTTGTTTCAGGTTTTTTTTTGTTTTTGTTTTTGTTTTTGNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNACTTCCTGGGTTCAAGTGATTCTCCTGCCTCAGCCACCCGAGCAGCTGGGATTACAGGTGTGCACCACAAGCCTGGCTAATTTTTTGTGTATTTTTAGTAGAGATGAGGTTTCGTCATGTTGGCCAGGCTGGTCTCAAACTCCTGACCTCAAATGATCTGTCTTCCTCAGCCTCCAAAAGTGCTGGAATTACAGGCGTGAACCACGGCACCTGGCCCTTGTTTCAGTTTTATAATTGCTATCTGAGGCATGATTATTCTGACCAAATTATTGTGCTATTAGGGAAACCATTTGTTTAAGTTCACATAGCTAGTTTGTGGAAGAGCCAAAATCTAAAACCAGTCAGATTACATAATCCTATGCTTGCTCCAGTTCACCACTATTCCTAAACACCTCAAGGTGGTTTGGATTCCAGCCTAGAGCCCTCTGGAAAGTATTTGGGGCTGGAAGGAGGAAAGAGCCCTCAAAACTCCTATTCAGGCTAGGGCAGTAGTTGCCCAGGCTGGAGTGCAGTGGAACAATCTTGGCTCACTGCAACCTCTGCCTGCCGGGATCAAGCAATTCTCCTGCCTCAGACTTCTGAGTAGCTGGGATTACAGGCGTACACCACCAAGCCCAGCTAATTTTTGCATTTTAATAAAATCACAAAGCCAGACTTAGATAGTTGAAAGTGCCCACCTCTGTTCCTGAGAGTTGGGCCTGAGACAGAGGATTCTAAGTGGAAACCACGCTCAACTAAGAGGACCCAAGAAAGGCAAGTTCTTTTTAAAAATTTTTTTTTCATTTTTTGTCTCTCTCTGTCACCCAGGCTGGAGTGCAATGGTGCAATCATGGCTCACTGCAGCTTTATCCTCCTGGGCTCAAGCCATCTTCCCACCTCAGCCTCCCAAGTAGCTGGGACTACAGGCACATGCCACCATGCCTGGCTAATTTTTATATTTGTTGTAGACAAGTTTTCACCATGTTGCCCAGGCTAAGTCAAACTTTTCTTTTTTTTCTATTTTTTATTTTTTTTAATTATTATTTTTTGAGATGCAGTCTCGCTCTGTCGCCCAGGCTGAAGTGCCATCTCTGCTCACTGCAAACTCCACTTCCTGGGTTCCTCAGCCTCCCGAGTAGCTGGGACTACAGGTGCCTGCCACCACGCCCAGCTAATTTTTTGTATTTTAATAGAGACGGGGTTTCACCGTGTTAGCCAGGATGGTTTCGATCTCCTGACCTCGTGATCCACCCGCCCGCCTCGGCCTCCCAAAGTGCTGGGATTACAGGCATGAGCCACTGCGCCTGGCTCAAATTAGATTTCTATATCCAGTAACAGTATCCTTCAAAAATGAAGACAAAACAGAGACATTGTCAAATAAACAAAAACTGAGTTT
->URS00011F5567 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGTGAACGAGGGAGCTTGCTCCCTCCGGATCAGTGGCGAACGGGTGAGTAACACGTGAGCAATCTGCCCTGGACTCTGGGATAAGCGTTGGAAACGACGTCTAATACCGGATACGAGACGCGAAGGCATCTGCAGCGTCTGGAAAGAACTTCGGTCCAGGATGAGCTCGCGGCATATCCGTGAGTTGGTGAGGTAACGGGTCACCAAGCCTACGACGGGTAGCCGGCCTGAGGGGGTGACCGGCCACGCTGCAGCAGAGATACGGCCCAGACTGCTACGGGAGGCATGAGTGGGGAAGGTTGCACAATGGGCGCAAGCCTGATGCAGCAACGCCGCGTAGGGGACGACGGCCTTCGGGTTGTACACCTCTTTTAGCAGGGGAGACGCGAAAGTGACGGTACCTGCAGAAAGAGCACCGGTTAACTACGTGCCAGCCGCCGCCGTAACAC
->URS0000FFF241 rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGCTCGGAATTACTGGGCGTAAAGCGCACGTAGGCGGCTTCTTAAGTCGGTGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTCGATACTGGGAAGCTCGAGTCCGGGAGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGATACTGACGCTGAGGCACGAAAGCGTGGGGAGCAAACAGGG
->URS0002017531 rRNA from 1 species 
-AACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGAGACCTTCGGGTCTAGTGGCGCACGGGCGCGTAACGCGTGGGAACCTGCCTTTAGGTTCGGAATAACTCAGAGAAATTTGAGCTGATACCGGATGATGTCTTCGGACCAAAGATTTATCGCCTTTAGATGGGCCCGCGTTGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCCATAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCAATGCCGCGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTTACCCGAGATGATAATGACAGTATCGGGAGAATAAGCTCCGGCTAACTCCGTG
->URS0000DCAE13 sRNA from 1 species 
-GCAACCCGATGTCGGGGGCTTGGGCGGAAGCCCACGTTGCCCGACAAAAAACGTACCCCCGGCGCGGTCTGCGCCAAGGAATCGAAATGAAGCAACGTGAGCAGTCCGCCCCGTTCGCGGGAAGTGGACGGCAACACGGTCTTCCAATGTATACTAAACGACTCTCGGCAACGGATATCTCGGCTCTCGCATCGATGAAGAACGTAGCGAAATGCGATACTTGGTGTGAATTGCAGAATCCCGTGAACCATCGAGTTTTTGAACGCAAGTTGCGCCCGAAGCCATTAGGCCGAGGGCACGCCTGCCTGGGCGTCACGCGCTCCGTCGCCCCGCAACCCCGAACCCCGAAACGGGCCAGGGTACTTGTGGTGCGGAGATTGGTCTCCCGTGTGCCTTGCTCGCGGCTGGCCTAAAATTGAGTCCCGGGCGCTCTGTTCTGCGGCCGACGGTGGTTGAGAAGCCCTCGAAATTGTGCTGCTGCAGTGCTGCCCGATGCGGACCCTGTGACCCTTGCGCGACCTCTCCCCTTGGGGTGAGGGAGCTCCATCTGA
->URS000109E99B rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGTGCGTAGGTGGTGAGTTAAGTCTGTCGTGAAAGCCCCGGGCTCAACCTGGGAATGGCGATGGATACTGGCTCGCTAGAGTGCGGTAGAGGAGAGTGGAATTCCCGGTGTAGCAGTGAAATGCGCAGATATCAGGAAGAACACCCGTGGCGAAGGCGGCTCTCTGGGACGGTACTGACGCTGAGACGCGAAAGCGTGGGGAGCGAACAGG
->URS0001484F89 rRNA from 1 species 
-CCTACGGGTGGCTGCAGTGGGGAATATTGGGCAATGGAGGCAACCCTGACCCAGCAACGCCGCGTGAATGATGAAGGCCTTCGGATTGTAAAGTTCTTTTCTTCGGGACGAAGAAAGTGACGGTACCTTAGGAATAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGAGGCAAGCGTTATCCGGAATGACTGGGCGTAAAGGGTGAGTAGGTGGTTGGACAAGTTAGACGCGAAATTCCGGGGCTCAACCCTGGAACTGCGTCTAAAACTGTTGGTCTTGAGTGAAGGAGAGGCAGTCGGAATTCCGGGTGTAGCGGTGGAATGCGTAGATATAAGGAGGAACACCAGTGGCGAAGGCGGATTGCTAGACTGTAACTGACACTGAGGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCCAGTAGTC
->URS0002155384 rRNA from 1 species 
-TCAAGTTACTAAGGGCATGTGGTGGATGCCTTGGCGCCTGGAGCCGATGAAGGACGTGGCGTGACTGCGAAAATCCCTGGCTAGCTGTCAAGCGAGCTTAACCGGGGGTATCCGAATGAGGCAACTCAGCTCAATTTTATTGAGTTACCGCTGATTGAACACATAAATCAGATGGAGGGAACCGGGGGAACTGAAACATCTAAGTACCCTGAGGAATAGAGATTATTCCCTTAGTAGCGGCGAGCGAACGGGGAACAGCCCAAACCGTCTTCTGCGGAAGGCGGGGTTGTAGGACAGTTCATATGGAGTTACAAATTGTTTCGATAGCTGAAGCGCCTGGGACGGCGTGCCACAGATGGTGACAGCCCAGTAAGTGACATTGAAACAACTCCGAGCTGTATCCTGAGTAGTGCGGGACACGAGAAATCCCGTATGAATCTGGGAAGACCACTTTCCAAGGCTAAATACTCCAGGCGACCGATAGCGTATAGTACCGTGAGGGAAAGGTGAAATAGTACCCCGAGAGGGGAGTGAAATAGTTCCTGAAACCGCATGCTTACAAGCAGTTGGAGCCAGTTCGTTCGCGAATTGGTGACAGCGTGCCTATTGAAGAATGAGCCAACGAGTTACGTTCAGTGGCAAGGTTAAGCGATGAGAGTCGTGGAGCCGTAGCGAAAGCGAGTCTTAAAAGGGCGAAAGTGGCTGGACGTAGACCCGAAACCGAGTGATCTACCCATGGGCAGAGTGAAGCGGGAGTAATGCCCCGTGGAGGCTCGAACCTTCCTGAGCTGCAAATCAGTTGGATGACCTGTGGGTAGCGGAGAAATTCCAATCGAACTCGGAGATAGCTGGTTCTCCTCGAAATGTATCTAGGTACAGCCTCGTGTGTTTTCTTCTGGGGGTATGGCTCTGAATGGACTAGGGGGCATAGCGCTTACCAAACCCAATCAAACCGGGAATACCAGAAGATTAGAACGCGGGAGTGAGACTGTGGGAGCTAACTTCCATGGTCAAGAGGGAAACAACCCAGACCCCCGGCTAAGGTCCCTAAATCCATGCTCAGTGTGCAAGGATGTCCAGTTGCATAGACAACCAGGATGTTGGCTTAGAAGCAGCCACCATTTAAAGAGTGCGTAACTGCTCACTGGTCGAGTGGCCGGGCGCCGACAATGTAACGGGGCTCAAGCATGGTACCGAAGCTAGGGGACCGCTTTTTAGCGGTCGGTAGAGGAGCGTTCTGTATGCGATGAAGCTGTGCGGGTGACCGTCGGTGGAGCGTACAGAAGTGAGAATGTTGGCATGAGTAGCGAAATTCAGGTGAGAACCCTGAACGCCGTAAGCCCAAGGGATCCTACGCAAAGCTAATCCGCGTAGAGTTAGGCGGGCCTAAGCCGAGGGCGAGAGCCGTAGGCGATGGACAGCAGGTAAGTATTCCTGCCCCACCATATGGGCGTTTGAGATGTGAGGTGTGACCCAGAAGGATAGACAGAGCGGGCCCTGTGGACATGGTCCGTCCCTACACCGTAGGCGTCTGACGATAGGAAAATCCGTTGTCAGGTTAAGCGGAGGGTGAGGGGGGCAGTGGAGACTTCGGTCAAAACGACTCTGTTGAGTCCATGCTGGCTAGAAAAGCATCGGCATCGAGTGCATATGGTGTCCGTACCGCAAACCGACACAGGTGGGCGACGGTAAGTACCGTAAGGCGAACGAGAGAACCTTCGTTAAGGAACTCGGCAAAATAGCTCCGTAACTTCGGGAGAAGGAGCGCCCTTGTGAGTGAAACACTTTACGTGTGGAGCATCACGAGGGCCGCAGTGAGCAGGCCCAGGCGACTGTTTAACAAAAACACAGGTCTCTGCGAACCAGTAATGGGATGTATAGGGGCTGACGCCTGCCCAGTGCCGGAAGGTTAAGGAGATGGCTGAGAGGCCAGAACTGAAGCCCCGGTGAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCCGCACGAATGGCGTAACGATCTGGGCACTGTCTCAACGAAGGACTCGGCGAAATTGAGATGGCCGTGAAGACGCGGCCTACCCGCAGCAGGACAAATAGACCCCGTGGAGCTTTACTGCAGTTTTGCGCTGGCGTATGTGATTAGTTATATAGTATATGGGGGAGGCTTTGAACCATGACCGTCAGGTTGTGGGGAGCCGTCAGTGGAATACCCCATTTCTAATTTTGTACTCCTCACCAGTGAGCAAGCACTGGGACAGCGCATGATGGGCAGTTTGACTGGGGCGGTCGCCTCCGAAAGAGTAACGGAGGCGCGCAATGGTTCCCTCAAGGTGGATGGTAATCACCTGTCGAGTGCATTGGCATAAGGGAGCTTGACTGCAAGACAGACAAGTCGAGCAGGGGCGAAAGCCGGCCAAAGTGATCCTATGGTCCCGAGTGGAAGGGCCATGGCTTAACGGATAGAAGCTACCCCGGGGATAACAGGCTGATCCTTCCCAAGAGTTCACATCGACGGAAGGGTTTGGCACCTCGATGTCGGCTCGTCGCATCCTGGGGCTGAAGAAG
->URS000254E3BB rRNA from 1 species 
-AACGGCTATACCATGCTGAATATACCGGTTCTCGTTAGATCACCAAAGTCAAGCATCAGTGGGCGCAGTCAGTACTTGGGTGAGTGACCATCTGGGAACACCGCGTGCCGTT
->URS00000821D9 rRNA from 1 species 
-TGCGAACGTTTGCGGCGGGCCTAACACATGCAAGTCGAACGCACTAGCAATAGTGAGTGGCGCACGGGTGCGTAACACGTGGGTAATCAACCCTTCAGCCTGGGATAACGACTCGAAAGGGTCGCTAATACCGGATACGGCGCGAGAGGCTTCGGCTTCTCACGAGAAAGCCACGCAAGGGGCACTGAAGGACGAGCCTGCGGCCCATCAGCTAGTTGGTGAGGTAAGAGCTCACCAAGGCTAAGACGGGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCCACGCCGCGTGAGCGATGAAGGCCTT
->URS00005A9635 rRNA from 1 species 
-GGGGCCTGCGGTTAATTTGCTCAACACGGGGAAACTCACCAGGTCCAGACACAATGGGTTGACAGTTGATAGCTCTTTCTTGATCTTGTGGTTGGGGGCATGGCCGTTCTTAGTTGGTGGGTGATTTGTCTGGTTAATTCCGATAACGAACGGCCATCCCCTGCTAAATAGCCGGCCGGCTTTGGCTGGTCGCTGGCTTCTTAGAGGGACTTTTAGCGTTTAGCTAAAGGAAGTTGGTGGCAATAACAGGTTAACGTCTATAATCACAGGCCTGTAAAAGCGGTGGTGCCAACTTATAAGTGCTAGTGATCTAGTGCTACAAAATCCGCTAGTCCAAGAGGTTAATCGATGCGGAAAAGCTTTCCATAGTCGGGCATCGAGAGTGTTTTAACTAACACTTGCTTCTGGGCGACACAACCTGGTACAGGGAACGCCAAACAGGTAATGCTGAGGTCGATCCTGTGGTGAGTTAGAGTAGCGTCTAACCATCGCAACGCGCGCAAAGGTGTGGGTCTTATCTGTGGATAAGGCTTAAGGTACGTGCTAATCCCACTAGTAATAGTGGTTTGCTTGAGAGCCCACAGCTAAATCAGTAAAGGGTTTGGACTTTAAGTTCAGACCGAATCCATTA
->URS0000F720C2 rRNA from 1 species 
-ACGGGAGGCAGCAGTGGGGAATATTGGGCAATGGGCGAAAGCCTGACCCAGCAACGCCGCGTGAAGGAAGAAGGTCTTCGGATTGTAAACTTCTTTTATGAGGGACGAAGGACGTGACGGTACCTCATGAATAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATGCAAGCGTTATCCGGATTTATTGGGTTTAAAGGGTGCGTAGGCTGTGCGACAAGTCAGGGGTGAAAGCCCGCCGCCCAACGGTGGAACTGCCTTTGATACTGTCGCGCTGGAATACGGATGCCGTGGGAGGAATGAGTAGTGTAGCGGTGAAATGCATAGATATTACTCAGAACACCGATTGCGAAGGCATCTCACGAATCCGTCATTGACGCTGAGGCACGAAAGCGTGGGGATCAAACAGGATTAGATACCCTGGTA
->URS0002411ED0 lncRNA from 1 species 
-AGCATTATATCCCCACGTTTGGCACATTAATCAACCCAATGTCAATCAAACCAATTGCAAAAGTCCTTTTCTTGGGTAAGTAAGTCTCCTACAACTCGCTAACCCTTTCTAATTGCTACAGGTTTTGTCTTAGAAGCACATAAGGGTATGGACATAGTCATGGATACGCATGTCAAGGAGGACACGTGTGTCCATAACGCGTCCCCAATGAGTCCAATAAAAAAAATAATTAAAAAATAGACAAGCCAAGTGGCATGTCAGTGTTCGACACGTGTCACACAC
->URS000239296D lncRNA from 1 species 
-TTTTTCCAAAACAGCAAAGCACGTCTCCTTAATAAAAGCACCAAGAACTTTACATGAATGTATTTATCGAAGATTCAGTAGCAAGGGCATTATTTACAAAAGGGACCATTTTGCCCCTTACAGGAGACAAAAAACAAACCCATTGAATTGGCATGATCTCAGAACAGCTCCATAATTTAATGAAACTCATGGATTCTCTTGAACTCCCCACCGCCCAAACCAAAATTGAACCTGACAAACAAGTACTGCAAATCACAAAAAAATAACCCACTCTTACTGGCTATTTTCACGCTTGTTTTTGCTGCTTCCACTCTCTTCCCCCTCCCCTGTGGCGTGACCTGTAACCACGTCTATTCAAAAACAAATTTGGAAATAGCAAGCTAACGCCGGTAAAAGAAACAGCAAAAAAGGAAACAAATAACCCTCTTTGATATTTAATACTTGATGACAACGTCAAGATTTCTTTAAAAACTACTGTTACTGTTATTTCCACGCTTGTTTTTGCTGTTTCCACTACCTTCCCCTGCCGCACCCTGACCTGTAACGACATCTCTTCAAAAACAAATTTGGAAATAGCAAGCTAACGCCGATAAAAGAAACAGCAAAAAATGAAACAAATACCCTCTTTGATGTCTAATACTTGACGACAAGGTCAAGATATCTGAAATTGAAAAAAATATGCAGAGAAAAACAGAGTTCTTGCCAAATCCAGATGAAAAAGCATGAAATTGTGGGAATTAGACATGGGTTTTGCTTAATTGTGAAGAGGGTTGGGGCCGGAGGGGACTAGTCTCTTCTCAACGCCGTATCTTGGATCGATTTCGTCGATTGGCGGCAGCGGTGGTGACAGAGGAGGGCCGTGGGGGATTCTTGGAAGGTTGTAGTAGCACATGGTGTTGCAAGAACGGGGTATATGGTGGCAGTGGTGGTGGCGGCTTTGGCTTGAAGAGGTTTCCCGCGACTTTGGGTTTGGTAATACTTGGGCCGATGATGATGATGGGACTATGAGTAGAAAAATTGTGAGAATCTGTAGGTGGCTAATGAGTGGCATGGTTGAAGAGAGAGAGAGCTCTTCACGGCTTGCACTCTGTGCTTAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGGAGTGGTGGTGGTGTTTATAGGAGGAGACGGGAAACTTGATTAATTTCAATCTTGATAGTAAAGATGACAACAAC
->URS00025DB68B rRNA from 1 species 
-ATGAGCATGCAGTTGATGGTAGCCACTTTCAATAACTACCAGGAGTTAGTAGATCGTGCGCTTATGATTGAAGGAAAGCAGCAGCAGATTGACAATCGTAAGAGGAAGTATGCACAGGGGAAGTACAATTCTGGAGCTCAGCAGAAGCCACGTTTTACCCCAAAGTCAGGGGACACTTTCAGCATACTCATGGAGGAGGCAGCTCGCACAATCATAATGGCACAAAGAATGGAAACGGAAATGGAGGAAGCAATGGACAAAACCGCACCAACCCGTCAACACCATCCAAGGCAGACCTGA
->URS0000382751 rRNA from 1 species 
-GATCGACCGCAGTCTACGAACCATGACTGCATGTACCGAACGATCGGGTAAGAAGCTCATAAGTACTGTAGAGAACGAGTCTATCATTGTGACGTACTAGATAGCCCGCTACTACGTCAGCAGCGCGTATCGGTAGTCGAGCGTATCGATTACTGCGTAAGCAGGCAGACGTATAGCAGATGTGAAATCCTGCTCAACTGGAACTGCGTCTGAACTGATAGCTAGAGTGGTCAGAGGGGGGTAGATCACGTGTAGCAGTGAATGCGTAGAGATGTGGAGGATACCGATGCGAAGCAGCCCCTGGATAACACTGACGTTCATGCTCGAAGCGTGGGTAGCAACAGGATTAGATACCCTGGTAGTCACGCCTAAACGATGTCGATTAGCTGTTGGGCAACTTGATTGCTTAGTAGCGTAGCTAACGCGTGAAATCGACCGCTGGGGAGTACGGTCGCAAGATTAAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGATGATGTGGATTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATGTACGGAACCTTCCAGAGACGGAAGGGTGCCTTCGGGAGCCGTAACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCATTAGTTGCCATCATTTAGTTGGGCACTCTAGCGAGACTGCCGGTAATAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGCTGGTACAACGAGTCGCAAGCCGGTGACGGCAAGCTAATCTCTTAAAGCCAGTCTCAGTTCGGATTGTAGGCTGCAACTCGCCTACATGAAGTCGGAATCGCTAGTAATCGCGGATCAGCACGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAGAGTTTGTAACACCCGAAGTCGGTGAGGTAACCGTAAGGAGCCAGCCGCCTAAGGTGGGATAGATGATTGGGGTGAAGTCGTAACAAGGTAGCCGTATCGGAAGGTGCGGTTGGATCACCTCCTTC
->URS000256CAD8 rRNA from 1 species 
-ATGTCATGTGCATTCCCTGTGCCCATTATTTGCTCACATGACATGATTGCCATGATTTCTTCTAGTGTGTTGCATTTTCGCTCCACTAGTTTGCACGACTTGATTACTATGCTTCCTTATGTTGCATCACCAATGACTCATACTTGCTCATTTCATGCGGTTGACGACAACCATCTATATGCTTTGCACACGATTCATATTGCTCCTTGTCATATCTCTCCATATGTTGACTCCCTCATGCTAGATGATTTGCCATGTATTGAGTGCAATTATGCCTTTATTCCTTATAATGAGTTTGCCCCCATAGCGCATTCTCACATATATTTGGAGATTTTGACATATTCCTTGTGA
->URS0001407240 rRNA from 1 species 
-GACGGAGGATGCAAGTGTTATCCGGAATCACTGGGCGTAAAGGGCGCGTAGGCGGCACTGTTAGTCAGGCGTGAAAGTCCTGGGCTCAACCTGGGAACTGCGCTTGATACGGCAGAGCTAGAGGATGGAAGAGGCTCGCGGAATTCCCAGTGTAGAGGTGAAATTCGTAGATATTGGGAAGAACACCGGTGGCGAAGGCGGCGAGCTGGTCCATTACTGACGCTGAGGCGCGACAGCGTGGGGAGCAAACAGG
->URS00021EF7D7 rRNA from 1 species 
-ACTTACGGCCACACCGCCTGGTTCACGCCCGATCTCGTTTGATCTCGGAAGCTAAGATAGGTTGGGCCTGGTTAGTACTTGGATGGGAGACCGCCTAGGAATACCAGGTGCTGTAAGGC
->URS0000188C7A rRNA from 1 species 
-GAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGTGATTTTTGTGGAAATTCTTTCGGGAATGGAAATGAAATGAAAGTGGCGAACGGGTGAGTAACACGTGAGCAACCTACCTTACACAGGGGGATAGCCGTTGGAAACGACGATTAATACCGCATGAGACCACAGAATCGCATGATATAGGGGTCAAAGATTTATCGGTGTAAGAAGGGCTCGCGTCTGATTAGCTAGTTGGAAGGGTAAAGGCCTACCAAGGCGACGATCAGTAGCCGGTCTGAGAGGATGAACGGCCACATTGGAACTGAGACACGGTCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGGGGAACCCTGATGCAGCGACGCCGCGTGAGCGAAGAAGGTTTTCGAATCGTAAAGCTCTGTCCTATGAGAAGATA
->URS0000626BAC rRNA from 1 species 
-TGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGAAGGAAGAAGTATCTCGGTATGTAAACTTCTATCAGCAGGGAAGATAATGACGGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGTAGGCGGCGGAGCAAGTCAGAAGTGAAAGCCCGGGGCTCAACCCCGGGACGGCCTTTGAAACTGCCCTGCTTGATTTCAGGAGAGGTAAGCGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCTTACTGGACTGACAATGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAATACTAGGTGTCGGGGCTCATAAGAGCTTCGGTGCCGCAGCAAACGCAATAAGTATTCCACCTGGGGAGTACGTTCGCAAGAATGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGCCTTGACATCCTGCTGACCGGTGAGTAATGTCACCTTTCCTTCGGGACAGCAGAGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTATGTTCAGTAGCCAGCATTAAGGATGGGCACTCTGGACAGACTGCCGGGGATAACCCGGAGGAAGGCGGGGATGACGTCAAATCATCATGCCCCTTACGGCCTGGGCTACACACGTGCTACAATGGCGTAAACAAAGGGAAGCAAGAGGGTGACCTGGAGCGAATCCCAGAAATAACGTCCCAGTTCGGACTGTAGTCTGCAACCCGACTACACGAAGCTGGAATCGCTAGTAATCGCGAATCAGCATGTCGCGGTGAATACGTTCCC
->URS00017894DA rRNA from 1 species 
-TACGTAGGGGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCGTGTAGGCGGTCCGGTAAGTCAGCTGTGAAAGTCAAGGGCTCAACCCTGGAATGCCGGTTGATACTGTCGGGCTAGAGTCCGGAAGAGGCGAGTGGAATTCCCGGTGTAGCGGTGAAATGCGCAGATATCGGGAGGAACACCAATGGCGAAGGCAGCTCGCTGGGACGGTACTGACGCTGAGACGCGAAAGCGTGGGGAGCAAACAGG
->URS00003589C1 rRNA from 1 species 
-CCGCGAATTCGCCCTTCGGGGTGCACCAGGCGCGAAACCTTTACAATGCTGGCAACGGCGATAGGGGGACCTCGAGTGCCAGGTTACAAATCTGGCTGTCGTTGTGTCTAAAAAACACGATATAGCAAGGGCCGGGCAAGACCGGTGCCAGCCGCCGCGGTAACACCGGCGGCTCGAGTGGTAACCGTTATTATTGGGTTTAAAGGGTCTGTAGCCGGCCTGGTTAGTCCTTTGGGAAATCCGGCAGCTCAACTGTCGGGCTTTCAGAGGATACTGCCAGGCTCGAGACCGGGAGAGGTAAGAGGTACTTCAGGGGTAGGGGTGAAATCTTGTAATCCTTGAAGGACCACCAGTGGCGAAGGCGTCTTACCAGAACGGATCTGACGGCAAGGGACGAAAGCTAGGGGCACGAACCGGATTAGATACCCGGGTAGTCCTAGCCGTAAACGATACTCGCTAGGTGTCGGCCACGGTGCGACCGTGGTCGGTGCCGTAGGGAAACCGTGAAGCGAGCCACCTGGGAAGTACGGCCGCAAGGCTGAAACTTAAAGGAATTGGCGGGGGAGCAC
->URS00024242CB lncRNA from 1 species 
-CTAGGTCTTAGTTAATAATTGTTTTTATATTTTCAACTTATACCCCATTGAAAAACCCAACAGCCAAGCGGCTGGGTTTAATTATGGTAGTCCAACAGATTTTTTTTTATTAGTTTTTATTTTAATCCTAATTTTTAATCTATCTTGATTTATATATCCAAGTTGTTGTTGTAAATAATAACTAGTCATGAATGGCCTAGAGGAGAGAGGGTAGTTTCTAGGTCTTTAGTGGAGTGGGTTCAATACCCACATTTGTAGCATTTTTTTTTCTTTTAGCATTTTATTTCTTTTAGCATTTTTTATGTTTATGTTTT
->URS00010F895C rRNA from 1 species 
-ACGAACGCTGGCGGCGCGCCTAACACATGCAAGTCGAACGAGCGAGAGAGAGCTTGCTTTCTTGAGCGAGTGGCGAACGGGTGAGTAACGCGTGAGGAACCTGCCTCAAAGAGGGGAACAACAGTTGGAAACGACTGCTAATACCGCATAAGCCCACGACCCGGCATCGGGTAGAGGGAAAAGGAGTGATCCGCTTTGAGATGGCCTCGCGTCCGATTAGCTAGTTGGTGAGGTAACGGCCCACCAAGGCGACGATCGGTAGCCGGACTGAGAGGTTGGACGGCCACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGGAGGAAGAAGGTCTTCGGATTGTAAACTCCTGTTGTTGAGGAAGATAATGACGGTACTCAACAAGGAAGTGACGGCTAACTACGTGCCAGCCGCCGCAGTAAGAC
->URS000253A30D misc_RNA from 1 species 
-TCCGGGTTTCGCCCGGCAGTCTCCCTAGATTATTCAACATAGGACAAGGGTTGCGCTCGTTGCGGGACTTAACCCAACATCTCACGACACGAGCTGACGACAACCATGCACCACCTGTGTACGGCCCAAAAGGACACCGTATCTCTACGGCTTTTCCGTACATGCCAAACCCAGGTAAGGTTCTTCGCGTTGCCTCGAATTAAGCAACATGCTCCGCCGCTTGTGCGGGCCCCCGTCAATTCCTTTGAGTTTTAGCCTTGCGGCCGTACTCCCCAGGCGGGGCACTTAATGCGTTAGCTACGGCACAGATCCCGTTGGTTGAGACCCACACCTAGTGCCCAACGTTTACGGCGTGGACTAC
->URS000078C8E8 rRNA from 1 species 
-CCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCGACGCCGCGTGAGGGATGACGGCCTTCGGGTTGTAAACCTCTTTCAGCAGGGACGAAGCGCAAGTGACGGTACCTGCAGAAGAAGCGCCGGCCAACTACGTGCCAGCAGCCGCGGTAAGACGTAGGGCGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCTCGTAGGCGGCTTGTCGCGTCGACTGTGAAATCCCGCGGCTCAACCGCGGGTCTGCAGTCGATACGGGCAGGCTAGAGTTCGGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGATGGCGAAGGCAGGTCTCTGGGCCGATACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGTTGGGCGCTAGGTGTGGGGGACCTCTCCGGTTCTCTGTGCCGCNGCACGCATAGCGCCCGCCGTCGGGAGGTACGGCCGCGACGACGTAAACGTTAAATAGAGTTAGACGGCGTGAGACGTGACCGACGGACGACGACGAGGGAGGTTAGG
->URS0000E2B2B0 rRNA from 1 species 
-CCCCTAGTAACTGCGAGTGAAGCGGGAAGAGCTCAAATTTAAAATCTGGCAGTCTTCGATTGTCCGAGTTGTAATTTAGAGAAGTGTTATCCGCGCTGGACCGTGTATAAGTCTCCTGGAAGGGAGCATCATAGAGGGTGAGAATCCCGTCTTTGACACGGACTACCAGGGCTTTGTGATGCGCTCTCGAAGAGTCGAGTTGTTTGGGAATGCAGCTCTAAATGGGTGGTAAATTCCATCTAAAGCTAAATATTGGCGAGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGATGAAAAGAACTTTGGAAAGAGAGTTAAACAGTACGTGAAATTGCTGAAAGGGAAACGCTTGAAGTCAGTCGCGTTGGCTGGGGATCAACCTTTCTTCTGATTGGTGTACTTCCTAGTCGACGGGTCAACATCAGTTTTGACCGTTGGATAAAGGTTAGGGGAATGTGGCATCCTCGGATGTGTTATAGCCTCTGATTGTATACAATGGTTGGGACTGAGGAACTCAGCACGCCGCAAGGCCGGGTTTTTAACCACGTACGTGCTTAGGATGTTGGCATAATGGCTTTAATCGACCCGTCTTGAAACACGGACCAAGGAGTCTAACATGCCTGCGAGTATTTGGGTGGAAAACCCATATGCGTAATGAAAGTGAAAGTTGAGAACTCTGTCGTGGAGTGCATCGACGCCCAGACCAGACCTTCTGTGACGGATCTGCGGTAGAGCATGTATGTTGGGACCCGAAAGATGGTGAACTATGCCTGAATAGGGTGAAGCCAGAGGAAACTCTGGTGGAGGCTCGTAGCGATTCTGACGTGCAAATCGATCGTCGAATTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCTGCCGAAGTTTCCCTCAGGATAGCAGAAACTCATTATCAGATTTATGTGGTAAAGCGAATGATTAGAGGCCTTGGGGTTGTAACAACCTTAACCTATTCTCAAACTTTAAATATGTAAGAACAAGCCGTCTCTTGACTGGACCGCTTGGCGATTGAGAGTTTCTAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGAACGCGAGGTTAAGGTGCCGGAATTCACGTTCATCAGACACCACAAAAGGTGTTAGTTCATCTAGACAGCAGGACGGTGGCCATGGAAGTCGGAATCCGCTAAGGAGTGTGTAACAACTCACCTGCCGAATGAACTAGCCCTGAAAATGGATGGCGCTTAAACGTGATACCCATACCTCGCC
->URS00007CECD4 rRNA from 1 species 
-ACGGGAGGCAGCAGTGGGGAATCTTGCGCAATGGGCGAAAGCCTGACGCAGCCATGCCGCGTGAATGATGAAGGTCTTAGGATTGTAAAGTTCTTTCGCTCGTGACGATGATGACGGTAACGAGAGAAGAAGCCCCGGCTAACTTCGTGCCAGCAGCCGCGGTAA
->URS00004EF8E6 rRNA from 1 species 
-GAATCTGCCTGTGGGTCGGGGACAACCACTGGAAACGGTGGCTAATACCGGATGAGCCGAAAGGTAAAAAATTTATTGCCCACAGATGAGCTCGCGTCTGATTAGCTAGTTGGTAAGGTAAAAGCGTACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGATGAGCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTCCGCAATGGGCGAAAGCCTGACGGAGCAAGACCGCGTGGGGGAGGAAGGTTTTTGGATCGTAAACCCCTTTTGTCAAGGAAGAAGTTCTGACGGTACTTGACGAATAAGCCTCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGAGGCAAGCGTTATCCGGAATGATTGGGCGTAAAGCGTCTGTAGGTGGCCAGCTAAGTCTGCTGTTAAAGATCACAGCTCAACTGTGGGAAGGCAGTGGAAACTGGCAAGCTAGAGGCTGGTAGGGGTAAAGGGAATTCCCGGTGTAGCGGTGAAATGCGTAGATATCGGGAAGAACACCGGTGGCGAAAGCGCTTTACTGGGCCAGACCTGACACTGAAGGACGAAAGCTAGGGGAGCGAAAGGGATTAGATACCCCAGTAGTC
->URS0001F5106B rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCAAATGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTG
->URS0001EC9022 rRNA from 1 species 
-ACGAACGCCGGCGGCGTGCTTAACCCATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTG
->URS000222C3C5 misc_RNA from 1 species 
-AGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAGCTCGTAGTTGAATTTCGGGATCAATATGTTGGTCGTGCCTCGGTACGTACTAGCATATTGGTTTCTCCTTTCTGAAGAACCATGATGTCATTTATTTGGTGTCGTGGGGAATCAGGACTGTTACTTTGAGAAAATTAGAGTGTTTAAAGCAGGCTCACGCTTGAATACATTAGCATGGAATAATGAAATAGGACGTTTGATTCTATTTTGTTGGTTTCTAGGATCGACGTAATGATTAATAGGGATAGTTGGGGGCATTAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGATGATGTTAATTTTTAATGTACTCTATTCC
->URS0002325A80 pre_miRNA from 1 species 
-AAAAAGACAAACCCTGGTTTCCGTGCCCAACGTTTGACCGTCTGTCTTATTTAAAAAAATTATGAAAAAAATTAAAAAGACAAGTCATGCATAAAATATTAATCATGTTTTATCATCTAACAACAATGAAAATACGAATTATAAAAAAATTTCATATAAGACGAACAGTCAAAGTTGGACACGGAAAACCAGGGTTTGCCTTTTT
->URS000130A086 rRNA from 1 species 
-GTAGGTGGCAAGCGTTGTCCGGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTTCTTTAAGTCTGATGTGAAAGCCCACGGGCTCAACCGTGGAGGGTCATTGGAAACTGGAGAACTTGAGTACAGAAGAGGAAAGCGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGGCTTTCTGGTCTGTAACTGACGCTGAGGCGCGAAAGTGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGGCCGCAAAGGCTG
->URS00002466F2 rRNA from 1 species 
-CCCCTACGGGAGGCAGCAGCGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCGACGCCGCGTGGGGGTGAAGGCCTTCGGGTTGTAAACTCCTTTCGCCCGGGACGAAGCCCACCTGGTGGGTGACGGTACCGAGCGAGGAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATGGGG
->URS00012DC715 rRNA from 1 species 
-TACAGAGGTCTCAAGCGTTGTTCGGATTCATTGGGCGTAAAGGGTGCGTAGGCGGCGCGGTAAGTCGGGTGTGAAATCTCGGAGCTTAACTTCGAAACTGCATTCGATACTGCCGTGCTTGAGGACTGGAGAGGAGACTGGAATTTACGGTGTAGCGGTGAAATGCGTAGATATCGTAAGGAAGACCAGTGGCGAAGGCGGGTCTCTGGACAGTTCCTGACGCTGAGGCACGAAGGTCAGGGGAGCGAAACGGGGATTAGA
->URS000259BFCE rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGCTCGGAATCACTGGGCGTAAAGGGTGCGTAGGCGGATCTTTAAGTCAGGGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTTGATACTGAAGGTCTTGAGTTCGGGAGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAGGAACACCAGTGGCGAAGGCGGCTCACTGGCTCGATACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGG
->URS000164E0EC rRNA from 1 species 
-CAGTCGCCACGGTAATACGGAGGGAGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCGCGTAGGCGGTTACTCAAGTCAGAGGTGAAAGCCCGGGGCTCAACCCCGGAACTGCCTTTGAAACTAGGTGACTAGAATCTTGGAGAGGTCAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAGGAGCACCAGTGGCGAAGGCGGCTCACTGGTCCGGTACTGACGCTGAGGTGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCCCGTAGTCCCTGTCTCTTATAT
->URS0000370A15 rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGGCAGCACAGCAGTAGCAATACTGTGGGTGGCGAGTGGCGGACGGGTGAGGAATACGTCGGAATCTGCCCAGTCGTGGGGGATAACTAGCCGAAAGGTTAGCTAATACCGCATACGACCGAGAGGTGAAAGCGGGGACCGCAAGGCCTCGCGCGATTGGATGAGCCGACGTCGGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGCCTTCGGTTGTAAGACGACTTTATTCAGGACGAAAAGACGTT
->URS00019773DC lncRNA from 1 species 
-ACACTTATTGAAGATTTATCTTGTATAGATTCTTTCTAAACTGCTTTATATATTCACTCATGTCATCATCACATAAACCTATGATGCAGGTAATAGTATTATCTCTCTTTTACAGATAAGAATACTAAAGCATGGAGAGATTGCTAGCACTAAATCACTTAGCTAATAAATGTCAGGATAAGAATTTGAGTACAGGGAGTCCAGGTCCAGAGTCTGTCCACTTAGTGCTGCCAAGTTGTGTGCGTGTTGGGGGCAATGGGTAGGTTAGAGGCAAAGATAGAGATATATAGATAGTTTTCAAGAGTTCCTGCCATGCCTCAGTGGAAAAGAATCTGACTAGTATTCATGAGGACACAGGTTCGATCCCTGGCCTCGCTCAGTGGGTTAAGGATCTGGCATTGCTGTGATCTGTGGGGTAGGCCATAGATGTGGCTTGGATCCCATGTTGCTGTGGCTGTGGTGTAAGCCGGCAGCTATAGCTCCGTTTTAACCCCTAACCTGGGAAAATCCATATACTGAGGGTGTGGCACTAAAAAGACAAAAAAAAAAAAAAAAAAAAAAAAAGAGAGAGAGAGATAGTTTTCAGATTCTTAATCTTGGTTACATTGGTGAATGGAGTTGGGCATAAAAGGTTGTTGCTTAATGTGGGATGTGATGAGTTTTTTTTTAAAAAACAGCAAGCAAGAAAGAAAAGTTTCACTTATAATTTGATAATGATTAAATTTTTATAATCTGCATCATCACTTTTACCATAAAAATTTCAAACCTGAAAAAATATTCTTTTTTCCTTCAACACATTTAGAAATACTGCTTTTGATTCTAAAAACAAAAAGAATGTAGATGTGGGCGTTCCCGTCATGGCGCAATCCAACTAAGAACCACGAGGATGTGGGTTTGATCCCTTGCCTTACTCAGTGGATTAGGATCCGGTGTTGCCGTGAACTGTGGTTCAGGTCATAGATGCGGCTTGAATCCTCCATTGCTGTGGTTGTGGTGTAGGCTGACAGCTGCAGCTCCAATTCAACTGCTAGCCTGGGAACCTCTATATGCCACAGGTGCAGCCCTAAAAAGCCTTAAAAAAAAAAGAATTTGTCTGTACTACAGGCCCAGTTTGCCACATATACATCTATGTCCTTGGGTCTTGACTTGACCACACCATGCTTTAGTTTCCTCTCCTGCATAAAAGGAATCATGATCCGTCCTCCCCCACTGGCTTGTGGTGAGTATCCAGTAACATCAGAGTTAAGTGCTCTGTGCAATGCCTGGTGCTTTATTCATCTCTCTCAACATTAGCTACCATAGTCATCATTGCCAGGCTGAACTCTTATTGCCCCTTCTCCTGGCCATTTGGAATTAAGATTGCAAACTGATTAAGTCATCTGAAGCAGTCAAGATACCAGGACAATGACGTTGGTGTGCTGAATAGAGAGTGTAAGTATACATGAGAGACTATCCTCAAGTAACTACTGATTAAAAACTGTTAAGTAGTTGTCAACTGGAAAACAAATGCACCATATGAGTTGTGAGTTAAGCTGGGGCAAAATGATGACTATAGCCTGGGAGAAAGCATTTCATATGGCTCTGAAAAACTGCTTTGAAGAGGTAGGAGAATAATATCAGTATATATGTGGTTTTGGTGAAGGGGAGGTACATGCAATCAAGCACAGATTTTGCAGAAGGTCACTGCTAGTCTTGTGAAGGTTACTGCTAATCATGAGGAGCAGATGTATCCACTAATGATTTCATTGCTTCTTTAGATATGAGAAGATGCAAGAATTCAGCGCATAAAATCTTTTAAAAATATCTAACTATCTGAAGGCCTGTTCTGCCAGGGATTCCCAGGCTGCCTCAATCCAGATCTCTACCTTAAACTCTTTCCAAGGGGTATTGAAGGTCAGGGGCTGCAGTGGCTTGTGCCTTAATCCTTGTAGAGACAGATGGCAAGTACCAATTTTTAGTAGTCAAAGGCTTGACCTGCAATGGTGACCTTGACAATGGTCCACCCCCTGAAGTGCTCCAAGCATTGGAGTTTTAGAAATCCAACCTCTGCCCATCAGCTCTCAGAATAAGGGGTCCCTTTTGTTCAAAATGGTGGTGTCTGCCATTGCTCCTTGTTTGCTCAGTAAGGATGAAAAAAGCCCAATAACATTATAAACCCTTCTTAACTCCTGCCTTTTACTTTTGAGGGAAGACTATGTATTCAGGAAGTGCTCATGGCAAAGCCTATTTAAGAAATAAAAAGAACAATAACAAAACATCTCAGAAATTCCTTTTGAAAACAAGAGCCCAGAACTTGCCTGAGACTTAATTGCCGCACACACACACACACACACACACACACGTGCACACACATACAGAGCTTGTCTCCTACATTTTCAGACTGTTTTAAAGTACAAGGCACAACCAGGTTAATAAAACATGCTTGAGGCTATGTTCTGTTTGTTCATTACACTATAAAGCATTTTAAACCTACAATTAATTTTAGATAAATTAAAGATTTGACACAGCCATGGTACTCGTGCAAGAGCATTTGTGTTAATATCTTATATTTTTCATACTCAATCACCCTGCTGAAAAGTTTAACAGCCTTCCATATTTATAACTGCTTTCTAGATTCTTCTTTCTTTTTTTTTTTCCTACCTTAGTTGTCAAAAGCATTAACGAAGCTGGCTTTGGGGAAGAATTCCAATTCAGAGTTATTTTTCCATGAGGTACTTAAGACTCCACACGGCAGCTTGTGATTATGTTGGCAGTGGCTTTGCATAACTGTTGGTTTCCTGTAGTATAAATAAGTGAACAGCTAAGAATGCTAATGTTTTGCTTTGACTAAGAAAAAGCTCTCAATAAATGACAAGGAATTACCCTCATTGGACTACTTAAGTTTTTCTTTCTCCTTCCTTTAAAGGGGTAAGTTAAACCAAAGCAATAGAGATAAGTGATCACATAATACTTGCTACCGCTTTAAGATCATTCTTCAAGTTGCAAAAAAAAATCAAATTGTTTCATTCCCAAAGTCCTTTCTAGTTGAGAAATTGAAGTGGGAGAAAGGCCATGAGGATCACTGGAAAACGCCAATGCAAGCAGTGTCCAATTGCAGCTAAATACAGGGCAAAGAAAGTCAGAGCCTTTGCCCTCTTGAGATTTGGACCAAAAACAGGAAAAAGATGCTTTGGCTAGGAGAAAGGACAGACAGAGTTTAGGGAGGAAAGGTTGCAGAGGAGAAAGCTTGGCAAAAAAGGTGTATGCAGATGGAATTCTCAGGAGCAGCTCCTGAGAGAGGCTTTGCATCATGTCAGCTGTCATGGTCAGGAGCAGGACAGGGACTCTGTGGGATGAGATATTATGGACCTTGCACAGAGCCCTGGGCCTTTGGCTAATTCCACATCCTCCAAAATCTCGAGTACTAAATGTTCCCATCCAGTCTCATCTGTTTTCACTCTTTCCCTCACAGAAGACAATCCCAATAAATGGAGTAAAAGCCAGAGAAATGTCCTCCCAGGACACCTGGCAGCTACCATTGCCCACAAGCTTCTCTGATCCCCACCTACCTTCTACCCAGTGAAGACTCAGCCTTCCAGCTGCCATCCTTCTTTCCAGGACAGGTTGACTGCACTGCCTTGGTGGATGAGCCATTGTTCACTTGGCTGCTATTCTGCAGTTCTGTGTTTCTCCAAAGGGAACCCTCCTGCACTGCTGGAGGGAATGTAAACTGGTACAGCCACTATGGAGAACAGTTTGGAGATACCTTAGAAATTTATACATAGAACTTCCATATGACCCCGCAATCCCACTCTTGGGCATCTATCCGGACAAAACTCTACTTAAAAGAGACACATGCACCCGCATGTTCATTGCAGCACTATTCACAATAGCCAGGACATGGAAACAACCCAAATGTCCATCGACAGATGATTGGATTCAGAAGAGGTGGTATATATACACAATGGAGTACTACTCAGTCATAAAAAAGAATGACATAATGCCATTTGCAGCAACATGGATGGAACTAGAGAATCTCATCCTGAGTGAAATGAGCCAGAAAGACAAAGACAAATACCATATGATATCACTTATAACTGGAATCTAATATCCAGCACAAATGAACATCTCCTCAGAAAAGAAAATCATGGACTTGGAGAAGAGACTTGTGGCTGCCTGATGGGAGGGGGAGGGAGTGGGAGGGATCGGGAGCTTGGGCTTATCAGACACAATTTAGAATAGATTTACAAGGAGATCCTGCTGAGTAGCATTGAGAACTATGTCTAGATACTCATGTAGCAACAGAACAAAGGGTGGGGGAAAAAATGTAATTGTAATGTATACATGTAAGGATAACCTGACCCCCTTGCTGTACAGTGG
->URS0000B9BAF2 tRNA from 1 species 
-GTCTTCGTGGCTCAGTTGGTTAGAGCGTTGGTCTCATAGTATGATCCAATCTCAGGTTGGGATATCCAAAGGTCGTGAGTTCGAGTCTCACCGAGGACA
->URS0000679C41 pre_miRNA from 1 species 
-CTTTTAATATAAGTATGTCCCATGAAATATTTGGGATATGCTTATACTAAAC
->URS00004B7CE6 rRNA from 1 species 
-GGCCGCGGGAATTCGATTCAGGCCTAACACATGCAAGTCGAGCGATTCTCTTCGGAGAAGAGCGGCGGACGGGTGAGTAACGCGTGGGTAACCTGCCCTGTACACACGGATAACATACCGAAAGGTATGCTAATACGAGATAATATGCTTTTATCGCATGGTAGAAGTATCAAAGCTCCGGCGGTACAGGATGGACCCGCGTCTGATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCGACGATCAGTAGCCGACCTGAGAGGGTGATCGGCCACATTGGAACTGAGACACGGTCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAAGGGGCGAAAGCCTGATGCAGCAACGCCGCGTGAGCGATAGAGGCCTTCGGGTCGTAAAGCTCTGTCCTCAAGGAAGATAATGAC
->URS0000D1B51B rRNA from 2 species 
-AAGTCGAGCGGACCGACGGGAGCTTGCTCCCTTAGGTCAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCTGTAAGACTGGGATAACTCCGGGAAACCGGGGCTAATACCGGATGCTTGATTGAACCGCATGGTTCAATCATAAAAGGTGGCTTTTAGCTACCACTTGCAGATGGACCCGCGGCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCGACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTTTTCGGATCGTAAAACTCTGTTGTTAGGGAAGAACAAGTACCGTTCGAATAGGGCGGTACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAGGGTCATTGGAAACTGGGGAACTTGAGTGCAGAAGAGGAGAGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAA
->URS0000C4FCDB tRNA from 1 species 
-GCCTTCGTGGTGTAACTGAAAGCATACTAGACGTGTATTCGATAGGTCCAGGGTTCGAGTCCCGGCGAAGGCA
->URS00022EE1E1 rRNA from 1 species 
-CCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAATTTCGAGATCGGTTTATTGGTCGTGCTATTGTACGTACTGGTATTACCGGTTTCTCCTTTCTGACGAACCTTAATGCCATTAATTTGGTGTTTTGGGAAATCAGGACTGTTACTTTGAAAAAATTAGGGTGTTTAAAGCAGGCTCACGCTTGAATACATTAGCATGGAATAACGGAATAGGACGTTTGATTCTATTTTGTTGGTTTCTAGGATCGACGTAATGATTAATAGGGATAGTTGGGGGCATTAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGATGATGTTAATTTTTTAATGACTCATTCGGCGCCTTAC
->URS00003E1810 rRNA from 1 species 
-ACGGGAGGCAGCAGTGGGGAATACTGCGCAATGGGAGAAAGCCCGACCCAGCAACGCCGCGTGAAGGAAGAAGGCCTTCGGGTTGTAAAACTTCTTTTAAGAGGGACGAAGAAGTGACGGTACCTCTTGAATAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCGAGCGTTATCCGGATTTACTGGGTGTAAAGGGCGTGTAGGCGGAGCAGCAAGTCAGAAGTGAAATCTCTGGGCTCAACCCAGAAACTGCTTTTGAAACTGTTGCCCTTGAGTATCGGAGAGGCAGGCGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCCTGCTGGACGACAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGAATACTAGGTGTGGGGGGACTGACCCCTTCCGTGCCGCAGTTAACACAATAAGTATTCCACCTGGGGAGTACGATCGCAAGATTGAAACTCAAAGGAATTGACGGGGGGCCCGCACAAGCAGTGGATTATGTGGTTTAATTCGACGCAACGCGAAGAACCTTACCGGGATTTGACATCCTGCTAACGAAGTAGAGATACATTAGGTGCCCTTCGGGGAAAGCAGAGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATTGCCAGTTACTACGCAAGAGGACTCTGGCGAGACTGCCGTTGACAAAACGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCTTTATGACCTGGGCTACACACGTACTACAATGGCGTTTAACAAAGAGAAGCAAGACCGCGAGGTGGAGCAAAACTCAAAAACAACGTCTCAGTTCAGATTGCAGGCTGCAACTCGCCTGCATGAAGTCGGAATTGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGCCTTGCACTCACCGCCCGTCA
->URS0000E780C0 lncRNA from 1 species 
-GGCGAGGGGGACACCGTGGAGGGGGGTTGGGGGGGACGAGGCCGGGCAGCTCTCCCGCAGGGGGCCGGGCAGGGCAGCGGGGGTGGGCTCTGCTGGGCGTCATCCCCCCCTCCCCTTCTCCCCGGGGAACCGGGGCGGTGTGGGGGGGGGGCCGCTCCCGGAGCATCCCCCCTTTGCCCGGCTCCCCCCCTCCTCCTCCTCCTCCCCGCTTCCTCCGTTTAAAGGCCGGGTCCCGGCGGGGCCGAGCGGAGGAGCAGCGGCCGCTCCGCAGCCCCAGTGCCGCGGCGGGGGCGCGCAGCGCACGGGGCGGGCGCTGGATGCGGCGCCGGGGGCGGGCGGGCGGCAGCCGAGCGGCTCCGGTCCGGTGCCCGGTCCCCGGTCCCCTCCTCCCGTCCCCCCCAGCGGGTCCTCCCCGCGCGGCGGCGCGGAGCTGGGAGCGATGAGCGCGGCCGGAGGAGCCGGCACCGCGGCGGGCACCGCCACCTCCGCCCTCTGCCTGCTCCTCTCGCTCACCGCCGTGGCCGTCTGCCTGCTGCTGGGAGCCAAAACGGCGGAGCTGCAGGGCCGCCTGGCAGCCCTGGAGGAGCGCGGAGCCGCCGGTCCCGGCCCGCTGCTGGAAGCGCTGCAGCCCCGCCTGGAGCAGCTCCTCCGAGAGAAACTGGGTGAAGGACTAGCTAAGCTGCGGACAGCGAGAGAGGCTCCGTCAGACTGCATGTGCCCCCCAGGCCCTCCGGGGAGGCGAGGGAAGCCCGGACGGCGCGGAGAGCCCGGTAAGCATCGCGGTCACCCCACCGCTGTCACGGGGCTGGGCACAAACATCCCGGTACCGCTACCATCACCTCTCTCTGACGGGCTGGCTCCTGGTTAA
->URS000240ACFD lncRNA from 1 species 
-AACCTGTTAATATGATTAATTATTGCAGTCAGAAGCAATCAATTTCCTGAGAGAAAATAAAAGTATTTAGTATTTCCTGAGAAAAGAACAATAAGTACATAAATTGAAATTACAACAGCAATGAAAGGTGGAAACCAAATCAGAGAAGAAGATAAAACTGGCAGAGGAGTGGAGATGTTTTGCCGCACGAAAAAAAAAAGTCAACAAAAAATACCGCATTAAACGTAAGATGATCCTTCGGATATGGTAAATAAATATATCCGATGAGATGAATTCAAACTATTATTGCGACTGTAGAGGAATTAACATGCTGGAACGAAGTCGCCCTAATTTTTCGTCTAGGGAGGGCAACTCGGGAGTCGAAGCGACGCTAGAGATGAAGGTGGAATGAAAAGTCTCTGAAGGAATTAAATGGAAAGAGAATGAGAAAAATAAACTGATGGGTGGGATCCATGAGCAAATAAGTTAAGATGACAATTGACTTCCCATAAAAGCCAATATTTTAAGATGGTAGGTAGGTCCCACAAAATTTTTTTGAAAAGTCTCTTAACCAATTAAAAAAAAACTGATAGATAGGCCCCAACATAAATCCACAATTAAGCAAAATATATTAGGCTGACAGGTAGGTTCAACAAAGATTCAAATTAAGCTAATATCGTCACGTGGACAAAAGGATATGGGATTTTATAGTAGTTAGTAGATGAGATGAATCCAAACCATTATTACGACCGGAGAGGAATTAACACGCTAGAACGAAGTCGCCCCAATTTTCCGTCTAGGGAGGGCAACTTGGGAGACGAAGCGACGCTAGAGACGAAAGTGGAATGAAGAGTTTCTGAAGGAATTAAATGGGAAGAAAATGAGAAAAATAAACTGAAGGATCGGTCCCATGGGCAAATAAGTTAAGATGACAGTTGACTTCCCACAAAAGCCAATGTTTTAAGATGATAGGTAGGTCCCACAAAATAAAATTTTGAAAAGTCTCTTTACCGATTAAAACAAAACTGACAGATGGTCCCCAACATAAATCCACAATTAAACAAAATATGTTGGGCTGACAAGCAGGTCCCATAAAGATTCAAATTAAACTAATATCGCTACATAGACAAAAGAACATAAGATTTCATAATAGTTAATAAATAACTCGCTAGCATTAATTTTTTGGTTTTTTTTTTGTTTTATTTTAGAATTATGTAAATGCATTTTAATTTACTCTCAATCAAACAAAGTTACATTTTGAATATTTTAAAAAACTTTATTTATTTTATAGCATGCGACAGGTGAATGTTCGCTTCCTCGATCTAAAAAGTATGAAACAAAAAATGTCAAATTTTTTTTTCACATGAATAATCGTTTATCTAGTCATCGGTGGGTTTAGTTTTAAGAAAAGAGGAATGCTTCAATACACCGGCTAAATTAAATCTAGCCGTTCATATTTGAGGGGCAAGATTGACTTTTGCATAATAGTTACCTGCTCAACAAGTTACCATTCGTAAGGGTACACTACAACAAAAATAGTCTATAGCTACACTTTTAAATATAGGTACATGTCAAAAAAGTGCTGTTAGCTAAAATTACCGACACTTTTAAAAAGTGTTGCTATACGTGGGGTCGCTAGATATATAGTGACAGTTAAAGAGTGTCGCTATAACCTAAAAGAGTGCTGCTAATTTACCAACACTTATTTGTTGGATTGGGCTTTATATTTAGGCATTAATAGATGTTTTTTTAAGTTTTAGCAAAAATGGGACACTTACTCAAAAGTGTCCCAAATATGTGTCCCTATAACCTAATTCTGTTGTAGTGGTAATATGGGAAAACAAATACAAGCTAATTACCAAATTTGATTAACCCTATACA
->URS0002381478 lncRNA from 1 species 
-ACTTACATAGCACTCGTACAATCGACTTGACAAGCAACAGAAAAGTACCCAATTAGTGTAGAATCAAGTATCAAAGCAAACAAAAAGGTAAAAATATAAAAAGAAAAACAAAGGAAATAAAGAACAAGGAAAGAACAAAAAGAAAAGAAAAGAAATGATAGAATTAGTTAGAAGGATTTAAATTAACTACCAACCAGCCTCCCGACGTTTAACAAAAATATTTCTCTATCGCATATAATGGGTTTTGAACTTGGAACCAAATAGAATACAAATATATGCTTAACCAGTGAACCAACAGGTTCATTCTTAACATAAATTTACACAGAATTGCACTTAACTATATAACACGGATAGGGGTTTTTTTTAAAAACAAAAAACAAAACTTCTAACAATGCGACTCGAACTCCCAATTTTTAACACAATAGAAGAACACAGAATCACAGATACAAAATTTTAATTACTGCAGATTCTCACAATTAAATTCTCAAATTTTTAGGGCGTTACACCACCACCCTAAGCTCTCAACAATGGACCTGTTGACTCTCATCCAGCACTCAACTGTATGATTATTCAATCACAAAGCAATATTTATAAACCAAGAAAAATTAGTCATTTTAATACTACTCTTTTCCAATTACTTTAAGGCACAATGTGTGTTTTTCCGTAATAAAACACATTTCCATAGAAAATTATGTCTCTTTATCTTGATACTTTTCCATAAAATTTATTATTTATATTATTTATATTATGTATCTCTTTGTAATGTGGGAACACTAACATTGGAAACTATTAATAGATTTTATTAACAAATTGAAGCACCAACTGAAGTTGTAAATGATTCAATCATTAAGTCAAAAGAGATGGTCAATAGAAAGAAAATGGTAATGATTAAAATAAAATAAAAGAGTTTATATATCATTAAAATAATTATTAAGTATATTTAAAATTATCATTATAAATATTTATATATGTGGAGTGTTTCTTGCATTTTTTGTTCAAATTAGAGTCAAAGTAGAGGCGACGTTGCAATGAGGAATCACGCGACGTCGCAACGAATCGACGACATTCGAAACAGAGGCAATGTCGTGACGATACGACGAGTTCCAAACTTAAAGTAGTTACGTATTAGACTATCAACAAGGTTACTTTTCCTAGTTAAACTCTGATTACATTAGAGATATTATAGTCATATTAGAACTCTAATCTTAGCCTATTTAAAGGGCAATAACAATCCTAAAATCGGAAGAACATAACACAGCATTAGAGAGAAAATCAAGAGAGAGTTTTAGAGAGCTTTAAGGGAATTTTGTGTTTTTAGCCACTGAGAGCTTTGTATTATGGGTTAAGGTTTGTTTTGAATTTCTCCATCTTGAATTCTTTGTTTGTTTGCTCATTAGTGAAGTCTCCTTTGCCTATGGTTTTTTATTCTCTTGATTGGAGGGATTTTTCCACGTAAATTTGTGTGCCTAGTTTTCTCTATTCCTTCTTTCTCGTTGTTTATACGGGTTGATCCCCAACAATATTTAGTATTTTATTATTTTATGTATTTTTATAATTTTTCATTGAAAAAAATATAAATGTTTTAAGTTTTTTTTTTCAATTTTTGAATTTTTTAGAATTAAGATTAAATTGTTAGAATGTGTAAATATTAATACCTAAACTTGTTAAGTTTTTAGAATTAGGATCAAATTGATAGAATGTGTAAACATTGGAGAGATAAATTCATTATTATGCCAATAAAAAATCACATCAAACTTCCCTTAACTATTTAAAGACAGAGTGACAAAAAAATCAAACTTAAAAAATGTTAGTGACTAAATTAAAAAATTTTATAGTTGACATTTTCTTTATTTCTATTCATATTCATTTTACAATACATATAGGATTGTGGGTACCTCCCAACAATGTTGTTTTCAATGTTTAAACTTGTGTTCTTCTCTTATGAATACAATATGTCTTACCACTCCACCAAAAACATGTATATAATAGTAATAAACTTTTTTTTCTCTCCATGCGATGCACGAGTTGCTTGTGTGTATTAATTAAAATATATGTAAAAAATAGAATGTCAGTAATGACAATATATCACAAAGAAAAGAGAAATAAAAATAAAGAACACACCAATTTTTACGTGGAAACCCTTTTGGGAAAAAACTACAGGTAGAGGAGAAAAAAATTCACTATGTCGAATTCGAATGATTACAAGAGGAGTAAACTATGTCTATTTATAGGCTTTGTAAAACCATATTCTAATAGGAGTGTAGTAAGATTGAAACACCTTATTCTAATCAATATCAAATAGATAGAGTTTAATAAGGTTTAAAAAACCTTATTCTAAAATAAAATAAAAGAAGTATAATTCTATAGGGATTTTACTTTTATTTTATTTTACCACTGTATTCTATTTAAATAAGGATTCGGGTCACTTAATTCTAACAATATATTATATTAAATTTTAAAATTTATACATAACATATTATAAATATTATTATTAAAAATTAAAAATAATATAAATATTTAATTTTGTAATGATGATAATTTAAAATATAATCAATATAATTAAAAAAAAATTTAATAAAATAAAATAGTTAATATTACTCTCAATTATGATTTCCGCATTACTTAAAAAAAATGCACAACTAATGGAAATATTTGAGTACAAAAATCTGAATATTAGGATAATGAAATTGTTTAGCAAAAGTCAACAATGATTAAGCATTGACACCCATAAACTTAAAGCATAATGAATGGGGTGTTTAAATTTAATTTTTTTAACATTTACTTGTGGAAAAAAGTATTAACCAATTAGGTAAATATTCAATTTTCAGCGTATTTATTTATTTAATGTAATGCTTTGTAATTTTTTTACTACAAACCATAGTCATAGGGAATACTAACATATTCTTATTCAAATGAAAATTTAATGCTTCATTAAGATAATTTTAAGCATTTAAATGTTAAATTAAATTATTATTCAGTTTACAACTTTTAACAATACGTACACATTAATGTGATAAATGTCATGTTTTAAATATGCTACATTGAATTAGCTGCTTAAATTGTAATTGTATATATATGATGTCATCTCCTACCGACTTAAGAAAAACTCTCAAATCCAAAATAAATTGAAATCTAAATCTAAATACAAATATGCTGAAACCTGCTTGTTTGCACTTTAATGGATCTTATAAACTAGTTGTGGGCCTGTATGTATCAAACCTCCTTATCCAAATGCAAAATAAACCCTAATTCATTTAGAAATAAGTACAGAGAGATCTGGTTATAAGCTTCTTAAGATGGAGGACGCCACATATGCCCCAGAAAAAAGTCCAAAGGCATCGCTTGGTACTTGGTACTCCCATTTCATTCTTTTGGTGGTTTGTTTCACTGAGTTTAATCTTAAATGGTTCCTTATTCACTGTTAATTTCGAATCGTCTATTTGGTTTCAACAATCAGTGATTGGCCGTGATGACACAAAGGCCGGACTTACGGCTGCTACTGCTCTTCCCTTGTGTGGTAGTAGTATGATGTTTGTTGTGATAAGGTGTTTGTGCTGAGCCACTTTTCTCTCTACGCTTTCTCTATTTTACTTGAGATATTTATACTGTGGATTTCTAGTTTGAATACAATTTTTTTGGTTATAGTAAACATGGGTTTGTTTTTGGTGAGCCTGCCCTGAATTTGTGTGGGATTCCCTTTGTAGTTCTAGGAATTAGTTTACCGATTCTACAACTGACCCTTGAAGAATTAAGTATTCCTTCATTTTCCTCATCTTATGCAGCTGATCAGCAATGATTCCTTTTAGGCTTGTTCTCTTCTGAACTTCAAATTACATCCTTTATAAGAGATTTGGTCAAGCTATTGTGTAGGGTTTGTAAGATTTTGCATTTTATTGGCTTTTGCATTGCATCATTGACACATGGTTCCATGTAAATTCTGATATTTCAACTTCTAACAAAGCATTTTTGGCTGTGCCTCAATGCTATGTATGGAACACTACTGGTGTTGTTTTGCCTGCTTTTTTGTTTTTACGAATTATGTTTAAAAGCCTTGTTTTGCTCTCAGTCCAGGATCAGCAGTTAGACATTTAGATCACATCGATGAATGTAGGTCTTGATAGTTGTTGATTCTTTACATGCATAGAAGCTAAAGAAAAAAGTTCCAATTGAATTGCCATGTATCTTTGTCACAAAGACATGATTTTTCCTACATTTGTAGAGTGTATGAGTTGCAATTAACTACTATCATAAGGGCAAACCATGCAACTATTACCTGCAAAAGAAAATGTAAGAGCATTTGAAGTGATGACTGCATTCTATAGCTGAGAATGCAACAAGGCCATAAGAAACAGTTTGTTCAACTTGATAAACATCATAACTTCTCTTGTTCCTATGTGATGATTGTCTGTGGAAGATTAGACCTTTAGAGTTGGCAATACTTAGAAGGTTATTGTTCCATTTAATATTACTCTCAAAGTTAGGCACCTCTGTTGATTTCAATCCTTCATGAAGTTTAACGGACGATCCGAATATCCCTCAAGTCCTGGATCTTCAGAAAAGGACCGACCAAAGTCTCCATGCATTAGAATTGATATGGATATCAAAGAGGGTCAAACAATAACTAGATGTTAACTTTGCAAGCAACCTGGTCTTGTTGGAAAAGAATACACCGAAATGTTCTGCAATTTAATGCACAAAGGTAAATTTTATTTTAATGCTTAAGCCATGATCATTTTAGTTATTTTATATTCTCTGGTCTTATATGTCAATATGCATAATTTTTGTTAAACGAAAAATATGTACAATGCCAAAAAAAAAAAAAGATTATTAGATGTATTTTTTCGCTATTCATAATTCTTCTTTTCGTTCATTTATCAATTGGCTTACAAGTTATCCTACAAAATTAGCTGGGGTGGTTATTTTTTCTGGTTCCAGAAAAATTCAAGATTATCCTTTGAATAGATTTATTTTTATTTTTTATTATCTTATATCAACCTGTTTATATAAAATGTAAACTGACAAGAATTGTTATTGTTTTATTTTGGGATAATGTCACTTTTGATACTTGTACTTTCACAAAATATTTAATGTGATATTTGTACTTTTAAAGATGTATATGTGGTACTTAAACTCAATATATGTTTTATTATAATACTTGTCCTTTCGTAAAATGTCCAATGTGTTACATGTACTTTGAAGATGTCTAATGTGGTACATTAATTATCAATATATGTTTCATTATGGTACTTATTAACAACGATAGTAAATTGCTAAATTAACCAATAAAAATGTGACACAATCTTTTTTCCAAATCATAAAGACTACATGAATAATTTAACATTATGCAAAAAATTAAATAAAAAAATTAAAATTAAAAAACAAGTAACCATATGGTTGATAAAGAAATAAGTAAATAGTAAACTTACAGAAAAGTACATGTATTTTCATGGTAAAAAAAATCATTTCAAAAAGGAAAATTTTATATAGAAGATGATGTTTTTGTTTATGTAAGTTTAATGTTTATTTCCTTTTTATTAATTGTATGATTAGTTATTTGTTTTTTTAATTTAATTTGATGTGTTTTCTTTATTTACTTTCTCACATAATGTTATATTATCTGTTTGGACTTGATGATTTGATAAAAAAATTACGTGTTGAATTTTCATTGGTTGGTTTAGAAATTTTCTAACAGTGCTATTAGTAGGTACCATAATAAAACACATTTATAATTTGAGTACCACATTGAACATTTTATGAAGGTACAAGTATCATAAAAAAATACTTATTAATAGTTTAGGTATCATATTGAATTTTTCAAAGTATAGATACTATATTTTTGAAAGTATAAGTACCAAATGTAGCATTATTCTTTTTATTTTTTATTTATAAAAAGCTTACACCACACGGATTTGTTTGTCTTGGTACATTTTCAACTATCTAAAATATTATTTTCGATAGTCTTTTTTTTTTCTCCGACATCAAACTATTTTTTTTTGTGACTTCGAAGATAAAAAACAAACACAAATTACAAATACTAGCCCAATTCCCCAAGTGGAGATACTTCAAAAATTCACAACTCATGGCTTTCCCTATGTACCAGCTTGACCAGTCTGTCAGTCTCCTGATTGTCTTCTCTAGAAATATGTGAAACACTCCAATGATTAAACTGTGTCAGCAATTGAAAAATCCTCTTTATCAAGGTCGAGTTAAATCCTTCTGTCAGACTCTTTTGAATAATCTTAATTGCTTCAAGACTATCAGTATGAATAATCATGTGATCATAACCCCGATCAATTAAAGTACCTAAATCATCCAAGATTCTCCATAGCTCAGCCTCAAACACTGAGCAGCTCTCCAAGAATCTATTGAAGCTAAAAATTCACTCCCCATTTCGGTTTCTCACAATTCCCCCTGCAGCAGCAGAACCACTTTCATATATGATAAAGCCGTCATTATACAAACACGCCTAGTTCCCAACCAAATGTATAGAAGAAGTCAGAATTTGAGTCGAATAATTTAAAGTCATACCAGATGAGGCAAAATGTTTGGCCCAACAATGAGAAACTTTGATGGACTCAACATTACTCCAAGAAACATCTTGGAATATGAAGATATTACGATTCTTCTATATACACCAAATAATAATCCCAAAAAAGCATTGCCAAATTATGATGATTTTGTAAGTTTGAGGTGAGCCAGTCCTACAGATTGTTAGAATAAAATGTCTTGTCAATCAATGGGAATTAATAGATTCTAAATGTTACACACTGCATTACAGTCCCTGATAGCATGCAGTACATCTTCTGAGATATGTCCACAAACCCTACACAATGAACTGTGCTCGAGACCTCGACGAACCCTTTCCACATTTCTCATCAGCCTCTACTTGAACGCAAGCCAAATGAAGAATCTAACCTTCTGGGGTCCTTGAAACTTAAAAGGAAAAGTGCTACACATCCTACTTTGGTTTCCAAGATGATTCCCAAAGTTTACCATATGCTTTTAACAGAAAAGGAGCCTGTCGAGGTACTTTCCCATATAATTCTATCAGTACCTACTGCCAAATGCGATGGGGGAATCCCTATAATCTTACAAATTATCATCTTAGGCAACCAAAGTTGAAACAAATCTAGATTCCAAGTGCCATTACCAAGAACCATATCACTCAAAACATAGTCCAAATCAAGGTTCATGTGACTAGGAATCATTCAAACAAGAGGCCCCACACCTAGTACCCACGAATCCTGCCAGCATCTGACACTTTTCCCATCTCTCACTAACCAAAGCAGATTCTCCAAGTAAGTGGCCAAACCTTTATAAGGGCTCTCCACAAAAACAATCATCTGTTGCGCGATAATGAGTCGGGCAAACTTTTGCAACCTCATATTTAGCTCGGAGAATCTAGACCCAAAGAGTTTTAGAATCTGTCACAAGTTTGTACCTTAAATTCATTATAAAAGACGTGTTAGAATCTTGAAGCTTCCGAAAACCAAGACCTCCATGATCTTTAGGCTGATAGATATCTTCCTAGCTAATCAAAGCCATTTTCTTGCCACTACTCGAAGATCCCCAATCAAATTGATACACCATATGTTCAACTTCCTCACACAAACCTTTGGGTATCATCATTGACCGCATAAAGTAACTAGGGATCACCAGTAAGACTGATTGAGCCAGAGTAGCCTTACTAGCTAGAGATAACGAGCTTGCATCCCAACATCACAATTTGCTCTGAACCTTGTCAACAACAAACCACAAAGTGTTATTTGTTACTTTTTCATGGAACAAGGGCACATCCAAATATTTCCCAAGATTTTGGACTTTTCGAAAGCCAAGAAGATTGCAAAATCTATCCCCCATATCCTCACACCATCTGAAAAAAAAATATTAGTTTTATTAGCATTAATCTTATGTCCAGAAAAAACATAAAAACTATCTAGGATTCTCTTCAGGACTGTGGCTTGATCCTCTTCTGCTTGGCCAAACAAAATCAGACCATCTGCAAAAAAATAGGTGAGACAGGGGAGGACCTGATTGAGCCAAGTGAATAGGCATTCAACACCTAGAATTGACACTCGAATGTATATTGTGGTCGAGCCATTCCATACATAGAATGAACAGGTACGGTGAAAGTGGACACCCTTGACGTACCCCTTAGTTGGACGGGACTTCTGTGTTGTTGTGTCATTCCACAAAATTTGCATGGTGGAAGTTTTGATAGCTAACATAATAACATTAATTAAAAAATTTGGAATACCTGCAGCTTGGAGAGATGCTTCAATAAACTCTCATCGCACACGATCATAGGCATTCTCAAGATTAATCTTAACTGCAAACCAGTTAATAGACTTTTTCTTAATCCTTATAGAGTGAAACACTTCCTGAGTAATAATAATATTATTTGTAGTGCTCCTTCCTGTAATAAAACCAATCTACTCTTGGCTGATAATTTTTGAAAAAACCAACTTAAACGGATTGACAATGATCTTCATCACCAACTTATAGAGAACCGAGCACAAACTGATAGGTCAAAACTGAGAAAAACATTTTGGAGTTTGAAACCTTTGGAATGAGAACAATTAAAGTATTGTTGAGCTGCGGGTCCATTTTTCCCCTAGCAAAGATATTTTTGATCCATGCACAATGTAACACCCCGAAAGTTGCTACAGTAAGAAAGTGAGATATTATCTTTGATATAGTAAAATAAGAAAATAAAATGAAAAAAAAGGGAAAAGTTTGAGTTAGGTAAACAAAATCTGTTTAGGAAGTATATTATGATGTATTAATTCAAGAAAAGACTAAATAGCAAAAGTGAGAAAAGTTTTGTGACCTAAGAGTAAATACTCAAAATTTGATGGGTTAAAGTGTAAATTTGAAAAAGTTGAAGGACCAATAGTGCAAATATTTTAAGGGTAGAAGGATCTAGAAAATAGGGAAAATGGATGAATTAGGACCAAATTGAATAAGTGGAAAAAATATAAGGGGTTAAATTGCAATTTTACTAGAATGAGTAATGACTCAATGGAGGAATTTTGAAAGATCATAAAGGGCAAAATAGTTATCTAGCAAGAAAGATATTTGAAGAGTAATGATGATGTTGGTGATATTTTAGATTAAATAAATAAATATTAGTTTATTAATATTTTGATTTGACATTTAATTATATTTAATTATTATATTTAGTATATAAGGAAAGAAAGATGAAGAATTCTCTTCATCTTTCCATGGTTCCAACGTGAGAAGAAGAAAAGAAAGAAAGAAAATTTTTCTTTCCTTTACAATTTGGTCATTTCACCAAAAATCCTCCATTTTCATTTTGAAATCAAAAGAATTTCTATAGCCACCAAGAGAGAAAAATAATAAGGAGACTATGGGGAGCTAGAATATCAATTTAGATTCGAGAAAATAGAAGTTGGAGGAGAGAGAAAGTTAAGTTAAAGTTTGGTTTCATTAAGTTGATGTGAAAAAAGAGATAGTGGAATTAATTATGTGAATTAAGTGAGATGTCAAAGAAAAATTATGTAATAATGAATAGAGAACTTTTATGAAAAAAGGTGATTAAATTGGAAAGTTATAAAAGTTTACAAGAAAATATTGATAATAATGCACATAGTGAAAAATAAAAGAATATATGAATATTGTAATCCAAACTAAAATTATTTCCTAAGTTGTGGAAATTAATGGTTAAATCGTAAATTTGAGAAAATTTATATTAGAAATAGAAAAGTGAAGTGCATAACAATTAGAATGAGAAAAATTGATGTTGTAGTGAATTTTGGAATATTAATAAGTATTGAATTATGTTATATGTGTTATTAAAAGTAAATATATTGTTATACGAAATATTGTGCTAATAACTAAATTACAAAATATTAAAAGTGATATGTGAAATACATGATAAGGATTATGAGAGAATTATGGATGAATATTGAATTTAGTAATATATTACATGTATTAAAGATAGTGAAGATATAAGTATATGGATTATTGTTATAAGGATTAAATTGTAAAGTATGTAAAAGCATTATGCGAAAAGTGTAAAAGTGATATGTGTGTATGATATAAATTGCCCAAGTAGACGAGATTAGAACTACTAGGATATTAGTGGCATGCCATTAAGGGACCCTAGCGCGCTCTTCGATTATTAGTACGTCAGTGTTATCTGATTAGCACATTTGTGCTCTTTGTATAGCACTTTAGTGCTCTCTGTTCAATAGTGCATAATAATGCACCTCTGTATCAGTTTCATATATATTAAGTGTTCTGTTTAGTCTACTGGGCCTTTGCTAAAAAGGTAAACAATTTTCGTTACAAGGTAAAGGTTTATCTTTGATTCATGTTTGAAATAATGAATTAAAATAAATTGTGAAAGAAATAGTGAGAAAATCATGAAAAATTACACTAAATGGTGAAATATGATACATGTATAAAAAGAGTAGTAATTTTTATAAGTTTATTTGAGGACTTAAGGACTAAATTGTGAAATATGTAAAAAGTTACAAATGAATATGATAAATAAACAAAGAAACGAGATATTGGAAATTAAGAAATTTAATAGAGTTTAAATATCATGGGTACTTACTAAGTCTTCACTGACTTAATGCGTTTATTTTCAACGCGTAGGTACAGTGCTTTTGAAGAGTTGTAATTGAGGTCATGGACATCCATCTCATCACATCTCCAAGTATCAAGAGGGTATGTTTCAAAATTTTGAATAGAATGACATGTACTTAGGAAGATCAAGCGTGTTCCAAGTAGTAGGGACTAAAATATAAGTTATGAAAACTTTATTTTTTTTAATGTTCAAACATATTAGTGATTAGCCAAAATCACTTTGGCACCAAATGTAATATTCCTATATCAAGTTCCTTTGGGTCAAACCGGGTATAGGGGTGTTACACATAAATCGAGCCCCCAATATGATCTCACTGACTCTGGAAGAAGAGAGCTTGATATCCATCACTTTCTAGAGCCTTTAGAGGGTCCCATATCAAACAAAGTGGTCTTTATTTCCTCATCAGTGATGGGCTTCAAAAATTGGGTCTCGCCATCCTGAAGTTGCGAGAAAGAACTAGTAGGAAGTCCCTTCATCGGTCCTGGGTCTTTACCATATAAATTGTTAAAAAATCAAATCGCCTCATGCCGCAAGTTTTTATCATAAAAAATCCACTCTCTTTTATTATTTTTCAGAGCCACAATTTGACTTTTCTTTCTTCTTCTAATAGTATGGCTACAAAAAAATTTTGTATTTCGGTCCCCCAAAGAGAGCCAATCACATCTCGTCTTCTGTTTCTAGAGAAGTTCTTCGTGATACAAGACCTGTTCCAGTTCCTCCCTAACTTCCAAATCCAACTGAAATAGAGAATCCGACTAAGAATAATCCAAATTATGCTGAATAGAATGAAATTTATGAAGCAACCTTTTTTACGAGACCCAATGTGACCATAAACCTGTTTGTTCCACTCTTTTATTTGACTTGTAAAGTTAGCCACTATATTTGACATTGAGCCATGAAAATTCCAACTCTTCTATACAAAGTCAGTAAACTCTGAATGTTCAACTCATCCTGCTAGAAACTGAAAAGGACATCCCATAATAGAATTAAGCCTAGGATGAAGTGATAAAAACAAAGGCCTGTGGTCAGACTTGAGTCTAGGGAGGTGAGTCACATAACAATTTGGAAAAGACACAAGCCACACACCATTCTTGATAAATCTGTCTAACTACTCATAGACTCTACCTTTATACCACGTGAAAGGAGCCCCTCTGAATCCAAAATCATGAACCCCAGTCGTATCCATAAAATCCCCAAAGTAAGAACATCTTTTCCCACTAACTCGCCCACCTTTCTTTTCGCTAGAGGCTTAAAGCGTGTTAAAATCTCTAACTACCACCCAAGGAGAACCATTACTTGGAAAAGTCGCATTTAGAGCGTCCCAAAGCCGTTTTCGTTTACAACTATTAGAATTATAGTAAACAAAAATAACAAAATGGGATGCTGGGAAGAACTATCGAAAACACGAGTTAAAATAAATTTAGGATGGCTTCGAAGAATTTCGACTTGAAGTGACTTCTTCTATCCAATCCAAATACCTTTAGAGAAACTGATTGCTTCTACCTGGTGAGAACATTGAAAACCAAGATTAAGGATAACCGAGTCAACTTTTCCACCACTAACTCTTATTTCTAACAGACGCACAATATCTGGTTTATATTCTCGATTATATTCATGAAAAATTTGCAAAAACTTGCTACTAGCACACATTTGAAAATTCCAAGAAAAATAGAAATAGTCAAATAATAATAAAAAATAAAGAAGGTAAAAAGTAACTATAAATACTAATTAACAACCTCTTTCACAATTTTTTCCATCATGGTTCAAACTTCCCTTCTCAACCTCTTTCTTGATCTACGAGCTTATGAGTTTGGCCATAGAATTCATGGAGTTTAATAGCGGAACCCTCGCATTACCTGAGTTTTTAAATCATTCCCCACGGTCCCAAACGATTTTGCTAATAGCGTCGCCACTTCAGATAGAACCACTTTTAGCCCCTGAACCCTTCCTTTTGAAATCATTATTCCTTTACCTCTTCCAAAAGAATCAACACCTTCATTTGAACTGATATTTTTAGGTAGCTCATTATCCTTGAAAATAATAACTAAATGTCTCATAGGGTCAAGGACCTCGCTATTGAGTTTCACCATTGACTCAATAGGATCGTTGAAGGTAGGGTTAAAATGGGAATTCACACCCATCATGATTAGATCATCCATAATATGCGAAGCCCCCAAAACTTGATTTTACTTCATACCGTCTTCTTTCAAAGGCAAAACAATATCCAATTTATTCCCATTTCCAAGCTCACATTGACCAGTCTCTGTTAAAATTGGGTCTCCGCTTATTGCATTTTCTATAACCCCCGAATCTGTGTCAATACAAGGTGGACCATTTTGTATACTCGTATTTGCTCCAAGCCCAACCTCTATTAGAGTATCAGTCTCAGGGTGAGTTTGGATGGGTGGTACGTTTACCTGCGGTTAGTGTAAAAACAACGGTGGCGGTGAGATTAGATACTATAGCGATACTGTAGTGTGAGACAAAAAGTAAGCTAAACGCACCACACCGCACCCAATCACCCATCCAAACCCACCAGCATCTATGGCCCAAAAGCCTCTATCGTCTCCACCACCTTATATTTTTCCAATGAGACTTCCACTGCCGAGACTCTATCCACCTCTGTAATGTTCGTTGAGCCGGAGCTAGGACAAAGATTCTGCATGTGTCCAAACCTGCCATAATAGAAGCACACTAACGGGAGCGATTCGAATTCAACCCTCTGAACCACTTTCTTAACCAGGATCTGTGAGATCAGAAGTTTTCCCAGATCGATGAACACTGCCATTTGGGTAAATTTGCCTCTCGAGCCCTTGTCCATCTGAAAGTCGAGTTTCGTGACTTTACCTATCAGACTCCCTATCTATTGCAAAACACACTATTTGTAAAGGTCACTTGGCAGACCAAGCAACCAGACCCAGACCATAGTGCTACTGGGAAAGTCTTGAAGGGGATTAAACTTTGGGGGTCCACGATTGAACAGTGAGGTACTGTCTGATCACGATCCACGACCCTTGGGGGAGAACTTTCTTGTAGTCCTCTCGGCTTTGAAATCTAGCTAGGAAATATCCATTTTCAACATCCATGAGATGGAACTATTGTGAGGGTTTTCAGAGGTTGTGAATCCTATTTTGTAGGAGGGTGTAGGATAAGTTCCGACCTAATAGTTTAACCACCACTGTGGTCGTCATATCTCTAACGACAATTTGTTGGATCCTTTCGGAGAAATTGATTGCTGGAATTCCATTGACATTAGTCCTCATGATATCTCATTCTATAAAGTCAAAGTCCTCATCGCAACCAGATCCAGAAATCCCTCGTCCCAGAACTTTGTCTATCCAAGACATTCCCGATGTTGGTGTTGAATCTACGGCCATATCGCTATTCGAATTTGAATCCAAGTCCTTAAAACGAACTTTTTTGGTGTTCCGATCAATCGAGTTGTCACCTCCGCCATCCTCAGTCATCTATATCAGTTGATTTTATTTTCTCTTATCAGTGCTTTGATTAAATGATAACGATGTTCACATCAACATATATTTTAATGTTTTAGTAGGTACCTAAAAAAGCATAAAGTTAGTTTATGTTTTCCAAGTTTTTTTTCTTTTCTTTTTTAAGTATATATAATTCAACACAATTCAAATTTATTTTCATTCATATTTATATATTTGATAAAAGCATCTTTATTATAACTAAATGACCATAAAATCAATGGGAAAGACCTTGCTTATGCTTGTTATTAGTGCACCCCTCGATCATGACCTTGATTACCTTAGCACAATTGGGTTCGACCACCACCTATCATAATTTATCTCCCTTAACCACGCCATAACTTCTGCAAGATCAGGTGCCAAGCTTCCTAAATTGTGCCCAGTACAACATTTCACCAGAATGTTGATTGCGTCCCTGTTACGCGCCATCCACCCCGCTGCATTTTCATTCTCCAAAGTGATTGCATCAACATTACATTTGGTCCAACAACTAATTTACCTTTTAAATCACCCAACTTATCATTTAGTTTCACATAGATCATAAATCTTTAATTTAATAATATCACATCATTTGACTTTTAATACTGGCAAACTGTTGAGAAGCATCAAACGGTTGAATTCATTTCACAATAAGCTTATGTTAGAATTAAGTGACCCAAATCCTTATTTAAATAAAATACTGTGGTAAAATAAAATAAAAGTAAAATCCCAATAGAATTATACTTCTTTTATTTTATTTTAGAATAAGGTTTCTAAACCTTATTAAACTCCATCTATTTGATATTATTTGAATAAGGAGTTTCACTCCTATTAGAATAAGGTTTACAAGCCTATAAATAGGCATAGTCTACTCCTCTTGTAATTAAGTTTTTTCGACATAGTGAATTTTCTTCTCCTCTGCCCGTGGTTTTTTCCCGAAAGGGTTTCCACGTAAAATTTGTGTGTTCTTTATTTTTCTATTTCTATTTTTCTTTGCGATATATTGTCATTACCGACATTATATTTTTCTCAAATTGGTATCAGAGCTTCCGGGTTGTTCATCTCAATCACGGTAATGACATTTTTAACCTCCTAACTATATTTAACAACTAACCAACTATATATAACTAACATCACTACATTCCCCCTCAAGTTGTGCCCCCAATTTGGATAAAAGATATTTATGTTGTTGAATTCCCAGACCTTTTGATAATATGTCAACTAGTTGTTCCTTTGTTGTGACATGTTTGGGCTAAATGGAGATTTTCTCATATAAAGTGAAAATAAATTTCTATATGTTTAGTTCGCTCGTGAAAGATATGTTGGATAATTTGAGTTGAGATGATAGATCTGGAGACAATATAAAATTAAAACAGTAGACTTCGAGGCACGAGTGACGCTTTCCAAATAGAACAATTTGCCCCCACACAATTTCTAGAGGGTTAAGAAAAGGTCTTTTCGGGACATAATGAAGACTTTTTATTTCTTTTGGTTAGCAAAATCGAGGAATTCCCTAACTCTTACTCTAATTTCTAAATTTGGATTGATTGTAATAATAATGTTTTGAGCTCCATAGTCCCTCTATTTATACGCACTAAATGGAAACTATTAAAGAGCCACAACCATTCATATTGGACATACTTTTTAGAAGAAACATATCCCATGGAAATAAAATGTATCCATTGGACGAATGAATCATCACTTTTTAATCCAAATAAGTGCTCATGAATCACACCAAGTGATCCATTAATAATATTTAATGAATTTGAAATCTACAATTTCCAACAATCCCCCACTAGATTGCTAATTCCAGAAAATAAGTACACAACGATCATGCATAAAGAAGGGTGTCCACAGATTGAACCTTCCTTTAGTGCAAACTCTTAAAGTATCAACAAAGATAATGATGGCTAGTCACTTGAAGCATCACTCGTCAATACCGAAAAAATTACACACATAACCATAAAGTATTAGAGTAAGAATTTATTTGCTTTAGCACTGTTATGCTCATGTGGTCATCCCGTTTCATGAACATGTACGAGAGAAAACCATAAAGAAAACTCTCGTTGAAGTAACACCACTTCATGTCCATGTAGGTGGATTTCATGACAATAAATGTCCATCCATTAAGAGTAAAACTCATCCTCTTAAAACATAAACACTAAATCCTGATTCTTAGTGCACGTTGTCATTCGATAACTTGTTATTACCCTTTGAACCTCGAAACTAACTTTTGGCTAGAAGAAAGTAGGGTTTCCATTATCAATGACGCGATTAGAATGATTTTAATCCTATCTTAGTGGTGGTACTCTTAACCAAATCCCTCGACAAACCTTTTGTTAATGGATCCACTAAATTGCCCATTGACTTAACATAGGTAATAGTTATCACACCGTCCCTAACCAGTTGTTTCACATACTCATGTCTCAAACTTATATGTCTAGACTTTCCATTATACACCTTATTGTACGCTCGAGACATGGTGGATTCACTATTACAATGTACGAAAATAGCAAACCTACGTTGTGGCCATAACTTTAGATCTAGCAAGAGATCTCTTAGCCATTTCGCTTTATTGCCAATATCCGCCAACACTATAAATTCAGCCTCCATAATTGAATGTGAGATGCAAGTTTGTTTTTTGGAGGCCCAACTAATGACTCCACCTGTGATTGTAAAAATCCATCTCGATGTGGACTTATTGTCACTTAAACTTGTAATCCAACTTGCATCCGAGTAACCTTCTAGTATCACGAGATAATCACTATAGAATAATCCCAAATTTTTTGTTTTCTTAAGATAGTAAAAAATCCTACTAATTCCTTTCCAATGATTGATACTAGGAAAACTTGTAAATCTCGCCAATTTGCACACAATAAATGTTATATCGGGTTTAGTGCAATGTATTGCATACATTAGACTTCCCATTGCGCTGGCATACTCAAGTTGCACTATAGCCTTGCCATTATTCTCATTTAACTTGAAGTTCAAATTGAATGGAGTTTTCGAATCCTTAATATTCAAGTGTTTGAACTTCTCCAATAATTTCTCGATGTATTGAGATTGCTTTTGTACAAAGCCTCTTTCATGCTTTTGCACCTTTATACCTAGAATTGTATCTACCTCGTTGAGATCCTTCATCTTAAAATTCGAGGCTAGATACTCTTTGGTCTCACGAATGCCTTCCAAGTTCATCCCAAAAATCAACAAATCGTCTACATAGAGAAAAATAATTACACTGTACATATCGCTGAATTTAGTGTAAATACATTTATTCGCACCATTATGTAAAAAACCATATGACAAGATAATCGAGTCAAATTTCTCATGCCACTTTTAGGTGCTTGTTTTAAACCATATAATGACTTGATCAACTTACACACCTTATGTTTATTCCCAGGAAGCGCAAAGCCTTCTGGTTGCTCTATGTAGACTTCATCTTCGAGATTACCATTCAAAAAAGCTGTCTTAACATCCATTTGATATACATGTAACTTATGGATAGATGCAAGTGCCATGAGAATTCGAATGAAGGTCATTGTAGCCACCAGTGCATAGGTGTCAAAATAATCTAGGCATTCCTTTTACCTGAATCCTTTTGCCACCAATCTAACCTTAAAGGTTGGAGAACCCCTGATTGGATTATTCTTGTAAACACTCATTTACACCTGATAGACTTTGATCATTGAGGAAGATAAACTAGGATCCAAGTATTGTTGGACAATATTGAATCCATTTCATCATTGATCACCTCTTTCCAAAATTCTGCATCCTTAGAAGTCATGGCTTCACCATAGGATTATGGATCACCATCCACATTAAACATTATGAGGATCTTTCTAGTTATGGATTCTCCATTTCCCTCAATGAGGAATGCTAGATATTGCGAGAAAATGAAATCGATACCAAAGTCCTTTACTTTTCTCACTCCTTGACGTTTCCTCAACTTCGTATCATTATTGTCACAAAGACATCTCTTGGTTTGATCACTTGAGATCATTGGTTGATATTCTTTTCCGAATCTGGTGAATCATCGAAAACTTTATTTTTAATGAATACAACATCTCTTATTTCAGTTATCGTATTTGACACTAAGTCAAGAACATTATAAGCCTTAGAGTGTTGGGCATATCCAAATAATGCACCTTTGATGGCTTTTGGTCCTAACTTTTTTCTTCGTTGGTTGAGAACTCTATAGTAAGCCAAACACCCCTACACTTTGAAATAATCTAATTTTGGCATCTGACCCTTCTATAACTCATATGAAGATACTTAGAATTTTCTTGATGATATTCTGTTAAGATATAACATGCAGTCAATAATGCTTTACCCTATAGATTATATGGAAGTTTAACATTTAACAATATCAAGTTAACCATATCCATTAAAGTACGATTGTTTCTTTCTGCTAAACCATTTTGTTGCAGAGTATAAGGTGGGGAACACTCATGTACTACACCTTGTTCCTCACAAAATACATTAAAATCATTTGAAAAATATTCATCCCCTTTATCACTACGAAGCACTTTTATTTTCTTACTAAACAAATTCTTAACCTCATTTTAAAAATGTTTTAACATATCAAAAGCATCCCCTTTACTTCTCATGAGATACACATAAGTAAATATAGAGAAGTCATCTATAAAAGTGATAAAATATCATTTTCTATCTCTTGTTAGAGTTACATTTAATTCACAAACATCTGAATGAATTAAATCTAACACTTGTGAATTCCTTTCACATTTATTAGGAAACAGTTTCTTGGTAATTTTTGATTGAATATAAACATCACATTTATTTACAAACTCATCGTTACTTAGACTGATACAACCATTCTTTTGTATATATGGCAAAGTTTTAAAATTAAAATCTGCTAGACGTGCATGCCGCAAATGAAAAGATTCAACAATATGAGTAAAAGAATTGACTTTATTCATATCAATGCTCAACTTGAACATGCCTTCGTTACAATATTCTTTTCCCACATATATATCACCCTTAAGCAGGACTAACTTATCGGATTCCAAGATAACCTTGAACCCTTTATTACACAGAAGACTTGTGGACACTAAATTCTTTCTCGCATTGGAAACATGCAACAGATTGATCAAATTCAATTTCTTTCCAGATGTGAAGTTAAGTTCCATCGTCCCTTCATCGAGCACCTTAAAATTGATTAGTTGCCCATAAGCACTTCACGGTTTGCCATTAGTTCATAACTCTAGAATTTTTTCGGTCATTACACACATTGACAGTAGCTCCGGGGTTGAGCCACCAATTATAAGACATATCAGTCATGGCTATGTTGAGTTCGGTAATCATACCAATTTTCAAACTCTCGATCCCTTCTGTAACCATGGCCACTAAGTCCATGTCCTCCACCATACTAGCTTTGAAAGTTGTGACATCTTGCTTCTTTTTGAGAAGTTTACAATCCTTAATGTAGTGTCCTTTCTTATTGCAATTATAACAATTACAAGATTTTTTCTTCTTGTCTTGTATGTTCTTGGTTTTGAATGTGGCCTTTCACTTACTGTTTCGAGAGTTCTTGGACTTACTCACATAGTTCACTTTATAACTTTAGGGAAGATACACCCCATCACGCTTTTGATTTTCCTCTTCAATACATAAATGCCTAAGTATTTTCTCCACAGTGAAGTCCTCTTCCATAAGCAGAAGTTTATTTCGATAATTTTTCCAAGACAAGAGAACTTCAAGATGATAGCCCCGACTTGTAACAATTCTGAAATAAAAAATTTTAGGTCACGAAGCCTACTTACAAGGACTTGATCCATGTTTGGGATACTATCGAGCATTTTGAATTCGAAATACTTCATTATTAAAAATTTATCGGTAACTTGTTGCTCGGTGTTGTATTTCTCTTCAAGAGCTTTCCATATTTCCACCAACGATTGCATTCACATGTAGAGATCATACAATCAATTGAACAAGGTGTTAAGGATGGGTCCACAACATGTGAAATTGTCTTCCTCGTGCTTCTTCTTGAGTTTGTCCACTTTCGTAATTTCTTGAGGTTTGTATTAGGGGTAGGATCCTCTATGGATTGTAGGTTTGGGTCCAGAACTTACGCTACATTCAAGATGGTAAGAAGGAAAAACATCTTGTCCTTTTAGTGATTGAAGTTTGAGCATCAAATCGGTCAAGTTTCACAAACTCTTGGTTCATCACTTTGAATATGGTGGTAACCTGCATTGCCATCTCCTAAATTGTTCTATTTGATTGTTGGATAATTTGAGTGGAGACGATAGATCTAGAGATAATATGGAACTAAAATAGTAAACTTTGAGGCACGGGTGACACTTTCCAAAAAGAACAATTTTCCCTCACACAAAATTGTTAGAGGGTTAAGACAAAGGTCTTCCCGGGATATGGACCTTTTTTTATTTCCTTTAATTAGAAAAATTGAGGCATTCCCTAAATCTTACTCTAATTTTTGAAAGTGGATTGATTGTAATAATAATTTTTTGAGCACCATAGTCCCTCTACTTATATGCACTAAATGGACACTATTGAACAGCCACAACCCTTCGTATTAAACATACTTCTTACAAGAAACATGTCTTATGAAAATAAAATGTATTCATTGGATGAACAAATCGTCACTTTCTAATCCAAATAAGTGCTTATGAATCACACTAAGCGATCCATTAATAATATCTAATGAATTTGCAATCTACAATTTCCAACAAGATAGGATTTACAGTTATTTGAATTGTTACTTTACTATCACAACACAACATAGGTGATCCTTTGTGCCTGTCACATCCCGAGATCAGGTTCGGAAGTTTTGGCCATACGAAGTTAAGGTTCACCATCAAAACTTGGGCGAACTGGGGGTTCACCAAGGTTCAAGCGAGCTAGGTGTTCGCTAGGGAAGTTTTAGCAAAGGGGTTTGCTAGCAGCATTGCACTTCAAATGAAGTGGTAAGGGGTTCGCCAGTTCCACTGCGAGGCAAGTTCATTAATGTGTTTGGCAACTTGAGATCCACCAGTCTGTGTGATGAACTGTGTTCGCCAGGTAAGTTGCGAACTGGGTTCGCTAGTCAATGTGCAAACTGGGTTGGCCGATCAAAGTTACAATCAAACTCAAATTAGGAAAAAAGTGATTTACCGTATCTAGGAATACTTTATGTACAAGAAATAAATTTCTTAAGTTAGGTTTTCCAAAGATATCTAGGATTCTTAGGTCTATAAATATGACCCTTAATTCTGTGAATTCTTTACTGAATATTCTGCCATTAAAGTCCCTGTTCTAAGTTCTGTCCGTAGCAATTCGAGTAAGTCTGTGTCTTGCTTAAGTTGATCATCTCTAAAGTTGGGTTCGCTTGTGTGTGTGATGTCTGTATGTTCTATTAGTAATTTGTTTGTTTGTTAATAACCAGCTGGACCATCTTCTAGCAAGGACAAAGCCAAAGCCAAACTCTTTTAAGTTTCTCTATTTTTTGATGAGTGATCAAGTTCAGATATGAATATGCTAACTGTCATGTTTTTCAGTTTATTCTGATATGTTTTTAAGAAATATGTTCCGAAACAAGTTCAAAGGCAGGTTTTCTGAAAAGCTCTGTTCTAAGCTACGAAACTCTGTTAAAAAAGATTTTTAAAAGATGATTTTAAAGCACTATTTAATGCGAGCTTCTATGCAAGCTATTGATAATATGAATGTTTTGAAAGAATGGTTTTAAACTGTGTATTTGAAAGGCACTTAACATGAGAGTTTTTTTAAGCAAACAATTTGGCTTTGCTTTGTACAAGCTCTCTAATTAGCTTTGCCTTAGTATGAGCTTTCTATTCTGTGTGCTCCTTAATGAGCCTTGTGATTGGTATAACAATGGTGTGAATACTCACCCTGTTAAGTCTCACTTTGGTGGTCCTTTGAGAGCATGAGCCTTTGTAAGCCTCACTCTACGTGTTTATTGAGAGCATGGGCTTTTGTGAGATTTGTGATATGTCTCATTCTGTTTGCTCCTTACGAGCTAGGTTGAATATAACTTATTCAATGAGATATGTCTTTTGTTTGATGAACCAGTTGTGTAAACTAAATGCCGACTCTATTCTTAATTTTTGATATGTACGAGCCGATCTCACGGCTTTATTCTAAACTCAAATTCATTTGTTAAAAAGAAATATAGCCTTGCACGATTTTAATGCGAGTCCCTTTTAAAAGAAATTTTTCGAAGGAAAAGATTTGTAAACATTGCTTTTAAACTGTCTTCAAAAAAATTGTTTTCAGATGCAAACTGCTCTTGCATTCTCAACTGCGAACTTAGCACGCAAAACATTTTCAAATTAAAGTTTTCTACTGTTTTCAAATATTTTTTAAGGCATGATTTAATGGTTTCTGATTATTCACTAAGTTCTCCCTGAACTCACCCACTTTTCTCTTACCTCTCAGGTAAGTAGATTGCGAGTGGCATTGGAGAGGTTGATGATTTGGCGAGACACCTAATTGGTATCGACGAACCATATAGATGGGCTATGGGTTGTTATATGATTTTTTTTCTAAGAATAGTTATAACATTGATTTGGTTACCCGAAAAATTTGTTTAAGGATTAGTTTAGTATGTTTGATTTTAAATTAATTTTATTATTGCGAACCATGTCTTGAAATACACATGTTCTTTTTCACTATCAATAGAATGATGTTATTCATGTACGTTTATTTTGTTTACTATTTATGGTTATAAATTACTTGTGTACTCTTGTATGATACATTATTTGCATAAGATTCAAAATTATTGTACATGATCCGCTGAATCCTGTGAACTCATGTTGTTGTGTGAGCCTATATTAAACTGCGAACCTATGGTTGTGTGTTTATCTGTAGCCTTTTATGTTGGTAAAAGTTTGGGAGCTATGTTTGAATGTTTTGCTTGATGTTTTAGAGTAGTGCGAACCTATTGATATTTTTAAGTATTTAGAAGTATTGCTTCACACAATTATATACTCTGATGTTTTGTGCATGCGAACCCTTTTGGTTTGTGTAAGAGTGTTTTTTGCGGCCTTGTTAAAGATTAACACTATGTTCACGTGCTTTATATATATGTATAAGTTGTGTGTTGGAGGTTAGGTTGGGAGTTAATAGAGAGTCACTTCGGTGGCTAATGTGGCACGCCAAATTTGGGTCGGATCTTTCTGACCGAGTTTGGGGTGTGACAGTGCCCAACACCAAGTTCCTTAAGCAAGCCACTTAACTGCACTAGTACAACCATTATTGAAGCAATACTTCAATATTTTGTTTCTATCGAAGAGCATGACATAATGCTTCTTTTTTTACTTCCATGAAAGTAAGGGATCCCCAAGCTTAACATAAAACCCCGAGACAGATTGTCTTGACATGGGACATGATGCCCAATCAGAATCATAATACACCACCAGTTGTATATCATCTATTGCTGGAATAAACAACCCTTGACCAAGATTCTTTTTTATGTACCTAATCACCCAAAGAGCTACATCGTAATGTGACTTCTTTGGCCACTGCATAAATTGACTAAGATGTTGCACCATAAAGTTATTTATAGCCTTGTGTCTATTAAGTATAACAACCTCCCAATAAGTCTTTGATAAAGAGTAATGTCAACAAACTCATTATCATCAGAATTTGCTTTTATAAATTCATCATACTTGCATGATGTCAAATTCTAACTTTGTTCCAAAAGAGTGATTGTCGTCTTAGATCCCCCTAACCTTGCATCATGAATCAACTCTAGAGCATATTTTCATTGGTTCCATAGTATACCAGCCTCGAACTGTGCAACCTCAATACCAAGAAAATACTGAAGATATCCCAAATATATCATTTTAAAATTTTATGCAAAATATTTTTAAGTTCAACTACAAGGTCACTATCATTATTGATTATTAAAAGGTCATCTACATATATAAGCATGAGACTAATTTATCTCAATTTCTCTTAGTGAATAAAGAATAATCATGTTTCCTCTAAACATAATCATTGCAAAGAAAAGCTTCAGTAAGCTTGATATTCTAATTTTGAGAGGTTGCTTCAAACTATACAAGGATTTGAGCAATCGACACACTCATGTCTCCCGCTAATTGTGAAAACCCTAGGGAAGAGTCATATACACTTCCTTATGCAAGTCGCCCTGTAGAAAGGCATTGTAAACATCCATTTGAAATAAAGGACAACCTAACCAAACATCAAAAGCAAGAACGAGATGGGCAATAACCTATTTAGCAACAGGAGAAAATGTATCATAGAAATCAATACTCGGCTATTGAGTATACCCTTGACCAACGAGATGAATTTTAAATTGTTCGATAGTTCCATCCAACTTGTACTTGAACTTATAAACCCATTTACAAACATAGGGGTCTTACCTCGAGGTAAAGGCCTCCAAATCTTGAATCTCGTATTTCACAACATTAACCCAACTAGGGTCCCTAGCTGCTTCTTGATAAGTATTTGGTTCAACAATATCGGATAGAGAAGCAATAAAATATTAAGCATGTAAAGGTAAATGATAATTAGTGATACATTGATAAATGGGATATTAAACTTTAGCAAGTGAAAAAGATGAAGAAGATTGAGAAGAGAAAAAAAAGTCTGTCAACCATGATGGCGGTCGGTTGGACCAGGTAGAATGACATAAGGGTGAAATTGGATTAGACAAAATAAGAGTAGGAGAAGAGGGAGGAATGTTGCAAAAAAATAGGATGAAGAAGATGGGGTGAGAGAAGGTAATGAAGTAAAAGGATGAAACAAGTTAGCAGGTGGGTCAAAAGGTAAGCTAGAACCTAAGGAAAGAAGTTAACGTAAAAATTATAGGAAGAGGAAATGGGAAATAAATGTGGTGTAGTAGACTAACATTAAAAAGGAAAAATCGTCTTATGAAATTTAACATCACAATTAACAAAAAAATGATTGGTAGCAAGATTGAACAAAAGATAATCCTTTTGAACAATGGAGTAACCCATAAAAGTAAAAGGTATAGATTGAGGTTGAAATTTATCTAAAGAATGAAGGACTTTAGCATAGCAAAGGAAACCAAAGACCTGTAAGAGGGACAACTCAAGTGGTTTATTATATAAAATTTCAACGAGTCTTCCAACCTAAAACTGAGGTCCGTAAATGATAGATAATAAAAAAACTAGTGAGAATAAATTCATCCAAAAATTTAGTAGGAACAGTACATTGAAATTTAAGGACTCTAGCTATTTCCAACAAGTGACAATGTTTACCATTAGGTATACCATTTTGTTGGGGCATACAGACACGAATCTTGATGAAAAATACCCAAATAAGAAAACAAAGAATTATACTCGACAATAAAAAATTCAGTAACATTATCATTACGAAAAATTTTATAATAATGAAAAATTGAGTTTTACCAAGGTAATAAATTGCTTTAAAGCAAAAAATAGCATCACTTTTGAGTGTAAGAAGATACGTACAAGTTGCTCGAATATAATCATAAACCATCGTAAGAAAGTAAAGATCCCACTATGTGTGGAAAATTTATATGGCTTTCGCAAGTCAAGATTGACTAAGGAGAATGATGTTTCAACTCGAGAATGACTAAAGGGAAAAGGTAAACGTGTTTGTTTAACTAGTAGAAAAACATGAAAAATATGAATATAACCATTGTTCAAAGGATTATAATGAAAATGGTCCATTTTGTTCATTTTGGAAAAAGGAGGCATGACCAAAGAAATGATGCATCGATTGTGGACAAAAAATAAGAAACTAAAGAAGGTGTAGCCTTAGTTGAAGAAAAATGTGGTAAGAGTAGATAAAGACCATGCCGCACTCTACCAAACCTCTTCACCTATCAATTGCAAAGGTCTTGTAAAAGAGAAATATGAATATAAAAAGAAACAAAAAATGTAAGTCACGAGTCAATTTTTAGATGGAAATCAAATTAAATTAAAATAAGGGATATAAAAAACATTGGTAAGCTTGTGCGAATGTGAAAAGGCTCGAGTACCCATATGAGAAATAGAGATAGACTTATCAATAGGAAATAAAAAAGATGATGGACAAGATGCATGTAGAACTAAAGAATCCAAACAGTGGATATCCGATGTCATATAGTTGGTAGCACCAATATCCAAAATCCAACGAGAAGCAAAAGGCTGTGAAACTATATCTGTTGTAACAACCCGATTTTTAGTGGTGCCAAAAAGGGTAGTTTTGGAACCCCATATTCGTAAAATGGGTCCATAAATATTAAATATAGAAATTTATGAAGTTGGTATAAAAGTTTATTAAAGTTTGGACCATCAATTTTGTTTATTAATTGTTTAATTAATGTACAAGGACTAAATTATAAAACTGTTATCGTTATAGATTTTTAATTGGCAAAAGGCTTAAGGACTTAAATTGTAATTAACCAAATATCCAAAATAGTAATTAAACTATTTTGTAACATGGAATAGTGGCATATGATGACATTCCCTCTAACTTTGATTAATGGTTAATTAATTAAGTTTAAGATAATTAATAAAATTTAGTTAATCCCTAATTATACTATATAAACTAAATTAAACAAAGAAGGAAAGAAAACCCTTATTGAAGGTCAAACTTTCGATCCTCAATTGGTGAGTTCAATTAAGTCATTTTCTTGTAAGTTATATGTTTTGAGGTCATGGGAGCTTGTTTTAGCTAGCCTATGTACGAATTTGTGAAACTGTTAAATTTTTTTAAGTTTCCATTGCTGATTTCTTGAATAAATTGGTCTTAAATTGATAGTTTTTAAGCTTAGATGTGAAAAGGATTAGATTGTAAAGTTTAACTATTAGTTTTGCACAAAAGGAATAAAGGGAATAAATTTTAAAAAGCATGTGAAATATCTAGAATAATAGATAGTAGGGAGTCCCTAAGGGGTGTAATTGAGATCGATTTTAAAATCGAGGCTTAAAATTGAAAGATATTTTTATTTTGGTTTTATGGACTAAATTGAATAAAATACAAAAAATTAAGGGGCATTTAAAAAATGGAATTAAATAGGTTCATGAATATCATGGAGTGATATAAATATGTTTGATATTGATGCATTGTCTAAAATAATTGTTTAGATCAAGAATTGAATCTAATCGGTGATAACCGGAGAACAACAAAATTGTGGAAGTCTTTGAAGTTTCAACTTGTTGTTTTTGCCAGGTAAATTCATATGAAACTTACTAATTTATTTGATGTTATGCTGAATTGTGTTTATTTCATAAATATGTTTAGTTTAAGGTGAATTTGGCATATTTTCATCAATTGGATTGAATTTCAAAATATAGAAATATTGTTTATTACGAATAGGTACAAAGTACAAAAATGAAGATGTTTAACATTGAATTACATGTGCTTGAATATTTTATTGTAAATTGACGATCGGGTCGAGCGAGGGGAGTTACATTTAGTGGTATCAAACCTACGGTTTAGTCAATTCTAGGACTGAAATGTAAAGCATGTTGAGTCTAGAAATACATGCCACAATAACCTGTGATAGTGTGATGTCTTCTGATTCGAATTGACTTTTTTTCCATATAGCTAAACCATGTCAGCCGAATCAAATCGAGTTGTGTCTAATGAAGTTGAAAGTAATATTTGTGCTTTCAAACAGGGAGCTTCCCGAAGTTTTCCCATTCCACAACGGCTAGGGAGTGAGGCAAGAGATGCCTTCTTCCAAATGATGAACTAGTGGTTCACCCAATATATGGGAGCTACCCCTTCCGCTCCACAACCTCAAATGCACCTTCCTTCCCCGATTGTGCCTCCTGTGGTACCCTTTCATCCTCAAGTTTCTAATTCGGTACCCATTAACCATCCTCTGATATATAAAATTTGTAAATGTGGGGCAAAATAATTCAAAGGCAAGAAAAAGGATGAACCAAAAAAAGTTGAGTATTGGATAGAAAACACTAAGAGGGTTGTTGACAAGTTATTTTGTATTCCTGATGATTTTTTAGGATGTGTCGTATCATTGCTCAAAGAAGAAGCATACCAATGGTGGATGACTCTAACGTTTGTTGTTCTGAAAGATCGAGTAAACTGGGAGTTCTTCCAAATTGAATTAAAAAGAAGTATGTTAGCCGACTATATCTTGAAAATAAAAAGAGAGAGTTTATGAAACTGAAACTGAGAGATAGGTTAGTAGTTGAATATGAATGAGAATTCATTTGCCTCAGTAAATATGTCAGAGAGCTTGTATTTAGTGAAGCTGAAATGTGTACTCGTTTTGAGTGGAGATTGAACGAGGACATACAAATGTTAGTAGGAGGTGTGGAATTGGAAAAGTTTGTTATTCTATCGGAGAGGGCTCAGAAAATGGAGGAAATGCATAAGGAGAAAAAGTAGACCAAACCTAAGATATGAGATTCTAGTAAATGGTGTATGGCCATATCTTTCCCAACTCATCCATCTAAAAAGTCAAAATATTTGTAAAGTCGTTTCTCTACTCCATTAGGGATTTTTGAGAGAGATGGGCCGAGACCGAGTATTCTGCAACCTCAGACTACGTCGGTAGCTAGTGTCAAAAGTGTTCGTAATGCAAATAGACCAATTTGATGACATTGTGGAAGAAACATAATGGTGAATGTAGATTGAAAAATGGAGCTTGTTTTCTATGTTGTTCCAAACAACATTTAAGAAGAGATTGTTCGAATAGGCCAGATCAAAGCAAGGAACAAAGTGTAAAGCCAGTGTCGACTCTGTAGAGGATTAGAAGACCAGGAACTGGTAGCAGCGCTGGTGCTAATCGAGGTGGAACTAGAGATAAGTTATGAGATTCGAGGCTTGTGCACCTACTAGAGCTTATGCTATTCGAGCCAGAAAGGAAGGTACTGCTACTAACATTATTGCTGATACATTTTTCTCTATTTGATGCTTTTGTGCCTGCATTGATTGACTCTGGGTCAACATATTCATACATCTACACCTCATTAGTAGCTTAAAAAATATACTAGTAGAATTGATAGAATTTGATGTTTGGGTAACCAACCTGTTAGGTTAAAGTGTTCTTGTCAATAAAAGTTGTAATGACTGTCAACTGGAAATTTGAGGCCGTAAGTTTTTAGCTAATTTGATGTTATTACTTTTTGATGAATATGAAATATTTTTCAGAATGGATTGGTTGACTTTTCACGATGTAGTGGTCAACTGTAAACAAAAGTGAATATCATTGCGGTGTCAGGATGGTGAATTGATAAATGTGAAGGCTGACAGATCTGATTGCTCGACTAACATAATATCAATGATGTTAGCTCGACTAACATAATATCTATGATGTCAACTCAATAATTAATCAAAAAAGGGTTTGAGGCATATTTAGCCTATATTCTAGATACTAGAGTGACAGGATCTAAAATAGAGCAAGTTTCGATGGTTTGAGAATTCACATACATGTTTCCCAAAGAGTTGTTAGGTTTCTCGCCTGAGAGAGAAATTAATTTTGTTGTTGAAATAACACCAAAACTATTTCGATTTCTATTGCATCATACAGGCTGACTCTGATTAAATTAAAAAAATTGAAAGCTCAGTTGCAAGAACTGTTAGATCAGGGATTTATCCGACCAAGTGTGTCACCTTGCTCCAATATTATTTGTGAAAAAGAAAGATGGAACCCTAAGATTGTGTATCGACTACTGGTAGTTGAATAAAGTGACCATAAAGAACAAGTATCTAATGCCCTAAATCGATATTTTTTTATCAATTGATAGGAGAAACAATGTTTTCTAAAATTGACCTTTGGTAATCCATTTGGGGTTACTAATGCTGTAGCCGATTTTATGGATTTGATAAACAAAATATTTCAGCAGTATCTGGAAAAGTTTGTTTTTGTGTCAACATTTCAGAATTGTATTACAGACTTTTCGAGAAAAGCAATTATATGCAAAGTTCAACAAATGTGAATTTAGGTCACGAGAAGTGGGATTCCTAGGTTACATTATATTAGCTAAAGGCATTCAAGTGGATCCGAGTAATATCTCAACAATTGTTAACTAGAAACCTTCGAAGAATATCACTGAGATACAAAGTTTTATAGAATCGGTCTGATACTATCGACAGTTTGTTAAAGGTTTCTCGATAATAGCCCTCCTATTAACAAAATTGTTACAAAATAATATCAACTTTGTTTTGTCAGGAAAGTGCCAGCAAAGTTTCAAACAGTTGGAAGCAATGTTAACAGAAGCTCTAGTTTTAAGTTAGGCTGAATCTGGAAAAGAATTTTTTGTGTTCAGTGACATGTCACTCAACTGTTTGGGTTGTGTACTAATACAAGAGGGAAAATTAGTTGCTTATGCTTCTTAGAAACTTAAGCCACATGAGAAGAATTATCCTACACATGATCTCGAACTTTCAACAGTGGTTTTTACTCTAAAGATTTGGAGACACTATTTGTACGTGGAAAAATGCCACATTTTCATAGATCACAAAAGTCTAAAATACTTGCTGACACAGAAAGAATTGAAATTGAGACAACGCAGGTGGCTTGAATTGCTTAAAGACTATGATCTGATTATAGATTATCATCCTAAAAAAGCTACCATTGTAGCTGATGCCTTGAGTCAAAAGTCCCTATTTACTTTAAAGGTGATGAATACCCGTTTGGCTTTGGAACGAGATAGTTCTATTTTAGCTGAGTTGATAGTTAAACTTATTTTTCTTCAAAAGATTCAGGAGTTGCAAAAAGATGATTCCAAGTTGTAAGCAAAATAGAAACTTGTTGAAGATAATCAGAGCAAAGAGTTCAGTGTTGATGATAACGTAAATCTATATTTTTGAAAGTGTTTGTGTGTACCGAATAATTTAGAATTGAAATGAGACATTTTGCACGAAGCTCATAATAGTACTTACATGATACATTTGGGCATCAATAAGATGTATAATGAGTTGAAACTGTTTTATTGGTGGCCGAGAATGGAAAGATAGAGTACTGAATACAAGTGGAAACACAGAAATATACACACTTTTTCATGCCTTTTTTAACTCAAATTCATGTAGTTTCAGTAAAATTCTTATCGAAAAAATATATAATAATTATAAAATACTTAAGTTGCACTCAAATTATGGACATGTTTAATTTTAATTAATTTTATATAAAATTTTGATTATTTTTTATTATTTTTGACAGATTTGCACAAAGGGCAAAAAATGGCTCGACAGACACTGCTAAAAGCACAAAACCGAGAAGCAATTTTGAAGCATGAAGGCGAAATAATTTTTCAGCATAAGATGGTCAAAATTATGTGTATTAATTCATAATATAATTAATTTTAATTTTAATCCAATTTAATTTGGGTTAAATAAATTACTATTAATTAATTATGAAAAGGGGCCCAATTGAGCTGAACCGAGAAAATTGAACCAATCGAGCACTGGGCAAGCCAAAATCGTCCAACATGCTGACCCAATCAGCTTGCTTGGCTGGTTATTTGGCTTGAAAAATGGCTCTTGAAGACTCCTTCAAATTTCATTCAAACCCTAGTATTTCTGCCTTTCTAGATTTGCCCCAACCTTAAAATAGCAAGTTTGAAACCTTAAAACTTGCCACTAGTGTGGTCGGCCATGGGGGGACTCTATGGCTGCTGATTTTTGCTAATTTTGGAAGCCATCTCAACCTATAACAAACCCCTTGGCTAATCACTTCAAGCACATCTTAAACTCATTCATTTCTTTACTTCTTTTTCATTTTTTTCTCTTCATTCCCTTCCATTGTTATTCATTTTCATCCCCTATTCCTATGCCGATTTCACCTCTTGAAAAAGAGTCCTTCAACCACCATTTGGAGTAGCATTCAAGTGTTCGTGGAAGCCTCGATTTAACAAGAACAAGCAGAGAAGGAGGAGCGGAGCAAACTAGTCAAGCCTCGGAGAAACACCAAATTTGATTCTTGTTCCTTATCTTTTTAATTTAATTGTTGTTGTTATGAACATGTTTATGAATATTTGTGATGTTGATATGTTTAATTTAGTTCATATAGCTTAAATTTAATTCGGGTTAGGTTGATTGCATTTCGTCTACTTGAGTTATTAAAATCGTGTTTGTGTTGTTACAGGCCTCGTTAAGATGTTTGATTAAGTAAAACCATGACTAAGTTATTCTTGCATTACAATTGTAAGGTAACTAATGAATTAATTATTTAATTGGATTTAAATTGTAATTATTGACACGATACTTAATTAGTGCATGTTTAATCATCTAAGGTAGCTGAGGGTTAAGTTAGCAACGGTATCTAACGATACATTAGCCTTGCATAACTTGCAAGATTATTGTGATTAAACTGTTTGAAGGTAGAAATACATTGTTACCTCACGTAATCCTTTATGTGCTTATGAGATTGAATTAATTGTTTGAATTGACATACAGATATGTACAAGAGATTATTTTAATTTCATAGGTATGTATGTGTATTAAAATATTTTCTTATTAAAATTTGTTTATTCAGTTGAATTGACATAGAGATATAGTCAAGAGATAAATGGATTTTGGTATGTAAGTATGTTCATAAGTTAGAAATTACCGAGTTACCGTGAATTTATTCGTAACAACATAAACATGAGTTTAATAATTCTAAGTTAAGAAATGTAATTAATCTAGCACAATTATGTCATTTTGAGTAAAATCATCTTTTGAAATCATGCATTGGAACTTTTATTTTAATTTTATTTATTTTACTTAGTTAAAATATTTTTCTTCACCAAAGTGTTTTTAAAATTGCATTCATAAATATTTTTTTTCACAGTCCTTGTGGGTACGATAACTCTACATTTACTTGTCACTTTATTACTTGTTGCGATTGTGTACACTTGCACATTCCTGTCGTTTCAAGTTTTTGGTGCCGTTGTCGGGGGACAACTTTAAAAATTCATTATTTGTGAATTTGTTAATTTTTCATTTTGGTTTATTTCTCTATTCAATTTTAACTTAATTAATTTTTCTGTGTTTTTTTCAAGTGTTTATGAGTATTGATCGAATTATCGATTTACTCCATGTAGACCCTGAGATTGAAAGAGCTTTTCGACAGCGGAGAAGACAAGCAAGTCAAAGAAGGACCGAAGAGATGAACTTCAAAAATCTGAATCAAGGAAATAGAGCAAACACTGCCCAAAATCCTATCCTTATTGCTGATGATAGGGATAGAGCTTTAAAACAGTATGTTGTGCCAGTGTTTCATGATCATAATTCGGGTATTAGGGGACCCAAAATTGAGGCACAACAGTTCGAGCTGAAGCCATTCATGTTCCAGATGCTTCAGATAGTGGGCTAATTCAGTGGAATGCCTACCGAAGATCCTTAACTTCACTTAAGACTATTCATGGAGGTGAGCGATTATTTTAAGTTAGCTTGAGTACCCGAAGATATGCTACGATTAAAATTGTTCCCATATTCGTTGAGGGACAGATCTCGAGGCCGGTTGTACTCATTGCCCCCGAATTCAATTTCCATATGGCAAGAGTTAATAGAAAGATTCCTCATGAAGTATTTTCTACCTAGCAAGAATGCTAAGTTGAGGAATGAGATCACTGCTTTCTAACAAATGGATGATGAGTCCTTGTATGAGGCATGAGAAAGGTACAAAGAATTATTACTAAAATGCCCTCATCACAGAATCCCATATTGCATCCAACTTGAGACGTTTTATAACGGTCTCAATGCCCACACGAGGATTGTAGTGGATGCTTTTGCTAATGGTGCTCTCCTTTCTGAGTCTTATAATGAGGTTTATGGAATCATTGAGAGGATTGCCAGCAAAAATTATCAATATCCAACCAATCGAGTAACGTCAGGAAGACGAGTTGCTGGAATACATGAAGTAGATGCTCTTACTTCACTCACATCTCAAGTATCCTTAATATCCTTAATGCTTAAAAATTTTACCACTAATGGGTTTAATAGTTTTGCAGCACAACCACCGCACCAATTTGAAAATGTAGCCTGTGTCTATTGTGGGGAAAGACATATGTTTGAAGAATATCCATCGAACTCAGAATCCATTTATTACATGGGTAACTAGAACCAAAACCGAGGAAGGCAGGGAATACAATCCAATTCCTACAACCCATCGTGGCGAAACCACCCTAATTTCTCCTAGAGTAACTAAGGGGTTGGACCCAGTAACACATATGCCCAACCTAGACCGACCCAGCCACCTATTTTTACCCAATAAGTTCAGAAACAACCTCAAGCTGAACCATCCAATGGCTTAGAAAACTTGTTGAAGGTATACATAGCCAAGAATGATGCCTTAATCAAAATCCAGGCAGCTACATTGAAAAACTTGGAAAACCAAATCAGCCAGCTTGCAACTGAACTCAGAAACTGACTACAAGGTGCTTTACCTAGTGATACGGAGAATCTGAGGAATTCTGGGAAGGAACATTGTAAAGCGTTGAAATTGAGAAGCGAAAAGACATTAGAGCCCAACACACTCGAAGTTTAAAAGGAGCCAACTGATGCTCAAGACTCAGGGGAAGTTCCATCGAGTGTTGAAATTCCAGTTACACTAGAACCAGAATATGCCAAATCTGATAAGGTAACTTCTTAACCACTTAATTTTGATAAACTAACAAATTCATTAGATGCAGAATTGCCACAGAAGACGAATAAACCAGTTCCAGTAAAGAAGCCTCCACTACCCTACCCTCAGAGACTTCAGAAGTAGAAGAACGAAGTTCAATTCTAGAAGTTTCTAGACATACTCAAGAAACTTCATATCAACATTCCATTGGTTGAAGCACTTGAATAAATGTCGAACTAGGTCAAATTCATGAAGGATATCCTGTCAAAATAATGAAGACTTGGAGAATTTAACACGGTAGCCTTGACAAAGGAATGCAATGCATATCTTTAAGACAAAGTACCTCCAAAGTTGAAGGATCCTAGATGTTTTACCATACCTTGCAACATTGGAGCAACATATTGTGGTAAGACACTATGTGTTTTGGGCGCGAGTATCAACTTGATGCCCATGTCAATATTTAGGAAGTTGGGGATAGGTGAAGTTAGACCTACTACGGTTACACTTCAATTAGCAGATCGGTCCTTAGCACGCCTAGAAGGAAAAATTGAGGACGTGTAGAAAAAATTATTTTTCTTACTGAATTTGTTATTCTAGACTTTGAAGCAGACAAAGAAGTGCCAATCATACTAGGAAGGCCTTTCCTAGCAACTAGAAGGACCCTTATTGATTTGCAGAAGGGCAAGCTTACCATGCGTGTCCAAGACAATCAGGTAACATTTAATGTTTCTAGGTCCATGAAAATTTCCTAACACAATTGATGATTGTTCTACAGTGTTCGATTTAGAAGAATTAATCATGGAAATTTAACTCAACTATGTTGAGGACCCATTGGAACAAATTTTGACATCAGAACCTCCAAGTGATGAAGAGGAATATGAATACTTAGCTTTGCTAGAAGCTAATCAAAGGGGATTTAATCTGTAATCCCTCTTTGAATCTTTGGAGTCAGAGAATTGAAATTATGCCCAACCAAAAGCGTCAATTGAGGAGCAACCTAAATTAGAACTGAAGGTACTTTCCTCACATTTAAAATATGTTTATTTAGGTAATGCTTCTACTTTGCCTGTGATTGTTTTAGTGGAATTAACCGTTGAGCAAGAAGGCTATCGGATGGACCATAGTCAATATTCACAGTATTAGTCCATCTGTATGCATGCACAAGATCATCGTGGAAGATGGCGAAAAAGGGATGATTGATGGACAACGAAGACTGAACCCCATCACGGAGGACGTGGTAAAGAAAGAAATCATCAAGTTATTAGATGAGGGTATAATTTACCCCATCTCAGATAATTCGTGGGTAAGTCTGGTCCAGTGCATGCTAAAGAAAGAAGGTCTTATAGTCATTGAAAATGATAATAACCATTTGATACTGACTAGAACGGTTATGGGATAGAGAATTTGCATCGATTACCAAAAGCTAAACAAGGCGACTAGGAAATATCACTTTCCTTTGCCATTTTTGGACCAGATGCTGGATAGACTCACAGGGTGAGACTATTACTGTTTTCTCGATGGATACTCGGGGTATAATCAGATTACAGTAGCACCGAAAGATCAAGACAAGACAACATTCACCTACCCATATGTATTCAGAGATACATATGATGATTGCCTAGCCAATCTAGCCAAGGTACTAAAGCGATGCAAAGAAACAAACCTCATACTCAAATGGGAAAAGTGCCATTTCATGGTACAAAAAGGTATTGTTTTAGGGCATTGGATAATGAGACATGAAATTGAGGTAGGTAAAGCAAAAGTAGACTTTATTGAAAAACTCCCACCTCCAACATCTGTAAAGAGTGTTGGGGCTTTTTGGGCCATGCCGGTTTCTATCGAAGATTTATCAAGGACTTCTCCAACATTATTTAACCCTTATACAAATTATTGGAGAATGACACGCCATTCAAATTTGATGAAGAGTGCTTAAGAGCTTCCAAGGATTTGAAGAGTCGATTAGTTTAGGCACCCATAATTGTCACACTAGACTGGGGTTTTCCATTTGAATTGATGTGTGACGCAAGTGACTTCGCGATAGGAGCTGTCATGGGCCAGCGAAGGAATAAGGCTTTTCATCCCATCTACTATACAAGCCGGACTCTTACAGGTGCTCAACTGAATTATACGGTAACAGAGAAAGTGTTACTTGCTATTGTGTTTGCTTTTGACAAGTTTCGATCTTATCTTGTAGGTACCAAAGTGATTATCTATACGAACCATTCAGCAATTAAGTATTTACTTTCCAGGAAAGATGCTAAGCCAAGACTGATTTGATGGGTTTTTCTATTTCAAGAATTTGATCTAGAAATTCAAGATTGAAAGGGAGTAGAAAACCAAGTAGCAGACCACTTGTCCAGATTAGAGCCGCAAGAAGGGAATTCTCCACTTATACCCATTCAAGAGACATTTCTAGATGAACACATACTAAATGTAAATCATGTCCATAATACCCCTTGGTTTGCTGATATTGCTAACTTTTTAGCTTGTGGTTTGATGCCGATTGATAAGACGTATCATCAAAAGAAAAGGTTTCTTCACGATGTGAAGTACTATTTCTTGGAAGAACCATACTTCTTTAAAAAGTTTACAAATCAAATGATTAGGAGATACGTGGCAGAAGATGAAGTGCATAAGATTCTATATCATTGTCACTCAATTCCGAGTGGGGACACTTTAGAGGTACACGTACTGCGGCCAAAGTATTGAAAGTTATATTCTTTCGGCCAACACTATTCAAAGACACATATGCTTCCATAAAGAGTTGTGATCGAAGTCAAAGGGTTGGAAACGTCACCAAAAGAAATGAGATGCCCCAAACAAACATCATTGAGGTAGAATTATTCGAGGTTTGGGGTATTGAATTTCTCAGTCCTTTCCCTCCATCTTTTGGTCACAAGTACATATTGATAGCAGTAGACTACGTGTCTAAGTTGGTTGAGGCCGAGGTATATCCAACAAATGATGATAAGGTTGTGATGAAGTTTTTGCAGAAGCATGTGTTCACAAGGTTTGGAACCCTTAGAGCTATCATTAGTGATGAAGGGTCTCATTTTGTGAACAGATGGTTGAAATGGTTACTCGACAAACATGGAGTGAAGCATAAGGTTTCCACAGCTTACCATCCGCAGACGAATGGGCAAGCTGAACTAGCAAACAAAGAGATCAAAGGCATACTCGAGAAGGTAGTTTGGCCGAACCGATGAGATTGGTCCAAAAGACTGGATGATGCTTTATGGGCCTATAGGACAACATACAAGGCACCTTTAGGGATGTCACCCTATAGGTTGGTCTTTGGGAAAGCCTGTCATCTGCCCTTGGAGTTAGAGCACAAAGCTTACTGGGATCTCCAACAACTCAACTCGGATTTTAAGCTTGCTAAAGAGAAACGAATGCTCCAACTCAACAAGTTAGAAGAATTCCGAATGTTCTCATACGAGAATGCCAAATTACTCAAGGAAAGACTTAAGAGATGGCATGACAAGCACATTCGAGTTCGAGAATTTGAAGTAGGTCAGCAAGTCTTGTTATTCAATTCTAGATTAAGGTTCTTTCTAGGTAAGTCAAAATCACGTTGGTCCAGTCCATTTACGATTCACCGATTTTATCCATACGGAGTTGTCAAACTTCAAAGTAAGGTAGGTAATTTTCGAGTCAATGCTCAGTGCTTAAAACATTACTGGGGGATAAAATTGAACGGGATCAAATTTCGTTCGTTTTATCAAATATTTAATTCTTCTTGTTTTTGTTTTTTAATAAATGATTTAGGGTATATTTTTGGGATTAGTATGTTCAAATAAATTCTGTCTAGGAGATTAGAACTTAAGCGGGACCGATTGTGACCCCTCCAATCTTTCCTAGGAATTGATTTTAACATAATCTTTTGAGAAATTTCCCTAAATGGCAAAATAAATTTTTAGTTTTAAAATAAAAGGGTCAATTTTGATCTACGTTTTAAATTGCAACTCAATTTTGAATTTTCCTTAAGTCCAGGTACTTAATTAAATTATTTTCAAAATTTGGTTTCTCTTTTTGTAAGTATTAAAAATTAGATGTCTCTTTTTGTAAATATTTTCAAAAGGCATCTAGAATAAATGTTTTTAATTTAATAAATAAGATGATAATTATTAATATATAATTATGTCCATTATAATATATATTAATTATTATCAACTTTGCATAGAATTAGGATTAGTTTAAATTTGATCATATTTTATTTAATAAGTTTTATTTTAATAAACTAATAACAAATAATAATTTAATATACATTATATTAATTATTAATTTTTGTTAACTTTATGTAGAATTAGAACTTAGAATATTTTAATTATTAATTTGTTCTAAGAATTCTAATTAAACTCCTACTCCTTTCATTATAAATTTCACCCACCTTTTCCATTTTTTCACTCATCCCTCAATTAAATCCTAGCATCCACAACTCACCAAGCTCCAAATCACCTAGTGCCAAAATCTCTAGCCGCAACACCGCCTAGCTTCACTCGGCACCCTCACCCATTCGGCCAGCAGCCCCACGCATGTACCCAGCAACCCCACGCACAACGTGTGCGCCACCAGCCGCTCTGTGCCGTTGCACCTGCCACTCGTCCGGCTCTAGTAGCTCGCCAGGCCTGCTCGACTCACTTGCTTACTGACCACTACCCTACATCCGAGCGGCACACACATGCCCTGCTACTCCTTAGCATGCTGTTGCCGCCTTGCTACTCACACCACACTATCAAGACACCCTACAACCATCCCTAAACCAACCTCTTTTGCTTTTGCTTTAGATTTATTTTCTTTGAGTTCTTAACTTTTATAAAAAGGTGGTAAGACAAATTTTTCTCCTAAAATTTCAATTTTATTTAATTATTTAAAATTTCAAATTATTGAATTATTAATATTTTATACTAATTAAATTTTTGAGAAAATATTTTTTCTATCTTATGATTAGGTTAATCATGCCTCGTAAAAGAACTCGTGCCTCTACCCAAATTGACGAATCACAAAACAAATTCCACTATGAAGAAGCTAAAGCGAGATACGAAAACATTTTCAAGAATCAATAGATGCACCCAGAAAAAGGCTTTACGCTGAAAAAAACAACTATATTGATTTCATGGCATGCATTCGACAAGTTGCTGAAGCTCTCAATTGGGAGTTGTTTTGTGAGAAAAGACCTAGTGTGGATGAGGAGTTAGTCCGTGAATTTTATGCGAATTTAATTTTAAGCGATTTGATGGAAGTTTCTGTTCGCGAAATCAAGATACCAATAACCTGAAATGCTATTAATGAATTCTTTGAATTACCTAATTTCAAAAACAACGAATATTATTCCTTGATGAGCAATATGGAGTCTAAAAATCTGCAACAAATTCTCGAGGAACTTACAGTTCCAGGTTCTAAGTGGACAGTGTCAAAGTAAGGAATTCACACTTGTCGCAAAGAATATTTGACACCACTAGCGAAGGTATGGTTATATTTCATTCGATTCAGCCTTATGCCTATTTCACATGGGACTACAATTTCATTAGAGCGAATGGTCTTATTATACTCGATTTTAACTGGAAAGACCACTGATGTGGGAAAAATCATCCTGAGAGAAATACAAAATTGTGCCTCTAGACGTTCTGGCCCAGCTTACTTCCCCTTACGATAACAATTTTGTGCTTGAAAGCTAAAATTCTTGCAAACGTAAAGAAAACAAGTTATAGCCAGGGCACAATCACAGATTGGGACCTCTACGGGATAGCCAGAGACTCAGTTCTACAGCAACGAGTTGAAGAAAGCGAGGATCCCGAATAAGAAGAAGAAGATCCCACAGAGATCAAACCGATGCAATCAGCTGAAATCCCTGATAAGGCAGAACCAATGGAACCAGTAGCCGAACCTGATGTCACAACTTCAATGTTTAGAACTCAATCGTCTTGCCTAGATCTTCGAGATGAGCTGTCAAAGTTGATGGACATAATGCAGCATATGCAGTGGCAGCAACAAACTTACTAGAGATATTCAAAAATACGGGATGACTCAATGAGAAGCGCTCTTACGAAAATATACAATAACCCGTTTATTTTTGTTCCTGATTTTCCATATTTCATATTTGAACCATGGAGTCCACTATCGAAGAAGAAGCAAAGACGACGGAGCAAAAGATGAGTCAAATTCGGAAGGATCTGCAAATAAATAAAAGGGGGAGATCTTGACTTTATTTTATTTCTATTCTTAGGTTATTTAATGTTTTAGGATTAGGTTCAATTGGGATTTTTATTTTTCGCATAATAAAACAAGAGGTGGAAATCATAAATAAAAATGAGCAAGTTGCAAAATACAAAGTGTGTCAATAGATATATACATGTCTAAGATTGGATCTAGAGAGAGCTTGGTACTTTGAAATTTTTCTTCTCAGAATAAATTTTTCTTTTAATTATGATTAGTATATATTTTGTTCAAAAATTTGAAATTTTGTTAAGTATGCTAAACTTCAGTATAAATAAAGTTCGATTATTTCAATAATTACTATGTTAGCTTAATAATGACATGAATGTATTTTTAATAAAAATATTTTAGCTCCTTAGGAAAGTTAGGCATGCATGAAAGTTTAAGTCTCTACAATTGGCTTAGTAGTTTCTTGAGGCGAAATCCTAGGAAGCATGGAATGTTCAAAATGATTTAGGCAACTTGTTTTTGGACCGTTTGAGCTTTTCAAGCCAACCATGATGAATTTTTATCCCTTGAAACCCAACTTTGAGACTATATGGCCTAATTTTATTTGAACCCTTGCAATGTTTAGCCATCACTTCTCTCTTAATTATCTTTAAATTATCCGAAACACTAGACTCAGTACTATTTAGAATATTCTTTGAAAATAAGTTTGGAGGAGTTGAAAAGAAGTATCAAATGCTAAAAAAAATTGTAGTGCATATAGTAAAATGATCATGTTAAAAAAAAGAGAGCATATGTACTTGAAAGAAAATAGATGAACAAAAGAGCATGTGAAAGCAAAGTAAGTTGGTGTGTTGAAGGTAATTATTTCGAAGGTCCGATTGAAGCTGAGTCTAGGGTTTTTAGCCTAAATTTATCTATCTTTTACCTACCCCTAGCCTAGCCATGTTACAACCTTTTTAAAGACCTATTGATTCAAGTTTCTATGCTACCTACATTAGTGGAGAGAAGTTGCTATGATCAACATATGAAGGCATAAGTTAAACTTAATGGTTGCAACTTAATCTTGAATAAGAGAATAAAATCAAATTCGCAGGGATTTAACATGTCCAACTATAAATAGATGCCTCTTCCTTCATTGTAAAGAGGGGAAGTGGGGAGTAATAATAATTCTTAAGAGTATTTACTCAAATTTCTCTCTCTCTTGCGTTCTTATTTTGTTAATTTGTGTATAATTTATTTATTGATTTGTATATTATTGATTTCAAATCTCTTTTTCCCTTATTATTCATTTTCAAATTCATTATTTTCAAATTTGTTTACATTTTATTTTGCCTTATATTTTTTTTTGATACTCTTTGTTTTAAATTCATTGGTCTTTGATTATTGATGCTATTTAATCCTCTATTTGTTATTTTAGTTTTTCTTATTATTAAATTAATTATTTTAATATTATTAATACTATTATGTGCCATCATTAATCTTGTATTATTATTATTATTATTATTATTATTATTATTATTATAATATTCATGCGCATGCATCGTTTTTATGTAATATATATATTGTTTTATATATAGTATACGTATGCTTATATATATTTTATACATATGTTTTTGTTTTTATTTTACTTCCTAACTTTTATATACATATATATACTTTTATATTTAGTTTCAATTTTTTTTTACTTTTGTATATATGTACATGTATGTATTTATATATTTTTTCTAATGAATATTTATATATATATATATACGCACATGTCTATGTTTTTTAATTGCTTAAATACAAACTTAAATTTTCAACACATATGTTATAATGTATATATGTATATTTATATATTTTTCTTTATTTTCATAAATGCATTATATATATTTTGTTATAAATTCTATAGTCCAAAATTTTATATGTAAACCCATGTGTATGTATTTTATTCTTTATAATTTCATGTATATATTTTGTACCTTTTTTTTCTCTTTATATTTTTTTGTTTATTTCTTTCATTTGCTTATTGATTTGTGTTTTCATTTATATTGTTCATTTGATACTTTACATGTCGTTGTTTTTTATGTACATTAATTTGGTTTATTTCTATGCCATTGTTGTATTTATTATTGTATTTTACACTTAATGTAGCATTACATCATTTTTTTACTCGATTTTAAAATTTTCAAAATTGAGATAATACTCGTATTTAGGATTTTCAAGGAAATTGAGCCCTAACGTATTGGGTTCCAATTTTCTTCGTTAAATCTAACAATCGAGAATTGCTCATTAATCAAAAACTAAAATGAAAAGCTTGTTGTCGGGAATTTAATATGTTGTATCCTAACGTATTGGATGTGACGTATTGATTTCTCGAGACAAAGATTTTTTTTTTAAAAAATAATAACAAAGGAAATATTTCAAGTTTAGGATTTTGAGAAATTGTGCCCTAACGTATTGGGCCGCGATTTCTTTATAAATCTTAAACAAATGAATATTCTTTTAAATTTTATTACACGAGTATTTTGGACTAATTCATTTTTGAGGAATTAGAATGTCGTGCCCTAACGCATTGGGTGTGACATTTTCTTTCTTCGAAATGATAAGAGTCTTAATAAGTAACGTTTTTTAAGTTTTTATTAAGGATCATATTTTTAAATTTTCGACATTAAAGTACTAATTAATTAACTAGGTACCAATTTTGGGCATTACGAGGGTGCTAATCCTTCCTCGTACGTAACCGACTCCTGGATCCATTTTTCTAAAACTCGTAGGCCAAAGCTATTTTTTAGGTGATCCAATCACACCTCAATAAAATATTGGTGGCGACTCCCAATTTTTGTTTTTTTAAAGTAGACAACTAATTTTTGTTTTTTTCCAAAATAAAAGTTAGTTTCGACAGCTTGGCGACTCCGCTGGGGACAAACACGAGAGTCGAGCCAAAAATTGATTAATTTCTGTCTTATGTCGAAAATTTTTTTGAGATCCTTTTGTATTCATTATTTTCTTGCTTAATTGATCTTTGCATTATACATTGCATGAGTTGAATGATTTTACCCCTCTAAGTGGGAGTGAGAAACTAGTCCTTCGTGATGTTTTCACCTCTGTGCAGGATAGTGGATCTCTTTCGGGATACATTCGTACCTATGTCTTCGTGAGATTTTCATCTCCGTGTAGCCATAGGGAAATGTATCCCCTTGAACTGAACTCGGTCTGTATGAGCCTATAATGGGTGAGGATTGAGAAATCTGCTGGTTCAGGTACCCTTACTTCAGAACCGAACCGCATATAGAAGACCTTAGGAGCTCACCCTAGGTAGAGCCACTTCAAACCCCTAGTGGTCACCCGAATAGACGTTTTATTTATTCTTGCTTGTTTTTGCTTTGTACTAACCTGTTTCTTTTTTGTTATGATTGCATTACATTTTCATCATAAAAAAGAGGTGTTGATTCACGTTCAGTTGTGAAATAGAGAGCTTGTCATAAGAAAATGAGTTTCTTGATAAAATGGAAGACAATATGGTTGTCCGAATATGGTCCAAGAAAACATGGTAAGAGAAGGATGACAGTTTAATGGAGGATTACACGACTATGGCTCCGTTGCCCAAGGATTCAAGATAACAAAGATTATTCGAGAGCCGCTAAACTTTCTTAAAGAGAAGCCAACGAGCATCACGAGGATGAGTGAGCAATGATTTACAGCCCGGATCAAGCAAAGAGGAGATGGAAGAGACGTACCTTTTGAAGAGTTCGTGAGATTTATCTTAACGCTCGAATGAAGAAAAGGATCGAATGTCTTCGCCTATGAGGGCAAGGCCATATAAATATCCATTTTATGCAAAGAGATTTATTTTCTAGAAAAGTTTTCTAAATGAAATTGAATCAAAATTGACGCCTTTTTGCATTCATTTCATGCATTGCATTTGCTTCATATATATTAAAAAAATACTAAAAAATTCTATTTAATTTAAGTCATTCCTCAGATAATCTAGAAACCAACCAACCTACCAAACACCGCTACGGTACTCGATCGAAAACTAAAGACATGGAACAAAGGCTAGAACAGTTCCAAAAGGAAATGCAAGATCAGCTTCAACAACAAATGAATGAGCAGCTTGAGAAGATTCAACAAAAAAGATGGACAAAATGATGGAATCTCAAGGGAATATGATGGTTAAGTTGACTCAGTTGCTGACTGGAGGAATTGATAAAGGAAAAAGCTCTGTGCTTAATGTTGAAGAAGGAGACAGTGAGGGACCTGTTTATCCCCTAGGCTTTACCCCTCAGCATGTTGAGGTATATCCACGCAAATCTTCTGTCACCATCAAGCCCCAGCAGTTTCAGGCCGGTGCTGTAACACCAATGAATTTTCAAGCAGGATCAGGCTCTAACCCCGGAGACAACATTGTTAATCCTGCTATCCCTAACTTCGACGAAACAGCTAAAAAAGAGAAAATGAAGGATGAATTGCCAAAACAGCTAGAAAAAAAGTACAAATGGCTGGAAGAGAAATTTAAAGCGATGGAATGTGTTGAGAGCTACTATGGGATTGATGCTAAAGAATTAAGCTTGGTTCCAGATTTAGTACTCCCTTACAAGTTCAAAGTGCCAGAGTTTGAGAAGTATAATGGAACTAGTAGTCCTGAAGCCCATATTACTACGTTTTGTAGGCGGATGACTGGGTATGTTAGTAATGACCAGTTGCTGATACATTGTTTCCAGGATAGCCTCACAGGGGCAGCGTCCAAGTAATACAGTCGACTAAGTCATGCCAAGATTAATTCATAGAAAGATTTAACATAGGCATTCATAAAGCAGTACAATCATGTAACTGACATGGTACCAGATAGAATCACTCTACAAAACATGGAAAAGAATCCCGGTGAAAGTTTTAGGCAATACGCATAGAGGTGTAGGGAGGTCGCCGTCCAAGTTCAGCCACCGCTCTTGGAAAGGGAAATGACAATGCTATTCATAAATACATTGAAAGCTTCGTTCATCACACATATGTTAGGGAGTGCCACAAAAAGATTTTCTGACATAATCATGAATGATGAAATGATTGAAAGCGCCATAAGGAGAAGAAAGATTGATGCTGGAAGGCAAGCCTCAAAAGAAAAAGAAAATGAGGTGAACAACGTGAATACATACAGCAAATCGATTGCTAATCAGTAGGGTTCATCAAGACAAGAATCATGTGTGAAGCAAGATACTGAAAAACTCCAGTTCACGCCAATTCCAATGTCGTACAAGGAGTTGTATCAAAGTTTATTCGATGCGCATGTTATTTCTCCTTTATATGTGAAGCCTCCATAGCCTCCGTATCCCAAATGGTACGACGCAAGTGCACAATGCGATTATCATGCTGGAATTACGGGACACTCAATAGAGTTTTTTTAAAAAACTCTAACGATTATCATGCGGTTTTGCCTATTGAAGATAAAATTCTTTCTAAGTTTTTGAATCCAATTCTGATTGAAAAGAAATGTTCAAAGTTGTCCATCATGGTCAAATGTGTCAAAAGCAAATGATGCAAGTTCACAAAAAAGGTCCGTCCTAAAGAATTCCTTGAGAGAGACCTGGTATTGAAGAAGATCCTTCCCATACAAAAAGAACTTCATCCCAAGCTGGGAAGGACCTTATGTGAAAGACCTTATTTGGAAAAGCGTCAATTTTGATCAAAAAGAATAACAATGACATGCATAATCCTATGATTTCAGATTCAATCAAAAATATTTCAAAATATAAAAAAAAGCAAAAAAAAAGGAAGAAAAGAAGAAAGAAAATGGAGAGCCAAGGTGAAAACCCGCAAAGGGCGCCTTGAGACCAAAGGGGATTTAAGTTGAAAACTCAAAAAGGGCGGCTCAAATATTGATCAGAATGGGGCATGAGGTGATCAGAGTAGTTCAAATTTTGATCAGATTGGGGCATATGATGATCTTGAATCAACAGGAAAGGGTAGACAACATCTTGGGACATCGACAGAGTACTGTAGATCTCCTAAACACATGTCAAACTCAGAAAGTTTGTATAGAGAAGTTCAAGCTGCGATATCTGGGGCATCCAATTTTTAAATTGAATTTGCTATTTTTGGAATACTTCATTCTTTTCCAAGATACACATTCCCAGTCAATTTCTTTGTTATCCTTATTTTTTGATAATCTATTCCTTTCGAGCTATGCTCAGAACCAATTGTATTCTCATCCATTGTTATACCCTTTTTGCAAGCATGTTGCATTGGAATAATGATTAATGGACTAATAAAACTTTCACAAGGGAAGTTTGGCATATTACTCTAGAAGTTTCTAAATAATACAGGAACCTGAAACAAGACTATTGTTTAGAACGCACCATGTTTAAATGTTGGAAATCTGAAAAGGAAGAGTCTAAATTAGGACTTTCTCTTTGGATTTTGTTGTTAAAAACATTGATTGAACAAAATGACAAAGCTAAAATAAACAAGTAAGCAATGATCACCGAACAGTAGGAAGAGGTTTTCTTGGAGAAGAAAGCCTTCATTTATGATTGAGCCTTTTGTACGATACCTTGGGAATGGTGTAAGGGACCAAAGAGATTTAGATCCTGTATCATTGAATTGTGATAAGAGAGGATCGAGAAAAAGCCATATATTCCTACCTTTGGGTTACAGTGGGAGAATGATGGTACAAATTTTGCGCCCCAATGGATTGAACTTTGAGGTTTATAGTGGGGGGCAACCTGACTAAATGTTTCTTCAAAAAAGCTAGCCAAGCAAGAAGGTGTCGTAGCACATCAGTGTTAAAGCCTTAATAAACTTCGAGCAATGACAACCTAAGTGGGATCATTCTCGGAAAAAAAATTATTAAAAAAATTATGCATTCGTGCAAACACCATTAAAAAATGTCTAGTTAGGAGCATTTGATTCATTTTATGCCATCCTAATCATTAGGCAAAATTAGGTTCATTAGACATGTCATGTTCCCCAGAGAGCAGATCAGTGAAGATAACAGATCTTGCCTTCCTACACTGACAGCAAAGCAGATTGAAGACACCAGCCTTGTCTCCCTGGGTTGTAGCGGAGCAGGTTAAAAATAGCAGATCTTGCCTTCCTGCACCGACAGCGAAGCAGATCGAAGACACCAGCCTTGCCTCCCTGGGTTGCAGCGAAGCAGGTTAAAAATAGCAGATCTTGCCTTCCTGCACGGACAGTGAAGCAGATCGAAGACACCAGTCTTGCCTCCCTGGGTTGTAGCGGAGCAGGTTAAAAATAGCAGATCTTGCCTTCTTGCACCGACAGCAAAGCAGATCGAAGACACCAACCTTGCCTCCCCGGGTTGTAGCGGAGCAGGTTAAAAATAGCAGATCTTGCCTTCCTGCACCGACAGCGAAGCAGATCGAAGACACCAGCCTTGCCTCCCTGGGTTGTAGCGGAGCAGGTTAAAAATAGTAAATCTTGCCTTCCTGCACCGACAGCGAAGCAGATCAATAACCCCAGCCCTATCTCCCTGGACAGCAGTGGAATAGGTTGAAGATTGTAAGTCCTATCTCCCTGGTTAGTAGTGGAATAGGTTGAAGATTGTGAATCCTATCTCCCTGAGCAACAGTGGAGTAGGATGAAAATAGCAGATCTTGCCTTCTTGTACTGGTAGTGAAGCAGATCGAAGACATTAGTCTTATCGCCTTGACGTTGCAATGGAAAAGATTGAAGCCACAAGGCAAATCTTATTTCCCTGGCGTTGTAGCGGAGCAGATTGAAGCTACGACGGTGAATCTTATCTCCTGAGCATTAAGGCTTGGATTATCTGAAGTGGAGCGGATTGAAGCTGTGTGCAGTGAATCCTATATCTTTGGCATTACAGTGGAGCAGATTGAAACCACGACGGTGAATCTTACTCCCCTGACGGTGTAGTGGAACAGATTGAAGCTACGACGGTGAATCTTGTTTCCCCAACATTGCAATTTAAAAGACTGAAGATGGCGAATCTTATCTCCCTGAAGTTGTAGTGGAGCAGATTAAAGCCAATAATCCTATCTCCCTGAAGTCACAGTGGAGCGGATTAAAATCACAAATCTTATCTCCTTGAAGTTGCAGTGGAGCAGACCCAAGAAAGCGAGTCTTATCTCCCTGAAGTTGCAGTGGAGCAGACTCAAGAAATCAAGTCTTATCCCTCTGAAATTGCAGTGGGGCAGACTAAATAAACAAATCCCATCTCTCTAAAGTTGTAGTAGAGTGGATTAGAATCTCTCTGAAATTACAGTAGAGCAGATCGCATCAAGTTCATCTTTAAAGTTGCAGCAGATCAAGTTGAAGCTATAAGTCTTATCTCCCTGGAGTTGCAGTGGAGCAGATTAAAGATAGCAAATTTTGAAAAACTACAACGTGCAAATCCTATCTCCCTGGCATTGCAGTGGAGTAGGTTGAAGCACCAGTTCCTATACCTCTAAAGATGCAGTAGGAAGGAATGAGGCTATTTGAAGAAGAAGAAGAAGAGTGCTAAAGTCTAGTACGACCAGCAAAATTGGTCATTTCTAAAGTCTTTGCTCCGTTCTTGTTACATGATAATGAGAAAAGAGGGGCAGCTGTAATAGACCAATTTAGCCCGGGCTCATAAAAAAATAATAAACCCAAAATAATAAAACAAAGTCCAAAATTATATCATTTGGCCCGATCGGGATGGCCCATTACTTGAAAAGGTTGAAGGTCTATCTACAAGCTTGATGCATATGGAAACATAATCTTCAATGATATGCAATCTTCGATATGATATGTAATCTTAGATATGATATGCAATCTTAGATATGATATGTAATCTTAGATATGATATGCAATCTTAGAAGATATGATTTTGTAATCTTAGAGATTTAATTTGTAGATACCTTTTAATCTTAGCCGTTGATGTAATTAATCTATACCGTTGGATTTGGGGAGGCTCAGCTATAAATAGATGTCTCTCCCTTCATTGTAAAGGGGGGAAGTGGGGAGTAATAATAATTCTTAAGAGTATTTACTCAAATTTCTCTTTCTCTTGCGTTCTTATTTTGTTGATTTGTGTATAATTTATTTATTGATTTGTATATTGTTGATTTCAAATCTCTTTTTCCCTTATTATTCATTTTCAAATTCATTATTTTCAAATTTGTTTACATTTTATTTGGCCTTATATATTTTTTATTTTATACTCTTTGTTTTAAATTCATTGGTCTTTGATTATTGATGCTATTTAATCCTCTATTTGTTATTTTAGTTTTTTTATTATTAAATTAATTATTTTAATATTATTAATACAATTATGTGCCATCATTAATCTTGTATCATTATTATTATTATTATTATTATTATTTTATATTCATGCGCATGCATCGTTTTTATGTAATATATATATTGTTTTATATATATTATACGTATGCTTATATATATTTTATACATATGTTTTTGTTTTTGTTTTTATTTTACTTCCTAACTTTTATATACATATATATACTTTTATATTTAGTATCAATTTTTTTTTTACTTTTGTATATATGTACATGTGTGTATTTATATATTTTTTGGACTAATTCATTTTTGAGGAATTAGAATGTCGTGCCCTAACGCATTGGGTGTGACATTTTCTTTCTCCGAAATGATAAGAGTCTCAATAAGTAACGTTTTTTTAAGTTTTTATTAAGGATCATATTTTTAAATTTTCGACATTAAGGTACTAATTAATTAACTAGGTACCAATTTTGGGCATTATGAGGGTGCTAATCCTTCCTCGTACGTAACTTACTCCCAGATCCATTTTTCTAAAACTCGTAGACCAAAGCTATTTTTTAGGTGATCCAATCACACCTCAATAAAAGATTGGTGGCGACTCCCAATTTTTGTTTTTTAAAGTCGACAACTAATTTTTGTTTTTTTCCAAAATAAAAGTTGGTTTCGACAATTGGTATGGCCTATCTGCGAACACCTTAACTTCGAATCGGTCTAGACTGTGAGGTCGAGAGATAAGTAGCTCTTTCCAACTCATTATTCTAGTGGAAGATCAGAAGATCCTACAAGGGTATCGACTAGTTGATTGAACAAGAAGCCCAAAGAGACAATTGATTATGATTAGTGAAGCGAGCTAATCACCCATGCTTAGATTTGATAAATTCTACTATTTGATTTCCTGCTATTTATTTATTTATGTTCTTTTATTATTATAAAAAAATCCCAAAAACCTTTCTTTATATTTTGATGTAATATAATCTATCTAAAGTATTAATTAGACATATTTGTGCTTAGGTTAGAGTTAACTTGCCTCCCTTGGGTATGATCCTCAGAGTACTTACCTACTCCGTTGTAACTATATTACAACCTGACCCGTATACTTGCGGTTACATCCTTTTTAAAATATTTTGTGCAGAATTTTTACTCTGGACGTTGGTACGTCTGGAGGCGGTCAATATCTTCTTCATTCGACAAAAATAAGGAACATAAAAGAAATAAGCTTGTATGTTACTCAACACCATTTTCGTGAGATAATCCAAAGGTTAATGAGCTTCTTCATTGAAATTTTTATTAGATTTCTACCCTATTATGATAGATGAAAATGACCCACTTGATAAATTAGAAATTGTCAAATTTTAGCTTAGTAACCATTAATGAAAGTTTGAATGCTAGTGACATAATGGTTGAACTTTGAGTAGTATTATGTTTATTGTTAATTAGATGTTCCTCAATTATAGTTTCAAAGTTGTATTTAGATTCGATAGGGTAAAATATAAAATATGAGGATTTCAAATATTAGAGCTATAAGGGACCTAATTAAAAAGAATGCATAAAAAGTTTAATTTAAATTTTTATAAGTAGGAGAATTTAATAATGTCTTTATACTTGAAATATTGAAAGATGCTAAAAACGAGGTTGGAACATTGAGGGACAATGAACAAGTAAGATCAGATAACAAGCAATGATGTCAATTTGTGCTACTATAATTAGATTTCAGTAATTTATTTTATTGAATAGCTAGTCGATATAATCTAGTACGAAATAAATGTCAAGGTAACTACATCTCTACTTAAAAGCTTTGAAATGATGAATTAGATGTGTTTGTGTAAATCATGTTATAAATGATTGATTTTAGGATATGATTCTATATACTCAATTTATAAGCATTGCTATATTGATATTTGACTATGATGATATATGTTATGATAATAATTATAATAATACTTCCCCATTAAACAATGTTAGATGTAGTTTGAGTGTAGTTGGCATGCCATAGGATTATTATCAGTGATTTTATTTAGCCCCAATTCCCAGAAGATCATGAGAAGTCCCAATTCCAAAGGGTCATGCACATATATTGATATACAAATTAGTAGCTTTAATTCCTAAAGAGTCGTGAGCAGTCCCAATTCCCTGAGGGTTGTGGGCAATTCCAATTTCTAGAAGGTCATGGACTTACTTTGACATGCATATTTGAGTATTCATTCTAGTGTCTACATTCAGTTAATAGGGGCTACACTGAATAAGAAATGAAAAGTGATATTTATTGAAATGTTATATGTTTGAATAGGCATTAATGCTTAATAATGAACTATGAAATGAAATAACCTAATATTGGGAAATGAGACAGTAACTATCTTGACTTATATGTAAACATGTTCTATGTTTGATTCATTTATATATAATTGTATTAATTTCAAATTATTGGCACAACTGAATATTCAATATGTAGCGTATAGATTTGTTTGTTTTCATGCGTAGGTACAAATTAGACTTGTTGGTAGACCGTAGGACCATCAAGCGTCCAACTTTTGACAACTCAGCTCAACTTGGTTAAATCTTGTGTTAGTTTTCTATAAAGTTAGTTAATGGCATCTATTTAACAACTCAATTTTTAGTGGTACTGGAAAAGGCAATTTCGGAACCCCACTTTTATAAAACGAGTCTCTAAATATTAAATATTTATATTTATGAGGTAAACATAGAAATATATCAAAGATTGGTCAATTTATTGAATTGATAGTTAATTAAGGTACAAGGACTAAACTGTAAAAGTTTATCTCTATAGGTTTTTAATTGGCCAAAGACTTAGGGAATTAGTTTGAAATTAACCAAAGGTATCAAATGAGAATTAAACCATTTTAATTTATATGTTAGTGGAGTATGATGAGAGAATCCACTTATATAAGTTAATGGTGGATTAAGTTAATAAAATGTAATTAAACTAATTAATTAAAGTGTAATTAAACTAATTAAACATCCTAAAAGTGTAAGGAGAAACCATGTTTTAGCTTAAACAATTCTGTCCCTAATTGGTAAGCTTTTCTAAGTCCTTTTTTCTTGTAATTTTTATGTTTTTAAGGTCATGAGAGCTTGATTTAGCTAGCCCATGTACCAATTCGTAAAAATGTCAAAGTTTTTAAAAGTTTCCATTGTTTATTTCTTGAAAAAATTGGTGCCAAATTGATAGATTTTAAGCTTAGATGTGAAAAAGGACTAGAATGTAAAGTTTAATTGACAGTTTTGTACATAAGGACTAAAGTGTATAAATTGTATAATTGATATGAAATTTTTGTTATAATAGATAGTATAGGGGTCCTAAAAGGGTGTGATTGAGATTGATTTTGAAACTGATGCTCAAAATCGAAAGTTATTGTTATTTCAATTTTAGGGGCGAAATTGAATAAGATGTAAAAATTTAGGGGTTCAAAAAATTGAAATTTTATAGGTTCATGCATATCACGGAATGATATAAAATATTTTATATTGATGAATTGTCTAAAATAATTGTTTAGATCAAGAATTGAATCAAATTAGGGATAATCGAGGAAAAGCCACAATTATTGAATAGCCCCTGAAGATTCAACTTATTTGTTATTTTTTTCCCGGTAAGTTCATATGGTATAAATGTTTTTAAGTTGTGGTTTATTTTATTTGTGATTATATGTGTTTGGTTGCGAATTGGTATTAAGGTGAGATTTGGACTAAATTGTAAAGAAATGTATATATGTGTTAAAAATGCTCAGGTGAATGATCTATCTTAATTTGATATGTCAAAGTAGTCTTCCCAGTTATAATTAAGGAGCTTGTTTTCAAGCAAATTAGTTTTGCGTAGTTTTCAGATTTTTTTTTTATTCAATAAGTGTTTAATGTGTTTTTGTGCTCATTTTGAGACCCAAATTGGACAAATGCGCCATTTGGACCCTAATGATCGATTAAGTGTTGTAAGAACTCAATGATGGCTCATTTTTTAGCGAAAACATCACCAAGGAGGGGTTATTACGATATCAAAGCATGAAAATCATGATACCCTTAACATTCCTAAAATGAAAAGAAAAATGAAGACCACCTACAGTGGTGTTGCGATACCTAATACCCAGCCTTCAAAGGGAACTCCTCATTTAGAAATTGCCAACGATATCATGATATCTAGACCATGGGTATTGCGATATCATTGTCATGAGGGGAAAAAAGTTAACATCAGAGGTAGTCTTTGTCCAACCGAAGCACCAATCAAAAAGACATGTTGAAGGGCATTTTGGTAAAAAAAGGGTCAAAATAGTTGCTAAAAAGAACCAAAAATTGGCTAAAGAGAGTGAGAGGAGGCATTAGGCATAATTTTTAGTCATCTTCTTAGTTGCTCTCCTTTATAGTTGTAGATATAATTTTCTACTAGTTTCCTCGTGTTTCTTTGCATTCTTAACTGTAGCTTAGGTTTATTTACACGTTTAGGACCTTTAACTTTCTTGTACTGACATTTTCATCTCTAGTTTAATGTTCTTTCAATATGTTTTCTTTTTCTTTATTAAAAATCTAATATTTATTATTCTTGTTCATTTATCTTGTTCTTAGTTTCTTTTCCTTTAATTCTTTCAAATTAAAAACCCAAGCTTTCATCTTTTTATTGAGTTTTATGTTCATGCCTTTCATGGTAGCTTCTTTGATGTTAGCTTAGAAAAGATAATGGTTAACTAAACCCTATGGGGGTTGGTTAATGGAGATGTAGGTAACTTATTTTTGGGTCGAGGAATAAATTGCAATAAATTGGACTAAATTGAATGAACTTAAAAACTTAGGATTGATGCCCCTAAGGGAAAATCAAGATAAGTGAGACTGAGAGGTAACCTTATTGGGAACCGATTCATTAATTCTTGGTTAATCAGGTGAGATTGAGAGGTAAACCGAACTAATTTATCTAACTTGGTAAAATTGAGACTGAGAGGTAAAATAGATCCATTTTAGGAGTTTAAGCAATTTAGATCCCTAATTCAATGATTAATAAACCGCATTGAAGTTAACCAACCACCGCTCATTATTGATTGGATAGTTTTATCACCTTGCATGCTTTACAATTTGGTCATTTTGTTAATTATTTAGCTAATTGGTTTAATAAAACTCAAATTCATGGTCTGTCGTACTATGTTATCTAGCGAATAGTTGTTTAAACTCTTTATTTGCATGTTTGTAGCTAGAATTCACTTAATCGTCGAGTTCTGTGGGTTCAATTCTTAGAACACTCATGTACCCCGTTGTACAAATTATATTACAACTGACCTGTCACACTTCTAGACACCACATGTACTTATTCTTGTAATGGCCCAAATTTGCCCAGCCCAAATCAGAAGTAAATAAATAATAAATATAAAACCAAAATTAAAAGTCCAAAATAGTCCCTTTACACCAGGCTCAATGTGGCCCAAACCAAACAGACCCTAAATCCCCAATCCAAGTTACAGAAACCCAACTAGCCTAACCCCAAAACCAAGCCCAAATACCCGCAGCCCAAAATAGAGAAAATCAGCAGCAAACCCTAGAGACCAAAACCCTAAACTAAGACGCCACAGCAGCCTCGCAACGCGCTGCCTTCGGCTTTCCTCTCTACGCGCGCCACGCCACCACCTCCGTACCCCCGTACCTTCAAACAAACAAACAAAAACAGCACAACAAAAAGAAAAAGAACGATTGTATTTTATTTTCGTTTTCGGCTATAAAAGAGCCAACAAAATCTGTAAAAGGTTCCCTTTTTTTACGATCAACAGACAGAGAGAATACGCAGAGATTGTATCAAAAAAAACAAAAATAAATACAAAGGAAAAGGTTTTTTTTCATTCTCTTTTTCGATTGCTTTTCTTTTTGGCTGGTTCGTTATTAATCGCATATAAGCATATATAAGGAAAATAAGAAAGAGAAACTTACCTGGTTGGTGTCGTTAACCCCCCGTTTTGCTCTGTTGAAATCGGAGTTAGAAAAGGTGGTCGTCTCTTGGCTGCAAACGGCGGAGCGGCGCAACATTTGGGGGCTGATGTTTAGTTTTTTTTTTTAAGTTTGTTTAAGGCTAATAGTTATTGATTTAGGGTTTATTTAGTTTTGTTTTATAACCAAAGAAACGACACCATTTTAAGACTGCTTAAGTGGCTTCAAAACGACGCCGTTTAGAGGCTTGCGACCCCGCGGTGACCCGACCCGGGGAAGGATCCGCGCGTTTTGGCCTCTGTTGGGAAATTTGCGCAGATAGTCCTCCACTTTTATAGAGCTTTCAAATTGATCCTTTTATTTCTTTTAAATTTGATCGCTCATTCTGTACTACATTTCAATTAGGTGTGTGCAAGGATACTGTGTATTGAGGGAAGGGATATTTACCCTTTTAGTCCCCAAGTTGTTCGCGCGTTCCTTTGTGGTCCTTAATGTTATTTTATTTTTATTTTCTCTTTTAATTTTGGAATTAAACGCAAGTTAGCCTGTTTTTGCTTAATTTAAATGTATTCAAAATTTTATTTTATTTTAATATTCATCATTTTTAAAATATATTTAACTTTACATCTAGCATTATTTTATGTTTAAATTTAGTATATTTTAAATTTATTACAATATTATTTTAATATTATAACATATTATTGTTCTAAACATATCATTAACATTATTTTAAATTTATCATGTACAATCTTATGCATTCTTGTTGCAAATTCAATATAATTTATACATATTTTACATCTTTATTTTATAATACATTTTTAACTACACTTATATAGTTCTTTGCTTTAAGATTTATACAATAATATTCTTACTTAATATTTTTCTATACATGTATATATAATTTGTGTTAAATTATTTTTATATATATACATAATATATTATCGATTTCATATTATTACATATCCTTTCATATATTTTTATGTATAAATAACTTATTTATTTCAAACCCTATTTTATTATATGTTTTACTTATTTCAACTCTTTTATCTATTATTATGTGTAATTTATTTATATTAAGTTTTCCACTCCATCTATTACTTATTTTAAAGTGTATATCATTCTTTTCTATTTTTGAATGTTTCAAGTTTGCAAATGTATTATTCATTTTAATTCTTTATTCATATACGTATAACCTATTATTGACGATTTCAAATATTTTATTTTTTCTCATCATTTTTGTTTTTGTTAGATGATTCCCTAATTACCTTTTAATTCATTTACCTTTCTAACATAATATTAATATTGGTTTAATGTGCGGTATGATTGCTTTTATGCTTATTGTATAACTTATTCGCATGAATTGATTCTTTGTAACTCGTTAGTATTGATTTTAGTTTGTAAATTAGCTTTTCCCGATGTACAATGTTATTTCGTTATTCATTCAAAAGATTACAAGTGTCAAAGTTATTTCATTCAAAAACTTTCAAAAATACTCGAAGTTTGGAATCCTCGAGAGAATTGAGCCCTAACGTATTGGGTTTCAATTTTCCTCGTCAAATCTAAATAATCGAAATTTTTTCAAACATACAAATTTCAAATAAAAACCCATTTTCGGGAATTCGACATGTTGTGTCCTAACGCATTGGATATGACGTGTTATTTCCTCGAGATGAGAATTTTTAAAATAATAATAAAGGTAATATTCAATATTTAGGAATTTAGTGAAATCGAGCCCTAACTTACTGGGTTTCAATTTTCTCATTTGACCTAAATGATCAAATATCCTTCTCAAAAATGCATAGGTTTTAAAAGTTAAAAGATAAACTTAATTTTGAAGATTAAAAATGTTGCACCCTAACTCACTGGGTGTGACATTTTATTTCTTTGAAATAAGAGTGTTTTATCATTCAATTTATTCAGGTTAAAAGAATCGTACTTTAAAATCTTTTCAAAATTTCGACACTAAGACATAAAATGATCAATTCGGTACCAATTTTGGGCGTTACGAGGGTACTAACCCTTCCTCGTGCGTAACCGACTCCTGAACCTATTTTCTCAAATCTCGCAGACCTAAAATTTATTTTAATGGTGAACCGGTCACACCTTAATAAAAGATCGGTGGCGACTCTCATTTTCATTTTTAACTCGATAACTAAAATATTTTGTTTTTCAAAAATGGTTTCGACAATTCTGATTTGATTGTTGTATTAGTTGTTAGCACCGTTGTCGGGGAGCTAGTGCTAGATTGAGTGACTATAGCTTTATTGCAAGATTTATAGGGAGATAGTTGACTAAAGCTTTATTTATAGATATGAATTTTTATTTTGTTTCTTTGCTTGTTATTTTGTTCAAAAAATTTATTGATTGTGTGAATCTCTTTTGCTTGTAGGAGGTAGTTTATGACTCAGACTAGTAATAAGATTGTACTATTTGAACCGAAATTGAAAAGAATCTTGACACATAGTCAACAAGAACAACTTTTGAGAAGAGCCCAACCTCCACCATTTGACAACCCAAGAGTTGAGGAACATCCACCACCAATTCATCAAAGACCGATGGCGGAAAGGACAATGAGAGACTACACCATGCGTAATCTTTACGCTGTGGAAGGAAGCATTAACCGCCAAGCGATTAATTGGGGAGGTCACAATGAACACAATCAATGTGAAGTTCAACTACTTATGAAATAAGGGGTACCTACAATCAATGGGGTCCTTACAATCAAGAAGTACCCAACTTCAACCCACCTAGGCCTAATGCACCATAACAAGCTCCGTAGCCATTTAGGGTAGCCCAAGAAACTATGAGAAAATTCGCCTAGAATAGCAACCCTCTAATACCCATTCATGTGAGTAAACTAGAGGAAGGCTTGCATTCGATGCAAGCAGAAGTGTGCCTAATGCAAGGTCAATTGCGCCAAATTTTTCATATGCTACAAAGTAGTGCTTCCTTTAGCATATCAAGAAATATTGAACCAAACCCGAAGAGGGAAGGGAAAGAACATGCTACGACCATTACCCTTAGATTTTGAGTGGTGGTTAAAACCCTATTAGACTGGTGAATGGAGAAGAGGTAGTAGAGAAGGAAGAGAACACCTACACTCCTAGTGGTGGACATAGGGTAGGAGAGAGAGTAGAAGCAGAAGTTGATCCCAAACAACCCAAACCTCAGGATAGGCCCATTGCACCCTCAAGTCAAGTACCCGTACCTTTTTTGACCCGTCTTGAGGAAAAAAAAAGAAAAAGAAGAGTAAGGAATTTCCAATTTTCATTTACATGTTTAAGGCGTTGAGTGTTAATCTCCTGTTATTAAAGCTCTTAGAAAAATTTTGAAATATGTTAAGTTTCTAAGGGAAGTTATGTTCCAGAGGAAGAAGATTGGGAGAGGAAAACATATTGCTCTTAACGCTAAGTGTTGTGTGATTGTGCCCATAAAATTTCCCCTAAAACTCAATGACCCGGGCAGCTTCAGAATCCCTATAGAAATAGGAGTGAATTACGAGAAAGCCCTTTGTGATTTAGGGGCTAGTATCAACCTCGTGTCATTATCAATTTATTAGAGGTTAGTATTAGGGAACTTTAGGGAGACCTCAATGACTTTGCAACTTTTCAATTGCCCTTTTTTTCCTTCCTAAGGGAGTCTTTGAGGACGTATTAGTTAGATTTAGGCAATTCATCCCATCAGTGGACTTTATTGTGTTAGACTTTGAGGAAGACCTAAAAATCCCTATCCTACTAGGAATGCCATCTTTGGTAGCCTCTATGGCAACTATAGATGTCAAAAAAGGGGAGTTGACGATAGACAGAGATGGGGAGGTCAAAATCTTTAAGTGTGTTGACCCCAACCTTAGTTCTAATGAGTCATCACTCTCTCAAGGGTATGAGTGTTAAGCAGTTGAGATAATATCCTATCATGCCACTGATCTTGCAACTATTATGAAATGATGTGAACTTAAAGTTTTTAGCTCAATGTGAAAAAAAAAGATCCAAAAACGAAAGAAATTTAGTAAGCCATGGCGATCCTAAAGTAGCCTCAGTCAGGTGATGAACAAGATGTGAATTAAAGTATCGAGCACACCACATTAGTACCACTTCGGGGGCATAACTGATCACCTTGAAGCTAATTTGTAATTTTTCTAGAAGGTAATTCAAATTAAGTTTGTAAATATTTGAATGATCCGAGCACGGAGTCCGTTTGTTTTCCTTGTTTAGTTTAGGTTTAAATTTGAGCATGTTTAATTTTTGCACTTGGTAGGGTAGATTTTGGATAATTGGGAGATTAGATGATAATTTTGTATGTTTTTTGGGCACCCTTCTAGTCGTATTGCGATATCCAAGAGGGAATATCACGATAACCTTAACAGTCTAGGGGGATGCTCAAAATTTTCTAGATATTGCAATACTGGTCCCTTGGTATCGCAATATCCCTAGCTATTTCAAAAATAAAAAAATTGTCAAAGTTATAATGGTATTGTGATACCAGTATCTCGGTATCTCGGTATCGTAGTAGTTTCAAAATAAAGGGTACAAAGTGAAAGGGGTATCACGATACCCACCTTCAGTATCGCAATATCTATGTTAGGTCGTGATCCCCAAGGTTTGGAGGCTTTTTAAGCCTCCAAACACCCTAACACCCAGATCTCTTTCATTCTTATGCCCTATTCGTTTTCAAAACACTCCCATCTTCATCTTCTCCTCTATTTTCCTTTTTAACCTTCATTTACTTTTCTCACAAATTTGCCTATTTAGTATTATTTCTTCTTCTTTTCATTCTTATTTGTAGGTTTTCCTTCTCCTTGCCTTGGAACAATAGTACTACATCCCCTCCAACCGCTTTGCCATTGCCATCAATACATTTTTATCGTGTCAAATTCCTTTTCCCTTTGTTTTCTTTGAAATTTTTATTTTTTTAGTGTTGCACTATTGATTTGTCTATTGGTTAGTTTATTATTTGTTAAAAAGCTTGATTAAATTGTGAGGTTAGTAAAATGTCGCCTAGACAAACTAAACGAACTAGGTCTCAATCGAACCCTCTTCTACCATCGGCGGTGGTTCTAGAGTGATTTACAAATAAAGAGGTTGAAAATTATTTTATGTCAATCCAAGGCGAAACATTTATTCTTGAGCATGGTTCCGACCCAATTGCTTCTCTTTGTAATGAGATTTGGGACTTTGTCTATTACCATGGATGGTTCAATATTTTTCTAGTCCCAAAATCGACTGTGGTTATCCCCACTGTTCTTGAGTTTTATGAAAATTTAAAAGTTTATGTTGAAGCTGCGTACTGGTTCAGGGAATAGAGATTGACATTTCCCTAAGTGCTATTAGCGAGCACTATGGTGTTCCATGGTATCAACAAGATGACATTGAACAAATGGATTTAAAATTTTATAAAATGTCGACATAGACCTCATTCTCGCCTACCTAATGTAAGGTCAAAGGGAATAGAAATGGGAATAGTACAAAAACCTTCCTCTATCTTTTAATCAAGTAATAATATTTTCCTTAGGAAAAATATAGATTCAATTTATCTCGACCCGTGTTAGTCTCATGCTCAACACTAACACAGTTAACAATTTTGTAGCAGTTTTTTTTTCAATTTTGTAATGGAAGCGAGTTTGTCTTGGGATGTGGATAAATCATTAGATGAAGAAGTGTCTTAGGGAGCAAAGTTGGCATGTACTTCCCTCATCTGATTATGGACTTATGTCATAAGAAGAGGGTAAAAATGAACCTGACTGAGTAGTTTCACCGCCCCACTTAGGGTATTATAGGCAATACCATGATACTTTAGCTTCACAAGTTGGAGTGGTAGAAAATTTAGGAGTGGAATCAAAGGCGCAAGCACAAGATGGAAATGCCTACGACCCTAAAGAAGAAAACCACAACAAAGAAGGTGTACGAAGGTACATAGTGGCAACGTAAGTTGTTTGATAAGGTTCGCTACAACACTCGACTACTCGAGGCGATAAAACCATTTATAAAAATATTTTTGATGAGCCAAGGGATAGAGGGCCCACAGTGGCCCGAACGATTGACCAACGCATCCTTTAGTGGCGAGGAGGAACAAGAAGAAAGAGAGAAATTGGAAGAGGAAGCAGATGAGGATGATAAAGAGATAGAAGATGATGACCCCGCACTGTATATTGATGATTTTGACGCGATTTTCGCTCCCGAGTGACCTACCACGACCAAGTTAATCTTCAAAGGCCTGAGACCACCGAGGCATCAGGGCTACTAAAGGTTGGCCAACAAGGGAAAATGGAAGGAGATAGTTAGACCGGAGTCGGGCTCTCATGATGATTAGTTACATGTTTTCACATTCTTTTCTTTT
->URS0000BE9894 tRNA from 1 species 
-GGCTCCATAGTATAGTGGTAGCACATCTGCTTTACATGCAGAAGGTCCTGGATTCGTGCCCCAGATGAAGCCA
->URS0000C75118 pre_miRNA from 1 species 
-GAGATACTCCCTCCGTCCCAAAATTCTTGTCTTAGATTTGTCTAAATACGGATGTATCTAACGTAACTAGATACATCCATATCTAGACAAATCTAAGACAAGAATTTTGGGACGGAGGGAGTATATG
->URS000029BCEB rRNA from 1 species 
-GACGAACGCTGGCGGCGCGCCTAACACATGCAAGTCGAACGGGGAAGTTAGCAATAACTTCTTAGTGGCGAACGGGTGAGTAACGCGTGGACAACCAACCTTCTGGTGGGGGACAACACTTCGAAAGGAGTGCTAATACCGCATGAGCTCTATAGGCCGCATGGTCTGCAGAGGAAAGGAGCTTCGGCTCCGCGAGAAGACGGGTCCGCGTCTGATTAGCTAGTTGGAGGGGTAACGGCCCACCAAGGCAACGATCAGTAGCCGGTCTGAGAGGATGAACGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTCGAGAATAGTCTACAATGGCCGGAAGGCTGATAGTGCGACGCCGCGTGTGGGAAGAAGGCCTTCGGGTCGTAAACCTCTGTCATGGGGGACGAAGGAAGTGACGGTACCCCAAGAGGAAGCCCCTGCTAACTACGTG
->URS0000023D8D tRNA from 1 species 
-ACATTTTTAGTATAATAGTACATTTGACTTCCAATCAAAAGGTCCTTTCCAAGGAAAATGTA
->URS00018C1C85 rRNA from 1 species 
-TACGTGAGGGTGCGAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGTAGGCGGTCTGTCGCGTCGGGAGTGAAAACTCAGGGCTTAACCCTGAGCTGCTTCCGATACGGGCAGACTAGAGGTATGCAGGGGAGAACGGAATTCCTGGTGTAGCGGTGGAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGTTCTCTGGGCATTACCTGACGCTGAGGAGCGAAAGTGTGGGGAGCGAACAGG
->URS00017FF56C rRNA from 1 species 
-TGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGCGAGGAGGAAGGTGGTGAACTTAATACGTTCATCAATTGACGTTACTCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTTGAAACTGGCAAGCTAGAGTCTCGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACGAAGACCGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAAACGATGTCGATTTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAATCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGTC
->URS0000142B05 siRNA from 1 species 
-GTCAAATAACCTATCGAAAGTGT
->URS0001228231 rRNA from 1 species 
-TACGTAGGGGGCTAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCGTGTAGGCGGCCAGGTAGGTCTGCTGTGAAAACTCGAGGCTTAACCTCGAGATGTCGGCGGAAACCATCTGGCTAGAGTCCGGAAGAGGAGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCCGTGGCGAAGGCGGCTCTCTGGGACGATACTGACGCTGAGACGCGAAAGCGTGGGGAGCGAACAGG
->URS0002355A6F lncRNA from 1 species 
-AAGAACTGTACGCCACTCAACTCTCACAGCTACAAGAAATGGGTTTCTTTGATACCCGAGAGAATATACAGGCGCTGATAGCCACTGCAGGGAATGTTCATGCTGCGGTGGAGCGGCTATTGGGGAACCTTGGTCAGTAGATAATAATCATTTGTTATTGTCCTATTCGTCGCAACATTTATTGTCAGTCGGGCCCGATGAAATTGGTTTGGACCGGACTAAAGAGGATTTTTCAAAACCTATCTTGGCTATGAATTAAAAATACAGATTCGATGTTTTGAAGTTCTTGGCATAAGGTATGATCATGGGAATACCCTCTTCTATTCCCCACCCCAATAGTAAAGCGAGTGATATGTACATACACTATTATGATTGTCTCTCGTAATTTTTTTTATTTGTAATACAAATTTTTCTATTTTTTTTTGGGTGGGTGGGTAATTTACTTTTTCTTTACCCTACGCTGGGTGGGTGAATTCTTATAATTATACTTGATCTGATGTACTGTTTCGTTTTTCTGCACTTTGTTATCTAGATGCAAGTTTCCGATTGCGGAAATGGAGGTGGAATAACTGGGGATCGATATAGTTTTTCTGCCGAATGCGATGTGGTTATTTTCATAGGCAATTGTTATATTATGATGTGTTTTAAAATTAGTGATTATGGTTGGTTGGTTTTTTATTTCTCCTTTTGAATCCCATGGCAACCAGATGGCATTGGAACCCGAAGGGTAGATTAAAATCCATTTTCATAGATAACCAAGCAAATAATAATAAAAAGGGAGCTGCTAATGCCTCGTTGAGAAGTTATGGAGCCATGCACAAGTAGTCAATTTGACATATTTACCCTCGAATCATTTTCAGTCAACTCTCTCTGCAAATTACGTTCCTTTATCCTCCATCAGTTTCCTCTCTCTCCCCAAAACCAGATCACTCTTCCTCAGTTGTTATAAAATTCTCCTTTAAAATATTGTAAACTCGCTAAAGAAATTGAACAATCTTACAAATATCATTTACACTAGGCAAGGCAAATGAGAATCTGACTTTTGACACCCTCCCTGTGATGATGGAATCAACCAGATCCAACACCACCCATCAAAAACCTAACATGATCCCGTCCACAGAGTTAAATTACGCTGCGGATTGTACATCTTTATAGACTTGATGATCATCGGCCTTCACCTGATCAGCCCTTGGTTTCCGGGCTGCCTCTTAGGGTAAGCCAACGGTTTCTTTCATGGTTTTCTAATCCAACCAACAAGATGAAGAGAGTCGCTCCATTTAGAACCATCCTCCATTTCAGAGGATTGAATTTTCATCCTACAGACGTGACGGATGAAAGAAAAAAATAGAAAATCCTTCATTTCACGATTCACTTTTTTAAATTTTCTAAATTGCTCTCTTCAACTCTTTGATTTTAAATTTGAACACCAATTTTATTCTTCTTATTTTTTATTGCTTTCTGATAAACTACATATAACTTTTAACATAGACATTTAAGTTTTATAAAATTAACATGGTTGAATATACATGGACTATACCTTTAAAATGATACCCATATTCAATATATTCTCTAACAATTTGAAAATTGGTTGGACATATAAAATTTCTTAGAAAAACAATGGAGGAAAATTTTTAGAAATGGAAGTAGAGATTTGTGGTTGGAGTTGAATAAAAAAGAATATTTTGATCTTCTAAATTGGGTTGGAGATGCTCTTAGATGGTGTTTGGTGATGCTTATTAGCAATAACTTATTCTTTTTTCTGTTTTAAAAGTTGTATCAGAGTACTTATCACAATTTTTATTTATATTTACGAGCTAAAAATAACTTAAAAATTGATTTTTGCAAAGCTACATTATTATTGTGATACTTTTTTACTTCTATTTTTGAATAATTACTTTTAATATAATTTCAGGTACAACAAACACTCTTAATTTAAATTAGACCAATAAGCCCCATCTAATGAGAAGAAAAAAATTAAAGTACAAAGAATAATGCGCATGATAATAAAAACTTGCAGGAAATAACTTGTTATTATAGAGGACTCATTTGTCTTTTTACATATCGTCACAATATTTTACAAAAAGGCGCTTGAGTATAGCCGTTAGTTCTCGCCTCCACCATCCGGTCCCAGTTGCGATTCCCTACCCACTCACCACCCAAAACTCGATGCACCGGATCACCAACAGCCTCAATCATCACGAACCGTACATTTTCATTATAAAAACAAAAAAACGGACGATCCAAAATCAAGGGACGCAACCTTTTGAAATGAGTTAGATACATTGGGAGTAGGTGAATATAACGGCCAATTCAAAAGTTTCCCACCAAAACTATATATATAACCACCTTCCTATTCCTTCCGCATCCAAATCTCTCTCTCCACAATGACTAACCCCAATGATTCCCCAAACCAATCCCCCACCAACAAAGCCCCGAAGCCTCTCTTCGCCTGATAGGGACCCTTTGGCAACACTCCTCCTCCCCTGAGTCCTATCGAAGTCAGTCTCTCCCGGTAACCTCTTCAAGGCTTCAAAACTCATACTACCACCGTGATTGGCGGCGGAGGCGGTAGGGGCGGAACCAAAATTTATGTTCAGTGGGGTCAAAAGAGTCAGAATTTATATTAGTGGTGTCAAAATTATAAAATTTATAAAATTTAGGACAAATTACTAATTTTTATGAAATCAATATGTATTTATGATAAATTATATTATAAAAAATAGCGTGCTTTTTTTCTGACCTCAATGCCCCTATGTAGCTCCGCCACTAGGGGAGGTGATGCCACCATTGGAGAGTCTTCTTCTGGTGGTGGCGGCGGTGGTGAGACTATACTGGTGTTTGCAAGTTTAGCCCTACTAGCAATTGGTGGTAGTGGGGATAGTGTGGCGGCCGCTGCTGGTGGAGGCAGCAGCATTGTTCGTAGGAAGAGACCCCAAGACTGAGTGCTGCCGCTGGAAGGCCAGCCATTGCAATGCCCAGTGTGCGGAAGGTGTTTTCCTTCTAATCGTAGCTTAAGTGGGCATATGAAGATACACCCCGACCGTGGCTGGCGGGGGATCCATCCACATCCAGTTTTTAGCCGCAACGAGTTTGGTGACATTCTCGGACAGGCGGAGGAGGAAATGGCGGCAGCGATGGTTGTGAATGAGGCCGAGACTGGTGGTGACAAGGAGGAAGAGGAGGTGGTGGTTGCAGCGGTGGCGGAGGGGAGAGAGGAAGTAGCGGCGGAGAAGGGCAGGGATGGAGTTGATCTGAAGGAAGAGCCACCGCGAAAACTGCTGGACTTGAACAGGCCTCCTTCACCGGATGAGTAATATTGGTTTTCTTAATTATTATTGGGTTGTTTCTCTATTTATTAATTACAAAGTTTTTCTTGTTTTTGAATGATGGTTTGGTGAATGGATGTTGTTATGAGGTTGTTTTTTCTAAGTATTAATTACACAGAGTTTATGTCTGTTAAACATGGATTATTCTATGGAGGATTTTAAATTTGGGAGATTAATATTGAGTTCTCTGTATTTTTTGATGAATAATTACATTATTCAATTCTATTTAAGTCCCATGCTTAATTGAACACAGGGAGAGAGAGAGAGAGAGTCTGATTATTAATGATCAACTGTTATGATTATTAATAATTACACTTTCCTCTTTTTATTTGTATTTATCATGATGAATTTACTCAAAATATTACTATTTAAATAAAAGTAAATATTTTAATAAAATTATTCTACTAAAACAAAAAAAATGGGTGCAATTACAGAAAAAGTGAGTGTAAAAATAGCATTTTTAAAAATAACTTAACCGAGTGATTTTCAAACTTTTTTTCAACACTCGTAAGTTTTCTAATTAAAAATAATAAAAAAAGTTATAAGGGAGATAAACGATCCAATCTTTTAACAAACTAAACTTTAATATTTTTTTAAAGTTTGTTAATATTTCAAACAAGCTTGAATACTCTACCATTCATTTCCATAAGTTGTTTAAAAAATTTAAATTACTAAAGGTCAGCAGCACGCTTGAGACCAATATAAGCTCGATTATAATTTTAAAACCTCGTTAATATTTTAAACCAAAATTAAACATTTCGTTAATCAATTCTACTGATTTCCCATGCTTGTTTACTGTGCAAACAAATCCTTAGGTCATGAATCATTGTTTAAATTACAATGAGAATCCTTGTTTCAAAAATCAGGGCGAGCAGTTGCTTTAGTCGGCTATCAACCGTTAGATCCTCAAATGAAAACCCTAGATTTTTGTTGCCTATATAATCACTTCGGGAGAGAAGAAAAAAAGAAAATAGGGTTTTTGTTGTAGAGAGATAAAGAAAGAGAGCGAGCGATAGAGAGCGTCCCGAGACAGAGTTTGTGTGCTACAAAGAGAGTTGCGGTTGAGAGAATTGATTTGATCACTGATTCCGTTAATGCAGTGAGTATTGAGTAATTGCTTCTTGTTTTGAATTTAGATCATCAGGTTTGTTGTTTGATTCTTGTGGTTTTACTTTTTTTTTCTTATTTCATATCATCATCTGTTCTTGGATCTTCGATTCTGTCTTCGTAATTAGGTATTTTGAGACTGATATAGATTTTTATTGCAGTTTTAGTGAAGATATTTGCGTTTGTGTAAGTTCTCCTTGTTTTGATTTCAATTATCAGGTTTGTCTGTCGATTGATTCTTGTGGTTTAGCGTTTTTTTCCTTTTAATATGATCTCCAATTATTTCATATCATCATCTGTTATTGGATCTTTGATTCTGTTTTAATAATTAGATGTTTTGTCTTTTTTTTTTGAGACTGATTTAGATTTCTATTGCATTTGCAGTGAAGATTTTTTTGCGTTTGTGTAAGTTCTCCTTCTTTCATACTTCGATCATCAGTTTGTCCATTTGTCCTTAGATTCTTGGGGTTTTACTTTTTTTTTCTTTGAATTTGATCTCCAATTATTTCATATCATCATCTGTAGATGGTTGTTACCTATAAATAATGCGATTAATTCCTCCATATCACGTCTAGTAGCGATTTGTCTCCCTTCTCTCTCCTTCTCTCTTTGTGTTCTGCGATTATCAATCCAAAACCCTCGCAAGCAATGCAATTCGTGGAATCATTCAATCTACGAGGAGAGACACACGTGAGGGATTGTTAATCTTCTCGATCTTTCTCTGATCTGCTAGCGATTGCCTAATTTGTTATGTAATTTATTTAATTTTTTATGTACATCCATTTATGTAATTGCTTCAAGGATCTTCCTTCTTGTATCAGTACATGCCGATTTGATTCTTCCTGTTCTAATGAATTTCTATGAAGATGTTGTTTTCACTTGCATCAATTAAACTCCAAATATTGCAGGCGTTGAAAAATATCAAAGTGGCTGCACTTTTTGATTGGATAGTCACAATACGAATCTTGGATCTCCTTGAAGTTCTGTCACAATCAGTAGCTCTCTCTCCCCTCTCCTCCTCCTCTTCTTCTTCTTATGATGATGATGAGTTTTCTATGAATATATCATTTTTTTCTTATGCCCATTAAACTCAAATATTGCAGGTGTTGAAAGAAGTTGAAAGTGTTTACTATTCTTGGTTGGATAATCGCAATATGAATCTGGGATTGAATTCTGTCTTTGAAGTGAAGCACTGTCACAATCAATAGCAATCTATCTCTCCCCCCCCCACTCTCTTCTTTTTTTTGTACTGCTGAATCTTCTATTTGTTTTCTCAACCACCAAGTATTTTGTTTCCACATCTAAAATTAACCTAGTGTTAATCTGCAACAGAAGGGCTGTTCTTGGAGACTTGAACAAAAGGGGAGTGTGAAATCACTCATCTATTGAACAATATGATTTCGTTTTTCCTTGAAAAGAAAATAAACAAAAAAGAAGGCTTTTCCTGATTTTAAAACCTCACGGAAGTTATTGCACAAGTCTGAGAAATAATATATTTTTATTGTAGAGGAAATATCAACAAAAAATTATATAGTTTGCTCCCTTTAAGACCTTCACATAATCATGCAAGGGCTCTCTTTTTCCGTCTTTATCCTTTTTTTTCTTCTATTCAGTGTACGGTTTGAATATTGAAGTAGCTTATTATTACTCAGAAATAGGAGAGCAGTTACTTTCTTTTTTGAACAAGAGGAAGGCGTGTTTACCATCTTAGCTAAAATTTACGAGGATGGTGTCATTAACACATGATAATATTCTTGGACCTTCACTTCTTATTATTACCAATGTGGTGAGTATAAATAAAATGACATACTATTGGAAACTAAGGATCTGTTCATAATATTTAACTGATGACATTAAAGGTTGGCTTATTCTTTTTCCTTTTTTAGGTTGGGAGATGGGGCTTGAGGGGGTGGCGCTGCCTGCCATTGCATATAGAGACTGCAGTACATTTTCTACCTCCACATGATAGGCTGGGCTTCTGATTGTTTGGGGACATAAAATGTTTTGGGGGCTATCAAGTGATATAAATGAAGAAACATCTGATCAGTGAGAGAGAAATAAATCTGTGTGGTCGCCCCTGGAGCTGTATTAATCGACACTTGTTGAGAAGCGAATTGATTGTGGGAGGCAGATGCGTCGAGATTCTGTGGTGATAATTAATTGGTTTTATCAGCCCTAGTGGTTTTCCGTTGTTTTTTGGCTGGGGTTCGGGCCTTGAGTTTTCAATATAGAATGGAAGATAGAAAAAATATTAGCTTGGTTTTACAGAGAATCATAGGGTTTGACTGCTTTTGAGAGTGTTTCAGATAGTCAATCGTTGCCTTGAAATTTCTGGCTTTCTTTCAGGCACATTATTAGTTTTATTTTCCAGAATATGCTTTTTTTTTCCTTTTCTTTTCATGTTGCATATTCCTTGATTGTAGACTTCTAGCTTTTCAGTTTGTTATACTTTAAAATTCAAATGGTTAGGCTTTGCATGCCACAATCAAGTAATTAGCCTTTTTATCTATGCTACATCATCTTTCCGTGTTTTCTTTTCATTAAAGTATGTACATGCTTCTGCTTTAGTATTGATTTTACAATTTGGATGCATTCTGCTTTGTATGGATTGAATCTAACATCTTTAAACCTTTTAAGTAACTTTCAGTTCCAGAACTGTATGGCAAGGAGGTGGAAATTGTCATAAATATTAAAGATGATCTTGAGGATTGTTTGATGCTTAAAATTTTTATGTGCCATTTAACAAGACTCCGAAATGTTTATTTGCATGGTTACTAATAGGTTTTTACATATTTTCCGCTGATGGCGGGTTTCTGTTGCTTCAATATTTAAGTAACTCATGGAGCCCTTTGGTAATGCATTCTTGTGACTAAAATTTAAATTCATATTTGAGGATGTTTTTGTTTTCCTCTCTATCCTTTGCGCTTTCTACTGCTCAAATGAATCTTAATTAGTTTTATACCTACGTTGAGATTCTCCACTTCTTAATCTGACTGATATATTTATATTGAATCTTAATGAAGTTTACCAGCCACCTTATGATTCTGCAATTATCGCTCTGATTGAAAAATTTATCATAAATGGTACCTTTAGTCTAAGGCCACCAGTGGGCTTGATTATTATGGCAGTGTCTTGATTCAGCACAATTTCTTTAGCAGGGAAGATGCTATCTTGGAGAGCAGGGAGTCCTTTGAATGACAATGTTGTGGTAATGGAATAGTTACTGTTTCTGACTATCATTCTTTGATTTATCACTAAAGTGTTTCCGTCAGTATATCCTATTTAGTTATCAGTTGGACAGAGTGCTCAGCTGCTCTGTCTTATTACCAGACAAGGAGGAATCCATCTAGTTTATTACAGTGTGCTGGACACTTGTGACATTAAACGGAGATGCTTTTGCAAAAAGCCATTGACCAAATAGATATCTTGTTAACCTCGTAGTAAGAGTTGGTGAACTTTTTGAACTTGTAATTTTACAAAAATAAGCTGGTTTCTCACATCAGCTTCCAGTCCTTTTTAAGTCCATTTCCTTGTCTCTCAATGGCTGTTAGGGAAATCTTTTTTCTATGAGTTTACAGAATATCATAATCCCACTCCCCCCAACCCATCCCCCCACCCAAATGCAATGTGCACCCAAAAAGGAAATCACCTTCAATCTTTGTTCCAGTTTCTTGGTTTCAACTATGTAGATTCGTTTCCTCTGGTAGCGTTCGTTAAATACCAAATTCTTATTTAAGTTTAAAGTATTATGCCATTCTTTACCGTCTCAAAGATGTTCACTTTGTTAGGATGGTTATGTTCAATATTATTCAGTAAGAATCAAATTGTGCTTGGTAACTGCAGAAGACTACTCAAAGAAGTGCAAGTCTTTCTGGAGATGTTGAACAATTCCCGGGCCCAATGTGGGCAGCATGGGTTGTACATCTGATGTGATGTGTTTTTCGGTAACACATCCAAATGCAAGAAATTTAATATTATCATTGTAGAGGTTGGTCAAATGGAGTTTCTTGAGGTAGGCGTGTTTTCAAGGTTTATTTTGTGACTTGAAATTGTGGAGAAAGAATTAGCTAATCGATTGTTGACCCATGTATTATTGTTCAATACTATTTTGTTGACAATTACAATAAAAATGTGTCTTGATTTTTTTTTGTTTATGTTTACTACTATTGATATTTTATTAGTATACTTGACACATTTGTTTGATATTTTTTAAATATTTTTTATCTTGATTCAATCGGTGGTAATATATCTTTGGTCCGTTATCTAAAAATCTATGAGAAAAATACTTTTTTAAATTTAACATGTTTGACAACTCGCCTATTCACAATGTATAGTCGAATGATTTATATTTTACTCTATTTTATAATTATTTTGGTATTTGATTATAATTATATTTATATATTTGTCAAAAAGTTTTTTTCTACTTGCTAATACTTTCTCCTAATGTTTTTGAGCGTATTGTATTTCATCGTCTAAGTTGATTCTCTGTTTTACATATAATTTGCTCAAGTAGTCCATTGTAAGTTTTATCCATACCAATTCCTCGGATTTTTGAAAATCGAATGAGTTTTCCTTAATCGGTACGTAAAGTTTTTTAAAAATTACGTTGTCGTGTTAAATTATTATATTTAGGATATTTAACTTGTAAATTATTACATTTTGAATTGACATCGTTTGTGTTTCATTTGACTTATCATTTCTATTGTTGATTGGGTCTTGGGTAAGTAGCACAATTGTGATGTGATTTACACCCCTTTATAGACGATCTCTTTAATTTATTTCATTTGTGTTTTGTTACCAGGTAGTCTCCTCACATTTGCGTATGCTTTAGGAACTTGTTACGTGCTTGGATGAGTGTTCCTTCATCGTTCCGTGAAGTGTTTAAAACATTGCATAATTGTGAAATAGTTTGATTGTTTAATATACTTGTAATTTGATTTACCCCTACCTTTTTCGATAATATCTCTAATTGACTCGGTTTTAAATTTTTATTTCCAGGTCGTGACTTCTTGGTTATGTAGCTAAGTGGTATTGATCTAGTAGTGCATGGAAAGTGTTATACTTACGATTCTTTTGGTTTTTAAAAATCATAAACAATTTTAAAATTGAGATCCTTGGGGTATTTTTATAGTTGCGATGTGATTTACTGCTAATTTCTTCAATTTTGTATTGTCTTTGCAGGTGATGTCTTCCACATCTACAACTACTTTGGGACCTTGGTCTTGTGCTTGGAATCAATTTTCCTTGTTCCGTGAAGTGTTTTAAAATATTACATAACACATGGATTATTAAATTTGTTTTTTTTAATGTTCTTGTAATGTGGCTTACCCCATGCTTCTTGATAATATCTCTAATTAGCTTAGTTTGAATTTCATTTGTAGGTCGTGACTTCTCATTTCTATAGTTGTGTCGAGCTTACTCAATTAATGCATTGTAAGTGTTATACTTGGTGATTCCTCTGTTTTTTTGAAATTCATAAGCAATTGTAAAGTTTATATTAGGATTATTATATTTTGAGTTTTCTTTGTAGGTGTGTCTTCTCATTTCTATTGCCTCTGCTTTGAGGCACAGTCTTGTGCTTGGAGTGGATTTTCCTCAGCGGGTTCAATGAAGTTTTTAAAATATTGCATTTCATTAAATTATTACTTGTAGGATTTTTACCCATGTGCTTCTCGATATATCTCCAATTGAGGCTTAGTTTGAATTTCTTCTGCAGGTCTCGACTACTAGTTTCTGAAGTTGGTTGAGAGTAGCTTTTGTAGTACATTATAAGTGTTACCCTTAGTGATTCCTTGGATTTTAGTTTATTTCGTTTTGTTGTGATGTGATCTATGCCATTTCGTGGACGATTTCTCTGATTTATTCAATATTGAGTTCCCTTTTTAGATGTTCTCTTCTCACTTCTGGAGATGCTTTGTGACCTTTTCAAGTGCTTCGAACGAGTTTTGATTAACCGTTTCATGAAGTTTTTTCAAAATTTTCAAATTTATTATATTTATTTTTTTAATATACTTGTCTCTAATTTGTAAAATTTTGTATTTCTGTTGTAGGTATTGTTTTGTCACTTCTGCAGCTGCTTTAGGACCTTGTCATGTTTTTGGAATGTTTTTCCTTAACGGTTTTGTTGTGTTTTTTAAAGAATATTCATAATTGTGAAATATTTAGCTTGTTAAATGTACTTGTAATTCGATTTACCTCTACTCTTCTCGATCATATCTCTAACTAATTTAGTTTCAGTTTCTTGTGCAGGTTTTGACTTGATCATTCCACTAGTTTGTTTGGACTTGCTCTAGCAGTGTATTACAAGTGTTACCCTTAGTGATTACTTTATTTTTGAAATTCTTAAGCAATTGTATTATAAGTTTTTTCAAAATTTTTAAAATTTCAAATTTATTATATTTGTTTTTTTAATATACTTATCTCTAATTTGTAAAATTTTGTATTTCTGTTGTAGGTGTTGTTTTATCACTTCTGCAGCTGCTTTAGGACCTTGTCATGTTCTTGGAATGGTTTTCCTTAACGGTTTTATTGTGTTTTTAAAAAATATTCATAATTGTGAAATATTTAGGTTGTTAAATGTACTTGTAATTCGATTTACCTCTACTCTTCTCGATCATATCTCTAACTAACTTAGTTTCAGTTTCTTGTGTAGGTTTTGACTTGATCATTCCACTAGTTTGTTTGGACTTGCTCTAGCAGTGTATTATGAGTGTTACCGTTGGTGATTACTTTATTTTTGAAAGTCTTTAGCAATTGTAAAATTGAGATATTTGGGTTATTCAATTTTTAGTTTCCTTTGCAGGTGGTCTTCTCATTTTTGCAGTTTCTTTGGGACACATGGTCTTGTGCAAGAATGGCTCTTCCTTAATCAGTTGGTGAAATTTTTTAAATATTGCATTGTCTTTAAACTATTATTTTTAGGATTTTTAATATACTTGTAATGTGATTCACCCATTCCTTTCTCGATATCTCTCTTATTGAACTAATTTGAATTCTTTTATAGCTTGTGACTTCTCGTTTCTATTATTGCTTGGGACTTGCTCACTTTGTGCATTGTAAGCATTATCTGTGGTGATTATTTGGAGTTTTTTAAAATGTTAATCAACTTTAGTATTGAGATCTTTAGCTTATCTCTTACAATTGTGATGTAATTTATGCCACTTCGGGGACGGTATCACTGGATTATTCAGTTTTTTATTTCCTTTTGCAAGTGTTGTCTCCTCACTTCTGCAATTGGTTTAGGACCTTGGCATGTGCTTGGTATGAGTTTTTCTGAATCTTTCTATGAAGTTTTTAAAATATTACCTAGTTGTGAAGTTTATATATTTGGAGTTATTTAATATCATTGTAATATGAGTTAATTAAATGGATTGTTACTAATATATATTTAACTTATTTGAACCTGGCAGTTGGAATTGCTGAATCCAGCTAGGGATGCTAGGTTGCCGATAATTGGTGGCCTAAGTGGGTTTTGTCTCCCAGAGGTTGAGAGCATTTTGTTCCAAACAGAACATTGCTTCATTCATTCAGTTTACGCAGAACTCAGCTCTGTGCTCTTTGCACGTCACTTTCATGGATTTGCAAAAAGGATTGAGTACATTCTTTAGGCGGCCCTTTACGAATCTGTTGGGTTGATATTGTGCTTCTTGGACGGTTGGACCTACAACATTGACGCAAGATCACTAAAGCTTAGTACGAGGAGATCAAGAAGCTTATGGAGGAGCTTCATTTGGTTATGTTCTTGCAATTGGTTACTAAGGAGGTTCTAGACTGCAGTTATACTCTCCCATTTGACAAGGCAAGTGAAAATTATCCACTTCCTGATTGATTGAAAACTTGAAATACATGGGGCCCAGTGAGAAGTGGGATATATCTAGCCGTATCCATATTCTATTCTCGTAGGTCTTACCATATTGATGTACCCTCATTGTACCTGTACCCATAAACGTGCTTCATAGCTTTTGACGCATGCACGCGCACAAACACCAATTAATATAGCTTTGTAAACCAATTAACTAGGTACTAAAAGTGTCCTCATGTTTTAGGGATAACACTGATGGAGACTTGGGGAAAATGGCAACTTAGAATTAGGTTTTGGAGGGTGGGGTAGCGTTGAATGGAATTTTTATAGAATTTGAGCATGAATATTGCATTTGGCATTAAAATACTTTAGGAGGACAAGAAGTGTAAGCATGCAGCCGAGCCCCCATCTGGAAGTATTGTCCACTTAGGCCTGGCTAAACAACTTCCCTCAATGGATTGTCCCTCTGGCATCCTAGCCCAAAAGGCACCTCCAAGTTGGAAGTGTCTTTCGCTGTCTTGTTTGGTCATCGCGGGCATTGTCCGCAATCCATGTGAGATTCCCACAAGAAGCATAGAAGTGGATACTCGGACCATAGCCTCTTGTAGGTAAGTTTTTACCTTTTCTTCTTTTTTAGTTTTCCATGCTGATGTAATACTCAATGTGCTTTTATTGATTTTATACATTATAGGATCAACTTTTTGAGTTGCATATAAGAAGTTTCTAAAATTTAGTCTCTTTTTCACAAGGCAGGAGTTGTGTCTTAATAATGAATTCTGTAGTTGAGGCTGTAACTATATTTATTGATTCTTGTAGTTTCATTATGCAAGTTAACTACATCATATGAAGTCTGAACTTTTATTCACTTAATATAGAAATTGCCAAAATGCTTTTGTAAAGTGTTCTTCCAAACCTGGAGTATACTTGAGCCTCTTTCATTGCATTTCCTGGACTTGTTAGATTGGTATGAAACTTTTATTTAGGAGAATAAACAACCTTATGCTTGGAGTTGGCGAGAACTGTGTCTCCACCCCTTCTATGCGTGCGTTCACATAAACCCTATATGGTTGTATCTTCGTGGATTATATTAGTTTACATTACTACGATTTGGATGGTATGCTAGGATGGGGAATAAAAAAGTACGCGTAGTTAGTACCCATAAAAGGTGTCTAGGAGGGATAAATTGGTAAAAACTTGACATTTGACAATATATGCACAAAGTGATTGTCGTCAGGAACCTACAACCTCAGGTTTAGTATGCCATGTTTTAACCACTGAACTAATGGATGGATGGTATGCTAAGAAGGGAAATACGAATGAATATTCATAAAAATCGGGATTGCTTAAATTAATGGATTGAGAGAAGGGGAAAAAACTATTACGAGGCTTGCATCTATATCTATACTTCGACAAGTGCTCTGAAGAATCGGAGTAGAATTAGGCATCGTTGCCAAATCCTAAACAAAGGAAACCTTGCTATCCAAATGTAGTTTTGTGGCTCAGCCGCCACCTCACAAATTATAGATCTAATTGAAGTAACATTACTGTTCATCACCCTTCCCTGTGCCATTTTTTTTTATTCAATGGAAGTCCCTGTGCTATTTTTTTTTTCATCCAAAAACAAATTTGTCCTTTCATTAGGGGATGATGTTTGCAAAAACTGTGTATAGCATCTTCACTTTATTGGTATCATTGAAGTAAACTGTTTGAATAACGGTAAAATATTGATTTACATTTTAGTTATCATGCACTTGTTACGATAAGCAAGATTGCCTGGCCTACATCTTAAAATATGATCGGTAGTGAAGTTTAATAATGAAGTATGTTTTAACGAATTCCTTATGCATTTTTTTTTACAAACTGGTTGTGCCTTTTCACCGTTTTGTTCGACGGAGCCCTGTTATATAAGTTTGTATGTATATCCATGTATAGATGTTGGTTTTATTTCAAAGTCATTTTAGTTATGTTGCATTAACGACTTCAACCATAATATAAGCTGGTTTTTTAGATGAAACTCTTTGCCTTTGCACAGGTTAGTAGTTCCTGAAGACCCTTTTGCCCTGTTCTTTAACACCCTTAAATTCCATATCTCTTCTGCATTTAGTTTACGGACTGGTTGTGCTTTTCACCCTTCTGACTTAATAGTTTCTTGATTGTTTTTTCCCCATATATAAATCTAGCTTTTCTTCTTGGCTAGCACCATTGGGAACTGTCCACATATTATACCTAAACCTGAACTATATTTATTTATTTTCCTTGTATCATGGACAGGATTGGTGGCAGATCACACTGTTCACTTGGTTCGTGGTTTCGCTCCAACTGTACCAGTCACCACTGCATGTGCAACCAACACTGGAGTTCCAAATTCTACTCCAAGTGGCGTGGCGTCTGTTGGTTCTGACGAAGGGGCATTGGGAGGAACTGGTTTGGGCTCTTCGCTCTTTCCTGGACTTGGTTTTAATGGATTAGGCAGCAGCAATGGATTATATGGAGCTGGACTTCCAGAAATTGAACAAGTGCAGCAACAGTTGACTAAGAACCCCAATCTGATGAGAGAATTAATGAACATGCCTCTTGTTCAGAACCTAATGAATAACCCAGACATTATGCGGAATATGATAATGAACAACCCACAGATGCGTGAAATCATTGATCGAAATCCAGAGCTTGGTCACATACTCAATGATCTTAGCACTCTCTGTCAGTCATTGGAGACTGCAAGAAACCCTGAACTCATGCGTGAGATGATGCGCAATACTGACAGAGCAATGAGCAATATCGAATCTTCTCCTGAGGGATTTAACATGCTGAGGCACATGTATGAAAATGTCCAAGAGCCTTTTCTAAATGCAACAACCACGGCTGGGGATACTGGAAATAATCCAGGATCAAACCCTTTTGTGGCTCTTTGGGGGACTCAAGGTGGCTGGCAGGGCAGAGATCTGGATACTAATCCTTCTAGCACTGGTTCCAAAACTAATACCAATTCTCCTGCTTCAAACACTAATCCACTTCCCAATCCGTGGGCCTCTGGTGGAGATAAGTTAAGCTCTCTCTTTAGTCCTCTTTTTCTTCTTTAGGATTTTGAATGTTTTGGTGTTGAGATACATGAATTTGAGGCTGTACTTATCCTTATTATCCTTTGCTCTGCTGCTTCATTTTGTTTGGGTTAAATTGTGGCGTTATACGTTGCTGATGTCAGCATTTTTAAAAATAAAAAGTTGGTTTTTATCTATACTTTTCTCATTTTTATTCAGTGTAGGTTGGAAGGATATCTTGTTTATAAGCTAGTCATATTAATAAGAGAGCCAACATATGACAAAAGTATTAGCATTCATTATAGGCATAGACTATTCAAGTTGAAAAACTTTGCTGCATCATATGTGATATGTGTAGTCCTACTAATTAGAATATCATCCCCAATTTTATTGTTCCTGTTCAATTTTTTAAAAGGTGTCACCGTTTTTCCCTGAACTTCATTATCTGAAGTTGACTTTAAATAAATTATATGGATTGTTACTAATGTTTAACTTACTTTGAATTTGGCAGCTGGTGGTGCCCAAACAAACTCCACTATGAGATCGAGTCCAGGTGGGGATGCTAGGTTGCCGACACTTGGTGGCCTAAGTGGTGTTGGTCTCCCAAGACATGTTTGGTTTCACACAAGACAACGCTTCATTCAGTCAGTTTATGCAAAGCCCAGCTGTATCACAGATGATGCAAAGTCTCCTCTCCAACCCTCAGTACATGAATCAGGTAGTACTTTTAATTTTTTACAATGTAGTACGTGTTTATTACCGCTTTCAGGGCTTGCTTATAGTTCGTTTGGTGTTTCTGTTTGTTGCAGCTTTCTAAAACAGCTCATGACCCTGACTTGAATATGACTATCCAGAAGCACACTTATGGATGCTTTTGGCTTCCGCTTACAGATTATCAACTTTCAGATTTAAATAAGATGAGACCAAACTGCCTCTAATATGGTTCATTTGACTATGGCTTTTCTAATTCTAATATGTATTTCAATTGGTAGATTCTTGGGCTGAATCCCCAGCTGCGCAATATGATGGATTCCAATTCCCAACTTAGAGAGATGATGCAAAACCCAGAATTCCTTCGCCAATTGACTTCCCCTGAAACAATGCAGGTACGATGCTTGAAATCCCACGTCCCTCTCATGCACTCTGTCTCCCTATATTTGGAAATGAAAATGAGACTTGCATATTATTGATATTGGTGTGATTAAAATAATGAAGGGCTGTATTGAGTCATTGACATCTCTCCAAGTGAAATCTGTTCCATTTTAGCATTTTAAAGTATTGTTTTGCAGCTTCCGACAATTATTTAGGAATTTAACATTTCTCTAATATCTTTCAAGAACTGCTTCGCTATAACCATCCCCTTGTGGTTGGTGAAGGGAGGGCCTCAGAGCCCCTATTGGTAGAAAAAAACCCACAATCCCTTGAGGTCCTCCTGAAGAAGAAAACGGATTAAATTCAGTGATAATTTGATTCTTTGTTGTTGCTTAACACATGCCAGTCTTACGAGCCGAAGTAGCTCTGCATGGTATTGTCATTTTACCTATAATAAATTGGTTTACTGAATAAGATTCAATTGGCCGTCTCTTAGGAACTGACCAAAGAGTTAAGGAGTTACGATCATCTCATATTGAGAAAACGTCATTGATAGCTTCCGCTACCCGACCCAGCCTTTGCTTTTTATTTAGGGTAAATTTCATTTATGACAAATGCAACTACCTCCTTTGTAGTTTTAGAAATAGTGTTGACCTCCCTTTCTTTTGAATCTAATGTCAACATTCCACCTGAAACTAATTTTTGTGCAAAAATGACAAATTTGCAATTTGATTTAGGGATTCCAATTTTTTTTTTCTCTATACACATTAAAATAAATAAATATTTTCTTCTTTTTCTCAAAATATCATTTACTTGTAAATAATTTTATTTTTATTTTTTATCACTAAGTAATTTTTGTAAAAAGGATTTTGATCTAAACAGTTTACTTTTTAAGTGCTCCAAATCTAAACATTCTTAAAAAATATTTTTTTTATCATTTTTTTAAAAATAATAGAATGTTTATTTATTTTAATGTGTGTTGAGAAAATAAATTTGGAAGTCCTAAATATAAGGGCGAGATTGTATTTTTGCTCAAAATTAGCTTTCGGGGAGAATCTTGGCCATAATTTCAAAAGTAAGGGAGATTAGAGCTATTTCAGAAACTATAAGGGAAGTGGTTGTATTTGTCAGAAACATCAGGGGAGGTCAATGAAATTTATTCTTTTATTTATTATTGGAAATGGGAGGCTGAAGAGAGGTTTATGTTGTTTTTCCTTTTATTTTTTGAGATTTGTTTGTCAACGACTAGTTTGTTTTCAATCTGGCTGTACAAACTCTTTAAATTTTTATTTTTTACTTAGAAAGGGCTTTCTCCCTAATACTAGGCATTGGATTGGGTACTTATTATCAATTTTCTCATTTTACAGTTTACAGATAGATCAATTGCCATCATAAGTGTCTCGAGTTCTCACCCCTTACTCATTTAGGTTTCTTGTTTTTTGGAACATCATGAGCTAAAATTAAAGTTCCTCCCCACCAACTGCATGGGTTGTTATGGGAAAAGTAAATGATTCATGTAAGAAATATCTCAATAAGTAGCATAGTTTATTCTCTACAGCACACTATAGGCATATGGACCCACTATTCCCGTGGCTTATTGTCATTGGGCGGGGCTTGTAGGCAAGACAATGAACAAGTAAAACACCCGGTGTGGTGCTGTATGATACACGTTAGACAGTCCCGCCAATTTGCAAGCAATAAGTTGACAAAATGCCAAGGAAAAGGCTACTCAAGCATATGAAAGTGAGACATTCAAGAGCGAAATGACAGCTTTCCATTGATCAAAAAGGTGTATTACAATGTTTTAGCCATGCACCCAAGTACATAACTCAAAACAAACCATTGTCAAAAAACTAGTTAAAGACAATGGTTGGGCAAGTCATGAACCTGACCCTAATGGTTCGTCAAAGTAGCTTGTCCCATTTTCCCTCAAGGGACCTTCATCAAATGTTATGCGAGAGAGAATTCACCACACGATGACTTGGTGACAAGCCAAATCTCTGCATCAATCAGCCGTCATAGCTGGAAGGAAATCGAATCCGTTGTTTAACTGCTAGGACTGATCCATGCATTCAACCGTCGGCCAGAAAAGTGAATGGGCTCCAACTGGTTTGCCTCCTGGACCAACCCATTCTATAATTTGAAGGATCTGTTCTCCAACAGAAAGTGAAATCCTCTCCTATTGGGATCATAGATGCCTCACCAGAGATTGCCCTGGCTCCCATCCAGTCATTTTTCTCCTATAATTTTACACTATGTTAGAGCACCATTACTCGTAGGCTCCACCGCGTCATTTCCACAATAAAAAAATAATAAACTTCAGATTTAAGATTCTTATATCTATCAAATAACTTTTTTAATTTGGCAGGCACTTAATTTTTTACGAAACACATTTTCAGCTGACAAAATTCAGCATTCAGTAATTAGTTTTATCTAACGCCACCTATGTTACTTGATTCTTGTAGTTTCATGGTGTAAGTTAACTGCATCTAGTAAATCTTGAATGTCTGTCACTGAATATATAAATTGCCGAATTGCCTCAGTCGATGTGCTCTTCCAAATTGGGAACTACTTGAGCCCCATTTTGCATTCCATTTCCTGCACTTGTTTTGCATAGGAGAAGTCATGATTAATATGAATGAAGTGGGGGAAATAGAACAAATTGGAATGCAAACATGTGGTAGTTACATCTTATTTGAACTTAAGTGGGAACTTTCTTATTTGTGGAGAACTATTCAATATCAGCATGCATATATGCATGTGCATGTGCATGTTTGAGCCTTTTGTCCCTCCTTTTGTTTTAAAACGTATTAACTTTGTTCTTTATTACTTTATTTCCTCTGGGTTGGGCCACTTCTTCCAAGAATTATATATAGCTCGTTCATAAATCCACTTGACCACTCAGACTTAACGACGAAGTCCTTCTTCATTACTTTATTTCCTCTCGTTCTTAATTTTTATTTTCCCTGTTTCAGCAAATTTTGACCTTACAGCGAACTCTTCGTCTCAGCTTGGTCAGCAATCTTCAACCAGGTAAGTGATTTTGCTTCTAGATTTTGTACAGTAAAGGAAACCAATTTCAAGCCTGCTAGTCTTATCATTAACCATACGTTTATCAGTGTAACTCACTTTTTACTCATATAGCTGTATGTAAATGTTGACACAATCAATATGTTCACGTTACTGTCCAGATTATTTGAAACATTGATTTTTCTAGCCTTTTATACCTGGCGACCATATAGAATTTTGTTGATTAGATTTAACCCCTTTCCTTTTTTAATTTGTCTATTTGTAATTGCACTCTTGCAGGGAAGCAGGTCAAGGTGTTGGTGGGACAGGTACGTTATCTTGGAACTTGACATTCTAATTGCATATATTTAACCATAATGCTCAGTGATTCTGAAATCAGAGTGTCTATTCGTGGTAATGCAAGATTGCAGCTTGTCTTGCCTCATCTATCTCAAGTTGAAAATTCTTTAAGCTTAAACTTCAATTCTAAAATAGGGATCTCCCAAGGCTGTGTTTGGATCAAAAGGGAAAAGGTGGAGGATCCAATGGTCCCGAACGGTTGGATCCTCTAACTTTTCTATTTTCTTTTCCTTCACCAAATCCTTGATCCAAACACGGCCTATGAGCTTGAAGACTGTTCCTTTGTAATCTTTTGTTGAATGTGGAGGATTCTGGGATTGTGTCCTTCCATCAATTAAGCACAACATGCCTAATCTGAAATCTCTGTTGATGCTAACCCTGAACCCCATATTTATTTTGTAAAAGAGAAAGGAAAACCGAATAAACAAGACATGAAGATGGCATTATATGAAAATTTCCGGTTGTTTTCTTTAATAGTAGTTATTTAACTCACAGTGACGTGCCCTTGTTCTCTCAATAGCAGAGAAATTGATGGCATGGGGCTGGAGATGTTGATGAACATGTTTGACAGACTCGGGATCGCAATGCCTCCGTCTCTAGGGGTAAGCCAACAGTTTCTTTAATGGTTTTCTAATCCAATAAATAAGATGAAGAGAGCAACTCCATTTGGAGCATCTCCAACCCACCATCTATATCTTCAAAATGAGAAAATAGAGAATCTTTCATTTCACGATTCACTTTTTTAAATTTCAAATTTGCTCCCTTCAACTCTTGATTTTAAATTTGATTACCAATCTTATCCTTTCTACTTTTTATTGCTTTTTGATAAACTACATATAACTTTTAACATACATTTATTTTTTATAAAATTAACATGGTCGAGTATATGTGGAGTATACCTTTAAAATAAGACCAATATTCAATATATTCGCTAACAATTTGAAAATTGATTGGAGGAACTTTTTTAGAAATAAGAGTAGAGATTTGTGAATTGAGTTTGCTTGAATAATAAAAGCCTCTAAACTTAATTTTTGAATAAAAAAGAATATTTTTATGTTATTCTGATTATGGCAATTTTTGAAGCTAGTTATTGTTTACACTATATTTTTTTTTATTTGTATTTGTCAGGGTGAATTTATTTTAAATATTAATATTTGAATAAAAGTGGGTATTTTAATAAATTTATTCTAATAAAGACAAAAAAATAGTGCAATTGAAAAAAAAATGAGTATAAAAATAGCCTTTTAAAAATAACCTAGGCTATTTAAAAAAAATTCTATTTTAACTCGATAATTAGTAACTTTTTTTCTTTCATTAATTTTCTCCTACCGTTCTGAAATCTTATGCTTTCCGATACTATATTCTAAAATTGTAATGCAAGCATATATGAGAATCTTTCACATAATGGGGATTGGGGACCAACAAAGGCCAAACCTATCCGCCATAACAAATTCACGATCCTTCCTAATCTGGCAAATCTTCTTATTTACCAAAAGCAAAAAAATCAAAATTTATGAAAAAATACAAAAAAAAAGAGAAGTGAAAAAATTCTACGGATTCAATTGATCAGAAGATATCAAGATTTTTCAAAATGAAGCCATTGCATATAGGGTAATTACCTCTCCGAACCCAAAGCTCCCTCGAACACAGCCTGCAAAATATATGCCCAGAAGGTGTGAATGCAGCCCCCTTGTGCTTCTCCATACACACGCAAAAGTTTTGCATTTTCAAACCTCTCTTTTCTACCGTTGCACTTATTTTTTTTTCTTTATTATTTGTTATGGTAAATTTACCCAAATATGCTTTTATAAAATAATTTTTTTATTTTTTACTTTATTTTCCCCTTTAAAACGAAGGTATTTTTGTTATTTCACTTAGTCATTATTATATGTGTGATTTGGTTCAAGATAATTATAATTGAATAAGTTTCTTAATGGATTAGGCAACCCCCCAAAAATTATTCTAAACATATCTCAAATAGGAACTTAAACTTTGTTTGATAATAAATTTTGAGGGTGAAATTAGATTATTAGTTATGTGGGGCCTATTTTAATTATGTTTTAGTGCAAAAATTGATTTCTAGACTAATAGTTCATTGAGACTATTAATCTCCAATGAATAGATGATTAAGAATTCCATGGGGGTTGGTTTACTAATTCAATCCCATAAAACTATTAATTCAAAGGAATTAGAATTAGATTTGAATTGATAAACTCACTAAATTGAATTTTGTTATTAAACATGGCCTTAGACCCAATTTTCATATTGTTTGAAAGCCCCTAATATGTTGTTCACCTAAATAGAGAAAAATAAAATTTCAAAAATCAAAATTTCAATGCCCAAACTAGAAGAAAAAAAATCCCAACGCCCAATTTCCAAGACTCATAAATTTCCTAATTAAAGACAATGAAAAAAAGGTGTCATGATTTTCAAAATTCTATTTTGGCTAATTTACAAGGCTAATAAACGAATCAGGTTGCTTTGAGATTGCTTTTGTTCATCTCATTAGAAGCTCATAATTGGTTTGTTACTTTAACAAACTAAGTTTGAACACTATCACTTGTTTCAATAAGCTTGTGCTATTTAACAAAATTCAAGTTACTCGAGTTCAACCGATTACAACGCGCTTAAGATCAACCAAGCTCGAGCATAATTTAAAAAACTCATTAAGTTTACAAACTAAGCTTGAAAACTCTAATGTTCAGCTCTTAAATGAACCCTCTACGCTACACTGTAGGTGTATGGACCCACCATCCACATGGCTAGTAGTCATTGGATGGGGGCTTGTAGGCAAGGTGTGGTGCTTACCAATTCACTTTAGGCAAGTACCCCAAGCTCAAATCACTTGCATCTAGGTTGCAAGCAATAAGTAAAAACAATGCCACGGAGAGGGCTACTTTAGTAATATAAAAGAGATCCTCAAAAGAAAAATGGTAACATTTTATGAATTAAATGGTGCATCACAAATTCTTTAGACATGACCACAAGGTTACAACTCAAAACAATAGTTGAGCAACTCGTCAAGGTAACACTTGATGTAAATAGAATTCTTAACTTTTTATCGTCAAGGTAACACTTGATGTTTTGGGAGTCATAATTCCTCTTAAAAATCACTGAAAATAGAATAATAACAATTGGATATGGGCTAAGCATCACAAAATAATACATCAAATATACATTTGACCTTAGTTTGTGCGGCAAAAGGAGTTTGAATATATTTGTAAAAAGTTAAGAACCTCTCCAATAATAGCTCTTATTCTGTCCCTAAATTTTAACAAAAAAATACATTCTCTATTTTTAAGGGATCATTTTTCAACTACAAACTCCAACAATACTATCTACTTTTATCATATTTCTTTTAAATACTATTTTTTAATTTATAATATTCTCCTCCAACTTCTCTCTCCTCCCTTCATCTCTCTGCACCAACCCAAACATCCAATCTCCCTTTTGCATTAACCCAGACGCCCAATCCCATTGCAATTTTACATAAATGGCATGATCTTCACCTCTTTATTGTGATTTTTCACCTTTGATAGCTATAAATTGGTTCTTGATTTTCTCAATTTTTGCGGTCTCGGTGAGTGATTTCTGAATGGTATTCTCGATCTTGATTTGTGAACTTGGCAATATCTTCACCGATCTCGATGGGGGGATATCCAAGGATATCTTTGATTAGTTTGTAGAGATTCTAGAAGGACTTCTTTTTGTTATTTTTTCTTCATATTGAAGTCTCCAATGACAAAGCAACAAGGAGTTTTCACAACTCAGCGCACATAATCATAATCTCCACCACTTTGGTTGTCTGTGTTGTTATGTGGTTTGCTCGGGCGAGAGACGAAGAATGCTGTTCAATTTCAGTTCTGTGTTGTTTGGGACTTGCTCAATTAATGTATTGTAAGTTTTATCCTTGGTGATTCTTTAGAGTTTTTAAAATCTTAAACAATTGTAAAATTTTGATCTTTAGGTTATTCTTACAGTTGTAATGTGACAATATCTCTAATTTGTAAAATTTTGTGTTTATATTGTAGGTGTTGTTTTGTCACTTCTGTAGTTACGTTGGGACCTTGTCATAATTGAGTTACGTTGGGACCTTGTCATAATTGTGAAATATTTAGGTTGTTAAATGTGCTTGTTGGGACCTTGTCATAATTGTGAAATATTTGGGTTGTTAAATGTGCTTGTAATGCGATTTTCTCCTACCATTCTCTCTAATATCTCTAACTAACTTAGTTTCAATTTCTTGTGTAGGTTTTGACTTGATCATTCCATTAGTTTGTTTGGACTTGCTCTAATAGTGCATTGCAAGTGTTACCTTGGTGATTACTTTATTTTTGAAATTCTTAAGCAATTATAAAATTTAGATATTTGGGTTATTCAATTTTTAGTTTCCTTCGCAGGTGGTCTTCTCATTTATCCAAGAATGGGTATTTCTTAATCATTCGGTGAATTTTTGCGGTCAGTTGGGTTTCGAGATTGCAAAAGATTGTTGCTCTTTCTACCACAGAAGCGGAGTATGTGGCTGCTACCGAAGCTTGCAAGGAGATGGTTTGGTTGCAGAGTTTTATGAGAGAGTTGGGCAAGGAGCAATCGAATTGCACTATCTACAGCGATAGTCAAAGTGCAGTTCATTTGGCAAAGAATTCAGCATTCCATGCCAGAACGAAACACATCGACATTAGATATCACTTCATCCGATCACTCCTAGATGAAGGGTTGATAAGTTTGGAGAAGATCCACACAAATCAGAATCCTGCAGACATGTTCACAAAAGTTGTGATCATTGAGAAACTGAAGCTATGTGCAGCTTCAGTGGGTCTTCTAGTATGAGGGCCGTAATGCCACACCGTTTGAGTAAATATTGAAACAAGTGGGAGTTACCCGGAGGAGCAGTTTGGTGGTCAGCCTTCAAGTGGGAGATTGTTAGGTATGTGAAATGTGGAGCCTGACATTTCAATGTCTACAATTACGGTTGAGTCCAAGTCTCCGATTGCGGCAAGTCCAAGTCTACAATTGTGGCAAGTCCAAGTCTCCGATTACGGCAAGTCCAAGTCTCCGATTGCGGCTGAATGACATCATTGCTTAAGTCATCCTCTTCCTAGGTTTCTCTATAAATAGATGTTGAAGTCTAGGAGAATGATAAGAAGGTAGCTAAGGCTAAGAGAGAGAGAAAGAGTGAGGGAGAGATTGTAATCCTAAATTTTGTTTTGGGGAATTGCTACTCGGTGTGGCCGTGGATGTAGGCTTAATTGGCCGAACCACGTAAAATCTCTGTGTCCCTTTTATTGTTTGTTTCTTACTTGCTTGTTTGTGTTAGAGGTGCACAAAATACCCACCCGACCCGAGACCCGACCCGACCCGACTTCATTGGGTCGGTTTGGGTCGGTTTTTTCAAGTCCATGGGTCGGTTTCGGGTCTAAAAATTATAGACCCGAGCGGTTCGGGTCGGTTCTCGGGTCCCTAAGTTTTTTTACCCAGAACCGACCCGACCGGAACCGACCCGAGAACCGAAGGGTAGAACCAACCCGATCGGACCCGACTTGAGAACCGAAGCCTAGAACCGATTATATGGGCTTATAATGTACTCTACCACACTTGATTATTGCCTATTTTATATAGAATAAGTGAAAATATTTTTAAAAAATTGAAGAACTGACCCGACCCGACGACCCAACCCGAGAATCGAAGAACCGAAGAACCGAACCGAACCGAACCTGAGCGGGTCGGGTCGATTCGGGTCGCCGGGACATTCGGGTCGGTTCTGGGTCTAAATTTCTGGAACCGTTGATGGTCGGGTCGGGTCTGGGTTCGACACATACCCGACCCAACCCGACCCGTGTGCACCCCTAGTTTGTGTGCGTGTTATTATTCCCGATCCATTAGGGTGAAAATACGCATTGGTGTTTTTATCACAACACATTTCTCCAACAGAAAGTGAAATCCTCTCCTATTAGGATCATAGATGCCTCACCAGAGCGCTCTCTCTCTCCATAGATTGCCATGGCTCCCATCCAGTCATTTTTCTCCTATAATTTTACACTACGTTAGAGCACCATTACTCTTAAGCTCACATCCCATCGTACTCAACAATGAACCTTCCCATTTCCCACACATACCATGTAGCATTGCAAAGCAATTCAAGTGTGTATGTGAGTGTATAGATAGTTGCAAACTAGGTACAACTAAGTGTGATCCATGTTCAGGGCCGACATTAATAGAGTGAGCATGAATTTTGCATTTTGGCATTAAAGTACTCTACATGTCAGAGAAGCATAAAAGTGGAAAGCGGGGACCATACCCTCCTGGACATAAGTTTTCACCACATTTTGTTATCAACTTTTAGCTAACCTACAGGTAGCTATCATAGGAAGTATGCATCGATGTGCACCACTATCACACAATTACCATCGCCACCCTTCGACACAATCCCTATGACCACCACCACCACTCCACTCCCACCACCCTCCATCATCATCACCATAGCCACCACAATCATTAATTCCACTACCATTTCACCACAACACCAACACCAACACCACTACCTCCACCTCCACCCCACCTCCACCCACTCTCTACCTTTACCACCATTGTTACCACCATCCCTCCACCTCCACCACCATTGTCATTGTTGCCATAACTATCAACATCATTCTACTACTATTACCGTCACCACACCACCACCATTGCCACTCTACTTCAATCATCACAACTATCACTACCCTACTGCCGCCTTCAGCACCTCCACTATACCACAAACACAACCAGCACTGCCGCCACCACCGCGTCATCACCACAATAGAAAAATAATAAACTTCAGATTTAAGATTCTTATACCTATCAAAAAACTTTGTTAATTTGGCAGGCACTTAATATTTTGTGAAACTTATTTTCAGCTGAAACAATTCAGTATTTAGTTTTCAGTAATTAATTTTATCCAACACCACCTATGTTACTTGATTCTTGTAGTTTCATGGTGTAAGTTAACTGCATCTAGTAAATTTTGAATTCTCTCACTGAATATATAAATTGTCGAAATGCCTCAGTTGATGTGTTCTTCCAAATTGGGAACTACTTGAGCCCCTTTTGCATTCCATTTCCTGCACTTGTTTTGCATAGGAGAAGTCATGATTAATATGAATGAAATGGGGGAAATAGAACAAACTGGAATGCAAACATGTGGTAGTTGCATCTTATTTGAACCTAAGAGGGAGCTTTCTTATTTGTGGAGAACTATTCAATATCAGCATGCATATGCATGTGTGAGCCTTTTGTCGCTCCTTTTTGTTTAAAACGTATTAACTTTGTTCTTTATTACTTTATTTCCTCTCGTTCTTAATTTCTATTTTCCCTGTTTCAGCAAATATTGACCTTACAGCGAACTCTTCTGTCTCAGATTGGTCAGCACCCTTCCACTAGGTAAGTGATTTTGCTTCTAGATTTGTATGGTAAAGCCGTAAAGGAAACCAATTTCAAGCATGATAGTCTTATCATTAACCATACGTTTATCAGTGTAACTCAAGTATTACTCATATGGCAGTATGTAATTGTTGACACAATCAATATGTTTTTGTTACTGTCCAGATTGTTTGAACCATTGACTTTTCTAGCTTTTTATACCTGACGGCCATTTAGAATTTTGTTGATTTGTCTATTTGTAATTGCACTCTTGCAGGGAAGCAGGTCAAGGTGTGGGTGGGGCAGGTACGTTATCTTGGAACTTGAAATTCTAATTTCATATCTTTAACCATAATGCGCAGTGATTCTGAAATCAGAGTGTTTATTCATGGTAATGTGGTAATGCAAGGATTGCAGCTTGTCTTGCCTCATCTATCTCAAGTTGAAAATTCTTTAAGCTTATAAACTTTAGTTCTATGGATCTCCCAAGGTTGTGTTTGGATCAAAAGGGAAAAGGTGGAGAATCCAATAGTCCCGAACGATTTGATCCTCTAACTTTTCTATTTCCTTTTCCTTCACCAAATCCTTCATCCAAACACAGCCTATGAGCTTGAAGACTATTCCTTTGTAATCTTTTGTAAATCCTTCATCCAAACACGGCCTATGAGCTTGAAGACTATTCCTTTGTAATCTTTTGTTGAATGTGGAGGATTCTGGGATTGTGTCCTTCCATCAATTAATCACAACATGCCTAATCTGAAATCTCTGTTGATGCAACCCCTGGACCCCATATTTATTTTTGTCCAGATAAAAGAAAAAGGAAAACCGAATAAACAAGACAGAAAGATGGCATTATATGAAAATTTCCTGTCGTTTTCTTTAATTGTAGTTATTTAACTCAGAGTGACGTGACATTGTTCTCTCAATAGTAGGAACTGATGGCATGGGGTTGGAGATGTTGATGAACATGTTTGGCGGACTCGGGACCGGAAGCCCCGTTGCACCAAGCATATCCAATGGTGATTATTATTTCCTTTTCCCTCGAGCCTTCCGATCTATGTTTTTGTTGATTTGTTGGCTAAATTCTTTTGGGCTCAAGCCCAATGCTAATTCTAGGCCCAAGCTTAGGCCCAAGCCCACAGAGAGCCATTGTCAAAGTTGCAGCTTCTTCTCTTGTTGCTGCCGACAGAGGAAGTAGTCGGCCGAAAGAGGAAGAAGCCATTTGTCAACAATGGTGGCACCTCCCCTCCCAAGTCAAGCTTGGTGAGGTCATTGCTTAGGTAATTCTGTCCCTAGCCTTCTCTATATAAAGCTGCGCTGATAGAGTAAAATGGCAGGGCAGAAATTAGAGAAAAATCAGAGAGAGTAGAAGGGCAGAGAGCTTGAGAGAATTCTCTCAAATTGTATTTGTATTTGTTTCTCTCCATATAATAGAATTGCTGCCACCCGAGGACGTAGGCAACATTGCCGAACCTCGTAAATTGTGTGTTTGTGTTGGATTTGTTAGTGTGTGTTATCAGAATTTGTTATTCCGCACAACAATTGGTATCAGAGCCAAAATCGGCATTTCGGACCTCTGTAAAAGTGGTCGAAATTGATTTCTGATTGCACCACCTTGTTCGTCTCCTCGAGACGAAACTCTAGCATCAAACCGCGTCGAAATCGGACTCCGAACGAGCTCACACGAGTTGCGTGAAGTCGGTGACGCGTCTCTGTTTCGCGTCTCTGTAAATTTGAGGAAGACGAACTGTTCATTGGTAAATTACAGTTTCAACCCCTGAAGTTTCTGTTATTTACATTTTGGTCCTTAAAGTTTTGATAATTACAGTTTGGTCCTTATATTTTCTAAAATTATAGTTTGGTCCCTGTATTTTCTAGAAATTACAGTTTGGTCCCTGAAGTTTTAAAAATTACAGTTTAGTCCCTGTAATTTTTGAAAATTGTATTTTAGTCCCTGAAATTACTAAAAATTTCAGATTGGTCCCCAGGAGTTCTAATTTTGACAAATTGGCCCCACAAGTTTCTGATTGTGACAGATTGGCCCCAAAAGCTTTTGATTTTTTCAGTTAAGCCCTTCTTAAGTTTTTTCAGCATTCCGGACTCACCTGTGTGGTCAAAATTTGCATATTTTGATCCTATATATCAGTTTGGGTGGAGTTAAGTTGTTTAGATGGAAGAAGATAAAATCACTAGCACTTCCACTAGCACTTCCGGTAGCTCTGGGCATAGGACTACAATGTCCAATGCCAAATTTGAAGTTGAAAATTTGATGGGACAAATAACTTTGGCATGTGGCAATGCGAAGTTTTGGATGTCCTAATTCAACAGGACTTGGATATTACTCTGGAGGCCAAGCCAGAGGACATGTCAGAGAAAGATTGGGCAAAATTGAATCGCCAAGCTTGCGGTACGATCAGACTTTGTCTTGCAAAAGACCAGAAGTACTTTGTTATGAAGGAGACCTCAGCAAAAGAATTGTGGGGCAAACTCGAGAACAAGTACATGACCAAAAGCGTTGAGAACCGGCTCTATCTGAAGAAGAAACTCTTCCGGTTCCAATTCAAGCAAGGTACGTCAATGCATGAGCATTTAAATGCATTTAATAAAATTTTGGCTGATTTGCAAAATTTAGACGTAGAAATTGACGATGAAGATAAAGCTCTTTTATTGTTAAATTCCTTGCCTGATACGTATGAGCATTTGACTACTACTTTGCTGTATGGTAAAGATGAAATTAAGTTTAACGATGTTTCAAATGCTTTGATGAACAACGAGGTGAGAAAGAAGGATCAAGACGCTCACCGGGAATTAAGTTTAAATGCATTGACAGCAAGGGGTAGGACGAGTACCCGAAAATCTGGAGGGGATGGAAGTCTCGCTCAAAATCAAGGAAAAAATCATCCGAGAGACGGCAGCTTGCAAAGGATGAGTGTGCCTATTGTCATCAGAAAGGCCACTGGAGAAAAGATTGCCCAAAGATAGAAGGCAAAGAACCAAAAGCGAACATAGCTCATGATGCAGTCGAGAAAGATGACACTGCATTTACTGTTTCTTTGTCTGCTAGCCATTTTGACGAATGGATTCTAGATTCTGGTTATTCCTATCATATGTGTCCTCACAGGGACTGGTTCTCGAGCTTTGAAGAGCTCGATGGAGGAGTTGTTCTAATGGGAAATGACAACGCCTGCAAAACGATGGGAATTGGCACAATCAGATTGAAGATGTTCAGTGGAACCGTCAAGGTTCTTACTGATGTTCGCTATGTACCAGATTTGAAGAAAAATCTCATTTCATTGGGAGATTTTGATTCAAAGGGGTACAAGATTATCTTGGAAGGTGGAGTTCTGAAGGTTGTTCGTGGTGCTCTTGTTATTTTGAAGGGCACTCGTAGAGGAAATCTCTACTTCCTCGATGGGAGTACTGTCACAGGGAGAGCTGCTGTCTCCAACAGTTCAGACGAATCAGACACTTCCAGATTATGGCATATGCGATTGGGGCATACTGGAGAAAAAGCTTTGCAAACTTTGGTACGTCAAGGAGTTCTGAAAGGAGCTAAGACTGGAAAAATTGAATTCTGTGAGCATTGTGTGCTTGGCAAGCAGACAAGGGTGAAGTTTGGCACAACAATTCATCAGACTGAAGGCATTTTGGATTATGTTCATTCCGATGTCTGGGGGCCTTCTAAAAATGCATCTTTGGGAGGCTCACGCTATTTTGTAACCTTCGTTGATGACTTTTCTAGAAGAGTTTGGGTATACACGATGCGGCACAAGGATGAAGTCCTTGAAATCTTCTTGAAATGGAAGAAGATGATCGAAATCCAGACTGGTAGAAAGATCAAGAAGCTCAGATCTGATAATGGTGGAGAATACAGGTCAGATCCTTTCTTCGATGTTTGTTCCAAAGAAGGGATTGTCAGACACTTTACTATTAGGGGCACGCCGCAACAGAATGGAGTTGCAGAAAGGATGAACCGCACCTTAGTAGATAAAGTTCGATGTATGATATGCAATGCTGGTTTGAGCAAAGCATTTTGGGCTGAAGCAATAAACTATGCCGCACACCTTATCAACAGACTTCCTTCCACGGCTATTGAAGGAAAAACTCCTATGGAGGTATGGTCAGGAAAATGTGCTACTGATTATGATAGTCTTCACATATTTGGATGTCCTGCATACTTTCATGTAAAGGAAGATAAGTTGGATCCCAGAGCCAAGAAAGCTATCTTTGTAGGCTTTAGCACTGGGATAAAAGGATACAGACTATGGTGTCCCGAAATAAAGAAAATTATTAACAGTCGGGATGTTACATTTGATGAGTCTGTGATGCTGAAGAATTCTGAGAAAGAAAATCTGAGTCCTACATCCACCCAGCAGGTGGAGCTCGTGAGTCCTGTAGTGCCAACTAAAACTGTTCAGACAGTTGATATTCCTGACGAGGAATCTGATGATATCGACACTACACCAGATCTGAAAGAGGCTCAATCTTCACAACCAGCAGAATTCATCGCGACGAGTAGGCCACAACGAGTGATTCGTAGACCTGCTCGATATACTGATACTGTGGCATATGCACTTCCAGTGATTGAGGGAGTCCCATGTACTTACAAAGATGCTGTGCAGGGGACTGAAAATCCAAAATGGAAGAGGGCCATGGATGAAGAAATGAAGTCGCTTCACAAGAATCAAACTTGGGAGTTGGTGCCGCTGCCCAAAGGAAAGAAAGCGATCGGTTGCAAGTGGATATATGGCAAGAAGGAAGATACTCAGGGAGTCAGATTCAAAGCTAGATTGGTGGCTAAAGGCTACGCACAGAAGGAAGGAATAGACTACAACGAGGTATTTTCTCCTGTTGTGAAGCATTCGTCTATTCGCATTTTGCTAGCTTTGGTTGCTCAGTTTAATCTTGAGTTAGCTCAACTCGATGTCAAAACCGCTTTTCTACATGGAGATTTGGAAGAAGAGATTTACATGTCACAGCCAGATGGGTTCCAGGTGCCTGGAAAAGAACATTTGGCATGTCGGTTAAAAAAGTCTCGAAGACAGTGGTATAAAAGGTTTGATTTGTTCATGGACGAGCATGGGTATACACGGAGTCAGTTTGATCATTGTGTATATTTTCGCAAACTCCAAGATGGTTCCATGATTTATTTGCTCTTATATGTGGATGATATGTTAATTGCATCTAATAGCAAGGTGGAGATTGACCGATTGAAAGCTCAACTCAGTCGGGAATTTGAAATGAAGGATCTTGGCGAAGCCAAGAAAATTTTGGGCATGGAGATTAAGAGAGACAGAGTGAAAGGTACAGTTTGGTTGACTCAATCTCAATATCTGAAAAAGGTTTTACAGAGATTTGGAATTGATAGTTCAACTAAACCTGTTAGTACACCGTTGGCCTCTCACTTCAGATTAAGTGCTTCTATATCTCCTCACACAGAAGATGAGCGAAAGCATATGGAGAATATTCCTTATGCTAATGCTGTTGGTGCCTTGATGTATGCAATGGTTTGCACAAGCCCAGATATTTCACATGCTGTTAGCATGGTCAGCAGGTATATGCACAACCCAGGAAAAGTTCATTGGCAGGCCGTGAAATGGATTTTACGCATGGTTATCAAAATCGCGATCCGGATCGTAGGATCATACGATCCCACGATCCCAAATGGTTGAATCGATCCGGATCGATAAAATAATCGCAGTGGGATAGGATCGTGATAGGATCGTTACAGGATCGTATAGGATCGTATGGGATCGTATAGGATCGTGACAGGATCGTAGTAGGATCGTTAAAGAATATAAGAATAAGAATTCTTGAATTTTTGTACTTTTGAATTCTTATAAGTTCAAACTATTAATATTTTATATGTTACTTTAGGTGCATTCAAAGCAAATAAATCGTTGACACCAAAAAAAATTGAATGATTTGGTTTTTGTTTTGCACAATTTGAAATTGAGACAAAGGCATTTTTTTCTTTTTGATATTTTAACTATTTTTTATATAATTTATGTTCATTTTCTATTAATTTTGAAGTAATTATCATAAATTAAAAAAATTATTAACCTTTTGCTCCTATTTGGTAGGATCTTACGATTCTCGATCCGATCCTACGATCCGATCCGAAAGGCCCCAAAACGATCCAAGGTAGGATCCCGATTTTGACAACCTTGATTTTACGATATATTCACGGTACAGTCAATGTTGGTTTGAAATTTCAGAGGGACAATAAGTCAAGTCAATATTCAGTTGGGTATGTTGATTCAGACTATGCCGGAGATCTTGACAAGCGAAGATCCACCACTGGTTATGTGTTCACTATGGCTGGTGGACCAGTATGTTGGCGATCTACTCTTCAGTCTACAGTTGCTTTGTCTACTACTGAGGCAGAGTACATGGCAGTGACAGAAGCCTTCAAGGAAGCAATCTGGCTTCATGGTTTGATAAATGATTTGGGAATTGATCAGGAGCATGTTGATGTCTATTGCGACAGTCAAAGTGCGATTTGTTTGGCTAAAAACCAAGTTCATCATTCCCGCACCAAACACATTGATGTTCGGTTTCATTTTATTCGAGAAATTCTGAATGAAGGAGATGTACTGCTTGAGAAGATCAGCACCAAAGACAATCCTGCTGATATGTTGACGAAGGTCGTATCTGGAATCAAGTTTAAACATTATTTGAACTTGATCAATATTTCTGAGCAGCATGGCGCCTAACGGCGCATTGGTGGCAGCATCACTCAAGTTGGGAGAAGTTTCGCCAAGGTGGAGATTGTTGATTTGTTGGCTAAATTCTTTTGGGCTCAAGCCCAATGCTAATTCTAGGCCCAAGCTTAGGCCCAAGCCCACAGAGAGCCATTGTCAAAGTTGCAGCTTCTTCTCTTGTTGCTGCCGACAGAGGAAGTAGTCGGCCGAAAGAGGAAGAAGCCATTTGTCAACAATGGTGGCACCTCCCCTCCCAAGTCAAGCTTGGTGAGGTCATTGCTTAGGTAATTCTGTCCCTAGCCTTCTCTATATAAAGCTGCGATGATAGAGTAAAATGGCAGGGCAGAAATTAGAGAAAAATCAGAGAGAGTAGAAGGGCAGAGAGCTTGAAAGAATTCTCTCAAATTGTATTTGTATTTGTTTCTCTCCATATAATAGAATTGCTGCCACCCGAGAACGTAGGCAACATTGCCGAACCTCGTAAATTGTGTGTTTGTGTTGGATTTGTTAGTGTGTTATCAGAATTTGTTATTCCGCACAACAATTTTGTCACATACTCACCCTTTTATTTTATTTTTTTTCATTTTTAGTGCCCCCGGAAGAACTGTACGCCACTCAACTCTCACAGCTACAAGAAATGGGTTTCTTTGATACCCGAGAGAATATACGGGCGCTGATAGCCACTTCAGGGAATGTTCATGCTGCGGTGGAGCAGCTGTTGGGGGAACCTTGGTCAGTAGATAATAATCATTTGTTATTGTCCTATTCGTCTCAACATTTATTGTCTGTCGGGCCGATGAAATTGGTTTGGACCGGACTAAAGAGGATTTTTCAAAACCTATCTTGGCTATGAATTAAAAATATAGATTCGATGTTCTGAAGTTCTTGACATAAGGTATGATTGTGGGAATACCCTCTTCTATTCCCCACCCTAATAGTAAGGTGAGTGATATGTACATACACTATTAT
->URS000039472C misc_RNA from 1 species 
-TTGGAAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTACCGAGTGCGGGCTGCCTCCGGGCGCCCAACCTCCCACCCGTGACTACCTAACACTGTTGCTTCGGCGGGGAGCCCCCTAGGGGCGAGCCGCCGGGGACCACTGAACTTCATGCCTGAGAGTGATGCAGTCTGAGCCTGAATACAAATCAGTCAAAACTTTCAACAATGGATCTCTTGGTTCCGGCATCGATGAAGAACGCAGCGAACTGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAGTCTTTGAACGCACATTGCGCCCCCTGGCATTCCGGGGGGCATGCCTGTCCGAGCGTCATTGCTGCCCTCAAGCCCGGCTTGTGTGTTGGGTCGTCGTCCCCCCCGGGGGACGGGCCCGAAAGGCAGCGGCGGCACCGTGTCCGGTCCTCGAGCGTATGGGGCTTTGTCACCCGCTCGATTAGGGCCGGCCGGGCGCCAGCCGGCGTCTCCAACCTTATTTTTCTCAGGTTGACCTCGGATCAGGTAGGGATACCCGCTGAACTTAAGCATATCAATAAGCGGAGGAA
->URS00020CB488 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAGACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGTGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATGGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCAGAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGTGATGACGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTG
->URS0000A7B684 snRNA from 1 species 
-GTGCATGCTACAACTTCTTGAATCCACATGCACATATACTAATATTAGAACGGTCTAGAGAAGATTAGCAGGCTTCTGTAAAAGGAAGACATAAAATTTCTGAAGCATTTCAATAGCAT
->URS0000077F17 rRNA from 1 species 
-CGTGTAGGCGGCCAGATAAGTCCGCTGTGAAAACTCGAGGCTCAACTTCGAGCTGTCGGCGGAAACTATCTGGCTAGAGTCCGGAAGAGGAGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCCGTGGCGAAGGCGGCTCTCTGGGACGGTACTGACGCTGAGACGCGAAGCGTGGGAGCGAACA
->URS0000CF0C65 rRNA from 1 species 
-GTGTCAGCCGCCGCGGTAACACGTAGGAGGCGAGCGTTATCCGGATTCACTGGGCGTAAAGCGCGTGCAGGCGGTTTGGTAAGTTGATCGTGAAAGCTCCCGGCTCAACTGGGAGAGGTCGGTCAATACTACCGAACTAGAGAGTAGAAGAGGAAGATGGAATTCCCGGTGTAGTGGTGAAATGCGTAGATATCGGGAGGAACACCAGTGGCGAAGGCGATCTTCTGGTCTATTTCTGACGCTCAGACGCGACAGCTAGGGTAGTAAACGGGATTAGAGACCCCGGTAATCCTAGCCGTAAACGATGTGAACTTGGCGTCGGTGGCTTAAACACCATCGGTGCCGAAGCAAACGCGATAAGTTCACCGCCTGGGGACTACGGCCGCAAGGTTAAA
->URS00022DC966 tRNA from 1 species 
-GCTGCAATAGCTCAGATGGTAGAGCGGCTGCCTTGTAAGCAGCGGGTCGCGGGTTCGATGCCTGCTTGCAGCACCA
->URS0001ACB2BC rRNA from 1 species 
-AGAGTTTGATCATGGCTCAGATTGAACGCTGGCGGCATGCTTAACACATGCAAGTCGAACGAGAAAGTGGGCTTCGGCCCGCGATTAAAGTGGCGGACGGGTGAGTAACACGTAGGAATTTTTCCTGAAGTGGGGGACAACTCCGCGAAAGCGGAGCTAATACCGCATAATCTCTACGGAGCAAAGCAGGGGATCGCATTTCGGTGTGACCTTGCGCTTTAGGGTGAGCCTGCGGCGGATTAGCTTGTTGGTAGGGTAACGGCCTACCAAGGCGACGATCCGTAGCCGGTCTGAGAGGACGATCAGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGCCTGCGGGTTGTAAAGCACTTTCAGTAGAGAAGAAATGCTCAAGGTTAATACCCTTGAGAGTTGACGTTACCTACAGAAGAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAATACAGAGGGTGCAAGCGTTAATCGGAGTTACTGGGCGTAAAGCGTGCGTAGGCGGATATTCAAGTCGAGTGTGAAAGCCCCGGGCTTAACCTGGGAAATGCGCTCGATACTGGGTATCTAGAGTATGGTAGAGGAAAGTGGAATTTCCGGTGTAGCGGTGAAATGCGTAGATATCGGAAAGAACATCAGTGGCGAAGGCGGCTTTCTGGACCAATACTGACGCTGAGGTACGAAAGCGTGGGGAGCAAACAGGATTAGAGACCCTGGTAGTCCACGCCGTAAACGATGAGAACTAGACATTACCTTGCACTTATTTTTATCGAATGGTGAAAATAAGTGCGGGGTAGTGTCGAAGCTAACGCGTTAAGTTCTCCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCTACGCGAAGAACCTTACCTACCCTTGACATCCTCGGAATCCTGTAGAGATACGGGAGTGCCTTCGGGAATCGAGTGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCTTGTCCTTAGTTGCCAGCCTCACTTCGGTGAGAGGAACTCTAAGGAGACTGCCGGTGATAAACCGGAGGAAGGCGGGGACGACGTCAAGTCATCATGGCCCTTACGGGTAGGGCTACACACATGCTACAATGGGTAGTACAGAGGGTTGCCAAACCGCGAGGTGGAGCTAATCTCACAAAACTACTCGTAGTCCGGATTGAAGTCTGCAACTCGACTTCATGAAGTCGGAATCGCTAGTAATCGCGAATCAGAACGTCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGAATTGTACCAGAAGCGGGTAGGATAACCTTCGGGAGTCCGCTCACCACGGTATGATCCATGACTGGGGTGAAGTCGTAACAAGGTA
->URS000199E147 lncRNA from 1 species 
-GGAAGTGGTTCTTAGAGGCAGTGTGTCTCCCTCTGGTGGCAGAAAAACTGGACCACAGGCTCGAGAGCAAACCACAGTCCCCTCTCGCTGCGTCCAGCTCTGTTATATAAAGCAAAAGAAACGATTTAGGAAAATAAAGACAAAGCGTCTCCTTTATAGACATATGAGCACCAATGAGCTGCGGCCTCACACCGCTGAAGGTAAATTTGTCCTACAAAGTTCAAGACTTCCTTTAGGTGACCTCAAATAAATGGAAAAGCTGTGTCTCACTTACAGAGAAGGCTTTTCCATGTTGTTTGTAAAGTAAATAACAGTCAGTGACCTAAACACGCTCACCTTCACCACGGATGCACAGTCCTCTGGATTTTTTACTTGCTAGCAACAAAATACTGAAAACATAGTGAGCTCATCTCCATGACAATGTATCAAACCTAAACCAACACATAAACACTTTAACACAGTACATTTGATAAAGCTCTAGATTTAATGCACATTCATGGGATTTTCTTTTATTAAACCTCTTATGCAGTCATATATAATAAAGCACTAACCTGAGGCTGATGCCATAAAGACTCCTGCCTGCTAGATACAACATGCCCGACTCCTTCAGCTCAGCCACTGCTTCAGGGGAGAACTTCACAACACAATTTGCATATAGCATAAGATCAGCCTTTTACTTTGTGCATGATGCAAACTTTAGTTTTCACTCTTTATTCAAGTAACAGGCCAGATGGCAAGAAAATCCACAGAGAGACACGGCAGCGGCACACCTCGCTTCCATGTTGTGACAACAGCAGCTTGTTTTAATGCTGAAACCTGCCCCTTGTAGGTGTGCACCAGGTAGGAGTCCTCTTTAAGACCTTCAGGTCTTTCAGGGAGCAGATGAGACACAGATGATCATGAGGCGGTTTTTCCGAGCACACCGGGACGAGGACTTCAGTCAGATCCAGTATCTGACGGCCAAGTGCACCCGCTTAGCTCATGACAAAGCGGTGTTGGACAGAGAGTTTCTGGTGTCCCGAGAGAGGGAGAGAAGGCTGCAGAATGATCTGGAAGCTGTGACCGCCCGACTCCTCGAGCAAGACCAGCTCAATATGGAACTCAGGATGAACCAGACCCAACTCATCAGCAGGATCCAGCAGCAGCAGGACCTGGTGAACCTGCTTCGGCAGCGCGTGGTCCTGCTAGTGGAGGCGAGCTCCCGGGATGCAGAGCTACTGCGGCAGGTCGGCGCAGAGCTGCTTTGCCTGCAGAGCTCTGAGGTGAAGCTGGAGGGCCTGGTGGAGGAGCTGCAGGCTGAGGCCCAACATAGAACTGAGGTGGCAGAAAATCTCCAGACAGAGCTGTATGCTGAGGCCCGGCACAGAGCTGCACTCACTGAGAGCCTCCACGCAGAGCTGCGCAGTAAGACAGTGGAGCTGGAAAAGCTAGAAGAAACTAACAGGACGCTGACAGAAGAGCTGACGGATCTGCGCAGAACTTATCAGAAGGAGGTGAGAGAACTGCAGCAGGAAAATGAGGGAAGCCTGAGGAAACTTCAGGAGACGGCAGAGCAGTTCGAGTGGCTCTGTCAGCAACAGCGTTACTGGATGTCTTGTGTGAAGAGGTTCAAAGACTGCCTCATGGAGGAGAGAGAAGCTCTGCTGCGACAGGTCAGCAGGTTGGAAAAGAAAGCTGAGAAACTAAAGCGTTCACACGACGGCAGTCCAACACGGAGGCTTGTCTGCCCCCTTCAGGACGCCGAGAGCTGTGACAGCAGTATAACATCATGGGAGGCAGATGCAGTGACCAACCTGGAGTCTCAGGTGGAGAAGTCAAACGTGCTGTATGAAGAGCTCCTCGACCAGGCAGGGAGCCCTATCAACGGATACCAAAAACCTCCATGAGGACAGAAGCCTGGATGTCTTTGCTTTCTTTTCTCACCTTCTGCAAGCCAGGAGATGCAATGTTTTATGTGTTTGTGGTTAGCTTACCTTCCAGTCATTGTTTTGAAAAACCAAACACCCTTGGAAAAACACACCCGTGAAGCCACACACGCATTGTTTTGTTTCCACTATTGTTCATTGTGATATATGACCGAATTAAAATACAATGTGCTCCTGTCCCGCTTTTGGTGTCACACATGCACATCACATGTGCCTCGAGTCTGTCTGGTCACATTTTTCAGTAATTGTCCATTGTTCAAACCTTGTAATCAACACCACTAACAAGAGCACAAGCACCTGCAAATGTTCTCTTTTGTTGTTTTGCCAATGAAACGTTGCAGGACAACCAGCAGCTGGCGTGCAGAGGAAGCAACAAATGTTCTTTTCAACAAAATGAAGCTATACTGATTATCCCCCCACTGGTACAGCTTGACTCTGATGATCAGATCTCTTCATTCATCAGTTTGCATGTGGCTCACATTAAACACAGTGACTCAGACGCTTTATCATATGTGAACCATATGATACACACATATTGCAAACGCAGTTTACACACGGTGAGCCAAGACTTTTAAAGTATGCATTGTGTCACACTACAAACATTACACTGCAATCAACATGAGGAGCTACACGTTTATTCAGGACTACAGCAAACTTTCAACATGCATAAGAAATCTTAACATCACTAAACCATTAATGACACTGGAACCATCATTATATTTCATCGGTGGTGCTGGGACAACATTTTTTTCTTTGCCCACCTTAAAGTTAGCATGACAGGGGTTCGTTTGACCAACAGTGGACAAGAAGGCCTGTGTGACTTAAGCTTTGACTCCATGATCAATAGGCTTTACACAAACTACACCACAGTCTCATAGCTTTAATGGCACGACCACCAAGCTCCTGCACTCAGTCCGATGATGCTGAATAGCAAACATTTGTTTGCAAATATCAAACATATCTAAAACTTTGGGTATGTTGCTACATTTTATGTCTAAATCTCACAACCAAAAACCTGCTGACTTCATGATGAGTGAACCATTACAGTTCTTACTGGTTTCAGGGCTTGATCCAGTATTTGAGGTAATCAGTTTTTAGCCTGGAAATATTGCTAATTCTCTATGTGAAATAAAAATAATGCATATATATATATGTTCATAACTTACATGATTAAGTTATGTTGGCCCATAGCCTATCAGATCATAAATTTACATGGTGTATTGCAGAGGAGAGATAGTTGGGCATTAACCTATGAACTTTGTTATAAAAATGAAATTCCACATTTCAGAACTGGAGGACATATTGCGACTAAATCACACCAGGACCACATTCATCTTAGAGCTCTGCCTTTGCTTCATTGTAAAACCCCCATATCGAAAGGTTTCTTGACTCTTTTGCTTAGTTGTTATGGTAACAAAGTGACAGAAAAGGCAGTGACTGAATTGGTAGTTTATGCTACCGTAGCATTCTTCCTTTTGCCAAATGAATGTTTGCTCTTTAAAAATGAATTAATAACAGGTTACAAGCCTGTCTGACAGCAAATAAAGCTCTTAACATCCACCTCAGTTCTATGAAGCAGAACTTTGTTTTGTCCAGGTAACTTTAGGGTAACCCTGG
->URS000201C513 misc_RNA from 1 species 
-GATGAAGAACGTAGCAAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCGCCAGTATTCTGGCGGGCATGCCTGTTCGAGCGTCATTTCAACCCTCAAGCACAGCTTGGTGTTGGGACTCGCGTTAATTCGCGTTCCTCAAATTGATTGGCGGTCACGTCGAGCTTCCATAGCGTAGTAGTAAAACCCTCGTTACTGGTAATCGTCGCGGCCACGCCGTTAAACCCCAACTTCTGATTGTTGACCTCGGATCAGGTAGGAATACCCGCTGAACTTAAGCATATCAATAAGCGGAGGA
->URS00025EF403 lncRNA from 1 species 
-GTGTTCTTCACTTCATGATGGAAGGGCTACTGACCCAGAGTGGAAAGTTTAGCTGGTGTTTTGATCAGGATTTCTTACCTTTTTCTTCATTAGAGAGATTCTTCTTGCTGCTGTCCTGCTTCAGAGCTGCAAGGAACACTTGGGAATGACTAAAGCGGTGTCTGTGCTGGAGTCAGAGGAGTGGCAGAGCAGGAGGCACATCTGTCTGTCGCCTTGCCTGCTGAACAACAAAGGCAGTGCTTCATAGCAGCGTGGCTTTTGGATAGGTAGCCCAAAAAAAGCAACCGTGATCAGAAATCTGGGTCGTTGTGCTTCCCCTGAGCAAGCAAAGTTAAAGATAGCTTGGGAGACGTTTGCTGCTTCTCCTGCCTATTCCTGCTGACATCCGTGGGGATTTGCTGGCATAGTGAGCTACAGGCTGGTGCACTTCAGAAGAAAAGACTCTTCATCATCCGTTCCCCAGCTAGTATCCTGGGTGGCTCTCTTCTGCTGTGTTTCTCCACCAGTTGTGGTGCCCTACAGTGTGTAACAATTCTTGTGGCTTCCAAGTAATTATTTTCAAACGCATATGAAGTAACTGAAACTGTCTTGTAAGAAGAAAAAGAAGTTCCATGAAATCTGATGCTGTGTTTAGAGGATGTTGGTGTGTTCTCAGCAGGTGCGCTTTGCCTACATGTGGATCCTCAGGGTGGAGTTTTTAATTGTTAAATGATATATGACGAATCAAATAGCACGTACAAAAGACAAAGGAAAAGAAGACGAGAAGGTAGAAAATGGGAATTCAGGGACTGGTAAATGTTCTGCACACCAACTCACAGAGTGCATTTCTAGTTTGAATGCCAGTGCCTTGCATCAGCTGGAAGAATAAGTTGATAGCTTCCTGATGCTGCTGTTCATTTGCTTTTTATTTGAGTCTGTTTTCACATGGATTATAAAGTACTGCAATCCTTTTCCTGTAAGCCTGAATGCAGAATTACATCACTTGTTTGTATGCAGTACATAGAGCTAAAGTCTCCTGGGAAATGACAAGTCGTTAGCCTGACTACTTAATCATACTGTGATATGAAGAAAAATATTTGTAACTTCACAGTCTGCCATAGAACATCTTCATGCTTTATAATGGTGTGCTCCAAATGAGAAACTGCTTAACCTTGCTTTGCAGTTCTCTCATTGTTCTGGAATTGTTGTTTGAGCAATGAAACTTAATTTGCAGTGCAGAACTATTTTAATAATAAAGAACACTTGATTTCAT
->URS0000CAA0FA rRNA from 1 species 
-CCTACGGGAGGCAGCAGTGGGGAATCTTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGGAGGAAGAAGGTCTTTGGATTGTAAACTCCTTTTCTCGGGGAAGAGTAGGGACGGTACCCGAGGAATAAGTCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTTTCAAGTTCGACGTGAAAGCTCCCGGCTCAACTGGGAGAGGTCGTTGAAAACTGAGGAACTTGAGGCAAGGAGAGGGGTGTAGAATTCCCGGTGTAGTGGTGGAATGCGTAGATATCGGGGGGAATACCAGTGGCGAAAGCGGCACCCTAGCCTTAGCCTGACGCTCAGGTGCGAAAGCGTGGGGAGCGAACGGGATTAGATACCCTAGTAGT
->URS00005B6C50 rRNA from 1 species 
-TACGTAGGGGGCGAGCGTTGTCCGAATTTACTGGGCGTAAAGCGCGCGTAGGCGGGTCAATAAGTTGTGGGTGAAATGCCGAGGCTCAACCTCGGCGCTGCCTGCAAGACTGTTGGTCTTGAGGTATGGAGGGGAAAGCGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCGATGGCGAAGGCAGCTTTCTGGCCATATCCTGACGCTGAGGTGCGAAAGCCAGGGTAGCGAACGGGATTAGATACCCCGGTAGTCCTGGCCGTAAACGATGGATACTAGGTGTTAGAGGTATCGACCCCTCTAGTGCCGGAGCTAACGCATTAAGTATCCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATACGTCACTAACCGTAGGACCTTACCCAGGCTTGACATCTGGAGTAAGTCCATGAAAGTGGCACCCCTGTATGGTAACATACAGCTCCAAGACAGGTGTTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCATTCCATGTTGCCAGCGTAAAGTCGGGAACTCTTGGAAAACTGCCCGTGTAAGCGGGAGGAAGGTGGGGATGACGTCAAGTCAGCATGGCCCTTACGCCTGGGGCTACACACGTGCTACAATGGACGTGAACAAAGGGCAGCGATACCGCGAGGTGGAGCTAATCTCACAAACACGTTCTCAGTTCGGATTGCAGTCTGCAACTCGACTGCATGAAGTCGGAATCGCTAGTAACCGCAGGTCAGCTAAACTGCGGTGAATACGTTCCCGGGCCT
->URS0001C9C972 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCCGAGAGGGTGGCCGGGCCCCATGGGCCCTGGGGACGGGCCAGGGCGCTACAGGGGGCAAGGGGGGGGAAATTTTGCCAAAGGGGCGGAGCCCGTAGAGAGCAACCCCGGGGGGGGAAGGCCGCCTTTGGGGTGGAAAACCCCTTTCGCCTGTACCGAGGCGGGGGGGCGGTTATTGGTGAAAAAGCCCCGGCTAACTTCGTT
->URS0001CC6C7B rRNA from 1 species 
-GTGAACGCTGGCGGTAGGCCTAACACCTGCACGTCGAACGGCAGCACAGTAAGAGCTTGCTCTTACGGGTGGCGAGTGGCGGACGGGTGAGGAATACATCGGAATCTACTTTTTCGTGGGGGATAACGTAGGGAAACTTACGCTAATACCGCATACGACCTACGGGTGAAAGCAGGGGATCTTCGGACCTTGCGCGATTGAATGAGCCGATGTCGGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACAATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATACCGCGTGGGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTGGGAAAGAAAAGCAGCAGGTTAATACCCCGCTGTTCTGACGGTACCCAAAGAATAAGCACCGGCTAACTTCGTG
->URS0002105CC3 rRNA from 1 species 
-AGTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGGCAGCACAGTAAGAGCTTGCTCTTACGGGTGGCGAGTGGCGGACGAGTGAGGAATACATCGGAATCTACTTTTTCGTGGGGGATAACGTAGGGTAACTTACGCTAATACCGCATACGACCTACGGGTGAAAGCAGGGGATCTTCGGACCTTGCGCGATTGAATGAGCCGATGTCGGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACGATCCGTAGCTAGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATACCGCGTGGGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTGGGAAAGAAAAGCAGCAGGTTAATACCCCGCTGTTCTGACGGTACCCAAAGAATAAGCACCGGCTAACTTCGTG
->URS00025E055D rRNA from 1 species 
-ATGAGTTCCTTGCCCTGTGGATGCAAGTCACGGACATTCATCTTGACTGAGATGCCACAGACTCAATCTCCCGGTCTTGGGAAACTAGTGGTGACTTCTCTACCAAGACAACATACATGGCGAAGTTTTGGAGAAGACAAGTGTTGCCCAGGCCTGCCTTCACTTCGAAAGCAAGGGCCCCGTTGCAGTGCCATTTTTTTTGCATGGCTTGCACTTCTAACAGATGTTGGACTTCCGACCGCCTGGCATGCCGTGGCTTGGATCATCAGGAGAGTTGCCCTTTCTATGCATGGGAGAGGAGAAAACAATCGAACACATACTGCTTTAATGTGTCATCGCAAGGGAGGCGTGGACCATCATATGTCGAGCTCTAGGCAAAATGGATTGGGTACCAGAGATAGGATCAAAGTTGGTGGATTGATGCACAAACAAGCTTAG
->URS0000DB583F tRNA from 1 species 
-GGGTCCATAGCTCAGTGGTAGAGCATTTGACTGCAGATCAAGAGGTCACCGATTCGAACCCGGTTGGGCCCT
->URS0002538569 rRNA from 1 species 
-ATGAGCAGCCGGGCTCCCAAGTTTATGCAGAACGTGCGCAGCTTCCCCGATGGTAAGCGCAACTGCTACAAGATTCGGTCCCTGGTGCGCGGGCTCAAGTACATCATCCGAGCGTGGTTCTTGTACGGCAACTACGACGGCCTTAACACATCGCCCATGTTTGACCTCTACATCGGCGCAAACTTTTGGACGACGGTGAACATGTCAGGGGGGCCATCGGACACTTATTTAACTGTAGAGGCCATGGTGGTCGTGCCGGACGACTACGTGCATGTCTGCCTGGTGAACACCGGCGATGGGACGCCGTTCATCTCGGCCCTGGAGCTGAGGCCGCTTAAGAGCATGCTCTATCCACAGGTGAGCCCGAAGCAGGGCCTGAACCTGCACCGCAGGTTAGACCTCGGCACGGGGAGTAAAACGCGCGTAATAAGGTACCCTGATGACCCACATGACCGAATATGGAGACCAGTGGATACCACCGCAGAATACCCCAGCATCACAACGTTTAGAAGGGTGCAGAACCCAAACGATGACCTTTTCCAGGTGCCGACGGAGGTGATGGAGACAGCGATGACTGCCCGGAACGCCTCCGCGCTCATAGAGATCACCATGCACCCTCAGCCTCAGCGCAACAACCCGTCGCCCGGGTACATTGCTGTCCTGCACATCGCGGAGCTAGGCATTCTCAGAGGCAACGCCGTGCGCCAGTTCTACGTCAACGTCAACGGCAAGCGATGGTACCCAGATGCTCTCACACCGAAATACCTCTCCAGTGGTGCCATCTACGGTGCCATTGTTCCCGATCAACAAGGCACCATCACCATTTCCATCGAAGCCACTGCCGGCTCGACACTGCCGCCGATTGTCAATGCTTTCGAGAGTTTCTCCGTCATGCCCACCACTAAAGTCGACACCGAGTCCGAGGAGGGTACGCCCTCGCCCACTCCCACCACTAACGCCGGGTCCAAGGATGGTAACTTCGGCTCCAACAAGTCCGAGGATGACGTTTGCATCGGTGGCAGTTCATGCAAGAAGAGTAATAAGCTTGTCCTCTACATAGCCGTCCCTATAGCCGGGCTTGTGGTGATAGGATCGGCGGCACTACTAATCTTTTGCTTGCTAAGACGGAAGAAGCAAGGATCAAGATGA
->URS00008935E5 rRNA from 10 species 
-AGTCGAGCGAATGGATTAAGAGCTTGCTCTTATGAAGTTAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCCATAAGACTGGGATAACTCCGGGAAACCGGGGCTAATACCGGATAATATTTTGAACTGCATGGTTCGAAATTGAAAGGCGGCTTCGGCTGTCACTTATGGATGGACCCGCGTCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGCTTTCGGGTCGTAAAACTCTGTTGTTAGGGAAGAACAAGTGCTAGTTGAATAAGCTGGCACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGCGCGCGCAGGTGGTTTCTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGGAGACTTGAGTGCAGAAGAGGAAAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGAGATATGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGTCTGTAACTGACACTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGAGGGTTTCCGCCCTTTAGTGCTGAAGTTAACGCATTAAGCACTCCGCCTGGGGAGTACGGCCGCAAGGCTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCTCTGAAAACCCTAGAGATAGGGCTTCTCCTTCGGGAGCAGAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGATCTTAGTTGCCATCATTAAGTTGGGCACTCTAAGGTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGACGGTACAAAGAGCTGCAAGACCGCGAGGTGGAGCTAATCTCATAAAACCGTTCTCAGTTCGGATTGTAGGCTGCAACTCGCCTACATGAAGCTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAGAGTTTGTAACACCCGAAGTCGGTGGGGTAACCTTTTGGAGCCAGCCGC
->URS0000FCD8C1 rRNA from 1 species 
-TACGTAGGGTGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTTGTAGGCGGTTTGTCGCGTCTGCCGTGAAAGTCCGGGGCTCAACTCCGGATCTGCGGTGGGTACGGGCAGACTAGAGTGATGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGGAATGCGCAGATATCAGGAAGAACACCAATGGCGAAGGCAGCTCTCTGGGACGGTACTGACGCTGAGACGCGAAAGCGCGGGGAGCGAACAGG
->URS000055AC24 piRNA from 1 species 
-TGACAAGTCCCAAGCGATAATACAGGCTA
->URS000027137F rRNA from 1 species 
-CCTGGCTCAGGACGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGGAGTTCTTGTGATTGAAGCTTCGGCAGATTTCACTTGAACTTAGTGGCGGACGGGTGAGTAACGCGTGAGGAACCTGCCTTCCAGAGGGGGACAACAGTTGGAAACGACTGCTAATACCGCATAATGCAGCGTGGTCGCATGACCGTGCTGCCAAAGATTTATCGCTGGAAGATGGCCTCGCGTCTGATTAGATAGTTGGTGAGGTAACGGCCCACCAAGTCTGCGATCAGTAGCCGGACTGAGAGGTTGAACGGCCACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGGGGCAACCCTGACGCAGCAACGCCGCGTGAAGGAAGAAGGTCTTCGGATTGTAAACTTTTGTCTTATGGGAAGATAATGACGGTACCATAGGAGGAAGCTCCGGCTAACTACGTG
->URS0001F1045E rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCCTTACACATGCAAGTCGAACGGCAGCACGGGTGCTTGCACCTGGTGGCGAGTGGCGAACGGGTGAGTAATACATCGGAACATGTCCTGTAGTGGGGGATAGCCCGGCGAAAGCCGGATTAATACCGCATACGATCCACGGATGAAAGCGGGGGACCTTCGGGTCTCGCGCTATAGGGTTGGCCGATGGCTGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGAAAGCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTCGGAAAGAAATCCTTGACTCTAATACAGTCGGGGGATGACGGTACCGGAAGAATAAGCACCGGCTAACTACGTG
->URS00007CE013 rRNA from 1 species 
-TTGAACGCTGGCGGCATGCTTTACACATGCAAGTCGAACGGTAACAGCACTTCGGTGGCTGACGAGTGGCGAACGGGTGAGTAAGACATCGGAACGTGCCTGGTAGTGGGGGATAACTACTCGAAAGAGTAGCTAATACCGCATGAGATCTAAGGATGAAAGCAGGGGACCTTCGGGCCTTGTGCTACCAGAGCGGCTGATGGCAGATTAGGTAGTTGGTGGGATAAAAGCTTACCAAGCCGACGATCTGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGCAGGATGAAGGCCTTCGGGTTGTAAACTGCTTTTGTACGGAACGAAAAGCTCTCTTCTAATACAGGAGGGTCATGACGGTACCGTAAGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTTTGTAAGACAGAGGTGAAATCCCCGGGCTCAACCTGGGAGCTGCCTTTGTGACTGCAAGGCTGGAGTGCGGCAGAGGGGGATGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAACACCGATGGCGAAGGCAATCCCCTGGGCCTGCACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGTCAACTGGTTGTTGGGAATTAACTTTCTCAGTAACGAAGCTAACGCGTGAAGTTGACCGCCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGATGATGTGGTTTAATTCGATGCAACGCGAAAAACCTTACCCACCTTTGACATGGCAGGAACTTACCAGAGATGGTTTGGTGCTCGAAAGAGAACCTGCACACAGGTGCTGCATGGCCGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGCCATTAGTTGCTACGAAAGGGCACTCTAATGGGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTATAGGTGGGGCTACACACGTCATACAATGGCTGGTACAAAGGGTCGCCAACCCGCGAGGGGGAGCCAATCCCATAAAGCCAGTCGTAGTCCGGATCGCAGTCTGCAACTCGACTGCGTGAAGTCGGAATCGCTAGTAATCGTGGATCAGAATGTCACGGTGAATACGTTCCCGGGTCTTGCACTCACC
->URS00018E2463 rRNA from 1 species 
-GTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCAACGCCGCGTGAAGGAAGAAGTATTTCGGTATGTAAACTTCTATCAGCAGGGAAGAAAATGACGGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGTAGGTGGTATGGCAAGTCAGATGTGAAAGCCCGGGGCTCAACCCCGGGACTGCATTTGAAACTGTCAGACTAGAGTGCAGGAGAGGTAAGTGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCTTACTGGACTGTAACTGACACTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGAAACCCCAGTAGTCC
->URS000076782D rRNA from 1 species 
-CGGATTTCTGGGTACCGGTTAATGCGTAATATCAGAAGAACACCCATGGCGAAGCAGCCAACTGGGCCAATACTGACGCTGAGGTACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGTCTACTTGTCGTCGGGAGGGCTAAACCTTTCGGTGACGGAGCTAACGCATTAAGTAGACCGCCTGGGGAGTACGGCCGCAAGGTTGAATCTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAAAACCTTACCTGGCCTTGACATCCTGCGAACTTTCTAGAGATAGATTGGTGCCTTCGGGAGCGCAGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCTTTAGTTGCCAGCACGTTATGGTGGGAACTCTAAAGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTATGGCCAGGGCTACACACGTGCTACAATGGTCGGTACAGAGGGTAGCCAAACCGCGAGGTGGAGCCAATCCCATAGAGCTGATCTTAGTCCGGATTGCAGTATGCAAATGGACATGTCATGAAGTCGTCCTCTATAGTGATTCGTG
->URS0002117D6C rRNA from 1 species 
-ATTGAACGCTGGCGGCGGGCCTAACACATGCAAGTCGAACGGTAACAGGAAGCAGCTTGCTGCTTTGCTGACGAGTGGCGGACGGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACTGGAAACGGTAGCTAATACCGCATAACGTCGCAAGACCAAAGAGGGGGACCTTCGGGCCTCTTGCCATCGGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAACGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGGGGAGGAAGGGAGTAAAGTTAATACCTTTGCTCATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTG
->URS0001747A8B rRNA from 1 species 
-AGTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGATGAGTGGAGCTTGCTCCACCCTTCAGCGGCGGACGGGTCAGTCATGCCTAGGAATCTGCATGGTCGTGGGGGACAACGTTTCGGAAGTAACGCTAATACCCATACGTCCTACGGGAGAGAGCAGGGGACCTTCGGGCCTTGCGCTATCAGATGAGCCATGGTCGGATTAGCTAGTAGGTGAGGTAATGGCCCACCTAGGCGTCGATCCGTAACTGGTCTGAGAGGATGATCAGTCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGTCTTCGGATTGTAAAGCACTTTAAGTTGGGAGGAAGGGCAGTAAGTTAATACCTTGCTGTTTTGACGTTACCAACAGAATAAGCACCGGCTAACTTCGTGCCAGCCGCCGCCGTAACAC
->URS00004DFF5E rRNA from 1 species 
-GCAGCCGCGGTAATTCCAGCTCCAATAGCGTATGCTAATGTTGTTGCAGTTAAAAAGCTCGTAGTTGGATTTTTAAGGGTGTCTGCTTCTAGTGTCCTACGTGACTCTAAAGTTGCAGACTCCCCTTATTTTGCCTCAGTGCTCGGTTGGGATTCATTTCTCGATCGGGCTTCCGGGGCGTGTTTACTTTGAGAAAATTAGAGTGTTCAAAACAGTCTTGTGATTGTATATCATAGCATGGAATAATAACTGATGACGTCGGTCATTTTTTGTTGGTTCGGATGGCTGAAGTAATGATTGATAGAGTTAGTCGGAGGTATTAGTATTTTATCGTTAGAGGTGAAATTCATGGATCGGTAAAAGACTAACAACTGCGAAAGCATTTATCTAGGATTTGCTCTTTGATCAAGAACGAAAGTTGGGGGATCGAAGACGATCAGATACCGTCGTAGTCTCAACTATAAACTATACCAGCTAGGGATTGGTGGGCGTTGCTTGACCTCATCAGAACCTTATGAGAAATCAAAGCATTTGGGTTCCGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACAAGTTGTGGATCCTGTGGCTTAATTTGACTCAACACGGGAAAACTTACCAGGTCCAGACATAGCAAGGATTGACAGATTGATAGCTCTTTCTTGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGTTAACGAACGAGACTATTACCTGCTAAATAGTATGCCCGGGCCTTTGGCGCGGGCTTACTTCTTAGAGGGACTAGCCATCTGTTAAGTGGCTGGAAGTTAGTAGCAATAACAGGTCTGTGATGCCCAAGGGCGATTCGTTAAAACTGCAGGA
->URS00008EA5F3 rRNA from 1 species 
-GGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCGACGCCGCGTGAGGGATGACGGCCTTCGGATTGTAAACCACTGTCGCGAGGGACGAAAATCTGACGGTACCTCGAAAGGAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAATACAGAGGGTGCGAGCGTTGTCCGGAATCACTGGGCGTAAAGGGCGCGTAGGCGGCCGGGTGAGTAGGGGGTGAAATCCCACAGCTCAACTGTGGGGCTGCCTTCTAGACTGCTTGGCTCGAGCACGGTAGAGGCTGGTGGAATTCCCGGTGTAGCGGTGGAATGCGTAGAGATCGGGAAGAACATCGGTGGCGAAGGCGGCCAGCTGGGCCGTTGCTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAA
->URS0000EF886C tRNA from 1 species 
-CGGCAATTAGCCGGTCTGAACAGCAGTTCTCAACGCCCTGTTTGAACTTTCTCCAGTACCAATGGTCAGAGTCGTCGTACTTTTCAGGAAACAGCAGACTTTCTGGGTTGTTTCTGAAGAACATTCCACGACCTTGCCTATCAATGCCAT
->URS0000B48067 misc_RNA from 1 species 
-ATCGCCTCCAGTTCAACCCACTGCTTGCTTCCTTATTGCCTATGCCCATCTCCCTACCTGCTCCCATTGGATCTGGGGCGCTGCCAAGTCTCAAATCCTCTTCTTTTAGCTAAGAGTTGTGTAGTTAGGGCCATAGAGAACAATGTTGTCGGTCACTAATCACTGCCCAATTTAGTTGCATTATAATTTTGAACCCGTGTTCAGACCCAGGTTGGTCCTGCCCTGCCGTCCTCGTCCTCACCATATTAGTCCATTTGGATTTTATTTGCCAGTACAAGTCATGGTCAAACTCGAGTCAAACTCTTCCTAAGCCTGTCCAAACAAGCTGTGCCAAAACAAGGACCAATAATCTCAATTTTCCCATAATACCCTCCCTTCAGACGACGTCGTTTCCTTCATTGCCTTTTGATATGCTGTGACCACATCACGTCACCTCTACTGCTCTCTTTATAAAAAGCCTAAACACGTGCTTCAACACCGCGATCCCGGAACACGGCCCTTCAGTGGCATCCTCGTTATTTGCAATCTTTTCGAGGTCAAATTCCTTACCTCTCTGTGTTTAGCTCACCTTCCCCGACCCACCCTTTCATATAACTACTCTTGCTGCCTCTTGACCAGAAACTCAGAACAAAACTTGAAGTCCGGTTCACCCTGTTTGCCTCTCGAGAAAATTTCTAATCGAGAAGAGTTTCTATCGATTAGCTTTTCTGGCTCTGTTGCAGTAGTAGTGTTGAGGGAGCTTCGTCGGAAAATGACGTCGGGGACGAGAATGCCGACGTGGAAGGAGAGAGAGAATAATAAGAGAAGAGAGAGGAGAAGAAGGGCGATCGCGGCGAAGATCTATGCTGGACTGAGAATGTATGGAAATTACAAGCTCCCTAAGCACTGCGACAATAATGAAGTCCTTAAAGCTCTCTGCAACGAGGCCGGTTGGACAGTTGAAGAAGACGGCACCACTTACAGAAAGGGCTGCAAACCTGTCGAACGTATGGACATTATTGGAGGGTCTGCGTCAGCAAGTCCGTGCTCATCCTATCACCCAAGTCCATGTGCGTCTTATAATCCAAGTCCTGGATCATCTTCTTTCCCTAGTCCTGTTTCATCCTGTTACACTGCCAATACTAATGGTAAGGCTGATGCCAATTCCCTCATCCCATGGCTTAAAAACCTCTCATCTGGCTCATCATCAGCCTCATCCAAGCACCCTTACCATCTCTTCACTCACAGTGGTTCCATAAGTGCTCCAGTCACCCCTCCATTGAGCTCCCCAACTGCTCGAACTCCGCGTGCCAAAAATGACTGGGATGACCCGGCGGCTGGTCCATCATGGGCAGGTCAGAATTATTCGTTCCTGCCCTCATCTATGCCGTCATCTACCCCACCAAGTCCTGGCCGTCAGGTCCTGCCTGATTCAGGATGGCTAGCTGGTATTGAAATTCCCCTAAGTGGACCATCATCACCCACATTTAGCCTTGTTTCACGGAACCCATTTGGCTTCAGAGATGAGCCTCTATCTGGTGCTGGATCGCGAATGTGGACTCCTGGGCAAAGCGGGACATGCTCTCCTGCTGTTCCTGCAGGTGTTGACCAGACAGCAGATGTTCCAATGCTAGACAGTATGGCAGCTGAGTTTGCATTTGGAAGTAACACAACAGGGTTAGTGAAACCTTGGGAAGGAGAGAGGATCCATGAGGAATGTGTATCTGATGATCTTGAGCTTACACTTGGAAATTCTAGGACCAGATGAGGGGGAACTGACAGAAAGGGTGAGAATGAATTATCCTCGGATTTCTTGATTTGGCTTCTTGCTTCCCTTTATGTTTCATGTCAATGACTTCATATTGTGCATGCTTCGGTTGGCAGAGAGCTGAGATAGAGGTACAGTGAGTAGGAGCACCTGTTCCTTTTTTCTTGTTCTATTATTTTTTACTTTTTGGTTTGCTTTTCC
->URS0000F753B8 rRNA from 1 species 
-TACGTAGGCAGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGAGCTCGTAGGCGGTTTGTCGCGTCTGCCGTGAAAGTCCGGGGCTCAACTCCGGATCTGCGGTGGGTACGGGCAGACTAGAGTGATGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGATGGCGAAGGCAGGTCTCTGGGCATTAACTGACGCTGAGGAGCGAAAGCATGGGGAGCGAACAGG
->URS00004B85F5 rRNA from 1 species 
-GATGAAGGTTTTCGGATCAAAAAGTTCTGTTGTTAGGGAAGAACAAGTACCGTTCGAATAGGGCGGTACCTTGTTGGTATTTTAACAGAAAGCCACGGCTAACTACGGGCCAGCAGCCGCGGTAATACGTAGGCGGCCCGCGTTGTCCCGGAATTATTGGCCGTAAAGGGCTCGCAGGGCGGTTTCTTAAGTCTGATGTGAAAAGCCCCCCGGCTCAACCGGGGAGGGTCATTGGGAAACTGGGGGAACCTTGAGTGCAGAAGAGGAGAGTGGAATTCCCACGTGTAGCGGTGAAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCCGCCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCCGCCCTGGGGGAGGTACGGGTCGCAAGACTGAAACTCAAAGGAATTTGAACGGGGGCCCCGCAACAAGCCGGTGGGAGCATGTGGTTTAATTCGGAGGCAACCGCGGAAAGAGCCTTACCAGGGTCTTGGACGATCCTCTGGACAGTCCTTAGAGATAGGGACGTC
->URS00022660AC lncRNA from 1 species 
-CTAGAATTACTTTTCTTAGTGAATTAAGTCCATAGGAAGCAGTTTGACGGAAGTATGAGTGCCAAGAATGGTTCCAAAAATTCTGATTGGAGAATAGGACTTTCACAAATATGCCATGTGAAAAGCAACCTGTTGAGCTGGATAATGATGTGCTGAGAGTTGCTGTTGAGAGAAATCCAGAAGCAGCAATCAAGGAATTGGTCACAATTGTCCATTCATTCATTTCAACTTTCAGAGGCTTCTACAGGACTTTGATTGTGTGTCAAAAATGGATAATGAGTTTCAGCCACAAAATCTGTGACCTAGCATGTAAATATTTGCATTTCCTTGCTCTCCCATGAAAAGAGAGAGTTGTTTTTGAAAAGAGTGGTTATGGGAAATAAAAAATGTTTTCACAAATGTCCG
->URS00003A7160 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTAGAACGCACAGGATGCACCGTAGTTTACTACACCGTATTCTGTGAGTTGCGAACGGGTGAGTAACGCGTAGGTAACCTGCCTGGTAGCGGGGGATAACTATTGGAAACGATAGCTAATACCGCATAAGAACATTTACTGCATGGTAGATGTTTAAAAGGCGCAAATGCATCACTACCAGATGGACCTGCGTTGTATTAGCTAGTAGGTGAGGTAACGGCTCACCTAGGCGACGATACATAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATTTTCGGCAATGGGGGGAACCCTGACCGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAGCTCTGTTGTTAAGGAAGAACGAGTGTGAGAATGG
->URS0000C46E39 snRNA from 1 species 
-ATCTTTGCGCTTGGGGCAATGACGCAGTTGGTGAGATGAAACCGAGACGCGTCAATTGCTGGTTGAAACTTTCCAAACATCTATATTTAGAATGTCTAATCTACAAAGATCCGGTGATGATGGATATTTCACATGAAA
->URS0001CDBEA4 tRNA from 1 species 
-GCCGGGGTGGTGGAACAGGTAGACACAGGGGACTTAAAATCCCCTTCGCCGAAAGGCGAGTGCGGGTTCGATCCCCGCCCCCGGCACCA
->URS000118F557 rRNA from 1 species 
-GACGTAGGGGGCAAGCGTTGTCCGGAATCATTGGGCGTAAAGAGCGTGTAGGCGGCTCGATAAGTCTGCTGTGAAAGTCCAGGGCTCAACCCTGGAAGGCCGGTGGAAACTGTCGGGCTAGAGTCCGGAAGAGGCGAGTGGAATTCCCGGTGTAGCGGTGAAATGCGCAGATATCTGGAGGAACACCGGTGGCGAAGGCAGATCTCTGGGCCGTAACTGACGCTGAGGAGCGAAAGCATGGGGAGCGAACAGG
->URS00016F7E24 rRNA from 1 species 
-TACGTAGGGCGCAAGCGTTATCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGCCTGTCGCGTCGGGAGTGAAAGCCCACTGCTTAACGGTGGGTCTGCTTCCGGTACGGGCGGGCTGGAGTATGGCAGGGGAGACTGGAATTCCTGGTGTAGCGGTGGAATGCGCAAATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCATTACTGACGCTGAGGAGCGGAAGCGTGGGGAGCGAACAGG
->URS00023D8557 lncRNA from 1 species 
-GATTCTTCTTCAGCTTGTTTTCTTTTCCTTTTCTTCTTCTCTCCAGCATCAGCATTTTCAACCGCATCAACATCCTCAGCTGAATGCTTCTTCTTCTTCTTCTTTTCCTTCTTCACGGGTTCCTCTTCTGCTTCCACATTTCCATTTATGTCATTTGACGCAGGCATGTCTTCATCATCAGCCTTCTTCTTCTTTTTCTTCTCTTTCTTATCTTCTCCAGCAGGTGTCGTTTGGCCAAGAACAGAATCTGCTGCGGGATTATATGCCT
->URS00020BFB22 rRNA from 1 species 
-AGCGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGGACCCTTCGGGGTTAGTGGCGGACGGGTGAGTAACACGTGGGAACGTGCCTTTAGGTTCGGAATAGCTCCTGGAAACGGGTGGTAATGCCGAATGTGCCCTTCGGGGGAAAGATTTATCGCCTTTAGAGCGGCCCGCGTCTGATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGATGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATCTTGCGCAATGGGCGAAAGCCTGACGCAGCCATGCCGCGTGAATGATGAAGGTCGTAGGATTGTAAAATTCTTTCACCGGGGACGATAATGACGGTACCCGGAGAAGAAGCCCCGGCTAACTTCGTG
->URS000081A35D rRNA from 1 species 
-CTACGACTCTCGACAATGGATATCTCGGCTCTCGCTTCGATGAAGAACGTAGCGAAATGCGATACCTTGTGTGAATTGCAGAATCCCGTGAATCATCGAATCTTTGAACGCAAGTTGCGCCCGAGGCCTAGGCCGAGGGCACGTCTGCCTGGGTGTCGTGAAA
->URS00004E6ABB rRNA from 1 species 
-AGGAAGGAGAAGTCGTAACAAGGTTTCCGTAGGTAAACTTGCGGAAGGATCATTG
->URS0001751255 rRNA from 1 species 
-GACAGAGGGATCAAGCGTTATCCGGAATGATTGGGCGTAAACGCGTCTGTAGGTGGCTTTTCAAGTCCGCCGTCAAATCCCAGGGCTCCAACCCTGGACAGGCGGTGGAAACTACCAAGCCTGGAGTACGGTAGGGGCAGAGGGAATTTCCGGTGGAGCGGTGAAATGCATTGAGATCGGAAAGAACACCAACGGCGAAAGCACTCTGGCTGGGCCGACCACTGACACTGAGAGACGAAAGCTAGGGGAGCAAATGGG
->URS000100F795 rRNA from 1 species 
-TACGGGGGGGGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCTCGTAGGCGGCCAACTAAGTCAGACGTGAAATCCCTCGGCTTAACCGGGGAACTGCATCTGATACTGGATGGCTTGAGTTCGGGAGAGGGATGCGGAATTCCAGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGTTCTCTGGGCCTTACCTGACGCTGAGGAGCGAAAGCATGGGGAGCAAACAGG
->URS0001BD843F lncRNA from 10 species 
-TGGGTGCCGGAGAAGCTCCATATAGTGCTAGgcccaactattccatgagctccaaactagagcgtctcacaccccctgtgtcccgtcctcctggatagctaatggatgtcttggatgtgggaaacttatccaggccagcatgggactctggatctttgccctaaacctgctcctccccaggcttcaccttctcagcagtggcatcacatccagccagctgctccagcccaaatgtgatgagatcattttgattccccttctctccacatcctctccccatattcaattcaacagcaggtgctgtcagtgctgccccagcctctgtctccctcgtgtctctccagggctgcactgtgacaaggccacggtgtctacctggacggccacagggactcccagttggtcttcctgcctctactgccgcccccgttgctctattccaacagggaaagtgtgacctcgtaagtcctgctcatcccctcccaggatttttcactgcacatggaaaggatccacctttctgcaaggtcctgcgtgacctggcacttgcctcgttttctgacgtgacctccttccctgctgccccttgttccagctgcactggccatttctccaacacaacaaatcctttctcatcatgccgcattccctgccccagaccttcacctggtggctgcctcaggttcttcaggactcaggggagatgttgtctcctcagatgccttctgggaccacctgaccaatgtggcacctcaagcc
->URS00008EF1EE rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGGACGGGATTTATTCGACGAACCTAAGTAGTTTACTATGAGGGGGAGTTGGGTAAATTTAGTGGCGGACGGGTGAGTAACGCGTGAGGATCTATCCATTACTGGGGGACAACAGCTGGAAACGGCTGCTAATACCGCATAAGCCTTTGGGTGAAAGAAGCGATTCGGTATAGGAGGAACTCGCGTCCTATCAGCTAGTAGGTGGGGTAACGGCCCACCTAGGCGAAGACGGGTAGCCGGCCTGAGAGGGCGCACGGCCACACTGGAACTGAGATACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGGCAATGGGCGAAAGCCTGACCCAGCGACGCCGCGTGAATGAAGAAATCCTTCGGGATGTAAAGTTCTGTTGTACGGGAAGAGCGAGAGACGGTACCGTACGAGGAAGCCCCGGCAAACTACGTGCCAGCAGCCGCCGTAACAC
->URS0001035ED5 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGAAGTGGCGAACGGGTGAGTAACGCGTAATCAACCTGCCCTTCAGAGGGGGACAACAGTTGGAAACGACTGCTAATACCGCATACTGAAGGAGGGGATTGCGTCTGATTAGCTAGGTGGAGGGGTAACGGCCAACCAAGGCGATGATCAGTAGGCGGTCTGGGATGAAGGACCGCCAAATTGGGAATGAGACAAGGGCCAGGATCCCTAGGGAGGGAACAGTGGGGAATCTTCCGAAATGGGGGGAAGTCTGGAGGAGCAACGCCGGGTGAGTGGTGACGGTCTTCGGGTTGTAAAGCTCTGTTAATCGGGACGCGGTACCGGAATAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATAC
->URS0001134E72 rRNA from 1 species 
-AGTGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGAGAACGGAATATAGCTTGCTATATTTGTCAGCTAAGTGGCGCACGGGTGAGTAATGTCTAGATAACCTGCCCTTAAGAAAGGAATAACAGTTGGAAACGACTGCTAATGCCCTATATGCCTTTAATACATAAGTATGCAAGGGAAACGCTTTAGTGCTTAAGGATGGGTCTGTATGGTATCAGCTTGTTGGTGAGGTAATGGCTCGCCAAGGCTATGACGCCTAACTGGCTTGAGAGGATGATCAGTCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGACGAAAGTCTGATGCAGCAACGCCGCGTGGAGGATGACACATTTCGGTGCGTAAACTCCTTTTATATAGGAAGATAATGACGGTACTATATGAATAAGCACCGGCTAACTCCGTGCCAGCAGCCGCAGTAACAC
->URS000222E680 rRNA from 1 species 
-TACGGAGGGGGCTAGCGTTGCTCGGAATTACTGGGCGTAAAGAGCACGTAGGCGGGTATTCTAGTCAGGCGTGAAAGCCCCAGGCTCAACCTGGGAACTGCGTTTGATACTGGATACCTAGAGTCCGAGAGAGGGTGGTGGAATTCCCAGTGTAGAGGTGAAATTCGTAGATATTGGGAAGAACACCAGTGGCGAAGGCGGCCACCTGGCTCGGTACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAAC
->URS00023D9DA4 lncRNA from 1 species 
-CCCTCACAGCATGTGTATTTTACACATACGCACCTCCATGTCCGATCTCACGCAATTCGGCACATAAAATATTAGATCTTTTCGCGATTTAACCGTTTTGCCAATTTGACCTCTCAGCGATAACTTTGCAAATACCGGAGATCCATCCGTCGAATTTTCGATCCGACAGTACCATTGCGTTCGGCACGTCGGGTGCATCGAATCTAGCATTTCGTTTCGTCCAATTTGACCCCCGATTCACGACGAAATCCGTCCGCTCTCCAATTTCAAAAACCACACACATATATCGATGTGTAATCCCGCTAAATCCTTAATTCAAATTCAAATTTGAATCTCCTACCACTAGTAGGTACAT
->URS0001FED5D7 ribozyme from 1 species 
-ACCTCGTGGAGAGCAATAAGGAAAAGCTGGTCCGTGCCCAGAGAGAGGAGCAGGAGCGGCAGATGGAGAAGGCGGCAGAGCAAGCCGGTCAACAGGCTGCAGTCCCTGACCTTGGATGGAACTCGCACCAGGGAATCGACCAGCAGATTG
->URS0001E7E931 rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGATGAAGGGAGCTTGCTCCTGGATTCAGCGGCGGACGGGTGAGTAATGCCTAGGAATCTGCCTGGTAGTGGGGGATAACGTCCGGAAACGGGCGCTAATACCGCATACGTCCTGAGGGAGAAAGTGGGGGATCTTCGGACCTCACGCTATCAGATGAGCCTAGGTCGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCCGTAACTGGTCTGAGAGGATGATCAGTCACACTGGAACTGAGACACGGTCCAGACGCCTACGGGAGGCAGCAGCGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGTCTTCGGATTGTAAAGCACTTTAAGTTGGGAGGAAGGGCAGTAAGTTAATACCTTGCTGTTTTGACGTTACCAACAGAATAAGCACCGGCTAACTTCGTG
->URS00019E4D72 tRNA from 1 species 
-GGCTGTGGCTCAGTGGTTGAGCGTTTGCCTCGCACGTGTGAAGCACTGGGTTCAATCCTCAGCACCA
->URS00000CF716 rRNA from 1 species 
-CCGTGTGGCGGCCCCTGTAAAAAGGTTGGAANCAACTTGGGTGGAGGGATTTTAACCGTAGAGTCGGGTTGCTTAGTACTGCAGCCCTAAGTAGGTGGTAAACTCCATCTAAGGCTAAATACTACCACGAGTCCGATATTTGACAAGTACCGTGAGGGAAAGCTGAAAAGGACTCTGAAGAGAGAGTTCAAGAGGACGTGAAACCATTAGAAGCTGAAACGGGTGGAACTGTGAAGGTGGAAAGAGGGGATTCAGGCTGTGGGCATAGACATTGGCTTGAGTTTTTGTATTGTGAATGGACCCGGCATACGAGTGAGTTGCCGGTGCTTTTCTTGCCTTTGTTTTGTGTCGGCGGGCTTAATTCTCCCTCGAGTACTAAACGTGGCGACCCGCTGGACGGACCCCGAGGGCCCTTAAGGACTGGTAGCCTATATCTTTGGTGTGGGTGATGACCTTAT
->URS000006D2C9 rRNA from 1 species 
-AGAGTGGCGAACGGGTGAGTAACACGTGAATAATCTGCCTCCGGTGTTGGGGATAACAGTTCGAAAGGACTGCTAATACCGAATAAGATGGTAGGTACAAAAGTACTAGTCATTAAAGGTGGGGACCGCAAGGCCTACCGCCTGGAGATGAGTTCGCGGCTGATTAGCTAGTTGGCGGGGTAACGGCCCACCAAGGCGACGATCAGTAGCCGGCCTGAGAGGGTGAACTTTCACATTGGGACTGAGATACGGCCCAGACTCCTACTGGAGGCAGCAGTTAAGAATCTTGCGCAATGGGAGCAATCCTGACGCAGCGACGCCGCGTGAATGATGAAGGCCTTCGGGTTGTAAAGTTCGACAAGCAGGGAAGAATAAGTGTGGGGTAATATTCCACATGATGACGGTACCTGCCTAAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTATGGGGCGAGCG
->URS000108241F rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGTGTGCGCAGGCGGCCGCGCAAGTCGGGTGTGAAATCCCCGGGCTTAACTTGGGAATTGCGCTCGAAACTACGTGGCTGGAGTGTGGCAGAGGAAGGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCGATGGCGAAGGCAGCCTTCTGGGCCAACACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGG
->URS0000A837F7 lncRNA from 1 species 
-NNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNCATCTAAGCTAAGGATGTCTTCACTGTAACCTCTGCCTCAGCAAGCTTTTCCCTTGCTGATCCCATCAGAACCATCCCCATTTGAGCTTCAGACTCCCCTCTGCCAACACTTAATCTTCTCTTTCAGCAAGAGTAAACAGATAACAGAATGTTCTTCCCTGAAGCTTACTAAAACTTTAAGTCCCGGTGTTATTCTCCAAAGGAAGCTGCTTTCTTCTGGCCACCAGGTCACCAGCTCCTATAGTGAGCTCTGAGCAGATTCTAGTCAGTCTCTTTAAGGGGCTGGGACTAATCGCTGTGACCTCAATCAAGCCTGCTGGTTTTATGATACCAGGAAGGCTCACCAGGTGAACTTCTGCTCCTTTTAGGAGGCTAAGCATCCCCCAGCCACCTTGGACTTGAGCAGTGTTACCTGCCAGCAAGCGCAACAGTGCCAACCACTGGTCTCTTCTTTTGGAAAACGTTTGACTTTTAACTTGCTTTCTTCTCTATTTCATCATTATCCTCCTTTCTGACTTTCATGTACTCCTAAAATTTTTGGTTGTAGAACTAAGCAAGAGAATGAGAACTGGGAAGAACCTTGGAACAATGCTGAGAGGCTGCCCAGATGCTCTTCTGTGTTCCACAGTACTGCCGAATCTTCCTTGTGGCTCTGGTACTGTACTGCCACTCAAATTTTGGTACAAACCATTGAAGTATTTTTTGCTTGTTTTTATTGGTCTACATAGTAATCTTAGTGTTCTGTTCCTGGAATAGTCTCTCAGTTAGCACATTCCCCCTTGTCCTGAGATCACCAAGACCTTCAAGATTAAGGCTCTTGCTTTCTACCCTGCCAGCTCTGACGCAAAGCAAACACCCTTTTCTACTCTGCAGTATGAAGTGCTCAGGACTGTGTTTTTAGCTGTTCAGAATGTTAGAGTTATTAATGTTGGTTAGTGGAGTTATCCTTCAGTGTAGAAAGAGAAAACTGCATGAAAAACTGGCACTAACTTAAGTGGCCTCTGACACCTTCCCTAACCCTGTCCCAGTTTGTGTCACATTCTACAATAGATGAGTGATCATGATCAGCAAAACTGTTTCTTTCTTTCCTTCATTTCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTCCTTTCTTCCTGTCTGTCTTTCTTTCTGTCTTTCTTTCTTTCTTCCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATCTATTTATTTTGGTGTTTGTTATAGCAGAATTTGATTCATGAGAAAATCATCAGGCAGCTGGCAAGTCCCAGCTTCTCCCAAACTCTATGTAACCTGTTCCCAGCCACCTATCTTGACCCAGTGTTCCTCATGTTTTAAACTAGCTGGCAAACACATTTGCACAGCCTTATTGTGGGAACATTCAACTTGGCAATAAGTACTTTGCTCTTGATAGGATCTCAAAGATTCCTTCAGACCAAGAGAGACTCCAGCAAGCATACAGTTACAGATACTGTTGCCCAACCTGCACATCTCTGTGCCTGCCTCCCAACACAAGTCAAATGTGGGAACCAATCCCCCACCAACTACACATACACACACAAACACACACCTCTGTCCTTTTTGGTATTAGTATTCCTTTTTTTTTTTTTTTTTAAATTTCACGCATCTCTTCAAAATCTGGACCTCTGGATCTACAGCCCTGGGTCGTCATAAATAGCTCAAAAATGAGAAATCATGACTTCGGCTTTCTTTTTTAAAATTACTTTAATAAATACCCCAACATGTTCACTATACCACTGTACAGACTTTATTTGTTTGTTTGTTTGTTTATTTAAGTGCTTCCAGACCTGTAGTTTGAATATATGTAGTTCAGGGACTGTTGTTTCTAGGCATTCTACCTAGGAGTTTGTGCCTGTGGAGCATGTGGATGCCCCACCCCTCAGCTACACCCAACCCATACAGAAGTGCTGACGGGACTGTTTCCAGAGTTCTAGCCTGTGGTATTAAGACTTTAAAAAAAAAAAAAAATGTAATGATTTTTTAAGCCTTTTCTTTTCTGGTTGCCCTTGCAATTAAATTAAATAAAAAGAGGCATATGTTCAAAGTTTTACTGTGGCAACAGTTAAACATACAACTAAGCCCTGTCAAGAAACAATCAAGTGGGGAGATAGATGCTTAAGTCTAGAAACTGCTGTCTTCGAGAAATGTGAAAGCAGAGACCACATACTCATGATCTCCCTCACTCCCACACGGCAGCAAAGGATTCCTTTCAGCTTTACTGATTCACACTGTGGATACAGAACATTCTAGAAGGCCAGCTCTTGCTTCTCACCTGTGTTTATTGTCCAGAAAGGACAAGTCTTTAGAGACAGAGGAGGCAGTATCATCCAGGATAAGTTATTAGGCCTGGCTTGCCATTCCTTTTAATCTAGTCCTTCAGGGAGGCTGCCATCAAGGAACAAAGCCAGAGAGAATGTAGAGATAGGGCCTCTCATGGCTGGAAAGCCAAGGCCTATTGCTTCAACTTGTGTCCTTGAGGTACTGTGTCTGTACAGAAATTAAGACCCCGAGAGGCCAACAAAAAATGCAATTTAAACTGCACCTAAGATAATAAAATTGGATGAAAAGTAAAAAGAAAAAAACAGATTTCCTGGTACTAGGGTTTCCTGTAAACACCTTGTGGGTACCTCATAAGCAGCTGAGATTATTAGTGTTTGGTCCTAGTGACTATTTCAGCTGCCTTATCCACATTAGCTGCTAAGAAGTGATAACTCCCCAAGTTCCCATATAAAGTCTCTCCTGCTACCGTATTACATGGCAAGGAGAACAGGGGCTTTTGTTTGTTTGCTTGCTTGCTTGCTTGTTTTACTTCCTTGAGGTTAAAACTAGAGTCCCACCCCCACCCCAGATTAGTCTAGAGTTGGGGCAGCAGTAATAAATTAGGACGCATTCAGGTGTGACAACACAGCTACCTTTGATGGTGAAGACCTAGAGTGATTTAGTGTATCTGTGCATTAAATTAGAAAATATTTAGCAGAAACATGTAGCATAGCCGCATTTGAAAACGAGATTGTGCACTTGGGAGGCAGAAGCAGGTAGATATCGGAGTTCAAGGCCACACGTGTTCTACAGAGTGAGTTCCAGGATAGCCAGGGCTACACAGTGAAACTCTGTCTCAAAAACTCCAAGAAAATAAAAAATAAAAAAATGAGATTGCGTTTTGAAAATACTTGAAGTATTTCCTGACCTCCAGGTACCACTTTAAGCATGCTAGATATCTAGGTTGGGAGTCACTGAAGCACACCCCACAGCTATATTGGCCAGTAATGGAAAGTCCACTTTGTAGGAAGTTGATAGTGCCTGCTCCACAGACGCTGTCATTTCTTAAGCCAATCTTTAGAATCCCCAAATGTTTGGGGCAGTGAAAAACAGTAAATATACTTTGTTAATTAAAAACAGACTTTCTTTTTTAATGATATACTTTTACATGACAAATGAAAAAAAAAAAAAACTTGTAATCTGTGTCTGTCACACTAAGACACCAGATACCACAGAGAATCTCTTAAATCGCCACCAAAGAAATGGAGAGAATAAATCAAATGTTTGAAAAAATAGAGAATGGCCTTGGGAGATGGCTCAGTATGTAAAGAACTGACCACACAACTATGGGAGCCTGAGTCAGGACCCTCAGAACAGATATACATCTGGGCAGGCATAACAGCTTCCTGCCATTCCCTTGTCTAAGAACGCAAAGACAAGTGACACCCCGCCCCCACCCCCTGCAACAGGGCAAGCTGGCTAGCTGGATTAGCTCTGGCTTCAAATGGAAGGCCCTGCTCCCATTTATAAAGTGGAGAGATATTAAGGAAGATATTTGACAATAACTTTAGGTCTCCAGAGATATGTGCACACATGTACATCCACACCCAAAGTCACACATGCAAAAGAAAGTGGACTAGAATCATAGTTAGTTCTTAGCACCTTACTGGAGTTCTTATAGTGTGGAACTCTTGTCTTATGGAACGAATGTGGTAACATTCCTACATACAGGAGATGGGTGGCCTCTCAGAGGGGCTCAAGTTTACCCAGAAGGCCAGTTAGTCTTTGAAGCTAGTCACTATTCAGTTTAATCCTTGGAGGCTAGTCTTCTTGACATGAACTGTCTGATTTTCGACACTATATATATAGAAATAGAAGTAGCAATCTATTCATTATGCCAACTTTATAGCTACTTCTGAAGACCTCATGTTGTGCTTGCCTCTCAGAAAGAGATGCCTACTCCTTACCTACTGCCTTCAGTAACAGCAGAGCTCCATGGGGCTGTCCTTCATGACATTATTCAATCCTGACATTCATTGTGGTATTAATATAAAGAAATTTAGTCTGCATACACGAGGTTTTGTGTTCCAACTTGTTTACTATCCTGAGTGTCCAGGTCCCTCATAGAGTCCAGAAGTCTCTGAAGGACTCTGAACATTGCCAAAGGCTTCAGTGAGGGAGTCTAACAGGTCACTACTAAATCAAGGCTTCTAGAGAAATGGTTTGCAGGGTGCTGCTTCAGTCAGATTATTTGCTGTTAGACACTGAGGCTCACAGTTTAGTGTGACTTAGTTCCAACTGTCCAGACTCCTTGGCTGGTAGATGTAATGCTCCGTTTTGTCATGTGAATTTGAAAGGTCACCAGGTGAGGGCAAATGAAAGCCATCACTGTGATTTGGAAATCAGCTCTCAGAAGCAGTTGAGTGACCATCCTTGGACCTTCTGCATGTCACAGTGCATTTTAGGATCTGTCATAGACAAGGCTTATGAAAGTAGCTTTTTGGGAAATTGGAAGGATAAGAGGGGTGGCTCACAGGAGCACAAATGCAGACCCACAACTCATATCAGAATTGAAACTGCTAAGTCCTCACTGCCAACTTCCCAGCTGGCTGGCTTGAAGATGACAACAGCTCAGGGAGCCTTTGAGCAAGTGAAGAAAATTAAATCCTCATTTCCCTGAAAAACTAAATTCTCAGGTGATTGCCTGACAGGGGGAAGGGGGGAATTTTTAAATCATGGCCTTTGTTGATGTTCTCTGGCTTTTTCTTGGGAGGCTGCTTCAAGCAATAACGTGAGGTATGAGGTAACCCTGTCAGGTGGTATGCTGGGCTTTTAAGTCTTGTGCAGGTTGCCTGCTTACCCACACAATTCACATAGGGGCTGAAAAGCTTAACTTATCAGGGATGGAACTAGGTTTTACAGAGTTCCTTTAACCAAATAGGCTTGCTACTTTTTCCTTTCTTCCTGCATCTGCCAAGTCTTTCCGACCATTTTCATTGATCTCACCAGATGAGTAACACTTTAAATTCCAAAGGCTTAAAAATCAACTCCTTGTCATTTTTTTCCAATTTAATTTTTCACTCTTTGTCATATTTTCATCTTCTTGCATTAGTTCCCATGGCAATGTGTCTGTTGGCAGAGAAAATTTAACTCTTTTAGTGTTGATCACAATGTAAAATCCTTTTTAGGCAAGTGCCACAAAAACAAGCAGAGACTGGAATTCTCTTGCTAATACGTTTTCTTATCTCTTATATTGATTTCCCATCCTATCCCCAAGCAAAGCTCTCACAGAAAAACATGCAGAGGCCTTTGAGGCAGCTACAGCTTCAAGGATTTAACCTTTGGCTTCCCATGGCTTCCCGTTCCAAGTGTTAAAAATATGAATGCATCTATCAGGAATGTACAGAAGACAACTTTCAATTTCTATCAGAAACACCCAGTGTATCTGAGGAAATACACACGTCCTAAAATGAGCCTCAAGTCAGGGTCTAATGGCAAGATGAGAGGCACTTAAGCAGATTTCCTCCCAGTAAGTAAATGGCAAAGAGGCCAAGCAAGCTCTAAGTTCTTGAAAGAAGCAGCAAAGACTCAGGTGGAAAGCAAATGACATGGTTACTTGTATGGGGGAAGCGGCACTTCAGTTCAGACAGTTTGTGATCAAGTATGAAAAAGCAAGCAACTGCATCAGGCTTGATGATGTATGCCTATGATTCCAGCAATGGAAGGTCAAAGGCAGGAGGATTACAAGTTTGAGGCCAGTCTGGGCTACATGGGAAGATCTTGCAAGGACTAGGTTTCAAGGTGCTAGGTTCAATTCCTAGGACCTAAAAGGCCTACTAAAGCCTTTAGAAATGCTTTAGAAATAGAATGTAGGGATAAAGGGAAGAGGACTATGCAGAAAGCCCAACCCAAGATTAAATGTTTGTTTCAAACTTTAGGTTCCATCATGGCTTGGCATTGGCAGCTCCTTCTACTGCTTCAGTATCCAGAAGCAACAGGTCTACTGTCAGAAATTGAACAGACTGACCCAAATATGTGTAGGATTTTTTTTTTTTAAGAAAAACTGATGAATTCAGGGGAATGAAATAGATATTAAATAAAATGTGGTTATCTTAAGTATAGTTAGGAAAAACGATCAAATGTAATTGATCTTCTTGCTTAGTCTAATGAGACACTTAAGCACTAAGCTGCTTGTATTGTATAAATGTATTTTTGGCTGTTCAAAGGTTATTTTCCTATATTAAGAAGTTTATTAAAACCTTTTATTGCAACTCAGGTTTTGTGTCTTTTAGACACACATTTTTCTTTGCTAGTTTGTTTTGCACAGCTGGAGTTTTGAGGTGGAATAATGCCTGGGCATGGCAGTCAGCTAAACTGCCTGATAGCGAGACTAAGGAAGGTACTTGACATGTGGACAAGCCACATTGTTGTTTCATAGCTCTCCATGCCTCCACTAAATACAGTTAGCCGGGAAATCTCACATGATTTTGTTTGTTTGTAAAAAGTCTCTGGAGAAACCAAGACGAATCTCTCAGGCAGATAAAGAGCTTTCCGTATTTGCCTAAACGTACTATTGAAATAAATATTATTTTCAATACTTGTTTTTCCACTCAGAGGGCACGCACTGGTCTCAGACCAGGGAGAGGACATCTGGCTTAGATCAGGACTGCTGAGTGCTGTGTAACTCTTAGGAAACTTTGTTTTGATGTCAGTGTCAACAGATTGCAAGGAATGGTTCGTATTTCTGCTCCCAACATTTCGATATTTCCTTTGCTTCCCTCCTCTGAAGAGCGAGCCTTACTGTGATATGTTTGGAGTAAAGACAAAGGCAATTGACAGGCAAACCGCACTTTTGTTGGAAGAGCCAGTTAAGTTCTCTTTGTACTCAGTGAATGTGAGGGACTGAAGGCAGATGGAGAATGTAAAACTGTTTATACATGAAGGAAGGGGCACTGTCCAGGGCTGGCAGGAAGCCAGAGGTAGATCTATTGAACTTCAAAGGGTAAGGTCATTGCAAGGTCACTACAGGTTATAGCAAAACCAGAATTTTCTTTCCTACTTACAGCCATGAAAGGGCACCTCACCATCAGCTGTGTATGAGAAACTCATACTGCAGTCTCATTCTTTTCAGGAAAGAAACATTAAGTAATTCAGATGGAAGAATAGAAAAGTAATTCTGACGGAAGACAATGGTGGGTTTACAAGAGGTTTGTAAAGAATTATACACACTACAGACTGATTTTTTTAAACACTCATGAAATTTATTTTTCACTTTCAAAACTATCAGATTGATGATTTCTTGCCCTCAGTAATTTGTGAGAGATGAACGTATTTCATTATTCTGTAAATGTTTTATGTGTCAAGCACATAAAAATTTTGAGGTCGTATTTGCCAGTTAACATTTCATTCTCATAAAAAGTCGTAAGAGAAATTCCTAAGTGGTGACGCAGCTTTGGGTCTCTTGACCATACTCTCTGATGGGATCTGGCTTCATTACCATAAGTGCGGTACCCGGGTAACAGATCTGCAGTAACCGCAGGAATCTTCCCTCAGAACCAGAACTGGGACCTCATTCCTAAATCTCCCATCTAGCTGATGACAGGTGGCAGGTGAGTGTTCCTTCTGTCCATCCTTTGCTGTCTATGTGGACATTCTGATATGTGTCAGTGAGCTGAATTCTACACGCTGTATATATTGCATGCATTTCACTGCAGTCTATGGACATGCCCTTTGTAGAGCTTTTATGGAAGAACCAAGAAGCCAAGGCAGTTTAGCAAACGAGGCTCAATATTTATAAACTGGGGCCTTTTCTGTCTCTTTGCTAGCCTAGGTGGCTGTATACAAACTGGGTGGGAGGGGCAGCAAACACCTCACACATCACATTTAGATTTTCTACTTGGGTGTACTCTAGCCAATTCAAAACAAATTGCTTACTTTAATAATAAAGTTTACCATTTTATATTAAAGAAAATCAAACCATGACATGTTTAATTGAACTGGCTGTATTGTAATTAATATTTTGAGATAATTGTGATTTTCAGCTTAAAATTATATATAAAAATTGTCATTTTTGTATGTGTTAAAAAAATGTACCATGATTAACAGTACTTTTTAGTTAAACTACATATTGGTGTAAATAAAACTGAATGAAGAAACACTTACTACTTTACTAACTTAGATTGTGAATGTACTTCATGGTTTTTTTGCCATATGAGACCATAACAACCTTGAAAGAAAGCTGTTTAATTTTATGTGCAAAGTCCCACTAACCTGTATTTCAACTCTGCCAAGCCAATGACTTTGCAAGTGTGATCTGTACTCTCCAGCTGTGTCTTACGTTCTGACACTATGGGTTAGGGGTAGGGTGTAGCCTGGAAGCATCTGCAGATGCGCTTTGTACAGATAATAGCGCTGTGTGGTGTATAGCAGAGCCATTTTTAGGTTCTGTTGTACTCAATTTTTTCAGAATTTAAAAAAGTGTTTTGAATAACATAAAAGTCTATTGTATAAATAATAAAATGTCACCTTATTA
->URS0000CDA9EC sRNA from 1 species 
-GTCTTAATTAAGGGAGCCCCGAGACCTTACTCTTTCACTTTACCTAGGAGTTTGGTTCCTAAACTCACCATTCAAATCCAGCAACAGAACTGATTGAAAGGAACCTTTGTCTTTTGTGTGAATGCTCATGAGGGGCCATCCTTACAGTGGAAACGCTCCTGAGGCTCCAGCGAATCAAGACTCTCAGACCCCCGGGCTGTCCCCACCCCATGACCACATGTTCCACAGGCACCCTCAGCACTGTGCCCTGCGTGTCACCCAGGCAGGTGTTTGTTTTCGAGCGCAGATTCTGCCTGTGGCCATAGCCATGTGGAGATGTTCACGCATGTACTTCCCTTTGTGATTTCAGCCGATACGGAAGATGTGTGCATCGTAGAGAGATTGTTCTCCAGCAGCCTAGTGGCCATTGTGAGCCTTAAAGCACCAAGGAAGCTAAAGGTTTGCCACTTTAAGAAGGGAACTGAGATCTGCAACTACAGCTACTCCAACACGATTCTGGCTGTGAAGCTCAACAGGCAGAGGCTGATAGTATGCCTGGAGGAGTCCCTGTACATTCACAACATTCGGGACATGAAGGTGCTGCATACGATCAGGGAGACGCCTCCAAACCCTGCAGGCCTGTGTGCGCTGTCAATCAACAACGACAACTGCTACTTGGCGTACCCAGGGAGCGCGACCATCGGAGAGGTGCAGGTCTTCGATACCATTAATTTGGTGAGATGCCTTTCCTGCTCGAATAGCTCTCTAAAGTGTGGCTTTTTCTTGAAGAGGAGCACTGTGGTGTCCCTGGCATCCTGACTTGGCTCAGCAATACAACCGCTGCACTTTTTTTTTGAGACAGGGTCTTGCTCTGTCGCCCATGCTGGAGTGCAGTGGTGCAGTCCTAGCTCACTGCAGCCTCAACCTCCCGGGCTCAAGTGATCCTCCTGCCTCAGCCTCCCAAGGAGTTACAGTCATGCAACACCACACCCAACTAATTTTTTATTTTTGTAGAGATGGAGTCTTGCTGGGTTGCCGAGGCTGGCCTCAAACTCCTGGCCTCAAGCCATCCTCCCGCCTTGGCCCCCTAAAGTGCTGGGATTACAGGCGGGTGCCCCGCGCCCAGCCCCGCTACTCTCTTCTCAGTAGCAGAGCAGGTCTGGCTCATTCTGCTTCTGGATCTGCTGCAGCGTTCAGACCAGTGCTGAGCTCCTCGCCATGGGAATGTTTGAAGGAACATAGAAAACCTTAGGGATAAACTGCTTTGCTTTTTCTAAATTTGGAGCAGCATTTCCTTGGATGCCCAGCCCCAGTAAATCAAGTGGGTTTGGCATTTGTTTGGACCGTAATGGTGTTTTAGGAATAGCTAATTGGCACTTGCGGACCAAGTGCCAGCCCTGGGGCGTGGGCGGTCACTGTGCGGCGGCCACGCTTTATTGGTGTCCCTTTTTCAGAGAGCTGCAAACATGATTCCGGCTCACGACAGTCCTTTAGCGGCATTGGCCTTTGACGCAAGTGGAACTAAACTTGCCACGGCTTCGGAGAAGGTGAGTCTGCTTTTCCCTGGGGGAGCGCTGGTGCCAAGGCGTCCAGAGACTTTTTCAGTTCTGTTCACACAGCCAGCTTAGAGGCAAGGTCTTATACTTACCAGCTCCGGGAGAAGCGAAGACAGCCACCCGCTTGTCAGGCCATGGGCTCGTGCTGCCCGAGAGTGAGCGGAGCTTGCGGTGTGTCACTGGGACGGGAGAGCTGGTCCACGTTTGTAGTAGAAAATACAGAAATGTCCAGAGGAGACGAAGTGCCGTGTGTAACCACGCCGCTCACCCAGTGTGTTTCTAAATGATGAAACTAACACGTAACAGTAAAGAACCCAGACAGTGATAAAACGTGAAAAAGCAAGGCCAGAATTCTATCCAGCCCGTCTGAACACATTTCAGTGTATTTCCTTTCATTTTCTCTTTAGTCAACAAAATTGGGATCTTACTATGGGTATAATTTATCCTTTTTCACTCTGCATGACATTTGTCTAAGTTCAAAAACACTTGTAATGGCCGTGCAGTATTTAGTTGTGATTTATGTCAACATCACCCTTTTGGGACTTTGTTTCTAATATGTTGCTGCCGTAGGTAGTAGTGTATTTAAGTCATGTATCAATCTTTTATATGTATTTCTAACTATGAATTCAAGAGATTCCAGTAAGAAGAATGTCTGGCTTTAAAGGAGATGGCCTCTAAATGTCCCCGTATACCTGTGACCGCGTGGCGAGGCTCCCTGGCCCCCAGGAGACTGAAGGCTCCTCGTTCTCTTCCTCACTTGGACTGTGCCTCTCTTTTCGTTTCAGTTCCTCTTTTCTTGAAAGTTCCGTCTTCTCTTCTTCTGTCTTGAGGTCGCGTCTGCTCTCCCGCCTCCGTTGTCTCCTCTGGATGCCAGTCTGCTCTTCATTGCCCACCGATGACCTTTACTTTGATTTGGATATGATTTTGCTTCTCATTGAAATCCTAAAATAGCCTCCCCTTTCAAGCCATCTCTCCCCTCAAACTATCGACCAGAGAAGATACAATAAAACGTCGGCTCACTTCCTTA
->URS0002144F5F rRNA from 1 species 
-GCGGAGGGATCATTACACAAAAAATATGAAGGCTGCAACCGCCAGTTTTGGCGGGGAAGCTGAATTATTTTTCACCCATGTCTTTTGCGCACTTGTTGTTTCCTGGGCGGGTTCGCCCGCCACCAGGACCACACCATAAACCTTTTTTATGCAGTTGCAATCAGCGTCAGTATAACAAATGTAAATCATTTACAACTTTCAACAACGGATCTCTTGGTTCTGGCATCGATGAAGAACGCAGCGAAATGCGATACGTAGTGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCTTTGGTATTCCAAAGGGCATGCCTGTTCGAGCGTCATTTGTACCCTCAAGCTTTGCTTGGTGTTGGGCGTTTTGTCTTTGGCTTTTGCCCAAAGACTCGCCTTAAAACGATTGGCAGCCGGCCTACTGGTTTCGGAGCGCAGCACATTTTTGCGCTTGCAACTAGCTAAAGAGGCCAGCAATCCATCAAGACCTTCTTCTCACTTTTGACCTCGGATCAGGTAGGGATACCCGCTGAACTTAAGCATAT
->URS00023B0815 lncRNA from 1 species 
-ATACATTCCTAATGGAACTGTCGCTGATCATCTTCATGGAAGACAGTCGAACTCTGGTTTGCTCACTTGGCCTTTTCGGTTGAGCATTGCTATAGAGACAGCCAGTGCACTTGCATACCTCCACGCTTCAGATGTCATACACCGTGATGTCAAAACCAATAACATTCTCCTAGACAACGACTTCCATGTGAAAGTGGCTGATTTTGGTTTGTCGAGATTGTTCCCAACTGATGTTACTCATGTATCGACTGCTCCACAAGGAACGCCTGGATATGTTGATCCGGAGTATTATCAATGCTACCAACTGACGGACAAGAGCGACGTTTACAGCTTTGGTGTGGTCTTGATTGAGCTGATATCAGCTTTAGAAGCAGTGGACACCAATAGGCATCGGCATGATATTAATTTGTCCATCATGGCAGTGAAAAAAATCCAAAACCATGCTTTAAATGAGTTGGTTGATCCATTTCTTGGATTTGACAAGGATTTCGTGGTGAGGAAGATGGTAACATCAGTTGCAGAATTAGCTTTCCGGTGTTTGCAACAACAGAGG
->URS00021A59B7 tRNA from 1 species 
-GGGGGCGTAGCTTAATGGTAAAGCCTCAGTCTTCCAAACTGATTACGCGGGTTCGATTCCCGTCGCCCCCTC
->URS000061A097 rRNA from 10 species 
-GGGCCTCTTGCCATCGGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAACGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGGGGAGGAAGGGAGTAAAGTTAATACCTTTGCTCATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCTGATACTGGCAAGCTTGAGTCTCGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACGAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGACTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCACGGAAGTTTTCAGAGATGAGAATGTGCCTTCGGGAACCGTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTCCGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGACCAGGGCTACACACGTGCTACAATGGCGCATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCATAAAGTGCGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTGGATCAGAATGCCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTTACCACTTTGTGATTCATGACTGGGGTGAAGTCGTAACAAGGTAACCGTAGGGGAACCTGCGGTTGGATCACCT
->URS0001E193C8 rRNA from 1 species 
-AACGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGCGCCCTTCGGGGTGAGCGGCGGACGGGTGAGTAACGCGTGGGAACGTGCCCTTCTCTGCGGAATAGCCTCGGGAAACTGAGAGTAATACCGCATACGCCCTTTGGGGGAAAGATTTATCGGAGAAGGATCGGCCCGCGTTGGATTAGGTAGTTGGTGGGGTAATGGCCCACCAAGCCGACGATCCATAGCTGGTTTGAGAGGATGATCAGCCACACTGGGACTGAGACCCGGCCCAGACTCCTAGGGGAGGCAGGAGGGGGGAACTTGAAAAAATGGGGGCAACCCGAAGCTGGCCTGGCCGGGGGGGGGATGAAGGCCTTGGGGTTGAAAAGCTCTTTCAGCGGGGAAGATAAGAAGGGACCCAGCAAAAAAAGCCCGGGCAACCTCCGG
->URS0000C56DA5 snoRNA from 1 species 
-GAGTGGAGTGATGATTGTATTTGATTCCCTATTGGTTTGATTGCCAGTGTGATGGCACGCATTATAATAGCTTTATCTGACCACTC
->URS0001BF6C2A lncRNA from 10 species 
-ccagcagtggcaacccgctagggtccccttccacactgtggaagctttgttctttcgctcttcacaataaatcttgctgcttctcactctttgtgtccacaccgcctttaagagctgtgacactcactgtgaaggtctgtggcttcactcctgaaatcagcgagaccatgaacccaccaagaggaatgaacaactctggacgcgccacctttaagaactgtaacattcactacgaaggtctgcggattcactcctgaagtcagcgagaccatgaacgcaccggaaggaatgaacagctctggacgtgccacttttaagagctgtaacactcactgtgaaggtctgcggcttcactcctgaactcagcaagaccacaaacccaccagaaggaagaaactctggacacatctgaacatctgaaggaacaaactctggacacaccatctttaagaattgtaacactcaccgcgagggtctgcggcttcattcttgaagtcagcaagaccaagaacccactggaagggaccaactctagacacattttggtgacccagatgggactattgcctatcgccaagcagattgaggccatcaagctacagatggtcttacgaatggaatcccaaatgagctcgactaacaacttctatagaggacccctggactgacctgctggccctttcacggcctaaagagttcccctctggaggacactatcactgcagggccccttctttgcccctgtccagcaggaagtagctagagtggtcatcgggtaattcccaacagcagttggggtgtcctgtttagaggggagatGgagaggtgaagccgactgggcttctgggtcaggtggggacttggggaaattttctgtctagctaaaggattgtaaacacaccagtcagtgctctgtgtctagctaaaagtttgtaaatgtaccaatcagcactctgtaaaaatggaccaatcagcactctgtaaaatggacgaatcagtgctctgtaaaatggataaatcagcaggatgtgggtggggccaaataagggaataaaagctggccacctgagccagcagcggcaacctgcttgggtccccttccacgctgtggaagctttgttctttcgctcttcgccgtaaatcttgctgctgctcactctttgggtctgcacaaactttaagaactgtaacactcactgcgaaggtctgcagcttcactcctgaagtcagcaagaccacgaacccaccagaaggaagaaactccggacacatctgaacatctgaaggaacaaactccg
->URS00022B9349 lncRNA from 1 species 
-TTCATTAGCTCAAATATATACATATGTCGAGGCACATTCCTAGGTAATATCTTCTCATTCAGATAAATAACTTCAAGTTAATATTAAAGTCATTATTCATTGATGCAGAAAAGTCTCTCCACTGTACTTTCCCAATTCTTGGGCATTCTACAAAAAATGCTCTTTCTGCAATGTATATCCCCTGAAACACAATGTTAAATTTGAAAAGGTTTAAATATTTTCCCAGCTCAAGAGAAATAAGGCAGATTTTCTATCATTGCTAGAATGAAAGGAGGTTTGTTTATCCTGTTCACTAAATCAACAACATACTTCCTGCTAATAGGATCAGAGAATGAGATGGGTAAAATGTGAAATCATTTGATTTCTTTGTTTTGTTTACACGTGTATGTTAACGAAGCATCAGATAAGAATGAGGTCTAATTTCCTCTTCTGCAGGTAGAATTTGAGTTAGGTTTCCAGAAGGACTTACCAAATTCTAGTAGCCATACACCGGTAAACAGGTCAACCTCTAGGTATTTAGAAAAACAAATGTCCTTTCCCAAACTTCTTAGTTACAGAGCCTTTCAAAAGCAGCTCATAATTTGTTCACATGTTGTTATTTGCCTAATGCACTTGATACATACTATCAGAACTGCACATAATGCCTGAGCTCTACAGATAAAAGCTAAAATGAAGGATACAATATATCTGATTTTCAGAGGCCTAGTATCATTTAAAAAGTCAGCTAACAATTCCAGACTATCTCTAGTTAGATTCTAAACACAAGAATCCATCCATCCATTCAATAAATACTTATTCAGCTAGACAATATGCAAAACCATCCCAAGGGGGTTGAGATTAAAAAAAAAAAAAAAAATCAAGATAAATCTGCCATCTTGCCACTAACAAAACATATCCAGGACAAAAAGTACTATAAGGGAAATGAGAGTGAAGAGCTTCAGCTTATGCAAAGACCCTGTACTGAATGAAAATGAGTAAATTTATGGGCCATAAAATGTAAATACATAGCATTGAAGAGAGGAAAATTCATGTAGTCCATAAAATTGGAATTCAGTAGATTGTGAGCCTTGCAAGAAAATCACTCACCATACAAGTCCTAGAAGCAAGAGGTACAGCTCTCCCATTAACCAGCTCTAGGACTTTAGATCAAGTCATTTCATTGCTCTGAGATTCTGTTTCTTCATCTGTAAAATGAGAGTTAAAATTTCTAAGCTACCTACCACTCATGATTGTCAAGGGATTATGCATGAAAAAATGCTTTACTAAACTAAATATCTCATATATACTAGTACTGGTTCAGCTTTTTTGGGGTCTTATTTTTAAATAAATAAGTTGAAATGATATTTTTTAAGATTGCATTTATTTGGGAGATTGTGCACAGACTAGCAAACTGGGTGGTGGGGGAGGAATAGAGGGAAGAGAGAGACTCGAGCAGATTCCACGCTAAGCATGCAGCTTGACACAGGGCTTGATCTCACAACCCTGAGAGTACAACCCCAGCCAAAATTAAGAGTCGGACGCTTAACCACCTAAGCCACTCAGGCACCCCAAGTTGAAAAGACTTTTAAGTTCTCTTTTTAGCACTGTAAGATTTTACGACCTAAAAACTAATCTTAACTCAATGAGTAACTAAGAGATTTCTAACTTCCTAAGCATTATTATTAGTAGCATCAATCAATAAATTACCACAGAAAAGGAGGTATGAGCTAAAACAAACTGTTCTAAAATATTGGTTAAAAAAGGAAGGGGGATGAGAATCAAAGGACATATGGAAGAAAGTTAAAATGACTATTAATAGTGAAGGAATCAAAAGTAACCCTGAGTCTGAGGGGAGAACCGAGATGACATTCTTCTGGCAATCCTTCACGACGGCAAACTATCAACTTTATAGGAAAAAGTTATTTCAATTGAAAAAGATTTCCCAAGCAAGTCTGGTGAATGAGCTTAGAATTCAAATTCATGATACAGCACTGATTCAAAAGCAAAATGTGCCAGAAATTGAGGGACAGGGCTCAGTATTTCCGAAAAGCGAGTTGTAAAAGGAAATTTCAGAAATCTGACTTCCGCAATTAATGCAGATGGTCTGTTAATGGTAACTCTATTTAGCACTCACTTTAATACATATTCTAAAATACTTCTTTAAAAATTACTACTACTACTACTACTGGCGATGGGTGGCTCAAGTGGTTGAGTCTGCCTTTGGCTTGACGTCAGGGTCCTGGAGTCCTGGGATCGAGTCCCACATCAGACCCCCAATGGGGAGCCTGCTTCTCTCTGTGTGTCTCTCATGGATAAATAAATAAATCTTTAAAAAGAAATTACTACTACTGTTACTTCACAATCAGACTATTCTATCATCCCTATTTTCCAATAATTAAGCATCTGGCTGGGAAAGCAAAACACAGTTAGTTACACAAAAGATAAGACAAAGGACCTACATTTCCAACAAAGCTAGACCGCATATTACACACCAACCCTCTTGCAATTAAAAAGTTAGACAAATGTATATTTTTTTTAATTCTTAAAAATATCAGAGGATATAAACTGGTGCAACCGCTTTGAAAAACTGATAGTTAACTACTGAAGCTAAATTATATCTACCAACAGCACCATACCCAGGAATACTTCCAAAAGAAGGAAGTGCATATCCGACAAAATACACATGTAAGAATGTTTGTAGCAGATTTATTATAGTAGTCCAAAATTGGAAATGATGCAAATGCCATTAAAAGTAGAATGGATAACCAAACTGTGATAGATCTGTATATGAGGCTACTACTATAGCACACTGTATTTTCCAATAATGGTGCCTACAATACTTCTGGTCTCACAAGCTCTTCCAGAACCTCAACTCCCCCCATCAAGAGGTAGAGTCCATTTCCCCTCTCTTTAAACCTCGGCAGGCTCATAACTGCTTCAAAGAGCAGAATACAATGGAAGGAAAATTGCATTAAGTTTCAAAGCCAAGTCATAAGAGGCAATCTAGTGTCTGTCTGGCCCATGGGCTCTCCACCCCACTCCACTCCCCACTGCCTGTGGGTGCAGGACACTAGCCCTTGGAACACTGCCACCGTACTATTAAGCACAGTCAGGCCACATTTAGGTGTTCCGTCATCAACCAGCAGACATGTGAGTAAACCTTCAAACACTTTTAGGCCCAGCCTTCAAACAGCCCTACTTGAAACCAAATGAAGCTAAGACAAGCATTGCACAAATTACAGTGTTGTGCAGAAAATATATGTTGTCACTGTTTAAGTCACTGAGTTGCTAGGCAATTTTTTAGGTGCTACAGTAACTACAAGTACAGTAACTACAAGAAACACTACTGCTATGTGCAACAACACAGCTGAATTTCACTGATACTATACAATGTTGAACAAAACAAGCCAGATCAGACACACGGGAGTAAAACATACCGTATGATACTATTTTGAAAAGAAAACTAAAAACTGCAAAACTGTTGACAGAAAACCAAGTAATTGCAACCTGCATCAGGAAAGGAAGATATAGATGGGGAAGGGGTGTGACAAGGTCTTCTGGGGTGGCAAAAATGTTCTACATCTTGAACTGGATATGATTACATATTTAGTTACATTCATAAAAATTCTTCAGGTTATACATTTAAGATTGGTGCACATTATTATATGTATATTATACCTTAATGAAAACGCAGGAGAGGATAGTAATCAAAGAGCTAACAAGGTAATAAGGAACTACTAGGCACAGTAGTCCAAGAGGACAGAGAGGAGCACAGCACCCTGGGGTCTCTTGTCCCCTGGAAATGCCTGCCTAATCAAAAAACTGCATGTAGGCAGGCTAGGAAAGTAGGAAGACAAAATGTCAGAGTACAAGATCCACCAAAGGAGCCATCCCTTGCTTTAGAATAAGACCCCAAAAAGCTGAATCCTGGAAGAGAGAACACAGAAGGAAACTAAACCAGTCATTGCATAGATAGACTCAAAAAAACAAACACAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
->URS00023D8047 lncRNA from 1 species 
-TAGGGTTTGATTTAGGGTTTAGGGTTTGGTTTAGGATTTGTTTGGAATTTGGTTTAAAGTTTGTTTAGAGTTTGGTTTAGGATTTAGGGTTTGATTTAGGATTTAGGATTTTATTAGGATGTAAGATTTAATTAGTTTTGGCCTAAAGTTTGAATGAAGTTCAATAGGATTTTGACTAGAATTAAATTAAGATTGAATTGAGATGTATTTGAGTGATATTTGTGATCATTCTAATATTTCTTTAAGAATTTTTATTGTTGATTTGAAATTTCTTTGAGGTTTTTTTGTATTTGATTAAGCTTGCATAGCATTATTATGGTCTAATTAGAGCATTTTTAGTATTCTATTAGAATTAGAATTTTGTTATTGTAATTTCCATTCTTTCTTGTAGAGCTAAATGCCCAGAGCA
->URS0001D8C773 rRNA from 1 species 
-TCCTGGAAATAGCCTCCCTATTAGACCGTACCCGAAACCGACACAGGTGGTCAGGTAGAGAATACCAAGGCGCTTGAGAGAACTGCGTTGAAGGAACTCGGCAAATTGCACGCGTAACTTCGGAAGAAGCGTGACCCTCACTCACGCAAGTGGATGAGGGTGGCACAGACCAGGGGGTAGCGACTGTTTATCAAAAACACAGG
->URS00006048F4 rRNA from 1 species 
-GAAATCCCTCGGGATGTAAACTTCGCAAGAACGGGAAGAATAAGTAGGGGACAATACCCCCTATGATGACGGTACCGTTTGTAAGCTCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGGGGGAGCAAGCGTTGTTCGGATTTACTGGGCGTAAAGGGCGCGTAGGCGGCCAGCACAAGTCAGTTGTGAAATCTCCGAGCTTAACTCGGAAAGGTCAACTGATACTGTGCGGCTAGAGTGCGGAAGGGGCAACTGGAATTCTTGGTGTAGCGGTGAAATGCGTAGATATCAAGAGGAACACCTGCGGCGAAGGCGGGTTGCTGGGCCGACACTGACGCTGAGGCGCGAAAGCTAGGGGAGCGAACGGGATTAGATACCCCGGTAGTCCTAGCCTTAAACGATGAATGCTTGGTGTCTGGGGTTATAAAGTCCCCGGGTGCCGTCGCTAACGCTTTAAGCATTCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAG
->URS0000A15EFB rRNA from 1 species 
-AGCAGAGCACGTCCTACGGGAGGCGAGCAGTGGGGAATCTTAGAGCAATGGGGAAACCCCTGATCTAGCCATGCCGCGTGAGCGATGAAGGCCTTAGGGTTGTAAAGCTCTTTCAGCTGGGAAGATAATGACGGTACCAGCAGAAGAAGCCCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGCATGCAGGTGGTTTGTTAAGTCAGATGTGAAAGCCCGGGGCTCAACCTCGGAATTGCATTTGAAACTGGCAGGCTAGAGTACTGTAGAGGGGGGTAGAATTTCAGGTGTAGCGGTGAAATGCGTAGAGATCTGAAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACAGATACTGACACTCAGATGCGAAAGCGTGGGAGCAAACAGGATTAGATACCCTGGTAG
->URS0001056185 rRNA from 1 species 
-TACCAGCACCCCGAGTGGTCGGGACGATTATTGGGCCTAAAGCATCCGTAGCCGGTTCTGCAAGTCCCCCGTTAAATCCAGCTGCTCAACAGATGGGCCGCGGAGGATACTACAGAGCTAGGAGGCAGGAGAGGCAAGCGGTACTCAGTGGGTAGGGGTAAAATCCGTTGATCCATTGAAGACCACCAGTGGCGAAGGCGGCTTGCCAGAACGCGCTCGACGGTGAGGGATGAAAGCTGGGGGAGCAAACCGGGATTAGAA
->URS000182C5B8 rRNA from 1 species 
-ACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGGCGGAAGCCTGAACCAGCCAAGTCGCGTGAAGGATGAAGGTATTATGTATTGTAAACTTCTTTAGATGCAGAGAAATAAGCCCCTCGCGAGGGGTGATGCTAGTATGCATAGAATAAGGATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATCCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGTGCGCAGGCGGCGCGTTAAGTCAGCGGTGAAATGCAGGGGCCCAACCCCGGCAGTGCCGTTGATACTGGCGTGCTGGAATGCGGTCGAGGCGGGCGGAATGTGGCGTGTAGCGGTGAAATGCATAGATATGCCACAGAACTCCGATAGCGAAGGCAGCTCGCCAGGCCTGCATTGACGCTCAGGCACGAAAGCGTGGGGATCGAACAGGATTAGATACCCTGGTA
->URS0002400B5F lncRNA from 1 species 
-TTTATTGATGAAGAAGGGTGTAGAAGTATTTTTGTGGTTTTTTTTTTGTAGAGAAAGGACAGGAATGTTTTTGTGTTTTTTGTTTATTATGACTGGGCCATATAGAATATGGTTGCCTACGTACTCCCGTGTATCAGGGAGATCAGGTCGACGTAGTTCACCCCTCAGGATGAATTGCAGTTGAAGAGAAGTGTGAATCCCATGTGCATGCTATACTGCGGGGAGAAGAAAGTTTGATACCATGATGGGGACAAACTGTAGGTTTGGAAAAAGTTTGATCCCGTCTTTAAGACAAACTGCAAGCGTAGAAAAGTTTAATCCCGTCTTCAGGATAAACTGCAGGTGTGAAAGGTTCAATTCCGTCTTCTGGATAACCGAAATTGTATGGAAGGTTTGAAATGAGGTGAAACTAGGCTGCTGGTTTGAAGTGTATATTTCCCTGAGGAGCAGAAGAGTATGTATAAAAGGTTAGAAACCGG
->URS00004FA46A piRNA from 1 species 
-TCTGAAACCAGAGGTACAGGTGTA
->URS000239D036 lncRNA from 1 species 
-AAGTGAGGGTTAATATAATTTTTCTACTCCTAATATTGGTTTTTATTTAGAAGAATCATAAACTACCGAAGTTTAAAGAGACTATGCTTTTAGATTCTAAGCCCAATGATTTGGGCATATAGTAATGGGTAAATCTTTTATGATTGGCACTGCATACATTAACGAATTGGTATGCATGCTACATATACAAAATTAATTTGCAGATCTAAATTCAGATGATGTGAGATTTATCTAACTTCATTTATACACTGACAGTATAGAAAAGTTAATCCATATTAATAGGATAAATCTTTTCTGTATCGACACTGTATACATTAGTGGATTTAGATGCATGCCACACACATAAAATCTCAGGGGTACCAAGTTATATTTCTAAAACCACAGGGGGCCAAGTGATGTTAAGAGAAACTTCAAAGGAGGTTTCTAATATTATTCCAACACATATTCAGTAGGCAAAAGATACTATTTCAATTATTTAGGTGGCAACGAGTTTTTTTTTGGCCTTATCACTGCATGTGATACTCGTGTACAAGGACAAAACTAGGGGATTAGGGCTGAAGTTTTATAGAATTCAATTTTCCTCCCTTACAAAATTACATATTGTCAAATCAAATAATCTTGCTCCCGAAAAAACCTAAAGATATTTATATTATA
->URS00001FA05A rRNA from 1 species 
-AGAGTTTGATCCTGGCTCAGATTGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGGCAGCATGAGATGGGGTAACCCATTTTGATGGCGAGTGGCGGACGGGTGAGTAATATGTAGGAATCTACCTAGAGGAGCGGGATAACTTAGGGAAACTTAAGCTAATACCACATAATCCCTACGGGGGAAAGCAGGGGACCGCAAGGCCTTGCGCCTTATGATGAGCCTACATCGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGATGATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGGGCAACCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGCCTTAGGGTTGTAAAGCACTTTCAGTGGGGAGGAAGTTTATTGTGTTAATACCATAATGAATTGACGTTACCCACAGAAGAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAATACAGAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGGGTGTGTAGGTGGTTGCGTAAGTTAGATGTGAAATCCCCGGGCTTAACCTGGGAACTGCGTTTAAAACTGCGTAGCTAGAGTATTGCAGAGGATAGTGGAATTTCCAGTGTAGCGGTGAAATGCGTAGATATTGGAAGGAACACCAGTGGCGAAGGCGACTATCTGGGCAGATACTGACACTGAGACACGAAAGCGTGGGGAGCAAACAGGA
->URS0001FB0CF8 rRNA from 1 species 
-GGGCACCGGGGGGGTGCCTAATACATGCAGTCGAACGCGTTGGCCCAATTGATTGATGGTGCTTGCACCTGATTGATTTTGGTCGCCAACGAGTGGCGGACGGGTGAGTAACACGTAGGTAACCTGCCCAGAAGCGGGGGACAACATTTGGAAACAGATGCTAATACCGCATAACAGCGTTGTTCGCATGAACAACGCTTAAAAGATGGCTTCTCGCTATCACTTCTGGATGGACCTGCGGTGCATTAGCTTGTTGGTGGGGTAATGGCCTACCAAGGCGATGATGCATAGCCGAGTTGAGAGACTGATCGGCCACAATGGGACTGAGACACGGCCCATACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCACAATGGGCGCAAGCCTGATGGAGCAACACCGCGTGAGTGAAGAAGGGTTTCGGCTCGTAAAGCTCTGTTGTTAAAGAAGAACACGTATGAGAGTAACTGTTCATACGTTGACGGTATTTAACCAGAAAGTCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGATTTATTGGGCGTAAAGAGAGTGCAGGCGGTTTTCTAAGTCTGATGTGAAAGCCTTCGGCTTAACCGGAGAAGTGCATCGGAAACTGGATAACTTGAGTGCAGAAGAGGGTAGTGGAACTCCATGTGTAGCGGTGGAATGCGTAGATATATGGAAGAACACCAGTGGCGAAGGCGGCTACCTGGTCTGCAACTGACGCTGAGACTCGAAAGCATGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCATGCCGTAAACGATGAGTGCTAGGTGTTGGAGGGTTTCCGCCCTTCAGTGCCGGAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCTACGCGAAGAACCTTACCAGGTCTTGACATCTTGCGCCAACCCTAGAGATAGGGCGTTTCCTTCGGGAACGCAATGACAGGTGGTGCATGGTCGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTTACTAGTTGCCAGCATTAAGTTGGGCACTCTAGTGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGACGACGTCAGATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGACGGTACAACGAGTCGCGAACTCGCGAGGGCAAGCAAATCTCTTAAAACCGTTCTCAGTTCGGACTGCAGGCTGCAACTCGCCTGCACGAAGTCGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGAGAGTTTGTAACACCCAAAGTCGGTGGGGTAACCTTTTAGGAGCCAGCCGCGAAGGTGGAACAGGAT
->URS0001125F2F rRNA from 1 species 
-TACGGGGGGGGCAAGCGTTGTTCGGATTACTGGGCGTAAAGGGCGCGTAGGCGGTCAGCACAAGTCAGTTGTGAAATCTCCGGGCTTAACCCGGAAAGGTCAACTGATACTGTGCGACTAGAGTGCGGAAGGGGCAACTGGAATTCTCGGTGTAGCGGTGAAATGCGTAGATATCGAGAGGAACACCTGCGGCGAAGGCGGCATCCTGGACCGGTATTGACGCTGAGGCGCGAAAGCCAGGGGAGCAAACGGG
->URS00020FB289 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACAGATGAGGAGCTTGCTCCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTCCCTATAAGAGTGGGATAACTTCGGGAAACCGGATCAAATACCGGATAATATATTGAACCGTGTGGTTCAATGGTGAAAGACGGTTTTGCTGTAACTTATAGATGGTTCCGCGCCGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGGTACGATGCGTAGCCGACCGGCGAGGGGGATCGGCCACACGGGAACTGGGACACGGTCCAGGCGCCTACGGGAGGCAGCAGTAGGGAATGGTCCGCAATGGTCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACAAATGTGTAAGTAACTATGCACGTCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTG
->URS000014A96C rRNA from 1 species 
-AGCCATGCATGTCTAAGTATAAACTGCTTATACTGTGAAACTGCGAATGGCTCATTAAATCAGTTATAGTTTATTTGATGGTACCCACTACTCGGATAACCGTAGTAATTCTAGAGCTAATACGTGCGTACATCCCGACTTCTGGAAGGGACGTATTTATTAGATAAAAGGCCAGCCGAACTTTGTTCGACCTGCGTTGACTCATGATAACTTCACGAATCGCACGGCCTTGTGCCGGCGATGTTTCATTCAAATTTCTGCCCTATCAACTTTCGATGGTAGGATAGAGGCCTACCATGGTGGTAACGGGTGACGGAGGATTAGGGTTCGATTCCGGAGAGGGAGCCTGAGAAACGGCTACCACATCCAAGGAAGGCAGCAGGCGCGCAAATTACCCAATCCCGACACGGGGAGGTAGTGACAATAAATAACAATACCGGGCATTTAATGTCTGGTAATTGGAATGAGTACAATCTAAATCCCCTAACGAGGATCCATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTTAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGGATTTCGGGTGGGTGCTAGCGGTCCGGCTCTGCTGTGTACTGCTAGTGCCTATCTTTCTGTCGGGGACGGGCTCTTGGGCTTCATTGTCCGGGACTCGGAGTCGACGTGGTTACTTTGAGTAAATTAGAGTGTTCAAAGCAAGCGTTCGCTGTGAATACATTAGCATGGAATAACACGATAGGACTCTGGCTTATCTTGTTGGTCTGTAAGACCGGAGTAATGATTAAGAGGGACAGTCGGGGGCATTCGTATTTCATTGTCAGAGGTGAAATTCTTGGATTTATGAAAGACGAACTTCTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTGGGGGCTCGAAGACGATTAGATACCGTCGTAGTCTCAACCATAAACGATGCCGACTAGGGATTGGCAGGTGTTTCGTTGATGACCCTGCCAGCACCTTATGAGAAATCAAAGTTTTTGGGTTCCGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGGCGGAAGGGCACCACCAGGCGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTTACCAGGTCCAGACACGGGGAGGATTGACAGATTGAGAGCTCTTTCTTGATTCTGTG
->URS00019D9398 rRNA from 1 species 
-TGGCGGCGTGCCTAATACATGCAAGTCGAGCGGACAGAAGGGAGCTTGCTCCCGGATGTTAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCTGTAAGACTGGGATAACTCCGGGAAACCGGAGCTAATACCGGATAGTTCCTTGAACCGCATGGTTCAAGGATGAAAGACGGTTTCGGCTGTCACTTACAGATGGACCCGCGGCGCATTAGCTAGTTGGTGGGGTAATGGCTCACCAAGGCGACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTTTTCGGATCGTAAAGCTCTGTTGTTAGGGAAGAACAAGTGCGAGAGTAACTGCTCGCACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAGGGTCATTGGAAACTGGGAAACTTGAGTGCAGAAGAGGAGAGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCTCTGACAACCCTAGAGATAGGGCTTTCCCTTCGGGGACAGAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGATCTTAGTTGCCAGCATTCAGTTGGGCACTCTAAGGTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGACAGAACAAAGGGCTGCAAGACCGCAAGGTTTAGCCAATCCCATAAATCTGTTCTCAGTTCGGATCGCAGTCTGCAACTCGACTGCGTGAAGCTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAGAGTTTGCAACACCCGAAGTCGGTGAGGTAACCTTTATGGAGCCAGCCGCCGAAG
->URS0000FD7098 rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGCTCGGAATCACTGGGCGTAAAGGGTGCGTAGGCGGGTCTTTAAGTCAGGGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTTGATACTGAAGATCTTGAGTTCGGGAGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGATACTGACGCTGAGGTGCGAAAGCTAGGGGAGCAAACGGG
->URS000131717B rRNA from 1 species 
-TACGAAGGTGGCAAGCGTTACTCGGAATTACTAGGCGTAAAGGGCAGGTAGGCGGTTTGGTTAGTCTGTTGTGAAAGCTCCTTGCTTAACGGGGAGAGGCCAACGGATACTGCCAGACTTGAGTATAGGAGAGGGTACTGGAATTCCCGGTGTAGCGGTGAAATGCGCAGAGATCGGGAGGAACACCAATGGCGAAAGCAGGTACCTGGACTATTACTGACGCTCAGCTGCGAAAGCTAGGGGAGCAAACAGG
->URS000115C7E9 rRNA from 1 species 
-TACGGAGGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCACGTAGGCGGCTTTGTAAGTTAGAGGTGAAAGCCCGGAGCTCAACTCCGGAACTGCCTTTAAGACTGCATCGCTTGAACGTCGGAGAGGTAAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAAGGCGGCTCACTGGACCGGTACTGGCGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGG
->URS0000E4B3A6 misc_RNA from 1 species 
-GCGTCCGTTTCTGTCCTGTCGTCGAGGGAAGCGCTGGGATTTATCCCAGCCGTCCCTCGACGGTCGTGTTGAGGCGTCGTCCGGGAACGGGCGTCCCTTCAAGTGCGAA
->URS00023A6056 lncRNA from 1 species 
-TACTTTGGCTAAAGACTTCCAGAATCATCGATCTATGATATCACATAGGATGTTTGCTCTCCTTATTAGGAGTGACTGATCCCTCATTGATTACTCACAACCTTCATGCATACTTTACCACATCCAAAATATCCCATATAAGGATCAAAGAATCAAGTTAGGTAGTGAACCAAAATATGGATTCATGTACACAAGGTATTATGACGATCTCAGGTCAAAGGATCACTTACACAACTCCCATT
->URS0000CE10A7 sRNA from 1 species 
-TTATTACAAAAAAATGCTGTTTAATTTCACATGATAGAGTTATATGGTAGAACGGTTTGGATTGATATTATGGAATATATACCACGCGTAAAATCTTAAAATTAAATAT
->URS000013D6AF rRNA from 1 species 
-CAAATGACTCTCGGCAATGGATATCTTGGCTCTTGCATCGATGAAGAACGTAGTGAAATGCGATACTTGGTGTGAATTGCAGAATCTCGTGAACCATTGAGTCTTTGAACGCAAGTTGTGCCCGAGGCCTTGCGGTCGAAGGCACGCCTGCTTGGGCGTCATT
->URS0002063A20 rRNA from 1 species 
-TTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGATGAAGGGAGCTTGCTCCTGGATTCAGCGGCGGACGGGTGAGTAATGCCTAGGAATCTGCCTGGTAGTGGGGGATAACGTCCGGAAACGGGCGCTAATACCGCATACGTCCTGAGGGAGAAAGTGGGGGATCTTCGGACCTCACGCTATCAGATGAGCCTAGGTCGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCCGAAACTGGTCTGAGAGGATGATCAGTCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGTCTTCGGATTGTAAAGCACTTTAAGTTGGGAGGAAGGGCAGTAAGTTAATACCTTGCTGTTTTGACGTTACCAACAGAATAAGCACCGGCTAACTTCGTG
->URS0001992F3F lncRNA from 1 species 
-CAGAACCGAAGATCGCTTACGTTTCCACACGGACCCGTTTTAGTGACGTACCCATCTGCCGTCAGCTTCTGTAAGTTTGGTGACTTGATTTTAATCGTGTTCTGTTCATTTACCTGCTTCCTAAACATAGGTGAACTCTTCTAATGTCTACCATAGAGACTTGCTGTAAGCTACAGACGTCTTTTCTGAATGGAGAAGATGGAGGATTATCCACTCTACTGCATCAAATGATTCCAGCATTACTGATCTGCACCCTAGAATATCCTGGAATAATCACTTGTGCAGTTTTGATGACATCTCTTGAAGTGTTATGA
->URS0001E8D186 rRNA from 1 species 
-TGAGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGCAGGAAGAAGCATCTATGGTGTGTATCCTGCTTTTGTACGGGAAGAAACACTCCTTCGTGAAGGAGCTTGACGGTACCGTAAGAATAAGGATCGGCTAATTCCGTGCCAGCATCCGCGGTTATACGGAGGATCCCAGCGTTATCCGGAATCATTGGGTTTAAAGGGTCCGTAGGCGGTTTAGTAAGTCAGTGGTGAAAGCCCGTCGCTCAACGATGGAACGGCCATTGATACTGCTAGGCTTGAATTATTAGGAAGTAGATAGAATATGTAGTGTAGCAGTGAAATGCTTAGATATTACAAGGAATACCAATTGCGAAGGCAGGTTACTACGAATGGATTGACGCTGATGGACGAAAGCGTGGGGAGCAAACA
->URS000118D854 rRNA from 1 species 
-TACAGAGGGGGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCGCGTAGGCGGCCTTCTAAGTCGAACGTGAAATCCCCGGGCTCAACCCGGGAACTGCGTCCGATACTGGAAGGCTTGAATCCGGGAGAGGGATGCGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCGGTGGCGAAGGCGGTTCTCTGGGCATTGCCTGACGCTGAGGAGCGAAAGTGTGGGGAGCGAACAGG
->URS00010E7D1D rRNA from 1 species 
-TACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCGCGTAGGCGGTGCGGTAAGTCACCTGTGAAATCTCCTGGCTCAACTGGGAGCTTGCAGGCGAAACTGCCGTGCTGGAGTGTGGGAGAGGTGCGTGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCTGTGGCGAAAGCGGCGCACTGGACCACAACTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACAGG
->URS00009F8AF6 misc_RNA from 1 species 
-CCTGTTGAAGATGGAAGAGTTGGCTGAGATGCCACGGATGTGTTTGACCCTTTTGAAAAAAAGTTGCCTGGGACATCAGTTACAGGTTGAGCAGCAGATCCAGTTGAAGCTTGATAGCCAACTTGTGAAGCAACAGGGGCAGTAGAGCCTTGTGGGAAAATGTTTTCATTGTTAAACTGTGGAGTTGGTCCTATTGCATTTTGATGAGCAACTTGTAAGCCTACTGGGGCAGCAGAACCCTGTTGTTGGAAAAGGTTTCCATTGTTAAACTGTGGAGTTGGTCCCGTTGCATGGTAAGCAGCT
->URS0002410C40 lncRNA from 1 species 
-CAGTCTCTCTCTAACTTTATCCTGGTATAGCATCCGTCTCTTATCCTTTATCTCTGTGAATCTCTCTCGCTAACTCTTTCTCTCTCTTGGAGCATAAAAATCCATCCATCTCAAACTTAGTGGTTTACTTCTTTACTATGTTTTTAGATAGAAAAAGAACTTGGGTATTTTGTTGTTATAGAGAAGAAAGGAAGAATAAATTCCTAAGTTCTTTATCTTTCAAAGCTTCCGCTCAACTTTAGCTTTTAACCCAAAAGAATCTCTTCATTTTGACGCGCCCACAGCCACAAAAAACAGCAACAGTAAGTCAGTCACAGAGTTGGTGGCAAAAAATCTCTTCACATCAGGATTAGGTTTGGGGATTGGGTGTGAGAGAGAAGCAGCAGGCAAATATACAAAATCTCAAAGAAGATCGAAGGATTAGGTTTGGGGATGAGCCTTAATCTGTTTTTTTTTTTTTCCTAAAAATGTTAGGC
->URS0002280BA0 misc_RNA from 1 species 
-GAAATGCGATAATTAATGTGAATTGCAGAATTCAGTGAATCATCGAGTCTTTGAACGCACATTGCGCCCCCTGGTATTCCGGGGGGCATGCCTGTCCGAGCGTCATTGCTACCCTCAAGCACGGCTTGTGTGTTGGGCTTCCGTCCCTGGCAACGGGGACCGGCCCAAAAGGCAGTGGCGGCACCATGTCTGGTCCTCGAGCGTATGGGGCTTTGTCACCCGCTCCCGTAGGTCCAGCTGGCAGCTAGCCTCGCAACCAATCTTTTTAACCAGGTTGACCTCGGATCAGGTAGGGATACCCGCTGAACTTAAGC
->URS00016372AB rRNA from 1 species 
-CAGTCGCCGCGGTAATACCGAGGGTGCGAGCGTTAATCGGATTTACTGGGCGTAAAGCGTGCGTAGGCGGCTTTTTAAGTCGGATGTGAAATCCCTGAGCTTAACTTAGGAATTGCATTCGATACTGGGAAGCTAGAGTATGGGAGAGGATGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGATGGCGAAGGCAGCCATCTGGCCTAATACTGACGCTGAGGTACGAAAGCATGGGGAGCAAACAGGATTAGATACCCGTGTAGTCCCTGTCTCTTATAA
->URS00017BF492 rRNA from 1 species 
-TACGTAGGGTCCGAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGTAGGCGGTTTGTCACGTCGGGCGTGAAAACTCAGGGCTCAACCCTGAGCGTGCGTTCGATACGGGCAGACTAGAGGTATGCAGGGGAGAACGGAATTCCTGGTGTAGCGGTGGAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCGATACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS00019F2EB9 rRNA from 1 species 
-GGCGGGTTTCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAGGGTCATTGGAAACTGGGAAACTTGAGTGCAGAAGAGGAGAGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCTCTGACAACCCTAGAGATAG
->URS000031863D rRNA from 1 species 
-TTGGCGGACGGGTGAGTAACGCGTGAGTAACCTGCCTTCAAGAGGGGGATAACATTCTGAAAAGAATGCTAATACCGCATAATGTCGCAAGACCAAAGAGGGGGACCTTCGGGCCTCTTGCCATCGGATGTGCCCAGATGGGATTAGCTTGTTGGTGGGGTAACGGCTCACCAAGGCGACGATCCCTAGCTGGTCTGAGAGGACGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCATG
->URS00002862DB rRNA from 1 species 
-CGGGTGAGTAACACGTGAGCAACCTGCCTTTCAGTGGGGGACAACAGTTGGAAACGACTGCTAATACCGCATAACGTGCCGGAAGGGCATCCTTTTGGTACCAAAGATTTATCGCTGAAAGATGGGCTCGCGTCTGATTAGATAGTTGGTGAGGTAACGGCCCACCAAGTCGACGATCAGTAGCCGGACTGAGAGGTTGATCGGCCACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAG
->URS0002137456 rRNA from 1 species 
-GAAAGTAAGAAAGGGCGTATGGCGGATGCCTAGGCTCACGGAGGCGATGAAGGACGTGATAAGCTGCGATAAGCTTCGGGTAGGTGCAAATAACCCTTGATCCGGAGATTTCCGAATGGGACAACCTAGCCGTCTGAAGGACGGTTACTCAATCTTCAAGGTTGAGAGCTAACGCAGGGAACTGAAACATCTTAGTACCTGCAGGAAGAGAAAATAAATGAATGATTCCCCTAGTAGTGGCGAGCGAACGGGGAACAGCCCAAACCGTTGACGTCGCAAGGCGCCAGCGGGGTTGTAGGACCGCGACATTGTATGCAAATCGTGAACAGAACACTTTGGAAAATGTGACCATAGACGGTGATAGTCCAGTATGTGAAGCGAAATGCAGCATAGCGGTATCCTGAGTAACGCGGGACACGAGGAATCCTGCGCGAATCTGCCGGGACCATCCGGTAAGGCTAAATACTCCCGTGAGACCGATAGCGAACGAGTACTGTGAAGGAAAGGTGAAAAGAACCCCGAGCAGGGGAGTGAAATAGTTCCTGAAACCATACGCCTACAAGCGGTCGGAGCATCTTACGATGTGACGGCGTGCCTTTTGCATAATGATCCTACGAGTTACCGTCACTGGCGAGGTTGAGTGTCACGAGACACGTAGCCGCAGTGAAAGCGAGCCTGAACAGGGCGCATAGTCAGTGGGGGTAGACGCGAAACCAAGTGATCTACACTTGGCCAGGATGAAGTCCCGGTAACACGGGATGGAGGTCCGCACCAATAAGCGTTGAAAAGCTTCTGGATGAGCCGAGTGTAGGAGTGAAAGGCCAATCAAACTTGGAGATAGCTCGTACTCCCCGAAAGGCATTTAGGTGCCGCGTCGGATGGTCACCGTGAGAGGTAGAGCGACCGATAGGACAAGAGGGCTTCACCGCCTATCGAGTCCTGACGAACTCCGAATGCTCACGGTCTGCAGTCCGGCAGTAAGGGGGCGGGTGCTAAGGTCCGTCCCCGAGAGGAGAAGAATCCAGACCGCCGTCTAAGGTCCCGGAGTTCTGCCTGAGTTAGTCTAACGAAGTCTGGTCCCCGCGACAGCTAGGATGTTGGCTTGGAAGCAGCCATTCATTTAAAGAGTGCGTAACAGCTCACTAGTCGAGGAGTCGGGCGTGGATAATAATCGGGTATTAAGTTGTCTACCGAAGCAGTGGGATCATTAATATGATCGGTAGGGGAGCATTCCAGTCGGCGTCGAAGGCGTACCGTGAGGTATTCTGGAGCGTCTGGAAAAGCAAATGTAGGTATAAGTAACGATAAAGGGGGCGGGAAACCCCCTCGCCGAAAGACTAAGGTTTCCTGATCAACGCTAATCGGATCAGGGTCAGTCGGGTCCTAAGGCTCAGCCGAACGGCGATGCCGATGGCAGAAACGGTTAATATTCCGTTACTACCTTCAGGAGTGACGTGGAGACGCAGTAGTGACAGTGCCGCCATCTGACGGAATAGATGGTTGAAGGGTGTAGGAGTCGATCATGGCAGGCAAATCCACCATGAGATCCGAACCTGATAGTATGCCGCGTCCTTCGGGACAAGGCAATAGTGCGCGTAAGCATGCTGCCGAGAAAATCCGCTAAACTTAATCCTGCAGGTACCCGTACCGCAAACGGACACACGTAGTCGGGATGAATATTCTAAGGCGCTTGAGTGATTCACGGTTAAGGAACTAGGCAAACTGACCCTGTAACTTCGGGAAAAAGGGTCCCGTCTCGCAAGAGCGGGCGCAGAGAATAGGTCCAGGCAACTGTTTAACAAAAACACAGGGCTGTGCGAAGTTTAAAGACGAAGTATACAGCCTGACACCTGCCCGGTGCCGGAAGGTTAAGAGGAGACGTCATCGCAAGAGAAGCGTTGAATTGAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGG
->URS000140E52B rRNA from 1 species 
-TACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGCCTTTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAAGGTCATTGGAAACTGAAAGGCTTGAGTACAGAAGAGGAAAGCGGAATTCCACGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAATACCGATGGCGAAGGCAGGTCTCTGGGCTGACACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGG
->URS0001C1D63F rRNA from 1 species 
-AGTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGGCAGCACAGTAAGAGCTTGCTCTTACGGGTGGCGAGTGGCGGACGGGTGAGGAATACATCGGAATCTACTTTTTCGTGGGGGATAACGTAGGGAAACTTACGCTAATACCGCATACGACCTACGGGTGAAAGCAGGGGATCTTCGGACCTTGCGCGATTGAATGAGCCGATGTCGGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGCACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATAGGCGCAAGCCTGATCCAGCCATACCGCGTGGGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTGGGAAAGAAAAGCAGCAGGTTAATACCCCGCTGTTCTGACGGTACCCAAAGAATAAGCACCGGCTAACTTCGT
->URS0000AD8EAF misc_RNA from 1 species 
-TGTGGGAGCGGGCTTGCCCGCGATAGCGGTGTGTCAGTCGATAGCAATGTTGGCTGGCAGTCAGTCATCGCGGGCAAGCCCGCTCCCACA
->URS000009FFA8 rRNA from 1 species 
-AGTCTCAGATAGCCATGCATGTCTAAGTATAAACGCTTTATACTGTGAAACTGCGAATGGCTCATTATATCAGTTATAGTTTATTTGATAATCTCTTACTACTTGGATAACCGTAGTAATTCTAGAGCTAATACATGCATAAATACCTAACTTTCGGGAAGGGTAGTATTTATTAGATTGAAACCAATTGATCTCGGTCATATTGTGGTGATTCATAATAACTTTGCGGACCGCATGGCTTTACGCCGGCGGTAGATCATTCAAGTTTCTGCCCTATCAGCTTTGGATGGTAGGGTATTGGCCTACCATGGCTTTAACGGGTAACGGAGAATTAGGGTTCGATTCCGGAGAGGGAGCCTGAGAGACGGCTACCACATCCAAGGAAGGCAGCAGGCGCGTAAATTACCCAATCCTGACACAGGGAGGTAGTGACAATAAATAACAATGCCGGGCCTTTTTAGGTCTGGCAATTGGAATGAGAACAATTTAAATCCCTTATC
->URS0001F65059 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCTCCTGCTTGCAGGGGTACTCGAGTGGCGAACGGGTGAGTAACACGTGGGTGATCTGCCCTGCACTTCGGGATAAGCCTGGGAAACTGGGTCTAATACCGGATAGGACCACATTTTGGATGGTGTGGTGGAAAGTTTTTCGGTGTGGGATGAGCTCGCGGCCTATCAGCTTGTTGGTGGGGTAATGGCCTACCAAGGCGTCGACGGGTAGCCGGCCTGAGAGGGTGTACGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAGGCCTGATGCAGCGACGCCGCGTGGGGGATGACGGCCTTCGGGTTGTAAACTCCTTTCGCTAGGGACGAAGCGCAAGTGACGGTACCTGGAGAAGAAGCACCGGCTAACTACGTG
->URS000066A79F rRNA from 1 species 
-AGCTATGGCTCTGTTGTATTAGGGATGTAGGCAGTTTCTTTCTCGTCTGATCTCGGAAGCTAAGCAGGGTCGGGCCTGGTTAGTACTTGGATGGGAGACCGCCTGGGAATACCGGGTGCTGTAGGCT
->URS0000B505A9 rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTCGTTAAGTTCGTTGTGAAAGCCCCGGGCTCAACCTGGGAACGGCAATGGAAACTGGCGGGCTTGAGTGCGGCAGAGGGGGGTGGAATTCCGCGTGTAGCAGTGAAATGCGTAGAGATGCGGAGGAACACCGATGGCGAAGGCAGCCCCCTGGGCCGACACTGACGCTCAGGCACGAAAGCGTGGGGAGCAAACAGG
->URS000084F4BB rRNA from 1 species 
-ACCTGGCTCAGGACGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGGACAGAAGGGAGCTTGCTCCCGGATGTTAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCTGTAAGACTGGGATAACTCCGGGAAACCGGAGCTAATACCGGATAGTTCCTTGAACCGCATGGTTCAAGGATGAAAGACGGTTTCGGCTGTCACTTACAGATGGACCCGCGGCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCGACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTTTTCGGATCGTAAAGCTCTGTTGTTAGGGAAGAACAAGTGCAAGAGTAACTGCTTGCACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAGGGTCATTGGAAACTGGGAAACTTGAGTGCAGAAGAGGAGAGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCTCTGACAACCCTAGAGATAGGGCTTTCCCTTCGGGGACAGAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGATCTTAGTTGCCAGCATTCAGTTGGGCACTCTAAGGTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGACAGAACAAAGGGCTGCGAGACCGCAAGGTTTAGCCAATCCCACAAATCTGTTCTCAGTTCGGATCGCAGTCTGCAACTCGACTGCGTGAAGCTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAGAGTTTGCAACACCCGAAGTCGGTGAGGTAACCTTTATGGAGCCAGCCGCCGAAGGTGGGGCAGATGATTGGGGTGAAGTCGTAACAAGGTTA
->URS0002524E6B rRNA from 1 species 
-ATGGTCGTAGCAGTTGCGATATGGATCATAGGATTCTTTTCTGTTCGCCGCAGGAGTATTTTACCTGTAAAGTTGCGATGCCGATCAAAATGCTGCTTGTTTTCTCTTCTTCCCCACATGGCCACGCCCACCGGATCTTGGACTTCACACCTCTTTCCATTATTTTTAGTTCCCGTTGGAGCGTATCTGTACGTCTGCACCTCAACAAGAATGTTCTCTCACTGGTATTTGATTAATACTACCACTAGTTTTTTGGAGAATGTTTGGTAA
->URS00020B9359 rRNA from 1 species 
-GACGAATGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTGCAGGGTACTCGAGTGGCGAACGGGTGAGTAACACGTGGGTGATCTGCCCTGCACTTCGGGGTAAGCCTGGGAAACTGGGTCTAATACCGGATAGGAACCATTTTTAGTGTGATGGTTGGAAAGTTTTTTCGGTGTAGGATGAGCTCGCGGCCTATCAGCTTGTTGGTGGGGTAATGGCCTACCAAGGCGGCGACGGGTAGCCGGCCTGAGAGGGTGGACGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCGACGCCGCGTGGGGGATGACGGCCTTCGGGTTGTAAACTCCTTTCGCTAGGGACGAAGCTTTTGTGACGGTACCTAGAGAAGAAGCACCGGCTAACTACGTG
->URS000047804E rRNA from 1 species 
-GATCCTGGCTCAGGATGAACGCTGGCGGCATGCTTAACACATGCAAGTCGAACGAAGCCATAGGAAGCTTGCTTTCTTTGAAGCTTAGTGGCGGACGGGTGAGTAACGCGTGAGTAACCTGCCCTCGAGTGGGGAATAACATCGAGAAATCGGTGCTAATACCGCATAACGTCGGAGAACCGCATGATTTTCCGACCAAAGGATTTATTCGCTTGAGGATGGACTCGCGTCCGATTAGCTAGTTGGTGAGGTAACGGCCCACCCAAGGCGACGATCGGTAGCCGAACTGAGAGGTTGATCGGCCACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGGCAATGGGCGAAAGCCTGACCCAGCAATGCCGCGTGAAGGATGAAGGTCTTCGGATTGTAAACTTCTTTGATTGGGGAAGAATAAATGACCTACCCAAAGAACAAGTCACGGCTAACTACGTGCC
->URS000041CA9B rRNA from 1 species 
-TCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTGATACGTAGGGTGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGGGCTCGTAGGTGGTTGATCGCGTCGGAAGTGTAATCTTGGGGCTTAACCCTGAGCGTGCTTTCGATACGGGTTGACTTGAGGAAGGTAGGGGAGAATGGAATTCCTGGTGGAGCGGTGGAATGCGCAGATATCAGGAGGAACACCAGTGGCGAAGGCGGTTCTCTGGGCCTTTCCTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGCTTAGATACCCTGGTAGTCCACGCTGTAAACGGTGGGTACTAGGTGTGGGGTCCATTCCACGGGTTCCGTGCCGTAGCTAACGCTTTAAGTACCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGCCCCGCACAAGCGGCGGAGCATGCGGATTAATTCGATGCAACGCGTAGAACCTTACCTGGGTTTGACATGGATCGGGAGTGCTCAGAGATGGGTGTGCCTCTTTTGGGGTCGGTTCACAGGTGGTGCATGCCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTTCACTGTTGCCAGCACGTTATGGTGGGGACTCAGTGGAGACCGCCGGGGTCAACTCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGCCCCTTATGTCCAGGGCTTCACGCATGCTACAATGGCTGGTACAGAGAGTGGCGAGCCTGTGAGGGTGAGCGAATCTCGGAAAGCCGGTCTCAGTTCGGATTGGGGTCTGCAACTCGACCTCATGAAGTCGGAGTCGCTAGTAATCGCAGATCAGCAACGCTGCGGTGAATACGTTCCCGGGGCTTGTACACACCGCCCGTCAAGTCATGAAAGTTGGTAACACCCGAAGCCGGTGGCCTAACCGTTGTGGGGGAGCCGTCGAAGGTGGGACTGGTGATTAGGAC
->URS00016BE8EB rRNA from 1 species 
-TACGAAGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCGCGCAGGCGGTCCTTTAAGTCAGGGGTGAAAGCCCAGAGCTCAACTCTGGAACGGCCTTTGAAACTAGAGGACTTGGGTACGGGAGAGGTGAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGTTACCGACGCTCAGGCGCGACAGCGTGGGGAGCAAACAGG
->URS000104102D rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTTGTAGGCGGTCTGTCGCGTCTGCTGTGAAAATCCGGGGCTCAACCCCGGACTTGCAGTGGGGTACGGGCAGACTAGAGTGTGGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGATGGCGAAGGCAGGTCTCTGGGCCACTACTG
->URS0001017A28 rRNA from 1 species 
-TACGGAGGGTGCGAGCGTTGTTCGGAATCACTGGGCGTAAAGCGCGTGTAGGCGGCCTTGTAAGTCTGGTGTGAAAGCCCGGGGCTTACCCCCGGAAGTGCACTGGAAACTGCAAGGCTAGAGTACCGGAGAGGAAGGTGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCGGTGGCGAAGGCGGCCTTCTGGACGGATACTGACGCTGAGACGCGAAAGCGTGGGGAGCAAACAGG
->URS0000908CE3 ncRNA from 1 species 
-CTGGTTAATTCCGATAACGAACGAGACTCTGTCCTGCTAACTAGGCGGGTAAACCCGGGTCGGCGTGTGCGCGGCGCTGGCGGTTTCGGCCGTCAGTGTTCGCGTACCCGTCGGCTCGGCCCGGTATCCCCGAACGCGTTCGCCCGTCGTCCACGGCGGTCGTCGGGCGCGGCCGCGCCATCCGCGTCCCGGCGTTCGGCGGGCGTATGTCGGCCGGGGGGCAACCTCCGGTCGGCCTGCGTCCGTCGTGCGTCGGGCTCCGTGGTGAAGCGCGCCGTGTTCGCGGCCGTCGCCGGCGGATCACGATACGTTACTAGGGCTACCGCCGGCTCCCAGGAGCTTAAACTCTTCTTAGAGGGACAGGCGGCGGACGAACATAGCCGCACGAGACTGAGCGATAACAGGTCTGTGATGCCCTTAGATGTTCTGGGCCGCACGCGCGCTACACTGAAGGAATCAGCGTGTTTAACAATCCTGGGCCGACAGGCTTCCGGGTAACCCGCTGAACCTCCTTCGTGCTTAGGGATCGTGGCTTGCAATTTTTCCACGTGAACGAGGAATTCCCAGTAAGCGCGAGTCATCAGCTCGCGTTGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTACTACCGATTGAACGGTCGCATTGAGGTCTTCGGAGTGGACGCGCGTTATTCGGCCCCCTCGGGGGCTGGGTCGTCGCGCGATCGCGAAGATGACCGAAATCGGCCGTTTAGAGGAAGTAAAAGTCGTAACAAGGTTTCCGTAGGTGAACCTGCGGAAGGATCATTA
->URS0001269AD4 rRNA from 1 species 
-TACGTAGGTGGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGCGCGCGCAGGCGGTGCGGTAAGTCTGTCGTGAAATCTCCCGGCTCAACTGGGAGGGTGCGGTGGAGACTGCCGGACTGGAGGCACTCAGAGGCCGGTGGAATTCCCGGTGTAGTGGTGAAATGCGTAGAGATCGGGAGGAACACCAGTGGCGAAGGCGGCCCACTGGGCCGGTACTGACGCTGAGGCACGAAGGCGTGGGGAGCGAACGGG
->URS00004A8CD5 rRNA from 1 species 
-CCTTGCCAGCCCGCTCAGAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGTATGTGGTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCCGGAGACCCTTAGGAAACTAGGGGGTGCTTCCATCTGGAAGAATCTGGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGCCTTTAGTTGCCAGCAGTTCGGCTGGGCACTCTAAAGGGACTGCCGGTGTTAAACCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCTTTATGACCAGGGCTACACACGTACTACAATGGCCGATACAAAGGGCAGCGACACTGCGAGGTGAAGCCAATCCCGTAAAATCGGTCTCAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTTGGAATCGCTAGTAATCGTGGATCAGCATGCCACGGTGAATACGTTCCCGGGCCTT
->URS000236C264 lncRNA from 1 species 
-CTGCATCCTTCCAAACAGAGAAATAGGATGAGAATCAGTATGTCTGAACTATAGGCTAAAGCGGCATGAGGTTCAGGTGCATCAACATGATTCAGTTTCCATGACCAGATTGCTCATTACAAAAATCAAAGCAGAAATATATTCCCTACACTAAAACAGAGTAAAGAGTTAGAAATATCATGGTCTCCAAGGCCACAATCCAGTTATGCACTCAAAAAGTCCAATAACGTCCAGGCTAGCAATTAAACATGCTAGCTTTCAAGTTCAACGATTCAAAGTTTATTGATTTATAACGAATCTTGAGAAGTTCCAAAGGAAGCATGCAGTGCATCATCCTAATCATTAATATCCTAAAATAAGGCTTAAATCAACAACAGCTCCAAGTATGCAGGTATCAAGAATCACCTTTGACAGCTAAATACAAGACATTTCATCTCTAATTGGCAGGTATGCTGGTAAGCTATTACAGAATAACCGATGAACAGGGTAACTATTATTTTGCTTCTTAACTGCCAGGGGGAACCAACTGAAGCATGGCATCTACATAATGTCATGTCTTGTGCCTGCTTCAGTTGCGGATCACTGAAGTAAAAATTCTTTAACCTAAATTAATAAATATACTACCAGAAGCAAGAGAGTCAAAAATGAAATGGATTACTAAGTATTACCAATCACATACATTTCCAACAGTCATATCAGAAGCTTCAAATTAACTAATAGATTTAAGATTTCGAATATCTCCCTCATTCCTTTATAATATTTTGTAGGTCACTTGGAAAGAAACGAATAGGAGGGTTTTGATGGGCTTTATTTGGCCTTTTGTAGATATGGATCATTGGCTCCAAAATTCTCTGTTTTTTTTGCTTAAAGATCATCCTCTCTCCCCTAAGTAGGATCGTGAAGAGCTTGATATTTTGACCAGCTTGCAACCTATGGTTTCGTATATGAATGCCACTTCCTTGCTGTCTTGTTAATATACTTAAAAAAATAATAATAAATTTTTAACCTGCCTTGAGCAGGCTTAAATTTAAGGATTATAACAGCAAGAACTTATTTATTATTTTTAAATATTGATATTAACAATGGTACCAATGGGGCACCACCCATATATAATATATTTACATGTCAATTAAAACTTCAATGACATTTCCAAAATTTTCCGGCCTATTAATGTCATGACCCAAAACCAAGAAACCAAAAATATGAATTCATCTATCTCTAATATTAACAAACTCCCTTTTTATTTCTTCAAATGCTCTAACATTCCTTTCTTTCCACACGACCCAAAAAATAGATAAAGGAATCAGAAGAAGATAAGTTTTCTTTGTACATAAGCCCGCCCAAGCCCACAACTCATCTCTCGCCAACCCTGCAATCACCCAATTGATCCCTAGGAGACCGTACACCATAGACCAAATACCATACACCATTGGGCACCATAGCAAAATATGGTTACATGATTCTGCATCCATCTTAAATAAAAGCAGTGATTAACTAGAATTTTGCCCCTCCACCTCAGCCTATCAATAGTTAGGATGCATTCTCTACTCATTTCACAAGCAACCAAAAAACAATTGTTGGTGGTGCCTTCGTCTTCCATATCTATTTAACTGGATAATGGACAGTTTCACTCCTTTTTCCCCTAGTCAAATGCTTGTAGAAGGTCTTTACAGAGTAATCTTCTTGTTTCCTCAATTTCCACATCAACTGGTCCCTTCGATCATCTAATTGAATTTGAGATAACAGGAGTAATAAGGCTTCATACTCTTCGATAATTATTGAGATTTCTTGTGACGTTCATATTCCACCCCCTACTCCCGCTCGCTGTCAAGTGAGCCTCCTCCGCCACCATGTTCTTTGATGACACAATGGCGAAGATCGCTGGAAACTGATCTTTCAGCCTATCCTCACCAACCCATTCATTCTTTCAAAAATGAATTCTATCGCCCTTATCCACCTTCCTCTTTGTGCATTCAAGAAATTTGTGTTTCTCCACACTAATTTTCTTCTATTCACATCCCTGACGTCCTCACCCACTTCCCTCACACCCCACAGAGCCTCCACAACAAGAACTTATTTATAAGTTGCGAGTGAAATATCAACACCACCTTCCATACACTAAATTATTATTATTGGACATTTGCACAAAGAAGTACTCAAATTAATTTACCATGAAAAGGAAATAATGCTCATACAGTATAATGGCCATTAATAAATGCTATTTTAGAACTCATAAAAGCCACTTAGTGTCTAAAAATTGAACAAATTCAGCTTTCAGATATAAAAGAATTAGATATCCCAGCAAAAAGAGAGAATTTCATGTCATATTATTGTTAGAAACTTGGGACTTCTTGCAAGCATTTTAGCAAATATGAAAAAAATCACAAAAGAACTTTGCCTACTACCATCCTCAGTCTCATCAAACTCCATCCTAATGCGATATACATGACTATGTTGCTTCGGTTTGACCTTGTGCAAAGCCCTAGGCTCTCTATGGTTTTTGCTAAAAAAATGTGACCTGTAATTCTGTGTACAATCATCAAACAATAACTGCACTAAATATCATGCAAATACAAAAAGTTGTTTCCTATCAAGTATTTCACAGTTTCTCTCTCAAAAAGTTTTCCATAGTTTTTTATCTCATGTCATATCTCATTTGTGTAGCATGCATACATACATAATAGTCATAACTGCATGTAAAGAATTGACATGCTAGATACATGACTGAAATAACTTACTGAGAAAGCCAACATGAGAGAAAAACTAAGATGAAGCAAAGCAAAATATCCAGTAAATTTTACTACATCCCATACCTTATACTGGTCATGCTATTAATATGTAGGCAAGTAAAACGACAAGACCTAAGCATGCTTCTTAAAACCAGCTGAGAAAAATTAGACAAAATCTAGCAGAAATTATAATAGATCTATCTCCAAATTGTAGTTTCCTGTTTATGGATGCGAATCAAGAAAAATAAATGCCCAAACTATCATAATGACAAGCAAATGCAAGAAAACAAGTTCACAATACAAAATACAGAAGTACAGATCTATGATATTTCTTTTAAAGATAGGGAGGAAGAAAATATCACAAACAATGTAGAAG
->URS000135D842 rRNA from 1 species 
-GACGAACGCTGGCGGCGCGCTTAACACATGCAAGTCGAGCGAAGCGGCGGACGGGAGAGTAACACATGAGTAACCTGCCTCAGACATTGGGATAGCCGCGGGAAACCGGGATTAATAGCAAATGGTCTAAGATGGCCTCGCGTCTCATTAGCTCGTTGGTGAGGTAACGGCCCACCAAGGCGACGATGGGTAGTCGGTCTCAGAGGGTGGACGGCCACATTGGAACTGGGAAGCGGTCCAGACTCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGAGGGAGCTATGAAGATTCGATGCCGCGTGAACGAAGAAGGCTTTCGAGTCGTAAAGTTCTTTTATATGGGCAGTGGTACCATAAGACAAAGGCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATAC
->URS0002034EF4 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTGTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGATGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTG
->URS00025BECD2 rRNA from 1 species 
-ATGCGGGTGGTTGGACTTGTGGTCATGGAAAGCGCTAGGAAAATACCAAGCTCTAGGGTCACTAACATTAAAGAGGGAGATGCCAACACCCGCTATTTTCACTCGAAGATCAATGGAATTCGGTGGAAAATCCTAATTCACCGCCTTAAGCATGGGAGTGGCGGGGTAACGGATCACGACTACAAGAAGGCCATTATCCATGCTCACTTCTCAGCTATGATGAAAAAGAGCAACCCACGCGCTAAGAGCGTCAATTGGGCTTCCATTCCTGCTGCCGACCATGACCTATCCCATCTTGGGGACCCCATCATGGAGGAGATCAAGGCTGCGATTTTTGCCCTCCCTAGTGACAAGGCTCACGGGCCTGACGAATTCACCGGGAAATTCTGCAAAGAATATTGGGATATTATCAAAGATGGCATCATGCTTGTGATCAATAACTTCTCGGGCCTCCACACGAAAAAAATTCACTGGCTAAACTCGACTAATCTTGCTCTCATCCACAAGAAAGATGGCGTCGAGGACATCACTAACTTAGGCATATTAGGCCCAAGGAGCTTGGAGGATCCATGCGCACTGGCGTGCACTTCCCCTGTTCAGGGCGCCATGACGCAGCCTTTAAAGGAGCAACCGGTAGTCAAGGACGACCTGGTTGGCCACGGCGTCACCGGTGGAGGACACTCGGAAGTTGATGGTGCGGATGGCGGGTGGGGAGGGGGGGTCACCGACGCCGGAGAAGAGTCTGAACCTAGAGGAATGGCGGGGGCAGCGGCAAGGCAATGA
->URS0002234228 rRNA from 1 species 
-GGTTAAGTTGTTAAGGGCGCACGGTGGATGCCTTGGCACTAGGAGCCGATGAAGGACGGTACTAACACCGATATGCTTCGGGGAGCTGTAAGTAAGCTTTGATCCGGAGATTTCCGAATGGGGAAACCCACTGCTCGTAATGGAGTAGTATCTTCACCTGAATTCATAGGGTGATGATGGCAGACCCGGGGAACTGAAACATCTAAGTACCCGGAGGAAGAGAAAGCAAACGCGATTTCCCAAGTAGCGGCGAGCGAAACGGAAGAAGCCCAAACCAAGAGGCTTGCCTCTTGGGGTTGTAGGACACTC
->URS0000D4A060 sRNA from 1 species 
-CTCCTGTCTGCAGGATTTACGCGCACGTTGGAACCGAAGAGAGCTCTGTTGTTGCAATGTTCAGCCCACAAGACCTTACTGGTGAAGGAATGGGACAAGACCCATCTTTATGCAAAGCCAGCGTTACAGTAATGTCCCAGCATCTCATAATCTATCCTGGGGAATTCAGCTGCCTCCCAGGGTGAATACAGGTATTCCTGATGACAGTCTGCCTTCTATCTTACAGAGCAGCTTGTTGCTATATACCATTGAAAAGCCTTCAGAGCTGAGAGGTTAGTTGATATTTTTTGTTCCTTACAGCTTATGCCACCAAGTAGGCAGTTTCTATGATGAATCAAACTAGCTCACTATGACCGACAGTGAAAATACATGAACACCTGAGAAACTGGAGAACGCAGGGAGTGGGGGGTAACCATGTCTGAGGAATCTTTCACCCACAGCTTTGTTTTTCTCTAGGTACTACTAACCAATAACCTGCTTGGCTCAAAGGGCCAGCACCTTCTCTCTAAAGCCCAAGAGGAGTTTGAGGTAAA
->URS0001621A90 rRNA from 1 species 
-ATACAGAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGCGCGTAGGCGGCTTGGTCAGTCGGATGTGAAAGCCCTGGGCTCAACCTGGGAATTGCATTCGATACTGCCAAGCTAGAGTATGGGAGAGGGAAGTGGAATTTCCGGTGTAGCGGTGAAATGCGTAGATATCGGAAAGAACACCAGTGGCGAAGGCGACTTCCTGGCCCAATACTGACGCTGAGGTGGGAAAGCGTGGGGAGCGAACAGGATTAGAAACCCTAGTAGTCC
->URS000183796A rRNA from 1 species 
-CACGTAGGGTGCAAGCGTTGTCCGGAATCATTGGGCGTAAAGAGCTCGTAGGCGGCTTAGTAAGTCGGGTGTGAAAACCCCAGCTCAACCTGGGGACGCCACCCGATACTGCTATAGCTAGAGTCCAGTAGGGGAGTGTGGAATTCCCAGTGTAGCGGTGAAATGCGCAGATATTGGGAGGAACACCAGCGGCGAAGGCGGCACTCTGGGCTGGAACGTGACGCTGAGGAGCGAAAGCGTGGGTAGCAAACAGG
->URS0001FEE94D rRNA from 1 species 
-GATGAACGCTGACAGAATGCTTAACACATGCAAGTCTACTTGAACTTCGGTTTGGGTGGCGGACGGGTGAGTAACGCGTACAGAACTTGCCTCACAGTTAGGGACAACATTTGGAAACGAATGCTAATACCTGATATTATGATTTTAGGGCATCCTAGGATTATGAAAGCTATATGTGCTGTGAGAGAGCTTTGCGTCCCATTAGCTAGTTGGAGAGGTAACGGCTCACCAAGGCGATGATGGGTAGCCGGCCTGAGAGGGTGAACGGCCACAAGGGGACTGAGACACGGCCCTTACGCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGACCAAAAGTCTGATCAAGCAATTCTGTGTGCACGATGACGTTTTTCGGAATGTAAAGTGCTTTCAGTTGGGAAGAAAAAAATGACGGTACCAACAGAAGAGGTGACGGCTAAATACGTG
->URS0001E248AA rRNA from 1 species 
-AACGAACGCTGGCGGCATGCCTAACACATGCCAGTCGAACGAGACCTTCGGGTCTAGTGGCGCACGGGTGCGTAACGCGTGGGAACCTGCCCTTAGGTTCGGAATAACTCCCCGAAAGGGGTGCTAATACCGGATAATGTCTTCGGACCAAAGATTTATCGTCTTTGGATGGGCCCGCGTTGGATTAGCTAGTTGGTAGGGTAAAAGCCTACCAAGGCGACGATCCATAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCAATGCCGCGTGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTTACCCGGGATGATAATGACAGTACCGGGAGAATAAGCTCCGGCTAACTCCGTG
->URS00001C5077 rRNA from 1 species 
-AGAGTGGGGGATAACGCAGCGAAAGCTGTGCTAATACCGCATACGATCTAAGGATGAAAGCAGGGGACCGCAAGGCCTCGCGCTCATGGAGCGGCCGATGTCAGATTAGGTAGTTGGTGGGATAAAAGCTTACCAAGCCGACGATCTGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGAAA
->URS000002F2FF rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGGTAACAGGGGGCTTCGGCCCGCTGACGAGTGGCGGACGGGTGAGTAATACGTAGGAATCTACCTTTTAGTGGGGGATAAACTTAGGGAAACTTAAGCTAATACCGCATAATCACTACGGTGGAAAGCAGGGGCTCGCAAGACCTTGCGCTGATAGATGAGCCTACGTCGGATTAGCTTGTTGGTAGGGTAAAGGCCTACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGGGCAACCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGCC
->URS0000AD69CA ncRNA from 1 species 
-GACCGGAAGGCCGTGTGGACTGTATAGAAGAGAGAATGTTGGCATGAGTAGCGAGAGGTGAGTGAGAATCTCACCCATCGAAAGCCTAAGGTTTCCTGAGGAAGGCTCGTCCACTCAGGGTAAGTCGGGACCTAAGCCGAGGCCGAAAGGCGTAGGCGATGGACAACTGGTTGATATTCCAGTACCACCTTTAAACGTTTGAGAGATGGGGTGACACAGAAGGATAGACTATCGCACTGATGGAATAGT
->URS00025CD331 rRNA from 1 species 
-ATGGCCAATGGATTTTACACTTCGTCATCGGCCTACAAGGTGCAATTCGAGGGGACTGTGGCCTCCAACATGACACGGGTCGTTTGGGGCAATTGGGGGCCTCCCAAGTGCAAATTATTTGCGTGGCTTGTCATCATGAATCGGGTTTGGACGGCGGATTGGCTTCGGAGGAGAGGATGGCCAAATTATAACTTATGTCAACTCTGTAAGAGGGAGCCTGAGACGGCGGCGCACTTCCTCTTGCATTGCAGGTTCTCCACACGCATTTGGAATGCGGTTAAGTGTTGGCTCGTCGTTCAGGAGTTGGATATCGCCACCTGGGCTGGGATCCCCACGGTCAAGCAATGGTGGGAGAAGACCGTCCTTGGACGAGGTCACAGGAGGAAGGCCGTGTCCTCTCTTCTAATGCTTGTATCATGGGAGCTGTGGAACGAGAGGAATGCGAGGGTGTTCCAAAAGAAAGCCACGATGCCGACCGTTGTGGTCAATCGTATCAAGGCGGAGTCTAGAAATTGGGTTCTGGCCGGGGCAAAACATATGGGATATTTGATGCCGCGAGAGTAG
->URS0001ED03C2 misc_RNA from 1 species 
-CAAGAAGCCGAAAGGCTACTTAAAACCATCGCGAACTTATCCAAGTTGCTTCGGCGGCGCGGCTCCCCTCACGGGGGACCGCAGCCCCCGCCTCTCAGGAGGTAAGGGGCAGCCGCCGGAGGTACGAAACTCTGTATTATAGTGGTATCTCTGAGTATAAAATAAATAAGTTA
->URS0001607725 rRNA from 1 species 
-GCAAGTCGAGCGAGAAGCCATCCTCGGGTGGTAAAGAGCGGCGAACGGGTGAGTAACGCGTAGGTATCTACCTAGTAGTGGGGAATAACCATTGGAAACGATGGCTAAAACCGAACGCCCTGAGGGGGAAAACTGAGGTGCTATTAGAGGAGCCTGCGTTAGATTAGCTAGTTGGTGAGGTAATGGCTCACCAAGGCGACGATCTATAGCTGGTTTGAGAGGATGATC
->URS0001D85733 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCTGCTTTCCCTTGTGGATTGCGGGTACTCGAGTGGCGAACGGGTGAGTAACACGTGAGTGATCTGCCCCCAACTTGGGTATAAGCCTGGGAAACTGGGTCTAATTCCCGATAGGACTGCAGGGTGGTGCCTGTGGTGGAAAACGATTTTCTAGTGGTTGGGGATGAGCTCGCGGCCTATCAGCTTGTTGGTGGGGTAATGGCCTACCAAGGCGGCGACGGGTAGCCGGCCTGAGAGGGTGGACGGCCACATTGGGACTGGGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAGTATTGCACAATGGGCGGAAGCCTGATGCAGCGACGCCGCGGGGGGGATGACGGCCTTCGGGTTGTAAACTCCTTTCGACCGCGAGGAAGCCACCTGGTTGGAAGGGTGGTGACGGTAGTGGTAGAAGAAGCACCGGCTAACTACGTG
->URS00025A5E17 rRNA from 1 species 
-ATGGGTTTCCGTGACATCCACTGTTTCAACCTGGCTCTGCTTGCAAAACAAGCATGGCGTCTCCTTGATAATCCTGACTCCTTGTGTGCTACTATTCTAAGGGCCAAGTACTATCCTAATGGTGATTTGCTGAACTCCAAGCCAAAGCATGGTGCTTCCTTCACCTGGCAAAGCATTATGGCAGGCATCACTACTCTTAAGCGAGGTTATATTTGGCGAGTGGGGGATGGACATAACATCAATATTTGGGAAGATGCCTGGATCCCAAATTGTGCCTCTAGGAAGATTATGACACCTAGGGGGGGGCATTTGTTATCAAAAGTCGTAGATTTAATTGACCCAGTCTCCAATAATTGGGATGAGGACCTGATTAGACAAACTATGTGGACCGTTGACGTACAACGAATTCTTTCAATCGCAATTTCGCAACATAATATGACGGATTTTATTGCCTGGAGTTATACGAAAAATGGTATGTTTTCGGTACGGTCTGCTTATTTAGTGGAGTGGAACTATCAATATGGGAGCAAGCTAAAATATTCCAATGGGATGGGACGGAGCACACCTAATCCTATATGGTGTCAGATATGGAAGTTGTCTTGTCTGGCTAAAGTCAATTTTTTTATGGCGGACACTACATGGCACTCTCCCATGCCGGGCAACACTCACTAA
->URS00017A11C2 rRNA from 1 species 
-TACGGAGGGTGCGAGCGTTGTCCGGAATCACTGGGCGTAAAGGGCGCGTAGGCGGCTTTTTAAGGGTGCGGTGAAAGCCCGGGGCTTAACCCCGGGTCGGCCGTGCCGACTGAAAAGCTGGAGCACTGTAGAGGCAGGTGGAATTCCGGGTGTAGCGGTGGAATGCGTAGAGATCCGGAAGAACACCAGTGGCGAAGGCGGCCTGCTGGG
->URS00012833E7 rRNA from 1 species 
-AGCGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGGACCCTTCGGGGTTAGTGGCGGACGGGTGAGTAACACGTGGGAACGTGCCTTTTGGTTCGGAATAGCTCCTGGAAAGGGGTGGGAATGCCGAATGTGCCCTTCGGGGGAACGATTTAACGCCTTTAGAGCGGCCCGCGCCTGATTAGCTGGTGGGTTGGGGTAATGGCCCACCAAGGCTACGATCAGTAGCTGGTCTGAGAGGATGACCAGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCCGCAGTGGGGAATCTTGCGAAATGGGCGAAAGCCTGACGCAGCCATGCCGCGTGGATGATGAAGGTCTTAGGATTGTAATATCCTTTCACCGGTGAAGATAATGACTGTAGCCGGAGAAGAAGCCCCGGCTAACTTCGTGCCAGCCGCCGCGGTAAGAC
->URS0001D3FFBA rRNA from 1 species 
-AGTGAACGCTGGCGGCATGCTTAACACATGCAAGTCGCACGGGCAGCAATGTCAGTGGCGGACGGGTGAGTAACACGTAGGAATGTGTCTTGAGGTGGGGGACAACCCTGGGAAACTAGGGCTAATACCGCATATGTCCTGAGGGACAAAGCAGCGATGCGCCTTGAGAGTAGCCTGCGTCCGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCGGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGGGTGAAGAAGGTCTTCGGATCGTAAAGCCCTTTCGGCGGGGACGATGATGACGGTACCCGCAGAAGAAGCCCTGGCTAACTTCGTG
->URS0000E6A59F rRNA from 1 species 
-ATCTACAGCCATACCACCCAGAAGGCTCCCAATCTCGTCTGATCTTGAAAGCTGAGCAGGGTTGGGCCTGGTTAATACTTGGATGGTAGAAAACAGTGTGAAGTCGAGG
->URS00000EB6A6 rRNA from 1 species 
-CTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCAGTGAGGAAGGTGGGTATGTTAATAGCATACTCATTTGACGTTAGCTGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGCATGCAGGTGGTTTGTTAAGTCAGATGTGAAAGCCCGGGGCTCAACCTCGGAATTGCATTTGAAACTGGCAAACTAGAGTACTGTAGAGGGGGTAGAATTTCAGGTGTAGCGGTGAAATGCGTAGAGATCTGAAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACAGATACTGACACTCAGATGCGAAAGCGTGGGGAGCAAACAGGATTAGATAACCTGGTAG
->URS000167F6B8 rRNA from 1 species 
-TACAGAGGTGGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCGCGTAGGCGGCCTTCTAAGTCAGACGTGAAATCCCCCGGCTTAACCTGGGAACTGCGTCTGATACTGGGAGGCTAGAGTGCGGGAGAGGGATGCGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAATACCGGTGGCGAAGGCGGCATCCTGGACCGGCATTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS0000D6C981 ncRNA from 1 species 
-AAAGGGCCAAAGGCGCCCGGACGAGGTGCGCCGTACCCGGCCAGCGACAAGACGGCGTAAG
->URS0000E05209 SRP_RNA from 1 species 
-GCCATGAGCGATGTCACCCACCTATAATCCAGCTACCAGGGAAGCTGAGCCTGGTAGATCTTTAGTTTAAGAGTTCTGAGCTTTAGTGAGCCATGTTGATGGGATGTTCACACTAAGTTTGGCATCAGTGTGGTGAGCCCCTGGAATTAGAGGACCACTAGGTTGTCTAAGAAGGGTTACAAATGGGAGCAGGTTAGAGCTCCCAGACCACTTAGTAGTGGGATCAGGCCTGTGAGCAGCCCCTGTACCAGTTCCAGCTCAGAGTGAGATGGAGAGACCCAGTCTTT
->URS0000BAE8CB rRNA from 1 species 
-CCTACGGGACGCAGCAGTGAGGAATATTGGTCAATGGCCGGGAGGCTGAACCAGCCAAGTCGCGTGAGGGAAGACGGCCCTACGGGTTGTAAACCTCTTTTGTCAGGGAGCAAGGTGCAGGTCGGGACCTGCTGTGAGAGTACCTGAAGAAAAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAAAACGTAGGGTGCAAGCGTTGTCCGGAATTACTGGGTGTAAAGGGAGCGCAGGCGGATTGACAAGTTGGGAGTGAAAACTACGGGCTCAACCCGTAACCTGCTTTCAAAACTGTCAGT
->URS00000F1EB4 rRNA from 1 species 
-GCTGGCGGCGTGCTTAACACATGCAAGTCGAACGAACCTTCGGGTTAGTGGCGGACGGGTGAGTAACGCGTGAGAATCTGCCCTCAGGAGGGGGATAACGGTTGGAAACGACCGCTAATACCCCATATGCCGCGAGGTGAAATGAATTTCGCCTGAGGATGAGCTCGCGTCTGATTAGTTAGTTGGTGGGGTAAAGGCCTACCAAGACATCGATCAGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGGGATGAAGGCCTCTGGGCTGTAAACCTCTTTTATCAAGGAAGAAGATCTGACGGTACTTGATGAATAAGCCACGGCTAATTCCGTGCCAGCAGCCGCGGTAATACGGGAGTGGCAAGCGTTATCCGGAATTATTGGGCTTAAAGCGTCCGCAGGCGGTCTGTCAAGTCTGCTGTTAAAGCGTGGAGCCTAACTCCATTTCGGCAGTGGAAACTGACAGACTA
->URS0000D30CB5 rRNA from 1 species 
-GGATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGGGTGAAGAAGGCCCTAGGGTTGTAAACCCCTTTCAGCGGGGAAGATAATGACGGTACCCGCAGAAGAAGCCCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCGCGTAGGCGGACCTGCAAGTCGGGGGTGAAAGCCCGAGGCTCAACCTCGGAACTGCCTTCGATACTGCGGGTCTCGAGTCCGGGAGAGGTGAGTGGAATTCCTAGTGTAGAGGTGAAATTCGTAGATATTAGGAAGAACACCAGTGGCGAAGGCGGCTCACTGGCCCGGTACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAA
->URS00003ED92D rRNA from 1 species 
-AACTTCTGAATGTTGACCTCGGATCAGGTAGGAATACCCGCTGAACTTAAGCATATCAATAAGCGGAGGAAAAGAAACCAACAGGGATTGCCCTAGTAACGGCGAGTGAAGCGGCAACAGCTCAAATTTGAAATCTGGCTCTCGGGCCCGAGTTGTAATTTGTAGAGGATACTTTTGATGCGGTGCCTTCCGAGTTCCCTGGAACGGGACGCCATAGAGGGTGAGAGCCCCGTCTGGTTGGATGCCAAATCTCTGTAAAGTTCCTTCAACGAGTCGAGTAGTTTGGGAATGCTGCTCTAAATGGGAGGTATATGTCTTCTAAAGCTAAATACCGGCCAGAGACCGATAGCGCACAAGTAGAGTGATCGAAAGATGAAAAGCACTTTGAAAAGAGAGTTAAAAAGTACGTGAAATTGTTGAAAGGGAAGCGTTTATGACCAGACTTGGGCTTGGTTAATCATCTGGGGTTCTCCCCAGTGCACTTTTCCAGTCCAGGCCAGCATCAGTTTTCCCCGGGGGATAAAGGCGGCGGGAATGTGGCTCTCTTCGGGGAGTGTTATAGCCCACCGTGTAATACCCTGGGGGGGACTGAGGTTCGCGCATCTGCAAGGATGCTGGCGTAATGGTCATCAACGACCCGTCTTGAAACACGGACCAAGG
->URS00001448B3 rRNA from 1 species 
-AACGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGCCCAGCAATGGGAGCGGCAGACGGGTGAGTAACACGTGGGAACCTTCCCTATAGTACGGAATAGCCCAGGGAAACTTGGAGTAATACCGCATACGCCCGAGAGGGGAAAGATTTATCGCTATAGGATGGGCCCGCGTAGGATTAGCTAGTTGGTGAGGTAATGGCTCACCAAGGCGACGATCCTTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGAGTGATGAAGGCCTTAGGTGTAAGCTCTTTGCCGGGGACGATAATGACGGTACCCGGAGAATAAGCCCGGCTAACTTCGTGCCAGCAGCCGCGGTAAT
->URS000098BB64 pre_miRNA from 1 species 
-TTTTTAGTATCAGTATGTCCCATACAGTATTGGGGACATACTGATGCTAAAA
->URS0001061001 rRNA from 1 species 
-TACGTAGGGGGCAAGCGTTGTCCGGATTCATTGGGCGTAAAGAGCGTGTAGGCGGCCAGGTAGGTCGGTTGTGAAAACTGGAGGCTCAACCTTCAGAGGTCGACCGAAATCATCTGGCTAGAGTCCGGGAGAGGAGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCCGTGGCGAAAGCGGCTCTCTGGAACGGTACTGACGCTGAGACGCGAAAGCGTGGGGAGCGAACAGG
->URS0000C64DF9 hammerhead_ribozyme from 1 species 
-ATCCAGCTGACGAGTCCCAAATAGGACGTGACGCGCGTCGTGTAT
->URS000215D057 rRNA from 1 species 
-TTAAGCGACTAAGCGTACACGGTGGATGCCCTGGCAGTCAGAGGCGATGAAGGACGTGCTAATCTGCGATAAGCGTCGGTAAGGTGATATGAACCGTTATAACCGGCGATTTCCGAATGGGGAAACCCAGTGTGTTTCGACACACTATCATTAACTGAATCCATAGGTTAATGAGGCGAACCGGGGGAACTGAAACATCTAAGTACCCCGAGGAAAAGAAATCAACCGAGATTCCCCCAGTAGCGGCGAGCGAACGGGGAGCAGCCCAGAGCCTGAATCAGTGTGTGTGTTAGTGGAAGCGTCTGGAAAGGCGCGCGATACAGGGTGACAGCCCCGTACACAAAAATGCACATGCTGTGAGCTCGATGAGTAGGGCGGGACACGTGGTATCCTGTCTGAATATGGGGGGACCATCCTCCAAGGCTAAATACTCCTGACTGACCGATAGTGAACCAGTACCGTGAGGGAAAGGCGAAAAGAACCCCGGCGAGGGGAGTGAAAAAGAACCTGAAACCGTGTACGTACAAGCAGTGGGAGCACGCTTAGGCGTGTGACTGCGTACCTTTTGTATAATGGGTCAGCGACTTATATTCTGTAGCAAGGTTAACCGAATAGGGGAGCCGAAGGGAAACCGAGTCTTAACTGGGCGTTAAGTTGCAGGGTATAGACCCGAAACCCGGTGATCTAGCCATGGGCAGGTTGAAGGTTGGGTAACACTAACTGGAGGACCGAACCGACTAATGTTGAAAAATTAGCGGATGACTTGTGGCTGGGGGTGAAAGGCCAATCAAACCGGGAGATAGCTGGTTCTCCCCGAAAGCTATTTAGGTAGCGCCTCGTGAATTCATCTCCGGGGGTAGAGCACTGTTTCGGCAAGGGGGTCATCCCGACTTACCAACCCGATGCAAACTGCGAATACCGGAGAATGTTATCACGGGAGACACACGGCGGGTGCTAACGTCCGTCGTGAAGAGGGAAACAACCCAGACCGCCAGCTAAGGTCCCAAAGTCATGGTTAAGTGGGAAACGATGTGGGAAGGCCCAGACAGCCAGGATGTTGGCTTAGAAGCAGCCATCATTTAAAGAAAGCGTAATAGCTCACTGGTCGAGTCGGCCTGCGCGGAAGATGTAACGGGGCTAAACCATGCACCGAAGCTGCGGCAGCGACACTATGTGTTGTTGGGTAGGGGAGCGTTCTGTAAGCCTGTGAAGGTGTGCTGTGAGGCATGCTGGAGGTATCAGAAGTGCGAATGCTGACATAAGTAACGATAAAGCGGGTGAAAAGCCCGCTCGCCGGAAGACCAAGGGTTCCTGTCCAACGTTAATCGGGGCAGGGTGAGTCGACCCCTAAGGCGAGGCCGAAAGGCGTAGTCGATGGGAAACAGGTTAATATTCCTGTACTTGGTGTTACTGCGAAGGGGGGACGGAGAAGGCTATGTTGGCCGGGCGACGGTTGTCCCGGTTTAAGCGTGTAGGCTGGTTTTCCAGGCAAATCCGGAAAATCAAGGCTGAGGCGTGATGACGAGGCACTACGGTGCTGAAGCAACAAATGCCCTGCTTCCAGGAAAAGCCTCTAAGCATCAGGTAACATCAAATCGTACCCCAAACCGACACAGGTGGTCAGGTAGAGAATACCAAGGCGCTTGAGAGAACTCGGGTGAAGGAACTAGGCAAAATGGTGCCGTAACTTCGGGAGAAGGCACGCTGATATGTAGGTGAAGTCCCTCGCGGATGGAGCTGAAATCAGTCGAAGATACCAGCTGGCTGCAACTGTTTATTAAAAACACAGCACTGTGCAAACACGAAAGTGGACGTATACGGTGTGACGCCTGCCCGGTGCCGGAAGGTTAATTGATGGGGTTAGCCGCAAGGCGAAGCTCTTGATCGAAGCCCCGGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGCGTAATGATGGCCAGGCTGTCTCCACCCGAGACTCAGTGAAATTGAACTCGCTGTGAAGATGCAGTGTACCCGCGGCAAGACGGAAAGACCCCGTGAACCTTTACTATAGCTTGACACTGAACATTGAGCCTTGATGTGTAGGATAGGTGGGAGGCTTAGAAGTGTGGACGCCAGTCTGCATGGAGCCGACCTTGAAATACCACCCTTTAATGTTTGATGTTCTAACGTTGACCCGTAATCCGGGTTGCGGACAGTGTCTGGTGGGTAGTTTGACTGGGGCGGTCTCCTCCTAAAGAGTAACGGAGGAGCACGAAGGTTGGCTAATCCTGGTCGGACATCAGGAGGTTAGTGCAATGGCATAAGCCAGCTTGACTGCGAGCGTGACGGCGCGAGCAGGTGCGAAAGCAGGTCATAGTGATCCGGTGGTTCTGAATGGAAGGGCCATCGCTCAACGGATAAAAGGTACTCCGGGGATAACAGGCTGATACCGCCCAAGAGTTCATATCGACGGCGGTGTTTGGCACCTCGATGTCGGCTCATCACATCCTGGGGCTGAAGTAGGTCCCAAGGGTATGGCTGTTCGCCATTTAAAGTGGTACGCGAGCTGGGTTTAGAACGTCGTGAGACAGTTCGGTCCCTATCTGCCGTGGGCGCTGGAGAACTGAGGGGGGCTGCTCCTAGTACGAGAGGACCGGAGTGGACGCATCACTGGTGTTCGGGTTGTCATGCCAATGGCACTGCCCGGTAGCTAAATGCGGAAGAGATAAGTGCTGAAAGCATCTAAGCACGAAACTTGCCCCGAGATGAGTTCTCCCTGACCCTTTAAGGGTCCTGAAGGAACGTTGAAGACGACGACGTTGATAGGCCGGGTGTGTAAGCGCAGCGATGCGTTGAGCTAACCGGTACTAATGAACCGTGAGGCTTAACCTT
->URS00016AAB81 rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCTTAACACATGCCAGTCGAGCGAGCGTCGGACGGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACTGGAAACGGTCGCTAATACCGCATTCCATCCTATGTGCCCATATGGGATTAGCTAGTAGGTGGGGTAATGGCTAACCTAGGCGACGCTCCCTAGGTGGTCTGAGAGGATGACCAGCGAGACTGGAACTGAGAGACGGACGAGACTAGTACGGGAGGCAGCAGTGGGGAATAGTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCGTTCGGGTTGTAAAGAACGTTCAGCGAGGAGGCGTTACTCGCAGAAGAAGCAACGGCTAACTCCGTGCCAGCAGCAGCGGTAATTC
->URS00018C3972 rRNA from 1 species 
-TACGTAGGGGGCTAGCGTTGTCCGGAATCATTGGGCGTAAAGCGCGCGCAGGCGGTTAATTAAGTTGGGTGTTTAAGCCCGGGGCTCAACCCCGGTTCGCATCCAAAACTGGTTGACTTGAGTGTAGGAGAGGAAAGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGCCTATAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGG
->URS00007617FE rRNA from 1 species 
-TACGTAGGGGGCGAGCGTTGTCCGGAATTACTGGGCGTAAAGAGAGCGTAGGCGGCACTACAAGTCTCATGTGAAATACCCGGGCTTAACTTGGGGGTTGCATGGGAAACTGTAGAGCTTGAGTACAGGAGAGGCAAGCGGAATTCCTAGTGTAGCGGTGAAATGCATAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCTTACTGGACGGCAACTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGG
->URS0000A668E1 tRNA from 1 species 
-TCTAAAATGACAGATGAATGTATAAGATTTAAGCTCTTACCATGGAGATTTATTCTTCTTTTAGAATC
->URS0001CAF6B7 misc_RNA from 1 species 
-GATGAAGAACGCAGCGAAATGCGATAAGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGACCGCCAGTATTCTGGCGGGCATGCCTGTTCGAGCGTCATTTCAACCATCAAGCCCCCGGCTTGTGTTGGGGACCTGCGGCTGCCGCAGGCCCTGAAAAGCAGTGGCGGGCTCGCTGTCACACCGAGCGTAGTAGCATACATCTCGCTCTGGGCGTGCTGCGGGTTCCGGCCGTTAAACCACCTTCATAACCCAAGGTTGACCTCGGATCAGGTAGGAAGACCCGCTGAACTTAAGCATATCAATAAGCGGAGGA
->URS0001A89386 rRNA from 1 species 
-TAGAATTAGGGTTCGATTTCGGAGAGGGAGCATGAGAAACGGCTACCACATCTAAGGAAGGCAGCAGGCGCGTAAATTACCCAATCCTGACTCAGGGAGGTAGTGACAAGAAATAGCAAACCGGGAACCTCATGGTTTCACGGTATTGCAATGAGAACAATTTAAAACCCTTAGCGAGAATCAAGTGGAGGACAAGTCTGGTGCCAGCACCCGCGGTTATTCCAGCTCCACTAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAACCTCTGTCTGGGGCTAGTTTTGGCTTTGGTCAGGCTAGTTCTAGGCATCCGCCTACAAGACTTAGAGGGCATTCAGTTGTTCACTAGGAGTAGTAGGCATTTTACTTTGAAAAAATTAGAGTGTTTAAGGCAGGCAATCGCCCGCATATATTAGCATGGAATAATAGAATAGGACACTTTTCCATTTCGTTGGTTATTGGAATCGTGTAATGATTAATAGGGACAGTTGTGGGCATTTGTATTTAGTTGTCAGAGGTGAAATTCTTGGATTTATTAAAGACAAACTAACGCGAAAGCATTTGCCAAGGGTGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCAAAGACGATCAGATACCGTCCTAGTCTTAACTACAAACTATTCCGACTCAATGTTTGACTGGCTTATATAACCAGTTGAGCGTTGTATGAGAAATCAAAGTCTTTAGGTTCTGGGGGGAGTATGGTTGCAAAGCTGAAACTTAAAGGAATTGACGGAAGAGCACAACCAGGAGTGGATTCTGCGGCTTAATTTGACTCAACACGGGGAAACTTACCAGGTTAAAACAATAGTGGGATTGACAGTTTGAGAGCGCTTTCTTGATTGGTTGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGCTTAATTGCGTTAACGAACGAGACCTTAACCTGCTTACTAGACTGGCGATCATCAATCGTTAGCTCTTCTTAGAGGGACTTTGGTTGTTTTAACTCCAAGGAAGTTTGAGGCAATAACAGGTCTGTGATGCCCTTAGATATCCTGGGCCGCACGCGTCATACAATGACTAGTTCAGAAAGTTTTCTCCTGACCCGAAAGGGGATGGGTAATCTTGATAATACTAGTCGTGTTAGGGATCGATCTTTGCAATTATAGATCTTGAACGAGGAATTCCTAGTAAGTGCGGTTCATCAGACCGTACTGATTACGTCCCTGCTCTTTGTACACACCGCCCGTCGCTTCTACCGAGTGGGTGGTCCGGTGAGATAATTGAACTTCGCAGGTAACTGAGAGGAAAGATTATCAAACCTATCCACCTCGAGGAAGAAGAAGTCGTAACAAGGTT
->URS00018335DB rRNA from 1 species 
-TCTACGGGTGGCAGCAGTGAGGAATATTTGTCAATGGGCGTAAGCCTGAACCAGCCAAGTCGCGTGAGGGATGAAGGTTCTATGGATCGTAAACCTCTTTTATAAGGGAATAAAGTGTGGGACGTGTCCTATTTTGTATGTACCTTATGAATAAGGATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATCCGAGCGTTATCAGGATTTATTGGGTTTAAAGGGTGCGTAGGCGGCCTTGTAAGTCAGCGGTGAAAGTCTGTGGCTCAACCAAGGAATTGACGTTGAAACTGGGGGGCTTGAGTATGTTTGAGGCAGGCGGAATGCGTGGTGTAGCGGTGAAATGCTTAGATATCAGGCAGAACACCGATTGCGAAGGCAGCCTGCCAAGCCATGACTGACGCTGATGCACGAAGGCGTGGGGATCAAACAGGATTAGATACCCGAGTAGTC
->URS00021B9194 rRNA from 1 species 
-GCTTGTCTCAAAGATTAAGCCATGCATGTCTAAGTATAAATAGTATACAGTGAAACTGCGAATGGCTCATTAAAACAGTTATAGTTTATTTGATAATTGAAAATTACATGGATAACCGTGGTAATTCTAGAGCTAATACATGCTATCAAGCCCGACTTCTTGAAGGGTTGTATTTATTAGACTTAAGCCAATATTCCTTGTGTCTATTGCGATGATTCATAATAACTGATCGAATCTCAAATTTGAGATAAATCATTCAAGTTTCTGCCCTATCAACTGTCGACTGTGATATAGACGCTCACAGTGGTTTTGACGGGTAACGGGGAATCAGGGTTCGATTCCGGAGAGGGAGCCTTAAAAACGGCTACCACATCCAAGGAAGGCAGCAGG
->URS0000AFABFB rRNA from 1 species 
-TAAGGAATATTGGACAATGGGCGGGAGCCTGATCCAGCCATGCCGCGTGAAGGATGAAGGCGCTCAGCGTTGTAAACTTCTTTTGGACGGGAACAATATCCCCGACTTGTCGGGGCTTGAGGGTACCGTCAGAATAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTATCCGGAATCACTGGGTTTAAAGGGTGCGTAGGCGGTCTTGTAAGTCAGTCGTGAAATCGCTGGGCTCAACCCATGCAATTGCGATTGATACTGCTAGACTTGAATGGGGTTAAGGCAGGCGGAATGTGGCATGTAGCGGTGAAATGCTTAGATATGCCATAGAACACCGATTGCGAAGGCAGCCTGCTGGGCCTTTATTGACGCTGAGG
->URS0001536541 rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGCTCGGATTGACTGGGCGTAAAGGCGCGTAGGCGGTTTGTACAGTCAGACGTGAAATTCCCGGGCTCAACCTGGGGGCTGCGTTTGATACGTGCAGACTTGAGTTCGGAAGAGGGTCGTGGAATTCCCAGTGTAGAGGTGAAATTCGTAGATATTGGGAAGAACACCGGTGGCGAAGGCGGCGACCTGGTCCGATACTGACGCTGAGGCGCCGAAAGCGTGGGGAGCAAACAGG
->URS0000DB123A rRNA from 1 species 
-GGATGCGATCATACTAGTACTGAGGCACCGAATCCCATCAGAACTCCGAAGCTAAGCGTGCTTGGGCGAGAGTAGTACAAGGATGGGAGACCCCCGAGAAGTCCTCGTGTTGCATCCC
->URS00009B63B2 lncRNA from 7 species 
-CACACTCTGACGTTGAAACAGTTTCCATGCAGAGCGCCCCCTCTCCGCCTCCCAGTGCCCCAGGTGCCTCAGGTGTAGAGGGACTGAAGATTTTCGGGGGGCTAGCGGAATGTCAGCACTACTACTAGTGCCCATACGGCAGAATGAACTGTTTCCATGAAAACGGGGCCTAAGGAGTTGGCATCCTTATGACAGAACAGTATTTTAAAAGTCAAGGATGCCCTAAGAGCATTTCAGAAAGAGAAGATCACTTTGGGGTCCTCAAGATGGCTCACTGGGTGAGGGCACATCACCTCTAAGCATGGCAACAGGGGTTCAGTGCCTGCACCCCACACTGAGGAAGGAGGAAACGGACTCCCTCAAATCATCATCCGACCCCCACATCTGAGCAAGATCCGCCTCCCCCTCCAACACACGCA
->URS0000351846 rRNA from 1 species 
-AGAGTTTGATCCTGGCTCAGATTGAACGCTGGCGGCATGCCTTACACATGCAAGTCGAACGGTAGAGGGGCAACCCTTGAGAGTGGCGAACGGGTGAGTAATGCATCGGAACGTGCCCAGTCGTGGGGGATAACGCAGCGAAAGCTGTGCTAATACCGCATGTGATCTGTGGATGAAAGCAGGGGACTTGGTAGCAATACTGGGCCTTGTGCGATTGGAGCGGCCGATGTCAGATTAGCTAGTTGGTAGGGTAAAAGCCTACCAAGGCGACGATCTGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCCACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGCAGGACGAAGGCCTTCGGGTTGTAAACTGCTTTTGTACGGAGCGAAACGGTCTGGGTTAATACCCTAGGCTAATGACGGTACCGTAAGAATAAGCACCGGCTAACTACGTGCCAGCCGCCGCGGTAATAC
->URS000003707E rRNA from 1 species 
-AATGGCCTAACGGCTGAACCAGCAACTTGGAAGAATGTAGGTGTATTAATATTAATTAATGCAATAACGATTCTATCGTATAAAATTCTAAATAGATTAATGATAATGACTATTATCTGTTTATAAGTCTTGACCAAATTGCGTGCCAGCAGTCGCGGTAATACGTAGAAGACTAGTGTTAGTCATCTTTATTAGGTTTAAAGGGTACCTAGACGGTAAATTAAACCTTAACGGGTACTTTTTTACTAGAGTTTTATATGAGAAGGGGAGTATCCTTGAAGTAATGTTATAATATTTTAATAACAAGGAGACTGGTAAAGGCGAAGGCTGCCTTCTATTAAAAACTGACGTTGAGGGACGAAGGCTTGGGTAGCGAGAAGGATTAGATACCCTAGTAGTCCAAGCAGAAAATTATGAATGTCATAAGCTAGATTAGACTTTACAATTAAAACACTAATATATTCGGGATATTAGAAATAAAGAGTAGTTTAACTAAATAGGGTGTTAACTATAAGGAGGACAACCGCCTATAGGTAGTCTCTTCTAATGTAAGTAAATTTTAGCTTATAAATGAAAGTGTAAGCATTCCACCTCAAGAGTAAAATGGCAACATTTAAACTGAAATCATTAGACCGTTTCTGAAACCAGTAGTGAAGTATGTTAGTTAATTCGATAGTCCGCGAAAAACCTTACCACAATTTGTATATTATTAAATTATTACACGAGCTGCATGGCTGTCTTTAGTTAATGTCGTGAGATCTGGTTAACTCCTTTAATTAACGAAAACCCTCACCTTATTTATTTACATAAAGTGGTTCACCGCTATATTGGATTTGATAAGAGGGATTAAGACAAGTCATCATGGCCATAATATTGT
->URS00004A8811 rRNA from 1 species 
-CGGACGGGTTAGTAACGCGTGGGAACGTGCCCAGATCTAAGGAATAGCCACTGGAAACGGTGAGTAATACCTTATACGCCCTTCGGGGGAAAGATTTATCGGATTTGGATCGGCCCGCGTTAGATTAGGTAGTTGGTGGGGTAACGGCCTACCAAGCCTACGATCTATAGCTGGTTTTAGAGGATGATCAGCAACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATCTTAGACAATGGGGGAAACCCTGATCTAGCCATGCCGCGTGAGTGATGAAGGCCCTAGGGTCGTAAAGCTCTTTCGCCAGGGATGATAATGACAGTACCTGGTAAAGAAACCCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGGGTTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCGCGTAGGCGGATTGGTAAAGTTGGGGGTGAAATCCCGGGGCTCAACCCCGGAACTGCCTCCAAAACTTCCAGTCTTGAGTTCGAGAGAGGTGAGTGGAACTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAAGGCGGCTCACTGGCTCGATACTGACGCTGAGGCGCGAAAGTGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACACCGTAAACGATGAATGCCAGTCGTCGGGCAGTATACTGTTCGGTGACACACCTAACGGATTAAGCATTCCGCCTGGGGAGTACGGTCGCAAGATTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGCAGAACCTTACCAACCCTTGACATCCTGATCGCGGTTAGTGGAGACACTTTCCTTCAGTTCGGCTGGATCAGTGACAGGTGCT
->URS0001995650 lncRNA from 1 species 
-ATGCCTCGGGGTCACAATGCAGAGAAGGAACACTTCGCTCTGGACGCCCGGAGAGGGACAGCTGGCCTGGGTGTGCCAGCTTCCAAAGGGCGGGAGGGACTTCATCAGGGAGACCATCCGTCCAGGCGGCCCCCAGGGTCTGAAATGGCCAAGGCGTCCAGGCGGCCCCCAGGGTCTGAAATGGCCAAGGCGGGGTCCCGTCCGCCCCCTCCCCCGCAGGGCAGCCCGGGTCCCCAACGTGGGCCGGGGCGCGGGGGCGGCAGGTTTCCGGCCGGTCCCACCCAGGTCCCACCCAGCCGACTGGCCGGGGCGGGGACCCCCCAACCCCCCCAACCTTCCCGGCCCCCCCCCCCCCCGCCGGCCTCCCCAGCCCAGCCTGGTCCCGGGTCCGGAGGCGGGCGAGAGGCAGGGGGGAGGCAGAGGGGAGGGGCGGGGGGGGAGCGGGGGGAGGCGGGCTGGAGGCAGGGGGGAGGCGGGCGGGCGGGGAGGGAGCAGGGGGCAGGCGGGCGGGAGGCAGGGGGGAGACAGAGGGGAGGGGCGGGCGGGGGGGAGCAGGGGGGAGGCGGGCGAGAGGCAGCGGGGAGGCGGGAGCGAGCGGGCCGCTGCCCGGAGGCCGCGCCGCCCCGGCGCAAACATTTCCTTATGTGGTGGCTCCGCGGGGCCGGGGCGGCGCCGGGGGCTGCGGGGACGGCGGCCACGCCCGGGGCCTCGCGGCCACCCTGGCCCTCGGCTGGGCCGCCGCGCCGCGCCTGCTGGACGAGACCAAGAGGGGAGGCCCCCGCCCCGCGTGTCCCCCGCAGCGCGTCCCTCGTTCCCCTGAAGGAGGAGCAGACCCTGTGGCGCCCCGACTTGGCCCGCGCTTGTGGGGGCTCCCGGGTCCGGACGAAGAGGGGGCGCGGGGTCCCCCGGCCCGCCACCTCCCTGCCCCTCCCCGGCGCAGCCGCCCAGCGCCGCAGCCTCCTTGGCCTTGGGAGCTGCATTTGGGGGTGGAGGGATAGCGGGGCGACGGCGGGGGGATGGCCCAGGGCCGGAGCGGCGAGTGCCTCACTGGAAATGTCGCGGCTCTCGGCGGGCTCCAGGCTCCAGGCTCCAGGCTGCAGCCCTCCCGAGAGAGCTCGGCCTCAAAACCTGGAGCCCGCGGCTGCCTTCCTGCGGCCAGGGCGTCCCGAGCCTGAGGAGTGCGACCCGGCTCCGACACCCCCACCCCCACCCCCACCCGAGCTTCGCAGGTGTCTGCTCCGACCCCCCAAACTGTCCTGGGGCCTCAGGCCGGCCTCCTCGCCAATTGCAGCCTTTGAGCCAACTTTCATAGCTGATAGGGCAGGTTCCCTATGGGATATTTATTAA
->URS0000856D3B rRNA from 1 species 
-TACGTAGGGAGCAAGCGTTGTCCGGAGTTATTTGGCGTAAAGCGCTCGTAGGCGGTTCCGTAAGTCGGGTGTGAAAAATCTGGGCTCAACCCAGTGGAGCACCCGATACTGCGGTGACTCGAGTCCGGTAGGGGAGTGTGGAATTTCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGACGGCGAAGGCAGCACTCTGGGGCGGTACTGACGCTGAGGAGCGAAAGCGTGGGGAGCAAACAGG
->URS0001FB44EA rRNA from 1 species 
-ACGAACGCTTGCGGCGTGCCTAAGAAATGCAAGTCGAGCGGGGACAGCAATATCCTAGCGGCGAACGGTCGCGTAACACGTAAGCAACCTGCCTCAAAGACCGGGACAACATTCCGAAAGGAGTGCTAATACCGGATGTGGCCACCTTTTCGCATGTTTAGGTGATTAAATCAGGAAACTGGCTTTGAGAGGAGCTTGCGGCCTATCAGCTAGTTGGTGGGGTAACGGCCTACCAAGGCGACGACGGGTAGCTGGTCTGAGAGGACGATCAGCCGGACTGGGACTGAGATACGGCCCAGACTCCTACGGGGGGCAGCAATTAGGAATCTTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGGAGGAGGAAGTCCTTCGGGATGTAAACTCCTTTTAGGTGGGAAGAAACAAATGACGGTACCACCTGAATAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCGAGCGTTGTCCGAAGTTACTGGGCGTAAAGCGCGCGTAGGCGGGTCGTTAAGTGGGAAGTGAAAGGCTGGGGCTCAACCCCATGCAGTGCTTCTCATACTGGCGGTCTTGAGTGAGGTAGGGAGAAGTGGAATGGCTGGTGTAGCGGTGAAATGCGTAGATATCAGTCGGAACACCGGTGGCGAAGGCGGCTTCTTGGGCCTTTGCTGACGCTGATGCGCGAAAGCCAGGGGAGCGAACGGGATTAGATACCCCGGTAGTCCTGGCCGTAAACGATGGATACTAGGTGTAGGGGGTATCGACCCCCCCTGTGCCGCAGCTAACGCATTAAGTATCCCGCCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTACTCTTGACATCCTGCGAACTTGGCTGAGAGGCTGAGGTGCCGAAAGGAGCGCAGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAGATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCTTGTCCTTAGTTACCATCATTAAGTTGGGGACTCTAAGGAGACTGCCGGTGATGAACCGGAGGAAGGCGGGGACGACGTCAAGTCATCATGGCCTTTATGGGTAGGGCTTCACACGTCATACAATGGTCGGTACAGAGGGTCGCCAACCCGCGAGGGGGAGCTAATCTCACAAAGCCGATCGTAGTCCGGATCGCAGTCTGCAACTCGACTGCGTGAAGTCGGAATCGCTAGTAATCGCGGATCAGCATGTCGCGGTGAATACGTTCCCGGGTCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTTCACCAGAAGAGGGTAGCCTAACCGCAAGGAGGGCGCTCGCCACGGTGAGATTCATGACTGGGGTG
->URS00021EF114 pre_miRNA from 1 species 
-GCTGGTTTCCGATGGTGGCTTAGAGTGCGGTCCTCCATCTAGCACCATTTGAAATCAGTG
->URS000103BC31 rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTGTTCGGATTCATTGGGCGTAAAGGGTGCGTAGGCGGCGCGGTAAGTCGGGTGTGAAATCTTGGAGCTTAACTCCGAAACTGCATTCGATACTGCCGTGCTTGAGGACTGGAGAGGAGACTGGAATTTACGGTGTAGCGGTGAAATGCGTAGATATCGTAAGGAAGACCAGTGGCGAAGGCGGGTCTCTGGACAGTTCCTGACGCTGAGGCACGAAGGCCAGGGGAGCAAACGGG
->URS00005A39E1 rRNA from 2 species 
-GGGATGGGGGGCATGCTATACATGCAAGTCGAGCGAACTGATTAGAAGCTTGCTTCTATGACGTTAGCGGCGGACGGGTGAGTAACACGTGGGCAACCTGCCTGTAAGACTGGGATAACTCCGGGAAACCGGAGCTAATACCGGATAACATTTTCTCTTGCATAAGAGAAAATTGAAAGATGGTTTCGGCTATCACTTACAGATGGGCCCGCGGTGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCAACGATGCATAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGCTTTCGGGTCGTAAAACTCTGTTGTTAGGGAAGAACAAGTACAAGAGTAACTGCTTGTACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGGGAACTTGAGTGCAGAAGAGAAAAGCGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGGCTTTTTGGTCTGTAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCTGGTAGTGCACGCCGTAAACGATGAGTGCTAAGTGTTAGAGGGTTTCCGCCCTTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGGTCGCAAGACTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCTCTGACAACTCTAGAGATAGAGCGTTCCCCTTCGGGGGACAGAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGATCTTAGTTGCCAGCATTTAGTTGGGCACTCTAAGGTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGATGGTACAAAGGGCTGCAAGACCGCGAGGTCAAGCCAATCCCATAAAACCATTCTCAGTTCGGATTGTAGGCTGCAACTCGCCTACATGAAGCTGGAATCGCTAGTAATCGCGGATCAGCATGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAGAGTTTGTAACACCCGAAGTCGGTGGGGTAACCTTTATGGAGCCAGCCGCCTAAGGTGGGACAGATGATTGGGGTGAAGTCGTAACAACAGC
->URS000041F567 rRNA from 1 species 
-TGGATCCAGACTTTGATCATGGCTCAGGACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGAAGCTTGACGAATGATTTCTTCGGAATGAATTCCGATATGACTGAGTGGCGGACGGGTGAGTAACGCGTGAGGAACCTGCCCTTCAGAGGGGGATAGTGTTTGGAAACGAACAGTAATACCGCATAATGTATTTTTACCGCATGATAGAAATACCAAAGATTTATCGCTGAAGGATGGCCTCGCGTCTGATTAGATAGTTGGTGGGGTAACGGCCTACCAAGTCGACGATCAGTAGCCGGACTGAGAGGTTGAACGGCCACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGGGGAAACCCTGATGCAGCAACGCCGCGTGAAGGAGGACGGTTTTCGGATTGTAAACTTCTGTTCTTAGTGAAGAAAAATGACGGTAGCTAAGGAGCAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTACTGGGTGTAAAGGGGGCGCAGGCGGGAGAGCAAGTCAGTTGTGAAATCCATGGGCTTAACCCATGAACTGCAGTTGAAACTGTTCTTCTTGAGTGAAGTAGAGGTTGGCGGAATTCCGAGTGTAGCGGTGAAATGCGTAGATATTCGGAGGAACACCGGTGGCGAAGGCGGCCAACTGGGCTTTTACTGACGCTGAGGCCCGAAAGTGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACACTGTAAACGATGATAACTAGGTGTGGGGGGACTGACCCCTTCTGTGCCGCAGCTAACGCAATAAGTTATCCACCTGGGGAGTACGACCGCAAGGTTGCAACTCAAAGGAATTGACGGA
->URS000022D4E2 rRNA from 1 species 
-CGGACGGGTGAGTAACGCGTGGGGAACCTGCCCTGTACAGGGGGATAACACTTAGAAATAGGTGCTAATACCGCATAAGCGCACAGTATCGCATGGATACAGTGTGAAAAACTCCGGTGGTACCAGGATGGACCCGCGTCTGATTAGCTGGTTGGCGGGGTAACGGCCCACCAAGGCGACGATCAGTAGCCGGCCTGAGAGGGTGAACGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGAAGGCAGCAG
->URS00023619E2 lncRNA from 1 species 
-AGCACAGATCCATTAAGGCTGACCACAAATTGATCATAATGTTTGTGAATAGATTTGAATGAATTTGAACTCTTAGCCTAAGCTTTTTTCTTTCTATCAATAAAAGAACAATATCTATAATTATGTTTACTGCTCCGTTCCTTCGATCTACACCAACAATGTTTGTATTTTTGGGGAGATCCGGTGCTTAAAGTAAAATTTTTAACGCAATGAATAGGGTGCATTTTTTTCTGATATTTTGGTTTCTCTGTTCCCTATTTATCCAAAATATGCTCACCCCAAATTCTTTAGTGCAAGAGCATGATGGAGCTTTCTCTTGCTGCTTTTCCTTGAAAGAAAGAATGGCAACCAGGAGGTGCTTGTAGCTAGCCACTTAAGTAGGCATGTGCCTCCCCAAAGCACACACTTAAAATAGAACAAGCTTGATCTTGAAGACTATTTAATCGACAAGATGATACATTTTGCGAGAGGAAGTATTAAGATAATAACAAGCTCGAAGACATCCGTACGTTGTCGGCTAGGATTCCTTTAGATTAATGGATTGGAGATCATCATCCCTCTTCACACCCTACATTCTCTAGATGCTCTTATCCTTGGCATCTGCACGAACAAGGATTTGTA
->URS00025F6FB7 lncRNA from 1 species 
-GTCACAGGAGGGAGAGAGCATTGTTAGATCCATGGACATGCAAGGAGAGGGATGCTCCTGCAGAAGCATGGTCCCCAACTATAAAGGCAGCATTGAATCACAGAATCATTGAAAAGGTTGGAAAGCCAATAAGAACATCTAGTCCAACAATCAACCCATGCCTGTGACTGCTCAAGACCATGTCATCCATGGATACAAAAGGGTTTTCCTTTCGGACAATATGAAACAAAGTGCTTGGTGGGATCAGACCAAGCAGCAGAGCCTTGCTTTGGAGCAGCTGCTCGTGCCACGTTGTTTTGTTTGCTGATGTCCTTGGGCTCTGCAACCTGACAGAATGCTGCATTCCTGGTGCTCCTGCTTTGCATTGGGATCAAACTGAAAGCTGGTATCTGGTGCCAAGAGGAAGGAGAGCTTTGGATTTTTGACCCTGAGCATGGAGCTCTCACTGTTGGGCTGTGAGCTCTTCACAGCATGAAGAAAGCACGATTCACTGCTGTAACGGAGTTCTTCAGAAAAAAAAACGTGTTGTATCCTGGGTATGAAATGCCTAATCAAATCATGTTTACTGCTCAGCACTACACTGC
->URS0000B25448 lncRNA from 8 species 
-TGGAGCCAGCTTATTCTAGACCAAAAGGGCCTGGACTGTTCTAGGTACAAGATGGTGCCATGAATGTGCCAATCTCGCCTCTTAAGAAAATGTTAAAACTAAAGTAAGTGCATAAACTATTAAACTAAATGCATGAGTCTTATTTACATATAGGAAATGGTAATTCAGAAAGCTAGCCTGTGAGATTATCAATCATCACCAAACCAGATCTTGATGACTGTCACATCTCTGCTATATTTTCCAAATAGGAAATCCCATTTACCAGGGCCCTCCTGAAATGCCTGGGATTATGCCAAGGATCGCTTCCCTAGTTATTTTTATGTGTAGACCTGAGGAGTGGCAGAGTATGTAACCTTTAAAGATCATTAAGCACCAGTCTTGGGCTCAGCCTGAATTCTCACTCAGCAAGAGTAATGTAATTGCAATTATAGAACTGATCCATTTTATCACTTTCTGAGAGATCAATTGTCAGAGATTGAGACTCTTAATTCATCCTGGGTTTTAAGGAATATTTAAATGAGAATAAGGAATAAATTGAAAACATCAAGAAACTGACACAAA
->URS000236373A lncRNA from 1 species 
-ATTTTATTTGTCTTGGACCAGCGTATCCTTTTGGGGGGAGGTGGGGAGACCTACGAATATTTGAGGAAGAAGCAGCTACCATATTTTTCATTCTCGCGCCAAGAATAAGGGCTCTGGAATTTGGACAGTCGATTGGCATTTGCAGATTCAAACTGAGGAGAAGAACACTAGCGCAAGAACATGAGTTCCGCGACACAAGGTGAACATTCTCGATCTTCTGAAATTTTCTGTTCTTGTTTGTAGCAGTCGCCGATTTATTTTTGATTGAATTTCTGAGACTTGTATTGTTTGACACGATTATGTTGGTATATATTATTTGCATTCCCATAGATGTTGATGGTTGCATCTAATGCGCCACAAATAGAGCGCATCTCGGCGAATTTTTTTCAATTTTCATAAAATATGTTGGATTTATGGAATATATGTCTCAAGCTTGTGTATTACTTGTCGCTGCATACTCAAATATTTTTCTATGGATAGTTGTAATTAATCAATAATTCATTGGGATTAGGTTTTGTGCAAATATCTTATGAATATTTTCTGTAAAATATAATGAGCCTCCTTGACAGCCTCTTGCTCTCTTGATAACTCATATAATTTGTGTACTTCTTGTTGGGGTTGATGGTTTGCAGATGGGAGCAACGGGTTTGTTCGTGGGGGTCGGGTAAACAAGACCGACAAGACTCGACGCAGTTGGTCTACTCAAGAGGAGGCAGTGCTGCTAGCTGCGTTGAAAGAATTGGTGGTGCAAGGATGGAAATCCGACAACGGATTTCGGCCAGGTTATTTGACTAAGTTGGAGGAGGCTATGAAAAAGGTATTCCCAACCACTGACTTGAAAGGGATGCCACATATAAACTCAAAAACCACGACATGGAAGAAGCAATACTATTCGCTAACGCAAATATTGGGGAATACTGGGGTGGGCTTCAATGTGAATGGCATGCATATGGTGGATTGTAATGACGAGCAATGGGAGCAAATCATCAAGGTTAGTAGGTGTTCATATTGTAATATTAAATTCAGGCTGTACAAGTTTTCTAATATGTCTAAATGAACTACAGAAAGATACAAACGCACGCACAATGCGTTACAAAAGTTGGCCCTACCTGGAACAGTGGGCTGAAATATTTGGGAAGGATAGGGCGACGGGAGATGTGGCTGAAGATCTTATGGAGGCCGCACATGACATGTATCGCAAGATTGATCTTAGCGAACCACAAAATGATGGTGACTATCATGTATCCCTCGATGACATGTTCGAGAAGACCGCAACCAATGACAGTGTCAGCCAAACACAAGAAACCGAGTCTGAAGTTCGTGTCAAGCGGAAGAAGAGAAAGCAAGGCGACGAGTTCGAACAAATGTTTCAGGTGTTGGCAGATATCCAACGCACAACCGGACAGCGACTTGTCACAATATCAAGTAGAATGGGCTACGACTTCGACGTATCCAAAGCGAGAAAGGAGGTCTTCGCACAACTAAGCTCAATTCTGGGTTTATCCCTCAAAGCGAAGTTCGAAGTCGCCAATTTACTTGCAAAAGAGGTGGAGATGCTCGATGTATTTACTAGCCTGCCCGAAGAAGCCAAGAATGAGTATGTCAACTTCCTACTCGAGGAGAAATATAAATAGGATTGCTTCGCTGCACCATAGGATCTTGGGTGTTTTTTGGTTTCAAATTTTATTTGCTAACAACTCCTTCATTTCTGGAATTATGTTAGACCAGTAGAACTGCTGTTTCTTTTTATTTTTGGTGTCTTGGAGCTTAGTTCAGACATATCTTATCAAGTGGCTGTATTTTGGAGTCTTGCAGAAGCCACTTGTCTTAAATTATGCAGTTGAAGCTCGACAGAACTTATTTGACATTTTATGTTGCTTTCAAATTTGAATATGTTGGTATGTCTGTTTCAGATTTGCTTATGTTTTATCTTGCGGTGGATTACAAAGGCTTTTGTATAATTTAAATTGTAGTTTCAATAGGGATTTATTTAAATTGCATATGAATCGAAAATTGCTAATTCAGATAAGTTCAAACACAGCTCCCACAGTAAGCACAAATTCATCATAACTAGAAATCATGAGAAAACCAACAAACACAATAGACAATAACAAAGCTGCCTTCATCTACGAGGCACCAAAATAAGAGAAACAACGGTAGACACTGGACCTAACAGCGTGCATCGACGCTAACAAAATGGGAGGGAATAAAATGCGGTCCACAAAAGAGAGTAAGCTCCGCTTACAAATTTATTTAAATGGAGAAGACGAAGCACATGAGCTCCCGCCATAACCGACGTCATCTTTCTTACCATCATTCGGTTTCACGGGAAAGGCGTTCTTTGGAGGAAAGGAGGACGTCGTTTGTTTTGAAAATTTGTTCTTGATGGTAGACCATGGGACGTAGACATGACCCTTATGCGATTTGGGAAACGAGGGAGACACACTCGAACATGCATCATCTGGCTGAACTACCAAGGCACACAGTGGTTGGGTTTTAGTAGACGGGGAGTTCACTTCGTCCTCCGATGAAGTGTCGGTGAAGCTTTCAAATGGAGGACTCTTTTCACCTTTTGACGAGTCCTCTATCACTATCACAGTGTGTGAGATCTCGGGCTTCACATCGTACATTCCGAAGAGGGAGCACAATTTTAGGTACTCGGGCTCACCCTTATGGTAGTAAGCTTTGTAGAACTCATTTTCCTACAACCGATAGTGACTTGTATTAGAAAGACTAGCACACAACAGATTTAAATGATTTAGAACAGCAAAAACAATAGTTATAAAGCATCTCACCTTGAAGAGTTGCTCCCACACTTCATCGCTTGCATGAAGAACATTTGTCGACGCGTCCCGATCGGTCTCCGGGATATTGCAAAGATACTTGAAACNAGCTCTGGAAAAGTCAGCTCTGCCTTTGGTCAGCTCTGGCGATTTTAGCTCTGGAAGTCGGCTCTGGCTCCGAAGTCAGCTCTGGTGACTTAGCTCTGGAACGTCAGCTCTGGCTTCTAAAGTCAGCTCTGGCATGTTGGCTCTGGAAAGTCAGCTCTGGCCTCCGAAAGTCAGCTCTGGCGATTTGCTCGGGAAAGTCAGCTCTGGCCTTCGAAAGTCAGCTCTGCTCTGGCGGTTTCCAGCTCTGCTCTGGAACTTCCAGCTCTGCTCTGGTGTTTCCAGCTCTGCTCTGGAATTTCCAGCTCTGCTCTGGAACTTCCAGCTCTGCTCTGGCATTTTCTAGCTCTGCTCTGGCATTTCCAGTTCTGCTCTGGCATTTCCAACTCTGCTCTGGCATTTTCTACTCTGCTCTGGCATTTTCTAGCTCTGCTCTGGCATTTTCTGTTCTGCTCTGGTATTTTCTGGGCAGAACGACGAGGGTTTCCAGTTTCCAAAACTAGGGTTCTTTGTCCTTTCTTGCCTCGATTCTCACTCGTACGTCGGCCCTAATCTATTCCTATGTGAGCATGCTGTGCTTGTTCAAGTTCATCTACGTTTAAAGCCTAAAGTTCTCGTCGTTTAATCAAGGTTTCAAGCCGTGGGTTCTACCGAAAAAGTGACTTAACATGCTTCTTGTGTTCGTGCGTATCTAGAGCCTAAAACATGCTTTCTACGAGCGTGTGATTCATGCTGAAAGGAGAGGTCGAGAGTTACCTTGATGTCGCGCGCTTTGGTCGGACAAGCACGATGGTTCCTCGCTTCTCCGATCGTCGAGGTTCAAGGTGTCGAGAGAGTGATGGAACTCTTGCTGTTGCTGCTGGATTTCAGAGTGCCGAAGGAAGAGGAAGGGTCACACAAAGGGGTTGAAGGGGAGTTTAAATAGGGTGTTCGGCTGATGCACTTGAGTGCCTAAGGGGAGAGCTTCGGCTGTAGCTCTGCACAGCGTGGAAGAGGGGTGCAGCAGGCGTGCTAAGCTCTGCTGTGGTGTTGCGTGGGGAGGGCTGCTGCTGCTCTGCCGGCGTGGAGATGGAGTGTGGCCTTTCGGCTGCTCGTCCAATGGAGGCTGCTGCCGTGGCTGCTCTGGTCTGGCGTGGAGTGTGGCGTGGCGTGGAAGAGGGGTGCAGCAGGCGGCCCTTCGGCTGCCCAGCCAATGGGGGCTGCTGCCGCACCTTTTCCTACTTTTCCTTTTCTCCATTTTTCCTTCTTTTCTTAACTTGTAGCGTTGGCAAGTGTTGGGATTGGGTGGCGTGAGTGGTGAAGTGATCTAAGAGAAGATCTAAATAAAATCCTTCAGTGTCGGTCATTCTCAGTATTAAAAATACTGGTTTCGTGCTTGCTAACATCGATAAATGCTAAATTAAATCCATAGACTCAATCCGTTCGTCATTCTAATACTTAAATTAAATCCGTAGATTTAATTAGCTTCAAAGTCGGAAATAATTCACGACTTAAGTAACAATGTGAAATAAACTCTATCTTGATAAATAACCCAACTTAGCTAAGTTGGTTATAACTTTGAAGAATAATAATTCATCGACTCAAGGATTCTCATCGCGGTCTTAAACACGCGAAGCTAAATAAATGCATACTTGCTAGTGTAGTGACTCTGTCTCCAAAATACGAAATTCATAAACATAGATGAAAACATGAAACGCTTCAATTACTGGCAGATAGAAAAATAAACATGCAAAAACTGAAATTAAATGATGATAAAAGAGCGGGTTGCTACAACTGAACATCGGGCGGAAGCTTACATCAGAACATACGAGGCAAATCATTATAATTCGGCTCAAAGGTATATACGTCAACATCGTTATAACTTCTTGAATATTAGAAATTTCAAGAAGAAAAGCAAAGTAGGTACAGCTTATTTTCCATAAGGAAACATAATATCAAGAGTACCACAGCAAAAGGCGTAACAATTATATGTATGAAGACATATAACCGCGAGTATATTGCTTGATTAGAAAGGAATAAGACATCATCTCACTAAGGTTTTATCAACATCAGAAGGAAAGCAAAGTACATCATCCTTAAGACTCTAACATCAAAGGAAAAACAATATAGAAACTTCATCAATGAAACCATCCCCACCAGCACCAGTCCAATCTTGCTCCATTGCTTAGCCTGCACATTTAGGCTATGTTTGGTGTCTGGTAATGGATTAGGCAATATAGTTTATTTTCGGCTACCTAATCTTGATTACAATGATATTAGTATGCTTTGTTGTTGTTTGATTATTTAAATAGTTACATAACAATCTATTTTGGTTGGTTTGGTGAGCAGTAATAATAGCACGATTAAAGCTGAATAGATGATAAAATGACTAATATACCCACCCATTTTATTTGTCTTGGACCAGCGTATCCTTTTGGGGGGAGGTGGGGAGACCTACGAATATTTGAGGAAGAAGCAGCTACCATATTTTTCATTCTCGCGCCAAGAATAAGGGCTCTGGAATTTGGTACAGTCGATTGGCATTTGCAGATTCAACTGAGGAGAAGAACACTAGCGCAAGAACATGAGTTCCGCGACACAAGGTGAACATTCTCGATCTTCTGAAATTTTCTGTTCTTGTTTGTAGCAGTCGCCGATTTATTTTTGATTGAATTTCTGAGACTTGTATTGTTTGACACGATTATGTTGGTATATATTATTTGCATTCCCATAGATGTTGATGGTTGCATCTAATGCGCCACAAATAGAGCGCATCTCGGCGAATTTTTTTCGATTTTCATAAAATATGTTGGATTTATGGAATATATGTCTCAAGCTTGTGTATTACTTGTCGCTGCATACTCAAATATTTTTCTATGGATAGTTGTAATTAATCTAATAATTCATTGGGATTAGGTATTGTGCAAATATCTTATGAATATTTTCTAGTAAAATATAATGAGCCTCCTTGACAGCCTCTTGCTCTCTTGATAACTCATATAATTTGTGTACTTCTTGTTGGGGGTTGATGGTTTGCTAGATTGGGGAGCTAACGGGTTTGTTCGTGGGGGGCCGGGTAAACAAGACCGACAAGACTCGACGCAGTTGGTCTACTCAAGAGGAGGCAGTGCTGCTAGCGGCGTTGAAAGAATTGGTGGTGCAAGGATGGAAATCCGACAACGGATTTCGGCCAGGTTATTTGACTAAGTTGGAGGAGGCTATGAAAAAGGTATTCCCAACCACTGACTTGAAAGGGATGCCACATATAAACTCAAAAACCACGACATGGAAGAAGCAATACTATTCGCTAACGCAAATATTGGGGAATACTGGGGTGGGCTTCAATGTGAATGGCATGCATATGGTGGATTGTAATGACGAGCAATGGGAGCAAATCATCAAGGTTAGTAGGTGTTCATATTGTAATATTAAATTCAGGCTGTACAAGTTTTCTAATATGTCTAAACGAACTACAGAAAGATACAAACGCACGCACAATGCGTTACAAAAGTTGGCCCTACCTGGAACAGTGGGCTGAAATATTTGGGAAGGATAGGGCGACGGGAGATGTGGCTGAAGATCTTATGGAGGCCGCACATGACATGTATCGCAAGATTGATCTTAGCGAACCACAAAATGATGGTGACTATCATGTATCCCTCGATGACATGTTCGAGAAGACCGCAACCAATGACAGTGTCAGCCAAACACAAGAAACCGAGTCTGAAGTTCGTGTCAAGCGGAAGAAGAGAAAGCAAGGCGACGAGTTCGAACAAATGTTTCAGGTGTTGGCAGATATCCAACGCACAACCGGACAGCGACTTGACACAATATCAAGTAGAATGGGCTACGACTTCGACGTATCCAAAGCGAGAAAGGAGGTCTTCGCACAACTAAGCTCAATTCCGGGTTTATCCCTCAAAGCGAAGTTCGAAGTCGCCAATTTACTTGCAAAAGAGGTGGAGATGCTCGATGTATTTACTAGCCTGCCCGAAGAAGCCAAGAATGAGTATGTCAACTTCCTACTCGAGGAGAAATATAAATAGGATTGCTTCGCTGCACCATAGGATGTTGGGTGTTTTTTGGTTTCAAATTTCATTTGCTAACAACTCCTTCATTTCTGGAATTATGTTAGACCAGTAGAACTGCTGTTTCTTTTTATTTTTTGGTGTCTTGGAGCTTAGTTCAGACATATCTTATCAAGTGGCTGTATTCTCGGAGGCACACAACAGATTCATATGACCATTTCCACAGCTGCATAGAGGGGTAGGTGTTGATGTCTCAGACGCGGCGTCCATCCTACAACACCAATGTATAGTATTTTAGTATTTTGACATGAGTAGCATAGAAATTGATAGAAAACTTATATGGCCATGACAAGCAGCATCGCAGCAAGATCAGATAAATATTAACAAGGGAATTAGCAAGAGACCACTAGAGACTACTATATTCATTGTAAAAATCAACAAGATTTTAAATTTTATTCACATCAATATCATCAACAGCTGAGATAAGGATTTCTTATGAATTAAAAAATTATTACAATTGTCGAAATCGAACACAATTAAATGGAATTTTATCATGTAAACCCAACATCATCAAAATCACAGCTGAACACAAGCAAATTAGAGATAGATGTCACCAAGAACTTGCTGCAACAGTTTAAAGACGAATTAACATGCAACATTCTAAAGAGAACACCTTAAATGAATGTAAAAATTATTGCAATCGTCACCTAATGATTATTCAAGTATTGAAGCCACATCCCCTCCGCCAATTCATCCCTTGCGGCATTCCATTGGGGAGAAGACTCGACCGTGGCAATGAACTCGTCATGATCGGCTTCAAGGCCATGAGCATTACTATTTGCCATCGCATCAAATTCCTCTTCTATTGGATCGACCGGCATTTGCATTCGAATAAAATTATGAAGTAAAAATGTTGCCATTATTAACCTATTTTGGACCTTAATTGGGTAGAACGTGGTGGACCGTAGAATACCCCACGCATTTTCATAATTCCAAATGCTCTCTCAATCACATTCCTCGCCTTACTATGCCTCAGGTTAAATAACTCCTCCTTGTTTTGGGCCTGGCAGCAGTGGGACCCCACTCCTTCAGGTGGTATCTAACGCCCTTGTAAGGCGTTAGAAAACCATCACTATTTGCGTAACCGTTGTCACACAAATAGTAATTTCCTGTTGAAGCCCCAACAAACCAAAACAAAAGAGTAATTTAGGTAAACTTTGATAAATAATCCACGTAAACACAAACGCTATTCGAATTAAAGAGCAAATAATTGGCATTACCCTTTGGCACTTTAAGACCGTGGGGTCTACTTATGGCATCCCTTAATATCCTAGAATCTGCAGCAGAGCCTTCCCAACCGGAAAGAACGTAGACAAACTTCAAGTTTCGGTCACATACACCTAACACATTCTTGGATATCTGTCCTTTCCTTGTCCTATAGCGTGCTTGGTCGTTAGTGCTCACCATCACATTAACATAGGTGCCGTCTATAGCTCCTAGACAACCCTAAGTTGAAGAGAGACATTTAAAAACGAGTTAGTGCTAATAAAATTTATGATCATACTTACTAGAATAACTACAAGGCTGCCCTACATACCTTAAACCACTGCCACCGGCCATCTGTACAGTCATTGGACACAGCTTCCGGTTTTGATAAAAAAATTTCGTGTATCTTCAATATTGCTCCTAACACGGCATGTACGTAGCGCGATATGGTTTGCCCAGAAACGACAAAAATCAAATCTTACAACTCTATTTTTCTTTGTGATGTGCTAAGACAGACAAGAAAATGGCTACTTGTTCCTCCACACTCACGTAATCACCATCAACTAAGCCTCCCAAACCCCGTAAAATGGTGCACAACCGCCCGAAGGTATTACGATCCATTCGCAAGTTCGCGATGCAATCGACATCATTGACACTTATCAGCCTACTTAAATATTTTATTTGGTCCGGCATTCTACTTATCATCCCATATTTTCGTGATCCAAACCCACGTTTTCTTTTTCTTGAGCTAGACTTGATAAAATATGTAATTACTATAACCAACTGCATTATATGCTGAAGCATTATTTCTTGCAATAGCAAGAACAAGATATCGGACATACGGGGACGTACACGGCCAGACATCTAAAATAGAAACAATAAGAGATAATTATAACTTATATTCACTGCATTTCACCACCATGGCAGATTTATTTAAATTAATTTCAGTTTGAGCAAGTGATGGCAGAAACAAAACGAACCATGAACATATCATCAATCAAAATGTAACTGCAACAAGTGTCGTACACCAAGAGACAATTATAACTTATATTAATTGCATTACCAGGCACTATGTCAGATTTATGCCAACAAGCCATTCAACAACCAATCAATAATTCATCACCACATTAAAACTGTACTACCGAGAAAAAATCCCAATAAGCAAATATTTTCTCATAAAAAAAAAGAATATGTCATGCATATCAGGAAGAGATACTATTCAGCCACAATAGGCACTCCGTTAATTCTTTCAGAAATCATATTATGTTATTGTTTATACATGCATCGATCGTCAATTTGATAGTTTAAAAGACATATACAACGAGTGTGATTTATATATATCCCTAGAGATAACAAGCAATCGGACAAGCACTAACCTTGGTCTGTTCACAAAGCCTTCGACGTGGAGACTGAGGCTGCTTTCCGATGAGCGTAGCGACCAGAAATACGGACAAGAAATCCCAAAGTGTTTTGGC
->URS0000A5EA3D rRNA from 1 species 
-TACGTATGGGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGAGTGCGTAGGTGGTTACCTAAGCGCAAGGTTTAATCTTGAGGCTCAACCTCATTCTGCCTTGCGAACTGGGCTACTTGAGTGCAGGAGGGGAAAGCGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTACACAGAACACCAATTGCGTAGGCAGCTTACTGAGCCGACACTGACGCTGAGGCACGAAAGCGTGGGGATCAAACAGGATTAGATACCCCGGTA
->URS00009D2B09 rRNA from 1 species 
-TACGAGGGGTCCTAGCGTTGTTCGGAATCATTGGGCGTAAAGAGTCTGTAGGCGGCTAGATAAGTCAGGTGTGAAATCCCCGGGCTCAACCCGGGACGTGCATTTGATACTGTCTAGCTTGAGTATGGAAGAGGCTAGTGGAATTCTTGGTGTAGTGGTGAAATACGTAGATATCAGGAGGAACACCGGTGGCGAAGGCGGCTAGCTGGTCCTATACTGACGCTGAGAGACGAAAGCATGGGGATCAAACAGG
->URS0000CEB689 lncRNA from 1 species 
-CACCCGCCCTGACACCGTCCTGATGGGGGTCCTGCAGAGAAGACTCCTTACTTAGCCCACAGTGCTCCCACCCACCCTCAATGTATAACTTCACGTTCAGAAATGTGTTACCCCCCTCCTCAGACCTCACACAATTCACGAATTTCCAAACAGCAGGAAACAGAAACTTCTAAGAAAGCAGAACCCTTGAGTCCAGGTGGGAGAAGGTGCCTGAGAAAACAGCCCTGCCAGAGACAGTACCCCAGCATCCGGACGTTACTCCACAGACGGCCACGTGAGAGACCGGGAACCACCCTTCCCACCGTACCCCAGCGTCCGGACGCTACTCCACAGACGGCCACGTGAGAGACCGGGAACCACACTTCCCAAGCCTTCTGCACTCCCAAAAACATCAGCTTCCCGGAAACCTGAGACATGCTCAAGGAAGAGCACGGTGTGAAGTCAGCTGTGGGTGGAGGATGACCCAGGTGCCCAGGCAAGAGACTGAAGGCACAAACTGTTTCAGTATAATAAAGCAAATAGAATAAGAA
->URS000155D742 rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGCTCGGAATCACTGGGCGTAAAGGGTGCGTAGGCGGGTCTTTAAGTCAGGGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTTGATACTGAAGATCTTGAGTTCGGGGAGAGGTGAGTGGAACTGCGAGTGTAGAGGTGAAATTCGTAGATATTCGCAAGAACACCAGTGGCGAAAGGCGGCTCACTGGCCCGATACTGACGCTGAGGCACGAAAGCGTGGGGAGCAAACAGGATAG
->URS000074D688 rRNA from 1 species 
-TTTATTCAGGGTTCAAAATNAACTTNGGCGGCGNGNATTAGNCATNCAANTTNGTCCTTCCCCAAGGCAGGGCGAGGCNCAAGGGTGANTAAGGCGACGTAANCAACCCCGAGGATGGGCATANCCGCGGNAAANTGCNGGTNATTCCCAGCGACGTCGAGACGTGNCATCACGCTTCGACCCAAAGGTGTGAATCCCCTCGGGACGGNCCNTCGTGGTATCAGGTAGTTGGTGGGGTGATGNCCCACCAAGCCAAAGACGCCTACCGGGCGTGCGAGCGTGGCCCGGCACACTGGGACTGAGACACTGCCCAGACACCTACGGGTGGCTGCAGTCGAGAATCTTCGGCAATGGGCGCAAGCCCGACCGAGCGACGCCGCGTGGAGGACGAAGGCCTTCGGGTTGTAAACTCCTGTCGAGGGGGAACAAGGGGGCGTGAAGAGCGTCTCTTGAGTGATCCCTGGAGGAAGCACGGGCTAAGTTCGTGCCAGCAGCCGCGGTAAGACGAACCGTGCGAACGTTATTCGGAATCACTGGGCTTAAAGCGCGTGTAGGCGGAGTGACACGTCGGATGTTGAAAGCCCCCGGCTCAACCGGGGAACGGGCACCGATACGGTCGCTCTGGAGGGGCGTAGGGGGAGCTGGAACTTCCGGTGGAGCGGTGAAATGCGTTGAGATCGGAAGGAACGCCCGTGGCGAAAGCGAGCTCCTGGACGCCATCTGACGCTGAGACGCGAAAGCCAGGGGAGCGAACGGGATTAGATACCCCGGTAGTCCTGGCCGTAAACGATG
->URS0000AF452E rRNA from 1 species 
-CCTACGGGATGCACCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGAGGAGGAAGGCGTTAAGGTTAATAACCTTAGCGATTGACGTTACTCGCAGTTGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTCTGTCAAGTCGGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTCGAAACTGGCAGGCTAGGGTCTTGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGTCCACTGGACAAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTCGTAGTC
->URS000178FACD rRNA from 1 species 
-TACGTAGGTGGCAAGCGTTGTCCGGATTTACTGGGCGTAAAGGGCGTGCAGGCGGTTTGTTAAGTGCAGGGTGAAAGCTCCCGGCTCAACTGGGAGAGGTCCTTGCATACTGGCAAGCTCGAGGGAGGCAGAGGAAAGTGGAATTCCCGGTGTAGTGGTGATATGCGTAGATATCGGGAGGAACACCTGTGGCGAAGGCGGCTTTCTGGGCCTTACCTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACGGG
->URS0000F98CBA rRNA from 1 species 
-TGCGTAGGCGGGCCCGTAAGTCAGTGGTGAAAGTTTGCGGCTCAACCGTAAAATTGCCATTGAAACTATGGGTCTTGAGTGTAAATAAGGTAGGCGGAATGTGTTGTGTAGCGGTGAAATGCCTAGATATAACACAGAACACCAATTGCGAAGGCAGCTTACTGGGATACAACTGACGCTGAGGCACGAAAGCGTGGGGATCAAACAGGATTAGATACCCTGGTAGTCC
->URS00020667BA rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTAGAACGCACAGTTTATACCGTAGCTTGCTACACCATAAACTGTGAGTTGCGAACGGGTGAGTAACGCGTAGGTAACCTGCCTGGGAGCGGGGTATAACTATTGGAAACGGTAGCTAATACCTCATAATATTGATTATTGCATGATAATTGATTGAAAGATGCTATTGCATCACTACCAGATGGACCTACGTTGTATTAGCTAGTAGGTGAGGTAACGGCTCACCTCGGCGAGGATACATAGCCGACCTGCGAGGGTGAGAGGCAAAACTGGGATTGGAACATGGCCCAGCCCACTACGGGAGGGAGACGTCGGGAACTCCTGGGAATGGAAGCAAGGCTGAACGAGCAACGACGGGCGAGTGAAGAAGGCTGTCGGATCGTAAAGGTCAGTTGTACGAGAAGAATGGGAGTGAGAGTGGAACGTTCACACTGTGACGGTACCTGAACAGAAAGCGACGGCTAACTCCGTG
->URS00019D34DB guide_RNA from 1 species 
-AAAACACGAGACAAAGTAAAGAGGGAGAATAGATAGAATG
->URS0000089A8C tRNA from 1 species 
-TCTAGAAGAATGGGACTTGAACCCACACCTAAGACTCCAAAATCCTTCGTACTACCACTATACTATCCCCTA
->URS00017CC75E rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTAGAACGCGTGGCGGACGGGTGAGTAATGTCTGGGAAACTGCCCGATGGAGGGGGATAACTAATGGAAACGGTAGCTAATCCCGCATACCATCGGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAACGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGGGAGGTGGACCAGCGCCCATGGAACTTAGACACGTTCCACACTCCTACGGGAGGCAGCTGTGGGGAATATTGCACAATGGGCGCAAGCGTGGTGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGAGGAGGCGTTACTCGCAGAATAAGCACCGGCTAACTCCGTGCCAGCGGCCGAGGTAATTC
->URS0001993F25 snRNA from 1 species 
-ATGCTTGTTTCAGTAGCACATAGACTAAAATTGGAACAATACAGAGAAGATTTGCATGGCTGTGTGCAAGAATGATAAGCAAATTTGTGAAGCATGCCATATTTGG
->URS0001E9A07D rRNA from 1 species 
-GATGAACGCTGGCGGTATGCTTAACACATGCAAGTCGAACGGACTCTTCGGAGTTAGTGGCGGACGGGTGAGTAACGCGTGAGAATCTGGCTTTGGGTTCGGGACAACCACTGGAAACGGTGGCTAATACCGGATGTGCCGAGAGGTAAAAGAGAAATTGCCTGAAGATGAGCTCGCGTCTGATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCAGCGATCAGTAGCTGGTCTGAGAGGATGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCGGCAGTGGGGAATTTTCCGCAATGGGCGAAAGCCTGACGGAGCAATACCGCGTGAGAGAAGAAGGCTCTTGGGTTGTAAACCTCTTTTCTTAGGGAAGAACAAAATGACGGTACCTAAGGAATCAGCATCGGCTAACTCCGTG
->URS00019E5825 rRNA from 1 species 
-TGATGCAGCGACGCCGCGTGAGGGATGACGGCCTTCGGGTTGTAAACCTCTTTCAGCAGGGAAGAAGCGAAAGTGACGGTACCTGCAGAAGAAGCGCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGCGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGCTTGTCACGTCGGGTGTGAAAGCCCGGGGCTTAACCCCGGGTCTGCATTCGATACGGGCTAGCTAGAGTGTGGTAGGGGAGATCGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGATCTCTGGGCCATTACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGGTGGGAACTAGGTGTTGGCGACATTCCACGTCGTCGGTGCCGCAGCTAACGCATTAAGTTCCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCAGCGGAGCATGTGGCTTAATTCGACGCAACGCGAAGAACCTTACCAAGGCTTGACATACACCGGAAAGCATCAGAGATGGTGCCCCCCTTGTGGTCGGTGTACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTTCTGTGTTGCCAGCATGCCCTTCGGGGTGATGGGGACTCACAGGAGACCGCCGGGGTCAACTCGGAGGAAGGTGGGGACGACGTCAAGTCATCATGCCCCTTATGTCTTGGGCTGCACACGTGCTACAATGGCCGGTACAAAGAGCTGCGATACCGTGAGGTGGAGCGAATCTCAAAAAGCCGGTCTCAGTTCGGATTGGGGTCTGCAACTCGACCCCA
->URS0000291A32 rRNA from 1 species 
-GCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTGATACGTAGGGTGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGGGCTCGTAGGTGGTTGATCGCGTCGGAAGTGTAATCTTGGGGCTTAACCCTGAGCGTGCTTTCGATACGGGTTGACTTGAGGAAGGTAGGGGGAGAATGGAATTCCTGGTGGAGCGGTGGAATGCGCAGATATCAGGAGGAACACCAGTGGCGAAGGCGGTTCTCTGGGCCTTTCCTGACCCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGCTTAGATACCCTGGTAGTCCACGCTGTAAACGGTGGGTACTAGGTGTGGGGTCCATTCCACGGGTTCCGTGCCGTAGCTAACGCTTTAAGTACCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGCCCCGCACAAGCGGCGGAGCATGCGGATTAATTCGATGCAACGCGTAGAACCTTACCTGGGTTTGACATGGATCGGGAGTGCTCAGAGATGGGTGTGCCTCTTTTGGGGTCGGTTCACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTTCACTGTTGCCAGCACGTTATGGTGGGGACTCAGTGGAGACCGCCGGGGTCAACTCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGCCCCTTATGTCCAGGGCTTCACGCATGCTACAATGGCTGGTACAGAGAGTGGCGAGCCTGTGAGGGTGAGCGAATCTCGGAAAGCCGGTCTCAGTTCGGATTGGGGTCTGCAACTCGACCTCATGAAGTCGGAGTCGCTAGTAATCGCAGATCAGCAACGCTGCGGTGAATACGTTCCCGGGGCTTGTACACACCGCCCGTCAAGTCATGAAAGTTGGTAACACCCGAAGCCGGTGGCCTAACCGTTGTGGGGGAGCCGTCGAAGGTGGGACTGGTGATTAGGACTAAGA
->URS0000A4E5B4 misc_RNA from 1 species 
-GTACCCTCCAGCCCTGCTGGGTGTTGGGCGTTTTGTTCCGCCGCGCGCGTGAACTCGCCTCAAATACATTGGCAGCCAGCCGTCCCGCGTGGGAGCGCAGCACATTTTGCGCTCTCCGCTGGGTGCGGCGGCGTCCACAAGCCTAATTTTTTACGC
->URS00007CA1EC rRNA from 1 species 
-TGGAATACAGCGTCATAGTGGTGAGAACCCAGTATATGATGTGGATGCCTAGTGCTTTGTGATACATTTTCAAAGAGTCGAGTTGTTTGGGAATGCAGCTCAAAATGGGTGGTAAATTCCATCTAAAGCTAAATATTGGCGAGAGACCGATAGCGAACAAGTRCCGTGAGGGAAAGATGAAAAGCACTTTRGAAAGAGAGTTAACAGTACGTGAAATTGTTGAAAGGGAAACGCTTGAAGTCAGACTTGCTTTTGAGTTTACTTGATGGCAGGCTAGCATCAGTTTCTGASAGTAGAAAAGGGTATTGAGAAGGTMGCAGCTTAGGTTGTGTTATAGCTCTTTACTGGATGTGCTCTTGGGGACTGAGGAACGCAACACGCTTTGTGCAATGTCTTCGGGCATTTCGTGTTAAGGATGCTAGTTAATGGCTTTAAACGACCCGTCTTGAAACACG
->URS0000B0FA7A rRNA from 1 species 
-TGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGAGTGAAGAAGGCCTTAGGGTTGTAAAACTCTTTCACCGGGGAAGATAATGACGGTACCGGAGAAGAAGCCCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGGGCTAGCGATGTTCTGAATTACTGGGCGTAAAGCGCGCGTAGGCGGCTTGGTAAGTTGGAGGTGAAATCCCGAAGCTCAACTTCGGAACTGCCTTAAAAACTGCTTGGCTAGAGGCAAGGAGAGGAGAGCGGAATACCCAGTGTATAGGTGAAATTCGTAGATATTGGGTGTAACACCGGTGGCGAAGGCGGCTCTCTGGCCTTGATCTGACGCTAAGGCGCGAAAGCGTGGGGCGCAAACAGGATTAGATACCCCCGTAGTCC
->URS00001D86A5 rRNA from 1 species 
-GGGTCGATACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTNCACGCCCTAAACGATNTCAACTAGGTGTTGGTAGGGTAAAACCTATTAGTACCGTAGCTAACGCGTGAAGTTGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGATGATGTGGATTAATTCGATGCAACGCGAAAAACCTTACCTACCCTTGACATGTCCAGAATCCCTGAGAGATTGGGGAGTGCCTTCGGGAACTGGAACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCATTAATTGCCATCATTCAGTTGGGCACTTTAATGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTATGGGTAGGGCTTCACACGTCATACAATGGTCGGTACAAAGGGTTGCCAAACCGCGAGGTGGAGCTAATCTCAGAAAGCCGATCGTAGTCCGGATCGTAGTCTGCAACTCGACTACGTGAAGTCGGAATCGCTAGTAATCGTGGATCAGCATGTCACGGTGAATACGTTCCCGGGTCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTTCACCAGAAGTAGGTAGCCTAACCGCAAGGAGGGCGCTTACCACGGTGGGGTTCATGACTGGGGTG
->URS000235E350 lncRNA from 1 species 
-GCTTAGTTTGCTAAATAAATAAATAAATGAAGTTTGCTATGAACCCTCATGATAAGCTCTCACATAAAAATGATGAATAGTTGCTCTGCCATTACTAGTTCTCAAAATTGAAATCTCTCTCAAGTTTAGGCATGACTGTTATGAATTAAGATTTGCTCTAAAACTGAACTTGTGGGAAGAGTACTTGATCAAAAGTCTATGTCGTTAACGGATACGATATGGGAAGGTTGAGCTGCTATTTATCTGTTCCTAGAGATGCTAGAATTCTAGAGAATTTTATCTTTGAAAATCTTTAAAATATTGCATGATGAGTTCCTGTATGATGAGTGTTTAAAATCCTACCACAGCCATATATACATGCTTATTAGACTATGAACCATACATTTACTTTTTACTACTTATGAGCATTGAGTGTGGTGAAGTTGTGTAGACCCTTAGGAGCTTGTCATGTGGTTAAAATCAAGATTCACTTGCACATTCACTCATACATGCTGCTTCTACTTCAGAAGTACGCATCTACATACATCCATTCATTTCCATCTCCAGATTCACCCAAAATTATTCAACTCCTATTCAGGAGAGAATAGCCAAAAACATTATCCTATCCCTGTAATTCCCCGTGAAATAAATGCTCTTGATATTTTGGTTACTACCAATTGCTACATTATTCTAGGAGGGTGAGTGCTCTGAAAAAAAGTGAATACGAGGAAATAAAAAGGGACAAGTGCCCGAAACCTCGAAGAAAAGAAAAAGTGAGACGAGAGGTAAAAATGGACAAGTGTCCGACAGTAGAATTAGGGGTACAAGATACCCACCTGAGAGAAAAGAAAAAAAGAGAAAATATAGAGCATCTCATTCCCCTAAAAAAAGCTTCAAAGTGCAAGAAAGGTATGTATCCCCTCAAAAGAGCAACAGTAGAATTAGACTTTCACCATTATCACCATCATCACCATACACCATTCATGCGCCACACATGCACATCTTGATTTGACTTATTGACTTGTTTCTTTGGATCCATGGTTTGACTATGCAATAAATGACTTGTAAGTATGTATTAGCTGTCTCCCACCTATGAGCTCCAGATATCAAAACCTTGTTAGAGTAGGGTGAGAGAGAGGGCAATATCATTATGCCTCATACCACAAATAACACATACTTTGAGAGAAGGCATATATCATCACTGCGTTGGTAAGGATCTAGAAATACCACAAAAGAGAGACTAGAGAGAGTCATACAAGGAATCTCTGAGTTTTATTTGAAAATTTGCAAAAACTCCAGAGCTATAGTTGATGAAAGAACAAGAGACATGGTGCTTGACTTGACCGTTCTATCTTTTAACTGCTCAAGACACAAGTGACGGTTGCAAGCCCCATGGTGGAAGGTAATATGAGTAATTTTAAATCTTAACAGTTTACCTTAACCCAGAGATGAGATTTTGTTTGAACGCATGTGTACCTTTAAGGCATAAAACCACTGAAGAAACTATTGAGTCCATCCTTGCTCAGGGACGAGCAAGAGGTATGCTTGAGGGAGTTGTTGACGGTCCTTAAGTACTAAATATAACGATCAAATAAATAAAGAAAAGGATCCAAATGCAACGAACACCCAGACTTAGGGTTTTATCTGACAGAATTCCATGAGTTTTGGTGTTTGTCTATTTCTGCAGGGGGTTATCAGGAAATATGGAGGAAAGGCCCACATGTCGGGTTTACATAGAGATATGAACGTACCGTGCAAATTTTTATCATCTAGAAGACTCTAGAAGCCACGGGAACGAACGGGAGGCCAAGCGGGCTCGGGGGTAGGGCGCCCGCCCTCCCCCCTTCGGCGCCCGCCCTATCCCACAGTCCAATCAGGACTCGCTTCGGGGATTATGCTCCACCGAGCTAAAGGATCAAGAATAACCGTTCAATCAACGTCGGTTTGATCCGACGGCCCAGATTCACTTGAGGGGACTATATAAGCAGACCCCTAGCCTCTGGAGGAGGCACCCCTTGATCCCTATTCATTATTCATAGATAGAGCAAAAGCTAGGGTTTGGAGATGAGAGCTCTCCTCTCATCTCTAAACTAGAGTAGATCTAGATAGTAGCGAGACGGAGAGCGAGGGAGGATTGGAGGAGAGGCCGGCCTGTCGATTCTTCCTCCGGTTGTACTTCGCCATGATCAAGCTCTAATCAAGCTTCCTCATGGGATGACTCTGGTAATCTACTTCTAATTCACTATGCAATTACTATTCATGTATGTTCTGGTTCACAACTCTTTTGTGTACTTCTAATCTCTAGGACCCTATAGGTTAGAGTTGTAGTATAGGTGTAAGCATGGTGCTTAGACCTAGATTACTTGTGAATATCCCCTGTCTAGCTGGATCGTGTGGTAGGCCGCGTAGGTGACAGTTACGTTGGTCCCCTGTAGTAAACCTCCTGTTAGCAGGACAGGTAGGGTTTATCGGCCTATGGATAAGCATCCTTTGTGGTGTATTCTTATCACGTAGTTCATCCCAGACATAGACATACCCCTTTGAAGTAGAAAAACCATAGTTATCATCTCTATTCTGCAACCATCGCCCATATACTAGAATGCTCTACTCTCTATTCCCATATTATCACCCATTGTTATCTTACCTTTAATATTGTTCTTATTCAATTCTACCATCTTTCCTATTTACACTTATCTATCTATCTTGGTTAAGTTAGAGCGTAGTTGGTTCTCCCGTTTCCCTGTGGATACGATAAAACCTTTAACCGGGTAAAAGCTACAACGGTATCCATGCGCTTGCAGATTTATCTGTGTCCGTATAAATACCATAGTACACTCTAGTGTCATGCTGGGGATGACAACCTAGTATTCAAGTGGTGTTAGCAAGTGTCAACAGTCGTCGGATGATGATCAAAGGGCTTAGGATTGGGTGGAGAGGTATTTCTAGTATTTGACTTCTGGCTAAGCTATCCTAAGTATATTTGAGAGTTAACTCCCTTCCTACTGTGGCCGATAGGTGAAAAGGGTGTGGCGAAACACTTCCCTAGGCAGCTACCATGCAAGCCAACTATTATTTGCAACTTGCCTAACAACACACTAAAGAGAACTCCTAATGTCCAGTAGAGGAATGTTATGCTTCGCTGCTGGTGTTCTTCAGGTGCGACAAGAAGTCCACAAGGGCAGACAAAGTCTAGACACCATGTCTACACTAATTCTACTACTCTAGACCCAGCTAAGGTTTCGAGCACTTCACACAAGGCAAAGCAATGTGCCAGATAGGCCGGTTGTATACTTAAAATAAACTAAGATAGAAAGTAAATACTGGAAATACTCAGATGAAAGGAAACTAGAAGGAAGACTTACTAGAAGACAAGCATCCGCTGAGGCACTCCTAGAAGAAGACTCCCGACAAGTCGGTGTTGACACTTGCTAACACCACTTGAATACTAGGTTGTCATCCCCAGCATGGCACTAGAGTGTACTATGGTATTTATACGCACACAGATAATCCGCAAGCGCACGGATACCGTTGAAGCTTTTACCCGGTTAAAGGTTTTATCGTATCCACAAGGAAACGGGAGAACCAACTACGCTCTAACTTAACCTAGATAGATAGATAGGTGTAAATAGGAAAGATGGTAGAATCGAATAAGAACAATATTAAAGGTAAGATAACAGTGAGTGATAATATGGGAATAGAGAATAGAGCAATTCTAGTATATGGGCGATGGTAGCAGAATAGAGAGAATAACTAAGGTTTCTCTACTTCAAAGGGGTATGTCTATGTCTGGGACGAACCACGTGATAAGAGTACACCACAAAGGATGCTTATCCTTAGGCTGATAAACCCTACCCATGCTGCTAACAAGAGGTGGACTACAGAGGACCAACGTAACCGTCACCTACGCGGCCTACCACACGATCCAGCTAGATAGGGGATATCCACAAGTAATCTAGGTCTAAGTGCCACGCTTACACCTATACTACAACTCTCACCTATAGCGTCCTATAGATTAAAGTACTCAAAAGAGTTGTGAACCAGAACATACATAATTAATAATTGCATAATGAATTAGAAGTAGATTACCAGAGTCATCCCATGAGCAAGCTTGATTAGAGCTTGATAATGACGAAGTACAACCGGAGGAAGAACCGACAGGCCGGCCTCTCCTCTAATCCTCCTTCGTTCTCCATCTTGCTATTATCTAGATCTACTCTAGTTTAGAGAAGAGAGGAGAGCTCTCCTCACTAAACCCTAGCTTTTGCTCTGTCTATGAATAATGAATAATGATCAAGGGGTGCGTCCTCTAGGGGCCAGGGTGTCTGGTTATATAGTCTTTTCAGATGAATCTGGGTCGTCGGATCAAACCGACATTGATCGTGTGGTTTTCCTTGAAGTATTAGGTCGGTGGAGCATGATCCACGAAGTTGAAGCTGATTGGTTACTGTAGCTGGGCGGGCACCCATGGGACTTGGGCGGGCGCCCTGCCCCCGGGCCCGATCGGCCTCCCGTTCGTTCCCGTGGCTTCTGGAGTCTTCTAGATGGTAGAAAATTGCGCGGCACGTTAATATCTCTATGTAAACCCGATGTGTGGGTCTTTCTTTCATATTTCCTGATAACCCCCTACAGAAATAGACAAACACCAAAACTCGTGGAATTCTGTCAGATAAAACCCTAAGTCTAGATGTTGATTTCATTTGGATCCTTTTCTTTGTTTATTTGATAATTAAATTTGATACTTAAGGACCGTCAACAAACTCCCCCAAGCTTACCTCTTGCTCGTCCATGAGCAAGGATAGACTCAGCAATGGATCAGAAGTTGTTGCAATATCTTAAAATTTTGATGGTACACATGCTTTTAAATAAGATCTCATCTCTGAGTTAGAGTAAACTGTCAAGAACTAAAACTTACTTACTTTACCTTTCACCATGGGACTTGTAACCATCACTTCTGTCTTGAGTAGTTAAAAGATAGAACAGTCTAGCCAAGTGCCATATCTCTTATTCTTGATCAGCTATAGCTCTGGAGTTTTTGCAGATTTTCAAATAAAACTCAGAGATTCCTTGTATGACTCTCTAAATCTCTCTTTTGTGGTATTTCTGGATCCTTACCAAGGCAGCGATGGTATATGCCTTCTCTCAAGATATGTGGTAGTTGTGGTATAAGGCATAGTGACATTTCCTTCTCTCTCACCCTACTCTAATAAGGCTTTAATATCTGGAGCTCATAGGTGGGAGATAAAGTATACATACTTACAAGACATTTATTGTATAGTTAAACCATGGATCCAAAGAAACAAATCAATAAGCCAAATCAAGATGTGCATGTGTGGCGAATGAATGGTGTATGGTGATGATGGTGATAACAATGGTGAAAGTCTAATTCTACTTTTGCTCTTTTGAGGGGATATATACCTTCTTTGCTTTTTGAAACTTTATGAGGAGAATGAGATGTTCTATCTTCCATTTTTCTTTCCTCTCAGGTGCGTATCCTGTACCCCTAATTCTACTGTCGGACACTTGTCCATTTTTACCTCTCGTCTCACTCTTTTTCTTTTCTTTCGAGGTTCCGGGCACTTGCCCCTTTTTATTTCCTCGTTTATTTATTTTTTTTTCTTTTCTTCTCTTTTCTTTTTTTTCAGAGCACTCATCTCTTGAGATAATATAGCAAGTGGTAGTAGCAAGATAACTTGAGCATTTATTTCACAAGGGAAAACAGAAATATTTTTGGCTATTCTCTCCCGGATTAGGAGTAGAATATTTTTGGGTGGTTCTGGAGATGGACATGGATGGATATATGTGGATGGTACTTTCAGAGTAGAAGTAGCATATATGAGTGAATGTGCAAGTGAAATCTTGATTTAACCACATGACATGCTCCTAAGGGTCTACACAGCTTGACCACACTCAATGCTCATAAGCAGTAAATAGTAAATGTGTGGCTCAAAGTCTAGCAAGCATGTATATATGGCTGTGGTAGGAATTTAAACTTTCATCATACCGGAACTCATCATGCAATATTTTAATGATTTTTCAAAGATAAAATTCTCCAGAATTTTAGCATATCTAGGAACAGATAAACAGCAGCTCAACCTTCCCATATCATATCCGTTAACAACTTAGATTTCAGATCAAGTTTTTATCCCACAAGTTTAGATCTAGAGCAAGCTTTAAATTATAACAGTTATGTCTAAACTTGAGAGAGAACTTCAAATTTACAAATTAGGCAGAGCAACTATTCATCATATCCATGCTAGAGTTTTATTATTAAGATTCAGATTAGCATAGCCACTTTATTTATTTATTAAACACACTAAGCAAAAGATATATATAAGCACAAAATCTTTATTTGGTTTTTCATAGTTTATGTATTTTAATATTCTAATATAATATAAGTATAAAGATAGTTAGAAATACTTAGCGAGATAAATGGGGGTGCTCTTCCCCAAGCTGAATTTTGACGTAATTTCTCTTGATGTAGCTAGCAGGTGGCAGAGGTGTATTTGAAAGTCAGTAGCATTCTGACAGCGATTAGAATGTCCTCCGTCTGCTAGTCTTCTTGATTCTTAAATTCTGTGGAGCTCAAATAGACAACAAAGCTTGTGGAACTAATTAAGTGTTAGCATAAATATCTAGCCTTCATCATGTTGAGCTTCGTCAATAAATATTACTCCCTGTTTTTATATTTTTATTTTATAAAGCAGAAAAGAAATATTTATTTTATTTTTATGCCACCACAGTGAAGGTACTTATGGGTTTTATGCCACTCGTATACTCACATGGGGCTTAGTATTTTTTAATATTTTTATTTTCTTTTCAAGATAGCATGATTAACTAATAATCTATTTAAGGAAAGTAAATAATTAAAGGGAAAAGGGAATGCAGAAAGGATAAATATGGATAACTACCGATCTTACCTTTCGGCGAGGGTTCAATGTTTTAAGTCTTCTTAACAAGACTTCTCACCGTGTTCATTCTTCAGGTGCGTCATTTGATTCAGGTGCGGACCTTGACGTCTGCACCTCTTCGTTTGCCCAGCAGTGGCGTTGGCAGTATCCTGCTCAGTGTGTTTGTGCTCGTAGATCCAGGTCCTTCACTTGGTAGAGTTTGAGAGTTACAAAACTTCTCTGTGTTTTGTTCAAAGTATACCTGCTCATAGAGACAAGGCAGAGATCATGTGCATGGGTCCTGTTGGTGGAAAACACCAACAGAACCTAAAGTGTATTTGTTCTTCTCTAACCCTAAGCATAGTGAGCAAGACAAAGTTGATGGATGAAAAGTTCATGAGTGTAGCACTTATAACATTTGTCAGATCAGATCGCTCAACCTTATGGAAAGATAATCTATCTATGTATAATGCTTTTTCTTTATATCTTCTCAAAGATTGAATGTATAACATTTTAGCTCATATGATTAGGAGTGTGGGATCATGGAGGTAGTACTAAGAACAAGGATTAAAGGACTAAACATGTTGAATCAGTTGGGTTGGTTAATATAGAGTTGTAAATCATACATGTTTGTCTCTTTTATTTATATGAACGCTAGAACCAAGGAGAAGCTTATAAAAGTGATAGTCAAGTACCTTAAGATGTTACCTTGCTTGAAGAGTGATGGTACAATATCACCTTGTGGAAGCTTTCCTTTCTTAGCGGTTGTGCATCGTGTTTGTGGCACCCTCCGTGGATCATCTCTCTATGATGAATGAGCTATGTCCTTCTTGTGCAAATTGTTAAACTTCATGTGTCACTCTCTTCGTCTCTGATGTGAGTTTATCTCAGGACTTCCCAAATCGATATTGAAAGTTTTTCTGCAGGGGTTAGTCCGACAAAAATATACCAATGTCTACACAAGCAGTTTTTAGTTCAATAACCGAACTAGACTCCATGTCTAATCAGATTAAGGAAGGCTGTTTAACTTAAGCACCATGCTTAATTTAAAAGCCAATAGAAGTATGTGTAGTACTTCCAAACTAACACTTACTAGGATAAACAAAGGTAGCGTGATGGCATTTATAGAGATCTACTCGAGTGGAGACGAAGTAGTGTGATTAGTATTTAACAAATTGAGCATGTCTTAAAGGTAGGGACAACCAACATAGCAACATGGCAAAGAATGTTTTTATGTAAAGTACTCCCCTAAGCTTGATTTTTGCAGAATTCAAGTTTGGATGAATTTAATTCAGTGTTGCATGATGATTGGTTGGACATACCTTGTACTTGCTTGTCATTCATCTGATCTTCTTGTTCCAATCCTGAAAAGGTTAGTGACAAGAATACCTGAAGGAATATTTTTACAATTATCCTTATATGCTCAATACACAAGGTAATGTTGCAAATAATTAAAAACTCATGTTACGATCTGATCAGTGCTTATTTTAGGACACTGAGCTTGTCCTTGGGAAACCATCAATTTATGTCGGCGAAGTGGTTTCCCTTCCAACGCTGACCTAAATCAAGATCAACTCAACGCGATCTGCAATATTTATTATAGACATATGCATCGACAACCACCCTTTTAAAGTTTTTATAAATAGAAAGGAAGAGGGGGTTGGAGATCTCAAATGTGGTGATGTTAGAGAGACCAATAGATTGGGAAGATGTTACATATGAGCATGGAGTAAACAAAGTGGCTATGAAATAAATTCCATGCTCATTAATGTTATCTTCGTCTCCAATCTGAATGTTCAGAGTTCCTCTTGGATTGGTCTAACTTATGTCCTCTTCTATAGTTGGATGAATCCCATCTTCAAAGGGAGTCAAGAACTCACCATTTGAAATTGAACCAAAGTCAGAATTCATTAAGGCTTCTTCCTTATCCATCCATTCTACACATTCTAGCCATTTAGAACTTGTGATCAGGAAAGGGGAGGTGTTAGAATTTTCTATATGGCTTAGCTCTCCTTCACTTGATATGTCATCCTTGACTTCTTCATAACAGGAACCAGGACATTCTCTAAGGATATGTCATCCTCGACTTCTTCATAACAGGAACCAGGATATTCTCTAAGAGAACCATTATTGCAAGGATTTGAATTATCCCTACTTGAAGGTCTCTTATGGAACCAGAAGTCTAAACCATCAGCATCTGAAAGATTTAAGGTCGGAATTCCTTCCTCCCTTCGACAATTTTGGGGTATTGATGGTTTAGGATTGATAGCTAAAGTTTGGAATTGAAGTGGTTGTGATCTGGCTATCGAAACTTCTTCTTCTTGTCTAGGAACTGGTTCTGTCTCTTTCTCAGGGATATAAAAGCTAGGAGACTTTCCACTTAATAAATCAATCAAATTCCAAGCTTCACTAGCAGGTAGGTGATAGAAGGATCCTCTAGAGGCTGTATTCAAGGTTTGCTTATCTTCCCTACTAAGGCCCTCAAAAAAGTGAATTAGAAGAACTTCTTCTGGAATAGAAAGCTTTGGGCCAGTGAGAGTAAGGTTAATAAAGCGGTCCCATGATTTGCCAAGAGATTCTTCTTCCAGTTGTCTAAAAGAAATAATCTCACGCCGAAGTTCCGCCACTTTGGAGATTGGAAAATACTTAGAAATAAAACTACTATATAACTCCTTCCAATCTCCATGAACACTCCCTATTTTGAGTTTGTACCAATGTCTAGCTTTTCCCGTTAAAGAGAACGGAAAGAGCTTCCATTTGAGGGTCTCATCGGACATTCCTTCTATGCGAAGGAGGTCACAGACTCGATAAAACTCTCTTAGGTGTGTCTATGGGTTTAGACAGAGCAAAAGCTAGGGTTTAGAGATGAGAGCTCTCCTCTCTTCTCTAAACTAGAGTAGATCTAGATAGTAGCGAGATGGAGAGCGAGGGAGGATGGGAGGAGAGGCCGGCCTGTCGGTTCTTCCTCCAGTTGTACTTCGCCATGATCAAGCTCTAATCAAGCTTGCTCATGGGATGACTCTGGTAATCTAATTCTAATTCATTATACAATTACTAATCCTGTATGTTCTGGTTCACAATTCTTTTGAGTACTTTAATCTATAGGACGCTATAGGTGAGAGTTGTAGTATAGGTGTAAGCGTGGTGCTTAGACCTAGATTACTTGTGGATATCCCCTCTCTAGCTAGATCTTGTGGTAGGCCGCGTAGGTGACAGTTACGTTGGTCCCCTGTAGTCCACCTCTTGTTAGTAGGACGGGTAGGGTTTATCGGCCTATGGATAAGCATCCTTTGTGGTGTATTCTTATCACGTGGTTCATCCCAGACATAGACATACCTTTTTGAAGTAGACAAACCATAGTTATCCTCTCTATTCTCCTACCATCGCTCGTATACTAGATTGCTCAATTCTCTATTCCCCTATTATTACACATTGTTATCTTATCTTTAATATTGCTCTTATTCAATTCTACCATCTTTCCTATTTACACTTATCTATCTATCTTGGTTAAGTTAGAGCATAGTTGGTTCACCAGTTTCCTTGTGGATACGATAAAACCTTTAACCGGGAAAAAGCTACAATGGTATCCGTGCGCTTGCGAATTTATCTGTGTGCATATAAATACCATAGTACACTCTAGTGCCATGTTGGGGATGACAACCTAGTATTCAAGTGGTGTTAGCAAGTGTCAACAAGCATTTTTGGCACCGTTGCCGGGGAGACGGTTGCTGAGTTGACTACGAACTAGCTTAATCATTTTATAAAAAAATAATAAAAAAATATATATTTTCCTTTTATCCTTTGCCTCATCTCTGCTATTCTTTCTTCTTATCTAATCCTTGATTTCTGGTCTATCATGAATGCAAACATGTCTATCTATGAATTTCATAGACCTACGGGCACACATCTCGAACCACCAAAATCTTCAAAGCCTATCATAGCATCTAGTTTTGAGATAGACCCCGAATACATAGAATTTGTTCAAAAACAACCTTTCTCAGGAGAAGGTGAGGAAAACCCATACACACACCTAAGAGAGTTTTATAGAGTCTGTGACCTGCTTCGCATAGAAGGCATGTCCGATGAGACCCTTAAATGGAAGCTCTTTCCGTTCTCTTTAATAGGAAAAGCTAGACATTGGTATAAACTCAAAGTAGGGAGTGTTCATGGAGATTGGAAGGAGTTACATAATAGTTTTCTTTTAAAATATTTTCCAATCTCTAAAGTGGTGGAACTTCGGCGTGAGATTATTTCTTTTAGACAACTGGAAGAAGAATCTCTTGGCAAATCATGGGACCGCTTTGTTAACCTTACTCTCACAGGCCCAAAGCTTTCTATTCCACAAGAAGTTCTTCTAATTAACTTTTTTGAGGGCCTTAGTATGGAAAATAAGCAAACATTGAATACAGCCTTCGGAGGATCTTTCCACCACCCATCCGCTAGTGAAGCTTGGAATTTGATTGATTTAATGAGCGGAAAGTCTCCTAGCTTTTTTATCCTTGAGAAAGAGAAAGAACCAGTTCCTAGAAAAGAAACAGAAGTTTCAATAGCCAGATCACAACCACTTCAATTCCAAACTTTAGCTATCGATCCTAAACCATCAATACCCCAAAATTCTCCAAGGGAGGAAGGAATTCCGACCTTAAATCTTTCAGATACTGAGGGTTTAGACTTCTGGTTCCATAAGAGACCTTCAAGCAGGGATAATTCAAATCCTTGCAATAATGTTCCTCTTAGAGAATGTCATGGTTCCTTTTATGAAGAAGTCGAGGATGACATATCAAGTGAAGGAGAGCTAAGCCATATAGAAAATTCTATCAGCTCCCCTTTCCTGATCACAAGTACCAAATGGCTAGAATGTGTAGAATGGATGGATAAGGAAGAAGCCTTAATGGATTCTGAGTTTGGCTCAATTTCAAATGGTGAGTTCTTGACTCCCTTTGAAGATGAGATTCATCCAACTACAGAAGAGGACATAGGTGAGACCAATCCAGGAGAAACTCCGAACATTCAGATTGGAGACGAAGATAACATTAATGAGCATGAAATTTATTTCATAGCCACTTTTTTTACTCCATGCTCATATGTAACATCTTCCCAATCTATTGGTCTCTCCAACATCACCACATTTGAGATCTCCGACCCCCTCTTCCTTTCTATTTATTAAAACTTTAAAGGGCGGTTGTCGATGCATATGTCTTTAATAAGTATTGCAGATCTCGTTGAGTTGATCTTGATATAGGTCAGCGATGGAAGGGAAACATTTGCCGACATAAATTGATGGTTTCCCAAGGACAAGGTGTTGGGTATTCTTAACATCACTACCAAAAGTAGACAGCTTTCTAATTCTAGTAACGGTGCCAAAAATGCCAAACCTATCCCTCATACCACTTAAGCCAAGTTATGATCCCCAGCATGACATGAGAGACGCGGTATTGAAATATGCAATTGCTCTTCTAAATATATAATGAATGGAGTCTGCAAGCGCACAGATTAATACCGATGTAGCATTTTAACCGGGAAGTATTCCAGGTATCGTTATTTATATTTTTACCACTGGGAAGGGATTAACAATCATCAATATTGATTACAGAATAGAATATGAGATTGAGTATCTATCATTGCATGTATAATTGAGAACATTGTATCTAATTCTTTCATATAGGGGTAAGTGTCACATAAAAGATATATGAAATAATGAATAGTGACAAAGGTAATTAGTCTGATCATAACTTCGCCACATATATATATGATAAGCACCTCAATTAGATACTCTAGAAAGTCATTAGCATGGTATTAGAACGAACTACAAGAATATTTCCTAAGTTATTCTCAACTATATAGTCTAGCATTATCATAGTTAGTGCAAGCATACTTAGCAATCATTGTGAGACAAGACTACGCCCATGCATAGTGATATTAGCAAGGTAAATGAGAAACATAGCAATCACTCCCCTGTAATAATGTTGCTCTGCTAGCCCGATACACGAGAGGGGGACTATATAAGAATCAATGAAGCTGTCACTATCACGAACTACCCCACGATCTGGCATATTGGGTACAATCACAGATAAATACGGTATAAGCACCACGCCTACACAATATCTATCATTTACCCATGGATCTGATGGATAAACGCTATACAATCCTAAACATGTATATAGATCCAATCTGTCGAGGGTATCAGTAAGGGGTACCCTCACCGATGCACATAACGAGACTACCCGTACGCAGGTCGAGGCCCTCAACTCGATGCCCTGGTCATACATATGCGCGGTCGTCGACGACCGCAGCCTCGAAGACGGAAATAGCGTCGAGCGAATCGATCAGGGTCGAGCGCCAGCTACCGTCGAATACGGAAACGGGCTCGCACGAACCAGGAGGCGTCGAGCGCAAGGACGCCGCCCGCCGCCTGACGCGTGCACGAGAGCCAGGGCATTTAATGCGCCTGTCGCTTTCCCACCTAATACGCTGGTCACGGGAAGCGTGATAGGGAACAGGCACCCGTCCCGTCGTTCTTTTTGCAGCCTTCTCCACCAAACGACCCACAGCATGTCAGGACGCGGGAAGCAGGGATGGAACGTCTAATGAGGACCCCCTCGAGGTAGCCAAGGTCAGCGCTCTGGATATCAGGGCATTGCACGGCATCCGACCCTCGATCAGACATGGTTCCTTCTTGGAGACGAGGTGGGCGTCGACTGACAACATCGCAACCACTCCGCCGGATCTGCCGCCATACCGTACAAGCGTGCGACCGGTGAACCAGCCCAAGACGGCGCGCAGAGCAGGATACAGGGGCACGCGTAATCGTCATCGAGCTACCAAGATGGGATGGCTCGAGACCACGCCAGTACGGAGGCCTCGAGTAGGTCAGCGCGCCATGCTTCTATCGACCCCTACTCTGACACCTATACATGTACCCTAGGTCTCTCCTTGGAGCTATAAAAGGAAGGACCCGCGAGTAGATAGACACACGCAACACTACACCCATACGCAGTAGAACTCCCATACTCCATACCACGCTTGTATTCGCCCCTGTACAAGCACTTAGGTGCAAGATAATACAAACTTCCCTCCCCCGCTGAACGTAGGGCCTTCTCTTGCCCGAACCAGGATAAATCTTTGTGTCTTCTTGCATCACCATCTGGGAAAGGGAGCACGCATACAAATTTACTCGTTGGTGTGACCCCCGTGGCGAAAACACCGACAGTTGGCGTGCCAGGTAGGGGTCCTGCGTGTTTTTTCATCGATTTCCCATTCCTTTCCAGATGGCCACTCTCGCCTCGCCGATTCCGCGCTCCACGGTGATTTGGTTTGGGAGTCTCGAGTTCATGTCTACTGGCTCCGGCTATGACATGATCTTGCTCTCGATCAAAGGACCGGGAGGAGCTCGCGTTGCGCCAGCACGGTTGAGGGCCCCGAGATGCCCTCGCCACCACGCCTCCCCGCCCAAGAAGAGGCGTGGACAGCACCATCGTCGCCCCTCTGCCTCGTCACGACCTGCAGTTTGTGCTAGGCAGGAGGTGACACAGGAGCCGGCAGCCCCGCGTGCCGGAGCCATGGACGTGCCGGCTCAGTGTCACATGACGACAAGAGGAGACGCACCTACCGCCAGGCTACTTCCACACGGGTTGTTCACTCCAAGAAGGGCACTGCCATTCGGATTGGACAACGTCGCGGCATCGCTAGCCAGAGCGATATGCCCAAACGCCCAGACGTACGTGGAGAGACCAATGGTCCTCCCATGTAACTCTAAAGCACAACAACCGACGTCCGAATTGCCAGATTTCTCCTAGGTACGAGGCCTCCGTCGCCTAGGCCCTGGACGGTACACGATCACCTCACTCAGGCAGCGGCTGCTGGAGGAGAGACGTGGATGTTTCTATGCCGCCAAGCCGGACTCCGATTCCAAGACCGATAGCTACGACCCTACTAGGGACTGCTATCACATCGACGGAGCGGTAGAAACTACCGACGAGACGCAGGATGCAGCTGCGGGCGGTCGAGCCCCTGCGGCAAGGGAAGACCCCAGGACGCCTGGGAACGACGGACAGGTCGACCCGCTTCCACAGGAAGACAGGGCTGCGCAGCTCGCGCAGCTACGAGAGCTCAAGACCAAGCTTGACGAGGATCGTGAGCGCCTCGTCTTGCTCGAGCAAATCCTCGAGCAAGACTTGCCTTACCCGCCTAGCGGGAGTGTCCGTAGGCGTGCTCGAGAGGTACACCGGCAAATCATCGGAGACGCGGAGCCAGAGCAACCCGTCAACCGCTTCCCTCGAGCAGGCCAGAATGTAGTGGCAGCAACAATGCTGCTACGCAACATGCCAGAGTCATCGAACTCCCAAGCTCGACGCATTCGAGACGAGGTGCAGACTTTGCTCCAGGTAGTGGCGGTTCAACAAGCCGAAAGCTCGGCTTCTCTATGACGAGGAGCCGCCACTGAAAAGCGCGATGAGCCACCCCAAAATGAAAAGGAGGTTTCAGTCCATCAACAGCCACCCCCTCGAGGAAGAAAGACCACTCTTGTCCTCCCTGTCGACAATCAGCGTCGACACAACGCGTGGCATGACATCGAAGAGAGTCGACGCCGTCGGTATGGGGACGCGGAAGAGCGTGGTTACAGCGCACATCGCGGTGGGAGGTATGACAGCGACGAGGACCGGATGGCCCCCGAACCACCAGGCCCACGGGTGTTCAGCAGGGCAATCCGCAGCACGCCTACCAGCATCGCAAAATACAATGGTGAGACCAAACCAGAGTTGTGGCTGGCCAATTTTAGGCTGGCCTGTCAGCTAGGAGGCGCTCGAGGAGATGATCGAGCTATCATCAGACAGCTACCGCTCTTCCTCTCCGACACCGCCCGTCGATGGCTCGAGGAACTTCTAGCTAATCAGATCCATGACTGGGTCGATTTGGTTAGAGTCTTCGAGGGTAATTTCAAAGGGACCTACATACGGCCCGGGAACTCGTGGGACCTCAGCAAATGCAAGTAGAAGTCAGGAGAAACTCTTCGAGAGTACGCTTGACGCTTCTCAAAACAGCGCACCGAGCTGCCACATATCCCCGACCACGACGTCATCCTGGCATTTGTCTCTGATACCACTAGTCGAGACTTGGTGCGGGAATTAGGTCAAAATGGACCTCAGACCATCGATGAGCTCATGGACGTAGTGGCAAACTACGCAGCAGGAGAGGAAGCAGTCGGTGCCTTCTTTAGTTGTGAAGGAAGGAAAGGCAAGCAGCCTGCCGATGAAGATGGGACCCCCAGTCGAGGGCTCAAGAAGAACAAGAAGAAGCAGAAAGTGCGGCAGTTCAAGTAGGAGAACTTCGACGACGACCTCGTCGCCGCCATGGAGCGGAAGAAACCTCGAGGCCCCCCAGATGGGGGTATCTTCGATAAGATGCTAGAGGAACCATGCCCTTACCATAAAGGAGGAGCCAACCACAAGCTCAAGGACTGTCGTATGCTGAAAAAGCATTTCGACGGCCTAGGGTTCAGAAAGGACGCGCGCGACGACCCAAAGAAGGAGAAGGCGGCGACAAGGAGGGCAACAAGGATGACGATGGTTTCCCTGCCGTCCACAACTGCTACATGATCTATGGTGGGCCCTCAACGCAGTTGACTGATAGGCAGCGCAAGAGGGAACGCCGTGAGGTCTTCGCCGCAAGAATGGCGGTGCCCCAGTACCTCAGCTGGTCGAGCACACCCATCACCTTCGACCGAGAGGATCACCCCGACAAGGTGGTTGCCCCAGGCGTCTACCCGCTCGTCGTCGACCCCATCATTGTCAATACCCGGCTCTCGAAGGTGCTAATGGACGGATGCAGCAGCCTCAACATCATCTATCTCGAGACCCTCGACCTCCTCGGCATCGACAGGGGACGGCTCAAACCAAGCGCTGGCGGTTTCCATGGCGTCGTGCCAGGGAAAAAGGCGCTGCCAGTGGGTCGAATCGACCTACCCGTCTGCTTTGGCACGGCAGCCAACTTCAGGAAGGAGACGCTCACCTTTGAAGTGGTCGGGTTCCGAGGCACGTATCACGCCATCATCGGGCGCCCGGGCTACGCCAAGTTCATGGCCATACCCAACTACACTTACTTGAAGCTGAAAATGCCCGGTCCCAAAGGAGTCATCACCGTCAGCTCCTCCTTCGAGCACGCTTACGAGTGCGACGTCGAGTGCGTCGAGTATGGGGAGGCGGTTGAAAACTCCACCCAGCTCGTCGCAAAGCTCAAGGCCCTGGCCGCTGAGGCTCCAGAGCCCAAACGCCACGCGGGCAGCTTCGAGCCAGCAGAGGGGACCAAGAAGATCCCGCTCGATCCTAACAACTCCGACGGCAAGGTGCTGACGATCAGCGCCGACCTCGACCCCAAATAGGAAGCTGTGCTTGTCGACTTTCTCCGTGCGAACGCCGACATGTTCGCATGGAGTCCCTCGGACATGCCAGGCATACCGAGGGAAGTCGCCGAGCACTCCTTGGAGATTCGAGCCGGTTCCAAGCCAGTGAAGCAACGGTTGCGCCGATTCGACGAGGAGAAGCGCATGATCATTGGCGAGGAGGTCCACAAGCTTTTGACGGCCGGATTCATCAAGGAGGTTCACCATCCCGACTGGTTAGCAAACCCTGTACTAGTTAAGCAAAAGAATGGGAAAATGAGGATGTGTGTCGATTATACGAGTTTAAATAAAGCATGTCCGAAAGTTCCCTTTCCATTACCATGTATTGATCAAATTGTTGATTATACTGCGGGATGTGAAACCCTTTCTTTTCTTGATGCATTTTCTGGTTACCATCAAATAAAAATGAAAGAGTCCGACCAGCTCGCGACCTCTTTCAAGACACCTTTTGGGATGTATTGCTATGTAACCATGCCGTTTGGGCTTCGAAATGCGGGAGCCACGTACCAACGCTGCATGCTTCACGTATTTGGCAAGCACATAGGGTCGACGTTCGAGGCCTATGTCGACGACATTGTCGTCAAATCAAAGCGGCGAGGAGACTTGATCCAGGACCTTGAGATCGCTTTTAGCTGCTTACGCGTCAACCAGATCAAGCTCAATCCCGAGAAATGCGTTTTCGGCGTGCCTCGAGGCATGCTCTTGGGTTACATTGTTTCCCAGCGGCATCGAGGCCAACCCCGAGAAAGTCTCGGCCATCACAAGAATGGGGCCAATCCGAGACATCAAGGGTGTGCAGAGAGTCACGGGATGCCTAGCGGCGCTGAGCCGTTTCATCTCGAGATTAGGAGAAAAGGCGTTACCACTGTATCGACTTCTAAAGAAGGTCGAGCGTTTTTCTTGGACCCCCGAGGCTGAGGAAGCCCTCGAAAATCTGAAGAGAACGCTGACCTCAGCACCAGTCCTGGTCTCACCTCAACCTGCGGAACCACTGCTCCTTTACGTCGCCTCGACGACCCAGGTTGTCAGTGCGGCGGTGGTGGTCGAAAGGCAGGAGGAGGGGCACGCATTGCCAGTCCAGGGGCCAGTATATTTCGTCAGCGAGGTGCTCTCGGAGACCAAGGCACGTTACCCCCAAATTCAGAAGCTGATCTACACCGTAATCCTCGCCCGCCGTAAGCTGCAGCACTACTTCCTCGGTCACCCCATCACGGTGGTCCCGTCTTTCCCCCTGGGCGAGATAATCCAGAGTAAGGAGGCCACGGGAAGAATAGCTAAATGGTCGGTCGAGCTCATGAGTGAGACTCTCACTTATGCGCCTCGCAAGGCCATCAAATCGCCAGCTCTGGTGGACTTCGTCGCGGAATGGACAGACTCCCAGCTTCCCCCGACCCAGGTCCAGGCGGAGCTGTGGATGATGTATTTCGACGGGTCACTCTTGAAAACAGGGGCCGGGGCCGGCCTGCTGTTCATCTCGCCCTTGGGCATCCATATGAGATACGTCATCAGGATTCACTTTGCCGCATCTAACAATGTCGCAGAGTACGAGGCCCACGTCAACGGTCTCAAGATCGCCATCGAGCTAGGAGTCCGACGCCTCGACGTCCGAGGCGACTCCCAACTCGTCATTGACCAAGTGATGAAGACTTCAAGCTGCCATGACCTGAAAATGGAGGCGTACTGCAAAGAAGTCCGTCGACTCGAGGACAAATTCCATGGCTTTGAGCTCGTCCATGTCGCCCGACGCTACAACGAGGCAGCCGACGAACTCGCCAAGATCGCGTCGACCCAAGGCACGGTGCCACCTGACGCGTTCTCGAGAGATCTTCACGAGCCATCCGTCGACTTGGGCTTGGGGGCTGGCGTCGATGCCGATCCTGCCCAGCCAACCGACATCGTCGACGCACTGTTAATGTCAGCTGAGGCGATGGAGGTAGAACAGCGGCCCGGTCGACCGTTCGACTGGCGCACACCATTACTCGACTGCCTAATCCGCTGCGAGCTGCCAGAAGATCGATCTGAGGCCCGCCATATCGCTCGAAGAGCCAAGTCATACGTGATTTATGGCGAAGACAATGAGCTATATCGATGAAGCCCGACGGGGATTTTGCAGCGTTGCATCACCGTGGAAGAAGGCCGGAAACTCCTCGAGGATCTGCACTCGGGGGCTTGTGGCCACCATGCTACTCCACGGACCCTTATAGGGAACGCCTTCCGACAAGGCTTCTACTGGCCAACGGCCGAAGCAGATGCCGTCAAGCTCGTACGCTCATGTGATGGTTGCCAGTTCTACGCCAAACAGACGCATCTGCCCGCCCACGCTCTTCAGATGATCCCCATCACATGGCCATTTGCGGTGTGGGGGCTCGACTTAGTAGGGCCCCTACAAAAGGCGAAAGGCTGGTACACCCACTTGCTGGTGGCCACCGACAAATTCTCCAAATGGATCGAGGCTCGACCCATCACCAACATCCGCTCCGAGTAGGCCGTCCTTTTCTTCACCGACATCATCCACCGGTTTGGGATTCCCAACGTCATCATCACCGATAACGGCACTTAGTTCACCGGCAAAAAGTTCTTGAACTTCTACGATCAGCATCACATCCGTGTGAACTGGTCTGCAGTAGCCCACCCTCGAACTAACGGCCAGGTCGAGCGTGCCAACGGCATGATTTTGCAAGGACTCCAGCCAAGGATCTACAATCGCTTGAAGAAATTCGGCAAGAAGTGGGTCGAGGAGCTTTCATCGGTCCTATGGAGCCTGAGGACAACGCCAAGCAGGGCCATAAAATACACCCCATTCTTCATGGTCTACGGCTCAGAGGCTTTCCTCCCCACAGACCTCGAGTATGGGTCTCCTCGACTCAAAGCATACAACGAGTAATCAAATATGGAAACTCAAGAAAACGCGGTCGACCAACTTGAGGAGGCTCGAGACATGGCCCTCCTCAACTCTGCCAGATATCAGTAGAAACTTTGACGCTACCACGACAAGCACGTGCGCAAGAGGGACTTAAACGTGGGCGACCTTGTCCTACGACGGCGGCAAAGCAATCAAGGACGCCACAAGCTGACTCCACCTTGGGAGGGCCCGTACGTGGTAGCCGAGGTCTTGAAGCCAGGGACGTACAAGCTCGCGGACGAAAAGGGGGCGATCTTCACCAACGCGTGGAACATCGAACAGCTACGTCGATTCTACCCCTAGAAGTTCAAAACTTTATGTCCCTATGTACATTCTGTACCAAGGCCTTGTAAATGAATAAATAAAGCCTTTCCCTCAAGCGATTTACTTTCTCACAAATCTCGATGCCAGAAGGGAGTACCAACTATGACCCATCATAGTCAATACCCCCTCGGGGGCTACCAGGGGGGCAACCCCCCCCCCAAGTGTCGAAAAAACCAAGAAATTCTCTCTTCCTTACTTAGTAAACCTTGCACGTTCGAGTAGTTGAGGCGCCTCGAGCCCCTTAAGGGCCGAGGGACAACGAGTCTGAGAACTCCTACGCCCCCGGGCTATGGAAACTCTACACACTTCCTCACCCTCGAGGTGACCGAGGCTGTTTTTAACAAAAGATCGAACAAGGAATACAAACGTAGGCGCAAAGGGAAATAAAAGAACCTCGAGCGGAAAGATAGATAAACATTTAACAGTCACAAAAAGACATTGTACCACTTATAGAGAAGTTAATAGAGTATTATACAAGGGGCCCTAGGCACCCTAAGCAGGCTCGCAGGCCTCAGTCTTCAGCACGATCCTCACCACCCTCGCCTACGCCCGAGCTAGTCTCAGGAGGAAGCACCTCAGGCTCAAATAGCTTGGCCAGCCTCTCTCCAGGAGCCTCCGCGTCGTCGATCAAGGCGTGGAGCCTCTCTTCGTTCTCCGCGTCGGTCTTAGAGATGTCGGTGACGAAGCCGTGGGACACCACCTCCATGTCGTAGGAGAAGACCGAGCAGACAACCGCCATCGCCCGCTTCACCCCGATGTGGAGGGCATCCCGCACCCGATCTCTCAGCGTCGCGCCTAGGTAGCACAGCTGGTCGACCAGTGCGTCGCCTCGAGCGTCCTCCTTCGACTCGTCCATAGGCTCGACCTCCCAAGAGGTCGAGAGGTCGTTTATCGCCGTCCGCACTCGACGGTTCAAAGCAATCTCCGCCTCAAGCTGGGCCTTAGCACTACGGGCCTCGACTTGGGCGGCCAAGAGTTCGTCCTTAAGCCCTATAAATGCCAATACAAGAAGCTTTAGAAAAAACCAAGCACACCTCGAAAAAGAAATCCGACAAAGGAAACGTACCGCGGACATTCTCCTCCAGGGCCGTGTTCTCGCCGATTAGTCTGGTGTTGGCCCTCTCGATCTCTTTGTTGGAGCGGGCCAGCTCAGTGTTGGCAACGCGGAGATCCTCGATCGCCTGGCCAGCCTGAGCAATGGCCCCACTCTTCTCCAACAGCTCTCCCTTCAGACGTTCGACGTTGTCAGAGAGACTGCGGGATCGAGCCCGCTCCGCCTCGAGGTCTTCGAGGGCCTTCTTCTTTGCGTCCTCGACGACACCTCTAGCGACCTCACTGTCCACATACGCCACCTTCATCTTCTGGAAGGAGTCTCGGAGGGAGTCCAGGTCGGTCTTGAGAAGGCCCTTCTCCTTGTCCAGGTCTGCAATGACGCTCTTGTAGGACAGGGCCTCCTCCCGGGCTTTGGATGCGGCCTCCTCGACCGTCAGAGCTCGCTCCCGCAGCAGCGTCATCTCCTCCTCTGCCTTCTTTGAGGCCTCTTGAGCCTCGACCAGGGCAGCCTCCCTTGCCTTCTTCTCCTCCTCGAGCGCTATGAGGTCTTTGTAGGCCTTAAGGAGCTTTTCTTGCGACTCGAGGAGTTGGTCCTAGAGGACGGGGAGCTGCTCCCAGCCTCCTCTTGTGGCGTGAATGAAGCTAGACTTGATACGGGAGGTCTCTTTCATGTCCTACGAGCCGGGGGTCGAACGGTTAGAACACGAAACCAAAGGATCTATGAGAATTAAGGACCAAAAAATACTTACAAAGTAGGCCGGCCCGAGCCCGTTGTTGATGACGTCCGATAGGAGCCCCACCACGTGCTTCATCCAAAGGCGGAGCTCCTCAACGTGTTCCCATTTCGCCGCCTCCTTCCTGTCGTCCAGGAAGATGTTGGGCTCGGACGGATCGGTGGAAGCCCGGATGCGGATCCGATCGGGGCACCAGTTCTCCATCTCCTGGTCAGCCCGCGCCTTGACGCCGCGGATAAGGTCCTCGACGGTCTCGAGGGAGCCCCCATGGCGCAAGAACAGGTCGACGAGGCATGGGAACCGTCCGTCGTCATCCACCGTCTTCCAGGTACCGTCCTTACTCCCCGACGTCCCGATCTCGTCCTCCTCAGAGGGAAAACGGTCCTCCCACGCCCGACGCTCTCGGAGGAACCCTGGGGCGATCCCATCCATGCCGTAGATCGTCTTCCTGATCTCGGACTCGGGGTCGGCGGGGGTGCGCATCATGCAGGCAAGTGCCACCACACTGTCCGCTCGCCCCGGCTCTGCCCGGATCGCGGTGGGCGCCCCCGGAAGGAGCCACGCTGGGGTTGGAGGGCCGTACACCGGCAAATCCTCTTCCTGTTCTCCGGGCTCTTGCGGCGCCGGTGGTACTGGTTGGGGCAGACCTTGAGGCAGGGGCTCGAGCGGTCCTTCTTCTTGGCCCCCCTAATGCTGTTGCTGCCCCTCGAGCATTTGCTGCTGTTGCTCCACCTGCTGCTGCTGCTGCTGCTCCTGCTGCTGCTGCTGTTGCTGCTCCTGCTGCTGCTGCTGTTGTTGCCCCGCGTGTTCCTACGACTCTTGTCAGCGGCCCTGCTCCTGCGGCTGCCGCCTCGCCTCGCGCTCCCGCTCCTCCTCCTCCTCCTTCTTCCTCTGCTCCTCGAGGGTGCGGAGACCAGCAGGCCAGGGCGTCCGTTCCACGACAAAGGAGGTCGACGCCTCCTCATCCATAGGGCGGGCATCCCTCGACGTCTCGTTGCCGCCAGACGTGTCGCAGATGGTGATGGGATCCCCCTCGACCCCCGATCGGGGAGGCTCGGGGGCTCCCTCTTGCCCCTGGGTCTGGGCCACCTCGACCCGTGTCGGCGGCGACGGGGCAAGCTCGAGACGAGGCGGGGCGCTCTCAGCGACGGCCGAAGGCTGAGAGTCGGAGGAGCCTATAAAGCCAAGAATAAAGGTCGGTCATTGTAATGACCAACGTAAGAACATCACAAGTCCCAGAGGTAAGTCACAAACCTGGCTCCTTGGAGGCTGCTCCCATTTTGAGCCTCTTCGCCATTGAAGGCTGAGCCTACTCGAGCGTCCACTTTAATCTGAAACAAAAGGAACAAGCGTAAAAAGACCGGCATACAAGAAAACACAGAGGAACAGGAGAACAAAAGTCACAACGTCGAAGAGCTTACCCCACGGGGAGAACAGCTCGCCTGCCGGTGCCCCGACCGGTGGGCCTCGAGCCACCCCGTGTCAAGGTCCCAGACCCCTCGAGGACAGGCGTTGGCCTTGGCCCAGCAACTTCCCCTTGGTGGGCACCGGGACTGGTGCTCCTGCGGCCAGTGTCTCCTTTCTCGGAGGCCGCGGCACGACCGCGAGTCAGTGGCCCCGTCGCCTGAGGCCTAGCATGGCCACCCATCTTGGGCGCTGGGGGAGGGCGCGGGGCAACCTGACCAGTCGCGGGCACCGGGGGGGTGTCGGCACGAGGGCGGTGAGTTCCGCCTGGTCCCTCTTTTGGTGTCCCCATCCGCGGGGCGTCGACGTCACCTCGAGGCGGACCCTCGAGGATGCGGTCGAGGCGAGACGCCATCCCCTCGGAGTCATCGCTGTCCTCATCATCATCTCCACCATCATCGTCGTTGGGGGACTCTTCCTCAGGCTCCCCCCTCTGCCTGAATTTAGACTGACGTGCCTCTAATGCTTGGCGATCGAGGTTTTTCTTTTTCTCCCCTTTCTTCTTAGAGTCCTTGGCGGACTTTAACTTCTCGGCGAACCGGCACCGCGCGTCGCGATCAACCTCGTCCTCCTTCACTGGAGGCCTCGAGGACCGGACATCAATCCGTCCCTGCCAGAACAAAGGTGGATTTAGGAAAAAGGGAAGAAAAGAAACCCAGAATCAAGGCTGCGCACGAGAAGAAAGCATACCAGATCGATCGAGCCTACATCTGGCCTCATGGGGAAGCCGTTAACATGCTCTGGCTTGATGTCACCAGCAATGGCGGCCCTGACCCTGGCCGCGACTTCGTCGTTCGCCGGAGCCTCGCTTGACATCCGGCATGCCTCGAGGTCCCAAGATGAGGCGCCAGGAGCCATCTCGTCCATCCTCAGCGGTCGAGACATCAACGGGAGAACTCTCCGGTGATGGACGGCCAAGAGAACGAGGGCGGCGGTAAAGCCCTCCGAGCGCAGTTTCTTCATGACGTCGAGGAGGGGGTCGAGCCGAGATTGATGAACCTGGACGACGCCGTACGTCCAATTTTCCGGACGCTCCGTGATCAGACGCCCGGTGTAGGCGGGCAGGAGGTCGTCGTCATTTCTCAAGTAGAACCACTAGGAATCCCAGCGGGCGTGGTTGGTCGACAGTCCCACCGGGATGTACTCGCGCGGCCTCTCCGTCTTCTCGGTCCTCAACACGAGGTTGAGGCAACCTGCCAGAACAGGCTTCCTCACGCTGGTGGTCCCAGTGGGGGCGTTGAAGAGCTCGCCCCTGTAGAGGTGGAGCCACAGCTCCCAGTGGGGCATCATCCCCAAATAGCCCTCACACACCGCGGCGAAGACCGCGGCGACGGTGATGGCGTTTGGGGAGAAGTGCTGGAGCTCCACCCCGTAGTGCTGGCAGAGCGCCCGCATGAAGCGGCTCGGGGGAGCGCCCAATCCATGGCGGTGGAACTTGGCAAACGAAACCACATAGCCCTTGGGCGGCCTGGGCTCCCTGTGGTCCGCCGGCGGCGCGATCCACTCCGGCGACGACAGCGAGGTGCGGCGGCGCAGGAGTCCCTCCCTCTCAAGCTCTTGCAGCCGGCGCTCCGTCATCGACGATAGGCGCCAGTCATCGGCGGCGACAAGCCTCATAGGCATTCTAGCCGGAAGGATGGCGGATCCGCTATTACTCGAGGGGGGCACGCGCGCATAGGATGGCAAGGGAACTAAGGCAATGAGAGGGCTAAGGCGAGAATGAAGACGGGAGGCAGAAGGGAGAACAGCGGCGACGCCAGGACACATTTATAGGCAGCTGTCCACCAATGGGCAGATCCGATAAAAGAGGTAGCTCCCCTCCGTAAATGCGCCGTCTAATGGTCCTTTCCCTCCTCTCAGGTGGAGCGCCCCGAATTCCACGCCAACGCAGTGTCATAACGTCTCCCACCTAAAAAGGCGCGCCCAACGGGCAAGAAGGCGAACTACCCACGGTCTTTTCCTTCCCTTGTAAGCCAAGGAGTGCACCCGTGGAAGCCTCGAGAGGTCGCAGGCTGGCCCACTGAAAGGGTTCGATAGCCGATCTCGAGCACCAGAGTCAGGGATCCCTAGCGAGAGGTCGAAGATCGAGGTCCGCCTCGAAGACTTACTGGGGATGTCCAAGGTAGGGTCGAGACAGTTGAGAGGAATGCCCCCGACGGGAGGCATCGAGCCGCCGGACACTATCGAATGAGACCGGTATCCCCGACCACGTCGACCCTGCTTTATGAGAACGCCTCCGGGCTACAGCTGACCCCCTCGAAAGGGGCACAGGTTCTCACTTGGACTACCCGCTAGGAACTCAATCTGGGGTGGAAGACGCTCGCTCTATCGAGAGTACGTCAAAACCTCCGCGCAAAACGAGCCAATCAGAACCTTCCACCACTGGTGTCGATAGCGTTTCTGCGAATTAGGCAATATAACCCTTGAAGGAGTCAAAAACTCCTCCAAGGGCTCGGGGGCTACCCCCGCGGGGTCGCTCGCGCGCCCCCATGGAAATTCGATCGCAAAACAAAGCCTCCACTCGAGCGCCAGCGCTCAAATGGAGACTCGGGGGCTACTGTCGAGGGTATCAGTAAGGGGTACCCTCACCGATGCACATAACGAGACTACCCGTACGCAGGTCGAGGCCCTCAACTCGACGCTTTGGTCATACATATGCGCGGTCGTCGACGACCGCAGCCTCGAAGACGGAAATAGCGTCGAGCGAATCGATCAGGGGTCGAGCGCCAGCTACCGTCGAATACGGAAATGGGCTCGCGCGAACCAGGAGGCGTCGAGTGCAAGGACGCCGCCCGCCGCCTGACGCGCGCACGAGAGCCAAGGCATTAAATGCGCCTGTCGCTTTCCCGCCTAACACGCTGGTCACGGGAAGCGTGATAGGGAACAGGCACCCGTCCCGTCGTTCTTTTTGCAGCCTTCTCCACCAAACGACCCAGAGCATGTCAGGATGCGGGAAGCATGGATGGAACGTCTAATCAGGACCCCCTCGAGGCAGCCAAGGTCAGCGCTCTGGATATCAGGGCATTGCACGGCATCCGACCCTCGATCAGACATGGTTCCTTCTTGGAGACGAGTTGGGCGTCGACTGACAACATCGCAACCACTCCGCCGGATCTGCCGCCATACCGTACAAGCGTGCGACCGGTGAACCAGCCCAAGACGGCGCGCAGAGCCGGATACAGGGGCACGCGTAATCATCATCGAGCTACCAAGATGGGACGGCTCGAGACCACGCCGGTACGGAGGCCTCGAGTAGGTCAGCGCGCCATGCTTCTATCGACCCCTACTCTAACACCTATACATGTACCCTAGGTCTCTCCTTGGAGCTATAAAAGGAAGGACCCGGGATTAGATAGACACACGCAACACTACACCCATACGCAGTAGAACTCCCATACTCCATACCACGCTTGTATTCGCCCCTGTACAAGCACTTAGGTGCAAGATAATACAAACTTCCCTCCCCCACTGGACGTAGGGCCTTCTCTTGCCCGAACCAGGAGAAGTCTCTGTGTCTTCTTGCATCACCATCTGGGAAAGGGAGCACGCATACAAATTTACTCGTTGGTGTGACCCCCCATGGGGAAAACACCGACACAATCTAACTAAGCCAAGTATATAACTATGATAAACTAAGAACAATATAATCTTGAATATAAGCAAGTAGAGCAAAGTCATAAGCAATATATTGAAATAGAACAAAATCATATTCATAATATTGAAGAACAAAGAAAATTAGAAGAACAATTAGAAGCACAATTAGAGAATTACCAAGAATCCTCTTGACAGATCCGGAAACCAATCGAAGATTAAGTCCTTCTAGTTCTAATCCTATGTAGCTATGCTAATCTAGATGTCTAATTGATGTGGTGGCTCTAATCTTGATGAGAGGCTTCTTCTCCCTTGAAGAATAATGAATTAGGGTTGAGAGGCTCTCTCCTCCAGGGGCCAGGGGGTCTGGTTTTATAGTCCCTTCAAGTGAATATGGGCCGTTGGATCAAACCGACATTGATTGAACGGTTATCCTTGATCCTTTAGGTCGGTGGAGATCTCCCCCGAAACAGAGTCCTGATTGGACTCCAATAGAGGGCGGGTGCCCTGGTTACCTGGGCCGGCGCCCAGGTCCTGGCCCCATTCGGCCTCCGCTTCCTTCCCGTGGCTTCTGGAGTCTTCTAGATGTAAGAAAATTGCACGGCACGTTGATATCTCTATGTAACCCCGACGTGTGGGCCTTCCTTTCGTATTTCCTAATAACCCGCTGCAGAAATAGACAAACACAAAAACTCGTAGAATTCTGTCAGATAAAACCCTAAGTCTAGATGTCGATTTCATTTGGATCCTTTTCTTTGTTTATTTGATAATTAAATTTGATACTTAAGGACTGTCAACAAACTCCTCCAAGCTTACCTCTTGCTCGTCCCTGAGCAAGGATAGACTCAGCTATGAAAGTTGTTGTAATGCCTTTAAAAATTGACGGTACACATGCTTTTAAATGATGTCTTATCTCTGAGTTAGAGTAAACTGTCAAGACTTAAAACTTACTTACTTTACCTTTCACCATGGCACTTGTAACCGTCACTTCCATCTTGAGTTGTTAAAAGATATAACAGTCTAGTCAAGTGCCATGTCTCTTATTCTTGATTAGCTATAGCTCTGGAGTTTTTGCAGATTTTCAAATAAAACTCAGAGATTCCTTGTATGATTCTCTTAAATCTCTCTTTTGTCGTATTTCTGGATCCTTACCAAGGCAGTGATGGTATATGCATTCTCTCAATATATATGGTATTTATGGTATAAAGCATATTGCCTTCTCTCTCACCCTACTCTAATATGGCTTTAATATCTGGAGCTCATAGGTGGGAGATAAAGTATACATACTTACAAGACATTTATTGCATAGTCAAACCATGGATCCAAAGAAACAAATCAATAAGTCAAATCAAGATGTGCATGTGTGGCGAATGAATGGTGTATGGTGATGATGGTGTTAACAATGGTGGAAGTCTAATTCTTTTGCTCTTTGAGGGGATACATACCTTCCTTGCTTTTTGAAACTTTATGAGGAGAATGAGATGCTCTTCTTTTTCTTTTCTCTCAGGTGGGTATCTTGTACCCCTAATTCTACTATCGGACACTTGTCCATTTTTACCTCTCGTCTCACTTTTTCTTTTCTTTCGAGGTTCCGGGCACTTGCCCCTTTTTATTTCCTTGTATCTTTTTTTTCTCTTTTTTTAGAGCACTCATCTCTTGAGATAATATAGCAAGTGGTAGTAACAAGATAACTTGAGCATTTATTTCACAGGGAAAAACAGAAATGTTTTTGGCTATTCTCTCCCGGATTAGGAGTAGAATATTTTTAGGTGGTTCTAGAGATGGAAATGGGTGGATATATGTGGACGGTACTTCCGGAGTAGAAGCAGCATATGTGAGTGAACGTGCAAGTGAAATCTTGATTTAACCACATGACAAGCTCCTAAGGGTCTACACAGCTTGACCACACTCAATGCTCATAAGCAGTAAAAAGTAAATGTTGTGGCTCAAAGTCTAGCAAGCATGTATATATAGCTGTGGTAGGAATTTAAACTCTCATCATACAGGAACTCATCATGCAACATTTTAAAGATTTTCAAAGATAAAATTCTCCAGAATTCTAGCATCTCTAGGAACAGATAAACAGCAGCTCAACCTTCCCATATCATATCCGTTAACAACTTAGACTTCAGATCAAGTTTTCATCCCATAAGTTTAGGTCTAGAGCAAGCTTTAAATTATAACAGTTATGTCTAAACTAGTGAGAGAACTTCAAATGTGCAAATTAGGAAGAGCAACTATTCATCATATCCATGCTAGAGTTTTATTCAGATACAGATTAGCATAGCCACTTTATTTATTTATTAAACACACTAAGCAAAAGATATATATATATAAGTATAAAATCTTTATTTGGTTTTTCATAGTTATATTTTAATATAGTATAAGTATAAAGATAGATAGATAGAAATACTTATCGGGATAAATGGGGGTGCTCTCCCCCAAGCTGAATTTTGACGTAATTTCTCTTGATGTAGCTAGCAGGTGGCAGAGGTGTATTTGAAAGTCAGCAGCATTCTGACAGCGATTAGAATATCCTCCGTCTGCTAGTCTTCTTGATTCTTAAAATTCTGTGGAGCTCAAATAGACAACAAAGCTTGTGGAACTGATTAAGTGTTAGCAAAAATATCTATCCTTTATCATGTTGAGACTCCTCAATAACTATTACTCCCTATTTTTATATTTTCATTTTTATAGAGCTGAAAAATATTTATTTTATTTTTATGCCACCATAGTGAATGTACTTATGGGTTTTATGCCACTCGTCTACTCACATGGGGCTTACTGTTTTTCAACATTTTTATTTTCTTTTTAGGATAGTATAAATATAACTAATTAAGTAAACTATTTTAAATAATTGAAAGGGAAAGGATAACTACCAAGTTTACCTCTTGGCAAGGCGTTCGGTATTTTTAAGTCCTCCGAACGGGACTCTTCTCTTTCTCCATTGTCCTAAGATTCGTTGGGTGGCGTAGTCGGTACTTCCGGCGGCGCCTCCTCTTCATGTATAGTTGTCTTCTCTTTCCATACCTGACTCGGTGCTACGGTCTCCTTTGGATAATTCTGTTTAAACTATACGTCTTCTAACCTTACAACTTCTCCATCATAGTCTGCCCATCCGTCCTTGATGATTTGCCTCCTCTGGTTGCGGTTGCGTCGTTTTCTTACCTGCTTAGATTCTTCAAAGATATATTTAGGGTCAGTAAAATAACGGCGTACCTTCTCTAAGGGGAAGTGCATATGGACTTCTCCAGTTTTAATGTAGATGATTGCTTTAACGTTGCTGAGGAATGGTCTTCCAAGGATGATGGGTGGATCGTACTCATCTTCTCCCATGTCAATAACCTAAAAGTCTGTGTAGACAAAATGATCGTCTATTTTGACTGGGACATCAGTTACTGTTCCTTTAACTTCTCGAAATGTCTGATCTGCCATCTGGAGCTGAGTGTATGTTGGTCTTAGGGGCATGGTTCCGAACAAGAGACGATAGGTGACTGCGGCCATTATGTTGACGCCTGATCCGGTGTCGCAAAACGTCTTGTAGAAGTTGTATCCATTTATGGAGCAATAGATGCTTGGCATTCCTGGGTCATCCTTCTTGGTCAAAAACGGTGACTTAAGTTGGTGATCTTGGCCTCCATGAACTACAGTGATCATCTTAGCTGACTCGGTCCACACTTGCTTGTTCCTGTTCCTCCTGTTGGTCCTCTTCCTTGATTCACGACTGGATTGATCTAGGATTTGTGTAGTCTTGTTCCTGAAGAAAAACGTCTCCTTCCTCCCTTTGAAGTAGAAACTGATCTTGGCAGCACTAGCGTAGATGATAGCTCCCGAGGTGTTCAAGAATGACCTCCCTAAATGATGGGTGCCCTCTCATCATTACCGGTCTCTATCACCACGAAGTCTGCTGGGGCATATAAGGTACCAACTCGGACACAAAGGTTCTTCAATATTCCTTTTGGAAAACTTAATGCCTGATCTGCAAACTGCAAACACATGGTTGTCTCTAATAAAGGATATGTAAAGAATTTTTCATAGAGTACCCTGGGTATAATGTTGACGCTAGAGCCAAAGTCGCAGAGTGCTTCTGGGACGTTCACCATGCCGATGGAGATCGGGAAGACGGGCGTCCTGGATCACCTCTCTTGACTGGCAGAAGGTCAGTAGTGAATTCAGTGATGGGGTTACTCCAGTTATTACCTGCATCAAACATGTCTACAAGATTTGCAGATTCTAATCCTTCCGGTTGTGATGGTATACCGGGGTTAGTAGCAGGAACAGCAGCAGATATTTGATTTAACTGAGATTCAATCATTTTATTAAAGCTAATTTGATTCTTGATGGAAGTAGAGAAATTATCCATTCTATTATTTATATTTTCTAGCATTTTATCATTATATGCCAATTTCTTAGATAGGTTATCCATTAGTTTTCCTTGATTAGACACTAACTCTCTCAGAGGTGGAAAATTATTATTATTACTGTAAGAATTGTTACCTTGATAATTACCTGAGTAGTTAGGCCTCTGTTGATTCCAACCTTGATTTTGTTGAGGACGGTTGTAATAGTTGTTGTTGTTATTATTGATGTAGTTCACACCCTCAAGCATCTCAGGACAGTGATTGCCTGAGTGTCCAGTATCTCCACACTCCTCACAAGTCATGTGAGAGTCGTAGATGTGCATAACTTCTTTCTTATCTCCAGCTCTATCGTCGAGCTTCTTCATGAGCAGGTCTAGCTTTGCAGACAGCATGTCTACCTCCTTGAGCTGATGCATACCTCCACCTCTCTTGCGTGTCTAGGTCCTTTCTTCATTCTAGCCTTGGTTGGACGCCATCTTTTCCACAAGAGCTGTGGCTTGTGGTATAGTAAGTGATAAGAATGCTCCTCCGGCTGCAGCATCCATGGTCTCTCGGGCACTGTTGCCGAGCCCATGATAAAACATCTGCATCAATAGCCAACTCTCCATTCCATGATGGGGACATTCTAGGATGTAGTCTTGAAAGCGCTCCCATGCTTCTGGAACGGATTCATCATTTTATTGCTGAAAACTTGTAATCTTCCCACGGAGAGCATTGGTCTTGCCCATGGGAAAGAACTTAGCCAGGAAGTTTGTTGAGCAGAGTGCCCACGTAGTATTCTTCTCCTTTGTAGCGTAGAACCACAGCTTCGCTCTTCCTAACAGTGAGAATGGGAAGAGGCGAAGTAGTATAGCATCTCTGGGGACTCCTGATATGGTAAATGTATTGCAAATCTCCAGGAAGTGTTGTAGATGAGCACTAGCATCTTCGTGTGCCTTTCCACAGAACTGGTTGGATTGCACCATGTTGATAAGTCCAGGCTTGAGCTCAAAGTTGCCATCGATCTCTGCAGCAGGTCCAGTGCGGATGTTGTCCGTAGTGGGAGCTGAGAACTCGCAGATTGATTTGTTCGCCATGGCTTCGAACTCTGAAGACAAGTTTCGGTGATCTTCTTGATTGGATGAAGCTTCTTGCTGAAGTGTTGATGATCTCTTCTTGAGCTTGGCTCTAGTTCTTTTGAATAACGCTTCGGGATTGTCAACAAAATTTCCTAGAAGATGTCTTCTATTCATACATTCCCCTGCATAAGATAAAATAGAAAATATCAGGGTAAAACTGTATGAGAGAATAGATAAGCTCAATCATATTAGTGATGCGAATGATAACTCAAAATCTATATCCATTCCTGATTAGTAATCAACCTTCCCCGGCAACGGCGCTAAAAATGTTTGGTGGGTATTCTTAACATCACTACCAAAAGTAGACAACTTTCTAATTCTAGTAATGGTGCAAAAAATGCCAAACCTATCCCTCATACCACTTAAGACAAGTTGTCATCCCCAGCATGACATGAGAGACGCGGAATTGAAATATGCAATTGCTCTTCTAAATAAATAATGAATGGGATCTGCAAGCGCACAGATTAATGCCGATGTAGCATTTTAACCGGGAAGTATTCAAGGTATCATTATTTATATTTTTACCACTGGGAAGGGATTAACAATCATCAATATTGATTACAGAATAGAATATGAGATTGAGTATCTATCATTGCATGTATAATTGAGAACATTGTATCTAATTCTTTCATACAAGGGTAAGTGTCACATAAAAGATATATGAAATAATGAATAGTGACAAAGGTAATTAGTCTGATCATAACTTAGCCACATATAAATATGATAAGCACCTCAATTAGATACTCTAGAAAGTCATTAGCATGGTATTAGAACGAACTACAAGAATATTTCCTAAGTTATTCTCAACTATATAGTCTAGCATTATCATAGTTAGTGCAAGCATACTTAGCAATCATTGTGAGACAAGACTACGCCCATGCATAGTGATATTAGCAAGGTAAATGAGAAACATAGCAATCTCTACCCTGTAATAATGTTGCTCTGCCAGCCCACGATCTGGCATATTGGGTACAATACATGAGAGGGAGACTATATAAGAATCAATGAAGCTGTCACTATCACGAACTACCCCACGATCTGGCATATTGGGTACAATCGCAGATAAATACGGTATAAGCACCACGCCTACACAATATCTATCATTTACCCATGGATCCGATGGATAAACACTATACGATCCTAAACATGTATATAGATCCAATCTAACTAAGCCAAGTATATAACTATGATAAACTAAGAACAATATAATCTTGAATATAAGCAAGTAGAGCAAAGTCATAAGCAATATATTGAAATAGGACAAAGTCATATTCATAATATTGAAGAACAAAGATAATTAGAAGAACAATTAGAAGCACAATTAGAGAATTACCAAGAATCCTCTTGACAGATCCGGAAACCAATCGAAGATTGACTCCTAGTTCTAATCCTATGTAGCTATGCTAATCTAGATGTCTAATTGATGTGGTGGCTCTAATCTTGATCAGAGGCTTCTTCTCCCTTGAAGAACAATGAATTAGGGTTGAGAGGCTCTCTCCTCCCGGGGCCAGGGGGTCTGGTTTTATAGTCCCTTCAAGTGAATATGGGCCGTTGGATCAAACCGACATTGATTGAACGGTTATCCTTGATCCTTTAGGTCGGTGGAGATCTCCCCCAAAACAGAGTCTTGATTGGACTCCAACAGAGGGCGGGCGCCCTGGTTACCTGGGCGGGCACCCAGGTCCTGGCCCCGTTCGGCCTTCGCTTCCTTCCCGTGGCTTCTAGAGTCTTCTAGATGTAAGATAATTGCTCGGCACGTTGATATCTCTATGTAATCCCGACGTGTGGGACTTTCTTTCGTATTTCCTGATAACCCCCTGCAGAAATAGACAAACACCAAAACTCGTGGAATTCTGTCCGATAAAACCCTAAGTCTAGATGTCGATTTCATTTGGATCCTTTTCTTTGTTTATTTGATAATTAAATTTGATACTTAAGGACCGTCAACACAAGCTTAGAGTCTTAAAATAAGCACTGATCAGATTGTAACATGAGCTTTTAATTATTTGCAATATTACCTGGTGTATTGTGCATATAAGGATAATTGTAAAAATATTCCTTCGGGTATTCTTGTCACTAACCTTTCCAGGATTGGAGCAAGAAGATCAGATGAATGACAAGCACAAGGTATGTCCAACCAATCATCATGCAACACTGAATTAAATTCATCCAAACTTGAAATTTTGCAAAATTCAAGTTTGGGGCAGTACCTTACATAAAAAAAACATCCTTTGTCATGTTGCTATGTTGGTTGTCCCTACCTTTGAGACATGCTCAATTTGTTAAACGCTAATCATTCTATTTTCATCTCCACTTGAGTAAGATCTCTATAATGCTGTTATGCTACCTTTATCTATTCGCAAGTAAGTGTTGGTTTGAAAGTACTCGACATACTTCCATTCGCATTTAAATTAAGCGTGGTGCTTAGGTTAAATAGCCTTCCTTAATCTGATTAGACATGGAGTCTAGTTTGGTTACTGAACTAAAAACTGCCTGAGTAGACATTGGTATATTTTGTTGGACTAACCCCTGCAGGAAAACTGTCAATATCAACCTAGGAAGTCCTTAGATAAACTCACACTGGAGACAAAGAGAGAGACACATCAAGTTTAACAATTTACACAAGGAGGACGTAGCTCATAAGAGATGATCCCTGGAGGGTGCCACAAACACGATGCACAACCGCTAATAAAGGAAAGCTTCCACAAGGTGATACTATACCATCACTCTTCAAGTAAGGTAACATCTTAAAGTACTTGATTATCACTTTTATAAGCTTTTCCTTGGTTCTAGCTTTCACATAAATAAAGAGACAAACAGGTATGATTTATAACTCCAAATTAACCAACCCAACTGATTCAACTTGTTTAGTCCTTTAATCTTTGTTCCTAGTACTACCTCCAAGATCCCACACTCCTAATCATATGAGCTAAAATATTACACATTCAATCTTTGAGAGATATAAAGAAAAAGACATATACATAGATAGATTATCTTTCTATAAGGTTGAAGGGATCTGATCTGACAAATGTTATAAGTGCTACACTCATGAACTTATCATCCATCAACTTTGTCTTGCTCACTATGCTTAAGGTTAGAGAAGAACAAATACACTTTTGGTTTTGTTAGTGTTTTCCACCAACAGGGCCCATGCACTTGATCTCTGCCTTGTCTCTATGAGCAGGTACACTTCAAGCAAAACATGGAGGTGTTTTATAACTCTCAGACTCTACCAAGTGAAGGACCAGGATCTATGAGCATAAACACACTGAATAGGATACTGCCAACGCCGCACTTCGAACTACTGGGCAAATGAAGAACATGGGTGACACCGTATCAAGAGGTGCAGACGCCAAGGTCCTCACCTGAATCAAATGACGCACCTAAAGAATGAACACGGTGAGAAGTCTTGTCTAGAAGACTTAAAACATTGGATCCTTACCGGAAGATAAAATCGGTATTTATCCATATTTATCTTTTCTGCATTCCTTTTCCTTTTTATTCCATCACTTGCATTAGCATATTTACCTTTCCACATTAGCATTAGAAAAGAAAACAAAAAAAATTTTGTTCATTGCACTGCATCATAAAATCTAAAGCATAGATTTGTGGTTTAAAACCCATAGGTATATTGACTGCGGTGGCATAAAATAAATATATTTTCATCTTACAATACAAATATAAAAATAATAAGTGCACGATCCTGCTAAATAAATAAAATTTATTAGGAGGAATCTCAATATGATAAAGGCTAAGAGATATTATGCTAACACTTAACCAGTTCCACAAAGCTTTGTTGTCTATTTGAGCTCCACAGAATTTAAGGATCAAAGAAGACTAGCAGATGGAGGACATCCTAATTGCTGTCAGGGTACTGCCGACATTCAAATACACCTCCGCCACCTGCTAGCTACATCAAAAGAAATTACGTCAAAATCCAGCTTAGGGGAGAGCACCCCCATTTATCCAGCTAAGTGTTTCTACTCGTGTTTATACTTTACTCAAATAATAAAAAGATGCAAAATCATAAAAATCCAAATAAAGATTTTTGTGCTTATATATATATCTTTGCTTAGTTTGCTAAATAAATAAATAAAGTTTGCTATGAACCCTCATGATAAGCTATCACATGGAAATGATGAATAGTTGCTCTGCCATGACTAGTTCTCAAAATTGAAATCTCTCTCAAGTTTAGGCATGACTGTTATGAATTAAGATTTGCTCTAAACCTGAACTTGTGGGAAGAGTACTTGATCTAAAGACTAAGTCGTTAACGGATATAATATGGGAAGGTTGAGCTGTTGTTTATCTGTTCTTAGAAATGCTAGAATTCTCGAGAATTTTATCTTTGAAAATCTTTAAAATGTTGCATGATGAGTTCCTGTATGATGAGAGTTTAAAATCCTACCACAGCCACATGTACATGATTATTAGACTATGAACCATACATTTACTTTTTACTGCTTATGAGCATTGAGTGTGGTCAAGCTGTGTAGACCCTTAGTAGCTTGTCATGCGGTTAAAATCAAGATTCACTTGCACGTTCACTCATACATGTTGCTTCTACTCCGGAAGTACGCATCCACATACATCCACTCATTTCCATCTCCAGATGCACCCAAAGTTATTCTACTCCTATCTAGGATAGAATAGCCAAAAACATTATCCTATCCCTATTATTCCCCGTGAAATAAATGCTCGAGATATTTTGGTTACTACCACTTGCTACATTATTCTAAGAGGGTGAGTGCTCTGAAAAAAAAGAAGAAAAATACGAGAAAATAAAAAGGGGCAAGTGCCCGGAACCTCGAAGAAAAGAAAAAGTGAGACAAGAGGTAAAAATGGACAAGTGTCCGACAGTAGAATTAGGGGTACAAGATACCCACCTGAGAGGAAACAAAAAAATAATATAGAGCATCTCATTCTTCTCAAAAATCTTCAAAGTGCAAGAAAGGTATGTATCCCCTCAAAAGAGCAAAAGTAGAATTAGACTTCCACCATTGTTACCACCATACACCATTCATTCGCCACACATGCACATCTTGATTTGACTTATTGACTTGTTTCTCTGGATCCATGGTTTGACTATGCAATAAATGTCTTGTAAGTATGTATTAGCTGTCTCCCACCTATGAGCTCCAGATATCAAAACCTTGTTAGAGTAGGGTGAGAGAGAAGGCAATATCATTATGCCTCATACCACAAATACCACATACTTTGAGAGAAGGCATATATCATCACTGCCTTGGTAAGGATCC
->URS000176A646 rRNA from 1 species 
-TACAGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGGGCTCGTAGGCGGCCAACTAAGTCAGACGTGAAATCCCTCGGCTTAACCGGGGAACTGCATCTGATACTGGATGGCTTGAGTTCGGGAGAGGGATGTGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAACACCGGTGGCGAAGGCGGCATCCTGGACCGACACTGACGCTGAGGAGCGAAAGCCAGGGGAGCAAACAGG
->URS0001DA5C55 misc_RNA from 1 species 
-GATGAAGAACGCAGCGAAGTGCGATAAGTAATGTGAATTGCAGAATTCCGTGAATCATCGAATCTTTGAACGCAAATTGCACTTTCTGGTATTCCGGAGAGTATGCCTGTTTGAGGGTCAGTGTAATAAAAATAAATCGTGGTTGTTTGCCACCTTTTCGTGGTGACGCTTCGGAATTGAGTCGTCTTTACCCCTTCGGGTTAAGTGACTTAAAATTTTTTCATACGATTTCGAAACGTATTTAATGTATTATTTACGTTCACGAATATCGAATTTTTATTAGGTGCGGTCATTTTTCATGAATTCGCGTCTATAATTTTTTTTTTTTTTTGACCTCAAATCAGGTAAGAATACCCGCTGAACTTAAGCATATCAATAAGCGGAGGA
->URS00001B9A8C rRNA from 1 species 
-CACTGTCACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGAGTGATGAAGGCCCTAGGGTTGTAAAGCTCTTTCAGCGAGGAGGATAATGACGTTACTCGCAGAAGAAGCCCCGGCTAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGGGGCTAGCGTTGTTCGGAATCACTGGGCGTAAAGCGCACGTAGGCGGACTTTTAAGTCAGGGGTGAAATCCCGGGGCTCAACCCCGGAACTGCCTTTGATACTGGAAGTCTTGAGTCCGAGAGAGGTGAGTGGAACTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAAGGCGGCTCACTGGCTCGGTACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAG
->URS0001494730 rRNA from 1 species 
-GTGGGGAATATTGGACAATGGGGGGAACCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGCCTTTTGGTTGTAAAGCACTTTAAGCGAGGAGGAGGCTACCGAGATTAATACTCTTGGATAGTGGACGTTACTCGCAGAATAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAATACAGAGGGTGCAAGCGTTAATCGGATTTACTGGGCGTAAAGCGCGCGTAGGTGGCCAATTAAGTCAAATGTGAAATCCCCGAGCTTAACTTGGGAAGTGCATTCGATACTGGTTGGCTAGAGTATGGGAGAGGATGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGATGGCGAAGGCAGCCATCTGGCCTAATACTGACACTGAGGTGCGAAAGCATGGGGAGCAAACAGGATTAGAAACCCTGGTAGTCC
->URS0000295BDA rRNA from 1 species 
-CCCTAGTAACTGCGAGTGAAGCGGGAAAAGCTCAAATTTAAAATCTGGCGGTCTTTGGCTGTCCGAGTTGTAATCTAGAGAAGTGTTATCCGCGCTGGACCGTGTACAAGTCTCCTGGAATGGAGCGTCATAGAGGGTGAGAATCCCGTCTTTGACACGGACTGCCAGGGCTTTGTGATGCGCTCTCAAAGAGTCGAGTTGTTTGGGAATGCAGCTCAAAATGGGTGGTAAATTCCATCTAAAGCTAAATATTGGCGAGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGATGAAAAGAACTTTGGAAAGAGAGTTAAACAGTACGTGAAATTGCTGAAAGGGAAACGCTTGAAGTCAGTCGCGTTGGCCGGGGATCAACCTTGCTTTTGCTGGGCGTACTTCCCGGTTAATGGGTCAGCATCAATTTTGACCGTTGGATAAAGGTCAGGGGAATGTGGCATCTTCGGATGTGTTATAGCCCTTGGTCGCATACAACGGTTGGGATTGAGGAACTCAGCACGCCGCAAGGCCGGGTATTTATACTACGTTCGTGCTTAGGATGCTGGCATAATGGCTTTAATCGACCCGTCTTGAAACACGGACCAAGGAGTCTAACATGCCTGCGAGTGTTTGGGTGGAAAACCCGAGCGCGTAATGAAAGTGAAAGTTGAGATCCCTGTCGTGGGGAGCATCGACGCCCGGACCAGACCTTCTGTGACGGATCCGCGGTAGAGCATKTATGTTGGGACCC
->URS0000468D61 rRNA from 1 species 
-GACTAACAATGGTTAGTTGAGTGGCTAAGCGAAAGTGATAAGTGACCCACCTGGGGAGTACGCTCGCAAGAGTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCAGGGCTTAAATGTAAGTTGCATGGACCAGAGATGGACCTTTCTTCGGACTACTTACAAGGTGCTGCATGGTTGTCGTCAGCTCGTGCCGTGAGGTGTCAGGTTAAGTCCTATAACGAGCGCAACCCCTGTTGTTAGTTGCCAGCAAGTAAAGTTGGGTACTCTAGCGAGACTGCCGGTGCAAACCGTGAGGAAGGTGGGGACGACGTCAAATCATCACGGCCCTTACGTCCTGGGCTACACACGTGCTACAATGGTCGGTACAGAGAGCAGCCACTACGCGAGTAGGAGCGAATCTTCAAAGCCGATCTCAGTTCGGATCGCAGTCTGCAACTCGACTGCGTGAAGCTGGAATCGCTAGTAATCGCATATCAGCCATGATGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCAAGCCATGGAAGCTGGGGGTACCTGAAGTCGGTGACCGTAAGGAGCTGCCTAGGGTAAAACTAGTAACTGGGGCTAAGTCGTAACAAGGTAACCGTAA
->URS0001AC9055 rRNA from 1 species 
-TGAGAGAAAGGGGGCCTCTGCTTGCAAGCTCTCGCTATGAGATGAGCCCGCGTCCGATTAGCTAGTTGGTAGGGTAAAGGCCTACCAAGGCGACGATCGGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGCCTGCGGGTTGTAAAGCACTTTCAATTGGGAAGAAAAGCCTGAGGTTAATAGCCTCGGGTCTTGACGTTACCTTTAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATCACTGGGCGTAAAGCGCGCGTAGGCGGCTTGATAAGTCAGATGTGAAAGCCCCGGCTTAACCTGGGAATTGCATTTGATACTGTCTGGCTCGAGTATGGTAGAGGGGGGTGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAACACCAGTGGCGAAGGCGACCCCCTGGACCAATACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGACTAGCCGTTGGGCTCATTTAAGGGTTTAGTGGCGCAGCTAACGCGATAAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCAGCCCTTGACATCCAGTGAACTTTCCAGAGATGGATTGGTGCCTTCGGGAGCACTGTGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCTTGTCCTTAGTTGCCAGCACATAATGGTGGGAACTCTAAGGAGACTGCCGGTGATAAACCGGAGGGAGGTGGGGATGACGTCAAGTCATCATGGCCCTTATGGGCTGGGCTACACACGTGCTACAATGGCCGGTACAAAGGGTTGCGAAGCAGCGATGTGGAGCTAATCCCGGAAAACCGGTCGTAGTCCGGATTGCAGTCTGCAACTCGACTGCATGAAGTCGGAATCGCTAGTAATCGCGAATCAGAATGTCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTTGGTTGCACCAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTTACCACGGTGTGGTCAATGACTGGGGTGAAGTCGAAACAAGGTA
->URS000014146A rRNA from 1 species 
-GATGAACGCTAGCGGCAGGCTTAATACATGCAAGTCGAGGGGCAGCGGGGTAGCAATACCGCCGGCGACCGGCAAACGGGTGCGGAACACGTACAGAACCTTCCTTTAAGCGGGGGAGTAGCCCACTAGAAATGTGGATTAATACCCACTAGTAATGTTTAATGGCATCATTAGATATTTAAAGTATTTATCACTTAAAGATGGCTGTGCGGCTGATTAGGTAGTTGGTGCGGGTAACGGCCCACCAA
->URS0002127D47 rRNA from 1 species 
-TAATTTATTGGGGGTAGAGCACTGAATGTGCTAGGGGGCCTACAAGCTTACCAACCCCAATTAAACTCCGAATACCGATTACATGATGTACAGCAGTGAGGCTATGGGTGATAAGGTTCATAGCCAAGAGGGAAACAACCCAGATCATCAGCTAAGGTCCCAAAATTGATACTAAGTGATAAAGGATGTGGAATCGCCCAGACAGCTAGGAGGTTGGCTTAGAAGCAGCCATCCTTTAAAGAAAGCGTAACAGCTCACTAGTCAAGGGGTTCTGCGCCGATAATTTCCGGGACTAAGTATCATACCGAAGCTATGGGATTCATTCGATTCGAATGAATCGGTAGACGAGCGTTCTATTAACTTGTGAAGGTTGACCCGTGAGGGCAGCTGGAGGAGATAGAAATGAGTATGCTGGAATGAGTAGCGATAAAGCCTGTGAAATGCAGGCTCGCCGTAAGCGTAAGGTTTCCTGAGTAAAGTTAATCTGCTCAGGGTTAGTCGGACCCTAAGCCGAGGCCGAAAGGCGTAGGCGATGGAAAACAGGTTTAATATTCCTGTACCAGTTTAATATTGTTTGAACTATGGGGGGACGCAGAAGTGAAAGGAGATCCCGGTTTTGATTGTCCGGGTTTAAGAGTGTAGGGAGTTCTGATAGGTAAATCCGTTGGAATAATCCTGAGACTCGAATAGGAGGGCTTAGCCCACAAACTCTCCCTAATCCTGCTGCCAAGAAAATCCTCTATGTTAGATATTTGACTGACCGTACCGTAAACGGACACACGTACGCGAGGAGAGTATCCTAAGGCGCTTGAGAGAATCCAAGTAAAGGAACTAGGCAAATTAGCCCCGTAACTTCGGGAGAAGGGGTGCCAATTAAGGAAAAGAACTTCGCGTTCTGCTTTTTATTTGGCCGCAGTGACCAGGCCCAAGCGACTGTTTACTAAAAACACAGGTCTCTGCTAAGTCGTAAGACGAAATATAGGGACTGACACCTGCCCGGTGCTGGAAGGTTAAATGGAGAGGTTAGCTTCGGCGAAGCTTTGAAACGAAGCCCCAGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCTGCACGAATGGTGTAACGATTTGGGCACTGTCTCTACTTGGAGCTCAGCGAAATTGAAGTGTCGGTGAAGATGCCGGCTACCCGCGGCCGGACGAAAAGACCCCGTGCACCTTTACTACAACTTATCATTGAATACTGATTCTGCTTGTGCAGGATAGGTGGGAGACTTTGAAGCAGTAGCGCTAGTTATTGTGGAGTCATCCTTGAAATACCACCCTTGTATTGTTAGTATTCTAATCCCATCCCGTGAATCCGGGTGAGAAACAGTGGTAGGTGGGTAGTTTGACTGGGGCGGTCTCCTCCCAAAAAGTAACGGAGGAACCCAAAGGTTCCCTCAGCATGGTCGGTAATCATGCGAAGAGCGCAAAGGCATAAGGGAGCTTAACTGTGAGGTCGACGGACCGAGCAGGTACGAAAGTAGGGCTTAGTGATCTGGTGGTTCCGTATGGAAGGGCCATCACTCAATGGATAAAAGGTACGCCGGGGATAACAGGCTTATCTCCCCCAAGAGTTCATATCGACGGGGAGGTTTGGCACCTCGATGTCGGCTCATCACATCCTGGGGCTGGAGAAGGTCCCAAGGGTTGGGCTGTTCGCCCATTAAAGTGGTACGTGAGCTGG
->URS0000ADD2ED rRNA from 1 species 
-AAGCCACGGCTAACTACGTGCCAGCAGCCGCGGCAATACGTAGGTGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGCGCGCGTAGGCGGTTTTTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGAAAACTGGAGTGCAGAAGAGGAAAGTGGAATTCCATGTGTAGCGGTGAAATGCGCAGAGATATGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGTCTGTAACTGACGCTGATGTGCGAAAGCGTGGGGATCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAAATCTTGACATCCTTTGACAACTCTAGAGATAGAGCTTTCCCCTTCGGGGGACAAAGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTAAGCTTAGTTGCCATCATTAAGTTGGGCACTCTAAGTTGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGATTTGGGCTACACACGTGCTACAATGGACAATACAAAGGGCAGCGAAACCGTGAGGTCAAGCAAATCCCATAAAGTTGTTCTCAGTTCGGATTGTAGTCTGCAACTCGACTACATGAAGCTGGAATCGCTAGTAATCGTAGATCAGCATGCTACGGTGAATACGTTCCCGGGTCTTGTACACACCGCCCGTCACACCACGAGAGTTTGTAACACCCGAAGCCGGTGGAGTAACCTTTTAGGAGCTAGCCGTCGAAGGTGGGACAAATGATTGGGGTGAAGTCGTAACAAGGTAGCCGTATCGGAAGGTGCGGCTGGATCACCTCCTTTCTAAGGA
->URS0000EBB953 lncRNA from 1 species 
-GGAAGAGAAGGAGGAGGAGGAGGAGGAGGAGAAAGTGGCTCTCAGCGGCCGGTCGGATTAAAAGTAACCAGACTCGTCCAGAAAACTGCGTCCAGGAAGGAAGTGACAGAAGACGAATGGGAAAAGGAGAACAGCTCACAGCGTTTGAAACATCGCGGCACCACTTTCAGATAAAAACATAGACCTGAATGGCATCATCCAGTATCCAAGGAAACCATGTTCTCTAAACATGAATATGCCTTTGGGGGAAGACAGAAGAACATGGAAGCCATGTGAAAAAAACGGATCCTAAGGCAGTTTTGAACATCTGGAGGCCTGATTTATTGGAGATTGCAAATGTACAGTGTAACATAGCTGTGGAGAGCGAGAAGATCAGGATTGTCAATGCTGTCATTGCTTTTACTGGAATCCCCAGCACGAATTGAAGGTCTCACTTTGCCACCTAGGCTGGATGCAATGCAACGGTATGTTGATCTTGGTTCACTGCAGCCTCAACCTCCTGAGCTCATGTGATCCTCCCACCTCAGTCCCCCACGTCGCTTGGATTACAGGCCTGTGCCACCACACCTGGCTAACTTTTTTTGTAATTTTTGTAGAGACAGGGTCTCACTATGTTTCCCATGCTGGTCTTTAATGCCTGAGCTCAAGCCATCCGCCTGCCTCGGCCTCCCAAATTGCTGGGATTACAGGCATGAGCCACCATGCCCAGCCTAATTCTTCTAAATCTTATCCTAGTAATTAAGCCAGAATTTTTCTCTGCCAAGACCAATAGATGGACCAAGAAGTACTCATCCTTGTAAACTTTCTTTGGATAAATTGCTTACATATAATAAATTCAGAGTTAAGTAATAAAAATAATGAACTACTGTCTTG
->URS000194FCEC lncRNA from 13 species 
-ATCTCCAGACCCAGTCAGACTTTCAGACACTGAAGTTTTGGCTGACATTTTGACTACATCTTCGTGAGAGTGCCCAAGGCAGAACCACCCAGCCAAGCCACTCTGACTCCTGATCCATAGAGACAGTGTGCGACAGCACAGGATTATTGTTGTGCGAAGTCATGAGTATTTGAGGCAATTGTTATGTAGCTTTAGCTAATAGAGACCTATTCTGCGGCTTAGGAGGAAGTGAGAATAGAGCCAGTTTGGGGGCTCCAGGAACCTACAGTCTCCAGGTGACCAAGCAGACACTGACGAAATATGAAGGCGCTGGGGCTGGAGAGAGACGACGTCTACTGGGCCTGATAATGGACTCAAAACTACAGAAGTAAACACAGGAAGGAAAAAAGTACCGAGAGAGAGGGGTGAGCTGCTGACAGAGGCTTAGGGACCATTTGGAATCGCGCAGACCTGGATTCAAATCCTCACTCCATCACTTTAGTCTTGGGAACTCAAGCAAATTACTTAAACTCCTTATAGAGTCCCAGATTCCTGTAACAGCAGCATGGATCCTTGCTGCAATGAGGATTAAGCAGAATATGTCACTGAAAATGAAATGAAATGAGAAGCCCCTAACCCAGCCCCCTAGCTCATGG
->URS00011AB3B6 rRNA from 1 species 
-TGGCTCAGATTGAACGCTGGCGGTATGCTTAACACATGCAAGTCGAACGGTAGATACTTCGGTATCGAGAGCGGCGGACGGGTGAGTAACGCGTAGGAATCTGCCCAGTAGTGGGGGACAACCAGAGGAAACTCGGGCTAATACCGCATACGCCCTAAGGGGGAAAGCGAGGGATCTTCGGACCTCGTGCTATCAGATGAGCCTGCGTCGGATTAGCTAGTTGGTAGGGTAAAGGCCTACCAAGGCAACGATCCGTAGCTGGTTTGAGAGCGCGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCAATACCGCGTGTGTGAAGAAGGCCTTAGGGTTGTAAAGCACTTTCAGCAGTGAGGAAAAACTTAAGATTAATAACCTTAGGCTTGACGTTAACTGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGGGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCGCGTAGGTGGTTTGGTCAGTCGGATGTGAAAGCCCTGGGCTCAACCTGGGAACTGCATTCGATACTGCCTGACTAGAGTGTGGTAGAGGAGAGTGGAATTTCAGGTGTAGCGGTGAAATGCGTAGATATCTGAAGGAACACCAGTGGCGAAGGCGGCTCTCTGGACCAACACTGACGCTGAGGTGCGAAAGCGTGGGTAGCAAACGGGATTAGATACCCCGGTAGTCCACGCCGTAAACGATGTCTACTAGCCGTTGGGTTCCTTGAGGACTTAGTGGCGCAGCTAACGCATTAAGTAGACCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATATGGTTTAATTCGATGCAACGCGAAGAACCTTACCTACCCTTGACATACAGAGAACTTTCTAGAGATAGATTGGTGCCTTCGGGAACTCTGATACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCTTATCCTTAGTTGCTACCATTAAGAGTTGGCCACTTTAAGGAGACTGCCGGTGATAAACCGGAGGAAGGTGGGGACGACGTCAAGTCATCATGGCCCTTACGGGTTGGGCTACACACGTGCTACAATGGCTGGTACAGAGGGCTGCTAACTTGCGAGAGTACGCTAATCCCTTAAAGCCAGTCCTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGCTGGAATCGCTAGTAATCGCGGATCAGAATGCCGCGGTGAATTCGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTGGGTAGGCTAACCTTCGGGAGGCCGCTCACCACTTTGTGATTCATGACTGGGGTGAAGTCGTAACAAGGTAGCCCTA
->URS00016A699B rRNA from 1 species 
-TGGGGAATTTTGGACAATGGGGGGAACCCTGATCCAGCCATCCCGCGTGTGCGATGAAGGCCTTCGGGTTGTAAAGCACTTTTGGCAGGAAAGAAACGTCGCGGGTTAATACCCCGCGAAACTGACGGTACCTGCAGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTCGGAAAGAAAGATGTGAAATCCCAGAGCTTAACTTTGGAACTGCATTTTTAACTACCGGGCTAGAGTGTGTCAGAGGGAGGTGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAACACCGATGGCGAAGGCAGCCTCCTGGGATAACACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGTCAACTAGCTGTTGGGGCCTTCGGGCCTTGGTAGCGCAGCTAACGCGTGAAGTTGACCGCCTGGGGAGTACGGTCGCAAGATTAAAACTC
->URS0000BC3C0C rRNA from 1 species 
-TTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGGCAATGGGCGCAAGCCTGACCCAGCAACGCCGCGTGAAGGAAGAAGGCTTTCGGGTTGTAAACTTCTTTTGACAGGGAAGAGCAGAAGACGGTACCTGTCGAATAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGATTTACTGGGTGTAAAGGGCGCGTAGGCGGGATGGCAAGTCAGATGTGAAATCCAAGGGCTCAACCCTTGAACTGCATTTGAAACTGTCGTTCTTGAGTACTGGAGAGGTTGACGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGTCAACTGGACAGCAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGCC
->URS0002274C91 rRNA from 1 species 
-AATGCCGGATGCTCCGACTCCTCGCATGGGGTGTCGGGAAAGATTTCATCGGTATGGGATGGGGTCGCGTCCTATCAGGTAGTCGGCGGGGTAACGGCCCACCGAGCCTACGACGGGTAGCCGGCCTGAGAGGGCGACCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCGACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTTGATCGGGAGCAAGCCTTCGGGTGAGTGTACCTTTCGAATAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTATCCGGAATTATTGGGCGTAAAGGGCTCGTAGGCGGTTCGTCGCGTCCGGTGTGAAAGTCCATCGCTTAACGGTGGATCTGCGCCGGGTACGGGCGGGCTGGAGTGCGGTAGGGGAGACTGGAATTCCCGGTGTAACGGTGGAATGTGTAGATATCG
->URS0001B5E2EE rRNA from 1 species 
-GGGATAACTACTGGAAACGGTAGCTAATACCGCATAACGTCGCAAGACCAAAGAGGGGGACCCTCGGGCCTCTTGCCATCGGATGTGCCCAGATGGGATTAGCTTGTTGGTGGGGTAACGGCTCACCAAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGTACTTTCAGCGGGGAGGAAGGGAGTAAAGTTAATACCTTTGCTCATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCTGATACTGGCAAGCTTGAGTCTCGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACGAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGACTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCACGGAAGTTTTCAGAGATGAGAATGTGCCTTCGGGAACCGTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTCCGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGACCAGGGCTACACACGTGCTACAATGGCGCATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCATAAAGTGCGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTGGATCAGAATGCCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTTACCACTTTGTGATTCATGACTGGGGTGAAGTCGTAACAAGGTAACCGTAGGGGAACCTGCGGTTG
->URS00005D6907 rRNA from 1 species 
-TGCCCGAACGTAACACGACACCACCGTCCGCCAAATAACTACGAGTACAAACTTAAAATTTAAAGGACTTGACGGTATTTCACACTCAACCTAGAGGAGCCTGTCTACTAACCGATAACCCACGATTAACCCAACCGCTTCTAGCCCCCAGCCTATATACCACCGTCGCCAGCCTACCTTATAAAAGAAACAAAGTGAGCTAAACAGTAATACACTAAAACGACAGGTCAAGGTGTAGCTAATGAATCGGATTAGGATGGGCTACATTTTCTAACCCAGACTATACGAACCAGGCCATGAAACAAGCCTTCGAAGGCGGATTTAGTAGTAAGCCGAGAACATAATACTCAACTGAAACCAATGCAATGAAATGCGT
->URS0000822125 rRNA from 1 species 
-ACATGCAAGTCGAGGGGCATCGGGATGTAGCAATACATTGCCGGCGACCGGCGCACGGGTGAGTAACACGTATCCAACCTGCCTTTTACTCGGGGATAGGCTTTCGAAAGAAAGATTAATACCCGATGGCATAATCTTCCGCATGGTAGAATTATTAAAGAATTTCGGTCATCAATGGGGATGCGTTCCATTAGGTTGTTGGCGGGGTAACGGCCCACCAAGCCTTCGATGGATAGGGGTTCTGAGAGGAAGGTCCCCACATTGGAACTGAGACACGGTCCAAACTCC
->URS0001663DCE rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAACGCAGTGGGGACGGGTGCGTAACACGTGGGTAACCTCCCATCAGAGGGGATAACCCTTGGAAACAGGTGCTAAACCGATACTGATGGATGGACCCGCGGGGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCCACGATGCCTAGCGGGCCTGAGAGGGTGATCTGCCACACTGGGACTGAGACACGGGCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGACGAAAGTCTGACCGAGCAACGCCGCGTGTGTGAAGAAGGTTTTCGGATCGTAAAACTCTGTTATTAGAGAAGCGTTATCTAACCAGGAAGCCACGGCTAACTCCGTGCCAGCAGCCGCGGTAATTC
->URS00009B24CA lncRNA from 1 species 
-GGCCAGAAGAGCAGTTCTCCAGGCCCAGAAGTAAGCTACACCCACAATTCTGTATGCAGCTGTGAGAAAGGAGAGTGGAAATCCAAGTCAATGCAGTATCACCGTGTTCCCAATCACGAGTATTCCACTGGGCCCACTGGCTGCCAAGACATGGATGGGATCCAGTGGTGAGCCTGCCCCAGCACATGAAACACATGCTTGGGAAACAGTGCCTGACTGGATGGAGCCCTCTGGTACCCTCAAAGAGAAGCAACTCGCCTCATGACGGCAAGAACTGTAAAACAAAGCTAGGATTTTACCCCTACTGGGCCATCCACGCTTTTAGAACCACAGATTCTCAGGGAATGCAGCATTAACCTACATACAGCTAGAAAATTGACAGTAGCATATCTCAACCCAATTACCTTGAATCACAACTCTGGTAAAAGTTTTAGCAATGGAAGAGTTAAAATGATTCACTAGATGGAAGTTTTTGATAATTTGTTGACTTTAGCCATGGATAATTAAGAGTGATGGAATCCTCGTTTCACTATCAAGGAAGCTGCAGTCAAGGTCAAACAGATGAGCGCCCTGGAATTCCATGGAAGACAGCACAAAACCAATAAAACCACTGGTGTTCAGTT
->URS000183F9F2 rRNA from 1 species 
-GACGAGGGCGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCTCGTAGGCGGCTTGTTGCGTCAGCTGTGAAAACCCGCAGCTCAACTGTGGGCTTGCAGCTGATACGGGCAGGCTAGAGGTAGGTAGGGGAGAATGGAATTCCCGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCGATACTGACGTGGAGGAGCGAAAAGCGTGGGGGAGC
->URS00021C87A3 rRNA from 1 species 
-TCGCGTCGGGAGTGAAAACACCGGGCTTAACTCGGTGCTTGCTTTCGATACGGGCAGACTAGAGGTATGCAGGGGAGAATGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGTTCTCTGGGCATTACCTGACGCTGAGGAGCGAAAGTGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACACCGTAAACGTTGGGCGCTAGGTGTGGGGCCTATTCCATGGGTTCCGTGCCGTAGCTAACGCATTAAGCGCCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGCGGAGCATGCGGATTAATTCGATGCAACGCGAAGAACCTTACCTGGGTTTGACATACACCGGAAGCCTCTAGAGATAGAGGTCTCTTTGATACTGGTGTACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTCGTTCCATGTTGCCAGCACGTAATGGTGGGGACTCATGGGAGACTGCCGGGGTCAACTCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGCCCCTTATGTCCAGGGCTTCACGCATGCTACAATGGCCGGTACAAAGGGCTGCGATCCCGTGAGGGGGAGCGAATCCCAAAAAGCCGGTCTCAGTTCGGATTGGGGTCTGCAACTCGACCCCATGAAGTCGGAGTCGCTAGTAATCGCAGATCAGCAACGCTGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACGTCACGAAAGTCGGCAACACCCGAAGCCGGTGGCCTAACCC
->URS00006073C1 rRNA from 1 species 
-AACGAACGCTGGCGGCAGGCCTCAAACATGCAAGTCTAGCGGGCGTAGCAATACGTCAGCGGCGGACGGGTGCGTAACACGTGGGAACGTACCCTTTGGTTCGGAACAACTCAGGGAAACTTGAGCTAATACCGGATGTGCCCGAAAGGGGAAAGATTTATCGCCAAAGGATCGGCCCGCGTTCGATTAGCTAGTTGGTGAGGTAATGGCTCACCAAGGCGACGATCGATAGCTGGTCTGAGAGGACGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTTGGGAATCTTGGACAATGGGGGAAACCCTGATCCAGCCATGCCGCGTGAGTGATGAAGGCCTTCGGGTTGTAAAACTCTTTCGACGGGGACGATAATRRCGG
->URS0000627A27 tRNA from 1 species 
-GCAGTCGTGGCCGAGTGGTTAAGGCGATCGACTAGATATCCATTGGGGTCTCCCCGCAAAGGTTCGAATCCTGTTGACTGCG
->URS000100738B rRNA from 1 species 
-TACAGAGACTGCAAGCGTTATTCGGATTCACTGGGCGTAAAGGGCGCGTAGGCGGCCACTGCAAGTCAGTTGTGAAATCTCCGGGCTTAACCCGGAAAGGTCAACTGATACTGCAGGGCTAGAGTGCAGAAGGGGCAACTGGAATTCTCGGTGTAGCGGTGAAATGCGTAGATATCGAGAGGAACACCTGCGGCGAAGGCGGGTTGCTGGGCTGACACTGACGCTGAGGCGCGAAAGCCAGGGGAGCGAACGGG
->URS00004CBF81 rRNA from 1 species 
-AGAGTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGGCAGCACGGTAAGAGCTTGCTCTTATGGGTGGCGAGTGGCGGACGGGTGAGGAATACATCGGAATCTACCTTTTGGTGGGGGATAACGTAGGGAAACTTACGCTAATACCGCATACGCCCTTCGGGGAAAGCCGGGGACCAGCAATGGCCTGGTGCTGATAGATGAGCCGATGTCGGATTAGCTAGTCGGTGAGGTAATGGCTCAACAACGGCGACGATCCGTAGCTGGTCTGAGAGGATGATCACGACCACACGTCGAACTGACGACACGGTCCA
->URS00017EC46A rRNA from 1 species 
-CCCTTAGATGTTCTGGGCCGCACGCGCGCTACAATGATGAATTCAACGAGTTTATAACCTTGGTTGAAAGGCCTGGGTAATCTTTTGAACTTTCGTCGTGATGGGGCTAGACCCTTGCAATTATTGGTCTCCAACGAGGAATTCCTAGTAAACGCAAGTCATCAGCTTGCATTGATTACGTCCCTGCCCTTTGTACACATTGCCCGTCGCACCTACCGATTGAATGGTCCGGTGAAATCTTCGGATTGAGACTTTGTTTTCTTCACGGAAAACGCTGTTTTAAAAAGTTGATTAAACCTTACCATTTAGAGGAAGGTGAAGTCGTAACA
->URS000026EF3C rRNA from 1 species 
-TAGGGAATCTTGCACAATGGGCGGAAGCCTGATGCAGCGACGCCGCGTGAGGGATGAAGGCCTTCGGGTCGTAAACCTCTGTCCTTGGGGACGATGATGACGGTACCCAAGGAGGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCGAGCGTTGTCCGGAATCACTGGGCGTAGAGGGTGCGTAGGCGGCCTAGCAAGTCCTGTGTGAAAGGTCTCGGCTTAACCGGGGAGGGTCATGGGAAACTGTTAGGCTTGAGTGCCGGAGAGGGCAGTGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAACACCAGTGGCGAAGGCGACTGCCTGGACGGTAACTGACGCTGAGGCACGACAGCTGGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCCAGCCGTAAACGATGAGTGCTAGGTGTTGGGGGTATCGACCCCTCCAGTGCCGTAGTTAACGCAATAAGCACTCCGCCTGGGGAGTACGGTCGCAAGACTG
->URS0001CAC1D5 rRNA from 1 species 
-AGCGAACGCTGGCGGCAGGCTTAACACATGCAAGTCGAGCGGGCCCTTCGGGGTCAGCGGCGGACGGGTGAGTAACGCGTGGGAACGTGCCTTCTGGTCTGGAATAACCCTGGGAAACTCGGGCTAATACCGGATACGCCCTTTTGGGGAAAGGTTTACTGCCGGATGATCGGCCCGCGTCTGATTAGCTAGTTGGTGGGGTAACGGCCTACCAAGGCGACGCTCAGTAGCTGGTCTGAGAGGAGGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGTAGAAGTGGGGAATATTGGACAAGGGGCGCAAGCCTGAGCAAGCCAGGCCGCGGGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCGTTTATCCGGGACGATAATGACGGTACCGGAGGAATAAGCCCCGGCTAACTTCGTG
->URS0000D28D64 lncRNA from 1 species 
-AAGAAGTCCTACCACTGAAAGGATGTGCGGGTAGAAATGAGCAATTGCAACTAGAAGAGCCTGTGTGCCCACAATCAGGGGTGAGGAGGAGTGTCATGGAGCAGCTCTCTACTGCCCTGAGAATGACATCCCCACTGTTCACCATGGCCTTAAATCCCCTGCGAATTCCACCTCATCCTCTGCCACTTCCCGTCACTGCTCTGAAGATGCCCTGATCTTGTTTCAGTCCCTTGGATGTACCCAGCTCTTCTCCATCTTTGCATGTGTCATAGCCTCTTCCTGGAAAACCCTTCCTGCTGCTCATCCCAGAACTGACTCTCCATGTATTTACTCTTATTTTGAGAGAAGGGGGCATTTCCACCACCAGAAGGGAACTTGCTATCTTGGTAGCGTTGTCCCCTGACACCTGGCACATCTACTCTATACAGTCACCATTCAAGTGGATGTTGAATGAGTACACTTGTTTCACAGTTTGGTTGGGTAAGCCCCAAAGCTTGGTTCCCGGTAGGATCAGGCTTTATGAGTGGGCTGAGTTTCTATAAAAGTCTCCCTACCAGTTTCCAATCTTGGTGAAACTA
->URS0000DCF6EE rRNA from 1 species 
-TAGGGAATATTAGAAATGGACGAAAGTCTGATCTAGCAACACCGCGTGTGCGAAGAAGGCCTTCGGGTCGTAAAGCACTTTTTGGAAGGAATAGGAAGGAATGTACTTCCAGAATAAGTCTCGGCTAACTACGTGCCAGCAGCCGCGGTAACAAGTAGGAGGCGACCGTTATACGAATTTACTGGGCGTAAAGCGCGTGTAGGTGGTTCTGTAAGTAGGGCGTGAAAGCTCCTGGCTCAACTGGGAGAGGCCGTTCTAAACTACAGAACTAGAGGATGGTAGAGGGAGGTGGAATTCCAGGTGTAGCGGTGGAATGCGCAGATATCTGGAGGAACACCAGTGGCGAAGGCGGCCTCCTGGACCATTCCTGACACTCAGACGCGAAAGCTAGGGTAGCAAACG
->URS000241AE0D lncRNA from 1 species 
-TGGTTCAGATTTAATATAAATCCTAGTCTAGTCCCCTTGGGTTGCAAAGGAATCTCTCTTTCAGTTCCTTGAAATTTTTTGGTACAGGTGTATTGATGTTGTTGAACATACATCAATATCTTGTCAAAGTATAAGTATCTTTCTGAGTTTTGATGCAATGTCTCACCAGTGTTTTTCTCTCTTTCATCTCTCTACTTATTACACAGTAATAGACTATACTTCTTGTTTGGTGTAGAACAAAAAGCTTGATAATAGTTCGATCAAAGTATGTTTATGTCATTAGACCTTTGATTGTATATATATATGACTTGAGAGAAGATCTTCTTGATTGGAGCAGATCTTTGAGAGATAGGCAATCCAAAAGAATTGATCCTTGAAATGAACCTTAATTGATTCCTTTCAGAAATAAGTTGGAACTTTCCTATACTTGGACCCTGAAGTACGGCGTGATAGATGTTGCTTCCTCGATCAGCGTAACTTGATATCTTTTGCAAATCTTCCATATAATGCGTCTGATATGATTGCCCTTAACTTTCGTGATTAAGAATTGAGACTGGATATTGATCTTCCTTGATCCCTGTGATTTGGAACTAAGAGCAGAATTGATTCTTCAATCTTAGCCTTCCTTCTTTGGATAGCTTCTGAATCATTAGTTGGCTCTTACTTCCTTCTTTGGATAGCTTCCAGATCCTTGATTGCCTGCAATAGAAATAAGTTATTGTTTACCATTAAAACTCAGATCTAACATTAACAAGTATGAGTTGGAAATGGTTTAAAGGTCTTTTAATTATATATTAGGCTATCAACTAGGTAATTGGCTGTAGCAAGTATGATTTGATAGCTTTAAGAAATAGAAAATATCCCATTATAGTTGGTTACAACATAGTAGTTAAATAAAATTTTAATGGGAAAAGCATAAAAAGAACCCCAAACTTATTTCGGATTACCAGATACACATTTAAACTTTGCGAGTGTCTTGTGACTCCCTTATACTATTTTGAACTAGAATTATTAACTCCCTAAGGAGTCGTTTGGTATGAGGTATAAGTACAAATAGTGTTGGAATAAAAATTTAATACCACCTTAATATTTTATTTGGTTAGCAAACCTGAGATAAGTTATCTCGGGATTAAAATAAATACCGGGATAACTTATACCTTGTAGGGTGTGGAGTAATTAGTGTCGGGATAGCTTATACCTTCTTCTTAGAAATTATGTAAATATCATTTTTAATACAACATACCAAACAGTGGATAAAAAATAATCTCAGCATAACTAATCCCAGCATAACTTATCCTAGCATAACCTATATTCAAACCAAACGACCCTTAAGTGTTGAGGCGGTAAAGAAAGTGTAATCCGGGACATTTTTGATAGCGTTTTTATGCTTTTTCCAGATTTTACGTTCGCAATGTCTATATATCAAATACAATTTTGAAAACCATGCCACTTGATGGTGTACATAACTTGTTTGTTTTCGAAATGAATCTGATTTTTGCACCAAATCTGCGCGAGTTCCCTGAATTTATAGCTACGGGACCTATGAATTTTCTATTTTTCAGTTTTCTTAATTCTGAGCTAGCACTAGGCAAAGAAACTTTCATGAAAGACCCATAGAAACCAAGAGAATAGCAAAAGATACACAAGAATTGAAGAAGTATACAAAATTCAATTTGATAATGAAAAATCTGTGACATAAGTCTAGAGGTCAATATGTGACAGTTCATTCATAGTATTATGAACTCATGAGTAACTTCATGGATACTGTTAAGTGGTCCTAGCATAATTGAAATTTTGCTATTTTTTTTATCAACAGTATTAAAAGTTATATGATTTAAAAAAAAGATGTGGATTTAATTTTGTGGGCATGGGAGGTTTCCAAAATTGCAAATTAAAATTAAAGTTATTCATCATGAAAGAAAATCAGATACTCCACTAAAATGACAATTTAATTTTTATCTTATAATGATCTATCGTTTTGAGTCAATGACTAAACTATTCTATTTGCTTCCTTCGGAAATCCCATTTATTTGGAGAAGAAATCAAAAAAACAGTCAACAGATTCTTAAAGTATGAAAAAGACAATATTTAAGAATTAAATTGCCATGAGATGGCTTAAGAGTTAAGACTCGTGGGAATTCACCTCTTGCTTGGTTTTTGTCCAAAAATAAATTAAATGAATAAATCTTGTTGCGTGCAATATAATTGTGTAAGAATGACATTAGAAAATAGAGGAAAACTAAATTATAACACAAATATTTGTTGTTATAGCGAATCTACGGTATCTTACGTGTTGATTGTGTTATCATCTTCTCTGTCGTTGGTGTCTTTCACCGTTAGTTCTGGATCATCCGATAAGTCGTCGTCTTCTTCTTGGAATGAAATGGTGTTTTTTGTCGTTGTGATAGAAATATCTGTGGTTAAGGTGTTTTTGTGATGGTGGTGTGGAGTGGTGAGGTTGTGTGATAACACGGGTATGCCCCATCTATGTCCGTGTATTTCTTGT
->URS000033F791 rRNA from 1 species 
-ACCGCCCGTCCAAGCCATGGGAGCCGGGAGTGCCTGAAGTGCGTGAGCGCAAGCAGCGCCCTAAGGTAAACCGGTGACTGGGGCTAAGTCGTAACAAGGTAGC
->URS0002366112 lncRNA from 1 species 
-TTTTAAAAGGCATCCAATAATTCTTGTGGCCATATATCAATTCATGTAAGTTTGATTGTAATTATTGGTGAAGGGGTTTCACTTCCCGTCTCTAAATAAAAATACTGATTCTTTAAGGTACATGCCACTAGGGATTGCGAGATTAACGAGTCTTTGGACATTGGAAGAGCTCCTTGTGAGTGGAGGAGGAGGTGTTGATGGTAGCAAAGCATGTGGGCAGTGGGCTTGAATCTCTTAAAAACTCGGAACTCCTCCAAGCGTAAGTATACGTATACTGGGAAATGTGTTAGATGTGGATGAGGCTAAGAGATTAGAGCTTGACAAAATGAAATACCTCTTTCATTGAGACTTAAATTTGATGGGGAAGAAGAAAAAGAAGAGGGAAGGAGGAAGAATGAGGATAATCAACTTGTTCTTGAAGCCTTGCAACCACCTCTGAATTTGAAGGAATTAGAGATTTGGTCATACAGAGGCAACAT
->URS00001A8944 rRNA from 1 species 
-AGAGTTTGATCATGGCTCAGGATGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAGCGATTTACTTCGGTAAAGAGCGGCGGACGGGTGAGTAACGCGTGGGTAACCTGCCTCATACACATGGATAACATACCGAAAGGTATGCTAATACAGGATAATATAAGAGATTCACATGGATTTTTTATCAAAGCTCCGGCGGTATGAGATGGACCCGCGTCTGATTAGCTAGTTGGTAAGGTAATGGCCTACCAAGGCGACGATCAGTAGCCGACCTGAGAGGGTGATCGGCCACATTGGAACTGAGACACGGTCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCAACGCCGCGTGAGTGATGAAGGCCTTCGGGTCGTAAAACTCTGTCCCCAAGGAAGATAATGACGGTACTTGAGGAGGAAGCCCGGCTAACTACGTGCCAGCAGCAGC
->URS0000D1F0EB sRNA from 1 species 
-GGGTCGCTGCGAACCCCGGCGTTCCGCGGTGGAGGGGTGCTATACTGGGATGCAGGCGCGGCAATCATGCCCTGGGAGCTAATGTAGAGCTTTGGATAATGCTTTTGCAAGTTGTACGAGAAGGGAAGTTCTTGGGGTTTCTGACCTCCTGCAGCCTCCTCTTGCCTCGGGCTGCCCAGATCTTGGCGGCTGAGGCTGGCTTACCTTCAAGCCGTTCCTTCATGGGATTTGCTGCTCCCTTCACCAACAAGCGAAAGGCTTACTCGGAGCGTAGAATCATGGGGTACTCAATGCAGGAGATGTATGAGGTGGTGTCCAACGTCCAGGAGTATCGTGAGTTTGTGCCCTGGTGTAAGAAGTCTCTGGTGGTATCCAGCCGTAAGGGTCACTTGAAAGCCCAGCTGGAGGTTGGCTTTCCACCTGTCATGGAACGTTACACCTCTGCAGTTTCCATGGTCAAACCTCACATGGTCAAGGTGAGGCCTGTATGGGAGGGATTGACAAGATTTTTTGTTTTTAGCAGTTTCATATGAAAGTGCTATTTTGGCCTTCCTTGTTAAGGACTTTATGTCCATGTGTCAAGTATTTCCCTAATATCAGAAAAGAAGGAAAATGGCTTTCAATTCCTTTATATTGTATCCTATACTTAGTAA
->URS0000B6CEE1 rRNA from 1 species 
-TTCCTACGGGGGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCGACGCCGCGTGGGGGATGAAGGCCTTCGGGTTGTAAACTCCTTTCGCTACCGACGAAGCCCTTTGGGGTGACGGTAGGTGGAGAAGAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTGCGAGCGTTGTCCGGATTTACTGGGCGTAAAGAGCTCGTAGGTGGTTTGTCGCGTCGTCTGTGAAATTCCGGGGCTTAACTCCGGGCGTGCAGGCGATACGGGCATAACTTGAGTG
->URS000200AAC7 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTGTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATGGGGACTGAGGTACGGACCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGACGGCCTTCGGGGTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTG
->URS00019A43BA pre_miRNA from 1 species 
-AGCAGAATTATTGAGTCATATGGTAATTCTATATTTAATTTATTAAAGAACTACCAAATTGTTTTCCACAGTAGCTACACCACTTACTTTCTTACCAGCAAT
->URS00012BF748 rRNA from 1 species 
-TACGTAGGGGGCAAGCGTTGTCCGGAATCATTGGGCGTAAAGAGCGTGTAGGCGGTCCGGTAAGTCGGTTGTGAAAGTCCAGGGCTCAACCCTGGGATGCCGATCGATACTGTCGGACTAGAGTTCGGAAGAGGCGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCCGTGGCGAAGGCGGCTCTCTGGGACGGTACTGACGCTGAGACGCGAAAGCGTGGGGAGCGAACAGG
->URS0000AF9FF6 rRNA from 1 species 
-AGGATTCCCCTAGTAACTGCGAGTGAAGCGGGAAAAGCTCAAATTTAAAATCTGGTAGTCTTTTGGCTGCCCGAGTTGTAATCTAGAGAAGCATTATCCGCGCTGGCACGTGTACAAGTGTCCTGGAATGGACCATCATAGAGGGTGAGAATCCCGTCTTTGACACGGACTCCCAGGGCTTTGTGATGTGCTCTCAAAGAGTCGGGTTGTTTGGGAATGCAACTCTAAATGGGTGGTAAATTCCATCTAAAGCTAAATATTGGCGAGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGATGAAAAGAACTTTGGAAAGAGAGTTAAACAGTACGTGAAATTGCTGAAAGGGAAACGCTTGAAGTCAGTCGCGTCGGCTGGGGATCAACCTTGCTTGCTTGGCTTACTTCTCCAGCTTGACGGGTCAGCATCAGTTTTGACCAGTGGATAAAGGTTGAGGGAATGTGGCACCTAGGTGTGTTATAGCCCTTGGTCATATACATTGATTGGGACTGAGGAACTCAGCAAACTCTTGTGCTTAGGATGCTGGCATAATGGCTTTAAGCGACCCGTCTTGAAACACGGACCAAGGAGTCTAACATGCCCGCGAGTGTTTGGGTGGAAAACCCGAGCGCGTAATGAAAGTGAAAGTTGAGATCCCTGTCGCGGGGAGCATCGACGCCCGGACCAGACCTTTTGTGACGGATCCGCGGTAGAGCGTGTATGTTGGGACCCGAAAGATGGTGAACTATGCCTGA
->URS0000C86EDA RNase_P_RNA from 2 species 
-GAGAGAGGAAGGGCGGCTCACGCACCGAAAGGTGTGAGGAAAGTCCCCCCACCGTTTGGACGCGCGGGCGTCCGCAAGGGCGCAGGGCGAGAGTCCTGGCAATTGCACAGAAACGCCACCGCCCCTCATGAGGGCGATGATTCCGAAAGGATGAGGTCGTGAGGCGGCGGATGAAACGGCAAACCCCGCGGGTGCAAGTGGGGAGTATGGTGGACGTCCAACCACCACCCCGTTGTACGCTAAGCCAAATGCCGCCAGAACAGAAGGGGGCTTACTCTCCTCACTC
->URS0000DA6093 tRNA from 1 species 
-GGTGGCTCAGTGGTAGAGCGCTTGCCTCGCATGCATGAGGCCCTAGGTTCAATTCCTCAGCACCA
->URS00017E371D rRNA from 1 species 
-GACGGAGGATGCAAGCGTTATCCGGAATGATTGGGCGTAAAGCGTCCGCAGGTGGCAGTTCAAGTCTGCTGTCAAAGACCGGGGCTTAACTTCGGAAAGGCAGTGGAAACTGAACAGCTAGAGTATGGTAGGGGCAGAGGGAATTCCTGGTGTAGCGGTGAAATGCGTAGAGATCAGGAAGAACATCGGTGGCGAAGGCGGCTCACTGGTCCGGTACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGG
->URS0000BEF9DA tRNA from 1 species 
-GACCTCGTAGCTTAGTTGGGAGAGCGTGCGCGTACAAAGCGTAGGCGGCGTCCATGCGTGGGTTCGAATCCCAAGGAGGCCA
->URS000130260F rRNA from 1 species 
-CCTACGGGGGGCAGCAGTGGGGGATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGGGTGAAGAAGTATTTCGGTATGTAAAGCCCTATCAGCAGGGAAGAAAGAAGACGGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCGAGCGTTATCCGGATTCACTGGGTGTAAAGGGAGCGTAGACGGCCGTGCAAGCCAGGAGTGAAAGCCCGGGGCCCAACCCCGGGACTGCTCTTGGAACTGTGCGGCTGGAGTGCGGGAGGGGCAGGCGGAATGCCTGGTGTAGCGGGGAAATGCGTAGAGATCAGGAGGAACACCGGCGGCGAAGGCGGCCTGCTGGACCGCGACTGACGTTGAGGCTCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCCAGTAGTC
->URS00023DD7C2 lncRNA from 1 species 
-GTACCACTTGGCGAGCTCATCGTCAGCAGGGGAGACAGCGGCAGCCTTAGCTTTGGCAGGAGCTGCAGCCGCCTTCTTTTTGAAAAGGGCAACAGTTTTGAAGGTAGCAGAGGAGGATGGAGATGGAGCAGCAGGCCTTGCAACACCGCTAAACTTGACCGGACTTCCGAGCATCTCGGAGACGTATAGAGAGGTAGCTGCAGCCATTTGTAGCTAAACGGTGTCGCTGGCAAGAGGTAAAAAAAATTGAGGTCGAGTTGATGATGAGAA
->URS00023CEA75 lncRNA from 1 species 
-GCCTCCGCTTCCTTCCCGTGGCTTCTGGAGTCTTCTAGATGTAAAATAATTGCGCGTCATGTTGATATCTCTATGTAATCCCGACGTGTGGGCCTTTCTTCCGTATTTCCTGATAACCTCCTGTAGAAATAGACAAACACCAAAACTCATAGAATTCTGTCAGATAAAATCCTAAGTCTAGATGTTGATTTCATTTAGATCCTTTTCTTTGTTTATTTGATAATTAAATTTGATACTTAAGGACCGTCAACAAACTCCCCCAAGCTTACCTCTTGCTCGTCCCTGAGCAAGGATAGACTCAGCAATGGATCAGAAGTTGTTGCAATATCTTAAAAATT
->URS0001CC7192 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTAGAACGCACAGTTTATACCGTAGCTTGCTACACCATACACTGTGAGTTGCGAACGGGTGAGTAACGCGTAGGTAACCTGCCTGGTAGCGGGGGATAACTATTGGAAACGATAGCTAATACCGCATAATATTGATTATTGCATGATAATTGATTGAAAGATGCTATTGCATCACTACCAGATGGACCTGCGTTGTATTAGCTAGTAGGTGAGGTAACGGCTCACCTAGGCGACGATACATAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGACGAAAGTCTGACCGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAGCTCTGTTGTAAGAGAAGAACGGGTGTGAGAGTGGAAAGTTCACACTGTGACGGTATCTTACCAGAAAGGGACGGCTAACTACGTG
->URS0000E5BE8F tRNA from 1 species 
-GCGGCGGGCTCCAGACTATATTAAGACGGGTATGATGACCTCTGGGATGATTGGAGTCTGGAGCTTTGGGATACCCGTCGGTCGTGGGTTCAAATCCCACCGGCCCCA
->URS0000E04A9A lncRNA from 1 species 
-CGTAGAGCTGCTGGTCAGAGATGTGACTTGGTGTTGCCACACTACTGACTTCACTCTGAAAAGGCCAGTTTGGAAAAGAAGCAGCCTCGTGTCGCGGGAAGCATTTGTTCCAAATTCTGTGCTGGTCTGGGACTGCTCTCCAGGTCAGCCGGGTAGACCGCATCCGTTTTGTTGAGTCAGGGCTCTGTAAGACTTGGTCCTTAGACGTTTTTCTTTCAGTCTCTGCTGCAACAAAGGGTAAATTAATAATGAGGTGCAGACAAATCGAGCCAAAGAGCTTTCAAGGGGAGCAACGTTATGGTTTCAGTGCTTACGTTCTACTTTCGGTCTCTGATTCTTCTGGGGTGCAAAACCACAAAAACCTTCTGTAGAGGCTGGAATCGGTTTCAGATTGTTCAGACAAGATCATCATTCTTATTCCTGACTCTTACCAGAGGCAGAGCTGAAGGTTGAGATATTTAAAGCTTTTCTTGTGGCCACATAGATGCTAAACTGTCAGAGATGGGGAGAGAGAATAATCAATTCATCTCTAATGTAAACCCACAGAAAAGGGCTTTTCAGTGAAAAGTAGTAAAAGTTTTACATTGACCGATGCCTCTGTGAGCTATTTGAGGTGGAGATAAACAACTAAAAGGGGAAGATAAAGACTTAAATAGGTCAATAGAAGTATTTTCAGAATTGTATTCCATATGTGAATATAGAACACTCAGAGGGAGCAGTCAACAGAAACAGCAGTGGTGCATCATTTTAAGCAAAAGACCTAGATGCATTAGTTTAGGGCATATTTTAATATGGTTTTACTGGTGAATAAATCAGTGTGGTTTTCCCTTATAGCA
->URS0000DD8E81 rRNA from 1 species 
-CCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCGACGCCGCGTGAGTGATGAAGGCCTTCGGGTTGTAAAGCTCTGTTGAGGGAGAAGAAAAAAGCTGGGAGTAACTGCCTGGTTCTTGACGGTATCCCTTTAGAAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAAT
->URS0000815E56 rRNA from 1 species 
-TACAGAGGGTGCGAGCGTTAATCGGATTTACTGGGCGTAAAGCGTGTGTAGGCGGTTCGTTAAGTCGGATGTGAAAGCCCTGGGCTCAACCTAGGAATTGCACTCGATACTGGCGAGCTAGAGTACGGTAGAGGGCGGCGGAATTCCGGGTGTAGCGGTGAAATGCGTAGATATCCGGAGGAACACCGATGGCGAAGGCAACCGCCTGGGCCTGTACTGACGCTGAGACACGAAAGCGTGGGGAGCAAACAGG
->URS0001E053E9 rRNA from 1 species 
-AGTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGGCAGCACAGTAAGAGCTTGCTCTTACGGGTGGCGAGTGGCGGACGGGTGAGGAATACATCGGAATCTACTTTTTCGTGGGGGATAACGTAGGGAAACTTACGCTAATACCGCATACGACCTACGGGTGAAAGCAGGGGATCTTCGGACCTTGCGCGATTGAATGAGCCGATGTCGGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGGGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTGCGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATACCGCGTGGGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTGGGAAAGAAAAGCAGCAGGTTAATACCCCGCTGTTCTGACGGTACCCAAAGAATAAGCACCGGCTAACTTCGTG
->URS000084AE89 rRNA from 1 species 
-AGGAAATAGATACCCTGGTAGTCCCAGCCGTAAACGATGCTCGCTAGGTGTCAGGCATGGCGCGACCGTGTCTGGTGCCGCAGGGAAGCCGTGAAGCGAGCCACCTGGGAAGTACGGCCGCAAGGCTGAAACTTAAAGGAATTGGCGGGGGAGCACAACAACGGGTGGAGCCTGCGGTTTAATTGGACTCAACGCCGGACAACTCACCGGGGGCGACAGCAATATGTAGGCCAGGCTGAAGACCTTGCCTGAATCGCTGAGAGGAGGTGCATGGCCGTCGCCAGTTCATACTGTGAAGCATCCTGTTAAGTCAGGCAACGAGCGAGACCCGTGCCCACTGTTACCAGCATATTCTCCGGAATGATGGGTACTCTGTGGGGACCGCCGATGTTAAATCGGAGGAAGGTGCGGGCCACGGTAGGTCAGTATGCCCCGAATCTCCCGGGCTACACGCGGGCTACAATGGATGGGACAATGGTCCCTACCCTGAAAAGGGCTGGTAATCTCACAAACCCATTCGTAGTTCGGATCGAGGG
->URS0001BF7771 lncRNA from 10 species 
-agctatgaggcaaataagaactagaacttgaacatttgaaaaattctcagtatacccatattgcaagaaatgatgaagcacgctctggaaagaacactaagggtgtcatgggactaacttttgctggagagattagacttgtgactcatgagttcactcaaccatctcagtagaacctctgccctcttggactgaaagggacagagatttgacaaaatgtaagaaggcagtcagacttctggaattcctgggtaggaaatgggctgaaagggctacttgacaatgaatacatatcatttttcaagaaaagcaaagcatgattttgagagtagctcagaggccagcagggCTGTGGAAGATctgcctacacactgattttggatttctagccttcagaactctgagataatacatttctgattttatacaacctagtctgtgataacttgttatggcagcactaggaaacAATGAAACCTCTCAGCGTCTTTTGATAGTGCTTAATATCATCTCAAAAATCCCTTTTACCATGACTTCTATTACACCAAGGCTTTGAGCTTGTTACTATTACTACCTGTTTTTAATGCATTTTCCATGTTGCAACCAGAGTGTTCCTTTAATTGCTTATGTAACAGTTTATTTCCAGTGATTCTGGTTACATGGAACTCCTGCATGGCTATCTGGTTTGTTtttgtttgtttgtttgtttgtttgtttgttttgagacagagtctcactctgtcacccaggcgggagtgtggtggcacaatctcagctcactgcaacctctgcctcctgggttcaagcaattctcctgcatctgccacttgagtatccgggattaaagccctgtaccaccacacctggttaattttttggtagagacagtttcaccattatggcaaggctagtcttgaactcctgacctcagatgatccacccgcctcggcctcccaaaatgctgggattacaggtgtgagccacctcgcccggccACATggctatctttacagcaatgattcagagaccaggttcctggcatcctgttgctccaccattatatagaaccacttattgatggagagggaataataagtgagaatgggggatcacgtattggagattttaatggatgggactgacctagaagcaatgcacatctatctcttcacatttcattgattagaattcagtggcattaccacacctagataaaaaagaaaaaaaaaa
->URS0000E4C665 rRNA from 2 species 
-CTGAATAGGGCGCATAAGTAACAGGTCGTAGACCCGAAACCAGGTGATCTACCCATGTCCAGGATGAAGGTAAGGTAATACTTACTGGAGGTCCGAACCCACGCACGTTGAAAAGTGCGGGGATGAGGTGTGGGTAGCGGAGAAATTCCAATCGAACTTGGAGATAGCTGGTTCTCTCCGAAATAGCTTTAGGGCTAGCCTCGAGGTAAAGAGTCATGGAGGTAGAGCACTGTTTGGACTAGGGGCCCTTCTCGGGTTACCGAATTCAGATAAACTCCGAATGCCATGTACTTATACTCGGGAGTCAGACTGCGAGTGATAAGATCCGTAGTCGAAAGGGAAACAGCCCAGACCACCAGTTAAGGTCCCCAAATATATGTTAAGTGGAAAAGGATGTGGGGTTGCTTAGACAACCAGGATGTTGGCTTAGAAGCAGCCACCATTGAAAGAGTGCGTAATAGCTCACTGGTCGAGTGACCCCGCGCCGAAAATGTACCGGGGCTAAACATATTACCGAAACTGTGGATGAACCTCTTTAGAGGTTCGTGGTAGGAGAGCGTTCTAAGGGCGGTGAAGTCAGACCGGAAGGACTGGTGGAGCGCTTAGAAGTGAGAATGCCGGTATGAGTAGCGAAAGAAGGGTGAGAATCCCTTCCACCGAATATCTAAGGTTTCCTGAGGAAGGCTCGTCCGCTCAGGGTTAGTCGGGACCTAAGCCGAGGCCGATAGGCGTAGGCGATGGACAACAGGTAGAGATTCCTGTACCAGTGCTAATTGTTTAACCGATGGGGTGACACAGAAGGATAGGGAATCGCACGAATGGAAATGTGCGTCCAAGCAGTGAGTGTGAGAAGTAGGCAAATCCGCTTCTCGCGAAGCATGAGCTGTGATGGGGAAGGAAATTAAGTACGGAAGTTCCTGATTTCACGCTGTCAAGAAAAGCCTCTAGGAAGAGTAGTACTGCCCGTACCGCAAACCGACACAGGTAGATGAGGAGAGAATCCTAAGGTGAGCGAGAGAACTCTCGTTAAGGAACTCGGCAAAATGACCCCGTAACTTCGGGAGAAGGGGTGCTCTATTAGGGTGCAAGCCCGAGAGAGCCGCAGTGAATAGGCCCAGGCGACTGTTTAGCAAAAACACAGGTCTCTGCAAAACCGTAAGGTGACGTATAGGGGCTGACGCCTGCCCGGTGCTGGAAGGTTAAGAGGAGTGCTTAGCTTCGGCGAAGGTACGAATTGAAGCCCCAGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCGGGTAAGTTCCGACCCGCACGAAAGGCGCAACGATCTGGGCACTGTCTCAACGAGAGACTCGGTGAAATTATAGTACCTGTGAAGATGCAGGTTACCCGCGACAGGACGGAAAGACCCCGTGGAGCTTTACTGCAACCTGATATGGAATGTTTGTACCGCTTGTACAGGATAGGTAGGAGCCGAAGAGACGTGTGCGCTAGCATACGAGGAGGCAATGGTGGGATACTACCCTGGCTGTATGACCATTCTAACCCGCCACGCTTAGCGCGTGGGGAGACAGTGTCAGGTGGGCAGTTTGACTGGGGCGGTCGCCTCCTAAAGAGTAACGGAGGCGCCCAAAGGTTCCCTCAGAATGGATGGAAATCATTCGCAGAGTGTAAAGGCACAAGGGAGCTTGACTGCGAGACTGACAAGTCGAGCAGGGACGAAAGTCGGGCTTAGTGATCCGGTGGTTCCGCATGGAAGGGCCATCGCTCAACGGATAAAAGCTACCCCGGGGATAACAGGCTTATCTCCCCCAAGAGTCCACATCGACGGGGAGGTTTGGCACCTCGATGTCGGCTCGTCGCATCCTGGGGCTGTAGTCGGTCCCAAGGGTTGGGCTGTTCGCCCATTAAAGCGGCACGCGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCCCTATCCGTCGCGGGCGCAGGAAATTTGAGAGGAGCTGTCCTTAGTACGAGAGGACCGGGATGGACACACCGCTGGTGTACCAGTTGTTCCGCCAGGAGCATCGCTGGGTAGCTATGTGTGGCAGGGATAAACGCTGAAAGCATCTAAGCGTGAAGCCCCCCTCAAGATGAGATTTCCCATTTCTTCGGAAAGTAAGATCCCTGAAAGATGATCAGGTAGATAGGTTTGGAGTGGAAGTGTAGCGATACATGGAGCGGACAAATACTAATCGATCGAGGACTTAACCAAAA
->URS0000CB5B26 rRNA from 1 species 
-AATGGGGGAAACCCTGACGCAGCAACGCCGCGTGAGTGAAGAAGGCCTTAGGGTTGTAAAGCTCTGTCATATGGGAAGATAATGACGGTACCATAAGAGGAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCGAGCGTTGTCCGGATTTACTGGGCGTAAAGGATGCGTAGGCGGATATTTAAGTGGGATGTGAAATCCCCGAGCTTAACTCGGGGGCTGCATTCCAAACTGGATATCTAGAGTGTCGGAGGGGAAAGTGGAATTCCTAGTGTAGCGGTGAAATGCGTAGAGATTAGGAAGAACACCAGTGGCGAAGGCGACTTTCTGGACGATAACTGACGCTGAGGCATGAAAGCGTGGGGAGCAAA
->URS0001773291 rRNA from 1 species 
-TACAGAGGTCTCAAGCGTTGTTCGGATTCATTGGGCGTAAAGGGTGCGTAGGCGGCGCGGTAAGTCGGGTGTGAAATCTCGGAGCTTAACTCCGAAACTGCATTTGATACTGCCGTGCTTGAGGACTGGAGAGGAGACTGGAATTTACGGTGTAGCGGTGAAATGCGTAGATATCGTAAGGAAGACCAGTGGCGAAGGCGGGTCTCTGGACAGTTCCTGACGCTGAGGCACGAAGGCCCAGGGGAGCAAACGGG
->URS0001DB2352 tRNA from 1 species 
-GCCCCAGTAGCTCAGCTGGTCAGAGCGGTAGCCTTGTAAGCTACAGGTCCCGAGTTCAAACCTCGGTTGGGGCT
->URS0002395A25 lncRNA from 1 species 
-AATTTGTTTGGTTATTACCCTCTTTATTCCTTAATTTCTCTTCCAAGTCACGTACAAGAGTTGATACCTCCCTGGTAAGTACTCCGACATGAGCCAAGAGATCAAAAAGTTTGTCATGATGAATAAAGTCCTTGGGCATATCAGAAAGAATAAGTAATAGGAACTCCATCATGACATGAATGTTTCGAGCCCCTGAAGTGCTAGGGTGAATAACAGTTATCATATGCTCTTGTAGTTGAATGATATATTCTCTGAGAATATCCGGTGAGGTTTCCAGGAGCTTCTTAATGAAGCGTCCAACTTCTGCTGAAGTTGAAGCTTTCAAGTTTGTATAACATATGTGCATAACCTCCATTTCAGTCGGAACAATCTTCAAGAGTAGCTGGAAGAGTCGAGAGTCTCTATCATTCTGATCATCCTCATCTGAGTCTTCATCAATCTGATCCTCCCAAAGGAAGTGTCCTACTCTTTCAGCCATCAGTTGAAACAGAGGTAAGACATTCTCAACCGTCTCATGCTTAATGCAACCATTCACTATCAACCCATGGAAGTCTCTTATGTTGCCACATACATTCTGAAGAACTTCATATTGAGTCACTTCAGGAAATATCTTTTCAGCGTGATGCTTGGATAGATGATACAGATTCAAGAGGAGGAAGTCCAATTGCTCATCCATCATGGTGGCATCTGATTTATAAGAACGATGATACAAGCTGATACAATCATCCATATTACTAGTGAGGCTAGTAAGGACATCATCATCCAAAAGTGGTTGAAGCAGATTCTCAACCTCTTGTCTTTTTCTCGTCATTATATCTTCAAACTGCTCAAAATTGGAATAAGAAAGTTGAACATATGTACAAATAAATGCCATTTTCAATTTTAGATTTTCAACTTCATCTTTGTCAAGAGATTTTTGATTTTCCTCATTCTCTAGGAAAACCAGAACATCGGCAATGTCCTTGTTAAGAGCAGAGAATAACACCTGCCAAAATAATACATTTTAAAGCCACATATCTATAATTCAATACTTTACGGTTTACTCTATAAAATAACATACCAATGAGTTGTTTGCTTCTTCATTATCTTTTCGTTTTTCCATGATTCTACTTTTTCTCTAGACCTGATGAATAAAAAGTAGATAAAACTTTAACAGGAGAAAGAAGATGAAAAGATAAGAATAATCAATAATATCACTATTTTCACACATAGTAATTTTAGACTCGCACAATTGGAAATGTCAATCTTAATCACACATCAAAATGTTTATGACATAAAATCACAAACATAAAATCTCACAACTGTTAAGTAAAATGTCATTAAATTAATAATCTCTCTAATAATATTTTTCTCCTATCTCCTTGGGCTAATGGAAAAAGATTACTCTTTTATTTTGATAAAAACTAGTCTTCGGAACTTGCATCGCACGTCTGTCCCCTAATTGATATTAGTAAATTTTAATTTATATAGCTATGTTCAAATGTATGTCCTTTCATATGTAAGTTTAACATAAGAATTTAACTTTGCACAAAGTGTAACATGAAAATCTTGTGTTAGATGTTGGAGGTCTGATATATTAAATACTTCATGAAAAATGAACATTTATTTTATCAGAGGAATTAATATATTTTAATTATTAAACATAAATTTTAATAATCAAAAAAGAAATTGTCTATAAAAAAGATACGTATAAAGAAAAATATTACAAAATGTTTGGGCGGTATACCATCAAATTTATAGAAAAAATTAAAATTTCAAACGAAAAAAAAAGAATAAATAAAGACGTCGCATCCATAAAAAAAGACATCACATTTAAATATATAGACAAAATATTTTCATACTAATTGAATTACATTTTGTTAAAAGTAGACTTATTCTAGACAAAACATGCCTTACTCTAGACGAAACATATCATATGCATAAAAAACTATAATCATATATAATAATAAATAAGACAAACAGAAAAGAAGACATGAATATGTTAAGAATAAAGATAAATTGTATTTCTTGAACTATATATATATATATATATATATATATATATATATATATATATAAATGAATTCTAAAATAATATTATTCAATATATCATTTAGTCATTTTTTACTATACATTATTTTATTTTATTTTTTTACTTTTGCACTTATTTTGTACCTCTCTATAACAATTAAGTGCATGAATTTTTTGAATATTTGAGATTACATATAAAAAGGAAAAAGTACAAATATGTTGGTTTAAAAAGATAAATGATTATCAAACAATGAAAAATACATAATTATTATTCTATGGGATTTAGCATGTTTACCCTCAAAATAATTAATGATAAATACAAAATGTGATTAGCTTTATTATATATATCCTAAAAATAGAAGAAAGGATGAATACAAAAATACAGTAATTAACTACAAAGTTATATTTAAAAACTCAAAATGATAGAGATGTGAAAAATAAATATTTACTTACAACTTCATGTTGGAGTATATTCATCTTGTAACTATCATAGTTTACATATTCCTCAACAAAAAGAAGATGAATATGTATGAAATTTTAAAGGATTAAATAAAATAGTAAGAATTCTTATATTTACAAACTGGTAATGAAAATTTTACAAGGGAGGTAGACTAACCTACTGTAGTATGCGAGATGATTATAAACTTGAATAAAATAAGGAATATATATAATGTGGTGTGAGCGTGTTTGATAGACTCTTCATTACCCCCCACTTATCTTACAAATTAAAGTTGAAAGGTTATTAGACTCTTCATTATCTACATTTAATTAGTACATGAATATATGATGCATTAAGATCTTATTTGACTTAATATTTAATTAATTAAATAGATATTAATATTAATTTATTTTAGAGGTAAAATAAGGTTAAAATGATAATTCAACTTTGAGGTTAGAAGCTTCTCACTTATAATAATAATATATGATAATAGTAAGATTTTTTGTGAGAGTAGCTGAAATAGAATCAATAGAGATCTCCGATTAAGCATGTTCATACCTTTTTGACATATTTTTGTTAGACAGGTTGAAGTAAGAGATTGAAGTCTAGATCTAGAATTGCAAGATTAATAAAATACAATTCATTGACTTCACAAGTCCTTTAAATACCAAAAGTGCTCACTTAATCATTAAGTTTAGCAAAGAAGAAGATGGTACCTTTACACAAGCTGAAGTTTAGCTACAGAACCCTTTGTTTGAGAAATAATGCTGAACCTATTGGAGAAAAAAACAAGTGTAGTAGTTGAAATATACAATACAAGTCTTTTAGTAATGAAATATTAAAACACAAACCCATAAGTCTTTTTTTAATCAATGTCTTTTGTCTTTCAATTTTTATACTGGCGAAGATAAAAACAAGTGGTTGTCATTTCATCAAACACATTGAAGACATTGGCAATTTCCACATTATAGAATTTAATACAAAATATCAAAACATGAATTCTTGAAATGGAGTATAATAATTATTTTCTTCACAATGAATATACGTACTATATGTGTATATGTTCAATATAACCGGAGAAAACATTGCCAGAAAAAATAAATAACAGAGTTTAAAATATGTACTCAAAAACAATAATTAATATCATAAGTATAAATTAATGAGGAAAAAAAATTATACCGCGATACGAAAAAATAGAACGAAAAAAATTGAGTCCACTGAATGCACAATGTCCTCTTAAGGAAACTACTATTTCCCTCCAATTCCGAAAATTTAAAGAATTACATCCTCTTAGGATGAACGATGTTATTCACCCATATGGGTTCGGCTCTGGTGGGCGCCCACCCAGTGACTCTAATTCCTAAATTCGTCTATACTGTCAGTAACTCATTCAACAGCATCAAAGTAAGTACATGAATATTTAATTTTGCAGAAATAAAAGAAAATGATTATAATTGTTTTTTGTTTTAAAATAAGGGTGTGTAGTATGAAGGAAAACATTTCTCGGAAAATATTTTTTCAATTTTCTCATATTTGGTTGGATGAAATCATTTTTCTCAAATTTAAAAAAAAAAAAGACTTCCTTTCCAAACTTAAGGAAAACATTTTCCAAAATTCTTTTCTAACCTTCCCCTACCCACCACCTGCTAGCCCCCCACCCATACCCCTAAAAAGTTTAAGTTTAGTTTTTTAAAATATTTTAACTTCACAATTTCTTTTTTTCACCCCTACCCTCGACCCCCAACCCACCCCCTACCACCCCCATCCCCAAAAAAAATAATTTAAGTTTGTTTTTTAAAAAATATTTTAAACTTAAAAAATTTATTTTTTCACCCCCTACCCTCGACTTACCCACTCCCTACCAGCCCCCCTCCCCCCACCCCCCCACCCCCTCTTCAAAAAAAAAGTTAAGTTTGTTTTTAAAAAATATTTTAAACTTCAAAATTTCATTTTTTCACTCCTACCCTCGACTCCCCACCCCACTCCACTAGCCCCCTACCAGCGCACCCCCACCACGAAAAAAAATTTTAAGTTTGTTTTTTTAAAAAAATAAATTCAACTTCAAAAATTATTTTCTACTCTAGTAAAAAATAAAGATATTTCTCAAAAGTATTTTTCATTGAAAAAACAAACACTAAAATATTTTTCTAGAAAATATTATCTACTGACCAACCAAACATCAGAATATAAGTAAAATATCTACCTGTTTTTCAGAAAAACATTTTCCAAGGAATTTCCATCATACCAAACACACCCAAGAGTATATTCCTCTATTTATAGACAACAAAAGGTAATGTGAACAAATATTTATTGTGCCTTATTAGAAAGGATAGAACTATTTGTAAAAATTGCAACCCTTCGGAAAGTTTATAACGTTTCATAAAAGTCGCAACTCTTCATAAAAGTCACAACTCTTCATTAAAGTCGCAACTATATACATATATACAAATCTTATAGGGATGAACAAGTTTGAACAAGTTTCAGTTTTGTAAACTATCTTGATCTTCGATTAATTTCACGGGATATATAGATCTAGATCTACATGTACAAATAGTTTATCTTCTTTTTTTTGAAAGAATTTTCTTGTGTATTATGTACGAGTATAAATATACAGGAAGAAATGCAAAATTTTAGCACAATATGAAGTGTCTAATCAATCTTGATATTTAAGCACCCAAATTCAGTATTTCGCTTTGATAGGTTCATAATTAAGAATCAAAATAATAATAGAGACTAAAATAAAATTCATTGACTTTTCAAGTCTTTTTCATCAATTTTGTAAATATGTATATTCATATTACAAGTTGATAGACTTGTGGAGATTGTTAATTAGCTTGTGAATGAAGATGATGTGTGTGTAGATCATGGATTTGAGCCACTAATGTTTCTATACTAATGTTGGGTGTAGGCTGCGTTCTTGTTAGCGGAAACGTGAAATTAAAGAATAAGGAAGAACAATAATGAAAATAAGAAAAGAAGAAGAGAGTTTTGAAGCATGAACTAATTACCTCTGCAATATTAGAAGCCCTGCTCCTTGTTTCAGAAACAGAGTAATTGTTTGCCAAATGATCCAATTAATGTAGTTGAAACAAGATCTGGACTTTATTATTATTATTATTATTATAAGTCTTGTTATTCACATAGGAAGATTCCTAAATGAGATTATTAATTCAACTGGCTAACAATGAATTAATTACTTGAAAGGCCAACTTAACAAGAATAAAATATATATATATATACATCTTGACAGTTTGTTCATTCATAATACTAAAATACAATTCATTGACTTTTGAATTATACATCTATCATCTTTTTGGTGCTTCTAATTTTGAGTGACAACGACATTATCATATGTTACTTTTCTATATTACTGAAGTGGAAAACTCCAAAAGTTAATTTTTTTAAAAAAAATAAATAAATTCCATTTCCAATTTTTATTTTTTTTTAAAAAAAGAACATCCTTCGTTTCAGAAAGAATGATCTAGTTTGACTTGGAACGGAGTTTAGGGAAAGAAAGAAGATTTTTTAGTCTTGTAGTTCTAAATTAAAATTATGTCATATGTACCAAAATGTCATTTAATCTTATGGTCTTAAACATGTTACATGAAAAATTAAAATTAAAATATTGTCAAAAAAGGAAAGGTGTCATTCTTTTTTAAACAAACTAAAATTGAAATAGGAACATTCTTTTTTAACAAGAATAATATATATATATATATATATATATACTAGTTTGTGAGGACGTGCTTCGCACGTGTGTTTCATGTGACTTTTTATAGATACGTTAGAATAACTAAAATCTCATGAAAATATATATATATATATATATATGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTATGTATGTATGTATGTATGTATGTATGTATGTGTGTGTGTGTGTAAATTGTAATGAATAATAAAATGTAACAACTACAAAATTAAGAAGTCTAACAGAGTAAAAAAGATAAAAAGAAACACAATATTTAAGAAAAAAATACAATATAGACATTATTCTTATAAAATTGATGTATATATAGATGAAAAAATAAGTACAAAATTAGTACATAACTCTTTTAGAAAACTAAATTAAGAAGTCTAACAGAGTAAAAAAAGATAAAAAGAAACAGAATATTTAAGAAAAAATAAAATATCGACATTATTCTTATAAGATTGATGTATATATAGATGAAAAAATAAGTACAAAATTAGTACATAACTCTCTGAGTTTTTATTGATTCCTTTCATATCCTATCAAAATTCAAGAATCTTCATCATCTGTTTTTACTATAGAATAAAAATAATATCCTAATAATCTTGGTAGGGTTTCATGAGATAAAGAAGTTGAATTTATATAAACAGAATAGAAGGAATATCAAAAGATATCTTAAAGTTTTAGTTTAAATATTTGGAAGTTATGAATATGAAAAGATGAGAGTTATGAATATTAAGAGTATAAAAGTTAAATAAATAATTAGAAAATAATAATAAATAAATGAAAGAATATGAAAAAAAATTAAAGTTAGCAAACCATGTAAAAAGAACAACTAAAGTTCTTATCATGTAATTAAGCATTAATGAATTTAAATTTGTGAAGCTAGAGTCATTCTTTAATAATAATTAAGAGGACATTATTAAAGTGCATCTCCATTTTATAGATTTGCACCCTTTAAATTATTAAATTTAGTTATTTATCATAAAGGATAATACTTTATCCACAATTATATTATTCATGAGAGGGGTTAAGAAAAAAGTTATAAGAAAAGGAAAAGAAAAGAAATTTAGGTAAAGATTTTTTCTAAAAAAAATTATAATTATTATATACACATAGATTATAGATGATAAATATTAATAGATTAGATATTTAATTAGTAATTAATCTTAGGAAGTCCAAAAGTCATTAACATTTAATTAAATTTATACAATCAAATATTAAATATTTTATAACAATTTAATTTATAGTAAAGGTAAAAGCGTAATTCAACTTTCAACTTTTTTGTTCATGCTTTTAGTAATATATGATATATATATTGACGGTTTGTTCATTCATAATACTAAAATTCATTGACTTTTGAATTATACCTATCATCTTTTTTTGAGTTACCAACGTCAGGGGCAAATGTATATTGTCGAGACATGAATGATTTGGCTTTTAGATGAGATGGTCACATATATAATAACTTTAGGATCCACCCGAACCCAATGAGTCAATGACGATAGATTTTTCCTGTAATTAACTTTAAGGTTGATGAGGTGAAAGGAAATTTTACTCATTTCTACTTAATAAATTCAGTTGAGACTTTTATCAAACACATCTTTTAACATTAGCGGTTTTCACTACAAGACTTGATTTTTAAGCAGCAAAAATGGTTACTTATAACAATAGAGAACATGTTATAATGCTGCTGTCACTTAAATTATGCTCCATAATTTTCCTTTTTGATTTTTGTTAATCATGCTGACTGGATTAACTTGCACACATTTCAATCAATTTCACAAGATACCGTTCACTTTCAATTTGCATGCACTTTGACTAATTTCATGCTTAACTCTATTCGTCAAAGACATGGATAGATTATAGAAAAAAGGCAAAATACATAAATATGTCCTATTAACTTGACTTCAAATAACATTTATGACCTTCAACTTTGGGCATGCACAAATACACACTTAAACTTGTATAAAGTTTATCAAATAAACACACATGTCCTATATGATATCCTACATGTAATTTTTTGTCCTACGTGGTGTCCTGTAGGACTCGTGTGTTTATTTGTTCTATTTTATATAAGTTTAAGTTCTACTTGTTCATATTCAAATTAAAGTTGGAGGACATAAACGTAAAATGAGGTCAAGTTAAAAAGTACATTTATGTTATATGCCAATAAATCACCCTTTTCTTGCTGAACTGCATTGCTCGCTGCTCATGAAAGAGTATTAATTTCTTATTTTCCATGCTATGTATGATCAAATTTTGGACTATTTTGATAAAATAAAAGGTAAAAAAAGGCTCAATATGTTGAATATTTTTGGGTGTGGAGACGACGGGGCACTATCGATTTCTCACAACTTGAATTTTATTATATCAAAGTAAGAACCCGATACAGTCTTACAATCTTTACAACACTTGTTGTTTTCTTCAGCAACACTCTTTACTTGAGCATTCATTCTTGGTTGCTCTCTTGCTTTTATTACTTTGTTCTTGCTAGCTTGCCTACAACTCAAATGGACCACCTCTATTCACAGGAGGTGATAGAACAATCTAGCTAAACATATTTTTCTGCTATATCATAGAATATTCCTTTAATTACTTAATTCTAGAATTACCCTATCTAGAATACTAGTCTCTCTAGAATACACATTTAGAGATCTTCCTCAATTCTCCATAACTCCGGAATATTCTAGATTTTCTTGACTTGTCTTGAGTACATAATTAAGTTGGCGATGAATTCTTTAAAAAATATATTATCGAATTTTGAGAAAAAGTTTATTTATGTAGCTTGACTCATTTATGTCATTGTCGTTTGAGAAAAGACATATTCATGCTATTATTTTTTAGGCATATTACATGAATATGCCCTTTAACTTGATCTCCTTTCACATTTATGTCCTCCAACTTTGAATGTGCACAAGTACACACTTAAACTTGTATAAAATTAAACAAACAGACACAAACGTCCTACTGGCATCCTACATGAAAATTTGTGTCCTATGTGGTGTCTGTTAGGATTGAATTCACGCACTCACACTTGATGAATGAAGAACACAAGAACTTTCGAAAGAAAGAGATGAGAGATCTAGAGAGAGAAATATAAAATCCAATATTTCGTGGTAACACCCCGTGAGTAAACTTCCACGGTGGTGAGGTATATTTATATTAATAAATCAGAATATTTTTTATTGCAGAGAATAAATAGTAAAGCCTAAAATTTCCATAACCCCTGGCAATCTCACCGCGGAGGTTAAACCACATAAACAATTATATATATTAATCAAGCTCCACAACCTAACAGTGTCTTGCATGTATTATGACAAGTAGGACTCGTGTGTCTATTTGTTCGGCTTTACACTAATTTAACTGTCTTTTTGTGCACACTCAAAATTGAAGGACATAAATACAAAATAAGACTAAGTTAAATGGTATATTTATGTATTATACCTATTTTTTAATTCCAATTATGCAAAATCATTTTTTAAACCTGACCATTTATTATTCGACCACATCATTAATTTTAAAACGTGAATAATCTGACATATTGTCTTTGCCAATTTATCCTCCCAAATTGGGATGACACACCCAATTTTTATATTCTATTAATTGAGTATTGAGTACTGAGGTGATTTCTAATTAACATAAAATCATATATAAAACTATAAATATAGAAACATGTGAAATAAGATGATTATATGGTTACTAACATAATAAGATATGATTTGTAAAAAAAATTTATACACATCAATACAGTAAGGTTATTTGCTTTCAATTTCTATTACCACTTAACAATGAAATCAATTAATTAGCTATAAAGAGGCATATTTATGTAATTTCTAAAGAAAAATGGAATTGAGCATATTATTGTACTTATTTTATTATTTAAACCAAAAGTGACAAAACTTAAGGGACTAACTATTATATTTGAAGGGTACAAAATGGATACTATCCCTATACATAAGTGATAATTTTGTCTTAAAAAAGAACTCTGATTATTTCAGTTGCGATTTTGGTAAGCAGAATCTTGATCCTAAAAAGAAAAATACTTCATTATGATTTCTTCATTTTGAAGACAAGTTTGAGTTTGAAATTCTCATCGTGTTTGTCACCTACTATGTTTGAACTTCACCTCATAAGTTAAGTTCTATTTGTGTTTGTCGAACAATAATTGAATCAATGACATCTTTTGCCTCATATGCCACATCTAAAACACGTGGCCAGAGATCCTTGTACCATTCTTGCTCAATATTTCTTATCCATTCGAGGTCTTGTTTCACCAGCCCAACTTCTTCCTTTATCAAAGCAATTGAATAAGCATTGGAATCCAACAAATCATCTAAGTGTCTCTGTAGAAGATGCATGAAGAGAGGTCCATGAATGATAAACATGTTTGAGATAAACATCGTTCTACAACTTGATTTAGAACGATGTTGTGAGCTTATAATCAATATTATCCCTGAGGCTAGCAAAGGACACGATGCATGTCGTATTTACATGCAACGTTGTTGTCAACATAATATAAAATTGATTGAATCAGATTCTCAACCTCTCGTCCTTTGGCAGTCATTACATCTTCAAACTACTCCAAATCAGAACATTTCAGCTTTTCAACTTGATCCACATCAACAACTTTTTGATTTTTATCATTCTTCAATCTCTCTAGGAAATCCAGAACATCGATAATGTCCTTGCAAAGAGCAGAAAATAATACCTGCGAGAATAACACATATCAAATTTTTAAGGCCACACGATATCTACAATTCAATACTTTACTCTCTATCAAATACTAACATACCAATGAGTTGCTTGCTATTGTCGTTTTTCCATGATTGTAATTTTCCTTTCAAGTTCTGCATAAAAAGTACACACAAACTTTATCATGTAAGAAGTCACCCTGCTTCTCACCTAGTAAGAATTCACACTTACCGGATGTTTAATACCAAACTAATACAACTTATCATGGGTAGGTAATGATTTAATAAGGTGAATATAAACATTAACTAATCATAATTAAGTGATAATGTTGTCAGTGACGGAGTCAGAATTTTTGCCAAGAGTGTTCATACTTTAGGAAAAAACAGAATAATGAATAAAAAAATTGTCACACTTGGGCTCGAACTTGAAGCTAGAGGTATTCTTGCACAGCCTTAACTGCTGGGCTGACAACCTTTATTATGTCAAGGTTGTTCAACAATTAGTATATATCTAAAAAAAATCGATATTTAGTATATATTCGGAAATTTTTTTTGATGAAGGTTGTTCATCTAACCAACCTTGTCAAGCTATAGCTCTGCCCTGAATGTTGTGCATCTATTGATTTGTTGTAAATCGATGGTGTTAGTACGTATTTAATTCTCTCTCTTTCTCCTGCATTTTGTTTCTGTTTATAGATTTCATTTTCCTTGCATCATTTTTTACTTTTCGATAATTTTACTTCAATAGAGATGAGAGTAGCAACCTTTTTACTTGATGATGAAACTATATATCCTTTGCTTGCTTTGATATTAGATTTATAGTGCTCAAAATTCTTGAAGTAAACAGAATACGGTGAAAGAGAGTGAGCGCACTCTGCCTACATTCTTGTTCTTCAGGATATAACAATTCAATAACGTCGGTATAACTCAAGAAACTTCGAATTAATTTAATAGTCCAAAACTTCACAAAAAAAAATATTTTTCTTCAACATATAATTATTCTCTTTTATATAGTGAATATAGTCGAAGATTTTAGAGTATTTTTCTTTGTCTCGACTCTATTTTCACTATATTAATCTCAATATAAACACAATGTAGTATTCCTCGTCTTTTTCACTCCACATTTTCTTGTATATCTTTTGTTATCAAAACAAAGTAAGACCATCACTATTCAATGGTGATACTTCCTTGCAATAAATAAAAAGATTATAGAATAGTAAATAAAGTAAATAAATAGTCCAAAAGTTACACAAATTACAAACATAATGTATTCGAATAATAACATTCAAAATTCTTCTCTACTATATTAAACTTTGTTGTTTGAAATAAAGTCAAACCTTAAAATTTTGTGGATGCAAAATTCTAAAATTTAAAAATTACAGAGTACTAAATTAATAATTTTTATATATTCAATAAATTTCTTACTACAAATTACTCTTATATTAGAAAAGGCATGTTCAACATGCCTGCTTCATAGGTCTGAGGGTATTTTAGTCTTTTTAGTACTCCATTCTGGCTACGTGTCCTGTTGTTGTGCTTTCAATGTACACGTTACTGCAGACTACCGATACATCAAAAGTTCTCCTTTCTCCAGCATTCTGTTGAGGTAAGCTTCTTCATATGATTTCTTTGGTTTTTTTGTGATCTTCTTTGTTTTCCTCAAAATTGATGATTTTTTCTTCTTTTTCAGTTGGTTTTAGTGTTGATGTTCAATTTTTGTTATGTGGTTGTGTTTTTCCTGTTTAATTACTGATTTTTGCTTTGTTTATTACATGCAACAATTAATTTAGTCTGTCTTCATCATAATTCTTTTGAATCTTATCTGTTCATAGATGGTTCTTTGTCGAAATTAACTTTTTGGGTTCCTTAATTCCAGTTGTTTTTTCCATCATACTTCTTTTGGACTTCCTCTGTTTGTATATGTTGGTTTTCCATTGGAATTAACTTTTTGGGTTTCTTCATTTTAATCATATACTGTTGTGGGTTTCGCTTCGAGTTCTTTTTACATCATTGCATTAACTTTTTGAAATTATTTTAATTTACAGTGTGAAAATTTAAAGATCTGCAACTACTTATGCCAGAATTTGAACTATCGATGTGTCTTCTTAGCAAATTCAAGGATCTGGAACTACTTATACCAGATTTGAACTACGGGTATGTTCGTTGATGGTTTCTTACGCCCTTTATTCCGATTTTGCTCTTTGTCCTACATTAGATACGTCTATGAGCTTTCTTGCTAAAGTGCATCTTCATTATCTGAGTTGTGTGTACTGAAGGACCTGAGAGAATTAGAGAACCGATTATTATGGGTGCTTCGTTTGGTCATGGGGAGAAAGTCAATCTGCATCTAGCCAGGGAAGCTGGCCACTCCTATTGCCAAATTGTCCGTGCTGCTAATATGAGAGTCAGAGAGATAGAAAAGGCTCTTATTAGAGGCAATCATTGAGTATCCTACAACACACGTGTTTCAACACCATTTGCTATAGATTTGTTGACCAATCAAGTAAGTTTATTCATTTATAGCAACTGTTTGTGTTGGTTATTATGGAGAAAATTTTCTGTTCTAGCATCAATTTGGTCTGAAATGAAGGGTTGTTGCTTTAATCTAATCAAACTTGGAATTATTCTTTTGCTTATGTGTCATAGTTGATTCGAATGACATGCATTCAAACAATTGCTATGTTGTCGATGTCTTAAAGATATTCATGTATTATGATGTATGAATTTGTGTAGGTGCACTAACTATGATTCTAATGATGTATAAATGACATTTAACGAAGTTTCGACCCGACTATATGTGATCTGTATGTTGTGAATATTGTACAATGATTTGCATATGCTATTGGTTATGATACTTGACTTCATATGCATACCTGAAAAATATTAGATCTCACCTATATAAGTGCTCCCAAAAGCTCTATTAATTGGCAATATTACTTACTATTATTGTGTCTTAAAAATAAATTCTCAACAAAATGGGTTTTCAATGAGTTGTTGAACTTCTGCTTGTCTTACATTTGTATTTTCCTATTGGCTCATTTGTTTTTTTTAAAAAAGATTCATTGGCCTGTTCTGGTGAAAAATATTGTCAATAACTTAGAGCTATTGGAGTTAGCAATTTCTTTATTGAAAAACTGAAGATCTTCTCGAAATAGCTCTTATTACTCTTTTTATTAATCAAGTGGAGTGTCAATGGTATGATCAAAGAGAAGGTAATTGTATATGACGAGAGCTGATACATGAAAAATGCATTTTTTGAACTTGTCAAGTCTATCAGTGAGCCAAAATTGTGTTGTTGTTGTAGTTATAACTTATTATTCATTACAGCTGCATATAACTATGGCTATAGTATTATTGATGTAGTTACTTTGTGAAGAAGGTTGACTCATCATCCAACTTTATAGTGATAATTAAACAAGTTTATTTACTAGCTCTTCCTTTTGATTAAATTAACATAATTTTTTGTGTAGTTGTCCATATTAATTTTCAGGTTTTGTAAAAAATTGCATCCTTTATTTTCCTCTTTACTTTTTTTTCTATTTTTTTATTTGCTATTTGGATATTAATTGTTAAGTGTTAATTGCTATCATTTTTTATGCTATGCTTAGTTTGTGGACTAATAGTTCAAAGAAGCTTAGCAGTCGTCCCTATTCTAGAAATTGAATGGTAATTCTATATTTTATACTGTTAAATTTATATATTATCAGCTTAGCTTAGTAGGAGAAAGTTACAACATGTGGGAAATGAAAAGGCTAGAAATACTCAAAAATGAACCAAGCAAGTCATGGCTTTTGTTGGCTTCTGCAATAGGAATGAGATTACTATGCTAAAATAGAAAAATGAAGACCCCTTTGTAGAATGCAACATCATTATTTGTTCCTTGCATAAATAATCTAGCCCAAATTTTTTTGTTCCTTGCATAAATAATCTAGCCCAAATTTTTTTGTTCCTTGCATCAGTGTTATTATCCATGCTCTTGAATAATTAAAAGCATAATAGTTGCTCCTCTTTTTGGCACAAAAATACTGAATTCATATTATTGTGAGTTGTTTTTAGGAATATTATTAGTTGGCGAACAAACAATTAATTTTTGTTCCATATTTTCAAGACATCCATAAAGTTTCATCCCTTTAGAATATTGAAGGAAAAATATATCGCTGAGACATTTATTTGTTAAAGTAATTCATGGTTTGTAAACATCTTTTATTGAACTTGAAATCCTAATGTTTCTCTATTTAATTAAGGTAGAACAAAAAATGAGAAGGTATGTGCAGGTTTGGACAATGCGATGAGATGTGTTGTAAGAGTCATGTTCTGAAGGATTAACAATGGAGTGTTTATATTGTTCGTGCCCCTGACTCTACTTGCTATGTGAGGTTTGTCATCTCTCCGTTTTATCACTTTGAATTTATTATATGGATGGTTCCTCACTCTTTGAAAGTGTAAAATGTTTTTGTATTGATATTGTGCTGCTGTGACTATGTTTATTGATGCTCTTCTTATGGCCTTTTAGTTTCTATATTTGTAAGGAGTTTGAGATTTTTATTTCAGGGTTTGCCAATTGAGGATTTAGGAGTGCAAATGTATTCTTTCATTTCACAGCTGAGTTGAGCAGTCATATGTTATTGTTGTGCGAAATTCGAGATAATACGTGAAAATATAAACGCAAAAAACAAGACAACAGATTTACGTGGTTCACCAATAAATTGGCTACATCCACGGGGAAGAGAGGGAGCAGTTTTATTATGGAGAGGCAAAAACAGAATTACAGAATAGGGTTTGCCATAGCGTCTATATATAGTGCTAAGCTACGCCCTAACAGACTTGGGCCCAACATACAGAATTGACAGATAATTAAGGGCCCAACAGCGAGACCCCCGTCCTTTCTGTTGTAACGGGTCCGATTCAAGGCATTCAACAGTTATGATTAAATATTTCTATTTCAGATCCTCATACTACTTTTTAAATTACTACTGAAGTTTAGTAATTTGATTTCAGTCGTAGTTACGGCATGAGTGTGTTATCTAATATTTATATTCTATTTTTGAGTTAGTTTTTTATGTTAGTTATGTTGAAATTCATTTTATTAACATGATATTAAAATTATACCAGCACGTCCATGTTGTGTGATTTTCAATATTTATCGCCCTGCTGTGTTGGTGTGATAGGGTGTCTCCATAGATTTCCAGAGTGAAATGTTGTCTACAAATGATGGATAATAATATGCTGCGGCAGAAATGTTGAAGTAGTATATCAATTTCTTGCTCTTCATTATTAAAGAAAAATTAGTTAAGTAGTTTCCTCATTTAAATTTTAGTTGTTTAGTAATAATTTAGAATGCTAATACAAACTTTATACTTGCTTCACATGATGAGGCCTCAACAACATTGGTCTATAGAGAGTTCGTTTCAATGGTTTTCAACAAGGTGTTTAATTTGTTCCTACTCTAAAATGAATGTGTTAAAGGAAACTTAGACTGAATAAGAGGTTAGACGTATCTTCTCTTAGAAACACCCCTAAAAATTCAAGTTAGTGAGACTGACAATACTATCTTTGATTTGTAAATCAGTTTACTTTATTAGTGAATCGTGAATTTGTGATTAATAAGATTTGTAAATCAATTGTTCCAAGTAAAGTATAAAGAAACAATTTATATGCTACCAAACTTTGAACCATGAACTCCTCAAGCCATGTGTTGTGAAATATTGCTTTTGAAACTTTTGTATGTTGAAGTGTTTGTAACAGATGTAGGATGTGGACATGCTTTCTTCTCTTTATTTTTCTAGGGAAGTTGAGGCAGAATCTGAGAGTGAGAAAAAGCCTAAACAGATTTAAAAACTATTTATTTATTCATCATGTAGACTATTTAATTAAAAAGGAATACATCTTTAATTAAATGTAACTAAATCTGTTAGAACAATATCTAGGAGAAGAAGCTAAAATAGAATACAATAGACTACCAACTAAAAGGTTATACCATATAGAATTAACATCCTCTAAATAAATCAAAGTTACATAAGTTAGGAATTCCCTCTCCCAGCGCCAAAATGTGAGTCTAAACCTCTGTCTCCTACAATTTTATCTAATATTTAGTGTTAGTCCGCCTAAAAGATAATGAAATCCGCAGATTTGAACAGACCATAAAAGTTAATCCTGATGATGATGATGATGATGATGGTGATTCCAACACGGAAGACGATAGGGATAACAAAGAGAAGGCTGAGGAAGCTGATGATGGGAACAAAGACCGTAGTAATTGTAAGAGTGATCCGCTTATCACAGATCATGTTAGAGTCCTTTGGATGGATGAGTCTGAGTCTACAGAGAGTAGTAATAATGTCATAGTTGTCGATAGAGGATTTCTGCATGGTGATTATGTTGCTGCAGCTTCTGATCCAACAGGTCAAGTAGGACTCGTGGTTGATATCAATATATCTGTAGATTTATTAGCGCACGATGGCTCTATTTTTAAAAATGTCTCATCTAGAGAGTTGAAACGTGTTCGGGGTTTTACAGTTGGTGATTATGTTGTCCTTGGCCCTTGGTGGGGTAGAATTGATGATGTTTTTGATAATGTCACAGTGATGTTTGATGATGGTTCTGTATGTAAAGTTATGAAGGCTGACCCTTTACATCTTAAACCAGTTGGTAGGAATGGCCTTGAAGATGGACATTTTCCTTTCTATCCTGGTCAGCGTGTAAAAGCTAGCTTCATCGTCAGTTTTCAAGAATTCCAGATGGTTATCTGGCTCATGGAAAGCAAATAGGTTAGATTATGAATTCGACTCTGATACGTATATTATTTGGTAGGTCATTTTCTATTGACAGAATTATTTATATATATATATATATATATATATATATATATATATATATATATATATATATATATATAATTCAAAGAGTTATGTACTAATTTTGTATCTATTTTTTCATCTATATATACATCGGTATTATAAGAATAATGTCTACGTTGTATTTTTTCTTAAATCTGTTTCTTTTTGTCTTTTTTTTCTCTATTAGACTTCTTAATTTAGTTTTCTATGAATGTTTAATTACTGTAAGTCTTTACACTTATTTTGTAACCAGTTTCTGATAACGTGCATTGCACATTTGTCCCTTACGTTCATTACAATTTTTTTTATTTATTTAGAAGTGAGTTATAAGATATTGATATTGAAATTAACAATATTAATTTTACTATTTATTTTTTATTGATTAAAATAAATCATAAAATAGAATGGTGCATTTGCTATCAAACCAGAAAATGTGAATCATGACTTAAAATGTCTATGAATTCGTGATAGAAAAATAATAATAAATGTATCTAATGCCTTTAATGAAAGAACAAAGGCGCGAGACAAATTTATCAGAAATATAAATTTCAATTACACATTTTGCATTTTCTATAAAGAACATAAACATCGAAGCTTAACGACAATATGATAAGATTGTCTTGCGAACACAATTACTTGTGATAAGTCCATGGGTCTATATATGAGTATATTCTGATGATATGATGTTTCAGTATTCATGAAAAAATCATCACTCTATTCAAATAGTAAAAATAATTAATATGTTTTAGTTTTCAAATTTAATTTTTAATAAACAGAAAATAAATTAACAAAATAAAAAAAACAGACGAACCAATAATAACATTATAAACATGCTTATGATGAGTCATATATAATTTGAAGGAAACAATACTACAAATTCAAACTGAAGAGAAAATAATATCTAAGACATACTAAGATTAAAATATGTTCTCTAACTAAGATCTTAATCTTAATCACCCATAAATTAAATAGGGAAAGAAAAGACTCTTGTAAAAGAAATGATGATGTATACAATTTAAAAGCTTGTATGTGAAAATAAGAGAATAAATATATTGCATAAAAAAATTATAGATGCGAAAAATACCATGTGTGATTCTTAAAGGTAAAATTATTTTACTATTACCTGTAAATTATATACTTTCATCATATTTATTGTTGAAATTTCACCTTTTAAAAAATGAAAAACAAGCTAAGAAAAAAAAAGTAAAAAGGGTAAAAAGGAACAAATAAAGACTAATAAAATAGAGAAAGGAAAAAATCCAGTGAATATCCTGATTGAAACAGCGTTATAGAAATACTCGGATAAATCAATATACCTTGAATTTCAAGAACACTTCAAATTGCATCACATATAAATCTAAGAAGAGACATATTCTACAATAAGAGGAGGGGGGATGGGGGGTTGGAAGAAAACAACAACAAAGAAATAGTGTTAAAAATTTGACACCTTCCAATTTCAAAAAAGAAAAATGATGAAGGGTAGGGGATGCTGGAGGACTATGAGATTTCTAGGAACATAAAATCAGTTTCTCACCGTGTGGTTGTCGAGAAATCGCTGCAGACACCACACTTCATATGTTCTTCATGATTGTCTTAAAGTCTTCGATTTCTTAACTAAAATAACGTTCCTATATCTTCTATACCTTTTGAAATGTATATGAAAATGAAATAATTTACTTAAAGATAAACATAGTTTCTTTATTTACCTGAAGAAAGTCATTATTTCACTTGGAAAAAAGATTTATTACTTTCAATTGCCTTTTTGTTTATCCTATTCATGGTTATTTAAATGTAAGTTTAACTGTTGTCTTTTCATTTATCCTAATTATTGTAATTGAAGTGTGAATTTATTTTTTTCAGGTCATTAAAAATGAAAATATTATGCTTTTATTTTCATATAATGTTATATATATTCAAATAATGTTCAAGTGAAGGGTAAATTCGTAATTCAACTTTGAGCTAAAGGACTTCCCACTTATAATATAACTAGTCTCCGAGCACGTGCGTTGCACGTGTATCCCAAATAAAAATCAATAAAAAAATAAATGAAAACGTATATAATAAACTATTAGGAGAATTATGATGTTTTTTTCGAGTGTTCTTTCGATATTTTCGATCTACTGCACATTAGATAAGTCTCCAAAGCTTCCAAGAAAGACACATCAAGTTAAAGAATTAAAAAGGGAAAATGCGACGTTACTTAAAGTCATCTGGTATCCTTAATGTGTATCGTTACAAATGTAACTACTTCCTTAAAAACTTTCAGATATACCCAGACTTACATTTACAGGCTTACAACTACTATCCATCACTGTTAGAGAAGACTTGGAGTTGCTACATTTGTTGAAGAAAATGTGATATATTTTGCTAGCAAACAACTGCAATTTCAATTTATTATTAATAGTTTGAAAGTTTAAACATGGTTTCTTTTCTGTGGGAAGCTATGCGTAGAGAGTTTCAAAGAGAGTTGATCATCATTCAGCATCAAACCATATGTGTACAACAGCATTCAATTTTTGATATGTGTGATTATACCTTTCAAGCTATTTATTTTACCTATTAAAAAAATTAGAAAGTTATCATTCAAATGAAGTTAGCAAATCAAACGAAAAAATCTAGACTTAATAAGATTGTACCTGAAAATTAGAAGACATTTTTGTACCCACTTAACAATGGAAGCTTGTGTTGAATGACTAATATTGAGTATGTTTATGTAGTGTAGTCTTGGAGATTTGTTGATAAAAACTCTTTGATATTCCTCAATTACTTAATTTGATCCTTTTCAACTTCTCATAATTAGCAAAATACGTTTCAACTTCTATATTAATTGAAACTTTATTAGTGTTCATCCTATTTGGTTGTTTCACACATAGTAATTGAATAGACTGTTGAACTTCTTATTTTGTTCCTTTATTATGTAATTCAATATTACTATTTAATTAGATATTTAATTTATATTTGGGAAAAGTATTTTATTACTTTTTAATTTAGTATAGGGGCAAAGTAGTAATTCAACTTTACACTTTAGAGCTTCATGCTTATAATAATACTAGTTTCTGAGGACGTGTTTCGCACGTGTATTCTATGTGAATTTTTATAGATATGTTATAATGATAAAAAATTTATGGAAATATATATGTAAATTAATGAATAATATAATTTAACAATTACAAAATAAGAATAAAGACTTACGCAATAAAACATTCATAAAAAAACTAAATTAAGAAGTCTTATGGTGATAAAAAAAAAAGACAAAAAGAAACAGATTTAAGAAAGATCCAATGTAAAAATTGTTCTTATAAGACTGATGTATGTATAGATGAAAAATAAGTACAAAATTAGTACATAATTCTCTGTGTTTTTATCAACTCCTTTCATATCCTATCAAAATTCAAGACGTTTCTTCATCTACTTTAACTATAGAATGAAAATGATAGCCTAATAATCTTGGTAGGGATTTCATGAGATTAAAAAAGTTGAATTTATATAGATAGAATAGAAGGAATATCAAAAGATATATTAAAGTTTTAGTTTAAATATTTGGAGGTTATGAATATGAAAAGATGAGAGTTATGAATATTTAGAGTATAAAGTTGAATAAGTAATTATCAAATAATAATAAATAAATGAAAACTATGAAAAAAGAAGTTAAAATTAGCAAACCATGTAGAAAGAACAACTAAAGTTCTTATCACGTAATTAAGCGTTAATGAATTTAAATTTGTGAAGATAGAGTCATTCTTTAATAATAATCGAGAGGACATTATCAACGTGTGTCTCCATTTTGCAGATTTGCACCCTTTATATTATTAAATTCGTTATTTATCATAAAGGATAATACTTTATCCACATAAATTATATTATTCATGAGAGGAGTTAAGGAAAAAGTTATGAGAAAGAGGAAAATATAGCAATTTAGTAAAGACTTTTTTTTTAAAAAAAAATTATAATTATTATATACATATAGATTATAGATGATAAATATTAATTAATTGGATATTTAATTAGAAATCAATCTTTAGAAGTCTAAAAGTCATTAACCTTTTAATTAAATTTATACAATTAAATATTTAAATATTTTATAACAATTTAATTTATAGAAGGGGTAAAACTGTAATTCAACTTTCAACTTTTTTTGTTCATGCTTTTAGTAATATATGATATGATATGATTGTTACATTTTATTATTCATTACATTTTGCATATATATTTCCATGAAATTTAGTCATTCTAACGTATATATAAAAATTCACATGAAACACACGTGTGAAGCACAAAGATTTATATAATCAAAAATTCAAAATTGCTGATTTTCAAGATTATCAGCATAATTTCTTCCTCCCAAAGGAAGTGTCCTACTCTCTCAGCCATCAGTTGAAACAGAGGTAAGACACATTCAACAATCTCGTGATCAATGCAACCATTCACTATCAATCCATGGAAATCTCTTACGTTTCTACATACATTCTGAAGAACCTCATACTCCAGGAAACATCTTTTCAGCACGATGCCTCGCTAGATGATAGAGATTCAAGAGGAGGAAGTACAATTGCTCATCCATCATGATGGCATCTGATTTAGAATGACGATGATCATCCATATTACCGGCGAGGCTAGTAAGGACATCATCATCCAAAATTGCTTGAAGCAGATTCTCAACCTCTCGTCATTATATCTTCAAACTGATCCAAATCGGAATAAGAAAGCTGAACATATGTACAAATAAATGCCAGCTCCAATTTTCGCTTTTCAATTAGATCCACATCAACATCCTTTTGATCTTGTTCATTCTTTAATCTCTCCAGAACATTGGCAACGTCCTTGCGAAGAGCAGAAAATGACATCTGCCAAAAGACCAATCAAATTTACAAAGCCACATTTCTACCCTGCAATAACTGCTGACATGTTATATTTCAGTGCCCAAATATTTGACTTATACTTCCTCGATAGCTAACACATAGTCCAGTCACTTCAATGATATAAATAACGTTTGAACATTGGGACTGTACAACCATTCATTCTCAACTATAAATATTAATAGCCTACTATATGGCTTGTTTACCCAGAGTAATCGAAATTTAATTTGTAGACAAAATATAATGATACTAACTCGCTATATATTTAGTAGATAATGTGCTTGATTAAAATCTTACTAGAAAATGACATTTAGCTTGACTTCGGTGGATAATTGTGACCTTTAACTTTGCCGGTGCACAAGTATGCTTATCTGCCACAAAGGAAAGAGATAAGAAAGTTAATCAAACTTTCAATAGTCTCAGTTTGAAGTCAATGAAGTGATTGAGAGAACTCAGGTTCAAATTTCAGTGGAGTTATCTGATACCTGTTGCTGGTGCGTGTTTTCAATAGTCATGGCTCGATACATTAACTGTTTTTTTTCTGAGAAGGGATACATGAACTGTGTTTGTGATAAAAGAGATAAATTGATTGTTAGTTGTAAAACCAGAAGTTTCCAAGAGAAAGAACAATAATCCTAATTTATTAATTGTGTTGCTGCTTTTGATAAATGCCAGGGATAAATAAACAGTGTAATGAACTTCAGTGTTTAGTGAGATAACATAGTTAAACAATTGATGTCGAGTGAACTCTTTGAATAATTTAGTGGTCTGCCATATGAAGAATAACTTGATGTTGCACAAATCCTACATTTTGACAATTCATGTTTATCTTTCCTAGTTAGACGCTTCATTAGCTTTTGAGCTCTTCTTGTTCAGTGGCTCTTTTGCATAATTGGTTATCCAGCTTACGCTTTAAGGCACTTGGAATGGATGTGATAGAGGAGATTACCAACACTAGTAAGGAACTTCAAGATCTTAGGGTGTTTCCTTCTGATCCATGACCTAATGTATCCTTGACAGAGCAAGGCCTTGTAAGTGTCTCCATGGGCTGCCCTAAGCTTCAGTCAGTTTTATACTTCTGCCTCCAAATGATAAATGACGCCTTAGTTACTATTGCTAGGAACCGTCCTAACATGATCCAATTTCATTTATTATTGAGCCTCGAACTCCTGACTTGAACCACTTGATGCTGGTTTTGGGACATTGTGCAACACTGCAAGGAATTGCAGCAACTTTCTCTTTCTGGCATCCTTACAGATCGTGTGTTTGAGTACATCTGGGTCCATGCTAAGAAGTTAGAGATGCTTTCCTTAGCTTTTGCGGGGGATAGCGATCTATGTTAATCTTTCACCCGCGTATACTTGCTTGAGCCTTGTGTAGTTGTAGTGCTGGTTATGACCCTTTGTTGAGCGACTTTGCAGCAATATCATTTTAAAGTTCACTACACGGCCTAGCTTTTGTGATGAAAGTTCGCTGGGTTTGTTATAGAGTAGTATCAATATCGTTTTAAATCAGTACCTTGACTAAGCTTTGAGCATATAAATGGGACTTCAGACGAAGTTAGACATAAAGGAGGTTTGGACAGCCAAAGGCAAATCCACGGAGTAATCTATGAATTCATGTGAATCCCTCAATTTCTGTCAAAATCCTATACATATGTGAATCTAATTGTTATTGATATTAACATGAGGTCGCCACAAATACTTGTAAACATCAAATCCTGGATTCCTCTTGCATACGGATAATACAGATGTAGTAATATGCAGTCTACTAGAAAATTAATGTGTATGTGAATGGAAAGAAAAAAAATAAAGAGAGAACGACAATGGCAAACAACATAGCATAGGAATAGTAGTTTGGTATACAAGATTAATGTTTATAATATGAACTTCAGATAGTTACTTCAATCTGGACAAATTAACAAATGATACGTGTACTTATAAAAATTATATTTTTTGTTAAAAGAAACTAAGAGGAATCTCATAACAGGATATTTTAATCATATACAATATCACCCAGCAAAGTTCAACCATAATGCTACTTAAATAAGGGGATATTCTTCTGGCCAAGGATCTGAAGCTCGCTCCCTCCTCTCATATCTTCAGCGTATTCCTTAATCTTGAGAGCAGAATCTTCAAGTTGAGGACTCTTTACAATTTTGATAACTTTCAATGAATAAATATCTCCAAAACTAGGTGGAATCTCCTCAAGCTTACGACATCCCTGCAGTTTTAACTTCTCAAGATTGGGGAAGGATTCCTCTCCAACCTCCCACTTGGAAAGAGTCGCTAGACGCAAGTTCAAAAATTTGAGATTCTCAAAGGTGTCTTCCTCCCCCATGTTCCATTCTTCTCCCTGGATGATTGCATCATAAAGGGACAACTCTTCAAGGTTGGGCAGTCTCGCTATTGTTGATAGTGAATCGGATGTCAGAGGAAAGTCATGCAATGACAGTTGTTTCAAATTTGAAGGAAAGTGAAAATCCCACGGCCGATTTGTCTTTACAGAGGACCCACTGTGGTTTGTGTTTGAACTTTTAAAACCTACATTGAGTATTTCTAGTTCAGTTAGGCAATCCAATTTCGGGAACCAATGTTGCTCTGTTGAATAATCCCATGACTCCTTGAGTTCAAACTGAAGCATCTGAAGATTGGGAAACCTTTTGAAAATATTCTTTGTATCTTTCGAATAGGAAATCAACAGTTCCCCTAATATTCTCAACTTCTCTAACTTTGTGTCCTCTGCTATCAATATTGATTCATCTGCATCCATATCAAAGAAAGAACAAGCATCCGCGAACAGCACTCGCAGCTTTACAAGATCCCAAATTCTTGGTAATAGTATCAAGGTTGATTCTTTGTTTTCAACCCACAATAATTCTAGATTCCAGAGGTTTGAGAAAGACAAAGGCAGATATTTAACTTGTGTCCCAATTCTTAAGTACCTCAAATGATTCAACATGCATATTTCATTCAGCAAAGAATCGTTCACCATGATAAAAGAGGTATCCAGGACCAACACTCTAAGAAGCCTCAAGTGTCTTAGGTGAAATGTATCAAAAAGACTGTCATCCAGCTCGTCTCCAAAAATCCTCAAAGAATAGATGTGTTTACCAGAATGCCTTTTCTTATTTGAATCAAAAATGACAAAATTAAGCCCAAAGTGCTCCTCATCATCATCATAATCAATGGTAATTTGACGAGGCAACAAATCTGTTGGAGCACTTGATCTTATCTGATCAAACAAATTTTCCTTTCTTGCTTTTATCAAACAAAAGTCATGCACAAGATCATGAATTTGGAAATTCAGTGCATCACCTATCTCATTGAAACAAATTACCAAGCTACTGGAAATTAAATCATCCATATAAATCTTCACCACTTCTTCCATACTGTTCATCTCCGCCTTTCCCACAAATCCTTCAGCACCCAAATAAACATTAAACTCATAGATTGTCAATGAAGTGTCCTTCGGAAAACTTGCAAAATACAGCAAGCATGGCTTGAGGTGATGTGGTAAATGGTCATAACTTAATTCTATAACTTTCATCACTTCCACTTCACTGTTCAAAATAAAAGAACTCAAACTACTTTGAACTTCAAGCCACACACTCCTTTTCTTTTCCCTCCCAGCAATGACTCCAGCAATCAGATCAGCCACCAAAGGAAGCCCTTTACAATTTTCGGCAATTTCTTTACCGACATCTAATAGTTCATCAGGGCAACTCTCGTCCCCAAATGCCCTTTTCTCTAATAATTCCCAACTTTCATCAGGTCTTAGCAATCGAAGGTCAAGAGGATCAGTGTAGAGCTTTCCATGCAAAGCTACTTCCTTTTCTCGAGTTGTCAAAATAATTCTACTTCCTTTCTTAGCTTCAGGAAAAGGTCTTGTCACCTCATCCCATGTAGTAGTCTCCCACACGTCATCTAAGACAATAAGATACCTCTTTCCATACAGTTGTTTCCGTAGCTTATCAGGAACATCAATATTCTCACTCAATTTTGAATCTGAGTCACTAACTTGATTGAAAATTTTATTCAACAACTTCTTCTCATCACATCCTTGGTCGACCGTGCACCATGCACGAAGGTCGAAATGGCTAGAAACTGACTTATCATTGTATACTTTGTATGCCAAAGTAGTTTTACCTGAACCCGGCATACCAGTGATCGAAATGACATCTAGATCTGCCGGTCCACTGGTGAGCTTTCTAAGTATCAAGTTCGTCTCCTCCTCAAAACCTACAATTATTTTATTAGTTGTCAATGACTTTCTCTCAACTGGTTTCTTGGGAGAGTTCACAGCGATTAGACCTCTGTCCTTGGGAATGCTCTCATCTAAAGCAGAGATCTCTTCTTTGATAAGTTTGATCTTCTTTATGGTAATGGGAAGTGAGAAAATAAGATGTAAGAGACCATTATCTCGAACAATAATTGAATCTATGACATCTTTTGCCTCATAAGCCACATCTAGGACACGTGCCCAGATATCTTTATACAATCCTTGCTCAGCATCCACAAAGAATGATCTTATGAATTCCAGGTCTTGTTTCACCAACTCGATTTCTTCCTTTATCAAAGAAATTGAATAAGCATTAGAATCTAGCAAATCATTTAAGTGCATGTGTAAAAGATGCATGAAGAGTGGTCCATCACTCATGGGGAAGCAACATTGAGATGAATCCGGGGCTTTCAGATAAACATGTTTGAGATCTTTCTTGAGGAGTTCAATATTTTCCAGCAAGTCTAGGGTTGCACAATTTGTTTGGTTATTACCCTCTTTATTCCTTAATTTCTCTTCCAAGTCACGTACAAGAGTTGATACCTCCCTGGTAAGTACTCCGACATGAGCCAAGAGATCAAAAAGTTTGTCATGATGAATAAAGTCCTTGGGCATATCAGAAAGAATAAGTAATAGGAATTCCATCATGACATGAATGTTTCGAGCCCCTGAAGTGCTAGGGCGAATAACAGTTATCATATGCTCTTGTAGTTGAATGATATATTCTCTGAGAATATCCGGTGAGGTTTCCAGGAGCTTCTTAATGAAGCGTCCAACTTCTGCTGAAGTTGAAGCTTTCAAATTTGTATAACATATGTGCATAACCTCCAGTTCAGTTGGAACAATCTTCAAGAGTAGATGTGTTAGCTGGAAGAGTCGAGAGTCTCTATCATTCTGATCATCCTCATCCGAGTCTTCATCAGTCTTATCCTCCCAAAGGAAGTGTCCTACTCTTTCAGCCATCAGTTGAAACAGAGGTAAGACATTCTCAACCATCTCATGCTTAATGCAACCATTCACTATCAACCCATGGAAATCTCTTAGGTTGCCACATACATTCTGAAGAACTTCATATTGAGTCACTCCAGGAAATATCTTTTCAGCGTGATGCTTGGATAGATGATACAGATTCAAGAGGAGGAAGTCCAATTGCTCATCCATCATGATGGCATCTGATTTATAAGAACGATGATACAAGCTGATACAGTCATCCATATTACTGGTGAGGCTAGTAAGGACATCATCATCCAAAAGTGATTGAAGCAGATTCTCAACCTGTTGTCTTTTTCTCGTCATTATATCTTCAAACTGCTCAAAATCGGAATAAGAAAGCTGAACATATGTACAAATAAATGCCATTTTCAATTTTAGATTTTCAACTTCATCTTTGTCAAGAGATTTTTGATTTTCCTCATTCTCTAGGAAAACCAGAACATCGGCAATGTCCTTGCTAAGAGCAGAAAATAACACCTGCCAAAATAATACATTTTAAAGCCACATATCTATAATTCAATACTTTACAGTTTACTCTATAAAATAACATACCAATGAGTTGTTTGCTTCTTCATTATCTTTTCGTTTTTCCATGATTCTACTTTTTCTCAAGACCTGATGAATAAAAAGTAGCTAAAACTTTAACAGGAGAAAGAAGATGAAAAGATACGAATAATCAATAATATCACTATTTTCACATATAGTAATTTTAGACTCGCACAATTGGAAATGTCAATCTTAATCACACATAAAAATGTTTATGACATGAAGTCACAAACATAAAATCTCACAACTGTTAATTATTTACAAAAAAAGAAAAAGGAGTCCTGCTCGTTTACCATTACTTTTCCAACCTATACAAAGAAGAAAGTTATCGACTTAATAATTATAAATATGTGATTGTCAATCTAATTATTATTGATATTAATATGACGTCGACATAGAAACTAGTAAATATCAAATCCTAGATTCGTCTATGTGTATATGGCATATAAGGAGCCTACAAGAAAATTATTGTGCGTGTGAATGTAAAGAAAATAAAATAAAGAGAGAATGAGAATGGTAAACATCATCAAATGTATCTGTCTAACTTTTTTCTGCCAAAAAGTCTATAAGGTAAAGGTAAAGAAAACAGTAATAGGAATGATGTTTTCGTGTATAAGATTAATGTTTAAAATATCAGCTTTAGATTTGGCATCAACCTCAGATAAAGTTGTGTATGATCAAGTAGAAATCTATACTTGACATCGGTGTGTCTCATGGACATACTCATATGTGATGACGTGCCAAACGGACAAATCAACAAATGATACATGTTTTAAAAAACTTGTAAGTTTTCTAATCGAAACACCGAAAAGTCAAACAAATATGTAATCATATACAGATCTACTCATTAAAGCATAACTTACTGTCTATTCTGCTATGTTTCTTCTTTCTACTTTCCACCCATAATGCTTAAAAGCTAGTTAAATAACGGGATATTATTCCCTTATTTTGATTAAAATTAAGTAAAATGTCATTAGATTAATAATCTCTCTAATAATATTATTTTTCTCCTATCTCGACTTGGGCTAATGGAAAAAGATTTTTTCTGAGAGTAGCTGAAGTAGAATCAATAGATTAAGCATGTTCACACCTTTTTGACATATTTTTGTTGAAGTAAGAGATCGAAGAAGTAGTTTGGTTGAAAGGAGACTAATCAAATAGCTAGATCTAGAATTCAAACAAAGATTACTAAAATACAATTCATTGACTTCACAAGTCCTTTAAATACCAAAAGTGCAAGATTACTAAAATACAAATGAGTAGTTTTTGTTGAAAGGAGAACAACAAAAAGCTAGATCTTAACCATTTTCATGTTATTCTGCTGCGAATAAAGTTTAGCAAAGAAGAAGATGGTACCTTTACACAGGCTGAAGTTTAGCTACAGAACCCTTTGTTTGAGAAATAATGCTGAACCTATTGGAGAAAAAAACAAGTGTAGTAGTTGAAATATACAATACAAATCTTTTTGTAATGAAATATTAAAATACAAACCCACTGACTTCTCAAGTCTTTTTTTAATCAATGTCTTTTGTCTTTCAATTTTTATACTGACGAAGATAAAAACAAGTGGTTGTCATTTCATCAAACACATTGTAGACATTGGCAATTTCCACATTATAGAATTTAGGGAAAAGGGTCAAATATGCCTTAAAATATTTAAAAAGGTCTAGATATACCTAAAGTTTGTTCATTGATGGGCTCGCCATTCAATTTTTGGTCCAAATATGCCCTTATGACCACGTTAGTTGTCATGTTGGACATATCCAACTCATTTTTCATTTCTTTAAATGTCACTTGGAATTGTCATGTCATTTTGGTCTTACCACATAACATTTATATGAAAATGGAAAGATATTTGGACTCATAAACACCTAATCCGACCCTTAAATAAACCTCCTTTTAAATAAATTATCCGGCTAATTTTCAACAATTTTGTTTAATTTTTATTTTTTCAATACATTCAAAAAATGAGTAATTGTTAATTAAAAAAATAGGAAAATATGAAAAAAGTATAAGATTAACGCCAAAAATTCATAAATAATTATAGTAACCTAAATTCAATTTAGACACTTTTTTTAAAAAAATCATTTTTTTCGATAAATCCCGAAATGAGTAATTGATTAATAAAAAGTATGAAAAGATATAAAATTAACGCCAAAAATTAAAAAATAAATACCGTAACCCAAAATTCAACAATTTCAACATTTTTTTAATTTTTAATTTTTTCGACAAATCCCAAAAATGAGTTTATTAACAAAAAAATATAAAAATTACACGAAAAAATCAGAAATAAAAAATAGGAAAATATGAAAAAAAATATAAAATAAAAAAAATGGTTGAAATTATTGAATTTAAGTTTACTATATTTAATTGTGAATTTTGACGTATATTTTTTATTTTGTTTTCATATTTTTCCCTTTTTATTAAAAAATTACTCATTTTCGGGATTTGCCGAAAAATATAAAAAATTTAAAAAAATTGTAGATTGAAATGTTACTATATTTATTTGTGAACTTTTGGCGTTAATTTATATTTTTTTCCATACTTTTGATAATTTTTATTAATTAATTACTCATTTTCGAGATTTATCAAAAAATAAAAAATTTAAAAAAAATTGAAATGTTAGATTTAATGTTACTATATTTATTTGTGAATTTTTGGCATTAATTTTATATTTTTCATATTTTTTCTATTTTTTATTAATCAATTACTCATTTTCGGGATTTACCGCAATAATAAAAATTAAACAAAATAGTTAAAATTGGTTCAGATAGTGAATTTAAAAGGAGTTGATTTATGGGTCGGATTAGGTGTTTATGAGTCCGAATATCTTTCCATTTTCATATAAATGTTATGTGGTAAGGTCAAAATGACATGACAATTCCATGTGGCACTTAAAGAAATGAAAAATGAGTTGGATGTGTTCAACATGACAACTAACGCCCATAAGGACATATTTGGACCAAAAGTTGGACGGCGAGGGCATGAGTGAACCAAACTTTAAAAGGAGGATATATCTAGACCTTTTCAAATTGTTTAGGAGCATATTTGACCCTTTTCCCTAGAATTTAATATAGAATATCAAAATATGAATTCTTGAAATTGAGTATAATAATTATTTTCTTTACAATGAATATATGTACTATATGTGTATATGTTCAATATAATCGAAGAAAATTTTGCAGAAAAATAAACAACAGAGTTTAAAATATGTACTCAAAAACAATAATTAATATCATAAGTATAAATTAATGAGGAAAAAAAAACATACCGCGATATGAAAAAATAGAATGAAAAAAATTGAGAAAAAACAGTGTTGTCAGTCAGCGGCAGATCTATCAAGGCCCGTGAGGGTGCCACACAACCCACGAACTTCGAAGGAAACTCTATTTATATTTATATACAACATATGTATAAATAATAATAGTGCCACTTAGAGAACAAAAGTATTCTTTGGTGTAGTGGTAGACTATCAAGTTTACAAGCCATAGTCCAAGGGATCAACCCTATTGACAGCGCTTTTTTGTTTTATATTTTTCTTTTTAACCACATGCAGTGTTTCTTTTTTAAACTACAAGGCACATTCTCTTTTGATTTTGATTTTTTTTATTAACTTCTTATTAAGTATTAATCAATAATTATTTTTAACTAATTTAATTTAACTTTTTGATTTTTCTTTTATATGATTAAATATAATAAGAAAATTCTATTCACCGTTGAATTCTCCTTTTAACTTTGGAACAACAAAAGTTGTCGTTAATTAAAGCTTCAGGCTTTCATCCGTCGCTCAATCCTGCTCTCCTGTCCAGCCACAAGACGAATAATTCTATCTGAATCTAATATTGATTTTATCGATGAGTCTACTAAGCATTAGAGACAATTTAAAATTTGAAGATTTTGATGCACCAATACTATTTTAATTGAGATAGTTAACAAAATTTTTACTACAATTAACGAATAATGTAGTACTTGATTGGTTACTAATGGCTCGAATATGATTTATAAGCTAAACTTAAAATAAAAAATAATGAAATACGATTGAACTGTATTCTCGCGAGTGGTTCCTCTGGCTTGTAAACCAACTAAACAAGGGCACCTCTACGCTTCTTATGGGTGCACTGTTGATTATATCCTACTTTATGTCAGTATCTCACGATAGATATACATATATACATGTAATTTTTTTGAAGTTAACGGATGCACGTGCACCCCTATCAAATCATGTGGGTTCGGCTCTGGTTGGCACCCAGTGGCTATAATTCCTAAATTCGCCTCTGCTGTCAGTAAGTCATTCAACAGTAGCAAAGTACATAAATATTTAATTTTGCAGAAATAAAAGAAAAAGATCATAATTGTTTTTTGTTTTAAAATGAGGGTGTGTTTAGTATGAAGGAAAACATTTTTCGAAAAATATTTTCCAATTTTCTCATATTTGGTTGGGTCAAATATTTTCCAAATCAAATCATTTTCCTCAAATTTATGGAAAATGACCTCCATTCCAAACTTAAGGAAAACATTTTCCAAAACTCTTTTCTAACCTCCCCCTACCCACGCCATTCTACCAGTCCCCAACCCACCCCCTTCCAGCCCTCTACCCACCCACCCATACCCCTAAAAAGTTTAAGTTTAGTTTTTTAAAAATATTTTTAACATCACAATTTCATTTTTTTTTTCACCCCTACCCTCGACCCCCTACCACCCCCATCCCCAAAAAATAATTTAAGTTTGTTTTTAAAAAAATATTTGTAACTTCAAAAATTCATTTTTTTACCCCTACCCTCGACTTACCCTCTCCCTACCAGCCCCCCCCCCCCCAAAAAAAAATAAGTTTGTTTTTAAAAAATATTTTAAACTTCAAAAAAAAAAATTCACTCCTACCCTCGACCCCGCACCCCACTCCACTAGCCCCCTACAAGCCCACCCCCACCACGAAAAAAATTTTAAGTTTGTTTTTTTTAAAAAATAAATTCAACTTCGAAAATTATTTCCTACTCTAGTAAAAAATAAAAGACATTTCTCAAAAGTATTTTTCATTAAAAAACAAGCACTAAAATATTTTTCCAGAAAATATTATCTACTCACCTACCAAATATGAGAAAATCAGTAAATTATCTACTTGTTTTCCAGGAAAATATTTTCCAAGGAATTTCCGTCATACCAAACACACCCAAGAGTATATTCCTCTATTTATAGACAACAAAGGGTAGTGTCAACAAATTTTTATTGTGCCTTATTAGAAAGGATACAACTATTTGAAAAAATTGCAACCCTTCGGAAAGTTTACAACGTTTCATAAAAGTCGCAACTCTTCATAAAAGTCGCAACTCTTCATTAAAGTCACAACTTATTATAAAAGTCACAACTTTTCATAAAAGTCACAACTTTTGATAAAAGTCGCAACTTTTCATAAAAGACAGATTTTTTCTTCAAAGAGGAAGGCTCGTTTTAGAAATAAATAAATTTAAAAGAAAATTATTGCTTGTGGCGGCGCTACATAGGTGGTCCTAGGATTCTCTTTTATATAAATATATGAATTTTTTTATTAACGTGGTGTTCGGACCAACTTTCACACTTTGATCTGCTGAAATTTGAACCTAAAACCAAATGGTTCTCATTTCTCAGTCACTTCATGGACCATTAGGTCACACTGTTAGGTGCCCAGATATATTCATGTCCAAACATCCCTTGGCCAATTTCCATATACCATTATTCAACCTTGTATTATTAGTTTATTCTAATTTCACATTTTTAATGTTCAAACGCCCACTTATATTCTGCCTGTTTATATCAAAAAATTCCAACAGATTTGAATTCATGGCATACACTTGATATTTTCTCAAAAGTAAATACTTAATAGGGATAACGCACAAGTACCTCCTCAAACTATGACCGAAATCGCAGAGTCACACTTATACTATACTAAGGTCCTATTACCTCCTAAACTTATTTTATAAATAATTTTCTACCCATTTTCGACCTACGTAGCACTATCTTTTTGGCCCAGCGTGACATTTTTTTCTCAAACTGAAATTAAAATTTAAACTATTTTCTTTTAAAAAAAAATAATTTGAAGTTTTGATTTTTTTGGTTGGGGTGAGGTTTATCAGTTCTTGCAAAAGGCTTAGAATTATCAAAGGATCTGAAGCTAAAGGTTTAGCAAGTCTATAAAAACATGGACATATATATATATACACACATATATACAAATCTGATAGGAATGAACAAGTTTGAACAAGTTTCAGTTTTGTAAACTATCTTGATTTTCGATTAATTACACGGGATATATAGATCTAGATCTCATGTACAAATAGTTTATCTTTCTTTTTTTTGAAGAATTTTCTTGTGTATTATGTATGAGTATAAATATACGGGAAGAAATACAAAATTTTAGCACAATATGAAGTGTCTAATCAATCTTGATATTTAAGCACCCAAATTCAATATTTCGCTTTGATAGGTTCATAATCAAGAATCAAAATAATAATAGAGATTAAAATAAACTTCATTGACTTTTCAAGTCTTTTTCATCAATTTTGTAAATATGTATATTCATATTACAAGTCGACTTAGACTTGTGGAGATTGTTAATTAGCTTGTGAATGAAGATGATGTGTGTTGTGTCCATGTAGATCATGGATTTGAGAAGATCTAATATTTTTTTGGTAGTAAAACTTAACTAGTGAACTTAGCCGCGCTTCGCACGATCATAAATAACTCGCTTAATTTGTCAAAAAAAAGAATTAAAATAGTATTGATAAAAGTTTTGTGAAGGTTCTTTGTTGTGTTTAATTGAAATATATCATATTTGAAATCTTAATCAAGTTTAAATACTATTTAAGTTTTTGTATCCGTTTTAATTTTAAATCGCTTAAGCTAAAAGTTCACATTCAATGATCTCAGCCTATAATTTTATTGGATATGTGTAGCCCATGCTTTTATAATTTTATACAACTTTTTTAAAATCTATCTTTTATTTTTAGTATGTTTTTTGTTTTGTTTGTATCTTTCTCGCAAAATTGAAGAATTTAAACCCAAATAAACTTGTAAATTTTGAAAGCTCAAAACATCAAAATGTCATTATCCTCCTTGTTCATCAAATCAAAATAATTTTTAAATATTTATTGTGGTTCAAGAAAATCAATTATATTTTTATAAAATTACTCTTTTTCCTCCAAACATCGTAGTCTCTTACTATTTTCTTTTTAATGTTTATATTCTTCAAAAGTTGTTATCCTTTCGTCGATAATGATGAATCAACTCTCTTTTCATCTTTCACAAGTCATAAACTAATTTTTACTACAATGTAATATACTTATAAATTTATATATAAAAAAATATATTGAGAGACATAGAACCTCAATTACACAAAAAATGTAAAGTATTTGGAGAAATTAATTATTTGAAACAATCTCTTAAATGCATATAACAAATTTGAGAAATTCTTTTTAAACAAACTTTATCAAAATCCCATTGCAAGAAAGTTGAGTCTTTTTTATACCTTTTTTTTTTTTTTTGAAAAAAAAAGCTTATCTTGTAGCATATGCATACAAATTATATTATTTATTTTGAGATAAAAAAAATCAAATTTTATTGACTTGTCACGTGCATTTAAAGCATGAAGCTAATCATACTTTATCAATTTCCTTTTATTTTTCAAGGGAAAAGGGTCTGATTTACCCCTCAATTTTGTCATTTGGAGCTGATATACCCCTCGTTATAAAAGTGGTTTATATATGCCCTTACCGTTATTCAAACGGCTCACATATACCCCTGCCGTTACAAAATGGCTCACATATACCCTTCATTTAACGAAAGTTAAAAAATTAGTTTTAAATTTATATTTATTACTTGTAATTTTTTTTAAAAAATTATTTAGGGGTATATATGATTCTTCTATCAAAGTTCAAGGTATATTTTAATTTTTTTTCATACATAAATTATTTTTTGACTTCGCTTATTATAATTATTTGAGTTTCTTATTCTTATTTTGTTTTTTTCTTTCATTACTTAGTTTAAAGAAAAAAATTTAAACAATTTTTTTGTGTATTGTAATTTAATTTCGTATTCGAAGAAAAAATTTGGTCTACAATAAGTTTTACAAGAATATTAGTGAAACATAAACAAATTTGATTATCAAAATTATAATTATAAATTAGTCATTGAAACAAAAAAAATAAAAAAAAATATGTTTTACGAGGATTAAATTTACTCATATTAGATTATATATTTTATAAAATAAAAATAAAAATTTAGATTAAAATTATTTTTTTCATTTCCGTTAGAGGAAAAGGGTATATGTGAGCTATTTGTTTACAAGTAGGGGTATATATGAGTCACTTTCATAACAAGGGGTATATCAGCTCTAAATAACAAAGTTGAGAGGTATATCAAACATTTTTCCCTTTTTTCAATTTGTAAATTAAATATGAATTTAGTATGTCATGATTATTTCTATTAAATTAAGATATTATCTTGACAAACAAAATGTGAGATTACTATTTTTGAATTAATATTATAACCATAAATTTTATAACATTTTGAAAGAGTAGAGAATAGTAACAAAATTTGCATATGTTAATAATGACAGTGTGTTCATCAAACTTGAACTTAAATCTCAAATATTGTCATTTGTTCATTTTATCTTTCACCGTAAACAATAAAAATAATTCACATAAAAAATGAAGAATAAAAAGAATGAAAAAATCACCAACAATAATGAAGAAAATAACACAGACAAGAAAATAGAAGGAAAAACACTATAAATAAGAGACATCAACAAAACTAAAATAAAACAAATAATCTTATCTATTTTGTTTAAATTTTGAATTTGAATTCTCACAAACAACATAGGTATATGCTCATCCTATCTTTCATACAATAAACCAAAAAAAACTAATCACATATAATATAACATTATAAAATTAGGCATAACAAAGTGATGTACTTAAGTGTAAATATAATCAAGAAAAAAATAATTTCTTACCATTGATGAGGATGATATACTTTAGTATTTATAGTAATCAGTAAATTTGTAACTTAATTAAATAATATGAATTAAAAAAATAATATAGTAATAAATAAAATTGTAACTTATATTGATATTAATTGTTTTAATTATAATATAATAATATTTTTAAGAAGGAATAAAGAAAGGTTTAGGAAAAGGTGATAAATGGTAATGGTAGTGGGCTTAGTTTTTAAGTAACTGTTGGGCTGCAAGATTAATTACTCTTATTTACTGTGATATTTTAACTCATTTAGACATTTATACATTTTTAAGGGGGAAAAAGTCAGAATTTTTTTTTTTAAAAAAAGAAAAAACATATAACTGCAAATGCTGATCATTGGAGGGTGCCACATCAATAATTTTAGATTTAGCTTTATATTATTATATAGATTTCGCTCCCTTTATTGAAAACGTAAAATGTTAAATATTTTTTTATTCTTAATAAAGATTTTTAAATTTGAACCTTAATATATTAAATCATCTTTATTAGAAAAAACTTACTTCCAATTATAAAATCTCAAACACACAAAAAATGATAATTGAATGTTAATATATTTATCAAACATCGAGCGAGAAATGAAAAAAGAAGAAGGGAAGTATAGGTGCATTACTTAGAAAACGACCATTCACTAATGCTACAACCCCACAATGTGTAAATTGATTTGAACTATTGCTTTCAACTTCACTTTTTTAGTTTTTTTTTTCTTTACAAGAATAACAATTAAATCAAATGATTTGGTTTGAAAACAACACCAATTTTTTGAAAAGTATTCAGAAAATTATTTTTTCAACATTTAAACAAAATTTTAACTACTTTTTACTATATTCCAAAACGTCTCGTTAAAAAAGGAATATAAAATCTCAATCAGGTTAATTAATACAATAAGATTTTTGTATTTTTAGCTATAGTCATAGATGAATTTAAAATCATTTTAAAAAATTAAGTTATGAAAAATTATTCTATATATATATTAAAAAAGTTCTTACTAGAATTATTGAAAACTTTTAAGACCGTAAATCGTAATCAATCATCTAACTAGCTTTTATCCGTAATATTCGAATAATTTTCTTCGCTTTTCCAAGAGGAATATATGTTGTTTTATGTTAAAAAAACTTCTACATAAGATTATTATTATTTAGGGTTAATTATATATAGTGTGTGCATTAACAATGTCACAAACTCTCAATATTACAAAAAAAAATTAGAAATATAAATCCACGCAATTGTATAAAAAGGGGTTAATCAATATCCTAAAATAATAATAATGTAATAGCATTAACGTATGTTAATATGTTATATTACGAAATTCAAAAATATGTGAACTTTAAATAATATTGTCATCATTGTATGAAAGATTCACAATTTATATCACTTTTGTATAATTTATTTTTTTTAAAAAAAATTGATTGAATTAACCCTCTAATAGTAATAATAATAACAATAATTATACAAATTAGTATTTTAATTATGTCTATCTTAAATCATTTCAAATTATAATGTGTAATTGATTACTTTTTAAATCATTAGATTCCCTAAATTTCTAAAGCCAAAATCCATTACTTTTCGTCTCGTTATATTTATCGGACACGTGTCTATTCATATACAATGACATAATTGTCCCCACATAAAAAAAGTAACCCAAACACTTGACTCATCTTAACCATGGTTTCATTTTAACCCAACACATTTCCACCTCTTTTTGTTTTTTATAATATAAAAAATCGTTTGATAGCAGAAATATAAGTATTAAATTTTACATAAGTAATACCGTATTTAATAGTTGATTGAAAAAAAAGAGCTATTCATAAGAAAGTTTTAATCTTTTCATCTGGGGTTTAATACCTGTATTTGCTTGTAATTGAGGAAATGGTAGGTTTTGTAGAGCATTATTGCTTGAGTTCTTTAGTATTTACTGGTGAAAAAGAGTTCAAATCTTTGCACTGTTGTCTAAGTACTTTAGCCGTTGCCGGTGACTTCATTAAACTGATTTGATAGAACAGAAGGTTTTGTGGAACATTGGTGTCTGAGTACTTCAGCCCTTACTGGTTGGGATGAGTTTTAATCTATGCATCTGAGGAACTTTTCTTGCTTGTAATTGAAGCAGTGGGTTTTGTGGAGCATTATTGTGTGAGTACTTTAGTCTTTCTGGTGAGAAAAGTTCTAATCTTTGCATCTGGGGTTTGAATGTTTCTTGTTAGTAATTGAGGGTTTGAGGAAGTAGTAGGTTCTGTGAAGCATTCTCGTCTGAGTACTTTAGCCCTCCCACATTGTGTGAACAATCTCTTCTCATCGAGCATGCGTTTCCCCATCAGCTGAAGCAACACTGTTAATCTTTATCTCTGGTTGGTCGCTGATATTAAAGTTGGGGTTGTTATAACCAAAAAATCAGGGTACATTTGAAAATAAAATATAATTCAACATTCGAAAGCGGGTTATAAGTTGTTTTCCAAATTTGATTTACAACTTCGAACTTTTCGTACACAAACACTGGTTTTCGAATAAAGTGGACATTATATCAGAAAAAAAGTAAATAATATTTATGGGTCCTTAATTAAGTCTTTCAGTTCATTCCTCTGTTTTGCTTGATTGATGGTATTTCACAGTAGTTGGTGGCCATAGAGAAGAAATGCCTTAGTACTTTGAATCGCTTACTGGGTAAAGAAGCAAAAGCATATAGTGTATGACTTGGCTACAACAAACGAAAGGGATGTAAGAGGGCACAATTTCGTCCACCTTTAGAAACTAAGCATAAACTGAATCTAATTAAATTTTTGTTTTGATATGTGCACTTTACTAGCAATGTTGCACAGAAAGTGTGAACTACTGGTTCGGTGTTATAAGTAGTTCAATGATTTGAATTATTGAAAGGGTTGAATATCTTGTAACATGGTTATCAAATTAATGTTGCATTTTTATCTCTTTCCATTTGATTTATCACAACTCCTCTTATATTTGGACCTTCTTTTGCTGCTATTCTTGTTTAGCGCTGGGAATAAAAACTATAGAAGCAATGTAACTCGTTTTTTGCTGCAGGAACCTGAGAGAACTGGAACTGGGAGAAAGTGAAGCAGAAGACCTGAGTGGCCATTGGCTTAGTCATTTTTCTGATAGTTGTACATCGCTTGTGTCACTTAACATTGCTTGTTTGGCTTCTGAGGTCAGCTTCTCAGCTTTGGAGCGTCTAGTTGCTCGCTCTTCTCATTTTAGGACTCTTCGGCTCAATCGTGCTGTTCCCATTGAGAAACTTCCAAAGCTACTTCGTCATGCTTCGAAGTTGGTTGAATTTGGTACATGATCCTACTCTGCTGACATGCAGGCTGATGTTTCTGAAGTTTTCGTAAATGTATCTCAAGCATTTTCAGGCTGTAATCAACTTAAAGGCTTGAGTGGGTTTTGGGATGCTGTGCCAGCCTACTTTCCAACTATTTATCCAGTCTACTCCAAACTCACCTCTTTGAATTTAAGCTATGCTACCATTCAAATAGCTGATCTTTGCAAGCTCATTGGCAATTGTTTCAATTTGCAGCGGTTGTGGGTAGGTTCTAGCTTGTGTTTTACTTTTGTATACTTATCGAGTGTTTTCAATAGTCATGGCTCAATACATTAACTGTGTTTGTGATAAAATAGATAAATTGATTGATAGTTGTAAACACACAAATTTCCAAGAGAAGAACAATAATCCTAACTTAGTAATTGTCTTGCTAATTTTGATAATGCCAGGGATAAATAAACAACGTAATGAACTTCAGTGTTTACTTAGATAACATAGCTAAACAATTAATTTCGAGTGAACTCTTTGAATAATTTGCTGGTCTGTCATACAAAGAATAAGTTAATGTTGAATCCTAGTGTTGCACGAATCCTACACTTTGACAATTCATGTATATCTTTCCGGGTTAGACGCTTCCATTAGTTTTTAGGCTTTTCTTGTCCAGTGGATCTGCTGCATAATTAGTTATCCAGCTTACGCTTTAAGGCACTTGGAATGGATGTGATTGCAGGTTCTAGACTACATTGAAGATAGCGGTCTTGAGGAGATTGCCAACACTTGTAAGGAACTTCAAGAGCTTAGGGTGTTTCCTTTTGATCCATTTGCTCCAGGACCTAATGTATCCTTGACAGAGCAAGGCCTTGTAGCTGTCTCAATGGGCTGCCCTAAGCTTTAGTCAGTTTTATACTTCTGCCGCCAAATGACAAATGACGCCTTAGTTACTATTGCAAGGAACCGTCCTAACATGATCCGATTTCGTTTGTGTATTATCGAGCCTCAAACTCCTGACTACTTAATCCTTGAACCACTTGATGCTGGTTTTGGGGTCATTGTGTAACACTGCAAAAAATTGCAGCGACTTTCTCTTTCTGGCCTCCTTACAGATCGTGTGTTTGAGTAAATCGGGGTCCATGCTAAGAAGTTAGATATGCTTTCCTTAGCTTTTGCAGGAGATAGTGATCTAGGCCTCCTATATGTTCTCTCTGGTTGTGAGAGCCTCCGTAAGTTGGAGATTAGAGACTGCCCTTTTGGCGATGAGGCTCTGTTGGCTAATGCTGCAAAGCTGGAGAGTGGAGACCATGCGATCCCTTTGGATGTCTAATTGTTCAGTAAGTTTTAAAGCATGTAAGCTGCTAGCCCAGAAGTTGCCAGGCTTAATGTTGAAGTTATAAACGAGAGGGGTCATCCGGATACGAGACCAGAAAGTTGCTCTATTGAGAAACTTTATATACACAAGACAGTGTCAGGAAGGAGGTTCGACACTCCTGGTTTTGTTTGGACTAGGCTCCGGGCACGTGTATTCCAAATAAAAATCAATAAAAAAAATAAATGAAAACGTATATAATAAACTATTAGGAGAATTATGATGTTTTTTTCGAGTGTTCTCTCGATATTTTCGATCTACTGCACATTAGATAAGTCTCCAAAGCTTACCCATTTATAAGCAATTAAATGTACAGACAGTCATCAACAAGTAAAAATTCTAAGAAAGACACATCAAGTTAAAGAATTAAAAAGGGAAAATGCGACGTTATTTAAAGTCATCTTGTATCCTTAATGTGTGTCGTTACAAATGTAACTACTTCCTTAAAAACTTTCAGATTTACTCAGACTTACATTTACAGGCTTACAACTACTATCCATCACTGTTAGAGAAGACTTGGAGTCGCTACATTTATTGAAGAAAATGTGATATATTTTGCTAGCAAACAGCTGCAATTTCAATTTATTATTAATAGTTTAAAAGTTTAAACATGGTTTCTTTTCTGTGGGAAGCTTGCATAGAGAGTTTTAAAGAGAGTTGATCATCATTCAGTATCAAACCATATTGTACAACAACATTCAATTTTTGATATGTGTGGTTATACCTTTCAAGCTATTTATTTTACCTATTAAAAAAATTAGAAAGTTAGCAAATCAAACGGAAAAATCTAGACTTAATAAGATTGTACCTGAAAATTAGAAGACATTTTTGTACCCACTTAACAATGGAAGCTTGTGTTGAATGACTAATATTGAGTATGTTTATGTAGTGTAGTCTTGGAGATTTGTTGATAAAAACTCTTTGATATTCCTCAATTACTTAATTTGATCCTTTTCAACTTCTCATAATTAGCAAAATACGTTTCAACTTCTATATTAATTGAAACTTTATTCGTGTTCATCCTATTTGGTTGTTTCACACATAGTAATTGAATAGACTGTTGAACTTCTTATTTTGTTCCTTTATTATGTAATTCAATATTACTATTTAATTAGATATTTAATTTATATTTGGGAAAAGTATTTTATTACTTTTTAATTTAGTATAGGGGCAAAGTAATAATTCAACTTTACACTTTAGAGCTTCATGCTTATAATAATATATGATTATTGATGAAGATGCAACATCGACTCCATATAGCAATGGGGATTGCTCTTTGGCTTCTTCTTAGGAAGACTTCAGGTATTAGTTCTATGCTGATCTTTCACCTGCATTTACTTGCTTGAGCCTTGTGTAGTTGCAGTGCTGGTTATGGTGGCAGTGAAGCGCATGTGCCATTGATTTGACCCTTTGTTGAGTGACTTTGCAACAATTAATTACAAATAATGAGTTTAAACTCTTGTTGTTGTGCTATATCACTAAGGATAACTATTGTATTTTCAACTCTTATTGTTTTTTCTGTTGAAATGATGCTGTCAATGTACTTGTTGTCCTGTATTGTTGTAATTCTCCTTGAAGATAAATGGGAACCTTTCATTCATTTGAGTGCTGAAATCCGATTTAATTTGTTGAACGTTTAGAAGAAGGTATTTTATTGTTCTAGTACGAGTCAGCCTGATAAACAAACACTTACATAGGTATGATGACTGTTCATTTTCTCAATTTTATACCTACTCGTGCAAATCCAAAGTTAAAAGGTCATGTTTATGTATTATGCCAAATCTATACTCACATGTGTGCTTGCGATAAAAGAAATAGACAAATCAACAAATGATACGTGCATTTATAAAAATTATAATTTTTGTTGAAGAAACTTTGAGAAATCCACAAAAATATTTCATAACTGCAACAAAGTTTTCTTAATCATATACAATGTACCCTGCAAAGTACAATCTACTTTTCAACCATAATGCTACTTAAATAAGGGGATATTCTTCTGGCCAAGGATCTGAAGCTCGCTCCCTCCTCTCATTTCTTCAGCGTATTCCTTAATCTTGAGAGCAGAATCTTCAAGTTGAGGACTCTTTACAATTTTGATAAATTTCAATGAATAAATATCTCCAAAACTAGGTGGAATCTCCTCAAACTTACCACATTCCTGCAGTTTTAATTTCTCAAGATTGGGGAAGGATTCCTCTCCAACCTCCCACTTGGAAAGAGTCGGTAGACGCAAGTTCAAAAATTTGAGATTCTCAAAGGTGTCTTCCTCCCCCATGTTCCATTCTTCTCCATGGATGATTGCATCACAAAGGGACAACCCTTCAAGGTTGGGCAGTCTAGCTATTGTTGACAGTGAATCGGATGTCAGAGGAAAGTCACGCCATGACAGTTCTTTCAAATTTGAAGGGAAGTGGAAATCCCACGGCCGATTTGTCGCTACAGAGGACCCAATGTGGTTTGTGTTTGAACTTTTAAAACCTACACTGAGTATTTCTAGTTCAGTTAGGCAATCCAATTTCGGGAACCAATATTGCTCTGTTGAATAATCCCATGACTCCTTGAGAACAAATTCAAGCACTTTAAGATTGGGAAACCTTTTGAAAATATTCTTTGTATCTTTCGAATAGGAAATCAACAGTTCCCTTAGTATTCTCAAGTTCTCTAACTTTGTGTCCTCTGCTATCAATATTGATTCATCTGCATCCATATCAAAGAAAGAACAAGCATCCGCGGACAGCACTCGTAGCTTTACAAGATCCAAAATTCTTGGTAACAGTATCAAGGTTGATCCTTTGTTAGACACAAACAGACTTTCTAGATTCCAGAGGTTTGAGAAAGACAAAGGCAGATATTTAACTTGTGTCCGAATTCTTAAGTACCTCAAATGATTCAACATGCATATTTCATTCAGCAAAGAATCATTCACCATGATTAAAGAGGATTCCAGGTCCAACACTCTAAGAAGCCTCAAGTGTCTTAGGTGAAATGTATCAAAAAGACTGTCATCATAATCAATGGTAATTTTACGTGGCAATAAATCTGATGGAGCACTTGATCTTATCCGATCAAACAACTTTTCCTTTCTTGCTTTTATCAAACAAAAGTCATGCACAAGATCATGAACTTGGCAACTCGGTTCATCACCTATCTCATTCAAAAGAATTACCAAGCTACTGGAAATTAAATCATCCATACAAATCTTCAGCACTTCTTCCATACTCTTCATCTCCGTCTTCCCCACAAATCCTTCAGCACCCAAAAAAAACATTCAACAAATAGATTGTCAATGGAGTGTCCTTCGGCAAACTTACAAAGTGAAGCAAGCATGGCTTGAGGTGATGTGGTAAATGGTCATAACTTAATTCTATAACTTTCATCACTTCCACTTCACTGTTCAAAATAAAAGAACTCAAACTATTTTGAACTTCAAGCCACACACTCTTTTTCTTTTCCCTCCCAGCAATGACTCCAGCAATCAGATCAGCCACCAAAGGAAGCCCTTTACAATTTTTGGCTATTTCTTTACCGACATCTAATAGTTCATCAGGGCAACTCTCGTTCCCAAATGCCCTTTTCTCTAATAGTTCCCAACTTTCATCTGGTCTTAGCAATCGAAGGTCAAGAGGATCAGTGTTCAGCTTTCCATGCAAAGGCACTTCCTTTTCTCGAGTTGTCAAAATAATCCTACTTCCTTTCTTAGCTTCAAGAAAAGGTCTTGTTAACTCATCCCATGTAGTAGTATCCCACACGTCATCTAAGACAATAAGATACCTCTTTCCATACAGTTTTTTCCGTAGCTTATCAGGAACATCAATATTCTCACTCAATTTTGAATCTGAGTCACTAACTTGATTGACAATTTTATTCAACAACTTCTTCTCATCATATCCTTGGTCGACCGTGCACCATGCACGAAGGTTGAAATGGCTAGAAACTGACTTATCACTGTATACTTTGTATGCCAAAGTAGTTTTACCTGAACCCGGCATACCAGTGATCGAAATGACATCTAGATCTGCCGGTCCACTGGTGAGCTTTCTAAGTATCAAGTTTGTCTCCTCCTCAAAACCTACAATTATTTTATCAGTTGTCAATGACTTTCTCTCAACTGGTTTCTTGGGAGAGTTCACAACGATTAGACCTCTGTCCTTGGGAATGTTCTCATCTAAAGCAGAGATCTCTTCTTTGATAAGTTTGATCTTCTTTATGGTAATGGGAAGTGAGAAAATAAGATGTAAGAGACCATTATCTCGAACAATAATTGAATCTATGACATCTTTTGCCTCATAAGCCACATCTAGAACACGTGCCCAGATATCTTTATACAATCCTTGCTCAGCATCCACAAAGAATGATCTTATGAATTCCAGGTCTTGTCTCACCAACTCGATTTCTTCCTTTATCAAAGAAATTGAATAAGCATTAGATTCTAGCAAATCATTTAAGTGCATGTGTAGAAGATGCATGAAGAGTGGTCCATCACTCATGGGGGAGCAACATTGAGATGAATCCGGGGCTTTCAGATAAACATGTTTGAGATCTTTCTTGAGGAGTTCAATATTTTCCAGCAAGTCTAGGGTTACACAATTTGTTTGGTTATTACCCTCTTTATTCCTTAATTTCTCTTCCAAGTCACATACAAGAGTTGATACCTCCCTGGTAAGTACTTCAACATGAGCCAAGAGATCAAAAAGTTTGTCATGATGAATAAAGTCCTTGGGCATATTCAGAAAGAATAAGTAATAGGAATTCCATCATGACATGAATGTTTAGAGCCCCTGAAGTGCTAGGGGGAATAACAGTTATCATATGCTCTTGTAGTTGAATGATATATTCTCTGAGAATATCCGGTGAGGGTTCTAGGAGCTTCTTAATGAAGCGTCCAACTTCTGCTGAAGTTGAAGCTTTCAAATTTGTATAACATATGTGCATAACCTCCAGTTCAGTTGGAACAATCTTCAAGAGTAGCTTGAAGAGTCGAGAGTCTCTATCATTCTGATCATCCTCATCTAGCTCGGAGAGCCGAGAGTCTTCATCAGTCTGATCCTCCCAAAGGAAGTGTCCTACTCTTTCAGCCATCAGTTGAAACAGAGGTAAGACATTCTCAACCGTCTCATGCTTAATGCAACCATTCACTATCAACCCATGGAAGTCTCTTATGTTGCCACATACATTCTGAAGAACTTCATATTGAGTCACTTCAGGAAATATCTTTTCAGCGTGATGCTTGGATAGATGAAACAGATTCAAGAGGAGGAAGTCCAATTGCTCATCCATCATGGTGGCATCTGATTTATAAGAACGATGATACAAGCTGATACAATCATCCATATTACTGGTGAGGCTAGTAAGGACATCATCATCCAAAAGTGGTT
->URS00015E57C9 rRNA from 1 species 
-CCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGACGAGAGTCTGAACCAGCCAAGCCGCGTGAAGGAAGACTGCCCTATGGGTTGTAAACTTCTTTTATATGGGAATAAAACGGTCTACGTGTGTGAATTTGAAAGTACTGTACGAATAAGGATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATCCGAGCGTTATCCGGATTTATTGGGTTTAAAGGGTGCGTAGGCGGAATGTTAAGTGAGGTGTGAAAGGTGCGGGCTTAACCGGGGAATTGCATTTGAAACTGGCGATCTTGAGTGCAGGAGAGGTAGGCGGAATGTGTGGTGTAGCGGTGAAATGCTTAGATATCACGCAGAACACCGATTGCGAAGGCAGCTCACT
->URS0000C6D546 snRNA from 2 species 
-AGCCATGTGGTGAGCACAAAGCGAACTATTCTTTCGCCTTTTACTAAAGAATACCGTGTGCTCTCCACGCTAAGTGGCATACGCCTATTTTTGTAGGGTCTTGCTTTTAAGCGAGC
->URS0000C3F3E8 tRNA from 1 species 
-GACGTCGTGCCGGAGTGGTTAACGGGTGCGCCTGCTACTTTTAGCATGTCAGTGTATAGGCTCTGCCTGCGTGAGTTCGAATCTCATCGACGTCG
->URS0000B1CE7F rRNA from 1 species 
-TGGGGAATCTTGGACAATGGGGGCAACCCTGATCCAGCGATGCCGCGTGAGTGATGAAGGCCTTCGGGTTGTAAAACTCTTTCACCTGCGAAGATAATGACGGTAGCAGGATAAGAAGCACCGGCAAACTCTGTGCCAGCAGCCGCGGTAAGACAGAGGGTGCTAGCGTTGTTCGGAATGACTGGGCGTAAAGGGCGCGTAGGCGGCCAATCAAGTCAGATGTGAAAGCCCCGGGCTTAACCTGGGATGTGCATTTGATACTGGTTGGCTGGAGTACGAGAGAGGAAAGTGGAATTCCTAGTGTAGAGGTGAAATTCGTAGATATTAGGAGGAACACCAGAGGCGAAGGCGGCTTTCTGGCTCGTAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAA
->URS000118AF15 rRNA from 1 species 
-TACGGGGGGGGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCTCGTAGGTGGCCAACTAAGTCAGACGTGAAATCCCCAGGCTCAACTTGGGAACTGCGTCTGATACTGGCAGGCTTGAATCCGGGAGAGGGATGTGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAACACCGGTGGCGAAGGCGGCATCCTGGACCGGTATTGACGCTGATGCGCGAAAGCCAGGGGAGCAAACGGG
->URS00008D4438 rRNA from 1 species 
-TACGGAGGGTGCAAGCGTTATCCGGATTTACTGGGTTTAAAGGGTGCGTAGGTGGATTGGTAAGTCAGTGGTGAAATCCCCAAGCTTAACTTGGGAACTGCCATTGATACTATTTGTCTTGAATACCGTGGAGGTGAGCGGAATATGTCATGTAGCGGTGAAATGCTTAGATATGACATAGAACACCAATTGCGAAGGCAGCTTGCTACGCGGATATTGACACTGATGCACGAAAGCGTGGGGATCAAACAGG
->URS0000E895E3 lncRNA from 1 species 
-CTTATCTGGTGAGGGAGGTTTTCCTTTGTTTCTGGAGCTTGGTTAAAGTAAGCCAAGCTTTATTTTTCTAACTTGAACTCTGACTAAGTAAATAATATTCTGATTGTCCTTAAAGATGCAGAGCATCTTACTCCGTGTGTGTGTGTGTGTGTTACAGCAGGGGTTCCTAACCTTTTTATGCTGCAGACTGGCAAACTGCAGACCAGAGATGACAGTGGACTGGAAGTGACCACAGACTGACAAACTGCGGACCAGAGGTGACTGTGGACCAGCAAACTGCAGACCAGCAGTGACCAGCATACTGGTACCAGACCGCAGTCTGAGGGTTGGGAACCCCTGTGTTACAGTAAAGCAAAAGCACAAAGTAGGAGGCATACTCTTAATTGGAACCCAGGTCAAGGAGATGGGTACCACAATGGCAGATGTGTGGATGGGACCAACCATGATGAATATCTTGCACAAAATTCAGCCTTGGATGAAGATAAAATTTGCCTGCCCTGGATCAACCTGGTAATCAAGTCAGTCCTGGGATTTATACCAAATTCTGGTGTTAATGCACCATGGACTCTTCAGTGCATGTTGCTTGGAGCCTTTGGTTCCTGCTGTTCACAGAATGCTGCAGATGGCTGCCTCAGCAGGAAGCCCTTCCCCCTTCCTTAATGGAGCTCGTGGGAATGCAGGGATCCTGGAACTGAAGCCCTCCTTCCCTTCCAAACCTCCTCTCCAAACCCCTACTGAGTAAAAGGAAAAAAATCCCCACATCCCTGGAAACATTTTTGCCAGCCTGTTTTTCAGTAAAATCTTAAATTAACCACTT
->URS0000DD7A4F rRNA from 1 species 
-AGGGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTTTTCGGATCGTAAAACTCTGTTGTCGGGGAAGAACAAGTATGATAGTAACTGATCGTACCTTGACGGTACCCGACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCTCGCAGGCGGTTCTTTAAGTCTGATGTGAAATCTTGCGGCTCAACCGTAAACGTGCATTGGAAACTGGAGGACTTGAGTGCAGAAGAGGAGAGTGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAAC
->URS0001657D77 rRNA from 1 species 
-CAGCCGCCGCGGGAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGCAGGCGGTTTCTTAAGTCTGATGTGAAAGCCCCCGGCTCAACCGGGGAAGGTCATTGGAAACTGGGAAACCTGAGTGCAGAAGAGGAGAGCGGAATTCCACGTGTAGCGGTGAAATGCGTAGAGATGTGGAGGAACACCAGTGGCGAAGGCGACTCTCTGGTCTGTAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGAGACCCCTGTAGTCCCTGTCTCTTATAC
->URS0000010E3A rRNA from 1 species 
-TCAGTCGACTCCTACGGGGAGGCAGCATGGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTGTAAAGCACTTTCAGTAGGGAGGAAGGTAGTGTAGTTAACACCTGCATATTTGACGTTACCTACAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGCATGCAGGCGGCCTGTTAAGTCAGATGTGAAAGCCCGGGGCTTAACCTCGGAATTGCATTTGAAACTGGCAGGCTAGAGTCTTGTAGAGGGGGGTAGGAATTTCAGGTGTAGCGGTGAAATGCGTAGAGATCTGAAGGAATACCAGTGGCGAAGGCGGCCCCCTGGACAAAGACTGACGCTCAGATGCGAAAGCGTGGGGAAGCAAACAGGATTAGATACCCTGGTAG
->URS00007A8810 rRNA from 1 species 
-CCTACGGGAGGCAGCAGTAAGGAATATTGGACAATGCTCGCAAGAGTGATCCAGCCATGCCGCGTGCAGGAAGACGGCCCTATGGGTTGTAAACTGCTTTTGAACTAGAGAAAACCCTTCTACGTGTAGAAGGCTGATAGTATAGTTAGAATAAGCATCGGCTAACTTCGTGCCAGCAGCCGCGGTAAGACGAAGGATGCAAGCGTTATCCGGATTCATTGGGTTTAAAGGGAGCGTAGGTGGACTGATAAGTCAGTGGTGAAATCTCCGTCGTACCGTAACGAAGTAAGTCGACT
->URS0001848EE8 rRNA from 1 species 
-TACGTAGGGGGCTAGCGTTGTCCGGAATCATTGGGCGTAAAGTGCGTGTAGGCGGTCCGGTAAGTCCGCTGTGAAAGTCGGGGGCTCAACCCTCGAAAAGCCGGTGGATACTGTCGGGCTAGAGTGCGGAAGAGGCGAGTGGAATTCCCGGTGTAGTGGTGAAATGCGTAGAGTATCGGGAGGAACACCAGTCGGCGAAGGCGACTACCTGGCC
->URS0001910395 rRNA from 1 species 
-CCCTTAGATGTCCTGGGCTGCACGCGCGCTACACTGATGCGCTCAACGAGTTTACGATCTTGCCTGAAATGGCTGGGTAATCTTTTTAAAATGCATCGCGATGGGGATAGATCATTGCAATTATTGATCTTCAACGAGGAATTCCTAGTAAGCGCGAGTCATCAGCTCGTGCTGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTCCTACCGATTGAGTGATCCGGTGAATAATTCGGACTGACGCAGTGCTCAGCTTCTGGACGTTGCGTCGGAAAGTTTCATGAACCTTATCACTTAGAGGAAGGAGAAGTCGTAACA
->URS00006E6EF3 rRNA from 1 species 
-TGGGGAATATTGGGCAATGGGGGAAACCTTGACCCAGCAACGCCGCGTGAAGGAAGAAGGTCTTCGGATCGTAAACTTCTATCCTCGGTGAAGAGGAGAAGACGGTAGCCGAGAAGGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTGTCCGGAATGATTGGGCGTAAAGGGCGTGTAGGCGGCTAAGTAAGTCTGGAGTGAAAGTCCTGCTTTTAAGGTGGGAATTGCTTTGGATACTGCATAGCTAGAGTGCAGGAGAGGTAAGTGGAATTCCCAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCTTGCTGGACGATGACTGACGTTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGACTACTAGGTGTCGGGTAGCAGAGCTATTCGGTGCCGCAGCCAACGCAATAAGTAGTCCACCTGGGGAGTACGTTCGCAAGAATGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCTGCTCTTGACATCTCCCTGACCGGACTGTAATGAGTCCTTTCCCTTCGGGGACAGGGATGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTATCTTTAGTAGCCAGCGGTTTGGCCGGGCACTCTAGAGAGACTGCCAGGGATAACCTGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGAGCAGGGCTACACACGTGCTACAATGGCGTAAACAAAGGGAAGCGAGCCTGCGAGGGTAAGCAAATCTCAAAAATAACGTCTCAGTTCGGATTGTAGTCTGCAACTCGACTACATGAAGCTGGAATCGCTAGTAATCGCGAATCAGAATGTCGCGGTGAATACGTTCCC
->URS00022CA99A rRNA from 1 species 
-TGGGGGATTTTGCACAATGGGCGCAAGCCTGATGCAGCGACGCCGCGTGAGGGATGAAGGCCTTCGGGTTGTAAACCTCTTTCGCTGGGTTGAAAGGCCATGCTTTGGGTGTGGTTGATTTGAACTGGTAAAGAAGTACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGTACTAGCGTTGTCCGGATTTATTGGGCGTAAAGGGCTTGTAGGTGGTTTGTCGCGTCTGTCGTGAAATCCTGTGGCTTAACCATGGGCTTGCGGTGGGTACGGGCAGGCTTGAGTGCGGTAGGGGAGACTGGAATTTCTGGTGTAGCGGTGGAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCGTTACTGACACTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS0000A0C1A7 rRNA from 1 species 
-GTGAATGCTGGCGGCGTGGATGAGGCATGCAAGTCGAATGGGTTTAGACCCATGGCAGACGAGGTAGGAACACGTAGGTACGTACCGGAGAGTCAGGGATAACCTGGAGAAATCCGGAATAATACTTGATGGTCCCGAGAGGGTAAAGATTTATCGCTCTCTGAACGGCCTGCGTTCTATCAGCTTGTTGGTAAGGTAACGGCTTACCAAGGCTACGACGGATAGGGGAGGTGAGAGCCTGACCCCCACCGATGGAACTGCGACACGGTCCATACTCCTACGGGAGGCTGCAGTCGAGAATCTTCCGCAATGGACGAAAGTCTGACGGAGCGACGCCGCGTGGTAGATGAAGTCCTTAGGGACGTAAATACCTTTTATGAGGGAAGAAGTTTATTGACGGTACCTCATGAATAAGGGGCTCCCAATTCTGT
->URS000254C320 misc_RNA from 1 species 
-GAAGTGCGATAAGCAGTGCGAATTGCAGAACCGTGAGTCATCAGATTTTTGAACGCAACTGGCGCCGATTGGTCCTCCAGTCGGCATGCTTGTTTCAATATCTTGTTCTCTCATCACCCAAATCTTAATGCTAGAGATACCCTTCTCTGGTTAAGTATGAAAGCACTCTGTACTCTGCAGGCAATCCTTCGGGAGTTGCACTCAATGCAGCAGTCACATTGATTACAGTGTGAACTCATTGAGAGTTGAGAACAGTTCAGCTATGCTGTTAGTGCTTAGATAACTAAACTTACTTGCATTTGAAATCAAGCAGGATCACCCGCTGAACTTAA
->URS000255DEA3 misc_RNA from 1 species 
-TCGCGGCTTATCACCGGCAGTCCCCTTAGAGTGCCCAACCTAATGATGGCAACTAAGGGCGAGGGTTGCGCTCGTTGCGGGACTTAACCCAACATCTCACGACACGAGCTGACGACAGCCATGCAGCACCTGTGTTCCAGCCAGCCGAACTGAAGGGGTCCATCTCTGGTCCCCATACTGGACATGTCAAAGGTTGGTAAGGTTCTGCGCGTTGCTTCGAATTAAACCACATGCTCCACCGCTTGTGCGGGCCCCCGTCAATTCCTTTGAGTTTCAGCCTTGCGACCGTACTCCCCAGGCGGGGTGCTTAACGCGTTAGCTAAGGCACCGCAGGGGTCGATACCCGCTACACCAAGCACTCATCGTTTACGGCGTGGACTAC
->URS000043B807 rRNA from 1 species 
-TCGAGACCGAAACACAACGAGCGATTTTGTGAACCTGTAAAAATAAGCGGTGGCTCTTGCTGCTGCGATAAAATCCACCCGAGTCATCGCCTCATCCCCTCTTTGGGGTGGGGACGTGATGAAGGATGGATGAACCCTCAAATCGGCGCAGCGTTGCGCCAAGGGAATCTTGAAGCACAAGCCCATAAATGGGTTTCGTGGGATGGGGTGCTGTCGCACGCCATATTGATTGACACGACTCTCGGCAATGGATATCTCGGCTCTCGCATCGATGAAGAGCGCAGCGAAATGCGATATGTGGTGCGAATTGCAGAATCCCGCGAACCATCGAGTCTTTGAACGCAAGTTGCGCCTGAGGCCAACCGGCTGAGGGCACGTCCGCCTGGGCGTCAAGCATTTTATCACTCCGTGCCTACTCTCCCATTCATGGATGTGTTGCTAAGGCTCGGATGTGCACGGTGGCTCGTCGTGCCCCTTGGTGCGGCGGGCTGAAGGGCGGGTCATCTTCTCGTTGGCTGCCAACAATAAGGGTGGATTAAATAAGGCCTATGCTATTGTGTCAAGCGCGCCCGAGAGATGGTCATACTTTTTAGGTGATCCCAATTCATGCGTTGATCCATGGATGGCGTATCGAAT
->URS0001EC40D3 rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCTTTACACATGCAAGTCGAACGGCAACAGGCCGCAAGGTTCCGCCGAGTGGCGAACGGTTGCGTAATGCATCGGAACGCGCCCAGTCGTGGTGGTTAACTACGCGAAAGATTAGCTAATACCGCATACGACCTCTGGATGAATACGGGTGACAGTAAGGCCTCGCTCGACTTGACCCGCCGATGTCAGATTAGGTAGTTGGTGGGGTAAAGGCTCACCAAGACAACGATCCGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGAACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGCGCAAGCCTGATCCAGCAATGCCGCGTGCAGGAAGAAGGCCTTCGGGTTGTAAAGTGCTTTTGTAGGGAAAGAAACGGATCTGATTAATACCCGGGGCTAATGACGGTACCGAAAGAATAAGCACCGGCTAACTACGTG
->URS000126A115 rRNA from 1 species 
-TACAGGGGGTGCAAACGTTGCTCGGAATCATTGGGCGTAAAGCGCACGTAGGCGGTCTGTTATGTCGGATGTGAAAGCCCTCGGCTCAACTGAGGAAGTGCATCCGAAACTGGCAGGCTAGAGTACTAAAGAGGGTCGCGGAATTCCCGGTGTAGAGGTGAAATTCGTAGATATTGGGAGGAACACCAGTGGCGAAGGCGGCTACCTGGACCGGTGCTGACGCTGATGCGCGAAAGCGTGGGGAGCAAACAGG
->URS00016D22DE rRNA from 1 species 
-TACGGAGGGTGCAAGCGTTATCCGGATTCACTGAGTTTAAAGGGTGCGTAGGTGGCTTTGTAAGTCAGTGGTGAAATCTTAGAGCTTAACTCTAAAACTGCCATTGATACTGCTTAGCTTGAATCAAGTAGAGGTGGATGGAATAATACATGTAGCGGTGAAATGCTTAGATATGTATTAGAACACCGATTGCGAAGGCAGTTCACTATGCTTGTATTGACACTGAGGCACGAAAGCGTGGGGATCAAACAGG
->URS0000FAD9B3 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGAAGCGACTCAAAGTTTTCGGACAGAGAGTTGACTGAGTGGCGGACGGGTGAGTAACGCGTGGATAACCTGCCTCATACAGGGGGATAACAGTTAGAAATGACTGCTAATACCGCATAAGCGCACAGTACCGCATGGTACAGTGTGAAAAACTCCGGTGGTATGAGATGGATCCGCGTCTGATTAGCTAGTTGGCGGGGTAACGGCCCACCAAGGCGACGATCAGTAGCCGACCTGAGAGGGTGACCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCGACGCCGCGTGAGTGAAGAAGTATTTCGGTATGTAAAGCTCTATCAGCAGGGAAGAAAATAACGGTACCTGACTAAGAAGCACCGGCTAAATACGTGCCAGCCGCCGCTCGTAAAAC
->URS000049D5CE rRNA from 1 species 
-ACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGGGATGCGTATCGGAAAGCTTCGGCCGGAAGATACGTTATCTAGTGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCTTATGGAGGGGGATAACAGAGAGAAATCACTGCTAATACCGCATAAGCACGCAGTACCGCATGGTAGAGTGTGAAAAGATTTATCGCCATAAGATGGACCCGCGTCTGATTAGCCAGTTGGCAGGGTAAAAGCCTACCAAAGCGACGATCAGTAGCCGATCTGAGAGGATGACCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGAGTGAAGAAGTATTTCGGTATGTAAAGCTCCATCAGCAGGGAAGATAATGACAGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGTAGACGGAGTGGCAAGTCTGAGGTGAAAACCCTGGGCTCAACCCTGGGACTGCTTTGGAAACTGTTAATCTAGAGTGTTGGAGAGGTAAGTGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAAGAACACCGGAGGCGAAGGCGGCTTACTGGACAATAACTGACGTTGAGGCTCGAAAGCGTGGGGATCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGAATACTAGGTGTCGGGGAGCAAAGCTTCTCGGTGCCGTCGCAAACGCAATAAGTATTCCACCTGGGGAGTACGTTCGCAAGAATGAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGAG
->URS000101C2DC rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGTTCGGAATCACTGGGCGTAAAGGGCGCGTAGGCGGTGTGTCAAGTCAGGCGTGAAAGCCCCGGGCTCAACCTGGGAACCGCGCTTGAGACTGGCACGCTCGAGTTCGGGAGAGGATGGTGGAATTCTCAGTGTAGAGGTGAAATTCGTAGATATTGGGAAGAACACCGATGGCGAAGGCAGCCATCTGGACCGACACTGACGCTGAGGCGCGAAAAGCGTGGGGAGCAAACAGG
->URS000172D02F rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGAGTGGCGAACGGGTGAGTAATACGTGGGTAACCTGCCCTCTTTCTGGGATACGCCTTTGCAACGGGGACTAATACCGAATATAGGGGGATGGGCTCGCGGCCTATCAGCTGGTTGATGGGGTGATGGCCTACCAAGGCGGTGACGGGTAGCCGGCCTGAGAGGATGAGCGACATAAGTGGGAATGAGAAAAGGCCGAGAGTCGTACGGGTGGGAGCAGTGGGGGATATGGCACAATGGGGGAAAGACAGATGCAGCGACGCCGCGTGGGGGATGAAGGCAAGCGGGTTGTAAACCTGTTTAGCTATCGAACGGGTAGGTGGAGAAGAAGCGCCGGCGAACTACGTTCCAGCAGCCGCGGTAATAC
->URS0000A77429 sRNA from 1 species 
-TTTTTGGGTGATTAAAATCCATATATTTTGTTACACTAGTTTTCATTCTATTTGAGACAACACGTTTTGTATGTTTACACGATTGTACGGCCACCTCCAAACCACGGGTTCGATGACAGATCAGTGATCACCTCTTTATTGGTTTAGCAAACGACGGCCCTAACCTCGATCCTTTCTCTCGGTTCCTTCTCTAATGGGT
->URS00004E56CD rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGGAGTTCCTTCGGGGACTTAGTGGCGAACGGGTGAGTAACGCGTGAAGAACCTGCCTTTCAGTGGGGGACAACAGTTGGAAACGACTGCTAATACCGCATAACATATATTGTGGGCATCCACGATATATCAAAGGAGCAATCCGCTGAAAGATGGGCTCGCGGCCGATTAGCTAGATGGCGGGGTAACGGCCCACCATGGCGACGATCAGTAGCCGGTCTGAGAGGATGAACGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGAGGCAGCAGTGGGGAATATTAGGCAATGGGGGGCAACCCTGGACCTAGCAACGCCGCGTGAAGGAA
->URS000163D073 rRNA from 1 species 
-ATACGTAGGTGACAAGCGTTATCCGGATTTACTGGGCGTAAAGGGCGTGTAGGCGGTCTTGCAAGTCAGAAGTGAAATTCCTGAGCTCAACTCGGGCGCTGCTTCTGGAACTGCAGGACTTGAGTGCTGGAGGGGATAGCGGAATTCCTAGTGGAGCGGTAAAGTGCGCAGATATTAGGAAGAACACCGGTGGCGAAGGCGGCTATCTGGACAGTAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGGGTTAGATACCCTGGTAGTCCACGCCGTAAACGATGAATACTAGGTGTAGGGGGTATCGACTCCCTCTGTGCCGCAGTTAACACAATAAGTATTCCGCCTGGGGAGTACGGCCGCAAGGTTGAAACTCAAATGAATTGACGGGG
->URS00025C2B18 rRNA from 1 species 
-ATGGCGATGGAGACGCCCGGGCAGGAAGGGCTCGATCCGGATGAACCAGCTCGCACCGAGCCCGGCCGCCTCAACAGGAGCTCGTATCTCTGCCTGCCAGCGGCTCACCGGAGCCGCCACTGCCGGCGACTGCCTCCCTCACCTTGTGCCCCTCCTCCTTCGCCTTTCTTCCTCTCTTCCCCGAGGAGCGGGGAGCCGGCGAATCCATCGGTCAGGAGCTGGGCGGCGCCCTCCATCATCGCCGTTGTTTGGGGAGGGACGCGGTCCTGGTCGATGCGGTATGGGGCGGGCGACGCGGGGCAGGAGGTGGCGGCGGGATGGAGGTACATGTGA
->URS0001D99DCB rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGCGAAAGTTCTTCGCTATGTGTAAAGCGGCGGACGGGTAAGTAATGCATGGGAATTTGCCTGGTAGTGGGGGACAACGTCTCGAACGGGACGCTAATACCGCATTAGCCCTACGGAGGCAAGGGGGGGTTCTTCGGACCTCTCGCTATCAGCTGAGCCCATGTCAGTTTGGCTCGTTGGTGGGGTAAGGGCCTACCAAGGCGACGATCGGTAACTGGTCTGAGCGGAGGATCAGTCGCACTAGAACGGGAACACGGTCCATACTCCTACGAGAGGCAGCAGTGGGGAATAGTGGACAATGGTCGAGAGCCTTGTCCAGCGAGGGCGAGTGTGTTGAGAAGGCCTTGGGGTTGTAAAGCACGTTCAGTGGTGATAAAGGTTTTTTACTTGATACGTAGGCAGAGTGATGGTACCTGCAGAAGAAGCACCGGCTAACTCCGTG
->URS00025F9C51 lncRNA from 1 species 
-TAGCTTTGAGAAACCTAGCCACACTTTCAGCACTCAGGCCTTTAGTGCTCATTGGAATAAGGTCCCCGCAATCCAATGTCGACCTACAAATGAAGTTTTTTACGGACAGGAGCATTTTTCTTCAACATGGAACTAACAGTCATGATTTTCTTCTCATAACGTAAATCTGAAAGGTCACTTGTTACATCCGACATCGGGCTGAAAATGTATACACATTGCATTGTGTTAAAAAGAATTATGATGGAAAAATAGTGAGATCTCTCTTTCTAGACTGTAGGGTGATGAACCTGTACCAATCATACTGTCTGTCTTATTTATCTGACAACTGTCCCGATACTGAAGAAAATGTTGACAGACAACACAATTAGGCTAGGAAGACTAGATGGTCAGTGATTCAAAATTACTAAATTTGAATTGTTACATAAAAAAAGTAACTGGTTTACAAATTATCCTAACAGTCAAAATTTGTTAAAGATATATTTTTAACCATTCAAAATTCAACTTTAAAGGTGGGGGGGGCAGAATTCATCACTAATGTCCTAGCTTCGAATCTAAGTAGCTCTGAATTTGATTGTAAACTACTTCATACTTAATCTCAAAATACTATTTTTATATTTGCTTATGTGTTTCATCCTGACATCTTCAGGGTTGCTAAGAACGGCATTCATACTCCAAAATTACAATTAAGTTCAGAACTTATTAGAAACATGTTTTTCTCAAGGGAAGTATGTGGCCTATTTGCCAAGAGAGAATTTTTTGTGTCAGAGCCTGTGCTCCCCCCCCTTTGGTTTTTGAATGCATTGTGCACAAGAGAAAACTTGGTCCAGAGCTTTCTCTATAAAACTGAGTGTTAATGTAAGAGAGTTGGCCAAAAAATAAGATAACTTATGTACAGGAATTATTGTAAATAAACTTGTAGGGTAGTACACTTTTTTTCTGCGTGTTACCTCTTGTACCCACATGATGATGATGTCAACTCTCTCCCTCTTGGCTTTACAACATTTTCATAATCCTATAATGATAAATATACATTACTCATTCAATTTTAACACAATACACTGGTAGATATGGTATTAATAGATTTAATTTTATATTAAAACACGATCCGAAAACACACACTGAACATGGTCACCAATACATTAAACAAAGAGAAGCAGAGAAATATTTGTTGCATATATAAGCACATGGATTAAATAGTTTGGTTCATTAAATAATAAAGAATCTACATCAAAGTGA
->URS00009B757A lncRNA from 7 species 
-AATTAGCCTCAGAGGTTTAAGACTTGCTTGCAAGTGTGCCTTCTGTTTATAGGTTAAGCTAGCTATTTTAATTCTATTATTTGTGAGTTCTCCATAGATGTAAAGTATGACGTAATTCATGTGCCAGGCCACATTGGAGATAGTCAGCTGCCATCGAGCCAGAGTTCCGCAGGCCCTCAGCCAGAGCTCCTCACCAGGGACCCTGCTAAACAGGCAAATCCGCATTCTAACACTGAGCAAAGATTCCTTTCTGAAGGTTGGGGAGTCTGGCATGCACCAATCAAAGGCCTTTCTTTATTGACCACAACACCCAAGACTGCCACCTGGGTAGCTTCCTTCCATACTCCTCACTTTAAATTTATAGCAGCAATTGCTTCTCAATGTAGTCACATGTGCTGGTATAATCTGCCTTTCTTTCTTTCTTTTTTTTTTTTTAAGATTTATTTATTTATTATATGTAAGTACACTGTAGCTGTCTTCAGATACTCCAGAAGAGGGAGTCAGATCTCATTATGGATGGTTGTGAGATGGTTGTGAGCCACCATGTGGTTGCTGGGATTTGAACTCCAGACCTTCGGAAGAGCAGTCGGGTGATCTTACCCACTGAGCCACCTCACCAGCCCGTAATCTGCCTTTCATAAGAATGAATTACAAGTAAAAATCTTGGGGTTTAGATTTTGTTTTGGTTTTTTTTGGTTATTTGAGGTAAGGTCTTATGTAGCTCAGACTGTTCTAGAACTTGCTGTATAACTGAAGCTGAACTTGAATTCCTGATTTGCCTGCTTCCACCTCCTAGGTACCACACAGAGGCCCTGTTTCTGTGGTGCTAGGATTTATTTTTATTTTATATACATTGGTGTTTTGCCTGCGTGTATGTATATCTGTTTGAAGATGTCAGATCACGTGGAGGTGGATTACAGATTGAACTTGCATCCTCTGGCCGAGCAGCGCCAATCTTAACCACTGAGCCATCTCTCTAGCCCTGGAAGCCAGGGCTTTATGCATGCTAGGCAAGTGCTTTCCAATTGAGCCACCTCTCCAGCTCTAGGGAATCTTAATATTATTTTATTCAAGGTACATTTATGCTTCTTTTGACTTAGATTAGATTTTATGAAGGTGTTCCATTTTCTAGTTTTTGGTTCACTCGTCTTAAAAACTTAGGAAGACTTTTAGTAATAATTTTCTACCTCTATATGAGACTTACTATTTTCAGAGAACTTTCAAGTTTCTATCTCATTTATTAATACTCCCAGAAAGACTCTGTGAAGCTAAGATGAACAGATATTTATTGCTATTATTGTTGTTTTCAGAATTTATTTACATTATTTTGCATGTATGACTACCTACATATGTGTCCATGGAGGCCAGAAGAGGTGTCAACACTTAAGACTTAAGAACTATTTTAAGGGGCTGGTGAGATGGCTTAGGGGTTAAGAGCGCCGACTGCTCTTCCAAAGGTCCTGAGTTCAAATCCCAGCAACCACATGGTGGCTCACAACCATCTGTAAGGAAATCAGATGCCTCTTCTGGAGTGTCTGAAGACAGCAACAGTGTACTTACATATAGTAGATAAATATTAAAAAACAAACAAACAAACAAACAAACAAAAAAAGAACTATTTTAAAAGCTATTTCAAAGGTTTGAATAGCTAAAACAAATCTAAAAGAGTTTAATAACTTAGTATAATAATATTAAGGTAATTATACTTTAACTAATCCACATAAACTGAACTTGGTTCTCTTTTTTTAAGATTCAAATAGATCTTAGTAACCTTTTTTAGTCTACCCTTCTTTCAAAGAAAGAAAATCAATATTCAGATAGGACCACAATATGTGATTCTGCTTGTTTATTCATTCATTTGTTTGATCACACCCATGCAGTTATTTATCCTGTATGTGCACATGCATGTGCACAGCATCTGTGTGGAGATCAGGGGACAGTTAACTTGTAGGGGCCTGTTCTATACTTCTGTTCTGTCATGTGAGTCCCAGGTATCACACTCAGATTATCAGACCTGGTAGTAAGCATTTAGCCCCCTGAGCCACCTCACCAGCCCAGATGTGGTCCAGTCTAATGCCACCATCTTATACCAGTTTCTGTGCAGAGAAAAACTTGATGTAGTTTGGGTTCCAATGGACTGGGCAGAATGTTCTCAGAGGCTTCGCAGTCGGCTGAAATGGGTCTCAGTGGAAGACATCACTCCTGAGCCCACTGGGGAGTGGCGTTCTCACCCATCAGTAGGACCTCCCAGCAGTATCTTCCAGAAGTAGAAATAAGTCACAAGGAAAGGAATTAAAGATGAAGTACAGTGAGGTGGCACAGCCCCTAGCCCTACCACTCAAGAGGCTGTGCGGTAGGAACACGGGAACTCCAGCGCCAGTCTGGGCTGTGAGCTCTTGTCTCAAAAAGCCAAACCATCGGTGTAAATGAAGTATAAAAGAGAATTTTATTTATTTCATTATTTTTTCATTTTCATGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGTGCTACACATGTACATTGCCTGCCATCCAAGGCTAGAATTAGAGTGGACCATGGTGCCTGCCTGGTGTTTGCTTATTCTTAGAATCCAGGCTTCTGTCCTCACTGTTGCATGGCAAATGCTTTAACTACTGAGCTGCTTCTACAGCTCCAAAGAGTATTTTAAAATCTATTGGCATTACAAAGCAACTGTAGCACAATGACTGGCATTATTTTAAAATGTGTATGTCGTTTTATTTATGACT
->URS000181443A rRNA from 1 species 
-CACGTAGGGGGCGAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCACGTAGGCGGATTTGTAAGTCAGGGGTGAAATCCCGGGGCTCAACCTCGGAACTGCCTTTGATACTGCAAATCTCGAGTCCGGAAGAGGTGAGTGGAATTCCTAGTGTAGAGGTGAAATTCGTAGATATTAGGAAGAACACCAGTGGCGAAGGCGGCTCACTGGTCCGGTACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGG
->URS00010F31BB rRNA from 1 species 
-CCTACGGGTGGCAGCAGTGAGGAATATTTGTCAATGGACGCAAGTCTGAACCAGCCATGCCGCGTGCAGGAAGACGGCTCTATGAGTTGTAAACTGCTTTTGTACGAGGGTAAACGCAGATACGCGTATCTGTCTGAAAGTATCGTACGAATAAGGATCGGCTAACTCCGTTCCAGCAGCCGCCGTAATACGGAGGATTCAAGCGTGATCCGGATTGATTGGGTTTAAAGGGTGCGTAGGCGGTCGGATAAGTTAGAGGTGAAATCCCGAGGCTCAACTTCGGAATTGCATCTGATACTGTTCGGCTAGAGTGTAGTTGCGGGAGGCGGAATGTATGGTGTAGCAGTGAAATGCGTAGAGATC
->URS00003180C5 rRNA from 1 species 
-GGGTGGTAAATTTCATCTAAAGCTAAATATTGGCCGGAGACCGATAGCGCACAAGTAGAGTGATCGAAAGGTTAAAAGCACCTTGAAAAGGGAGTTAAACAGCACGTGAAATTGTTGAAAGGGAAGCGCTTGCGGTCAGACTCGGGCGCAGGGTTCAGCGGGTGCGTGTCACCCGTGCACTCCCTGCCGCCCGGGCCAGCATCAGTTCTGACGGCCGGTCAAAGGCCCCCGGAATGTGTCGTCTCTCGGGACGTCTTATAGCCGGGGGTGCAATGCGGCCCGTCGGGACTGAGGAACGCGCTTCGGCTCGGATGCTGGCGTAATGGCCGTAAGCGGCCCGTCTTGAAAAACACGGAC
->URS00019A9808 lncRNA from 1 species 
-TGAGTTCTTGATTAGAATAATTATATTATATGTATGTATAATATGTCAAAATATACTCTAATATCATGTATACATTAAAAGAACAAAGGAAAAGAACATCACTGGAATTGAAAAGGGCATGGTGATACAAGCTAATGGTACTAAGAACTTTTCAGTCGAATAATAGAAAAAAATTTTTTAAACTTCAAGTATTAGGTGAACATTTAGGAGTCATATAGAACTAAACATATAAAATAGCAAAAAAATCTCTCTGACACATCATAATCAAAATGCCTAACATAGTGAATAAGAATGGAATTTTAAAACTGCAAGGAAAAATGTCAGAGCCAGGCACAGTGGTACACCTGTAATCCCAGGGGCTCAAGAGGCTGCTACTTCAAATCTAGCCTTAGCAACTTATCAAGGAACTAAGCAACTTAGAAAGACCCTGTCTCTAAATAAGTTACAAATAATGGCTGAGAATGTGGCTCAGTGGTTAAGTGCCTCTTAGTCCAATCCCCAGTAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAGAAACATGTCAGCACACATTAGAGGTAAACCAGTGCAGACAACTCCTCAGTTCTTCACACCATTTTAAATCCAGGAAGGCATAGAATGAGGTTATCTGATCTCTGAAAGAAAATTCCCAACCAAGATCACTATATACAGCAAAACCATCCTTTAGAATCAAATAAAAAATAAAAACTTCCAAAAATGAGAATATACTAAAAGAATTCATGACTACAAGGTAGCACTACATAAAATACTTAAAAAAATACTATCCATAGAAGAATTTAAAAATAATCTCAACTTGCCTCTAATGTGGGCTGCCATTTTTCTCTTTCAGCTTTTAAAATTCTATCTTTGTTCTGTGTAGTAGATGGTTAATTATGATGTGTCTTGGGAAGGATGTTTTTTCATCTTATCTATTTGGGGTTCAAAATTCCTCTTGTATTTGGATTTCACTTCATTCCTACAGTTTGGAAAACTTTTTGATATAGTTTCACTGAAAATTTTATACATTTCTTTAGTTTGTGTCTTGGTGCCTTGTTCACAAAGAGTCTTAGAATTGAGCTCTTAATGCTATCTCTGATTTCTTGTATATTCTGGTCATGATTTGTTACCTTTCATTTATTGTTGACTTTGCTTTTAAAATTGTATACTTCATCTTTGATATTAGAAAATCTGCCTTATGTGTGGTCTAATATATTGGTGATGCTTTCAGCTGAATTTTTTATTTGATTTATTATTTCTGTTCCAGAATTTGTTCTTTTCAAAAATTTCTGTTTATTTTAATATTATATCATTTCTGGTATATTATCTCTTAGTTCACTTCATAGCTATGCCTTTAGTACACTGAAAAATTTAATTAGCAGCTGTTTTAATCAGCTTATTTTGCTACTGTGAACTCAAGACCCATCAAGAAAAATATTAGAGGAAGAAAACTTGATTTGGGGGCCAACGGTTTCAGAGGTCTCAATCAATAGACAGCAGGCTCCCATCCTCAGGGCTCAAGGTGAGACTACTCATCATTGCAAAGGGAAGCAGTTCACATGATGAACAAAAGGCAGAGAGAGCGGTCTCCACTTGCCAGATACAAATATATACCTCCAAACCATGTCCTCAATTCCCACCTCAACCAGCTACAACCCACCACTGCAGTTACTACTCAGTCAATACCTATTAAGGGATTAATTCACTGGTTAGTTAAGACTCTCACAACTCTATTATTTCTCCTCAGAACCTTCTTGCGTTTTCTCACACATAAGATTTTGGGGAACACTTCATATCCAAATCATACATAAATTTTCTAAATTCTTTTTCTGGCATTTCCTCCATTATGATATCAATGGGATTAGTTGTATTGTGGGGTATTCGGAATGACTTGATTCATTGCTTTCCATATTGTTAGTATTCCTTAAGGGATATTTATCTCTTTTGCTTTTATATAAAGGACATTTTCTTGTTATGCTGTGGGTTGGGTGAATGCCTTGAGGTCCACATTTTCACTCAATTTAAATTTCCTATTATGTCTAGTCTCTAAGAGGACACTGAGAGGAGAGAGATTAATTTCAAGTAGTTACAACCACTTCAGAACAATTTCATACTCATAAATCTTTTAAAAACGTATTACAAATGTTCTCCAGAAATCCACTAGTCTGAGTGGTAAATGGGGGTGATTTTATTTAATTGGTTGATAAATTAGTTA
->URS00020D7727 misc_RNA from 1 species 
-GACGAAGAAACGCAGCGAAATGCGATAAGTAATGCGAATTGCAGAATTCAGTGAGTCATCGAATCTTTGAACGCACATTGCGCCCCGTGGTATTCCGCGGGGCATGCCTGTTCGAGCGTCATTTCAACCCTCAAGCCTGGCTTGGTGTTGGGCTCTGCCGTCCGCGGCCGGCCCTAAAGACAGTGGCGGCGCCGCATGGCCCTGAGCGTAGTACATCTCTCGCTCCAGGGCCCCGCGGTGGCCTGCCAGAACCCCCAACTCTATGGTTGACCTCGGATCAGGTAGGGATACCCGCTGAACTTAAGCATATCAATAAGCGGAGGA
->URS0002581D6F miRNA from 1 species 
-TGTGTATTTAGCAGTCTGTGTGTGTGTGTGTATTTAGCAGACTGTGTACTCAGCAGTCTGTGTGTATTCAGCAGTCTGCTAAATACCCATACAGACAGACTGCCGAGCAC
->URS00017F4189 rRNA from 1 species 
-TACGGAGGGTGCAAGCGTTATCCGGATTCACTGGGTTTAAAGGGTGCGTAGGCGGGCAGGTAAGTCAGTGGTGAAATCTCCGAGCTTAACTCGGAAACTGCCATTGATACTATTTGTCTTGAATATTGTGGAGGTAAGCGGAATATGTCATGTAGCGGTGAAATGCTTAGATATGACATAGAACACCAATTGCGAAGGCAGCTTACGACACAATGATTGACGCTGAGGCACGAAAGCGTGGGGAGCAAACAGG
->URS00025256B9 misc_RNA from 1 species 
-TCCGGTTTGTCACCGGCAGTCTCGCATGAGTCCCCAACTGAATGCTGGCAACATGCGACGGGGGTTGCGCTCGTTGCGGGACTTAACCCAACATCTCACGACACGAGCTGACGACAGCCATGCACCACCTGTGAAGGTGCCCCGAAGGGAGGCCGTGTTTCCACGACTGTCACCTACATGTCAAGCCCAGGTAAGGTTCTTCGCGTTGCCTCGAATTAAGGCACATGCTCCGCCGCTTGTGCGGGCCCCCGTCAATTCCTTTGAGTTTTAGCCTTGCGGCCGTACTCCCCAGGCGGGGCGCTTAATGCGTTAGCTGCGGCACGGAACTCGTGGAATGAGCCCCACACCTAGCGCCCAACGTTTACGGCGTGGACTAC
->URS00002B3B99 rRNA from 1 species 
-GGAAAACCGTAGAGATACGGTCCCCCCTTGTGGTCGGTGTACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCTTATGTTGCCAGCACGTGATGGTGGGGACTCGTAAGAGACTGCCGGGGTCAACTCGGAGGAAGTGGGGACGACGTCAAGTCATCATGCCCCTTATGTCCAGGGCTTCGACACATGCTACAATGGCCAGTACAGAGGGCTGCGAGACCGTGAGGTGGAGCGAATCCCTTAAAGCTGGTCTCAGTTCGGATCGGGGTCTGCAACTCGACCCCGTGAAGTCGGAGTCGCTAGTAATCGCAGATCAGCAACGCTGCGGTGAATACGTTCCCGGGCCTT
->URS00000C876E sRNA from 1 species 
-TGGAGAGGTGGTCCAGGGTTACGTAAA
->URS00005C10BC rRNA from 1 species 
-GATGAACGCTAGCGGCAGGCTTAATACATGCAAGTCGAACGGGATTTAGGGGCTTGCCCTTAATGAGAGTGGCGCACGGGTGAGTAACACGTACACAATCTACCTTGTACAGGGGGATAGCCTTGGGAAACTGAGAATAATACCCCATAGTTTTTAGTTATCGCATGATGATTAAAATAAAGCTGAGGCGGTACAAGATGAGTGTGCGGATGATTAGGTAGTTGGAAGGGTAACGGCCTCCCAAGCCGACGATCAATAGCTGGCGTGAGAGCGCGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATATTGGACAATGGGCGGAAGCCTGATCCAGCCATGCCGCGTGGAGGATTAAGGCCCTCTGGGTTGTAAACTTC
->URS0000CDD785 rRNA from 1 species 
-TTTAATTGAAGAGTTTGATCATGGCTCAGATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGTAACAGGAATTAGCTTGCTAATTTGCTGACGAGCGGCGGACGGGTGAGTAA
->URS000241D8E8 lncRNA from 1 species 
-GAAACTTGATCTGAGTGAAACCGCAATTGAAAGTCTACCTGCAAGCATTGGTAATTTGGAATCTCTTGAGAACCTTGATTTGAGTGGAACCGCAATTAAAAGCCTACATGCAAGCATTGGTAAATTGCAATATCTTCAGAAATTTTATCTGAGTGGAACCGCAATGGAAAGCCTACCTGCAAGCATTGGTAATTTGAAATGTCTGGATAAACTTGATCTGAGTGGAACCGCAATTAAAAGCCTACCTGCAAGCATTGGTAGTTTGAGATCTCTTGAGAAACTTGATCTGAGTGGAACTGCAATTGAAAGCCTACCTTCAAGTATTGGTAGTTTGAAATCTCTTGAGAACCTTGATTTGAGTGGAACCGCAATTGAAAGCCTACCTGCAAGCTTTGACAATTTGAATTCTCTTGTGAAACTTGATCTGAGTGGAACCGCGTTTAAAAGCTTACCTGCAAGCATTGGTAATCTGAAATCTCTTGAGAAACTTGATCTGAGTGGAACCGCAATTGAAAGCCTACCTGCAAGCATTGGTAATTTGAAATCTCTTGAGAAACTTGATCTGAGTGGAACCGCTGTTGAAAGCCTACCTGCAAGCATTGGTAATTTGGAATCTCTTGAGAAACTTGACCTAAGTGGAACAGCAATTAAAAGCCTACCTGCAAGCATTGGTAATTTGGAATGTCTTGAGAAACTTGATCTGAGTGGAACCGCAATTGAAAGCCTAC
->URS00006EC10E SRP_RNA from 2 species 
-GCTGGGCGTGGTGGCACGTGCCTGTAGTCCCAACTTCTCGGGAGGCTGAGGTGGGAGGATCGCTTGAGCCCAGGAGTTCTGGGCTGTAGTGCGCTATGTCAATTGGGCGTCCGCACTAAGTTCGGCATCAATATGGTGATCTCCCGGGAGTGGGGGACCACCAGGTTGCCTAAGGAGGGGTGAACTGGCCCAGGTCAGAAATGGAGCAGGTCAAAACTCCCGTGCTGATCAGTAGTGGAATCGCGGCTGTGAACAGCCACTGCACTCCAGCCTGGGCAACATAGCGAGACCCCATCTCTA
->URS00007D8A7A rRNA from 1 species 
-TGAGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGTCTTCGGATTGTAAAGCACTTTAAGTTGGGAGGAAGGGCAGTTACCTAATACGTATCTGTTTTGACGTTACCGACAGAATAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAATACAGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCGCGTAGGTGGTTTGTTAAGTTGGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTCAAAACTGACAAGCTAGAGTATGGTAGAGGGTGGTGGAATTTCCTGTGTAGCGGTGAAATGCGTAGATATAGGAAGGAACACCAGTGGCGAAGGCGACCACCTGGACTGATACTGACACTGAGGTGC
->URS0001F1218A rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCCTTTGGGGGTACTCGAGTGGCGAACGGGTGAGTAACACGTGCGTAACCTGCCCTTGACTTCGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAATCCTTGCTGCATGGTGGGGGTTGGAAAGCTTCGGCGGTTTTGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCTGGCCTGGGAGGGCGACCGGCCACATTGGGACTGAGATACGGCCCAGACGCCTACGGGGGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTCAGCAGGGGCGAAGCTTGTGGTGACGGTACCTGCAGAAGAAGCACCGGCTAACTACGTG
->URS000062BC82 tRNA from 2 species 
-GGGATTGTAGCTCAGTGGCAGAGCACTTGCCTAGCACATATGAGCCACTGAGTTCGATCCTCAGCCCCA
->URS000041D298 rRNA from 1 species 
-AGTCGAGCGAACGGATGAGAAGCTTGCTTCTCTGATGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATTTTGAACCGCATGGTTCAAAAGTGAAAGACGGTCCTGCTGTCACTTATAGATGGATCCGCGCTGCATTAGCTGGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCATAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAAACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACATATGTGTAAGTAACTGTGCACATCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTATCCGGAATTATTGGGCGTAAAGCGCGCGTAGGCGGTTTTTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGAAAACTTGAGTGCAGAAGAGGAAAGTGGAATTCCATGTGTAGCGGTGAAATGCGCAGAGATATGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGTCTGTAACTGACGCTGATGTGCGAAAG
->URS00020E5DB6 misc_RNA from 1 species 
-GATGAAGAACGTAGCGAAATGCGATAAGTAGTGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCCTTGGTATTCCATGGGGCATGCCTGTTCGAGCGTCATTTGTACCTTCAAGCTTTGCTTGGTGTTGGGTGTTTGTCCTGAGGGACTCGCCTTAAAGTAATTGGCAGCCAGTGTTTGGTTTTGAAGCGCAGCACAAGTCGCGATTCAAGGCTATACACCAGCTTCCACAAGCCTTTTTCACTTTTGACCTCGTATCAGGTAGGGATACCCGCTGAACTTAAGCATATCAATAAGCGGAGGA
->URS0002614DC9 lncRNA from 1 species 
-GAAACAAGAGAGTGTGAGAATTGTCACGTGATCTCGATGACGCAACAGTATTAACCACTGTATTTAAGGCTTTTCTTTTGGCAATTGTGACAAATATTTGTGCCAGATGGTTTTCATACATCATGTGATGTACAAAACACGTCATTCTTTTATTAAGAAAGAGAACCTGACTTCAGTATCCTAGCGTACTTAGTAATCAATAGTTTCGTAAAGTTGTTCTTGTTTGTATACTTTGAGTGCGTGTTGTAATTATATTATAGTTGATAGTGGAGTATAATTATGAAGCTGAAGATCAAAGTAACATATTGTGGTGCCTGAGGGTACGAGCCCAAGTTCCAGAAACTTCAAAAGGAACTTGAGCAGAAATTTCCTGGAAAGTTAGACATTGTAAGTTACTACTTCATGCATTTGTGATTTGCAAAAAGGTTGT
->URS0000D36178 rRNA from 1 species 
-AGTCGTACGAACAGCGGAAAGTGCTTGCACTTTCCAAGTAAGTGGCGAACGGGTGAGTAACACGTGAATAACCTACCTCAAAGACTGGGATAACCATTGGAAACAGTGACTAATACCGGATAAAACCCAGTAGCACATGCTACAAGGTTAAAAGCTGCGTTTGCAGCGCTTTAAGATGGATTCGCGGTGCATTAGTTAGTTGGTGAGGTAAAGGCTCACCAAGACAATGATGCATAGCCGAGTTGAGAGACTGACCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCTGCAGTAGGGAATCTTCCACAATGGGCGCAAGCCTGATGGAGCAACGCCGCGTGTGTGATGAAGGCTTTCGGGTCGTAAAGCACTGTTGTATGGGAAGAACGGGTTTAAGAGGAAATGCTTAAGNAGTGACGGTACCATACCAGAAAGGGACGGCTAAATACGTGCCAGCAGCCGCGGTAATACGTATGTCCCGAGCGTTATCCGGATTTATTGGGCGTAAAGCGAGCGCAGACGGTTCGATAAGTCTGAAGTGAAAGCCCACAGCTCAACTGTGGAATGGCTTTGGAAACTGTCGAACTTGAGTGCAGTANAGGTAAGTGGAACTCCATGTGTAGCGGTGGAATGCGTAGATATATGGAAGAACACCAGTGGCGAANGCGGCTTACTGGACTGCAACTGACGTTGANGCTCGAAAGTGTGGGTAGCAAACAGGATTAGATACCCTGGTAGTCCACACCGTAAACGATGGATACTAGTTGTTANAGGGTTTCCGCCCTTTANTGACGAAGCAACGCATTAAGTATCCCGCCTGGGGAGTACGACCGCAAGGTNANACTCNAGNAAT
->URS0001AD154A rRNA from 1 species 
-CCTGGTTGATTCTGCCAGTAGTCATACGCTCGTCTCAAAGATTAAGCCATGCATGTCTAAGTATAAATACTTGTACTTTGAAACTGCGAACGGCTCATTATATCAGTTTTAATCTACTTGATAGTCCCTTACTACTTGGATAACCGTAGTAATTCTAGAGCTAATACATGCGTCAATACCCTTCTGGGGTAGTATTTATTAGAAAGAAACCAACCCCTCCGGGGTGATGTGGTGATTCATAATAAGCTTGCGGATCGCACGGCTTTTGCTGGCGATGGATCAATCGAGATTCTGCCCTATCAGCTTTGGATGGTAGGGTATTGGCCTACCATGGCTTTAACGGGTAACGGGAAATTAGGGTTTGATTCCGGAGAGGGGGCCTGAGAGATGGCCACCACATCCAAGGAAGGCAGCAGGCGCGTAAATTGCCCAATCCTGACACAGGGAGGTAGTGACAATAAATAACAATGCCGGGCCTTTTTAGGCCTGGCAATTGGAATGAGAACAATTTAAACCCCTTATCGAGGAACAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGGATTTGTGGGTGGAGCGACCGTCCCGACGCTTTGCGTGGGTGATGGTCGTCTCCGTCCATCTTTGGGTGGAATCCGTGTGGCATTAAGTTGTCGTGCGGGGGATGCCCATCTTTTACTGTGAAAAAATTAGAGTGTTCAAAGCAGGCTTACGCCGTTGAATATATTAGCATGGAATAATGAGATAGGACCTGGGTACTATTTTGTTGGTTTGCGCACCGAGGTAATGATTAATAGGGACAGTTGGGGGTATTCGTATTCCATTGTCAGAGGTGAAATTCTTGGATTTTTGGAAGACGAACGACTGCGAAAGCATTTACCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCGAAGATGATTAGATACCATCGTAGTCTTAACCATAAACTATGCCGACAAGGGATTGGTGGGCGTTGTTTTGACCCCATCAGCACCTTATGAGAAATCACAAGTTTTTGGGTTCCGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGAAATTGACGGAAGGGCACCACCAGGAGTGGAACCTGCGGCTTAATTTGACTCAACACGGGAAAACTTACCAGGTCCAGACATAGTGAGGATTGACAGATTGAGAGCTCTTTCTTGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGTTAACGAACGAGACCCCTGCCTGC
->URS0000B34B7F misc_RNA from 1 species 
-ATAAAAGTACCTCAGGCTGAGAAGAATTTGCAGATGAATGATATATCTTTCTATTTGTTAGTGTCAGTGCAAAAGTTTGTTTGAGACTTGGCCACTTTAAGTGAACAAGATATAAGATTGATTTATGGCTTACATACAAGATCAATTGTTCAAAAATGTTAATAAAAAATATAAAAAATTTCATATAAGATAAATTCATTACTTGGCCAAAAACATAAACTCCATGAGAGAGTGTCAAGTACATAAGAACATTGAAAGAAGTAAAATGGGAAAAAAGAACCTGGCTTACTCTAGGTTTTATTGTTGTGAACATCCTCATTTAAGAATTTTAATTAGCGATAAGGTAGCCAACTATGCTTTATTTTTTTTCTTTTTTGAATGAATGCTTTAAATTAATTTAAAAAAAATAATAACTTCAATTAGCAACAAATAAAAGCAATAATAATACTAATCTAAGAGAAGATGTTTAGAATAGCCTGGGATATGTCGATCGAGGCACGCAAATTCTGCGCTGTCCTTAGAGGTTAGCTAAGCTACTCCTATGATTGTTTTTTCATATTTGTTTACTTGAACCACCCTTCAACTTAATTGTCCAAGTGTTCATAGAGATAAATCAAAACTGTAATCAAATTTATATGTAATTTACTTGTTTAAGAATCACATTTTTGAACATTAAAAACTTGTTAGGCTTCTGCACAGTGACAAAGCCCAAGCCCAG
->URS000228E453 misc_RNA from 1 species 
-AACTTTTGGCAACGGATTACTCGGCTCGTGTGTCGATGAAGAGCGCAGCCAGCTGCGTGAATTAATGTGAATTGCAGGACACATTGAACATCGATATCTTGAACGCATATTGCGGCCTCGGGCAATCCCGAGGCCACGCCTGTCTCAGGGTCGGTTGAACGTCAATCGCGAAGCTGCTCTCCTCGCTCGCGCATTGGGCGTCGCAGTCGCTACCAGCGGCTGCGTCGCCTCAAGTTCAGACGGGTTGCTCGGTCTTCGACGCGTTCGCCTGACCGGGACGGTGACTCGACTCTCGTAGAGCGCACCATCTCCCGGGTCGTGGCGATTGTCGCTGACGTGCGGCGACCGCAAACATACTCACACTGACTTCGACCTGAGATCAGACGAGATTACCCGCTGAATTTACGCATATCAATAAGCGGAGGCT
->URS0001A2104B lncRNA from 1 species 
-GTGGAGGCGAAGTCAAGATCGAGAGCCGGAAGGTCAACTTTAAGGAGAAAGCTCAGCCCAAGGTGAGCTCGATGGATAATGTTAATCACGAGCCCGGAGGCGGGAATGTCAAGGCTGAGGGGGCGCAGGAGACTGCTGAGGGCAGCGGGGCTCCCTCTAGTGGTGTCTCAGCAGGCCCTGCCCAGGAGAATGGGCTGAAGGAGGGCGCCCCCTGCAGGAGTGAGGAGCTCCGGGACCCGCAGGGCCTGGACTCGCTCATCCCTGAAACAAGCATCTAACTCGACTTTTTGCTATCACTCTGCCCTCTTCATTTCCCCCCCCCGACCGCTTCCTCTCCTCCCCTTCTTTATGTCCTGTCCCTCCTCTGTCCTGTCTTTCTCCACACTCTCTGATGCAGATTGAGTCTTTCAAGCTAAATTTCCGCGAGAAGGCCCGCTCTCGCACGGACCACGGCGCCGACATCATCACCTGGCCCGTCTCGGGTGACAGCCCTGCCCCCCCCCACCTCGCTCCGCAGCAGCGTCTCGCTCAACGACTCCCTCGCGACCGCCGGCATCCCTCGCTCTCACACCACCCCGGCCCTCTCCTCCTCACAGGAACAAGGCTCGCTCACCGGACTCTGGATATGATTTCTGTCTTTTCATTGGCCCGCTGCTCTCTAAACCCCGCCCCCTACCATTGCTAAGACTCATGTGATTGGTGTGCTCTCTGTTGACGTTCTTGATTCCTGATTGGTGAGGCTGTACAGATTACAGTCATCAGGATGCGCTAAAAAATGAAGGCTGCTGACCCGAGGGTCTGTAAACTCTGAGGTTACACTCTGAGTACATCCTGCTACATCACTTGTTGTAGATCTGATCACATGCAAACACATCTGGACATCATCTCTAGCTGCCTTCAAGTCCTCATGGGAAGTTCGTACTTACGAGTTGTTTACGATGCGATCGTGTCATGTGATTTTAGATGGAAAAAATCACTTTCTGACCAAACCAAGAAGCTTCTTTTAGTGCCAAAGCAACAAAATGAAGAGCAAAGCATGTGCATTAGATGTGTGCATTTGATCATTCTAATGAATAGGGAATGTAGTTTGGTTTTGTGAAGATTTAATTCACGTTCACACTACATTTCGAGCATGCAAAGTGTCTACAGATTTAAAATACACTGAAAAAAAATAAAATAAATTGGTGCACGAACAGTTTTCGCTCAGAAACGGCTTAATTTCACAAACAATTACAAAGAAACCGCATGCAACGCGTTTGAATTAGACGCGCAATTGTAAAGTAGAAGAATTGAAATATTTTCCTTTATTTACTACTATAAAAAGAAAAAAAAATTGTAAAATGGTGTTTTTTTTTAATAAAAATATGCAATCTGCAATCTACTGAAATATACTGCAAGTCTGCAGATTTAAAGTTTGCTGTTTTTGTTTAATTCAGCTAAGACGTCACTCCACGTGCATGAGCTTGCTTTTCCTCTCTCCACGTTTGCATGCGTGTGAATCGAAGTCAGTAGAACGTAAAGTGTAGTGTGATCGTCCCTTTATGCCTCAAAAATTGTCTAAATGAATATTATCTGAAACTTTTACATCTAAAATGGCTAACAACAGCTCCAACTCGGAAAGTCCCCCAACATCAGATGTCAGATTTGGGTGGCGCTCGTCTCGTAAGCACGATCATTTCTGCTTGATTTGAAGGCAGCATCATTCAGCATACAGGGCTGTCATGTGACCCTCTCTCACCTTCACCCTTGACCTCCAGCAGAGCTGTCATCGGAGCACATAGGCTTTCTGAATCTCTCTCTAAAGCTGTTTTGTGATGGTGTGTTTGAGTGAATACTGTAGCAATGAACCGCTTTCCTTCGACTCTTCGTTTTATTTTTCGTGACCAGCAGATGTTTCCTTTTCCTTGTTATTGTAAAGCAATATAACAGTCTCCTATAATGCCTATAAGACATGAAACTCCACTTAAACGCACAGTAAACAGCACTCAGTGTCAAACGCAGCTCCAGACGGCTTCAGGAACGTGTAGAGGGTCTGAGGTGGACGTGTAACGAAAAATACCCTTGTGAAAAAGAAGAAACAATAATATTAATGAAATAAAAGCCCACTTAAGTGTACTTACAGTAGGCCGTTTCCTAACACACTTAAGTACGCTTTGCAATATTGTCAAATTAATTGTTTTAAAGTACATTTTAAATCATTATGTTTTGATAATCTTTGAAGACGTACACTTATTTTGACGTGTTGACTGTCATACTAAAGCGCATGTGAAATACTTGATTATAATCGAACTGTAGTGTTATGCGATATTACATTCAAAGTTATTTTACTCGGCTGCATTCATCATTACAAATGTATAATTAAAAATTTATTTAAATACATGACTTACAAGTTTAGTTTACCATGCATGCTTGTCATTGCAATCAGCAATACACTTTAACCGTGTTTCAAAGACACTAGAAGTATTTGTGAATCTGCGTATAAAGATGTACTTAAATCCTACTTACAGTAAATGGCTAAAAAACACTATAAAGTTCAGATCATTGCATTTAAAATAAATTTGAACCATTATAGACTTCATTTCAATTAACATACATTCAGTTCACACTTACAGTAAGTATATTCGTCTAAAGTGCATTGCTGTAATAAGTATACTTAAGTGTACTTCTTTTTCACAAAGGCAAGGGAAGTGTGGAGACACTAGATGTTGACTTGATGCTTGAGGGGTTTCTGTTGGGATTGAATAGTTGATGTTTTGGCATCATGTACAGTAGGTACAGTATGTTTTAAATGGAAGTGAGGATCAAGTTCGTGCCTGATAGAAATCGCATCCCTTCGGAGGGACGCAGAGACAGAATGTCAAAGCTTGAAAGCTTTTACGTACTTTTAATAGTTGCTTTACGAGAAACCAGTGAAATTGCGAGTGAGTCTGGTGGTGGTTTTACTTCTCTTATTCGTTTCTGCAGGTCTTTTTTAGGAGTTAAAGTGTGATCATGTGGGTTGAAACGTTCCTGCGGGGTTTTAATGGTGGAGCTTAATTCTCTTGTAGCATTTTACAATAGTTTATCTTCAGATGGTCGCACTGAATCACATGCTTAACACGAATCTGCTTGGTTTAGTGTCCTTTTGGTGTAATAATGGGGTAAGAGGACGTGGCCGTTCTTTTAGTGTTCATTTTGTCATCAGCTGAGGGCGATATGGAGGTCCGACGTACATTTATTTTTTATGAGTATGACAAATTATTGTTGCATCTATCTTGTCAGACCGTTTCAATCCCAGAACATACAAAGCAATAAGACTGTCACACTGACAGACCCCAGATTTCGACTTTTAGAAACCTACATCGTGCATGACGGCGTAAAGCATTCAGATCATGAAATATTACGCGATTGATCGAAAAATTTACGAATGCATGGCCATGCTACAAAATCAAGTTTCTGAGAGATAGCTACCTTATCTAAGATACAGATGGTAGACAACCAAAATGGGTAATACCGCCGCGCGTACCGCCGCCGCAGGGCCGCGGCGTTAACTTCAAGTCAGTCAAGTGTTAAAATCCTTCGCGAAACTACCACCAGGTGGCGCAAAGGGACGGATTGCGAACTGAATGTAATTGTAAAATGAGATAAAAGGAGGAGGTAAAACAACAATAACATTATGATATAACATTGTACCATCTTTAAAAAACCATTAAAAAATGTACAGTGAGTTAATTTCAAAATGTAGGATAGTCTTAGGCTACAGTTTACTCA
->URS000030206D rRNA from 1 species 
-GTGGGGTAATGGCCTACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGCGACCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCGACGCCGCGTGAGGGATGACGGCCTTCGGGTTGTAAACCTCTTTCAGCAGGGACGAAGCGCAAGTGACGGTACCTGCAGAAGAAGCGCCGGCCAACTACGTGCCAGCAGCCGCGGTAAGACGTAGGGCGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCTCGTAGGCGGCTTGTCGCGTCGACTGTGAAAACCCGTGGCTCAACTGCGGGCCTGCAGTCGATACGGGCAGGCTAGAGTTCGGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCGATACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGTTGGGCGCTAGGTGTGGGGGGCCTCTCCGGTTCTCTGTGCCGCAGCTAACGCATTAAGCGCCCCGCCTGGGGAGTACGG
->URS0000C8846A pre_miRNA from 1 species 
-GAATTACTCCCTTCGTTCCAAAATTTTTTGTCTTACATTTATGTAGATATGAATGTATGTAGTCATATTTTAGTATTTAGATACATCCATTTATAGACAAATCTAAGAAAAGAATTTTGGGACGGAGGAAGTACAAA
->URS0001332FF6 rRNA from 1 species 
-TACGTAGGGTCCGAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGTAGGCGGTTTGTCGCGTCGGGAGTGAAATCTTACAGCTTAACTGTGAACTTGCTTTCGATACGGGCAGACTTGAGGCATTCAGGGGAGAACGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCAGTGGCGAAGGCGATCTTCTGGACGGATACTGACGCTGAGGCGCGAAAGCTAGGGGAGCAAACGGG
->URS00019FE4B3 tRNA from 1 species 
-GGATTGTGGCTCAGTGGCAGAGCACTTGCCTAGCACGCGCTAGGCCCTGGGTTCAATCCTCAGCACCA
->URS00021AA98B tRNA from 1 species 
-GCGGGGTTGCCCTAGCCTGGTAGGGGGCAGGCCTGCTAAGCCTGTGGCCGATTTCGGCCGCGCGGGTTCAAATCCCGCACCCCGCGCCA
->URS000050F67C piRNA from 1 species 
-GCAGAAGCTCCACCACCACAGCAAAG
->URS000242CB14 lncRNA from 1 species 
-CGGCGAAGCTTTTCCGGTGAGTAATTGGACGGCACAGGGACGGTCTTCCGCGGTGGATTTTTCGGCGATCTCTACCGTTTTCCCCCAGAATTTCTCGATGAGAGGAGAGAGGAGGGTTCTCCTCCTTAAATAGGACTGGAGGGAGATCGTTTCCGACTCCGATTGGGAGCCGGCGAGAGGAGGAAGAAGACTCCCTTCGGGAGTCTTCTCCCCTGTTTTCTTCTCTTTTTTTTTTATTTTGGGCTT
->URS000242DE7D lncRNA from 1 species 
-TAAATCATCGAGCTCTTTTTGACTTAGTGTCAATACAATTTTATGAGATAATAATGTCTATTTCCTAAATCGGAAAAACGAAAAATACAAAAATAAAAATTTTTAAATACGATTTCGGATCTTAAGACTCTTTCCTGAATTGTCTTTCGACCTAAAGATAAATCAAGCTAAATTATAAATCAAACAACAATAAAAAAAATAATAAG
->URS00022EBB93 tRNA from 1 species 
-GGTGCCGTAGCCAAGTGGTAAGGCAAGGGTCTGCAAAACCCTTATACGTGGGTTCGATTCTCACCGGCACCTCCA
->URS00019F1EF9 lncRNA from 1 species 
-ATGGAAATATCTTGGATCAAGTTGGATCCCATTACCTTGAATCATCGACAAATTCTTTCACTTATCGCATTCTCAATCTTTTCTTTATTTTTTATTACAATACATATCGACATGCTTTTGAAAAATATATCATTTACATAAACAGTTAATTTTTTAATATATAACGTGATGTTATCCATTCATCATAATATTTTAACATGA
->URS0002545815 rRNA from 1 species 
-GGCCAGGGAAAAGGACACGGAGGCTGGGACAGCGATGTCCCCGCTCGGGGGCGGCCTGGTGGAGCGGCCGCAGCCGCCCACCTATTCCGAGGTGGGTGCGGCGACTCCCCTATTCAGAGGGGGAGTCGGAGCAGGAGTAGTCGGGGGCTATAAAGCGGTGAGAGAGCGGAGGAGTTACCAGGAGAGACAGCTCCCCCTCTTCGTCGGCTCGGGGGACAGCGGCGGGCGGCAGCGAGTGGCGCCACTGGCGGAGGGGGCACGAGGAGGCTAACCAAGTTGTGGAGGCGGCAGAAGGCGACGATGGAGATGCAGCTGCGCGCGCTCGGCCCTCCGTGGTGTCGTGGCCTAGCTCGGCAGAAGAAGGAGCCTAGGGGCGGCAGCCAGCGGCAGCTAAGTAAGCGGAGGTCGTTGGGGCCGGAGGGGCTCTACGAGAGGGAGAGGCGATGGGGCTCTGGCGACAACTACGGGGACACTAGCTGATGCAGCTGCTGCTGGGAAGAAGGCAAAGTCGCTTCGAAGGTCTACCACCTAGGGACCTTGGTCTACGGTGGCGGCTACCTACGACGATGTACTTCTGGCGGCTGCTGGTACTCATCAATCCTCCAGGGTCCGTCCTCCAGAACGGAGAAGCTAGCAACAACGAAAACACGATCGGAAGAATTCCGTAGGAACAAATTGAATACATATATGAGTCTATAACAACGAAGGCGACTGAGAACACATAGCTCGATACATAAACTCGGGAGCTCCGGGGACCGAACATTATATTTCGAACATAATAAAACTAAACACAGATCTCAACACAACACTATAGAAGGGCACTCAGG
->URS0002061C56 rRNA from 1 species 
-AGTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGGCAGCACAGTAAGAGCTTGCTCTTACGGGTGGCGAGTGGCGGACGGGTGAGGAATACATCGGAATCTACTTTTTCGTGGGGGATAACGTAGGGAAACTTACGCTAATACCGCATACGACCTACGGGCGAAAGCAGGGGATCTTCGGACCTTGCGCGATTGAATGAGCCGATGTCGGATTAGCTAGTTGGCGAGGTAAAGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATACCGCGTGGGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTGGGAAAGAAAAGCAGCAGGTTAATACCCCGCTGTTCTGACGGTACCCAAAGAATAAGCACCGGCTAACTTCGTG
->URS0000EFE3C8 pre_miRNA from 7 species 
-TTAAGGGAGTTATTGACTGGGCTTCCCACCACTTAAACGTGGTTGTACTTGCTTTAGACCTAAGAAAGTAAGTGCTTCCATGTTTTGGTGATGGTATGTTTTCCTTTATATTCATGCCTTT
->URS00025F4A4B lncRNA from 1 species 
-TATTTTTTACAATATATTTTTAATAAGAAAACTGTCAGTTTTCTTGTGGGGATTTTTGATGTTTTTATTGTATTAAAAACTATTGCAAATCAGCTTACAGTTTCAATGTAGGAAAAGGGGTCTGGCTCCTTAGGCAGGCCTGATGTGGGCCATAAATATGATACAAATTTTGAGAGCAGAAAAAATCACAGGGATATTTCAAACTTGCTGACTTTGTGTTACCCCGTAGGAAATGAATCTACCAATAATGGGCCTTATTATTCCACCTCCTGTAGACTAACAAGAGCAATTCTGGTTGTTTATTTAGATACACTGATTTTGCAGACTATACCTCGAGATGGTTGAGCTTAATGTGGTCATACTTATTTGACTAAGGGTAAATTTTTAGCTCTGGCAGAGAGCAGATGTAGCTGTCAACAACTTCCAAGCATAGCTGTCTTTAAGGGAGCTCTTTCTATTAACAGCAAACACTCAGTGAATGAGAGGGCAGTACTTGTACAGTGCATGTCCACAGTTACATGCATATGGCAAAGCATACTTCAGCTTTTGGTTTTGAAACTCATCTCCCACTAAGGCCAAAGCCCTGACATCCTTACTGCCGTGTGTCTGGGATTTTGTTTCAGCGTATGTCCAGTCTTATCTTATGAGCTGAACACCTTCAGTATGTATATGTGCAATTAGCAGTTTGTTCTTGCATGGGTCTGTCAGGGCTTGGGAGACATTCGGCATGTGCATGGGTAGGTTCCCCTGGCTTGATTTTTCTCTGTGAGGAACCTGGTTCATATGCATCGGCACTGCTCTGCAGCCAAGCCCTCATCTGAAAGTAATTGAGTGGCTCTCTTCAAACCTGCCTTGTTGCCCCAACCAAAACATTAGTGTGAGCCCAGTCCCTGACAGCTCACTGCGGTTGGCTCTCTGTGGGCTGATTTGCGTGCTGTGTTGACTGAGTTTCCTCTCAGCTCTAAAGACTGTGTATCATTTATCTATTTTTTTTACAGGTGTCATTATGCAAATTATGTATGCATACAAATATAAACACATATACACAAATCTTACGTGGATAAATATGTAAAAACAAACTTCAATTATACCTACAAACATCCATGTATATGTATATATTTGCCATAATATATTATTGCAAAGGTATTATCTCCACAGTTGATGATGGTCTGAATGCCATTGCAGCTACTGTTATTGTCCTTTGGTTGGAGTGATACCCGTCCAGCACTGCCCTTTATTAGAAGATTATCCGAACTTCTCAGTTATGCAAACAAACAAAAATGTATTCTGTAGGTTTGTTACATTGGTCACAATGTGAAGTGCATTTGTATGAATTGAAAGCACATGGGACTGCAAGCTATAGCTACATTACAAGTTTCCAAGGATATACTGCTGTCAATGTCATTTTTTTTAGCAAAAGTATCTTCACCAAACCTCAAACTACACCTCAAGAAGCCAAGAAATAATAATGGTGGTTTGAGGCATGAAACAAAGGATGGTATTGTTGTGTGGAGGAAGCAAGCACAACCTAGGTAGGTAAAGCATGGTAAGTCCAGGTGCAGTCTCACATCAGTGCCTGACTGCCTGCATTCCATTGGCTTCCTTGCTGCATTTATTTCTTTTCCTATGAGATGCCAAAGCCCCAGCCATGCTAGAGTGTGTGTCTAAGCAATGAGCTGCTCTGTTGATTAATCTGCTGTCGCTGTGGAGCAAATTGCTTGGCATGTTTTAGCTGTGACAGGTGGGTTTCTATTAGCCAGTGTTCACGTAGCTTGCACTATCCATCACATAAAGAATCATGTCATGTCAGAGCTGCATTGTGATCATGACAAGAAGACAGATCAGGTATCGTATAGGGGAAATAAAAATACATGCATGGTGCAAATAAAAAAAATCTTTAGGGTTTCTTTGTTTGTTTGCTTTGTAATTAAGAAGACACAGAGATGCAGGATGAAATTGGGAAATAGAAACTGATAACTGAGTTAGAGGGACATGGTTTTCATCCCAGAGGTTTTTACAGAGTACACAGGGATTAACTGAGTTGTTGAAGCTTGTACTCTCTCTTGCTAATTAAGCCTAAGTTCAATACAGAATAATTGCTTGTGCATTGCAGGTAAGGTGAAGGAGGGAACTCGTTGCTGTTGTGCAGTTCTGCAGCAGGCAAGACCTGAGCTGCATAAAAAAAAGCATTTATCTATGGTAATGTTTTTGTCACCTTTTTGATACTTTAGAAATATTCCTAATTCACTGTCTTCCAGGTAGAGAAGTTATTTCTATTATATAAATGATATTAAATATGTATATTAAAATGTAATGTCCTTTGGACAGTTCTAACTTGTGGGATGAAATGGCAAGGCAGATGGGGAAAATGTCTGTGGGAACAGGGGAGTAACTGGAAGATAAGTGAAAAAAACAGGATCTGACTATTAAAGACATCTGGGAGGTTTGTATGTCTAAAAAATTTGGGGATTTACAATCACAACATGCTATAAAACTGGAGTTGCAAATCAAACTTCTCTTACTTTATATGCCTTGCAGGGGGAGTGAGCCATGTTTTGTGAGTCAAACACAGAACAAAATAGAAACCCCCAAAACACCCCAAGCACACTGGGAAGTCACCCAGAGAGAAGAGATTACGTTTAGAAGAGCTTTTGTTCCCAGTGAGCTAAAGATATTAATACGCATCTGGTATACAATGATATCAGCATACTGAATTGCAGGAAGAGCAGGTTATTGGGGAGTCAGGATCTGTTGTTGAGATTTGTTTGTACTCAGTATTTAGCAAAAAGAAAAGGAATATAATTAGAAGACTGTGAACTGGGGTAAGAGTTGTTTCTTCTAAAGAAGAAACAATGAGGAGAGGATGTCTGCTGAAATAGTCTCTTCATGCAGGCAGCTCAGAGATGTCCACGGAAGGAAATCTGTTCAGTAGCCCATAATCGCTCTGAGTTCCATGTAGATGTTGATCTTTTGTTCAGCTGATTTCCTTTTGGTAGCTGTTTTCTGCTTTGCAATCAAGAGATAGAATAAACGGGACTCCTGCTTTTCCTTATTCTTATCGAACGACAGAGGAATCTTAAGGCCAGGTGTTGGTGTATGCTAGTTGCTCTCCAGGGAACAAAAGCAGCAAGCAGGTGGAGACAGAATGGTTCGCTTCCAAATGTTTCAGAGTTCTTGGGCTTGGGATGTGTTACCTCCTAGCTCAGTTCGACGCAAGGTGGTGGCTTGCAAAAGGAAGCCTCCCATGGCAGCCTTCAGCCAGCATAGCTTTACCAGGCTCCCGTTGAAATGAAGTGAGCGTTTAACTCAGATGATAACTGTGTGTCTTGTGGGTTCCTTCACATCTCCAGTCCGGTTACTGGGAAGTTTTCTCCTCCAACCACCCTTTGACTGTCTATAAATAAGTGTAACAAAAAGGGTACTGAGTACTAATTCACAGTGAATCACAGCTGAACAGTATGATCAGGTGAATCCCATAAAGAGAACTGACAGTGTATTCAGATCGGGTGTTTGCCATTCAAGGATCTGCACCTCTTATGATCTATTTGGGCCCATCTTTCTCTAGCCTTTAGAAAAGACTTCTAGAGTCTTGCTGGTTGTCTTATTAACATGTAGAGATGGCTAACTGGTGAATCACAGCTTCCTTTAAGTAGCCCCTGACATCTGTAGCATTTTGTCAAAGTGTAGAGGGAAATGAGATGAAAGGCTTAAAATGCTGTGTGGCTTTTCCAATTTTAAGTAATGTCAGACATTCTTTGAAGTAATTTGGCCTCTTGTGAAAAATGTTCCCTGTGTTCAAGGGCATCAAAACCAGGCAGCCCTCCTAAAAATAGTACATACTTATTTGTTGAGTTAAAAGTTTCACAGGTATCCTTTTTATGCATCCTACTTTGTTTATCTGTGAAGGTGCTCATTTGTTTGTTTTCCTTGCAAGATTCCTGAGAACGTTCTTATACTTCCAAACCACATTTCTCGAATCTGAGTATGGGAAGGGGGTAGTACATAGATTACTTGCTGAATATACTAAAACTCAATCATATTTAACTACTTTATGAAGTCTGTTTAAGTTTTGTAACATTTAACTACTTTAATTCTAGGCTAGATCCTCTTTTCTGCTAACTTGTTTTCCTAGTGAAAAAAGAGAAAATAATAGGTGCATTAATTGTTAGTTAAGGTAGCAGGCCATGGTGAACCTCTTAACATTCTCCTATTTTATGAGCATAAAACTTCTATTTTAATAATGCCTTGCAATAAAGGATCTTTTCATGGCAGCTAAATGATGTACAATGGTAATATTTCTACAAGAAAATTAGATTTTGATATTGCCTTGGTTTTCAGTGAAACAAAAGAATTTGTGAAGAACTTGAAAGAGAATACCACTCATCATCATGGACAGCTGATGAAGAAGACGGAACCAGGGAAGAGTGGTTGAGATTCTTTTTTTCTAGTTAAAGGAAGCAGGAGATGTTCTTGCTCTAGCAAACAGCACTGACATGATCAAGAATCTCTGAAAATCCCTGGAGAGATCTCTCCAAGTGAGCATTGAATTAACTTCCTTTCCTACTGTTCCACTCTGTACAAAAGAAGTCCTTCCTTCAAAAGTCCTTGGAATACAATGCTGTGTTTTGTAAGCAGAGTCCAGAAAAGCACAAACACCTCTAACAAAAGAATAGTAAATAATGGCTATTTCTACTCTCATTACCCTGGGCTGCACTTCCTCTGCTATCAGGCACTGTGACAGCAGGGAGGCAGGCATTCTCTTGCTACTTTATGATTCAGTAAGAAAAGGATGAGGTTCCAGAAGTGAAGGATGTAGAAGAGATGACTTCAGTTGGTGCACAAGACATTTATTTCAAGTAGCCGTTTCAGGGCTAAGACTTTGCCCACCATCTTCACCCCCTGCAGTACTCTGGTTTCTGAAACTTCAAGCCTGCTGAGCAAGCCTGTTAGGTTTCACAGAAGGAAAATTCAGATGTGTAGACTCAGGGGAGCTGGGGAGTCCTCTGCAAAGTGGACTTGAAAATACTTCTGCAATTTGCTGAAACAAGTAAACTGAAGTGCAGAAGAGAGGCTGAGACGTGGCAAGGAATCGGTTAATCCTGAAATGTAAAATATGTGAAAAATCTGCACTATTTTGATTTTTAGCATATATGGTATTGCTGGGTTAGGTTTCCTAGGGTTTCATATGTACAAAAAAATCACTCATCACAATACTGTGAAATAAATGCATTTACATGCCATACCAGAATCTGATATTATTTGCCTGTACAGGGTTTCATAAGGTGGACCTCTGTGGAAAATGACTTAAGACTTCCAGCAGTAACTTCTCCTTCTCTCTTGGAAGAGAAAGATATCCTTGTGCTCTTGGTTCTGTGTATTCTGGAGCTTTCCTGTCAGCTTGAGTGGATCAGAACAAGTCTGTCTCCATTGATCAGACTTCTGAAGATTAATGCTCAAACACTGAAACTTTCCCCACGCTGCACTGCTAAATTGATGCAGCAAAACACTTGAACACACACAATCAAACTGAAGTTTAAAACAAGTCACACAGAATTGAGTTTACCTTTGTATTAGTTTAAAATCTGCTTGAAGACCATTATCTTTGTGCATCCTTTCAGGAAAGCTTTATTAGGCACCAGAGGAAATTATTTCTAGACCAGATGTAACCTAAATACACTCCAGGATTGCTGCCCATTAGTTTTTGTTTTTAAAGACTGGAATAGAAAATTAAGTGCAAATGAAATGTTTAGGAAAGTATGACCATAACTACATCAATCTGATTATGCAATTAAATGGCCTTTATAATAATAAAAAAAAGACTGTGCTCTCTAAATGTTAGACATATGCCAGTAAACCAGTTTTACTTTCAGTTGCTGAATAAGAAGCGTGGGAGCGCATTGTTCCATTTCATTTTCTTCTCTGCTGCTTTCTGTTTAAAGTCAGACATAGCGAAAAAAGAGGAGCTCCTCAGTAAGAGCTGTAGTATGGTTTGTCCTTGATTTACACAAAGTCAATGTTGCTGTTTGAAACAGTCCCTCAAGTTGTTACTTTTAAATGTTAGCTTTAGCAACTCTAAAATTAGTTTTAGCTTAGCATGGTAACCAGGGGTTATTATTTTTCCCCTTCAATGAGAGGGAGTCTGAATATCAAATTCATACACTTTGGTCCTTCTTTGATTAATGAACAGGCTCTTTCAGTGTGTGGTTTAAAATGCACTTATAAAAATGAATTTTACAGCATTAATTTAAAAAAGTAATATATGAGTATGGAACTCCTGTTTCATCTTCCC
->URS0001447AD9 rRNA from 1 species 
-CACGTAGGGTGCGAGCGTTGTCCGGAATTATTGGGGCGTAAAGAGCTCGTAGGCGGTGTGTCGCGTCGGCCGTGAAAACCTGTGGCTTAACCATGTGGTCTGCAGTCGATACGGGCAGGCTAGAATTCGGTAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCGATATTGACGCTGGAGGAGCGAAAGCCGTGGGGAGCGAACAGG
->URS00001955B1 rRNA from 1 species 
-CGGGGTGCAGCAGGCGCGAAAACTTTACAATGCTGGCAACAGCGATAAGGGGACCTCGAGTGCCAGGATACAATCTTGGCTGTCGCGATGCCTAAAAAGCATTGCATAGCAAGGGCCGGGCAAGACCGGTGCCAGCCGCCGCGGTAACACCGGCGGCTCGAGTGGTAACCGCTATTATTGGGTCTAAAGGGTCTGTAGCCGGCCGGATAAGTCTTTTGGGAAATCCAGCTGCTCAACAGTTGGGCTTTCAGAAGATACTGTTCGGCTCGAGACCGGGAGAGGTGAGAGGTACTTCAGGGGTAGGGGTGAAATCTTGTAATCCTTGAAGGACCACCAGTGGCGAAGGCGTCTCACCAGAACGGATCTGACGGCAAGGGACGAAAGCTAGGGGCACGAACCGGATTAGATACCCGGGTAGTCCTAGCCGTAAACGATACTCGCTAGGTGTCAGCCACGGTGCGACCGTGGTTGGTGCCGTAGGGAAGCCGTGAAGCGAGCCACCTGGGAAGTACGGCCGCAAGGCTGAAACTTAAAGGAATTG
->URS000146AAE0 rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGAGTGGCGGACGGGTGAGTAATGTATGTGAAACTGCCTGGTGGAGGGGGATAACTACTGGACACGGTAGCTAATACCGCATACCATCGGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAAAGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTTGTAAAGCACTTTAAGCGGGGAGGCGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCCGCCGCGGTAATAC
->URS0001DA31B7 rRNA from 1 species 
-AGTGAACGCTGGCGGTAGGCCTAACACATGCAAGTCGAACGGCAGCACAGTAAGAGCTTGCTCTTACGGGTGGCGAGTGGCGGACGGGTGAGGAATACATCGGAATCTACTTTTTCGTGGGGGATAACGTAGGGAAACTTACGCTAATACCGCATACGACCTACGGGTGAAAGCAGGGGATCTTCGGACCTTGCGCGATTGAATGAGCCGATGTCGGATTAGCTAGTTGGCGGGGTAAAGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAGTGGGCGCAAGCCTGACCCAGCCATACCGCGTGGGTGAAGAAGGCCTTCGGGTTGTAAAGCCCTTTTGTTGGGAAAGAAAAGCAGCAGGTTAATACCCCGCTGTTCTGACGGTACCCAAAGAATAAGCACCGGCTAACTTCGTG
->URS00016B5AE1 rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGTTCGGATTTACTGGGCGTAAAGCGCACGTAGGCGGACTATTAAGTCAGGGGTGAAATCCCGGGGCTCAACCCCGGAACTGCCTTTGATACTGGTAGTCTTGAGTTCGAGAGAGGTGAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAACACCAGTGGCGAAGGCGGCTCACTGGACTGGTATTGACGCTGAGGTGCGAAAGCGTGGGGAGCAACAGG
->URS00023938D4 lncRNA from 1 species 
-TGGTCTATGTTAGTAGCTTGGACAATCTACATAGTACTTTAAAGAAGTTTTTTAAGTGATGGTTTGGACCGTATGTGGTAACAATTACTCATGATAATGTAACTTATTTGTTGCGGGAGTTAGATGGAACAAGGTTAAAAATACCAATTATAAGGAAGCGAGTAAAAATATTTAAATAAAAATATACGGAAATAAATATAGAAGACCTTATTGAGGACATAGATATTCATCAACAGGAAGATGAATTTGACTTGAATAACAAAAGTGATGAAGAGGATTTGAATGGAAACTTGAAGAACATATTATGAATCAAACAACAACTAGGTGATTTGGTGCATACCATTAGATGCACAGGTTCAGAGGGGATGTATGTCGTATTGTAACATGACTATATGATGAAAATATAAATTAAAAAGATTTTATTAATATTTAGTCATCTTGGATGTTAGAAATAGTGGCCAATTCCAGTACCAATATTCAAGGGCCAGTTAATGTCACTCTATTGTAAGTTATACCACCGTATGTGACATCAGCAATATGCTCTACCAACGTCATCAAATTTAGTATCCTCCATATCAACGGGACAACTAGAATTATTTTCTAACCCTATATGGAACAAGCCTAGTAGGTATGTACCGATGGAGACAACCAATATGCTTGATGGGGGTACAAGAAGACTATTTCGTTGTTTCTATTACAAACAGATTGGTCATTATGCTAATGAATGGTCCAATCCCAGACCCAGTGACAATTGTGCACTAGTGTGTGGGAATTGCAAGCAGTCAGAGCATACTTATTAGCAAAATAATGCTCCGTTCAATTTTAATAATCAAGATCCGCAAATCCAAAGTCAAGAAAGAAATTGAAGAGATAAATGGAAGACTCTAAGATTCTCTGATAAATTGAGTGGAATGTGTCTAAGCCGTTCTTACCGAGAGTCCGCAAAAGGAGATAGGACCAATTCAACAATTAG
->URS00018A4A88 rRNA from 1 species 
-TACGTAGGGGGCTAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCGTGTAGGCGGCCAGGTAGGTCTGCTGTGAAAACTCGAGGCTCAACCTCGAGACGTCGGCGGAAACCATCTGGCTAGAGTCCGGAAGAGGAGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAGCACCCGTGGCGAAGGCGGCTCTCTGGGACGGTACTGACGCTGAGACGCGAAAGCGTGGGGAGCGAACAGG
->URS0000CC585E snRNA from 1 species 
-TTGCTTTGGCAGCAAATAACTAAAATTGGAATGATACAGAGAAGATCAGCAGGGCCCCTGAGAAAGGATGACATGCAAATTCACACAGCATTCCATCACAGC
->URS0001480F9E rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCTTAACACATGCAAGTCGAACGAGTGGCGGACGGGTGAGTAATGCTTGGGAATCTAGCTTATGGAGGGGGATAACTACGGGAAACTGTAGCTAATACCGCGTACCATAGGATGAGCCCAAGTGGGATTAGGTAGTTTGTGAGGTAAAGGCTCACCAAGCCGATGATCTCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGGCAATGGGGGAAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGCCTTCGGGTCGTAAAGTACTTTCAGTCGGGAGGCGGTACCGACAGAAGAAGCACCGGCTAACTACGTGCCAGCCGCCGCGGTAATTC
->URS0001FB3C4B rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACAGACGAGGAGCTTGCTCCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAGACCGGAGCTAATACCGGATAATATATTGAACCGCATGGTTCAATAGTGAAAGACGGTTTTGCTGTCACTTATAGATGGATCCGCGCCGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGGCCAGACTCCTACGGGAGGCAGCAGTAGGGAATATTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACAAATGTGTAAGTAACTATGCACGTCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTG
->URS0000CF422D rRNA from 2 species 
-ACGGGAGGCAGCAGTGGGGAATATTGCACAATGGAGGAAACTCTGATGCAGCGACGCCGCGTGAGGGAAGAAGGTTTTCGGATTGTAAACCTCTGTCCTTGGTGACGATAATGACGGTAGCCAAGGAGGAAGCTACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTACTGGGTGTAAAGGGAGCGTAGGCGGGAAGGTAAGTTGACTGTTTAAACTATCGGCTCAACCGATAGTCGCGATCAAAACTGCCATTCTTGAGTGAAGTAGAGGCAAGCGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGGCTTGCTGGGCTTTAACTGACGCTGAGGCTCGAAAGCGTGGGTAGCAAACAGGATTAGATACCCTGGTA
->URS0000E65B77 lncRNA from 1 species 
-CTGATCTCTATTCCCGGATCTGCCTCTGGCTTCCTGCGTGACCTTGGGCTGGTCACCTACCTTTTCTTTTCTTTGGTTCCCAAATTGTAACATGGAAATAATTCTCTTCCTGCGGTGCCTCAGCCCCTGCTGCCTTTAGGGTGGTCGAGATCCTCTGACGGGAGGAAGGTAGCACGTTTCCACTGGAGAAATACTTACCCAGAGCACGGTAATTTGGGGGCGTGTTGGTGTTCACTCGGGTACAGCAGGGTGCGTGCTGCTGCTTGTGCTTTTTTTTTTTTTTAGTAGGCAAACCTGTGGTGGAAGTCAAATTCCGTTTGTGGTGGATGCAGAGCAACGTCAGCTGCAGCGTGCCCTTTCCTCACTAGGAGATGGTTACCTAGCCAAGGTCACTGCTGCTGCATGCCTGTATCACGCAGCGAGCCAGCCTCCTCTTCCTTCCACGGGCGCTGATCTCAGCGAGGCTTCCCCAGAGCCAGCTGCTCCCGGAATAGTTTGGGAATGAAATGTCACCGTTTGAAACTGCTGGATCCTAGCGCCTTCTCCGACAGGACTAGGTCGTATCTGTCTGACAACGCACCTACAGTGACTCTCTTAATTAAGTCTCCCTGCACTGCTGTGAGGGCAGCATTCTGTGTTCCTGCTCCAGCCTACGAGAGCCAGCCATTTCCACGCGGCAGCTCTGCCTCGTAGGCACTAAGAAATGGGCACCTTGAGCTGAAGTGCCATGGTTGTTGTAGTACTACTGGTGTACTACCGAGCGGTCCCGGGCGTGCTGACTGTAGCTGTCGCTGCCCCAGCCTGCTGCCAGAGGTTTGTG
->URS000031FA0E piRNA from 5 species 
-TGTAAACATCGTACACTCTCAGCT
->URS0001CC563E rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACAGACGAGGAGCTTGCTCCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATATTGAACCGCATGGTTCAATAGTGAAAGACGGTTTTGCTGTCACTTATAGATGGATCCGCGCCGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATGAGCAGAAATGGAAAGGAGAAAGCGGAAAGCACAGTCAGGGAGGAACAAGTGGGGAAAATGGGCGAAGGGGGGCAAGACTGAGACAGAAATAAAGAGGGGGTGAAGAAGGTGTTAGGGTCGTAAAACCTGTTTGTTGGGAAAGAAAAGAAGCCGGCGAATACACAGGTGCCGTGAAGGTACCTAAAGAATAAGAAAAGGATAACTTCGTG
->URS0002428F28 lncRNA from 1 species 
-GTGAATAGTGGCCTCCTGGGTAAATGAAGGTGGTGGCGAAATGCGGTCACCTCGCTGCTCCCAAATATGGACCTGCTGCTGGAGCCATCCATAAATATATTGTCCACCCTGATACGGTCATCCCGCTGATAGTGTGTAAGGGACCTATGAAGGCTCCCCTGGTATAGGATGGGGACAGTGAAACTAGCGAAGCACACGCTCTGTGGCATGATACTCAACCATATCAAAGAAGATCATCGGGACCGAGGTGGCCAAAGCAGTCGGTCGACTGAGCAATAATAGGGCAACTGAGCTAGCAACTCGTCGCTGTATGGCGTCCAGATGAA
->URS000018DC94 rRNA from 1 species 
-AACGAACGCTGGCGGCGCGCCTAACACATGCAAGTCGAACGAGAATCCGGGGCAACCCGGTAGTAAAGTGGCAAACGGGTGAGGAATACATGGGTAACCTACCCTTGAGAAGGGAATAACCCGCCGAAAGGTGAGCTAATACCCTATACGCTATCTTTTTTTCGAAAAGGATAGGAAAGCCGGGTCGAGGACCTGGTACTCAAGGAGGGGCTCATGTCCTATCAGCTTGTTGGTGGGGCAACGGCCTACCAAGGCTACGACGGGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGCACTGAGATACGGGCCAGACTCCTACGGGGAGCA
->URS000019B6AB rRNA from 1 species 
-CCGTTGCCGGCGACCGGCGCACGGGTGAGTAACACGTATGCAACCTGCCCGTGGCAGGGGGATAAGCCGGGGGAAACCCGTCTAATACCGCGTAACGCGGCCTTGGGGCATCCCAAGGCCGCCAAAGGGAGCAATCCCGGCCACGGATGGGCATGCGGCGCATTAGCTAGTCGGCGGGGTAACGGCCCACCGAGGCGACGATGCGTAGGGGTTCTGAGAGGAAGGACCCCCCACACTGGTACTGAGACACGGACCAGACTCCTACGGGAGGCAGCAG
->URS000060EFE9 rRNA from 1 species 
-AGTGATTTTAAGTCATGCAAGTCGAACGAACCTTGTGTTCGTGGCGAACGGCTCAGTAACACGTGGATAACCTGCCCTTGGGACCGGGATAACCCCGGGAAACTGGGGATAAACCTGGATAGGTGATGCGGCCTGGAATGGTGCTTCACCGAAACACCCCTCGGGGTGCCCAAGGATGGGTCTGCGGCCGATTAGGTAGTTGGTAGGGTAACGGCCTACCAAGCCCATCATCGGTACGGGTTGTGAGAGCAAGAGCCCGGAGATGGAACCTGAGACAAGGTTCCAGGCCCTACGGGGCGCAGCAGGCGCGAAACCTCCGCAATGCACGCAAGTGCGACGGGGGAACCCCAAGTGCCACTCTTAACGGGGTGGCTTTTCAGAAGTGTAAAAAGCTTCTGGAATAAGGGCTGGGCAAGACCGGTGCCAGCCGCCGCGGTAACACCGGCAGCTCAAGTGGTAGCCGCTTTTATTGGGCCTAAAGCGTCCGTAGCCGGTCTGATAAGTCTCTGGTGAAATCCCGCAGCTTAACTGTGGGAATTGCTGGAGATACTATCATGACTCGAGGTCGGGAGAGGCTGGAGGTACTCCCAGGGTAGGGGTGAAATCCTGTAATCCTGGGAGGACCACCTGTGGCGAAGGCGTCCAGCTGGAACGAACCTGACGGTGAGGGACGAAAGCCAGGGGCGCGAACCGGATTAGATACCCGGGTAGTCCTGGCCGTAAACGATGTGGACTTGGTGTTGGGATGGCTTCGAGCTGCCCCAGTGCCGAAGGGAAGCTGTTAAGTCCACCGCCTGGGAAGTACGGCCGCAAGGCTGAAACTTAAAGGAATTGGCGGGGGAGCACCACAACGCGTGGAGCCTGCGGTTTAATTGGATTCAACGCCGGACATCTCACCAGGGGCGACAGCAGTATGACGGCCA
->URS000043FDF3 rRNA from 1 species 
-AGCAGCCGCAGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAATTTCAGGCCTGGCTGGACGGTCCGCCCTTCGGGTGAGTACTGTCTGTGGTCGGGTCCTACCTTCTGGCGAAGCGTCATGGCCTTAACCGGCCGTGGCGGGGAACCAGGACTTTTACTGTGAAAAAATTAGAGTGTTCAAAGCAGGCAAATCGCTTGGATACATTAGCATGGAATAATGGAATAGGACAATGGTTCTATTTGTTGGTTTCTAGGACCGTTGTAATGATTAATAGGGATAGTTGGGGGCATTAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGAATCGGGCGATGTTGAAAAAATGACGC
->URS000076D469 rRNA from 1 species 
-ACGGAGGATGCAAGCGTTATCCGGATTCATTGGGTTTAAAGGGTGCGCAGGCGGAATGATAAGTCAGTGGTGAAATCCTACGGCTCAACTGTAGAACTGCCATTGATACTGTTATTCTTGAGTACACTTGAAGTGGGCGGAATGTGTCATGTAGCGGTGAAAAGATTAGAGATGACACAGAACACCGGTGGCGAAGGCATCACACTAAATTGTAACTGACGCTGGTGCGCTAAAGTGTGGGGATCAAATAG
->URS00025935AF lncRNA from 1 species 
-TTAAAATTAGCTAAAATTTGGTATGGAGCAGGTTAGTAAGTAAAGCAGGAATGCAGAGTTGCTTAGGCCGGTATGGAGCAGGTTAGTAAGTAAAGCAGGAATGCAGAGTTGTTATGGTTGGTATGGAGCGGGTTAGTAAGTAAAGCAGGAATGCAGAGTTGTTCAGGTTGTGTGATGCTTTTGTGTAATACCTCTTTAATTGGAACTCAACTGCAGAATTTTCTGAGGGCAGGAACAGTAAGTTTCACCTCCTATTATATTGGAGTGAAATCAGTGGACTGTATCTTTAAATAATAATCAGGAAAATGCCAAGTTAGTTCCAACTTGAATTTTAATAATGAAGTTTTAGCCTTAGCAGCAATCCTTATTTGTCAACAGAGAGTTTAAAGAAATTAAATACTATAATTAATTGATATGACTTGCTTTCCTTGACAAAAGATTTACTTAACTTAGAAGCACTCTGGCACTGGAAGGGTTAATTCACCCAATGGAGGAAGAGGAAGGAGTCTCTTTTAACAAACTGCAGTTTAGTAGTGAGAGAAAGGAAGTCCGTTTGTCCAAGCCGAGGTCTGAGAGAGGAGAAGGTAGAAATCCGTTTACAAGCCGAGGTCTGGGAGAGGAGAAGGTAGAATTCCGTTTATAAGCCGAGGTCTGAGAGATGAGAAGGTAGAATTCCGTTTACAAGCCAAGGTCTGAGAGAGGAGAAGGTAGAAATCCGTTTACAAGCCGAGGTCTGAGAGATGAGAAGGTAGAATTCCGTTTATAAGCCGAGGTCTGAGAGATGATAAGGTAGAAATCCGTTTACAAGCCGTGGTCTGAGAAGTGGAGCCGGTAGCATCGAGTAGAGCAGCTGATCTCACTGCCGCACCTGAGTGAATAATCCAGCACTTTGAATCTGGCGCGGTCTTCCTAAGTATCGTGGAAAGACCGCGTCAGAAAAAAGGGGCGGAGCTAAGTGCCGTGAACCCGGAAGTGGGTTCCGGCGGCAGCATGATTGTTAGGTATACCTGACAGTACCCCCTTCTCATGGGGCATCCTCTGGGTGCACTTATTTCGGTTTAAAGGGGTAGCGTTTGTGAAAAGCATCAACTAATCTCTTAGCATGAACATTAGATGAATCTTCCCAGGTATCTTCATCTGATAAGGTATTGTAAAGAGCCACGGTGGATACAAGAATCCAAAATCTTATGAATTTCATATTCTTCTTCACCTTGGACGATGATAGGTTCAGGAGTTGTTACTATTTCTCTATGGAAAGGATCAGGGATGTGTGGTTTAAGCAAAGAGACATGGAATACTGGATGAAGTTTAAAACTTGGAGGAAGTTTTAATTTAACAACGTTATCATTGATGATTGTAGTTATTTGAAAAGGACCAAGAAAAAGAGAGCTCAATTTCTTTGAAGGACGGTTTGTGGTAATATTTTTTGAAGAGAGCCAGACAAGATCCCCCACTTTATAAGGAGGGGGAATTCTTCTATTATGGTCAAAAAACTTTTTCTGGTAGTTTTGGGCGAGTTGAAGATTCTCCCGTAATTTAAGGAATAGAGAAGACATAAATTCATTTTTTGAAGTAACCGTGGGATTGGATGAAGAATTAGATGGGATGGGAAATGAGGACGGATGAAAACCATAGTTGGAGAAAAAAGGAGTCATTTTCGTACTAGAATGAATGGTATTATTGTAAGAAAATTCAGCCATAGGTAACAAAGTGGTCCAGTCATCTTGCAGGTATGAACAATAACATCGGAGATATTGTTCCAAACATTGATTAACTCTCTCTGTTTGCCCATTAGTTTGGGGATGATAGGCAGAAGAGAGTTTGCGTTGAATTTGAAGAGAGAGACACATCTCTTTCCAGAATTTGGAGGTAAATTGTGTCCCCCTATCAGAAATAATTTCTTCTGGAAGACCATGAAGCTTTACAATATTATCAATAAAGACTTTGGACAATTCTACGGAGGAGGGTAATTTTTTTTTAAAGAGATGAAATGGGACATTTTAGTGAAGCGGTCCACAACAACAAGAATAGTGGTGAACTGTCGGGATGGAGGAAGGTCAACAAGAAAATCCATAGAAATGGATTGCCAAGGTTTTTCTGGAATAGGTAAGTTAAGTAGTAATCCAAAAGGTTGGTTATGTTCAGATTTGGACCTTTGACAGATAGGACAAGTTTTGACATATAATTCAATTGTTCTATCTTGGCGAGGCCACCAATAATATCGTGAAGTTAGTTCAAGAGTTTTCTTTATTCCAGGATGTCCAGCTAGGGGTGAATCATGAACCATTTTGAGTAATTTGTTCCTAAGAATGGGAGGAATATAAATTCAATTTTTAAAGTAAAATATACCATCCTTTTTTGTTAAATTAGGTGTTTTGGGAAGTTCAAAATCCTTTTGATTCAAGTTCCTTAAGTCATCCTGAAGAGAAGAGAGGATCCCTATTATTTTGTTAGGAGGATAAACATCAATAGAAGTTTTAGAAGGAATTCGAGAAAGAGCGTCAGCCTTTTTATTTCTAGTTCCAGGTCTGTATATTAATTGGAAGTTAAACCGGTTAAAAAATAGGTTCCATCTAACTTGTCTAGCCGTAAGGGTTTTATTAGTATAGAGATATTCAAGATTTTTATGGTCTGTATAGACTATGATAGGTTGATTTGTATCTTCTAATAGATGGCGCCAATTTTCAAAGGCAGCTTTAACACTTAATAATTCCTTTTCACCAATAGGATAATTTTTTTCAGCAGAGCTCAAGGATCTTGAAAAGAATGCGACTGGATGAAGTGGATCTTGAGGAGTCTTTTGCTGAGAAAGAACTGCTCCGATAGCTGAATCTGATGCATCGACTTCTAGGACATACAAGAATGTTGGATTAGGTAGCTGTAGAATAGGTGCAGTTGTAAATCATTTTTTTAAACTGTCGAAGGCAGCTTGTGCATCTTTATTCCATTTGAAAGGACGTTTAGTACTGTTAAGGAGGTTAAGTGGATGTGATACCTCTGAATAGTTTCTAATGAATTTTCTATAGAAGTTTGCAAATCCAAGAAATCGTTGCAATTCTTTTGTAGTAGTAGGAACGGGCCAGTTAATAATACATTCGATTTTAGAGTTATCCATTTTCAGAGAATGAGGTGAAATAATGTATCCAAGAAAGGAGAGTTCAGTAACTTCAAAAAGACATTTCTCTGGTTTAGCGTATAATTTGTGAGTTCTCAATCTAGATAGAACACATCTTACATGCTTCCTATGTTCATCCAAATTGTTAGAATATATTAGAATATCATCTAAGTAGATAATAACACAAACATCTAAAAGATCTCTAAAGATATCATTTATAAAATGTTGGAATGTTGCAGGGGCATTACAAAGCCCAAAAGGCATCACTAGATATTCGTAGAGACCATATCTAGTCCGGAAGGCGGTCTTCTATTCATCATCCTGTTTTATTCTAATGAGGTTATATGCGCCTCGGAGGTCGAGTTTAGTGAATATAGTTGCAGTTCTTAACCTTTCAATTAATTCATTTATTAGTGGAAGAGGATAACGATTTTTTATGGTTATTTTATTTAAGGCTCTGTAATCTATAATGGGTCGGATGGTTTGGTCCTTATTCCTCACAAAAAATATACTAGAGGCAGCCGGTGAAGTCGAGGGTCTGATGAATCCTTTACGTAAATTTTCATTAAGATATTCTTTTAAGGTCTGTAATTCCTTTTCAGAAAGTGGATAAATGTGTCCATAAGGAATGGGAGCACCAGGTATTAGATCTATTGGGCAATCATATGCTCGATGAGGTGGAAGTGTTTCCGCTTCTTTTTTACAAAAGACATCTGAAAAGTCAGAGTAGAATGGAGGTATAATTGATTCCTGAGTAGTTTGGAGAATAGGAATATGTTGGTTCCATTGAAATTGGCTGGATTATTCTGTGATGCTTTTGTGTAATACCTCTTTAATTGGAACTCAACTGCAGAATTTTCTGAGGGCAGGAACAGTAAGTTTCACCTCCTATTATATTGGAGTGAATTCAGTGGACTGTATCTTTAAATAATAATCAGGAAAATGCCAAGTTATTTCCAACTTGAATTTTAATAATGAAGTTTTAGCCTTAGCAGCAATCCTTATTTGTCAACAGAGAGTTTAAAGAAATTAAATACTATAATTAATTGATATGACTTGCTTTCCTTGGCAAAAGATTTACTTAACTTAGAAGCACTCTGGCACTGGAAGGGTTAATTCACCCAATGGAGGAAGAGGAAGGAGTCTCTTTTAACAAACTGCAGATTTAGTAGTGAGAGAAAGGAAGTCCGTTTGTCCAAGCCGAGGTCTGAGAGAGGAGAAGGTAGAAATCCATTTACAAGCCGAGGTCTGGGAGAGGAGAAGGTAGAATTCCGTTTATAAGCCGAGGTCTGAGAGATGATAAGGTAGAAATCCGTTTACAAGCCGAGGTCTGGGAGAGGAGAAGGTAGAATTCCGTTTATAAGCCGAGGTCTGAGAGATGATAAGGTAGAAATCCGTTTATAAGCCGAGGTCTGAGAGATGATAAGGTAGAAATCCGTTTACAAGCCGTGGTCTGAGAAGTGGAGCCGGTAGCATCGAGTAGAGCAGCTGATCTCACTGCCGCACCTGAGTGAATAATCCAGCACTTTGAATCTGGCGCGGTCTTCCTAAGTATCGTGGAAAGACCGCGTCAGAAAAAAGGGGCGTAGCTAAGCGCCGTGAACCCGGAAGTGGGTTCCGGCGGCAGCATGAATGTTAGGTATACCTGACAGGTTGGTATGGAGCGGGTTAGTAAGTAAAGCAGGAATGCAGAGTTGTTCAGGCCGGTATGGAGCAGGTTAGTAAGTAAAGCAGGAATGCAGAGTTGTTATGGTTGGTATGGAGCAGGTTAGTAAGTAAAGCAGGAATGCAGAGTTGTTCAGGCTGGTATGGAGCAGGTTAGTAAGTAAAGCAGGAATGCAGAGTTGTTATGGTCGGTATGGAGCGGGTTAGTAAGTAAAGCAGGAATGCAGAG
->URS0001BC7D2F tmRNA from 13 species 
-GACGGGAUUUGCGAAGCCCUAGGAGCAUGCCGAGGGGCGGUUGGCCUCGUAAAAAGCCGCAAAAAAAUAGUCGCAAACGACGAAAACUACGCUUUAGCAGCUUAAUACCCUGCUUAGAGCCCUCUCUCCCUAGCCUCCGCUCUUAGGACGGGGAUCAAGAGAGGUCAAACCCAAAAGAGAUCGCGUGGAUGUCCUGCCUGGGGCUGAAGCGUUAAACUCAAUCAGGCUAGUCUGUCAGUAGCGUGUCCAUCCGCAGCUGGCCGGCGAAUGUAAAGAUUGACUAAGCAUGUAGUGCCGACGGUGUAGUAAUUUCGGACGGGG
->URS00004B6BEF rRNA from 1 species 
-CACGTAGTTAGCCGGTGCTTTTTCTGCAGGTACCGTCACTTTCGCTTCTTCCCTACTAAAAGAGGTTTACAACCCGAAGGCCGTCGTCCCTCACGCGGCGTTGCTGCATCAGGCTTTCGCCCATTGTGCAATATTCCCCACTGCTGCCTCCCGTAGGAGTCTGGGCCGTGTCCCAGTCCCAGTGTGGCCGGTCACCCTCTCAGGCCGGCTACCCGTCGTAGGCTTGGTGAGCCATTACCTCACCAACTACCTGATAGGCCGCGAGTCCATCCTTGACCAAAATTCTTTCCACAACCAGACCATGCGGCCAGCTGAAATATCCGGTATTAGACACCGTTTCCAGTGCTTATCCCAGAGTCAAGGGCAGGTTACTCACGTGTTACTCACCCGTTCGCCACTAATCCACCCAGCAAGCTGGGCTTCATCGTTCGACTTGCATGTGTTAACGCACGCCGCCAGCGTGTCCTGTAGCCAGGACGTCAAACGTCT
->URS00023C0FDA lncRNA from 1 species 
-GGAAATTAGAAATTAAAACTGTCACTAAAGGGCCCTATAGCGACAGAACCGTCGCTACAGGTGTTCTTGGTGTTCTTGATGCCTGCCCAGATCTTCAAGTCAGTGAACAAGGTAGGTGGTTTGACCGGATATAGATCTTTGGTCCTTACGTTTTCTGGGCTGCTAAAGTGTTAAGATTGTAGTACTTATGTAGTACTACAACTACAAACGACTGTCATGGCCATCATGCATCTAAACAGAAAGTTATAGGCCATCAAAATCCTTGTCAGACATGTTCTTCATTTTCTGGGTTACCCAGAAAATGAAGAACAGTCAAGGTACCTACTTTGGATCCTTATAGTTTGCAGTATAGGTCTTGTTTGTATAATATAGTGGTTCCATCATGTAGAAATAATGTCAGAGTACAACTACATACCCTCATATAAGTCTAATCAACATTACAGATGAGAGATTAAGGCCGGTCAAAGT
->URS000109A09B rRNA from 1 species 
-TACGTAGGCAGCGAGCGTTGTTCGGAGTTACTGGGCGTAAAGAGTGCGTAGGCGGTTTTCTAAGTTTGGTGTGAAATCTCCCGGCTTAACTGGGAGGGTGCGCCGGAAACTGCGAGGCTAGAGTGTGGGATGGGAGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAGGAACACCTGCGGTGTAGACGGCTCTCTGGACCACTACTGACGCTGAAACACGAAAGCGTGGGTAGCAAACAGG
->URS0000E5769B tRNA from 1 species 
-AGCTCCGTGGTGAATAGATCATGTTGAATTGCAAATTCAAAGAAGCAGCTTTAACGCTGCCGGGGCTTC
->URS00026126AE lncRNA from 1 species 
-CCACAATGATGTTTTAGGGGCTCTGTTTTTTGTTGAGGCTTAAAATACTGTACTATTTGTTGATATATTTCAGACCACTGCGCCCCCAACCCGTGCCAGAACGGCGGTACGTGCCAACCATCAATCTGGCCCCACGAGCCCCACCTGATCACCTGCCAGTGTCCACCTGGGTTCGAAGGTCCTCTGTGTCAGTACACAGCTCTAGATCCTTGTAGTCTGCCTCTCAGCACAGGTTCTTGCTCAAGCAGAGAGTCGAGATGGTACTTTAACCAGCTCAGCGGACGATGTCAGAAGTTCACATATCTTGGTTGCCATGGCAATGCAAATAACTTTGCCTCCATTTTTGAGTGCCAAGAGAGATGCATCAAAGGATCATGCTGTACCCGCACCCCAAAAATTCGTAGTCAGAACATTGGATTTGACAGTCAAGGATATGATAAGTATGTCTGACTTTTTTTATGAGTTCTTCTGTGTCATTTTGTTGTTGGCTTATCATTGTGTTCACCTGTTTCAGTTGAAATATCTGCTGCATGAAAAAATAGAGGATGCAAAACAATTTTTGTGGTCTGTAATTTTTCAAAGTCCTCTGGGTTTTAAAAAAATAATAATTTAGGCGCAGTTTTCTTTGCTGTTTCTTCTTGAACACGTACAGTTTATTATAGTAGAACAGCCAAACCTGCCGTGATGGTCACCTGTTCTTGTTAAAAATAGATGGGTATTTTTTCACTAATCAACACGCTGTATGATGATACCAATAGCTCTAGCTATATGTCCAAATATTGATGAACGCCTGATTTCACCGCATCGTGACACATATTAAAATGATTCTGTCATAGAGGATGGCCTGTCTGAGATGACCACTTTTCTTCTGAGCATTGGGTGGTTATCTTGTAGGCCTACATTTGATAATACTTATATTTAAGAACTTGGTACCAGTATGCTGAAGTATGAATAAAGTAGTTCAATGTAATATACTGGTATACTACAGTACGAAAGTAGTCCAATATAATATTTTGGTAAGCTAAAATACGGAAATAGTCCTACATGATATTTTGGTAATCAAAAGAAATGGAAGTTGTGCTACACAATATTTTGGTAATCAAAAGTATCTCAAAATTCATCATTACTTTCCATTAGCTTTGAGTTTGTCTCATTCTGACTTGTTTGCTTGTCCCTTCTCAGTTGTGTTCAATTGTCTCGTGATACAGGTATGGATTCAATCAAGAGGGACTGAACAGATTTGGGGACAGGAGAAATGTTGACAACAGCTTCCCACTCAGTACCCGTCGCTTTGACGAGTCCGGTCTGGACTGGCAAGGTTATAACAGAGAGGGCTATGGTGAAGATGGCTTGAGCAGAGCTGGCTTTGACAAGTACGGCTTTGATGTGGACGGCTTCAACATCAGTGGGTACAGCCGTAGTGGAGAGTTTGACGGGATCATTGACTATGATGAAGAAGGATATGATCCTGAGGGATTTAACAGGTAATTCTTCCTTCTTTGTATT
->URS0001321690 rRNA from 1 species 
-CCCTTAGATGTTCTGGGCTGCACGCGTGCTACACTGATATTGCCAATATGTCATTCTTATCCGAAATGGATTGGGTAATCAAGTAATGAAATTTCATGCTTGGAATCGGTAATTGCAATTTTATCGTGAACGAGGAATTCCTAGTAAGCACTAGTCATCAGCTAATGTTGATTATGTCCCTGCCCCTTGTACACACCGCCCGTCGCTACTACTGATTGGGTGTTCAAGTGAGATGCTTAGACCCTTGTTGCATGGTTCATTATTGTGCTCCGAAAGGAAAAAGTTTCAAGCTTGAGTGTCTAGAGGAAGTAAAAGTCGTAACA
->URS00004F4253 rRNA from 1 species 
-GATGAACGCTGACAGAATGCTTAACACATGCAAGTCGATTCGATTTACCTTCGGGTATTGAGGATGGCGGACGGGTGAGTAACGCGTAAGGAACTTGCCTCTTGGTCTGGGACAACTGTTGGAAACGACAGCTAATACCGGATATTATGAGATTCTCGCATGGGAAACTTATGAAAGCTATATGCGCCAAGAGAGAGCCTTGCGTTCCATTAGCTAGTTGGTGGGGTAACGGCCCACCAAGGCGACGATGGATAGCCGGCCTGAGAGGGTGAACGGCCACAAGGGGACTGAGACACGGCCCTTACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGACCAAAAGTCTGATCCAGCAATTCTGTGTGCACGATGAAGGTCTTCGGATTGTAAAGTGCTTTCAGTTGGGAAGAAGAAAGTGACGGTACCAACAGAAGAAGCGACGGCTAAATACGTGCCAGCAGCCGCGGTAATACGTATGTCGCAAGCGTTATCCGGATTTATTGGGCGTAAAGCGCGTCTAGGCGGAAAAATAAGTCTGATGTTAAAATGCGGGGCTCAACTCCGTATTGCGTTGGAAACTGTTTTTCTAGAGTACTGGAGAGGTGGGCGGAACTACAAGTGTAGAGGTGAAATTCGTAGATATTTGTAGGAATGCCGATGGAGAAGTCAGCTCACTGGACAGANACTGACGCTAAAGCGCGAAAGCGTGGGGAGCAAACAGGANTAGATACCCTGGTAGTCCACGCC
->URS00003E0BF5 rRNA from 1 species 
-GCTCAGAAACTTAAATGACTTGAGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCTGGGCTCAAATGTATGTTGACGTATTCTGAAAGGGATACTTCTTCGGACAATATACAAGGTGCTGCATGGTTGTCGTCAGCTCGTGCCGTGAGGTGTCGGGTTAAGTCCCATAACGAGCGCAACCCCTATCATTAGTTGCCATCAGGTCAAGCTGGGGACTCTAATGAAACTGCCTACGCAAGTAGTGAGGAAGGTGGGGATGACGTCAAATCAGCACGGCCCTTACGTCCAGGGCTACACACGTGCTACAATGGCCGGTACAAAGGGCAGCTACCTGGTGACAGGATGCTAATCTCAAAAGCCGGTCTCAGTTCGGATCGGAGTCTGCAACCCGACTCCGTGAAGCTGGAATCGCTAGTAATCGCGCATCAGCCATGGCGCGGTGAATACGTTCCCGGGCCTT
->URS0001224666 rRNA from 1 species 
-TACGGGGGGGGGCAAGCGTTGTTCGGAATTACTGGGCGTAAAGGGCTCGTAGGCGGCCAACTAAGTCAGACGTGAAATCCCTAGGCTCAACCTAGGAACTGCGTCTGATACTGGATGGCTTGAATCCGGGAGAGGGATGCGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAATACCGGTGGCGAAGGCGGCATCCTGGACCGGCATTGACGCTGATGAGCGAAAGCTAGGGGAGCAAACGGG
->URS000137232C rRNA from 1 species 
-TACGAGGGGGGCAAATGTTGTTCGGATTCATTGGGCGTAAAGGGTGCGTAGGCGGCGCGGTAAGTCGGGTGTGAAATCTCGGAGCTTAACTCCGAAACTGCATTCGATACTGCCGTGCTTGAGGACTGGAGAGGAGACTGGAATTTACGGTGTAGCGGTGAAATGCGTAGATATCGTAAGGAAGACCAGTGGCGAAGGCGGGTCTCTGGACAGTTCCTGACGCTGAGGCACGAAGGTCAGGGGAGCAAACGGG
->URS00009BFC8A lncRNA from 7 species 
-CACAAAGAGAAGCTTTAAAAATCTTGCCTTCTGCCCCCTCAATTTCTTCTCCCTTCCTTCTCTATTTCCCACTGGTTTAGCGTGCCTGTCTCTCCCATTTTACCCTGCTTCAATCTCCTCCCAGTTGCTTCTGCTAGAGTTGCCTTTTGTCCTCTCACATCCCTAGGTCATCCTTGTTAGGGCTCTCCTGGCCTGGTTCCTTGTCCGCTTGAATTCCAGGGAGTGTTACAAGGTTTGGAGGTTTTTGCTTTACACATGGACCCAGAAGGAGCTGCAGCCTACAGGCCTCTCCCAAGAAGGCCTTTTCTCTGCCTGACTTTGGACTTCTCCCCAAGGTCAGGACAGTGTCCAGATGGCCCTGCTGCAGAATCTTTGCCTCCACTTCCTTCATCAAGAGGCTGTAGGTACATCTTGAGTTCATCTTGTGTCCTTCTGAAGCATTGCAGAGGGCAGCGGCTGCCTGGCATGGCACCGGTCCTGGGCATCACCCATGGGCCACCAGTGTTTTAGGGAGTGGAGAGCCTGGCTTGGGCAAGGACCTCAG
->URS000260A6B2 lncRNA from 1 species 
-TAAGATCTGGTGTACCAGCCATTACCCAAGTGTTAAGGTCTGGTATATCAACTATTCCCCAAGTGTTAAGGTCTGGTGTACCAGCTACTACCTATTGTTAAGGTCAGGTATATCAACTATTACCCAAGTGTTAAGGTCTGGTATATCAAGTATTACCCAAGTGTTAAGGTCTGGTATATCAACTATTACCCAAGTGTTAAGGTCTGGTGTACCAGCTACTACCTATTGTTAAGGTCAGGTATATCAACTATTACCCAAGTGTTAAGGTCTGGTATATCAACTATTACCCAAGTGTTAAGGTCTGGTATA
->URS00002A34A8 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGACCTATGTTGAAACCTAGTGATATATAAGTTAGTGGCGGACGGGTGAGTAACGCGTGGATAACCTGCCATATACAGGGGGATAACACTTAGAAATAGGTGCTAATACCGCATAAGCGCACAGTTTCGCATGAAGCAGTGTGAAAAACTCCGGTGGTATATGATGGATCCGCGTCTGATTAGCTTGTTGGCGGGGTAACGGCCCACCAAGGCGACGATCAGTAGCCGGCCTGAGAGGGTGAACGGCCACATTGGGACTGAGACACGGCCCAA
->URS0000F20FBF rRNA from 1 species 
-CACGTAGGGCGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGTCTGTTGCGTCCGCTGTGAAAACTCGGGGCTTAACCCCGAGCCTGCAGTGGATACGGGCAGACTAGAGGTAGGTAGGGGAGAATGGAATTCCCGGTGTAGCGGTGAAATGCGCAGATATCGGGAAGAACACCCGTGGCGAAGGCGGCTCTCTGGGACGGTACTGACGCTGAGACGCGAAAGCGTGGGGAGCGAACGGG
->URS000118C396 rRNA from 1 species 
-TACGTAGGAGGCGAGCGTTGTCCGGAGTTACTGGGCGTAAAGGGTGCGCAGGCGGTGGCCCGCGTGGGCGGTGAAAGCTCCTGGCTCAACTGGGAGAGGGCCGTCCAGACGGGGTCACTTGAGGGGCGGAGAGGGGCGTGGAATTCCGGGTGGAGCGGTGAAATGCGTAGAGATCCGGAGGAACACCAACGGCGAAGGCAGCGCCCTGGACGAGACCTGACGCTCAGGCACGAAAGCTGGGGGAGCAAACAGG
->URS00013DEF05 rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTGTCCGGAATTACTGGGCGTAAAGAGCTCGTAGGTGGTTTGTCGCGTTGTCCGTGAAAACTCACAGCTTAACTGTGGGCGTGCGGGCGATACGGGCAGACTGGAGTACTGCAGGGGAGACTGGAATTCCTGGTGTAGCGGTGGAATGCGCAGATATCTGGAGGAATACCGGTGGCGAAGGCGGCATCCTGGACCGACATTGACGCTGAACGGCGAAAGCTAGGGGAGCAAACGGG
->URS000057D191 piRNA from 1 species 
-TCTATTAGGAGCTGTCAGGTGTGTT
->URS0002185586 lncRNA from 1 species 
-TAACATGGTAGGAGCACAGGTTTTTGGGAATATGTGGAAACAGACTCTGTTTAGCAACCATAACCATTTTGACTTCAACTGTGAAGATAATGACAGACCGTAAAGGCCACACATTACCCATGTGAACTATCGTATGCTGCGTGTCATAAGTATGACGTTGACCTCCTGAACTCTCGGTTCTGTGTTGTTTGCGTTGCAGAGAATAAGGCAGTTGGAAGACATGATTGAGATGCAAAAGAGACAAGTAAAGGAAATAGAAGAAAAGTTTTTGTTCCTCTTCTTGTTTTTCTCTCTAGCTTTTATTCTTTGGCCTTAATGACACTGACATGGACCGACAACAGGTGCTAAGGTGCTCAGGTGGAGAGTGAGGAAGAGAAACACAACATTTTTTTTTTTTTTTTCATGCATTTATAGATGGTTCACAAACCTTATATGGCCTTTTTGATACACGTGCACTTTTGTGGAAAACATTTACCTGGAATGCAAAACAAAACCAGGACTTTGAAAAGTGAACAAATATCAGAGACATGTAAAAGAGGTATATCAGAGATTTTTTTTATTTTTTATAACGGAAATGTCCCCTACCATTTTTGGAAGTGGAACATTTAGCCAAACTCTAATGTGAGTTCTAAAAAGCAAGAACATTGTAACTGGAACTCTGAAGCAGGTCAATAAAGGAACAGAGCAACTGAGATGGAGACAGTGCCTCAGATGGATTTAGAGCCAGACAACGAAAGAGTGCAATCGTAGAGGAGGAGGAAGGAGGAGGAAGGAGAAAGAGTTGATTCAAAAAAGCAGGACGATTTCCAAACAGACGAGCCAAGTCCTGGGCATTCCCAGAAAGCTCAGTGCAGGAGGGTCTCCATGGAAACAGCTGGCGAAACGGCTGTCATGGCCAAAGTTCAATGAGCAAGAAGTGAAAGCTTTGTACTCCGGAGTAGAGCGACACCAGAGGACTACGGGGACAGAATGTGTCACCGGTCTGTGAAACACAAAGAATCCTCAATAGCTGTGACCTCCAGGTTTTGACCCATAGAGTGAACCGTCTAGAGCACAGCCTGAGAGACAACGTCAGCTCCTTTACTGAGTCTGAGAGCTTGCTGCACAACAGAGAGTTGGAGGTGCCAGAGCAGAGCCTGCTACAGAAGGTGGAGGACCTCACAGCACACTCAGTCCTCCACTGTCCCAGCATGCAGCGACGCCAGAGGCTGGACGAGCGGCTCCACGCGCTCAGGGAGGAGGTGCGCTTCATGGTGAGTAGAGACTGTACTGAGCTTTACATTAGCTTCAATGAGGCTTATAGAGTGAGAAGTACTCAAATGTACATGTCATGTAAGCTGTACTGTAAATTGTAGTATAAGCCTGTAATTATTGTGTAAGTGTAATTATTGTGTAAGTGTATTGTGAGTGTGGTTTAAATCTATCGTTTCTCAGGTGTAGTGCTATTGTGACTGTAGTCTCCCTCTCTGTTGCATTATATGAGATGTGTATGACATTACTCAGATGTGAGGAGTAACTGTGTCATAGTTCTATCATGACCGGTCCTTCCCAGTACCAGGAGAAGGAGCATAGGAATCGTGTGTGTGGAGGGAGAGGCTACAGTGCTGCCAGGCCCAGC
->URS0000A07E96 rRNA from 1 species 
-CACGCAGTAAACGATGATTACTAGTTGTTTGCGATACACAGTAAGCGACCGAGCGAAAGCATTAAGTAATCCACCTGGGGAGTACGTTCGCAAGAATGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGAGGAACATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCCGGGCTTGAAATGCAGATGACAGGGGCAGAGACGCCCCCTCCCCTCGGGGCATCTGTGTAGGTGC
->URS000257F2CE snoRNA from 1 species 
-GTTGCTTCATAATGGTGAAATCTCTCAAAATCGAATGAGAGAATCTCAAGTTTCCGGAGCATAGATTAAGCATTCTATCACCAGTATTAAACAGCTCGGTGCGTATACAATCGCAT
->URS000210DF6D rRNA from 1 species 
-AATTAATGAATTAATTATAATTAGTTAAATTTTATATGAAGTTCAATATTAAGTTTAGAAATATTGGCGGTGTTTTATTAAATTCTGAGAATCTTGCATAATTAAAATGATAGTACACAATTTATCTTATCTTAGTTTTGTTGGTTTATATATTGCTGTTTTATTTATGGTTTGGTTTTGATAAAATAGGTAAAAGGATTTTGTAGTAAGAAGTTCAAGTCAAAATATAGTTTTATTAAGGTTTATGTGAGTTGCTTTTGTTTAGAAAATAGGAATAATAAAGTAAAATGAAATTTTATATAAGAAGGGATTAGGTTGTAAGGGAAAAATTAATAAGTTTTCTTGATAAATTATATGAACATGT
->URS00014E047D rRNA from 1 species 
-GACGAACCGTGCGAACGTTGTTCGGATTCACTGGGCTTAAAGGGCGCGTAGGCGGACGGTCAAGTCAGGGGTGAAATCTTTCAGCTCAACTGGAAAAGTGCCTCTGATACTGATCGTCTCGAGGGAGGTAGGGGCATGTGGAACTTCCGGTGGAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGTGGGCTGGGCCGGAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS000238B563 lncRNA from 1 species 
-ATTCTCTCTCCATTTTAGAGAGAGAGTTGAGATGGAAATTATAATTTTCTCTCGATTTTAGAGAAACAGGTTTTTATTTTTTTGTGAGGCAAAGGATTTTGATTCGTGTCAATTTACGGCCTCTACCTCAATTGGACAGATGTGGCTCTCTTTACCTCTCTCAAAAATGTGTTTCTTCCTCCCTGTCCTTCCGGGTGAGAGTGTAAATAGATTTTGATCTGTGGTTTTTCGGCAGGAGATAGTTATTTGTGAGGGAGTCTCCATTTTCCTACCAAATAATTTGGTTGCATGTTTGTTTTCTTTTTCTCTTCCTTTGTGTTTTGCAGATGGAGGATTCCTGGCGGTGCTTTTTCTAGTTTGTTCTTCTGCCATTAGGAAACGATGGAGAGATCTATACTTTTCAATCTCGTAATCGACGCTTTTGTCCTAAGTTCTCATTCCTTGGCTCGAGAGGATGGTGGGTGGACTCGATTGCAAAAGTCTCTTTTCTCTTTCTATTGTATTCATCGTTCATCTCTCAACCTTGCTAGGGCTGCATGCGTTTTTCTGCTCGGTGCCATCCTTTGTTTCTATTGCTTTAGTTGCCGGAAAAGAACTACTGTTCGGAAAAAAAAAACTTATTTCCTCTTATCGGCCATGGCAACTGAGTTTTTGGGTCTTAGGGTTTCTATGTGTTTGAGTTGCCTCCAAATAAAAGTTTG
->URS00021B94DD lncRNA from 1 species 
-AGTTGGTGAACACAATAGCAAATCTTTTTAATAAAAATAACAGCAATAAAAAAATAACAAATATTTGAAATTTGATATTAAAATATGAACAATGACAAAAATACTGAAAGAAGTTACAATATTAACAAATATTGATATAAAACAATGGTTAAAAAATTGTCTTCATAAACAATAGCACGTGCATTTTTCTCGTGCAGTTACGTCAGGTGACCATGTATTCAGTGAATCACAAGTAATAAATAAACAAAAAATATGAGTGTGTCTTACCTGAGTTATACATGTTATAACCAACAAAAGTATTAAAAGTCTTAAAACATTTTTAAATATTATAATAATATGCCCTAGCAAGATACATAAACAATCAACCTTAAGAAAAACAATAACAAAAGTAAACCTAATTTAGGTAAACATGATAACATGGTACGCATTTAACAAAAAAAATTAAAAATTAAAAAAAAAATTCTGAAAAACTTGGATCATTTTTAGAACACAAAATATTAACATTGATGAAATAGTGTCATAGCCTATGAGGAAATCGTTTTAAAATCAAGTTACTTCCCAAATAACTGACATCTACTTTACATGTGTATATGTCTCATCCCCACTTTGAAGATGTAGATTTG
->URS0000350E7B rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAGCGGTAAGGCCCTTCGGGTACACGAGCGGCGAACGGGTGAGTAACACGTGGGTGACCTGCCTCTAGCTCTGGGATAAGCCTGGGAAACTGGGTCTAATACCGGATATGACTCCACGGCGCATGTTGTGGGGTGGAAAGCCTTGTGTGGCTAGAGATGGGCCCGCGGCCTATCAGCTTGTTGGTGGGGTGATGGCCACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGCGACCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATCTTGCGCAATGGGCGAAAGCCTGACGCAGCGACGCCGCGTGAGGGATGACGGCCTCGG
->URS00015AB4C8 rRNA from 1 species 
-TACGGAGGATCCAAGCGTTATCCGGAATCATTGGGTTTAAAGGGTGCGTAGGCGGGTATGTAAGTCAGTGGTGAAATCCTGGAGCTTAACTCCAGAACTGCCATTGATACTATATATCTTGAATATTGTGGAGGTTTGCGGAATATGTCATGTAGCGGTGAAATGCTTAGATATGACATAGAACACCTATTGCGAAGGCAGCAGGCTACACATATATTGACGCTGAGGCACGAAAGCGTGGGGATCAAACAGG
->URS0000254467 rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCTTAACACATGCAAGTCGAACGGTAACATGAAGAAGCTTGCTTCTTTGATGACGAGTGGCGGACGGGTGAGTAATGCTTGGGAATCTAGCTTATGGAGGGGGATAACTACGGGAAACTGTAGCTAATACCGCGTAGAATCGAGAGATGAAAGTGTGGGACCTTCGGGCCACATGCCATAGGATGAGCCCAAGTGGGATTAGGTAGTTGGTGAGGTAAAGGCTCACCAAGCCGACGATCTCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGGACTGAGACCTGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGCAATATTGCGCAATGGGGGCAACCCTGACGCAGCCATGCCGCGTGAATGAAGAAGGCCTTCGGGTTGTAAAGTTCTTTCGGTAGCGAGGGAAGGCATTTATGTTTAATATGATCTAAG
->URS0001ED777B rRNA from 1 species 
-TCATATGCTTGTCTTAAAGATTAAGCCATGCATGTCTAAGTATAAGCTTTTATACGGCTAAACTGCGAATGGCTCATTAAAACAGTTATAGTTTATTTGATGGTCTTTACTACATGGATAACCGTGGTAATTCTATGGCTAATACATGCGCACATGCCTCTTCCCCTGGAAGGGCAGTGTTTATTAGATACAGAACCAACCCACCTTCCGGTGGTCCTCAGGTGATTCATAGTAACCGAACGGATCGCGTTGACTTCGGTCTGCGACGGATCATTCAAGTTTCTGACCTATCAGCTTTCGACGGTACTGTATTGGACTACCGTGGCAGTGACGGGTAACGGGGAATTAGGGTTCGATTCCGGAGAGGGAGCCTGAGAAACGGCTACATCTAAGGAAGGCAGCAGGCAAATTACCCAATCCTGATTCAGGGAGGTAGTGACAAGAAATAACAACACTGGAAATTTCATTTCTAGTGATTGGAATGATAGGAATCCAAACCCCTTTCAGAGTAACAATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGGATTTCTGCTGGAAGCAGCCAGTCCGCCCTCAGGGGTGTGCACTTGGTGAATTCTAGCATCCTTCTGGATTTCTCCACACTTCATTGTGTGGAGTTTTTTCCAGGACTTTTACTTTGAGAAAATTAGAGTGTTTCAAGCAGGCTTGTCGCCTTGAATACTGCAGCATGGAATAATAAGATAGGATTTCGGCCCTATTTTGTTGGTTTCTAGGACTGAAGTAATGATTAATAGGGACGGTTGGGGCATTCGTATTTAACTGTCAGAGGTGAAATTCTTAGATTTGTTAAAGACGAACTACTGCGAAAGCATTTGCCAAAGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGCTCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGAGATAGGAAAACGTCATGCTTGACTTCTCCTGCACCTTATGAGAAATCAAAGTCTTTGGGTTCTGGGGGGAGTATGGTCGCAAGGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGCGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTCACCAGGTCCAGACATAGGAAGGATTGACAGATTGATAGCTCTTTCTTGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGTGATTTGTCTGGTTAATTCCGTTAACGAACGAGACCTTAACCTGCTAAATAGGATCAGGAACTTCGTGTTCTTGTATCACTTCTTAGAGGGACTTTGCGTGTCTAACGCAAGGAAGTTTGAGGCAATAACAGGTCTGTGATGCCCTTAGATGTTCTGGGCTGCACGCGCGCTACACTGATGCATCCAACGAGTTTATAACCTTGGCCGATAGGTCTAGGTAATCTTGTGAGTATGCATCGTGATGGGGATAGATTATTGCAATTATTAATCTTCAACGAGGAATGCCTAGTAGGCGCAAGTCAGCAGCTTGCGCCGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTCCTACCGATTGAGTGTTCCGGTGAATTATTCGGACCGTTTTGTGGCGCGTTCGTGCCCGAAATGGGAAGTTTTGTGAACCTTAACACTTAGAGGAAGGAGAAGTCGTAACAAGGT
->URS00019AFD52 lncRNA from 1 species 
-GCTTAGGCCACCATGCAGCCTTATTTCTTGACCCTGCTTTAACTCCTACTCCTGATGTGAGCCGGAAAAGGACTCCCCATGTCCACCTTCTTTGGGTGTAGGTTCCATTTCTACCCCCAGTGGGGTCCAAAAAGGTTTCTCTTCGCCATTGCAGTTTCTTCTGCTGTTTCCTTGCATTCTGGGGCCCTGTTTGTGCACATAACCTTTGCCTCACCTATGTGGCCGCCTCTTGCCCCTGAGCGCTGGCCGTCCCTGTTGGACCGGCTAGTGACCTGACTCCATGGCCGCCCAGCAGTGCCATCGCAGGCCGGGCTGCCTTCAGGCAGACCCAGGCACACTTGCGGTATGTGAAAGCAAGCATTCCTGCCTTTCAGTCATGAAAAGAATGTCCTTGGCCTCTACGTTACGGTGACGCTAGTGGATAGCTTAGCCCGCACAACCCTGCCTCCTCCTCCCGGGGCCTGGGGCTGGCCCTCCTCTCCTGCCTCCCACACCTGGCCACCAGAACCCCTACCACCCTGCACCTGGTGGATCGCTCAGAGCGCACACCCCCTGGTGCTGACCAGTCGGGGAGCGCCTGGACGCAGCGACCTCTGGCCGGCTTTCGGTGTTCTCATGCGTGCGAAGAGAGCGCGTGAGGAAAGCCGCGCGGGGTCGGCAGGGTCGGCGGCCGGTGCGGACGCGCCTCGGCGGCGCGCGGCGGC
->URS00001839AB rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGGAGTTGATCCTTCGGGATTAACTTAGTGGCGGACGGGTGAGTAACGCGTGGGTAACCTGCCGTATGCTGGGGGACAACAGTTGGAAACGACTGCTAATACCGCATAAGCGCACAGTACCGCATGGTATAGTGTGAAAAACTCCGGTGGCATACGATGGACCCGCGTCTGATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGTCGACGATCGGTAGCCGACCTGAGAGGGTGATCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGGGCAATGGGCGAAAGCCTGACCCAGCAACGCCGCGTGAAGGAAGAAGGTCTTCGGATCGTAAACTTCTGTCCTAAGTGAAGAGCAGAAGACGGTAACTTAGGAGGAAGCCCCGGCTAACTACGTG
->URS00002AB1FD piRNA from 1 species 
-TGGAAATGAAACAGTCTTTAATGTCTA
->URS0001E049BC rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGGGCCTTGTCCCCTTTTTTTTTGGGGGTGGGGTTAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCCTCACTTCTGGATAACCGCTTGAAAGGGTGGCTAATACGGGGTGTTCTGGCCTGCTCGCATGGGTGGGTTTGGAAAGATTCGACCGGTTTTGGTTGTTTTGGTGGGGGATGGGCTCGCGGCCTATCAGCTTGTTGGTGGGGTGATGGCCTGCCAAGGCTTTGACGGGTAGCCGGCCTGAGGGGGTGGGCGGTCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGCGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCGACGCCGCGTGAGGGATGGAGGCCTTCGGGTTGTGAACCTCTTTCGCCAGTGAAGAAGGTCCTGCTCTTTGTGGTGGGGTTGACGGTAGCTGGGTTAATGAAGCGCCGGCTAACTACGTG
->URS0000DC40A1 rRNA from 1 species 
-AACTCAAATGAATTGACGGGGCCCGCACAAGCAGCGGAGCGTGTGGTTTAATTCGATGATACGCGAAGAACCTCACCCAGGTTTTGACATGCATGTGGTACCAAGGTGAAAGCTGAGGGACCCTTCGGGGAGCATGCACAGGTGTTGCACGGCCGTCGTCAGCTCGTGCCGTGAGGTGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTGTCGCCAGTTGTATTTTTCTGGCGAGACTGCCGAGAAAACCTCGGAGGAAGGAGGGGACGATGTCAGGTCAGCGTGGCCCTTACGCCTGGGGCTACACACACGCTACAATGGGCAGTACAACGGGTCGCGAAGCCGCGAGGTGGAGCTAATCCCATCAAAGCTGTCCTCAGTTCGGATTGCAGGCTGAAACCCGCCTGCATGAAGCCGGAGTTGCTAGTAACCGCAGGTCAGCATTACTGCGGTGAATACGTTCCCGGGCCTT
->URS00009444FC ncRNA from 1 species 
-CATCGAGTTGGTGCGCTAGGCCGCGACGAGTAGGAGGGCCTCGGCGGCGGGCGTAGAAGCCTAGGGCGCGAGCCCGGGTGGAGCAGCCGTCGGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTGAAGGCCGAAGTGGAGAAGGGTTCCATGTGAACAGCAGTTGAACATGGGTCAGTCGACCCTAAGGGATAGGCGAAGGCCGTTCTGAAGCGGGGTGATGTTCGCGTCGCCCCGGCGGACCGAAAGGGAATCGGGTTAATATTCCCGAACCTCGACGCGGAGATTGGCGCTCCGGCGCCTAGTGCGGCAACGCAAACGAACTCGGAAACGCCGACGTGGGTCCCGGGAAGAGTTCTCTTTTCTTGGTAAGGGGCGGCGACCCTGGAATCGGTTCGCCCGGAGATAGGGACATGGGCCCCGTAAAGCAGCACGTCTCTTGTGCTGTCCGGTGAGCTCGCGTCGGCCCTTGAAAATCCGAGGGAGACGGTGTAATTTTCGTGCGAGGTCGTACCCATATCCGCAGCAGGTCTCCAAGGTGAACAGCCTCTGGCCGATAGAACAATGTAGGTAAGGGAAGTCGGCAAACTAGATCCGTAACTTCGGGAAAAGGATTGGCTCTAGGGGCTGGGTCGGTCGGGCTGAGGTACGAAGCGGGGCGCGGCGCTGTACCGGACTGGGCG
->URS0000B3F0C3 misc_RNA from 1 species 
-AATAAGATTAAATTTTGTAACAGATCAATGAGATCCAGAGCAGACATTCTTAAAGACAACTAAGAAAACAAAAATCATATGTAGAATCTTTCAATATTACAAATGAAAAATCAAGATTTCCTTATTGCTCATCTACCGGTTTGAATCCTTAACAAATCGCAAACCAAAGCTATTATGGAAACCACAAAGTAGTACTCCAGCTTTCGCCTTCTCGGGCTTTTCCTTCAAGCTGTGTCCAATTCCATTCATTCTCCTCCTCCTCCACAATCTTGCCTTTAAAAATTCACTCCAAGGGTTAACCATAGAAGAGCGACAATGAGTACGATCGGAGCCCAAGAAAAGAGCGGTGCCGGGGACTGGACAAATTTTCCTCTGTCTCGGCGGCGGCGACGTTCTTGATCCTCCAAGAGATGGCAGTATCATGAGATGGCGTTCAATATGATGGCAAAGTGACACCAAACTCATATGAGTCGT
->URS000206F7FE rRNA from 1 species 
-ATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACAGACGAGGAGCTTGCTCCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATATTGAACCGCATGGTTCAATAGTGAAAGACGGTTTTGCTGTCACTTATAGATGGATCCGCGCCGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCGACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACCCGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACAAATGTGTAAGTAACTATGCACGTCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTG
->URS00022DD3B1 rRNA from 1 species 
-CCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAATTTCGGGGTTAGTAGGTTGGTCATGCCTCTGGTATGTACTGGTCTCACTGATTCCTCCTTCCTGATGAACCTTAATGCCATTAATTTGGTGTTTTGGGGAATTTGGACTGTTACTTTGAAAAAATTAGAGTGTTTAAAGCAAGCTAACGCTTGAATACATTAGCATGGAATAATGAAATAGGACGTTCGATCCTATTTTGTTGGTTTCTAGGATTGACGTAATGATTAATAGGGAGAGTCGGGGGCATTAGTATTCAATTGTAAGAGGTGAAATTCTTGGATTTATTGATGACTAACTACTGCGAAAGCATTTGCCAAGGATGTTTTCATTAATCAAGAACGAAAGTTAGGGGATCGAAGACGATCAGATACCGTCGTAGTCTTAACCATAAACTATGCCGACTAGGGATCGGATGATGTTAATTTTTTAATGACTCATTCGGCGCCTTACG
->URS00017ABA52 rRNA from 1 species 
-CCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGCCGGAAGGCTGAACCAGCCATGCCGCGTGAAGGTCAGTGCCCTATGGGCGTTAAACTTCTTTTGTGCGGGAGCAATAATGGTCGCGTGTGGCCAGACGAGAGTACCGTACGAATAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGGGGATGCAAGCGTTATCCGGGTTTATTGGGTTTAAAGGGTGCCTAGGCTGGGAGGTAAGTCAGCGGGGAAATGCCCCCGCGCAACGGGGTGAAGTGCCATTGATACTGCCTTGCTGGAATGCGGATGCCGTAGGAGGAATGTGTGGTGTAGCGGTGAAATGCATAGATATCACACAGAACACCGATTGCGAAGGCATCTCACGAATCCGCGATTGACGCTGATGCACGAAAGCGTGGGTATCAAACAGGATTAGATACCCCGGTAGTC
->URS0001280152 rRNA from 1 species 
-GACTAACGCTGGCGGCAGGCTTAACACATGCAAGTCGAACGCATCCTTCGGGGTGAGTGGCAGACGGGTGAGTAACGCGTGGGAACGTGCCCTTCAGTTCGGGATAACCCAGGGAAACTTGGGCTAATACCGGATACGTGCGAGAGCAGAAAGATTTATCGCTGAAGGATCGGCCCGCGTCTGATTAGCTAGTTGGTGGGGTAATGGCCCACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGATGATCAGCCACATTGGGACTGAGACACGGCCCAAACTCCGACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCATGAGTGATGAAGGCCTTAGGGTTGTAAAGCTCTTTCGTCCGGGACGATAATGACGGTACCGGAAGAAGAAGCCCCGGCTAACTTCGTGCCAGCCGCCGCCGTAA
->URS00025670D8 misc_RNA from 1 species 
-AACGCACATTGCGCCCCTTGGTATTCCATTGGGCATGCCTGTTCGAGCGTCATTTACCCCTTCAAGCTCCGCTTGGTGTTGGGCGTCTGTCCGCGTTTCCGGCGCGGACTCGCCCCAAATCCATTGGCAGCGGCTCCGCCGGCTTCTCGCGCAGCACATTGCGCTCTGGGAGGCTCTCGGCGGGGCCCGCGTCCACCAAAGCAACCCCCCATTTTGACCTCGAATCAGGTAGGGATACCCGCTGAACTTAA
->URS000223CBAB misc_RNA from 1 species 
-AGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCAGTTAAAAAGCTCGTAGTTGAATTTCGGGGTCAGCAGGTTGGTCGTGCCAATGGTATGCACTGGCCTTGCTGATTCCTCCCTCTTGATGAGCCGTAATGCCATTAATTTGGTGTTGCGGGGAATCAGGACTGTTACTTTGAAAAATTAGGGTGTTTAAAGCAGGCAAGCGCTTGAATACATTAGCATGGAATAATGAAATAGGACGTTCGATCCTATTTTGTTGGTTTCTAGGATTGACGTAATGATTAATAGGGATAGTTGGGGGCATTAGTATTCAATTGTCAGAGGTGAAATTCTTGGATTTATTGAAGACTAACTACTGCGAA
->URS0000D99911 rRNA from 1 species 
-GGGTAAGTCGGGACCTAAGGCGAGGCCGAAAGGCGTAGTCGAAGGACAACAGTTTGAAATTACTGTACCACCGTAATCCGCTATGAGCGATGGGGTGACGCAGGAGGGTAGTGACGCGGACTGATGGATATGTCCGTCTAAGCAGTGAAGAGGCAGACCAGGGGAACTGAAACATCTAAGTACCCTGAGGAAGAGAAAACAATAGTGATTCCGTCAGTAGCGGCGAGCGAACGCGGAACAGCCTAAACCAAGGGGCTTGCCCCTTGGGGTTGTGGGACGTCTCACATGGAGTTACAAAGGAATATGGTAGGCGAAGAGGTCTGGAAAGGCCCGCGATAGAGGTAAAAGCCCTGTAGCCTAAACTGTGTTCTCTCCGAGACGGATCCCGAGTAGTGCGGGGCACGTGAAACCCCGTATGAATCCAGCAGGACCATCTGCTAAGGCTAAATACTACCTGGCGACCGATAGTGAAACAGTACCGTGAGGGAAAGGTGAAAAGCACCCCGGAAGGGGAGTGAAATAGAACCTGAAACCGTGTGCTTACAAAAAGTCAGAGCCCGATCTATGGGTGATGGCGTGCCTTTTGTAGAATGAACCGGCGAGTTACGTTTAACATGCAAGGTTAAGGTGAGAAGCCGGAGCCGCAGCGAAAGCGAGTCTGAATAGGGCGACTAAGTATGTGGACGTAGACCCGAAACCGTGTGATCTACCCCTGTCCAGGGTGAAGGTGCGGTAACACGCACTGGAGGCCCGAACCCACGCATGTTGAAAAATGCGGGGATGAGGTGGGGGTAGCGGAGAAATTCCAATCGAACTCGGAGATAGCTGGTTCTCCCCGAAATAGCTTTAGGGCTAGCCTCGGTGAATGGAGTGGTGGAGGTAGAGCACTGATTGGGTGCGGGGCCCGCAAGGGTTACCAAGCTCAGTCAAACTCCGAATGCCATTAACTTCTTGCCGGGAGTCAGACAGTGAGTGCTAAGATCCATTGTCAAAAGGGAAACAGCCCAGACCATCAGCTAAGGTCCCCAAGTGTGTGTTAAGTGGGAAAGGATGTGGAGTTGCACAGACAACCAGGATGTTGGCTTAGAAGCAGCCACCATTGAAAGAGTGCGTAATAGCTCACTGGTCGAGTGACTCTGCGCCGAAAATGTAACGGGGCTAAACACACCACCGAAGCTATGGCTAGATGCTTTGCATCTGGGGTAGGGGAGCGTTGTATGTGGGTTGAAGGTGTACCGTAAGGAGCGCTGGACAGCATACAAGTGAGAATGCCGGTATGAGTAACGAAAAGATCAGTGAGAATCTGATCCGCCGAAAGCCCAAGGTTTCCTGAGGAAGGCTCGTCCGCTCAGGGTAAGTCGGGACCTAAGGCGAGGCCGAAAGGCGTAGTCGAAGGACAACAGTTTGAAATTACTGTACCACCGTAATCCGCTATGAGCGATGGGGTGACGCAGGAGGGTAGTGACGCGGACTGATGGATATGTCCGTCTAAGCAGTGAAGCTGATGTGTAGGCAAATCCGCACATCAATAAGGCTGGGCTGTGATGGGGAGCGAAAATTGTAGTAGCGAAGCTGGGGTAGGGGAGCGTTGTATGTAGGTTGAAGGTGTACCGTAAGGAGCGCTGGACAGCATACAAGTGAGAATGCCGGTATGAGTAACGAAAAGATCAGTGAGAATCTGATCCGCCGAAAGCCCAAGGTTTCCTGAGGAAGGCTCGTCCGCTCAGGGTAAGTCGGGACCTAAGGCGAGGCCGAAAGGCGTAGTCGAAGGACAACAGTTTGAAATTACTGTACCACCGTAATCCGCTATGAGCGATGGGGTGACGCAGGAGGGTAGTGACGCGGACTGATGGATATGTCCGTCTAAGCAGTGAAGCTGATGTGTAGGCAAATCCGCACATCAATAAGGCTGGGCTGTGATGGGGAGCGAAAATTGTAGTAGCGAAGGTCATGATCTCACACTGCCAAGAAAAGCCTCTAGCCAGGAGAAGGTGCCCGTACCGCAAACCGACACAGGTAGGCGAGAAGAGAATTCTAAGGCGCGCGGAAGAACTCTCGTTAAGGAACTCGGCAAAATGACCTCGTAACTTCGGGAGAAGAGGTGCCTCGGTAGGGTGAATAGCCCGAGGGGGCCGCAGTGAAAAGGCCCAAGCGACTGTTTAGCAAAAACACAGGTCTGTGCGAAGCCGCAAGGCGAAGTATACGGGCTGACGCCTGCCCGGTGCTGGAAGGTTAAGGGGAGTGGTTAGGCCGAAGCTGTGAACCGAAGCCCCAGTAAACGGCGGCCGTAACTATAACGGTCCTAAGGTAGCGAAATTCCTTGTCAGGTAAATTCTGACCCGCACGAATGGCGTAACGACTTGGGCGCTGTCTCAACGAGAGATCCGGTGAAATTTTAATACCTGTGAAGATGCAGGTTACCCGCGACAAGACGGAAAGACCCCATGGAGCTTTACTGCAGCTTGATATTGAATTTGGGTACGATCTGTACAGGATAGGTGGGAGCCGTTGAGGCAGGAGCGCAAGCTTCTGCGGAGGCGCCGTTGGGATACCACCCTGATCGTATCTAGGTTCTAACCTAGTGCCCTTACCGGGTACGGGGACCGTGTCAGGCGGGCAGTTTGACTGGGGCGGTCGCCTCCTAAAGAGTAACGGAGGCGTTCAAAGGTTCCCTCAGAATGGTTGGAAATCATTCGCAGAGTGCAAAGGCATAAGGGAGCTTGACTGCGAGACCTACAAGTCGAGCAGGGACGAAAGTCGGACTTAGTGATCCGGTGGTACCGCATGGAAGGGCCATCGCTCAACGGATAAAAGCTACCCTGGGGATAACAGGCTTATCTCCCCCAAGAGTCCACATCGACGGGGAGGTTTGGCACCTCGATGTCGGCTCATCGCATCCTGGGGCTGAAGTAGGTCCCAAGGGTTGGGCTGTTCGCCCATTAAAGCGGTACGCGAGCTGGGTTCAGAACGTCGTGAGACAGTTCGGTCCCTATCTGTCGTGGGCGCAGGAAATTTGAGAGGAGCTGTCCTTAGTACGAGAGGACCGGGATGGACGTACCGCTGGTGCATCAGTTGTTCCGCCAGGAGCATGGCTGAGTAGCTACGTACGGACGGGATAAGCGCTGAAAGCATCTAAGCGTGAAGCCCCCCTCAAGATGAGATTTCCCAATTAGTAAGACCCCTTGAAGACGACGAGGTAGATAGGTTGGAGGTGGAAGTGCAGCAATGCATGGAGCTGACCAATACTAATCGGTCGAGGGCTTATCCAA
->URS000235B2B5 lncRNA from 1 species 
-AACTGTTGCGGCAGCCATGCTTGTGAGCTTATGATGTGCCGCTAGTTTAGTTTGTCGGTTTCTGTGAACCGTTCTCTGTGATGTATGATGTATTGCTGCTGTTAGCTGTAAATGTGTTGTATGATGAGTTGACTTGATGGTTCGTTTGAGGCTGTCTTGTGAAGGTTACTGTTAGTTAACATGAGTTAAACAAATACATACACTTGCTGCTGTTAGCTGTAAACATGAGTTGACTTGATGGTTCGTTTGAGGCTGTCTTGTGAAGGTTACTGCTAGTTAACATGAGTTAAACTATTACATGCACTGGGACCCATTTGACTAGTGGACCCATTTAATAAAAATAAAAATGAAATTGTTTAGACAAAAAGGCCACGGCCCAACAATAAAAAAGGCTGCAACGTTGGGCTTGGCCCATGAAGTCGACCAAAAATTAACAGAAAAAGGCTGAATTGTTGGGCTCGGCCCATCTAAAGCAGCGAAATGGACCGGGCTGATTCTTATCAACGACCTTTTCATTTGGTCGCAATTTTGCCACGTCAGATTGCCACGTCGGATCCGACGGGGCCTGGGCAGAGAGCTAGCGACCAAAATAGAAGGTCACAGAATCAACGACCTTTTGTTTTGGTCGTGGAATTCCACGACATTCTCAAAGAGAAGGTCGTTAATTTCAATTTACGACCGCCAGCTTTTGACCATCTATTTTTGGTCAAAAAAAGGTCGCAAATGAAAATCAATGACCTTTCAGTGACCAATAGTGAGGATTGCAAGTTGACATATTTCTTGTAGTGAATTCCGGATAACTTCATAATATATTATGAAGCCTCTGCTTGGCTCAATGGATAGGCGTACAAGTCGCCGCCACTGTGTTTTGATTAACTTCAACAACCAGTTGGGATGAATCATCAGCTGGGTTATTGACACAGCCCATACGGGATCATTTATAACCCGCCGAGGGTTCCGCTGTTTAACAATATGTCGGTTTATATCACGGTCAAGTATGGAGAATCTCAAGACAACTCCTCGAGTCGTCTTAAGACTCGGGGGCTACAATGACATGACTCAGCAAATCCTGCCAGCTTCAGCTAATTCAAGAACCCCGGGTCATTGGAGGGAAGATAACCCGGTCCCAGAGGCTACTGCTATATTGATGAAAATTTAAAGGCCGTCAGAAAATTCCTGGCTTAAAATGAAGAATTCGGGATTAAAATCCAGCTCAAGGGAAATCTATCTCTCATAAAGCTTTGAAGCTCTCAACATCCGGTTTAAAATTCCGGTTCAAAAAGAATCCTTCTCTCGCAAGTTCGAGTTCAAGAAAAATTAAAGGTTGCCAAAGAGAACTCGCTACCATGATGCGCGGTTCAAACATGGGTATCCTGCCTTATTGGCTTATCACATTATTGATCACTTGGGGGCTTGCTGCTCATTGAGCATAGCTATGACTACCTTCTTAATCCGGCTTGTACGCCATGATTACAAAATACTTGGGGGCTTCCTGCTCATTGAGCATAGCTGTGATTACCCTATTGATAACCCACTTGGAGACTTGATGCCCGGGTTAAAGGTACCAAAGAGAGTCTATTGCAGAGCACAGCTCAAACATAGGTACCCTGCTTTGATGGCTCAATATATATCACTTGGGGGCTCCCTGTTCATTGTAACATAGCTTTGGTAACCATTTTGATTGGCTTGAAACGCCAGGTGTATACACCAAAAAATTTCAGTTGATCCTGCCTTTTACGTCTGCCACTTCGCTCAGGTAATCCTGGAATGACCCACCGAACTCTTAACAGTCAATCTTATTAAGACCCTGAACTTGTCAAGGTTAAAACGGCGGTTGGTCATGTGAGGCCCGACTTATAAGGTTTGAATGAAGGATTAACTTAGCGGTTGTGCAAGCCTATGAAAAGCACTTGATGATTGAGGCCTGGCCGCCTATGAAAGCCTTGATTTTTTGTTATTTGTTTTTGAACGATGTTTGAGTTCATACCTTTTTTGATATATGGTTTAAACTGATTCAGGCCATGTAGCCTTAATCCTTATGACTCGTATTTGAGCATATTTGGGGTTTGATAACCCAGCCTGGCTTTGGATGATAAGTCGCCAGTATGCTTTGATTGTGCGCTGATGTCTACTACGCAACCTTCTTCTTGTAGACGTTGTTGGGCCTCCAAGTGCAGAGGTTTGTAGGACAATAGCAAATTTCCCTCAAGTGGATGACCTAAGGTTTACCAATCCATGGGAGGCGTACGATGAAGATGGTCTCTATCAAACAACCCTGCAACCAAATAACAAAGAGTCTCTTGTGTCCCCAACACACCCAATACAATGGTAAATTGTATAGGTGCACTAGTTCGGCGAAGAGATGGTGATACAGGTGCAATATGGATGGTAGATATAGGTTTTTGTAATCTGAAAATATAAAAACAGCAAGGTAACTAATGATAAAAGTGAGCACAAACGGTATTGCAATGATAGGAAACAAGGCCTATGGTTCATACTTTCACTAGTGCAATTTCTCTCAACAATAATAACATAATTGGATCATATAACTATCCCTCAACATGCAACAAAGAGTCACTCCAAAGTCACTAATAGCGGAGAACAAATGAAGAGATTATGGTACGGTACAAAACCACCGCAAAGTTATTCTTTCCGATCAATCCATTGTGCTATTCATATAAGTGTCACAAACAGCCCTAGAGTTCGTAGTAAAATAACACCTTAAGACACACATCAACCAAAACCATAATGTCACCTAGATACTCCAATGTCACCTCAAGTATCCGTGGGTATGATTATACGATATGCATCACACAATCTCAGATTCATCTATTCAACCAACACATAGAACCTCAAAGAGTGCCCCAAAGTTTCTATCGGAGAGTCAAGACGAAAACGTGTGCCAACCCCTATGCATAGGTTCATGGGCAGAACCCGCAAGTTGATCACCAAAGCATACATCAAGTGAATCAATAGAATAACCCATTGTCACCACGGTTATCCCACGCAAGACATACATCAAGTGTTCTCAAATCATTAAAGACTCAACCCGATAAGATAACTTCAAAGGGAAAACTCAATCCATTACAAGAGAGTAGAGGGGGAGAAACATCATAAGATCCAACTATAATAGCAAAGCTCGCCATACATCAAGATCGTGCCAAATCAAGAACACGAGAGACAGATCAAACACATAGCTACTGGTACATACCCTCAGCCCTGAGGGTGAACTACTCCCTCCTCGCCATGGAGAGCGCCGGGATGATGAAGATGGCCAGCGGTGAGGGATCCCCCACCCCTCCGGAAGGGTGCCGGAACTGGGTCCCGATTGGTTTTTGGTGGCTACAGAGGCTTGCGGCGGCGGAACTCCCGATCTATTCTGTTTTTCGAAGGTTTTTGGGTATATTGGTATATATAGGAGGAAGAAATACGTCAGGGGAGCCACGAGGGTGGAGGGCGCGCCCAGGGGGGTGGGCGCGCCCCCTGCCTCGTGCCCTCCTCGTTGATTTCCTGACGTGCACTCCAAGTCCCCTGGATTGCTTCCATTCCAAAAATAACTTTCCCAAAGGTTTCATTCCGTTTGGACTCCATTTGATATTCCTTTTCTGCGAAACACTGAAACAAGGGAAAAACAGAAACTGGCACTGGGCTCTTGGTTAATAGGTTAGTCCCAAAAATAATATAAAAGTGTTTAATAAAGCCCATAAACATCCAAAACAGATAATATAATAGCATGGAACAATCAAAAATTATAGATACGTTGGAGACGTATCAGCATCCCCAAGCTTAATTCATGCTCGTCCTCGAGTAGGTAAATGATAAAAACAGAATTTTTTATGTGGAATGCTACCTAACATAATTATCAATGTAATCTTTTTTATTGTGGCAAGAATATTCAGGTCCATGAGATTCAAGACAAAAGTTTAATATTGACATAAAAATAATAATACTTCAAGCATACTAACTAAGCAATCATGTCTTCTCAAAGTAACATGGCCAAAGAAAGTTCATCCCTACAAAATCATATAGTTTGGTCATGCTCCATTTTCATCACACAAGAATGCTCTCGTCATGCACAACCCCGATGACAAGCCAAGCAATTGTTTCATACTTTAGTAATATCAAAATTTTCAACCTTCACGCAATACATGAGCGTGAGCCATGGATATAGCACTATGGGTGGAATAGAATATGATGATGGGGGTTATGTGGAGAAGACAAAAAAGGAGAAACTCTCACATTGACGCCGCTAATCAACGGGCTAGGGAGATGCCCGTCAATTGATGTCAATGCAAGGAGTAGGGATTGCCATGCAACGAATGCACTAGAGCTATAAATGTATGAAAGCTCAACAAAAGAAACTAAGTGGGTGTGCATCCAACTTGCTTGCTCATGAAGACCTAGGGCACTTGAGGAGGCCCATTGTTCGAATATACAAGCCAAGTTCTATAATCAAAAATTCCCACTAGTATATGAAAATGACAAAACAAGAGACTCTCTATCATGAAGATTCTGGTGCTACTTTGAAACACAAGTGTGGTAAAATGATAGTAACATTGTCCCTTCTCTCTTTTTCTCTCATTTTTTTGGGCCTTCTCTTTTTTTATGGCCTTTCTCTCTCTTTTTTTTATAGTCCTCACTTGGGACAATGCTCTAGAAAATGATGATCATCACACTTCTATTTATTTACAACTCAATGATTACAACTCGATACTAGAACAAAGTATGACTCTATATGAATGCCTCCGGCGGTGTACCGGGATATGCAATGAACCAAGAGTGACATGTATGAAAGAATTATGAATGGTGTCTTTGCCACAAATACTATGTCAACTACAAGATCATGCAAAGCAATATGACAATGATGAACGTGTCATGATAAACGGAACGGTGGAAAGTTGCATGGCAATATATCTCGGAATGGCTATGGAAATGCCATAATAGGTAGGTATGCTGGCTGTTTTGAGGAAGATATAAGGAGGTTTATGTGTGAAAGAGCATATCATATCACGGGGTTTGGATGAACCGGCGAAGTTTGCACCAACTCTAAATGTGAGAAAGGGCAATGCACGGTACCGAAGAGGCTAGCAATGATGGAAAGGTGAGAGTGCGTATAATCCATGCACTCAACATTAGTCATCAAGAACTCACATACTTATTGCAAAAATCTACAAGTCATCAAAAACCAAGAACTACGTGCATGCTCCTAGGGGGATAGATTGGTAGGAAAAGACCATCGCTCGTCCCCGACCGCCACTCATAAGGAAGACAATCAAGGAACACCTCATGTTTCAAATTTGTTACATAACGTTTACCATACGTGCATGCTACGGGACTTGCAAACTTCAACACAAGTATTTCTCAAATTCACAACTACTCAACTAGCACAACTTTAATATCACTACCTCCATATCTCAAAACAAGCATCAAGTATCAAACTTCTCTTAGTATTCAGTGCACTTATATGAAAGTTTTTATTATACCCATCTTGGATGCCCATCATATTAGGACTAGTTACATAACCAAAGCAAACTACCATGCTGTTCTAAAGACTCTCAAAATAATATAAGTGAAGAATGAGAGTTCATCTATTTCTTCAAAATAAAACCACCGCCGTGCTCTAAAAGGATATAAGTGAAGCACTAGAGCAAATGACAAACTACTCCGAAAGATATAAGTGAAGATCAATGAGTAGTCGAATAATTATACAACTATGTGAAGACTCTCTAACATTTAAGAATTTCAGATCTTGATACTTTATTCAAACAAAAAGCAAAACAAAAGAAAATAAAATGACGCTCCAAGCAAAACACATATCATGTGGTGAATAAAAATATAGCTCCAAGTAAAGTTACCGATGAACGAAGAGGAAAGAGGGGATGCCATCCGGGGCATCCCCAAGCTTAGGCTCTTGGTTGTACTTGAATATTACCTTGGGGTGCCTTGGGCATCCCCAAGATTAGGCTCTTGCCACTCCTTATTCCATAGTCCATCGAATCTTTACCCAAGACTTGAAAACTTCACAACACAAAACTTAACAGAAAACTCGTAAGCTCCGTTAGCGAAAGAAAACAAAAAACCACTTCATGGTACTGTAATGAAATCATTCTTCATTTATATTGGTGTTAAACCTACTGTATTCCAACTTCTCTATGGTTTATAAACTATTTTACTAGCCATAGAGTCATCAAAATAAGCAAACAACACACGAAAAACAGAATCTGTCAGAAATAGAACAGTCTGTAGTAATCTGTAACTAACGCAAACTTCTGGAACTCCAAAAATTCTAAAATAAATTTTTGGACCTGAGGAATTTGTCTAGTAATCATCTGCAAAAAGAATCAACTAAATAGCACTCTCCAGTAAAAAGTTTAGCTAATCTCGTGAGCGCTAAAGTTTCTGTTTTTTTACAGCATGCTCATAAAGACTTCACCCAAGTCTTCTCAAATGTTCTACTTGGCACAAACACTAATTAAAACACAAAACCACATCTAAACAGAATCTAGATGGATTATTTATTCCTAAACAGAACCAAAAAGTAAGAAACTAAAATTAAGTTGGGTTGCCTCCCAACAAGCGCTAATGTTTAACGCCCCTAGCTAGGCATGATGATTTCAATGATGCTCACATAAAAGATAAGAATTGAAACATAAAGAGAGCATCACGAAGGATATGACTAGCACATTTAAGTCTAACCCACTTCCTATGCATAGGGATTTTGTGAGCAAACAACTTATGGGAACAATAATCATCTAGCATAGGAAGGCAAAACAAGCATAACTTCAAAACTTTAAGCACATAAAGAGGAAACTTGATATTATTGCAATTCCTACAAGCATATGTTCTTCCCTCATAATAGTTTTCAGTAGCATCATGAATGAATTCAACAATATAACCAGCACCTAAAGCATTCTTTTCATGATCTACTTGCATAGAAATTTTACTACTCTCATAAGCAAAATTCTTCTCATTCCGAATAGTGGGAGTATCATAAGAGACTTGAATACTATAAATTGTTTCCACATTAAAAGAGTAATGTTCAGAAAAAGGGTAATCAGAATCATGACAAGTTTTATAAATATAATCATCACTACTTTTTATAGCATAAGTTTCATCACAATAATCAGCATAAGTAGCAACTGTGTTCTCATCATAATCAATTGAAACCTCTTCCGAAATAGTGGATACATCACTAAATAAAGTCATGACCTCTCCAAATCCACTTTCATAAATATTAAAAGATTCAACACCCTCCAAAATAGTGGGATCATTACTTCCTAAAGTTGACACTCTTCCAAACCCACTTTCATCAATATAGTCATCATAAGTAGGAGGCATGCTAACATCATAACAAATTTGCATATCAAAACTTGGGAGGCTAAAAATATCATCTTCATCAAACATAGCTTCCCCAAGCTTGTGGCTTTGCATATCATTAGCATCATGGATATTCATAGAATTCATACTAACAACATTGCAATCATGCTCATCATTCAAATATTTAGTGCCAAAAATTCTAATGCATTCTTCCTCTAGCAATTGAGCACAATTATCGGAATCCTTATTTTCATGAAAGATATTAAAAAGATGAAGCATATGAGGTACCCTCAATTCCATTTTTTTGTTGTTTTCTTTTATAGACTAAACTAGTGATAAGGCAAGAAACTAAAAGATTCGATTGCAAGATCTAAAGATATAACTTCAAGCACTCACCATCCCGGCAACGGCACCAGAAAAGAGCTTGATGTCTACTAAGCAACCTTCTTAGTGTAGACGTTGTTGGGCCTCCAAGTGTAGAGGTTTGTAGGACAGTAGCAAATTTCCCTCAAGTGGATGACCTAAGGTTTATCAATCCGTCGGAGGCGTAGGATGAAGATGGTCTCTCTCAAACAACCCTGCAACCAAATAACAAAGAGTCTCTTGTGTCCCCAACACACCCAATACAATGGTAAATTGTATAGGTGCACTAGTTCGGCGAAGAGATGGTGATACAAGTGCAATATGGATGGTAGATATAGGTTTTTGTAATCTGAAAATATAAAAACAGCAAGGTAAGTAATGATAAAAGTGAGCACAAACGGTATTGCAATGATAGGAAACAAGGCCTAGGGTTCATACTTTCACTAGTGCAAGTTCTCTCAACAATAATAACATAATTGGATCATATAACTATCCCTAAACATGCAACAAAGAGTCACTCCAAAGTCACTAATAGCGGAGAACAAATGAAGAGATTATGGTAGGGTACGAAACCACCTCAAAGTTATTCTTTCCGATCAATCCATTGGGCTATTCCTATAAATGTCACAAACAGCCCTAGAGTTCGTAGTAAAATAACACCTTAAGACACACATCAACAAAAACCCTAATGTCACCTAGATACTCCAATGTCACCTCAAGTATCCGTGGGTATGATTATACGATATGCATCACACAATCTCAGATTCATCTATTCAACCAACACATAGAACCTCAAAGAGTGCCCCAAAGTTTCTACCGGAGAGTCAAGACGAAAACGTGTGCCAACCCCTATGCATAGGTTCATGGGCGGAACCCGCAAGTTGATCACCAAAGCATACATCAAGTGAACCAATAGAATAACCCATTGTCACCACGGTTATCCCACGCAAGACATACATCAAGTGTTCTCAAATCATTAAAGACACAATCCGATAAGATAACTTCAAAGGGAAAACTCAATCCATTACAAGAGAGTAGAGGGGGAGAAACATCATAAGATCCAACTATAATAGCAAAGCTCGCGATACATCAAGATCATGCCAAATCAAGAACACAAGAGAGAGAGATCAAACACATAGCTATTGGTACATACCCTCAGCCCCGAGGGTGAACTACTCCCTCCTCGTCATGGATAGCGCCGGGATGATGAAGATGGCCACCGGTGAGGGATCCCCCCCCCCTCCGGCAGGGTGCCGGAACAGGGTCCCGATTGGTTTTTGGTGGCTACAGAGGCTTGCGGCGGCGGAACTCCCGATCTATTCTGTTTTTTGAAGGTTTTTGGGTATATTGGTATATATAGGAGGAAAAAATACGTCAGGGGAGCCACGAGGGGCCCAGGAGGTGGGCGCGCCCCCTGCCTCATGCCCTCCTCGTTGATTCCCTGACGTGCACTCCAAGTCCCCTGAATTGCTTCCGTTCCAAAAATAACTTTCCCGAAGGTTTCAGTCCGTTTGGACTCCGTTTGATATTTCTTTTCTGCGAAACACTGAAACAAGGGAAAAACAGAAACTGGCACTGGGCTCTTGGTTAATAGGTTAGTCCCAAAAATAATATAAAAGTGTTTAATAAAGCCCATAAACATTCCAAACAGATAATATAATAGCATGGAACAATCAAAAATTATAGATACGTTGGAGACGTATCATGCGCTTGGAGTTCTGTGCTCTAAGTTTTTGGGTTGTTACCCTTGCTGCGTATGGCGCTGTAAGCCGGCTGTATGAACCGATTTCACAGGCCATGTAGCCTTGATTGTATGACTCATCATGGAGCATCTTTGGGTTTGATAACCCGCCCTGATAGCGGATGTTGAGTCGCCAAGATATCTTTGCATTGAGCAATCAAAATTATGATATTACATGCCTACGGGTCAATACCCGTGACGGATTATAATTATTGAGGTATCACCAGGATGTCAATCTCCAGGTATGTTTTTCAATAATGGTATGAATATTTTGGGTTTGGTAACCCGCCCTGGCTATGGACTTTAAGTTTCTAGAATACTTTGGATTGCGCAATTGGGATTATGCGCTTATGAATACTTGGGATGTGGCTATGTAAGCCGGCAATTTGAGCCAAATTTCTAGGTATGTTTTTAAATTGTTGGATGAATATGTGAGGTTTGATAACCCGCCCTGGCTTTGGACATTAAGTCGCCAGTATATTTTGGATTGCACCATTGGAATCATGCGCTTATAAATTATTGGATTGTTACCCTCACTGGATATGGCGATGTACGCCAGCGGTATAAATCAATCCTACAGGTATGTTTTCCTGGTTATATGAATATACGAGGTTTGATAACCCGCCCTAGCTTTTGACTTTAAGTCGCCAGTATGTTTAGGCTTGAATGTCCTTGCTTAGTCTTTTCGGTAATTACATAAGACTATATTATGTTTGGGTTGTTGCCCGCCCTGGCTTTTGACGTTAAGTCGCCAGGGCATATGTTGTTTAAACTGTGTAGAACATGCAGAGCTTTACACATAAGTAAGAATACTGCTATTGCTCATATGAATCATTGCGTTTAAACCCATCATCTGGCCATCTGAAGATATTGCCGGGTTATCCGGCTCCGGGCTATATTGTTCAATATTGAGTTTATTGAGGCTATGAGCTGCCAAAGTGATCTTGTCAAAAACTGGACATGATTATGAGCCGCCATGGATGGGGTTATCAATTCTTGATTTTTACAAAGGCTATAAGCCGCTGGATTGCAAAGTCCCGGATTACAATGGATGCGCATTAAGTCGCCATCGACCAAGAGCCGCCGGGTATTTAAATTCCGGATTTACTTGTCAAACAGATAAGGTATTCAAATCTTTAATAGCCAAACTTGGCTGGAGTTTCATTATAATATTGAATGATTGAGGTTTTCATACCGGATTATATGACCCGGCCGGACATGGCGCCTCACCAGAAACCCGGTTGATACTTGGCGACTCACTAGAGACCCGCCCGAACCTCAGCGACTCATTAGTAACCCGGCGGGCGGGTCAGACGATCGACAAGACCCAACGGCCCAGAAGGCGACTCGTGGGAAGGCCGGCTCGTGTTATGGTGGGCCGGCTTAAGATGAAAGGCTAAAGAATATTCTCCTAGAAAGAAAGCAAGACTAGGACTGCACTTGTAATAGAGTAGTCCTAGTCCTACTAGGACTCCACATGTAACCCGCCCCTCCAACTTAGATAAGGAGGGACAGGGCACCCCAAGAGGGACAAGTTTTCACGAGTTGGACAAGTTAGGGTTAGACAGACAAGTCTATAGCTATCGAGATAGAGCACCCTTGTAATCGTGATCATCATCATCAATATCAATGAAGCAGGATGTAGACTTTTACCTCCACCGTGAGGGCCGAACTTCGGTAAAAAACCTCGCGTCTCTCGCCCCACTCAACCCCTCTCAAGCTACCACATAGATGCGTTGGCTTCATGACTAAGTCCTCATACTAGGACATCTGCCGTGACAAATCCACGACAAGATTCAAGTGGAGGCAACATGTGGTGCACATCGAAAGTTTGGATTAGTAGTATAGCTTCGAGATGCACCACATGCTGCCTCCACTTGAACCTAATCCACCTCCATTTCACACACTGTTATGGACATAATGATATATCAACCTCATAATTGGTCCTGTATACAAATTTGTACAACGGCGTATAAATACACTAAAAGTAAAAAAATAAAAAACAGTATACTGGTAGCGCTGGACCGGAAACACGCTACTACTAGCTAGTTAGATTAGCAGTAGCGTGTGTTGCACGGGCTACTGCTAAGGAATAGCTGTAGCGCCTTACTAGTAGTGCGGTGACACGCGCTACTAGTAGATCAACGTCTTCAGTGGCATGTTCAGCAGCTGGATCTTCTCCGCGGTGGTCGGCACTACCATCGGGTTCCAGGTGATCCTCGTGGAGTTGTTGGGCACGGTTCACCTGAACGGGAGGCTGTGACTCATGAGTGTGTTGATCGGGTCGGTCAGCCTGGTTATCGGCGCCGTCCTCAAGTGCATCCCTGTTGGTTCCGGCAACGCCTCGTCCGATCGTCACGACGGATACCAGCCCATCCCCACCGGCCCTAGTGCCATGTGATTTTGAAGAAGTTTTGGTTGGTTTGTTTAGGAAAGGGGAAGATGTATGAATCTTTTAGAATCAAACTTTGCAGCTTCAGTTTTTTGTAGGAGGTACCGGAACAATTTTTTTGGATTGAGAAAACCGGACATACTTGTGGTAATGACGGTTCTGAGAAATTTAAGTTTCTATTTTTTTTCGTTGTTTTTGTTTTGTGCTTTCTAGCCAAATAGGACTATGGATTTCCATTGTAGGATTACTATGCAATGATAAATGCAGTTGCTTACTATCTAGTATCTATACACAAATCTTCACATTTAGGGTTATACTCATGCGGGTGACATGTGATTTCTGGAAGATGTTCTTTTTATTTATTTTTCCTTTTGGAGGAAAAGAATGTAGTGTTAAATGAACTTTTAAGTACAGTTTGAGCTTTTTCCCCACTCAGGCAAATGAAGTTTCTGAAATTTTATTGTAGAATCCTTATAAACAACAAAAAAAAACTGAACCATGCAGGAGACTTACATGTACTCCCTCCATTTCAAAATATACGGTGTATTAGTTTTTTCAAAAATAAAACATGTGCAAGCTTGACCAAGGTTTAAGAAAAAATTATCAATATTTACAATACCAAATTTGTAGCATTAGATCCTTCACTAAACAAATTCATATTTTCTTTATTTGGTTTTGTAGAAGTTCATATTTTATTCTATAATCTTGGTCGAACATATATAAGTTTGACTTGCACGAACCTGATTCACCTTATATTCCGGAACGGAGGAAGTAATTCGGTAATAAAGAGATCAGTACAACGCCAAAGATGGCACAACCGTTACATCGCCAACACCATGACCAAACTACGACACTTACATCACCAACAATGGCGCAACCTAAACAACACAATGAGAATGACCCAATACAACTCGGACTAGGGCAAGCGTCCAACACCAGGCATAAAGAACAGAGAAAGATCCTCTGCAAGAGCCTGCACAATAGCCCGACACAACACTACCCCAACGACGACTACCACGTCAACGATTACTGACGTACAAGCAATACTATTTGCAGCAACATAGGCATGACGTCACGAATACAAGAGTCCACCTCAGGCTGTAAGTGGGACGCTCCGCGGGAGGCCCGCGTCCGCCCCACATCTGCCGCGTAGATTAAGTGGAATTCCCGTTAAAGCCTGCATATTATTATGTGGGATATGTGGGTTTAGTAGGATACCCACAAAATTCATACAGATGCTTCTGTTGAAAGTCAACTTGAGGTGGTGAGCTACAATGACTGGTTCGTCGGGAGCTCGAACAGCTCGTGTGCATGATGCGCACGTACAGCCGGCATGCCTTGGCCTTGCCCTAGTGCTCTTGTGCCGTCGATGGAGCCTCTTGGAGCAAGAAAGACTGCTCGCTGAAACAAACCCAACAGTTCAGATCGCTGAATCAACTACTCCCTCCGTTCGGAGTCATTTTTGTGACAAGTAATTCCGAACTGAAGGAGTAGTAACTAATAGCCATACATTTACAAGTTTTCAGTAGAGTAGCATTTATATACCAGGTTAACACCTCACACATACACAAACACAGACACAAATACAAGCGTCCATGGCTGGACGCGGCGCGGCAGCCGGTGCTGGCGATGCACGGAGACAGGCTGTCGACGTGGCCGTCCAACAGGCCGCGGCCCTCACGGACACCGACGAGCAGGCCTCGGTTCCACGGACGTCGCACACAGGAGTACGTCCTCGAGCCTGCAGGACCGTCGGCGAGCGCGCCCGGCGGCCGGAAGCTGCGACGGAGGTAGACGGCGGCACTGCGGCGCCCACGGCGGAGATGGGCGATGACGCTAGTGCGGCCATAGAGGAGGTCGACGGAGTCGCTAGGTCGTCCATGGAGGAGGTGGACGACGAGGTAGGCCGGCCATGGCTGGCGGCGACCCCTAATCCCCGCAGCGTGTCCAGATAAGTGGGTTCGATGTGGGCATCGTGGGATAACCCACATATTCCACATATTGTGGTGTATTGACCGTGGGTGTCCACGAACGCAAAATAAACGGGCCTTTAAGTGGGCACCGCGGGTGGCCCGTGTCCACCTACAGCCTGAAGTCCACCATTCCAACGCCGCCAGGCTAGCCTCCATCCAGACCATACAAGGAGAGTCATGGGGGTGGGCATGCAAAACCGGAGGGGGGCAGCGACGACCAACCAGGGGCGCTAGCGAGGAAAAGGCGACGCTCGCGCAAAACAAACACTGACTATCACTAGCCTTCCATCAACACCAGTCACCACGGGTCTCTCTCGAACTCTCCATAGAAGACAGAACGCGAGAGGAATCCCAGAGGCGTCCGTTTTCCCGGTCCTTCCGCCGGCGACCTCGCCGCTCCTCCTCGCCTCTGATGGCCGTTTTGGCCTCAGCAGGAGGGGGGAGCTCCGGGGAAGCCCGGCCGTCTAGGTAGGTTCCAGGAGGCGCCGTTTAGATGTCGGCGGCGGCACCGTGTCAGAATAAATGTCGCCTGGCTTCAGCCGTGTTTCGTCGGAGATCTTGTCCCCGGCGAGAAGCCCATGGGTGCGTGGTTCATGTTGAGGATATGTGTTATGTGCATATTGTGTATTGGGCTGGCTTCCTAGTTCCTTGTATAATTGAGGTATGTGGCTCATCTTTGTATATCATATATACGTGCCTATGCACAAAGAGCAATACATCATGCAATTCACATATTCTATATAGTATCAGTTTTTTAGGTTCTCTCGCTTCCGCTGCCGCCGCCGTCGTGCGTCTCCTCCGCGCCGCCGCCGCCGCCGCCCGATCTCCTTGCCGCCAACAGTCAATCCACGGCCGCCGCAGCCCTCTGCCACCCGTTCGCCGACGCCAACCCTCCCGACGTCAATGACATCCGCAACCTCAACATCTTCGAGCGGGTGTCGGTTCGTCTTTCGCAGGCGAACTCCTCCTACTACACGTGGAAGACCTACTTTTCCCTCGTGTTTCGGGAGTATCATCTTGTTGATCACGTGGACGGCACCGTCGACTCCAGCCTTGTCCCCGATTTCCATGAATGGTCCACCATCGACACCACGATCATCCGATGGTTCTTCCTCACCATCTCGCCAGACCCCTTCCAGGCGGTTGTCCAAGACGGTGATGACGCATGCGCCGTGTGGACCAACCTGAACGGGCTCTTCACCGACAACAAGCTCCAGCATCGCGTTTTTTTTGCAGCAAGAGTTCTTTGGGTGTCACCAGGACAACACCTCCGTCGACGACTATTGTCGCCGCCTGAAGACTCTCACTGACGAGCTCCGCGATATTGGCGCGAAAATTGATGATGACCTCCTCCTCACCACGCTGACCGCCGGGCTCAACGAGGATTTCGGCAACGCCGCGGCGAACCTCAGTCTCATCCCCAACCCGTCCTTCGCCAAGTTCATTGTGTACCTCCGCTTGGAGGAGCAGCGGATGAAGCAGGTGAAGGCGCGGGCCATCCACACCGCCCTCGCCGCCGGCACCACCCATGGCGGGTCCTCGGCGCCTCCCGCTGCCCCGGCCGCGCCCCTGCCGCAGCGCCACCTGGCGCCGCTGCCGTACCCGGCGCCCCAGCAATCGGGGCTGCTCCCGCTGCCTTATGGGTCGCCCGCCCCTCCCGCAGAACGGCGCCGCGGGGGCCGGCGTGGTGGGGGCCACCGCGGCGGTCAGCAGCAGCAGCCGCAGGGCGCCGGCCAGCCCCGTCAGCAGCAGCAGCAGCAGTTCCAGGTGCCCCCTCCGTGGGCCTCCGGCTACAACCCGTGGACCAGTGTTGTTCATACCCACACCATGCCGGTTCCACGGGCTCCTGGACCGACCCTTCCCGTGCCGCGCCCGTCGGCGCATCAGGCGTATTACGCGGCTCCGCAGCCGTACGGAGGATACCCACTGCTGCAGCTGAGCGGCGCCTACGGTCTTCCTGCGGCCCCGCCGCCGCCCTTGCCGGCCCTGCCGCCGGCGCCTTGGGATCCGGTGCTCCTCGCTGCGCTGCACACCGCGCCTACGCCGAACAACTACACTGGAGGCGGTGATTGGTACATGGACACCGGGGCTACGGCTCACATGTTTGCTTATCCTGATAATCTTGCCTCCTTCACTCCCGTCACCACCGATCGGCGCATCATTGTCGGCGACGGTTCCACACTCCCTATCACACATGTCGGGCACACTTCTTTTCCTTCTAATTCCATGCCTATTACTTTGTCTAACATACTACTGTCACCTCATCTTATTAAGAACCTTGTTTTCGTTCGTTGTTTAACTCGTGAAAATCCTGTTACTGTTGAATTTGATGAGCCTGGTTTTTGTGTCAAGGACGCTCGAACCAGGATGGTACTTCACCGATGTGACAGCCTCGACGAGCTCTATCCGGTGCATCCGCCGTCCACACCGGTTGCTCTCTCCGCCGGTGTCAATCTCTGGCACGCTCGTTTGGGTCATCCCAACCCAGTCACACTTCGTCATATTCTTAGGAGTTTCAGTTTCAGTTGTAATAAGATAGAGGATCACACCTGTCATGTCTGTCGTGTCGGCAAACATGTTCGCCTCCCATTTAATAACTCCACCACCATAGCTTCTTTTCCTTTTCAGTTGATTCATAGCGATGTGTGGACCTCTCCGGTTCCTAGTAATTCGGGCTATTTATATTATCTGGTTATCCTTGATGATTATTCTCACTATGTGTGGACGTTTTCTTTACGACGAAAGTCGGATGCACTCTCCACTTTGTCGGCTTTTTACTCCTATGTCAGCACGCAGTTGGGCATCCCATCCTTGCTCTTCAGACTGACCATGGAAAAGAGTTCGACAACCTTGCTTTCCGCACCTTTCTGTCGCACCACGGCACAGTTTTTCGTCTCACATGCTCGTATACTTCATAGCAGAACGGTCGAGCTGAACGCGTCCTTCGCACTCTGAACGACTGCGTTCGCACGCTCCTGTTCCATGCTAATGTGCCGCCTCGTTTCTGGCCAGACGCACTCTCTACTGCTTCAGTTCTCCTTAACCTTCGCCCTTGCCGCCCACGATGGAACTATGCACCTCACCATCTTCTCTTCGGTACGCCCCCATCTTATGACGGCTTGCGTATTTTCGGGTGCCTTTGCTATCCTAGCACTGCCGACTCCGCTCCTCACAAACTCGCACCTCGTTCTATCGCTTGCATCTTCATCGGCTACCCCTCCAACTCCAAGGGATATCGGTGCTACGATCCCGTCTCCCACCGTGTGTTCACCTCCCGGCACGTTTACTTTGATGAGCATGTGTTTCCGTTTCAACAGGTACCCCCGGCTGTTCCTCCCGCCACCAGTGACGTGGGCTCCTCGACTCCTCTCCCAGGGCGCTCACACGCCTCTCTTGGCCCGCCCCTTGGCTTTGAGGCGCGCCCCCCGCATGCAGCGGCTCCTACCGCCGCGGCACTAGCGCCCCCGACATTGGCGCCCGCGGCCCCCCTGGCGCCCCTGGCGTCCCCGGCCCCCCGGCTCCCTCGGCGCCCCCGACGCCCCCGGTGCCCGCGGCCGGTCCGGTCACCCGCGCCCGAACGGGTTTTTTTCGCCCGAGCTCGCACTACGCCTCGGATGATTACGTCCATGCGGCTGATGACCCACAAGTATCGGGGATCTATCGTAGTCCTTTCCATAAGTAAGAGTGTCGAACCCAACGAGGAGCAGAAGGAAATGATAATCAGTTTTCAGTAAAGTATTCTCTGCAAGCACTGAAATTATCGGTAACAGATAGTTTTGTGATAAGATAATTGGTAACGAGCTAGTTTTCATCACGCTCATATGATTCGCGTTCGGTACTTTGATAATTTGATATGTGGGTGTACCGGTGCTTGGGTGCTGCCCTTACTTGGACAAGCGTCCCACTTATGATTAACTCCTATTGCAAGCATCTGCAACTACAAAAGAAGTATTAAGGTAAACCTAACCATAGCATGAAACATATGGATCCAAATCAGCCCCTTACGAAGCAACGCATAAACTTGGATTTAAGCTTCTGTCACTCTAGCAACCCATCATCTACTTATTACTTCCCAATGCCTTCCTCTAGGCCCAAACAATGGTGAAGTGTCATTTAGTCCACGTTCACATGACACCACTAGAGGAGAGACAACATACATCTCATCAAAATATCAAACGAAAACCAAATTCACATGACTACTAATAGCAAGACTTCTCCCATGTCCTCAGGAACAAACGTAACTACTCACAAATCATATTCATGTTCATAATCAGAGGGGTATTAATATGCATTAAGGATCTGAACATATAATCTTCCACCAAGTAAACCAACAAGCATCAACTACAAGGAGTAATCAACACTACTAGCAACCTACGGGTACCAATCTCAGGCTATGAGACGAAGATTGGATACAAGAGATGAACTAGGGTTTGAGAGGAGATGGTGCTGGTGAAGATGTTGATGAAGATTGACCCCCTCCCGATGAGAGGATCGTTGGTGATGACGATGGTGATGATTTCCCCCTCCCGGAGGGAAGTTTCCCCGGCAGAACAGCTCCGCCGGAGCCCTAGATTGGTTCCGCCAAGGTTCCGCCTCGTGGCGGCGGAGTCTCGTCCCGCAAGCTTGCTTATGATTTTTTCCAGGGTAAAAGACTTCATATAGCAGAAGATGGACACCGGAGGCCTGCCAGGGGGCCCACGAGGCAGGGGGCGCGCCCAGGGGGTAGGGCGCGCCCCCCGCCCTCGTGGCCAGGGTGTTGGCCCCCTCTGGTATTTTCTTCGCTCAGTATTGTTTATAATTCCCAAAAATAACTTCCGTGGAGTTTCAGGACTTTCGGAGTTGCGCAGAATAGGTCTCTAATATTTGCTCCTTTTCCAGCCCAGAATTCCAACTGCCGGCATTCTCCCTCTTCATGTAAACCTTGTAAAATAAGAGAGAAAAGGCATAAGTATTGTGACATAATGTGTAATAACAGCCCATAATGCGATAAATATCAATATCAAAGCATGATGCAAAATGGACGTATCAGCGGCGTCCACCTCTGAGCCGTCATTGTTGCCGTCCTCTGTTCGAGCCGCTCTTCGTGACCCGCTCAGGATGGCTGCGATGCAAGAGGAGTTTGACGCCCTATTGCGCAACCGGGCGTGGCAGCTTGTTCCCTGTCCCCGGCGCGCCAACGTGATTACCGAGAAGTGGGTCTTTAAACACAAGCTCCGTCCTGATGGTACCCTTGATCGCTCTAAAGTGCGTTGGGTCGTTCGTAGCTTCCGACAACGTGCTGGCATCGACTTCACCGACACCTTCGCTCTGGTCGTCAAGCCCGGCACAATACGCACGGTTCTCCACCTTGCGGTCTCCCGTGCTTGGCCGGTGCACCAGATGGACGTCTCCAACGCCTTCCTCCATGGTCACCTCGAGGAGAAGGTCTTCTGCCAGCAGCCCACCGGGTTTGTTGACCCGGCGCTTCCCGACCACGTGTGCCCGCTTTCGCGGTCCTTGTACGGACTCAAGAAGGCTCCGCGCGCTTGGTACCAGCGCATCGCAGCGTTTCTCCACCAGCTTGGGTTCCGTTCTACCCGCTCGGACGCCTCGCTCTTCGTCTATCATCAGGGCTCTGACACGGCCTACTTGCTGCTCTATGTCGACGACATCATCCTGACGGCTTGTACGGCTGGTCTCCTCAGTCAGCTCAAGGCTCGTCTTCGCGCTGAGTTCGCCATCAAGGACTTGGGTCCTTTGCACTACTTCCTCGGTGTCGAGGTGGTGCGCCGTCCGGATGGCTTCTTCCTTCATCAGCGGAAGTACGCTCACGAACTCCTGGAGCGCGCCGGCATGCTTAACTGCAAGCCCGCCGCTACGCCTATTGATACGAAGGCCAAGCTTTCTGCCACGGATGGTTCTCCTGCTTTGGATGCCGCTTTCTATCGGTCTATCGTTGGTGCTCTCTAGTACCTCACTCTGACTCGACCGGAGATCTAGTATGTCGTGCAGTAGGTGTGTCTTCATATGCATGCTCCTCGAGACGTCCACTGGGCTGCCGTCAAGCGGATTCTCCGCTATATCTGTGGCACTATGGATCTTGGCGTCACGCTTCACGCCTCCGCCGACACCGCCCTCACCGCCTACTCCGATGCAGACTGGGCGGGCTGCCCTGACACTCGTCGCCCCACTTCGGGCTATTGTGTCTACCTTGGATCCTCACTTATCTCGTGGTCGTCCAAGCGGCAGCCTACGGTCTCTCGTTCCAGCGCTGAGGCTGAGTATCGTGCGGTGGCCAACGTCGTCGCCGAGTGTTCGTGGCTTCGCCAGCTGCTTAAGGAGCTCCCTTCCCCTATTGACCGTGCCAGGATGGTCTACTGCGACAATGTCTCGGCGGTCTACCTCTCCGCTAACCCGGTGCATCATCGACGGACCAAGCATATTGAGTTGGATATTCATTTTGTTCAGGAACAGGTGGCCCTTGGCCTAGCCTTCTAGAGCTTGTTGCATGCCACTGTTATCTCTCAAACGAAAGAACATATAAATGTATCGCGATCCGTGCAGGTTATCAGTGACAACAGGCAAGGATCTCAAAGCAATGTTGGAGGGATGAGGATAAGAGGTTTCATATAGCTCGGCCTGCACAGGAACTTTCTGTATCTCCATTCACCGTTGTGCCGCCCTTAAATTGTTTCCGTAGGGTTCAGCCCGCGTAGAGCTTGCCGATCTGTACGGCAGTGTATCCAGCAGGGACAATATGATAAGTGGATACAGTAGCTGCATTTCCGTGTACCTCCTATACCCAACATATTGCACCAGCCACCCCAACTCATACAAGTTGTCAATTCTTCACTTTTTCATTCTTGCTAGTTTGGGTGCTACTATCTTGATAAGATGCAGACGGTCAGGAGGCTATGAGAACATGACTCCATAGAAAGGATATCCTTTATAAGAGTTGTTCAAGTTTATAATAGGAGGAGTTGGTGAGCGCATTAGATATCCATAAATTGAATCTAAAATAGAAATAAAGTCTCAAGGTTTACTACTTTCTATTCAATGGTATTTGCGTTATGTCAGTAATTTTGATGATGGGGCATTGGCAAATGCATCCATGTTGAATTTAGTGACGATTAGTCCTACCACCATAATATAGGCTACCAAGGTGAACTCGAGAGTGATTATCATAGTGGTCAACATCGCCAAATGGCGCCACTCCGTGTAAATCAACTCCCAAAACTTCGTCAGTTCCAACTCACTGCCAGCATGGTGGCCCACATGGTCGACTTTAATTGTCTCCGCATATTTCACAGGTGCACTGAAACTAACTCCATTGATTATTCACGCTCACACATTTTTGCGATGTCCTAGCACTCTCTGAGTCCATTCACATATGTTTCGATGCGTGCTGTTGATGATCGTGTAGCTACTTTAGGTGAACCTAATCATAGACACCCTCAGCGCGTTCATAATACAGCTACCAACCAATACTTCCTCTGATCACCACGATGGATACCAGTTGATCCCCACCGGACATGGACAAAGTGTCATGTGATGATATTTTAAACATGTTTTGTTCTTGCTTCTTTGTAGGAAGAAGAAGAAGAAGAAGAATCTGTGCTTTACAAATTGACTTTCCATCTTTAGTTTTTCTTCTGATATGTGACACCGGAATGGATTAAGATGGTGATTACACTTCCGACTTATTTGAGACTTTTCGATCAAAGTTTTCATCCGATGCTTTCTAGGTAACAACATATCTGAAACTTCTTAACCATGTCGGTTTCCATCAACAAAGGATTAAATGTTTCTTACATATAGACAAAAATTTCTTAGTAGAAAATTCCACCCAGAAACTCCTTCGGTTTCCATCTAGTAGTATCCTTTCTTTGGGCTTGGTTATAAGTTTTTGATGCCTCTAGAAGCAAAAGTTTAAATGAACACCTAATTTTTAGTTTGCTCATGGGAAGCATTTATAAATAATGCACTACAATCAAGAAGCACGGAAATAGTGGCTTCTGCAAGGCCGTAACTCCTACCAGCTTCTATTTTTTTGATAAAGGACATTTTATTGAATTGATATATCGAGGTGATACAATCGCATCGAAAGAATGCCCGACCTCTGCATAACTCCATGCACACAGCCAAAAAGTCCAACCGATCCAAAAAAATAAAATCGTCTTACAACTTAAAAAGATAAATTAGTCCAGCCTATGATGTGGCAGATCCTATCCGGAGATCACACCGCCATCCATGGGGGAGAAAACCTCCCTGGCTATACGCTCCAGCCGCGTAGACGCCATCATAAAACGGTCCCTGTCCTCCGGCCTCTGCAGGATATACCAAGTACGGAGCCATCGCGTACATACATGAATAATCTGCATAGGAGATGAAACACATTTTTTATTAAAAACCACATCATTCCTGGTAAGCCACAATGCCCAACATAAGGCAGCCGCCCCCACAAGAATATGTGCACAAAATTGTTTATCAATACCCCTCAACCAGTTGCCGAACATGTTACATGCACTAGGTGGTGGGTATAAATTTGAAGCTACTCGAACTATGGCCCAAACCGCCCAAGCGAACTTACACTCAAAAAATAAGTGCTTAATAGACTCGTCGTGTTGGCAAAAGACACACGCCTTGGTGCCTTGCCAGTTGCGTCGTGCCAGATTATCTCTAGTTAAGATGACCCCTCTGTTTAGGAACCAGAGGAATATCTTCACTCTTAGAGGGATTTTAAGCTTCCACAATTTCCTGTTATTAACTGGAACATCACAATGAACCATTGCATCATACATGGATTTGACTGTAAACTTGCCATTCCGATGCAAATTCCATCAAAAGATGTCCGGTTCATCTGACGGCTGAATAGCCTCTAGACGTATGAGTAGCTCATTCCAAGCTGCCAGGCGAGGTCCTAAAAGGTCCCTACGGAAGGAAATATCAGGGTTTTCTTGTCCCAAAACTTGTTTGATGGTGACAAATTTATGTCTAACAATCCTATACAAACTCGGGTATTGCACCATGAGTGGTGTGGTCCCTAGCCAGGTGTCTTTCCAGAATCGAATCTGGGAACCGTCCCTAACCGAGAAAGTCCCAAATTGGAAAAAGAATTCCTTGGGCTTCATGACTCTAGACCAAAAATGTGAGTCACCAGTTTTCCAATGGACTTGAGAAATGGCCTTGGATTCCACGTACTTGTTACGAATGATTTCCTGCCACACTCCATTCTCAGTGAGTAGTTTATAAACCCATTTGCTGAGAAGAGCAATATTTTTAATCTCAAGGTCCTGAATTCCAAGTCCCCCTTGACTTTTAGGTCGACATAATACAGTCCACCTAGTCAGTCGATATTTCTTTGATTCATTATCACACTGCCAAAAAAATCTAGATCTAAAGTAATCGAGACGCTGAAGAACCCCTTTCGGTAGATGGAAGAACAACAACATATATAAAACCATGTTGCTGAGGACGGAATTGATCAAGATCAATCGCCCCCCATATGACAAGAGTTTGGCTTTCCAACTGGCTAGCCGTTTCTCAAGTCTCTCTTCCACGTGCTTCCACTCAGCGATAGTTAAACGCCGATAGTGTATGGGAATACCCAGATACCGAATCGGGAACTGCCCGAGCTGGCATCCAAAAATGTCAACATACTTAGGTGCATATTCTGCAGCATCCCCGAAGCAAAAAAGTTTGCTCTTATGAAAATTAATTTTGAGGCCAGAAAGTTCCTCAAATGCACATAAAAGCAGCTTGAGATTTCTTGCTTTATCTAGATCATGATCCAAGAAAAGTATCGTGTCATCTGCATATTGTAGGATAGATAAACCCTCTTCTACCAAATGAGGAATGACACCGCTAACCTGACCGGCCACCTTAGCCCGCTCAACAAGGGTAGCTAACATGTCAGCCACAATGTTAAACAAAATGGGTGATGCGGGGTCCCCTTGGCGAAGCCCCTTCCTTGTCTGGAAATAGTTGCCAACCTCATCATTAACTTTGATGGCCACACTACCTCCAGAAACAAAACTCTCAACCCATCGACACCATTTTGGTGAAAACCCCTTCATGCGTAAAGTTTTCAACAGAAAGGGCCATTTAACTTTATCATAGGCTTTTTCGAAATCTATTTTAAAGATCACTCCATTCAACTTTTTGCGGTGAAGCTCATGTACCGTTTCATGCAGCACAACCACACCATCTAGTATGTTGCGTCCTTGCATGAATGCTGTTTGAGTGGGCTTGACGACATGATCAGCCACCCCGTTCAACCGGTTAGTTGCGACATTCGTAAAGATTTTGAAGCTTACATTGAGAAGGCAAATCGGTCGATATTGTTGAATACGACTGGCCTCCTTAATCTTAGGCAGTAGGATAATCTCCCCAAAGTTTAAGCGGGAAATATCAAGGTCTTCGGTATGCAGTTGGTTAAGCAACTGAACCAAGTCCGCCTTGATCACATCCCAAAAGCATTGATAAAACTCTGCCGGAAAACCATCCGGTCCCGGAGCCTTGTTGTGTTCCATTTGAAACACCGCGGTTCGAATTTCCTCTTCAGAAAACGGAGATGTTAAGAATTCATTTTCCGCTTTCGAAACTTGAGGGATGTCATTTTCCTACCAGCTTTTATACCCTTGTTACATGAATGCTCTAAAAGTTGCTCTGACTTGTTGTATGTATACCTAAAATTCCATTACTACATATATAGACATGTTTATGATTAATTTGCCACCTTCCTTGTTGGCCCGTCATCCGTCAACCAGGTTGCAACCCCAACCTCCCTCCTTTCCCTCCAACTCAATTCACTGTTGCACACCACCCTTGAATTGTTTCCATGTAGTACAACCCACACATAATGGATTAGCAACAATATGCTAAGTCACTACAAAACACACGATTGTTAGTAACAAAAATCCTCATGACGGGAAAGGAACTGTCACCTAAAATCATTTTCCGTGATGGTGGTTGTCACAAACTAATGCCGGCCCGGGCATCTTAGGTGATGGTCCGGTCTGATTTTAGGTGACGCTTTCCAGTGTCACAAGACATATGCATGTTCGGTGAAGATTTTTAGTGTCACCAATATCTTGGATGGGTTAGTGAAGGAAATATATAAATAGAAAAAAATTGGTCTATGAAATTCGAACTCGTGACCTCCCACATTTGTGCATGTAGGACTCAAAGTTTGGTCGCTAGGCTAGTGTTTAATTAGTGATAATACTTTGTAGCTCTATTTTTAGTATGTAGAATGGGACTACATGTACATTTCAATGAAATAAATAAAACAAAAAACACCTTACCTTGAGACTAGTCTAATTAAAAAGAAGACCCCACATGTCATGTCTTATTTTGAAACCTCCAAAGGAAAAATAGGTGTTATTAATGAGGCCTCAACCATGGCCATGGGCCTCATGTGAAGAGAGAGAGGTTTATTACTGGGCTAGTGTTTTATGAGTGGTAACTTTGCAGCTCAATTCTTTTGTAGTATTTCCAATGGCACTACATGTGCATTTCCGTGAAAAATAAAAAAAATCGTGTTCACTTGAAACTATTCTAATTAAAAAGTGGACCCCATCTGTCTTGTTTTATTTGAAAAGTAGGTGCTACATATGGGATTTGAACCCTTGTCATGGGACTCATGTGGAGAGACAAAACACTAGCCATTTTATATATGTTGCCTTGGTGTTGAAATAAATGAAGTTGCCCTACTTGGGTGCATATGTTACTAAGACGTGCAGGGTTTCGGCCTCAAGGCGGCTTCAAAATGAAAAAGTTCTCAGCATGAAAGTTTTTCGCCTCGTCGAAGCGAACAACATAGCTTTTTCATCACCTTAATCTGGTATCACATGCAATCTCCACAGCCGATACAATGTGAAAACTTTTGACCTATGTGAAATTCTGGACACACTTGTCCGAATTTGAAAAACATTTGCTTACACGATATCGATACTTTTGCATGTGCTCATCTCATGGCTTAGGAGATAGGTGAAAAGTCACATGAGAGTTACTAAAACTCTCAATGTACTTTTCTTTGACTGGGTGGATCTACTAGGATGTTTCTTAGACATTCAAGACAAATTATGATGTTTCCAATAACCAATTGTTCTGTTTGTACATGTAACTTTAAAAATGGACTGGACCATGTACTTCATCATTACTACTGATAAATTTAGCTTCATATTGCCATTTGTCAAGTCATACAATGATTTTCCTACTTTTTAAATGTCTAAAAATGAGTACGTTAAGCACAATGTAAAAATGTTTATAAACCATGAACTAAACCATGTATTACAGATACTTTCTAGTTTTGATATTTTTCTAGATCTCAATTTCAATTTTAAGGCTTTAAATGCATTTTCTATGCATTTTTCATCAAAAATAGCAACCACCCAAGTTCTGATAAAAAATGTGAACATTTGCATCGACTGATATTATTCGTTTAGGATATAGGTGAAAAGTTTGGTGATATTTAAAAGTAATCTTGTACTTTGCTTTGTAATGGGTCGATCTACTAGGATAATTCTTAGACATTCAAGTCAAATTATGAGGTTACTAATGAAAAATGATTTTATATGTACATGTAACTTTATTTTATAGTGGACCATGCCATGAAGTTCATCGATAGTATTGAGAAACTTAACTTCATATTGCCACTTGTCATAGTCACAATTTCTTTGTCCTACTTCACAAATACTTAGAAATCGGTACCTTGTGAAGCACCTTGCACGGATATTTATCCAACATGTTCTAGACTTTTTGTACATGAACTAAACAACAAATTAGAGATAATTTGAAATTTATGGTTTTTAGATCCCATTTGCTACATTTTAGAAATGAAATGCACTCTTTGGTTTTTTAGTCAGAAAACAGAAACCAACCAAAAACTGCTCGAAAAGTGGTAAACTTTGCATGGGATCATGTACGGGTTTAGGAGTTAGGCGATAAAGTCTCACAAGATTTGACAAAAGTTTCCTTCTTCTTTGCTTTGTAATGGGTGGATCTGCTAGGATATTCCTTAGACATTGAGGTCAAACTATGATATTTTAATGTCATATCATTTTATATGTACATGCAACTTTAAAAATTGACTAGACCATATAGTTCATCGAGAGTATGAGAAATTTAACTTCATATTGCCACTTGTCATGTCATAATATATCTTTCCTACTTTGCAAATACTTACAAATAGATACATTGTGGAGCACCTTGTATTAATATTTATCCATCATGCTCTACACTTAAAAAAATGGACTGGACCATGAACTTTACCATTAGTCTTTTTCAAGATGCTCCACATCATTAGACTTTACCATTAGTCTTGAAAGACATAACTTCATATTATCACTATCATGTCATAATATGTTTTTTTGTACTTCGTAGATGCCTAAAACCTAGTACCTTGTGGAGCACCTTTCAAAAGTATCCATATGAAACACTCATCTGCCTTCAAGCATCTTCCTATGCCTTCACGCGTCCGCCTCTCTCATCTTCCTCTGCCTTCGTGTATGAGAGCCTGAGCCTCCAGCCTAGCCTTTCCTCCTTCACCTCTTCATGTGTTCGTCCACCGGGAGAAGGATCTCACCCACGGATCTGGCGCTCTTGTTCAAATCCAGCTAGGAGAGGCCTCGGGCCACATGCCGGCGAGGTCCCCTACTTTGTGCGGCAGGGTTGGCATCATCCTCGCCATATCCATCTCCACCATCCCTCCTCTCTCACCGTCACTTCATCACCGGCGTCCTGATCCTCAACAACAGCTTGTAGGATCTGGCACCAGGGCATGGAAGTTTCCATCTCATGAGGCCATGGGCTCCGTGTTCAGCGGTGCGGCAACAGTCGGCGTGACAAAAATGGCCTCTCGGGTGCGTGTGGATCTACATGCGGAGCTTGACAAGTTGACATCCAGTGGTCACACCATGCCTGAGATGCGCCATTCAATGGTCGTCCGGTGCAGGAAACACAATGGGCCGGCGAGGAGTTTTGATTTTGTTGGCTTTGGTATTTGGTATTTTCTCCATGTATAAACCAATGGTCAACTTATTTATTCAATGATTCTTCATATTATACATATATATATATATATATATATATATATGAATGGAATGGTATGTATTAGGCGAATTGCATCATGTCACTAGCCAGGTAAAAGAGCATACTTTTTTGTTTTGTGAATTGTTTACTGATGGCGTGCTGTCAATAAGTGCACATCATAGGCATGTGTGCTCATTTGTGATGGTAAGATTAAAGGCACACCACCAATATTCCTATTAGTAGTGGCGTGGAGGTTGGAGGCACACCACCAATATGTAAAATACTGATGGCAAGTGGGCCACATGCCACCAACAACCACTTATCAGTGGCGTCATATCGGTGGCTAAGGCCGTGGGGCCCCTATGCCACTAAAGTAGTTTTTGGCATGCCATTAGTAGGGTTTTCTATAGTAGTGACAATTTTTCATGCAATAGTCATACAACTCATGGGTTGGTGTGGGGCGTGCTGATGGGTTGTTGTAGCGTTGTGAACCATGGGCTAGGAACAACCCAACAAAAAATAGCGCGCGAAAGAAGAGAGAAAGTTCTGGTTGCATGCTTCATGGGCCGGCCCATTATGCGGTTTTCCTGTGTCTTTTTCTAGCCGGTTATGGGAACGTTTTATATCCTCCCCTAAACCGTTTTTTTTTTCACCTTTTCACTTGTTTCTTCCATTTTATTTTTTATTATTAGCATTTTTATTTTTAAATTCATGAATATTAATGTGTTTTTTCTTTCGGTTTTTTTGATTTCTTTCTTTCCACCAATTTTTCCTATTCAGTTTTTCCATTTTCAAATTCCGAAGAATTTTTGAAATTAGCAAACCTTTTTGAATTCATGAATATTTTCTAAAATTCACAAACATTTTTTAAAATTCTCTTGCTTTTATAAATTTGTGAACATTTTTTCACTCAACGAACATTTTTCATTATTTGGGAACAATTTCAAAATTCATGAAGATTTTTCAAATTTGCAAGCTTTTTCGAAATCCATGTAAATTTTCAAATTCATGAACACTTTTTTGAATTTATGAACAAATTTTGAATTGGAGAACATTTTGTTTGAAATTAATGACCTTTTTGTATTCCTGGATAGTTTTTGAAATTCATGAACAATTTTCAAATCATCATTATTTTTGAAATTAGGAAAAAAAATAGATTCATGATATTCTTTGAATTTTGACCGTTTTAAGACTTCATGGACATTTTATGAAAACCCTAGAGATTTTTTAAATCATGGACTTTTCTCGAAAGTCAGAACATTTTTTAAATCCTCAAAAAATTTGAAATTGAGAACTGTTTGTGAAATTTCAAATATTTTTAAAAATTATTCATGAAAAAATTGAATAAAAAGAAAAAACAAAAAAAGAAAGAACAAAAATGAAATAAGACAAGAGCGGCCAGGCCGCACATGAGCTGGCCTAATGCGCGATGGGTGAGCTGTGGGGTGCGCGATTTGTGGCTATCTGCCGACGCACACGACAAATACAAGCTCCTGTTTGGGCCATCCTTTTTCGAGCTATTTTGGTCCTGGTTTTCCCAAAAGGAAGAGAGGAAAGAAAAGGAAATGAGCGAACGGCCCAAGAGAAAATTCAAAAGAGGGAAGAAAGCGTTCTGGCCATGGTATATGTGGCATGGTTCGTTGAGGTTTAAAAGATGAAACAATAATAAAATAAAAATGGCCTCGAAAAATATGATTAAATTAAACTAAACATGAAGATTCCAATAAAATAGCAGTTAGGGTCAGCAACCAACTTAGGGTGCTTAGGAAATACTTTTAGCTACCATCAAGGATCTGGTTCAAAAACCTTAAATCATGCCACGAGGTGACCTGGTTGTCCAGGACTCTTTTTTCAGTCTACAGCCTGACCATGTCTATGGTGCCCTCTAAGATTAGCAGATGCGGAAATTTTCCTTCCTAATGTGTCTCATCCCCATCATGTATGGAGGCCACCGTCTATCATTATCTCCCCTTATTTCCTTTGAGTCTCCTATCTTGATTCATTCCTATTAGGAGGGGTTCCTATTACCCATGTGTTACCTGTTAAGATGTGGTATGTGGATTGTGTATGTAAAACGGTGGTCACTACATAGCACACATATTCACACAAAATGTCTATCTACACAAATAATGTAATTACCCACACAATTGCCTAGACATCACTATTTATACCAAGAGCACTAGCTACCAGTTTCAATACTATAGATGAAGTTCTATAATTGGTAGCAGGGCTAGGCCCACCTACCCAACAACCTAAGAGATTCTTTTCGAGCCTCGTAATAATTGTAGTTCAATTACGTTCTTGTACAATGTTGCATCTAATTCTCCCTTCTCGTATTTTATTAACAAACCATTTGCTAATTTCAATTCAATGGCTGAAAAACAGGATCAACTCATCATGGAAAGAAAATAACTCTATCGGGCCATGATGTGCACGCTGGTTAATTAAGCCTTCAAACACTTTTGTGCACTCATCAATAGATTCGAAAATAACTAAAGGCATGCCCATGCTTGAAATACTGCTCGCATCGCCGGAGGGGTGGGGGTTGAGGCGGCTCAGGTGAAACCCTAGCTGCCCCCACCATGTCACCTCCTTTCCTCACCTCCATCGTCACCTTCAAATGACGCAAGTGGGCAATGTCCTCTCGGCCGGCGATAATGGCGGTGATGCCTTCATGTGCGGTAATCTCTCGCACAAGGAGCTCTCCAGTCATGCGGTGCGGTGATCTCAGAGGTTGTGACATATTCAATGGAGCTTGGGTGTCGCAGCAACATCCCGGGGTGCCCTAAGTTGTTGTGATGCCACTATGTTGTGTCGGAGGCGGCCGTTGGCGCGGGAGGCCGCGTGTGATGATGGGCCTTTGTGCTTTGATCTGGCAACGGCACCTCGTGGACTAGTCGGTAGTGGCAACAACAAAGCGACAACGGTGGCGGTGACACAAACACATGCATAGGAAGGTCGGGGTGATGCGGCTAAGGCTTGTCGCAACCACAAAGTTGTCGCCATGTCTCTGCACTATTGTCCCCGTCTCCTCAGCACCTGATTTTTGAAGCAAGTGCGCGTAAGAAGGATTCTGGTGATGTTTGGCTCTCTCTGTTTTGTGAGAGTTTTATGCTCGCATGCACAGATTCGATCATGTGGTGATATCTACGCTAAGGATGTGCACACGAGCGGCTACCTTTGAGCGTGAGTTCCATCAAATGGTTGGGATATTGATTTTCGTTACCATGGTGTGTCGATATCTTTCCATGCAGTTTCTTCTTCGGCAAAGGGTTGTCTGCAACACATGGTGTCTTTGGATTGGTGCACTACAAAAAAAAGACACATCCGTGATGATACGCCTTTGTCAGGGTAGATCACATTTTCTGTCACTCATGTATATCCGTGACGGTTTTATGAAAAATCATGATAGCCATACTTGTGCTGTCGAGGATGTGTTACATGACAAAATCACTTTATTATCATGGAACTGTCCACTTCCATGAGATTAAGGGCCTGTACTGAAGTCCTCCCACTCCACGCTTCTCCAACTTCAGATGTGGAGTCGGACAGAACGTTTGAGCTCCGTGGAGTCAGCTTTAGGGCTTGTTTGGGACTGCTCCGCTTCACTAAAATCAGTTTCACTCCATCAAATTCACTTTAGAGCAGTTTCATACAGAAGTTATGCATACCAAAGAGAATGTTTGGCTTCCATGTAGCTCCAGCTTCAAGAATGGAAAATTTGGTGAAAAGGAAATATTTGATTGGATGAGAGGGGAGAAACGAAGGGGTATCCACTTACTGGTGGCAGTGGTGGGTAATTTCCCCCCAACTCCAGCTTCTAGAGTTTTTTGAAGCACCCCCTCAAGAGCTTCATAAAAAACTGGGAGTTGTACCCCAGATTCTAGTTTTTTTGTGAGCGGCATATCGTGGAGCTACCCTGTTTGGCTAATGTTTTCTGAAGCGTAGCTGAATTTTAAGAAGCAGAGCAGTCCCAAACAGGCTCTTAAGAAGCGGTACAAGTCTGTAGTGCAAATTTCTGAAGCTGCTAAAGCCCAGCTTCACAAAACAAAGAAGCGAGGAGCTCCTACTAATTACAAGAGGATGCCACCGCGAAGTATAGAAAACGATTCGCGAAACGGCTCCCAGCCGCTCGTGGTATGCTCGCCTCGCTAGTTTCCTGTGCGAGCGCACGTGGCCAGCCCTCCTCCACACAACGATACAAGGTGGACTGCCTCCATCCGGCCCAAACTGGCACCCAACAGGCTCCCAGCTAGGACAAATCGTGAAGAGAAGCTACAAACACTGTTGAACGAATGGAATCGCCAGGTGAAGTTCGAAGCAAGCTCCAGAAGCTGGTTTTGTGGAGTTTGAGAAGCCCAAAGAGGTTCAGAATAGGCTCTAAATAGCACATCATAATTATATTCGTGAAGGGTTACCAAAATCTGGCAGTGATATGTCTCCAACGTATCTATAATTTTTTACTGTTCCATGATGTTATATTATCATTATTGGATGCTTTACAATTATTTTATAGCAACTTTATGTCATTTTTTGGGACTAACCTATTGACATAGTGCCCAGTGCCAGTTGCTGTTTTTTGCTTGTTTTGTACTTCGCATGAAATCAATATCAAACAGAGTCCAAACACAGCGAAACTTTTTCGAGAATTTTTATGGACCAGAACACCCAGGATGGGCCAGAGAAGTACTAGAGGGGTGCCCTGAGGGGGGCACAACCCACCTGGACGCGCCTGGGGGCCCAGGCGCACCCTGGTGGGTTGTGCCCACCTCGGTGGCCCCCCACACTTCCTCTTCGCCCTATAAATTGTCAAATATTAAAAAACCAAGGGTACCCCCTAGATCGGAAGTTCCGCCGCCGCAAGGCTCTGTAGCCACGAAAAACCAATCTAGACCCCGTTCCAGCACTCCGCCGGAGGGGAAATCATCACCGGTGGCCATCTTCATCATCCCGGCGGCCACCATGATGAGGAGGAAGTAGTCCACCCTCGGGGCTGAGGGTTTGTACCAGTAGCTATGTGTTTAATCTATCTCTCTCTCGTTCGCTCGCTCTCTCTCTCTCTCCCCCTCTCGTGTTCTTGAGATGGCATGATCTTGATGTATCGCGGGCTTTGTTAATATAGTTGGATCATATGGTATTTCTCCCTCTCTATCCTGTTGTGATGAATTGAATTTTCCCTTTGAGATTTTGTTTTATCGGATTGAATACTTTTATGGATTTGAGAGCACTTGATATATGTCTTGCATATGAATACTCGTGGTGACAATGGGGTATTATATTGATTCAATTGAGATATGTTTTGGCACTCAACTCGTGGATTCTCGAGGTGACATTGGGGTAATCTATGCATAGGGGTTGATGCACGTTCTCGTCTTTTGTTTCTCCGGTAGAAATCTTGGGGCACTCTTTGAGGTTCTTTGTGTTGGATTGAGTATTATGAATCTGAATTTGCTTTGGTGTTATTTTAGTACGAACTCTTGATAGATCGATCGGAAAGAATAACTTAATGTCATTTTAGTACGAACTCTTGATAGATCGGTCGGAAAGAATAACTTGGTGTTATTTTAATACGAAGTCTTGGATAGATTGATCGGAAAGAATAGCTACAAACAATTTTTTTCTTATGTTCCCCGCTAGATAAGAACTTTGGAGTGATTCTTCATCACACGTTGAGGGATGGTTATATGATCCAACTAGATTAGCATTGTTGAAAGATTGCACTAGCTAAAGTACGGACCCTAGGCCTCATTTTCAAGCATTGCAATACCGTTTGTGCTCCGTTTTATCAATTGCTACTTTGCTGTTTTTTATTGTTCCTATTATAAAAAACCAATATCTACTATCATTACTACGCTTTTATTACCATCTCTTCGCCTAACTAGTGCACCTATAAAAATTACCATTATATTTGGTGTGTTGGGGACACAAGAGACTCTTTGTTATTTGGTTGCAGAGTTGTTTGAGAGAGACCATCTTCATCCTACGCCTCCCACGGATTGATAAACCTTAGGTCATCCACTTGAGGGGAAATTGCTACTGTCCTACAAAACTTTGCGCTTGGAGGCCCAACACGACTCTACAAGAACAAGTTGTGTAGTAGACATCAGGCAGCAACTGTAATGGGTCATCACTAAGCTATCAGGTGCGGGTTCCAGATCCAATACCAGTTAACAACCCCGACCAATGACAAATTTCCACATGTTGGCTTCTCATTTGTCAACGGAGCCACGCGTCAACTCTTCCTTGTGATAGGTGTCACTCATCCAACGGATGATATGCGCCTATGAAACGAAGACACATGGCATGGCCCAACATTGGCCAGTTATAATGGCCAGCCCAGTAGGAGGCCCACAAGATTTGGGCACAACTTAGCGGGTCAGCCCACTAACAACCCTCTTGCAGATAGCTCAATTACAACTCTAGTCCATACATCCTAGTGACAATTCGGTGCGTCACCGCCCCGTTGGGTCTTCAGCATCATTACGACCCTTTGGTAGTTCTGGCCCATTAACAACCAGCTTTGTCTTTGGCCCAATTATGACCCATTGTGTCTTCCAGCCTATTAAAGGCATGTGGTAGACTCAGACTCATTTGCTGCCCAATGTTTCTTTCGGCCTGTTAGCGGCTCGTGGTGGAATTGAACCGTTTTCTATGTGATGTGTCTTTCGGCCTATTAATGGCCTAGGGTACACTTGGGCCCATTTACAACCCGATGTGTCTTTCGGTCTGTTAATGGACCAAGGTACACTTGGGCCCATTTGTTTTCCGAAGTGACTTTCGGCCTGTTAAATACACATGGTATATTTTGGCTCATTAATAACATGAGTTGGCTTTTGGACTATTAATTGTTTGTGATGTAGTTTGGCCAATTAAGGCCTGATTTCATTATCGGCTTGTTAATTGTCCGTTGTCTTGTTGGTACGATATGCCTTTTGGACTGTTAAAGGCCCGTGGTATCTTCTGGCGCATTTTAACAACCCATGGTGTGTTTGGGCTAAATGTGGCCCGAGGTTTATTCGGCCTGTTCACAGGTACTGGTGCGTTTGGTCCGGCCATACATTTCGGCTTGCTAATAGTTCAAACTGATTATGGGCTCATTTAAATCCCATAGACCGTGTCGGCCCATGAATGGCTCGTGATGATTTTGGCCAAGTTAGATTGACCGATACTATTTTGTAGTTGCGTTAGGACAATTCGAACTGATTATGGGCCCATTTAAAGCTCCCGCTTCAAGTTCATGCGATAGCACATCGACCTTCTGATTGTTAGGTTACCAAAATTGTGGTGCTCGTGCCCTGGTTTGTGTGTTTAGCTCTTTCTGATTTGTCTTCTGATTTGTTTCTATTGGTGGGAGGGATGCAAACTCGATAATGGCAATGGCGGTCATTCACCGGGGTGATAATGTTCTCAGTTTTATGTTTGTTGTCATATTTCTTAGATTTTGAATTTCGTGATGGTGATTACTCAATAGTTTTTTAGTTCGTTAATCATTTACTGATAATTTTTCAGTCCCATTTAGCATATTAGTTTGTAAGATGATTAATAGTTTTTCACATTTTCTTATTTCAGTCTGTGTTCAGTTCATCAATTATCAGTTAAACTAGATTTCAGTTTGTAGTGTTTTACTTTTGATTTTTAGTCTTTGTTTATTTTTGAGTCTTAATTTTTCAGGCTTGTATGTCTATGTCTTAGTCATAGTTCTTTTTTCAGTTAGCAAGCTGATGAATAGTCAGTTAGTTTTCAATTTAGGTCATTAGTCATTACTTATTAGCCATGTTTAGTCATCTATTAGTTAGTTCATCAGTATCTTCAGTTAGTCAAGTGTGTTCAAATTATCAGCTCATTTCATTTAATCTAACCTTCACTCGTTGTATAGGTTATCATTGTATTTATTTTCAGTCTTTCATCTTCTTCGAGTTGATCAGTCCATATTGTCTCCCTTAATAGTTAAGTTATTTAGTCATCTATCAATTACACTGGTAGAAAATGGGCCTTTAGTCCCGGTTCGCAAAGGCCTTTAGTCCCGGCTGTGCAACCGGGACTAAATATGCGCGACTAAAGACCCCCCCCCTTTAGTCGCGCCTCTTACGAACCGCGACTAAAGGCCCGTCCACGTGGGCGCCAGGGGTCCGTCGGGGCGGAGGACCTTTAGTCCCGGTTCTCGTGGCTAACCGGGACTAAAGGCCCGTCCACGTGGGCGCCAGGGGTCCGTCGGGGAGGAGGACCTTTAGTCCCGGTTCTCGTGGCTAACCAGGACTAAAGGCCTCCTCCGCAGGTTTAGGGTTTTAGCCCCCCTAAACCTGGTTTCTTTTTAATTTGTAGTGTTTTATTTCTTTTATATTTTATTTTGTGTTTTATTTTAATTTTGATGAAGTTTCAGTACACATATTCTACGCTACTATATACATGCATATGAAATTTCAAACAAGAAGAATTCAAGAGGAATATATAATATATATTCAATCTCGGGTGACCATATACAACTTCGAACAAGTTTCCATACACAATTAGGATGGATGACCATATACAACTTCGAACAAGTTTAAATCTCGGGTATGCATATAAATTTCTTCGTCCTCGGTATAGTGTTCTCCTTTAGGATTGATGACTTCCCTCATGAAAAATCCTGCTAATTCATCTTGAATTGGTCGGAAGCGAGCTTCTGGACTAAGCCTCCTCCGCAAGTTATCCGTCGCCTTCCGCACGCTATCCGATGCCTTCCGCTCAGAGGTGTGTCTCCGGATGTTCTCACAAACATAGTATCCACATAGATTGGTCCCCGGTGGCTGCTTATCCACACTAACTAACCTTCTAAAATCTAGCTCATGTTTGAATTCACCGACAATTTCTTCTGAGAACTGTCTCCAAACCCTACAGGGCAAAGAAAATTAAATGAACAAGGGAGTTATTAGTTACTTGATATTAGGAAATGAACGAAAGAGACCGATCGATATAGAGCTCAAATGATTGAAAATAATTACTTTTGCAGCAGTTTTCTCATGTCGGCCCAACGCTTTGGATCCGAATCCATAGAGTCCATGATTAGAACTCTGGAGGTGTGAAGTTCAATATTTAGCAGAATCCAGTGGAACCTGCGGACACGTTACATGCACAGTCATGCATAACTCATCGATTAGACATACCATGCATGGAGTAAACACAAGAGAATGGGCACAAGAGAGAAACACTCACCCAAAATGGTAAGGAAATAGAATATGACTTTTGAGTTGATGCTTTCTAAGAAACTTGTACAAGTCTTTCTCCACGTCTTCGGGGTGATTTTGTAACACATGTCCATTAACGATATGTGGGTCAATGAACCCAACATCATGGATGTTTCTTATTTTGCATTCCCAAATCTTCAATCTGCATAATAGCGTACGCAACAATATAGTTAGGACAATATATATATATATATATATATATATATANNNNNNNNNNCAACGCTTTGGATCCGAATCCATAGAGTCCATGATTAGAACTCTGGAGGTGTGAAGTTCAATATTTAGCAGAATCCAGTGGAACCTGCGGACACGTTACATGCACAGTCATGCATAACTCATCGATTAGACATACCATGCATGGAGTAAACAAAAGAGAATGGGCACAAGAGAGAAACACTCACCCAAAATGGTAAGGAAATAGAATATGACTTTTGAGTTGATGCTTTCTAAGAAACTTGTACAAGTCTTTCTCCACGTCTTCGGGGTGATTTTGTAAGACATGTCCATTAACGATATGTGGGTCAATGAACCCAACATCATGGATGTTTCTTATTTTGCATTCCCAAATCTTCAATCTGCATAATAGCGTACGCAACAATATAGTTAGGACAATATATATATATATATATATATATATATATATATATATATATATATATATATTTATTTATTTATTTATTTATAGTGCAGGCAATGAAGAACGAGATGAGGTAGAAATAAATCACTTACAGAACGTAGCAACTCAGCATAGATTTGTCGAGGTCGCGCAGATTGAACAGCTGGAACAATTCACTCATATGAACTTGTACAGAGTACCGTTTGGTGTGATGCTCCTCTGTAACATCCGCATAAACATATTCTTTGTCGGCCCATGTTATGAATTGCTTGTACCAACGTAGCAGATTTCGCATTTGTGGTGGTAGACTCTTTTCCCGCGCAGGCTCGACGAGAGGCCCATTCCGCACATATTGTAATGCTATCTCACATACTGGCGCATCCTCAAGGCCTAAGAAGGCACGAAGAGTCAAACCCATCTCGGACGCTTGTTTCATGGCACTCGCTACAGTCAATCCAAGTGCTGCCGCAGCTGCTATGATCTCGGGGTCCTCTTNNNNNNNNNNCACTCACCCAAAATGGTAAGGAAATAGAATATGACTTTTGAGTTGATGCTTTCTAAGAAACTTGTACAAGTCTTTCTCCACGTCTTCGGGGTGATTTTGTAACACATGTCCATTAACGATATGTGGGTCAATGAACCCAACATCATGGATGTTTCTTATTTTGCATTCCCAAATCTTCAATCTGCATAATAGCGTACGCAACAATATAGTTAGGACAATATATATATATATATATATATATATATATATATATATATATATATATATAGTGCAGGCAATGAAGAACGAGATGAGGTAGAAATAAATCACTTACAGAACGTAGCAACTCAGCATAGATTTGTCGAGCTCGCGCAGATTGAACAGCTGGAACAATTCACTCATATGAACTTGTACAGAGTACCGTTTGGTGTGATGCTCCTCTGTAACATCCGCATAAACATATTCTTTGCCGGCCCATGTTATGAATTGCTTGTACCAACGTAGCAGATTTCGCATTTGTGGTGGTAGACTCTTTTCCCGCGCAGGCTCGACGAGAGGCCCATTCCGCACATATTGTAATGCTATCTCACATACTAGCGCATCCTCAACGCCTAAGAAGGCACGAAGAGTCAAACCCATCTCGGACGCTTGTTTCATGGCACTCGCTACAGTCAATCCAAGTGCTGCCGCAGCTGCTATGATCTCGGGGTCCTCTTCCGGACCGGCTTTCACTATGAGCGGGGGGATCGATTGTTTATTCTGCATCCCGAGCTGGTCAACTTGTTTCCCGCTTTTTTTACTTTCTTCTTTCTCCTCCTTCAATATTTTTGCTTGCCTACGAAGTTCATGTCCATAGTCGTCAGGCATATTCAGCTCGGCTTGGGACGGTGTCGTCAAAAAATCCTTAGCCCACTTCTTTTGCTTCTCAGTGAATACTTGCTTGGGCTCAGGCTCTTTTATCGCCTTCATATCCGCCTTCCATTTCTCATAATGAGCAGACGCGGCCAATTTGGTTTCAGCTTCACTAAGTTCCCAAGGCCTTGGGAGGAGAGGCTTCAGTGATGGCTCCGGTACCCTTGTGGTCTTAGGTACATAAGGGTCCGGGTTAATAGTCCAGGAGCGGGTTTCCTTGCTATCCGCCTGCTTCTGCTTCTTCGCCGGAGGTGGATTGGGGGGCGTCGTACCCGCCGGAGGAGGATTGGCGGGCGTCGTACCCGCCGGAGGTTGTGGATCGGGGGACGGCGTCGAATGGCGTGAAGGAGGTGTAGGTGAACCACCACGACCACCACCACCGCCACCACCACCACCACCACCATCGGAGGGGGGTGGACTTGTTAGCCTTGGCGCCTCGCCTGGAAACACTATGTACTTCTTTTTCCATAGAATGATCTGGCGCTTGACATCTCCAAGTCTTCTCTCTCCTTCGGGTGTAGCTTTGTCAATCTCCAGGTCCTCAAACCCTTGGACTATGTATTCCACCGTGACACGAGCATAGCCATATGCAATGGGGTTGTTGTGGTGGAGTGCTCCAGGTGTACAGGGTAAAGCACTGCCGCTAGCTACCTTCGTGGAAACGTTCCCCACGGGATAATGCAGATCACATTCTTTCATCTCCTTTACATCATCCACGGGGTAGTGAGGCTCCGGTGCACGAATCTCGATCATCAGTGCACTAGCACCAGGCGGGGCATCCGTGGAAGCCACGCTGCTTCTCCGCTACTGGCTTCCGCGATCCGCTTCATGATCTTCATGCGGCCCTGCAGCCGATTTTTCTTTTACTAGTTCATGCACGGTCGGCTTCAACTCATGGAGTTCCGATGCAAACTTCGCCATAAGATCTGCATCCCGGTCCGTCTTTCTCTTACGGCTTCTGTAACAGTACGGGTCATTGTCCTGGGAAAACCCTACTTTCCACGGAACTTTGCCTTTGCCTCGTACACGTCCTCCGTGTTCATCATTCCCGAGGGCTGTTGTCAGTGCGTCTTTCTCTCTGTTGAACTTGATCAAGCCCTCTTGAGCTTGGATCATTGCGTCAATAAGGGCTTGGGTGGGAGCAAACTTTTTCTTCCGGTGAACACACAACCCTGTCTCCGGGTCTAGTGATCCCCCATGCCCGTACCACCAGCTTTTGGCCCTTGGGTCCCATCCCTCTGTACCTAGAGGGATTCCTCGCACCCTCAGGTCCTCCTCCATCTTCTGCCACTTAGACTCCGAAAGGCGGTATCCTCCTGGCCCCATAATATGATGGAACTTTTTCTTACTCGCATTATCCTTATTTTTTTCGATATTTCCTTGAAATGCTCCGATTGCTTTTGCCTCACAAATTCTGGCCAATCATCTTTCAGTTTCTCATGTAGTCCATTGAAATCCGGAGTCTTGCCCTTGTTGACATAGTCACGGGTTAAATTTTTCTTGAAGTTCCGGAATGCTTCGCCCATCTTCTGAAAAGCGAACTCTTTAACTAGCCTCCTCCTCTCACGTCCACCCGGAACCTCGTTACCAAATTCATCGACTTTGTTGTATTCCGGAGGTAGAATGAAATGTTCCATAGCTTTCTCCAGCAATCCTTTTTCGTTCTCTTGTCGACAAAACTGAAACCAAGACGTGCCTTCTTTGGCTCCTTCCATTCCTGGACGGTGATCGGGACGTTGTCTCTAACAACGACTCCGCATTGGTTGATAAACTTTGAGGTGTGCTGTAGGGGCTTGCCGGTTTCACTGACAAACTCAATGGCATATGTTTCTCCTGTTTTCATCGCCTTGGATTTGCCACGCTTTGTCGTACTCGATCCGGCCGAGGGCTAAAAAAAGAAAGAGAGTCGCGCGCATTAATACATATGTATTCACATTTCAGTAAGTTTGTATCACGAGAGGCTCAATGTATATATATACCTCGCCGGAGGTGGTTGCTACTTGCAATTCGAGATCGTCGTTTGTTGACGGTTGACCTCCGTCGACAATGTCCGTTCCTCCACCTTCTTGATCATCGACAATGTCTGTTCCACCGTCAAGGTTCAGAAAAGAAGAGACTACATCCTCTTCTTGCTCATATTCTGAGCCCGGCACATAAGGAATCTCGTTGTTTATGATGCCCATTAAATAACGTTCAGCCTCCGGATCCCTAAGCGGCTCGGCTCTATCGTCCGCCATATGTCACTCCTGCATGTAGTAAAAATTAATTAAGTATAAAGGAATTAAAAAATAAGATTAAGGAGACATAGAGGAGGAGGAATTAAAAAATAAGATTACTGAGCACTGCCAAGTATTTTGTTTTTCCTTTTCTTTTTCCTTTTCTTATTTTCTTTTTCCTTTTCTTATNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNTTCTTCTTCCTTTTCTTCTACCTTTTCTTCTTCCTTTTCTTTTTCCTTTTCTTCTTCCTTTTCTTCTTCCTTTTCTTCTTCCTTTTCTTTTTCCTTTTCTTATTTTGTTTTTCTTGGTTTTCATTGGTTTTCTTTGTTTCTTTCTCGATTTTCTTGATTTCATTCCTTTGCATTGGTTTCTTTTGTTTTGTTTTCTTTGTTTTTCTTTTTGGTTTTCATTGGGTTTCTTTGTTATTCCTTATCTTTTGTCGATTTTATCGGTTTCTTTTTGCTTCAACACGTGTTAACTTTTTCAACCTTTTTCTTATACATCAGAAAGATTTTCATATATACATTTAACATTTTTAAACACATGATTAAGTTTTTTTTGAAAACTTATTTTTTTGGATGTATGGGTTTTTTTCATACACACTGTACATTTTTGGCATATATCTAATACATTTTCCTAATACATGTTTAACATTTTCCTAATACATGTTTAACATCTTCCAAACACATTTTAATATTTTTTGAACACATGGTCAACATTTTTCCTTCGTTTGTGGAGGCGGCGGCGGGAGGCGGAGGACGGCAGGCGGCGACGGGAGGCNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNATCAAAAAATTCAGAAAAATAAAACTAATTCATTTTAAAACCTTAAAAATACAAATAATATATCAAAAAATTCAGTTCATCGATCCCTTGAAGGTTTGACAAAAGGTTTGATACATCATTCAGTTCATCGACCAAATACAAATCATCCGGATTCGCCATCGTACGTTTTAATTCACATGATCCATTCAACAAAGTTTGGTACAATACATTATTACACATCAATTCCTCCCTTGTGTCCCTGCTTGCTTACGATTGTGCCGTATCCATGGAGCATCCTCATCATTTAACTTAATGCTTGGGTCAGTGTTCACTTTGAAGGACAGAATTTCACCAAACATATTATAATCTTCTGACATGTCTGTCTTGTCCTCCACTCCCACGATGTTTCTTTTCCCTGAAAGAACAATGTGGCGCTTTGGATCATCGCATGATGTACTGATCGTTTTCTTATCTTTCTGTTTCCTCGGTTTGCTACTCATGTCCTTCAAATAAAAAACCTGAGCGACATCTTTGGCAAGGACGAAGGGTTCGTCAAGGTAACCAAGATTGTTGAAATCCACCATTGTCATTCCGTATTGCTCGTCCATCTTTACCCCACCTCCTGTTAGCTTGAACCATTTGCACCGGAACAAAGGGACCTTAAAGGAGGGTCCATAGTCAAGTTCCCATATCTCCTCTATGTAACCATAATATGTGACCTTTTGCCCATTCTCGGTTGCTGCATCAAAGCGGACACCACTGTTTTGGTTGGTGCTCTTTTTATCTTGGGCGATGGTGTAAAATGTATTCCCATTTATCTCGTACCCTTGGAAAATCGTTATAGTCGAAGATGGTTTCTTGGCCAACATGTACAGCTGATCTCTAACATCATTGTCATTCATTAAATGTTTTCGCAATCAACTGCCGAAAGTCTCCATGTGGGCCTTTCTAATCCAGGATTCAGGCTTCCCCGGGTTGTTCGAGTGTAAAATATTCTTGTGTTGCTCGAAGAACGGAGCCACCAAGCTGGAATTTTGCAGAACTGTGTGGTGTGCTTCAGTCATAGAATGACCGTCCATACATATCGTTGATTTCCTTCCGATCGTGCCTTTTCCACTTAGTCTCCCCTCGTGCCGCGATTGAGGAATACCAATCGGCTTAAGGTCAGGAACATAGTCAATACAGAACTCAATTACCTCCTCATTTCCATAGCCCTTGACGATGCTTCCTTCTGGCCTAGCACGGTTACGAACATATTTCTTTAATATTCCCATGAACCTCTCAAAGGGGAACATATTGTGTAGAAATACAGGACCGAGAATGGAAATCTCTTCGACTAGGTGGAGCAGGAGGTGCGTCATAATATCGAAGAAGGATGGTGGGAACACCAACTCGAAACTGACAAGGCATTGGACCACATCGTTCTGTAACCGTGGTAGATCTTCTGGATTGATTACCTTCTGAGAGATTGCATTGAGGAATGCACATAGCTTCACAATGGCTACTCGAACATTTTCCGGTAGGAGCCCCCTCAAAGCAATCGGAAGCAATTGCGTCATAATCACGTGGTAGTCGTGAGACTTCAGGTTTTGGAACTTTTTCTCCGCCATGTTTATTATTCCCTTTATATTCGACGAGAAGCCATACGGGACCTTCATACTGCTCAGGCATTCAAAAAAAATGACCTTCTCTTCTTTGGTAAGAGCGTAGCTGGCACGACCTTGAAACCATTCCGGATGCCGGCCATCTGGGTCTTTCAAAAGTTGCTGGTCCTGCCGTGCTTCCTTTGTATCATTTGTCTTCCCATACACGCCCAAGAAGCTTAGCAGGTTCACGGAAATATTCTTCGTAACATGCATCACGTCGATTGCAGAGCGGACATCTAGGACTTTCCAATATTCTAGCTCCCAAAATATAGATTTCTTCTTCCACATGGGTGCGTGCCCGTCAACTCCCCGCGGAACTGATTGTCCGCCAGGACCCTTTCCAAAGATGACTTTCAAATCCTTGACCATATCAAATATCTCAGCACCAGTACGTTCCGCAGGCTTTGGCCGGTGATCTGCCTTGCCGTTGAAATGCTTGCCTTTCTTTCTTACGTTATGATTTCGGGGAAGAAATCGACGATGACCCAGGTACACGTTCTTCTTACAATTAACCAAACGTACACTTTCAGTCTCATGTAAGCAGTGTGTGCATGCATTGTATCCCTTATTTGTCTGTCCCGAAAGGTTACTGAGAGCAGGCCAATCGTTGATGGTTACAAAAAGCAACGCTCGTAGGTCAAATTCCTCTCCTTTGTGCTCATCCCAGACACGTACACCAGGTCTGGCCCACAACTGTAAAATTTCATCAACTAATGGCCTTAGGTACACATCGATGTCGTTCCCGGGTTGCTTTGGACCTTGGATGAGCACTGGCATCATAATGAACTTCCGCTTCATGCACAACCAAGGAGGAAGGTTGTAGATGCATAGAGTCACGGGCCAGGTGCTATGGCTGGAGCTCTGCTCGCCAAAAGGATTCATGCCATCAGTACTTAGACCAAATCTTATGTTCCTTGCGTCAGCTGCAAAATCTTTGAACACTCTGTCGATCTTTCTCCATTGCATTCCATCAGCGGTGTGTCTCAACTCCCCGTCGGACTTACGGTCCTCTTTATGCCATCGCAACGACTTGGCATGCTTTTTGTTCCTGAACAGACGTTTCAACCGTGGTATTATAGGAGCATACCACATCACCTTGGCGGGAACCCTCTTCCTGGGTTTCTCGCCCTCAACATCGTCACCAGGGTCATCGCCTCTGATCTTATAACGCAATGCAGTGCATACAGGGCATTCATTCAAATTCTCGTATTCACCGCGGTAGAGGATGCAGTCGTTAATGCATGCATGTATCTTCAGAACCTCTAAACCTAGAGGGCAGACAACCTTCTTTGCTTCGTACGTACTGGAGGGCAACTCGTTATTCTTCGGAAACATGTTCTTCAACATTTTCAGCAAATTTTCAAATGATGAGTCACCTACACCTTCCTGTGCCTTCCATTTTAGCAAATCCAGTGTGCAGCCCAGCTTTTTCAGACTATTATCGCATCCTGGATACAACGACTTTTTGTGATCCTCTAACATGCGATCCAAATTCTCCCTATCCTTGTCAGTTTCGCAGCGTCTCCGTGCATCAGCAATGGTCCGACCAAGATCATCAGCGGGCTCATCATGTGCCTCTTCTTCACCTTCACCTAACCCTTCCCCACCTTCAGCATCATCCTCCATGAAAGTATCACCGAAATGATCATGATAGTTGTCATCGATATCATCCCCTTCTTCATCTTCTTCCATTCTAACCCCTCTTTCTCCATGCTTGGTCCAACAATTATAGCTTCGCATGAAACCGTGCCGAAGCAGGTGCATGTGAACGTCTCTTGAGGAGGAGTAACCCTTCTGATTCTTACAAACAGCACATGGACAGATAATAAAACCTTGCTGCTTGTTCGCATTTGCCACTACGAGGAAATCTTTCAAACCCGTAGTGAACTCGCCGGAGAGTCGGGGACCGTACATCCATTGCCGATTCATCTGCATTATTATTATATAAAGTATATAATTGACCATCATGCATTTGTTAAACTAACTAGCTAGAAATAATACAAATTAAACAATGAACTACACACATGCATATTTTATCAATGACACATGAAAGGTTCAAGTTGCTAACCGCGATCGCGAAGGAAAAATAAATGAGAAAGCTCAAGTGTGGCTCGGACACTTCGTATCATGTTTGTTTCAGGCTCTCAGGCATTTCATCGAACACCTTGTGTGCATAGGAGGAACCAAAAGCAAACCCGCCACCCCCTTCTGAATATTGTGAAGTGAGCTGAGTGAAGTGAAGTGAGCTGAGTCCTATATATAGGGATGGGCCTTTAGTCCCGGTGGCCTGGCCAACCGCGACTAAAGGCCTTCGGGGACCTTTAGTCCCGGTTGGCCAGGCCAACCGGGACTAAAGCCCCTCCCGTCCGCCAGCTGTCGACCGAGCGCGCTGGGCCCAGATAGTTGGTCGCGGGTCTCCTCCCGAACCGCAACTAAAGACCCCTTTGTCGCGGTTCGATTATTTTGGGGACTAATGGGGGCGTATGGAAGCCTCTTTTTCTACTAGTGTTAGTTCATCAATATCACTAGTAAGTTCAATGTGTTCTGTTCATTAATTAGTTCAATTTCTTTAGTATTCATTTGTTTATTCACTTCTTTAGTTTATATTACATCATTAATTCTTATAATTATCAGTGTTTTTTTTTGTTCTTTTCACATTCTCGTTTGGTGCACTATCTCACTACGACGAACAATGAACTACCATAGGTGGTATGTAGGGGTTTTCACGATTTCTTAGATATGTACTCTTCACAAATCATTATTTCATTATGCAGGCATGTCTATATATGTATCTTCACTCTTCACTCATTCTATATTTTGTCATTCATTCATCACTATTCACTTATCAGGACATTTGTTTCATCCTTTAAGTATTTTGTTAAGTCCATTCTCTATTCCTTAGTCATTTGTTCCATTTAACTTGATAACACAACATTTTATCATCGATTGGAACACTTTTTGTTCATGTGTAGTTCTGACCAGCTAATCAGTGATGGTCACTGCCTAGAACTAAGAATTAGAGTTATATGTACCTATGTTCTGATTCCAAATGTTTGAGTTATCATTAATACATTTTCATAGGTTTTTTTTATTTCCTATCATTCAAAGATCAGGACACTTTCAATCCATATTTTTTGGTGGAGTGTTGATGAATGGTGTGTGTCATACCTGGCCAAATGGCTCGGCACGGCCCGGCCTGCGGTAAACGTGCACGACACGACCCGCGACGGCACGACTAATAGCCGGGCCGTGCCGGGCCGGCCCACGGGCGGGAGCTCGCACCCTAGGCACGGCCCAGCTACTAATTGGGCCGGCCCACCTGAAGGAAATATGCCCTAGAGGCAATAATAAAGTTACTATTTATTTCCTTATTTCATGATAAATGTTTATTATTCATGCTAGAATTGTATTAACTGGAAACATGATACATGTGTGAATACATAGACAAACAGAGTGTCACTAGTATGCCTCTACTTGACTAGCTCGTTGATCAAAGATGGTTATGTTTCCTAGCCATAGACATGAGTTGTCATTTGATCAACGGGATCACATCATTAGGAGAATGATGTGATTGACTTGACCCATTCCGTTAGCTTAGCACACGATCATTTAGTATTCTGCTATTGCTTTCTTCATCACTTATACATGTTCCTATGACTATGAGATTATGCAACTCCCGTTTACCGGAGGAACACTTTGTGTGCTACCAAACGTCACAACGTAACTGGGTGATTATAATGGTGCTCTACAGGTGTCTCCGAAGGTACTTGTTGGGTTGGCGTGTTTCGAGATTAGGATTTGTCACTCCGATTGTCGGAGAGGTATCTCTGGGCCCACTCAGTAATGCACATCATTATAAGCCTTGCAAGCATTGTAACTAATGAGTTAGTTGCGGGATAATGTATTACGGAACGAGTAAAGAGACTTGCCGGTAACGAGATTGAACTAGGTATTGAGATACCGACGATCGTATCTCGGGCAAGTAACATACCGATGACAAAGGGAACAACGTATGTTGTTATGCAGTTTGACAGATAAAGATCTTCGTAGAATATGTGGGAGCCAATATGAGCATCCAGGTTCAGCTATTGGTTATTGACCGGAGACGTGTCTCGGTCATGTCTACATTGTTCTCGAACCCGTAGGGTCCGCACGCTTAAAGTTCGATGACGGTTATATTATGAGTTTATGTGTTTTGATGTAACGAAGGTAGTTCGGAGTCCCGGATGAGATCGGGGCATGACGAGGAGTCTTGAAATGGTCGAGACGTAAAGATCGATATATTGGACGACTGTATTCGGACATCGGAAAGGTTCCGAGTGATTCGGGTATTTTTCGGAGTACTGGAGAGTTACGGGAATTCGCCGGGGAGTATATGGGCCTTATTGGGCTTTAGGGGAAATAGAGAGGAGAGGCTGGGCGCCCCCCCAAGGCCTAGTCCGAATTGGACTAGGGGAGGGGCTGCGCCCCCTCCTTCCTTCTCTTCTCTCTCCCCTTTCCTTGACTCCTACTCCTACTACTTGGAAGGGGGGGAATCCTACTCCCGGTGGGAGTAGGACTCCTCCTAGGGCGCGCCATAGAGAGGGCCGGCCCTCCCCCTCCTCCACTCCTTTATATACGGGGAGGAGGGCACCCCTTGGAGATACAATAATTGATCGTTTGATCTTTTAGCCGTGTGCGGTGCCCCCCTCCACCATAGTCCACCTCGATAATACTGTAGCGGTGCTTAGGCGAAGCCCTGCGTCGGTAGAACATCATCATCGTCACCACGCCGTCGTGCTGACGAAACTCTCCCTCAACACTCGGCTGGATCGGAGTTCGAGGGACGTCATCGGGCTGAACGTGTGCTGAACTCGGAGGTGCCATGCGTTCGGTACTTGATCGGTCGGATCGTGAAGACGTACGACTACATCAACCGCATTGTGCTAACGCTTCCGCTTCCGGTCTACGAGGGTACGTGGACAACACTCTCCCCTCTCGTTGCTATGCATCACCATGATCTTGCGTGTGCGTAGGAATTTTTTTGAAATTACTATGTTCCCCAACAGTGGTATCAGAGCCAGGTTTTATGCATAGATGTCATATGCACGAGTAGAACACAAGTGAGTTGTGGGCGATATAAGTCATACTGCTTACCAGCATGTCATACTTTGGTTCGGCGGTATTGTTGGATGAAGTGGCCTGGACCGACATTACGCGTACGCTTACGCGAGACTGGTTCTACCGACGTGCTTTGCACACAGGTGGCTGGCGGGTGTCAATTTCTCCAACTTTAGTTGAACCAAGTGTGGCTACGCCCGGTCCTTGCGAAGGTTAAAACAACACCAACTTGACAAACTATCGTTGTGGTTTTGATGCGTAGGTAAGAACGGTTCTTGCTAAGCCCAGTAGCAGCCACGTAAAACTTGCAACAACAAAGTAGAGAACGTCTAACTTGTTTTTGCAGGGCATGTTGTGACGTGATATGGTCAAGACATGATGCTAAATTTTATTGTATGAGATGATCATGTTTTGTAACCGAGTTATCGGCAACTGGCAGGATCCATATGGTTGTCGCTTTATTGTATGCAATGCAATTGCCCTGTAATGCTTTACTTTATCACTAAGCGGTAGCGATAGTCATAGAAGCATAAGAGTGGTGAGACGACAACGATGCTACGATGGAGATCAAGGTGTCGCGCCGGTGACAATGGTGATCATGACGGTGCTTCGGAGATGGAGATCACAAGCACAAGATGATGATGGCCATATCATATCACTTATATTGATTGCATATGATGTTTATCTTTTATGCATCTTATCTTGCTTTGATTGACGGTAGCATTATAAGATGATCTCTCACTAAATTTCAAGATAAAAGTGTTCTCCCTGAGTATGCACTGTTGCCAAAGTTCGTCGTGCCCAGACACCACGTGATGATCGGGTGTGATAAGCTCTACGTCCATCTACTACGGGTGCAAGCCAGTTTTGCACACGCAGAATACTCAGGTTAAACTTGATGAGCCTAGCATATGCAGATATGGCCTCGGAACACTGAGACCGAAAGGTCGAGCGTGAATCATATAGTAGATATGATCAACATAGTGATGTTCACCATTGAAAGCTACTCCATTTCACGTGATGATCGGTTAAGGTTTAGTTGATTTGGATCACGTGATCACTTAGAGGATTAGAGGGATGTCTATCTAAGTGGGAGTTCTTAAGTAATATAATTAATTGAACTTAAATTTATCATGAACTTAGTCCTGGTAGTATTAGCATATCTATGTTGTAGATCAATAGCTCGCGTTGTTGCTTCCCTATGTTTATTTTGATATGTTCCTAGAGAAAAACTATGTTGAAAGATGTTAGTAGCAATGATGCGGATTGTATCCGTGATCTGAGGATTATCCTCATTGCTGCACAGAAGAATTATGTCCTTGATGCACCGCTAGGTGACAGACCTATTGCACGAGAAAATGCAGACGTTATGAACGTTCGGCTAGCTCAATATGATGACTACTTGATAGTTTAGTGCACCATGCTTAATGGCTTAGAATAGGGACTTCAAAGACGTTTTGAACGTCATGGACCATATGAGATGTTCCAGGAGTTGAAGTTAATATTTCAAGAAAATACCCGAGTTGAGAGATATGAATTCTCCAACAAGTTCTATAGCTAAAAGATGGAGGAGAATAGCTCAAGCAGTGAGCATATGCTCAGATTGTCTGGGTACTACAATCGCTTGAATCAAGTGGAAGTTAATCTTCCAGATAAAATAGTGATTGACAGAATTCTCTAGTCACGATCACCAAGTTAGTAGAACTTCGTGATGAACTATAATATGCAAGGGATGACGAAAGTAATTCCCGAGCTCTTCGCGATGTTGAGATCGACGAAGGTAGAAATCAATAAAAGAGCATCAAGTGTTGATGATTAACAAGATCACTAGTTTCAAGAAAAGGGCAAAGGGAAAGAAGGGCAACTTCAAGAAGAACGGCAAGCAAGTTGCTGCTCAAGTGAAGAAGCCCAAGTTTTGACCTAAGCCTGATACTGAGTGCTTCTACTACAAAAAGAACTGGTCACTGGAACAAAAGTATATTTGATATACATGTTATTGATGTGTACTTTACTAGTGTTTATAGCAACCCCTCGGTACTTGATACTGGTTCAGTTGCTAAAGAGTAGTAACTCGAAACGGGAGTTGCATAATGAACAGAAACTAGTTAAGGATGAAGTGACGATGTGTATTGGAAGTGGTTCCAAGATTGATATGATCATCATCGCACACTCCCTATACTTTCGGGATTAGTGCTGAACCTAAATAAGTGTTATTTGGTGTTTTGCGTTGAGCATGAATATGATTTGATCATGTTTATTGCAATACGGTTATTCATTTAAGTTAGAGAATAATTGTTGTTCTGTTTACATGAATAAAACCTTATATGGTTACACACCCAATGAAAATGGTTCGTTGGATCTCGGTCGTAAGTGATACACATATTCATAATATTGAAGCCAAAAGATGCAAAGTTAATAATGATAGTGCAACTTATTTGTGGCACTGCCGTTTAGGTCATATTGGTGTAAAGCGCATGAAGAAACTCCATGCTGATGGGCTTTTGGAATCACTTGATGCTTGCGAACCATGCCTCTTGGGCAAGATGACTAAAACACTGTTCTCCGGAACAATAAAGCGAGCAACAGATTTGTTGGAAATCATACATACTAATGTATGTGGTTCGATGAATATTGAGGCTCGTGACAGGTATCGTTATTTTCTGACCTTCACAGATGATTTGAGCAGATATGGGTATATCTTCTTGATGGAACATAAAGTCTGAAACATTTGAAAAGTTCATATAATTTCAGAGTGAAGTGGAAAATCATCGTAACAAGAAAATAAAGTTTCTATGATCTGATCGTGGAGGAGAATATTAGAGTTACGAGTTTGGTCTTCATTTCAAACAATGCAGAATAGTTTTGCAACTCACGCCACCTGGAACACCACAGCGTAATGGTGTGTCCGGACGTCATAACCATACTTTATTAGATATGGTGCGATCTATGATGTTTCTTACCGATTTACCACTATAGTTTTGGGGTTATGCATTAGAGACAGCTGCATTCACGTTAAATGGGGCACCATCGAAATCCGTTGAGACGACACCTTATGAACTGTGGTTTGGCAAGAAACCCAAGTTGTCGTTTCTTAAAGTTTGGGGTTGCGATGCTTATGTGAAAAAGTTTCATCCTGATAAGCTCAAACCCAAATCGGAGAAATGTGTCTTCATAGGATACCCAAAGGAGACAGTTGGGTACACCTTCTATCACAGATCCGAAGGCAAGATATTTGTTGCTAAGAATGGATCCTTTCTAGAGAAGGAGTTTCTCTCGAAAGAAGTGAGTGGGAGGAAAGTAGAACTTGATGAGGGAACTGTACCTGCTCCCTTATTGGAAAGTAGTTCATCACAGAAATCTGTTCTTGTGACTCATACACCAATTAGTGAGGAAGCTAATGATGATGATCATGTAACTACAGATCAAGTTACTACCCAACCTCGTAGGTCAACCAGAGTGAGATCAACACCAGAGTGGTATGGTAATCTTATTCTGGAGGTCATGTTACTTGACCATGACGAACCTACGAACTATGAGGAAGCGATGATGAGCCCAGATTCCGTGAAATGGTTTGAGGCCATGAAATCTGAGATGGGATCCATGTATGAGAACAAATTATGGACTTTGATTGACTTGCCCAATGATCGGCGAGCCATTGAGATTAAATGGATCTTCAAGAGGAAGACGAACGCTGATAGTAGTGTTACTATCTACAAAGCTAGAATTGTCGCAAAAGGTTTTCGACAAGTTCAAGGTGTTGACTACGATGAGAGTTTCTCACTCGTATCTATGCTTAAGTCTGTCCGAATCATGTTAGCAATTGCCGCATTTTATGAAATCTGGCAAATGGATAAACAAAACTGCATTCCTTAATGGATTTATTAAAGAAGAGTTGTATATGATGCAACCAGAAGGTTTTGTCGATCCAAAAGGAGCTAACAAAGTGTGCAAGCTCCAGCGATCCATTTATGGACTGGTGCAAGCATCTCGGAGTTGGAATATACGCTTTGATGAGTTGATCAAAGCATATAGTTTTATACAGACTTGCGGTGAAGCCTGTATTTACAGGAAAGTGAGTGGGAGTACTACAACATTTCTGATAAGTATATGTGAATGACATATTGTTGATCGGAAATAATGTAGAATTATTCTGCAAAGCATAAAGGAGTGTTTGAAAGGAGTTTTTCAAAGAAAGACCTCGGTGAAGCTGCTTACATATTGAGCATCAAGATCTATAGAGATAGATCAAAATGCTTGATAAGTTTTTTCAATGAGTACATACCTTGACAAGATTTTGAAGTAGTTCAAAATGGAACAGTCAAAGAAAGAGTTCTTGCCTGTGTTACAAGGTGTGAAATTGAGTAAGACTCAAAGCCCGACCACGGCAGAAGATAGAAAGAGAATGAAAGTCATTCCCTATGCCTCAGCCATAGGTTCTATAAAGTATGCCATGCTATGTACCAGATCCATTGTATACCCTACACTGATTTTGGCAAGGGAGTACAATAGTGATCTAGGAGTAGATCACTGGACAGCGGTCAAAATTATCCTTAGTGGAATAAAGATATGTTTCTCGATTATGGAGGTGACAAAAGGTTCGTCGTAAAGGGTTACGTCGATACAAGTTTTGGCACTGATCCAAATGACTCTATGTCTTGATCTGGATACATATTGAAAGTGGGAGCAATTAGCTAAAATAGCTTCGTGCAGAGCATTGTAGACATAGAAATTTGCAAAATACATACGGATCTGAATATGGCAGACCCGTTGACTAAACTTCTCTCACAAGCAAAACATGATCACACCTTAGTACTCTTTGGGTGTTAATCACATAGCGATGTGAACTAGATTATTGACTCTAGTAAACCCTTTGGGTGTTGGTCACATGACGATGTGAACTATGGGTGTTAATCACATGGTGATGTGAACTATTGATGTTAAATCACATGGCGATGTGATCTAGATTATTGACTCTAGTGCAAGTGGGAGACTGAAGGAAATATGCCCTAGAGGCAATAATAAAGTTACTATTTATTTCCTTATTTCATGATAAATGTTTATTATTCATGCTAGAATTGTATTAACCGGAAACATGATACATGTGTGAATACATAGACAAACAGAGTGTCACTAGTATGCCTCTACTTGACTAGCTCGTTGATCAAAGATGGTTATGTTTCCTAGCCATAGACATGAGTTGTCATTTGATCAACGGGATCACATCATTAGGAGAATGATGTGATTGACTTGACCCATTCCGTTAGCTTAGCACACGATCATTTAGTATTCTGCTATTGCTTTCTTCATCACTTATACATGTTCCTATGACTATGAGATTATGCAACTCCCGTTTACCGGAGGAACACTTTGTGTGCTACCAAACGTCACAACGTAACTGGGTGATTATAATGGTGCTCTACAGGTGTCTCCGAAGGTACTTGTTGGGTTGGCGTGTTTCGAGATTAGGATTTGTCACTCCGATTGTCGGAGAGGTATCTCTGGGCCCACTCAGTAATGCACATCATTATAAGCCTTGCAAGCATTGTAACTAATGAGTTAGTTGTGGGATGATGTATTATGGAACGAGTAAAGAGACTTGCCGGTAACGAGATTGAACTAGGTATTGAGATACCGACGATCGAATCTCGGGCAAGTAACATACCGATGACAAAGGGAACAACGTATGTTGTTATGCGGTTTGACCGATAAAGATCTTCGTAGAATATGTGGGAGCCAATATGAGCATCCAGGTTCCGCTATTGGTTATTGACCGGAGACGTGTCTCGGTCATGTCTACATTGTTCTCGAACCCGTAGGGTCCGCACGCTTAAAGTTCGATGACGGTTATATTATGAGTTTATGTGTTTTGATGTACCTAATGTAGTTCGGAGTCCCGGATGAGATCGAGGACATGACGAGGAGTCTCGAAATGGTCGAGACGTAAAGATCGATATATTGGACGACTATATTCGGACATCGGAAAGGTTCCGAGTGATTCGGGTATTTTTCGAAGTACCAGGGAGTTACGGGAATTCGTCGGGGAGTATATGGGCCTTATTGGGCTTTAGGGGAAAGAGAGAGGAGAGGCTGGGCGCCCCCCAAGGCCTAGTCCGAATTGGACTAGGGGGAGGGGCTGCGCCCCCTCCTTCCTTCTCTTCTATCTCCCCTTTCCTTGACTCCTACTCCTACTACTTGGAAGGGGGGAATCCTACTCCCGGTGGGAGTAGGACTCCTCCTAGGGCGCGCCATAGAGAGGGCCGGCCCTCCCCCTCCTCCACTCCTTTATATATGGGGAGGGGGGGCACCCCTTGGAGATACAGCAATTGATCGTTTGATCTTTTAGCCATGTGCGGTGCCCCCCTCCACCATAGTCCACCTCGATAATACTGTAGCGGTGCTTAGGCGAAGCCCTGCGTCGGTAGAACATCATCATCGTCACCACGCCGTCGTGCTGACGAAACTCTCCCTCGACACTCGGCTGGATCGGAGTTCGAGGGACGTCATCGGGCTGAACGTGTGCTGAACTCTGAGGTGCCGTGCGTTCAGTACTTGATCGGTCGAATCGTGAAGACGTACGACTACATCAACCGCGTTGTGCTAACGCTTCCGCTTCCGGTCTACGAGGGTACGTGGACAACACTCTCCCCTCTCGTTGCTATGCATCACCATGATCTTGCGTGTGCGTAGGAATTTTTTTGAAATTACTACGTTCCCCAACACCACCGACACGCCGGGCCCGCTATTTCGTCTGCTATTTGACGCATTGGGCGTTTTTAGCCTGTTTTACCTATTGGGCCATATAGAGATGTATAGAAAAAAAAACCGTAATCGATCCGTGCCGTGCCAGCCCGTGTGCTCAGGCTACCAGCCCAAGCACGGTCCAGGGCGTGCCGCATGCCGGGCCCGTTCCGTGCCTGGCACATGGCGGGTCGTGCCGGCATGCTCAGGGACCGGCCTGGTTAATTAGCCCGGCCCATTTGGGCAACTATAGTGTGTGTGTGATCACTGCATTTATATGTTTGGCCAAATAGTTGTCTATTTTTCGTAGAAGAGTTTCTGAATACACTTTATGTGTGTGTAATTTGTTTTTTTTAAAACGTGTGTGTAATTTGTTGGCATCTAGAAAGTACTAGAGGAAGTTGCTACGACCGTGTTGGCAGAAGCTGCAGCCAGCCATGGTGGAGCTAACCGGCTTCGACTCGTGTCACGACTGGCGGTGGCAAAAGCTACAACTGGCGTCGTCTCGTGCTATGACTTTTGGCGGCGGAAGCTACAACCGGCCACATTGACCGACATAGGTTTTTTGCTGGAACTAACGGTGGCAAAGCTGCAACCAGCGACGTCACTTGCTGGAACTGGCAACATTGAGTGTTGGCACTGGGTACGGCCATTTGCTAGAACCAGCCACATAGATTGTTGGGACCGAAAGGACGAAGCAAGCGGAGCAGATCCGACGGTTCACATTAGTCGCATCCTACGGCGCGGATTGCGACCGATCGAGGCTGGCGCCGATCGACCGGCGCCTGGCAATGGCCTAAACCAAAACGCACGTGCTTCTCGCAGTGGGGAGGTGGGGAAATGGCGTCGGTGAACAGTTGACCACTCGATCTATCCTCCTCACTTTTCCTATTTCCACTCCACCACGCGGTTCGGGCGCGCTCCAACTCCCAGCTCCATAAACTCCAGATCCATAGGAGTCGGCGCGCTGCAGCTCGTCCGCCGGCGGCAGCCCTCCCCACCGCCGCGGCCTGCCTTGCCCCGCCTTGAGTCGCCTTTCACCGCCGGGCTCCCCCCTTGTCTGCCTCCGGGCCCCTCCTTTTCTGCCGCCGTCGTCGACCATCTCCGCCGCCGTCCCCGACCACCGGACTCCCTCCTTGTCTGCCGCCGTCTTCCCCGACCACCGGACCACGCAGGCTGTGCGCCTCCTCTGCCTCCCCGACCACCTCGCATATCAACTGAATCACAGTAGGTGAGTGAAAAAAATTGCATTTTTCTTTGATTGGTACTAGTATTTTGCTGCGATGTGCTACGGTGGTGTGCTGCTGCTAGACTTGTGGATGGTCTGTAGGACTGATGATGTGCTAGGATGCTCATTTGGGGTTTGGGCGCTGGGGATTTGGGGTTTCGAGTATCAGATCTCTGGGCGATCTGGTCCGGCACTGGTGGTTGGTGGCGAATGCCGCCGGTTTTCGGTTAAGATCTCGCGAGCTTGGTGAACCCTTCGGATTTTTAGATTCACATCTGTGTGAAAGGTGCAAAATTTGCGGACCGAGATCTGATCCTGCTTACTCAAATCTCCTGGATCAGTGCAAATGTGTGGGCATTGTGTGTTCCGTTGGGAACCACATGATTACTTGATTTATTGGGACCAGGGGTTTAGTTTGTTCTTACTTGCAGTTGAGTTGTGCGTCAAAGCTTGGTCTCGTCATGCCTGAGGAAAACACTTAGCATTACGATTTGGTACATGGATATGTGTAAGATCAATCTCAATCCGTATACAATACAGGTCTCTATGGGCATGTTCATCTAGATTAGCATCTTTACTTCATAAACGGCGCAAAAATTCTGAGTATCTTGGAATGCTTTCTTTCCTTTTCTGGGAATGTGAAGGTTGTGACTGTGTAAACTGTGGGTCCTACAAATTGCAGTTTGCATTTAAAGAATAGTTGATGATAGTGTAGGATTCTAAATCTTTTTCTCACATTGCATAATGGTAAATGTAATATGCATGCCTTGATTCATCTAAGATCTAACTGAGCGGTGTTGGTTTTTCCATCTCCATTGAGCAGGTCGCTTGAGTTAATGTGCACCATATAGTGCTTTGTCTCTGTTAAATTGCTTATGAGATCAGTAAACTGCTATGGATATATGAAGCACAGCTGAAGAAGCCCATAGTGTTTCATACCAGTGAATGATCAATATTTTGTCTGTTTCAGATCTTAGTACCACTAGAGATGCAAGGAAGAATGACAGATTTATGGTAAACCCTGGTAAATATTCGTGGGAGGTCAACAAGTGGCGCCCTGATTAAGACTGCTACAACACTTTGTGGTTCATCTCTAATTAGTGATGGCGAGAATGAAGATCCCAAAGCGTTATGTCATAGTATTGCTGACATTCATCTGCACAAATGTTTGTTACGTTGAGCGTGTGGGTTTCTCGATTGCGTACACCGTAGCAGCTGATGCAATCAACGTGAATCAAGCAAACAAGGGCCTGATACTCTCCATGTTCTATTATGGTTATGTTTTGTCGCAAATTCCTGGTGGATGGGCAGCTCAGAGATTGGGAGGCAGACGTGTTCTGCTACTGTCATTCCTGTTGTGGTCTTTGATATGCGGTCTAATTCCACTGGACCCCAACAGAGCAGTCATTCTGGTCCTTTCTCGCCTTTTTGTCGGTGTAGCACAAGGTTTCATATTTCCTGCCATTCACACAGTCCTGGCACAATGGGTGCCACCGCAGGAGCGCTCTCGCTCAGTGTCATTAACAACCTCAGGGATGTACCTCGGGGCAGCTTGTGGCATGTTGTTTTTTCCAAGTCTGGTGAAGCACATGGGACCCCAATCTGTATGTTTAGTCGAAGCAGTACTTGGAGTAGCATGGTCTGTAATATGGTTGAAGTTCTCCAGTGAGCCACCTCGCACTGACCTTCCAAAAGTGGCAATGCCAAAAGTAGCATCTCGGGAGAAGATTAAGGCGCAATCAGTAGGGGTTGTTGCACCTCGCACTGTAAAGATACCATGGCGAAAGATTATCTTCAGTCTACCTGTTTGGGCAATTGTCGTGAACAACTTCACCTTCCACTATGCCTTGTATGTTATCATGAACTGGCTGCCTACCTATTTCGAACTAGCCCTTAAGCTTAGCCTCCAGGATATGGGATCGTCAAAGATGCTTCCCTATTTCAACATGTTTATATTCTCCAACATTGGTGGAGTGGTTGCTGATCACTTGATTACAAAAAGGATCTTATCAGTTACCAAGACAAGGAAGCTCCTTAACACCATTGGGTTTGTTGTCTCGGCTGTTGCACTCATGGCCCTCCCTTCATTCGGGACGCCCTCAGGGACTGTGATCTGTTCATCGGTGTCTCTTGGCTTTCTGGCTCTAGGAAGAGCAGGGTTTGCCGTGAATCACATGGATGTTGCTCCAAAGTTCGCCGGCATAGTGATGGGGGTTTCCAATACAGCTGGGACATTGGCTGGGATAGTTGGCGTTGGCCTCACGGGAAATATTCTGGAGGCTGCAAAGGCTTCTAACATGGATCTAACGAACTCCGAAACCTGGAAAACAGTCTTCTTTGTTCCAGCATACCTCTGTATTTTTAGTTCAGTCATTTTCTTGGTCTTCTCAACTGGTGAGAAGATTTTTGAATAGAGGATGATTATTTTTGCCTGTTCTTTTCTTGTCATTTACGGGCGGCGAGGCAGGATAGAAACACGGGAATCTCACATGTATTTTATTCATTATACCTGTCAGATTTCAGAGCTCAGACTGCATCCCACACATATTAAGACTTATGTTATGTTAGGAGGAATAACACTTGTCCGTAGTAAATTGTGTTATTTGGAATGATCCTATGACTCTGTTATTCCAGCTGGCTGGTTGGCCTATTTACAATACGTTGTGTAAGCTGGGCATACATCATCTTTGTTTTGTAAGTCATTTTCCTGGGGATAGGAAACAATGTGAATTGTGCAGCAAGAAGTCAGGATGACATGACAACATTTTGTTTGCTGGCAGGATCTGAAAAGAAAATGTGATTGGTCTACATTTGATCTAAATGAAATTTCTATTTAAAGGTAAATCTGACTGGAACATGGACGCTCCCTTTGGCTGTGTAGAGGCGCATTTTTATGTTTGATAAACCTGCTGGAAGATGTTTATTTCACTGTAAGTGAGCAGTAGAACCTGAAAAACCTGTGCCCACACATCCCTAGCAAGCTCCATTCCTTTACATTCACATGTTAGTTCAACTATATTGGGTAAAGTTGAGGGCCTCTTTGATTCATAAGGTTTCAAAAACACATTGATGTGCATAATTGGGTGTTTAATTCACAAGAATAGGACAAGTACAGGAAGCCTAAAATATTATGGTCAAATTAAGATTTAACCATATGCAAAGGTAAGATGAAGATATTATTATATGCTACTTAAGGCCTTTGCCTTGTTCTTCATGCATATGAATGTGAAAGAGAAATTTCAATGCTTTGAATCAAATGGATAAAATAGTAGGAAAAATCTTATTGATATGGTTTTCTTATGAATCACAGACACCATCAATGTAAAGTCTTGAGAAAACTACGCTTTGCAACCAGTAGTCATTACATATACCGCTGTCCATTGTGTCCTCTCGTGGAAAGTAGTAATCTAAACGCTTTTATATTAGTTTACGGAGGGAGTATTATTTTTGAACAAGAGCAGCAGGGCGGGATGGTGATCCTACCAGCTTACAATACAAGATACATTAACAAACAAACAAAAGGAATATAAAAAACAGAAATCTTGTCCACGCGTCGGCAAAGCAGAGACAATAGATTCATGGCCCTGTTTTCCCCAGTCATCTCGCACAGTTCAAGGTTAGAGTATATGCTTGTGGACTTTTATATAGAATATGAGAATGGGGAACTATCATTGAAAATCTTTTGTCAAGCCATCAAACGGGTGACAAGTGAAGTGTTTGGCTATTTTTGTGATTGTAAATGTTTATAGGGAAAAATATTTTTTGCCAGGTTTTTCATCTAAATATTCGATTATGAGCACTACTTTTTTTTCCGTTGCAGCTCAAATTTTTTTCCTATGAAAATTTTCATATCTATTTTTCTGTATCTTTCGATAACAGAAATTAATTTTCTATGGGAGTATGTCGCTCGGAGACATTTGGCAGTCTTCCTATTCTGAATTTCTTCCAGTAGCGTAGAGTTCAGACACGACTTGCTCTCTTATACTTTTCAAACTTCTGGCACTAACCTAGTTGCTGATGGCATTACCACTTGAGATATTTCCACCCCCAAAAGTACTGCTGCGAGCGCTGCCTTCAAGTTTCGGTTAGTCCAAAGCGTTTCAAGATGCCTCCCATTCCTAATGAACTACAGACGCACTTCCACTAACTTCTTCTATTTGCCATTCCTCTCACCCTCTCTCGAGGCTCTCAACTCAATTCTTGTTAACTAGGAGCTACTTGCTTCATAAGAAGAGCTAATATATGAGGTGGGAGGAAGACTACGGTCAAAAAATGGGTATGCAAGTATTGAGCAGGAGAAGGCAATGCATCCTTATATAAAGGCACGTGCCATAGGCCGAGAGTGTTCACCTCTTTTCTGAAAAAAGTATAGGAAGACACATGTACAAGAAAATAAAGTTGATACCTATGTGTGTTGCTTCAACTTTATAATGCGACCACAAGCACCTTACATAGTAGTATTGCTAGAATCCTAAAAAAAAATAGTATAGCTAGAAAAATACTCACTTCATTTCTTTATGTAAGGTGTATTATTTTTGGCACGGTGATCATGGCATAAAATTAGACAATTTCAGACAAAACTACCCTTGACAAATCATTGGTTAGTGGCAAGTAAATCAATTAGTCCAGGAAATAAAGAGGTATACACAATCAAGAGACAGATATTTTCCTTCTTTTCCTAGAAGGAGATATACATGCAATCATAAGAGAGATACTTTCCTATTTTCTGGAGGGCTAAGAACGGAATAAGGAGGAATTAGAACAAATGCACCTTAATTGTGAAATTTTATCAAAAAACAAATACAACTTTTTTTGATCGGTAACAAATACACCTTATATTAAGAAACAGAAGGAGTATATAACAATAGTAAAAGAAACAGGCCCAGCCCATTAAGAGAGGCAAGTCACGAACGAACGTGATCTCCTTTCTTTCGTTCTCTCCGATAACGCCGCTGCAATCTCATTCGTCTCCCAGTCTCTCCATATTTCTCTCCCCCAATTGATTGCCCCGAATTCCTAAGAGACTCCAACTCCCCAAGCTAATCAATTAATTTGTGTCACTGTCCCCATGGATTTCTTGGGTGTCTTTCATCATATAACTAACCCCAAAGCCATTAGTGGGCCGGAGAAGAGAAGCCGACGAGGACGCCAACCCGCGGCGTGGCCGTCCATCGTCAAGGCTCTGCCAGGGTCCGAGCCTCCGAGGGTAGTAGGCGGTGGAGTATTATGCTATATGACGAATTGATGCAATGATATTTGACCGGCTTGATCTTTTCTTTTACGTCAGTACAATGAGGTAGGTTCTGCTGTTTATGACATTGCTTGCATTTGGATTATTGGATAGCTGGAGCATGGGATTTCTTCCAATGTACTCCAAAATGAGTAAATTAACTGTTGGCCTAACTTATTACAAGTACCAGAGGAGTCTCGGGCAGAATAAAAGCTTTCATTACATTGGCCCAACTTGTTACAAGTACAAATGTTTACATTTGTTTTGTTGATTCTCATCTACCTCATGTGTTTTGCTCAAAGAAGTTTTTTTAACCCATGTGTCATATAATTTTACACGGAAACTCACGGATATTTTTATTGTTGTATCTCTTTTTTCCTTTCGATAAACTTTCAAATTCCAAAAAAAATCAAAATTTAAAAAACGTTTCATTTGAAAATATTTTCTCAAATTAAAAAATGCTTGTGGTTTTCAAAAATATAAAATTTGAAAATATATTCACAAACTAAAAAAATCGCTTTTAAAAATATGTTCAAAATTTAGAAACAATTTGAATTTAAAAAATGCTCATGTTCTCCTAATATTTTGCATTTTCAAAAAATATTATTTTTTTTCTAATTTTTTATCGCTTTTGTAAAATGTTCGCAAATTGTAAAAAAACTTTCACGTTTTCAAAGTAATGTCGTCCAATTTGAAAAGATTGTTCGTGTTTGCCAAAAAAGTGTAAAATTTGAAACACAATTCACGTTTACAAAAATGTTCATTTGAAAAATTCTCTCGTTTTCAAAATTTTACATTTTTGCAAAATGTGCAGAAATTTTAAATAATTGTTTCCGTTTTTGCAAAAAAAATATTCTAAAAAATTTCAATTTATATGCTGCAGTAGTCTCGTTGGTTACAGAATCCAGTTTCCTACAGGTCGGGTTGCTATAGTATCGGGTTGCTATAAGAAACTGGTGCGCTATATAAAACCCGACCCGCTACAATGTGTCTAAAGAAAATACCAAGAAGCCCCTTGAAGAAATTGGGGTCGCTACATGTTTTTTTTTTTTTGAGAATTGGGGTCACTACACGTGAGCGCGCCTCCGTGCGAGTGGGCTGGCCCAGGCGGGGCAGAGGGCACCTGTTTTGCACTGGCATTCATGTTTTTTTTTTTTGCTTGTGATTGTGCTCAAAAGGAACTGTGCTAATTTCATGGTATTTCACAACAAATCGAGTTACAATTTGCGTTTTCCCATCCTGTTTGATTTGATCTCACAAGGTCTTATGGCCTTAACCTTCACATATGTCCAGCATGTGCTGGTGAACTGGTGATAGGAAGCAACCGAGGCCTCCATTGCAACGGCAAGTGGAGGGACGTATTTCCGGATGCTTCCCATTTCCAACGCATCTGACCCCTCCTGTTATCATGTCATTCCCGTTTATCACTTTCTTCTTTCCATGTCTTAATCTCATTTGTGTCGATTTGGCGGCTTCAAATTGAGAAGCAGAGCTTGCTAAGATGGGTAGTAGGCTAAAGGAAAAGGAGTGCCCATCAATTGGATATATACTCAGCTGGGTTTGGAAGTATGAAGAGGAGCCATATACTTTATATATATGTGTAAATGGTGTGGGCCCGTGTAAAGATCGTCATAGTTTCTAGTTAAATATCTCCTGTGTACTACAACTCATCAATGATCTCTTGCTCTAGTAAAGTAGAGGATAGGTATCTCAGTGGCATTAGTGATATCTCAACTCATCAATTGTTTCTTGTTTCCATCTCCATGAACGTAGCAAGAAACCAGTTTCAAAAAAAGAAGTACCAATAAACCTACAGACACTTGCAGAGTTCTTTTTCTCACTACTCTGCTATTGAGGAGTAAATAGCAAAAAGCTACCACATTATAGGCTAGGGTTACAAAAAACTACCTCTTTTCTTAATTTCCCAAAATGCTAGCACAAATTTGGTTCGCTGTTCCAAAAAACACTAGTGAGTAAAGCGTTAACTTTTAACTGCGGTTATGACAACTTTGGCCCACCCGTCAGGTCTGATGTGGCATAAAACTCAACACCGTTAGCTTTGGCCGTTATGACAGGTGGAACCCACATGTCATTCACTTCCAAAAAAATAAAAAGCAATCGGGACCCTATACCTTTCTAGAAAAGCAATCGGATCACTGTAAATGTCTAAAAAAGCAATCAAGTCCCTGTAACTTTCTAGAAAAAAGCAATCGGGTCCTGTGAAAAAAATTAATCGGGTCCTGTGAAAAAATTAATCGGGTCCTGCTTGGCTGCCGGCGAGCTCATCCCTGCTTCGGCTGCCGCGGCCTAGGGTCGCCGCGCGCGCTGATCCTGGCTGCGCACCTTCCACTCGCCAGTGAGGAGAGCCAGAGAAGTGATGGGATGGCGAGGGAGCTCCAGCTCTCCCTTCATTGGCCTCCGCCGCCACTCCCGTGTATGTCCCTTCCCGCGCGCTTGACCGGGAGAGTCCCTCTTCTCCGGCACTGGTGACGCCAGCCCGGCCCGCTCACCCTCGCTTCCACGCTCCCCCCTTCCGATACCGACGCAGCAGTGAGTAGCAGCATGCAACGGCAGCGGCATGCAGCATCGGAGAATTGCGGCGGCGGCGGTGGAGAGCAGCAGCAACAACAACACACAGCAGCAGCGGTAGCTTCTGCCCATGGCGTTGGGGCTACGGGAGAGAGACAGAGCAAGGCGCATAGGGTGGGTGTCGTGATATAGAGAAGAGAAGAGAAGGGAGAGAAGAAGCTGACATGTGGGCCCCACCCGATCATAACCGTCAACTTAACTGTTTGTTTATATAACGGTGCTGACTTTTTTGCCACGTGGAACTGACGAGCGGGCCCTCCATGTCATAAACCAGATTAAACCATTCAGTCACTAGTGTTTTTGGAACAACAAACCAAATTTGTGGTAGCATTTTGGGAAGTTAAGAAAAATGTTAGTTTTTCGTAACCCTATCCCATAATGTGGTAGTTTTCTGCTATCTACTCTTTGTTTAAAAGGGGAAGTTAAGAAGTTGGCATCCATGTAATATATTTTTTGAAAAGGGAAATATATTAATATCACGAAGATGCCAATTTCTCTGTTTAAAATTTGCTCTAAAAGCCAAATCAAAATACACACATATTGTTTGAATGGATTATAATTTCCTCGTGGGCGCTGGAGCTCCACTCAGATCTACCCACACTCAGTCATACGAAGCCAAGGTCGGAATGCTGCGCCGTTGTAGGATCACAGCAATCACACATGCTAAGGTTGATCCTGTGTGTTGGTCCGGCTCTAGTTGATCCTCTGTGTCGCCATCCAAACTCGGGAAGGTCAAGTGCCCACTGCCACCATCACAACTCACATCATTGAGCGCCTACACTCGTCCAAGTACAAACATCATTGAGCGCCCAGTCAGACGAAGCCAAGGTCGGAATACTGCTCCATTTATAGGATCTGTCAGACCAGAGCCCTCCATCTCCTTCGCCATGGTCGCTCACTCGATCACAGTTGTAGCGCACGCTAAGGTTGACCCTACATGTTGCTCCAGCTCCAGTTGACCCCCTGTGTTGCCATCCAAACCCGGGACAGTGATGCACCCTCTGCTACCAGCATAAGCGACCGATCACCATTCACCCATCCCCACAATGCCGACGTCCCCTCCCACTAAACCCTCTCATGGCAACCCCAACACAAGCACCAAGAAGAATTAGTTCTCAGAGTTCGGTGAAGATGGCGAGCAGTATAGGGGAATAGGGCATAGCGCTAAATCACTCTTTGCATTGTTTGTCGTAGGTGTGAATTATAGCATGACTGATTGTCTTTCTTCCTGTTCATGTAGCTGGTCATTGGTACTTATCTTTACCATGAGTGGTAGTCTGTTATCTTGTTCTACAATTTGGCGTTTGCCAACTTGGTATACTGATCGTTGTAGCATTGCACTCTGCTTATCTTTAGTGAAATACGTGCACTGTGTGTTCTCGAAATCAGCATTGTACTCTGCTTCTCCTGGATTAAATATGTGTTCTTGGAAGAAACACCGGACTACTTTAAGTATTGCAATATATTTTATCAACAAGGTAAATAGGTTGCATGAAAAAAATTCAGTCAGTAGCCAAATTTAGTAAATCAAATATCGAGGAGGTAATTTTCTTTCAATTGGTTTTGGATGAAGATCTATTTCAGATTAAGTACTACTCATCTTATTAACTTGTAGTTCATGATTTTTTAATTGTATTCATAGATGTTGAATATTTTTTTTCAATAATACAGGAGATAACGTGAGTCTTCATTAAAAGCTGCATGATTAGTAACTCCCAGTATAGGAACATCTTCCCAATTTGGGCACTCGCAGAGTACCGGCACCGAGTCTTGGCTGGTGGCAGCTAGTACTTATGTGTTTAGGGGCAATGAATTTGTGCAGTCTGTAGGAATCTGCAGATCATTTATTTATTTATGTATGTTCATTGTTGATGAATATATAACCCAATATGTAAAACATATAATTTTGTGAGGGGTTCCGATCTCTTTAAAACATAAATCAATGCAATTCTAGATGGACAGATAGTAGAGTTCATCAGTTTATGTCATTGATAAGAGCGACTTTTTCAGAGAGCTGTAGTAATTTTCTGTAGATATATTTCCACCAAAGGGCAAATTAGGTTAATGCCGAAAATCAAATCAATTCTTTGGATGGAAATTTCAGTATATCGAAATGTGGGCTTGCAGCAATGGTACCGTCCTATGCACAATCCAGATCAAAGCAGCGCATTGTCCCCTTTGCTGAGCTCGCGGCCACCCCTAGTTGTGCCCAACCTGCACCCGCGAGATGAAAGCCGAGTTCCCTCTAGTCTTTAACCTTCACATCCTAGTCATTGCATATTCTGCATGTGGTGGAGAAAGGCAGCAATCGACGCCTCCGTTGCAACAGCAAGTGGAGGGACGTTTTTCCGGATGCCTCACATTTCCAGCACATTGCACACCCATCTAACCCCTCCTATTGTCATGTCATTCCCATTTATCACTTTCTTCTTTCCATGTCTAAGTCTCATTTGTGTCGGTTTGGCGGCCTCAAATTGAGAAGCAGAGCTAGCTAAGATGGGTAGTAGGCTAAAGGAAAAGGAGTTCCCATATACTTTATATATATGTGTAAATGGTGTGGGCCCGAGTAAAGATCGTCATAGTTTCTAGTAAAAAAGAAAATATCTCCTGTGAACTACAACTGATCAATGATCTCAGTGGCAGCAGTGATATCTCAACTCATCAATTGTTTCTTGTTTCCATCTCCATGAACGTAGCAATAGACCTCAAACGAAAAAAAAA
->URS0000F1BCF3 rRNA from 1 species 
-TACGTAGGGGGCTAGCGTTGTCCGGATTCATTGGGCGTAAAGGGTGCGTAGGCGGCGCGGTAAGTCGGGTGTGAAATCTTGGAGCTTAACTCCGAAACTGCATTCGATACTGCGGTGCTTTGAGGACTGGAGAAGGAGACTGGAATTCATGGTGTAGCAGTGAAATGCGTAGAGATCATGAGGAAGACCAGTGGCGAAGGCGGGTCTCTGGACAGTTC
->URS0000D17570 sRNA from 1 species 
-TCCCAGCCGGGTTCGTGTCGCCATGGGGCAGATCGAGTGGGCCATGTGGGCCAACGAGCAGGCGCTGGCGTCCGGCCTGATCCTCATCACCGGGGGCATCGTGGCCACAGCTGGGCGCTTCACCCAGTGGTACTTTGGTGCCTACTCCATTGTGGCGGGCGTGTTTGTGTGCCTGCTGGAGTACCCCCGGGGGAAGAGGAAGAAGGGCTCCACCATGGAGCGCTGGGGACAGAAGTACATGACCGCCGTGGTGAAGCTGTTCGGGCCCTTTACCAGGAATTACTACGTTCGGGCCGTCCTGCATCTCCTGTGAGTCCCCGCCCTGCACCCCCTCTAGGGCTCAGGAGGGCTTGGAGCCGACCCTCCCCACTGTCCCACCGGCCGGGCTGCCTGGACAGGAGCCACCCCCACTTACCTCAGTGTTTTTCCAAACAAAAATTCGGGTCCCTGGCTCTGGCAGGGCCTGTGTCTGCTGTCTAGTGTGCAGGATTTGTAAGGATCCACTCCAAATCCGAGTAGCTCCGATCCGTCGCCACGGTCTGGGGTCAGCAGGCACTGCTGGGGGGTCTTGCCTGGGCTTCCTGGTAGGGTGGAGGGTTCCGTGCTGTGTGTCTGGTGGTTACTGCCGGCTGAGGCCAGGAGACCCACACGTGGCTGGTTCCTCCGAGCAAGTGCCCCAGAGCCACTAGTGTCCACATCAAGGCCGAGAACACCCAGGACCGAAACAAGCCCTGGTCCGCGCACGTCCCCTGGGTGTTCCTTGTGCTGAGACTTTGCAGCCCTGGGCCATGCACGTCCCCTTGGTCTGCAGTCTGCCTTGTCCTGAGACTTTGTGGCCTTGGCCCCCAGACCTGGGGCTCCGTTCCCCTTTCTGAGTGCCCTTCTGTGTCCCTGCCTCTCACCCGCTGTCCCCCAGGCTCTCGGTGCCCGCCGGCTTCCTGCTGGCCACCATCCTTGGGACCGCCTGCCTGGCCATTGCGAGCGGCATCTACCTGCTGGCAGCTGTGCGTGGCGAGCAGTGGACGCCCATCGAGCCCAAGCCCCGGGAGCGGCCGC
->URS00003EB83F lncRNA from 1 species 
-CAGATTTAGGGCAAAGTTAACACTTCAAAAATATCTCCAGTAATTGAGTAAATTGCTCATCTGTCAAATTGGCTCTTTGGCAAATTACTCTGCTTGCACATATTAATAGCCAAGCTTAGCCAACTTGAAATATGGAGATTTACTGGAAATCACAGTGAAGTGAAGAGAGAGGCAAGAGCAGAATTGAAATTCCCACCTGGCAGCAAAAGAGAGTTATGCAGAGCCTATCAGGACCCGTGTTCACACCAGCACTTAGTTTGGAGGAAGCACCTGGAGGAGATGCAGAGTCCAGATGTGCGCCCTCTGCCGGAAGCCTACTGCACCAGGACGTAGGCCTGGAGTGGCCCTTAACGCATTTGGAAATCAGTCTTCACTAAAAAAACTTCCTCCAAAATGTTCTTTAACAGCCCTTTAAAAGCCATTGTTTCAAAACAGTCCAAGGTGGTGAACAATTAATATTTTCGATTTACATGAAGACTCTGGAGTAGGAATTACCTGAGTTGGAAACTCAGTTCTACTCTATTGGTATCAGGTTGCATTCTGTATCATCATTAAAATTTTCAGAAAAACTCTC
->URS000039DFEA rRNA from 1 species 
-GAATCTAGCTTCAGGTCTGGGACAACCACTGGAAACGGTGGCTAATACCGGATGTGCCGAAAGGTGAAAGATTAATCGCCTGAAGATGAGCTCGCGTCTGATTAGCTAGTAGGTGGGGTAAGAGCCTACCTAGGCGACGATCAGTAACTGGTCTGAGAGGATGACCAGTCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTCCGCAATGGGCGAAAGCCTGACGGAGCAATACCGCGTGAGGGAGGAAGGCTCTTGGGTCGTAAACCTCTTTTCTCAGGGAAGAACACAATGACGGTACCTGAGGAATCAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATGCAAGCGTTATCCGGAATGATTGGGCGTAAAGCGTCCGCAGGTGGCTGTGTGTGTCTGCTGTTAAAGAGCAAAGCTCAACTTTGTAAAAGCAGTGGAAACTACACAGCTAGAGTGCGTTCGGGGCAGAGGGAATTCCTGGTGTAGCGGTGAAATGCGTAGATATCAGGAAGAACACCGGTGGCGAAAGCGCTCTGCTAGGCCGCAACT
->URS00007386F9 rRNA from 1 species 
-GCGGCAAACGGGTGAGTAATATCTGGGAATCTACCCAAAAGAGGGGGATAACTACTAGAAATGGTAGCTAATACCGCATAATGTTGAAAAACTAAAATGGGGGACCTTTTTAGGCCTCATGCTTTTGGATGAGCCCAGACGAGATTAGCTTGTTGGTAAGGTAAAAGCTTACCAAGGCTACGATCTCTAGCTGGTCTGAGAGGATAGCCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCTATGCCGCGTGTATGAAGAAGGCCTTAGGGTTGTAAAGTACTTTCAGCGGGGAAGAAAAAAATAAAAATAATACTTTTAT
->URS00008F63D8 tRNA from 5 species 
-GTGCCCATAGCTCAGTTTGGTTAGAGCATCCGACTCATAATCGGCAGGTCCTCGGTTCAAGTCCGAGTGGGCGCACCA
->URS00007B46A8 snRNA from 1 species 
-CCCACCCTGGAAACGGCTCAGC
->URS0000B49266 rRNA from 1 species 
-AGAGTTTGATCATGGCTCAGATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGTAGCACAGAGAGCTTGCTCTCGGGTGACGAGCGGCGGACGGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACTGGAAACGGTAGCTAATACCGCATAATGTCGCAAGACCAAAGTGGGGGACCTTCGGGCCTCATGCCATCAGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAACGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGCGGGGAGGAAGGCGNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNNCGATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTCTGTCAAGTCGGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATTCGAAACTGGCAGGCTAGAGTCTTGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACAAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGATTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAATCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCACAGAACTTNTTGGTGCCTTCGGGAACTGTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTTCGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGACCAGGGCTACACACGTGCTACAATGGCATATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCATAAAGTATGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTAGATCAGAATGCTACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTTACCACTTTGTGATTCATGACTGGGGTGAAGTCGTAACAAGGTAACCGTAGGGGAACCTGCGGTTGGATCACCT
->URS00003BE16A rRNA from 1 species 
-TGAACGCTAGCGGCACGCTTCATACATGCAAGTCGAGGGGCAGCATAAAGTACTTGTACTTTGATGGCGACCGGCGAACGGGTGCGTAACGCGTATGCAACTTACCTTTTACTAGAGAATAGCCAAGAGAAATTTTGATTAATGCTCTATACTCTTTTTAACTCACATGAGTTTTTAAGAAAAGCTCCGGCGGTAAAAGATGGGCATGCGTCCTATTAGCTTGTAGGTGAGGTAACGGCTCACCTAAGCTCCGATAGGTAGGGGTCCTGAGAGGGAGATCCCCCACACTGGTACTGAGACACGGACCAGACTTCTACGGAAGGCAGCAGTAAGGAATATTGGACAATGGAGGAAACTCTGATCCAGCGATGCCGCGTGAAGGAAGACGGCCCTATGGGTTGTAAACTTCTTTTATACAGGAAGAAACCTTTCCACGTGTGGAAAGCTGACGGTACTGTAAGAATAAGGATCGG
->URS00025B9EB0 lncRNA from 1 species 
-GGAGAATTGCAGTGATAAAAATGAATGTTTTACCGAGGCTACTCTACATATTTCACACAGCCCCACAGGTGATTCCGCAGGCATTTTTCAGGACACTCAAAACAGCAATCACACAATATATTTGGAGAGGGGAGAAGGCCCGCATTGGCTTTGACAAGCTCTGCTTACCAAGAAGCTGGGGAGGGTTAGCCTTGCCCGACATCAGAAAATACCACCAGGCTACAGTACTGCAGAGGCTCAAG
->URS0001DE2DB5 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTTGAGCGCTGAAGGTTGGTACTTGTACCAACTGGCTGAGCAGCGAACGGGTGAGTAACGCGTGGGGAATCTGCCTTTGAGCGGGGGACAACATTTGGAAACGAATGCTAATACCGCATAAAAACTTTAAACACAAGTTTTAAGTTTGAAAGATGCAATTGCATCACTCAAAGATGATCCCGCGTTGTATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCGATGATACATAGCCGACCTGAGAGGGTGATCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGACGAAAGTCTGACCGAGCAACGCCGCGTGAGTGAAGAAGGGTGTCGGATCGTAAAACTCGGTTGGTAGAGAAGAACGTTGGTGAGAGTGGAAAGCTCATCAAGTGACGGTAACTACCCAGAAAGGGACGGCTAACTACGTG
->URS0001C397AE rRNA from 1 species 
-GATGAACGCTAGCGGCAGGCCTAATACATGCAAGTCGGACGGGATTCAGGAGCTTGCTTCTGATGAGAGTGGCGCACGGGTGCGTAACACGTATGTAACCTACCTTTATCAGGGGGATAGCCTCTCGAAAGAGAGATTAAGCCCGCATAAAATCACAGCACAGCATTGTGTAATGATCAAATATTTATAGGATAAAGATGGGCATGCGGAACATTAGCTAGATGGCGGGGTAACGGCCCACCATGGCGACGATGTTTAGGGGATCTGAGAGGATGGCCCCCCACACTGGTACTGAGACACGGACCAGACTCCTACGGGAGGCAGCAGTAAGGAATATTGGCCAATGGGCGGAAGCCTGAACCAGCCATGCCGCGTGCAGGAAGACGGCCCTACGGGTTGTAAACTGCTTTTATACGGGAATAAACCCAGATACGTGTATCTGGCTGAATGTACTGTAAGAATAAGGATCGGCTAACTCCGTG
->URS0000EF62B1 lncRNA from 1 species 
-GCTGCCACCTCTCTTGACTCCCTTGTGAGGAGATCGGCTCTTGCTCCTCCTCATGCCATGACTCTTTAATTTGCGGCTGGTCGACATGCCATTGTGACAAGGCACCATCAATCATCATGTCCCTTTACCAGGAGGGCCCGTGTCATAAGCCACTATATAAAGGGAATGATGGGTGGACTGCTTTGGACAAATGGACCTGCGGTAGGAGAGAGGGACAACAGTAGGAGCAGGCAGATCTTGCTGTTTCAACCAAAACCTCATGCTGACCAGAGTTGAGGAACAGAAGAAGATGGTGAAGGCCTGCAGGTATAGGTGTTCAGCATGTCATCTGAAATATTCCCCACAGAGGCAAAAAGAAAGGAAATTATCTCTGAAAAGGAATGGGAGGACAAGTCAGCAGAATATGTCAATGTTTTGGTTGAAGAAGCTGCTTGAATCTGGGCTTTTCTGTGCCATGTGTTCTCCCAGGGCCAGCACAAAGAAGGGCTTTTGGTGCAGGCCCAAGACCACCATAATCATCATTGATTATTCCTCTCCACGCCAGTGTCTCTAAATAAACTTTCTCTTCTTTCTCTGACAAA
->URS0002429CE1 lncRNA from 1 species 
-TTTTCTTGAATGGACAATAATGCGTTTTGTGTCCAAGTTTGCAACAAAAGTTGTATTTGCTTTGGTGTTGAACATGTAAGATGGGGCCTTTTATGAAGGTGGTTGGATTTTGGTGAGGACTTCTCACAAATCCGATTCCACTTCTTTTGGGAACGTGACCCTTGTTTGCAAGGATCATGTTCAGTGACTTGCTACCAACCTCGAATTTCTTCAAGGTGTCCTTAAGTAGCAAGTTTTCCTTTTGGAGAGTTTCTAGATCATGGCATTT
->URS0001CE0F72 rRNA from 1 species 
-GGGTTGTGAGGTTAAGCGACTAAGCGTACACGGTGGATGCCCTGGCAGTCAGAGGCGATGAAGGACGTGCTAATCTGCGATAAGCGTCGGTAAGGTGATATGAACCGTTATAACCGGCGATTTCCGAATGGGGAAACCCAGTGTGATTCGTCACACTATCATTAACTGAATCCATAGGTTAATGAGGCGAACCGGGGGAACTGAAACATCTAAGTACCCCGAGGAAAAGAAATCAACCGAGATTCCCCCAGTAGCGGCGAGCGAACGGGGAGGAGCCCAGAGCCTGAATCAGTGTGTGTGTTAGTGGAAGTGTCTGGAAAGGCGCGCGATACAGGGTGACAGCCCCGTACACAAAAATGCACATGCTGTGAGCTCGATGAGTAGGGCGGGACACGTGGTATCCTGTCTGAATATGGGGGGACCATCCTCCAAGGCTAAATACTCCTGACTGACCGATAGTGAACCAGTACCGTGAGGGAAAGGCGAAAAGAACCCCGGCGAGGGGAGTGAAAAAGAACCTGAAACCGTGTACGTACAAGCAGTGGGAGCACGCTTAGGCGTGTGACTGCGTACCTTTTGTATAATGGGTCAGCGACTTATATTCTGTAGCAAGGTTAACCGAATAGGGGAGCCGAAGGGAAACCGAGTCTTAACTGGGCGTTAAGTTGCAGGGTATAGACCCGAAACCCGGTGATCTAGCCATGGGCAGGTTGAAGGTTGGGTAACACTAACTGGAGGACCGAACCGACTAATGTTGAAAAATTAGCGGATGACTTGTGGCTGGGGGTGAAAGGCCAATCAAACCGGGAGATAGCTGGTTCTCCCCGAAAGCTATTTAGGTAGCGCCTCGTGAATTCATCTCCGGGGGTAGAGCACTGTTTCGGCAAGGGGGTCATCCCGACTTACCAACCCGATGCAAACTGCGAATACCGGAGAATGTTATCACGGGAGACACACGGCGGGTGCTAACGTCCGTCGTGAAGAGGGAAACAACCCAGACCGCCAGCTAAGGTCCCAAAGTCATGGTTAAGTGGGAAACGATGTGGGAAGGCCCAGACAGCCAGGATGTTGGCTTAGAAGCAGCCATCATTTAAAGAAAGCGTAATAGCTCACTGGTCGAGTCGGCCTGCGCGGAAGATGTAACGGGGCTAAACCATGCACCGAAGCTGCGGCAGCGACGCTGATGCGTTGTTGGGTAGGGGAGCGTTCTGTAAGCCTGCGAAGGTGTGCTGTGAGGCATGCTGGAGGTATCAGAAGTGCGAATGCTGACATAAGTAACGATAAAGCGGGTGAAAAGCCCGCTCGCCGGAAGACCAAGGGTTCCTGTCCAACGTTAATCGGGGCAGGGTGAGTCGACCCCTAAGGCGAGGCCGAAAGGCGTAGTCGATGGGAAACAGGTTAATATTCCTGTACTTGGTGTTACTGCGAAGGGGGGACGGAGAAGGCTATGTTGGCCGGGCGACGGTTGTCCCGGTTTAAGCGTGTAGGCTGGT
->URS00003281C0 rRNA from 1 species 
-CTACGTGCCAGCAGCCGCGGTAATACGTAGGTCCCGAGCGTTGTCCGGATTTATTGGGCGTAAAGCGAGCGCAGGCGGTTAGATAAGTCTGAAGTTAAAGGCTGTGGCTTAACCATAGTACGCTTTGGAAACTGTTTAACTTGAGTGCAAGAGGGGAGAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAGGAACACCGGTGGCGAAAGCGGCTCTCTGGCTTGTAACTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAGGTGTTAGACCCTTTCCGGGGTTTAGTGCCGTAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCCTCTGACCGCTCTAGAGATAGAGCTTTCG
->URS00016D14C4 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAATGGATTGAGAGCTTGCTCTTATGAAGTTAGCGGCGGACGGGTGAGTAACACGTGGGTAACCTGCCCATAAGACTGGGATAACTCCGGGAAACCGGGGCTAATACCGGATAACATTTTGAACCGCATGGTTCGAAATTGAAAGGCGGCTTCGGCTGTCACTTATGGATGGACCCGCGTCGCATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCAACGATGCGTAGCCGACCTGAGAAGGTGGTCGGCCACACTGGGACTGAGAGACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCGTCCGCAATGGACGAAAGTCTGACGGAGCAACGCCGCGTGAGTGATGAAGGCTTTCGGGTCGTAAAACTCTGTTGTTAGGGAAGAACAAGTGCTAGTTGAATAAGCTGGCACCTTGACGGTACCTAACCAGAAAGCCACGGCTAACTACGTGCCAGCCGCCGCAGTAA
->URS000090AB96 SRP_RNA from 1 species 
-GCCGGGCGTGGTGGCGCATGCCTGTAATCCCAGCTACTCGGAAGGCTGAGGCAGGAGAATTGCTTGAGCCCAGGGAGCGAAGGTTGCAGTGAGCAGAGATCATGCCACTGCACTCAAACCTGGGCAACAGGGTGAGACTCTGTCTCAA
->URS00023BAE1B lncRNA from 1 species 
-CTGAACCCTTATCAGTAAAAGTTTATCCGGAGTCAGAGAACAGGGAATGGCACTCGACGCAAAAATCGGGCGAGGCCCAGCCCTAGATGTGGGTTCATCTACAGTGTGGGGGTTTTGGGGGACCAAACAAAGGCCCTAAAAATCCTGGAACCACTAGAGGCGGAGGTACCGAAAGATATTTCAAACAAAGGCCCTAAAAATCCTAGAAAAATCAGGCGGGATAAGAGGTGAAAGGTTTGCGGGGGACCAAACCAGAGGAATGTGGCAGAAGAAAAATGGAGGAGAAAGGGCACCT
->URS00022ED730 rRNA from 1 species 
-TGGGGAATTTTGGACAATGGGGGCAACCCTGATCCAGCAATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTTGTCCGGGAAGAAATCGCACCTGATAATACCGGGTGTGGATGACGGTACCGGAAGAATAAGGACCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTCGGGTCCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTGTGCAAGACCGATGTGAAATCCCCGGGCTTAACCTGGGAATTGCATTGGTGACTGCACGGCTAGAGTGTGTCAGAGGGGGGTAGAATTCCACGTGTAGCAGTGAAATGCGTAGAGATGTGGAGGAATACCGATGGCGAAGGCAGCCCCCTGGGATAACACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGG
->URS00010F344E rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTAGGACGCAGTTGCGAACGGGTGAGTAACGCGTAGGTAACTACCTATTAGAGGGGGATACCTATTGGAAACGATAGCTAATACCGCATACCTGTAGATGGATCTGCGTTGTATTAGCCAGGAGGTAGGGTAATGGCCTACCTAGGCAACGATACATAGCCGACATGAGAGGATGATCGGCCAGACGGGGAGTGCGGCACGGCCCAGACTCCTACGGGTGGCAGCAGTAGGGAATCTTGGGCAATGGGGGGAGCCCTGACCGAGCAACGCGGCGTGAGTGAAGAAGGTCGTCGGATGGTAAAGCTCTGTTGTTAAGGGAGCGGTACTTAAAGAGAAAGGGACGGCTAACTACGTGCCAGCAGCCGCGGTAATAC
->URS0001F774E1 misc_RNA from 1 species 
-GATGAAGAACGCAGCGAAATGCGATACTTGGTGTGAATTGCAGAATCCCGTGAACCATCGAGTCTTTGAACGCAAGTTGCGCCCGAAGCCATTAGGCCGAGGGCACGCCTGCCTGGGCGTCACACGTCGTTGCCCCCCCATCTACTCCTTCGGGATTGCGGGGGGCGGATGATGGCCTCCCGTGCGCCTCGCCGCGCGGTTGGCATAAATGCCAAGTCCTCGGCGACGCACGCCACGCCAATCGGTGGTTGCGAAACCTCGGTTGCCCGTCGTGTGCGGTCGTCGCGCATCGAGGGCTCGAAAAAATTGCCGGGTTCCGGCTCGGCTTTCAACGCGACCCCAGGTCAGGCGGGGTTACCCGCTGAATTTAAGCATATCAATAAGCGGAGGA
->URS000076AF46 rRNA from 1 species 
-GGTTAAGCGACTAAGCGTACACGGTGGATGCCCTGGCAGTCAGAGGCGATGAAGGGCGTGCTAATCTGCGATAAGCGCCGGTAAGGTGATATGAACCGTTATAACCGGCGATACCCGAATGGGGAAACCCAGTGTGACTCGTCACACTATCATTAACTGAATCCATAGGTTAATGAGGCGAACCGGGGGAACTGAAACATCTAAGTACCCCGAGGAAAAGAAATCAACCGAGATTCCCCCAGTAGCGGCGAGCGAACGGGGAGGAGCCCAGAGCCTGAATCAGCATGTGTGTTAGTGGAAGCGTCTGGAAAGGCGCGCGATACAGGGTGACAGCCCCGTACACAAAAGCGCATGTGCTGTGAGCTCGATGAGTAGGGCGGGACACGTGGTATCCTGTCTGAATATGGGGGGACCATCCTCCAAGGCTAAATACTCCTGACTGACCGATAGTGAACCAGTACCGTGAGGGAAAGGCGAAAAGAACCCCGGCGAGGGGAGTGAAAAAGAACCTGAAACCGTGTACGTACAAGCAGTGGGAGCCCCACCACCAAAGCATTCTCTGGTGTTGAAGGCCCTGCAAAGCAGCATCGCGGTGGCGGAGCGTCGTTTGCGACGCCCAACACACAAAACAAGCGGTGAATGCTTTGGGGTGGGGTGACTGCGTACCTTTTGTATAATGGGTCAGCGACTTATATTCTGTAGCAAGGTTAACCGAATAGGGGAGCCGGAGGGAAACCGAGTCTTAATTGGGCGTTAAGTTGCAGGGTATAGACCCGAAACCCGGTGATCTAGCCATGGGCAGGTTGAAGGTTGGGTAACACTAACTGGAGGACCGAACCGACTAATGTTGAAAAATTAGCGGATGACCTGTGGCTGGGGGTGAAAGGCCAATCAAACCGGGAGATAGCTGGTTCTCCCCGAAAGCTATTTAGGTAGCGCCTCGTGAATTCATCTCCGGGGGTAGAGCACTGTTTCGGCTAGGGGGCCATCCCGGCTTACCAACCCGATGCAAACTGCGAATACCGGAGAATGTTATCACGGGAGACAC
->URS0001199C7A rRNA from 1 species 
-TACGTAGGGTGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGTCTGTCGCGTCTGCTGTGAAAACTCAGGGCTTAACCCTGAGCTTGCAGTGGGTACGGGCAGACTAGAGTGCGGTAGGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCATTTCCTGACGCTGGAGGCGCGAAAGCGTGGGGAGCAAACAGG
->URS0000FE9A33 rRNA from 1 species 
-TACGGAGGGTGCAAGCGTTATCCGGATTCACTGGGTTTAAAGGGTGCGTAGGCGGGTTGGTAAGTCCGTGGTGAAATCTCCGAGCTTAACTCGGAAACTGCCGTGGATACTATCAATCTTGGATATCGTGGAGGTAAGCGGAATATGTCATGTAGCGGTGAAATGCTTAGATATGACATAGAACACCAATTGCGTAGGCAGCTTACTACACGATCATTGACGCTGAGGCACGAAAGCGTGGGGAGCAAACAGG
->URS0001565352 rRNA from 1 species 
-AACGTAGGAGGCGAGCGTTATCCGGATTCACTGGGCGTAAAGCGCACGTAGGCGGTCGGGTAAGTCGGATGTTAAAGCCCTTGGCTCAACTAGGGGAGGTCATTCGATACTGCTCGGCTTGAGGATGAGAGAGGAAAGTGGAATTCCCGGTGTAGCGGTGGAATGCGTAGAGATCGGGAGGAACACCAGTGGCGAAAGCGGCTTTCTGGCTCATTCCTGACGCTGAGTGTGCGAAAGCGTGGGTA
->URS000144CD04 rRNA from 1 species 
-CAGTCGCCGCGGTAATACGAAGGGTGCAAGCGTTACTCGGAATTACTGGGCGTAAAGCGTGTGTAGGTGGTTGTTTAAGCCTGTCGTGAAAGCCCTGGGCTCAACCTGGGAATTGCGATGGATACTGGGCGACTAGAGTGCGGTAGAGGATAGTGGAATTTCCGGTGTAGCAGTGAAATGCGTAGAGATCGGAAGGAACATCTGTGGCGAAGGCGACTATCTGGGCCAACACTGACACTGAGACACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCGTGTAGTCCCTGTCTCTTATAA
->URS00000D01ED rRNA from 1 species 
-AGGATGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGTCCTGTCTCGCAAGAGGCAGGGAGTGGCGGACGGGTGAGTACCACGTGGGTTATCTACCGTGAGGTGAGGAATACCGGCGAGAAATCGCCGACAAGACCGCATAGCCTCGGTGCAAGCCGAGGAAAGCTTTCTCGAGAGAGGGAGCGCCACACGAGGAGCCTGCGCCCGATTAGCTAGCTGGTGGAGTAACGGTTCACCAGGGCGACGATCGGTAGCTGGTCTGAGAGGACGATCAGCCACACTGGGATTGAGAACGGCCCAGACTCCTACGGGGGGCAGCAGTGAGGAATTTTCGTCAATGGGGGCAACCCTGAACGAGCAACGCCGCGTGCAGGAAGAAGGTTTTCGGATCGTAAACTGCTTTTCTCGGGAAGAGAACGGACGGTACCCGAGGAATCAGCCCCGGCTAACTACGCGCCAGCAGCCGCGGTAA
->URS0002347B5A lncRNA from 1 species 
-TTCTATGTAAGTATACTTCCGGGGTCTTGCCTCCCTTCTGCCCTGATTCTTCCCTTGTGGGTGTGCTGTCCGCATGCGCAGTGGCCTGCTAGCCCTTGGAAAGGAAGCATACGCAGTGTTTACTGGAGTTGTACGCATGCTCACTCCAGGCGTTCTTCCCTTACCTGCCGAATGTCCCTAGGAGGTCATATACCAGTTAAACTGCCCCATTTTGCCTCTTAGTGTACATTGTGAGCCCACTCAACCAGTTCCTGAGATACTACTGGGAAGCTGCTGATCACCAGTTTCAGGTTTTTTCCATCTGTTGGGAAACTGCCTATCCCTTGTGCTCGCTGCAACCAATTATTATTTTAGGGAGACAGTTAACCGCCTGACCATCACCCGATGATCGCCTGATGTTCATGCATCCATGACTACATAAACTTTTTGGCCGTTTGACCAAATGGGGACATCTGGCATACTGCTATCAACCAATATCACTTACTATGTCATAGGCACTGAACCACAAGCCTTCTGCAGGAATGATCTCATTTAATTCTTACAGCAATCCTATGAGATAAGTAGTACTGATATTACCATTTTACTAATTAGAAACTTGAAGCTTGGCGAGGTTAAATAATATGTCCAAAGTTGCAGAATGATTCAGTAGCAGAGGCTCATTGAGGGGCAAACAAGATCAATCCAATCCCATTCCTGTGTGAAGAAGACAGACATTAAACAATTAACCAAATAAATAATTGATGATAGCTGTAATGAGTGCTATGACAGGTGCTGAGCCAAGGCATAACTTCTGTTCTGAGGGTTCAAGGAAAGCATTGTTCCCTGACAAAATGACATTCAGTCATGGACTCCCACAGTGCTTAGGAGCTGGCAAGGCAAAGGCTTGGGTAGGATGGTTGGGATGAAAGTAAGAATGAGGAGTGAACAGTATTCTAGCTGGGAGGGTCCAAAGTGGGAAGGGGCATGGCAGACCATGGAACTGAGAGAAGGCCAGCAGGCAGGCTGCAAAGAGGGTGAGGGAGGAGGCAGCACCAGATGAGATTGGAAAGCCAGGTTGGGGTGTCATGATAGAGGCTTTGTAGCCATGAGAAAATGTTGGGCCAGGCCAGGTGTGGTGGCTCACACCTG
->URS000084D716 rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTTTTTAAGACAGATGTGAAATCCCCGGGCTTAACCTGGGGACTGCATTTGTGACTGTAAGACTAGAGTGCGGCAGAGGGGGGTAGAATTCCACGTGTAGCGGTGAAATGCGTAGATATGTGGAGGAATACCGATGGCGAAGGCAGACCCCTGGGTCGACACTGACGCTGATGCGCGAAAGCGTGGGGAGCAAACAGG
->URS0000CD773A rRNA from 1 species 
-TACGTAGGGTGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGTTTGTCGCGTCTGCTGTGAAATCCCGAGGCTCAACCTCGGGTCTGCAGTGGGTACGGGCAGACTAGAGTGTGGTAGGGGAGATTGGAATTCCTGGTGTAGCGGTGGAATGCGCAGATATCAGGAGGAACACCGATGGCGAAGGCAGATCTCTGGGCCATTACTGACGCTGAGGAGCGAAAGCATGGGGAGCGAACAGG
->URS00011E7DCB rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTTGTTAAGACAGATGTGAAATCCCCGGGCTTAACCTGGGAACTGCATTTGTGACTGGCAAGCTAGAGTATGGCAGAGGGGGGGTAGAATTCCACGTGTAGCAGTGAAATGCGTAGAGATGTGGAGGAACACCGATGGCGAAGGCAGCCCCCCTGGGTCAAGATTGACGCTCATGCACGAAAGCATGGGGAGCGAACAGG
->URS00002D8EF0 rRNA from 1 species 
-AGCGGCGAACGGGTGAGTAACGCGTGAGCAACCTACCTTAGTTACTGGGATAGCCCGAGGAAACTCGGATTAATACCGGATATTCTTATTTAATCACATGATTTTCTAAGGAAAGGTCAGCCGAACTAAGATGGGCTCGCGTTCTATCAGCTAGTTGGTAGGGTAACGGCCTACCAAGGCTACGACGGATAGCTGGTCTGAGAGGACGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCTGCAGCAGGGAATATTGTGCAATGAACGAAAGTTTGACACAGCGACACCGCGTGTGGGATGACGGATCTAGGTTTGTAAACCACTTTCAGGAGGGAAGAAAACGACGGTACCTCCACAAGAAGCCCCGGCCAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCTCGTAGGCGGTTCAACAAGTCGGTCGTGAAAGTTCAGGGCTCAACCCTGAAATGTCGATCGATACTGTTGTGACTAGGATACGGCAGAGGTGAGTGGAATTCCGAGTGTAGCGGTGAAATGCGTAGGTATTCGGAGGAACACCAATTGCGAAGGCAGCTCACTGGGCCGCTATCGACGCTGAGGAGCGAAAGCTAGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCTAGCTGTAAACGATGGATACTAGATGTAGGAATTGGTTTAACGATTTCTGTATCGTAGCTAACGCGTTAAGTATCCCGCCTGGGGAGTAC
->URS0000C7CC16 tRNA from 1 species 
-TCTCTGGTAGTCCAGTGGCTAAGGCATTGCACTGCCAATGCAGGGGACCCAGGTTCGATCCCTGGTCTGGGAA
->URS00000379BF rRNA from 1 species 
-GGCTTTTTGATAATAATTTAAAGTCTTACCTGCTCTATGATATTTTAAATGGCTGCAGTATTTTGACTGTACAAAGGTAGCATAATCATTAGTTTTTTAATTGAAAGCTGGAATGAATGGTTTGATGAAAAAATATCTGTCTTTATTTAATGATTAAAATTTTATTTTTAAGTTAAAAAGCTTAAATTTTTTTAAAAGACGAGAAGACCCTATAGAGTTTGATATTAATTTTTTTTTATTTTAAATTTAGAATAAATTTTTTAATTAATGRTGAATATTTGATTGGGGTGATTAAAAAATTAATTTAACTTTTTTTATTTTATTTCATAAATTAGTGTATATTTGATCCAAAATTTTTGATTATAAGTTTAAATTACCTTAGGGATAACAGCGTAATTTTTTTAGAGAGTTCTTATCGAAAAAAGAGATTGCGACCTCGATGTTGGATTAAAATTTATATTTGGTAGTAGAAGCTGAAATATTGGGTCTGTTCGACCTTTAAAATTTTACA
->URS0002047E1F rRNA from 1 species 
-CCTACGGGTGGCAGCAGTAAGGAATATTGGTCAATGGACGCAAGTCTGAACCAGCCATGCCTCGTGGAGGATGAAGGTCCTCTGGATTGTAAACTTCTTTTATTTGGGAAGAAACTCCCGATTTCCATCGGGCTTGACGGTACCAGATGAATAAGCACCGGCTAACTCCGTGCCAGCCGCCGCGGTAATACGGAGGGTGCAAGCTTTATCCGGTTTAAATGGGTTTAAGGTGGGCAGGGAAGGCAGTGTAGAAATCTCCGGGCTTAACCCGGAAACTGCCATTGATACTATTTGTCTTGAATACTCTGGAGGTGAGCGGAATATGTCATGTAGCGGTGAAATGCTTAGAGATGACATAGAACACCCATTGCGAAGGCAGCTCACTACGGAAATATTGACGCTGAGGCACGAAAGCGTGGGGATCAAACAGGATTAGATACCCTTGTAGTC
->URS000059B2B0 rRNA from 1 species 
-CTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGTGGTTTAATAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGTTTAACTTGAGTGCAAGAGGGGAGAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAGGAACACCGGTGGCGAAAGCGGCTCTCTGGCTTGTAACTGACGCTGAGGCTYGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAGTGCTAGGTGTTAGACCCTTTCCGGGGTTTAGTGCCGTAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTACTCT
->URS00014BE65D rRNA from 1 species 
-ATTGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGATCGGTAACGCGGGGGCAACCCTGGCGACGAGAGGCGGACGGGTGAGGAACGCTTGGGAATCTGCCTATCAGCGGGGGACAACACGGGGAAACTCGTGCTAATACCGCATACGCTCTACGGAGGAAAGCCGGGGACCGCAAGGCCTGGCACTGATAGATGAGCCCAAGCCGGATTAGCTAGTTGGCGGGGTAACGGCCCACCAAGGCGACGATCCGTAGCTGGTCTGAGAGGACGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAGTATTGGACAATGGGGGAAACCCTGATCCAGCGACGCCGCGTGGGTGAAGAAGGCCTGCGGGTTGTAAAGCCCTTTCGGTAGGGACGAAAGCTCTCGACCTAACACGTCGGGAGGATGACTTAACCTACAAAAGAAGCACCGGCTAACTCTGTGCCAGCAGCCGCGGTAATAC
->URS00004D4C08 rRNA from 1 species 
-ATGCAAGTCGAACGATGAAGCCCTTCGGGGTGGATTAGTGGCGAACGGGTGAGTAACACGTGGGCAATCTGCCCTGCACTCTGGGACAAGCCCTGGAAACGGGGTCTAATACCGGATACGACCACTGAGGGCATCCTCGGTGGTGGAAAGCTCCGGCGGTGCAGGATGAGCCCGCGGCCTATCAGCTTGTTGGTGGGGTGATGGCCTACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGCGACCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCGACGCCGCGTGAGGGATGACGGCCTTCGGGTTGTAAACCTCTTTCAGCAGGGAAGAAGCGAAAGTGACGGTACCTGCAGAAGAAGCGCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGCGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGCCTGTCACGTCGGATGTGAAAGCCCGGGGCTTAACCCCGGGTCTGCATTCGATACGGGCAGGCTAGAGTTCGGTAGGGGAGATCGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGATCTCTGGGCCGATACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGTTGGGCACTAGGTGTGGGCAACATTCCACGTTGTCCGTGCCGCAGCTAACGCATTAAGTGCCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGCGGAGCATGTGGCTTAATTCGACGCAACGCGAAGAACCTTACCAAGGCTTGACATACACCGGAAAGCATTAGAGATAGTGCCCCCCTTGTGGTCGGTGTACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCCTGTGTTGCCAGCATGCCCTTCGGGGTGATGGGGACTCACAGGAGACCGCCGGGGTCAACTCGGAGGAAGGTGGGGACGACGTCAAGTCATCATGCCCCTTATGTCTTGGGCTGCACACGTGCTACAATGGCCGGTACAATGAGCTGCGATACCGCGAGGTGGAGCGAATCTCAAAAAGCCGGTCTCAGTTCGGATTGGGGTCTGCAACTCGACCCCATGAAGTCGGAGTCGCTAGTAATCGCAGATCAGCATTGCTGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACGTCACGAAAGTCGGTAACACCCGAAGCCGGTGGCCCAACCC
->URS000030D236 rRNA from 1 species 
-CATGCAGTCGGAGGTAACATTTCTAGCTTGCTAGAAGATGACGAGTGGCGGACGGGTGAGTAATGCTTGGGAACTTGCCTTTGCGAGGGGGATAACAGTTGGAAACGACTGCTAATACCGCATAATGTCTTCGGACCAAACGGGGCTTAGGCTCCGGCGCAAAGAGAGGCCCAAGTGAGATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCGACGATCTCTAGCTGTTCTGAGAGGAAGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGTTGTGAGGAAAAGTTAGTAGTTAATACCTGCTAGCCGTGACGTTAACAACAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATCACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGCTAGATGTGAAAGCCCCGGGCTCAACCTGGGATGGTCATTTAGAACTGGCAGACTAGAGTCTTGGAGAGGGGAGTGGAACTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAACATCAGTGGCGAAGGCGACTCCCTGGCCAAAGACTGACGCTCATGTGCGAAAGTGTGGGTAGCGAACAGGATTAGATACCCTGGTAGTCCACACCGTAAACGCTGTCTACTAGCTGTGTGTGTCTTTAAGACGTGCGTAGCGAAGCTAACGCGCTAAGTAGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTACACTTGACATGCTGAGAAGTTACTAGAGATAGTTTCGTGCCTTCAGGAACTCAGACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTAAGTCCCGCAACGAGCGCAACCCTTGT
->URS0000D53B79 miRNA from 14 species 
-TTTATTCTCAGTTTGTTGCTC
->URS00018E852B rRNA from 1 species 
-CAGCCGCCGCGGTAATACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTATATAAGACAGATGTGAAATCCCCGGGCTCAACCTGGGACCTGCATTTGTGACTGTATAGCTAGAGTACGGTAGAGGGGGATGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAACACCGATGGCGAAGGCAATCCCCTGGACCTGTACTGACGCTCATGCACGAAGGCGTGGGGAGCAAACAGGATTAGATACCCCGGTAGTCCCTGTCTCTTATAC
->URS0001DF4263 tRNA from 1 species 
-GGGTGATTAGCTCAGTTGGTAGAGCAGGTGACTCTTAATCACCGGGTCCACAGTTCGAGCCTGTGATCACCCACCA
->URS00007C3FF8 rRNA from 1 species 
-TGGGGAATCTTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGAGTGAAGAAGGCCTTCGGGTTGTAAAGCTCTTTTACCAGGGACGATAATGACGGTACCTGGAGAATAAGCCCCGGCAAACTTCGTGCCAGCAGCCGCGGTAATACGAAGGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCACGTAGGCGGATTGTTAAGTCAGAGGTGAAATCCCGGAGCTCAACTTCGGAACTGCCTTTGATACTGGCAATCTCGAGTCCGGAAGAGGTTAGTGGAATTCCCAGTGTAGAGGTGAAATTCGTAGATATTGGGAAGAACACCAGTGGCGAAGGCGGCTAACTGGTCCGGTACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCCAGTAGTCCCTGAGCGGGC
->URS0000D54BB5 miRNA from 15 species 
-ATGGGTAGCACAAGGATTAATG
->URS000041BA98 siRNA from 1 species 
-TCAACCTAGGCTCTGATA
->URS00000BB073 rRNA from 1 species 
-GGCGGTTAGATAAGTNTGAAGTTAAAGGCTGTGGCTTAACCATAGTACGCTTTGGAAACTGTTTAACTTGAGTGCAAGAGGGGAGAGTGGAATTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAGGAACACCGGTGGCGAAAGCGGCTCTCTGGCTTGTAACTGACGCTGAGGCTCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTNCACGCCGTAAACGATGAGTGCTAGGTGTTAGACCCTTTCCGGGGTTTAGTGCCGCAGCTAACGCATTAAGCACTCCGCCTGGGGAGTACGACCGCAAGGTTGAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGTCTTGACATCCCTCTGACCGCTCTAGAGATAGAGTTTTCCTTCGGGACAGAGGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTATTGTTAGTTGCCATCATTCAGTTGGGCACTCTAGCGAGACTGCCGGTAATAAACCGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGACCTGGGCTACACACGTGCTACAATGGCTGGTACAACGAGTCGCAAGCCGGTGACGGCAAGCTAATCTCTTAAAGCCAGTCTCAGTTCGGATTGTAGGCTGCAACTCGCCTACATGGAGTCGGAATCGCTAGTAATCGCGGATCAGCACGCCGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCACGAGAGTTTGTAACACCCGAAGTCGGTGAGGTAACCATTNGGAGCCA
->URS00002C2482 rRNA from 1 species 
-TGCGCCTTGCCAGCCCGCTCGAAACTTAAAGGAATTGACGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCAGGCCTTGACATGCAGAGAACTTTCCAGAGATGGATTGGTGCCTTCGGGAACTCTGACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCTTGTCCTTAGTTACCAGCACGTTATGGTGGGCACTCTAAGGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGGCCTGGGCTACACACGTGCTACAATGGTCGGTACAAAGGGTTGCCAAGCCGCGAGGTGGAGCTAATCCCATAAAACCGATCGTAGTCCGGATCGCAGTCTGCAACTCGACTGCGTGAAGTCGGAATCGCTAGTAATCGTGAATCAGAATGTCACGGTGAATACGTTCCCGGGCCTT
->URS00007D10E7 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATGCATGCAAGTCGCACGCAGCACTCTTCGGAGTGCTGAGTGGCGCACGGCTGAGGAACACGTGGGCACCTGCCCGCGCGTGGGGGATAACCCGGCGAAAGCCGGGCTAATCCCGCATACGCTTGGCTCCCAATAGCCAAGCAAAGCGGCAACGCGCGCGCGGAGGGGCCTGCGGCCCATCAGGTGGTTGGCGGGGTAACGGCCCACCAAGCCGGTGACGGGTAGCTGGTCTGTGAGGACAACCAGCCAGACTGGGACTGAGAGACGGCCCAGACTCCTACGGGAGGCAGCAGCAAGGAATTTTCCCCAATGGGCGCAAGCCTGAGGGAGCAACGCCGCGTGCAGGACGACGGCCTTCGGGTTGTAAACTGCTTTTCGGAGGGACGAGAGTGACGGTACCTTCGGAATAAGCCCCGGCTAACTCTGTGCCAGCAGCCGCGGTAAGACAGAGGGGGCCAGCGTTGTCCGGACTAACTGGGCGTAAAGCGCGCGCAGGCGGTCGGAGGCGTCGGTGCTGAAAAGCTCCCGCTTAACGGGAGACGGCGTGCCGATACGCTTCGACTGGAGGGCGGGCGAGGGTGGTGGAAGTGCCGGTGTAGTGGTGAAATGCGTAGAGATCGGCTCGAACACCAGTGGCGAAGGCGGCCACCTAGCCCGCCCCTGACGCTGAGGCGCGACAGCGTGGGGAGCGAACTGGATTAGATACCCAGGTAGTCCACGCCGTAAACGATGCCGACTCGGTCTTCGTGGAGCGACAAGCTCCGGGGGGGCCCGAGCTCACGCGCTAAGTCGGCCGCCTGGGGACTACGAGCGCAAGCTTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCAGCGGAGCGTGTGGTTTAATTCGACGCAACGCGCAGCACCTTACCCAGGCTGGACATGGAGCTGCACAGCGGGGAAACCCGCTGGCCTTCGAGGGTGCTCCACAGATGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCCGCGGCCAGTTACACGTGTCTGGTCGGACCGCCCTTCGGGGAGGAAGGCGGGGATGACGTCAAGTCCGCATGGCTCTTACGTCTGGGGCGACACACACGCTACAATGACGCCGACAGTGCGAGGCGAAGGAGTAATCCGAAGCGAATCGCCAAACGGCGTCCCAGTGCAGATCGGGGGCTGCAACTCGCCCCCGTGAAGGCGGAGTTGCTAGTAACCGCGTATCAGCCACGGCGCGGTGAATACGTACCCGGGCCTTGTACACACT
->URS00004C538B rRNA from 1 species 
-AACGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGANCGAACCCTTCGGGGTTANCGGCGGACGGGTGAGTAACCCGTGGGAACGTGCCCTTCTCTGCGGAATAGGCTCGGGAAACTGGGTTTAATACCGCATACGCCCTTCGGGGGAAAGATTTATCGGAGAAGGATCGGCCCGCGTTAGATTAGGTAGTTGGTGGGGTAATGGCCTACCAAGCCTACGATCTATAGCTGGTTTAAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGAGGAATCTTGGACAATGGGGGAAACCCTGATCCAGCCATGCCGCGTGAGCGATGAAGGCCTTAGGGTTGTAAAGCTCTTTCAGTCGTGAAGATAATGACGGTAGCGACAGAAGAAGCCCCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGGGCTAGCGTTGTTCGGAATTACTGGGCGTAAAGCGCGCGTAGGCGGACTATTAAGTCAGGGGTGAAATCCCGGGGCTCAACCCCGGAACTGCCTTTGATACTGGTAGTCTAGAGTTCGAGAGAGGTGAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAGGAACACCAGTGGCGAAGGCGGCTCACTGGCTCGATACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGAATGCCAGTCGTCGGCAAGCATGCTTGTCGGTGACACACCTAACGGATTAAGCATTCCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGAAGCAACGCGCAGAACCTTACCAACCCTTGACATCCTGATCGCGGTTACCCGAGAGGGTTCCCTTCAGTTCGGCTGGATCAGTGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTCGGTTAAGTCCGGCAACGAGCGCAACCCACACCCTTAGTTGCCAGCATTCAGTTGGGCACTCTAGGAGAACTGCCGATGATAAGTCGGAGGAAGGTGTGGATGACGTCAAGTCCTCATGGCCCTTACGGGTTGGGCTACACACGTGCTACAATGGCAGTGACAATGGGTTAATCCCCAAAAACTGTCTCAGTTCGGATTGTTCTCTGCAACTCGAGAGCATGAAGTCGGAATCGCTAGTAATCGCGTAACAGCATGACGCGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTTGGGTTTACCCGAAGACGGTGCGCCAACCCTTACGGGGGGCAGCTGGCCACGGTAAGCTCAGCGACTGGGGTG
->URS0000D271BB rRNA from 1 species 
-GAGGAGAGCTTGCTCTCTGATTTAGCGGCGGACGGGTGAGTAATGTATAGGGAGCTGCCCGATAGAGGGGGATACCAGTTGGAAACGACTGTTAATACCGCATAATGTCTACGGACCAAAGTGTGGGACCTTCGGGCCACATGCTATCGGATGCACCTATATGGGATTAGCTGGTTGGTGGGGTAATGGCTCACCAAGGCGACGATCCCTAGCTGGTTTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTTGTAAAGCACTTTCAGCGGGGAGGAAGGGGATGTGGTTAATAGCTGCGTCTTTTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGTAGGCGGTATGTTAAGTTGGATGTGAAAGCCCCGGGCTCAACCTGGGAATTGCATTCAAAACTGGCATGCTAGAGTATGTGAGAGGGGGGTAGAATTCCAAGTGTAGCGGTGAAATGCGTAGAGATTTGGAGGAATACCAGTGGCGAAGGCGGCCCCCTGGCACAATACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCTACTA
->URS0000CC6E85 SRP_RNA from 1 species 
-GCCAGGAGAGGTGGCTCGTGCCTATAGTCCCAGTTATTTGGGAGGCTGAGGTGGGAGGATTGCTTGAGCCCAGAAGTTCTGGGCTGTAGTGCGCTGTGCCGATTGGGTGTCTGCACTAAGTTCAGCATCAATATGGTGACCTCCCGGGAGCGGGGAGCCACCCAGAGGGGTGAAACTAAGGAGGCATGAACCAGCCCAGGTTGGAAACGGAGCAGGTCAAAACTCCCGTGCTGATGAGTGGTGGGATCATGCCTGTGAATAGCCACTGCACTCCAGCCTGGGCAACATAGTGAGACCCCGTCCCC
->URS0001C732DD rRNA from 1 species 
-AACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGAGACCTTCGGGCCTAGTGGCGCACGGGTGCGTAACGACTGGGAACTTGCCCTTGGGTTCGGAATAACTCCCCGAAAGGGATGTTAATACAGGTTAATGTCTTAGGGCCAAAGATTTATCGCCTTTGGATGGGGCCGCGTTGGTTTGGCCAGTTGGTAGGGTAAAAGCCTACCAAGGGGACGATCCTTAGCTGGTGGGAGAGGAGGCTCAGCTACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGGAGGAGTAGGGAGTATTGGGCGATGGGCGAAGGCCTGATCCAGCAATGCCGGGTAAGTGATGAAGGCGTTAGTGTTGTAAAGCTCTTTTAGCCGGGATGATAATGACAGTACCGGGAGAATAAGCTCCGGCTAACTCCGTG
->URS0000BDC546 lncRNA from 1 species 
-GAACTTCCTACAGTCTGAACTGGCTGTCCTCGCTTTGTTTGTAGACAGCCACGGACATGAGTTAGGAGAGGAAGACTCGGAGGGATCACTGGCCCCAAGTGGAAATCGAGGAACCTTCCCGACCCAGGAGGGCCCCGAAGAACTCGAGGAGCAGGACTGCGGAGAACAACGGGCTGGGAGGTGCGAGCCCGCCGAGGGCCTCTTCCTGACCTCCCGTCAGGTGAGGGGTCACGGTCCTGGCTGGCATGAGTTTCTCTCAGGTCCTGGCTCACGGCTGCTCTACAGGTGCACTTTCCCGGGCTTATCCTGTCACTAGACATCTGGGCTATGACAAGAGCAGGACCTCCCGGTAGGAAGACAGAGCAGGACACAGGAGCCGGGAGCCAGCGTGAAGGGAGGAGGCAGTGAGCTGAAAGGGGTAAGGCCCTTGGCAGCGCATCAGCGTTTCTCAG
->URS0000DCD19B rRNA from 1 species 
-AACTTAAAGGAATTGACGGGGGCCCGCACAAGCGGTGGAGTATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCCGGAGACCCTTAGGAAACTAGGGGGTGCTTCCATCTGGAAGAATCTGGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCCTGCTTCCAGTTACCATCATTAAGTTGGGGACTCTGGAAGGACCGCTGCGGTAACAACGCAGAGGAAGGTGGGGACGACGTCAAGTCAGCACGGCCCTTACGTCCAGGGCTACACACGTGCTACAATGGTCGGTACAAAGGGTTGCCAAGCCGCGAGGTGGAGCTAATCCCATAAAACCGATCGTAGTCCGGATCGCAGTCTGCAACTCGACTGCGTGAAGTCGGAATCGCTAGTAATCGTGAATCAGAATGTCACGGTGAATACGTTCCCGGGCCTT
->URS000122ED6C rRNA from 1 species 
-TACGAAGGGGGCTAGCGTTGCTCGGAATCACTGGGCGTAAAGGGTGCGTAGGCGGGTCTTTAAGTCAGGGGTGAAATCCTGGAGCTCAACTCCAGAACTGCCTTTGATACTGAAGATCTTGAGTCCGGAAGAGGAGAATGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCCGTGGCGAAGGCGGCTCTCTGGGACGGTACTGATGCTGAGACGCGAAAGCGTGGGGAGCGAACAGG
->URS000217E4C6 lncRNA from 1 species 
-AACAGCTCTCCCCATCCCCGACTTGCTGAGCAGCCCTGGGCAGTCTACTCTACAGCTCTCGACCTCCCTGAGGTCCATCTAGGGAGGACACAGGGACAATAATTCAAACAAATGCTTTCACGTCGGTCTGAGCTAACAGAGGGGGTGACTGGGGTGGGGGCCCCCTGGGGAGAGAAGGAGGGAATGGAGAAGCCTTCCCAGTGTCCAGAGTCACCACTTATTTCAGAGACGCTGGCTTCTGTGGGCCACCCAGATCTTCCTTCTCCTCTTCAGTGAATGACAGGCGGGGACCAAAGTCCCATCGAGCCAGAAGGGTCATTTGATAGTCCCATTCTCTATTACTGGTGCCTTTACAGGTGAAAAACTAGCCCAGCTCCCACTTACCCAAGAACACATCACAGGCCTTCCAATGTCTCTAAGCACTGCCGGGGCCCCAGGGCCTGATCGAGAGGGCAGGCCCTGCGGATGGCCGTCCACCACAGGGGAACCTTAGGGACTGTCTATGGAAACTGAAAAGAGCCACTGGCACCTGTCTTTGTCCAGCGAAGAAGGGAGATGAGCGGCCCCACCCAGCCCTTAGAGCTGCTTTCCTTCCCTTCCCCCACAGCCCGTGCCCTGACCCGGGGTGAGGGCTGCCCTGGGGCCTGGGCGCCGGCCTGCTCTTTGCCTGTGTGTGCCTGCGAGTGGGAGACGGAGAGAACACTTGGGAGCGAGTCTTTCCTTCCTGAACTTCTATTTCCTCAACTATTAACAAGGAAATTGCATTAGGTGATCTGTGGGTCAGGGCTTCCTCCTCTCCAGGAGGAGGATGTTCTAGTCTTTTCTCGCTGCACGCAGTCCTGAGCTCCACTGCAGAGAGAAACCGAGAGCAGAACGTTCATTCCTAAGAGTGAGGTGTCCAGTGCCCAGCTCTCCCTGGCTTTCCTGCTTGGAAAAGGCAGAGGAGAATGGCTTACAAACGCCAAAACCTGGCCGGCGATCATGCTGTGGTTTGCAGAGAATTAGAAGGCATTGTGGATCTCGCAAGGTGTTTGTAGCCAGAGCAGAAATGCCTTGGCAGGAGAAGCCAGGCGCACCAGCCCAGCCTCGTGGGTGGGCCTCTCTGTTGGCCACCGGACAGGGGCTGCCAGGACGTTTCTTGCCCCCAGCTGCCCTAAAGTCATGAGAGAAAATGGGTCAGACTGCAGAGGCTTATCCTTCTGGGACTCAGCTTTACTGCCCTGTGGCTCCAAGAGAAATGAAGAATATTAATCAGAAATTAAAAAAAAAAAATCAGCTCCATCAAAGGCCCCAAACTAGGCAAAAGGTTGAAGAATCTGCTCTCTGCTTGTATCTCTCTGTCTAGAGGGTATCCTCCCAGCAACAGCTTGTAGGGATGCTGTTATGGGCCCTTCTCCCAAATCCATATATCCTAACCCCTAATACTTCAGATGTGACTATGTTTGGAGATATGGTCTTTACAGAGGCAATTACATTAAAATGGAGTAACTAGGGTGAGCTCGAATCCAGCAGAACTGTAGTCTTTATCAGAAGGGAACATTTGCCTGCGGACGCACATGGAGGAGAGACACCAGGAGAAGATGGGCGTCCCCAGCCAGGGAGAGCGGGCCGGGGTGGATTCTTCCTTTGCACCCTCAAAAGGAGCCCACCCTGCCAACGCTGTGATTGTGGACCTCTAAGCTCTGCTGTTTAAGCCACCCAGTTTGTGGCACTTTGTTAGAGCAACTCTAGCAAATTTCTCCAGATGCTGCTCTGTTGGGAGGTCTGCACAACCTTGAGACTGCCTGGACTCAGAAGAATGAGTCCGCATGAGGGGAAGGGTTCTGCCCTTGCAGTGCAGCCTTATTTTAACATGAAACAAAACTGATCTATTACTCTCTTCCCTCAGAGCCTAGTCTTTTAAATTTTTTATTTCTTTTGGTATTGGTTTAACACGTTTTATTGTTTTAATCCCTTTAGTCTTTTTATTTTGTGAGTTTAATGAGTTTACTTATCTCAGTCATTTTTTAATCCCGTTTTTTCTTTCTTCTAGCTATTTTATACTATGTCTTTTATCTCATCTTCTAGATCTTTTGGTATTATATTTTTATTTTCCGTCTGTTATTTCTAACCCTTTGCCTTATCGTGCCTTTGTTCCATCTTTTAATTTCTTTTTAGCTTATTTTTTTTATTTTTAGTTCATATTGTCGCTTGCCTGCTGCCTTTTTTTTTAACTACTTTTTATTTCTTC
->URS000185AE94 rRNA from 1 species 
-GACGGAGGGTGCTAGCGTTGTTCGGAATCACTGGGCGTAAAGGGCGCGTAGGCGGCCTTGCAAGTCGGTTGGTGAAAGCCCGGGGCTCAACCCCGGAGGTGCGGCCGAGACTGCAGGGCTGGAGGCCGGAAGAGGAGGGTGGAATACCCAGTGTAGAGGTGAAATGCGCAGATATCGGGAGGAACACCAGTGGCGAAGGCGGCTATCTGGACGGTTTCTGACGCTAAGACGCGAAAGCGTGGGGAGCAAACAGG
->URS00013B9BDC rRNA from 1 species 
-TACGTAGGGGGCTAGCGTTGTCCGGAATCATTGGGCGTAAAGAGCGTGTAGGCGGCTCGGTAAGTCCGCTGTGAAAGTCGGGGGCTCAACCCTCGAATGCCGGTGGATACTGTCGAGCTAGAGTGCGGAAGAGGCGAGTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCAATTGCGAAGGCAGCTCGCTGGGACGTCACTGACGCTGAGACGCGAAAGCGTGGGGAGCAAACAGG
->URS00021EA825 tRNA from 1 species 
-GCCGAGATAGCTCAATGGTAGAGCAACCGCCTTGTAAGCGGTAGGTTACGAGTTCAAGTCTCGTTCTCGGCT
->URS0001B16A08 rRNA from 1 species 
-ACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCTACTAGCCGTTGGAAGACTTGATCTTTTAGTGGCGCAGCTAACGCGATAAGTAGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGACGCAACGCGAAGAACCTTACCAGGTCTTGACATCCTGAGAATCCTTTAGAGATAGAGGAGTGCCTTCGGGAACTCAGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCTTGTCCTTAGTTGCCAGCACGTAATGGTGGGAACTCTAAGGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGACGACGTCAAGTCATCATGGCCCTTACGACCTGGGCTACACACGTGCTACAATGGCCAGTACAGAGGGCTGCAAACCCGCGAGGGAGAGCCAATCTCACAAAGCTGGTCGTAGTCCGGATCGCAGTCTGCAACTCGACTGCGTGAAGTTGGAATCGCTAGTAATCGTGAATCAGAATGTCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTGGCTAGTCTAACCTTCGGGGGGACGGTCACCACTTTGTGATTCATGACTGGGGTGAAGTCGTAACAAGGTAGCCCTAGGGGAACCTGGGGCTG
->URS000113661D rRNA from 1 species 
-GCAGCAGCCGCGGGAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTCTGTCAAGTCGGATGTGAAATCCCTGAGCTTAACTTAGGAATTGCATTCGATACTGGGAAGCTAGAGTATGGGAGAGGATGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGATGGCGAAGGCAGCCATCTGGCCTAATACTGACGCTGAGGTACGAAAGCATGGGGAGCAAACAGGATTAGATACCCCTGTGTCCCTGTCTCTTATACA
->URS000018AC20 rRNA from 1 species 
-ATTGAACGCTGGCGGCATGCCTTACACATGCAAGTCGAACGGTAACGGGCCTTCGGGTGCCGACGAGTGGCGAACGGGTGAGTAATGCATCGGAACGTACCTTTCAGTGGGGGATAACGTAGCGAAAGTTACGCTAATACCGCATATTCTGTGAGCAGGAAAGCAGGGGATCGCAAGACCTTGCGCTGATTGAGCGGCCGATGTCAGATTAGCTAGTTGGTGAGGTAAAGGCTCACCAAGGCGACGATCTGTAGCGGGTCTGAGAGGATGATCCGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAAATGGGGGCAACCCTGATCAGCCATGCCGCGTGAGTGAAGAAGGCCTCGGTT
->URS0001022610 rRNA from 1 species 
-CAGTAGCCACGGGAATACGAAGGGGGCTAGCGTTGTTCGGATTTACTGGGCGTAAAGCGCACGTAGGCGGATCGATCAGTCAGGGGTGAAATCCCAGAGCTCAACTCTGGAACTGCCTTTGATACTGTCGATCTGGAGTATGGAAGAGGTGAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAGGAACACCAGTGGCGAAGGCGGCTCACTGGTCCATTACTGACGCTGAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCCCGTAGTCCCTGTCTCTTATAC
->URS0000FD5F85 rRNA from 1 species 
-CCTACGGGCGGCAGCAGTGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCGACGCCGCGTGAGGGATGAAGGTCTTCGGATCGTAAACCTCTGTCAGCAGGGAAGAACGGTCACTGTGCTAATCAGCAGTGAATTGACGGTACCTGCAAAGGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATTATTGGGCGTAAAGCGCTCGTAGGCGGTATGTCAAGTCAAGGGTGAAATCCCCGCGCTCAACGTGGGAACTGCCTTTGAAGCTGGCAAACTGGAGTGTGTGAGAGGATAGTGGAATTCCAGGTGTAGGAGTGAAATGCGTAGATATTAGGAGGAACACCAGTGGCGAAGGCGACTTTCTGGACTGTACCTGACGCTGAGGCGCGAAAGCGTGGGTAGCGAACGGGATTAGATACCCCAGTAGTC
->URS000184CF18 rRNA from 1 species 
-AACGAACGCTGGCGGCATGCCTAACACATGCAAGTCGAACGTGAAGGGGACTTCGGTCCCTGGAAAGTGGCGCACGGGTGAGTAACACGTGGATAATCTACCCGATGATCTGGAATAACACTTCGAAAGGGGTGCTAATACCGGATGAGCTTACGACGTCTTCGGACGACGCGGGAAAAGGGGGCTTCGGCTCCTGTCATCGGATGAGTCCGCGGCCCATTAGCTAGTTGGTAGGGTAATGGCCTACCAAGGCTACGATGGGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGCGCAATGGGCGAAAGCCTGACGCAGCAATGCCGCGTGAGTGATGAAGGCCTTCGGGTCGTAAAGCTCTGTCAGAGGGGAAGAAACTCCCGTCGGTTAATACCCGGCGGGCCTGACGGTACCCTCAAAGGAAGCACCGGCTAACTCCGTGCCAGCCGCCGCAGTAAAAC
->URS00020C60CA rRNA from 1 species 
-GACGAACGCTGGCGGCGCGCTTAACACATGCAAGTCGAACGGAAAGGCCTGCTTTCCCTTGTGGATTGCGGGTACTCGAGTGGCGAACGGGTGAGTAACACGTGAGTGATCTGCCCCCAACTTGGGTATAAGCCTGGGAAACTGGGTCTAATTCCCGATAGGACTGCAGGGTGGTGCCGGTGGTGGAAAACGATTTTCTAGTGGTGGGGGATGAGCTCGCGGCCTGTCAGCTTGTTGGTGGGGTAGGGGCCTACCAGGGCGGCGACGGGTAGCCGGCCTGGGAGGTGGGCAGGCGAAATCGGGCCTGATATAGGGCGGAGACTCCGGGGGGAGGCATCAGTGGGGGGGATGGCACAATGGGCGGAAGCCTGATGGGGGGACGCCGGGTGCGGGGTGACGGACTTCGGGTTGTAGGCGGGGATCCCCTGTGGTGGAGAGGGTGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTG
->URS00023F918D lncRNA from 1 species 
-CCATACATGTACCACTGCTACATGGTGCAGTAAATTCAACACACAACCTACCCCTTAAACCCTATGAGTTACAACATAGGCACCTGCACTATCAACTTCTCATGACTACTAACGAACATGTCACACAAGCATACAAGTTCAATGGAATACTTATAATAGGATTCTAAGCTCACATTGTCATAATAGTTACCATACATGTCATTCATATTATCAAGAAGATAAATACACATCTATATCACAATAAGGCATCCCATACATGTAGACTAAGATATATATATTACTTGGGATAATTCACTAACTGATATTGCCTGACTAAGCCCTACTTGGTCTTTAGTAATACTAATTTTAGTATTCAAGAACGATTAAGAACATTTTGATCAAAATCAAACCTAGTAGATCAATTAGGAAGATCCGCCCACTAGATTTTCAATCCGTAAATTCCTAAGGTCCTCAAATATTACATATAATAACATATTAAAGTTTGGTAACGATCTAACGGTCGGATCATCGATTGTTATAATATTCAAGTGGTGGTCTCTAACGAAAATATGTTCAAACGACGGGATTTCATCAATCGGATGACACATATTAACTCGAGGTATTGAATTTAGCATAGAAAGATAGAGTTGGCCCACTGGTTACTCACCGCCACATGCGGCGGTTTCTGGCAAACGAAAACCCAATTTTTTGACAAACTCCAAAAAATTACCAAATTTTATAGAAATGTAGAGCAAGTCAAGGGGAATAATTTTCATACCTGGGTCAAAGTTCAATTTGGCTA
->URS000228E004 rRNA from 1 species 
-GCATCTCTTGAATATCAAAGGTGAGCCAGTACAGGATGGACCCGCGTCTGATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCGACGATCAGTAGCCGACCTGAGAGGGTGATCGGCCACATTGGAACTGAGACACGGTCCAAACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGAAAGCCTGATGCAGCAACGCCGCGTGAGTGATGAAGGCCTTCGGGTCGTAAAACTCTGTCCTCAAGGAAGATAATGACGGTACTTGAGGAGGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCTAGCGTTATCCGGATTTACTGGGCGTAAAGGGTGCGTAGGCGGTCTTTCAAGTCAGGAGTGAAAGGCTACGGCTCAACCGTAGTAAGCTCTTGAAACTGGGAGACTTGAGTGCAGGAGAGGAGAGTGGAATTCCTAGTGTAGCGGTGAAATGCGTAGATATTAGGAGGAACACCAGTTGCGAAGGCGGCTCTCTGGACTGTAACTGACGCTGAGGCACGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCTGTAAACGATGAGTACTAGGTGTCGGGGGTTACCCCCTTCGGTGCCGCAGCTAACGCATTAAGTACTCCGCCTGGGAAGTACGCTCGCAAGAGTGAAACTCAAAGGAATTGACGGGGACCCGCACAAGTAGCGGAGCATGTGGTTTAATTCGAAGCAACGCGAAGAACCTTACCTAAGCTTGACATCCCAATGACATCTCCTTAATCGGAGAGTTCCCTTCGGGGACATTGGTGACAGGTGGTGCATGGTTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCTTTAGTTGCCATCATTAAGTTGGGCACTCTAGAGAGACTGCCAGGGATAACCTGGAGGAAGGTGGGGATGACGTCAAATCATCATGCCCCTTATGCTTAGGGCTACACACGTGCTACAATGGGTAGTACA
->URS0000E6547F lncRNA from 1 species 
-CCATCACCAACACCATGTCCTCCCTGGTGAAGGAGCTGCACTCGGCAGAGGAAGAAGACGAAGAAGAAACAGAGAAGCTGCAGAATGGGAAGGACCGAGGTGAGGAGACAAAGCTGTCTGAGAGCTCTGCAGCATTTTCTGACTCACTCAGGGTTCTCTGGCTCCCTTTGGAGCCCCACCAGGGCCTCTGGGTGCACGTGGGTGGCTCTGGGTGCCTCTGGATCAGATGGCTCTGGACCACATGGATGGCTCTGGATCAGATGTGCTGATGGGGTTCCATGGTGACCTCAGCTGGACACGTGTCCCTGTGCTGGGTCCCATGGTGTCCCTGTGCTGGGTCCCTCAGTGTCCC
->URS000193CF2E rRNA from 1 species 
-GTAGGTGGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGCGCGCGCAGGCGGTCCTTTAAGTCTGATGTGAAAGCCCACGGCTCAACCGTGGAGGGTCATTGGAAACTGGGGGACTTGAGTACAGAAGAGGAAAGCGGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATTTGGAGGAACACCAGTGGCGAAGGCGGCTTTCTGGTCTGTAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGGGATTAGATACCCTGGTAGTCCATGCCGTAAACGATGAGTGCTAAGTGTTAGGGGGTTTCCGCCCCCTTAGTGCTGCAGCTAACGCATTAAGCACTCCGCCTGGGGATACGGCCGCAAGGCTG
->URS00011F5F41 rRNA from 1 species 
-TACGTAGGGACCGAGCGTTGTCCGGAATCATTGGGCGTAAAGAGCGTGTAGGCGGCTTGCTAAGTCTTGCGTGAAATCTCGGGGCTCAACCCCGAGCGGTCGTGGGAAACTGGCAGGCTAGAGTGCGGGAGAGGAGAATGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCCGTCGGCGAAGGCGGTTCTCTAGTACGGTACTGACGCTGAGACGCGAAAGCGTGGGGAGCGAACAGG
->URS00005015FB rRNA from 1 species 
-TCTTCGGGATAGGTAGTAGTTAAGGTGATGGCTTAACTAGCCAAAAATTCTCGTAGTCGAAACTGAAAGGTTGATCGACCACATTGGGTCTGAAAAAACCCCAATGCAAGTTAGTACAGCAGTGAGGAATATTGGTCAATGGCCTAACGGCTGAACTGGCAACTTGGAGAAGTGGTAAGTCTTATTTTGATTAGATTATAATATATAATCTATAAGATTGTATTAATATTGAATAAAGCTTTGTTTATATATTGATAATGACAGTATATATATCGTGTCTTGACTAATTACGTGCCAGCAGTCGCGGTAATACGTAAGAGACTAGTGTTATTCATCTTAATTAGGTTTAAAGGGTACCTAGACGGTCAATATATCTTGTAAAATGTTAGTACTTGACTAGAGTTTTATATAAGAGGGCAGTACTTGAGGAGGAGAGATGAAATTCTATTATACCAAAGGGACTCGGTAAAGGCGAAGGCAGCCCTTTATGTATAAACTGACGTTGAAGGACGAAGGCACAGAGCACAAACAGGATTAGATACCCAAGTAGTCTTTGCAGTAAATGATGAATGCCATAGGTTNAGATTAA
->URS000156E271 rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCTTAACACATGCAAGTCGAGCGGAGATGAGGTGCTTGCACCTTATCTTAGCGGCGGACGGGTGAGTAATGCTTAGGAATCTGCCTATTAGTGGGGGACAACATTCCGAAAGGAATGCTAATACCGCATACGTCCTACGGGAGAAAGCAGGGGATCTTCGGACCTTGCGCTAATAGATGAGCCTAAGTCGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCTGTAGCGGGTCTGAGAGGATGATCCGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGGAAGCCTGATCCAGCCATGCCGCGTGTGTGAAGAAGGCCTTTTGGTTGTAAAGCACTTTAAGCGAGGAGGAGGCTACTGAGACTAATACTCTTGGATAGTGGACGTTACTCGCAGAATAAGCACCGGCTAACTCTGTGCCAGCCGCCGCCGTAATAC
->URS0001EFA8A7 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACAGACGAGGAGCTTGCTCCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATATTGAACCGCATGGTTCAATAGTGAAAGACGGTTTTGCTGTCACTTATAGATAGATCCGCGCCGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCGAAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACAAATGTGTAAGTAACTATGCACGTCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTG
->URS000127A0CB rRNA from 1 species 
-TACGTAGGGGGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCGTGTAGGCGGTCAGGTAGGTCCGTTGTGAAAACTCGAGGCTCAACCTCGAGACGCCGATGGAAACCATCTGACTAGAGTCCGGAAGAGGAGAGTGGAATTCCTGGTGTAGCGGTGAAATGACGCAGATATCAGGAGGAACACCGATTGCGAAGGCAGCTCGCTGGGACGTTACTGACGCTGAGACGCGAAAGCGTGGGGAGCAAACAGG
->URS0000123E88 piRNA from 1 species 
-TGATAAGTGTCCTCCAAATGGCCAGTGAGC
->URS00015DB2A6 rRNA from 1 species 
-TACAGGGGGTGCAAACGTTGCTCGGAATTATTGGGCGTAAAGCGCGCGTAGGCGGCTACTTAAGTCGGATGTGAAAGCCCCTGGCTCAACTGGGGAAGTGCACCCGAAACTGAGTGGCTTGAGTGCGAAAGAGGGTCGCGGAATTCCCGGTGTAGAGGTGAAATTCGTAGATATCAGGAGGAACACCGGTGGTGTAGACGGCTCACTGGACCGTAACTGACGCTGAGACACGAAAGCGTGGGTAGC
->URS00006B5731 tRNA from 1 species 
-TCCCTGGAGGTCCAGTGGTTAGGACTTGGTGCTTTCACTGCAGTGGCTGAGGTTCAATTCCTTGTCAGGGAA
->URS0001521DBC rRNA from 1 species 
-CCTACGGGTGGCAGCAGTGGGGAATATTGCACAATGGGGGGAACCCTGATGCAGCGACGCCGCGTGGGTGAAGAAGCGCCTCGGCGCGTAAAGCCCTGTCAGCAGGGAAGAAAATGACGGTACCTGAAGAAGAAGCACCGGCTACCTACGTGCAAGCAGCCGCGGTAATAAGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGGGCGCAGACGGCGATGCAAGCAAGGAGAGAAAGCCCGGGGCCCAACCCCGGGACTGCTCTTGGAACTGCGTGGCGGGAGTGCAGGAGGGGCTGGCGGAATTCCTGGTGTAGCGGTGGAATGCGTAGATATCAGGAGGAACACCGGTGGCGAAGGCGGCCTGCTGGACTGCAACTGACGTTGAGGCCCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCCTGTAGTC
->URS0001374C98 rRNA from 1 species 
-TACGTAGGGTGCAAGCGTTGTCCGGAATTATTGGGCGTAAAGAGCTCGTAGGCGGTTTGTTGCGTCGGCTGTGAAATCCCGAGGCTCAACCTCGGGTCTGCAGTCGATACGAGCAAACTAGAGTGTTGCAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGATGGCGAAGGCGGCTATCTGGCTCACAAACTGACGATCAGGCACGGAAAGCGTGGGGAGCAAACACGG
->URS00005F7B23 piRNA from 1 species 
-TCCGAAGTCACAAGTAGGCAAAGCTGGCCTT
->URS0000A2FBFB rRNA from 1 species 
-GACGGAGGAGGCGAGCGTTATCCGGAATTATTGGGCGTAAAGCGTCCGTAGGTGGCTGAGCAAGTCTTTTGTCAAATAGTGGAGCTTAACTCCATAGAGGCGGGAGAAACTGTTTAGCTTGAGTATGGTAGGGGTAGAGGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAAGAACACCAGTGGCGAAGGCGCTCTACTGGGCCATAACTGACACTGAGGGACGAAAGCTAGGGGAGCGAAAGGG
->URS00023F966A lncRNA from 1 species 
-CCATTCCAATCACATCTAATGCCTCCCTCGCTCGCCAGAGGTATGCCGACTCTTGCGAGGCTGCCATTAACGAGCAAATCAAGTAAGCATCCATCCATTAAAATCAAAAGCTCCCTTAAAATTTAGATATTAACAGAGGTTGAGGTTGATTTTTGGACAGTGTGGAATACAACGTGTCGTATGTGTACCATTCAATGTACGCCTACTTTGACAGAGACAACGTTGCTCTCAAGGGTCTTGCCAAGTAACTTTTTCTTACTACTACTACTGCCTTTCAATCTTAATCTAACTAAAGCAAAAATTTAATAATATGATAAAACTTGGTTCAGATTTTTCAAGGAATCAAGTGATGAAGAAAGAGAGCACGCTGAGAAGTTTATGGAGTACCAGGTTTCCCTCTCTTTTTTCCCCATTCTAGAAGTTGAAAAGAATATTGATTTGATTTGAGGGTTAATATATGTATGGTTTATGTATATGTGTGTAGAACAAAAGAGGAGGAAGAGTGACACTCCACCCTATCGTCTCCCCTATCTCTGATTTTGAACATGCTGAAAAAGGAGATGCCTTATATGGTATATATTTTTTTTTATACTTATACAAAAAAAAAAAACACTTTCTTTCTTGATTAATAAGTGTATACACAGATCTTGAAATGGTCTTATACTAATCTATATTATTTTCAGCAATGGAATTGGCCCTGTCTCTGGAGAAACTTACCAACGAGAAGCTTCTAAACCTTCACAGAGTATGTTCCCAAAACTTATCCATCTAAAGTCAATCAAATAAGGCATTCACTAATTTTAAAATAATAATTAAAAAAAACAGGTGGCATCAGAGAACAATGACCCACAGTTAGCTGATTTTGTTGAGAGTGAGTTTCTCGGAGAGCAGGTGTGTTTTTCTTTTGTTCGTTTTCTTAACTAGTGACTTGAAACTAGTACCCACTTTTAAATAAACATATTTTTCTCTCCCCCTTAGATTGAAGCAATCAAGAAGATCTCAGACTTCATCACCCAGCTAAGGATGGTTGGCAAAGGACACGGTACGCTGTTTGATCTAAACCTCCCCTATATTCAGTACTAGGACTAGAATTTCAGTAGTAATTTTTTTAGAAAAGCTTATTAAATTTTTATGTGTCTTTTGCAGGAGTTTGGCACTTCGACCAGATGCTTCTGAACTAGAGTGGGACCTCTATAAGTTCACTTTATGCTCTGGGGAGATTAAAAGAGAAGTAAACAGAAGAAGATTCTGTAAAAGTTGCTAGAGTGGAAGTTATTATTGGAGCAAAAATAAGATTTGTAGTACTAATAGTAGTAAGCTTTGTGTGTTAAGATGATGGGTTTTTTTTTGTAATAATTTCATAAGTTTAATCTATGAAGGTGGTTTTTGTTTCATATTTTCATGTTCTGACTATATATATGAACAAACGGAGACTTGAGTCCGATTAATAGGTAGAGAAACACTCTAACTAAACGCAATGCTGCAATTCAAAAGGTGAAAGAAGAGTTAAAAAAAAATAAGGAACCTGTGGATGAAGAACATGAAGCCTCGGTCACTCAGTGAGATAACTGAAAAGCAAACAAAGAAGAGTTAAAAAGAAAAGATATATGAATTGAGACTTTAACATAAGTGCAATGCAAGTTGTTTATATTTCCAAACAGTATGTTTGATCCAGAGCTAGTATCTGATGCCCTAACTTAGATTCTATCTTGAACACTAGACTAGACAGTCTTCT
->URS000010D699 rRNA from 1 species 
-AGGACGAACGCTGGCGGCGTGCTTAACACATGCAAGTGGAGCGACGAACCAGGGCTTGCCCTGGGGCAGAGCCGCGAACGGGTGAGTAACACGTGGGTTACCTGCCTCGATGACCGGGACAACCCGAGGAAACTCGGGCTAATACCGGATGTGCCCGCAAGGGGAAAGGAAGCTTCGGCCTCCGCATCGAGATGGGCCCGCGGCCCATTAGCTTGTTGGTGAGGTAACGGCTCACCAAGGCTTCGATGGGTAGCTGGTCTGAGAGGACGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGGGCAGCAGTGAGGAATTTTCCGCAATGGGCGCAAGCCTGACGGAGCAACGCCGCGTGCAGGAAGACGGTTTTCGGATCGTAAACTGCTTTTCTCGGGGACGAGAACGGACGGTACCCGAGGAATCAGCCCCGGCTAACTACGTGCCAGCAGCCGC
->URS00002998B4 rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGATGAACCGGAGCTTGCTCTGGGGATTAGTGGCGAACGGGTGAGTAACACGTGGGCAACCTGCCCCAGACACCGGGATAACCATTCGAAAGGATGGCTAATACCGGATACGACCACTTCGGGCATCCGATGGTGGTGGAAAGGATTCTGGTCTGGGATGGGCCCGCGGCCTATCAGCTTGTTGGTGGGGTAATGGCCTACCAAGGCGACGACGGGTAGCCGGCCTGAGAGGGCGACCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCGCAATGGGCGAAAGCCTGACGCAGCGACGCCGCGTGAGGGACGAAGGTCTTCGGATTGTAAACCTCTTTCAGCAGGGATGAAGCGAAAGTGACAGTACCTGCAGAAGAAGCACCGGCTAACTACGTGCCAGCAGCCGCG
->URS0000E6E834 lncRNA from 1 species 
-GCAGCAGCAGCCAGCACAGTGTCTTTGGCACAGCCCAGGCAGACAGGTGGAGGAGAACTGAATCCTGCTTCTTGACAGCCCATTCTATCAGCCTTCATCTCCAACTTGTTAAATTTCCAACAAGTTGCTTCGTGCTCTCCTTTATCCACTGCCCCCAAGCATGGGAGGAGTTACTGCAAGTAGCCACAGAGCCACCTTCTGTTCTCCTGCAGCTTCCTCCTGCAAAACCCAACCACCAGTCCAGGAACACAAATATCAGCCAGAAGTGGTATGTGATTGCTTCCATCTGATTTGGAGAGGAATTGCTTTTCCAATAGTGGATGATTTGATCCAGAACTGGAGAACCAACCTGGCAGTCAGCAGCTTCATGAGACCAAATCTGACCCAGGGCCTCAGAGCTCTGCCAGCTGCAGGCAGGTGATCACAGAAGCTAGAACAGAGCAAAACAAAATTAAAAAAAATCCATGAACTAAGTGTAGAATCCATCTGAATTCAGCAAGATGGGCTGTAACAGGAGAAGTTTTATTTATTCCTTGACCTGAACTCAGCTCACACCCATCAAAGTGACAAAAGGTGATAAATATCCTTTGGGGTTCCAGGTAATTTCTTCCCTTCTGCTTTACCTGGCAGGGAATGTTTTTGGAAGATTAATGAAATACCCAGAATTTTGTGCATGTATATGTGTGTGCGTATGTGTGTATAGCTATTTATTTACTTACTTATATCTATAAACCAGCATTTTTCATGCAAACTGAGAATTCATCGACATGGTATTGTTCTTGTTGCAACCCAGGGAATTAAAGGATGCCGACAATTAATGGAATCACAGAAGTACAAGATGGTTTGGGTTGGAAGGCACCTTAAAGCTCATCTTGTTCCACCCCGTGCCCTGGGCAAGAACACCTTCCACCAGACCAGGTGGCTCCAAGCCATGGAACATACGCAGAGCTGGGGCAGACACACATGGGGGCACAAACACAGCTTCTGGTTTTTATTTCACAGTTCTGAGTTGTGGGTCTGTTTAGGAGGAAATAACCCCCCACACACACAGTAAGTGCAGGGTTTTCCAGGCCCCCTCCAAACATCCCCTGCAGGCTCCCCCTGATCATCCCTGCCAGGCCAGCAGCCCACCCCCACTGCTGTATTCAGTGGTACCAGGACACCTCCAGCTCTGTATCTGTGTCCTCCTGTTCTCAGGGAAACCCATGAGGATCAGTTTGCTTTTGTATCAAATTTACTTCTTTGCTGGTACCATTTTCTCTGCTTACTCATAAACACACCGAGCACCACAAACACTTTGGAAACTCAAATGACTCCTTACTGTGAAAACTGGGAGCAGAGCCTAACCCCCATCTGGGTGCACCCTCCTGTCAATGAGAGCAATGGGAGAGTTCTTCCAAATCAGCCCAGCTGAGCACAGGTGTTTCCTGATGTCCCTCCAAACCTGCAAGATTAATTTTCTGCCCATTTAGTCCTTGTGCTGGCAGTGGAGATGTCCTGGTCACAGTTTTTAGATGTCTTCTCTAGACTGAGGAATCAGAGTTCAGGCATAAACCACCTTCTTTTGGGACATGAGGAATAAAACTTCCATATCCGCAGCCCA
->URS00019739F1 lncRNA from 13 species 
-ATGCAAGGTATCTGTGGAAGCCTGAAGACGCCAGAATTTTGTCTGCTTGTAATGAAGGTTTCAGGTCTTACAGATCCCTCGGCAAAGTCCATGCCCCCTAGCTACCCACAGTGTGACACTAGCGCTCTACCGTCTAGTTATGTCAGCATCACAGTAAGAATGCCCTCGCATCCGAACCATGATGGGAAATCAGCTGGCCACAGCAAGGCTGGAGAACCCTGTGTGTGCAGTCCTGCAGCACGGCCTTCTGAAGGCGCACCTCCTGCAGAGGTGTTGACGGGAAAGGCGAGGAAGAGGGGATAATGTGACCTGCTTTCACAGGAAGCTTCAGATCATTTCCCTTTGTCTCTGTGCCCCTTTGGGAGATTTTGATCCAATTTGCTGTGGTGAGAAGAAGCTCTCGACATTACAAGAGAAAAAAAAAAAACCCAAAACTTTCATTTTCCTCCTAAGAAATGAAATTTTATTTCTGGATGACAAGGGCTTTGGAAGGCCATGGTGTGGTAATGAGTGACCCTTTCATAGCTGTTGAACATCAGTAGGCGACACATCCAAAGTATAGAGGCAGCTCTTAAAATACCAGCTAAAGGAAGAATTTAGAGAACAGAATGTCTTTAAGGAACTGTGCGAATGTTATTGATTCTTTCAAATAATGGTGTAACCTCTGTGATACAGCAACAATCTTCATGAGCTGTATTTATAAGGAACTGAGCTCATGAAGACAGCATGGGGGGTCTGGCGATGCAGGGCCCTTTGTTAACCATTGTTCTATTATTAGTATTGTTAGCATTGCCCTGCACAAGTTATCCACTTTTTCTCCAGCCCCCTGGGTATTCAGCAGAAATGATTTAAGAATGCCTGTAACAGCTGGGTGCAGTGGCTCACACCTGTAACCCCAACACTTTGGGAGACCGAGGTGGGTGAATCACAAGGTCAAGAGGTGGAGACCATCCTGGCCAACATGGTAAAACCCCGTCTCTACAAAAAATTGAAAAAAAAAAAGTTAGCTGGGCCTGGTGGCGTGCACCTGTAGTCCCAGCTCCTTGGGAGGCTGAGGCAAGAGAATCACTTGAACCCAGGAGGTGGAGGTTGCAGTGAGCTGAGATTGTGCCACTGCACTCCAGCCTGAGTGAGAGAGCGAGACTCCATCTCAAAAAAAACAAAGAATGCCTGTAACTTAGTCTCCTACTTGGCATCACCTAAGAGTTCAGGAGTGCAGTGACAGGTTAACTGAGCTCTTGCAGAAAGGTGCTGTGGACAGCGAGGTATAAGTCAGAGGAGTGACATGTTCTATGATGGGAAAGAAGAAAGCTGAAATCCCAAGGTGCTCCCTGACATTTGCCACTCACATAAACTGATGAGAGAGTTTGTTATTAAAGGCCTTTTTGTTTAATTAGAAATCAAACCAGAAGACCCTGGTGTCATAATTTATTCTCTTGCAAAATTATGTGATCAGAAGTTCCAGCCATAACCACAGAGGCATTGGAAGTTGGTAAATGATGCTCTGACTCAAAAGCTTCAAAGACATAGGAGGGGCAGAGGGAAGGAAATGTATCATTAATAAACAGCCTGAGCAAGTGGGCA
->URS00014F887F rRNA from 1 species 
-TACGTAGGGTGCGAGCGTTGTCCGGAATTATTGGGCGTAAAGGGCTCGTAGGCGGTCTGTTGCGTCAGGAGTGAAAACCCGGGGCTTAACCCCGGGCCTGCATTCGATACGGGCAGACTCGAGTGTGGTAGGGGAGACTGGAACTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAAGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCACTACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS00019CB411 rRNA from 1 species 
-GGCTCAGGACGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAACGCGTTTCCGTTATTGATTTTAGATGCTTGCATTTAAATGATTTAACACGAAACGAGTGGCGAACTGGTGAGTAACACGTGGGTAACCTGCCCTTGAAGTAGGGGATAACACTTGGAAACAGGTGCTAATACCGTATAACAACCAAAACCACATGGTTTTGGTTTAAAAGATGGCTTCGGCTATCACTTTAGGATGGACCCGCGGCGTATTAGCTTGTTGGTAAGGTAATGGCCTACCAAGGCAATGATACGTAGCCGACCTGAGAGGGTAATCGGCCACATTGGGACTGAGACACGGCCCAAACTCCTACGGGAGGCAGCAGTAGGGAATCTTCCACAATGGACGAAAGTCTGATGGAGCAACGCCGCGTGAGTGATGAAGGGTTTCGGCTCGTAAAACTCTGTTGTTGGAGAAGAACAGGTGTCAGAGTAACTGTTGACATCTTGACGGTATCCAACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGTGGCAAGCGTTGTCCGGATTTATTGGGCGTAAAGCGAGCGCAGGCGGTTTCTTAGGTCTGATGTGAAAGCCTTCGGCTTAACCGGAGAAGTGCATCGGAAACCAGGAGACTTGAGTGCAGAAGAGGACAGTGGAACTCCATGTGTAGCGGTGAAATGCGTAGATATATGGAAGAACACCAGTGGCGAAGGCGGCTGTCTGGTCTGTAACTGACGCTGAGGCTCGAAAG
->URS000065A135 ncRNA from 1 species 
-TGTCTCCTCCAACTGATCAAATATTGGATTCAGCCCGCTGCCGCAAGGAAGCGGGCTTTTTTTT
->URS00000A33BD rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTAGAACGCTGAAGGAGGAGCTTGCTCTTCTGGAAGAGTTGCGAACGGGTGAGTAACGCGTAGGTAACCTGCCTCTTAGCGGGGGATAACTATTGGAAACGATAGCTAATACCGCATAAAAGTCGACATTGCATGATGTTGACTTGAAAGGTGCAACTGCATCACTAAGAGATGGACCTGCGTTGTATTAGCTAGTTGGTGAGGTAACGGCTCACCAAGGCGACGATACATAGCCGACCTGAGAGGGTGATCGGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATCTTCGGCAATGGGGGCAACCCTGACCGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAGCTCTGTTGTAAGAGAAGAACGAGTGTGAGAGTGGAAAGTTCACGCTGTGACG
->URS000054A298 rRNA from 1 species 
-GCTCAGTAACACGTGGATAACCTGCCCTAAGGTCCGGCATAACCCCGGGAAACTGGGGATAATACCGGATAAACCATAGATACTGGAATGTTCTGTGGTTAAAAGTTCCGGCGCCTTAGGATGGATCTGCGGCCTATCAGGTAGTAGTGGGTGTAAAGTACCTACTAGCCGACGACGGGTACGGGTTGTGAGAGCAAGAGCCCGGAGATGGATTCTGAGACATGAATCCAGGCCCTACGGGGCGCAGCAGGCGCGAAATCTTTACAATGCGGGAAACCGCGATAAGGGGACACTGAGTGCCAGCATATTATGTTGGCTGTCCACCTGTATAAATCACAGGTGTTAGCAAGGGCCGGGCAAGACCGGTGCCAGCCGCCGCGGTAACACCGGCGGCCCGAGTGGTAGCCACTATTATTGGGTCTAAAGGGTCCGTAGCCGGTTTGATCAGTCTTCCGGGAAATCTGACAGCTCAACTGTTAGGCTTCCGGGGGATACTGTCAGGCTTGGGACCGGGAGAGGTAAGAGGTACTACAGGGGTAGGAGTGAAATCTTGTAATCCCTGTGGGTCCACCAGTGGCGAAGGCGTCTTACCAGAACGGGTCCGACGGTGAGGGACGAAAGCTGGGGGCACGAACCGGATTAGATACCCGGGTAGTCCCAGCCGTAAACGATGCTCGCTAGGTGTCTGGGATGGTGCGACCGTTTCAGGTGCCGCAGGGAAGCCGTGAAGCGAGCCACCTGGGAAGTACGGCCGCAAGGCTGAAACTTAAAGGAATTGGCGGGGGAGCAC
->URS00002125CA piRNA from 1 species 
-TGCGATAGATATTGCTTCCTATCCTGGGCT
->URS0000BE8870 snoRNA from 1 species 
-AGGATCAGTGATGAGGACTGGTGGCGAACGAGTCACAGAGATGACTACACGTCTGCGACTCTGAGGTCTAT
->URS0001BC925D snoRNA from 16 species 
-GUCGACGUACUUCAUAGGAUCAUUUCUAUAGGAAUCGUCACUCUUUGACUCUUCAAAAGAGCCACUGAAUCCAACUUGGUUGAUGAGCCGAAGAACCUUUGUACCCAAGAGUGAGAAAAAAGAAUGUAUUAUUAGCUUGGUCCACAACCCUUAGCGGUUUGGCCAUCUACUCCCACAUUUUUGCUUUGCCUUUUGCAUAUGGUUUGUGUAUGGAUAGAGAACUUAGCUUGGUGGUUUAGAAGUAGGAAUUUCGAUUCUAUGCUUUUUGAACUUACCGGCUUUUUUCUUGUUUUAACUCCUGCAUGAACCGCCUUUUAAUUGGCGCGAUGAUCUUUGCCCAGUUUGUGGACUUCUUCGUGAGGGGACAAACGUAUUGGGUGGGUACAAAUGGCAGUCUGACAAGU
->URS000199981D lncRNA from 1 species 
-TTTGCAAACATAATTAAAACACAGACATGTTCACTAATACTATCTAAAAACATACAAGTGTCGTGAGTCTTTATTCACTTACTGTATGCTTGTTCTGTACTATTGCCACTTCCTATGGAGTAACGTCCAGTAGTAACACTGGCACATGGCACCTTCTCTGAGTCAGACTTTTATAATCAAAGTTGCCAATACAATGCCTGAGGTTGATAAGTAAGATACAGGGTTCTTCTTCTGAGTTATGTCAGTGGCTGTATAACTCTAAATACGAAAGAGATGTTTTACAAAAAAACAAAGGCAAGTGTTTTACATTAAATCTTATAAAACTGTACATAATAAAAGTCTACAACATGAAAACGGCCATTAAACTGTTGTGATAGTTACGAAATGTAGTAAATATAACAATGCTAATGTTTCATGTATTTATCATTAATCACTGTATTCATACAGTGCTGTTTGTATATATAAATATTCAATGGCACTGTAAACAGGTGTTGGAAAACACACATTTACTCTTAACCCATTAGAAGTTATTGTAGTACTTTTTAATCCAAAAGGTCAAAATGCATTAATGCATCATTGATTTAGAAAAATAGCCTTGTACTATGATGCACATTTTGACATTTTCTAGGGTAGCAATCAGGATGAAGCATAACAAAGAATGCCAGATTTCAGACTGGTTTACATTTACACCTACCATGACACAAAATTTTAAACATTAAATGTCATTAAATAATACACAGTTTATAAAACAGTTGATTTCAGAGATGCACAATACACAAAAATCTAGTTAGTGTCTAATGGGAGTTCCCAATAATTTATATCTCTGGGACCTTTATGAGAAATTTAAGTCTGTTTCTCTTTACCATCACGTAGGCAAAGTGAGTTTGAATTGAATTACCTTTTTCTTAGTCTGTACAGAGCTGCATTCAACTGGATAAAATATGCTTATTCATGTTTTCCACTGCTGGACATTCATCCAATAAGTCTTGAGCATATGCTTAAGCATCTGGTAATGGCATTTTGTGGGGCAAGGAAACTCACTATCTCTATCCCTCAGTAAACAAAGTGGTTCTAATTTTATCCATAGTTAAGGCAACTATACTGATATATTAGACACACCATATGCTTTTATGTTGCTGCCTACAATCTAAACGGTAAGAGCGAAAGGAAGTTTCAAACATGCTTTGATCTTCTTGACCACTCAGGAGTTTCATC
->URS0000E66266 lncRNA from 1 species 
-TCAACTTGTAACAGGTGCAGCATGTACCTTCCACTTCTTTTATTGACCGTGAATTGTCAAAACACAACTGCAGCATGATTCCGAATCAGGGCACGAGCTGGGGATGAAACCTTCACCTTCTTAGGAAGAAGATGAAGCCAGTAATCCAGAGGTCACCTGGTATGTGGGCCTTCTGATTTAAAGGCTTCTTTTGGGTCAGGAATTACTGGGGAAGCCATACGGAGTTAGTTACTCCACACAGAACTGAGAAGAGGTTTTGGACTTCCTCTTACAGCTGAAGTTTCTTCAACCCAGTTGTGCTGTTATTTAATTAGCATCGCCTAGGAAAGTCTGGTATGAAGTCTAAAATGTGTCTGAAAAGTGTAACCTTTGCATGTGCCATTGTAAATG
->URS000194BC91 lncRNA from 1 species 
-CCAGGGCCTGAACCCATGCCACAGCAGTGGCAATGCCAGATCCTTAACCACTAGGCCACCAGAGAACTCCCTTTTACTTGTTTTTTGGCCAATGTTCCAAGACATTAAAGGGTTAATCCTCCTAATTGAAGCTGAGATCTTTTTTTGTGGCATCATTTTTGACAAGAGAAAGTCCTCTAAAAAGGACTTGTTGAGCGTTAGGAGGTCTCCTCCTCAACAGCGGTAACAAATGTTCCCTTTGTTATAACTCGACCTCCAATTTTCTCTATTTTCAACCCTGCTATATAGACAGGAAAATTCCCCCAAGTAATCATCATGATGCTCTTTCAGATCCAAACTCCTTGGGCCTCTTCTCCGCAAAAAGTAACCTGGTATGAATTGTCCTCTAGAACAAGGTTAGAAGGGTAACTTGAAACCCAGTTGTACAAGAGCATAGAAGCTCCATGCCCTTTCTGAATAAAATTATAAAGACTTTAGATTTGGTACAGCCATACTGGAAGCCCTACTCCCGTGGGTCCTACTCCAGCGAAAGTGCCAGGAACTACAGACGTCAGCCCCATGTCCCTTGGTTGCATTGCAGCTAATTATTCACAACAGCAAAGAGGAAACAAAGATTTACTCTTTTCCTGAAAGTCTCCACCCAGGTTCCTCAAGAATCTTGAAGCGCCTTGTAGGTGCCTTGAATCCCGAGGCCAGCAGTGGCTATGCTGAGCTAAGTGATATCTTGGTCATCCTTCTGATCTTCCCTGGCTCTGTTTTAGTCCAGGACCCAAAGGCCATAGAGCTAGTGGTATTGAAAGAGCCAGGAATGACCACGAAGGATGCCCCGCTCCTAGGCTGCCTTCCTCCTTCTCTCCCTCTTTCTTGTTAAAATCTAGTGAACTACATAGATATTCTTCTATGGATATCTTGAAGGCTATTCCAGATATTCCTGAAAGGCTTTCCAATCAGCCCTGCCTACCCCTCTAATCTCAGTCTCCTGTCCTCCAAGTATTTCACCACTCAGAAATGTCAGACTTCCCCTTTCTTGGTGCATTTTAGGGATTTTTCGGTATCCCAAGGGAGGGATTCTGCACAAATCTCTTCTTCTTTTCTTGATTCCTAGGATGCCTATTCCTGGTTCAGCATAGTACAGGCTCAGACAATGGTACTCACTGTTGGACCGTTTATTTATAGCAGGTTGAGTATGAGTTGAGACATTGGACAGACGTGGCATTGGATCCTACCTCTTGTGACTTGCTAAGTTTGGGAACTAGGGAAAGTTATTTAATTTCTATGGACCTCATTTTCATCATTAGTAAAATGAGAATCCTTATGGCAAGTACTACTTTAGGATTATCGTAGTACCCGACAGACAGAAGGTTTCAATCCAGCTGTTATTAAGGGTCTGAAACTTGGAGTTCCCATCGTGTCGGATTCGTTAACCACTGCGCCACGGCGGGAACTCCAAAAATGAGTGATATTACTCCAAAGTTGCACACTTCCCCTGCGGCCCCTCATGCCAGGCTCCACTGCCTTGGTGGGGGCCACCTGCTCTTCTCAGGCCTGAGCATGGAGACCACCAAAAATGCCCCCTCACACCCTGCTCTCCCATCCTTCCTCTGAGCCCACTTTTCCCTTCTCTTCAGCTGAGGGAACTTCAGCCACTCACAGTATCTTAGAAGTATCTTTCACAACAAATAACAGTGCCTTTGAGAAGAGAGAACCCAAAACACTTTCCCTCATGGGTCTTTAAAACAGTCATTGGCTGTACCCACAGCAGGTGGAAGTTCCTGGGCTGGAGATCAAACCTGGGCCACAGCAGTGACCCAAGCCACTGAACTACAACCCTGGATCCTTAACCTGTTGAGCCACAGGAGAACTCCTAAAACACGATCATCTTCATGATCACGGAAGCAACATCCTCCACTATCATTTGCTATTGAGTGAACTAACATACATGAAATAGTTCTTAGGGCCTGACACATATTCAATGGGCATATATAGTACATATTAGCTCTTACCACTATCATGGGATTAAGTACATACTAAGTTTCAGGGTGCTATGCTGAATCCTTTCTATACCAAATCTCCTTTAATTGCTGTAAGAACTCCATGGGTGGAAGATATTTTATACCCATTTGAATTATTTACTTACTTAAAAAAATTTTTGGAGCATTTTATTTTACTTATTTTTATGGAAGTATAACTAATGTATAATATTATGTAAATTATAGGTGTACAATAGAGTCACAATTTTCAAAGGTCATACTCCATTTTTAGTTATTATAAAATAACTATAATCCCCATGTTGTACAATTAGTCCTTTTAGCTTATTTTATTTTATTATTTTTTGACTGTGTCCATAGCATGCGAAAGTTCCCAGGAGGGAACCCCATCCACAGCAGTGACAATGCCAAAGCCTTAACCACTAGGCCACCAGGAAACTCCAATTATAGCTTATTTTACACCTAACAGTTTGTACTTCTTAATCCTCAACCCCTTTCCCTCTCCCCACTGGTAACCACTACTTTGTTCTTTATATCTGTGAGTCTGCTGCTTTTTTGCTATATTCACTAGTTTGTTGTATTTTTTAGATTCCACATATAGGTGATATACAGTATTTGTCTTTCTCCAACTTATTTCACTTAGCATAATTCCCTCCCAGTCTATCCATGTTGCTGCAAATGGGAAAGTTTCATTTTTTTTCTTATGGCTAAAATATTACCTTGGAATACCCTTCATCTGTTGAGAGACACTTAGATTGCTTCCATGTCTTAGCAATTTTACACCCATTTTACAGATGAGGAAACAAGATGGTAAGAAGTCAAGTGCCCAAATTCATAGTGTTGATTCATTCTAGAACTGAATTCAAACCCAATCTCCACAGACTGTATTGTCTATCCCCGACGTCAACTGTGTTTGTGTTTAGGTGGGAATGACTTATGGGCAGTCTTTGAAAAAGACTGGGGAATCATCAAGCTGAAATGTTCTCTTGGATTTAAAAATTCTGTAATGAAGACTTAGATGGTTTACTAAAGGAGAAATACATCTGGGTTGGGGGGAGAGGAATAGAAGCAAGGAAGGAGAGAAGAAACATTTATTAGGTCTCCCAGTTGGCTTAGTGGTCAATTCAAACTTTATTTATTTGCTTTTTTTTAGGGCCACACCTGCAGCACATGGACGTTCCCAGGCTAGGAGTCGAATCAGAGCTACAGCTGCTGGCCTATGCCACAGCAACACCGTATCCTTAACCCACTGAATGAGGCCAGGGATCAAACCCACATCCCCATGGATACTAGTCAGGTTCATTTCCACTGTGCCACAATGGGAACTCCCCAATTCAAACTTTAAATCCAGGTTGGTCTCACCTCAGAGCCCAGCTTTCTGCCAAGGACTCCAGAGTTGTACACTTGTGCTCCAATTCTATAACTCCACTGCAAGTAATTTAACAATAATTTCATATTTTCCACTGAGACACTGAAACGTCTTATTGAAAGAGGTCAGGGAAGTCGCTTCCCCAGAGCAGAGTTGGAGAGACAGCTAGACAGTGGCACTGGGGGTGGGGGTGGCTTTCAGTGCAGAACTACGCAGAGGTGTGAAGACGAATGAGCTGGCCTTTTAGGTCTTTTCCAGTCCCCGAGCTCCAGGATTTATTTGGCCATGAAAATGTCAGGCTTTTTCTTCCATAAAATGATGTATGATGGTCTGAGTACATTCCCCAATCCCACCCCCACCTCCTCATATCTGATTAAAAAGCAAAGATTAAATCACTGAAAACAATGGAAAGGAAGGTTTTTCTCCAAGAGGGATGAGGTTTTCCTGAGACAAAGCAACAGGAGGAGCAGAGGGAGTACAAAGGAAAACGCAGGGGTCTGGGAGGGACAAGCTGAGCATAGAGCAGGTGGATGGATCCAGCAGAGAGTGGGGGCTGGGACAAAGGCCAGTTGCAGTTGGGTTATGAGGGCTATCAGCTTACATTAACCAACAGGCATGGAGTGGAAACCAGGGCTCTAGTTATGCAAACCAAATGAATGCATTTGAACAATTTGTGAACCATGTTTTTTATTTTTATTTTGAAAATTTTTTCTTGATATAGGATCTCAGTTTCCAGAGAAAGGACTGAACCTGGGCTGCAGGGGTGAAAGCACTGCATCATTATGACTAAACCACCAGGGAACTCTCTAGAACCATCCTTTTTTTGTTGGGTGTTTAGGGTTTTTTTTTTTTTTTTTTTTTTTTGGCTGGCTAGCAGCATGTGGAAGTTCCCAGGCCAGGGATCAAACCTGCAATCAATTGAAGTTCTCTTGTGGTGCAGATCTTTCACTTACTGCACTGCACGAGAACTCCTAGAACCATCCTCCCCCCACCTTTTTTTCCCCCCAGCACATGAAAGTTCCCTGGCCAGGGATCAAACCGGAGCTGGAGCTGCGACCTCCACCACAGGGGCAGCAACTCCAGATCCTTAACCCACTGTGCCAGGCCGGGGATTGAACTGGTGCCTCCACAGAGATAAACTGGATCATAATGCACTGTGCCTCAGCAGGAACTCCCTAGACCTATCCCTTTTTACCCAGGAGATATGAGGTCAGCCTTGAATCAGAACTCATTCATTCAACCAATACTCATCGCCGCCACTGTACCAGACAGAGTTCTGGGTTTGGAGGATACAGAAATGACCCAAGCAGTTCTAGTTCACTGCCTTTGGGAAGAGAGAAAATAAACACCACGATCAGTAGTAAAGCATGTGGTATTCTAGTTAGCATCAGGGACTAAGTAAAAAATAAAGCAGAGAGCCCAAGAGGAAACATCGGCGCAAGAGTCGGAGGTGGTAATGTTTGGGGGATTTGGCCAGGCATGATGCCTGACTGAGGGGGTCAGAGCAGAGGAAGGAAAGGACAGGGTGCTGATGACAGTGGGGCAGGAGGGTCCTAGGCAAGGGAGGGACAGTCCAGGTCCTGGGGTGGGAGAGGACCTGGTGCCTGAGAGACAGTGAGGACAACCAAGTAGCTGGGTAGGAGGTGGAGTCACAGAGCTCACAGGGGCCAGATCCTGCAGGGCACTGAATATACCTGAAAAGATTTTAGCTTTCAGATCCAGGGAGATGGGACTGCACCCTGGGAAAGGTAAAGCAGGGAGACCACCTAGGATGCTGTTGCAATAATCCAAGCAAGAGATGATGTTGGCGTAGACCAGCTGTAGTGGTAGCAGAGGTGGAGGAAAGTAGTTAATGTCTGGATATGTTAAAATGCTAGGCCTTCAGGGGTAAAAAGGAAGACAAGCCTCAGGAAAGGAGGGAAGCTCTTGCTAATGATCTGCCCTTAATACATCTGCCACCGTTTGTCATCTCAGCAAAAAAAAAACCCTGGAGGCTCCATTCAGACTGACTGTGCAATGGGACTCACTCATGCGCTTAGCTGGTTTCCACTGAGAGTTGGGACAAGGGGTTGTATTTTCCATATTTGCAGGTGACTGACTTCT
->URS000240C156 lncRNA from 1 species 
-GGGATAACTATCACTCCTCCATAATTGAATTCGGTTTTCATTTGTTTATTTATTTATTTTTTTTCCCACCTGTGGCATTGAGTTATTGATAATTGTCAAGTACTTTTCGGATTTGTATAATAATATAATTATTAATTATTATATGTTGGGGAAGAAGTTGTCGGTAAGGTCATTGTCTTAGTAACTTAAATGAGTTTTTAAGCAAAATAAGGACAAATATTTGTTGCCAGTGGTACTGATAATTTATTACAACTTTCATATACATGTATCTTTCATTGTTATAATAATCGCAAGATATTTCACACTGCTTGTTAATACTATCCAAAGAGTTGTTGACTCAAATGACTCTAAAACAGAGGTCTAAAGATGGATACACTACTTGATATATTTATTAAATTTTTTTATTTATTAAATTTTTAGTTTCTATTCTAAGATCCTAATTGATAAGAGTAATAAATCTTCATATTATTGTAAAACAGTGAACTAGCAGAGTATAAATGATAAAAGCAAGATCAATTCTTCACTACTGATTAATAAACAGATATGTAGATTAATTTTTTAAGTTGAATATTCGAAATTTCAACTAAATTTTTTCTTATTTAGTTAATTTTTTCCTGTTAAGCCAAGTGGGGGATTATGGTCAGTTAGTTCTTAATTTAAACTTAGAATCCCCCCCCCCCCCCCCTCCCCTTTCTTTAGCTTTCCTTTTTCAAGCTAACTAAAGATGCGAAGTTTATTTTGCCTTCTTCTGTTTTGTGGTGGTCCAGATTTGGTTTAGGTATATTGATTGAGAGTTATATAATTGTATAATTTTTGTTTGAAGGTATATAAATTAAGGACGCGTGCGATGTATTAACAATAATTTTTTGAAGTTACATTCGTTGTTGGTCGTTGATTGTTAAATGATAAATCTTTCCCATCAAACACTTTGCTCAGCGTCCATGCAATTATACACGAACGATGACACTTTTATTTTATTTTTTCTTTTTTATTATTATTATTTTTGGACCAATTAAGTTCATTACCCTAGTATTTTTAGCAAGACTTCGGTTCATACTTTGACTGGCAAAGAATTTTCAACTCAAATTTTAAGCCTAAAACAGAAGACCATTAACCCAAAAGAAAGAAACAAAATATGTTTCAGGAATTTGGTTAGATATCACAATCAAGTTATTATAAATATAATTTACTGGAGGGGCAACATTATCAGAGTCTTGAGTCATGGAGAAAAGCTGTGTCTGATATTTGATAATTTGAAAAGCAGGTATTAATTCTTTCCGTCCGAGGGTAACTAATACGGCACAGAAATTTTATTTTATTTTCTTTAAATATTATTATTTAACATTCAAACTCTTCATCCCTGATGACTTAATTTTGGGCTGGTCGGTTTCTAGATACAAACTATATATGGCATGTGTTAATCACGGAATAGTCTTCATGCAAATGGGAGACGTTCACACGGGAGCGGAGCCCACATTAAAATTTTAGGGACACAATTCTATATCACAAAATTTTAAAGAGTTAAAAAAATGGACTTAATTATTGGGTTAAACTGTTGAAATATTAAACTTGCATGATTGCATCGGTTAAATTATAAAAAAATCTCTCTTTTAAAAGTTAAATTTCTAAATTTATCATATATGTAAACTAAGTTTTTTTTTTTTTCTAAGACCAGCAGCAGGTGCCATGGCACCTAGTAGTTTTGCGGCAGCTCCGCTCCTGCTCACACACTTAGGTTACTTCTAAGTTACAGCTACTTTTTGTTGCAGACCATTTGTATTTTTATTTTTTAACATATTAAATTACAATCTAATAATATTCTAGTTTATACTTTGATAGTCTGATCATATGTTTCTTTTGATGAGTAAGAGACTTACTATGACCTCTTGACAAGTTTTACAATTTTCCCTCCTCCTATTGAGATTTCGGAGCAAAAAAAAAAAAAAAATCCACCAATATTTTTGGAAAAATAAATGTATTATGGATTAGATGGCTAATGTCAGTCTTATTTGCGCTTCTTTAACTTAAGTAACACCCTTTTGCAGCCTTCCCAACAAGGGTGCTGATACTTACCCTAAGTCAAACCCCGGACATTAGCGAATGACACATTTTTTTATAAAAATTACAACACAATTTTAGTTTGGATCTTTATAGAAATTAAAAAAACAAAAACTCATTTTCCTTAACACAATTCAAAAGCAACAAAACTCAATATACTGCTGCGAGTAACCAACCGTGGCCAAGCCACGAATCCCACTGTACCACTGCGAGCAGTCATATTCAAGCCACGACGTTTAAAATGTCTGTGCCTAGCTGTTCTAGCCACTGCTACTCGTGTAAGTTGAACTTGGGATTTTAAATATTTTCTGGAATTTTATGATTGAATTTATTATAGACTAATTCAGAGTGTTATTAGCATAAGAAATCTCATGGGAGTTCAAGAGAAGTTTCTTGTGCTCATAAAATAATTGGGATAATTAATTAATAAAACCAAGAAATTGCATACTTTTATGTTGTTATTTTGCAGTAGTTATTTTAAATATGATTTGAAAAAAAATTGATGTAGTAATGGAGAATTTGGAACAAGTGGATCAAGTCAAAGAATTGGAGGAATTGGAGGCATTAGACGAGTCTGATTTATAAGAAAATATTGAGTAATTCGAGGAGACCGAATTTGATAACAATGAAGATGTGAAAGAAAAAGTTGCTAAGCCTCAGGTTGGGGTGTGAAAGAAAAAGTAGCAGTGGCAATGGTTGATTTTGGGGTGCCGCTTTGTAAGTGGCCGTGGTTGTCGCGTGGTGGCTGTAGGCAGTGGCAGTGACAATGGCTGTGGTGTGGTGGTTTGGGTGATTTTGGGAGAGTGCTTGTGCTATGTGACTCTGGGGAGTATACTTTCTGCTTTGTGGTTGTCATTCACAACCATAAAGAATAAGAAAGTTTTTTATTTTATTTTATTTTGATATTGCTAAAGTTAGACGGTGCATTTTCATCCCAACAATAACTTTTGTAAAATTCTTCGTTTTGCGTTGTTTTACCTCTTAGTTTTTTCTGTTTGTATTGTTTGCATTTTTATATGCTACTTTTATCTCTCTCTCTCTCTCTCTCTACAAGGTAATTAGGATCATTACATACTCCTCTTATTTAAATGTTTTTTTTCCACTTTACTTTAATAAACTTCCCTTGTAGAGTTAAGATTTCACTAAAAAATTACTAATATTTATAGTCTGAAATTTGTTGTGGTTTTGTCTTGATAATTGTTTTTTTAACGCAATAAGATTTTGTCTCTAATACTTCGAAGGAAGTTTTAATAACATATACACAAAAGAGAATGTATTACCTTACTAATGGCGGGTGATTGCCAAGTCAATAAAACCATTATTTGTAAGTGCTATTTCACACTTATTATATAAACATTAACTTATTAACTAAAAAAGTTATGAGTAGATTTCTTTGTTTCTCCCTCCACTCGATACAACGGTAGCAATGTTTAAGCACTGGGAACTTGCCAAACTTTATTAAAGAGAAATCTCGCATTGAATTATTTGCATAATCAACGTAGATTCAAATAATTGGGCTCCCTAATGGGCCAATTGGGTTCCTCAATGAGCCTCAAATGGTCGAAGATATTTGTTAGGTCCAACTCTGTAGAAGTTCGGGCAAATCATATGCCATCCAATATTCCAAATCCTTTGAAAAAAGCAAAGGGTTAGACTACTGACACCCTTCCAATTTGGGGTATACAAGATATATACAATTGAATTCAACTCAATCAAATCAATTAATCCAACTTAAATTAATCTAATTTTATCGGACTGACTTTTTAATTAGATTAGATTATATTAGATTAGATTAGATTACAAAATAGAATATCTAATGTTATTATATTGGTAAATGGATCTATGTGTTAAAATCTAATATAAACTATTCTAACCAACTGATTCTCATTTTCTTTCTCTATTTTTTAAAAAGGTTACGTGGC
->URS00021E5558 rRNA from 1 species 
-GCTAAAAACCTAGCTCAAATTTACGCAAATGCCACAACCAAACAACTGTAACTAAACAAAACATTTTTAAATTTTAGTAAAGGCGATTGAAAAATACCTAGAAGCTATAACAATAGTACCGCAAGGGAAAGGTGAAATAAAAATGAAACAACTTTAAAGCAAAGCTAAGCAGAGACTTAACCTCGTACCTTTTGCATCATGGTCTAGCTAGTTCAACCAAGCAAAACGCAATTGTAGTTTGACACCCCGAAACTAGGTGAGCTACTTCAAAACAGCCTTTAAGGGCCAACCCGTCTCTGTTGCAAAAGAGTGGGAAGATTTTCAAGTAGAGGTGACAGACCTACCGAACCTAGAGATAGCTGGTTATTCAGGAAAAGGATTTAAGTCCTACCTTAAGTTTTTTTATACCACAAAATATAACAGTAGACTTAAGAGCTATTCAAATAAGGTACAGCCTATTTGAAACAGGAAACAACCTTAAACACAGGGTAATGATATTCTAAACGTGACCAAGTGGGCCTAAAAGCAGCCAACTTTTAAACAGCGTTAAAGCTCCATCACTTTATTTAACTAATAACATTAATATTACAAAACCCTTCACCACTACTGAATGACTCCATAACCATATGGAGAACACTATGCTAGAACTAGTAACAAGAAGAAGACCTCCTCCAAAATGTAAGTGTAAGCCAAAATGAACAACTCACTGGCACTTATCGTCTCTGAACTTAAAGTAGTAACTTCACAAGAAAATTCTACCCCCACAAACGTTAACCTTACACCAGAACATTACCGGAAAGATTAAAAAAAGAGGAAGGAACTCGGCAAATTTTAACCCCGCCTGTTTACCAAAAACATCGCCTCCTGAAATAACCATAGGAGGTCCAGCCTGCCCAGTGACAAAGTTAAACGGCCGCGGTACCCTAACCGTGCGAAGGTAGCGCAATCACTTGTTCTTTAAATGAGGACTAGTATGAATGGCATCACGAGGGTTATACTGTCTCCCTCTTTTAATCAGTGAAACTGATCTTCCCGTGAAGAAGCGGGAATACATCTATAAGACGAGAAGACCCCATGGAGCTTTAAACTCAGTATCAACTGCCCTCCCAATATATCCACCTAATTAAGCAGACATGACTACTAGTTTTCGGTTGGGGTGACCGCGGAGCAAAACAAAACCTCCACGATGAAAGGAATTAACCTCCTAATCAAAGAGCTACATCTCTAAGAATCAACAAATTGACATTTATTGATCCAATTTTTTGATCAACGAACCAAGTTACCCTGGGGATAACAGCGCAATCCATTTCAAGAGCCCCTATCGACAAATGGGTTTACGACCTCGATGTTGGATCAGGGTATCCCAGTGGTGCAGCCGCTACTAAAGGTTCGTTTGTTCAACGATTAAAACCCT
->URS00018C7DE1 rRNA from 1 species 
-TACGTAGGGTCCAAGCGTTGTCCGGATTTATTGGGCGTAAAGAGCTCGTAGGCGGTTCGGTAAGTCGGATGTGAAAACTCAGGCTCAACCCGGAGACGCCATCCGATACTGCTGTGACTTAGTCTGGTAGGGGAACACGGAATACCTGGTGTAGCGGTGAAATGCGTAGATATCGGAAGGAACACCAGTGGCGAAGGCGACTTCCTGGCTCATTACTGACACTGAGGCGCGAAAGCGTGGGGAGCGAACAGG
->URS0001E9E6F4 misc_RNA from 1 species 
-GATGAAGAACGTAGCGAAATGCGATACGTAATGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCATATTGCGCTCTCTGGTATTCCGGAGAGCATGCTTGTTTGAGTATCAGTAAACACCTCAACTTCCATATCTTTTTTGAAATGGGAGTTGGACTTGAGTGATCCCAACGCTTTTCCTCACCGAAAAGTGGCGGGTTACTTGAAATGCAGGTGCAGCTGGACTTTTCTCTGAGCTATAAGCATATCTATTTAGTCTGCCTAAAAAACAGAATATTACCTTTGCTGCAGCTAACATAAAGGAGATTAGTTCTTGTGCTGACTGATGCAGGATTCACAAAGACGGCTTCGGCCGACTTTGTAAACTCGATCTCAAATCAAGTAAGACTACCCGCTGAACTTAAGCATATCAATAAGCGGAGGA
->URS000057C40D tRNA from 1 species 
-ATTATTTTGGCAGATTAGTGCATTAAATTTAGAATTTAATTATGTAAAATAAATTACAAATAATAC
->URS0001919D12 rRNA from 1 species 
-TACGGAGGGAGCTAGCGTTATTCGGAATTACTGGGCGTAAAGCGTACGTAGGCGGCTTTGTAAGTAAGAGGTGAAAGCCCGGAGCTCAACTCCGGAACTGCCTTTTAGACTGCATCGCTTGAATCCAGGAGAGGTGAGTGGAATTCCGAGTGTAGAGGTGAAATTCGTAGATATTCGGAAGAAACACCAGTGGCGAAGGCGGCTCACTGGACTGGTATTGACGCTGAGGTACGGAAAGCATGGGGAGCAAACAGGG
->URS000239B5F5 lncRNA from 1 species 
-GGAAAAGGAGACAGGGAGTTCTGAGGTTATCCACTGCCATGGAGCCATCACTTTTGGCCAATTGTTGAGATGGAATCCAAGACCAGGAGAACGGTACACAATGATGTTGCAAGCATTGCACTTCGTTTTTACCTCAGAGATGCTCGGCATACAACGGAGACATGGCCTGTCCATCATGGAGAAAGTTCTTTCTCCGTGAGACCCAGGCG
->URS000017EE1C rRNA from 1 species 
-CAGCAGGTCACGCAATTACCCACTACCCGGCACGGGGAAGGTAGTGACAAAAATAACGATACGGGACTCATATGAGGCCCCGTAATCGGAATGAGTACACTTTAAATCCTTTAACAAGGATCCATTGGAGGGCAAGTCTGGTGCCAGCAGCCGCGGTAATTCCAGCTCCAATAGCGTATATTAAAGTTGTTGCGGTTAAAAAGCTCGTAGTTGGTTCTGCGTGCTACGCTGTCGGTTCGCCGCCTGCCGGTGTAACTGGCATGCCGTGGCATGTCCTGTCGGTGGTGTTCGGGAGCCTCGTCTAGGTGGTGCCCTCGGACCGCAAGGTACGAGGTGTTCACAGGCCGGAGGTCCCCCCGTTCGCCTACTCTATCCTACCTAGGTGCTCTTCACCGAGTGTCGAGGTAGGCCGACACGTTTACTTTGAACAAATTAGAGTGCTCAAAGCAGGCTGAAATTTCTGCCTGAATAGTGGTGCATGGAATAATAAAACAGGACCTCGGTTCTATTTTGTTGGTTCTTAGGAACACGAGGTAATGATCAATACGGACAGGCGGGGGCATTCGTATTGCGACGTTAGACTTGGCAAATGCTTTCGCGGTGAAATTCTTGGATCGTCGCAAGACGCACAAGAGCGAAAGCATTTGCCAAGTATGTCTTGATTGATCAAGAACGAAAGTTAGAGGTTCGAAGGCGATCAGATACCGCCCTAGTTCTAACCATAAACGATGCCAGCCAGCGATCCGCCGATGTTCCTCCGATGACTCGGCGGGGAGCTTTTTCCCGGGAAACCAAAGCTTTTGGGTTCCCGGGGGAAGTATGGTTGCAAAGCTGAAACTTAAAGGAATTGACGGAAGGGCACCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGAAACCTCACCAGGCCAGGACATTGGAAGGATTGACAGATTGATAGCTCTTTCTTGATTCAGTGGGTAGTGGTGCATGGCCGTTCTTAGTTGGTGGATCGATTTGTCTGGTTAATTCCGATAACGAACGAGACTCTAGCTTATTAACTAGGCGTTTTCCGGTGCCCTCGTCACCGGCGACACTCATTCTTCTTAAGGGGACAAGCGGCTTATAGCCGCACGAGATTGAGCAATAACAGGTCTGTGATGCCCTTAGATGTCCTGGGCCGCACGCGCGCTACACTGAAAGAATCAGCGTGTGCCTCCCTGGCCGAAAGGCCCGGGTAATCCGCTGAACCTCTTGCGTGCTAGGAATTGGGGCTTGCAATTGTTCCCCATGAACGAGGAATTCCCAGTAAGCGCGAGTCATAAGCTCGCGTTGATTACGTCCCTGCCCTTTGTACACACCGCCCGTCGCTACTACCGATTGAATGATTTAGTGAGGTCTTCGGACTGGCGGTAATCCCTATCGACTTGTCGGTATCGATGAACGCTGGAAAGATGACCAAACTTGATCATTTAGAGGAAGT
->URS000219C8A1 lncRNA from 1 species 
-ACTGCCTCAACTGTTCGCTCAATGATTTCTGGACCCAAAATTCTGTTTTCCCCGACTTCATCCCAATGGATAGGGGATCTGCACTTTCTACCATAAAGAGCTTCATACGGGGCCATTCCTATAGTGGCCTGAAAACTATTGTTGTAAGCAAACTCCACTAACGGCAGGTGTGTCTCCCAACTACCTCCAAGATCCAAAACACATGCCCTTAGCATATCTTCCAAAGTTTGGATGGTTCTTTCTGATTGTCCATCCGTCTGAGGATGATAAGCTGTGCTAAACTTCAGTTTTGTCCCCATGGCTGTCTGCAAACTTTTCCAAAATTTAGATGTGAACCTCGGGTCTCTATCTGAAACAATGGTGACTGGGACTCCATGCAACCTGACTATCTCCTTGATGTATAAGTGTGCCAGCTGTTCCAAGTTAAAGTTTACTTTAATTGGAAGAAAATGGGCTGACTTCGTCAGACGATCCACCACTACCCAGATAGCATTGTGACCTTTTGCTGATCTCGGGAGGCCTACCACAAAGTCCATCGTTATGTGTTCCCATTTCCATTCTGGAATATCCAACGGTTTCAGTAATCCTGATGGCCTTTGATGTTCTGCCTTAACCTGTTGACAGATAATACATCTCTCCACGAACAGACCAATTCCTCTCTTCATGTTTCTCCACCAAAATACATCCCGGAGATCTCGGTACATTTTCGTACCACCTGGATGAGCAGAATAAGGGGTTGAATGAGCCTCTTCTAATATCTCATTTCTTATACTTTCATCCTTAGGTACACACAGTCTTCCTTTGAAAGTTAGCGCATTATCTGCAGATACTTCAAACCCTATATGTTTATCTGTACCAATCTCGGCCTTTATCTTCTGTAAAAATGGATCTTTATCCTGTGCCTCCTTGATTCGATCTCGAAGTGTAGGTTGAATCATGAATGCTCTTATTCTCGCTGAAATCTGAGTTGGCGGCGTGATAACTTCCAATCTCAATTTATCAAACTCCCTTATCAAGTGTTCCTGTACTGTGGGTAAAACTGCTAACTGTGTTCCTGTCTTTCTGCTTAGGGCATCTGCAACTACATTAGCCTTACCCGGATGGTAATGAATTGTGCAGTCATAATCCTTCACTAACTCCAACCATCTCCTCTGTCTCATATTTAGTTCCTTCTGTGTGAAAAAGTATTTGAGACTCTTGTGGTCCGTATAAATTTCACACTTCCCACCGTAAAGATAATGACGCCATATCTTTAAGGCGTGAACAACTGCTGCAAGCTCCAAGT
->URS0000884EE1 rRNA from 15 species 
-GGCGTGCTTAACACATGCAAGTCGAACGGAAAGGCCCTGCTTTTGTGGGGTGCTCGAGTGGCGAACGGGTGAGTAACACGTGAGTAACCTGCCCTTGACTTTGGGATAACTTCAGGAAACTGGGGCTAATACCGGATAGGAGCTCCTGCTGCATGGTGGGGGTTGGAAAGTTTCGGCGGTTGGGGATGGACTCGCGGCTTATCAGCTTGTTGGTGGGGTAGTGGCTTACCAAGGCTTTGACGGGTAGCCGGCCTGAGAGGGTGACCGGCCACATTGGGACTGAGATACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGGAAGCCTGATGCAGCAACGCCGCGTGCGGGATGACGGCCTTCGGGTTGTAAACCGCTTTCGCCTGTGACGAAGCGTGAGTGACGGTAATGGGTAAAGAAGCACCGGCTAACTACGTGCCAGCAGCCGCGGTGATACGTAGGGTGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGGGCTCGTAGGTGGTTGATCGCGTCGGAAGTGTAATCTTGGGGCTTAACCCTGAGCGTGCTTTCGATACGGGTTGACTTGAGGAAGGTAGGGGAGAATGGAATTCCTGGTGGAGCGGTGGAATGCGCAGATATCAGGAGGAACACCAGTGGCGAAGGCGGTTCTCTGGGCCTTTCCTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGGCTTAGATACCCTGGTAGTCCACGCTGTAAACGGTGGGTACTAGGTGTGGGGTCCATTCCACGGGTTCCGTGCCGTAGCTAACGCTTTAAGTACCCCGCCTGGGGAGTACGGCCGCAAGGCTAAAACTCAAAGGAATTGACGGGGCCCCGCACAAGCGGCGGAGCATGCGGATTAATTCGATGCAACGCGTAGAACCTTACCTGGGTTTGACATGGATCGGGAGTGCTCAGAGATGGGTGTGCCTCTTTTGGGGTCGGTTCACAGGTGGTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTTCACTGTTGCCAGCACGTTATGGTGGGGACTCAGTGGAGACCGCCGGGGTCAACTCGGAGGAAGGTGGGGATGACGTCAAGTCATCATGCCCCTTATGTCCAGGGCTTCACGCATGCTACAATGGCTGGTACAGAGAGTGGCGAGCCTGTGAGGGTGAGCGAATCTCGGAAAGCCGGTCTCAGTTCGGATTGGGGTCTGCAACTCGACCTCATGAAGTCGGAGTCGCTAGTAATCGCAGATCAGCAACGCTGCGGTGAATACGTTCCCGGGGCTTGTACACACCGCCCGTCAAGTCATGAAAGTTGGTAACACCCGAAGCCGGTGGCCTAACCGTTGTGGGGGAGCCGTCGAAGGTGGGACTGGTGATT
->URS0000B9E3AC rRNA from 1 species 
-GCGCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCGACGCCGCGTGAGTGAAGAAGTATTTCGGTATGTAAAGCTCTATCAGCAGGGAGGAAGAAGGACGGTACCTGAGTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGTAGACGGCGAAGAAAGTCTGAAGTGAAAGCCCGCG
->URS000252BD60 tRNA from 1 species 
-GATAAGATGGCAGAGAGTTAAGTGCATTAGATTGTAAATTTAATAATGAGGGTTAGATTCCTTTTCTTATTA
->URS000022CE74 rRNA from 1 species 
-TTCGGGGTGAGTGGCAGACGGGTGAGTAACGCGTGGGAACGTGCCCTTCAGTTCGGGATAACCCAGGGAAACTTGGGCTAATACCGGATAAGCCCTTACGGGGAAAGATTTATCGCCAAAGGATCGGCCCGCGTCTGATTAGCTAGTTGGTGGGGTAATGGCCCACCAAGGCTACGATCAGTAGCTGGTCTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTTAGGAATCTTGGACAATGGGCGCAAGCCTGACGACGCAACGCCGCGTGGAGGACGAAGATTTTCGGA
->URS00001AC001 rRNA from 1 species 
-CGTACTCCTACGGGGAGGCAGCAGTGGGGAATATTGCACAATCGGGGGAAACCCTGATGCAGCCATGCCGCGTGTGTGAAGAAGGCCTTCGGGTGTAAAGCACTTTCAGTAGGGAGGAAGGTAGTGTAGTTAACACCTGCATTATTTGACGTTACCTACAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGCATGCAGGCGGCCTGTTAAGTCAGATGTGAAAGCCCGGGGCTTAACCTCGGAATTGCATTTGAAACTGGCAGGCTAGAGTCTTGTAGAGGGGGGTAGGAATTTCAGGTGTAGCGGTGAAATGCGTAGAGATCTGAAGGAATACCAGTGGCGAAGGCGGCCCCCTGGACAAAGACTGACGCTCAGATGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAG
->URS000182260B rRNA from 1 species 
-ATACGTAGGTGACAAGCGTTATCCGGATTTACTGGGCGTAAAGGGCGTGTAGGCGGTCTTGCAAGTCAGAAGTGAAATTCCTGAGCTCAACTCGGGCGCTGCTTCTGAAACTGCAGGACTTGAGTGCTGGAGGGGATAGCGGAATTCCTAGTGGAGCGGTAAAATGCGCAGATATTAGGAAGAACACCGGTGGCGAAGGCGGCTATCTGGACAGTAACTGACGCTGAGGCGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCAGGTAGTCCACGCCGTAAACGATGAATACTAGGTGTAGGGGGTATCGACTCCCTCTGTGCCGCAGTTAACACAATAAGTATTCCGCCTGGGGAGTACGGCCGCAAGATTAAAACTCAAAGGAATTGACGGGG
->URS000010CDEA rRNA from 1 species 
-TAGGCCTAACACATGCAAGTCGAACGGCAGCGCGGGTGCTTGCACCTGGCGGCGAAAGGCGAACGGGTGAGTAATACATCGGAACGTGCCCTAGAGTGGGGGATAACTAGTCGAAAGATTAGCTAATACCGCATACGATCTACGGATGAAAGTGGGGGACCGCAAGGCCTCATGCTCCTGGAGCGGCCGATGTCTGATTAGCTAGTTGGTGGGGTAAAAGCCTACCAAGGCGACGATCAGTAGCTGGTCTGAGAGGACGACCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGAATTTTGGACAATGGGGGCAACCCTGATCCAGCAAAGCCGCGTGTGTGAAGAAGGCCTTCGGGTT
->URS000217ECBF lncRNA from 1 species 
-GGATGTTAAGAGAAGGGGTTGTTTAAGATAAAAGATAAATTCTATATTGATGTAAGTTAAATTTAAAATACTGATGGACTATCCAAGGTGAAGATGTCAAGTAGGTATTTGGGGAAATAGCAATCAAGTGCAAGAGACAGGGAATTTTCTTTTGGAACAATGAGAATTCTCCAAGCTTCCTCAACAGACAACTGGAAGTGGCAGCAAAGAGGCAGTGGAAAAGCAGCAGAATGGCAGTAGAATGGCAACAGCTGCACTGGGATCAGAGGCTGCACTGGGATCAGGGGCTGTGCTTAGATCGTGCTGAGTCATTGCTGGTGTTGGACGGAGTGACAGCGCGGAGGAGGATTACGTGTGCCAACTGCTGGATTTCCCAAGTTTGCCTGCCCTTGCCTAGGTGCGAGCTGAGGTGTGTGAGTGTCGGGGACTGATGGGTTTGGGGAGGCCTCAGCCCGGACGGCCCTCCGCGATCTGGGTCTGAAAACACGAGCCCCCGTCTCTTAGGAGGCGCGGGAAGGAAGGTACATGATAACTTCTGTAAAGAAAGATGGGATCAGACTTATGTTGAAAAAGGAAGCTGGTAAAATTCTCTGCTAGTGATTCATGTACCACTATGAAGCATTTGAGTCAATGGTTATGGATCTCAATCGACTCCACCATTTTCCAGGTCTCAGAACGGCTAGCGATTGGATGAACATTCTTTGATGTAACTGTTCTATTAATTCATTATATTAGTGGTGTAAAACTTTCTGGTTCTTGTTTGATCCAACTTTTATTTTCATTGTCCATTATTTTATTGTCCATGAAGATGACAAAACCTTTTCTACATTTTTCTGGCTTCAGAACTTCTCTTACCTCTGATTGCTTTGACTCTAAAGATGCTATAATAAAATTACTGATTGATATTCAACTG
->URS00016BEEAD rRNA from 1 species 
-TACGAAGGGTGCAAGCGTTACTCGGAATTACTGGGCGTAAAGCGTGCGTAGGTGGTTTGTTAAGTCTGTTGTGAAAGCCCCGGGCTCAACCTGGGAATGGCAATGGATACTGGCAAGCTAGAGTGCGGTAGAGGGTAGTGGAATTCCCGGTGTAGCGGTGAAATGCGTAGAGATCGGGAGGAACACCAGTGGCGAAGGCGGCTACCTGGGATGACACTGACGCTCATACACGAAAGCGTGGGGAGCAAACAGG
->URS00011B15C7 rRNA from 1 species 
-CCCTTAGATGTCCTGGGCCGCACGCGTGCTACACCGATGCATACAGCGAGTACTTTCCAGCTCCGCGAGGCAGCTGGTAATCAGCAATATGCATCGTGCTGGGGATAGATCTTTGGAATTATAGATCTTGAACGAGGAATTCCTAGTAAGCGCAAGTCATTAGCTTGCGCTGATTAAGTCCCTGCCCTTTGTACACACCGCCCGTCGCTCCTACCGATTTCGAGTGATTCGGTGAACCTTTTGGACAGCGTCTGTCCTCGTGTCAGATGCTGAAAGTCAAGTAAACCATATCACTTAGAGGAAGGAGAAGTCGTAACA
->URS000170A9F1 rRNA from 1 species 
-AACGAACGCTGGCGGTAGGCTTAACACATGCAAGTCGAGCGCCCCGCAAGGGGAGCGGCAGACGGGTGAGTAACGCGTGGGAACATACCCTTTTCTACGGAATAGCTCGGGGAAACTGGAATTAATACCGTATACGCCCTACGGGGGACAGATTTATCGGGGAAGGATTGGCCCGCGTTGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCAATAGCTGGTCTGAGAGGATGATCAGCCACATTGGGACTGAGACACGGCCCAAACTTCTACGGGAGGCAGCAGTGGGGAGTATTGGACAATGGGCGCAAGCCTGATCCAGCCATGCCGCTTGAATGATGAAGGCCTTAGGGTTGTAAAGCTCTGTCACCGGAGAAGATAATGACGGTATCCGGAGAAGAAGCCCCGGCTAACTTCGTGCCAGCAGCCGCAGTAATAC
->URS00021A8CBE lncRNA from 1 species 
-AATCATTTTGTTGTACAAGTCAGCATGAGTTATCAAAAGGACATGAAGGCACCCTAACATTATGGAAACAAAAATTTAAAAAATTTGCTGATTTAGTATGCTGGTATATAGATGTATGAATAAAAGTGCTCACATGGTCAGTTTTGGTCTACACTGTCAAATAATTTTGTTGCACAAGTCAGCAAGAGGTATCAAAACTACTGAAATTTTGTTACGTATCAATATTTTGAATAAAAGGAGGACATATGCTGGCACCCTAAATTTA
->URS00020CA31D rRNA from 1 species 
-GATGAACGCTAGCGATAGGCTTAACACATGCAAGTCGAGGGGTAACGTGTTGGAAGCTTGCTTCCGATGACGACGACCGGCGGATGGGTGCGTAACGCGTATGCAACTTGCCTCACAGTGGAGAATAACCCGGAGAAATCCGGACTAATACTCCATACACTCTTAAGTACGCCTGTACATGAGAGGAAAGATTTATCGCTGTGAGATAGGCATGCGTCCTATTAGGTAGTTGGTGAGGTAACGGCTCACCAAGCCGACGATAGGTAGGGGTGCTGAGAGGCAGATCCCCCACATTGGGACTGAGACACGGCACAAACTCCTACGGGAGGCAGCAGTGAGGAATATTGGTCAATGGAGGAAACTCTGAACCAGCCAAGTCGCGTGAAGGAAGAATGTCCTAAGGATTGTAAACTTCTTTAGCGAGCGAGTAAGGACTTCCACGTGATGGGAGTTTGAAAGTAGCTCGAGAATAAGTATCGGCTAACTCCGTG
->URS0002179DC9 lncRNA from 1 species 
-ATTACTTTGTTTAGAAAAATTAACATTTTTCTGGTTATGATGTAAGACACACAAATAGCTACTTTGATTTTTATTTAACAAATACATGAACCATTCCCCATGCTCCGAATAAGTCATCATGAGTCTATAAAATCTTGTAACTTTTTTTAATGGTACTTGAGACAGTTTACATTGTTTTATAGAACAAAATACAATACTTCTAATTCTCCTCATACTGCCTTTCAACTCTACGGTGAGAGCTGTGCATAAAAACATAGCAGCTTGGGTAGCTCATGGGTTGCAACATAATCTCCGCATTGGGTTGGGCTGGGGGATGGCAAGGAAGGCATTCTAAGATATAAGTTCTGAGAATAAAGAAACAGAGATTTCCCTCAAGAAAATTTATACTTGTCTCCTTTATAAGCACAGGTCCCATACAAAAAGTATTATCACTGAATTGCTCTGTCTGACTTATAAGCTATAATTAAGATTCCAGTCTGATGTGGAGCAGCTTAAAATAGCATCACACACCCTGTTGATTCTTGCCTAGTTGAAACAGAAACATAAATTTGAGGGAAGAAGGTGGAAATGATTATTATCAATTCCCCTTTAATAATACTGATATAGGTATCCATGGGCACAGAAAATTAAGTAAAGTAAGTATTCCAAATTATCTCCCTCTTCAAATCGCTTATACCTGATTTTGGCTGGGCAGAGATTTACTAATAAGGAGGTGAGGGTTTACTTCCAGGAAAAGCTATAATAGTGAGACAGAAGTTCAGGGCAGAGCAAGCACCAAATATAGGGCAGTACAGATAGTGACCTGCTTGGGACCTAGGAACTAGGTAGCATGTGGAGTAGCAGGAGGAGAGCCTAGAAGACAAGCGCTTGACCAGTAAAGTGAGAAGACCTGCTCAATTTAGAGAAGGATTTGCAAGTAAGAAACAGAACATTTCTTGAGTATTTACCTAATTCTAGGTTGATACTAGGTACACTTCATTTAAACCTAACTTTAAAAAGTCAGAAATATCCATCATTTCACCAATTCACTCATATGGAAACTGAAGCTATGAGGTTCCCTACCATAAATCCCACATAATGAAGCTGGGACTCAAACGCCCGCATAATTTAAAACTTTGTGCCCTTTTATGCTAAC
->URS00012349DE rRNA from 1 species 
-CAGCAGCCGCGGTAATACGTAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGTGCGCAGGCGGTTTTGTAAGACAGAGGTGAAATCCCCGGGCTCAACCTGGGAACTGCCTTTGTGACTGCAAGGCTAGAGTACGGCAGAGGGGGATGGAATTCCGCGTGTAGCAGTGAAATGCGTAGATATGCGGAGGAACACCGATGGCGAAGGCAATCCCCTGGGCCTGTACTGACGCTCATGCACGAAAGCGTGGGGAGCAAACAGGATTAGAGACCCCAGTAGTCCCTGTCTCTTATAC
->URS0000B93F3B rRNA from 1 species 
-TGAGCCTACGGGGGGCAGCAGTGGGGAATATTGCACAATGGGGGGAACCCTGATGCAGCGACGCCGCGTGAGTGAAGAAGTATTTCGGTATGTAAATCTCTATCAGCAGGGAAGAAGATGACGGTACCTGACTAAGAAGCCCCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGGGGCAAGCGTTATCCGGATTTATTGGGTTTAAAGGGTGCGTAGGCGGACAGTCAAGTCAGCGGTAAAAATGCGGTGCTCAACCCCGTACTGCCGTTGAAACTGCATCCCTTGAGTGCGCGAGAAG
->URS0000854D01 rRNA from 1 species 
-AGAGTTTGATCATGGCTCAGATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAACGGTAACAGGAAGCAGCTTGCTGCTTTGCTGACGAGTGGCGGACGGGTGAGTAATGTCTGGGAAACTGCCTGATGGAGGGGGATAACTACTGGAAACGGTAGCTAATACCGCATAATGTCGCAAGACCAAAGAGGGGGACCTTCGGGCCTCTTGCCATCGGATGTGCCCAGATGGGATTAGCTAGTAGGTGGGGTAAAGGCTCACCTAGGCGACGATCCCTAGCTGGTCTGAGAGGATGACCAGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGCACAATGGGCGCAAGCCTGATGCAGCCATGCCGCGTGTATGAAGAAGGTCTTCGGGTTGTAAAGTACTTTCAGCGGGGAGGAAGGGAGTAAAGTTAATACCTTTGCTCATTGACGTTACCCGCAGAAGAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTAATCGGAATTACTGGGCGTAAAGCGCACGCAGGCGGTTTGTTAAGTCAGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCATCTGATACTGGCAAGCTTGAGTCTCGTAGAGGGGGGTAGAATTCCAGGTGTAGCGGTGAAATGCGTAGAGATCTGGAGGAATACCGGTGGCGAAGGCGGCCCCCTGGACGAAGACTGACGCTCAGGTGCGAAAGCGTGGGGAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGTCGACTTGGAGGTTGTGCCCTTGAGGCGTGGCTTCCGGAGCTAACGCGTTAAGTCGACCGCCTGGGGAGTACGGCCGCAAGGTTAAAACTCAAATGAATTGACGGGGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTGGTCTTGACATCCACGGAAGTTTTCAGAGATGAGAATGTGCCTTCGGGAACCGTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTCCGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGACCAGGGCTACACACGTGCTACAATGGCGCATACAAAGAGAAGCGATCTCGCGAGAGCAAGCGGACCTCATAAAGTGCGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTGGATCAGAATGCCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGGTTGCAAAAGAAGTAGGTAGCTTAACCTTCGGGAGGGCGCTTACCACTTTGTGATTCATGACTGGGGTGAAGTCGTAACAAGGTAACCGTAGGGGAACCTGCGGTTGGATCACCT
->URS0001C3A371 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACGGACGAGAAGCTTGCTTCTCTGATGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTGCCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATGATATTTTGAACCGCATGGTTCAAAAGTGAAAGACGGTCTTGCTGTCACTTATAGATGGATCCGCGCTGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCATAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACCCCTACGGGAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAACTCTGTTATTAGGGAAGAACATATGTGTAAGTAACTGTGCACATCTTGACGGTACCTAATCAGAAAGCCACGGCTAACTACGTG
->URS0001B15B4F rRNA from 1 species 
-CCTGGTTGTTCCTGCCAGTAGTCATATGCTTGTCTCAAAGATTAAGCCATGCATGTGTAAGTATGAATAAATTCAGACTGTGAAACTACAAATGGCTCATTAAATCAGTTATAGTTTGTTTGATGGTATCTACTACTCAGATAACTATAGTAATTCTAGAGCTAATACATGCAACAAACCCCGACTTCTGGAAGAGATGCATTTATTAGATAAAAGGTCGATGCGGGCTCTGCCCGTTGCTACGAGGATTCATGATAACTCGACGGATCGTACGACCATCGTACCGGCGATGCATCATTCAAATTTCTGCCCTATCAACTTTCGATGGTAGGATAGTGGCCTACCATGGTGGTGACGGGTGATGGAGAATTAGGGTTCGATTCCAGAGAGGGAGCCTGAGAAACGGCTACCATATCCAAGGAAGGCAGCAGACGCGTAAACTACCCAATCGTAGTTGCACTTTGGGATGGGCCGGCTGGTCCGCCTATGGTGCGCACCGATCGTCTCATCCTTTCTGTCGGCGATGCGCTCCTGGCCTTAACTGGTCGGGTCCGGTGCTGTTACTATGAAGAAATTAGAGTTCTCAAAGCAAGCCTACGCTCTGTATACATTAGCATGGGATAACATTATAGGATTTCGGTCCTATTACGTTGGCCTTCGGGATCGGAGTAATGATTAACAGGGACAGTCGGGGGCATTCGTATTTCATAGTCAGAGGTGAAATTCTTGGATTTATGAAAGACGAACAACTGCGAANCTGCGAAAGCATTTACCAAGGATTTTTTCATTAATCAAGATCGAAATTTTGGGGCTCGAAGGCGATTAGATACCGTCCTAGTCTCAACCATAAACGATGTCGACCAGGGATCAGCGGATGTTGCTTTTAGGAATCCACCGGCACCTTATGAGAAATCAAAGTTTTTGGGTTACGGCGGGAGTTTGGTCGCAAGGCTAAAACTTAAAGGAATTGACGGAAGGGCTCCACCAGGAGTGGAGCCTGCGGCTTAATTTGACTCAACACGGGGAAACTTACCAGGTCCAGACATAGTAAGGATTGACAGACTGAGAGCTCTTTCTTGATTCTATGGGTGGTGGTGCATGGCCGTTCTTAGTTGGTGGAGCGATTTGTCTGGTNGATGGCTGTTCTTAGTTGGTAGAGCGATTTTTCTGGTTAATTTCGTTAACGAACGAGACCTCAGCCTGCTAACTAGCTATGCGGAGGTATCCCTTCGCGGCCAGCTTCTTAGAGGGACTACGGCCTTTTAGGCCGTGGATGTTTGAGGAAATAATAGGTCTGTGATGCCCTTAGATGTTCTGGGCTGCACGTGCACTACACTGATGTATTCAACGAGTTTATAGCCTTGGCCGACAAGCTCGGGTAATCTTTGAAATTTCATCGTGATGGGGATAGATCATTGCAATTGTTGGTCTTCAACGAGGAATTCCTAGTAAGCGCGAGTAATCAGCTCGCGTCGACTACGTCCCTGGGCTTTGTACACACCACCCATCGCTCCTACCGATTGATTGATCCAGTGAAATGTTTGGATCACGTCGACGTGGGTGGTTTGCTGCCCGCGACGTCCCGAGAAGTCTATTGAACCTTATCATTTAGAGGAAGGAGAAGTCGTAACAAGGTTTCCGTCGGTGAACCTGCGAAAG
->URS0002562826 rRNA from 1 species 
-ATGCCACCTGTTCAGGGAAATGGGCAAGCCCTAAACGGCAACAGTCAGCAATCTTCTCAGCAATTTCCAACGCCAATCTTGTGGCAGCCAACCAGCAACCACTCAATGCAACATGGCGAAGGATGTAGTCTGCCACCACCTAGCATGCCGAATCCATTGCCAGTAGCAGTTCCAGGATATTATCCACCTTTACCTGCTTTTGGACAGGACCACTGCACTAGTTTACCTAATGCAAGTTCTCAACTTGAATTTCGGAACTTCCCAGCGTACATGCCGTTTAATGATATTCCCCAGGGGAATTCCATTCTTGGATGGGAAGAATTTGTTGAAGATGTAAGTCATTCAAATGTCCGGCCACCAGTTGAAGAGCATTATGTAGATGCGTCATTTAGATGTAATCAAGTGCTACTTCAATGGGATGAGCCTCATATGGAGGTCAAGAAACGTTGGAACTTTCTTGATCAGCTCATGCCGCTGTATAGCACACAATCAGGGTTTTATAAAGAAGATTTCCCCAGTACGAGCCTCATGGATAAAACCCATAAGTTACTGGCCAGTATTTCATCAGACGATTCTGTTTGGAAGATAATTACCAGTGTTACGAGTCGAGCCACACAAACTCCTCAGAGGAGAGGTGTTCTCATTCGGCCCATTGAGCCATATGATTCAGATGATGGGCCACCAATTAAGAAGCAAAGGACCAAATATCAATTGCGATTTGTCAATACGGTGTGCAATGACTACTTCACACGGGAGAATATCAAATCAGAGGATGGAAATCTCTTAAAGGTGGCTTTGTATGATGAGAACAATCTGGTTGTCACATCTGGTCCGCTGTCTGCAGCTTTTGTGGAGATCGTACTACTTCATGGTGATTTCAATGCTGAAGGTCAAGATTATTGGACATCAGAGGAGTTTAGTGACTGCCTAGTGCATCCACAATCTGTAAAAGAACCACCAGCCTTGGGAGGTGATCGTGTCTTGACACTGACTGATGGAGAAGCAGACCTTGGTAATGTCTATTTCCGAACTTCCTCCTTCCATGCTAGAACTGAAAAGTTCAAGATGGGTGTTGAGATTAAAAATGTAAGAGAAGAGTGTGTTCAAGAAGGAATCACTAGCCCTTTTTTTGTGAGAGTTCGCCAAGGGGAAGAATCAATTGGCCAATGGATCACATCCCTCAAAGCATCGCTCAGAGTGAGCAAACAAGTCCCCCCGCTGGAGTGCGATGCTAGGAAATACGTCGACGCATTAGCAGTTAAAATGAGCACGGAGGAAAAATTCAAAACTGGAAAGCTTAAGGTAAAAAGGGAAAAAGATAAGAACAAATATGAGGAAGATCTCAGAATACTCATGGAAGACCACCAAGAGTTCACATTAAAAACCGAAGATATGCGAAAGGAAGGGCGTGCTGAGTTAAATCATTACATTCTATCTCCACCTCAGAGATCAATGGTTATCCAATCAACAAGATTTCGTCTAGTAATTGAAAATAGTGTGAGCAGAACAATTTACAAAAATAGTACTGTAAAGACCGAGGATGGCGGAGATCACATAAAAGTTGTCATGTACGATGGTGGCAAGCCAATTGCATTTGACCACCCTCTTGCTTCAATAACAGTTGACCTAGTTATCATTGAAGGAGGGTTCGATGAAAAGCGAGATTCGTGGTCTAAAGAGGAGTTTGAGGAAAGCATAATAGAACCAAGAAAAGGAATCAAAAGGCTAGTGAAAAATGGTACATTTGATTTGATTGATGGGAGGTGTGATCATCATGGTGCCATTATTATGGACAATTCACTACGAATGGAAGTTAAACTTGGAGTAAGGATCGCAGTGCATACAGACATAAGAGTTATTGAAGGGGTATCAAATCCTTTCAAAATGAAGGAAGTCCGGACAAGAGTACATGGAAAGAGTACTATTCCATACAAGGACGACGCGGTACATCGACTGAAGAAAATTGCCCTGAAGGGAAAACATTGGAACAATCTTGAGGATCAATATATTACCAAAGTGAAGCACTTGTTGCGCCATTATCACAAAGATAAATTTGGTCTCCAAAAGCTTGTTGACATGAAGAAAGAGGATTGGAATACCATGATTAATCATGCCACCATGTGTGTTCCTGGGGATGAGATCTATTCCTACTGTGTTCAAGAGGATAACTGTGAAATCCTATTCAATGATTTCTATGATCTTGTCGGTAAGATCACTGATGACTATGTTCCGTACAGTGTCAATGACGTCGATCAGTTTCCGCAGCTTAAAGTGAACAACTGGAAAAAGTCTGCGTATAAGAAGTTTGACGAGAGGGAGAACTCAGGGCTCTTTGGTCTTACTCCTGATTACTTCATGAACAATGGCCGCCCAGTCCGTGCAGCGCCCCTGAACAATGACGCAGGTCCTACTGTACAAGCATCTACATGGCAATATCCTAATGACAGGGCTGCACAACACGGCCTTAATAGAAGTGCAGTCTGCCAATACACAGATGCCTGGAGTCCGGCTTCTAAAAATACCAATCAAAATAATGTGATTCCTCCAACGACGACAGCAGATGGGAATGGGATGCTTGGGTCACTGACAATGGGGACAAGCAGCACCAGCGACATGAAGAAGAGCATGATGGAGGACGTTGCCAATGGTCTCTTCAATTGA
->URS0000051310 piRNA from 1 species 
-CAGGTCTTGTTTTAGTTGGACGAGGA
->URS0000A621CB tRNA from 1 species 
-AAAATGCCAGCTTTGGGAGTTGGTGATGAAGGTTCGACTCCTTTCTTTCTGA
->URS000113D973 rRNA from 1 species 
-TACAGAGGGTGCAAGCGTTGTTCGGAATCATTGGGCGTAAAGGGCGTGTAGGCGGTTTGGTAAGTCATGTGTGAAATCCCTCGGCTCAACCGGGGAACGACGCATGAAACTGGCAAGCTAGAGTACCAAAGAGGGCGGTGGAATTCCCGGTGTAGCGGTGAAATTCGTAGATATCGGGAGGAACACCAGTGGCGAAGGCGGCGATCTGGACGGATATTGACGCTGATGTACGAAAGCGTGGGGAGCAAACAGG
->URS00001901B3 rRNA from 1 species 
-TTAAAAGCTCGTAGTTGGATTTCTGGCAGGAGCGACCGGTCCGCCGCAAGGTGTGCACTAGGTCGTCTCCAGTCATCTTTGTGGGAACTGCTCTGGCATTAGGTTGTCGGGGTTAGGGAACACATCGTTTACTGTGAAAAAATTAGAGTGTTTAAAGCAGGCTTATGCCGTTGAATACATTAGCATGGAATAATAAGATAGGACTTTGGTGGTCTATTTTGTTGGTTTGCACACCAAGGTAATGATTAATAGGGATAGTTGGGGGTATTCGTATTTAATTGTCAGAGGTGAAACTCCCTTGGATTTATGAAAGACGAACTACTGCGAAAGCATTTACCAAAGATGTTTTCAGGGTAATCAAGAACGAAAGTTAGGGGATCGAAGATGATTAGATACCATCGTAGTCTTAACCATAAACTATGCCGACTAGGGATTGGTGGTCCGTTCATTATGA
->URS00005FFC84 siRNA from 1 species 
-TGACTTTGGAGCCATTCTTCCC
->URS00005C67CE rRNA from 1 species 
-TTAATTATAGTTAAATAGTATTGTGAAAGAAAATTGAAATAATTTGAAAAATTAATATTTTAAAAGAAAATTTAATTTATTGTACCTTGTGTATCAGGGTTTATTAATTAAAAATTATTTACTATAATTTTCTCGATTTTAAAAGAGTTAATATATTATAAAAGTTAATGTGACAAAATTATTTTATATAGTATATTAGAAATGAAATGTTATTCGTTTTTAAAGGTATCTAGTTCTTTAAGAAATAAATTTAATTTAGAAATATTATATTATTTAGTTAAATGTATTAATTAAATAATTATTTTATTTTAATATTTTATGGGATAAGCTGTGAAATAAATTATTAAAAATTTTTAAATAGTTTAATAAATATAAGCTTAGAAATAGTTATTATTAATGAAATTGTTATAATTTATTTTATAATATTTATTATTTATTAAATTTTAATTATGTATTAGAGTATTTATTTTAATTTAAAAAATAAAAAAATAATGATAAAATTAGTATATTATGATGTATAAATATGTGAAATTGATAAGTTTTTATAAAGAACTCGGCAAAAATAATGTT
->URS0001988726 lncRNA from 1 species 
-CACATGTTATGGACATTTTTATTTATTGACATGGTCAAATTAACAGGCAGCAGCATTTATTTTTAATGATAGCCTTGAAATCAGCCCAGGAAGAAAGTTAACATTGATGTTCAGAATACTGCATGCCATCCACATTTTTCCAGATGAAAGTATATTTTAAACTAATAATTAAATATTGTCACCCTAATTAAGTTACCTTGAGCAGGTGAGAGAAACACAGTTCTTAGTCATTGCAAATCTTGTTTGTCCTATTCTCAAGCTGTACAGAAAAACTACCCAGCAGGAGAAATTCGGCAAGCTCCATGGTTTAAAGTGTGCACTTAATTTAGGTGAATGATAAGCTGTGTCTATAAAGATTTGTGTTGGTCACCACGGAATGGAAGATTCCTGTGAAGTAGACAAGATGTAATTGCCAGTAAATATCAGTGCTAGCTTGGCCACACAACATTCACAGAGCAGGAGGGAATATCTTGGTATATTTATTATTACAGTGGGGAATTTTGACAGTCACCTTAATCACTCTTTGAGACAGGTAAAGAGAAAGGAACTGGGCAGCAGCACAGTTATCAGCTGGGTTAGAGAAAGCACACAGAGCAAAGGAGAATGAAGAGCATTTCACAAGGTATTTTAAACAGGTTTACATTGGGATGAAGATATTAGGAGTTTTTAGATATTAAGCACTTGTGGAAATTAAATCATTGCTTCATGCATTTAAAATTTACGCCCTAGAAGTACCTTCACAAACCAGACTGCCCACTTTAAAACTTCTGATCTACCCACCTTAAACAAGAATATTCTATAAATTACAAAGAAAGACTGGGAAATGATCTGTGTGTAATAGCTGAACCAAGCAATTTGCATATTTTCATGAATTACTGTAATGTGTTCTGCTTGTAATTTCACTTGTATACAAAGGATCACAGTTGCAAAAAGTACCAACTTTTCATGTTCAAAAGTGATTCAGGAGTCGAATTTCCTAGTCCAAAATGCTGAGACACTTAAAAATTAGAAGCTGAAATCATTGTTCTCTTCATTGCACTAGAAAGTTTTGCACTAAATCCTGCTCAGTGGCTTAGATATGAGCTGGAAATAATTTTTAGGAAAGCCCTGAACCAGGACACACTATTAGAGACTCCTTGGTTCTTTTGACTTGGCATTCACACATGTGCATGCAGATATGCAGATAGCCCTGTCATGATCTATTAAAAAAACAAACAAACAAAAAAATCTAGAAAAATCAATTTTCACTGAAAGATTCCAGTTTTTTTTCAGGGAAGAAAAGGTCTGTAAGCTTACCTGAGAAAAAGTTTCCACAGCAATTTTATTTTTTAAAAATGGTGATGAACGACCCACAGTGAACGTGGGAGAAGGATCCAATTTCTGCCCACGAGGGAGAAGAGTGTGTGCATGGTGGGCACCTCAGGCTGCAAGAGCAGGCACAGGATAGGGCATGGGCACGCAGGGCAGCTGCCTGCAGCTCCTGGCCAGTCTCAGCCTCTGTGGGGTCCCTTAGAGGGGTGAATTATTGTGCCCAGGGAGCTCCCCCCCCCATCCTGGCCAAGTCAGGATACATTTTTATAGCCCTTCTTCAAGTGATAGAAATATCAAGGGGAGGGCAAAATATATGGGAGGAGGGAAAGGGAGGCAGTTTCCAGTATTTGTCATTATTATAGGTTATATATACAGGAAGAAAGTTAATTAAGCTTTAAAAAATCCATCACACATCAATGGGTGCATTTTAATGAGTAGAAAAAGTTGAGATGTTTACTGCCAATTAAAGTGGTTTTTAAATAAGCATTAATTAACACAGAAATTCAGAAGAAAGTTATACCTTGTCAAAGAAAGGCCAGTGCAGTCTATGCCCACTTCTGCTCCCATTCATACTCAGATAGTAATTACCACCAACCCTATATTTTCCATAATAATGAGGAGAGGCTGTCATGGCTGTCAAACAAAAACAAAACAAAAAAAAAAAGAAAAAAAGGTGCTGCACAAAAATACCCTCAATCTGAAGTAAACTTTTGTTTTTAAATGTATAATAAAAAGCCACAGGAGACAGCAATATGGGGCAAGGCAGTGAGTGGGGCAGTCAGGCAGCCATGCCAGAGGCAGCTGCACACACATGGCTCCTTCCTAGGGAGCAGAGACTTTGGAACTCAGGATGAAGCCTCTCCAGACAGTCCAGCTGAAGAAAGACTGAAGAAAAGCCAAAGAAAAAGCAGTTCGTTCCTAGTTTCATCCCTAGCGCTGGAACTCGTGGAGGAGCTGATTCCCCTGTTAAAGCCAGAGGAGCTCGTTTTTTCCACAAACAAGTGCTGACAGACTAGCTCCATGCTTCCCAAAGTCAGATCAAAGCAACCACTGCAAATAAGTTCAGCTTGCATGTGCACTTCCAGCTGGAGCAACTGGTGACAGGAAAAACAGTACGACCCTCAATTCTGTCACTTCTCCATTCTTGCAGGATTTCTTAATAATTGTCAGGAGTTTCAGCTCTACTTCAGCTAGTGTCAAATCCTGATGGGACAGCAAAGGAAGTGATTTCTCCCATTGTTAGTCTGGTGAATGTTTAAATATCTTAGGAAAACCTTCCTTCCCCCAAATGCATCTTAGGCACCAAGTAAGATTTTCAAACTGCCTCATTGAGAATGGCTTCTCTCCTCACTTCCCCAGCTCCAGCTGTGGAGAGATAAAAACCCCACTGCCTTTTCAGACAGCAGAAGAGGCAGGTCACATAAAAATTTGTTAGTAGCCTAAGAAATTTTACAAAAATCTCTGGTGTAGTGTTTTTAAAGTTAATTTAAAAAACAAAACAAAACAAAACAAAAGAAGCAACAAAACACAGAAAAGAAGGCTGTAGATATGCACAGACTCCTGTTCCTAACCCTTGGCATTTCACTCAGATAATGTGCAGCCTCTCTGTAGCTTGTGTCTATCAGGGAGTATCTGGGAGCCTTTTTCCTACTCCATGTCCACAGGCAATATCTGCAGTAGAATAAAAAAAGGAGAGCATTAAATGCCATGGAAGTTTTGTTGAATGTAACTGGACAGGGCCTTCAGATCTTG
->URS0000ADFB99 rRNA from 1 species 
-TTCTAACAGAAATAATTGTTAGTAAATCCTGCTCAATGATTCGTTAAATAGCCGCAATAACTTGTGCTAAGGTAGCATAATAATTTGCCTATTAATTGTAGGCCAGAATGAAAGGATTAACATAAGAAATTCTTTATTCATTAAATAAATTTAACTTCATTTATAAGTAAAAAAGCTTATATTTTTTAGAAGGACGACAAGACCCTGTCGAACTTCACTAAAGTTTTACTGGGGCGGTAAAAAAACTAACACTTATTTTCCATTTACAAAATATAAACATAATGTTAATTCTAAACAAGTTACCGCAGGGATAACAGCATAATTTTTTCCTAAAGATCTTATTAAAGAAAAAGATTGTGACCTCGATGTTGAATAATTTATCTTATTGGGGCAGCACCTAAACAAGTAAGTCTGTTCGACTTTTAAAAAATTACA
->URS00009AD4FC lncRNA from 7 species 
-ACGCCGGCGTGAGAGGGCACGGGGAAAAAGGTGGCTCTGGCCGGGGCGGCTCTGTTTCCTGGGGTTATGTAGCAGGGCTTGTCGGCTCGCGAGACCTCCCGCTGCCCTCGCCCGTGTCCTAGCGCGGGGTTTCTGCTCCGGGCGGAGGCCGTGTTCAAGCCCGCCGCGCTCCCTCGACGTAGAGCTCGCTCGTCCGCCCGTGGGAGCGTCCCGGCCGAGCTGCGCTGAGGGGGGAGGGGAGGCCATTTTGTCCCGACCGACTCCCCGGAACCGGGCGGAGCGGCTGGGAGAGGCTGCGGAGCCGCGGGCGCCGCCCCTCGGAGGCACGGGCGCCGCCACCGTCGGGGCTTCCTCGACGAGGCCGTTCGGAAGGTCTCCTGCTCCGTCTCGAGAGCTGCTTTCTCCTTCCGCACACGCTACCCGGCTGCTGCGGCCCCAGAACGCCCGGGTGAGGAGTTGGTTGTAGTGAGCAGTTCCGATCCCTTGGGGCTACCGGCGGCGAGCGCCCGAGCCGCTCCTCCCAATGGCGAAGAAGACGTACGACCTGCTTTTCAAGCTGCTCCTGATCGGGGACTCGGGAGTGGGCAAGACCTGCGTCCTTTTTCGTTTTTCGGACGATGCCTTCAATACCACCTTTATTTCCACCATAGGTAAGACCTGTGGGAGGATGGTGTGGGGGCTCTGTAGCCGCGAGCCGTTTTCTTTTATTCCAGACATCTTGCTTCCCGGAATTTACGCCTTTGTTCCAGTGATTCCGATTCCAGACGACAGACCTAAGTTACTGTTGGAATCGGAATAGCCTTACTGGGGCGGGGTCTTCCCATGCTTACCATCCGGTCTCAAGTCTCCTTCTCTGTTCGGTGCCTTCTGGCACAAAATATGCAGCATTTAGCAGCGTTCCAGAATCCGGTTTCTTTAAGTGACTTGCCTGGCCTTACCATAATTGCATGAAGTTACTTGATGTGCTATTTGTAATAGACGTAATTTAGTGGTTGGGATTGAAGCAGTACTGGCTATGTGGCAAAGGCCCGAATTGGGGGTCAAAGAGAAAATATTCTATCTGACTGTAACTTGGAGTAAACTTGAGAGTTGCAGAATCATTAAGGAAAATGAGAGGGGCGGGGGAAAGTGAGTTGGCTGTCTTGACTGAACCATTGATGTGTCAAACAATCGGAGGCCCTTCGTGCTTGGGGTGGGAATCTGGCATGGTTGGCTCACAGTGCTTTTTCAAGACCTCAACGAAGCAGATGGACGGTTTCTGTTTTCAACCCAATGGAATCAAGTCAAGTTCTAATGTTTTACTTGATGTTAGAATTTACAGGAAAATCTTTCGTCAGTCATGGCTCTAAGGACTTCTAATGTACTACCACATATTTCGGAATTACTTGGTATGGAAATAAAAACTGACCTTTTAAATGGGTTTCCTGTTTCGGAAATGAAAAGGGAAGGTTTCAAGAAAGTCGTTTTGACGCTGGCACCAACATCAATTTTGTCAAAGTAACTGTACATGACCACCCCCCTCCCTGGTTTTTTAAAGTATCCGGTGTCTTTCATTTTTGAACCTCAGCTCCGGCATTAGAGCAGTGCAGGAAAACTTGTGATAAATGTAACTAGCTTCACGATGAGAAGCGACTCTAGTGGTTTTCCTTAAGAATTGTGAAAATCTTGTTTTAACCAATTTATAGTATAGGATTTCCTTAAGACATATTTGTAAGTAGCTTAAGCATATTTTCGCAAAATATGCTTAAGTTATACTGCAATTAAGATGAGCAAATTTTTATTTAAAATAGGTTGTTTTACCTTACTGGTGGGCAGGATTGTCAAAATATCACGAAGCTTGAACTTGTCCTCTGCTTAGTGGGTTAGCACTTACACAGCACTAAGTTTGCTTTGAAGTGTAGCTGGGTCAGTCAGGTGGCTAGATCAGCAAATATTTATTGAGCACCAAGTTCTAGGCACTGTTAAAAGCGTTGAAAATAAGTGGTCGATACAATAGACCCCTTGAGCATTCTGATAAAGAAGGCAACAACAGTGTGCAAAGCACTAGAGTGAGGAGAGGGAGGAAGGGGAGTAGTCTGAATTATGGGGAATCTGCTTTGCATGGATGTTTAAAACGTAGTCTGAAAGACAAGTATGAATTGGATCAGAGGAGAGGTAGCCTCTTTGAAAGAGAATTTAGTGTGCGATCCTTTTTTTTTTAACCTGCTCTTGAGAACGGGTAGGTGAAAGTAGGAAGTAAAGTTTCCTGGTGAAGAAAGCTACTTAGCCCCCCAGCTGCCTGTCCTCAGGTACTGGGCATTGACTAACCTCATGCGTGGTAGGCAAGCTGCTGAGTTACACCTCCAGTCCTCCTTGTATCCATAGTCTTCATTGTCCTTTGACTTAGGGAGATGGGTTGTTTCCCATGCAGCCTGCTGTTTTGAATTCCTGGCTCCACAGGAATTGCAACTTTGGCTACAGTGTCTTATTCGACAGTGCAAATGCCATGTATGGTGCTTGTGAGGATTAATACAGGTCAGCGAGAGCAAAGCACCTAACAATGGTGCCAGGTACTTTGTAGGAACACAGTGCAGATTTGTGCAGAATATATGGCCTTCCTGATACTGGTGTGTGACAGAATAAGTTGCTTTATGGATTGAATATGTCTTGTGTGTAATGGCTGCTTGAATATCTGTTGGTGCTCTGCTAAACAATTATACAATAACCTCTGACATTTATACATTTTGATATAAAAACATTTGATGTTTTGACACAAGATTTGAATAAAGTAAGCTAAGAAAATGAACAAAATTCTGACAATTCTTAGTCCAGCTCATACTTGACTCTTTGCAGATTTTGAATTCTGTTAGCCTCATAAACTTTGGTAGTC
->URS0000A9B0F3 lncRNA from 12 species 
-TTTCCTTCCTCTTTTCAAGCTTATTGAAGGAGCCAAATCATTCCAATTCAGCCTGGACTGACCTTTATGTGCTTCATTTTAGTTTAAAAGAAACCCAAACTTCAGTTCTCTGGGATTCTGGGCTAAACATTAAGGAATCCATTCAAAGGTTGTACCTTCCTCCTCATGGTTAACCATTTCAAAG
->URS00013E7246 rRNA from 1 species 
-TACGTAGGGCGCGAGCGTTGTCCGGAATCATTGGGCGTAAAGAGCTCGTAGGCGGCCTGTCGCGTCTGCTGTGAAATCCCGGGGCTTAACCCCGGGCGTGCAGTGGATACGGGCTGGCTGGAGGCAGGCAGGGGAGAACGGAATTCCCGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCCGTAACTGACGCTGAGGAGCGAAAGCATGGGGAGCGAACAGG
->URS0001D4A06F rRNA from 1 species 
-AACGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGCCCTTTCGGGGGAGCGGCGGACGGGTGAGTAACGCGTGGGAATATGCCCTTCTCTACGGAATAGCCTCGGGAAACTGAGAGTAATACCGTATACGCCCTATGGGGGAAAGATTTATCGGGGAAGGATTAGCCCGCGTTGGATTAGGTAGTTGGTGGGGTAATGGCCTACCAAGCCGACGATCCATAGCTGGTTTGAGAGGATGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCGTGGGGGAGGCGGCAGGGGAGAATCTAAGAAGTGGGGGGCAACCATGAGTGAGCACTGGCGGGTGAGGGATGAAGGCCTTGGTGTTGTAAAGCTGTTGACGGTGGGAATAAAATGGCTGTACCAGCAGAAGAAGCCCAGGACAACTCCGTGCCAGAAGACGAGTTAATAGTCAAAGACACACGTCTGAAC
->URS00022CCAAD rRNA from 1 species 
-TGGAAGCGTCTGGAAAGGCGCGCGATACAGGGTGACAGCCCCGTACACAAAAGCGCATGTGCTGTGAGCTCGATGAGTAGGGCGGGACACGTGGTATCCTGTCTGAATATGGGGGGACCATCCTCCAAGGCTAAATACTCCTGACTGACCGATAGTGAACCAGTACCGTGAGGGAAAGGCGAAAAGAACCCCGGCGAGGGGAGTGAAAAAGAACCTGAAACCGTGTACGTACAAGCAGTGGGAGCACCCTTTGGGGTGTGACTGCGTACCTTTTGTATAATGGGTCAGCGACTTATATTCTGTAGCAAGGTTAACCGAATAGGGGAGCCGCAGGGAAACCGAGTCTTAATTGGGCGTTAAGTTGCAGGGTATAGACCCGAAACCCGGTGATCTAGCCATGGGCAGGTTGAAGGTTGGGTAACACTAACTGGAGGACCGAACCGACTAATGTTGAAAAATTAGCGGATGACCTGTGGCTGGGGGTGAAAGGCCAATCAAACCGGGAGATAGCTGGTTCTCCCCGAAAGCTATTTAGGTAGCGCCTCGTGAACTCATCTCCGGGGGTAGAGCACTGTTTCGGCTAGGGGGCCATCCCGGCTTACCAACCCGATGCAAACTGCGAATACCGGAGAATGTTATCACGGGAGACACACGGCGGGTGCTAACGTCCGTCGTGAAGAGGGAAACAACCCAGACCGCCAGCTAAGGTCCCAAAGTCATGGTTAAGTGGGAAACGATGTGGGAAGGCCCAGACAGCCAGGATGTTGGCTTAGAAGCAGCCATCATTTAAAGAAAGCGTAATAGCTCACTGGTCGAGTCGGCCTGCGCGGAAGATGTAACGGGGCTAAACCATGCACCGAAGCTGCGGCAGCGACGCTGATGCGTTGTTGGGTAGGGGAGCGTTCTGTAAGCCTGTGAAGGTGGCCTGTGAGGGTTGCTGGAGGTATCAGAAGTGCGAATGCTGACATAAGTAACGATAAAGCGGGTGAAAAGCCCGCTCGCCGGAAGACCAAGGGTTCCTGTCCAACGTTAATCGGGGCAGGGTGAGTCGACCCCTAAGGCGAGGCCGAAAGGCGTAGTCGATGGGAAACGGGTTAATATTCCCGTACTTGGTGTTACTGCGAAGGGGGGACGGAGAAGGCTATGTTGGCCGGGCGACGGTTGTCCCGGTTTAAGCGTGTAGGTGTGTGTTCCAGGTAAATCCGGTTCACTTTAACACTG
->URS0000B7FAC1 rRNA from 1 species 
-ACCTACGGGGGGCAGCAGTGGGGAATATTGGGCAATGGAGGCAACTCTGACCCAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATTGTAAAACTCTTTAAGTGGGGACGAAGAAAGTGACTGTACCCACAGAATAAGCCTCGGCTAACTACGTGCCAGCAGCCGCGGTAATACGTAGGAGGCAAGCGTTATCCGGATTTACTGGGTGTAAAGGGAGCGTAGACGGCTTGGCAAGCCAGATGTGAAAGGCTGGGGCTCAACCCCAGGACTGCATTTGGAACTGTCATGCTAGAGTGTCGGAGGG
->URS00001F4C6B rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAACACATGCAAGTCGAACGGGGGTAGCAATACCTCAGTGGCGAACGGGTGCGTAACACGTGAAGAATTTGTCCAACGGCGGGGGAGTAGCCGGCCCAACGGCCGGGTAATACCGCGTACGCCCTTCGGGAGGCATCTCCTGATTGGGAAAGCCGCAAGGCGCCGATGGAGAACTTCGCGGCCTATCAGCTAGTTGGTGAGGTCATGGCTCACCAAGGCGACGACGGGTAGCTGGTCCGAGAGGATGACCAGCCACATTGGGACGTGAGACACGGCCC
->URS000030270D rRNA from 1 species 
-CAGCAGCCGCGGTAATACGTAGGGTGCGAGCGTTAATCGGAATTACTGGGCGTAAAGCGGGCGCAGACGGTTACTTAAGCAGGATGTGAAATCCCCGGGCTCAACCTGGGAACTGCGTTCTGAGCTGGGTGACTAGAGTGTGTCAGAGGGAGGTAGAATTCCACGTGTAGCAGTGAAATGCGTAGAGATGTGGAGGAATACCGATGGCGAAGGCAGCCTCCTGGGATAACACTGACGTTCATGCCCGAAAGCGTGGGTAGCAAACAGGATTAGATACCCTGGTAGTCCACGCCCTAAACGATGTCGATTAGCTGTTGGGCAGCTTGACTGCTTAGTAGCGAAGCTAACGCGTGAAATCGACCGCCTGGGGAGTACGGTCGCAAGATTAAAACTCAAAGGAATTGACGGGGACCCGCACAAGCGGTGGATGATGTGGATTAATTCGATACAACGCGAAGAACCTTACCTGGTCTTGACATGTACGGAACCCTCCAGAGACGGAGGGGTGCCTTCGGGAGCCGTAACACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTGTCATTAGTTGCCATCATTAAGTTGGGCACTCTAATGAGACTGCCGGTGACAAGCCGGAGGAAGGTGGGGATGACGTCAAGTCCTCATGGCCCTTATGACCAGGGCTTCACACGTCATACAATGGTCGGTACAGAGGGTAGCCAAGCCGCGAGGTGGAGCCAATCTCACAAAACCGATCGTAGTCCGGATTGCACTCTGCAACTCGAGTGCATGAAGTCGGAATCGCTAGTAATCGCAGGTCAGCATACTGCGGTGAATACGTTCCCGGGTCTTGTACACACCGCCCGTCACACCATGGGAGTGGGGGATACCAGAAGTAGGTAGGGTAACCGCAAGGAGCCCGCTTACCACGGTATGCTTCATGACTGGGGTGAAGTCGTAACAAGGTAGCCGT
->URS0001E386D7 rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGCTGCAGGGTACTTGCTCCTTCTTTCGGCTGCCGACTGGTGGACGATGCCTAGGTATCTCCCTATTTGTTTTTGCTTACGTCCTAACGTGGGCGCTCTTACCCCATACGTCCTTACGACCTACGTGTGGAATCTTCGGACCTTCCGCTCTCGCATGATCCTATGTCGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCCGTAACTGGTCTGAGAGGATGATCAGTCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGGGTGAAGAAGGTCTTCGGATTGTAAAGCACTTTAGGTTGGGAGGAAGAGCAGTAAGTTAATACCTTGCTGTTCTGACGGTACCAAAAGAATAAGCACCGGCTAACTTCGTG
->URS0001DD23C1 misc_RNA from 1 species 
-GATGAAGAAGTAGCGAAATGCGATAAGTAGTGTGAATTGCAGAATTCAGTGAATCATCGAATCTTTGAACGCACATTGCGCCCCTTGGTATTCCATGGGGCATGCCTGTTCGAGCGTCATTTGTACCTTCAAGCTCTGCTTGGTGTTGGGTGTTTGTCTCGCCTCTGCGTGTAGACTCGCCTCAAAATAATTGGCAGCCGGCGTATTGATTTCGGAGCGCAGTACATCTCGCGCTTTGCACTCATAACGACGACGTCCAAAAGTACATTTTTACACTCTTGACCTCGGATCAGGTAGGGATACCCGCTGAACTTAAGCATATCAATAAGCGGAGGA
->URS000221B86E rRNA from 1 species 
-TGATCCCGGCCCAGAATGAATGCTTGCGACAAGCCTAATACATGCAAGTCGAGCGCACTTTTAGAGTGAGCGGCGAACGGGTGAGTAATGCGTAAGAATCTACCTTCTACATAGCCATAAATAGGTAAAGGCCAAGTCCGGTAGAAGATGAGCTTGCGTAAGATTAGGTAGTTGGTGAGGTAAGAGCTCACCAAGCCAGAGATCTTTAGCTGGTCTGAGAGGTTGATCAGCCACACTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTAGGGAATATTGGTCAATGGGCGAGAGCCTGAACCAGCCATGCCGCGTGCAGGATGACGGCCTTCTGGGTTGTAAACTGCTTTTATATGGGAAGAAAAAGGTCTTGCGAGACAAATTGCCGGTACCATATGAATAAGCACCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGGTGCAAGCGTTGTCCGGATTTATTGGGTTTAAAGGGTACGTAGGCGGATTTTTAAGTCCGTGGTGAAAGCCTACAGCTTAACTGTAGAACTGCCATGGATACTGGAAATCTTGAATTCAGTTGAGGTAAGCGGAATTTATGATGTAGCGGTGAAATGCATAGATATCATAAAGAACACCTATTGCGAAGGCAGCTTGCTGGACTTGAATTGACGCTGAGGTACGAAAGCGTGGGGAGCGAACAGGATTAGATACCCTGGTAGTCCACGCCGTAAACGATGATTACTCGCTGCTAGCGATACACAGTTAGTGGCCAAGCGAAAGCGTTAAGTAATCCACCTGGGGAGTACGCTCGCAAGAGTGAAACTCAAAGGAATTGACGGGGGTCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGATACGCGAGGAACCTTACCTGGGCTAGAATGTGAGCGCTAGATTTAGAGATAGATCGTTCTTCGGACGTGAAACAAGGTGCTGCATGGCTGTCGTCAGCTCGTGTCGTGAGATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCCTATCCCTAGTTGCTAGCAGTTCGGCTGAGAACTCTAGGGAGACTGCCGGTGACAAACCGGAGGAAGGTGAGGATGACGTCAAATCAGCATGCCCCTTACATCTTGGGCGACTCACGTGCTACAATGGTCGGGACAAAGAGATGCTACCCTGCGAAGGCAAGCTAACCTCAAAAACCCGATCTCAGTTCGGATTGCAGGCTGCAACTCGCCTGCATGAAGTTGGAATCGCTAGTAATCGCAGGTCAGCCATACTGCGGTGAATACGTTCTCGGGTCTTGTACACACCGCCCGTCACACCATGGAAGTTGGTAATACCCGAAATCGCGCGTCTAACCTTCGGGAGGACAGTGCCTAAGGTAGGATCAGTGACTATGGTGAAGTCGTAACAAGGTAGCCGTACTGGAAGGTGTGGCTGGATTACCTCCT
->URS00005DE4A8 rRNA from 1 species 
-GGCCCGCGCAAGCGGTTGAGCAAGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTACCCTTGACATCGTGCGAACTTTCCAGAGATGGATTGGTGCCTTCGGGAGCGCACAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGTAACGAGCGCAACCCTTGTCCCTATTTGCCAGCGATTCGGTCGGGAACTTTAGGGAGACTGCCGGTGACAAACCGGAGGAAGGTGGGGACGACGTCAAGTCATCATGGCCCTTACGGGTAGGGCTACACACGTGCTACAATGGCCGGTACAATGGGTTGCAAAGCGGCGACGTGGAGCTAATCTCATAAAGCCGGTCTCAGTCCGGATCGGAGTCTGCAACTCGACTCCGTGAAGTCGGAATCGCTAGTAATCGTGCATCAGAATGGCACGGTGAATACGTTCCCGGGCCTTGTACACACCGCCCGTCACACCATGGGAGTGGACTGCACCAGAAGTGGTTAGCCTAACTTCGGAGGGCGATCACCATCGGTTGTACATATCT
->URS00010C272E rRNA from 1 species 
-TACGGAGGGTGCGAGCGTTGTCCGGAATCACTGGGCGTAAAGGGCGCGTAGGCGGCCTGCTAAGTCGAACGTGAAATCCCCGGGCTCAACCCGGGAACTGCGTCCGATACTGGCAGGCTTGAATCCGGGAGAGGGATGCGGAATTCCAGGTGTAGCGGTGAAATGCGTAGATATCTGGAGGAACACCGGTGGCGAAGGCGGCATCCTGGACCGGCATTGACGCTGAGGCGCGAAAGCCAGGGGAGCAAACGGG
->URS0001E10DE4 rRNA from 1 species 
-GATGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAGCGAACAGACGAGGAGCTTGCTCCTCTGACGTTAGCGGCGGACGGGTGAGTAACACGTGGATAACCTACCTATAAGACTGGGATAACTTCGGGAAACCGGAGCTAATACCGGATAATATATTGAACCGCATGGTTCAATAGTGAAAGACGGTTTTGCTGTCACTTATAGATGGATCCGCGCCGCATTAGCTAGTTGGTAAGGTAACGGCTTACCAAGGCAACGATGCGTAGCCGACCTGAGAGGGTGATCGGCCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTAGGGAATATTCCGCAATGGGCGAAAGCCTGACGGAGCAACGCCGCGTGAGTGATGAAGGTCTTCGGATCGTAAAGCTCTGTTATTAGGGAAGAACAAATGTGTAAGTAACTATGCCCGTCTTGACGGTACCTACTCAGAAAGCCACGGCTAACTACGTG
->URS000163CC5A rRNA from 1 species 
-CCTACGGGGGGCAGCAGTGAGGAATATTGGTCAATGGGCGGGAGCCTGAACCAGCCAAGTCGCGTGAGGGAAGACGGTCCTATGGATTGTAAACCTCTTTGGGCGGGGAGCAATGCCGGGCACGTGTGCCCGGAGGGAGAGTACCCGCAGAATAAGCATCGGCTAACTCCGTGCCAGCAGCCGCGGTAATACGGAGGATGCGAGCGTTATCCGGATTTATTGGGCGTAAAGCGCTCGTAGGCGGTATGTCAAGTCAAGGGTGAAAGCCCCGCGCTCAACGTGGGAACTGCCTTTGAAACTGGCAAACTTGAGTGTGTGAGAGGATAGTGGAATTCCAGGTGTAGGAGTGAAATGCGTAGATATCTGGAGGAACAGCAGTGGCGAAGGCGACTATCTGGCACATAACTGACGCTGAGGAGCGAAAGCGTGGGTAGCAAACAGGATTAGATACCCCAGTAGTC
->URS0000FA15DB rRNA from 1 species 
-GACGAACGCTGGCGGCGTGCCTAATACATGCAAGTCGAACGCAGTGGGGACGGGTGAGTAACACGTGGGTAACCTCCCATCAGAGGGGATAACACTTGGAAACAGGTGCTAAACCGATACTGATGGATGGACCCGCGGTGCATTAGCTAGTTGGTGAGGTAAAGGCCTACCAAGGCAAGGATGCATAGCCGACCTGAGAGGGTGATCTGCCACATTGGGACTGTGACACGGCCCAACCTCCTACGGTAGGCAGCAGTAGGGAATCTTCCGCAATGGGCGCAAGCCTGACGGAGCAACGCCGCGTGAGTGAAGAAGGTTTTCGGATCGTAAAGCTCTGTTGTCAGAGAAGCGGTATCTTACCAGAAAGCCACGGCTAACTACGTGCCAGCAGCCGCGGTAATAC
->URS0000AF79E1 sRNA from 1 species 
-ACCCGCTGAATTTAAGCATATTAATAAGCGGAGGAAAAGAAACTAACAAGGATTCCCTCAGTAATGGCGAATGAAGCGGGAATAGCTCAATTTTGGAATCTCCGCTTCGGCGGCGAATTGTAGTTAATAGAGGTGTTTTCTCAGGATGCGGTGTGGTTTCTAAGTCCCTTGGAACAGGGCATCATAGAGGGTGAGAATCCCGTATGTGGAACCGCACTTGTCCCTTCGATACACTTTCTACGAGTCGGGTTGTTTGGGAATGCAGCCCAAAATGGGTGGTAAATTTCATCTAAAGCTAAATATTGGCACGAGACCGATAGCGAACAAGTACCGTGAGGGAAAGATGAAAAGCACTTTGAAAAGAGAGTCAAACAGTACGTGAAACCGTTAAAAGGGAAACGATTGGAACTAGCAGTGACAGCATGTAATCAGTGGTTTGCTTGTGTTGTGATGGTTGTGTCTTTAAAAAAGCTCTTCTTGATCAGCCTTGTGGACTATGCACTTGCGTGTTTGTCGTGTCAATGTCAGTTTCTTCGGCGGGAGAAAACCGGGGAAAAGGTAGCTTGGTTCTTCCAAGTGTTACAGGTTCTCGGGTATATCGCCCTAGGGACTGAGGAGTGCGGGTCGTGCCTTTTGGCAAGGAAGCCTTTTGATGCCGGTGTATGTTTCTGCCCGACTGCTTGCAGTGGTGTGGTTGCATGCATGGTAATGCTTGGGGTTTTCCATTCACGTCCCTCAGATATTGACGAAATAGTTTCAACCGACCCGTCTTGTAACACGGACCAAGGAGTCTAACATGTATGCGAGTCTCTGGGTGTAAAACTCGTGGGCGCAATGAAAGTAAACGTAGGTGAGACGCTTCGGCTGCATCATCGACCGATTTGGATTTTTTATGAAAGATTTGAGTATGAGCATATATGTTGGGACCCGAAAGATGGTGAACTATGCCTGAATAGGGTGAAGTCAGAGGAAACTCTGATGGAAGCTCGTAGAGGTTCTGACGTGCAAATCGATCTTCAAATTTGGGTATAGGGGCGAAAGACTAATCGAACCATCTAGTAGCTGGTTCCCACCGAAGTTTCCCTCAGGATAGCTGGAACTTGTTCAGTTTTATCAGGTAAAGCGAATGATTAGAGGCCTTGGGGTTGAAACAACCTCAACCTATTCTCAAACTTTAAATAGGTAAGAAGTCTGACTTGCTTAACTGAAGCCAGACGATCGAATGTTGAGTTCCAAGTGGGCCATTTTTGGTAAGCAGAACTGGCGATGCGGGATGAACCGAACGCGGAGTTAAGGTGCCAAAATCAACGCTCATCAGACCCCACAAAAGGTGTTGGTACATCCAGACAGCAGGAAGGTGACCATGGAAGTCGGGACCCTCTAAGGATCGTGTAACAACTCACCTGCCGAATGTATTAGCCCTGAAAATGGATGGCGCTAAAGCGTTGTACCTATACTCCGCCGTTGTGTTAATAACGATGACACAACGAGTAGGTGGGCGTAAAGGTTTTTGTTCTTTTTGAACTTTTGTGACGAAGCTTTTGATGTGAATCTGAGTTGAACGGCCTTTAGTGCAGATCTTGGTGGTAGTAGCAAATATTCAAATGAGAACTTTGAAGACTGAAGTGGAGAAAGGTTCCTTGTGAACAGCAGTTGGACAAGGGTTAGTCGATCCTAAAAGATAGGGTAATTCTGTTTGAAATGGCTTTCTTGTAAAGCACCTTATTGAAAGGGAATCAGGTTAATATTCCTGAACCGGAATGTGGATATTTCTCTCTTCGGAGGGAATGTGTGGTAACGCAACTAAACTCGGTGACGCTGGCAAGTATCCCGGGAAGAGTTCTCTTTTCTTTTTAACGATTGCATTGACCATGAAATCAGGTTAACTGGAGATATGGTTAAATCGCAACCAGGGCCACCTTCGGGTAGCCGACGGTAAAGCACTGCAATTTTTTCGCAGTGTCCGGTGCATTCTTGACAGCCCGTGAAAAACCGAGGGAAATAATAATTCTCACATCCGGTCGTACTCATAACCGCAGCAGGTCTCCAAGGTGAACAGCCTCTAGTTGATAGAAGAATGTAGGTAAGGGAAGTCGACAAAAAAGATCCGTAACTTCGGGATAAGGATTGGCTCTAAGGGTTGGGCATGTTGGGGCCATCTCCTTTTTGGATTTGCCTGAAGCTCGTTGATTAGCGGGCGTGGATGCGCTTTCGGGTGCGTTCTGCCTGCTCGATTGACCTGTTGAGGGTGGTGGCTGAGGGGGGGGGTTTTTTCTCCTCTTCTCAACTGGCATGTAATTAGCAACCGACTTAGAACTGGTACGGACAGGGGGAATCCGACTGTTTAATTAAAACAAAGCATTGCGATGGCCGGAAATGGTGTTGACGCAATGTGATTTCTGCCCAGTGCTCTGAATGTCAAAGTGAAGAAATTCAACCAAGCGCGGGTAAACGGCGGGAGTAACTATGACTCTCTTAAGGTAGCCAAATGCCTCGTCATCTAATTAGTGACGCGCATGAATGGATTAACGAGATTCCCATTGTCCCTATCTACTATCTAGCGAAACCGCAGCCAAGGGAACGGACTTGGCAGAATCAGCGGGGAAAGAAGACCCTGTTGAGCTTGACTCTAGTCCGACTTTGTGAAAAGACATTGGAGGTGTAGCATAGGTGGGAGCTTCGGCAAACTTGAAATACCACTACTCTGATCGTTTTTTTACTTATTTAATGAAGCGGGAAGCGAGTTTTCACCGACTCAATTTTTGGGATTTAAGCTCCCCCTTTTTGGGGGGGTGATCCGAGTTAAAGACATTGTCAGGTGGGGAGTTTGGCTGGGGCGGCACATCTGTCAAAAGATAACGCAGGTGTCCTAAGGTGAGCTCAATGAGAACGGAAATCTCATGTAGAACAAAAGGGTAAAAGCTCACTTGATTTTGATTTTCAGTGTGAATACAAACTGTGAAAGCATGGCCTATCGATCCTTTAGTCCTTTTTTGAAATTTAAAGCTAGAGGTGTCAGAAAAGTTACCACAGGGATAACTGGCTTGTGGCAGCCAAGCGTTCATAGCGACGTTGCTTTTTGATCCTTCGATGTCGGCTCTTCCTATCATTGTGAAGCAGAATTCACCAAGTGTTGGATTGTTCACCCACTAATAGGGAACGTGAGCTGGGTTTAGACCGTCGTGAGACAGGTTAGTTTTACCCTACTGATGAGTATCTATGATATAGACCACAGTTGTTGCAATAGTAATCAAACTCAGTACGAGAGGAACCGTTTGTTCGGACAATTGGTATTTGCCCTTGGTTGAACAACCAATGGGGCGAAGCTACCATCCGTAGAATTATGACTGAACGCCTCTAAGTCAGAA
->URS0001793305 rRNA from 1 species 
-TACGTAGGGGGCGAGCGTTGTCCGGATTTATTGGGCGTAAAGCGCGCGTAGGCGGTTTGGCAAGTCTGATGTGAAAACCCGGGGCTCAACCCCGGGCGTGCATTCGATACGAGCAAACTAGAGTGTTGCAGGGGAGACTGGAATTCCTGGTGTAGCGGTGAAATGCGCAGATATCAGGAGGAACACCGGTGGCGAAGGCGGGTCTCTGGGCAACAACTGACGCTGAGGAGCGAAAGCGTGGGGAGCGAACAGG
->URS0000082604 rRNA from 1 species 
-GAGTTTGATCGTGGCTCAGGATGAACGCTGGCGGCGTGCTTAACACATGCAAGTCGAACGAAGCACTTTACCACGATTCCTTCGGGATGACGGTTTAGTGACTGAGTGGCGGACGGGTGAGTAACGCGTGGGGAACCTGCCCCATACCGGGGGTAACAGCCGGAAACGGCTGCTAATACCGCATAAGCGCACAGTACCGCATGGTACGGTGTGAAAAACTCCGGTGGTATGGGATGGACCCGCGTCTGATTAGCCAGTTGGCGGGGTAACGGCCACCAAAGCGACGATCAGTAGCCGGCCTGAGAGGGCGACCGGCCACATTGGGACTGAGACACGGCCCAGACTCCTACGGGAGGCAGCAGTGGGGGAATATTGCACAATGGGGGAAACCCTGATGCAGCAACGCCGCGTGAGTGAGGAAGTATTTCGGTATGTAAAGCTCTATCAGCAGGGGAAGAAGAAATGACGGTACCTGACTAAGAAGCCCCGGCTAACTACGTG
->URS00023E414C lncRNA from 1 species 
-CATGTTCACAATTTGGTAGCTGCTAGTTATTAGTCATTACATATAATATTTGAGATCAAAATATATTATTTTTTTAGGAAAAAAAAATCAAAGTATATGTAATGCAAGCTAGGAGGCCTAGCATGAGGTTCACTGTAATCTAGAGGAAGATTAAATTAACTAAGAAGGAATTAAACTAATTATAAAATAAAGAAAATATCAAACTCCAAAAATCTACGGGCA
->URS000233A4B4 lncRNA from 1 species 
-TGTTAACAAAAATAGAGTGGGGAATAGGGTTAGGCCATGACAGGCAATGATCCTAAGAGCTAGAGATCTCTCCCACCCCAACAGAGAGAGACAGAGAGACAGACAGAGAGAGAGAGAGGGAGACAGAGACAGAGAGAGAGACACACACAGAGAGAGAGAGACACACACGCACACACACAGAGAGAGAGAGACACACACACACACACACACAGAGAGACACAGAGAGAGAGAGAGACAGAGACAGAGACAGAGAGAGAGAACCCTAAGGTATTAATATTCCTGACTTGAATACCTCAGGCTTTTCCCAGCCAACTTCCACGTTGCTCTCCTATCCGTCTCCACACCTAATTCTTCTACCAAACCCTTCTGTCCACCCCAGGAGATTGTGAACTCAGGCACCAAATCCAACAAGCTCCCCGAGGAACTTACAACAGTCTGTTTTACAGAGAAGTAAATGTTGCTGAGAGAGAAAATTGTCAGGCCTCGGTGTTCCAGAGCAAGAGGCATTCCTTCATTCCCAGAGAGGCCCTGGGCCTCAGCAAGCAAGCCCGACAAGCCCTCCGCAGCCAGAATCCAAGCTTCAGGCTGCACCTCCCTCACCGCTGGGCCCTGGACAGTGAGGCTGCTGCTCAGAACCCCTCTCCTCAGAGGGAAATTCCTCAGGGCTGCCCCACCCGACCCGTTCTATCAGTCACTCAAGCCCTCTATCCTCTGTCACAGCCTGGCTCTGTCCCTTCCCATGCCCCAACCCCCAACCTCCCAGGACCCAGTATCTCAGGATTTCTGCCCTCCTCCAGCCCCGAGCAGCCTGGAAGCCAAGTGGCAAGGATGTAGTCAGCCGGGTGGGCCCTGAGAGCCGGTGGAATGGTGTCCATGTTGCAGGAAACAAGGGAAGGTGAGGGGTACAGGGGTGCCTGTGCCAGGCCACCACTCCACAGCTCATTCTTCTCTGAGGTTATTCCCCGACCCATACCCCTCTGGAGCCCACCCCAGCTGCTTCCTCTTCCTAGGGGTCTCCACCTGATGTTCTGTGAC
->URS0001C069FB rRNA from 1 species 
-ATTGAACGCTGGCGGCAGGCCTAACACATGCAAGTCGAGCGGATGAAGGGAGCTTGCTCCTGGATTCAGCGGCGGACGGGTGAGTAATGCCTAGGAATCTGCCTGGTAGTTGGGGATAACGTCCGTAAACGGGCGCTAATACCGCATACGTCCTGAGGGAGAAAGTGGGGGATCTTCGGACCTCACGCTATCAGATGAGCCTAGGTCGGATTAGCTAGTTGGTGGGGTAAAGGCCTACCAAGGCGACGATCCGTAACTGGTCTGAGAGGATGATCAGTCACACTGGAACTGAGACACGGTCCAGACTCCTACGGGAGGCAGCAGTGGGGAATATTGGACAATGGGCGAAAGCCTGATCCAGCCATGCCGCGTGTGCGAAGAAGGTCTTCGGATTGTAAAGCACTTTAAGTTGGGAGGAAGGGCAGTAAGTTAATACCTTGCTGTTTTGACGTTACCAACAGAATAAGCACCGGCTAACTTCGTG
->URS0000ECE6B7 rRNA from 1 species 
-GGGCCCGCACAAGCGGTGGAGCATGTGGTTTAATTCGATGCAACGCGAAGAACCTTACCTACTCTTGACATCCAGAGAACTTTCCAGAGATGGATTGGTGCCTTCGGGAACTCTGAGACAGGTGCTGCATGGCTGTCGTCAGCTCGTGTTGTGAAATGTTGGGTTAAGTCCCGCAACGAGCGCAACCCTTATCCTTTGTTGCCAGCGGTTAGGCCGGGAACTCAAAGGAGACTGCCAGTGATAAACTGGAGGAAGGTGGGGATGACGTCAAGTCATCATGGCCCTTACGAGTAGGGCTACACACGTGCTACAATGGCGCATACAAAGAGAAGCGACCTCGCGAGAGCAAGCGGACCTCATAAAGTGCGTCGTAGTCCGGATTGGAGTCTGCAACTCGACTCCATGAAGTCGGAATCGCTAGTAATCGTAGATCAGAATGCTACGGTGAATACGTTCCCGGGCCTT
diff --git a/src/alphafold3/test_data/miniature_databases/uniprot_all__subsampled_1000.fasta b/src/alphafold3/test_data/miniature_databases/uniprot_all__subsampled_1000.fasta
deleted file mode 100644
index 318b0b77c80645da34d4d17e33cbdbec6b88e98a..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/uniprot_all__subsampled_1000.fasta
+++ /dev/null
@@ -1,2000 +0,0 @@
->tr|A0A3A3JCS5|A0A3A3JCS5_SALMO Octaprenyl diphosphate synthase OS=Salmonella montevideo OX=115981 GN=ispB PE=3 SV=1
-MNLEKINELTAQDMAGVNATILEQLNSDVQLINQLGYYIISGGGKRIRPMIAVLAARAVGYQGNAHVTIAALIEFIHTATLLHDDVVDESDMRRGKATANAAFGNAASVLVGDFIYTRAFQMMTSLGSLKVLEVMSEAVNVIAEGEVLQLMNVNDPDITEENYMRVIYSKTARLFEAAAQCSGILAGCTPEQEKGLQDYGRYLGTAFQLIDDLLDYSADGEHLGKNVGDDLNEGKPTLPLLHAMRHGTPEQSAMIRTAIEQGNGRHLLEPVLEAMTTCGSLEWTRQRAEEEADKAISALQILPDTPWREALIGLAHIAVQRDR
->tr|K8XEW0|K8XEW0_RHOOP LexA repressor OS=Rhodococcus opacus M213 OX=1129896 GN=lexA PE=3 SV=1
-MKDDSSTDGSTPRVSGGSAAGLTDRQRRVLEVIRTSVNERGYPPSIREIGDAVGLTSTSSVAHQLRTLERKGFLRRDPNRPRAVDVRGLDEVAAGVAANASASAAVGLAAVKSGADGAPLPEPTFVPVLGRIAAGGPILAEEAVEDVFPLPRELVGQGSLFLLKVVGESMIDAAICDGDWVVVRQQNVAENGDIVAAMIDGDATVKTFKRTENEVWLMPHNPLFDPIPGNDAVILGKVVTVMRKI
->tr|A0A0P0EB71|A0A0P0EB71_9MICO 2Fe-2S ferredoxin-type domain-containing protein OS=Microbacterium sp. No. 7 OX=1714373 GN=AOA12_02545 PE=3 SV=1
-MPRVTYIQPDGASSEVEASRGDSVMSAAIAAGVPGIVADCRGGLTCATCHVFVDEEWLERVGEKEPEEEEMLELTAVPATECSRLSCQIVLVDELDGLVVTVPEEQE
->tr|A0A212KYF3|A0A212KYF3_9DELT Uncharacterized protein OS=uncultured Desulfovibrio sp. OX=167968 GN=KL86DES1_10311 PE=4 SV=1
-MNFPFIPKIVAFARQHTLALAAAVLVLIVFVVSFSGWRYYQYRQSSQYAYEILRDALKTGDTETIAELVDFNSLSRGLAKDLAQNYPFLKAGADQERQIGDMIQTALLKQSRTKQEPVKDEPDLKIRLKTALYALPPDFLAQLASSLSLQPPNDGTALLTAKVRHPLLDKNFLLILRMDQTPTGWRVRQLVNSPELVRQFREAQVERMTAQRQMILDKNAATEKRMKELFPLQPCSASAGLISDGSTLLVVVHVLARDIGTVSVNNMNLFTELSSATGELLLTRYLNAVQPTHPGEDFERNWTIELDGNSELGRRVLNGQPLQCKGAWKTLGLDNGEVLHISEAPAPIEEFQ
->tr|A0A5H1ZRJ3|A0A5H1ZRJ3_DANRE Transmembrane channel-like protein (Fragment) OS=Danio rerio OX=7955 GN=tmc2b PE=3 SV=1
-XSSSSDNNSDDESMSEGEMARLKEEVEEKKKLIATLRNKPWRMKRRLKCLKEAQEFVEKFEGALGKGKGRRLYAFKVMMTKKLIKFNRDFENFKTACIPWESRIKEVESHFGSSVASYFIFLRWMYGLNLVLFGFMFGLVVIPELLMGIPYGSIPRKTVPREEQDSAMDFSVLFEFGGYCKYSILFYGFYNNQRTIGFLQFRLPLSYLLVGVGIFGYSLMVVIRTMARNANEGGDGGDEGNFTFCWKLFTSWDYLIGNPETADNKFASTTTSFKESIVDEQENLKDENIHLRRFLRLLANVLILCCLAGSGYLIYAVVKRSQDFAKRDRNELTWLQKNEVEIVMSLLGLVCPPLFEAIAELEDYHPRIALKWQLGRIFALFLGNLYTFLFALFDEVNGKLENEKQIKNQTVWALKEYYANYTLQYNITENIPPPNIAPADVIRGPCWETEVGIEFVKLTVSDIQVTYLTILIGDFLRALIVRFLNYCWCWDLEAGFPSYAEFDISGNVLGLIFNQGMIWMGAFYAPGLVGINVLRLLSSMYYQCWAVMACNVPHERVFKASRSNNFYMGLLLLVLFLSLMPVIYSIMTLPPSFDCGPFSGKDKMYDVITETIDKDLPPFMADIFSYASNPGLIISVVLLMVLAIYYLNAVSKAYQNSNLELKRKMQMQRDEEKNRRNNKDSTNQVMKDLEDLLPNKSLIPPPSVEETEKPAEQPSKSSKVTGKPGAAASGKGVHVQKDVSLAAANPRAPVTRAPGPRQPGPLPGNPRGPPPGQGMGRGRGGPPPRR
->tr|A0A1H1BTM6|A0A1H1BTM6_9GAMM Short chain dehydrogenase OS=Pseudoxanthomonas sp. CF125 OX=1855303 GN=SAMN05216569_1554 PE=4 SV=1
-MTADPNLDQTLQLLEAIAADRTVLDMWPEEERVRLHKAIASIYHPEPKLRRKKTKELERERHAEKLRRADALLDQTGIRALRRAPVFTTPNYFPPAGFVAQDNVEERPEPLESPELRHCYVCKKKYTQVHHFYDQMCPECAEFNFAKRTELADLSGRVALLTGGRVKIGYQAGLKLLRAGAHLIVTTRFARDSAARYAQEPDFEQWGHRLEVFGLDLRHTPSVEAFCRELSAKYPRLDFIINNACQTVRRPPEFYAHMMEAETAALRDTPEHVRKLLGSYEGLRSHDLLPEASALQVAIKQGFPEVAGLTHAAELSQVPLLAEELLGQKHLFPEGRLDQDLQQVDLRGRNSWRLQMAEVPSVELLEVQLVNAIAPFLINARLKPLMLRTPERDKHIVNVSAVEGQFYRNFKTTRHPHTNMAKAALNMMTRTAAADYHGDGIHMNSVDTGWVTDEDPVELAARKTVQERFHPPLDIVDGAARIVDPIIHGINTGEHVWGQFLKDYRPTDW
->tr|A0A217EZB4|A0A217EZB4_9SPHN Uncharacterized protein OS=Croceicoccus marinus OX=450378 GN=A9D14_19100 PE=4 SV=1
-MAAPLALAACGSGDDTEMMDDTAMAEGQMADGQMPMDGGDMSMMGSDSAMQTASAEGTVTAIDADAGTITVDHGAVPAIEWPAMTMAFEADEELRQDVAVGDTISFDFTTDESGNAITSITKK
->tr|A0A1C5RVT8|A0A1C5RVT8_9CLOT Uncharacterized protein OS=uncultured Clostridium sp. OX=59620 GN=SAMEA3545292_01435 PE=4 SV=1
-MSGLYTITLNGVSEEVYNKAADYIQAHALRLNYRPEVSTIDCEFPDDLDPAKAPELSEAVIRKVHQQL
->tr|A0A2M7MVT7|A0A2M7MVT7_9PROT Uncharacterized protein OS=Hydrogenophilales bacterium CG_4_10_14_3_um_filter_63_21 OX=1974028 GN=COZ24_06435 PE=4 SV=1
-MRTWLDLNGLCARKREQGEHPRPFWTLMKRYLPQNYRWNIVHEDDSLIIAGIEHGLHGHLGPNGARGNPKNLRSVGKANTGHTHSAGITEGVYTAGVFGQLDMGYNKGLSSWSHSFILTYENGKRTICTIRDGRAWR
->tr|A0A1H5Q8D7|A0A1H5Q8D7_9PSEU Transcriptional regulator, LacI family OS=Amycolatopsis pretoriensis OX=218821 GN=SAMN05421837_101914 PE=4 SV=1
-MTTKSDDPEPCASRVTIARIAAETGVSVPTVSKVLNGRPDVAESTRARVEAVIGKYGYRRRADERSRRSRLLELMFHELESTWALEIIRGVEYVARENGMAVVLAESSGRHTPGQSWLESVLARRPVGIVSVCSDFTGGQLAKLRARDIPLVVVDPAGAPGPETPSIGATNWQGGLTATRHLVELGHRRIAMIGGPDGVLCSRARIDGYRTALETAGLAFDPALVRRGDFHVRSGYRELASLLTLPDRPTAVFAGSDLQALGVYEAARDAGLRIPDDLSVVGFDDLPVARWLTPELTTIRQPLQEMAAAGARLAISLARGTHPESHRLELATSLVVRQSTAAPARRAVPAGRG
->tr|A0A1I0W1D7|A0A1I0W1D7_9ACTN NAD-dependent protein deacetylase, SIR2 family OS=Nocardioides alpinus OX=748909 GN=SAMN05192575_101623 PE=4 SV=1
-MTLAPTDRVESALDLLTTRPLVVLTGAGLSTDSGIPDYRGPGSTARAPMTYQEFVGSAEAQQRYWARSHLGWQRMGRALPNDGHRALAALDPVLLITQNVDGLHEAAGSRHLVALHGRVADVICLSCRTTSSRDDLEQRLDDLNPGWLEQHGWVESRPDGDVDLDDTSDFVVPTCACGGPIKPDVVFFGENVPADRVARCYAAVESLGPDGALLVAGSSLTVMSGLRFVKRAAQGGTPIVIVNRGATRGDPLASYTLDVGCSEFLTRLAELAG
->tr|A0A4W2HU19|A0A4W2HU19_BOBOX Ubiquitin conjugating enzyme E2 L3 OS=Bos indicus x Bos taurus OX=30522 GN=UBE2L3 PE=3 SV=1
-EGAEARGDARPQQVALLPQLFDLLVLGQQRARLLRQVPRALVGQGLAKLQARAALSGHRRAHGPQELEEIRKCGMKNFRNIQVDEANLLTWQGLIVPDNPPYDKGAFRIEINFPAEYPFKPPKITFKTKIYHPNIDEKGQVCLPVISAENWKPATKTDQVIQSLIALVNDPQPEHPLRADLAEEYSKDRKKFCKNAEEFTKKYGEKRPVD
->tr|H2DDU6|H2DDU6_9BACT Exported protein KikA OS=uncultured bacterium OX=77133 GN=kikA PE=4 SV=1
-MNRKMTVVSASLVGALSLFSQTAKADDWGCQVLLCLSDPRGPTTESECKPPIHKLWDHLRKGKPFPSCAMATNSRTGKRSYAQLVYDPYDPCPDGTKPAGGYIAQSQSADRKDWRRLQYAFSTHGRRYDSGGAWNMYEGNGPRACVGNHLGSYSVYRGNDDSNISVQVYDQVVWQQPQNPRAIDVFIDEAFHHRVRY
->tr|A0A7D7KQY5|A0A7D7KQY5_9MAGN Maturase K OS=Neolitsea pallens OX=344110 GN=matK PE=3 SV=1
-MEELQGYLEMDGFRQQYFLYPFLFQEYIYALAHGHALNGSILYEPVENLDHDNKSSSLIVKRLITRMHQQNRLIISVNDSNQNRFVGHNNHFDSQMISEGFAVVVEIPFSLRLVSSLEEKEIAKSHNLRSIHSIFPFFEDKLSHLNRVSDILIPHPIHLEILVQTLHSWIQDTPSLHLLRFSLYEYWNSNSLITPKNAISLFSKENQRFFLFLSNSHVYECEFIFIFLRKQPFHLRSKSFGSFLERTHFYAKIEYLVVVLCNDFQKTLWLFKDSFMHYVRYQGKSILASRGARLLIKKWKSHFVNFWQCHFDLWSQPARIHIKQLYNHPFHFLGYLSSVRLNSSVIRSQMLENSFRIDTAIKKFETVVPIIPLIGSLAKAKFCNVSGHPISKPFRADLSDSEILNRFGRICRNLSHYHSGSSKKQSLYRIKYILRLSCARTLSRKHKSTIRAFLKRLGSEFLEEFFTEEEQALSLIFPTTSSPSHRSHRERVWYLDIIRINDLVSHL
->tr|A0A839YFJ7|A0A839YFJ7_9SPHN Glutamyl-tRNA synthetase OS=Sphingomonas sp. BK580 OX=2586972 GN=FHY05_001379 PE=4 SV=1
-MSATEINERAVVTRFAPSPTGFLHLGGARTALFNLLFARHHGGTFRLRIEDTDRARSTQPAIEAILNGMRWLGLDWDGEEVYQFARADRHAAVAHRMIEAGHAYRCYLTSEELDAMRAAAQAAKQPLRIRSPWRDRTDWPADQSYVVRLRAPTEGATTIHDRVQGEVTVQNAELDDLVLLRSDGTPTYMLAVVVDDHDMGVTHVIRGDDHLNNAFRQLPIYRAMDAIEGGWPDPVYAHIPLIHGSDGAKLSKRHGAVGIEAYRDEMGILPEALDNYLLRLGWGHGDEEIIAREDAVRWFDLDAVGKSPSRFDLKKLEHLNGHYIRASDDSRLADLVAEKLGLDRDDTRRAVLAAAMPALKPRAANLNELADGTAFLFATRPLVIDTEAAPLLAGEAPALLARLHAALDAVHNWDTETIEAAVRQVADAAGVKLGQVAQPLRAALTGRRTSPGIFDVLVLLGRDESLARIADHQA
->tr|A0A1B3Z9R2|A0A1B3Z9R2_9SPHN Uncharacterized protein OS=Sphingomonas panacis OX=1560345 GN=AWL63_09520 PE=4 SV=1
-MFDRCNDKALTVVSMCDDVPPAPERRSDARNLSILKAAILRTALGEELCLVRNISRGGLMAHIFSELEVGDPVKIEFRSSKIVRGRVVWRRPELMGVRFSQFIDIGEILTDPKPQPSHAARAPRVTVNVPARLRSGGRYQAAALGNISQGGARIYLSEPDRLGDDVVLSVAGLPVLTGSVRWRDDTAAGIAFSELLAFEDVGRWVSSHNIGVPPQLVE
->tr|A0A7V8Z0K8|A0A7V8Z0K8_9BACT 2,3-bisphosphoglycerate-dependent phosphoglycerate mutase OS=Blastocatellia bacterium OX=2052146 GN=gpmA PE=3 SV=1
-MHKLVLIRHGESEWNKENRFTGWKDVDLSEKGREEAQAAGKLLKAEGFTFDESYTSVLKRAIRTLWIILDELDLMWIPETKSWLLNERHYGALQGLNKAETAAQYGEEQVQIWRRSFDIPPSIMEETDERHLGKDPRYCEIEAGKFPGSECLKDTVARVIPYFETAILPKVKDGKRIIVAAHGNSLRALVKYLDGISDTEIVNLNIPTGIPLIYELDDDIKPIKSYYLGDNEAIRKAQEAIANQGKAK
->tr|A0A3C0TX47|A0A3C0TX47_9PROT Ribosomal-protein-alanine N-acetyltransferase (Fragment) OS=Alphaproteobacteria bacterium OX=1913988 GN=DCO82_10580 PE=4 SV=1
-VATHNEAAISLYKRQGFIAAGLRKAYYAPEPGQSTSTDALIMRCNL
->tr|A0A1M3DHD8|A0A1M3DHD8_9SPHN DUF4142 domain-containing protein OS=Sphingomonas sp. 67-36 OX=1895849 GN=BGO24_13795 PE=4 SV=1
-MKLAAMTMTAAALALTACGHKETTTTMTTDNTVVATNDIAAVPTPSGGQSFANTAAASDAFEIATSKLALDKSGSAAVKKFAQKMIDAHTGSTARLKAIAAGAVPAITPDPTLTAGQQATVDSLKNLTGPDFDKAYAAAQVDGHQKTLDALKAYAATGDVPAFKDFATNLVPTVTAHLNMAKSLKP
->tr|A0A661FLP6|A0A661FLP6_9GAMM ThiF domain-containing protein OS=Gammaproteobacteria bacterium OX=1913989 GN=DRR11_20880 PE=4 SV=1
-MTTDYTARFARQITLPQIGTVGQQRLADSHALIIGLGGLGSAASLYVANSGVGRLTINDFDRVDITNLPRQILFTEQDIDEFKTTATAKRLQQINPGIQIDEINQRLTEAALHEAVAASDIVLDCTDNFVTRGAINRACYAAQRPLITGAAIRFEGQLAVFRHDVPRGRHLPDNPCYNCLYTEEDENLEGCAGQGILAPVVGTIGCMMATEAIKLLAGIESLLNGKLWIYDALSVTTKTVRINARVDCPVCGVKA
->tr|A0A225NGS3|A0A225NGS3_9RHOB PMT_2 domain-containing protein OS=Marinibacterium profundimaris OX=1679460 GN=ATO3_21925 PE=4 SV=1
-MRLGVLAVLALTLYRVVLLAFASADLFVDEAQYWAWGQNLEFGYYSKPPLIGWVIRAFTEVAGSDAPFWIRLPGPLFHGAAALVVLATARRLWGDVAGAATGIAYASMPGVALGALLISTDTILLPFFALALFFWLKLTERSSAGVALAMGAAVGLGMMAKYAAIYFVLGALFSVIFVRGARISWRDAALAALAFLVVFAPNILWNLQNGLTTVSHTADNVDWINDPSTRLRLNFSGLAEFFGGQFGVMGPVFFAAYLVVVARKIVTGDWPARWLIWMSLPIILLVCVQAILSRAYANWAAPAYVAAVILTAPWLFDRARRIYCAALGINLALSLALPLAAVFATSWTLNDRLVLGRYVGRAEASARILSTAREAGLTDVVATSRDLLADLFHAAKGTGIAPWSVPFEGHVPHYYAQRFPYPTGQSAPALYADFADVPPLCAPGTEVTELTRWDIPGGAYRGRTLVAWRVGPGCWTD
->tr|A0A0E3SH12|A0A0E3SH12_9EURY Uncharacterized protein OS=Methanosarcina horonobensis HB-1 = JCM 15518 OX=1434110 GN=MSHOH_2470 PE=4 SV=1
-MIMNEHKTLWEKYFLNFRNVASPLRKPALFDWLYNSYRCLYLSCVDPSLVSRLTDLKTCLSMIGVAVDDSCDYALLREKNGGDKFSYEILSMLYNTDKIESGDYILLDAHLTNNMYIKTTIGIYSDLVRNQIASLPRYCDFRGEFLLAMRNVAESMEFSYLLNKNKIVYPFSHVVRSRAASTMIETHSLLDLMSSKNFDTSELGKAIVLFKLADIVAMLSNTINTWTREITERDYSCPVISLALEKKLIKFSDFERASTENLKEKLSPVSEVIEDELDKAILSMKEFAENSEIKSFDTSKFVNNYVNLYWQTDAMN
->tr|A0A6P1BJ03|A0A6P1BJ03_9BRAD Isoprenylcysteine carboxylmethyltransferase family protein OS=Bradyrhizobium uaiense OX=2594946 GN=FNJ47_21045 PE=4 SV=1
-MNETSNPPRINLRRAAFTFVGLGTLLFLAAGTMRWAGAWVFLLEITIGGLITEAWLARHDPGLLAERRTARGQAGWDRIITSIMPLLWLTWLPLMALDAVRYQTSFIPVWLQCTGALMIAASFYIAYRTYRENSYAAPVVKIQRERGHTAVTTGPYAYVRHPIYAGGLLTYLGTPLLLGSWYGLAIVPVMAALLGLRSMMEERMLTAELDGYADYIARVRYRLVPMVW
->tr|A0A7X6LY41|A0A7X6LY41_9NOCA Respiratory nitrate reductase subunit gamma OS=Nocardia veterana OX=132249 GN=narI PE=4 SV=1
-MTSTVWATLPYIAFTSFVLGHLWRYRNDQFGWTTRSSQIYESRLLRLGSPLFHFGMLGVIGGHVLGVLIPQSWTDAVGISEHLYHVIAVAAGSVAGVAVIAGIAILAYRRLRVPAVRKATTRNDVFMYVLLAAALITGLLNTVGSNLLWGTYNYRETVSPWFRSLFTAHPQPDLMVGTPWTFQAHGLIVLTLIAVWPYTRLVHMFSAPVGYLVRPYVVYRSKPVDTANKRKYARAWQTPVLPR
->tr|A0A508XB42|A0A508XB42_9HYPH Diguanylate cyclase OS=Sinorhizobium medicae OX=110321 GN=EMEDMD4_790360 PE=4 SV=1
-MELQESAIYAGPPIASPEVRSQLLRPAVMAEVERLLGGRTRDIRLKGELGRLFEERSWSRTAKIIRAWMIWVTLLDVLTLGLNAILLPNAVALSMLPPACILPPAALATAFIWRKPRGVGLQRVSLVAGLFLILLSVALVGVSAGGEFYERHLNIMLFVAITAIIIFSIPLAWTVAVASFALALYLIFQLRNPMLDTGSAVAGTLFFTSGIVATVVARRTMTILAQKTFLLELRDKRRVAELADANARLERLAKTDPLTGIANRRWMMETLNRLWGAGAERPAGTAMLMCDIDDFKSLNDRLGHAEGDRCLVKVAGIIQSSVRRNRDHVARYGGEEFLVVLPGADVQAALATAERIRASVEAASLPNPASRVAPYVTLSIGVAAQGAAGEIIEPEKLQNQADTALYLAKQAGRNRVVLFRPE
->tr|A0A820L477|A0A820L477_9BILA Hypothetical protein (Fragment) OS=Adineta steineri OX=433720 GN=OKA104_LOCUS48766 PE=4 SV=1
-VAYGGTTMHGIRHYCQFPFIYQGKQYTNCISDKPPHATPDQTVFDPWCSLTHNHDIDDQWGFCDIGVTDSTIYSICQNQLQTIQCSPGYVIDILTADYATKQDGTNSCNYNKNDCFQSDASTIENLCSGKTSCTVYHYAKTLVSCQNRLSTYLQIDYTCVPNDIETIMTYDICNNDSKPSGDIRRGFLISPNFPNVKNNINCIYDLHILKPHQD
->tr|A0A841MMF6|A0A841MMF6_9CAUL Two-component system response regulator FixJ OS=Caulobacter sp. YL-Caulobacter OX=2723104 GN=HDO15_004474 PE=4 SV=1
-MSDAAPIGAQVVHVVDDDESARESLAFLLESADFEVAAYASAPAFLDALADARPGVIITDVRMPEMSGQELVARLGALKVKMPIVMITGHGDIPMAVEAMRSGVVDFIEKPFSESRMLDALGRAFKSVEAAPASNDQTAILKRIETLSERERQVLDGVVAGHANKVIARELGISPRTVEIYRAKLMTKMQADNLAALVRMTLSARGE
->tr|A0A1E2YF14|A0A1E2YF14_PARBR GTP-binding protein rho2 OS=Paracoccidioides brasiliensis OX=121759 GN=GX48_00269 PE=4 SV=1
-MAQQQLQQLQTENVMRRYVDGKHLWSWKLVIIGDGACGKTSLLSVFTLGYFPTHYVPTVFENYVTDCRVDGRSVQLALWDTAGQEDYERLRPLAYSKAHVLLIAFAVDTPDSLENVRNKWIEEANERCPDVPIILVGLKKDLREDPLAIEEMRKKSLRFVSSKEGHDTAAQVGARKYLECSSLTGEGVDDVFEAATRAALLTFEKDRGSCCVIL
->tr|A0A6N9C681|A0A6N9C681_9BACT FRG domain-containing protein OS=Candidatus Poribacteria bacterium OX=2026781 GN=F4X33_06180 PE=4 SV=1
-MNTQNSTDLQDYYLNGLNKIINEIMEKSADGNYIYRGEPKCYPTIASQLYLNRYAESNQRLTPIDVAQAFEIVMASNYLDSEAEKEFFPIASELRHYGSPVNYLDFTTDYNIALYFACAKHFACAKLGEDGHGKDGRIVLLQRNKETKEKYQIKPVQDPPNRAKAQKSVFVEPPDGFILSNDKDVKTVCIPKELKQWILIHLHRFQCISYQTLYHDIYGYIAQKDLRASAEEKHKSHEGTERWHIAQIEHSPYSVRYYYDLACYYGKDMYKYDCAIETFSKAILLKPDSVFAHINRGISYARNNILDRAIQDFVKVIPMLFKFPFSDALFLVYKSLGQVYDIRGDCHSAIEYYQKAQQLRFDDPVVAAYLDKSKRPQLSKLEYYVR
->tr|A0A1H0ZCM6|A0A1H0ZCM6_9MICO DNA-binding transcriptional regulator, LysR family OS=Leucobacter chromiiresistens OX=1079994 GN=SAMN04488565_1638 PE=3 SV=1
-MNLEQLRGFVEIAQLGNFTRAAERLHLAQPSLSRQIAALETDLGVELLHRVRGHVAATPAGERLLPIARRMLADAETARHEMSDLAELRGGRIRLGATPTLCTSLVADVLAEFRARYPGIEIEILERGSRSLISALMEGALDLALIVTSVSSGAARAVLEREQILSERLVVVSDPNRPDPFAPEGAEARDPGRPVDLEELARVPQVLFPENYDLRATVDAAFRARGLTPLVAVAGAEMDAALSFARRGIGVAVVPAMVAADRPALRTAPLADDALARTVSVARRADMAPTRAGAALQAVIREIADRVTAPGAELSSLVTRVGEPAPLRSAAPPPA
->tr|A0A1G6ZFJ8|A0A1G6ZFJ8_9BACL Uncharacterized beta-barrel protein YwiB, DUF1934 family OS=Paenibacillus sp. CF095 OX=1881033 GN=SAMN05428987_0174 PE=4 SV=1
-MSNMRPVHIRLHSRYEGEDVLQEMQGEAVLKGSVLYVRYEEPQVGPEGGTTRTTLKLGGQSIKIIRHGEVESEQTFELNRKLPGFYRSPYMSFALSTHTQKLELSIQGLSARAAWSYDFYRFDEESGHFAISLHIQEEPIS
->tr|A0A654FXQ0|A0A654FXQ0_ARATH (thale cress) hypothetical protein OS=Arabidopsis thaliana OX=3702 GN=AN1_LOCUS20985 PE=4 SV=1
-METPGASHDSFRGSPRRNSILSASNIIQAPISTLLEYSGLFRARPSPSHEAETLVSDDSSGLSNGEVAIRIIGNTEQDAETDTNALREPGHSELLGSSATQVDPMGGASEGASQAAPGDPAAGDAASRDSPYQRYDIQQAARWIEQILPFSLLLLVVFIRQHLQGFFVAIWIAAVMFKSNDILKKQTALKGERHISALIGISVAFTAHVVGVYWWFRKDDLLYPLIMLPPKSIPPFWHAIFIIVVNDTLVRQASMIFKCFLLMYYKNSRGRNYRKQGQLLTLVEYFMLLYRSLLPTPVWYRFFLNKDYGSLFSSLMTGLYLTFKLTSVVEKVQSFFTALKALSRKEVHYGSYATTEQVNAAGDLCAICQEKMHTPILLRCKHMFCEDCVSEWFERERTCPLCRALVKPADLKSFGDGSTSLFFQIF
->tr|A0A7K9WNV0|A0A7K9WNV0_9PASS DMXL2 protein (Fragment) OS=Rhipidura dahli OX=667186 GN=Dmxl2 PE=4 SV=1
-LTGAQDGSVRMFEWTRPQQLVCFRQAGNARVTRMYFNAQGNKCGVADGEGFLSIWQVNQTTSNPKPYLSWQCHSKTTSDFAFITSSSLVATSGQSNDNRNVCLWDTLVSSGNSLIHAFTCHDHGATVLQYAPKHQLLISGGRKGYICIFDIRQRQILFTFQAHESAVKALALDPSEDYFVTGSAE
->tr|A0A7Y9UAN0|A0A7Y9UAN0_9CELL YCII domain-containing protein OS=Cellulomonas hominis OX=156981 GN=GGD73_001711 PE=3 SV=1
-MPSLWHERPEEPPVGHDAGMPIFAVRYTYDARTDLQDAIRPEHRAYLQGVAERGELLGSGPFPEGPAGALLVFRTADRDALDAVLTADPFALAGVIAETEVRTWNLVLGPWAEHPAG
->tr|A0A660XH96|A0A660XH96_9BACT TonB_dep_Rec domain-containing protein (Fragment) OS=Candidatus Marinimicrobia bacterium OX=2026760 GN=DRP89_06950 PE=4 SV=1
-AETFKSPELGDIEHRQLLAVIPGLSIRSYGGPAGITTLSLDGGPSSQTKVIVSGFDLTNAQNGEMDLSQLPGPFVENVSYIPQDENFYGSGSNESTIHLNPWSGKSGLSLSTGSYGHSSIHGTLNLHKNQWIGNFLIGKRHDDGNYPFKWRNESFKRENNYFDQKFISAQFNTVIQKRAFLRFLYLLSNQSRGIAGQSWNPSKNANRDDKLQIIGVKFGWTNKKGHGYIQTMYRYSWENYKNPMIAVNSFHRLSTWQFILNQEKKINEKIGVNLLFETKKDGLKSKDTNNHYRISYSTAITVPYFLSKTFKFQPAYCYDISPNLYYEHSYVLKLLTSLNFLFIKSLTIHQGRYFRYPTFNDLYWIPGGNPNLKPEHTDNVSLDINCHLIQDSDLEILLFYKSSDDLIQWTPISSYWQPKNIQHAVRKGYKIIYRWNSQNIPLEAFVHYSSNRTKDLSQGNCYGKPLRYAPEQTAAVGINWQPEPLSFHLQIHHTSERISMYSWPEDVILSEATLIFTSCAYTWKRPSGDIIIVFAMDNLTDKRYETIKGYPEPGRTFRMTISYQH
->tr|A0A2U0ZQI9|A0A2U0ZQI9_9BACT ATP synthase subunit beta OS=Filimonas sp. YR581 OX=2135469 GN=atpD PE=3 SV=1
-MSNKGKIKQVIGAVVDVHFENDHSLPEIYNALEITRPSGEKLVLEVQQHLGEDSVRTIAMDGTEGLVRGMEVIDTGKAIAMPTGPGINGRLFNVTGDPIDGLPALSKTTSRPIHALPPKFEDLSTATEVLFTGIKVIDLIEPYAKGGKIGLFGGAGVGKTVLIQELINNIAKGHGGLSVFAGVGERTREGNDLLREMIEAGIMKYGDKFIHSMEEGGWDLSSVDMEGLKESKATFVFGQMNEPPGARARVALSGLTIAEYFRDGDGTGKGKDILFFVDNIFRFTQAGSEVSALLGRMPSAVGYQPTLATEMGLMQERITSTKSGSITSVQAVYVPADDLTDPAPATTFAHLDATTVLSRKIADLGIYPAVDPLDSTSRILTPAVVGEKHYNTADRVKLILQRYKELQDIIAILGMDELSEEDKQIVSRARKVQRFLSQPFHVAEQFTGLKGVFVSIDDTIRGFNAIMDGEVDEYPEAAFNLVGTLEEAIEKGKKLLAQAQG
->tr|A0A231W898|A0A231W898_9BACI 2-dehydro-3-deoxygluconokinase OS=Bacillus sp. OG2 OX=1979526 GN=B9K06_14550 PE=4 SV=1
-MDVITIGETMVLFTPQTTGLMRYANQFSMTFGGAESNVAIGLTRLGHKAGWISKVGNDEFGKAMLSFISGEGVDTTQVLIDSEAPTGVYFKEPRRANDVRVYYYRKDSAASRLEPGDINEEYLSNANYLHLTGITPALSDNCRELVYEAVAMAKKHGVQVVFDPNLRKKLWPEDQARKVLLDLASKAAIVLPGIAEGEFMFGEKDPVKLGRLFLALGPAVVVLKLGEEGCMVFTKDLQAKVPGFPVDRVIDPVGAGDGFAAGFLSGMLDGLSLEDAATRANAVGAFVTMVDGDVEGLPEKDEILGMLENKFDDVSR
->tr|A0A0B7HH50|A0A0B7HH50_9FLAO Tetratricopeptide repeat protein OS=Capnocytophaga cynodegmi OX=28189 GN=CCYN74_100115 PE=4 SV=1
-MTKKYLLIFIIVALILTILAFVFLPKKDSYSKIEKVDIVTNQGYAGSHSCKECHEQEYAEWELSDHFKAMQHADDKTVLGDFNDVTYTADGITSRFFKKNGKFYINTEDENGKYRDFEIVFTFGHYPLQQYLTKFGGGKMQVFRQSWDSRENKWFHQYAGEKIPPGDYLHWTNAGQNWNLMCSTCHSTNLQKNYNPLKDTYKTTYDELTVGCESCHGPGKKHNDFMRSSDYQKGISKNFFITLGVNTPQKTELNTCMPCHARRGEVTQHHTASDEIMDNYIPEIPITNIYFADGQALDEVYKYGSFLQSKMYHVSIKCTNCHLPHSGKLRMQGNQLCLQCHTPNYATSAHTFHKENTEASDCKSCHMPTRTYMGNDIRHDHNFAVPRPDLSEKYGVPNACNACHNDKSAKWASQAVEKWYGKERRPHFAENLIIGSLQNEKSLERLNELLTNSATPDIIRATAVHYLGGIYTEQSLQLVKKELNNSDAQTRYRAVIALGNFPIHLYENELISLLSDKVKAVRIATAYVFLSQKGWEQSKLLTSFESARKEYETFVLSQADFPVGSATAADYFTHLGDTDKAILFYERAIKKDKTLNHVRLNLATLYNGKGQNDKAWQILHQAQNYAPENAQVYYFMALLSSEEKDYNQAKKYFEKAMQLGMNNENIQRNYQSVIQIINKKN
->tr|W2ZLA7|W2ZLA7_PHYPR Uncharacterized protein OS=Phytophthora parasitica P10297 OX=1317064 GN=F442_06838 PE=4 SV=1
-MQTRASIFAQHIPALHHVSSTLYRSQSAAVAASSPLSRVTSDRPAIRQQSRPDGDNG
->tr|A0A1F9MIM0|A0A1F9MIM0_9DELT Metallophos domain-containing protein OS=Deltaproteobacteria bacterium RIFOXYA12_FULL_61_11 OX=1797896 GN=A2284_00320 PE=4 SV=1
-MVPTAADLVPFSIVLVPDTQYYTSKQGNGEENTYWKQMRWIRDHRETENILMAVHLGDITGSNEPEQWEIASAAHRILDQADLPYSVVPGNHDYLGKSSASFRSRTFFDSHFPASRFSGRAWFGGSLGSSNVNNYTLFENGAQKFLVLSLEYAPRKDTLCLAEDLLARHPDRRVIVATHCYLTKGGAYAEGCPNPDYGTVGAAGETVWDEFVSRYSSIFLVVSGHVNESAHAPRTGNAGNTVQQLVVDYQAEAACNAKSPDQCNDHCKAGTYTGNGWLRQLVFDPAVGQVQARTFSVEDGNTSVFPGGHPVLFCSELNKQGNDDYPSDPLAPDHAFSFTYEPLWTKPFVREDLGRRSFLDRTVNSVGEGQQERPAVAMAENGDFVAVWEDDSSKADGAGNRDIFLRGFLAGGCQKFPAQVINGNQNGQQRHPAVAVDRDGRAVVVWEDDTDGNGVFQVKARGFHADGSERLPVFTVNSEASGQQRNPAIGMSSDGRFVVAWEDVAGGNGAQILVRGFNADGSPLFPDRSGHTDTAGQHLEPTVALDASGAFVVAWQDDTDGNGYYQIHARGFDSAGKERFPKIVVNSVDTGQQYRPSLSLDQAGHFVVVWEDDQDKDGNSNLLARGFNADGTARFSDFAVVAGAGTHAAPSLAAGTDGSFVVAWQDDGDGNGTSQIHAKAFRADGSEWQARWTVNLQSAGQQLSPSVALAGKTLVVAWQDDLDGNEVYQILARGVDLP
->tr|A0A1S7RCV2|A0A1S7RCV2_9HYPH Uncharacterized protein OS=Agrobacterium sp. NCPPB 925 OX=1631629 GN=AGR6A_Cc80407 PE=4 SV=1
-MSAEPVDTNDAYRPIMETVSTMVSSIDLSTRLTATRLALKAIKQQDDSSADQSSSTRTALLSSYGIDSSSSTNTRLAQLLAQYGEASGDDTQTEGTDTQPSSGDITKADFMKGLKGMLEELSKDPDKASQANAMLEALKAGTLTVSDPAEGARIKAWDVASDTETASKPSTEITTTGWSDFLKEHLKRDGSIYAKGASGAYVDTISGDNAFFGSVGSRYYYLTWPQAKNGTLTV
->tr|A0A5X5WLM0|A0A5X5WLM0_SALET Diol dehydratase reactivase subunit alpha OS=Salmonella enterica subsp. enterica serovar Corvallis OX=593905 GN=pduG PE=4 SV=1
-MRYIAGIDIGNSSTEVALARQDETGALTITHSALAETTGIKGTLRNVFGIQEALALVAKRAGINVSDISLIRINEATPVIGDVAMETITETIITESTMIGHNPKTPGGVGLGVGITITPEELLTRPADSSYILVVSSAFDFADIANVINASMRAGYQITGVILQRDDGVLVSNRLEKSLPIVDEVLYIDRIPLGMLAAIEVAVPGKVIETLSNPYGIATVFNLNADETKNIVPMARALIGNRSAVVVKTPSGDVKARAIPAGNLELQAQGRTVRVDVAAGAEAIMKAVDGCGKLDNVTGEAGTNIGGMLEHVRQTMAELTNKPSSEIFIQDLLAVDTSVPVSVTGGLAGEFSLEQAVGIASMVKSDRLQMAMIAREIEQKLNIDVQIGGAEAEAAILGALTTPGTTRPLAILDLGAGSTDASIINPKGEIIATHLAGAGDMVTMIIARELGLEDRYLAEEIKKYPLAKVESLFHLRHEDGSVQFFPTPLPPTVFARVCVVKPDELVPLPGDLALEKVRAIRRSAKERVFVTNALRALRQVSPTGNIRDIPFVVLVGGSSLDFEVPQLVTDALAHYRLVAGRGNIRGSEGPRNAVATGLILSWHKEFAYGQ
->tr|A0A4S1A4Z3|A0A4S1A4Z3_9BACT LPS biosynthesis choline kinase OS=bacterium M00.F.Ca.ET.156.01.1.1 OX=2563902 GN=EN799_28860 PE=4 SV=1
-MTDDLRAALATVPVLAGYDGPLERLGGLTNMVYRAGDVCLRIPGKGTEEYINRANEAVAAREAAKAGVSPEVLYADPETGRMATRFIAGAETMSPEKFKTRKGSAARAGEAFRKLHRSGAVFPFRFELFAMIDDYLKVLSTKDVALPAGYHDVVREAGSVRAALDAHPIELAACHCDPLCENFLDTGERMWIVDWEYSGMNDPLWDLGDLSVEGKFNEAQDEELMRAYFGGEARPAERGRVVIYKAMCDLLWTLWGLIQLANDNPVDDFRAYADGRFARCKMLMETAEFSGHLAAVRLG
->tr|A0A5B8NLP5|A0A5B8NLP5_9CHRO 50S ribosomal protein L35 OS=Euhalothece natronophila Z-M001 OX=522448 GN=rpmI PE=3 SV=1
-MPKLKTNRAAAKRFRATGRGKIRRRKAFKNHLLEPKKTSRKRRLSKLTFVNERDAEKVEQMLPYMK
->tr|A0A098VY33|A0A098VY33_9MICR ATP-dependent Clp protease proteolytic subunit OS=Mitosporidium daphniae OX=1485682 GN=DI09_143p40 PE=3 SV=1
-MQLIKAPVYTIAMGMAASMGSFLLAAGAPGHRKALPNSRIMVHQPSGGATGPAADIEIAAKEILRLRTLLNEIYARHTGQSLSTIERALDRDRYMTPEEAAGFGLIDGVLNATPSRQIL
->tr|T2IPC9|T2IPC9_CROWT Transposase OS=Crocosphaera watsonii WH 0005 OX=423472 GN=CWATWH0005_4898 PE=3 SV=1
-MGLCVVQIAKVLNLNYCYRIYPDSSQEKELLDWLEICRGVYNYALRERKEWINSRKCKVNACSLHSEYIIPADQPFPDYYKQKKALTQAKKEYPSLKRVQSQVLQQVMGRLDKAFNFFWKRSFGFPRFKKYGQYRSINFPQFKENPITGYQIKLPKIGSVRINLHRPIPDGFVVKQVQIVKKASGWYAVICIQSDVKVPSPQPQGKSLGIDLGLEKFIATSQQELIARPRFFVELQSKLQWLQRRLSKKQKGSKNWHKAREKVARLHEHIYNTRKNFHYQVAHHLCDQANIIFAEDLNLKAMSRGMLCKHTLDAGFGGFLEILKHVAWKRDVYFEKVDANLTSQTCPNCGMVTGKKDLSQRVHECSNCGFITDRDVAAAMIVEQRGLAALGLGVKLPVEDEVIGDVRKKSSRASRRSRKAS
->tr|A0A1G1DFT8|A0A1G1DFT8_9BACT Uncharacterized protein OS=Nitrospinae bacterium RIFCSPLOWO2_01_FULL_39_10 OX=1801683 GN=A2889_02485 PE=4 SV=1
-MVAVRRKLLTAQKMRKIYRRVKSVCLSVCLSVCLCKVDTILFIPHPPPSPQPSPRGRGREGQGEREYQ
->tr|A0A524FY20|A0A524FY20_THOAR Response regulator OS=Thorarchaeota archaeon (strain OWC) OX=2053491 GN=EU527_15255 PE=4 SV=1
-MALEDAGFDVVAEAEDTENLLIQCQGNRPAVVIIDFNMDQIEIVRLIEHLLDIDPIVAIVVISDIADGQTEMVLAAGARAFLQKPFSMYDMTDIVRKVKPVY
->tr|A0A853UB48|A0A853UB48_9MICO Uncharacterized protein OS=Dermabacter sp. HMSC06F07 OX=1581125 GN=HMPREF3157_09225 PE=4 SV=1
-MRGVSAKSLQSVLRRAAESTSANTPSTEIASELFEAVRVIDSSNQLVRLLSDPGRDEDLKADVVRRLFGGRVSEAALEVLLEASRCTWSEQNHLLEGIEFAGVSLVLDKARGRGTAHAVEEELFQVARLVEDTPELSEAFDSKRDDVPARVGIIERLLGGKVDEATVALAAQAVSFEPEAKVPARLLEFANFASAERDRRSGVVTSAIALSPEQQERLTRILSARYGGELSLNYEIDPSVIGGLRITIGDDLYDATIFGRVRDARERISA
->tr|M0J625|M0J625_HALVA Uncharacterized protein OS=Haloarcula vallismortis ATCC 29715 OX=662477 GN=C437_14607 PE=4 SV=1
-MSATEETVRVWLVERTYSDDEQNLIILTYATPDGDQYFRKERALTSFSDVRETTAAVDADPDNLGSVDDPDLQAQYAAEATRMAEKHDPDDAI
->tr|A0A2W5SS74|A0A2W5SS74_STANO Uracil-DNA glycosylase OS=Starkeya novella OX=921 GN=DI549_11565 PE=4 SV=1
-MASPSETLDDVLAAIRACRVCVEHPLGRPLPHEPRPVLHMGTRARILIAGQAPGTKVHGSGLSFNDRSGDRLRDWLGVDRETFYDGDSIAVAAMGFCFPGQDAKGGDLPPRRECARLWHDRLFAARPPFDLVVAVGATSQAYHLKRLGLERFATGGLTERVMRWREIWAASNQTRVLPLPHPSWRNTGWLKRHPWFEAELLPVLRQEVARIVGSAREGREPREPA
->tr|A0A3G8GEA2|A0A3G8GEA2_9BURK Acylphosphatase OS=Pigmentiphaga sp. H8 OX=2488560 GN=EGT29_00430 PE=3 SV=1
-MQELDSTAPLETVLVRVTGRVQGVGFRLATVRRAHLVGVGGWVRNNEDGSVEALVQGTPDQVDQMLEWMRQGPPQARVDDLASERQFIDRRFARFEQQ
->tr|W9AG96|W9AG96_9BACI Glutamate racemase OS=Oceanobacillus picturae OX=171693 GN=racE PE=3 SV=1
-MEQAIGVIDSGVGGLTVAYELMRQLPKEKLIYLGDTARCPYGPRSEEEVKKFTWELVDFLLEKNIKMLVVACNTATAFTLQELQEKLDIPVIGVIQPGARAAIKFTRNNNIGVIGTEGTIRSEAYTKALESIHSSIKVNALACPLFVPMVEQGILTGKKAQEVVESSLSPLMEGEMDTLILGCTHYPLLKQTIQNVMGEQVTVISSSEETARETSTILDVHNIIKTGDVIPVHEFYTTGELEIFIEIAKSIFKDPYLQMVTIKKAQLGQTQKT
->tr|A0A5D2YB87|A0A5D2YB87_GOSMU HIT domain-containing protein OS=Gossypium mustelinum OX=34275 GN=E1A91_A08G187300v1 PE=4 SV=1
-MARAISPCIFCQIAGSSNSTPLLHSVRSLDDKVVAFKDINPSAFRHYLVVPVEHIPTVNDLQRRNEDYTLVSHMINVGETLLRRDAPQSNQYRFGFHQPPFNSVDHLHLHCFALPFIPRWKQLKYMSLGPLGGFIEAEKLLEKIKPLSPIPP
->tr|A0A1L8DSH3|A0A1L8DSH3_9DIPT Putative ubiquitin carboxyl-terminal hydrolase 46 OS=Nyssomyia neivai OX=330878 PE=4 SV=1
-MGANISQLERDIGSDQFPPNEHYFGLVNFGNTCYSNSVLQALYFCRPFREKVLEYKAKNKRTKETLLSCLADLFYSIATQKKKVGSIAPKKFIARLRKEKEEFDNYMQQDAHEFLNFLINHINEIILAERNIKGKITTGNTETPPEPTWVHEIFQGILTSETRCLNCETVSSKDENFFDLQVDVDQNTSITHCLKCFSNTETLCSDNKFKCDNCCSYQEAQKRMRVKKLPMILALHLKRFKYMEQYNRHIKVSHRVVFPLELRLFNTSDDALNPDRLYDLMAVVIHCGSGPNRGHYISIVKSHGFWLLFDDDMVDVYIFLNCARKKN
->tr|A0A428EVY3|A0A428EVY3_STRIT Uncharacterized protein OS=Streptococcus intermedius OX=1338 GN=D8829_03240 PE=4 SV=1
-MTKRYNINKIFESIITSRTRETFEVTESLIELGKIVGTRPVAFKQLYKAYRSLETSFSYTPVIGAPISCRFDYDKEEATLAYLDLSADLSLADFTDFMGVIDSVYSSIYPIGTVVELDLDLLPPHLHRLFTDGPGALVTITGRKLPVRGKFGEYIVDYLARLWPFGELPGVAPIYVNNMMIRQVHQEGLRNDWEDEFTEDILRSNQLSAQLVSTAFMRKEDNAVYVQELLKEATHELSH
->tr|A0A436AXU5|A0A436AXU5_9HYPH Antibiotic biosynthesis monooxygenase (Fragment) OS=Mesorhizobium sp. M7A.F.Ca.CA.001.08.1.1 OX=2496691 GN=EN913_26470 PE=4 SV=1
-MSGFVVWVDFRLKPGARGRFRELVDANATASVRREAGCRRFDVTQARGEP
->tr|A0A4Q2S8K2|A0A4Q2S8K2_9ACTN Maleylpyruvate isomerase family mycothiol-dependent enzyme OS=Nocardioides glacieisoli OX=1168730 GN=EUA06_04035 PE=4 SV=1
-MTRLPSETYLDHLRTESARFREVLTACDPAARVPSCPDWSAADLLWHLATVQRWWAEVVAARPTRPEEVDPPRPESYDELLATFDEWSAELARVLEAADPAEEAWNWSDDHTVGFILRRQAHEALIHRVDAELAAGDRTDLEPLLASDGVHECLAVMYGGCPPWGRWEPGEDLVRVDVTDTGEEFWVRFGIFSGTDPESGTTYADEEDFHVVDAPEDDAVEPDVVVDGTAAALDLWLWSRSDDEELSVVGDEAVLDRFRAIVGSPIN
->tr|A0A2W5D315|A0A2W5D315_9PSED Recombination protein RecR OS=Pseudomonas kuykendallii OX=1007099 GN=recR PE=3 SV=1
-MSFSPLIRQLIDALRILPGVGQKTAQRMALQMLERDRSGALRLAHALNEAMERVGHCKRCRTLCEEELCPQCADPNRDDSLLCVVQAPMDVFAVDQTGFRGRYFVLKGHLSPLDGLGPEAIGVPELLARIAEGAFSEVILATNPTVEGEATAHYIAQLLIPKGLSVSRIAHGVPLGGELDLVDGGTLAHAFNGRKAITL
->tr|A0A4P6U3H2|A0A4P6U3H2_STRSO Catalase OS=Streptomyces seoulensis OX=73044 GN=D0Z67_28970 PE=3 SV=1
-MTDIPRTTTDSGAPVESDEHSLTVGPAGPILLQDAYLIEQMAQFNRERIPERQPHAKGSGAFGHFEVTGDVTPYTKAAVFQPGTRTDLVARFSTVAGERGSPDTWRDPRGFAVKFYTSEGNYDMVGNNTPVFFVKDPMKFQHFIRSQKRRADNNLRDHDMQWDFWTLSPESAHQVTWLMGDRGVPRTWRHMNGYTSHTYMWINEAGEEFWVKYHFKTDQGIEFFTQDEADQMASADTDYHTRDLFEHIRDGEHPSWTLYVQIMPYADAAEYRFNPFDLTKVWPHGDYPLIEVGKMTLDRNPTDNHAEIEQLAFQPNNFVPGIGPSPDRMLLARLFSYADAHRYRIGANYAQLPVNAPITDVHTYSKDGAMAYRKTSDPVYAPNSKGGPAADTAEFGKPPTWHTDGDITRTAYATHAEDDDWGQAGALVREVLDDDARDRLVDNVVGHLLNGVTEPVLERAFEYWTNIDPKIGARIAEGVRAKADAKDPKAADQGNPARSSMQHKA
->tr|A0A2U3P8A5|A0A2U3P8A5_9MYCO Endonuclease III OS=Mycobacterium numidiamassiliense OX=1841861 GN=nth PE=3 SV=1
-MNRTLAQAFPDAHCELDFRTPLELTVATILSAQSTDKRVNLTTPALFVRYTSALDYAQADRAELEELIRPTGFFRNKASSLIGLGQALVERFGGEVPSTMDELVTLPGVGRKTANVVLGNAFGIPGITVDTHFGRLVRRWRWTEDEDPVKVEHAVGELIERKEWTLLSHRVIFHGRRVCHSRKPACGVCLLAKDCPSYGLGPTDPLLAAPLVQGPETEHLLALAGL
->tr|A0A3S5CJ78|A0A3S5CJ78_9PLAT Uncharacterized protein OS=Protopolystoma xenopodis OX=117903 GN=PXEA_LOCUS6098 PE=4 SV=1
-MLNQYYKIKKKSESVHEDSRRKNRELLERHNADLRLFDSESTRLGINTDALLGANTVSELIPPGASHLNNLARHFSAMQSVVIDTSSTSSSCGSTGRAAPTASGETNSSGRLVFANRNSMIVLNAGNTAHMSGHHVSMSESDSPGQNQR
->tr|A0A1V2VH64|A0A1V2VH64_9BURK Aliphatic amidase OS=Herbaspirillum sp. VT-16-41 OX=1953765 GN=amiE PE=3 SV=1
-MRHGDISSSKDAVGVAVVNYKMPRLHTRGEVLENARKIAAMLVGMKQGLPGLDLVVFPEYSTHGIMYDRDEMFETAATIPGEETAIFSEACRIAGVWGVFSLTGERHEEHPRKVPYNTLILINDQGEIVQKYRKIMPWTPIEGWYPGDTTYVCDGPKGLKVSLIICDDGNYPEIWRDCAMKGAELVVRCQGYMYPAKEQQIMVSKAMAWMNNLYVAVANAAGFDGVYSYFGHSAIVGFDGRTLGECGTEEMGIQYAELSIGAIRDARRNWQSQNHLYKLLHRGYTGKINSGESPAGVAECPFDFYRTWVNDPQAARAQVEALTRNSAGTPECPMPGIPTEPAA
->tr|A0A370VY99|A0A370VY99_9ACTN ABC transporter ATP-binding protein OS=Streptomyces sp. M7 OX=255705 GN=DWC19_11045 PE=4 SV=1
-MIGVAPPAYDPAAPTTAHTLPVGAPATVRAYVAELFRRHRRAFLLLVLVNTVAVVASMVGPWLLGGLVERVSDGAAGRDLRLELTVGLFVAALLVQAAFVRQVRLRGAMLGERMLADLREDFLVRSVGLPPGVLERAGTGDLLSRITTDIDRLANAMREAVPQLAIGVVWAALLLGGLVATAPPLAAAVLVAVPLLVAGCRWYFRRAPSAYRSEAAGYAAVAAALTETVDAGRTVEAHRLGERRIEQSDLRIKQWTAWERYTLWLRSVLFPVINVTHVTVLSSVLLIGGVFVLQGWIGVGQLTTGALIAQMLVDPVGLILRWYDELQVAQVSLARLVGVRDIEPDAGDARLTPDGRDVHADRVHFGYREGVDVLCKVSLEVAPGTRLALVGPSGAGKSTLGRLLAGIYAPRDGRVTLGGAELSRMPAERVRAHVALVNQEHHVFVGSLRDNLLLARTGAGDAELWEALRAVDADTWARALDEGLDTEVGSGGFALTPAQAQQIALARLVLADPHTLVLDEATSLLDPRAARHLERSLARVLDGRTVVAIAHRLHTAHDADLIAVVENGRVSELGSHTELVAADGAYAALWRSWHG
->tr|A0A150FR67|A0A150FR67_CLOPD Uncharacterized protein OS=[Clostridium] paradoxum JW-YL-7 = DSM 7308 OX=1121328 GN=JWYL7_1169 PE=4 SV=1
-MGRLERTLEKKKNKKAKRVGYCIFILIIFMLILGVNIVDYRINTFMGNYNRALILRVYDFTKGLSLLQR
->tr|A0A7G6UKH5|A0A7G6UKH5_PSEMX Uncharacterized protein OS=Pseudoxanthomonas mexicana OX=128785 GN=H4W19_14390 PE=4 SV=1
-MAVRYYISLPDPARARGGDPAFSFDAHGADEFAAQLQHALRTSSLFERWRARQDDPDDVDPGLGAVDPDAAVAGQQDDLSILLVARSSIPGHVLKHRLRLLAGRAWELRDVAAA
->tr|A0A4Y8KC96|A0A4Y8KC96_9MICO Triosephosphate isomerase OS=Cryobacterium sp. Hb1 OX=1259147 GN=tpiA PE=3 SV=1
-MNINPRRTPLIAGNWKMNLDHLQAIAFVQKLAWNLKDAGHDTAAVEVAVFPPFTDLRSVQTLISADKLPLAFGAQDVSAHDSGAYTGEISGAFLAQLECQYVIIGHSERRTLHNESDEQVAAKVTAALKHNLVPLICVGESAEDLAVHGPSAVPVAQLRAALAGVTNAVDIVVAYEPVWAIGSGQAATPEQAEQVAAALRGVLSDTLGQDVADKTRILYGGSVKSTNIAAFMREPNVDGALVGGASLDIAEFSSIIRYQKHVGL
->tr|A0A328IIY1|A0A328IIY1_9MOLU Thymidylate kinase OS=Candidatus Phytoplasma oryzae OX=203274 GN=tmk PE=3 SV=1
-MKFIAFEGLDGSGKTTQINLLKVVLTKEYRKKVTVIQGLGSSIIGPMLREMFLYQTKITPFTRMWLSFANMEQTQTEIIQPALENNHIILADRWIASTYAYQVFGHYLDIPLKKFHKLHCSFFFQPAITFYFDIKPAIGLIRKQQKLDYEPDLFEKKGIAYFEQVKRGYDYFFKKDFLVKNYNADIPKSILFKKVITFLKEKKIIEFRI
->tr|A0A502MPE9|A0A502MPE9_9HYPH 4-hydroxybenzoate octaprenyltransferase OS=Mesorhizobium sp. B4-1-3 OX=2589889 GN=ubiA PE=3 SV=1
-METVQSKVIQGRVADAPSGHWVYRVLPRWVWPYAQLARWDRPIGWQLLLWPCWWSAALAAGAYPRPTDPLLTLLPAPWYLLLFFIGAVAMRGAGCTYNDLADEDIDNQVERTRSRPLPAGKVTRRQAWAFVIIQALVGLAVLLQFNSFAIPLGIASLAIVAVYPFMKRITNWPQFVLGLAFSWGALMGWAVEFGDIDDPAIMLYIGSILWVIGYDTIYAHQDKEDDAIVGVRSTARLFGDNTKMWLTGLYGGALICFAIAFASAQAPIVALAGLIAAGAHMARQIIRLDINNPDQCLKLFKSNNQVGWLIFLGLIGGSVWIWLKPLV
->tr|A0A3S1L2A4|A0A3S1L2A4_9HYPH Flagellar biosynthetic protein FlhB OS=Mesorhizobium sp. M1E.F.Ca.ET.063.01.1.1 OX=2496750 GN=flhB PE=3 SV=1
-MAEAVDKDSKTEEATEKKIRDTIEQGKLPHSRETAIFASFLAILVFAVFYAKDAVVDLGMFLSTFLEKPEAWPMDTETDVITLYEQVLIEIGRAVVSLLVLLVVAGIGASVFQNMPQLVGERIRPQLSRISIAKGWSRLFGVQGFVEFGKSLAKLAFAIAVLAFTLSEDHRRLLAGMITNPVSFGMVIRGIFVDILVSIVFVMGLIAVADIVWSRFHWRRDLRMTKQEVKDELKQSEGDPIVKSRLRSLARDRARQRMMTAVPRATLVIANPTHYSIALKYVREEDSAPVVLAKGQDLVALKIREIAREHNIPIFEDVALARSMYKQVSVDSVIPSQFYQAVAELVRIVYSKKAVRRVPS
->tr|A0A6P7RXF0|A0A6P7RXF0_MUSCR Pendrin OS=Mus caroli OX=10089 GN=Slc26a4 PE=3 SV=1
-MAGRGGRSEPPQLAEYSCSYAVSRPVYSELAFQQQRERRLPERRTLRDSLARSCSCSRKRAFGVVKALLPILDWLPKYRVKEWLLSDIISGVSTGLVGTLQGMAYALLAAVPVQFGLYSAFFPILTYFVFGTSRHISVGPFPVVSLMVGSVVLSMAPDDHFLVPSGNGSALNSTTLDTGTRDAARVLLASTLTLLVGIIQLVFGGLQIGFIVRYLADPLVGGFTTAAAFQVLVSQLKIVLNVSTKNYNGILSIIYTLIEIFQNIGDTNIADFIAGLLTIIVCMAVKELNDRFKHRIPVPIPIEVIVTIIATAISYGANLEKNYNAGIVKSIPSGFLPPVLPSVGLFSDMLAASFSIAVVAYAIAVSVGKVYATKHDYVIDGNQESTGGKTQVAGLISAVIVMVAIVALGKLLEPLQKSVLAAVVIANLKGMFMQVCDVPRLWKQNKTDAVIWVFTCIMSIILGLDLGLLAGLLFALLTVVLRVQFPSWNGLGSVPSTDIYKSITHYKNLEEPEGVKILRFSSPIFYGNVDGFKKCVNSTVGFDAIRVYNKRLKALRRIQKLIKKGQLRATKNGIISDVGSSNNAFEPDEDVEEPEELNIPTKEIEIQVDWNSELPVKVNVPKVPIHSLVLDCGAVSFLDVVGVRSLRMIVKEFQRIDVNVYFALLQDDVLEKMEQCGFFDDNIRKDRFFLTVHDAILHLQNQVKSREGQDSLLETITLIQDCKDPLELMEAEMKEEELDVQDEAMRRLAS
->tr|A0A1I3Q7I7|A0A1I3Q7I7_9DELT tRNA uridine 5-carboxymethylaminomethyl modification enzyme MnmG OS=Desulfomicrobium apsheronum OX=52560 GN=mnmG PE=3 SV=1
-MTIPTVPDIFDVIVVGAGHAGCEAAMAAAHMGMQTLLLTINADRIGHLSCNPAIGGLAKGHMVKEIDALGGMMGKWADQAGIQFRILNTRKGPAVRSSRAQIDRTEYVRVVQQDIFTCPNLFVRQETVASLTVEDGRVTGVVTTLGETIACRAALLTTGTFLQGLIHVGLDSFSGGRQGDPASHGLSPRLTELGFELGRLKTGTVPRLLKSSIDYSVMEEQAGDNPPRPFSFDSPGIKLRQLPCFVTYTTERTHEIIRTGFDRSPMFTGVIKGTGARYCPSIEDKIARFPEKDRHQIFVEPEGLTSHEVYPNGIPTSLPLDIQKALVTSIPGLEKAQIIRPGYAIEYDYVPPTQLKPTLETKLVRGLYMAGQINGTSGYEEAAGQGLWAAINAVLALRGEPELILTRSQAYIAVLVDDLVTKGTLEPYRMFTSRAEHRLLLREDNADERLTAIGRELGLVDDSRWQRFTRKQAAVNEIMTGLESIRVRPDAATKDLVEAMGGTIPQKSVSLKELLRQPELTIEVLAPLWPELENFDEEALEEAEIKAKYEGYLRRQQELVDRFEKMEQTALPEDMNYVGIPGLSREVTEKLTRIQPRTLGQAGRISGITPAALSCLEIQLKKIGRL
->tr|R6KI73|R6KI73_9CLOT Type I restriction-modification system S subunit EcoA family protein OS=Clostridium sp. CAG:265 OX=1262787 GN=BN573_01150 PE=4 SV=1
-MKKVRDKYKMTELGEIPSEWHIEVLGECSNVTKLAGFEFTEYIEYIDDGEIIALRALNLKNGKLNLEDIKKIDKKVSESLTRSKLYINDVLFSYVGTVGEVALIEENDKFHLAPNVAKLTFNDSVVPKFALQYLMSSNMRNEINRYVTTTSQPALSMENIRKLKIIVPKKEEQEKISFILSTVDEQIDNVDALIEKNKELKKGLMQTLFTKGIGHTKFKNTEIGEIPEEWDVKKIGDICEVKGGKRLPKGYQLEDEDNAFPYIRVADMYMGGIRQDDIKYVPKDIVDKIKNYKISKDDLFISVAGTLGIVGQVPYELDGANLTENADKLCNIQINKLYLMKVLQSNIVQSIIEAEQTKSAQPKLALTRIKEFLIPVPSDIEQVKIASILMEVDEKIGQYKNKKQKLEELKKGLMQQLLTGMIRVTV
->tr|A0A669D541|A0A669D541_ORENI Uncharacterized protein OS=Oreochromis niloticus OX=8128 GN=miga1 PE=3 SV=1
-VSVCCTQVMRAPNSENIHTVLRIRELPSHGQSVTMTHETLTSSQLSMRTAALRMVDLPLSVYSSLTQVRIVSTDTKKLVVATAFGAVSLLFLARRFQRRKGRKKVHPQHWEQAGLEFHPPAAGENDNTSQNITLSLNSKNGYSSDLVLSAGGYRKLSGSVMSLASVKSLNSSSSSTCANDSTCWDGVEDADSCSVLNLPVTTPENLYLMGMDLFEEALRRWEEALTFRSRQAEDDASCASVKTGAGDTIAEQSMEDVISAEFIHRLKALLHRAYRLQEEFEGVLGMSEPSSHMADILSREELDDACLRDSISIASTDSFVSAAEMSEHRELRSVFTLGHHPLYEEAHGNLYSVVIVPLTEMLECLGDLDFLAKLHCVRQAWQLILCDRTTWTFLADTGKKILSSIIVKAHKSPKRFEEVFEEMISFLEHTEHWENTELELATRGVKHLNFYDIVLDFILMDSFEDLENPPISIQNVINNRWLNSSFKETAVASSCWSVLKQKRQHMKVSDGFIAHFYSVCEQISPVLAWGFLGPKGSLHDLCCFFKDQVLHFLKDIFDLDKVRYCSVESLADDVLQLLHRRSELLLAYLGADSLRYLNGCNSPPVQLVPSALLEARVQ
->sp|A3CWV2|FEN_METMJ Flap endonuclease 1 OS=Methanoculleus marisnigri (strain ATCC 35101 / DSM 1498 / JR1) OX=368407 GN=fen PE=3 SV=1
-MGVAIRDILADCKETLTWDDLSGIAALDAHNALYQFLSIIRQPDGTPLMNGAGRITSHLSGILFRTVNFLEKGIRPVFVFDGKPPEFKQETINERREHRARADEAWKTALREGDMEEAYKQASASARIDSHTIASSRELLDLLGIPWVQAPSEGEAQAAYMARQGKVTYAVSQDYDSLLFGSPVLVRNLTVSGRRKTRGRTITVNPERIVLSSFLDRLGVTREQLVKIGILVGTDFNPGIRGVGGKTALKIVRNGEFESVIAEKQPDFNPAPIRDFFLNPPVTDDYTLEWRTPDVEGVVEMLCGRYDFSEERVRSALAKVSVKATQKTLDAWF
->tr|A0A3S4B8B4|A0A3S4B8B4_9ACTN MBL fold metallo-hydrolase OS=Streptomyces albidoflavus OX=1886 GN=EQK42_07550 PE=4 SV=1
-MRFIKKRHSCVRLEKESGTLVIDPGGFTEPDAALGADVLLVTHEHPDHFDEGRLRAALEASPAAQLWTLASVAEPMAAAFPGRVHTVGHGDTFTAAGFGIEVHGELHAVIHPDIPRVTNVGYLVDGEVFHPGDALTVPDRPVETLLLPVMAPWNKLSEVVDYVREVRPTRAYDIHDALLTDLALPVYERQIGALAGTDHHHLGPGTFTEV
->tr|A0A5J4FE44|A0A5J4FE44_MICAE Uncharacterized protein OS=Microcystis aeruginosa NIES-4325 OX=2569534 GN=MiAbW_03334 PE=4 SV=1
-MYQMNKTAIDQWLKGVGAFLFQNFGVHLFIENQNNLKKA
->tr|A0A5E7AN68|A0A5E7AN68_PSEFL Glyco_trans_2-like domain-containing protein OS=Pseudomonas fluorescens OX=294 GN=PS720_01060 PE=4 SV=1
-MASRKFGLNLVIVLAIAALFSGFWALINRPVTAPNWPEQISGFSYSPFQQGQYPQKDQYPTDDQMRRDLEIMSKLTDNIRTYSVDGTLGDIPKLAEEFGLRVTLGIWISPDLERNEREIQRAIEIANSSRSVVRVVVGNEALFREEITPEALIVLLDRVRAAVKVPVTTSEQWHIWEKNPQLAKHVDLIAAHILPFWEYIPMDKAGQYVLDRARDLKKLFPKKPLLLSEVGWPSNGRMRGGNETSPADQAIYLRTLVNKLNRQGFNYFVIEAFDQPWKVSDEGSAGAYWGVYNAARQQKFNFDGPVVAIPQWRVLAIGSVVLALLSLTLLMIDGSSLRQRGRTFLTFIAFLCGSVLVWIGYDYSQQYSTWFSVTVGILLALGALGVFIVLLTEAHELAEAVWTHKRRREFLPVEGDSDYRPKVSIHVPCYNEPPEMVKQTLDALAALDYPDYEVLIIDNNTKDPAVWEPVRDYCETLGPRFKFFHVAPLAGFKGGALNYLIPHTAKDAEVIAVIDSDYCVSPNWLKHMVPHFADPKIAVVQSPQDYRDQNESTFKKLCYAEYKGFFHIGMVTRNDRDAIIQHGTMTMTRRSVLEELGWADWCICEDAELGLRVFEKGLSAAYYHDSYGKGLMPDTFIDFKKQRFRWAYGAIQIIKRHTASLLRGKGTELTRGQRYHFLAGWLPWVADGMNIFFTVGALLWSAAMIIVPTRVDPPLLIFAIPPLALFVFKVGKIIFLYRRAVGVNLKDAFCAALAGLALSHTIAKAVLYGFFTTSIPFFRTPKNADNHGFWVAISEAREEMFIMLLLWGAALGIYLVQGLPSNDIRFWVVMLLVQSLPYVAALVMAFLSSLPKPAPKVELATAE
->tr|A0A7S1LF74|A0A7S1LF74_ALECA Hypothetical protein (Fragment) OS=Alexandrium catenella OX=2925 GN=ACAT0790_LOCUS8164 PE=4 SV=1
-MCEAQIQKDDGDQKKQGHTAFATATMARDLAREAGDLRAEAEALHAMALAQERLDCFEEALRYADEAMDLYLELKDKRREAGELLSMADLSLCLGDFKQALIHAEDAMSIYQELGSKSEVEAIQTVYRVLVCRGDFQAARKIANRGLKRFHDLGNIKAQSQMMFMLINLNCKEGEIEYLTDKTRNKYKDALEVTQKALRLMHQLGEKQIEARLLVVLSALCLRLDRLDGALLAGQQALKMIKETGDTPWTSSARYFIENNSGLSSSNMGDVLFTLSHAYMKKDQHEEALALAQDLQQYFRENSNRRGEAAALMTINTCYLKLDLKPEAMKVAMQAQMLFNEAGDAAGEAYVLRALMDAEWEREDYAAAVRLGERAAALFREVEDRRSEAGVLYGIAVNNIHMAVRMGARVGDGGAGQRYYGERTRAITEALAKAQRAAENGVRLCKELMQETSKAGQLLAASLATLAQVHMFNSKPATALECADEAVILFREQGDYHSEGSALLQSADALRVTGQYEEAKEAAEEALSLCQKYEDEAGVMVAK
->tr|A0A7R8YYH3|A0A7R8YYH3_HERIL Hypothetical protein OS=Hermetia illucens OX=343691 GN=HERILL_LOCUS11551 PE=4 SV=1
-MVAVPYLFNEVYDIFRKAPFYTVVLEVLLLISVVWVIFYNNKNKRKRYTPEQEEEIIAKWQPEPLVGDTPADHPALFPRIVEGRVGKRINVDGHDCLNLATHDYLGLLEDEGIRKAAITSLRKYGVGSCGPRGFYGTLDVHLELEERLAKFMEMEEAVVYSYGFSTIASAIPAYSKRVDIIFADEKVNFAIQKGLDASRSTIYYYKHNDMKDLERLLIEQQKRDEKNPKKAAKTRRFLVAEGIYMNTGEICPLPELVELRKKYKLRLFLDETISFGTLGENGRGLTEHFNVDRIEVDLIIGGLENSVASIGGFCVGSSFIVEHQRLSGLGYCFSASSPPLLTQAAICALDRFENEPKMFAQLQESTTKLHNKLGSLTHMSLGGNKISPVKHLYIKESRDVDTERALLKEIVGKCIEKGLAVIDAQYLEHIEKHCPRPSLRITANRLLEDKDIDFAFQTLEKVSSDILS
->tr|A0A3D9YZA5|A0A3D9YZA5_9HYPH TYR_PHOSPHATASE_2 domain-containing protein OS=Methylovirgula ligni OX=569860 GN=DES32_1626 PE=4 SV=1
-MPRIHVCSLFQIADVTAATGARSLITVINQGIYVDRPPAIAPERHLQVAISDVCEETEGHILADSGHIQSLIDFVRAWDQAEPLVIHCFAGVSRSTAGAFIAACTLNPQVNEAEIARRMRRASPTATPNIHLVSLADQALGRDGRMITAIREIGRGAECFEAEPFALELY
->tr|W1WC24|W1WC24_ECOLX Transposase_31 domain-containing protein (Fragment) OS=Escherichia coli DORA_A_5_14_21 OX=1403943 GN=Q609_ECAC02469G0001 PE=3 SV=1
-MSKKQSSTPHDALFKLFLRQPETACDFLAFHLPAPIHALCDMKTLKLESSSFIDDDLRESYSDVLWSVKTEQGPGYIYCLIEHQSTSNKLIAFRMMRYAIAAMQNHLDAGYKTLPMVVPLLFYHGIESPYPYSLCWLDCFADPKLARQLYASAFPLIDVTVMPDDEI
->tr|A0A811T4R2|A0A811T4R2_9EURY Uncharacterized protein OS=Candidatus Argoarchaeum ethanivorans OX=2608793 GN=EMLJLAPB_00228 PE=4 SV=1
-MIENEKEIIFHPYALYKMNKRNISKQEVIKTLKEPHSGMDGQYGRRISQRVYGHHVLRVIFEEYEDHILVITAYPAKAERYLGRM
->tr|A0A022PN75|A0A022PN75_ERYGU Uncharacterized protein OS=Erythranthe guttata OX=4155 GN=MIMGU_mgv1a007123mg PE=4 SV=1
-MLELRGMSELTEWLQAELRSAAPENDQRLVVFPRLEYLQIIYCRQLKSAPSHFPCLKELLIDGVESELPLVSICGINLISLTKLHIHSIDGLTCLPNCLFRKNQNLSMLVISGCRNLTHLVPCLEGGGTALRNLEIWDCPELRELPDDLHTLSALENLAIYGCSKLKTIPYPYETHNDDDDEQLLLGLSCLRRLFIEYCDELTNLPIELCAESLESLTLRGLMNLRMTMGTLIGYCMQKMPRLSELRIVDVPTTNNPWEIVGSVTLGNLRDLTISCDEYSVSAVDAILKASAKSLHRLTLLGTEHSRELPGQLQHLTALSELGLYDFGEMEELSDWLIGNNNNNNLSSSLQILHLSRCKKLRYLPSKEAMLHLTKLYISNCPMLHIKGGDSDYGSEWPKISHIPYVVLDWVQIPTHAQ
->tr|A0A0N0T8W0|A0A0N0T8W0_9NOCA Chaperone protein HtpG OS=Nocardia sp. NRRL S-836 OX=1519492 GN=htpG PE=3 SV=1
-METLEFQSEARQLLQLMIHSIYSNKDTFLRELVSNASDALDKLRLESFRDKDMVVDTDDLHIVIESDPAQRTLTVRDNGIGMTREDVVRLIGTIAKSGTAEFLRKAKEQQAGAGSDLIGQFGIGFYSSFMVADKVTLLTKYPHAEKGVRWESTGESTYTIEDVDDAPQGTSVTLHLKPSDDEDQLPDYTEPAKIREIVKRYSDFITWPVRLGGEEINSRKALWARPASEVTEEEYAEFYRHISHDWNAPLETIRMQAEGTFEYQALLFLPAQAPLDLFMRDGKRGVQLYVKRVFIMDDCAELMPEYLRFVKGVVDAADLSLNVSREILQQDRQIQLMRRRLVKKVLSSIKALMGSRPDDYAKLWREVGAALKEGLLSDADNRDAILEICSFASTHSAEAPTTLADYVSRMKDGQEHIYYMTGDSRTSVEHSPHMEALRAKGYEVLILTDPIDEMWVDAVPAFDGRQFQSVAKGQVDLETEEEKSAAKAKAEEFGDLLTWLQGLLEENVKEVRLSSRLTTSPACVVGDAHDITPTLEKMYKAMGQELPKIKRILELNPSHPLVEGLHKAFAAGERDALADTAELVYGLALLAEGGELADPSKFVKLVADRVQRTF
->tr|A0A4V3UMH6|A0A4V3UMH6_9EURO PKS_ER domain-containing protein OS=Aspergillus tanneri OX=1220188 GN=EYZ11_013270 PE=4 SV=1
-MQRARVRAGKPEKLEHSSPQRFNIGAENPRKISRTKRNTRKYATFPTNSSTLTLLQPDLSSTRLELVDRPIPIANPDANEHLIRVHCTAPCAGELGWYAYVSLPDREPVPCDDMAGTVVTAPPNSPFQPGDEVYARSTFNRPGCARDYTVVVTDELARRPQNLSWAESAATPLSAETAWQALFEQSGIGGFSSSAWKGKRILVTAASSSTGMWLVQLGRIIGAQIIGTCGPNNVDLVRGLGAVDVVNYRSQSLREWGQNEENKVDLVIDCIGGQSLEDAWRCVRDQGIVISICRSPNEVKPAEVTAKEVRGLFFIMTPRRSDLEEITKLVEAGECRPLVDSVWPLEQFQSVFDRVEGRHARGKVVMDLRLNRKLES
->tr|A0A1H5GDJ1|A0A1H5GDJ1_9ACTN Succinate--CoA ligase [ADP-forming] subunit alpha OS=Streptomyces sp. Ag109_O5-10 OX=1855349 GN=sucD PE=3 SV=1
-MAIYLTKESKVLVQGMTGGEGMKHTRRMLAAGTDVVGGVNPRKAGRTVDFDVPQCPNGLGGAPTAVPVFGTVAEGMAATGADVTVVFVPPAFAKAAVLEAADAGIGLAVVITEGIPVHDSVAFTSYARRNGTRIIGPNCPGLITPGQSNAGIIPADIAEPGRIGLVSKSGTLTYQLMYELRDVGFSTCVGIGGDPVVGTSHIDCLAAFEDDPDTELVVLIGEIGGDAEERAAAYIREHVTKPVVGYIAGFTAPEGRTMGHAGAIVSGAAGTARAKQEALEAVGVRVGSTPTETARLVLELLKAGS
->tr|A0A2P7YVD5|A0A2P7YVD5_9ASCO Uncharacterized protein OS=[Candida] pseudohaemulonii OX=418784 GN=C7M61_001726 PE=4 SV=1
-MSTWQAHTDHSATSPRSTLPATKQLDSDATPRMSHLPTPLGELKLLVNNDLLRKNPNFVTSEAALSSTIEQLDLETLKISAYARLDFENYTFFVQTLQVVLGRKAVEDAAPTHHAVDVHLSSKKAISRRHAKIFYNFGTQRFEISILGRNGAFVDDQFVETGITVPLVDNTKIQIGDIPFTFVLPSLEPPEKKNATPAKPFNPSDAINLRSNLYLNPASPNRKKSLTDEQKKARRNLRADIVRRLSNARRKSLASSTNDEITALLKELEDIGDDDESDPFDKEVNELLRLGNLEAEEDELDELVKQHNLLQGIGVEDKDRKDVDVDMSVLDQEIASLAPLIDGQHPEKDAIDNKQGVYGRHGTTLATDTADNKNAPLMGRPAGPRMGKPAQIQPPANRAYGRQPVGPMYGYPNSGAYPQGYNSPYGSPAGYPTGARNSMYHPMMMPTRPPPPKLEVEVETISTVPVKSATIPFKAISTGVGNVQRPPVCVFKTLDIPLNKPKIPLRRKDAPSIKRPKSQGNKDITDQYKSKPTVSITAMITSVLRGPNSRKSGFTFSEICDGIKEFYPYYQYCPDGWQSMITHNLKTHNMFKREFKGGLDSEHLWVIDDDYLAEKERVRKKQQEVAMAKAKEAALKAVELRLKQLTPQYGAVGRPFMTPYASSFGQPRYPTSRDLSPPMPNGAPGQKPKSIAELASEIKRDSPGALNQSSYLPRLSLSPTVNSAEQSNSIKDQLAANRSASASLTNITSDVKTERSSPTPQPVAAAAAAVSANTNSGLVSKLLPMNADTKKSLGYLQKELFTLYKARKLSYNTATTTNIITKALATTIAQVNTIGAKAGCGDNALSFLVEKAPQQVSKILDIALTKSIKEVEGKLSNPTSKESTPVPTASPAASNIGLVQKPPASIESTSSASRPATPNSPAGGTPKPSYSGGLSRPHFSGMARPQNPSKPGALLKGPLFLSNKPRQEKRPAEETGEDPLKSIKLE
->tr|A0A6P1IPK0|A0A6P1IPK0_9BURK AMP-binding protein OS=Hydrogenophaga sp. BPS33 OX=2651974 GN=F9K07_06005 PE=4 SV=1
-MTAQVATGWNLANIFDGVAARVPKDRPAIVHGDTVVRWGELDARSNRAARALLATGHTAGERVGFLSRNHPGYIEGFVACLKSRLIHVNLNYRYTVDELAGVLEDAGATALLYQQEFAPLVPALLERLPALRSRICLDGDGLGQATAQFQTMAAQGDASPLDASTREERDPLLLYTGGTTGRPKGVVWPGHHYRACQLESPLVQRRPANLGEHLDLVAANANPGRVLPACPLMHGAGISSTLAELLNGGTALLLAGARFDAHELWQLAERERASRVLIVGDVFARPMLAALDEQPGRYDLSSLKVISSAGLMWSEEVKAGLLRHMPWLVLADIYGASEAAGLGYAITTQDRATPTGRFEPGPRTVMVGDDGHIVPAGQEGEGWLARGEPLPEGYFGDPKKTAEVFRTIDGQRYAVPGDRVRRHADGSMQLLGRGSLVINSGGEKIYVEEVEEALKRLPGVDDVLVVGVPDVRWGSAIVALLRTDTPPDVQALRAGLAPHLAGYKMPKHFLAVDQLPRADSGKGDYKAARALAEQLLETT
->tr|A0A7D8UVQ1|A0A7D8UVQ1_9HELO Aspartate--tRNA(Asp/Asn) ligase OS=Lachnellula cervina OX=1316786 GN=aspS PE=3 SV=1
-MTIILRAARHMIVRNTRTAVYVSPWRGAAASLVSSWLPSRGFHVSYRLAKEERWGREVEKPEDKERRGRSLEEQGVVEEQEEVEAEALKPQSFWEEFKGTSFVNLYLDNVPPPTFPFEKRIPSHFMALRVTTVGFLTKIVRLSDALTFAHINRGTGPEVLQLLSKNKETTKKLQSMRLNSAISVTGVIHKKYKPKVASKRKELEFEEGWFYLEELELEIEEITCLNTFDKDIGYGPEHVYRPENRHLQIRFDTNLQKALLYRSDVAACAREELKDFYEIETPILFKSTPEGAREFLVPTRRPGFAYALPQSPQQYKQMLMASGIHKYMQFAKCFRDEDLRADRQPEFTQIDLEMAWADGEVVMARVEKLIRALYKKFAAPDTQLQPLFQTPFHRITYDEAMSHHGSDKPDFRIPGLIQQVDHIVPDQLGKMLTHIEYPIFEACKIRLNGHPERIKKFVSMFFSTPVGEVFGKNIDGGPGVAVFDSSRPLEGLQTFGFEGAEKLKALYSNLPQQAFHGKEAHENATTFDDGDLIIVQARKNLPHSGGSTALGRLRIALYRAALAEGLLEPDLYHHYLWVTNFPMFTLENGVDPGQEGTAGFSATHHPFTAPKTAEDVDLLRTDPLMAKADHYDLVVNGVELGGGSRRIHSAKMQRFVMQEVLKMNPRRIEDFSHLLKALSAGCPPHAGLAIGFDRLIAVMRGVDSVKDVIAFPKSSKGEDMLVKSPRRISRKEWKRYHLQKIDLRTENSHKPMEKDATEKPKESKWTRFWNIVTIRK
->tr|A0A1X1VYA0|A0A1X1VYA0_MYCGO Aminotransferase class V OS=Mycobacterium gordonae OX=1778 GN=AWC08_00950 PE=4 SV=1
-MREAFGEKFDVPAGYLDTAAIGLPFARVADTLVDTIAHWRAGALQVTDFDADVVAARNAWAQLVGVAPLDVVTGASVSQLVGLLAASVPDGTKVLTVHNEFTSVTFPFAAQQRRGITVTEARPAELLSQLRRHDLVAISAVQSADGFTVDLDELRAAAEAARVRVLLDVSQAAGWQQLRLHWAEFVVGAAYKWLLAPRGAAWMAVRRDVLADVVPQAANWSGAEDIWSGLYGLPLRLADNARRLDLSPVWFSQRGAAIALPWLAGLDLSAVRQHCVGLANATLAGLGLDPCNSAIISLGIAAEAAHRLVQAGAAISMRAGRVRLSFHLYNTMEDVELVLSALR
->tr|A0A0C5V338|A0A0C5V338_9GAMM tRNA 2-selenouridine synthase OS=Gynuella sunshinyii YC6258 OX=1445510 GN=selU PE=3 SV=1
-MSRPDTDDYAAIFLHDTPMMDTRAPGEFLKGAFPHTVSLPLMTDNERAKVGTCYKQQGQQKAIELGHQLVSGTLKEERIQRWLEFARAHPDGYLYCWRGGLRSQIVQQWLQQAGCDYPRIKGGYKALRRFLIDTQERIVSNTRFRILAGHTGCAKTDLLTAVPGSIDLEGLAHHRGSTFGKRPAGQPSQIDFENRLAIALLRQDHQYPGATILLEDESRLIGRCALPETLRRRMAEAPLIIVESTLEQRVEHSFRNYILNKLAEWQQARGAEEGFTAFAEDLTTSLFKIRRRLGGLRYQELSAILEQALKQQQQGDDSLHREWIRILLRDYYDPMYDYQLSQKQGPVEFRGTATDIKNYLLTH
->tr|A0A7K7XU01|A0A7K7XU01_9PASS SGSM2 protein (Fragment) OS=Mohoua ochrocephala OX=874463 GN=Sgsm2 PE=4 SV=1
-GVVEACLLHMLKRRAAGFLRTDKVAALFTKVGKTYAVAGDVCKKVQELQQQVESRKNQPNGQEPLKRQGSTTSKTPVLTPQAIKHIWVRTALIEKVLDKIVQYIVDNCSKYYEKEALLADPVCGPILASLLVGPCALEYTKLKTADHYWTDPSADELVQRHRIHGAHGRQDSPSKRPALGIRKRHSSGSTSEDRFAASAREYVESLHQNSRTHLLYGKNNVLVQPKDDLEAIPGYLSLHQSADSLTLKWTPNQLMNGTLGDSE
->tr|A0A4R6GLC2|A0A4R6GLC2_9BACT Coenzyme A biosynthesis bifunctional protein CoaBC OS=Sunxiuqinia elliptica OX=655355 GN=coaBC PE=3 SV=1
-MRLKGKHIILGLTGSIAAYKAAYLLRGLVKEGAEVQVVMTPAAKEFITPVTMSALSGRPVASEFFAANDGTWHSHVDMGQWADLMLIAPVTAATLGKMAHGIADNLLVTTYMSAKCPVYLAPAMDLDMFKHQSTLNNLETLRSYGDVILEPGEGELASGLHGKGRMQEPEQLVEEVVAFFHSKKKLLNKKVLVTAGPTYEKIDPVRFIGNYSSGKMGFALAEELAKEGAEVILVTGPVHLKTTHPNIHRVDVESAMEMHNACLEHFPATDAAIMCAAVADYRPKEQADRKIKRNAGEMNIELQATEDIAAALGQLKTPSQRLVGFALETNDEKQNALAKMQKKNLDFIVLNSLQDNGAGFGVDTNKITILSKDNNAQEFELKQKTEVAVDIVKKLIGELTND
->tr|A0A4S0Y8E6|A0A4S0Y8E6_9BACT UPF0102 protein EN806_46285 OS=bacterium M00.F.Ca.ET.163.01.1.1 OX=2563906 GN=EN806_46285 PE=3 SV=1
-MAERTLGHRRKAYRRGHRGEWLAALALMLKGYRILARRHRTRLGEIDLIARRGDLVLFVEVKARRTLIEAMEAIGHESERRIEGAADIWLSRQPDYGRLSLRFDMVAVLPWRWPVHVENAFYGRN
->tr|A0A3G5P5X5|A0A3G5P5X5_9HIV1 Envelope glycoprotein gp160 OS=Human immunodeficiency virus 1 OX=11676 GN=env PE=3 SV=1
-MRVTGILRNCPRWWIWGILGFWMVMSYNVVGKEDLWVTVYYGVPVWKEAKTTLFCASDAKAYEKEVHNVWATHACVPTDPNPQEMELENVTENFNMWKNDMVDQMNEDIISLWEQSLKPCVKMTPLCVTLECQDANFTKANLTNTVTNNSDSIITNGTMKDVMKNCSFNATTELRDKKNKEYALFYRLDIIPLSGENNSASGNYRLINCNTSTITQACPKVTFDPIPIYYCTPAGYAILKCNNKTFNGTGPCNNVSTVQCTHGIKPVVSTQLLLNGSLAEGEIIIRSENITNNAKTIIVQLNKSIEITCTRPGNNIRKSVRLGPGQAFYATNDIIGDIRQAYCIINRTDWSETLQGVGKKLKEHFINKTIVFSPHSGGDLEVTMHSFNCRGEFFYCNTSKLFNSNSTANESNIELPCRIKQIINMWQGVGRAMYAPPIAGTIQCTSNITGLLLERDGGNHNGTETFRPTGGNMRDNWRSELYKYKVVEIKPLGIAPTGAKRRVVERQKRALGIGAMFLGFLGAAGSTMGAASIALTAQTRQLMAGIVQQQSNLLRAIEAQQHMLQLTVWGIKQLQARVLALESYLKDQQLLGIWGCSGKLICTTTVPWNSSWSNKSQNAIWGNMTWMQWDREISNYTDTIYGLLEESHYQQEKNEKDLLALDSWQNLWNWFDISKWLWYIKIFIMIVGGLIGLRIVFTVLSIINRVRQGYSPLSFQTLTPNPRGPDRLGEIEEEGGEQGRDRSIRLVNGFLAIAWDDLRSLCLFSYHRLRDLILVTTRVVELLGRSSLRGLQRGWEVLKYLGTLVQYWGLELKKSAISLLDTIAITVAEGTDRILELLQRICRAICNIPARIRQGLERALL
->tr|F6HXQ9|F6HXQ9_VITVI Uncharacterized protein OS=Vitis vinifera OX=29760 GN=VIT_09s0002g00830 PE=4 SV=1
-MGVSFKISKTGSRFCPKVVLSDAPLNEEEEEIAKENSRIPDRNESLSNSTTRKLEADIIEGDEDVAGISGSSISSGGLLIPSDNEVSFTLNLFPDGYFIGKPSENETTHQAMLQDVPKLLHPYDRTSETLFSAIESGRLPGDILDDIPCKYVNGALLCEVRDYRKCASEPGFSVPCADGLPIVNKVCLRMSLENVVKDIPLISDNSWTYGDLMEVESRILKALQPQLCLDPSPKLDRLCEKPVPAKLNLSLSSVRKKRLRQMPEANITSSNKIHVKKISMDRAGESLNGRLRDSGPMSGAVMAQHVHENLAAQNVGPINILTPGPKSFVQDASNPALPLASPRSKYQVSVGNPKIMQDHGSGSVVNASGASSSIQDMMISYTDNVHGKRENQDDQLSPLSNMTKRQRLTAVGPEGIQQQHLVPHIDSFHGSDLQWKNAALLPHQLNARGNPYANTGIQKYPQQVFDGVLNQEAASASFAETEKLDRPELNRVKNDMHMGEIESNHLDPQQSRLQSRLPQQIPFMRSNSFQAPWNNITQHIEKDPRKERKLVQSPRVSAQGLVQSPLSSKSGEFSSGSLGPQFGPTATTAVLGASQKDKPAVTSVPPVVGTPSLTSSANDSVQRQNQMQIVPKRRSNSLPKAPAVGSPASVGNMSGPSNANSPSVATPPSADQTMLDKFSKIEIVVMRHQLNCKKNKVEDCPVKKPTFSPQELLGRLSMASHNEDIKDDTCKMPLSKSLAGGSMNVCKLRVLNFVQAERVVQGSVVSVVPRARSTMIMSEKANDGSVAVHHGDVVDGDFLSAEDYVSTLPNTHFADLLAAQFCSLMNREGYHLMEDRVQPKPARMNLASSNQSNAPGISPNNSAAEMQQYSETASGQPHNEVAKPTNSGNTPLNASQNLLANSRMLPPGNAQALQISQGLLTGVSLPTRPQQLNPQPLQQPQQQNPQSLIQQQHSQFQRSSLMLPTNPLSHLSAMGQNSNMQLGNHMVNKPSATLQLQMLQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQQPMQRKMMMGLGTAVNMGNMGNNIASLQGLGNVMGIGGARGMGSTGISAPMGSISSMGNVGQNAMNLNQASSVTNMLGQQFRNPQLGTMAAKIRMLNPAILGGRQAGIAGMTGTRQMHSHPGSTGLSMLGQNLHRPMNPMQRTGMGPMGPPKLMTGMNLYMNQQQQPQQQFHLQQMQQQQQHHQQQQLQQQQLQQQQQQLQQQHQQETTSPLQAVVSPPQVGSPSTMGIPQQLNQQPQQQQPQQQQASPQQMNQRTPMSPQQMNQRTPMSPQQMSSGAVHPMGTGNPEACPASPQLSSQTLGSVGSITNSPMDLQGVNKSNSVSNT
->tr|A0A7Y3TR66|A0A7Y3TR66_9FLAO IS701 family transposase OS=Flavobacterium sp. CLA17 OX=2724135 GN=HAV12_33835 PE=4 SV=1
-MPASRAARPTIHFVDEYCQLYEDLFPEVRSYEAFKLLHLGMISEIKRKSLPAIAKAVGLNNQQNLHHFLTESPWQVQQLRQKRLELTLKVLNGRSLILLIDETGDCKKGKSTDYVKRQYIGNVGKKENGIVAVTAYGLVDGMIVPLSFEVYKPRERLKEGEEYQSKPQIAATMIRQLQALGFEFELVLADSLYGESKVNFVDVLDELNLPYILAIRSNHALWLPQDQEVYQEPWQTFKRTFSNGTTETRHMAEVIYGKSHRKQYWLLTTDPDTLPDNSTSYVMVCAPAIKLKDIGDSYGFRTWIEYGLKQAKDALGWADFRMTRYEQIEKWWELVMSTFLMVSLFADPFNDSCPLAHQRFSQHPWWNNQSGWKNLLNNLRLVIQPLVCFNWLKHWLTVFPIASLQLGFEQLTQKMNQFICPRVHQLNLQLIFSSA
->tr|A0A7G3FQZ2|A0A7G3FQZ2_9BACT CsbD family protein OS=Roseivirga sp. XM-24bin3 OX=2133949 GN=DCO95_02490 PE=3 SV=1
-MSATTDKLKGNWNIIKGKLKQNYADLTDDDLTYTEGQEDELLGRIQRKTGKTKDEIKDFIDSI
->tr|A0A2T0UIC1|A0A2T0UIC1_9ACTN Acetolactate synthase OS=Glycomyces artemisiae OX=1076443 GN=B0I28_10654 PE=3 SV=1
-MSTPVKAPKPGPQAGSAGTQAAKAQPARPKAPRPAPPLGAPAAAPVLTGAQAVVRALEELEVEAVFGIPGGAILPAYDPLLDSEKVRHVLVRHEQGAGHAAQGYALATGRVGVCMATSGPGATNLVTPLADAHMDSVPIVAITGQVASTAIGTDAFQEADIVGITMPITKHSYLVTTGEEIPRVLAEAFHVASTGRPGPVLVDIPKDILSGSAPFVWPPKMDLPGYRPTTQPHGKQIREAAALIAEAKRPVLYVGGGVVKSGAHAELRELAELTGAPVITTLMARGAFPDSHPQHLGMPGMHGSVPAVHALQKSDLIVALGARFDDRVTGKLDSFAPEAKIVHVDIDPAEIGKNREVDVPIVGDCRAAIAAMTEAYADPGKERLKTWWETLDDLRGRYPLGYTDIDDGLLSPQYVIERLGALAPEDTIWTAGVGQHQMWASQFIKYETPGTFLNSGGLGTMGFAVPAAMGAKLGEMGRTVWAVDGDGCFQMTNQELATCAVEGIPIKVAVINNGNLGMVRQWQTLFYDKRYSNTNLSTHHSEASPRIPDFVKLAEALGCVGLRAETPEEVDAVIAQANAINDRPVVVDFTVGPDAMVWPMVPAGVSNDEILYARDVRPNFDDEGEI
->tr|A0A1Z2XRM7|A0A1Z2XRM7_9FIRM DUF3502 domain-containing protein OS=Acutalibacter muris OX=1796620 GN=ADH66_10645 PE=4 SV=1
-MSKKILCLILTLALLATCFVGCADKGESKKESSSTPESSAAESSETQSSDTGDKTTDEEPYTVHFAYYIAKESPNMGALSDAVNELAMKELNMKVDLQALTQGTYHQQIPMMLAAGEPMDVFISRASEVGTFIESQYILDCTPYLDKMENAKAALGDDIQACYIGDFLAGFGSMAERATPGAMVVRKDIFDELGFKKEDFDYTLPNMGVLDQITEMYAKVKEKYPDMICFDGTAVPASCAFCFVDNLSSSFGVLETPESTTVVNWFETDMYRRLCEAAMEWYNKGYSSKDIAVNTDGGDVKMKGGNCFSYFQSWKPGVETEKKSQTGYDVEMIQLIDAPKTSYNVNTRLWSIANSSEDPEKAAQFLDWTYKSGEFTDLINWGVPGTDWVLNDDGQADYPEGVTAATVGYHNDKGFSYPNQFNGTLWAGAPKDLWEQYETWHATLKESAAFGFAFNSMPVATEMATLQTVYDKYQKTVGFGTLPDLDAAIQEFNDALYEAGLQKVLDEKQKQLDEWLANK
->tr|A0A0Z8MB24|A0A0Z8MB24_STRSU Membrane protein OS=Streptococcus suis OX=1307 GN=ERS132461_01172 PE=4 SV=1
-MKKLLTNHFFYLTIAFLLILVIYFSGIDKRWIILASFLYFIPSQILYRRRLKERLQEDQPK
->tr|K8FB40|K8FB40_9CHLO ATP-binding cassette transporter OS=Bathycoccus prasinos OX=41875 GN=Bathy12g02760 PE=4 SV=1
-MSAVDHRKENVEDPTNRLEQYASLCRDELEAHGGKLPSVEIKCDFDYTLHLPANKIDRSIKTVPGVLTDVAMKIPNKVREKISGKENDATKMEPFRVLKDVDCCFKAGSLTLVLAPPGHGKTSLLKAVGQILPSAVLSGGKGVTYSKMTAEELKEKDIDANRMAMYVTQQDEHLPFLTVRETTKFSHENATPTPTNEREEDVHSRKIDSVHRLLSLENCLDTIIGNDLVRGVSGGEKKRVTIGEAMVTNARVFCMDEISTGLDAAVTHNIIAALREWTRITNGTVIVSLLQPTPEVYELFDDVLCLRDGTPVYHGDVDKVVDHFCGLGFDSENAKKGDVADWLLSVLVDPLAHSKTGASNQFASGDGLRKGWVENSNGLYKKSIGETDCVDKSDGKNMIDLRTPFAKAQYSTAYPKAWPSMYKSVIKRQFQITLRNKVFLSARMFGALITSVVLGSVWFDLPLDRGFERLGMLLFCVLHISFSNFSELTFSVEQKYVAYKQLDYKLFPTFAYIVSSIATQLPIAVLETAIFSCILYPMVGLSMEFENWLVFFINLTCANVAMASFFRVVALLAPNMEAAQTFPGPVIAIMVIFAGFLISPEKMGVLHFLYWISLFAYSLRSLCQNEFLSDQFKYKVPLDPTAAAVYVQGYTGDPKTMAEFCEENAFPCEDAGKITLSTIDISSDKKYFWAGPIFSIGFFCLMTAIGYRALSKIRIQRNIGSSRTSSSEKKKDGENAEEVSISISKVDAEASQRALSFTPMSITWEDLEYTVKVPGEDGKPLSGSKKILNSVTSAAQPSRMLALMGASGAGKTTLLDVIAGRKSGGEMRGTIKLNGHVVKKETFARLTAYCEQQDLHNAFTTVKEALEFSATLRLPSDVSKDARKAVVDEALDILELRGIENRLIGVAGSPSGLSPGQRKVLTVGVELVSNAPVFFLDEPTSGLDSRAALIVMREVKKVANLGRTVITTVHQPSKEIFNLFDDMLLLQRGGYQVYFGPCGVNGKTFVDYLQKIPNAHALPDGMNPASWMLDVLGGTDSSNAGEKSALKKSKSTAAGSLQPAMTMKRSGSGGALNGLLLVERFKASQEGAAGTRLVKELCAKGEKSEMFAFASPYARSFLAQLRCLIQRASLAHNRDVAYNLGRIGILFVLYLLFGFVYFDLDASNETGVQAMVGVIFMTSIFAGIIFMNSVMPVRVRERAVAYRERTSFMYDAVPYSLSHAICEVPWVLLVTFVTVTPLYFMVGLVPTFEHYIFHVLMVFTVSMAFMSLGQLIACLCATIQTAQAGASAFIPICFLFGGLYLPYPQIPVYWKWAYFIDPVAYAIQGVTAPQFEHRGCTGAYPDGDCPTIQAFRGTYFETVDTLAYVEEKYDVQLSQKWYMLIYVAIFVLCMQTLHIIAFKFKKVVAR
->tr|A0A0B7H5Q7|A0A0B7H5Q7_9FLAO Uncharacterized protein OS=Capnocytophaga cynodegmi OX=28189 GN=CCYN74_10172 PE=4 SV=1
-MNYILPFLSIITGFGTVLIFKPKNQRNIKLLLAFSGAFLLAMTVFTLIPEVFHSLEHSHEHDIHDHNTGKKIGLWIVIGILLQIILEFFSKGAEHGHMHHPHSELKNAFPWSLFISLSIHSILEGFPLHHHHHMVYGIFVHHLPIAMVLTIFFLDSGIGLKKTFIFLILFALMTPFGTLLAEFIPQLGRYHIQISAIVIGIFLHISSVILFETSENHKFNHIKLGTIILGFVAAYFT
->tr|A0A7I6VAI1|A0A7I6VAI1_AERCA Membrane protein OS=Aeromonas caviae OX=648 GN=WP8S18E04_21180 PE=4 SV=1
-MNLMLYVSTVLIWGSTWIAIAWQLGPIPIEVSVLYRFALAALALFALLTVSGKFPRLPWAGQRYAALLGALLFSTNFLCFYHATLYIPSGLSAVIFASASIFNGLNLWLFEGKRPGLRWLQGSLLGLLGTLLLFWPVLADAQLGANGWKGLLFACAGTLCFSLGNLVSARGQRQGYHVLQMVPWGMVYGVALLQGWVTVLGQSLTLPTDPRYLAAMVYLAIFGSVIAFTAYLTLVGRIGASKAAYATVLFPLVALTLSTFYEGFVWQTVSIVGVVVSLIGNLVIFAPPVKAWRWPLSRAANGTCP
->tr|H8X476|H8X476_CANO9 Histone-lysine N-methyltransferase, H3 lysine-36 specific OS=Candida orthopsilosis (strain 90-125) OX=1136231 GN=CORT_0C06550 PE=4 SV=1
-MNGNTKNSDYASPLFLDVEDKTEEALTKFQNLQISTYQSKSIAAPSNNKRPEYMTCDCEEEWDGEQEKNLACGEDSNCINRLTSVECTNRHCLCGDDCQNQRFQKRQYADVSVFQTELKGYGLKANKPISEGQFIYEYIGEVIDEGAFRQRMIEYDVKNYKHFYFMMLKPDAFIDATEKGSLARFVNHSCNPNAFVDKWVVGDKLRMGIFAKRKIAKGEEITFDYNVDRYGAQSQPCYCGEPNCIKFMGGKKQTDAALLLPEGIAEALGVTSRMEKAWLKENKHVRADQQKDDSTINEMFVQSLEVEPMQDADVSKVMAALLKSQQVSITRKLIMRMHMTDDPTVNSLMVKLHGYKTLSGVLQGVEDEDLIKMILEILSKWPAMTKNKISSSQIEDVVKEIEANSTNEEIRQLASDLLAQWSVLEMAYRIPKTQASDKSLMESYGRVSRSPEHSNGNTSGVINHDQSNFAQYSTNVSQVYSATLPKGPASVPNFGLPENWQAQFDPNTQKYYYYNVLTRETTWDKPGVSIPTRPKLPTGPSSMINQQPQTSHSSQYQNGPPSRNNNIEEEIARREEEKERRERESRAQELLNKERKLRELIEQAQSVKSTPEPEKKSKHKHKHEHKHRHGRTKSHEGKGTAALDDDARVSKESKHKSSSHQHKKKEVKETSLEAQWKHIMAKHVPNLLKSYVEEIGKDNVKGCAKEIVNNLASREAHKGVPPSSSKELDKHKLKKLKEYSDTYMDKFLSKYRSKHHGKRKLGEDEANATSREESRGIDSNVSLSNIDTNGEVESEENKKVKLDSGV
->tr|A0A5N5DU29|A0A5N5DU29_9PEZI Inner centromere protein mis6 OS=Lasiodiplodia theobromae OX=45133 GN=mis6 PE=3 SV=1
-MHATIDALRTASTLPAKQRGEKVNAVVDAVCSHAYQHGLSRDHLQSIVAIVTRRNHLDQTSLTNLIKNLYPADRVSSDIVLAIVGSLGHGQAKPSAATQAALLKWIIAVIDALQDATVLSKLYGVLFNMLDTMTLRTPLCHLLSLITRRKHVRPFRIQQLLEMVRGSGQDPALVGLLRVYKDYYPEIIVGNAASGRTSFASAAQDEWRQRLQVIQDANADSNEQLYAQQDGFKVIRRGAKRAKASILPDVHTSYANEKSVTLEEVNSADGLVKNLERIELPNQLLASFKDPLLQKYLILKPSDTAARRLELWLESYLRETLETISSGTKNPDHFDELLDGMLNYTKATKDFKEFKASYLNPAEAAIVTSGTVDAYDRLVTFYTALVQNWNHAANTSRPDSGDAANDLITSTDFTGLTTHISNTILSLLTSQSHTPISTTTTILTYYTTLSTLSSGLTPLTIPTAPTLYTLLFQPSLATLSQLCTLLATYKRAFEADLQDHTTTAANLPRAVTNAFNGYLMDVANLLWRSRALTSTDPNAMACLCAPGVAAALHAYISTTLPPVLIPSANDNTTAPAPGTGPDYTLAALFGLPHNALTAPLARAAFRDLEDAHHGTSGSSNAPRHPPGPVTQRTLHRLARAGNNGNGNGNGNGGGAAGGGGGGLELSWKAYRVCVLEWLAERGVRGLRDFMFVTMKDLMKESAAAAAAAAAKTGATTTTATA
->tr|A0A559MAT3|A0A559MAT3_9HELO VPS37 C-terminal domain-containing protein OS=Lachnellula willkommii OX=215461 GN=LAWI1_G004602 PE=3 SV=1
-MSSPSTAYPPYQPHRNSQSFDPNAPPAPPPKPSSQEVSRRSTPAGSQPLPPPPPPQPEGFGTYGASDDPRSFQQARFSSSEVLYAEQIQDPGERWLPKILEDKTFVTLRHKIKQDLADVLAKPDLLAALAHSTSTAHASIASAQEPLQAALTENIALASHLNELEARLAHLRSSTQAQLLSTHALERQWKQKQSDMDRALAPFSPSSLYQRLSQAVQEQEMVCRALEESFLEGDGGTATEREVVEWVRRYREATKVYYSRRERKERWDEGRVGGWR
->tr|A0A3D4HVI7|A0A3D4HVI7_9BACT Uncharacterized protein OS=Patescibacteria group bacterium OX=2052139 GN=DIV45_01950 PE=4 SV=1
-MAKQLKLFEKSVKKKQLTKKLVVLGKKKGNFSCQARVPFSEPVGSPNRRSGPEATKLRKYPLKSLPLKKGRRGGDVNLLAPSSPSPSSGRRGEKRHWHWTDYFVSSPLKITPKKKRKTPVVFVMMSGGVDSSATAYLLKEQGFEVVGVYMKNWSFPIKRIDECPLYQDYKDMVKVCKFLKIPYQVWSFEKDYRKRVIDPFFKGYEAGLTPNPDVMCNTEIKFDDFFKKAMKLGADYIATGHHIRSRCADPRFSRHSGESLGRLQNLIIRSWTSQDDDAKXXSG
->tr|A0A1X0VXM2|A0A1X0VXM2_9GAMM NGN domain-containing protein OS=Rouxiella silvae OX=1646373 GN=BS639_21155 PE=4 SV=1
-MKNWYLVYCNYNQEDRAIINLERQGVQVFCPMLSQDNHSPHKKGGYMFPRYLFCLFNPEVTSKTTINSTRGVSQLIKFGGRQEIIPNIVIESLMFYIERSPEAEFKGGESPNLKKLSEDLSAIIKGILSECESDKRVLLFFSLYSLIVRDIAKEIVKIPVKK
->tr|A0A1F1KDD4|A0A1F1KDD4_9MICC GntR family transcriptional regulator OS=Micrococcus sp. HMSC31B01 OX=1581073 GN=HMPREF3105_05090 PE=4 SV=1
-MSRTGIGTVSLGSAPVSKADRAYQAILEGIRDQRHEPGDRLVLSQIAAELGMSVVPVREAIRRLQSEKLVAYERNVGATVVGIDPVEYRHTMETLALVEGFSTAQCAPHVTAEDLAAAREVNATMRAMTESETAWDPVTFTELNRRFHSILFEHHQNEHVHDLVHRGWNRLAALRSSTFAYVPGRAVASVDEHEHLLRLIEDGARFEEIEAAARAHRLNTLRAYLEHSAEPSA
->tr|A0A7C4I6T5|A0A7C4I6T5_CALS0 TatD family deoxyribonuclease OS=Caldiarchaeum subterraneum OX=311458 GN=ENM30_04935 PE=4 SV=1
-MIDVHCHLTEEPLLSNLGEVIMEAKKSSVEAIITSGIGPADCEKVLSIVDGVYIYGSLGIEPYALEGYEKVIELIMRNRERVVAVGEVGLDYYWGKKETREMQAKVFREFIELAKSLDLPLVIHSRSAGKYALNILIEEKAERVVMHAFDGSAGEAERGAAKGYFFSVPPSVVRSEQKQKMVRRLGLENLLLESDAPVLGPERGVVNKPSNIAISAKAIASLKNIPLDKVVEKTTENAKNIFRI
->tr|A0A2E7SH61|A0A2E7SH61_9EURY Thioesterase OS=Euryarchaeota archaeon OX=2026739 GN=CMA77_02820 PE=4 SV=1
-MTSDEIGVQRKFAPTSICFGCGPANEKGLQINSTRIEDGLELWFTPSSEHQAFPGMINGGIIGTLLDCHGNWAAAMSIMDARGDSEPPCTVTASYSIQLRRPTPADIPLHVTARVIELQDDRADVEMELYAEGKLCAKGKGLFVAVNEGHPAYHRWG
->tr|A0A1J0GT11|A0A1J0GT11_9CAUD Uncharacterized protein OS=Arthrobacter phage HumptyDumpty OX=1913080 GN=SEA_HUMPTYDUMPTY_66 PE=4 SV=1
-MSLTRKERENNLVCRHCGRPIVRNTGPRHRWARALPKMEWLHNAKDFDPSKPIDCFTPEPKA
->tr|A0A7G9IUQ7|A0A7G9IUQ7_MACNE NADH-ubiquinone oxidoreductase chain 5 OS=Macaca nemestrina OX=9545 GN=ND5 PE=3 SV=1
-MIMYTPIMMTTLISLTLPIFASLINPSKKHPYPNYVKTTVMYAFITSLTSTTLFICLNQETTIWSWHWMMTQTLNLTLSFKLDYFSMMFIPIALFITWSIMEFSLWYMSSDPNIDQFFKYLLIFLITMLILVTANNLFQFFIGWEGVGIMSFLLISWWHARTDANTAAIQAILYNRIGDIGLILAMAWFLLHYNSWDFQQMLALNSNPSSLPLMGLLLAAAGKSAQFGLHPWLPSAMEGPTPVSALLHSSTMVVAGVFLLIRLHPLMETNVLIQNLTLCLGAITTLFMAICALAQNDIKKIVAFSTSSQLGLMMVTIGINQPYLAFLHICTHAFFKAMLFMCSGSIIHNLNNEQDIRKMGGLFKTMPLTSTSLTVGSLALAGMPFLTGFYSKDLIIEATNTSYTNAWALFITIIATSLTSAYTTRTILLTLTGQPRFPALTNINENNPALLNPIKRLTMGSMITGFLITNSIPPTSPLQPTMPLYLKLSALYATALGFLAALDLTLMTNKLKMKNPSQTFKFSNMLGYFPTTIHRMIPYQNLLMSQNLALLLLDLTWLEKSMPKMISQTHITTSMTVSPQKGMIKLYSLSFLIPLTLTLFLMM
->tr|A0A2D6YFP4|A0A2D6YFP4_9DELT Ribosomal RNA small subunit methyltransferase H OS=SAR324 cluster bacterium OX=2024889 GN=rsmH PE=3 SV=1
-MSEPRFRHLPVLLAEVLGSTPANSKNLLDCTLGGAGHSRALLGKFPKANLYGIDRDPAALAASRHRLAEYPGVTAIEQASFLELPYWAEKWRKPFDFILADLGMSSEQLAAPERGFSFLQEGPLDMRMDPFRQVETATQILQQRSEFEIRRLLQTYGEERFAPQIARAIVQHRANAPLVTTSELAELVERVIPRKFQKPNFHPATQTFQALRMEVNQEPQEINALLDFAIENLQPGGRLAIISFHSLEDRPVKQRFREWERPCRCPSDLPRCVCGLQALGVSLQRKPIVAGAEEIEKNPRSRSARLRVFERNAVCFPGXXKXSRN
->tr|G3NV60|G3NV60_GASAC G_PROTEIN_RECEP_F1_2 domain-containing protein OS=Gasterosteus aculeatus OX=69293 PE=4 SV=1
-MNNVSVVRFFILSGINETNDYRVTLFTFTLLYYCIILILNTSIIMIIILDQNLHEPMYILLCSFCMNGLYGTTCFYPKFLLDLFSSSQQISYEWCLLQAFVIYSFPCYELSILAVMAYDRYLAICRPLHYQSVMTKRKVSQLICFSWFTPFCILSINIVLTSRLKLCGVNIDRLFCVNWKIVQLACYESDTFSNNITAYFTMLIFISHGLFVVWTYMHLIRTCVKSKDDRVKFMQTCVPHLVSLVTFIVAVVFDLLHIRFGSKDLPQSLQNFIAIEFLLIPPVMNPLVYGFKLKKIRNRILVYCPDAEATASLPGVQKRTPSKTVMHLCNTSSQRTTKNQSCILILSH
->tr|S9V0M4|S9V0M4_9TRYP Npa1 domain-containing protein OS=Strigomonas culicis OX=28005 GN=STCU_11365 PE=4 SV=1
-MCTHGFFTHIIEDAADLLQEGSEAGMRLAREAIHTFETQFITSKSVSTHQKRAVLLGQRSILRLLVKALEYAPAAETAAQVLYRIIVELAESPSDYASSHLESVSGQGMPNYLLFTLLRQLRPKCSPLASHLVLFLLHTAPDLIRPFFARVSVHMTEEGGSTAMGRVAASTARVATLNVMTRILQLPLPYHLAARQATLEPVATKVRTFYTMSPREVADEICPAWVAEYVHRLVNGSTNLLMLTFAMQLTQAALIRAQAVMRVVAEIQEVARRPRGDGAGRALGGRRRRHAGRRDRLGGLQRPRACAAGGGGAQTRGVLAPHDAAAAAAADPARGGGRRRRREGAGEDGLCVPPHAPPHGPVRQGARAAAAVAERGARIAPAVHAVAAADRAGAAGRQRRFPVLAGDLHLGPLRAAHR
->tr|A0A096XL47|A0A096XL47_9HYPO DNA-directed RNA polymerase (Fragment) OS=Thyronectria aquifolii OX=1491451 GN=RPB1 PE=4 SV=1
-VKKILEIVCHNCSKVLADKSDPEFVAAINTRDPKLRFNRVWAVCKKKRRCENEDRSEKKEKEEEYAPGLKPFVVENHGGCGNVQPQVRQAALQLKAAFEVAQEDGPKKKESMPITPEMAHGILRRISEADLRNMGLNSDYARPEWMVITVLPVPPPPVRPSISMDGTGTGMRNEDDLTYKLGDIIRANGNVKQAIREGSPQHIARDFEELLQYHVAT
->tr|A0A1D5P1X9|A0A1D5P1X9_CHICK FHA domain-containing protein OS=Gallus gallus OX=9031 PE=4 SV=1
-MSVTSWFLVSSTGIRHRLPREMIFVGRDDCELMLQSRSVDKQHAVINYDKEKDEHWVKDLGSLNGTFVNDVRIPDQKYITLKLNDVIRFGYDILPL
->tr|A0A2J8WE22|A0A2J8WE22_PONAB ARL8B isoform 4 OS=Pongo abelii OX=9601 GN=CR201_G0011344 PE=4 SV=1
-MIRLASWVWLLPPAGVRPCRAGAPRSRWRVRAEARSCGSRRRRRSSVLLSVLAPGRHHAGAHLPPAGLVPFALLEGGDGADARGAAVLGQDHLRQCHRVRSIQ
->tr|A0A1V8U653|A0A1V8U653_9PEZI Uncharacterized protein OS=Rachicladosporium sp. CCFEE 5018 OX=1974281 GN=B0A51_10502 PE=3 SV=1
-MGEASVVASQWRMVEVGRVVLFSNGPFAGRLAAIVEIIDHKRVLVEGPSESKDLLVPRHSSPLAALSLTRIVIEKLPRGAGSAALQKLWQAQEVEGTWNKSTYALNKAKTMRRRELNDFERFKAMRLKKQVRFQHRKSFAAAKASA
->tr|A0A7L3JVW9|A0A7L3JVW9_9PASS LTK kinase (Fragment) OS=Drymodes brunneopygia OX=626378 GN=Ltk PE=4 SV=1
-WAGGGGGGGGATYIFRQKDGIFEPLLIAAGGGGKAYLKAQDNSLDDVPLEQFENSTAVPGVSGRTGAAGGGGGWQDESLLPQAGKSLLEGGEGGQACPQALAKLQWTTSGGFGGGGGACTSGGGGGGYRGKSAGA
->tr|A0A7J7IY04|A0A7J7IY04_BUGNE SLC39A1 OS=Bugula neritina OX=10212 GN=EB796_022902 PE=4 SV=1
-MKAATNTENTRRKSMLDRCISFLSCFAAGVFLGTCLLDLYPEVQTKLYSAVTLYISKDSKFACYPFGEAVMVAGFFLVLIVEQMVLALKEMSVESSTPANQNSQPGSSSQSKRVTYDSINSTTNEYAEHERLLRSNSRDNTQSRSRLGSLSSIRSIESRNNVHSQSDDQHEHSMHHDPSSHSPIRSLIMLAALSLHSVFEGLAVGLQDTEEGVLSIFGALILHKCIIAFSIGLNLVQSKLAVKAIIVSNAVFCFASPLGIAIGILITDFNSDADSSLLVNGILQGLACGTFLYVTFFEVLPHEFNKPKDRLLKLLFVIVGFAFVNGVLFLEMFLSKEPGCD
->tr|A0A7I6S0I5|A0A7I6S0I5_9ENTR DUF446 domain-containing protein OS=Klebsiella sp. WP4-W18-ESBL-05 OX=2675713 GN=WP4W18E05_35930 PE=4 SV=1
-MTRHDSLRDQLLLIETLLRQHQHWQDDAPHESAFASDQPFCMDTLEPLEWLQWVLIPRMHQLRDSGMPLPKDFAIAPYYEMALDAAHPLRAIILPPLEQLDAFFTSDPH
->tr|A0A2L2NMZ0|A0A2L2NMZ0_9NOSO Histidine kinase OS=Nostoc sp. 'Lobaria pulmonaria (5183) cyanobiont' OX=1618022 GN=NLP_1471 PE=4 SV=1
-MEPRHIDTEVTRLEALRQYQILDTEPEEAYDNLAQLAAFICGTPISLVNFIDENRQWFKAKIGLDVSEMPRNVGLSYLCQEQRNVVVISDTLADEKLASNPVVTGYPYIRFYAGVALITPKGDMLGTLCAIDQVPRQLSQKQVEALVGLSRLVIAQLELRRHVIEVSKVTEKLVAHEQAACAQSEATKTRITNLLESITDGFFALDQKWQFTYINGQAEQLLQKTRNELLGKNIWEMFPEIIGTTFDCEYHRAILEQVSVEFEEFYLPQQQWLKVHAYPAKDGLSVYFQNVTERRKTAEALRESEERWQLALNGNNDGIWDWNLKTNEVFFSTRWKEMLGYKDHEVSNRWDEWTKRIHPDEQDWVLQAFQDHFATKTPFYVCEYRVQCQDGSYKWILDRGQALWDTLGDIVRMVGSYTDITDRKRADEELKRQNLRSQLFAEITLKIRESLQIDEILKTSVTEVQKLLQADRVLIFRLEIDGSGTVVQEAVLPGWPVILGENIFDSCFKEEYIERYRQGRVSVMEDIEAAHIQPCHRKFLQQFAVRANLVVPILVRDGIWGLLLAHQCAAPRQWNQFETDLLQQLANQIGIALSQAQLLEKETQQSQELTRSNAELEQFAYVASHDLQEPLRMVTSYLQLLERRYKNKLDANADQFITYAVNGASRMQTLINDLLNYSRVSTRGQPFVPVDCSAVLEQVLANLQLAIADSKAVVTHDTLPQIMADATQLTQVFQNLIANAIKFCQNQQPRIHIGVARGDTNINGESLNVIPSADEWLFWVRDNAIGLESQYAERIFIIFQRLHGRGKYPGTGIGLAICKKIIERHGGQIWVESKPGQGSTFYFTIPDRALKQSSTL
->tr|A0A4S4NBC8|A0A4S4NBC8_9RHOB Alpha/beta hydrolase OS=Aliishimia ponticola OX=2499833 GN=E4Z66_11820 PE=4 SV=1
-MPNYFETAEGRRIAYHKTEGAGPTIVFLGGLKSDMEGTKAVHLEAWAKAQGRAFLRFDYSGHGESSGTFEEGCIGDWHQDTLAAIDNLTTGPVVPVGSSMGGWQSLLLARARPNRIAGLVTIAAAPDFTEDGYWAGFSEAQKALLDSQGYVELPSDYMEPYHVSKRMIEDGRTHLVLRTPLALPFPVRCLQGTADTAVSTETALRLLDHADCEDMRLTLVKDADHRFSDPRCLAMIEAAVSDVLGI
->tr|A0A6I4G232|A0A6I4G232_AGRVI Chemotaxis protein OS=Agrobacterium vitis OX=373 GN=GOZ89_08175 PE=4 SV=1
-MTARRSLGARSGFSSFAFYGVLLTLAVGGPVACAGQAYAAGPNTPASNGPSTAPVAGTTGPAKSLPAGGDSDNLPPYLMLRSLQFVQDSVVRGDHSAADMQRFLLTRIDKRLRTAVSSDFEDPRNVDAALIYTMSGGNPATLDYLVARDVDGHFDNRVSDMLRKYLSGKGVLVASSLGEMVPLYQNGRVGPYIALVAGNVTLVKDPAAALKFFDIARLVAPGTIVEEAALRRSFQIAMDTGQNRRAMAYANRYARRFLYSPYASQFADLLVQLVVDHFSELDKNDILATLATMDPDRQREVYLRIARRATINGNQALASLASSQAQSLAGLPDKNDPQALLYGGAALISTTDVKNALSTISQLPKDQLSASDNALLEAARAVAQEIITLPTAPQSPSASPSTPPPSGDYTAPDAPANVSDQQDPGAPANAKANVVPDAGVGTAPVSPASADAKQKPDPEFQTFMSGGRSKLEEIDKMLKGEGVTK
->tr|A0A4Q3Y2I0|A0A4Q3Y2I0_9PROT ATP-binding protein OS=Alphaproteobacteria bacterium OX=1913988 GN=EON59_07995 PE=4 SV=1
-MIVGLDEPAFREKLKALLTPAQPISKPEHLHGRDKKLMLIDRALNSPGKHIFIFGDRGVGKTSLARTAAAIHAADEEGFAFIACDQGTTFFDMVEDIYRQLHRLYSLGKFKMDGIELSVPFLKIKANEAFGLPALRTINDAIETLKTIAPKDGVTPVVVIDEFDQLRSDTEKKYIADLIKQLSDQRINLRLIICGIGSSLDELIGVHLSTDRYLATIPLEPLPHDARWQILRTASDALGVTLDRNSEVRIGQLSDGFPYYVHLMGEQIFWQVLDDPKPIKSVSMEHYATGIRASIEEAQTSLKQAYEIATQKHKNSEDYEQVLWAVADGGILKRQVSEIYEKSYLPIMDQFEGRNPLPKNLFYQRLNRLKKATHGSIVIGSSTGWYGFKENVVRGYVRLRAERAGVEIGVDHILG
->tr|A0A7C3NPT6|A0A7C3NPT6_9CHLR Dienelactone hydrolase family protein OS=Chloroflexi bacterium OX=2026724 GN=ENS08_10630 PE=4 SV=1
-MYQTHMYEGMLAETITHHGYQAEVINAYFARPLGAGPFPGMVVIHHMPGWDEWYREVTRKFAHHGYAAISPNLYYRAGHGTPEDVAAKVRAAGGVADDQAVGDIGGALQYLLSLPYINGKVGVFGTCSGGRHAFLAACRLKGFAAAVDCWGGRVVMSKEELTPMQPVAPVDYTQDLSCPLLGLFGDEDRSPSPEQVNQLEAALQAHGKVYEFYRYPGAGHGFFYYDRPNYRQEQAVDGWKKIWTFLEKYLKV
->tr|A0A699THK2|A0A699THK2_TANCI Retrotransposon protein, putative, Ty3-gypsy subclass (Fragment) OS=Tanacetum cinerariifolium OX=118510 GN=Tci_880515 PE=4 SV=1
-MRQRRWLELLKDYDTNIQYHLGKANVVADALSRKSGMIVGIKVEEEIIRDLERLDIELYVRGQHGYWASLRVEFRLDDDNVLWQNTRLVVPNDASLREAILTEAYSSLFSIHLGSTKMYHDLKLHFWWSGMKRDVATFVSRCLVCQLVKIEHQRASGLLQPLDIPVWKWDEISMDFVTG
->tr|A0A328S3F9|A0A328S3F9_9EURY GTP cyclohydrolase MptA OS=Methanosphaera sp. SHI1033 OX=1945632 GN=mptA PE=3 SV=1
-MSVPEFPDTQDKQPSAPISLTRVGVTGVKKLLKIERSGNKRPIILLPTFDAFVDLPSTQKGVHMSRNPEAISEIVDEATNEPEIHIETICANLVKKLLEKHEYAVNAETEAKSEYIINKLSPVTKKKTQETTQIISRAVAHKNEDGTINVKKMIGAEVVGMTVCPCAQESVEKDSKEKLLEFLDEETTEKVLKTVTFASHNQRGIGTILLEVSENQEVNVDDLISIIQESMSSPVCEILKRPDENRIVTNAHQNPVFVEDCVRNMVIGLLNKYPNLPDNSMVTIRQVNQESIHQHNAFAEKVASFGELRQENIQE
->tr|A0A433MDU9|A0A433MDU9_9BURK Phosphoadenosine phosphosulfate reductase OS=Variovorax guangxiensis OX=1775474 GN=EJP67_02995 PE=4 SV=1
-MSIDIERINAELGRNAQGLVDWALGLGQPAIVTTNFRPFEAVILHLVTQVKRDVPVVWMDNGYNTEATYRFADEVTKQLGLDLHIYLPRRSRAHREAVEGPTPALDDPRHAAFTEEVKLEPFARALRETAPKVWFTALRATDTAVRAQMDPVSINPDGLIKVAPLLHWSSKDLHEYCVKHGLPNNFDYVDPTKGEDNRECGLHLAH
->tr|A0A147H9Y5|A0A147H9Y5_9PSED Ribosomal RNA small subunit methyltransferase H OS=Pseudomonas psychrotolerans OX=237610 GN=rsmH PE=3 SV=1
-MNPVFHHVSVLLDEAVQALEIQPAGRYLDGTFGRGGHSRAVLRLLGGEGRLLGFDKDPQAIAAGQALAAEDARFEIVQRSFAELGDELVSRGWSGQVDGVLLDLGVSSPQLDDPERGFSFMQDGPLDMRMDPSRGQSAAAWIATAAEADIAQVFKEFGEERFAKRMARAVVQRREVQPFERTADLAKVLTEANPAWEKGKHPATRAFQGLRIYINRELSDLEQGLQAAYEQLAVGGRLVVISFHSLEDRIVKQFMRRLAKGEADQLPRDLPIRATVFEPSLRLLGKPIYASEGELAANPRARSAVMRVAEKLK
->tr|A0A2F0BA01|A0A2F0BA01_ESCRO Ubiquilin-2 (Fragment) OS=Eschrichtius robustus OX=9764 GN=ESR_40773 PE=4 SV=1
-MQQLIQRNPEISHLLNNPDIMRQTLEIARNPAMMQEMMRNQDLALSNLESIPGGYNALRRMYTDIQEPMLNAAQEQFGGNPFASVGSSSSSGEGTQPSRTENRDPLPNPWAPPPATQSSATTSTTTSSGSGSGTSSSSATGNTVAAANYVASIFSTPGMQSLLQQITENPQLIQNMLSAPYMRSMMQSLTQNPDLAAQMMLNSPVFTANPQLQEQMRPQLPAFLQQMQNPDTLSAMSNPRAMQALMQIQQGLQTLATEAPGLIPSFTPGVGVGVLGTAIGPVGPVTPIGPIGPIVPFTPIGPIGPIGPTGPAGPPGSTGSGAPPGPTVSSSAPSETTSPTSESGPNQQFIQQMVQALAGANPPQLPNPEVRFQQQLEQLNAMGFLNREANLQALIATGGDINAAIERLLGSQPS
->tr|A0A7U8PMI8|A0A7U8PMI8_BRUAO tRNA (guanine-N(7)-)-methyltransferase OS=Brucella abortus bv. 3 str. Tulya OX=520451 GN=trmB PE=3 SV=1
-MIDENHPMRAAGNFFGRRHGKPLRPHQSNLFEDLLPRLKLDLATPAPQDLRSLFEAPVEAVRMEIGFGGGEHLHHESGRYPQSGFIGVEPFINGMAKMLAALDQAPRPNLRLYDEDATAVLDWLPDASLAGIDLFYPDPWHKRRHWKRRFVSDANLDRFARVLKPGAKFRFASDIEHYVNWTLQHCRRHAAFDWQAESPADWNDAYEGWPGTRYEAKAFHEGRRAAYLTFIRR
->tr|A0A2S5CXJ6|A0A2S5CXJ6_LYSSH Single-stranded-DNA-specific exonuclease RecJ OS=Lysinibacillus sphaericus OX=1421 GN=recJ PE=3 SV=1
-MILSKKRWQVKRPDAQLVQTLQNDLQLSAIAAKILAARGCTTSADAESLLNMTEANIHDPFLMHGMAEAVARIQQALENNEKILVYGDYDADGVTSTTVMLHVLLDLGADVSFKIPNRFLHGYGPSEALFREAHEEGIQLIITVDNGISGIEPIRVAKELGLDVIVTDHHEPGEELPQADIILHPRVPEGHYPFGELAGVGVAFKLAHALYGELPTHLFEFVAIGTVADLVPLVDENRYLVKRGMEEMRRSLSPWIQAMCEVASAEQATINEETIGFYFGPRLNAVGRLGEASPAVELLMAEDTAKATALAKQLNGCNAERKDIVKSITDEAIAFIEADKKIGDSLVLVVAGEGWNAGVVGIVASRLVELYYRPTIVLSLDFEKGTAKGSARSIEGFHLYNELAKNRDILPHFGGHPMAAGMTLPLEHVDELRTRLDAQARACLTEEQLTPVLAIDIPLKIDEISADAIEEIATLGPFGTDFPKPVYVLEDVEIATMRKIGAAENHIKMELTDGLEKLDSVGFNKGHLYHELTYGIKVSFTGDLQINEWQGRKKPQFMIEDVQTTEWQLFDIRGIRQTSRWLHTVPKEEAVFFAFRLETISYYQSLLGVPIELVDVELSNVEQTDYIVLLDLPHNVQLLENVLSKTAPTRIYAHFYMPDSQYFNGIPTREQFAWYYKFLKQRPAFPLDMHLPDLAKHTGWPLEALKFMTQVFFELNFVKMESGLTTVNMNAPKTALTEAPSYKQRSEQIEIEQKLVYAPYIELKQWFDERLNLYANTVS
->tr|A0A0C2NMI1|A0A0C2NMI1_9VIBR Serine--tRNA ligase OS=Vibrio renipiscarius OX=1461322 GN=serS PE=3 SV=1
-MLDSKLLRTELDDTAAKLARRGFKLDVETIRTLEEQRKSIQVEVENLQSTRNSISKQIGQKMAAGDKEGAEEIKKQIGTLGSDLEAKKAELDALMAQLDDITLSLPNIPSDEVPDGKDENDNVEISRWGEPKAYDFELKDHVDLGEMADGLDFASAVKITGARFIVMKGQFARLHRAIAQFMLDLHTEEHGYTEMYVPYLVNSESLFGTGQLPKFGKDLFHTEPLAEKVNDEEPRKLSLIPTAEVPVTNLMRDTISDEADLPLKMTAHTPCFRSEAGSYGRDTRGLIRMHQFDKVELVQITKPEDSMAALEELTGHAEKVLQLLELPYRKVVLCTGDMGFGSHKTYDLEVWVPAQETYREISSCSNMWDFQARRMQARFRRKGEKKPELVHTLNGSGLAVGRTMVAILENNQEADGRIRVPAVLQKYMNGAEYIG
->tr|A0A0B4FII0|A0A0B4FII0_METAF Src-like protein (Fragment) OS=Metarhizium anisopliae (strain ARSEF 549) OX=1276135 GN=MAN_04425 PE=4 SV=1
-MPAPTVEAPAVALSFANNFWGKEDAGVGPLLERMQSAKTTSDELKSFYSARASIEDEYARKLLHLSRKSLGSHEMGSLKTSLDTVRVEVESMAKQHQSIAAQMKSELEEPLAAFAGGMKERRKIVQSTVEKLLKTKIQQTQQVNKTRDKYEQECLKIKGYLAQGHMVMGQEERRNKAKLEKTQISLATANTEYESAVKILEETTTRWNREWKAAADKFQDLEEERLDFTKSSLWTFANVSSTVCVSDDASCEKIRLSLENMEVEKDIIHFITERGTGQEIPDPPKYINFCRGDVNDGQSEVSEDDNYSVAQFPRSINPAFRSSSPQPSTFESHHDPNSMLANNLAHREPREPPQPTSREAIVTPQKAPPPMRNSVDEQRRGQGQQKPPQYDVNQHGPLAAVPHDPYPMDGMTMLCRTGPPGPQSDRSSQPHSARPSSRESHSDYSIPTSLSSVEPPSGQASPVKQEPVETRSPEKRVLKKKSGFFQNHSPFRRKSTKEVQAPSQNRSTWHVAPGRAELERTASPEPIDANASLALGVGQNVLPVTTPDTRRRPGQGREQDVDQSDPIAMALAELKDVNLGKQSSLRMSADHYHGIATPGPGADPRSGRSSGREAPPSYNTQASVSRLGVPPPAVTSRAMKEATKKATDQSRAVFGNAGNRGASPASRPATRGSDMPRAASPAPTRSASPQPRMSGDSRYRSASPNPYSGHHRNASQASVSQQRGSGQGYYGSGSPHGSTRGSVRGASPASFRGDYDRPRSSYGGGSDMAVQLAPAGDDRYGSQRGRGAVDLYDGGSRPRSKSVADPSRQYTRDGRPILHFARALYMYQAAIPEELGFAKGDYLAVLRHQDDGWWEAEVHGGNGRVGLVPSNYLQPC
->tr|A0A1H6SIL1|A0A1H6SIL1_9SPHN Uncharacterized protein OS=Sphingobium sp. AP50 OX=1884369 GN=SAMN05518849_101367 PE=4 SV=1
-MLRRRAQGWCPDTQRAFIDALSRCGVVAQAARSVGRSPRSAYHLRRRAGADSFAAAWDWALDMGLDESRARAIALIRGKRVRPIVRRGEVVGQRTDNDPRLMFAALNALGADQDGRRAAMPHRQRMALRHVITTLIDNGPFSPEEWARLVPALAAVAGASPRPDALS
->tr|M6A221|M6A221_9LEPT ATP-sulfurylase small subunit OS=Leptospira sp. P2653 OX=1218600 GN=cysD PE=3 SV=1
-MNRSRLTHLEQLEAESIYILRETASQFERPALLFSGGKDSITLVHLALKAFRPGKFPFPLVHIDTGHNFQEALDFRDELASKIGEKLIVRYVQDSIDQGKAVEEKGKFPSRNGIQTVTLLDTIAEFKFDACIGGARRDEEKARAKERVFSVRDEFGQWDPKLQRPELWNIYNGKIGPGENVRVFPISNWTELDVWEYIRKENIALPSLYFSHKRQVIYRENLLFPVSKFITIDSNDRVEDKVVRFRTVGDMTCTAAVDSQADNIDDIILEIQTTRTTERGSRLDDKRSEAAMEDRKRGGYF
->tr|A0A438U9M4|A0A438U9M4_HELPX 2-amino-4-hydroxy-6-hydroxymethyldihydropteridine pyrophosphokinase OS=Helicobacter pylori OX=210 GN=folK PE=3 SV=1
-MMREILISRFFPSLFKKRLDFSNRVVLGLGSNLKNPLKILKNCFLYFKNHSKIGKIFSSPIYINPPFGYTNQPNFYNATIILKTSLSLRHFFALVFYIERRFGRARKRDFKDAPRTLDIDIIAFNQVILRQNDLTLPHPKWNERDSVLVPLALQQILFKKGEW
->tr|A0A4Y7J8A4|A0A4Y7J8A4_PAPSO Uncharacterized protein OS=Papaver somniferum OX=3469 GN=C5167_014818 PE=4 SV=1
-MSRGILVWFISSNLRFLDLDGGDCDNQLGAVEYVEEYFISSSKSQSLVRDYLGIHSLKSMRSGSLKLLGMSSMPIASEYEEIWAPEVEYLGIHSLRSMRSGAVALREVRLEKNSLFWKKCSSLTTLTKQATTQFRELRGAPPGSVNWEMQRQATARFCELSGGQMQLHTGLAFVFLLQIQLAELLKWNAGASWRCPAFGQRA
->tr|A0A2T0RHF1|A0A2T0RHF1_9ACTN Transcriptional regulator OS=Pseudosporangium ferrugineum OX=439699 GN=CLV70_12320 PE=3 SV=1
-MRVRLLGTVDVHAGDEFRQVPGLRRKAILSVLALNAGRTVSAGRLLELVWGDRAPATGLNTVQSHVSYLRRILGARSAIVSRSPGFLLDLPGDATDAATAERLIHAGLRAADPARAAEHLRAALGLWRGSPLQGVTELPWLAEQARRLSKLELEARRALAEARLALGEHAELVPELQALAAQHPFDEQIQAQLVLALYRTGRQSDALAVVREVRRLLATELGIDVGSALSELETAVLQHDVAPARERIEPAPVPPAGPELVGRGRELGALLRHLDHRRPSGAVVPVVSGDPGMGKTRLLTELAVRAGQSGRTVLWGRAAEFEQQVPFALVMDALADHLAGTDPRRLDAVAGTDRALLREILPMLPAPENRTAARQAVEAERYLLYRAFRCLLEALAAPPGLLLVLEDLHWADQGSAELLAYLLRHPPRGPVVVAVSYRPRQMRGPLRQALGRAIQDGSADLVDLDPLSPAEADTLLPAELAADRRQHLYALSGGNPLYLLALAREGAAGPGEDDRSLGEQDPVPAAVREALRGELDALSAAETVVARAAAVVGNLAEVPLIAATAGLPEAEVSRALDALVGHDLLRPVPRTGRFQFRHPLIRRIAYDMAGPGWRVAAHGRAAAALARQGASAPEQAHHIESSARRGDPAAIDILRRAAAEVLHSSPGTAAHWLGAALRLVTDDHPPEVAQQLLGLRAQSLATSGQLAESREVLHRLRQAIPAEVTPERARLASWCAGVERMLGRHREANALLRAELARVADADGPVAATLLLALGARYIQPVPPGEPDWPRRALAAARRAGTPWMVAEALLQCVYADQAAGTWDASTRERLDEAAALVDARPDGELLELLHMVVWLATAETVYERLDDATRHVDRALGLARAAGQMYVVPGIHLLFVGLHMARGDLPAASRSLDEAREAVALAGTDTMMSMVLSRECTLAALTGDGKLAHRAGTEAVALAGRRGDYAAGVAVQALATAHLQAGEPAMCSSLLDGTEELPSTPTTRGTLYETLALAWSAQDRPEVAATWADRAEREVAVCPTPRRAGLAELARAHALRPVSASASAARAAAAARLFAGVDDRLLGGQAHLHTATALAADGQPGRARRELDRARTLFLSCGATALVDRTDQEERRIRR
->tr|A0A4R4X727|A0A4R4X727_9ACTN Cupin domain-containing protein OS=Nonomuraea diastatica OX=1848329 GN=E1294_00855 PE=4 SV=1
-MRRLAAISGATAGSTRLWMGQTHVAPATRSSDHHHGASETAIYVVSGTPAFVFLEDAEEVRIEAGPGDYIYVPPYVPHREENPDPSQEAVVVIARNTQEAIVVNLPGLAG
->tr|A0A7W1Q9P6|A0A7W1Q9P6_9ACTN Response regulator transcription factor OS=Actinobacteria bacterium OX=1883427 GN=H0W90_11130 PE=4 SV=1
-MRVLIVEDELKMASLLRRGLVEEGHAADVAPTGEDAVWMAQSHPYEAIVLDVMLPGLSGFETCRQLRNVGVWSPVLMLTARDGVDDRVAGLDAGADDYLSKPFSFAELLARLRALVRRGGGERPTELQVGSLRLDPASRRAWRGQVEISLSPKEFALLEAFMRRPGQVLSRLQLLEHAWDFAYENRSNVIDVYVRYLREKVDRPFDTDSIETVRGVGYRLSEDSDA
->tr|G3MBJ6|G3MBJ6_9CAUD Gp134 OS=Bacillus virus G OX=1084719 GN=134 PE=4 SV=1
-MKSSKRVDERIVKDYRIIDSAWDEFSDYVGEHNIGTPLTVKQFEEIFSKLNRNNKFSPMKDYILESFRNDCYAWPFVEKNQ
->tr|A0A5B1MAL1|A0A5B1MAL1_9MYCO SDR family oxidoreductase OS=Mycolicibacter arupensis OX=342002 GN=E6Q54_00665 PE=4 SV=1
-MSVLDKFRMDGRVVVVTGASSGLGVYFAKAFAEAGADVVLAARRVEKLAQAADLVAAAGRVGLPVATDIADPDAATAMVEAAMERFGRVDVLINNAGIGTAHPATRETPEQFREVIDVNLNGAYWAAQACGRVMQAGSSIVNISSILGLTTAGLPQAAYAASKAGLIGLTRDLAQQWGGRKGIRVNAIAPGFFASEMTEQYRPGYLESVSGRIVLGKMGDPEDLAASVLWLASDAGGYVTGQTIAVDGGFTIN
->tr|U4PPA8|U4PPA8_9HYPH Putative pyruvate, phosphate dikinase regulatory protein OS=Rhizobium pusense OX=648995 GN=BN877_I0001 PE=3 SV=1
-MENKKSFFHLHLISDSTGETLMSAGRAVSAQFHASMPVEHVYPMIRNQKQLAQVIDLIDKEPGIVLYTIVDQQLAEFLDLRCHAIGVPCVNVLEPIIGIFQTYLGAPSRRRVGAQHALNADYFARIEALNFAMDHDDGQMPETYDEADVVIIGISRTSKTPTSIYLANRGIKTANIPVVPNVPLPESLYAATRPLIVGLVATSDRISQVRENRELGATGGFDSRRYTDRATIMEELKYARALCARNNWPLIDVTRRSIEETAAAILALRPRTR
->tr|A0A1G9FD20|A0A1G9FD20_9SPHI Peroxiredoxin (Alkyl hydroperoxide reductase subunit C) OS=Pedobacter sp. ok626 OX=1761882 GN=SAMN04487898_112159 PE=3 SV=1
-MAIVGKKFPSVSIDAMSEMGDDLKINIFEEAVSKEKKVILFWYPKDFTFVCPTELHAFQAALPDFEKRNTIVIGASCDTNEVHFAWLNTAKENGGIEGVTYPILADTHRHLANILGILDQDVEYDEEGNESFSGSNVTYRATYLIDETGKVFHESVNDMPVGRNVKEYLRLIDAYAHVQKHGEVCPANWEEGKEAMNANRTGVAEYLSAN
->tr|A0A2T6ZBV9|A0A2T6ZBV9_TUBBO Interferon-related developmental regulator-domain-containing protein OS=Tuber borchii OX=42251 GN=B9Z19DRAFT_1104137 PE=3 SV=1
-MSELRRKALGSGKTVSRKAASRQSSAASSRANSRNTSRAGSRAASRANTDDEGSLSDETTFSLGSVDELATIDAELDETTTLWQEELGDRVNQIIERKKSSSAGREESLTAYIRILCAKYAKDEILPKKSELLDAFVRSFKQGKTEKEALLAAKALAITIVTDPEDTLFDKLAPDFKRTITDHASLPLKNALIHALGAVTFYGGASAAETELIMDFLKDIVESDGHDIGAGDDAGVVAAALEEWGNLATQLDDAEEITRRSMSFLVDQLDSSEVLVQVAAGENIALLYEKSYTEAEEDEVVEDHSESGLGKNFIQKYKPYPRHDVLIHTLRGLSSGSKKYLSKRNKKTQHSAFVDILHSVENPMKGPRYSEALDKDNRVRGSRMTVRIHKKGLLRVERWWKLHRLQHLRRILAGGFLNHWIENPVIFESLSLFVEEI
->tr|A0A811ATS3|A0A811ATS3_9GAMM Alpha/beta hydrolase OS=Acinetobacter variabilis OX=70346 GN=RYU24_01130 PE=4 SV=1
-MSHPLSSLEYQPDILGEGYEQATLEFPPDTEGTVVATLIRKKTDQPTSKAVLYIHGFIDYFFQTEMAERFNQQGFDFYALDLRKYGRSYMSHQKLYNVYHLSEYDAEISQALEIIGQEGHDTVLLSGHSTGGLITTLYAAHHPDRPLIKGLWLNSPFYDFNMTPFEKKFLVPKLSRLGKRFPEMLFPSRLNRHYVPSLHISYQGEWHFDLEWKKPSYHWVRLSFVHAIHEAQKEIHQGVRLNIPTLLMHAHKTTYPLRFNRNAQTSDVILQVHDMIEHAQKIQGDVQLCSIQNGVHDLVLSEKPVREQVYQQLFQWLENKAL
->tr|A0A3N5TH00|A0A3N5TH00_9DELT TPM_phosphatase domain-containing protein (Fragment) OS=Desulfobacteraceae bacterium OX=2049433 GN=EHM30_15800 PE=4 SV=1
-SINKAESETSGEIAIMVLDSSDSYSEAETFGAFVLSGLFSLMLELIISYLIGSEPGWGHGGSGFPYGFLADAAKSASIWTYIPMVFVFYFAFKFLLSKAPEIKILFMSGRRIEETVRERAVMAFYEKGLYKTRDETGILIFISLLEHKVWILGDRGINAKIAPDFWEKIAAELSAGIGKKEYGKAACQAITKCGEELSRYFPIKKDDTNELTNEVIL
->tr|A0A6H3NV40|A0A6H3NV40_9LEPT ParA family protein OS=Leptospira bandrabouensis OX=2484903 GN=EHR08_11550 PE=4 SV=1
-MKIITVASLKGGIGKTTTALYLSQALRSLGKKILLIDLDQNNNLSNFMIKQFPKGNDLDEKNILNMLKGYAEISEFIWESSDGIDLIPAKKDIKNIDIEFATDPILGLRFRNDLKSLNYDFILIDAHPATNTGLRCAILASDEIICPVEPSVWSSQGIDDIEIERQNASKAMKNEIKLRALISKCTLKKAEELKPILKKKGYQVFQTAIVNSEAIKVSNDISEFLNEKTGKAFPMFLSLAKEILK
->tr|A0A2T6K4E5|A0A2T6K4E5_9RHOB NADPH:quinone reductase-like Zn-dependent oxidoreductase OS=Yoonia sediminilitoris OX=1286148 GN=C8N45_1303 PE=4 SV=1
-MKALVYQKFGPPENLVISDLARPEACSHEVLVRVAYAGVNSVDWKIGAGRIDHYRNAPFPLVTGRDFSGTVVEVGSHVRNFSVGDAVIGCLPGPGGSFAEYVATDALSLARAPSNLTLAEAASIPLVGLTCWQALVGSAKLSKGEVLYVLSGAGGTGSIAVQLGAALGAKVITTCSERNRDYVTGLGANYIFDYSKPNFTDDLIAEFPQGVDVVFSNVLGPLHRDAYRTLRPGGILVTIGESPLPAVAEKHGVDEIDLIVQPNGKQLTEIVTYLENGTIKPPSVSIHALVHGAHAMQNISEGHVRGKIVLQVS
->tr|A0A6G0Z856|A0A6G0Z856_APHCR Dopamine beta-hydroxylase (Fragment) OS=Aphis craccivora OX=307492 GN=FWK35_00015581 PE=3 SV=1
-MKKRSASQRSFGHRWTTVVAAVVVFLSATCLVGHAGAEGRRVYTAPLDDTGRTAVYWTVDYGSRTVKFEAHFSGSGSPFDWFAVGFSDRGNHSGADFCVMWVDWKGVTGMLDTWTNDAGRISVDERQDCEEFNVARFHGGGTALTFTRKFDTCDDERDYLIQDGTTHIVWMVGGGPLFAVEGLLVSQARAKGMQRVQLLKPETPQVKLPNKVSKIDVLASKVNIPAEETTYWCHVMKIPLDLSFKHQIVRFESVIEESSRGVVHHMEVFHCEANANSRIPLYSGPCFSEKRPYKTQVCKKVMAAWAMGAAPFVYPEEAGLPIGGPDFNNYIMLEVHYNNPGLRKGMVDSSGIRLYVTPNVRKYDAGVIELGLEYTDKMAIPPKLEDFTLSGYCIAECTAV
->tr|A0A7R9IK79|A0A7R9IK79_9NEOP Hypothetical protein OS=Timema tahoe OX=61484 GN=TTEB3V08_LOCUS7834 PE=4 SV=1
-MCQGLYRLLYVSWEGVTPRSRRTTRVTESLRVTEVSRRMEEPDSYYTSNYHLLEAGRILQPEGDDYKLVFISSDSSSKEEEGSYSDDADSSSTTSSVTGVPGFTLDDCDWDYFESSSMVRPVLKDWSWSNNKVSPLGADASVDQQQHSFGFDSPQLSSRRLIYSRPSRGDVDPMLETEEKKTPPARGVRSELSSSPLFLDSPLSSETGSSFLHRRRSPMNMSGGSYIEAPVSPSRYRRPLFQLSRGDSARSSGERSVEEITSSDHYYYGCPPPQQWKVRVGGEMEGKVEKCPPGGIVTEQRTSHSATTAERVRSPSCETCGGPSALFPPGVYGVPVPVPIPVPVPIPVLIPASLWSVGGQHATTTGDTVSVADIVYVGSSGAGDEPTNAGSVRIRIHSFQRPSHGLAGPWCAWPVDNSGVLISPMITDNSAALRGEAEKVPVGRVPDSDRELSDGVHSRGPQSEHLAGDGVHVHTLKTTSSNSHEGETITNSVNFDIMINSPFVELKESEVSCKVLLSVDKDRSDDSATAHECDKDVGDNKIKTNSSVLEQTEPEIEEMSAGKTLPTEPELNTSQSEICASYLTKVTYCEDILDSNMKTEPSDAVSEKSDDEHNSGIVLVNFKPIPSESYSDSLTERHRFIITPEPMSTSATGSDTDNDHPNRRKGYTADKNLLKTKKRRLRKCLHSNDDSKFLPRERMSSNCSSDSGSSADETCVKTPVKRKYYLAGGDMSESGDDAASDVSSDDSTAGHTTDNEEGHFSRVFVINSTQSTSEEENDDSDTGENKTIEECTVLMSESVDRSCDESNEVGVVVQLKHIMALSDEEDMSSHHSEVPKAISTSDTGIVVLKHVRDIPEEHSFASQVPWRSDETVQVLKTNNGVSRSEGKEETPERSTNCLNNICLPTAAGELNNSVNIDGEPEDKCFVHHNEVISKLVSDLKNEVDKMKCEFVARASSVSTGPDKRSITPEESGMVARLQEHLSSEHAGARLVLPPSGNSENLTPPPVDGWPSPPPDTATSLGEVESNQDPSSNVTERETSGIAASASEVDNILARSAVVINTSIKSDLSTFHEGSGDREVIKSEIGENCLSLQDICGGPCSRTNPNSSRDSGDSSPTSPAPTDNTDQTKSPVLHLENTPVENEEVTSETPGALVELYLIDEESPIAITKDTLGDQSAAITSGSSPADLIDEESPVAITKDTSGDQSAVITSESSPADVDTPNISVNTDDLNIPQIEKNIFSDITPVSQKSKEHNLEISSDQTVETLSNSSIRYICKESETGKSSKTIQNELPGSDHAAPSIELVGSESKSGPTDCETSITCDELSGTESFNDYKLKGSFKESSDIEDDRDIEHNLTTEEISCPQVVDSEETGVKFEGNISCNNDDVALDCSSVYSKSGSRDHSQSLEEVQTNTLEDKKGPSPVESFRSGGDTVTAAAESASVGRETTGEREVGCQGVLSVASEPLTVKQRRGDVCPEAGAAAVGSHLSRYTSLVMITQDNNSFLKSQETSPSVVSVVTSETTTVVPEERNGDIIVSHTNWEEDDDAIHEKVSGLAGYFTLTLETAGSTPSMKRPLVTKNKHFMNEYSPPLPAQESGEGESEDLVKVVTGGDTLSAVVCLEEGLADDDSWVEEMDDRNHEDEDFATTTPTEDSSSGDEACSSASYGDREAELRGYHRAALDFTLHTIVEESCEESDDGPAKRKKPRPTSASELEKYFFYELGGGSSGSPGSRNLNSFSDSCSSIYSESLESLRGDDVTGNGEDKRDPAEMASSRLEKYFLKEFMGFAGDNYRDSDGSGSVGSDSEGRPSPEQRRKRLVRARGTGRQHSSSLDNLVASEHSGSEQQTTDTLVESEGSSTETDTHDELGGSMTFEKPDGQFDTVKRKKKKRSVAGSSSPAISDLERRPTPTEFLEKTLTSSNVEDVPQAGGEEDMSSDEDGSKTPQPEFLLPADLSATRNKQQSRDSGFIGSCDDLLREQRSQSDSSSCSNSAEVAQKTKTGSDGSGSGSDHDPPSGERPVTDHAKSESKATQSNKNNRKPSISDDDKSQSCTLSMTSTSVPPTTALTRKDSFNNWSSDEETNLMMSKMRAFFKTMVIAANNTNGPQKTPQTSPSLRPRGMKPPQLVYFENELTRLMKTVPGIRDDQVKEIVEYLSSEDTWSDSYDSSDYTSSDLEGAAAYYQHAMNRSELQEEISASCQQIINKFDTSVEEDNEEDKNGKVSDKSVDNEPSGIRRDTAFVYQKLVASFNKMGSGEQSASSDTNSSPHSSPPLIDKVMHHIGSRLVALMHEVSGGEGAGEMTTSSPKVRYHHHRRLQHKMSVTSTTTEEEDDSHTDTESDSNARSGNELGHDLVGSSTYNPLLARSKSHDLLLEKESRNYSHYHPQHKESSSSGVSDIAEEREASDYERFSWRGSFESALMTSDSRTKLSLLSCGDGSTSSSALALAAKRRSAGDLLFASSSKSSSREQLDRVRSCGSIGGNNAGSVEDKIWGTCNRRNSIPDASAGSGASADGDDDDDDDDDDDDHDDDLRSGRSTTLPRSLQTSCSAGTNSLPRLPTTGPMSSSVPNTPNIHKAHSMHLFLQSQANVKSARYRPPGFNRPAAPKRAVSAPGMQPPHPRRDAARRRPQATSQVLETVKFYSSSKWLPIHDCEALLVYSLGYIPLSTDT
->tr|A0A6J2QCM0|A0A6J2QCM0_COTGO AP2-associated protein kinase 1 isoform X2 OS=Cottoperca gobio OX=56716 GN=aak1 PE=4 SV=1
-MKKFFDSRRELVSSGPGSGVGGGGAGSGGGGTFIGRVFTIGRYQVTVEEIVAEGGFAIVFLVRTHQAVRCALKRMYVNNEHDLQVCQLEIQIMRDLVGNKNIVGFLDSSITAVGAGDVWEVLILMDFCRGGQVVNLMNQRLQTGFTEAEVLQIFCDTCEAVARLHQCNTPIVHRDLKVENILLHDRGHYVLCDFGSATNRFQNPQTEGVPVVDEEIKKYTTLSYRAPEMVNLYGGMIITTKADIWAMGCLLYKLCYFTLPFGESQVAICDGNFTIPDNSRYSQDMHCLIRYMLEPDPDTRPDVYQISYIAFKLARRECPVPNVHNSPIPAKLPEPVRASDAVAKKSQSKARLTDPTPTMETSIAPRQRPKAGQAQPQPISGILPIQPALTPRKRPNVAAGGPQAIGVGINVPTPAAAAVQAAAPQPAQTANMLSQPTPQHQQLLMKQQQATPFLSPQSNQQRQLIQTLQQQQQTSSQAFTLLQSKDKPVPPVIALQLHHRQHLAPVHETAASHLTPIPESAVAGPAADPEMAGRVIHKVGSLTPPSSPKMAPKSGHRRILSDVTHSAVFGVPVSKSTLLLQAAAAEASLNKSKSASTTPSGSPCSSQQSVYHPGDGDAQLALTAPNIQPSWNPFGDDNFSKLTAEELLNKDFAKLAETAAPGEKVTGSSENLIPGINAFPEKLIEGLKSPETSLLLPDLLTLVNPFNSSAENSANVKSEVCVDSLIPGLEAPQAQRHSGQPELNPASMPDSLTGEDSLLGCDLLSLTSPHGNQSGSALPSSSSCSSAPPGCGSGSCLEELPPGQTASDSAFLMSCGEKGNGDEFDPIPVLISKNSNQDVQGESNGYSVLDEGRETELQEGDSQANESCVHSSDEEDDDDDDYEEEEEEEAHKEEQQDEGAIESHAAAHDCSGSRPLLLDSEDEEEPGPQLALHSSPHSSTVPTQPSTTFHQPTPSTFAQNHSQHVHEPAQGADAAAADVFLKAPFPIVQEESADVFANAPFPRAHTAAPQPFDVFSQAPFGKRKEATVAHPSYAVTPDQGVLGQVVQQPFRPQALAKYSRHFEGPVPQQPVAAHRVVSNVSRQAAVASVPVGPLHLWTSEVSAVDPFVSAPFHLKATQEKP
->tr|N2A2M6|N2A2M6_9LACO ATP-binding cassette, subfamily B, bacterial OS=Lactobacillus sp. ASF360 OX=97137 GN=C821_00970 PE=4 SV=1
-MDIFKKLGWFFKEEKKRYIIGVLFLALTSLANLVPPRVLGLMADELDKGHITWGQYGALILAIVAAAIVLYVLRYFWRKQIWGGAAELERKMRTRLFNHFMIMDKTFYQRHRTGDLMAHATNDVTAIQNVAGDGVLTLVDSLIMGLSTMIAMIVFVDFRLTIVALLPLPFLAWGAWKLGDHLHVAFDKSQAAFSRLNNKTQESVSGIKVLKTFGQGKEDTAAFEKMVDETIKINKHVFVWDSLFDPLGTLIIGLTYAITIIYGGFLVKQNILSVGQLVSFIAYIGNMVWPMFAIGYLFNILERGSASYDRVEKLLNEKSLITDENADETLTAKDIEGDLDYNIKSFAYPDEKDISVLKNIDFTLKPGQTLGLVGRVGSGKTTIIQLLLREFDNYEGKITLNGHDIREIPLNVLLRQISYVPQNNYLFSTSIQNNISFSQIDADNNQVVEAAKKSDLHNDVLQMPCAYQTLVGENGISLSGGQKQRMSIARALLKHSQILILDDALSAVDAKTENEILKSLKKERKGKTTLIATHRLTAVKNADLILVLKNGRIIERGSHDDLLQENGWYADMWRRQELEEKVGDENE
->tr|A0A1J5KGW7|A0A1J5KGW7_9PROT Peptidase_M14 domain-containing protein OS=Bacteriovorax sp. MedPE-SWde OX=1860085 GN=BM556_01360 PE=4 SV=1
-MNLLKNEFEFIEELVKRSPDIVDHEVLDSVKFKNKSYDIHSFSIGPKDPEVPVLALFGGVHGLEQIGSHVVIAYLNYVIERLHWDKNFAALFEKVRLVSIPIVNPVGFKNFRRSNGNGVDLMRNSPISSKEKVFPILGGQLISSKIPWYRGDTNQMEKESQLMCDFVKDNVINSKNAISIDFHSGFGFKDRLWYPYACSKKKFDGIDNLKRIESLLDRTLPHHIYKVEPQSDHYTTHGDLWDYLYFHKKEHHPTMNYLPLTLEMGSWIWLKKNPLQLFSKLGLFNPIKDHRFNRAMRRHFLMIDFFLKAAANPDEWTA
->tr|A0A6H1WSD3|A0A6H1WSD3_9BACT Ribonuclease 3 OS=Thermosulfurimonas marina OX=2047767 GN=rnc PE=3 SV=1
-MKELYPRLPELERRLGVRFRDPGLLVQALIHRSYAAEKKLPPGADNERLEFLGDAVLSAVITHLLFERFPEASEGELSRMRAWLVREERLARIAERLGLFEFVLVSRGEARSGGPKKASILAGALEAVIGAIYLDGGYGKVFECLRRLFARLLPQARRGMEADYRSRLQELTQALFRETPTYEVVSEKGPSHAPIFEVEVRVGERVLGRGKGRSKKEAAQEAARKALDILEKEK
->tr|A0A371WXQ8|A0A371WXQ8_9HYPH Transposase (Fragment) OS=Fulvimarina endophytica OX=2293836 GN=DYI37_19485 PE=4 SV=1
-MARGDLTDEEWAVIGELLPSERGRKSRPAYDNRRFLNGMLFVLRAGCPWRDMDERYEKWNSVYVRFRRWAEQGVWDALLETLVETGLTDDWQ
->tr|A0A7X8YS75|A0A7X8YS75_9BACT Uncharacterized protein OS=Acidobacteria bacterium OX=1978231 GN=GXY47_00410 PE=4 SV=1
-MARTMILLALIAAFCTTAAANTDATCDRACLEQWVDRYLAAMRDRDTSPEMFAPGLKFTEDGVRLPFGNEGLWHSMSGVGKYRFYVPDVEAQQVAFLGTVREKAPRSREESLSALALRLKIRNDRITEIEQIVIRPDSVNSSAGDFPPTGPAVEAMGAPHPVFAESIPEAERMSRKDLIETANHYFTGLENNDGKGYYPFTDDCVRFENGVDVLLNTNKETGEQTRTTCKQQFEEGVKGIVTRIRDRRFVAVDREKGIVFSFAFFDHDFIHWTWQLAELFKIENGQIRRIEAIFHRAPYGMNSGWSSFEKGISNEIQAP
->tr|A0A1L3I1X5|A0A1L3I1X5_9RHOB Glutathione hydrolase proenzyme OS=Phaeobacter porticola OX=1844006 GN=ggt PE=3 SV=1
-MKHLFWAGILLAATPAWAQEAADAVAPEGAAETADAGFAAISEEVAAAIEAKEEGTPVEADNWMVAAANPHAVSAGAEVLRAGGTAADAMVAVQTVLGLVEPQSSGLGGGAFLVWYDAATGEVTTLDGRETAPLAATPTLFQDDSGEPLKFYDAVVGGRSIGTPGTPALLEAAHRRWGRAAWPGLFTAAIDLAEDGFAVSPRLAGLIEKDADRLSRWSDTADYFLPGGTPLAVGSTLKNPAYADTLRRLAAEGARGFYSGPVAEAITSAVRGAEGNPGVLSAMDLALYQVKERPAVCVAYRAFEACGMGPPSSGALTVGQILGMLGNYDLAELGADNPDAWRLIGDASRLAFADRGRYMADSDFVPMPTQGLVAQDYLATRATLLSGDDALPAVNAGAPEFDHALLLADDESIELPSTSHISVVDQYGNVLSMTTTIENGFGSRLMAAGFLLNNELTDFSFRSHREGVPIANRLEPGKRPRSSMAPTIVLKDGEPVLAVGSPGGSRIIGYVAKTIIAWADWGMDVQQAVALPHAVNRFGTYDVEAGTSAEDMTQPLTDMGFEVNARDLTSGLHLIEIGDGLKGGADPRREGIALGE
->tr|A0A5B7FTI9|A0A5B7FTI9_PORTR Uncharacterized protein OS=Portunus trituberculatus OX=210409 GN=E2C01_042056 PE=4 SV=1
-MGWYEARSVGSLQELGMGMRMENFQQVAADIAELEEGGLERGWEVGEELVWDMVGTQ
->tr|A0Y2I9|A0Y2I9_9GAMM Uncharacterized protein OS=Alteromonadales bacterium TW-7 OX=156578 GN=ATW7_12101 PE=4 SV=1
-MHVYTFAFKNIVDLYLSIGFNQVLTYTADLHVLFDMYKHRNIVALEYP
->tr|W7X7N4|W7X7N4_TETTS Uncharacterized protein OS=Tetrahymena thermophila (strain SB210) OX=312017 GN=TTHERM_000096738 PE=4 SV=1
-MVMSNKINNVQDALLKIATFVINSNVVSNAKVDISYLTIHRFVLKIVELDIIYQIIMNVWRVIKLVSLAKVQQTQIAQLAKVIYISHLPAQNVHNAKTNNIQTIKIIVKVVSPFVRLVTAHQANNVQAVKISQLQAIYHLNVLLQINNIQNHYNIIFKMALSVLKYQVKI
->tr|A0A5S3TR38|A0A5S3TR38_9GAMM tRNA-uridine aminocarboxypropyltransferase OS=Pseudoalteromonas sp. S4498 OX=579562 GN=CWC29_08935 PE=4 SV=1
-MKRNTCPVCRFPTNTCVCSYIGNTISNTTQVIIIQHPSEVKVAKNTAKLLALQLDRFTLYVGENTADFEELINFCRLNHVAVLYPNSHAKTLTTEYNFDQTLDAIILLDGTWKKATKLYNLNPWLSQLPSFQFDSVNASEYTIRKSKHEYSLSTLEAAAQFLEIVDQCETADLYKLQAGMVKEQMKLMPDDVKARY
->tr|A0A859QKW3|A0A859QKW3_9HYPH DHA2 family efflux MFS transporter permease subunit OS=Ensifer mexicanus OX=375549 GN=FKV68_04155 PE=4 SV=1
-MNRIVPLILAIALFMEQMDSTVISTSLPAIAHDIGVGPITLKLALTSYMVALAIFIPLSGWMADRFGAKRIFRTAILVFIVGSVLCAISNSLIAFVLSRFLQGMGGAMMTPVARLVLVRGAPRSELVSAMALLTIPALVGPLAGPPLGGFITTYFSWHWIFLINVPVGIAGYVLSGIYLPAMERRNPPPVDILGFLLGGIAASGIVFGLSVISLPALPTSVGFASVSAGIAATLLYIVHARRHPAPVLDLKLFRNSAFRAATIGGTIFRISVGAIPFLMPLMLQIGFGLNPFESGLITFVGAIGAITTKFLARRVLAFAGFRTTLIVAAVVGGLLTFANGFFTPATPYLVMISILLLAGFARSFFFTSINALSFADIDDADASKATSMSAVLQQISLALGVAVAGAILEVQTSISGGPLGLEDFHIAFMIIAGANLLGAIPFLTMAKNAGASVSGHRLQMREAETTAGK
->tr|A0A1H3LQ38|A0A1H3LQ38_9ACTN RNA polymerase sigma-70 factor, ECF subfamily OS=Asanoa ishikariensis OX=137265 GN=SAMN05421684_0874 PE=3 SV=1
-MVSLRDGGDLDVVPGLGPPGQTSFEEFYAAHFQSLTIQLYAYTRDLPGAQDVVQEAFCRALSRWKHVVDYDDPAAWVRRVAWNLATSRWRRTRTAAQFLRQQRPEHVAEPSPDRVALARALAALKPDHRKALILHYLADLPIAEIARQEGISENTVKSWLHRGRAALATQLSEEEADSA
->tr|A0A0M1JIZ9|A0A0M1JIZ9_9GAMM Uncharacterized protein OS=Achromatium sp. WMS3 OX=1604836 GN=TI05_02375 PE=4 SV=1
-MTETTTPQIISIGPENTINEVVVFTSHAQIKRQITTPVQLGTNRFLIELHAFEVDADSLQAAVYGTGEIISVQYKEISVTEAETKQLDLNELKAQQHQLEDQRRTLKYTLEDCKKQRAFVDSALKQVETRDVLGKINIKELFENLQYMLEIVDTTYAKLSQQELDIFKKTQAIEEQLNLVQQQLATRPDVPSTHKIVEVLFNSKTSEKIKMEISYIVNYAIWKPFYKVDVTQDLTNLTIMMFAHIEQNTGEDWQQVKLSVSNAMPIQSTRLPELKSWHIQQPDIFECSTDPWDSNTQQAPLNGVQLDGSSNMEELTTSNLSDFPGSEVHTDDFASEADPLEEADLYIAYGRYEHAETVLLEYIKNHPNSNDAKNKLRALYLVTRNTQKLRELARNHPGKTYLQEILQHIENDDTAFPSSAPAATFIQAQDLQSSLAFEFQLPTLIDIPANGNETLLPLFTKIPKYGFFYYTIPKQDPLVYLVCQADLSNEWLPGRMNIHIGGRFVGNTILDEKQAGQELLINLGSVQDVKIKREKYLDEVSKRMFKGMLDRSNALRKVEIRIVIENLKEQEIQIKILDAIPVSSTDTIQIKDVTMTPEPTLKDWQSQQGVMQWDLNIAAKSVIEIRMQFIVKYPRNCQIAHLNID
->tr|A0A7K5B0S4|A0A7K5B0S4_9FURN IL8 protein (Fragment) OS=Furnarius figulus OX=463165 GN=Cxcl8_1 PE=3 SV=1
-AILEGNGNLSCRCAKTTSAYISPKKYESIEIRPVGSTCRRMEIIIKLKAAGKVCVNPEAPWVTKLLKRIAST
->tr|A0A842V0K5|A0A842V0K5_9ARCH Uncharacterized protein OS=archaeon OX=1906665 GN=GF352_04095 PE=4 SV=1
-MVKKTELMKEFEEETDQHAVWGGKVTKAFKEWKKERRLKKLVICPWCGKRVKNYTTHQCSRRRRWKG
->tr|A0A1I8IUJ6|A0A1I8IUJ6_9PLAT TGF_BETA_2 domain-containing protein OS=Macrostomum lignano OX=282301 PE=3 SV=1
-TACLPAHSEPPSLQSTPTPPGSRSSIKTRPVGGRGEDPLLSRLFHWCGGSFCLSDQTCLEFERSRCLCLAAAICLCGCLLCADSAPAPTTFATPEPLVSSSTEEDAVSFLHKEFYSNAGTTKDGRVISDIIREELRRINLKYEGLSNMTVSTWRKFLRDAYMGVYLKQQSMSDRVTNLLYENLGISKGDVLLDVSEKEDLLTRIPDAILTRVYKWNARPMTRKFEESIFIGTPKTIQDLAGREHHGWSFIIDRSISEQRITKLSMSVHLTPKSRPLVKAMRISVYQLSNASDTLLSPGATRTKNVILSAAAMDEISVDFSADVKPIITKFFSPQSGDQIELFFLIECPQCKTKSDLNVAYLVMDCKVRIRETTGPEDQQNDRQKREASREPWPFEVAAASLFNNVTSSKDITKTQKCILEKMRMRHGQVSCCMMDFTYDLIHQSAVLAPRQLQINYCTGECHGQSEVNNAHSSLLQIFSHSQTSQLSHATREEISLCCVANTYRDFQVLTVVRKPGGGSNVQLKTIKDLSAETCTCA
->tr|A0A0C4EGC0|A0A0C4EGC0_MAGP6 Uncharacterized protein OS=Magnaporthiopsis poae (strain ATCC 64411 / 73-15) OX=644358 GN=MAPG_11851 PE=4 SV=1
-MEDLGSGHESLGAASLVARLKALGGSVMAEKKARVRDNWAMRHDCLCFQVLTACAHMPCLPSASRCSPRRARQIREAVYDRVSPRHGHIRHGPVCAIQPRVEALDVHLQTPTGQRAVIARHVVQTTSVGFQQLYKPSLAGEHDYKGGGIHSPEYGGGGGELGQDGAGFEVVMTARSPRYMETLQNVTHPTTLGLYDIGVKEANGLAGLAAAGFPVVDGAPVASVATVAFA
->tr|A0A178C6C2|A0A178C6C2_9EURO Clr5 domain-containing protein OS=Fonsecaea multimorphosa OX=979981 GN=AYO22_04817 PE=4 SV=1
-MASADGSPVDRKSKISKRSSNSYTSEEWRRHRPLITQLYFEEGRTLKDVAEYLKREYDFAPTERMYKSRLHTWGLDKKKKEHEMLDLVRQGLQQKGDDKDKVFLVRGRQVTLADALHYFNRKGIKDPSSLLEPQRSVSGDISSPEDADVKTPLSSNDDMLNATQDASDLEMTRSPMEMSEPEKPTLALRLRTSDVAAERLAMLQQALNIPELPPMPPFRTLSVESSVAQVTASAEDQRYQDVIFQNMQNHYMNLFTTRNLSIRNTTGTWTATSDDALADRFYYSMYHGYSFLWNGQRDRAFDNFYKAFALIEGLLKDDHVGFMIYIFDLIIRHDGTGYEEPLLMLLQHLADMAKTVFESEDHPIYVIAMHMHDATASRAWLAESTLRRLLDFFQDSIGYFHPETIALLQTFASGLLNREHFAEAAVRFQQLVDAFETTVNKRCYEVCYALRSTSEAFFHMEDYMRALQAIKASLERSQTLPRTEEREIYVRCLRGLAEISNKLGRKDEANETMQYVVDICRDAFGPEHPFTNRARMHLKTILKGDASSVSAIPPVVYRLGRGGSAAKYIWISRSSPTRLQA
->tr|I2NKN2|I2NKN2_NEISI Proton-translocating NADH-quinone oxidoreductase, chain L OS=Neisseria sicca VK64 OX=1095748 GN=HMPREF1051_1935 PE=3 SV=1
-MNDMTLYLIIALVPLAGSLIAGLFGNKIGRAGAHTVTILGVAVSAVLSAYVLWGFIDGSRAKFDENVYTWLTMGGLDFSVGFLVDTMTAMMMVVVTGVSLMVHIYTIGYMHDEKVGYQRFFSYISLFTFSMLMLIMSNNFVQLFFGWEAVGLVSYLLIGFYFKRPSAIFANLKAFLINRVGDFGFLLGIGLVLAYFGGSLRYQDVFAYLPNVQNATIQLFPGVEWSLITVTCLLLFVGAMGKSAQFPLHVWLPDSMEGPTPISALIHAATMVTAGLFMVSRMSPIYEMSSTALSVIMVIGAITALFMGFLGVIQNDIKRVVAYSTLSQLGYMTVALGASAYSVAMFHVMTHAFFKALLFLAAGSAIIGMHHDQDMRHMGNLKKYMPITWLTMLIGNLSLIGTPFFSGFYSKDSIIEAAKYSTLPGSGFAYFAVLASVFVTAFYAFRQYFMVFHGEEKWRSLPEHHSDDHGEEHHGLGKNDNPHESPLVVTLPLILLAIPSVIIGYIAIEPMLYGDFFKDVIFVNADAHPTMHIMKEEFHGALAMVSHSLHSPVLYLAIAGVLSAWLLYVKLPHLPAKIAQTFRPVYVLFENKYYLDALYFNVFAKGTRALGNFFWKVGDTAIIDNGIVNGSAKLVGAIAAQIRKVQTGFIYTYAAAMVFGVLVLLGMTFWGLFR
->tr|A0A233RNA1|A0A233RNA1_9ACTN Uncharacterized protein OS=Streptomyces sp. 2R OX=1883452 GN=BEH93_02570 PE=4 SV=1
-MKPRARALAVLSVVAMSIGGVTATATPAAAVGGCPSGKLCLYEGTNYNRLAVTSTSTQACVYLRNFGSGFGTGIASYVNNLPVNAVVYNYRGSTDTFAVAGTIRPGGFSSNSLGANFGVSGAVCMGGVSPS
->tr|A0A1I9YL31|A0A1I9YL31_9BURK Polysaccharide deacetylase OS=Paraburkholderia sprentiae WSM5005 OX=754502 GN=BJG93_10115 PE=4 SV=1
-MKRCKALVKEMLAGFVVVSGLAWFTRKLLWRDRVAVLLYHDPDPDTLDRHLTYLRKLCEFVPLTDVSAPGRDRPRVAITLDDGHAGNAKLLPVFIKHNVRPTIFLCSRIVGRPRSHWWLHPGSLRIGHERLKRMTNDERLAALAAQGYQQDGDDRPTGLSIEQIQAMREHIDFQAHTRFHPILTHCSDAESAAEISDSRREIAALLQQPCEHFAYPNGNYGDREVEFVRAAGFKTARTCDIGWNDQHTDPYRLRTIIIDDAASTLRFAAQLSGIAVFLRYLREGGGWRGKFPQF
->tr|A0A8A5HS67|A0A8A5HS67_ECOLX Uncharacterized protein OS=Escherichia coli O89m:H9 OX=2810406 GN=JSU13_20360 PE=4 SV=1
-MSGTIRALCHRAHQSSTTRDVALDRHVPGCEDILKEVIWAFSDFVRDHRGVYDPEARYPAGNPWYPVTGQF
->tr|A0A0M1MZY3|A0A0M1MZY3_9MOLU 50S ribosomal protein L17 OS=Candidatus Phytoplasma pruni OX=479893 GN=rplQ PE=3 SV=1
-MGYSKLRRTTPQRKSLLRSLVSSLIVNEQIVTTFSKAKELRRVVEKSITLSKKNTLHARRQASLLMFDKKIDEDKTVLQKLFNELSSKYQDRPGGYTRIIKTESRKGDAAPMAIIQLV
->tr|A0A1G7QPU8|A0A1G7QPU8_9EURY C2H2-type domain-containing protein OS=Halorientalis regularis OX=660518 GN=SAMN05216218_11345 PE=4 SV=1
-MWGYDTGNLMPECNYCDASFEQEGAYLEHLHTEHDESELSRIDRRRVADHVGDDEEGEFPTGPAIIGGTLLLTVGILVYVVFFLNIGGGSGPAAASGSVGDVEQTPYGLQTVHQHGTIDVIIDGNTLDFSQQQYQLQADAFHFESGNGVRWHKHAQGVTLEYAMSTLSIGVTDSSVTFQGTTYNESDPDTNVTVAVDGNDVDPSSYVLQDDDRIRIVANSS
->tr|A0A4R2BCF3|A0A4R2BCF3_9BACI Histidinol-phosphatase OS=Mesobacillus foraminis OX=279826 GN=EV146_107111 PE=3 SV=1
-MVKDGHVHTHFCPHGTNDPFESYIEKALSLGYTEISFTEHAPLPLSFTDPTPLRDSAMDHSDLEEYFAEVNALKKKYGDKIKINAGLEVDYIEGYEKETAKLLDKIGPKLDDSILSVHFLKDPFGYSCIDYSPDHFRYMISAYGSIEQIHVNYYRTLIHSILADLGPYKPKRIGHITLVNKFQLKFPAPRTFSEEITQVLKAMKEYGYELDYNGAGTSKPLCREPYPPAEVIDQAVSLGIPLVYGSDAHRAKELGQGLDLMSKKLENRQ
->tr|A0A5E4KIF3|A0A5E4KIF3_9ARCH Uncharacterized protein OS=uncultured archaeon OX=115547 GN=LFW28011_00478 PE=4 SV=1
-MADFEGLELNFTMANLPEYPPDFLPGISFGPLSRYFSGSDQKPPGGAEIEGNYLCNPFCSSCFLVNLHPANRVYAILFLHLKL
->tr|A0A210RZX5|A0A210RZX5_9BURK Peptide methionine sulfoxide reductase MsrA OS=Polynucleobacter hirudinilacicola OX=1743166 GN=msrA PE=3 SV=1
-MNETLDKNQTTLERATLGGGCFWCLEAVYQQVSGVKSVVSGYAGGARPNPTYEAICTGVTGHAEIVDILFDPQVISFRDLLEIFFVIHDPTTLNYQGNDHGTQYRSVIFTHSDEQSNIAHEVVKELDDSKIYSRAVVTQIDVAPTIFPAEDYHQNYFVQHPNQGYCMAVVAPKLAKFRAKFKALIAPHYS
->tr|A0A0M8WET4|A0A0M8WET4_9NOCA HTH hxlR-type domain-containing protein OS=Nocardia sp. NRRL S-836 OX=1519492 GN=ADL03_23475 PE=4 SV=1
-MHTAGFRNDIGVDQVECDTVSLPYRIGDKWTAHVLRALSPRRRRFTELRAGLPPVTAKVLSETLRTMERDGTVARESFDENPPRVEYELTGQGRKVLALLDLCCEWARENLVET
->tr|A0A519KUV8|A0A519KUV8_9CAUL Uncharacterized protein OS=Brevundimonas sp. OX=1871086 GN=EON87_17510 PE=4 SV=1
-MRALILCAAAATALSACASTGENTYANSTAELAAQCRERGGILVPTGRPSTGRPETDNACQINGGASRIP
->tr|A0A416ETJ7|A0A416ETJ7_9FIRM Threonylcarbamoyl-AMP synthase OS=Lachnotalea sp. AF33-28 OX=2292046 GN=DWZ56_01980 PE=3 SV=1
-MDTKVYNVEETGRCQEIFMEAGRVIRSGGLVAFPTETVYGLGGNALDARASEKIYAAKGRPSDNPLIVHIADLEELPDLVAEIPPMAETLMNQYWPGPLTLIFKKSLKVPPETTGGLDTVAVRMPDHEAAAMLIRASGVPIAAPSANTSGRPSPTRAKHVQEDLSGKVDMILDGGEVGIGLESTIIDVTGSDPVILRPGYVSLDMVKKLFEGVRMDKACTEPLKEGERPKAPGMKYRHYAPKAGLTIVEGGRAEVSSFINNHIQEESLAGNKVGVLCTEETAGCYPGGICKCMGRRADEETVAHNLFAALREFDEEEVSQIYSESFYGGQLGQAIMNRLMKAAGYHLIQV
->tr|Q7P5J6|Q7P5J6_FUSNV Uncharacterized protein OS=Fusobacterium nucleatum subsp. vincentii ATCC 49256 OX=209882 GN=FNV0999 PE=4 SV=1
-MVGNLTDVMEKFDNNNVYSSLGLNRFKFDKNIGFYNLDANLFNLGETKDLSFTGKMSLVSDKKAYGLLVYDKIDDISYGSTIDHDLYTNLSLTKDNNKFRLNARYDYLYDMDPGSTSSDLMSRNERIGANFLLKENGLSISYDKRRGDDYRNFNFLEEDINTSARKRNVLGIDFSYTPTTVAKYEFNNFENIKASLGNYKVGNYTFTPSVSYNFLDRKLDTAKDTYRATVLGSNRLAEFNRFENIVYNNSLERRADLNLSNDNETYRIGFGKTTSEIWSREGLFDGTYRKYENKSKFYEIQLGRQNLPLGNIGTFGIDGTFRQDEFDGSSDKTNLINLKLNNDLYLYKAENLKVTNKFKAEIQKYNFSGNKNNEEGRLITKSDYIKFDNSLIFDGKSTVTTYNIGYKSSKNPYGKKNKSAEQFTTGLGIKFDENTNLSLKYTDDKRFTSKINSGKNVNDLSMKQYSINFETKKYDLGFANTDIDFVGDDFSTITDFREDINEHRIRAGYKFDNSKISLSYAEGKDKLKVDDGRYLDRKNRMYSVAYNIYGDVEQDFIGAFKTYRYGNTRIADDIRNTDVYSFSYAYRDKRFEQEELMKYATLEYEKPKDQITNDEIEQIRAILDRKSSFYNQFELARIQDETFRIGNYKKTLSAYVNLEKNNKRYSQTGNLKDSLSKFSGGLTVSYNRLGIGYTFTQKASWKNSGGSYKWSKDTKEHELSVYAKIGKPSQGWKIKTYAMFYDNKNDSTSSRNRKRSLDSIGVEIGKEMGYYEWAVSYENRYKTSSKDYEWRVGVHFTLLTFPNNSLFGIGAKNRGGTASTKPDGYLLDRPSQLKNSY
->tr|A0A4Q3CBA2|A0A4Q3CBA2_9SPHI Alpha-amlyase (Fragment) OS=Sphingobacteriales bacterium OX=2044944 GN=EOP54_25765 PE=4 SV=1
-PAMMENSVIYEVNIRQNSPEGTFAAFSKDLPRLKELGVKVIWVMPIHPIGVKSRKEGLGSYYSIQDYKGVNKEFGTLEDFKAMVKAAHQNGIYVIMDWVANHTAWDHAWVTAHPEYYTKDKDGKMISPFDWTDVVELDFDNKDMRKAMIADMEYWLKEADVDGFRCDVAGEVPVDFWDAAAKDLNNVKPVFMLAEAEKPELMKNAFDMAYGWESHHIMNDIAQGKKTVKDWDTYMATKDSLWEKDDFTMYFTSNHDENSWNGTEYERMGDAAETFTALTFMVPGMPLIYNGQEYDFKKRLKFFVKDQLTKEKGKMYPVYEKLGALKNNNPALNGGKDAASYKRIATSADAAMLAFEREKGSDKVTFIANLTKVPQVFTVPVEGTFTNYMTGEKVTLTKGQKHNLAPWQYWILTK
->tr|A0A2G2HQJ2|A0A2G2HQJ2_9PROT Pyruvate, phosphate dikinase OS=Robiginitomaculum sp. OX=2030823 GN=COA60_09450 PE=3 SV=1
-MTKWIYGFGGGTADGSASMKNLLGGKGANLAEMCSLGLSVPSGFTLSTEVCTNYLENQKTWPDGLQNQLAKALQVLEQQSGKSFGDAANPLLVSVRSGGRASMPGMMDTVLNLGLNQKTVEGLAELSGDRRFAFDSYRRFIQMYSDVVLGIDHDLFEEILDEHKDVQGFATEADTELAADDWEQITKLYLALVADELGHEFPDDPVDQLWGAIGAVFDSWTNDRAKVYRDLHDIPQSWGTAVNVQAMVFGNMGQTSATGVAFTRNPSTGESLYYGEFLINAQGEDVVAGIRTPQALTERAKAEIGDTEPSMEAAMPKVFAELTEVFKQLELHYKDMQDIEFTVERDQLWVLQTRSGKRTAKAALKIAVDMVAEGLITEREAILRVEPASLDQLLHPMLADGHNCPIICTGLPASPGAATGKVVFSSEEAVIMASRGEDVILVRIETSPDDIHGMHAAKGIVTARGGMTSHAAVVARGMGRPCVAGAGELKIDYSKGSFMVSGQTVHKNDVITIDGAKGHIFSGTATMVQPELTGDFGVLMFWADKVRRMKVRTNAETPVDVKTACDFGAEGIGLCRTEHMFFEESRIAAVREMILAKDKAGRIAALDRILPMQRDDFVEIFQIMGERPCTIRLLDPPLHEFLPHSEADVAQVSQATGIAVGELMSRAESLAEANPMLGHRGCRLGISYPEIYQMQARAIFEAQGKVKQQTGIMADVEIMIPLAATARELEILQGKIRQIAEQVTGDQGFAPEYKYGAMIELPRAALCAAELSEFASFFSFGTNDLTQTTLGLSRDDATSFLGDYICQGVFEKDPFVSLEQSGVGQLLEIATERSRQAKPDIKLGVCGEHGGDPASIHFFEGLGLDYISCSPFRVPIAKLAAAQAVLLREK
->tr|A0A395H0X9|A0A395H0X9_9EURO Uncharacterized protein OS=Aspergillus ibericus CBS 121593 OX=1448316 GN=BO80DRAFT_465679 PE=4 SV=1
-MAGHRRFASTLTSAAMDIGFYGSVRRRVDGALWLPFRDSSFYPERPQIRSPSLIFPWTAIVALPVRNVQMSSWTRTHSCASRLRSRLSFLHVVTVGAVISLCYLFYTFAVPQLHRLQLRTDLSWYDLGLYGFGPSRSYVSFEYESPAVQISEWESGCDSRYTFFAPRGDSVAQPGPMILDSKGELVWMKYNWDVTQDFKVQRYQDTDYLTYWEGGETEGRGYGAWYMLDSTYTQRYVISPVGNHGGDLHEFNITPEGTALVTIYDPLPADLTSIGGPELGWIYDGVFQEIDIATGELIFEWRASEHYPISITYEKLGKSGRLRSFAFDFYHINSVDKDDNGNYIVSARHTHTVSCIDKNNGQVLWTLGGKLNEFRDLSDGKATNFAWQHDARWHANNTLTLFDNARHSSNDPENESRGMAIELNVAAREASLRAAYHHPQQMLSVSQGNVQMLDDSGRVLVEWGHSAAFSEFSADGQLLCNTHFGASAFFGFGRVVSYRAFKGTWVGRPQTVPDAEVLGDRVYVSWNGATEVVAWRLEVWETDDVHDNSFRVVAQFPKDSFETEIEIPNLELPLFRLAALDSDGNVLGITELLQREQGGSFEQVINPQYWIIVMAFVMSGVGLFVGLYTCCGWGQYFRRCRSRSSEYQLVAFSDSEAPV
->tr|A0A828ZLR4|A0A828ZLR4_9BACI Uncharacterized protein OS=Lysinibacillus fusiformis ZB2 OX=1231627 GN=C518_0034 PE=4 SV=1
-MVFRPPYPYPMYPGGMRMPMPMQTPPQMSPQSFFPPGGFPVQPRIPGGFPMANGIGSFGGQMPMPPVQEASKVGSFLQQANSLFNTAKTYTPYIQQAMPMVKNIPSLLKLYKGFQGLPSAGGGATEAAGSDSKAAGSRRSSRQSASFTPPEPLPSKPRIFQPPM
->tr|A0A2K5HSM9|A0A2K5HSM9_COLAP Histamine N-methyltransferase OS=Colobus angolensis palliatus OX=336983 PE=4 SV=1
-MASSMRSLFSDHGRYVESFRRFLSHSTEHQCMQEFMDKKLPGIIARIGDTKSEIKILSIGGGADFLIWGSSRVLKQNSCFIFCRTCQNDKSVMRIHDEHSSELPFGAARLKGTSSFPSFLVSFSLF
->tr|A0A834YI29|A0A834YI29_9MAGN Uncharacterized protein OS=Tetracentron sinense OX=13715 GN=HHK36_028814 PE=4 SV=1
-MGRGRVELKRIENKINRQVTFSKRRNGVLKKAYELSVLCDAEVALIIFSSRGKLFEFGSAGNAVVAVMTKEELWLNSPEQIPSRPGDMGFVLILDLLSFPPISLSSLILFLQTHRSTYNLH
->tr|A0A3S3PID2|A0A3S3PID2_9ACAR Cell cycle control protein 50A-like protein (Fragment) OS=Dinothrombium tinctorium OX=1965070 GN=B4U79_11510 PE=3 SV=1
-MPVNFVYEVNSERELQELKNKQTARDALRRQRLPAWEPILTPTAVLSSILLIGFALIVIGIMLLITIEQVNEKVIDYTNCVSSVNIRENCSTVIARNIYEPCWCIQRFSLDEDFGADAFFYYRLSHYHQNLRRYINSKDSKQLLGYDHRKKVSKKCEPFEKNFDPLQGQVLPIAPCGAIANSLFNDTFKLYFIENMSLIPVEIIETDISWPTDKKHLYINPPNMNFEGFTKPPYWRKYVFELDLNNSDNNGYQNEHFIVWMRTSAFPTFRKLWGRIDHKNRFSRSLPKGNYVLQINYNYPVISFGGAKSVIISNTSWLGGKNYFLGYAYIVCGTLFVILDIALFAIYYLYGY
->tr|A0A3G9HIV9|A0A3G9HIV9_9PROT Porphobilinogen deaminase OS=Hydrogenimonas sp. OX=2231112 GN=hemC PE=3 SV=1
-MEKLIIATRGSQLAMWQAEYVKSELRKRFPEMEIEFEVVTSTGDKILDKPLALIGGKGLFTKEIEDVMLAGKAHMAVHSLKDVPTVMPEGLKLAAITKRDDIRDCFLSHKYRNIDDLPEGAVVGTTSLRRQMQLRAIRPDLKIKNLRGNVNTRLRKLAEGEYDAIILAYVGMKRLGLLESVPYHDPIDDNVMIPPSGQASLGIEIVDDERVAEIAAVLNDEDSALAARIERDFVSELEGSCQVPIAVNAKISAERVVVRAMVGLPDGTEILKEIIDAPKSEARDLGVRLADIMIEAGAKELLERAEAMAFKDERCERL
->tr|A0A5E4QBA8|A0A5E4QBA8_9NEOP Uncharacterized protein (Fragment) OS=Leptidea sinapis OX=189913 GN=LSINAPIS_LOCUS7231 PE=3 SV=1
-MKYVSFSLIATLIFAGYVINTIWNLAEIFIPPECSRGERCFTSYLASNPVQHLVLYTSIKENPYRGGISDAAVNKVHTSLKFDYRKPAKIDLTLKIPRRTRNNGTLFMHAVLLDERRLYDDFIDIFRNEAIYTLPLVTYMDQKDETFNLLQGNNGQEIKPKKIVKPYSHIFKVAPLSILTDDLQLPVKKIPGELYPYVRVRNEKFLPIIQHNVLKSRISDLELLRSNTSEVNVTVEISPTSYGVLRLALHVRLALLQLQSLGFSEKDVDDAKGIFADTNLYLLSATVLIASCHLLFDFLAFKNDVSFWRS
->tr|A0A093L9J8|A0A093L9J8_EURHL Melanotransferrin (Fragment) OS=Eurypyga helias OX=54383 GN=N326_02722 PE=4 SV=1
-AALGLERVRWCTISQQELSKCNDMSKAFGRAGILPPLECTAWGSAANCTQMIKEDLADAVTLDGRLIYQAGKEHGLKPVVGEVYDQEIGTSYYAVAVVRKNSSITIDSLKGVRSCHTGINRTAGWDVPVGYLTDSGRLAAMGCDLPQGKTVSDYFNASCVPGAIGVNYPSSLCQLCRGNSAGKSKCERNSQEQYYDYSGAFRCLAEGAGDVAFVKHSTVPENTDGRSLSSWAQRLRSRDFQLLCRNGNTADVTEWRTCHLARVPARAVVVRPDTDGAAVFQLLNQGQQRFNGVGTKFQMFDSAAYGAQNLLFRDSTMELVAITAQDYQAWLGEEYLRAVQALSCNPNTLPESLNWCVVSTEEIWKCGEMAIAFRKKNLKPAIQCISAKTKEQCMEMIQKKESDAVVLGGDDIYTAGKTYGLVPAAGESYSADDNSNAYYAVALVKRNLSNAFTISDLKGKKSCHTGLGRNAGWNIPIGILIKRGIIKTRDCDIPQAVSEFFSASCVPSAKLDSYPSKLCQLCVGDDSGNHKCSASSQERYYSYSGAFRCLAEDSGDVAFVKHSTVFENTDGKNTDSWAQNLNSSDFQLLCPNGARAEVTQFAECHLAQVPAQAVMVHPDTNVFALYGLLDKAQVYFGNSSNGNGFKMFDSSTFQGKNLIFKDSTVEIVPVEEKRTYAEWLGREYLESLEGMQTPQCSGAGNKIRPYLLVTVVSLLWCQAQGLD
->tr|A0A4D6WVR2|A0A4D6WVR2_9FLOR Photosystem I reaction center subunit PsaK OS=Gayliella sp. OX=2575623 GN=psaK PE=3 SV=1
-MYINILLNISSNTVNWSPKIALIMIICNLLCITIGRYSIQVRGLGPSIPLIGSEGPGLPELLATTSLGHVIGAGTILGLRSQGII
->tr|A0A255GDV3|A0A255GDV3_9ACTN Uncharacterized protein OS=Propionibacteriaceae bacterium NML 030167 OX=2016500 GN=CGZ94_12075 PE=4 SV=1
-MARERTEKRDRPEKRDRDKGDRDRLNTPGRESSRFPRIRMDGDTFGEFAEAFARFMGTAGFLMWMTIIIILWIAWNTLAPESVRFDPFPFIFLTLVLSLQASYAAPLILLAQNRQEARDRISVEDDRRQAAQSRADMDFLAREIASVRMNVGELATRDYIRSELRKELRELLAEHDEPAAGPERGSVGG
->tr|A0A1X6Z5H1|A0A1X6Z5H1_9RHOB Uncharacterized protein OS=Roseivivax jejudonensis OX=1529041 GN=ROJ8625_01941 PE=4 SV=1
-MDAAFIVPVLALITLLAGTVYALWSKHVTEQAKADPAHPKSRLAADTPSR
->tr|A0A4T0PB80|A0A4T0PB80_9BASI P-loop containing nucleoside triphosphate hydrolase protein OS=Wallemia mellicola OX=1708541 GN=E3Q18_02634 PE=4 SV=1
-MDTVTNSIFEEIKSEISALPEDQRYLVGIGGFPGSGKSSFTKHLTDKFTDSSIKAVAISMDGWHYTRDDPTAAFARRGAPHTFDAEAYTEFVQSLKLEPRVALEAPTFSHSLKDPTPSGTQVDTSVKVVIIEGNYVLLNEERWMKAANNLDKKIWVDIDEETTRQRLIKRHVESGICKDSQEAYDRAENNDLDNGRYARQNLVPDTQIIKSIEDEKFAI
->tr|A0A4Q9TDA8|A0A4Q9TDA8_9GAMM Penicillin-binding protein 2 OS=Pseudoxanthomonas sp. NML171590 OX=2527958 GN=mrdA PE=4 SV=1
-MTMSRRRPLKNAHAEADQFRRRAALGFLGVFVCLAGLGAWYFKLQVLDHAEYATRSEANRIKLRPVVPARGSIYDRNGVLLAENIPAFRLDVVPDQAGDPDEWLDALGKVVALDPEEVKHFLAARKVSRGFRGITIKPKLSEEEIAALAVDRWRFPGVEVVPYLTRHYPYGPLLAHVIGYVGRVDEADLAQLGEGNSALTHVGKTGLERYYEQQLRGKVGYEKVETNVEGRALGVVGRVPAQAGTDLKLSIDIKLQQAMTEAFGQYEGAAVAMDPRTGQILGMVSLPSYDTNLFVNGISTRDFKALNENPSRPQFNRLVLGGVAPGSTIKPLMGLAGLDSGTRRPQDKILSTGMFYLPGVSRGWGDSHRGGHGWTDLRKSIAQSVNTYYYKLAVDMGITQVDAYMTKYGFGAPTGIDLAGEIGGIVPSPAYKMKSRKEAWYPGDTVNIAIGQGDWKVTPLQLVRAISGVADGQLRTPRLVMDTRNGFDQPWQPIAPGPTKPISDRPDNLQWVREGMMDTMRPGGSGYAIAVGAPYQMAGKTGTAQVVSRKGLAAVDPRSLPMHLRHRSLFEGFAPAQAPTIALAIAVEGGGYGASTAAPIARKIFDAWLLGKMPGDTPDAPDIVVPEDGTDTGAAPPAPSEIPGAPGPTPPPAPTAAPVPAEAPREPQAAP
->tr|A0A1H3A3S6|A0A1H3A3S6_THIRO Uncharacterized protein OS=Thiocapsa roseopersicina OX=1058 GN=SAMN05421783_11845 PE=4 SV=1
-MTNAQCLYGHRPTPGWPGFARACRPSWRDDLCPTWIDLVVPPCSFRVFRDHEVAARRVVGHDGNDIPCFQAYDYRRLDLRSDDDEEYYLAVSYSESVSAWRLRDGRWLVHRRVELLGDEDAATSALSIDERMPR
->tr|A0A1L7CG91|A0A1L7CG91_9CORY Threonine--tRNA ligase OS=Corynebacterium aquilae DSM 44791 OX=1431546 GN=thrS PE=3 SV=1
-MSDQPEREFAPFNVPAGTPVGAAMRELELPNKGPEAIVCVKDADGQLKDLSFVPDTTAEFTPVPANTEEGRSVIRHSCTHVLAQAVQAEFPGTKLGIGPAIENGFYYDFDAAEPFTPEDLKRIEKRMKKIIKQGQKFERRVYADQAEAREALANEPYKLELIEDKGNVDPNSDEATEVGSGELTGYYNLNPRTGDVEWYDLCRGPHVPTTKYIPAFALTRSSAAYWRGDQSNAGLQRIYGTAWESTEALEEYQHMLEEAEKRDHRRLGTELDLFSFPDEIGSGFPVFHPNGGIIRLEMEEHSRRRHIASGYSFVNTPHLTKGDLFSKSGHLDFYADGMFPPMQLDGEYDENGNCTKQPQDYYAKPMNCPMHNLIFASRGRSYRELPLRLFEFGTVYRYEKSGVIHGLTRARGFTQDDAHIYCTEDQLEAELTSVLDFIISLLRDYGLDDFYLELSTKDEGKFVGSDEIWEKSTAILQRVADTSGLDLVPDPGGAAFYGPKISVQARDAIGRTWQMSTVQLDFNLPERFNLEYTDSDGSKKRPIMIHRALFGSIERFFGVLLEHYAGAFPAWLAPQQVVGIPVAEAFSPHLEEITARLRDKGIRATVDTSDDRMQKKIRNHTTAKVPFMLLAGARDVEAEAVSFRFLDGTQVNGVPVDEAVELISAWITARRNEQPTEANLRG
->tr|A0A7X7K3W6|A0A7X7K3W6_9CHLR Uncharacterized protein OS=Anaerolineales bacterium OX=2073117 GN=GX601_14875 PE=4 SV=1
-MVALRDDFAGELNRHWNTSLVGQGTLTMGESRMRLGVTGASSRRYSNAQIDDYQDLMRRRFPWAPPLRLSVRARFSGSAQTLRGTAGFGLWNDPFMMTGARPPNLPRALWYFFGSPPSNMKLDLHAPGHGWKAATIDALRPISLALGMIALPAVALMNVRPFYRALWPPIQRALHVQEAPLETDMAEWHTYEIEWSASHSYFRVDGTAVLTGAPSPRGPLGFVLWMDNQSLEITPWGRVRWGLLDIPDGQWMDVDWVELA
->tr|A0A4R2CCK3|A0A4R2CCK3_9ACTN Polygalacturonase OS=Kribbella sp. VKM Ac-2500 OX=2512214 GN=EV642_10991 PE=3 SV=1
-MVQDKFSRKNFLRMTAGAALLPTAAALTAGQAAAAAAGTPDATAPLGPDGHGGPGWGHVGEILRETRPPRFHDRDFPITAYGAVGDGSTDATAAIRAAIEACHLAGGGRVVVPAGTFLTGAIHLRSNVNLHVSEGATLLFSTDPAQYLPVVLTRFEGMELMNYSPLIYARDCDNIAVTGTGTLDGQATWETWWSWVGPSGPDAQALTDLADRGVPVPERIFGAGHFLRAAFIETYHCRNVLIDGVTLLRSPFWEIHPVLSRNVTVQNVHIDSRGPNNDGVDPECSQYVVIRNCTFDVGDDCIAIKSGRGTDGLRVNVPSENILIEDCTMNIRYGAITIGSEMTGGVRNVFVRNCRIGSGYQYFGLYIKTNSVRGGYAENVYLKDIEISNLTKEVVSCNFYRGEGDTGPLTPRVRNVELRNITVGHARNAFSMTGYPRLPIQDFRLIDCTFTSIDAASTIQDVDLSFENFFVNGQPITDPAQLL
->tr|A0A0A7RLM7|A0A0A7RLM7_9LACO Flagellar motor switch protein FliY OS=Liquorilactobacillus oeni OX=303241 GN=fliY PE=3 SV=1
-MSDSLSQAEVDALMAGNAVSKDEGQDNDNGMDEKTRQDIIGEVGNISMSQAATTLSSILNRRVSITTPHVSRMKFEEVLSAVHTPKVATVVEFKEGLAGSNLLLLEVKDAVVIADLMMGGDGNPKSSEFSELQLSAVAEAMNQMIGSASTSMATMINRKVDILPPAVKLWENASNIEYNGIVNAEEIYRISFSLSVEGLIESEIMQIFTKDMVDDITDAMLSDKATVIEREKAVSQPEQKEETKSAPKTASVDTKMMSKEQTKHVEVSKPEFQQLEENKVAEGDNLDLLLDVPLNLSVVLGRSEKTIRDILSFNSGSVVELDRLTDEPLEILLNGKPIATGEVVVINENFGIRITNILSPSQRIHRLK
->tr|A0A3N0E5U7|A0A3N0E5U7_9ACTN Non-specific serine/threonine protein kinase OS=Nocardiopsaceae bacterium YIM 96095 OX=2487137 GN=EFW17_17180 PE=4 SV=1
-MTDQEHPQVPVHGDPADGDMPDAVLGARRDVVTFVESANQPDQLVRLWWVTVVLQIAEQHIPNLRMTNGHKHSVKYPRRSYAINSTSSARRYSTTSGRVGRPRLRPRPVTLRHTPRFRPPQPCGKIPVSLAVPNERVVATVRGTPSSGRHSAGPYELVRELGRGGFGSVHLGRDSAGRHAAVKLLHLNQAESARVRADFAREVDAARKVNPFCIAQVLDADLDADEPWIATEYIEGPTLLEAVRADGPRTGADLQRLAVSMATALTAIHRAGIVHRDLKPGNIMLASDGPRVIDFGIARGFEGTEFSVSQMVGTPNYMAPEQLEGNRLTPAVDVYAWGAVIVFAATGRNAFTAPSQAALIRRVLLGEPDLDGTPETLLPLVRRCLAKAPEQRPNAHALLEALLDGATPGTEPGADTGGTATPAPLPNVGPESDGAPPRGPAEPAEPAPPFVFADDSYHSPGDLASAMRRNWSAAVRVFANDQERALLRTWLLEDIDDRTVDRALLRRPPEDPEAVLTEFIAQVRPDLPPTYRGRDMRLSALRQTLRNHSGQPPAELHGLGSRVLRALARHHCVEEDHTCASGAPCKEYQRIHSEFVTRVERVRAATEQVDRTLRAESPQLADTVDVPALAASVTTTLLPGLLHPADETWPPREQRPRTHTEWYTALATAVGSDIPPELHEDRGVTLLYDATATRIAGIQDTEQLRVHTLERDLDRLMAGWRQATKTVFVRTFGGWCAVTLVSLPFFPWTGVFPSGVALVVGLVVVIGTLMAAGRPYAAQRHSLHTPPPDPSWREGRIATWLDGEITQAKQRAGRLPRILAHMTGGSTTG
->tr|F1A946|F1A946_9CREN Acetyl-CoA carboxylase alpha subunit (Fragment) OS=uncultured crenarchaeote OX=29281 GN=accA PE=4 SV=1
-AMTDFVVMVEKAATMFVTGPDVVKTVLGEEVSFDELGGAMTHGTKSGVAHFVAKNEYDCMDIIKNLLSYIPQNNTESPPRVKTSDDPNRLDHNLLNMVPEDSLKPCDMKPIILSVLDDNKFFEIHELFAQNVIVGFGRMNGRTVGIVASHP
->tr|A0A497UYM2|A0A497UYM2_9FLAO Uncharacterized protein DUF4230 OS=Flavobacterium lindanitolerans OX=428988 GN=CLV50_0313 PE=4 SV=1
-MRRILIIAGIVVAVILAFRFCEFKKDDRSTIEYDTNLIQERIVNVGKLIVTEGHFAEVLTYKDQEKYLMDLISFEKKALVIVNADVTVSYDLRQMKYDIDEKNKTITIKYIPKEEIKINPDIKFYDINQSRMNPFTGDDYNKINKSVKANLAKKIEKSSLKTNAQNRLISELSKILITTNSMGWTLRYDGQTVNEESIDKVLL
->tr|A0A1V2ZGA3|A0A1V2ZGA3_9MICO SGL domain-containing protein OS=Rathayibacter sp. VKM Ac-2630 OX=1938617 GN=B0T42_04245 PE=4 SV=1
-MRRRAIAVPVLLAGALAGCTQAGDPAEEEAPPSVATAERVLQVTEVHEATGMTLLEGPAFGPDGSLYVVDVTAPPGEGKVLRIDLDDESVEPVWTDDSSALTSAQFGADGRLYVTDFLGGAVRSMTADGEDVREIAAGAVEGVPMQPDDLDFGADGALYVTDAAGAQDPYWEASGRVVRVDPATGSASVLADELPSPNGIAFSPDHRELWVSMNTGNRIDRLTLTGDGTEVATAFPAIHASPGIGQLDSIAVDADGNLYVGLHSRPEILVYDTAGALLQTVTVAESGLSSATNIAIRPGTTEAFATVSGSDGGFVHSFEALAEGMPQSNGG
->tr|A0A1D8NL70|A0A1D8NL70_YARLL Catalase T OS=Yarrowia lipolytica OX=4952 GN=B0I71DRAFT_163235 PE=3 SV=1
-MSKELYANSKDDAVYSYSFGVPYPHHPYSSQRAGPTGPLLLQDTYLIDALAHFDRERIPERVVHANGGGAHGYFEVTDDISDITYAEPFQKIGYKCPTTVRFSTVGGERGSPDTARDPRGFAVKHKTDWGNWDMVGLNSPVFFIRDPVKFIHVNHSQKRDPQTNLTAGDDASNYWNYLVQNPESLHQVVYMFGDRGTPNGWRHMNCFSTHTYKMINKEGKLTYVQFHYKSDQGVKNFTGPEAAEMAGKSPDHDQKDLFFAIDNGDYPSWTVSLQTMTPEQAEEWEYSILDMTKTWPYDKFPLRKVGKLVLNKNAENFFEEIEQAAFSPSNLIHGIEASDDPVLQARLFSYPDTARHRLGPNFNQLPVNQARTFQKGSGCPFMAGNFQRDGNMAIHNQGNRPNYLSTIRPIQSVSVPNEDFKNTHDYCGVVTKEMEDESFKVQAEAAKKHNEKIWESSSYLYLSGFQESDAAQPRDLYERVYDDAAKQRMIDNVVDHASTIKQHGLKEQVAKYFGRISDDLGKKIAEGLGVPY
->tr|A0A4R2XLQ7|A0A4R2XLQ7_9HYPH 50S ribosomal protein L2 OS=Rhizobium sp. GV031 OX=2135727 GN=rplB PE=3 SV=1
-MALKTFNPTTPSQRQLVIVDRSSLYKGKPVKALTQGLTKSGGRNNLGRITARFIGGGHKRTYRLIDFKRRKFEVEGTVERIEYDPNRTAFIALISYADGEQAYIIAPQRLAAGDKVIASEKAVDVKPGNTMPLQYIPVGSIIHNVEMKPGKGGQIARSAGSYAQLVGRDAGLAILRLNSGEQRLVPGSCLASIGAVSNPDHANINDGKAGRTVWRGKRPHNRGVVMNPVDHPHGGGEGRTSGGRHPVTPWGKPTKGKRTRSNKSTDKMIMRSRHQRKK
->tr|A0A6F8T1T8|A0A6F8T1T8_9GAMM Superoxide dismutase [Cu-Zn] OS=Legionella sp. TUM19329 OX=2708020 GN=sodC PE=3 SV=1
-MNKLTTALISSLLSFNALHAAPMTTTLYTTDTNPTAIGTVEFEETPYGLLISPNLIKLPAGLHGFHIHQLPDCGDHGMSAGGHYDPTNTKSHKGPYGDGHLGDLPVLYVSSDGKANTPTLAPRLKLKDLTGLTLMVHAGGDNYSDTPSLGGGGAREACGVIK
->tr|A0A3D0ZXQ6|A0A3D0ZXQ6_9GAMM LLM class flavin-dependent oxidoreductase OS=Gammaproteobacteria bacterium OX=1913989 GN=DEQ32_11910 PE=4 SV=1
-MKFGIFYEHQLPKPWSEGLEEKLFQDALDQVELADKLGIDYAWEVEHHFLEEYSHSSAPEIFLAAASQRTKNIRLGHGIRQVIANYNHPARTAECIATLDLVSGGRVDFGTGESSAILELGGFDIPVESKRQQYLESVEQICNMLAMDPYPGFDGQYFSMPCRNIVPKPVQKPHPPLWVACSNRDTIKMAARLGIGALTFAFVDPLEAQHWVDEYYSIIKSDECVPIGHTVNANICMVTSFSLHHNRAVAIERGLEGFEFFGYALGFLYGFGIHKPGRTDIFREFQAARNAKLVESPVEVGESLTGERGGIGTPDDMREHLRKFERVGVDQVTFIQQAGMNKHEHICESLEIFAAEVMPEFKSRETEREARKAEELAPFIEAAMARKQYMKMPKDDDIPVFPALGRSVVEGDADLTKKAVG
->tr|A0A7Y7XFB0|A0A7Y7XFB0_9PSED Acyl-CoA dehydrogenase family protein OS=Pseudomonas gingeri OX=117681 GN=HX882_17635 PE=3 SV=1
-MNLHQYAETHEVTNQPPSLDGTNLYRIDLPLQEWARRFGAGWAESRIEAYGALAGGPLMEAGFLANQNKPVFVSHDRYGHRQDLVEFHPAYHELMRTAVEHGLPSLPWTDPQEGAHVARAAMTYLHSQAEAGTGCPLTMTFACVPALRLQPEIAGQWLPSILSTQYDPRNLGIAHKTGATIGMAMTEKQGGTDVRANTTRAYPVGAGGPGQPYELVGHKWFCSAPMCDAFLTLAQTDKGLTCFLLPRHRPDDSRNQFYIQRLKNKLGNCSNASSEVEFRGALAWMIGEEGRGVPTIIEMVAMTRFDCMVGSSALMRQALTQASHHCAHRLVGGRVLAEQPLMQNVLADLALESEAALALSLRMGRALDRLGDDHEAKFARLVTAVGKYWICKRAPAMINEAAECMGGAGYVEDSILPRLYREAPVNSTWEGSGNVQCLDVLRSLSKEPGVLEVLFSELGDGHGDKRLARHIEHLKLAFTDTHDIQYRARQLTEDIALALQAKLLLEAGNAEVSDGFIASRLEAGGRVYGTLPRGVNVEAIVARSTPQGG
->tr|A0A218LFE2|A0A218LFE2_AGRCR 50S ribosomal protein L33, chloroplastic OS=Agropyron cristatum OX=4593 GN=rpl33 PE=3 SV=1
-MAKGKDVRIRVILECISCVRKGANEESTGISRYSTQKNRHNTPGQLEFKKFCRYCRKHTTHHEIKK
->tr|A0A7W2KV63|A0A7W2KV63_9PSED Cytochrome c-type biogenesis protein CcmE OS=Pseudomonas asiatica OX=2219225 GN=ccmE PE=3 SV=1
-MNPQRKKRLLLIVGLLVGVGVAVGFALSALQQNINLFYTPTQIANGEAPLDTRIRAGGMVEKGSVQRSSDSLDVRFVVTDFNKSVPITYRGILPDLFREGQGIVALGKLNADGVVVADEVLAKHDEKYMPPEVTKALKESGQAASGGEARP
->tr|A0A495JIB9|A0A495JIB9_9ACTN UDP-N-acetylglucosamine 1-carboxyvinyltransferase OS=Micromonospora pisi OX=589240 GN=murA PE=3 SV=1
-MPADLSAGVTAGVAADSTMADVDVIRVSGGARLAGEVHVVGAKNSALKLMAVALLAPGRSVITNVPRITDIAIMGEVLRRLGCEVSFGEDNGTSTGTIDGIPVVGVGDGVPAEVPPVDGAGPVRDVATTPSGEAQAAVDLGAAPGRARTVTIDVPAEPGTDADYDLVRRLRASICVLGPLLARRGYVRVAHPGGDAIGSRGLDMHVSGLARMGAEISGSHGFVIASAPNGLHGATIWLDFPSVGATENLVMAAVLAKGTTEIDNAAREPEIVDICAMLSAMGARIEGAGTSTIRIEGVSELRPVRHRTVGDRIVAGTWAFAAAMTQGDVTVTGASPGFLEIALDKVISAGGLVETRTDAFRVRMDRRPRAVDVVTLPFPGFATDLLPMAIGMASVSEGASLITENIFDGRFMFVNEMARLGADIKTDGHHAVVRGRERLSSAPVRATDIRAGAGLVIAGLCADGVTEISHVHHVDRGYPDFVADLRALGVEVERTTAPAEQAFTL
->tr|A0A1G3BE39|A0A1G3BE39_9BACT Uncharacterized protein (Fragment) OS=Planctomycetes bacterium RIFCSPHIGHO2_12_FULL_52_36 OX=1801980 GN=A3E19_05430 PE=4 SV=1
-MGICLSRTIPVRDLFTGLFSGRGAVAIAGFVNKVGSKWYGTARLRRITAYCLLALFLCGLYSAEGVLGAQSVENPYPLFKHDAQHTGRSTFLGAQKANVKWSYPTEDHIISSPTVGGDGTVYVGGMDGNLYAIRPDGHTKWFYPAQSAIFSSPAIAQDGTVYFGCRDKVLFAVGPDMKEKWKFRMGGEILSSPTVGPDGTVYVGNWDGKLYAINQEGALRWTYQTGDSIVASSPAIAHDGTVYVGSRDRQLHAIDPASGKKRWGFQAGDKVDTTPCVGPDGTVYFGANDGILYALSPQGDPKWKFETGSWIYSSPSLGADGTVYFGAKDGKVYAVSPQGQKKWAFQTGDSVSSSPTLGSDGTVYVGSWDGKFYALGPDGQLKWSYDAGASIASSPAIDAEGTVYVGCDSG
->tr|A0A552XCD5|A0A552XCD5_9LACT Carbohydrate ABC transporter permease OS=Lactococcus lactis OX=1358 GN=FNJ55_12300 PE=3 SV=1
-MKDSIGYKIFKVINAIILILIVIATVYPFWNVVVQSFSSENAITAGNVVLTPVGFNLETYKYVMSDPIFWINYKNTIIYTVVGTAISLFLTTTLAYVTSKKYLPGRKFFIGLSVFTMFFAGGLIPNYLLIKSLGWMNTMWAVTVPGALSIFNMLIMKSFFESMPDALEEAAIIDGATPFQILMRIILPLSKPILATMVLFYAVGAWNAWFGAFLYMDNKNLFPVSVYLRNLVKGATGAEAQSADEQSQVSSNIKAVTMVLTVLPVLIVYPFCQKYFVNGIMIGSVKG
->tr|X6GFZ8|X6GFZ8_9HYPH Oxidoreductase OS=Mesorhizobium sp. L48C026A00 OX=1287182 GN=X737_09625 PE=4 SV=1
-MILQGRIAIVTGAGSGIGQAGSEAMAREGATVIVTDRDLDAARGTVDSIAAAGGRGEAIRVDVTDDAAVVGVIQDVADRHGRIDILHNHAGVQVAGSVEEIDGAGFDHSWAVNVHAQFVACQAVLPVMKRQRGGVILNTSSNSGVFLDRAMTAYITSKAASITMTRQIALDVARYGIRINSLCPGWVDTPFNDPYTDQLGGRKALEHAIANIVPMGRFATTDEIAEVILFMVSDKSSYMTGHALVADGGESLAGGTNSGQSITR
->tr|A0A368JR03|A0A368JR03_9BACT Serine hydroxymethyltransferase OS=Larkinella punicea OX=2315727 GN=glyA PE=3 SV=1
-MSTLVTPITRDTQVFELIAKEQHRQESGIELIASENFVSKQVMEAAGTVLTNKYAEGLPGKRYYGGCEVVDEIEQLAIDRVKELFGASWANVQPHSGAQANTAVFVACLKPGDTILGFDLSHGGHLTHGSAVNISGKYFRPTFYGVEQETGVINYDKVEETAQRERPKLLICGASAYSRDWDYVRLRAIADSVGALLLADISHPAGLIAKGLLNDPMDHCHIVTTTTHKTLRGPRGGMIMLRNDFENPFGIKTPKGDLRMMSSLLDSGVFPGTQGGPLEHIIAAKAIAFGEALSDEFGDYANQIQRNAQAMAAAFVSRGYKIISGGTDNHLMLIDLRSKGLSGKLAENTLIKADITINKNMVPFDDKSPMVTSGMRVGTAAVTTRGMKESDMEQIVVYIDDVLMNHDNDAKIQVVKEEINSWMKAFPLYN
->tr|A0A1M3KRH6|A0A1M3KRH6_9HYPH Uncharacterized protein OS=Devosia sp. 66-22 OX=1895753 GN=BGO81_01360 PE=4 SV=1
-MVEVKQLLSFPLPRNPAIVSPGLREILMSGSSLSGLPSLYDGKDMFRSAGNRMLWPKPLPAPLYGGATKGRIFSYVAGVIFVPNTVKGVVKNIKKDFWDDSIGKVIKAQMLGIDFQAMTAPPWAGEPPEDISDAVEAVFDAIESGTGKVDENLLYATYWSYRWFSMQKRGAVFLPLTDLVEVSVQQTKGGFLEHFKYEVGEHIGLTFETASGQRSTYYATMSYPDEDERLLRFVPPADRKKEYQSRKLSTEEATALIFADQRIRADIRAVMRTLLDEHLGPGVLPAAYAELSKTRTQDWSRGLDVYYEALRSTDYNVWHAHGDVLARMGSTCVAFRALPFARHGFTNPIDSIERGEPMTWVSIT
->tr|A0A271J2M4|A0A271J2M4_9BACT Uncharacterized protein OS=Rubrivirga marina OX=1196024 GN=BSZ37_13095 PE=4 SV=1
-MGALADRVIVAAERQTGCEMPYLRTLADASGGAFARWMLAMPAAQFRQRAPRDAWHLARLGATVAQDCGTCVQIVVTVAQRDGMSVTTLRQALDDPGALYDDARAAYAFGFSISSQADDVADRVAEVEALFGHEAHVELAMAVATCQLFPVLKRGLGQSLACSLVTIEME
->tr|A0A368CC63|A0A368CC63_9GAMM Phosphoribosylformylglycinamidine cyclo-ligase OS=Candidatus Thioglobus sp. OX=2026721 GN=purM PE=3 SV=1
-MGLTYKDSGVDIDAGNALVTRIKQAVKSTHRDEVLSDLGGFGGLFELASHKYKQPVLVSGTDGVGTKLKLAQQMNEHSSIGIDLVAMCVNDVIVQGAEPLFFLDYFATGKLDVDVSEDVITGIAHGCRLAGAALIGGETAEMPGMYNDGEYDLAGFCVAVAEKSDIITGQGIQQDDLIIGLHSSGIHANGFSLVNKLLAENNSTLTQDFNGTSLGATLLTPTTIYAKPVLQMLSAFPIKGLCHVTGGGITENLPRILPANIRADINTHAWQRLPIFDWIQTQGNVAEQEMLRVFNCGIGMIIVVTAEHQTAVEQIAKTHNIASNVIGKMSTTDATSHVNYL
->tr|A0A1T1IFK7|A0A1T1IFK7_9PSED Gamma-glutamyltransferase OS=Pseudomonas sp. MF4836 OX=1960827 GN=MF4836_00365 PE=4 SV=1
-MLKFSAHEYPYPSQRQSVFARRGMVAASQPLAAEAGIEIMRQGGNAIDAAIATAAALTVVEPTGCGLGGDAFALVWTQGQLHGLNANGHAPAALSIEAVQAAGHQQMPLYGWEPVTVPGCPSAWAELSRRFGKLPFADLLQPAISLARDGFPLSPVVAHQWQIALDEFSPHRSALLEPWFDTFLIDGRAPRAGELFRNPAQARTLEELATSACESLYRGPLAQRMDAHSRATGGYLRATDLADYRAQWVEPIHINYRGVDVWEIPPSGQGLVALMALKILEGFDFDHRDSQQTWHRQLEAMKLAYSDGLHYITDPQHMRVAVADLLSDAYSARRREQIGEQAQPPKPGDPHASGTVYLATADAEGNMVSFIQSNYHGFGSGVVLPDSGIALQNRGQEFSLDPSHANCLAPGKKTFHTIIPGFLSQGGEALGPFGVMGGYMQPQGHVQMVMNLVDFGLNPQAALDAPRWQWLGEMKVGIEQGASRDLANALARRGHQVEIASDLTDYGRGQIILRDPDSGVLCGGTEPRADSHIAVW
->tr|A0A3M3ZGU4|A0A3M3ZGU4_9PSED Uncharacterized protein OS=Pseudomonas syringae pv. tagetis OX=129140 GN=ALQ32_04322 PE=4 SV=1
-MFSLKKIALVTAAAAMLGSGPVLAQPDLPAQLDEARQEGSIWTAFALNKHLSPFKIDVDVEQGTAILKGKVENEVDRELAERIALDTKGIEKVDNQLEIDPAVASDPGTRTNMAQRFEDATLVATVKSKLLWSSVTEALSIDVDSKDGVITLKGRAQSPEAKELAGSLASNTDGVVSVNNLISLSAADSIAAKTQPQSVIPTEEMSDAWITSKVKASLIYSRTLDGLNIKVDTNAGVVSLNGVVANFAEKELAVEIARNIRGVKGVNGDALKVMARSAG
->tr|A0A4R8QWY5|A0A4R8QWY5_COLTR Short-chain dehydrogenase chyC OS=Colletotrichum trifolii OX=5466 GN=chyC-1 PE=4 SV=1
-MARIFITGSSDGLGAIAAQKLVENGHQVTLHARNAQRAEDASKAVPGAEGVLVGDLSKLADVKKLAQEANSLGTFDAVIHNAGLFRGPFRKTDFGLPIMPSLTAVNVGAPYVLTALLNRPKRIVYISSGLHRGGDATFNDPTWVERGEARWNEDQAYSDSKLHVSTLASAVARLWPDVKSNSVDPGWVPTKMGGASASGSAEDGVATYVMLAEGADGGHVSGKYFKPGKQEDTPQPFTQDEKRQDQLLSLWGELTGVKFPAA
->tr|L0HHT0|L0HHT0_METFS 2-oxoacid:ferredoxin oxidoreductase, alpha subunit OS=Methanoregula formicica (strain DSM 22288 / NBRC 105244 / SMSP) OX=593750 GN=Metfor_2322 PE=4 SV=1
-MTRTEFWQGNTACAEGALAAGCNFFGGYPITPSTEVAELMAAKLPKKGGVFIQMEDEIASMASIIGASWTGARAMTATSGPGFSLMMENIGFAAMTETPCVVVNVQRGGPSTGQPTMSAQGDMMQVRFGSHGDYAVIALSPATVQEMFELTAKAFNLADKYRTPVFLMADETVGHMREKILVPDSVEKIGRKPFVPGTPPFKVTDPDLIPGFPTFGTGQHVHVTGLTHDERGYPAATNPPLHAALVKRLVDKIENARDEMADYDIVNPDAEQVFVAYGGPVRTVMQVMHDKKDTNIGFLRIRTVWPFPEKALAKFKNAQRFLVPEMNLGQIAREIQRHVKVPVVPIPKLGGELHTPAELVKVLEGKA
->tr|A0A0G0BS17|A0A0G0BS17_9BACT Sortase OS=Candidatus Roizmanbacteria bacterium GW2011_GWA2_35_19 OX=1618478 GN=UR68_C0020G0028 PE=4 SV=1
-MIVRTFYNPLVEETKYFVNKAANKQYIVADNFEANKIQPTIQENQSASKGILAKAFNIKPIEILSPEDPDFSIIIPKIGANSKVVPNVDTSDEKIYLDVLNRGVAQAAGTAYPGEGGHIFLFAHSTDYFWNVTTYNAIFYLLYKLEKNDEVDLFYKGQRYVYKVIGSEVVDPSQVQYLTRKTNREFLTLQTCWPLGTTLKRLLIFAVRVSE
->tr|A0A2S7ULD4|A0A2S7ULD4_9VIBR Probable membrane transporter protein OS=Vibrio jasicida OX=766224 GN=BTO01_24490 PE=3 SV=1
-MEMIEPTMLLVLALVAFVAGFIDAVAGGGGMLTVPALLSLGLPPHIALGTNKLAASFASSTAAYTYYKKRLFKPQCWGRAFVATLVGATLGTLFVDAISTEWLEKALPLIILAAAMYTVFHKPPQSTHQSPTPEPCPMLNKKQYMQGLSIGFYDGLAGPGTGAFWTVSSMALYRLNILLASGLAKAMNFTSNFTSLVTFAVLGHINWVLGLTMGVCLMAGAFVGAHSAIHFGAKFIRPVFVTVVSVLAIKLAYDAWFVGLT
->tr|A0A5E7K8T9|A0A5E7K8T9_PSEFL Uncharacterized protein OS=Pseudomonas fluorescens OX=294 GN=PS874_02483 PE=4 SV=1
-MRQPDIEIYLKDADVDYKAIAAWLGAALGPCTDWVQKGQTYKCKAGNVPVTWLPKAVGKWNSLFLESDQTPWEDDIACARAAFVALNVEVRCAPGTWVEEEGEETADRWMRISADGEEEITWKTA
->tr|A0A0H4KSG7|A0A0H4KSG7_9RHOB Transcriptional regulator OS=Marinovum algicola DG 898 OX=988812 GN=MALG_01290 PE=3 SV=1
-MSGAARELGIAQPALSKQMSQLEHELDAQLFQRHSRGVTLTRAGEKLRQEAAELIRRMEAIRQAIHTEAEDVTGKVVVAVISSLAPTLATELYPRLEQEYPGISLHIVDFPSERAGQALLNEEADLAVMPNAATEFPQLRSRPLFEESFHFLTKATPRAPARTIRLSEAAEHPLVLPFRSHDLRRRIEEAAGSIGVTLNVKYQTGSINVIDAMVERGMVASIVPMTHWLDRIASGQVSARLVTEPGVSRVHSLCHRPVRDLAPAAKVVHDVIMTEVQSLVAAGKLSGKPVRA
->tr|A0A7W0EWG2|A0A7W0EWG2_9DELT Uracil-DNA glycosylase OS=Desulfobacteraceae bacterium OX=2049433 GN=FP816_06960 PE=4 SV=1
-METCIHCKYYFITWDSKRPHGCKAMGFKSREVPCVVVRKSSQGLDCLQFKRKDDKSK
->tr|A0A174QDC4|A0A174QDC4_BACT4 RteC protein OS=Bacteroides thetaiotaomicron OX=818 GN=ERS852557_01330 PE=4 SV=1
-MKELLENILSEIDVEIDEIDLYGYDIVENSLSMVHRLQAVLNDLKTKLQTYSFPAKEDEITFFKTQKPEILGRLLFFYKIYRIETQCPNGSDDVIRSYINRELDNLTYFFNRNLDFYQYYRSHSTLYDEYYFVRGKSDLRLCTDSAQFDKDPNFSTGYDYKVAKIIANEMLRIYLNKRLVKLETNTQVEDNLQKCLKYPFRFTGKKVFLIELGYSLVSSGDINNGNVEIKEMMNFLGTVFQVELGDYYAAYIAMKERKKDRTAYLSRLQDSLVKRMDEDDSK
->tr|A0A6B0Z2B0|A0A6B0Z2B0_9CHLR LLM class flavin-dependent oxidoreductase OS=Caldilineaceae bacterium SB0664_bin_27 OX=2605260 GN=F4Y42_21435 PE=4 SV=1
-MKFGAQVNCYLTTWDNIRAVIEAMEAGRWDSLWFADHYMPSSPKREEELLPAYEGYTLIAAAASITERMRLGNLVLGNTYRNPALVAKMAGTVDQISHGRFTLSIGAAWFQREHEAYGFDFPPMKERSDRLEEACALLRALFTADGPVDFEGRYYRLDQAPLSPGGYNNRQIPIMVGGTGERRTLRTLARYGDIMNLDGWAGGPMTQEYYFHKVGVLERHCENVGRDPSEIKRTILMPVKVTDDPAEAEAFIASRSLGEGTAAGPKDYVIERIGQFMDVGVDEIMFAGLLTRDVEQYHYFEEEILSAFD
->tr|A0A5K1GDA5|A0A5K1GDA5_9MAGN Uncharacterized protein (Fragment) OS=Nymphaea colorata OX=210225 GN=NYM_LOCUS28356 PE=4 SV=1
-IVWAGRGADRKGETERGGVQTKKGKTAVGVREEREQVG
->tr|A0A3A8NX55|A0A3A8NX55_9DELT Uncharacterized protein OS=Corallococcus llansteffanensis OX=2316731 GN=D7V93_32740 PE=4 SV=1
-MRRSSLQRRLQRGQAMAEYGVITAAFFGFTVLSWPFLIQLLRALNTYFQSIYYIIQSPIP
->tr|Q8X4F5|Q8X4F5_ECO57 Uncharacterized protein OS=Escherichia coli O157:H7 OX=83334 GN=Z5883 PE=4 SV=1
-MQPDKLGAKKWMS
->tr|A0A4W6DJV8|A0A4W6DJV8_LATCA Uncharacterized protein OS=Lates calcarifer OX=8187 PE=4 SV=1
-IAAHEGSANVVELLLKHGSDPLISDHQGQTPLSLASRQGHVKVLSVLLEWAKSQKPEIAAQMMEHVDSEGWTALRSAAWGGHSEAVRLLLDAGADVDGCDGEGRTALRAAAWGGHEEIVLTLLNYGAEVNKADSKGRTPLIAAAYMGHHEAVEILLDRNAEVDLADGDGRSALSVAALCVPTAAGVKGYGEVASLLLERGADPGHRDHDGMTPLLLAAYEGHDEVVELLLEAGADVDETAGPDGNVPAAAAVTPLLAAAAMGHMKTVSRLLFWGAAVDAIDCEGRTALCLAAARGSTEVVRALLDRGLDENHKDDLGWTPLHAAACEGHRAVCAALTERGSMARVGEMDIEGRTPLILAAQEGHWSTVRLLLDRRSPIDHRAYDGHSALSATLLERPC
->tr|A0A2V8IIA6|A0A2V8IIA6_9BACT OmpA-like domain-containing protein OS=Acidobacteria bacterium OX=1978231 GN=DMF84_27170 PE=4 SV=1
-MNAVSEFIVALAVAATACIGATHSVSDADVRPQDAIDLILTAFQNYPLVALSDGAGHGQLETRDFFIGLIRDRRFPQTVRNIVIEFGNARYQSVMDRYVSGEAVTREELRHAWEDTTQVTGVWSLPMYEHMLAEVRAVNRPLPPALRIRVLLGDPPIDWSTVTSPADEDMNDWRDAHFAHVIEREIMNRTANALLFFGGAHLGRKVIFPNSLIHLLDARFPGRTFVLAALDAGRTDSRITKRLQGWTVPAGVSVRGTWLGKMDVQDIGFGFSRGVVEDDVDVVLLLSSAPPRQDEPPALTSSYGRELARRRALHQATLPFRGAKIRFEESRAAFATDADEPLQAVVSELFRDRGVRLLVKAFADPTESNAVALSTLRAELLVDWLAARGVERHRLVPKGCGALRPLTFGKTAADRAMNRRAELVRLTPTAGCEPTTATSPPHSGPPRRSSD
->tr|A0A140H1J1|A0A140H1J1_9VIRU Nonstructural protein (Fragment) OS=Mamastrovirus 1 OX=1239565 PE=4 SV=1
-TAKQLRDSGLPARLTEEQLHRIWRGGPKKCDG
->tr|A0A0C3DQN5|A0A0C3DQN5_9AGAM Uncharacterized protein (Fragment) OS=Scleroderma citrinum Foug A OX=1036808 GN=SCLCIDRAFT_63544 PE=4 SV=1
-AARKTTHKNVLYEVDSEDTVAWLRSPEGQRLFASKFGTEISLAYRPFSVLIEYVPIALELENPNVHRDIERRNNLPTRSIRSARWIKP
->tr|A0A534C027|A0A534C027_9GAMM Homoserine kinase OS=Gammaproteobacteria bacterium OX=1913989 GN=thrB PE=3 SV=1
-MSAAPPRTRASAFAPASVGNVAIGFDILGFAVEALGDRVTVTSTAAPGVTISAVRGIADELPQRAEDNTAGRALLAMQEALQPKFGFTLEIDKGIPLGSGLGGSAASAVAAVVAANALLAEPCGQLELLRFAMAGEAVASGGRHVDNIAASLYGGLVLTVGIDHPRVKRIPVPASVRAVIVHPHMYLATANARAILRRSVELSDFVWQTAHLAGFISGCYTDDLDMIRASLEDVVIEPQRQALIPGFADVRRGAMAAGALGCSISGAGPSMFAWALEATAPKVLAAMREAFARHSLATDEWVVELRSNGARVIG
->tr|A0A1N6JS24|A0A1N6JS24_9RHOB Ribosomal RNA small subunit methyltransferase E OS=Rhodovulum sp. ES.010 OX=1882821 GN=SAMN05444722_2370 PE=3 SV=1
-MTPMSDSRSAKIRLYVEQPLGEGQTVPLSRDQAHYLFSVMRLAAGDRVLVFDGRSGEWLARVAEAGKKGGTLVCEAQTRPLQPPPDLWLFFAPIKKARTDFIVEKAAEMGAARICPVQTDFTNAERIRRDRLQAHAVEAAEQCGGTFVPEVCEMRKLSEVLEGWPHGRRLMFCDEMLAGAGRALGDAAPGPWAILIGPEGGFSEAERDRLRALPFAHPVSLGPRVLRADTAAVAALTVWQQALGDWA
->tr|A0A6G5A2B5|A0A6G5A2B5_RHIMP Putative secreted protein OS=Rhipicephalus microplus OX=6941 PE=4 SV=1
-MNFEKFAILLMFRHLSVCVALHIKIYTLDHFKGCRNDIYFCKFNTNLCFTREYIIYIELPPRLSTADRKRTSLHRGFLGSLLNAPKPAC
->tr|Q3ZH33|Q3ZH33_9NEOB Rhodopsin (Fragment) OS=Exerodonta chimalapa OX=318317 PE=4 SV=1
-NFYVPMSNKTGVVRSPFEYPQYYLAEPWKYSVLAAYMFLLILLGFPINFMTLYVTLQHKKLRTPLNYILLNLAFSNHFMVLCGFTVTMYSSMHGYFVFGQTGCYI
->tr|A0A5F2E027|A0A5F2E027_9LEPT DUF962 domain-containing protein OS=Leptospira licerasiae OX=447106 GN=EHR05_01230 PE=4 SV=1
-MTENKKYETLQEFWPFYLREHSNKMNRVFHFIGTTCALVFIVSAIFYLNAWYLLGALFSGYLFAWIGHFFLEKNRPATFIYPFKSFVSDWRMYFYTITGQLGKELEKAGVK
->tr|A0A1H1IN95|A0A1H1IN95_9EURY DNA-binding protein SAMN04489842_3657 OS=Natronobacterium texcoconense OX=1095778 GN=SAMN04489842_3657 PE=3 SV=1
-MSERPDEEKLEELRQKKMEQLQERADGQDAEAQEAAQQQAEAQKKAVLRQHLTDDARKRLNTVKMSKPQFGEQVERQVISLARSGRIQGKIDDDKMKQLLKELKPDSKSFDIQRR
->tr|A0A7M3A1Y5|A0A7M3A1Y5_PSEAI Cold shock-like protein CspD OS=Pseudomonas aeruginosa OX=287 GN=cspD PE=4 SV=1
-MLSGKVKWFNNAKGYGFILAEGRDEDLFAHYSAIQMDGYKTLKAGQPVNFEIIQGPKGLHAINISPATATTAAPSAPAPQEEPQATPVEA
->tr|A0A2Z6N5H4|A0A2Z6N5H4_TRISU Uncharacterized protein OS=Trifolium subterraneum OX=3900 GN=TSUD_214070 PE=4 SV=1
-MKKLVIQVKRMNLTGFYITLFSNTYSHINRVLFYRERILSRESPSTVVHKIPESFQSATDYKNSFIPLLFEETRADLFSSLYGVSQAPFCEIANVSESRRLTTPFPEVQNQFIQFHHVLWLKSETTGNYKPVSGDLIALTHIRPKGLSELNTLESPYRIAYVKEARKEWKELPDRISVLTSKCMKMDIENDLGNNKELSSKCMKMEIRYDLWNNKELKLYAVHLMNMTTNVRIWDALNTISRVKIMKTMLGPSQIVAIRLHRLVMDSLEHDMYGLGDIVLFGHNKRMKLGSHTGLDNVFLDNRVEKLMQCFNPNTGWKTNLQYMIELLESMKESANNTESMKAFKEEFGKQREKLTFLMQILYTHISTSLISPEMVKEMLQALDLLRRLGISLSQAKFKIPANFQLLQISVILDEVCLKGL
->tr|A0A832LQC9|A0A832LQC9_9BACT S1 RNA-binding domain-containing protein OS=Phycisphaerae bacterium OX=2026778 GN=ENS20_04560 PE=4 SV=1
-MIPTSYSQEAWPMSESSNDPLKEKFRPEEDPQVKKEVDAALAGVDVEQLLGGDQAAAARAVADGSSRERRGKVVGIGADDVIIDLGEKAQGIAPLSQFDQVRIGEEMDFILDRFDEAEGLWILTRKGAVSQNVTWETLEPGQIVECEATAMNKGGLEVKVKTLRGFLPSGQVDVVYLKDISIFLGQRFKVQVMQVDREKKNLIVSRKKIVEREREELRAKLLAELAEGQVRRGVIRSVTDYGAFVDLGGADGLIHVSEMSHRRIRHPSEVVKIDDIVEVKVLKIDPETRKISLSLKAVGADPWADAAARYAPGTEVTARVAKIESFGAFLSVEDGIDGLLPVSEISWQRIRHPADVLKEGETIKVVSIAVEPQQRKLTFSLRQAVPDPWGVVADKYPRGTVTTGKVTKVLDFGAFVELENGVEGLVHISELAARHVKNPAEAVQAGQQVKVRVLEVDREKRRISLSIRRSEEPKPPEPPSPEELKRREEEAKRLARKKEQRSKLRGGLDF
->tr|A0A1J0GQZ4|A0A1J0GQZ4_9CAUD Uncharacterized protein OS=Mycobacterium phage Albee OX=1913041 GN=SEA_ALBEE_18 PE=4 SV=1
-MSASDRQPPGPYPEGFTEAVRPEDVDVSKCDHEFGVCFCVHDWRIHWGNLDRSGL
->tr|A0A3B9GZ83|A0A3B9GZ83_9PROT Aminodeoxychorismate/anthranilate synthase component II OS=Hyphomonas adhaerens OX=81029 GN=DCG58_11365 PE=4 SV=1
-MILVLNNRDSFVFNLARCLTLAGADVEVEDSGRITINDIIRRRPEAIVISPGPSRPEQAGVSIAAVQTFGADLPILGVCLGHQVIAAAYGGSVRRSLTPSHGRTANIMHQGRHLFRGLPSPLPVGLYHSLTVDLEPNETGLQVDATAPDGEIMALSHVEHPVFGVQFHPESILTEQGQGLLGNFLRQYRSVPCL
->tr|A0A349TMC4|A0A349TMC4_9GAMM UvrABC system protein B OS=Gammaproteobacteria bacterium OX=1913989 GN=uvrB PE=3 SV=1
-MSKPFQLESSFKPAGDQPAAIASLVEGLEDGLHAQTLLGVTGSGKTFTIANVIEQVQRPTLVMAPNKTLAAQLYGEFKEFFPHNAVEYFVSYYDYYQPEAYVPASDVYIEKDASINDHIEQMRLSATKALLERQDVIVVATVSAIYGLGDPNSYLQMVVHLDRGDRMDQRKLLRRLTDLQYTRNDMELRRATYRVRGDVIDIYPAESERHAIRIELFDDEVEKLSYFDPLTGALIKEVPRLTVFPKSHYVTPREKLLATLDDIKIELHERLKQLTSNNRLVEAQRLEQRTKFDLEMIQELGYCNGIENYSRYLSGRESGEPPPTLYDYLPDDALVVSDESHVSIPQLGAMYKGDRSRKETLVEYGFRLPSALDNRPLRFEEWESLTPQIIFVSATPGPYEEEHEGQQVRQVVRPTGLIDPELEVRPASTQVDDLLSEVNRVVALKERVLVTVLTKRMAEDLTDYLAEHDVRVRYLHSDIDTVERSEILRDLRLGNFDVLVGINLLREGLDIPEVSLVAILDADKEGFLRSERSLIQTMGRAARNLNGKAILYADTVTGSMQRAMDESNRRRETQLAYNEAHNITPIGVQKRVLDIMEGAYSAPGSRTRQRTRSVAEPQGDYGTLNFNDPYEIRKEITKLEAAMYEQAKNLAFEEAAATRDSIADLKQQLLRQ
->tr|A0A0Q7TC29|A0A0Q7TC29_9HYPH Protein-export protein SecB OS=Pseudolabrys sp. Root1462 OX=1736466 GN=secB PE=3 SV=1
-MTTTNGGQSQDFNPEQVPQLNVVAQYIKDFSFENPNAPKSLIGGEQPQISIQINVNAAPMSDSDIEVVLQLSGKAETGGSLMFSFDLAFGGVFRIRNVPQESMNAVVLIECPRLLFPFAREIIATTVRNGGFPPLLLDPVDFVALYRQKMAQLGGQAPAQ
->tr|A0A1H8PJE2|A0A1H8PJE2_9PSED Ca-activated chloride channel family protein OS=Pseudomonas sp. NFACC39-1 OX=1566195 GN=SAMN03159293_02848 PE=4 SV=1
-MFEFAWPWIFALLPLPWLMRLVLPAADSGEPALRVSFLGDLEGLVGRRARSNLPTWRQQAPFILLWLLLLIAAARPQWLGEPLPIAASGRDLLVAVDVSGSMDFPDMRWQDEDISRLALVQHLLGDFLESREGDRVGLILFGSQAYLQAPLTFDRRTVRLWLDEARIGIAGKNTAIGDAIGLALKRLRQRPANSRVLILVTDGANNGGEIDPLTAARLAAEEGVKIYPIGIGADPEESGTAGFVGVNPSLDLDEATLREIAQATGGQYFRAQDGQQLLAIKTTLDQLEPVTQQPTQARPAQALYQWPLAVALLLSVLLVARERWPDNPLQRLFTQPLFQPAEHSEWRRRLKRMRLGKRR
->tr|A0A1C3Z1D9|A0A1C3Z1D9_9LACO Citrate lyase alpha chain OS=Lactobacillus apis OX=303541 GN=GA0061073_0264 PE=4 SV=1
-MENKVKRNLPDELMSDMKLKPFESVEVGNPEIKRIAPKVHVTTGENKVVDSLEEVIKKTLKDGMTISFHHHFRNGDFAFNKVMDLIIKLGYQNLTLAPSSLTSVMNDKVIEAIQKGVITNITSSGMRGTLGDFVSHGGLKNPVVFRSHGNRARSIEEGEIKVDVAFLGVPNSDPAGNANGQEGDAVFGSLGYALIDAQYADNVVLLTDNIIDYPNTPASIKQTQVDYVVKVDQIGDADKIGSGATRFTKDPKELKIAEMVNQVIVNSPYYKEGFSFQTGSGGAALAVTRYLRQSMINDGITASFALGGITKPTTDLLDEGLVKKIMDVQDFDKGAAASMAKNRNQQEIDASWYADPHNKGAVVNNLDVAILSALQIDTDFNVNVMTGSDGVIRGAIGGHQDAANAKMTIITAPLVRGRNATVVPSVETVVTPGDSIDVLVTERGIAINPKRKDLIEAFSKVPDLNIVDITELQQMAEKQVGVPKPLEYTDRTVALIQYRDGTIIDTIKQVKD
->tr|A0A3S0XSH9|A0A3S0XSH9_9GAMM 10 kDa chaperonin OS=Legionella sp. km772 OX=2498111 GN=groS PE=3 SV=1
-MKIRPLHDRVVVRRMEEERTTAGGIVIPDSATEKPMRGEVIAVGAGKVLDNGDLRALAVKVGDVVMFGKYSGTEVKVEGKELVVMREDDIMGVIEK
->tr|A0A5S9Q0P4|A0A5S9Q0P4_9GAMM ATP synthase subunit delta OS=Zhongshania aliphaticivorans OX=1470434 GN=atpH PE=3 SV=1
-MAELSTTARPYAKAAFEHALAASTLGEWSAMLVTAAAVSQQPEVMKFLSSPAMTTAQQAQMFIDVCADTFNAGGENFIKILAENKRLGLLPTISELFDAQKAIQERTVDVELTTAFALDSESEKRLAEVLGKKLAREVHVHTTIDPLLLGGVIVKAGDLVIDGSVRGRLAKLAEAINS
->tr|A0A1H7GQD5|A0A1H7GQD5_RUMAL Uncharacterized protein OS=Ruminococcus albus OX=1264 GN=SAMN05216469_102219 PE=4 SV=1
-MKKFTMTNLYSYNELYLSLYLESEETLFVVHTERSECAGTPVTSISG
->tr|A0A699MW03|A0A699MW03_TANCI Reverse transcriptase Ty1/copia-type domain-containing protein (Fragment) OS=Tanacetum cinerariifolium OX=118510 GN=Tci_766510 PE=4 SV=1
-MQEELHEFERLEVWELVPRPDKEEGIDFEELFALVSRLEAIRIFLAYAAHKNMVVYQMDVKTAFLNGNLWEDVYVSQPNGFVDPDNANHVYKLKKALYGLKQAPHAWYDMLSLFLLSXELVPRPDQVMVITLKWIYKVKLDEERQRLTSGLQISQNPRSIFINQSKYALESLKKYGFESCDPVDTPMVEKSKLDEDKEGKVVDPSHYRGMIGTLLYLTASRPDLQFAIC
->tr|A0A1C4LAA2|A0A1C4LAA2_9ACTN Uncharacterized protein OS=Streptomyces sp. BvitLS-983 OX=1838282 GN=GA0115250_119211 PE=4 SV=1
-MTLFLGLGIAGIVLLVLSLIFDGVLEGFFGDFLDGLLSLPAIAGFVSMLGFGGAIVLGTTGLGVAGATVVGVLAGVVTGWVVLKLSKALMRDQTDATPRSADLVGTAGSVVTAIPASGYGEVLVYLGGQPLKLSAKSTAPLTRGTEIWVEASLSSTSVSVRPVER
->tr|T2KLF8|T2KLF8_FORAG Uncharacterized protein OS=Formosa agariphila (strain DSM 15362 / KCTC 12365 / LMG 23005 / KMM 3901) OX=1347342 GN=BN863_18780 PE=4 SV=1
-MFKVKLAFMIKVLINNTATKNIHDKKNYIYLTKHQLYGVLPRFC
->tr|E3RGL9|E3RGL9_PYRTT Uncharacterized protein (Fragment) OS=Pyrenophora teres f. teres (strain 0-1) OX=861557 GN=PTT_06956 PE=4 SV=1
-MLKDVIANNPDKTLTQCLDIVIDKLQLLHQAMTQQNGPSERALANQLISACQGVEACSAVLIRPASTFEA
->tr|A0A7J6B8G4|A0A7J6B8G4_AMEME Sodium/hydrogen exchanger OS=Ameiurus melas OX=219545 GN=AMELA_G00035750 PE=3 SV=1
-MGSERKHHAAKGAWGTLRLCVLASLSVCLCLCRAEDSSMENIVTEKKAEESHRQDSVDLLVFILLLTLTILTIWLFKHRRFRFLHETGLAMIYGLLVGVVLRYGIHVPRDINNVTLSCHINASPATLLVNVSGRFYEYTLKGKISSNDVKDVQDNEMLRKVTFDPEVFFNILLPPIIFHAGYSLKRRHFFRNMGSILAYAFVGTVVSCFIIGLLMYGCVMLMKYTGQLGGDFFFTDCLFFGAIVSATDPVTVLAIFNELQVDVNLYALLFGESVLNDAVAVVLSSSIIAYQPEGNNSHTFEAMAMLNSLGIFLGVFSGSFALGVATGVMTALVTKFTKLRDFQLLETALFFLMSWSTFLLAEACGFTGVVAVLFCGITQAHYTYNNLSPESQVRTKQLFELLNFLAENFIFSYMGLALFTFQNHVFNPVFIVGAFLAIFLGRAANIYPLSFLLNLGRRNKISYNFQHMMMFAGLRGAMTFALSIRDTATYARQMMFSTTLLVVFFTVWICGGGTTQMLSFQHIRVGVDPDQDNSIGPEGLERRSTKQESAWLFRIWYNFDHNYLKPILTHSGPPLTATLPACCSPLARCLTSPQACENEGQLKDDDSDLILNDGDISLTYGDITVNTDATGTRTISIPAGAAGVHSDDALDRELTFGDHELVIRGTRLVLPMDDSEPPLRHREI
->tr|A0A1I5AAM2|A0A1I5AAM2_9MICO VOC domain-containing protein OS=Mycetocola miduiensis OX=995034 GN=SAMN05216219_1297 PE=4 SV=1
-MFTPVHAFSGFSVDDIDAARSFYSEKLGLTVADDDMGILRITLPGGAEVIAYPKPDHTPATFTILNFVVSDVDAAVDELNGRGVTTKIYEDENLPTDEKGVMRDNGPTIAWFRDPAGNVLSVISQ
->tr|V4K2D3|V4K2D3_9CREN Uncharacterized protein OS=uncultured Acidilobus sp. MG OX=1410573 GN=MGAcid_05220 PE=4 SV=1
-MLSHTVELMKSSQGERPDGLPGRGYLLTCTPAPR
->tr|A0A1D6F6L1|A0A1D6F6L1_MAIZE Uncharacterized protein OS=Zea mays OX=4577 GN=ZEAMMB73_Zm00001d007456 PE=4 SV=1
-MLEPVDIGRDGKTVSCRIHDMVLDLISFLSNEEHFLTKVGEQQPISLDLPKKIHRLSLQISQEEEVKQLATMSFSHVRSLTVSTKVFQLMPKLSAFLVLRVLNLKKCKGVRNHHFKDICNMFHLRYLSLNAEFITEMPREIQNLQFLQVLDISNLGHKVKMPTIIHLRQLLRLCFRPMWGIRLPDGFGKLTSLQEVKGIITIKLPSMLHNLGCLTNLRTLAIDFCDWDESYEEPFIQCLSNLVSLKSMEIKGTMVSSLCSECDKLYPGPQHLCSIDIESTAVPRWMSSLCFLSSINIELLALGAQDFHVLGSIPSLRCLSIHVKETRDERLVIGKCYPFRCLTEMQIDYESMAVVFAPGSMQNLKELHLVFGVKEVMHKYGDCNFGLEHLMSLEHVSVKTMYSIMPEEVEAVKDEFQKSLDMNPGKPTLIVDYKYPIKRKIRSHAQAIRAAILFANAGRIPATEGL
->tr|A0A6A9K9T2|A0A6A9K9T2_PSEAI Exodeoxyribonuclease III OS=Pseudomonas aeruginosa OX=287 GN=xth PE=3 SV=1
-MDTLKIATFNVNGIQTRLAALLAWLEREAPDIVCLQELKTPDARFPAAALERAGYGAIWQGQSAWNGVAILARDSQPLEVRRGLPGNASDPHSRYLEAAVDGLLVASLYLPNGNPQPGPKFDYKLAWFEHLIRHAAELMESGHPVVLAGDFNVVPSDFDIYDTRSWKKDALLQPESRECFERLLRQGWVDALRQRFPDRRLYTFWDYFRQHWQRDAGLRIDHLLLSASLADHLEDAGVDRWVRGEEHASDHAPAWVSLRLS
->tr|A0A024VDL3|A0A024VDL3_PLAFA Uncharacterized protein OS=Plasmodium falciparum Vietnam Oak-Knoll (FVO) OX=1036723 GN=PFFVO_00427 PE=4 SV=1
-MAFMFKREGCYSKNRLNEVFRKNKSFVNQLMYDLTSFHYENYMKNKIHKNIMNNYNNIEKIQSMLNLINGEKENAYKIKTGYFYFRSGVPVITPHIEQTNEFAESNNYTYNFKNIKKKYLKEVYDSYKHKIGGTDPSVPHFYKHK
->tr|A0A1Z9W0I5|A0A1Z9W0I5_9GAMM Cysteine--tRNA ligase OS=Oceanospirillales bacterium TMED91 OX=1986769 GN=cysS PE=3 SV=1
-MSLQIFDTLAREKRVFQPLEAEKIGMYVCGMTVYDHCHLGHGRVMVAFDAIVRYLRFRGFEVNYVRNITDVDDKIFXRAAERQIPFSALTAEMIDAMHADEAKLGCQLPNHEPRATANIDSMLRLXERLLERGAAYQGDSGDVYFRVGAFPEYGKLNNRNLDDMVAGARVAVAKDKEHPADFVLWKSAKAGEESWSSRFGPGRPGWHIECSAMSMDALGETFDIHGGGPDLKFPHHENEIAQSESATGCQFAQYWMHAGAVRVKDEKMSKSLGNFVTLAELFREFHPQVIRFFLLQSHYRSAISFSDDALVQAGAAYTRLVQALPDQLTSPSSDAIFQFQQFMDDDFNTPRAIALLFDLAAEGSEESGSSLLAIGKVLGLFATDKVTFLAEQQQLKAANSGLSDAAINALIAARKQARKDRDFFTADKIRDDLVAQGVVLEDAAGGTSWHRK
->tr|A0A4U5PX20|A0A4U5PX20_POPAL Eugenol O-methyltransferase family protein OS=Populus alba OX=43335 GN=D5086_0000167450 PE=3 SV=1
-MASSIENHVSQVDEAKDENFGYAMQLALSSVLPMTLHTAIQLGIFEIITKAGPDVKLSAADIAAKLPTDNPDTPKMLDRILRLLASHQVLCCFVDGSERFYSLAPVSKYFVRNQNGVSLAPFMAMIQENVILQGWSQLKDAVLEGGVAFVRVHGVQAFEYPGLDPRFNQVFNTAMYNQTTIVNGHMLEKYDGFKNLKQLVDIGGGLGHTLKAVTSKYPQIKGINFDLPHVIEHAPAYPGVEHVGGDMFESVPKGDAIFLKWILHNWSDDHCLKLLKNCYKAIPEDGKVIVMESVLPITAKTSPAAKAISQLDVMMMMSQNPGGKERTEDEFMALATAAGFRGIKFETFVCHFWVMEFFK
->tr|A0A2T6GMZ3|A0A2T6GMZ3_9PSED Isocitrate lyase/phosphoenolpyruvate mutase family protein OS=Pseudomonas protegens OX=380021 GN=C5U62_08510 PE=4 SV=1
-MDAQSLRANVFKALHERAGAFVIPNPWDAGSARMLVGLGFEALATTSAGNAFSLGRPDAEGAVSLEDTLNNVREIVGASSLPVAADLENGFSDSPEGCAQALLLAAASGVVGGSIEDASGRADEPIYDFNLAVERIEACVVAARSLPFPFTLTARAENLLHGRDDLPDTIRRLQAFAEAGADVLYAPGLRSAEEILQVVRAVAPRPVNVLMSGGLNLSVAQLAELGVKRISVGSALARAAYGAFYRAAEDIRDHGRFDFAERAMPFRQINQLFKQP
->tr|A0A7R9P3G8|A0A7R9P3G8_TIMCA (California timema) hypothetical protein OS=Timema californicum OX=61474 GN=TCMB3V08_LOCUS1220 PE=4 SV=1
-MAGSEPASAWKESGKLFRENYLSSPDRDLNLDLFIAGSLAQHETSPLDNYATEATPEEIETSLDAALKAGYRHIDTAFAYKNEDAIGRVLKRWFDSGKIQRKDLFIVTKLPGTGNHAESVEKYIKLSLSALQMDYVDLYLIHSAVGKKDSDRGPAGSDHQAELDMNTDHVSVWKAMEAQVDAGRAKAIGLSNFNARQIKRIWSSARIKPANLQVELNVYFQQRELTAFCKALDITVCAYAPLGNPDFAKRISGKSDLKFSSPMEDPVVVKIAKKHNKTPAQVLLRWIIQRGIVVIPKSKTPSRIKANFEVFPSRVCIQRALLGVPREMEQL
->tr|A0A7K2SMN5|A0A7K2SMN5_9ACTN Gfo/Idh/MocA family oxidoreductase OS=Streptomyces sp. SID8350 OX=2690337 GN=GTY74_01910 PE=4 SV=1
-MARSQEQGTEAQTGTPAPPSGQALGTLGVGMVGYAFMGAAHSQGWRTAGHVFDLPVRPALAAICGRDRAKVDAAAARHGWAAAETDWRALIARDDVQLVDICTPGDSHAEIAIAALEAGKHVLCEKPLANTVAEAEAMVRAAEAARARGQVAIVGFNYRKVPAITYARQLIADGRLGTLRHVRASYLQDWLVDPASPLTWRLKREHAGSGALGDLGAHIVDLAQYLAGELLTGVSAVAETFVRERPLLAGAPAGLSGRADTAELGEVTVDDAALFNGRLASGALASFEATRMAAGRKNALRLEINGELGSLAFDLERLNELSFHDHTEPAATSGFRRILVTEPEHPYLEAWWPPGHGLGYEHTFVHQARDVIRTIVEGTEPRPSFADGLQVQRVLAAVEESAAKNSVHTAVPS
->tr|A0A6M1RBC6|A0A6M1RBC6_9GAMM Uncharacterized protein OS=Grimontia sedimenti OX=2711294 GN=G5S52_07050 PE=4 SV=1
-MQADQMRKGMIISKTCAVIAKGKSPQTTQPGYSLQSMRHGEPVNEDAIRAKAKQLGLDQQEQDLFVVIKRNLVHSKKVKDGQIAAFAKHVVQYCDSEADIYNALKGIEQQMAVMDHFIRYIHV
->tr|A0A533RQR5|A0A533RQR5_9ACTN Uncharacterized protein (Fragment) OS=Actinobacteria bacterium OX=1883427 GN=FDZ75_06060 PE=4 SV=1
-MLEMRIGTIKTPWFLALAVVVALVAIASFALVAVAEPPMAEQSSNDVAHHWTARSAGVAPYTELAPAEAAAIDTAKKALTQPPLGVIRNADHGYGAAQGALDTMKAVSTAAPIVAGHELVLSNGTKAVRVYVNQDGSVKPLGSGTLWVSATPNKALSDHNDFDAAEIARGALALHAALDPGTA
->tr|A0A2A8FPC4|A0A2A8FPC4_9BACI PucR family transcriptional regulator OS=Bacillus sp. AFS026049 OX=2033493 GN=CN563_06555 PE=3 SV=1
-MNTSITIEEILTRKHFNLTDIIAGSSGIKRQVKWVHCMEVTQISHLLNGNELILTTGLGWKDCDDTFLSYLRQLIECDAAGLCIEMGANTMAVPQCAIDLANERQFPIILFHEEVPFVEITQDIHSLIINKQYQMISNLENYSQQLNKNLLEIDHYEPILKFLHSYLHVQVILIFNENDIASIPKIKKKSTYQMVADIYEEKRKLDKTVLGQPIQVLGENYAELLICSNGRELTDFDSLILDRTATALAQHLLRELYIEEKKMSEESIWLTNWIEGEYSDEAIRERLSYIDPKMQLDGGIVCICKQHPKYNKNSAKLDGTYFKIMFRTVFEQYGFQIFSMEIQQHLVFILGDNRSSEDWKSRVTSALDRIMKMDVSGRNRMGLLSIGFGKHVQRLSEIYKSYETARETLLLQDTLPEDDRSFFYQDLHMHRMISLINKHGNLEETVYEYLGPVIEYDKQNNGELMPTLKTYLACNGSKQETSKQLFIVRQTLYHRLEKLEKLLGSDFMRSDKRLGLEFMIFALDFLQYSSRKISGKYVDKYIGR
->tr|A0A6N6RG02|A0A6N6RG02_9HYPH sn-glycerol-3-phosphate ABC transporter ATP-binding protein UgpC OS=Brucella intermedia OX=94625 GN=ugpC PE=3 SV=1
-MASIDIQSVRKSYGEHAVLHGVDLEIKDGEFIVLVGPSGCGKSTLLRMIAGLEDITSGQVQISGKRVNELAPKDRDIAMVFQSYALYPHMSVADNMSYSMRLRKTPKEKIASAIQSTAAKLGLEPLLERRPKALSGGQRQRVAMGRAIVRQPKAFLFDEPLSNLDARLREQMRAEIKKLHGELKATSIYVTHDQIEAMTLADRIVAMHGGVVQQVGSPLELYDRPANLFVAGFIGSPAMNFLDVTYLEQDGGPRLKLKDGTLIALPQPLNLKDGAKATLGIRPEHVHIEKSAGLPADVDLVEPTGFGIILHLSLHGLPFKIFTLDRDALHMQGSIQVSFPAQHLHLFDGDGNRVEPRAVQ
->tr|A0A522BP99|A0A522BP99_9BACT Transketolase family protein OS=Patescibacteria group bacterium OX=2052139 GN=EPN90_03525 PE=4 SV=1
-MELKPTRDGYGLGLVDAGKKDAKVVVLCADLSESTRSHWFKKEFPARFVQIGVSEQSMAAIASGLALAGKVPFISSYAGFSPGRNWEQIRTTITLNDANVKVAGAHAGVSVGPDGATHQMTEDLALMRTLPNMVVLAPCDMQETKKATVAVAGVYGPHYLRFGREKSPVFTTPATPFKIGRAEIFRFGRDVTIVACGILVHEALKAAEELRKKGIEAEVIDSHTIKPLDAKTILASIAKTGCVVTVEEHQVDGGLGAAVAEALGAARPVPLERIGVQNRYGESGEPIMLLEAFGLTSPYIAMAARRATARKAGKKVSEVPDYMAAAERRAVELKKQVISEALSRAPREWGGKKGNIKDLIKKSK
->tr|A0A852SI39|A0A852SI39_9MICO Putative membrane protein YkoI OS=Herbiconiux flava OX=881268 GN=BJ984_000542 PE=4 SV=1
-MQKKTKIIGGATLAAVLVLGGTGIAYAATDGFEGSDALTGGDLDRAATVASEEIGGGSVTSAERDDDGYELELKGDDGRYYEVELDGSFGVVSSSADDRVGDTGSSGSGSGSGSGESGESGESGTGEAGGPADGGDDEGDGAGAGSASVDPDDLQGEELEKASAAAIAEAGGGSVTDAETSDDADHAYDVEVRLDDGTEVDIDLDASFGVVRTEK
->tr|A0A0E0XWR4|A0A0E0XWR4_ECO1C Lipid A 1-diphosphate synthase OS=Escherichia coli O104:H4 (strain 2011C-3493) OX=1133852 GN=lpxT PE=3 SV=1
-MIKNLPQIVLLNIVGLALFLSWYIPVNHGFWLPIDADIFYFFNQKLVESKAFLWLVALTNNRAFDGCSLLAMGMLMLSFWLKENAPGRRRIVIIGLVMLLTAVVLNQLGQALIPVKRASPTLTFTDINRVSELLSVPTKDASRDSFPGDHGMMLLIFSAFMWRYFGKVAGLIALIIFVVFAFPRVMIGAHWFTDIIVGSMTVILIGLPWVLLTPLSDRLITFFDKSLPGKNKHFQNK
->tr|A0A2V7LM58|A0A2V7LM58_9BACT Non-specific serine/threonine protein kinase OS=Gemmatimonadetes bacterium OX=2026742 GN=DMD60_00570 PE=4 SV=1
-MTEGDPRPCARNHRRSVRMLLRPRDRTAQLARNLVYTPRGTEGPVTVDLLLPDLQRALAGRYVLERRLGRGGMGVVYLARELRLDRRVAIKLLPPERATQPTARERFLREARTAAQLSHPGIVPIFAVHEVSDFVYFAMAYVDGDTLGRRVRRRGPVPYATAARLLEEVARALAYAHDRGIVHRDVKPDNILLDQTTGRALVSDFGIARVGSATTTGPQRVVGTAEFMSPEQVLGERVDPRSDLYSLGVVGFFALSGELPFLGPDDMTVLARQVSDPAPPLASVAPHVPHRLAEAIDRCLAKDPAERFPNGEALAAELAAALDRRAAVAVRAFVTEARQLSTTTLFYGAFAAVALPLLVLRLLEPDDPPTRAALVGSVATVVAVPLVVMVLRVRRLSKAGYGQADLVDALSAELGHRREELAFLYGEGPSPLERALRRLCYVCVAAAGAIVAALERVPALAGALGVPTLFGVVTAAALVAAVAARARTEHRTNPKGERRLRFWSGPLGRWLFTLAGLRVKRRATPAPGVLSPVVTPVPEARDA
->tr|A0A1I3RF39|A0A1I3RF39_9DELT Glyceraldehyde-3-phosphate dehydrogenase OS=Desulfomicrobium apsheronum OX=52560 GN=SAMN04488082_103115 PE=3 SV=1
-MEKTRIGINGFGRIGRQVLKTIWQRHRDTLEVVAINDLFDTQTNAHLLRHDTSYGHFAAPVEADADTIRVGGEWEIKSFAQRDPKLIPWKSCGVDIVIESTGIFRTGPTAGQHLESGAKKVIITAPSKDEDLTVVIGVNEDKYDPAIHHIVSNASCTTNCLAPAVKVMHAKFGVAKGVLTTVHAYTNDQRILDLPHKDLRRARAAACNMIPTSTGAAKAVAKVIPEMAGRFDGYSVRVPVPAVSLVDFVAVLERDTTAEELKAAFKEASENELKGILGYAEEALVSSDFIADPHSGVVDADFTTVQAGNLAKVLIWYDNEWGYSCRVADLAHLMAQKGL
->tr|A0A401RBY4|A0A401RBY4_STRA9 TetR family transcriptional regulator OS=Streptomyces albulus OX=68570 GN=SALB_07941 PE=4 SV=1
-MERAERGERILEAAGELLVAWGYRRVTIDEIARRAAVGKGTVYLHWKTKDALLLAVVLRAKSRSLHAQLARMRADPREILPSRMMRGYYLDFLAEPVLRALYTDDVDVLGRLNDVAKKELAELMAFNDGILLRYLAVLREHGLVRTDIDVRHQQYVLMSTATGFFMAEAMLADHAPDTPEVRADLFAATIRSAVDMPVEGFGAQTVGPPGRSGAPRARTVEEALVAARRDVLPLYEQAEEYGAREMRRQLRG
->tr|A0A1X2LS66|A0A1X2LS66_9MYCO Dehydrogenase OS=Mycobacterium decipiens OX=1430326 GN=B8W66_16385 PE=4 SV=1
-MCVLRLLDMALERLCAEGLIKGPLRAGFGQEAVSIGAAAALGEGDITITTHRPHAQHVAIGGRLGPMVAAMTGSTAADIWGGDNQVLDAFPRGGLSAGPCVVKQSPSYAIGHAYRQWLADTGGITLCVTEDCDVNSAAFNEAANMAAVWQLPVVILVENIRCALSVRSDRHLREPQAYRRAAAYGMPGVSVDGNDVKAVRDCVTSAVLRARAGGGPTLVQAITYRTIDFSGSDRGGYRDLAGSEQFLDPLMFARRRLIAAGATRDRVAEEERAACQLVADAVAFAKAGSRRDSGARSQPPACV
->tr|A0A380JP96|A0A380JP96_9STRE Myo-inositol-1(Or 4)-monophosphatase OS=Streptococcus equi subsp. equi OX=148942 GN=suhB PE=4 SV=1
-MEDKYAFAKTIIKEAGLFIKDRMKDSLAIEIKTQHDDLVTNVDQETQDFLISKIKKAYPSDHMIAEEGDICHAITDGKVWVLDPIDGTVNFIVQKANFAIMMAYYENGIGKFGLIYDVMADQLFSGGGDFAVTLNDQVLASYQDKPLDLSLIGCNAGMLSRNEYNLHQLIDQTLGVRVYGGAGICMTKVLKQQLMAYFSYIQPWDYAAAAIMGESLGYVLLTLEGEQPDFQSRQKVMFVPKSKLATIQSLLHINENNQ
->tr|A0A2E6Z7C9|A0A2E6Z7C9_9GAMM DUF2061 domain-containing protein OS=Rheinheimera sp. OX=1869214 GN=CML21_09570 PE=4 SV=1
-MLKTTTFAIMHFTIAFAVTYAITGDLVLGGLVAVIEPAANTVAYFFHEKIWQRLQQKNTVQKSLTIFKKPALKW
->tr|A0A1D2SEW3|A0A1D2SEW3_9BURK Ribosomal RNA small subunit methyltransferase E OS=Lautropia sp. SCN 69-89 OX=1660104 GN=ABS56_13610 PE=3 SV=1
-MIRTLDARQSHHLVRVLRLAAGAPVEGFDGKGARFDARIERADPKACAIRLLAPIAACTESPLAITLAQGISAAERMDWTVEKAVELGAHAIQPIVCARTQVRLDAQRLQRRHEHWARIVEAACMQCGRDHLPELGVPLAFERWLAATDRRAARTRIVLDPRGAVRLAALRVDAAQPVDLLVGPEGGFDATELEAARAAGFQAVRLGPRVLRTETAGLAAIAALQAIAGDF
->tr|A0A1A8F559|A0A1A8F559_9TELE IK cytokine OS=Nothobranchius korthausae OX=1143690 GN=IK PE=3 SV=1
-MPETESYSNPLAPDDHELDDHRGGSQAKLTNDDFRKLLMTPRATPSSAPPTKSRHHEMPRDYNEDEDPAARRRKKKSYYAKLRQQEMERERELAEKYRDRARERRDGVNKDYEETELISTTANYRAVGPTAEADKSAAEKRRQLIQESKFLGGDMEHTHLVKGLDFALLQKVRAEITSKEKEEEDLMDKVQKETKKDLEPEEKIEFKTRLGRNIFRMVFRSGVSERNELFLPGRMAYVVDLDDEFTDTDIPTTLIRSKADCPSMEAQTTLTTNDIVISKLTQILSYLRQGTRHKKLKKKDKGKLDDKRAPEADLSIFDDIGDYIPSATSGTKPVKDKDRHRERERERERERNREDDSKSRRQSYFEKPRADEHQLMDVDAGPGSVRDQINMINEKFGGAAGSQWQGQEPGSQRRDSSKEHLGDFFGGSNSYAECYPATMDDLAVDSDEEVDYSKMDQGNKKGPLGRWDFDTQEEYSDYMNNKEALPKAAFQYGIKMSEGRKTRRFKETNEKAELDRQWKKISAIIEKRKKLEADGVDVKRPKY
->tr|A0A5C8LAV1|A0A5C8LAV1_9FLAO Uncharacterized protein OS=Mesonia sp. HuA40 OX=2602761 GN=FT993_07960 PE=4 SV=1
-MKKIDKKEIITSTAKSIFGAIPFGGAALDELFFEYNGRLKQNRLNRFVKILAENFTEESDINLDNIKTEDFNDLFESVLRKVVQTKSEAKLIRFKDVLLNELKKPTKQAEINELYLNLISELTEQEIEILYNHRFFTEEFEEEVNEMNRHRDNMKSLKNQMDKESIIVDESKFLKPYENVKAQFENKKSKIDKVLKYRNADFYNLNENKFMFFKQRLFSKGLLIDDRMKRIGTLPFQSMGITEFGVEFIDFIKTSEKKITVGNTVYNK
->tr|A0A1S6WTD4|A0A1S6WTD4_9HYPH 23S rRNA (Guanosine2251-2'-O)-methyltransferase OS=Bartonella sp. WD16.2 OX=1933904 GN=BWD162_004080 PE=4 SV=1
-MKEKVSKNSYFPHPRRQYRNTKSFNRMPSIHLKHRSTSSIQNIVYLYGIHSVKEALKNPKRVFNHLYATPNALQRLNITKSDLPCSLKLYPPKKLDELVGKDAVHQGVVLETETLKPRHLSELTNTNLIIVMDQITDPHNVGAIMRSAVAFKAGAIITTYRHSPQESGVLAKAASGALELIDYITVRNLAEALTEIHQAGFNSLGLDSESELPLETALTGKKIALILGSEGKGLRKKTRETVHSLARLNIPGDIKSLNVSNAAAIALYAAHNYLKH
->tr|A0A538MZI6|A0A538MZI6_9ACTN Peptidase_S8 domain-containing protein OS=Actinobacteria bacterium OX=1883427 GN=E6F93_02950 PE=4 SV=1
-MAMLRNGGRPGGQSRSSALWGTGNNDDSRSNALWGKGGRGLVTLMAAVLVLGIPLAASAGGDDNTGPETQTYVSPGMLANASKHPDKTIHVIVTANAGDLPKSRILDKTLGSVDRRLGLIDGIALDLRANRLDQLAKIPGLTITPDAPAHPTGSTFSSKQLWVPNTGIDKLWNAPVANSTKTQSDLAVPAIAVVDSGVDTSKAADFGARVVQQVNLTTLPNNSPGDGRGHGTFVAGIAAGQATGYAGASPRSNIVSLDVMDDTGTARTSDVIAAAQWILDNKDKYNIKVANFSLHASNSSSFTHDPLDKAVEKLWFSGVTVVAAAGNYGYANAPSGVKYAPGNDPFVITVGAADMDGNPSPNNDTAPSWSAYGYTNDGFAKPELAADGRYMVGPIPAGSTLASQKASNIVSPGYIMLSGTSFAAPIVAGIAAQIIARNPTWGPDQIKGGLMETARPTPNATPGSLGLGEVNALKAVLLSGAPNPNKALEKFLGPDPSGGNLPAFNAVSWSDTAKANVSWDAVSWGDVSWGDSALAAVSWADISWSDVSWADSLSSADVSWADISWSDSSYEDAAEGDGAGNTTDSFADPADLAAAAADPDLQLPSDLVALQPSATTSLP
->tr|A0A5E6PHC7|A0A5E6PHC7_PSEFL Alginate_lyase2 domain-containing protein OS=Pseudomonas fluorescens OX=294 GN=PS645_00335 PE=4 SV=1
-MIDLSTWNLTIPVGAPARVIETPRLVDGYSDAYFRAGNTLFFWAPVTGGTTSKSEFARSELRETYKDGELRNWKYPKADHRMTASLSVNQVPSEGRVVIGQIHIYQGKGPLLKVEYVYDKARQTGSVIANYRLKPGSADTKVVIAEDVDLNKRFTYEIRLSSAGYLHVISQGNRWGKQLSKSWQNKQLYFKAGAYALDNTGYKSEGAQVTFNKLEVKHSKG
->tr|A0A4S2D6C4|A0A4S2D6C4_9MICO Redoxin domain-containing protein OS=Microbacterium laevaniformans OX=36807 GN=E5344_10370 PE=4 SV=1
-MNHRALIATASVLLVVGLLAGCGSSESLAQQYRNGNEKGYIAGDFQIVEIPDPDRGEPVAFEGVTETGETVTSDDYRGGVLVVNFWYAACGPCIVEAPLLEEVWQDYQDQGVAFLGVNTYDQPATALSFARDNNVTYPSVIDVNDGRVKLAFAQVTPIQATPTTLVIDQDGRVAARIIGQLASASILSTLVADTLAEDSS
->tr|F2YA48|F2YA48_GLOPA Pectate lyase (Fragment) OS=Globodera pallida OX=36090 GN=pel1 PE=3 SV=1
-MLFVIISIVFAQLCQVHALCTFPASPKTTTVQSTINVASNTDYKYTTFVGGSGILNGGCDVKNGKMKYLMVLKNGVTIKNAIINTPGLGIYCEGNCVLENIYYKKLCYHATGFGYKSTSTSYTYQVIGGAGQGSPDKYFTQSGRGTTIIKNFCAEGKYGKVWCSCGNCIDQMPRSVQISNTKIQGPGLAIISANSNLGDKISISGLTLYGQGSPNTLTKYVCQTYNGLTKMATMQPTAKFRPTQAGTGTCAYSTSAIKIVN
->tr|A0A2K4FSF4|A0A2K4FSF4_9PSED Uncharacterized protein OS=Pseudomonas sp. MPBD7-1 OX=2075549 GN=C1892_11745 PE=4 SV=1
-MTSKKTATAVSDLTLSPAANGPEVSKPSSPPRPLSTQQYLYFTETNTDRILDNLDGLRDTVFPRPPHLVDDEYDRAQQEFPSVCLIGLGRCGSNIALDVAELVYNARKFYLNEFNAEDKGYSDKGYSPAQWIRNNLRLGTSKASKPVFLVEPLVMLGDLDKDIAGRIRFSRKGEKSGFLRDYSKMKIMDLSEVHAGGAGNAPILGQYLAKIILNKDTQRFSSPDWKMIHSYLIDSCGIKANQSRLYFSIFSAGGGTGSGMASEFGLAQQYSYMNKTFDTKPMDEHDSKSGHSFVFEPIFTSGICVLPNISDHRSEMSEALHINAGRLLCKYLSEEWDFSYNFANEDSSEASVMGRIRPWNAMMLISNDIMRYAEESDDGNIQNIDVNAMEKHANQYISQQIFNILTAQAVTTDYDQNYFRRAGIDIGETIRLDANDLFMSLAGPVAIAYAESVVPETPVPSGDKFKVFEKEPPRLNIDDLFFRSIDLPHFNKVTQAIEGISLLPIESKRYRASLEQYKNSGYDAAALHDLHFFKNCSSVVSIVSLPKDYKLSYMDLNRLKTHLNSLFPNTTLKRYALVIGASANLSLTTLIAKSPCLSDDFLTLIVAFIKRCFARTPYRFDETLDNSILDFIINEDFDEARIDDLLNEFENPAKILDTNWYAIKPMYEKKYRELINDKDKFVSINDIRLSRDCVKKSIKYLREIYRHRIGKTKVISLNNHTGRTY
->tr|A0A401T372|A0A401T372_CHIPU ENTH domain-containing protein OS=Chiloscyllium punctatum OX=137246 GN=chiPu_0015593 PE=3 SV=1
-MTSSSLRRQMKNIVNNYSEAEIKVREATSNDPWGPSSSLMAEISDLTYNVVAFSEIMSMIWKRLNDHGKNWRHVYKALMLMDYLIKTGSERVAQQCKENVFAIQTLKDFQYIDRDGRDQGINVREKSKQLIALLKDDERLRVERSHALKTKERMSSVTTAVGSNNQIMFGRGSSHPNLSTSQSDECGKIGGSPASYHGSTSPKISSELEQTRPQTSGEEELQLQLALAMSREEAEQIFKSATTAGSQPRNTVLTLSAQDEQHRRGDDLRLQLALEESRQKLQMPGMAPHKTETALLDLTDSTPSPLTQKSDPWGAPLPSTSTTKPDPWAAVSRPVSNDPWKQMAGSRLAAATSDPWGSSGRRLSGEQQSRSADPWGSAAAAPDRDPWAPTSPQVAPPFHSFSAADAAVTDEFSVFSHLRGSPRKVEGQGTGGRFEVLGDGLTTPATSVVTGCSDVFDMPSMSSTVPSKLPTPKHQPTTQKNPESFLGPNASLVNLDTLITHTTHPNVSTNPFLAQAVPVASANPFHSTPTQMSSSMMAVTQTPFGPVDVTATSFSAMPRVGAAPMVTMPAMQMPQSTGMQGMMGSNYVAMAAPPPTGQSASSTNPFLL
->tr|A0A318DIN8|A0A318DIN8_9GAMM Extensin-like_C domain-containing protein OS=Dyella sp. AtDHG13 OX=1938897 GN=BDW41_11025 PE=4 SV=1
-MSVVRYLGLLILMVGVFIALLVASGWRPPYRYNPWARLDLRAEPDWLTRFRLYRLQHHNDQCLAALAQAGAEYRAVSDRPLVDGCGWQGTVMLRGTGQATLATPTVVTCPLAASLVMLDAHVLQPRAASTFGSPVAVIEHVGSYSCRNIRGDDGSALSSHARAEAIDITGFRLKNGHDISVMRDWKRSVSGAFLHQIQAQSCGYFGVALGPDYNAAHAGHFHLQAGAMGWCR
->tr|A0A1R1WU44|A0A1R1WU44_9ACTN Uncharacterized protein OS=Streptomyces sp. M1013 OX=549798 GN=BSZ07_05050 PE=4 SV=1
-METLAQFGDGGPGPWILLFPVIWALVIGGGITLLRRTVWRGRRGPARPGAVEDNSPITVLGHRFASGEIDEDEYWRRLSVLDEQFGRTGKGGAA
->tr|A0A2S8IRD2|A0A2S8IRD2_BURCE Uncharacterized protein OS=Burkholderia cepacia OX=292 GN=C5615_17140 PE=4 SV=1
-MKKTTLKSVFLTGLLVLVPLAITLWVLGLIIGTMDQTLLLLPESWQPERLLGFHLPGIGAVLTLAFIFIVGLATRNFIGQKLVTWWNAVVRHIPVVGPIYTSVKQVSDTLLSSSGNAFRKALLIEYPRRGSYTIAFLTGTPGGDVLNHLTEEYVSVYIPTTPNPTSGFFLMLPKSEVIELDMSVDAALKYIVSMGVVAPPAPAPAPARRPVEPPL
->tr|A0A2T4IVX8|A0A2T4IVX8_9HYPH Integrase OS=Mesorhizobium helmanticense OX=1776423 GN=C9427_13580 PE=3 SV=1
-MLVGYARTSTAEQDAGLLAQQRDLREARVEKLFSEQVSSIGHRKELETSLDFLREGDTLVVTKIDRLARSTSHLLAIVDRLEEKKVGLRILDFGGASVDTKSPSGKLMLTMFAAMAQFEREMMLERQREGIAKAKLDGKYKGRKPTARARSGEVIKLHIDGVGPTEIAKRLGMGRASVYRILEAPGE
->tr|A0A8A6NMP5|A0A8A6NMP5_9ERIC InfA OS=Impatiens loulanensis OX=2822277 GN=infA PE=4 SV=1
-MKEQKWIHEGLITESLPNGMFRVRLDNEDLILGYVSGKIRRSFIRILPGDRVKIEVSHYDSTRGRIIYRLRNKDSRD
->tr|A0A7C6PFE8|A0A7C6PFE8_9RHOO Uncharacterized protein OS=Rhodocyclaceae bacterium OX=1898103 GN=GXX56_08515 PE=4 SV=1
-MQLPITIELHRSRLQPRILALLLSVALIVVLFYPLPVPLRLIGVTLLALGGGWMVRQLRPQVAALQLLADGSLGIRGTDWNHPEFVPARMLQGATVHPWLTVLRLEAQEGQPYRLLLTPDCLLPEDFRRLRVFLRWRSTVSASDAPV
->tr|A0A6P3QY80|A0A6P3QY80_PTEVA zinc finger protein 512B isoform X2 OS=Pteropus vampyrus OX=132908 GN=ZNF512B PE=4 SV=1
-MADPFCVGASRRLPGSSKSGPGKDGNRNEVRLPVRHDPPKLGLPVARGGQSVPSQAPLCFDPGSLASDRTEGKKKGRPKAENQALRDIPLSLMNQWKDEFKAHSRVKCPNSGCWLEFPSIYGLKYHFQRCQGGAISERLTFPCPFCEAAFTSKTQLEKHRIWNHMDRPLPAPKPGPVSRPVTISRPVGVSKPIGVSKPVTIGKPVGVSKPIGISKPVTVSRPVPVTKPVTVSRPVPVTKPVTVSRPVPVSKPVTVSRPMSVTKAVPVTKSVPVTKPVTTNKPVPMTKLVTVTKPVPVTKPVTVSRPIVVSKLVTVSRPIAISRHTPSCKMVLLTKSENKTRAAGRSSGKKRAADGLVACPIPPKQTRPENGEHGPSTLGQSSAFQLGTDPSGGPLSVGNRPSGGKEAPRAPGPVSPTEEGAERTKHRRKQKTPKKFTGEQPSISGTFGLKGLVKAEDKSRSYRARKQDGPSPEDVRKKAPAPASTVSKEVPAPTAHLAPGGPEEQWQRAIHERGEAVCPTCSVVTRKTLVGLKKHMELQDALKCQHCRKQFKSKAGLNYHTMAEHSAKPSDTEASEGSEQEERERLRKVLKQMGRLRCPQEGCGAAFSSLMGYQYHQRRCGKPPCEVDSPSFPCAHCGKTYRSKAGHDYHVRSEHAAPPPEEPEDKPPESEDLLGVERTPSGRIRRTSAQVAVFHLQEIAEDELARDWTKRRMKDDLVPETARLNYTRPGLPTLNPQLLEAWKSEVKEKGHVNCPNDCCGAIYSSVSGLKAHLAGCSKGDHLVGKYGCLLCAKEFSSESGVKYHILKAHAENWFRTSADPPPKHRSQDSLVPQKEEKSLAGGRKRGRKPKERPPEEPAPRTPPRQDDWPPGGRDKGVRGSAGRKVGAGKAPEK
->tr|A0A081RSK0|A0A081RSK0_PHOTE Chemotaxis protein CheW OS=Photorhabdus temperata subsp. temperata Meg1 OX=1393735 GN=MEG1DRAFT_03734 PE=4 SV=1
-MSAIEAFNKLSGETAGEGYLVFTLGDEEYGIEILKVQEIRGYDQVTRIANTPAFIKGITNLRGVIVPIIDLRIKFAQETVTYNDNTVVIVLNLLNRVVGIVVDGVSDVLSLKAEQICPAPEFAVTLSTEYLTGLGSLDDRMLILVDIEKLLNSEEMALVDSVAKN
->tr|A0A1V5AGS2|A0A1V5AGS2_9EURY tRNA (Guanine(10)-N2)-dimethyltransferase OS=Methanosaeta sp. PtaU1.Bin028 OX=1811687 GN=A4E47_00993 PE=4 SV=1
-MDGRDLKCGLEEAVASELWAFELSGEHATLPRSEALALLKVHSSSFKEVCLLDQCLIVRAPSIDAAALEARLAMSHRVLRVLAISSCSHSDLSFAASSIDIPRQTYRVRARSVGRSALSGYDVEVAVGRELFRRGYRADLSAPCQEIRCIVSQGLVVLGVEVARPDRSGFEGRRPHLKPFFYPGVLMPRMARALVNLTCVRPGERLLDPFSGTAGILVEAGLIGTRCVGLDVQMKIVRGSLANIDGIECSLLAGDARRLPFRDASVQAVVTDPPYGRSAAIRAASRDELLARSFEEMARVLQPGRRAVVVADHPIDDLLASAGFLQREIHSERVHRSLTRRIYISEI
->tr|A0A4V3XAK0|A0A4V3XAK0_9APHY Uncharacterized protein OS=Phlebia centrifuga OX=98765 GN=EW026_g3689 PE=4 SV=1
-MSDASDILPPSLDLPPHLSAQKYFFVCTLTVAAWDTLVLSPRSWRLFRTKGWPFLKIAYHFLRIFMPVEFTIVGVAFFDTKWSQETCSHFFLFEPICTAILLAVCSAVHVIRINAIYDKDRRVFTPMVALYAIQILITAICCGFYRSTPLLIGQGCIAEPKHSWVGIYWISATMLYTASFGLALSRAIRSLKIKKISYWKLMLRDGLNLYAAVFLVNLVNMLFWFIITPTGPEDPIRTIVTSMSAVLTASMTLRIILSVRGTLEKGGSTGPVLSLQQPGTGTFNVPLGATESKTHDWVDDKASDQMGMSEVKGEGDFPVESGLGTPTSEDAPKGVKITIDTETAF
->tr|A0A1M8A1H4|A0A1M8A1H4_MALS4 Similar to S.cerevisiae protein RKM2 (Ribosomal protein lysine methyltransferase) OS=Malassezia sympodialis (strain ATCC 42132) OX=1230383 GN=MSYG_0658 PE=4 SV=1
-MEQALAAYVARASGSPTLRVAVSDQVPAGRGLVTTGAVQAGETVLRLPPSVLLNPSQMARGRPVPWAPLRHAEEPCPNARPLSTHQLLACVLAQWRAARVAGPSTELSDRDAFFASMPSAFPTVPLSWALDGDTQLLSALPPRAARLHDKVQARFEADWRRLDALDEATRASIWASVSRPGIPAVRPRKADVLWGWLCVNSRCVYVDLRYVRHEDNFTLAPLLDMANHTFVQGKQCKVRYSAEGMELCAPAQCGLQAGDEVCITYGPHTNATLLTEYGFLLAPRDALRGASAWDGNPHAELAVDDAIAERFRAEGDEGAWKVQRLKEEGYSGDYTMHPEPAPAHVSHRLLMALWLLSMAMENKHTTQRLSLRARAALQAKQGLRCVYSPKEAARQWKQVTYGMPDSRHERPMRDVLCRLCTEMAEQRSALLEQLQGRHDEPASLVRLLLEEERDIAHRVQTSAERGEAW
->tr|A0A4V6I9D8|A0A4V6I9D8_9BURK Glycoside hydrolase OS=Burkholderiaceae bacterium PBA OX=795666 GN=MW7_007585 PE=4 SV=1
-MAGAPPCVHAETARSRAIDVPGPWTTYYGAASKLDLQQVARTYRLLVIDADPGQHNFTPEQIAQLRDGGRNRVLSYLNIGSCERFRTYWRTTGTAIPGCGANRRAQRGVYHGYPDEVWMDPSDPDHQRLVLDYLAPRLVAQGVDGFYLDNMEIVEHGVRTDNGPCGDACRRGGLELVYKLRARYPQLTIILQNTAGPVTRMGQAGGVPFPTLLDGIAHESVFAPQHDADADAQLALWRAWSSERPEQRFWIGTLDYVGKCENVDRARKAAARSRARGYVPAVSDASAGQQRICDWPQPLAE
->tr|A0A851NIW1|A0A851NIW1_9GALL PPARD protein (Fragment) OS=Penelope pileata OX=1118817 GN=Ppard PE=4 SV=1
-MEQLQEEVPEVREEEEEEEEAVTVTGGASDPSAGPDSSLPSSSYTDLSQSSSPSLSDQLQVGCEEAASGALSVECRVCGDRASGFHYGVHACEGCKGFFRRTIRMKLEYEKCERSCKIQKKNRNKCQYCRFQKCLSLGMSHNAIRFGRMPEAEKRKLVAGLTASEISCQNPQVADLKAFSKHIYNAYLKNFNMTKKKARGILTGKASSNPQPFVIHDMDTLWQAEKGLVWKQLVNGIPPYKEIGVHVFYRCQCTTVETVRELTEFAKSIPSFIGLYLNDQVTLLKYGVHEAIFAMLASIMNKDGLLVANGNGFVTREFLRSLRKPFNEIMEPKFEFAVKFNALELDDSDLSLFVAAIILCGDRPGLMNVKQVEEIQDNILRALEFHLQSNHPDAQYLFPKLLQKMADLRQLVTEHAQLVQKIKKTETETSLHPLLQEIYKDMY
->tr|A0A1H7HQ73|A0A1H7HQ73_9LACT Transposase InsO and inactivated derivatives OS=Alkalibacterium pelagium OX=426702 GN=SAMN04488099_103146 PE=4 SV=1
-MKIIGLAESTYHYHAKRMNQPDPDREWKTLITKIFLDKDKRAGYRSIHDILIFMGYTINHKKVQRIMQELGLKCHKFSRKSRSYSSYKGTVGKIAKNLINRRFHSTIPLQKLVTDVTEMKCAQGKKLYFNPILDLYNSEIISYSISDTPNVDFVMQALEEALPIINKHATYRTTIHSDQGFHYQNKRWVKKLKENKVFQSMSRKGNCLDNASMESFFGIMKQEMYHSEPLKTFKELKKEIEEYIIDYNESRLKRKLNRQSPVQFRKNQGYTYAV
->tr|A0A2D1KXX5|A0A2D1KXX5_9LACO 50S ribosomal protein L7/L12 OS=Lactobacillus farciminis KCTC 3681 = DSM 20184 OX=936140 GN=LF20184_09720 PE=4 SV=1
-MALDTQKIIDDLKDASILELNDLVKAIEEEFDVKAAAPVAAAGAAGGDAAAEKDSFDVELTEAGQEKVKVIKEVRGITGLGLKDSKDLVDGAPKVIKEGVAKADADDMKSKLEAVGATVTLK
->tr|A0A2E5T8Y9|A0A2E5T8Y9_9GAMM Glyoxalase OS=Alcanivorax sp. OX=1872427 GN=CL551_10510 PE=4 SV=1
-MFNHIMIGSSDIERSERFYTAVLGVLGAGEPMRXXSXSGHIRLFYRHDGNTLAITQPINNEPATGANGGTIGFKCESPEQVKEFHDVAVANGGTSVEDPPGLREGPMGALHLSYVLDPDGNKLCGIHRLK
->tr|A0A4R4X4E5|A0A4R4X4E5_9ACTN Uncharacterized protein OS=Nonomuraea diastatica OX=1848329 GN=E1294_04030 PE=4 SV=1
-MTTPDDYTYVRFGSMEQAYEELKKVVTELDRATDDLYADIKRELGPSWEGEAERFFEEKRQKWNAHEKAMGQQLFQAASAVNVANGNYQQAERRNIGIWTD
->tr|A0A401SWZ4|A0A401SWZ4_CHIPU Uncharacterized protein OS=Chiloscyllium punctatum OX=137246 GN=chiPu_0013380 PE=4 SV=1
-MAQDTRVMTFYMELRTDPPGHCAITPPGSLYHDEPSPAQSVANTRSPCFLSPIVPPCTQRRSLPPDTKMDFLGFPGCKKGTASLVRTQSETNPFREFAPASSGRSTAPSSPVCIRTHPFCPVTLENTMGGDTRGRSSVVTFSYIEKARVKTVVNPFNVSVLPQGVKLAGMGQGSSIGWKSPQTSHKVSHGIISMPTPMESFDTRVSTVSVGSCREPSNSLIPNRSLLSSVGSASQRYSDAAAQSPCPGGKRAQSGNELRQGYPSKQVCTKALDLGTDLMTVATPNKTSSNHSIAAIPCVNPIGREIPNSPGLTQVEACMLVGEHSERAQRIAKARREFFYGTLEPQIPEDKADSKTWQAPVNPDNNTTREIAESKDQGASANGSLDAKLGTLSQGSAKVVNDLKSAPLSNGTSTDYKARDQLRAMKYSETDLDAVPIRHYQETNLDEVMTDYNITSSDGQELTHLMNSTLDSVQMDHPVPSRGFGRDQTTGNHEVCREEQSKAAEDDVFSELSSAADERSLEVEVKNLLPPVATIPIARSLSEEGTDTFSKQFESILESHRDKGTSYTSLDSMETLPSPSRNQGNYFTFDFPSLTSEIQVQIKENARLIEEEWSSADGEGCTNSAKASDWPDSPGCQATRTERKLGVSPMVGYSKSENTLTRCQLYAEGNLLKRALEIGDDEPKSEYSSSDSNLNHLVMDSESEMDSTEQLALGSTDTLANGNKTDQEAAKRLAKRLYYLDGFKRSDVARHLGKNNDFSKMVAEEYLRFFDFTGMNLDQALRAFLKEFALMGETQERERVLIHFSHRYHQCNPGAISAEDGIHTLTCALMLLNTDLHGHNIGKRMSCSDFIGNLEGLNDGKDFPKELLKVLYSSIKNEKLQWTINEEELRKSLSELVDERTDPSLKAMNRISGGSNPFLDIVQDPNAATYKHGFLVRKVHADSDGKKTPRGRRGWKTFYAVLKGMILYLQKDEYKSDKQLSEDDLKNAISIHHSLAVRAADYSKKPNVFYLKTADWRIFLLQAPNAELMQSWITRINLVSAMFSAPPFPAAIGSQKRFSRPLLPTTLTRLSLEEQIKAHDTRLKSMTVDLTEHRSYPPDKKVKGKELDEYKQKEEYLEFEKMRFSTYVSLLRAKLKSGTDDLDKFESALFDNIESEGNGLTKSHSSPSLHQEPPVMAIRVKRNTSERRSYRHSANTKHKL
->tr|E3NQ34|E3NQ34_CAERE SUN domain-containing protein OS=Caenorhabditis remanei OX=31234 GN=CRE_07925 PE=4 SV=1
-MKYKTGAENKPFLRDVESPSDNPSNPFHFRKNEYFGNEKPIAKKESWHQVLNNRLRHYTVLEAFLFVFLVILLFKIYSLQSQIDTLERKLDSKKNAESHLMKTKEILEEKKVIHEIVQNVINPSSPFPKEKEGKVKLNSEFNAASLVLGASIETRQSSHSVSPGNSYFDIVSFALGSDQSAFSLLDRVELPVDKAWCTDDRKPVLTVNLADYIKPISVSYQHSKWNRTVPNGAPKLYDVVACIDGDCNQPLVSNCEYSKSGNQEQKCLISTGLPLVNKIQFRFHENHGNLNKTCVYLVRVYGEPSGSKEVKIQVKNQKEEEETAKICSRLAWFHDNIPVFYNGLASKNCSTLYSNNCCHECPNCCSECQINDSTLLNNLQFFIIFFVLFFILFPMYIAGISACCFGLKRFFGI
->tr|A0A1Q7VVJ2|A0A1Q7VVJ2_9ACTN Uncharacterized protein OS=Catenulispora sp. 13_1_20CM_3_70_7 OX=1805055 GN=AUG49_18720 PE=4 SV=1
-MSSPSKFLRDLAKKTNTASAARAVLRAAHVKTGPSRLGDPRAGLPASVLPAGGNRITVENAKPGSANWRMGSGRSRAATDYERQIKGYASTDSVALGSAIDFHVAVXYGVAGAGGRTAAGPHSGPGNGTDRRGMASRMDAGHPHGLGLRNICRCPG
->tr|A0A4R4JD96|A0A4R4JD96_PHOLU Flavin prenyltransferase UbiX OS=Photorhabdus luminescens subsp. mexicana OX=2100167 GN=ubiX PE=3 SV=1
-MKRLIVGLTGASGAIYGIRLLQVLQPVEGVETHLVISHSARQTLALETDYSLRDVQALADVVYDNRDIAAAISSGSFKTLGMVILPCSMKTLSGIVHSYTDGLVTRAADVVLKESRKLVLGVRETPLHLGHLRLMTQAAEIGAVIMPPVPAFYHQPQQIQDIIDQTVNRVLDQFDIELPHDLFTRWQGAKSVEI
->tr|A0A1E3ZHP6|A0A1E3ZHP6_9BORD Nitrate/sulfonate/bicarbonate ABC transporter ATP-binding protein OS=Bordetella sp. SCN 67-23 OX=1660091 GN=ABS43_07680 PE=4 SV=1
-MNTAPVLEARGVARRFPNGVDALSPIDLTVRAGEFVTLLGPSGCGKTTLLRIFAGLDAPTAGSLRRHGEVDELSYVFQDATLMPWASVATNVRLPLDLERGPRRQPMEARRGRVREALERVGLTDFAAARPSELSGGMRMRVSIARALATEPSLLLMDEPFGALDDITRQHLDDELLGLAARQNLTVVFVTHSIFEAVYLSSRVIVLSRRPGRIVADIPIEAPTRDAAFRVSPAFAMQAARLQAALLEGQQ
->tr|A0A2D4C9B4|A0A2D4C9B4_PYTIN Uncharacterized protein OS=Pythium insidiosum OX=114742 GN=PINS_010966 PE=4 SV=1
-MNPQQFASYVPQQQQMQGRVGSMGFAGQFATTGRVASSSSMASPVPIHAWTPPSPMEQQYFDMLFTMADEERRGAIGGRIAVAFFSRSNVDKTLLREQRSELSRNEFYVAMRLISMAQRGEAINVQRFYEMAAAPFPLPTLDGVPPPPSPQSSFVPGAPQPAVPTPSPMGGPQKGPFAITDEEKARYDGIFQQYDTDRDGFLQGGEAVGLFSKSGLDRMILRDIWAMADRTQDSRLDAKEFYIAMHLIVCISKRGLSMPTEAPQELLESPPVAPPAPEPKKDPMDAFAGLSPIQDSSDDPVDDGGAVGVNAGGPSAISK
->tr|A0A0C1QX44|A0A0C1QX44_9CYAN Uncharacterized protein OS=Tolypothrix bouteillei VB521301 OX=1479485 GN=DA73_0227160 PE=4 SV=1
-MYTIDLTVRNTAFPISVERKSAEDAEQLYQLILTAMRSGNPDIVELQSEGKTEKKIAVRASEIAGVQVIQKDGSAAGTGRPPGFFALASE
->tr|A0A7T0C4B3|A0A7T0C4B3_9BACT tRNA 2-thiouridine(34) synthase MnmA OS=Candidatus Nitrohelix vancouverensis OX=2705534 GN=mnmA PE=4 SV=1
-MTEKPKIVIAMSGGVDSSVAAALLKERGHEVVGISLQLWNYSGESDNRFGTCCSLDDLSDARRVAHKIDIPFYVLNLESEFRAEVVDYFVDEYLQGRTPIPCTLCNQKLKFDRLFQKAEAFGIERVATGHYASIVQVDGRYTIRRGEDRTRDQSYFLFNLSQSQLSRLEFPLADMAKTEVRRIATELDLVVAQKSESREICFVPDNNYAKFVASEAPHAFAEGEIVDKSGAVLGRHGGYPAFTIGQRKGLNIGGLKEPHFVTGIDPESNRITVGPKDDLIASEFYVSRANWCLDVTGPVEAEVQIRYRHSAAPAEVTPLENGRAKVSFYDPQLSITPGQAAVFYKDDCIVGGGWIE
->tr|A0A2S9KN53|A0A2S9KN53_9BURK Hydroxymethylglutaryl-CoA lyase OS=Burkholderia ambifaria OX=152480 GN=C6P77_27700 PE=3 SV=1
-MTFPTAVKIVEVGPRDGLQNEKTFVPTDVKIALVDRLSRAGFRNIEAASFVSPKWVPQMADGADVMAGIERRAGTVYSVLTPNLKGFENALAARADEVVIFGAASEAFSQRNINCSIAESIARFEPVAKAAKDAGVRLRGSVSCTLGCPYQGEVPVASVVDVVERFAALGCDEIDIADTIGVGTPKRTREVLSAVTRVFPRERLSGHFHDTYGQALANIYAALFEGIEIFHASVAGLGGCPYAKGATGNVATEDVLYLMQGLGIDTGVDLAQVVAAGDFISNAIGRANVSRAGRALLAKAQSATDAPSCV
->tr|A0A4U3MG24|A0A4U3MG24_9ACTN Winged helix-turn-helix transcriptional regulator OS=Herbidospora galbida OX=2575442 GN=FDA94_14520 PE=4 SV=1
-MSAVPPYDPDAPGPATYVYARVADHIAARILAGELVPGMRLPGERDLAAEYGVALGTARRAIEELRGRRLVVTLAAKGTYVARPEDIDPPTG
->tr|A0A7Y4Z391|A0A7Y4Z391_9BACT Uncharacterized protein OS=Bacteroidales bacterium OX=2030927 GN=HOO91_10445 PE=4 SV=1
-MNNKNQILPEEIKSILLKYYDGCTTIEEELLLKKYFAQNQIPYSNISDKALLSFVNDNELSIFPENEIWNKILVTEKKVNKQRKTIRILSSIAASVLILISLSIWLFYPTKRVEILTDSYSNPHDAYNAVQKYLGLVSTKLSYAYNEIKPIEKLTIPCDAMQAFSTIDKNVKRLQQFDKLGASAHELERFSIISDIVIVDKN
->tr|A0A257X4W0|A0A257X4W0_9PROT Uncharacterized protein OS=Methyloversatilis sp. 12-65-5 OX=1970398 GN=B7Z51_07255 PE=4 SV=1
-MSLSDIPDEMTLRLAADGRIECRRGTDAAAPAIRFDPAFFGQPESADAQRALGRFVFSLLQGMAPAAGTAAGPAIDGPASLLELAEKSLQQSAAAGFGQAIEALKDWPSVRTVADMLIARGPEQPR
->tr|A0A800G627|A0A800G627_9CHLR Uncharacterized protein OS=Dehalococcoidia bacterium OX=2026734 GN=EYQ67_00675 PE=4 SV=1
-MPRLHLNPNRMIKDRGQGGRLRRALENLRKQHQWGDISDDEYRRERGIIMRQLKVHTSTIVMPTHLPNLERAANFLEDLPALWLHPGVTHEEREALVRQVFLRITIAGKEFVDIEPKPEYASLFATMVTAQKIGYQELESSRSPVSLLLLPSGISVFGI
->tr|C8BFH5|C8BFH5_9HIV1 Reverse transcriptase (Fragment) OS=Human immunodeficiency virus 1 OX=11676 GN=pol PE=4 SV=1
-PISPIETVPVKLKPGMDGPKVKQWPLTEEKIKALVEICTEMEKEGKISKVGPENPYNTPVFAIKKKDXTKWRKLVDFRELNKKTQDFWEVQLGIPHPAGLKKKKSVTVLDVGDAYFSVPLDKEFRKYTAFTIPSINNETPGIRYQYNVLPQGWKGSPAIFQSSMTKILEPFRKQNPDLVIYQYMDDLYVGSDLEIGQHRTKIEELRQHLLKWGFTTPDKKHQKEPPFLWMGYELHPDKWTVQPIVLPEKDSWTVNDIQKLVGKLNWASQIYPGIRXKQLCKLLRGAKALTEVIPLTAEAEL
->tr|A0A2M9CET1|A0A2M9CET1_9CELL Uncharacterized protein OS=Sediminihabitans luteus OX=1138585 GN=CLV28_2224 PE=4 SV=1
-MREYDATPASTSRGQAALRWVLWIGGAALLAFGVLTALTTVPSTSQRINVLLWLAGGVVVHDAVLVPLALLVGVVVLPRVPPSWRPALRGGLLALAVLGIVAVALVAGAATRANPSVVPQDVGAALALAGIVLVVGVLVGMFLGGARRPR
->tr|A0A1Q5JW10|A0A1Q5JW10_9ACTN Lysophospholipase OS=Streptomyces sp. TSRI0107 OX=1703942 GN=AMK31_31985 PE=4 SV=1
-MDDAREHVLTGTRGAITVREWAHPRPRYTALLVHGYGEHGGRYTETAGVLAEHGAAVFAPDHAGHGGSAGERVLIEDFEDVVADVRQVAERARAAYPGVPTVMVGHSMGGLISARYAQRYGGDLAALVLSGPVIGTWETPARLLAHDAAHGEIPDIPISPAALSRDPRVQAAYAADPLVWHGPMKRPTLRAFVRALQDVAEGGDVGPLPLLWLHGDDDRLVPLAGSRTGVERLSGGALTERIFPGARHEVFHETNKAEAFAEVTAFLDRVLGA
->tr|Q87XS4|Q87XS4_PSESM Uncharacterized protein OS=Pseudomonas syringae pv. tomato (strain ATCC BAA-871 / DC3000) OX=223283 GN=PSPTO_4102 PE=4 SV=1
-MSAFFRLFLRFFAAQRHGLLEGVAHFVEAFVVQIVNAPGALCAQVDQFFIVAHGLPLSDTGKQCQ
->tr|A0A2I2FRI4|A0A2I2FRI4_9EURO Uncharacterized protein OS=Aspergillus steynii IBT 23096 OX=1392250 GN=P170DRAFT_441696 PE=4 SV=1
-MSVPTVRRAFGSISKQRSLYSVRDRLHFGILVHLFNIALALVLLPLNNTILLAAYTAGYLSFVLSRSDPIQRRQAALRDVQFYPKTILVTGVDTPHGLAVARSCYHQGHRVVGVSVTETAIPSGESMSKALGAFYRIPKTKYVSRLLDVINREKADVWVPCSEKASVLDDAMAKQVIEGRTECKCITMDTELASMFGRPATFRQYLVEKELPVVENHQVQSRDSIHKILHRSPTKTYRISRPDPVTRENKIITLPKRTLSLTYSEVSEIQISKESPWTLQQQSRLGEFLAEMLVVHGHVKAIKVRPADDQSTWGRSRLDEGLTMSIHKLMERFALKGGYRMTGHICVRVMVDEEVDANQVRYALHINGCTQGAGAVNDLLQDASEQLVRGYLSVEAPHLNGFMASDSVDALRIQAAQSIVSTTPRPKFSLYQKLKEHDDENLFTVLYPVAQHIDTLISGTERALMFWRDWRFSIHDPLPWWWDAHVYQPLKELESIVSGAEVKEA
->tr|A0A1Q5DAT6|A0A1Q5DAT6_9ACTN Nuclease SbcCD subunit D OS=Streptomyces sp. CB02058 OX=1703921 GN=sbcD PE=3 SV=1
-MRILHTSDWHLGRSFHRVPMLDAQAAYLDHLVETVRARSVDVVVVAGDVYDRAVPPLSAVQLFDDALHRLAAAGVPTVMISGNHDSARRLGVGAGLIARAGIHLRTDPADCATPVLLPDPEGGDVAFYGLPYLEPALVKDSLGASKAGHEAVLTAAMDRVRADLAARPDGTRSVVLAHAFVAGGEPSDSERDITVGGVAAVPAGVFDGVDYVALGHLHGCQTVTERVRYSGSPLAYSFSEHTHRKTMWLIDLGTGGDLVAERVECPVPRPLARLRGRLEALLEDPALDRHRGAWVEATLTDPARPDEPMARLLERFPYTLSLVFEPERTPDDPSASYAQRLRGRDDQQIAEDFVAHVRGGSGPSARERTVLRAAFDDVRVDDVTGEVSR
->tr|A0A7Z7ZTA3|A0A7Z7ZTA3_9MICO Type III secretion system (T3SS) chaperone YscW OS=Cryobacterium psychrophilum OX=41988 GN=EDD25_0264 PE=4 SV=1
-MDESDDDAQTVRGTIVFPPAQRPEEPFTVIVQLEDVSRMDAPSRILAEVRLANRDFGAGRGRELPFRLPFPTELLDPAKAGPLRLNLRVHVRHTAVSHEPASRGIMTHVDVTEGDFVSTQSHPVPRGGALVRIPVQRV
->tr|F9WTX3|F9WTX3_TRYVY Uncharacterized protein OS=Trypanosoma vivax (strain Y486) OX=1055687 GN=TvY486_0039130 PE=4 SV=1
-MLGKSCHQLQKNKKLIEMIDTRDECKSYTEKYSVSIRLSSYAEKLDEMNNLIEWKNEMVKLVGQTHKEVKSSAYRGNLWTVNDEKVKEVVQAIRNLTDKPVVTLELLETVRVSVVEANKTVNSTVNSMENVNKTMLSALEGNGTLLPQLVGQYSEVSAQLHERKGRLATTQGNINSTMKAIENALVDVAATESLVKYVNGLILLLSLFGYSSVSRQLRGAKIASETTHDTSDAKAAALMASELPGSAHSYASTAQVEIERETGSLESIKPQLMKHLNETGISISSLTTEACDKGLSKVFNGSLAVAFSRAAGLNSSGMAKAQEALKKLKAEAALVNAKLAYINGSLQQAEKAVQDVDQHDEAVMSTVKNSIVEVVSGAMKDLCETMKGLYTFRLASTSLNEEAEGILGNVSVLVGLSNVTRNKMNKAVKTVPNAAEYFGVANRELAVFARATNKIEKLHSTVQSDVASFLEEQMKRESHINTTHMPSL
->tr|A0A1V0RMR8|A0A1V0RMR8_9RHOB Uncharacterized protein OS=Roseovarius mucosus OX=215743 GN=ROSMUCSMR3_01389 PE=4 SV=1
-MTIFTPLTAATNADRLEPSHDTVYSIAFAALLPSLADFIEAERDLDDICHSYDPAYGVWHRDAQVARMRLDSTLRHVHGLRVERPEDQPLRRMALLADAMLKDGAPERPQYLHRQMKLVFFRQFQVQGFGPTAHSRNAMLIQARHLIDAMMRLPLFDYSPDCAIAPDASAPADDLSPAFF
->tr|A0A0J8BW32|A0A0J8BW32_BETVV Uncharacterized protein OS=Beta vulgaris subsp. vulgaris OX=3555 GN=BVRB_8g185090 PE=4 SV=1
-MRSKREREELTDGEVKRQRVEKDEEEEVSSPKTHAFENPLLPLASYNDDDEEEEEGNVKKAEVNGRKNEIVDDDEDDDDEEDFKFGQGKHNRLVVVRRDCPYLDTVNRQALDFDFEKFCSISLTNLNVYACLVCGKYYQGRGSKSHAYTHSLEAGHHVYINLKTEKVYCLPDGYEINDPSLDDIRHVLNPRFSKEQVEQLDKSKLWSRALDGSDYLPGLVGLNNIKETDFVNVTIQSLMRVTPLRNFFLIPENYQHCKSPLVHRFGELTRKIWHTRNFKGQVSPHEFLQAVMKASKKRFRIGSQSDPVEFVSWLLNTLHADLRSSKKNTSIIYQCFQGELEVKKEIQSKGTVERRLKGNDQNGGSENPNVITETSKMPFLMLGLDLPPPPLFQDVMEKNIIPQVPLFNILKKFDGETITEVVRPQIARMKYRVTKLPPYIILHMRRFTKNNFFVEKNPTLVNFPVKNLELKDYIPLPTPNDKEKSESKGNKKMQSKDHEKLRSKYDLIANIVHDGKPSEGSYRVFVQRKSEEQWYEVQDLHVSETLPQMVALSEAYMQVYELQQPH
->tr|A0A430LAB7|A0A430LAB7_9HYPO Uncharacterized protein OS=Fusarium euwallaceae OX=1147111 GN=BHE90_012892 PE=3 SV=1
-MDSKNSLLYKNFHKHPAALVESASGIYLHTSDGRKILDATSGAAVACLGYDNKEVQKAVVDQLVSVPYCHPGFYKTKSAEDLADFLVDSTNGQMSKAVLCGSGSEAVEVALKLAKTHFSHLAIPQTERCHFIARVGAWHGATLGALTLGDFKVRKDPFVQLISQNSSRVSACSTYRGLRKGETEEAYVQRLAQELDDEFQRVGPNKVCAFVAETVGGSASGCAMPVKGYFPAMKAVCEKYGALLILDEVMCGMGRTGSLHAFEQEDVVPDILVVGKGLGAGYAPISAVMLNTKLVESFQKSGKGFAHGQTYMAHPQAAAAGLKVQQVIRDTNMVAHVQRMGDYLGSRLKERLLPLPWVGDIRGRGLFWAVEFVIDKKSKDPFPYSLGLHGMLHSKGMSKGYEISLFNANGGYDGYSGDHFLICPPFIVNEADVDEIVDRTARVIEDTFSELVNSAVWEKIAIQMDISTEAPVTDISVGETLVSVN
->tr|A0A5I4QS92|A0A5I4QS92_SALET Mn2+/Zn2+ABC transporter ATP-binding protein OS=Salmonella enterica subsp. enterica serovar Agbeni OX=1967642 GN=znuC PE=4 SV=1
-MTSLVSLENVSVSFGQRRVLSDVSLELSPGKILTLLGPNGAGKSTLVRVVLGLVAPDEGVIKRNGQLRIGYVPQKLYLDTTLPLTVNRFLRLRPGTQKTDILPALKRVQAGHLIDAPMQKLSGGETQRVLLARALLNRPQLLVLDEPTQGVDVNGQVALYDLIDQLRRELDCAVLMVSHDLHLVMAKTDEVLCLNHHICCSGAPEVVSMHPEFISMFGPRGAEQLGIYRHHHNHRHDLQGRIVLRRGNGHS
->tr|A0A6H0AMT6|A0A6H0AMT6_9MICO Transport permease protein OS=Clavibacter michiganensis subsp. capsici OX=1874630 GN=GW571_05855 PE=3 SV=1
-MTAVRPARPAADRAPSLPGVVPLGIHRVRYEVRRYFRQTDTIIFTFLFPVIMLSIFSVAFGSSGNLGTAPDGSGGVSAAAYYLPGMIAAGILLSGVQNLAVDIAMERSDGTLKRLAGSPLPVLSYFIGKGGQVIVTSLLQMVVLLLVARFAFGVELPTDAGRWATFAWVYALGITSSAVLGIALSRIPRSGASATAVITPIVLVLQFISGVYLTFTMLPTWLQDVAAFLPLKWMAQGMRAVFLPDALASVERGGTWDLAGVAVVLAVWLVGGTIAAVATFRWIRRDS
->tr|A0A668RY45|A0A668RY45_OREAU VEFS-Box domain-containing protein OS=Oreochromis aureus OX=47969 PE=3 SV=1
-MAPHKQSHPVGLGSGGKPNGLYHHQPSSASMAAAKKPNMQLIQADHELFLQAFEKPTQIYRFLRTRNLIAPIFLHRTLTYMSHRNSRNNVKRKNYKVDNLLFKVEKMRGEQETHSLASNLQLTFTGFFHKAGKLSQDSENEQNSVSLEVLLVKVCHKKRKDVSCPVKQVPTGKKQVPLNPDTSAGVQAKLSSYPSLLVPSSEFEPSNSHMVKSYSLLFRVSRPGHPRTQINGLANGEIHHKEAVNRKRRSSALREEGETTFVAQMTVFDKNRRLQLLDGEYEVSMQEMEECPVGKKRATWETILDGKRLPPFESFSQGPTLQFTLRWTSDSADHSTAPVAKPLATRNSETNQDTRPSTLRATHTPTVKESVNTDVQTRREQVLSEPRQKLRIFYQFQYNNNTRQQTEARDDLHCPWCTLNCRKLYSLLKHLKLSHSRFIFNYVPHPKGAKIEVSINECYDGSYAGNPQDIHSQPGFAFSRNGPVKRTAVTHFLVCRPKRTKPSLSEFLESEDGDREAQRTYISGHNRLYFHSDSCLPLRPQEMEVDSEDERDPDWLKEKTVKQIEDFMDVNEGEKEIMKLWNLHGLFCLFMNEACLLFAEHHAAVIVKRNLCRNFLLHLISMHDFNLISTLTINQAMARLRLVESQSEASISDLPGTLSSTKGFLLAGSVCTCSVESRLRRLLGVKSAAVLQKEV
->tr|I6XM23|I6XM23_9CAUD Uncharacterized protein OS=Pseudomonas phage MP1412 OX=1204517 GN=MP1412_18 PE=4 SV=1
-MDLEKLRRDWAEDPQLKFYAFDTVEELAAHLRKVHTDMMNGEHGCFGYLYRQQTLRLRELMKELQDERERKASGR
->tr|A0A498P3D5|A0A498P3D5_LABRO VPS10 domain-containing receptor 3-like protein OS=Labeo rohita OX=84645 GN=ROHU_001246 PE=4 SV=1
-MRGRMIKMKDVLGFESSWTYWTLFCLCALLPLPASADITCASCFAPIRRNEAHAKPTAVVSRDFGSAKDGSTDKNWKWRLDGAQLSPEAHKKSPFVSRRQKLQNAHIPRAERTSPAGEKDGKVYPTWSPVETKVDRREKRSLSDSASGSRFEFRRTGGVDGTGKSPRQNEPHLITSTFALSGDAAHNQAMVLWSGHNSSEDGSQGSRVAEPVAVNTLTRGHIKPVKTHSGKTDARLFTVVYERVLRMFCQVILILTKLFDFNLGTVTESSLWRSVDFGTTYEKLTDKVMIRTMLSYLYVCPTNKRKILILSDPEVESSLLISSDEGATFQKFNINFYIMSLLFHPTQENWILAYSHDQRLYSSVDFGKKWILVHERVTPGRFYWALSGLDKEADLVHIEARTDSGQMQYITCRAQKCSEEGRQYPFSGRIDTNSLVVQDQYIFLQLTTAGRTTYFVSYQRGPFRTIQLPKYCLPKDMHIVSTDEGQVLAAVQEWNENDTYSLYISDTPGVYFTRSLPNLRTSRGLAGNLIVDVYKVAGVSGLIIANKKEDAQMRTYITYNKGQTWSLLQPPAKDTTGHDINCNLPSCSLHLHLQMSENPYTPDTISTKHSAPGIIVATGNVGPELSFANTGMFISSDAGNTWRQGEVCVMGERQVYMKRKPGTHCTLGREYSRVVSAEPCICTLYDFECDYGFERQASGKCAPAFWYDVSLPAHTCSHGQRYRNSTGYRKVLLNNCREGLKDTLSPRMQQCKPIAPSGLQLSTVNSQLTAVLGTNITFRVALQNPLITLEGSVSHTFTREGPNSVTVQVSAGGTVLQDVKIITVKDFFRSLLLSFSPNLEEHNPSVAEWRQDVGRVVRATLSQMSEVFMNALNQNLIQFDLKPDTRVTVSVSQLTLAPLVDSSVLPSGSAMLLLVSLGLVGLAILFIYKFKRKIPWIHVETEDTHEKEPEMISAVGQEKNGTRTTATSFTTCSTHTTHTPFPSNTGTHNSFSHLPPPRDLMEKELEAHNTGGLGVGERQRTRQIPNCTNV
->tr|A0A424MM85|A0A424MM85_9GAMM Tryptophan synthase alpha chain OS=Gammaproteobacteria bacterium TMED112 OX=1986734 GN=trpA PE=3 SV=1
-MQNSNLLTVNKNKTAFIPYLVAGHTSNEVFSAALKLLNDVGADLIEIGIPFTDPIAEGKIIESAHHHALKNNFVLSEVCKIVKEFRTYSDTPVIAMGYTNSFINPSSEYIATKLSESGFSGVLIVDLPASEKSIINSFTEKKLNLVQLIAPTTQLNLIESFLENDPALIYYITQRGITGSTNLDLAEISEKLSSIKKLSNKPVVTGFGIKTVEDVKNLKNLTDGIVIGSPIVEKINLDSSLNALKEYLKPIVKAIKE
->tr|A0A4P7QD82|A0A4P7QD82_9CORY Putative NUDIX hydrolase OS=Corynebacterium endometrii OX=2488819 GN=CENDO_01140 PE=3 SV=1
-MTFIPQPDAPGSNVTLRPEDSPAWMRPALGIDAAHAQRTMGDRAVTNGPWKKEAAVLVLLAGDSVEEGSVLLTHRSPRMRSHSGQIAFPGGRIDPEDLNAVDAALREAWEETGLDRSTVTPVEQWARLSIRATGNPVSPVLAHWHEPSPVGVASPNEADDVFTVPLADLIDPANRLTVGWGQWSGPAFHAQDYVVWGFTGGVLATLLERAGWAEDWDRDTVHPLHETLARSRNNERMR
->tr|A0A257QSR6|A0A257QSR6_9PROT DNA topoisomerase 1 OS=Rhodospirillales bacterium 20-60-12 OX=1970565 GN=topA PE=3 SV=1
-MTDIVVVESPAKAKTINKYLGDGYHVLASFGHVRDLPPKDGSVKPDQDFAMLWESDSRGEKQVGAIAKALKGAKILYLATDPDREGEAISWHVRAMLEDKKALKGVTVKRVTFNEITKSAVTTAMAHPRELDQPLIEAYMARRALDYLVGFTLSPVLWRKLPGSKSAGRVQSVALRLICEREAEIEIFKAREYWTIEAGMITPAGAPFTARLTHLQGKKLDQFDLPNEAAAMAAKAAVQAGDFSVVQVEKKRTRRHPPAPFTTSTLQQDASRKLGFSAQQIMRTAQQLYEGVAIGGETVGLITYMRTDGVQMAREAIMAVRDRVKANFGTDYLPATPREYNSKAKNAQEAHEAIRPTDFGLSPDQAGRYLNAEQSKLYELIYKRALASQMQSAELDQTSVDISDAAGTTLRANGSILAFDGFLRLYREDMDDVADDDDAKILPPLAKNDPLKRGEVKAEQHFTQPPPRYSEASLVKKMEELGIGRPSTYASILTVLRDRNYVRLEARRFIPEDRGRLVTAFLTSFFARYVDPDFTAGLEEKLDLVSDGKADWRQVLRDFWRDFSAAIGQTTELKISDVIDALDEDLGPHFFPSRADGSDPRACQACGTGRLGLQLGRHGSFIGCSNYPDCQYTRRLIVDGEEGADTLKEGMKILGQHPETAEDVTLRRGPYGLYVQQGEPVDKEKPRRSSLSRGMNADDLTLDQALGLLSLPRLVGPDPQTGQKIEAGVGRFGPYVKMGSIYASLDKDDDVLAIGLNRAVMLIAKKAEGIRNVGPHPKDGADVMVRKGRFGPYAQHGKTVANLPRGTEIADITLDEAVALLAERGKTLAPKGKAKAGAKKPAKAAKIMATGDAAPKLKPKARPPVKAAKPKAAPAGTAKPAAKAKPKPKAAPKAAAKPSAKKAAARAK
->tr|A0A087GHN3|A0A087GHN3_ARAAL RNase H type-1 domain-containing protein OS=Arabis alpina OX=50452 GN=AALP_AA7G126600 PE=4 SV=1
-MYIAESGTSVSAVLVREERGEQKPIFYVSKTLTDAETRYPQLEMLALSVVIAARKLRPYFKSHSIVVLSTFPLRSVLHSPSQSGRQAKWAVELSEYDIEYRGRSCAKSQVLADFLIQLLEGDVAKEDSSQEATLSGEWQLHVDGSSSKSSYGIGIRLTSPTGEILEQSFRLGFKASNNEAEYEAILAGIRLARAFNIEEISVFSDSQLVVNQFSGKYATKDERMEACLGLAKELAALFKKFMFTQIPRGENVNVDALANLASTSDPALKRMIPVEFIEFPSILPAVSLTIITRSQAARKIKVTQKRGENDGKDIVITDATKDNVEMSDATEDTPLTQTDPNPSRLPIANGSSYACY
->tr|A0A549YU05|A0A549YU05_9CORY MMPL family transporter OS=Corynebacterium silvaticum OX=2320431 GN=EU799_09205 PE=4 SV=1
-MFSRWGDFAYRHRRVVPVAIVVFIVAIYGIFGIRLADRMSQEGWDDPGSSSTQAANIEQEVFGRDNSGDVVLLFSSEDGIAKNKNFDEIKRYLSDLKALHPNQIADVTSYFDNRNAQLLSKDGKTAFAAVSLRGDHEQTLKDFRAIKGNLKPKFDGVTVQVAGATAVADALDSGMAGDIKRAEVVALPLVAILLLFVFGSVVAAFMPLIVGILSILGSLGVLSILAGFAQVNVFAQSVVTLLGLGLAIDYGLFMVSRFREEMDQGRDIRDAVRITTSTAGKTVVFSAAMVAVALSGLLVFPQAFLKSVAYGAISAVGLAALLSITVLPSIFAMLGTRIDKWTLRRTKRSARTLADTWWYKLPAWAMKRSKTVVVSVVFLLIALTVPLAGITFGGINETYLPPNSDVRKAQSTFDQEFPAFRTEPIKLVVSNATNDQLIKVYQQANTVTGLTDRFKPSTATKDGTTVLSAGIAERKDNESVVKQLRAIEVPEGVSVHIGGTPAMEVESIEALFEKLPWMAIYIVLATFILMSLVFGSMILPAKAIIMTILGMGATLGILTAMFVDGIGSSLFNFSAGPLMSPVLVLIMAIVYGLSTDYEVFLVSRMVEARDNGESTDEAIKYGTAHTGGIITAAALIMIVVCGAFGFSEIVMMKYIAFGMVVALLFDATIIRMLLVPAVMHLLREDNWWAPRWVKRASEAMGHNSAPEPLPVASRPVESGDKPARRVEPAQPRVPVSAYMDDTSTMAPVKEPPAPQRPAAPRPTPPRPMPPRTPPRTDAPAFNPKRTWGSTPATSHNAGGADTVEGQGSHTPKRKLHHSRRETLVSDTTVVDPRTAGRSGRIASEDNELVPFSELVKRLREEH
->tr|A0A662N443|A0A662N443_9EURY Thioredoxin-disulfide reductase OS=Thermococci archaeon OX=2250254 GN=trxB PE=4 SV=1
-MFSLTGLSTSGKDENKVRDVLVIGAGPAGYTAALYAARYGLDVDIISKDLGGQIALTDIIENYPGFPEGISGQELATRMYEQVKKLGVDVIFDEVVRIDPTECAYYEGPCKFEVKTKNGKSYKTKTVILAVGAEPRKLHVPGEDKFYGRGVSYCATCDGPLFKGKSVIVVGGGNTALQEALYLKSIGVNVSLVHRREGFRADKIVQDRFRESGIPMILNTVVTEIKGEAKVESVILKNLKTGETFEKKVDGVFIFIGYEPKTDFVKHLGITDEYGYIPVDMYMRTKVKGIFAAGDITNTFKQIAVAVGQGAIAAASAKELLEDWREKNLSE
->tr|A0A7U9R2R0|A0A7U9R2R0_9FIRM HTH-type transcriptional regulator YesS OS=Lachnospiraceae bacterium OX=1898203 GN=yesS_1 PE=4 SV=1
-MKAFHFFRHSRTYRRMFLHTYVLYAASSLLLLLAAGLFLFYQDSHTIRNNTLQAAANLAYYADDRLSACQKLSASVGQSERLLSLSSNAATDLDFSLLDSTTLFAAQHDLVSAKALNRFAATLGVYLYNKGFVVSDYGTLTLESFYQSIFNMSPNVFSEYLRPLGSGSYLFLPRGAVEETGTPQHPLIVLSVIDSNSRRYGNLFIFMDERQMREDIEQLLNNRDMEYYLFAGEGQLVVSNRCADPKELSRIYSGLMENDSYQSNTGKYSGWTAFAGYSDAYLRERLHRRLWILAAGLAFLLLSGLPLTHAICRKNYAPIRELAYIVSSPEQRSDNRDMEYEALKSIISSIFKDKSLLEEQLLIYRPLLVNSMLLELLEGAQPRKEVLPGLQKLGIRFPYPYHVCCCLLTARATQDFLMSLAQATRDGETGCLYITFRKHLGIFLISASSPEKCGDAVTRLLALLAEVNPDAFLGVSDAVDDLEQLGAACQQSRSALEYLPSDPFSRGIYWSRVKSSGILKLALPTCLASLPNAFGTGQFAEARNNLNLYFQTISRCGLTKKEHLTHARDRLLEAISRAEKEHGLLFDSASLLNWTPEQPHALKCLQESAFLACDRLERDMLESREQQSLNAAQNLMDYLQLHLRDEDLSLSKLAETFQLSESSISRRIKQITDYNFLEYVNRKRIEYACSLLSETDLSVNDISKASGYVNDITFRRLFKKYMGVTPGEYRRQA
->tr|A0A540WLW0|A0A540WLW0_9DELT LPS assembly protein LptD (Fragment) OS=Myxococcus llanfairpwllgwyngyllgogerychwyrndrobwllllantysiliogogogochensis OX=2590453 GN=lptD PE=4 SV=1
-MSLLVPLAAALLVSSAQIPLATQVQLPSGETVELAADFLTYEADKQLLTARGHCELRTGEMLLRSDEVTYDEANQVATATGNVMFVGPDGMAAVADDVHVDIRTFVATLKGGLFMQKKGVTQEALLTAKTPQELRAMGETPIILSGSRIRRTGPNAFVVDDLAFTPCECGPGTPTWRMEASSANVILGERATLTWPVVYIQSVPIFALPWVYLPLAERRTGFLFPSPQFSSLNGLGLEQPLFVTLGRSYDLTFTPGYYHGALVEKTHDPDGNSETKNTITYEEPRPNGVKGPRLLTEFRYVPSERTRGRATLGFLYDSRPKLDPTTLDFFRYPVDPNGIRKIIDAPRGLRGEASWQHFQDLGSGWYDRVDASVVSDGNYTRDLTADILVQGLDYLRSTATVFRRQEDSYAGLDVSLRQDIRWPYRFFQDNRVPAEVDPLRPDLPSPRTFQRLPGLVLSLPERPLLGGITGGLRAEFTRLAPIHEGFGDEGVDGIFRPNGNYLLLGVGDAPDPGQSNALFDSRDREARDRIDFTSRLSTSVALGDVARVTPSLSLRQDVWAGEYSGKSWQRGYPIGGLMLDTQLSRTWTGAKTSYRHSFAPSLELRYVPGGWG
->sp|B8CSY5|RL21_SHEPW 50S ribosomal protein L21 OS=Shewanella piezotolerans (strain WP3 / JCM 13877) OX=225849 GN=rplU PE=3 SV=1
-MYAVFQSGGKQHRVEAGHTVRLEKLEVATGETIEFDQVLLVADGETVHVGAPLVEGGKVVAEVVSHGRAEKVTIVKFRRRKHHDKKMGHRQWFTEVKITAISA
->tr|A0A815PV26|A0A815PV26_9BILA Hypothetical protein OS=Rotaria sordida OX=392033 GN=JXQ802_LOCUS53044 PE=4 SV=1
-MEELIRSVIQFDGALNQDVIQWLEYIEEVFDRVQLQTSNKYIAIQYFLTNSAATWFKYKKSNIPDWFTFKRELIEAFQSSSSFSSSHLLDRHQLIIKEEPQKLEQEQDILPVPASTSIISNKKNDSEDYQLDLVHDGSIKSLENLEVDDLEDKCLHEHEQGYYSSILVNTNDFDLDIQHQDADAADSCDTQQQGANVADVCDQLEQQGESVINSDSVQTDIEDTFEDFTRPMDSLTGNDSLINIVLPHDVQYLWSDKYKPRPPRILNKAHAVYNWNRYNKLHCNQDDSPPPTIQENQFNTVSTEWNYTYNHGLRFYFYNEMIQLRFSFQKTRKEVIVLRTLQHENIVGYKTVWCEHPPDDWQKKQEKSFQVPSSSEDSTTGFNTIHSISKESKSNQESNDDTSNPFHHSEKWVPLNANSDENKKAPEITNIRSEEEEDNNYEEQ
->tr|A0A444Z367|A0A444Z367_ARAHY Rep_fac-A_C domain-containing protein OS=Arachis hypogaea OX=3818 GN=Ahy_B05g076446 PE=4 SV=1
-MISLFKSLISNGVVYAFAYFRVYNNRGSYHTTSHHFRMFVQAIPTVRPSFCNAILLYSIKLVPFTKIMGYFSQHPFLVDVARVITGVEGERKYVKDGKLIDMLLNVAVLGEMVERIKDFVAAGEQQVPVVIFQFATVKTFRGLHRCHEKPPHVEEKDVTHRIEEGDDILSSLRLVAVAERGAPSSPSRLRVWGFEEREKLAEERETVCCREASQYLSILSSKLAYVAEDEVLYSIERKTIKELRAVGFYIVLATVLDVEPALIWWYKSCVCSVKAKANADTYFYDGCNKDVNHVVDMYKLDLLVFYGTATTTFVVFDKEATALFGWTCTEMVKELNEKGKAGKDPIGFKEFLFKVELKTTGWCDSYDVSLISFELTILARWRDTQGLVKSGIAPAGPTTHFDGDDFLIFEKKRSIEQLKLSKEFE
->tr|A0A379C7X7|A0A379C7X7_9FIRM Uncharacterized protein OS=Peptoniphilus lacrimalis OX=33031 GN=NCTC13149_01564 PE=4 SV=1
-MDKKTDAPTFTKEQFLNAKDPIGNVDALYAILEDGKEYTKEEALKIYEDFMNREVK
->tr|A0A2I0I053|A0A2I0I053_PUNGR Uncharacterized protein OS=Punica granatum OX=22663 GN=CRG98_042231 PE=4 SV=1
-MVKQGFEGRSRRNRSPRWCQRHPKSLVAMVWAAQQRREGVVKETHKTHRIGRFNGILLKTDRFNGSDGSKLQFRFSGESDRTWCRFSEPAGPDHGPSPPATAPARSRSGCSLRSTPARYTFEGVVCLFVGEHCHHRGDEVPGGP
->tr|A0A1L9V3M1|A0A1L9V3M1_ASPGL Chorismate synthase OS=Aspergillus glaucus CBS 516.65 OX=1160497 GN=ASPGLDRAFT_40709 PE=3 SV=1
-MSTWGQYFRVTTYGESHCRSVGCIVDGCPPGLQLTEDDIQPQLTRRRPGQSVLTTPRNEKDRAEIHSGTEFGHTLGTPIAIMVRNEDHRPRDYGGQTMEVFPRPGHADLTYLQKYGVKASSGGGRSSARETIGRVAAGAIADKYLRLVHNVEIVAFVSSVGREYLNPPTPEHPSGINPEFQQRLKGITRSIVDQFEPVRCPDQEASQRMIRVIERFRDEHDSIGGTVTCIIRNVPTGLGEPCFDKLEAKMAHAMLSIPATKGFEIGSGFAGCVMSGSAHNDPFVRQNRVLVTKTNHSGGVQGGISNGSAIYFTVAFKPPATIGRPQSTANYQLQDSVLEAKGRHDPCVVPRAVPIVEAMTALVLMDALMAQYARDAARGITGASGWGNKCV
->tr|A0A7N5JEP9|A0A7N5JEP9_AILME Lipocln_cytosolic_FA-bd_dom domain-containing protein OS=Ailuropoda melanoleuca OX=9646 PE=3 SV=1
-MPPNLSGYYRFVSQDNMENYLRALDINVALRKLVCLLKPDKEIIHTGDHMTIRTLTSLRNYIMDFDLGVEFEEDLGPVDGRKCQTTTQTR
->tr|A0A353MIV1|A0A353MIV1_9DELT DUF490 domain-containing protein OS=Geobacter sp. OX=46610 GN=DDY22_22195 PE=4 SV=1
-MRRAALYIGCALAGLLLLCLLGLFWLLDTTAGARFAVTALTGAAGFNISMQGVEGRLLDRLHLTGVRVSKPQLRAQIDRLDLAWEPRQLWNGHLQVHELAVSGVRVQDDRPATTEPPQLRWPRVSAPLRGLSAQLSRLKVKDLSYRHLEAAPLLVTELTGSLHFKDGLLSASQLSLLSPDGRVSGEIAAGLWHPSLRLDLAVVPAQPVQELDFFSLQARLLPGRLPEQLAGGIVVAGRSGGARRLELTGELGIAVNALNLRRLKLSRPGSRGTLTGDVSMLLSKPEPLFSLALRATDLDLAKELKLQLPTRLSGTVTFSGSLSNFLGSFDLANSGPGWQTASLAAQYRGGPTGVKLAPLTGKLLDGRLRGALEVAWSEGLRISGNLAGRGLNPGRLAAQWPGLVNLDLAGKLEMPEQGVARGELRGKLLESRLHGRDLQGELVAAFAGERLRIDRLLLRGRGFNLQGAGELDRRLNLAARVSDLSGLVPGAAGQLQADGWVRWRDGLFSGAASGQGANLAAAGVSAAALRLDARLGEGKSPPVYLDASLNRLRVGRFQADSALLTLQGTPASHTLTAKLSSSSFAEAPADSSAFAEASASAKTLAELRVALSGGYRDGVWRGELTRFSGRDGVGPWSLAAPTPLMLSAQRMRIAPLVINGLPGERVEVAGELERQPLSGAVRGAWGGLNLARANAWLDGVQLAGASSGDLSLRLLPGERLILTGRAEAKGTLVADGQRVDLERLAATLQGDAGGLRAAVDLTLAGGDGEAHLLFTSTDPASLALPKRGDLTLNWSEFDLALLRPVTPAGLIVDGRSAGLVRGKLLPGSKLELRGNAALDQGHLNWRAEGDELDASIDSAELSFSWRGGTQGAGKGGAGLLTLNARAAATGLYTSKGQRIALIRGTLRADADEQGSRAGLDLTLEEGGALRVDLSSDSPASLGIPETGDLAMEWGGIDPALLKPWLPGTLDLQGEFAGEASGRLLPGKRLEMAGQAEFSQGRAKWQGENGEVSANLRSANLSWNWRGETLSGALSLALAEYGQARGSFVLPIPARLPLLPDRNGALQGALAGRVQERGFLTAFLPGLVQESHGDLDLDLKLAGTWSDPRIAGSLQLSKAGAYLPTAGIRVSDVQLMARLEGDQVRIDNFRAVSGAGHIEGNLEARLEGWQVAEYSGTLSGERFQTVYLPELQMVTSPQLSFKGGGDSVTLRGELRVPEMLVSGPPVRQIVTPSGDVIMEGAPPASEGKPFPLALDGRIRVVLGEKVEVKASGIDAQLGGSMDLVLQGVDSITSSGEIRVVKGRYRAYGMDLEIVRGRVYYVDDPVDQPTLDILALRKVGDVRAGVTVAGFLKAPIVKLYSEPPMPEVDILAYMVLGHPLGASSEQGNMVAMAATSLFSLGESSSVQEQIKDRLGLSVLGVETVDTAGVGLMGYKEIPVTPTGEAQARPAAAESLLTVGKYLTPQLYLSYGRSLITGGNLFMLRYDISRRWQLETQSGSESGLDLYYKLEFN
->tr|A0A1R3FS38|A0A1R3FS38_9VIBR Diguanylate cyclase OS=Vibrio sp. 10N.261.45.E1 OX=1903177 GN=BH584_20360 PE=4 SV=1
-MKVTRKYILRFSIALAVVSMILSAVQFNRTEKSLLESNQLFFRTIVNASYDIVDTTVNEAIKTYLKGITDTVASHVWHATPEQEIEQVKQIASELHIGQSGYIYLMSPQGVHLYHPFLQGKKRGHLTHIQKQLSIDSGMSEYFHANPHEISRRAKVAYSMRLPSGNTLVATTYKEELMYLVDIEGLKDKLRKYAFGDSGYVYIIDLKGDLVLHPDYEHKSLQSLIGYSSQLLIDRIATKPEGHFSYSVSSDSGTSSKNVFYKFYPYLNWVISAGILEQELNRNHSLLFISLMALVVSLLCIIVVLVLYLRHRHLKILDVASLDYLTGLPSRRSFIEQLKLKIAQRSPNSLTNVGVILLDIDHFKRVNDQYGHAQGDRVICEVAKSLKRFVNRRRLIARYGGEEFILVTFDCDERELFELSEALRLCIQQLQGLVSPVTISAGCCHAQALTDIETAIDQADKALYQAKESGRNNTQMYRENEYRVAYM
->tr|A0A509DWZ7|A0A509DWZ7_9HYPH Uncharacterized protein OS=Thalassocella blandensis OX=2584524 GN=TDB9533_01798 PE=4 SV=1
-MQNKSSQATFENLTQFRTIRRKQMSGGTELPAMTPNEVTAKVVEDINFLRGRIDHIKKAKHANTNPSILKTYESMLESRETILAWLDENYHIQINQSAQVATASAKTSSN
->tr|A0A7C3D3X0|A0A7C3D3X0_9BACT Ubiquinone biosynthesis protein UbiB OS=Bacteroidetes bacterium OX=1898104 GN=ENK07_06575 PE=4 SV=1
-MAITSAPRKLKRTRQVMSTLARHGLGAFAAGARRWYTTVLPYRKARPGVEAIPVEVRVRIALEELGTTFIKLGQVLSMRPDLIPHSLAQELEKLQDKAAPLPFDVVEKELARALGPDFREQLGEIEPEPLASASIAQVHRATLPSGEIVVLKIRRPGIKRQVETDLAILHDLARMAERTVTELELIEPTRIVEEFARTIRREMDFIREARNVERFRRHFRNDSTIYVPQLYWKFCRENLLVMEWIDGIKVSDVEHLRKAGLDPKIIAIRGAQAILKQVFEHGFFHADPHGANVFVIKGNVIVPLDYGMMGSLDDRLVRQIEDLLIGIVRMDVDRIMTVLENLGSIRPGTDTRSLYSELYDFLDRYYHVPLYQLNTPELVGELLDIVRRYRLRLPPDLVLMIRSLMLAEAGGRRLYPEFDMMTLAKPYVKRIIMRRLSLKRRIKEAPDTLEEVETLVRLAPKQVQSILSKASQGELSVRVDPAGIPEILHELDRSSNRLAFAMICAALVIGSSITISAGFGPFLFGFPLLGVVGFGLAALLGFWLLFSIMRGGKL
->tr|A0A1Y0RNH2|A0A1Y0RNH2_9CYAN TonB_C domain-containing protein OS=Nostocales cyanobacterium HT-58-2 OX=1940762 GN=BZZ01_25955 PE=4 SV=1
-MSYVSLLKNIPEFLSQPTGIAAIASLGIHGAIALLLPIVPMASKPKQEQPSSKSSVGLVELSQAEQSRLPKPATPQLSLQPQAPVLPQVPPTNFANQSIPPLPPLPPPAASTELILPPLPKTDNLAVASLPKGQSLPILSKRDLQPDTSLRTKSRPFSPFVDRVKLGEPKPLESARIPDNIPPVQAANIPQEQDLVNTAAPMSSDQVATALPQGSTATQTTQPGDEVSQVARKQQLVTPVVQPPQARDSSIALGGQNLPQLPQGSNFTAPELPPLAAERSLSTPKTFAERFTEVKNQYPNLETKQPIAAIVDAKAGTEGNVEGDLVVNPQGQVESINFLDNSVASELKTSVREYFRQYFQSNPVQANGKPKFYPFNISFKLNSSNISKTPAQGLSTSSQVNQAQRSLVQRLRSVEVSSQPSKEPQKLNQVERLRSSSVNQQVSQTNQKTSAPQASQERQTSKQQVILRQTTSAPQTNKEEQTSRQQVVVRQSASSLQTNKEEQTSQQQVVVRQSTSAPQTNQEQTSQEEATNNQPSASIESSKKLLQQLRQIRDKRQTSNQEK
->tr|A0A3G1T1W8|A0A3G1T1W8_APPPP Immunodominant membrane protein OS=Apple proliferation phytoplasma OX=37692 GN=imp PE=4 SV=1
-MEANQQKKILIGVGSVVGALVLYLILAWSISFWPFSSQSKQEIFDDLSNKITFSTDLEETNTIFNKAATERKKQFKEGFIDNKVNKLVELANKLTTPKITDGDKKTSFDSASASLKEITDNQTLLLNHNDDFWKAETNKTTVQGEIKKIIDAYVQFKTQIKTALDLK
->tr|D4KZC5|D4KZC5_9FIRM Uncharacterized protein OS=Roseburia intestinalis XB6B4 OX=718255 GN=RO1_22070 PE=4 SV=1
-MGQSHNKSSFVLEKDRSAAKINHMEGMV
->tr|A0A261RL90|A0A261RL90_9BORD Uncharacterized protein OS=Bordetella genomosp. 9 OX=1416803 GN=CAL26_00210 PE=4 SV=1
-MFSWFKQGLGAYAPAPVGASRRDKILGALGALLGLSCTEWIARHALGEASPWFIAPMGASAVLAFAAPASPLAQPWSLMVGNVSAALVGVFFSHLIPAPGLAAACSVAAAIAVMFALRCLHPPSGAVALTAVLGGPSIAQLGYGYALYPVAVNSAVLLCIAVVFNGVLKRNYPHRHVQAAPAALNRAATPLGFTGADLDEALRSHDQLLDISREDLADIVLEAERRASLRRFGGLACGQVMLRDAVVVRDDEPLDAALRLLDRHRLAALPVVDGQGHLLGLLAHGDASARTVRLASAPGAPSRASLARDCMRSEVAYATPAMPAIELARPMASGIACVPVVDDARRLVGVIHASQLIDALYQLALASGDSAAGNPAARRALDVAA
->tr|U3PX63|U3PX63_POPTO Cytokinin dehydrogenase OS=Populus tomentosa OX=118781 PE=3 SV=1
-MAENPTITICLMAILFITRLASTLGKSKSWTGLLPPQIQTLDFARHLHVEPDAIKSVSSDYGIIVHENPAAVLYPSSIEDITSLIKFWYNNYTPFTVAARRHGHSVGGQAMASNGVVVDMTSLRNHKNGTGITVSKCPSLGFYADVGGELLWIDVLHSTMEHGFAPVSWTDCLYLSVGGTLSNAGISGTTFRYGPQISNVYEMDVVTGKGELVTYSSHTNSELFYAVLGGLGQFGIITRARIALEPAPNRVKWVRILYSDFSAFRRDQERLISINGRKQKNALAYLEGSLLMAQGPPNNWRSSFFPSSDIPKIMSLVTQHAIIYCLEVAKYYDDGTRHIVDQDLQQLLKGLSFVAGFMFEKDVSFVDFLNRVRSGEQKLHSQGLWDVPHPWLNLFLPKSRILEFNKGVFHDLVLKRNITTGVVLFYPMNRKKWDDKMSAVIPEEHIFYTVGFLHSSGFNDWQAYGHQNKDILKFCDTAGIEIKQYLPLYNSNKEWINHFGSKWRNFRERKAQFDPKMMLSPGQRIFNDI
->tr|A0A5B7BHJ3|A0A5B7BHJ3_DAVIN Uncharacterized protein (Fragment) OS=Davidia involucrata OX=16924 GN=Din_037375 PE=4 SV=1
-QRRTVFNSDGSSKSKLQIDGDAASEDVGFDKIYPVESFSSESEGEEMEENSSRSYLKEVEQSKKKAGLERRLSASSLDSAGNDSSTIKMSSNLHDKNEPLSKEIVFDESDDETGNDQDNIPWLKHHDSSSDKKSNLPINEFPKTRQYNAAADEKHLYSQHSDRDRKPASMRTRRVHRD
->tr|A0A327WVV0|A0A327WVV0_9BACT Outer membrane receptor for ferrienterochelin and colicin OS=Larkinella arboricola OX=643671 GN=LX87_02312 PE=4 SV=1
-MLVSIAAHAQAPVLFSGSVREITTQEPLQGVHVYVRDHRLGTVTNNAGYYTLALPARDSLTITFSSVGYQTVTRTISSHRPQPLDVYLIPGQTLNEVAIKAQAPLQKGSDLAQMSQIQLPIEQLNKIPALMGEKDVLRVLQLMPGVQKGSEGNAGVYVRGGGPDQNLITVDEAVVYNPSHLLGFFSVFNGDALKQVELTKGGFPARFGGRLSSVIEMSMKEGDRHDLHGTGSIGLIASRFTLEGPLQKGKSSFLLSARQCYLGALTQLLSPRPVSDLPSRSGFGDYNAKLSFDLGARDHVYVSGYTGSDQFRSQQTYDKQVLDAGLNWGNTTGTLRWTHRFSNRTSAHTALIFSQYRMRVVSEETVTAEAPGQPGAILRLEYLSSIRDLSLKQDWDLYAGSGHQLRFGFQITPHRFTPSAVVTAESQAASLSRTSDQAIQVVESGAYVEDFWQPTDRWRINAGLRLSYFWHKQTQYARPEPRLSVGYKLPGDWTLKGAYAQMNQYVHMLSNTGVGLPTDLWVPTTDRVKPQQSEQIALGVVKDINSDITLTVEGYHKTMKNNISYREGANFLVTDITATGDKARWEDNVTAGRGWSYGGEVMLQKKTGRLSGWIGYTLSWTQWQFAELNGGRRFFPRYDRRHDLSLVAVYELSKRINVSGTWVYGTGQALTVPLARYYASANNPEHTTTPAANPFIDTRNVKDYGEKNSFRAEPYHRMDVSLQFHTRRKSWENIWELSVYNAYNRRNPFYYSLEGKGGSEGIASKSVLYRYSLFPVIPTVSYRFTF
->tr|A0A364VAY8|A0A364VAY8_9CORY Coproporphyrinogen III oxidase OS=Corynebacterium heidelbergense OX=2055947 GN=hemG PE=3 SV=1
-MTPRVAVIGAGIAGVSAAWELRRQLGPEANIMLVEAYDRIGGKLKTVNFAGGPVDMGAEAFLAFRRDFVELVEQVGLGHQLRAPSTEYTSSLYCRGQLVDVPAATVMGIPARGEDVQAILPAEERRRIDEERGGEPMTWEPGQDAAVGQLVEARFGRAVVDRLVTPLLGGVYSCGADGLGVRSTIPQLAAALDRAGAGGAQFYLSDVVADLLAVRTAGGARRSGPVFQTLAGGFRSLLEQMVLQADPEILFNTAVESIGRSREGWYLEPIGTVDGVVLAAPAPTAALLLRDVADTAAGILSDIELSSSVVVGMRFASDHGIPERSGVLLGPDAPTEAKAFTFSSRKWPHIAEHGGAFVRASYGTYDQPWYVELPDRALINFAAEDLEAITGERKRPEEYFVQRWHGGLPRYGVGYAEALKVAMDSVAAVPTFALAGAMVDGVGVPATAASGIAAARRLAADLSPSPRP
->tr|A0A0N4SWJ4|A0A0N4SWJ4_BRUPA Uncharacterized protein OS=Brugia pahangi OX=6280 GN=BPAG_LOCUS6 PE=4 SV=1
-MTVRIKVENGFERITVDNNMYARQFRNTQHPVSGSIAVDGAAGEKNWSTGALRCIEARLTNQYCTSAAQRERRECRDASDARVEMRESC
->tr|A0A2D1UI31|A0A2D1UI31_9INFA Protein PB1-F2 OS=Influenza A virus (A/swine/Iowa/A02215363/2017(H1N2)) OX=2007353 GN=PB1-F2 PE=3 SV=1
-MEQEQDTPWTQSTEHTNIQKEGNGRQIQRLGHPSSIRLMDHYLKIMNQVDMHKQTVSWRPWLSLKNPTQGYLRIHALKQWKLSNKQGWIN
->tr|A0A7S3I079|A0A7S3I079_9SPIT Hypothetical protein (Fragment) OS=Favella ehrenbergii OX=182087 GN=FEHR0123_LOCUS5015 PE=4 SV=1
-MSIKCLAARQNKSAAINSYGELFMWGSSKNRSLMHASGNGHKDNLKLPTVFESETLLFTKVAVGNEHVAAITEDGRLFTMGTTEHGKLGHPPQELNEEEKQKERDRYKRAGYKPGGLDRSKPAFGFVEGELAGKKIVSVACGDKHTVCVTEDGAVYSWGNGRSGALGHSNTENSAEPKRVEGLSNIVRVDCGTDHTIALDSKGKLHSFGSNTYGQ
->tr|A0A1S1HUD1|A0A1S1HUD1_PROST Uncharacterized protein OS=Providencia stuartii OX=588 GN=A3Q29_01410 PE=3 SV=1
-MQFPPCPKCQSEYTYTDNDMYICPECAHEWNDAEPVVESDELIVKDANGNLLVDGDTVTVIKDLKVKGSSSMLKIGTRVKGIRLVEGDHNIDCKIDGFGQMKLKSEFVKKN
->tr|A0A369D4D8|A0A369D4D8_9BACI AsnC family transcriptional regulator OS=Bacillus sp. AG102 OX=2184001 GN=DEU45_10192 PE=4 SV=1
-MQLDRVDRKILNELYNDSRLSMRELAKRVNLSAPSTAERVRKLESEGVIQKYTIDIDYKKAGLVLDCILEITLKNGDTTRMQQFIQSYPSASFCYRVTGSLCYIVKISVPSLVELEEFINDVSSYATTVSHIVLSEVSLTPDIEHIFPED
->tr|A0A370DS84|A0A370DS84_9GAMM RNA polymerase sigma factor RpoS OS=endosymbiont of Escarpia spicata OX=2200908 GN=rpoS PE=3 SV=1
-MDEPNDANAAGEDSVSSDKPEVSPKPETAQKLKKPNARAAREPNDAQMDATRLYLNEIGISKLLTAEEEVYFSRLAQKGDQSARQRMIESNLRLVVKIARRYMNRGLALLDLIEEGNLGLIRAVEKFDPERGFRFSTYATWWIRQTIERAIMNQTRTIRLPIHVVKEINVYLRAARQLAQTLDHEPSSEEIADLLDRPIGEVKRMLGLNERVTSVDTPYGKDADKPLLDTIPDERASDPTVDIQNDGLNANLDRWLEKLNDKQREVVERRFGLHGYENSTLEQVANELGVTRERVRQIQMDALRRLRDILERDGFSVDTIFK
->tr|A0A2C5Z117|A0A2C5Z117_9HYPO Uncharacterized protein OS=Cordyceps sp. RAO-2017 OX=2004951 GN=CDD83_9509 PE=4 SV=1
-MKTDSLSPLFLLSVDASDGPRTTTCDRFVGCHRYDDCRQPTRRPTYANTIIIRTPPLPPAVMAGGRPTTPPTSIVPSPCVPRIMASLLPLISDTPSHGHARLGSGGDGRLAAARCCSSYRGRIRSHPACHRQSTRQNGRSWSVSPTETEMASF
->tr|A0A6J3K058|A0A6J3K058_9HYME zinc finger protein 271-like isoform X3 OS=Bombus vosnesenskii OX=207650 GN=LOC117231473 PE=4 SV=1
-MNSEQHALPATTQAQQEDVNAGQSGRPSYPGGLATTTSLGNVGSTPHSSADLRVSVYHHSHHNSSHRSSGGGEASSKEPASSLNQEMALTSSSHHQSTPTHHHHQPSVSSSSHHSSLQPNSQQIPVSLPGLNLDGAHIPASVSHLQAAHAQMQQMQAAQQQQLHQQQQQQPQQQQQQQQQQSHHQMQSHQNAQNSGPTAHNQNAQRDDNKVKDESGSCTTERCSDNQVHCQVQCDLQLQTSQDLQQSLMQQQQQQQQQIGVNISGNSSSEGGSQNNTEKPEKEKELRQLNMTQFQVPDLKPGGHMMDVRTADGSVVKISAGNEQDLAKTLGVEMVQNMYKVNVEDINQLLAYHEVFGKLQSEIAAGTTLVGSTVPTQTVTTIQNGTPIVQQVQLNKFDIKSSDGEATPGPSASPVSVGSHACEICGKIFQFRYQLIVHRRYHTERKPFTCQVCGKAFLNANDLTRHGKCHLGGSMFTCTVCFHVFANAPSLERHMKRHATDKPYNCTVCGKSFARKEHLDNHTRCHTGETPYRCQYCSKTFTRKEHMVNHVRKHTGETPHRCDICKKSFTRKEHFMNHVMWHTGETPHHCQACGKKYTRKEHLANHMRSHTNDTPFRCEICGKSFTRKEHFTNHIMWHTGETPHRCDFCSKTFTRKEHLLNHVRQHTGESPHRCGFCSKSFTRKEHLVNHIRQHTGETPFRCQYCPKAFTRKDHLVNHVRQHTGESPHKCQYCTKSFTRKEHLTNHVRQHTGESPHRCHFCSKSFTRKEHLTNHVRIHTGESPHRCEFCQRTFTRKEHLNNHLRQHTGDSSHCCNVCSKPFTRKEHLVNHMRCHTGERPFVCTECGKSFPLKGNLLFHMRSHNKGSNAERPYRCDLCPKDFMCKGHLVSHRRSHSDERPHSCPDCGKTFVEKGNMLRHLRKHAAEGPPTQVSTPSAIPQSGVLPIPAAAVLVGHPLAPPAPPVVPQHTVVVPTPPGVLTSY
->tr|A0A7V1JCS3|A0A7V1JCS3_9BACT Histidyl-tRNA synthetase (Fragment) OS=bacterium OX=1869227 GN=hisS PE=3 SV=1
-MNRPVQPPKGTRDFLPEEMLLRGKVIETLRECFALYGFIEIDSPVFEYFELLSRKCGSEIEKEIYTFDDKAKRKLGLRFEFTSPLGRYYAANRSRLVKPFKRYVIGKVYRYENTQAGRYREFYQADADIIGSYSMNVELELLNLAIFTLSKLGFGDYEIFINDRKILDGIVNAAGIGEDKKDTALRAVDKMAKIGEQGVIKEFAENGIAEDNYKSFMEFIELDKDLSDIGKLSALGGRINAAVKDEFIKNKALEGIEELLSILKNAEAIGLDFITYDPLLVRGLGYYTGPIFEIKSKDVSIGSFAAGGRYDNLVELYGARPEGACGISFGVERIIDIIKERDGKTLELQAFPVKLYVIYLSEDERSYAYKNAEALRLNGINTELCISNR
->tr|A0A0F0I472|A0A0F0I472_ASPPU Classical c SDR OS=Aspergillus parasiticus (strain ATCC 56775 / NRRL 5862 / SRRC 143 / SU-1) OX=1403190 GN=P875_00053022 PE=3 SV=1
-MTKITIPTTPPSRSLQGKTAIVTGAGCLGNGIGNGRAIAILLASDGCNVLCVDRNLEWAERTVDMIKAQAEDALVEGKSNYGHATAIQADVTIAADCESIVSTALTTFNRLDILVNNVGISGAAGTAVDVDMEAWAKSLEVNVSSMVLVSKYAIPAMMKNERDEYSGMCGSIVNLGSVAGLRGGTPHLLYPTSKGAVVQLTRAMAAHHASDGIRVNCVCPGMLFTPMMYGGGMSEEAREARRKRSLLQTEGNGWDCATAVVFLAGPHARWMTGVILPVDAGTTAAVGIGMPKSASVNG
->tr|M1EY39|M1EY39_9HYME Protein Wnt (Fragment) OS=Hypoponera sp. Mal1 OX=1157064 GN=Wg PE=3 SV=1
-LPAFRVVGDNLKDRFDGASRVMVSNSDRTRGNSNTITSNSASNSVHGHRDGPRRRHRYNFQLKPYNPEHKPPGPKDLVYLEPSPPFCEKNPKLGILGTHGRICNDTSIGVDGCDLMCCGRGYVREDVMVVERCNCI
->tr|A0A452QU07|A0A452QU07_URSAM Uncharacterized protein OS=Ursus americanus OX=9643 PE=4 SV=1
-AKQNKDKKDEIIKRKEAPPHEGLEIEEPSSLGLMVGGPDPDLLTCGQCQMNFPLGDILVFIEHKKKQCGGSLGACYDKGLDKGSPPPSSRSELRKVSEPVEIGIQVTPDEDDHLLSPTKGICPKQENIAEPPPRGLCSVQATVFASGPSSEPGRPRKGRGPWQPVFLRQDGTGTRVDEGSHPAGPAASWGQASVS
->tr|A0A4R6LBV2|A0A4R6LBV2_9FLAO Surfactin family lipopeptide synthetase A OS=Flavobacterium sp. P3160 OX=2512113 GN=EV143_10517 PE=4 SV=1
-MGYDLFTKLKKLNVTVKVTDGQLDIKAPKGVLDEELLIEIKTKKEDLINLIGKYTKDKANEKNQIPVAPKSEHYPLSSSQKRLWVLSQIDTANFSYNIPGLQVIEEVLNVNAFMLATQDLFNRHEILRTVFKSLDNEDVRQFVIAAEDFEFPFQQIDVDNDEVKLNEILAEVKNTIFDLEKGPLFKGVLVRVTDNKWVFSYNMHHIISDGWSMDIMINELLNNYILRRKDEFVSGLPLKIHYKDYAVWQQQRLADKEFDKEKNYWLTNLEGDLPTLAHFGDNPRPAIMTYNGSVVKRTIETLLIQRFKSFCQEQEGTLFMGCLSILNVLLHKYTEQEDFIIGSPVSGRTHKDLADQIGFYVNTVALRTQLEADNSFKEIFQQNKISTLNAIENQNYPFDELLDNLNVKRDLSRSPLFDVMISVQNENQLNQKADDLSYNEFLDRRVSKYDLTFTFVEKAASLTVELEYNMDIFSKETASTLLYHLENLLVEVLKNPSEEIKSINCLDSEEQFELLENFNNTEKQYPDTGSIVSFFREQVQKTPQNTALVYKDVSFTYLELDALSNQLSNYLEKQYLLDNEDFIAILLQKNEWQIIAILAILKAKCAYVPIASDYPESRIQFILEDTKCKLVITEEEIANFLNVQAEYSDVKTSSPLSPSHLAYVMYTSGSTGVPKGALIEHGGVIRLVKENNYVQLTGKEALLSTGSFSFDATTFEYWSMLLNGGKLVLCDENTLLSPHELSKIIKEEGITIMWFTVGLLNQIIDDNIELFEGLDTILAGGDKLSFTHIDRLQRSYPHLEIINGYGPTENTTFSLTHKIGILNNTNIPIGKPITNSTVYILDKNDNLVPKGVMGEICLGGAGLSRGYLNQPKLTREKFVSHIFKGNERLYKTGDLGRWLKDGTVEFLGRKDNQIKLRGYRIELGEIESVLSQHEAVNSSLVMVHQDNENEKVLVAYITVNTPVNISNLKQWLSERLPYYMVPNYLEVLDIFPLNVNGKVDRSKLPLPESINFDKREEYTEPATAFEKSLAKLWEEVLGISKVGLEDNFFDIGGHSLKATKLISKIHKEFQVKLKLKDLFVHASLQSQCKLIAEAQHSGYSKIPVLTKQNGYPLSLMQRRLWILSQHQAANIAYNMSGAYVFEGDLNVRILEEAFIQLIKRHEILRTSFKEDANREILQYVTEPENVSFTIKNIDLRGTEKLVLDKYLSEDLIAPFDLSSGKLFKANIYRISDNRWVFSNVIHHIISDGWSLGIIVNELLYLYNTLLTGGSVTLTPLNVQYKDYSSWQLKELSDSRLEFHKGYWINQFKGDLPVLDLSGGKQRPITKTYNGGVYNKIISAELSNKLAEFLKTEETTLFMGLLSAVNVLFYHYTKQEDITIGSPIAGRDHADLENQIGFYVNTLALRTIFLKNDTFKTVLAKVKEVVLGAHEHQLYPFDELVSSLNITRDMSRNPLFDVQVIVQNNQDTANTELKNLAVTAYQGELPQSSVFDLVFNFVESENGLATSIIYNSDVFDSERIEQFASHLEHLLAALLQDTELPIEEVKWLSEEEKQHLLSFNSKQMDYDQSKTVIEMVNDQVNKNPEAIAIAFEGTQITYLELHERSNQLAHFLLENYTIEPNDFVGIMMDRSELMFIGILGILKAGAAYVPIDPDYPVSRKEFILKDTNVKVLLTQSDYIFDLAYYQGEIFAMDLQMDTLTNSVTNSEINVLPEHLAYIIYTSGSTGNPKGVIVTHANLQHSLAPRNDVYVPIKCFLLLSSFAFDSSVAGIFSTLTNGGKLAITTNANIANVNFIADYIVAEKVSHLLTVPSYYKLLLMALQGKETALEEVTVAGETCPISLIEDHFKSKIGQSGCQLFNEYGPTECSVWSSVHKYEEGKPVTATIGKPIANTHIYILNDKEDLVPVGVIGELHIGGNGVTKGYLNNSELTNQKFVKDPFQKSGLMYKTGDLGRWNSEGEIEFLGRKDNQVKVRGYRIELNEVQYAIEQSGFIQSAVVLTKENKSGDNELYAYLVADEALNTSDLKNYLKDLLPGYAVPAHFITLSGFPATPNGKIDTKALLEIGDSDNRTGEDYVAPQTEEEIALVNIWQTVLDKEKIGVNDRFFDLGGDSIKVLKIVNGIYNEMRLEISISDVYTYANISKLADFIIHNKKSLDSRKAESTEARKDVVNYIDAIKNSVLESLDQNKSEAIEDLYPMSDIQKGMVYESLLYEGTSIYHDQIINQRQFVNFDISVFRLAMQLMVNKHEILRTGFNMHDYEQEVQIVYKNIEIPVVYQNLSHLDSLKEKEQVIGAFLQSELAKPFDLTSIPLFRMAAFNIGDDMIVFVSQCHHAIIDGWSDSMLLTELNNLYLNLLEDITFKPEKIKASYKNYVIEHEIDKKDTEIQSFWKEELQDSSKLNIFTNTPVSSIYGNILSENEVSELKLLASNSGTTVKEVSLSAYLYMLSILNADPDVVTGLVTNNRPSCEDGDKILGCFLNTIPLRFAINYEVTVKDFILEVQHKLIALKKYERLSLLQIASLSDNQQSNENPFFDVYFNYVDFYTYNKIKSEIKENSNPDKEEESVSLIGANKTNTFLDFNVNTTGDLYHASLSLTKILKSGLTVEQVNDLYFSILRSFIASPHQLLKSVDYLGAKEKHTLLHEFNDTKHEFPSETTLGELFIKQVKNTPDKIALVFQQKEFTFAELNEKSNQLAHYLKANYTLGANDLIAVALPRSEWMITAILAIHKIGGAYVPIDPKHPQDRIDYIVQDSASALIIDAKVLGEFQAVAENYSNENLTLINKPTDVAYVLYTSGSTGNPKGCILEHSGVVNRIQWMWEAFDYTNQDVILQKTTFTFDVSVWEIFMPLCWGTKMVLCSDEDVSIPQNIETLIKNHKVTCLHFVPSMLDVFIDSLFYEAYDFSNLSSLKQVITSGEALQLNTVKKWYEKLETPIQNLYGPTEASIDVTYYTTSKQDTVIPIGKPVWNTSIYILDANNNLVPIGCSGEIYLAGTGLARGYLNRPELTAEKFVANPFAPGEKMYKTGDIGKWTSDGNIIYAGRNDNQLKIRGFRIELGEIEQCLLEIETLDSATVLARKSASNEIDLVAYIVSNQELDVKGIKGTLKKKLPEYMVPNHFVKLETLPLTLNGKLDRKKLLAISTDSEGQTVEIVKPENDVEKKILQIWKEILSKEEISVTANFFEIGGHSLRAIKLQSMLKRKIGLDFSIKDIYNRPTIKRLASDKEKSNSLLIDLQINNRKNIIYFIPPLTGSSILYHPLAKVLSNEFDSVGFQYQGLEHGEEFSLSIKEMAKSFLDEIKNRQTHEPFIVLGYSMGAAIAFEIVRELEKYYSNIDLILVDRPTTVEADQLELQNMDHQANWLLAEYKKVIKLDEEQEKRTLAFLKNNLVLNNQYQLEGKISSNIYVFEATDNKYKGNMQNWQDYTNGDFKHHYLLGTHWDAVSEQNFESYRELFRSIYKKTSIETI
->tr|I4C7D0|I4C7D0_DESTA Uncharacterized protein OS=Desulfomonile tiedjei (strain ATCC 49306 / DSM 6799 / DCB-1) OX=706587 GN=Desti_2801 PE=4 SV=1
-MSGKCKMLGLVMLLGLGVTVHAWAVGYERLEVDATKTRTNVVSSNGPAASIAEKCPALLDEVAGVITDLLSQFGIINKKAP
->tr|M6VC02|M6VC02_9LEPT Acetylglutamate kinase OS=Leptospira noguchii OX=28182 GN=argB PE=3 SV=1
-MEKLLERVNHILEALPYITQYSGKTVVIKYGGAAMAKADLKESFAKDIVLLKYVGIHPVIVHGGGPEINRLLDNLKIPTEFVHGHRVTDTQTMEIVEMVLTGKVNKQIVSLINSQGGKAVGISGKDGNLAKATKAPVEIELEGKEKQLFDVGLVGKIESINPEILHNLQKEGFIPVISPVAENSEGESLNINADTFAGEIAGALKAEKLILLTDTQGILINQQLVTGLNRSKVKDYIRKGEISGGMIPKVECCLTAIDQGVRRTHIIDGRVAHSILIEIFTDQGIGSLIES
->tr|A0A7G5XKD1|A0A7G5XKD1_9BACT Copper chaperone OS=Lacibacter sp. S13-6-6 OX=2760713 GN=H4075_07020 PE=4 SV=1
-MELITFKTNISNERALQRVAPLLNNAVGSSNWQLDVSGAENKLMVYSPGSINEMQVIDAVHKAGFYAVNIEDFYAIF
->tr|A0A7X1L7W5|A0A7X1L7W5_9DELT Bifunctional protein PyrR OS=Desulfobacteraceae bacterium OX=2049433 GN=pyrR PE=3 SV=1
-MRKSEMVMDAKDIERTIIRMTHRILEVHKGAADLTLIGIQTRGVFLAKRIQDNIRAIEGTTVATGDMDITLYRDDWTRISHHPVVQATDILFSVDGKEIILVDDVLFTGRTTRAAMDAIMDFGRPDRIELAVLVDRGHRELPIQADYVGRFIETRRSEMINVGLRENDGEDKVLIEERQD
->tr|A0A3R6LV74|A0A3R6LV74_9CLOT TetR family transcriptional regulator OS=Clostridium sp. AF35-15 OX=2293013 GN=DWZ76_13300 PE=4 SV=1
-MEISGNTCSLLNYKLYLNNNGLPEEKSMQQGNTKERIVEAYIELESERPVEKITVTALVERSRITRKTFYYYFKDIYDLMEYRMEREMKRVMEETMSQTDPEKALTQLYMYIMENQKHIRALSESVQFMALRRQMGEKVYQYFYNHLERMGMFKNLTMSEAAMAVQIIIFSVMGVAFDAPFKNEADVKERVATFMSVIRKCTGCDPTRNR
->tr|A0A7C3N467|A0A7C3N467_9DELT Universal stress protein OS=Deltaproteobacteria bacterium OX=2026735 GN=ENV48_17320 PE=3 SV=1
-MYKKILVPLDGSQLAERALDPAEKLAQFFGSEIVLLQVIPFMPIYGAPELVTPLVVDEKHRESAERYLAALAEKLKAKGLQVSATVRTGQHVAGEILDFAKASAADLIVMNTHGRSGISRWFLGSVTLKVLSRSETPVLLIRSKP
->tr|A0A1I6UAS3|A0A1I6UAS3_9EURY GTPase, G3E family OS=Halostagnicola kamekurae OX=619731 GN=SAMN04488556_3691 PE=3 SV=1
-MVTSLSEIPITVISGPLGAGKTTLVNRLLNDPGERRIAVIVNDMGEVNVDAELIADETEEGVVDLSNGCICCRLQGDLVDQATRLAEERSFDYLAVEASGISEPIPIARALTDGTEADSLPDRFRLDTTVSVVDAYGFWKAFDSEESLPDAAPDPERPLTEVLVDQIEFCDVLLLNKCDMVPDDARESIEAAIRELQPRATLHRTTYSDVDPSAVLDTGSFDFEAARRQQGWKRALAGDTANEHPDHDHSDDAVSAAEAHGVESFVYRRDRPFHPERFDAWLDDWDGEIIRAKGFAWVASRPETVLGVSQAGPSVQAGPIGEWGDDDPVTRLVFIGSDLDEAAVTTELDDCLASFDERTDEYSTDPFPRKSN
->tr|A0A126S3A9|A0A126S3A9_PSEPU Heavy metal RND efflux outer membrane protein OS=Pseudomonas putida OX=303 GN=AWT69_001931 PE=3 SV=1
-MPIPRKIALLCLLLAGPAGAQGLSLDQALDAAFSQNPDFAAIGREIGIAEGERRQAGLIPNPELSWEVEDTRRDTSTTTVTLSQALELGGKRGARIEVAEAGQAIARLELERQRNSLRADVIQAFHAALRAQTALELAQQSQALTERGLRVVEGRVRAGQSSPVEATRAQVQLAQAEAAVRRARTERGVANQVLARLTGSAEARFDRLDASNLSPGPAPQAEPLLAKVEQTAEWRLAAAQIERGDASLGSEKAQRIPNLTVSLGSQYSREDRERVNVVGLSMPLPLFDRNQGNVLAAARRADQARDLRNAVELRLRSETRSALEQWGTAMGEVQAYDRTILPAAQQAVDTATRGFEMGKFAFLDVLDAQRTLIEARGLYLEALAQATDARAQVERIYGEL
->tr|A0A7L9UZJ5|A0A7L9UZJ5_BIFLN Response regulator transcription factor OS=Bifidobacterium longum subsp. longum OX=1679 GN=BL7055_06065 PE=4 SV=1
-MDNDPFALDAMCAMISAVSKDFRVMWSTGSPAVAIEHCHNPHTRPEVLVLDMALGGITGADVCRRIRRRTGGTGIVCVTSYSVDVYQREAIASGAQGLFAKERLRTDIAVAIR
->tr|A0A7W5LBF7|A0A7W5LBF7_9HYPH Diaminopimelate decarboxylase OS=Rhizobium sp. BK312 OX=2587080 GN=lysA PE=3 SV=1
-MNHFEYRDGILYAEDVPVPEIAKAVGTPFYVYSTATLERHYRVFAEAFDDVDAMVCYAMKANSNQAVLKTLGRLGAGVDVVSVGELRRALAAGIPASRIMFSGVGKTAQEMDAALEAGIYCFNVESEPELEVLNQRAVRAGKVAPVSFRINPDVDARTHAKISTGKKENKFGISWQRARAVYERAASLPGIKVTGIDMHIGSQITELQPFDDAFKLLRDLVETLRGDGHDIHHVDIGGGLGIPYRDDNNPPPLPDAYAEIVKNQLRGLNCKIVTEPGRLIVGNAGILVTEVIYVKDGGDKSFVIVDGAMNDLIRPTLYEAYHEIRPIAVGDVSTPRIKADVVGPVCETGDYLALDREMALPKPGDLLAVGSAGAYGAVQAGTYNSRLLVPEVLVKGNEFHVIRPRTTYEELIGLDSIPAWLEG
->tr|A0A2S0UY05|A0A2S0UY05_9GAMM dTDP-glucose 4,6-dehydratase OS=Colwellia sp. Arc7-D OX=2161872 GN=rfbB PE=3 SV=1
-MKKLLVTGGAGFIGANFVHYWMEKYSADKVVVLDALTYAGNIANLDSVKDEDNFTFVHGNICDQALIETLLVEHSIDTLVHFAAESHVDRSITGPDAFIETNIMGTYSLLKAAKKVWLDGESIVEGHRFHHVSTDEVYGTLSPTDPAFTEDTAYAPNSPYSASKAASDHLVRAYHHTYGLNVTTSNCSNNYGPFHFPEKLIPLVITNILHDKALPIYGDGQQIRDWLYVEDHAYGIDLVLQNGRVGENYNIGGDNEWANIDIVKTISKLVEQEFVKNKDLATRFPAAKAAMTQNTESLITYVKDRLGHDRRYAIDATKTNNELNYQPKESFETGIAKTVAWYLNNEAWWQSVMDGSYQNWIAEQYS
->tr|A0A7K9XDW7|A0A7K9XDW7_9GRUI KRBBB protein (Fragment) OS=Psophia crepitans OX=54359 GN=Klrb1b_1 PE=4 SV=1
-EDCVDRGAELVMPEDQDELGFLNEILQKPNRQFWTGLSVSPTGKGWTWLNGSRLDQSRFPLSPGDEGRRCGVLKGGRITSQNCSSEFQWICQKEATQL
->tr|A0A0R2NXL2|A0A0R2NXL2_9ARCH RNA-binding protein OS=Nitrosopumilus sp. BACL13 MAG-121220-bin23 OX=1655561 GN=ABR53_02015 PE=4 SV=1
-MKSNLISKSETASLLKKISDAWGIEFPKMKNVKVHQILSDAQIITGDGLKILKINEDYLPFLSETEILKKFPSVEVDMGAVKFMCKGANLMRPGIKKFTEFEKEKLVCIVEETHHKFLAIGKSMVSSSELENMEKGEIIQNLHYISDRFWETGKTIYN
->tr|A0A6I3FRK9|A0A6I3FRK9_9ACTN Uncharacterized protein OS=Actinobacteria bacterium OX=1883427 GN=F2575_05150 PE=4 SV=1
-MRLVHPLIWWLWALLLATFVIRADNILIAAAVACAVTLVVVKLKNDNYWSKSFALSIRLALLIIVVRMLIAITIGVPMPGQILFRIPSITLPSWMVGIRIGGDVTSQRLTSTFHEVIIIATVILLCGAANSLASPHRMIRSLPKAMYNLGVALSVATSVLPQIVKSIGRIQSAKRLRGQKTRGIRAWRGIALPLLEESLERALDLATAMEARGYGYHGKTTKYRAEPFTFIDLVMIASGVYLVLLSATLLSHFSVVVLALFSLVIVASPIAIVKR
->tr|D5EYN5|D5EYN5_PRER2 Uncharacterized protein OS=Prevotella ruminicola (strain ATCC 19189 / JCM 8958 / 23) OX=264731 GN=PRU_0725 PE=4 SV=1
-MGIVAVLAVVRAEFPQLAEPRIAESHVEVNADSVAAAMPHTDFSATATAKKHKIYSVPSFKACFPDTQSVQLAAAMKWGVKRVKNREDAEKRKSELVYVGANPYVHIDKLYSSIPYLVPRAAVLLQDVGQAFFDSLYVKGIALHRPIVTSVLRTEADVTKLRRHNGNATENSCHLYGTTFDICYNRYETVQDPDGPARRAVRNDSLKYVLCEVLRDMREQGRCYIKYEVKQGCFHMTVR
->tr|A0A0F8VXL6|A0A0F8VXL6_9ZZZZ Uncharacterized protein (Fragment) OS=marine sediment metagenome OX=412755 GN=LCGC14_3138660 PE=4 SV=1
-MYRGFRVLVDSALGTLAGAFATNSNRDRAGLLYDKNIAQHNGGVETGSNAYKNWDVLRGRVSANDDQVAVIGEGIVYEYTLGSTTWADASATARANDCFHIYFSCTAAQGASEIAKGGGDYGDTSGVKYIYEYSPWTALAATADIIVPNYYSLGAWANFRVPFPHNTYNTVSTIGDKFGNSTSPFEPATLDSNNFHLDHTGGTGFNQDNAEDFAPFTALELQGLIDYIVVSSGDGVALQADFKMRCTCYDTSDNVVVVDFTIPHRNNYFHVSLPLTQFKNYRARASRRWGDVISNLEPAELEIQEQFEWKNLCMISIQTQDSYDDQGRYFPEDGLFLK
->tr|A0A1C4Z724|A0A1C4Z724_9ACTN Potassium-transporting ATPase ATP-binding subunit OS=Micromonospora matsumotoense OX=121616 GN=kdpB PE=3 SV=1
-MREKAMTTSTPAPHGTADAATAGTPATQGNRGGGLLDPRQLLRALPDALRKLDPRTLWRNPVMLIVEIGAAFTTVLTVADPSVFALAITVWLWLTVIFANLAEAVAEGRGKAQAAALRRAKTDAVATRALDWSRGAAPGTYRTESVPAPQLRQGDVVVVEAGETIPGDGDVVEGIASVDESAITGESAPVIRESGGDRSAVTGGTKVLSDRIVVMITQKPGESFIDRMINLVEGANRQKTPNEIALNILLSALTIIFLLAVVTLQPLAIFSKNFQAAAPDSNAVTDGGVTGIVLVSLLVCLIPTTIGALLSAIGIAGMDRLVQRNVLAMSGRAVEAAGDVNTLLLDKTGTITLGNRQAAEFLPVDGLDAAGVADAAQLSSLADETPEGRSVVVLAKNEFGLREREPGLMPHATFVPFTAQTRMSGVDQGAQGGAGGARRIRKGAAAAVMKWVRDNGGHPTEQVGQIVDEISGLGGTPLVVAEHVDGQPARALGVIHLKDVVKAGMRERFDEMRAMGIRTVMITGDNPRTAKAIADEAGVDDFLAEATPEDKLALIRKEQEGGRLVAMTGDGTNDAPALAQADVGVAMNTGTSAAKEAGNMVDLDSDPTKLIEIVEIGKQLLITRGALTTFSISNDIAKYFAIIPAMFAGIYPGLDTLNVMRLSSPESAILAAVIFNALVIVALIPLALRGVRYRPGAASKLLSRNLLVYGLGGIVVPFVGIKLIDLLIQFIPGVS
->tr|A0A2V1NJD8|A0A2V1NJD8_9ACTN ABC transporter OS=Streptomyces sp. V2 OX=1424099 GN=DF268_33570 PE=4 SV=1
-MTSTTPHPDGALPRPAVQLTSVTRRYGPGVTALDDLSLTLPAGSFTAVMGPSGSGKSTLLQCAAGLDRPTSGSVRLDGTELTGLSERRLTLLRRAHIGFVFQSFNLLPSLTAAQNVALPLRLAGRRPSSARVREVLARVGLADRAGHRPGELSGGQQQRVALARALITRPRVLFGDEPTGALDSTTGREVLRLLRGMVDAESQTVVMVTHDPLAASYADRVLFLVDGRVHGELAGAGAETIAARMTGLTAAETPPGPRRTGPDPHGTADLHDTADPHGLRDPHDTGDPDSARPNPQGTPTARQETLPC
->tr|R8RZS5|R8RZS5_BACCE Methyltransferase OS=Bacillus cereus HuB4-4 OX=1053211 GN=IGM_02991 PE=4 SV=1
-MNELEYKSFYDKVGRLNGWDFSKIKCETVGDTWDFYSEVKERCKPSHILLDVGTGGGENVLNIASSAKLLIGIDNSNGMIATAHSNLKKSGVQNVEFLQMGSEALTFPHAHFDIASSCHAPFLASELAKVMKKGAFFLTQQVSENDKLNLKEAFGRGQCLGERDGTLKEKYMNELISAGFDLVQVREYDVTDYYSRSEDLIFLLKHTPIIPRFGEQEEDFTILQKFIDTYSFEKGIRTNSKRFMIIAVKP
->tr|Q8EYI3|Q8EYI3_LEPIN ABC transporter ATP-binding protein OS=Leptospira interrogans serogroup Icterohaemorrhagiae serovar Lai (strain 56601) OX=189518 GN=dppD PE=4 SV=1
-MIRIENLTISYYTKSGFGLKKSRIVAVDGVNLEIGKNEIIGLVGESGCGKSTLGRGLVKLLKPEFGSIYFEDKEITSLSSSEFFPFRKNIQIIFQDPYSSLNPRMTIAEILMEGLEIHEKTSREEAETKIKKILEKVNLSSDILSRFPHEFSGGQRQRIAIARALVLKPKFVICDESVSALDVSTGTQVLKLLVELKNEFGLSYLFISHDLGVVKSISDRIAVMYLGKIVELGNTKNIISSPAHPYTKALFQSTFDVYDRKKNRIPLKGEIPSIVNKPTGCHFHTRCPIARDLCKSEVPVWKEIRNGQKVLCHFPID
->tr|A0A5X0ZI55|A0A5X0ZI55_SALET Bifunctional glutamine synthetase adenylyltransferase/adenylyl-removing enzyme OS=Salmonella enterica subsp. enterica serovar Stanley OX=192953 GN=glnE PE=3 SV=1
-MTPLSSPLSQYWQTVVERLPEGFTETSLSVQAKSVLTFSDFALDSVIAHPEWLAELESASPQADEWRHYAGWLQEALAGVCDDASLMRELRFFRRRIMVRIAWAQTLSLVDDETILQQLSHLAETLIVGARDWLYAACCREWGTPCNPQGVPQPLLILGMGKLGGGELNFSSDIDLIFAWPEHGETRGGRRELDNAQFFTRLGQRLIKALDQPTMDGFVYRVDMRLRPFGDSGPLVLSFAALEDYYQEQGRDWERYAMVKARLMGDNDDAWSRELRAMLRPFVFRRYIDFSVIQSLRNMKGMIAREVRRRGLKDNIKLGAGGIREIEFIVQVFQLIRGGREPSLQSRSLLPTLDAIAALHLLPENDVAQLRVAYLFLRRLENLLQSINDEQTQTLPADDLNRARLAWGMKAENWPQLVGELTDHMANVRRVFNELIGDDEADTPQEEERSEPWREVWQDALQEDDSTPVLAHLADEDRRQVLTLIADFRKELDKRPIGPRGRQVLDQLMPHLLADVCSREDAAVTLSRITPLLAGIVTRTTYLELLSEFPGALKHLIMLCAASPMIASQLARYPLLLDELLDPGTLYQPTATDAYRDELRQYLLRVPEEDEEQQLEALRQFKQAQLLRVAAADIAGTLPVMKVSDHLTWLAEAMIDAVVQQAWTQMVARYGQPAHLDERQGRGFAVVGYGKLGGWELGYSSDLDLIFLHDCPMDVMTNGEREIDGRQFYLRLAQRIMHLFSTRTSSGILYEVDARLRPSGAAGMLVTSADAFADYQQHEAWTWEHQALVRARVVYGDPQLTSQFDAVRRTIMTTARDGKTLQTEVREMREKMRAHLGNKHRDRFDIKADEGGITDIEFIAQYLVLRYAHEKPKLTRWSDNVRILELLAQNGIMDEHEAQALTVAYTTLRDELHHLALQELPGHVAQTCFSKERALVQASWRKWLVAV
->tr|A0A846PBJ8|A0A846PBJ8_9BACT ATP-binding cassette domain-containing protein OS=Candidatus Latescibacteria bacterium OX=2053570 GN=GTO29_14730 PE=4 SV=1
-MNEPWIQLKNVHLSRGGRPVLKGVTADLAGRAIGLVGANGAGKSTLIGALLGVLKAESGMIHVLDLDLPRNAMQVRSRAGVMAEQAGVFPGGSGVDAVVFAAMLNGLSRRESLRKAHRALDALDVGEERYRPVRGYSTGMQQRCKLAMSLVHDPEILILDEPTVGLDPPGRTQLLNLIRDLRDEGRRILVSTHIMHDADFLCDELLLLEAGTVAFSGPIRDLIDTGVGVVVAAGEGLDAAFAETLGQRGYDIREQADEHITFEPNQDVELREFWQLAAERGAEVRALGRDLPSLESAVIRAMEHTDEQ
->tr|A0A7U8ZSQ3|A0A7U8ZSQ3_VIBCL Uncharacterized protein OS=Vibrio cholerae MAK 757 OX=412967 GN=A53_02263 PE=4 SV=1
-MRYLAVLMMGLLTFPAFALTRVNLYQAEVAVDPQQSNADAAARVRGMEEVIVRATGSQDALKNDAVQKALRQSNQYITQISTQQEGAQSVMRLQFSAQHIRSLLSQAQLPFWPESRSNLLVWLVEEANYDRSVSWEHADTPLLNQMKVRARIRGLPLTVPVGDFDDVTGVQVSDLWGGFINPISIASQRYPTDAVLVVRAQGSELRWTLFDQLANTMVSQPKAPISGQASGEQAVTEMIDEISDYYARKSAVVVSSESSQSVLAQFSPLDSAQDFFVVENKLKRLSSVASLDILKVQGTQVTFNVHLLASVEEFTNEVVRMGQAVLMEMPPEEPVSADNNLLENSSLENSASEMPVDPSNPNNAAAQPQPVQPKTLYFSWQG
->tr|A0A7W0QRE7|A0A7W0QRE7_9CHLR D-aminoacyl-tRNA deacylase OS=Chloroflexia bacterium OX=2448782 GN=dtd PE=3 SV=1
-MRVLVQRVREARVTVDDVEAGAIGPGLLLFVGIAATDGDGELRAMADKIANLRVFEDDAGRMNRSVLDLVAGGDPVGALVISQFTLYGDVRKGRRPGFTRAAAPEEAAPMIEAFAVCLANPGLVVERGVFGAHMMVSLTNDGPVTIWIDSDDLRQPRRGETSSAI
->tr|A0A7L4YJJ8|A0A7L4YJJ8_9ACTN Uncharacterized protein OS=Epidermidibacterium keratini OX=1891644 GN=EK0264_02370 PE=4 SV=1
-MEQTLINDGLPFLGSALPADLAGVELRRAITEHRVLRMMRNTFRDARVPDSREVRVAAIALHAPKDAIVADDTVAWLQGVDTNDPRDRFSFSPSLIVPNHACRPQHPGVRVREGTIDDCDVVEEGGLRLQTNLRATADMLRLKWRPNALATADAMCRHNLIDKGELAEFIRPLRRLPGIPQARALVRLVDPRSMSWGESVLKLRLVDAGFPMPALQHEVNDPRIGVRYLDCAYVAPRVGVEYDGKEFHTAESDREHDAERRELLSDILGWRWEIARRDDLIGTNDALEWRVGEKLGLTPRPRSW
->tr|A0A0P1FSG2|A0A0P1FSG2_9RHOB Uncharacterized protein OS=Thalassobacter stenotrophicus OX=266809 GN=THS5294_03520 PE=4 SV=1
-MRLLGAFSLVLGLLVAPEVAPAQGTSVVTGTGTGAVLRTLDKVTGAVFDVEVASGQTMGYGTLEITLSECRYPASNPAGDAFAHLTVMDGSKRQDIFQGWMIASSPALMALDHARYDVWVLRCITS
->tr|A0A1C4RDB8|A0A1C4RDB8_9ACTN Uncharacterized protein OS=Streptomyces sp. DvalAA-14 OX=1839759 GN=GA0115240_152365 PE=4 SV=1
-MPTAPRTIDELQQALMANQQLPYGRTRTVGAEELVDAAEQFAEPIALVRTLLELQSAYVYGSEPRKSPVVFARLLALFDEQPDLFDERLRHELFWRFKWVANALRQLPEMPLASIQQWLTEMRTRYEKAGLGLQPYYGQAFQLAAHVGQDIAPAYELWAARTRTPLSDCEACEICDRALYHLRGGDDERALESWEPVLTGTASCQEEPARSISYALLPLLRTGRTDRARELHLAGYRACRHRPSMSGEVGRHLEFCALTGNEARGLELLAENRGLFDEVESPHANFDFLTGVEVLLQRVGLLGHGELPAAGYAGRVWSVAELRAEVRARADDLAARFDARNGTTAHTDRRRARLDRAPLLDALELTLRSRTLDVVAQAAPADAAAGAPVSAPAGAPVPRTPAAVSDSLPELILQARDLDERAHPDANACWARLRALVAAPDYTHPDDPAVGSFVRLRADLLADEASRVHEKEEYAVAAALFTQAGDLYDEAGEPGHAAFARGYALLAEAEQVTEPVKPPEPAEPADAAEAADAAEAAGPAEAGQPAAPAEPAERAAGADGANGAEKAEKAEKAEKAEKADRTGPAAAVEARVAALTGVHAAAVRLQEDTPGLAPYQEARLLRLRATALGLRLQASGNEEHAAPVLAEADLLREFATRHGVVTQISGARFLRATTWAIRGDLPAAHTEVDGLLDELKERGPAWHLPRALGLRARLRLGLGEAQGAHDDLTEALRLAADWPAEAVHTSRLQGDLAEVCMHLGRPDEALRHLTRSAELELRADQRAEAFTTYGNAAALSLDLGRVEDSIALLDSLLAEPDAVAGELNDRLLAQLRLTRARALHAGEDLKAATAEFVALAAESAGWDDDPGSHAMIAAETAVLLGEAGEFGPARQAAEQALAAHARAPRYEQLSNALRELARLQAEQQGPDGLTDALAFLADAGRIADEARAAGFEARGRSLDTALAYEHGRVNAYAGAYEDALAALDKALDLIGEPAPEDDRVEEWAESVRLAGVVEGLYLKRTAPALARLDAAIARLTSLGHPKEATPLTSLAARLRDDK
->tr|F7Y857|F7Y857_MESOW SnoaL-like domain-containing protein OS=Mesorhizobium opportunistum (strain LMG 24607 / HAMBI 3007 / WSM2075) OX=536019 GN=Mesop_3059 PE=4 SV=1
-MNKNYEAIKAHYAGSDAMDLAAMMAPITGRTAWTEMAGFPYAGTYVGPDAIIAGVFKRIGEEWDGYNLKLEKLVDGGTTIVGIGTYSGTYKKTGKPMSARVVHVWEMEDGKVLSFEQFTDTRLVAAATA
->tr|A0A2V6GK08|A0A2V6GK08_9BACT Aminopeptidase OS=Verrucomicrobia bacterium OX=2026799 GN=DMF43_07280 PE=3 SV=1
-MHDIRFDNLAKLLVEYSIRLGRNEAVLIEAFDIPDEMTIALIQAARKAGGVPFAQIYHTRVNRALAFEASDRQLNLLASHELARMKKMDAYIAVRGSNNITELSDVPAEKMKLLNKKMRPVQDQRVKKTKWVVLRWPTPSMAQLAGMSTEAFEDFYFEVCTLDYRKLQPGMKALKGLMEKTDRVEIKGPGIDLRFSIKAIPAVICGGDRNIPDGEVFSCPVKDSVEGHVTFNAPSIYQGIGFDGIRLEFKNGKIIDATSNETKKLNKILDSDPGARYIGEFSLGFNPRVLQPMRDILFDEKIAGSFHLTPGQAYEEADNGNRSQVHWDMVSIQRPEYGGGEIYFDGKLIRRDGEFLPKQLHSLNRSRTR
->tr|A0A0F9KX35|A0A0F9KX35_9ZZZZ Uncharacterized protein OS=marine sediment metagenome OX=412755 GN=LCGC14_1274400 PE=4 SV=1
-MKPKNYKYLDGSGNQYNIQDDMRKTLEYVPVKPESSSSGIYDGGKYVKTEITIDQFNKIVSLLNSAIRKSEIHIKDRVKMSGMIIVEEEGNRNAYILDPYSEEKFSIETKLREIFEI
->tr|A0A1L9MTS9|A0A1L9MTS9_ASPTC FSH1 domain-containing protein OS=Aspergillus tubingensis (strain CBS 134.48) OX=767770 GN=ASPTUDRAFT_130501 PE=4 SV=1
-MRFLCLHGAGTNAEIFEIQSGGISYDLAKYGHTFKYYDGCMEAEVEPRTSPRPPHLKIRKLKGLFTGPFYNHYPRDRAPGEYLAPAMKHVYDIIEREGPFDAVMGFSQGAALACAMIVHHAKTHQEPLFKVAVFICGAAPFDSTGNEVIPDTSAEGEYPVKIPTANIVGKQDELYPSSMHLSRLCEPSKMSFHDHGSKHMVPFDVENTNAMVAAIEATVQKALRGE
->tr|A0A2V3TT51|A0A2V3TT51_9HYPH Flavin reductase (DIM6/NTAB) family NADH-FMN oxidoreductase RutF OS=Chelatococcus asaccharovorans OX=28210 GN=C7450_11941 PE=4 SV=1
-MADKTRLIVEGGDPAADPKAFRRALGSFPTGVSIITTPGLDAPAGVTANSFASVSLDPPLVLWSIAHTSRSHAAFRQSAHFAINILADDQVGVSQAFASASYDKFSLVDWHRGGTGSPLIDNALAYFDCVCEARHEGGDHTIMIGRVIEFGRSEGSPLAFSQGRYGITLDHPEVAAKARDRKFEEPGLDELPFLSLIAKAHYKEDADLEERRSAARYTQVGSKVLAGLYQSAPLTADELARRMYLDRREVDDSLNEFLADGHVAIFDGHRFALTESGKQRRRQMIEYLSRYQDEQLADINPADLIVATRVLKAFLTGPHQGKPDLHI
->tr|A0A532EZD0|A0A532EZD0_9BACT LPS export ABC transporter ATP-binding protein OS=Nitrospira sp. OX=70125 GN=lptB PE=4 SV=1
-MTQSIHAESEALVGPIAVQQGHCLRATGLVKSFRGRKVVKGVAVEVYAGEVVGLLGPNGAGKTTIFDMMVGLCQPDEGEITFIGESVTNLPMYKRARRGIGYLPQESSVFRRLSVEHNVLAILEMLGYARKERSQRVDALLKELDLIHIRKSMAYALSGGERRRLEITRALAATPSFMLLDEPFAGIDPIAVADIQQIITRLKEKGIGILITDHNVQETLSIVDRAYIINEGLILEAGSPEAIVQSPTARAVYLGEQFKL
->tr|Q08U50|Q08U50_STIAD Putative surface protein OS=Stigmatella aurantiaca (strain DW4/3-1) OX=378806 GN=STIAU_1615 PE=4 SV=1
-MNPAVPAQYTLTYNVTDSAANVAAPVNRTVTVQDTQGPTLVLNGPATAGLECGTPFNDPGATANDLCEGDLSGAVVRTGTLNQGAVGNYTLTYNVADQGGHTAAPVSRTVAVSDTLAPVVTINGPASLAVECGDNGFQDPGAMAEDACAGTLPATPSTEVDPAVPGVVAITYSATDPSGNTGVGNTGRTVTVEDTLPPTLALLGPANQPLECGTPYNDPGATADDQCAGDLTGSIQRTGSINNKQLGAQMVSYTVQDPGGRTAGPVSRTVTVDDSLAPAIAVNGPLDQVFECGSTYVDPGATANDLCATI
->tr|A0A1X0UNC0|A0A1X0UNC0_9NOCA Putative fluoride ion transporter CrcB OS=Rhodococcus sp. 1163 OX=1905289 GN=crcB PE=3 SV=1
-MIAPARPLHLRPRALALVFAGGVIGTAMRYGIEIAIPQVIQGWPVATFSINLLGAFVLGVLLENMARRGADAGVRQQIRLLAGTGFCGAFTTYSTFALEAVLLTRDGHLPIALAYGVSTVFLGALAAWAGIVVGASMHVDRSAR
->tr|A0A3N2GU17|A0A3N2GU17_9PSEU Uncharacterized protein OS=Amycolatopsis thermoflava OX=84480 GN=EDD35_2465 PE=4 SV=1
-MDPRDRADALLARAQSRGAFVVTPDAATSPMDASTTQQIPRNVVKEIDNDDPDTTAVVPSSVIESVQGSLAASKPDTHVNMTPVQPEEEVDGLVPTTKTQTGNSDFARRLEGL
->tr|A0A3P9I8G7|A0A3P9I8G7_ORYLA One cut domain family member OS=Oryzias latipes OX=8090 PE=3 SV=1
-MELTMENLHSVSAHSQAGDLMSSPHARPSQSPSSTPRNLVSHAPSARSAMVSGMASLLEGSGGDYRTDPSGLSGHLHPSISMCETGMSLSNTYTTLTPLQHLPPISTVADKFHHPHSHHHAAAHQRLSAGNVSGSFTLMRDDHRGLTSMSNLYSHYPKEMSGMGHGSLSPLSSGLGSLHNSQQSLSAYGHSAHLSDAKMISPVPGFESHASMLSRSDQEHLARSLGGHGHGMISNLNGMHHHPHSHLHSQANGAVMLGDRERHGHGASQGVSGSNIQAEEINTKEVAQRITAELKRYSIPQAIFAQRILSRSQGTLSDLLRNPKPWSKLKSGRETFRRMWKWLQEPEFQRMSALRLAACKRKEEDRGRERSQVPKKQRLVFTDLQRRTLVAIFRENRRPSKEMQLTISQQLGLELSTVSNFFMNSRRRCPDRWDTEEHGVHGHGPSGNSSASPIQPGISSANTFSKA
->tr|A0A3Q0S8Y1|A0A3Q0S8Y1_AMPCI Translocase of outer mitochondrial membrane 40 homolog (yeast) OS=Amphilophus citrinellus OX=61819 PE=3 SV=1
-MGSVLAAASPSPAPAAAGSGQGVPGLVSVPPGFTMPSVSSVPPASGSDQQTADAQSSLSNPGTYEECHRKCKEVFPLQMEGVRLLVNKGLSNHFQVSHTVTLSTLGDSGYRFGATYVGSKQTGPAESFPVLVGDMDNTGSLNAQVIHQLTTAVRSKIAIQTQQHKFVNWQCDVEYRGEDFTSAVTFGNPDILVGSGILVAHYLQSITPALTLGGELVYHRRPGEEGTVTSLLGRYTGENYVATLTLGGAGAHATYYHKANDQLQVGVEFEASTRMQDTTTSFGYQLDLPKANLLFKGTVDSNWVVGATLEKKLVPLPLTLALGAFLNHRKNKFQCGFGVTIG
->tr|A0A7K3UVX5|A0A7K3UVX5_RHILE DUF21 domain-containing protein OS=Rhizobium leguminosarum OX=384 GN=GR236_14365 PE=3 SV=1
-MAIEGALAFLETYWPEILSITALVLMSAFFSGSETALTAVSRSRIHTLEANGDERAGLVRQLIERRDRLIGALLIGNNLANILSSSIATSLFLGLFGNSGVALATLAMTVILVIFAEVLPKSWAISTPDRFALAIAVPAKLFVTVVGPVSTFVNAIVRQILSLFGINLSRETSMLTAHEELRGAVDLLHREGSVVKADRDRLGGVLDLSELELSDIMVHRTAMRAINADDPPEAVVRAILESPYTRMPLWRGTIDNIIGVVHAKDLLRALAEPNMEPQNLDIVKIAQKPWFVPDSTNLEDQLNAFLRRKQHFAVVVDEYGEVQGIVTLEDILEEIVGDISDEHDIEIQGVRQEADGSVVVDGGVPIRDLNRALDWNLPDEEATTIAGLVIHESMTIPEERQAFTFYGKRFVVMKREKNRITKLRIRPAGEDGAKPA
->tr|A0A6J5FC43|A0A6J5FC43_9BURK GAF domain-containing protein OS=Paraburkholderia humisilvae OX=627669 GN=LMG29542_08208 PE=4 SV=1
-MIGDPILAMTTSAENQLYALDEIALTLAQPCQRTAVYHTVEDVMQRLIGHRLFTLLAVLPGGHRVQRFWSSNETVYPPSGRKCLDSTPWGEVVLKNKKAWLGRNAADIRWAFADHALIASLGLGSVINVPIVVRGQLLGTMNLLHRENHFTVDDVTIAARVAPYLIPAFIEEVKTIEVS
->tr|A0A7C4RW34|A0A7C4RW34_9BACT Adenosylcobinamide kinase OS=Fervidobacterium thailandense OX=1008305 GN=cobU PE=3 SV=1
-MILITGGVKSGKSTFALLMALRYKKRAFLATGVPFDDEMMERIRKHKEERKNLFDTYEEPVDIATILQKIDRHYDVIVLECLTTYLGNLLHYNEDVESRFNILVDVVKTMVSQLIIVTNEVGWGIIPENNLARRYVEILGRWNNELAKIAQEVYLVISGIGVRIK
->tr|A0A221MBY2|A0A221MBY2_9BACI Cysteine desulfurase OS=Virgibacillus necropolis OX=163877 GN=CFK40_08985 PE=3 SV=1
-MNQIYLDHAATTPMATEVIDAMVPVYSEVFGNPSSVHAFGRKARHVLDQARRVFAKSIHADEKEIVLTSGGTEADNLALIGTALANKQKGNHIITTVQEHHAVLHAAEHLEGNGFEVTYLPVYEDGKIAVQDLRNALTDKTIVVSIMTVNNETGIIQPIHEVGELLNDHQAYFHTDAVQAYSLLTIDVKKDYIDLLTVSSHKVNGPKGIGFLYINKSVQVNPLQFGGEQERKQRPGTENVVSVVGFQHAVQLLIEQKEKRRETYTSYKKLFLETLEQAGVNFEINGEQSDAVPSIINISFPGTNVESLLTNFDLSGIAASSGSACTAGSVEPSHVLSKMYGANNDRTTNSIRFSFGLHNKKEDSIEAAERIASIVKRLISLQ
->tr|A0A841Y9U4|A0A841Y9U4_9LIST Alpha/beta hydrolase OS=Listeria booriae OX=1552123 GN=HB847_15185 PE=4 SV=1
-MKKCVTFIALLIFLLAGCSTDKTTEQDMKNLPNLSAQTALILVHGTGGSTDTFDGFSDVFIDDYHTSNERIKLHIGTDGALTYHGIFSKKALHPIVQIGFADSIDASITQQAVWLRLAMEDLQKKYKFAAFDGVGHSNGGLVLSTYAQKYAKTAPTLERLVAIGSPYNDLDQDDNKGDLAFTDVPKATPLLQKYEKNRSKINPDLLVLSIASNIDDGSFSDDIVPVLSAFSSRLIFKNEAKTYLESYYKGEEYDHRTLFANPDIQKKIAWFLYEYPGDKKEISLAKN
->tr|T0PB79|T0PB79_AERSA ABC-type transport system periplasmic substrate-binding protein OS=Aeromonas salmonicida subsp. pectinolytica 34mel OX=1324960 GN=Asalp_31750 PE=3 SV=1
-MIKKLILSTLLLCGLANAAAPASTLDAVLDRGVLRVGFDAGYQPFEMTNKQGQYIGFDVDLAKMVAKEMGVKVEFVNTAWDGIIPALLTDKFDVIMGGMTVTPQRNLRVNFADPYIVVGQTIVLRKDKAGEIKSFSDLNDPKYKIAVKLGTTGEQAVKRLIPKATLLQFETQDDAKLEVINGKVDAFVYDLPYNAIFASQNTGAVVHLDKPFTFEPLAWAIRKGDQDTLNWFNNYLRQIKGDGSYDRLYKKWFESNAWLNQLK
->tr|A0A6C2U970|A0A6C2U970_9BACT Uncharacterized protein OS=Pontiella desulfatans OX=2750659 GN=PDESU_04858 PE=4 SV=1
-MDIKRWISLVAVMAVAGTVQAADPLVYEGFEYDTTTGGIESASLGGGVGLSGAWGSSDAAGSFFNVTSGSFSLGSLTVSSNKLKRTNTGGVEAIERTISASLPSEFWFSVLHETSATTQFGIGGGAFGDGSSGNGNMATGPGFGFTHKGGNLGAAVWPAGSAVSVSVGGTVAKSDNNVLLLVGHVKRNVGGNDTVDLYEVDATLVLPGAPLSTVSQPTAAGSLNTLTISSNRGPGIDEIRVGATYNDVVPASAAFTFNLTPDDTQDLLADYPAVVVSNSILTEYANSSSGVEITALNVMSVSNAITAITATPFTLSTPSPAITALDFAFDASAIKAITSATEAFTTTGTVDIVYKNLDDNVLQTNTVALKGTFSNPPFQFSSDSSLGLTLVAPATLVSNDIAVSYVEGRPGYTNVVISEVNILDEQHPGAFSANNPGAIQTTDVITVTFDDSFVGLGNKQSSTCTVEVVYGEAGSSIDYTNTVSVAAFNYDLSTGSVIQQVFGNAVNLNGPLGGGTLPMNNFEAFTNNWNHNGNFTQETSAGSITLSSSGNTRSAYNLVEANTAGSDNFGAQDTHILTNGLYRYEFDYEVLNTDGANVIWSFNAYGLIDQQLFSTSSNPDKVVLDIATGASGGVDVDIQNDGNGYYSEHGDGILAGTGDVARTTGYVYLNVKDNQDALFVMHRSGKCDVRLYDLVLTRVGDYELPVNSTNAVLAAQFEDSAVTNSIVVVGATETNTNGVNNTWRGTGLSHVDRKLKSNAADTAVRATGTIIHRNTAGYDDVGLQDTIALTEGTYELSLDVQVDGTFPSNDSIARVEFWALDQDTSGTNNYVKWDHAPGTGEYLKTNGNAKVTLLGSKTYTNTVTETLVLSDLNVQADQDVAIVFYHRYGPDFFIDNVELLRTGDLPLEGYSLWAEDNGLTAGVNDGLEDDAENGGLGDGLNNLMEYALGGDPLVDDAATVSPQTSEAGGFFYHVYNERTDDPSLTFIVDLNGNLTIPGGWGSAGLEAEERGLDDGEFQSVTNSTDMLEAAEFIRLQVEKD
->tr|A0A2P9ADD5|A0A2P9ADD5_9HYPH Uncharacterized protein OS=Mesorhizobium delmotii OX=1631247 GN=BQ8482_111084 PE=4 SV=1
-MHRFCRAGKAAGVDDRDEGLQLIEIEWRFHRSHPSLVLMLKIRNIRWINQSNDGKFTTVHMTACESGPERPLFPAPIARLRPFEYEGD
->tr|A0A3G3A397|A0A3G3A397_9HYME Cytochrome c oxidase subunit 1 (Fragment) OS=Ceraphronidae sp. BIOUG12096-H04 OX=2463984 GN=COI PE=3 SV=1
-FLMIFFLVMPIMLGGFGNWLTPIMIGAPDLAFPRMNNMSMWLLPPSLMMLLMSMMTNTGVGAGWTLYPPLTLTPYHDGMSMDLTIYSLHIAGISSIMGSINFLVTIYKMKPSHQTLTSLPLFCWSIMITSLLLLLSLPVLAGAVTMLLTDRNLNTSFF
->tr|A0A7C1QH02|A0A7C1QH02_PSEAS AraC family transcriptional regulator OS=Pseudoalteromonas sp. OX=53249 GN=ENH79_16645 PE=4 SV=1
-MDVLSSVLSHFSLNANVFFSGNMCGTSDFSDDQGVGHLHLLRSGTLKVRSNSGFEVVLSTPSVIFFPHSTGHCLFSDKSDGADLVCAQISYQSGGHSPLLQALPFCLNYELTGNGLLEQSAFWIFEEAFKDASGKDLIIDRLCDVFLISVLRKVLKEGTIKSGMMAGLAHPQLAKVLIKIHQTPEQSWSLSAMAEECCMSRSKFADTFKRVIEQTPADYLADWRLSVAKKLILKNQNMDLVANQVGYENGSALARVFRKKTGQAPKEWLLSQQ
->tr|A0A511X4K5|A0A511X4K5_9BACI Uncharacterized protein OS=Halolactibacillus alkaliphilus OX=442899 GN=HAL01_23460 PE=4 SV=1
-MELMLEQFMSLNLLNQFWITLFLIIPMVLIARTVVAGTRYSPILIIVIFGLSMGYILVETGVAEPGIGAFPMVNMVASATIIALVVSFFVGGQELRKIFSNKPLTNEEMVIPSQEEAVLGTTRTQIVMIIRSFFLLIGIESSSRVLIGGSTSALSNVYPLIAYIGIVGAIIFIDNRATITNKSLYIRKGIIEIIAIIGILYLSSLIAGGIESLIALPQIFFAMIISAALGALLYRWSFGPTIKALLFAGIPVVLAGNFMVGGSRIGEAFTIDGVNSLILYGFFGQLFFMFGGISLIMYFAKNNHVRNLAPGMAGALSHSGLTGACTAGDLGKEAAQRAPIMINIPFFGHIFVFSVLAISAERGELWTLPSIAIVAIGVLFTIISLKQLKKANNESNKEVKALMQFSFGWQLVAVFGGLLLLSFSQIPFLFTGMAQASAISHFGLFAAVQGGMFGAESASLIPFIFSMPFLVHPVVFFMFGKAMKDDGLMPVKTVHAISFIGLIGVVVSLFIV
->tr|A0A7Z9M5B3|A0A7Z9M5B3_9CHLR Alpha/beta hydrolase OS=Dehalococcoidia bacterium OX=2026734 GN=EYN92_08525 PE=4 SV=1
-MPFYERGPVSIFYEEVGSGFPLMIIPGGGLNSSIASLDTSVPFNPMNTYKNDFRCIAADLRNADSGQSSGPLEIDRPWDAYSDDQLGLMDHLGIQEFLVMGFCIGGPMIHNLLRLAPGRIPAAALMQPSGFTSEHPDIFYQTNTERWGPPLCEMAPDITMDKVHDFLTNMYTNRADFVFTVSRDFVRSLQTPLLIAPDNIPAHPYETAMEVAELAPNAETTIFPWKDTPKNIDEAVKHARRFLKKHEPDISP
->tr|A0A7X7DHL1|A0A7X7DHL1_9BACT Uncharacterized protein OS=Lentisphaerae bacterium OX=1932692 GN=GX634_11015 PE=4 SV=1
-MNPFPARTRPVRLAMVPLMVLFLGSAIRVGAWESLTFDLPSGGRESLWRDELARHWHGQTEKRIEGGRIDVLTGEYAIEVEFPHKWHEGLGQALHYANATDRQGVLAIIAYARGEAYLHGKSRRRLELIEEQCSANNIKMLVLFPNRPEEFIRHVAPIWIE
->tr|A0A807R958|A0A807R958_PSEME 23S rRNA pseudouridylate synthase OS=Pseudomonas mendocina OX=300 GN=PSMEN_15330 PE=4 SV=1
-MTTPASPTSGVQLIEVAPDFAGQRIDNFLRTQLKGVPKTLIYRILRKGEVRVNKGRIKPEYKLQAGDIVRVPPLRLAERDEPEPVAQGLLERLEAAIVYEDKALIVLNKPAGIAVHGGSGLNYGVIEAFRQLRPDAKDLELVHRLDRDTSGLLMIAKKRSMLRHLHEALRGDGVDKRYMALVRGHWATAKKQVNAPLQKSNLRSGERMVEVDGEGKEALTLFRVLRRFGDFATLVEAKPVTGRTHQIRVHAKHAGHCIAGDSKYGDDDFTREIRELGGKRLFLHAYELHVPLPEGGVLKLEAPVDEMWAKTLERLSA
->tr|A0A2T6KQJ4|A0A2T6KQJ4_9RHOB DNA repair protein RecN OS=Yoonia sediminilitoris OX=1286148 GN=C8N45_101426 PE=3 SV=1
-MLRGLDIRDMLIIDRLELTFQPGLNVLTGETGAGKSILLDCLGFVLGWRGRAELVRQGAEQGEVTAWFDLPAGHAAFAVLADAGISAEDELILRRVNTKDGRKTAWINDRRVSGEVLRALSETLVELHGQHDDRGLLNARGHRQMLDTYAQLDDDIAEVRSAWRSLSRARKRLSEAEALVAEAKAEEDFLRHAVAELDKIAPEPGEEATLDTQRRLMQAAERIIQDIAKAGEALGLNGAEGMVSDASRWLVGVADKAEGQLDPTLAALEQVMASLDEAQQGVSACLDALSFNPHELEEVEERLFAIRGLARKHGVLADDLSDFADGLRARLAVLDDSAADLAALQASVDESAADFGTKSDALHRKRVSAAAALDAAMSAELAPLKMERAIFATRITEGTPGPEGADDVAFTVATNPGAPAGPLNKIASGGELSRFLLALKVCLTQADAGLTMIFDEIDRGVGGATADAVGRRLAQLAQEGQILVVTHSPQVAALGGHHWRVEKRQDAQSTTSTVVPLDASARVDEIARMLSGDKITDAARHAARALIEA
->tr|A0A2L0BX41|A0A2L0BX41_9CUCU Protein wntless (Fragment) OS=Cyclotoma sp. CSR020 OX=2055377 GN=wls PE=3 SV=1
-MALKTFFFPLVVGVIAWFWRRVHLVSRVPALLEYMLLSLGCTLAFLNCPIEYLTLWFDMPYMLLVSDIRQGVFYAMLLSFWLVFAGEHMLIQDNGEKNGIKLYWKHLSTIIIGCASLLVFDLCERGVQLVNPFYSIWITPIGSNLALTFIILAGISASIYFIFLCYMIWRVFKNISIKRSVLPSMSQARRLHYEGIIYRFNFLMMATVICAAITVIGFILSQVAEGQNKWDENMELELSSILH
->tr|A0A1J6PS54|A0A1J6PS54_CAMJU Uncharacterized protein (Fragment) OS=Campylobacter jejuni OX=197 GN=A8118_08150 PE=4 SV=1
-MFGAKKNNTEIIEQLEKKCNGLEDILRSIGNTMAVIEFTTDGVILEANQNFLTTMKYSLSEI
->tr|A0A4P8GRK2|A0A4P8GRK2_9MICC L-2-hydroxyglutarate oxidase OS=Arthrobacter sp. 24S4-2 OX=2575374 GN=lhgO PE=4 SV=1
-MVEDIGIIGGGIVGIAIARALSSRNLANVTVLEKEQRVAMHQTGHNSGVVHAGLYYAPGSLKAMLCQRGRELTRDYCREKDLPYRELGKLVVALTDDELPALADIERRSVANRVPGLRRLGAGALREIEPHVAGVAALHSPQTAVVDFVAITEALADDVRSSGGQILFGHEAIAISTGQGKVRVTTGRADLVFDRLIVCAGLQSDVVAGLVGASPAPRILPFRGEYWGLAAAKQHFVKGMIYPVPDPRFPFLGVHFTRGVYDTIHVGPNAVPALAREGYGWNRVSFKDTAASVMWPGARALAKQHWRMGAKEIAASLIKPLYYRQAHRFIPELQIGDLTAKTASGVRAQAWSLDGSLLDDFAIDQVGPVTLLRNAPSPAATSAMAIADHLLEHFIHLPK
->tr|I0SJ56|I0SJ56_STRMT Bacterial sugar transferase OS=Streptococcus mitis SK616 OX=1095735 GN=HMPREF1045_0997 PE=3 SV=1
-MYSILKRLGDISISLIAITLFCPVFILIAIAIKLDSEGPVIFKQKRFGIHKKTFYVFKFRTMKVESPKYVATRDLQNPEQWITRVGAFLRKTSLDELPQLCNILVGDMSIVGPRPVVVSERDVIETREKYGANDVLPGLTGWAQINGRDNLSTDIKAKLDGYYVKNRSLITDIKCIVRTIPYVLKRKGIVEGSKRES
->tr|A0A1F3KL50|A0A1F3KL50_9BACT Peptidase_S24 domain-containing protein OS=Bacteroidetes bacterium GWF2_43_11 OX=1797352 GN=A2X09_17370 PE=3 SV=1
-MAKRLDLKNALQTIKDFYYRNQRIPSLSETAGIFNYSSRNTALYLLNKLVETGYMTRGTKGRLLTTPKFHDKTKLLGSISAGFPAPEEEELRQSLSLDEFLIRKPSATYMLEVSGDSMIGAGILPKDFVLVEKGRTPAPGDIVIAQVDGEWTMKYYRMENGKAYLQAANAKYPDIYAKEELVIAGVVISCVRNYA
->tr|A0A1A0T4H8|A0A1A0T4H8_MYCFO ABC transporter permease OS=Mycolicibacterium fortuitum OX=1766 GN=A5751_24895 PE=3 SV=1
-MTVGLAVRTHAASRPSNTRPSRRRSVVARLGVLGWTLAGMGITAALWSVIVATGRFPRQLFPSVPEILAAGQTLWTEGLLAADVSASLSRAAVGFAIGAVAGIAVAVLTATTRAGRSLLQPVLRVFSPIPTIGLVPLAILWFGLGENSKILVIALGVFVPVWINSHSGLASTPVDYLKAARCLGAGRWQTLSRVVLPEAAPDIASGLRVGAAMAFVLIVVAEMTGTTMGIGYRISQAQLFSQADRLIFCLIVLGIIGALCDQLVASVTSPFTRWAHEER
->tr|A0A417V5I4|A0A417V5I4_9FIRM Deacetylase OS=Lachnospiraceae bacterium OM02-26 OX=2292908 GN=DXB19_04045 PE=4 SV=1
-MLRKITILILLILTVAQFTSSDSIQSAREFIQNNIYVWSETQEEKLPIYCVDTQKKQIALTFDTAWGNEDIQQILRILKQENVKATFFFCGDWISKYPTDIKTIYEEGHDIASHGDHHKYMTKLTDKQQQEEIQGVTQKIQGLLGIKIDLFRAPYGDYNESVVRNARKMNYYIIQWNVDSLDWQEPTKEQLIEKVCGHKNLSPGSIILMHTGTKCTKQALKQIIRNIKAKGYEFVSVSRLIYRSNYRIDPTGKQMKL
->tr|A0A1H1FUZ1|A0A1H1FUZ1_9HYPH Uncharacterized protein OS=Rhizobiales bacterium GAS113 OX=1884352 GN=SAMN05519103_00535 PE=4 SV=1
-MAGGQTPGSFSKNFAWGHTGLRKLHESIRLGFADVLEPVSRKLWRSQSQIDNPGLDLIPVNFFLHNAAGQLTVDELVYQAVSQPYSLRFDRLALFAFNLSQVGRPPLKGPGRPAAWANEFVKEALWQNGVWRRSALAKPAMGAFLKTHIKGQSYWKCQTNYRRLFGLCGYLTGTSPTVNSGAADCQSAWKKDPVSAPKRDPSRRRARRIDPARGAGRGCAARRDRCPVGRSVWVQARFLKRQLSLPVSTISQ
->tr|A0A0N0MN32|A0A0N0MN32_9ACTN Major facilitator superfamily MFS_1 OS=Actinobacteria bacterium OK006 OX=1592326 GN=OK006_1213 PE=4 SV=1
-MRTNACPTGSTTRYAAARRPSDTVTTVADQERPGTAAAPTAEHGRLGLALILVAAFMVVLDFSIVNVALSSIQRELGVSAATVQWVVTGYAIAFGGLLILGGRAGDLYGRRRLFLAGIAVFTAASLAGGLARDPVLLIASRVVQGSGAAMVAPAALSLITTGFPEGPRRTRALGLYGATASVGFVAGQVLGGVLVEFLTWRSVFLVNVPVGLAALLLAPRTLRESRSPRTGRHLDASGALLITLAVGALVFAVSRGGGTGIGSADVLVPLALSALAAAAFIANEHHHADPLMQPALLRLHGLRSAGVLMLLLGLWNGGEMLVLSVYLQQVLHMSPLAAGLTIAPQGVFGLATGLLGARLARHLGIQKVLVATGAAATIGFAALTRLPGSDGSHLPLAAVTLVGCGTAGMAFGSMVTASAGVADRDQGLVGGVINTSRQLGAAIGAALLPAVADAVDRTRHASTAVGDRAAMLAGLAAAALAPLVAMNAWRRSRHDGVARCAPRA
->tr|A0A2A7X0U8|A0A2A7X0U8_9BACI Helix-turn-helix domain-containing protein OS=Bacillus sp. AFS002410 OX=2033481 GN=CN692_02510 PE=4 SV=1
-MTELGKFLKEAREAKGLSIDDVQELTKIQKRYLEAIEEGNYEILPGQFYVRAFIRQYAETIGVDVSGFLSDKPVVEDTVEANTITEEVKHEEIPSRASKLKEPLNNVKSSRVMDYLPRILIAILIMGICIAIYMMLPSKNDEKSADTNQSQTNSNSEIEKPKNNALDQVKNDNKKQTEKAKNDETKQEPTQKITVDAAQGKRTSISLSGTDVFKLEVVANGESYVDLKNASGKMFYSGILKQGQTQNYDLTEENEVTVNIGASNNVELRINDEVFKYPVSPTNAVHQKITIKNLKMNQ
->tr|G3HRZ4|G3HRZ4_CRIGR Differentially expressed in FDCP 6 OS=Cricetulus griseus OX=10029 GN=I79_013619 PE=4 SV=1
-MELKKEEAARQRQRIAELEEMQERLQEALQLEVKARRDEEAVRLAQTRLLEEEEDKLRQLMHLKEEQERYIERAQQEKQELQQEMALQSRSLQHAQLQLEEVRQHRQRAGEDVEAAQRKLRQASTNVKHWNVQMNRLMHPIEPGDKRPTTSSSFTGFQPSPLARRDSSLKRLTHWGSQGSRTLAANSSERKSLNGGDETPILASASQEDKLDPAPEN
->tr|A0A4D9CK05|A0A4D9CK05_MASLA Uncharacterized protein OS=Mastigocladus laminosus UU774 OX=1594576 GN=BLD44_003515 PE=4 SV=1
-MAKVNYKLTGKYLPPQIFILGICFVPGVTEVSSEQLTEIRRFIKSDRLLQHYLEQKILIIQD
->tr|A0A1H9PEC9|A0A1H9PEC9_9HYPH Pseudouridine-5'-phosphate glycosidase OS=Rhizobium sp. NFR03 OX=1566263 GN=psuG PE=3 SV=1
-MTRPISHDLPIAYSAEVAAAKARGSAIVALESTIITHGMPYPGNLDMARSVEAIIRDQGAVPATVAVIDGTLHIGLDAELLEALAQTRGAMKVSRADLAFAIAERRTGATTVAATMIAAARAGIRVFATGGIGGVHRKAEETFDISADLEELACTGVIVVCAGAKAILDVPKTLEVLETRGVPVVTYDSEIFPAFWSRDSGLKSPLMLNSPAAIANFQRMRDRLGIDGGMLIANPVPEESEIPRDEMEIYIARALDNADRDKIIGKAVTPYLLQSIFELTDGRSLETNIALVENNARLAAEIAVALM
->tr|A0A151WTB8|A0A151WTB8_9HYME RNase H type-1 domain-containing protein OS=Trachymyrmex zeteki OX=64791 GN=ALC60_09730 PE=4 SV=1
-MLITPALPAYQNSYYSTCTNVSYLSLPPNILKNLDTIPQQNIQPIFEDTFQRVLARAIVFYTDGSKVDDGTYVGSAVYSPQLDLHFMFKLSSYASVFSSEAWAIYNALLFALHNDFSCIVIVSDSKSVLDSLAGFRNRTNNYIISYIRALIEEAKFCNTQVSFIWVPSHCGIQGNEIADQLAKKAIREGAESNFMTPYSDLFSIPRMRLSKAFDSYIERTSRITGEYYFKNCYSHNNKPWFHDLRFSRIMITTMNRLRSNHFNLNHSLFRKNLIDNPSCPCGAPSQDLAHVIFFCPLTESHAAPIRLALNDLDQDSSQDPITVIIRALCNPSAKICRLFVSFGLACDRLF
->tr|A0A2D1IHR8|A0A2D1IHR8_9ACTN Uncharacterized protein OS=Micromonospora sp. WMMA2032 OX=2039870 GN=CO540_27970 PE=4 SV=1
-MSGGGPRRGRRDNGLDAAEYAVAGDVDPRVGEHLLDVLAAGGIAAYLQPSADLNPVTRTTTVPARPVDRLYVDRSHLTTARDYLTQLADEGSDDPPRPDEPDIEAEWAKIVAGFHTTPTAGSHPWPAAEDVDDPVPPAGATAGRAEEPAGPTATDVRRLPYAADVSGVSLGRDRSDEPSLLDGLDTFGADLPGDAEEEHYTPPPPPPLPRFSKYAVLGVLCVVLGFLLFLSPTVVSLVDPAVVTLLGFTGILAGFVMLVWRLRPGDRDEDDPDNGAVV
->tr|A0A3S0HSP6|A0A3S0HSP6_9GAMM Phosphoribosylamine--glycine ligase OS=Halomonas nitroreducens OX=447425 GN=purD PE=3 SV=1
-MKVLIIGGGGREHALAWKVAQSPRVETVFVAPGNAGTAREPGLENVAIGVDDLDGLVAFARDEDVALTIVGPEAPLVAGVVDRFREAGLAIFGPTAGAAQLEGSKAFTKDFLARHAIPSAEYRTFVAVEPALAYLAEKGAPIVIKADGLAAGKGVIVAETVEEAEAAVRDMLEANAFGDAGARVVIEEFLEGEEASFIVMVDGETVLSLATSQDHKRAFDGDSGPNTGGMGAYSPAPVVSETVFERIMARVIRPTVQGMAEEGHPYTGFLYAGLMIDTEGNPKVIEYNCRFGDPETQPILLRLTSDLAELCLAGARGELAGHGCDWDERAALGVVMAAGGYPGSYRKGDAIQGLEAAEATGCKVFHAGTAEGESGEVVTAGGRVLCVTALGEGVSAARDLAYRGVAEIHWPEALYRRDIAHRAIARERGER
->tr|A7B7B1|A7B7B1_RUMGV DNA binding domain, excisionase family OS=Ruminococcus gnavus (strain ATCC 29149 / VPI C7-9) OX=411470 GN=RUMGNA_03477 PE=4 SV=1
-MNKQYVAICEKVALTIEEAAEYSNIGQNRISSLLKEPRCPFVLYVGTKKLVKRKEFEKFISESVEI
->tr|A0A059AXC2|A0A059AXC2_EUCGR Uncharacterized protein OS=Eucalyptus grandis OX=71139 GN=EUGRSUZ_H01175 PE=3 SV=1
-MVMKVHGSVFSAPTMRVLIALHEKDLEFEFVFVDLRAGEHKKEHFLALNLSLHHRPPPPFGQVPAFEDGDLKLLVEAHQFDPAASKLHWELVYKSKIGMATDAAVVKDADKEANLAKVLDIYEARLSQSKYLSCDCFTLADLHHLSALTSLMGTLVKKLLDARPKVSAWVADIVTPPALAKVLTMRNQQ
->tr|A0A2E3M894|A0A2E3M894_9RICK Diguanylate phosphodiesterase OS=Rickettsiales bacterium OX=2026788 GN=CMP19_12800 PE=4 SV=1
-MSQHHNSLATLPNRFAFIDTVSKCGVLHPSLSLMLVDVVRFSDVTTSLGINIGDRFLLEIANRIQSLFGGDIRLGRISGDVFGIAFLGTRSSGQMRDMFERLVEHFKTPMHHDGHAFIADFNVGVVTSEGQTFEITAFVSRGEAALKQAKENKYENFCLYNMQDKTDTGRSLALKADLKRALSQNELELYYQPKVNLQTLEVIGAECLLRWNHPLDGVLFPGPLIEAAESYNMMNELGYWTLEQAFRSLVDFDFHRLSLTLSVNISPTQLYDNHLIPSLKMLSKSYAMPLTRIELELTEDVALSNSLMVKRQLDELRALGVAISVDDFGKGYSNLAYIRDLDLSALKIDKTFVIELANHPVNRAIIEAAKIIGKAKNCDVIAEGVETIAQLHILREVGVTIGQGYLFSKAIPLNDFISLAQQEIIVGNSPLRA
->tr|A0A4Z1G3Z5|A0A4Z1G3Z5_9HELO Methyltransf_25 domain-containing protein OS=Botrytis hyacinthi OX=278943 GN=BHYA_0421g00010 PE=4 SV=1
-MATVAAGSQAGHDTFDALNIEYEKAYRDNPFKIAAIKKAITLLDPGSKVLDVGCGTGVPVSELLAEAGLEVVGFDIAPKMVEFAQKRVKGTFSVSDMVQFQVEDTFSGVFMIFAHLQLSYAAVHAAVYKYVSALKPGGVFVLGQMPSDSYVKGEGNAAYDETRTYVEDYDAPFMGEPLPTFMMSEQGQRNFLTSMGLEIVSETIDQFQPDNEKCEPEMQQYIIARRPVDGTIVEPQPLPKNK
->tr|A0A526YNJ2|A0A526YNJ2_9HYPH 3-isopropylmalate dehydratase small subunit (Fragment) OS=Mesorhizobium sp. OX=1871066 GN=E5Y60_26890 PE=4 SV=1
-MEKFTKLTGVAAPMPIVNVDTDMIIPKDYLNTIKRTGLGSG
->tr|A0A0A1TZ67|A0A0A1TZ67_ENTIV Uncharacterized protein OS=Entamoeba invadens IP1 OX=370355 GN=EIN_043770 PE=4 SV=1
-MVSRLEMVFLANVVLKLTNYIDIHNFILVSHNCYESVKSLKTTPKLSSAIDLSWFLSHFYLDTVDFDEVQIPVEKYISSVQCIRNPNFLEDAIAGKLTQSYADTIFPKVVSLSLLYPVYEKDDPCNNLIISNSKKFMSLRRLSGDLEQISLFLKNLTDNGEAIGTKYPNLIVIDSYLESTIVLNETTLNLLRSVELYLKKSYNEKVCYVVAEVPEDRSLIDFVKKGKFYCKNAGSVMCNKDDIFGVCGDFELSGEVERKGEDLKILNERIGANLDAASAFSLTHKYMSNTEYSLELPDSVREYNICVSSLPELVDANYFKYPINFNKIEVLKLVSVSNVSLEVTNALNCLELKSCDFCVFTNDEDSLIAIEEIFVEDSKHIRFLTHSEAIVENVHLFSDTEIDFNWSIKNTENVEIVESRNVGFVGGIFSASCIFHVERSTDTVIKNGEQIASYIKEVNVANFVIGNTGETKSCVLANKHFVCHSVDYLINNHFSCYNEVTENVRSFRPERIVLFTINNFNETSAKVPYFEVKEKGCMLSLGLYDTKGSALTNSTYPIHVGWENGSLGIHTDDWCLYGLDIGGEGENVNVAFDKFESCECVIGCGYNNTRKEVFFTLNGKIVKKIEIPWKNIGAAFAVQRLGTLFVNTGDQKFTFDIENYK
->tr|A0A7C0YEA6|A0A7C0YEA6_9FIRM Uncharacterized protein OS=Firmicutes bacterium OX=1879010 GN=ENF61_00215 PE=4 SV=1
-MKHKKEEEMVRRIKMFLMLLLGLGIFLAPLTFHVQDHRKGNGHLVKLDCFCGGDECGICIIPN
->tr|A0A2Z6P333|A0A2Z6P333_TRISU TFIIIC_delta domain-containing protein OS=Trifolium subterraneum OX=3900 GN=TSUD_213440 PE=4 SV=1
-MNSPSPLQSAMLMGSPCFPNAISWSQDNLIAVASGNIVTILRPDLPNGPRGLIKVLPREPLIVGFVHRKDVVSGCLMPTSLYRDDKPVVQSISWSPLGMAANSGCLLAVCTSEGHVKVYRPPFCDFCADWIEVVDITERLYEYLQYTEFKDAGVPSSDFSEVPRIRPCLQKNALGQADSITPNDELLENVPDNQLSPLISADEYASRSAMLYSLVVSWSPLLRVASEFSPDPNTSASVSLLAVGGKSGKVSFWIFYQPDCYTIEESKTPTAVKFVGFLQAHNSWITTMSWLLFSFDSSNPLIILATGSSDGSVKVWLGDNDKLLKSSAVDQTSFSLLKEVITVNAVPVSVLSVTVHVQYPSKMLLAIGKGSGSIEIWLCDIPSREFDKLGSYDAHYYVVTGLAWAFGGRFLCSSSQDNGLRGWILHERRLEEMTTFSEMPRSNDSTCPSRDAYDSCFGVAVSPGNLVVATVHCFDVVKLNRMYEGRILRAAIEYLWIGGLQVDVWLKSPSPCYIEELPSFPEKELTYWAANIIWSLNQYQCLDKPLVFWDIIAALLAFKDNNSKYVEYLVIKWLSLSYLGSRTNLPPEEVLSRVISRLSDVPSRLLHLLNIMCRRVMLAQLDADQITTINSKGQNLEGVCPVIEEKMTKWIEILLGSERELRERHVGFSFSAVKTTTSHLEETPSQPGRWYPVGLAQMEQWVALNQEQIRDQLKLIATKVTHGKRFKTKRCSAVEPCSYCSAPVPFESPEFGFCQSKNRSNGNVKPHKLSRCAVCMEVCPSSPLWFCVCCHRNVFRLAPEPLFRMPSCCLDSDSSNRTSSEAVSSKPLCPFCGILLQRKQPDFLLSPAPV
->tr|A5E9B7|A5E9B7_BRASB Hydrogenase maturation factor HypA OS=Bradyrhizobium sp. (strain BTAi1 / ATCC BAA-1182) OX=288000 GN=hypA PE=3 SV=1
-MHELGITRNIVKIVEEAAKGRRVKRVTLDVGQFSGVMPDAILFCFDIVAKGTLLDGALLDIQKIAGLARCRSCGEAFKTTSLYQACACGSRAIDRLAGEELKIREMEIEEAA
->tr|A0A0J0YQQ3|A0A0J0YQQ3_9NEIS Probable allantoicase OS=Neisseria arctica OX=1470200 GN=alc PE=3 SV=1
-MELPDFATRFVNLASADFGAEVLSCSDEWFAAANRMLQTAPPVFVVGKFDDHGKWMDGWETRRKRYEGYDHAIVKLGLPGVIKGVDIDTSHFTGNFPPAASLDACRCTGVPDESTEWVTLVEAVSLQGDSHRFVEVDDEREWTHVRLNTYPDGGIARLRVYGLPKVDWDALPKDEVYETSAVENGGRIVAVSNAHYGVPFRLNMPGRGINMGDGWETARRRVPGNEWCIIELGTKTLIEKIEVDTAHFKGNYPDTVSIQAADVTFGTDESLVTQSMFWQTLLPQTKTEMDKQHFYTQADFNDLGAVTHIKLNIHPDGGVSRLRVWGKPVR
->tr|A0A4S2D9L7|A0A4S2D9L7_9MICO Glyoxalase OS=Microbacterium laevaniformans OX=36807 GN=E5344_04275 PE=4 SV=1
-MTSIFVNIPTNDLERSVAFYRALGCAINPNFTDENAACVVWSDDIFFMVLRREFFATFTEKPVGEPREWAQASLSFSRGSRADVDAIVEAGLAAGGTEPHPAQDYGFMYSRDLDDPDGNSLGFLYMDPVAAEQGPPAEAS
->tr|A0A2R2WQG2|A0A2R2WQG2_XANCI Uncharacterized protein OS=Xanthomonas citri pv. aurantifolii OX=76802 GN=TP45_21175 PE=4 SV=1
-MSLLVNAYSTLRTPLWPDFLPQAAVQHRDYADPALVDHLHGFVGYVNQAGDGQMTQSRYHLMRHVQRVRQHFSFQVDDADFGALAQWAEQANAVCFLADGSVRDPHGRVLISQGEPAIDDDAQVPYPPDALQRRAQQSSLLTAQGIRVPPSLPPVPGEAEARVRDAAVVSRRMLALFAVALRAEILATGDTPPSLDEVETRLPGVAAALSPQERAFFAQAAPDAQALANFGWRYEALAAQRALDNAQAAERTTLARRPLPELLDTLDRHLRLHWAVRQAGRSGQPLPAGIVPGVVYERHYALNWLLHFEDAEWDEVETPT
->tr|A0A1M3MBX0|A0A1M3MBX0_9BACT Tryptophan synthase alpha chain OS=Paludibacter sp. 47-17 OX=1895899 GN=trpA PE=3 SV=1
-MNRINQLFKNKPSGIMSVYFTAGYPQLDDTLPILDALQANGVDLVEIGIPFSDPMADGVVIQESGHQALQNGMNLRMLFQQLTGMRSSVTIPLVMMGYLNPILQFGFHDFCRECRRVGVDGMIIPDLPMDDYLSEYKAIAEAFGLKFIFLITPETSDERIRIIDQQTDGFIYMVSSAAVTGTQQSFDSREEYFRRIESMKLKNPRLIGFGVSNKATFEMVNRYSSGAIVGSAFIKSLQSSCSVSEAVQALIQQLRS
->tr|A0A418ESL0|A0A418ESL0_9STRA Uncharacterized protein (Fragment) OS=Aphanomyces astaci OX=112090 GN=DYB26_008272 PE=4 SV=1
-MTTTRASSIAAAASASPTLATTPTTHDVNDDMEEGAPTPIADAVPTHDANDTLTPGTAPTATLGDDDMTAAAAHRLEEDFPELDGSKATTPPPVPATNPWNWAATTGADMSKPRADDIGFHPATDAQLATLLQLQEQGTWSYDAVLALESSPRREAVGHLIMRPGVSTAKVSENRLFQA
->tr|A0A7X8UWW0|A0A7X8UWW0_9BACT Methyl-accepting chemotaxis protein OS=Phycisphaerales bacterium OX=2052180 GN=GXY44_13280 PE=4 SV=1
-MSLKAKLFSSNMILAIVPVVLVSIIVHRTVRDGFRVSAAEAEAGLTTTIQTGREALIASGMTDLRHTAEHVYAMCAAQQEVLQQKVGYDLNVARDLLTQGGGITLMDEEIRWEAVNQFNRQTVSVSLPKMCVGTEWLGQNQEAGTTSPIVDRAQQLVGGTCTIFQRMNPEGDMLRVCTNVMGADGKRAIGTFIPARHPDGQVNAVVEAVRNGKPYLGRAFVVNAQYVTAYEPITDATGQVIGMLYVGVKEESAESLRRAIMSIKVGETGYVYVLNAKGATRGHYVISSQGQRDGEDLWMSKDADGHLFIQDICAKAITLKDNETVMVRYPWQNPGEPRPREKVVTLAYFAPWDWVIGVGSYEDEFFETVKAMEAEGAETLASLQEAGALAIGTVQKWSIGVGLAALVLSFFVAWFVSQGMSRALRRIIADLNEGANQVNAAADQVAGSSQHLAAGASEQASSLEETSSALEEMAAMTRTNASNAQQANGLADQARTAANQGDQTMEQLNQAMTGINDSSQKISKIIKVIEEIAFQTNLLALNAAVEAARAGEHGKGFAVVADEVRNLAQRSAQAAQETTQLIEDAVDKSHNGTQVATQAGQALAAIVKNVDAVTRLINDIAQASSEQAQGVEQVNMAISQMDKVTQQNAAGAEQSAAAAEELSSQSKVLKETVGNLVTLVEGRGAQIE
->tr|A0A258R204|A0A258R204_9PROT Thymidylate kinase OS=Hydrogenophilales bacterium 28-61-11 OX=1970529 GN=tmk PE=3 SV=1
-MNMTGKFITLDGVDGAGKSTHIAFVADWLRRQGREVIVTREPGGTPLGETLRELLLHRDMDADTELLLMFAARQEHLAQLILPALARGAWVLSDRFTDASYAYQCGGRGIAAERVAALEAWVQRGFSPDLTLLFDVPPEVAEARRSAARAADRFEREAELFYNRVRQAYLDRAQADPQRIRVLDARHTIAELQAEITRLLQELA
->tr|A0A6D1WBS5|A0A6D1WBS5_9PSED Arabinose 5-phosphate isomerase OS=Pseudomonas sp. JMN1 OX=2518650 GN=EXW70_13605 PE=3 SV=1
-MSQSSDLIQSAQRTIRLELEAVEGLLAHIDADFVRACEMILASKGRVVVVGMGKSGHVGNKIAATLASTGTTAFFVHPAEASHGDMGMITKDDIILALSNSGTTNEIVTLLPLIKRLGIQMISITGNPESTLAKAAEVNLNVHVAHEACPLNLAPTSSTTAALVMGDALAVALLEARGFTAEDFAFSHPGGALGRRLLLKVENVMHAGDELPHVQRGTLLKDALMEMTRKGLGMTVILETDGRLAGVFTDGDLRRTLDRTIDIHTATIDAVMTPHGKTARPEMLAAEALKIMEDHKIGALVVVDSDDHPIGALNMHDLLRAGVM
->tr|A0A2L2WP68|A0A2L2WP68_9BACT Ribosomal RNA small subunit methyltransferase E OS=Prevotella sp. MGM1 OX=2033405 GN=PvtlMGM1_1921 PE=3 SV=1
-MKETRFFYVPNASISEELPEEEALHALRVLRLNVGDEIVLMDGCGKYYNAEVTFASNKRCVYKILEEHPQKCQWARHYHIAIAPTKMMERMEWMVEKATEIGIDEFSFLNCKFSERRIIKLPRIDKIVISAIKQSHKAWKPQVNDMIAFKQFISTPRAGLKFIAHCYTEIPRKYFFDELKTQGQMDDVTVLIGPEGDFSIEEVRLAIDKGYVPVHLGESRFRTETAAIAALMMMQLSDKLNGK
->tr|A0A663BED7|A0A663BED7_9ENTR Crossover junction endodeoxyribonuclease RuvC OS=Klebsiella quasipneumoniae subsp. similipneumoniae OX=1463164 GN=ruvC PE=3 SV=1
-MVRTLLKLPANPQADAADALAIAITHCHVSQNAAQISETRLNLARGRLR
->tr|A0A803PXS8|A0A803PXS8_CANSA Uncharacterized protein OS=Cannabis sativa OX=3483 PE=4 SV=1
-MSGSNTNHQETKCKIRKRNCSSSSSSSLVRKYRFKRTILMGKRGGSTTPAVTMWETTSSPAPVSMAETGKGKEAAPGKSVSARKLAATLWELNQKKDGTAKLDKLPKLPSQSASLPPDPSYTPISDRRRDDHAERVGHHRTMSAVTQKFQLTDYYLGGLDSLSTASLMEVEDHARAKTHHHQHHKKCVTNNGGSNKTRLKEVSSGLATSKELVKLLNHVCGLEEQRSLSTSLFSALRFELDRALIHVDRFMREQRSKGGEIEFLVKQFAEEKAAWRSKERERIREAMSCVAEELKAEKKLRKQTERLNKKIGCELADAKAALSKAVKELEREKRAKEILEQVCDELARGIGEDRAQVEELKRESEKVREEVEKERQMLQLADVLREERVQMKLTDAKYQFEEKNAAVEQLRNELETYLLNMDNNSRSYRWSYACGEELNEDEDEESRRVSVDRDFKGRKSISEKIQWGSICLNKSDSGLELDFGNKSQGNSDGVVSQAKKQEFEDEFKRYRSSIKGLADQILSGSEMVPIHGLTSPSRQWGKT
->tr|A0A6N7L718|A0A6N7L718_SINTE DUF1109 family protein OS=Sinorhizobium terangae OX=110322 GN=GHK62_00935 PE=4 SV=1
-METHELIKGLAADSRRTGMPMNTAWWAAVLIAIAIAAAVFFALLGPRPDIAGAAQTVRFLFKFVVTIALAASAFVPLRMLSRPETDPRGGLLYLAIAPALILAGVAIELVVAPAETWLTRLVGTNSLVCLTFIPLIGVGPLALLLLALRHGAPSHPALAGAIAGLTAGGIAATFYASHCTDDSPLFVATWYTIATAILALLGTLGGRYVARW
->tr|A0A1Y4K2B0|A0A1Y4K2B0_9BACE Conjugative transposon protein TraK OS=Bacteroides sp. An19 OX=1965580 GN=B5F25_04455 PE=4 SV=1
-MVIKNLENKIKLVGIICVSVIIGCVIISLSSIWMARGMVADAQKKIYVLDGNVPVLVQRTSMEETLEVEAKAHVEAFHHYFFTLAPDDKYIQYTMEKAMYLVDETGLAQYNTLKEKGFYNNIMGTSAVFSIFCDSIKFDKEKMEFTYYGRQRIERRTSILMRELVTAGQLKRVPRTENNPHGLLIVNWRTLLNKDIEQKTKNNY
->tr|A0A7X5XVZ8|A0A7X5XVZ8_9SPHN Murein tripeptide amidase MpaA OS=Sphingomonas trueperi OX=53317 GN=GGR89_000656 PE=4 SV=1
-MSIQISAAFDSGNIRVVAIEGDRVDCEIVLDHQSDFFQWFHFRVAGAKGRTLTFRILNAGSSAYPFGWPGYKARWSADRESWRMTETDYADGILSFTHHFQTDLTWFAYFAPYSMERHHDLVSRIALQEGVTHRQLGETLDGQPIDCLTMGEGPKQVWLYARQHPGESMAEWWMEGALEFLTDEDNAVAQALRTKATFHCVPNMNPDGSRRGHLRTNAAGVNLNREWHTPTPERSPEVLAVRNAMDATGVDFAMDVHGDEAIPANFLAGFEGIPSWTDALGEKFYEFGRRLAAHTPDFQTELGYDKSPPGKANLAMSTNQLAERFGAVSMTLEMPFKDHDANADPEFGWSPTRSKLLAHACLETLAGMIDTL
->tr|C7LTP9|C7LTP9_DESBD Diguanylate cyclase OS=Desulfomicrobium baculatum (strain DSM 4028 / VKM B-1378 / X) OX=525897 GN=Dbac_0207 PE=4 SV=1
-MLNFFCGGQPVKERSSSRVSAPETAAQASFDPGRASWPSRIGIVRRVALLLFVLVLVPMGTTLAMLESGTVIDPVNMLVASLAVALGLLAPISRIGAHFLVLRDLRLLNEFCSQIQQGRYGARFPVGLEGDDEHEMLRLKRNMNWMAHHIETQTKKLHERLDESDLRKRFYEEMSYRDPLTGLYNRRYFDCFVPNALRDPARRQGVFLALLDCDGFKRVNDTHGHQVGDEVLATLGRVIGESVREGVDVGFRFGGDEFGVIFRTVDFSACLGACERIRVRFANSNADGCTVSIGLCAWSPALGHDMPDLVRSCDTCLYQAKGLGGNQVVTNETVSIPPRLSSPAPS
->tr|A0A3D3VBE3|A0A3D3VBE3_9PROT Cysteine synthase A (Fragment) OS=Rhodospirillaceae bacterium OX=1898112 GN=DIT35_08550 PE=4 SV=1
-AARKLARLEGIPVGISSGAALAAAAEVGSREEMTGKLMVVLLPSFAERYLSTALFEGV
->tr|A0A7X7I035|A0A7X7I035_9BACT DUF87 domain-containing protein OS=Fibrobacter sp. OX=35828 GN=GX639_08725 PE=4 SV=1
-MTFSPIEHNASLRIGSVEFVSPDELKVCLDLEAPDGISANAGIPRAFPRINSYVLIATEAGYIVAQVEWIAIEKTPFPKRKGFQDYGLVDLPYPTRKLRANPLGILKQNSNNQFEFQRGVQSFPSIGEPVLIPTDQQLQAIVESGKNRRIKIGSSPIAGNAEVMIDPDRLFGRHLAVLGNTGSGKSCSVAGLIQWSLAAARPKDSEPNARFIVLDPNGEYTKVFKDKGRVFHVGSDANSLQVPLWFWNSAEWCSFTQASAKAQVPMLKRALREIRSGGGRIASDVDLELRRKISSILISLRTQIRNGDNYEGWKFGPKLEAYKKDIEAFARHFSGHTTTLGEISNAITKALSFPHQTYIKKDGCIGYNDFPVVNIEPIENVIEKFLTTIGGLVFQNDFNEDIPLSFNSVQFADHIDNLAREDSNPHFFEFLVMRIRTMLADTHMQSILGDTVDMTLEKWLKTYIGDNNPTNGCVTIIDLSLVPAEIVHIVTSVISHMVFEALQRYHKHKKTSLPTVLVMEEAHTFVKKYKEEAENQSVSAMCCQIFEKIAREGRKFGLGIVLSSQRPSELSPTVLSQCNSFLLHRISNDKDQELVSRLVPDNLRGLLRELPSLPSQNAILLGWASELPIMVRMNDLNKSERPHSDDPDFWNVWTGKDECGNTVVRDVDWEKIAADWQGRIK
->tr|A0A1Q6MVU0|A0A1Q6MVU0_9FIRM Phosphoesterase OS=Coprobacillus sp. CAG:235_29_27 OX=1896995 GN=BHW13_05765 PE=3 SV=1
-MKILLVSDSHGYDDELKKVLENVKCNLKIHCGDSCFDKNSPFIKEFAAIVDGNHDQGFFPLTATLPTALGNILITHGHKFNVYAGYDYLVEYMNKADIHICFHGHTHVPHYEIYKNKIFINPGSIMFNRGQSQCGSYAIVSVDDKLHVDFFDSRTQKKIPQSLIDKDQDILNEFKRFACQK
->tr|A0A495SQH4|A0A495SQH4_9FLAO Helix-turn-helix protein OS=Chryseobacterium defluvii OX=160396 GN=BCF58_0976 PE=4 SV=1
-MKTSPKPYSILLFILLFHAVSSELRGQYSEFYQIRKRYEDRKENDTSALPLVQISIEKAKREKNYHELYNGYKFSGYFSESKNSKLIYADSAIEAAFLSKDEALISRAYMGKGIVYYYSFKKYKQALDQYLKAYEYSKKTKDQYQQNKLQYHIGVVKSYIGFYDDALDNLYPSKNYFYNESLKKDIHPNILFGIKRGYFNSLHQILVCYRNLRDYKRIDSLLALAVNDQNLKDNYTLEYGYFLKEKGINEFHKADFRSSITSLNQSLIPIKKAKDFAWESVCYAYLGKSYLRLNNEKKAIEYFTKVDSIFQKEEFMIPEVRDSYECLIQYYKTRGEAKSQLYYTGQLVKADNILNRKFPYLSSKIFREYDTSKLNETHHQEKKTLQREKVIFIGGTIFLLVIFLHRYWKEQNLQKNYRLLEERILNKNVKSNKTQDRQDNPYSLEIEKEILDDLLKKLEDFEKKNKFLESGITLYKLASKFQTNSTYLSQVINEYKGSNFKKYIGELRIEYITQKLYNDKKYLSYTIEGLAEECGIASRPNFSNLFQEYNGIRPRDFIKKRMEDLKNKENLEEGAISCE
->tr|A0A182RGG3|A0A182RGG3_ANOFN Uncharacterized protein OS=Anopheles funestus OX=62324 PE=4 SV=1
-MEEFLEAIQCGQYEVVRAALKNSDLDLDHQDPAREGNSALHLATIAKHNKTRLIELLIEAGADCDLRNHANLTPAELALDNGSQYVAEFTLCKELDAVPDDQALRRLIRRGSVELLKIFLEKRAFDIHTKMKLIANLLDELTVKGVPIDRSMRVFLEYELIAHSYEDGTEGNATRQRRLGASGGASSKRKADGKVQSSTGETEADRRIELVLSYTKYLTDRYDDDNLNDLDDEFVVRLRAICECLYYLDGLDCCARSDWKLLKLIPLGELAYLCSVLLSILEKSVGFEMYKLVLNKHQIVSFLRAVSAELGTLVKASTRTVRTDRSFQWTPQLLLDLIVCIREQKLSQYVGRRRRACEDLQRIATTTCPLGAAEHDRVLVELGRRELIALQDGVLERGTKWGVADYVAYLRDDHPLTVGQLWHRYHPKLRLSKRQVAYAASRRELLSKIRARRLDELSRNKTKLLERELGARELQGSPSARTVRRRHRTVFGHIRRTYEQIWQMHTVKKIAYYVENALVIDLDDRSNATLCLMAIQRVMQFIGEVSKESQQHQATFARMLANLLDHVLSPLCTTATLTDADDLRESFSARCSVGKYFLHETLTGEQVRTIQERLKAVYRFCLYVINIQLIEAYKTFLGTAYRLRNTNQLQSYARYIGEHNLHTLSHIKFEHVFYDEKETARIVQELKKMYLGMSNELKLLSFIEKNIHFRFYHMQYHQTRLRVTLSNFAIVYRALKANPDYGCVRRLLHSYLHQSYQKYDISRSISISDANLALKELLRPYSSISENEDTLKVVRHLEELQHLMDPDRLFGINPVHRTGGHSSLEAARYQKFTRKLLKDMNASTLNDEEFQQLHDKLSRMYYGNIFLVQQRYHTLEEFFRTKGVALDETDLLTRRESDEEMLQELFDSKVNDVVEILEKFECTDVQNLCEVIEQLPPVVQFALEYGLLELLEILTSVNAIGSNRWHSLQCSTAVLCGHNLKTFLTGGRESQVLESLTLKSNATIFLNAIIFKQRSYELYGGRVDGRHCSKSKLMVSCFADKFANRLQWLEQQRILYETIRTGEVKLSTLRRQVRDGVEIGGQRFGSLMPNEMCHYGLIDCAIAGDFRAMIDLLTETDSTAESGVSSSERHHLLRYLLRRTTKSHFIAEPLERMKQEDRHTLVLYLCLFLGDVALFRQQLVRYNAYDELHLFVNSEDHRFVQQLLSELPDYDWSRTDANGMTILQKLVNAGNQPAIEDLIRRMSPEQLNSLCSMKYTALNLAARLNLVEIVRVLASAGIDLNVMSEDEKLPVFWLIQYGNSRTVVQQTIDAATELTAFSSELCLLHRAIEYDNEDVLRYLIEDCKVDPTRIYSNCNNVLHVAAGFDRCRIMRYLLTIPGLRKIVNNCNLVKNSPLNVACKEGYIRSARVLLAQGGASTETCGEYGLNALAFAMYTNNVKLARCLFRYDASIGNPLSSDFQPINMAIRNRNIRMLELLLRRGVDVNSAPLCFINAVYAQSRDIVQLLIGRGVKHVNHRDEFCQTALHLCVERDEYEMARDLIRYGAHINAKNRSGMTPLHLAVQRGNVRLVQLLLDHKCSVDELNYHGETPLIRAVASNNTKLVKILLNNGASIERLRNSDPPVLLYLVQENHEEILDYLLEHYQFNANEQDAYGNTLLYVATQHNHINIVKLLVDKYHAKTNPTNHKKLTPLMIARVKEYKEIFHFLEARLVEE
->tr|A0A1S9BZC6|A0A1S9BZC6_9FIRM Oligoendopeptidase F OS=Oribacterium sp. C9 OX=1943579 GN=BXO88_02085 PE=4 SV=1
-MKFSEMPYERIDFTKLSKDFKELEERFEKAASGEEQYAVHEDFYKIYNHVMTESQIAMIRSDIDMSDEALLEEQQYFDENMPVFQNLVVSYRKKLFNSKFRPYLEERIGKVAFRNIELAMKSVDEKLIPLMQEENKLQTEYNKLLASARIPWNGEELNLSLMNPYLHNQDRTIRKEAWEKYSAFFVAHQEELDDFYDKLVKNRTKQGELMGHENYLPLGYARMNRNSFGRSDVEEFRKQVKKDFVPFAEKLHDIRRQQLGLSRLSYIDEGVYFTNGNPAPTGTPEEILAAGRKMYNELSPETGRFINFMCDSELFDVLGRKNKKTGGYMTMIPDYQAPFVFANFNGTSGDADVITHECGHAFQGYITAGDPVIEHNDITMEVAETHSMSMEFFTEPWMPLIFGNRAEDYVKMHFMDSVIFIPYGTMVDEYQDIVYSNPGLTPKARNEVWRDLERQYKPHLDYTGNEYFEKGGYWQRQHHIYDSPLYYIDYCIAGANALQYKVWMDQDYKAAWKSYLELCRLSASDFFDGLVKKSGLNNVFEDGCLRYVVKQLEEKM
->tr|A0A355Z3B3|A0A355Z3B3_9PORP Uncharacterized protein OS=Porphyromonadaceae bacterium OX=2049046 GN=DD424_00560 PE=4 SV=1
-MQLKSSLKQLLVESRANPGFTSLYVGGVAFAVAFTMIFAIIYYVHLAPLYPEYNRSSTYYINNLTVRNDKTGAMNQSSVGIPFVREFVEKSKNIEYSTIVFQMQGFIQPPDQSGDFSVNIIDTNPDFFKLYSYEFVAGRPFNEAETESAINNIVVDSSVADRLFGVSEQAIGKEISISYRPYRIVGIVRSGNPVAYMSYANVFRPYTIRTKSANTSLKGDKCDYLGDYSVPIKFKDSRQAERFREELTEKVRRINAADSTGQRLDIQSAPISHTLRILSQRSNGENLSMTEYLKPLLITLLVLLIIPAINISGMIGGQMDRRLAEIGVRRSFGATRGHLTRQVMFENLILTLFGGIIGFAIAWIIIAFGRNMLLKLIIPAWECIDAPAEISTEMMFAPLVFIAALLLCLVLNLLSAYIPVRLSLRRPIISSLNSKR
->tr|A0A195BT40|A0A195BT40_9HYME Uncharacterized protein OS=Atta colombica OX=520822 GN=ALC53_01728 PE=4 SV=1
-MAKNIGSILLLTFALSFVRADEYERQWNTPPELIPESIVKILDNEESQMRLLSLIPVTATVSLTGENNNAHSVSLDASLDGISFSESKIHDRPTGYETDGSSVSVSKSTTVSAGLSGISTAAAEAYNNGNNAKTESHSLSFGQSTATSFGTIENGQAITGAASSTGLSQSFTIGDNRRQFSQVGAVNMQYPTWSNIGPNNGYIDQRFKRPTLTISNIDPNNGYNDQRFNRPTLIISKPWDETNRPTLNIDVSDTSRQEQKPTIHIHKWQPNRRISRPDFSIKHQLHDIRNDRNHGSISLRIENKNFKQEYSGSDLISDLAQTVDKLFDIV
->tr|A0A5B7XNA0|A0A5B7XNA0_9ENTR Mechanosensitive channel protein OS=Leclercia adecarboxylata OX=83655 GN=ybiO PE=3 SV=1
-MPWILLLLISLFCLPAQAVSLPGMPAATAQTPPPAEPDVEQKKAAYSALADVLENDTSRQELINQLRSVAATPPQEPVPKITPPEIADEKTVLENVTDISRHYGDALATRFAQLYRNLIGSPHKAFNPQTFTAAAQQFLILAGLVFAFYWLVRLCAWPLYRRMGSWGRKKNRETSSWIHLPLTIAGAFIIDLLLLALTLFIGQILSESLNTGNPTIAFQQALFLNAFALIEFFKAILRLIFCPRVPDLRPFAINDSAAHYWSLRLSLLSGIIGYGLLVAVPIISNQVNVQIGALANVLIMLCITVWALYLIFHNKRAITEGLLHLADRSLAFFSLFIRAFALVWHWLASAYFIVLCFFSLFDPGNSLKFMMGATFRSLAIVGVAAFVSGLLSRWLAKTITLSPHVQRSYPELQKRLNGWIGVSLKVARILTVCVAIMLLLSAWGLFDFWNWLHNGAGEKTVDILIRIALILFFSAIGWTILASLIENRLSSDIHGRPLPSARARTLLTLFRNALAVIISTITIMIVLSEIGVNIAPLLAGAGALGLAISFGSQTLVKDIITGIFIQFENGMNTGDLVTIGPLTGTVERMSIRSVGVRQDTGAYHIIPWSSITTFANFVRGIGSVVANYDVDRHEDAEKAQGALKAAVDELLEREDIRGLIIGEPSFAGIVGLTSTAFTLRVSFTTQPLKQWTVRFALDSMVKKHFDLANVRMPVQMYQLLPSPTGENTQIQNRT
->tr|A0A1F1XSS9|A0A1F1XSS9_9MICO Esterase OS=Brachybacterium sp. HMSC06H03 OX=1581127 GN=HMPREF3159_00885 PE=4 SV=1
-MIRLRTDFFAESLGMGTSMVVLMPQAASGIGMEGSDAPGAGPSADGTADGGADAGGAGAADGPAVPVLYLLHGLSDDCTIWERRTSIERYATEKGIAVVMPEVRRSFYTDEAVGEAYWTFVAEELPRIVARTFRVSTAREDTFVAGLSMGGFGALKLALNHPERFAAAASLSGAVDLTSMDLDWTGTLAQRVWGGREIAGTADDLLGLLGKRDPAELPALFLDCGTEDQLIDQNRRFLAAAEQAEVEVASRLRPGAHTWEFWDEGIQDVLDWLPIRG
->tr|A0A2D8DKP5|A0A2D8DKP5_9GAMM Oxidoreductase OS=Gammaproteobacteria bacterium OX=1913989 GN=CMQ67_01330 PE=4 SV=1
-MSDTYNAFVVDEIEDQFKSSIKSLPLPELQDGFVLIEVLYSSLNXKXALSASGNKGVTKSYPFTPGIDAVGKIRQSKDNNLKEGDEVIVTGYDLGMNTNGGFGEIIHVPSGWVVPXPNNLSMEEAISFGTAGITAAASVDAVLSKIDAPEXPVAVSGATGGVGSIAVGLLSKLGXDVTAITGKENSSQFLKDLGAKNIXLRDDFCSEKIRPLDKTKFSAGVDTVGGEILSRIISQVDRHGVITCCGNVNSIKLETTVFPFILRGIALQGIDSAESPITYKKYLWDKIASEWQIGYSKSSIKIIKLNELAPEIDKILNGNQQGXVVVKHGE
->tr|A0A562L573|A0A562L573_9GAMM Aspartate--tRNA ligase OS=Luteimonas cucumeris OX=985012 GN=aspS PE=3 SV=1
-MRTHFCGLVDEALIGQTVTLCGWADVARNLGGLCFIDLRDHEGIVQIVAEPDADMAGNADVIAAASQVGYEDCLRVTGVVRRRQSVNDKIRTGQVEVVATKIELLNKAEPLPFHAHENAGEDIRLKYRYLDLRTPEMQRKMRTRIKLVQALRRWLDARDFQDIETPILTKATPEGARDFLVPARMHPGEFYALPQSPQLFKQILMVAGFDRYYQIARCFRDEALRADRQLEFTQLDMEFAWVGERDVQDTTEEMIRSVFREVMGVELASEFPRMTYAEAMRRYGSDKPDLRIALELTDVAELVRNCEFKVFSDWANHADGRVVALRAPGAAALSRKQIDDYAAHAAKHGAKGLAWMKIEDAAKGRDGINSPIAKFLDDATLAAIVSATGAQSGDAIFFGAATYKSASDFMGALRLKLGKDLGLVADGWAPLWVTDFPMFEWDDEEQRYVALHHPFTAPAVDDAADLRANAKTAVSRGYDMVLNGNEIGGGSIRIHNSQMQSTVFELLGIGAEEAEGKFGFLLDALRFGAPPHGGIAFGIDRIAALMAGTESIRDVIAFPKTTTAQCLMTGAPSPVPDKQLAEVHVSIRPKAQP
->tr|A0A830CSJ2|A0A830CSJ2_9LAMI Uncharacterized protein OS=Phtheirospermum japonicum OX=374723 GN=PHJA_002054300 PE=4 SV=1
-MAMRTFYNEIKGMKVKELPAHLKPMFTIDYAKNSVKRGLDNYHAKYIETSSVDPLFHICFGGMIFSYLVALPEERRHLEHAKEHGGGH
->tr|A0A5R2N5V0|A0A5R2N5V0_9HYPH 23S rRNA (Pseudouridine(1915)-N(3))-methyltransferase RlmH (Fragment) OS=Mesorhizobium sp. M2D.F.Ca.ET.145.01.1.1 OX=2563933 GN=rlmH PE=3 SV=1
-MKISVHAVGRMKAGPERELADRYFERFAKSGPAVGLEFAGITEIAEGRAQSASERQRDEGSRLQAQLQPGTALILLDERGKNLSSQDFASHIGQLRNGGRKALVLAIGGADGHDPPLRDQAELVMSFGALTWPHQLVRVMLGEQLYRVATRSEEH
->tr|A0A7G8J7C1|A0A7G8J7C1_9SYNE Uncharacterized protein OS=Synechococcus sp. SYN20 OX=1050714 GN=SynSYN20_02147 PE=4 SV=1
-MVVDCLDHLFLILWSFTTFIDLGFRDLMFFDRLLHAFCFC
->tr|A0A1L8E3I3|A0A1L8E3I3_9DIPT UDP-glucose 4-epimerase OS=Nyssomyia neivai OX=330878 PE=3 SV=1
-MSNGKTVLVTGGAGYIGSHCVVSLQEAGYQVIALDNFTNAVNNFKNESMALQRVAQITGKDVAFYKCDLLDKEALEQIFQQYKIDSVIHFAAMKAVGESMQQPLLYYKNNLIGMIHLLEVMKKHKVFNLVFSSSCTVYGEPKELPITEEKETGKVTNVYGRTKFFIEEMLRDISVAEEEWNIIALRYFNPVGAHKSGLIGEDPTKQFTNLMPYISQVASGKKDCLTIFGDDYDTPDGTGIRDYIHVMDLSTGHVKALEKLEKQHLRLKMYNLGTGKGVSVLELLQTFERVNNVKVPYVIEARREGDISSMYADPTLAETELGWKAECTLEEMCTDFWRWQTMNPNGYKTGIVNGH
->tr|A0A1M3I4N8|A0A1M3I4N8_9SPHN 3-oxoacyl-ACP reductase OS=Sphingomonadales bacterium 63-6 OX=1895846 GN=BGO57_05825 PE=3 SV=1
-MSISFEGRVAIVTGAGGGLGRAYALELAKRGAKVVVNDLGGARDGTGHSDAALKVVEEIEAAGGEAMSNGASVTEYAQMVEMVAKAKEKWGGVHVLINNAGVLRDKSFSKMEPEDFEFVVKVHLFGSAYATKACWELMREQNYGRVMMTASSSGLFGNFGQANYGAAKLGLAGLAKTLHLEGAKYNIRVNTLAPLAATRMTEDIIPEQIFPMFAPENVVPAALFLVSEDAPNNVIVGAGAGGYHSAWVTMNTPVILPEGERSVEGFAAHWDQISSREGDFVPVSGMEQTQRVLAAIQKAAAGG
->tr|A0A7C6JME1|A0A7C6JME1_9BACT ABC-F family ATP-binding cassette domain-containing protein OS=Petrimonas sp. OX=2023866 GN=GXX67_10465 PE=4 SV=1
-MATPILQIDKLTKSFGDLLLFRESSFGIAEGEKVGLIARNGAGKTTLLNILAGKEPYDDGRVVFRNDTRVAYLEQSPTFDPDLTVMEACFSSDNEVVRLIARYEEVIASGDTSNLEEVLTQMDFHNAWERELQVKQVLTWLNITDFQQKMGELSGGQVKRVALANVLISEPDLLIMDEPTNHLDLEMVEWLEERLTRSSVTLLMVTHDRYFLDRVCTRLLEIDDQQIYAYKGNYSYYLEKREERVMAQQAEVERARNLLRKELEWMRRQPQARGTKAKYRIDAFHDLAEKARGESAEQSVRFAAKGSYIGKKIFEAKNVSKRFGDIRITESFNYTFTRYEKMGIVGKNGTGKSTFVKMLLGEVKPDSGYFEIGETVRFGYYSQEGMEFDEQLKVLEAVQKIAEVIDLGEGYRLTASQFLQHFLFPPEKQYDYVYKLSGGEKRRLYLCTVLLKNPNFLVLDEPTNDLDILTLNVLEEYLAGFKGCLIVVSHDRYFMDKVVDHLLVFHGDAKIQDFPGNYSQYREWKAEEDRREAAEAKAEAVKIEAAKAEAINPGKGRVALPNGKTDELGVGSSGETDPETTDLTTHGSKKGEKKRLTYKERQEYESLEGEIERLEKEKESISELLSSGNLPAEELISQSERLSLLLEQIDEKMMRWLELSERA
->tr|A0A839T1V7|A0A839T1V7_AZOMA Ribosome biogenesis GTPase OS=Azomonas macrocytogenes OX=69962 GN=FHR87_000879 PE=4 SV=1
-MAKRQLNRRQSWRIEKIQEERANRAARRESRLVDELEGGDLGREQEGLVIAHFGVQVEVEARQDELAGQIFRCHLRANLPALVTGDQVVWRPGNQGNGVIVAQLPRRTELCRPDSRGQLKPVAANVDRIVIVFAPLPEPHANLIDRYLVAAEHAGIQPLLLLNKADLVTAENQVRLETLLAVYRALDYPLLEVSARQGSGMDELKARLDGHVSVFVGQSGVGKSSLVNSLLPGLDTRVGALSELTGKGTHTTTTARLFHFPGGGELIDSPGIREFSLGHVTRAEIEAGFREFDDLLGRCRFRDCHHEHEPGCALLKALEQGRIHPQRMESYRHILSSLPQTEY
->tr|A0A523ZWY7|A0A523ZWY7_9ARCH Transcriptional regulator (Fragment) OS=Candidatus Bathyarchaeota archaeon OX=2026714 GN=E3J20_08840 PE=4 SV=1
-HLYVVESADFLFLMRQTGMTFGNLSSHMSRLETAGYIDVEKEFVGKKPNTKLHLTEDGRAAFQEYRRNMRHVFGDLSS
->tr|A0A0B5IZ06|A0A0B5IZ06_9VIRU Uncharacterized protein OS=Pandoravirus inopinatum OX=1605721 PE=4 SV=1
-MSQARRVGWRSRRPDAPIHYFFLLHRQTIAGEKRWSSFFGIVSVVLAPLFFSDKRPRPAPPAALSNRTRHGQAARLHTRKAHKACLLRHNQKSIIPSEKEEAEQEKGKQ
->tr|A0A7W5U4L6|A0A7W5U4L6_9HYPH Surface antigen OS=Rhizobium sp. BK612 OX=2586988 GN=FHX13_001390 PE=4 SV=1
-MKLRTFFLVVPSLFAALALSGCSTTSSLGGGKSLFSSAKPPASATFINALDGGIVERTGIKLSDSDKQRALEAEYRALETSPLGQPVAWKGRNASGEVVPAAPYQVGSQNCRQYTHTVTVDGKPTTARGAACRNDDGTWTPLE
->tr|A0A382FFA2|A0A382FFA2_9ZZZZ Uncharacterized protein (Fragment) OS=marine metagenome OX=408172 GN=METZ01_LOCUS214166 PE=4 SV=1
-VDKNIIAAGDKTTVEAAKEILWLGGNAYDAAVAAVFTSMTAEPALTGPGGGGHFMAYPADGRAVLFDFFVDMPSGVIEPN
->tr|A0A835W1B8|A0A835W1B8_CHLIN Uncharacterized protein OS=Chlamydomonas incerta OX=51695 GN=HXX76_008806 PE=4 SV=1
-MEEARVAAVSVSGGVRQQPQVQAQAQTRAASPAASAADAGVGATAATAATPGFAAATATDSAAAATAVAASGPAAAGGGRRPSRSAAVRARSAITHQLHEEQLPLAKREKRDAEFSEQVSDVEGDGVAGTGAAPAAATTAAAEPCGSPPVGDAAAAKQRPRKLRLLPRAPNVICAACAKSCAARGGFFAQGTGAYTCSSCCSRNRIECGFYGPPGTHSLEEAGGRKHNAQQSRPRGISPSASASEGATAVRVVTAATAGTAATAAPGAKAPSGTAAVAGLAAAGGGQKAAAAKAAVARATARVHGAAGASTARKRLPPPPPRPPPPPPPLEDAVPAEDATPAGDATPAPAQPAPPKCTTCGAVRAPHKLTSPGFFARGTGAYTCHGCCVRNLKSAHGFYGPPGTRSLEEAGGRECAECGTQGANSTSWRLHPDRLGHYLCSSCSGRYESRKRKLDRSGGGGGGPAPKAQKRSLGGVVDKASGGGDAPAAAENATAPAAAGKGGSGTKRQRQLAEAAGAGSRSGADAAASSAAAAAPATPAATRQAQSQQPKRQGPTKAASGTVRQAAPAAAAPDGPPAGGGGGAAPAAAAGRPPPAPEPKCSGCSSSFKRTDNGLFGFFSHGTGAYTCHGCCSRNQHAQGFYGPLGTRSLEEAGGRACAGCGRQDATQWRPYPPRLGAYACAACISKHTRRMQQEAQDPEGLTAPADAPRRQTPQPPQQQQQQPKQQPKQQPKQQPKQQQSQQQSPGQGQRQSQPQASGSGPAHSCATPAAPQAQGRGARLGAAPSRAATSAAPAARAQASSQAGASTGLCGASDAAATAATASMSRSTNATAATAFTSSEWTSPAVDGIRCDFCGGRFVRAATGQFGFFARGSSVYTCHGCCCRNLSRYAFYGPPGTRSLQEAGGRECASCRTTQAERWLPHRFRLGLYLCRPCRCRQDKGTLPKVGGGARGNQQAAAAATKAAAPKAVAAKPVAAAGGSARAPPQRRTAAARSEHVVGSDDEELEEQAADGEEEVEKAEDEAEDEEAARSARQRLEQEAAARVRSSRALLAASVDASAVAVAGLIAAEQAAGRRGSSSSGNNSSSCRLPAPPKLEQVAGRISAWLQAHVCQQPLALLLGPSAKALGLDREDGLLGLEAEEQETWNVCRARVCGVWLRVAHQAMEPAAATSPAADAAATAAAAAAAAAAVEARAGAQPAAPSSPAAVQQFRMVAFRASTALASELARWLRSAPRLEVPRASPPPAAPLTPAHAPAARPVRPAGPAEAAQHTSAPGPSQCAAASAAGDGAAVSAGAEVGGGSGGGGSALPPRSPAGSASGSGPAAELPGEDIRVLEAALQPLLLRSVCEAMWLGLTEGSAGDGGVGGGRRRI
->tr|A0A7X4ZEP7|A0A7X4ZEP7_9CLOT Sugar isomerase OS=Clostridiaceae bacterium OX=1898204 GN=D3Z55_07300 PE=4 SV=1
-MRNRMGKLKRNSIVALAAQIVNIISAFILPRLILSTFGSDVNGLVNSISQFLQIIGLLELGVGAVVESSLYKPLSERNNLKLSQIMTSATKFYKKIAIVLLIYSVGLVMLYPATVGQAYPFFDVAILIIALSVNSFAQYYFGMVNALLLNADQRSYIVQMLSIIATIANTVISVLLIYSGCSIQAVKVVSSFVFLSKPIFLNNYIKRHYQINYHEVYEVEPIPQKWYGIAQHMAHIVLDSTDVVILTIFSSLSSVSVYSVYNLVTNGMRSLVLSVGTGMQSLLGELIAKKEKGKLDTVFARLDWLIHTVAVVCFGCTMALVVPFVQIYTSGVTDINYVQSLFAFFISLAQCFRCIRLPYNVVILAAGHYKQTQSNYIVAALLNISISIFTVIRFGLVGVAIGTLVAFVYQNIWMAHYISKHIVCWPFKNFIRQTLIDLITLACGYAVTRSLYLGELNYVHWMLNGMLTSVIWIALSMIINFIFYRERLREIYYRYIRRLIG
->tr|A0A7J5A9S6|A0A7J5A9S6_9FLAO RecQ family ATP-dependent DNA helicase OS=Flavobacterium luteum OX=2026654 GN=F6464_13185 PE=4 SV=1
-MQTALQILQKYWKHDAFRSLQNEIIDAVLNGKDTFALMPTGGGKSICFQIPGMMKEGICLVISPLVALMKDQVANLQKKDIKAIALTGGIKSEEMIDLLDNCEFGNYKFLYLSPERLQSDWILERLKNLPINLIAIDEAHCVSQWGHDFRPAYLKIAELKPHFPKVPFLALTATATPKVKEDIIAELNLLNPQIFQKSFARENIAYMVFEVEDKLFRIEQILRKNPQPSIIYVRNRKSCLEVSSQLQSLGIKSTYYHGGLSPKEKDKNMQLWMREEVQVIVATNAFGMGIDKANVKTVIHIQLPENLENYYQEAGRCGRDGEKAFSVILTSPSDIVQAESQFIAVLPDKSFLNTMYVKLCNYFQIAYGEGINEQFSFNLNHFCLKYGFPILKTYNAMQFLDRQGIISLSQEFTEKITLQFLISSKEVIRYVSLNPNDESIILNILRTYPGVYDMQTSFNLQLIAKKSNHSENEVLAVLHKLKEKEIIDYHSRNNDATLIFNEVREDERTINRVSKYLERQNNLKKEQLDAVLHYIQEKSVCRSKLILNYFGEKTDSVCGVCSYCISKNSKKRNTTTTTEAIIILLNKGDLNSREIEIKLKYNAEDIIFALQQLLDNDTIMVKPNNKYSIKL
->tr|A0A7K6EWN1|A0A7K6EWN1_9PASS F162A protein (Fragment) OS=Grantiella picta OX=266360 GN=Fam162a_1 PE=3 SV=1
-LASLHPLLSLPDRAVKLLGKNIPSILRMSEGVDPKISRRLSIKPQEDLQPKSRSASGVPGYKPTNWEKRFLLWAGHYKKPEDIPETVSIETVRAAMTKLRVKFSYVMIALTIVGCITMVIRGKQAMKRHESLTSINLEKKAQWKAESASAKP
->tr|B0YHV5|B0YHV5_ULVIN Ribulose bisphosphate carboxylase large chain (Fragment) OS=Ulva intestinalis OX=3116 GN=rbcL PE=3 SV=1
-ILAAFRMTPQPGVPAEEAGAAVAAESSTGTWTTVWTDGLTSLDRYKGRCYDIEPLGEDDQYIAYIAYPLDLFEEGSVTNLFTSIVGNVFGFKALRALRLEDLRIPPAYVKTFQGPPHGIQVERDKLNKYGRGLLGCTIKPKLGLSAKNYGRAVYECLRGGLDFTKDDENVNSQPFMRWRDRFLFVAEAIYKSQSETGEVKGHYLNATAGTCEEMMERGQFAKDLGVPIVMHDYITGGFTANTTLSRFCRASGLLLHIHRAMHAVIDRQRNHGIHFRVLAKILRMSGGDHLHSGTVVGKLEGEREITLGFVDLMRDDYIE
->tr|A0A2S8NPN6|A0A2S8NPN6_9MOLU Uncharacterized protein OS=Spiroplasma sp. ChiS OX=2099885 GN=C6B38_09260 PE=4 SV=1
-MKTLHEMIKDLTGIDVEQDKISDYLEEEVLYLHGAYLRYANLSCANLKGIKITKKQLDQLTVIEENE
->tr|N8Y4E3|N8Y4E3_9GAMM Uncharacterized protein OS=Acinetobacter gerneri DSM 14967 = CIP 107464 OX=1120926 GN=F960_03962 PE=3 SV=1
-MKLDPQTALVHAERKAPQYIETVQAPIYRASTIIFKNTSALFDRHWTDDYDYSYGTHGTPTTYTLADNIAQIEGGHYCLLAPSGLSAINLVNSCFLSQGDEVWVADNIYGPNMEHLQDLAKRYGVIVKVYNALDVDSFQPSDKCKLLWLEAAGSVSLEFPDLVQLVKKAQALNILTALDNTWGAGLAFSPFDFSSEHLKVDISVHALTKYPSGGGDILMGSVVSQDKALHHKLFQTHAIQGISVSGDDVAQVQRSLASMQIRYEQQAKSALTLLAWLKQQKQFAQVLHPADPDAAGHQFWQEVCQTQKSAGLVSVIFNDHYDLTDIRKFCDNLNLFKLGFSWGGPVSLAMLYDLKKMRALDYPHLKQGFLVRFCIGLEEPNDLIQDIENALNKMK
->tr|A0A7S0UZ86|A0A7S0UZ86_9CRYP Hypothetical protein OS=Hemiselmis tepida OX=464990 GN=HTEP1355_LOCUS251 PE=4 SV=1
-FWFGGEKEKVTDHCRSWRARSLAGGGRLGARLGGRPTGDLTRSRQLGMLFARLAGKAPFDSPGAWDSPSADADIGGADYGKPINLSIYKSIKDDQCSRRRTGCDWTVVGPVTARSRRWEFK
->tr|A0A015LJQ4|A0A015LJQ4_RHIIW DNA helicase OS=Rhizophagus irregularis (strain DAOM 197198w) OX=1432141 GN=RirG_229180 PE=3 SV=1
-MSESPSRNRNENNTPEREQPSSPQTMSDAMLESPNRNRNENNTPEREQPSSPQTMSDAMLESPNRNRNENNTPEREQPSSPQTMSDAMLESPNRNRNENNTPEREQPSSPQTMSDAMLESPNRNRNENNTPEREQPSSPQTMSDAMLESPNRNRNENNTPEREQPSSPQTMSDAMLESPNRNRNENNTPEREQPSSPQTMSDAMLESPNRNRNENNTPEREQHFSPQTMSDAMLESPNRNENENNTSEREQRRSLTQTISDAADSTRNFISNALGLRQEQDNMSTPTHLRTENYSNVHTPRNLLSPATVASSLATPRSISSPRTPRRSQISHDNTPRKSQTSTPRRRINTNPENLAENPDNDLLKEYYEGIKSGSATPRTPRRQQRRGDIHSARSAKRLIDLDIQKGDEDVTMLEAEEKITTDQIWGTTIKVEEVRKSFKKFLKEFKLSDLSRRNGRSDDDPFYIEYLKIIERTEEFKFNLDTQNLLAFEDTHKLYYQIVRYPQEIIPILDYVVAQMYTELHEKEPKEDIRVFRVRPYNLGISKNMRELNPSDIDQLVCIKGLLIRSSPILPEMAVAFFRCSICDKSVEVEVDRSKIDEPSRCPRKQCNSSGTMVLIHNRSIFKDKQVCRLQETPDCIPDGQTPHTISLCLYDNLVDIARPGDKIELTAIYRSSPIRVNNRQRTIKSLFKTYLDVVHIRRSENIHENGDNDFTQIYHGLEDENKEVENVQEGFSHDHFSRDQKRKQLTFTEADIQYFKELSKNPLLYETLAHSLAPSIFGMDDVKKGILLQLFGGTNKLFRKSGSPRFRGDINVLLVGDPGTSKSQMLQYVHKIVPRGIYTSGKGSSAVGLTAYVTRDPDTKQMVLESGALVLSDGGVCCIDEFDKMSDGTRAVLHEVMEQQTVSVAKAGIITTLNARTSILASANPIDSKYDPKKSIVRNIDLPPTLMSRFDLIYLVLDKIDKQADWELATHLVSLYAEDSPFSASVNILPVETLAKYIHYARIHYNPIIGNDEAHKALVDAYVSLRRLGQDPRSSENIVTATTRQLESMIRLAEAHARMRLSNTVEMADVEEAERLLREAIKLSALDPETGRIDLDLITTGHGSYERRLLTVMREAFQKMLNRRNITSINWKKALEDFNEQSDVKINEKQFETMVNSLEQEGILRLAGNGNDREIITLNEDDE
->tr|Q0V3S1|Q0V3S1_PHANO Eukaryotic translation initiation factor 6 OS=Phaeosphaeria nodorum (strain SN15 / ATCC MYA-4574 / FGSC 10173) OX=321614 GN=TIF6 PE=3 SV=1
-MAVRAQFENSNEVGVFSTLTNAYAIVAVGASENFYSVFEAELQDVIPICHATIAGTRIVGRLTAGNKKGLLVPTTTTDQELQHLRNSIPDSVKIQRIEERLSALGNVICCNDHVALVHPDIERETEEIIADALGVEVFRQTIADNVLTGSYMALSNQGGIVHPKTSIQDQDELSSLLQVPLVAGSVNRGSAVVGAGMVVNDWMAVTGLDTTATELSVVESVFRLGEGNGPSNINTTHKDAMVESFY
->tr|A0A816CJR2|A0A816CJR2_ADIRI Hypothetical protein OS=Adineta ricciae OX=249248 GN=XAT740_LOCUS50392 PE=4 SV=1
-MSIIDVDDAKNRLQEYCQQRNLPLPIYSLIEKTGPDHSPMFQVEVIVDGMTFIGDRSTKKRVAEKLAASEALDYINKPQSPPKKIVNQQTKDPFTLFQSLNLEDESTEIESMEYD
->tr|K1XWP4|K1XWP4_9BACT Site-specific DNA-methyltransferase (adenine-specific) OS=uncultured bacterium (gcode 4) OX=1234023 GN=ACD_80C00146G0003 PE=3 SV=1
-MAQLFWTGTIKSHTEILQWFDESKISLIKKLHQDWKNWLLAGETEYEQTFNQLFFWELLGYENRINRIPKGAVIGTGIADLTLWYFDEGKYSPDDIQIVCELKGAKTNLVKKQFWHGGLSAVGQWFSYKTGLKNCKRLIVSNFYEIRLYRDNQTDFEVWTLDELIDPKDNYSNLRKLYLLLHRENLLAHTGKSKTEDLLSHFREEQKEITVKFYKEYKQLRIELINDIKQHNPWISIEILIEKAQKIIDRLIFIFFCEDKGLLPDKKLKENIVRSREAGFSAWEVTKKFFGLIDKGSEQLGIPSGYNGWLFQKDDVLDNLEIGDSICKKFTDMTNYDFDDKLSVNVLGHIFEQSISDLENLKIDLLGQEVETWQLADTGKGRRKKDGIFYTPEYIVDYIVQNSVMKYLNEKEDELIKKYRGEKNDPKLVAKAEIEAYQAYQNILQNIKVLDPACGSGAFLVRVFDVLFEENKRVWSILNSLFDESETYKNILTNNIYGVDLNEESVEITKLSLWLKSAQKGKKLNNLDGNIKCGNSLIDDVFIAREKAFDWNVQFKEIMKNGGFNVIVGNPPYVRTQNLDKNSKSFFDEKYKVSYKNYDIYILFVEKAFSLLESDWVCSYIMPKKFINTDYWEKFKMFLYENNFIDSFVDFWTNQIFGDATTYTWIFVFTKGIKKTLNYKNIDDLNQFPPIWFDSINYSNLSWKDWILTNPKEKELFWKLQKESFLWEFTDRVFQGLVTGVDGIYIMEQKWNNLFSKENGKSYTFDCDIVFPLLKWTEIKRYSTPSANYKIIFPYKIVDWKAILIDEETMKNKYAEIYNYLKEFEIKLRTREWWKFDNQNWYSYSRNQNIALMPSKKILTQVLSNHSSLTLDEAWKYFFVWWWTAGWYWISIDSNWKLDYKYLLTLLNSSLLEWFLHKYASPFNGWYYAYSRATMEKLPIKEIPLSDQQPFVERADKMLALNKDLYELTGKFLHRIQDNLKIEKLTKKLEKFYELDFKYFLIELKKQKVLLTLAQQDEREPYFKECKEKILALKGEIERTDKEIDDMVFDLYGLSEEERKVVFNG
->tr|A0A6I4N661|A0A6I4N661_9ACTN Transcriptional regulator WhiB OS=Streptomyces sp. BA2 OX=436595 GN=whiB PE=3 SV=1
-MDWRHNAVCREEDPELFFPIGNTGPALLQIEEAKAVCRRCPVMEQCLQWALESGQDSGVWGGLSEDERRAMKRRAARNRARQASA
->tr|A0A2V5BXM8|A0A2V5BXM8_9GAMM 50S ribosomal protein L23 OS=Pantoea sp. AG1095 OX=2184004 GN=rplW PE=3 SV=1
-MIREERLLKVVRAPHVSEKASTAMEKTNTIVLKVAKDATKAEIVAAVEKLFEVEVKDVNTLVVKGKVKRHGQRIGRRSDWKKAYVTLKEGQNLDFVGGAE
->tr|A0A4Q4HXK7|A0A4Q4HXK7_ECOLX IS3 family transposase (Fragment) OS=Escherichia coli OX=562 GN=EWK56_27125 PE=4 SV=1
-ELPTYGYRRVWALLRRQAELDGMPAINAKRVYRIMRQNALLLERKPAVPPSKRAHTGRVAVKESNQRWCSDGFEFRCDNGEKLRVTFALDCCDREALHWAVTTGGFNSETVQDVMLGAVERRFGNELPASPVEWLTDNGSCYRANETRQFARMLGLEPKSTAVRSPESNGIAESFVKTIKRDYISVMPKPDGLTAAKNLAEAFEHYNEWHPHSALGYRSPREYLRQ
->tr|A0A455L1B7|A0A455L1B7_9REOV Non-structural protein 2 (Fragment) OS=Rotavirus C OX=36427 GN=NSP2 PE=3 SV=1
-MAELACFVSFSLTEDKVKWFPINKKAVKTMLCAKVEKDQRSNYYDTILYGVAPPPEFRNRFKTTERHGLDYESDQYSEVVNLLADVLNMVSMPTEKFQFDIVKTVVQVRHLENLLLRIKDMDDILNENVKLRVKAVMIACNLVNETETTPLTESNDIVYQDSYFTITRLDYSSHKLLPLMTEEYKITINTKTDIPERDQTAFAAYIRYNFNKFAAISHGKRHWRLIPHSQLMAHAERLDRKIKSDKKHGRQFAYDDGDMAFVHPGWKACIGQLCGGTTFDVAKTSLYSVKTSKTVRTATNKIESDLISMVGN
->tr|A0A2N9NG79|A0A2N9NG79_9BACT Glutaredoxin OS=Verrucomicrobia bacterium OX=2026799 GN=SBV1_130006 PE=4 SV=1
-MNKPKIVAYLKPTCGWSQGVRAIFRKYDLPYEDRDIINDPAQRQEMIERSGQMLSPCVEIDGSMLADISGEEVEAYLLAHNLVTPSNREADAPIDQPCAHEAPPSAPLHFRR
->tr|A0A1X0RRK1|A0A1X0RRK1_RHIZD Chromatin modification-related protein EAF3 OS=Rhizopus microsporus OX=58291 GN=BCV71DRAFT_229219 PE=3 SV=1
-MYFVHYKGWKQTWDEWITEDRVLKYTESNRQKQKQLQEMNARLKTSRTPTRESTEPRGRKRYRDSDIERQRAEEETRRTEFKLIMPETLKGILVDDWENITKNRLVLNIPGEYTVDRILDEYKNQYPVKDDVLDEFIKGIRLYFNKTLGSLLLYRNEYDQYTELCADKEPSSIYGAEHLLRLFVEMPNLLAQASIDAETQNELKSRFEDFLNYMQEHEKDYFLNDYQTKA
->tr|A0A1C3EUB3|A0A1C3EUB3_9PLAN Translational regulator CsrA OS=Planctopirus hydrillae OX=1841610 GN=csrA PE=3 SV=1
-MLVLSRKAGESLLIGQGLLGEGIQVTVVAVQGNRVRLGITAPAEVSIRRQEIVLDLPEVAGSEEPCAMSSESHSRTPEFV
->tr|A0A810P5E5|A0A810P5E5_9MYCO Uncharacterized protein OS=Mycolicibacterium sp. TY81 OX=2759662 GN=MTY81_06740 PE=4 SV=1
-MPSTNWFERLTGFTEVDYESTCSRLSVDGNQLVSLVNGARYGTGTLRTPTLAELRATVTISDRGRTTVTCTVGDVGAMHGEPEFEGALFQVASQFNLLEMTHYTVTPEDGVTRYAHDHTQGPACAIAAGAGTIYRNYFAPVNGVPGQTADRQLNMLERLGLSLSTHLGRPISSLWRMENGYALCTADGLAAISDYLAAASPQTRDSLAGELAIGLHLGVEVTGVEPLPRQAVSQAYCSALPVAYSDVPQRYWEGFARLVLDSAYEATLLAAAESAANGWSNIVLLTRLGGGVFGNDDEWIDTAILRALKIVECAGLDVRLVSYGSVHPNMRGIADRWAR
->tr|A0A2T0Q272|A0A2T0Q272_9ACTN Acetylornithine deacetylase/succinyl-diaminopimelate desuccinylase-like protein OS=Allonocardiopsis opalescens OX=1144618 GN=CLV72_105245 PE=4 SV=1
-MAEVSGEGVEGGRAEVEVVDLCRELIRIDTSNPGDHSGPGERVAAEYVAAKLDEVGLATQIFESHPRRTSVVARMEGEDPSRPPLLLHGHLDVVPADAADWSRDPFGGEIADGCVWGRGAVDMKDMDAMILAMVRERMRTGRRPPRDIVLAFLADEEAGGYFGAKWLVDHHPELFADCTEAVGEVGGFSFTVRDDLRLYLIETAEKGIAWMRLTATGTAGHGSMVNDDNAVTELAEAVARLGRHRFPLRLTKTVRAFLEEVCDAFGIEFDPDDEEAVAETVARLGPIATMIGATLRNSVNPTMLRAGYKTNVIPQTATAEVDGRFLPGLEDEYFATIDELLGPKVTRDSERQLPAVETDFSGALVAAMADALKAEDPAARAVPYCLSGGTDAKAFAELGIKGYGFAPLKLPPELNFAGMFHGIDERVPVDGLQFGVRVLNRFVDNC
->tr|W1INK5|W1INK5_9GAMM Uncharacterized protein OS=Xenorhabdus cabanillasii JM26 OX=1427517 GN=XCR1_1340019 PE=4 SV=1
-MTEAQRTAFTVASGHFDITFLYLVCVGFFLAILFLWAAWAAVDVWNGWANEKVRNQTISQFAMRTAILLVVAVWMFAS
->tr|A0A520JI48|A0A520JI48_SPHSX PIN domain-containing protein OS=Sphingomonas sp. OX=28214 GN=EOP67_16805 PE=4 SV=1
-MAGRMTTVVDASVAVKFSVEELGSAAASDLIRSEPRLVAPDLILTEAANAYWAMVRGSRLLMIHAERNLDDLPRYFDRLYPTGTLIQQALRIAFHLRHPVYDCVYLALATKLECRLITADRKFHLKAADHYPIDLLPFETD
->tr|A0A2R7W9K3|A0A2R7W9K3_ONCFA Abhydrolase_2 domain-containing protein OS=Oncopeltus fasciatus OX=7536 GN=OFAS_OFAS008407 PE=3 SV=1
-MSGLESIRVGRAIEVEYLRLRPEAGRERTAGRFSSNMDRRYKVSGTHKFSNIILCVMVLKAWFSVSKDLIVNQQHVNKAIDLLDSIIQVEKENGIPLNRMIIGGISQGGMLAIDAVYRSYPKVAGCIAVSSVILDSNIFEAAKTRSKNPPLLMCVGSEDNAIGVELARESFQKIFKAGVPAEWKEFLGAHHELTVEELELIYERVKQLIPEKNL
->tr|M4H1V8|M4H1V8_PLEBA Putative secretory peptide-20 OS=Pleurobrachia bachei OX=34499 PE=2 SV=1
-MRCFLILISLLALSSATAAWNPVVRDTFIPFDLESTPLQIKTDSTAGSEEQIWVRTYTADGSLVGGVGLKFTSSIQYAIGFCNNNLWVSLPVQPPEEVDKVWTIRKNTTAVSIECNGVEVLNYQLSESSDTRCVSTWGGDVVEKIMFHSSLDTASDSYRTAAVWCPVVRDTLIPFDLESTPLQIKTDLTAGSEEQITVDTYNIGSSFIGGVGVKFTSPIQYGISFCTTSWTVLPVQPGDEVDKIWTIRKTTTAVRIECNGLEVLNYQFSDSSASSCVSRWGGDVVEKILFYAYDTASDSYRVKPVKSVCPEFTVDGSVQESWNDTDIGQTVTINCQRKHVLDGSSERTCNAEGVWDSDAPLCRKLSEFRWEIEKLGVMGLRVFPYYS
->tr|A1JIE2|A1JIE2_YERE8 Putative membrane protein OS=Yersinia enterocolitica serotype O:8 / biotype 1B (strain NCTC 13174 / 8081) OX=393305 GN=YE0246 PE=3 SV=1
-MPAFVISLWRQIVLSSPLFVLLALGYGLVRFGQWPSTITDGLTRFVFSLALPAMLFRMMCDFSERPAVDARLLIAFFGSCLVVFVIGRIIASRVFHLDGVSGSVFALGGIFSNNVMLGLPIATIMLGEKSIPAVALVLVFNGLILWTLVTISVEWARNGSPTLAGFAKTARSVLTNPLIIGIISGTLFSLTGLQLPQFIDQPVTMLGQVAPPLSLIVLGMGLAEYRVSEGWQISSAICFLKLIVQPMVIWALAWAMNLPALETQVVVLLGSMATGVNVYLMSRQFNVLTGPAAASLVMSTVLAAVTTPLILTIIGVGMS
->tr|D5EZ65|D5EZ65_PRER2 Uncharacterized protein OS=Prevotella ruminicola (strain ATCC 19189 / JCM 8958 / 23) OX=264731 GN=PRU_0802 PE=4 SV=1
-MKATELAQQQIERAIRKIADKFPPTQEANVMTDIHFRVTQDTGELMAFDDNDEEINRCIIEDWIGDTSDNFFEEIPAVFRKCLDKMKDTIENMSILKPFSFVLENEDKESVAELYLVDDETVIFDPELMKGLDEDLDAFLKQLLAD
->tr|S9WGT7|S9WGT7_CAMFR Uncharacterized protein OS=Camelus ferus OX=419612 GN=CB1_001879002 PE=3 SV=1
-MASNDTFYITTENSEMSTNIVELRQIHMETIPVETIPVETIPVETMALESIEGCEDISGSWVHGGHHQLPLMALQPLVISSPNPGDHDQEMIMVQTQEEVVGYFESDNLQAGNVENQILIPVDDDAFQQTLASLAASASSSAHSHSRTRSSQGKKPSGKKSCAGSKAEAASSSKVVTKKWEQKQVSIKTLEGEFSVTMWSANNNTDLKTGQTEEHPAPNFSENMTEKKLPPEGIPGVDFSDPKQLAEFTRMKPQNTKDETPRTIACPHKGCMKMFRDNSAMRKHLHTHGPRVHVCAECGKAFVESSKLKRHQLVHTGEKPFQCTFEGCGKRFSLDFNLRTHVRIHTGEKPFVCPFDCCNRKFAQSTNLKSHILTHVKNKKSQ
->tr|A0A183M848|A0A183M848_9TREM Uncharacterized protein OS=Schistosoma margrebowiei OX=48269 GN=SMRZ_LOCUS12223 PE=4 SV=1
-MMVGGSQQETLDPGFLLLGTRHQGVPVILKKLVLPGGFDLVSLSFTVID
->tr|K9U3M1|K9U3M1_CHRTP Sulfate ABC transporter, inner membrane subunit CysW OS=Chroococcidiopsis thermalis (strain PCC 7203) OX=251229 GN=Chro_3349 PE=4 SV=1
-MNSRMNNSKAKSREQKSWVPTILIVVAIAYVSLVLYIPALNVFIQAFSRGVGPFFANLTRPEFLHAVQLTVMLAAIALPLNTVFGLCAAWALTRHRFPGRAFVLSLIDLPFSISPVVAGLMIVLLYGRQGWFGGWLQDRGLNIIFAFPGMVLATAFVSMPFVAREVIPVLEELGSDQEEAAKTLGANDWQIFWRVTLPNIRWGLLYGLILTNARAMGEFGAVSVVSGNISGKTQSLPLFVEDAYKQYETEAAYSAAVLLALLAVVTLVLKEILERKTRIKDVE
->tr|A0A090PRU2|A0A090PRU2_NONUL Uncharacterized protein OS=Nonlabens ulvanivorans OX=906888 GN=JCM19298_2278 PE=4 SV=1
-MVIMKRIIYILCAVVGFTAAAQQTPAPATNKSYTIMNATAHIGNGELIENSVIVIENGKITTVADATTVKMQPKGEVINASGLHVYPGIIACNTTLGLVEIDAVKASDDDREIGTFNPHIRSLIAYNAESRVVETMRLMVFLLLK
->tr|A0A4S0ZDT7|A0A4S0ZDT7_9BACT NAD-dependent succinate-semialdehyde dehydrogenase (Fragment) OS=bacterium M00.F.Ca.ET.156.01.1.1 OX=2563902 GN=EN799_58250 PE=3 SV=1
-MPLCLPMIRRLKSPHLFGAIDRLPALGRPVGNKTFEVVNPSTGEVLAELPDMGVEETRAAVDKAYVAQSGWAALTARERSDVLWRWHQLIIDHAGDLAAILTAEMGKPLAEAISEVSHAAAYLQWYAEEANRVYGETISAPSTDRRMLVIKQPIGVVGTITPWNFPASMVARKISPALAAGCTIVLKPAEQTPLVAGAMFALAHQAGFPDGVVNLIYASEGDRVGRELCTNSKIRKISFTGSTEVGRLLMRQCSDQIKKVSLELGGNAPFIIFDDADIDGAVDGAVQAKFRNAGQTCVSANRIYVQSSVHDEFVKKFVERIRHLSVGDGFDAGVDIGPLIDKHALAKIESHIADAIAKGGTIRCGGQRIGKNGTFFEPTVLTEISSVMAVAQEETFGPLAPIIRFNDAD
->tr|A0A5P2QPP3|A0A5P2QPP3_9RHOB Uncharacterized protein OS=Paracoccus yeei OX=147645 GN=FOB51_08200 PE=4 SV=1
-MQIVGICRFSLLGRGDWAAFRTIPQDKADENAEAVEARKASIFAPERLERRFTTFEHLTLASIRAQTDPDFTFVVLASELMPQPYRDRLAALCAAVPQVVLRFFPVIHAGTAQGQVFKELGIDYRQTLQFRLDDDDALCNVYIRRMRQAAGGIVPNAFPFAASFRDVLFCSVGGDHAGVYQWRSPFFSAGVALFHPSASIFGFGHYGMAERFTSISIPGHMSLVTHNGMNDTTLDEGRIRRQKMNLIDDEAATKAVERHFPYLTPEARAVAGLPV
->tr|A0A252DKQ5|A0A252DKQ5_9NOSO DNA polymerase III subunit gamma/tau OS=Nostoc sp. RF31YmG OX=1932668 GN=dnaX PE=3 SV=1
-MSYEPLHHKYRPKSFAELVGQEAIATTLTNAICSSKIAPAYLFTGPRGTGKTSSARILAKSLNCLGSGKPTAEPCGVCDVCQGITKGYSLDVIEIDAASNTGVDNIREIIEKAQFAPVQCRYKVYVIDECLTGDSLVLTDEGLLRIDDPNIKNKRVLSYNDSSEKWEFKQVVRWLDQGERQTLVIKTTKGEIRCTGNHLVRTDRGWVAAKDVKEGVKILSPVNVDAAASFTNLATVESVYLAGVEQVYDIEVEDNHNFVANGLLVHNCHMLSTQAFNALLKTLEEPPKHVVFVLATTDPQRVLPTIISRCQRFDFRRINLEAMVKHLSAIAHKENIQISLDAVTLVAQIAQGGLRDAESLLDQLALLSGEIIPDRVWDLVGSVSERDLLGLLDAIAQDHAEAVLDCTRNILNRGREPLTILQNLAACYRDLLIAKTAPNRHDLVACTQQTWQAFIGLAQKLDITTILAGQKHLREAEVQIKNTTQPRLWLEVTLLGLLPSANIPVQAASVAPRVSAPVVSPSQPPITSSPPAVASPPVSPLSPPANNISALKAVPSQPPETITVSQPPEEPQPLHPPVQPVTPAASPPVPELIEDTEADFTQVWQQVLSNIQQIPRRELLRQMCHLMEFDGAYARVGVKSAWYKKVQTDLQMITAAFQQTFQREVKVSLEIGNPSTSTSAKKESSANGSSKLKQPSPPSYDKQIPPPAPVQPTPTPAPTKTEPTPKGNSGVQTLPPPTPTTSGDWETDEVAIAAQRLAEFFQGQIIRLSDDAAAFSETMVGSDLLDESDLDDE
->tr|A0A0B2USS7|A0A0B2USS7_TOXCA Cullin-4B OS=Toxocara canis OX=6265 GN=Cul4b PE=3 SV=1
-MFRSTEEPGLILMEACDYSRKYLVEPPSNANFSSPVVSGRDLDGWDVGLEIFRDVIMNNDRVRMRTTSGIIKLIETEREGAQIDRQLVKSLLRMMSSLGIYQAVFERRFLETTTALYETEGRNLSRDLEVPAYLLHVKRRLDEESNRVDYYLDASTRKELMAVAEKSLIVDHMEAFIDKGVESMLSGNHCSDLKLMYSLLARTKNGLVLLKSAFAAYIKVCTDHIFASLMFTLLPGVESMLSGNHCSDLKLMYSLLARTKNGLVLLKSAFAAYIKVCTDHIGCGVESMLSGNHCSDLKLMYSLLARTKNGLVLLKSAFAAYIKKVGQAMVMDSARDKTLVADLLVMKSKLDNMLKSCFRNNEKFVQAEKDAFDYFINTRANKPAELVAKYLDSKLRSGNKESTDEELENLMDEVIVIFRFIQGKDVFEAFYKKDLAKRLLLGRSASVDAEKSMLSKLKQECGAGFTTKLEGMFKDMELSKDLAVAFKQYLDHGGPDRALQHSDGHIEFSVNVLTMGHWPSYEPMDVVIPPYLAEYQELFKRFYLSKHSGRKLQWQHSLAQVLLRAHFKPTVVKELQVSMFQALVLLLFNEKTEWAVEEISNATKIETNELERTLQSLACGKLRVLLKTPRGKDIKPKDRLTFNEECNDRLYRIRICQVQMKETAEEHSQTEEQIFQDRQYQIDAAIVRIMKTRKSLAHQLLISELFKQLRFSVKPIDLKKRIESLIEREYMCRDKDDCNTYNYVA
->tr|A0A3R9XIK9|A0A3R9XIK9_9ACTN Uncharacterized protein OS=Streptomyces sp. WAC05374 OX=2487420 GN=E2B92_01640 PE=4 SV=1
-MDRSVWDGVERLRQWLDAKAAPATAGDVRLLRVLKIGEEYGEVAEALHGALGANPRKGASHTWQDVEQELCDVIVTSMVALATINGDGARLLDERVRHLVRRALPDEPA
->tr|A0A0E1UTW8|A0A0E1UTW8_BURPE ATP-dependent endonuclease, OLD family OS=Burkholderia pseudomallei Pakistan 9 OX=595498 GN=BUH_4320 PE=4 SV=1
-MRLCRFEVRNFKCVEYASLEWEDLLVLIGENNAGKSTILSAIAAFLSGSAIKDPSLFRRHLTDVANAIELIGHFDGLSDEETTQVAVRGRMNGDRWVLKKRYWFEAGEDGESGGWKEALYSFSGAERFEGWPEADATWNAFPEEYQPLIAALPNRGVRPTNAARETLREAVRRQRPDLVAFGAPNWVPNPGGGGNWKSNANSILPRPILVRAVQEASDETNAKDASTYGKLVNLIVERSLAQRPEMVRLQEALDEVLALFRPDEANPQRQAQEVRDLQDRINRSLNEVVGGQALIRTEAPEIRSMVLPSTSLVIRDVEAGIDTDVGHQGHGLQRTLVITLLQSLADAQAQVVPGAALAPVRANILLIEEPELYLHPQMERLMRDVLYRLAEQASTQVACCTHSPVFLDIATKYRAIIRMFKTPQGDAAAHQVTQDLFPGQPLQADRQRLNTVARFDPTVNELFFAKRVVLMEEFSAIAAFERGAELMGLFERHLRLRREVSLVDCNGKSNIPAFQRVLNAFNIPYRVLHDEDPGNPAEQANNQNILALLVAGANQRHLVAPDLEGLLGYQAPRKNKPFLAVSTVEDLHAQGQLPAAFREAVCMAYFGQAVEPLPPP
->tr|A0A5A7S8C7|A0A5A7S8C7_9NOCA TetR/AcrR family transcriptional regulator OS=Rhodococcus cavernicola OX=2495913 GN=FOY51_19370 PE=4 SV=1
-MPRSGAETRSHLLKVAGELFYAKGIRATGVDLVAVEAGVAPTTLYRQFASKDDLVGSYVEGVDLAFRDRFASAIAAAGAEPRDQIFAIFDDAIAQAAQDHFRGCPAQMALAEYPDPASSAHANAVTAKSWLLNSIAAVTERLDVDDSVALARQLFVVWEGMLASTMSMGSTGPAQQSRRIVEALLPGE
->tr|A0A3A5ZLU0|A0A3A5ZLU0_9BACE Inorganic phosphate transporter OS=Bacteroides sp. AF25-38AC OX=2292924 GN=DWY55_04125 PE=4 SV=1
-MELLVIIIVLALIFDYINGFHDAANSIATIVSTKVLTPFQAVIWAAFFNFVAFFIAKCVIGGFGIANTVSKTVMEPYITLPIILAGVIAAIAWNLFTWWKGIPSSSSHTLIGGFAGAAIMAHGFEAIQLSIILKIAAFIFLAPLIGMVVAFGFTLLVLYICRRAHPHTAEVWFKKLQLVSSALFSIGHGLNDSQKVMGIIAAAMIAGHSEGLGMGINSIDDLPDWVAFSCFTAISLGTMSGGWKIVKTMGTKITKVTPLEGVIAETAGAFTLYLTEYLKIPVSTTHTITGAIIGVGATKRLSAVRWGVTKSLMTAWVLTIPVSALLAAGIYCIVSLF
->tr|D6CL53|D6CL53_THIA3 UDP-N-acetylglucosamine 1-carboxyvinyltransferase OS=Thiomonas arsenitoxydans (strain DSM 22701 / CIP 110005 / 3As) OX=426114 GN=murA PE=3 SV=1
-MDKLRITGQRTLQGVVQASGAKNAALPLIAAALLTAETVQLNNAPQLMDVRTLAKLLRSLGAQVEQDGGQIRLSAAAVNHYEASYELVKTMRASVLVLGPLLARFGQARVSLPGGCAIGARPVDQHIKGLQALGADIAVEHGYIVARVATPSGRLRGARITTDMVTVTGTENLMMAATLAEGETLIDNAAREPEIVDLANLLRAMGAQIRGDGTSQIRIQGVDALHGASHRIIPDRIEVGTFLCAALAARGDVTVQGAEPAHQDALLDKLREAGAQIDTGADWVRLRADALPGGRPRAVSVRTTEYPGFATDMQAQFMAVNCLADGAARMTETIFENRFMHVQELMRLGAQIDIDGHTCVVHGVPQLSGATVMATDLRASAGLVVAALAAEGETVIDRIYHLDRGYDAMEVKLRGLGAQIERISDRISGK
->tr|A0A150TBH6|A0A150TBH6_SORCE Uncharacterized protein OS=Sorangium cellulosum OX=56 GN=BE18_01125 PE=4 SV=1
-MKTHDGYVALLASGGKRKLRANSLLAYGDEESRFKAAVLFHEAAEIERRALSLLEDAAPETRLRAAVERCACLVMGLDVVEAARAFREVEEASAAVPQETANAHRDRLDPLYFAARQDLTELLKRAPVLVSSRFRWEEIAETDRSRARAELDALLQRFPGESTFHLVDARAALDERRFDDLGRAVRRAHRLCPDNPLLRAYMLLVTAQSIAYPGSATTREEAEAELDTAYQELNREPADGVVYLGFMTASLAAFLAAFYAGEDAAEAHGRRARWAAEIAAQRRSIISEDIGKYIEAAGPLIELLTTQPQMLTAIIENTLREALLNSDVGRASGESLQQPKAASLIRGVISQASRWLTPSAELAELSELALAA
->tr|H3BNA2|H3BNA2_HUMAN Coronin (Fragment) OS=Homo sapiens OX=9606 GN=CORO1A PE=1 SV=1
-MSRQVVRSSKFRHVFGQPAKADQCYEDVRVSQTTWDSGFCAVNPKFVALICEASGGGAFLVLPLGKTGRVDKNAPTVCGHTAPVLDIAWCPHNDNVIASGSEDCTVMVWEIPDGGLMLPLREPVVTLEGHTKRVGIVAWHTTAQNVLL
->tr|A0A7L4N192|A0A7L4N192_9AVES FA11 factor (Fragment) OS=Ceyx cyanopectus OX=390723 GN=F11 PE=4 SV=1
-SARTVRIVGGTDSSPGEWPWQVSLHVKLSRQRHLCGGSIISKQWILTAAHCITSLENLNIWRVYAGILKQSEINEDTPFFKVEEIIVHPQYKYAQTGYDIALMKLDKPMNFTDLQLPICLPSKEDANILYTNCWVTGWGYRKEKGRVQDILQKAAVPLMSKEECQARYRKRTIGDKVICAGYEEGGRDACK
->tr|A0A373A0Y4|A0A373A0Y4_9ACTN DUF3117 domain-containing protein OS=Kitasatospora xanthocidica OX=83382 GN=DR950_28830 PE=4 SV=1
-MAAMKPRTGDGPLEVTKEGRGIIMRVPLEGGGRLVVELTPDEAQALGEALKKACG
->tr|K9IQ04|K9IQ04_DESRO DNA polymerase subunit gamma-1 OS=Desmodus rotundus OX=9430 PE=2 SV=1
-MNRLLWKKVAGSTVVGPGPVPAPRRWASSSVSVPVSSNGQPQVRSSEGGQLRYNPLHIQMLSRGLHEQIFGLGAETPGEAAVRRSVEHLQKHGLWGQPDAPLPDVELRLPSLYGGDLDQHFRLLAQKQSLPYLEAANSLLQAQLPPRPPSWAWAEGWTRYGPAGEAEPVAIPEERALVFDVEVCLAEGMCPTLAVAISPLAWYSWCSRRLVEERYSWTSQLSPADLIPLEVPARTGSPAQRGQQEQLVVGHNVSFDRAHIREQYLVQGSLTRFLDTMSMHMAISGLSSFQRSLWMAAKQGKRKAQHDTQRAQKPRSKANGPVVSSWDWLDISSVNNLADVHSLYVGGPPLRKEPRELFVKGSMRDIRENFQDLMQYCAQDVWATYEVFQQQLPLFLERCPHPVTLAGMLEMGVSYLPVNQNWERYLAEAQSTYEELQWEMKKSLMDLANDACQLLSGERYKEDPWLWDLEWDLQEFKQKKAKKVKRKEPEATSPLPVEAAEAPGAPEDQEDPGPPSEEEESQRAVATRTCLEQLKGTTALLPKRPQHLPGHPGWYRKLCPRLDDPAWAPGPSLLSLQMRVTPKLMALTWDGFPLHFSERHGWGYLVPGRRDNLAHVPASTSPAPTGVTCPYRAIESLYSKHCLEQGKRQPEPQEAGLAEDFLLAEEWQMVEELGCLEVQAEAEVEPAEGAVAAQPPAPTGTGRPRGSQPAYHHGNGPYHDVDIPGCWFFKLPHKDGNSCNVGSPFAKDFLPKMEDGTLQAGPGGASGPRALEINKMISFWRNAHKRISSQMVVWLPRSALPRVVTRHPDYDEEGRYGAILPQVVTAGTITRRAVEPTWLTASNARPDRVGSELKAMVQAPPGYVLVGADVDSQELWIAAVLGDAHFAGMHGCTAFGWMTLQGRKSRGTDLHSKTATTVGISREHAKIFNYGRIYGAGQPFAERLLMQFNHRLTLQEAAEKAQQMYAFTKGLRRYRLSDEGEWLVRQLHIPVERTEDGFVSLRDLRKIQREASRKSRRKNWKVVAERAWTGGTESEMFNKLESIAMSDEPRTPVLGCRISRALEPSVAQGEFMTSRVNWVVQSSAVDYLHLMLVAMKWLFEEFAIDGRFCISIHDEVRYLVQEGDRYRAALALQIANLLTRCMFAYKLGLNDLPQSVAFFSAVDIDRCLRKEVTMDCETPSNPTGMERRYGIPQGEALDIYQIIELTKGSLEKRSQPGP
->tr|A0A2N8M530|A0A2N8M530_9GAMM Short chain dehydrogenase OS=Alcanivorax sp. MD8A OX=1177157 GN=A15D_00345 PE=3 SV=1
-MKTVLITGAASGLGWALAQQAFALGYRVILADMNEVLLEARVEALAARDAERVTSRVLDVTNSDAVTLLVPWLEKHGGLDLLVNNAGITHRSLAEKTAMSVFQKVMAVDWQAPVELSVACLPLLKKSRGGIINIGSMAGWMPVLGRAGYCSAKSALGQFFEVMRGEVSRYGIHILMAYPSFLDTPIEKNALGHDGKPAAHARSMVGNMRTPEWMAEQVFEAYGKGRKRLFPDRFTWFASVLWRVAPDLYQRLMLRKFASELEQ
->tr|A0A8A9J5M6|A0A8A9J5M6_SARS2 ORF1ab polyprotein OS=Severe acute respiratory syndrome coronavirus 2 OX=2697049 GN=ORF1ab PE=4 SV=1
-MESLVPGFNEKTHVQLSLPVLQVRDVLVRGFGDSVEEVLSEARQHLKDGTCGLVEVEKGVLPQLEQPYVFIKRSDARTAPHGHVMVELVAELEGIQYGRSGETLGVLVPHVGEIPVAYRKVLLRKNGNKGAGGHSYGADLKSFDLGDELGTDPYEDFQENWNTKHSSGVTRELMRELNGGAYTRYVDNNFCGPDGYPLECIKDLLARAGKASCTLSEQLDFIDTKRGVYCCREHEHEIAWYTERSEKSYELQTPFEIKLAKKFDTFNGECPNFVFPLNSIIKTIQPRVEKKKLDGFMGRIRSVYPVASPNECNQMCLSTLMKCDHCGETSWQTGDFVKATCEFCGTENLTKEGATTCGYLPQNAVVKIYCPACHNSEVGPEHSLAEYHNESGLKTILRKGGRTIAFGGCVFSYVGCHNKCAYWVPRASANIGCNHTGVVGEGSEGLNDNLLEILQKEKVNINIVGDFKLNEEIAIILASFSASTSAFVETVKGLDYKAFKQIVESCGNFKVTKGKAKKGAWNIGEQKSILSPLYAFASEAARVVRSIFSRTLETAQNSVRVLQKAAITILDGISQYSLRLIDAMMFTSDLATNNLVVMAYITGGVVQLTSQWLTNIFGTVYEKLKPVLDWLEEKFKEGVEFLRDGWEIVKFISTCACEIVGGQIVTCAKEIKESVQTFFKLVNKFLALCADSIIIGGAKLKALNLGETFVTHSKGLYRKCVKSREETGLLMPLKAPKEIIFLEGETLPTEVLTEEVVLKTGDLQPLEQPTSEAVEAPLVGTPVCINGLMLLEIKDTEKYCALAPNMMVTNNTFTLKGGAPTKVTFGDDTVIEVQGYKSVNITFELDERIDKVLNEKCSAYTVELGTEVNEFACVVADAVIKTLQPVSELLTPLGIDLDEWSMATYYLFDESGEFKLASHMYCSFYPPDEDEEEGDCEEEEFEPSTQYEYGTEDDYQGKPLEFGATSAALQPEEEQEEDWLDDDSQQTVGQQDGSEDNQTTTIQTIVEVQPQLEMELTPVVQTIEVNSFSGYLKLTDNVYIKNADIVEEAKKVKPTVVVNAANVYLKHGGGVAGALNKATNNAMQVESDDYIATNGPLKVGGSCVLSGHNLAKHCLHVVGPNVNKGEDIQLLKSAYENFNQHEVLLAPLLSAGIFGADPIHSLRVCVDTVRTNVYLAVFDKNLYDKLVSSFLEMKSEKQVEQKIAEIPKEEVKPFITESKPSVEQRKQDDKKIKACVEEVTTTLEETKFLTENLLLYIDINGNLHPDSATLVSDIDITFLKKDAPYIVGDVVQEGVLTAVVIPTKKAGGTTEMLAKALRKVPTDNYITTYPGQGLNGYTVEEAKTVLKKCKSAFYILPSIISNEKQEILGTVSWNLREMLAHAEETRKLMPVCVETKAIVSTIQRKYKGIKIQEGVVDYGARFYFYTSKTTVASLINTLNDLNETLVTMPLGYVTHGLNLEEAARYMRSLKVPATVSVSSPDAVTAYNGYLTSSSKTPEEHFIETISLAGSYKDWSYSGQSTQLGIEFLKRGDKSVYYTSNPTTFHLDGEVITFDNLKTLLSLREVRIIKVFTTVDNINLHTQVVDMSMTYGQQFGPTYLDGADVTKIKPHNSHEGKTFYVLPNDDTLRVEAFEYYHTTDPSFLGRYMSALNHTKKWKYPQVNGLTSIKWADNNCYLATALLTLQQIELKFNPPALQDAYYRARAGEAANFCALILAYCNKTVGELGDVRETMSYLFQHANLDSCKRVLNVVCKTCGQQQTTLKGVEAVMYMGTLSYEQFKKGVQIPCTCGKQATKYLVQQESPFVMMSAPPAQYELKHGTFTCASEYTGNYQCGHYKHITSKETLYCIDGALLTKSSEYKGPITDVFYKENSYTTTIKPVTYKLDGVVCTEIDPKLDNYYKKDNSYFTEQPIDLVPNQPYPNASFDNFKFVCDNIKFADDLNQLTGYKKPASRELKVTFFPDLNGDVVAIDYKHYTPSFKKGAKLLHKPIVWHVNNATNKATYKPNTWCIRCLWSTKPVETSNSFDVLKSEDAQGMDNLACEDLKPVSEEVVENPTIQKDVLECNVKTTEVVGDIILKPANNSLKITEEVGHTDLMAAYVDNSSLTIKKPNELSRVLGLKTLATHGLAAVNSVPWDTIANYAKPFLNKVVSTTTNIVTRCLNRVCTNYMPYFFTLLLQLCTFTRSTNSRIKASMPTTIAKNTVKSVGKFCLEASFNYLKSPNFSKLINIIIWFLLLSVCLGSLIYSTAALGVLMSNLGMPSYCTGYREGYLNSTNVTIATYCTGSIPCSVCLSGLDSLDTYPSLETIQITISSFKWDLTAFGLVAEWFLAYILFTRFFYVLGLAAIMQLFFSYFAVHFISNSWLMWLIINLVQMAPISAMVRMYIFFASFYYVWKSYVHVVDGCNSSTCMMCYKRNRATRVECTTIVNGVRRSFYVYANGGKGFCKLHNWNCVNCDTFCAGSTFISDEVARDLSLQFKRPINPTDQSSYIVDSVTVKNGSIHLYFDKAGQKTYERHSLSHFVNLDNLRANNTKGSLPINVIVFDGKSKCEESSAKSASVYYSQLMCQPILLLDQALVSDVGDSAEVAVKMFDAYVNTFSSTFNVPMEKLKTLVATAEAELAKNVSLDNVLSTFISAARQGFVDSDVETKDVVECLKLSHQSDIEVTGDSCNNYMLTYNKVENMTPRDLGACIDCSARHINAQVAKSHNIALIWNVKDFMSLSEQLRKQIRSAAKKNNLPFKLTCATTRQVVNVVTTKIALKGGKIVNNWLKQLIKVTLVFLFVAAIFYLITPVHVMSKHTDFSSEIIGYKAIDGGVTRDIASTDTCFANKHADFDTWFSQRGGSYTNDKACPLIAAVITREVGFVVPGLPGTILRTTNGDFLHFLPRVFSAVGNICYTPSKLIEYTDFATSACVLAAECTIFKDASGKPVPYCYDTNVLEGSVAYESLRPDTRYVLMDGSIIQFPNTYLEGSVRVVTTFDSEYCRHGTCERSEAGVCVSTSGRWVLNNDYYRSLPGVFCGVDAVNLLTNMFTPLIQPIGALDISASIVAGGIVAIVVTCLAYYFMRFRRAFGEYSHVVAFNTLLFLMSFTVLCLTPVYSFLPGVYSVIYLYLTFYLTNDVSFLAHIQWMVMFTPLVPFWITIAYIICISTKHFYWFFSNYLKRRVVFNGVSFSTFEEAALCTFLLNKEMYLKLRSDVLLPLTQYNRYLALYNKYKYFSGAMDTTSYREAACCHLAKALNDFSNSGSDVLYQPPQTSITSAVLQSGFRKMAFPSGKVEGCMVQVTCGTTTLNGLWLDDVVYCPRHVICTSEDMLNPNYEDLLIRKSNHNFLVQAGNVQLRVIGHSMQNCVLKLKVDTANPKTPKYKFVRIQPGQTFSVLACYNGSPSGVYQCAMRPNFTIKGSFLNGSCGSVGFNIDYDCVSFCYMHHMELPTGVHAGTDLEGNFYGPFVDRQTAQAAGTDTTITVNVLAWLYAAVINGDRWFLNRFTTTLNDFNLVAMKYNYEPLTQDHVDILGPLSAQTGIAVLDMCASLKELLQNGMNGRTILGSALLEDEFTPFDVVRQCSGVTFQSAVKRTIKGTHHWLLLTILTSLLVLVQSTQWSLFFFLYENAFLPFAMGIIAMSAFAMMFVKHKHAFLCLFLLPSLAAVAYFNMVYMPASWVMRIMTWLDMVDTSLSGFKLKDCVMYASAVVLLILMTARTVYDDGARRVWTLMNVLTLVYKVYYGNALDQAISMWALIISVTSNYSGVVTTVMFLARGIVFMCVEYCPIFFITGNTLQCIMLVYCFLGYFCTCYFGLFCLLNRYFRLTLGVYDYLVSTQEFRYMNSQGLLPPKNSIDAFKLNIKLLGVGGKPCIKVATVQSKMSDVKCTSVVLLSVLQQLRVESSSKLWAQCVQLHNDILLAKDTTEAFEKMVSLLSVLLSMQGAVDINKLCEEMLDNRATLQAIASEFSSLPSYAAFATAQEAYEQAVANGDSEVVLKKLKKSLNVAKSEFDRDAAMQRKLEKMADQAMTQMYKQARSEDKRAKVTSAMQTMLFTMLRKLDNDALNNIINNARDGCVPLNIIPLTTAAKLMVVIPDYNTYKNTCDGTTFTYASALWEIQQVVDADSKIVQLSEISMDNSPNLAWPLIVTALRANSAVKLQNNELSPVALRQMSCAAGTTQTACTDDNALAYYNTTKGGRFVLALLSDLQDLKWARFPKSDGTGTIYTELEPPCRFVTDTPKGPKVKYLYFIKGLNNLNRGMVLGSLAATVRLQAGNATEVPANSTVLSFCAFAVDAAKAYKDYLASGGQPITNCVKMLCTHTGTGQAITVTPEANMDQESFGGASCCLYCRCHIDHPNPKGFCDLKGKYVQIPTTCANDPVGFTLKNTVCTVCGMWKGYGCSCDQLREPMLQSADAQSFLNRVCGVSAARLTPCGTGTSTDVVYRAFDIYNDKVAGFAKFLKTNCCRFQEKDEDDNLIDSYFVVKRHTFSNYQHEETIYNLLKDCPAVAKHDFFKFRIDGDMVPHISRQRLTKYTMADLVYALRHFDEGNCDTLKEILVTYNCCDDDYFNKKDWYDFVENPDILRVYANLGERVRQALLKTVQFCDAMRNAGIVGVLTLDNQDLNGNWYDFGDFIQTTPGSGVPVVDSYYSLLMPILTLTRALTAESHVDTDLTKPYIKWDLLKYDFTEERLKLFDRYFKYWDQTYHPNCVNCLDDRCILHCANFNVLFSTVFPLTSFGPLVRKIFVDGVPFVVSTGYHFRELGVVHNQDVNLHSSRLSFKELLVYAADPAMHAASGNLLLDKRTTCFSVAALTNNVAFQTVKPGNFNKDFYDFAVSKGFFKEGSSVELKHFFFAQDGNAAISDYDYYRYNLPTMCDIRQLLFVVEVVDKYFDCYDGGCINANQVIVNNLDKSAGFPFNKWGKARLYYDSMSYEDQDALFAYTKRNVIPTITQMNLKYAISAKNRARTVAGVSICSTMTNRQFHQKLLKSIAATRGATVVIGTSKFYGGWHNMLKTVYSDVENPHLMGWDYPKCDRAMPNMLRIMASLVLARKHTTCCSLSHRFYRLANECAQVLSEMVMCGGSLYVKPGGTSSGDATTAYANSVFNICQAVTANVNALLSTDGNKIADKYVRNLQHRLYECLYRNRDVDTDFVNEFYAYLRKHFSMMILSDDAVVCFNSTYASQGLVASIKNFKSVLYYQNNVFMSEAKCWTETDLTKGPHEFCSQHTMLVKQGDDYVYLPYPDPSRILGAGCFVDDIVKTDGTLMIERFVSLAIDAYPLTKHPNQEYADVFHLYLQYIRKLHDELTGHMLDMYSVMLTNDNTSRYWEPEFYEAMYTPHTVLQAVGACVLCNSQTSLRCGACIRRPFLCCKCCYDHVISTSHKLVLSVNPYVCNAPGCDVTDVTQLYLGGMSYYCKSHKPPISFPLCANGQVFGLYKNTCVGSDNVTDFNAIATCDWTNAGDYILANTCTERLKLFAAETLKATEETFKLSYGIATVREVLSDRELHLSWEVGKPRPPLNRNYVFTGYRVTKNSKVQIGEYTFEKGDYGDAVVYRGTTTYKLNVGDYFVLTSHTVMPLSAPTLVPQEHYVRITGLYPTLNISDEFSSNVANYQKVGMQKYSTLQGPPGTGKSHFAIGLALYYPSARIVYTACSHAAVDALCEKALKYLPIDKCSRIIPARARVECFDKFKVNSTLEQYVFCTVNALPETTADIVVFDEISMATNYDLSVVNARLRAKHYVYIGDPAQLPAPRTLLTKGTLEPEYFNSVCRLIKTIGPDMFLGTCRRCPAEIVDTVSALVYDNKLKAHKDKSAQCFKMFYKGVITHDVSSAINRPQIGVVREFLTRNPAWRKAVFISPYNSQNAVASKILGLPTQTVDSSQGSEYDYVIFTQTTETAHSCNVNRFNVAITRAKVGILCIMSDRDLYDKLQFTSLEIPRRNVATLQAENVTGLFKDCSKVITGLHPTQAPTHLSVDTKFKTEGLCVDIPGIPKDMTYRRLISMMGFKMNYQVNGYPNMFITREEAIRHVRAWIGFDVEGCHATREAVGTNLPLQLGFSTGVNLVAVPTGYVDTPNNTDFSRVSAKPPPGDQFKHLIPLMYKGLPWNVVRIKIVQMLSDTLKNLSDRVVFVLWAHGFELTSMKYFVKIGPERTCCLCDRRATCFSTASDTYACWHHSIGFDYVYNPFMIDVQQWGFTGNLQSNHDLYCQVHGNAHVASCDAIMTRCLAVHECFVKRVDWTIEYPIIGDELKINAACRKVQHMVVKAALLADKFPVLHDIGNPKAIKCVPQADVEWKFYDAQPCSDKAYKIEELFYSYATHSDKFTDGVCLFWNCNVDRYPANSIVCRFDTRVLSNLNLPGCDGGSLYVNKHAFHTPAFDKSAFVNLKQLPFFYYSDSPCESHGKQVVSDIDYVPLKSATCITRCNLGGAVCRHHANEYRLYLDAYNMMISAGFSLWVYKQFDTYNLWNTFTRLQSLENVAFNVVNKGHFDGQQGEVPVSIINNTVYTKVDGVDVELFENKTTLPVNVAFELWAKRNIKPVPEVKILNNLGVDIAANTVIWDYKRDAPAHISTIGVCSMTDIAKKPTETICAPLTVFFDGRVDGQVDLFRNARNGVLITEGSVKGLQPSVGPKQASLNGVTLIGEAVKTQFNYYKKVDGVVQQLPETYFTQSRNLQEFKPRSQMEIDFLELAMDEFIERYKLEGYAFEHIVYGDFSHSQLGGLHLLIGLAKRFRESPFELEDFIPMDSTVKNYFITDAQTGSSKCVCSVIDLLLDDFVEIIKSQDLSVVSKVVKVTIDYTEISFMLWCKDGHVETFYPKLQSSQAWQPGVAMPNLYKMQRMLLEKCDLQNYGDSATLPKGIMMNVAKYTQLCQYLNTLTLAVPYNMRVIHFGAGSDKGVAPGTAVLRQWLPTGMLLVDSDLNDFVSDADSTLIGDCATVHTANKWDLIISDMYDPKTKNVTKENDSKEGFFTYICGFIQQKLALGGSVAIKITEHSWNADLYKLMGHFAWWTAFVTNVNASSSEAFLIGCNYLGKPREQIDGYVMHANYIFWRNTNPIQLSSYSLFDMSKFPLKLRGTAVMSLKEGQINDMILSLLSKGRLIIRENNRVVISSDVLVNN
->tr|A0A2S2NUK6|A0A2S2NUK6_SCHGA Uncharacterized protein OS=Schizaphis graminum OX=13262 GN=g.56950 PE=4 SV=1
-MPYSIGSGFTRYTVGPSVRDVFGENEKIVFIIKLFAEYPAPKRSRDAFRLLSNGDIFFSTVVKNHFSGYRFLSMKNMKLCEKKYQRLSECVLEKRGSCEATSKTVKKNK
->tr|A0A438P4J0|A0A438P4J0_HELPX DEAD/DEAH box helicase OS=Helicobacter pylori OX=210 GN=ECB92_03930 PE=4 SV=1
-MELNQPPLPTEIDDDAYHKPSFNDLGLKESVLKSVYEAGFTSPSPIQEKAIPAVLQGRDVIAQAQTGTGKTAAFALPIINNLKNNHTIEALVITPTRELAMQISDEIFKLGKHTRTKTVCVYGGQSVKKQCEFIKKNPQVMIATPGRLLDHLKNERIHKFVPKVVVLDESDEMLDMGFLDDIEEIFDYLPSEAQILLFSATMPEPIKRLADKILENPIKIHIAPSNITNTDITQRFYVINEHERAEAIMRLLDTQAPKKSIVFTRTKKEADELHQFLASKNYKSTALHGDMDQRDRRASIMAFKKNDADVLVATDVASRGLDISGVSHVFNYHLPLNTESYIHRIGRTGRAGKKGMAITLVTPLEYKELLRMQKEIDSEIELFEIPTINENQIIKTLHDAKVSEGTISLYEQLTEIFEPSQLVLKLLSLQFETSKIGLNQQEIDAIQNPKEKTPKPSNKKTQHEPARSFKKGHYREKGSKTNHHSKKPKRR
->tr|A0A5D4XPJ5|A0A5D4XPJ5_9GAMM Uncharacterized protein OS=Luteimonas sp. XBU10 OX=1132694 GN=FZO89_00285 PE=4 SV=1
-MKAVAVSTVLLSSSLTAFAAMPEQVQFVGSIQHDDLTPVTFDLHLPSKQSATLKLADGSTLELVTPGGQASPDGARIRLLSPAGEIMHAATVPDPSLASTSFAYRICDGQVTYMSPAPAVVPDCGA
->tr|A0A0W0TLV5|A0A0W0TLV5_9GAMM MFS domain-containing protein OS=Legionella geestiana OX=45065 GN=Lgee_2174 PE=4 SV=1
-MHTEKNKHYMWYAWFVCALGAVFYSYEYFLRISPSVMEEALRAHFELNSAGFGKLSAFYYYAYVPMQLPVGILMDRYGPRRLLTIACMICVLGTWMFAGTSVFWVAASGRFLVGLGSAFAFVGVLKLATLWLPEDRLALVSGLATALGTIGAMLGDNILGALVDSAGWQQTVNLTAISGILLVLVLWLGLRDHPDSDEESGSIENFRQSIRDLCIIARNRQIWINGLYGCLVYLPTTVLAELWGIPYLQHAHGMTRSNADFANSLLFLGFTVGAPMMGFLADKLHRRKLPMMTGALGAVIVMSIILYMPGLTAMQINVLMVLLGLLYGAQAIVFAVGRELSPDEAAGTAMAMTNMIVMLGAMFLQPLVGYLLDWSGDYRIALSVIPLGMLIAAVLVFFLKETHAHAPQ
->tr|A0A556AMN3|A0A556AMN3_9BURK Putative glutamate--cysteine ligase 2 OS=Verticiella sediminum OX=1247510 GN=FOZ76_12590 PE=3 SV=1
-MHAIEFTPSRYNTLGIELELQLLDPRTLDLSGQAASLLEHIAGHPSADHVKPELTRAMIELNSSVHEHPAGLLAEMRELRDLVCEAGDAIGVRVAGGGAHPFTSWRDCDIHDSPRYRRLADLYGYLARQFTVFGQHIHLGVASGDAACGLIHRLSPYVPHFIALAASSPFREGEDTLFACSRLHALHSFPLAGHMPEHIRDWYQFEAHYTQMRSLGLTESLKDLYWDIRPKPELGTVELRVCDTPLTVEKACQLAAFAQALAIAVQRASAPTAAFWMAYETNRFQACRFGLHANYVTRAGERVRLIEHLRGTFEQLMPVADELGTTDLLGALREDALRLGNDARWLRARHHELRELPAVAAAAADVWRGEPAGAAQAGPGRRRVRASSEPIVHGLPLLPEGTPANLPPRLH
->tr|L7JZ93|L7JZ93_TRAHO Uncharacterized protein (Fragment) OS=Trachipleistophora hominis OX=72359 GN=THOM_0239 PE=4 SV=1
-VHPVSPSDVVGLTMLICKTMMGFMGLRERVTSSHMVGPEGHELDLGITGPKFRRDTFITDIEVFAGLFSLTMPFPEPERVKCFNKHIDRSLFVKKFDSSRCEVDMQALVLYIDDFYTACRVTSSLCKYALGFISLCMRPEYGDFGSILSDSPTSLFVELEKFKATGMGSAPACALREPSDFLLWYDRLCSLRALFVNYLTTRNGRFRGLVEMCRIAKEVEKDIEKLESEYNAYLDSQEGFVQDYFRTWGLVGGRGPLFIHSVPMIDVYQACTDKFKNKVNSLVARDDSPVVALMQNLRENGGVLPPDLVERRERFWEWQKKIKKEQKPMRVPINDLLLEFQSEDSGAFVFERQMTFMNLHQAIIERVARCWLNSSLYNDDQSMCNMQ
->tr|A0A6A1VVY6|A0A6A1VVY6_9ROSI Peptidyl-tRNA hydrolase ICT1, mitochondrial OS=Morella rubra OX=262757 GN=CJ030_MR4G021223 PE=4 SV=1
-MAIMRTTTSVILRGVVHLPSFSVSRFSALPGVGGTIGYTHRGISFGRIQCAASDSGDGRKVSARLSQVQQLLQEAEERALSADDEPTPKITIALLLRPEDVALVPYSISPVWSWKKRGKGPRGGQNSSTNSCIAWSFERVVTAKSYIGTVIGQQRFQPTFGWITDNYEAQLHFLYFWLFDWLDDSTIGSLQIIWLDHVTVNFARSGGPGGQNVNKVNTKVDMRFNVKSADWLSDRIKEKIIQMEKNRINKDGELVISSTKTRTQKGNIQDALEKLQVLKTPHCIRPYLYSVLEAIIDAASYVPPPPTEEQKKKIAKLAAIGEQKRLKSKKVLSEKKAFRRSRDSWD
->tr|A0A2D5SZF1|A0A2D5SZF1_PSEAS Methyltransferase OS=Pseudoalteromonas sp. OX=53249 GN=CMK64_03795 PE=4 SV=1
-MSVCGLCGSDELQPYHQDKRRRYLQCTQCALVIVDERDRLSPEDEKAIYDTHENSLHDEGYRRFLSRAFEPTVERVPSHSKGLDFGCGPGPLLAEMFKEVGFEMACFDLFYANEPEVLTKTYDFVTCTEVIEHLSQPGEVLAKLLSLLDAGGPLVLMTKLIIDQNRFAQWHYKNDLTHIVFFSRETFNYVAAHFDCQVEFIGNDVIVLTKSKK
->tr|A0A091NFS5|A0A091NFS5_9PASS Leucine-rich repeat-containing protein 45 (Fragment) OS=Acanthisitta chloris OX=57068 GN=N310_05272 PE=4 SV=1
-GVKLLLHGLCSNTTVKSLDLKGNNLRTVGAEALGKLLRQNKSIRSLTLEWNSLGMWEEGFSFFCQGLGANNFLQRLDLRNNQINHQGAAELAMALTQNDSLQELDLRWNNIGLLGGRALLNCLQSNRTLKKLELAGNNVPGDILKAVEQALDHNRDRETILSEAQNQVSILSKEVMSLKDEKNKQFLDLMDTVDKQKEEKARSERMSAAQISQLQEALDEHYSIVNSLKAKLQMTEAALALSEQKVHNLGELLNAMKQEQTSVAESHFKELQQQRQESADREDKLLHDLSAASEKNLLLRNQVGNQVLGREDQLFQVKQDLTNTTAELKLRAVQAEERLEMEKRRFKQSLEDMESLRVKEVDHMTQHIEASERSMQDRIQRLEAIRISLEEELSQVKAAALAERGQAEEELMKVRSQARLEEQQRLEHLEEKLRLMTESRDEAQNCCLKQKEMVAEAQARAKQCSMQADGLRRRLEELQQDLNRKEEEKVTEVNKVKVELQEQIGHLQAERTAQDGLREKIAALERQLKALSNNHREALLDKEGEMSLLLEKLRMKEAEISRMREEEAQRASFLQNAIMAYVQGSPLGTHSSRK
->tr|A0A817VJW3|A0A817VJW3_9BILA Hypothetical protein OS=Rotaria sp. Silwood1 OX=2762511 GN=CBO169_LOCUS792 PE=4 SV=1
-MAYVCSPQHCYQKNLSREKNSSDPSLVVHVNKFDIVPKVLNDYTYRTEVYLQQREKQNIDKTSSSSTSATITTWKILKYQKEMLKNDQAEIDRALSTINSIHEIFNRSASIPYNQVYSSLYGDNNKSDHLMKTFCRCQNHFRKEDDDNHIQTISSSFVNFEDTDSDLDYNEDEEEKKKTYDSGYETFKLIPIDVDLHTQKNMEEHSTNHYDIPGLVLRRGQSFSFTVTFNKDYDIEQNQLYIRLAIGPRSMISKRTQIRLLVDGTPSGNGWSAKSIPIEDDDVKTKKKNCISLQINSPSDAIIGKYTLLLEVCPSKNDDKKFLNKQDPTLFLIEADLYFLFNPWNKDDACALSSSEQINEYVMNEHGQIYLGTSNKPQPIPWYFGQFERSTLLTALTLLDKAKLPAQNRIDPSIIIRILSSKICSNPGTNNGIFPSSYDTKVYSSENHGYTSSTGIFKQYLLSNCRSVQGGCGNNWQHAAILCSLSRSLGIPCRIVTIYNAACQTDGTEDNDTHWDTKQRPLHKLNFDLICSSHVWNECWMRRHDLPNDEQDWQIVDSTPVQMCDGIRRTGPCSVSSLKNDKLSFRWDSPFIHSTINGKKSHWIVYPDGHMELLDVQENIVGTKIITRSLDNEFEPSDITKNYKNLMKTYNKYDNITERINNDVDIELKIPDNIEFGDDITFELNANNKSNEIRTIATALTISILSNNDQKLIVSHDQPVQTLNLEAEKNDHIQLKVTSKQYASYGKQENIILKYYIHSLIKETDQTFTRDDNIVFNKYDIIKPILDDDVIEIGKPVLLKILIANTLSHPINSGQIYIDGLGINQIVHVNRSFAPKESTTLHIKLYPTRIGVSRLYVTFISNNVSSSTQTIPLEIIREPIKQQHERINAQEEPLLTTNTETSAETDEKIEIPSKEDKLVTQSNISDRQDETLIHEEEQHPLVQSPSSLSSSINIADEYQDDRTSNISQPKFELSTTEDDDDDIAELNLKKNQDESSPNPNTSSSLPHDSTLSLEKDKISVDSLDIAHDRRYGTNNNQ
->tr|A0A819KK27|A0A819KK27_9BILA Hypothetical protein OS=Adineta steineri OX=433720 GN=JYZ213_LOCUS36401 PE=4 SV=1
-MELNKDNGSWIIHVTFKMGLVYMKWGRYDSAIRHFQGVLDYSSSIQSFPLEVIATFHEHLAMAYEKQRKYKEALNHWEKLLEIQTKIFEPFSIEIADTYLSMAENYLMLLEFGRVIEMWHKVKSVHLNPLSPNYNAASFLFNQMENPDTSSPEYIKTLLLQLRSHSASVKLKAQPSYISEKTEL
->tr|A0A2P1NJ72|A0A2P1NJ72_9BURK GP-PDE domain-containing protein OS=Pulveribacter suum OX=2116657 GN=C7H73_05065 PE=4 SV=1
-MKRRAVFALLAGATLAACGGGGDDLEPDQSRPIVIAHRGASGYLPEHTLGGYELAMRLGADYIEPDLQLTRDGALVAMHDETLERTTNVAALFPPRSGGYKVADFTLAEIKTLAVKPTGTGKASYPGFAPGSATPWSVPTFDEVIRLAQSSRSLVGREVGIYPEAKQADPAMEDAILKALVQGGYSARSRVFIQSFSDQTLRSMHVKAQAQGNPLPQILLGAAVMGADGVARLGVIGQAAQPVLLTFKDVASFAQGVGVVINASAYPITKAYIDQAHAVGLKVHGWTFAQPEAGAAAAEYRRYLELGMDGMFSNYPDLAVKARDQYVRERQADWGARGPAHPH
->tr|A0A7J2PPS0|A0A7J2PPS0_9ARCH Uncharacterized protein OS=archaeon OX=1906665 GN=ENH77_08385 PE=4 SV=1
-MTLRSRNESKINRFRALNNFLQNKYIILVFIGHKNQIDQTSTVIDVVDEFKIGSRYAYKLLEELESGRFIIKKAKVLKHGIYYSNYIITETAKSELREILKIITSIL
->tr|A0A6T8JG47|A0A6T8JG47_9STRA Hypothetical protein OS=Proboscia inermis OX=420281 GN=PINE0816_LOCUS10274 PE=4 SV=1
-ETGLLVDMDPSDQEKAGENLASALQGLLEEPERAIRLGKRGHAHVTERFGLEPFRREWNEIVTGAIPKGATRVSLRAAKNSANSVKQRMRTLARLLAFVAVVYQYGGEGLAVIQRKAAEHFKVIGTILRMVVALIAVMAIRYRS
->tr|A0A6P7FQQ6|A0A6P7FQQ6_DIAVI farnesol dehydrogenase-like OS=Diabrotica virgifera virgifera OX=50390 GN=LOC114332982 PE=3 SV=1
-MVLSMKRWIGKVAVVTGASSGIGAAVAKQLVEEGLLVVGLGRRKEKIESLGNRLSGKQGKLFAVKADLTKEDDIKQAFKWATENVGPISILINNAGTHIRTGLLDGDTEAWKTTINVNLLALCIATREAIQSMRKNSIDGHIIHINSFLGHNVAPLPDLDVYPATKYGVTALTETLRVELNSFNLKTKITSISPGFVDTEIIADMKNNEEFKRNVPNLLNPEDIADGIIYALSTPPHVQVHELTIKPLGEKY
->tr|A0A2G2QTX8|A0A2G2QTX8_9GAMM Heptose kinase OS=Porticoccus sp. OX=2024853 GN=COB19_03790 PE=4 SV=1
-MSCWFVDRAILSEAAAERFSSLDSVFATTGRRVTRCPISELILTEIGEKSYYVKRYSRRGKVIRRWLGRSRVRAEWENLLFFRGLGLRVPPIAAYGESGARGVLITEEVPGAIDLHSLVRQRPELLRDRNWLDQVVVQVADVAKQLHANSFAHNDLKWRNILVAGEVTPEVYLIDCPMGQTWWGPLLAYKKIKDIACLDKVAKYCLNRTVRLRFYLHYVGRDRLTAADKTFIRKVLAFFAGRE
->tr|C7GZL0|C7GZL0_9FIRM Uncharacterized protein OS=Eubacterium saphenum ATCC 49989 OX=592031 GN=GCWU000322_00425 PE=4 SV=1
-MGYDDFFMDIGALFVVLIVAFLGNGLGEFSFKYVAREVFILALLSTAGAFVWTLILAYLKYKRSNNKSK
->tr|A0A4S1VTE3|A0A4S1VTE3_ECOLX 4-aminobutyrate aminotransferase OS=Escherichia coli OX=562 GN=gabT PE=3 SV=1
-MSSNKELMQRRSQAVPRGVGQIHPIFADRAENCRVWDVEGREYLDFAGGIAVLNTGHLHPKVVAAVEAQLKKLSHTCFQVLAYEPYLELCEIMNQKVPGDFAKKTLLVTTGSEAVENAVKIARAATKRSGTIAFSGAYHGRTHYTLALTGKVNPYSAGMGLMPGHVYRALYPCPLHGISEDDAIASIHRIFKNDAAPEDIAAIVIEPVQGEGGFYAATPAFMQRLRVLCDEHGIMLIADEVQSGAGRTGTLFAMEQMGVAPDLTTFAKSIAGGFPLAGVTGRAEVMDAVAPGGLGGTYAGNPIACVAALEVLKVFEQENLLQKANDLGQKLKDGLLAIAEKHPEIGDVRGLGAMIAIELFEDGDHSKPDAKLTADIVARARDKGLILLSCGPYYNVLRILVPLTIEDAQIRQGLEIISQCFAEAKQ
->tr|A0A4U1G485|A0A4U1G485_9SPHI Methyltransferase domain-containing protein OS=Pedobacter sp. RP-1-16 OX=2572196 GN=FBD94_20505 PE=4 SV=1
-MNQELEIIRDQQQEVWNKFSAGWKKWDTLTMDFLKPVGDEMIRLLNPKGNDMVLDIASGTGEPGLTIASMLTNGKVTLTDLSADMLEIARENGADRGIKNIETIVCDVCELPFEDHTFDVISCRFGFMFFPDMLLAIKEMARVLKPGGRIATAVWNIPEKNFWVTASMGVIRKNMDIPVPPPEAPGMFRCAEAGMMSDLFKQAGLINISEKEVAGKMNCGTTDTYWNLMTDVAAPVVAALSKADQATKDKIKAEVYETINQKYADGDVVIDSSAIVIYAEK
->tr|A0A6G2IRX0|A0A6G2IRX0_STREE PTS fructose transporter subunit IIA OS=Streptococcus pneumoniae OX=1313 GN=GRB29_07185 PE=4 SV=1
-MKYLILVSHGGFAQGLKTSLAMFAEDKMDQVIALGLKNGSSVDDFAKECHQAVDHLTEEDTVIVLADIVGGSPLTTALTVLEEKGKLDTTVVLGGMNLPMALTSVVMKDDLEGDDFVAAVLPEASAALQEFKVATTTDNDEDDDI
->tr|A0A847WTI5|A0A847WTI5_9BACI Geranylgeranylglyceryl phosphate synthase family protein OS=Amphibacillus sp. OX=1872500 GN=GX972_07265 PE=4 SV=1
-KQFGSMIDWSELTTEGYVILNPEAKAYQLTNCYLPDREDVIAYAQMAEQMFNLPILYLEYSGTYGDPELVRQVKQHLNKTQLVYGGGITTLEQAKEMAQYADTIVVGNSLYDNFAEAIETVHVKE
->tr|A0A7W5HC73|A0A7W5HC73_9BURK Uncharacterized protein OS=Massilia umbonata OX=864828 GN=FHS02_002507 PE=4 SV=1
-MVHEEARPPQAARLPLPAPVVAQEIASPPQAAELPLPLPVVVHEMALPPHAAALPVPLPVVVQDIASPPHAASLPAPLPVVVQERARPPHAALLPTPLPVVVQEIARPPQSAWLPAPLPVDAQLIAIPPHAARFPGPEPVVMHDIARPPHAAQLPGPLPVVVQVAARPPQAA
->tr|A0A085DW41|A0A085DW41_9GAMM Uncharacterized protein OS=Halomonas sp. SUBG004 OX=1485007 GN=DK37_25465 PE=3 SV=1
-MSLHQDLIERDRKVTFHASTHLRDFAHGDAPGRVITGGKGIHIVDKDGREFIDGFAGLYCVNIGYGRTEVAEAIYKQALELSYYHTYVGHSNEPQIELSERVLKIAGLNMSKVYYGMSGSDANETQLKIVRYYNNVLGRPQKKKVISRMRGYHGSGIASGSLTGLKAFHDHFDLPIDTIRHTEAPHYYLRAAEQHGLTELEFSAYCADKLEAMILEEGPDTVAAFIGEPVLGTGGIVPPPEGYWEAIQPVLDKYDVLLIADEVVCGFGRTGSDFGSHHYNMKPDLITIAKGLTSAYQPLSGVIVGDKVWKVLEQGTGEYGPIGHGWTYSGHALGCAAGLANLDIIERENLVGNAAETGAYFQQQLKATFEGHPLLGDVRGVGLMAALEFSPDAKQRLHFDPTLKVGPRVAAAAMEENLIARAMPQGDILGFAPPLTINRGEVDEMIGRAKRAIDRVTDELVRAGDLKTGQQEAAFTI
->tr|A0A6A3RIU8|A0A6A3RIU8_9STRA Uncharacterized protein OS=Phytophthora fragariae OX=53985 GN=PF001_g20766 PE=4 SV=1
-MANLIKPITSGHDLIALAAKCDLTTDAVLDSTEVTKPLPHDKTYLILQRPADMDIGHWTCVHNGKYFDSMGEGPPTK
->tr|A0A2A2IY53|A0A2A2IY53_9PSED Cell division protein ZipA OS=Pseudomonas sp. HAR-UPW-AIA-41 OX=1985301 GN=zipA PE=3 SV=1
-MDIGLREWLIVIGIIVIAGILFDGWRRMSGNKGKLKFRLDNSFGNLPDEDVDPNLLGPVRVKEKHAEPQLDEHDLPSMTATDGGKKRSEPFQGDLSLDEPVPTLLNPVDDEVKSESPREQVPVDEVLVINVIARDPEGFKGPALLQNILESGLRFGEMDIFHRHESMAGNGEVLFSMANGVKPGTFDLDDIDLFSTRAVSFFLGLPGPRHPKQAFDLMVAAARKLSSELNGELKDEQRSVMTAQTIEHYRQRIADHERRKLTQKR
->tr|A0A2M9EG28|A0A2M9EG28_9GAMM Efflux transporter periplasmic adaptor subunit OS=Xanthomonadaceae bacterium NML95-0200 OX=2032577 GN=CO610_06720 PE=3 SV=1
-MSSQLRPNPPKRRGFWMPAIVIAVLAAGALWWWQGKRSGSDEGAFRTVQIEQGDIRVAISATGTLSAISTVTVGSQISGQVTEVLVDFNSPVKKGDVLARIDPSTYRAQIAQGDAAIASAQAVLRQAEANLRNVRADFSRKNELGAQQLVSRSDVDSARASLEQAEAQVNVARAQIRQQTANTQTTRLNLERTVIRSPVDGVVLMRKIEPGQTVAASLQAPELFTIAEDLSKMKIELGVDESDIGQVKAGQGVSFTVDAFPNRQFRGVVEQVRLAATTSNNVVTYPVVVTVDNSDGTLLPGLTVNAEIEVSKREGVLKVANAALRYKPSEATQALLGEAAASGGSGNARRGMSEKLPKIAAGLRLQPAQQQVFDEALAAMRAAQAERQGATRSGNGSAGGPPMMMRSGSAPDPAMMAQIRARMRERMQRQFAQFRSTLDDEQRAQWDSAMDALLNSNRAPLYLLVDGRPRRVMARIGASDGSSTEISGDFRAGDAVISGERAASSAR
->tr|A0A2D7G1K4|A0A2D7G1K4_9GAMM Uncharacterized protein OS=Gammaproteobacteria bacterium OX=1913989 GN=CMP96_10680 PE=4 SV=1
-MDLLKELFSFLRARKKLWLAPIILIMVALGGLLVIAEGSVLAPFIYTLF
->tr|A0A5E4IWU6|A0A5E4IWU6_9ARCH Protein-synthesizing GTPase OS=uncultured archaeon OX=115547 GN=eif2g PE=3 SV=1
-MPQAEFNVGVVGHVDHGKTTLTSALTGKWTDTHSEELKRGITIKLGYADVVFKQCTRCGFSSTKERCPKCGAPTQATRKIAFLDAPGHETLMATVIAASSIMDGALFVIAANEKCPQPQTIEHLMILEAAGIKNVVIAQNKVDLVTRQQALEHYKQIREFLKGTTYENAPIIPTAANSGGNLDSLVSALLETIKPVPRESGKTRMLVARSFDVNKPGTNVEKLYGGIVGGSIVSGVLKNGEEVRILPGALRTHKGKEHYQELSTKIVGIRVGDETLEEAKPGGLVALATTLDPSLTGADVLVGCLLFPAKDEPPVVYQTFSLEITPLSRLLEKFPSSFTPNEPLVLGVGTATTVGFVTKQKKKICELMLKKPVCASKTDVIAVMRRANNRWRLYGTAKLVS
->tr|A0A209CHN7|A0A209CHN7_9ACTN Flavin reductase OS=Streptomyces sp. CS057 OX=1982764 GN=B9W61_33485 PE=4 SV=1
-MTATPDLAPAPTAATPELFRSVFRRHAAGVAVITAAGERPVGFTATSLTSVAAEPPLISFGVGTSSSSWPVLSEAAYVGVHILGEHQHELAATFARSGADRFGPSTEWSSGPEGVPLLAGVSAWLVCRVVTRVPAGDHRIVIAEAVSGAPSGAARPLVYHQGRFTALRD
->tr|A0A1A7C0Q9|A0A1A7C0Q9_9BURK Porin OS=Janthinobacterium psychrotolerans OX=1747903 GN=ASR47_1005274 PE=4 SV=1
-MPIMKKSPLSLRAHQGASLLFLAISGTAAQAASLPEWTLGGFGTAGLVHSSERQADYSANVINRGGAGRTDRWSGSVDSRLGAQLGVEFTPRWSAVLQVIAEHNLQNSWLPVVEWANLKYQATPELSLRLGRIALPIYLAGDYRKPGYALEWVRPPVEVYGSLPVSNSDGVDASYRWQAGATNNLTQVFYGHTSIETDDGGKRARGRQLAGLSNTTTYGALTIRASALTAELTVDLVRPLFDAFRQYGLRGGQIADRYDADHKRVAIANLGVSYDTGDWFLQAEGSRLNTRSFLGDKSSMYLGGGYRLGAWTPYATYAKVKANVPNRDAGIDSAQPGAAYLNGQLNALLQRISSQHTISTGVRWDFLPDRAVKLQYDRLRPTGASSGTLVNVQPGFRTAHPIHVVSIALDFVF
->tr|A0A124SC33|A0A124SC33_CYNCS Homeobox domain-containing protein OS=Cynara cardunculus var. scolymus OX=59895 GN=Ccrd_005381 PE=3 SV=1
-MEVARFEDEQQHKNKFFGFNSMSQDYIFNFSHGFERPSQDQQQQNHISHQIRRDKLRVQDFEPPAPASLVGLEQVDEGTGGAGGINPAVYETGAGMLSEMFNFPTGGPATELLENQINYQHHRNQRPNSATGDWYGNSTAQAMQLFLMNPSHESPSSQSSSHHHHHHNSSTSSSTLHMLLPNTVPSSTSTLHHQQSFGSTSGSGQGQFGPSTQFAWIPPGGTTHEGGGGGGDSHGLSLSLSSTLQHLEAAKVEELRIGDDPAATAMLYFNQSGSDPYRHLQLQGGGGGVMGSTHHPIHVGYGSSTVGVVKALRTSRYVKAAQELLEEFCSVGRGQFKINKSGSKPANNPNQNPSNSCGGASSASSKDHPPLSSAERIEHQRRKSKLLSMLDEANRLTKITIETKKSRWIGDTITTMVVNSFDLILGFGAAVPYTALAQKAMSRHFRCLKDAITAQLKHSCELLGEKDVGTSGVTKGETPRLKMLEQSLRQQRAFHQMGMMEPEAWRPQRGLPERSVNILRAWLFEHFLHPYPSDADKHLLARQTGLSRNQVSNWFINARVRLWKPMVEEMYQQESKEEADQHHNHSPHHRHQDDDDDDEDDDQEQEEDKENTKYHNHNHDQNQTDNDGHHHHHPPPQPSSAATQTSMHAPPPPLTSAPTYTTTTTTATDSAAKRSEINDSENDPSLLAINTQHCFSENQAMTYSYSNPIGGITTMAPPPPPPFDGDTCRRGSMLGAEYRTTTGNDAADIGSTLIRFGTTSGDVSLTLGLRHAGNLPEKTSFFS
->tr|A0A1B1T822|A0A1B1T822_9NEOB KIAA2013 (Fragment) OS=Afrixalus dorsalis OX=367642 GN=KIAA2013 PE=4 SV=1
-PSKLSSISQLLQLWDLWKLTLQKRGCKSLVMAGAHGLMQGMMLSFGGLQFTENHLQFQSDPHVLHNSYALRGIHYNKDLINLAVLLDQDEKPFLHVSVKFQDKLVKLYACEAGCLNEPVELTSEIRGHTFPVLVTQPLTPLLYISTELTHLQDLRHTLHLKEILAHEEHMAKQYPGLPFL
->tr|A0A251VB46|A0A251VB46_HELAN Putative pentatricopeptide repeat-containing protein OS=Helianthus annuus OX=4232 GN=PPR38 PE=4 SV=1
-MMNRIAFIKLRGNFTTSSFLLHSETPFSSFHIGLHSDTRNVSVNRSMFDKITNLNDALNLFDEMSHRHPLPSVVKFTRLLNVVTKMKHFTYALDLFKQMCSLGVPLDKYTLSIAIKCCCQLNRTKDGFAVLGSCFRRAIPPDVYIFSVLLDGLVLEDRILEAEMFFKKLIKQKLCEPDVVMYNTMIKGLCKFGNNVTAVALLRLMEQTNCKPSIVTYSTIIDSLCKDKMIDDAFKLFKEMVFDIGILPNVITYTSLICGLCKLGRWDEASKMLKEMEDENISPDVQTFNVLVDAFCKEGKVEEAEAVINIMIERGKVPNIVTYNALIDGYCLRGEMIKANTIFDSMTLRGLVPDVVTYSSLLNGYCKNLNIEKAEQMFHEMTVKGLKPDVVTYSTMIQGFFQVGRCVAARRLFDEMHARGQIPDQCTYGIVLDGLCNNHLVEDALSLFYLVGKSKLNSDIAVYNILIDGAGKNGKVEVARILFQGLIDKGLQPDVRTYNVMISGFCREGQLGEAKLLFLKMEESGCPPNNITYCVLLQGCLKNKHYDDVEMLLKEMDARGYSLDASTLSLFIDHIAAGLLDRSMLKLFNKLVPKELLDDPRLCDWESN
->tr|A0A258FT73|A0A258FT73_9PROT Uncharacterized protein OS=Caulobacterales bacterium 32-69-10 OX=1970503 GN=B7Y99_04785 PE=4 SV=1
-MRCVAASLCEDTTTTVAALLRSTAQEMASLSDMSNRLHDLVARQMGAAVIHEQSVEEAQSIDLLVQHLETIGRFLHLLADEVPSSLAVDFSPIRDRLPLAALADRLGGEAGRRRLDDGDPGDLDLF
->tr|A0A329S1R4|A0A329S1R4_9STRA Uncharacterized protein OS=Phytophthora cactorum OX=29920 GN=PC110_g12992 PE=4 SV=1
-MRATAAKQRHKRRRPTAGQDDEGTVAATAGDKNGADRGEDGDESHGVVIAAV
->tr|A0A6A3VWU9|A0A6A3VWU9_9STRA Uncharacterized protein OS=Phytophthora fragariae OX=53985 GN=PF001_g28857 PE=4 SV=1
-MALLNRRFDSEDSATAIENLTAKLKKGIQAASTHFFEQEFPHDTREAILCTLDPTKTPLTPVQSGQAIRDHLEAIGRSTSKT
->tr|A0A0D0XGW5|A0A0D0XGW5_9TREE Unplaced genomic scaffold supercont2.14, whole genome shotgun sequence OS=Cryptococcus gattii VGIV IND107 OX=1296105 GN=I308_04987 PE=4 SV=1
-MPFRKTPCLSKPIIQFKLPFSSFSYPPCTPPERGTPAQTPGLAMSQTSWPRAMAVSFMIVTPPGQYSTQFPSLYPTEYPAEAAIDESSESDDQSVEDLMSLVTENEDGQERRWDGKGQEPLEKDAICPGAPKLSPIDLPN
->tr|A0A4Q1BKZ0|A0A4Q1BKZ0_TREME Uncharacterized protein OS=Tremella mesenterica OX=5217 GN=M231_04342 PE=4 SV=1
-MTGLTLPPLTLFLFSLLLFLLVGPTLVIASPDPTSPNVKRERLVAQAPSNTEITPIETKNIERGITTLPVLPRNDHPTSPPRLPRQPNRLVPQPTKRAEALIENDSVERFIDDVKVERRDEIGIGKRDDACSIAININLSDKTAPAIDLPSCLDGLDLQLGINLDLTDDDGGDDDCELGGGNFLAHSETSSNTKPPASTSKSANPGKSTPGNGGNDSDNIVALSWHVFGGNGYDGPSCGKTLTIVTSKGKQATAVVADECASCPDMYHVDMSTGLFSALGLDKSTGEYVVKWQCPDCVFEEDPTIGGCKNNPGGQYC
->tr|A0A1S1XQS9|A0A1S1XQS9_9XANT Transcription-repair coupling factor (Fragment) OS=Xanthomonas alfalfae OX=366650 GN=BHL63_10710 PE=3 SV=1
-ISQRLAALHRLPGLTRGVVIVPVQTLLQQLAPLSYIVGGSFDLTVGQRLDLDAEKRRLESAGYRNVPQVMDPGDFAVRGGLLDVFPMGADTPLRVELLDEDIDSIRVFDPESQRSLDKVDAVKMLPGREVPMDDASVERVLACLRERFDVDTRRSALYQDLKSGLAPSGIEYYLPMFFAKTATLFDYLDKRVLPVIATGVSNAADAFWTQAQNRYEQRRHDVERPLLPPDELYQSPDALRERLNKLARIEVWASDHARIDEAAPLGDQPLPPLPVAAKDAPAGQALATFLSHYPGRVLIAADSAGRREALMEVLAAAQLKPELVADVPAFLAGTLRFAITVAPLEDGFALDQPQIALLTERQLFPERANQPRRTRRVGREPEAIIRDLGELSEGAPIVHEDHGVGRYRGLIVLDAGGMPGEFLEIEYAKGDRLYVPVAQLHLISRYSGASAETAPLHSLGGEQWTRAKRKAAEKVRDVAAELLEIQARRRARAGLALQVDRAMYEPFAAGFPFEETGDQLAAIDATLRDLGSSQPMDRVVCGDVGFGKTEVAVRAAFAAASAGKQVAVLVPTTLLAEQHYRNFRDRFADYPMKVEVLSRFKSTKEIKAELEKVASGEIDVIIGTHRLLQPDVKFKDLGLVVVDEEQRFGVRQKEALKAMRANVHLLTLTATPIPRTLNMAMAGLRDLSIIATPPPNRLAVQTFITAWDNTLLREAFQRELSRGGQLYFLHNDVESIVRMQRDLSELVPEARIGIAHGQMPERELERVMLDFQKQRFNVLLSTTIIESGIDIPNANTIIINRADRFGLAQLHQLRGRVGRSHHRAYAYLVVPDRRSMTSDAEKRLEAIASMDELGAGFTLATHDLEIRGAGELLGEDQSGQMAEVGFSLYTELLERAVRSIRQGKLPDLDAGEEVRGADVELHVASLIPEDYLPDVHTRLTLYKRISSARDPDALRELQVEMIDRFGLLPDPVKHLFAIAELKLQANALGVRKLDLGENGGRLVFEAKPAIDPMTIIQMIQKQPKIYTMDGPDKLRIKLPMPEGADRFNAARGLLAALSPG
->tr|A0A241PHY0|A0A241PHY0_VIBAN Coenzyme A biosynthesis bifunctional protein CoaBC OS=Vibrio anguillarum OX=55601 GN=coaBC PE=3 SV=1
-MRRIFEEKTMQTLAGKKILLGISGGIAAYKCAELTRRLIERGAQVQVVMTHAAKEFITPLTMQAVSGRPVSDSLLDPAAEASMGHIELAKWADLVLLAPATADLIARVAAGMGNDLLTTLILATNAPVAVSPAMNQQMYRNIATQENIATLKRRGMMIWGPAAGEQACGDVGPGRMLEPMQLVERCEFFFQTEVANNTLLAGKSLLISAGPTREALDPVRYISNHSSGKMGYAIAQAAAQLGAKVTLISGPVNLLTPPQVQRIDVESACDMHQQVMAQAQSHDVFISCAAVADYRPEIVADQKIKKTDASDHMLITMVKNPDIVASVAALNENRPFTVGFAAETQQVEKYARAKLLNKKLDMICANDVSVAGQGFNSNDNALTVYWQGGEQALPLSSKSALAHALMQLIASQL
->tr|A0A4V1XBV3|A0A4V1XBV3_9PEZI Oxidored_FMN domain-containing protein OS=Monosporascus ibericus OX=155417 GN=DL764_002426 PE=4 SV=1
-MASPMSQSRLFEPLQIANGKITLKHRVVLAPLTRNRGTPLNPNSTCENPNRIWIPNDLMAEYYSQRTTDGGLLISEGIPPSLEGNAMPGVPGIFIQEQVEAWKRVTAAVHAKGGIIYAQLWHSGRANIPHLTGTPIVGPSSLPWDDPEECYMYPIPHTDTRVKLADHPPVEMTMSKIKQTIDDFRRAARAAMDAGFDGVEIHGGNGYLPEQFLSSNVNRRTDEYGGSPEKRCRFVLELMAEVAGAIGQENLAIRLTPFGLFNQARGEQRLETWGHLCRELKRDLPHLSYVSFVEPRYEQVFSEAEKQRFLDSWGLPDVDLLPFRRIFGETPFFSAGGWNDANSWGVLETGDYDALLYGRYFISNPDLVERLRHGRPLAPYDRSRFYGPFEDNSIGYIDYPPYKEDNDPPCEEDNGDEDRARRLSVL
->tr|A0A1C5LQ41|A0A1C5LQ41_9CLOT 4-hydroxy-tetrahydrodipicolinate reductase OS=uncultured Clostridium sp. OX=59620 GN=dapB PE=3 SV=1
-MTKIILSGANGKMGKVIARCTEERNDCEIVAGVDLNTQAYSDFDIYPSFSECGESGDVIVDFSNPAVLDGMLDYALKTNTPVVIATTGYSPEQIEKIQKAAEQIPVFFSFNMSLGVNLLVSLAKKAAEVLGGQFDIEIIEKHHNQKIDAPSGTALMIADAINDTLDQTQKYMYDRHAQRKKRDKNEIGIHSVRGGTIVGEHEVIFAGHDELLSLKHQAMSKEIFAVGAVNAAVFLKGKPAGIYDMGKMV
->tr|R7KGB8|R7KGB8_9BURK ATP synthase subunit delta OS=Sutterella sp. CAG:521 OX=1262977 GN=atpH PE=3 SV=1
-MAELSTIARPYAHAMLLALQDANKGPEEAADLAAVLDGIAQVVTTPELVSVIGDPKLSSEQIYDLIIAGLGQTKLPEEAANLLKVVVENGRLEAVPEIARQFRELKNQSEGVADAYIESAMPMTQAEVDDLVAGLGKRFPGLKLTPVVTINEALIGGVRVRVGDRVLDGSIQTRLAQMQEALTA
->tr|A0A496GGQ1|A0A496GGQ1_HELPX Uncharacterized protein OS=Helicobacter pylori OX=210 GN=DD744_03805 PE=4 SV=1
-MRIKAYFLRFIALVLIVLLGFSACKNSQKSQDSQNNTTQQDSPKTYTAMDLNNQEYTITGDLDSLNISPDSNTPTLLVLSALDDFLKDYAPTFNILKKTFKDRLRVLILLNQPYSSDAIKDFIAPFQADLMILNPKDTALFDHLNHNALNHSFNMLLYHKHQLIKMYQGIVPAEMLQFDISNLKD
->tr|A0A847F664|A0A847F664_9DELT Uncharacterized protein OS=Sandaracinaceae bacterium OX=2510337 GN=GX614_10825 PE=4 SV=1
-MSSPCLRIALIALLFALPSLSSADDGDLRLLRESIGYIEVADAADDEDPFDFNLSLGFRHDRVSGNITREMLSPVDGSVMQKVGDYSATRSYLDVAAEIGLYRDLAVRLMVPVLLSYDQSITDIESAATPLLGSQDAVSPTRSGIPEIIVGLAWQPMNQMRRADRPNWTWLFNVALPTGKVMSPCLDVPGSSCASNAGVSTGVVRLLPEWRLSYRFRYVETYGGLKGEIPFPTASRDSLFTPGGQLLGYRKTRPSIRGGFIVGAALIPWERRATHQRLAIDMRFHAHYVSGGRDFSPLFDVLGDPNLSPTPRFPEICEDGSVAGTGGVCNPGDPYATRFTGLTTTQSHGNIGGRLTLEIKAARYITFYVSSGLQWITSHLLTTESECNASVDPHPQDAINCNVGRPNPHYQREIDMVGNRFGVGNLTNLDLVLRAQGTF
->tr|B4RA04|B4RA04_PHEZH Transcriptional regulator, Cro/CI family OS=Phenylobacterium zucineum (strain HLK1) OX=450851 GN=PHZ_c3099 PE=4 SV=1
-MPRPATDPAKAAQIKALRQQAGRWLKAAREAAGMTQAELAEKVGLRYYTFVSQVESGLGRLPIETQAAWATALGLDPGEFARTLLRYYEPELFRLLFETDSAQGRATA
->tr|A0A1V2CHU8|A0A1V2CHU8_9FLAO Vgr family protein OS=[Flexibacter] sp. ATCC 35103 OX=1937528 GN=BXU01_03190 PE=4 SV=1
-MTPPTIIFGIDSKKISHFTSIELVQVINDHHRFEILVPHAAVESPLAYTLENAQAWLGKVVHIVLEEKNNFLGVVTNIDFDQEMGHSGNQIIVSGYSKTILLESGEKLHSWEELTLKDIVKEVVKNGAGEQLQNEINPEYTSKMDYQNQYLETDFQFIQRLAKQFNEWLYYDGEKLIFGKPKSFDSPISLTYNSEISKLKISVQAVPNKFSAFTYNESADKRYTAKSKDTVGGLPKLGNEAFASSKEVFATPAYTHGIVSTGDDLVLESFLKKKQESAAADTNFVSATTKNSKLRIGSIVTIQSSVLENKSLITQEVGSFIITEISHYATHLGEYENNFRAIPSKVLSLPEPDVAYPIAQTQQALVESNTDPQNKGRIRVQMLWQQGTQMKTAWLRVMTPDAGSSDKVGTNRGMVFIPDVGDHVMVHFRYGDPNRPFILGSVFHGKSGGGGGKDNNKRSFATRGGTSLVLDEEKNTFTATDPSGNMIMLNGDGTMTIYAPNKVDIQSKEINLIADEKVSISGVNEVSVDSKKVLVSGTDEVTVKSDTQITDEAPSINIKGKNTILAEGTVVDIDGKTMTNVKGGVVNLN
->tr|A0A7X9ZH40|A0A7X9ZH40_STACP Pur operon repressor OS=Staphylococcus capitis OX=29388 GN=purR PE=3 SV=1
-MRYKRSERIVFMTQYLMNHPNKLIPLTFFVKKFKQAKSSISEDVQIIKNTFQKEQLGTVITTAGASGGVTYKPMMSKAEATEVVNEVITHLQEKERLLPGGYLFLSDLVGNPTLLNKVGKLIASIYMEEQLDAVVTIATKGISLANAVANVLNLPVVVIRKDNKVTEGSTVSINYVSGSSRKIETMVLSKRTLAENSNVLVVDDFMRAGGSINGVMNLMNEFKAHVKGVSVLVESKEVKQRLIEDYTSLVRLSDVDEYNQEFKVEPGNSLSKFS
->tr|D2PK46|D2PK46_SULID UPF0148 protein LD85_1482 OS=Sulfolobus islandicus (strain L.D.8.5 / Lassen #2) OX=425944 GN=LD85_1482 PE=3 SV=1
-MTNESEVGVKKAAELLRQGATMLEEACPICKMPLFKLKNGDVVCPVHGKVYIVKSDDEEKIVKRNLQLDEIESILIDGLYLSAKKMKEDPLDSERIIQIIRYLDALERLRKIKINSSE
->tr|A0A353T2J5|A0A353T2J5_9FIRM FAD/NAD(P)-binding oxidoreductase (Fragment) OS=Clostridiales bacterium OX=1898207 GN=DDW86_03375 PE=4 SV=1
-TTEQGEIRASYLVNAAGVYGEVVSEMVQERSFTIHPRKGEYLLLDKSQGNLVHSVIFQTPTKMGKGVLVAPTVDGNLLTGPTALDVSEKDDVGTTAEGLEKIRKEAGKSVPDIPFRDVITSFAGLRATPDTGDFIIEASGTVKGFLNVVGIESPGLTAAPAIGEYAVDLLGKEGLPLVPRGDFQPVRKPAVRFREQTDEEKQRLIRENPLYGNVICRCEIITEGEIVDSIRRPAGARSLDGVKRRTRAGMGRCQGGFCTPRVTAILARELRIPEERVTKKGKGSELLAEKRGPSC
->tr|A0A3D6A882|A0A3D6A882_9FIRM Guanylate kinase (Fragment) OS=Lachnoclostridium sp. OX=2028282 GN=DHU73_00550 PE=4 SV=1
-KSATGKDTLYKEILKRRPKLRTVTMYTTRPIREGETDGVEYFFTDREELERQLASGKVIESRTYQTIAGPWTYYTVDDGQFDVADDESCLMIGTLESYEKMCAYFEAGKMVPVYIEVPDGIRLLRAVKREENQKKPNYREVCRRYLADEKDFSEENLERLGITKRYQNTDMEMCVEEILRDLDK
->tr|A0A5P9EVH6|A0A5P9EVH6_9GAMM Uncharacterized protein OS=Microbulbifer sp. THAF38 OX=2587856 GN=FIU95_07605 PE=4 SV=1
-MKKITSKYPQYRAVLKNSIASFTLICASTLVQADTISTKIDLGEPFPFKMEDGVEYEVDLDIGYQFDSIDNACISTEVKGGNASKAFLELESEPAAGSFILGYSESHEIGMIYSFDFPTQENPNPVSELISFGFCAGRFNGSLLKRNFLDGEGKFTVSVSGGYVEFWDFKLVVEGDLSDIQLAIELDEPADFSVPSYGGRVNYDASIRNLDSSQSLITLDQWSVLTLPNGDNYPIHKSRDVVLNYSEAKDYTRNYLTIPEWFEAGDYELTWYVADPSTGVRVKDSLHFTKSAD
->tr|A0A161IP46|A0A161IP46_9BACI Uncharacterized protein OS=Fictibacillus phosphorivorans OX=1221500 GN=ABE65_012790 PE=4 SV=1
-MKRQCLHMLTGFLFILLLTACIGEDYDAGPPELRLSVEEDLYALKQANVDWKTEEKEFKNKVEHFLTLGSEQKEIKLSPNQSAELILLENKEDDGEYTNETLEISLWKENEKIELTTKSSTDYSFSFPSDPGQYVLEVNFRTSNGRSQYVGNITLK
->tr|A0A2W4W2P1|A0A2W4W2P1_9CYAN Uma2 domain-containing protein OS=Leptolyngbya foveolarum OX=47253 GN=DCF25_12600 PE=4 SV=1
-MIAAKDHPPKLTSEEYFAWEEKQLEKHEYIDGQVYAMSGGSVNHGRLAIRLTAMFDNHLEESSYITGNSDIKVNIVKTVDYTYPDASVTCDDRDQNTPNYFTYPCLIVEVLSDSTEAYDRGGKFRMYQNNPVLQDYLLVSSTRIEMDLYHKNENGDWLILTYQKGDMVTLKSIGLSFPIEQVYRGLSLQQPDQFY
->tr|A0A1B2E8Q8|A0A1B2E8Q8_9BACL Serine/threonine protein phosphatase OS=Paenibacillus ihbetae OX=1870820 GN=BBD41_01205 PE=4 SV=1
-MLWILVIPVLNIFYAVLNQAHMPVYSLMTDLDAQIPFVPMFIIPYLIWYPFIIIVLFMLCIRERSVYYRTLLTQCLGLVACYIIFYLFQTTVERPTTMGTGIFEGLVNLVYSTDNPYNCFPSIHVLTSYLMIKGATACASYPNWERTAVKVCAWMIIASTLFVKQHVLLDIAGAIAVVELLWYGVGKLPLGQQSKFKGEVVRQNLTAD
->tr|A0A044SS46|A0A044SS46_ONCVO Methionine--tRNA ligase OS=Onchocerca volvulus OX=6282 PE=3 SV=1
-LHLMIRSIKTICAIEGVSISSMRLKHFITTPIFYANGPPHIGHLYTALLADALNRWKLLKDGNIDSDNLLFTSGTDEHGLKIQRSATAAGYDPQSYCDNISGKFKDLFHVFGIHPNDFIRTTEVRHKEVVNHVWVTKELNKRGQIQLGKYEGWYSTIDECFYASDEVETLSGQTSTISKITGSVVEWVQEENYIFPLSKYLGTVRNWLNNCDVIRPKIYFPEALQHASIEGNLSLSRDRKRVTWGIAVPNDESQTIYVWFDALMNYLTVSGIFSNKKRINWPPTCQIVGKDILKFHAVIWPAILLALDLPLPKRIFVHSHWLVNGTKMSKSVGNVVDPFSVSKSLSEEGLRYFLLRQGTPQNDANFIMSKAVDVINTDLVNNVGNLLQRSLIEKLNPSQTYPTFYPDSFHNSLLELGEPLVKSVSCLAELYEEQFDELMIYKALEMLMEVMRQANGFFQFYEPWKELDNRKMSSLLYVCYEVLRICGILLQPVVPHYADHLLNRLGIKKNERGLDNVKFTIDSKYSGKPLGEYNGPIMDRIMCKTGTV
->tr|A0A4D6LT85|A0A4D6LT85_VIGUN Uncharacterized protein OS=Vigna unguiculata OX=3917 GN=DEO72_LG5g291 PE=4 SV=1
-MPNDQEALGQLEDPHGSDGHNNSTGSGRHDDPNGSSELDNQDGLARSTTKTGRVGWVNDLNGPNGPNDPNGRHRSNDPNGPDRPDDSNMPICLTILIGLTGPMI
->tr|A0A0S6UQD0|A0A0S6UQD0_9BRAD Sulfopyruvate decarboxylase subunit beta OS=Bradyrhizobium sp. DOA9 OX=1126627 GN=BDOA9_0130710 PE=4 SV=1
-MSKANLLDRRQVVSTLLANRKDVVAIGGLGASTNDMCAAGDHARNFYLWGGMGGAAMIGLGLALAQPKLPVLVITGDGEMLMGMGSLATIGLQKPANLSIAVLDNEAYGETGGQTSHTSAAADLVGIAKACGINDSRAVTTMADVEAFAKAVHDVSAGPRFANVKIDSANLERILPTRDGTYIVNRIRADLGFQPI
->tr|A0A3R0JE73|A0A3R0JE73_SHIDY Anaerobic sulfatase maturase OS=Shigella dysenteriae OX=622 GN=DL723_09995 PE=3 SV=1
-MHVTAKPYSFQCNLKCDYCFYLEKESQFTHEKWMDDSTLKEFIKQYIAASGNQVYFTWQGGEPTLAGLDFFRKVIHYQQRYAGQKRIFNALQTNGILLNNEWCAFLKEHEFLVGISIDGPQELHDRYRRSNSGNGTFAKVIAAIERLKSYQVEFNTLTVINNVNVHYPLEVYHFLKSIGSKHMQFIELLETGTPNIDFSGHSENTFRIIDFSVPPTAYGKFMSTIFMQWVKNDVGEIFIRQFESFVSRFLGNGHTSCIFQESCKDNLVVESNGDIYECDHFVYPQYKIGNINKSELKTTNSVQLTAQKKRISAKCLKCVYKPICNGGCPKHRITKVNNETVSYFCEGYKILFSTMVPYMNAMVELAKNRVPLYHIMDVAKQMENN
->tr|A0A1V2IM99|A0A1V2IM99_9ACTN Uncharacterized protein OS=Frankia sp. BMG5.30 OX=1834514 GN=BL254_17150 PE=4 SV=1
-MSAEPIILLDPATDAGLIVAATEHTFACQMQTFAWAAANTNLPASERAIARAMTGRARAVSPLTQAQMNAQLHQTGGSR
->tr|A0A7V4T793|A0A7V4T793_9DELT Sigma-54-dependent Fis family transcriptional regulator OS=Desulfobacterales bacterium OX=2044940 GN=ENK36_05755 PE=4 SV=1
-MENILVVDDEKNYTMIIGEILQEEGYTSITASSGMEALDILNNEIIDLILTDVKMPGMSGIQLLEKIKELNPDIPVIIMTAFGSVEKAVDAMHRGAYTFILKPFENQALIAHIAKALSVYKIVQENSRLRDAISSRYSFDNIIGKSRPMQEIYEIIKKVAPSNASVLIEGESGTGKELVAKSLHYNSPRRNKPLIVVNCSAFAETLLESELFGHEKGAFTGASALKKGRFEISDQGTLFLDEIGELPISLQTKLLRVLQEKIIERVGGTLPIPVDFRLIAATNKNLEDEVKNGNFREDLYYRLNVVKTVMPPLRERSEDIPLLIKHFMDKYTNEQQLESRVSGITSEAVKILCDYQWKGNVRELENILESCILLGSGDMITPSDLPLQVRQNTSSFLDLDGIPQDVGLAETLTAVERRMIRRAMKLSGNVQTKAAQLLGIGKSGLNQKLKKFNLG
->tr|A0A6G1U079|A0A6G1U079_9BACT Virulence protein E OS=Prevotella copri OX=165179 GN=F7D73_08405 PE=4 SV=1
-MNINIFNGYQSTEPAIIKFQQMVDIIRGDKQLAELTKRYRITHQREYKSQCYCFSVTCVFQGGKAKKDIIEVTGIGFSDFDHVPKEKLAELCAKLREDRHTLFFHITASGEGLRVLYRYEMKPGMTLEEQMKFYPTAFLHGNQYFSDLLGVEYDEHCCNLGRLMGAAYDPDAFFRPNAEPFSYDWLVARQQEKTLQDNATARLRREVKKIDRLYEDKLAKELEQEMKTYVAGSKNEYVSCLAYKLNAFGFSADAALEFICQEFPDYERPKAVVDSCYRQTEEHGKRKHELQNRRHEAGKSASVNDIIRFLGEHVDLRYNQITMRVEYRMKEESDGEDSSTPGLWQIINDRAVNTLWSEMSKTNRAAVQDFFRVIESNYVQPFNPFTDYLGSLPEWHEGDTDYIQQLADSVTIKGGEEQQKLWACYLRKWLVGMLAGWTLDDVVNNVIIVLIGAQGSGKSTWIAMLLPPELRQYFYTKTNASRLTKDDLLVLATYGLMLCEELDTMKPSELNQLKAAVTMLTIDERAAYAHFAEHRPHIASFAATGNNVQFLSDPTGNRRWLPFEVESIQSPREHPFDYPHIYAQALHLLRSGFRYWFTQQEIIELNLHNHKFEAPRLERELVALYFAHPTEEQHGIFMTASRALQIIGAGISQKLSAVYVGRAFCELGFRKVRVNHCWGYLVIERDGDMIKAQQVRLAMEAEDDYSQQETDPDLPF
->tr|A0A806DEP4|A0A806DEP4_HAEI6 Catalase OS=Haemophilus influenzae (strain R2866) OX=262728 GN=hktE PE=4 SV=1
-MSSQCPFSHLAATNLTMGNGAPVADNQNSLTAGPRGPLLAQDLWLNEKLADFVREVIPERRMHAKGSGAFGTFTVTHDITKYTRAKIFSEVGKKTEMFARFTTVAGERGAADAERDIRGFALKFYTEEGNWDLVGNNTPVFFLRDPRKFPDLNKAVKRDPRTNMRSATNNWDFWTLLPEALHQVTVVMSDRGIPASYRHMHGFGSHTYSFWNEAGERFWVKFHFRTQQGIKNLTDAEAAEIIANDRESHQRDLYEAIERGDFPKWTLFVQIMPEADAEKVPYHPFDLTKVWPKKDYPLIEVGEFELNRNPENFFADVEQSAFAPSNLVPGIGASPDRMLQARLFNYADAQRYRLGVNYRQIPVNRPRCPVHSNQRDGQGRVDGNYGSLPHYEPNSFSQWQQQPDFAEPPLRINGDAAHWDYRNDDKDYFSQPRALFNLMNAEQKQSLFNNTAAAMGDAPDFIKYRHIRNCHWCDAAYGEGVAKALGLTVEDALKARDTDPALGQGGLL
->tr|W7JTJ0|W7JTJ0_PLAFA Uncharacterized protein OS=Plasmodium falciparum UGT5.1 OX=1237627 GN=C923_00937 PE=4 SV=1
-MSLINKKNKENHNLIGKEEKIENDNTQDIKDNVYSSYSNDNNKYDNNNNTYDNNNNKYDNNNNNFNINTNYLMNICPLFYSFMIFFNQLNSRKKLMKIINIIDEEKCLDKDENEINKKILSSICHGGVWDELVTLYDPIYSSNYESFINRKKNDYNKIYDKPIEMNKNGQDMQSKGNYTTTKNSTTNYNNIQKNDLNKKFVDATTGNTYSDRITAQSYIHDNNDENNNIHNYIDEIDDMDNVHNVVNSCGVHLNDVHSFQKDREDNSSYSYRRNEHMSNNIDTICGSKNLLLNHKGTNQDNNIFERNKENVSNSSYNYINENNTFSEKNFSTCSILKRRNVYHNKDYRYCFSTSQQNDGKYLEQNKSNVLHNDDYNDYYNDEYNDDYYDADNVDVFHYINKNKSNSIISNNYPCDNTYNQNTNLNNDNCKTKNNINMPLNINYPYGISKDEMIHFKNYPYNYNDKYDFDEDISSLMKNLKTDDYTNDDIINIKKKKKKGSLINNKNITDITTYTNSSSSLYNKNNNNKNNNNNYYYTNTKDNFYYNYNQNYDIPKKTYDNISTSCEPNHYMKNSSNNSSHHHSVYEGRYTFNKLNKTNKYMYNSFLPNKQQSFFNNNYNNNYNNNNYHCDYSKFDSEDLIWKYYNNPSNNRNHIKNIHNLEKKYEHNINLASKVSSATWLIYLYELKRASFFINYYFYHLHLFIYFKNYFINYQKNYKLFQNNKWIILKRNYEKQKKKEKYWDMINMKEPEINVHTTCISKKLNDIKAKNVLNNNDHMNKEDKQKNVIDQENNNKQKSNKTHYDIFKRDMHEIIKCTVQNLNYCIDALFEKTKGDIYSLPFKIDKKNKNKNKKINNNNNNNNNNNNNNNNNNNNSNSSSCSSSCCCFNNTTNISPQLNNIHSFLNNKNCKQNNINKDSMTNSYGLILIEGKLIFVKFLYICIDKEKFWDESFLCRRDIRTVIHVKALDVLFISKNKLKKKIKKNIKKKAKNEKDNNLNNIINQNICNNDKKDIYFDIEQNLCTNNKSSQEFSSSNTSNIDNQFLSDDIIFCEQKNNLLKDSKLTHQQTYDINTNLQNNKNHFEEKISMYNNTHKKNDHYVNDDIINLWKCKQEKELSNNFIYNNKNNYIGILMEQNSNQDIFFKNNSKFIIKKNYIDQNNEHMDNMKTYQNDQTDMEKKKYNDENIFSINPCNFVTRINVKTIYVSGKHIHDDLKGTLLQKIDIKKEFKNDDEMNTFLQNQKDIYDEEIYCLRIISRNEIMRYKELIKIMKKGPYYYKNAKNILNNLNNLNNFNTPLQQTVPLCNFCGIKGMCNINTKHYKMSSIQEHVKNKFYTFMYHIFYKYKPKNQGGNIHNNNNNNNEDHLICNHSSKFKHINKEKRNKELPTNYENNIFNHTIVTSKDDQHNCLSDTNYRDNNLSDQCKNYSFHNIYNCDDHENKSELKNNREDKNDHDMYNIVEDIKHTQRNNQYNYKDIKVDNHYDNIIHMDKEKNIEKINIKSNYTKNNSEQYVNKIENFNDKKCESQNNIINNNNNINNINNNIKTELLHQNEINKNCINNNSTFPIKDKQIINNSKGIKNNILSEYYKIKKRQKSIDKISKLYKDEIKKKNNNDFIPHNKKIMRINNTINCLVGQRAQTNFLFLKKNHLNTTTENITTKIVTGAQNNNLNNVSLKKNNSGQMEENNTNDISYVPTFRKFQESKK
->tr|H6AA47|H6AA47_PINCO Tubulin_C domain-containing protein (Fragment) OS=Pinus contorta var. murrayana OX=1115831 PE=3 SV=1
-QVYRSLTVPELTQQMWDAKNMMCAADPRHGRYLTASAMFRGRMSTKEVDEQMLNVQNKNSSYFVEWIPNNVKSSVCDIPPKGLKMASTFIGNSTSIQEMFRRVSEQFTAMFRRKA
->tr|A0A7V8T8F4|A0A7V8T8F4_9GAMM Nuclease SbcCD subunit D OS=Pectobacterium versatile OX=2488639 GN=sbcD PE=3 SV=1
-MRIIHTADWHLGQYFYTKSRAAEHQAFLHWLIAQVEQHQVDAIIVAGDIFDNGSPPSYAREMYYSFVVALQRTGCQLIVLGGNHDSVAMLNESRELLACLNTQVIACASDDPAQQVILLETRQRQPGALLCAIPFLRPRDVLTSKAGQSGDEKQLALQEAITAHYLQCYQLACQKRDELGLPLPIIATGHLTTIGATASESVRDIYIGTLDAFPAQAFPPADYIALGHIHRPQRVTQSEHIRYSGSPIPLSFDELNSEKSVCLVSFAPDTPAQVEILPTPVTQPMQLIKGSLSDIEQQLTTFQNYQGEKPVWLDIEINTQDYLSDMQKRIQAMTEHLPVEVLLLRRTREQRLQAITQQDKETLNELSVHDVFERRLATETDMEDGRQQRVRTLFNQVIDELENSEPAQ
->tr|E2ZKL4|E2ZKL4_9FIRM Alkaline phosphatase family protein OS=Faecalibacterium cf. prausnitzii KLE1255 OX=748224 GN=HMPREF9436_02217 PE=3 SV=1
-MKREDHVMKENKISRRSFLKFGAAASAAGMMAAAPVAANAAQPDADAAADEENCLLGLFQKPKYIFLFIGDGMGTAQIQSARFYKGTVDNNGAVTEADLSFTSFPTVGSVTTYDSTSFCPDSASTATSIATGHKTESGVINMCPWTRDVPYETIAEKLHAQKGYKVGIISSVNIDHATPAAFYAHQKTRKNYYQIGVELANSGFEYFAGGEFQKVNGDGAGPNNHEVAAQAGYNVVTTQAGAAALTAGAGKTLIIAENLADGKAMNYAMDAAAGEWQLTDYVKKGIELLDNPKGFFLMTESGKIDWACHANDAAASIHDVLEMSNAVQAAVEFQQKHPNDTLILVTADHETGGMAIGYKTTNYDTFLTNLAHQKMSYAKFDSTYVQNYIANKTPFEAAMQDVKANFGLTLPSDPDAANAGKLLLTDYEVQNLRTAYERTLKVGSASQKDMSQQDYEMYGTYIPFSMAICHTINHKSGMDHTTYAHTGAMVNVYANGVGAEKFGGVFDNTEIYHKLADLTKVK
->tr|A0A8A6LC47|A0A8A6LC47_SARS2 Surface glycoprotein OS=Severe acute respiratory syndrome coronavirus 2 OX=2697049 GN=S PE=4 SV=1
-MFVFLVLLPLVSSQCVNLTTRTQLPPAYTNSFTRGVYYPDKVFRSSVLHSTQDLFLPFFSNVTWFHAIHVSGTNGTKRFDNPVLPFNDGVYFASTEKSNIIRGWIFGTTLDSKTQSLLIVNNATNVVIKVCEFQFCNDPFLGVYHKNNKSWMESEFRVYSSANNCTFEYVSQPFLMDLEGKQGNFKNLREFVFKNIDGYFKIYSKHTPINLVRDLPQGFSALEPLVDLPIGINITRFQTLLALHRSYLTPGDSSSGWTAGAAAYYVGYLQPRTFLLKYNENGTITDAVDCALDPLSETKCTLKSFTVEKGIYQTSNFRVQPTESIVRFPNITNLCPFGEVFNATRFASVYAWNRKRISNCVADYSVLYNSASFSTFKCYGVSPTKLNDLCFTNVYADSFVIRGDEVRQIAPGQTGKIADYNYKLPDDFTGCVIAWNSNNLDSKVGGNYNYLYRLFRKSNLKPFERDISTEIYQAGSTPCNGVEGFNCYFPLQSYGFQPTYGVGYQPYRVVVLSFELLHAPATVCGPKKSTNLVKNKCVNFNFNGLTGTGVLTESNKKFLPFQQFGRDIDDTTDAVRDPQTLEILDITPCSFGGVSVITPGTNTSNQVAVLYQGVNCTEVPVAIHADQLTPTWRVYSTGSNVFQTRAGCLIGAEHVNNSYECDIPIGAGICASYQTQTNSHRRARSVASQSIIAYTMSLGAENSVAYSNNSIAIPINFTISVTTEILPVSMTKTSVDCTMYICGDSTECSNLLLQYGSFCTQLNRALTGIAVEQDKNTQEVFAQVKQIYKTPPIKDFGGFNFSQILPDPSKPSKRSFIEDLLFNKVTLADAGFIKQYGDCLGDIAARDLICAQKFNGLTVLPPLLTDEMIAQYTSALLAGTITSGWTFGAGAALQIPFAMQMAYRFNGIGVTQNVLYENQKLIANQFNSAIGKIQDSLSSTASALGKLQDVVNQNAQALNTLVKQLSSNFGAISSVLNDILARLDKVEAEVQIDRLITGRLQSLQTYVTQQLIRAAEIRASANLAATKMSECVLGQSKRVDFCGKGYHLMSFPQSAPHGVVFLHVTYVPAQEKNFTTAPAICHDGKAHFPREGVFVSNGTHWFVTQRNFYEPQIITTHNTFVSGNCDVVIGIVNNTVYDPLQPELDSFKEELDKYFKNHTSPDVDLGDISGINASVVNIQKEIDRLNEVANNLNESLIDLQELGKYEQYIKWPWYIWLGFIAGLIAIVMVTIMLCCMTSCCSCLKGCCSCGSCCKFDEDDSEPVLKGVKLHYT
->tr|A0A6B9XTV0|A0A6B9XTV0_PICSI Uncharacterized protein OS=Picea sitchensis OX=3332 GN=orf05555 PE=4 SV=1
-MRCYGHWNVMVPHPAQQIFESHLLQVYTVFHNFYKLAAIEWGMPAIMNSPCLAIDFFLPVGEKTLHSADHTPLCGCNSLCHSYLFESRVSFFSYYSPQRAV
->tr|A0A2A4QF02|A0A2A4QF02_9GAMM Uncharacterized protein OS=Gammaproteobacteria bacterium OX=1913989 GN=COB83_09745 PE=4 SV=1
-MLKIIVGFIIVIILTGGVVTPSIEWINKVFHVKNGGIYLSIAFFICYFFLLAFRLIKKK
->tr|A0A418RSL3|A0A418RSL3_9GAMM Antitoxin OS=Methylococcales bacterium OX=2304002 GN=D0528_03225 PE=3 SV=1
-MINEVNTAVFQQNLGEMLNQVQYRHDSILIKEDGKPVAALVDAQLFDRIRRFKNRFDTLSNQIANAYESVPQEDGLNEIDAIVSEIRHSQF
->tr|A0A510B6M8|A0A510B6M8_9POAL Photosystem II reaction center protein L OS=Avena longiglumis OX=4500 GN=psbL PE=3 SV=1
-MTQSNPNEQNVELNRTSLYWGLLLIFVLAVLFSNYFFN
->tr|A0A2D5H536|A0A2D5H536_9PLAN Antibiotic biosynthesis monooxygenase OS=Gimesia sp. OX=2024833 GN=CME31_26170 PE=4 SV=1
-MFCLNVILTLKDAADAEEIQGLLTEACRLSRTEPGCLRFDVYQSEGEPATFVLVEHWESEDAWQTHREAEAYTQIYQPQILPRVERVPYRMKMLLE
->tr|A0A7L7BQ76|A0A7L7BQ76_9ENTR Alpha/beta hydrolase OS=Enterobacter sp. RHB15-C17 OX=2742619 GN=HVX06_10740 PE=4 SV=1
-MFSKLAYSTLALTVSLGTVISCQAEATGTDFATAFDHPQQINAGDLNVGYVDIGPKNGQPIILLHGWPYDIHSYAQVAPALAAKGYRVIVPSLRGYGTTRFLSDKTPRNGQPSAMAKDVVNLMDALNIKQAVFAGYDWGARTADIVAALWPERVKSLVSVSGYLISSQQIGKQPLPPKAEVQWWYQFYFATERGAEGYAKNTHDFARLIWSQASPDWKFSDATFDASAKSLDNPDHVAVTLSNYRWRLGLEKGERKYDSYEQKLATLPNITVPTITIEGGNNGAPHPAPQAYAGKFTGKYEHRTFGKTVGHNPPQEDPQDFVNAVVDADKL
->tr|A0A7N0VAI1|A0A7N0VAI1_KALFE Uncharacterized protein OS=Kalanchoe fedtschenkoi OX=63787 PE=4 SV=1
-MENAEAFEASTAPLSLHDFFERMRQPAAAEFVKAIKSFVVSFSNKAPNHERDSAAVQDFLSNMERAFREHPLWAGCSVEELDCAGEGLEKYVMTKLFTHVFASLPDDLEVDRQLSDKMALLQQFIRPENLDIKPNFRNEASWLANPPQLHSNLLYIQRYRHHPRLVAEYAYYFTNMLSVESFITNINAKALSMDETEFEMNMESARALNLGLSADTSDMSDQNEQNLENTSNKEAVEIKQGFSNFKTDHVTRPPPSVSKSGKIELRHTKAESSIRKIPSMSDLENKGAFMLLNENRLSRVFQEYPYLFSQVGDLTLDDVESLLNNYKQLVFKYVSLAKGKGSEPLPPPFISMSNSQSQRATPADAERESIEEPVAEKTNNRNEANSWTDEGSIEVSQVPELNSPDYKMPEVSSAQVEADHDHDNS
->tr|A0A3N0D1M1|A0A3N0D1M1_9FLAO NAD-dependent epimerase/dehydratase family protein OS=Sinomicrobium pectinilyticum OX=1084421 GN=ED312_22910 PE=4 SV=1
-MKVALIGATGFVGTNILKELVDRGHKVTAIARNPERSEIKGYHVTPVKADVLDTDRLAEILAGHDAVVSAFNPGWANPNIYDDFLRGAKAIQEAVKKSGVSRFVVIGGGGSLYLKPGLQVVDTPEFPAEIKSGADAARLYLEEIRKEKVLDWVFFSPALEMHQGITTGRTGKYRLGLENPVFDKDGRSVLSGEDVGVVIADELETPKHHRERFTAAY
->tr|A0A6P0AN79|A0A6P0AN79_RHILE Siderophore-interacting protein OS=Rhizobium leguminosarum OX=384 GN=GR232_16200 PE=4 SV=1
-MDNNQFKDQASSTPGIERIRHDTRRRLLTVESVVDITPSMRRVVLAGDDLADFISLGADDHIKIFVPVADGSEERRDYTPRRYDNIERRLTIDFALHEAGPVTKWAIDADPGDRLEIGGPRGSAVVSKTVKRWLLIGDETALPAIGRRIEESGAGTVVTTIAAVTGPLEEQTFETSAELHLHWAHRPLSQATSATALLKLLSTVDIQPETFIWVAAEASVTRDIRAYLLERGCPLGWIKASGYWVFGKADTTEKFG
->tr|A0A7K4JQ10|A0A7K4JQ10_GEOCA GT252 galactosyltransferase (Fragment) OS=Geococcyx californianus OX=8947 GN=Colgalt2_1 PE=4 SV=1
-VATDHNVDNTTAILKEWLKNVQNLYHDVEWRPMEDPQSYPEEIGPKHWPSSRFTHVMKLRQAALRAAREKWSDYILFIDADNLLTNPETLNLMIAENKTLVAPMLESRSLYSNFWCGITPQA
->tr|A0A673XYG3|A0A673XYG3_SALTR Gamma-tubulin complex component OS=Salmo trutta OX=8032 GN=LOC115201020 PE=3 SV=1
-MSEFRIHHDVNELLSLLHVRGGDGAEVFIDLLQKNRTPYITTTVSAHSAKVKIAEYSKTPEDFLRKYDELKSKNVRNLDPLVYLLSKLSEDKEVITYISHLITVLCYVPITFVCNRMPKKGLKRLLMRQQVQPLLSLQPSAEVTRKMLRDRHNKKNPTQPNPVFPNWVYDRPALIGDFITGATAAGDPEVAIGTMPLPAQEQALVDDLLFVLVGVDGRDITAQPVLGRQNRSFIVDPTLDMSIKELVNRILPVASYYSTITRFTEEKSSFEYGQVNHALTAAMRTLMKEYLILVTQLEHLHRQGMLSLQKLWFYIQPTMRTMEILASIASSVDKGDCMGGSTLSLLHDRTFNYTGDSQAQELCLYLTKAASVPYFEILEKWIYRGIIKDPYSEFMVEEHELQKEKIQEDYNDKYWDQRYTIVQHRIPSFLQKMADKILSTGKYLNVVRECGRDVTCPDAKEVLYTLKERAYVEQIEKSYYYASKVLLDFLMEEKELVARLRSIKHYFLMDKGDFFVHFMDLTEEELKKPVDDIVPPRLEALLELALRMSTANTDPFKDDLKIDLMPHDVITQLLRVLAIETKQEKAIINADPTEVALSGLEAFSFDYIVKWPLSLIINRKALTRYQMLFRHIFYCKHVERLLCNVWISNKTAKQYALHRAKWFATAFALRQRMLNFVQNIQYYMMFEVMEPTWHIMEKNLKSASNIDDVLCHHTSFLDNCLKDCMLTNPELLKIFSKLMSVCVMFTNCMQRFTQSMKLDREMNRLSLEHGTMEGPPTQSERTEEQEKKRLTSKFLAEHVDALQSDACFEATVSKFDSNFSTLLLDLLDKLSVYSTNDCEHSMINIIYRLDFNGFYTERLERMAIERSQKAAA
->tr|A0A5S5C3J5|A0A5S5C3J5_9BACL Uncharacterized protein OS=Paenibacillus methanolicus OX=582686 GN=BCM02_107172 PE=4 SV=1
-MTESNYKNWPTDEHARWIRMGHFFGKTLMEEVKGHAKERIDPASSVEERLAAEKAIRDTLYGFMMLLDGVIDSPIDQDHGVEFALVARVFNQDTREYLEEIELAPDGDGLCMGIHMWEDGEFE
->tr|M5BKI9|M5BKI9_THACB Septin homolog spn3 OS=Thanatephorus cucumeris (strain AG1-IB / isolate 7/3/14) OX=1108050 GN=BN14_01267 PE=3 SV=1
-MAYRHRGRKNAKKGIQFTLMVVGASGTGRTTFVNTLCESEVLAPKIADNAETAHVEEGIRIKPVNVELEEDGTRIALTIVDTPGFGDNIDNEFAFQEIVGYLERQYDDILAEQSRIKRNPRFRDNRVHALLYFIPPTGHALREMDIELMRRLSPRVNVIPVIGKADSLTPSELKGFKKRVMEDIEHYGIPVYNFPYDVEEDDEETIQDNSELRAMLPFAIVGSGDEVEIDGQPVRARIYPWGVVEVDNPKHSDFSRLRSALLNSHLMDLKSLTDDVLYETYRTEKLSRMVHADNTDDSILPEDLATQSVRLKEEQLRREEEKLREIELKVQREINEKRQELLAKEESLRNLETRLAAQGSQAEF
->tr|A0A6P8KJN9|A0A6P8KJN9_DROMA synapse-associated protein of 47 kDa isoform X6 OS=Drosophila mauritiana OX=7226 GN=LOC117143185 PE=4 SV=1
-MFSGLTNQFTSLVGAVKGGAGDEDVPAPTGDAPAAAPAASTSVEATASSAVDPEAAAAAGGEGLEGEEAGKSGWLGSAKGWLGNASIPSMPAMPSMPSMPAMPAMPSIPSIPGLRKGAGADGAEGAEGAVAGEGGAAASGAVSGGEDDDKSRYISATEGADSHPASGGGTPTGDEGQIGQGKGDEVKITTKVTQQAKHFGSFLSSAISKAGSKIKETVKDNTILDSFNKEQEAFIKGQGGVGNGAAPWIGHANEAKIKEEILGLSQDRRNFVRAPPAGVDFEFSYDTAYPTAIAIMAEDKALETMRFELVPKIITEENFWRNYFYRVSLIIQAAELGTLGADGVGQASSGEDANEVATKEKKSKTAQPAKGDSSVKAIAEQPKAVIEPEAQESDVQAAKSKAKAQAGKELGQKISESEFVSDDFQASSESDLAEIQDGMRKLGIDSMTQQALAPTDEEQWEKDLEAELKDYEVVDEGGTGGGGRRKGRKAGEDDTEADEDEPTISNLRTRSTNNDWEEYADLIEDTDDLKTLKCLKRTMLGYP
->tr|A0A3S6F4D4|A0A3S6F4D4_YERET Fimbrial protein OS=Yersinia entomophaga OX=935293 GN=PL78_17300 PE=4 SV=1
-MNKTLLMALLFTLPGVALAATSNNTIKFQGEVAEQTCQVDINGSANTPIVLLPTVASASLSGPNSVAGKTNFTINLTGCNVASKETKISSVFQGMNVTPAGNLGNTGTAQFVAIQLLDSTDRPVILTSGPVEVPGITLATGATSASQDLSVQYISESGNAVAGSVMASAQYAITYP
->tr|A0A2S1PWN1|A0A2S1PWN1_ORITS 56 kDa type specific antigen (Fragment) OS=Orientia tsutsugamushi OX=784 PE=4 SV=1
-GDRDFGIDIGNIPQAQAQAANPALNDDQRAASRIAWLYNCAGIDYRVTDPHNPIGPMVLIPTLLTIPKGNPNPAGNPPQRAHQPANFAILNHDLWRHLVVGLAALSNANKPSASPVKVLSDKITQIYSDIKPFADIAGIDVPDTSLPNSASV
->tr|A0A126E925|A0A126E925_9RICK Uncharacterized protein OS=Rickettsia raoultii OX=369822 GN=UQ52_02815 PE=4 SV=1
-MNSTNQLQNNSLTNSWLKLGILSLGFAGLYSIILVVLRTPQLSSFFPNPHIFKSALIIHVNLSVLIWLLSVTASVWGGETSLRGEAKPRRGNLMKQYKIPEIAKFSTFARNDVFRLYPKLAFLATLLIAISPIAGHNPVMNNYIPMLENIVFILGLSLFGVTLLLYAINILYFFDWTNLNSLVNFTVLSTIIMFILSFVCFGWSYNGLQNIMQIIPIEIEFYYELLFWSGGHLLQFIYTQILIFIWVSLFRELIARELKFQKFYLFLLYLNFIFGILTLFGHIFYDIIDGAFKVFYTNHMKYLGGIAPVLCLIGMGVELVWVFVIPQLDREIQTKYQNNVIDLAIKLRDDTVTINDRVIKTILLCSITLFLLGGLIAMNITGINVAIPAHYHGSIVGISIACMGCSYLGIGRYQRHCERLKRAWQSHEVIQKLPRLPRRYFVPPRNDNIINFTFYLLTFGQILHILGLAFAGGYGVMRKDPNSVMPMSAKLLMGMMGGGGFIAIVGGLMFVYICVKVMFFKSIKLAHE
->tr|A0A159KM53|A0A159KM53_9HEMI Cytochrome c oxidase subunit 1 (Fragment) OS=Corythucha sp. BOLD:AAG8847 OX=1793449 GN=COI PE=3 SV=1
-SWIIRXELSQPGPFIGNDQIYNVIVTAHAFIMIFFMVMPIMIGGFGNWLVPLMIGAPDMAFPRMNNMSFWLLPPSLTLLIMSSMVENGAGTGWTVYPPLSSNISHMGPSVDLAIFSLHLAGVSSILGAINFITTVINMRPSGMSLEKTPLFVWSVVITAVLLLLSLPVLAGAITMLLT
->tr|A0A4U5P1N6|A0A4U5P1N6_STECR Uncharacterized protein OS=Steinernema carpocapsae OX=34508 GN=L596_013647 PE=4 SV=1
-MKQRKNALWEMQKLIDCLQSTKWLNVCCYLETDVTSFSINHVMVGPNLTLILDVCLLQVRYRYFDIRYRTAVYWKRNSCFSAFPTYFDKQK
->tr|A0A3E4WUS6|A0A3E4WUS6_PHOVU Uncharacterized protein OS=Phocaeicola vulgatus OX=821 GN=DXC16_05095 PE=4 SV=1
-MDDKTGALEKLKAIMAKAEQVEMSSVKIGDIIYVPLDEEDGLILKDGYKDRNKYIVIIGFTPEGVAIGALLINSEIDSSKRSEELLDCQYPLMVRNYRDILDYDSWLDCSDIFELSKLKITEKNGKLKGCLISEDRERVMQFLRETEVFDNATKRRYGIIK
->tr|A0A1R4HFW4|A0A1R4HFW4_9GAMM Secretion ATPase, PEP-CTERM locus subfamily OS=Crenothrix polyspora OX=360316 GN=CRENPOLYSF2_460006 PE=4 SV=1
-MYDGFYNLSKKPFQLNADSDFFFNSAVHKRALAYMRYGLTQGEGFVVVTGKPGTGKTMLVKELVNSLNSNDITIGIMVSSQVGADDLLKIISATFGLPYDGEDKATLLTRIERFFIQQAVDGKRVLMIVDEAQNLPKDSLEELRMLSNFEMSGKALFQTFLIGQLQLGETLFLPEMEQLRQRIVATYQLKPLEEEETKNYILFRLEKAGWQQTPQFEEEVFNAICAYTQGIPRRINTLCDRVLLFGYLDELSVIGLNAVNKVIADIEEEASIVTDEFHDVVALSASSNVSYSDGFSPQMEERIVALEKTVENLRNVLGRERALLRKAILIQLDMNEVYDDLGE
->tr|A0A5D4XIW7|A0A5D4XIW7_9GAMM Integration host factor subunit beta OS=Luteimonas sp. XBU10 OX=1132694 GN=ihfB PE=3 SV=1
-MTKSELIEILTQRQAHLKADDVDLAVKSLLEMMAGSLAHGERIEIRGFGSFSLHFRPPRTGRNPKTGDAVALPGKHVPHFKPGKELRERVTAVIPLPAEE
->tr|W7W772|W7W772_9BURK Transposase OS=Methylibium sp. T29-B OX=1437443 GN=Y694_04599 PE=3 SV=1
-MAMLAKIRRMHLRDGLSIREVARRTGLSRNTVRQWLREEGVTEPKYPERSTASVLDAWAEHLEAALRADAHRPVRERRTAKALFEQIRALGYAGSYPRVVVWVRRWRERQASAPRRAAFVPMSFELGDAFQFDWSCEYVFVGGLRRRLEVAHTKLAASRAFWLTAYPAQSHEMLFDAHARAFEALGGVPRRGIYDNMKTAVDKVGVGKARSVNARFQAMCSHYLFEPEFCNPASGWEKGVVEKNVQDRRRQVWREAGERRWSDLASLNAWLAERCRQGWEETAHPEWSELSVADVLQDERTRLMPCPKPFDGYVEQPVRVSATALVHFQRNRYSVPTRWVNEVLSLRAYPEAVVLVAEGVEVARHTRSFERELTFYDWQHYIALVQTKPGALRNGAPFKAMPEVLQTLQRHLLRHAGGDRVMAQVLAAVPVHGLEAVLVAAEIALEAGRPSAEHVLNVLARLKDGAPALRELTQPAPTLKEEPRADVQRYDSLREAQQP
->tr|A0A6J6Q2H3|A0A6J6Q2H3_9ZZZZ Unannotated protein OS=freshwater metagenome OX=449393 GN=UFOPK2366_01453 PE=3 SV=1
-MFEWNEEQQMIRDAVRRFVDDEVRPHVEELEHGDLAPYDILRKLFATFGMDSMARDRFAKQIAREKSVAEMVARGETPPAPAAERSGGDGGGAAMSLIPIIELCRVCPGMVTAMGVSMGLTSAAIMSKGTIAQKERWALDLLTMDKVGAWAITEPGSGSDAFGSMRATARRDGDDYILNGSKTFITNGPYADTTVFICKLDDGGPIEQRKVVSFVLDRGIPGFVQSKRLRKMGMHSSPTGQLFLDDVRVGRDRLIGETEDQPAGGREGAKATFQQERSGVAAMALGIIEECLQLSVAYAKDRVQFGKPIGEFQLIQDKLARMEVARINVQNLVFRTIEMSAAGKTMSLAEASAMKLYSARAATEVALEAVQVFGGNGYMSEFRVEQLARDAKVLQIYAGTDEIQITHIAKELLRA
->tr|A0A1X0ZA11|A0A1X0ZA11_PSEPU Hcp1 family type VI secretion system effector OS=Pseudomonas putida OX=303 GN=hcp PE=4 SV=1
-MPTPAYIAIEGKTQGNITKGAFTSDSVGNIFVEGHEDQILVQEVNHRITVPTDPQSGQPAGQRVHGPLIFTCALNKAVPLLYSALSSGEMLPNVELSWYRTSVEGTQERFFTTKLIDAVIIDIDLEMPHVQDKDNSNFTQFFKVSMAYRGIEWEHITASTAGADDWRKPKETAV
->tr|A0A6I3MVR7|A0A6I3MVR7_9ACTN Uncharacterized protein (Fragment) OS=Actinobacteria bacterium OX=1883427 GN=F2940_05525 PE=4 SV=1
-MNTSPFRSVLIVCGVATFGLVACGAQESQPQPISFSLAASTRSASDVVGAPESSNSNSKIMAPNYSVEYVVDGKLADLGQEASSWRAQTNVVASDADLKKIATALGVKNTEVQTSSGDPYLSWYYSGAVSSEASSPPSVGMSDSDAETTAPDRTVVSPPVPENVPTKEEAQSIIQKMMAKMGVDVDDANIEINGDEYGIWATAWKTFDGMRSPMSWNIGLGANGAVTYAQGNFLKFDRGANYPVVNTTEAVKRLGNPRYSGWFGYGAVSSKEVLAKDSATIPSQEVVVQTIRLTKVSASLTPVIASDKTLWLLPSYEYLTSDGYTVSTLALDDKYIDQTPTSTVPDNDVNVTTPDAGSGSSGSSTGGTPAVDGGVVEPAPAPQTILPTEKDAKALVGLNEDEAVKIIEGNGWTYRIGSRDGEQFMLTEDYSASRLTLGIE
->tr|A0A067Z5I4|A0A067Z5I4_GLUOY Uncharacterized protein OS=Gluconobacter oxydans DSM 3504 OX=1288313 GN=GLS_c18640 PE=4 SV=1
-MMTMNNEERDLIARFVARVGGGPQVTGPGQPPAAPLPPIDPEADRFIAENFQKYPEARYRITQMAVVQEAALAQAQNRIRQLEFQLQQAQQQLAQVQQSGGSKPGLFGGLFSGGNRPQQSAPPPGWGSQAAPPPNFMPQQQYAYPPGYQPGMFQRGGSGFLGSALTTAAGVAGGMMAANALEGLFSDHHGAGGDAAGGWGAGGDTIINNYGSDASASDPFGGAGTDAGSFSDSDFGGGGDAGGGGDFGGGDGGGGGFDDMF
->tr|A0A4P7HFW9|A0A4P7HFW9_9NOCA 2-C-methyl-D-erythritol 2,4-cyclodiphosphate synthase OS=Nocardia sp. CS682 OX=1047172 GN=ispF PE=3 SV=1
-MRVGIGSDVHPIEAGRPCWMAGLLFDGDDGCAGHSDGDVAAHALCDALLSAAGLGDVGAVFGTGRPEWAGVSGAAMLKEVRRLLDEAGFEIVNAAVQVIGNRPKIGPRRGEAQQVLGELLDAPVSVSGTTTDGLGLTGRGEGVAAIATALLQACR
->tr|A0A5S4G1W4|A0A5S4G1W4_9ACTN HAMP domain-containing protein (Fragment) OS=Nonomuraea zeae OX=1642303 GN=ETD85_40700 PE=4 SV=1
-MSDPAVGTTRSAARTKRSRGPGEVGEPELRQLLAGLTAVRDGDFRTRLPDDADGLLGEIASVFNGMVDQLSLFTSEVTRVAREVGTDGRLGGQADVPAVSGTWKDLTESVNAMAGNLTDQVRSIAQVTTAVARGDLSQKITVHARGEILELKNTVNTMVDQLSSFADEVTRVAREVGTEGQLGGQADVKGVAGTWRALTDSVNFMAGNLTDQVRNISQVATAVARGDLSQSITVSARGEILELKNTLNTMVDQLSSFADEVTRVAREVGTEGNLGGQATVRGVSGTWKDLTENVNVMASNLTNQVRSIAQVATAVARGDLSQKITVEAKGEVAALAQTINTMVDTLGAFADEVTRVAREVGTEGQLGGQARVPNVAGTWKNLTDNVNSMADNLTNQVRSIAQVTTAVAKG
->tr|X0VWK7|X0VWK7_9ZZZZ Uncharacterized protein (Fragment) OS=marine sediment metagenome OX=412755 GN=S01H1_51379 PE=4 SV=1
-MAYSLTFGDVAENHIGNQQIGSICHDGFTKAELLYAKTQFEVKGCTCELVELHKDV
->tr|A0A439RUF8|A0A439RUF8_9HYPH PhzF family phenazine biosynthesis protein OS=Mesorhizobium sp. OX=1871066 GN=EOQ56_14750 PE=3 SV=1
-MLTRNYLLYDVFTTERLGGNPLAVVLDSKGLDTAAMQAIAGEFNLSETVFVLPPDNPKHRARIRIFTPDHEMPFAGHPTVGAAIALAEMAGDGDTAGIFVLEENIGPVRCAVSKHAGASFAEFDLAKLPEPLELSADPEAIGAALGLGPHEIGFENHRVSFWSAGVPYVTIPVADLEAAARIKLDNQAWSELAPRKSDWALASPYVYCRETVNHDSAFHVRMIVPGNPSYEDPATGSAAAAFAGAIMHFDGPREGVSQRWIEQGLEMGRPSRIRLELNVEGGKLAAARIGGHAVKVAEGKLFV
->tr|A0A669NV56|A0A669NV56_PHACC Membrane associated guanylate kinase, WW and PDZ domain containing 2 OS=Phasianus colchicus OX=9054 PE=4 SV=1
-SKFRPHKEGEVPGVDYIFITVEDFMELEKSGALLESGTYEDNYYGTPKPPAEPAPLLVNVTDQILPGATPGAEGKRKRNKSVSNMEKTGIEPPEEEEEERPVVNGNDVTVTPESSEHEDKSTGVSGEVSSTQPCPAPGYTQPEEAKEDMDVTKQTKPEENDDLGPLPDNWEMAYTEKGEVYFIDHNTKTTSWLDPRLAKKAKPPEECKENELPYGWEKIDDPIYGTYYVDHINRRTQFENPVLEAKRKLQQHNMPNAELGTKPMQAQGFREKPLFTRDASQLKGTFLSTTLKKSNMGFGFTIIGGDEPDEFLQVKSVIPDGPAAQDGKMETGDVIVYINEVCVLGHTHADVVKLFQSVPIGQSVNLVLCRGYPLPFDPEDPANSMVPPLAVMERPPVVVNGRHNYETYLEYISRTSQSVPDVTDRPPHSLHSIPADSQLDSTFPPPAHDDNVSMASSGATQAELMTLTIVKGAQGFGFTIADSPTGQRVKQILDIQGCPGLCEGDLIVEINQQNVQNLSHAEVVDILKECPVGSETSLIIHRGGFFSPWKTPKPVMERWENQGSPQTSLSAPAMPQNIPYPPTLHRSSFPDSTEAFDPRKPDPYELYEKSRAIYESRRPDYKELDVHLRRMESGFGFRILGGDEPGQPILIGAVIAMGSADRDGRLHPGDELVYVDGIPVAGKTHRYVIDLMHNAARNGQVNLTVRRKVLPTGEPCPENGRSPGSVSTHHSSPRSDYATYANSNHAVSSSNATPPEGFTSHSLQTSDVVIHRKENEGFGFVIISSLNRPESGSTITVPHKIGRIIDGSPADRCAKLKVGDRILAVNGQSIINMPHADIVKLIKDAGLSVTLRIIPQEELNSPASAPSSEKQSPLAQQHSPLAQQHPLAQQQSPVTQHSPVAQPTLPQPLQLQGHENSYRSEVKARQDVKPDIRQPPFTDYRQSSTDYRQPPLDYRHPPVMDYQQPPPLDYRQPPLLDYRQHSPDTRQYPLSDYRQPQDFDYFTVDLEKGAKGFGFSIRGGREYKMDLFVLRLAEDGPAIRNGRMRVGDQIIEINGESTRDMTHARAIELIKSGGRRVRLLLKRGTGQVPEYDEPSSWSAPAATSPGLQEVALSLDDIISPLSSSHIAPPSDPSHQISPEPTWDIKREHDGRKPKELSVNGHKKKRLGEQRERSASPKKADRSKHDEPSWKGYSEGKTKVTDGGRLTSESRAVGHSVMMEAGAREHVCAGSSDEQFGRKGHLHPISTRSTNTTVRKATVSPGPWKIPGSDKLPGVLKSGTSAMSR
->tr|A0A516QZI1|A0A516QZI1_9BACI Octanoyl-[GcvH]:protein N-octanoyltransferase OS=Bacillus sp. BD59S OX=2499213 GN=lipL PE=3 SV=1
-MSNSRSILSQPEWRIVDQSSLGPTFHALQSFAMDDTLCTSIGNGQSAATMRSWVHHNTIVLGIQDSRLPHLEEGISFLKENNFNVIVRNSGGLAVVLDEGVLNVSLLFQETEKGIDIDLGYDTMWHLIQEMLKDYDVTIEAKEIIGSYCPGSYDLSIRDQKFAGISQRRIRGGVAVQIYLCATGSGSERAALVRDFYNLAIQGEETRFTYPEIVPSTMASLSELLGETITVQDLMMRLLKTLQQFAPKLTPSQLTIDEIPLYETNLQRIIDRNNKALGLEK
->tr|A0A7C4ETP5|A0A7C4ETP5_9DELT Uncharacterized protein OS=Desulfomonile tiedjei OX=2358 GN=ENV54_02205 PE=4 SV=1
-MLIHDKKTFGLGLLLFITFLIVLGIMFSPFFSGENALKASDKLFNSIAKGSTYYIPDLLKKAQAMGGAKFEATIKLKSDELAQKAQKVLTASGSQVSAAGAQLNVKGALGDVLSAALKDSDSMFHNRDSEVAQRYGFSGREALFVWWSLLKEVEKELTRQSKFKDAAFVSTVVKKGVEVGYNFFGIAPESALSKAGILTFALVFYVVYTLWWGIAILFLFEGLGLEMKAGAKKEV
->tr|A0A0Q7FUL9|A0A0Q7FUL9_9GAMM 3'-5' exonuclease OS=Acinetobacter sp. Root1280 OX=1736444 GN=ASC84_16360 PE=4 SV=1
-MRLPVLVFDIETLTDLKSGAHLYGLDLPQDDLEQALAKLRRQESGMDFQRLALHEIVCISGLWIDENGVMKLFSFSREHYTETEILQKFLSIFDKRHPTLVSWNGSQFDLPVILFRAMYHGLSAPSLFDQGEIDTQKRYNNYQNRYHNRHVDLMDVMAMFNGRHFQKLDDVAHLLGYPGKRGISGYFVPEYVNTQQWLKLTSYCEGDVLNTWLIFLRWALLKGQISLQDHRLWIQASIHYLQGQTQQHEFLNVWRETSQRTEFTQADFSSTPD
->tr|A0A5K1MIC2|A0A5K1MIC2_ACIBA Uncharacterized protein OS=Acinetobacter baumannii NIPH 615 OX=1217641 GN=F978_03533 PE=4 SV=1
-MKIKEMPKIKVRNQVALSPLLHKGGMHETEKPRAQHRRNRQDTKQQLKKGVW
->tr|A0A7L3CZ56|A0A7L3CZ56_PLUSO MX protein (Fragment) OS=Pluvianellus socialis OX=227228 GN=Mx PE=3 SV=1
-QGEEHTLYNQYEEKIRPCIDLIDSLRALGIEKDLALPSIAVIGDQSSGKSSVLEALSGIALPRGNGVVTRCPLELKLKRIPATQAWKGKMCYRNSSVELQDASEVEKAIREAQNVVAGTRGAISGELISLEIWSPEVPDLTLIDLPGIARVAVGDQPKDIGEQIKMLLKKIIGCKETLNLVVVPCNVDIATTEALKMAQEVDPSGERTLGILTKPDLVDRGTEESIVNIIRNLVVPLKKGYMIVKCRGQQDIHDKLALTAAIQQERRFFENHKYFSLLLDEGKATIPCLAEKLTNELVRHIIKTLPTLENQVREVLQKTLQDLQKYRRGTPRTESERLIFLTDLIKLFNQDISQMMRGEEQLYGNEVRLFTKIRREFRTWEVTLLESAAKVKNNVPSKVWKYEDQYRGREFPGFNNYRTFEDIIKEQIIELEEPAVEIMSNVIGLVEEKFMEVTKRHFANFHNLNRAAKTRIEHIREKQAEEAERHIRTQFKMERIVYCQDDAYINDLQSVKQEGATKAGNEKGLLVGSVSNQETSFVQEMGASKRLCNQIPLIILSSALHDFGDQLQTTMLHLLQEKDKLSHLLQEDSEAAKQRTYLSQRVNRLTKACQYLRDFTLV
->tr|A0A1H2WI61|A0A1H2WI61_9ALTE Ribonucleoside-diphosphate reductase OS=Marinobacter mobilis OX=488533 GN=SAMN04487960_104173 PE=3 SV=1
-MSTAALAEPQSPASSLQVIKRNGTLVSFDPAKITVAVTKAFLAVEGDQVSGSARIHDSVARVTEQVVQAISRRLKAGGKVHIEDIQDQVELALMRAEEQKVARAYVLYREAHAQERASRAAPVEAHPSLTVKQRNGQVAPLDLGLMKFQVEQACGGVDGVDAAAVVNEALKGLYDGIPEADVLSALVMTARGRIEQEPGYSQVTARLLLEQLRMEAAGALALPLQASLPSVYPQALTAFVHAGIRYELLDEALAAFDLERLGAALKPERDGQFGFLGLQTLYDRYFLHWQGARLELPQVFFMRVAMGLALREDDPNARAIEFYNLLSSFDYMASTPTLFNSGTRHSQLSSCYLTTVGDDLEEIYGAIRDNALLSKWAGGLGNDWTPVRALGSHIKGTNGNSQGVVPFLKVVNDTAVAVNQGGKRKGAVCAYLESWHLDIEEFLELRKNTGDERRRTHDMNTANWVPDLLIERMRRDQDWTLFSPSDVPDLHDLYGNDFRTRYEEYEARAARGELPLHKTVPAKQLWRKMLTVLFETGHPWITFKDPCNLRSPQQHVGVVHSSNLCTEITLNTSAEEIAVCNLGSVNLAAHINGGELDVQRLERTVNTAVRMLDNVIDINFYAVPQARESNLRHRPVGMGLMGFQDALYQLKLAYSSPEAVEFADLAMEQISYFAIRASAELAAERGAYPTYEGSLWDQGILPIDSIQLLADARQDGDLSVNTEARLDWTPVRELVAKHGMRNSNVMAIAPTATISNIVGVSQSIEPAYQNLFVKSNLSGEFTVVNPSLVAELKAEGLWDNVMVNDLKYFDGSVQQIERIPAEIKARYATAFEMDARWLVEAGARRQKWLDQAQSLNLYMAEPSGKKLDALYQLAWERGLKTTYYLRSLGATGAEKSAPVQAAPAPQVCSIDNPDCEACQ
->tr|W6TAY6|W6TAY6_9LACO Terminase OS=Lactobacillus fabifermentans T30PCM01 OX=1400520 GN=LFAB_00210 PE=4 SV=1
-MIEYVDQVLSGQVLAGQKIKWACERFKRDLSRSKDDSFPFYYDEDKAAQAVKFIELMPKTDGSQLTMQPFQKWIISELYGWREKTTGNRRYDRAFISMARKNGKTYLASGMAANGLLRERQPARNRQVLFVSNALKQAKLGYDMLSSGLRQVRKQSKYMRQRIKVQKQAITDLETDSQALALASDTSTLDGYAGTTVILDEWHEAKDRKVYNVLKSGQAQEDNSLLAVISTSGLNLNVPMHAEYDMLTDVLKGKTEADRYFVAIWELDDREEVYDQANWIKANPLFSEPHVKQRMTEKIKADVDLAIKQNNLIPILVKNFNMWLQASEDSYISADDWAAGKLAKVPDLHNRDAYIGIDLSKSNDLTAVSWLVPIGNGQFYCDSHSFVGTKYGLDSKIKRDGIDYRSMERAGECSITRLDSGVIDYDELFDYVQNLVGKYNWKVKAIAYDPYNAQTLITKFEKLSYPLFEVRQGTKTLNIPTRNFRDQLYDDKIKHNGNKILAYAVNNAILKVLNNGWQLDKARNSNRIDPIAALINAFVAGMDYYQESEAQQHAEDYYKTATAADLF
->tr|C5LGB5|C5LGB5_PERM5 Subtilisin OS=Perkinsus marinus (strain ATCC 50983 / TXsc) OX=423536 GN=Pmar_PMAR016847 PE=4 SV=1
-MPSRVDYDLRNRRIDEKESKIEEILLTGSNGDNDDDAMEHKDNDIVIIKLEACIIDSFVDGEGDGAVIVAVIDSGIDYTHPDLVDNIWINKDEIPGSDNIDNDANGFIDDIYGWNFVHNTNNIMDDNGHGTHIGGIIGAKGSNNIGATGIAWDVAIMPLKFLNADGIGRVSDAMRALDYAIQMGATISQNSWTCHKCDDTTTTNYNAIKMAIQKAGNAHGSINFYATPVDIKNAIMNSVDTDPNLEMKCLSSGILNAYRALNTVIHNNNKNKKKKNDHLHKSKTSSSVINIIISTTTTMNDDYICGDAFCNKYVGSVMTVSDE
->tr|A0A2E9Q7Q3|A0A2E9Q7Q3_9SPIO Aspartate transcarbamylase OS=Spirochaetaceae bacterium OX=1898206 GN=CMN76_04620 PE=3 SV=1
-MFDQSKIHPLLKQPVVSRDGIRGIERPRHLLESIPEDAEPLRSLAGMHIVSARQFDRNKILQLGRLAASYETQPDLIHPPLRGKILVSAFYEPSTRTRLSFESAWHRLGGDIMSITDPNTTGIAKGESLADVGEMFNNYGDVVVLRDSSEDSVYAMLDSLRIPIINAGNGIDEHPTQALADIYAMLKWRPDFGSGNLSEEEKITIGVIGTPNRMRTVRSLLLLLSLFSDSIKKVYIVNPASDVLDKEQDEELRAAGLKLEVVHKLRDILPEIDVVYINSIAWVGDSYETLTGDIKLTSESQLKQGAIILHPLARGEELDESLDGTSHNWYFSQARGAVFIRMALLTCLVHRINLVVDSPVEQPDSN
->tr|A0A520KE24|A0A520KE24_9ARCH Uncharacterized protein OS=Candidatus Verstraetearchaeota archaeon OX=2250257 GN=DSO09_03215 PE=4 SV=1
-MKKSRIIPIMSIIFTLLLILIIIINQVQWQNHEYYYELRRTIGLPSIAIGTNYEGTRNPLLDIFVRALYDVPGGHDYVVSSSFIDTPLKLKDFFERIPGFNMTVMREGK
->tr|C4NUU6|C4NUU6_ECOLX Aminoglycoside O-phosphotransferase APH(6)-Id OS=Escherichia coli OX=562 GN=strB PE=4 SV=1
-MPPVFPAHWHVSQPVLIADTFSSLVWKVSLPDGTPAIVKGLKPIEDIADELRGADYLVWRNGRGAVRLLGRENNLMLLEYAGERMLSHIVAEHGDYQATEIAAELMAKLYAASEEPLPSALLPIRDRFAALFQRARDDQNAGCQTDYVHAAIIADQMMSNASELRGLHGDLHHENIMFSSRGWLVIDPVGLVGEVGFGAANMFYDPADRDDLCLDPRRIAQMADAFSRALDVDPRRLLDQAYAYGCLSAAWNADGEEEQRDLAIAAAIKQVRQTSY
->tr|A0A1Q7EW51|A0A1Q7EW51_9CHLR DUF218 domain-containing protein OS=Chloroflexi bacterium 13_1_40CM_68_21 OX=1805084 GN=AUH33_06650 PE=4 SV=1
-MTNDDGDLAEFPEVAVVLGGGMSASGVPSPSTAARAHAASQLAHHRPSLAVIASGSHGDDPAPAKSEAAVMADLISKAGVPRERIFLEERSRDTIGNGVEVAARYLAKIEPRPLYLVTSPFHLERALVVFRNVLGFAWQVQAVAAEQTDDDLARANSETTFLQETFAFFEGIRPGDFPAVEKRYRARQVR
->tr|A0A519RZM3|A0A519RZM3_9SPHI Ankyrin repeat domain-containing protein (Fragment) OS=Pedobacter sp. OX=1411316 GN=EOO86_13990 PE=4 SV=1
-MNIYQIEQAYIQGKSLDEIKELYQSEIVGITDEQQVEVWEQVCGFANVEMIDYLIAQGWRTAGVENRNGDTLLHFLATPLHSYDYFISEKRVFECTKKLLEAKVSPLRKNSEGNTALMLGAKVAYTEMLEAYAEIGAKIDFTDRKGNTTLHILAEYSYSAVSDFETALERLMIHQRESNFDENNQRQVQVRHELEWRHNVTKARFNQFITFAIVAREFGIDPFQKNNEGQTAVDIAIYRKSKSIGAILKGVDFDDQERASLYFNAGGMDVHQACVHKDVEALTALITLGENLNEAYDKENDKHNGMTPLAIAMMEHSYEITDLLLKNGADATLRDSKSWHPFRYLFTPNSSVNVNFERFKEKTFQRILKAYID
->tr|A0A429HFY5|A0A429HFY5_9ACTN YceI domain-containing protein OS=Streptomyces sp. WAC 05379 OX=2203207 GN=DMH26_27780 PE=4 SV=1
-MGLTARIRTRDGWAVSHAVVTVTDMTGTQVLRLEADTEGAVRDADPLAPGAYTVIVTAVGYAPAAASAIVTASGRAEVGTVTLARQGGTELPPPGPWTVDPAHSSVAAVAQHLGISSVHGRFTRFSGAIEIAPDDIAKSRVDAVIRADSIDTGNGMRDGHLKSPDFLDVERYPEITYRSTGLTAAAGTDRWTVHGELTMHGVLRPVDLDLAYLGTGADPWGGTRAAFRATTELHRDDFAMNYNQVVQAGIAAIGTTLKVELDIQAVQGETLPQA
->tr|A0A7K9HDP6|A0A7K9HDP6_9AVES NCF2 factor (Fragment) OS=Bucco capensis OX=135168 GN=Ncf2 PE=3 SV=1
-MSLVETIQLWQEGVCAADRKEWRAALDAFTAVQNPPAKICFNIGCIHLVLGKLAEAEQAFTRSISCDKHLAVAYFQRGIVFYQRQNHEKAIEDFKEALTQLRGNHLIDYKILGLRYRLFACEILYNIALVYATMEDWKKAEEHLALAVNMKSEPQHNKIDRAMEAILKQKVCELVTISAGKLFRPNEKQVAQLEKKDYLGKAMVVASVVDKDDFSGFAPLQPRASGPPPRPKTPEILRALQGQPHRVLYEFIPETAEELQVLPGNIVFVLKKEKDNWATVMFNGKKGIIPCNFLEPVELQNKLHIQEETPLEDEIPESPHSTAPEKPRRPAPVYHLQVVEAAVTSPYILKVHYNYTVTLQVKPGLSYMELLDLVCKKLELQPEHTQLRYKPVESQALVTLSMENLDVAWSQSKGNCLTVWCEITEGEGFLLPQEATLEMGPTQVVAQYSYEATQPEDLEFQAGDVILVLSKVNEDWLEGQCNGKIGIFPSAFVQ
->tr|A0A368E3B5|A0A368E3B5_9PROT SDR family NAD(P)-dependent oxidoreductase OS=SAR116 cluster bacterium OX=2024888 GN=DBW67_07180 PE=4 SV=1
-MFRYDNKIVVVTGCGSIAAGIGNGRAMAMAFARQGAKVIGTDRNLEAANQTLEMVHQEGGLMEVVGLDSLDDMSVLAFFEDVLAREERIDVLVNNVGQSEPGGPYDMALETWRGQFALNIDTAFMAIKHVLPSMRARKNGAIINVSSVAGMRYIGKPQVGYAAAKAALVQMTKTTAIIEAPHNIRLNCVVPGLMHTPLVQVLAQKYAGGDTEAFVAKRNNQVPMGRMGDAWDVAHAAIYLGSDEASYVTGTELVVDGGITATTP
->tr|A0A7L4KQA5|A0A7L4KQA5_9CORV Kinesin-like protein (Fragment) OS=Callaeas wilsoni OX=1347786 GN=Kif2c PE=3 SV=1
-AMDSRLCRNVHPGVIIKIQRSNGSIHKATVKVVNVEHSCVTVEWSEDGATKGKEVDINDVIAINPELLELPPADVKENVPLQDNVTLQKQKRRTTLSKIPAPREAVRGRSRMSAITESQCSFQEDEMAVDPCTSLQTRKYLLLPAGRTRASGLGCVPEASLSSVNGNTENHLPAARTSSSESPVRRRSNIVKEMEKMRSKREEKRAQISEIRIKRAQEYDSTCPNWEFARMIKEFRETLNCQPISISDPIEEHRICVCVRKRPLNRQELLKKECDVVTVPSKCVLMVHEPKQKVDLTKYLETQTFRFDFSFDETSSNEMVYRFTARPLVETIFEGGKATCFAYGQTGSGKTHTMGGDFSGRTQNASKGIYAFASQDVFLLLNQPRYRSQNLEVYVTFFEIYNGKVFDLLNKKAKLRVLEDGKQQVQVVGLQERPVGCAEDVIKMITIGSACRTSGQTFANASSSRSHACFQIILRRRGQMIGKFSLVDLAGNERGADTSSADRQTRMEGAEINKSLLALKECIRALGQNKSHTPFRESKLTQVLRDSFIGANSRTCMIAMISPGMSSCEYTLNTLRYADRVKELSPHDGGIDAQSQMETEEIETSTEGSGLQFSFSKDEEEELSPHIFSYREVMTQISEREEKVVEQLKELRQRMITELDYLLGMAEKPDYDLETFVSRAKYFVEDSSRNFLSVRETLDALGTAMQLEEQASKQIS
->tr|A0A2D9JC90|A0A2D9JC90_9BACT Protein translocase subunit SecA OS=Rhodopirellula sp. OX=2024855 GN=secA PE=3 SV=1
-MSESSARETTNPNELDSSGVPLSSSSTEETGPDPXWTPPDPVLSEATALDPLAPNEPLEDAGNXVETTQEAVVRRSSDPSANKKKWTKASNWRPRMVRWQRXLARVNALESTLQAEDDQTIRKRSLALRYRAMAGEKLSEXLPEAYAXCREAGRRSLSMRHYDVQILGGIALFEGHXTEMQTGEGKTXTATLPLYLHSXVGKGAHLATVNDYLAKRDAEWMMPLFEMLGVSVGIIQTEDDQGGRRKSYGAAITYGTAKEFGFDFLRDRLXLRAQNRMQTEMLGSGDGGFSNSGDQVVMRGMHFXLVDEADSILIDXARTPLIIGSIEDTVRDQIIETYKWAAENAPXFELDEHFEIDDETKRYELTARGRSXVRALPKSDLVRTMGLVDMYEYIERSXKTHREFLLNRQYVIRPSEKDPNVDEIVIVDEFTGRLAEGRKWRDGIHQSIEAKEGVEXSVPTGQAARITVQDLFLRYPHLAGMTGTAATSAGELRKIYRTPVVRVPTNRPPQRIQLPSRVFGTLNSKFEAIAKEVEEXHATGRPVLVGTRSIXKSVLLSKLLDDLGXEHEVLNANXVERXAEIVAEAGGRGKVTVATNMAGRGTDIKLSNDVEQIGGMHVICTXLXXAARXDRQLIGRCGRQGDRGSYRQYLSLDDDILKGGYGAIKYEKLKKRGEATSGSVDRLAAMFHKAQRKVERRHFRDRMVLMHHEKERKXMQREXGQXPYXDTPD
->tr|A0A256Z8B1|A0A256Z8B1_9ARCH Uncharacterized protein (Fragment) OS=Candidatus Bathyarchaeota archaeon ex4484_231 OX=2012512 GN=B6U79_02805 PE=4 SV=1
-MNKKLRLLSVFLLLLASFSPVVQAEASCTGSVRRWYSFRELAWGDMNSWADVDGNWVKDEQEIISPCILVSVTFGRGRVICIGDEGFLSNVLVNEADNLRLGLNIIAWLAEAEGNRHRVLFDSAHNEMQDIGSGDPWRGYSIFAGKLRKAGYTVEKNTA
->tr|A0A4Q8BRW3|A0A4Q8BRW3_9ACTN Xaa-Pro aminopeptidase OS=Streptomyces sp. CNZ288 OX=2512147 GN=EV377_6800 PE=4 SV=1
-MDKPLARPHTGSHDLDVSAALHTFMGSAWAPSPLPSGVRVPGYDALAGRRARLSARFPGERLVLPAGELKVRSNDCDHRFRPHSAYAWLTGLTGEDQAGHVLVLEPAGAEGHEAALYVRPRSDRSTDEFYRDRRYGEFWVGRRPDLGEAAELTGLACRDLDDLAKLTAGPRPPARVLAGVDARTDGLFDRGPHSAAEPDRDAELGTYLAELRLLKDEWEVGQLQLAVDHTAAGFEDVVRALPAALRHPRGERWIEGVFQTRARAEGNGTGYETIAASGAHACVLHWIRNDGPLDPGHLLLLDAGVETDTLYTADVTRTLPLSGRFSRIQRQVYELVLAAQNAGIAALRPGARFRDFHRAAMAVIAEGLYDWGVLRITPEEALAPDSGLYRRYTLCSSGHMLGLDVHDCAKARASQYLDGVLEAGQVLTVEPGLYLQPDDETLPPELRGIGVRIEDDLVVTEDGARLMSDALPRDPDAVEEWMGTLLDGFRPGA
->tr|A0A068CJ75|A0A068CJ75_9PLVG Protease (Fragment) OS=Human immunodeficiency virus OX=12721 GN=pol PE=3 SV=1
-PQITLWQRPLVTVKIGGQLKEALLDTGADDTVLEEINLPGRWKPKMIGGIGGFIKVRQYDQVPIEICGYKVIGTVLIGDTPVNIIGRNLLTQLGCTLNFPISPIETVPVKLKPGMDGPKVKQWPLTEEKIKALVEICTEMEKEGKISKIGPENPYNTPVFAIKKKDGNKWRKLVDFRELNKRTQDFWEVQLGIPHPAGLKQKKSVTVLDVGDAYFSVPLDEDFRKYTAFTIPSTNNETPGIRYQYNVLPQGWKGSPAIFQSSMTKILEPFRKQNPDMVIYQYMDDLYVGSDLEIGQHRTKIEELRQHLLGWGFTTPDKKHQKEPPFLWMGYELHPDKWTVQPIVLPEKDSWTVNDIQKLVGKLNWASQIYSGIKVRQLCKLLRGTKALTE
->tr|A0A2Y9SHQ2|A0A2Y9SHQ2_PHYMC Fibroblast growth factor receptor OS=Physeter macrocephalus OX=9755 GN=FGFR3 PE=3 SV=1
-MGAPACALAFFVAVAVVMTGAVSGSPGMEQRVVRRAAEVPGPEPGPRELVFGSGDTVELSCPLPAGAPPGPAVWVKDGVALAPSDRILVGPRRLRVFNASHEDAGAYSCRQRPSQGVLCRFAVRVTDAPSSGDDEEGEDEAEDTAGAPYWTRPERMDKKLLAVPAANTVRFRCPAAGNPTPSISWLKNGKEFRGEHRIGGIKLRHQQWSLVMESVVPSDRGNYTCVVENKFGSIRQTYTLDVLERSPHRPILQAGLPANQTAVLGSDVEFHCKVYSDAQPHIQWLKHVEVNGSKVGPDGTPYVTVLKSWISESVEADARLRLANVSERDGGEYLCRASNFIGVAEKAFWLRVHGPQAAEEELVEAGEAGSVYAGVLSYGVGFLLFILVVAAVTLCRLRSPPKKGLGSPTVHKVSRFPLKRQVSLESSSSMSSNTPLVRIARLSSGEGPALANVSELELPADPKWELSRARLTLGKPLGEGCFGQVVMAEAIGIDKDRAAKPVTVAVKMLKDDATDKDLSDLVSEMEMMKMIGKHKNIINLLGACTQGGPLYVLVEYAAKGNLREYLRARRPPGTDYSFDACRLPEEQLTFKDLVSCAYQVARGMEYLASQKCIHRDLAARNVLVTEDNVMKIADFGLARDVHNLDYYKKTTNGRLPVKWMAPEALFDRVYTHQSDVWSFGVLLWEIFTLGGSPYPGIPVEELFKLLKEGHRMDKPANCTHDLYMIMRECWHAVPSQRPTFKQLVEDLDRVLTVTSTDEYLDLSVPFEQYSPGGQDTPSSGSSGDDSVFAHDLLPPAPPGSGGSRT
->tr|A0A0R1W6U3|A0A0R1W6U3_9LACO CDF family cation diffusion facilitator OS=Lactobacillus suebicus DSM 5007 = KCTC 3549 OX=1423807 GN=FD16_GL000874 PE=4 SV=1
-MGGVFSGSLALLSDAFHNLGDSAAILLGYFAQLIGRHPETERRTYGYRRAEIIFALLNSIFLIVISVFLIFEAAKRFSHPQPINGELMLIVAVVGLLANLASAFLLQGGSKDSLNIKATYLHILSDALSSVGVIIGALFIWFTDISWIDPVITILVAIYICYETWPIIHQTLSILMQSSPELDYACIKKDIKQIDGITGVHHVHAWMIDEHRIIFSVHINLKDMKLSEVEPIYQRIETLLKNKYHICHITIQAEVERGIEETMFNTPADKATTSDEVE
->tr|A0A0B1R8M8|A0A0B1R8M8_9GAMM DUF262 domain-containing protein OS=Pantoea rodasii OX=1076549 GN=QU24_03595 PE=4 SV=1
-MANDDKTLNLFPIDYPFETLCSRMESNPVKLKLNPDFQRKYKWDQDGWQRSSKFIESCLMRIPLPSCYFAEENDGNHIVIDGVQRLTTIQKFFNDEFSLEGMTTFKELEGKKFSELGSLRSELESTTIRCIVLRKENPKALIREIFSRLNQGAVKLSDQEIRHALYPGGFDDLLNELGGIEAIKNFGLAETTTVKRDSREPDEQVLRFFAFYDDGFAEHFNNTLKDFLDDQMETFSTLEEDRLNEMREIFKSSLQKCEKIFGDDTFTNPTVRRKRKGLVHYDILMPTIGKLSDEVVNDKAENIRQAWEDLCSSNEFKRTLSGGLQNKSSVIRRRDSWTKLLKEVTDGKD
->tr|A0A3E4PQR0|A0A3E4PQR0_9FIRM DUF3794 domain-containing protein OS=Dorea formicigenerans OX=39486 GN=DXC93_09950 PE=4 SV=1
-MLNIYRQGKTFTDQFYVDEDYNVPDTKADIREVIESDAVMEEIDLKLVENYIRITGRLAFQVLYVADNSDNTLSSLEGKIPFEEMYYVDETLEETLFLKAAQTELTVNLIHSRKINVKAMAEVTMSSDSQVSEEVTTGIESGEQIYTKYQEKQILTLHTVKKDTYRIKEQLTISGTKESIGNILWKEVLSRRLDTRLEADTLKLQGELLVFCLYESVDGKTDWICENVPYEGQVECFGAEEGMYHQIYPILTDALLEPAMDEDGEMRLLGIEATLSMRFFLCTEEKIQILDDLYSLKTCCVPAYTQCKVENVLMQNHSKCKIAERLSLPEIKDDILQICYSDARIQVEQMTVQDTGIQIEGVLHIRFMYVRPDDQIPFALWQGMIPFSWLLESNEVQEDMTLDMMPSLEQLGISLLGNGEIEVKAVLAFRSFLRGKVTFRNIDSVEEKEIDYKVLEQRPGIIGYIVKEGDELWNLAKYYGTTKEGIMDINHMESEQLKCGDKLLIFKENASIL
->tr|A0A285F1R0|A0A285F1R0_9PSED 3-oxoacyl-[acyl-carrier protein] reductase OS=Pseudomonas sp. LAMO17WK12:I10 OX=1286371 GN=SAMN05660489_00338 PE=4 SV=1
-MTESILVTGSSRGIGRAIALRLAQAGYDLILHCRSGRSEAEAVQAEVEALGRQARILQFDVTDRASCKAVLEADVEAHGAYYGVVLNAGLTRDGAFPALSEDDWDTVLRTNLDGFYNVLHPLIMPMIRRRAAGRIVCIASVSGQVGNRGQVNYSASKAGLIGAAKALAIELGKRKITVNCVAPGLIDTAMLDENVPVDELLKMIPAQRMGTPEEVAGAVNFLMSAEAAYITRQVLAVNGGLV
->tr|A0A1B9FWL6|A0A1B9FWL6_9TREE Nuclear RNA export factor 1/2 OS=Kwoniella bestiolae CBS 10118 OX=1296100 GN=I302_07512 PE=3 SV=1
-MAPGTSNSNNNNSRGGRPTRGSNNARNPTGTPPIVKQLQTISGKAEREHSKSELTKKLHGEEMKEWIRKRVIADGVLDMSNLPNDPWLKENGILPPGHPNAPPNAGTVFWRIIEGVVQKGAGITVLTLSLANNNLEHLAQLSKLPLTLPDIRALDLSGNPIKNIGELDNLRAAGEKKGKATSGAGSLKSLVEIKLNDCFFRERMLQQPDGPNIYKHDILRRFPGLRILDGVELERIILPIDRKPKVRLTDEQKAAFVAKPFAFPCDVQGGFSEEGVKEAAMQFCAKYFTLFDNDRNALIPGYAPNALISISANTLPSRSAYQVEAQKTRANRPQPVSFEAWTNLPSRNFFRGITTIRARMDSLHNPADAERLLRWWNKVVPRTKHPLSDPERWCFDTWVLDGEGENTKLCLMIQGEFEEMPSGTYRSFSRTFILSPAPPGSLAANAGWPAIALSDTMTVHSYLGTFAFDERNRSLATHGVTIQPPSLPATAPVNGAATGNDALIAQMSQQTRMNAQFSTMCLEQNGWNFEAALKNFEEIKGSIPPEAFV
->tr|A0A1Q6Z6P7|A0A1Q6Z6P7_9ARCH Uncharacterized protein OS=archaeon 13_2_20CM_2_53_6 OX=1805020 GN=AUI07_07525 PE=4 SV=1
-MKKSSDPADMVLREIEEMGKKSFIPSIGPLKGRILADIVREHKPRLILEVGALYGYSAILIAKNSPAHAQITTVEKDPKNARITQENVARAGLDDMIEVIQGDAIIILPELPGPFDLVFLDAEKIQYLAYLKAIEAKLHQGSVIVADNVGVFRDQMMDYLNYVRTTGRYRSRTVETLLEFSETTKDAMEISEKRY
->tr|A0A7Z6L1Z8|A0A7Z6L1Z8_9NOCA Low molecular weight phosphatase family protein OS=Rhodococcus sp. AQ5-07 OX=2054902 GN=CVN56_03915 PE=3 SV=1
-MHVLFVCTGNICRSPTGERLARAYAAEAGVSGFTASSAGTRAMVGHPIEPTAARVLAGLGGDPTEFQARRMTTALASDADLILTMTESQRDKVLAMAPARLKRTFTLREAARLGSLADARTVEDLAAARPRFRAAEPEDVMDPMGKEENVFHEIGLEIADLLGPLLSRLRFGER
->tr|A0A5T8G289|A0A5T8G289_SALER Phage terminase large subunit family protein (Fragment) OS=Salmonella enterica OX=28901 GN=DQ454_26965 PE=4 SV=1
-PPTTGILSLYNRGDRRRWYWPCPHCGEYFQPSMENMTGYRDSADPMVASEAARLQCPHCHKLTEPQQKRELNNRGVWLREGQHIDRDGNITGEARRSRIASFWMEGPAAAYQTWAQLVYKLLTAEEEYERTGSEETLKAVINTDWGLPYQSRRSLEARSSDALMARAEDVSKRTVPDGVRFIVATVDVQGGKKRRFVVQMVGYGAYGERWIIDRYNIRYSLRVNENGESQPVNPAAMPEDWDLLRTDVLDKEYPLAGDPEQFMPVLAMAVDSGGEDGVTDNAYAFWRRCKRRGVAGRVYLFKGDSTRREKLITKTYPDNTERSDRKAKARGQVPLYLLQTNALKDRIAAALEREEPGANYIHFPDWLGPWFYEELTYEERGADGKWKKPGRGNNEALDLMCYAHALVIIRKYEQINWEKPPGWARLPEKGAAKTTQPVGARRQEQHEGGEKAVKARKKKILPAWGGGSGGGWL
->tr|W9B5Y0|W9B5Y0_9BACI 3'-5' exonuclease DinG OS=Oceanobacillus picturae OX=171693 GN=dinG_1 PE=3 SV=1
-MERFVVIDLETTGHSAVKRDKIIEVGIVVIEENEVVDSYGTFLNPGKSIPEFISSLTGIRDEDVKDAPTFEERAEEIAALFEDSYLIAHNVPFDMGFINAEFAAVGRELLQNPVLDTVELARVLYPKAPSYKLGQLAEYLGIHHEDPHRALSDAYVTAKLFLKLRERLDNLPYETITHLIRLEKMLKSDLFALLADRENELAFSTQEDPELETFQGLAFKKIKETKNTPQTRIGSYGDFLDAIYEEGGTLSQQMARYEKRTGQREMSETIYDAFQSRRHALIEAETGTGKSLAYILPAIYDAVISGQRLVISTFTTQLQTQLLEEEIPLIRNLLPFPFKVALLKGKSHYISLEKFERELLSTEKDNYDITLTKAMILVWLTETQTGDIDEVQLPSSGYLFFRRVSTDTEAHVDPQSPWFLRSYYQKARKAAQQADIVITNHALLATDIFNDYQLLPSYDKVIIDEAHHFEETASKHYGLKLDYMNMQYTLNQIGETNDPKFIGQLITKYRDFIEEEMIDRWDDLIIDAKYETDDLFRGIFQYVAEQNKHQKSLSDIGRTQYRFENSKEDTAKWDTILEMTNRLMFFLRDLIYILARLDQNLAKQYEDKYDKNEVEQYIEQLQQYMDHLESLFLAADSPKFVKWVEVETYGAKNAVYLYSEPTDISGFLSTDFFAKKESVILTSATLTMKNSFTFIKERLGLTDEEIETKKIPSPFSYKDQVQLMIPTDFPDIKHGNQDDFIYATCEAIFSLAEITSGRMLVLFTSYDMLKKSYYLLKEIMDTSTYALIAQGISSGSRSRLKKNFQTFDQSILLGTSSFWEGVDIPGEDLSSLVIVRLPFQPPDHPIFEAKSANLKENGKNAFMELSLPNAVIRFKQGFGRLIRSNTDRGIVFVCDSRIIQARYGKYFLDSIPEIPLTKDTTQQLMRKAEEWF
->tr|A0A0D3HJS1|A0A0D3HJS1_9ORYZ Uncharacterized protein OS=Oryza barthii OX=65489 PE=4 SV=1
-MATKATTALLLLAAAAAALLCHVHVAVAAADSEPCDPSDITIATVKTGRVVGGLPEFQVTIGNECSCPEGDVVLSCLDGVPAGVDRSKIHTAGNDGLCLVNDGLQIVKGSPVVFTYAASAPISLAFDNASPRCQR
->tr|A0A481QYF4|A0A481QYF4_9PSED Pilus assembly protein PilO OS=Pseudomonas sp. DTU12.3 OX=2073078 GN=C2E19_18930 PE=4 SV=1
-MRIPRLIVHEYLQGLGIPGLAGLALLLIAVAWALGGLLPGWQSLQHLSQQTQEATEYLAKVEDGSIAPPVVPQRQLDDFRNKLPAQPQATVAIDRIYALAAQEHITLARGEYALGVDPKTHLARYQILLPVRGSYPQLRRFVHALLGQLPAVVVEDLELQRKKIGDTDLNGRIRLTLFLSRS
->tr|A0A412E108|A0A412E108_BACSE Transposase OS=Bacteroides stercoris OX=46506 GN=DWY58_15645 PE=4 SV=1
-MEPSIKDKYIILGFIFVAICMISFFITIIIAASFNQDNFVRLIVFVCSNLLGWLLYLSFQTVIFDTYEIYRIKFGKKEMKEITTETVALQEEEPQNTIEPVTQIAEGASSDAHPIELNIDPKRHEEIRSSYKDEQDKENERRIRMVVEYIHFYMPRIADEETVNHVCNEVSNWMNKNNYKPKPIKRRLTQDISNIPLRHFIWNIAERCMYKRYYNGDNRARFVKELFPREFSETDIATIKNFKVDPLKSPIPIDEPEDGKPDFHYPNGYLRKE
->tr|A0A448JZC9|A0A448JZC9_PASAE Membrane-fusion protein OS=Pasteurella aerogenes OX=749 GN=acrA PE=3 SV=1
-MTKKRFFLLFIVIVALAAGYFYYGNKNDKTITYLTETVQRGNLQKTVIATGTIRAYNRVEVGAQVSGKIEKIYVTLGQKVKTGDLIAQIDSSTQQNTLDTATAKLASYQAQLKAKKVAYSVAKSSYDRLAKLYAKKSVSLDEFESAKDTLATAEAAIEEIDASIKQAEIEVNDAKTNLGYTKIVAPIDATIISIPVSEGQTVNANQTTPTIVQVADLSKVLIKPEISEGDITKVTAGMEVKFSTLSDPDKIYRATIDSVDPAMTTLTDNEYTESVSDTNAVYYYANVVVENPDNNLRIGMTTQNTITIADVKNTLLIPTMTLKKQNNKVFVNVLTTANQVEQREVQIGLNDDMNTQILSGLNEGEKVVSSQVAAGETVGTVRGPKMF
->tr|A0A1T0CT31|A0A1T0CT31_9GAMM Pilus assembly protein OS=Moraxella pluranimalium OX=470453 GN=B0680_01190 PE=4 SV=1
-MTVQKGFTLIEMLVVLAIIAVMAMVAIPAYHAMMQRFESQSSKRHIAEAIRRAKIEANLHQKDIILCPYGVNEQCDRLGQVGLLVFVDKNSNNRLDDADIVSMKQPLDLRYGLLSMRVSLGRHYIKFMSDNAKPRGHIGNIRYCNTEQNNSLSHLTTINMHGVVTAKSGDVVSIDCG
->tr|F8J9Q9|F8J9Q9_HYPSM DNA (cytosine-5-)-methyltransferase OS=Hyphomicrobium sp. (strain MC1) OX=717785 GN=HYPMC_1709 PE=4 SV=1
-MEKLKLLDLFSGIGGFSLGLEASGYFEPVAFCEIDTFPQSVLARRFVGVPIYGDIRALTAERLRADGIMVDAICGGFPCQDISVVVLDPFGGSGTTALAAETTERKWILIERDEEYAEKAMARIRDHVLGESHPAPAKKKRTPAALPKPTHEIAQVSLF
->tr|A0A1U8LF61|A0A1U8LF61_GOSHI tubby-like F-box protein 5 isoform X1 OS=Gossypium hirsutum OX=3635 GN=LOC107926834 PE=3 SV=1
-MIQMSLKSIMRELKELKDGIGNMSKRGDQSKLWRSRTRSHVAPDEAPLESQLSEQSPWANLPPELLLDIIQRVEESETAWPARAVVVFCAAVCRSWREITKEIVKTPEQCGRLTFPISLKQPGPRESPIQCYIRRDRTSSTFLLFYGLVPSEGESDKLLLAARKVRRATCTDFVISLVADDFSRASNTYVGKLRSNFLGTKFTVYDSQSPCDSRIQSTARPRRRFHSKQVSPRLPACNYIIGTVTYELNVLRTRGPRRMHCILHSIPVSAIQEGGTAPTPSALPQSLDEQLSPLHSSKGKEPIVDIISPSIQATPVFSPGSREPLALKNKAPRWHEQLQCWCLNFKGRVTVASVKNFQLVAAVEPSHNVSPEEQEKVVLQFGKIGKDIFTMDYRYPLSAFQAFAISLSCFDTKPACE
->tr|A0A212IWF4|A0A212IWF4_9BACT Chaperone protein htpG OS=uncultured Dysgonomonas sp. OX=206096 GN=htpG PE=3 SV=1
-MQQNGKIGVTTENIFPIIKKFLYSDHEIFLRELVSNAVDASQKLKTYASLGEFKGELGNLSVKVKIDKDNGTLTISDNGIGMTNEEIDKYINQIAFSSANEFLDKYKKDANSIIGHFGLGFYSSFMVSKKVEIITRSFKEGAEAVKWSCDGSPKYTIEAVEKAERGTDIILYIDDENKNFLEQGEIDKLLKKYCRFLPVPIVFGKKTEWKDGKSVETEEDNVINDTNPLWTRKPADLKDEDYKKFYQELYPFSDEPMFWIHLNVDYPFKLTGVLYFPQIKSNVDMNRNKIQLYSNQVFVTDSVEGIVPEFLTLMHGVLDSPDIPLNVSRSYLQSDQNVKKISNHITKKVADRLEEIFKNDRSRFEEKWDSLKIFIEYGMLTDDKFYERAQKICLLKNTDAKAFTFEEYKTLISSDQTDKDGNLIYLYASNKDEQYFYINTAKDKGYDVILFDGQLDVHMAGMLEQKFEKSKFVRVDADTIDNLIPKEDSKEVNLTDKQKEELNEAFTSQLPKIEKTEFIIDYKALDEKAQPIQITQNEFMRRMKEMSAMQTGMGFYGEMPNSFNLVLNIEHPLIKKIMGDIDNKDKEAVNLYATENRDIRQLIDLALLSNGMLKGEALNNFVKRNMENI
->tr|A0A1F0KNA7|A0A1F0KNA7_9MICC Long-chain fatty acid--CoA ligase OS=Rothia sp. HMSC066H02 OX=1739503 GN=HMPREF2999_09040 PE=4 SV=1
-MKVFSTPAEVLVDPSLNLTSIVERHRADSSNPVLYRRQMSPGNWQPVRAQQFHQMVTDLAKGMIASGIRPGDRVGIMSRTRFEWTVIDFAIWYAGAISVPVYETNAPAQAAWALAHSEATAIFVEDEKLLARIAEAEEFASTTQEPMQLKHRWVIENGDLDTLSTRASEVSDEQLEQVRSAAGCDDLATIVYTSGTTGRPKGCALTHGHFLNLSANTRLVEPEIANSRNSSILFLPLAHVLARLIQVLALDAGLVIGHSPNIKNLASDLDSFKPTMLLVVPRVFEKVYEGAMAKAAKGGKFNKSLFERSTDIAVRWSQAKVEGRVPLKLAAQYALYDKLVYSKLRAALGGELRYAVSGGGPLGERLAHFFHAVGVQVVEGYGLTETCAPIAVGRINPYQIGMLGPLIPGAEGYIAEDGELLVRGVGVISSYYKNPEEDAHAFTEDGWFRTGDLARFDERGYLKIVGRKKEIIVTAGGKNVIPGIAEGHLRTSPLVSQAMLVGDEKPFISALVTLDPDTLPEQLEHLGLPRSLSIPEAAVHPAVRAAIQKLVDEANQLVSRAEGIREFRIMNRDLTEEDGYLTPSQKLRRAKILQDFSSYVDEMYGKVSDSTSDSLARLQEYAAEQSEKFAELREQAAERLHEYADQQTERLAELREQAAEKFEELREQAVERMQKPQEDKTETKEDAERSEKTNDDSEHETATPAKGVEAKKADTQRSEGEDS
->tr|A0A370IAZ5|A0A370IAZ5_9NOCA Uncharacterized protein OS=Nocardia pseudobrasiliensis OX=45979 GN=DFR76_102294 PE=4 SV=1
-MKIALVGILAGLGLLTAAPAHAAALTPDYAQPPNGAGVDPGHNLTPVWSPIQVPALDDVDTASTTTITAHPYLAPWAHERVPIPAGTAVELRGAARVRIPEANGKTLVVNPNGHCYFDGPNAVSGDLTPTALTPVRIDTSAFQLTIEPTLYRH
->tr|A0A5K3FDK5|A0A5K3FDK5_9CEST Uncharacterized protein OS=Mesocestoides corti OX=53468 PE=4 SV=1
-MDSVWLLLCTIAKLVFTIIWLMLVVIFRTGKCAVRTAAWVIVKCARFVGIRRKRIHFALMGETQGLVEETTGPIAPWRLVREGLDPEKYRGNYPVLRTHVPPVTTPQPRLVCRSFRATGTGRQVRGRPGAGEIVLRGSTKYRSFAALH
->tr|A0A4U1DEZ0|A0A4U1DEZ0_9BACI Uncharacterized protein OS=Bacillus kyonggiensis OX=1037680 GN=FA727_10130 PE=4 SV=1
-MQTLERKGAGGVVVNPNRDKFLKEQRDLKQQYLGGARDNRTEMKSDPEYNNKNDTDISVGATGREVEEE
->tr|A0D4D9|A0D4D9_PARTE PUM-HD domain-containing protein OS=Paramecium tetraurelia OX=5888 GN=GSPATT00013372001 PE=4 SV=1
-MKSQIVNNQRYYSCQDEDGNSTRMLRNSNNSVRILTDIQLPQQMSKSTQDAYEKGESEMKNNIFDNVIKENIIGFSIDIYNHYIIQCILEKGLSEHKSYVLRQVVENMDLFCYRKYAYKIVQACLTQFQNNQIIQYIIDNIKRLQFDQYGNLIISTLLDTIQNDEQFAQIINKLQIDKIKYHQYGCVILINMVTCPKANHVGPIINKLIQESIQLSKSQFSNYIIQKMLKERTIEQNKVLINEFLIPNFVELSCNKFGSNVCEIMVTKSLAYQLQNLWNLVIKQYDFYLFQESEITFEQ
->tr|A0A1S1CB24|A0A1S1CB24_9MICC Uncharacterized protein OS=Rothia sp. HMSC061D12 OX=1715161 GN=HMPREF2682_07995 PE=4 SV=1
-MQYKARKHYETYYQKIAEAEKDPAVVKGENADGKTYILEKDKLAMVVGKNNEYIIFHQHDGNWSRLRPNGELELTYSDRAWVRVMPDGERIAVKASGNTNIAYHQGDVSEDIITSLKTPEVPAQVEGFASVPQKPVKPKKLGTVVGTK
->tr|A0A1Q4EHA6|A0A1Q4EHA6_9PROT Carrier domain-containing protein OS=Thiobacillus sp. 0-1251 OX=1895858 GN=BGP19_06145 PE=4 SV=1
-MDTRQTLADIAIKEFQCDPEKIKEDASIKDLGIDSLGLLEFIFRIEEVFAIRVDNEDAEKVQTLTDIANLVDRLRTMAAA
->tr|Q48M18|Q48M18_PSE14 Type III effector HrpK1 OS=Pseudomonas savastanoi pv. phaseolicola (strain 1448A / Race 6) OX=264730 GN=hrpK1 PE=4 SV=1
-MRISSSPSPALGSIVNQPTSGELAAETPLAKVSLTQSSAGGDQAFVQFGQANDNTSFFSDAEQSGSSLMSLLTRSSNSESTSSVDQDSDQVSPITSVLSTASASPAASASGPANAPSATDAAFLDNSEYSSPEALKRWDPMVAHLPPEEREQAAKELNRPIAAAWMAREHGPNADKAMAFINANPALKTAVDVGKDGGNADGKITNKDLKAFAKNMEKAADNADKDLAKYMEDNPGADPQSLEMVRSAAVMRANMPLATAADPHHAVGAPDKTDVDGNVSAEGLKALIKSNPGLSGTLKQSSNMWSQAGFLSQVDEAGLTGRKKAAHSPDQVFDASNMSEWIRKSAPKNGGQFASMLSDAATLNSVAGIDISKLNAQVFEKPKAYTGAQKAAVMIKLQQTQQSVIAGRDLRNTEKTEAGLNERIAQLQADPDVQEYLNKSIPEQERSLVSSDSALQKAVTEQVQNVNSGKALQTDLATADKAVGKHNPDPDYSGAITGLSAQLQLQKDLFPDAQVPTAQQVFNNQPDEVQTKIADSYVRNFSEGGALKQLLGQKKSDAGESLQTADNQKAAYESVLPADFVNGERESYTASTLSELQNSKKGRKLLEGKTDEEGGPSLAAQLAEQGIGGKAFNSVMGFASVSDRLASGDKLGAAQSIIDSSRLGAEAIKGGIDTGAKMMGREASAGLGRLGGQMIGRAVGLVAGEATGLAAGAALGAAIPVIGWAIDGAMALGFGISAIIDAVKKHKAQKAFDHNVDPVLDQFGIAKAH
->tr|A0A7C6ZKE3|A0A7C6ZKE3_9FIRM Ribulose-phosphate 3-epimerase OS=Syntrophaceticus sp. OX=2699755 GN=rpe PE=3 SV=1
-MQIKIAPSILTADFSKLGDVVKELEKCGADQLHLDIMDGHFVPNLTFGPPVVASLSQITSLPFDVHLMVEHPEGLFSAFATAGAKSLTVHAEACTHLHRTVQMIKDLGIRAGVALNPATPLSFVEYILPDLDIVLIMTVNPGWGGQAFITTMCEKIRKLRMMLKDSGSPAELQVDGGINQQTVKSVVEAGANSLVIGSALLMERDWGQAIEQYRSLAVEAARDSWWCSS
->tr|A0A089X985|A0A089X985_STRGA Uncharacterized protein OS=Streptomyces glaucescens OX=1907 GN=SGLAU_22790 PE=4 SV=1
-MSATPKSQLPVRGGDRKPARVRPYSLTGGRTRFGHVLLVETFVASTAALEAPEERRELTNGSLTTRVMPEMLAIVELCRRMRTVAEIAALLKMPLGVVRVLLSDLADQGKIRVYGTGTGHGTGRPNRALLERVLSGLRRL
->tr|A0A849PEY0|A0A849PEY0_9MICO Acetyl-CoA C-acetyltransferase OS=Calidifontibacter sp. DB2511S OX=2732509 GN=HK411_11245 PE=4 SV=1
-MPEAVIVSTARTPIGRAFKGSLKDIRPDDLAAQIVQAALAKVPGLDPTLVEDLYLGCAEPWAEQGSNMARVVAVLSGLDHVPAATVNRFCASSVQTIRMAAHAIKAGEGDVFISGGVECVSRYADFAGAGGSKADWQNPKFADAIKRTEQIAQDNTTWTDPREQGLLPDIYIAMGQTAENVATSRGISRQRQDEWGVSSQNRAEKAIADGFFEREITPVTLPDGSTVSKDDGPRAGVTLEKVSQLQPVFRENGTVTAGNCCPLNDGAAAVVVMSDTKAKELGLTPLARVVSTGVSALSPEIMGLGPVEASKQALARAGMTINDMDLYEINEAFAAQVLPSADDLGMDFDKLNVHGGAIALGHPFGSTGARITTTLLNGLQSTDGTFGLETMCVGGGQGMAIIYERLS
->tr|A0A415DY63|A0A415DY63_9FIRM Amino acid permease OS=Emergencia timonensis OX=1776384 GN=DW099_13175 PE=4 SV=1
-MDTKKHEGSFKKAIGPFSGISIVAGMVIGSGVYYLGSYVLERTGLSMGWSLVAWIVGGFITIVGGLCFAELGASMPVAGGQTVYLSKAYSPAFGFINGFSCFLLTGSGGVAALAMAAVTAYRTVFEISDIMVKVLAIAIILVLMVINLLGVREMTFYQNFSMVIRMVPILMIIIAGFVMGKESPDLSLSLAGTSAEGGGVTAVISMIGFATFASLWAYDGWYNLNTVAEEMKNPKKDLPFAIITSLIGVTLIYVLFYLAVYKVLPSEDIAEMINSGNLYLGNEVVSRTLGGTGIWILLICMTIGIVGSANVNTLCDPRTYYAMAKEGYFPKLFGHLSEKHGVPSYGIIVSAGMAVLLVIFNSLQELTDMLIFTTSILNLMTIYGVLIMRKKYPDIERPYKVWGGKFTIYLTSLMYVVLMVNEFIDAPKAAITGVGITVAGLIVYLYFKKKNGGEEYKGEGIE
->tr|A5I032|A5I032_CLOBH Putative non-heme chloroperoxidase OS=Clostridium botulinum (strain Hall / ATCC 3502 / NCTC 13319 / Type A) OX=441771 GN=CBO0840 PE=4 SV=1
-MGYYIRVEPNVKIYVEDLNPEGNKTIVFLHGWPGSHNLFEYQFNQLPKMGYRCVGIDTRGFGNSDKPWSGYGYDRLSDDVRCVVEALKLHDFTLLGHSTGGAMAIRYMARHKGHGVSKLALIDAAAPSLIKRPNFPYGLEKEDVIKIIQGTYNDRPKMLRDFGDTFFFQHITEPFSDWFFQLGLQAASWATAAIANTWINEVLFSDLETINVPTLIIHGIHDKVVPFELGEIQNKMIKHSKLIPFKYSGHGSFYDQRDKFNKELVKFIEE
->tr|A0A3D2U5H6|A0A3D2U5H6_9PLAN Tagaturonate/fructuronate epimerase OS=Planctomycetaceae bacterium OX=2026779 GN=uxaE PE=3 SV=1
-MTDIPGPCQTLGTIPSFGFGDRIGLATPGHVLAMQRSGQGILPIFPQQSIREMARTDRSPDDVMNDALTGMREAGWDGITGADADHLKTNTDAEITAEAGYTFFTIDPSDHVDEKADTYDEATLRERFAEIQHDLTWLGDYRGRKLTLETGARIECTEQACLRAGVKYGRAINHAIELAGHIAAVQGQAGRDYEIELSVDETDHPTTLAEHYIIADRCLVDGIRLISLAPRFVGDFEKGVDFKGDLEQLVRSLADHAALARHLGPYKLSLHSGSDKLAMYAMLAQATRGCYHVKTAGTSYLEALRVAARHDVSLFREVIEFSRGRFEIDRATYHLSATIDSAPPAEEISDPIELERLYLGLWSEVPVGEGFTGLGRQILHCTFGSVLTDSRLGPRLRSLLETHQDTYTEVLADHFGRHLDALQAGLSQSG
->tr|R7KQJ7|R7KQJ7_9BURK 50S ribosomal protein L11 OS=Sutterella sp. CAG:521 OX=1262977 GN=rplK PE=3 SV=1
-MAKKIVGYIKLQVPAGKANPSPPIGPALGQRGLNIMEFCKAFNARTQGVEPGLPIPVVITAYADKSFTFIMKTPPATILIKKAAKIQKGSSRPHTDKVGKITRAQAEEIAKTKMPDLTAADMDAAVRTIAGSARSMGITVEGL
->tr|A0A2G9V0G2|A0A2G9V0G2_TELCI Uncharacterized protein OS=Teladorsagia circumcincta OX=45464 GN=TELCIR_02714 PE=4 SV=1
-MHDIFDVVARIHVKWVRVVARTCSLILMVLDVMKPLKHKQLLEYELEGFGIRLNKQPPNIGFKKKDKGGINLTQLISLAELGSLEEEHFCFDVPTKALMNQMGETVLRITSKGHAADGVASTKSQRNTSANAAGLRKKV
->tr|A0A4Y1VGS1|A0A4Y1VGS1_BACUN Protein kinase domain-containing protein OS=Bacteroides uniformis OX=820 GN=Bun01g_11110 PE=3 SV=1
-MFTLAKRQQLGNYIITFQVKEGDYAETYRVKDADGKNRFLKLINCAKLHRTQFDANGNILEVQIAKTLNHPNVVKYHDNGEVVLDGRKFAYIVFDYISGETASQYIAREGSLSVYDAKTIVLGILNGIKFLHTQQEPIMHNDLTIQNVMLDMSKGTNVPRIIDFGYARYLSQGSSSFNKNGLSPFYLAPEALNGVFSVKSDIFSSGAILYNLIFGIPPYFVDLSDCKNDATAQREKIDAQRELPLHIPDNDKFELDEQIMNIMRKALASDIEERFKSADEFIRALNGDIKIARIDNQKKAKSGKTPTKKVSYSVPKGKGFSAIAGMEELKEQMRVEVIDALNSPEEYAKYGLTIPNGMLLYGPPGCGKTFFAKHFAEEVGFNFMLIKPSSLKSRFVNATQENIAQMFKDAEENAPTIIFIDEMNELVPNRDSDVHEMARSAVNEMLAQMDRTGERGVFIIGATNYPDMIDPAILRAGRLDKKYYIGTPDFKARSLMFELYLKSRPYDFGLDYEKLAQLTENYVSADLEMIVNDASRIALRQKSRITMVILEDVISKTKPSLTKSELDKYLRIKAAMAGEQIQQSRRRIGF
->tr|A0A3L6ZV02|A0A3L6ZV02_9MICO Multicopper oxidase family protein OS=Mycetocola manganoxydans OX=699879 GN=D9V29_08490 PE=4 SV=1
-MPNSISLRQQLSRRTFLSAGLSGAALLALAGCTPTPAFLSPTSARVAKTEAARKATGATTKVALRASTGAIDLAGTSAQTWSFGSIPAPIIRLAQGDELDATIQNTLPDATTVHWHGLALRNDMDGVPNLTQDAIAAGSSFRYRFTAPHPGTYWFHPHVGTQIDRGLYGALIIEDPREPLAYDDEWVVILDDWLDGVTATPEEVLAELSKGMKEMAGMEGMMMRMGNTLMGAESDALGGDAGDVYYPHYLINGRPPADPETYTSAPGKRVRIRMINAGGDTAFRVALAGHTLTVTHTDGFPVEPLDVDSVLVGMGERYDVIVTLGDGAFAFVAEAEGKNARAFAVVRTGSGATPASNVTVSEITGRLATADGLRAASEVVLPNKKPDRELTIRLRGSMKKYDWSLDGRPFTMDDPMIKPYSIAEGERVRVNFVNTTSMWHPMHLHGHTFQHAGGGPRKDTSIVLPDRTLTVDFDADNPGRWLAHCHNIYHGEVGMMGVFAYTG
->tr|A0A817XL60|A0A817XL60_9BILA Hypothetical protein OS=Rotaria sp. Silwood1 OX=2762511 GN=BAC187_LOCUS7404 PE=4 SV=1
-MAYLNLASAANSTTSSTSSPYSHVNSNGGVSTIPPSLVSNSPSIFGSVGGGKQWTTIGQPTSSSSSSTLTQQLLMKQQQNILNNQQTNPLSSSSSSSHFDSILGLTMASALASSSQTQIEKNFELQQEDFPPLPHRSNSHEPTSSSTNVQPLYQSQYSSSSSSSNLHQPITNGYSSSQQQQQQQQHSQSQSPISFKTSIDALSTLINRRQTSVNNKTTSLTNNSTSSTTNPQQISSTSTTNINGLPSSTITDQYGLVGLLQMIQQAEKNPETSTLLNYDLTTLGLSMESQNDLYPSFLSPFSDSQARPYEIDYQVPFEYQMGLQIRDKLPPLNFNTLNEDTLFFLFYLFGNDHVQLLAAAELYRRDWRYHKEERIWLTRIKNIMPDQKYDTYETGVYCVFDVQLWRKTHKSMRIDYEKLDVNPVLKQDLFASKLLQQQSPVQPQFAPVSSYNTNSSR
->tr|H6QSH4|H6QSH4_PUCGT Uncharacterized protein OS=Puccinia graminis f. sp. tritici (strain CRL 75-36-700-3 / race SCCL) OX=418459 GN=PGTG_11407 PE=4 SV=1
-MAGSLSLILLCLQVVSTVLGNSDPSAQIHRRSPQKPSKPPVSNTKANAKPVPFGFGSKVTGGGNAAPQTPKDPAELEAWLNDPAPRVILISKTYDFTSPNITKTSGW
->tr|A0A2U8VWI3|A0A2U8VWI3_9HYPH Uncharacterized protein OS=Methylobacterium sp. 17Sr1-43 OX=2202828 GN=DK427_22560 PE=4 SV=1
-MEHVSEGDPQAGPAFGRTASLLAEIAVILRVDPVIFFDGEIRKRVDQDLAVDELADLLALLRSVDGPDLRAAARDLIRALKRNEADED
->tr|A0A0B7NY01|A0A0B7NY01_PROFF Uncharacterized protein OS=Propionibacterium freudenreichii subsp. freudenreichii OX=66712 GN=PFCIRM138_07065 PE=4 SV=1
-MTEAKNPWLSHPAEPEPDTPVAIEEHVRPATGPVAPQRGVPAPDRADQLPLFDRRQNADVWWLGVHGGAGESSLSVVLPGSAAADHGWPQTPGEQPARVVLVARSNMRGLRAAQAAATQWASGLVPGVDVLGLVIVADAPGRLPRPLRDFAHLVGGGVPRTWTVPWIESWRLGEPPALSDAPREVRRLVDELHALIRPGADGTTN
->tr|D7SV11|D7SV11_VITVI Uncharacterized protein OS=Vitis vinifera OX=29760 GN=VIT_04s0008g06260 PE=4 SV=1
-MVGLSVGEKHFIQGGIAQDLRTDGRRRLTYRPFNVETGVIPQANGSARVRLGGTDVIASVKAELGKPSPSQPDKGKVNIYVDCSPTAAPMFEGRGGEELSTELSGALQHCLLGGKSGAGAGIDLSSLVVVEGKVCWDLYIDGLVVSSDGNLLDALGAAIKAALTNTGIPKVEVAVGASGDGLPEVDISDDEYLQFDTSGVPVIVTLTKVGRHYIVDATLEEESQMSSAVSVSVSGQGRICGLIKRGGAGLDPSVILDMISVAKHVSEQLMNKLDSEISAAEAFEEES
->tr|A0A352XE32|A0A352XE32_9CYAN Phosphoenolpyruvate carboxykinase (ATP) OS=Cyanobacteria bacterium UBA11367 OX=2055774 GN=pckA PE=3 SV=1
-MNQQNYAVESQRRNLHQAHQTSSPVHEQIERHSYTLGSLGMKNLGMVYHNLSVPQLIEKAVARGEGVFADNGALCVKTGKYTGRSPSDKFIVDEPSIHDEVDWNRVNVPLTQEKFDQLYRRMLAYVQGRDLFIFDGYVGADPQYRLSVRVINQLACQNLFAHQIFIRPTEEELQTHEPELTIIAVPGLQGDPDLDGINSEAFIVISFEKRIVLIGGSHYAGEIKKSAFSFMNYLMTKQGVLPMHCAANMDDDGNTALFFGLSGTGKTSLSADTTRHLIGDDEHGWSDRGVFNFEGGCYAKTLHLSHENEPQIWEAIHFGAVLENVILDEETREPDYDDESLTQNTRVAYPVEYIPNCAIPGIGSHPKTVIFLTADAFGVLPPIAKLTNSQAIYHFISGYTSKLAGTERGITEPQATFSCCFGKPFLPLCADVYGEMLYERLVKHNVDVYLVNTGWTGGSYGVGKRIAIQDSRAMVAAALNGELNRVRFYPDPIFKILVPEAVPGVDSDILDPRKTWSDSEAYEQQAQALAKKFVANFQQFNNVSQEIKQAGPSLD
->tr|G5ZW58|G5ZW58_9PROT Putative phytoene/ squalene synthase OS=SAR116 cluster alpha proteobacterium HIMB100 OX=909943 GN=HIMB100_00002480 PE=4 SV=1
-MRPMKLSAYSDLRRHAPRLALTLLFQTEEQKQILAFLLLFGLELDRISALASEPMLALIRLKWWEDQLEVKTDEAGPLAGYLHQQLSSAHLKKADVIKLIDLWTMSVQAGQADQSENWAELIDLMAAKVNVQSSELARQIGRAVALSRSGQPSGVIPSARDIHKACGQGAEFLICLAYLAAESQKRDLNSSPFLVLGLLKQVLFKPASR
->tr|A0A183VZ29|A0A183VZ29_TRIRE Uncharacterized protein OS=Trichobilharzia regenti OX=157069 PE=4 SV=1
-LCVHIFSCQTCGKEFIQPSNYSRHLRIHTKERPYSCKLCSAEFLYSTSLKRHQQRNHGVELLRCQLCQKTFLNESCLIRHRTGCELRACVKTADEGLCTQLL
->tr|A7LFU4|A7LFU4_CAPHI Galectin OS=Capra hircus OX=9925 PE=2 SV=1
-MDSLPNPYQQSVSLTVCYMVKIKANLLSPFGKNPELQVDFGTGTGEGGDIPFRFLYCDGMVVMNTLKDGSWGKEQKLHTDAFVPGQPFELQFLVLENEYQVFVNNKPICQFAHRLPLQSVKMLVVRGDIVLTSVDTL
->tr|A0A4R7X8B1|A0A4R7X8B1_9NOCA Uncharacterized protein OS=Rhodococcus sp. LP_11_YM OX=2485207 GN=EC908_103210 PE=4 SV=1
-MTLTTDITVGEVLPQLSIYGDPTFVVSAALATRDFQDVHHDRDLAQKRGSKDIFVNILTDTGLVQRFVTDWAGPRAVLTSIKLRLGVPWYAYDTLTLSGTVTSYDEDLVSLAVVGKNSLGDHITAQVTLAFPASGSNGDIENGDIE
->tr|A0A838UPM3|A0A838UPM3_9CHLR AAA family ATPase OS=Ktedonobacterales bacterium OX=2306968 GN=H0X24_05985 PE=4 SV=1
-MPGRTPTAKPMPGQTSDPLPGVQHRGGMCSLGKSSRFAMIPGGLCAIRCRDHEGKRRIEKISHAFSVPPLSMAKREGASAQGRSLCARAFPIWVHCQNFTSEPSQTTLLITQSATLAKELLHSNLDEAAARLAATWLKDGARFPTMVREYREEFEQGAFDFLAFFFHEIILSEKYRPLFQAANGLELLKTQQHMAHDVTAIRGMLELLINHQVPSREEERLGHLMTYLARGNNATSEEQTTAPHHLWKLRTPRQFVGRDADVHWLTQRLSTPPPGDRISGVRGIGGIGKTALVGHVVTRLQQGGAFPAGIVVVNCSELHDVRDIWAEVAQSFGCQVDSPLGGEQLAHLMHETLRERDALVVLDDVQGEVRFTELVQPFAGTTPQIVVTSRLAFGAFPPEALWEVRELSSDHAVDLFRQCYGQPVDADEAALLPQLVAALYHHTLAVRLAGCYAAECQRDLGELLAELRADPLALPAEDQNRMVALILEKSLQNIERIHPLCRQIFTGLAAFGTPEFSREAAVALATYLDHQAPGFAIDRLIRYGLLEAASPHAGSVKVHQSRLHLHPLLYTLALQHFTQADGAQQQPLYSTICRY
->tr|A0A1H9KCN1|A0A1H9KCN1_9BACT Uncharacterized protein OS=Lewinella agarilytica OX=478744 GN=SAMN05444359_12049 PE=4 SV=1
-MVAQTQQGRYELTPYAPHAYVFTTERGNTYIVRFIRYWQEEVVELYIKKELEVFEIYFEVMEIKDKGYDRRIQFTIIGAIVDFLAENDRVGFFDIKREDGRGLELLRVYRIWLKMYERNRKEKSIMLNRIVSIPDQFDSHIACLVHPNNKSFKGQNVDQLMDSVLKEIFPRATLTPF
->tr|A0A7J9HNJ9|A0A7J9HNJ9_9ROSI RIX1 domain-containing protein OS=Gossypium harknessii OX=34285 GN=Gohar_003306 PE=3 SV=1
-MARFDQLENMYDLGLKPVMLRSLIRQYLPAENHPLNLNNSCFELPSLVSIVQTHCLLSELDSQSIDPKLINTWKSAVDDWLSCLLSLLSSDMSDKCWVGICLLGVTCQECSNQRFLSSYSIWLNKLLSHIQPPADSQLVKIASCTSLADLLTRLARFPEVKKDGNLLAGKLVQPVLKLLNEDNVEAVWEGAANLLYALIAFFPASIHHYYDKVQLMVAGTGRSFFGGWGVKVLEKEDIGVMAYFLGCLNVEAAIASKILSGKYSTKTLKKLGYFLALLPKAKGDKDSWSLMMQKFLISINDHLNEAFQGVEEEAKSDEARRLLVPPGKDLPLPLGGASFKGTSSERLPTATISTLMFCCCKMLTSSYPVQVTVPVRSILALVERLLRVDGSLPHTMLPFMTSVQQELICSELPVLHAYSLELLIAIIKGMRRQLLPHSAYIVRVVTRYFKRCSLPELRIKLYSIIRMLLVSMGVGIAIYLAPDVIENASNDLNSLGGEDIETSPANTDPATGALPQLSNRKRKHGAKTGSLEEKQDAASPKVGESNTHQMTPITVKMAALDTLEVLLTVGAASKSESWRSSIDSLLMKTAINSCKRGWGNLESNIFLPHESASVWADFQFSSLRALLTSFLAPARTRPPYLSQGLELFRRGKQEAGMKLAQFCAYALFALEVLIHPRALPLDDFYSACHNSTDGASNRFLENIYSGSQKQNTSFLSAMRRTEQGGVESHDDDLYDRWLQNENENQNENENIPVEDMKDQTSRPNDPSFTNVLEVREQEPAAANADVHMRTENEIVMQPWHLEESVPKSQGVASAKAVMSPPVGTNPEGSEIESKTPLSASDRLNDTNHDMFSCVDKVDGFDHVAGKTSSTLPNAEKGSSSMVHLDSDSSMDSFPGIVDADPDTDADSD
->tr|A0A239QJE5|A0A239QJE5_9FIRM Redox-sensing transcriptional repressor Rex OS=Clostridiales bacterium OX=1898207 GN=rex PE=3 SV=1
-MRSSTLSKATMGRLPLYLQFIRTVQTENVSSATVARALGLGEVQVRKDLASICPAGMPKIGYPTERLREDLEAVLGMKQTIPAVVVGAGKLGRALMAYDGFREYGLEIAAAFDTRVTDSSHERKPILPMEEMTGWCREHEVHIGILTVPAGAAQEAADQMVNSGITAILSFVSVPIRVPDTVTVKHENIALSLACLKIVAGMSNETTEEDSHGSEDL
->tr|A0A1R4IEU8|A0A1R4IEU8_9ACTN Potassium channel protein OS=Luteococcus japonicus LSP_Lj1 OX=1255658 GN=FM114_01400 PE=4 SV=1
-MVPGNGTNDDTLLTAGITRAAGFVTAIDDDADNVHATISARALNPELFIVSRASTKAVMHKLEPAGADRAISPYVMAGRRAVQLATRPGAVTCPSAWRRSESMRSWMASPWPTCVVAGWQPWPSATTTATTRPTRPSTVCCAWGRR
->tr|A0A1D7XM32|A0A1D7XM32_9CLOT MBL fold metallo-hydrolase OS=Clostridium taeniosporum OX=394958 GN=BGI42_10650 PE=4 SV=1
-MDLRITTLIENNPDKDNLLLSEHGLSLYLEIDKIKVLFDTGKSGDFIKNAEKLKINLNDLDYVILSHGHYDHSGGFKSLVENTNKSFDLIVGNGFFNKKYKLLEEDKYKFNGNSFDEKFIDKNNISIRYVNNDLFKITKDIIFFSNFEKNTDFEMINKKFYIKKDNQYVKDDFLDEIVLAVKHEKGLIVVLGCSHIGVVNILKTIIKRTNMPIYAVIGGSHLIEADELRLNNTIEFFKENNIKLLALSHCTGENAIKKFQYEFGNNFIYNNTGNVIEII
->tr|A0A0P1BF93|A0A0P1BF93_9BASI Zn(2)-C6 fungal-type domain-containing protein OS=Ceraceosorus bombacis OX=401625 PE=4 SV=1
-MSHVTSSPIWHEGAFSAEQYRQSAPAVPLQMVPPNAQLRGRMPPSLGHARHFTTPIAAPAQGPTIAHDEARPSDSNGLTPSCSRCRQKKLRCDFQTPCSNCIGKGLQSECHKDVRIPRGRKRPKAESQLTDEEEIVKLRKRLAELEERAGGGRLTPSTSSANSLGGRVSTRSDKPLRHRHHATGPADDRSGGNSSPGSRSHLSSSFVTATRDIIGSQEGLSIHLPLSGSASSDSFRSVPHGSTVPSPHSASVNESVLMKPQTRTRSSKPLILSPLLPAERALRSLETVANPSAARTICGTSERDGLLKRLTGLSDDVPNAYWSDPANAEERIALFVEARAAIPDPIVVEELARTFLYRANHCGGHVVYTPWHKAATELLSIASPEQAVSAPMFQDVSNLGLWFLILSVGYHFHPNNGPTSHTRGFAAVHALRKSGIDPSVRWYGIAKRALAIEKDYVLKSLPALQCASLFLLLGRDDPAWLRMLRAMTIAGARDMGLPRLGSASYAREMTTNDFVRLETAVRVWNFLCVRDWCWSQRDGSYSLHPSQMTTRLPLNLNDADLEAGTTESKSSSNWTEMSFVIAQVGLAHCVREAADLRNANLDDTSRAVVECIDESFRRFLSAGLPHFYSVNSREATPPIMAPQRWMLHQQVFHQLLLVHRNHIASPVGRSTCLSLALGTLELFKQLRMMCPVIEGMYVNSHHLFAAGTLLLLDLFNDNVDDEHRANVRDKVSAAVQYMSPAPRAKQLLSTLLDEEAQYYEATRDRKAYVQRDRTLDLATLCDRVAEVIEQTPGLPRDDVNAIDDVRMPDHHLMPALIGLQSPTSDFNQTKPNLEHHLSQDKVGPNSAFEDPRFFGFDHRQGNTSASPSSRPNTGLMPRRGTVLSPALPSPAELARRAPRILAEGAITLPSIGVDHNLSSNQHNSFNIHPSFRSAVALYHQSRKAHLKNV
->tr|A0A5D8QFW2|A0A5D8QFW2_9THEO Stage 0 sporulation protein A homolog OS=Calorimonas adulescens OX=2606906 GN=spo0A PE=4 SV=1
-MDKKYRIAIVDDNKEFCTILKSYLEKEEDLEIVGTANDGNQGLKIIQEMQPDLVILDIIMPYLDGIGVLEKISSLDLIKFPRLIILSAIGQDTITQKAISMGIDYYIVKPFNMDTLLQRVREVLNIKESRTLKLYETSSSKYKWREEPNLEILVTNVIHEVGIPAHIKGYIYLRDAIIMVIENMDLLGAVTKELYPAIAKKYNTTPSRVERAIRHAIEVAWGRGKIETIDNIFGYTIQKNKGKPTNSEFIAMIADKLRLELKVS
->tr|A0A2W5ZP71|A0A2W5ZP71_9BACT ATP-grasp domain-containing protein OS=Candidatus Dormibacteraeota bacterium OX=2052315 GN=DLM67_22145 PE=4 SV=1
-MTEPAILFVNLRGVPSEDRSALIAARRLGYQVDLIGPSLPAHAAGLVREFRLADTDDPEQGLRAARALAERASPAGVVTWGDRGVELVALIGQELGLRALSPAAGRRARHKVAMKQAVAHLPGIVGSHVGVVERSDLAPALRQVGFPAVLKPAAAAGSAGIFEVRDRDQAEAAFDRLAGWLQGAPRPFRGDGQGELILEELIEGPEFSLEGWVHEGGVTIAGVTDKWTTDGFHLEYQHVHPSGRLDSEQSVLRKGAELVVRTLGLDHCAFHLECKLTPRGFRLIEVAGRTGGDYIGSHLVPLSTGLDFHGNCIRVACGFPPRMEPVDSLCAGVRFLLARNEGIFLGLDGLAEVLQMGDVEQVFIEVPVGSALRLPPDDYDLQRVAAVVARGPEHSAVIETLDRAARCCAPRVERWDGHR
->tr|Q1Q6C1|Q1Q6C1_KUEST Uncharacterized protein OS=Kuenenia stuttgartiensis OX=174633 GN=kuste2370 PE=4 SV=1
-MDLNEKIKEDLKSSMKAQDKMRTSVLRMMLADIKIAETSGKPRDQIDYAAVVQGYQKKLKKTREEYERLSLPEKTREIDNELAIVEEYLPKQLSDEDVQKIVDEVVDENKFTGKEFGVAMKLIMNKCGGTADGKKVLTILKQKLGC
->tr|A0A3A9BJV2|A0A3A9BJV2_9BACT DNA primase OS=bacterium D16-54 OX=2320104 GN=D7X87_23470 PE=4 SV=1
-MNVFEAVRENGITARQAAEHCGIKINRNGMAVCPFHKDKNPSMKIDRRYYCFGCGEKGDAIDFVAKFYGLGKKDAAVQIAAAFGISFDDNGGRKPPPIRKRKLSPEQRFERVEKKCFRVLSNYLCRLREWQEQYAPHKAEEEWHPLFCEALEKKDYIEYLLDVLLYAPLSERVELVTDYGEEVLKIERRLEQCTEGTAGGTGKNYEQDGAGGTAGNMV
->tr|M3NA57|M3NA57_HELPX Uncharacterized protein OS=Helicobacter pylori GAM244Ai OX=1159035 GN=HMPREF1407_01122 PE=4 SV=1
-MKIIKNGIMIGTLGALLLSGCSSFDAQRFACLPKDHSSKDASTKKEAQYIPKGFFDPYSSNLNHWDSTF
->tr|A0A0B8PB49|A0A0B8PB49_9VIBR Putative ammonia monooxygenase OS=Vibrio ishigakensis OX=1481914 GN=JCM19232_3271 PE=4 SV=1
-MKPALNSVSTLAIAFATSALFVLLSVPLGEMFGSIIAIILLSKWGIKTKVPTHTLIFVQLALGLSVGGLIPPSFFATGFPLTMLIGLVVCMSLQVLCGYWLLQRFSWSKSDSLLASIPGAMAAVMVLNESQKTPSARSSSYIPFD
->tr|A0A1A8U716|A0A1A8U716_NOTFU ATPase, Ca++ transporting, plasma membrane 1b (Fragment) OS=Nothobranchius furzeri OX=105023 GN=ATP2B1B PE=4 SV=1
-VYFAGQLYKKVPEPDLIPAKILDLLTLGIGVNCAYTTKIMPPERDGGLSRQVGNKTECALLGFSLDLHRDYQAIRNEIPEEKLFKVYTFNSVRKSMSTVLKNSDGSYRMFSKGASEILLKKC
->tr|C3DIS9|C3DIS9_BACTS Oxidoreductase, aldo/keto reductase OS=Bacillus thuringiensis serovar sotto str. T04001 OX=527026 GN=bthur0004_18590 PE=4 SV=1
-MKYTKLQKAGLNISKLGLGTNAVGGHNLYADVNEEEGKQLVEEAIQQGITFFDTADSYGVGRSEEMVGEVLKGKRHKLILATKGGIQPLLNGETYINNEPSYLRNAVENSLRRLQTDYIDLYYLHFTNSETSYIDSIGELTRLKEEGKIRSIGISNVNIEQLKEANQHGHIDVVQSPYNMLERTAEEELLPYCIEAGISFIPYGPLAFGILGGKYTEDFKLNEVDWRQNVNLFEENTYKSNFKKVEKLKGLAKENDIEVSHLALAWLLNKEGIDTVIPGGKRAEQIRESVKAVDVALNKRVMKEIQSILED
->tr|A0A659QZ73|A0A659QZ73_SALET MFS transporter (Fragment) OS=Salmonella enterica subsp. enterica serovar Wilhelmsburg OX=1960126 GN=C9F09_13540 PE=4 SV=1
-SDWPLNRGNSLSVARILPVICGMLLSCVIVIANYTSSEFVVIAAMSLAFFAKGFGNLGWCVLSDTSPKEVLGIAGGVFNMCGNMASIVTPLVIGVILANTQSFDFAILYVGSMGLIGLISYLFIVGPLDRITLTSSAA
->tr|G8G1N4|G8G1N4_9HELO NADH-ubiquinone oxidoreductase chain 4 (Fragment) OS=Phialocephala helvetica OX=242229 GN=nad4 PE=4 SV=1
-MLLTLLLLTPILGIFAISTGISYELS
->tr|A0A4Q2K9X0|A0A4Q2K9X0_9FIRM Uncharacterized protein OS=Candidatus Borkfalkia ceftriaxoniphila OX=2508949 GN=ESZ91_10490 PE=4 SV=1
-MIDFEALKRFIEAKRTPPRKVLRAAFKIDAECEPRALCGAAETDENALRERIGKRGKTFSEMLFYWIDARGEKDSDVYKRAGVDRKLFSKIRSDANYTPKKRTAILFAFALSLNEDQARDLLARAGYSLSDADTTDIIVQYFLQTDNHDLSELDEALVRFGEQPVYSE
->tr|A0A841U1R9|A0A841U1R9_9BACL Aldehyde dehydrogenase family protein OS=Cohnella xylanilytica OX=557555 GN=H7B90_11630 PE=4 SV=1
-MNGTATIDNYIGGWRPPASGRRVPSLNPARRSETVGLVPDSDRTDLDAAVAAAEAARRSWRKLAGSQRGALLFKAADLLESRMDEIGRAMTREMGKTIGEAKGETARGAAILRYYAGEGMRPIGDVIPSTDAEALMYTTRVPLGVVGVISPWNFPVAIPLWKIAPALIYGNTVVWKPAIETAVTAALVMECFHDAGFPAGTVNMVVGDGAAIGQGIAEHPGIHGVTFTGSNAVGKRVGQIALARGAKYQLEMGGKNPIVVAADADLDLAVDATISGGLRSTGQKCTATSRVIVVREVYETFKEKLLAKIKTLTVGDGLDAETWLGPCASEKQYETVIGYIRKGREEGAELLVGGERPSHPSLADGFFVTPAVFDRVTTGMTIAREEIFGPVLALMEAGDLKEAIELANDTEFGLSASLYTRDLANALAFAQEMEAGLIRINAETAGVELQAPFGGMKGSSSHSREQGQAAIEFYTAVKTVFVKP
->tr|S3MU72|S3MU72_9GAMM Pyridoxal phosphate homeostasis protein OS=Acinetobacter rudis CIP 110305 OX=421052 GN=F945_02860 PE=3 SV=1
-MNELHRARREVLEHIQKACEQANRSADEVQLLAVSKTHPSQAIEQLYQSGQRAFGENYLQEALDKIEALKALEIEWHFIGHVQRNKTKHLAEKFAWVHGVDRLIIAQRLSQQRPAGLAALNICLQVNIDQQDSKDGCAVADVVDLVREISALPNLRLRGIMVIPAPHNHQAFNAAAELFQQVKTEHVHAQDWDTLSMGMSADLQAAITAGSTMVRIGTALFGQRSYDLS
->tr|A0A7I7TGD8|A0A7I7TGD8_9MYCO Uncharacterized protein OS=Mycolicibacterium helvum OX=1534349 GN=MHEL_56620 PE=4 SV=1
-MAHSIELLIDQRADTAVRQMWHALADGGLPSRHRVPSGTRRPHITLVAAERIAPGIDRVLGGLAEELPLPVVLGAPLVFGTDRLTLARLVVGSAALLALHDEVYGLCRPFAFNVFAHSAPGRWTPHITLGRRFTPAQVGEALAAVDGIAADIRASIVGLRRWDGDAKREYLMVN
->tr|A0A4V2FIN5|A0A4V2FIN5_9HYPH Ribulose-bisphosphate carboxylase large chain OS=Rhizobium sp. BK696 OX=2512157 GN=EV569_4023 PE=4 SV=1
-MAQRFTVTYFIRGADAAEAKARALDIALEQTVEIPRAAVPKGYVEDVILGRLEGLEQVRDGRSGFLATISYSEDDVGGDFLQFLNIVFGNSSIKPGLKVEDIGLSSGILDLCRGPRHGIAGLRARAGIGQTPLLMSAIKPVGLSTKELASLAHDFAIGGVHFVKDDHGLVDQRTSPFSERLRACVAAVGEANAKTGGRTSFVPNITGPATAIVERAKEAQEAGAGGVMIAPALAGYDIIRTLAADQDFTLPVVSHPAFSGANVVSPDCGFTHRTFFGTLHRLMGADAVIYPNFGGRFGFSREECLSISAACAAEMGGLNTIAPAPGGGMTLDRVAEMRAAYGNDIMYLVGGALLVDPGGVIAACQRLVSKIYD
->tr|B4DA31|B4DA31_9BACT Uncharacterized protein OS=Chthoniobacter flavus Ellin428 OX=497964 GN=CfE428DRAFT_5771 PE=4 SV=1
-MADDSSRYERKDFSPKAVGLSGLGLIVVCVISAVLIRHFEKDLNQFFAYQGRATWTSSPTMQPPEPRLQTNSAREFAEMRAQEEAELHSYGWVDRQYGVIHIPIDAAIKIALERGLPVRKSTPTAAATPVPAPATPTPAPKSAQ
->tr|B1ZML6|B1ZML6_OPITP Stress responsive alpha-beta barrel domain protein OS=Opitutus terrae (strain DSM 11246 / JCM 15787 / PB90-1) OX=452637 GN=Oter_1073 PE=4 SV=1
-MSLTSRRQFLATSALATAAAVSPSHAAGTSAMPKLVHHVFFWLKNPSSKEDLATLLAGIRSLGAIETIRSIHVGVPASTEKRDVVEASYSASELLLFDDVEGQNAYQAHPVHQKFVQDCSGLWSKVVVYDSVSVDVPAGSKP
->tr|A0A4Q1QFK1|A0A4Q1QFK1_9GAMM ATP-dependent zinc protease OS=Idiomarina sp. 29L OX=2508877 GN=EST55_04790 PE=4 SV=1
-MTTIGWREWGHLPELGISNIHMKVDTGAKTSCLHAFQLEPFMKKGEEWLRIFVHPKQDSQEEHVCEAKVHDKRDVTDSGGHTETRYVIKTRLVLGSFDQKVELTLTNRDTMKFRMLLGRQAMRGHFLVNPDASHLLGDVK
->tr|T2C928|T2C928_9BETA U7 OS=Human betaherpesvirus 7 OX=10372 GN=U7 PE=4 SV=1
-MKNFETMAEQYKTLPCVGQLNDGLLRELKNLCRFTDFPGIRLLTERHRNECLSLIWPKNLWLRLAQPVDVAGYSEQQLAELNDHYQGFKENLCLIGAIQIGRKDVPIFVGKSSRIFCHDLEDDVLYYIAEDFDKFVRFGILGTNVITCSEPVYTRFYYDGPKFEKLETLKDLGLLQEPLNLNSSLRFNRKTALALKALRRNYISMLSELDELARCKTLAEIEHFVSINTGLKLRLETPIFTALILQDRKNIHCSTSDQKRFEEQEALFEKVVVLGFLNISAEDYGLRPILCIGETGAIYYYDWIDKVLTRIADCLLTFARIGFARYCGDFGYDKIGKVTARFGRLSTLGSAPVQQYSWYLKIVPVCNDVCIEPTPDLPSFDFAVELLLSSYGEGMEIVRNGIKCCLAWPPNYVLIFGEFYHFKCRRSVITYDWSNLVGADEFLCAVGYAHPNYREPDPDFDPFVMYCSSNKMLALDTVTDELYIIAESPAHFCSIGLRNFPPFARIELDIELDRLWYGETKCSGEEFVLLQKNIPALKNFVNRQCGQKIRIDAFQNFDLSFCSSNDIHYITGSGILEKILRRKYVVIGTCARCQVEPNCRAVILLGPNFHIYVYCDNKINKVARSIREFIRRGFEELLYKERYALNWHDDSLIYVSESEAENLNRMLNGESPILRKKPRHMYPRCDRLLKNMPSILFAVHSSEISNPLVQSVTKFLHPIIIPNGDTELKYIVPVTESRLINGLQASAAGRFGIKGLRLCSDGVIWNRLIDYEYEMFKYPSTFTRADKFLLQLRDLKFMEDFDPKWQCITKLAAVGFYSGASLFNLGAKPGIGYWCRYLCEYLSMLFFKLDGKLKELSKESKQKLGGFSCAFWSESFKTEMQNKTESFFRRDFFDRFQLYLLEHFLLFCGCEECRYNFFRFKNVGTMKKNPGSVKLHFFPALGKIDLPIFPHLSEKYSNLSMFVAKDLCLSFIEGQIEHSRFPISVTVDMGQDKRNLLNILSNIVFLLFIIQTLNSVLFTELKMYYDVYLDELKNLESSMECEMKLGSKGCMNNIVYFNMLKQVKDIVRNPGTSSNFIFNCLEVIKMSFEIPYYKNYDETNFMESFYLHHLYIQRQPAKHTDLVAANNLAPGFFIVNAKEKSFIDVLERSIVNIEAEYLSNTKNINGAMALFFSGLKYFGNFGNGNFQTSPEKDVRAVGYKLGGLDKIQNDLCYFANVETLACVGVDASDGNE
->tr|A0A5C4V3X6|A0A5C4V3X6_9ACTN Pyruvate dehydrogenase (Acetyl-transferring) E1 component subunit alpha OS=Streptomyces sedi OX=555059 GN=pdhA PE=4 SV=1
-MGRTQARTAAGKSTAGKTTAGKSTSGKAKPTARKSAAGNATANGAANGKPPAKKATTRKPAASGTAAKPAARKPAAKKPAAGKSPARGTAARTKPADGPEMVQLLTPEGERVEHPDYPLTVSHEELRGLYRDMVLSRRFDAEATALQRQGELGLWPSMLGQEAAQIGSGRALRADDYVFPTYREHGVAWCRGVDPTQLLGMFRGVNHGGWDPNSNNFHLYTIVIGSQTLHAAGYAMGVAKDGGDAAVMAYFGDGASSQGDVAEAFTFAAVYQAPVVFFCQNNQWAISEPTERQTRVPLYQRAQGYGFPGLRVDGNDVLAVLATTRAAAEQTRSGQGPVLIEAFTYRMGAHTTSDDPTRYRRQEELESWEARDPILRLRRHLDREGAADEAFHSELEAESETLARRVREAIRTMPDPDPIAMFDHIYADGHTLVDEERAEFAGYLASFADHEGN
->tr|A0A5B2V3L5|A0A5B2V3L5_9PSED Chaperone SurA OS=Pseudomonas brenneri OX=129817 GN=surA PE=3 SV=1
-MNVKIKLSDCLRPLMLGALFLGTAAAHAAVQPLDKVVAIVDNDVIMQSQLDQRVKEVQQTIAKRGGGVPPTSVLDQQVLERLIVENLQLQIGDRSGIRITDEELNQAVGTIAQRNNMSIDQFRAALARDGLSYEDARDQIRREMIISRVRQRRVAERVQVSEQEVKNFLASDLGKMQLSEELRLANILIPTPDSANAEQLNAAAAKTQAIYDRLKAGADFAQMAIAQSGSDNALEGGDMGWRKAAQLPPPFDRELSAMEVGGITQPARTPGGFIILKLLERRGGEASLKDEVHVRHILVKPSEIRTEAQTKELAQKIYERIEGGEDFATLAKSFSEDPGSALNGGDLNWIDPRALVPEFQQVMNDTPQGVLSKPFKTQYGWHVLEVLGRRATDNTTQAREQQALTVLRNRKYDEELQTWLRQIRDEAYVENKLPGAEPTGTDQAAQ
->tr|A0A1D1ZL49|A0A1D1ZL49_9ARAE 60S ribosomal protein L35a-4 (Fragment) OS=Anthurium amnicola OX=1678845 GN=RPL35AD PE=3 SV=1
-FLFSYTHPHISYKMGKAVRLYAKGRVLGYKRSKVNQSPNTTLVKIEGVTAKEETQFYLGKHIAYVYRAKREKAGSKIRIIWGRIARPHGNGGVVKARFRKNLPPKTFGASVRIMMYPSRI
->tr|X0K267|X0K267_FUSC4 Uncharacterized protein OS=Fusarium odoratissimum NRRL 54006 OX=1089451 GN=FOIG_02629 PE=4 SV=1
-MTALAQVALLRLGASRAMISLFDCQHQHIIAEATPALRISAHANPPSSGSDSLWLCGTAIPRSYGICDRVLVYPEFGGPQQASLASELPVTVISNLAENEEYRNTWYYKARPEHRFYAGVPIRTRRGINIGVFCILDNEPRETLDEASLQVMRDVSASILGQMELTRSGDGRRPGERMVRGLGSYVEGKTTISGWQNSSTHAFNTDASTEEGSLNQTQQKIQNQRDNAAAAADTESISTPDTFVLESPSQNRPTSPFHPTDKTPHSVPTGEESRSQQLNQIFSKAANILRESIEVEGVLFLDAGIGSFAGRIRSGSLRRNSRTHDRSSSSSSSSSSPGKGNISVSSPRNSADSRSSGAMCPILGFSTSVSSSINGEAPAGRSRTIPERQLQMLLRRYPKGKIFNFDGYGVMASSDPASEDSAMAVFQAQKARSIQEGQRGDNQKSRKVNDPYSRKNEGMAIRDVFPGARSVAFVPLWDSHRERWFSGCFVYTMTPTRIFTVQGELSYLAAFSAVIMADVAMMESSIVSLATTSLLSSLSHELRSPLHGIVLCAELLRDTALDVFQGDVLRSLEVCGRTLLDTINHLLDWTRINNFVKAPSGQSPNSGIAFVRGAQSNQRSGPTDGMMHITSNLDLDMLVEEVVECIYAGHTYQQQSLSLVHDDKPNEELNRDPFTRLDGMDVADSIKAGEKISNGAGPDAVLVMLDIDPAVNWAFHVESGALRRIIMNLCGNALKYTTRGYVKVSAYQDTPGQSRLRDRVVHIDITDTGAGIGQDYLNHRLFAPFAQENIHSSGAGLGLSLVRKFVRALGGSIHVQSKVGTGTRIAVKLPLEAVSVDSTETISDREEFQSQAIELSGLRVCINGFTPFGGGGSESQRWNSREFDERALLQKVCHDWLRMHVVDSLHNAEYLPDLILCDESHLETIANQPRDELSSPVVVVCRSAAVARSLDRSHRSQRKLNWGLFSFISRPVGPRKLAKAFVLCFRRWTKLQATAADRASVSTRLDEPPTVSTAETDLVQHGSDDKNRGYFDIAPTLSPKKRRAHWNDDGTRTPLPSMPALQLPTIPRDQRFLLVEDNAINMKILQTYMKKMGVEYDSASDGLQALECYKAQEGCYKCILMDISMPVMDGFEATRQIRGFEKASDLPRRHIVAISGLASKDAQEDAFANGLDLFLSKPVQLKELSRILKSRGLI
->tr|A0A813QIU7|A0A813QIU7_9BILA Hypothetical protein OS=Adineta steineri OX=433720 GN=IZO911_LOCUS5098 PE=4 SV=1
-MCGIKRCCRNCCPNGCCGFCKPPKQVQQQVDTLIHLKEAVTASETRYGFIKFYPGVRTVDNNYTCPMFAIHLYRQGKLNANMAQDNRTVTYAGRNHQQTHQGEKQFISTQNASAEEEVIMVPLEDVIHISYKADVKIGMQADIKSHVTPVHERSENCCDRCCAPIVNCCRKTRDCCCCHSRQEENKVAPFVQNTTTIINANSNRNEDYVEQDLPLPKVKESCWSKCCNPCRCWCCRKKRLVRLIKRTNTKAARQAERVITMTIQYSKYSNLDTASHTRLLSNQHQLEYFKAKFQPDAELEFYLINDTEFEPMNFDVKKNEAEVLCRTVMQLKGMKNRYPSADELDKILDQPQQRIFGTIFHEPILQLPSNAEIQRVT
->tr|I2FGU6|I2FGU6_9ANNE Cytochrome c oxidase subunit 1 (Fragment) OS=Megascolecidae sp. Esik120 OX=942496 GN=COI PE=3 SV=1
-TLYFILGIWAGMIGAGMSLLIRIELSQPGSFLGSDQLYNTIVTAHAFLMIFFLVMPVFIGGFGNWLLPLMLGTPDMAFPRLNNMSFWLLPPSLILLVSSAAVEKGAGTGWTVYPPLASNIAHAGPSVDLAIFSLHLAGASSILGAINFITTVINMRWSGLRLERIPLFVWAVVITVVLLLLSLPVLAGAITMLLTDRNLNTSFFDPAGGGDPILYQHLF
->tr|A0A2I7QPQ3|A0A2I7QPQ3_9CAUD Coil containing protein OS=Vibrio phage 1.034.O._10N.261.46.B7 OX=1881189 GN=NVP1034O_23 PE=4 SV=1
-MATVAAIAGVIGAVTGVVGAVQQRKAAKKATAEQKRQNALNNRVQEVNQRRDIRRSIAASRAQQAQLEQGGIDFGVQGSSIVAGAQGAAQTDLATSIGSGFANQGASAGFAASRNRQADAMLDVQNNIYTDVSNFAGNFTHAGVNEVYKSELTGLFS
->tr|A0A537DGT1|A0A537DGT1_9PROT Thiamine pyrophosphate-binding protein OS=Betaproteobacteria bacterium OX=1891241 GN=E6H40_11730 PE=3 SV=1
-MENERPLASPKQNEIWGSDAIAALLRELDIPYIALNPGASFRGLHDSLVNYLGNERPQLLLCLHEESAVAIAHGYAKASGRMMGVALHSNVGLMHATMAIFNAWCDRVPMLILGATGPWDAARRRPWIDWIHTSADQGALVRDYTKWDNQPASVPAAWEALLRAAQIANTAPRGPTYVNLDAALQETKIGPLPPLPDVSRYRAPEAVLPKAELIDAAAQLLSAAERPVILAGRFARTGAGWKSRVALAEKLQASVLTDLKAGASFPTDHPLHVAPPATFLHENAREALREADVVLSLDWIDTAGALKQAWGDAPIGAKVILVSPDAHAHRGWSMDYQGLPPADVYLMCEPDAVVPLLLEAVEPRAAAAAEQRAEETTTDKTLSLRALADGFNTATAGLNVCLARLPLGWNGAYRHFKHPFDYLGGDGGGGVGAGPGMIVGAALALNDSGRMVAGILGDGDFLMGVTALWTAAHYRIPCLLIVANNRSFYNDELHQERVAHERGRPVENKWIGQRIDEPDIDLASMAGAQGAFGIGPVTDLAELQPSLARAIELVREGNVCVVDVRVVPGYDSSVSGSPARR
->tr|A0A7L4GLY1|A0A7L4GLY1_PODST SESN3 protein (Fragment) OS=Podargus strigoides OX=8905 GN=Sesn3_1 PE=3 SV=1
-GRLEAVTQQMGYHPQYLDSFLKTQHYLMHMDGPLPFDCRHYIAIMAAARHQCRYLVNLHVLQFLRAGGDPQWLRGLDFIPPKLRNLNEINKILAHRPWLITKEHIEKLLKISEWSWSLAELVHAVVLLAHCHALASFVFGCGCEQDEGLGGRGLLKPLSPGNQCFCEATAGNGCSQELLRISRKRSLDSCMELDSLRERMQRIHVETEGREEMRLLQQDREEGEGQGAEVGHHSDPPAGLSPLADTDGEVTGATNLACYMQDPDFGYQDFARRDEDQTQVFRVQDYSWEDHGFSLVNRLYSDIGHLLDEKFRMVDGLQSSAMAKRQGCEPSVFKRGIWNYIHCMFGIRYDDYDYAEVNQLLERMLKVYIKTVTCYPEKTNPEMFDRFWKQFKHSEKVHVNLLILEARMQAELLYALQAITQYMI
->tr|A0A6A3AK87|A0A6A3AK87_HIBSY C3H1-type domain-containing protein OS=Hibiscus syriacus OX=106335 GN=F3Y22_tig00110462pilonHSYRG00339 PE=4 SV=1
-MYTSRHVVFDELQFPFAKLHEKVSNEYNTHASSSSLQIVAVVHKFQHVLAEGYDNNSMTNNSPATVSSNYFSSNVAATSNSQNEAQEDVVDSSSATQNDATQDDDAHEETVVPQSVNECTPSEGVNSDMPTNTHHMMTRSKCGVFKPKVRKETVQAEFDALLTNNTWTLVKLPEDRTAVGCYDFKDTYNPIIKFSILNIVLSIAVTRKWCIRHVDVNNAFLNGKLAEDVFMQQSPGFEKYAVDESVLVCKLNKALYGLRQAPRNWHDKLKTSLIRLGFTESKADVSLFVRIDADCRIYILVYVDDIIITGDSSPSIDSIVHALSRDFSLKDLRSLAYFLGIKVKRTEEAMLLSQRKYIIELLEKICLLNATPTVTPMIGASKMTQEVGALLSDAREYRSIVGALLYVCHTRPDIAFSVNKATQFMHAPRELHLAAVKRILKYLASTLNYSLTFSSNDVSQDVVAFTDADWGGSLDDRRSVSGHAVFLGHCLVIWCSKKQKIISRSTMEAEYRIIADAAVEVMWMSSLLCELGVKHRNMPVEWCDNTSTVALSTNPVYHSRSKLVDMDVHFVREKVAANQLQVNYVHASHQVADVNPTESGSSGQLLLDASNFPERPDQPECRYYMNTVTCKYGSDCKYHHPKEMIANSTINGIGPLWLPSRPPSSVFDSSALTYQRMSPTAHLSETPLPSKLTDWTGNTESVSKKHQNTEMKNSDDPAEQAALTHSLQISSKNSQDD
->tr|B6WSE8|B6WSE8_9DELT Tyrosine recombinase XerC OS=Desulfovibrio piger ATCC 29098 OX=411464 GN=xerC PE=3 SV=1
-MGRHIEKDTMEEELDPRTTLEIESFLAWLDVQRGLSPTTQIAYGTDLRQLALFLAQRGASLARPAEVSKKHIQAWLARLYALGEAKSTMARKLAAARTFFRYQQRMGRTENNVAAQVRNPKQEQRHPRVLNVDQAFAVLDTPDALAGTGSPRIPPATGDALAARDHALAELLYGSGLRISEALGLDVTDLRLDESVVRVFGKGARERMSPLSDTSVTALRAWLEQRGTLAPEGEKALFVGARGGRLDRREAMRRIERLCRNAGVEPVSPHALRHSFATHLLDAGADLRSVQELLGHQRLTTTQRYTRVSLERLMHLYDEAHPRAQKK
->tr|A0A6A7M004|A0A6A7M004_9PROT Uncharacterized protein OS=Rhodospirillales bacterium OX=2026786 GN=GEV13_06010 PE=4 SV=1
-MWVNAREVPRFYPNAVTLAHDDASIAEQLSNIEVLQKSNLPGRWAVKDSFQALDLSRRGFDVLQEASWIRSVMPTGSSATDIEWQRETQGKAPWPYDDPNFAMFTGRRGFSVVAGGMLYRAAGVAGLSNVVAEAADAVTVWRSLILLASRTFPRLPVVGYESGGELAAALDAGFEIGDPLKIWVRARD
->tr|A0A2T0N3A0|A0A2T0N3A0_9ACTN Uncharacterized protein OS=Nonomuraea fuscirosea OX=1291556 GN=B0I32_10527 PE=4 SV=1
-MTEKIPVDLWFDPSCPFAWVTSRWLLEVEKVRPIQPRWRQMSLYFLNEEKDVPADYLERAAKAMGSVRVIAAAAAKHGEHVIGQLYTGLGTRLHNQGLSKEPERLREVIEGALDDAGLERSLAEAMHSEEYDATIRASHDEGIGLVGQEVGTPVIRVGDNAFFGPVITRILRGDDAGKLWDGVLAVTQFDDFFELKRTRTRRPQFD
->tr|A0A3A6JJ78|A0A3A6JJ78_9FIRM Uncharacterized protein OS=Coprococcus sp. AF38-1 OX=2302943 GN=DW025_00330 PE=4 SV=1
-MAIRKDGPQKAVMREMMRDYLKNNDISIKDGTDVNSIMCDMMFVILEGALDEKLGYSKMTVELFTSFRV
->tr|A0A4R1JNC6|A0A4R1JNC6_9GAMM Ribosomal protein S18 acetylase RimI-like enzyme OS=Celerinatantimonas diazotrophica OX=412034 GN=EV690_2119 PE=4 SV=1
-MIQYRPMQINDYDSVMALWLQTEEMLLREADSQTNIAHYLARNHNLSFVAENENHEIIGAILVGTDGRRGYIQHLSVALECRSQGIGRDLIAKAVKALKEIGIAKTHLFVNIANENAKKFYQRLGWQVREEVRMYSFNSSEDTQI
->tr|A0A7S6MMK8|A0A7S6MMK8_9GAMM Flagellar assembly protein FliH OS=Gammaproteobacteria bacterium OX=1913989 GN=HRU78_01625 PE=4 SV=1
-MIASNFVPKEKLTAYQRWEMDSFEAPELSQEAQEAGKESNDQSDSQPQVSLPTEEEIAAVLRSAKEQGYAAGLQEGHTAGHAAGYAEGRALAESEVKAEVARMQTLLTKLDQDLQQMDQQVAASLLELAIALTKKMVTEALKLQPELIVPIVQEAIRNLPNATQHPRLFLHPEDAKLVLAHLHEQLEQDHWSIREDEQLIRGGCRIEAGGSEINGSLEVRWQRVLSTLGQTDEWLNKAD
->tr|A0A852D8G1|A0A852D8G1_PASAF PDIP3 protein (Fragment) OS=Passerina amoena OX=142471 GN=Poldip3 PE=4 SV=1
-QLAFSPLEGTKMTVNNLHPRVTEEDIVELFCVCGALKRARLVHPGVAEVVFVKKEDAITAYKKYNNRCLDGQPMKCNLHMNGNVITSDQPILLRLSDTPSVKKEGEPRRSSASASSNPPAEVDPETILKALFKSSGVSASVQPTEFKIKL
->tr|A0A2T7IVZ0|A0A2T7IVZ0_THEOR Uncharacterized protein OS=Theileria orientalis OX=68886 GN=MACK_00001413 PE=3 SV=1
-MDGKNPYEFESLVSLMRMNFASIVEKVKGMKVLILDSETSKIISLVYTHSYLLENEVLLTLNIDDGTIFNPDPNVTVDSNLKYLKGIYIVSPNXESLNXISSELKNPHFKEYYVYFTNKVKEDLLELMAKSDTLEIVKGVYEYFVDFYVLDECLFTLNIANLQSLYKDDVNMMLDFSVSKMVNSLFSVCCMLNQIPTVVYRRNNPILQTIANKLQADFNNNNLNLQSIIQSYNNYNSKNPTADHSGCVLLILDRREDCITPLMNQWTYRAMIHEMLKINNNKVMXEDTEYILGNNDDFYGKHLFDEFADVESDLNVLINENKPANSDIYKILESLPEQSKTLNDTTRHVKVLHELSKHIQKNKLLDSGILEQDIATNRRNVINELAEFLNDKTAPTYEKLRVALIFCLKNPGDTNKVNRVKDYLKMNRLDQHVGLVDLCLKLAKFRPVSKTNQDFTLSSLKDKFNKVSLESQSPYLQYKSQLHSTCYNLIKGKLDVELYATMPSAYDLGYTLKHKPASVSIKFFYSSRRTVGDVTYDRPHQITDEMPKVSELDVYKEVLSGEKRKSIRRSDFLKFTGGKRPLISSHLHANLIASGLVVWAVVAFFLTFKVMKPESYEWVENERRRIEAAKQKIALIKKDQENKALAQ
->tr|Q3JRW6|Q3JRW6_BURP1 Putative membrane protein OS=Burkholderia pseudomallei (strain 1710b) OX=320372 GN=BURPS1710b_2292 PE=3 SV=1
-MSTLTSPPLSVAAPSMRGRLNGVLFVGLFALAVTSVAQLPAVAHLGLSPLIVGIVAGALYGNLLREGMPASWAAGVDFSARKLLRIAVAFFGLRVSLQEIAQVGVPGLAVSALVVASTLAVGTWAGIKLMKLDRDTALLTAAGSAICGAAAVLAFESALRSKPHQSAMAVGSVVLFGTLSMFAYPLAYRAGWLHLDATGLGLFFGGTIHEVAQVVGAASDVGPEVARVATIVKMTRVMLLVPVLLVLGAWLARSARRSTAAGRGAPRKLAVPWFALGFLGFVIVNSLQMLPAAAIGTLNALDTFALTMAMTALGIETRMSQIRAAGPRALMTGLILYAWLVFGGYAIVWATQRWLG
->tr|A0A661D2Y2|A0A661D2Y2_9GAMM Uncharacterized protein (Fragment) OS=Gammaproteobacteria bacterium OX=1913989 GN=DRQ40_10815 PE=4 SV=1
-QDTDPEPEPEPEPEPEPEPEPEPEPEPEPEPENTDDSDELEPVPSNKLSDYLTKSLGGSISDKDNNSVDEVEVDPQTKIESDAGVESELGSEQDQLLSMVADIEAEEADPPIVEDAAESSDEQNQPEDTKSVYGSEIEALSAKVKARTSELKAEAEKAQIRLDSNLEVKTSFDVELQLDKGSELEPNLENDSNLSATDIDLVNDEDFNLEQPEEQPEEQPEEQPEEQPEEQPEEPLPSEEQLDSMLSEVRALEQDKTLKNEKAEEPVVAKSTQDELQAILSSIPSFSDMNKK
->tr|A0A6N6VZN6|A0A6N6VZN6_9BURK Magnesium transporter OS=Paraburkholderia madseniana OX=2599607 GN=FSO04_44420 PE=3 SV=1
-MATELLSAQNTDHFPLDRGYLFSGNGVGREIDANTAIEWLKHRDDDSTEFIWLYFHDIPTVPEGWPLQHVQVPEAFGDTLKEGSRSTRITHVYQTLIAVLNDVEYDLERKTSLKVATLWVNVGVHYLISVRNSPLRSVNQLRLAVEAVETFRSPMALLIHLLQEQADVLIGIVRTAAQAANDVDETLLAGRLPTRSGLGGIRRDLVRLRRLLAPEPAALFRLVSRPPHWVLEEDAQSLRQSAEAFSLTLRDMAGLQERIKLLEEEIADRVAEHTNRSVLILTAVAVIALPVNLISGLLGMNIGGLPFKYQPFQGLDQDVPPLARLSRRAVL
->tr|A0A063XZJ1|A0A063XZJ1_9GAMM Biotin synthesis protein BioH OS=Nitrincola lacisaponensis OX=267850 GN=ADINL_1947 PE=4 SV=1
-MLSIESLAGQGADLVLVSGWGSDSGIFDPLLPLLSPYFRVHRVLWQTSGWPADDGQLRYQLLNCLRRQAPSRAIWVGWSLGANLALTLADSFPEKVSRLVTLAFNPCFVQRDDWSCAMPQTEFLHFQQNFLTAPAATLKRFQALQVMGSVDRRQVIAALQSSPAHLPPARLSQLLQLLADDLRPQLKRLSQPQLHCLGAQDTLVPCASLLAAYPHLNPQVELRCYAQSAHLPFLSEASRWCEDLRQWCQA
->tr|A0A7V9MZW3|A0A7V9MZW3_9PROT Pentapeptide repeat-containing protein OS=Alphaproteobacteria bacterium OX=1913988 GN=H0U98_14635 PE=4 SV=1
-MMLPLPAMAADPAAVAKIHGGIVDCVGCNLAGADLSNTCVKDHDLHGADFTGADATLMCMSFANFTGVSFRGAELSGANLAGAKMDGADLTGAGTSITSFLGTDLTKVKGLTQKQLDIACGDATTRLPPGLNIHTCE
->tr|A0A3A5H6E9|A0A3A5H6E9_9ACTN Recombination protein RecR OS=Nocardioides sp. K1W22B-1 OX=2321396 GN=recR PE=3 SV=1
-MYEGIVQDLIDELGRLPGVGPKSAQRIAFHLLQADPADVRRLADVLIQVKAKVKFCSICFNVSEEEQCRICRDPRRDPSVICVVEEYKDVAAIERTREFRGRYHVLGGAISPIDGIGPDQLRIRELLIRLADGAVTEVILATDPNLEGEATATFLTRNLKPLGLRVTRLASGLPVGGDLEYADEVTLGRAFAGRRSADD
->tr|E9F284|E9F284_METRA Cytochrome b-c1 complex subunit Rieske, mitochondrial OS=Metarhizium robertsii (strain ARSEF 23 / ATCC MYA-3075) OX=655844 GN=MAA_06282 PE=3 SV=1
-MASLTSASRLCLRSAAKPAMPAVRALSTTAMRSDSAASSYQSPFKMGSDKGSSIPDFGKYMSKKGEGNNKLFSYFMVGTMGALSAAGAKSTVQEFLVNMSASADVLAMAKVEVDLNAIPEGKNVIIKWRGKPVFIRHRTQDEIDQANKVNVASLRDPQTDDERVKQPEWLVMLGVCTHLGCVPIGEAGDFGGWFCPCHGSHYDISGRIRKGPAPLNLEIPEYDFPEEGKLVVG
->tr|A0A2M7QIU8|A0A2M7QIU8_9BACT Restriction endonuclease (Fragment) OS=Candidatus Roizmanbacteria bacterium CG_4_10_14_0_8_um_filter_33_9 OX=1974826 GN=COY87_02155 PE=4 SV=1
-MLFKNDWEKTVYESENKIIDFENKLKNITQFPKGKERDCIVKSRINQN
->tr|B1KM11|B1KM11_SHEWM AAA ATPase central domain protein OS=Shewanella woodyi (strain ATCC 51908 / MS32) OX=392500 GN=Swoo_4641 PE=3 SV=1
-MDNNYINSMEQALSLSPDNFILRITLIQALYEHQQLSTALSLLKEVESCQVEQELHQILAAKIFIESGDGENALLFLSSNLPEVKILKAKAYQILNEFSLAREFYVEAVKENSSLEDIDFARELRVAKDALDNSKRIKLTVVANDDTDAVEVTRLIKPREEVISFSEVGGLADVKKQIRKKIITPFQKPSLFQRFKKKVGGGILLFGPPGCGKTLLARATAGECNATFINVVISDILDMYIGESEKKLHAIFEQARQNTPSVIFFDEIESLAAKRQHTREATSAKLVSQFLSELDGFAQNNHGVLILGATNVPWALDPAFRRPGRFDRVVFIAPPDVDARTDILKGLLKDRPGGESVDAQKIARLTSGFSGADLMNLVETAVDEAIDHSIESGEEVPLNQTFVKEALKEVNPTTLEWLTMARNYAKYANDSGQYNEVLAFLRKHGK
->tr|A0A2T7C6Y6|A0A2T7C6Y6_9POAL Glyco_trans_2-like domain-containing protein OS=Panicum hallii var. hallii OX=1504633 GN=GQ55_9G257400 PE=4 SV=1
-MAPTTVVGSSSQLSPHPNVLLLVPLPLVASRPPTPPPSAGRSYHHGITPTPTHPALSKPNRKKGARSQSCCTRAHPPPHSSLRSVRSKQGTQPARVPMPALAAAAAAWALRAAVWACLAASAMLVAEAAYMGLASLVAAVALWRRPGRRYRWEPMPGGVGGDVEAGPAAAAEFPMVLVQIPMYNEREVYKLSISAACALTWPPDRIIIQVLDDSTDPIIKELVELECLDWASKKINIKYEVRNNRKGYKAGALKKGMEHIYAQQCDFVAIFDADFQPESDFLLKTIPFLVHNPKIALIQTRWEFVNYDVCLMTRIQKMSLDYHFKVEQESGSFVHSFFGFNGTAGVWRVSAINQSGGWKDRTTVEDMDLAVRASLNGWEFLYVGDIRVKSELPSTFQAYRHQQHRWTCGAANLFRKMAWEIITNKEVSIWKKHHLLYSFFFVRRVIAPLVTFLFYCVVIPLSAMVPGVSIPVWGLFYIPTAITCMNAIRNPGSLHLMPFWILFENVMSMHRMRAALSGLLETARANDWVVTEKVGDPAKDDLDVPLLEPVKPTECVERIYIPEILLALCLLICASYDLVLGSHKYYLYIYLQAFAFIVMGFGFVGTRTPCS
->tr|A0A3N5TBJ3|A0A3N5TBJ3_9DELT NlpC/P60 family protein OS=Deltaproteobacteria bacterium OX=2026735 GN=EHM37_16680 PE=3 SV=1
-MGRLVRGTMILPFFVLMAAGCTPKYDYTIHKPRVVYQQPSRQALRTSLGEILGKKYVWAEEGPEAFDCSGLTYYAFGRMNLEIPRVSSDQAQGGVEVPRDALQYGDLVFFDTGKNFTGTVTHVGVYIGDEKFQQASTNYGKVVISSLNDSNYANRFLTARRYLTDAASPRQTPTGWARNHGY
->tr|A0A418MJS3|A0A418MJS3_9BACT Uncharacterized protein OS=Fibrisoma montanum OX=2305895 GN=DYU11_05040 PE=4 SV=1
-MKSALSKGLLVVAVLSLASCDYQKYNTIRQSDYRGNDPYVYGPNKDSAAIQSKYKYTPNPALEERTQKIREKLFGAGTIGEGA
->tr|A0A2Z5TXE8|A0A2Z5TXE8_9MYCO Putative lipoprotein LppW OS=Mycobacterium pseudoshottsii JCM 15466 OX=1136880 GN=lppW PE=4 SV=1
-MRARPLTMLTAAAAVALVVSLVLTGCEAKVQAKAYGTDDRESSRQQSQPQQQQLIELLLRAITPPEDPAALLPSAGLVGVQERIQRATEEAAAKGATITVAILDRATHQLVSNGKTSIIATASVSKLFIADELLLRASQGKNTLSAQDRQALENMLRSSDDGAAEQFWGELGGDAIVTEIATRYGLAATAPPSDGRWWNTFSSAPDLIRYYEMLLDGEGGLPLQSAAIIVNDLAQSTPNGIDGYPQRFGIPDGLYAEPVAVKQGWMCCIGADWMHLSTGIIGSDRRYIMVIESLQASDDATARETITQAVKTIFPAGRI
->tr|A0A839NTR2|A0A839NTR2_9SPHI Large subunit ribosomal protein L5 OS=Sphingobacterium sp. JUb56 OX=2587145 GN=FHR29_003793 PE=4 SV=1
-MTYVPRLKVKYAEEIRTALKEKFQYKSVMQVPKLEKIVVSQGVGAATSDKKLIDNALSELTLITGQQAVATKSKKDISNFKLRKGMPVGARVTLRDNNMYEFLDRLIAVSLPRIRDFRGINDKGFDGRGNYNLGITEQIIFPEINIDKINKIQGMDITFVTSAGNDVEALELLKQFGLPFKNQNTNNNG
->tr|A0A432QAS4|A0A432QAS4_9DELT Bifunctional 4'-phosphopantothenoylcysteine decarboxylase/phosphopantothenoylcysteine synthetase (Fragment) OS=Desulfobulbus sp. OX=895 GN=DSY50_03665 PE=4 SV=1
-PARYLSNRSSGKMGYALARVARRRGGRVTLVSGPVNLAPPPDVECVNVLTAAEMHQAVMERAADSSIIIKAAAVADFKPQESSPRKIKKSGADLTLELTANPDILAGLGKARTDHQLLVGFAAESDNHEDEGQRKLYDKNVDLMVVNDILGEKTGFDVDTNQVTLITRKNVLPLPFLSKEETAGRILDKILELSRK
->tr|A0A840G848|A0A840G848_9BRAD 3-carboxy-cis,cis-muconate cycloisomerase OS=Bradyrhizobium sp. CIR18 OX=2663839 GN=GGD65_001449 PE=4 SV=1
-MSTSLSPLLAPMLSSAAMRAVCDDRSTLQNMLDFEAALARAEAATDVIPASAVVSIEAACKADSFDMTALAEAATRSGNLAIPLVKMLTANVGKADTEAARYVHWGATSQDVIDTATMLTLRAGLDALDADLSRAIRGFAALARSHRNTAMVARTWLQHALPMPFGLKAAEYAASLARARCRLRRLSREGLALQFGGAAGTLAALGDKGLAVAERLAQELNLPLPEAPWHTHRDRIAEAASAFAILAGTCGKIARDVSLMMQTDVGEAFEPAGEGRGGSSTMPHKRNPVSAASALGAATMAPQLAATIFAAQVQDHERSAGPWHAEWPTLPQLMLVTSGALAAIVDIAEGLDVDAARMRSNLDATHGLIMAEAVTFALADKIGKSDAHHLIEAASKRAVAEKKHLREVLTADSQVTAHLSPEKIAALFEPMAYQGASQALIDRLLDSLDRK
->tr|A0A7N8WV28|A0A7N8WV28_9TELE Transducin-like enhancer protein 4 OS=Mastacembelus armatus OX=205130 PE=3 SV=1
-MYPPARHPVPHQPGQPFKFTVTESCDRIKEEFQFLQAQYHSLKLECEKLASEKTEMQRHYVMYYEMSYGLNIEMHKQVGNFFFFFLLECQQEVKPHYSRCQMNAQQQLQAQHLSHGHAIPVPLTPHPAGLQPPLPPGAGTASLLALSSALSHQLPLKDERKHHDNNSEHPRGKDCPVCVYLKIKCPSVCVCQESDGEKSDDNLVVDVSNEDPASPHGSPAHSPRENGLDKNRLLKKDAPLSPSSVASSSSTPSSKSKEINLKSTTPVSKSSTPTSRSDALTPSSTATPGLRSAPGKPSGVDTLAPGLRTPLAVPCSYPGPFGMVPHPGMNGELSGVGAAYTGLHNISPQMSAVAAAAVYSFVVGFDPHHHIRVPGLPPNLSGIPGGKPAYSFHVSADGQMQPVPFPPDALIGPGIPRHARQINTLSHGEVVCAVTISNPTRHVYTGGKGCVKVWDISHPGNKTPVSQLDCLNRDNYIRSCRLLPDGRTLIVGGEASTLSIWDLATPTPRIKAELTSSAPACYALAISPDSKVCFSCCSDGNIAVWDLHNQTLVRQFQGHTDGASCIDISNDGTKLWTGGLDNTVRSWDLREGRQLQQHDFTSQIFSLGYCPTGEWLAVGMENSNVEVLHVTKPDKYQLHLHESCVLSLRFAHCGKWFVSTGKDNLLNAWRTPYGASIFQSKESSSVLSCDISIDDKYIVTGSGDKKATVYEVIY
->tr|A0A3D9SW97|A0A3D9SW97_9ACTN Uncharacterized protein OS=Thermomonospora umbrina OX=111806 GN=DFJ69_4288 PE=4 SV=1
-MLTSKTKVAMGGVALGVIALWLIPGWILTLLVLGAIAVPVAAYLMLDPSQRRKVRARGRKRLGA
->tr|A0A2U3LCS8|A0A2U3LCS8_9DELT PC4 domain-containing protein OS=Syntrophobacter sp. SbD1 OX=2043167 GN=SBDP1_820009 PE=4 SV=1
-MAKEPQIVHSFPKNPLEEVRSSVTYYKGKQYVDIRIYYKGDDGEFHPSKKGVTLSVELFPELETGFQKLKEALEEEQ
->tr|A0A173RRC4|A0A173RRC4_9FIRM Auxin efflux carrier OS=Faecalibacterium prausnitzii OX=853 GN=ERS852582_00615 PE=3 SV=1
-MELALITAQQVAVLFLLIGTGMVAVKTGVLKLENKQALSNLLVYIIVPAMVVNSYRMEFSAQILHNLLAAFGMSVLSVLLGTVITLLLTARKTGSRMPIFRFACIFSNAAYMGFPLISALFGSEGLLYASAYVTVFNILLWTLGYGLVSGGSSVKEIARSLVRTPVLYAIVVGLGIYLLQIPLPALITQPLELLAGVNTPLSMLITGMLIAAGDVRSIVTDKHIWKLASVRMLLIPAATLALFGVLGFHGTATQVVTLLECCPAAAITSVFAVQFGHDEHFAAGSVVLTTLLSIITLPLCALIITMVM
->tr|A0A3M1TWK5|A0A3M1TWK5_9BACT Uncharacterized protein OS=Bacteroidetes bacterium OX=1898104 GN=D6730_19965 PE=4 SV=1
-MLIGQNPCVCIHKGFFFERKNRLPSAAHNNAAVGALSYRNVKNTGPMAPKGDKCLIFNFRK
->tr|A0A7C3Z4Q6|A0A7C3Z4Q6_9BACT Uncharacterized protein OS=bacterium OX=1869227 GN=ENW92_06685 PE=4 SV=1
-MSKFNETIRGIEDRLDLLQDNIQAIKDDLKILDSISTKIDVLTEQVKSHDIILNGNGSEGLKSKISRFEEIISVLKEKIDNIVTLLFGDLNNEGIKSKINLIDFKIGLISAIGGVAGAVAVTIMSDTIVNLIKKIF
->tr|A0A2T6RAW0|A0A2T6RAW0_HELPX Methionine--tRNA ligase OS=Helicobacter pylori OX=210 GN=metG PE=3 SV=1
-MQKSLITTPIYYVNDVPHIGHAYTTLIADTLKKYYTLQGEEVFFLTGTDEHGQKIEQSARLRNQSPKAYADSISAIFKDQWDFFNLDYDGFIRTTDSEHQKCVQNAFEIMFEKGDIYKGTYSGYYCVSCESYCAISKTDNTNDKVLCPDCLRETTLLEEESYFFRLSAYEKPLLDFYAKNPEAILPIYRKNEVTSFIEQGLLDLSITRTSFEWGIPLPKKMNDPKHVVYVWLDALLNYASALGYLNGLDNKMAHFERARHIVGKDILRFHAIYWPAFLMSLNLPLFKQLCVHGWWTIEGVKMSKSLGNVLDAQKIAMEYGIEELRYFLLREVPFGQDGDFSKKALIERINANLNNDLGNLLNRLLGMAKKYFNHSLKSAKITAYYSKELEKAHQILDNANSFVPKMQLHKALEELFNVYDFLNKLIAKEEPWVLHKNNESEKLEALLSLIANALLQSSFLLYAFMPKSAVKLASAFNTEITPDNYERFFKAKKLQDMILQDTEPLFSKMEKIERTEKAGEASPEKNEKEKKDRKEKAPLKQENYIGIEDFKKVEIKVGLIKEAQRIEKSNKLLRLKVDLGEGRLRQVISGIALDYEPESLVGQMVCVVANLKPAKLMGEMSEGMILAVRDSDNLALISPTREKIAGSLIS
->tr|A0A6P8YKE1|A0A6P8YKE1_THRPL Non-specific serine/threonine protein kinase OS=Thrips palmi OX=161013 GN=LOC117644815 PE=4 SV=1
-MEIVGDYEYNSKDLIGHGAFAVVFKGRKRKDPNYVVAIKSISKKSLAKSQNLLGKEIKILKELTELHHENVVALLDCKESPLQVFLVMEYCNGGDLADYLSVKGTLSEDTIRLFLRQLAGAMKALYAKGIVHRDLKPQNILLSHSGGKPCPQPQEIRLKIADFGFARFLQDGVMAATLCGSPMYMAPEVIMSLQYDAKADLWSLGTIVFQCLTGKAPFQAQTPQALKNFYEKNANLSPKIPAGTSPELRDLLLGLLRRNARERMTFDSFFTHPFLQREAEPTPAPPMPGELPPSPRALFQPPATQSPTHKARLDTCGSQPVPANIPSDHSSDSNPERPSRTRTSSASAASPPRPSFLPISEPIPVPTHRDAFQQRQSIHSQDNEPSKGSVPRSQPINMRRASDQRAANATPDLSSLSPPAVQFMIGTPPNGGCGQRRRSASGSSCETPPPVSTWQVTPTSSPLRRSGASSPLLSGPLAVLPSILGSPNRMSENNNMRQSPLMPFGSRAMTLPEISEAGNFQRLFQDANQPSNIDAPLTFLAPELPEETLLEREHNETLAKLHFVLALSDCVLELAGSRGTPLAALTESVNLGGGGSPNGSSNITGNGVISEGARRAEQLVLLVRALQLLSSGLSLATQQIRAGHLQPSSSVKSVVGIMNQKFRQCLADCKQLNTPGLLQKAGVDPATTNIAADKILYNHAIQMCQSAALDELFGNPEDCFQRYQTAQILLHSLSQQVHHQQDRALLTKYKDAVEKRLFVLQQQGFIYSTQCFTHLA
->tr|A0A151YSI4|A0A151YSI4_9GAMM Mandelate dehydrogenase OS=Acinetobacter lactucae OX=1785128 GN=AWW73_12870 PE=3 SV=1
-MSRKLINVEDYRLQAKRTLPRIIFDYLEGGAEDEKGLNHNRTIFDQFRLKPKRLVDISQRDISCKIFNKKWDAPFAIAPTGLNSSLWPHADSILAKSAAKANIPFMLSTASNMSIEAVAKSCDGEKWFQLYVVHQELAVKMVQRALSAGYTTLIITLDVGVNGYRERDIRNGFAIPLKFSPSLILDGMMHPGWSLRFLSQGMPKLANFESSEAHSLEVQNALLKRQMDTTFNLESLKKIRDLWPHTLLVKGLVRQEDALKAIEAGADGVILSNHGGRQLDCSISPMETLYEVSQTIEQPVLIDSGFRRGSDIVKALCLGANMVCLGRATLYGLAANGEAGVDDVIQLLKQDVDRTLAQIGCPSVSQLNKEYIT
->tr|A0A502DVG8|A0A502DVG8_9MYCO Uncharacterized protein OS=Mycolicibacterium hodleri OX=49897 GN=EAH80_27785 PE=4 SV=1
-MERTDRRKAQAAIIGGTALLAMGIIGGAAGGPGDGKTALVSGGSMQTGETTTLTYTGTIAPVKAVPSVKATPH
->tr|A0A6P7I339|A0A6P7I339_9TELE caM kinase-like vesicle-associated protein OS=Parambassis ranga OX=210632 GN=camkv PE=4 SV=1
-MPFGCLTIGEKKDYNSPSDVTDKYDLGQIVKSEEFCEIFRAKDKTTVKMYTCKKFMKKDGRKVRKAAKNEIFILKMVKHPNILQLVDVFETKKEYFLFLELATGREVFDWILDQGYYSERDTSNVVRQVLEAVAYLHSLHIVHRNLKLENLVYYNRLKHSKIVISDFHLAKLENGLIKDPCGTPEYLAPEVVARQRYGRPVDCWATGVIMYILLSGNPPFYDETDDDDYENHDKNLFRKILAGDYEFDSPYWDDISDSAKSLVARLMEVDQDQRLTAQEAINHEWISGGAASDKNIKENVCAQIEKNFARAKWKKAVRVTTIMKRLRAPEQSDSRSTSPAAGTPADTAAPPADPAAPSSAAVPEVSPAAVTELPAGAPPEAGAGAAAEEPQPPNPALQVAEPASRCNGEASAILHTAAEAGDEQG
->tr|A0A521F3G2|A0A521F3G2_9RHOB Do/DeqQ family serine protease OS=Ruegeria faecimaris OX=686389 GN=SAMN06265380_11652 PE=4 SV=1
-MRKVLCSLLLTVAAVSAKAETKVPQTQVEISLGFAPVVKQAAPAVVNIYAKIVREGRSNSLFSDPFFQDFFGGGFGEPRPRVQNSLGSGVILTDDGYVVSNYHVVGSATEIRVVTTDRREFSAEVVLGDQESDIAILRLKDAEALPSIDMRDSDLVEVGELALAIGNPFGVGQTVSSGIISGLARTGTATGNARGYFIQTDAAINPGNSGGALIDVNGDLIGINTSILTRSGGSNGIGFAIPANLVAEFLRQAQAGNDSFVSPWAGMAGQHMSADIAESLGLVIPQGVVISDLHALSPLAEAGLQVGDVVTHVDGDEVNSPAEMKFRMSVAGVGGTSVVTRLRGEDRAELEVALVKAPEVPAAEVTTLNDETVMPGLTVSRINPAVIARLGLLLSQTGVVVVDAGRYGGRSGLRPGDVVDGINGARVERPADVVKALTDPGRRINLDILRGGRPVSLRFRL
->tr|A0A1H9D944|A0A1H9D944_9BACT Monosaccharide ABC transporter substrate-binding protein, CUT2 family OS=bacterium A52C2 OX=1855383 GN=SAMN05216548_102373 PE=4 SV=1
-MKSIRSLAVALALGVAAVVSAQAEAADITVGFVPGTVSDPFFQAMKKGAQQAADRLGMKLNWQGSSGEYSPQQQLPFVDAMLANNVSVLIFCPTDPDSMQASVTKAQIQGIPVITVDTTVTDQSSVTSFITGDNVAGGRQAAQTLAEQIGNKGKVFIMATSPSATTNTLRRQGFEEEMKNHPDIKIVGIQYSQSQPDRATSAVNTVLLDQPDLAGVFALDGTNTQGAVAAIRNSGKTGKVKLVGYDAYQAEVDALKDGVVTALVAQRPSEEANMAMEFALAKVSGKDTDKIQKNAVIPNVVITKDNLSENEKYVYSE
->tr|I7C407|I7C407_PSEPT Sulfate adenylyltransferase subunit 1 OS=Pseudomonas putida (strain DOT-T1E) OX=1196325 GN=cysN PE=3 SV=1
-MSHQSDLISEDILAYLAQHERKELLRFLTCGNVDDGKSTLIGRLLHDSKMIYEDHLEAITRDSKKVGTTGEEVDLALLVDGLQAEREQGITIDVAYRYFSTAKRKFIIADTPGHEQYTRNMATGASTCDLAIILVDARYGVQTQTRRHSYIASLLGIKHIVVAVNKMDLKGFDEGVFESIKADYLKFAEAINLTPSSLHFVPMSALKGDNVVNHSEQSPWYAGPTLMEILETVEVSADRNFTDLRFPVQYVNRPNLNFRGFAGTIASGVVHKGDEIVVLPSGKSSRVKSIVTYEGELENAGPGQAVTLTMEDEIDISRGDLLVHADNVPPVTDQFDAMLVWMAEEPMLPGKKYDIKRATSYVPGSIASITHKVDVNTLEQGAASALQLNEIGRVKVALDTSIALDGYDSNRTTGAFIVIDRLTNGTVGAGMIIAPPVLPHGSTGHHGKQAHVSTEERALRFGQQPATVLFSGLSGAGKSTLAYAVERKLFDMGRAVYVLDGQNLRHDLNKGLPQDRAGRTENWRRAAHVARQFNEAGMLTLAAFVAPDAEGREQAKALIGKERLVTVYVQASPLVCRERDPQGLYAAGGDNIPGESFPFDVPLDADLVIDTQATSVDEGVKQVLDVLRQRGAI
->tr|A0A2P5F9R2|A0A2P5F9R2_TREOI Son of sevenless protein OS=Trema orientale OX=63057 GN=TorRG33x02_095620 PE=4 SV=1
-MARRTAQVLDSIHLMNTTQIFKESIRVILLHPTQFHSISIFLFSPLPISLFISHLLIHHFPNIPSSTISLTHNLFGFPLPKLFSKTMIHIIICFPSSITFSLLGRAAIVQAVSDIYNGINLDGRRLFMRSGLTWIKLLYTTFWEYLIVFGLLGVFALNLVIMPKMFHAFGICSEILGFWGVLGVLGIPFCVAFAHVMVVGNLARVLSVLEGNCYGFESLLKAKSLMEGRRQIALVMALLSNIGFRLVESLFEFRMCKGINLWEGPLLVSMYSSVLVFDTVMNVVFCYACKSFNDQ
->tr|S1PYQ0|S1PYQ0_ECOLX Starvation-sensing protein RspB OS=Escherichia coli KTE182 OX=1181728 GN=A13A_01543 PE=3 SV=1
-MKSILIEKPNQLSIIEREIPTPSAGEVRVKVKLAGICGSDSHIYRGHNPFAKYPRVIGHEFFGVIDAVGDGVESARVGERVAVDPVVSCRHCYPCSIGKPNVCTTLAVLGVHADGGFSEYAVVPAKNAWKIPEAVADQYAVMIEPFTIAANVTGHGQPTENDTVLVYGAGPIGLTIVQVLKGVYNVKNVIVADRIDERLEKAKESGADWAINNSQTPLGESFAEKGIKPTLIIDAACHPSILKEAVTLASPAARIVLMGFSSEPSEVIQQGITGKELSIFSSRLNANKFPVVIDWLSKGLIKPEKLITHTFDFQHVADAISLFEQDQKHCCKVLLTFSE
->tr|A0A0D8JWE6|A0A0D8JWE6_COCIM Uncharacterized protein OS=Coccidioides immitis (strain RS) OX=246410 GN=CIMG_11771 PE=4 SV=1
-MVHPEPDRIQTGIANDAPVNRLLLPSTSLLDTQFTRTPLGFRGGPDEFPADVDKEFTKSE
->tr|Q4S6C8|Q4S6C8_TETNG Chromosome 9 SCAF14729, whole genome shotgun sequence (Fragment) OS=Tetraodon nigroviridis OX=99883 GN=GSTENG00023347001 PE=4 SV=1
-LLLGLFVVCGLALLGLLAFVSWKFAGAARQPAKACCSGSSLSPERHPLQPPLPLPPSPQHPLVTMATEKVKDPAGSLGFLEAAVKISHTSPDIPTDVQLSMREHFLRRTQRMQRQTTEPASSTRHNSFKRHLPRQMQVGSLDLGNDYVLEKEEKSTSLGRIQPELYQQKDLESEDSSKNSSGKNCGSINFSLKYDYENQALLVDILKAVDLPAKDLCGTSDPYVKVYLLPDRKKFQTRVHRKTLNPTFSETFRFPVPYEELAGRKLHMSVFDFDRFSRHDMIGEVELDNLFDLSDLSRETNVWRDIQYATSESVDLGEIMFSLCYLPTAGRLTLTVIKCRNLKAMDITGYSDPYVKVSLICDGRRLKKKKTSIKKNTLNPSYNEAIIFDIPPDSMDHVSLHISVMDYDLVGHNEIIGVMRVGCNAEGLGRDHWNEMLAYPRKPVAHWHPLLEPKKSEKEWKARTASFDSQGSCPSPRPPASP
->tr|A0A4Y6N1A7|A0A4Y6N1A7_SALET AI-2E family transporter OS=Salmonella enterica subsp. enterica serovar Indiana OX=286783 GN=D4X88_10560 PE=3 SV=1
-MLEMLMQWYRRRFSDPEAIALLVILVAGFSILFFFSGLLAPLLVAIVLAYLLEWPTARLQAIGCSRRWAASIVLILFVGILLLMAFVVMPIAWQQGIYLIRDMPGMLNKLSDFAATLPRRYPALMDAGIIDAMAENMRTRMLNMGDSVVKYSLASLVGLLTLAVYLVLVPLMVFFLVKDKEQMLNAVRRVLPRNRGLAGQVWNEMNQQITNYIRGKVLEMVVVGVATWLGFLLFGLNYSLLLAVLVGFSVLIPYIGAFVVTIPVVGVALFQFGLGTEFWSCFAVYLIIQALDGNLLVPVLFSEAVNLHPLVIILSVVIFGGLWGFWGVFFAIPLATLIKAVVHAWPDGQVTDTSS
->tr|A0A265NA24|A0A265NA24_9BACI Serine/threonine dehydratase OS=Virgibacillus indicus OX=2024554 GN=CIL03_13610 PE=3 SV=1
-MVTVKNIYKAREQISDVINKTPILSSSQLSSICGNRMFFKAEHLQKTGAFKIRGATNKVKQAVKDGATFVTAASSGNHGQAVAYIANELGVPATIVVPEDVNPSKEAAIKAYNGEIERCGLTSAERLPRAEALAAENNGGVIPPYDDPLIIAGQGTVGLEILDQLDGVDVVVVPIGGGGLISGILTAIKEIKPSIKVIGVEPEKANDTYQSIQQGKITSIKEAATIADGLRTSQPGSLTFPIVQKYVDEIVLISEAEIRKALFFILQRMKQLIEPSSAVTVAAAMFDKLNVRDKNVVCVLSGGNVDLKQLGEMNPEK
->tr|A0A2A5WAU1|A0A2A5WAU1_9GAMM Sulfite dehydrogenase OS=OM182 bacterium MED-G28 OX=1986256 GN=CNF02_07660 PE=4 SV=1
-MGPKKQNRREFLKQGAAIAGGAAVGAASQSASAQLPGPEGFLHGRDDIVAYGQRSRFIESKRIPHGGRHSPDTFGLDFHIATPLQDQHGVITPSSLFYMGTTRGSYIPDIDPEKHRLMIHGLVDNPLVFTMEELKRLPSVTRMHFVECAGNRSNRRHTTVQETHGMTSNAEWTGVLLSTLLKEAGVKEGADWIVAEGVEEVKGASSIPMTKAMDDTLLAYSMNGEPVRPQQGFPLRMLAPGFEGIFNVKWLRRIKVVDQYYMTYNDYGHLTQDPATAALGYQIGPKSVIVHPSGGQTLPGAGYYQVSGLAWSGGGKVARVEVTTDGGETWFDAEIRGEPQAMAHTLFAFEWEWDGSPCELQSRCIDEIGQVQPSRAEVAEFWNQPADQPPRVRGQDNSIQPWRIESDGSIHNAIA
->tr|A0A1J5QM58|A0A1J5QM58_9ZZZZ L-cystine import ATP-binding protein TcyC OS=mine drainage metagenome OX=410659 GN=tcyC PE=4 SV=1
-MSPTEEPPPMGEVLLSVHGLSKSFGANPVLRSIDLTIERGRVLALIGPSGSGKTTLLRCLNGLELADGGTINTPGELTLDFTTPPTRSQLNALRDRSGMVFQHYNLFPHKTVLQNVLEGPLVVQRRPRAEATASALELLARVGLSEKTHTYPFQLSGGQQQRVGIVRALALQPQLLLFDEPTSALDPELVGDVLRLIKELAADGWTMVIATHELEFAREVAHEIAFLDAGTILERGHPSQLLRDPQHERTRQFLHRVLHPF
->tr|A0A0M0J7I6|A0A0M0J7I6_9EUKA Cyclin-y-like protein 1-like protein OS=Chrysochromulina tobinii OX=1460289 GN=Ctob_004972 PE=4 SV=1
-MGDEGLTLCARTWRPALLMAIVIASKVVYDEKVYLADYRDMLPEFCLDAASAQELELLKLVNYNTTVRRGQYARYYYALEDVARNQSSNQIFAARS
->tr|A0A7X6ZE57|A0A7X6ZE57_9FIRM Sporulation sigma-E factor-processing peptidase OS=Syntrophomonadaceae bacterium OX=2093811 GN=spoIIGA PE=3 SV=1
-MTGHKVYADLTLIINLLMDAVILWAAAKLAGFKFSYTRIFFTAMLGAIYAVGYLFYPMNIFYSFPLKIIFSCFLILLAFYPQSWKDLKRAFQYFYLINFIAAGAITGFASLTAGMKHINNISILWLLMGVIIVIGLGKWGQKYLVNRIIPQLLNYMVEIKFNGHQCSGSGFLDTGNMLRDPLTNRPVLIAEYAWLKNFLPLDLIEFFETGSSETEILSFAANSTWADRVRVIPFSSIGRHNGLLLGFRADEINVSLGDRNICHKNLIVAVYRSKLCQDGHYQMLVPAEILQSG
->tr|R6ZSV7|R6ZSV7_9BACE Putative CTP pyrophosphohydrolase OS=Bacteroides fragilis CAG:47 OX=1263046 GN=BN669_00524 PE=4 SV=1
-MKSIEVVAAVIRLGEKYLCVQRGQTKFSYTSFRYEFPGGKVEEGESLQEALQREIMEEMDYVIEVGEKLLTVHHTYPDFEITMHAFLCHPVGQRYVLKEHIAAQWLSTREMAILDWAEADKPIIRKISEQ
->tr|A0A535V1X9|A0A535V1X9_9CHLR APC family permease OS=Chloroflexi bacterium OX=2026724 GN=E6I76_01260 PE=4 SV=1
-MRGGRARRKEFDKVAEGYLQAKEESVKPTTQLGRLRRALLGRPLASKQQIHERLTKVKALAVLSSDALSSVAYATEQILLVLGAAGAAAYSYSMPIMVAILVLLIAVGLSYRQTIKAYPKGGGSYIVASDNLGPLAGVVAGSALMTDYVLTVAVSVASGVDSIVSAASAMQAYRVELCVAFVAILIVGNLRGIRESGSIFAAPTYLFIGGILLMLVVTGLRWGTGNVHEATPMLGKATQQVSIFLILRAFASGCTALTGVEAISDGVPAFKPPEWRNARTTLTVMVVLLATMFMGITISARATGARAYDSSDPNYQTVISQLAHTAFGSTFLYYYVIGATTAILVLAANTSFSDFPRLFFFMARDDYAPHLFKRLGDRLAFSNGIIVLGGLAILLLVVFRGRTDALIPLYTIGVFVAFTMSQAGMVSRWLRLREPGWQHGLAMNAVGMTLTAIVFVVTAGDKFTEGAWIVLVLIPLLVMTFFSIHRHYSEVTVDLATETPTSPDELKPVVIVPLADLNGPALQSLALARTLSDQVIAVHISDDPDEIARLKAKWEAWGDHVPLEVIESPYRSLVRPLLAYIDAIDRQRRDDTIVVVLPEMVATRWWHQVLHNQTALRLKAALLFRPGTVVVNVPYHLRRYQHQRRRLRARHGGDDAL
->tr|A0A7T7DGS6|A0A7T7DGS6_9BETA Cy128 OS=Cynomolgus cytomegalovirus OX=1919083 PE=4 SV=1
-METHLFSDLAFEQVFEEDPQLPLHVVLDPVDLSFAEAETVRYVYYRSDPDPVGRWRRAAFRVFLRPFELLTYLRDAGLMVAPTVRVVCHHALFTTLGIRCAEQRLSGAQMLYLRLVWNEERFRDWEFLVRDLLREEMSVCQSTEPADRPDPSLLMTDAMLELAKSSSTTAPFFEMPSSGTGNNNASSASAADESSQVERRVIQFLRGDSELTYHAGPLEPPSKIRGHEIVQPRIEVNPDVIYASGPHEDDRTSKTDEWQKGGVMRLGSVWDVRQRLRLHVLWYAQSFWRSRGLKYEDREEDLRLTLDSYFDRLSVEYQVLREVYREIKAVLRSDRMVAQKFSCHLSIETSWLLIWELFDRALELWRDQADVNSCIIKALAHKLRSKAQSSHGNSVSAGKTNPTETWYADVVRCVRAEVNLGLEVQVETCSQSGLWLVRGRDGQLRKWITQPQTYVLYATPGLVFHWVLPGGFAISSRVCLDGVGRDHFERFQMSAPVLTKRMLLETGWTRTEASGVPSCGL
->tr|A0A852XDT0|A0A852XDT0_9MICO GTP-binding protein Era OS=Microbacterium esteraromaticum OX=57043 GN=GGD75_001854 PE=4 SV=1
-MTEQTRSGFVTFVGRPNVGKSTLTNALVGEKIAITSEKPQTTRRAIRGIVNRPDGQLVIVDTPGIHKPRTLLGERLNDLVEQVLGDVDVIGFCVPATEKVGPGDRRIAASLDGYPRAKKVAIVTKTDAADKDDIVERLMEVDSLREDWAAVIPLSALTREQLDVLADEMLQLMPVGPRLYDEGVVTDESTDDRIAEMIREAALEGVRDELPHSIAVVIDDVEPRGDSDLTDVYASIIVERDSQKAIIIGHKGSRLRSVGATARAGIEELLGTRVFLKLHVKVAKEWQRDPKQLGRLGF
->tr|A0A7G9B3G3|A0A7G9B3G3_9FIRM MarR family transcriptional regulator OS=Oscillibacter sp. NSJ-62 OX=2763056 GN=H8790_11715 PE=4 SV=1
-MDKTERQTTKITREAAKLTLQTMRAEGGTAEFDFIHLVRHYPGITQAELREALKIDKGAAARRAAHLEAKGYLVRRENPADGWSQLLYATEKAEKLKNSKAGIESAFKRLIS
->tr|A0A2K6TWZ0|A0A2K6TWZ0_SAIBB DNA repair protein OS=Saimiri boliviensis boliviensis OX=39432 GN=XRCC3 PE=3 SV=1
-MRPLFCLSCEVNHPGDQPTDRMDLDLLDLNPRIIAAIKKAKLKSVKEVLHFSGPDLKRLTNLSSPEVWHLLRTASLHLRGSSILTALHLCQQKERFPAQHQRLSLGCPVLDALLRGGLPLDGITELAGHSSAGKTQLALQLCLAVQFPRQHGGLEAGAVYICTEDAFPHKRLQQLMAHQPRLRTDVPGELLQKLRFGSQIFIEHAADVDTLLECVNKKVPVLLSRGMARLVVIDSVAAPFRCEFDSQASIPRARCLQSLGATLRELSSAFQSPVLCINQVTEAVEEQSTVHGPPGFWDERISPALGITWANQLLVRLLADRLREEEAALGQPVRTLRVLFAPHLPPSSCSYTVSTEGVRGTPGTQSH
->tr|A0A2M7XMW0|A0A2M7XMW0_9BACT Uncharacterized protein OS=Candidatus Shapirobacteria bacterium CG_4_9_14_3_um_filter_36_12 OX=1974877 GN=CO168_02590 PE=3 SV=1
-MVETELLKNLKTYFGYDGFRALQEEVVGATLAGKDSLVLMPTGGGKSICFQLSALMLPGITLVISPLIALMKDQVDSLKNNGIKAEFINSSLTTGEILRIETEIIGGKIKLLYVAPERLVLPQFLEFLKTIKISLIAVDEAHCISEWGHDFRPDYRNLTILRQNFPSVPIMALTASATEKVRQDIGLKLNLNNHQLFISSFNRPNLYYTVLPKRNTFEQLLSLVEKYKNNSIIIYAFSRKETDELAVNLSTQGYQALAYHAGLESNIRREVQDKFIKDEVKIIVATIAFGMGIDKSDVRLVVHYSLPKSVESYYQETGRAGRDGEKSECVLFYSYGDTAKQNYFIRMMTDGVVRLNAQKKLREMVNYCELKSCRRQYLLKYFGEELGNNCQSCDCCVKSPPTPSLTKEGNLNLFEKLRILRKQIANQNKVPPYIIFSDATLREMVSFLPKNETEFLKINGVGAEKLKRYGRQFLETINSQNAPKVFLSGTYLETQKMWVAGLSIEQIAKNRGYTNETIINHLEKIIESGVQLNLDKIIFDPTRLKIIKDAFAQTNDTKLAPIKAILDDDYSYEEIRLGRLMVAK
->tr|B4ELZ0|B4ELZ0_BURCJ LysR family regulatory protein OS=Burkholderia cenocepacia (strain ATCC BAA-245 / DSM 16553 / LMG 16656 / NCTC 13227 / J2315 / CF5610) OX=216591 GN=BCAM2812 PE=3 SV=1
-MTEQSKNLQSGYAAHAYPLADLTRPLPPLAAIQSFVAAAQLGSVSKAADHLCRTQGAVSRQIQQLETHYRCALFVRHVSGLTLTAEGNALLTVAVNVLTQLVRHADVHARATSVLTLKLPSTFAVRWLLPRLPDIQRAMSGTELRISTSADDTPDFTTSDVDAVVVRGTGQWTGMEAIPLFAEMLTPMCAPALAASLRSVADLAQVELLHPGPSHAEWRCWLDHVGARQVDAGRGLVFDTLELTLAASMEGHGVAIGDPRMARDRLRAGSLVTPFEDVARDGLSYFLVYPPQRAAQPKIRALADVLLRLAREDR
->tr|E9HNJ7|E9HNJ7_DAPPU Uncharacterized protein OS=Daphnia pulex OX=6669 GN=DAPPUDRAFT_116105 PE=4 SV=1
-MPCSVVLNENVLHISWELALYGASRISFSDHSAHCFRRKLQCCPCHTPPGVSCGQQLGKCVYVREIFVLRFRSVYPSLAREWLPRIRRWCSWSDLKSVVDKFASLACCKLGYIIPHPKIMASRIGAYRSGSVLAGGRQAGVTVRPGIQYRLMGLGKLAILFAHECPPHLVHFVRFVWDGTGRSAVLRRHQGADGNVAAAGPASSGSLAEEHQRRRAAARPARRQGSRPGLHGEPATDVGDGPQQRRDDGQPDRQSNVGPVVDGSTSAFGRTQEPHRHSVSRLEDSATQTQMEESFFSENKDGTEIQLSSAGVRLSETESGLRRQRIRRRAQQRRFLTDPRPPPNDEEFRWKSRQRYSDDSGSESDDEQHLPGLRYHQQQQQQRPNLSQYVSDSGAPGTGGSGGDGSSQGLSNINTVHLEPLVKSSQVATDLAVRSQSILSNVGTESSGQNNSGFSDLVARSEEDINSSALSRRTDSAILLLDHIGSPSEQQMMNGPDGENLNRSSSSLNKKTTTHSPLMDDVESSRKRTKSERRSEHEGSSAHPPTATHPHSERIKYKAEIPISVIRAAQAKTRRYNLERKIFQQLLDWKQMQIRIGQANEHQLRLVQGGRTLLPLVDSATDREDAATTNGLKYGDVIETESANGTSRTTTTTMPVEKGTHTTQRCPHAMYACTTLPPALAARPCPALPLVISRFSMDVVVEPIDFDSFEGLLVSFLNDSAVPYHKHHRPVTQQHQQPQQPTNHPGTAKLTTENGRIILPKLNLNNNINGHQKSNAPANKGNH
->tr|A0A6P1MDY7|A0A6P1MDY7_9FIRM Type II secretion protein F OS=Aminipila sp. CBA3637 OX=2697030 GN=Ami3637_02060 PE=4 SV=1
-MLTYFIAFFAAILTYFIILLIKKNSGREFIENRLNKYLNKDAISRIQDQFYKEKIEKYKKKKDRNFKIASKEFSDYLAMSGIKLRASEFIYIWIIMTYLPILIISLSGLSIVTAAGFAIVGFIIPPLFIHKSRRKRQTEFNKQLGESLVVMSNCIKSGFTFQQSMESIANDMQPPISVEFTKTLREMRFGVNKNDALHHMVNRVQNNDLGLLVSAVITSEQVGGNLSEILDTISDTIKDRIRIKQEVRVLTAQGRMSGIVIGLLPIFIIILLMILNPQYFLSFFETSIGKIMIGVSILMELIGFVIINKIVDIEY
->tr|A1JPW7|A1JPW7_YERE8 Peptidoglycan D,D-transpeptidase MrdA OS=Yersinia enterocolitica serotype O:8 / biotype 1B (strain NCTC 13174 / 8081) OX=393305 GN=pbpA PE=3 SV=1
-MKKEPNPFRDYSAESALFVRRALVAFLGILLLSGILVANMYNLQIVRFEDYRTRSNENRIKLVPIAPSRGMIFDRNGTPLAMNRTIYQLELMPEKIEDLPATLNALRPIVDLTDEDIANFEKERKRSRRFTSIAVKTPLTEVQVARFAVNQFRFPGIEVKGYQRRFYPYGSALTHVIGYVSKINDKDVERLDKEGILANYAATHDIGKLGIERYYESVLHGKTGYEEVEVNNRGRVIRQLHEQPPQAGKDIYLTLDLHLQTYIEQLLSGSRAAVVVTDPRTGGILALVSNPSYDPNLFVDGISNKDYQGLLNDPNRPLINRATQGVYPPASTVKPYIAVSALSAGVITKNTSLFDPGWWQLPGSEKRFRDWKKWGHGRLNVTKALEESADTFFYQVAYDMGIDRLSSWMSKFGYGEYTGIDLSEERAGLMPTREWKQKRHKKPWYQGDTIPVGIGQGYWTATPIQMAKALMTLINDGAVKTPHLLQSTRIDGVLVPYKQEDSTQIGDIHSGYWEIAKDGMYGVANRPNGTGRKFFEGTPYKAAAKSGTAQVYSYETYNAHKVAEHLRDHKLMVAFAPYENPTVSVAMILENGGAGPAVGTITRQILDHILLGDNNTELPDAAPLPPGVEAD
->tr|A0A7K2NHN8|A0A7K2NHN8_9ACTN Indole-3-glycerol phosphate synthase OS=Streptomyces sp. SID5468 OX=2690295 GN=GTW54_22445 PE=4 SV=1
-MITTVLMIEKPLAPVDVQLVTTLHSDEAVSFVVLMQPRGDQERLLRALDDVALGELREAAREEEEPEGDQALAPAVHALEHSLKALRATGAEAVGQIVEEHPLDLLRSVVEQTGADEVIVLTAPHLVEEFFHRDWASRARHKVGVPVLKLYAHND
->tr|A0A132DP21|A0A132DP21_BURVI NAD(P)H quinone oxidoreductase OS=Burkholderia vietnamiensis OX=60552 GN=BvRS1_03110 PE=4 SV=1
-MKAITFKEFGDAEVLQLAEVAAPEVRPDDLLVRVHAAGVNRADLTHRRGGYGRPNFGDSTIMGLEIAGEVIETGSSVQGYKVGDRVMGVVGGGAYAERARIDWRMAMPIPATLDYVHAAAIPEVFVTAHEALLHLGRLQRGDAVLIHAAAGGVGSAAVQLAYATGATIFATAEASKLERIVQLGVDHAIDYKTQDFSEVVASRTGKRGVDVVIDFVGAPYFSRNVASLANGGRLVQVGILGGGGDVSVSLEQILYRHLQIIGTVMKSRDQSEKHAMVRRFREHWLDRFAGGAGLEPVVDSVFPLADAAAAHRRMESAVNVGKIILTMSEDS
->tr|A0A1G8CMD4|A0A1G8CMD4_9PSED Peroxiredoxin, Ohr subfamily OS=Pseudomonas panipatensis OX=428992 GN=SAMN05216272_101672 PE=3 SV=1
-MHSIKALYTATATATGGRDGRAVSSDGILDVKLSTPRELGGQGGAATNPEQLFAAGYSACFIGALKFVASQSKRQIPADSSITGKVGIGQIPGGFGLEVELNISLPGLDRTVAEELVAAAHQVCPYSNATRGNIEVRLNVAV
->tr|A0A1Q8LW97|A0A1Q8LW97_9PSEU Methyltransf_21 domain-containing protein OS=Pseudonocardia sp. Ae717_Ps2 OX=1885573 GN=Ae717Ps2_3992 PE=4 SV=1
-MTGPRLSFVGRSRVRARRLLARLLRAVPGRTVDWAHRHWITDDGRTDPRWAPVARLLFHRPLHQTVVTVPGSGGIRLHVVGARLERTLYWFGEQGYEPGEAAWWRLLCSRATAVLEIGSNIGWYTTVGAAAAPVGGYLAVEANPEAARATRRNLELNGLGHGAVLTAAAVGQGAPSSLYLALPDQESFSAAPTGSYLRGHTEGTADRAARRSLTVPTLSARHLITGRDLVKLDVEGAEAGILESALDIILRDRPILLVERMPDTPRLDRVLEQLVGGGYLVLRLGTQLQPAGPRPPVDEHYDVLLVPAERGAVPVHLGDLR
->tr|A0A165XXG3|A0A165XXG3_9BILA Cytochrome c oxidase subunit 1 (Fragment) OS=Keratella cochlearis OX=204738 GN=CO1 PE=3 SV=1
-TLYFIFGIWAGFIGLSMSLLIRLELGVVGPFLSDEHLYNVIVTAHAFIMIFFMVMPISMGGFGNWLIPLMLGVADMAFPRMNNLSFWLLIPSFTFLLLSSILDSGVGTGWTVYPPLSDSKYHSGISVDLAIFSLHLAGISSILGSINFLTTIICSRTTKVISLDRMPLMLWAISVTAILLITSLPVLXGAXSMLLTDRNLNTSFFDP
->tr|A3XB71|A3XB71_9RHOB Uncharacterized protein OS=Roseobacter sp. MED193 OX=314262 GN=MED193_21946 PE=4 SV=1
-MLWTTIQNAILVSMIDLYSAEPDFEAEITILRVEEGGRTVPPHNYIRWDFGYAEDNPLEPRRNLSANIYMIYPNFLNEDGVPIPKGVPLNGTYNAYMHILVRDMVDYHQSRLSVGTNFNCHEGSRIVARGTVTKLRAISP
->tr|A0A7V5NXA8|A0A7V5NXA8_9PROT RNA polymerase sigma-54 factor OS=Hellea balneolensis OX=287478 GN=rpoN PE=3 SV=1
-MALAPKLQQKQAQGLTMTPQLQQAIKLLAMTNLELQLFVEEQLQSNPLLERGTGTENRRGENVPEGKPDEAGPEELQLGEASPVALEALDVSAETLEPDSAPSDLPSSGGEIDWSRAGNGGSFNPSSGLDRLENTAAQKTLKQVLSEQLVIAFPSGQERLIGAHLIDQVDENGYLHASLSEMAERLGVEQTQLETILAKLQTFEPCGVMARSLSECLRLQLREKGELDGPMQRLLDNLELLARHDMQGLAKCCGLDREALGAYVKRLKALAPKPGLAYGSDVAQAVAPDVFVRARPDGGWAVELNTETLPQILVNARYYAEVCSSAKDEKVKSYMSECAQNASWLVKSLDQRARTILKVASEIVRHQDAFFAYGVNHLRPLTLKTIAEAIDMHESTVSRVTANKYMATSRGLFEMKYFFSNSISASDGGEGHSAESVKHKIKILISEETTANSVLSDEKIVRLLRDQGIDLARRTVAKYREMLGIPSSVARRRILKNK
->tr|A0A255T6L9|A0A255T6L9_9BACT Zinc ABC transporter permease OS=Prevotella sp. P2-180 OX=2024224 GN=CIK98_17110 PE=4 SV=1
-MDNDNIIIRLARPDEAEHVAKLIMTAMTEECCLWFCGKDHDIGDFHKVMTELVKQEDSQYSFLNTLCAVDSHDNIVGILTSYDGGRLHEFRQRFIEAAKMAWGIDHSNIPDETGPGELYLDSLAVEPSSRGKGIASKLIEASVDKARKMGLPFTGLLVDTSNPRAEALYTRLGFRVEGTNQWGGHPMRHMVKLTSNR
->tr|K7P3Q2|K7P3Q2_PINMU Uncharacterized protein (Fragment) OS=Pinus mugo OX=28528 GN=UMN_1037_01 PE=4 SV=1
-SSISPAAASSSENSTVTGTPSSSSSNSRVNTPAGDGTAGLYGFSLEVRDALTEQAHCSVTAEECSTVPVPAPYTGLVALDCGSLGTMDQQIHINPELLNSGDLLNSSSFSFGDLIGSSNLAGVTLADLQWKLQQ
->tr|A0A1C7MXD4|A0A1C7MXD4_GRIFR Uncharacterized protein OS=Grifola frondosa OX=5627 GN=A0H81_00337 PE=4 SV=1
-MERCAAPYLAESSRSEGCRSVEENWAPRAIVHTDVYRFLGYTNIHLLHCNAPERNTFSTGLLTNHLTQWLRHVTFVRVLTYLFSAQTDVKETVLYGVN
->tr|A0A439ZYD0|A0A439ZYD0_9HYPH Uncharacterized protein OS=Mesorhizobium sp. OX=1871066 GN=EOS34_27205 PE=4 SV=1
-MAPNARAHDALLTTAQPHGWTYPFACCSGYDCREVAENAIRERPEGYVIEDTGEVIAYTDSRIKNSPDGVFHWCSVAGANDGHTVCLFAPQRGF
->tr|A0A2E6K1T8|A0A2E6K1T8_PSESP Uncharacterized protein OS=Pseudomonas sp. OX=306 GN=CML01_16865 PE=4 SV=1
-MKISNHDHSSSNPGDEAPPGTPGTGENICPVCNGSGRTEAGECKNCGGTGKVIEGIGGA
->tr|A0A4V6KLH6|A0A4V6KLH6_SERFO Immunogenic protein MPT70 OS=Serratia fonticola OX=47917 GN=NCTC12965_00545 PE=4 SV=1
-MKKLLCTALCSSLLFSSVSMAAMMSDTVMVGGAAMYPSKNIVENALNSKDHTTLVAAVKAAGLVDTLQGAGPFTVFAPTNEAFAKLPAGTVDTLLKPENKAALTGVLTYHVVAGRYDMKQLEKKIKEGHGTAELKTVNGQPLWIMNNGPPQYSAQRWPRSYCQHQHL
->tr|W9XCM7|W9XCM7_9EURO MFS domain-containing protein OS=Cladophialophora psammophila CBS 110553 OX=1182543 GN=A1O5_01390 PE=4 SV=1
-MSEKITAPFLKLYRHLFPKGRNVQNDTAEKAIPPESLIVVLQDIGRVDEVIRRELQDISEEEILSIAKRIKRLLDVCLVSMAWIMFALNSFDRSSLGNARVMGLQKDLDMNSNQYGLAMMLLFIAYVLAQVPSNYYLARGRPSIYLPVVMVLWGCVCTATAFVTTPSQLYVVRFFLGLLEAPFCVGCLFLISSWYTRTELGLRSAILLTAPMMANAFSGLIAFGIYDTIDGARGLEAWRWLFIVGGVCTVFVACVGFYVLPDFPSNTRYLSEKEIAVAQLRMIANGVQDDESDYGRWRGLVMAVRCWQVWVFAGMFLLLAIGASVHNFFPSVVNTLGFSRNTTLWMTAPPYLIGVVVTIANSLCADRHRNACPHVVAPAALAMLGFLLFLLDQSSTRSGVWVRYAAAFLMIVGAHSGYPVVLSWAQKTIRGPKEMRACAIAIINTSGSISQLSMALIYVFTDRHIRTVSKPMGTEVYTVDVLEYHLRAGSDFTCDLHAPSNPCLKLRCDAKSVGCFDEISNWRANPLLISFPVF
->tr|A0A193ATP2|A0A193ATP2_9INFA Nucleoprotein OS=Influenza A virus (A/South Dakota/20/2016(H3N2)) OX=1866071 GN=NP PE=3 SV=1
-MASQGTKRSYEQMETDGDRQNATEIRASVGKMIDGIGRFYIQMCTELKLSDHEGRLIQNSLTIEKMVLSAFDERRNKYLEEHPSAGKDPKKTGGPIYRRIDGKWMRELVLYDKEEIRRIWRQANNGEDATSGLTHIMIWHSNLNDATYQRTRALVRTGMDPRMCSLMQGSTLPRRSGAAGAAVKGIGTMVMELIRMVKRGINDRNFWRGENGRKTRSAYERMCNILKGKFQTAAQRAMVDQVRESRNPGNAEIEDLIFLARSALILRGSVAHKSCLPACAYGPAVSSGYDFEKEGYSLVGIDPFKLLQNSQIYSLIRPNENPAHKSQLVWMACHSAAFEDLRLLSFIRGTKVSPRGKLSTRGVQIASNENMDNMGSSTLELRSGYWAIRTRSGGNTNQQRASAGQTSVQPTFSVQRNLPFEKSTIMAAFTGNTEGRTSDMRAEIIRMMEGAKPEEVSFRGRGVFELSDEKATNPIVPSFDMSNEGSYFFGDNAEEYDN
->tr|A0A270NRH6|A0A270NRH6_STEMA Uncharacterized protein OS=Stenotrophomonas maltophilia OX=40324 GN=CEK00_00720 PE=4 SV=1
-MLLVLLAPLVSRWLAQGHVAAAAPVAAMDHAMHAEHAQHAMEGHHDHHAMAMPHGETAKKPPADPHADHEMGVDCDYCLIAARLITLLVAAVLLLAPMVPVCRALRGAVQALPQRIGGTLGARGPPALMAA
->tr|A0A0S2CGT9|A0A0S2CGT9_9AGAR DNA replication licensing factor MCM7 (Fragment) OS=Hebeloma hiemale OX=91672 GN=MCM PE=3 SV=1
-LLQVNAYTCDVCGSETFQDISNKTFSPILDCQNENECKKNGIHGSLHMQTRACRFSPFQEVKIQEMPDQVPVGHIPRSMTVHVNGNLTRLMNPGDIVHIGGIFLPIPYTGFQAIRAGLLTDTYLEAHHIDQLKKQYSEMELTPEIEXKIAALQKDPNLYEMLASSIAPEIYGHEDVKKALLLLLVGGVTKVTGDGMKIR
->tr|A0A1S3XHK0|A0A1S3XHK0_TOBAC Chlorophyll a-b binding protein, chloroplastic OS=Nicotiana tabacum OX=4097 GN=LOC107765079 PE=3 SV=1
-MASMASMAATGSSATVVRATPFLGQTKYANPLRDVVPMGSAKFTMSNELWYGPDCVKYLGPFSAQTPSYLTGEFPGDYGWDTASLLADPEAFAKNRALEVIHGRWAMLGALGCITPEVLEKWVKVDFKEPVWFKAGAQIFSEGGLDYLGNPNLVHAQSILAVLGFQVVLMGLVEGFRINGLPGVGDGNNLYPGGQYFDPLDLADDPTTFAELKVKEIKNGRLAMFSMFGFFVQAIVTGKGPLENLLDHLDNPVANNAWLYATKFVPGS
->tr|T1TFT7|T1TFT7_HHV2 Helicase-primase primase subunit (Fragment) OS=Human herpesvirus 2 OX=10310 PE=4 SV=1
-ADPRRFHFHAPPMFSAAPREIRVLHSLGGDYVSFFEKKASRNALEHFGRRETLTEVLGRYDVRPDA
->tr|A0A7M4AVR9|A0A7M4AVR9_9ARCH RRM domain-containing protein OS=Candidatus Poseidoniales archaeon OX=2163009 GN=D7I13_00030 PE=4 SV=1
-FTATQDQLNALVASHATVNEVILAMGPGGKPKGFGFVFIAEKDKGEAVVAALNNSDFEGRNIKVDIAKAKGGKGGGRGGNAGGNNSGKSARELQALREEGEGGKKRKRRQRQKKD
->tr|A0A2G4HE61|A0A2G4HE61_9FLAO Phosphoserine aminotransferase OS=Flavobacteriales bacterium OX=2021391 GN=serC PE=3 SV=1
-MKKHNFTAGPCILAPEVLEGAAAAVQDFEGMGLSLLEISHRDKKVVAVMEEAQQRVLQTLGLGDDYAVLFLQGGASSQFAMVPFNLLRSEGKAAYLNTGTWASKALEEANKLAPGQAVELASSAEQNFSYIPKGFAIPSGLDYVHYTSNNTIFGTQMKAFPKADSLMVCDMSSDIFSRQLPFGQFDLIYAGAQKNLGPAGATLVVVRKEILGKSGRAIPTMFDYPVHIKGESMYNTPPVFSLFVSLLTLRWMDSQGGLLEMERRANARSAALYGEIDRNPLFKGSAAAEDRSPMNACFLLHDEAKYQAVFDALAKEAGLVGLPGHRSVGGYRASMYNALPQTSVDALVEVMREVERRA
->tr|A0A737VAW6|A0A737VAW6_SALET Putative transport protein YbjL OS=Salmonella enterica subsp. enterica serovar Sendai OX=363568 GN=ybjL PE=3 SV=1
-MNINVADLLNGNYILLLFVVLALGLCLGKLRLGSVQLGNSIGVLVVSLLLGQQHFSINTDALNLGFMLFIFCVGVEAGPNFFSIFFRDGKNYLMLALVMVGSALLIALGLGKLFGWDIGLTAGMLAGSMTSTPVLVGAGDTLRHSGIASTQLSSALDNLSLGYALTYLIGLVSLIVGARYLPKLQHQDLQTSAQQIARERGLDTDANRKVYLPVIRAYRVGPELVAWTDGKNLRELGIYRQTGCYIERIRRNGILANPDGDAVLQMGDEIALVGYPDAHARLDPSFRNGKEVFDRDLLDMRIVTEEIVVKNHNAVGRRLAQLKLTDHGCFLNRVIRSQIEMPIDDNVVLNKGDVLQVSGDARRVKTIADRIGFISIHSQVTDLLAFCAFFIIGLMIGMITFQFSNFSFGIGNAAGLLFAGIMLGFLRANHPTFGYIPQGALNMVKEFGLMVFMAGVGLSAGSGISNGLGAVGGQMLIAGLVVSLVPVVICFLFGAYVLRMNRALLFGAMMGARTCAPAMEIISDTARSNIPALGYAGTYAIANVLLTLAGTLIVIIWPGLG
->tr|A0A195DVT9|A0A195DVT9_9HYME Uncharacterized protein (Fragment) OS=Trachymyrmex cornetzi OX=471704 GN=ALC57_10841 PE=4 SV=1
-EGSRYDSHSAQSTQDRRKLLKRTRSLAVISEDDSRQDREAANFRLGQSTFDLPRRHQLIPRAKLIDRNSLKDRFILLTFYKRFKVIQMQILFKSNRSRGSLCSRLSKSQQHLSDSYERFNEAKSYHSRSTCGLYSISSGLESLPDPLSYTRKNRIDPDRLNILDWPDPPRRYRSVQNLDTVSGLVDIVEDNWPIEGNRSIDCIYTQFARYNDVSCLRSAVLGLLNILAGLRSLLPTLVKRKRKEHRSLDSILFEDDGELEYFDVLNLLPLSNIRLEYNETDLSSDSNFARKKIHGLRDLRVLEYNEPNEVSPTRSSNATDEEKCKEHEVNDESEKELRENLNSEGTSKRTDSNRRQHRETDESFGADSKINSVNQFTDQYSPSSSKIDHRRTDVENFVISCEEEDQKFEEIEDYKSIWISDENQNKMSRRPQVLKVVDNDVTRRRHRRSVVEIDAIVEDVPKDKRSQEITEEVNERLNASIITSINNVNEKDEGHGRKAKEATTPENAENGATVDDARNFLERKSTEKEAVRNKQNEGRFERIVKETSNILGKACSVVKGSLGFEARSESSDLGLGSESGSDSRRRSMDDGIEDDRPSKKVENSNNSATLRTDDSKKSHTNLTRSRSCVDSIECQDDGQEFDHVRYKIVKSHMFSKNMFNTARGDVTYEGLMQYLREYSFQELLMDNNVVIIEPVRAETIERKSSPLTRTEPKCKIAGAIQKKTENHERNGERSQSGGTAKSSRQSSIKKHFFYQPIRVNRELIDEELPDPDTVRNVRRMFENTLEKKKISDAEFSRDDKTRRSVSMKDLTTIDDNRYDEISDKTREESRSRCSSRAKDLTRLFETKSASSTISIAKEEIGSPRCESKTRILAQSFEARSGNTSPSGSNCSKNKIGRYHHHHHHHHHHHHQNWDSGSVSSGVSSDYPDTDPGSGAHCTSSDDEDVNCNDDDADTRGPGHYVSQDVLRKIRECGTSVTYYGGKVVNMHNGPLVSPLIGNGFKRIDESNDYVKFKLVKSNSCDSRLELTGRFVEGQSLRRTRDRCADLRQCTIAETPSIEITSIDSRQKDEVQRDEDVEQIEQMKREPPVVIGLEPKKEDSKESRKIFKADFKLGDLDDSRSNYPSKFMPSALTRWEVNSSWKVGNDFGKMEFEEFEVLEDSLNGISEQNKYTQAS
->tr|A0A7K9E8D5|A0A7K9E8D5_BARMA Beta-MPP (Fragment) OS=Baryphthengus martii OX=176943 GN=Pmpcb PE=3 SV=1
-QCVHAGTGRLRASRAATEVVLNVPETRVSPLENGLQVASEDSGLSTCTVGLWIDAGSRYENEKNNGTAHFLEHMAFKGTKKRSQLDLELEIENMGAHLNAYTSREQTVYYAKAFSKDLPRAVEILADIIQNSTLGEAEIERERGVILREMQEVETNLQEVVFDYLHATAYQKTALGRTILGPTENIKSINRNDLVEYITTHYKGPRMVLAAAGGVPHDELLDLAKCHFGNLPSAPEGGLPPLPPCSFTGSEIRIRDDKMPLAHIAIAVEAAGWSHPDTIPLMVANTLIGNWDRSFGGGVNLSSKLAQIACHGNLCHSFQSFNTCYTDTGLWGLYMVCEPSTVQDMVHFVQREWIRLCTSVTENEVARAKNLLKTNMLLQLDGSTPICEDIGRQMLCYKRRIPIPELEARIEAIDAQTIREVCTKYIYDKHPAVAAVGPIEQLPEYNKICSGMYWLRE
->tr|A0A498AHI4|A0A498AHI4_9ACTN Phosphoglucose isomerase-like protein OS=Micromonospora sp. M71_S20 OX=592872 GN=DER29_1292 PE=3 SV=1
-MIDGAAGVSGRREPDEALLDDPAALAEHDPGGMLRHTASAGAQVRETAALAAEANLQVLADEGRPRAVVIAGIGTAGRTGDVLATVAGPRCPVPVIPHRSAGVPGWVGAADVVIAVSASGRSPEALGAAEAAHRRGARLVAVGAPDSQLQSVAERARAPFIPVPRRAPARASLWALTVPVLLAARTLGLVKVNEADLAETAARLDAEADRCRPTAESFVNPAKSLALGLAGSVPIVWGSSPLATVAARRFGDTLSANARYPVVSGALGEAGRGRVGLLDGVFGGLAEGERDIFADPDAEAPSGTRLRLVLLRDGGLNPEDDADEPLDVEERRADAVQTLAERRGVRCDVVTAEGGSALERLASLVAVPDFASIYLALAHGLDPMAVPAITEMKELANQ
->tr|A0A3D8YU66|A0A3D8YU66_9BACL HTH domain-containing protein OS=Sporosarcina sp. BI001-red OX=2282866 GN=DVB69_12070 PE=4 SV=1
-MRTKVAIFGSEEFCQRALQFTEQRSDIILDLYPYTIPSEAPDLLKKLLPCDAILFSGSLPYVASTDVLQSIPVPAIYLKQDETEITTTLLAISIHHSLELEKMSIDVRDCSVLENVLADIKADEQRPLTYQLEKNYVLEEVVQFHASAYANSPSNVAVTSVHAVYDRLTEQGIPVFKMISVKSSFLKTIDRVCQEALLQKSETSKIAAGILDNSILTTEVKDIYKRLAQVLHAHCIHSEEGFLFYTTQGAIQSALHTPLFQQLAVQVSGQLAFGSGRTLTAAKENAVSALRYMQTEHNAGPYLLDEKKELHNLIQTNGSAIELRVIEPILTEIAEKTALSPAVLSKLVTFGQSQQSTQFTANDLASHLGVSRRTAERTIKKLLTSEYVNTVGEEMTYRQGRPRAVYELNFPVY
->tr|G9Q7I1|G9Q7I1_9BACI Uncharacterized protein OS=Bacillus sp. 7_6_55CFAA_CT2 OX=665957 GN=HMPREF1014_02623 PE=4 SV=1
-MIDKIKNAVEDMYEDEAKDLLQSILIQLNLLEENYSEDTIKNLMDIPKQLTSNPTYKRNVKESAHVHIAFDDSTAGCLKYMLSQEELFEESVVAFSEFFSIGPIYRLHTNEGQLARQKWLINNLTAYDSYFEEEYLSRFIATIEELHTIPVETPITIWKADNAHEHVGLSFVMAQLKDKKNIRVINTSEASREILKQEYDIRGTGELPPESLALFQKSFIKLPYLTEEKRMKFENEWDRLSESIECLRVWKENEVHSVQEDYFDQFIIECAKSVGADREFLKAPRVIGEALGLVEQLVGDTFLEYRLKQLIKQEVFEFEGSLDEMRFYSVKLRK
->tr|A0A5N7CTG2|A0A5N7CTG2_9EURO Uncharacterized protein OS=Aspergillus pseudonomiae OX=1506151 GN=BDV37DRAFT_266922 PE=4 SV=1
-MYLSVLSFVDSDSLTSKQQQHYALALYFDWKCAITGKIYQSHSDQTFHAVSKGKFYRAVMARFLDTKMLQFATLCQDLESFDWLTTTTSKMWSDNPNRTLEESFQILEAFDFISNFMLLHILEGPGTFADWVISSDEHQAFTQDPNDSFLNNWISLLRRLQPYLSPFDILVAFRMDEIDLQTLQYFNSLLSLEEYDLKSPIYEIEKEVCCKLSEEYDVADHVWKMYRNHGWRNGARGTSFNEHLSVGAIASEIIGFECHRRNWWELMKQSSKASPYGVRFSLPSCYLSTFNERMDEDEDIHFIITKDDLLTLNH
->tr|A0A210QLV9|A0A210QLV9_MIZYE Uncharacterized protein OS=Mizuhopecten yessoensis OX=6573 GN=KP79_PYT04528 PE=4 SV=1
-MVGQRGNRGGGRGGGAWGDDSQDMGAMGGSMLGGYGTQSDTSMYAQGGKKRSYNDSQDGYSMPNYYDSTSTDPYFRGMDPPASRFVKTESTQQPDQYASYYENWDSGYYNQGNDSQSSYSDYGSSPQQSGGGYNQSSDFSQDVDFPSNNTSGFNKGYNKNQQSWNKRGGGGGGGGGRGGRGQQQQQQQPWGRGGQGMRGGGRGNNRGNQGGGMMGKRGQQKPGFPPQKAFPGPMRGNKRGRGGRGGNAMVPPIHSLAKVSVPDVTKMSIAEKIRRFCLYLQAETNKVNSIQTIENALTGSKLGLKTEYEVEELMRVAGRWMYTGYLKLDSIFLTRSVGANKKEVKHDVYTKGLDIVKTKTVAEIFALKDPGVEAIRSELTNSLEVKKEGLGKTESLQVAKQAMEEMTNTYSTKHDGFDKLMTYLRESTNLPESQISCIEQGISASHCGLTHTFDGQMVRLPTGKLFFRGSLTIAEVVVAVGTGYKKKDAKVQTYERALEALRTKTMAQILKSVPEAEAVTGVVQEKVPTVPEKDRSSQTLLEKMTEITQLIKEAQFRENNINYLDVTAIHLGFTPTCIYRKLESEGNKTMIACELYLDSILMATGEAERRKDAQVETYNSAWDVLCTTAPDYILKEHKRLKPGDQDDPSVMDVWVKGSGKPNANTNMPGLKRNKMDPNEAWKTVDVIVLMEHEDWSFDRQRQAFCILNYSSTFNGMLLQWQTEHDGNMFKSTINLQHKMIGEASALGKNTSRNLAAACALFKLYETQHVIRISRRDDTKLWVEYPEIKTKAEALRVASGAPMEEVVATPTPADGEEKPSIPANKWVVQVAEQMITQHIAKQTLDELTFGPGMPFSESKEVRQIARNLDLKHDIRQQEGQSYLIIHKRMTPQEMIKILQANNSQSGKYSLVDKDTLPTYQNILPEIEKHEAMRNTGNTEGASKKKIKKEDISMTDLS
->tr|A0A7Y7LU15|A0A7Y7LU15_9BURK DNA-binding transcriptional LysR family regulator OS=Variovorax sp. SG517 OX=2587117 GN=FHT32_002399 PE=3 SV=1
-MDSEALATFLTVHRQGGVSAAATALSRTQSAISRRLALLEEELDAPLFERVGRGLRLSQAGEALLPHAEKVAAAMGDAVAAVQAAKSDAAGTVHIAAVGTLASSGLATVLAKLRQSLPGLDVRLQTATSAEVSEKVRASDVAVGLRYYEDPSPDLLCKVIHHEQLVVACAPSHPLAGTRLKSLVRLSKERWLAFPQPPRRTEPHAEAIFSQFLVRGVERIDWSAVDSLTAQKRLVEAGFGLAFLQESGIAEEVARGSLALIRIDDLDVRVPVACVVRRSAFLSRATRALLAELERAEL
->tr|A0A2A7QG65|A0A2A7QG65_9LACO ClC family H(+)/Cl(-) exchange transporter OS=Lactobacillus sp. UMNPBX18 OX=2042029 GN=CP369_02605 PE=4 SV=1
-MESRKEVFHRYNQFNQLIRAIIIGILTGLVVSVFRLIIQHFLQLVTASFAYFHSHPLWLIPWTIGSIILALLLGWLAQSYHDIKGSGIPQVEGQLTNQFDEKWWPVLWRKFLGGIFAIGSGLYLGREGPSIQLGATIGQGVEEKAKVGHLNRQIGIASGAAAGLSAAFNAPIAATIFILEEVYHNFSPVIWLATFVSSLCSNIISMQFFGLRPVLNVPYNHMLPNNLYWHLIALGILLGILGRLYQIVILHLNGWTARIPKLSPIAYPIIPFLLVIPIAWYFPITLGGGNELIIILRSLPFSLALFVGLFVLRFVFSMISYGSQLPGGIFLPILTLGAILGAVYCALMVRLGLMPVRYLPNFIIYGMAGYFACISKAPFTAILLITEMVGSLAHLMPLALVAVVAYLVVDALHGEPVYTAMFNAFIGNNPQPARHKEDVTMSITIYAGAQLDGCKIKDFPWPTDCIVMVVYRGEEKIIPNGQTKLQAGDTLILRANSATTRQAYHEISRAAHYAQG
->tr|A0A0R2BHK3|A0A0R2BHK3_9LACO Uncharacterized protein OS=Lapidilactobacillus dextrinicus DSM 20335 OX=1423738 GN=FC84_GL001267 PE=4 SV=1
-MRIIFIGDVMGPIGQETLTTYLPKLKAKYRPQLTIVNGENIAMGKGITKSLYKTILTAGADVVTMGNHTFDKDDIYEFIDDANKLIRPANFPAQHTPGKGYVLTKVNQTTVGVINLQGRVFLDSIDDPFAKVDEILAEIQAQCDYIFLDFHAETTSEKEAMGYYVDGRVTAVVGTHTHVQTNDAKILPKGTAYLTDVGMTGPYDEILGMRKERVIERFLNHRPVRFETPLSGRGQLNGCVIDFSSTKNAARKIELIQITPDQPFLE
->tr|T1BH73|T1BH73_9ZZZZ Translocation protein TolB (Fragment) OS=mine drainage metagenome OX=410659 GN=B1A_07070 PE=4 SV=1
-NSDSSINYDGSQIAMMQGNGNVYRIAIMDRKLDNQTRFISPGPMDGSPSYAPNGSMLLYAATDNNGKGVLYEVADNGSVRQRLSLVNGTVQSPSWGPYRVPPSTQP
->tr|A0A7W7F9L6|A0A7W7F9L6_9SPHN Spermidine synthase OS=Sphingosinicella soli OX=333708 GN=GGQ98_002410 PE=4 SV=1
-MLPRVLIDTAKIPGGGELRLIQRGTEFSIMLGANELMNSRLKGSEESLASLSCGKIQSRPQPRMLIGGLGMGFTLRAALAKLPADASVTVAEFVPSVVAWARGPMAHIFDGCLDDPRATVAVEDVADLIGDVRSHYDAILLDVDNGPDGLTHPDNDRLYSRKGLIAAREALRPGGILAVWSAAPDHAFKNRLIKVNFEVEETVVRTNGERRGARHIIWIATRPS
->tr|A0A1H5CGP3|A0A1H5CGP3_9MICO Peptidoglycan/LPS O-acetylase OafA/YrhL, contains acyltransferase and SGNH-hydrolase domains OS=Ruania alba OX=648782 GN=SAMN04488554_0368 PE=4 SV=1
-MVSTATQDRGRIEGLDGVRALAIVAVLIFHLRPLSLPGGYLGVDVFFVVSGFLITTLLVRELRANRELDLTAFWTRRARRLLPALATVVAASVALAFFAGDDLLVNIGRQVVGALTFSNNWLEISAGSSYFNATSPQLFVNFWSLAVEEQFYLLWPLLFVLIMATTRTGRQRVGVVLGLAAASALLMALLYTPGEDATRVYYGTDTHAFGLMIGAALALSAAGESWNLLAQTWYRRARVLLALGALGGLVALMLVLDPTQPMAYRGGILAASLLTALVLGALPGPTNLLHLIFRLRPVAWIGERSYGIYLWHWPVILLIAAFAPPTAPDSVASWVQRGAALVLTLAVSAASYRWIEMPVRRDGFRATGRRVLAALTAPGGLTPPRVAFLSTTAVLALFAVAVATAPDRSQVQIAMDEASGVVEASGGESGSVAGSTESPQTGSGETDGESSETDGGQTVDGAAEGPGAQISGFGDSMMYVAAPGLSATFPGMSIDAESNRQWPAVAETVAAALDEGTVRDVVVIAAGTNAGVREPEIVRETLDLLGPDREVVLVNIYGSSFWVEESNENLAEIAADYPNVVIADWHQAALDHPEDLQPDRIHPDMEGMYLYADIVQAALEELGVG
->tr|A0A5I0WZT4|A0A5I0WZT4_SALET Type II toxin-antitoxin system RelE/ParE family toxin OS=Salmonella enterica subsp. enterica serovar Oslo OX=1005394 GN=G4H23_002326 PE=4 SV=1
-MRIFKTRWFNREAKSHTIKDDELSEAINAVLQGKADNLGGGVYKKRLNQNRDRAIVLAKGGEHWFYTFLYAKQDMANISYRELAGFRELAKHYACLTEDQITALINNKELVEVRHVSKN
->tr|A0A2S8FEH7|A0A2S8FEH7_9BACT Uncharacterized protein OS=Blastopirellula marina OX=124 GN=C5Y96_14010 PE=4 SV=1
-MPLLVSGICLLVPSLLAAAPQADFEKILSPILEDAVRRSLPTSFKDESDWGSTHEFTKRLKVRGKWDSLKLERVREAKNHGDWVRYLGHIEDPNQHVRIWIENLSVGPTRSTCQIHARVEFQGEAEYQQWVRGVRLLGVSVVTEATVKIHLDVQLDSKWDMSSLVTSAELTPTVTGGQIELERFYVHRIGKAHGEVAEQIGEQLEGTLAKKLAKKEEKLVREANKAIAKELENGTVKLDLVDYLKKQLLK
->tr|A0A069RH84|A0A069RH84_PEPLI Putative transposase InsK for insertion sequence element IS150 OS=Peptoclostridium litorale DSM 5388 OX=1121324 GN=insK PE=4 SV=1
-MICETLSITRSAYYKYKKRVKPEKEKQDELLCSLILEYHAMYDGILGYRRITMFINRLNQTTYSENYVHRLMSYLGITARIRKKKVNRKRVKPDYVKDNILARDFTAKTPNEKWLTDVTEFSIPKDSRKLYLSPIMDLYDNSIIEYEFSFRNSNQLVFKMFDRAVANNPGARPIFHSDRGFSYTNNAFKSKIKNAGMIQSMSRVGKCIDNGPMEGFFGILKSEMFYGKIFKSLDDLVDKIKEYIVFYNERRFQKRLKCLAPIEYRNKALIA
->tr|Q1ZM26|Q1ZM26_PHOAS Uncharacterized protein OS=Photobacterium angustum (strain S14 / CCUG 15956) OX=314292 GN=VAS14_08110 PE=4 SV=1
-MTLIERLKDEQKAAMKAKDKPRLGAIRLVLAAIKQREVDEKITLNDDDVLVVLTKMVKQRRDSVAQYEAAGRQDLADVEHAEISVLAEFMPQPLTEEEISALMDEAIAATGAATMQDMGKVMGVLKPQIQGRADMGIVSKLVKTKLG
->tr|A0A1C1VV15|A0A1C1VV15_9PSED Phosphatidylethanolamine-binding protein OS=Pseudomonas sp. S3E12 OX=1873126 GN=BB029_27630 PE=4 SV=1
-MNIRSILPALSMAVTLSGYAADFSLTSRDIADNRPLTRREVFQGFGCDGGNTSPELSWKNAPAGTKSYAITVYDPDAPTGSGWWHWTVVNLPASTHSLPSGVGANLPAGAVQGRTDYGQPGFGGACPPVGDKPHRYQFTVWALKVDKLPLDNQASGALVGYMLNANVLAKATITSTYGR
->tr|A0A161XBG4|A0A161XBG4_9CELL Histidine kinase OS=Oerskovia enterophila OX=43678 GN=arlS PE=4 SV=1
-MRRRVLQATVAAVAVAVLLLGFPLAFLGAQFVLANEMDQLQGRVDTLARNIDNRLAQNEPIPQSVLDNASVGRPGELPAYVFVNLPDGEQMTAGEVVTGRANEAADRTDQNATVALSTSFAESYWKAAQIVLLVVAASVVAFAAGIAMAVWQANRLSAPLVYLAASAEQLGSGQVRPRLEPSGVEEIDLVAAELARSSDRLAGRLAAERQFASDASHQLRTPLTALSMRLEEISMASDDPAVQEEARISLEQVERLVTVVDDLLTQSRRAQGGTTEAVRLIEVVRQQEEEWVPTFAQAGRELVIDVPEGYQVLATPGALAQVLATLIENSLKHGAGTTTVRARPSGTSGAVAVEVGDEGEGVSDEMAPRVFERGATSGAGTGLGLALARDLAAADGGRLELAQRRPPIFALFLAGVPRTLDPRVVLPTGTLISARGGRRRRRGRGPEVEPR
->tr|A0A0D0Y6D7|A0A0D0Y6D7_9TREE Small nuclear ribonucleoprotein Sm D1 OS=Cryptococcus gattii EJB2 OX=1296103 GN=I306_06210 PE=3 SV=1
-MKLNNETVTIELKNGTVIHGTITSVDPQMNTHLKSVKLTLRSQPSSQPPLSLDSIAIRGNNIRYFILPDSLPLDTLLVDDAPKPKKKKEGAAARGARGAARGARGARGGGRGAPRPRGRGF
->tr|D0TP63|D0TP63_9BACE 4Fe-4S binding domain protein OS=Bacteroides sp. 2_1_22 OX=469588 GN=HMPREF0102_01363 PE=4 SV=1
-MNVAELDIDKCSGCGLCASVCSKHSISIVPDDSGFLRPIVDKNTCVDCGLCVKRCVIVNPRKQTIPQKTYAAIRQDKDRIALSSSGGVFAAVAEYVLLKKTNWVVVGSTLDETVSANHIIVDNVVDLKNLYGSKYVQSETTGIYKKIQILLDDSKSVLFSGTPCQVAAIQRYTNNHPNLWTIEVICHGVSNNKMFNSYLDMYKRNEIRMFYFRDKEQGWSFNNKIVYQNGKEKKINHRMSSYMTYFLKGETYRDCCYCCPYAKPERCADITIGDFWGILQTRPDLNNKIDIEKGVSCVLVNTDKGISMVGNAELELYDVEYDAIRKENGPVNEPSHHTVKRDLVLAEWGKKKDWTDVHTFWKKNDRKITFVLWSMIPVSLQHKIRVMLGKR
->tr|A0A2A2CDI5|A0A2A2CDI5_ECOLX Spermidine/putrescine import ATP-binding protein PotA OS=Escherichia coli OX=562 GN=potG PE=3 SV=1
-MNDAIPRPQAKTRKALTPLLEIRNLTKSYDGQHAVDDVSLTIYKGEIFALLGASGCGKSTLLRMLAGFEQPSAGQIMLDGVDLSQVPPYLRPINMMFQSYALFPHMTVEQNIAFGLKQDKLPKAEIVSRVNEMLGLVHMQEFAKRKPHQLSGGQRQRVALARSLAKRPKLLLLDEPMGALDKKLRDRMQLEVVDILERVGVTCVMVTHDQEEAMTMAGRIAIMNRGKFVQIGEPEEIYEHPTTRYSAEFIGSVNVFEGVLKERQEDGLVLDSPGLVHPLKVDADASVVDNVPVHVALRPEKIMLCEEPPANGCNFAVGEVIHIAYLGDLSVYHVRLKSGQMISAQLQNAHRHRKGLPTWGDEVRLCWEVDSCVVLTV
->tr|A0A168G2W8|A0A168G2W8_CORDF Sulf_transp domain-containing protein OS=Akanthomyces lecanii RCEF 1005 OX=1081108 GN=LEL_05631 PE=4 SV=1
-MATVLSGAAFGAAMIAAGFYNPAVVISQLKFENWHMVQAFLAATASSIAYYAISDRAGYASLQPRASSPIGLFGSTYDGNVLGGALLGAGMALSGSCPGTLFAQMAAGVHTGFYALAGAVVGGVLWTGILSKAVARARARAGSKPETVTVNQHLGVSKPAAMLLYEAGFAAVIIVTSLYTPRFPGTKMSGALGGFLISLSQLASIATRGSMIGISGSYGELGGLLWAGLAGDAASKPKSYPNVLFAVSAGAGALLLARLAPVLVEAPALEVAPAVAVLGGALMVVGARMAGGCTSGHGISGISLLSTSSLITIATTFAVGFVVATLVY
->tr|A0A3N2RNP2|A0A3N2RNP2_9ENTR Uncharacterized protein OS=Kluyvera ascorbata OX=51288 GN=EB837_25720 PE=4 SV=1
-MSEPRLGNLITVLLPARSYKINCALTTEKLMPGIEQFACRLLLIFDQLYPSELQNYFGLTDREREVLLDGLLANRLININPDGHIEASSFLRKHAASNGGKPSLVKYQERTEEVAFDLLTLSICKPQPNRRFTSGLPELLPRHQIGGDAAAVTEAFSSQFRHHLLLSRNSEYERQRTRLYKIMGCSSHEMVQLPIEIEVSYDASAGSIEPQKFTRSYEYLGNTRLPLSNELEAHIADFLGEHKLDEFGIDCEDFCKLANDKVLLQFANGYKFDYSGWIEAREQRKTGYGTSLTTGMLGAVYLPHNSKLFISMLHNALRDYVGKTAPKALWYSSKVPLWGANGSQLSRFNRDLGDILGNYADDKIARISLLHPSADEGEKRQERKRHLGRFPTGIGLTSEAKFDRLEILLIPDVIALVQYHGQPNSDSALTLPIGYITVEPERLELLKNLMIKRIEGVVATINWSESKLENLTSLLPVEFLIKLNKKSGEDVDAAIQKMQIANRAETARAILSLRK
->tr|A0A1A7ZNK3|A0A1A7ZNK3_NOTFU HFM1, ATP-dependent DNA helicase homolog (Fragment) OS=Nothobranchius furzeri OX=105023 GN=HFM1 PE=4 SV=1
-DTAVKTTCPVYKHARAGQHGTCVLTWYLPGHFNHWTTKANTTADLPKTLHVVLEQILNRHPPFGNQIRDSVRHLPKYSVTLEQLPRFGSDTAEVVARVNLKNQADLLSRRTAPGHHFVSLIIGDADNNVAFLQKITDSMLLKSGSWSKKIQVAKPVKGNEISVHLISSDYVGLDIQQRFTMQFSASRTFGSEIPYNTIEQRPQLTAQTPLSAAQRDKASPAEEQGSTYPGHKRQCNHLCKNKTLCAHDCCKVGVAVGRKRSTNHESSFSSYLTDLRNRSDALVQTPVKRLKMGNGPLAVSMQRFAFKPKENLSPVSCYSENEYKAGQMDLAADDSSQLKDISCLNDPDPGTFSDADGAENRTRTTQNPAATQQMFLKDSSARIMSRTGGEPLKSGVNQTKTSTSVHSNWSAATSEQEALQIPAVTFDLGNEWDDWEDFDEENLLHTAAALVPQCRTKPEPQIQQRVDYTSGCPTGSSPVFLSCSQTKCQGTTITTPLRSISAAASCEIRKFDPSPITNILNDEITGKTPEMFFKPPPETQVNRRCDFFHTVDVPLRSDLSLDRSKEEETFFGIFDGIF
->tr|A0A7C6JKA3|A0A7C6JKA3_9BACT 3-isopropylmalate dehydratase small subunit OS=Petrimonas sp. OX=2023866 GN=leuD PE=3 SV=1
-MEKFTTITSTCVPLPIENVDTDQIIPARFLKATTREGFGDNLFADWRYDKAGNPKGDFVLNNPTYKGEVLVAGKNFGSGSSREHAAWAIGGYGFKVVVSSFFADIFRHNALNNGILPVAVSEEFLGELFVSVKGNSKATVTVNLQEQTITNNETGKSESFNINAYKKECLLNGLDDIDFLLSNRDKIEAFEKQRVYSY
->tr|A0A7X6IU76|A0A7X6IU76_9PSED EscU/YscU/HrcU family type III secretion system export apparatus switch protein (Fragment) OS=Pseudomonas sp. BG5 OX=2722817 GN=HER21_45805 PE=4 SV=1
-GLMRVFGKQALWEGAKALLKTVAIGVALWIVVSGLVPVLMASGSHNITWLLEQAAGGAAALLQVAVVVGIILAALDVAVVMRRNRKHT
->tr|A0A7Z1UA43|A0A7Z1UA43_9GAMM Methyl-accepting chemotaxis protein-2 (Aspartate sensor receptor) OS=Erwinia sp. AG740 OX=2183904 GN=DFO54_1118 PE=4 SV=1
-MSVFGRYVRNLKVSHKLYGGFGIVLLLVVLASTFSSARFFAIRDLYIKSSIMNEMGNFIDLTRIARIKFTYTLNDDNLTNLNKYLQQARQLNDKAKALKWDETYQGDFKNVEQDFADYTQNIDRIKSSVEGMNEVTKGISALDQQAAPGDALYTLSNDINLLRQYHQTSVLYGQLVDKVHLLQKENSDAAFKAVKSAYDQAKKSFDSLNSTLPGEVKNSISELGDRIERYNQSGVKYNDKVNQLKASDSALRATGDKLISDIDGVLKKIGARNNDIINNSVFQTVICGITAVILGLLIAWSVTRQITRPVIANLKLAEKIASGDLSASVTVERHDELGQLTLAMMSMTEKLRQLIADIRHSVYSVAKASSEIAAGNHDLSSRTEQQSSAIVETAASMEQLTATVKNNADNARHASQISEQATDNANRGGDIIHRVVQTMGEISGSSKKISDITSVINSIAFQTNILALNAAVEAARAGEQGRGFAVVAGEVRNLAQRSSQAAKEIEGLISESVSRVNTGTVLVSDAGSAMDDIVASVKRVHDIMGEIASASDEQSRGIAQIGGAVSEMDSTIQQNAAMVHESSAAANSLEDEAARLSQLVSVFRLSAQDEPQTSGHTAMLASRLRRPEIANRQAALPGSNTTPGTIANTSADNWTTF
->tr|A0A810LQW6|A0A810LQW6_9ACTN Uncharacterized protein OS=Actinoplanes ianthinogenes OX=122358 GN=Aiant_38990 PE=4 SV=1
-MAGASDNGGWPPPDGGSSDDLPDLPEEWGVIVIPDDLSELSDEVEAVRAELHLAPPPNRWQRFARRPAVRRLRRAGALLLRAPVLIVSMAILVTVASLFASAWPGTPRQPATQRTSDTTTTPAKTLPALDLIGADGQAVPLLAHRPMVVIITDGCDCERLIAETVAAVRQDVSVLAVSTTAPSATASQGGLAPAQTPRADGKTVLYLQDPTGHLRERAGLTSARDGSAATFVVNKAGDVLRVCQHVVSVAAFEADLARI
->tr|A0A6B8MQP2|A0A6B8MQP2_KLEOX Helix-turn-helix domain-containing protein OS=Klebsiella oxytoca OX=571 GN=GJ746_00670 PE=4 SV=1
-MDNSINQVIDSFIKGQAVIGRVRFSTESRPASEKAVSVDFPRLEIMLEGQLRDPAIKSEYAQLTPHDVLYIPAGGWNDPQWLMPSTLLTILFDKQQLEFVLCHWDGNALNVLDKQQVPRRGPRVGSFLLQALNEMQMQPQEQHTARCIVTSLLSHCADLLGSQAQTSSRSQALFEAIRKHIDAHFAEPLTRESVAQAFYLSPNYLSHLFQKCGPMGFNEYLNHIRLEQARMMLKGHDMKVKDIAYACGFADSNYFCRLFRKNTERSPSEYRRQYHSQLTEKTSSAKN
->tr|A0A1Q3WCK3|A0A1Q3WCK3_9BACT Ribokinase OS=Spirosoma sp. 48-14 OX=1895854 GN=rbsK PE=3 SV=1
-MPGQILVVGSSNTDMVVQTTKLPAPGETVLGGTFFMNPGGKGANQAVAAARLTGNVTFVAKVGTDIFGEQAVAGFRQEGINTTYIQSDPDHPSGVALINVDAAGENCITVAPGANAQLRPAETNPALMSAEADALVLVQLEIPLDTVVHVISEAATRGLRVILNPAPAQPLPDELFPNLFLITPNETEAELLTGIRVDDLSSAGQAAQKLHAMGVSNVIITLGSKGAYLSTGTQSQLIATPPVKAVDTTAAGDCFNGALAVALAEGQPLPDAITFACKAASISVTRMGAQASMPRRNEVNE
->tr|A0A2D8DNN8|A0A2D8DNN8_9ALTE Uncharacterized protein OS=Marinobacter sp. OX=50741 GN=CMG78_10605 PE=3 SV=1
-MKLAKFIGSALVALTISAPAIAQQSPGGQPDQVAQLAQMVGLSEEQQTEIRGIIDDMQGEIGELRQDARSLQEDLQEQIKPDYDESAIRDNAAKLGDVTGEIAALSALMQAKVDAVFTQEQRDELDRRMKQMQQQMQQQRQMMQPQGQQ
->tr|A0A842MKE0|A0A842MKE0_9ARCH Uncharacterized protein OS=Thermoplasmatales archaeon OX=2268204 GN=H5T45_04690 PE=4 SV=1
-MKKIICLFIFLALMGCLKSEKEVEKETAEGFEVLSVFFSETEDYNTVLLNMKVKWVGKEKGAPRCDIYFPPQERLEMGIGPIENGPSIVEPLYQEGSEVKTAILKEFIARSFYPDYIAPEFGKSYYAQIKFYWPSLNETYEWQGNVGWSE
->tr|A0A7X3C2Y9|A0A7X3C2Y9_9LACO Xylose isomerase OS=Secundilactobacillus folii OX=2678357 GN=xylA PE=3 SV=1
-MAEDLWNMKNIEYAGNKDLGSGAQFHYYNPDEVIGGKKMRDWLRFSVAYWHTFDQRLVDPFGDGTAMRPYDKYTDPMDNALAKVDYAFEFYRKLGVDFLAFHDRDLAPEGDTLRETNKNLDKVVDKIVEYQKTSGMKVLWNTSNLFTNPRFVAGAGTSPYADIFAYSAAQLKHSLEIGKRVGSENYVFWGGREGYESLWNTNMKLEQEHAAKLFHMAKDYANEIGFDAQMLLEPKPKEPTTHQYDFDAATTIAFMKTYGLDKDFKLNLEGNHANLAGHTYQHEIRVAREAGLLGSLDANQGDKLIGWDIDEYPSNLYETTAAMYEVVQEGGIGPRGGLNFDAKPRRSSFEANDLFYGHIVGMDSFAAGLRVALKMKEDGVLDKIVADRYSSYKSGIGADIESGKATFKTLEDYTLDKTQADLRAATSSDHLEQIKDIINHYIVNVLGK
->tr|A0A5N6QTR5|A0A5N6QTR5_9ROSI Uncharacterized protein OS=Carpinus fangiana OX=176857 GN=FH972_006142 PE=3 SV=1
-MGTLVHDAQNVDSDIYLSLGLTELRKGVPAIPRVLSLLSSLLERSVQKNEILLEATQIKDVVTIFHGLRAPTLSIRQYIDRIFKYSGCSPSCFVVAHIYVDRFLQSTEVHLTSLNVHRLLITSLMLAAKFIDDAFFNNAYYAKVGGVSTAELNRLEMKFLFSIDFRLQVTIETFGRYCLQLEKETAEGLQIERPFKACGIKESWSNKDDSSCAPTVAQ
->tr|A0A0D6QGJ2|A0A0D6QGJ2_9DELT Putative ECF RNA polymerase sigma factor SigI OS=Anaeromyxobacter sp. PSR-1 OX=1300915 GN=sigI PE=4 SV=1
-MTDTGETFEAQRPALLALAYRMLGELARAEDVVQEAWIRWQRRPGEVDSPKAFLLTTVARLCLDELGSARARREESRSDRLPEPVELDRAGLGRVELLDRISMAFLVLLQRLTAAERAVLLLHDVFDMTHAEIAARLEKSEPACRQLLRRARENVATERRTLRTSRDEHQRLLAAFMEASARGDQGALLDLLAEDAVLVADAGPGVVRYGRIRNVGRPVVGGLKVAALLASVARQRVGPPLELRERTLNGEPAAVAFEGGRPVSAILLGVAEGKVRHVYLQADPERLRHVGSLD
->tr|A0A178W037|A0A178W037_ARATH (thale cress) hypothetical protein OS=Arabidopsis thaliana OX=3702 GN=AXX17_At2g00490 PE=4 SV=1
-MEACSRKRRRRRAYTTSTTGYAAVFFCGIFVFAQFGISSSALFAPDHYPSLPRKAGHFHEMASFQAPKATVSFTGQRREEENRDEVYKDDKRLVHTGPNPLHN
->tr|A0A1F8I579|A0A1F8I579_9PROT Rhomboid family intramembrane serine protease OS=Caulobacterales bacterium RIFCSPHIGHO2_01_FULL_67_30 OX=1797584 GN=A2795_02220 PE=4 SV=1
-MSDPDGRFAAPPNSEGPKSERLFNAPVAVVLIALSMPVLFFFQRQLPDMGASMAFAPIDLQNGRWGGLFTAMLLHGSWTHALMNAIGALAFGAPVARLFGDRIGPTVFLLFYIGCGVVAALGYGLVHWGSTEAMVGASGAVFGLIGAATRLMGGRGRVLSLFDRRVIGASIAWMAVNAVTGLIGYAPGADGARIAWEAHAFGFIAGLLVIGPLGRAFGKGPLPMGTSARPESDV
->tr|A0A3Q8V945|A0A3Q8V945_9ACTN DUF4132 domain-containing protein OS=Streptomyces sp. WAC 01438 OX=2203204 GN=DLM49_03910 PE=4 SV=1
-MGWLAAGEAYEVALVDGRVVARQATPDAPAGQEHTPRKTLPAEIRDRPEVVELQRFAQWLDRHAAECAAQVTTWMVSSLPVPAGLLARVWPDEAWRTALRDIVVVGDGPDETGFLRDARDTGELSVVNLDGETVRLNLPTVTMPHPVLLPDLEELRVFAAESGMVQGVEQLHRATWRKPEGIAPGTTRVTEFAEAEYRSWFHLTARATSLGYKIAGSAVVDRIRDAGRIVTASVGMSDPYSEEKAWTGHLTWGDADGQGTLPLTEVGPVAWSEGMRMAAALHAGRSEGTEGSR
->tr|A0A7Z7G4Q5|A0A7Z7G4Q5_9BACL Drug resistance transporter, EmrB/QacA subfamily OS=Paenibacillus sp. OK076 OX=1884379 GN=SAMN05518670_2026 PE=3 SV=1
-MSQARLKERDDVKKGPILFVMILGAFLATLNQTVMSVATPELMGDFNISAATAQWFTTGYMLVNGVLIPITAYFMQRFSTRQLFQASMFIFLIGTIISALASNFGTLLTGRMVQAAGAGIIMPLLMHVILTLFSPEKRGAAMGMVGFAIIFAPAIGPTLAGYILEHYTWQTMFYGMIPLTVIVIGFAFVYLKNVSERVKLKFDTLSVLLSTIGFGALLYGFSRAGSLGWSSAEVIICLAAGVVALGLFTWRQLASANPLLDLRAFKYNMFSLTTIINIAITMIMYADMMLLPLYLQNARGYTALESGLLLLPGALVMGFLMPITGRLFDRFGAKWLAIIGMVITIVTTIGFIDLTDSTSYTYLVLMSTGRRIGMALLMMPIQTAGLNQLPPRLGPHGTAISNTVRQVAGAVGTSLLVSVMTSRTTAHVQDMVATGAAKGLTQQQLGMESMIQGINDAYVVIIGIAVVGLLLSFFIKRTKQATEEDSKQPVRQKVSMNTN
->tr|A0A4Y7SBP5|A0A4Y7SBP5_9AGAR Uncharacterized protein OS=Coprinellus micaceus OX=71717 GN=FA13DRAFT_1647367 PE=4 SV=1
-MLGSAKLSRLGGHIAFLGDRFSLVQAARASIEKKAKALYYPVEPPNNEKYNPTRPPKYNLKDLPRRSQAHYWKVIELLNLAKTKTARATISRDSGIVALPACAASPAFLHPSYFPLDPFHLFYENITPFLWDLWTVDSTPGESVHVPSPKIARFGVLVAEAMRTLPPAFCGPVRNPHLKRQSQYKAYEWMALFHWYILPIGLELEFPPALLRNFSYLVEAVEIAMTVQSHSISDLQSLEDLIVDFLLQYEHLYVGDDPEKVQRCRLCIFQLIHVPIHIMWYGSIRLSSQATVERSIGEVGRKITSRKEPFAHLSNIIVEQEIIRVLSLYYPELTHKGATTTNTTRSDTRQKIRISKSENLSEELAHHLSAIFRDPFITWLTHLGQGRNSEGKTSGTLQPTNQHKQMFGEVISFYAITNADNETVEVAVYRPLVDVCQPLKTVIQGRWPSASAKVKIAAVEVESICTVVGIWAAPQSENIYILRKHPGLLMLTPLERGIQEDTERDEMDD
->tr|A0A1B4C1D0|A0A1B4C1D0_9BURK Esterase OS=Burkholderia diffusa OX=488732 GN=WI26_24630 PE=4 SV=1
-MRGSMNLVRAFWLLLLLAAAGPALAFQTRIVAIPSAAMNQTLKATVVLPDDYARPRHGPERSVERFPVVYLLHGSGGDHTDWTANTHIAALADRYRVILVMPDGGHESWYIDSPFDSGSRYETFVGDEVVSYVDMHFRTIATKGARAITGLSMGGFGALRIALDRSDTFGAVGSISGAVDPRCCEDEPGIDHVFGDPGRHPSFWNRNAIVENARAFVRAHLDLTIDCGRDDSFVGSNRTLHQRLVALGVPHDYAERPGGHTWDYWAHAIRYQMQFFAASFQHGGYA
->tr|A0A2E7H1W3|A0A2E7H1W3_9EURY Uncharacterized protein OS=Euryarchaeota archaeon OX=2026739 GN=CMB34_05090 PE=4 SV=1
-MLLSACEGISVADAYVKADRMTYEAIAPSYRAYVEADENLDEPSKQSRYRLLQTWELRINSNTKNK
->tr|A0A0E0KM68|A0A0E0KM68_ORYPU E2F_TDP domain-containing protein OS=Oryza punctata OX=4537 PE=3 SV=1
-MDGSTTIPLPQPPRPPPPAPAPAPPQVFLRRSVLPPPQTGPHRVAPAPPPPGAHVHYFRAASPIPIFRAAASSRPPRPPPTTAPAPPPPPAAPAVTPARPVAVAPPPPPATTTATATEEVAAPATGNPMANTADNEEKNEREAVQSEVPKGETVQGPDKECTTGTVKGIKRPRKPKGFKKGSLRSNEGDAGASLFSPNNCRYDSSLGLLTKKFINLLEGAEDGTLDLNKAAETLEVQKRRIYDITNVLEGVDLIEKTLKNMIRWKGFDMSKPKERERQISALKEEIESLYDEESRLDDEIMEAQEKLNALRVDEDRRKLLYVSKEDINAIPRFQGSTLIAVNAPRGTYIEVPDPNLDMDIYKDLDNQEKHYQIVFRSAMGPVDCFLISNHQETFNADQQMADDLDAAVTSGSSQALQQMDYVQAPEIGESNGVREHTSEPSKRDDPVPGIVKIVPSDDDIAADYWLSSDADS
->tr|A0A3N1VCH1|A0A3N1VCH1_9ACTN Hemerythrin HHE cation binding domain-containing protein OS=Streptomyces sp. 2132.2 OX=2485161 GN=EDE04_6244 PE=4 SV=1
-MDSEHVAPARPYGPAAADLTGVRVAHRAILADIERLAGLLAALAAAAEPAGPARAGAIAGYVHRFNDAVRGHHREDRTLWPVVLDAVPDAAEAAAGLAGFVADHEALDAVQADCDAAAARFAAEPGRHAGLLAGLLAVQRDLLAAHIEAEERHVLPVITRRVPGAAYAAARARVRRADRSPDPAWSRAWLLSHATEDETRRLLAVAGARPAAVEPELREYAAQASAVFAG
->tr|A0A2S6FD50|A0A2S6FD50_9PSED DNA topoisomerase 4 subunit B OS=Pseudomonas laurylsulfatiphila OX=2011015 GN=parE PE=3 SV=1
-MATPSASSYNADAIEVLSGLDPVRKRPGMYTDTSRPNHLAQEVIDNSVDEALAGHASSVQVILHADHSLEVSDDGRGMPVDIHPEEGVSGVELILTKLHAGGKFSNKNYQFSGGLHGVGISVVNALSTEVRVRVKRDGNEYQMTFKDGYKATELEIVGTVGKRNTGTSVFFAPDPKYFDSPKFSISRLKHVLKAKAVLCPGLLVSFEDKATGEKVEWHYEDGLRSYLVDAVSEFERLPDEPFCGSLAGNKEAVDWALLWLPEGGDAVQESYVNLIPTAQGGTHVNGLRQGLLDAMREFCEFRSLLPRGVKLAPEDVWERIAFVLSMKMQEPQFSGQTKERLSSREAAAFVSGVVKDAFSLWLNAHPETGMLLAELAINNAGRRLKASKKVERKRITQGPALPGKLADCAGQDPMRSELFLVEGDSAGGSAKQARDKEFQAILPLRGKILNTWEVDGSEVLASQEVHNIAVAIGVDPGAADMSQLRYGKICILADADSDGLHIATLLCALFVQHFRPLVDAGHVYVAMPPLYRIDLGKEIYYALDEAERDGILDRLVAEKKRGKPQVTRFKGLGEMNPPQLRETTMDPNTRRLVQLTLEDFEATSEMMDMLLAKKRAGDRKTWLESKGNLAEVLG
->tr|A0A3R7JJI1|A0A3R7JJI1_9EURY Helix-turn-helix domain-containing protein OS=Haloarcula sp. Atlit-47R OX=2282132 GN=DVK00_02090 PE=4 SV=1
-MRFIEEIVVDDFLPTFRSLLADALRERGLTQSEVADLLGISQSAVSKYVHGDVARQEDLLAHRGLEELVERLADGLADGDMSPVQALVETEVFIRELEQGGVLAQIHEDAVPELGDYDDEFAVHDPDSQLRAAERTLASVRRGLSVLENTSGFATLIPAVGSNLVQCLPDAESIEDVAAVPGRILDVKGRATIPADPEFGVSEHVATLLLAARTAGSDARAVLNVRYDDGVVAALREAGRTVVEFDAEERVEPAVAAALADDPGVDVLYHTGAMGIEPVVYLLGDDAVSVAETAREIL
->tr|A0A1D3UJH6|A0A1D3UJH6_TANFO Uncharacterized protein OS=Tannerella forsythia OX=28112 GN=TFUB20_01002 PE=4 SV=1
-MDIGQIRKDVHAYYHSIFNDKYGRYVRILELFPPIKESDCILDYGCGTGCVSQYFYNKYKCKVDAVEQSEIELTKAKISFQRGG
->tr|A0A4Q7MI29|A0A4Q7MI29_9BURK Enoyl-[acyl-carrier-protein] reductase [NADH] OS=Kerstersia gyiorum OX=206506 GN=EV679_2606 PE=3 SV=1
-MRSANLAGKKGLVVGIANDQSIAWGAARAMRASGAELAVTWYSDKSLPYVTPLFDEIGATLRLPLDVSDTAQQQALFDTLRERWGRLDFLVHSVAFAPRDDLHGRVLDSSAAGFAQAMDLSCHSFIRLARDAEPLMAQGGSMMTISYLGAQAVMPGYGIMGPVKAALEASVRYLASELGPRGIRVNAVSPGPLETRAASGIAGFDSLIKDSMERAPLRHTLDIEDAGALCAFLASDAARAISGSTLFVDNAFHILN
->tr|G5HTX5|G5HTX5_9FIRM Uncharacterized protein OS=[Clostridium] citroniae WAL-17108 OX=742733 GN=HMPREF9469_06037 PE=4 SV=1
-MGLFGNIIKPLQGKLTTKQEENMKKVAEVFKEKTGKDYQTAVVWKMTTKKKLTKTVYTYYNWIIGYGVNADHIPEIVFIPVDPKWEWIGDPIYCPKTNSEMVQDKKTTLFALKNSQLEDGKMDLQLISSMAMMSNYLMDVNYMFEYDKLNEYCLEHWVGK
->tr|A0A0Q8RTN2|A0A0Q8RTN2_9SPHN Uncharacterized protein OS=Sphingopyxis sp. Root214 OX=1736491 GN=ASE06_19140 PE=4 SV=1
-MPLDGSLGTTNAARATVTIEYSATDRSYTVTTDGRSQTFRPADIDAARSSAAATVYIRTNGGTADVLTLTKPGTSGRLTYQYVAGGFWERTVSGATSTSGSVDGFAYGVETPDAALPRSGTANYGIDLIGVMGYPNSAPSPLAGRGTLYVDFAKGSIVITGEADGGTTFNGTATIASASNNFSGRFEYYSLGSMTGQIDGRFFGPGAQEVGAAWHVKNNGGNAAAGIILGRKNPDTPVNSDFVNIANSQFFENSGVILKATYANGSNNSSNKLTQASDFLVHYDAGYKSYTIVAGDKAEFFGPDRVPDNAAPGSHWTKGIGTTRSTLQFLNGGTHVTGARYVFTDGDATSSFVTSNFFIYGFPTANADIVRSGTSFFKSSIAGSMTDQGYDSLLDIAGPGVIQVNFATGAIDIRGAFDIVYRPITGPRAVGNGSYTGTAQLASSANSFTGSIELAASDTYRGDLSGRFYGPAGKELGAIFKASDSGGDVAAGTITASLDPSANASTKALADLTETTVFISSKAQAGITVDQPSGRQFSLGPPSVSRTGLQPRITYDPQTGSYIVREFGGDHQDQLLETLRFGTADRDTAASDAKFDVFNVASGNTTHRISLLRPGAGNPAIQLTYASFIGLVSKTVEGAPINRDTTRYSYFALGTPTAETLMPRSGTGTYNGLATGYGTVRGIGFAEYDISGTSKLSVNFTSLATQLDLTLAGRNLADGTNFNFGDFIFNGALGYSLVDGQRLNQISMGLKRDTLPPGSSGDAFGHLYGPAGQEHVTPFGMQVRGADGSETVIGGVAYGKRD
->tr|A0A6N7CL63|A0A6N7CL63_9NOCA HTH-type transcriptional regulator IscR OS=Rhodococcus sp. T7 OX=627444 GN=iscR PE=4 SV=1
-MKISGGVEWSLHCCVVLSQAEGPVPTARLADLHGVSKSYLAKHLQSLARAGLVHPTEGRDGGYVLTRAPGDITVLDVVQAVDGDAPAFRCTEIRQQGLLAAPPEQCKTPCGIARVMADAERAWRSTLSGVTIADLAATLDVTVLKATLEASG
->tr|A0A678Y985|A0A678Y985_9INFA Polymerase acidic protein OS=Influenza A virus OX=11320 GN=PA PE=3 SV=1
-MENFVRQCFNPMIVELAEKAMKEYGEDPKIETNKFAAICTHLEVCFMYSDFHFIDERGESIIVESGDPNALLKHRFEIIEGRDRIMAWTVVNSICNTTGVEKPKFLPDLYDYKENRFIEIGVTRREVHIYYLEKANKIKSEKTHIHIFSFTGEEMATKADYTLDEESRARIKTRLFTIRQEMASRSLWDSFRQSERGEETIEEKFEITGTMRKLADQSLPPNFSSLENFRAYVDGFKPNGCIEGKLSQMSKEVNAKIEPFLRTTPRPLRLPDGPLCHQRSKFLLMDALKLSIEDPSHEGEGIPLYDAIKCMKTFFGWKEPNIVKPHEKGINPNYLMAWKQVLAELQDIENEEKTPRTKNMKKTSQLKWALGENMAPEKVDFDDCKEVGDLKQYDNDEPEPRSLASWVQNEFNKACELTDSSWIELDEIGEDVAPIEHIASMRRNYFTAEVSHCRATEYIMKGVYINTALLNASCAAMDDFQLIPMISKCRTKEGRRKTNLYGFIIKGRSHLRNDTDVVNFVSMEFSLTDPRLEQHKWEKYCVLEIGDMLLRTAIGQVSRPMFLYVRTNGTSKIKMKWGMEMRRCLLQSLQQIESMIEAESSVKEKDMTKEFFENKPETWPIGESPRGVEEGSIGKVCRTLLAKSVFNSLYASPQLEGFSAESRKLLLIVQALRDNLEPGTFDLGGLYEAIEECLINDPWVLLNASWFNSFLTHALK
->tr|A0A2N6J824|A0A2N6J824_9BURK Lrp/AsnC family transcriptional regulator OS=Herbaspirillum sp. BH-1 OX=2058884 GN=HBH1_03049 PE=4 SV=1
-MELDTTDLRILNILQENSSISNLELASRINLSPSPTLARVKRLETEGIISRYVALADPHLLGLKVNVFVKVILERQGAEALAQFETAVSAFDEVMEVYLMTGDEDYLLRIVVPDLLTLEHFIVDHLTKIPGIKNIRSSFALKQIKYKTALPTPKIKTRR
->tr|K2Q3C7|K2Q3C7_9HYPH Uncharacterized protein OS=Agrobacterium albertimagni AOL15 OX=1156935 GN=QWE_16493 PE=4 SV=1
-MATILLQAAGAALGSVFGPVGAAIGQAAGALAGSMIDRSLLSGTREVNGARLSSARISGASEGTVIPRLYGTARLGGTLIWATRFEEETVTERTGGKSSGGTRTTTYRYFANLALGLCEGPIAGVRRVWADGRELDTTEIEMRVYRGTESQPADPLIAAKQGADNAPAYRGLAYVVFERLPLDDFGNRIPLIQFEVIRPVGALEEKIRAVTMIPGATEHGYATVRISDAPSEGAKRWLNRNTLVAATDWQASLDELQALCPDLESVALVVAWFGTDLRAGDCRVLPGVEVGYRNEESRPWSVAGLARGDAYVVSRHSGGPAYGGSPSDESVIEAIRDIKARGLKVTLYPFVLMDIPAGNGLPDPYGGAEQAAYPWRGRITAYPPGSDKTASARAQVSSFVYRSDGYRRLVLHYAALAAAAGGVGAFLLGSELRGLTVLRDEANAFPFVEALVALAGEVRGLLGGGTAISYGADWTEYFGHQPPDGSGDVFFHLDPLWASPHIMAVGIDNYMPLADWRDEDLEAESPDGFTGADDAEGFARTLTSGEGFDWFYASEADRRARVRTPITDGAYGKPWVFRFKDLKSWWENPHFNRIGGVEQASPTAWVPRMKPFWMTEVGCGAVDKGANQPNIFVDAKSAESGRPYFSAGARSDSQQRRFLEAHLDHWTGSLLPPDMVDPSHVYAWTWDARPYPAFPQNMALWADGSNWRTGHWLNGRLGTATLADTIAAILRDHGFADFDVSEVAGDLGGYVKGDLTSARDLIEPLLELFQIDVIEDAGRLKFRTRPTASLAAREITVLADIADRPLWSETRGHDSDFASEALVTFYDPASDYVEASVRSRKVEAATDRQLARDLPAAMPEETALAAAEGWLRDNRLARRTVQLALGPQEIVVEPGDVLRFPEGPEGRFLVQGIDEGFERRLTLRAFAGKVSAPVPVVEPGRVVDGGGAAGFAPVVQFLDLPRLEGASHAGDASVAAYGRPWRRLAVSSSPEAEGYRLRLTLDRPATLGRLVEPLLPGPVGRFDGANALVVEVLAGAFASANRMAVLSGANRIAVRTGTGGWEVIGFVEAEEIAVGHFRLTGLLRGLGGTEDAMAAGAAAGAEIVALDEAVRSLGLANAERGAAQNWILEPMGLVSELSGPHVFAGGLRAETPLSPVHAKVRRQATGDLAITWIRRSRIEAEAWTEGEVPLDEAEERYRLEILDGGTVLRVVEVTEPAWTYAGADELTDFGVPQTALGLRIRQLGRLAAGMPLQAVVPID
->tr|A0A373NFP0|A0A373NFP0_9FIRM Histidine kinase OS=Ruminococcus sp. AF31-14BH OX=2293173 GN=DWZ26_10045 PE=4 SV=1
-MIETIMLIVVIFVLSGVFWYSFFYQKEKKLFNRLQQMLDCAIDGELERTEISEEKYSALENSMKQYIDSSFLAKKNQQEQKEVIQKLISDIAHQTLTPISNLKVYGEIISEMSNENQEEIATILEQTEKLDFLIQSLVKLSRMESGIIAVHPEDTAIAQMFASVQQQFNVKAMEKDISLSLFDTDLHAMCDAKWTVEALGNIVDNAIKYTACGGNVQIKTEQYSFFVKIDIIDDGIGIEKEEIPKIFGRFYRSLSVADQPGVGIGLFLAREIIQAQKGYIKVTSKRGKGSTFSVFLPIAKKE
->tr|A0A538LIU9|A0A538LIU9_9ACTN Alpha/beta hydrolase (Fragment) OS=Actinobacteria bacterium OX=1883427 GN=E6G01_13160 PE=4 SV=1
-EAAPIPGPNGKSLGPSELVDAGLIPTYEPAADSQFYDALSSALNDRPGQMLALAAAYQESVDYPLYASVECIDSPHPEGSAAFRAFAQELASLSPRFGAAIANELLPCAYWSAPVRSVVGPVTAPDAPPMLVIGTTGDPATPYDQAVRVAQTLAHGRLLTFVGDRHAAYGASQCAADAEAAYFVDLTLPPEGTTCTR
->tr|A0A7K0C3Y3|A0A7K0C3Y3_9ACTN Uncharacterized protein OS=Actinomadura macrotermitis OX=2585200 GN=ACRB68_61920 PE=4 SV=1
-MAVFGVDYAWGRPGAAALKRSGVRFACRYLSHDTGGKNLTRAEAAELSAAGIWLVVVWESTASRALSGRAGGAADAREAARQAAACGMPADRPIYFAVDFDATAGQQAAINAYLDGAASVLGRRRVGLYAGLGPVRRAFDAGKITYGWQTYAWSGGRWDGRAQLQQYSNDHTVNGVDVDYDRAVAADYGQWRVGVSPQEDDMPDYVSVGTTTAQPLPPGAWTTVVWDAEYSDAGRQHADKGGPGVLNGPARYSLTAAVRIVGVPAGTRIQARAIEADAGGFEAGAVQDFTSAGEETNLLYGISADSVAKDRSVRFQVLQHGAQAAAIGGGSAKLLYWRG
->tr|A0A173CWC4|A0A173CWC4_9NEOP Cytochrome c oxidase subunit 1 (Fragment) OS=Bucculatrix sexnotata OX=687279 GN=COI PE=3 SV=1
-IFGMWAGMVGTSLSLLIRAELGNPGSLIGNDQIYNTIVTAHAFIMIFFMVMPIMIGGFGNWLVPLMLGAPDMAFPRMNNMSFWLLPPSLLLLISSNIVEMGAGTGWTVYPPLSSNIAHGGSSVDLAIFSLHLAGISSILGAINFITTIINMRTNKMSFDQMPLFIWAVGITALLLLLSLPVLAGAITMLLTDRNLN
->tr|Q0JI52|Q0JI52_ORYSJ Os01g0823700 protein OS=Oryza sativa subsp. japonica OX=39947 GN=Os01g0823700 PE=2 SV=1
-MESATEKVRRTPSSCLLLRISDICKVRSVGVAPTVREKPKADGSATGESSEDGGAHLKVHPHHVSDHESVSECSSARCEEAFVERLLDAISGLKLSYVNLQQALVPYDPEEITIADERFTSELQETAGLKDLYVNMNKWRNPMYQCYVGSRIQEQQKLAVELQAGMCKRDSEIVCLRAELDELERKNMELEEKIGQSALQKEGSFAIGMGVSTDMFMELFELSTKSIHDFAKLVVRWMKLSRWNLGNLTSPIDNSVVYDKRSHKNYAVEAYFACMMLMGHKEEYLSLDVFDYVMSFSDPFDALMKAPDSCFGRFCREKYLAILPPSMEDSFFGNLDHRSFVENGGHPRTPFYQAFVTMSRYVWASLTVARSLNPRAEMFYVKGGTEFRSKHMECVPSKITKEGDKVSVGFTVMPGFKIGCTVIRCRVYLSMVNERNF
->tr|A0A7S0VQU1|A0A7S0VQU1_9CHLO Hypothetical protein (Fragment) OS=Polytomella parva OX=51329 GN=PPAR00522_LOCUS21823 PE=4 SV=1
-KGNQYTNRNYNPHHNDRGDGDEGNSSHCSSDDDGNVDRVATTLKKGNKDSELIDSSFHYREMEVKEERSDTWSGLSNLFHPIASPSAEQILEQLQMIGRTRQLERDRLKQGLQGEESSAESHVAS
->tr|A0A7N0VGN9|A0A7N0VGN9_KALFE Smr domain-containing protein OS=Kalanchoe fedtschenkoi OX=63787 PE=4 SV=1
-MASSTPPPHCSITTTNPRSHSRTKSNRVVSLTNPTPSAAAAGAPPCCASSKPLCPAKTHPLASASPSSPRNPNFPSLSDFSGRRSTRFVSKMHFGRHKPSPTSSRHTSVAEDALHQVIRVNATDHRALDAVLHAFAPNLSGSDDYTFLLRELGNRGDCSKALRCFDFAVQRERRKNEQGKLATAMISVLGRMGKVDLARKVFDDAAAQGYGNSVYAFSALISAYGRSGYCDDAIQVFEAMKKSGLRPNLVTYNAVIDACGKGGVEFSRAANILNEMLSDGVLPDRITFNSLLAVCSRGGLWEAAQNLFSEMIYRGVDQDIFTYNTMLDAFCKGGQMDLAFQTMSEMNSKNICPNVVTYSTMIDGYAKAGRLSEALNLLEEMKYAGIGLDRVSYNNLLTIFAKLGRFDEVVNVCKDMESSGIRKDTVTYNALLSGYGKQGKYDDVKKVFQAMRHEHISPNLLTYSTLIDIYSKGGLYQEAMEVFTDFKKTGLKADVVLYSALIDALCKSGMVETAISFLDEMTKGGIKPNVVTYNSIIDAFGRSAIKDFQTDSPAEASELQNESSSSTLPPARSQNGNRIGSGFIKILGHLAAEKPCYLKKYDGKPLEILCILAIFHKMHELEIKPNVVTFSAILNACSRCSSFEEVCMLLEELRLFDNKVYGVAHCLLMGCRGSVWVQAQSLFDDVKQMDSSTASAFYNALTDMLWHFGQKQGAQLVVLEGKRRHVWENLWSDSCLDLHLMSSGAARAMVHAWLLNIRSIVFEGHELPKLLSILTGWGKHSKVVGDGTLRRHIEALLNSLGAPFRLAKCNLGRFISTGINTYMIMMLPSL
->tr|A0A2V6QIG5|A0A2V6QIG5_9BACT 5,10-methylene tetrahydromethanopterin reductase OS=Candidatus Rokubacteria bacterium OX=2053607 GN=DMD80_16590 PE=4 SV=1
-MRLGLALPNASPEGRPLTGPALIAGTRAVERAGFDSLWCFDSIGRGSMIPDPLIAVSVAATVTERLTLGTGILQVPLRRPVELAHRILTAHLICGGRLLLGVGAGSTKADFDAVGVDFDTRMQQMEEALALMRRLWQGEKVGPAQLNPWPAALGGPKLLIGSWAGSRWIPRAAKDFDGWIGSGARSSVAALRDGIKRFREAGGQRAIATNIPVDLEAPTAPMPEEGQFHLRCDPTTAAQRLRMLADLGFDDAVLVTRRYGDADLAALRALWP
->tr|A0A7Z7G3P1|A0A7Z7G3P1_9BACL UPF0310 protein SAMN05518670_2319 OS=Paenibacillus sp. OK076 OX=1884379 GN=SAMN05518670_2319 PE=3 SV=1
-MNEQAKHDLMANNTEIQQTHTREFLSHQLDIEAESDEGNRYWIGVVSASHVEKGVEGGFAQLCHGKVASLRRMNAGDWLIYYSPRTSMQGGKVLQAFTAIGRIIDDQVYTYHVSDSFVPHRRNVHYYPCQQVKIADLLDQLILTRGQARWGYPFRYGHLQIQREDFLKIAVAMLGTEAENLLTGNKKN
->tr|A0A1I0CXW7|A0A1I0CXW7_9FIRM D-alanyl-D-alanine carboxypeptidase OS=[Clostridium] aminophilum OX=1526 GN=SAMN04487771_100922 PE=3 SV=1
-MKSNLFHWKRYLWILSAAGILTVSATPAVVFAAPETGAASTAAQSGSEASAIAETTETATKALYGTSPQQAQSARVASIAAQAAATAGTGEEASAAVASIAAAAAETAAQEVTEDAQAWPSDTGIFSEAGVVIDVDSGCVLFGQNMHQQKAPASITKILTALVVLEHVDNLDQMIPYSHDAVYNTESGSGNKYGLDEGDSLSVRDALYLMLLASSNQSANALAEYVGGTREGFVQMMNDKVAELGCRDSHFANPSGLNDDTQLTSCYDMALIGMAAYRNERLLEIGSTRSHKITTPTKNNPNGINVKMEHKLLITEDPNSENYYPFAVAGKTGYTSIAGQTLVTYAVKEGRRLIAVTMKSRQKTHYTDTINLLEFGFNRFENVPVAEQETAISQASGNVTLGDSTFDAADLSVEETVMTVPKNLSVTDLERTVLTGEDMPAPAPDGAAAYIQYSYRDRVTGGAYVTAESLRAKETGATGTEGNRRTKAESGDNIFSKAAKGIGSFFAGIGDAVRNLSVPGIIAIAAVAGLAILTVIAFFTYSVQKRRENERLERRRTRLREMGVSEEEFAEMVGRRRRSRGEKNSSRDFSAETYRVTEAGNSPADHHGRAEDVKSPAVPQTEALKTETPENPDDSFLDEDFGMDGELITEEDPEKRQPHV
->tr|A0A445NDM6|A0A445NDM6_STRNE Putative glycosyltransferase EpsJ OS=Streptomyces netropsis OX=55404 GN=epsJ_2 PE=4 SV=1
-MVKLSVIVPFFNVQTYAPDTLRSLRANARADFEFILVDDCSTDETPDILRRAERELPGAVLVRHEKNGGLATARNTGLERARGEYITFLDGDDWLAPGYYEQLLDVIEGLGVEFVRTDHVQCTARARTVHRVPHGRRGVVLSPRDAILPADRSTSVDYAYAWAGIYHRRLLDEGLLHFRHGLRTAEDRPWIWRLHREARTFAVAGLLGVFYRRGVASSLTQIGDVRQLDFLRAFDQVIDETSRDADAEILLPKAVRTYCAIISHHLGSIERFEPAVARTLRSKSAAALRRMPQDLLKDALNSMDDDRAARLRRLRRRPAPAGVTG
->tr|A0A1G5TNQ2|A0A1G5TNQ2_9HYPH Uncharacterized iron-regulated membrane protein OS=Methylobacterium sp. UNC378MF OX=1502748 GN=SAMN02799622_03000 PE=4 SV=1
-MSRARSFRQSMAWLHTWSGLVVGWVLFAIFVTGTASYYRTDISHWMRPELSDSSSDPAAAATRAGAFLQKAMPNAAGWSVRLPNAENPAVEVYWWPHPGGPYHHALLDPATGEPARVRDTRGGDFLYRFHFELSLPPIWGRWIVSVCAMILLIALISGIVTHRRIFADFFTFRRDRSAQRGWLDAHNVMGVLALPFHLMIVYTGLVTLSAMLMPWGMKAVYGNDPLRYYAEAGLATPGVAPAGRPGTPLPLGELVARAAAAGGAVPEVMLVTRPGDAGATVTAYFEEPMGLAHLHPQIAYGADTGSEIARVGEPGAATRTGAVMAGLHEAHFAAAPLRLLFFLCGLMGAATVASGLVLWTVARAPRGADPEGFGLRLVRLLNIGTIAGLPVGLAAYFLANRLLPLGLEARADWEIRVFFAAWITAAIAASLYPRRRAWSVALAVPACAFLVIPVIDAVLVGQPRFLAFDAAMAVVGLALVAGSRLAARPRPAESRLVEANLSRTVEA
->tr|Q71P98|Q71P98_9BRYO Protein PsbN OS=Homalothecium laevisetum OX=184649 GN=psbN PE=3 SV=1
-MLTLCTIILIKLIKNKPFFWNYLKMETATLVAIFISCSLVSFTGYALYTAFGQPSKELRDPFEEHED
->tr|A0A3B0J0J5|A0A3B0J0J5_9RICK Uncharacterized protein OS=Wolbachia endosymbiont of Aleurodicus floccissimus OX=2152762 GN=WBAF_0556 PE=4 SV=1
-MRLKLAYTNTIHLKHDFNIGDIETKKLCHSKIMLRFQEKAVSSQISCVTEINFGRIAIATANDKQASVYYIFKQNVKHMGNHVLFKVRVGRVATHIFVSDPNLAKIIKCLTIRVMIYIIMAII
->tr|A0A4T0N0J3|A0A4T0N0J3_9BASI Tudor domain-containing protein (Fragment) OS=Wallemia mellicola OX=1708541 GN=E3Q01_03257 PE=4 SV=1
-SAEEISQYELQLEQVKETLTADPTNAELIGLKDELSNLIDLLKASTAPAQTAPSTSEQPPQSKGKDSKDVKIFKAGEDIMAKYNDGKFYPAIVKAVSGIHPKIVYTINFRGYEGTQQVQPNQIKAMDPHTKISLTNKRQRDSQKSLTSIEDEKERERKRKKSEKKAEAREQKNSEMNNKQNNWQKFAKKANKKGIHIAGSEGRSIFKTPDNPYGRVGVTGSGKPMTEQKSVRDKHVFVPTLEDQ
->tr|A0A2I2A5J4|A0A2I2A5J4_9GAMM YigZ family protein OS=Hydrogenovibrio sp. SC-1 OX=2065820 GN=CYQ88_04895 PE=3 SV=1
-MAYLEPVNAVVEETEIKKSRFIAYAKKVVSRQQAMEYVSELRVAYPDARHVCWGYVIGDPNNSTNSGCNDDGEPSGTAGKPILSQIHYSNIGNVVVVIVRYFGGIRLGAGGLVRAYRESAQKGLKALQTEDYIPKLELSLDCPYEEEALIRRVMASLQGEITDAIYTTQVNLLVSIPTHSLTLLQDQLASLSATIIEN
->tr|A0A7W8SVI5|A0A7W8SVI5_9BURK Membrane fusion protein (MFP) family protein OS=Paraburkholderia sp. WSM4180 OX=2723099 GN=HDG39_006657 PE=3 SV=1
-MNFNIFKRGKKKAKLTKGDAAFMSDIRESLLTQSTPGSMIMLYVILTVLAGGLTWAYFARVEEITHGEGTIISKSREQVIQSLEGGILEQLDVREGDIVKKGQVLAKIDPTRAETSYREAWSKSVGLKATIARLRAEAYEQPLTFPDDVKAVPTVVKQETLAYNARRRALNDSVTALEKSYSLSNKEIGLAEPLAAKGLVSEVELLRMRRQANELRSQIVERRNRFQADANSELTKLELELAQTSETVVGRADVLQRTTVIAPVYGTVKNIRFNTIGGVIQPGEHIMEIVPLEDQLLVEARIKPSDVAFLHPDQPSTVKITAYDYGIYGGLKGTVQHISPDTLKDDQKAAAGRPDATYYRVLVLTDSSELHAGGKSLPILPGMVATVDIRTGEKTILDYILKPIFKAREAFRER
->tr|A0A421K520|A0A421K520_9GAMM Alpha-amylase OS=gamma proteobacterium symbiont of Stewartia floridana OX=1968599 GN=B6D75_05870 PE=4 SV=1
-MSVDELDTRLLGHLSLLYGEQQAATLLPKLHELIGRHIEVRQGKRLEIPRWDEKDSVLIGYGDSIQYPGMTPLASLKQFLDRRLNGVFSMVHVLPFFPYSSDDGFSVSDFRSVNPELGDWQDIRELGENFSLLFDLVLNHMSREHLWFVNFVHDEEPGRDYVVQVSPDENLSMVVRPRSTPLLSRVRTPRGMLDVWATFSNDQIDLNYANPEVLLEFIDILLDYIRRGARAVRLDAVAFLWKEIGTSCIHLPQTHEVIKLFRTLLDVLEPGAILLTETNVPHQENISYFDQGDEANMVYQFSLPPLILHAIMCQTTEFLVPWARSLEQETLPEGCTYLNFTASHDGVGLRPLEGLVPDEDLDELLDMMRRRGGYVSMRATTEGRDRPYELNISYFDAFAAEDDDVDPWHIARYMLSQTLPLSFRGIPAVYINALGATPNDPLGVERTGMTRSINRRKWDGAELERLIDLPLTDAGQVFPEYIRRLRIRSGIKAFHPDAPQRVLDMPDGILALERTSLDGGQRVYAIHNMTGDLRSVDISALGGASRRWFDALHQVVPDMDGDGVRFRPYQTVWLMAKG
->tr|A0A182WP14|A0A182WP14_9DIPT Uncharacterized protein OS=Anopheles minimus OX=112268 PE=4 SV=1
-MSPCVNFRLANLLSHKS
->tr|A0A6P5JSA5|A0A6P5JSA5_PHACI probable aminopeptidase NPEPL1 OS=Phascolarctos cinereus OX=38626 GN=NPEPL1 PE=3 SV=1
-MANVGLQFVASAGDGDPQSRPVLLLGQLQNLHRVPWSHLRGKLQPRVTEEIWQTALGTLNPNPTDSCPLYLNYATVAALPSRVSRHNSPSAAQFITRLVRNCLPGGTNRCILMVCERSEVFASACALARAFPLFTHRSSASRRTEKTVTVEFFLVGQNNGPVEVTTLKCLTSATEGVRLAARIVDTPCNEMNTDNFLEEIKKVGKDLGIVPTIIRDEELKQRGFGGIYGVGKAAVHPPALAVLSHMPEGATQTIAWVGKGIVYDTGGLSIKGKTTMPGMKRDCGGAAAVLGAFRAAVRQGFKDNLHAVFCLAENSVGPNATRPDDIHLLYSGKTVEINNTDAEGRLVLADGVSYACKDLGADIILDMATLTGAQGIATGKYHAAVLTNSEEWEAACVKAGRNCGDLVHPLVYCPELHFSEFTSAVADMKNSVADRDNSPSSCAGLFIASHIGFDWPGVWVHLDIASPVHAGERATGYGVALLLSLFGGASEDPLLNMVSPLGEDADPQGDMERDCKRRRLV
->tr|A0A5J6X1V6|A0A5J6X1V6_9GAMM Histidine kinase OS=Aeromonas simiae OX=218936 GN=FE240_18420 PE=4 SV=1
-MPRSLLSRMLLLLLLAILLSQTILTGIWMQQIQKRELDGMLSTTRNLAMSAASTVSFFKSLPLQYRHIALDQLRNMGGSRFFVSLNEEEIRINPIPDSERKTMVLSEVKAILGNKLSDTMAIKVNFSHPEDLHVFNNDTLLADLPSSWARYTLSLEPINPPVLVIQIEIKRGEWLYLAALLPAPYMTLDDTVMPANQVRFIALMTVFLCFFTFLLVRWQTRPLRRLAKAAVNLGKDIDQPSLKEEGASEIVAATRAFNIMQHRIRRYIGDRELLFSSISHDLKTPITRLRLRVELLDDETQITKFNKDLDELELMVKGALQTVKDTDIHENMAQIDVDGMLHQLAESLNLREERLTIEGHCKHPYRGKPLALKRCIANLVDNGIKYGKKVRIIILDDDEMLILFIMDEGPGLPEEQIERIFEPYYRFDTEKPGNGLGLGIARNIAHAHGGDLVLENRPTGGLQATLSLPRQ
->tr|A0A1Q6SWC2|A0A1Q6SWC2_9FIRM Aspartate--ammonia ligase OS=Subdoligranulum sp. 60_17 OX=1897022 GN=asnA PE=3 SV=1
-MSHITIPEGYQSLLGLYDTQKAIGLIKTIFQEKLCMALHLKRVTAPLFVMQGSGLNDDLNGVERPVSFDVPSLNEQAEVVHSLAKWKRYALYKYGFRPGQGIVTDMNAVRRDEELDNLHSIYVDQWDWERVITADQRTLEFLQETVRDIVDAVCATSDELRWKFPELKNNIHLGREVAFITTQELEDRYPDFTPKQRENAFAKEHGTVCIMQIGGRLKSGQPHDGRAPDYDDWTLNCDILFWHKPLDCALELSSMGIRVDADALRRQLDAAGCPQRAELPFHKLLLDGTLPLTMGGGIGQSRLCMLLLGKAHVGEVQVSLWDDATVQACRNSGVELL
->tr|A0A7W1W6Z4|A0A7W1W6Z4_9BACT S46 family peptidase OS=Acidobacteria bacterium OX=1978231 GN=H0X49_12420 PE=3 SV=1
-AAENLFNKFEGKERRSAEETFAESIAERENFDTPEKVIKLYDLSLSDLQKRYPNIVEFMTALGQEKSAVTARTAKFNGEIDRLRLLYQQGMAEMKGIQPYPDANSTLRFTYGNVRGYSPREAVTYSPFTTLRGMIEKDSGEIPFDVPQKLIDLQRTKDFGRFGVGDTVPVNFLATTDIIGGNSGSPIMNAFGEQVGIVFDGNYEGLGNDLFYNEAVGRTIAVDIRYVLFVTEKFGGAGWILGEMNIKGRTPVKARSAAAE
->tr|A0A1Z2QUG4|A0A1Z2QUG4_9ASTR Ribosomal protein L14 OS=Legenere valdiviana OX=2010882 GN=rpl14 PE=3 SV=1
-MIQPQTYLNVADNSGARKLMCIRIIGASNRRYAHIGDVIVAVIKEAVPQMSLERSEVVRAVIVRTCKELKRDDGMIIRYDDNAAVVIDKDGNPKGTRVFGAIAEELRQFNFTKIVSLAPEVL
->tr|A0A239R358|A0A239R358_9FIRM Exodeoxyribonuclease III OS=Lachnospiraceae bacterium OX=1898203 GN=SAMN06297422_103139 PE=3 SV=1
-MKLISWNVNGIRACVNKGFMDTFNTLDADILAIQESKMQKDQLILETPGYHQYWNYAKKKGYSGTAVFTKKEPLGVTYGMGIEEHDQEGRLITLDMGDYYFVCVYVPNSQNELKRLDYRMKWEDDFRKYLNDLKAEKPVIICGDLNVAHEDIDLKNPSANHRNAGFTDEERGKLTELLESGFTDSFRKLYPDMTDIYSWWSYRFNARERNAGWRIDYFLVSDDIKDKISEAGIHTDIYGSDHCPVELDIDL
->tr|A0A498QHK7|A0A498QHK7_9MYCO Uncharacterized protein OS=Mycobacterium attenuatum OX=2341086 GN=LAUMK136_05508 PE=4 SV=1
-MPHAESTVGPALMVAHSGASSHASAPGRDRLEPRAVSRELRASDPEVWQTGLHAASEDAPLRVVGNTPSGMFVDGRRKGSVTVSDKTIVRFGDPTGGKALTFEVVRPSNSPEEQRREQRPSDQSDGHTGEADPGVVRAGAAAAARRRELDISQRSLAADGIINAGALIAFEKGRSWPRERTRAKLEEVLQWPPGTIARIRQGESVGYQAPSPTAQADDEAQPTEGPASLIAQAVAAAVDTCSLAIAALPPPEDPEFTERAAPILADLRQLEGIAVQATRISRITPELIKALGAVRRYHDKLMTLGATAPGATLAQRLYAARRRANLSTSETAQAAGVAEEMIVRAEAEEALPAEAAEAIEALIHQIN
->tr|X0B5K4|X0B5K4_FUSOX Uncharacterized protein OS=Fusarium oxysporum f. sp. raphani 54005 OX=1089458 GN=FOQG_17891 PE=4 SV=1
-MVGRPKETSACSGKSGPGSRPDNPVGRGSVWGPEEGSSPARNRASARGTAGRLSMSSRSLYTGRRGRTRMSVGQEDGI
->tr|A0A345E3A3|A0A345E3A3_9EURY Sodium:calcium antiporter OS=Haloplanus rubicundus OX=1547898 GN=DU500_09665 PE=4 SV=1
-MRRQALTALGGAAALTLPWVVTYLSGMAHSLATGTVVLVSGLSVLGASFLLAWGAETAEKDVPRAFAIAVLAVLAVAPEYAVDALYAWNAGVHAGTARGVEAGNLAVANMTGANRILIGIGWAGIALFTVYRAGSGDDPAVESRSGFLADAVTLDHDIGLEIVFLFLATLWAFLVPLGGGIDILDMAFLVGLYIAYIAVILKGDVDPDEAHVGVPAYLQRFPKPYRAATVIGLFVYSGLMIFTAVEPFAHGLEQLGQNIGIPSFFMIQWIAPLASESPELIVVVYLVNKARSTAGFNALISSKLNQWTLLIGTLVVVYSIALGQYGALPFDQKQSGEIWLTAAQSFFAISLLVNFEISVREAIVLLVLFLTQVLSEFLLIRGILELPISDYQLLLVFTGIYIVLGTTLFVARRHALGSIVRDSAGTVSDAFSSSGEPRGAD
->tr|A0A1E5AGD2|A0A1E5AGD2_9RHOB Peptidoglycan-binding protein OS=Rhodobacteraceae bacterium (ex Bugula neritina AB1) OX=1868286 GN=AB838_08000 PE=4 SV=1
-MTPPRSLLRGRQAPPLLLALLATLAACVQPQPGGPGSETGRYAPPGAAPGTCWSKHTAPAVIETVTRQVLAEPEQQDANGRVIRPATFRTETRQEIVRPRQEQWIEIPCPAMMTPDFIRTIQRALTARGLYRGPVHGRMDAATRRAVQRYQAPLGPDSGTLTLTSARRLGLVAVPG
->tr|A0A0K0DCJ6|A0A0K0DCJ6_ANGCA Ge1_WD40 domain-containing protein OS=Angiostrongylus cantonensis OX=6313 PE=4 SV=1
-MGMGDPCVPADHLSPSLARIGAYTAQNDITITLLIIGRSCIVNLGAILFTSVSVIYSSTLDGSDGVIKFANGNNVRALKGRFLTVQGDLIAFRFFNEHTGDVIRIINRVSRNRRLIKGFSKAPVDLCFATHLPLLAVVDGESNLHVYSVASDCQDVETYINIMNWPGSTSNSTPRVVWCPYVAENPSDPSDVVNMLALSKKNSVYVVNLSILKERGSRMTFEEALAVEEAVLSVEMEEDVTAVCISPDSTAVAIARADGVVSFYVMNSNESGLKFAHTWNPQMNRPIVELFFLDGARHIKNQEQFWRHCLVVAEGGRRLALFECENWRCLGRVRFESSVEMATFAVHVDPQARYVHILDIDGSNVFCIELEYSDHPRFAGVTQVTFSHPIIAIVPYEHVYIFIEYSLDDEFDGDRTRNEVLAHYIAIGHRSLLQLDVHLELAELPKPNVDVVPLIKTDAGRDEAERNNEGPSNLLTMVHPPAMNSTSTITYEKLLELVKDMSDKIEQLSVRVERADIERRSAATNEHILSQLQCFKEEFSLREDRLLANVSDLIETNHRETINVVRNALNENSVAVENSIQANHKVFFSAVLCELFTYDMNITYLLLCFLKIVDNLKLPYCSSA
->tr|A0A1P8LAL0|A0A1P8LAL0_9INFA Polymerase basic protein 2 OS=Influenza A virus (A/Washington/101/2016(H3N2)) OX=1936961 GN=PB2 PE=3 SV=1
-MERIKELRNLMSQSRTREILTKTTVDHMAIIKKYTSGRQEKNPSLRMKWMMAMKYPITADKRITEMVPERNEQGQTLWSKMSDAGSDRVMVSPLAVTWWNRNGPVTSTVHYPKVYKTYFDKVERLKHGTFGPVHFRNQVKIRRRVDINPGHADLSAKEAQDVIMEVVFPNEVGARILTSESQLTITKEKKEELRDCKISPLMVAYMLERELVRKTRFLPVAGGTSSIYIEVLHLTQGTCWEQMYTPGGGVRNDDVDQSLIIAARNIVRRAAVSADPLASLLEMCHSTQIGGTRMVDILKQNPTEEQAVDICKAAMGLRISSSFSFGGFTFKRTSGSSVKKEEEVLTGNLQTLRIRVHEGYEEFTMVGKRATAILRKATRRLVQLIVSGRDEQSIAEAIIVAMVFSQEDCMIKAVRGDLNFVNRANQRLNPMHQLLRHFQKDAKVLFQNWGVEHIDSVMGMVGVLPDMTPSTEMSMRGIRVSKMGVDEYSSTERVVVSIDRFLRVRDQRGNVLLSPEEVSETQGTERLTITYSSSMMWEINGPESVLVNTYQWIIRNWEAVKIQWSQNPAMLYNKMEFEPFQSLVPKATRSQYSGFVRTLFQQMRDVLGTFDTAQIIKLLPFAAAPPKQSRMQFSSLTVNVRGSGMRILVRGNSPVFNYNKTTKRLTILGKDAGTLIEDPDESTSGVESAVLRGFLIIGKEDRRYGPALSINELSNLAKGEKANVLIGQGDVVLVMKRKRDSSILTDSQTATKRIRMAIN
->tr|A0A0A9C7I2|A0A0A9C7I2_ARUDO Uncharacterized protein OS=Arundo donax OX=35708 PE=4 SV=1
-MRSKSARMRRLVPPTTFSRYRETSSGGRRKQSVLTTTKDCSSMGLWAIRGEHSLVLCSTSFLWVPAVRRVSAAGPPLAFPL
->tr|A0A834SHI8|A0A834SHI8_9FABA Uncharacterized protein OS=Senna tora OX=362788 GN=G2W53_041746 PE=4 SV=1
-MVGSLKPSRITRRKTCCASEPNTSVRVVFAIRSGFDAPIGVVLAWEERGSCLDIFRTRNRGRISKTLMDYEAKDLLLGVVLAWEERGSCLNIFRMKNHGRISESFMNYEAKDLLRKSADHVLTYSGRQIMVGSQKPSRITREKTCCASESNTSVHVVLANRTGFDAPIAVVLAWEERGSCLNIFWMTNRCRISETFTNYVAKDLLRKSEDHVLTYSGRQIKVGSLKPSRITMQKTCCASEPNTSVRVLFAIRSGFDAPIGLVLAWEERGSCLNIFWTTNRGRISETFMNYEAKDLLRNESNTSVRVVFATRSGFDAPIGVVLAWDESGSCHNIFRTTNLGWISETLTNYEAKDLLRNRLGMGGTWIMSELIPDDKSRSDIRNLHELQGKRLVAQSDLRNLHELRGKILSAQVSQTRWFPLYLRTGVVLMLQLESSWHGRSVDHVLTYFRMTNRDRISETFRNYEAKDCCANESNTSVRVVFVNRSGFAAPIAVFMAWEERGSSLNLFRTTIRSRISETRPFVLYLRTIVVLLLQLESSWHGWSVDLDLTYFGRKSRFKISESFTNYVAKDLLRNRLGMGGVWIMPYHITDDKSRPDLRNLHELRGKRLVALVSQTRRFALYLRTGVVLMLQLESSWLGRSLYHVLTYSERQIMVGSQKPSRITRQKTCCANDSNTSVRVVFANHSGFDALIGVVLAWEERGSCLNIFRMTNSCWILETFTNYEAKDLLRN
->tr|A0A7T9DJD5|A0A7T9DJD5_9ARCH Uncharacterized protein OS=Candidatus Diapherotrites archaeon OX=2026736 GN=IPJ89_04390 PE=4 SV=1
-MSASFKVVIILTAEAHHAEVLSGIHKQFKDFFDYSEQAVYIYLDDHHVVWNKKFGELVGYATPAAAFKSKKHFLELFVDASSQKKLVKAFSNAMESGAGSSNTIVWKHKSGKKKKTTTILVPIPYDGHLLALHFIQ
->tr|A0A8B6DBA9|A0A8B6DBA9_MYTGA Uncharacterized protein OS=Mytilus galloprovincialis OX=29158 GN=MGAL_10B009134 PE=4 SV=1
-MTTVPTTSELTTEPTTSEMTTEPTTSQMTTEPTTTEMTTEPTTSESTTEPTTSEVTTELTTSEMTTEPTTSELTTVPTTSDMTTERTTSENQNRTTTSELTTEPTTSELTTEPTTSEMTTEPTTSDVTTVPTTSEMTTEPTTSELTIEPTTSDMTTEPTTSEVTTVPTTSEMTTEPTTSEMTTVPTTSEVTTEPTTSEVTTEPTTSDMTTEPTTSESTTEPTTSDMTTEPTTFEVTTEPRTSDMTTEPTTSELTTEPTTSEITTEPTTSEMTTEPTTSDMTTEPTTMR
->tr|B7M9W0|B7M9W0_ECO45 Uncharacterized protein OS=Escherichia coli O45:K1 (strain S88 / ExPEC) OX=585035 GN=ydgC PE=4 SV=1
-MGLVIKAALGALVVLLIGVLAKTKNYYIAGLIPLFPTFALIAHYIVASERGIEALRATIIFSMWPIIPYFVYLAALWYFTGMMRLPAAFVGSVACWGISAWVLIICWIKLH
->tr|A0A7X8AQI6|A0A7X8AQI6_9ACTN DUF2142 domain-containing protein OS=Propionibacterium sp. OX=1977903 GN=GX412_13535 PE=4 SV=1
-MSRLARALVAIAVAAAALVVGVAWSFASPPVSSPDEDYHLGSIWCPPPAEESGCRMGTVDGKPVVWVPEVMAQRPCYVGRLGDSAACQDELSATELVPSIRFDQGDYPGQYYRIMHAFVGPDLDRSVLTMRVVNVVVAVLLVGAALVLAQPHAGRAATYALFAGLVPTGVFIVASVNPSSWAFVGLTTLWIALNSLAQASGTALRVANGALAVSGAVLASVARGDTGPFVAVIVLALGLLHVRRRPDRGWLAVAAITLAVGAWSYLGSGQAGVAPTVTDVEGRNFGEVLAHNLVEILQVPAGILGVGPWGALGWLEIPMPTSVHVPTISLAGMLLFQGLRRLDRRKALALAVVAGALLALPFYMLMRNLEIAGIQPRYVMSLLPLLFALCLLHPGAVAAYRFTRAQAVLAWVMVTTAHSVALLTTLRRYVTGLDGSYLLGRGGEWWWSSGPSPLAWWLAGSAAYGLAALTLVATAGIERPAASVGRHE
->sp|P36783|VE2_HPV14 Regulatory protein E2 OS=Human papillomavirus 14 OX=10605 GN=E2 PE=3 SV=1
-MENLSDRFNALQDQLMNIYETAANTLESQIEHWQTLRKEAVLLYFARQNGVTRLGYQVVPTLAISEAKAKQAIGMVLQLQSLQKSQFGSEPWSLVDTSGETFRSAPENHFKKGPVSVEVIYDNDKDNANAYTMWKHIYYQDDDEQWHKSASGVNHTGIYYMQGTFRNYYVLFADDATRYSKTGHWEVKVNKETVFTPVTSSTPPESPGGQADSNTSSKTPTTATDSTSRLSPADSRKQSQQANTKGRRYGRRPSSRTRRTTETRQRRRSRSKSRSRSRSRSRLRSRSRSQSSERRSRYRSRSRSRQKEVSRITTTTRGRGRGSSSTSSKRSQRARGRGRGGSRGRRSSSTSPTSSKRSRRESESSRQRGISPSDVGKSLQSVSSRNTGRLGRLLDEALDPPVILVRGDPNTLRCFRNRAKQKFTGLYRAFSTAWSWVAGDGTERLGRSRMLISFFSFNQRRDFDQTVKYPKGVDRSFGSFDSL
->tr|A0A7Y4GUD3|A0A7Y4GUD3_9BRAD NAD(P)/FAD-dependent oxidoreductase OS=Bradyrhizobium australiense OX=2721161 GN=HCN58_21515 PE=4 SV=1
-MLNKVNKPKLVVIGNGMAGVRTVELLLDRAPDLYDITVFGSEPYGNYNRILLSPVLAGEKTVDDIMLNTEQWYDDNGITLRKGEMIEMIDRRTCEVVTREGARVPYDRLLIATGSNPIMLPLPGKDLPGVIGFRDIQDVEHMVQASTSYKNAVVIGGGLLGLEAANGLMKRGMNVTVVHLLDTLMERQLDQVAGGLLRKSLEERGMVFKMPAQTEAILGEDRVTGVRFADGEVIPADLVVMAVGIRPNVELARKAGLYCERGIVVSDTMQTYDGRIYAVGECVQHRRQTYGLVAPLFDQAKVCANHLAMKGFATYDGSVVSTKLKVTGIDLFSAGDFAPGADKEEIVMQDASRGVYKRIILRDKKIVGAVLYGDTIDGPWYFQHLRDGTDVSQMRERLVFGAANLGDGGHSGKNSVAAMSDDAEICGCNGVCKGTIVKAISEKKLFTIDDVRAHTKASSSCGSCTGLVEQVLAFTLGGDYSAAPKVKPMCACTDHSHDDARRVIVENGLKTIPDVMKFMDWKTPNGCHSCRPALNYYLLATWPGEYRDDQQSRFINERVHANIQKDGTYSVVPRMWGGVTTPDELRAIADVADKFNIPTVKVTGGQRIDLLGVKKEDLPAVWADLNDAGMVSGHAYAKGLRTVKTCVGSEWCRFGTQDSTGLGIKLEKFMWGSWTPAKVKLAVSGCPRNCAEATCKDVGVVCVDSGYEIHFAGAAGLHIKGTEFLAKAATEEETLEIIAALTQLYREQGWYLERMYKWCDRVGLDAIRNQVVDDVANRKTLFSRFTYSQQFSQSDPWAARAQRGVDRNEFTPLAELELA
->tr|A0A4P7ND20|A0A4P7ND20_MAGOR Uncharacterized protein OS=Magnaporthe oryzae OX=318829 GN=PoMZ_04838 PE=3 SV=1
-MAFAHQLGAARLLLRQHRFGLAQSSCRRNMATLSQKLSNEPAVIKPSAAEIKNKTLSSRNLEIAVRHLHADGLVVVEDAVPHADLDALNAKMVPDARYLQSLGENGPFNYNQGNLQQDPPPVAEYFFPSIFTNKIATQITSSILGPRPKWTFCSANSAMPPSSPDSPPQRQPVHSDADFDHPHHPFALVVNVPLVTMTLHNGSTELWLGTHHLSDLSAQEGAHGERASGRIKQRLLDARRSTRGPCQPVVKKGSVVVRDLRLWHAGMPNLSRDEVRVMLAFIHFAPWYRNPMRLRLGEDVKARIEDVAAELDVPVDWVGREEVLGEYLRRGFGNSYDFGQEA
->tr|A0A3D1Q1J9|A0A3D1Q1J9_9FIRM MFS domain-containing protein OS=Lachnospiraceae bacterium OX=1898203 GN=DER20_01345 PE=4 SV=1
-MAKNVERLQAREAKELIRREKQLGARSNKFYLIYLFMILSLIYITDEIASTISIQFQANIVTEFFVKNMGMEYGAGLSLFSAIGFISYPVTLLIIFYRPLADKFGRKPFLVINTLCMGLGLFLVYLSKDIYVYMIGGTLMGFMVSHDMQCVYILECSDAKSRARNYAIVKAVAILGTLLVPLLRATLMQNVSERWHVVYLVPAIVGFVMSLFALLFAKETNAFLIKRIEYLKTPIEEREQRSKEGREQNAQGGILTAVKFAFKHRQLRFLIIACCCFYLASLGTATYSTVMAKSALMTEEEITLALFLYPVGNALFTLISGFVSDKFGRKVTIVAMSCSALTCYLLFIFSGMFKWTPYLTGFAIGGFMGSYWGAGDTIGGIMFSESSPTNLRSSVTVINTLLNGVMGGLATVITMILLPIIPERMFGYMYLGLTVPGLVGAIVIMWLFVGETRGLDLKTVTGTEWDKPKKVKEEQQEGE
->tr|A0A484R0A0|A0A484R0A0_9ZZZZ Uncharacterized protein OS=plant metagenome OX=1297885 GN=ANDA3_0622 PE=4 SV=1
-MTPCLLLRGMCGDLMWAGRGRIAEKRGEMAPLRHRGKSLVSFAGAALRGTPAWCAMPRRRACRHRLRHQFGAGMSTR
->tr|Q5DYX4|Q5DYX4_ALIF1 DUF4123 domain-containing protein OS=Aliivibrio fischeri (strain ATCC 700601 / ES114) OX=312309 GN=VF_A0952 PE=4 SV=1
-MHEQSYLVVNPLEDKEVIERFYHYGGGNAFPLYLDTEFDAQKEIGPWLLPYPPKEFLAYFANKPSGFRIYFSDDIETHIQHWKSLTFAGLDGELVLFRYYDRVVLEAMLVSFNQKELSLFLGSSECIEIISSVGSLCSYENSASQVSYKSEPWWKIEKHHSSYSVERHAWITERLAWQRLPSLMKEIYEKNSDIQSQLINHLIEGRAHRLENEELEAYSMNMLIKDSKQQSHDIYEAWYLDSAQIKTVKQVENLVTRSELQQGTQI
->tr|A0A132B1M6|A0A132B1M6_9HELO S-adenosyl-L-methionine-dependent methyltransferase OS=Mollisia scopiformis OX=149040 GN=LY89DRAFT_633225 PE=4 SV=1
-MHDDEEDTNAIEAESSDGFDGDSAYAGSSAGSLTETLASTIARGIEEHGRTYAAYGNEEYGLPIDEEELDRIDMSHAKYSMLLEKRLFVAPINPQPQRVLDIGTGTGIWAIEMADKYPSAEVLGLDIAPTQPSWVPPNCIFQIDDVEMPWTLGVETFDYIHARDLLLSIRDWPRLVEQSFDHLKPGGYLELQCVYPRIRCDDGSTPPQTGLEQFSAHAQEASVRIGCPLDACTRYAEYMSSAGFEDVVEKRFKMPSAPWAKEKRMKLIGAFEMHNLLKGISGMSLRMFSKGYGWSREEIEVFLVQVRKDIQNLKYHTYYEFIVVYGRKPGGSGATANHSSV
->tr|A0A6H5HNS4|A0A6H5HNS4_9HEMI Uncharacterized protein OS=Nesidiocoris tenuis OX=355587 GN=NTEN_LOCUS22830 PE=4 SV=1
-MIDDLRFLRLSAIPPWETFTLSIVRLLNPFRPMGPSCVIAFKDVFSFHQSLVITCHFGSTWKLCTTAPFSPTNDPHNWIIIGLHWSHNEPYCGMEMIPASLHCRRVTALRKFTRWQQLKEPATISWRILVKTVVIAGLLSVFIDQCERETILNCKGSGAHGRSIWRVEFGHNGDRFLRPSLVVFEDDTDMSFDLDVEYLTPHGSTAPWNPLLVSHRCFLEALFHSSGTQSEVQNRFISEYAEGLKSWAVISVGIVSTVLLNLIMVKQNKKSEARLLDEQTNYEGEFPFPVPDSVFADVERRTSTKRATKNSSGDIINIEPPVKTDRRMSGDHAFTTDPLEEQARSSPRVVAWGPIDRKTPSQMSNINKDPTIQQNLEGITEMKGSPEIYPSKEFSRRISQEGPSGAQRPSNAMSPMVAANPKGVHTFTDSSKSSLGSQVTSDMSMSMTSLSWVDATVEREPFEYKDEQLPRERGNPTNRSV
->tr|A0A5W0I3M7|A0A5W0I3M7_SALTM Transcriptional regulator (Fragment) OS=Salmonella enterica subsp. enterica serovar Typhimurium var. 5- OX=1620419 GN=AT998_25380 PE=4 SV=1
-MRNVIIYGINWTNCYALQSIFKQKYPEKCVKTCNSLTALLHSLSDMPDAGLILALNPHEHVYLFHALLTRLQNRKVLVVADRLYYIDRCVLQYFGVMDYVLKDELSCAIRSEREKLRLPEAWLRFCHRPQKKTVAATYAFNAGETPEEVLFNINQYAWWNLPPGVTQAKYALLILLSSGHPAIELAKKFGLGTKTVSIYRKKVMYRLGMDSSPLSLFRGLKLDAHLQRTAFAHNPAVPDDNCALP
->tr|A0A177BXN8|A0A177BXN8_9PLEO Peptidase C45, acyl-coenzyme A:6-aminopenicillanic acid acyl-transferase OS=Paraphaeosphaeria sporulosa OX=1460663 GN=CC84DRAFT_1169559 PE=4 SV=1
-MDAQKQNLIITKITQAGKPTIVQVTEAGIIGKIGFNSSGVGTLLNAIKVHGVDASRMPVHFGLRAALESNTAREAVQKLESYGMAASAHILISDSSEALGLEFTKSTFAHCKADGKGRIAHANHLLLEHPGEVDTVWLKDSPVRVKTMTNNTEKLSTEPSWEDISRLFEDEHGFPHSICRQGQDGGSTTLFNIVIDLKAKKGVVRLGRPTQAEETVSLEL
->tr|A0A7R9KXX5|A0A7R9KXX5_9ACAR Hypothetical protein OS=Medioppia subpectinata OX=1979941 GN=OSB1V03_LOCUS10746 PE=3 SV=1
-MSKKPEDIVVSGMSGRFPLSVNTDEFAKNLFSGVDMVTEDDSRWPIGLYDMSGRMGKLDCYKDFDSPFFGLNDQIIAESDPQARLLLEVAYEAMMDAGVNPQELRGTKTGVYVGVSIYSMTDGYPEDGQPDLHESMQTLMVQTLANMKTLYSSRISFANDFKGPCLVVDTACSASLSALTLACNDLLLGNTDYAIVCGTHMDFEPFIFQFQQELGICSPDGMSRVLDAAANGFVKAEAVCCVFLQRRQCARRLYGHILTARMNVDGHKKMGMQRRLYGHILTARMNVDGHKKMGMFFPSSEAQEELMRMTYTDAGIDPKKMTFFEAHATGTKVNYMHSCYN
->tr|R5P6Y1|R5P6Y1_9BACT Uncharacterized protein OS=Prevotella sp. CAG:1092 OX=1262919 GN=BN465_01592 PE=4 SV=1
-MKQLLFLLIMITGACTFTSCDKSDDTVDPIKENLFNSKYIVNDAGCCVLDGLQPIRAEIINDEVKGYGWKVIGIYKIMDNGKLSQKDYRDMVYGSGYTDYWFKADNNLIGFLHGDVSGKNYINTEWSYDDSKGYIMRYSADLSISERYMQVLYVATLQGKEFYLYTIQKLGYTTIKNDTTKPFYGLVIYQRMTDKELAEIKKEYKLQL
->tr|A0A1Q2H2K3|A0A1Q2H2K3_9GAMM Acyl_transf_3 domain-containing protein OS=Pseudoalteromonas aliena OX=247523 GN=B0W48_18560 PE=4 SV=1
-MIRINYIDNMKAAGIILVVLGHAAWLNESIYILIYSFHMPLFFFMSGYLASRQHPIKKALIKLNHRLIIPFGFFFFVSFCVWLPLHFFGGGQASNMPWFDPLFRLITAQADSFHINGVLWFFPCLIVISVLQIVIFSKMKLITAFITSAVILSFLLVNVGLIKTRFYWCISIYKFVDTL
->tr|A0A416WAN5|A0A416WAN5_9FIRM Uncharacterized protein OS=Eubacterium sp. AF15-50 OX=2293103 GN=DWW50_03425 PE=4 SV=1
-MTNNEIWENIRHNNMKRDGVNNPIKVDNFVYEIYSLMKERDFSIIESDEIVKSLSGLIENDKKLILREPLKTVEKYNKEG
->tr|A0A7X1RI95|A0A7X1RI95_STRMT GNAT family N-acetyltransferase OS=Streptococcus mitis OX=28037 GN=GEZ71_00850 PE=4 SV=1
-MELRRPSLADKETVLEMMEEFEKYQSPHDGGFWDTENFSYEEWLESNQNQEMGINLTEGWVPAIQLVAFSVKGKAIGFLNLRLRLSNFLLEEGGHIGYSIRPSERGKGYAKETLRQGLQVAKEKNIKKALVTCSVNNPASRAVILANGGLLEDVRDGVERYWIEVANE
->tr|Q2VZI8|Q2VZI8_MAGSA Predicted membrane GTPase involved in stress response Membrane GTPase LepA GTPase-translation elongation factor Translation elongation factor EF-1alpha (GTPase) OS=Magnetospirillum magneticum (strain AMB-1 / ATCC 700264) OX=342108 GN=amb4183 PE=4 SV=1
-MELRNIAIIAHVDHGKTTLVDAMLRQSGTFRENQQVAERVMDSNDLEKERGITILAKCTSVEWKGTRINIVDTPGHADFGGEVERILSMVDGVVVLVDAAEGPMPQTKFVTGKALGLGLRPIVVINKVDRGDARPHEVHDECFDLFAALDADDNQLDFPTMFAVGRDGWADDSLDGPRKDLSALFDLIVAHVPPPRRDLEAPFSMLATTLEADPYLGRVLTGRIYSGTAKLNMQVKGLSHDGQLLDSSVSPSCWPSAASSAFRWKAPRRATSSPSPA
->tr|A0A5M4AG34|A0A5M4AG34_9BACT Uncharacterized protein OS=Prolixibacter sp. NT017 OX=2652390 GN=NT017_31240 PE=4 SV=1
-MKTINIFKAVAILFFTFAAFSCNDLFNWGTRDYSTQLEIGVTKGGAALKSATNDPIYYLDNCELITADAIRISIATPDPGGGDPIPIDDMQDKILPLHAVGNGVASDLIMLLPGTYVVTKFEVLQLVDAGNGGTKYETIMATPMQNSAFSGYVNTPLNYEFEVELYQKKRLLMEVLCFEPTDVASFGFVWTGVDVILGDEICLYVSQCTSNGTETWGPADYSATFYTMIDEQNVGEVYASSGTSSEGWICFPLWSGATDYGVGVHIVYDGSVEEDFIITAAEVNQILLDLQQEPVEAGTGYYLYEIPCPVVP
->tr|A0A1G2MCL2|A0A1G2MCL2_9BACT Uncharacterized protein OS=Candidatus Taylorbacteria bacterium RIFCSPHIGHO2_02_49_25 OX=1802305 GN=A2W52_04225 PE=4 SV=1
-MLEEQTPTQTYPPELKRIKTFQSDVEELIQKQQISKAAIALAESERRVKKEEVSAQPSAPAPAYSAKILTLSGGLPPAAPKWNTSTLLAVVVLVLAVLGMGTGVYFFLKQNAPLQISPPRVNVKSGTAITLNTKESREKIVEKIRSHVQALSVPQNEVRVIPIVLDGKTITTTELLEEIEASVPAALLRALGTEPVLGVHGFRGGQPFLLFSVHSYDHAFDGILSWEPNLLREVGPLFGISVRNILGRVASTTSDILENTLTIKDVIIRNKDARVVLGPGEEKIFLYSFLDKETLVLTTNTDTLQFLIGKAWGGRLR
->tr|A0A3Q0R773|A0A3Q0R773_AMPCI Interferon regulatory factor 8 OS=Amphilophus citrinellus OX=61819 PE=4 SV=1
-MSNSGGRRLKQWLMEQIQSAQYSGLQWEDESRTMFRIPWKHAGKQDYNQEVDASIFKAWAVFKGKYKEGEKAEPATWKTRLRCALNKSPDFEEVTERSQLDISEPYKVYRIVPEEEQKHGKSPMMAVTATTSSGEITDMDCSPELEELIKEEEGCSIQASPEYWSQGSINAFPLHQDPLPSSSLSSALCQMMISFYYGGKLMHSTLVTHPEGCRISPQQHLGRGALYSSDSMQSVYFPPAELIEFERQRYVTRKLLGHLERGVLVRANQEGIYIKRLCQSRVFWSGLGEVGSQYGSMPGKLDRDAVVKIFDTGRFLQALQLYQEGQIPAPDPTVTLCFGEELNDHNSAKSKLIIVQITAVNCQHLLETMNVRRSQPYCNNPNLEMPDEVVTDQMARIYQDLCSYSGTQRPACYRDNMPITA
->tr|A0A7L0PVY4|A0A7L0PVY4_9AVES EHD3 protein (Fragment) OS=Mesembrinibis cayennensis OX=1118748 GN=Ehd3 PE=4 SV=1
-MFSWLGTDDRRRKDPEVFQTVSEGLKKLYKTKLLPLEEHYKFHEFHSPALEDADFDNKPMVLLVGQYSTGKTTFIRYLLEQDFPGMRIGPEPTTDSFIAVMQGDVEGIVPGNALVVDPKKPFRKLNAFGNAFLNRFVCAQLPNPVLESISVIDTPGILSGEKQRISRGYDFAAVLEWFAERVDRIILLFDAHKLDISDEFSEVIKALKNHEDKMRVVLNKADQIETQQLMRVYGALMWSLGKIVNTPEVIRVYIGSFWSHPLLIPDNRKLFEAEEQDLFRDIQSLPRNAALRKLNDLIKRARLAKVHAYIISSLKKEMPSMFGKDNKKKELVNNLGEIYARIEREHQISPGDFPNLRKMQDQLQAQDFSKFQPLKSKLLETVEDMLANDIAQLMVLVRQEESQRPTQMVKGGAFEGTLHGPFGHGYGEGAGEGIDDAEWVVARDKPMYDEIFYTLSPVDGKITGANAKKEMVRSKLPNTVLGKIWKLADIDKDGMLDDEEFALANHLIKVKLEGHELPNELPSHLLPPSKRKITE
->tr|A0A815YX94|A0A815YX94_9BILA Hypothetical protein OS=Rotaria magnacalcarata OX=392030 GN=KQP761_LOCUS19763 PE=4 SV=1
-NNGTLVAGGNGQGSVLNQLNSPACLFVDRDHSVYVSDYSNNRVMKWVEGAKEGIVVAGGQGGGSALTQLNYPVGIFVDALGTLYVADSRNHRVMRWAQGAKQGTVIVGGNDQGAGANQFNTPIGLSFDRHGNLYVGDWNNHRVQRFSIE
->tr|A0A2V4LES8|A0A2V4LES8_PSEAC Peptidase OS=Pseudomonas alcaligenes OX=43263 GN=DMO17_00310 PE=4 SV=1
-MRSTTLRRWSFVHTWTSLICTLFLLLLALTGLPLIFHHEIEHLLGEAPQLRELPADSPRLSLQQLVEAAERHRPGEVVQYLGWEEDEPNGVVTIMAATAGTEPNSSHTFMLDARTGEAVEMPAANGGFMMLMLRLHVDLFAGLPGKLLLAFMGILFVVAMVSGVVLYAPFMRKLKFAEVRRDKSTRLRWLDLHNLIGIVTLTWALTVGVTGVISACADLLIEAWRNDTLATMVEPYRDAPPLTERAPADELLRIAGEAVPGMRPDFIAFPGTRFSSAHHYAVFMVGSTHLTSHLWTPVLIDARSLAVTAVGDRPWYMDALAMSQPLHFGDYGGRPMQILWALLDGLTIIVLGSGLYLWWVRRRAPRQALRDEVAA
->tr|J3LRP0|J3LRP0_ORYBR Uncharacterized protein OS=Oryza brachyantha OX=4533 PE=3 SV=1
-MRGGGRDDEEAAHKLKSMDVDKLENGANGADTPPRPALKYHGWRAMPFIIGNETFEKLGTLGTSANLLVYLTQVFHMRSVDAATLLNGLNGTTSLAPIIGAFLSDAYLGRYLALAIASVASLIGMFLLTMTAGAEGLHPAECGVGEACEKATSGQFAVLFISFAFLVLGSAGIRPCSMPFGADQFDPHTESGKRGINSFFNWYYFTFTSAMLVSATVIIYVQSNVSWPIGLGIPTALMFLACVLFFLGTRLYVRVTPEGSPFTSIVQVFAAAARKRSLKQPKDPKQDLFDPPHTSAIVTKLAHTDQFRCLDKAAIVAGPDEVRSAGGGGPAPANPWRLCSVQQVEEVKCLIRIVPVWSTGIIYYVAVVQQSTYVVLSALQSDRHLGKSFQIPAASFTVFAMLAQTLWIPIYDRLLAAAPPQGHRQGRGAHAPAAARHRHRALHGGHGDVGHRRGPEAAHRADAADAGDDHHRRRHLRHVQPVDGAAAHGAGPLRGVQPHQPDRVLLQGDPGAHAERRRRAGLLQPRARQLPQRLPRHHRAPDHRLRQQLAGAGPQQGEARPLLLDDRRHWHLQHRLLHDLRQVVQVQGSSQLRSESLFIWVVN
->tr|A0A177BWM7|A0A177BWM7_9PLEO SEC14 cytosolic factor OS=Paraphaeosphaeria sporulosa OX=1460663 GN=CC84DRAFT_1169075 PE=4 SV=1
-MAATGAKELTLDPKYDDYDYPTTAPTPQNGHPGHTTPEQDAQVHQLRAMLEQAGYTKNLDTLTLLRFLRARKFNVELSKQMFIDCEKWRASYADVGVEELVRTFDYKERPEIFKYYPQYYHKTDKDGRPVYIEQLGNVDLTAMAKITSQERMIQNLVCEYEKMADPRLPACSRKSGYLLETSCSIMDLKGVGIAKATSVYGYLQAVSAISQNYYPERLGKMYVINAPWGFSGVWSVVKRFLDPVTVNKIHILGSGYQKELLAQVPAENLPKLFGGSCDCPGGCELSDAGPWQDDQWVKPPKWAKKAEDKNVIDNTGVPAPTADAPQQPLTGAGPEGVEPAAAPAQNPNTANSA
->tr|A0A371GLZ4|A0A371GLZ4_MUCPR H(+)-exporting diphosphatase (Fragment) OS=Mucuna pruriens OX=157652 GN=CR513_26426 PE=4 SV=1
-MFPGATLFLFTEYRYLTMFMGVFGALIFLFLGSVKGFSTQSEPCIYNKGNMCKPALASAICSSVAFLLGALTSVLSAFLLVLYIAINLFKLYYGDDWEGLYHCITGYGLGCLSMTLFERVGGGIYTKAADIGADLVGEVEHSIPEDDPCNPANFICTSVFFLQYEILLTPGSPLLIPIPNKCWKQNLGGFYHPPIDQSFLFSLPRHTLDPCYRKLQEPVNSAPTKPGSTALIPVDRIGYCRQHRR
->tr|A0A5E8VDI2|A0A5E8VDI2_9BRAD ArgE/DapE family deacylase OS=Bradyrhizobium sp. LVM 105 OX=2341115 GN=D6B98_18630 PE=4 SV=1
-MNAETQQRILDAVDAGFEAQLATTRDFVAIPSTRGAEGPCQDMIGDLLRERGYEVDDWHIDVDDLKDLRGFGPIEHDFSKARSVVGTYRPQTNDGKSLILQGHCDVVPAGPLELWDTPPFSPVIKDGKMFGRGACDMKSGTIGALYALDAIKAAGFKPTARIHFQSVIEEESTGVGALSTLQRGYRADACFIPEPTGGKMVRSQVGVIWFRLRVKGHPTHVAFAGSGANAIMAAYHLIQALQKLEIEWNERAKADRHFKTLNHPINFNPGIIKGGDWASSVPAWCDVDCRIAVLPGWSIADHQKEIMACVAAAARNHRFLANNPPEIEWSGFLSEGYELTDAAAPEAAFAKAFGKVYGGVPEDLVFTALTDTRFYGLNHGIPSLCFGASGGEMHGFNEFVDLESLKKTTKAMALFIAEWCGLEKA
->tr|A0A498CZE4|A0A498CZE4_9GAMM Uncharacterized protein OS=Acinetobacter cumulans OX=2136182 GN=D9K80_11310 PE=4 SV=1
-MGVAIDLTNTERRVSTAEFAMRMNVSEKELYDRIRDGRIKAPAKDGRKNYWLNSYVLECITGVEDGASLLV
->tr|A0A853LVH8|A0A853LVH8_9MYCO Acyl-CoA dehydrogenase OS=Mycobacterium colombiense OX=339268 GN=A5628_13360 PE=4 SV=1
-MLLELDDDQRLWRETVRGALTKQCPPSLVRAIAEGGADGGDLWQWYIEQGWTELTSAESLVELTLLLEELGRASDPTPFLATTTQFAPLVGDRVPQDGAGAAVYSGVTACRDRGGWVLEGAARYVLDADRADQLAVVTPAGVFVVEAKAASSRRVAAIDPVLHLADLRFNEVHVSDAHRIASDTERAWHIALTGMAITIVGACQRIVDMVLEHLKQRYQFGVPIGSFQALQHKAADMHVAIERARALAYLSALTIVADDPRRRLFAAMAKAAAGEAQSLVVQHGLQCFGAMGFTWENDLQFAIKRAKAGELMLGDAAEHRALIAREYRAADF
->tr|A0A3B3U8V4|A0A3B3U8V4_9TELE DENN domain containing 3 OS=Poecilia latipinna OX=48699 PE=4 SV=1
-MAELPSGLLEACVVVGAPSDKLRELPQHTKSSELPLLDPEVLQVHAPPFVSIEANSNHVIGPAFSRVQRRRSFIKKKRRDRAAEGVSNGDSSSRHEASPVPATEDISVPKDLDLIALPQLCFPDGLQLASEQKDDAYHFLVFTDLFGNRTHGVVVHYYRAVQSFQDSVFQNGHRWNAPKSRLFAPFAVCIISKFPYYNALKDCLSCLLVQLRTVRQADLEETIREFSAKLSLVPLPPPGQLHVSFSLRPLQVVLPSRDDQDSPVVDLNLHLPLLCFTHTALLQVLSCLLQEQRIVFFSSDWARLTLVAESLLLYLQPLSWQQPYVPVLARGMLDFLMAPTAFLMGCHINHFEEIAAETEDLILVNVDDGFIQTSWSEAVDLPALPLAAAECFISRAESLQLQYDLELCHLGTGTDVNTLRSQRRGWQQKLNSQIQNIALELVVNIFRGVQDFLNHEHRVFNSEEFLRTREPDDQLFYRKVLETHIFHSFLRDRLNRKRDSFSRMEQMTQSHAHRNRAMTESPRRPPMSELSRAGPDRKLSKRLGASLPNLDQPINESVPLNANRLLSIRKISPDSGLKFLQKPLKVFRLPEFPPPLAYHYVQNYYSDMVASLGKAINATPPDESALLARYHYLRGLVNTVSNRRLDALEDFHSLYKTDAGIFPSQMVNSLIDSLPDVERVQADRRPEIKRLISRLKREQERERATQGTGQEDAAVKRFQLPKKYMHLEEFVKCVQESGIVKDQGTIHRLFDALTVGHQKQVGPDLFRVFYTIWKETEAEAQEVCLPASVLEHIDAAECVFKLSSSVKTSRGVGKIAMTQRRLFLLTDGRPGYVEVAQYRDLEEVRVSSAPFLVLRIPSLKIRVHGRKETFEANLKTETELWNLMIKEMWAGRSIADRHKDPQYMQQALTNALLMDAVVGSLQSSKAIYAASKLAYFDRMSLEAQMMVPSTTSETLKHKINPSVEFAVPQAVDVLLYTPGQLWVSVGGGKVMVYDASSWSLIQTCQVGNARLNCMLGVDRDQVWMGSEDCVIYIISLVSMVCNRQLTEHRAEVTGLALDNEKYCHKVAYSCSAEGTVMAWEVSTLQVKRHFRLSCDRLQSVYSCGGVLWCCARDGIMEVWRNGTLKQHINLPEQQRVTFSSALLITESEELWSVCVDSAEVYIWHIKNTSRPINRVMLQDCIGCYCMIQVKNQVWVGGMGRSSTKGKIYILDTERYEVLKELHGHIDKVTALCSAEDRYVLSGAAKHDGKVAIWKVEDRGLDSSKC
->tr|A0A6P9APX4|A0A6P9APX4_PANGU pentraxin fusion protein-like OS=Pantherophis guttatus OX=94885 GN=LOC117655567 PE=4 SV=1
-MVEASIIPVGDPNVAVGKLSSQSSTFEEKGESRKAIDGSLANIYTNGDCTLTKKDFEPWWMVDLISAFQVSAVVITNRGDCCESRIQGAEILIGDLPQKGGTMNPRCATINSMERGETMSFNCAGMQGQYVTITIPGRYEYLTVCEVQVLAYPWLRIVHGGRSPVLDSDTDSGLQGRVLSFPNESKDSFVIISPMQPFNLMEFTLCMRIAVEYLDEHEIILFSYHSQRDELRVLREAMGHFGLHMGGRSVRFALPDLSPLGSHICVTWESVFGLTAFWMNGKSSIRKVHNMGHILQAGGTAMLGQDQGAQNMSDQQKPHFVGEITDLYMWDYVLKSHDIQKVFQAHEFPRGNIFDWKILSYKIRGNVMVLPKG
->tr|A0A087WPU9|A0A087WPU9_MOUSE La-related protein 4B (Fragment) OS=Mus musculus OX=10090 GN=Larp4b PE=4 SV=6
-MTSDQDAKVVAEPQAQRVQEGKDSSHLMNGPISQTT
->tr|A0A4Q7AXS9|A0A4Q7AXS9_9GAMM Efflux pump membrane transporter OS=Acinetobacter bouvetii OX=202951 GN=EXE25_14110 PE=3 SV=1
-MSQFFIRRPIFAWVIALFIILLGVLSIPKLPIARFPSVAPPQISITAIYPGATPKTLNDSVVTLIEREMSGVKNLLYYSSSSDSSGTATITATFKPGTDVELAQVDVQNKIKAIESRLPQTVRQQGLMVDAASSGFLMMVGLSSPNGKYSEIDVSDYMTRYVIEELKRVEGVGKVQNFGAEKAMRIWVDPDRLISYGLSIKDVNTAIQNQNLPISPGRIGDVPALTGQQITIPLTAQGQLETVEQFKNISLRAQQNGANVRLSDVARVEIGAQMYNFAILENGKASTAVAIQMSPGANAVKTAEGVKAKIEQLSPALPDGMKFSIPYDTAPFVKVSIQKVIATLLEAMVLVFIVMFIFLHNVRYTLIPAIVAPIALLGTFSVMLLAGFSINVLTMFGMVLAIGIIVDDAIVVIENVERIMATEGLSPVEATSKAMKEITNPIIGITLVLAAVFLPMALAAGSVGIIYRQFTITMSVSILFSAFLALTLTPALCATMLKPIDLNHKKKGIFAWFDRSFEKLNNRYERSLFKVIQHKTIAMLCFLSIVIVLIFSFKQVPTAFMPEEDQGWFMTSIQLPADATQERTRKVVAEFQNHLDQETGIKDNMAVLGFGFSGSGQNTAMYFTNLLPFEERTITAQEVVNNANMAMAESSEGQTMSVLPPAIDELGNSSGFSLRLLDRGNIGMPALREAQDQLLALAAQSKLVADVYPEGLPDGSSVQLKIDRDKLQALGVNFSDVTDIISTSMGSMYINDFPNQDRMQQVIVQLDAKSRMSIEDILQIKVNSQSGKLVSMSEIITPIWQHSPQQYNRYNGRPSLSITGSPAAGMSSGQAMSEMENLIKQLPKGVGYEWTGISLEEKQSESQTLFLLLLSMLVVFLVLAALYESWSIPLSVMLVVPLGLIGAFLAVMLRGMPNDIFFKVGMITIIGLSAKNAILIVEFAKALRVEGMGLVEATVAAAKLRLRPILMTSLAFTCGVIPLVIASGASSETQKAIGTGVFGGMISATVLAVIFVPIFFIVVMSTVEKFSKRKAAH
->tr|M6TB98|M6TB98_LEPIR Transposase DDE domain protein OS=Leptospira interrogans serovar Bataviae str. HAI135 OX=1085538 GN=LEP1GSC170_1474 PE=4 SV=1
-MKNKLMPLVDKILLRKRAIIESVNDELKNICQIQHTRHRSFCNWAVNLLSGLVAYSFFPKKPSLNLRSKDNLQLLISP
->tr|A0A2D0KA88|A0A2D0KA88_9GAMM Adenosine deaminase OS=Xenorhabdus ishibashii OX=1034471 GN=add PE=3 SV=1
-MIDIQLPLTDLHRHLDGNIRPETILDLARQHNIPLPAYELEALRPHVQIIENEPNLVSFLQKLDWGVTVLADLEACRRVAVENVEDAVNAGLDYAELRFSPYYMAMKHQLPVEGVVEAVIDGIHSASQQHDIQIRLIGILSRTFGEQACTEELAGLLAHKQHITALDLAGDELGFPGHLFEQHFIRARDAGWNISVHAGEAAGAESIWHAIRELGATRIGHGVKAITDPTLMDYLAKNGIGIESCLTSNLQTSTVSSLPAHPLKQFLEHGILASINTDDPAVEGVEIRHEYTVAAPAAGLSPAQIRQAQINGLATAFLSEAEKQALKTKVANR
->tr|A0A2K6SAF3|A0A2K6SAF3_SAIBB 35 kDa nucleoporin OS=Saimiri boliviensis boliviensis OX=39432 GN=NUP35 PE=3 SV=1
-IQPPLSGFNMFSPASIGQPRKTTLSPAQLDPFYTQGDSLTSEDHLDDSWVTVFGFPQASASYILLQFAQYGNILKHVMSNTGNWMHIRYQSKLQARKALSKDGRIFGESIMIGVKPCIDKSVMESNDRCALSSPSLTFTPPIKTLGTPTQPGSTPRISTMRPLATAYKASTSDYQVISDRQTPKKDESLVSKAMEYMFGW
->tr|A0A0D6JIV9|A0A0D6JIV9_9HYPH Probable membrane transporter protein OS=Candidatus Filomicrobium marinum OX=1608628 GN=YBN1229_v1_3342 PE=3 SV=1
-MGRESVGDVGFMDIGMTWAGFSMLAFSLLAAGVIVGFLSGLLGIGGGGILVPVLYETFAALGVDPAIRMHMAIGTSLAVIIPTSLRALMAHSAKGVVDWVAVRRIGPWIVIGVVLGIMFADQVTGTTLKWVWVVFGTLFAAKMAFGRDTWRLGHDLPALPKLEIFSVLVGIISVLMSIGGAAFIVTFLTLYGRPILTAVATSSAIGPLIAIPGAIGMMWAGWGHPGLPPLSLGFVSLLGAALIVPSSVLVAPVGVRLAHGVSRRKLELAFAVFLVVIVLRFLSSLILE
->tr|A0A353GX24|A0A353GX24_9FIRM Aspartokinase OS=Firmicutes bacterium OX=1879010 GN=DDW50_18565 PE=3 SV=1
-MKVIVQKFGGTSVATREGRENVASKVKEALGKGLGVVVVVSAMGRNGDPYATDTLIGLARGVLKYIKPRELDLLMSCGENISTVVMVQTLKAHGIEASAFTGGQAGIITDHHFNNARIIEIKPDNLWKCLEEGKVAVVAGFQGVTKDGEITTLGRGGSDTSGSALGVALHAELVEIYTDVDGIMTADPRLVPQAKPLPVMTYNEVCEMAHLGAKVVHPRAVEIAMEGRIPLRIRSTFSNNLGTLISDGTSIGDIEIRNGKVVTGLAQIAEMALVKIISKVDLNQNGAVLKIFQVLAGAGISVDMIQVAPLNIAFIIKEDLVDKAKEALSPLGLELLVEKGYAKVAIVGSGMRGIPGVMARMVKGLQKEHIAIYHSTDSHTNIACLVKQEDMCGALQALHDEFELAE
->tr|A0A1N6LEK7|A0A1N6LEK7_9BURK Amino acid/amide ABC transporter substrate-binding protein, HAAT family OS=Paraburkholderia phenazinium OX=60549 GN=SAMN05444165_6866 PE=4 SV=1
-MAAKWGRVVAAALAAMVMTAAYAAGETGVPSSSAAPGGKPIQLALIEGMSGPFANAGAAVERNLRFGVEAVNAHGGVKLADGAHPLELVVLDSKGSPEEALLQLRAAADRHIGYVLQGNSSAVAAALIGAIDKQNSREPDNRELFLNYSADDPALTNAACSFWHFRFDAHAGMRMDALADVIQHDPSVRKVYLLNQDYSFGHDVSALARSALAAKRPDIAIVGDEFHPIGRVKDFAPYIAKIRASGADAVVTGNWGNDLTLLVKAAREQGLDTKFYTFYGNSLGAPAALGDAGVKRVIAVADWHPNAGGAASDAWYKAFRARYPAAQDDYPVLRMELMVEMLAAAMNKAGSAEPEAVAKALEGMKFDNGFHPSWMRAEDHQMIQPLYVMEMDKAGTPGVRFDNEGSGYGFRTVLALPPGRTVAPATCRMTRP
->tr|A0A850WM95|A0A850WM95_FREMA SIM1 protein (Fragment) OS=Fregata magnificens OX=37042 GN=Sim1_1 PE=4 SV=1
-KEKSKNAARTRREKENSEFYELAKLLPLPSAITSQLDKASIIRLTTSYLKMR
->tr|A0A482IAK4|A0A482IAK4_9DIPT Cytochrome c oxidase subunit 1 (Fragment) OS=Tipulidae sp. BIOUG26266-C02 OX=2544765 GN=COI PE=3 SV=1
-FIMIFFMVMPIMIGGFGNWLVPLMLGAPDMAFPRMNNMSFWMLPPSLTLLLASSMVENGAGTGWTVYPPLSAGIAHTGASVDLAIFSLHLAGISSILGAVNFITTVINMRSSGITLDRMPLFVWSVVITAILLLLSLPVLAGAITMLLTDRNLNTSFFDP
->tr|A0A2A8TFK0|A0A2A8TFK0_9BACI Transition state regulator Abh OS=Bacillus sp. AFS017274 OX=2033488 GN=CN380_26055 PE=4 SV=1
-MKSTGIVRKVDELGRVVIPIELRRTLGINEKDALEIYVEQERIILQKYKPNMTCQVTGEVSDDNMKLADGKLILSPEGAELLIKEIQASMEPAK
->tr|A0A531KVX5|A0A531KVX5_9HYPH M20 family metallopeptidase (Fragment) OS=Mesorhizobium sp. OX=1871066 GN=E5X43_21305 PE=4 SV=1
-MDTVPIDRWESDPFSGEQRDGRIYGRGSCDTKGSLAAMLIALSSLGERQPRATVVLAASIDEEYRKLGARAIADSGVTYEGAVVGEPTELELVVAHMGSVRWQIEVQGVPAHTSKPHLGVNAITGMAKVVLALDEHHRSLVSRAQHPLVGSAQLTVSLIEGGLELTTVPPVCRIWVDRRLIPGEQPQDALAEVESILEGLRQGEDKINVRSLLPALEDPPPISSESSRIAAVAAAACAHVAGTGEQKGATGGSDANQLSLAGIPCVIIGPGRTAQAHTNNEFVEIAQLIKAAELYQKIM
->tr|A0A2D5TAC4|A0A2D5TAC4_9GAMM Uncharacterized protein OS=Gammaproteobacteria bacterium OX=1913989 GN=CMP85_02235 PE=4 SV=1
-MTFDLVTDRNTCPLLDTRSFVMLRTTCRTHYRDDEAWALRTRDVLLRVSTLTPRQTLGLNYLYKYALQFDAPVGSTEWFQNIVNWLDFKSSIRIVHSFMFETRPKLLYSLDFGTLSPGPRMLWQRLWCRYERVYKKHLKKRKSDLFDVVPCKKRRVLCH
->tr|A0A833PV08|A0A833PV08_BURL3 HTH-type transcriptional regulator NimR OS=Burkholderia lata (strain ATCC 17760 / DSM 23089 / LMG 22485 / NCIMB 9086 / R18194 / 383) OX=482957 GN=nimR_1 PE=4 SV=1
-MTANDYAAGTTFPEHAHGRGQFAFASRGTISVSTPHGRWLVPPQRACWVPAGVRHEMTMTGPVTMLNTFVSGDAAQEAGLPEQCGVYGVSALLRQLIDDAIDLPALYDVDGRAGKLMALLVAEIATMPRLSLHAPLPADARLAKVCRHLLASPSIAADLDQVAADAGVSRRTFTRQFRAQTGVSFAAWRQQVCMLSAIARLSDGQPVTRVALDLGYASASAFTSAFRRILGDTPSRYLEIRR
->tr|V7PXT1|V7PXT1_9BACT Cupin_2 domain-containing protein OS=Parcubacteria bacterium RAAC4_OD1_1 OX=1394712 GN=O210_OD1C00001G0424 PE=4 SV=1
-MKKGFKENIEKLTEENNNFRKVLYTGASSQLVLMSLLPNEEIGMEIHNENDQFFRFEKGSGKVIIDTTEYEVKDGDAVVVPMGARHNVIAGEEGLKLYTIYSPAHHKDGIVRETKEEAEQNEADFDGQTTE
->tr|A0A1L8MN76|A0A1L8MN76_9STRE D-alanyl-lipoteichoic acid biosynthesis protein OS=Streptococcus bovimastitidis OX=1856638 GN=A9Q68_01415 PE=4 SV=1
-MNEKRKILMLFIGKTVLFYLIFILLIYIFDYLGHGQSAFIYNEF
->tr|A0A846M925|A0A846M925_9BACI 2,3-bisphosphoglycerate-independent phosphoglycerate mutase OS=Saccharococcus thermophilus OX=29396 GN=BDD39_000516 PE=4 SV=1
-MSKKPVALIILDGFALREETYGNAVAQAKKPNFDRYWNEYPHATLTACGEAVGLPEGQMGNSEVGHLNIGAGRIVYQSLTRVNIAIREGEFDRNETFLAAMNHVKEKGTNLHIFGLLSDGGVHSHINHLYALLRLAAKEGVKNVYIHGFLDGRDVGPQTAPKYIKELQQKIKEYGVGEIATLSGRYYSMDRDKRWERVEKAYRAMVYGEGPTYRDPLECIEDSYQHGIYDEFVLPSVIVREDGSPVATIKDEDAIIFYNFRPDRAIQISNTFTNEDFREFDRGPKHPKNLFFVCLTHFSETVKGYVAFKPTNLDNTLGEVLSQHGLRQLRIAETEKYPHVTFFMSGGREEKFPGEDRILINSPKVATYDLKPEMSAYEVTDALLKEIEADKYDAIILNYANPDMVGHSGKLEPTIKAVEAVDECLGKVVDAILAKGGIAIITADHGNADEVLTPDGKPQTAHTTNPVPVIVTKKGIELRKDGILGDLAPTMLDLLGLPQPKEMTGKTLIIKK
->tr|A0A5C3E0M0|A0A5C3E0M0_9BASI Related to MRPL44 - mitochondrial ribosomal protein, large subunit OS=Ustilago trichophora OX=86804 GN=UTRI_01617 PE=4 SV=1
-MSIAAASLKHITAMSFEFAPLSASQASRSMRLLLARLPTKAPMPGMDLPDISTKTVATDALQKIEITYKNKQKLVLDHVASETRLSDLVKKIEEPARALRLKEEGL
->tr|A0A812PJQ8|A0A812PJQ8_9DINO GrpE protein OS=Symbiodinium sp. CCMP2592 OX=631055 GN=grpE PE=4 SV=1
-MLDRVSAGPTDCLLGKCLCKDGYCADGDMCKPQVCFAGAEPPRFRPNRWLAFYSGMSDLEQFPEYEELEEEYVQFVLRISPVPLLFLLLGVVVSITTCACLCCGGSGYHFSMDFSDMTHDETKGFVSGTTGNAVIGDEEFARRAWKKRPSCFPMFCAALLIILLCFFGGLTRIVNAAWTEYIIVSSLDRAMDNAADIANASLTINETVTHLHDKLLELPLTCKTDSKAAKQVLYTFVHSALGAIDDYVEQVYFIVETVQPIPDQIGKFKQLTHRAKPFFASLPLAPLWLVAFICIGIVVEATCTTCCRSSSLARCVDVGLKLSALLFGLIVFVVAVLVCVETIVLIALSKFCEDVDHNVLSYVNSTTYNISYIIPEIANYYIRGGDRNPIDEYDTLAMKYINQIQDYYNQAAIGVAGLGMACPAFFDLDVNAIATKARGILGKARELLKGENIYPYYRKVIRAGICNVVISGVGHPS
->tr|A0A5C6ACY5|A0A5C6ACY5_9BACT Isoleucine--tRNA ligase OS=Rhodopirellula pilleata OX=2714738 GN=ileS PE=3 SV=1
-MTVPPPKPSSKPSLPSSVDLSSTSSAGGFRAADGSPSFPKLEEEVLAFWDANQIYEQSLARRADAPTFVFYEGPPTANGMPHPGHCLTRAIKDVFPRYKTMRGYRCERKAGWDTHGLPVEVEVGKELGIHSKEEIEAYGVEPFIQKCQQSVWRYMQQWQTLTRRLGFWVDLEKAYVTYHQSYVESVWWSLKNLFDRDLLYQGHKIVWWWAQGGTALSAGEVGQGYREVADPSVYVLFPLIDDNNKKTKRSLVVWTTTPWTLPSNMYAAVKADLDYAVVEDSETGEQLILAEALVETLAGKIKRELRTIETVSGRSLVGMRYVPPFENYRDTLADPVGELKDGGSDSLYWRVVAADFVTTDSGSGLVHLAPAFGEVDHEVLVEERMRFVDGQRPDLLCAVGPDGKFTDDFPSLKGEWVKAADKTLTRDLRERGLLLHLEQYLHDYPFCWRAEEDPLIQYPRESWFIRTTKFRDLMLKNNSKIGWQPEHIQDGRFGNFLESNVDWALSRERYWGTPLPIWVCQSTGRMEAIGSYDELLAKPGVEGTEVWAQAKAENPELVDDLRVHKPYIDAVTYASPFEDGARMKRVTEVIDCWYDSGAMPFAQWGWPHQNHDRFAEQFPADFISEAIDQTRGWFYSQLAISTMLFGEGASIGTDLNTDVPTVSTDAAQDYPHPFRNCIVLGLMLSQWYEAANESGPKTIVLTEEETAEHADLKFTKKTGKMSKSLRNYRSPSEIFDRYGADAMRWYFFANQAPWNSIIYADQAIRDSIPEFLLRLYNTFSFFTIYAEIDGFDPTLAADADDQLSPASLASATTYRDVSQRSEIDRWILSELNRTLEVVVERMDKLDNYNACQAITSLLDGLSNWYVRRSRDRFWGSDKASQDKLDAYWTLYESLVQLTKVIAPFVPFLADKLWQELTRPFGDRVLRSVHLTDYPTADSSRIDASLSESMKVLREIASLGRSARADAKLKVRLPLSKVEVILANDSQIGWLESHDQLVLEELNVKAVEYTTEGGDYVQYNVVPNFKRLGPKVGKNIPLVKKMLGEADGNELLGQLQTSGKVTLAMPDGPLELDNEDIEVRLKAREGWAAAQGTSCVVVLNTEVTDALRREGIAKDLIRAIQSQRKEMKCEYTDRIEVAIVSDDADTEAAIAAHREMICEETLAIRLADQPLQAIDATSIENGQLFVAKVPGE
->tr|A0A165E1C3|A0A165E1C3_EXIGL Uncharacterized protein OS=Exidia glandulosa HHB12029 OX=1314781 GN=EXIGLDRAFT_725429 PE=4 SV=1
-MSAPAAQDDADAMDVDATPTPKPARAPRRRRGRPQPPHVQTPRSATAPTTDAHVPFPTSAGPPSPTKSPTKQRSMPDHAFRRPSSPTKTRSSWFDASDTDLTSLGRSTSPTKSGSWASSRSSRSSSPSKSSRSSARPPSPTSLPWAEGRIPPSPSKTSLSSGPDSPQKVRNRPPSLRLHDNPDGIDPSTIVGKVLKRVHRGAAHPNLTLVFADDSVVQVKIEGYHPNARGLSKELEMDSSLDDFLASSAASTVDLLILDCALVRLTDKAFERSDSDASNDSRWSQDHLGLAFKFEGMPHRWYSVWATMQDFDDDGICRFRSYDDVFLSPVAQTPRRPRHARKNSKQIV
->tr|A0A7C1SJJ1|A0A7C1SJJ1_9SPIR ZIP family metal transporter (Fragment) OS=Spirochaetales bacterium OX=2026792 GN=ENI06_01135 PE=4 SV=1
-MIFTWFTNQHPILQALLATIFTWLVTALGSAMVFFFKEVKRKVLDSMLGFAAGVMIAASFWSLLAPAIAMAEESGAIPWIPALVGFLMGGLSLRLIDIFLPHLHLGLPMEQAEGVKTSWHRSVLLVLAITLHNIPEGLAVGVAFGALYHNLPGASLAGAIALALGIGIQNFPEGAAVSIPLRREGLSVSKSFWFGQLSGLVEPVAGVLGALAVVVMKPILPYALSFAAGAMIFVVVEELIPEAQMEKNTDIATMGAMLGFAVMMTLDVALG
->tr|A0A2M6W0D3|A0A2M6W0D3_9BACT Uncharacterized protein OS=Candidatus Magasanikbacteria bacterium CG10_big_fil_rev_8_21_14_0_10_43_6 OX=1974650 GN=COU33_04145 PE=4 SV=1
-MNVFRVWRKIQNTSNSEKTVLIIGDIKNKIKGLGGDYLSPIVFFLQKSGKLLFLANFVIMRV
->tr|A0A0K2J648|A0A0K2J648_PORGN RND family efflux transporter, MFP subunit OS=Porphyromonas gingivalis AJW4 OX=1403336 GN=PGJ_00014360 PE=3 SV=1
-MQLSGYRVVWLPFIFLMALSVVGCNGGKKKTADTSSGEDMELFTSGGDTIDVQIAELKLGPFDRQIVSHGKLRARETAVLQFEDSRQPLHRLYVRNGQHVVQGQKIAAVDDRTALLEVQKSEDEFKQRELDLQDVLVGMGYSPHDKSDIPADKLALACIKSGYNIAESNYKQAQLRLKHVCLTAPISGVVADLHAQEHTIPESGKPLCRIIGDNGFEVVFEVLESELSAIRTGERVEIRPVALRDVTAEGVLQEINPSVDDRGMVQVSAGLRNPSKNLFDGMNVEVRINQRMEERMVIPKSAVVLRSDKPVVFSVRNGTAAWNYVDIEAENAESYCIVSKTLKPGEMIVVDGNANLAHKTPVALRR
->tr|A0A2G5ISA1|A0A2G5ISA1_9ACTN Uncharacterized protein OS=Streptomyces sp. HG99 OX=1958787 GN=B1C81_17685 PE=4 SV=1
-MTTPPPQGQNPFAQGQQPYGQPPQGQNPYGQQPGQPGFPQQGAPYDPVPPQRPKRGIKQYLRIAVIVFAVIAAGVGWIASRDDANTAKVGDCMSISNPESTTDPGLEVVDCSSSKAKYKVEEKKSDNSGCDRTKYSEYTETGKNDFTLCLSEYSAK
->tr|B9YBS2|B9YBS2_9FIRM Resolvase, N-terminal domain protein OS=Holdemania filiformis DSM 12042 OX=545696 GN=HOLDEFILI_03279 PE=4 SV=1
-MDAQEVMHMTDYSKITALYSRLSVGDEDRDGGESNSIQNQKIFLENYARGQHLTNIRHYIDDDESGRFFDRSAYSRMMDDVENGKIGVCIMKDLTRWGRDYLQVGNAMEIFRRNNVRFIAVNNGIDSEKPDTLEFAPFINIMSEWYAKDISKKVKTGIKTKGMSGKPIVTEAPYGYVKDPDNKDFWIIDEEAAEVVRLIFRLFIGGKNRNQIAVHLKNEQIPTPTFYMKDRGRGTCKNKTLNEDNRCKWNKATLTNILTRQEYCGDVVNFKTTKHFRDKHNHYVDRSQWHITENVHEPIISRSDFETVQRILENAPVKRPNGDGEIHPLSGLLFCKDCGAKMHIRIDYRNGGKRHVAFCSEYHKGKAKNPKCHSPHIMDADLLMQTIAEVLKKIEDYSISNRAEFEALVKKNLAMQQTDQTKKQQKRIPQITTRLEQIDKVLNKLYEDNALGTIPQDRYEQMSQKYSEEYYALKAELATLQEQLSAYENAGGRAQKFLKLTERHAAFTDLTPAILNEFISRIEVHERDQKRARYAIQHISIYFNYIGKFENEVTQLAEPTEQEIRQMREEIEEAKKEKSRAYHRQYSREYRARNLEKQREYDRMKAREYRARRKAQAAAQPAQ
->tr|A0A317E7E7|A0A317E7E7_9PROT XdhC /CoxI family-like protein OS=Zavarzinia compransoris OX=1264899 GN=DKG75_13590 PE=4 SV=1
-MIEPDLFAKVYDLQEAETPFVLATVVRTVSVTAAKAGAKAVILADGTVAAGWIGGGCARGATLKAAQDSLADGQPRLISVQPDDQMEEQGLLNGETRDGVRYAHNHCPSRGTMDIFVDPVLPRPELLVMGTSPVARVLVALAGEFGFRVMAAAPAAAHGQLSLADRLIDGFVPPPANGLRYVVVATQGADDFAALSAAVALDVPYIAFVGSRRKAESLRGDLLDAGVPAARLAALKAPAGFDLGAVTPEEIALSILAEAVAVRRRGIASPAP
->tr|J9VWE8|J9VWE8_CRYNH Pre-rRNA-processing protein TSR4 OS=Cryptococcus neoformans var. grubii serotype A (strain H99 / ATCC 208821 / CBS 10515 / FGSC 9487) OX=235443 GN=CNAG_06340 PE=4 SV=1
-MSPSSPAGSSSSSLCYTNTLLALPDGPIPSSHRDLISHTTSFIGGYPTFPALPSSSCSTKKVGNTPSEINCGICHKPIPLLAQVYCPPEDGENDRTIYVFACPRVGCQKREGSIRAWRASVRNEEYVRDVEEKRKAAEKAAQEERERARKNPFTVDEAARLNGSALFGTASPLFGGAAHNPFAPPNPVPAMATLSVSDDRPAPTPITSGPSRTFTPPIPAYHPVQYLSTIEEYIPPVDDDVSVASSDDDESPEQKAEWREEGWEKVLPRNVDEVFENFVRRLDQADGGKKQVLRYELGGMPLPYSSASPLTRKLFPGCEKPLAKDEELDLSALYTPKFIPTCPRCGGKRVFELQLVPSLINILRPHTISTTGEAPKASFPKAATEEERKKELAKLAAGVKEEASKDEEGEMEWGNVLVYGCERDCVGVGEEWVGVEWEATLEL
->tr|A0A2T0PRW1|A0A2T0PRW1_9PSED Flavin reductase (DIM6/NTAB) family NADH-FMN oxidoreductase RutF OS=Pseudomonas sp. NFACC11-2 OX=1566246 GN=OE22_101713 PE=4 SV=1
-MSSLCDTAFDTRAFRRALGNFATGVTVVTAATEDGRKVGVTANSFNSVSLDPPLILWSIDKRSSSHEVFEAASHFAVNVLAADQIDLSNNFARPKEDRFAAIQFETGEGGAPVFVDCSARFHCEKFQQVDGGDHWIMIGKVVAFDDFGRSPLLYHQGAYSMVLPHTRMTKREEGQSPSSHFQGRLSHNLYYLMTQALRAYQASYQPRQLCTGLRTSEARMLMVLENDAGLNLCDLQREVAMPVREIEEAVANLKRKGLVSDEGERVRLTAKGIDETEGLWAIAKEQQDKVFGQFSEEQVEHFKQVLKGVIRGA
->tr|A0A7H5EXY5|A0A7H5EXY5_9BACT Rhomboid family intramembrane serine protease OS=Lewinella sp. W8 OX=2528208 GN=E1J53_0011935 PE=4 SV=1
-MFFPIGDDQVHRGFTPFFSYGFIALNVMIFFYQSSLGEAGAEFIYNYGSIPLEFERGEDYHTLITSIFLHGSWMHLIGNMLYMWIFADNIEASIGNVPFLIFYFLGGLAASLCHIYFNAGSQIPAVGASGALSAVMGAYIVMFPKSNIRGYLLFFRINVAAWVFLGFWFFQQSQAGYASLGDTSGGIAWWAHIGGFVFGVLCGFFFRQRYGVPELDRGRDRYA
->tr|A0A1A3D3H4|A0A1A3D3H4_9MYCO Uncharacterized protein OS=Mycobacterium sp. 1245805.9 OX=1856862 GN=A9X00_01450 PE=3 SV=1
-MVQCASEISWDPADTDGLSEDWLDRLLDAVDGNTVVRTPVGMLFAGVSQIERLLAHPALKVPVVEQYELMGVSEAILERARRVILGLDGAPHTRLRRLVSRAFTQRAVERLAETMRSYLVPRLDDVDGEVDFIDEIVGDYPAAIIGGLLGLPAADLPHLTSIAQVITSSQFSLDVDRAHQYLAAAAECDAYLADLVTSKRKAPGDDILTHLTQVGVEGDSLSDAEIVSLCASLMNAGIDTTRNQISLGMTLFARLPEQWNRLRDESVLVGNAVEEILRFLPVTPLLTRLNTEALTFDGVDVPERTYISLGVAAANRDSTLNTGDALTFDVSRPNPRHFTFGHGAHFCVGAALARLEMRELLTQMVSRFVSVEVVGQAPRRSAMGVYGVKNLTLRLDRQRQNAS
->tr|A0A2P8DYT4|A0A2P8DYT4_9BACT Uncharacterized protein OS=Cecembia rubra OX=1485585 GN=CLV48_110110 PE=4 SV=1
-MRTLLSIFAISIFISSCVQQGVDKEAQRIVDQSIKAHGGALYQEALISFDFRERHYSIFKSPSKYEYIREFTDSTGFVRDVLNNDGFQRTVNDTPVDLPEDRIRAFSNSVNSVAYFAFLPYGLNDAAVIKTYLGETELEGNSYHIVKVTFRQEGGGEDYDDEFLYWFHKEKYTMDYMAYSYHTDGGGVRFRKAIKQHQVNGLLLLDFENYKPEEKNTSVDKMEGLYKEGKLELLSEIRMENIKVSF
->tr|A0A1U9N7G6|A0A1U9N7G6_9GAMM Muramidase FlgJ OS=Cellvibrio sp. PSBB023 OX=1945512 GN=B0D95_04590 PE=3 SV=1
-MQSIDTGIKVPQVQDNYFDPNSLNSIKAMGRDRDPQAIKEVAKKFEGLLVQQMLKSMREANDVFGEGSFLDSQTTRFHRDMLDQQMVLDLTSGPGIGLADHFYRQMMQNYGSTMRPEGGVKNTDSSALGEITPRTANKTSVAEQASVDALDDWIQDFMRMSDNVQMQALGDGDEQQVPAVPAINYALIPQLLSKQAIGTVRGGQKSSISPTQENFVMMLKPHAERAAAELQISPDVLIAQVALETGWGKHVIHDRSGNNSFNLFNIKAGGQWQGEKVNVNTLEYRNGIAAQEKSDFRKYNDYSESFSDYVRLMKNNPRYEKVLATGTNSSAYADALQSAGYATDPHYAKKIKSLLNSDVIKSLDLASVTENMQADLLQTGAQAILSLAASASRHIVE
->tr|A0A411GH85|A0A411GH85_ENTCL ABC transporter ATP-binding protein OS=Enterobacter cloacae OX=550 GN=sapD PE=4 SV=1
-MPLLDIRNLTIEFKTGEGWVKAVDRISITLAEGEIRGLVGESGSGKSLIAKAICGVAKDNWRVTADRMRFDDIDLLRLSPRERRKLVGHNVSMIFQEPQSCLDPSERVGKQLMQNIPGWTYKGRWWQRVGWRKRRAIELLHRVGIKDHKDAMRSFPYELTDGECQKVMIAIALANQPRLLIADEPTNAMEPTTQAQIFRLLSRLNQNNNTTILLISHDLQMLSKWADKIDVMYCGQTVETAPSEDLIGAPHHPYTQALIRAIPDFGSAMPHKSRLNTLPGAIPLLESLPIGCRLGPRCPYAQRKCIETPRLTGAKNHLYACHFPLNMERE
->tr|A0A7X8MBI3|A0A7X8MBI3_9BACT Type II toxin-antitoxin system HicB family antitoxin OS=bacterium OX=1869227 GN=GX408_15355 PE=4 SV=1
-MRTLKYTYWQDGNFYLGYLIDYPDYQTQAKSKEELIENLKDLLHDIESGDIPFIRKIEELVLA
->tr|A0A1V3S1A0|A0A1V3S1A0_9PSED Alkyl hydroperoxide reductase C OS=Pseudomonas sp. A25(2017) OX=1945865 GN=B0E42_23545 PE=3 SV=1
-MPIINSQVKPFNATAFKNGEFVPVSDADLKGKWSVVFFYPADFTFVCPTELEDLADNYAEFKKLGVEIYSVSTDTHFAHAAWHNTSPAIGKIQYTMIGDPTHVISRNFDVLIEEVGLADRGTFVINPEGQIKIVEINDGGVGRDASELLRKIKAAQYVAAHPGEVCPAKWKEGEATLAPSLDLVGKI
->tr|A0A2V9NH91|A0A2V9NH91_9BACT Uncharacterized protein OS=Acidobacteria bacterium OX=1978231 GN=DMG98_20865 PE=4 SV=1
-MNDEETIMKHKLTTALLLALCVPIASATTWYVNGVSGSNSNNCKSPTTACKTIGHAISLAVSGDSIIVAHAIYAENLAIGKNLTILGSGAATTIIDGGGTATVVTISNGTHVTLSKMTIRNGNASGVVVIGFMRAISGGGINNSGTLTLTNSTVSGNLAPIPCIHFFVFCEIRGGTAWGAGIYNSGALIISNSIISGNQAGGYCNATCSSFGGGIYNRGTLLMIKNSTLTGNIADTACSTSISCAVGVGGAFYTVGGTVTLNNSTVTANIADRCSGMCGGTGGAIVNGSGNLAVNNSTVSGNYPAGGIFNSGTATLQNSILANNSGRNCRGIITSHGYNLSSDGSCPFSNTGDLNNTNPLLGTLGNYGGSTQTIPLLSGSPAIDSGNPNGCTDGQGHLLKTDQRGKPRPDIEDTAGCDRGAFERQSD
->tr|A0A7D3VXP3|A0A7D3VXP3_9ACTN TPR repeat protein, SEL1 subfamily OS=Actinomadura verrucosospora OX=46165 GN=ACTIVE_7586 PE=4 SV=1
-MPVRPWSPEDLGRPTDGTWADVAFGLGEIYECEGDLGQAADWFRRAAESGHAAAALRLGAVLGRMADDGADGSAEDLLAEATRWLSGAQDIATPDAIELITDMLNRHQRQAARRGLEPAVATG
->tr|A0A370P2G6|A0A370P2G6_9BURK ABC transporter permease OS=Cupriavidus lacunae OX=2666307 GN=DN412_03430 PE=4 SV=1
-MKSIRLGHAVATVCVVQLLAASPYAVAQGKGSYSQDTVKIGVLTDMSGIFADLGGKGSVTAAQMAIDDFREQNTPPFKIELLQANHQNKADIGASRAREWFDVENVDMITDVINSGVALAVAKVAQNKNKMVMVTGSGTARLHDEDCNPNTIHYGWDARTFANAHVRAQTEQRRKSWFFLSVDYALGRSLEQDATAAIMANGGTVAGSVRHPLSAPDFSSYMLQAQSSKAQVVGIANAGADLVNAVKAANEYGVTRTKSLAGLAATITDVHAMGIDATQGMVVVEDFYWDLNDRTRAWSRRFFDKQKRMPNFVQAATYSAVLTYLKSVLAARSDDSNVVLKQMKQLTINDVFANNGKIRDDNKMVHDVYVMEVKKPQESKAPWDYYRVRRTVAGSDASQPLSASKCPMVKKGI
->tr|A0A1A8TK33|A0A1A8TK33_9GAMM Peptidyl-tRNA hydrolase OS=Marinomonas spartinae OX=1792290 GN=pth PE=3 SV=1
-MTGFKLLVGLGNPGSEYENTRHNAGAQWIEALARQSQCSLRTEKKFFGQFGKVSIAGEECYLLIPTTYMNLSGKAVQAVCQFYKIPPEQILVIHDELDIPPGTAKLKKGGGHGGHNGLKDIIARLSNNREFGRLRIGIGHPGHASQVANYVLKKASQDEYRKIEQTIDESLRYIDDIVGGNLNTVMNQLHSFKA
->tr|A0A373QD60|A0A373QD60_9FIRM Uncharacterized protein OS=Firmicutes bacterium AM55-24TS OX=2292896 GN=DXA10_01295 PE=4 SV=1
-MEEFFNRTDKKYKIIMLCVIVCIIIVAYIGSQLHDDNHLIVGRWEEVGDCWMDELEFFSDGTYSSDKDNYFGSYTIEDGRIRLGGVLMSDLVYSYKLDGDTLILYKKDIDDGDEYRRVK
->tr|A0A7K2JSV5|A0A7K2JSV5_9ACTN DUF2470 domain-containing protein OS=Streptomyces sp. SID5910 OX=2690312 GN=GTW67_25625 PE=4 SV=1
-QELEAAELDPLATSEAGMLTHFVDDHPELVPLLLRLVRPGPDRGVRRALPVGIDRYGLTLRLELARGHRDVRLPFNRPVRDIDHVGAQIHALLSAARRLSHPGHLLT
->tr|A0A6N9SLE2|A0A6N9SLE2_9PROT Cell division protein FtsL OS=Ferrovum sp. OX=2609467 GN=ftsL PE=3 SV=1
-MSRSDILLFVCVVVLALGVIHGQQHARRLFIDLQQARDQQVQLQTEGDQLQIEEGTLSASRRVEDRAIRGLKMQLPKSEQKRLVVLGQPGSTP
diff --git a/src/alphafold3/test_data/miniature_databases/uniref90__subsampled_1000.fasta b/src/alphafold3/test_data/miniature_databases/uniref90__subsampled_1000.fasta
deleted file mode 100644
index d68321dd92b82fb383248f92008f86ccb60a8bb7..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/miniature_databases/uniref90__subsampled_1000.fasta
+++ /dev/null
@@ -1,2000 +0,0 @@
->UniRef90_A0A8C0C0Z5 NADP-retinol dehydrogenase n=1 Tax=Buteo japonicus TaxID=224669 RepID=A0A8C0C0Z5_9AVES
-MATLVPRIVLITGCSSGIGLAVAVRLAQDPQQRFHVIATMRDLRKKEKLEEAAGPALGKTLSIQRLDVCSDSSVAECMENIPGGRVDVLVNNAGVGHVGPVESISVEEMKRIFETNFFGVVRMIKAVLPDMKRRQSGHIVVISSVMGLQGIVFNDVYAASKFAVEGFCESLAVQLLQFNVXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXPAFRTQTNSLYTPLVALKYADPSGDLSVRTYYRLLFNYGTLFHLSMAALRCLTCGCFRRRVTPL
->UniRef90_UPI001863CDCB tumor necrosis factor receptor superfamily member 19L isoform X1 n=2 Tax=Megalops cyprinoides TaxID=118141 RepID=UPI001863CDCB
-MMRNHLRCSALVLLSLLGLRGALATQCGWGKVLTSEGCVCLQCPVGQEPSKACGQAEGPEEVVRCQACSAGTFSDTYDSDLCRPHTSCAALNRLLMSPGSTERDATCGDCMPGFYSAAKEKSSSPDSCVRLIPRPLVRVLRNVGKGVARGTGRGPANATNVRSAEEKNTEYAVFALVPIFCVMGLLGILICNILKKKGYHCTAEKEGGDEEAPTPQKEGNSGPYIVDDPNEDTISVLVRLITEKKENAAALEELLLEYESKQMSISKASSIKFPVLPHLPHQFRSLPRLCPHQHHLHTINGLAPRAGNGSCCSRCSQKKWPELLLPPIDTHKTTTVGGKNPLPGEVTILSVGRFQVAQIPEQKALPAELTPPESSDTDSVDTSHTEAADEKSLLGVSSLSSSSTWTKSKQEDRKFVIRLGETNLVI
->UniRef90_UPI00049204AA adenosylmethionine decarboxylase n=1 Tax=Paenibacillus pinihumi TaxID=669462 RepID=UPI00049204AA
-MEYSTFGRHVAVDTWGVDFELLNSAEFLQAQMVEAAESCGATVLSVQAKQFEPQGATVLVLLSESHLSIHTYPEKGFAAMDCYTCGETVDPQMAIDYMLSVLKPKTVHAKKLVRGMGELKVEEPVMQQAELV
->UniRef90_B8CVZ9 Putative CoA-substrate-specific enzyme activase n=1 Tax=Halothermothrix orenii (strain H 168 / OCM 544 / DSM 9562) TaxID=373903 RepID=B8CVZ9_HALOH
-MGKYYLGVDVGSVSTDMALIDPFGNLIEKIYLRTKGQPIEVIKRGLKKLKENYGSIKVAGVGTTGSGRKLAGVMLGADVIKNEITAHAVAATHLVPDARTVLEIGGQDSKIIILKDGIAVDFAMNTVCAAGTGSFLDQQAARLGISIGEFSRLALKARSPVRIAGRCSVFAESDMIHKQQLGHDLPEIVAGLCEAMVRNYLNNVAKGKDIKPPVVFQGGVAANIGIKKAFEKELHTEIYVPEHNGVMGAIGAALLAMEEVRSRKKETSFKGFEVTEFKFKTTSFECKGCPNRCEIVNINQDGKTIARWGSKCLKWDMTEDKKKEEVNLNPS
->UniRef90_A0A7R9F0M8 BESS domain-containing protein n=1 Tax=Timema bartmani TaxID=61472 RepID=A0A7R9F0M8_9NEOP
-MSSRSLVAGGGGSVRQPTPSSGVKLAGEDFNKDKMYEPKHTKRLVRVLTVVAYVFSVSLAAIMLSVYYVFLWNPRDARHPRLPPPTPPTCQPAQVISMYDNYSTEVGMRKEALQRLHLHGRRVVNHLVKTTFNRADWNLNPNLQQPARTTSASSVEDAEEQSAEDEVESQTDLGPNQLTERSKPTQNNQKSPVRNNTCELEFQLSQFMTLHKERQKDDPDKDDRAFFESLLPSLKSLDTDEKLNFRIHQLTLSLVNNRRAVFFTPSSHPAVLI
->UniRef90_A0A2A9MK67 Ras family protein n=1 Tax=Besnoitia besnoiti TaxID=94643 RepID=A0A2A9MK67_9APIC
-MRDPSCWQFPSHSSSQESEAVAWAPPRGPGQSGAGRFEGEGGEATACSALSPAGCPLPPFSVPSASVSSSASLTPLCYAVRSVPSSPHSLPVPAPPPVPPPVAIAPSSFLSPPRSPSLLPSCPSSSSPPVQSSSPLVSPLHAFSPSWAPDLLSRSPSPAVCRKRTEEFSSVPPSPEWRAESRFPTSHRSLLDSPVCRPAVVAGGGVAAGGFLSEGEGAAPPGGEIGSEEEDDGASVASSSSDASTAFLRILVVGDQGTGKSFLLHSLCHSPDPQSEFQRPCPAHRGRRGLREQVDTRASDAGAADEKSAPRQDGTGSRLEHSGSRAQLRRGTPDRRDAVHGVGVRMDASEQLERDADAPFSSFASVELTEWPRRADAETGGTQAGRIRGLPEDGRPRAEPRASEPCLAESCVSAPSEQSGDSTSVPRSPSLSPSASPVPSPSSSFSFSLPTSFCPASSSRPPAPVAPPRAASSSSPASSSAAPVARAASAEAAAAAQPAACEDASRQRECTCEADEQQCPACRLPGSYEWTCGVRIFHMFWELPPRERGSKDRQRQSSPGSSSSESSADSLSERGRPAASYPLLPESDASCASGAAAARSAGAATRCLVEFWEVGGTEMLESVRSLAYGQEFDGVWVCFDSRSAASFHHAALWTRELCVHLHLPSSLLFPSSGPQAPLSLAPRSYEAAAPSSSLRSFLPAPAVFQSFACSRRVRRWRRHQEHNAAGEARQRSAEGAAHEVQSLTSFFQMLPTSTVGKVTRAAASAVVRLGSTVASPVVSLVAGERERETDDSATDREEDEMARLKPEREGRGRRKFSAKPSRPFRKGSRRTARFASSLLTSASSVRPPPGMPERDGEEEPREDGEGGGTSVEEKDVELGVLEGGRETLESPADAECRADTASAAKEGTAPTLEAAAFPKGQQGAGPGPEDPDGASSRAFANLEKELTHQQFAVRLLQGVCPVLLVGTKEDLLLSSTAARQTSNESAGGGCEVDEKGLSPFLKHLRSRASVLSGFLSSSSPEAAAGCAVGEDDEDGRGGEAACRASDPSCAAPALCLEEDIGGGTPSRLQTPFSRAYFTQNSFVKARDNIFARLCGTLGPRRVPSGDARLALDGDAGVKLNRRICHLLNSSPLVLTSAVGRTVDPAALSAFFSDALLCQTLFRERSREKKVRRRSKAKSRGARPPVDVMQHVEDAPALLSPLPSPSLRASPGVALSDSANVRRVGVGAGDAAKQTAPVGEAEDGGATPPHARGRAQQPCQDPRLGEERELSADPEPRESPVAEDRPAEERDGKLDGKSRPQTPFSDVAAAAVAAGAAAAAIQWLH
->UniRef90_M3EC79 DDE_Tnp_1 domain-containing protein n=1 Tax=Streptomyces bottropensis ATCC 25435 TaxID=1054862 RepID=M3EC79_9ACTN
-MPDAPSARSSLFRAGDRLGPEPLRVLFATTVKPMATEATTGAFWRGLRLPAVDGTCWDPCGQRSRRGRLREAGQRPRDGPERVSPGADGRSGGGGHACGAGRGTRRLAAPGESPLVGRLPGSYGPGQLVLADREFLGTGLWWAFTTTGADPLGALSGGQAPEDC
->UniRef90_A0A4Y2GBA1 Uncharacterized protein n=1 Tax=Araneus ventricosus TaxID=182803 RepID=A0A4Y2GBA1_ARAVE
-MSRPLFVIGAKKARNPRPQNKDERVSPHSLQPTTCPDGPEVANDRRARASTVHLRAPLMPKKEERAAACHLQMEIKREAVQFRFAGQSGAEYRLSRASHFGQVARGRHAPSVEKRGERGLTIFLRFLVSKMPWSPEAVRETHMPLCLRRPAMFGSCCFNLDGFGQMARYEGCRWGLRSRRAARGILANCAVMRAPGKGSSHRRFLKSCAEYPDDMQMSSGLFIAVCPVHELPLRFLLAVLLDLEEDVDRCIEHEDHQAKPFISVHELPLRFLLEVLLDLEEDVDRCTEHDGDEEHDGHQGEQIGQEDQVGLKHFSL
->UniRef90_UPI001E28E105 low molecular weight phosphotyrosine protein phosphatase n=1 Tax=Paracoccus sp. MA TaxID=2895796 RepID=UPI001E28E105
-MPPPSVLFVCLGNICRSPLAEAALRAAAKRAGAGLLIDSAGTGDWHLGHAPDRRAQAVAARAGIDISTLRARQVAAEDFRRFDHIVAMDRQNLADLRRIAPLDGRARLSLLLDHVPGRAGQSVADPYFGEAAGFETTWHDVTAGTQALLRLLLGPD
->UniRef90_A0A522C2W7 MBL fold metallo-hydrolase n=1 Tax=Frankiales bacterium TaxID=1909291 RepID=A0A522C2W7_9ACTN
-MSTFRVEHLSTSGTFSLDGQTFDVDNNVWLLGNDHEVLVLDAPHDAAAIERAVAGRAVVAIACTHAHDDHVRYAPELAERLSTQVLLHPADRVLWDLTHPDRAPDGELRDGAVLEVAGTRVEVLHTPGHAPGAVCFSVPSEELLFSGDTLFAGGPGATGRSYSDFDTILGSIRSRLAPLPPATTVHTGHGPSTTIGAELPSYDEWVRRGH
->UniRef90_Q1PS67 Telomerase reverse transcriptase n=8 Tax=Oryzias latipes TaxID=8090 RepID=TERT_ORYLA
-MTSGDLSSVLNILRSLYKRTRTLEEFADGVVFREGRRAALLQPSDTHSFKSFVRGVFVCSDEELQDVPSCNQTCTFPELLAFILNSLKRKRRRNVLAHGYNFLGVAQEDRDADHFRFQGDLSQSAAYIHSSDLWKKVTARLGTDVTRYLLGSCSVFVLAPPSCVFQICGVPAYDRVSMTTASSGFLLRPPSRKHKSFQVGKKTRSANLTKTGSVGDVEESRKRRRVESEVSTRKRKRESEEEESRERRRGVHHEERRQHEAVLDESTLSGKSGENDAAAVKPPPETSAAPPPLEGGPSWRSGAFPPLPSSQCFIRTLGFLYGGRGMHGFCLNRKRRTAAGPRRLQGQDLVRLVFFEGLPYLNGQERKPKKLPLRYFNMVPVFGRLLQRHRKCRYSSVLHRMCPVVELSRAAQGELSSLIPQHCAPHRVYLFVRECLTAVVPEELWGSDHNRLQFFSRVRGFLKSGKFERISVAELMWKIKVMDCDWLKLRRTAGRFPPSELAYRTRILSQFLTWLLDGFVVGLVRACFYATESVGQKNAIRFYRQEVWSKLQDLAFRRHIAKGEMEELSPAQVASLPKGTVISQLRFIPKTDGMRPITRVIGADSNTRLHHKRIRDLMSMLQARVRSAPALLGSTVWGMTDIHKVLRSLAPAQKDKPQPLYFVKVDVSGAYDSLPHDKLKEVITEALSPVQEEVFTVRHYAKIWADSHEGLKKAFARQVDFSDGSMGSTSMKGFVMSLQKSSKVHHAVLVEQAFGSNLRGKDALQFFTQMLTGSVVQHGKKTYRQCRGIPQGSVVSSLLCCLCYGHMENVLFRDIKNKGWLMRLVDDFLLITPDRNQAQSFLSILLAGVPQYGVVANPQKVVVNFQGSEGGGAFPDIRVLPPHCLFPWCGLLLDTRSLDVCKDYSSYAGLSLRYSLTLGSAHSAGQQMRRKLMSILRIKCHPLFLDLKTNSLESAYKNIHKLVLLQACRFHVCVQSLPFAQTVAKNPTYFQQMIWDMAHYANALIRRSNTGLVLGDGAQKGSVQYEAVELLFCLAFLRVLSKHRPVYKDLLPRLHKWKRRLERLLGDLRLARVRQAANPRALLDFLAMQM
->UniRef90_A0A6B3G495 Alpha/beta hydrolase (Fragment) n=1 Tax=Streptomyces sp. SID7982 TaxID=2706094 RepID=A0A6B3G495_9ACTN
-MPRSLQAALILLHVLFVATLVGAIRALSTASSVDAVDGYLLGLLLYASLPGVAVFVLSLYVRHGGVRAWYGLLAVLAWIVLGALAELSGGGAEGQGVARLAVPVAVIVLLCRPESRRWFRSGLEQRAEQRLFSFARMMRLRRDGGQTALEYLGLVLVVVALVGGLMATGTGQQLTAEIRSAICELTGSSCPAPGRDVAAGGGSGDGGADGGGDRDTSSSGADGMSGEGESSLTGGTGSTGTTGENATSGTSGTTATAGSPGDTATTGSPGDTATTGAPNTPQGSTPFPQGDFIAPVDAGRPAGPHGGGFIGGFLGDGVGGDVRGVVGAVLRPGETGQRIADQWARDTRGAEQKWARGDYIGAAWDWNKAVGGAGAGLAIPGSGARVDAEVRDAERAHLGERIPQNATPAQRKAWWDGLSPEERERYIELLPERIGNLDGIPVLAR
->UniRef90_A0A833ECX2 Enoyl-CoA hydratase/isomerase family protein n=1 Tax=Caldiarchaeum subterraneum TaxID=311458 RepID=A0A833ECX2_CALS0
-MSRQYQDIIYDKSYHSHTALIQINRPHELNSYVLNTLREMIDAFDDAMWDDNIQFIVLTGAGDKAFCTGGNVREYAEIYNRKPSDWWKWGEIYGRFLDVIMHCGKPVLARVNGIVAGGGFEFVAASDLAVAAEHAKFISPGPRVGMTSIGGLSQWLPLHIGLKRTAQVVMTSDEIPARQALEWGIVNDVVPYEGLDDKVKEYIDRMLELSPTSLHYFKVHLNWWRDLVWRLTWEHAKEFFSLNIGGIEPAEGLHAFKEKRRRRYREIRGDIGRGVDPRYPHGPYMLSCNGCGAKYLPLASSYCLNCGKPIKG
->UniRef90_UPI00046BDA5A protein O-mannose kinase n=1 Tax=Eptesicus fuscus TaxID=29078 RepID=UPI00046BDA5A
-MEMKPQDGRRSPPHREVPPVVGLLLALAVMNALLYLCLDRFFIAPRRSAPDPRHCPSGHFRVGRMNNCSAWLSCEELRTEVRQLKRVGEGAVKRVFLSEWKERKVALSRLTSLEMKDDFLHGLQMLKSLQSQHVVTLLGFCEEDNTILTEYHPLGSLSSLEATLNLSKYQTVNTWQQRLQLAMDYVGIIHYLHHSPLGTRVMCDSSDLPKTLSQYLLTSNFSIVVNDLDALPLVNRSAGALVKCGHRELHGDFVAPEQLWPYGEDVPFRDDLMPSYDEKIDIWKIPDVSSFLLGHVEGSDMVRFHLFDIHKACKSQTPAERPTAQAVLDTYQKVLSLLRDTVTSQTREML
->UniRef90_A0A0F9NQL3 HTH_7 domain-containing protein n=1 Tax=marine sediment metagenome TaxID=412755 RepID=A0A0F9NQL3_9ZZZZ
-MKINVSIEKEYIKCPVCNGAGKIEEIHSDIKIKHAIVIKLFNEGYTYRKIMKLTGYKSTNSISDILIKNKMKLEKPIKNR
->UniRef90_UPI001866D008 ABC transporter permease n=1 Tax=Fluviibacterium sp. MJW13 TaxID=2720031 RepID=UPI001866D008
-MGARILNALFVTAVLLGLWQALVTLADLPPFILPGPVRVAQALWNNAGLIGWHALVTFSEVLAGLVLGSLLGIVTALQLATSGLARRLIRPALVLTQALPVFALAPILTLWLGYGLWSKVLMAVLIIYFPVTSAFFDGLMQTPRGYLDLAQTMQATPRQRLWRIRVPAALPGLASGLRLAAVYAPIGAVIGEWVGASNGLGYLMLLANGRAKIDLMFAALVVLACLTLTLHVLVSRACDRLTARMV
->UniRef90_A0A5C5WGI8 Periplasmic protein n=1 Tax=Botrimarina hoheduenensis TaxID=2528000 RepID=A0A5C5WGI8_9BACT
-MPALSTPALAVPALADLAPLESRVQEALTGSPYLVASNRLRVEAGEGRVSLHGHVGSFFEKQMAQEVARRIDGVQQVENLLTVAWA
->UniRef90_A0A2K9F958 Lysine biosynthesis protein LysW n=1 Tax=Paracoccus tegillarcae TaxID=1529068 RepID=A0A2K9F958_9RHOB
-MPAREAHQPITINCPHCGGESILADACARWNVETQEWELSTVYDDKTCADCGIEVSAEERSVQEGA
->UniRef90_UPI0014593CCD alpha/beta hydrolase n=2 Tax=Aromatoleum aromaticum TaxID=551760 RepID=UPI0014593CCD
-MKTWVFLRGLTRESGHWGGFLETFACIVPDSRIVALDLPGTGARHRETSPGDVPRIAEDCRSTLFRLGVDPPYRLLALSLGAMVALAWADRHPAEIAECVLINTSLRTYSPFYRRLRPRSYARLLYLALRDDARACETMILRLTSGQRDERLVDEWVTLRVRHPVTLANAVRQLFAAARYRPPRDRPAPPVLVLASRNDRLVHVACSKAIAAAWNCSLRIHPYAGHDLPLDDGAWVAEQVRHWTDGGGA
->UniRef90_A0A0F8UN67 Cupin domain protein n=3 Tax=Aspergillus TaxID=5052 RepID=A0A0F8UN67_9EURO
-MFIRPPLEIQVTSRQIPQWNCIPNTSIQSKPLMIYHQAFAASPEELKQHFRMVGEVTPGWVYTMYSQTHFHSTTHEVLGVVSGSAYLCFGGEGNPGRFETRVEKGDMIIIPAGVGHRLLHEPDLDKGSFKMVGAYPQNKTWDMCYGQSGDEEKCRNIESLGWFQADPLYGTDGPALRV
->UniRef90_A0A2C9GSP0 Glutamate-gated chloride channel n=2 Tax=Anopheles TaxID=7164 RepID=A0A2C9GSP0_9DIPT
-MLDHASKAPKSAGWIKLNVFRMASGHFFCAIFYFACLCSASLANNPKVNFREKEKKILDQILGAGKYDARIRPSGINGTDDKATQVFVNMFLRSISKIDDYKMEYSVQLTFREQWLDERLKFDDIGGRLKYLTLTEANRVWMPDLFFSNEKEGHFHNIIMPNVYIRIFPYGSVLYSIRISLTLACPMNLKLYPLDRQVCSLRMASYGWTTADLVFLWKEGDPVQVVKNLHLPRFTLEKFLTDYCNSKTNTGEYSCLKVDLLFKREFSYYLIQIYIPCCMLVIVSWVSFWLDQGAVPARVSLGVTTLLTMATQTSGINASLPPVSYTKAIDVWTGVCLTFVFGALLEFALVNYASRSGFIVFLCETNTINVNNIFAHGQTSVATHRSVYHFRFYCIRSFILSPPTHPQLNRHTHFRFRITPVNQPPTAISPVTPSVKHSHNYERYLVLFVPHLGSFDAFSLFLEKQNLFSFEPPVPGILLFYNNQKFNYFHPFLFALNIRLLLGIVGLTFPLTFSPIWHVNI
->UniRef90_S5G9S1 1-phosphatidylinositol 4,5-bisphosphate phosphodiesterase gamma n=17 Tax=Percomorphaceae TaxID=1489872 RepID=S5G9S1_PAROL
-MCAARFSGCLNGCAEEAAAGAAGPVMASRMMDWTEAGPRILHSLEMGTVMTVFYQKKSQRPERRTFQIRQDTRQIVWSRNPDKVEGEIDIREIRELRLGKGSRDFERYPEEARKLDSAHCFIVLYGLEFRLRTLSVAAFSEEEVNIWVTGLNWLMIDTQRAPAPQQIDRWLRKQFEVMDRNHEGSVTVKEVKALLPQVNYRVPNMRFLKDKLQEVEARSDLSYPNFAQLYRTLMFDAQRSIIEQLELAFPLRNVDRPELCQISLYDFQKFLQMDQKESWASELSRVREFLMGYMMGGPHPEPMLQLDEFLTFLFSKENSVCDPRLSPVVLDDMKRPLSQYWISSSHNTYLTGDQFSSESSLEAYARCLRMGCRCIELDCWDGPDDLPIIYHGHTLTSKIKFLDVLHTIKEHAFVTSEFPVILSIEDHCSVVQQRNMATHFKKVFGDLLLVKPVDNNAEELPSPHQLRRKILIKHKKLVEGTLYEEVTSASYSENDISNSLKNGILYLEDPIDHTWTPHYFVLTSNKIYYSEETSHYQTADEEEDDEGKEEHNNNNNNNEQHCAERWFHGKLGGGRDGRQVAEKLLREYCEGGAKDGTFLVRESETFVGDFTLSFWRSGRVQHCRIHSRQESGSTRFYLTDNLVFDSLYCLICHYRVTPLRCNEFEMRLGNPVPQPNAHESREWYHSSLSRVQAEHMLMRVPRDGAFLVRKRSEHNSFAISFRAEGKIKHCRIQQEGRLFMLGSSAEFESLVDLVSYYEKHPLYRKMRLRYPINEDTLGRMGTTELDYGALYEVRTPHFYVEANKMPTARCTVKALYDYRAQREDELCFPKQALILNVDKQEGGWWLGDYGGKKQLLFPANYVEEVPSSPTREQEDVSTENSPLGTFLKGFIDVPSGHVVVHKDGKNSRPYVSTIHSQHLSSHPVQTLDVAADSLEDLTSWVAKIREAAQNADARMQEEKQMERRKKIAVELSELVVYCRPVPFNEDKIGTERTCYRDMSSFPETKAGKFATRSRGKRFLQYNRRQLSRVYPRGQRLDSSNYDPLPMWLCGSQLVALNFQTPDKPMQLNQALFMLGGGSGFVPQPDIMRDDAFDPFDKDSLHVEPITIQLQVLGARHLPKNGRSIVCPFVEVEICGADYDGCKCKTDVVADNGLNPVWVQKQFVFDIHNPTFSFLRFTVYEEDMFSDPNFLAQATYPVRLLRTGYRSVSLKNSYSEELELASLLVHIEIVNAKEEDDENLYTSIQLLRDRTSELSSQVSVLERSGSADLSYQQSLEELRAAQDQLSELVEARNRRLTEKKRREKLRQQVAAKRS
->UniRef90_A0A3L6FD03 NAD(P)-bd_dom domain-containing protein n=4 Tax=Zea mays TaxID=4577 RepID=A0A3L6FD03_MAIZE
-MEDTIMAPSTLIIKSMSSMVDQVAAAVRSPAQEFYIKSRLLLRDPEKALTLFGKQDESVLQGVTHVICCTGTTAFPSKRWDGENTPERVDWNGIRNLVSALPQTIKRLVLVSSIGVTKYNEIPWSIMNLFGVLKYKKMGEDFVRNSEYHSRLSCIQVFTEKFFGGSEIYSDMIQAVCRPGRLTDGPYTSYDLNTLLKATTGERRAVVIGKGDKLVGEVSRLVVAEACIQALDIESTEGQMRLIQ
->UniRef90_UPI000CE4C9A8 pyroglutamyl-peptidase I n=1 Tax=Arthrobacter sp. GMC3 TaxID=2058894 RepID=UPI000CE4C9A8
-MILLTGFEPFGGESFNPSWAAAQQAAASLTASGLPARALQLPVEFGTSADVLRRALATDPFDLVIAVGQAGGYGTLMLERVAINVDDALFPDNAGHSPVDEPVVAGAPAAYFSTLPIKACLQALQDAEIPARVSQSAGTYVCNHIFYALMNALADMPGVRGGFLHVPYSPEQVTDGKHPSMDVAQVARGLELMVRTSLATEKDLKLGAGTTH
->UniRef90_A0A1G2CBS7 POTRA domain-containing protein n=1 Tax=Candidatus Liptonbacteria bacterium RIFCSPLOWO2_01_FULL_45_15 TaxID=1798649 RepID=A0A1G2CBS7_9BACT
-MPKENPVLWSDVRSREERRRARIFSSLVFLIISAFLIFGAWAVIYSPLFKIKSVEITGNKSVSDGDIMELATAEIPRGSFWKSVFGTGNILTWPDGFSGESLKFLPELKSFSVQKSYGQRKIKITVEEKKPFGVWCLLGARISADETQISADTKNNISENQPQNLRESAADCWWFDSSGVIFRKAIGVEGNLIASLDDYSQKNIGLNSKILPDEFIPNIFSIFRAVSASGLSVKEMRLNDLALQEIEVDTYNGLPADLSAIALATAEALAKAGPKIYFSLRFSADNVPEVIKSLKEKTTFGSLQYVDFRVENRVYYK
->UniRef90_A0A410GDA7 Glutamate--tRNA ligase n=2 Tax=Alcaligenaceae TaxID=506 RepID=A0A410GDA7_9BURK
-MTTSTPTQVRTRFAPSPTGYLHLGGARTALFSWAFARHHQGVFVLRIEDTDLERSTPEAVQAILDSMDWLGMQPDEGPFYQMQRMDRYREVIARMLKEGTAYYCYSSPAEIEAMRDKARAAGLKPRYDGTWRPEAGKTLPSPPAGRKPVVRFRNPVDGVTAWNDLIKGPISFDNTELDDLIIARPDGTPTYNFCVVVDDWDMNITHVLRGDDHVNNTPRQINILRALGATLPEYGHLPMILGPDGEKLSKRHGAVNVMEYEGQGYLPEAMINYLARLGWSHGNDELFTREELVAWFDTRHLTKSAAQWDPKKLNWVNAHYIKTTTDADLAAHVAPRIRTRGGDPDAVDLLAVMALLKDRAETLEQLADGAMLFCAPFSPADPELQAQYLDDGAKSLLAAFAAKASDLAEWNTESLDGLIKELLTEHGVKMPKLGLPLRLAVTGQKQTPAIGAVLAIIGRERVLQRLAAA
->UniRef90_A0A481SX22 Putative ras-related protein Rab-2A n=1 Tax=Franklinothrips vespiformis TaxID=297892 RepID=A0A481SX22_9NEOP
-MSYAYLFKYIIIGDTAVGKSCLLLQFTDKRFQPVHDLTIGVEFGARMITIDGKQIKLQIWDTAGQEAFRSITRSYYRGAAGALLVYDITRRETFNHLTTWLEDARQHSNSNMVIMLIGNKSDLETRREVKTEEGEAFAHEHGLIFMETSAKTADNVEEAFINTAREIYEKIQEGVFDINNEANGIKIGPQKSSTDPSLPSSGQGAGQGSGCC
->UniRef90_A0A2A5J168 GGDEF_2 domain-containing protein n=3 Tax=Rhodococcus TaxID=1827 RepID=A0A2A5J168_9NOCA
-MSQPLNASPALLSIFWHSREDYSMAQWWIHFDLAGIQRYVFASRTLLDAIGRAAQVEDATDRAVLTAAAVLPEGVEVEFGAAGALILTTEATEFDNPEQPPQRVKDAVSAYTRWLYEVSDAFTPVVAIQYVRGGEEQQAQMAAADLLRQARHKRIPGVGSAVPPGVLRCALTGAPATDFLPPASEIPVAAEALTARRRGRTWHEAQQSKILASAPLPDGLSVDLPVQIDHLGRTEGASSHVAVLVIDVNDLGAALRTLPPDTLHARSAVADHLRALADELAEHLVHRVCSAIEITAGVPSIAGAPTALSFPLHQAPSPSRAAEPDALSCLTADRSTLDSPGEDLGQTAAPARWSLPLRPWVIAGDDLVLVCESRLAWDLATAAMNWIGEPATSGARTDLAGLGPAFGTGGRLSLTVGIGIAVVPVGYSLAAAHDLAAGLCKNAKKQRRDNKWTGHVLDWHRGPSAIADVLAHRARSDLRSGLRPYRYAPKQAPDESHTSTPTWSDVMTLLDADSPGSMRGPTVDEKSHGWASRRNWVKTDLLAAARSTGNNAVENALAAKNTREKVLTDAPMAELNIDGNSWQECDRANLIVDVIDLLDDHLDLTAAVSPS
->UniRef90_UPI0002377054 shikimate kinase n=1 Tax=Verminephrobacter aporrectodeae TaxID=1110389 RepID=UPI0002377054
-MQIRCALVGMPGSGKSTLGRQLAQHSGVPFIDLDQRLEQTLGCSIRSYFEVAGEACFRDLEAQALADVAQQPGGMLLSTGGGAVLRADNRDVLRRFGSVFYLHALPEEICRRVQHDRTRPLLQGGNPLKRLRALYAQRDGLYRETARHVIETGRSSVRTLVGMAALQLEQDLAADAAQRAAE
->UniRef90_A0A251XIF6 RibD_C domain-containing protein n=1 Tax=Clavibacter michiganensis subsp. michiganensis TaxID=33013 RepID=A0A251XIF6_CLAMM
-MLDDAGTRTWLEDLYRPGSADHVRLNFVASVDGSVVGADGTSDSLSSVVDRRILGVIRELADVVLVGAGTVRAERYVLPAGRPWQSPPRRAIWRVTASTRTPRRAASSCSARRRRATAPSRRSTACRRRS
->UniRef90_A0A5F0LGG4 N-acetyltransferase family protein n=6 Tax=Herbaspirillum TaxID=963 RepID=A0A5F0LGG4_9BURK
-MTTSIRPATTADAAAICEIYNHYVLTTTISFELEAVSTEEMAQRIVEVSAIFPWLVYEEDGRILGYAYATKWKARKAYQQSVESSVYMAKDSGGKGVGTKLYSALFAELKACGVHAVMGGIAQPNPGSIALHEKMGFVKVAHFAQVGRKFDQWIDVAYWQLIL
->UniRef90_A0A849U3X0 Glycolate oxidase iron-sulfur subunit n=1 Tax=Methylococcaceae bacterium TaxID=1933926 RepID=A0A849U3X0_9GAMM
-MFEFMDMEYDQAVDASEQTGPYIPEAGECMRCGQCVSSCPTFRLFQIDEETPRRRIRTISKVLVENLPISDDERHHLDNCTQCRACETVCPSRMAYGQLFDLARAQFQAEPGSLAKLAFKLIENKSWRRRLMPLLAIYLKSGLQKPLRRIGLLKKLGLAEAEALVGNPALQALATSYSARAAMRGRVALFTGCIAEHFDRDTLLAAIKLLNAIGYEVLVPPQQGCCGAIHQHNGQSAVGLINNNIAVFNALDVDAVLHTASGCGAMLSEYQADDDAAAELFKQRLQDIYDFLLKHWPDDLQLMDSTLNVAVHEPCSQRNILKNQQSVYALLQKISTISITPLADNQVCCGAGGSYMLTHPDNSGQLRELKRQAIGAAQADLVVSSNFGCAVFLSSDSVRVAHPLILLAGQLQ
->UniRef90_A0A3R7NVI0 Saposin B-type domain-containing protein n=2 Tax=Trypanosoma rangeli TaxID=5698 RepID=A0A3R7NVI0_TRYRA
-MRKDHQMRTFIITVCILVVLLFSSAVAAKKEKPLHIPFPKDAVDGISCGVCTFVVKQVYRDVLVLFNASIRRRVRMSEDDVLTALEDVCNPFAETGQWIRRITITHKRETAPFLGVEELQVYTKCKRTCSTVVEACEGVLDHESMDMLSPRLLHLTEYADADKFAEALCDRSPICTKRWGLTASRYDELTTMIDEDTMEEIDPKEMEVERMMDHMERKENRRHSIFYRDEIVKMQEAILRGDKEAVAKVDPSIADLSEEEFAAVQAMVRGKNNEKLRSGTHRADDEGKARDTQRRKHRESDGGEGDLENFELEQEDL
->UniRef90_W6KER4 Cytochrome b5 heme-binding domain-containing protein n=1 Tax=Phytomonas sp. EM1 TaxID=479712 RepID=W6KER4_9TRYP
-MLSSLLGFNLWQKKWPLLSDEEICKHNNRMSLWIVSGNSVYDVTSFLNSHPGGDAILLRCGGGSKNCAEDFALHSQFGQRQWERLKIGEISEASTTKKSIFYGKEYSATDPEEEEEAALC
->UniRef90_A0A7W4J316 Amino acid ABC transporter permease n=1 Tax=Gluconacetobacter asukensis TaxID=1017181 RepID=A0A7W4J316_9PROT
-MIDWHFIAIIMPRLLRACGQTMGISLCSLSLATILGLSVALLRLSPIRVLGTAAWTYVWLVRGTPLLLQLFALYYAVPLTGLRLDPWLAGVLALGFNSAAYFSEIFRAAIQSIPPGQSEAAIAIGMGPATTLWKIVLPQALRPALPPYIGQAITLIKNSSLVSVIAVPDLMQTAQSIYSVTFKVVEVMLATGVLYLFMTTLLQIAQTWLERRLNYYTVK
->UniRef90_UPI00174618E5 clostripain-related cysteine peptidase n=1 Tax=Phormidium tenue TaxID=126344 RepID=UPI00174618E5
-MYAQRLLRSSRLFDSDRQASFDQASRSASLFSSDSPRDTTRAGQRNRAAAAKSAKRQPRRQKTRSVGSAADWTVMVYMAGNTLERFGIQDFLEMANVGSDSRINLVVQFDRTAGGNTSYGNWTDTRRGLVRAGDMPNAFWGNGLGELNMGSTATLKNFVDWGTNTYKANRYALVMWGHGDGFNVSYDDNTGDGISGSELSSVLSSTGNKIELVGTDACLMATTEFAYQIADNASIFVGSQELEPGTGWNYTTTLQDLKANPTMSAAQLGSSIVTRYGQAYPTGNETFSAINLLALRSSNASSLTNTLNSFASTALTSATSSDLSILDSLRDYFANDFGDATYRGSEDLCDVGNLFSNLVNRLDISAAVRTAAQSVLTAYDSTVLQNYSATPGRSTGLSLYFSDRNSIPKSSYTSRLYGFLATTQWDEFLQGWLWN
->UniRef90_A0A1A2YYB8 MarR family transcriptional regulator n=1 Tax=Mycobacterium kyorinense TaxID=487514 RepID=A0A1A2YYB8_9MYCO
-MGRIEDAPLGYLLYRVGAALRPEVAAVLRPLELTLPEFVCMRILSMYPGMSSADLARQTNVTPQAMNTVLRKLEDVDVVARPATVPSGRALPATLTTAGRALLKRAEAAVREADARILSKLSASEQREFKRMLEALGSD
->UniRef90_UPI0003641618 heavy-metal-associated domain-containing protein n=2 Tax=Streptomyces TaxID=1883 RepID=UPI0003641618
-MTAQTDTQGSVTTVYKVSGMSCGHCEGSVSGEISGLPGVSSVKAVASTGEVTVVSAAPLDDEAVRAAVDEAGFELVGQA
->UniRef90_R9J9S0 DNA repair photolyase n=1 Tax=Lachnospiraceae bacterium A4 TaxID=397291 RepID=R9J9S0_9FIRM
-MKNLKEDYFNPFFSHIYVEKSVRNHARTQNILAKFPSAQIIEIGHYKDVFCRSRQNIRLQHCAQKLILAARQGTLLYEGAPVCQRFGNEHFYYVSCAMNCIFDCAYCYLKGMYPSANIVVFVNLEDIFAEVERVLENHPLYLCVSYDTDLLALEPLIGFVQEWCAFAAKHAQLTIEIRTKCANKAFVQSIVPMPNVIYAYTISPQAVIDAFEHHTASLSDRLFCAAALMRAGCPVRLCFDPMIYLPGWKTHYSEMMNQVYRSIAVDQLLDVSIGTFRISQDYLKNMRKQAKDSAVIWFPFQKEDGYCHYPAPLMEEMESFLTAQIAEKIDREKIFRWNV
->UniRef90_A0A6I6SRI0 Gamma-glutamylcyclotransferase n=2 Tax=Halomonas TaxID=2745 RepID=A0A6I6SRI0_9GAMM
-MRLSHVVLAASAALLAIVGWLWLTMLSPLTYDRPDHLPEIDEGEHAVFVYGTLRFAPVRWVVMGRAGETEAAVLEGFRREGLDLAEAPDERVQGEIVVVDADELERLDRYERLGIRYQRVPMRLADGRVAWVYRRLNEITQASESPATD
->UniRef90_A0A373XTP8 Dihydropteridine reductase n=1 Tax=Ruminococcus sp. AF17-11 TaxID=2293150 RepID=A0A373XTP8_9FIRM
-MNTDKIYAEQLANEYTPKDTSKVVALRKLDAKAKLPATIFTYTFGIISALIAGVGMCLSMKVIGSGSDAMFILGIIVGIIGFVGVAVNYPIYKKLLNKGKKKYAFEIVQLAKEISEKDM
->UniRef90_A0A366JGF4 FAD:protein FMN transferase n=1 Tax=Marinomonas rhizomae TaxID=491948 RepID=A0A366JGF4_9GAMM
-MRKKILFSVFLLIAIAVVYRLSVFTPELASFSGPTMGTTYTVKFFTTKEVGDAWVVKEDVDAALVRVNSLMSTYDPNSELSLFNTLPAGQSAVISDDMAYVVDKALLISEMSGGEYDVTVGPLVNLWGFGPGKHEDKVPSQELIDEAKSRVGYQYLKLDGRRLMKEKDIYVDLSSIAKGYGVDAVARVLQDRGIESYLIEVGGEIVSKGLKPDGAPWRIAIESPAGGHDIAERIISVTDVAVATSGDYRNYFEKNGVRYSHTISPISGRPITHRLVSVTVVDKTTTMADGLATAVTVLGPDKGFEFVQKNGIAAYLLVKTDFGFEEHSSDAFKAYLK
->UniRef90_UPI0019100A88 hypothetical protein n=1 Tax=Aliterella atlantica TaxID=1827278 RepID=UPI0019100A88
-MVLIDNPNTRVTVRNIVQTLVFEDEEENTISETNGCLVGKLIEVRFGLLRSCGKEK
->UniRef90_UPI0013E3DCB5 hypothetical protein n=1 Tax=Streptomyces sp. B29(2018) TaxID=2485016 RepID=UPI0013E3DCB5
-MSNVDELRDLPALLQRVDFREEVVPHTAGAIEVFFGECREMPLRAVDPTKPRERHV
->UniRef90_A0A8C8YVF0 Actin binding LIM protein family member 2 n=1 Tax=Prolemur simus TaxID=1328070 RepID=A0A8C8YVF0_PROSS
-MSAVSQPQAAHSPLEKPPSTAILCNTCGNVCKGEVLRVQSKYFHIKCFVCKACGCDLAEGGFFVRQGEYICTLDYQRLYGTRCFSCDQFIEGEVVSALGKTYHPDCFVCAVCRLPFPPGDRVTFNGKECMCQKCSLPTSVGSSAHLSQGLRSCGGCGTEIKNGQALVALDKHWHLGCFKCKTCGKLLNAEYISKDGLPYCEADYHTKFGIRCDGCEKYITGRVLEAGEKHYHPSCALCVRCGQMFAEGEEMYLQGSSIWHPACRQAARTEDKNKETRTSSESIISVPASSTSGSPSRVIYAKLGGEILDYRDLAALPKNKAIYDIDRPDMISYSPYISHSTGDRQSCGEGDQDDRSYKQCRTSSPSSTGSVSLGRYTPTSRSPQHYSRPAGTVSVGTSSCLSLSQHPSPTSVFRHHYIPYFRGSESGRSTPSLSVLSDSKPPSSTYQQAPRHFHVPDTGVKDNIYRKPPIYKQHATRRSDGEDGSFDQDNRKQKTSWLILKGDTDTRTNSPDLDSQSLSHSSGTDRDTLQRVQGDNFHSRPPYSKSDSLPGHGNNGLDHRNANLAPCGADPDASWGMREYKIYPYDSLIVTNRIRVKLPKDVDRTRLERHLSPEEFQEVFGMSIEEFDRLALWKRNDLKKKALLF
->UniRef90_UPI002036F24A dirigent protein 23 n=1 Tax=Beta vulgaris subsp. vulgaris TaxID=3555 RepID=UPI002036F24A
-MNKFRLPTSFICVVLTFYIVNVSSAKTPSWAKTERYGHEHKTVIQFYFHDVRSGDAPTVALIAQPVEARSFASGFGNLFMADDPLTVSPDPNSKLVGRAQGFYGSASQESVSYIMGLTYGFVDGIYNGSSVVIFGRNSIVNRVREFPVVGGTGIFRMARGFAVAQTYFHNSTTHNAIVVGYNITVFHLELAMGRAGPDHGPGPRAEVEYGPGQARGP
->UniRef90_UPI000C85D657 HNH endonuclease n=4 Tax=Vibrio TaxID=662 RepID=UPI000C85D657
-MNWVIYVANATTKNFDIGLNQGIWGHKEIFSTVNTDKIKVGDTLYFVHHLTFMRDDNGNVIKGAPRVAAEHYKGSISTLVETRVTKGFYIDKKTVWPDDIYPNRYNFEVIEKHQNLPFSDEFFSSEFVQAVRTSTLTKGLAIELEGEHGEVYASNENIDLEYFEGNTVFRRHLVRERSTKLVNDKKRSVRDANLKLACEVCGFDFEDTYGERGYDYIECHHKNPLSESNGQKTKLKDLALLCSNCHRIIHRSRPWISVDELKEILNERASEATV
->UniRef90_A0A507FHA7 PRP1_N domain-containing protein n=1 Tax=Chytriomyces confervae TaxID=246404 RepID=A0A507FHA7_9FUNG
-MFHKPAFAPDFLSKKPPPNYIAGLGRGATGFTTRSDIGPAREQAPEEVAPPAIGPMMGGPAIGPGMPGMPPGANGDAPKKPLDDDDEQFQDPDNETGLFNTAPYEADDEEADRIYEEVDKAMDERRRARREAREREELERYRKERPKIQQQFADLKRGLAAVSQEEWAALPDVGDLVRKKGTKKKLPDRYTPSADLITIGGGFGSTVSGGGDAASGFATSIDPRMMGGLSTPAGTASVAGDQSGILTDFVQFGQGRNKVLGLKLDQMSDSVSGQSTIDPKGYLTDLNSMVTKTDAEISDIKKARQLLRSVITTNPKHAPGWIAAARLEEVAQKIVAARELAAKGCEECPKSEDIWLESARLNSTENAKIILATAVRHIPTSVKIWLRAQSLEQDVKAQKRVLRRALEFIPNSVKLWKAAVSLEEDSDDARILLSRAVECVPLATELWLALARLETYENAKKVLNKARTAIPTSHEIWITAAKLEEQQGNIGSLDKIIPNAVTRLAQKGSTLDRDSWIKEAEECEKEGFVGTAQAIIKATIGIDVDDDDREGTWLEDAESSVSHGAIATARAIYAYALQVFPQEEGIWRKAAFLEKSHGTRESLEEVLQRAVKYCPQAEILWLMGAKEKWLAGDLPGAKGILASAFEANQNSEQIWLAAIKLEVETGEYGRAQALLLQARTKADTDRVWMKSAMLERQLGNLPVAMSLLEEAITKFPQFGKLWMIKAQIEEHQLSNVVAARDTLSKALKAVPKSSPSAVTLWLMASRLEERAGQLTKSRALLEKARLLNPKQPELWCEAIRVESRASNQAIADALISKALQECPTSGLLWSEAILSESRPQRKARSKDAWMKSENDPLVLVTVARLFWSERKVEKARNWFARAVKVNPDLGDSWAWWLKFESVQEGDTTKMVADIVAKCKAAEPHHGERWQACAKDLSNTGRSVEEILKMVASSLPVTV
->UniRef90_B2YJ48 Cpn60 (Fragment) n=2 Tax=uncultured soil bacterium TaxID=164851 RepID=B2YJ48_9BACT
-ATILAQSIYREGVKAVAAGANPMALKRGIEKAVEAVVEDVKKLSKEVKDNETIAQVGTISANGDAEIGKTIADAMKKVGKDGVITVEESKTMTTELQTVDGMQFDRGYLSPYFITDPDRMECVLEDPYILIHEKKISNMKDLLPLLEQIARSGKPLLVIAEEVEGEALATLVVNKLRGTLNACAV
->UniRef90_A0A6I7QH38 Translocation/assembly module TamB n=1 Tax=Bacteroidia bacterium TaxID=2044936 RepID=A0A6I7QH38_9BACT
-MVIIIMMPFIAYAFLQSSRVQTYLVGHLTDYFSRELQTEISVGSVDIRLFRSVILKDVIINDRQGDLILEMRKMRFELGKLSFQNRSLVIKELEFRDAFLNLFKDKQEENYNFQFLVDYFSSPTVANGHNRWEFTCEAFKLTNASFWHLDLNRKSGVNGFDPANFYVSGFYLAMNQIEIVDNTLSLALDYLYYNESSGFIIDYLSGNFLLKHGQLDIDNFIFRTDGSDLNFSLSAKYGSFTSLEELVADLRFQMDIGKSVLHLADLGHFIPGLYGVNDTMKIEGAFEVLGDTLTGDNVLVEYGLKSRFDGDFQLKNFLGGSDMRLEFTARTLQSNFNEIAALNLPVSLEKSKPEFPPFLYNLGDFEFSGRIYGGLHSFQSEGSLASSIGTTYANLLMQRDNESMPYQYQAKVNTRNLDIGRLFGIGASAGKATLELNIKGEGFHPDNLDLLVDGHIASVELASYTYNDISFQTEFLNQNLNGQLGVKDQNLLLDITANAQFDKEIPFFDVLVNIEHANMTKLALFQKDSLVESLLKTHIHFNGKVSSLDSFEGDLVFREIRYEEIPLEQDHHSSRYLVFTDSIFINSKKWSPDNQHIRLRSGFADADVHGKLHLTALPRNLKESVQNILPFGEPDLSGYTGTEYYQDQDIQFSFHFKDTRILSELFLPALSLSGNSWLNGHYRSADHHLIFIAHADTLALENRRFLDLNIGGTHGENNYSITFDSKRLMVSDSLHFDLVSLQSGWKEQSLDVKLEWQGTNGDESGIGVISGHANVYDKNHIEFSFLPSYALIHGDLWRINIDNKIIVDSSRIEVSGLMVYHGDQFIRADGVLSDHPRDRMMVSFSNFEVAYSDLFLGESNFKFGGILDGYVTFTALYQSPSIGAGLTIQNFAFNHQELGDLQLSSIWQFDKQAFLVDGKITSKADDQEHNLLTLSGSVYTGQNIGRYDLGISLHNMKMEVWRPYVQSFSENFKGLATGELHLGGPLNSPELTGQVRLMETSMHIPYLNVTYFLEDDVRFTKNAFVFEDVAIRDTLGNIAKASGAILHNSLRGFGLDLHIRPSNTIVFNTTAVDNSIYHGTGFVTGLAHLHGPVNDITMDITARTNRGTRVILPLNSAGEVRENHFITFVARNPENNLPLMPPPDLSGNITLNFDLEVTPEAEVLLMFSPPFGDIIRGRGNGNLKLEIPPDGAFNIYGDYVITEGEYLFNLQNIINKRFRIEQGSTIRWTGDLNDADVEMQAAYRLRTSLYDLFVGEGIDSETVEMFRRRVPVETLLILQDRLFNPTISFDIQVPGGDENTREMIERVITTEQEMNRQVFSLLVLNRFLPSREDQYNTALGFGVGSTSSELLSNQLSNWLSQISTDFDIGINYRPGDEITSQEVELALSTQLFDNRVTIDGNFGVAGNQTASGQPTQATNQIIGDVNVEVMITPEGKLRVKAFNRSNTFDIIHTNAPYTQGIGVFYRKEFDRLEELFRRNRIPEIPVDSD
->UniRef90_A0A6G6Z3X8 (2Fe-2S)-binding protein n=2 Tax=unclassified Bradyrhizobium TaxID=2631580 RepID=A0A6G6Z3X8_9BRAD
-MFKRSDQDKRPSVQIFVDGAAIEARAGDTVSAALLASGRDVRRATAVNGAPRLPYCMMGVCFDCLVTIDGVGNRQGCLVPVTEGMQIEIQKGKREIGR
->UniRef90_A0A7K0PYB7 M50 family peptidase (Fragment) n=1 Tax=Actinomycetia bacterium TaxID=1883427 RepID=A0A7K0PYB7_9ACTN
-MLGRSVSVMPGRYPSSPGLSPRRPGVVGWTAMTEIWDRVGATSPPLPPLWLGVTAVLALVLVVQRDLWRVTRNAVTIAHEGAHGVAALVTGRR
->UniRef90_A0A177HN16 Cell wall protein-like n=1 Tax=Streptomyces jeddahensis TaxID=1716141 RepID=A0A177HN16_9ACTN
-MPSLKLAPLYLRAEEKGSDSVQRHSSLSGYASMIACRLAFGRGSDSPRAPRTLRMYVSSAPSSARTSVTSMPPSVSVPVLSRQTVSTRASPSIAGSSCTRHCFRPRRMTPIAKATEVSSTSPSGTIGTMPPTVRAIASLKPESSVSSASWLMIRPRAVGIIIHVTYLRIVEMPVRSSEWTSVKREASSASCAAYASRPTLVAVNAPPPATTKLPDITGSPGFLTTGSASPVSSDSSISSPSASATAPSTTILSPGPISIRSPRTISEVLISADTPSRRTVGLASPINARESSVFLARSSWMMPMPVLARIT
->UniRef90_UPI00083E5566 3-deoxy-7-phosphoheptulonate synthase n=1 Tax=Streptococcus himalayensis TaxID=1888195 RepID=UPI00083E5566
-MTFKALSQPINVKEVRSNYKLEGASLQRKEERDAALNAIIRGEDDRILLVIGPCSSDNEEAVLEYAKRLAALQETVKDRIFMVMRVYTAKPRTNGDGYKGLIHQPNATAAPSLINGIKAVRKLHYRVITETGMTTADEMLYPENLPLVDDLISYMAVGARSVEDQQHRFVASGADLVTGLKNPTSGNLTVMFNGIYAAQNKQSFLFGNTEVETSGNPYAHAILRGAINEYGKNVPNYYYDNLLDTIAQYEKMGLENPFIIIDTNHDNSGKQYLEQVRIVRQTLINRAWNEKIHRYVRGFMIESYLEDGRQDEPDVFGKSITDPCLGWDHTEQLVREIYETLGK
->UniRef90_UPI0003685307 undecaprenyl-phosphate glucose phosphotransferase n=1 Tax=Gayadomonas joobiniege TaxID=1234606 RepID=UPI0003685307
-MGKRGYLREHQHAFSSLYRVIDVVLICLTLFVSWDCFAGLDTKQHYFVAIVASLIFLYLAETFGLYRSWRLARFYQLARTITFVWSVTFLSTVFVAVLLEIPEGVSQLVFVSWGLVGTFLLSAWRYAYYVAIKKLRKKGFNTRSVAIIGHTRVGKELYKQIRLHSEAGLKFVGFYEDRMPQRYMGDKYSSDFIRGSAEDAIKAAQRGEIDQIYIALSLKQEDRISQLLVELGDTTADVHFIPDFFVFNLVQSRMGYVGNLTTLSVFESPYAGTNSWLKRAEDIIFSSIILFIISPVLLAIAIGVKVTSPGPVIFKQYRYGLDGKRIKVWKFRSMTTMDNGDKVVQAKKGDARITPFGGFLRRTSLDELPQFINVLQGRMSIVGPRPHAVAHNEEYRKKINYYMMRHKVKPGITGWAQINGWRGETDTLEKMEKRIEYDLHYIGNWSVWFDIKIIFYTVFKGFLDKNAY
->UniRef90_A0A7V0QHY8 3HCDH domain-containing protein n=1 Tax=Deltaproteobacteria bacterium TaxID=2026735 RepID=A0A7V0QHY8_9DELT
-MMGGSMKEKILVLGRGEIARSLFDICKQTELSVTFLESADELGPQLRDTDIIVQFVADGLELPHLKESDFIGKYKVWLIEVIDQSVTRAAGRMGCSERIVGFSISKSFQERRFIEVIGGERTGSDAVTTARNLFERLQFTVVISKDHPGYILNRVVASMINEAIYVSMYGLAQMEDIDQMMRLGANFPMGPFEYADYLGLDRVLKTLEWLAEELGPQYRPCPLLRRKVEAGLLGKKTGKGFYEYGI
->UniRef90_UPI001106F8B2 antibiotic biosynthesis monooxygenase n=1 Tax=Eubacteriales TaxID=186802 RepID=UPI001106F8B2
-MICTLVRFHIKHGCGDRFLELARTSVEQTRLEKGNISYDMGPELGKTDTFIFFERWKNQESVDIHESQTYFQSFDRAAGELMDGPVEVFKMEPPF
->UniRef90_A0A2E6YUS8 SLT domain-containing protein n=1 Tax=Halieaceae bacterium TaxID=2026743 RepID=A0A2E6YUS8_9GAMM
-MKNVLGIVTLVLSMGSLPGISLAASDDDRAALTTDLSKALTEDNEFQDRFDAEVWLVDMQQRLAPLVPDAQERLDLLTQVHQQASRVVLHPELVLAVIEIESHFDRYAVSRAGAQGLMQVMPFWKNELGRPEDNLTDTATNLQYGCHILRFYLDREDQHLSRALAAYNGSSGSERYPNKVRDAWQTRWRTQPIDW
->UniRef90_UPI001D0CC098 thioredoxin n=1 Tax=Roseitranquillus sediminis TaxID=2809051 RepID=UPI001D0CC098
-MLELGGRKEDAATDLIKDSTEATFMQDVVDASRDVPVIVDFWATWCGPCKQLTPALEKAVTEARGKVRLVKVDVDRNQQIAAQLRIQSIPTVYAFWQGQPVDGFQGAVPPSQIKEFIERLVKLGGGDDGDPLAEAVEAAETMLAEGAAVDAAQTFAAILGEAPTNAAAYGGLVRAHLAMGEADRAAQLIDAAPAEISGSPELEAARAQLELARQAEKAGPVAELQQAVEADPTNHQARFDLALALHAKGDVAGAVDQLLELFRRDREWNEAAAKTQLFTIFDALKPQDPIVLNGRRRLSSMIFA
->UniRef90_A0EUM8 Protein Nef (Fragment) n=1 Tax=Human immunodeficiency virus 1 TaxID=11676 RepID=A0EUM8_9HIV1
-MGGKWSKNSLGGWPKVRERMRRAEPAADRVEAEPAAVGVGAVSQDLAXXGAITSSNTAATNABCAWLEAQEDEEVGFPVRPQVPLRPMTYKAAXDLSHFLREKGGLEGLXHSQKRQDILDLWVYHTQGYFPDWQNYTKGPGIRYPLTFGWCFKLVPVEPEKVEEANEGENNSLLHPISLHGMDDPEREVLVWKFDSSLAFHHRARELHPEYYKD
->UniRef90_UPI0021B1B406 hemerythrin domain-containing protein n=1 Tax=Mycobacterium sp. SMC-2 TaxID=2857058 RepID=UPI0021B1B406
-MTSAWRSSDLAEAFREDHAVLGRGLHEVSEHLRAGNDQAAKARAERVDREAGAHIAFEEQFFYPALRRTLGDAEVDGLYEEHGEGLSVIKALAQLPEGAELTEADRRTLLQASELTESHVAECGELFGVMGRIPPDEQQALYRELLSLREESPRWTEFAARTKEG
->UniRef90_A0A7D4A833 Superfamily I DNA and RNA helicase-like protein n=6 Tax=Actinomadura TaxID=1988 RepID=A0A7D4A833_9ACTN
-MTERHLVALTKPEPSPVLDPGEAATRAVDGVLADLGGGHRGVVVDSPPGAGKSTLVVRAAAHLAEAGERLMIVAQTNEQVDDLIERIATKHSQLTVGRLSASGYLPSERVLAHPSVRVAQKADDLAEHTIVIATAAKWATLSDGSWPWAIVDEAYQMRSDMLLRIAGRFERALFVGDPGQLDPFSTVEVERWAGLSWDPMRSAVSVLLAHNPGLPVHRLPVSWRLPASAAPVVSDAFYPFTGFRAGTSDGDRRLEYGARGMGTTYDHALEEAAATGWALYELPARHTLRTDSEAVRATAALAVRLLQRGPVAHSELGSKPVDATRVAIGAAHRDQVTAIRAALGEHGEGITVDTANRLQGREYDVTVMLHPLSGRRDATAFHLESGRLCVLTSRHRHACIVVARAGIPELLDAHPSTEPVHLSVPVKFPDGWEANQSILAHLARHRVAAD
->UniRef90_UPI00132F9BB1 sulfatase-like hydrolase/transferase n=1 Tax=Klebsiella pneumoniae TaxID=573 RepID=UPI00132F9BB1
-LRNSGSTFSLVYFSDHGLAFKERGKDVQYLAHDDKYQQNFQVPFMVISSDDKAHRVIKARRSANDFLGFFSQWTGIKAKEINIKYPFISEKKAGSIYITNFQLQKVD
->UniRef90_A0A554VFG8 AtpZ/AtpI family protein n=2 Tax=Flavobacteriaceae TaxID=49546 RepID=A0A554VFG8_9FLAO
-MGGTIFLCAYGGKKLDAYYELEKQWFTMGLVLFGVTASIYLVIKQLNRINKSDR
->UniRef90_A0A7C1UAD0 CBM-cenC domain-containing protein (Fragment) n=1 Tax=Phycisphaerales bacterium TaxID=2052180 RepID=A0A7C1UAD0_9BACT
-MNVRWRSQGDFCESTCSDGGRGHNNRGALSKRRTTMYKQLMFPICLTVVLGLTARASEPFGHWPFDGHVNDVAGSANGTFFGGSPDYVNGRIEQAIRFDGVDDYVEVMVENLDAYTITAWVMPDRVEPASIVVRTSPSGTTTHWSHQMRIAASGQFEHYVWDGAAQTALGTTQVEAGNWYF
->UniRef90_A0A6P0WQH9 Type II secretion system protein n=1 Tax=Caldora sp. SIO3E6 TaxID=2607806 RepID=A0A6P0WQH9_9CYAN
-MNICELPQKLLPQKKTTQPNQSGFTIIESLVAIIVISILMLGLSPVIFLSVAARVQSRRVERGTEVARTYIDGVRSGAIPATNVVVGAATDRTLEAGPVPTALNPVDWSDPGGLYCVDLDASGGCEAGSMNDMVVQGFRTPGDADRGYLLGVRVYRAHAFSGGEPLQKGQTQSSFSGTLGNSKVPVVEMTTEIPPSGAFQDNFSEWCARLPNTNPISTCN
->UniRef90_UPI0006E338CE trehalose-phosphatase n=1 Tax=Streptacidiphilus griseoplanus TaxID=66896 RepID=UPI0006E338CE
-MGIPEPTTPAGAEGLAALVADPAHSVIALDFDGTLAPIVPDPDQARAHPGVVPALARLAPQVGAVAVVTGRPAGVAVRHGGFAGVPGLEHLVVLGHYGAERWDAVTGEVRAPHIHPGVASVRAELPGFLDRIGAWEGTWVEDKGRAVAVHTRRTEDPDTALEQLRTPLLELAARHGLMGEPGRMVLELRPPGVDKGVALTGFLHERKARSVLYAGDDLGDLAAYDAVTRLRTEGVAGLLVCSAAEGEEPVGRLEERADLVVGGPSGVVGLLDALADEMGAPRP
->UniRef90_UPI001CB69EC9 polyubiquitin-A isoform X6 n=1 Tax=Frieseomelitta varia TaxID=561572 RepID=UPI001CB69EC9
-MQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDDRTLSDYNIQKESTLHLVLRLRGGMQIFVKTLTGKTITLEVEASDTIENVKAKIQDKEGIPPDQQRLIFAGKQLEDGRTLSDYNIQKESTLHLVLRLRGGQ
->UniRef90_A0A6M3XMR9 UDPG_MGDP_dh_C domain-containing protein (Fragment) n=2 Tax=viral metagenome TaxID=1070528 RepID=A0A6M3XMR9_9ZZZZ
-ANPFGFVSEAREKQSKWLAKLIKREQERRKLPVVIMGLTFKHNTNLTTDSPAILLMEQLEDMGVKTSAYDPVVMPSRPKDVPSIYFIATRWVKFSTFPYAKGSLIIDPWGFFGVAPEGCELFSIGRNR
->UniRef90_A0A7W1P943 DUF4625 domain-containing protein n=1 Tax=Acidobacteria bacterium TaxID=1978231 RepID=A0A7W1P943_9BACT
-MKKPPLQRRTISVPVPELPPGKYKLVIIAESRGAVARSEVLAYEVR
->UniRef90_UPI001F566F06 DUF6516 family protein n=2 Tax=Shinella zoogloeoides TaxID=352475 RepID=UPI001F566F06
-MQARLILKTRRHIGEAMFADLVIWRVPEPLRGSRHPFKYRLAFVADGICVMRYDNEAGKGDHKHIGAEEQPYAFQSIEKLLLDFDADMKGWIDGNADRED
->UniRef90_A0A1I7GQJ1 Glycine--tRNA ligase beta subunit n=4 Tax=Burkholderiales TaxID=80840 RepID=A0A1I7GQJ1_9BURK
-MTAPSNLLVELFVEELPPKALQKLGDAFAQVLLEQLTAQGLATGASQCTAYASPRRLAAHITAVLPQAADKAVSQKLMPVSVGLGADGQPTPALLKKLTALGADASAAAALKRVHDGKAEVLYFESTAKGALLAEGLQKALDEAVAKLPIPKVMRYQLQDGWSSVNFVRPAHGLVALHGASVVPVAVLGLQSGRATQGHRFEAAASPVALRDADSYAAQLRDEGAVIASFAERRAEIVRQLQAAADKVGGGVRPIEDAALLDEVTALVERPNVLVCQFEQEFLAVPQECLILTMKANQKYFPLLDAEGKLTHQFLVVSNISPQDPSAVIQGNERVVRPRLADAKFFFDQDRKKTLVSRVEQLAKVVYHNQLGTQGERVERVRAIAKAIGAQLFEALAAQHRIDGTQDAEVVQDYLMTCVDNAALLAKTDLVTDMVGEFPELQGIMGGYYAVNDGLPDDVAHAIEDHYKPRFAGDALPRNNVGLVVALADKLETLVGMFGIGNLPTGDRDPFALRRHALGVIRMLAERDLPLDLSALLAAATPAFGGKIEDATAQLADFIYDRLAGSLREQGYSAQEVDAVLALRPQRLALVPKQLAAVRAFAALPEAPALAAANKRVTNILKKAGEVDAHVNPELLQEQAEKDLYVALQRFVPEANAQFLAGDYTGSLQTLAVLRAPVDAFFDDVMVNAEQLDLRLNRQGLLKTLHDAMNRVADLSRLAA
->UniRef90_A0A835R703 Transmembrane protein adipocyte-associated 1-like n=1 Tax=Vanilla planifolia TaxID=51239 RepID=A0A835R703_VANPL
-MMAYYGLIWIVSVLNLTWCILQAWQCTPTKEFSWNLLSLCTKSGMLFLEVSLISFLLQGNQAGDLEALTRTFVVSGVIVAVDVLLKAVYVFGFGVPMFLDGVGPSNHVKWGLWIVHKLLLAAVYVLILFMYHSKWREMLPAQPAFRNYICVMFSINALSLFSCLLMENGAGFGYWLLSLVTLCYHSLYLPFLYITFLADFFREEDMRLENVYYSEMKDAGFFDADWD
->UniRef90_A0A806X1Y9 DUF4091 domain-containing protein n=1 Tax=[Enterobacter] lignolyticus TaxID=1334193 RepID=A0A806X1Y9_9ENTR
-MLNPCIDDPDEHLVFLDDGRVEPALINGQESRKGKASIQYLGLARAELLQMRARHRRTVIAAIRHTIAALEEGRDPGTDLDDLLTLLSSKEAYVAYTRTLVRTHMSAYIEALGL
->UniRef90_A0A1V9ZKS3 Secreted protein n=1 Tax=Achlya hypogyna TaxID=1202772 RepID=A0A1V9ZKS3_9STRA
-MAGRERRAWCSWLLVLLYALTVRGNQLLVISQPATMTAGDMLSPPVLQIVDDTGLVLSDINTGTVTVSIETNPLMYAVLSGTSGLAFPIVAGVVTCSGLSINLVASGYTLSFVALSYGLQTSSNPFDIILGPPYQLSMYTYIGVAQGGTPFSPQPTVAIVDKGGNLVASVSSGSVSVAILNNPVGGILTPAIAHTVYFYEGFGKFYDLQIDKAGGPYTLKFTCDASLNLPGGNSYTTFPFTVAIGPPRTMFIAAYPLAAFGGEAFVTQPMIQLLDAGGNTLQTQPSMQIAATIYANPSGGRLYPATETSASVINGFASFKNLRIDLAGNNYMLRFAITMLNVLGVYAETGLAVVGPSLNVYLGALFSLQVLRPPESAIADGQPFYTQPVLVLRDRGNNTISTENLALVSVSMVPSLALYNNLIVSTANSPIATITDVTLLFSPFSAPFGAGTDLFINVTFSQQIMATGSIVLQMNSAPGALATCNTLLTWSNRLTFGYGITAGDAAAALNYASTSALTLQGGATLVDRLGVPASLILPAAGLRPAVVVDTTAPSIVSVGCVPPFVAGTYGPGQVVSLLVTFSAPVSIYSTLMPYLLLNTLPAQSAIYSSGNQTASLVFQYIVGPTDAVATLDVVAALNTNGGLLRRAGTALKQDALLQMPATASSRLPAQCPLVISSVVPAIDATVGVTSATPNGVYATGDRIFITVPFTALVAVSGIPLLALNTGRNAAYSSGSGSSVLTFQYIVQAGDSVAALDYASPAALMLNAGTIQRFVTAGSPLLDVNIDLTATTASNRNLGQTAALVLNGLAPTVVSVAFPVAPTTYTRGGTVAITVTFSYAVVVQGQPSILLNTGVAATYASGSGSTALVFNYRVQLGDATTDLAYAPTSTIVLNGGSILQQSSTPSLAAQLMLPWPPAIVNAPVTIDPALTAVTTVVSITADQVAGEYGQNQVIQITVTFSDAVQIVGGVRLALTTQTVAYASGSGTKALVFLYIVQPNDATSSLNIASASPFTCTAGGGCSIANANYLAANLDCTGLTLQPTAIVINTVAPSVVSVAALTPAPTINRGTFVVGDLIQILIVVSKAVDVQPSPSVFPTKVPTLLLNTGQVAYFTGYDNGDRTRLLFQYTVAVGDATPNLQYASTGALTLNYNQASIRRLATNPTTPMNLLLPVVANLGTNLVVDTSRTPIVINVASITADGTYFVGDVIAIRVTFSEYVVVSGIPVLLLNLGVYDRSAVYVSGSGSTSLVFQYTIGQDDFSKDLSYIDLRSLYNPPGASILFQSTNPTVAANCQLPLPGSAGSLSANSNLQVLGGTPYIVDIAFLSPNATYTVDNTIDVQVTFSAKVVVSGTPFLRMASGPSLRQAFYVPTVGASTTVVFRYRVQTGDVSMDLDYADTAAIQLNGGSILTAPTLLTSIPVQPANLQLNPPGGALTGTRTVQTVAGVVNYVNLGIDTMGLGYIFYFATATVVTSVQFDVTYSAVWEVRNAPLNEQNRGDRTGSSVDITTGVAVVGSAGAKARQYNVQVVTASGSATKYVNEIQYVQTTCVQRDAIQVLTSSAAPGSTLGGYFTLMLGAEGPTRRLAYNFDATQLKVALELDFGFDAAAVEVTRTPNTFCGCFDAYAWTITFHTDGEIPTLLARSYLTGVSATVGDGTGGASALVLSLPPVVNGQFALRYGALVTASMPSNVDATTMANRLTTDLNLPILSVQRSLPTVQAGYTWSITFYASATIFNPNELEPAPLLLTGNQVLLSVTTVQEGQAPLYGNFRLSIAGHTTPNIAVTASAGDVQTALQTLPEVTSVAVTRSAVNPSGGYSWTITFLQINLMSTYGLVLNSLGTLPPLTPMTLVNGAPILMGTSATIMVNYAGVNPSANSPAGFGNAPGESAGSVTIFVPRNLQWIQSANLLGSDTQSGDNFGAAVAINTAGTQVDRGRKEIQTLTCTADGGSFTLTFLGITSPPISFAATAATLQAAIARLLNVPLSQIAVSTYTNLCAGIGVAVTFATPDLSTETGNVPNLVPDGSSLTSSGGPGSIVVQEIAPGTYRLDGTEAKGATCGGAYFYQASAGMWSQMAKMLPMDGSEGTSSEFGASVALENTYAVVGAPAAADSVGEAYVYIFNGLTWSFFQKLTCAPYAGTKGDRFGEVVKVSGSTIAISAPGYASNLGAVFVYKLVSGVFLSHEKIQAGDLSAGDRFGSAIALDMAVSTLVVGTERQATATGAVYVYYSRDVYFALQQKLQGSDTRVNDGFGHSVAVVRNVLLVGANANFGATTPLTTRKAVQSIVTSATSPIRAGSTFLVGFRQFSIGFENDYVMSTPIPFDASAVLLQVILQRTLNTGALVVTRLGPDANNGYTWYVTFAGSTAAVTRFAVDGTGLKGSNADVAASVLVAVPPIVRSNTYVFTRTGTFWREQATLRPTNKQYFSLFGHSVALSRNGYHAAVGAPNADTLFTGVNSGAGYVFDLGFLDFQLSASAYSVLEGGTISIPVQRCGPLGLTCTMKSTSVEGFIDLDTGDAVTDRAGTNNVPSKMLKYIGPYQQLAMLDMAAVTSGAKYYPGIWGPEPYPQVPMGRYLLPSWVGTAESRAQFYGSAETRSLWIDSQFDYQGHSDYTPTDVAMAFAVNSITSTALIQTTDDMVFEYPDETINVRLSVPGMWPSYPSQFWSQITILDNGDGGFGTKSYTAILLSSATAPVAHGTAVALLDAFNLAAVGEPGEVHPTTRVACGAVLIYLATSGIWALEATLRPPTCIAGSGFGTSVAIDGSYGTVRLVVGAPSALTPTVFVYVRNSATATWNLETAFTEPAAASTSANYGGSYAVDIFGYNIVVGASGLECTFVYTYTTTGWLPAVVLRANDYATDVVYLQNVVHEFEFGAAVSIGQRSIVVGAPRANYGTSRQLDTTFLGTGAAYVYYLPAQVQTITLNIDVLVTAGQFVLSLGGASTSRLNYAISDVDMTTAIQALIPSVQVTRAGTTETGFTWRVTILSEVTTVPLLVATWRGYGCSTCIAFNTGYTADPGRQVDVTSTAALGTWTFHQRLTAADGNRADRFGAAVDLDGDSIIIGAYGSFSLTTTTWDFETGDLTGWVQTGTAFGSQPTFGENVRARASGYLSSYLKSASGILNFEGRYWVGTYEARPGAGRTQQYTPFSCAFMNDDCKATGYTTPDSSIAGSAQGDGPMGTLTSQPFSILGSAIRFRIGGGCNLATVYVELLVDGLSVRKATGRCRESLHRVAWNVTAFTNRTGQIRIVDDTDSVNWGHINVDDFQFDWPVQQPSTEKAGAAYVFYRSTSTTSYGVCQGVPKLQCAWMLQARLVASDKRDHDMFGFSVGINDALGMAVIGAYGQSIVNLNNSIAGGDDAGSLYLFIKTPALLDGVGSIITPQRWPAFETAKLQAVNKAPNAQFGYALSQSNGRVAVGSPGMQRGIGTAYVLDTQFIQVSFASDEVAVNENDVNGQAIVVLYRAGDTSAPLTIEYGGFVKAMNKVTMLARYATSDLTGAGVDATRFAQCMAMPIQNRIRCGRYQQTSGVATFPVGGTSLAIAVPIMNDWCYAEGQTHVAFHLNPPGGDVILGEQFTLRIRIDDDDFGRTAC
->UniRef90_A0A1W1Y6B4 EAL domain, c-di-GMP-specific phosphodiesterase class I (Or its enzymatically inactive variant) n=1 Tax=Oscillospiraceae bacterium TaxID=2485925 RepID=A0A1W1Y6B4_9FIRM
-MTPVGTTYLENYTPAADVLVVAVCVVFVILIRSAYINRTRSFRYLRHMIYMAVVASVSNLIFHGILPRAATLPNILIYLPHLLFHASLYSILWLQVQYLKETVRLTFRENRLYTVLSSSGLVALIVLEIVQPLFGFGFYMGADNTLHREIPAFIFGYVFFVLLMLSMLLKYREMIFRAILVGILSSVSISFLLMLIQEWVGETSYTVFTFLFPIYALLYLAHSNPYDLEIGAVDERAFTDLVAISYEHKDELYLMSLYMHDYDGKGQHYPEELQKMIKHFVYKFFKHPTLFLISGGHMILVVRTSSDPGYLEGAEKMIEEFMKLYSEYKIDYKIVYTKNDVRLAEDNDVVNFIKYLHFDMDENSISKPGDKEIEAYLRYKYIVSELVDINNKHDLNDPRVLVYCQPVLNIKTGKYDTAESLMRLDLPKTGLIYPDEFIYIAERLKYIYTLTQIILNKTCLKIKEMLENGYYIQRISVNFSVYDIREPDFCETVEKIIRDSGVPYDKVAIEITETQNERDFENIKKRIDELKESGVRFYLDDFGTGYSNFERIMELPFDIVKFDRSLVIASGSGNKYKSMVSNLAMMFDNGDYSVLYEGVENDEDEKRCIDMNAKYLQGFKYSKPIPIERLTEYLDKGHED
->UniRef90_A0A7W3YDD2 Molybdopterin-synthase adenylyltransferase MoeB n=1 Tax=Lysobacter penaei TaxID=2759900 RepID=A0A7W3YDD2_9GAMM
-MEIERIPPAEALRRQRAGTVLVDVRASHERAAGAAEGALGIVRETLEADPTAALPDREAPVMLICQMGGRSLKAAEALRAAGYARVASVEGGTERWRDEGLPLVRDEANADFYERYSRHLRLPEVAEAGQRRLQAARIAMVGAGGLGSPAAFYLAAAGVGTLVLADDDMVDRSNLQRQILHTEARIGTAKVESARIALNALNPSTRVEAFPERITAANVERLLEGADLVIDGADNFPVRYLLNDACVKLGTPLVYGAVHRFEGQASVFDAGRHRGEAPCYRCLFPEPPPAEAAPNCAEAGVLGVLPGLVGLVQATEALKLLLGIGEPLRGRLLQVDALSMRFRETRLGADPDCPVCAPGRPFPGYIDYAAFCAGG
->UniRef90_A0A8H6JB52 AB hydrolase-1 domain-containing protein n=1 Tax=Colletotrichum sojae TaxID=2175907 RepID=A0A8H6JB52_9PEZI
-MAATKAPRSLGIVLIHGGFHQSTCFALAKSRLEAAGFSPVLGVDLTSVGTNPSVTLDDDARSIQAAIEPHIDAGREFLALAHSYGAGKKGGIRAAIYLTANMPPKKGASALSVLPPGLDIVDVGDDGLVRANAKAKAAFYGPDMSDETADACMAALLPQSSAALFGGASVGLDELTVPAYYILCEKDQTIAPATQQEIIATIPTLRRVLRNPGGHSAFITEVDRFVEQVVEIAEEVEREGEVEA
->UniRef90_A0A4Q9GHY3 histidine kinase n=1 Tax=Hansschlegelia quercus TaxID=2528245 RepID=A0A4Q9GHY3_9HYPH
-MTSEPRLRDGSTLRRHDGAVRPLSASERKIEEAAHEIRTPLGGLLALADLLLAEDLTDAARGHAEAMKDAARHLFGVATTLLGGAETGAASLGMSRFLDRTVPPIAARAAVQSLSFQLLRGPGVPERVTADESWLRQIIDNLADNALRATRSGGIELAVDCIGEDANSALVRFAIRDTGPGLGDDPKALFARYAQGDEPGAAGIGLSLVARLAHRMSGRLEAANRPEGGAEVAAVVRLATQSEPVRHAGAQLKILIAEDNIVNQRVVATILNQFGHDYDIVGDGEAAVAAASTGAYDLVLMDAAMPHLDGLRATRRIRSMDTPAADVRIVGVTARAFAHEIADFIAAGADAVVTKPISIAELWRVIGADVRKAG
->UniRef90_A0A429S8T5 PLP-dependent aminotransferase family protein n=2 Tax=unclassified Streptomyces TaxID=2593676 RepID=A0A429S8T5_9ACTN
-MANGRVVHTADRTIGSRQLAALLPPPVLARPGYRALAEAIRTLILDGRVALHIRLPAERELAECLGAGRATVTGAYDLLRESGYARSRRGSGTFTELPDGHRPVGAHALLGAGGSGGFLPDGDPGIDLAIAAMGAPDGALAEALAQAAPRLPAAARTPGYLPFGLPDLRAAVAERFTRRGLPTRPEQILVTAGAQQALTLVVSLLCRAGDRVVTENPTYANALDALRHARLRTAPVAVTDAGWDLEIAESTLRQTVPRLAYVIPDFQNPTGALMPEDQRLALLAATRRTGTWLVVDETLADIALDVPAPAPLAALAARGGADHVVTIGSLSKTHWGGLRVGWVRATAKLVAELTAVRAATDMTGSVLDQLVALPLLDGLERTLPARLEQLRVQRAALIEALQRHTPEWSWTVPPGGLSLWVDLGEPVSSALAERAAAAGVHIGRGARFGVDPGTFEHRLRIPYTLPPERLDEGVRRLAAAFHDGVPLAPAVDRPHWVA
->UniRef90_UPI001F223AC7 type VII secretion system-associated protein n=1 Tax=Streptomyces sp. GQFP TaxID=2907545 RepID=UPI001F223AC7
-MADFSHTDKQSIQTFIDGDLASFIGDLKKILAGDPSMKDFENGVYTDRTAGAIEKGKPIMMGRIDRNDLMTGTSFTDALSTSISTVVDVLTAQQDTFDEIDEGLRTTLHELFKTQGDNLGNISAEEFSTSMSDSGFDDSSSSGDSTGDNGSDSTDGESA
->UniRef90_A0A4S4FJ12 4-aminobutyrate--2-oxoglutarate transaminase n=1 Tax=Glaciibacter flavus TaxID=2565934 RepID=A0A4S4FJ12_9MICO
-MTTIDAPARTVGGPDIVQERRLVTSIPGPLSRALMTRKTDAVAAGVGATLPVFAAAAGGGVVVDVDGNSLIDLGSGIAVTGVGNSHPRVVEAVKAQLDAFTHTCFTITPYESYVAVAEALNRLTPGDHLKRSALFNSGAEAVENAVKIARHHTGRQAVVAFDHAYHGRTNLTMGLTAKNQPYKNGFGPFAPEIYRAPLSYPFRDGGIDGVTAARTAILQIEKQIGAENLAALIIEPIQGEGGFIVPAAGFLPTLLEWSRANGVVFIADEVQSGFGRTGAWFASEHEGIVPDLVVTAKGIAGGLPLSAVTGRADIMDAAQVGGLGGTYGGNPLACVAALAAIESYASEGLIERAGDIGRLLIDRLTALQASDPRIGDVRGRGAMIAIELVDPETDAPDAALTARVASAAHAQGVIVLTCGTYGNVIRFLPPLTIGDDLLTEGLDVIAEALATA
->UniRef90_A0A7W5AC37 glutamate dehydrogenase n=5 Tax=Actinoplanes TaxID=1865 RepID=A0A7W5AC37_9ACTN
-MAVADEAATDSDQTVLDDVPNAERLVAQAVEQAGDDHTTASLVGRFWRFAPDEELVGYTPQEMFAAAAEHRELARNRLPGELKLAITEPSGSQSHSVLRIVTDDMPFLVDSVIALLNAHNLQVYLTVHPLIVVRREPLGALAQLEAEVEPDDAIEGDLVESWIRIEIDPVRRPEAREQLLNEVRRVLTDVRDAVEDWPRMRQRALVISDELAAARGSKNPSPVPDKDLTDSIELLKWLANDHFTFLGYREYRLDDGVLSAVPGTGLGILRGASKPRRLAEEMAPEIYERAMEKRLLVITKANSRASVHRSAYLDYIGVKLFNEAGEVVGERRFLGLFSSSAYRTSVRELPVVRRKVQEVMDRSGLSPRGHSGKDLLQILETYPRDELFQIKTDDLYEAVIGVLRMAGRRQLRLFLRRDGYGRFISCLIYLPRDRFTTGNRLRMQEILLRELNGVGVDYTTRVTERMLARVHFIVRTDPAAPPGQLDPNELAERLADATRMWDDDFSLVLERKLGDEQARRLFQRYSAAYPESYKNTHTPYEGMQDLAKLELLEEPGQLAMHLFRRRRLGADGTPQPDERDVRFKVYRYGEPMMLSAVLPVLHSLGVRVTDERPYEIRRPDGTIYLYDFGLLPPAGHRELAEVRPQVENAFAAAWRGETEVDGFNELVLRAGLTWRQVVVLRAYAKYLRQAGNVFTQQYVESTFTAYPEIAGLLVRLFEVRFSPALPIGEAERTRRAGELRGRITELLDQVESLDQDRILRSYLTLIEATLRTSFYQRGAEGRPKSYVAFKLDPQAIPELPQPRPKFEIFVYSPRFEGVHLRFGAVARGGLRWSDRREDFRTEVLGLVKAQMVKNSVIVPVGAKGGFVLKQKPGDRDEAVECYKRFITALLDVTDNILSGKIVPPEDVVRHDGDDPYLVVAADKGTATFSDIANEISVRKDFWMGDAFASGGSAGYDHKKMGITARGAWESVKKHFRDLGTDTQSEDFTVVGVGDMSGDVFGNGMLLSQHIRLVAAFDHRHIFLDPDPDSSISYAERRRLFDLPRSSWADYDASLISEGGGVYPRSAKSIPVSPQVRAALGLGEASTISPAELMRAILKAPVDLLFNGGIGTYVKGAAESHAEVGDKGNDAIRINGSELRVKVVGEGGNLGLTQRGRIEFARAGGRVFTDFIDNSAGVDCSDHEVNIKILLGGAVVDGELSLPERDDLLAAMTGEVGELVLRDNYEQAMALGNARSQAHSLLPVHRRQLKSLEERGELNRELEALPSDLELAARYENGQGLTPPEFAVLLAYVKISLEREVLTDELVDEAWTTDVLSGYFPTPLRERFAGRMAGHRLRREIISTALVNEVVNRGGTSFVYRAMEESGASAADVIRAYVVVRDVFGLEEIWAAGEALDNRVPTSAQTLVFLETRRLLDRAVRWLVSTRRSPLDVPGEIAKLRPGISALLPLLPEVIVGAERRALFDRIAELVAKDVPEDLAAAVSRVFYGFGLLDVLETAAAIDRDAEEVAQVYFVLSERFGVDALLSHISRLPRGDRWQTLARMALRYDLYAALAALTAEVLHSTPSSAPPEDRVSEWEQVNAASIARASNAMGDVDDSPADLAALSVLLRQIRTLVKTSSAG
->UniRef90_A0A2E6Q8T7 Oxidoreductase n=1 Tax=Rhodospirillaceae bacterium TaxID=1898112 RepID=A0A2E6Q8T7_9PROT
-MSVPLFTPIELGNVTLANRIVVSPMCQYSAVEGSATDWHLMHLGNYALSGAGLLIHEATAVVAEGRISHSCLGLYSDKNESALARVLEFCRGISDIPLGIQLAHAGRKGSCERPWEGRGPLSGENAWQTDAPSALAMADNWPTPNAVSIEEMKAIKAAFVTATERAIALDYDLIELHCAHGYLLHEFLSPLANAREDDYGGNLANRMRYPLEVFEAVRAAWPEGKPLGVRISATDFAEGGWEIADSVVLSDALKGLGCDYVTCSGGGVTFDQTIELEPGYQMPGAEAVKRETGMPVMAVGMIRDPKFANTAIADGKTDMVALARGFLYEPRWPWRAAYELGVDAAYPPQFERAAPSAWPEAFPDQSD
->UniRef90_A0A5F7ZVD1 Secreted protein n=1 Tax=Macaca mulatta TaxID=9544 RepID=A0A5F7ZVD1_MACMU
-LPEAASLQSSHFYSVPCHNPTVHALCPNIHFLFFLFLLRLSFALVAQAGVQWHDLGSPQPPPPGFKRFSCLSRLSSWNYRHAPLHTPNFVFLVETGGFSMLVRLSRNSHVRRVGRSLFTDEEGNCSSESMTVWLR
->UniRef90_A0A5B9Q9U5 Glyco_hyd_65N_2 domain-containing protein n=1 Tax=Bythopirellula goksoeyrii TaxID=1400387 RepID=A0A5B9Q9U5_9BACT
-MKIHLWEIVLFLLAISVANSVARESESELVWFDRPATHFTESSPLGNGRLGAMIYGGTIDETVVLNESGMWSGSTQEADRLGAAEFLPEIRRLLFLGKNVAAEKLMNEEFTCTGQGSGHGSAAELPYGSYQTLCKLQIKFLQNETAPSVQNYRRELDLHDAVVRIEYSRNGVDYLREAFVSFPDQVFLYRFTANKKNSLSFDVSLSRSERSNTKNVGKDELQIEGQLDDGKEGETGVGFCSRVRVLHDGGMVTTQDGTLKVRSANSVVLLVSAATDLEALVSQVDEDIYKATEVVLDRAAAKPFADLLKDHISDYQNYYNRVGLRLAPTRIDSRSKLPTEERLHANWRDTQDNSLAALYFNFGRYLLISSSRPGGRPANLQGIWASEIQTPWNGDWHANINVQMNYWPAEVCNLAELHEPLFRLIESLVEPGSQTAQIYYNARGWVSHVLANPWGFTSPAERVSWGSTNTCSAWLCQHLWEHYLFTQDREFLLSVYPIMKEAAQFYLDTLVEHPTQEWFVTAPSTSPENRFLLPNGEEASICIGATMDMQILRSFLYACREAANELDCDEVFRTQLSDVIGRLAPTRIASDGRIMEWDQEYPEKDPEHRHVSHLWGLYPGDEISNSQTPELAAAARKSLNVRGDSGTGWGLANKIAMWARLHDGDRAHRLLQQHLHPVTHGQRKQQWSGGTYPNLFDAHPPFQIDGNFGATAAIAEMLVQSSISDIDNIKHVNIELLPALPTAWPEGEVRGLCTRGGFEIALNWKDGKLGDVEIHSRHGLPLQLRYKSQEVTLTPARGEKVHFDGDLKLLSTPKSAVVPPSGSNK
->UniRef90_A0A417XX54 SCP_3 domain-containing protein n=1 Tax=Nocardioides immobilis TaxID=2049295 RepID=A0A417XX54_9ACTN
-MPSRLRPADPVDVSRALAGVSGGTADRAELRLLTKHFLALLEERAPGRSVEVRVPPFAAVQVIEGVRHTRGTPPAVIETDAETWVALATGELAWADALASGRAQASGERTDLSPYLPLG
->UniRef90_A0A512JR32 Fusaric acid transporter n=1 Tax=Methylobacterium gnaphalii TaxID=1010610 RepID=A0A512JR32_9HYPH
-MTLPGWRDWVFAIKTFGAAILAMYLAMWIDLPRPYWALGTVFITSQVLAGATRSKAIYRVCGTLLGAVVSVILVPNLANAPELLTIAIALWVAVCLYFSLLDRTPRSYLMMLGGYTAALIGFPAVGDPGTMFDTAVARAEEITLGILCASLANTVVLPQSVAPLIAGRLDHWLTDARGWIVSVLSHTSNAGDTQSKRLKLASDAIAFDALATPLRYDMSGAERSAEAMATLRQHMLMFLPIVSALSDRIEVMRRAGTMPSRLETLLDDVAAWLAAGRIDEIEAQGLRSRADALCPPMSQQASWTDLVLASLLARLNNFIDLRQDARLLQRHILDGTLTTERLAFSYTAAARTIRHRDHGMALLSAIGVFLSVLLSCTIWIATGWPDGAGAPMMAAVGCCFFAAQDDPAPSIVGFANSAIIGGIASAIYLFAVLPLATNFEMLTLALAPALLTCGVFMTQPKTAPIAMGAAVNGSAMIALQGSYTGDFAAFANSSIAVIAGMWVAALVTRLVRSVGAGWAAHRLRSVNRRSLAQAAERQGAQNGLELAAIMLDRVGLIAPRLTSLPPGDAEWTADLLAEVRVGINVVELRRNRRALSNEARKAVEALLAALARHFHAKALIPPTGLLADIDAALDAVIADRLHAARGVALMGLVGVRRALFPEAPDYKARRTATSEPGWAA
->UniRef90_A0A3D3L9U4 Heat-shock protein Hsp20 n=2 Tax=Verrucomicrobiales bacterium TaxID=2026801 RepID=A0A3D3L9U4_9BACT
-MKITRFNPSLNLGRVADFDQWLRNPFAAFPLMGQLLGDFAPAFTSGRPATDVHEDKDNYYACFELPGVKKEDLKVEIHDRLLNVSAERKEKNGEQESSLTLCRSISVPEGVNAEGISARLEDGILVVTLPKQEHRKPKLIEIA
->UniRef90_M4NI99 Dipeptidyl aminopeptidase/acylaminoacyl peptidase n=11 Tax=Rhodanobacteraceae TaxID=1775411 RepID=M4NI99_9GAMM
-MSSKTGSSRVLGALVMGALSAGVAAQARTLSADDYARAERFMSYNTVPLVDHAVPKVEWLDDGHFWYVDHDAAGDHFVRMDAASGKTAPLFDQAKLAVALGKAGGKPVDAKKLPVTGYEARPDGRVDIAVRGKHYVCDLAAVEASCVDRTALVKTGKEPGALSPDKQSEAFIRDWNLWLRDVASGKETQLTTDGVENFGYATDNAGWKHTDNAIVEWSPDSKRIATFQQDQRKTGEMYLVSTNLGHPKLEQWKYPLVGDKDVTMIERVIVDVAAKKVLRLQMPPDQHRSTLCDDVSCGPDGGWDDVKWAADGKTLAFVSTSRDHRHEWFRIADANTGKVRTVFEEVVPTYYESGNGAVNWRYLPETNEAIWFSERNNWGNLYLYDLTSGKLKRAITKGEGNVTELLKVDPKTRTVWFRGVGRTAGVNPYYQQFFKVSLDGGKPVLLTPEAADHTVTLSPDGRAFVDAYSTPTTPPVIVLRASDDGRKVASVATADIARLKAAGWVPPIPFTVKGRDGKTDLYGMMFKPTHFDPSKKYPIIDYIYPGPQTGSVRGRSFSAARADHQAMAELGFIVVAIDGMGTPWRSKAFHDAYFEHVEDNTLPDQVAGLKELGKQYPWIDLDRVGIWGHSGGGNATAAAMFHYPDFFKVGWAESGNHDNRNYEDDWAEKWQGLLVTNKDGKTNYDAQANQSFAKNLKGRLMLVHGTMDDNVPPYQTLLVADALIKANKDFDLLLIPNVHHGYAEATPYATRRRWDYFVQYLAGNTPPHEYQLKAWPWR
->UniRef90_A0A1B7P3P8 UDP-N-acetylglucosamine transferase subunit ALG13 (Fragment) n=1 Tax=Emergomyces africanus TaxID=1955775 RepID=A0A1B7P3P8_9EURO
-MDSSKRARKLCFVTVGATAPFNALVLEVLGEPFLEALRINNYTDLRIQHGQMGESTFQEFKLQNGTMAKEKYGLDITGFDFNLAGLKNEMLDVKADVDANKAEGFIVSHAGSGTILEVLRLGIPLMVVPNPQLLHNHQDELAKQLAVSGYVIHGKL
->UniRef90_A0A2T5J629 Type I site-specific deoxyribonuclease n=1 Tax=Mucilaginibacter yixingensis TaxID=1295612 RepID=A0A2T5J629_9SPHI
-MNEHEFQTYVAQIIGQLFPTLQEGQIEQEHAFSLKFGHHAVVIDGKEPGKYAKSAIYDILLKFQGKPFALLELKKPGNGIEPEDIRQGVSYARLTQPICPLTILTDGTTTQLINTFDGEPFKEEAMDIQFIENLFRQGLLLSANSLKNAISTLLEADHRVIFDVINTISHNAFEQLRGDPEDISKPIMRDFKVARSAERKIWDQLEKTPGVFLTGEPFVGKTNLLYQLFETAKNAGQALLYINAADQNYNIFRRLSNFITMRMRYPVTEERVKEWLLLSSNRSPQDRLVVVYDHFRHDTDEHLKADIAELFDVFEADNNRVILATDNANYDLLTTTAGRTTTNFYRERFARIRLKTFSSKEFELANQLLYDRYGGMVLPGGIFAGEYRNPRVWRLIAKAIRAERTQATALGIIEAVPSFQFLQLISNHWHFDAQTRQDFKALSVAFMESMPLRNEQGDLKLMALNLPVIAEQELKKHLENEVIERLKLAGLLERRLLPDDRWVFLPKLPELIAKNAGEHLKARFQPLLLADFHQHYPEFLEAYQYLPFGEIIAAQTIVHWGYQQELDLFSAFIRKLQSDKPEIETATGGGLVRLYLPEKGHITLPIEPGEEQKYIGNLFPYLILSHLVTLQFVDDSQHPDMERARCIAAVGQTNFQVRSLNVNTFYEPMPTNHEVGNIGNITHSGIGIVEPIVQAMQANIIQSPQVIDILFRHALEKKYYRLLHRIYIAARYSDGLGSPESDALCESIQARYMDHFNKMMAFAIADKGATRSERRKIEKGLRKRDRKQKK
->UniRef90_A0A841IL00 Beta-N-acetylhexosaminidase n=1 Tax=Nocardiopsis algeriensis TaxID=1478215 RepID=A0A841IL00_9ACTN
-MRLPAPYALACVGLALSTAACTLLGEVNPSEEDGGSPTEESFEPVLAPRLLEEMDLGDKIGQLMVLTAQGTTAAENAALIETYRPGGLIYFDANLTGAEQIASLSAGVQEIAAEQGAGVPLFLGIDQEQGLVARLPVGTSFPDAMAVGATGDTGQAVLRATTTAAELNALGINLNYAPVADVNTDPDNPVIGIRSFGSDPALVSEMAVAEAGAYAEAGIVPVVKHFPGHGDTDVDSHTGLPVIDMPRDEWEAEHLPPFRAAVDAGVDAVMTAHVIMPQLDAGTDPATLSPAIIDGILRGELGYDGVVTTDALNMEGVRQDHTDGEIAVRALEAGVDQLLMLPDPAAAVAAITEAVEQDRLTEERIDESVLRVLVLKERRGVLEADPVDPAAAEAALSDPAHAEAAQTVADASATLVRNESGLLPLAAGARVRVEGTGADRLAGALAEAGLEVVTEGADAVVVGTNGARGSAEQSAPVEAARAQGLPVVVVAQGGPYDLEAFPGVEGFIAVYSSVDVSLAAAAGVVAGEVEPTGTLPVDIPGADVAAGTGLGF
->UniRef90_A0A5C6Q7Q0 OmpA family protein n=1 Tax=Colwellia sp. C1TZA3 TaxID=2508879 RepID=A0A5C6Q7Q0_9GAMM
-MNYIMTILLTLAISGCSIQIQEMTPEPTVQKADLADIEADGIINARDQCQDSFVGASVANNGCGSDRIEELKHKLQVNFIPNSYTVEWRFLSEIKKLAEFMKDNPRAKLTIEGHTSKRGTKVLNQILSQNRAQAIQNILVNKFMVEQARITAIGYGFDRLLLAGDDEYIHARNRRIVAKLSREKLLTDMKWTIYSVDQAEE
->UniRef90_M3I5W0 Oxidoreductase, short chain dehydrogenase/reductase family protein n=2 Tax=Leptospira interrogans TaxID=173 RepID=M3I5W0_LEPIR
-MASFNSSGKMNAFVIKHDVTNFDQVETVFQKAIKSMKGLDEIYYASGVMHNIKPDEFDVEKDISMLNTNLLGCVAWLNPAANLFQKQKSGKIIGISSIAGDRGRRGNPVYNTSKAGMNTYLEALRNRLSVLGVQVLTVKPGFIDTAMTKGMKGLFWLISAKEAAEIILKAADSGKENIYVPARWGLVGLIIRCIPSFIFRRLSI
->UniRef90_A0A3E0HEB5 Serine/threonine protein phosphatase PrpC n=1 Tax=Kutzneria buriramensis TaxID=1045776 RepID=A0A3E0HEB5_9PSEU
-MSTAHDLTYGRRAAVATRRGVRDHNMDAPALFQASTGVVVAAVVDGIGNDPDGAATMHLIAETAVRIGATKGALAGVLAGAALVEDPGVENHMPDGVIVLALAVPGRPTHLAWVGDSHAYSWDGDTLSRRTDPHTMGAYLRGNGAVDLAPLHDSWVRVTLTSATVTNVAVSSIPANELVVLVSDGLDTLPHDELEALVREHQDNPDTLADAIVAAARETEDGYRDDATAIVLTTAG
->UniRef90_A0A6A5YPJ8 TauD domain-containing protein n=1 Tax=Lophiotrema nucula TaxID=690887 RepID=A0A6A5YPJ8_9PLEO
-MAPIALPIVESIKETDTVQPKKDSLALPEPARKRLEDAGIDLSSGYPYRPAKPLYLDDVYNIRNEEREFVDAGSRADPEKKALLSAAKEVIHLTGHIGTEIVGLQLKDLTDQQKDELALLIAERSVVFFRDQDITPQQQKALGEYYGEIEIHVRIQPQVPSVPGVPGTTVIWPALQATEFAASFRQTGGASRWHTDLVHERQPAGITHLHNDTIPSLGGDTLWASGYSAYEKLSPDFRKIIDGKEAVYRSAHPYLDRKNPTAGPKFIERTHPLVRVHPATGWKALWVNRAMTVRIVGLDKAESDLILGYLYDVYERNVDIQVRFKWTQGTSALWDNRITIHNASWDYEGKEPRHGTRVTSLAEKPYFKADAPTRRQALGLAGPGDI
->UniRef90_A0A285NT28 Acetoin utilization deacetylase AcuC n=1 Tax=Natronoarchaeum philippinense TaxID=558529 RepID=A0A285NT28_NATPI
-MRFGYSETCLDHDTGDRHPETPDRLRAIKEGLKRKHGVEYVEADSADVETVAAIHDREYVEEVREFCADGGGNWDPDTVAVEGTWDAVLQSAGLSAWAAERAMDGDSGRETPFALGRPPGHHAVVDDAMGFCFVNNVAVAAQHALDDTAAESVAIVDWDVHHGNGTQDIFYERDDVLFCSTHEEGIYPGTGGSGETGTGDGEGTTLNLPMPAGAGDADFAAAFERVVEPAVESFDPDLLLVSAGFDAHRHDPISRLRVSTDGYGVLTGRLRDLADETDTALGFVLEGGYGLDVLAEGVAMVHEVFDGLDPVQPDDDVDDDVEELLTGLRSRHPLLVGN
->UniRef90_A0A1A8J6Y5 Ectonucleoside triphosphate diphosphohydrolase 5b (Fragment) n=1 Tax=Nothobranchius kuhntae TaxID=321403 RepID=A0A1A8J6Y5_NOTKU
-MKPTVLLLLLVLLAVSGPSRAQVRSSHLDLPRILPSLSRPANHSRIFYAVMFDAGSTGTRIHVYTFIQNGSEKLPVLDNEMFHSTKPGLSAYADSPETAGETVRRLLKVAKKAVPRLDWKRTPLVLMATAGLRLLPVEKAQALLDQVKGFTRHCRDPRWGCFYK
->UniRef90_UPI000DD31245 peptidylprolyl isomerase n=1 Tax=Paraliobacillus TaxID=200903 RepID=UPI000DD31245
-MKKLAIAATIAAGMITLSACSSDDSETVVETASGNITQEAFYEELKELSGSTVLEQMVTQTILEDNYEVDEDQLDEQLQVYKDQYGDQWETILTSSGYADEEAFREDLKLQLLQQEALIEDIEVTDEEIEQRYERMQTEIEASHILVADEETAIDIKAQLDDGADFATLAEENSTDTASAAEGGSLGYFTAGDMVAEFEEAAYSMEVDAISDPVETTNGWHIIQVTDKRDAEEAPEPLEDIRDDIRDEIALTKVDDTAAQEKLDQLMEDADIDVKIEEFEDLFTAEEETATE
->UniRef90_A0A6P0X9G7 AI-2E family transporter n=1 Tax=Okeania sp. SIO2D1 TaxID=2607792 RepID=A0A6P0X9G7_9CYAN
-MQQILNQLKKWGEKYLHFDLISLFLIGYATAIILSIDNYIIRILTFFPLLLLLLVDLVILLFAPEKLREIYSKTTLFICTLTAALLLVWII
->UniRef90_UPI001B3ACF38 ribonuclease P protein subunit p14 isoform X1 n=1 Tax=Toxotes jaculatrix TaxID=941984 RepID=UPI001B3ACF38
-MSFIWRSVFNKPRLCLSSIAAALPPCRLLHVGQRASLTKAFSSHDVELFAKLTGDNNPLHLDPVYASSTSFEAPIVHGVLINGLISAVLGTKMPGPGCVFLHQEIRFPGPLYVGEEVLAEAEVLKIKMSFALITVKCSVKDKVVMEGEVMVMMPEDQQKRG
->UniRef90_A0A1M7FK69 Uncharacterized protein n=2 Tax=Flavobacterium TaxID=237 RepID=A0A1M7FK69_9FLAO
-MNTYADNNKENKKQQTPSAIHKKDNRDTALPVTDSHLSSVAAQLQLQEIANNSPQVKQAFQLQAIANAHAALPIQKKDLITTQSVFQLQKLERGKLNVVGEHHSESNQRRGQEIDIAEREVGGEYWTENNFRIRETKSPGENAVRDTTGDPRILGDALYLRIVESIQYVYEAKNNFEKEWKHWTTQNLNKEELPILKGELQPLLVICKNHTLEANKLAKAYMYNEEFKTLPEFVSDQIVQMYKLLPETEKLFLILVETWKSYTLEQLILKKFLSSFNVFGSNIDILNIYAAQIGGASRTDTSKLRSYEMDNAADFAHDRIGVWKIGFDHVKDIKEDMQHNDTKNYILINREEFNHEYKELPILVEDQMVKQK
->UniRef90_UPI001FB4782B PTS system mannose/fructose/sorbose family transporter subunit IID n=1 Tax=Coprobacillus cateniformis TaxID=100884 RepID=UPI001FB4782B
-MGALIPSVVNAKFAYTFTQGEVSIAVQELADKIMPSLAPCLVVLLTYWLLGRKKMNSTRVTLLLVVLGILAFNLMIFA
->UniRef90_A0A2T6FJL9 tRNA (guanine-N(7)-)-methyltransferase n=4 Tax=Cellvibrio TaxID=10 RepID=A0A2T6FJL9_9GAMM
-MKPEFKPKSIRSFVIRAGRITVGQKNAFDKYWPGMGLSLFNGAINPDVVFGRQAPLVIEIGFGMGDSLLEMAANEPDKNFIGIEVHPPGVGRLISTASQQGLSNLRVYMADAMDVLEDCIPDGSIDRLQLYFPDPWHKKKHHKRRIVQPAFIQKLRPKLKMDGVLHMATDWQPYAEHMLEVMNSATGFATDFTETGFAPRPDYRPVTKFEKRGERLGHGVWDLLFKKTA
->UniRef90_UPI0012F6EEC0 DUF927 domain-containing protein n=1 Tax=Methylobacterium sp. WSM2598 TaxID=398261 RepID=UPI0012F6EEC0
-MSEALFATEMQRLDEAGVEEPSEVRANQERHGGIRWPKGFRMRADGLWYEPEGDEEAMRVSGPFRVPGLARDPAGSGWAVTIEWKDRDDRPHRGFVSYADLVGDGVDWLRPLAAAGLPVTIGTKALRLLKRALYELECTARVRLIRRSGWYRGAFVLPERTIGSAPGEEAVFEGRLDAARYASAGTLEQWVDAVAAPAAGNSRLLLALAVAFAGPVADLLEDEGGGVNLKGASSVGKSTLLVAAGSVWGGGARAGFTQTWRATGNGLEGVAKAHSGTVLILDELGELEAREAGSTAYLLVNGLGKARATRDAELRARHEWRVMLLSAGEVGLADKITEGGKRARAGQLVRLVDVTADAGRGLGIFDDTKGMEPAPFSNMIKSAALKVYGTAGVGFVSGLANDPDRYAAAARRRIAEVSRNLLVGLPEADGQATRAAHRFALIAVAGEMARAVLNLPWAEGEVDGAIKTCFDAWRATRGGDGPGELVAALEAIRSAIERHGEARFRNLDQHDGGAAPIRELLGYRQSRDGDVIYAFTATGWAETLAGTADPKSIVKMLFERGVLFAGRDRTHRHFVKFHGQPIGTYAVRASAVLDTEAA
->UniRef90_A0A7Y9LCB2 DUF2264 domain-containing protein n=2 Tax=Microlunatus parietis TaxID=682979 RepID=A0A7Y9LCB2_9ACTN
-MSKPGESWTRDDLVQFTDRSLLALRRWATPGRARFDLPGPRVGSGPERDGLEAFARSFLAVGFRLSAAEIDSHDHAGWYAAGLAAGTDPESPEFWPSLRELPQARVEAAAIAIALHESRRWIWDALTPAVKQRVIDWLSGSVGIAYPDNNWRWFQNVTQAFLRSVGGPYDQAELDENLTFLDDCYLGDGWYSDGRPDRRTGNVDWYVGWVMHLFSLWYCRMSEGEPGIAELQARYAERLRPYLTDAADLFGADGAPLHQGRSLVYRHAVVGALWTGAVFDANPLPLGRLRRTALGAIRFFAERGAFDEDGLLSLGWLGRFEPMRQPYSGPGSPYWASLGLAGLVLPESHPVWAEPEQPTPIETGDVVRPIRPIGWLVSGTADDGIVRVINHGVDHSTATPAPENPYYNRYGYSSVTGPVPAPAGTADGAVDQQVALIDPDGRWSQRPMIERVAVDDHRASSRQRARFARTEPEQGFDDGPELTCVSLVRGSVEVRAVRFDDHDQASAALVISGYAVPRKPAEGARTGLHSAVTALTEGGSSGSSVHPVANAFGADLEVPWCRFEHPEPGRWYVIALCLGEREPAWPTLADTPSGPVITWPDGTTDPL
->UniRef90_A0A0S6VXT7 FGE-sulfatase domain-containing protein n=1 Tax=Candidatus Moduliflexus flocculans TaxID=1499966 RepID=A0A0S6VXT7_9BACT
-MSNTTQTRIREKIIMIGISLFILISLGITWFVLYAIIAIKRQNAHRSAILEGLGFSPVANPPAAFVEYITTLHHHVKTSKPRLKLDHVFQQRIGNADVYLFELIDNGSEHSKHYEVVAYVSPSLRLPRFLLNPVLPTKEAKPDENSAIFKVLNSMFRYNHKVEFPDVPEFEERYTLSITDEQDDSEIQNTFTPPVTAGLLNSPSQYSMLGWGDTITERSRLKITTKTTIEEAKAMLEDILSLFLLFENQGASSTVNVRALDSSLSRNLAGKNEIPAALKTFEKSVKIIAALFAISFLLTGASFIFKAVSFQKEQAASQEEAVHEMPAPPIATPTPAPELPPKLPELTGFACAETNGHLECVEPLTGMILVNIPVAQSDMCGAKTEYWLGKYEVTQEEWEKLMGTNPSFFNRSKLGDGYKRHPVEQVSWDDAQAFLQVLNSRYKDKGVKFDVPSTAQYQRGCQAGMNAEWPYGTRDATQLDAYAYHNGNALGSSHIVGEKAGNAFGLYDIIGNIYEWSRDTNFTLKMTDGNAEFIPDKDGRKDLLGGSWKTDPDSQRCTMIPAELPAARRNDVGFRVAVEPVAP
->UniRef90_A0A7Y4V1B9 Transposase n=4 Tax=Mycobacteriaceae TaxID=1762 RepID=A0A7Y4V1B9_MYCFO
-MQRPIEPAQYLSLAYTDRLIELGIAPSVGSRGDSYDNALAEAVNAAYKTELINRGKPWRGVDDVELATAEWMAWYNQERLHEALGYVPPAEYEAALKGASHPASQPTPALVPN
->UniRef90_UPI001490A0B5 MlaD family protein n=1 Tax=Muricauda amphidinii TaxID=2735167 RepID=UPI001490A0B5
-MKLTREVKTGIIVLAGIVALIFGLNYLKSSPFFENNKTFYAVYSHVGGLQPGTQVSINGLNVGNVQSIRFLDSSGKLVVTFTVGKDFDFSKNSVAELYDTGIIGGKGIQINPVFDKAPNAQSGDTLTSNIKPGITELVQQKLTPLQMKVEGAVSHADTLLMNVNEILDEPTKRDLKLAIGTLNEVVTSFKGSADKLNLLLENNKEQLDSSLKNVDNITSNFSKLSDSLANAGLAQTVSDFQTTVESLNTILSKIEKGEGTLGKLTHDEELYNNLSEVSRELDLLLQDFRLNPKRYVNVSVFGKKQKDYELPENDPAQKQD
->UniRef90_UPI001BCFD6CE universal stress protein n=2 Tax=Roseibium polysiphoniae TaxID=2571221 RepID=UPI001BCFD6CE
-MSFKTILAVAEFTEDVKSRLKSAVDLARTQDAHLAVLLVGEVPSLPFYGYGGAGYTKVWMEEGEERAAALKAVQEDVEAALAKEGISFDVRAHQAIVAREDNLVARHAIYSDLALILRSGDGELNTVERQAIDGALFDSGRPLLFLPKPDVPQTVGQNILVAWNSRAEAAEALSDAMPFLVGAGKVTLLLVDPVSGPDDHGESPGADMALVLARHDVEVEVRQVSSNGSSIAEVLNREAKTLGADLIVMGAYGHSRMRQTILGGTTREMLEETACPLFLAH
->UniRef90_A0A6B0S860 PAN2-PAN3 deadenylation complex catalytic subunit PAN2 n=2 Tax=Bovinae TaxID=27592 RepID=A0A6B0S860_9CETA
-MNFEGLDPGLAEYAPAMHSALDPVLDAHLNPSLLQNVELDPEGVALEALPVQESVHIMEGVYSELHSVVAEVGVPVSVSHFDLHEEMLWVGSHGGHATSFFGPTLERYSSFQVNGSDDIRQIQSLENGILFLTKNNLKYMARGGLIIFDYLLDESEDMHSLLLTDSSTLLIGGLQNHILEIDLNTVQETQKYTVETPGVTIMRQTNRFFFCGHTSGKVSLRDLRTFKVEHEFDAFSGSLSDFDVHGNLLATCGFSSRLTGLACDRFLKVYDLRMMRAITPLQVHVDPAFLRFIPTYTSRLAIISQSGQCQFCEPTGLANPADIFHVNPVGPLLMTFDVSASKQALAFGDSEGCVHLWTDSPEPSFNPYSRETEFALPCLVDSLPPLDWSQDLLPLSLIPVPLTTDTLLSDWPAANSAPAPRLRAPPVDAEILRTMKKVGFIGYAPNPRTRLRNQIPYRLKESDSEFDSFSQVTESPIGREEEPHLHMVSKKYRKVTIKYSKLGLEDFDFKHYNKTLFAGLEPHIPNAYCNCMIQVLYFLEPVRCLIQNHLCQKEFCLACELGFLFHMLDLSRGDPCQGSNFLRAFRTIPEASALGLILADSDEASGKGNLARLIQRWNRFILTQLHQDLQELEVPQAYRGAGGSSFCSSGDSVIGQLFSCEMENCSLCRCGSETVRASSTLLFTLSYPEGSNSDKTGKNCDFAQVLKRSICLEQNTQAWCDNCEKYQPTIQTRNIRHLPDILVINCEVNSLKEADFWRMQAEVAFKMAIKKHSGEISKNKEFALADWKELGSPEGILMCPSIEELKNVWLPFSIQMKMTKNKGLDVCNWTDGDEMQWGPARAEEEHGVYVYDLMATVVHILDSRTGGSLVAHIKVGETYHQRKEGVTHQQWYLFNDFLIEPIDKHEAVQFDMNWKVPAILYYIKRNLNSKYNLNIKNPIEASVLLAEASLARKQRKTHTTFIPLMLNEMPQVGDLVGLDAEFVTLNEEEAELRSDGTKSTIKPSQMSVARITCVRGQGPNEGIPFIDDYISTQEQVVDYLTQYSGIKPGDLDAKISSKHLTTLKSTYLKLRFLIDIGVKFVGHGLQKDFRVINLMVPKDQVLDTVYLFHMPRKRMISLRFLAWYFLDLKIQGETHDSIEDARTALQLYRKYLELSKNGTEPESFHKVLKSLYEKGRKMDWKVPEPEGQTSPKTCRALVDELEWEIAQVDPKKTIQMGSFRINPDGSQSVVEVPYARSEAHLTELLEEVCDRMKEYGEQIDPSTHRKNYVRVVGRNGKSSELDLQGIRIDSDISGTLKFACESIVEEYEDELIEFFSREADNVKDKLCSKRTDPRVRPPWLYSLRPPGYSELRRTPARLKGALRLAGRLLRLELPGLCAFRPTAGENLKDILADLIPKEQTRVKAFRQQHGKTVVGQITVDMMYGGMRGMKGLVYETSVLDPDEGIRFRGYSIPECQKLLPKAKGGEEPLPEGLFWLLVTGQIPTEEQVSWLSQEWAKRAALPSHVVTMLDNFPTNLHPMSQLSAAVTALNSESTFARAYSEGINRTKYWELIYEDSMDLIAKLPCVAAKIYRNLYREGSSIGAIDPKLDWSHNFTNMLGYTDAQFTELMRLYLTIHSDHEGGNVSAHTSHLVGSALSDPYLSFAAAMNGLAGPLHGLANQEVLVWLTQLQKEVGKDVSDEKLRDYIWNTLNSGRVVPGYGHAVLRKTDPRYTCQREFALKHLPQDPMFKLVAQLYKIVPNILLEQGKAKNPWPNVDAHSGVLLQYYGMTEMNYYTVLFGVSRALGVLAQLIWSRALGFPLERPKSMSTDGLMKFVDSKSG
->UniRef90_A0A8C0HHE9 G protein-coupled receptor 158 n=1 Tax=Buteo japonicus TaxID=224669 RepID=A0A8C0HHE9_9AVES
-MPHKRKLPIPTQTSRPPPNASLLPPGTARPLRRANCSGRYELASLAGKSRFTSHPTLHGALDTLTHATNFLNMILQSNKSREQNLQEDLEWYRALIRSLLEGDPNISRAAITFSTEPFSSTPQVFLQASRHESQVLLQDLSSSAHRLANASVETEWFHSLKRKWRPHLHRKVLNTGPKTLENSWKRRESFTADKNHIRWSSPYLECENGNYKPGWLVTLSAAFYGLRANLLPEFRGVVKVDINLQKVDIDQCSSEGWFSGTHRCHLNNSECMPIKGLGFVLGAYKCICKAGFYHPNIFSVDSFQRKDAENRFSGGELSEEVYTCLPCREGCSYCTDDTPCYAQEDKYLRLAIISFQTLCMLLDFISMLVVYHFRKAKSIRASGLVLLETILFGSLLLYFPVVILYFEPSVFRCVLLRWVRLLGFATVYGTVTLKLHRVLKVFLSRTAQRIPYMTGGRVMRMLAVILLIVFWFLVGWTSAITQNLERNIPLIGQGQTSDHLIFNMCLIDRWDYMMAVAEFLFLLWGVYLCYAVRTVPSAFHEPRYMAVAVHNELIISAIFHTIRQVIYSKVSLMPFLEQWVMHSSGCLLDQTCSVHTSFAIHFALQDELKKLYAQLEIYKRKKMIANNPHLQKKRCSKKGLGRSIMRRITEIPETVTRQCSRDEKDLMEHSAVKNMATLRKNPQDSTSSAKPKEETLKNRVFSLKKSHSTYDHVRDQTEEPNSLTTESTEVIATENSLLDSLNGNKLTKNAPEKVEAVSTESVPLVCKSVSAHNLSADKKPLHPRTSVLQKSLSVIASAKEKTLGLTGKTQSLEESTKSHKSQQKGKEASKKHSASDKGEHKDSHRKNSTHSEETKKTHKSGIMKQQRVSQTPANPDTGPGKSLHKDNFNIGEVCPWEIYNQTPGPVPSDSKVQKHVSIASSEPEKNHPSQPKVKTHHKLKTPEGYQQSNQKSPEKVEAPTRETQEQQVFENEKKQSNSKSQVSPGLKCENVNRYTPNTCAGEREELPQKAPEKENLNKLAEQKKNASCEGNVLSSDSHKPSSYLQQPLASRAEVCPWEYDTPDLPNAERSVALSNTSAISANKTATPRK
->UniRef90_A0A2T6DUT4 Endoribonuclease L-PSP n=1 Tax=Opitutaceae bacterium EW11 TaxID=2161865 RepID=A0A2T6DUT4_9BACT
-MDLTTPSPQPFLRSAQSLAEDLESEIYATPESEARSSWTHRGCRVEVRASERDSFAEFHVTGLVECAGSAAELAEIVLEEVASVLASRRIQPIQEKLYGLTAIRGEVMKRRETAYRRRRLDPSVPTTWIQGLPLLGCDFVGIQIWGVAPYGGETCVTTVENPSTGAGRLWKGRGFRMLHLPCVRGIQHDGKLAAGPASQADWMFTNAEQGLAAHGFSYSQVVRTWIYVDRLLDWYGDLNCVRTAHYRRLGFGTTGGPAFPASTGIQGRFEEEECLVDVLALETDGRHATAAPVTRSPRQDQSFNYGSAFSRGMTLDVEGRRTIHISGTASINTAGDSTHLGDAEMQSLETLMSIAAILQEQGGTLENITSATLFCKTREAWEAWRRVSQLLRLPAFPKVCVLADVCRDNLLVEMEAVAVI
->UniRef90_A0A8S9K9L2 Transcription termination factor MTEF18, mitochondrial n=1 Tax=Brassica cretica TaxID=69181 RepID=A0A8S9K9L2_BRACR
-LEAACALSGFGFPWNKLGRLYREERSVFLQSGDEIGSLLGRLSGVGFSTVAVAGVCLAFPSVLRGGVEIGCLFVKVKRLFEEFGSEDVVEENVESWYAFGRKIRVFYDLGFESEEMWELMGRNRSLFIECSEEALMRKTDYFCRFGVGKEEAALLILRNPDVMSFDLEKPVISVKGVLKHFGLSEDEVDALSLKHPHVFGRNRMKNLPHVVRALGLHERIFDKLKNGTYHLLSSYSLMKPDEDIDREYQRGLEEIQNLRCKTHSFQKLDFLHQIGFAENGLTMKTLQHVHGTAVEIQERFQVLLDSGIDFSKACMLIRSSPKSLNQKPHSIQEKIRFLCEEMGDSLEYLEVYPAYLCFDLENRISPRFRFHKWLVEKGLSEKNYSIASIVATSEKAFIARLYGIHPAIPKHYFERFSYRKDRTTVS
->UniRef90_UPI000836FEF3 nuclear transport factor 2 family protein n=1 Tax=Rhodococcus phenolicus TaxID=263849 RepID=UPI000836FEF3
-MTTTPAESTGEAGIAERITRLEDLEAIRLLDARYCRHLDDGNWDALMDLFTEDGEFDGLSHPRGRTEMRAFFAGLAEDGLTAFWHFITNLEIDLDGDRATVRSFLWQPCVTDGVAGIAAGRYTDQVVKIDGRWLYKVKQVRFHFFGPLESGWDENLFALDSARRAAVRA
->UniRef90_A0A523XA31 Phosphomannomutase/phosphoglucomutase n=1 Tax=Candidatus Cloacimonetes bacterium TaxID=2030808 RepID=A0A523XA31_9BACT
-MNKEIFRTYDIRGKADIDLTNEVVEILGKSYSIFLPSNAKRIGIGRDIRLSSERIKNNFVKGLLSTGIDVVDFGVIPTPLLYFTVHTHALDGGVEITGSHNPKEYNGLKMLVGKNTIYGDEIQEIRRIADKGVFRKGIGSYEEKETVNEYINDILDRISLGKRKLKIIFDTGNGTTGPVVKRLYSKLPFEFEILFEEPDGSFPNHLPDPTIPEYLNDLIQRVKESKADLGIAFDGDGDRIGAIDEKGRIIWGDKLLAIYSKEVLRKRQGAKIIFEVKCSNGLIEYIKEKGGVPLMWKTGHSLIKAKMKEEDAPLAGEMSGHMFFGDNYYGFDDAIFASLRLIELLSRTQNPLSLLADEVPSYFVTPEIRVDCPDSEKFKVVEDVKKTFEKEYNIIDIDGVRVVFPDGWGLLRASNTQPILVLRFEAKTEEALSRIKKSFTQILEKFPFIKI
->UniRef90_UPI00048A2204 TolC family protein n=1 Tax=Anaerovibrio lipolyticus TaxID=82374 RepID=UPI00048A2204
-MRNNRFKTLTALVISGVMTMSMAGTAMAETMDVDIEDCVNMAMANNHTVKSAIDDYDSAVWARHEARRMHGPTLNWTSAAQHIGGKFYDAHNVNSMYTNTVAVSMPIYTGGQLEGSIKAADLALDANELALEATKQGIKAKTQAAYYSALNCRNQIKVAQNSVKTLEEHLRNVNAQFGAGTVAKSDLLASQVQLSNAQLNLVSSQNNYDVAIATLNNVVGLPTGTELNLKDELGYVPYEISLDQCSEYAQLNRPDILAAEYKVKIAEAQLDVASSGNLPKVNATVSKTFAGEKPFSADERPVDNFYQQNTWYAGIGISWDIFDNNVTQAKVKQAKAAIEKAKEAAQEARDTGDLEVRTAYLNLTAAEKSISTAKVAMEKAQEDYTIAQVRYGAGVGTNLDVMDAEEKLTTAQSNYYNALYKYNSSKAALDKAMGLMVDLDVTQLQEKLAKN
->UniRef90_A0A0N8K910 Oligoendopeptidase PepF n=1 Tax=Bacteroidetes bacterium HLUCCA01 TaxID=1666909 RepID=A0A0N8K910_9BACT
-MSEKKTSNGAETIYWDLSDLYTSGEDPNIRKDQHRLRDLASTFAARYRGTLATAHAGDLAEALRTYEEINDLLGKMGSFAYLQWSTNTENISYGQLMQQINEFSSELSQQLVFFDVEWLALEEERAAELIADERLKSWKHYLTASRRYKKHILSEKEEQILTAKSVTGSQAWVRYFDETLGAARFELDGEQLTEQEVLSKMHEPDRELRQRAADSLTRGFREHRRTLTFIFNTLLVDKFTNDTLRKYPSWISGRNLSNQIADDTVETLVESVQKFYPTVQRYYKLKKQLLGYDSFFEYDRYAPLLQTESRVSWSDAQTMVLDAFNGFNPEMGRIARRFFDENWIDAAIRPGKRGGAYSASTVPSVHPYVFMNYDGRLRDVQTLAHELGHGVHQYLSREQGILQADTPLTTAETASVFAEMLVFQKLLAELTDPREKLALLMGKIDDTIATVFRQVSMNRFEDAIHTARRQEGELSAERFSELWRKTQTDLYGDSVQLTENYDLWWCYIPHFLHTPGYVYAYAFGELLVLALYNRYENGAENFPQRYEQLLRAGGSDWPENLVSKLDVDIKDSTFWESGLAIIDQLVDQAEQLSAQAGMGQ
->UniRef90_A0A3M6WIU0 C3H1-type domain-containing protein n=2 Tax=Hortaea werneckii TaxID=91943 RepID=A0A3M6WIU0_HORWE
-MAGKKPCHLFQLGRCKYGNGCKYAHVKDPSFKRKACINFAKGTCHRGKTCTYSHDQADIDLWGASNDQDTAANASGPSHVDNSQAMFKNWRYNIPQEVGTPTPLGINLGRFFKQAAELIDGDAGRMQEVIVLLASEGGVQRIIELLEQPLDKCHPDILPRLFNTQIICFLEIITHKHVTVSAILKPRLTTIYNIVWGEGGQQAMKLFSAVAQHLQTLRLMGQGEGSSTNTTAIHAIECALTALDKLTEVNTSAQVHDGLKRVAEAFAILFKEPMTDQVRFAVKPSQRHLRRVEQRLGLGQAIPTQSEGKQHKGERAFFTLERPGPGELNIDGVAPRYDNDHVDIRGISILPTTLEIQFAGAEYLPLTDPTQWHIGGLEGLLDRHFRLLRADTVGQLRDTAKTELARLQAPEARGPTQQNKQRTSRAFVYGNATIVDATFTSQNGIEFAISFDQPGKVQRKKKNERKDWWQNSKTLSDDALVCLLSSLGSAIFLTVVPEPKNPKKDAAKGEQQTSIHKQYDLWSNGQRAHVIVKPAQQDGIELILRELSSSGNARLSLVEFPSVLLPAFQPTLRAMQRLTETLEVPFAEVLAPVSTRDNPTREIEIQPPNYATRPGFQFDLSVVTTNGKALRFTPGRDIDGAAAELAQYSIVSSLSRSLALIQGPPGTGKSYTGVQLVKILLAHKKACNLGPILCSLERLLDEGVSNIVRIGGRSKSDRLANVNLREVAHRLDLTKTEKSERFRLTKEVEDEVTELKLILRSMSELGSQSSIEEYLREWQPQHHHQLFSNIDEEGFITVNRHQDSELQQWLNSVPWDQKKRRPVAELENADLRQMTARERRRLYRDWTAKAAHKVQEKFDRALTEYNNAKEQQDDIRTETDQRALRQANIIGITTSGLARNLDLLRRVNAKVLVCEEAGEVLESYLLTALLPSVEHAILIGDHQQLRPHVQNYDLSTESRGGAQYALDVSLFERLVQPQDILAHPLPFCRLQVQRRMHPSISQLVQETLYPNLQNAESVNPIPDVVGMRRRLFWMHHEQIEDHAGDGLKTSHTNSYEVEMTAALVKHLVHQGVYKSEEIAVITPYLGQLRLLRRKLASSFEIVLNERDDEELLKDAGNGIEGDPPSTDVPLRRPSVARGTLLNALRIATVDNFQGEEAKVVVISLVRSNRERKPGFLKTPNRINVLLSRAQHGMYIIGNSDTITGDAGSKAGSVEMWENVLDIFRTNDNFGTALELCCPRHQDTPMSVQQPSDFVRLSPEAGCNLLCDQKLSCGHACTSKCHSDMLHDAVFCSKPCYRLDQDAPIRAKRNACMVLIKDVNVQLECRHIHKSLRCFEYQDPSKVQCQVPVTWTVPGCEHQVKEPCSTDVYSDDYKCRAMCSAILPCGHLPATAKKSARRVQPSAKPVVFTVRVARHAVSLLQLSSRPSMPFALCRSLRLASLLEEVSSDIEVYFLDSKLLTSYCRCEKTLSCGCRCPSVCGEACPTSDFCQVHGSEHIESLNADLVMLCAYRDVDLDEDPCIFPPCGHVFTATSMDGTMEMAAHYEIDPLTGAFTALKSTSEPFSSQELKTCPECRGSLRSINRYGRIVRRALLDEGAKKLTAWANRTHHDLSERLANDQCRLLDSLEMARKPSQNVKLTNSIDDQLREVKRLKYSKRYRQTFAIRTAVKNFSDRLIVDEQPYQRVRDLVETRRRQQLASSSATDIAEFSFASEELQLHEHLQAMLLLVRTEIVILSDVIAMHDKADGPVKGILKLQFDANRLQCTELAEEAARTVNVRQEVEAHIFWAKFAAMECGTSMATEEEGDADVSDYLERLRDKAITHLDTAEAICKRFTANEPDPTSDLSDELAEVRRMLDEGISSSEMRMVVAAMAKEFRGTGHWYRCVNGHPFTVGECGMPMQLARCPTCGEGIGGQHHRPTAGVQHANDIEERFGRMAI
->UniRef90_UPI001FBC0094 HlyD family type I secretion periplasmic adaptor subunit n=1 Tax=Methylobacterium sp. E-016 TaxID=2836556 RepID=UPI001FBC0094
-MTHALVVPPPPIQMDWRKPVLTAYLVILLAFGGGAGWASVAKLESAAIAPGVVIAQSNKKTVQHFEGGIVREILVRDGDQVQEGQVLLRFDETQARASLDTIRSQQAVARIQEARLIAERDQTGKIILPENVASRAHEPAVARAIEDQQSNLRERATYLRSQVDVLNSKILQTEQEVRALTNDADSTKQQLVTIDQELGGLRQLLAKQLVPVSRVAALERERIRLQGMLDRAISDAKKGAQSIGETRLTIIQTQKQFLQQVSTDIIEVRKNLSDLIEKERVAQDVLSRLDVRAPRTGIVQSLKVFTIGAVIRPGDTILEIAPTGDQLTVSVQISPNDVDSVSEGLRAEVRFPTYHSRRVPIMLGKVRSVSYDRVTDAQNPQNIYFQGEVVVQASTVPSEIKDKLKPGMPAEAIITTGEQTPLDYFLGPLFDRVSHGLREK
->UniRef90_A0A7R8VGG4 JmjC domain-containing protein n=1 Tax=Timema douglasi TaxID=61478 RepID=A0A7R8VGG4_TIMDO
-MHYLLNSGFDYPIVVDDPNGLEMAVPTNFNALQLLDYIDGMQQVKAIDVMSQNIITIYLIDFVDYFLSPYRWHPINLLSVEMSQTSLRDAIQPPLISRILDWSEIAWPADCSEPKSDVQRYCLVSTKRSFTDFHVDFGGSSVWYHVVKGEKILYLIKPTAANIQLFIQWTNTSKHNNSFFGDHVDDCFMLILTEGQTLFLPTGWIHAVYTPEDSVVFGGNFLHDLNIPLQMEIYKMEKATHTRQMYLYPQFEELNWYAGQHILQVICNTNIVGAVPRKYLMQGIRALIPMLNLWLTKNEDGQPFTSIMCQNLIRDLKRELKIGELNTKMLTTPRPGRESKRQRKKTFNADFYYFPAANKVASKASVAKVPLGGSTSPNQSNVSSQKIPLSLCSLPIMSHDLQEKGSSDSSSNKTSHSSSPTLSKDMIHAPETIQQNELKMLCSQIPNQLEEAHALFSTERVDSATILTQMSHQVSESLNSQTITRQKMESTSSQSKQPHTAREESSSFWQASVLGNVPTLKVVLNRLANVPEPVTYPYSTNSVTTKKHHTAACTITSRESQDNNCQPWFVQAHTLCSKKELKMKVKAVSDSSKQTTPRDVYDFHASEDENSLLIDDQSSIESWHTNMQSKVNRKSPNSSVSSPTLSLGSSTQSDSIGLPYVKVNRIDELLKASALTGSGGTSPSTRDAIQGMLSISCSGSSSTSKMPIKTRSKKQHYEMVDDAQELVDEVHRDDDFVYPSLDVSDGEEPLNKRSKKRNIDEAWNPSARIGRLVPRTDRPTRYIKKNQAIEKGLEAAAAKRANLPPPKRPYNKKKTSDTPIPSTPGTLPKKEMPKEIKGIKCKHRQMGEKVTRGERKRKREGRKRQKSQGTPQGQQRSMLETLLPSRSRPFQLLGDEARMRVIFTMLVSLPNSS
->UniRef90_A0A1K0ILZ2 SPOR domain-containing protein n=1 Tax=Cupriavidus necator TaxID=106590 RepID=A0A1K0ILZ2_CUPNE
-MRVQSPASAPAPDAAPRSALPSATLAAACIEIGGFSAQAARRATEDLAAAALRVEAFARQEQVRWWVHLPAQPTREHAERKLAELRRRNVTEYSLVTAGTPEATTYTVSLGLFRERERAQQYLDSLRGHGVRTAMLTEAARPLTRQWLRVRDADHAARARLEAMRQRYGAEDVLACS
->UniRef90_A0A6H5GIQ7 Zonadhesin (Fragment) n=1 Tax=Nesidiocoris tenuis TaxID=355587 RepID=A0A6H5GIQ7_9HEMI
-GGINHPGPSGTSCYRNQFSEVTLSANFDQIRSNSTSRSIQLRDQTRLRDQTQLQVQRQHRDRIQLRVQTQHRDRIQLIDQSQLRVQTELRDQIQLRIQTQLRDQIQLRDQSQLRVQTELRDQIQLRDQSQLRVQTQLRDQIQLRDQSQLRVQTQLRDQIQIRDQSQLRVQSQHRDRIQIRDQINFEFKLNFEIKFNFEFKLNFEIKVNFEIKFNFEFKLNFEFKVNIEIEFNFEIKVNFKIKVNFDFKLNFEIKFNFEFKLNFEIKINFEIKVNFEFKPNFEIEFNFKIKVNFKFKVNFETKFNFEFKINFEIKVNFEFKLDFEIKFNFKIKVNFKFKVNFEIKFNFEVNGSIVIVLKSRIGTELQKKLFLIHIYSESLPEQVSVCPFDNIFGCSPTNMYPEKIEKIIFYYLIRTPQFLCGRSSNFINTYLILLTGLTRQQFGGVRPCRDKHFSSRNLKKGRKPMPPQ
->UniRef90_A0A067KLY9 PPR_long domain-containing protein n=1 Tax=Jatropha curcas TaxID=180498 RepID=A0A067KLY9_JATCU
-MAVKLSHSYFFNSYKPDDASFKQMGAPKRDLLVNPRIRKSNPTKKQMSETPKRGMIKPNSLSLTRSLCEFVDSGAMDNALYLFEKMNQPDTYIWNVIIRGFSNKGLFQEVIDFYHRMEYEGIGIDNFTFPFVIKACGRLLSFIEGKKVHGKLIKIGLDRDIYVCNSLIDMYFKFGFVEVAEKVFEAMPLRDLVSWNCMVNGYRVIGDGLKSLMCFKEMLGLGEKPDRLSMISSLGGCSIGCCVRGGKEIHCQVIRNGLELDIMVQTSLIDMYAKCGKVDYAERVFNEMTCKNIVAWNAMIGGYAINGHFLESFTCLKRMQEDNLIPDAITMINLLPSCSKFGTLLEGKCIHGYAIRKMFLPHLVLETALVDMYGKCGQLKFAECVFGRINEKNMVSWNAIIAAYVQNGRNEEALELFHCLRNQTLKPDAVTIASILPAYAELATVTSLVWSMKGGNCSIL
->UniRef90_A0A521B5K5 Uncharacterized conserved protein n=1 Tax=Saccharicrinis carchari TaxID=1168039 RepID=A0A521B5K5_9BACT
-MSEKNLTVTSNKTGQLFDAKGQLLSPPSQWSFLPAGDAGVTRKVTANGKYWRVVFKKGRRIMSKGVWAPTQVIEMAKKEMEATRSTDDYLKKKEYNAKRRKKQQQAYEIEFCAEVEKFLNFHSDYAPVARAMAILVTRHAVPVGSGTVARTAMIPVHERAARAVIAWMRHQTTAYDHMKIARIKGERREVRRMLAQESTRLMNNYRRGLPIPFTCPLKKALDKIISP
->UniRef90_A0A517WN20 Putative adenylyltransferase/sulfurtransferase MoeZ n=1 Tax=Gimesia aquarii TaxID=2527964 RepID=A0A517WN20_9PLAN
-MKWTCAVVFTLLITSMGFAVEHTKDSLATIKKNVESKKAVLVDVREKGEWDAGHVKGAIFLPLSSLQDGITAAEQKKLPQDKVVYLHCAVGFRAKIAASLLKKYNDKVRPLPQGYEELIESGFQKSK
->UniRef90_A0A0F5FR09 Serine hydroxymethyltransferase n=2 Tax=Devosia TaxID=46913 RepID=A0A0F5FR09_9HYPH
-MSAATSLPLFPHFFSDSVAETDPELAKAISDELARQQGEIELIASENIVSQAVLEAQGSVLTNKYAEGYPGRRYYGGCQFVDVAETLAIERAKQLFGVGFANVQPNSGSQANQGVYQALLQPGDTILGMSLDAGGHLTHGAKPNQSGKWFNAIQYGVRKQDGRVDMDQVRQLAREHKPKMLVAGFSAYSRIMDWAEFRAIADEVGAILFVDMAHVAGLVAGGVYPSPFPHAHVATTTTHKTLRGPRGGLILTDDEDIAKKINSAIFPGIQGGPLMHVIAAKAVAFKEALSPEFKLYARQVVANARVLADTLVKGGLEIVTGGTENHLMLVDLRPKGLTGKATETALGRAHITCNKNAVPFDPEKPAVTSGVRIGTPAGTTRGFGEAEFRHVGELILEVLDGLAANGDENNAAVEEAVREKVKVLTDRFPIYGQ
->UniRef90_A0A6F8V0N0 Prevent-host-death protein n=1 Tax=Bosea sp. ANAM02 TaxID=2020412 RepID=A0A6F8V0N0_9HYPH
-MARRDLNARLDQATHALCTRVERAHAVPAGATLRFRQGKPLAPVIFTILESADWDRSALPARDGYPFR
->UniRef90_UPI0014890022 alpha/beta fold hydrolase n=1 Tax=Ruegeria sp. HKCCD8929 TaxID=2683006 RepID=UPI0014890022
-MRFLPVLVAVVWLAACTDRSSFVLVPDAVDVGTPRTVFAASARAREADGSYGYRRADRLQFLELTVSIPPTHTPGSLNLSYGRPDPETQFVLAGQEVFASPEPLRQRLLNDQREHGSALREVTLFVHGYNATQNETAFRAAQLANDIEIPGSLMIYSWPSRARAFGYAYDLDSMLFARDGLEQTIRQLKASGAERIVLVAHSMGAALSMEMMRQAEIREPGWSDRMLEGVVLISPDLDVDVFRTQMDRIGTVPQPFVVMVSRKDPALNISARLRGTAESRRLGNIDSIDRIADYPVDVIDTTAFSGDAASRHFVAATSPALVTLLSSAPAMGEAFGPEETSFDFLIPGGVEVSGRAKEIILARPGENR
->UniRef90_UPI00049064DE HAMP domain-containing histidine kinase n=1 Tax=Paenibacillus sp. UNC451MF TaxID=1449063 RepID=UPI00049064DE
-MRGLYRRFAFTFICITCGILLIASIVFILETHYHFALYQHQSMDMGADNAQLNAHFEQALVQSVIWTAVGGIALASVVSLYVAKRMTSPLLEMKAAAMKMAEGNLQARTKLVGNDEITDLGLSFNHLAEQLEKQEQLRKTMTADVAHELRTPLATLKSHMEAMIEGIWEPSAKRLKSCHEEIERLIHLVGDLEQLTHLDSPHFQLHMKSENMVSIASQCVQAMQAAFQLKGVQLTLHKPNEDIFAIVDRQRVCQIIINVLSNALKYTPVGETVAVTMAGDHRSSTATISVRDTGIGIESRELPFIFERFYRTDKSRDRKSGGSGIGLTIAKKLTEAHCGKIEIQSEVGRGTTVQIHFPIKSKKSSLSTQDLQKSRI
->UniRef90_A0A2J8RU61 MAP4K4 isoform 8 (Fragment) n=1 Tax=Pongo abelii TaxID=9601 RepID=A0A2J8RU61_PONAB
-GRHVKTGQLAAIKVMDVTEDEEEEIKLEINMLKKYSHHRNIATYYGAFIKKSPPGHDDQLWLVMEFCGAGSITDLVKNTKGNTLKEDWIAYISREILRGLAHLHIHHVIHRDIKGQNVLLTENAEVKLVDFGVSAQLDRTVGRRNTFIGTPYWMAPEVIACDENPDATYDYRSDLWSCGITAIEMAEGAPPLCDMHPMRALFLIPRNPPPRLKSKKWSKKFFSFIEGCLVKNYMQRPSTEQLLKHPFIRDQPNERQVRIQLKDHIDRTRKKRGEKDETEYEYSGSEEEEEEVPEQEGEPSSIVNVPGESTLRRDFLRLQQENKERSEALRRQQLLQEQQLREQEEYKRQLLAERQKRIEQQKEQRRRLEEQQRREREARRQQEREQRRREQEEKRRLEELERRRKEEEERRRAEEEKRRVEREQEYIRRQLEEEQRHLEVLQQQLLQEQAMLLHDHRRPHPQHSQQLPPPQQERSKPSFHAPEPKAHYEPADRAREVEDRFRKTNHSSPEAQSKQTGRVLEPPVPSRSESFSNGNSESVHPALQRPAEPQVPVRTTSRSPVLSRRDSPLQGSGQQNSQAGQRNSTSIEPRLLWERVEKLVPRPGSGSSSGSSNSGSQPGSHPGSQSGSGERFRVRSSSKSEGSPSQRLENAVKKPEDKKEVFRPLKPADLTALAKELRAVEDVRPPHKVTDYSSSSEESGTTDEEDDDVEQEGADESTSGPEDTRAASSLNLSNGETESVKTMIVHDDVESEPAMTPSKEGTLIVRQTQSASSTLQKHKSSSSFTPFIDPRLLQISPSSGTTVTSVVGFSCDGMRPEAIRQDPTRKGSVVNVNPTNTRPQSDTPEIRKYKKRFNSEILCAALWGVNLLVGTESGLMLLDRSGQGKVYPLINRRRFQQMDVLEGLNVLVTISGKKDKLRVYYLSWLRNKILHNDPEVEKKQGWTTVGDLEGCVHYKVVKYERIKFLVIALKSSVEVYAWAPKPYHKFMAFKSFGELVHKPLLVDLTVEEGQRLKVIYGSCAGFHAVDVDSGSVYDIYLPTHIQCSIKPHAIIILPNTDGMELLVCYEDEGVYVNTYGRITKDVVLQWGEMPTSVAYIRSNQTMGWGEKAIEIRSVETGHLDGVFMHKRAQRLKFLCERNDKVFFASVRSGGSSQVYFMTLGRTSLLSW
->UniRef90_A0A1V5E6B1 LPG_synthase_C domain-containing protein n=1 Tax=Syntrophaceae bacterium PtaU1.Bin231 TaxID=1811718 RepID=A0A1V5E6B1_9DELT
-MNFKKLEVADYAALKPYFDPIPYRLSIYSLPSLIAWGDCVFETRYAVEGDLLVIANESQLRPDDRHLILPVSPGGDPSPERLRAIALESGHRRYWCACGNYVERHRQGLEPLFHIEEQPEFEDYVYLAEDLAELRGNRFVRKRNLIHQFEREFMRNGSRASVEPITRESVPECLAFLEAWCVQRDCDVDGDIDLACERRAVITSLEQLEALDLRGILVRLDERVCAFGIASRLNGDTGILSYEKAFSDVKGLYQFLDRECAKRLFAGCRYINKESDMSLPNLAAMKRSYHPVLRVKSYRLTLR
->UniRef90_UPI000D0912D6 B3 domain-containing protein Os12g0592300 isoform X2 n=1 Tax=Rosa chinensis TaxID=74649 RepID=UPI000D0912D6
-MELEERPSFFKVLVDGFSQQLRIPRAFVKNFNGRVPRMCGLRGPCGNLWAVNLKEIKDRVVFHNGWQSFAKHHFLEVGDFLTFTKDDGSIFDVIIYDKSYCEKNVEAAKSRIGNVVDRTINNHIILGKRPALDLVEETSIGSISFNSENPFFTTIFTREFQAK
->UniRef90_A0A0N0N6B7 Amidohydrolase 2 n=1 Tax=Actinobacteria bacterium OK074 TaxID=1592327 RepID=A0A0N0N6B7_9ACTN
-MFKEFVVSGDSHIIEPVDLFKTRLPKNLRERALWEEEFTLEEPIVPGGHTEFKKLHTIGFDGWTISKYRQTGGITPDGEPEHIIRDMNLDGVDASVMFPNLSLFVLFTDDHELSMAHAKVWNDWIAERYLQYKDRLRPTAAIPLTYIPDAVAEIERCSRLGIGAILLPDVPPELPYWSSEYDPVWAAADAHGMPVFFHVATGGVKVKESSSATATTVRGMVSSMNMGKGQLTDAMVASRTMSAGGSGAAGPQGIIADLVAGGVCERFPNLHFNLIEYSAGWLVSYMGFMDKLWKTGTGQDPDWWLGFWDDSRSPKDQPTMGRMFAVNQRWPWPLKPSEYVRRQIHVQFADDPTAVKCRNITGLSTIMWGNDYPHAEGTFRSSADCIAENFEGVGDEDRAAILGGTLADIVHFDKSKKLAPVAENA
->UniRef90_A0A4Q9KAX3 VWA domain-containing protein n=1 Tax=Propioniciclava sinopodophylli TaxID=1837344 RepID=A0A4Q9KAX3_9ACTN
-MVPLISFFHPERLWLLALVPVLLLLYGALLQRSRTRSRTQGIDNLAKVMPKQAAWKRHIAVLAAVVSLAALVVAFAQPKDAVDVPRERATVVLAIDVSRSMEATDVDPNRLDAAKEAASGFVDLLPRGFNTSLVAFAGSSSIITPPTQDRGLVKRAIDNLQLAPSTAIGEGIYSALDAMLLVPQDPNDPEESTPGAIVLLSDGYTNIGRSSTVAARDAKEAGYPIYTIAYGTPNGYVVSNGRREPVPVNPAELNAVARESGGEAFQAGSREELQRVYASIARSVGYEKVDQEVTEFYAGIALGFAVLASLAVLSLAARWP
->UniRef90_UPI0004DC9B9D PE family protein n=1 Tax=Mycobacterium tuberculosis TaxID=1773 RepID=UPI0004DC9B9D
-MSLVIVTPETVAAAASDVARIGSSIGVANSAAAGSTTSVLAAGADEVVSAAIATLFGSHAREYQAISTQVAAFHDRFAQTLSAAVGSYVSAEAT
->UniRef90_A0A2E4XJ01 Enoyl-CoA hydratase n=1 Tax=Acidimicrobiaceae bacterium TaxID=2024894 RepID=A0A2E4XJ01_9ACTN
-MEEIQLTQEENIATVTINRPQVKNAVTSDMWDELQRVFTELGYRDDVRAVIVTGAGDDFCSGADVGGMGSRSEGPRLHQLDAMRKVGDCCLSLFNMPKVTIAKVSGVAVGAGMNLALSCDLVVASENARFSEIFAQRGLSVDFGGSFLLPRIVGMQKAKELVLLAEVISASKAHEMGLTNYVVPREQLDEKVLDLATRAASGPPRALAMSKAMLNKSFANSIQDALDQEGTSQTVNFTTKDVSEAMKAFQEKRSPRFKGW
->UniRef90_A0A7S1QCM4 Guanylate cyclase domain-containing protein n=1 Tax=Alexandrium catenella TaxID=2925 RepID=A0A7S1QCM4_ALECA
-TSLAGGGDATVAREELVSECRHKLGRSPTNVHLAWSDPHWLIQPRGAWVIGHELQGHFRFNMSADPFAANAIDCRRFDLNTVVLIITGILTCLVFAVTYVHLRTYAVVAVSTTFISLACATGIFGVWMRWVDCRTSGLHDHNMVFRHLATSCFQVANFNGTMYANAMQKHGKLVIAFESNFRHVRQVSRSEVWFGSLSEAFLLVLVIAAHVTFRHKRMQTREARYELMCRRPRLVRCLLENISFLDQLPPRDRTMMAFTLKRVYDEDDGKKFSDLEERYREMLSMKPSPSDLDGVGSSFWPAAVYSLVRALIPSTYRQFIPTATTPGSGMQAYANAVPEENTLWMLSALLRVVMTFCVYLFVLFSIKEASRRYTRTMQVWLVFDSKWHFPSQTSLAGDPMTETVQVSMDDEGECLHMLDRNHQPPIGNFSSEHCCSPRDSEDDGNIVNTQEVKDKLTTWWAWREYLIIDYTDKRVRLEFHLVVAVAMLVVSAVLICVDDFKEGFRPPQLLDIDESMSWFRGHVNSLSFQTAWDLLFLTWPVLNAINTAATMNRLIESHLQKIKHLADLLNEAGIGLPVGADSSPAGQSDVSPQDDVGPSIRNIFRVAKAELASGGSNATRFLNIVPINRQTFAIAGTVLSLFTGGQFMEIFNNLLGAVNGS
->UniRef90_A0A193G2U0 General secretion pathway protein GspM n=2 Tax=Bordetella bronchialis TaxID=463025 RepID=A0A193G2U0_9BORD
-MKVSARRAPRLLLPAPLLARCRDTAERASRYWTRLTPRERRLLRALGAILTAAAVFALGLRPAWRDIERWRDELPRLRAQAAAVDALVQEARALKREQGNRIPARDMEEALRASLARAALGGTQQVGKTPDDKAWRIAFDDASPAALFDWLAHAPAFLHLRVVQVHIVRPRDSLGRPIPARATGTLVLRDAGDAAIGARP
->UniRef90_A0A0B8NUT2 OMP_b-brl domain-containing protein n=13 Tax=Vibrio TaxID=662 RepID=A0A0B8NUT2_9VIBR
-MIEAETMDHEIRATWTRQGVQPYFEFRSQANGAENAQGDSLVNNAFVFGASYGF
->UniRef90_A0A7S3J898 STI1 domain-containing protein n=1 Tax=Euplotes harpa TaxID=151035 RepID=A0A7S3J898_9SPIT
-MLKSLDNLRAAHPGCRQQISLLPPQQMIRKIGDMKNDDPQMTMRGMDKEELSHMQRIMGSMESMAADRSMQFPQVPEDILRRDMEEDQDNSNHNEPEEE
->UniRef90_A0A653T2G2 Glycosyltransferase EpsD n=2 Tax=Microbacterium sp. 8M TaxID=2653153 RepID=A0A653T2G2_9MICO
-MSQRSELRTHHRRDLLSDPELPPASAPRVAHLAHTTVAGGAELGLARMLRADAPWRASVLLPPVPAEDGAFAGLPASIPIHRIGVAQPHGASGASAMSAFSLGVRLVAQAVATRRHPSFRQADLIVANSTRAAAYGALAAFGSRKRFLVHLHDITDRETLGGFGLRMMTRIVLPRADGVIANSQATLASAEPYLRPDAVREVIAGASGLTGAARGAREPGPLRVGMLARIDPWKGQLLLLEAFAQAFPGGDEILEFAGGAPFGHADFAVELRDRARALGIADRVHLLGHVEDVDRLLRRWDVGVQASLRAEPLGFNVLEYLDAGLATVVAAEGGPVEWVRDGVNGLVVAPRDVGALAAALRRLGADAGLRSRLGDAARSTPGLATDHVVAQQHAAAYLRVIAQRR
->UniRef90_UPI001B319B05 hypothetical protein n=1 Tax=Bacillus suaedae TaxID=2822140 RepID=UPI001B319B05
-MAINYKQCINCESKNTLNLLYGMPTDDASKQAKEGKFKLGGCCVIVGGPEYCCNVCESEWNKEQAIDAAYEKIIGLNAYVGGFFGASYNVDLDLISGSAAWSHWENGEEVASECKALKETTVKKLIEELKIINFLNWKREYIEPGVLDGTSWSVELIREGRNLKRSGANKFPEEWDDFCKLVRRMTGKRFS
->UniRef90_A0A516GYM1 YdcF family protein n=1 Tax=Ferrovibrio terrae TaxID=2594003 RepID=A0A516GYM1_9PROT
-MARKDRDDEESTPFFTRISRWLMLLATIGLLWLGGGIAYVERVESIPAPAETKTDAIVVLTGGAARLATALRLLNENKADRLLVSGVAQTATKATLLQAVLPTMPDAAQASSNWQGIDLQLLFDCCVDLGFEADDTAGNAAETASWAAARGYRTIRLVTANYHMPRAQVEFGRYLSGMTIVPHPVRSDAMRVEDWWQRRAATVFLLGEYSKYLAALLRARLGTQLTATLEQKPQTVPVQPAAAPTQEKPTEEKPQ
->UniRef90_A0A7C9L683 Alpha/beta fold hydrolase n=1 Tax=Sediminimonas qiaohouensis TaxID=552061 RepID=A0A7C9L683_9RHOB
-MTVVQDPAANADLPVVVMIHGSGWHAQQFDRLAWALRDVAELRAVTLRGHGADPVRRGDVDYIGQLEDDLASAIGDVAPGRKVVMLGHSSGGGLVVRFAGGPHDGMIDAAILLAPFLKHNAPTTRTDAGGWARPLTRRIIGLSMLNMVGIHEFDHLTAIHFAMPKKVLDGPLGHTATTAYSWRLNLSYAPRRDYKADIAALPPFVLIAGADDESFRADEYEPLMSGVTDKGRYHVLPGVGHLGVVDAPQTETLIREALRAL
->UniRef90_UPI001BA7DB86 DUF2130 domain-containing protein n=1 Tax=Bradyrhizobium sp. AUGA SZCCT0177 TaxID=2807665 RepID=UPI001BA7DB86
-MTFKATASDAHEPVVRCPNCSHDIRLTESLAAPLLEENRRRFQEQIAQKDAEVARKSEVLLKERDDLARARDQVEEQIKQRLAVERNQLIAAEGKKAQEAAAVELQAKSTEAAELRRTLEANNVKLAEAQKAQADVLRKKRELDDEKRELDLTVEKRVQSSVEDVRVKARQEADDAARLRISEKDHTIESMTRTIEELKRKAEQGSQQTQGEVFELELEEILRGRFPTDMIEPVAKGELGADVVQQVNEASGQPAGIILWETKRTKNWSDSWLAKLREDQRRCGADVALIVSHALPKHVEYFDLIDGVWVAHPRCALPVAVSLRQALIAVSNTRLVQQGQQTKMEQVYQYLTGTKFKQRVDAVIEKFNDMRDDLDKERKFMICQWAKRETQILSVVESTVGMVGDLQAIAGKAMPEIPSLDLPLLEISDAAE
->UniRef90_UPI001447B9A0 helix-turn-helix domain-containing protein n=1 Tax=unclassified Cryobacterium TaxID=2649013 RepID=UPI001447B9A0
-MPEAATKKQTLAWLKTVSGELATATLKRLDDTLPWYREMPPGRRSAVGLVAQAGITSFMQWYDDPSSTPWIAADVFGAAPRELLRSVSLTQTLQLIKVTVEVVEERVKGRDESLREAILLYSREIAFGAADVYARAAEARGLWDARLEALVVDSILSGEYDDELPSRIAALGWHGHGEVSVLVGTAPKMLDVDMLRRTARHQDADVLIGVQGSRLVLVIGRAQPASVNEDEGTAPPKPFLDIAMELEPGFGDGFLVLGHEVPSLVDASKSAKAALAGFAVARSWRNAPRPTLADDLLPERALAGDPLARATLITRIYRPLQAHSTELLSTLWSYLDNGRSLEATARELFVHPNTVRYRLKRVSEVIGYDATGARESLILQAALIVGSIAEHDTPRRR
->UniRef90_UPI00131B79F4 3-hydroxybutyryl-CoA dehydrogenase n=2 Tax=Chachezhania TaxID=2603319 RepID=UPI00131B79F4
-MTIKSVGVIGAGQMGNGIAHVMALAGYDVLLNDISQAALDKARATIEKNMVRQVSRGAISEDEMKTAMGRMTTSMTLSDVGQTDLVIESATERESIKQAIFEDLLPSLKPNTILTSNTSSISITRLASRTDRPERFMGFHFMNPVPVMKLVELIRGIATDEATFNACKEVVARLGKTSATAEDFPAFIVNRILVPMINEAVYTLYEGVGSIESIDTSMKLGAAHPMGPLELADFIGLDTCLAIMNVLHDGLADTKYRPCPLLTKYVEAGWLGRKTQRGFYDYRGEVPVPTR
->UniRef90_A0A0B5L654 Gag polyprotein n=1 Tax=Human immunodeficiency virus 1 TaxID=11676 RepID=A0A0B5L654_9HIV1
-MGARASILSGGKLDMWEAIRLRPGGKKKYRLKHLVWASRELDRFALNPSLLETAEGCQQIMNQLQPALKTGTEELRSLFNTVATLYCVHHRIKVSDTKEALDKIEEIQKKQKTQQAVADAGNNSTVSQNYPIVQNAQGQMVHQSLSPRTLNAWVKVIEDKGFSPEVIPMFTALSEGATPQDLNMMLNIVGGHQAAMQMLKDTINEEAAEWDRLHPIQAGPLPPGQLREPRGSDIAGTTSTIQEQIAWMTNNPPIPVGDLYKRWIILGLNKIVRMYSPVSILDIKQGPKEPFRDYVDRFFKTLRAEQASQDVKNWMTQTLLVQNANPDCKSILRALGPGATLEEMMTACQGVGGPSHKARVLAEAMSQAQQPNIMMQRGNFKGQKRMIKCFNCGKEGHLARNCRAPRKKGCWKCGREGHQMKDCTERQANFLGRIWPSSKGRPGNFPQSRPEPTAPPAESFGFGEEITPSQKQEQKDKELYPSASLKSLFGNDPLSQ
->UniRef90_E1GWA8 Anaerobic ribonucleoside-triphosphate reductase n=8 Tax=Prevotella TaxID=838 RepID=E1GWA8_9BACT
-MQNFTITKRDGSKEMFSLDKIMGAILKAFESVNAPTDLAAVSKILSDLTIHNDITVEDIQNQVEQALMKEGYYDVAKSFIVYRHQHSQDRETQDKIKFLTEYCGASNAATGSKYDANANVENKNIATLIGELPKQGFIRINRRLLTDRIKQMYGKELANEYLDLLTHHFIYKNDETNLANYCASITMYPWLIGGTTAIGGNSSAPTNLKSFCGGFINMVFIVSSMLAGACATPEFLMYMNYFIQKEYGKDYWKNADKVVDLSLRQRTIDKVITDYFEQIVYSLNQPTGARNFQAVFWNISYYDKYYFESLFGNFYFPDGSQPDWEGLSWLQKRFMTWFNKERTRAVLTFPVETMALLTENGECRDKEWGEFTAEMYSKGHSFFTYMSDNADSLSSCCRLRNEIQDNGFSYTLGAGGVSTGSKSVLTINLNRCIQYAVNKGEDYKLFLDHIIKLCHKVQLAYNENLKNFLKNKMLPLFDAGYININRQYLTIGINGLVEAAEFMGLDITPNEDYKHFVQGVLGLIEQNNKAFRTKEAMFNCEMIPAENVGVKHAKWDREDGYFVPRDCYNSYFYRVEDTGLTILDKFKLHGAPYIEHLTGGSALHMNLDEHLSKAQYKQLLTVAAKEGCNYFTFNIPNTVCNDCGHIDKRYLKECPCCHSKNVDYLTRVIGYMKRVSNFSQPRQQEAAKRFYAGSDKME
->UniRef90_A0A3S4JM46 imidazolonepropionase n=1 Tax=Klebsiella aerogenes TaxID=548 RepID=A0A3S4JM46_KLEAE
-MVFSHKKITFPCAIVDFTGVMKINVYTTHDKLSAMTEATSELVIWRNGRLATLNPDHAQPYGLLERHALLVRDGRIAAIVAEDDVPSGRSIDLEGRLVTPGLIDCHTHLVFGGSRAQEWEQRLNGVSYQTISASGGGINSTVRATRDSSEAELLALAQPRLERLLREGVTTLEIKSGYGLDLPNERKMLRVARQLADHNGVELSATLLSAHATPPEYQGDANGYITLVCETILPTLWQEGLFESVDVFCENVGFSPQQTERVFQAAQALGIPVKGHVEQLSSLGGAQLVSRYHGLSADHNRVSDGRGRGGDARKRHRGSPAPRRVLLP
->UniRef90_UPI001653AF6D hypothetical protein n=1 Tax=Lewinella lacunae TaxID=1517758 RepID=UPI001653AF6D
-MPRLKKILLTLLLLTVLAAVFRGPLYRTLVDYESVGASTNYTVKDEKLADLIASKVNRRTDLGITEAIKLSLSITSSQLHFTADNNDVDPNKLVTSKATHCVGYAAFFAATCKYVLSQQKLASSWTAEPQEGQLYFLGTNLHQYFHSAFLKDHDFVAIENHVTGEVLAVDPTIKDYFHIDFIRLRP
->UniRef90_A0A0T0M9T5 Peptidase C51 domain-containing protein n=1 Tax=Chryseobacterium sp. Leaf394 TaxID=1736361 RepID=A0A0T0M9T5_9FLAO
-MFKENLILFAVFVMTLVSCKETEYRQKTNQKEPEKELSKKIPEKNILIVEAIKKFGPEISSTYEKAVCTELVIQIIEKFHHLEERDKFRIRIITDGNIQDLIKENSPIPKGVFYALTEKGIGIPIKKEDVLEGDFVQFWTPTWGHCGIVKSISLEKQEMELYSSFPSTKGYGIQKFKIPEYTFFVRVK
->UniRef90_A0A1Y4S3Z9 Hydrolase n=1 Tax=Lachnoclostridium sp. An131 TaxID=1965555 RepID=A0A1Y4S3Z9_9FIRM
-MERLKYLFFDLDMTLLRDDKSISDEALAYLRDLKKRKDVRYGIATGRAWTAIEPLIERFGLDTLFDVIVMDNGSEIYDLAEGRRERLGIIQTEQMKQLLDAFGGYDFLAVAFHNPKGFFTTKISYRTERVLINNRLSGYHDPYKEEFEATARVMLLFLIEDQERVLEAVRLHPVPGIHGMLSEPEVYDFLCEGVSKAEGIRHYVTANGDRIEQTVVFGDSENDLEMIQKCGVSVSMKNGTEAVRAAADYVTGYTNNEDGVFRFLKEHEDWFQEG
->UniRef90_C7ZDV9 Succinate-semialdehyde dehydrogenase n=9 Tax=Fusarium solani species complex TaxID=232080 RepID=C7ZDV9_FUSV7
-MPYSAPKLKDPSLFVGKNYVDGQWIESVSGKRFDVHDPASGALIGSCPESVAQDAEQAIKIAAAALPEWRSRTGRNRSRILRRWYELVIENKEDLATLITWENGKAGPDAAGEVLFAASFLEWFAEEAPRVYGDVIPHSAPGFRVSVIKEPVGVVGLITPWNFPAAMITRKLGPALAAGCTAVVKTAGETPFTANALLVLGERAGVPKGVINSIAALENTPEIGQTLCASDVVRKISFTGSTRVGKILMNQSSDTLKKLSLELGGNAPFIVFDDADLDLAIAGAIASKFKCSGQTCVCSNRIFVQKGIYSQFVEKLKAVVSKFQVGHGFDSKTTHGPLVTAAAAERVDDLVKEAVKAGAKVEVGGKRRTDLGKSRPNFFEPTILTNVTTDMRLVRDEIFGPLAPIFSFDNEDEVVDIANKCDVGLASYIFTQDVNRVARVTELLHFGMVAVNTGIMSDAAAPFGGVKHSGMGREGSKYGIEDYLHVKTIVTGNVNVVHRALL
->UniRef90_UPI001F05B46E response regulator n=1 Tax=Desulfobulbus alkaliphilus TaxID=869814 RepID=UPI001F05B46E
-MHLSTASAMHDEGESYPMKEIRLLTDRLHQEIAEKTRALEKFRHLFEGAENGILVARGDTIEFANPALKHILGHDAEKITSEPFITFIHPDDRATVLDRHIRRMRGEDLEKSYDFRVVASDGSVRWINLSAQIINWDGDLANLSFVNDITERKTAEKEHEKLQEQLFQAQKMETVGRLAGGVAHDFNNMLGVILGYSEMALSQMAADHPLHGALHGINQAAQRSADLTRQLLAFARKQTITPRIIDLNETVEGMLKMLRRLIGEDIDLIWLPGRNLCPVKMDPAQIDLILANLCVNARDAIKGHGKVTIETGLTSFDDAWGAVHTGVVPGEYVLLAVSDNGCGMDQETINHMFEPFFTTKEQGQGTGLGLASVYGAVTQNNGFIDVESEPGQGATFKIYLPQYVIRTEPLPVQDQVGATMRGHETILLVEDEPVILKMLRTMLEHQGYTVLTAGSPEEAIRLAEEHSSRIDLLMTDVVMPGMNGLDLARNLLSRYPGIKTLFMSGYTDDVIAHHGVLDEGVHFIQKPFSMRVLGEKLREALEG
->UniRef90_A0A8B8IMG2 serine/arginine repetitive matrix protein 1 n=4 Tax=Nymphalini TaxID=171576 RepID=A0A8B8IMG2_VANTA
-MSSRRNGSVSRAAEAASKNRLHMDRNPQHSRITDPSNPAGRRKEIDNVMKRARQASPGSWDRKLLEVEEKDPNRWRHTGYKQMYLDGSGSASPRRSRSPRRSRSPSRRSRSPRKSRSRSPRRRSPLRRSPARRRRSASPRARRTRPPPRPPSPPDPRKSSPSGSSASSCSDESCSVCSAKNKKVPPKPIKPGVRTSPSPPRTKRPAPPVAARAVQPTRELLKARESSKRSREEKVLEWQRSQLAVRPAPPIPPAHIKREGERRPRPPRPERPDRPDRTDRVSPAAIAAALADSDSDSESDASSEPPPQRLTLSERFGKMAQWSAARCARLENMRITRRDSALHVHIERDDAAPAAPDAPRADYPGLDPAPVGSYPEELLAVAPGGLPSWDDVRVRYDYYKKRGYLRGLTLGDYVKWEEWWYKYQEWLKRERAYERWAEGEGGTSRRERRRRGGRHRRS
->UniRef90_R6N0F5 Polysulfide reductase n=2 Tax=Firmicutes TaxID=1239 RepID=R6N0F5_9CLOT
-MESTLFKISEPSRVSGVLYGPITLVYGLGGIALTLADKYILSKIKCNKVLKIILSFIILALILTTVEFLSGYLCKLIFNTEMWNYHNKPYHIGKYICLEYIPLWGLLGTLIIYVLKPFFDKIIKLIPKEATYLLYLIMILDIIITLFTK
->UniRef90_A0A506TYF2 Sigma70_r2 domain-containing protein n=1 Tax=Pararhizobium mangrovi TaxID=2590452 RepID=A0A506TYF2_9HYPH
-MTRKNMHINKRINFVIERRFPSFYEEIENVLDQAVDKYQTQNIRDPRIISYIISKCDTDTAVLVSRENDVDLLNDKDKISKDEKINKYLEIFEEYESRIHSFSSEELNAAYKEEKKLEENENLREMMAWDERQEFSDPMASADFDTWLSMATWTVDEAVSLSLAKEPGTVDRSSGFYKFSLKTGSPFISEYEKRTDQLSRAIKAQDLDKPLRPEAVMAWFQGQGMQGAFGGRVHHIARYDEEVEVLRRENERLKRLVTSPEKLETNSVLGLYRLCLGMAICRYEYRTDMRNGAAKSIAGEFAEVGLSITDDTVRKHLQRASKELGFEWKTRSPFEVRSKLRAKPKSD
->UniRef90_UPI000A646756 hypothetical protein n=1 Tax=Colibacter massiliensis TaxID=1852379 RepID=UPI000A646756
-MADIKKVINEKKEALRQICKGFTSNNTGGCCGVSLPPEEQAELKRLKEGKT
->UniRef90_A0A7L5ZNR0 Tetratricopeptide repeat protein n=1 Tax=Exiguobacterium profundum TaxID=307643 RepID=A0A7L5ZNR0_9BACL
-MLARLAIALFWAAIFFGLGAWSGGHLRPIGDALVTGXANTGEKAVRLWTWARHGAPDAAPDASPATTAAALVDKGRAAFARGDLQGAVEAYREALELRPGDADILGELGNVYYTSGQTAEAALAFHAAAEALIDSGRIEAARALLPAVRAAAPTLAADLDTRLAAAAPVTQ
->UniRef90_A0A4T2C462 DUF445 domain-containing protein n=2 Tax=Subtercola vilae TaxID=2056433 RepID=A0A4T2C462_9MICO
-MKLLATGLLVLMAVIFAVSFALQARYPWLQYVRAASEGGMVGALADWFAVTALFRRPLGLKIPHTAIIPTRKNEIGESLGEFVEENFLSDAVVQEKLASVGVSRVVSGWLSQPANAHRLTNEIAGGLTGALSFLSDDEIRSVIEGLARTHLVGRDWSPQIGELASSVLATGHQHIAVDLLVDKAEQWLAANPESFTALVSKRLPSWLPSFVDRLVDDRVYREALKFVQSVQANPGHPLRKALDEYLLRLADDLQHDPAMMKRVEALKEQVLDDPRLRELAALAWQAIKDALTASLENPESALRLTIESTLVDVGTRLASDARLASTVDTWVANAASHLLASYRHDIAAVISETVSRWDGKEASQKIELQVGRDLQFIRINGTVVGSLAGLAIFAVAQGLLSAF
->UniRef90_A0A2M9FV78 Enoyl-CoA hydratase n=1 Tax=Minwuia thermotolerans TaxID=2056226 RepID=A0A2M9FV78_9PROT
-MNTTSEVAVGRVDGVVEGGIGWIVFDNQRRHNAMSMAMWEQLSEVLDKHVADPEVRVIVLKGAGDKAFVSGADISEFEKRRSTPEQSDAYSDAGTRAYTALADCPKPTVAMIHGYCLGGGLAIAVNCDIRIAAEGSTYSIPAAKLGIGYMVAGVERLLNLVGPAWTKEIFFSARRFEAAEALNMGLVNRVVPLENLADDVLTTAKQIASNAPLTIAAAKMAVDELLKDSANRNLGACERAIAACMQSSDFVEGRRAFMEKRPPRFTGA
->UniRef90_A0A2D7S292 Cysteine synthase n=1 Tax=Flavobacteriales bacterium TaxID=2021391 RepID=A0A2D7S292_9FLAO
-MSNNIKEDLLLFNELVDVFLEEERLKPVTEYIEPNNVQQLLDIKLENNGLSKDKFKEALKQLILNTPKSSSKLFFNQLFGGRHSKAVLGDLLAAILNNSMATYKIAGPQVSVEKEILCQVYKLIGYNKNPGGTFPTGGSMSNFMSLVMARDKVNLEIQQKGITRKLVAYTSENAHYSVSKNASFIGLGKSNVRYIKSDLYGRISVMEFEKQVEKDLKNGFTPFYLNATAGTTVLCAFDNVNELSKCCKKNNMWLHLDGAFGGSVIFSDKYKRLVKGVNLTDSFCFNAHKTLGAPLSTSILVVKDKQDLYNSFNSKANYLYQTHGNEFNLGQTSFECGRRNNALKFWTMWKAIGLKGIASIVEEQFQLANAARKYIISNQDYSLYSFDDSLSICFNYKNFDPEDLCTKLFEMNSLMVGYGTFKKNRFIRLVIVNGENSLDDVTRFFGILERFTEEHQEHIKKI
->UniRef90_UPI001867027B BppU family phage baseplate upper protein n=1 Tax=Staphylococcus cohnii TaxID=29382 RepID=UPI001867027B
-MAIYKNKDITTNIESEKLSINNSNTSFYTEDKGSAALRIFIKYRDGAFNLNDTNLTPTLDLFHNDGSIWRDEPLEVIMSDKGLLQYNIPDNVIAHAGLIKAKLFLRNAEQSVHVANFTFDIKDSGIEEAVAKEINVNIVDDTVKRIMNEQPELFKGEKGDDANPEDVKVLLEPYVDEKTNQEFEKLSSAKQVDGEVINARGSDKSLKSRLENPNYVPTKDEMNTKVIATHYDKKPMVTFIDDDGRTEVLQKWEPILQEKGNKLTIALVSSWIDNKESTVIKWEDVYRLKEQYGVEFVNHTYEHKHAQQLTDAEVDAEFRKNKEVLKREGLTHDIIVQPYGENTDSVRRISRKYAKANVSVKEGVNTLPLDTYRLFRISLGEDLYTTFEQYKAILDEAISKNAWVIFKSHSQYTSFDENQLQLIRQIIDYCRENGFIEATMEEGLRDRGNLIDVGDYTLKAKDSDYFILDKEGNIHSRKFAKNYYTLKYNTVDFNTPITNFEDMTTSTLAIVSTNSQGFPNNASGQLLTTKSESLVLSYQLYLPNNSNEIYKRRWNTKTNNWTEFELITPAMKELKTRHYAGNVDLNGQNTVDVVITNSVLDTMNFNTGDVISATVETPLPNGIMYNVFITEKNKITIRYSNVTTEKITIPATYFNFRITYK
->UniRef90_A0A7J2S7S4 DUF5050 domain-containing protein n=1 Tax=Thermoplasmatales archaeon TaxID=2268204 RepID=A0A7J2S7S4_9ARCH
-MRRSYVKTIKSNSKMMKNTSLICISLLLINVLGSTGVLQNCGKKEEQVYFNFISRSMPHGRIIFQSLRDAPLGNPNSIKKYWELYSMDVDGSNVTRITRNLYWEHQPDISPDGNKIVFAIHYNPSIDTKETDSGWEIAVMDIDGTNLTRLTSNDKLDACPHWNHDGTKIVYVSDTYGNFSCFDIYIMDPNGENVTKLTNAGIGEFYADPSFSFSDGKSKILYIHSKGYTSNWDIYMMNEDGSDQHLILSTNNKYLAYHDPMFSPDDSAIVFSAKLNENGNHGIPIYKIFTARVDGSNIRQITDNDDESDVVPQYSPDGGKIVYFTWKWNGVVFERKIRIINIEGTNERIISSFSPEEMPSWYPRYIRIEKPVEKHLYIADREIIRLLKNTVIIGKITIKADAYDENGVEKVEFYIDDELKNTDYIMPYSWLWDEFAFGMHEIKVIAYDNEGNADTDEMEVAIFNF
->UniRef90_UPI001D13EC9B DUF485 domain-containing protein n=1 Tax=Saccharopolyspora sp. HNM0983 TaxID=2781240 RepID=UPI001D13EC9B
-MRPPVAAGPPDYRAVVDSAEFQQLRTRFRAFVFPMSALFLAWYLTYVVIAAYAPAFMGTPVLGLINVGLLMGLGQFVSTVLIALGYRRYAERRVDPLIDDLRADPPREGDR
->UniRef90_UPI0021BCFAD5 translation initiation factor IF-2-like n=1 Tax=Macaca thibetana thibetana TaxID=257877 RepID=UPI0021BCFAD5
-MALNSGRRKEATLQKGVRTALEHSQERSLGGRPEWLRGPGGPGGPRSPAGQPLQPAGSDSRSSANTALGATPTSTRGHLPSLPPPDLQDRIYPGRPPARVSAPSRLGLSPPCTEMAAAGSLLPQPVAASSGPGWPRPPCVSRGTHCAVPVPPVLS
->UniRef90_A0A4U3CDX7 ATP synthase subunit b n=1 Tax=Blastococcus sp. CCUG 61487 TaxID=1840703 RepID=A0A4U3CDX7_9ACTN
-MNILAAEQSVLVPPVGEIIIGLIAFAIVLFVVVKFVAPRFEQVFQARREAIEGGIERAEVMQAEAKAALEQYRAQLAEAREEAAQIRDAARAEGQQILEELRAQAQEESARIVARGEEQLATQRQQIVQELRGQIGTLAVDLAGRVVGESLADDARRSGTVDRFLAELDGMSAAGNGQGGAVPAGESNR
->UniRef90_A0A450TCR7 Uncharacterized protein n=1 Tax=Candidatus Kentron sp. FM TaxID=2126340 RepID=A0A450TCR7_9GAMM
-MDKKSPFLAQFLARMSAFERENTMFLLVFHPVSADVIFWECTPFSVLLPGHFLFFSHVFGPPSLPQGAKYHSLGLWR
->UniRef90_A0LFP1 Ketoisovalerate ferredoxin oxidoreductase, delta subunit n=1 Tax=Syntrophobacter fumaroxidans (strain DSM 10017 / MPOB) TaxID=335543 RepID=A0LFP1_SYNFM
-MNKAREDKFTQARSALCKGEAGRTGDWRSVRPRIDHAKCIPSKNRRPSCFICWLYCPEGVVKRSIPVEIDLDYCKGCGICAEECPGKAIEMVEEHEEA
->UniRef90_A0A351GGH7 TonB-dependent receptor n=1 Tax=Bacteroidetes bacterium TaxID=1898104 RepID=A0A351GGH7_9BACT
-MVKKILNLILFLGLSFLSVAQTTTVTGTVKDTTGQTVIGAAVVVKGTNNGKITNENGAFSLNIQDPKTAILQVSYSGYKTNEVAVNGGKNIEIVLRENSLGLSEVMVVGYGTSTKKEFTGANSKVDGEDLQKLNIPRFDQALQGQVSGVNISTNSGSPGGGASIRIRGLSTFGDNDPLILVDGVVFDAAGLNSLNPDDIASVNVLKDATAGIYGVRAANGVILIETKKGKRNSKPSISISSYFGVQSTSRKLDLLNATEYATLKNEMFANGGDDVPFSNVNLLGEGTDWQAEVFQNAPIQSHNITISGGSEKTTYSIGGSYFTQDGIVGLDKSNFTRMNARVNLSTQMSDKLRLTSVFLYTKEQRSTLRENQIGSVLYNTVNAFPTDSVRTSDGRYSYLEEVSDIINPIAQMENTFNEANVNKFVGKEELAYDITDNLTFTNRLSYNYAIVDDKVFSPLVWYGPGKAPNTALNEDLDPTSVEIAPGTSVDRGASVYEQRASYSDLNFESFLNHEVRIKSLHRIKTTAGLSVFTRNGQAVNGTAYNIPNNDLEFADISANLAPGGYLNNTGSFQFQERLLSTFIRGEYGYGSRFNGSFILRRDGSSKFGPNNRYGIFPTVSGSWVISEEKNYAIDRMKFLKLRVSYGISGNDQIDNFAYRGLLNGEGHYVFDDIITQGVAIGRASNPDLKWETTRQFNIGTDFTFLHSFDVTMNYFIKNTRDLLFQPEVSAVLGTYGAGSFPPFINAGDVSNKGFELEVGYKTKSSKIWNLSTGLNATFIRNKVIKTPKGVDFLPGASFGVGGGTATRFQEGYAIGYFIGYETDGIFQSQEEIDNSPVVQEGAKPGDLRYKDINNDGKISFSDDSDKTQIGTPIPKVTLGFNVKVDYKGIDLSGNLFASLGQQIVRNYERQQPYANQLAYNINRWTADNPSQEYHRLTTDLTRNTVFSDFYVENGSFLRLRNLQLGYTFNPLLLKKAKIQSARVYISANNLLTITQYQGFDPDIGSSGGTLAAGIDYGFYPQARTLMTGLSIKF
->UniRef90_A0A565C3H5 BHLH domain-containing protein n=1 Tax=Arabis nemorensis TaxID=586526 RepID=A0A565C3H5_9BRAS
-MNLLNSDDNLSMIEALLTSSDLCPLTPPNLSLETTLQKRLHAVLNGTHEAWTYAVFWKPSYYDYSGDSVLKWGDGIYKGDDGNSPRRRMKTTAEKDHRSNVLRELTSMIAGEGFPVMSDGDNDVEVTDTEWFYLVSMTWSFGSGSGLAGKAFATYDPVWVTGSDQIYGSGCDRARQGGDLGLQTIVCIPSDNGVLELGSTEQIRQNSDLFNKIRFLFNFERSKDFSGAPSLMPNELENGNLSXXXXXXXXXXXXXXXLVYKQIQNSLIQDLNFSTATFTSARDIPGEILSFGDDGIRISENPNHNSYSDQIPNEAGKISTGGQKFDSSYQFNIDDSDQYKIDDSILVLENKRPKKRGRKPAHDREVPINHVQAERLRREKLNKRFYALRAVVPNISKMDKASLLGDAIRYIHELKSKAKNTESEKNAIQIELNKLKEAITGRRENAISSVGEKDAITEIDVKIIGFDAMIRVESSKRNHPGARFMTALMDLELEVNHASISVINDLMIQQATVKMGSRSYTEEQLRVMLISKI
->UniRef90_U4LXJ3 Similar to Putative alpha,alpha-trehalose-phosphate synthase [UDP-forming] 106 kDa subunit acc. no. O14081 n=1 Tax=Pyronema omphalodes (strain CBS 100304) TaxID=1076935 RepID=U4LXJ3_PYROM
-MSTGTTFVAALHLPYTVQFRSKESRPSSSKSLSSRSLPPPIPETRANVPQLTLSTLRNDLAKTPYGEPIATPMPNLLESLGHGNIATSPTPPLTPTTTTAEELFFRVPSTNSIALGSPSDPSMRRIPTIPAARPKATPFLPGGENVVGRGYFDIPVTEKLAPATRPSRRRSSVASGASIYSQQEQDDWTIEKTDFGNGGLKNAVEASQDASENVYVGTLGFGTDTLDEATKVAIEGRLREDHNCLVAYTSNADFDGHYNHYCKEVLWPVFHYLIPDHPKSKAFLDHSWQYFEALNRSIADVIIKDYKKGDTVWVNDYHLLLVPKMVRDALGPDARIGFFLHVGFPSSEIFRCLAHREKLLAGILGATMVGFQTEEYVRHFLQTCSRLLNVEVQENGVLLDSRLVNVVTLPIGIDPIQLAEKRNEQEVTNWTEQLQQRYAGKKLLVARDKLDGVRGVKQKLLAYELFLKKNPQWVGKVVLIQVALTTTSIVESQSTVSDIVTRINCTYSTLDYQPVVYLHQDITYHQYIALLQIADALVVTSLRDGMNLTSHEFVYLQDKHHAPLILSEFTGSAAIFGGAEISVNPWDHSMCARALERALTMPSQEKEERWKKLYARVTGHTAAHWFSEFLSKLEDAWEEQQRCGSAHIPRLSAKILAEQYSAARKKVFFLQYEGTLVSWGSSSSTVVTSPQRIMDTVNDLMEDPTNVVYIMSSRTVQDLEQIFLRVPSVGLFAEGGCFLRPFGKEKWIRLADPELPWKSSVRDILDYYVERTPGTWIEERSCSFIWHLEKAEDKASAQRQAGDCGNHVNGSCESFDVHAIPVTGGLLVECRRWNKVNACRLVLEHMEERKWVVDWILVAGSGRDDEGVFEWANGLRVEEGEEKEGKSKREVVTVRVGTGHTQAKATTNGVAGVVTALQRLANISVNEST
->UniRef90_A0A8S0R5G1 Eukaryotic translation initiation factor 4B2 n=2 Tax=Olea europaea subsp. europaea TaxID=158383 RepID=A0A8S0R5G1_OLEEU
-MSKSPWKNIGDWAAESERAEAEEREQAEQAAAAAQAGGGNFPSLKEAVNTKQKKKTKMSLQEFTMQPSYGSGSAPPSRGLTQEEMFRLPTRPKERPPDEMQHGRHGGGFPSYGNRPGSGYGDGYSDRPTREFENRRSYGGFEDENRRGPTRVSGFDQQTSRADGVDNWASGKKALPDYTSGPAGRPARYSSLGGSSDGISRADEVDSWVATKKPFVQSQPPQQARSSGFGRLEPDRWTRNEGERQRLVLDPTKSDRGGDADVLVKVNKSNPFGAARPREEVLAEKGLDWKKMDMEIEVKKQQHSVSSSRPTSSQSSRPGSTHSSRSESLTTLQSGMAEGAAKQTPKMNPFGDAKPREVLLEQKGLDWRKIDLELEHRLVERPETEEENSLKEEIEHLKKEFLEKSGEEQSCLQDLILKREKDLELLRRELDDKVRYSQKVFERPGSGAGRDAISIERPSRLAPYEEPRAGFPERPPSRPGAHEDPRAGHSERPRSRPGLSEKYRPGFPERPSRPGLYEESRSVFTERPSRSGSYEETRAGFSEKSPSLSQAYQDPRAVDYMERPRSRGTVNSRTRPIDDRKASQGGGVRGFVGSRDVDRSRPRW
->UniRef90_A0A1V5GBZ2 DUF11 domain-containing protein n=1 Tax=Firmicutes bacterium ADurb.BinA205 TaxID=1852897 RepID=A0A1V5GBZ2_9FIRM
-MATFYNQATLSYNGTVTNSNITAGEILEVLSADKYAVTSTYSADSDIVYIISIVNSGSSPVSNITVTDDLGAYPFGEEEDYAVPLTYNEGSVGYYINGIQQTPPTVADLSPLTITGITVPAGGNALIVYSARTNAFAPLGAGASITNTASISGTGFGTITASEQITADNAIDLAITKALSPSTVEANGEVTYTFVIQNFGGNAVTPADDVIFSDSFSPAIGSLTAEYNGTAWYEGTNYRYSETSGVFSSLSGQITVPAAQFIQDPATGEWSVQPGISTLTIKGNIL
->UniRef90_UPI001F36B3C5 hypothetical protein n=1 Tax=Alicyclobacillus tolerans TaxID=90970 RepID=UPI001F36B3C5
-MTTVFFKNLQINSVSQTSGVFHGDNYLGGFVSKTKSNEGFGEVSGQKNVVVECLDLVLDLDTLDTVVKKPPSPSSE
->UniRef90_W8SRT6 Transcriptional regulator, LysR family n=4 Tax=Alphaproteobacteria TaxID=28211 RepID=W8SRT6_9RHOB
-MDWDKLRIFHAVADAGSLTHAGDTLHLSQSAVSRQIRALEEGLNTTLFHRHARGLILTEQGELLFDATKHMTKRLDAAAARIRDSEEEVFGELRVTTTIGFGSLWLAPRLPALYAKYPDLRIDLMLEERVLDLPMREADVAIRMKEPSQADLIRRKLMAINMRLYASPSYLEKNGTPQSLEELSEHRLISQNANSAQVSAGAVLVRELTSYDVGSHLTVNNYFGVLQGVIHDLGIGVLPDYLTQDFPEMVRVLPNVESNEVPVFLAYPEELRQSKRIEAFREFVTEEVIAHRKRLKESLGAQAG
->UniRef90_A0A0S8K1U0 Acyl-CoA_dh_1 domain-containing protein n=1 Tax=Anaerolineae bacterium SM23_84 TaxID=1703388 RepID=A0A0S8K1U0_9CHLR
-MRVIHEYTRGCGRREEGGVYLVSELSPLGTLPPWVAIEPPILYGGEHFRGYIYVNGDQLLAGDEEGTWLIGPSLDRLIGEEWKLTLGMPLKIRQKFGICAGLKTVEDVTEKLADLGLYSDKMYPEIATDIHRALEYLKQLDTPAEGAASQLKMAQRLGLSGAQILARCWLIARQLLWDLPLRDPHNDIRVELRKDLARVMVLVGALEDARDLLTGRSREARATGRRSGALTEANTAAAPAPPNGGPARVERWPSVWLHAGRILRAAYSSSIVARSPCFVINSSHFCQTASWNCSRVPRSARLSASCRKSAHAGNGNLIAS
->UniRef90_A0A5P8D839 Lipoprotein n=1 Tax=Mycobacterium phage Marshawn TaxID=2652423 RepID=A0A5P8D839_9CAUD
-MNRTLKGLAAAVAAATAVTVVGCSSDADVASDNLSKASEQFEVSRRIVAINGVTDKYLFVVEGRCSLEYPENRTEIVCKLDDGNLIKHVVRQSDNVTLIMEQTNGTAVSTDHYRVIFKPEVIIPNVDRP
->UniRef90_A0A1X7C2T9 histidine kinase n=4 Tax=Cellulosimicrobium TaxID=157920 RepID=A0A1X7C2T9_CELCE
-MLRRLSVRGKILAALAVPVLVLFAAAAIISAQAISTARDASQTSALVAALAAQDAAGTEIAAERTYAFLDARGASEDAEAQMMAQREKTDKALDVRDRAYERLDTSALDPRVREALADTIADRSDLQSVRQAIDRSGLGQLQRNSLYGNLIDDALEVPRTLADTTPDRGLAQYLDTYVLLDELLAQQALEQPVAGAVLQAAQVGQESIATNQQAAVLVTTGDELAKRTQTAVRQLPGELRLETATATYNQIRQNLMGSRPGATPASQAAEWPALSQADRDQTAPVRDAVRVETEKKASDLAAAATTRAVVTILVTLAAVILSVLVAGLIARAIVNPLRRLTDAAEDVRDQLPKLVEQVAVPGQGPGIDLAPIAVESTDEVGQLATAFNDVNETTIRVAREQAALRGSIAEMFVNVARRDQVLLNRQLAFLDDLERSEEDAGTLSNLFRLDHLATRMRRNAESLLVLAGIDSGRRVRQPMPASDVIRTASSEIELYDRVRLNLVVDPLMLGHNALNAAHLLAELLENATMFSEPHTPVEVTTGRDENFVYVTVRDHGLGMTPEEIADANRKVATHAASDVVGAQRLGLFVVGRLADRLGAKVRFSAGGDEQGTEVVVSFPAVLFVPDSSVPLPQPTDPLETSTQAAAQQLAGPAAAPALPAPEAPAPFAAPAATASFPAVEPEAPAAVPVDIDALTDGTTQTGMPRRRSRTVDPAAAAPSASFASGPQTGAIVLPPLATPALPDQLPAADEAWTPPAEVADAGSALPSRARPAATPVEPVSAEIPVLDVSTRSALFSSFRPMGDRPAENPVELPAAPDVTATDIPLVTEVPTGSAPVPQDAWSPQPAPAEEPVAQAWPAPEAQAWAPEQAWAPEQPAVAAEQPPAAPEQPAEQSWAPAQAADTWAPSSVGDESLDATRVVPPVPAEPAEEATVARVPLAERAPAVSAPAAPEARPAEDVPVVESANAAAPAEDIPAELTFEALPRFEELMADLPTRRSLRESQARKRGLFGRRPRTTATPQARPAGTSASAAPAATAPAPAGPSAPAPSAPAPAAPAAAATPTAAPVAPSIPVAPQEPAAPARTSAFAPRADQPAPAASFAPPTTPAEEQVPASPEAAYTPLETAYSATEAPAAPQPSYEPSYAAPEQAYAPDVAPSEAGREPAPARDSWAPEPADAAEPAGYGPPSPLVRRPVSETTLEPLEPGYISDSVEARSDWMASAVLYEEMSTLLQGSTDFQEATLADSNDGIYQPLKVDATTASGLARRSRGEEREGYVDRFTARIDRDPEQLRARLSAFQSATARGRVEGQDETSSTWDPQAVDYVPDSAPQAR
->UniRef90_A0A6G5YKI4 Haemolysin XhlA n=1 Tax=Bacteriophage sp. TaxID=38018 RepID=A0A6G5YKI4_9VIRU
-MDYMDDYRQQVTDARFQDLKEVINTRFDDMNSRLVTISKQLDNYETKDHAASEINHLAFRCDDLEQKLQDAEDELAKFREGIYRKAALLTTVLSSIVSLVFGILQFVIH
->UniRef90_UPI00190A6268 non-ribosomal peptide synthetase n=2 Tax=unclassified Streptomyces TaxID=2593676 RepID=UPI00190A6268
-MEKYRSLPAVGDTVVQLPDAGIPELFERQAAMTPDAVAVVSGDASMTYGELDAGASGVARELLRRGVGPESVVAVAFPRSPELLVALLGVLKAGAAYLPTDPDYPAERVGFMWGDARPVLLLTTAGTAVDLPDSCPRLTLEDLSPADAAPGGRTPYGGPAVHADQLAYVIYTSGSTGTPKGIGVTHRDVVALAADRRWYGGAHERVLLHSPLAFDASVYEIWVPLLNGGRVVVDPDGDLTPGGLSRLVADHGITAVFLTTALFNLLVDEDVRCLAGLREVWTGGERVSPAAFRQAVDACPRTTFVHVYGPTETTVFAVCRPMDPARPVGGDVPIGRPMDHTRTYVLDGSLRRVPPGAAGELYVAGAGVARGYLNRSALTAERFVACPYGTAGERMYRTGDVVLTTPDGELVFQGRADAQVKVRGFRIEPGEIESVLLAHPDVAQAVVTAREDRGAGTGKQLVGYVVPAGAGDGGAALDSASLVGELRTFVAERLPEFMMPAALVVLEQLPLTPNGKLDRTALPAPEFTAMTYRAPRSAGEETLAGIFAEVLGLGRVGIDDDFFTIGGDSIRSIQVVTRARAHGVSVSAGEIFRHRTVTGLAEAAAANARDGGSPVLAELDGGGVGPMPLMPVAKWIEELGPGFDRLSQAMVLELPAGIDRGGLAATVTAVLDRHDLLRARLIPDGLLVDPPGSVDADRLIRDVTCDGQWSGEPWRHLLVGELDEAAGRLDPAAGVVAQFVRFEPPSGPGRLLVVLHHLVIDGVSWRILMPDFAAAWKRIRAGEAPEPAGTLTSARRWAHALVDDAAGAARMAELPLWRSTVDGPDPLLGSRRLDPAVDVRSTVEKVRVLLPVPVTEALLTAVPTVFHGGVNDGLLTGLALAVGQWRRTRGVDEPSTLLTLEGHGREEDAVPGADLSRTVGWFTSVFPVRLDLAGIDLDEAFAGGPAAGAALKAVKEQLLAVPGRGIGYGLLRYLNPETAEVLRAYPMGQIGFNYLGRFSAADMPEELRGLGWTGTAELAEFTELAELDAGHDAAMPALSEVDINATVTDTAAGPRLGAVFGAPTGVLSPAEVRELADLWCAALRGLARYAAEPGAGGLTPSDVPLVSVGQREIEAWEKVYPALVDVWPLTALQSGLLHHSMLAGADADTYQVQLVFGFEGAVDASRMRAAAQALLDRYASLRTAYVPDSAGDFVQLVVEGVTLPWREVRVAAEAYEEFLAEERSVPFDTAAPPLLRTTLVRIGAERTELVLTAHHVLFDGWSEPILLHDLLCLYASDGSAPADPPSFKDFLAWLARRDQEQSVRAYARALEGVTGPTLLAPADPATGAAGFGELDVDLTAAEAQMLARRAADLGTTLNSVVQAAWAVLLAELTGGSDVVFGATVSGRPPTLAGVDSNVGLFINTLPVHVSCAPWKTLARVAADVQSAQAALLDHHDCGLADLHEATGLGVLFDTLVAFQSYPFDNTSIAEASSAAGLGVPSFRSIGGSHYPLVVMAEQDPHLRLRLQYRHSAFERDAAGRMADRFLRVLRAFLADPAGRVGAVGIRTPDERNTSRPEPGTPEVSVPELFVRRAAAMPDAPALVVDEVPVTFRELNARADRLAGACLGLGLGPDSVVAVRCSDPVDQVVALLGVLKAGACFLPIDPEDPPQWSDAVVRDAGPRAVVVDQEAAGPSWGVPRIRVEAPAGDSGPADGGPTGPALPGHMAYVDYVPDESAQPCGTAVTRGGMAARVPRFETFFPGETLAVGPGTRATDLLLALCAGRTVEVRKEAPSAHGDAPDSDRVQVLSPSLAPAAAEAVGELYVTGDVGRGHPGRPGLTAQRFVADPYGTAGSRMYRTGVLGPQGAPGTPAVGSPEVRTGRRAVESVLLAHPGVARAAVVTDGPGLVGYVVADGQAAVVADELRAFVARHLPDRLVPSALVEVDRLPMTANGRLDRRRLPAVAGEQHRTARGEREVLLSRLFSDVLGREEIGIDDDFFALGGNSLLATRLIGRIRNELGVEVSIRSVFQYTTIAELDAQWDDIATASGPRLRKTSRK
->UniRef90_A0A4R1FKP2 Lipoprotein n=1 Tax=Nocardia alba TaxID=225051 RepID=A0A4R1FKP2_9NOCA
-MGVVSEIEGSRRRIMMSRSVSYTLPAVVAVALVSAGCGSATPKPAPRAASATLTTTSKPPLTTSRSATPTTTAAKSAAVGVCVDKTTNVRVADDRCDTGSSTHSRFWYQHTDTFVYPAIGVAVALAAGSFLRPTTGEVFDRGAPTDGGTVARGGLGKARPDSSGGGGSAGS
->UniRef90_A0A5E4BYY0 Calmodulin protein 4-like n=1 Tax=Marmota monax TaxID=9995 RepID=A0A5E4BYY0_MARMO
-MTTVTIVNQVELAVTRVQGGRLTSPRAFPSLLTLLFGGFLDRNGELDFSTFLTIMHTQIKQEDPKKEILLAMLMADKEKKGYIMASELRAKLTRLGEKLTQKEVEDLFKEANIEPNGKVKYDEFIQKITLPVQDY
->UniRef90_UPI00101D8BA6 hypothetical protein n=1 Tax=Sphingosinicella sp. CPCC 101087 TaxID=2497754 RepID=UPI00101D8BA6
-MTDGARLFLDAWTHARPQPPARRAATLLARLGGEAEPERLPIGVRDRRLLELFAGMAGAHLAGVAECDSCGGAIEVAASVDMLMSGPPTAPILVEIDGERVPVRFPTTHDVLAAVAAPDPSRRLAELCAGKGELGAGEAEQVGAALLAADPLLDPQIAVTCPDCGAETVFGFDVGAFLWAKVEDRARHLLSQIHRLACAYGWTESEILKLPEARRAAYLELSAA
->UniRef90_A0A8D2QA42 NME/NM23 nucleoside diphosphate kinase 3 n=1 Tax=Zonotrichia albicollis TaxID=44394 RepID=A0A8D2QA42_ZONAL
-SSGSKPSIRTNSFPSPCLEASPPELNLSSCLPGLVPSAQLQHPGSQRSVCSVQASEELLKEHYSALRDRPFYGRLVKYMSSGPIVAMVWQGLDVVKTVRSMIGETNPAESRPGTIRGDFCVEVGKHSCAKPARNESAFPEQKFSLLCSDQS
->UniRef90_A0A8D2AEW9 Espin n=1 Tax=Sciurus vulgaris TaxID=55149 RepID=A0A8D2AEW9_SCIVU
-MAHSEEAALLPGNHVQNGCAADPKASRELPPPPPPPPPPLPEAQSSLPPAPPLPLEGAGSGQRRSSSSTGSTKSFNMMSPTGDNSELLAEIKAGKSLKPTPQSKGLTTVFSGSRQPATQPDTQVPPVSPAPSRARSPTPPAVGPQPLLNGSIVPAPPAIPAPGVQLNVETLVPTHDEQGRPIPEWKRQVMVRKLLVKMQEEEEQKRKEEEEEARLASLPAWRRDLLRKKMEEEREQKRKEEERQKQEEIQREKEQSEKLRTLGYDESKLAPWQRQVILKKGDIPKY
->UniRef90_UPI001E3E9EE4 hypothetical protein n=1 Tax=Mucilaginibacter roseus TaxID=1528868 RepID=UPI001E3E9EE4
-MMISIAACKNDNDNNPEPSVESVTIDGTSYPTVKIGKQQWISINYSGKGGVFYNGDRDVKYGKLYTRKEAQAIKLQDGWRLPTRSDFVKLASNFPNISADGYVNLKPEGVLKLASSSGWRDKSGDNSSGFNALPAGICKVEADGDNDYSYRGIATQFISSTTETFNDNGATRARTTTFFLQIANSSSQPPTTETAGGVVDVIRADDYRFSVRFLRDID
->UniRef90_A0A7W0CLV6 S1 motif domain-containing protein n=1 Tax=Nonomuraea soli TaxID=1032476 RepID=A0A7W0CLV6_9ACTN
-MLSIQQRIADELGVREGQVSAAVDLLDGGSTVPFIARYRKEVTGALDDAQLRTLEERLRYLRDMEERRAAILESIESQGKLTDELREQILAAETKARLEDIYLPYKPKRRTKAQIARELGLEPLADALLADPSLDPVATAGPYVVEGLADAAAALEGARAILIERFAEDADLIGSLRERMWSYGQVSSRVKEGKEEAGAKFSDYFEFAEPFTKLPSHRILAIFRGEKEDVLSVALEPEEGDEYELRIASRFGVSDQGRPADKWLNETVRWAWRTRILVHLGIDLRTRLWQAAEDEAVRVFAANLKDLLLAAPAGARTTMGLDPGLRTGVKVAVVDKTGKVVETATIYPHEPKRQWDQSLAVLGALCQRHGVELIAIGNGTASRETDRLAAELVKHMPGITKIVVSEAGASVYSASEYASKELPELDVSLRGAVSIARRLQDPLAELVKIDPKSIGVGQYQHDVSETKLSRSLDAVVEDAVNAVGVDVNTASAPLLTRVSGIGSTLAASIVAHRDGNGPFRSRTALKDVPRLGPKAFEQCAGFLRIPGGDDPLDSSAVHPEAYPVVRRILTSAATDLKTLIGNTAALRSLKPADYVDDTFGLPTVTDILGELEKPGRDPRPAFKTATFKEGVEKISDLAPGMILEGVVTNVAAFGAFVDVGVHQDGLVHVSAMSRTFVKDPRDVAKPGDIVRVKVLDVDIPRKRISLTMRLEDETEQPTSGGAAGGGSGRGPRQSGGRPGGPRPASQDGRSTDTRPARDGAGGDASGRGGSRDGSARQGAGSGGAGSGSGRDGARGNRDNRGQRGDRSGDRAGDRSGDRAGDRSGDRAGDRSGDRGNDRGNDRRGGQRSGGDRRQDRSAPSGAMAEALRKAGLGGGSDTR
->UniRef90_UPI00068DFD47 tetratricopeptide repeat protein n=1 Tax=Herbidospora cretacea TaxID=28444 RepID=UPI00068DFD47
-MNPPEASGEAAVHNEITNGVFFSAVIQGRDITVQLPPQITPALSGMPAGSPAFTGRDLDLRDVLDVLAPVGTTDGSVPSTAVSSAAVVVTAVGGMGGVGKTELAIQAARTALDCGWFPGGVLFVDLFGYDKARRVEPGEALGGLLHALAIPGDHIPSDTEDRARLYASVLAAYAAAGRRVLVVIDNVCSAEQARPLLPTDGSSKAIVTSRHTLGMLGARLLDLKVLAEAEAVALLTRAVDIARPGDTRVSDHPEEAAELAHLCGYLPLALQIIAALLAENPVRPLSTMIEELADESSRLDEMEYGEVAVRAAFELSYRHLAAQEARVFRLLPVNPGPDVSTQAAAVLTGLEAVPARRLLERLARAHLIEHGLGYGRWRMHDLVRLFAEEHGRADAAADGRADALTVLLVHYHSTATAACHHLAATDRDAAKGGFGGRGDALTWLDAERANLVAATHTAAGHDPHRAIARDLPIRLGPFLQLRRHFDDWVALTTAALDAARELGDRRGEARASGDLGLAFRYSRRFDESISAHREAARIWRELGDRGGEARALSNLGLALQEVRRFDDAVAANQESLNIQRELGDRSGEARSLGTYGNALVLKRQFDEAVNVYRKARDIFHAMGDQSMEAAILANLGVALHELRRLDEVAVTYQDALRIYRELEDRHGQARTLTNLGHLLLEEQQLNLNDAVTNLQDALVLFRELEDRHGEARALNNLGLALQGLGQPNVAVTVHQQAVNAFRELEDRHGEAQALCNIGRSLLELMRFDEAIPHLRSALDLFAKIEDRHGAAQVLINQGVALTGLRRFDEAVAAIEEARDVFRELGDQHREAIALTNLEEIRRHR
->UniRef90_A0A7C6BF04 Glutamate synthase n=1 Tax=Rhodobacterales bacterium TaxID=1948890 RepID=A0A7C6BF04_9RHOB
-IMMRSGAKSVTLITASGLPGPDTAPDDLINVVPCELEEAVEEGLQIIDHATVGRLIMKGSRVTGVEIVSLKKEVGKDGRKRRVASFGTERVVSVDMVVPCVGEQVDPEAFEGYIDGAYFWPDNPYGRIAEGVYAIGDARGNRGTVAAAIGDGRIAAEAVAAELSGEIDPPADERPVMELDGLNTAYYASTARVKVGKLAVSERTFEAEIEGAISRSEALAEAQRCLSCGNCLACDNCWTMCPDNAVIKTTELARDGSHYVFDYDYCKGCGICAQECPTGYIQSVPETS
->UniRef90_UPI0008A66679 hypothetical protein n=1 Tax=Streptococcus sp. HMSC072D07 TaxID=1739495 RepID=UPI0008A66679
-MVKSLCISDSREGIIEHIPKGAIAYYLPNPRGRKKVFFTKETLLLMYHLIRLKYFSREMILDQYFILTGKELYNDALYSLIGNSRMPICQFSSNYNIGRTKFMYVPKVFASWLLSVIPQIPELAELTEVTEYDGSHYSLITNRMNGGTYGIKKINLHDANTRSLALKIGRALIENKVGVSPSELNITYFFPTNRELISVVPDAVIFVQGERYYIEYDRNTEQHFKLLGKIIGYFEESYYKGDTIFFVFDNISEPKDNYLNARVMNFISNVHNVKFKDSGLTYYEQAQQNKVSLYALPYVNAISQIAEVIHLELDHDSTKEDIELVDRFKNEHLVPYEVLSADLVDEPDSPFDLTLTYIDDFFDKKEMPLLKLNYGDISNPDYFENLYKEYKDVYPQCGIIFSASISKQYYPIPHDDFFLAIYIR
->UniRef90_UPI0019112769 ABC transporter substrate-binding protein n=1 Tax=unclassified Pseudomonas TaxID=196821 RepID=UPI0019112769
-MTKPLETLWYTHSPVPTGLGIAVQSGRLAEAFTPFGTNIQSLRESSEREVREAHYDHHLQNSVRHGGNIPAIWAYASGVETRVLGLSWSDEVQLILTTEESGVRSIRDLKNRRFGIPKWANVQIDFTRAQALRGLENALKLEGLAVGDVELVDYPYGGTYSDDAKRHLYGAEVSLGTSRVSRRNNELIGLLRGDIDAIFLKGAHAVHLAHEFGLRVVVDTGSHPDPLIRSNNGTPRTLTVDRHLLENHFDASRTLVDTVLRTEQWAWANPVETRRFLARELNTSEYWVAAAYGDDAHRRLRTALDSRSIEALQDFTEFLFRWGFIPRRFDVKAWIDFRVLESVIGSTSRLAV
->UniRef90_A0A7C7DC20 2-isopropylmalate synthase n=1 Tax=Firmicutes bacterium TaxID=1879010 RepID=A0A7C7DC20_9FIRM
-MRQVFIFDTTLRDGEQSPGVNLNVEEKVEIATQLAKLRVDVIEAGFPVASPGDFAAVEAVASQIKGPTIAALARTMEKDIDKAWEALRYAERPRIHTFIATSPVHMRYKLRKSPDEVLRMAVEAVRHAKSLTNDVEFSAEDAARSDRGFLREIFEAVIEAGATVINIPDTVGYSTPWEFADLVSYVKANTAGIDRVTISVHCHNDLGLAVANSLAAVTAGATQVECTINGLGERAGNAALEEVVMALRTRKDYFDVSVGIDTTHIYRTSRLVSSLTAVFVQPNKAVVGDNAFAHESGIHQDGILKERTTYEIMTPESVGLPESRLVLGKHSGRHAFSEKLKALGYSLTRDEMEKAFNRFIELADKKKQVSDRDIEAIVEDELVATPGFFELEYIHVISGNHAVPTATVRLKTVDGSVEEAACGDGPVEAVFKAVDAAAKLETHLVSYSLNAVTGGKDALGEATVRIKDNGDTYVGRGTSTDVIEASAKAYVQAINKLLHNRRTFSKAAAPAGAAGVSRPVQDALGTSGS
->UniRef90_A0A8H6QPS6 Uncharacterized protein n=3 Tax=Aspergillus TaxID=5052 RepID=A0A8H6QPS6_9EURO
-MAPTKEAASSTSTSTSTSSSSPSSCPTNSASDANTNISDHGSGDSKTLAVGVGVGVSLGVVSLISLIWGVYERRKRQQLLNSMPSMMPMNSDPYAPPAVAKNQYTEPQELAP
->UniRef90_A0A6P6W929 uncharacterized aarF domain-containing protein kinase At5g05200, chloroplastic-like n=4 Tax=Coffea TaxID=13442 RepID=A0A6P6W929_COFAR
-MAGVSLMRGMVNDGCLSIFHHQSRQLAPVTVRVSSRSRSTAARKLQFLSKRSSFYARYSQSRDIFTSRVQDRMEKLPKLVEDIVQTSLSTGPRGALRLAQGIQAVLGVGSEWLADLSKTANSSTTLPTEMQLGLLSPLYLRRLFERMGATYIKLGQFIASAPTLFPPQYVQEFQYCFDRVPAVPFADIQAILREELGQPIDAIFEYVDPTPLASASIAQVHGARIRGTQEDVVIKVLKPGIEDTLVADLNFVYIVARILEFLSPELNRASLVAIVKDIRESMLDEVDFKKEAANIESFRRYLEAMGLTRQATAPKVYLQYSTRRVLTMERLYGVPLTDLDSISALVPSPEASLITALNVWFGSLLACETFHADVHAGNLWLLRDGRIGFLDFGIVGRISPKTWAAMEIFLQSLATEDYNSMASALIDMDATNKDVDSMAFARDLEKIFSSIQDLDTEIVVATARGPNTSTTAVAANVIVDERQMNALFLDLVRVSESYGLRFPREFALLMKQLLYFDRYTRLLAPNLDMLRDQRITIVPNQRSRRIY
->UniRef90_UPI001C62E845 hypothetical protein n=1 Tax=Qipengyuania flava TaxID=192812 RepID=UPI001C62E845
-MAIASVWVLSGGLGGGSLLTWVVGLPGFLFFGGAMVGFVAALFDRRVKVSVSPQGLVVYPHSPRPIALRSIKRIGTQQSQVRILLHKPSKYPVEGRWRKALIAISSGIQRANGDVWMFCQLYDCSAREMVDAIRAARPRTKFEQEIDAVVASWDENGGPYGDAAHG
->UniRef90_A0A1E7NDJ8 3-dehydroquinate synthase n=37 Tax=Actinomycetia TaxID=1760 RepID=A0A1E7NDJ8_KITAU
-MTDTTVRIHVGGSAGHDPYDVLIGHQLLGELAPLIGTRAKRVAIIHPEALAATADAIREDLAGEGYEAIALQVPNAEEAKSAEVAAYCWSVLGQTGFTRSDVVVGLGGGATTDLAGFVAATWLRGVRWISMPTTLLGMVDAAVGGKTGINIAEGKNMVGAFHPPVGVLADLGTLETVPRHDYVSGLAEVIKCGFIADPAILDLIEADPEGAKSPAGPHTVELIRRAIQVKADVVSGDLKESGRREILNYGHTLGHAIERNERYKWRHGAAISIGMVFAAELGRLAGRLDDETADRHRTVLASVGLPLSYRADAWPKLLDAMKIDKKSRGDLIRFIVLDGLGKTSVLEGPDPSLLVAAYAEVSA
->UniRef90_A0A1E3H4Y8 2-keto-3-deoxy-L-fuconate dehydrogenase n=1 Tax=Methylobrevis pamukkalensis TaxID=1439726 RepID=A0A1E3H4Y8_9HYPH
-MTDRLKGKTAIVTAAAQGMGRTAVLAFAAEGARVLATDVNAERLAALADVPGVTTRLLDVTDGAAVAALAAEAEAPDILFNCAGFVHHGTVLDCDEAAWDFSFDLNVKSMYRMIRALLPGMLDNGGGSVINMASVASSVIGAPNRFVYGASKAAVIGMTKALATDFVARGVRFNAVCPGTVESPSLEGRMRALGDYETTRAAFVNRQPMGRLGTAEEIAHLVVYLASDESAFMTGQAIVIDGGWSNT
->UniRef90_A0A374BYN1 ParB/RepB/Spo0J family partition protein n=2 Tax=unclassified Firmicutes sensu stricto TaxID=84086 RepID=A0A374BYN1_9FIRM
-MSEGKMNIGSAEGDQVLELDINRLRAFKNHPFKVTADMSMVELKDSIEKYGILNPFIVRPVPEGYYEIISGHRRKFAAKQLGYTKVPVIIKVMKNDEAIVAMVESNLQAGLIFV
->UniRef90_A0A254RGW8 Endoglucanase n=1 Tax=Fibrobacter sp. UWR2 TaxID=1964352 RepID=A0A254RGW8_9BACT
-MSFKKLITTSTASVIALFIAACGDSDSGLRPVNENPDTPSSEAAVDPSSSSVADTSAQIPPVTGTGLLIDDLEDGDGSTLIGSGWYTYDDHDNGGASVITTPNVTEKGDPLPTATDNGSLYAFTVNYTLDKGDYAYDPYVGWGLLVPDAIDCSNFGGISYWYKGGKHEIHVETTDVTDYDVHLATVPASREWKQVSIRFKDLAQGGWGEEVAFDPFHIRAVSFQAKGDKVTDSLSIDNLYFQDTSEVEKDKPDMTIMDPIIPTVVIPEDLTISSPLQEKAMKYLNKGINITNWLEENKAYFKGKFKFDESDVKLMADNGIKSLRFPIDLDSYATNRDEFVADTTDTVELKFDDENLFAVLDSFVEWTGKHNMSFVIDYHEYDNSYNITSSKNARYIKMMANVWKHVAAHYASNEREDIFYELLNEPDMTNGAVKSPAWHAAAQEDVDSIRTVDTKHTIIFGDAEWYSISVLSKSEPLNDDNVIYAIHTYEPFIFTHQSASWAETKTIKNLMFPYDKEKWSEYSADFGVTKSTPSHIKNSLKNYNRTGSMEAILKSVVPAKKWAIEHNVPVIINEFGAYNLKTDKQSVLNYMSAMRTISDTLQIPLTHWGYTGGFALFDSEDGVKGTKLIDGMKEAYGL
->UniRef90_A0A0A9IMK9 Protein Iojap-related, mitochondrial n=1 Tax=Arundo donax TaxID=35708 RepID=A0A0A9IMK9_ARUDO
-MPSVEGQQAGKWVVIDSGSIIIHALEERAREYYDLESIWSKEVSSNISVQELETSLVKTRRRNHSQKPMKSI
->UniRef90_A0A4D4MEH6 Mrr_cat domain-containing protein n=1 Tax=Streptomyces avermitilis TaxID=33903 RepID=A0A4D4MEH6_STRAX
-MHQRGLPRKSSHPRAESAPGGPGRAARDSKGAAAYRERKLHKLRNKLTLAEVDRLLTIQETRWMQDMQDGHADGFGATNVWFPSTPTQAIDWRACEHIAAEHLRALGIADAEVTPARGDAGIDVRSEIAIAQVKHQRTPVGRPALQNLVGAAGPAHRGEIKPLKFFYSTSGYAKPAVEYARVNDVILYVINPATGCVSFVSTLYATSVSMPGLIR
->UniRef90_A0A3B3QJW8 Cingulin like 1 n=5 Tax=Mormyridae TaxID=31092 RepID=A0A3B3QJW8_9TELE
-MEMESYRVGGISGGSLPPAYLAHECPSRPVSSGPGRYGLSIRVQGIGGHPYVVLNNREREPSPCKELESNGHSADGDPAEQYGQDRYTPPWEQHPDDSLVEYRSHKQMLFAGSHNGVTEFQESQKKPSTLLNFQRHPELLRPYDPENNSLNLEDLPVLTPRPASLSETGSLPCSQLTRGMSPSLDKPGTSATPVYQDRFPQQSEAQVQSLPRRHAPSPDRPAFQVQPETQEMLLPEPTPQSRQPVRPEAQVQQKPQLETQVQSPPHQQAKPQKPVQPTPQDQQKPQTEAAALAPSAPDAGQQARVAPPASTSTGSSLERSRRKPDVLLLRRHDSSGPVLQSQHSSHSSSSPSSTSRPLLGDPLESLGSDPINRHQNRRYIPFMPGTGRDIDTGSIKAVEELIDKFDGKEGLQRRGRAGRRNRINPEERKRSRSVDSAFPFGIRGDTDYLEEFSKNQGRSTEHVLRPSQLRQLKGALAQDFSGPTSPPRGKDGASAVARGRSAPGSPQGTALHSASSALGCRTAVSRSSTLPLESKGGDEPKSIRSFKVLTGMAAASPAVSMISSSKKNEADNPVTPDLLKDQQTLSQQTNEETAKQILFNYLKDGNPDNDDTTKRKVNLVFEKIQTLKSRAAGNVQGDNNPPEAASEVKALQDQKNQLEKEVTVLKKQLEEETKKTAGPTEVQENAGMRDLRMELVRSMEECARLQELLSKAEEELRTTMEELFQVKMEKEKHQTEIRDLQDQLSEMHDELDGAKRSESEGGEQEDVLEEMMQLKLDFQELLQVKEEQEELLRRRERELTALKGALKEEVATHDKEVDTLREQYEEEIRKLLSCVEDAKQNNVSVCREKQEVEAAKGVAESRVERLSLETERLRRRVQELENEVAKLNRIIDESKLQEGRLTDHMRHLEKENSLLGDSLAEVREQEEAMSRANRALTTRLEDVQRNLTKLTQDHKDLNEKLKEERIQKEQFKRTKDEIEDERRLLDRTVEKLQKEMCDMVEASQTSTQDLQVQIDEYKEKNRRELAELQRQLQERGVELENSRMATRKLQEEVSHLEEDLKQCKKERDEAVLREKKLELKVFDLEVELENVSHSKQDRPRYSKITEDRITQLEMDLEEERNNGDLLMDRIEQGRKQVEEMRNELLQERAMRQDLECDKVALERQNKDLKSRVTHLEGSQKSNKESLVSQLEGRIQELEERLEGEERDRANLQLVNRKLERKVKELMIQVDDEHTALQDQKDQLHLRLKALKRQIHEAEEEIERQEHGKKKLQRELEEQLEANEQLQGQILGLRNEMRRKNTTAPSLKDLDDNDDDMSTDGEIYYRSASGYKRSNHNPIS
->UniRef90_A0A3P9PT27 Chromosome 11 open reading frame 87 n=1 Tax=Poecilia reticulata TaxID=8081 RepID=A0A3P9PT27_POERE
-MLAAPAASHCVKCVTTIRFTHFSPALPDCFIVAEASGLPAPPQRCLGGLQPNNGTCAEQLSVSLFPPLSSTLALLVLVAVLVGIILVSLATFLFHKRKLRNRKIQRAQEEYERDSRSPARAGPGAGEPARPCVIVRPVRRDEKPSRVTGCVRVAAEPWPRSTGSPHGRQKKPSGIQYF
->UniRef90_A0A183N228 Secreted protein n=1 Tax=Schistosoma margrebowiei TaxID=48269 RepID=A0A183N228_9TREM
-MGQGLELHDFISLFIEVFDFLLLLLCTVRHGWGVGQVLIANFFSTFLVNDSLFLLEVCKIFEGISTADDLFTLPILNGDE
->UniRef90_A0A2U8W4D6 DUF2092 domain-containing protein n=2 Tax=Methylobacterium durans TaxID=2202825 RepID=A0A2U8W4D6_9HYPH
-MSTAEPTVVRPAPKFCRNVSTRALPRACACTSIPRGARPRSGSGRQSGGSNAAALRRPAAEARASQPRCPRDREETMARPRDAIGLLAALVLCMTAPERAAAQQPAAAQPAQGVEPAAVALLKAAGDTLAAAKSLRFTAIAVHDVPNAEGQSIFYTVRSRVEFRRPDRLRVVTDGDGPSREFIVDGRTLTLFRPEADTVATAPAPASLDAALKAEVAATGESQAFADMLLTNPAQALTNGLTRAFVVGRSRLVGGVETDVVAFADRDAQAQVWIGVQDRLPRQLYVTETGAPGRPRNAVTFSDWMIDPPIEDRIFSTAHTEGARSVPFPNPDF
->UniRef90_A0A419WT42 Uncharacterized protein n=1 Tax=Marinifilum flexuosum TaxID=1117708 RepID=A0A419WT42_9BACT
-MNKNTKVIEKYYEQIKANIELGLSPADFANKCVSDYVLIQDNEIKRKREEREKKKKNKIIKKQKEQAKTNIQEREKDLARTILYTKKMVKPITNTSEIDSKNANINPEQRRANKIAKLNINSLSSKMHVTDEVKDLGRLSTKEFDKNTVEGAINSLKMASRMLDLMRGGDDDSDEDYDDDIDE
->UniRef90_A0A6S4NGA2 GRAM_POS_ANCHORING domain-containing protein n=2 Tax=Lactobacillus johnsonii TaxID=33959 RepID=A0A6S4NGA2_LACJH
-MPTDAEIIQAIGGLKSGDVYINGFTNGQMPVNVGSYQVKITDQLLQRLQAAFPDYDWDAVSGNNGTARSGSSDSDPIDARHEPATYVITPADTTVTINGAEHIKYGENSTIQYGSDNGYSITITAPVKNETTDNEHEPIYTDLKLETGDLEFVTTPGNVGTYEVKLSAQGLKKLQALTGSTNYSWTQASEARANFFVDQMPVTITVGGNEQNVTYSSNDWLKAIKENPQGYTLTVMTENGTTLNYQAKDGDLIFSQTPGDVGSYQVVLSAQGLDNIKQALGTNYAYPQAASDVTTYGTFNVNQGEVTISLDGSDSKIYDGKTTVPADLNIGKYNLTYSAPVYAPDGSPQTIKLTSDDLQFANGDPINAGTYTVELSPAGQAKLKNLTGNNGDNYKWIFNTQATYTINSATDASASLSGSNQMIFNGSPVTTAEINNGGNIVVNLNFPGSTENSIYHLQDGDYIWNDGAAPTNVGTYTIKLTQAGLAHLQAAIDQYAGSGNAKISADSLTGSATFEIVPKSITDVTISGKDQEKTYDGQAASLDVNDLTISATNLVTDSPLSMKDISASDFDWYDAQGKKLDAIPADAGTYEARLKPSALQALQKDNPNYSFNTASGTIKYTINQKAATDTLDGNGNKVYNGQETTVSDVLNSITWTPSGIVDGQSLDLSKLSDADYAWYTKNADGTYTEMAGLPTNAGTYYLKLKDSSIAKIQVANPNYSFATGAISGEYTYVITQANAVITLPNTSDQTVTWTGNPATIDPANFIPEITTDNPNEKTIVLPSTLQLTASDYEFSQNGKVISAPSEVGTYQVRLTEAGWQKVQNAIAENTNYTWNYQGEGNYHIEKATANVTLDGSASTIYTGNSVVIPATAGVVNGINVKLSNGQTYVLKPEDLEFVNDQGNQIPAPTDAGTYKVRLTKIALDQIRNIESNHYNYTYNNDAVDFTIEKANADVITSGSYDVVYNGQTPEINVDKITNTIATNNDVKLTAPTLTADDYEWVDETGKVITDPVNVGTYYLKLKDSSQSKIANNSNYIWNFKGLASVTISKANATIGFNGNQETSYTGSVIAVDPDKFEVKLSNGQTYQLTDKDIQVIGNPINVGTYKVELSQAGIDSIKAADSNYNYSYDDSQGVLVIVPAKASATISGSQTTQDLELDPHNYSVVLTLNGQQQTITGLTASDFVFSKDGHPAQLTEAGTYDVELSGDAINKIRQENPNYNIDFSSTATFTLENSSQTINYVDADNNVIGSTNISGHIKGTKLPFTPEIPVGWVASDPSDVPTEITINNGTTIIKIKHGTTNVDHNNPVPDGAKTVTGEVIDGAHASDLNQTITRTINVTNPDGTKSTEVQTAKIYRDASYDNVTGEVTYGEWSTGSWKEFSPAEIEGYSASEKVVPAVEVKDGQKNVTVDITYTANEQSGIISYQDEAGKEISTTPLSGKTGETVTVNPEIPAGWELVPGQEIPKTVTATGEGIPTVVIKIEHGITNVDHNNPVPDGAKTVTGEVINGAHASDLNQTITRTINVTNPDGTKNTEVQTAKLYRNASYDNVTGAVTYGEWSTGSWKEFSPAEIKGYTASEKVVPAVEVKDGQPDETINITYTANEQSGIISYQDEAGKEISTTPLSGKTGETVTVNSEIPAGWELVPGQEIPKTVTATGEGIPTVVIKVENSTIIVTPETPEKDIPNGKVPGNPSKNYPEMEKLEVAPTRAIILIKPDGSRENIIQKVIFTRSATFNEVTGEITYSAWKLSNSDDHEALWEAYEPMSISGYTVMNVNQEKVTPDTPNTQLEVTYIPINRPAVTATQTIHFVDEKGKLVESKIYTGKFGEVISVSLSVPKGYSLRNGQSLPTQITIENGMITINLKSESKHPIPNSENKQKPSVTPNTPDAHTDKNNLSSKDNKVVKSHGEKLINTNHVDHVVINQKATRKGTKASSQTYGEKHFESRHMLPQTGAHSENPIFTALGMLAVGLGLFGLSDRRKKKDK
->UniRef90_A0A438IK19 Retrovirus-related Pol polyprotein from transposon RE2 n=1 Tax=Vitis vinifera TaxID=29760 RepID=A0A438IK19_VITVI
-MLVTVFHSGPLILFPNHSGQPHRRRISTTPATFSGEIFQRPIFRETTTYSETPEADLHASGNPTGNRHLTRPLARPDISFPNRGHTQVVGYTDTDWAGLPTDRRSTSGYCVFIGGNLISWKSKKQDVVVRSSAEAEYRAMTLATCELIWLRHLLRELRFGKDEQMKLICDNQAALHIASNPVFHEMTKHIEVDCHFIREKIASGCVATSFVNSNDQLADIFTKSLRGPRIKYICNKLGAYDVYAPA
->UniRef90_A0A847NUJ3 DUF1653 domain-containing protein n=1 Tax=Mollicutes bacterium TaxID=37628 RepID=A0A847NUJ3_9MOLU
-MDIKIKGIYRHFKGHLYIVECIATHTETLEELVIYRNLETNEIWARPSHMFLAEVNKNNQKYRFELQK
->UniRef90_A0A8B9BS21 vesicle-fusing ATPase n=1 Tax=Anser brachyrhynchus TaxID=132585 RepID=A0A8B9BS21_9AVES
-MASSTLYVVFTHRKPPHSPQTSQTAPWPSPEPRPPGGSALPGSPPLAPQPAPEGGPLPAAGSGQLGQLHAHPPVLVGPPPQPCPAAPVMCLLRGISGDDKVPKMLRAGLAQLSLSSMKSAGACIGRPVLLSAAEGRQEVCTAWPTTGFPGGKVGLSETTQKSLKVNLGDAVTVQPVTGAVIQAEEVDVKLRDKDACIKAEEMSVCLLRNLDGKVVLPGNLLAFSFYGKLCNIVVMRVKGTDGTELTAPATSSETQEPDLEKSDLEASALDLSLQLSGLDLDDNPEAVSVSTPSRRMDPASPVPPSSAVASGGHGPAEGALTGSPGVGADLPHGSQPAGTGGREGLLPPGKAGAASSTDSFYYISSRTRIQFVETRTGVADDGDCESRVTYDMIGGLNSQLKTIRETVELPVKQAELFKSYGIPPPRGVLLYGPPGTGKTMIAKAIANEVGAHVTVINGPEIISNPKSVLASTRCRPSIIFIDELDALCPKREGAQNEVEKRVVASLLTLMDGIGSEGSEGQLVVLGATNRPHALDAALRRPGRFDKEIEIGIPNAQDRLDILQKLLKKVPHSLTAAELVQLADSAHGYVGADLAALCKEAGLYALRRALGKRANPSDNEVAGSVMIAFNDFLQGMNDVRPSAMREVAVDVPKVSWSDIGGLEDIKLKLKQAVEWPLKHPEAFIRMGIQPPKGVLLYGPPGCSKTMIAKALAHESGLNFLAVKGPELMNKYVGESERAVREIFRKARAVSPSVLFFDEIDALAVERGSSSGAGNVADRVLAQLLTEMDGIEQLKDVTILAATNRPDMIDKALLRPGRIDRIIYVPLPDAATREEIFRLQFRSMPVSEEVCLVELVQQTHKYSGAEITAVCREAALLALQEDINAKFIMGRHFRYALTVVTPRNPDSLIQFYADYQQQSGLHAL
->UniRef90_L8JDR2 APH domain-containing protein n=1 Tax=Photobacterium marinum TaxID=1056511 RepID=L8JDR2_9GAMM
-MIQPQLKRIAGNAYRMMFGLRPEVCNLQETFYGWVVFVASPGSRKAVVKFSREIGRLAKEVQGLERLSQVLTCPVPEVLFFGREEGHDYIMLEWLDGESAHNLPDDPVALEQFRESYTDVLLALHEHQSQKGFEIGDDEFVPDFIQAYESWMSPVLRYVQSSCSPFSSKLKDAYAGLWENREEILSPLNQIASLVHDDCHVGNVLFDPRTYKVAAIVDPCDVGFKHYELDLFHLYDVRPDLRLVERYQEKKKLAEGFEWRRWFFSLWDDAKHSRNMGWYDERWLVSKVALFEASYAGR
->UniRef90_A0A3M7QPY3 Uncharacterized protein n=1 Tax=Brachionus plicatilis TaxID=10195 RepID=A0A3M7QPY3_BRAPC
-MNLFIITRFSQIDLIKLNSRQNYVKTTFLRNINNFIFKQYNKEFNFKIFIMIILLYIMDTIDRIIRPLVQTAIGAIMQVLPVTIVLVSFWICGHMASIRYM
->UniRef90_UPI0010AADB8D class I SAM-dependent methyltransferase n=1 Tax=Halorhabdus amylolytica TaxID=2559573 RepID=UPI0010AADB8D
-MKRSLDDHAARFDQAADSYDEDGSPEYRAAAALVIEHAAPEPDDVVLDLGTGTGAIALALADDAGAVIGRDISEGMLEQAREKAAERGLESVTFDEGRFREPNVSGDRSVDVVVSNFAMHHLDDDAKREAIETIADLEPRRFVLGDVMLFGEADPEEPFYSPAVDDPATVGVLADALTDVGFALTAVEPVHEQVGVLVAERSEPTEDERA
->UniRef90_A0A8S1JP47 Histidine kinase domain-containing protein n=2 Tax=Paramecium TaxID=5884 RepID=A0A8S1JP47_PARPR
-MENKAIKYLGMGLNVLISVFLALTECFIYELSDSIIMDIVLILCGTFFSWIFITQQLGWKKGDISPFFYWALAIKRITLVGTYRSEFIYFLFGFLNGIYSSKLVVKDQKRYFQKARTSFQVILILVLILFNFLTNTFQYQIILIIFNIILLLLLGIYDNIEIQPINSKQQDFNTDQRNTQAELKKCQTIIQQYQSSKSIWEQFNYLTDDWICKIDINKYKFNRSWESKEQSFVLKNFLQENKTNLNQFLNSLIIVGQSSNASVQLQYELQENNTLLQWLEKNYLQENRQNQQNFEKQKQLKDTKTNKQQVQDDQQSILSPQNDGKYIIQKDQSQDFSRLQATPLNMDQQVFANKKFLQCQLCLNQIIYNLNLSIFLIDDDKSNEIKQQSIIIQMKNIDRLIKSEIIDQQRSLFYRFISRLSFHSSQMLKSVCLIKKSIQLQLKEFDSIKSSNFNSSFNDIVLRKSERHIGGLFNAQQTFANQTSEQNTNQKITSTHSNPHESQILNMQQLQIAYFQQSQEIFKQIEKLNFDLIIMKQNNFNFFELFSHTKLDIEQFNILSSFNIVKDIFQQNPLLNQHNIIITQEINHETQVIIQSDRQKFKQILINIINNSIENFEHNFNIKKYQNYENPQIQQRYLKSKQDLKQQNMIVIKAQSDQDRIIIEIQDNGGGIDEEQLKNRLNECKFGLAASQKLLRYLAYDTRKPLEIINYEKCTTGVKGTIIKFVLPITFDNFQQNEDSNQSESLIISNIRDKV
->UniRef90_A0A7S4ARR9 CCHC-type domain-containing protein n=3 Tax=Pseudo-nitzschia australis TaxID=44445 RepID=A0A7S4ARR9_9STRA
-EEHSETIEEHVAGLDRILEYPRVNEEIEIEEELAEEDSISSEESDSEFSCGETSSDSGIGSEDSWSTYSYNDLYTESDTDLYSELDSDSEESDGSSMKKSRRLYFGGEKGEFENFMIKWKTRGAKKGYSPYIMDKRHEDLPETGLMMDWTGVAKDVKKRQKKALRLHNYCIADLQEACEPWMVTAWIEESIGTTDEKRRAYPFGRVWIVLKAMITHYRGFSMLDINRFDIDKATIKMLPNENPDAIFNRIYAVRQKYAHQKDLQISDSSWVGLAVNGCTEAYRPVFMSAYSQNKHLPPKEIMAKLKDIAQDNFASMVQSKEIVSKFVTSDEVGLFAGIGPKTAKDKWRKGQECYLCGSKKHKAYNCPKKNQTNTGGGNGGGNGGGKTQNRGKSHANVECYYCHKKY
->UniRef90_A0A7K4MZ21 C2H2-type domain-containing protein n=1 Tax=Marine Group I thaumarchaeote TaxID=2511932 RepID=A0A7K4MZ21_9ARCH
-MNFFRRNKEIVITGTTCKFCGMEFSAPDRMVKHMLKAHGKPKKNKGSSCPNC
->UniRef90_UPI00110FA3E4 hypothetical protein n=2 Tax=Streptomyces TaxID=1883 RepID=UPI00110FA3E4
-MSTARYLALIDLLRTREFPAQRRRTESGFSGPGYHTVELSAAGEPAGEPAGEDAADQVEARERCLAEHDALVAVLDGRWGEAQVFGLWSLLERSVGGEAVPAPWDELSAGFDSLHLWRADGRWIAVGLALDAEGPSYALAAVVTGIDPP
->UniRef90_A0A847PHQ1 GTPase n=1 Tax=Candidatus Atribacteria bacterium TaxID=2053509 RepID=A0A847PHQ1_9BACT
-MFLKKQNVLIMGAAGRDFHNFNVFFRNNENFNVAAFTATQIPDIAGRKYPPELSGPLYPDGIPIFPEEDLPELIKKHNINQVVLAYSDLPHQYVMERASLVLAHGADFRLMGPDNTMLKAKVPLISICATRTGSGKSQTTRKVSAILKEMGKKVVVIRHPMPYGDLSDQIWQRFKTYDDLDRYECTIEEREEYEPHIDVGNIVYAGVDYGEILKRAEQEADIILWDGGNNDIPFYHTDLHIVVADPHRVGHELTYYPGLVNMMMADVVVINKIDTADQENIVQLRDHIAKIVPEAITIDAASPIKVDHAELIRGKKVIVVEDGPTLTHGEMQFGAGIVAAQKYGAAEIIDPRPFAVGSIKDTYQKYPGIGMVLPAMGYGSKQMQELESTINSIDVELVIIATPIDLSRVMKIEKNNVRVKYDLQEIGSPNLKEILLQKLS
->UniRef90_UPI0005F56F2E NADH-ubiquinone oxidoreductase subunit 8 n=2 Tax=Myrmicinae TaxID=34695 RepID=UPI0005F56F2E
-MMGPLQIFTLSGKLAPRFLRIAPKGVSVYLSRNKYYYVREDKEQNWTDIMEAASTHMFFHELFRGFGIILSQVFREPATINYPFEKGPLSPRFRGEHALRRYPSGEERCIACKLCEAICPAQAITIEAEERADGSRRTTRYDIDMSKCIYCGFCQEACPVDAIVEGPNFEFSTETHEEMLYNKEKLLNNGDKWESEIASNIHADHLYR
->UniRef90_A0A1G0YLB9 Methyltransf_11 domain-containing protein n=2 Tax=PVC group TaxID=1783257 RepID=A0A1G0YLB9_9BACT
-MSAAEYPETADIETSSDDYAGRFSGPIGEWMLGVQEQIALKVLSDRPGATVLDVGGGHGQLALPLCHRGFKVTVLGSADSCRRRIQGVVDEGLCKFLVGNVVELPFPAKSFDVAMSFRLLPHCERWPTLIAELCRVSRHAVIVDYPTTQSVNAFAPMLFGAKKKVEKNTRAWRMFGQGEIRQAFRQNGFSQLSLRKQFFLPMALHRMLNKPAFSKTAENLCRFLGLTAGLGSPVILKAVWDEDR
->UniRef90_UPI001572454A MerR family transcriptional regulator n=2 Tax=Nocardia TaxID=1817 RepID=UPI001572454A
-MKSSRTLTIGELAQRFGLGTHVLRYWESMGLLEPARRAGGQRLYEHADLERVALILMGKEAGLTLGELATVLSTADPRDHRDLLCHHVEELERRITQARAAKELIEHVLACPHSLAECEHAREHIAARIPPLPRNSASV
->UniRef90_A0A8C2IYT9 Slow myosin heavy chain 3 n=1 Tax=Cyprinus carpio TaxID=7962 RepID=A0A8C2IYT9_CYPCA
-MGDAQMAEFGAAAPFLRKSDIERLEAQTRPFDMKKACFVPDTEEEFVKATIISRDGDKVTCENSKGTTVTVKEIDVHPQNPPKFDKIEDMAMFTFLHEPAVLFNLKERYAAWMIYTYSGLFCVTVNPYKWLPVYNQEVVLAYRGKKRSEAPPHIFSISDNAYQYMLSDRENQSILITGESGAGKTVNTKRVIQYFASIAASPTKKETSDKKGTLEDQIIQCNPALEAFGNAKTIRNDNSSRFGKFIRIHFAASGKLASADIETYLLEKSRVTFQLKAERDYHIFYQILSQKKPELLEMLLITANPYDYAFISQGETQVASIDDADELMATDEAFDVLGFTQEEKNSIYKLVGAIMHYGNMRFKQKQREEQAEADGTEDADKSAYLMGLNSADLIKALCHPRVKVGNEWVTKGQNVQQVSYAVGALSKSVYEKMFLWMVVRINQSLDTKQPRQYFIGVLDIAGFEIFDFNTFEQLCINFTNEKLQQFFNHHMFVLEQEEYKKEGIEWVFIDFGMDLQACIDLIEKPMGIMSILEEECMFPKASDATFKAKLYDNHLGKSANFQKPRIVKGKPEAHFSLVHYAGTVDYNINNWLVKNKDPLNETVVGLYQKSTMKLLSILFANYASADSGELSKEKKKKGSSFQTVSALHRENLNKLMTNLRSTHPHFVRCIIPNETKTPGAMENPLLMHQLRCNGVLEGIRICRKGFPNRILYGDFKQRYRILNPAAIPEGQFIDSRKGAEKLLGSLDIDHNQYKFGHTKVFFKAGLLGTLEEMRDDRLALIITNIQARARGLLSRVEFQKIVERRDALLVIQWNIRAFMGVKNWPWMKLYFKIKPLLRSAEAEKEMANMKEEFLKLKEAYAKSEARRKELEEKMVSLLQEKNDLQLQVQTEQDNLCDAEERCEGLIKNKIQLEAKAKELTERLEDEEEMNAELTTKKRKLEDECSELKKDIDDLELTLAKVEKEKHATENKVKNLTEEMAALDEIIAKLTKEKKALQEAHQQTLDDLQSEEDKVNTLTKAKAKLEQQVDDLEGSLEQEKKLRMDLERAKRKLEGDLKLTQESLMDLENDKQQLEERLKKKDFEISQLNSKIEDEQVMAAQLQKKLKELQARIEELEEELEAERAARAKVEKQRADLSRELEEISERLEEAGGATAAQVEMNKKREAELQKLRRDLEEATLQHEATAATLRKKHSDSVADLGEQIDNLQRVKQKLEKEKSELRLELDDVVSNMEQLAKAKVLVSTLAFLLFSRQLEEKDSLVSQLTRGKQSYTQQIEDLKRQLEEEIKAKNALAHAVQSARHDSDLLREQYEEEQEAKAELQRSLSKANSEVAQWRTKYETDAIQRTEELEDAKKKLAQRLQDAEEAVEAVNAKCSSLEKTKHRLQNEIEDLMVDVERSNAAAAALDKKQRNFDKVLAEWKQKYEESQSELESSQKEARSLSTELFKLKNSYEESLDHLETMKRENKNLQEEISDLTEQIGESGKNIHELEKIRKQLEQEKAEIQAALEEAEGSLEHEEGKILRAQLEFSQIKADIERKLAEKDEEMEQSKRNQQRMIDTLQTSLESETRSRNEALRLKKKMEGDLNEMEIQLSQANRQASEAQKQLKGLHGHLKDIQLQLDDALRSNDDLKENIAIVERRNNLLQAELDELRSLVEQTERGRKLAEQELLDVSERVQLLHSQNTSLLNQKKKLEGDNSQLQTEVEEAVQECRNAEEKAKKAITDAAMMYFLYTLNNGLNNAFSFHTSCMFVRELENEVEIEQRKASESVKGVRKYERRIKELTYQTEEDRKNLARLQDLVDKLQLKVKSYKRAAEEAEEQANTNLGKFRKIQHELDEAEERADIAESQVNKLRAKSRDTRAAKKTSMMNLVQTDHKYHIN
->UniRef90_A0A6G7V9X9 Purine-binding chemotaxis protein CheW n=1 Tax=Caldichromatium japonicum TaxID=2699430 RepID=A0A6G7V9X9_9GAMM
-MSAEHLQEAAVDEEGTESADVHQFVTFVVGGEVFAVDMAPVQEIIRLPAVVRVPLAPSSLLGLANLRGKVLPIILLRRIFGFPEQAHDDATRALVIDVGQPLGFVVDRVASVISVRSEQIEPVAGIQGTFNSELLTGILKDVGGFAMVMVLNFARLVAQEFAEIAQIARGTAMTGGVLDSSADNEDKEASDELQLVSFAVAGQEYAIDITSVQEIVQIPETIVHVPNSPTHVLGLMTLRERLLPLVSLRSLFALPARALDEKSRIVVVALGQAAVGIITDSVSEVLRVPLAQVDRMPGLLAREDALSDITEICRLDGGRRLVAILSVDNMFKHTVVQEALKTVDGMNANTHDEQPGEDRSDEEEQLVVFRLAESEFGVPIESVQEIVRLPDELTPVPKAPAYVEGVINLRGAVLPVIDQRKRLGLPPIERNDRQRIMVFVLNGVRTGFIVDTVTEVLKIPKAAIETAPRLSGEQARLLGRVANLEQQGRMIQLIEPAHLIDTTELADLNT
->UniRef90_UPI001A9564E1 hypothetical protein n=1 Tax=Segetibacter sp. SYSU D00508 TaxID=2810307 RepID=UPI001A9564E1
-MVLITLHEILLVVTAISFLLLPKLFFKYLPSPYEFYCKIASGILLLLVIWIPEPGDQQSQLLLQVLLTLLTTYYMCKNVMEYRKRKTGITHHK
->UniRef90_UPI0020C6B0B3 SPOR domain-containing protein n=1 Tax=Deinococcus sp. JMULE3 TaxID=2518341 RepID=UPI0020C6B0B3
-MIGALVLLLLGGFGTLLLRPQAGTPVSAAADSGTDAPATDTTTLDSVPGAPGSTESTDAATAPVSTTEITAPTGQDSVTSPGSDAPQADGSANPGSVPSTDGADTPVIAAAPIGTPDPTLTDTQTAPQTEDADPASADPASDTPATDPAAPAARTGGAVPTSEQRTPLRSDYRITLGTFGSDAAAQSATQGVGALGYTVYPITVAAGVVAQVGPFADEATAREALADVQRAYPGAVLYPPRDRSLSTPSTPATTGATAETAQTTPAEPATPAPTATTPTYLQVGAFDRLESAQNLVQQLRDLGYNPTVNAPAGKKVTVLVGPYTGDPLTRTETRLQENGLDSFRVR
->UniRef90_A0A2Z6TDT3 Spore coat protein n=1 Tax=Burkholderia vietnamiensis TaxID=60552 RepID=A0A2Z6TDT3_BURVI
-MRALRRSFQPYFQPHFQPHFQPHFQPHFQPHFQPHFQPHFQPHFQPHFQPHFQPHFQPHFQPHFQPHFQPHFDPNSPPYSQPPP
->UniRef90_A0A5Y2QT59 PLD phosphodiesterase domain-containing protein n=3 Tax=Enterobacteriaceae TaxID=543 RepID=A0A5Y2QT59_SALER
-MNQLIHNAEHYIYIENQFFVSAFGEPSVPDNAPYSPEAKEIARLDRIKAVTTKLVYGDSDKQPVNQIAQWLGDRIKNVIYARYTHDFHVCIVLPVHPEGKLDDGAVMAQVHLTRQTLVSGSKSLLNRVRQALWVRQQLDEDPRANWSKLIPALEKRCETEKKYEEISFEACAKYVTLLNLRGYAELAAYPDKKIAVTEQIYVHSKLMIVDDRYVLVGSANINERSLQGNRGYLATVLAGAGSNLALEGTPV
->UniRef90_A0A1J9RUE5 Cation chloride cotransporter n=1 Tax=Diplodia corticola TaxID=236234 RepID=A0A1J9RUE5_9PEZI
-MASRGGSSRMPSRLHSRSNFTTRSAQDDSHQLQRRWSLSQMSAQDEAEPLLAAGPRRRRPVSVPRENRTFGSFLSALFTRRASTRSRSGHRRTRSSGTDRCKPASAPAKLGTFAGVFVPTTLNVLSILMFLRFGFILGQGGLLGMMGLLVACYAINLLTTLSVSAIATNGTVRGGGAYYLISRSLGPEFGGSIGIVFYLGCVLNTGMNAVGLVACFVQNFGSTHGSWANWLPDDFWWQYLWATVVLAVCTVICLAGSSLFARCSNALLIILLVATFSIPVSTLVQTPFSNVKLGIEYTGLSLETLKGNLLPNLTQGAAGSGLKGRETWQDLFGILFPATGGIFAGASMSGDLEAPSKSIPKGTLYGLALTFVTYTIVIISMAASITRLSFYNNDNVIQVVNVSGALVLLGEFASTLFSTLMGVIGSAKLLQALARDKLIPGLLVFAQGSKAADEPMLAIGLTYVLSQLTMLADINQIASLVTMAYLMTFLVTNLACFLLKVASAPNFRPSFHFFNWWTAAIGAIASALTMFFVDGLSASACFATIVLIFLIIHYTTPPKAWGDVSQSLIYHQVRKYLLRLRQEHVKFWRPQILLFINDPRRQYKLIQFCNSLKKGALFVLGHVIVTNDFAGAVPEVKKQQSAWTKYIDFSRIKAFISIVISPNIEWGTRNVVLSAGLGGMKPNIVVMGIYNLNDLRTNPLVDVPSPQPEHTQGTANGTAPHRLKSKGKWKIAEENKLRGQLPTDAIRKESAVTPQSYVTILEDLLLRLQMNVAIAKGFQDLELPAPRPSRLERVLDALHAKSADEEEGTKKYIDLWPIQMSAEVAAPSDGTQSILTTNFDTYTLILQLGCILNTVPSWKRAYRLRVAVFVEYESDVEEERARVKALLYNLRIEAEVMVLWLASGDLQSYEIIVNGQADESYREARQDIEEALREEAWWQDIQKLRQRQTGAITPMEELAQIEGFLETASNWPGTAFRQGDRETKSKRFADIKDMLIERRRTSVGSLKQMGVSMGMRTHRLPPGLDGQESSSDGSSSGGESEAECSDSDRSASSENDPQTESDEGTLSPMRRARSERESTSSFPSTPRQQSQPRRGELLPPAPTAAANSDSTLVTSQPPTNAGSHQSPPTFTSKPVPRTEVAADDGPGPSIMFAEPLSPEEQRERRFGTSIYTRSGSPQVAAPLPGPANPDESGSDSPSTPGSPGAASSSMSQASGFPLQQSVPLSFNDLPCRAQHLILNELIRRESGKDQRTAVVFTTLPSPVEGTCEDEHASVRYLADLEVLCQGLPPVMLVHSNSMTVTTNL
->UniRef90_UPI001F1A8850 DUF6338 family protein n=1 Tax=Pelomonas sp. P8 TaxID=2906762 RepID=UPI001F1A8850
-MNLALPTVVVFILLLPGFIFRSRLKRVERTSLDFSPFGAVVAEAVFFAAVLHAAALLLLFWVTGALPDLALLLTLLAPSPAPLNAIPAIGQHAGLVTGYFGLLLVASWLVPTLTRWLITVGRLDRLGHPLSPIARFHQAPWYYLLTGADFAADELPDYIRVTAVVDVGKGAVLYRGTLEEWFTNPDDGQLDRIVLSAASRRPFELDKPLDGSDGGAERFYPIDGDYFVLRYEHMLSLNVQYMRIIEQPDDDLPDDEEADTPAAQ
->UniRef90_V4QRW5 Methyltransferase n=1 Tax=Lutibaculum baratangense AMV1 TaxID=631454 RepID=V4QRW5_9HYPH
-MQSEILEGYATAGPELIALYEAVPSAEIYALVRDLLPPGPARAADIGAGTGRASPRCWRRPGS
->UniRef90_A0A0D3GCY4 Uncharacterized protein n=1 Tax=Oryza barthii TaxID=65489 RepID=A0A0D3GCY4_9ORYZ
-MNLSATYDSRTSDVESSVVARGDLWRAEASHSSAAAAAPPLFMVQLGPVLFVRDTTLLFPVHLSKRHLIWYGFERKNGVHSVCPAYWSAHRRWFFMSMICLNPFTCSFMDMQFPNGQLRYVAGDGFTTRAFLPLYRGIFQAHVKFPGEKKFSYSFKVSCQMNSKPYLNLLHLNSEVSLLHHIARLVLLTIFFQNRSGGSITPMVQWPDKSLSLGTVQTLSWKRCGLIICPTFGGSRPGLSMELIHSVNENAGVVCGYSHTASPSAYASVSIGRSKLNGSAASSGLVLRVDAPLQSFGRPWFSIQMNSGLEF
->UniRef90_K3XLW2 Ras-related protein RABE1c-like n=2 Tax=Setaria TaxID=4554 RepID=K3XLW2_SETIT
-MAAPPARARADYDYLIKLLLIGDSGVGKSCLLLRFSDGSFTTSFITTIGIDFKIRTIELDGKRVKLQIWDTAGQERFRTITTAYYRGAMGILLVYDVTDESSFNNIRNWIRNIEQHASDNVNKILVGNKADMDESKRAVPTAKGQALADEYGIKFFETSAKTNLNVEQVFFSIARDIKQRLSETDSKPEDKVVNIRQDQGAEASSSQKSACCGS
->UniRef90_A0A8C0C567 Uncharacterized protein n=2 Tax=Accipitrinae TaxID=8955 RepID=A0A8C0C567_9AVES
-MSKQVVNSSETVTPGPNEGTGVVGISPENEPQNAPSQAPAAMARLPRSLSNDNKTLSSEEAKPNDFERTKVGICKLSSTPVQANSTLQRESVETFPCKHTPGAGVAGQAAIPHCKIPALQSTDGDANLNLGKSTLEQNNAKGAWVTLSQSTVVLGTDGNTSVLPGRVEGVSWLLVGFLSPAFNSWE
->UniRef90_A0A2B7X7V6 Replication factor A protein 3 n=1 Tax=Polytolypa hystricis UAMH7299 TaxID=1447883 RepID=A0A2B7X7V6_9EURO
-MSLSTPRLLPEHLHAFAPAPHKSARTVRILGTVSSLRGEHASITCGSHGEVTLVLNRDSHIQMGRVVDVIGKVVEVEGGLGVRVLGAADCGDPKDVDYKIYEELVDVTHRFKEIFYDE
->UniRef90_UPI001663C50F hypothetical protein n=1 Tax=Belliella aquatica TaxID=1323734 RepID=UPI001663C50F
-MKKVLHTLAAILISVVSYAQVGIGTDNPDNSAMLQVASSEKGFLLPQMTSTQRNAVSSPANGLQVYDTTTNSIWFFNGSYWVNTQAMATVGDVKSGLQTNDHSGWVLLDGRSIGTLSDNQKAAASALGLSGTLPNAADAYLVQNGGSMGAISGSNTVTLTQANLPNVSFSGTAASAGGHTHTVDPAPVDTDSKGNHTHTVDPAPVNTDTKGEHTHTGSVGGSNWLGGGTLTGGFNAGTFPFQIPNLTINPAGDHFHTVDIPSTTSSENGAHKHSIDIPSTTSSSNGAHTHDVTVSSGGSATPVNVAPKSLSVNMFIYLGL
->UniRef90_A0A3Q3E9K7 Hydroxycarboxylic acid receptor 1-like n=3 Tax=Hippocampus comes TaxID=109280 RepID=A0A3Q3E9K7_HIPCM
-MDLDLRSTPAPGGGGGGCPPVGIQLEGVILPPVLTVDVVLGLLGNAVALWVFCFRVKSWSANTVFLVNMVAADFLALVSLPLRIDALLRGHWVFGDVVCRLNLFLMFSNRTASIALMTVIAFYRYVKVVHPHHRFNRMSKRQAGILSLVVWLLVSSPRVPMLAYNHIKELFLKKKTSFTITNYFKRYLKRLLAGIVILVETHRVLTVLEFVIALALLVFYSVQISRSLKRRQMGNVAKVRKAMRVCAAVVAIFLVCFLPTTITTLGLWVSRSLRPWDCAAFYALTQLNIVSLSLNFLNSALDPILYVFSSSVFRKELLAAVPPRLRCKRAVEGTSSVSTSQSTGQVELESVKMTAGSEAS
->UniRef90_A0A3N0Y0W4 Complement factor I n=1 Tax=Anabarilius grahami TaxID=495550 RepID=A0A3N0Y0W4_ANAGA
-MPYKCPRQDYHVCTLDGSEYYSMCQTKAISCRSNKPVFSHISTTCRAEEKVKVTVEDSGSHKVVMINTRLGKMFVCGNDWNMAAANVVCRNPLNVARGAAEVTKIKNRILDRDTKWPTECMSVRCTGSELSLAECTIYNPQPITENTVAIAKCYNEPKGAFSSF
->UniRef90_A0A124ILI9 30S ribosomal protein S15 n=1 Tax=Gracilibacter sp. BRH_c7a TaxID=1734398 RepID=A0A124ILI9_9FIRM
-MLTPEKKKDIITKFQQHEGDTGSPEVQIAILTTRINELTEHFKTHKKDHHSRRGLLKLVGQRRALLNYLKKNDVNRYRKIVSDLGMRR
->UniRef90_A0A4C1ZDE1 Tubulin_C domain-containing protein n=1 Tax=Eumeta variegata TaxID=151549 RepID=A0A4C1ZDE1_EUMVA
-MTVSFLCSGGDAPPQGLCFQNLNMRIHSYAHSNIFAEYYTSYVTDALYKQISKPKFSFWARRGKTVVALCVPFGVSPYRAALSSSPYTDREFLDSSVNIMRRAHDQSIGGGSAVWDLTIKRRPLRDRGVRYETCTALCE
->UniRef90_A0A2J6IBB8 Endonuclease/exonuclease/phosphatase n=1 Tax=Marinilabiliales bacterium TaxID=2053303 RepID=A0A2J6IBB8_9BACT
-MKILKLIFFIALSVNLSSQSIMSFNIRYNNPNDGNNSWENRKFELTDLITKYRPDIFGIQEGLYEQNEYIKEQLANYTYVGVGREDGNKKGEFSPIFYDSLKYELIETKTYWLSDTPSEVSVGWDASMERISTFGAFRNINTKDTLYIFNCHYDHIGKKARRKSSKLIIKLIEDKGLLIKNLVVMGDLNSMPEDAAIKILKNKLTDSFEVSNYLKEESIQTYNNFDNQYISNKRIDYIFTRNIYVSSHKIIREKRSNGLFISDHFPVLIQFRNN
->UniRef90_A0A0F2Q2J6 Cupin_2 domain-containing protein n=1 Tax=Clostridiaceae bacterium BRH_c20a TaxID=1629719 RepID=A0A0F2Q2J6_9CLOT
-MNKKIRDEIERSLNLKIIDEQSFSWGESYSLQLESKMDFDKYSKKNSRNVAVVTVKPNIKHESHTHYGYDEILYGLEGETIHWANSKKTYLQKGQLVLIPAEGQHIMVNNSPVPAKFLSIVYPTIPERWRR
->UniRef90_UPI00037CD391 VWA domain-containing protein n=1 Tax=Gilvimarinus chinensis TaxID=396005 RepID=UPI00037CD391
-MANSLIRVSVLLWAAFFCFHSHAQSPSPSAALVDADVRLLVDISGSMKNTDPDNLRQPALELMVKLLSESAYGGVWTFGEQVNMLVPFSRSDEDWQRRALEQTSRINSVGLFTNIGEVLHRATEVPAKTSSADVILLTDGKIDVDKNAGVNSRERNRVLSELLPEIAEKNFRLHTIALSADADSELLQQLSRTTDGHHLVAKNADELMQAYLQIFDQAVPAKRLPLENNRFLVDDQVNEFTALVFRAPTAEPTQLLMPDGKALSASSHGDNTQWYSADGYDLITITNPAAGRWQLKAQESAQNRVTVVSDLQLYVESLPNNLLAGNALTLAYALQEKGNNLTDADFLDLITAEIVVMNVTRDVSWNLALTDQPDKATGVFTHELPTFNERGQYRLRLRVDGKTFAREFQHQLQVGSMFAVQLDKAVQSSQVKYTLNVKTDSEFVNTDKTSVVAHVKHSSGESELRALKKVSDTQWQLTLTPAKPMRTLIELNASGELTDGREFNEVLPSQYVQFPQEGDPLVVQEDSELAMLKQQIETERAALANEERLADTVAKTPAAKSQTSSPVSESQDDKQEAGFESGPDSAEETDEGGINWPMIAAITLGNLLLIGGLYWAYRRFSAKDVQSELDEIEQQLQAAPNEPSGQATEQQKKEAVALDDDNSVSVLDSLDESSLPMDDFSFDDESDKK
->UniRef90_A0A853FEG6 5-formyltetrahydrofolate cyclo-ligase n=1 Tax=Pusillimonas soli TaxID=659016 RepID=A0A853FEG6_9BURK
-MNDSTRNNATPLRTRLKQRRAAMDPVERSRGALLIRGRLYTWLATTRTRLREAGRPVPENIAAFWPLDEEPSLLPLLQQWVEEEGYRVSLPVVTVAGAPLQFRIWTPDAPMQPGAYGIHEPAGEIAPPPDIILVPALGYTRQGDRVGYGKGYYDRTLAALREQGHAFTSIGIAWATGDLSGDSHAPEPHDYRLDSILTDKGWAVPAPVIA
->UniRef90_UPI0021E303A4 FERM domain-containing protein 5 isoform X1 n=2 Tax=Acomys russatus TaxID=60746 RepID=UPI0021E303A4
-MLSRLMSGSSRSLEREYSCTVRLLDDSEYTCTIQRDAKGQYLFDLLCHHLNLLEKDYFGIRFVDPDKQRHWLEFTKSVVKQLRSQPPFTMCFRVKFYPADPAALKEEITRYLVFLQIKRDLYHGRLLCKTSDAALLAAYILQAEIGDYDPGKHPEGYSSKFQFFPKHSEKLEKKIAEIHKTELSGQTPATSELNFLRKAQTLETYGVDPHPCKDVSGNAAFLAFTPFGFVVLQGNKRVHFIKWNEVTKLKFEGKTFYLYVSQKEEKKIILTYFAPTPEACKHLWKCGIENQAFYKLEKSSQVRTVSSSNLFFKGSRFRYSGRVAKEVMESSAKIKREPPEIHRAGMVPSRSCPSITHGPRLSSVPRTRRRAVHISIMEGLESLRDSAHSTPVRSSSHGDTFLPHVRSSRADSNDRVAVIADEAYSPADSVLPTPVAEHSLELMLLSRQINGATCSIEEEKESEASTPTATEVEALGGELRALCQGHGGGPEQQQVNKFVLSVLRLLLVTLGLLFVLLLLLIILTESDLDIAFFRDIRQTPEFEQFHYQYFCPLRRWFACKIRSVVSLLIDT
->UniRef90_A0A485M2C4 Transcriptional regulatory protein ZraR n=1 Tax=anaerobic digester metagenome TaxID=1263854 RepID=A0A485M2C4_9ZZZZ
-MPSKERKLAKKNIRILIIDDEESIRDGCQQILTRQGYEPTATADGMTGLELARTGAFDVILLDLRMPRIEGLEILRILKSEHPVASKIIVITGYGTIPVAVEAMRLGAHNFITKPFSAAELKLAVQDCLSEKSEERPTGDSLSMIIGTSDYVEELKETIRRVAKTDSTVLITGESGTGKELVARTIHSLSARSNKPFVPVDCSSLVHNLMESELFGHIKGAFSGATENRDGRFQTADKGTLFLDEISNISLDVQAKLLRVIQEQEVPRVGSSIPEKIDVRLITATNKDLRVEVQNGTFREDLFYRISVVPIHIKPLREHRSDIAPIAFHYFDIFRSRHGSKAQSLSPEVVKSLTSYTWPGNIRELKNTIERLCVLCDHEEVTLSDILYYGQDTCSKAPVVDPFSGKMTLVEVEKEHIEKALHHFNNQINKTARFLGIDRKTLRTKIRNYGIEIKDDE
->UniRef90_UPI00103184EA hypothetical protein n=2 Tax=Streptomyces TaxID=1883 RepID=UPI00103184EA
-MSAGNNGMSTPEGGDDPFGYLYRPEDGQAPAQQPQQPSYHQVRPVGERRPYGGQRSGYGYPQPQSAPPQHDPHYAAPEAQPGGGGYHSGGPPGPYQNGGEPPRRNTLLIGAIAVVTAVVLGVGAALLFSNNDAGGDDDRADDSSEVNPTPDVPDDEDEGDTDEDGADEDETGEDEEDPEDSGDLPVADFNGADITLSNGAIVGGGQLEGARSSDGSYITGLNNNNSTVSWQFDFDGTPGDYRVYVGYTVEDGDQLMSWAINDSLRGDELEFKDHRKSGAYKDNWTYTWKQVYLNEGSNLLQIGCGGDDTCDVVIDGLVVTPHADGMEPW
->UniRef90_A9YMW7 Ac78 n=2 Tax=Betabaculovirus TaxID=558017 RepID=A9YMW7_9BBAC
-MQQHLDIPFDRLTVPDVVDAIPLKLAYSKESDDNNKPPVVPSAQAVYGSREEKSAQSDMSNVWFIALACITVLVVIMLISYYIVSVLRTNNAPLRDYDDDDFE
->UniRef90_UPI00188515FC mitogen-activated protein kinase kinase kinase kinase 4 isoform X15 n=1 Tax=Peromyscus leucopus TaxID=10041 RepID=UPI00188515FC
-MANDSPAKSLVDIDLSSLRDPAGIFELVEVVGNGTYGQVYKGRHVKTGQLAAIKVMDVTEDEEEEIKLEINMLKKYSHHRNIATYYGAFIKKSPPGHDDQLWLVMEFCGAGSITDLVKNTKGNTLKEDWIAYISREILRGLAHLHIHHVIHRDIKGQNVLLTENAEVKLVDFGVSAQLDRTVGRRNTFIGTPYWMAPEVIACDENPDATYDYRSDLWSCGITAIEMAEGAPPLCDMHPMRALFLIPRNPPPRLKSKKWSKKFFSFIEGCLVKNYMQRPSTEQLLKHPFIRDQPNERQVRIQLKDHIDRTRKKRGEKDETEYEYSGSEEEEEEVPEQEGEPSSIVNVPGESTLRRDFLRLQQENKERSEALRRQQLLQEQQLREQEEYKRQLLAERQKRIEQQKEQRRRLEEQQRREREARRQQEREQRRREQEEKRRLEELERRRKEEEERRRAEEEKRRVEREQEYIRRQLEEEQRHLEILQQQLLQEQAMLLECRWREMEEHRQAERLQRQLQQEQAYLLSLQHDHRRPHPQPPPPQQQPQQDRSKPSYHAPESKPHYDPADRAREWSHLASLKNNVSPVSRSHSFSDPSPPKFAHHHLRSQDPCPPSRSEALSQSSDSKSEVPDPTPKAWSRSDSDEVPPRVPVRTTSRSPVLSRRDSPLQGSGQQNSQAGQRNSTSIEPRLLWERVEKLVPRPGSGSSSGSSNSGSQPGSHPGSQSGSGERFRVRSSSKSEGSPSQRLENVAKKPEDKKEVFRPLKPAGEVDLTALAKELRAVEDVRPPHKVTDYSSSSEESGTTDEEEEDVEQEGADDSTSGPEDTRAASSLNLSNGETESVKTMIVHDDVESEPAMTPSKEGTLIVRQSAVDQKRASHHESNGFAGRVHLLPDLLQQSHSSSTSSTSSSPSSSQPTPTMSPQTPQDKLTAHETQSASSTLQKHKSSSSFTPFIDPRLLQISPSSGTTVTSVVGFSCDGMRPEAIRQDPTRKGSVVNVNPTNTRPQSDTPEIRKYKKRFNSEILCAALWGVNLLVGTESGLMLLDRSGQGKVYPLINRRRFQQMDVLEGLNVLVTISGKKDKLRVYYLSWLRNKILHNDPEVEKKQGWTTVGDLEGCVHYKVVKYERIKFLVIALKSSVEVYAWAPKPYHKFMAFKSFGELVHKPLLVDLTVEEGQRLKVIYGSCAGFHAVDVDSGSVYDIYLPTHIQCSIKPHAIIILPNTDGMELLVCYEDEGVYVNTYGRITKDVVLQWGEMPTSVAYIRSNQTMGWGEKAIEIRSVETGHLDGVFMHKRAQRLKFLCERNDKVFFASVRSGGSSQVYFMTLGRTSLLSW
->UniRef90_A0A0S9PKG7 4-hydroxybenzoate polyprenyltransferase n=3 Tax=unclassified Agreia TaxID=2641148 RepID=A0A0S9PKG7_9MICO
-MSAAFAAASVGLFTPTTDTPGAHTWSSAILLFVIYLALLLRYRVTDEWKDFAHDSAVYPDRPVQRGVVSPRTLFVIGAGAFAVELLGVLLIGGALGFVLYLPVLAYSALTVFEFFSAPRLERHFTLSFVLHEAIYLPLFLWVAVVLGAAPDWRTAAGVLACTALFVSVELARKFSPRFDTEGRVVLDTYSAVWGRGRTLGAMVVLVVLSGVLATTAGAGLASPVIAVVAAAVALARPASDRWVTTVVAIHLPLQAAAMLS
->UniRef90_A0A835JN83 Dentin sialophosphoprotein-like n=1 Tax=Salix dunnii TaxID=1413687 RepID=A0A835JN83_9ROSI
-MDLEHGSGTHSESHQEVIDGTGGSDNEDTYPRLRVRIGSSGRLQIDPEKIEGSESGKYSESHSEVINGSDSDKHIEPKPEFTVIEGDIYMPTIKFGSSYSSSSSSSSPSSSGSSLYDLFDVIPKESADPGAGSADFESSNKPHEVTQPASKDHENGVSIDNSHRSEENEDGSSDHALTPPVSGATCESLAHNMSPKQSPPLQVMERPGGYDPLRIPSSIFENNKGTQPMDWSVASNESLFSIHVGNNSFSRDHVLLFGDPGKSGDITKSGESIMFSPLPPREMVTNDNQSSVPDMETNKQKGGSSGMADNTVKDPAEYQNEEDNTNQAVSWKSPSSSNRSYGSGDSVKSFSFPIKASTLAHIMPKFTFSLLYMDVFIFADLLCEFSPDRNACVLGMLVFYA
->UniRef90_A0A0Q5NNY0 Response regulatory domain-containing protein n=2 Tax=Pedobacter sp. Leaf176 TaxID=1736286 RepID=A0A0Q5NNY0_9SPHI
-MRYKILIVDDDEIALFLHEMVVGDCGPIDDAETFSSAETALSYLGDINDGSCEYLILLDINMPQMNGWEFAEVVKNHPLREKIKIVMVSSSVEKKDIERADSSVVIDDYLIKPLREEQILTLKEQPKFRAFFNDHQ
->UniRef90_UPI001D111BD5 2-oxo acid dehydrogenase subunit E2 n=1 Tax=Haladaptatus pallidirubidus TaxID=1008152 RepID=UPI001D111BD5
-MVEIIRIPKLGLSDYGDLVSWEAEDGEHVTAGDVVAIIESEKASAEVEAPTDGTLLGRYVEEGEEIEIEVGKPLAVIGDEGEEIPDISAIEDGSEVSTEGNSGKDNSSKNRATSSDDGSDVITDVKATPRAKRLATEKDVNLKQIEGTGPQDAVSEEDVQAFLESSDTDTKGDEQEVETEQSSSAGLTVTDSRKLTGTRKTIAKRLSQSAREKPHVMGTREVSVERIQALQSRLSERYGVEVSLNDIILFFVGRVLQDLPEFNAHFEDSQHKLIDEVNIGYAVDGPKGLVVPVIDDVTGRSLAELAERRRNLVGKVLDNEFTTVDLQDGTFTVTNVGVFNMDVSYSIINPPEVGILAIGRRKQAPVERDGEVEFETVVTMSLTIDHRVLDGADSGAFLECLAEYLEYPGNALESVQNEQESV
->UniRef90_A0A7Y3X359 DUF637 domain-containing protein n=1 Tax=Flavobacterium sp. CLA17 TaxID=2724135 RepID=A0A7Y3X359_9FLAO
-MPTLSNLVAPKLGFSNGLVGNVMTGLLSNVISKAVQPNYTAQMNRQADEVGTRLLTTVGYSQSSLMNVSSSTRHAQIRAKVQQLIGSNSSSSWWSSGR
->UniRef90_A0A2H0L707 IPTL-CTERM sorting domain-containing protein (Fragment) n=1 Tax=Candidatus Peregrinibacteria bacterium CG11_big_fil_rev_8_21_14_0_20_41_10 TaxID=1974792 RepID=A0A2H0L707_9BACT
-DADNNGIGDACDDPIATCEGVVLAPNCTTGNLCDNGDTMPGTEVCNIPNGVVEITCEDRPELCTDNCTDPTIVLNISRHTGDLCDTGEFCADGSERSGHWEVGDNCNYYPDECKVECDAFCVPNPNEECVPVTNNGEVTNNGGITNNGQIANNGDTHNNDTTNNGGDKIPAAPDTGCNVSTIDTPLQARDQIWALLMLAMAAGAMGYSKQRK
->UniRef90_UPI0020C3A1E9 DUF2243 domain-containing protein n=1 Tax=Halomarina sp. BCD28 TaxID=2961595 RepID=UPI0020C3A1E9
-MARTTTRRALVAAGVFGFGFSGLIDVLVLHHVLQLHHLVSGLYPMDTLSGLRTNIRADGLFSLAMVGIAGVGAGLLWQSERRTEAPLALRPVAGAALVGLGAFDLFDVLVDHVLLGLHQPTMQGGVYNPHWAAVSLLFVAAGWLLYRSGRDAEDVTRDTAETANDRTE
->UniRef90_A0A6P4XS04 protein timeless homolog n=1 Tax=Branchiostoma belcheri TaxID=7741 RepID=A0A6P4XS04_BRABE
-MDLYMMNCELLATCSALGYLEGDTYHKEPDCHETVKDLIRYLRREDETRDIRQQLGASQIVQTDLIPIIKQYHDDKALFETIIRLLVNLTQPAIVCFGKVPKDKMFRHYFLDVVSYLQGYKVAFADGEVWTVLSRKLYELLQLDWENRQEEDSLLIERMLLLVRNILHVPADPEEEKRTDDDASVHDQVLW
->UniRef90_A0A7C3W5F8 4-hydroxythreonine-4-phosphate dehydrogenase PdxA n=1 Tax=candidate division NC10 bacterium TaxID=2072417 RepID=A0A7C3W5F8_9BACT
-MKRPLIAVTMGDPAGIGPEIVVKALQDEEVMAASRPLVIGDRGVLEQAARFCEFQGKIRVVGGPEEGAYTLGTIELLDLENVELASLKIGAVQGMCGRAAFEYIQKAAELASSGRVDAIATAPINKESLRAAQVDFIGHTEILSALTGATDPLTMFQVRTLRVFFLSRHVPLQRACELVTRERVLSYIQRCSEALRQIGVAEGTLAVAGLNPHSGEHGLFGEEEVKEIEPALREAQRLGCRVVGPVPADLVFHQALQGQYSAVLSLYHDQGHIPTKMVDFERTVSVTLGLPFLRTSVDHGTAFDLAGTGKASAASMKEAILVAARYLRDFRRP
->UniRef90_A0A1G3PK91 DUF4294 domain-containing protein n=1 Tax=Spirochaetes bacterium GWF1_49_6 TaxID=1802189 RepID=A0A1G3PK91_9SPIR
-MKHTLFLLLLLSCFSHLFAAPVNYPEIFGQDFMKALNISIEIKAQVVKLSKEMKADPELVLPAAFPELIRYSLFRDSMELFTLEVFYVNFGSGVNDFSVGIFQMKPSFVEQMENYLNTHDELKMYRPVFVYKFPNDPSAVRKERIERMTKIDWQIRYLVLFSKIAEQVFPKQPGQTKSELVKFYAGVYNTGFWKTKEQILKTMALNIFPNGMSYPGEQNNYSDIALYFFENYWQKFLKDDSIKSFPLR
->UniRef90_A0A6A5RRK3 4F5 domain-containing protein n=1 Tax=Didymella exigua CBS 183.55 TaxID=1150837 RepID=A0A6A5RRK3_9PLEO
-MKETAHAEKLEKANVKELKAANKLYNNKIKEQKREAAAAAKEVRDRKCAEERVAIDARKAQRLKDKQARDAQKASQLPNKGKRKASKAPQAPAAKKRRSAQPRSGAVAAAAAPPRGTHTTRSGRTATLYK
->UniRef90_A0A7W8D7Z3 6-carboxy-5,6,7,8-tetrahydropterin synthase n=1 Tax=Chiayiivirga flava TaxID=659595 RepID=A0A7W8D7Z3_9GAMM
-MPLTIFKVFQLEAAHRLPHVPPGHKCARVHGHSFKVEVHVGGPLDPTLGWVMDFADVKAAFAPLHEQLDHHYLNDVPGLDNPTSERIAQWIWERLQPTLPGLARVVVHETCTSGCDYRGPTA
->UniRef90_UPI001069C9AA uncharacterized protein LOC114541692 isoform X1 n=2 Tax=Dendronephthya gigantea TaxID=151771 RepID=UPI001069C9AA
-MEKDKERSDKNVNEVQPVQTVPVERRVKTKALKGIYHSILMQNSKKTKSIEEPPPVKKQCVSAEEDDAPDDDDVYTTTMIEKQTYCALIPQKFKSLNDLCFSGVLQNCLAVISNVFTPKLAKNGNHFLKISITDPTHYGSYELMWFSKPTEFPNIYRTGEIVLLKGIKCQKYNEIHQILKNFTTNICVIPLDDDPPLMKKARQPLERYESKFGDAIKFLKKWRNSNITATTFSQLDVITTAVEGSSFNFCVKIMKLTELTCDSYCLTVWDGSRPSLQARAREENSNAKANACDVDEEELVDIIVLDQNRSIKKYNLRPLNVLALYDVTLNTDRRLELNMENEESGFTVVKPYCHVARYVPAREQRQEHTWNFKGW
->UniRef90_A0A356NIC5 Probable dual-specificity RNA methyltransferase RlmN n=3 Tax=Verrucomicrobiales TaxID=48461 RepID=A0A356NIC5_9BACT
-MLPSLQSITPEILKSQLVDWKQPAYRGDQILDWVYHKRAVTVDSMSNLPKDLREQLDKNFKCYLPDCMQKQGSDDTTQKFLWKLNDGAFVESVLIPANPALYGEASDRHTLCISTQVGCAYGCKFCASGLDGWKRNLEPEEILGQLLAIEHHFQPKLKQGQGRKVNNLVIMGMGEPMANYENLMKALKIANAPWGCNIGARKITISTSGLAPQIVALSREPFQFRLAISLHGATDEVRSRIMPINRKYPIKDLMDACRQYLNKKGKMITFEYILIEGVNDGQNQIQPLADWARELHAKVNLIPYNTVEGLPWSRPEEDIQESFLEGLLSRGINATLRREKGHDIDAACGQLRLKVEKGLTE
->UniRef90_A0A1V5K701 Cell division protein FtsL n=1 Tax=Candidatus Aerophobetes bacterium ADurb.Bin490 TaxID=1852830 RepID=A0A1V5K701_9BACT
-MAEFSNRFLRGLNAGSVRPARGGANKAVGLILLLSLPFLLVVWFYTQSAKLSYDITELTRERDSLKSQNKMLEMKVQVAMSGSGIEHIARERYGFRPAKPGDVQVIKKEYGALGLF
->UniRef90_A0A8H3UYL2 Carboxypeptidase n=2 Tax=Venturia inaequalis TaxID=5025 RepID=A0A8H3UYL2_VENIN
-MSRFVALIACVFALLNGLSIARETMDERARSSRQRRSEMMTPVRRSPLESRDNSTWRFLNSKSQAYAVDSLPDLDFDLGEMYAGQIPIGNDTSRNMFFVYEPTISEPVDEVVIWFNGGPGCSSLEAFLQENGRFIWGWGQYSATENLYTWVNLTNVLWVEYPVGLGFSTGNVTATSEEETAADFVAFFKNFLDIFAIKNFKIYVTGESYAGRYVPYVSAAMLDENNKESFDLAGALMYDPVIGQYEYVGQTIPAVPYIQEYSKFFNFNQTFMDQLASAHESCGYADFIDKYMVFPPAGVQPWLEGGFNNKSAECDVWDLAWAAAFQPNPCFNVYEISSMCPILSDPLAYPSDLQYQYDGMGGIYFNRSDVKAAIHVSQDLSWSECSGPVFVRSAGGLYGNGDTSLDPIQYVLPKVIEATNRVLVANGDYDFELITNGTLLSIQNMTWNGALGFQSAPTTEIDITLPDLQWQATFEASGLGGYDGPGQGIMGVQHYERGLMWAETFQSGHMQPQFQPRSSYRHLQWLLGHIDTLYVAKAMTNPENEYVSLNKQRCMNEVLVAQADEVKNLLIGAFNTPPGYRPAHAKGTVLTGTWTPTTLPSPLTKAWHIQTPTTVLARFSNNTGIPTIPDTDPNATPKGLALRFNYPPAAADGKRKHTDIVAHSTPHFPARTGAEFARFLKALGEGAAAVDGFLGTHPHTLEFVQAAKPLPVSFGTEAFFGLNAFKFVAGDGVETYVRYEFVPVAGVAHLSDEQARGKGADYLAEEIRERIGRGPVGIKLIVQVAEEGDVVDDITVHWPAERAKVELGTVWLDAVDEEGLETQKKTIFDPIPRVEGIEPSADPILDFRAALYLISGRERRAA
->UniRef90_UPI0003871D39 macrophage-capping protein n=4 Tax=Falco TaxID=8952 RepID=UPI0003871D39
-MAPSDPRSPPERANPPGGTRGGAVRPPGVRLAVRRLHIWRVEKLRPGEVPKATWGTFFSGDAYLVLHNGPDERAHLHLWMGRDSSRDEQGACALLSTQLNALLGERPVTHREVQGNESDVFMEYFPRGITYQEGGVDSAFKPTRPSAGAGPVCKLYQVKGKKNIRASEQDLSWASFNTGDCFILDLGETLFVWCGARCNILERSKAQELAMAIRDGERGGKARLEIVVDGEEPPEMLQVLGPKPTLQEGSPEEDVVADQRNAGAAVLYKVSDMTGRMDLSQVATSSPFSQSLLCSDDCFVLDDSAGGKVYVWKGRKASEQERQAALKVAEEVITRMGHSPRTQVEILPQGHETPLFKQFFTSWK
->UniRef90_UPI002022F6CD restriction endonuclease subunit S n=1 Tax=Pediococcus acidilactici TaxID=1254 RepID=UPI002022F6CD
-MSNKVPQIRFNGYSDAWEERKLGDVGDTFTGLTGKTKEDFGHGSAKFVTYVNVFQNPIATLDQLDAVEIDEKQNQVQKDDVFFTTSSEIPEEVGMSSVWTYDTKNVYLNSFTFGYRPRVSFDLNYMASMLRSPSIRKKITFLAQGISRYNISKTKMLEIEIPAPNLSEQKKSVRSSNS
->UniRef90_UPI001CBE7AE7 immune inhibitor A n=1 Tax=Kangiella taiwanensis TaxID=1079179 RepID=UPI001CBE7AE7
-MKIKLLAGLLAAAIIPSVNAAALESGAQVSPKDPALVNHERIIYWLEKRGELDANATDSQREAALATYLKGVRSNNVALPKIEQARLQRQQTSYLKGESKSHKRTDEKTVKVLAVLIDFPDLKHNAHGLTSGDTDMYYSSYPVSHYQDLMFSTTGFTGPSGQNFTSGYQYYQNESGGTFNFTGQTFGWVTADNNAKHYGQNDPDSNDNDKNVPALIKEAVTKAVAANSINLADYDIEDPYDLDGDGNVDEADGMIDHVMVYHSSIGEEAGGGNLGEDAIWSHRFFVDTNTNGYTIPGTGKKLFGYTIQSIDAATGVVVHEFGHDLGVPDEYDIAGSAVGSPVGYWSVMAGGSWAGEVAGTQPTGFSPYARAYFQSVYGGDWIDEQTVDFKAMATGSQNFDLVEAVNHNGLNQIRIDMPKPLVDFAPPYSGSYQYYSDEGHYLNNALSFDVNIPASGNSVLSMKARWDIEVDYDYAQVLVNGNPIAGNHTKVNNQYHSGVTHFITGESKTISGAEGALGWLDLTFDLSAYAGQSVTVEIKYVTDPAVGGYGLVIDDLVLNNGSDIFTDGAETEGSLTLNGFLRVSDKTDGKAQHYWVQLRSENGQDEGLKRTVYTPGVLVWFADEAYSDNKVEEHPGHGFLGVVDADQNPIKRNGSIASSSLQVIDAAFGLYNQKSYSGDSHLSSTATFDDSLDYSLPQQPESGLVLPTHGLSIEVTAQATNSSTATVKISKATPALTADFGFDIDYKQVAFSNNTKGGDANYTYAWDFGDGSAVSVDANPTHTYAQSGVYTVTLTVTDGEATVDSKSKSVSIADELQAEIVSSVNGAKVSVSGNAVGGSPDYTYSWDFGDGATSSNRSGEHTYALTGEYTITLSVTSSDKQAVEVSKVVQVVAALNASMNTSANGLKVNFTSNVGGGDGNYSYSWNFGDGSSATGANPSHTYASAGSYDVAFTVADSTGVEVTVNKTISVAEKSSGGGGGGSGNILLLMLLAAGLVLRRKS
->UniRef90_A0A0D2KAI6 Pentatricopeptide repeat-containing protein n=2 Tax=Fonsecaea multimorphosa TaxID=979981 RepID=A0A0D2KAI6_9EURO
-MSMSLVHCLSDSVSSSGSFSRTFSRPFSISTSNFSASITSTKRPQRRSTSKSWLEDLSPRFFTDTPIYPDVLRIKPLTSNGAPPQDLSSLRPPPLPFIPPPQSNRNGRITLLQRLRYWWRRAAVMRKFYKQRIAQTRQNRKECALLSKRLPRMFVEHPDRAAIYGGSTFTVNDKSFPIPRISRREFQLLVQYGYDNWGFALAVRALPTSEKPEEDRNRQLKALCNRYDWFARNRNDKLDNVTDNSNLSHTAQAEEVFTLLQRRLLRWHYVVVDDALCKLIPWVPFAWTVYAARFFDRWCADYYRIITADTVLIMRQGGFNTLSADDIYDYCVKCASPTFISYAKQALQDGVNPANEAMRKAMIPVLDARAKRMLSIDWTRLKPHALGRIEPFSRVKDLKQPDSVWGRK
->UniRef90_UPI001CCE8B09 LacI family DNA-binding transcriptional regulator n=1 Tax=Celeribacter litoreus TaxID=2876714 RepID=UPI001CCE8B09
-MSEPDRISSKNLTMQDIAKAAGVSPMTVSNCFRYPDRVRPKTRETVMNVAAQLGYVPNMSAGLLAAGSSQVIGAVLPSIRNSAFYRYVAGLRQAATERGHELITMIAETPEEELSAVQTLLGLRVAGIALVAGPHVADLRQLLALSGTPVVESWGGEDAIGCGVAYDVGAASRELTQHLIKQGRRRIGFVQVLGGGEQRYTMRFPGFQKVMFDAGLADNLVLTVRAADGFGSGARILNEFLSLEPRLDAILCPTDVVAAGALFECQRRGLDIPGDIAIAGWGDYDIGRQLSPTLTTITPFSFDIGAGAVKMLLEGGAERPNSLLTPYALEVREST
->UniRef90_A0A7D6Z791 AAA family ATPase n=1 Tax=Nocardia huaxiensis TaxID=2755382 RepID=A0A7D6Z791_9NOCA
-MAPNHQPFAQVRETHTGVVFLCGERAYKVKKPVVTDFLDFGTAAARERACARELELNRRFAPDVYLGLAQLSDPTGGPDEPVIVMRRMPDSARLADRLDADEEAPELSALAELLARLHDAARRGPEISAAGTPAAVRARWQALLHSLREQPLGALDPDDVEYAELLAGRFLDGRGDLLAQRIAQGRIVDGHGDLLAEDIFVLPDGFRILDCLDFDDALRYVDRLDDAAFLAMDLEFRGHSRLAEDFLREYLRRSGDAPPASLRHHYLAYRALVRAKTDRLRAAQGDPEAGGQARRHLRLTLRHLAAGAVRLVLVGGLPGTGKSTVAAQLGRLTGAEVISSDTVRAELRARGAITGRAGVFGAGAYRPQAKHAVYTQMLERARERLAHGVPVILDAAWTDVAERRRAVRLATDTCSDLVQLCCTCPGTMAAARMRTRAHGDSEATPAIAEAMAVAGEYWCGATLLDTTDTLEHTVAAALREWDAAPLRAPRRPESSSLPSR
->UniRef90_Q31A46 General secretion pathway protein C n=1 Tax=Prochlorococcus marinus (strain MIT 9312) TaxID=74546 RepID=Q31A46_PROM9
-MKKFIKFLFFVFICGLVSNSHLVLTKDDNRSKKEIKLHELPIKIKNSKNNQIQLKTLPLPLIEVAANSVNSERNPFLELNKSIEEIGINPKKFFTLTGIIQTGEQLSAMLKSSDGVNLFKEGENINKNLKIKKISLENETVIFTDGENEFKLEFSEK
->UniRef90_A0A848CYM8 YqaJ domain-containing protein n=2 Tax=Aneurinibacillus aneurinilyticus TaxID=1391 RepID=A0A848CYM8_ANEAE
-MSNLINRSAAEALRRQISEAAEAQRGHEMVSDFLTMMDRWHGSAEVWDDTLEAEILEQQAYAIRRLKVFPPRGTTYFSPSSANSCKREMYVKLTGAARDNSDSQPHQGRWQRAGTAFGDTIQRDLLFIEKHYEKKFGEKPPFVPERTAHGFPMWERFARKFHSVEHRGYTVNFLGQPDGILRYKDGTRVGLEIKSKQTTSAQTTEYSMRGPKEDHVKQCVVYSIMYGVDDYLIVYGNLSKKAWVMTPEEYAKNPDLRAFYIHVSESDRQALLDDFVDVLQAVKDGNPPRLDVEKWTFNNYKTACALSLTDAELEDIRKQVRQVGRSRLPDWKKQAYYDALDFIERVRKEAM
->UniRef90_A0A1G5F3R4 Aldehyde dehydrogenase n=2 Tax=Desulfoluna spongiiphila TaxID=419481 RepID=A0A1G5F3R4_9DELT
-MDTQQEMNKMETSLATMKRAFASSPMPSLNTRIGMLKNLKTALIEYTGKISSAMSDDYGKRSEIDTLIADIAPCIANINHTVGHLHEWMEPSKRDSGPLLSTASVEVIYQPLGVVGIVVPWNFPVMLSIGPLISAIAAGNRAMLKMSEFTPHTNKVLGEMLQSVFDEAYVNVFEGEAEVSAAFTALPFDHILFTGSTTVGRHVMRAAAANLTPVTLELGGKSPVIVADDVSMEMAVERIIYGKSLNNGQVCVAPDYVFLPEGRVESFIAEYKKQYGDLFPDGVDSENLTSMANTRQFNRIEGLLNGETEKQTRIEPCHGNSRDNAKNRLVTHMIVDPAKDSEVMTEEIFGPLLPLIPYGDVQEAMAYIQGNPRPLALYLMTFDEDLQQQVKTTVHSGGMCINDSVFHLAVDDAPFGGVGESGMGNYHGFEGFLTLSHSKTVMTSGTKHNIKHLFAKDDNAFKKAVLEAMLR
->UniRef90_A0A1X1T8H9 Chromosome partitioning protein ParA n=11 Tax=Mycobacteriaceae TaxID=1762 RepID=A0A1X1T8H9_9MYCO
-MSADYDRLFHSPDAAQTPDEATLHVDRDALMRSNAAAPAPAGGSNHADGAVPPPLPITQPRTQTAPAPPPRHAEITTQMPPTTQMPPTTHMPPTTHMPPTTHMPPTTQMPPTTQAPPAQSPAPQRPPNGMMRTPQTNLPGGARFEAPRQATTPAPRPAPAPPPSAHFADAPPTEAAWPHGQPPAQPAPTSAAAMGNHRAIDALSHVGVKSAVKMPSQRGWRHILYLLTRINLGLSPDELYEMDLHARIRRNARDSYQIGVLGLKGGVGKTAVTVALGSTLAKVRGDRILAIDADPDAGNLADRAGRQSAATIADLLSDKELARYNDIRAYTSMNGANLEVLSSEEYSQARREFNDDDWKGATEVVSRYYNLVLADCGAGLFQPSSRAVLATVSGLVIVASASIDGARQAAVTMDWMRQNGYQDLLSRSCVVINHIVPSKPNIDVDDLVQQFERHVAPGRVIVLPWDKHIAAGTEIHLDLLDKVFQRRIIELAAALSDDFDRLERR
->UniRef90_A0A0R3QEL7 SH3 domain-containing protein n=1 Tax=Brugia timori TaxID=42155 RepID=A0A0R3QEL7_9BILA
-MEKIKVINGLRTTISSLPVRESRKALRYLGRIKRTKRVKAVALECGLLRKLLPGFIVYFNVMLRKELVASGVRYGVMEAVAEHDFNATAEDELSFRKNQILK
->UniRef90_UPI001944A0FC hypothetical protein n=1 Tax=Levilactobacillus andaensis TaxID=2799570 RepID=UPI001944A0FC
-MEREQQRLDTGLAAELNAALKTKRTQLELLQLLYGQTPRSQRQCSSVATEQVVRTDAE
->UniRef90_A0A672LGG0 C-type lectin domain-containing protein n=3 Tax=Sinocyclocheilus grahami TaxID=75366 RepID=A0A672LGG0_SINGR
-DQNDLDLKIQDQVIHLTFLLVFQRGSRCLVLITVGLGLICVLLLVFIILQHITITAERDRIKSYKNTAEEFNQTINSLQDNHTDLTIKKSQLQDNFNSLSQKNLELESQVRSLSDQLKKESKRGQICCFWSSSLLMHVYSFLKCLCKNLCGLDGFFLSNEFKSWSDSRQYCRDHGADLVIINSGEKQVSFLWIGLSDRQQEGNMKWVDNSPLKQGFWLKGEPNDQGGDEDCIELMPSNPVLNNWNDLSCSEKRKGICQK
->UniRef90_A0A538MFC4 Thiamine-phosphate synthase n=1 Tax=Actinomycetia bacterium TaxID=1883427 RepID=A0A538MFC4_9ACTN
-MRLHAIVEDLASARAAVEGGATVVQLRCKGASTDELVEAGRGFGVLEAAFVVNDDVEAALRLGADGVHLGRDDPGAERAVAAGLLLGTSAARVEEARAGEALGAAYVGAGPVWATPSKPDADPPIGLDGLAEICAAVSVPVVAIGGVDASSAGDCIRAGAAGVAVIRAALDAAAVRAAVDAAL
->UniRef90_A0A7V9WRH6 Nucleotidyltransferase family protein n=6 Tax=Streptococcus porcinus TaxID=1340 RepID=A0A7V9WRH6_STRPO
-MEVIDKLISQNAELMNLLKLIKGLDLPDSWLCAGTLRNFIWNKLSNHNEILTTDIDLVFFDPNMTYQESLALEQSIMRKFPQYNWDVKNEVYMHYHTPAASAYSSACDAISKFPEKCTAIAARLDDKNQLELFLPYGEADILQFQVNPTPYYTENRERHKKYNQRQYQKNWSSTWPQLKVSFFPE
->UniRef90_UPI001CD804F7 response regulator n=1 Tax=Desulfuromonas sp. CSMB_57 TaxID=2807629 RepID=UPI001CD804F7
-MGHKVPKILVVDDEENARLALRVILQQEGYQVDSVANGLEALEFLRRHRVNVVISDIKMPQMNGLAFLRELNRRYPSTRVIMVTAHGGIESYLEAIHLGAFEYIHKPVRVEELKWVMSKMFNEGRTAKAN
->UniRef90_A0A167SRD8 Uncharacterized protein n=1 Tax=Fibularhizoctonia sp. CBS 109695 TaxID=436010 RepID=A0A167SRD8_9AGAM
-MCHCGAECHHNINLFEVSQKSDHTSSEVQLIGLLFPYVARLWQRVNITLIAAAVCSRNGDLFGDVEMAAS
->UniRef90_A0A5B7IY87 Secreted protein n=1 Tax=Portunus trituberculatus TaxID=210409 RepID=A0A5B7IY87_PORTR
-MLRLMLLSGWILHYHYATTLPRAPPCQCLTPSRPCRHLPLVKTRQQNMEYRLGPAECRRVLCNATPHSQSGLPPPCSFRPSDQHPTTPLVFPPLPQHTL
->UniRef90_A0A6M0BSB5 Uncharacterized protein (Fragment) n=1 Tax=Okeania sp. SIO2H7 TaxID=2607802 RepID=A0A6M0BSB5_9CYAN
-MLNLAVIYIDNIFTNVEKKETGDRRQEMEKGVRRQESGDRRWKKESGDRSQETGVRRQELELCFLERSLKKELIDRMKREPAKN
->UniRef90_A0A7S1N3F1 RRM domain-containing protein n=1 Tax=Eutreptiella gymnastica TaxID=73025 RepID=A0A7S1N3F1_9EUGL
-VEATAAGAAPTESKAKGTKRKRLPPASEDAAERPPPSKKERKGQLVSATTPKEVAALPPPPADVREVWMTNLPVIVSEKDLYAAYEELGWEAITKVKWMQRTHAAGTSFRRCAYVTFATPDLARRACTLDVEIKGKKPKLELTNPHHVHKSLELFTQGWPTQITDKQVHEAFLLLGLTGITAIRWLPKKGNRLSCFLDFDSKEARDKVLQGGTLQYKGRTVLVQKPLNTLPSDQRTAADRSAKSCELFLDPCFKAMTNDIIQTHYESTLGPDTVVTVRRWQNRGWVVFKTHELALQASKMKPPRNPGKEQVLVRWRLNAK
->UniRef90_A0A4Q3K0R9 MBL fold metallo-hydrolase n=1 Tax=Myxococcales bacterium TaxID=2026763 RepID=A0A4Q3K0R9_9DELT
-MASLGEGNGKHPADFGVGVRPLTEVSPASGKPVLAFASHAHVDHIGSLHLYERRAGHPLEAHTFAAMDDLGTLAPEFIGIEGAVTASPSPGWTMADYALVPAPLTELLGEGDHVDLGDRRFTVLHLPGHSPGSIALLDERNGDFFSADAIYDEGLVDDIPGADIETYLRTMRRLADLDVGTVYAGHGEIMDRKQMRDVALGYIASKGG
->UniRef90_UPI000719B42D xenotropic and polytropic retrovirus receptor 1 homolog n=1 Tax=Priapulus caudatus TaxID=37621 RepID=UPI000719B42D
-MSTARTCMLPTMLKDLLYAAQDEAPNADAVDDDHVQRFLANFEERFFRKSDQELVKINTFFSEKLAEAHRKWANLKSELGELEERDRNHVSGHQRRKLSSVVQRAKNKKEPAVRNLPQLKLAFSEFYLSLILLQNYQQLNFTGFRKILKKHDKLMQTETGSQWKSVNVASAHFYINKDIDRLIQETEVGRGYYEAIIPRNSGVRPWHSSEDHAGW
->UniRef90_UPI00123D7996 HNH endonuclease n=1 Tax=Roseibium aquae TaxID=1323746 RepID=UPI00123D7996
-MIEAPQSFVVREECGKAAFQNGFRRKREEREGWAGFSSTTVPGTIHLAAASAQGPWFLALDHTGVVEELDIPVVDIAGPGLARYAFETLGQVYAVLPRIYQLAASLPDAPLQEFETKVKDLPKTTEAERLVVQRIGQDIFRSGLLEYWQGRCPLTGISDEPLLRASHIIPWKDCESDAERLDVHNGLLLSALWDAAFDRGLVSFDDVGQPIFSPALGEHARSELRWQQPIALTEKHRARLAWHRSHLFKAEQ
->UniRef90_A0A3B6R914 Homeobox domain-containing protein n=2 Tax=Triticum TaxID=4564 RepID=A0A3B6R914_WHEAT
-MSPSTSPESGISAGTKRGLEHTSSGVFPAASSDEDDGGGDGAGGRKNLRMSKDQSAVLEECFKTHSALNPKQNKALANRLGLRPQQVEVWFHNRRARTKLKQTALKAAPQAHNGASEGPLTTLTMSLSRKRVASTSSASACTVPRFSANAGTGMPMPSLKEWQFFCAFRDTGAMYGGSSRLAKVVKPAR
->UniRef90_A0A401M0J4 Potassium channel protein n=3 Tax=Bacteroides TaxID=816 RepID=A0A401M0J4_9BACE
-MKSALSDFVWEKKGIYGILHVVILLMSLFLVISISIDTFKGIPFYTQTSYMKVQLWICIWFLFDFVLEFFLARHKWHYLRSHFVFLLVAIPYQNIIAYYGWTFSPEVTYMLRFIPLLRGGYALAIVVGWLTHNRASSLFISYLTMLLATVYFSSLAFFVLEHKVNPLVVGYGDALWWAFMDVTTVGSNIIAVTVTGRVLSVVLAALGMMMFPIFTVYVTNLIQRFNDQKNKYYQQQTTQQESVVSQGQTSPQGQTSQQSPTEKSAS
->UniRef90_UPI001FE9B9A5 beta-lactamase family protein n=1 Tax=Sphingomonas colocasiae TaxID=1848973 RepID=UPI001FE9B9A5
-MLALALLSLPAALAAQAPVPSDTPGKTASGISYTQPRDWTMTVKGSATIFAAPEANLNIAVVDAGEAESAQAAAAKAWAAYRPDAARTVRLVSPAARGDGWDERVGIAYETSPNERATVSALALRKDKGWTVVITDGAESTANKRSAATSVIQGSLRPAGYAPETFAGKAAHRLTPDRIQAIRDFVAESAKQLEVPGVGIALIDQGKVVWEGGVGVREIGGNEPVTAHTKFMVASNTKGMATLLLSVLADEGKLRWDQKVTDLYPAFRLGSDAVTQSTLVRHLVCACTGLPRKDYAFILADAGAPASDTFRQLAETQPTSKFGELFQYNNLMASAAGYLGGSLAYPKMELGAAFDKAMQTRIFGPLGMRDTGFDNAAAEKGDWARPHGLDVDGRMVEIPNTFNHLIVPHRPAGGAWSSAADMARYAQLELSKGLTPEGKRLVSEANLLERRKHGVPIGENGWYGMGLMERVVSGVTVVTHGGTLQGYHSSFFVLPDAGIGAVILTNADPGASMIAPYLRRLLEVVYDGKPEAAQDVAAVAARIKAQAQARRAKLTVPGDPAVLAGLATTYRSQIDGKISFSDRGGAKWMKAGFIEGPVATRKNADGTVSIVSAGGGAIGVEAVVGSKDGARTLTVRDSQHDYVYTEVR
->UniRef90_A0A536UTK9 SCO family protein (Fragment) n=1 Tax=Betaproteobacteria bacterium TaxID=1891241 RepID=A0A536UTK9_9PROT
-REFKFYYSAQQADAQGNYTVDHGAGVYVFDPRGRLRLMMRPGSAVDAMAADVAQLLKE
->UniRef90_A0A290RU70 Cytochrome b561 n=15 Tax=Pseudoalteromonadaceae TaxID=267888 RepID=A0A290RU70_9GAMM
-MFKNTPTSYGLIAITLHWLMAFTVFGLFGLGLYMVELTYYDSWYKGSLDLHKSIGITLAAVLIFRILWRVFSPKPRPLSQNKTVNHIAHTAHIVMYLILAVIVVAGYLISTADGRAIAVFSIFNIPALDYNFDGQADIAGKIHYYGACTLIGLAVLHALGALKHHFIDKDKTLTRMIKPKEY
->UniRef90_A0A7W1BD12 DUF1570 domain-containing protein n=1 Tax=Actinomycetia bacterium TaxID=1883427 RepID=A0A7W1BD12_9ACTN
-MTASLDECWLKITRAESHFDIVKSAIHGFLQPNPERIAGQLDAESGEEVYYTRRYPGTRREWSIIIGDALQNWRNALDYIVCGLVRMNGEEPSSSNAFPIVDRESDYPAQSKQRIARVYPGSEAVVEGLQAFNRGNAPEDDPLCRLRDMNNWDKHKALHTTTHVVQLESAWPVRMSEDPSAGKFVSGAFERERPLARIPADRELGQAYAEMVFDATFDIAFEGGPPLTEGLEVIETLQQIGDFVRFETLPRFAQFFA
->UniRef90_A0A7C3X0Q5 Aldehyde dehydrogenase family protein n=1 Tax=Candidatus Hydrogenedentes bacterium TaxID=2030809 RepID=A0A7C3X0Q5_9BACT
-MSKKELKVINPYTEKEVYSFPMDTIEDAYQKIENAYKAFQEWRFTSMNTRKELCLKFMKEFEKNRDNIAHEITEQMGKPLQQSQNEINTMLDRAQYMISIAEQTLADEYLPEKPGFVRYIRHEPIGVVLDIAAWNYPLLIAVNVIVPAIMAGNAVIVKHARLTPLCGKAFVEAFEKAGAPKGLIQDIIADHQVIDAVIKHPKIGFVSFTGSVRGGHEVVQSASTRFINQGLELGGKDPAYVCADADFDYAVANCVDGAFYNAGQSCCAVERIYVEKPIYNQFVEAFVELTRQYKLGDPMQKETTLGPLAVSSARQFLKKQVEEAVAQGGKLVVSPDEFEVPDQGWFFAPAVVADAPQKSSLMQEESFGTVIGILPVHNDEEAIEYMNDSPYGLTASIWTSDFERAKRIGERVETGTFYMNRCDYLDPALPWTGVKDTGRGASLSHYGYYQLTQLKSMHLRIKW
->UniRef90_A0A7Y5VDB2 Rhodanese-like domain-containing protein n=1 Tax=Saprospiraceae bacterium TaxID=2202734 RepID=A0A7Y5VDB2_9BACT
-MFGLFQRTSSDYKNLNADDFRKAIEHDKNAVVLDVRTPAEAHGGKIKGAKVINFMDPGFATAISKLDPGKSYYVYCRSGVRSANACQVMAKNGFKELYNLRGGVLDWPFQLL
->UniRef90_A0A1F2RY10 Lactamase_B domain-containing protein n=1 Tax=Acidobacteria bacterium RIFCSPLOWO2_02_FULL_68_18 TaxID=1797185 RepID=A0A1F2RY10_9BACT
-MTGRYVGIVAALALGGASATLQDATSVLNDAARALGASELRTVQYSGTGFVYAFAQSYRPGGPYPKFHATYSRAIDFERGLSRDETVRTQFEDPPRGGGGQPLYRDARAAGVVTENSPWGAGALALTPHGFLQAAMRATPTISTRRVGGGTVTVISFTARERYRVDAFVNGQHLIDRIETRAANPILGDMLIETTFAEYRAFGGVQFPTRIAQRQGGFPTLEIAVTDVRPNAAVALEAPEGGAPQPARSEGQRIAEGVWYLAGRPDPNSQLVEFRDYTVLIESSVTEARALLNLAEARRLVPGKPVRYHVNSHHHGDHAAGLRAMVAEGVTLITHETNRPFYEQTVLRNPHTLAPDLLARNPRPPAWVWVNDKYVLSDPTRTLELYHVENGHAANLLMGYIRQEKLLIITDIFNDFGEPRPNDPPSGLVSPYYAALGDRIRRLGLDVERIAPSHGTGTVPAERLWKALEGKVQAPPVAGR
->UniRef90_A0A7J5FRL1 Transposase n=3 Tax=Bacteroidales TaxID=171549 RepID=A0A7J5FRL1_PHOVU
-MGIDDQNKLVNAGFQIIRKDDYPSPRIKFCTGRNGSWKTYKKFETKAERDRAFALLLKDEKIISD
->UniRef90_A0A0E3X9I7 Group-specific protein n=1 Tax=Staphylococcus phage IME-SA2 TaxID=1610831 RepID=A0A0E3X9I7_9CAUD
-MDYREKMVSQGQPPLSNFEYYHVIVPYLVGVIVIILSIIFRDSLYSAQSGFGVIITSFIYMLVYVIIGLVGSFVLTIFQARKARQYQTQEDNNEVQ
->UniRef90_A0A2K2F967 Protein jag n=1 Tax=Pseudoclostridium thermosuccinogenes TaxID=84032 RepID=A0A2K2F967_9FIRM
-MSYTIEKSAKTVQEAISAALEELNADENEVEVEVIDEGNKGIFGIIGTKLARVRVTLLDTPAKKAQDFLEDIFSKMGIAPEMELTEEDDTLSIKIKGKDIGIIIGRRGETLDSLQYLTSLVANKNGGKYKRVIIDVENYRQKREETLIKLANRLADRVVKYKKSVTLEPMNPYERRIIHSTLQNHKSVETYSVGEEPNRKVVIAPK
->UniRef90_A0YFF1 Hcy-binding domain-containing protein n=1 Tax=marine gamma proteobacterium HTCC2143 TaxID=247633 RepID=A0YFF1_9GAMM
-MVMSKVVLLDGGMGQELLRRSSQKPHSMWSARVLLEEPEIVEAVHRDYIEAGARVITLNNYSATPERMAREGHPELFDILQKKAIDIAKRARDNSPRARDHDIKIAGCLPPLFASYKPELAPNFEECLERYRVIADIQKADVDLFICETMSSIKEGTASAVAAASTGLPVWLGLTLEDNLEGRLRSGETLADAMAPIVDLGVEALLLNCSMPESINAAIGTLINGYDTVGAYANGFTSIAALKPGGTVEELQARQDLSPNGYAKFALSWVDSGAKIIGGCCEVGPAHIAELEQQLLAKGHEICSAL
->UniRef90_A0A2T9WSI7 Nucleotidyl transferase n=1 Tax=Nanobsidianus stetteri TaxID=1294122 RepID=A0A2T9WSI7_NANST
-MSLYTLILAGGFAKRFRPLSDYVPKPLFPVGGVPLIYYIIEKALETGSDGIIISTNKKYEYHFRHILASLYSFYEPSQIGKIRLVIEPSNSEENKLGSIGGLHYAIKEMGINNNLLILLGDNLFSFNLNKIIKLGNENNSIALAIYDVKNPDNAKNYGVVKIENNIIKEFYEKPQNPLYTTISTGIYYIPREKLYLLDEYMNSNYSKDSMGNFFEYLIKRGEKLYGYIYIMTIMNIGLILVQ
->UniRef90_G2I2J0 Competence-damage protein n=10 Tax=Komagataeibacter TaxID=1434011 RepID=G2I2J0_KOMMN
-MNPTACLLVIGNEILSGRTQDVNVQYIARRLSETGITLSEVRIIPDIRTVIVRNVTETRAAYDNVFTTGGIGPTHDDITSACVAESFGVPWVHHPETFRLLEAHFAPDAFNAARQRMATMPQGATPIRNSVSVAPGFTMGNVHVMAGVPRIMRAMFEEVLPTLPHGTPVTSQAWHANGLYEGALAASLEAIQHCYPTVDIGSYPYRLDESQRGVCLLCKGTDTQAVQDAATAVRNLIVEMGFRPQAGEPAKA
->UniRef90_UPI0008255106 DegT/DnrJ/EryC1/StrS family aminotransferase n=1 Tax=Bacillus acidicola TaxID=209389 RepID=UPI0008255106
-MISTQLRNIPFSPPDLTEKEIEEVIKTLKSGWITTGPKTKEFEKKIAEYVGVNKAVCLNSATAAMELTLRILGVGPGDEVITSAYTYTASASIIEHVGAKIVLVDTAPNSFEMDYKKLAEAITEKTKVIIPVDIAGKMCDYDTIFEIVESKKELFNSNNELQGLFNRVIVMTDAAHAFGAERRGMKCGQVADFTTFSFHAVKNLTTAEGGAVVWRDIFGLDNEWLYKQFMIYSLHGQSKDALAKTQKGAWEYDIVYPAYKCNMTDIMASIGLIQLDRYEKLLQRRREIIEMYDKALSPIGVQSIQHFGEDFSSSGHLYLARIPEINEQHRNEIIVKMAEAGIACNVHYKPLPMFTAYKNLGFDIKDYPNAYNQYVNEITLPLHTLLSDEDVEYVVGNLKWNLNEI
->UniRef90_A0A455ZFP0 Paeninodin family lasso peptide n=1 Tax=Elizabethkingia anophelis TaxID=1117645 RepID=A0A455ZFP0_9FLAO
-MVKKKDYIPPKLEVEIVEMECGIAANSAAVSPQTVNGNTDEAQTDWNGNDDTTIDTPF
->UniRef90_A0A7S3Z719 RNase H type-1 domain-containing protein (Fragment) n=1 Tax=Lotharella globosa TaxID=91324 RepID=A0A7S3Z719_9EUKA
-WSLLLAPKAFLKRATSMQRRTLKRFLSLPTCAGGDVAEVYAAIAPLDVLLHRLCAGTLVRMVSAEDHEGRLAYRRYLDSDQPIKDIRRKVSTWKSPFGVMLKAAQALGLPLFPRAKRVRHAMAKSNVNVNVPVFKNFNKKFSERCKKKAREFAESVIANIPSDEYTLYTDGGQCDDHKFAAVCGVKDNMESFTLCFRLTGAAVSSHVAEVYAIKAAILWSIKHDVKVHIVSDSQAAIRATLSPASQCIHARKVHTLLANSKVASLVWVPSHVGLPGNERADAIASGGDHSTIVRVPTSVSDYTNRIKLRALEIWNDRWKRSKNSKELHRLMPNVPHDRSHILGCITARIMARLRTGYCSVASFLHRHKLKDSNLCGRCLDVGKHRVETVAHFFVCKANRPHSTAVLVDFTAILGHRPTSLSEVLDVNLYLSKQI
->UniRef90_K3VTF1 Adenylyl-sulfate kinase n=2 Tax=Fusarium pseudograminearum TaxID=101028 RepID=K3VTF1_FUSPC
-MTLKKLTLPYYAPNAEASDKYPSFCPRLKPSDCNKKVERPAPIVHINGFPGVGKSTIAKKLHEHINKWKIKVVQHHELDLLANTIKTPETFDHEQLRRATRALALNTIAESEDRLDTCYVFEDFALNNQGGFRIMEEYRLLALRRGCSLIRIELTCDDVAYKTRLKDQGRIDFRTENDYPRRSCLTCTDQRLVTSPILCRGFSDGGLKSLDVSSKPELWTAMSAAHHVMVTWNAGL
->UniRef90_A1DJ33 Cyclic nucleotide-binding domain-containing protein n=11 Tax=Aspergillus TaxID=5052 RepID=A1DJ33_NEOFI
-MERVRKTFFNPLATSKAQVEKILEGLPVGSAHPFSLEQILLCRTENGIEEIDISSYPENFFFNAMDLGEMGEILLRRMAGFQSHLKVFEDFQITQAPSSTFKIPIVSDQITILAVSERTPTYYDFCFADESCNACCWLARNTFPGITHSGDILNGQDLLDYVKINKDSLIEKEICVFISGYQSTLITRFLGTHPALLVADHVDKVLYIIPVPLDAATIGDATICCPLVIKRDGDSLIYSILPTATTDRGMMCDSNKLVSPAFPEAIKRADFTMCTPDLTTRKTAPANDSVVEDTASNSENLRKIITKENAIFTTDSAALPSFIDLEKTQIIRFGTGLEFKLPDEEVPMREEPSAIVLPCIFGTELQGPVLLATGTVPSNVPFPNENALRDYYKQLKNAVVIVDERMTDNARNLASAYRINALFIVQLTPETEPKDTNGVISLMDLANINAVTALAGPQSLILVQISEKYYFYRGIANRAHLNTSGLAFGADVTSVLESVGIGSILDPRIERVINLGDANSIVLPTTGQLVQPQDLQKLFEEISVDQIQNLEEDISAVVPQLQVLLNQKDLQELSRALVTALSTKISNAATPLRDSYTKFLTQDYRMEDPKSVQKKNKMLGELRKITKDMQKALEPVISCLANMISSQTTSKRTHDLKRLVRQTTIQNNVEAVKSMTFETLSGYLEEYAGDMGVMLLNIETTPYRELLGNLKNSAIDASQCCALDSRILHLEGFDAGIIMEQSQTKHNGPLKSTIGPSQPILALPYLSQSSGTGSMLAWVLRWMEKCNEPHIAALRIIMRSTLGQAVASREHDIQPSSPETGHLMSALLMAAMSKLAAMRTSKPVELEKAEDTVTRLMRGLFGNLLTIAGSGIRPLSMVWQLFGLNPQYDLPTSSAEWIWYENVVALYPYTGWPLRQFHGNLEKLLDKAVIRVVTKNENLARIKASRTAEMVKFCKLRNIQLEHSRTIITVFMRMLTAEDIDLQPVAARLLAQLPHKLERQSQSYTRMIMYLNHLARGGERRVNDDLTAANVYTSRSATFAELKKQVCEACKRSDWARMKEACQEIMTKHVEIAALWRVKPESLKIQNMKLYKALLAADFDDIDQNTQIKNIELTRQVLGDAENKRVPWQVGKKGQFGSSIEPLDEVFLHEIMTGEKSEPAPPATIDDFKGEEERAMIETEDEFAEFESSLRAEFIKTMQKNLSAEEVCDIINVPVSAMRVFIKALNPEFIWEDLAVNFKSVILELVKDRSNRVESRPVRRLLRIEVRKNLQIEG
->UniRef90_UPI001C2561C3 uncharacterized protein LOC121770608 n=1 Tax=Salvia splendens TaxID=180675 RepID=UPI001C2561C3
-MSAIEKKIEMEDEEKEMIDHWSHKHPLTLVDTTGSDRCYGCERSFSSGEQAYGCSIPGCEYSELLHEECSAMAREIRHPLHTQHILSQRHSQELFRCLICEGIIYSIGYKCTSSGCGYQVHLMCAHDKGVVDANHPEHELKLWRRRCSFKCDACGITSRGSSYTCIKGDCQYWIHVRCASLPQTLKREDHHHSLSLSSYIPPEYIKYNYKCDVCSKALLLKYWIYHCQICRFIVHIKCAFNKPPPPLTDASIGKDIVRLPMNEVAVELVTPFVMRQRGGEVGTLIPPFLIPATAVFDEEDELVNMKYKFLHHQHHLTLVSSTSQHPQILGEEEDEENYGVRWELICDGCITPISSSSSSSYYYMSCSECKYNLHLACFHLPPQLYSLPLHQHDDHQLVLQSCDKHQPWNYETCSVCEYPMNGLFYSCTACDFEVDIKCACMPDTIHHAAHPRHLLKHVTQSDLGRDINRWSLSCAATCGQHVVNYDCYRCCNSSCDFIVHVRCAVLLASVSSRRWDEQHPLLLTYDATVNRPGDFYCDQCETQMNPRSWMYHCRPCDVSFHPRCFITTSGEYRNIKMGQEYDVNEETHPHPLTFQLLTTKRRCNICHINNYELQGFYCALCNFFICYNFCGKGMIAKGDLKAVDLGKLSVLDH
->UniRef90_A0A0G1JNZ0 Integral membrane protein-like protein n=1 Tax=Microgenomates group bacterium GW2011_GWA2_44_7 TaxID=1618500 RepID=A0A0G1JNZ0_9BACT
-MGNPSTRQFLLVAALALFLRLILIPHPGFLADIAYWKWWTKDSAQNGLVHTITQTGINYPPLYLTIMKATGHIYGLFANLNNDIQYWDKGNLLFLFLIKLPFILADLSVGYLIFWLLRRFYQRNLSHLGHLSNLPLLGAAFWLLNPGVIYNSALWGQTDSLGVVPILLAYLFAVSGRPIFAGALTGIAFFLKAQSIPLILFLYLYLYLKNGLLTTVKSGAAAVTAGLIVTSPFFLTHTMDRIISTIFTSVGYFPYASLYAFNLWWLVIRGASFQFPDQTLVGNLLSYRTIGFTLFWSAFGFLAFVLWQTALKKNAQELTERFLLSTPLVILSMFLLPTEIHERYLLPFFAFALLPLAFDAISARVKNIKLYLFSYAVLSLIWLLNLHFVMIKNYPENEQPILSLISPSMPVLGVVFSAVSVTLYLVFFGVFLKRCLPTNLKSRILAIGLLILLPLGLLSLQAAPVIKAKSQSKVLLSEIKPTFVRQGWGELSKDKSVAGGNLSTWYFFSWKGLGTHANSQIDFNLDGHYRRLETNVGVDTGGGEAASVEFLILGDDKVIAKSGILKKWQYQKSLVADLTGVKKLSLVVTDAGDGINGDHADWLYPTLYK
->UniRef90_K2AFW7 Extracellular solute-binding protein family 3 n=2 Tax=Bacteria TaxID=2 RepID=K2AFW7_9BACT
-MKKLLLASALLAFGAGLASAEVVRLATEGAYPPFNFIDDKGEIAGFEREFGDEICKRAALECTWTTNEWDSIIPNLQSGNYDVIIAGMSITEERGKIITFSENYYPPAASAYLAASADADVKGGVVSAQVSTIQAAYVAESGATLLEFPTPDETVAAVRNGEAVAVFADKDYLRPFADESNGALMFVGDDISIGGGVGLGMRQSDTELKAKMDAAIQAMKADGSLNTLIEKYFGAEGLKF
->UniRef90_UPI001E5627F1 hypothetical protein n=1 Tax=Streptomyces sp. VRA16 Mangrove soil TaxID=2817434 RepID=UPI001E5627F1
-MRTLHGEWTKFRTVPGQLWTLPALPLAMIVCTALIAAGAHPEQEGTLDVTALSLSGVYFAQAVAVLVAVAVVSAEYPRMMRTTLAANPRRGTVFTAKTLLAAGAVGVLALPGVTGALLTGRAVLTGGAARLPLSSWPLWRATLGTAVYLLLVALLTTGIALIVRHAAAAVGTALTLLYGPYLATLIIEMPDHALHLVQKISPMTAGLAVQTVGGAGGTSPWSPGAGLAVTAVYAAGALVAGWGMLRWRDA
->UniRef90_A0A3B1DZ09 Chromosome partition protein Smc n=1 Tax=hydrothermal vent metagenome TaxID=652676 RepID=A0A3B1DZ09_9ZZZZ
-MKLNSSGKTATIFLVIFSVLLISMTAISVFIFQKEKEMRIESEGDLEKKRSEVIELKTEMREVKRKNFLLQEKNKEADERVNSLMDEVELEKGLKEEVKQENVALEEKVEMFIIARKKLDEKIKKKKEDSQKKVAEFKTLLQAEAERLKEIESLKKVNKELEQKNKDLQGQVTKILEEGKLLKEDNKGSEVIKEMGEVKKKVKNKVELEPIIVTPASGKIAKDNKEKKSVQEEVAQTVANSMKGRIISVDRETEFVIVDLGKKSGIKMGQVMSVYRGKEYLGDIKITRIQPKMSAADLIPPFSSRIVHKNDQVVVK
->UniRef90_UPI0012E1D502 hypothetical protein n=1 Tax=Pseudorhodobacter antarcticus TaxID=1077947 RepID=UPI0012E1D502
-MRSLISSSAQAVACRAPAVTAVTAVTAVTAVTAVTAVTAVTAVTASLIRVSVLIKPL
->UniRef90_A0A2D9X1Q0 Protein TPX2 n=1 Tax=Actinomycetia bacterium TaxID=1883427 RepID=A0A2D9X1Q0_9ACTN
-MKELDSPRNFSRDLQTPARILKVTRGKKKVTRATKLLPIGQSKKLENKFVESKRSAFKTVKPKGKLSPIQEVTQKTDKDSNTSLRSVETPLSRSLELPPPPPAPKKERAGRLEPLAQGIETNFYKNYYSL
->UniRef90_A0A7V6UPT2 Thiazole synthase n=3 Tax=Bacillales TaxID=1385 RepID=A0A7V6UPT2_9BACL
-MTDKLVIGGYEFQSRFILGSGKFSLDLMEAVVEYGEAEIVTLALRRANTGGEENIVHYIPENITLLPNTSGARNAEEAVRIARLARELGCGNFVKLEVIHDSKYLLPDNYETIKATEILAKEGFIVMPYMYPDLYVARSLVDAGAAAVMPLGAPIGSNKGLATKNFIQILVDEINVPIIVDAGIGRPSQACEAMEMGVDAIMCNTAVATAGDVALMAKAFKLAIEAGRSAYLAGLGRVLDFKAEASSPLTGFLED
->UniRef90_UPI0005738328 YqcI/YcgG family protein n=1 Tax=Pseudomonas putida TaxID=303 RepID=UPI0005738328
-LRGVHARDPHPWPQAIPADPHDSGWSFCYAGMALFINMNFPGHHQMKSRNLGNHITFVINPRENFDEVANADTESGKRIRARIRERVQHYNDGVMPDSLGFFGQADNFEWKQYQLQEAGSLNPSRCPFHANVHAAPDTQIEN
->UniRef90_A0A158Q2K6 Cytochrome P450 n=1 Tax=Dracunculus medinensis TaxID=318479 RepID=A0A158Q2K6_DRAME
-MSVLGIVIVISMAAWMTWMLLRKVSSIFNKINIIQGPSPLPVIGNIHQIHFKPDDFFEQAQGIAYMLQKNGERMTRIWFSGWPWVLLYGAEECEAILSSNRTLKKPFQYGFLSDWIGEGLLISDPKKWRPRRKLLTPAFHYDILKDFVGIYYKHGRTLLSKFENMIGEHYNEIFHIVSYCTLDVICEAALGINPDAQNKPSPYLDSVWRMKYIIHQRTIKAQYYPKIFFNLFGNGSECKKHIKILHDFTGKAIKERKRLADEAGGIENLLKSESKRENEKISINFFTSLFIYFRNQNISGKKRMAFLDLMLDMHSKGDLSLDGIQEEVDTFTFEGHDTTSASMNWFLHLMGTNPDIQRKVQKEVDDVLGKVNLTRLMTDLEERPITYEDLGELKYLEACIKETLRLYPSVPILARLLQEETKIKNNTLPKGTGVIIVPSMVHRDPRYWPDPEVFNPDRFINNEVKHPYSYIPFSAGARNCIGQRFAIMEEKCILALLMRHLKVKSELRTDQMRVSGELVIRPFFGNNIRFAKRTYGDYTQIA
->UniRef90_A0A3S1DSJ7 Alpha/beta hydrolase n=2 Tax=Halomonas TaxID=2745 RepID=A0A3S1DSJ7_9GAMM
-MLTKEQVVARNNVTIVGSGEKTLMLAHGFGCDQQMWRHLIPHLKERYTLVLFDYVGSGQSQISAFSESRYRALEGYAKDVTEICQALNLTQVHLIGHSVSGTIGLLASIAHPELFASQVMICPSPCFLNMPPDYYGGFECADIEELLGLMDRNYIGWANYLAPLVMGLENSELLTSELSDSFCSTDPVVAKAFAKATFFSDYRHLLPQAKHEALLLQSQQDSLASPDVGHYMHAHMPGSTLRLLASEGHCLHMTHPELVAQEINTWLRD
->UniRef90_UPI001F334FC1 bifunctional ornithine acetyltransferase/N-acetylglutamate synthase n=1 Tax=Ktedonobacter robiniae TaxID=2778365 RepID=UPI001F334FC1
-MYTNFCSFSIKRLIHLCSKVACRLLVHILRDLLCERLRRCTVKVTVADAESFAQAKRVAKVVVNFPLVKTAIFCADPNWGRIAMVIGKCEAQTAIVLEKVSI
->UniRef90_UPI001EE7BB04 hypothetical protein n=2 Tax=unclassified Micromonospora TaxID=2617518 RepID=UPI001EE7BB04
-MAVPVTALLAGCAPATAVAGGATGPVSARRSPEGSYAVGVRTNPNAAFPPRPLADTARRRRPLAERAA
->UniRef90_A0A5E3WRX4 Oxidored_FMN domain-containing protein n=1 Tax=Peniophora sp. CBMAI 1063 TaxID=718367 RepID=A0A5E3WRX4_9AGAM
-MSTTDKVIPTLFKPTKLGNLLLNHRVVLAPLTRFRADDDSVHTELAVEYYRQRSSTPGTFLITEATVIAPQAGGYPNAPGIWNNEQVAAWKKIADVVHGNGCPIFMQLWSIGRVAVPEVLEKYGHDVVGPSAIALDANHATPRALTVDEIKEYVQLYAQAARNAIRAGFDGVEVHSANGYLLDEFIQSNSNHRTDEYGGSIENRIRFTAEVVEAIAAAVGPERTSVRLSPWSRFQAMRMPDPIPTFNALVQRLADTQPALAYLHIVEPRVNGEADATDVGEDNNDVLKKIWSPRPLVVAGGFSLETALQVSERQENVLVAMGRYFISNPDLPRRWQEGFALAPYERQYFYSRGSRGYTDYAPYVEATKIAV
->UniRef90_A0A350NT93 COX3 domain-containing protein n=1 Tax=Flavobacteriales bacterium TaxID=2021391 RepID=A0A350NT93_9FLAO
-MFWTSSEFMIKNTTPAPSNRRDVFDGVEPAVRERTKKMLMYFIIFAVVMLFAGFTSAYIVSNMGQYWVNIEPTSAFWVSNVLLVLSSIGLWSAVRSMRENHKQRAVLALAFTLISGIGFTISQAEGWKTLAEMGLGWTTTDHESGLEAYRWNSIESLLESDAIYGQDYTISRGGEPLLFDASKNEFYASNDALMVRPITRDVARTSNSGASYLWILIAVHILHLTFGFIYLVINGIRVVQGTIHAKDVVQLESLSIYWHFMGALWLYLFVFLFFLH
->UniRef90_A0A1J5ICS2 Polar amino acid ABC transporter permease n=2 Tax=unclassified Syntrophobacteraceae TaxID=869804 RepID=A0A1J5ICS2_9DELT
-MDLTKFFLVVAAVAGLLAVGTERLGYHWQWYRMPRYLVRIGDGGWRPGPLLDGVLITFKISGLSLILCFSFGLVAALFRLSHSYLARLLARLYVELIRNTPLLVQIFFIYFVLGPVLGITRFTSAVLALSLFEGAYAAEIFRAGILSIPRGQWEAARSLGLSTYKCYRAVILPQAVRHVLPPLTSQAISLVKDSALVSTIAIYDLTMQGQAIIAETFLTFEVWFTVAAIYLIITVILSILVNVMENRLRVTG
->UniRef90_A0A5B8ASF5 DUF4760 domain-containing protein n=1 Tax=Georgenia wutianyii TaxID=2585135 RepID=A0A5B8ASF5_9MICO
-MSVEVWVTLGGVILAGLLAWHQLRASLYVRRREFEDIYVQRYWEISNRLNLDLRIGSYSGGDFAELADAEDKDAQYLAMWDYLALCEDQIDLRKSGNVTDEAWAVWSSSIAGTVSRYPYEAFYDLIEQGLDEAHVDESDRPWEHLRTLRHDPGAGLPDPYPLSGTGWRQRWRRYATGRRERVALTGLEVERLKMRRR
->UniRef90_K1JNL9 ATP synthase subunit b n=2 Tax=Sutterella TaxID=40544 RepID=K1JNL9_9BURK
-MNINASLFLQMVVFFLGAWITMKYIWPPLIHAIEERQKKIADGLSAANKGEKALAIATEQGKAIEADARARATTIVSDGEKRAQSIVDEAKAQAQVEADRIIENARAEAAQEMQRAREALRNEVAALAVAGAEQILAREVDKTVHAAMLEQLKAKL
->UniRef90_A0A1J4Z6F5 Chemotaxis protein n=2 Tax=Hydrogenophilales TaxID=119069 RepID=A0A1J4Z6F5_9PROT
-MTTQRSFSIFDTAWGSGILGALAVAGPLAGTLAGGPWWPLVFALMAVALAVVCARHRLRQNAWMEKIRRMAADIADGHLSSRLTHVSDARSLAPVVTAFNDAMDRIEAAFREMSGALTAQEAGYTARHAQVIGQVGDYSHVLNTFNTVLASISKHKQAEAYNHMVVRVQSLNAAHLIPDLALTQADFARIVKEEEQVIDLASGSSQKANESAVAVEAMHQGFQRLQALIGEVSAAILDLSAKSSEINQAIDTIHALANQTNLLALNAAIEAARAGEAGRGFAVVADEVRKLAGHSKDAAMQIGNTMQALVSETQSMVVSAEEMRAITEESGRAAADISSEFSQIVSRSSETLRRAKTALTVAFASLTKCDHVVYKQRAYQTIVAGDESLRQQVDVDHHNCRLGKWYAGEGREQFGQLEAFREIDRPHAAVHDAVRQMLALTHQRTWQNDTAQMERVFAELQRMEDASEQVMSVLIALPEQASASSVPG
->UniRef90_UPI0018C1FAF3 GIY-YIG nuclease family protein n=1 Tax=Actinoplanes sp. NEAU-A11 TaxID=2792083 RepID=UPI0018C1FAF3
-MTSSGTRPDDVPTDRARTEEALRLLSGVPTGLDVAVKMLSRGGGVYAWWAAPSIFPDLPGPSNLSVPSLRLLYLGRATSLRGRILRNHLRRSGSSTLRRTLAGLLTCEGYRTTWTDRVVLIPEDESRLTAWMYTHLRLTWAEDPEPATIEAELVRRLHPPLNVHGVDPEHIQPAVVAAKNSYNASSRPTERPPTL
->UniRef90_A0A7C3K6X1 Ribosome maturation factor RimP n=1 Tax=Firmicutes bacterium TaxID=1879010 RepID=A0A7C3K6X1_9FIRM
-MTREAIVAQVEALVEPIAQRYALEVADVELLGQGARTLLRVTVEQPAGAERVGVDELARFSEALSRQLDLRDLIPHAYTLEVTSPGLDRPLKKDRDFQRFAGREVQVTTFVPVEGRRHFTGRLVGLEAGEVRLEVAGHPVRLPRAQVASARLSIDENELKRDLSGGGRAAR
->UniRef90_A0A1E1W481 Chloride channel protein (Fragment) n=4 Tax=Pectinophora gossypiella TaxID=13191 RepID=A0A1E1W481_PECGO
-GGYATVGAAAFTGAVTHTVSTIVIVIEMTGQVTHLLPIMAAVLAANAVAALLQPSCFDSIILIKKLPYLPDLLSSASRMYDICVEDFMVRDVKYIWNRMTFQQLKDLLKENKTIKSFPLVDSPTSMVLLGSIHRWELVRVIEKQVGRSRRLQVAAQWLRDAERRRQENEAKKRRPSRFEVTPAPDMLQVPGTGMTRGSSLTTKDQGGLIPSPGQLFRPKSILKKTNSFTLTRGLVSPGVPQTPLSP
->UniRef90_A4ERI7 Ubiquinone biosynthesis accessory factor UbiK n=1 Tax=Roseobacter sp. SK209-2-6 TaxID=388739 RepID=A4ERI7_9RHOB
-MGTIERLAEKLAEDTLKVQDALGEDRFYMEVAQVLGAASQSLEEAFLTEIRVSLADRKAREFISKKLAQVQRELEEKAKG
->UniRef90_A0A7Y0XJK6 DZANK-type domain-containing protein n=3 Tax=Limosilactobacillus reuteri TaxID=1598 RepID=A0A7Y0XJK6_LIMRT
-MKKCPYCNTLNPDDAEVCENCGKPLKGRMLALVCPNCGKVNALGSRECSVCHTKLSQSNHQLVSREITPRKNNKRWGYIALIAFGILIALFTYLGGRYARSTSIPGKIEALEFE
->UniRef90_A0A1Z8PZI4 HemY_N domain-containing protein n=1 Tax=Micavibrio sp. TMED27 TaxID=1986607 RepID=A0A1Z8PZI4_9PROT
-MIKAFWFAIKVGLVVAIAIWIAERPGFVRIEWLDYVATIQMGFFLLLCVIAILISIFVYRVIAAIVNFPKTYQRYLEVRGYEKGVRALTLGMAAVAAGDEKIAVYQAHRATKLMPEDTGLTNLLTAQAARLDGREDDAVRAFARLLENKEASFLGVRGLLQAAIDKGDYETAKNLVDRALGLYPKQGWILKTAFDVYVRAEDYTEARVLLKRAAKAGTVKSETLHSDLAALYLAEALQDFEAARNERGIKLIKQALKKSKDFIPASVALIQYYIDNNDISSASKLLKKYWRREAHDLYVPQWLSIYKGASSEDKLKHMQSLLKINEKNAVACMETGKAALESSLWGEARKYFEKAESIEPTASLYRSYAQLEELSIHDEAAARTWLEKAINAPVERQWVCQETGRLYTQWKPIAQPHGAFNSMIWGRSTDLQSDNALLIHSGQSTMQGLVHAV
->UniRef90_UPI001FFBE095 hypothetical protein n=3 Tax=unclassified Bradyrhizobium TaxID=2631580 RepID=UPI001FFBE095
-MEKTTMRLAQKFWLVFLALGAAIAVQGAPASAQQRLEGQVLLAGEPVVSATVTLWTAGADQPRQVTQTQTGADGRFALSTPPGAGNAPTYLVAKGGTAGGAANTGVNNAIALMVLLGDPLPRAVTVNELTTVASAFAAAQFIKGEAISGNPLGMRIAAGNVPNLVDPATGQWGKVLLDPLNSTRTTTLANLNTLGSLITAFATTTNEDWRARFLKAATVPGGATPKNVIEAMTGIARKPWAQPKELYALFDEAYPQPKDGARRKAPFVPYLAYVPDDFVLSLCFAGGGVYSAGRLMFDAESNLWSGQNWMAGSQSGVNQSIGGGVVKLSPNGTALSPPITGFTGMGIDGVGWGTAVTKDKVWLTSFNGKILVLDFDGHPIGTESDFPFKEKFLGLMGIGVAANGDVWIADGSDNQLLHFPGGRVTDGRIVKVGGLKSPFDIVIDAQNRVWVSNSQSDKVVRFPADDPSKAESFRAGIGVRALALDSKSNVWVASNMSLDFPPPVIPDGASIMEQFKIAAGHMLKVLETNPHMVTGVVNMIRPDGSQPAPTGFTGDKAVSVPWGLNIDGNDDVWIGNFWGRGVVLMAGDNTKGHPAGTKMGDAIHVFKGGSIQMLTDVSIDPAGNVWAANNWNDLNGAASPDPTRPTSTWGGGSGITVIYGVAAPVQPPRMGMVRKP
->UniRef90_UPI0019539C4C hypothetical protein n=1 Tax=Serratia marcescens TaxID=615 RepID=UPI0019539C4C
-DVGGRKFEMSDMAYVIRGLGYIKSKEDVENISLGQYNGIPVRVKDLGNVQMGGDLRLGIFDQNGNGEVVGGIV
->UniRef90_I3SW78 F-box/LRR protein n=7 Tax=Trifolieae TaxID=163742 RepID=I3SW78_MEDTR
-MSSNSTSEDVISALCINEALTDDELRSILAKVDSEKDKETFGLVCKRWLRLQSTERKKLSARAGPHMLRKMADRFTRLVELDLAQSISRSFYPGVTDSDLAVIANGFRCLRILNLHNCKGITDVGMKAIGDGLSLLHSLDVSYCRKLTDKGLSAVAKGCCDLRILHLTGCRFVTDSILEALSKNCRNLEELVLQGCTSITDNGLMSLASGCQRIKFLDINKCSTVSDVGVSSICNACSSSLKTLKLLDCYRIGDKSILSLAKFCDNLETLIIGGCRDVSNDAIKLLATACRNKLKNLRMDWCLNVSDSSLSCILSQCRNLEALDIGCCEEVTDTAFHHISNEEPGLSLKILKVSNCPKITVVGIGILLGKCSYLEYLDVRSCPHITKAGLDEAGLHLPDFCKVNFNGSINEPAVLL
->UniRef90_UPI001F28D147 RimK-like ATPgrasp N-terminal domain-containing protein n=1 Tax=Thiomicrorhabdus immobilis TaxID=2791037 RepID=UPI001F28D147
-MSHFYVVVDSLTDWKPYYSSQDVITFDDYLERVNDRSKKRIRVINLCRDYRYLKTGYYCSLLAEARGHHVLPSLMTINDLGRKSLSSIQLTDTSQLVNRLPLGNEGEQLTFRCWFGKTLNPALAKLAAKLFEKFPTPLLEITLQFKQHWQVKQVKGVSLKALVDPAEQEAFAETFEKFSLQMWRKSKTRKAYRYDLAILVNPDDPLPPSDDAALKQFKKAANQLGIATEFITRKDYMRLAEFDGLFIRETTSVEDHTYQFAKKAEAEGLMVIDDALSILRCTNKIYLADLLNTHKIPTPKTVIINQPSEQALLKLENEIGFPMVLKIPDGSFSRGVVKVENAEELTEQAKILLKQSVMLLAQEYMYTQYDWRIGILNNKPLFACRYYMVDDHWQIYKHESQDTQSGGFETLPTFEAPKAVIDIALKAAKLIGNGFYGVDIKQSGDRVVIIEVNDNPSIDSGVEDKYLGEELYHEIMKDFLLRMESLGR
->UniRef90_A5W1W3 Antibiotic biosynthesis monooxygenase n=32 Tax=Proteobacteria TaxID=1224 RepID=A5W1W3_PSEP1
-MVKVALFVRLKAKPGKEKDVESFLLGGLPLVEEEPATTAWFGIRLGPSTFGIFDAFPDEAGRQAHLSGKVAAALMANAAELFAEPPSIEKVDVLAAKLPS
->UniRef90_A0A167MC44 Ribosomal RNA-processing protein 43 n=4 Tax=Cordycipitaceae TaxID=474943 RepID=A0A167MC44_CORFA
-MPEVGLSRATFAKLSPHPYLLANLEPSNQDIPPARSNGRAPDEARTPEVNLSSLSHAHGSSLVRIGDTTAICGVRGETILTANIPNYRASNAASELRDYDLLVPNIELATGSSPQNLPGGPPSTLAQTLSTRVYSLLHSSQLLDAADFRIWHTQTADLTAADDEEMQDADADADGEDQAQFNNERQVIAYWVLYIDIFFISLDGNQFDAAWAATLAALRDTKLPRARYDPDSELIVCSRKDPKPLSLNGFPIACTAAVFTGKETDRPTEGKYWVLVDPDTLEESLCDESLTVVADCSGGTTSLLSVSKHGGTVLTPKHLRSKQLLGFVEKRWKGFADAMSV
->UniRef90_A0A1V6I1U0 TonB-dependent Receptor Plug Domain protein n=1 Tax=Bacteroidetes bacterium ADurb.Bin035 TaxID=1852799 RepID=A0A1V6I1U0_9BACT
-MKKQKILLIIMLIFNISLSSQITINGKVIDRDSQKPLSFANIKIAGTFLGTVSGNDGSFSLQVKSLPVTLIISFIGYQTDTIVVNENQFLTIYLAPKSILTDEITVTAIRLDDNSPKNFTNLSIEKIQSLKTGQDLPLILNFTPSVVATSDAGNGVGYSDIRIRGTDITRINVTINGVPYNDPESQGVFWVDIPDIASSADNIQIQRGVGTSSFGTASFGASINILTGVMKNDPFVELQTNGGSFNTWGASAKFATGLIKDNWYLEGRLSHQYSDGYIDRAWSNLNSTYLSGGYYGKNTIVKGLFMAGIEKTYQAWGGVPKEYLDDPILRRYNPYTYENETDNYWQYHYHLNVTQKINDKNTLNATLFYIDGLGYYEQYKDNKKLSNYNIPPVILIDTTSNDTIMINSMDIIQRKYLENDFYGAIMSHIFDNNKNLKIRTGLNLYQYDGWHYGKIIWMQYAHNTPINYEWYRNKSIKKEFSLFTKIDYAINEYFNLFTDLQYRYIDFAIKGTDDAFISDTLTKYYNFFNPKLGLVYKISKKDELYLLLGMSHREPNRDNLMLINEDSLKPVPETLYDLELGYSRYFSKGIVNINTFYMYYDNQLVLTGKINDVGDPIMQNVPTSYRAGVELIWNFNFTKWLSWDANCTFSENKIKKMKIYIDDYDLWPQQRIYQVENRPISFSPSIVASSILTFKPISNLSVSIQSKYVSKQYIDNTGDEECVIDPFFVNNIRLDYCIKGKKFDKINLFVNFNNIFNEYYETNAWVYRYYEAGNEYKDFGYFPQATFNVLAGLNFYW
->UniRef90_UPI0019146668 MarR family transcriptional regulator n=1 Tax=unclassified Pseudomonas TaxID=196821 RepID=UPI0019146668
-MNPELQLAAPYLPALASYIETVLGDSPTFSGWDQTSRLPYYLNSSYFILQMTLLGQTCIVLLENQQRSVSLPDVKKHMDALRQLTESPLVFVTETLASYERKRLIERGVQFIVPGNQLFIPELGLDLREYFRARQEKTEFMSPATQAMVIHLLMNDWKHSLQLSQATLGQPFKYSKMTISRAVKELKGLGLITVEADKQQHIEIHVPARQLWQNARKHMRSPVKRTLWLNRVPLLDGQPLLLAGESALARQTLLVEPWLAIYACSSETLNALQNAAEPITEVAPEEAACALQIWSYDPTVYAWAVPYVDPFSLILSLQDSKDERIQIGLSQLEGDMKW
->UniRef90_A0A7C6YG77 Uncharacterized protein n=1 Tax=Actinomycetales bacterium TaxID=1911520 RepID=A0A7C6YG77_9ACTO
-MNEYVEYPASAEAACRSTYKPASRLPGPGHEERLALSSPAVSSGA
->UniRef90_A0A8J7E1C9 Glutamine-dependent NAD(+) synthetase n=1 Tax=Nodosilinea sp. LEGE 07088 TaxID=2777968 RepID=A0A8J7E1C9_9CYAN
-MKFAIAQLNPTIGDLAHNAQQVLNAARQADQLGAQILVTTELVLCGYPPRDLLLRPSFIQAMAQTLEDLALALPPHLAVLVGYAAANPKARYSGEKPLFNSTALLQGGQVQQVFHKQLLPTYDVFDEDRYFAPGQGPSSFTLPCGDWGIRVGVTICEDLWNDEEFWGGRSYARNPIADLAGDGVDLVINLSASPYSLHKAQLRSAMLAHSAARFRCPILYANQVGANDDLIFDGASLAFDRQGELVARLPAFQAGLAVVDYDPVKGDLTPGEVAPLPTDDNEALWSALVLGVRDYTHKCGFAQAVIGLSGGIDSALVAAIAAAALGPDNVLGVLMPSPYSSAHSVSDALALAQALGIAHQTLAIGPLMADYDQVLDPLFADTSPGIAEENIQSRIRGNLLMAISNKFGHLLLSTGNKSEMAVGYCTLYGDMNGGLAVIADVPKTRVYALCQWLNQQVGQGSNGAIAPVTLGTLATRVSAQGLIPQNILDKPPSAELKPGQVDQDSLPPYDVLDDILDRLVQRHESIADMVAAGHDAAVVEKVLRLVSRAEFKRRQAPPVLKVTDRAFGMGWRMPIANRWRSEAAVHPLTAEQLLEA
->UniRef90_L2GXC0 SWIM-type domain-containing protein n=1 Tax=Vavraia culicis (isolate floridensis) TaxID=948595 RepID=L2GXC0_VAVCU
-MHFHTLEMLVMVVIFVHADLLKLKSVCKCAEEGSYQCQNVNNPNVKGNGGTTRKACITDDLYAGIFADVVGKDGLTDSHPRTDNAAHSQIMGCSSAPCPCDELLSDEMVEDASNLMRKSYQQNVEHSSCRIAARGDSPNNEEKLNVSDQPVCTRIGVEKECDQDNEENNDENAYWFGSYISSAIQNGCRTVSSIVEEVFSMFQGCGLWIDPSDERNEEFIDEAIDNMSESGNGTDNELKKAGKLLARTCKCFIREFFWCTIGLCDKISGVIGKRKVKYRDANIGSDKNKDKYSNLERTCTCEAYIKRAACRHGSGLKGKKGKAVEHVSDSIYCEFMRAFEQEKHGLTMQELIERVASRGEHRGTQIVDSKKCFNGCDEVQDVTKRSNFYETVELAIKMVSLMGVLLFMVALVATVLHHWTK
->UniRef90_A0A3D1CV37 Single-stranded DNA-binding protein n=1 Tax=Candidatus Pacebacteria bacterium TaxID=2053589 RepID=A0A3D1CV37_9BACT
-MSVRSLNKVMLIGNLTRDPNLRFTPTGTAVCSFGIATNRAWTPSDGGEKQERVDFHNIVSWAKLAEICGQLLHKGDKVYLEGRIQTRDWKTEEGVEKRITEIIIDNMMLLSNGRGGAMGGNDQDGAGEDLGQTAPTPVSATTTRAKTKPAAKTDNEVEVVEDVSDDIPF
->UniRef90_W0ZCU4 Geranylgeranyl pyrophosphate synthase n=2 Tax=Microbacterium TaxID=33882 RepID=W0ZCU4_9MICO
-MQGSPDAIQAVSQRLERFVSARVDEAADAGPLARPILELSAATLQGGKRLRAAFCYWGWRSVTDATGTDEIVAAAAALEVFHAAALVHDDIIDNSDTRRGHPATHRAFEGAHLAGGWTGDAAAYGRSSAILAGDLLVAWSDDLFEEGIADAPADRARAARRRYAEMRRDVTVGQYLDIAAETVPAPDAEQLGRALHVASFKSARYSVQQPLLIGAAIGGGSTEQQEALRDFGHPIGMAFQLRDDVLGVFGDSAATGKPSGDDLREGKRTALIAFARQELPASVRRTLDELLGDPDLEDTQVRMLQDTIRDSGALDRVEDLIASYTREADRALSGAPLDNASVGALRDLARAAVHRVA
->UniRef90_A0A1I9RWB5 Major capsid protein (Fragment) n=1 Tax=Feline calicivirus TaxID=11978 RepID=A0A1I9RWB5_9CALI
-WSTPRFRPITINISVSNGAKLGXGVATDYIVPGIPDGWPDTTIAEKLTPAGDYSITTXSGNDITTAAEYDKADVVKNTTNFRGMYICGSLQRAWGDKKISNTAFITTGTVDNNNIKPSNTIDQXKIAVFQDTHAXXSVQT
->UniRef90_A0A7S1QBK8 Pentapeptide repeat-containing protein n=1 Tax=Neobodo designis TaxID=312471 RepID=A0A7S1QBK8_NEODS
-APEHAVALDTVRTALSAPSHTALIEDALEGRPLRGVDLSALPKDVQCSVRRVDLRDASVVGCSFFAGANFDLADCRRTDFTGSQFRDISFAGATLRGAKLQRCTFKHCVFRRCDIRDADLCGATFVGCDFTLCDMSGCTTSGDTTFFEPQSWWRSRREEWRGTKPFVNLDAEEATQQMAARDDSRSRPRGGRPRNTPRRGKTWTKKISTKR
->UniRef90_UPI001F4247D0 hypothetical protein n=1 Tax=Xanthomonas citri TaxID=346 RepID=UPI001F4247D0
-MFGEGAEIRFAYQSFKWANLAAKNAGVSVAIIGLTRRNGGTKQIFIANEDGVVTVRTVSNISPYLVPGDNVLVSPRSKVPDERAPMQFGNHPYYANELMLSLDEASGMVGEDARVAEFIRPLYGSRESISGTPRTCLWITDENLALAQEIPAVWARVEKVRKDRKTKTKDVQAKKLVETPWRFRDQYEAESSLLVVPIVSSENRPYLPVVLLSKEAIVHNKAFALYDAPLWNFALIVSKMHLVWVAAVCVRLEMRYSYSNTLGWNTFPVPTLTEQNKADLTRCAEDILLARESHYPATIADLYGPDNMPDDLLRAHERNDEVLERIYIGRRFRNDTERLEKLFDLYTKMTAGQGKPKKKAKK
->UniRef90_A0A3C0QT04 Magnesium chelatase n=1 Tax=Ruminococcus sp. TaxID=41978 RepID=A0A3C0QT04_9FIRM
-MIQTFAEKLHNSMAKAIVGKDDVIDRVIAALLCRGHILLDDIPGTGKTTLAKALASSIGCHHSRIQFTPDLLPSDVTGIHWFNQKTQEFTFRKGAVFTNILLADEINRTTPRTQSALLECMQERQVTLDGETMSLAEPFFVIATQNPIETQGTYPLPEAQLDRFFICLHLGYPEKEAERLILTGASQTISEPVCTVEELIQAQNAVENVLVSEPILEYLLAIAEKTRKDRTTIIGLSTRGLQALQLCSKAWAGMQGRNYVIPEDVQAVAPEIIAHRLIMKGGERLQRMEFRHESALRMVEEVSVPVE
->UniRef90_UPI000A359F7A tubulin polyglutamylase TTLL5 isoform X13 n=1 Tax=Heterocephalus glaber TaxID=10181 RepID=UPI000A359F7A
-MPVVMARDLEETESSSEDEEVVSQEDHPCIMWTGGCRRIPVLVFHAEAILTKDNNIRVIGERYHLSYKIVRTDSRLVRNILTAHGFHEVHPSSTDYNLMWTGSHLKPFLLRTLSEAQKVNHFPRSYELTRKDRLYKNIVRMQHTHGFKAFHILPQTFLLPAEYAEFCNSYSKDRGPWIVKPVASSRGRGVYLINSPNQISLEENILVSRYINNPLLIDDFKFDVRLYVLVTSYDPLVIYLYEEGLARFATVRYDQGAKNIRNQFMHLTNYSVNKKSGDYVSCDDPEVEDYGNKWSMSAMLRYLKQEGRDTTALMAHVEDLIIKTIISAELAIATACKTFVPYRSSCFELYGFDVLIDSTLKPWLLEVNLSPSLACDAPLDLKIKASMISDMFTVVGFVCQDPAQRAATRPIYPTFESSRRKPIQKPQRSRPLSASDAEMKNLVGPPREKMSEKLGGSVLGLSMEEIKVLRRVKEENDRRGGFIRIFPTSETWEIYGSYLEHRTSMNYMLATRLFQDRGNTRRSLLTGRTRETRGLVKFQDYCHIRLKMTTDGMPELKVESVNSKAKLHAALYERKLLSLEVRKHRRRSGRLRALKPKYPVITQPAEMNGKTEAESEEEEEEVALDNEDEEQEASQEESAESLAENQGKFAPPLTIGIENLPKENSMEVPVWNNKGEQGCKIETQEPEPNFNLMQILQDNGNLSKVQARIAFSAYLQHVQTRLMKASGGQTFSASWAAKEDEQMELVVRFLKRASSNLQHSLRMVLPSRRLALLERRRILAHQLGDFIVVYNKETEQMAEKKSKKKFEEEEEDGVNAENFQKFIRQASEAELEEVLTFYTQKNKSAGVFLGTHSKSSKHSQTLSDNGAKGDHPEMIEEVKIKQPKHQQATEILSDKLSPSLCHPNKHHSGVAKAQKEGEDGSLYSKRYNQSMVTAELQRLAEKQAARQYSPASHITLLTQQAANLNMASGAINRSSASTPPSLRPVISPSGPAWSIQCDPHAPESHSSPPGSRRLQAGGFAWEGEIENNAYSKATGVVPQHKYLPTAGSYQLHFALQHLEQQKLQSRQLLDQGRARHQAIFGSQILPNSNLWTMNNATGCRISGATASGQKPTTLPQKVVPPPSSSTSLVPKPPTNHKQVLKKATSQRASKGSCEEGQLSELQSSLNTTAFVPLPSSTDHLSSFQKGMRQETRTPNPWLDHLPKGTRELKTTRVL
->UniRef90_UPI0016748451 MarR family transcriptional regulator n=1 Tax=Streptomyces xantholiticus TaxID=68285 RepID=UPI0016748451
-MPDLSHGATDADVAAVNSLRSAVMRLGRRLKHQRVDETLSPTEMSVLGTLATCGSATPGELARKEHVQPPSMTRIVALLEAKGLVRLEPHPADRRQKVVTQTEQAETMLEESRRKRNAWLATLAEGLDDEEWAKLRAAAPVLEKLAHLQ
->UniRef90_UPI0003C1277F tubulin polyglutamylase complex subunit 2 n=1 Tax=Latimeria chalumnae TaxID=7897 RepID=UPI0003C1277F
-MDDNENSSISGFLDRLTLGVTKILETRPGVTEVKFFEKEPVERHVIISWEQRNCCTLPEDLKNFYLMTDGFHITWNVKFDDVPMQLGSMVINSILKLCRLKGSSVYALPHAPTLAILESDSDEEANESQPEKPHFDSRSRLFELDSCGGHGKVCLVYRNAKP
->UniRef90_A0A6J1YNG1 Voltage-dependent P/Q-type calcium channel subunit alpha n=1 Tax=Acinonyx jubatus TaxID=32536 RepID=A0A6J1YNG1_ACIJB
-MWKASRVPDPMFSPRSYDALHDGGRGPPAADGTAGAPQDARGPRMSGPCPGPPLKRRGGVVDHRDVILAHQAHKIHSTPQARRKEWEMARFGDEMPARYGGGGSGAAAGVVVGAGGGRGAGGSRQGGQPGAQRMYKQSMAQRARTMALYNPIPVRQNCLTVNRSLFLFSEDNVVRKYAKKITEWPPFEYMILATIIANCIVLALEQHLPDDDKTPMSERLDDTEPYFIGIFCFEAGIKIIALGFAFHKGSYLRNGWNVMDFVVVLTGILATVGTEFDLRTLRAVRVLRPLKLVSGIPSLQVVLKSIMKAMIPLLQIGLLLFFAILIFAIIGLEFYMGKFHTTCFEEGTDDIQGESPAPCGTEEPARTCPNGTKCQPYWEGPNNGITQFDNILFAVLTVFQCITMEGWTDLLYNSNDASGNTWNWLYFIPLIIIGSFFMLNLVLGVLSGEFAKERERVENRRAFLKLRRQQQIERELNGYMEWISKAEEVILAEDETDGEQRHPFDVGALRRATIKKSKTDLLNPEEAEDQLADIASVGSPFARASIKSAKLENSTFFHKKERRMRFYIRRMVKTQAFYWTVLSLVALNTLCVAIVHYNQPEWLSDFLYYAEFIFLGLFMSEMFIKMYGLGTRPYFHSSFNCFDCGVIIGSIFEVIWAVIKPGTSFGISVLRALRLLRIFKVTKYWASLRNLVVSLLNSMKSIISLLFLLFLFIVVFALLGMQLFGGQFNFDEGTPPTNFDTFPAAIMTVFQILTGEDWNEVMYDGIKSQGGVQGGMVFSIYFIVLTLFGNYTLLNVFLAIAVDNLANAQELTKDEQEEEEAANQKLALQKAKEVAEVSPLSAANMSIAVKEQQKNQKPTKSVWEQRTSEMRKQNLLASREALYNEMDPDERWKASYARHLRPDMKTHLDRPLVVDPQENRNNNTNKSRAAEPTVDQRLGQQRAEDFLRKQARYHDRARDPSGSMGLDPRRPWAGSQEAELSREGPYGRESDHHAREGGLEQPGFWEGEAERGKAGDPHRRHAHRQGGSRESRSGSPRTGADGEPRRHRAHRRPGEEGAEDKAERRSRHREGSRPARGGEGGEGDGPEGGERRRRHRHGPPASYEADAARREDRERRHRRRKENQGSGVPVSGPNLSTTRPIQQDLGRQDPPLAEDIDNMRNNKLATAGSAGAHDSLGRPGLPQSPSRTGNSTDPGPAPAPPAVAANPQNAAGRRAPNNPGDPSDPGPPKTPENSLIVTNPSSTQTNSAKTARKPDHTTVDIPPACPPPLNHTVVQVNKNANPDPLPKKEEEKKEEEEDDPGEDGPKPMPPYSSMFILSTTNPLRRLCHYILNLRYFEMCILMVIAMSSIALAAEDPVQPNAPRNNVLRYFDYVFTGVFTFEMVIKMIDLGLVLHQGAYFRDLWNILDFIVVSGALVAFAFTGNSKGKDINTIKSLRVLRVLRPLKTIKRLPKLKAVFDCVVNSLKNVFNILIVYMLFMFIFAVVAVQLFKGKFFHCTDESKEFEKDCRGKYLLYEKNEVKARDRQWKKYEFHYDNVLWALLTLFTVSTGEGWPQVLKHSVDATFENQGPSPGYRMEMSIFYVVYFVVFPFFFVNIFVALIIITFQEQGDKMMEEYSLEKNERACIDFAISAKPLTRHMPQNKQSFQYRMWQFVVSPPFEYTIMAMIALNTIVLMMKFYGASVAYENALRVFNIVFTSLFSLECLLKVMAFGILNYFRDAWNIFDFVTVLGSITDILVTEFGNPNNFINLSFLRLFRAARLIKLLRQGYTIRILLWTFVQSFKALPYVCLLIAMLFFIYAIIGMQVFGNIGIDVEDEDSDEDEFQITEHNNFRTFFQALMLLFRSATGEAWHNIMLSCLSGKPCDKNSGILTPECGNEFAYFYFVSFIFLCSFLMLNLFVAVIMDNFEYLTRDSSILGPHHLDEYVRVWAEYDPAACGRIHYKDMYSLLRVISPPLGLGKKCPHRVACKRLLRMDLPVADDNTVHFNSTLMALIRTALDIKIAKGGADKQQMDAELRKEMMAIWPNLSQKTLDLLVTPHKSTDLTVGKIYAAMMIMEYYRQSKAKKLQALREEQNRTPLMFQRMEPPSPTQEGGPGQNALPSSQLDPGGGLLAHESSMKESPSWVTQRAQEMFQKTGTWSPERGPPTDMPNSQPNSQSVEMREMGRDGYSDSEHYVPMEGQARAASMPRLPAENQRRRGRPRGNNLSTISDTSPMKRSASVLGPKARRLDDYSLERVPPEDTQHHHQRRRDRGHRASERSLGRYTDVDTGLGTDLSMTTQSGDLPSKERDQERGRPKDRKHRQHHHHHHHHHPPPSDKERYAQERPDHGRARARDQRWSRSPSEGREHMAHRQGSSSVSGSPAPSTSGTSTPRRGRRQLPQTPSTPRPHVSYSPVIRKAGGSGPPQQQQQQQPAARPGRAAPSGPRRYPGPAAEPLAGERPPAGGHGSSRSPAMERRGPGPARSESPRACRHGGARWPASEGPPGPRHHGYYRGSDYDEADGPGGGGGEEPRAAAYDAPPPARRACSPRTPRAPGPAACASPSRHGRRLPNGYYLAHGPARPRGPGPRRGLHEAYSETDDDDWC
->UniRef90_A0A7W4JVT6 Chromosome segregation protein SMC n=1 Tax=Gluconacetobacter azotocaptans TaxID=142834 RepID=A0A7W4JVT6_9PROT
-AAEAAERARAAARRALDRVEAHIALGRLERERHDEATRLDRLEHAEAEVARAGLRLAACTMDDARMAAIRQAERAVQTARAASRAQATVLNVVLEDGAEGRLVLDGRVLQTGSVDLTDSATLRIDGVGTIRIEPASGDRARLRAELTAAEDALRRMLNQAGCADPDAAETALAQRRQADLALNAARSVLSHLLPGTQDVAAAMAEARRRVAALDERIARQAASLAHGPNPADAAGGEPGVDVAATHDAALRAMQAADARAADARQALFAPDETLRQAAADLAGVRAEEQSAREAAARLVRDMAAARTAEADDVLSARQETARAALAQAGQAVQRAEAARPEGTEALADAAIRRQERLIQDGQARLGTLRQDMAALEARIRAAEGDGLDERIAGQERLRESCAAECAVCTREVKILHCLRDTLTAAERAATERYLAPLCRAIQPALAALFPRAGVTMEADFSVSRLTRRMDEPFDTLSDGTREQIAVLVRLGLADLLRARGRPAMLVLDDALTYSDAGRLERLFDILTDAADRMQILVLTCRAELFTGLGARPLTVEAVDKVQ
->UniRef90_A0A327SST6 Ferredoxin-NADP reductase n=2 Tax=unclassified Kitasatospora TaxID=2633591 RepID=A0A327SST6_9ACTN
-MDLETPPPDLYGRPRADRFFARLTAFGDRYSPALGRPGLRRSPRRPEARPVPPLHLVVVSHRVVAEDVAELRLADPSGGMLPPWQPGARIVLTLPSGRARHYSLCGDPADRHAYRIAVRRIADGGGGSVEVHDDLHVGVRLRVRRPRNGFAFCGEEKVLFLAGGIGVTPLLPMARAARQAGLDWRLVHTGRTAAALPFTDELRALDPARVTVRTDDEHGLPDAAELLAHAPRGAAVYVCGPAPMLLAVQRALPGSPAAALHFERFGAAPIRDGHPFGIRIDGRTLTVPADRSALDVAREVRPDLPYSCRQGFCGTCVLKATGGTPEHRDRRLTAEQRAAGLILPCVTRAAAGETLVLEV
->UniRef90_UPI0002D87B73 type II secretion system minor pseudopilin GspI n=3 Tax=unclassified Sphingomonas TaxID=196159 RepID=UPI0002D87B73
-MPDRMRPDERGFTLIEMMVALAVFSLAALALIRLEGATIRGATTLDTTLMAQIVARNVAYTAMTDGRAPTIGAASGIEQNGGRSWAWTRVVQPTGDARILRIDVTVLDPGGRRAGHLTVVRDGATRP
->UniRef90_UPI000FEB7CF9 aspartate-semialdehyde dehydrogenase n=1 Tax=Streptomyces cavernae TaxID=2259034 RepID=UPI000FEB7CF9
-MAQARSGRPTLAVVGATGAVGTVMLQILSQHADIWGEIRLIASPRSVGRKLTVRGEEVEVVALAEAAFDGIDVAMFDVPDEVALKWAPVAAGRGAVVIDNSGAFRMDPDVPLVVPEVNPHRARVRPRGIVASPNCTTLSMIVALGALHAEFGLRELVVTAFQAVSGAGHAGVIALRRQLSLVAGTELGTSPGDLRRAVGDDTGPFPEPVALNVVPWAGSLHENGWSSEEMKVRDESRKILGLPHLPVAATCVRVPVVTTHSLTVHARFEGDVSVDGAREILATAPGVVLFDDPAAGEFPTPADAVGTDPTWVGRVRRALDDPTALELFVCGDNLRKGAALNTAQIAELVAEELTGR
->UniRef90_A0A7X3VZR8 Xanthine dehydrogenase family protein molybdopterin-binding subunit n=3 Tax=Dehalococcoidia bacterium TaxID=2026734 RepID=A0A7X3VZR8_9CHLR
-MTTTEREETKFKVVGTRPVRHDGIEKVTGQALFGADIDLNGLLHGKVLRSPHAHARVVSIDTNRAESLPGVHAVITGDDLTPAGPMERGGGNRTDAILAQGKVLYKGHPVAAVAANSPHVAEEAITLIDVTYEPLPSVTNVEDAVAPSAPVLHEGWDDPSNGVPSSELDSPNAASLERHVRGDLEAGFAEADLVVEREFRTKTVHQGYIEPQNGTASWSPEGRLTIWCSSQGHFGIRDAVAELLDIPVSQLKVVPMEIGGGFGGKLTAYLEPLAAVLSKKSLRPVKMTMTRAEVLEASGPTAGSHVKVKIGVTNEGRITAASGKFLFEGGAFGGGPVAPACAAIFAPYNLENVRIDGYDIVTNKPSTRAYRAPGAPIVAYAVESVMDEIAEMLDIDPMEFRLLNVAREGIRRADGVMNGRIGAAEVMEAVRSHPHYVAPRDGANHGRGVAMGFCRNNTGPACVIANVQDDGRISLIEGSVDIGGSRTVIAQQLAEVLGIPVEDVNPSIGDTDSIGFTSNTGGSGAAFKSGWAAHEAARDIIAQLTERAALIWDVSPEQVRYEDGGVEHVSDTELRMSFREIAGMLPDSGGPVVGRANLNPVGQSGSYSANIVDVEVDPDTGKVDILRYTAFQDVGFAIHPSYVEGQIQGGTAQGIGWALNEEYFMSDDGAMLNTSLLDYRMPTTLDLPMIETVLVEVNNPGHPFGVRGVGEANISPPMAALANAIHDATGLRLRELPMNPQAVSKAIQEKAG
->UniRef90_A0A6G4ZTC8 Sodium:solute symporter family protein (Fragment) n=1 Tax=Chlamydiae bacterium TaxID=2081524 RepID=A0A6G4ZTC8_9BACT
-MFLDLFFAGLFLAGLYFFGIRKSEKVQTESAYLIADRKIGLFPLTATLVMTEFNTATLISFSSLGYLAGKRALSLPLVFLIGLLFYAVSVAKKWKGFDGISVASYFSKRYGRDIGIIASIALFMAMSGFSAVYVKSLLLLFSPFFPSIEPWVLSGVLVALVLVMILRGGLLSIIRTDVFSFIVILGFFPLVALFAFKTPLGTPHEMIDVSSHLPVRFVISLVVLTMFTYILAPWYGQKIFAAKSQKTAFLSVFFAAIIVFVLYGLAVMSTWFLRKNGAEVSNPEQAFPMAMMLTLPSGLKGLGYAILFAASATTLSGVWSAMCSLAVGDFLKAKNSYKRSMGLTLMFALLSFVLANVLVDKVLDKLILANIPIAALSFALLAGFYWKRTSRFGVYLSMFVGWVCGIGSYLYFGEAGGYTWYWAMWGIPAT
->UniRef90_A0A7G9G4R0 Ribosome assembly RNA-binding protein YhbY n=2 Tax=Lachnospiraceae TaxID=186803 RepID=A0A7G9G4R0_9FIRM
-MNSRQRAYLKSLAMTIDPVMQIGKSSLTPEITEAVSEALEARELVKVNVLKNCLDDPRMIAEALAERTRSQVVQVIGKKIVLYRESKTKKKLELPK
->UniRef90_P59908 Photosystem II protein Y n=4 Tax=Bacteria TaxID=2 RepID=PSBY_PARMW
-MLGIDARLFLVVAPILAAVSWAAFNIGRAAVGQLQLLIKRSRA
->UniRef90_A0A645HJN1 CN hydrolase domain-containing protein n=1 Tax=bioreactor metagenome TaxID=1076179 RepID=A0A645HJN1_9ZZZZ
-MGDGIQFWGQSFIAGTSGEILAKASADKEENLLVNLDLAEVDATRTHWPFLRDRRIDAYGDLTRRLID
->UniRef90_A0A3A4YZV3 Sulfurtransferase TusA family protein n=5 Tax=Deltaproteobacteria TaxID=28221 RepID=A0A3A4YZV3_9DELT
-MTDITPNETLDCRGLSCPMPILKTKKTIGNMKSGQILEILGTDPGTRNDLPAFAKRSGHEYLGEKQDEGFSRFYIKVK
->UniRef90_A0A4U5NX06 Peptidase S1 domain-containing protein n=1 Tax=Steinernema carpocapsae TaxID=34508 RepID=A0A4U5NX06_STECR
-MGAVHLFAVFGLLALVEAKELKLVSCFFTFQNVNRAVFSSTTASKVPFCARLELTKEPFKGQFRHIACSTLTSQFIFTSAHCVTFTANGAVFVGITDMATAFNDPNKQFVDFTPTDVIIHPEFSHKKGNGIALVKVRSL
->UniRef90_UPI0020216C25 phage major capsid protein, P2 family n=1 Tax=Halomonas sp. ATCHA TaxID=2945104 RepID=UPI0020216C25
-MRKDTRIAYNRLLDRIAQLSGVPSAKEQFAIEPSVQQTLESKIQESSEFLSSVNIIGVDELKGQKLGLGVTGPIASRTDTTQKDRTTSDVSSLESHDYECVATEFDTHITWAKLDAWAKFPDFQTRVRNAIVRQQALDRIMVGLNGTTAAAETDRVANPLLQDVNIGWLQQYRTHAPARVLSEGANAGEVRVGPSGDYENLDALVYDVVNEMLDPWFRESTDIRAICGRKILADKYFPLINQEQAPTEQRALDMILSQKRMGGQQAARVPFMPDGTLLITPPENLSLYWQNGSRRRYLEDNPKRNRIENYESSNDAYVIEDYGFGCLVENIVFGDWSV
->UniRef90_A0A3M1UPZ1 Chain-length determining protein n=1 Tax=Gammaproteobacteria bacterium TaxID=1913989 RepID=A0A3M1UPZ1_9GAMM
-MHELYEQLLTQLRGIWRFRWVIPTVAWVLFVAAAVVILRLPDEYRATATVYVDTHSILRPLLRGLAVTGNAEQRVRIMTKTLLTRPNLEKLMRMTDLDVKAATPAEREDLLDSLAARIRVESSRRGENLYKLSFEDPDRKLARKVVQALVSIFVEGLLGQSREDTDTAQKFLDRQLAAYAQRLNEAEKALADFKRKHVGMMPGEGKDYYASLKEEEEKLETARLQLRELENRRRVQRRQLAHLDEEESLFDLDPAEGGSLATPYDARIEALHQRLDELLLRFTDRHPDVIETRRLLAELEAKRKAFLAQARQEHKATGGSDPVRAQLQVLLSETESQIAALRTRVKAYEARVEKLRKMVDTIPKVEAQLKQLTRDYEVYKQQYEALLARRQQADISEKAEVSADDVKFRVVDPPHVPLTPSGPPRLLYLGLAVLGSLAAGVGLALLLHLLRPTFQDVRQLRDTLHLPVFGSVSIAVTDEIRRKRRMEMLSFGTIVLLLFGFYGMALFAELFQLGIIRQLHLHP
->UniRef90_A0A1T4V4Z1 Arabinogalactan endo-beta-1,4-galactanase n=2 Tax=Eubacterium TaxID=1730 RepID=A0A1T4V4Z1_9FIRM
-MKKRSLQKVISTILCTAMVASLTSCSIGKGGKSEKPKETGIFADIVNPELSDKHKGDAVESSVLVNKVEGLSEGFIKGMDISSLIAEEQSGVKYHDKDGNEADLLKILKDSGYNYVRVRVWNDPYDANGNGYGGGNNDIDKCVEIGKRATENGIKTLVDFHYSDFWADPNKQSAPKAWANMGIEEKEKAIYEYTKESLNKLKTAGVDVGMVQLGNETNAWLCGEINWINITTLMNSAAKAIREVDKNIIIAVHFADPSSQERYKNYLQILQNFEVDYDVFGTSYYPYWHGSLENLTEILKFAAETYNKKVMVMETSWAYTPDDLDGHGNTIGAGANVVKNYSYTLQGQVEVINDVVQAVVNVGDAGIGVCYWEGGWIPVPEGDAPRSEKWEKYGSGWASSYSAEYDPDDAGKWYGGCAWDNQAMFDENGNILESLYTFDYCYTGTKCDVAIDEVANTECTIRIGDEIKLPETVTAIYNDRHTEEISVKWEEISESAKYSMQESGAQKYVIKGVASVSGTDYDVTCDVNMIEPNYVENQSFEDDSEEGMKVWTIEDRAKDDAEHELFNMDKITDAYTGTHALHWYSKTKCDFTVTQKITGLKPGKYKASCQVQGGDTTNGAFKLTVESNGKTYEEPTEVTEWAVFRQPTIENIVVGKDGTATISFTVYAEANGTKGPWGTVDDFLFNPVEKNK
->UniRef90_A0A1H3EFD9 Cyclic nucleotide-binding domain-containing protein n=1 Tax=Ruminococcaceae bacterium YAD3003 TaxID=1520816 RepID=A0A1H3EFD9_9FIRM
-MYVICYGKSPKALEAGGKLIKDIGGRYITGTELLTGSFVIAEGETKCAIVMILPLEAAIRAMGETVTDKTRDLPVIAVSPEGHYAAIIKRGNSVYEQGTDEVYAAVLKSMGPFCFSEFESKSEITSDLTKLISKYNMAVNSEAVLDKVNAAINSGEKINVYTDLPIVFADPVIDPMTYSLHSYPYDLRDEFIKQYKATKNDKNVPSVFITCTYLGDEEDDTNLILVPKLLSLGIEIKVKTDPGYCRPAIRQSLINHLLNPMSVAKVAATYSARESEMVTGIAEELGAEVISYDAEQIANANAPMSMTFNPEKKNDTATALAFLASSEGSIVIRRATSAKGLVFSAAMNRDNIILPE
->UniRef90_A0A3B0X686 Sel1 repeat family protein n=1 Tax=hydrothermal vent metagenome TaxID=652676 RepID=A0A3B0X686_9ZZZZ
-MNHFSPLALILLLACALSSTSLAASKNKKPGPPDDFEKGLIAYQKKDYATSLMLWFPLADAGNPQAQYRLGKMYLDQKDQRKDPAEAANWIKKAAIQKHAAAQSLLGQMYLKGVGVKRSFSKSAKWLLKAARKKDREAQYILAKLYYYGDGVDKSAPKAAYWYKKAAKQNHTAAQNKLALMYLTGEGIKKKHKKAKQWFEKAALAGSTHAQINLAKLYLNNEVVKKDSHKAFKWYQKAAITGNAEAQNQLGEMLENGVGTQKNIKQAINWYKKSAAHNYPQAHYNLGRAYVNGYGITKNFKKGIAHFHQAAEKGNGKAQKDLGVAYYTGKGITPDSAIAYAWFYVAAANNVADARKTTNALYKKLTAEDKKKAIALATEYKRKYFIRPE
->UniRef90_A0A4Y2D9G6 Uncharacterized protein n=1 Tax=Araneus ventricosus TaxID=182803 RepID=A0A4Y2D9G6_ARAVE
-MVSFDDVWRAIACPWLSPHHCPSGIDLDVKSRLIRKEYVSPLLWCPTATFTGHSRALTCAGDKGTQTTGRRANIPPSCSLHDIVWRDMVLPASTESCDVSCRAVSVLRRLAH
->UniRef90_A0A2K9NRQ2 Peptide ABC transporter ATP-binding protein n=1 Tax=Bacteriovorax stolpii TaxID=960 RepID=A0A2K9NRQ2_BACTC
-MLLEVSKLNIHFKSDRSPEPIHAVRDLSFTLKQGEMLGVVGESGSGKSITNMALMGLLPDTAIVRAEKANFNGHNLLNLKEKEWQKVRGQEIAMIFQDPMTALNPFLSVQFQMVETIQGHLKLSKKDAIDKSIELLNLVGIPSPKDRLKSYPFELSGGMAQRVMIAMAISTNPKLLIADEPTTALDVTIQKQILNLIKMLQEKNNMSVILVTHDLGVVSEYSERLQVMYAGEIVETGATADLVRHPRHPYTHALLASRPGAVVDDKKRIPKTPLPSISGIVPAFHQRPLGCQFNPRCQYMTHECQQGHIAIVGEGPQNDNFREYRCIHPIEEAIR
->UniRef90_A0A521V9W9 T9SS type A sorting domain-containing protein n=1 Tax=Saprospiraceae bacterium TaxID=2202734 RepID=A0A521V9W9_9BACT
-MQPITHCMKKHLTLALLSLASILAAQPDSLTQEYIHGNNIGALLNSNGSLFWDGGNGHFIAGEDGRSLVRAAGLWIAGVGKAGNLKGAIQMYNEDGRSDFVPGLLGDTVNAENWNHIWKVTGEDILLHIRDWETDGVLDDTIASIFGWPGRGNPFFEQYNGFPLPDINSHQLAPFYDVNLNGVYEPHFGDFPMNDTRSCGSAPVPAELSWFSFHDNTPHSESNMAPLQIEVSTEVTAYRCTDNQFANNSLLLFYKITNLAQEDIDSCYFGVFFDFQIGCPNDDYMATYPEKNIFYAYNSDGYDEDCSPYNGFHDQPPVVAVTLLRGPRNEFLEELPLSVIMPIHEGSTIPGQAPPEQPAEYYNYLTGRGKDGIPLTNGGTGYNPGSTDYTNIIFPGRPGMDTTGWTELNAGTLPGRRRVLASYGPFTLQPNAVNAIQLIITQIPGTNGPLLENLDALYDSLFEAFGFLYNGCIDPTPLYPKCTEDIEIPPLPPPPPLPEEFIISPNPVSKILTIQIKDPGNVERLSIYDATGRLVFEKKMLTDVLEIDVAGWPKGTYFVRLGKGDEQFVKGFVVMRR
->UniRef90_A0A6L2N053 Extensin-like n=1 Tax=Tanacetum cinerariifolium TaxID=118510 RepID=A0A6L2N053_TANCI
-MSDVSSAVTYTLVYTDSEPWRYYGEDSAETGPPRIIVLQPVAPPSLDYVPGPEHPPSLDYVPGPKHPPSPIEIPYVPKPEYPEYLAPSNDEVPLEDQPLRADASPIAASPDYLADSDPEEDPEEDPEDDQADYPVDGGDGDNEPFDDDDTDDEDPEEEPFEEDDEEEEEHLASADSPAAALLSPPLLVPSLPLPLPSPLITSSVDTGASLSYREAGIRMRALLPSTSRRTDILGADMPPQKKACLTTPAPGFEIGE
->UniRef90_A0A3P8RZN5 Otopetrin 2 n=1 Tax=Amphiprion percula TaxID=161767 RepID=A0A3P8RZN5_AMPPE
-QGRGEPCGEQCSPWPRCSPCKCVTSDNPCEPCRMTVKDRETEEVHLSNNINAVGQTESASEPDLNDSSTEVVRERSRNWGWLLSGIICVNILILGCALVSGSAYNNVKISTPDLQVFLIIILLLTSIWMVYYVIYTARTENAVVYKDDHAGPVWLRGGLVLFGLLICNICFGFMVLKYESNCEIVLQTYFLWVHAKDCVQLQRNISRCGLMLTLSTNLVLWMTNPSARKHIITLLSFGTISCLTAGYGDDKCKCSHTSCSMFKEAYYYLYPFNIEYSLFASAMAYVMWKNVGRVAAEHGHHDIKFSLRDIFLGPVFGVLLVFTGLATFIVYEMEMKKDDHDADKKDQAVMMHFVMNIVIVTLMSVSSVIGCAIYRVDHREHVSEKNPTRSLDVGLLVGASLGQFIISYFSIVAMVATGAKGYLNGLNLAWSILMVIQLGLQNFFIIEGLHREPFHEVEPVAVVPNPYVLEPSKDLSIPEGPVMDTKPNPELTAHSHTPEHRHKLVWKRRVLKEVCVFLLLGNIILWIMPAFGARPQFDHDTETEFYKFNMWAAVVNIGLPFGIFYRMHSVASLFEVFLCS
->UniRef90_A0A267H7W8 ATP synthase subunit e, mitochondrial (Fragment) n=2 Tax=Macrostomum lignano TaxID=282301 RepID=A0A267H7W8_9PLAT
-YLLLLFLLFKMLNYLMSASRASKLTFLASLAFTGFSVSFVLWTQKSERDAVKQGVLADIERQKLYEETLQKRAA
->UniRef90_UPI00201FA0E7 ABC transporter ATPase n=1 Tax=Flagellimonas sp. 2012CJ39-3 TaxID=2942214 RepID=UPI00201FA0E7
-MLVDFETLPDTARIWIYQSNRSFSPEELEEINQALSQFLNEWTAHGSTLQAGFEVKYKRFIVIGLDQSQASASGCSIDASVHFIQGLEQKYGVELMDRMNVSFKQGEYIAYKSLKDFKKMAKAKSISKNTTVFNNLVANKLEYSEHWEVPASESWHSRFL
->UniRef90_A0A674GZ47 Rap1 GTPase-GDP dissociation stimulator 1-like n=2 Tax=Estrildinae TaxID=40155 RepID=A0A674GZ47_TAEGU
-MRTSESASESKGEAQGIHLTVTINCTVAPRANNRGGRPGPSDLTETLNKHLEHLGLCGDGTEAEDQILESLNGILLAITEDKQRSFHLLRGSKIFPTLAKILKGNPRCAVKAAHVLSEIAKNEEMKKPCIEADLVLTLIPLLESTDQEMLLHAGRAIGRICYDNRSLQEELVKVGVIPSLVRILTDYADSEPLVHVALLALYNLADLDSAKEALSMTKVAEQLVKQLRRAESHEKLEIVFEVLQALAENDALKVQLVDAGVPEVLSEILLRLQGSSQAEDTCIMKAASDLIVSLLLGDGNCLRMFQLGVVHQLLDLLEKQVQSGDTSVQQAALSALQSLAVPVVSKVQMLEEGVAERIEALLRAESPPVQFKLLGTLRTLADGQADAAEILGQDPQLLSRLVQWCSVSDPSGICGEANRLLASILHHNRSQEVVKAIQAAQGVKHLVSMTTNEHAAMQNEALNALAIASAIDLETLEESFKESQLVQSLHKLLRDDNTSPEVKYNSMGLLCRLLNSGDLRQEIEEDKIKDTLEKLCSHSNADVVKGATTTLQVLRGETPH
->UniRef90_A0A6L8ETX0 Helicase C-terminal domain-containing protein n=1 Tax=Candidatus Poribacteria bacterium TaxID=2026781 RepID=A0A6L8ETX0_9BACT
-MSRANYSNREALNDALKVYLQAMYSFVSECLDEQSIRDFLKLQSSDDLMEDIEVKDIANLIKSYSYWSKCFKEKFKIIDRDNTRYYDARSVTSLIVEGRNQLSHQWLRELDPEFTRTQLFFITDILGKIKRSDAQREVEVIRDELFNDTTEQLVTIGVEDEKAKYEKSIAEMEKRLASAEKNKKKLSKQIVDNAVKLDEKTEELEKRSEQLVSAKLSKQECEKQRDSISKQLKKVQTAHSACKEHITTISNQLTTAETERDDYKERFETASRKREEAETEWQACEESLIAMRKLFTIAAIGNQTVQVVYPPIQTDSTIRILDRRNVEKKNYLLELLEQKQPTVIYVQSEERIDQLLALVGPEKADVIGEHNERISEAEEREILEKLQSGELIAVVSNTAFSTLASPHRIEHFVFCHLVPGLDEFFRQCTPAFASEKHAYLHLIYNSEQDIKGLDQKYPDRKTLEKFYPELRKLAETNGDLIRPESLYNELDIAKQGIETGLAIFEELQLLERNDEGIRLLPPAGNKLEASEIYRRGEQIKNGAADFQAFQFEQSIEQIWEALLKELNVDNEHILEASRVYEVRAFQDAIEDSRAQSESSTDAVEDDNAVDSEDAVAKPTLKSARANAKVTEEDVTEIRSRSAAGESDSELAEADSEKKPEVKQSEFWQPIRAGEFGELFTGKPVPVSNEGWIAKTVRNIGVCLYLTNQRCYVQVYFHGANGSERREKIMTLFPKSEYTYAYRDSSRETKVQFPVLDKGRKDQDDWDEIREKLVAMGTDIYNKIDASDL
->UniRef90_A0A4D9D465 MFS domain-containing protein n=2 Tax=Monodopsidaceae TaxID=425072 RepID=A0A4D9D465_9STRA
-MEAPFLAPESSGSSQDGNVASQETVIQRHPWRVHGSRYFQLILLCILILNNAVVWVAFSAITPATAAVYGVSPGLVNIVALSFQMLFLPGTIAGYMLKERWGLRLTLLAGAFMTALSAAIRFVSLYVPPVSLRNASTDGHDVNNGGGAYALLLLGTSLAALAQPLLLNTPPDLAVHWFAVKERDLVTSLAFMCSPLGSALGVTLAPVFVSEAGADTEEDVSGSHRNDARGGLRLFLLAQLGMSVATTLLAHAGATDRPPTPPSRAAALGSQREEERVHSSDASGSRVLCMPLAWELVAPDLRRCLLCNPSFLLLLFCFGIGLGFFNALLTLLGQLLAPCGYSEAEAGALGGIFLGTGLVGAVMAGVLLDASHRYGLLLKSGFLGAWAASLFVVFTLRPDNFLVLALCFGLLGFTMLPLLPVAIENGVEITYPDVPEFFSSGLLLSAGNLTGIPLAFIFAWTIDSYEGSCRKLWKPAAVLVVVVTTACALPVLGYRPRAFGRWEAEKEQRREGLEGCGHDVATRDA
->UniRef90_A0A833JG99 Uncharacterized protein n=3 Tax=Komagataeibacter medellinensis TaxID=1177712 RepID=A0A833JG99_9PROT
-MVVTMLFATVLFVVFVTVFVATLFTVLTTLAVVLTMVVTMLSMVFAVIVFSVGDNRQGQTKGSSKQKCFFHVNHFLLIN
->UniRef90_A0A8S3R600 ANK_REP_REGION domain-containing protein n=1 Tax=Mytilus edulis TaxID=6550 RepID=A0A8S3R600_MYTED
-MNSWKMLLDNFGSLRDCEWFDVHLAIKSALESAFLYMDKSFIDYISFTYGKKTVDLNYFLNFACQNGKEIVVRWIFEQFETNHIDIIAPLLSVCRKGNKELVVYLLRKCCIEDLNLNATMQAACESGTLDVVTMLWEKFNFDIFDVESCFKSSCRKGNLNIVKWLYESFDKALFHDISVLNLACISSNIELVEYLIINFLKTSDNEMTKIEECLSYCNSSMLRFFVGKYGCDLFDLDHILSVGLSENNAEFVIWSLTNFDFKSVDLNNAVKLACQNGNFRLHTSGETRLVEWFLNSNCYESLELQQASNVSCARGKIDVVIMLHKRYNEKACNVKAAVNNACFSGSIETVYWLLNTFQEKDADLDVALAMACGNGKNNLVMWLLEKYDMKFNMKLAILETFKASLKKERSNGKLSENSSFELLNWMLKECGNHILDIKISVLLACKQGKIGHVKWLFDKFSETCRDINPSEALEAACHGFDTFAIYLFLVKRFRNRKFDLQKVMQYACEFGNDQIVEDLLKRFDKNKLNVREGIFAACLKGHLNVLRVLWLYAKPKYFREKRLVNLVSNSENSEMVNWLIAAVDR
->UniRef90_A0A6M3SAA8 L2 (Fragment) n=1 Tax=Human papillomavirus 35 TaxID=10587 RepID=A0A6M3SAA8_HPV35
-KRASATQLYRTCKAAGTCPPDVIPKVEGNTVADQILKYGSMAVFFGGLGIGSGSGTGGRSGYVPLGTTPPTAATNIPIRPPVTVESIPLDTIGPLDSSIVSLVEETSFIESGAPVVTPRVPPTTGFTITTSTDTTPAILDVTSISTHDNPTFTDPSVLHPPTPAEXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXPIPGSRPTTRLGLYSKGTQQVKVVDPAFMTSPAKLITYDNPAYEGLNPDTTLQFEHEDISLAPDPDFMDIIALHRPALTSRKGTIRYSRVGNKRTMHTRSGKAIGARVHYYQDLSSITEDIELXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXSNTTIPLSSGYDIPITAGPDXXXXXXXXXXXXXXXXXXPIXXXXXXXXXXXXXXXXXXXXXXRKRIPXFFADVSVAV
->UniRef90_A0A7C6DX07 Oligosaccharide repeat unit polymerase n=1 Tax=Candidatus Bathyarchaeota archaeon TaxID=2026714 RepID=A0A7C6DX07_9ARCH
-MGTVDLLVFVILGALCYFALRFSRFVYGDYFAPVGIFFGVNLASLAFYHLRLIPMVPLSSQAYALIAVAFFSFFTGALTATPTVALRGQPLRKRASSRHVWNSKGLGLFYYFSACVALAGWVFFVTQIVPPGWVRNLWMLQGDYEFPYHLGYTLVAGIAVPPSFVLLGAVRGKTTLPMIFFLITTVFALAIVGIKSYLTIAIATSLIVWATIHPGRLKWKHLAFLALCLVGFMALYDHFIDIFVPRHFPGSRFPTILAFLERPYLYLVGPWAAMSVVMAAPPPQAQWGQVTLFPLWKILGPGGLSVMERVPQYLPFVDIGPSMFNVYSLIGEVYWDWGWVGVILICFLLGFISTRLYVKAQNSRNWIDYLSTGFFSYGLFISFFAYYYRETLIFLLIYPVVIGPLVSKLVSSLRVPRVRPVGIKI
->UniRef90_A0A1M5D686 DNA-binding transcriptional regulator, Lrp family n=2 Tax=Caldanaerobius TaxID=862261 RepID=A0A1M5D686_9THEO
-MDKCMDVIELLYENSRLTDEQIATMTGLDTEEVKNIIKKLEDEKVLLKYRALVNWEKTQKEVVHALIEVRVTPQQGHGFNAIAERICQFDEVTSVSLVSGGYDLAVEVEGKTMKEIALFVAERLAPIDGVLSTTTHFILKKYKQEGVFFTDGPEDQRLVVTP
->UniRef90_A0A353M699 ATP synthase protein I n=8 Tax=root TaxID=1 RepID=A0A353M699_9GAMM
-MAVKSKLPKIQLIIILVTVAYFSTLGAGLSAAYGGLISLMNTGLVNRHTNKQREDLTISAQAGVGMMAISVIMRMAMVVSLTLAGHFLLKLSTDALIVSLVLGLIGFLIDKMLSNGGQ
->UniRef90_A0A8T0H0I4 Cytochrome c oxidase subunit 1 n=1 Tax=Ceratodon purpureus TaxID=3225 RepID=A0A8T0H0I4_CERPU
-MINHSEGSTVKIMFYWGYFVSSSRKTGQWMSSSSFHTDIFTNGFYVGLHEASLIVLIAWFFPSPSICSSQSASVLFVIIASVSSCCKKNDCSPSLAMLHICSTIIKRVAIQFKCTH
->UniRef90_A0A536S874 SGNH_hydro domain-containing protein n=1 Tax=Chloroflexi bacterium TaxID=2026724 RepID=A0A536S874_9CHLR
-MMHRVVAVDLLILVLLAGCNAASTATARVTPSPSGTSSPIATATPSSSASLNSVRYVAIGASDTVGVGAVDPARGSWPARIAALLPSGAAYVNLGVSGSLALQAQREQLPGAVAQRPTVVTVWLAVNDLNATIDPASYQDALGAIVDGLVQGTSAMIFVGNVPDLRGVPVYASVDKARLLAGITAYNDAIARVAARSATRVFVVDLFTGSAALVSTATVATDGFHPSDAGYQLIADRFAGAMRAKGIPLRS
->UniRef90_A0A1Q9YEZ7 Translation initiation factor IF-3 n=2 Tax=Erysipelotrichaceae TaxID=128827 RepID=A0A1Q9YEZ7_9FIRM
-MSKGRYSIINNRKVAPNNVNDDLFNEKIPFREVRLIDSNGDQLGVKSKREALEIAYRQNLDLLCVAPKARPAVCKILDYGKYHFEQQKKAKEAKRKQHTVELKALRLSPVVDTHDFETKLRQARKWIEQGMKVKIDMRFRGRMMTRQEVGKQIMNDFLEQLSDIASVEKKPSLEGNTMSLILAPQKKK
->UniRef90_A0A1R4ENY9 LigA domain-containing protein n=1 Tax=Corynebacterium glutamicum TaxID=1718 RepID=A0A1R4ENY9_CORGT
-MTLTPEDMQLFKDLRMTEFGRVIQEIIDDPDRDHDSFEDKIQQALYAQRDARDNRRIEKLLKAAGLSYTAAALERFDVTGDRGITADRLLRLGPATG
->UniRef90_A0A7J9XK46 Phenylacetate--CoA ligase family protein n=1 Tax=Pseudonocardiaceae bacterium TaxID=1873463 RepID=A0A7J9XK46_9PSEU
-MSNANSTAPASRRGAAQRLSEYRRYWDEDRETMDPRLREKKIVERIQNQLRYVYAKVPFYRRHYDAHGFTPDMVTSLEDFTTKVPVITKKMLVADQAEHPPFGSYLGVERSELTRIHGSSGTMGTPTMYGVSRRDWAGAGKFSCMALWCAGLRPDDVVHISFPFTLFFGGWGLLQAAEQLGACTFPVGTMVSTERQIELLQRLDCDVLVATPSYVNHLGTTARAHGIDVRASAISVAVMGGEPGASIPAVRESLHQLWGEVSLIDLAAGSTSEMYPFTTSMGCLESDGGVHLFQDENYTEVVSIEDPNEPVPPGTSGAVVATHLWRDSQPMIRFWTGDEGVIDTEPCPCGRTYPRMPKGVYGRLDDMLLVRGANVYPSAIESVVRGVEGSGGEFRIIVDRPADLDEITVEVERDAALATDRAPALQATLQEQFKNALGVRVAIRVVEPATFEQQTFKARRVIDRRSSS
->UniRef90_A0A7S3PQM2 SSD domain-containing protein n=1 Tax=Aplanochytrium stocchinoi TaxID=215587 RepID=A0A7S3PQM2_9STRA
-MLKDGAIDQSEEEGCVGSLKRRYLESMHKRTKTHCGGCFAIVLLLSFTVSAAYEFLQGDADFADPNQPATLAFDAVELSRELFDIAAEESEEESNHFEGVSFGYEWKDGRSENIFTPKNLQTICTIEQIMFAQSAYGFDLCDPRNINTTQTCVTSFTEEGVDTSIAGNFYRFENASFNFEDCHLLADEVVGNYSDLIYTSLSLSDSSPARFFVNSKTKSTITRSTLLLSHPVEKTAEEKLLDMEQDYFDFFGMEATLFRSVYRNPATLGDIKMSFFNIVLLENEFERMLPSDFIMAFGSMTFVAVWMGIYTKSLFLTVCCTGYILFSIPVSLFMYKVVFRILYFDFIHVLVIFIILGIGADGTFVVIDAYKQSRLLLDDDLERLVYSWSRSTATVFNTSFTTVVAFVVTGFTPLIPLSTFGIFAALCITVNFVFVCTIVPSTVILWERWFVKDKEKGVEKSEVVPELKKENSNSSFEGHFKSKDEAKHTLDALVEGNNRVFEHYYVPAILKCKQVFVLLGLVIGILGVYGVTKVSQLTKPEQWFPEDHTQSIFIEKLILEFLSGEEGEYAEVTVFWGIDKVERDYPARYSGDTETYDDKVIFDDSFDITDFQTQLAIIKMCELLENRTCDEDTCGGFTTLLFPETNTYQGMCTMREFHNWWNVEKNFSVPLNSANETLFYERLGLFVVENPEMARHVGIIGGVVKFFSIEYIMTLKILAPGSEVQNYVDIMDNIIEKYKSFAPASAQSVDYSSPDFVEYALELSLQETVIKGLAITFPIVFVVLLLATGNWILAAFSVIAIAFIVVTVMGFVFAALGWELGIAESIVSIMIVGLSVDYAIHLGHMYTVAGKSEGFESREDKFHYAVLTMGPTVLAGGMTTLGAGAFLFGAQITFFGKMGVLLVLTVTCSLFYSLVFLMSVAAWFGPQGTYANLNRTCSKQ
->UniRef90_H6QP23 RNase H domain-containing protein n=1 Tax=Puccinia graminis f. sp. tritici (strain CRL 75-36-700-3 / race SCCL) TaxID=418459 RepID=H6QP23_PUCGT
-MAGARRWIGLEALEAGYSAACGEILGSRISGYSMYTDSMCVHNSTNRTFGWARS
->UniRef90_UPI00197E61F8 hypothetical protein n=1 Tax=Salmonella enterica TaxID=28901 RepID=UPI00197E61F8
-GRGGGGGRGGDRGRGEGEEEKGEGEGGERGGKKGRRGKEKDRKEERGGRGEGGKREREKEKKGREKGGGKENIGKKKGKRRRRRKGKKEEERGEKKKRKRRKGRRKRGGGKEERKRGKKKKGRKEEEGKRKRGKRKEGRKREEGEGEKRRGEGEKERGRKGERKRETRKKKRERRGEG
->UniRef90_UPI00082B7ECA thermonuclease family protein n=1 Tax=Sphingomonas soli TaxID=266127 RepID=UPI00082B7ECA
-MLAALSLLIAAAPAGAACVAVDGDTLRCGDERVRLLGIDAPELPWHCQQGRHCAPGDPYASTRSLRAALSRGPVSLRRFGTDHYGPTLALVSAGGVDLSCWQLSHGQAIYKSWWDNGGQLARICPAAR
->UniRef90_A0A1V6AN80 Heptaprenyl diphosphate synthase component I n=1 Tax=Firmicutes bacterium ADurb.Bin146 TaxID=1852882 RepID=A0A1V6AN80_9FIRM
-MNNTKKLTISAIFTALAIAISIAESYIPYSAIAPGVKLGLANVIPMTLLYVLGPLYAISVQAVRIIVTGLLRGNLVTFFFSFFGGMASTVLCALIKKQKIIEFSVIGLSVIGAVIHNTAQFFTALVILKNINILWYIAILAIFAVIAGVLTGIIAKYTIKAIERYSRSI
->UniRef90_V7ICF6 Signal peptide protein n=17 Tax=Eikenella TaxID=538 RepID=V7ICF6_EIKCO
-MQKYILTTLLLACATTAGADNFRPQKLALIHSLYVPYQNGNTVHAHPERHFSADLRAVYQEDKQHTAPNEVGCIDYDPIIAGQDWDSASLNRTLNIRPLANGRIEAVFQQFPGDFSATQVQFVLQCSPNGRCLVDDIYSATPGHRLVSFKRSVRRCISEMTNQH
->UniRef90_UPI001C0085A9 TIGR02680 family protein n=1 Tax=Nocardioides sp. LMS-CY TaxID=2840457 RepID=UPI001C0085A9
-MTLTQIPTEGIETADQTPPKHHPYRWRMNRAGLVDVWYYYDTEFDLSGGRLVLRGTNGSGKSRALELLLPFVLDADRRKMDATGSGKVSLVELMKAGAADRTTRAGYVWLELARSVDPTDPADAELHESGTTEQHTTIGAHIRFSRSTGEAKVHYFTTDLRVGYDLELLSPTRETLPRDKLADLIGADRITTSPGTHRDRVRATVFTLTGDAGAERYAGLLQLLHTLRSPDVGNRIEEGRLPQILSDALPPLDERALNAAGEQLDGLSETRLAQGRLEAALGHVNTFFDTYRRYAATAVSDSAENTTKAASAAEAAVKDAKNRATVHAELDKARGENQARMGELDESIADLSGTIAGIKQSSAYADARDLDEREKRVEALGAAAVAALVTAERARGAEGREVRTANEAAAKGVSASERAAAAVEKARTKVDAAGVSGGLPASIAATTAPASVLTEPVRLTRDGDPTPLDRPVPVQLSVTPDDLGSAVEQARLVQVSATERGRQAAGRLDKAQALDVQRGKVEAAERRAEEADQRANEAEEVDLERQVELTTAADTYASQWRDWVSAAATVAAFGAEPDLTGTGIDAVLADAPIVIGDLSEDDLTELDHVAGMLAETVREQHTHTIAELDAADQVDDAVRNNLKVERTQLESAVDPSPTTPTWIRPRGVDAIPLWRAIDFGDDLDATDRAGLEGALLASGLLLADLHRDGTLHAENGQLLLTPTGPVDETPVTGKLIADPGSPMPVEVVEAVLARIGFGDRRSGGATTPAGVWVAPDGSWGSGPLTGRYLQPVARHIGTTARAEARRVRLAAIEVELAQLADAAEVRAAARAEARAARDRLGAVTRNAPRTQAVSSARVRAADATNRAAKERSRAHEAAMQASELRTAWSRDVSEHRAICSEFNLPHTADDLQVVRHATGEAESACRDLSNLLDQLITVVADHADAVGRAGDRTDERVEDELRAATEWTTWHREASELESVRSSIGQEAEAAKAELRECETTRKTLEGELDKARTLDSRLGVEVGTAEAEARAAAERVTTTHEDLAATFDQFRRRLEMPGITAAAFAEPPETIELSEVTPAAVRKAVTRTAAGLRRHSQGADENTLFGPQRTLERDLSGSYDVITEVRDGVRLIELSDATGRRSIADAAAELTRTVEEGRNALSERERSVFTEFVLGGVAEELRRRLDQADELIAAMNASLATIRTSHGIGVKLRWKISESSDPAVVRIKELVSTAGAVRSADQTAELTELLKDRVNEAFELDESAGYATHLHDALDYRSWHTVEVIILGPKSGQERRISRKARLSQGETRFVSYVALFAAIDAYLSGLPDTGRALRLLLLDDAFAKVDNRTIGELMGLLVRLDVDFAMTGHALWGDYPQVPALDCYEVRRVEGSAAVTTHVRWDGHTRHLRAAPR
->UniRef90_A0A3A5MMX1 DUF2236 domain-containing protein n=2 Tax=Cryobacterium TaxID=69578 RepID=A0A3A5MMX1_9MICO
-MHELAGESVLIAAGGRSILLQLADPQIGHGVADHSNFAQRPLDRLNGTLSYVYAIACGTPAEAAHATARVNRAHKPVQSDGAGGGPAYSAYTPQLQLWVAATLYDSAITMYELIYGRLDDDRADDIYREYAALGTALQVPPGLWPATRADFAAYWQRRLGELATDAATRSVARQLLHSPTGPLWLKLGMPFARFLTIGLLPAHVRDLFDLEWTPGAERRFRRTLRVIRAVYPALPERIRHWPKNHYLRSLRASMAAVG
->UniRef90_A0A4Y9ZFN4 homoserine kinase n=1 Tax=Dentipellis fragilis TaxID=205917 RepID=A0A4Y9ZFN4_9AGAM
-MQLSFITLALAFSALSVSAAPHSLAERAGKGGNKGGNANKGNANNDKGNNDAGAKAGGGGGDLQTSLTLDPSVLAKGFESDGQAQQEAGQVPSLTSSNNFINFCATTKKPITNGQQIKGGSCNPAPMGVIAATDKMPSSKFVFPKNTQTIKANQQFDVQMAIQNIVTGNFVNPNTNYYAAPQHTDDSGTIIGHTHFVIEKLDAIDQTKPTNPGTFAFFKGVNTAAKDGVLSVSVDKGLPAGIYRLASINAAANHQPVLVAIAQHGSLDDMVYFFVTEDGQPDAAAAGAQGNGTAAADVKGGAAADGQGGAAAAKGGDGAGAKGGQAQAAKGGNAQGGKGVYWLSGSGYYTVRTAMSTAPRSFTIRVPATSANIGPGFDVATPMSRPPSPTPARGADEVPLDPYKNLTTRVALYVLRCHDIPLLPSHLSIHVNNEIPFGRGLGSSGAAVIAGVLLGSALGNLNLPRERMLDYALMVERHPDNVTAALVGGFVGSYLRELDAAATQAASVPLSEVLPEYPPDAGPEWGTNPPKPPMGIGHYVRFGWAPAIRAVAIIPQFELSTAKAREVLPESYSRKDLVFNLQRLAVLTTALAQSPPDPELIYEAMKDRVHQPYRRGLIPGLPEVTSSITPKSHPGLLGICLSGAGPTILALAVSGFDAIAEDARKIFKEKGVEVIWKLLDVVSEGSLIKEED
->UniRef90_A0A1J3I6D3 Retrovirus-related Pol polyprotein from transposon TNT 1-94 n=1 Tax=Noccaea caerulescens TaxID=107243 RepID=A0A1J3I6D3_NOCCA
-MTTTRIDVDRFDGTGDFSLWKVRMLAHFGVLGLKDILTDETLLRDSPTTGAASKEELDAAKKDPQKGIAAEASSSMDPGQELRVCCELQNLI
->UniRef90_UPI0020262455 photosystem reaction center subunit H n=1 Tax=Flavobacterium anhuiense TaxID=459526 RepID=UPI0020262455
-MDADNRTIGTIDNLWVNKDMQRVVYLDVKADKTLIEDSQREVHENIADGNEKEFMYRDGDSHLIIPIGSVNINKDTKTVMASGIGYDTFRRTGRFNTQQRFDRNYERAVLRSYYPDNDPSVGYDADDDTFYSRKEFGNR
->UniRef90_A0A4Z1PND5 DDE-1 domain-containing protein n=1 Tax=Venturia nashicola TaxID=86259 RepID=A0A4Z1PND5_9PEZI
-MLRSKMICEKPVLWLRQQHTSAQDLVDAEIDTHGRIHFAGTSAAAWKIGDAYCKVKSYIPGMEYEADSINFVCSKVPTIPLPEVIHTWVDEELCRAFLILSQVKGKTLAECWHSLSSEQRTIIARTIASFCTLLAQNSESSLQSVAGRRISM
->UniRef90_A0A7V3M636 TNase-like domain-containing protein n=1 Tax=Proteobacteria bacterium TaxID=1977087 RepID=A0A7V3M636_9PROT
-MRAVAIAVLLTLGACGPQLGSLEKGETGRVVRAYNGDTLELDSGLRVFLAEIDAPQGENAYAAQAQGELEALALHRDVQLAYGGARRWVGRAREGQAAAPEAAIAHVFVKSEGGRWFWLQHELVSRGAAYVRPRRDNHARTPELLALEAQARAAERGLWDRREYRSLSVRAAARLATESGGNCMRGDAPYRVIEGEVGEARVSESRALLRMEGAPAETTFALVVFGDNFRAWDGAPLASLNGARIRARGPLGVYAGEPQLCLEHASQLEVLTD
->UniRef90_A0A1C6CXG8 Membrane protein of uncharacterized function n=1 Tax=uncultured Clostridium sp. TaxID=59620 RepID=A0A1C6CXG8_9CLOT
-MKRVSLFIIVNAISLYLVSLLMNSMYIGSFGALIILTIIFGALNLTVKPILEFLSLPITFLTLGLFLLIINAIVLKLAFGLVPGVYLYGFVNAIGASILLSIVNTIIYKILD
->UniRef90_UPI00097C6FDA NAD(P)H-quinone oxidoreductase n=1 Tax=Pseudomonas sp. KK4 TaxID=1855729 RepID=UPI00097C6FDA
-MTLPHTMTHIEITQPGAPEVLQPRQVPVPTPGDGDVLIRVHAAGVNRPDALQRAGKYPMKPGMNPIPGLEVAGEVVAVGSGVRTFNIGDRVCALTNGGGYAQYCAVPASQTLPIPEGVDWLHAAAIPETYFTVWANLFEMGGARTGHRALIHGGTSGIGTTALMLCREFGIEAFATAGSADKCAVIGELGAQAINYRDQDFAKVIAEKTAGKGVDVVLDIMGGSYLNGNVAALGMEGRLVMLGFLGGAVAKEVDLLSIMAKRAIVTGSLLRSRTREEKAAIAQQLREHVWPVLAAGRCLPMIDKVYPLADASLAHARMEGGDHIGKIVLSVVQ
->UniRef90_A0A3D2TG15 Serine protease n=1 Tax=Planctomycetaceae bacterium TaxID=2026779 RepID=A0A3D2TG15_9PLAN
-MTPIVRAVRDARPAVVNIQGQKSVSESAEGTPTSPRQVNGMGTGVVIDSRGYILTNHHVVAGVRRINITLAGGQTYVASVVAYDKTTDLAVIRIRTPSPLQTIRLGTSEDLMEGEAVIAVGNAFGYEHTVTTGIISALHRNVQVNEKQQYLDLIQTDASINPGNSGGPLLNIDGEMIGVNVAVRAGAQGIGFAIPLDKALEIAARLLSIEKLDNHWHGMTALSLDGPTGPVTIARLDRKSPAERSGLQRGDQLQRIGKTSIHRPLDVERALLGRGSGERVPLIVRRGDETLKLDLRLANRSHKRSRGTTRQLSSAIALQQASWDTLGLKLEVEPLDSFQELEVPYRGGMRVVSVRPGSSAAKQGVQTGDVLVKMHRWTTASEKDIRFIVEHADTLARAGKVKFYVVRGEETFFGHLSVAKRSESAVR
->UniRef90_A0A7I7W7J5 6-phosphofructokinase n=1 Tax=Mycobacterium branderi TaxID=43348 RepID=A0A7I7W7J5_9MYCO
-MIKRIALNGHRATIVTLTMNPALDITTSADRVLPTDKIRCRGTRYDPGGGGINVARVARVLGASVSAVFPAGGPAGDMLANLLVGEQVPFHRVRIASSTRESLTVNEESSGQQYRFVLPGPQLTFSERAQCLDELRMAASSARFVVASGSLPPGVPAEFYQSVADVCRELGARLVLDTSGTGLQHITSGVYLLKPSVRELRECIGRDLGTEAEQVDAVQELIARGVAEVVVVSLGAQGALLVTKQGAQRFPAIHMRSGSGVGAGDAMTAAVTVGLCRGWPLAKSVQCGIAAGAAMLMTPGTAVCRRDDVERLFELAAEPVDLSSVSR
->UniRef90_A0A499UVA6 Secreted protein n=1 Tax=Streptomyces antimycoticus TaxID=68175 RepID=A0A499UVA6_9ACTN
-MLGAEVVTLGLQLDVLRKGGGEHLQALGHDFLADTVTGDHCEANAARHTGTLPLVPWIDIAVPAFGQPPSGNHPFTPCMVRC
->UniRef90_A0A5P1EE21 Pyr_redox_2 domain-containing protein n=1 Tax=Asparagus officinalis TaxID=4686 RepID=A0A5P1EE21_ASPOF
-MGNARDRLASKFAAKNAGLWSMDPNQIEEHKGNYANEFIERVRLCDVSAVIQEVMESYEVEINGKVFKKAKKVVVIGGGYIGMEVATATIGWNLDTTEDDDVNSANEGSLPHLRPMGTVVNRHPRHGNRHTRAYGDVLHPSRLQPAGGLMASLCSLVQRFVNRAQQYHKGTVVC
->UniRef90_A0A8K0D6L2 Peptidase S1 domain-containing protein n=1 Tax=Ignelater luminosus TaxID=2038154 RepID=A0A8K0D6L2_9COLE
-MAKPTFLVLVCFLLMETYESRRQLKDYPFMKFSGIDDYPFHEEEASSLRNKMVPLVVNPPEQLQPPGFSIVVFRRSSIIGSGAIIAKYFALTICTLLKNLGEETFDLTPITKIQYVLHNSSVDDVDVITPIIHKLIPHPHCGNMKKWNPKANIGLIQTKEPMDKTASLRYPLLLTSGQPIPKGEYILSNFRIKNPNAINIKQAIWYVISKPASHQLCRNLFRADRQAYDTQTNLCMSYVHVGDADSCKGDLGIPLSVRHKNRDYLIGFSVHKHYCGSPKEVASFILVGPNKKWIESTIKKLQS
->UniRef90_A0A6B2C3S4 DEAD/DEAH box helicase n=2 Tax=Thermoprotei TaxID=183924 RepID=A0A6B2C3S4_9CREN
-MQPDFTIEVPTFSIPYSNMYLSDSLRLNTFQAEAYNKINNRRDLVLVAPTGSGKTLILLLNNISAQDKIRGFAALYPNNTLLINQMRTVEEILIEHLEAKEVERVTSGCDNEGNKTEICKEEIFPLKIYKINRGKAEGPWSDTEYAAIMALSGKYIKPTSEETKSDVVYRLVEKLYEYSRKNNLYVIVFATPDTYLLVSTGAYRNFELVGKTLHNILVALVNEKSIDELDNILRRTKVLTRDQVSKSLSVYHQLLNQLPLFIDEFHLYSPFELSALYVIIKIYKSMSDLPIVFSSATPAKEIINELRDAGINPEMLNAEIIHGGDGFHVKGDSVIEVIGVDTGKKGLPAYYEAAEKVPGIVTEDLFDEVKEIDRYKDGRALIILERLWMVTRLAEELSKKGIRPDCIASIVPSKICAKGSNVIVGSEATTQGVNLGKIVWGITAGVSSEDVIQRIGRFGRKGVSSKIYLVLPKHVLEKNLPKSTMNYYELTEWLSKVYLDYPKRKKDVSNIIPSEFYNVRKKLIHAYALSSMVRVSGMKGLGEIDLKKEEALKLLNSFIGDSRALVNLLVFRRTGFSVEFIDIKYGEQGEASIGLIARNFKVLAYKGGKLEIDLSQSERQELVLSLNKEPRSFVNKFIDIRTLLKLLKGSLKIGDSLMLDEKSVGEGLVYVVDAGEDLAEYLSYTGEGARTVYTGGSEIRYAIMFI
->UniRef90_A0A6P0Q7Z9 VanZ family protein n=1 Tax=Microcoleus sp. SIO2G3 TaxID=2607795 RepID=A0A6P0Q7Z9_9CYAN
-MPSHRSWFFALWFYLGILAAISLAVYLKIIPSKITKIQPIDTILHFIFIGFLAYIGHLSIKKYKIKIFQIFLPIAPIIVLFFSFIDEFIEIFIWRAGFDKLDSAADFCGVIFFTWLAERRHT
->UniRef90_A0A0N4VJ66 LisH domain-containing protein n=1 Tax=Enterobius vermicularis TaxID=51028 RepID=A0A0N4VJ66_ENTVE
-MVEQCDKLLNFLSNEDSVKSNTEDLAIVAMFAPQPKAQATTRPAQMLTSQSEASAKENHKLYKVLGGIVLKVRLAGYVYEYLILNGATKTAECFKSEYLSTITKAMPTLQSSDPPGFLQNWFFLFWDLYSAAPEKRDSCEASQEAKAFHEFGFMNPSHGVPTGPVSGPMMNGMHTSHMFSSAAPSPLSLGPGPGGDGMMPGGGYYPPRSAQPGPSGSTSQASPISGVPSAGNFAAVPPRYGMPAARNGPPGPGGMPPAGFPGGAPPHMFTGSEQMRPLPAQRLPPNAGPMRMPTGYPGMRPNGPMRYTSPMYMESPTGAPFSNTMMPNGAMCSSSAASMMSSPGPGGPMQSGPESQDPRSYMMMSSASSMQYMHPEGSMTPGAGGRGSAGPPCSTSDPQMTSLLNGDEMKHSPASTHGGISCGTPSATGGPGSQAAVGGPGSVAGAGVGGPGSVHSQSGGSTGGQGGPPISQGGNAVSGQEEASEISKIKQSLFDDMKYGGKEESTTDNYHQYP
->UniRef90_Q0I9X6 Membrane or secreted protein n=1 Tax=Synechococcus sp. (strain CC9311) TaxID=64471 RepID=Q0I9X6_SYNS3
-MNLTKFILRASLLVLAVLVAVAFVLVRRDSIVGGDSFVGDQTKSQRFLVRNGRDRTQSPSTSNSY
->UniRef90_A0A1B6BJ90 Fe-S oxidoreductase n=1 Tax=Fusibacter sp. 3D3 TaxID=1048380 RepID=A0A1B6BJ90_9FIRM
-MKTLFMTLNSKYIHSNLAIHSISKYIKRYCTHYDALHDDVLVKEYTINQSQDDILRELIEIDADVIVCSSYIWNIEALIILFSNYRKLNHNSYIIFGGPEVSYDAKDKLEKQAFLDMIAMGEGERTITQVLDLIYEQFKNSNPRNALTANFSHVSGVAYRAGDLISVNSKRIPIEPLDEIPFVYDDFTPFENRILYYESSRGCPYSCSYCLSAAEKGVRFYSLERVFNDLNVFLEKKVSQVKFVDRTFNVDKEHALSILRYLIEHDNGITNFHFEMTATLFDEDYFKLLLNAREGLFQFEIGVQSTYKETMIAINRPIAFDKLKINCMRLLKMGNIHIHLDLIAGLPHEGYERFLRSFDDVFEMNPHALQLGFLKILKGTPIMATQEKHGYEFRKQTPYEVLYNRYIRFEDLTKLKNLETVLEYYYNSGKFKHSIQYLLKTEKGTPSDFFLKLCDYFKAHDLMYIAHSTANLYDILYEFYQENYENHALFNDLLKFDYYYAHMKGLRPFFVMSEIPQFNTRRLHYLKALEHQELINPFYVGMQSKQILKTVEFITLNYDIIALIQSQYEFIEAKLNVVLFDYQRANHAIEPSKYFKVELPVI
->UniRef90_A0A2E4DAR7 ABC transporter domain-containing protein n=1 Tax=Halobacteriovoraceae bacterium TaxID=2026745 RepID=A0A2E4DAR7_9PROT
-MKYRLNRKFIPWLVLHSIEYWYYYLGALFCLVMLHHFSSEIPMLAKELGDLAIAGKLDEIEIKTFFLLAIYILFFRTLSRLLFFYPARIQQRNLRMELVNRLEVAPPRNYKNYNEGMLFQTLYNDLNRIRGFVGFALLQFGNIIIATYIFVPKIRDFNPDFLVAFTPLIGTVFCFALIVGGFFPFVKRQMDQYADVQNFLLESYEAKKTIQNYHAEKDFYKYFDEVSGKELKTFFISSIGRVISFPLVKLGFGASLIWAALIVKNDNLPASDLIYFSSFLFLILEPLMFVSWIGIVTTQGYAAWVRIKSLVRDLSAPLTADWLVNQSGLESVRMPLWDHEIEVEFPKNQWSVIVGETGSGKSWLIENYAQYLQVKGKRYSLIHQEPYIYNDTILDNIFLGQEVTLEKLKLAKEYLHKFGLDILAKNMDDLLSLELGENGKRVSGGQAKRIALIRSLVADVDFVLWDDPFSSVDLILEAKILDDLQKEASLKNRTFVLTSHRLSTVRACDHITYISKSQGIIEKGKIEIILNQKSRVDEFFNKQMA
->UniRef90_A0A0C5PBV5 TrfA n=11 Tax=Enterobacterales TaxID=91347 RepID=A0A0C5PBV5_ECOLX
-MTDNKTHSELDKLKEAALAQRKKTIDEKNTQKQLTLFDIAPWPDSMRALPNDYARSALFTVKNKRQPREALQKKEIYHINKDVRITYTGLELRADDDELVWQQVLEYAKRKPMGEPITFTFYELCQDLGWSYNGRYISKAEECLTRLQATAMQFISDRVGQLESVSLIGRFRVIERGTRSSRCEVMIDKEMVLLFAGDHYSKFVWEKYRKLSPTARRLFDYFGSHREPYPMKLDTFKLMCGSDSDRIKKWREQVNKACVELKESGLIHSAWVDKDRIYCKRSTDEPKSDGDT
->UniRef90_UPI00036E30A4 DUF4170 domain-containing protein n=1 Tax=Methyloferula stellata TaxID=876270 RepID=UPI00036E30A4
-MSQEAPAQLLHLVFGGELENLEGATFKDLSKVDLVGMFPDYASAYAAWKSRAQATVDNAQIRYFIVHLHRLMDPAKGE
->UniRef90_A0A151E9N9 DUF3467 domain-containing protein n=1 Tax=Euryarchaeota archaeon SM23-78 TaxID=1803821 RepID=A0A151E9N9_9EURY
-MEKKEMPLIQNLDNNPLLSNQHAIVHNPDKFIIDFKGLYPQFTPDNKPQMVLTHKVVVLEPYVAKEFVKSLSDNIKKYEDKFGKIKEPKAVEKARKESKKADKKNKSTTPRPSYMG
->UniRef90_A0A8S5REQ6 ABC transporter permease n=1 Tax=virus sp. ctkyY8 TaxID=2827995 RepID=A0A8S5REQ6_9VIRU
-MHTSVLSRIVRVFQMILTELSTKRRILTLFLWVGVVI
->UniRef90_A0A6P6A4G9 zinc finger protein 6-like n=1 Tax=Durio zibethinus TaxID=66656 RepID=A0A6P6A4G9_DURZI
-MAENSISNKSSSADMAPDKQSDQKPSSSLKLFGFSLTEQDEILEKAEDFGESRKFECPFCHRVFANSQALGGHQNAHKRERQRARRAHFHSHQRFIAAAPVLSSHAVRSMPPSFPRGFSSNSAGKLVSQPGYYPSQPLLLPPTPSQYTPRIYIARPLHFGTAGPGFAEFSGKLPEADIGIDLHLKLSPSGS
->UniRef90_UPI000767A53D serine/threonine-protein kinase 17B isoform X2 n=3 Tax=Vespertilionidae TaxID=9431 RepID=UPI000767A53D
-MFTIFLLLQKCLETVLSRGKFAVVRQCISKSTGQEYAAKFLKKRRRGQDCRAEILHEIAVLELARSCPHVINLHEVYENTSEIILVLEYAAGGEIFNLCLPELAEMVSESDIIRLIKQILEGVYYLHQNNIVHLDLKPQNILLSSIYPLGDIKIVDFGMSRKLGNACELREIMGTPEYLAPEILNYDPITTATDMWNIGIIAYMLVTHTSPFVGEDNQETYLNISQVNVDYSEETFSSVSQLATDFIQSLLVKNPEKRPTAEICLTHSWLQQWDFGNLFLPEEMSSPPQDQDHTTRSSEDKTLKSSCNGTCEDREDKENIPEDSSVVSKRFRFDDSLPSPHELVSDVLC
->UniRef90_A0A0F5JDP3 N-acetyltransferase n=21 Tax=Tannerellaceae TaxID=2005525 RepID=A0A0F5JDP3_9BACT
-MGVVIKEVTSKKELKKFVKFNIDLYKDNPYHIPGLIEEEMVTLDKKKNPAFEVCDAIYFLAYKDGKIVGRIAGMINRRSNEVWNQQRARFGFLDFIDDAEVVDALFNAVEKWAKEQGMKEIHGPLGFTDMDHEGMLIEGFDQLGTMAAIYNFPYYPQHLERMGYEKDQDWHEFKIYIPEGVPDKHLRIGEIVKKKYGLKTMKFKKTKEIWPYAQKIFETLNEAYAPLYGFAPLTQKQIDYYVKMYIPMIRLDLVTLIIREEDDTVVGFGISLPSLSHAMQKAKGHLFPFGWIHLLKALKTKPKVIDLYLTGVLPEYQNKGVNALLFNDLIPVYIGLGVEYAESNPELASNNAVQAQWDYFKREHHKTRRAFIKKLK
->UniRef90_UPI001C659291 IS30 family transposase n=2 Tax=Arthrobacter sp. AQ5-06 TaxID=1914304 RepID=UPI001C659291
-RAAIPSEPSKRQGDLGHTHHPRVIETLRQLRSHPQQNRKEGDLIIGKGNQSAIGTLVERSTNYTMLVHLPDGYKAEQMRDALAAKIKTLPAALRHSLTWDQGIEMQDWKTVKIDTGIEIYFCDPHSPWQRGINENTNGLLHQYFPKGTDLSIHSAADLDWVAQELNDRPRKRLEFRKPIELIENLLLQRPPESADPSTGRRVGARANLLIRS
->UniRef90_A0A6G1SZ52 Flagellar basal body rod protein FlgB n=1 Tax=Dehalococcoidia bacterium TaxID=2026734 RepID=A0A6G1SZ52_9CHLR
-MNTLFDTTAMRAAKAALTGLSRRQEAISANVANIDTPGYTRRAVSFEGALEAEVMRSQGAAAPGELVRTDAAHLAHRGGSQLGGAGASGDVTRDVVSARNDGNTVSVDEEMLLLVETQLRYQALTQSVGRRLSTLRSVIRG
->UniRef90_UPI001939DEA2 hypothetical protein n=2 Tax=Microvirga TaxID=186650 RepID=UPI001939DEA2
-MHLFGALELEIRPGTPDNPASVKIALLRYTRGEDGRLFITPECTSFEEIEGQINSLQDELDEIRERAQRAFQVT
->UniRef90_A0A7W0G2E6 HNH endonuclease n=1 Tax=Acidobacteria bacterium TaxID=1978231 RepID=A0A7W0G2E6_9BACT
-MRGEFSNPTRRQAFERAGGRCEICAIPFTPGKFAYDHRDPEWMCGDSTLGNCQVICNQCHADKTAVDAGNRSHVKRLIDRQLGIPKRKGPPMAGTRASGWKKLMNGQVVERR
->UniRef90_A0A4Y3PSW6 BPL/LPL catalytic domain-containing protein n=4 Tax=Paenibacillaceae TaxID=186822 RepID=A0A4Y3PSW6_BREPA
-MPFYWWEQTPVQLLATVSRPYRGEVLIPFSVDEAYARLCSQEPTTAPVIHLWRHEKAIVLGARDAKLPHAAEAVRQLEAAGYQTAVRPSGGAAVPLAPGVINLSLVMPVAASDLNPEPFFLRMVELIRATLGDDGAKMSSGEVEGAYCPGTYDLAIAGYKFCGIAQRRLTRAVAVQAFINVEGCGRTYEEIIQSFYEKAAMGAPGEQFPQVQPGRMASLSELGVSGGVEGFVLRLQELLHAHAESSVAVLDACPDSLAHEAKQALDLLKGRHRQLVGS
->UniRef90_UPI001657DD0C hypothetical protein n=1 Tax=Sphingomonas sp. JC676 TaxID=2768065 RepID=UPI001657DD0C
-MTIRSRPSLWLALVVPPLAWYGFQQGLATTLRGACGAAGVPLGPLWGAGSIALCIGAGWFARPRPGQQSSDRLLSQLGVLAAGLFSLAIFYQSVATMIIPPCAR
->UniRef90_B7K1R7 Transcriptional modulator of MazE/toxin, MazF n=1 Tax=Rippkaea orientalis (strain PCC 8801) TaxID=41431 RepID=B7K1R7_RIPO1
-MVTYNQFDVVVVPFPLTDKTTSKKRPALVISDMAFNLSLKKIVMAMITTSGHSSWMFDVSIVNLAASGLKSPSLIRMKLFTLDDALIVRKIGTLTQSDQERVKNSLKQLFKLL
->UniRef90_A0A846C4J9 Cobyrinate a,c-diamide synthase n=1 Tax=Okeania sp. SIO2F4 TaxID=2607790 RepID=A0A846C4J9_9CYAN
-MSLIVAGERSGVGKTTITLALLAYLKQQHLKVQSFKVGPDYIDPMFHQYVTGKPCRNLDPVLTSEVYVQQCFGRNIQDVDCALVEGVMGLFDGVRFFDPPLPPLERGEKDDGDGCFPSFASTAHISRLLNLPVLLVLDCSRLSASVAAIAHGFVSFDPSINFAGLILNRVGSDRHLQLLQNSLKCINSPILGVFRRHQNISIPDRHLGLVPTDEMPDLDILINDLANLAKTCFDWEKLLPILKVENEIYQYLLSSQVCSDQTIYLPSLVANNFEKKRSEILIGVARDRAFNFYYQDNLDILEELGAKILFWSPLKDENLPVGIQGLYFGGGFPEVFAQQLSENFMVRKAVKEAIISGMPTYAECGGLMYLSEAIIDFNSNSWEMVGILPTKAVMGKSLKLGYRQAISNIDTPLLVANTQVYGHEFHRSELTEAPPMPLYKMWRVDEKKNQSQATFEGWNFEIVHASYLHLHWGNRIDIPRRFIEQGSRGVREWGRSQNKNN
->UniRef90_A0A1T0CQ58 Prevent-host-death protein n=2 Tax=Moraxella TaxID=475 RepID=A0A1T0CQ58_9GAMM
-MMIDFATLPITVQERIVNLQEPVSILKDGQVVAVLSPKSYDAKFDFARIQASVSSGQVAVPKTATADIDAFDRWLADVAP
->UniRef90_C5M2E7 Topoisomerase I damage affected protein 11 n=1 Tax=Candida tropicalis (strain ATCC MYA-3404 / T1) TaxID=294747 RepID=C5M2E7_CANTT
-MDIDEQLRYLALKEMCVVEIKDHITNLNNKLNEHQKELHHLREIIQRSLYKELSTGNSLAKATETRPRQNSNPRDEAIARTRRRRSSLFNDHHNKDFVTPPINDTTTNNTTPATVTTTANPESTSRIWSGLSKPLNLIQQFDTLIQNEFEKSLLSEKDQQVHNDQSRKLEKQISHQSKSSEGSISSIGSINSPLQSKSVNPRPIPMPKPYHNKPSKSDDMMQSVSSSLWSFVNDVKANVLSSLQEDERERKISGQNPPARMYNLDTGSTVDISQTSIAVEDDESETELLEPLASDEEDNVIETLDLSMYKR
->UniRef90_A0A6B8KL02 Type VI secretion system contractile sheath small subunit n=1 Tax=Methylocystis heyeri TaxID=391905 RepID=A0A6B8KL02_9HYPH
-MARPSDSGQKFISRNRPPRVQIVYENPNNAEEKIELPFVMGVMADLSGNASGVEKQEVAQRKFLDIDMDNFERRMEAISPGVSLRVANKLADEPGEKLSINLKFQRMEDFGPAAIAEQTPALKKLLDARTQLANLLRYMDGKVAAEEQLRKLLKDPQLMAALRQHFPDQQNNEQ
->UniRef90_A0A1Q3DY06 Dipeptidyl-peptidase V n=2 Tax=Lentinula edodes TaxID=5353 RepID=A0A1Q3DY06_LENED
-MVHSSFQFKEGADVFTPKDLMELGRPGVGVANHAGDFVIIPYSKYSFEEKKNHKSIYVAPLESTVKPFKLPLVEGGEAFWLNGKTLAYVVESEQKNLEIFALDVLYQPSTNDSAAVLSTNAPILLGSFPTTSASNFRYSTDGYLVFSDSVYSDGNLTTVKEQDEAWENRGNTALVYDRTYERHWDHWVGPKTQSLFSVRLVQDPNHMWTFGSEFVNLLAGTGHSSPVEPFGGTDDFYVSKQSVIYTTLDPAFEEERAWHTKQNVYIVSITAAGKPRELTSGSQGATRSPVLNDAGDKAAWLELDEDGYESDRAKIVIYDLKKDVRFTLTQKWDRSPGSLAFSKEGDFIYFTADDHALVKVFVLPIPSTPAKSTTDPSLSPKYLNPVTIVEDGASSGLQTLPYGRILISKSSFTSPNDVFLVKGLDALQAQITQSNGTARFTGEIDQVTNFTAPDLEGKNLSKGENFWFKGANDIDVQGWILKPKGWKHGEKKAFPILLLIHGGPQGAWEDQWSTRWNPNVFAQQGYFVVAMNPTGSTSFGQAFTDAIAGDWGGKPFVDLQKGWKYVLENYPEVDADRAVAAGASWGGYAINWIQGHPEFDFGFKALVCHDGVFDSNYNGFSTDELFFFNHDWRGRPWDKNSEEVLRKFNPANFVHKWSTPQLLIHGSKDYRLPETEGIGAFHALQQLHIPSRLVIFPDENHWVLNHGNSLKWHYEVLRWFDQFVGKKD
->UniRef90_A0A2N1ZL77 DNA repair protein RadC n=1 Tax=Gammaproteobacteria bacterium HGW-Gammaproteobacteria-12 TaxID=2013794 RepID=A0A2N1ZL77_9GAMM
-MTAFSPSRAACASRIGGWAGYRPATAEQILDAARKVIDQKVQRGAAFTSSELVKDYLIAKLGGFEHEVFAALFLDAKHRLIQYVEMFRGTIDSASVYPREIVKEALRLNAAAVIFAHNHPSGIPEPSQADKVLTQRLKEALALVDVRSLDHIIVAGQRTVSFAELGLL
->UniRef90_UPI0021149202 TonB-dependent receptor n=1 Tax=Pseudomonas sp. LD120 TaxID=485751 RepID=UPI0021149202
-MDNLSLTLGNRFDHSEKYGNHNSPRAYVVYHPHPDWAVRGGVSKGFRAPSLKEGSAGAATESRGRGCGSLRPLGYVTGSCWMAGNPNLMPETSTNKEIGVAFEHDGWEAGLTYFHTDFTDKIEYGPLGQYQGRWWTMLENVDKARTRGWEGTTRVPLGDSVTWRTNATYMLESRNLSTGEDLISSPKLSAFSALDWQINDRLSTELSAQHVGKQRGMGNDFVQSYTTYDLTANLAVTKWLTLNGGVQNLMDKDLRDGSTNFYVPGRAFFAGATTYF
->UniRef90_UPI0020420B8D Na+/H+ antiporter NhaC n=1 Tax=unclassified Staphylococcus TaxID=91994 RepID=UPI0020420B8D
-MGKKSENSDKNHKTKKPLGLTSALVTLTIMISTMLFTVAVLEKEPHIPLMIGTAVAILITMLHGYEFSEVEEMMYKGIRHALPAIVIIILVGLIIGSWIGSGVVATMIYYGLQLIDPRFFLAVVLILCGIVALAIGSSWSTMATVGVASMGIGISMGISPGMVAGAVICGSYFGDKMSPLSDTTNLASGLTDVDLFEHIKHMFYTTIPALIIAVVAFFFMGLQFGGKHFDTKKVEGILTTMQDNFTISPWLLLIPLIVILLVVVKVPAIPAICVGIILGFFAQIFVQGDSLTDALTALQTGYKIDSGNKMVDELFTRGGLESMFYTISLTLVAMTFGGVLEYSGMLSALINVILKFAKSTGSLIASVIVSCIGTNFTCSEQYISIIVPSRMYASTFKEKNLHPKNLSRALEDGGTLTSVFVPWNTCGVFIASTLGVSVMEYAPFAIVNYLVPIISIIYAYIGFKIVKLNDDRDTSLKEKPLSQSKPV
->UniRef90_U6R8E6 Transposase n=4 Tax=Phocaeicola massiliensis TaxID=204516 RepID=U6R8E6_9BACT
-MRYALDIIKKWQFNFPILKYVTGKSGYNVKIRKLLDQIDREVKIFDKDSFDNIYNALYTMGSSKLCRKTHLDMLTKVQVNMYVSGHHKEGSSAVKHNSSLILKDRFIFMCAAYKQLNVIEK
->UniRef90_A0A534PU07 MarR family transcriptional regulator n=1 Tax=Deltaproteobacteria bacterium TaxID=2026735 RepID=A0A534PU07_9DELT
-MRLLWAVDHSLQSASKRMESTYGITGPQRLVVRIVGRFPGIAAGRVAEILHVHPSTLTGILKRLEARSVLQRRSDPRDARRALFGLTAKGRKLDSVKTGMVEQAVRRVLTRDGEKVAAAQEILAALAEELEIEE
->UniRef90_C4GAH0 TonB-dependent receptor n=2 Tax=Shuttleworthia TaxID=177971 RepID=C4GAH0_9FIRM
-MSRADFRAENLGYLAQSQEIAGAVSGLNFGEQSGIVIIENVPQRSEDNGYKI
->UniRef90_UPI001F50FB05 type I restriction endonuclease n=1 Tax=Enterococcus faecium TaxID=1352 RepID=UPI001F50FB05
-MIRVLGEGHNQWTYRPDLKSEEDLWVNLRQKIISNNQAELNDSPLTDKEFETIKTELLLRTKTPFEAAKWLKGENGMARITIEREDPQLGSASLILYSNQDIGGGISTYEVVHQIAKRGSNIEARDRRFDVTLLINGLPIVQIELKQVTA
->UniRef90_A0A061J7E0 Secreted protein n=2 Tax=Trypanosoma rangeli TaxID=5698 RepID=A0A061J7E0_TRYRA
-MSPRRVCLSLQLHLCGAKLPFSLTSGGGCRYAHTGRPSTSFLWFSHKREKAARNVTFPPEATCSPSRAASKMSVVGGTLASSSSPPLLLDPPFTPVPGESQALRQRTNCGAPSFLLLYVCGTCKSPLFCSSEYAASSSLGQHSSGWPSFTAPVCNSVLQLRSLLQRSAVQEGGQTPLTATLAARGLRVEGEMRRQTRGGGCERLRPRTWREECLRDENKRSDPTVLEGCCTKCGRAVCRVVMERRRGVKYVVNPTAVNAELTECSDPGVASTPHPSQLPH
->UniRef90_A0A4Q8QWM3 Lipoprotein n=4 Tax=Bradyrhizobium TaxID=374 RepID=A0A4Q8QWM3_9BRAD
-MLLRTCLAVIAALIVSASSAQAQAPTTHQTQPVQFRTLFKVLPDPRGEFVRQCAPHMLGRWAHPEAVCGCLHDYAAATVEDPDLREALLRGISETGVPTIETDWVPPSKQSEIGPTFTKIAKPTLQCMFDPATE
->UniRef90_A0A7W2L3H7 NADH:quinone oxidoreductase n=3 Tax=Pseudomonas TaxID=286 RepID=A0A7W2L3H7_PSEPU
-MNRFCLLVAGLAPLLGATSSVAQGTAIGMSMLVLILAHQVLLSPLRSQLQGARYWLASLLIVAALASCLQLVLRAWALPLALSLGDFPLLIGVQCLATDSLLPNQGRWRQLLRYLSGLLFISVLLGASRQWLAEGLGLHLASLPSGALLLLGLLLALYNCLRPGPARQGKR
->UniRef90_A0A2V8UVF1 PNPLA domain-containing protein n=1 Tax=Acidobacteria bacterium TaxID=1978231 RepID=A0A2V8UVF1_9BACT
-MAGVWPKRYHFVDGGYYDNYGVATLVEWLEDVSHAQSVQPEILLLQIRDSPENGPPRPAEGQAGFLSQMLAPFFTIFRFRDAGQIAHGNLEYCSRQSLETASGVLLSPGLTTPRR
->UniRef90_A0A839QHS3 Uncharacterized protein n=1 Tax=Paeniglutamicibacter cryotolerans TaxID=670079 RepID=A0A839QHS3_9MICC
-MSKPRNKKNTARPALRAAPAPVVNQSTQRTPEQARGNGNVIVLAAVGATILLFWYFHLLVLNQMSDLSGGLAMPDQMMGGYSVADIEALRAAMNSDAIGQLNYVHKTAGMLFPLFLALTTMLVVNLHTVRGPVRWVLWAVPMLFAIVDLWENAAIDALFNGPLDPGAVSLASTLTTISWVLLFATAAVLVGVLIASFITTFKAKWSEAGLS
->UniRef90_A0A100YU56 IstB_IS21 domain-containing protein n=2 Tax=Atopobiaceae TaxID=1643824 RepID=A0A100YU56_9ACTN
-MGIVGSMGDFHADTGRDGRETRPQVLITPEEAIARGFAREAPPPVRCAHCGRQLRPLGIPVFGSIAWVSHEPCECDGSVRERMEEEQRILEERAMERERRLDRSGIPLRFRRAAPTEAQCIAYADAISGSTSDGLFIHGPVGTGKTHNAAAVAIAASDRGLRTVFTSAIAIFSNIRETFDGGGSSKRALERYASCEMLVLDDLGKESSSRWSLMTLFTIVNARYEGMRPTVITSQYTLGQLRARLASTGEAETAAAIVSRIAAMCADVTLSGPDLRGDAWKPLGMQTMQRTCDVAKRSKLDNFR
->UniRef90_A0A7H8S915 ATP-binding protein n=1 Tax=Lentibacillus sp. CBA3610 TaxID=2518176 RepID=A0A7H8S915_9BACI
-MVEALKQTNFTAEPGELIVVVGPSGSGRVHPDDCRRSSNAESWEVINKHNITQMKEKKRSNIRLHEIDISGIPIWSISDSG
->UniRef90_A0A834H4E1 Transmembrane protein n=2 Tax=Rhododendron simsii TaxID=118357 RepID=A0A834H4E1_RHOSS
-MIEDRRGGGGAPHAAIFAVVVVAVVVISVVLGDQGQVLTDFIAELLSPVGLLLLPIGLLLVIVFLSSDAGSAFSGLFSTGEPDTIHRVSGSPVGVALFLALLLFLLYSRVSIFGGDDGSDE
->UniRef90_A0A830HN61 MYND-type domain-containing protein n=2 Tax=Pycnococcus provasolii TaxID=41880 RepID=A0A830HN61_9CHLO
-MSTGKDVSLVMELCHSSPLGHVVLHEVLRTTVANPDAWPALFPAEERSDGDDDDARHCQQPWNRAISLLRTMSHVSQLARSVATADALWKPAVHRLFEEKAFVCTEALKLKEEGKWRKAYFAACRRVREPRLTQGELCSINFHKRMKKCAGDAWLLRDPYWVTHGARCATMRFLDDGHAETSGEQVSEAAVPTNDEGANERADTAVDNGAPTTLAQLHPPPGAVSTRRKWRFSETGGGRGGPLGAFVRLSDGVREFPTFVVSFHRDTWSPYLESCWAVAASWQLKPEGEDSCMDDANLAISVDAQKAEALAYNCGLPMPEVRSPLEMKNAIAEILEKRDEDQRRLLHAMGIQDEEDDEDNRETTAVEEHDVATTSAGASATPTNSTTTNFDAIIQANRDFLSSFDSRWNAVKRRFDRAINRSIATIALGMTGDVDHAEALLTGSQARRSGGGADERRFEEDEEEQ
->UniRef90_UPI00207B9FB4 hypothetical protein n=1 Tax=Streptomyces hygroscopicus TaxID=1912 RepID=UPI00207B9FB4
-MCGICPSLRLPGGAFDVHLRPSAACPFDASTGHRFTEAGVPVCVHPERVGLPAAEYATAGLPLPWETPPPASPDEVAVWVRAALDAAPPDACAEVIERATEILRAADPELDVVAVLRTALS
->UniRef90_A0A386HU81 ATP-binding protein n=3 Tax=Arachidicoccus TaxID=1769012 RepID=A0A386HU81_9BACT
-MPELIVGRDAEKKILKEVLDSKEAELLAVLGRRRVGKTFLIRNYYSKQLVFECTGMHEVSLMEQLSNFSNALQQAMKLQVPLAIPDSWLQAFTFLSDFLQAKPEKQPMVILFDEFPWLHTPKSGFLAAFGHWWNNWASRRPQLKVVICGSAASWMTENVLHNRGGLHNRVSRNIRLLPFSLKETEAYLVSRGISLDHYQILQLYMAMGGIPQYLKQVGRGESATQVIDKLFFEKGGMLKTEFDVLYRSLFNNASHHESIVRQLAKRAKGMSRAEVIKACGLTTGGTTTRLFEELEQSGFISQSIPFEKTSRDAIYKLLDEYSLFYLKFIDRARATGTGTWHKLAQGQSYNSWSGYAFEAICQKHIQQIKEVLGIGGVYTEASGWRYTSKTGETGTEIDLLLDRQDRCINLCEMKFSGQEFVINKKYASELDNKVNVFKEQTGTKKTIFLTMITTYGTKQNIYYTGRITSEVKMEDLFR
->UniRef90_A0A6I6M0J7 PEP-CTERM sorting domain-containing protein n=2 Tax=Pseudoduganella flava TaxID=871742 RepID=A0A6I6M0J7_9BURK
-MPMKRLATIAVLGAALTAAFASPAAHAATSVATLSGLHVAIIDLTPDDGVAPSLTFMSTGGLVSAGVGTAGGMDTVTDFLRSGNVTAHNAIGGTASVAALYEGQVQAMGSVGNYGDFISQSWLYSNFTLGANTQLVLTGHASLGTDFAAGNPNNVGSASVYIEIVDDQDGGGISLMETYSNEVTSYTAGPVGANDDFTLTFTNASANALLARMTLSAHAEGLVSAVPEPSTWLMLGAGLALTGTLARRRRAQQAN
->UniRef90_E0RVU6 Flavodoxin/beta-lactamase domain-containing protein n=3 Tax=Butyrivibrio TaxID=830 RepID=E0RVU6_BUTPB
-MNGVKKVTDGIFWIGGSDRRLERFENIFPIPEGVSYNSYFIDDDKTAVFDTADITISDQYLENLKDCLDGRKLDYLVVLHMEPDHCSLISTVTGLFPEVTVVGNAKTFQIMEQFFPEAAGFNKLEVKEGDSLSTGNHNFKFVTAPMVHWPEVLFAYDDTSKALLCADAFGTFGALDGGLFADEYDFEKVFLNSARRYYANIVGKYGMQVQAVLKKAQGLDIQMLLPLHGPVWRKDIAWFIDKYQKWSTYEPETEDIVVIYGSLYGHTASAAEAVAASIRNKTKAGVKVYDVSGTDVSYLIGEVWRCKNIVIMCPTYNNGIYPPMESFIADMAALGVQNRSFALAQNGTWAPVTVKLMTEKLQTLKNVTILEESLTIKSALHKKDTDSLEAFTDAIVKA
->UniRef90_UPI00034ADB16 hypothetical protein n=1 Tax=Wolbachia endosymbiont of Wuchereria bancrofti TaxID=96496 RepID=UPI00034ADB16
-MLTEISIDDLVRAKPMAGKKTVVSFTERENIREMPNKPQKHKFIANIIYSNTSTQTGDCILKFHPAA
->UniRef90_A0A3P8ZCD7 calcium/calmodulin-dependent protein kinase n=1 Tax=Esox lucius TaxID=8010 RepID=A0A3P8ZCD7_ESOLU
-MATIVTSTRFTDEYQLYEELGKGAFSVVRRCVKKSSGQEFAAKIINTKKLSARDHQKLEREARICRLLKHPNIVRLHDSISEEGFHYLVFDLVTGGELFEDIVAREYYSEADASQCINQILESVQHIHQHDIVHRDLKPENLLLASKMKGAAVKLADFGLAIEVQGDQQAWFGFAGTPGYLSPEVLRKDPYGKPVDIWACGVILYILLVGYPPFWDEDQHKLYQQIKAGAYDFPSPEWDTVTPEAKNLINQMLTINPSKRITADQALKHPWICQRSTVASMIHRQETVECLRKFNARRKLKVRYFLYLYMSPPSFLTPPFCLNPVIYIFSLFTPLSLLGSDPHHNAGVKELLRWVCLPPSLQLQSGGRSELYSILGSPSIVNTILREGSTESCNTTEDEDMKEMETRGGLRDGDSQYRHSRGENGFYIAVSLNFCLNSSPPDLLSGFLFLARKQEIIKITEQLIEAVNNGDFEAYTRICDPGLTSFEPEALGNLVEGMDFHKFYFENLLSKNSKPVHTTLLNPHVHLIGEEAACIAYIRLTQFVDAQGRPRSSQSEETRVWHRRDSKWLNVHFHCSGAPAAPLQ
->UniRef90_UPI001A9C264E hypothetical protein n=1 Tax=Intestinimonas butyriciproducens TaxID=1297617 RepID=UPI001A9C264E
-MRIIENADKEFAAEMHKAVKDNNGYCPCFIEKTPDTKCMCKEFREMEEGACHCGLYIKVK
->UniRef90_UPI0003B3D06B CCA tRNA nucleotidyltransferase n=1 Tax=Flavobacterium antarcticum TaxID=271155 RepID=UPI0003B3D06B
-MNYSKDLQNPIFDVIAKASEQLNVESYVIGGFVRDLLLNRTAKKDIDIVAVGSGIELALKVSELLPKNPKVQVFKNYGTAMLRFEDTDIEFVGARKESYNFDSRKPLVENGTLEDDQNRRDFTINALALSLNKTNFGALLDPFNGLVDLEQKTIKTPLNPDVTYSDDPLRMMRGIRFASQLDFEIAAESFASITNNKDRISIISGERIVEELNKILMTDKPSTGFLLLYKSGLLDYILPELTDLNQVEEIEGHTHKNNFYHTLEVVDNIAPNTNDVWLRWAALLHDIGKAPTKRFTKKQGWTFHGHEFLGGKMVKKIFERLHMPLNQKMKFVQKMVIMSSRPIVLAQDEVTDSAVRRLVFDAGEEVDDLMTLCEADITTKNPSKFKKYHNNFNLVRQKIIEVEERDHVRQFQPPISGEQIMELFNLKPGREIGTLKESVKEAILEGHIPNEYEAALEFVTKKALKMGLNKD
->UniRef90_UPI001912B9C1 DUF86 domain-containing protein n=1 Tax=Cyanobacterium sp. IPPAS B-1200 TaxID=1562720 RepID=UPI001912B9C1
-MVFALVKAIEIVGEAAGKVSKEYQINHPEISWTAMISMRNRLVHAYFDINKKILWQTLKKDIPELVNILTELLDE
->UniRef90_A0A8J2SN30 3-isopropylmalate dehydrogenase n=1 Tax=Pelagomonas calceolata TaxID=35677 RepID=A0A8J2SN30_9STRA
-MKLSLALLAACSDALIAPPAPKPTKTQLRAVAAPQDSYKITLLPGDGIGPEITTATVKALVAAGKTKGVTFDFDEQLLGGCAIDKEGTPWPDKTLKSCQAADSILMAAIGGPKWDGNPRELRPETGLLAMRQQLGLFANLRPAKAIPQLLDASSLKREVVEGVDIMVVRELCGDVYFGKPAGIYTDDAGVRWGQNNMIYSEPEIERIARVAMDVAQKRQGRCCSIDKANVLDVSQLWKDVVIRVHGECGQGVELSHMYVDNAAMQLVRWPKQFDTIVCGNIFGDILSDEASMLVGSLGMLPSASLPSEGPGVFEPIHGSAPDIAGTDAANPLAMILSAAMMCQYDLLQPDLAKLLEDAVEAVLDAGYRTRDIVNEGNADETLVGCKEMGDLVAAKVAELAA
->UniRef90_U4L0U5 Uncharacterized protein n=1 Tax=Pyronema omphalodes (strain CBS 100304) TaxID=1076935 RepID=U4L0U5_PYROM
-MMVNSAAFADRQSIPLLS
->UniRef90_A0A8I0SUD4 Octanoyltransferase n=1 Tax=Magnetococcales bacterium TaxID=2026759 RepID=A0A8I0SUD4_9PROT
-MVHPPENTHPYDLMRLGQMDYAQALAIQQQRVETLIAHGGPNLLMLLEHPPVYTIGRSGKSGEILDAIPTREHINIIATDRGGRVTYHGPGQLVAYVIRDLRPDTGRILDHVRRLEETIIGTLACFGILGTRERANPGVWVGNEKIAALGVRIRRGITYHGIAINRDPDLDHFSGIIPCGIRDRGVTSMARLGFKTTAEELEECLLAAFAKVFAARWTQ
->UniRef90_A0A3D9YY19 Heat shock protein HspQ n=2 Tax=Methylovirgula ligni TaxID=569860 RepID=A0A3D9YY19_9HYPH
-MNVKPRKAKFGIGQIVKHRKYPFRGIIYDVDPVFANTDEWWLAIPEEVRPRKDQPFYHLYAENADTEYVAYVSEQNLLPDTSGDPVRHPQVEEMFTRADDGGYRVKTVRLN
->UniRef90_UPI001E452D4C zinc metallopeptidase n=1 Tax=Aegicerativicinus sediminis TaxID=2893202 RepID=UPI001E452D4C
-MGIGLGYYILIGAIALVSWAVSAQLKSKFKKYSQVHLQNGMSGKEIAEKMLADNGIRDVQVISTAGQLTDHYNPKNKTVNLSEPVYHQRNAAAAAVAAHECGHAVQHATAYSMLQLRSKLVPVVSITSQMSQWLIIGGLVLGAAAGVGLGYWVAVAGLAMMGMATLFSFITLPVEYDASNRALAWLENKHMLNREEHAAASDALKWAARTYLVAAIGALASLIYWALQIFGGRD
->UniRef90_A0A5C5TAF6 Sorbosone dehydrogenase family protein n=1 Tax=Reyranella sp. CPCC 100927 TaxID=2599616 RepID=A0A5C5TAF6_9HYPH
-MRPIIKKVLLGTVAIIAIVAAAAAFLIRGDTAKLPDEASVGPNPTLPQPTRSLVPTVSIATARGWPQGAKPVPAAGLSVQAFAAGLDHPRWLYVLPNGDVLVAETNAPARPQEGRGVKGWIADLLQNRAGAGVPSANRISLLRDADGDGVAEVKTPFITGLNSPFGMALVGQDLYVANTDAVVRFPYTVGATRIDAPATKIADLPAGPLNHHWTKALIASPDGAHLYVTVGSNSNVGENGLDNEARRAAILRIDRATGQIGVFASGLRNPNGMAWQPETGVLWTVVNERDELGSDLVPDYLTSVKEGAFYGWPFSYWGQHVDARVVPPRPDMVAKAIAPDYALGNHTASLGLVFGAGTSLPAMYRSGAFIGQHGSWNRKPRSGYKVIFVPFASGRPSGAPVDVLTGFLSDDDAAFGRPVGVVTDRTGALLVADDVGNVIWRVTSIGR
->UniRef90_A0A1S1R6I4 Secreted protein n=1 Tax=Frankia sp. BMG5.36 TaxID=1834512 RepID=A0A1S1R6I4_9ACTN
-MVEAATASGAGIAKAADRAGPVLDRLDDALVPRTGRALEAVVGAAAATSRTVTAGLLRLALRTRLLPGPPEPPAPAPRPRTADGGSGPDAGSSPSPAAARDASASAVAEGPSVGRALLERGARIAVLGLVAMIVLSAAAALLPGMDGQPRTEPASPPPGGAPAGQADAAVVPSVTIGPTAGESTADYVGGADQSLVALAEAAPEADLLAVVSLNDYRTPDGLQALLATYRVTQVFFTVPGSGTVHQAEVRTPVDDVLAALAAQAAESSRRAATATDPAARERASAQAQTMRGGRSCSCLFAAVVRASAARLLALRQDSSVRVIDAAPPATLENAVRFIPVTPESR
->UniRef90_A0A8B6C0H3 RING-type domain-containing protein n=2 Tax=Mytilus galloprovincialis TaxID=29158 RepID=A0A8B6C0H3_MYTGA
-MTDIPPNVSLPLLGIGLISLLLSFIFCIYMWRLRCRAREERGYNRIQFKEKNKKFSSMCAVCLEEFRNYEYIAICRCKHCFHMNCLLQWLKHRNFCPMCKATVQRVPSGERSSLIIMPQQAVPSTSNEPPVEGAQNV
->UniRef90_Q0RVU7 Biotin carboxyl carrier protein of acetyl-CoA carboxylase n=1 Tax=Rhodococcus jostii (strain RHA1) TaxID=101510 RepID=Q0RVU7_RHOJR
-MSDTHTLKTSIPGIFYRRPSPSEPVYVEVGQEVATGDIVGLVEIMKSFHSVPSDLAGTVVRFLVEDGAEVSPGQDIVELARS
->UniRef90_A0A8H6B9I7 HAD family hydrolase n=4 Tax=Dekkera bruxellensis TaxID=5007 RepID=A0A8H6B9I7_DEKBR
-MRPRMPKLITADAYGTLYAPRFSIPKQYNDVTARFGVVIPENQLEKKWLNSYHTVKKTYPNYGKAAGLTVDEFWRKVLVRIYGKCQEHPEMIGMIIDKLGKKESYKVFRDFVSLAEWAVWEKEIPFCVASNADSGVTHLVIKEFGMETFLDSQDIYLSYDLELWKPNPEFFNRIIDDQLARLRGIRSTDPNYLEERRKLLQSSWHVGDEYENDVKCAMAAGMGAILVDRSITNPELAIQKRGERFYVVSSLDRVRQIFEK
->UniRef90_A0A5J9WI98 Phospholipase A2 homolog 3 (Fragment) n=1 Tax=Eragrostis curvula TaxID=38414 RepID=A0A5J9WI98_9POAL
-MASVLAFSRCSLLLLLLLLATTASHALNVGNLLGTPPAGSQGCSRKCESEFCTIPPLLRYGKYCGILYSGCPGEKPCDALDACCMVHDHCVAAHNNDYLNTRCNENLLRCLDSVSPAGPTFPGNDCDVGRTKFVIRGVIETAVVAGKILHKRDDGH
->UniRef90_UPI00200ED720 hypothetical protein n=1 Tax=Serratia sp. arafor3 TaxID=2824122 RepID=UPI00200ED720
-MMRYKDIPAEEQQNGPPNTDPASIMHTRLVIGDNVIMASDSCPADPTGATHRAYSLSIRSENVEQGGSITMPFQPAFWAKGFGMLTDKFGVNCRTV
->UniRef90_A0A2W6USA3 Glycosyl transferase n=1 Tax=Microbacterium sp. TaxID=51671 RepID=A0A2W6USA3_9MICO
-MSKEPRVVLVAVPLMARSGVYRSTHDLVRAASAAGHQWQALIGMRPQASGDALATPGVREVPFDARGVGGISQIRALIDSVPEVRDADVIVSMITQTDIAVSRARAREDRGWIAWVRGKPWPAAGEQNLARRLLLRAWETRALRSADAVWATTPVLADEFASACQAAIVPAGIPSSRRIAHGEDATSPLVWAGRVDIDKRPELFSRIVELTGHPGRLYGDGPLKDRLASRRVTGLDWAGWRPSGELWSDASVFVGTSSREAFGRSAVEAAAAGIPIVIAREYGAAPLLFTDETLRRACVIDSADPEAWANAVRALLTDRQLRMAVSDHVHSNAQTLTIEASVDAAARRAAALLEGGCK
->UniRef90_A0A327NX72 ISXO2 transposase-like protein n=1 Tax=Algoriphagus yeomjeoni TaxID=291403 RepID=A0A327NX72_9BACT
-MNIINFVQYFPDEESCEVYLKSYREKAGIRYKTCKSITKHYWFSTGKFFECSCCRRRSSLKSGTVMERSKLSLHVWMTAFMLMAATKKGFSCLEFQRQLGLCRYDTAFRLMHKIRVVMGKRDALYTLTDMVEMDEAYIGIATDKKVKENLKRGKGSQRKASVAVSAESIPLEDLETGKTSRFCGYYKMEVLGKVDGEHAEKFIKKNTSGEIVLFTDKNTAYEHIEDIVETHFTVISGKESTNDTLQWVHKAISNLKRKLLGINHMITYKYLQNYLNEFVYKLNRRYFGDRLFDRLIIAGIYPYVQ
->UniRef90_A0A3N1WFC1 D-alanyl-D-alanine dipeptidase n=1 Tax=Erwinia sp. JUb26 TaxID=2485126 RepID=A0A3N1WFC1_9GAMM
-MDDIQLTDIATSLPQVKIDLKYATADNITGQPIYCEHRCLLHPDAAAALVRSAHIAAIAGFTLLIYDAYRPQKAQMNLWQACPDPDYVIPVSQGSNHSRGTAVDVTLIDEQGSIVDMGSGFDEMHERSHPWHPSVSARALRHRLMLSAIMLEGGFKGIATEWWHFELPGAADYPLLTDIFDCYPPPSAA
->UniRef90_A0A7J3I7R8 Na+/H+ antiporter subunit C n=1 Tax=Ignisphaera aggregans TaxID=334771 RepID=A0A7J3I7R8_9CREN
-MSDLLISLAFRTAMIAFVFNTAIALYGVLSRPSLIKKFLCLIMFTDSINIFAIFIGFRYIPGSYPSPPILEDIPTSVRDIERLISMAVDPLPQAMILTAIVIGIACNMFLLSLILMYYKHYGTTDIHVTEEAEAYEETLE
->UniRef90_UPI000C1F926A ATP-binding protein n=1 Tax=Limosilactobacillus fermentum TaxID=1613 RepID=UPI000C1F926A
-MDFLKFEDLSFSSAFSEPKEDIHLEYKTATWKLPKNFWETVSSFANTDGGLIVLGVKEDKDNHKYEITGVDDPIVVRQEIFNGNSNSECLSSPVIHDSDVKLVDCFDRTIIEVLVHPEQYNKRPLEAHGIAYVRTDDGDRKATEEQLKYFLVEHQQEIDTRLLRNFDLEDINSLDLDEYVTVLRKNTNTRYKDLESLAFDLGVFRRDRTSNGKDRLLTEGGLLFFGKYKVKSKMLV
->UniRef90_UPI001C270FE8 TRAP transporter substrate-binding protein DctP n=1 Tax=Desertibacillus haloalkaliphilus TaxID=1328930 RepID=UPI001C270FE8
-MKSFFVIFCLFIISIVTTACVQDGSNNNGSQSSENSEDTITLRVSSSLSPQNGWWAGFFIPWMESVEEKSEGKVQFDYFTAEELLSVGEELQGMREGTIDIAAPLWTVYDPQRFPLSEVTMLPLTDSDPMMASLAYSELVQSELELVDGKTYADYEFVEKGIKALPIPTTEQYVISTKDYEFNTIEDFEKVSLRSPSRVHEVFANEVGINTVTLPSTELFDSVNRGAMEGSFFSISDWTGYGMQDVFNYTLEGINLGHYSGVWAMSEDKWNSLPKEIQDIMIEAAIEQIPGGAQLWMDRSIENKENSIEDGGVFATTADLEPEAEEMVLQGMENTWYEWIEMTESNGHPGTQIAKLWRDLIVEQGGTVPESIMNLE
->UniRef90_A0A140IHG3 Sodefrin-like factor n=1 Tax=Cynops pyrrhogaster TaxID=8330 RepID=A0A140IHG3_CYNPY
-MRAIIATVVLLQALITGDCLLCEQCFALQTSSCSGIFKQCSPDVTHCVAGLENNTLGTHVILTAFKDCLDPSQKAACGREVSFTAPAASLWTSRTCCDSDFCNGGDVQVPPPDDTPNGYICEGCGSDQSAKPCTATEYVQCSGKQNACGTFYGTASRPGKTGEEYTFKGCTTQDFCIAGIFHMAGMQAYDYYVLKCSPALKV
->UniRef90_UPI0021C67275 ABC transporter transmembrane domain-containing protein n=1 Tax=Mycoplasma gallisepticum TaxID=2096 RepID=UPI0021C67275
-MLGVAAVGFTFGYLGGRSIIIASVEFAKQLRVNIFERYQSFSVKNTDKFEKASVLTRMTTDINFIHQSIQSGRTAIRGMSVFLFSLVLMFVTS
->UniRef90_A0A5P2U3Z0 MFS domain-containing protein n=2 Tax=Kluyveromyces lactis TaxID=28985 RepID=A0A5P2U3Z0_KLULC
-MAVKEEVLGKQAVSTHAVAANEHDLDEKQQEEFLNEYGLPDKLRFTRSLVLRKTEILAQQYDSWYWKAVLLFSVFLCSYGYGLDGSVRSVYTTYATNSYNTHSLLSTISIINLVIGASAQVFFARLSDVFGRLTLLIVATVFYSVGTIIQSQAYDVQRYAAGAVFYNVGLVGVVLQVILILSDFSSLRWRLFYTFVPSWPFIINMWVSGNVVDAANPLENWSWSIGMWAFIFPLTCLPLVCCILHMRYRASKTEAWRHLKVEKTYYQSHGLLQTLIQLFWKLDVVGVLLLTVTLGCILVPLTLAGGVSQKWNNPHVIAPFVLGFVLLPMFVVWESKWALDPIAPFKLLKDRGVWSALTIQFLIYFVYQMAVGYLYTILVIAVDESTTSATRITSVYSFTAAVASPFFALVVTRSKRLKPYIITGCSLWMVAMGILYHFRSGKDSDKGIIGGLVLWGLTSTLFTYPVTVSLQSITSHENMASVTALNYTVYRIGGAVASAASGAIWTQLLYKKLLKEMNGDAALATAAYGSPFDFILDYPWGTPTRDAMVESYRYVQKYEVLVALVFTVPMFILSMFLRDPPLTDDQAQENLKEGEYINTEHDDPIAAWMDDKWTRLTGGRKKE
->UniRef90_A0A2N6BMK7 Serine hydroxymethyltransferase n=2 Tax=Deltaproteobacteria bacterium TaxID=2026735 RepID=A0A2N6BMK7_9DELT
-MILIASDHGGFEVKEAIGEHLKARGLEVEDLGTTNTDSVDYPDFAKKLARRVADEPQSKGILICGTGIGMSIAANKVPGIRAALVADTFSAKMAKEHNNANVIAVGGRTNTPEEAKSLVDAWLDAEFEGDRHARRLNKISQMEVSCGVARSISAEDPEVFSAMMGELRREEDTIVLIASENYASTAVLEAQGSVFTNKYAEGYPGARYYGGCEFTDKVETLAIERAKKLFGAEHANVQPIAGSAANMAAYYALINPGDKVVSMSLAHGGHLTHGAKVSFSGRLYDIVHYFVEEDTGKIDYDKLAELVKREKPRLVVAGASSYSRTLDFQRFREIADSVGAYLMVDMAHIAGLVAGGSHPSPVPYADIVTTTTHKTLRGPRGGLILCKAKYAAAVDKAVFPGLQGGPLVHTVASKAVAFREAMTDGFKQYADMVVKNAARMAEGFKKAGYDVVSGGTDNHLFLLDLSSRGLTGDAAEKSLDRAGITCNKNAVPYDKLPPTVTSGIRIGTPILTTRGMGEEEMDKVVELIIRVLENVGDAKVEASVREDVAALCRQFPFYADFLAD
->UniRef90_A0A2V8W5K0 DUF393 domain-containing protein n=5 Tax=unclassified Acidobacteria TaxID=305072 RepID=A0A2V8W5K0_9BACT
-MISLVSEYTDGKGRHARGWLFFDAECKFCTRIARWLAPILEKRGMALAPLQDPRVGALLGLAREDLMREMQFLLSDGSRFGGADAAVALAREIWWGRPLVWISKIPGMMEILRKGYHWVAASRSCAAVSCPANEPSPRV
->UniRef90_A0A0A9RIL1 DUF5753 domain-containing protein n=1 Tax=Arundo donax TaxID=35708 RepID=A0A0A9RIL1_ARUDO
-MQRVPLQVPLHHPPGQGHLLAHREHERLAIARRTAGRPANPADVLARVTGVVEEHHVVHVSKVDAS
->UniRef90_A0A1Z4M0Q0 Outer membrane efflux protein n=1 Tax=Calothrix parasitica NIES-267 TaxID=1973488 RepID=A0A1Z4M0Q0_9CYAN
-MIAVAALNTQSAKADSNSLRQMQTIPNYSIPTSEETTGNFQLSVPSEVIPPDDVEKQLTSDESKSVLDALSPNPNPLQYPTRPEEVQIQKIQAITLEQALELARRNNRELQVGLLELQRAQAAVKESQASLLPNAGLSAEVARQQSAQNQLAVESTNIGTDEATTAFNGSLQLSYDLYTGGRRNAQIGQAKERLRVQELAVEVLEEEVRLNVSTEYFDLQQADEEVRIANAAVVNARASLRDAQALEQAGVGTQFDVLRTRVNLANAQQQLTNAVASQQVARRRLVTRLSLPQSVDIAAADPVKLASLWNLTLENSIVLAYQNRSELQQQLAQRNINLLDRRLALSALKPQVSLVASYSLLDQFDDSVSLTDGYSVGVQANLNLFDGGRAKAQAAQAKANAKIAETQFADTRNQIRFQVEQAYSGLQSNLENVQTSNAALEQARESLRLARLRFQAGVGTQLEVIDAENALTTAEGNNIRAILDYNRALASLQRSVTSRAIP
->UniRef90_A0A0W0Z402 Type I site-specific deoxyribonuclease n=1 Tax=Legionella spiritensis TaxID=452 RepID=A0A0W0Z402_LEGSP
-MKKTFDKLDKLKLEQLDNPNYLPKIQNFLPQLKSDFEQHVAPGEFDPIKQADNWLEVVRNLANNKHPAINKDSLKKIEKIYDLLGGQDEDAFRLLDMYQSIDTVNSEQVASKTKKIVADYRAHLANKIEEKGFIISSEDNSIVSLNEGEITPKQQKLLNRYEAISALDERIHNKRILDESDKSEAKQALDICLKNKPEWSEKPFLQKLTDVLSVGIKPLYKAFFSKETRLKEELDQVISGPKR
->UniRef90_A0A2Z6DW79 GTPase HflX n=5 Tax=Proteobacteria TaxID=1224 RepID=A0A2Z6DW79_HYDTE
-MFERPRFGERAWLVQIDFGEGRVAERLEELRQLVVSAGAEIVGALTVRRAKPDPATFLGSGKVTELAALVREHGADLVVFNHALSPAQQRNLEQALACRVVDRNTLILDIFALRAKSAEGKLQVELAQLEYLSTRLVRGWTHLERQRGGIGLRGPGETELETDRRLIGARVNRLKARLQRLEKQRATRRRGRQRYGVPQVSLVGYTNAGKSTLFNALTKAQTYAADQLFATLDTTSRRIWLPQTGNVVLSDTVGFIRDLPHDLVAAFHATLEEVKEADLLLVVSDLASPDNDAQREAVTETLRQIGAESVPVLEVGNKIDLLDQSPEVVRDGCGTIRRVTVSAATGAGLELLRAAIDERLHTATNASSGEKNTETNSASTQDHTEPFWEPLEREVSPCP
->UniRef90_A0A2M7SV67 PolyA_pol domain-containing protein (Fragment) n=1 Tax=Chloroflexi bacterium CG_4_10_14_0_8_um_filter_46_9 TaxID=1973937 RepID=A0A2M7SV67_9CHLR
-MDLASKINSYFPKELLELLQDTSAEANKLGQRVYLVGGIVRDLLIGYPNFDLDLVTEGDAIELANRIARMSEAKLVIHPRFNTAKIKSGDFAIDIATARSETYASHGALPTVTPCPIEKDLFRRDFSINAMAISLTPEHYGELLDPYHGKDDLDAHLIRILHPGSFTDDATRILRAIRYEQRLGFNLEHETAQLLKRDISMLNTISGDR
->UniRef90_A0A0G1DQW2 peptide-methionine (R)-S-oxide reductase n=2 Tax=Candidatus Magasanikbacteria TaxID=1752731 RepID=A0A0G1DQW2_9BACT
-MNDQEFREKLTQEQYHILRERGTEAPFSGKFLDHKEDGSYTCAACGNVLFASGAKFDSHCGWPSFDRDMGEGTVTFLDDTTLGMTRTEVRCAQCGSHLGHIFDDGPTETGKRYCINSLSLGFQSVDKR
->UniRef90_UPI000FD1EFED acyltransferase n=1 Tax=Mesorhizobium sp. M7A.F.Ca.ET.027.02.1.1 TaxID=2496655 RepID=UPI000FD1EFED
-MTHQFGMKPRLVGLDVARIFAALAVMVFHLGFWSWAVKGSTPQSVVQGAAAFPELAPFTFWGRFGVEIFFVISGFVIAFSAASATPWQFIRARFLRLVPAALICATMTFVVAITIGLLPTSTLVDRYIRTLTFNPYAPWIDGVYWSLGVEISFYVLIAALLMIRRFSWIEPVAAIIGTASSFFWVWILAATLGYVHPPVSMIDGRSMDLLMITYGAYFATGVFLWSSLMIKPNAARSVALLLFVAGGLAGIYMNAPAYFAKIIDPSLRCVPAVVWLFAISFIVLATRFDYLIVSRMKPGMLAAIRLCGMATYPLYLLHDIIGAAVLRMLVLQDIDRFVALTYTFALMIALSLAVTLAVEPPFRKAISRVIDFRVLRPTTAEASQKA
->UniRef90_A0A2E6BIU5 Dephospho-CoA kinase n=4 Tax=Gammaproteobacteria TaxID=1236 RepID=A0A2E6BIU5_9GAMM
-MTQTLKSERLIIGLTGGIGSGKSAATRFFSELGITVVDADELSREVVKPGEPALQAIVAHFGDGVLLDDGQLDRRQLRQRIFDDHNERKWLEQLLHPLIRQEIITRLTASTSPYTLLSSPLLLETDQQRLCSRVLLIDAPESLQIERTIIRDNSSEATVKAIMESQMARHARIERADDIIVNDGDLNQLKDAVAAQHQRYLEMTQ
->UniRef90_V7F2Q5 Stm1_N domain-containing protein n=1 Tax=Mesorhizobium sp. LSJC264A00 TaxID=1287321 RepID=V7F2Q5_9HYPH
-MPETPKDKDLEKGDEVLRRLLKTPPKPHGDKAAKEKPEARPAKRSQNAKAK
->UniRef90_UPI0018E26317 uncharacterized protein zgc:113436 isoform X1 n=2 Tax=Cyprinodon tularosa TaxID=77115 RepID=UPI0018E26317
-MLSVDSLQVAEEEMVESSSNKLSDIYTFVAKGSLPLTMNPLQKKNFKRYAKKFIFEEGKLFYVGPKKEEKREVVIEAKRKMQIFLDSHLSDVGRHLGQKKTVHRIQSRFYWLGIIKDVVEWIKVCETCRQTERNKNLARTVRPARVEAPWDIVGIDFIGPFTETRRGNRSVVLFIDYFSKWPEAFPVQTVDPLSVARCVSNCIYRFGATKTVVCAQKPEFCEEVSKVLHEKWKLVQRVSALDQPQLNPLHDCSGPLLKEAVEQMVAEKQADWDDFLDPVLFLFRTSSNPTTKFAPYSLMFSRKANPPGETRLTPPQYDEPETDGCREQDGCREQDGCREQDGCREQDGCREQDGCREQDGCREQASTCMNIMREQQNAVKQMVIANMNAAYKQEKKRKKAKRRMQSASPATLKVTEPLFAAGDSPSAKKVKDSLYLSFPVETVLATEPNGAEGVKTELAYRLAQPDVH
->UniRef90_A0A672QD87 Serine/threonine-protein kinase VRK1 n=3 Tax=Sinocyclocheilus TaxID=75365 RepID=A0A672QD87_SINGR
-MPPKSKAGGAKKARAPTKRKLAEEFPPGEVLTDNAKKKWKLGSPVGQGGFGLLYLANEDSSGSVGAAAPYVIKVEPSENGPLFSELKFYMRAAKPDLIGAWMKSRKIDYLGVPKYWGSGFHEKGGKRYRFMVMDRFGTDLQKKFEGNEKKFPRKLVLQLGLRLLDILEYIHDHEYVHADIKASNLLLSYTNPNQVYLVDYGLAYRYSPEGVPKEYKEDPKRCHDGTIEFTSIDLDFDVSTNDAGPPSIKTPKRKKAEEKGQSADETEGTPAKKRRAPQKKDVNGAKKTASPAKRPAKKEAQASSEPAVKKSRGRPKKNS
->UniRef90_UPI0013C2E1C0 hypothetical protein n=1 Tax=Trinickia diaoshuihuensis TaxID=2292265 RepID=UPI0013C2E1C0
-MVAVGNGKGAAGRGNGKSTVVDEAAVVAGLIFLKTIPCSCAPAATVHAAGGAALFEEDDEDDEDAADDEDAADDEDAADEEDAADEEDAADEEDAADEEDVADAAERGLNPGEPG
->UniRef90_A0A2X1W8T8 Ovule protein n=1 Tax=Photobacterium damselae TaxID=38293 RepID=A0A2X1W8T8_9GAMM
-MCQKLYKLLIYYYSVCYFRILVRFTVLKNHGYLFAVKFKKSCTSGWLNLLSGSDYNRDMITLVLISLRIY
->UniRef90_UPI001FFDE7FD SusC/RagA family TonB-linked outer membrane protein n=1 Tax=Sinomicrobium weinanense TaxID=2842200 RepID=UPI001FFDE7FD
-MKAMMCKRKTIYVLSAFFFYCQFMLAQQKTVTGVVTDADDGMPLPGVNIVIKGTTKGVSSDFDGNYSIEAPEDAVLVFSNLGYASREVPVAGQSTITITLSADAQELEGVVVTALGIKRETKRLGYAMTEVKGDELAKTNTVNPVQALQGKAPGVSIGSSDGGLFGNSKIQIRGVSALNSNNNQPIFVVDGVILDNNVSDSSADWEGNPNDYGNMLKNLNPDDYESISILKGAAATALYGSRGLNGVVLIKTKDGSGTRGLGVSVKQSVGIDHVYRQPDIQYEYGVGTRAGAVSYGERDANGNYYRFSNNQFYTNDDGIPTLIEHPSSLGYGPKYDGRPIIGYDGEMTTYSPAKDNLLDAYDTGWNTNTSVSLSGGHDKGNFFLSLSHNDRSGTLPNNSFKRDALLFSGAYQLADWLRADASISYTTSKSKNARNDLSQFFINGTYANGYNPSKYRQRQFWQASHGGIPNSDYSDKYAYVPGKSIWFEYSMNNAGSEEQVTRPIVRLTADVAEWLSITAEGNMNYYTTKYERKDWGSGFLNDGGEYQMRHNTDKSYTGKLTANFQKDLTPDITAQLLVGGELWKQEKSETDVRTDGGLIVPGQFFLENSKRNLISSGKVYGTKQISSLYFLSSFGYKDQVFLDITGRNDWSSSLVYTNGEGNYSYFYPSVSSSWLFTQTFNTPDWFTFGKLRASWAQVGSDTDPYAINKGYGIGRYQMDGDKFIYTNDITTTLVDKNIKPERKNSYEIGMDIRFFNNRLGVDFAYYNEIIKNQIGEIPFPQESGYNNYFTNIGTLSNYGVELSVTGTPVKTKNFTWNTTFNYWKNTTKIKDLHEDYGEYKALGGDVAYGNFRIGSVAFKGGEYGVLMSDSSPKKWQSDNPDDPRNGMNVLKWVDSDRGAFYERSYEPERVGKVQPDFEGSLNNSFTYKGISLSVLLDARFGGHIASYSNRYGTSYGWLETSLRGRSPEHGGMTWTSQYSDSQGQQFNDGVIPNGVFAEGQTVTAPNGSTVDVGGLTYQEAMDNGYVEPTHASYFNYYTNSWSDGVVNDDWFSEVKYIALRNISLGYNFPKSVSDKLGAKNFYVSFNARNLGYLYNSLPNNLNPESFRGTSSSDSFRERGFIPYTASYTMTIAIDF
->UniRef90_X1TZX9 KTSC domain-containing protein (Fragment) n=1 Tax=marine sediment metagenome TaxID=412755 RepID=X1TZX9_9ZZZZ
-GFEYDPKVKDVFRLLMTPERYNTLYHRSKAAKTRIDRS
->UniRef90_A0A2E0MWS0 Asparaginase n=5 Tax=unclassified Euryarchaeota TaxID=115531 RepID=A0A2E0MWS0_9EURY
-MTEQDRPSSVSHGRPGSGIYPSNPLGEKHEGIPTGRDVEWEPLVDFRRLDVSENTIHGAISWVHGDEVIHSFGGNVLVYGRSMMKPLLMKIFTDVLDDVLTDEQKAIACSSHNGDTEHVATAQSILTESEWGLMQCPLDVPLVQFGRQVRRPRRWFHTCSGEHAALLRALRLKGINRAGYTLPTSSWFQDFIDLLNSMLHPDWKPLRIAKDGCGLPTVSNTVDELATLFSALVRTKDDDWIWDAMCKHPDLIGGFNRLDSTIIKAGEGRVLAKEGADGLLGIAIEHDDWPKGLGIVIKIAHGWNSQATWYVARAVLGVLGIQLRNPYPLHRQKAFIVPGIVPEMYLKQLESVVTWDEWDPDQDRFQILENQDNLARNPHGNEGRM
->UniRef90_A0A348B110 Shikimate kinase n=1 Tax=Sulfodiicoccus acidiphilus TaxID=1670455 RepID=A0A348B110_9CREN
-MQARAFGGISVVNAVPAWLGSTMAINLVVSVEIEEGDGREEGLIGYVLSYLRNAYSLPPLRVKVYSSLPQGGGLKSSSAVTVALIEAVSRLFNLRLDPPFLSAKLSLEGGFSLTGAYDDAFAAYRGGVSLTDNKSISLLKHLQPPEGLVFLVVPKEGRTADPRLLRRYSKTFEAIFQLALQGKLLEAMKINGVLVAEILGYDLSPIEVALSRGAIAAGVSGNGPSIFAACNEGDEGPVEDSLSRYGRVVRVEAVRIEGEDLQGQG
->UniRef90_A0A5S4GRQ6 ABC transporter substrate-binding protein n=2 Tax=Streptosporangiales TaxID=85012 RepID=A0A5S4GRQ6_9ACTN
-MRRTAKIISVAMLAVAAAACAPSTAGNAPSTAATAKALPGPSLDANFDLEALVAAAKKEGSLLVYDSSGDIEEVAKAFTAKYGIAMEGVKSDTPQTAEKMIREHAADNVTIDAAMYEDGGVLVGQLAPQGVTQTWIPQDLKEQIPAENQNPLLALSKATVFAYNTKLSPGGCPVKNIWDLTEPEWAGKLVMQDPLGKPTVLSFFTQLDAHGNQALEQAFQAKYGKALKTEEKSAAYEWVKRLAGNRPVLTGSDEDISGAVGAPSATDKKIGFMSISKFRNNEDKGYTQSTCEGMAPFTGFSYPKYVAIASKSKHPNAAKLYVHFIMTEEGVKHEIGEGGISGNSTVKPLVTPAGLSDWQGQLFHTDPKGLLGDMQNRQTISDFWRVNKS
->UniRef90_A0A453IYK0 ADH_zinc_N domain-containing protein n=2 Tax=BOP clade TaxID=359160 RepID=A0A453IYK0_AEGTS
-MALPTQGWGKTIILGVEMHGAPLTISSLEILHGKCVMGSLFGGVKPKQDIPILADKYLNKELELDKFITHEVGLKDINTAFDLLLQGKSLRCTIWMDK
->UniRef90_UPI0021183352 helix-turn-helix domain-containing protein n=1 Tax=Bifidobacterium longum TaxID=216816 RepID=UPI0021183352
-MGEVYSHLSEEERQVIQIEVGNGASIRGIGAMLGRSPSSISREIKRNTWFPSNENESYRPVLLQCLFDRFGSVFPQCGLMVFPGVVIVSR
->UniRef90_A0A4R6PNK8 Sucrase ferredoxin n=4 Tax=Nocardia TaxID=1817 RepID=A0A4R6PNK8_NOCIG
-MNPFEGMVCSAAAADLPLLGTAVHATGWLCIEHPGAWGRDVLGDEVLGPEITAELAARTSAAKVRPTLIRRPGRYEFTGTRTVLLASARPEGSWCVRFEITDLRELFDIDLHLVDGPAPEIDVPVDDPIVLVCAHGKRDQCCARLGRPIAAALAAEQPGRVWEASHTGGHRFAPAVVLLPSGLTYGRVDIPAARDLLAAADTGEVSLTGLRGRSCYPPIAQLAEVAVREQVQAPADALTVALDPTPTHDPTLAGAAVVTHRDGRRWRVTTRTASAPPRQASCNAKPKPAGYLEPVSIEQLPTL
->UniRef90_A0A7W0RJ01 DNA ligase (ATP) n=1 Tax=Nocardioidaceae bacterium TaxID=1871072 RepID=A0A7W0RJ01_9ACTN
-MDLPVMPPLSPMLAKVAKTVPSPEAFEGGLLYEPKWDGFRCIVFRDGDEVELGSRNERPLTRYFPEVVEAAKASLPDRCVIDGEIVVPIDGRLQFERLLERIHPADSRVRKLAVETPASLVAFDLLAIDDEALLGTPLGERRPRLEQALAGATDPIHVTPASDQLSTAEEWFAVFEGAGLDGIVAKPCASTYQPGARAMIKVKHVRTADVVLAGFRLHKKSTEQHPLLGSLLLGLYDDNGRLQHVGVSAAFPADRRAELVRELQPLVVEPADHPWAEWAIAEAGGDRMPGAQSRWNAGKNLSWVPLDPALVAEVGYDHMEGTRFRHTTQFKRWRPDRTPESCTYAQLEEPVNYDLDDILV
->UniRef90_UPI001C08EAC3 hypothetical protein n=1 Tax=Tamlana agarivorans TaxID=481183 RepID=UPI001C08EAC3
-MKNVLTLTKKGILMVAMLATVLGFANADDKVIVKRDAKKTSITLEDVKQGDLVSIKDNQGIIIFKESVEATGTYKKGFDLTGLENGDYVFEISKDLEVNTIPFTVNTTNIEFDEAEESTYYKPHTKHEAGLLYVTKLCSENEAAIINIFTEVAAGEYEMIHSELIEDALVIEKVYKLNTGNYKITIHSNNKEYTKFINN
->UniRef90_G0R3Q1 Transmembrane protein (Fragment) n=1 Tax=Ichthyophthirius multifiliis (strain G5) TaxID=857967 RepID=G0R3Q1_ICHMG
-MEQERQYIQNQFKNDKNNLINQINFNNENIKLDDKQIKLLKEKKNITRDMLKQHYLQELKKNKGLQNTSMVWITKALLNINEDVNQSEIFPSIIDQQSVSYLIEYAQSEINYDELTFMLQKQQLQNISSSKLEENNFDKNYLNTQYQYNINTIKNKVSKLAQQTVKIKNPLLIQSSKTSIPNLVWEDTESAQKSSN
->UniRef90_T0DQ77 Globin n=3 Tax=Alicyclobacillus TaxID=29330 RepID=T0DQ77_ALIAG
-MLSQETRDIIKSTVPVLETHGTAITTRFYQLLF
->UniRef90_A0A2C9KHU1 SHNi-TPR domain-containing protein n=1 Tax=Biomphalaria glabrata TaxID=6526 RepID=A0A2C9KHU1_BIOGL
-MATESSTSAVDSVEKLEVMKKAADLLAQGKRNMLCGEVPKAVNLFEEAVQLLVKECGELSRDCADAYFSCGSALLELGRMETNVLGTALEGVEVEEEKEEEESEQFEKPPAEDDSVRQQLREEVYEAMAEGEREKDMQKTDKEIKDGEDGGASQMETVTDENKDNVADKSDLKESITAAGDADKELKKEEIPETNSTVEDKSLTESKINEVKPADSNTVADKDETKDQLEKPKQEEEMEVVEKNSEKSEISHKAHEDAAQSAEAEKETASENAVDTAMDIDEKKDVELEDESEADKDDEETEETVDEEEAVEGDESADGEKDEDVPNFQLAWEYLDLAKVIYLKNESKEDQLKAAECHLKLGEVSMETEQHTIAVEDLLSALKIQQKYLAPDDRLIAETHYQLGLAYGLGKEFKLSIEQYQLAISVIEAKIASLKKVLEDEQIDAENKENLETNPELKKFADEIKELQDLIPEMKNKTEDARIEENDLQKMKAIVKENLFPSGTTKEFGSPSKKSGGSVTSGDVDENGERKASDIAHLVRKKRKPEEDTSAPSEQEVKKIRQEVVSDDVNVETKVDDEAKMNVDEQVNTEESQVNSDNSNINVEPKVNGDEPKVNGDEPNVNGDEPKVNGDEPGVNGDDIKVSGDIIESKVISKVEVSPTEDAKMNGDTETPSIETSASTEVAPMAT
->UniRef90_Q883V3 histidine kinase n=513 Tax=Pseudomonadaceae TaxID=135621 RepID=Q883V3_PSESM
-MSDSGRADALLAQLPREGRGRLKVFLGAAPGVGKTYAMLQAAHAQLRQGVRVMAGVVETHGRAETEALLNGLPQQPLLRTEYRGMTLEEMDLDALLKAAPSLVLVDELAHTNAPGSRHTKRWQDIQELLAAGIDVYTTVNVQHLESLNDQVRGITGVQVRETLPDWVLQEAFDLVLIDLPPRELLERLRDGKVYVPEQARAAIDAFFTQTNLTALREMAMQTAAAQVDNDLAQGYRQLGQSAPAVRGRMLVGIDGDMHAERLVRHASRVAQRRHLPWSAVHVDDGQTLDEQSRARLQNAQQLAERLGGEAVSLRAGEVARTLVQHAIERRASVVLVGQSRRHWRRRVFGGGVAARLLREGHGLEISVLDDSEELPDQPPRARPAREVVWFDYGLAFVATLIASLVAWGVAGVLALPNISLIFLAAVLLVAVRSSMGPALACAGLSFLAYDFLFIPPSFSLNIQREEDVLTLLFFLLMSALTGKLAARQRRQLQALRDTQEQTSELLDLSRKMTAATDRKAVLNAAEQHFSGWKELYLCLVDRDTQGGLVVETGGPLTFSEAERAAADWAWQHDQPAGSGTGTLPSGRWWWWPITAEEGPLALLGVCAREGQSFTDQHRRLLAALTQPLAQALARAQLAQELEAARLHGETEQLRSALLASVSHDLRTPLTSMRGSIDSLLALGEAIALEDRRELLEGTRDEAERLDRYIQNLLDMTRLGHGALKLARDWVSPADIVGSALNRLRAVLTPLQVSTQVTGDLPLLYVHAALIEQALVNVLENAARFSPLGGRLQVTAGVVDSELFFSVSDEGPGIPEDERAKIFDMFYTAARGDRGGQGTGLGLAICQGMIGAHGGRLTVEEGIDGLGTRITLFLPLQAQPDAEMEEPA
->UniRef90_Q2KHZ9 Glutaryl-CoA dehydrogenase, mitochondrial n=28 Tax=Pecora TaxID=35500 RepID=GCDH_BOVIN
-MALRGVYAQLLNRGPGLRVFRSWSSATAQTEKGEKTQSRSAKPSRPEFDWRDPLLLEEQLTADEILIRDTFRTYCQERLMPRILLANRNEVFHREIISEMGELGMLGPTIQGYSCAGVSSVAYGLLARELERVDSGYRSAMSVQSSLVMYPIYAYGSEEQKQKYLPRLAKGELLGCFGLTEPNHGSDPSGMETRARHNPSSRSYILSGSKTWITNSPVADLLIVWARCEDSCIRGFLLEKGMRGLSTPRIEGKFSLRASSTGMIIMDDVEVPEENVLPGVSGLAGPFGCLNNARYGITWGVLGAAEFCLHTARQYTLDRIQFGVPLAKNQLIQKKLADMLTEITLGLHACLQLGRLKDQDKAAPEMVSLLKRNNCGKALDIARQARDMLGGNGISDEYHVIRHVMNLESVNTYEGTHDIHALILGRAITGIQAFVAGK
->UniRef90_UPI0021D8BFC3 hypothetical protein n=1 Tax=unclassified Shewanella TaxID=196818 RepID=UPI0021D8BFC3
-MALRLADIPYYLNPTYQSDGRVKIDSPQQLCIYLIGPDTVEKVRKTLNFFATISKICLVRREKLHIDFSNLQNFTAAASVLLFSEITRAQLVTEIADVVTFTLPKTPDVLKLFRGFGLYKAIMPGGNRKLINLFDDDHPYQSGTDPNKFLISTILNLKNQGLELSNPETRIIHRGIQEAMLNVIHHAYEHETDVSSGIGSRWWQLSFCKHDSKSVAFIIYDKGISIPESIAGKLPVNITTDAEAIEFAFQKGVTRYTDKPTRGKGSEDIKDVTTVKDNSKLLVYSGNGMYYINRERGDTRKLSLPASINGTMIEWLIPYE
->UniRef90_D9WD85 Integral membrane protein n=2 Tax=Streptomyces violaceusniger group TaxID=2839105 RepID=D9WD85_9ACTN
-MGADVNEEEIARAVEEGMRRNDVRRAAAWRKARDQEARNLLKGLGCMALVFIVFIVLMVKNPGG
->UniRef90_UPI001FB071F5 discoidin domain-containing protein n=1 Tax=Clostridium perfringens TaxID=1502 RepID=UPI001FB071F5
-MLKNRERMKRLIACGIAASIVSVNGLSVLASELNKSDKVNLALNKKTVASSREVNDKWGAELITDGIKDKPSDPNAKPGNSRWASSRSVPQWIYIDFEEATTFDQVDILWDGAYSRNYKLEVSNDGETWEEVYATSEGKGNQESINLGEDITANYLRVSCEDTAHEWGNVSIYEVEVYDNENEENVTPPETETGVNIALNKTATASASETNTLTPDKVVDGDTSSRNSRWSSGGFSNGAKQWITIDLEKESTFDKVRLFWEAANAKVYEIQTSNDNENWKTVHRNEAGKGGTEVIELSEKENARYVRVYCEENNPAVWSSVSLYEVEIYNGEIPSSGDLDEVLNSLEVPTINKGDSKLQMPEVPKGFEIKFIGADYNQIRLLNKQNL
->UniRef90_UPI00166CCB99 hypothetical protein n=1 Tax=Kroppenstedtia guangzhouensis TaxID=1274356 RepID=UPI00166CCB99
-MEKFGLAVKVDGEELLLLEIEVENDGKKVISDLPGSIRKLAESMAILIEENGNPLEEVAK
->UniRef90_A0A1G6XTJ4 RNA_ligase domain-containing protein n=1 Tax=Niabella drilacis (strain DSM 25811 / CCM 8410 / LMG 26954 / E90) TaxID=1285928 RepID=A0A1G6XTJ4_NIADE
-MPVIKLETLVSADPETCFDLSRSIDLHRFSTVQTGERAIAGKTSGLIEAGETVTWQARHFGVRQKLTSKITAYQRPVHFRDEQQRGAFRFMKHDHYFSAVEAGTLIKDVFEFQSPLGVLGRLTDAIIMRRYLTRFLTKRNRVIKDIAESGMGACLVAAERNPYILERAGAFSYTHDGFIQEEALLRACYAWADVETIFAYKQDLLTTDEVCLDLFTRNGMRVFISESCSGWDRFLQKLSEQFPSLSEGWEWEVAQPPFKTNLALLFDRRGRTLTQAETDCYGGAHKP
->UniRef90_A0A0G1M8D9 Single-stranded DNA-binding protein n=1 Tax=Parcubacteria group bacterium GW2011_GWA2_45_30 TaxID=1618834 RepID=A0A0G1M8D9_9BACT
-MLVEGRLQTRSWQDQQGQKHWRTEIIAERIQLGPKPGGGGYEGAGIENENFEPAQNQARGPAAPKAVPPEETTPIIDIAEDEEINVKDIPF
->UniRef90_A0A388PNR4 PPM-type phosphatase domain-containing protein n=1 Tax=Opitutae bacterium TaxID=2026771 RepID=A0A388PNR4_9BACT
-MFSSTKKNQTLRWVNCLSGARGLVDQFPFRLPAGSPSPQVTVSPATQGLTLTPTPGRRPLVNGLAIDGPVTIAETSTLQLEDGLLALSLEEADTFRDLRTDAWMLFDAASGELLGEFAPADLLDRANDLGRPPEHLACTPTGLEVGFSLSLAAPLLSPREEIATRGPGPALLAAEQNRGAHLCPVCWTRFDAGDALSIAVHEDLRGDPILGSDARLRFQPTRFNDQGLALDPMGLACTDLACPHCRRQLPPGYLDMPHRILSLIGAPSSGKSYYLAVLTRELQERLPKDFGLAFKDGDPSGNMLLNQMRNTLFSAATPEEALLGKTALEGATYEKLPRLGRLVSLPRPFIYALSRPGARKQETSLILYDNAGEHFEPGVDIHDSPGAMHVATSAGLIFLFDPTANARFKARLIGVEDPQLSLKGRVDQQDSILAEMETRIKRVMGLAHDQRIATPLAFVVGKCDTWSRLLSSPLEPVTTPTGLDLAAIERNSQRVRAVLLDLCPGLVASAESLAEEIRYFAATSFGHNPVVIQQGPNKGRIAPDPQRLAPAHVEEPVYWLLHRASPELLPSAPRVNLEKSPAASRP
->UniRef90_UPI0005BA3CE0 TSUP family transporter n=4 Tax=Streptomyces TaxID=1883 RepID=UPI0005BA3CE0
-MPDIALSTLVLLCLAALVAGWIDAVVGGGGLLLLPALLIGLPNATYPYVTGTNKAVAIVGTTGAAVTYVRKTKVPVWTAVRVGLAALAGSTAGALFTTAVDEEILRPLIIVVLVAVAAFVILKPSFGARPEGEDRAPLTRARVVTAIVLVGGGIGFYDGLFGPGTGTFLVLALTAVLHLDLVTASATAKIVNVCTNAGALAMFAYQGTVYWQLAALMAAFNLAGGMAGARMALSKGSGFVRGVLLVVVLSMVAKLGWDQWS
->UniRef90_A0A5Q2W0C9 Substrate-binding domain-containing protein n=2 Tax=unclassified Pseudactinotalea TaxID=2649176 RepID=A0A5Q2W0C9_9CELL
-MAVSVRDVAALAGVSVGTVSNVLNRPEKVAPATVERVQGAIGELGFVRNDAARQLRAGRSSTLAMVVLDVANPFFTDVARGAEERAAEDGLTVLLGNSDDQAEREALYLEQFEQQRVRGVLITPVAEDMPLLRQLRERGTPVVLVDREVGDRTFSSVAVDDVAGGRLAVEHLLDGGRRRIAYVGGPVGTRQVIDRLSGARRAVAAVDGASLETVETRALTVHQGREAGEAIAGRDRADRPDAIFAANDLLAIGVLQGLQRSKVEVPTEVALIGYDDIDFVQSTVVPLSSIKQPAHLIGRTAVELLLQDAAGAGSPPEQVVFDPELVVRESTQTT
->UniRef90_UPI000D3822E6 PAS domain-containing protein n=1 Tax=Mangrovicoccus ximenensis TaxID=1911570 RepID=UPI000D3822E6
-MEREAGMPDKAGDLGEHVWADVLSAVDRTYAELIEYQEKLEARNNELQVLQDFLASVLASISDVLVVVSRDGLIEDASRSFCDAIGQKIGALRGQTLEGFFAEPARSQVGGAIAAAIRERRESVLEVDLAGAEEPVPLEFSVTAVIS
->UniRef90_A0A5B1CRN5 DNA-invertase hin n=1 Tax=Rubripirellula obstinata TaxID=406547 RepID=A0A5B1CRN5_9BACT
-MKNRNIIAAYLRCSSDDQSTEAQRADLERYLEREGFDLSRVQWFIDEGTTGDNLDRPAFEELDRLIANGAVATVVVWKLDRLSRSMIDGLTTVSRWLESGVRFVSTTQAFDFRGTIGKMVAALCFGFAEIEQQSRRERQAVGIQHAKANGTYKGRAKGATKAGVDPSRAKELRSKGLTFREIAAALGVSAPTARSYCMA
->UniRef90_UPI001CB8FAB8 hypothetical protein n=1 Tax=Nostoc sp. 'Peltigera membranacea cyanobiont' 210A TaxID=2014529 RepID=UPI001CB8FAB8
-MPELFAGIERQDDSFPVPYPDANIPQAWAAGSIFLLIRTILGLKADASKQQLKVQPNLPDCLPDLELTNLSVGDATVGLRFWRNGEQTQWEVTHLDGELEVSTT
->UniRef90_UPI00200782AC uncharacterized protein n=1 Tax=Purpureocillium takamizusanense TaxID=2060973 RepID=UPI00200782AC
-MDCDICHRGHDPQRLPFLCAVDARNQVYDARLKNLHLLIENDKLQAQIAKASGDDTPATTAQLALARQRLAEDRTDQILAAADKLRAEIQAARDDIKARRAALARRRSDLSSVSTGLVDRRARQQHEVEKSLQMLRFRWSQSAEDMAQTRAFLCTEALRLYGLKRTRKSNTSRYDYQIGKVPIVDLTSMDSLTPEIISTSLAHVAHIVMLVSHYLAIRLPAEITLPHRDYPRPTIFNLPGSYQHGPFAFPSASSSMTPMPSSAQIRDPESHHVPRPRPLFVDKPLPQLSKEDPTTYSFFLEGVTLLAYNIAWLCSCQGVSIGDKGSFEDMCHMGRNLYNFVLASQLQGYVQPAEPTNKGSNADNNNGVESRSNWIGRYSHGTSYYYLGGMEGTDFVRTFKLPSPMKLADKLKKKLLGDTPGADWEVLDDDAWKPEDGRTDQSGAKALSGALADKGGLDGTGATRSGTNGWTKVKHRT
->UniRef90_A0A2H5YHE1 Methylmalonyl-CoA carboxyltransferase 5S subunit n=4 Tax=Bacteria TaxID=2 RepID=A0A2H5YHE1_9BACT
-MGVRVTDTTLRDAHQSLLATRMRIEDMLPIAPLMDEVGFHSVEVWGGATFDTCLRFLREDPWERLRRLKQCFRRTPLQMLLRGQNVVGYRHYADDVVEKFVELAVKNGMDIFRIFDALNDLRNLETAIRAVKRYGGHAQGTICYTISPVHTIDLYARLAQELVEMGSDSICIKDMAGILRPYEAYELVKRLKDTVPVPVQLHTHSTGGLAPLAVLKAIEAGVDVVDCAISSLSLGTSQPPCESLVATLHGTPYDTGLDLELLSQIADYFAQVRRKYAAFEGEVTVDVGVLIHQVPGGMISNLLSQLREMGAADRLPEVLAEIPRVRAELGYPPLVTPTSQIVGTQAVLNVLAGERYKQVTRETRAYVQGYYGRPPAPIDPDVQRKVLGDADVISGRPADHIPPELEKARADLGELASSEEDVVSYVLFPQVAREFLEWRARGGGLEPEEVAAIAVALAQDHARPQPAAAPRREVSLWKVAGRRRLLNRAGVP
->UniRef90_UPI0014216B0F DUF5668 domain-containing protein n=1 Tax=Alkalibacillus almallahensis TaxID=1379154 RepID=UPI0014216B0F
-MKQSQSFLAITLIGFGLYFLIQQYDIPILSQFGNWPSILVILGVAFLFSAYGNNQHDNILPGIILFGLGVHFHLLQHQVNWIDHWGMYTLIIGIAFILRAQKKRQGTIIGIIFIVISFLALSAFAMPTWLGWLDVVFNMIEQFWPILLIIIGFVMLFKK
->UniRef90_UPI001E50B040 type II secretion system protein GspM n=1 Tax=Bordetella sp. LUAb4 TaxID=2843195 RepID=UPI001E50B040
-MKRPDDKDVSVPANAGRQSARGPDTPPAPVRGLAPTFATWRLKLRDALRPVAAWHAALTPRERRLVDVGGIVLALFLVFTFAIDPALTTIARSRNELPALRAQAAAVASLTNEAQRLRQHGGRTSNAPLAQTDIDESLRRAGFAPDSWRITQEVGNGNGGGNGNAGKPAVWRVELKQAPSTALMRWSDNVPAELRLRVANVELIRASTEYGRPIPGKVNGTVRLAASVGN
->UniRef90_A0A2T2YAG9 MFS transporter n=2 Tax=Adhaeribacter TaxID=299566 RepID=A0A2T2YAG9_9BACT
-MKRTLAASRWYRLIPVAFITYSLAYLDRANFGFGAASSMATDLNITPATSSLLGSLFFLGYFFFQVPGAHYAAHNSAKKLIFWSLILWGGLATATGLVSNVNLLIVIRFMLGVVESAVMPAMLILLSNWFTKTERSRANTFLILGNPATILWMSILSGYLINAVGWRWMFILEGLPAVVWAFFWWRLVDDKPTKASWLTEPEKRALAEQLQAEQQGIKPVKNYAEAFKSRTVILLSFQYAFWSIGVYGFVMWLPSIIKAAPNMDIVKTGWLSSVPYVLAIIGMFSASYFSDKTLNRKAFVWPFLLIGALAFYGSYAIGSDNFWLSFVLLILAGGAMYAPYGPFFAIIPELLPRNVAGGAMALINSMGALGSFAGAYIVGYLNSSTKSFGASYLFMAGSLLLSALITLYAVRGTRTKTPEPIKQAV
->UniRef90_A0A7N1A149 DELLA protein n=1 Tax=Kalanchoe fedtschenkoi TaxID=63787 RepID=A0A7N1A149_KALFE
-MKRENQYLYPNPDSSGAGSSSGGKGKVCWEDDPLPESGMDELLAVLGYKVKSSDMAEVAQKLEQLEEVMGSVREDGLSHLASETVHYNPSDISNWIENMLSEFVPAGFDSSLQPLPPASVHSFIPQLDSSASVNFPGFGGGDTSLPDYDLKAIPGNQIIYSPKQQQQQIDELGGNANKRLKTTVTATEAPLTTSTRPVVLVDSQEAGVRLVHTLMACAQAIQQSKLEVAGTLVNQIGLLAASQAGSMRKVATYFAEALERRIFNCHPQESVNPSFTDLLLMNFYEACPYLKFAHFTANQAILEAFSGKKEVHVIDFSMNQGMQWPALMQALALRPGGPPAFRLTGIGPPSPDNTDRLREVGLRLAQLAETIHVDFEFRGFVANSLADLDASKLELNPSDTESIAVNSVFELHRLLARPGAIEKVLSVIREIKPEIVTVVEQEANHNGPVFLDRFTESLHYYSTLFDSLEGSASSQDKVISEVYLGRQICNVVACEGPDRVERHETLDQWRLRFGSAGFEPVHIGSNAFKQASMLLDLFSGGEGYRVEENNGCLMLGWHTRPLIATSAWRVGSTGPS
->UniRef90_UPI0021515D3C SDR family oxidoreductase n=1 Tax=Streptomyces sp. KMM 9044 TaxID=2744474 RepID=UPI0021515D3C
-MRIVIAGGHGQIALRLERLLAARGYEVAGIIRKPEQADELRKLGAEPVVLDLESASVEEVAERLRGADAAVFAAGSGPGSGVARKEAVDKASAVLFADAAVRAGVRRFVVVSSMGADPAHEGDEVFDVYQRAKGEADAYVRGLDALAWTILRPGSLTDGAGTGLVRLEARTGPGPISRDDVAAVLAELLKDSSTAGLTLELISGPSPIPAAVKSVAGE
->UniRef90_A0A850P7D6 ArsC family reductase n=1 Tax=Ameyamaea chiangmaiensis TaxID=442969 RepID=A0A850P7D6_9PROT
-MTLTLYGIKACDTMKKARVWLETHAIDVVFHDYKTAGIDRRTLERWVAAKGWETILNRAGTTFRKLPEADRLALTPERAVTLMLAQPSMIKRPVLEGDGTLIVGFRPEFYETLLSA
->UniRef90_A0A559KBH2 ThrE_2 domain-containing protein n=2 Tax=Paenibacillus sp. JC52 TaxID=2163881 RepID=A0A559KBH2_9BACL
-MMLAAYFGGPVSALAELAVVYIGRFLKEGAIGYVQMAIGITAALGTGLFYRYCRG
->UniRef90_S6GGD3 Lipoprotein n=1 Tax=Osedax symbiont Rs2 TaxID=1330035 RepID=S6GGD3_9GAMM
-MQTHQINSWLLFSCLSALTGCANNYPLLQQQIETDNTLYRSGSHSISVSALLQNASTGTVAKVPQKKVQTPFQLRFNDTEVELNYVQQQRLQDYAQSLSAAVLSVHCGAGNSSSTLQAVSIALRRCQKIQRFLSGIQQQSQALVQADTPSQLITVAAANRQSGI
->UniRef90_A0A7V9G8G6 AraC family transcriptional regulator n=1 Tax=Planctomycetes bacterium TaxID=2026780 RepID=A0A7V9G8G6_9BACT
-MAQSLRKTAFTIGPACRERFLPLDRPAGLVLRDLGVHLAGISDLARPYEIGRPGVDFHCVLYTVSGAGWCELEGLPPSVGPGDMLVLPAGTSYGYGIAADSWRILWFHFDDGRGLGQALHGRKPAIHAAASIPRLQAAMEGFLAEARETDPESLRAAGLHAELIACYLGRELAADIDPRVAAVRHRLQKLWDDVDRDLRHPWSVAALAGRVHESQINLYRLCARHFRVKPMAMVTRLRMERAKQLLRETDEPLKRIADWVGYHNEFAFSTAFKRFTGSNPRDFRKRKRS
->UniRef90_A0A804R300 LigA n=2 Tax=Zea mays TaxID=4577 RepID=A0A804R300_MAIZE
-MRPRPPRVHDRSRQAAARQKPLPHVPHRAHHADDHVRQPDVRRRRHHATGSRLRPGHPLRPPPRRGAPHRPPRPRGLHDALHTAPRDARQGGRLRHVVPGRRGRGGLLLHHPVRRRARARAAGVRLHAVRRVDGRAHAAVTGAGRGGVRGLRGDGRNGRSARDAAGAGSSHAVSADEEGPELRVAGVPRQALHGGRRGHREHGGRAGAVHPRGHRRRPLRAKTPRSGRLPDRPGPASQAAVRARRRRAGSSTAARVREVARRAAPSVRRAALLWEHGRQLPVAPGPRDRRRPRAQRAPLPVGAPWPATAGRFQVPDGRQRPRAAPGRVPGEDEGPRPRVAHVGAAEGHPRQPRRRRLRHPLRLELHPREPVARRTDGALAAVRGAAPERVRARGRHGRRRRHAGGQEARQLRRGGGAGARGPVPDGRVGGEGEEGAGEGHGGEGPEPERRGQRRVVGRVGAETGARDFAQARRQGVCHRKRGEHGQRRRSRISGQNNMIPRTRRNRRRPRINRRPPCDPSGTAHVVWHCSQSPCAL
->UniRef90_A0A1Q9JNL8 Sugar ABC transporter permease n=2 Tax=Roseburia sp. 499 TaxID=1261634 RepID=A0A1Q9JNL8_9FIRM
-MQPFRQSKQKWIPTVRNKKVPKWVLGLLFLAPSLLGVAVFVLVPFADVVRRSFLDAMGKEFAGISNYESVFQNEAFQLAAGNTIKFILICIPLLLLVSLVCALLINGLKGYQEFFKTTFLFPMAIPVASVVLLWRLFLDRNGFFNEGVRLFGLSPVDWMNSEKAFGVLVFTYLWKNVGYDMILWLAGLAAIPKERYEAASVDGAGRWQTFRYVTLPGLRSSVFVIGILSLVNCFKVFREAYLIAGDYPHESIYMMQHLFNNWFVSLDIQKMTAASVVMAIVMLVIMSLVWYRNERSQE
->UniRef90_A0A7C7UU56 Septum site-determining protein MinC n=1 Tax=Aquificaceae bacterium TaxID=2053503 RepID=A0A7C7UU56_9AQUI
-MIEIKGKTTPVIYITIKEKGNIEALIQEISKKLNNKIFEGSLVIIENPEVLSEWERKKVEEILKKLTKGVFEKQKEEKEENRLLIINKSLRAGQRVEHKGDILILGDVNKDAEVLAGGNIIVFGKLRGIAKAGLIGDDIAP
->UniRef90_A0A535UZE8 M24 family metallopeptidase (Fragment) n=1 Tax=Chloroflexi bacterium TaxID=2026724 RepID=A0A535UZE8_9CHLR
-FAWFGDRTAFVGFRLPHQFFPSGRRLEEGMPYILDVAPIVGGYTADIGYAACLGENPVHARLLADLAEYRELLLAGVRARRSLRTVYEDVDRLIDRHGYVNRHRAYPFGVIAHRVGTVGGRGPRPTVAGFGLRALRSLAHDGVMGRRGGWSPLWGPGRASDHPPTPGMWAVEPHIGFRGVGVKFEELLVVTESDAFWLDDDLPHVRRWRGAAAAVPA
->UniRef90_UPI00166AE77F antibiotic biosynthesis monooxygenase n=1 Tax=Ornithinibacillus halotolerans TaxID=1274357 RepID=UPI00166AE77F
-MYAHMTNGTIDFLMKLTEKHPTIPFHFMSGTSKDVAYYEGVKKKYFQAGRSFEILVQLGEIQEQGYVVMNHIPVLDEGRPVFEDNFRKRKDEIHHQKGFQAFRLLKPLKGNTYVVFTQWDSANSYEQWKNSKEFQKAHTNIKPPAYFADRPFVNVYQMIEEE
->UniRef90_A0A1M3B6X1 K(+)-insensitive pyrophosphate-energized proton pump n=1 Tax=Chlamydia sp. 32-24 TaxID=1895742 RepID=A0A1M3B6X1_9CHLA
-MLSYDYGFVIACGFLAILYGIIMIRYILSLSSGNEKMQSIASAIQEGASAYLNRQYQMITLVGIVIFALLTWILGWHVGIGFLIGAILSGLAGYIGMNISVRANVRTTEAAKKGLSEALGVAFKSGAITGMLVVGLGLLGITGYYLYLKWHNVPMRELLEALVGLGFGASLISIFARLGGGIFTKGADVGADLVGKIEANIPEDDPRNAAVIADNVGDNVGDCAGMAADLFETYCVTLVGTMLLAGVFFQGAILEKMMFYPLAICAVCIIASLFGTYFVKLGTSNNIMNALYKGFVSTAIFSAAGIWAVTKYVLGTDVIYENNGISFNGMNLFYCALTGLAVTGLIILITEYYTLGKYRPVKSIAESSKTGHGTNIIQGLAVSMEATALPVITICAGILIANANAGLFGIAVAATSMLALAGMVVALDAYGPVTDNAGGIAEMSNLPAEIRKTTDALDAVGNTTKAVTKGYAIGSAGFAALVLFAAFLQDLTRYFPASADQCSFNLTNTYVLVGLLIGGLLPYLFGALSMMAVGRAAGSVVVEVRRQFKEIPGIMDGSGKPDYGKAVDLLTKSAIKEMILPSLLPVGAPILLYVIINAFVGQNEAFVALGSMLLGVVITGLFVGLSMTSGGGAWDNAKKFIEEGNFGGKGSDAHHASVTGDTVGDPYKDTAGPAINPMIKIANIVALLLLAILAAMSNQ
->UniRef90_A0A3B4T4F2 Coiled-coil domain containing 142 n=4 Tax=Seriola TaxID=8160 RepID=A0A3B4T4F2_SERDU
-MDQNNPETLKDPGGEPGLTADWNNSESVCPEKEQRRCLVTEDVTTNGSWSQSSISRSLQRAETLLRTTFNPSLKWLFHSRSQDEDAEEGHFVVAHNLVSRSSARLLRLQQALLTVAPQWQLVGGAQVGSPQVCVKGIPEREAEGGVVLVPSSSSLQGPYRTLWRLLEQRSLLLFIHEYTRRARLAAAYISRVSHLLEEQLRRPHLTPHQTLSSLSSFRVSLGSLSQELRVHLNHWSCLFSKVQSDHYLRPALVQQTRLLVEIKQTLDSLGLQALVLMEHYVCVILSAVAQAELDSVPREVLQDILAGTDVYNQAVEEQRAQRSATQLRTAVLLRAHHSTLDPGLPHSKQHHPAAFSVRELTVILAVHHAETAAEQLRSWASAQSCQVCQVHHTQEAGTSSVRSSISCGTCTLRPEWTWEQLQHTFLIPPPLLSSHQPTLQLHQDSAENHLPVLAKPTSVQQRPDCSDKDPTSQCQTHIPRNSPIQASVETVDLAQPHVENCEPPQTISPPSESSHRLSAPPVSAVCQQERSSVELLFQLLVSCSDLLVPLVSHTEAPAEPLLPHTPTDVTVTAPIISTDDSVELNRLSTDLNTEGSQADWAELDMTTRLETTCSSGFQRDRDPEGEGTVGLEGTAVAPDCVRPHSVQWLDLGQSLVFADLLGQYRALLWTLCSRALWLQMFVPPAGNAAGSINLQDNHRGFQILDRLSRASKTEDLVPKECRAMLEDFRLNLLVCTAHAQWDYVLCRGLGSALKDKCLIDGSHSVMSSSKMMSVTMEHFLLLTPPLLSSLCCQLSDSRSSGSSSLLTLHRQSVSLVLATVQLSTFWILSKAYQFLSSWSLNRFLLITQGDLKELRESLEVMVRQTRSLMMTPDSDYYSSLLLRQQLEALDRAVSELQTFSSLVLKTFSSDCKRMSGEIFEQTMPSSVHWKHSHRTGFPSSPSEYASLAAQTVIGQVLEGVAPLSDDARVQALSVTMTAFLEAWMEHILKQKIKFSVQGALQLKQDFDSIRELIQSDRYGLSADLHQHLLSLRVFQQVDSAVVCLLQQPQAKPYLQSRTWEPFTRCCPAGSRDSSDAAVGSSITNLGYVEGEDLTQADPSVMTSDLPPVDPSNPGEPYLAPSLALGPVQQEWLDLRIHGSARRWRLPGLQCLSKSEP
->UniRef90_A0A4Z1JUV9 MFS domain-containing protein n=3 Tax=Helotiales TaxID=5178 RepID=A0A4Z1JUV9_9HELO
-MSQGEQIKDSDHVAVPTSEKQASSDSQESSDVEKKASFTTPDGIVEDTSFVYMTGWRLHLMRLCCAISMFLVNMEVSIIGTSLISITNDLRGFSQMGWVVTGYLITYTGLLIIWAKISDIYGRKPAMIISMLIFTVFSGGCGAAHTMMQLIVCRVFQGVGAAGAVSLALVAAYEMVPKDKYPLQAALIGSAIALGSLVGPLIGGGVSEHSTWRWVFLINVPVGVVCAALLYISVPSNFPYHGRPVLPHPITNSLSRLDISGASLLLGATVLLVTVLLEAGIEFAWKSGTAIALIILSGILFVAFMLNEKVVSKEKRTQEAVFPFRFLSNRPWMGTLLMSFLSGVPYNIIVIDIPQRFQAIDSISPFTSGLRLIPFNFSISLSSILVNIIAKQRVPPIILLFIGSIIQLVGMSLFSTLPENGTLPNTIYGWEVLTGFGMGWVMGICLLLPPAVVEGRDLAISGGSLLQFRVLGGVLGLAISTAIMNNHLTSHLTPLLGAEQLSLLLQSTREIENLSEELRIETVKAFAYGYNMQMKVNVAFSVVQVLIVGVMWTRNGKGWRGQIEVVEKQILKE
->UniRef90_A0A3C1JH31 Ovule protein n=1 Tax=Acidimicrobiaceae bacterium TaxID=2024894 RepID=A0A3C1JH31_9ACTN
-MHLSTRAWDNHLEFIMLKGKNPKLTCRLYGATQMVSMANQSQNFFKKYTKLSLNRKTLWQTWTAGILIA
->UniRef90_A0A7V7MZ47 catalase n=1 Tax=Proteobacteria bacterium TaxID=1977087 RepID=A0A7V7MZ47_9PROT
-KTDMFARFSTVAGERGAADAERDIRGFALKFYTDEGIWDLVGNNTPVFFFRDPLKFPDLNHAVKRDPKTNMRDANNNWDFWTLLPEALHQLTILMSDRGLPVGYRNMHGFGSHTYSLLNKDNVRHWVKFHFVTQQGIENLSDEEAAKVIGMDRESSQRDLFEAIKNKDFPKWKMFIQVMTEEQAKTYRFHPFDLTKVWSKKDFPLIPVGEFELNKNPENYFQDVEQAAFNPTNIVPGIGFSPDKMLQGRLFSYGDAQRYRLGVNHYQIPVNKPTCPYHAYHRDGAMRVDGNYGGSKHYEPNSYGEWQEQPEAQEPPLELSGDAYAHNFRDDDEDYFTQPGDLYRIIKADGKADLLFNNTAANIGGAEKFIQIRHIRHCYQADPEYGEGVAKALGLSMDEVNNFDMKPHDQWAPRPSQE
->UniRef90_A0A258AK22 Histidine--tRNA ligase n=1 Tax=Verrucomicrobia bacterium 12-59-8 TaxID=1970608 RepID=A0A258AK22_9BACT
-MASFRTVKGFRDFFPEECALRNYITETWRSVARRYGFVEYEAPLVESTDLYRKKSGDEITNQLYCFLDKAEREISLRPEVTPSLARMATARQRDFKKPIKWFQIGPCFRYEEPQEGRGREFIQFNADILGDSSPATSAELIALAIDVMREFGVSADDFIIRLSNREIWSIFLADKNIAEEHTTTFLSIIDKIERARPEETEKKLALIGLTTAEVRAFMSSTDENHPAFAALRENLTARGLWQFIRIDATIVRGLAYYTGVVFEVFDLKHGLRALAGGGTYDKLCALMSDGGVDMPAAGFAMGDVVLGILLKRTPGAQMKLTSAYLAASSIDAFVVVADEAQRPHALAAVQSLRAAGIRIDYSFGSQKVGKQFQAAEDRKARFAIVFGAEYPEVVIKNLIARSQCAVPASGLVGEVQKMLAEPAVGPLIA
->UniRef90_A0A078FTM1 BnaC01g23140D protein n=1 Tax=Brassica napus TaxID=3708 RepID=A0A078FTM1_BRANA
-MLLIDWKVTTVNASRVPTFRPHLTAERYILSPDLMWLCCNPNFRLDVFVTLSMFDSNTVSFHKRLEAMRGDPRKWLEVVSILMPLQEHTFISIRRLMLERATFTSWSPLMKHGNGNSLPSHVPDALPGRGRGGDGLGTFPKCFRDSGDGKCFWGRVARCTHAVPVSINFKFSRFPSPYLSPYPFRCNIVLHRTGLPSAAPLLRGYAKVETLTISERNEFIITALTQDIDFICTGKVTSSKIEKMMMFCCLL
->UniRef90_A0A369H8Y5 Uncharacterized protein n=1 Tax=Ophiocordyceps camponoti-saundersi (nom. inval.) TaxID=2039874 RepID=A0A369H8Y5_9HYPO
-MAAANPFWWPMTIHKDVRFFQGQPNAPPHPPEARRRKEKLYREAMRKDDYDWASAYALEPVVKDISCDESTCARLCLDAFDDEPGLGRGRRGVWGFWFDFEHGACPMKRCWLDNDWSRKEDVLHWKIGGDRAVFDGLGYPTRDVVLLPGAFIVESLIYSCGDGW
->UniRef90_A0A7K6ALI1 Cytochrome P450 1A (Fragment) n=2 Tax=Upupiformes TaxID=57389 RepID=A0A7K6ALI1_UPUEP
-MLAAMKAAMSLVETQGIVSATEVLLAAAVFCLVFLLIQSLRQHVPQGLKRPPGPRGYPILGNVLELRKDTHLALTRLSQKYGDVMEVKIGMRPVLVLSGLDTIRQALVKQGEDFMGRPDLYSFQYISNGQSLAFSTDSGEVWKARRKLAQNALKTFSIAPSPTSSSTCLLEEHVSKEADYLVTKLLQVMEKQKSFDLNQYLVVSVANVICAICFGKRYDHNDEELLKVVNLNNEFGDVAASGNPADFIPVLQYLPSHTMKLFKDVNKRFNFFVGKIVQEHYTSFDRGHIRDITDSLIEHCQEKTVGEDAHISLSNKKIINIVNDLFGAGFDTVATALSWSFMYAALYPDIQKKIQEELDQTIGWERRPRLSDRSMLPYTEAFILEVFRHSSFLPFTIPHSTTKATVLNGYYVPKDTCVFINQWQVNHDEKLWKDPSTFNPKRFLNATGTEIKRMEGDKVLAFGLGKRRCIGETIGRWEVFLFLATMLQQLEFSLLSGEKVDITPQYGLTMKYKRCEYFQVKKRSPVKNS
->UniRef90_A0A2E0V7U8 DNA-binding protein n=2 Tax=Verrucomicrobiaceae TaxID=203557 RepID=A0A2E0V7U8_9BACT
-MNKAELIETVQGSLGRDATKRSAEDAVAAVLGAIANGVRTEGKVQLIGFGTFAAKTRKARMGRNPKTGEPMHIAASKSVGFKPSASLKASLAEPTEPTPPSA
->UniRef90_A8UFE2 Peptidase_M24 domain-containing protein n=1 Tax=Flavobacteriales bacterium ALC-1 TaxID=391603 RepID=A8UFE2_9FLAO
-MTRTIPVSGKYNDRQKAVYNAVNRVKKEATKMLVPGTLWEQYHVEVGKLMTSELLGLGLIDKADVQNENPDWPAYKKYFMHGTSHHMGLDTHDYGLLNEPMQANMVFTVEPGIYIPDEGFGIRLEDDVVIQDSGEPFNLMRNIPIEIEEIEEIMNS
->UniRef90_A0A2V9IHY2 DUF4488 domain-containing protein n=2 Tax=Acidobacteria bacterium TaxID=1978231 RepID=A0A2V9IHY2_9BACT
-MNRSLRAAVIGSVMLWLAALGLAAEKKPKSGPLTGTWECVSHGGPQGDMKFTLYLEQNKETVNGTVSSPLGSTELTSASFKKNTLEIHIDTDQRNYLLIGRYKDGQLAGAWSTNEDQKGTWEGKKSAQTTSQP
->UniRef90_A0A2R6HCQ5 DUF4265 domain-containing protein n=1 Tax=Halobacteriales archaeon QS_4_69_34 TaxID=1919177 RepID=A0A2R6HCQ5_9EURY
-MIDGGRGAGEGAPPDVPHWDDEYVDRVSDRLLSNYDLEKDYRVRGEVFPLYGQLSMTSHKQFLHPALSYARHDSAEHLFVRRVGSVTVAELERLVALAHDLADEWIVADEEHFGTEFTFALVVPAIPDEVRAFVADFSDRTLLKYGYYGHYEVNLVVVAPGREAHVASEGADVWRAFAPWADTDGEQPGLIDRLLGVLGR
->UniRef90_A0A3B9ERX6 Glutamine amidotransferase type-2 domain-containing protein n=1 Tax=Rhodospirillaceae bacterium TaxID=1898112 RepID=A0A3B9ERX6_9PROT
-MCGIFGIILKDRSAAPKDAFEHDLSLLYKASMARGRDATGLALHDSRNVHLIRRDCSPKQMLASDAYRRVVREGYAAQAAAPLAAFGQCRLVTNGSLAIEANNQPVVAGNVVGAHNGIVVNDGDLLPSEAPKTSAGGGTTALAETVHAANDTTRLMEAIDGALNRLGNLRRAVGEVFLRLEGEASIVVMSRLDGAMTLATNTGSLYFLSRADGSAFAFASERPFLRRLIAEGYVFTDVGDDAVVHLKPGEFLHLVPGRTTFDHGSLTDAAVAPDSGKQADPDNEPPVAAPVIRASNSAGGLLRCTACVLPHTYPGISFDDKGVCNFCRNHQHQKVHGRAALEQLLDKHRRNDGCYDCIVGLSGGRDSSYGLHLLKTEYGMNPVAYTYDWGLTTDQSRRNQAIMCSKLGVEHVLRAPDIAKKRRHVRKNINAWLERPRMGMVPLFMAGDKDFYQLGRDLKRDYEVDLTVFCSGSLLEQRQFFVGFCGVHDHVTYTARLYGYTPKVKAQLALYYLSQYLLNPRYINESFFDSVRSFFTSFLFKDDFLYLYEYIDWDEREIDRTLRDLYDWQSDSGYGRNQWRMGDGQTAFTNYIFHAVAGFSEFDNFRSNQIREGLIERDEALKLVEEDNQPKWGALEYFAYVIGINLDEVLARINNIPKLY
->UniRef90_A0A7X7D244 Cytochrome c domain-containing protein (Fragment) n=1 Tax=Acidimicrobiales bacterium TaxID=2201156 RepID=A0A7X7D244_9ACTN
-MSDHESGGEPSVPEVPEPPATAATAAGSAERSQTRRRLRIASLTGVAVALAAVGAFAYKQIKPVVDAQRYATVTYEVPVAPQLTAASGETLLRIDPTRSSLTYEIEETFAGAKRSTATGSTAGIAGDLALNTARLEDSRVGQIVVNIEQFESDNNLRDARIRQDFLQSHRYPLATFDFEEIEGLSGQLEEGETYEFQMLGHVTVKERPAASTWDVTASYDDGVLTATATATAKLSRFDAGPISIAGLVQTEDEVLLTLELTAVEPSANDIATTVERAGRLEAGSQEAPSYEQVIEPILEQHCASCHNSGQFGAHTLTLDDAGDVQAVSDGLKTVTQTGYMPPWFASDEGVELAHKPTISDEEIAALAAWSDAGGPLDVDPETPLDPTKEAAELLPRQDQELRIEPYTGSL
->UniRef90_A0A1F5NZ36 50S ribosomal protein L28 n=2 Tax=Bacteria candidate phyla TaxID=1783234 RepID=A0A1F5NZ36_9BACT
-MITPMKSCDVCGKGSKMVGHRIKLRGHYNPTNWTRKYPNLQKTVTPAGEKAVACVQCIKTFAKPARPVKARVLAKTTASAK
->UniRef90_A0A091DCM9 Spindlin-4 n=2 Tax=Fukomys damarensis TaxID=885580 RepID=A0A091DCM9_FUKDA
-MSPPAVPPTGIDGVSAYLMKKRHTHRKQRRKPTFLTCRNIVGCRIQHGWKEGNEPVEQWKGTVLEQVSVKPTLYIIKYDGKDSVYGLELHRDKRVLALEILPERVPTPRIDSGLADSLIGKAVGHVFEGEHGTKDEWKGMVLARAPVMDTWFYITYEKDPVLYMYTLLDDYKDGDLRIIPDSSYYFPTAEREPGEVVDSLVGKQVEHAKDDGSKRTGIFIHQVVAKPSVYFIKFDDDIHIYVYGLVKTPKKAVVTAAAWAVPSTIHHWRSGPPTKIIRKLRKITKLLCLQRMTTAFQIRTRSIAFSPQTPKLLEEIVGETDQAVAKNWDQGTYEDNLEGLRVFDKEGKGKVMGTEPRSVLITLGEKMTEEEVETVLAGHKDSNG
->UniRef90_A0A4U3LSB8 aldehyde dehydrogenase (NAD(+)) n=8 Tax=Herbidospora TaxID=28443 RepID=A0A4U3LSB8_9ACTN
-MTRQIVSVIGGKDEPSGTPYVSRNPARLKEVVAEVALADAATFAAACRNAAAAQHDWARVPAPVRGRVIASIGRLVETNAEALARLVSEEIGKPYAEALGEVREIVDTCDFFIGEGRRLYGQTVPSEMPDKNLFTFRTPVGVAAVITAGNFPVAVPSWYLVPALLCGNSVVWKPAEYAAASASALHRIFSAAGLPEGVFNVVFADGEQTFAGLETALGEGTVHKVGFTGSSEVGRKIGELCGRHLQSPCLELGGKNPMVVMPDADLTLATEGALFAGFGTAGQRCTSLGTVIVHESIHSDFVARFTAAAQSAHVGDPARKVLMGPLLDQKFADRYEEFLTWIGDHHTVTGPVGRITEANPCGHFLGDDPNEGLFYHPVIVDGVRPTDRLFLEETFGPIVGVTTFSTLDEAIELANLPGYGLSSSIYTRDPQSAFRFRAGVSAGMVSVNNSTSGAEAHLPFGGNGKSGNGSRQSGMWVLDQFTRWQAMNWDYSGRLQKAQMDVAEITPDLEFTL
->UniRef90_A0A250G1B9 site-specific DNA-methyltransferase (adenine-specific) n=4 Tax=Capnocytophaga TaxID=1016 RepID=A0A250G1B9_9FLAO
-MNDLKMNIPAKQSTKNKFGQYFTPEVIANFMISLANISNESKILEPSCGEGVFLNLLKEKGYHNLSAFEIDKELSKDFDFVRYESFISAKIDEKFDLIIGNPPYIRWKNLEEELKQELLKNETWNKYFNSLCDYLYIFILKSIELLSEKGQLIFICPEYWMNTTHSVSLRNYMVQNGYFEEIYHFNETPIFDKVTVSTVIFKYVKNCVRKEKIQISKYHSNKKLNNEILENLKNKKTFKDTYHFDIDQFKLNERWILQPEKLKRKLEVLENNCFKKNQSTLLSLFDENKREFHTIGDFCDIGNGLVSGLDKAFQINGCLLTKEENQATINVIKAKNINPYIANNITKYIYIEEGLEESEFIKKYPNFYLHFQKYKSQLEKRYQYNRKINYWEWVFLRNISLFKKQEKRIFVPCKERISNKNYFRFALVDKDVFPTQDVTAIFRKPNTSESIEYILAYLNTPIVFDWLKANGIVKGNIVEFSEKPISSIPFRTIDWSNGKEVEIHNFISESIRNYLKRPNELLLNLINESFSNLLCVK
->UniRef90_A0A7J5EE96 Hemerythrin domain-containing protein n=1 Tax=Flavobacteriales bacterium TaxID=2021391 RepID=A0A7J5EE96_9FLAO
-MTKKTPQKRATELVSLSHEHHHALVFCVRLKKASQTTPEITQNYVRYFWENHISSHFDNEEKYLLHLMPTAPLKEQFLSEHNEIRVLVNQLLTSAEEVMNNALLLSEKLNQHIRFEERILFPEIEKFASKKELQAVALQLNKSADCPVFFPEFWK
->UniRef90_UPI001175E0D4 diacylglycerol kinase zeta isoform X2 n=3 Tax=Euacanthomorphacea TaxID=123369 RepID=UPI001175E0D4
-MEQPEEDQPPQHDTSLQDGEEPFTSTSVASSSSSSSSNTELPSVPPAPRCLHTSRTFTGLRIFCRRKALSKSGLQHVAAQPGASTPSRTDPLVEPSGTIDWTDNAQFGDHIWFETSGSGDFCYVGEQYCIAKTLQKSVARRKCAGCKISVHTMCMEQLEKINFRCKPSFREPGSRAVRESNVVRHHWVHRRRQTGKCRQCGKGFQQKFSFHSKEIVAISCSWCKQAYHNKVTCFMLQQIEECCSLGAHAAVIVPPTWIIRVRRLQSSLKSSKKKKRTSLKCSKSSKKGTEIQDGRWKPFLVKPLPSQLMKPLLVFVNPKSGGNQGAKIIQSFMWYLNPRQVFDLTKGGPREGLELYAKVPNLRILACGGDGTVGWVLSVLDQLKLRPQPPVAILPLGTGNDLARTLNWGGGYTDEPVTKILSHVEDGNIVQLDRWNLQVEPNPEARPEERDEHQTDKLPIDVFNNYFSLGFDAHVTLGFHESREANPEKFNSRFRNKMFYAGTAFSDFLSGSSKDLAKHIKVVCDGTDLTAKVQEMKLQCLLFLNIPRYCAGTMPWGHPSEHHDFEPQRHDDGCIEVIGFTMTSLATLQVGGHGERLHQCKEVTLTTYKSIPMQVDGEPCKLAPSIIHISLRNQANMVQKAKRRISMPHLNDQQPVPEKLQIRVNRISMAAYEALHYDKDQLKEASTPLGVIIVPGDSDLETCRSHIERLQDNLDQVDTATGQDQDAMKAECLSSQKLSPKWCFLDCTTADRFYRIDRAQEHLNYVTEISQEELYILDPELVLKETVGTSPGMPDLVDSYGEECQDHQRQFAFPCSPSSPSSSTTPRVRDCQRKRISSDSSVAEALAQSSSKTTLCRRGAKILNVHRSNTTLADFRPMLSSTSATSSDTEKELELINCVKTEDLDRLMELHQQGADILLQDSRGCTLLHHAVEAGSKDIVKYLIGNVPTSHLDITEKETGETALHKAATSCQRTICHILVEAGASLMKTDLQGETPKQRAEKAEDQELAEYLENRQHYQMIQREDQETAV
->UniRef90_A0A396NWZ4 PBSX family phage terminase large subunit n=3 Tax=root TaxID=1 RepID=A0A396NWZ4_9FIRM
-MSDLTKLIAPSFYGVHHDIKAGRHTHYWLKGGRGSTKSSFISVEIILGMMQDAAANALVLRKVAVNLKDSVYEQLLWAIEALGVENLWQAKLSPLQLSYLPTGQRILFRGADEPKKIKSTKFRKGYCKYIWYEEADEFAGMQEIRTINQSLMRGGSSFFVFYSYNPPKSQSNWVNRECLQPKANRLVHTSDYRRVPPAWLGDAFLQEAEYLKELNEKAYRHEYLGEVVGSGGAVFDNVTVEEITDAEIAAFDRIYNGVDWGFYPDPWAFNRMHYDAARRTLYIFGELTRHRTGNAETARLLRQYGVQDTDLITADSAEPKSVADYRCYGLFCRGAVKGPGSVDYSMKWLQALVRIVIDPVRCPDTAKEFTAYEYDRNKEGEVISGYPDRDNHHIDAVRYGTEPIWKRRGQ
->UniRef90_W6SGZ7 Putative MATE family multidrug efflux pumps n=2 Tax=Clostridium bornimense TaxID=1216932 RepID=W6SGZ7_9CLOT
-MENTISESSFSKSIIRIALPITLQSMIRSSFSIIDQVMIGQLGSESIAGIGLGGKFASIYSVVLGAITATAAIMISQYMGQKNVKNVRRSFHVNLLVALFITVLFTFASLLFTEQIFSFYTKDSVTKELGKSYLQIYAWSFLPIALSGMAEAMLCCMEMAVFPLVASVSSLFVNTALNYILIFGKFGLPELGVKGAAIGSVVAQIISCLLTLVFLLWQLRKKKMNLSFDIRFNGNEYISYIKILTPLLICEFMWSLGENVYSAIYGNISTNDCAAMTMTSPIQGLMIGALCGLSQAAGIMVGKSLGNQNYEKAYNDSKKLMKYGLIVSIALSILLILLGKVYTGIYNVAAAVKQTAYALLVVFAIVSPVKVQNMILGGGIIKSGGKTNYIMWIDIIGTWGFGVPLGLLSAFVLKLPIIYVYFILSLEECVRLAISLILFKRKSWMQKI
->UniRef90_A0A8B8PLS0 segment polarity protein dishevelled homolog DVL-3-like n=1 Tax=Rhodamnia argentea TaxID=178133 RepID=A0A8B8PLS0_9MYRT
-MTTDIDSNSYFTETEDDSMSCSNYSETTCDTFISQRRNRYYNERSNGRSPNHHHGNQDTYRHTNSRARNIDNISQSSSSTTTSASQSDATAVHCITVYLVLTNENFLGLHIYANTLEGRDEGIYVDGVTENSAVALDGRIEPGDKIMQVNDVSLEELDNEEAVKVLKDAVIKRGPLKLVVAKFVDNNKDPVNGIVDPKEAIHPIDTAAWVAHAQAITMPRISSEMANSATSSPSFGSNAQDTDCIRPASAGMSRLNTGLRLNKATTDIQEIIEHMRMPNIGLEIKDREWLKIHIPKAFLGSDLIKWLERNVYGFSSNRDAKKFASRLLKEGYIRDPISKKSFNSKSYYTLEA
->UniRef90_A0A6L9YVB8 Efflux transporter periplasmic adaptor subunit n=1 Tax=Moorena sp. SIO4A3 TaxID=2607836 RepID=A0A6L9YVB8_9CYAN
-MPIASCLARSAITVAAAAEVEATKGVITAMASLQQSQASVRAEQANQARALASLAQAKADMKKAIAARNLAETEMKRYQRLWQQGVVSASDRDRAVTQFQDAQAAVEAAEAGIVSAQSQIRAAQASLEAARGELIAAQAQIDTAESAVSSAKAQLNKRNVILKDTVLRAPFDGIVAYLNIREGL
->UniRef90_UPI0020C880D2 PfkB family carbohydrate kinase n=1 Tax=Alsobacter sp. SYSU M60028 TaxID=2962936 RepID=UPI0020C880D2
-MDALFIGQTYIDVTFLADRMPTGDEKSVARDYAVSFGGNAVTAAFCCAKLGVVPDLLTSLADDWLGRMFLDMAAKYRISVHGRKVRESSLSFVLPNNGKRAIIRCRDDHYLHPFPILNIGNIRALHLDGHQGDAAMHYARVCRERGVLTSLDGGGLRENTHDLLGFIDVAICAERLAEQMNLSPEGLLAYLKERGVKIGGVTMGEKGMLWYDEQGVIRRQPPLAVPASAVIDTSGAGDVFHGAYVYSAMQRPDAPWREHFAFARAASTYKIQHLGNEEGLPSLADIERIVSEYREAA
->UniRef90_A0A4R7D5Q2 peptide-methionine (S)-S-oxide reductase n=1 Tax=Maribacter caenipelagi TaxID=1447781 RepID=A0A4R7D5Q2_9FLAO
-MKNVNKVGFGGGCHWCTEAVFMSLNGVIKVEQGFIAPKEHLTSFSEAVIVDYDSNVIELKDLVAIHLDTHRSTENHSMRNKYRSGIYFFKQEDELVLKEIMTDVQQDFETPLITAIFPFGAFKSSEDRYHNYYFKDTEKPFCKTHISPKIKMLKEKYAKHVSAKVQ
->UniRef90_A0A2J6HZN0 tRNA dihydrouridine synthase DusB (Fragment) n=1 Tax=Marinilabiliales bacterium TaxID=2053303 RepID=A0A2J6HZN0_9BACT
-MSGTDNLYLAPFQGITGAVFREVYTRYFVGVDKLFTPFFTGIYKKKNLTTRSDELDKIHHNKIPLVPQILSKDADEIMRFGEFCSEKGFTEINWNLGCPYPRVANKKRGSGMLPHPKMVAEILSRVQGHLPVQLSVKCRLGYHTPDEIFKLIPVFNQFDI
->UniRef90_A0A3G9IWN6 Uncharacterized protein n=1 Tax=Paenibacillus baekrokdamisoli TaxID=1712516 RepID=A0A3G9IWN6_9BACL
-MAAEPMIFIFTGTSGSGRKTIAKQIGSELGLYHVLSCTTRVPRATEGQDRDYHYISHDEFVELERSGQLLQSTTIGKERYGIRHQELDRALANGKHAYLILNSEGASLFKNLFKDRVIRIFIYVDKQTVRERLERKGTPYDVVDRYLDQYTEEVVYRKQCEHTIENVELIRTLEQIRTAINSHL
->UniRef90_A0A661X5S4 Ion_trans_2 domain-containing protein n=1 Tax=Caldiserica bacterium TaxID=2052147 RepID=A0A661X5S4_9BACT
-MRIYLFLFFMVGVSILWLWFLFFITRKLTGAKVIAVIIIALVGLVVFFGIKYYSFYLYDPKSFYIIPAHKLTYGGVRLFDFIYFSFVTITTLGYGDIIPLHTLTKILTILEVLMGVSFVGLILGRIVIKRES
->UniRef90_A0A2M7LC39 Copper chaperone PCu(A)C n=1 Tax=Sphingomonadales bacterium CG_4_10_14_3_um_filter_58_15 TaxID=1974093 RepID=A0A2M7LC39_9SPHN
-MNKISIMLAASASLLLASCGQGDVLYADKAVVNLSPVEGNPSAGYMNLHGGRTDVALVGVTSDDVLRMEMHETVEKDGMASMNQLKEIPVPAGKTVKLEPGGKHLMIWGVGAGSQQRGLLKMTLIYSNDDRIEIDAVVKKVGEAAPAVE
->UniRef90_A0A6H2DTH0 YbhB/YbcL family Raf kinase inhibitor-like protein n=1 Tax=Mycoplasma sp. 1654_15 TaxID=2725994 RepID=A0A6H2DTH0_9MOLU
-MIKIEIKDVKDGVLDTQFGNANLGGKYKNTVSFPIKWSKVKDAKSYAITLVDLEASGAMGIVFIHWIAANIKTNKLSWDFSFEHKDKIYQFENSITDKAENYLLKAFYTEHPNGVYYGPFPPDQDHNYEFRVYALNVDDIFGSHPQLKNNNLFYDDFINLIHNKVIDQGFTTFLYRAKTKINADYTLEKLDKSPKELNAPLKKEKQNFYAIEHPVDFQIFSNSLEKINDNTFLLDINNLMSLANLGYFHGKELELQWNKVDSVQEYVILLYSIAETKTLGVGLVEWVKVGIRSKDFPNNVISSLNSKESVKISNTFSSISLFNIAKLADLDETAFDYIKNGYGLCYIPYLTNNQGNYILNVYGLNQEIDWEQYQKELNRELNLADVYRKIKSKVIAKSEKIIKISPTLI
->UniRef90_X1LS14 Ribosome-binding factor A (Fragment) n=1 Tax=marine sediment metagenome TaxID=412755 RepID=X1LS14_9ZZZZ
-ASIKKLKEEKTVISFFLIKSFLNKKTFAFLNPNLKRSIRIKIADRLPVKIKISFLSK
->UniRef90_UPI0011132975 hypothetical protein n=1 Tax=Enterobacter kobei TaxID=208224 RepID=UPI0011132975
-MISYKVEFPTQKTVGFKVNGYSSAEGLDCKMVEAIGGDVKVQLDQKTMLTVPYREDITADFTLEGYKQRAETYAKTMIDQIVNAAQHRAADDLIQEVTNAVVSSELFSQLS
->UniRef90_UPI0004D08E5E LOW QUALITY PROTEIN: U7 snRNA-associated Sm-like protein LSm11 n=1 Tax=Galeopterus variegatus TaxID=482537 RepID=UPI0004D08E5E
-NVLTRMPLHEGSPLGELHRCIREGVKVNVHIRTFKGLRGVCTGFLVAFDKFWNMVIKPFSRAWGTSXRLNLLYLFDRLKLQDSSKKEADSRSAVEDSTLSRYSQTSTWKVASVWGRGDTDRGSRRRSRSVPSSLQASAREESRSEMSGRTTRTEGSSAGGTFSRATTLSRGQSCKKKRKPKVDYQQVFTRHINQIFIRGENVLLVHLAQ
->UniRef90_A0A8J2R764 THAP-type domain-containing protein n=1 Tax=Daphnia galeata TaxID=27404 RepID=A0A8J2R764_9CRUS
-MVRPCCICGIKKNSEAATKGIRFFKFPSTKSESHSNWIKTIRHHSTKISRPFTPRRNSIVCSSHFEDSCFNRSYRKLQLKQGSIPTIFNFDDSSKKVFSTACDVTSKADEEKEGNTEGNVSSSSLRDYASDGSSSLSPPVLLPLQDVNSDFEETIEDPPDLELYHINHDYDESTGLTSFADLDMIKMDHIGSVADILGPDPYMQDESIVMDERPDSSVGEERDEVDGQTILSFTSAEEMHEFAHREASSRLTKTNDFRQIKGWRNKFQQLTPSLSPSPCSSPVSLPARSAISASENSKSPLPTHFSRLCQNPSTSFEMKNLKENGASCEKNSPNLDTQQRPTSPVEEGCIVPSEETAETTEEMANSSLESTLPLPDLIAHSEETKETFQEERKEPLEEGMKKSLEDERKKPLEEETKEPLEEETSELLEETDELMEETAEPSDESTEAFPELGIDGLISYDYAKFAASAACFPFDEKRGKTFKKADNSLTASKKVSPRPKNSATRTRINKQSAVQHVQILPIVDIDEIPSGDMTGFDDSMEEVVVQEEEYVEVYDVPGNLVLPTADCGQLFCRLGCICDILIKTKNRTKVSVEHCGLPECMLQCVCGYQKGKPSSRKCFASLLKGNESFYSKINWSGERRRRERRVPERFSEFHLGNESSSSVSNRSSEEFKQVESKSKNNSHHRAGNSHSSRSSSPFKNASPPQSHSVSPQSVQDSLPCPPKNRKWEPFRVKVCADEIKLLRWDSFVSLSKVYIAPDHDIFCMEHTMYGCPCIETDRRIIRIPSEYVPLPVIDTTKNTENKSPTSSAKKVKAKNVTSSPSAKNVAKKHTNPNMRLAPKSKVMEENAAPAAPQEPVAKTSSLSKMRKILSDERFQLQKLMTEEKTRAFDEEVDLTVRQGQTVQLVAWIRFHRIYHAGRIHIRFLSRRAGPVILVMRPTEIVAADITCDIQDMKGNTNSPEIVKELLDPCISPEETSRYAFLLCDGVKWELVGCLSLKASNDAPPPTSTVPPASLDTPTLFPSPPSPQHSISTTEVPSVVLDEQNAQQKRVAAQMKFLARCPPRTRDEVSPDPSAIQRSSALELKRMQLEERLSVINSKLTLQPPKQSVSFKQFKNKSRASMAPILQPIIPTVSVVETPVIVEELPPSSLSAADPSIQAPRPKTVRRAGKRKPDMTYLIPDQCILPDDPEEMPVVSLTEELPEAQPKKNSQNLPDSVVSQEGKDPNQTLYPAAEKLAMFSRLIINSRNDSMSGGNFSNFEDSSMTASKLSRPAKRPPPKLERIPTPPLPVAVPLPLIAPESTVPNIPPSEMTFIKLQPIGSSLPNGISGQNTVRRIRILTPNSTVNGGSGNSLLPVLTSRNGWEPNLIQQQRLHWSSKGVKPPVNAKITPTPVISDSLITVLPVPTSLGTGQNVSTLTSSCATNASDIVQFIGPVPNQDGKTPAITSDLQVPDWSTQLLMKANAVASTSISLAGVKLLQQKQRGKSTSPPVVNAEPSKETESTSCVFPKIFTAEVITVKSPPGNASQRLKIIYEAMVGQHRDFCPSRASMILPLHNVDDQWCIVAINQVPDSGFQVPGVTVFIPRDMLGRAASAAMERKARVSFPLHFKLKNDGSALKSGFEVYGTPQLPHHVFVGPFPFNYIESCTPLSMMNNNVCMFVIKLTKPIPVSVSDCAKEVQQLKPTEQTEEVIQSTETKSTVNTPEPISETSPSTIEEVSVTSTPVSSNKSSSEADHTASSEATEVSESTLLNTKDSESAEIQIVDEKINSNPKSLSQLPGSSLLRQPIQSESVKRTKKPIRMFVARTPGLPPVNIKLFSENSVVVDHPFLSGEKKMFTSLEKAKTWLQTLAIRNCNVEVKKSKTSNSAEDSWANSDFTEDEEIDVCGQTQGESQEQEETVDSASTTSRSPKRIRRLTEKARILAASKSKSSRNSGSTTSSFKRSQDKLPLPRKVGSSRKNSIQRMLHIQKEQERRGLLGKLIRDLDALCASSSGTRAKIVVLKNATILVGQLEQQAKEMEALYQNLKEQRTTLLTLREQIFNKLPPNASQIFSCFMESVPLPSRHLAMIENNRIKRYRPQVPDRQSQNRVAVIVPNNALLSESVDVAQGGYVLTGVES
->UniRef90_R8UAD6 HTH cro/C1-type domain-containing protein n=1 Tax=Bacillus cereus VD184 TaxID=1053242 RepID=R8UAD6_BACCE
-MEIKKFIALTLFDLRNDEGYNRENFAELAGISLNAYASIENGKSLIKIDTLHTLLSELSLPLSVFFRRVEAKIESSK
->UniRef90_UPI0021CAFDB3 AAA family ATPase n=1 Tax=Acidiferrimicrobium sp. IK TaxID=2871700 RepID=UPI0021CAFDB3
-MAIANQKGGVGKTTTAVNLGAGLAELGYRVLVVDLDPQGNASTGLGVNARNLEASVYDVILHDVPMEDVIEPTTLRNLFVVPATIDLAGAEIELVPAFSRELRLRRAVESVADDYDFVIIDCPPSLGLLTVNGLAAASEVVVPIQCEYYALEGLGQLLRNVNLVQTNLNPRLEVSTIVLTMYDARTRLAEQVVGEVRQHFGDRVCRNVVPRTVRLSEAPSFGQPIIVFDPSSRGAIAYRELAKEVSGGAAQRVG
->UniRef90_A0A176TEJ0 Cytochrome-c peroxidase n=1 Tax=Polaribacter atrinae TaxID=1333662 RepID=A0A176TEJ0_9FLAO
-MKKLILSFLIIQLISSCTKEDVYEPFIFYNPEIEVAIPVNFPELNNSFYTNKPTKYGVKLGEKLFFDKKLSANNTISCSSCHIQANAFSDGISEAIGIYGRVGFRNTPPVQNMAFMQFYNWDGNKQALESQPLVPIITHEEMDSSILEVISKLETEEEYLHLFYNAFGDSKITGDRIYNSIAQYEYTLISANSKYDKVKRNEGETFTENEILGYKTFQDKCATCHSTELFTDQSFRNIGFPKNPNTDEAGRARVTGKTEDISRFRVPSLRNIEYTAPYGSFGQFATLKEVLDYLDNGVLEADNLDSVLKENNNQIPITEEEKDNLILFLKTLSDTDFIGQ
->UniRef90_A0A5C6S3D4 SDR family oxidoreductase n=1 Tax=Phaeodactylibacter luteus TaxID=1564516 RepID=A0A5C6S3D4_9BACT
-MDFTGKRVLITGGSRGIGRAAAVAFARAGARVAINFHSNKEAAEEAIKAMPGNGHFAVRADISKPDAVFRMVGAVAEELGGIDILVNNAGVFFPHPVAQSDYAAWQESWSQTIGINLMGAAHTSYCVARQMMGQGMPGKILFVSSRGAFRGEPEHTAYGASKAGMNALAQSLAQELAPYHIFVGAVAPGFVETDMAAHVLDGEGGAAVKAQSPTGRVARPEEIAHCILFLATEGAAYATGCILDVNGASYLR
->UniRef90_A0A1V6YXR8 Abhydrolase_3 domain-containing protein n=4 Tax=Penicillium TaxID=5073 RepID=A0A1V6YXR8_PENNA
-MSSIYAPAWDEFVQEIGPLLMTGSTVEDLYKDSEVNIQKIISKYEIPPPDNSVKTEDIKLNYAWIRVFTPPSATGNEPVGLFMHGGGWIMGSVDHEDAACRHITKSTGMKVVSIGYRLAPKFKFPRGLNDCVEATLWTLKHFSLSSVVLMGGSAGANLAFGVALRLIDAGVGDKVRGIVALVPCTVHPDAVPEDKKEHFTAYQENAVHTVNTLAAMKCFLDSYAPPPDDKYFSVLLHPRLQDLKKVYIVECGTDTLRDDARLMKGALEEAGVPIMYDDYPGYPHYFWSYPSPALAKASEEFHTNMFRAIKWINME
->UniRef90_A0A0M2PUS6 Imidazoleglycerol-phosphate dehydratase n=2 Tax=Prochlorothrix hollandica TaxID=1223 RepID=A0A0M2PUS6_PROHO
-MTAQGIAVFDIDGVVRDVGQSYRRAIADTVEQFTGGAFRPTLDQIDGLKAEGIWNNDWLGSQELIYRYYEGQGQSRESISLTYDEVVDYFQRQYRGANLEDPSQWDGYINQEPLLMGAPYLQQLAAAGIAWGFFSGATRGSADYVLQRRIGLQFPPLVAMGEAPDKPDPLGLLKVVEQLTHSLGLSPTLPVLYAGDTVADLYTIREAQSQAPDRPWWAVGVLPPHVQEPGPRRQAYEQRLWDAGAHRVVSRVTDLTPGAIGQLFREGA
->UniRef90_A0A1Y4NII1 Topoisomerase n=2 Tax=Lachnoclostridium sp. An169 TaxID=1965569 RepID=A0A1Y4NII1_9FIRM
-MPGVTKEQIQQARETDLFAYLQFHEPTVLKRDGPNYRHREHDSLVYVTGKKYWYWNSRGRSINALDYLIEIRGYDLVDAVNQLLGTDTRSVSIPKSSRAVTDQERNVAGEQRKQGNPSAESFSLPWARRCATFAVSYLRRRGISSEVILKCFRLGIFYEARYKGEAVCVFVGKDDEKKARFACMRSIMGKLKKDVYGSDKRYSFCYPPEHPGSRQVAVFEAPIDALSHATLQEVEGWKWDGYRLSLGGTSGVALFSFLERHPEILRVTLYMDNDLAGLVNARKIRSALHKDPMFKHIRVGINPPRTGKDYNEKLLCRLQQIKEDPDVSRQKEAAISI
->UniRef90_UPI001AE5D1C9 PTS transporter subunit EIIC n=1 Tax=Vagococcus allomyrinae TaxID=2794353 RepID=UPI001AE5D1C9
-MNAFITLVNKRVTPFATKLSRNIWIASLQDAIMSTLPLTLVGSVISVLSILNSYFPKFPDLSPISSFSFGIIGLAISFVLPVYILQRKKMDNKKNLAGIANVGLYLMLVLAQINENGELVFAGDSFGSGGMFLGILSGYFTAIIFILLAKFTFFKDSEAIPDYIVSSFDSFMPILIILTIAYLVVFTFNINFFEILTKILLPLTNFGQSYLGLLAFVFVTTILYSFGISPWLLYGLFYPIQLAGIAENTQLISQGLAATNINTGEVVQGLITLGGMGTTLPLAFMLIKSKSARLKAIGKAGIVPSIFNINEPIVFGAPIMLNPLLMIPFWLNSFINPTIVYFALKSGLVAIPTKVFNLWFIPAPIQGYLVSGDWKGILLSLVVLAVATAIWYPFWKAYDLEQLELEGEAK
->UniRef90_A0A1X9YSF4 Conjugal transfer protein TraG n=1 Tax=Pontibacter actiniarum TaxID=323450 RepID=A0A1X9YSF4_9BACT
-MQTGENAQALRKIIDMTRLISLTLLILHAYVHLYRAFAAWQLTWPLLDRLLDRVLASGLLDGFHRSKFLALGFLAISLLGTRGRPSEALRPRTGWACLAAGLLLYTASSLFLYLPWPVTKAALGYLALLTTGYLLMLSGGTLLARVVRLRLQRPDIFNRANEAFPQEERLLENAYSVNLPARYTLRGKLRRSWINIINPFRGLLVLGTPGAGKSYFVIRHVITQHIRKGFTMFVYDFKFDDLSRIAYNTWLRQRPHDPVPPAFYTINFDDLSRSHRCNPLEPATMRDITDAAEAARTILLGLNREWIRRQGDFFVESPINFLTAVIWYLRCYRDGEFCTLPHVIELMQLDYDSLFTCLRTEKEIEVLINPFVNAYLHDVMEQLEGQIAAAKVAMARLSSPQLYYVLSGNDFTLDINNPDAPKIVCMGNNPQKIQVYGAVLSLYVTRLVKQVNQKDKRPSSLIFDEFPTLYLSSMDSLIATARSNRVATCLGLQDLSQLRKDYGREQAEVIAGIVGNVVSGQVTGDTAKQLSERIGRILQDRASVSINSSDTSVSRSTQLEAALPPSRIAGLSSGEFVGLVADDPDCRIERKAFHSEILNDHAALQREQESYLPLPQVRQLDQAVVQKNYRQIKQDMEELVSSEMERLLQDPSLRHLVIRK
->UniRef90_A0A4U1HMG8 Asparagine synthase (Glutamine-hydrolyzing) n=1 Tax=Polyangium aurulentum TaxID=2567896 RepID=A0A4U1HMG8_9DELT
-MCGIFGYVTKKRAVGGPRALGAALRALRHRGPDDEASIELTSGDSRCGLAHTRLAIIDLSPAGRQPMSTADGRFTLVYNGEVYNHPELRKQLEALGVSFRGTSDTEVLLEAFARWGEAAIPRFRGMFALGIWDADRRSLLLARDHMGIKPLYFTAGPDGLAFASEVRALVAAGFAEPRPSRRAIASYLATGSVAEPDTIFEGVSPLPPGTILEYTDAGPRLSPYWELPLETAPPADRASAIEDVRATLADAIRLRLVADVPLGVFLSGGMDSTVIASFAARASSRPLNTFTVTFDEEAYSEERHAAEVARRIGSEHHQVRLSGGETMKSLPAAIDALDQPSVDGFNTYFVSKAARAAGLKVALSGLGGDEVFAGYASFSRFGPLLAAGRAGRRMMPLFDRAARALGKPFGALPQRGRKLLDALRAGGSPEKTYGVMRSMFDLGQISALLSPELAHEAASLPLNVPERLEPLVERGAMDPENAYSALEISNYLRNTLLRDTDVMSMSHALEVRVPLVDHVLVERVIRLPGDMKVGGGLNKPLLAAAAGDLPESVLRRPKMGFCLPFAEWMKGPLRGWAEEALLGEATRRLGFLNADAVARLWRAFLEGDRRVSASRVFCLITLAAYFGSHEALF
->UniRef90_A0A6C0E3C4 Methyltransferase n=1 Tax=viral metagenome TaxID=1070528 RepID=A0A6C0E3C4_9ZZZZ
-MQFWKNCLQFFNLVKSTEQQGVSETEASHAKAKAEEPSKEPEVEDEKVKDVVAQESPIEPEVDHVEAEAEAEAEEALVEPEVAHVESEAEAEEALVEPEVDHVESEAEAEEALVEPEVAHVESEAEAEEALVELEVAHVESEAEAEEALVELEVAHVESEAEAEEALVEPEVAHVESEAEAEEALVEPEVAHVESEAEAEEALVEPEIAHELELNTYFNNDPFEYFRSEHTQEKDLLDSDSE
->UniRef90_A0A4R3GCS8 Conjugative transfer protein TraD n=2 Tax=unclassified Rhizobium TaxID=2613769 RepID=A0A4R3GCS8_9HYPH
-MARTSTSDARKKDTREKIELGGLIVKAGLRYEKRTLLLGALVELKQRLGDDAGERLRLTLIGAKAFGDDA
->UniRef90_A0A150G0L4 Myb-like DNA-binding domain containing protein n=1 Tax=Gonium pectorale TaxID=33097 RepID=A0A150G0L4_GONPE
-MARKKKCHDAKAQKKHSVKGTNTAWSDGEKLILAQAVSEVMPGAANADNIDWPVVARAVPGRTAKQCREKWLSDLRPGIKKGAFTLKEECVLIMAHSKFGNMWAKIAKYLPARSANAIKNCWSSRGRAKELQKVHTLLYLYILLVDVASKEPQEAGRRGKRRREGEDGAAAADNADAVKKAKEEYRELAAAHKLVPLKAFLVDIDHYLSDADGTSPAMRDPRPEIWIMGRGKSRVPVAGEVDRNRCLPLGHDDDDDDDDDDDEQTTTNGNGSGNDDGQRHEMPCDERAGGRPRAMPPVPSVGPGGGGGGGGNGDGGGNGDSCGAAMAAWNASEGERKAEAVDEGSAARGKVGRKGSAGSTARDGSHSFRTAATSNASAGAEQAVPLLEPPSGAYHPCVGGAIGTGDSGALGQQRTESPQHPAPFVFASYGMPGPLREALDAAERTARPQGPQGPQGPQGPGDASFEACLRTLGQRLAERDEQLGRRGGEGGDGGGGGGGQEGDWLCPLDAALRGNAREGGRGRESTPGRDLRRGRRASWSGGAFPSPSPPSFWDTREIDAHFAAELGHPLPGSGFGEADHHRDTPQQQCRSDCACGFHATGCPAAQAAAATQAWAPAPAPVPGWGRVSAGAFHPQQLAPALQNQLIQTPPATAAPSYGSVLPFHSLPGLTAPWEPHHQPPPPLRPATSAPAPFALAALSEPGLVPQQHYGLHGGMTAAPGVAHQAGGGVAGAGAGGAYAAAAFALAPPQPPQYMMLPPRPVWQHGPRLEVDAIRRARFHAEALM
->UniRef90_A0A7X9ZMZ4 Endolytic murein transglycosylase n=2 Tax=Sphingomonas sp. G-3-2-10 TaxID=2728838 RepID=A0A7X9ZMZ4_9SPHN
-MIVLILVALAAGFGVLQIWAGPGPSRANVSVIIPEGASLTRAANELEKAGAIRSARVFVVLSQVFGGSEPIKAGEYRIPAGLRQSDVLAMLQGGKTLQRMVTVTPGTPSILVYEALMKAPHLTGEIEIPAEGSVLPDSYAYNRGDTRQMVLDRMQKAMVNYLAKAWEKRAPGIAVNNPRDALILASIVEKETGKAEERGLVAGVYSNRLKRNMKLQADPTIIYPITRGKALGRRILRSEIDAVNDYNTYSMTGLPKGPIANPSRASIDAVLNPAQTNAVFFVADGTGGHVFNETYEQHDAAVQKWREIRRQRGEIQ
->UniRef90_X5MP23 NADH dehydrogenase n=1 Tax=Candidatus Phaeomarinobacter ectocarpi TaxID=1458461 RepID=X5MP23_9HYPH
-MGIRVSDVAFVRFQAPDLDQMEAFLSDFGLVRAARTEDALYMRGAGSDPFVHVTHKGEPGFAGIAFLADSVADLEVLAAMEGASPVEDITEPGGGKRVRFVDPNGHKVEVVADRELVPTLPVRRNTPGNEATHSQRVDAALRSGEGPAQVMRLGHCVLNVIDFRQSEAWYKERFGLVTSDEIEIEKDMSIGAFMRCDQGDKPVDHHTLFLLGTGAAGFNHAAFEVANVDDLMAGNSHLQAKGYTHEWGVGRHFLGSQIFDYWRDPWGHTVEHWTDGDLFTSDTPPNMQGIDTLLGVQWGPPPPPTLGT
->UniRef90_A0A259M653 DUF3298 domain-containing protein (Fragment) n=1 Tax=Hyphomonas sp. 34-62-18 TaxID=1970392 RepID=A0A259M653_9PROT
-MNHPLNRRVAPLAAVFLLGLIGACGEPPKPDASDTDHGEATVEDYVRGPHNGRLLEDGAFALEMTIFETGVPPQYRIYPYKDGAPLDPSSVDLTVKLHRLG
->UniRef90_A0A060AF13 Flagellar FliJ protein n=1 Tax=Staphylococcus phage 6ec TaxID=1500386 RepID=A0A060AF13_9CAUD
-MNYIERIYSELVDLKGTVNILQIEMKEINSKFEDILIKIRETEFNVSQSVEMYKRLQEFLQERRLLRAQIEEMEVQYEILGGDEQLKKYEKALDFKEVKKDREFKKDKKYYRDKKYYNNFREDLKEKAIDLYHIV
->UniRef90_UPI001F0D41BD helicase-associated domain-containing protein n=1 Tax=Arthrobacter silviterrae TaxID=2026658 RepID=UPI001F0D41BD
-MAHFGWHHPRPARRVAKALAGFLSEAELLGLSGAGALTDHGRAIVHRDWDGALALVAAALPEPVEHLLLQGDLTAVAPGFLAPELAAELALLADPEGRGAAGVYRFSAASIQRAFSAGRTAEGILSFLAQHSATPVPQPLEYLLRDAQSRHGRFTVGQAGTYLTAEDAAALAELLAGGAAAALELTAISPTAAVSPRSAAEVVSALRAAGHSPGIAPGTPLAAGSDDGGTRRGTTSGAPRSRDRAAQSGPEMLAPHEVARLLAEEADETFEGGAGPDADSGAATAAVVLASAAEAAAAAQLGLLRSRPAWTPGTGESAPALALEQLHAAVRGKQAVWLTAVGSDGHPERRQLFPVSVAGGRVRVFDPGSGRERAIGIHRVMGVEIIAKGKGAP
->UniRef90_A0A6G0IZR0 Cilia- and flagella-associated protein 300 n=1 Tax=Larimichthys crocea TaxID=215358 RepID=A0A6G0IZR0_LARCR
-MAGDESDVERAFRLRYGRHRDNTAQMSHVLRYITDGGVKEHFSQFGDVSGDKLVKFGSFWRTEPAPISAAKIRECQHFFSHLSGLAAFFTKSAKRTKLLDEICHAKTACLVCTVYERREELVELFEFVVDSHNDFDDDAVHSMALLTGFEFCFLLATFNSVFSFSDMLFGILQNKEYDMQFCLSSIDDFCSTTEREKVKFDSINEDTVREVGGPCGHRAQRVGDVRAVYQQVYCAFEIVL
->UniRef90_A0A2R6KP62 Cation transporter n=2 Tax=unclassified Halobacteriales TaxID=38063 RepID=A0A2R6KP62_9EURY
-MSRASSLRRVGALVLVANIGLFAAKAVVWQTTGSLAVGSEAANSLADSAYSAVVLAGLYLTTQPADADHPHGHERIEPFVSLVVAGGIFLAGGAVAYNAITTVLSGSVTVSRGPTAAVVLAVGGVVKFGLYRYVLGVATDEQSPALRATALDNRNDILAAGAALAGVLGAQVGVPVLDPIAALAVSVAIGYTGVEVVRDNLSYLVGGAPPEELRAEILSRALDHPDVAGAHDVVAHYVGPEVDVSLHIEIEGATTVREAHEIETAVVRAVGETPEVDDVFVHVDPKELDEWKTDSEVDRLAVFEES
->UniRef90_A0A6L5DZ66 CHAT domain-containing protein n=2 Tax=Marinifilum sp. N1E240 TaxID=2608082 RepID=A0A6L5DZ66_9BACT
-MKNILKKILLFSLLLVFLSGENLNLAHNSILFSVSEVKTNPDSLLVQQFDRAFQFLRKGDFQYAEQSFRNATNTIENGIVNNKILVYRTYVNFGVLLGRIGKSQEALKYYNLSEQFTIDNFGVNSQKLVPLYVNMGNIFAEAEDLFKAQTYYEKALNLIGNAKSRFLPKIHNNLGTVYYKKRQYNLALQSYKESLRLKELAKTGDKFSSLNGIANCYKRSGNFNEAELFYSKSIYEIKRIGGDNSYQLGDVYLNYAVFQNESKNYNKVLPYLTLAYKVYSSNYGLKHPDTAHCLFNFGDWYHDTNKKYDIALEYYQKAIVSELDNFQDSSIYINPNLNEIEPQLSILQILKGKARALKSLYSTSNKISDLDFGLQTYDLCLNIIDKIRIGYQDEESKFYLSKNEKDTYTVAIEIAVELFQLTGDVSYKEKAFKYAERSKAASLMSSLNDVNAKNFGGIPQELQDEEIQLRKDIASYREKIYEERKKASPDRKKISDWQGVLFDLNEKYNQMVLRFEEDYPEYYALKYDNHTIDIEELQSRLEDNDVLIEYSISDSALFTFTITSSSFEVTRQNLDKDSFESHLEEVRNCLKTNDFAEKSADYYKRYTKSAFHLYKELFQNQPNNLDNKNLMIVPDGKMAYIPFGVLLKNEADSTRMNYRGLDYLIKSNTITYHNSATLGFSIESAGFSFSSNKSVLAFAPSYEDVNDSILYAERAYRDKLYPLPGVKEEVNNISKVIPGDLYVDDFATERNFKDHASDYDVLHLAMHTIIDDENPMYSKLVFTQVEDTTQDGLLNTHEIYNMNFNARMVVLSACNTGDGKLMKGEGVMSLARGFFYAGCPSIIMTLWTVEDQTGSNLMTNFYNFLSQGLKKDEALRQAKLEYLKTADPLKSHPYFWSGYVTMGDVEPLYDFNLKSNIAYMAFGSLGLIFLLIAFRRFRAKKMTA
->UniRef90_A0A1H7CBQ7 Negative transcriptional regulator, PaiB family n=3 Tax=Paraburkholderia TaxID=1822464 RepID=A0A1H7CBQ7_9BURK
-MYIPAHFEENRLEALHRLIADYPLGSLVTVGPNGLDANHVPFEFDAGKGPHGTLRAHVARANPVWQEVAERPDALVIFQGPSAYISPTWYPSKHETHRQVPTYNYMVVHAHGPIVVRDDEAFVRGLVARLTRKMEAGEPVPWKMGDAPADYISQMLGAIVGIEIELTKLTGKWKLSQNKASADRRGAADALNERDSDEQRAVADAMLAAPPNLD
->UniRef90_A0A1R3VCA4 MOSC domain containing protein n=10 Tax=Mesorhizobium TaxID=68287 RepID=A0A1R3VCA4_9HYPH
-MQALTEIGTVSELWRYPASSLAGERRDVISVGSETIDGDRLFGLVDASDGEIARPDREAKWHKVPLIRARLSQARQLEIATPQGDWLPAPGAECDGAVSAFLGFAASIRPFRQKDAPDYAGLLTAERYRKAPIHLLTTASLARLKALHPEGVADPRRFRPNIVVDVAAIEGSFPETEWIGRKLAIGDLLLTISEPCRRCGFTIIAQDGFDHDAAILRNLVRHNAHNFGVYCTVDRPASVGVGEMMRLV
->UniRef90_A0A4C1WBZ0 Uncharacterized protein n=1 Tax=Eumeta variegata TaxID=151549 RepID=A0A4C1WBZ0_EUMVA
-MPATFRTANPGWVHAATPTRKEDADMTNARVPRDLMLFSRSTSLAAGLRRFSQRLKLSPTNTARAPPAGMSTGDNPWRPPTDFDAKAAFDLIEFDHLSYVRLTHCPPLLSSDL
->UniRef90_A0A4Y9ZGX7 Fip1 domain-containing protein (Fragment) n=1 Tax=Hericium alpestre TaxID=135208 RepID=A0A4Y9ZGX7_9AGAM
-MRGWFVHSFLAVAELRVEPGRGSNGTASEIETHVGEIVRRAKRASDSRLSFRCRFDQHTLEGEGSPGQLPTTMDDDDFLYGGSAEPEPVPTTPAPEPKPVVAAIEAETIVPDIPFGKREPSSGPITPLTPLDVKDESRNGSVIPPDIGVVVQEAAVMEEVVQVDAKMETEEQEQEEEEEEVEIEEESEDDIEFIMEPPTRSLDLRPSRPVQPRVPSATATFTPTKAPLAAGPSLTTEYTPRERGAPPKPAVTXPSAPPSVSVPPSLPPGPSAEPMQPEQPKIEEGPEPSTLPLVTAPPSHPQINPDIPGTLDGRSILDIDLANMSEKLWRRPGADISDWFNYGFDELSWEAYCYRRRELSDVSSMLKTNVL
->UniRef90_A0A515EVL7 DUF502 domain-containing protein n=2 Tax=Rhodoferax TaxID=28065 RepID=A0A515EVL7_9BURK
-MVWLPLAITLWVLLWLVGLLDAVFASFLNGLSAVTPESLGPRLERLHAIPGLGVVLVFSAMLVTGALVSNVAGRWWVKQWDRLFTNIPIVKSIYNSVKKVSDTLFSSNGNAFRTALLVQYPRQGSWTVAFQTGSPSGEVASHLGADFVSVYVPTTPNPTSGFFLMLPKADVIELDMSVDEALTYVISMGSVAPGAQASKIPVSQ
->UniRef90_I9LJW7 Phage_Mu_F domain-containing protein n=1 Tax=Pelosinus fermentans B4 TaxID=1149862 RepID=I9LJW7_9FIRM
-MDADSKAIIVQFLATVDKILLDGDFTTSKMLDLNKAILTLKNDYTKLIREGTVKATESAKKLKGVEFKAYKAEVQRLLSAQEVAAAEQVFILGKITAEFGGGLDAKVIDSVWNKVWPDALNVDDRIKRLSAKVKEFTERTIKQGISEGNSAANISRILREHFVIEGLEGKAAFRLAAHTTNMVYQATQAEISIQATFVMGIRIVRGMFGKISPKCPICYEHGGDSYKEYFKSYFGGRDIDLWVLANMPPYHSNCSCGIEQITEDAITFIQRARTEYALKNA
->UniRef90_A0A7R9TH37 IPPc domain-containing protein (Fragment) n=1 Tax=Micromonas pusilla TaxID=38833 RepID=A0A7R9TH37_MICPS
-MAMGAGARASSIEDAEGPHPLTKAWAGRIKNAKVRAAFMDEPIAGYTSARDLKVLCGTWNTNGKSPPADLDVSRWLDASSRPDVVVVGFQEIVPLTAGKVLAVEDDKATREWEAIIERALNDAATTATTTAAAAAAPKNAAAFASDTSWQRAGQPPRTQTPQSAAGWTSFDSPGVSGGGGGWTSFDAPAFPGAAAAAAGRDRYIRLASKQLVGVYITVYVNASTAEHTRDVRVHTVSTGFNIGLNLGGFKTPDITLGNKGGAAVWMRVYSTPIVFICSHLSAGSKEGDAEKRSADFGEIVTKLSFPAPPSASSDGVAEKPAGVADAHAAVWLGDLNYRLNLPDDRVRAAIASGNCASLLGSDQLLLERAARKAFVGWIEAPVTFPPTYKYRPGTNTYSGAGDAGAEDENGGGGENGDAGGARVKVSAKEEKKKRTPAWCDRILWRGRDIRQNSYARAELTQSDHKPVLAEFTIVARELQPERLQETLDSLRRRLDAEEAASQPRCTLENPQADFGDLKHGETKAISFRLVNSGDVPARWGFVPGGA
->UniRef90_A0A2W4M120 Oxidoreductase n=1 Tax=Proteobacteria bacterium TaxID=1977087 RepID=A0A2W4M120_9PROT
-MRLAPRVGFLGVGWIGSARLASLAASRTAHIAAVCDPSPEARARAHEVVPEASLFEHYEELLEVPLDGVVIATPSGLHARQCVAAFERGLAVFCQKPLATSAAEVQRVIGAARASDRLLRVDFCYRHTRALSVARELVASGELGPIHSVELVFHNAYGPEKAWALDPDLAGGGCLMDLGVHLVDAALWVLGSPRVERAVGRRFREGQRLAPHSSTLEDFAVGLLDLDGGVSASLACSWWSSFGDHARIRAEFLGARGGVVVENVAGSFYDFACDRLRNATRERLVSPPDDWGGRALVSWVAELRASPKYRPEPELLEVARSVDLLLGRDPTAASASEPERVDAAGVV
->UniRef90_UPI00140DB29E hypothetical protein n=1 Tax=Psychroflexus maritimus TaxID=2714865 RepID=UPI00140DB29E
-MKNLSYLLFLFPVLCFSQIDLSPILTSGLEDANKFTSSYLEPGLDAVAFNLSNGWYSSAKAKGLGSFEIAIIGNASFVSEDQQSFELNTNEYDFLEFSDGSSAKNVANVLGENDPSITALSVYTDEFGNEQTVSFELPDGLSGSGLNFVPTAALQANVGLVFGFEAVVRALPEVKSENNKFRFYGFGLKNEFTKWIPGTKALPISIAGMINYSKFDARFALEETVLINGNDQRIDLGLETWAIDLIVSTRLPVINFYAGGGYVMANSTYGLNGTYQINDGPNSGETIVDPISNSSSLNGYRATLGTRLSLGIFKLFADYSFQEFSSVSVGMGFGI
->UniRef90_A0A0S4HPD3 SLT_4 domain-containing protein n=5 Tax=Pseudomonadaceae TaxID=135621 RepID=A0A0S4HPD3_9PSED
-MKQWRTWLPVLMLLTLTGCATPPPKDQNNLCNIYREYPDWYEDSLKMQEKWGTPQHVAMAIMKQESSFISDALPPRDYLLWVIPWGRVSSAYGYAQAQDPVWGEYKNGTGNGGSRDNFDDAIMFIGWYTTGTQRQLGISKWDAYNQYLAYHEGRGGYRNGTHLSKPWLIQVARKVEQQSQSYNSQLKLCRQALEDNRSWFF
->UniRef90_A0A392UKT4 Ig-like domain-containing protein n=1 Tax=Trifolium medium TaxID=97028 RepID=A0A392UKT4_9FABA
-MVTIPNFKAPGANLTVRCKSRNISNNSCWLAITAEHADTLFLLKASATTFAFPG
->UniRef90_A0A231P0P2 Aspartate 1-decarboxylase n=4 Tax=Desulfovibrio TaxID=872 RepID=A0A231P0P2_9DELT
-MLKILRAKLHGIRVTQCALDYHGSITLDPEVCRLAGILPLEFVYIWNKNSGQRISTYVIFGEAGSRCCILNGAAARTCQIGDEVIIGAFEYVSGPQDICHREPVVLTFDAQNRIEERLRYVVAQDGEDMAFSIVPDPL
->UniRef90_A0A8H4AAK2 Nucleus protein n=3 Tax=Gigaspora TaxID=4873 RepID=A0A8H4AAK2_GIGMA
-MPDESGHKRQRVSKACDSCRRKKVKCDGVQPVCGNCSTFNLDCTYNDATKKRGPPKGYIEAIETRLHRMESLLGGLVHSNDPFAEAVLAELMQDDPRPSRRSGNMEFTWKNGSLSTHGDTGRSGGSEVQSPENVLTSEAKDNSIDDLNEIMGILSIDENRQVRYHGRSSGFYLLKNSERYKNGILSLSDNSPKENLISTQNLESLKRPELTTLPPQEISDHLLETYFTHIHPLLPIIYKPIFFNRLKDRNNPPFLLLNAIYALAARYSDRPELRKVIQDSQTAGDEFFDRAKALLDNDYDKSHITTIQALIIMAIRDIRIDNTTRSWIYIGMAARMAQDLGIHRNNEKWQPISLSHEEKEEQKRAFWSCFVIDRIASTHMGRPLGIDEKDVDAAYPSEDEDDEYELLPFKMIHATSSTLLSSPASTNSSVLGSPMSPASTIINKDSPNAAHSVSRFNCLIKLCEIMGRIIQNIYAIRCNVSSANSTVTSILDSSLTSWYVNLPPHLQYNSSSDQHYDTTTLNLHGLYYSTLILLHRPYANTIGKNPSHNICTTAANAITDIADLMRQRKQLRHSPTTVIYCTFSAAVIHTYNAIQPDITISQPARVNLEKCLKILGDLITIWPLTYKYAVILTELANLRDAQLDVNMEQKNDGSEDGFNSRKHINPPIILDQHERQARYHPLNNKIITSHNNKGSSTQSQMFNPVSLNHSQTYERHPVMGFGNPITISSQSSSSYNQTQKSQLQLHHDLPESAQMFNNPFGYRYITSSTADQQTQHTMGGTDPYAAPGVVSTNNRIGNDTINSINSDLWFSQNAELNERSSYFGSQQMQQSVSPFSSPPSLHSQPQALMQIPLLHDDGNDVNMFADNHAFAAIGVGNCGNRRGNTSPVYY
->UniRef90_UPI0013A69B69 DUF2079 domain-containing protein n=2 Tax=unclassified Actinomyces TaxID=2609248 RepID=UPI0013A69B69
-MTAARLRPDRPLTRLLDGLPAALAVVVGAAAMIVYSVGQWRAMQVPSWDLAIFSELAKAYSRLEAPVVPIKGEGYNLLGDHFHPLLVLLGPVWRLFPTPLALLVVQDLLLAISAWPLTRLATRLLGRLAATVLGLFYVLSWGFQGAVASQFHEIAFAVPLLAWAAVAFVEGRWRSCALWLAPLVLIKEDLGLTVLMAGLAIALRGWQGAAQQPTHRGPAWWRRLSTARLGVLVALFGAAAFLLTVLVLLPALSPSGTWEYGLTGGGGADTSLIARLLSSEVKLQTLGALVGTAGLIGLTSPWMALVLPTLSWRFLSSNEFYWGWQNWHYNAILIPIALGALLDAVARLQAAPDAPATEVPGTPTPGTQQPDPEAPHATPGWSAVPMWARWAAALGVVLPLATGLLTLRDLPLWSITRSGYGAPSPRTQAAAQVMDLIPAGASVETDLGLLAYLVPDHTVYWVGTSEVDTDYVVVDSLSSAWGGNPPTDAAAWATGQSQNGAVYELVLDEGGYQLARRVS
->UniRef90_W7AVG7 RMI1_N domain-containing protein n=4 Tax=Plasmodium vinckei TaxID=5860 RepID=W7AVG7_PLAVN
-MKRLIEKNVIKINYNTFVNQYKKAFKCEKDIIDEELYEHFIINPFTYSRPFGCLLPNYNNTETYYLNGINIFEVVDYVNINERLYKVENSGDNEDDSDQNEDSFNFPDNSGNEDTIDYSNSEGEYGNGNKKGKKNKKSNKNSESIKTKGHTKGTNRNINSSNITQAKKSNNKYRRIFRFLLFDGKYFIYAYEYEYNEIFNYLETNKYKYPKIILYNNPVIRRKVILLKKNQVIILFKGNTTIEQNSSSIKDEEECYDITDINKKSYFNYTNKQEELIPISTKNESNSYNWSGNYNMPNQNRHRNDDPNYLSRENNVRNFYYEDNKIKNTYTNSGTTKDEKNYNYFHNNNNSKGYNRFTLQENNNNSDKYEHFKSYTPLKQAPNFNENVHNKNFTQTNSPNNNPNRIWINNQSNINKDSFHTNNSNNNNQLIDLTEGFFSSKFFQKSPDISNTCDDVIILDD
->UniRef90_A0A6I7QQX8 ABC transporter permease n=1 Tax=Spirochaetaceae bacterium TaxID=1898206 RepID=A0A6I7QQX8_9SPIO
-MFLRMALLNLLKHRRRTILIVFAIMVSVLVMEVMAGMFEGMRVNFFRNLTRESGHIQIHAPGYRDRLNPFTLDYVISGYEEITAALREIDGVLEAEEVLHFGALLEHEGRDLTMAGVGVRKGTRFYRDVREGIRGGTFPGDDAQADHTASGVLLSVAVARLLNLEQGDRVNVIVEDSTGSPYYLQLPLTGLFETSSPDLDEYTFFIDHESAQDLVYLEGGTIEIRLRLLHADEADAVAARIPGHLRRAGIDADLDVRTWRELHGGLTSLLEMMDFFILAMNVFVIIVVASVITNAILMNVFERMRVIGTMRAIGLKRRSAGAMILAEGAIQGVIGSALGLAAGIPIVLYFSVNGLDWGGISEAFGMGSSYYYFGYSLHNSVISALGGVLVALSGSLYAAWVGMRLTIMEALHHV
->UniRef90_J4S719 Universal stress family protein n=5 Tax=Burkholderia cepacia complex TaxID=87882 RepID=J4S719_9BURK
-MHRHPFKGHAMYSNILVALDGSDTSSRALDAALDLAAQTGARLTPVYVVDFLVPAYDTFGYDPSILIDAFREEGLRVTEDAAHRMTARGVTGTPQISNVAPAGEDIAHRIVTVADDIGADLIVMGTHGRRGFRRLVLGSVAERVLRQATCPVLMIPASCASKASADTAAASIEKEPS
->UniRef90_A0A849MVB4 Uncharacterized protein n=1 Tax=Roseicella sp. DB1501 TaxID=2730925 RepID=A0A849MVB4_9PROT
-MTLVFIALLALSWTGLSLAVLAMLMKRLGPPRQAAWRAFGLSLAVNTMGAAYATPGEPLSAVILILLCHALLLPPLLLAARREGQREGQRP
->UniRef90_A0A1G9RLY4 NlpC/P60 domain-containing protein n=2 Tax=Actinomyces ruminicola TaxID=332524 RepID=A0A1G9RLY4_9ACTO
-MSPFKSLHRCTSTAVSVSAAAAAALSIAVALPAAPAQAVVQFDTTSDLMSASGLSGTVYTAGDEAADDGAGMSFSVTNTLPDGIEGNIAVPLADDTWAVPQGLPTSPTREADSAAVEDLISRAQTFYDAGGQLIWDSSRPTPLTGTVVRDSTTAPYGVTCSTFVSMVLLGWDYQHTTYTADTNTQVGYAVDFGVDPTTSKIWRANNLASWFYANGDLWLETDGNYQRGDILFFSEQDPEGRIDQVRSGAESTYFGNVYHAAIYLGDGMLIHSTGTGNGVNITTLNPLLEADLSFVARPTFTAEAANTGQAAESGDDATAQGETTESAGDDAAPTETTGSEGQDSSQDGTTGTTGTTGAGGVRAVTPVSPNRQYSRPIEDHRGWMSR
->UniRef90_UPI001F24B592 CHAD domain-containing protein n=1 Tax=Streptomyces sp. GQFP TaxID=2907545 RepID=UPI001F24B592
-MAQQHLEPTDPTTAGPVTADALADYLRAQATEFLRALRLHRETGTASSAPSAEEPVDAARALRHAARRITGTLHTFRPLLDPTWSETMHPELAWLSGTLAREHAYAARLERLLLALQRLSGAVPLPAQAGVAVGSRSARAERVGTAEPGTAGPPTHPATPDRSNLTVGAAKAGALLERQLTLARTRAHSAALQALGSSRFHAVADNVAVLASEVPLTPAATTTPTDLRPLAAAADERLCDAVNALPLLTAGHPYNAEALVHGLSPDPAPHPQDAPWHHVRLLLRLRRYAHEVLDGDEARVDVRMLTAGTALNRHRDASEAAAAAAAAARTPRIAPATAYALGVLHADQRHEVEAARFAFQQSWEKKAMSTR
->UniRef90_A0A0R1J1V1 N-acetylmuramidase n=3 Tax=Companilactobacillus TaxID=2767879 RepID=A0A0R1J1V1_9LACO
-MPQKRNYNRRRRRKNKYNQPLIIFLTIIILLGAGVFGFRRYSEYKQEAQTEQVETEHNAFVKKVAPYAIYLGKEYGVLPSITIAQAILESDWGRSTLAKDYNNYFGVKGSDPSNTKVLQTKEYTDGQWVTINGRFRVYSDYRESMKDHAELLVNGTTWNSQQYQQVIHSKDYIEAAVALQTDGYATDPGYTSKIIRVIQKYNLKKYDEGIK
->UniRef90_A0A1Q6SW29 Glycerol-3-phosphate cytidylyltransferase n=2 Tax=Firmicutes TaxID=1239 RepID=A0A1Q6SW29_9FIRM
-MNEKQPVIGYTTGVYDLFHIGHLNLFKNAKGMCDRLIVGVTVDELVEYKGKKAMIPFEDRIEIVRSCRYVDAAVPQYDMDKLTAARKLGATVLFVGDDWYGTEKWKKYEREFAEYGIRIIYFPYTKGISSTKITEALNSVRRDDLSDLK
->UniRef90_A0A4V6IDT8 DUF4309 domain-containing protein n=2 Tax=Chryseobacterium taihuense TaxID=1141221 RepID=A0A4V6IDT8_9FLAO
-MKRRIIAFAVLFLFSAGIYFLLYHKDKNLNFIPENADAMILIDKKKLTRQYLSAFIAHPSQWFIESSESEKKRSVFKAGLKIPDFLQIFHLKNSKLTEWYAVFDIENPQKLLVFLKEHKFKNLGQNLYIKDMLYIKIADQKCYAGISGHDFEKIGRPLNGIFGDKKLNADHFMEEGTGSLSFISGTRTRNFSIELKDREIEIKNASNIENYASFISQLSKEDLFINAELNKENIKVFNKVLPDFFKDLSEVNHLKMNAKLKQVKDTIISYGYDDDFNEIEEISYQEIVQPDYMIQLETQDPAKIWKHFRSENLINDKNEFTGIPFQPNRVYQSDNGIVIKSVTEQSLHSQKKGKNFILIKNDPLLFSFSKGLNDFKYLKDIEYFFYGNKGQDFFLTLKLKDQKLPLILQ
->UniRef90_A0A4R2KRA3 Purine hydroxylase delta subunit apoprotein n=1 Tax=Marinisporobacter balticus TaxID=2018667 RepID=A0A4R2KRA3_9CLOT
-MFRINFTINNKGYTVDVDEALRLVDLLRDKFQLTGTKEGCAEGECGACTVIMDGRTVQSCLVMAFQADGSNITTIEGLEREDGLHPIQRAFLDAGAVQCGFCTPGMVLSSKALLDKNSNPSREEIREGLSGNLCRCTGYNKIVDAVALASKYLKEEESDGASENSRK
->UniRef90_A0A0G1RJJ4 S23 ribosomal protein n=2 Tax=Parcubacteria group TaxID=1794811 RepID=A0A0G1RJJ4_9BACT
-MDKLSNNGKYDLEERTAKFAECIIDFVRTIKQDAVNRRIIDQLVGSAGSTGANYCEAVEAESKKDFIHKVGIVKKEIKETKHWLRLFARANPERAEEMRKFWKEAHELLLIFSKISRSSRGQ
->UniRef90_A0A0Q9NGW8 Helicase n=2 Tax=unclassified Arthrobacter TaxID=235627 RepID=A0A0Q9NGW8_9MICC
-MIDNDEIFEEAPASLQDLIDNDLDGLLNVPEKAKKVTSSDRLERAFLEIVEFRRTHERLPSSATREIAERKLGARLEGILANDEKIAALKHLDTEFELLAVEAAPESLDELLDSDDLDDLLGDDSGILDVSDLPVIKRPESPDSVAQRVKAEDFDLFEPLFKAKHAELAEGTYSLVPFTGMDLIREGAFFVLSGVMCFVAEVGEDVDLIVGGKPRQKQRLRLVFENGTESAMYKQSLMTRMYEAQGQVLARTGHDATEALDADVESGHIYVLQSLSKDPVVAGMKDLHKIGFSTTKVETRIKNAAKSPTYLMAPVKVLADYRLYNVRASWLEHLLHRVFAEVRLDLTQVDRKGRDYDPSEWFVVPLETINKAVAMIMSGEITDYVYDAQLKKLVERQQAGWE
->UniRef90_T0Z4L1 Delta-aminolevulinic acid dehydratase n=1 Tax=Leptospirillum sp. Group IV 'UBA BS' TaxID=1260983 RepID=T0Z4L1_9BACT
-MSYAVKYASALYGPFRDAMMSGPQFGDRSSYQMDYRGIRDALREARLDAEEGADILMVKPALAYLDIITRVSEGPDLPVAAYQVSGEYAMICAAGQNGWIDQDRVMIETLTAIRRAGAQMIVTYFAVAAAKLLSLRP
->UniRef90_A0A8H7V2K7 ADF-H domain-containing protein n=1 Tax=Mucor plumbeus TaxID=97098 RepID=A0A8H7V2K7_9FUNG
-MSLNVSDSALIDKYEDVRDDKSETNWVFFDFADGKPDRLQVAGSGNGGLAEFVAQLKPEVAGWGYLRMNMSNDEYSQRIKFVLVPWCGEKVGIMRKAKLSIQISDVKNVLRNFHIEVPASQTSELTESEILTRLRRAGGANYDRQSSNY
->UniRef90_A0A538BAD3 Trypsin-like peptidase domain-containing protein n=1 Tax=Actinomycetia bacterium TaxID=1883427 RepID=A0A538BAD3_9ACTN
-MQMFTAGSQCTANFVYYDGTNVYVGQAAHCSGTGGNTETNGCTSGTLPVGTQVDVDGASKPGVMVYNSWITMQRLGEKDANTCQYNDLALVKLDPSDVASVNPSVPHWGGPVGLDTTGTTPGEKVYSYGNSELRGGVSQTSPKEGTSQGDTGAGWSHTVMTYNPGIPGDSGSGFLDATGNALGVLSTIDVGFPTGVTNGVGDLAKELSYLHAHESSFASVQLVDGTDPFQAGTLPGLGGLLGGLGLA
->UniRef90_A0A2E1DI39 Two-component sensor histidine kinase n=3 Tax=Flavobacteriaceae bacterium TaxID=1871037 RepID=A0A2E1DI39_9FLAO
-MRENNISLSSRIFYYMMVFIVVESIMIAGVTLYQFNNQNSEYHEGRLERKEKNLLTDLKYEIDKSGINSIDALSNSMILEVADVHNLEFELYSLEGFLLKSSTALTGVRGTTIIDQQIVDYFKNENPSRYVEDDTNTNYFKSSYNLVTNFKNEPLGIIYIPYFADDTSSKQELTGFLIRLGFVHGNMILIAFVIAYFISNFVTKSLDSIGETIKKTNLQNQNVKINIDNTPREVVALIDSYNTMIDELKSSAVKLAKSERETAWREMAKQVAHEIKNPLTPMRLSIQTFERGFSKGQEFTKERIKEFSDSLIQQIDTMSSIATAFSDFAEMPEPKKELLNVVEVVGLAIDIFNKDHINFNSSNKVIQANFDRTQLIRVITNLLKNAFQAIPEDRTPEIKVSILEKDDNVNISIADNGYGISKTDTEKIFEPSFTTKSSGMGLGLSMIKSIISAYNGNITFSSKSNVGTTFNITFPKN
->UniRef90_UPI000DC13EC3 piggyBac transposable element-derived protein 4-like n=1 Tax=Melanaphis sacchari TaxID=742174 RepID=UPI000DC13EC3
-MTRNRFFELRSCFHVVDNKAIPKENSDKFVKIRPMYNSFIKRCAQLPVEQNLSVDEQTVPFKENLSIKQYIRGKPSLWGIKNCLLCGQSGLVYNLLLYQGSSTQIDENMQKNFGLGGAIVLKLVENVKPNKHFLFFDNYFSSYNLFCCLLKYKILAAGTI
->UniRef90_J4GUB1 Zn-dependent exopeptidase n=1 Tax=Fibroporia radiculosa TaxID=599839 RepID=J4GUB1_9APHY
-MAGNKPSAKLEKQPGTIPAPVVSSPAPARGRCLLRRTVLVGIAAIATFYYVGSLVCQINREINAQQGLWLAKAFGGHSQKGFKHKAAPFGKVAEEIFLAVPNPASALATSRQYATAPHLAGSEGDYKTATDFLALLQSELGISASSPLPVFPAGSSESRGATLSITSSSPSKPSAWIDVYYPVMNTPLDRSLEILDEDGNAVWAANLEEQADETDSDAGKYADAVPTFHGLSRGGEAAGKLVYANYGRKQDYDALVASGVELNGTIVITRYGGIFRGLKVKGAQDLGAVACLIYSDPRDDGTVTQENGYEAYPNGPARNPTSVQRGSTQFLSIYPGDPTTPGYPSYENSTRTEGTNIPTIPSLPISWANAKVLLDEIEEGGGNRTISLVNHVDDRVIPIWNTMGVIPGYIKDEVVVIGNHRDVAHCIRAAWVLGATDPSSGTASIHEVIRGLGVLLKQGWKPLRTILIASWDAEEYGLIGSTEWGEDFADWIDEHVVAYVNLDSSVSGSSFYSAASPSLSHFMRSAAETIAHPTKPGLTLWDATKDKGPLYGNHIDAEALSVYEEEQAQMAADDLGVNVLGSGSDYTVFLQRIGVASTNNGFKSTLSDPVYHYHSVFDSERWQELYADPGFLRHVAIARFLGLQTLRLADSIVLPLNTTHYSVQLDAYLDKVEQLRSSMALDVDFSSLRESISSLRAASVALDNEKSEAESELRHLIRRIARRKFVRDHIRKAWCKLRKIFRKPCKHRKHEAGEEYGHRGNEEHARPRAGHAHPASPARTIEGRTVKPRVGRWAGMLKEQREREHGRDSADKHVRGQKCHIEAHDGKDKELREAFVRAVKRVRAANKKLVAFERGFIHPDGIRDREWYRHLGVAPGKWLGYGATTLPALTESITFDANATMAKYEAGRLKVLFDKLAEEIQV
->UniRef90_L7KPS4 DUF697 domain-containing protein n=2 Tax=Gordonia aichiensis TaxID=36820 RepID=L7KPS4_9ACTN
-MDDVRAQPSTLDAVGAQSGQTSVSAGGRVVVAAAGGVDVEALVEACREVGASRGAPTIDFVGFDSDHGHAATSAAVFVIDPASAVVDDEEIAVLHELTAAVGNVALVCGRIESFWDWPRIVRGYRAELDPDELLPVFAVSATAALAGAVDESGIGDLIEWFSTPASAVGDGVAAGTPTPAGEVMSVGDARMRADALATRRARLLAQRDRGRSDRLASLRAGIVRVRAQSSADIATRVRELAAGAEHRSNAVTNADVEATATWLDREIAGLVADIDAVTHARLDAVASSTLVGLDVDDPPVQRADEPMGTRRDVPSGRRTGEDAMVLVIGASTGIGIGRLAVAPLASVHTLQWISMPAALLLGLAVAVWVIRMRRAATTRAQVRTWVGEVLADARTRVERRVAMVLSEAESRIGGQLLRAYERQGRRIADEVAEIDERLRELRTAVTGRSEK
->UniRef90_UPI001C5DEC67 DUF917 family protein n=1 Tax=Saccharothrix obliqua TaxID=2861747 RepID=UPI001C5DEC67
-MREISAADLPALMTGSRLLSASTGFIVDACLDWVAELVDRHGPVPLVGVADLPPESPCAAIAMVGSVTALAELPPTGEEPELAVRALEARLGHPLRAVMPLAAATVNALFPIAAAAVSGLPLVDCDGMGRVLPLIQQSTYALAGLPLTPLAAVGAAGDVVVVDAAATRADPLLRAAVTTAGGWMLCAMNPTTAGHLRNAAIPGAVSRLIDVGRVLRTAADHTALLDDLTRVLGAKLLGSGRVVELSHDTRPTGPGLPANPTSVAVVEYTGAGRLIRLEAQNEFLLATVDGAVAAAVPDLLCLLDRRERRVVDPESVVVGDHVDVLVIPAAPVWHTPEGLRLAGPRAFGFPVGHPREGISP
->UniRef90_A0A653DFF8 CCHC-type domain-containing protein (Fragment) n=1 Tax=Callosobruchus maculatus TaxID=64391 RepID=A0A653DFF8_CALMS
-MESFVAPPRKTNFMEPDLAYVQVDEDRSIVDQGSSKANSTSKQFRCYRCNQPGHRAAGCTAGMSKKKKPKATDESLTNSLGFTQICSLENNSKSIAELLKENEELKEIIQQNQAIISEKEKLINQLLKENDHLQSHYNLINSNIIEKDTIVGTIDKITKRLENLEKQPSPISYASVANKQLGTPQKSLKKLVIKPKGKQNCSDTKKDLNKNINLSKLQIKIEAVNDTRDGGVELKLQDKYVNILKNEMDQVLLRKYEVMEEKKILPKIKIVGYKTREKPTMEEIKEKLIRENYFLHEEDIRVTYLNYIVQHNYYTIHAEVSG
->UniRef90_A0A0F8X3M4 Glyco_hydro_2_N domain-containing protein (Fragment) n=1 Tax=marine sediment metagenome TaxID=412755 RepID=A0A0F8X3M4_9ZZZZ
-MLLYNSPDLQFSTMNLQRSTEKIVFCLLLICLQTSLLKAEKTDTGNPRTSYTINEDWSFTPQGLAFGYRPLAKDPGAEIISLPHTWNTQDPFDGKYTYRRGISWYRKELVVSEKLKGKRLFLYFEGANQVSDVYINSVFVGQHKGGYTAFAVDITDYATFGREEPNLIAVQVDNSHDNHIPPLSVGYALYGGIYRDVRLIATSPVHFKVSDHASSGIYIATPEVSDKMARVDVRGTLVNNTNE
->UniRef90_A0A3Q9BJ05 Cytochrome P450 CYP721A63 n=1 Tax=Panax ginseng TaxID=4054 RepID=A0A3Q9BJ05_PANGI
-MNPFLLILLLLVISLLKFIHKFIWIPLSIQNHFRQQGIRGPNYRPFFGNTAEIRRWMMAEAKSSRTDFNHDIVVQRVMPHYYNWSMEYGKNFLYWFGAKPRLAIAEPDLIKVILMNTNGAFRKLKLNPSASLLFGDGLIELVGEKWAVHRRITSQAFNMERVKDWVPEMVASTMKMLDKWEEERGGRDDYEVDVHKELNKLSADIISRTAFGSNFEEGKRIFELQDQQTDLVLQAVRSIYIPGFKFLPTKKNRMRWRLDKETRHSIRTLIERSYTTQDKTKCLLTLLTSPYKNQENEEERLSSEEVIDECKTFYLAGKETTANHLTWTLLLLALHQEWQRKAREEVFQVCRNGEIPTADNLMDFKIINMILNETLRLYPPPVMLMRETCKNVKLGGFDIPAGTQLLLPMAAIHHDTEIWGADAKEFNPMRFAGSRKQLASFFPFSLGPRICVGQNLSVVEAKIIIAMIVRQYYFEVSPSYVHAPRQLLTMQPQFGAQILLRRISE
->UniRef90_A0A6L5FCG8 Thiamine pyrophosphate-binding protein (Fragment) n=1 Tax=Acidimicrobiia bacterium TaxID=2080302 RepID=A0A6L5FCG8_9ACTN
-MTTVGHQVGLAVASFGARYAFGVVGSGNFHMTNGLIDGGSVFVPARHECGAATMADAYARTSGELGVVTLHQGCGLTNALTGITEAAKSHTPMLILAADTSSGAERSNFNIDQDAIAASVGAVPERVFSGSTHLDDLIRARNIAMGTGATVVVNVPIDIQTEEVPRQPDPTPFAPGPPLSPDDDSVEGFGRLLENAERPVFVAGRGARSEPARDSLLALSEQAGALLATSAAAKGLLVGSPWNLDISGGFATPLAAELIMGADLIVGWGCSLNMWTMRHGRLISQGTKVVQVDTDADALGAHRPIDLGVLGDVSETARAVSGTVSHGETRYRTDEVAQRIAEEGRWRDVPYHDRGDGERIDPRTLTIGLDDILPADRVMGLDSGNFMGYPSMFLDVPDERGFCFTQGFQSIGLGLATTIGAALAQPHRLPVAAVGDGGILMGASELDTVVRLGLPMVV
->UniRef90_A0A2J6L521 XH domain-containing protein n=2 Tax=Lactuca sativa TaxID=4236 RepID=A0A2J6L521_LACSA
-MEEMENTTDDEKTTSLKASILSKYDEVFHAHTSDIKKVNEKITVDCEKFLQYYEDSCSQMEASSKSLQQQEYEITKKELKIQKAKSKQELKKRVRERLLSCKQLLNESCTSKRLLEGVKDELVILRKRRAELESQLKAENYESLESEITQLETALQAIQDDDCIDLQEQMKILQTKLIQKNEQIEEKKHQETIFRLAIETKNKELQEARWELIDGLKTYPIGGVIGTKRMGLVDSNPFFVGCTSSEKKKESATKFASLCKHLIEDPNWHPFTRKSDGSEIINEEDGKMVILKSECSVEQYGAVVTALVERNRYHKNGRNLMEEVWNYRENREVTLIEGIEHILKEWKIQKQRKR
->UniRef90_A0A2A4LJ60 Corrinoid adenosyltransferase n=2 Tax=Alphaproteobacteria TaxID=28211 RepID=A0A2A4LJ60_9PROT
-MVKLNKIYTKTGDKGTTMLTSGDIVPKFDLRIEAYGCVDELNAQLGMACILAKKGSKLADLLQYIQHDLFDLGADLSTPKVEGEAPDAALRIIASQVSALEQNIDEFNANLTALKSFVLPNGTQLAVQLHICRTVTRRAERIVAQLMSEQAEQTNAESLKYLNRLSDLFFVLSRYDNDLSGQGDILWKPAKNR
->UniRef90_U7P8K1 Tryptophan-rich sensory protein n=2 Tax=Halomonas TaxID=2745 RepID=U7P8K1_9GAMM
-MTPTRSALILLGWLALVMLAALTGIATPPGAWYAGLSKPPFTPPNLAFPIAWTLLYLLMALAAWRATLEAPAAMRWHTLWPFVAQLAANALWSPLFFGLHWMGAALAVLLLLWGLILLTLCRFAAVSRPAAWLLVPYLAWVSYAAYLNAATWWLTG
->UniRef90_A0A4S5EQE4 Transposase n=1 Tax=Candidatus Frankia alpina TaxID=2699483 RepID=A0A4S5EQE4_9ACTN
-MPPSRPDARARAEALKPLLRTAHQREQVDQAVAAADGRWNVALDALKRKLPTVADRLAAADALVGWAGDHPSVARARCAEPAADPA
->UniRef90_UPI0004150940 Nif3-like dinuclear metal center hexameric protein n=1 Tax=Peribacillus kribbensis TaxID=356658 RepID=UPI0004150940
-MELLHQMVQKLDQELRIDDYGKDSGFSRFIPAVYEPAGFEWDMFFEKKFTELFNGLMLKGGPEVSKVFLAVFPADEVLEKFIAEAKEGDLLFMHHPLVMECGDPQGKWGQGFIPVKERYLRQIKEKKLSLYTCHTPLDYHQELGTNGAMAKALNGNVIDRCLPNEFGEYLVWICEIPSKSTQMLLSELKEIFEIPYVDFEGPAAGRIEKAAIIAGCGDKVSWMEEALRKGAQAYITGEIHCHINNEYGRRRYSEMMEFATRSPIPLIGVSHAASEFLVMKTLMKDWFEANFKVETVMLRQDQWWV
->UniRef90_UPI000C18D182 helix-turn-helix domain-containing protein n=3 Tax=Lysinibacillus TaxID=400634 RepID=UPI000C18D182
-MAFEYLAQYTTFESIADMDTAVENHMAAHYYDLTESERAIVFKLASHSLENPGACHLKAATIAAALEISTKTVYRSVKRLEELGIIEKVPSTKLNGIKGASIYRILPHVPSSVSQRETAQAISNDAVSETFTENQSSKSFNHLSFKTSTLQEIYNNTHAEKEAHKEYMNEYQVMLFDFMSSLPLADNLKDELHKVVLAAQVQNASDFIKAKNVLFKIAMDIKEGILTVTSTLRAVFTGAYNKAVQRSNMKLSKSSSIEETADRERLVPFYNWLNERDSRSEICSRPNLENWLEW
->UniRef90_UPI0021CC4CFF uncharacterized protein LOC127046616 n=1 Tax=Gopherus flavomarginatus TaxID=286002 RepID=UPI0021CC4CFF
-MLERGHDRDTMQCRIKVKELRNAYCKAREGNRHSGAAPMTCRFYKELDAILGGDPTTNPRTTMDTSERGGEVEAEEKRGEEETESESTGVGGDTLESQEVCSQELFSSQEEGSQSQQPVLGEGQAEERVPATLSSQLPVLTAAQRLQNLWKKPRKSKDDLLQTVMDHSARENKKLQDWRERESRIHQRNAAARKKSTKQLISILARQVDSIHAGRALPRHPPIPKLFPLCPNVSSKPPSPASRFLPPPAASNTCTFTNQP
->UniRef90_UPI00167E4099 hypothetical protein n=1 Tax=Streptomyces echinoruber TaxID=68898 RepID=UPI00167E4099
-MTVHDDLASVQRCLDDLTRSVGRLEKQLGSTSLDLRRVRTDADHLRESVALLRAAAAAGPTAARPELVTIPDTPYDGSLWTDSDDEGLGARDRHAP
->UniRef90_A0A3B0UW67 FAD-binding PCMH-type domain-containing protein n=1 Tax=hydrothermal vent metagenome TaxID=652676 RepID=A0A3B0UW67_9ZZZZ
-MAQFSPVSEAVLAALTAVVTSDNISTAEAERQLHAQDMSQHAPSLSEVVVWPTTAQQVANVLRIANENHIPLTPWGAGSSLEGNPIPLFGGILLSLQRMDQIITLHEDDFQVTVQPGIGYKDLNEFLGRHASFLPQTREPMPPLAACWQTMQQAAAR
->UniRef90_A0A085F9L8 Transcriptional regulator MarR family protein n=4 Tax=Massilia TaxID=149698 RepID=A0A085F9L8_9BURK
-MGERYLKSVRLLAECMQGFERFSGESVRQHGLTHAQFDIIATLGNTPGMSYKELGERTLITKGTLTGVIERLEQKGLVLRERSSDDKRSFFVRLTPAGDGIFRDVFPRVIAHGKQLFSSYGEADFDALENVLRKLRDQIAAGSLPPQPPQAKELP
->UniRef90_UPI001662A726 hypothetical protein n=1 Tax=Pedobacter quisquiliarum TaxID=1834438 RepID=UPI001662A726
-MKLKNLSILAVLGLLAYSNHAEAQLLKKFQKTLEDKASQKVDDVLNGKKKATSPAAESTAAKDAPPPVEEVYSFTPGSTILFESDFKRDSKGSMPKRWKTSSTGSVVSIPDMPGNWLALAPRTTYKIDSLLKAPENFTIEFDLVTRSDEAKDIGSMAFGFARDNSIKNYISDAYNDNGITNTQFHFHNRDINNSSSDTKVYNTLSYPFANYANGLLHVAIAVEGETMRVYVNRSKVLDTRMLRKDLPKYFYLSAPFSYDNQAKVYFGNFVMSKS
->UniRef90_UPI00168950BE sulfotransferase family 2 domain-containing protein n=1 Tax=Leptolyngbya sp. FACHB-16 TaxID=2692800 RepID=UPI00168950BE
-MKIYNPDQPLFSLHIPKTGGSSLEYVLATWFNKRKFPILRNRPKLERILSIGSLDFQIQRTLGCGFYFHYKNHRRNEVPRRVPLGKTYGFLRPTKQPECVHGHFSDYNTGENVFDFYPEASQFIMVLRDPLEMHISLYHYTKRMIEDNSLYWNGQKRDEFQFNSLDQWILERDFFLLKSLPWNLKAENFKGIIDKYFVHVCVLENFQESLNKLADKLGFEPVKIPQVNTTLRCEMSSSEAAIAFREKYSLEYAIYDYAKTLS
->UniRef90_A0A7V7X2U6 Outer membrane protein assembly factor BamA n=1 Tax=bacterium TaxID=1869227 RepID=A0A7V7X2U6_9BACT
-MQKKRSTAKNKIVYISVLKFIHSTTERKFSLMKKLFLHRLPIVLVMALISCLFTVHIAAQTQGLAGRPKIASIKVEGNLKSDAELIIIASGLSVSQEFNADDITKAIENLWEMNVFKDIQVYGEQVEDGIEVVIVVKEYPRLESMDLEGQDNIDEEDIRGKMGLYTSQTVSPQHIKKAIERIKRKYAEEGYLNADVEITTYASQNDSNKVLLKIKITEGAKVKIRGINFFGNYSFADAKLEGTFDDTKSKSGVFRWFKGGDFDEKKYREDVKKLIAYYKKKGYRDFQVVNDSTYYAKNKKDFFIDIHVEEGVKYRIGDVRWTGNTLFSNEELSHAFGFSRGEIFNQEKYDKNMQEQVNAMYYDRGYIFAQIVPIEKPVSKDTLDLEFIVTEGNQVYIEKVEIRNNTKTKEKVIRRDVVAFPGEKFSREALIRSQRNLMVLNYFENVIPDVQPISQDKVNVIMTVTEKPTDTANLSMGYSAQDGLIGSAGVAFNNFLGNGQIVSLNLQLGGAGYRVFSVGFSEPYLFDTRTSFGASFYFSLDGNRRAQYVGYKQRSFGGSISFGRRLKWPDDYFLANWSVGYANSTLKPLSLSNLFPQFTYGQQQSLTLTQVIQRNSKDAAEFPKSGSVYTLTTDFGFVSIDTSGYANAVRVLPQNYTRHTFRAENYYPTLWSFVLYTDFTMGYSRTFKRNPLVEEIPQLDRFYMGGSALDIGSIQLRGYGGRGVGPQESGFAAGGASMVKYSAEIRLPVIPSPTMYILGFAEAGNVFRSLSETDPFKVKRSFGYGFRLFMPLVGVIGLDVAYGLDKTNKNRNFPRFHFQLGQQF
->UniRef90_UPI00217ED0B7 hypothetical protein n=1 Tax=Herbiconiux sp. CPCC 205716 TaxID=2970912 RepID=UPI00217ED0B7
-MADWHPVQTLHANSWIFPRPGTTEPFAEIRHLPVKVGERTVWAFRAVSWRRPRHLIGAGYFGTLEDAARECHRVALASAVPSVLNEQRR
->UniRef90_UPI001E5ED8EC ribonuclease HII n=1 Tax=Bordetella petrii TaxID=94624 RepID=UPI001E5ED8EC
-MGQNSLFAETPDFTGVLMAGVDEAGRGPLAGGVYAAAVILDPDRPVAGLADSKVLIAERREELALLIQERALAWCVASATVPEIDTLNILRATLLAMQRAVDGLAHVPQVAMVDGNQAPKLRCTVQTVIKGDALVPAISAASILAKTARDADLLRLHALYPQYGFDQHKGYGTVLHMDRLREHGPCPEHRRSFAPVRDRLAGLP
->UniRef90_A0A2T2ULY6 SET domain-containing protein-lysine N-methyltransferase (Fragment) n=1 Tax=Proteobacteria bacterium SW_6_67_9 TaxID=1919227 RepID=A0A2T2ULY6_9PROT
-QRVYVGRSPIHGWGLFAREHLERDAHIGTYLGPWAQRNGSHVLWVDTGEGWIGRRGFNRLRYVNHSKRPNAEFDGFDLYARRTIRPDEEITIDYGWDDD
->UniRef90_UPI001B816F5E CvpA family protein n=2 Tax=Neokomagataea TaxID=1223423 RepID=UPI001B816F5E
-MQSFSDLAHGSLDALTRFDDVVLALIILSGLGGFVRGFATEISGLFSWVMAIAVTNRLHMMFEPYLAPYVHDVWLLQIFSGILVFLVTLLFLAMVGRKIAGIARVGLLSGVDRVLGLGYGLFRGYLVIVTLCLIGGAFFETTASYLMQRSLTAPYIVAGETRLVGYLPLSWRSHLASLATSGHDAR
->UniRef90_UPI0013CE7A73 prepilin-type N-terminal cleavage/methylation domain-containing protein n=1 Tax=Metabacillus litoralis TaxID=152268 RepID=UPI0013CE7A73
-MKFKLAKLFTYNKGFTLIEVLLSIVIFSILTLGMLALFSQAMTYTQKSENDTLGVYAARNMLNFMEQQSFEEIKKIYIDHLKSRGEGSITILNKGICEDWYKDMESDGYELCDLAFNPTINNREINVSVELKKHDDQSLQDLLIPIKVFVQWDKDNESTLEGFITNEKLR
->UniRef90_A0A4D6HJA5 DNA-3-methyladenine glycosylase 2 family protein n=1 Tax=Halapricum salinum TaxID=1457250 RepID=A0A4D6HJA5_9EURY
-MTTVTDSPHAALRSDEYLGPLVERHGPVEVEPAEDFFQRFVVSILRQQVSMESAAATRERLFESVEVTPNGILAADKQVLRDAGLSRQKTRYVRNVAEAFIEEGYSRAYFEGMDDDAVRAELTEIPGVGPWTADMQLLFSLGRPDVFPVGDLGIRTRMARLFDDLAVEDRAVMRERSERWKPYRSYASLYLWRATES
->UniRef90_A0A3P1S3R7 FMN-binding protein n=1 Tax=Erysipelotrichaceae bacterium OH741_COT-311 TaxID=2491058 RepID=A0A3P1S3R7_9FIRM
-MKKTVQLMLFLAIVSAIAGGILGYVNSITAPVIEKMAIAAEQKNLELLFPNGEFKALEFKDETGLVKGVYQVEGQGYVFKVETVGYNSSTPIVYMVAFSNEGNIIGFKELQQQETNGIGSRVFTDEYSQGLLKKTNKDNYDTLTGATVTSTAVVKGLNASRDLFNTINGLEKVETVEQEPKEVQAVKVLINQDWSVYDAQVTVEGSTYQVNVKGYGLLEGDSSHFDYVRNEFMIEIEDQKIKSITLVTFGDTPNIGDKAVDQTYLDQFIDKTMDDEVDLVTGATYTSNSVIASVLAALQAAGQ
->UniRef90_A0A5C7IGY6 Galactinol--sucrose galactosyltransferase n=1 Tax=Acer yangbiense TaxID=1000413 RepID=A0A5C7IGY6_9ROSI
-MPSLSESRRRLLQVSSALLKKAWSILQRLGIWRFQEIYARSFANRLTNIKENHKFQKNGKEGHRVEDAALGLRHIVSDIKENRDLKYVFVWHAIPGYWGGVRPGVTEMEHYESEMAYPVSSPGVQNNEDCECLNSLAKNGLGLVNPEKVFTFYNELHSYLASAGIDGVKVDVQNILQTLGAGHGGRVKLTRKYRQALEASIVRNFRNNGIISCMSHNTDGLYSAKQTAFIRASDDFWPRDAASHTIHIASVAYNTSLHPMAEYHGAARAVGGCAIYVSDKPGQHDFYLLKKLVLPDGSILRAKLPGRPTRDCLFSDPARDGKSLLKIWNLNDFTGVMGVFNCQGAGWCKIGKTNLIHDEQPGTISGYVRAKGVDYLSRLATDQWTGDTIVYSHLGGEVVYLPKNATIPITLKSREYEVFTVVPVKEFSNNEAKLAPIGLIKMFNSGGAIKELRYDEAEGTAAADMKVRGCGLFGAYSSARPKMIQVDSEEVQFGYNEESVLQENKVIPGIKVDKGTVELAGTNQYNKTGARFAKWRAVLKIGPKRAI
->UniRef90_A0A2V5VET0 Divalent metal cation transporter (Fragment) n=1 Tax=Verrucomicrobia bacterium TaxID=2026799 RepID=A0A2V5VET0_9BACT
-VLYLQQKGFRYIEALVITLIATIACCFGAELIFSKPNLMSVMLGFVPGPHIVTNQEMLYVSIGIIGATVMPHNLYLHSSIVQTRKFEQSPQGKREAIKYASIDSTGALMFALFINAAILILAASVFHWSGHQEVAAIQDAYQLLSPLLGVGFASALFAIALLASGQNSTLTGRAIAIVPAVLVIGIFGESKTTQLLIASQVVLSMQLGFAVWPLMRFTNEKAKMDEFANLLWLKILSWTTAAIIIVLNVKLLFDTFMPDSVLKAFYNFLRLPAPQ
->UniRef90_A0A6P0P8U6 Tandem-95 repeat protein n=5 Tax=unclassified Okeania TaxID=2634635 RepID=A0A6P0P8U6_9CYAN
-MGTEGDDLAFGSVFSDTYSALGGNDIVFGQEEGDSLLGQEGNDQINGNRGNDTVSGGLGDDSLRGGRDADSVLGDAGNDTVFGDRGSDTVRGGEGRDVIYGGKENDDVAGGEENDFVSGDIGDDTVAGDGGNDTLLGQDGNDIISGGAGLDVIRGGEGTDSISGNEDNDSLSGNQGNDTLDGGTGDDVLSGGKDDDLLLGDAGADTLNGERGNDTLDGGEANDILSGGKGNDSIDGGQGDDLLIGGRGDDTLTGGEGEDSFVIVDFEESDNLYTVTDFNTTDDLLSLEGGLTFEDLEISDEGGNTVIRNADGNTLAILIGVDSGTLNSGNFFPTPETPFPTATPTPTPTPTDSPDPSPTPTDSPDPSPTPTDSPDSTPSPTPTDSPDSTPSPTPTDSPDSTPSPTPTDSPDSTPSPTPTDSPDSTPSPTPTDSPDSTPSPTPTDSPDSTPSPTPTDSPDSTPSPTPTDSPDSTPSPTPPDPGEVTPPSLNDPPTDILLDNDSVEENSEAGTVIGTFTTEDPDESDVHEYRLVDDADGRFALNEDQLVVAEGTNLDFEQQETYDIQVRTFDNAGENLTKSFTIALLNVNDPPEITIPDDQQLVNEGEQLDIVGIEVTDPDAGDGELEVTLETTNDGNLTLNSTSGLTFTTGDGQADAEIVFTGSLENINQSLNTLTYTGNNSGSDSISISVNDQGNTGLGEPQTDTALINLSINDLPLVGTNTELVVNTQETGIIDNTLLETTDDSKTSLIYTVTELPTRGNLLVDGGSFTSFTQEDIDQGLLTYEHDNNDTKNDSFSFSVSDQVGGETTDTFEIRVNVPPNITSKNLSLDEDTQEEITNKNLLAEDPDTDAVAETLIYEVTELPTSGKLQLGKAILEVTDTFTQEDIDQGSLSYQHTGDEPGTDTFSYVVTDQDGGTTSGLLNININPGDTSPIAGDDVFETNEDTAITINKSELLANDSEADGEQITITEFAADNIKNGTLAETTESFIYTPNENFSGQESFTYTITDTQGFTDTATVNINVTPVADTPNLEISTPNVSGTDIEELPLGIAASLVDTSGSENLSITISGVPAGATLSAGTDQGDGSWVLTPEELTNLTISPPGDRETGTTFSFDLTVTATATETANDATATQTGTISVQVEALNDAPVLTDLGNLALTTINENEVNNTGTPVASIIAGAVTDADGGASSGIAITQIDNSNGLWQYSVDDGTNWVDVSNSNTTLLKATTSDRLRFVPNTDFFGDATIQFRGWDTTDGSSNTSELTDISTIGGTNAFSEGVGTANILVNDIPEITKNSELVVNFGGTGSISQNLLQTTDGDNGTNAFTYTVTTEAAAGILQLEDNPTNTFTQENINSGLVIYEHTATNTNDDSFSFRVIDVDGGKVTDTFNIRVNEPPVGTTTDLSAFIGQSKVIPTENLQFIDPDVETATPASLQYTLTEVPTLGELQQGGETLAVGSKFTQENLDNGEISYATTTASIGTDSFNFLVTDQDGGTTSGLLNINIVEANRPPEVEADKTVTLEEDNNATLDIPAPTDPDGDALTITVDSIPNAEIGQVLLSNNTSVTALQQLTTEQLTSLTFVPVANANGAAGTFSYTVDDGNDENSSSTQVINIDVTPVNDLPIAIDDGPVFTNLGNVITIDVLGNDSDIDGPDPLSITTLSNDEPLGILNNLGTQVQYTAVFGTGTDLFQYTITDGLDEATATATVNILDVSNDPDFLVGGEFNDNFDGSGGDDTLEGLAGNDTLAGDDENDSLVGGDGNDSIDGGDDDDIFIGGLGADTLSDDNGNNTFVYTSADDGGAKFNAADAASIGTAISAGLYDRITGFEDLGVVGGDTIAFSSTVIPAVDNIATDVQTTNISGNVLIAGNPGLFAYEVEGKTYLIYDANGDNTVGDDSQILAELEDVSGVVALDINDDFTII
->UniRef90_A0A7K7WYR9 TENX protein (Fragment) n=1 Tax=Mohoua ochrocephala TaxID=874463 RepID=A0A7K7WYR9_9PASS
-HFHTHHHPLSTTAAAQPEELPLTSEEPQHEKHRTESPASEAPLVRAVLGELRVSSVTPNSAQLQWSVPEGSFDSFMLQYRDAQGQPQALPIDGGSHSVTVPRLSPSHRYRFHLYGLRGRKKIDHVSTEAVTGTQEQEELPLPSEEQKHEKLQTEAPPSDAPLMRAVLGELKVSSVTPSSVGLQWSVPEGSFDSFMLQYRDAQGQPQALPIDAGSHSVTVPGLSPSRRYRFHLYGLQGRKKTDRVSIDIITAQPEELPLPTEEPQQEKPETKPRPSEGSPVRAVLEELRVSSVTPNSVQLQWSVPEDSFDSFMLQYRDAQGQPQALPIDGRSHSVTVP
->UniRef90_UPI001131192E phosphatidylinositol 5-phosphate 4-kinase type-2 alpha-like isoform X3 n=1 Tax=Oncorhynchus nerka TaxID=8023 RepID=UPI001131192E
-MAKELPTYKDNDFINDGQKICIDDDNKKMFLEKLRKDVEFLAQLKLMDYSLLVGIHDVERAEQEEVESEDNEGDDEGESDGGIGTPPDSPSNTLDSTKPLSPGEFDPTIDVYAIKSNDGAPRKEVYFMAVI
->UniRef90_A0A101DIC7 DNA repair protein RadC n=1 Tax=Desulfonauticus sp. 38_4375 TaxID=1635258 RepID=A0A101DIC7_9DELT
-MPNKNKPHYLGHRQRLKKKLRENPEALADYEVLELLLGYALPRKDTKPLAKTLLAKFKNFKQLLFAKEKELENIEGVGPGISTFWLALREFLSRASVQEFQKTKQKITSPQDVYNLLAPKLIPLSKEEVWLVMLDNKHQLIKMSRLSQGTLDSSPIYVREILEQVLLNQAKAFILAHNHPSGEPTPSLADLEITRKIEEACKNLEVSFLDHLIISKQGYQSLKEQGF
->UniRef90_UPI001D97EE8E Choline kinase n=1 Tax=Passalora fulva TaxID=5499 RepID=UPI001D97EE8E
-MQSHRSSQVFSVFSVTFNPTARPNSRFGVQPHLYSCSSSTRSREEPLTDIRASCPWNHRRSLSALYHIWLRLPPLGPRSRHQSARNSDGREARDDTSCVSITMPHSEQPSPMSSGLVKPKLEECASPSSYLGLNRAASPRSTPKSVSISHHAETISPLILGQRKEDEESDLSPRRPAVISARSRRLSGRPASYGSPGLKPLTPALDGAVHSDERDAADSQHDGHHHIDALVDQVSMWIKDRRAKRSKRKEKRSARREARGAKASDGDVDEPEKSQRRDSDASDSSVDLENLERIIASNLSLRRSSVRRSSISLKSKASVRRLLRKQSTVSDSEEVDVSVPGCDAFLDNSKTLAYTGGASDLSDNDGDELRQVPSYRDFDAWAKFKFDIVRIIHTLRLKGWRKVALEMSSAIAVKRLSGALTNAVYVVSPPADLSLEKYDESGKVVGVSKAPPKLLLRVYGPQVEHLIDREAELAILQRLARKQIGPRLLGTFVNGRFEEYLHAQPLTPKELRDPATSRQIAKRMRELHEGIELLDQERSDGAFVWRNWDKWFQRVEHIVTRMDNQIKALPEDAKPTGQQAWMRRGYICGVPWAQFREIVEKYRMWLKAQYGGSKEVRDQLVFAHNDTQYGNILRMTPSGESPLLLPANTHKQLVVIDFEYANANTRGLEFANHFTEWCYNYHDERKPYAFNSSWYPTPEEQDRFLRAYVRHRPQDGLSTPQTGPSTPSSEVSTPPVKRATSSISDFMLDARHPQSARPNAAKEEEAAKAAEDLEIGRLANETRIWRLANTAQWVAWGLVQAKVPGMPDFDPDSPTSELTSDTEPEELLGERAEEYRQLAKEQAGEDEEEDEEFDYLGYAQHRALFFWGDAVQMGFVKAEDLPEETRSKLKTVPY
->UniRef90_A0A0E3NZ95 Probable dihydroorotate dehydrogenase B (NAD(+)), electron transfer subunit n=2 Tax=Methanosarcinaceae TaxID=2206 RepID=A0A0E3NZ95_9EURY
-MIPLNATIEKIMEESPFIRTFVFDHRFEEMEPGQFVMVWVRGVDEVPMGLSRKNSITVQNVGEATAKLFELKEGDSFGLRGPLGKGFSSPAAGEKILVIAGGVGAAPLAPYAEAASTAGAKVHTILGARSGGDLLFEERFAAAGVLDITTDDGSKGTKGFVTDVLKKIDVSSYDNIAVCGPEVMMGFIFKILQEKEVLDKSEFSLHRYFKCGIGVCGACCIDRSGLRVCKDGPVFSGVQLVDSELGKYARDASGRRVKI
->UniRef90_A0A8T4KUD5 Pacifastin domain-containing protein n=1 Tax=Candidatus Aenigmarchaeota archaeon TaxID=2093792 RepID=A0A8T4KUD5_9ARCH
-MKGVSLPVNAVIIIALAAVVLLVLSTFFLMGTGPSMSNIEAQRVFEEQCPKIKCEKFVTPGTPAFGGLYKNFFDACQRLYGISGTDSEKSKCFFYCNCGALTSECNTDCTICKNFPVDKERCFAELEKKHGLGCKNSCF
->UniRef90_C0HI41 Uncharacterized protein n=1 Tax=Zea mays TaxID=4577 RepID=C0HI41_MAIZE
-MEGCRGRHQSHPPHAIDGARGKTAHLLPTPNLLPFQLKQHRRLVAVWLLVKAPADKGKMEHTTAAVSSVRWVCRSRCKATARSSWEAMVTANFGLWLANTCCRAPDYGSQGEVMLTFAENGSSKVGVRFDKQIPGAIDLGGSCELDHGLLCSVDSLCLDGPGWEDRAKHSFDVVFEVMEFLFFLEHAGELHIIIFRGKIESKLDQNKHYKLTKLPSGGHKHQCTKGSINLEEKQTNHLNSTKDLQ
->UniRef90_UPI001CDD57D1 hypothetical protein n=1 Tax=Vibrio vulnificus TaxID=672 RepID=UPI001CDD57D1
-MVENLVSGLVSGLIVVLITLVISRVWTLIVVPWFEERVYKDVKIEGKWFSYYTGGMLGRQEVITLKRHGHQITGTMVCTNIGQPDHGEQYNIHGTFKNLILPLVYENDNQSKTDRGTITLKSTFSAKKLVGQISYYSCREDIINTSIVTWYRTQEDMEAAKNSHETRLKEGFNPQGLIPTEDVVHDGVDKAQVG
->UniRef90_A0A267E9L2 NDT80 domain-containing protein n=3 Tax=Macrostomum lignano TaxID=282301 RepID=A0A267E9L2_9PLAT
-MINGGFEDRDNFFLEEEHLTTSLEPHQFDPRLSNAEFIRASVLDGQKIKEELFGICESPFDQQDPSQFDSSVTYAPPATPAFVQPEALYVDQPSRIKRGYDESSSTLEVQTYRRPTSCGGGIDSCLAPPVAKRRLGHNRLQLVQTSVPSSSPSNSSSDAQSPAELGSSGAAAGQPTVAAATQPTSIVISSGPNSMATVGEYDKWSTAAQSFVRRSTIRETDALQCSAANRVGLSTSESRQIYAVDSKTAVDRITTELPPTRPPPAPPPPLSLVPSQQQNGDADVVHPPPPLRFQPWDAAPALTLLEVKPVSQNLQPASISFKIEVDKGFQFSGKEGIWICQKKNHFQITCQVSVTGCQWAVGASSGPQPVTGFRVNLYGVKAESPLDSLVSLEQSEVNRTKRLFAPIPVAMPGGGRFVRVVAQRLHFASTTLNNQRKRGDLHPDQRFFQLVLALEALTETSVAPVQRYISRFIIVRASNPGQFDSASASAVPDNPPAPTPLPQRQPPPQQRSPLPQSSMPPTVEEAATPEDAVGAWISDRPGVVYYSGNVGINTPNPAEALTVEGNLQLRGNLLQPSDARIKSIERELSPAEQLANISRIKIYSYSLSPNDVSDTGVIAQEVAGILPDAVHASSTERVPTGEPLLLVNKDRIYMENVGAVKQLGELTASLDCRIGELERMRSKLCRLRDSLRSSSSSSSTVTAAAAAAAAAAAATASSGCLVGSPRFRSVGTQSSLELEAGLPWPPNLPPPQPPPPPPPPPPPPPPPTLPKSTTPSLTVPASAAAAAAAAGQDQRNRRPRLCSHQHPVAQTLHQQQQQHQQQQRRSSFRFNVVLVALLVTLIVCFLGLASLLLIEKLLPHLSGPGFVGSRNGSSTVSSSGGGSSGGSSGSGPATPPGGGWPRPLHGASSHTTPPEPTPTQKPTPFRPASCGAGGGPCPPVRCCRGQQKLANGNSSGSGGAGSGSGDVIALFESAGDRSGSRGGSSDASSGSGNAAFWELLGAQLISPALGNWSLADAASMHCGSSSGSSSGSGSDVGGHRRRLLRYGGCTGSNLTFHLLLSNSFPLDARLSLRLTMSETLLAVRHCPPVESLSRCDGSGGPGAAADSQSSGCTPVLGDQRGFDCDVSAAASHLLHLAKFRLAAEAKNLCQLESSGLGKEFVELTVLLERQEFGC
->UniRef90_A0A2E8JXE6 Creatininase n=1 Tax=Planctomycetaceae bacterium TaxID=2026779 RepID=A0A2E8JXE6_9PLAN
-MNSEAPWRLDETTLGDLEDRCTEPDDPGFDVAVIPFGCTEPHNLHLPYGTDTIESLAIGDRICGHAWRQGARVALLPAIPYGTTTNQAGVRLTLNLMPTTILAITRDLVASLVRHGVRRIVLLNSHGGNDXKWXLRELHDGPSPSAHLFLVDWXRAXRDVSDRIIEQPDDHAGEMETSILMAVRPDLVRHRSDGSLDADDGEVRSTSFEAVEKGWVSITRPWHLLTTNTGAGNPHAATAEKGETLLEILEERFGSFLVELAKGEPGPSFPFPDE
->UniRef90_A0A8J4EGG7 RGI_lyase domain-containing protein n=1 Tax=Virgisporangium ochraceum TaxID=65505 RepID=A0A8J4EGG7_9ACTN
-MRAWNRRRFAALAVAAVCLVGVPLPASAAPGAPAGGGHGRVQLEKLDRGLVVATTTGGAFLSWRLLGHEVTGRTSSGMKGPGFEVYRDGRRIATVTDSTNYLDPAGTAGSTYQVAPVRGRKSAPARAWSTTHLDLPLRKPADGVTPAGEAYTYSANDLSVGDVDGDGAYEYIVKWDPSNSKDVSQVGYTGNVYIDAYELDGTPLYRIDLGVNVRAGAHYTQFLVYDFDGDGRSELMFKTAPGTKIIRYDRSGAVRSERFVSLPREDVAKGVTHADDYRMSAADYFEHLVTMFQGWHDHPEVEAGRWPATLEQAFGIAPAYTYPLSREDATALANHFVDVYAPARSARNQLRNFAGFIVDGPEYLTVFEGATGRELQTVRYEPGRHDDGLMWGDYAMARIEPGNRVDRFLATVAYLDGRRPSAVFARGYYTRSTLVAYDWDGRRLHKRWYVDSGWTPMTNPFNDSPHGRDGTDPEFRTLTTQGFHSLSSSDVDGDGKQEIVYGAATIDHDGSLLYSSFAPLPEGSASPGTQARLGHGDAMHVTDIDPTRPGLEIYTVHEGAAGAPYGHAMRDAKTGQVLFGTYSGRDTGRGMVGDILPEHAGLEAWATTGMGLWTAQGQKLGDTIPGTNQSIRWAADLSTQIVDGALEVTPTIQDHRRGTLLTAANTLTNNGTKGNPGLVADIFGDWREELLLRTADSSAIRIHLSTEVTTHKLYTLMHDPQYRAEVARQQTTYNQPSYTSFHLGTGTDWARVPVPTASYR
->UniRef90_A0A372F876 ZU5 domain-containing protein n=1 Tax=Emticicia sp. C21 TaxID=2302915 RepID=A0A372F876_9BACT
-MKTLQTVAITLLSLLGLISCETDQQNPKPEQPSKGTPTEVGKPLGAVTAKMIGAQGGNISTPDGKVTLTFPAGALSKETNITIRPVENKAWGNVGIGYEFGPDGSEFAKPVTFTYRYTDKEISGVSLDNMALAFQDQNKIWQATAPLTVNKTQKTITGSIKHFSWWSMITKYRLTPEYDTVLIKQTKELQIEYLESEWPWSNKPDSDILLLVPLVAPKLADRTAISKIYLNGVDCTTTLPKDQSSGLLGFANKDNKAVVMYTAPNKKPNAAYNPVAISIELQHAGKAKLMLVSNLYIDTENTFSIDGSDPTSIAINAAYGAGALYISFEDNMSNVLRVYTEHFAPGTYTFNIKDTNIAAMHHSKKKAGGSVYEHCRDEKSESGRIVIDRIYQSNGKTVIQGSVTGKVCTLHDTDEKCNIIKHETMTVSAKFTTVVMM
->UniRef90_A0A7K4IPH3 DUF420 domain-containing protein n=1 Tax=Candidatus Bathyarchaeota archaeon TaxID=2026714 RepID=A0A7K4IPH3_9ARCH
-MALWIADVNFVLQFVILGVLSVGLFYKQRGKFVFHGSTMLIAVVLNAVSFFLVMWPSFVAFDFTVLDSPLKVVSLTHGILGGIAEILGLFLVVAWGVQKKMQSCIRRKIVMRITILLWLIALVLGILLYAGLYGIITI
->UniRef90_A0A662SB18 TMP_3 domain-containing protein n=1 Tax=Candidatus Korarchaeota archaeon TaxID=2056630 RepID=A0A662SB18_9ARCH
-MLRNAGIDPTTGSLKAIGDAVAALGGGQEKFNRVLIAFAQIAAKGRVQAEELLQLMEAGIPVQKILQEELGLTNEQIAEIGKLGIDAQVVLDALFSGMQRRYGGAMAELMQRFTGIISNLRDQWDLWLRDIMNAGPWQTLTALLKMALDHINRLKEEGKLDEWAEKIGKRVEDTFWNMAIGTATAIDALKEPILAVWGIIEDMWEGFKKLPSWIREIGIVAAIVGGKKGAAVIASLSWLVETLGRSVKGFEYAWKGWISWKDYITANKEELEKLIQEADRAHKTTGELGDISLDTSSKMGNLEQKVRQIRKEVEKYIETLKDEQKQERKPTETPTAKIPVEFVFDEEKLQKLYQDTIDQINKTILQGQELQAYRAEKWYEQMMENIDTLLEAGQITGEEWSRLFDRIEEGYQKLLEKSGESFDYMQEFAIQAARNMQTAMSDFFFDVMTGKFESFKEYIQGLANTISRIISEILAKLALAKIFGAFGWQAGIAALGLAKGGIVPGPVVPIKQFQYGGIVDRPTLFLAGEGRYPEAIVPLPNGRAIPVQIINKTEEKPIVVHIHIQTPDVESFRASRAQIATEITMALARARR
->UniRef90_A0A0F8B2Q3 Putative Ras-related protein Rab7 n=4 Tax=Sordariomycetes TaxID=147550 RepID=A0A0F8B2Q3_CERFI
-MSAGKKGLLKVIILGDSGVGKTSLMNQYVNKKFSASYKATIGADFLTREVLVDDRQVTMQLWDTAGQERFQSLGVAFYRGADCCVLVYDVSNAKSFDALDSWRDEFLIQASPRDPDNFPFVVLGNKIDVEESKRVISNRRAMAFCQAKGGIPYFETSAKEAINIEQAFEVIARNALAQEESEEFSGEFQDPINIHIDNDRDGCAC
->UniRef90_A0A846WZ52 Signal peptide protein n=1 Tax=Tsukamurella spumae TaxID=44753 RepID=A0A846WZ52_9ACTN
-MIARRLSVIGTVALATLAVVPGVAQAAPVNTARTILAAHEFPLGSTGYKVETETLKPFDEPDNANTPCSRFIRTMFERLGGAQVTNAQVTRGTTEVEVAVVNRPMAALMAEGFPTCEAQVDPRARSTVLAAPGDLTRLRPFVFRDADEMQAWVDLRGISVNVTATTKNRGPADAETFWQTLRAQVAKVERQP
->UniRef90_A0A6P6DIM4 protocadherin beta-14 n=1 Tax=Octodon degus TaxID=10160 RepID=A0A6P6DIM4_OCTDE
-MIVFLNTASFGPRETLEMLLSKAPAKRQVTAILFLLLLREVGSETIKYSVLEESDRGSFVANLEKDLGLGLGELAVRGAQVRSKGSKQHLQLEQSGNLLLREKLDREELCGDTDPCLLPFQVLLKNPLQFIQGELQLQDINDNDPEFLENEILLKISESSRPGTPFPLKIAQDLDVGNNTVQNYTISTNSHFHLVTRDHNDGRKYPELVLDKALDHEEQPEMMLTLTALDGGSPPRTGIAQVHIMILDINDNAPEFGQGLYKVQVPENSPIGFHIITVSARDLDAGTHGELSYTFFQSSSQVMQTFEINTNTGEIRLKKLLDYEETKFYHVEVEASDGGGLSGKCTVKLEVMDVNDNAPELITSLLISDIPENSPETVVAIFEISDPDSGDNGKMVCSIQNHLPFNLKSTVENFYTLLTEGALDREKKSEYNITITVTDLGTPRLKTQHTITLQVSDINDNAPTFTQSSYTLFVPENNSPALLIGTISATDRDSGSNAQVTYSLLPPQHPHPHPQPHPQQQPQPDLASLVSINADTGQLFALRALDYEALRAFEFRVGAADRGSPALSSEALVRVRVLDANDNAPFVLYPPHNASAPYAPRHRLLVQVRDNGEPPLSASVTLHVLLVDGFSQPYLPAAEAAPERAQPASLTAHLVVALATVSSLFLLSLLLFVALRLCRRSGPAALGVCSAAPEGPFPAHLVDVSGTGTLSHSYQYEVCLTGGSGTDEFKFLKPFFPNLPPPNAAQQTEGSAMVRNSFGFH
->UniRef90_A0A0H3GRA2 Bifunctional protein PutA n=3 Tax=Enterobacteriaceae TaxID=543 RepID=A0A0H3GRA2_KLEPH
-MGTTTMGVKLDDATRERIKSAASRIDRTPHWLIKQAIFNYLEKLENDETLPELPALLSGAANESDDASEPTEEPYQPFLEFAEQILPQSVSRAAITAAWRRPETDAVPMLLEQARLPQPLGEQAHKLAYQLAEKLRNQKTASGRAGMVQSLLQEFSLSSQEGVALMCLAEALLRIPDKATRDALIRDKISNGNWQSHIGRSPSLFVNAATWGLLFTGKLVSTHNETSLSRSLNRIIGKSGEPLIRKGVDMAMRLMGEQFVTGETIAEALANARKLEEKGFRYSYDMLGEAALTAADAQAYMVSYQQAIHAIGKASNGRGIYEGPGISIKLSALHPRYSRAQYDRVMEELYPRLKSLTLLARQYDIGINIDAEEADRLEISLDLLEKLCFEPELAGWNGIGFVIQAYQKRCPFVIDYLIDLATRSRRRLMIRLVKGAYWDSEIKRAQMEGLEGYPVYTRKVYTDVSYLACAKKLLAVPNLIYPQFATHNAHTLAAIYQLAGQNYYPGQYEFQCLHGMGEPLYEQVVGKVADGKLNRPCRIYAPVGTHETLLAYLVRRLLENGANTSFVNRIADNTLPLDELVADPVSAVEKLAQQEGQAGLPHPKIPLPRDLYGSGRSNSAGLDLANEHRLASLSSSLLNSALHKWQALPMLEQPVAEGEMQPVVNPAEPKDIVGYVREASDAEVQQALTSAINNAPIWFATPPQERAAILERAAVLMESQMPTLMGILVREAGKTFSNAIAEVREAVDFLHYYAGQVRDDFDNETHRPLGPVVCISPWNFPLAIFTGQIAAALAAGNSVLAKPAEQTPLIAAQGVAILLEAGVPPGVIQLLPGRGETVGAALTSDERVRGVMFTGSTEVATLLQRNIASRLDPQGRPTPLIAETGGMNAMIVDSSALTEQVVIDVLAPRRQRRPALLRPARALPAGRGRRSHLNHAARRHERVPDGQSGAPDHRYRSGYRCGSEREYRTPYSGDARQRPHRLPGGA
->UniRef90_A0A0X8F9Q8 Lipoprotein n=4 Tax=Aerococcus TaxID=1375 RepID=A0A0X8F9Q8_9LACT
-MRKKVFLLVAVFALFLTACGSSSKETTHVKLGVVGDKNDQWEYIQKELKDKENIDLELVKFTDYRGPIVALEDGSIDLHAALTEIFMEEVNKEGGYSNTTIAYTTLNPMGVFSEKIDSLDDLRDGAVVALPNDVSNESRALLLLQTAGLIKLDPDKGLLPSISDITENPKNLNFKSMAANQTARSLGDADIALINNDMASDAGFVPTQDSIYLEPVAESSKPYYNVIAARQNEKDKDVYQTIVKYYQTDEVAKIIDEMTNGSSIPVWDKDQ
->UniRef90_UPI001E506DDD EcsC family protein n=1 Tax=Mycobacterium florentinum TaxID=292462 RepID=UPI001E506DDD
-MGTVATAMGVDAAVLTACSAVVAHDALYYGYDPLDPAEEIFMMHVIALGLAETEPAKVAAYQQLTLLTESLARNAAWQQLDRQVAVKVIQKFAVKFAQDLTLKKLVQLVPGLGVGLGAALNWTTVGEIADAAYWAYRERFLYERAPNSSPSQPISRAPRTTIDYRSISKTSSSRKASSSTANANHGDPTAPTHYRDGQANKGRAPVDHIATADAIAAAAHAGQVDKAGMPYIGHVRRVASYVDPANTDAVVAALLHDVIEDTGLTAADLAERGIPQAAIDAIELLTRRDDQPSADYYRRISAHPTAGKSSSRTWPTTPIPNGWQT
->UniRef90_A0A117EBF1 DUF5753 domain-containing protein n=6 Tax=Streptomyces TaxID=1883 RepID=A0A117EBF1_9ACTN
-MTSKLSRIETAKSPTKPNDLEDLLDLYAGLGRDVDDELRAALLALTNEGVRRGWWHSYRGTLTPVYEDLISLEAEAESVSYWQLGAIPGLLQTSEYAREIIRATAMSADVEARVDALVEVRLARQVVLTRETPLTLRAIISEAALRSTSGVDGLMDEQLGRLLTMGKRPNVHIQVLPSDAPLHAGQVGSFVILGFGPHADLDVVHIEGLSSASYIIEEREKVATHRDAWQRLTTTALPPEASTELITEIRKSV
->UniRef90_A0A6J2SVJ9 carboxypeptidase B n=1 Tax=Drosophila hydei TaxID=7224 RepID=A0A6J2SVJ9_DROHY
-SLNSFKIYEVATKSRSAGDGLDFSKLANNDSYYELYYSNDAATHVLVHPDAQPEFIELLNGNTLSYKIVNHDAGLSLHREFETNRKLRNAHPYRGRLGTERYYSHGEINQYIEDLAKQHPTRVLVKTVGRSYEGRWLKTIRITNGDGRANKNVILMDGGFHAREWISPAAVVYAIGELVDNYEAYAQLLLDYDWVILPVVNADGYEYTQVSPDTRMWRKTRQPSSAACIGIDPNRNFDFHWNETGASSDPCSETYAGPKSFSEPEAIVVRDLIRGLADRGKMYLTVHSYGNYILYPWGYIDELPDTWEDLDEVGRAGGDAIKAATGTIYKVGCSTQLLYPAAGASDDYAFNAGFPISFTMELPAGGDNYFNPPPEDIDRLVKETWVGIVAMAQKVVEKYPLN
->UniRef90_A0A4Q6E3N3 Glycosyltransferase n=1 Tax=Sphingobacteriaceae bacterium TaxID=2021370 RepID=A0A4Q6E3N3_9SPHI
-MDVSIIIPYYNAGNYLPDAISSVRQLLRRTDISCEIVICDDGSTDPYSIEILSGLEKEGLFTIARQPNKGPAAARNTAVKNSTGKYLVFLDSDNKLRERLVEKGIEILGSNKADVVYGNAAFFGESTKPLFTQGELNIPLLMARNYIDMCAIVRREVWETTGGFDEGEELRKGQEDWDLWLRAIKAGFRFLYVDEVLFDYRVRAASLTNDDSLERYNKAREYIYSKHPDFFKQSFFWLSDQLYAYQQDKRTPFRSFFKYLYLKYFKGGK
->UniRef90_A0A1W9W8B2 Prenyltransferase n=1 Tax=Anaerolineaceae bacterium 4572_78 TaxID=1972460 RepID=A0A1W9W8B2_9CHLR
-MKNHSRSTKDLSFASNKLSSKIVSKPKSKVRLRTIALPAEHGSWGFVLEPICLGLGVAPSWAGLCLAIGVFALFLLRRPLKIILTDWQNHTTPPPPLKRRGAMRTVIAKRFVMGYGLIAVLGLISGVWLAGWESLYPLLIAVPFSMIFIAYDVKNKSRTWQAEFAGPTAFSLAAASIALAGGWAYNVSFALTGALFARAIPSVLYIRARIRLDKNKPHNKLLAIGMHVVGLIFVAVLTVGAYNHKPLLPTLAEVGLGIFLVLMMIISTRL
->UniRef90_A0A3N5LLQ8 OmpR/PhoB-type domain-containing protein n=1 Tax=Acidobacteria bacterium TaxID=1978231 RepID=A0A3N5LLQ8_9BACT
-MKELPEEKTALTQELDRIVKSEAFRSSESLRRLLLYLGNKSLAGEAGDLKEYVVGVEAFGKSSAYDPQLDASVRIQAGKLRQKLQEFYRTEGMEDTVVVSLPKGHFQLDFELRSKPQERQQLQSVPRKWKIAVWSLAAATLLCCSCIAYLLLSVPSGNQPDGNGRLTADLRAIWDPVLKDDRPLVVAVGTPLFTKIGQGFYRDPAINEWNHSAVPSHLERLRDTLGATTLIPAPIYTGIGEATAAFLLCRLLSSEKDLEVRRSSALSWDDVKENNMIFVGCQKYNLQLRDLLSQQDFFMDGNHITNRRPRKGEPHSFTGTCPPDSAYVTQDFAVVTKLPNVQGRELFALAASSTEGTWAASEFLTNEIHARELVSLLRTPSGEMPDSYQVVIRARFRGQVPFEMAIVAERGASPAKSEATDTQTRR
->UniRef90_R8W248 Undecaprenyl-phosphate glucose phosphotransferase n=3 Tax=Butyricicoccus pullicaecorum TaxID=501571 RepID=R8W248_9CLOT
-MKGFLQLCRSQLLSGISLGLALMVSALFAVYSFGDSAISARWMNLLPCMTVLYMLAGVLLMAWHRRPPRRRPATPYLSGLNARYIWVLPAFLWWLLFRLTGFDVLERCLLFNLILLAVLWTVEYSMARRMAKALNGALGTRTPTVMPASLIVDLDDCPKGIEAFCIEIERYCIKNHIDYQFIERDKPAIVLMNGVKHRVELGVYYGYVPGWFLKFTEL
->UniRef90_UPI0006692FD6 MazG-like family protein n=2 Tax=Pasteurella TaxID=745 RepID=UPI0006692FD6
-MKLTNEQLIDNIKQWARDRGLDTGSTLGKQFVKLMEEFGELCSGLAKQKTDVIADSIGDMIVVMVVMNTIYDNLPLQLKSDSDDKLLIKETMQRLESKYKQDQINTLSEHYFNHYDRRVSFAVGALNALGDETSRIDVFGKDTNIDFMSEAMFSLFRELYNLATAFGLNVNDCLNQAWNEIKDRKGKMIGGAFVKEGDLKDGQ
->UniRef90_A0A387BQQ7 Alkaline phosphatase family protein n=1 Tax=Gryllotalpicola protaetiae TaxID=2419771 RepID=A0A387BQQ7_9MICO
-MATLPNAYSQSVSLAAVLASCFAAVERGAPQLPLAPVDAAVVVLADGLGALPLKARAGHARTIAPRLNRATTIESGFPTTTAAALATLCTGVFPGQHGITAYEAVDPEADRVFNHLSGWKTGPDPATWQRVPTLFETHAATGIRSYLVGQARYADTRLTQAVHRGAEYVPAKSIAERMSAAISLARAGRAVVFVYVPELDMAAHQYGWQSPEWTAALEELDAGMAQLERGLGKAQGALLTADHGMVDIADSGKLFFDREAELIEGVRHVAGDYRCVQLHLEPGATAGDLERLAQVWHEAEDDRAWVATRDEAIAAGWFGPSGVADEVLPRIGELLIAARSQVVYYDTRSTNAGNWSMVGQHGSFSPDEVRVPLIGFGAFA
->UniRef90_A0A4Y2A7J8 RNase H type-1 domain-containing protein n=1 Tax=Araneus ventricosus TaxID=182803 RepID=A0A4Y2A7J8_ARAVE
-MSKKIRILHPPKSEFVSVYRTPSRKSVPIFIMMKFKFLDINSIPRFPPVGSKSFFAASCDFHVFSYHIETEVHQFRIRDECSVFQAELLCIAQAVNWIRTNENLSSNFLICSDSLSSLYALNCITSPNRLIVKTQTNLNFLHGRGVKVFFSFVRGHIGIYGNERADWLAKEATKLIDFIPVTVRKSFYKSVFKKHVISQWNNLHQISHNAKSTKEFFPSIHGRLKAVHFVPNFRVTQFLTGHGNFKAYLKRFNLSRTDLCSCSSGEIQDVNHLILSCPKFTPARCLLVSTLKKNNFAWPPSFSTLFQNKTCFASFCEFIDGIFPHTI
->UniRef90_UPI0018ED6A80 IS30 family transposase n=2 Tax=Dyella sp. ASV21 TaxID=2795114 RepID=UPI0018ED6A80
-SLTWDRGKEMADHRRFTLATDIQVYFCDPQHPWQRGSNENTNGLLRQYFPKGTDVSVYSQAKLDAVARRLNERPRQTLNFETPAERFQQCVAMTG
->UniRef90_UPI0020CC1823 hypothetical protein n=1 Tax=Phocaeicola vulgatus TaxID=821 RepID=UPI0020CC1823
-MTTLSSIADYVTDKISSNDISLNEYVTTDCILQNKKGREIATNLPPQPCSLAHYKRGDVLIANIRPYLKKVWFADIDGGASSDVLVFRAKEGHSPSFLYAVLLQDAFFDYVMQGAKGSKMPRGDKDQILRYKMPTLSCSEESIGTLFMNIDSKIRLNEQINQNLPKLDHSSEGAEARHVA
->UniRef90_UPI0021123217 secretion-regulating guanine nucleotide exchange factor isoform X3 n=3 Tax=Delphinidae TaxID=9726 RepID=UPI0021123217
-MEREPSATAAAPAAAALFAWGANSYGQLGLGHKEDVLLPQQLSDFCNPGCVKRITGGGGHSAVVTDEGSLFVCGLNKDGQLGLGHTEDVLYFTPCKSLLGCPIQQVACGWDFTIILTENGQVLSCGSNSFGQLGIPHGPRRCVVPQAIEPLREKVVSIAAGLRHALAATASGMVFQWGTGLASSGRRLCPGQTLPLFLTAKEPSRVTGLENSQAVCVLAGSDHSASLTDAGELFVWGSNKHGQLTSHAAFLPVPQKIEAHWFQNEKIAAVWNGWTHLVAQTETGKVFTWGRADYGQLGRTLESHEGWKPKKQDPSVRCSRPSKSTPSSLHCLTGATEQRLLPDAGICQWLVSGSPWSSRLVSSAALSPRVSCGSEHNLAVIEDLVLFQSLAFQVVSPQQCYPSTSQHSGFVVLRMGHWSCHHRLSVSGFRFPARPCEGDVHVTCLPSHDSRFRTKALR
->UniRef90_U3A3Q0 Fimbrial protein n=3 Tax=Vibrio TaxID=662 RepID=U3A3Q0_VIBPR
-METMKTFVNNFINDEEGLTLLEYILGAALIVAALLSIGFWDTLASKFTDVASEISGINPTP
->UniRef90_A0A2E3DER3 Phenylalanine--tRNA ligase alpha subunit n=2 Tax=Euryarchaeota archaeon TaxID=2026739 RepID=A0A2E3DER3_9EURY
-MDXVDLSPNELKLLKCLRVGTLTPHEASLKSELGEKETMSAASWLRSKGLVNILEESTTFLFPNEEGKKYAEQGLPERRAVEWLNQMGESLVDELPLDDDEKKVVIGWLKRKKFAELEKTEEGLKLIPTGNIDETPDENLLVILSRKPLAESEIDKEGLALLKGRQVLSSKEEISRTFTLTEEGQNFDVDSIDEGMIGELTPEIIKSGSWKDKTFQKYSTETSIESSDFATLHPLTRFTEEIRSIFLQMGFSEIEGDYVESAFWNMDVLFIPQDHPARDLQDTFYLSEPASFVINDQDLVEQVKAIHEDGGETESAGWGSKWSKEKAQQALLRTHTTVGTIRHLSNNPDPPVRVFSVGRVFRREALDATHLPEFTQVEGIIVEPEANFGMLIGVLKEFYRRMGFHDVRVRPAYFPYTEPSLEVEVRFGDKWLELGGAGIFRPEVTAPFGIEHPVLAWGLGLERLAMLHLGIKDIRMLYQSDLQWLKETV
->UniRef90_A0A842MRA5 LLM class flavin-dependent oxidoreductase n=1 Tax=Candidatus Bathyarchaeota archaeon TaxID=2026714 RepID=A0A842MRA5_9ARCH
-MSLKSFKQLNFVGTPEDLMQSMQPYLDLDVTFFMLYFGDLPYGDSIKIFAETILKELS
->UniRef90_A0A3Q7RJQ3 complex I assembly factor TIMMDC1, mitochondrial n=41 Tax=Carnivora TaxID=33554 RepID=A0A3Q7RJQ3_VULVU
-MAVRPRAPQCFLCGRLGPLPRVFAAGAVAAEAGALAGDQELPEYAESGWDRLRDLFVKDEQQRTSKELENIYKAAVSAGIIGWAYGGIPAFIHAKQRYVEQSQAEVYHNRFDAVQSAHRAATRGFIRYGWRWSWRTTVFVTIFNTVNTGLNVYRNKNALSHFVIAGAVTGGLFRINLGLHGLVAGGIIGALLGAPVGSLLMAFQKFYGETVQERTQKDRKALHELKLEESKARLQFTQLLPEEIESSLQKNQSKDDVKKIEALLNLPRNPSSTNKQDKD
->UniRef90_A0A0F9E616 Deacetylase sirtuin-type domain-containing protein (Fragment) n=1 Tax=marine sediment metagenome TaxID=412755 RepID=A0A0F9E616_9ZZZZ
-MKTIDLFPPCTIENCEDKTPLHKHILDLQQEFLDASERFVAL
->UniRef90_UPI0021BE6A85 DinB family protein n=1 Tax=Deinococcus sp. Marseille-Q6407 TaxID=2969223 RepID=UPI0021BE6A85
-MTQADPRAQASTLAFARLLPKLFRGGQAFLSVEEIISDISPEQAAQQPERLPHSVASLLDHVNWWNRWMLDILESGEAKPYPEHAADTWREVPAGEWNAVKTEFYDLLARIDAHAARPDLSNPVNFEETVGELLADFALHTAHHFGQIISVRQSIGAWPPSGGGDTW
->UniRef90_A0A1S3XUT0 cytochrome b5-like n=2 Tax=Nicotiana TaxID=4085 RepID=A0A1S3XUT0_TOBAC
-MPTLTKLFTMEEASQHNTKGDCWVVIDGKVYDVSSYLDEHPGGDDVVLAATGKDATDEFEDAGHSKDARELMEKFFIGELDSTSPPIPELEIVKKAAKNIPQKVKEITKQYWFIPVAVVGISVVVGFLYTRKK
->UniRef90_A0A8T1TPU1 Secreted protein n=2 Tax=Phytophthora cactorum TaxID=29920 RepID=A0A8T1TPU1_9STRA
-MKVALSFFVVVLLSPMTGSSWLAAGNWCLGYTRVLVAGLELMVKDCSAFMFTIVGALEYGSGIIQNGRQVCIC
->UniRef90_A0A443J140 Ribonuclease n=1 Tax=Siminovitchia fortis TaxID=254758 RepID=A0A443J140_9BACI
-MIIHSIVPHEHIFPANKDDFSNQTECIWNNIPLLVEQDGHKCKVIRIMSSNPSDYLKSEIQPGSHLYINEVHFS
->UniRef90_A0A2T0LCA4 Bh protein n=1 Tax=Planifilum fimeticola TaxID=201975 RepID=A0A2T0LCA4_9BACL
-MEFQELQTELYCIKCEENEMHVLTYLNQRLYKARCEGCGHELFISPDPRKVLYDEFLQRIVTKPERISRELKENPRRIVTLPYRVISKPYRMYKEMQGLRQFIAQGKSRNGSKIS
->UniRef90_UPI00203278C4 MarR family transcriptional regulator n=7 Tax=Curtobacterium TaxID=2034 RepID=UPI00203278C4
-MQFVSRAEEAGRTVRVKDLSKHLGLTGPAITGMVDRLEHSGHISRVPNPDDGRSRYIELTDAARRDYARAMDGTNKHLHDLMASFSERERARFVRIIDRIVAAVDLGAPSP
->UniRef90_A0A6A5UJA8 SET domain-containing protein n=1 Tax=Bimuria novae-zelandiae CBS 107.79 TaxID=1447943 RepID=A0A6A5UJA8_9PLEO
-MGFVSHPESCVNSLPCLFGSGYTVEGQKTSVEAHGGLQIEVIPKYQDHLRRWFQDTDGHVKTLDLNDVDIDWSQNLNEHDTPASIGLRVGQSVRSYAEPALQRKPLNVEGVAGQRDAVTPQAKYWTSNINASFSLSDPLLVPEFSMWNTKAHAATPATATVTTEAWETTLFSGKKKKAKAKNQWSLGSNEGVYLLNLEIHSSCDTLPEQEPAAEEVLEVQTRDPKAMGLAIDGKIVQDIY
->UniRef90_A0A849VSC1 High-affinity branched-chain amino acid ABC transporter permease LivM n=2 Tax=Phyllobacterium TaxID=28100 RepID=A0A849VSC1_9HYPH
-MADVQNTERDSVFAKALKEGIISGAIALGLFCLIVGFRTEQNIRNELILTQRWGLLAIFVLVAAVGRFLVTYTAPMRAERKKLHKVAEAREPSAFRKSFPKIGLGLLFLYPALVVLILSAYQGSMMGGLQASLKYVDNFGIQILIYVMLAWGLNIVVGLAGLLDLGYVAFYAVGAYSYALLSAHFGLSFWLLLPMAGIFAATWGIILGFPVLRLRGDYLAIVTLAFGEIIRLVLINWTAVTKGTFGISGIAKATLFGIPFTPGPTGFAAMFGLPNSGVYYKIFLYYLILCLALLTAWVTIRLRRMPVGRAWEALREDEIACRSLGINTTTTKLTAFATGAMFGGFAGSFFAARQGFVSPESFVFLESAIILAMVVLGGMGSLVGIAIAAAVMIGGTELLRELEFLKLIFGPDFTPELYRMLLFGLAMIVVMVWKPRGFAGSREPSAFLHERKMISGEFTKEGHG
->UniRef90_A0A370FR42 NTE family protein n=4 Tax=Pseudacidovorax TaxID=433923 RepID=A0A370FR42_9BURK
-MSASALPLPGRRPKVNLALQGGGSHGAFTWGVLDALLENGRLALDGISGASAGAVNAVALAHGFAKADDAGDPARTAARQAARETLERVWRRVAGVGAPGALASQFMRMLFGQAPAFPSLTTDPWASPYQFNPLGINPLRTLLDQEIDFDALATLDSPRVYVSATQVRTGRAQIFHGAQLTLSAVMASACLPTMFQAVEIDGEPYWDGGYSANPALLPLIENCDSADIVLVQLNPLHRADTPRTPHEIAQRVDELAFNASLISQMRSIDFMQQLLADGRLQEGRQFRQLRLHRIDIDSALDDPLPSSSKLSTDIAMIEQLFERGRHAAQDWLARHIDDVGRRTTIDIQADYVAGAPLPTEPVAKRAPQLRSA
->UniRef90_A0A024U664 TAZ-type domain-containing protein (Fragment) n=1 Tax=Aphanomyces invadans TaxID=157072 RepID=A0A024U664_9STRA
-MTSTPFSSSTSTAPMTDGGATLSIQLPLPEQVAVLATHHSEIQLSQTEIHADSTTFLSRVQRYADTGKVDVDGLTATDAAALVHILRRLHATFVKQIDCDEIKCDASRKCPKCGASRVPSSPETSPQRNGTGTTPMSPTAASFRLNGSNSPPADVDMT
->UniRef90_UPI0016706687 nitrate reductase subunit beta n=2 Tax=Streptomyces TaxID=1883 RepID=UPI0016706687
-MRVMAQIAMVMNLDKCIGCHTCSVTCKQTWTNRAGVEYVWFNNVETRPGQGYPRRYEDQDRWRGGWELTRRGRLRPRSGGRLRRLASIFANPLLPGIRDYYEPWTYDYRTLTEAPAGDDFPVAAPRSLISGERMDTIPWSANWDDNLGGMPGHGPDDPVLARMSQKVRLEFEQSFMFYLPRICEHCLNPSCVAACPSGALYKREEDGIVLVDQDRCRGWRMCVTGCPYKKVYFNHRTGKAEKCTFCYPRVEAGLPTVCSETCVGRLRNLGVLLYDADRVREAAATPREQDLYEAQLSLFLDPHDPAVAGAAERAGIPLAWLDAARRSPVYDLIATHRVALPLHPEYRTMPMVWYVPPLSPVVESLTATGHDGEDEHNLFGAIASLRIPVAYLAELFSAGNTGPVDTALRRLAAMRAHRRRLNLGERPDASIAGSVGMSTEQLDDMYRLLALAKYEDRYVIPTAAVGDARALEESALGGCSLDFEGGPGMGGGHGSGPFGEASGRPAPATVETFHALRARATDDRPADTAGPGARVNLLNWDGNGRPDGLFPPRTGRDGDDADGDGDGDGDGRRR
->UniRef90_UPI0002DB281B autotransporter domain-containing protein n=1 Tax=Chlamydia abortus TaxID=83555 RepID=UPI0002DB281B
-MLCPPPTPEPEPEPPLEGATSLTKLKEANLGSIPSPMGIMHSSVESSETTDNSVFTFEGNSGLTFSENSSDKCGGAIYAKNLKIVSGGPTVFTNNTAKKTGGAIADGGTLSLTAESGDIIFKGNTSNGGTPNAINIGSKAQITDLRASQGRSIIFYDPISFQPEAGTGGTLTEADGTLKINAPDPLPEKSSLPSMGRLMIRAEGDGQPTSKSYTGTVVFSGKSTTKAKEVTNIFLFPSPVELTAGRLVLSDGALFSATSFTQKDADSCVMLEQNTQLQASNSMDLKNLWVNIKDLNSSTFARVSAMGSSGNVNVSGPIIFTVSDPDFYNNPKLAQQLSREFLKISATRGQVTVSDNSNITNDKEETHLGYQGIWKLTWEDSPTGGSGNEKVANLNWQPLGYIPTMDDTQSYTSLVPNSLWGMVADVTAIQRLIEGEANSATGKDIWGAGLSNFFQGKKTHRNRKFRNFSSGYAVGVSSQSLHNFKFSFGFCQLFGQAKDYGETRIHEKILSGSLYTEYSTELLPILKFLAGTSVFKPKILKQVPEDFLVKFQSQSGYFYGDNSMKVRYSDGTQTHSSWENHCYSGDIGTSITLPIKSKDGLLQKATPFVKVQSVYIYQKGFHEKGLRRRAFSHTYLTNISLPLGIKIHGDSLSKDLHYELSAAYVGDAYRHNPKNITMPIVTHVVTTPWLTTATNLQRHAAQFACSGDYALTSYIHLFAQGSIELRKSARGYHANAGSSIHF
->UniRef90_A0A7C1IRV4 Glycosyltransferase family 2 protein n=1 Tax=Chloroflexi bacterium TaxID=2026724 RepID=A0A7C1IRV4_9CHLR
-MFLSLIFPAHNEEHRLPPSLMAANAFLAKQPFESEIIVVENGSQDLTAVVAEAFAAEHPRVRVIRERGRGKGLAVRRGMLEARGQFRFFADVDLSMPIEEVSKFLPPQLGGFDVAIGSREAPGARRFNEPAYRHVQGRVFSNLVKWFALPGFEDTQCGFKCFTAHAAEDLFRTQTFDGMSFDVEVLFIARQRGYKILEVPIDWYYRSESRVDPLREPLRMLRDIFTIRRNWAAGKYVKREA
->UniRef90_UPI001E5CF05F helix-turn-helix domain-containing protein n=1 Tax=Streptomyces sp. UNOC14_S4 TaxID=2872340 RepID=UPI001E5CF05F
-MADHDETVFFRGGDISALHALVGAEFSPYRLRVTGSCPRAEGSFRRLGRGALSVYELGYGVDADVLPGELPDFYHVHIPLAEHGVLTVDGKEPDSPLSVVGPGQRLVMSWRGDSLNQIVHVPRRTVDRAVAVRLGEPPASVVRFDPSLREENAPVRAWLSVVRAYVEGAEGGLLSASPLAQGHFEQLLVHGLLDTQPHTLGGALRESAAVPPAAVRRAVVFCDEHAHEPISVADIAQAARVSLRALRSGFRAHLGTTPLGHLRRVRLTRAHDDLRAAALGDTAESVTDIALRWGFTHLGRFAQAYRDAYGRTPSQTLRGEG
->UniRef90_UPI001E4F729E glutamate--cysteine ligase n=1 Tax=Blastococcus atacamensis TaxID=2070508 RepID=UPI001E4F729E
-MGVEEELLVVDANGRPVPKGPQALDVASRAGEGEDVNLHDRAEHGEVETPETAHLMPELKAQQLELGTPVCSTLDDVRRELRHWRGRADAAASAVGARVAALATSPVAVEPVPTEGERYARLNEAFGLTAWDVLTCGCHVHVSVADDEEGVAVLNRIRVWLPVLTAMTANSPYWRGRDTAYASFRSQVWHRWPSAGPNGPFADAADYHRLVDEVLATETVLDTGMIYFDARLSAKWPTVEVRTADVALRVEDAVTLSGIVRGLVETAAREARAGGAVPHMRPEVLRLAAWRAGRSGLSGNLVHPPTGRPAPATDVLAELVDSIRPALSDAGDEQAVEQGVRAILERGTGADLQRRVHRETGDPAAVVRAAVEATHEDADRATAEATG
->UniRef90_A0A8J3L304 Aminotransferase n=1 Tax=Catellatospora coxensis TaxID=310354 RepID=A0A8J3L304_9ACTN
-MTVSHGPESGRPARFPVASMSDLVDRPVRYDLAESTSPPLRLDELLDGDVADRLGALEIGYGTSQGDAELRALIAAGAGVSPADVLVTAGGSSGMFLLAFTLCRPEDHAVVVTPCFPPARAALDALGCRVTPVALSFDDGYRLDVDAVAAALTPQTRLVSLASPQNPSGVRFTEQELRALLGRMAVAAPHAVLLVDETYRQSCYGAAPVPRSTAGLSPRVVTCSSVSKAHGAPGIRVGWLTVTDPALYESLRVAKFNTLITGSGVDELLAAEVLRREEQILGVRRTALATALDTLDRWTAGHRDAVEFVRPDGGALCCLRLRADRYDDQAVRRFHEELAKRETRVGLGGWFGEPDRVFRLGFGHLPAPDFRTALERLAEALAVA
->UniRef90_UPI001BED38F5 hypothetical protein n=1 Tax=Arthrobacter sp. ISL-28 TaxID=2819108 RepID=UPI001BED38F5
-MKSKLLFGAGIAAGYVLGSRSGRAAYDKLKARATSIWDSKPVQDKVTAATEVVKEKAPEVGDQLSEAARRAGTVLSSAIHRDASKSADATSGGTSASVGTSVSSGTSASATSTSGTGASGTGASTGAGAGGDTLGSGHVPAHSTHPETVNLGTTSDVESDPARNDAMGQDWSDEGGATDAGAATNVDSKRH
->UniRef90_A0A3B9ZLU8 ABC transporter permease n=1 Tax=Prolixibacteraceae bacterium TaxID=2053594 RepID=A0A3B9ZLU8_9BACT
-MNKSFLILKREYLTRVKKKSFIIMTLLIPLFMAAFTILPAYLASMDDKEERTIAVYDPTSLILGKLEDQGYTKFHYIPEQQYNELRKDFKSGQFYALLYIPENILTTNQAELISDKQITFDIKNMVSGRIGTIIETEKMQQVINETGMPDLEKKLAATKTHIELTTIKLGEEGKAVKSSTEIAMAIGYACGFLIYMFVLLYGTMVMRGVMEEKSSRIVEVIISSVKPFQLLFGKIVGIGLVGLTQIALWIILGIGISTGATFFMGGGSAATAVHAQDIMSGGKAMEQMASSNAAHGNVALDIIQMIGNLNLPLIFFALFFYFIGGFLLYASLFGAVGSAVDSDEDAQQMMFPIMMPLIFSIIMLFPVVKNPEGALAFWVSMIPFTSPVTMMVRIPFGVPVWQIILSMSILVATILGTIWVAGKIYRTGILMYGKKVNLKEIVKWLFYKN
->UniRef90_A0A136MJX9 Homoserine dehydrogenase n=2 Tax=unclassified Candidatus Omnitrophica TaxID=1047005 RepID=A0A136MJX9_9BACT
-MAKEVKTGLVGFGVVGTGLVQCLQNNQHQIDDRAGIPIRLKTIADLDILTPRDADTSGIHLTTDVNDILNDPEIDVVVELIGGTGFAYDLITQALNAGKDVITANKALLALRGQDLFNLAHKKNRLLLFEAAVGGGIPIIQALRTGICSTEVERIYGILNGTANYILTRMEEAHLDFDVALIEAKAKGYAEADPTYDIEGHDTTHKILLLSQLAFGCQIRFDDIYREGITRLTFFDLQMARELGYRVKLLAIAKREGDRLDIRCHPALIPLSSQLAAVNGVYNAMVVAGHPVGTVMFYGPGAGGPATGAAVASDLMEVARQIQRGNQRRNDYSFDYRNLAIKPVGESACPYYIKLNVLDRPGVVAQVTAVLAEQSISIASFIQKERREPHEAVPIVLTTHEASESAMELAVEKIATLDSVVERPFLIRIENLQ
->UniRef90_UPI0017897FD0 DUF1906 domain-containing protein n=2 Tax=unclassified Paenibacillus TaxID=185978 RepID=UPI0017897FD0
-MAKGFDCATPLTDSTAAAFKRDGYVFVARYLVPSSWKALSVKEVQSICNAGLQIVSVFETTADRALGGRSAGLKDGAIALDLAAQMGQPPGSTIYFAVDFDATPAQMSSVIAYIKGASEATPGYNTGVYGSYAVVEAVYAAGACSRFWQTYAWSGGKKSSVANIYQYLNDIVVNGIGIDLNESYGQEGWWSTIPADYMLNPEDANKLIGFMKAGYEAANDAAGKEDFHRLANELRKASGQPEQ
->UniRef90_A0A377GHF6 Sulfate transporter ychM n=2 Tax=Legionellaceae TaxID=444 RepID=A0A377GHF6_9GAMM
-MLAIVESYRAGLLTSKYWIQNLIAGLIVGVVALPLAMAFAIASGVKPEQGLYTAIIAALIVGIFGGSRVQIAGPTGAFVIILANITAQYGIDGLQIATLFAGFILVFMGFLKLGAVIKFIPDPVIVGFTGGIGVIIFVGEWNDFFGLSVHIPLNAPFYLKLLALIRAFPNLDWSTVGLAGLSLFLILITPKFLKRVPGPLIAMVVATVLQTLFHFKSVATIGSTFGGITQTLPQFHLPQIQLEYAFNLIGPAFTIALLGAIESLLSATAADGMSATRHHSNQELIGQGLANILSPLFGGFAATGAIARTATNIRNGGNSPIAAIVHSIFLILVIVLLAPFASNIPLCTLAAILFVVAYNMSDVPHFIYMIKHAPSYDLLVLITTFLLTIFTDLVVAVNVGVILAMLLFVRRMGQFVAIEQQDHETLKNELSDIILPKNTVVYTIQGPFFFGAAEKLERAFMITHSDPKNIIFRLKDVPFMDITGLQTFIEIIEQFHKRHINVYLCEAKSNVKNKLMNIGVMHLIKGERIFPTLKDTIKKLQN
->UniRef90_A0A0N0UYH6 Lipocalin-like domain-containing protein n=1 Tax=bacterium 336/3 TaxID=1664068 RepID=A0A0N0UYH6_9BACT
-MKINLILKFLVLVAIFTFSCKKKSEPTPKDLLTAHIWIGVNLNYNVNTFGFSDAQIVNTDSTAVEFTKDNIVIFYTRDVNTGLLTERNRQTYTLSSDSKKIEISSTDGLLSPEIQASLSVFGITVPTSINIEKITTTELILKGSLQQNINIPQLPIPVPLTANYTWTYRN
->UniRef90_UPI001CF7C5F2 V-set and immunoglobulin domain-containing protein 2 n=1 Tax=Varanus komodoensis TaxID=61221 RepID=UPI001CF7C5F2
-MTGKMKAPAPPHLTLTSATQLPRHPLTGLGACVDVTVPHGQVMQKKGLNVTLPCNYQTSVDKAFMLEWKFSPGSTSPDGGKQILYFTSNTLYKPGAQAKRLHLLQDPPTLGIATIQLTDLRSSDAGIYTCEVNNPPDFYGTSFGQIELIVLMAPSSPVCRGTTSVSVGSNTTLTCNSTEGVPAPIYSWKRLDSKSPLPVSNTVQNEKTGTLELLNVSLALAGIYQCTSSNEFGQKTCQITLQVTAMAQAGVIAGAVIGVLLALLLLVGIAFYVLHRRKQKRNKKAQSIYSANEIREDATAPGISETSLQKKDSKSELHLLESESSRPGSASTTKSQLKHLFI
->UniRef90_A0A6M3IHK1 Putative peptidase n=2 Tax=viral metagenome TaxID=1070528 RepID=A0A6M3IHK1_9ZZZZ
-MKIERRCLPITELRTIRDEGQRPKISGYAAVFNMLSEDLGGFREKIDPGAFKKSLGASDTRMLWNHDSNYVLGRKSAGTLKLKEDEHGLKIENIPPDTQWARDLLVSIERGDVTQMSFGFRIEEDKWEEKEGKETIRTLVSISDLMDVSPVTYPAYPDTEVALRSLDEWRAQNDPEHANAAGDHSEDANAPESVPFQALHRRRGLELKLKNERAE
->UniRef90_A0A7L9FI35 Magnesium-translocating P-type ATPase n=1 Tax=Infirmifilum lucidum TaxID=2776706 RepID=A0A7L9FI35_9CREN
-MSSEGEWVERDARELVPGDIVFLRLGSIVPADAKVIDGNVLVDQ
->UniRef90_A0A538JN64 DUF5666 domain-containing protein n=1 Tax=Actinomycetia bacterium TaxID=1883427 RepID=A0A538JN64_9ACTN
-MGTRTIKAVSAVTALAGVAAITGMVAYERGESHASSATVRYAVHLDGLAVVDGLDHVSRGHELRVAGSYDGRRGTLTITRN
->UniRef90_A0A6L5NWZ8 Methyl-accepting transducer domain-containing protein n=1 Tax=Shewanella sp. XMDDZSB0408 TaxID=2664453 RepID=A0A6L5NWZ8_9GAMM
-MFFKKSKAAKVNQSTTAEVLKGSSNRVADKLALTQYSLILCYLPPSLAAQDVSQLTKQLTQRCGDVITIMSSGTISGTENIYNSPDESNVVIHAFPKSMISDVSVAKISIPAHTTDKEIHRHKNSLKSSLKGVNFNFDVDLKDTFILSYFSGLNAFENQTVESILNSGNENFSTHIIGGSAGGKLDFKSAAVAHNGNFSESQLLLVAVKLHPDFGYAINKTHNFAKNRISFVVAKSDNTTRTVTHVLDDNGNLTSIVSYLCSALSCSKQELSAQLANKQFCVDIEGDVMIRSVAAVDLEKESIAFFCDMAFGETIYMVTQEDFATKSNREFDKFTNDLTAKYCQEIDTIIGIDCVLRRLQNDPKVLKQVRLNNVKSHAAFSSFGEIHGQHQNNTSVLVAIYRKQTQSPHASVKRYFVALTEVARYYLAVELNRERFIGELKTSLIDELNHYEGIVVSSTEDLLRLSELSGLIDGEQQTVSQLINELLAKGESQAQIRQDLEARVTELKNSSKQILNVMSSIDAIAEQTNLLALNAAIEAARAGEAGRGFAVVADEVRSLASKSQQDIGRSREAIDSVELSIANISKSVDILTTTSVQMEQSIESAMEQTKKIAELTSKSSQIATHGLSSAQANQNEHVRIQAQKDKLTSLL
->UniRef90_A0A265NDR7 Hemerythrin domain-containing protein n=1 Tax=Virgibacillus indicus TaxID=2024554 RepID=A0A265NDR7_9BACI
-MAITGPALRHLDSHRSIHQGAYAEARDITDVMNRLFYDNRMEDCLKAANALVEYWETRVIAHADTEDEGFYKELLEKKPELTKEIHMFSRDHDLFRKIVADIKEEISEEEKVTKNMVNQFNALLIIKKHHNKGEEENLFTE
->UniRef90_A0A838GFU4 Carbohydrate ABC transporter substrate-binding protein n=1 Tax=Chloroflexia bacterium TaxID=2448782 RepID=A0A838GFU4_9CHLR
-MATSWARLYNQDLFTQAGIEAAPTSWSELIDAATRLNEAGITPCAGSWNPSWFGRHFLSDFYSTEYEALTGCDGSPGQSPQDEAAAIKAGILSTDDPRFMAWWPFFKGLTDLWSPEYLAQELSVADEGAQEDFQAGQSAMFYSGSWIPRTLQTVGIEFELGSFSFPQLTTEDIEFATNVDVAGVVGGPNAAFQYAMSTPESNTTLEEEGKEAAVIDFLHYIGTPEVIEKVVNELGSFAPTWPGTTPVTGLETFAEQANTGLRVVNIGNSSATILPSWERLFGLYLSGNLELEEAANQFQRELDRGVQGYEEDNPDLDIDSCFAS
->UniRef90_A0A1C0A8Z2 LYZ2 domain-containing protein n=1 Tax=Orenia metallireducens TaxID=1413210 RepID=A0A1C0A8Z2_9FIRM
-MNKPKFKVIFLLVIMIFLAMMGYFWTSLFNSKEVNLKQDDSTGEALVSEEEAEPITEEAQEVQEVEQNSFTNIAYDSYKDWERLLEEYNYNINQELVEIPRVKVEKFPEDIGEISDVAKKKKIFLSIILIGAYHVNQDLIEDRRRLQSIAKQYSISDKIGLEDEEWLNQLKKEYSVKSDDLQESLDLLLVKVDIIPLSLVLAQAACESGWGTSRFTRVANNIFGEWTFSKMVAGVVPKDRPVNATYKIRKFDTIEESIKSYINNLNSHYAYEELWKIRANLREREERLDSLKLAEGLLNYSQRRELYIDELRDIIKYNNLQKLDSLLEE
->UniRef90_A0A382ZW10 Tripartite tricarboxylate transporter TctB family protein (Fragment) n=2 Tax=root TaxID=1 RepID=A0A382ZW10_9ZZZZ
-MPLDRAIAGIFILICLIYGYTAFVPMEEGLLPFELNMTFLPNTLPKYLSVLGIVIGLVIVLQPRYEGASDSDPNEIDQKKLLQYKFSQALFLLGLMLAYALLLRPIGFVTTTTLFLAFGGIILGERRLVIL
->UniRef90_UPI0009B405AA mixed lineage kinase domain-like protein n=1 Tax=Monopterus albus TaxID=43700 RepID=UPI0009B405AA
-MDFIDPILSIASQIYTLVENVQANKKRCRRVSDRVRALEELVKSIEKRKTVETSGNVTKALKELYHTLEAAQKLVKKYTLATWVKRILKSSSHEDEFNIVNERLNNAFQVLSGALQLEQGNVLCKVFALASREEEDKMDGKEDDAELGKLLLEHIKDQEEKTKAMQRTFDELKTSVEMVIEKLNKPSITSEGIRMIKLEELKNRRPFMKTPTSEVFKGQYHGFTVAIKRYTGLVNTSPREVRNIFTKEVETMKRFESPNILRMFGICIQDEDGPSPEFLIIMEYCEKGSLRQVLDSDCKLSWLKKACMCLDAAQGLYRSVIWLLDKFICVRNDRNMGRREEKPRYTGVIKKVKCHFECDIL
->UniRef90_UPI001CA7B725 uncharacterized protein LOC122510909 n=1 Tax=Leptopilina heterotoma TaxID=63436 RepID=UPI001CA7B725
-MPSSCIVDKCISASLIRKGRKLSLFKPRESTLELWRQIVPTKDNKELLKSHVVCELHFNENDMDKTFKTIINGVQHEMQKEKISLKVGAVPSLLLSNVKDKLDYSQIIKEKQIIALPSKNWSVVRTSEFIVWINWINNNPHTDRRIILYPDMKIKVFVYGNEVKEKDMDVKSVGDLIALFEKLEKFFPCGSSGTCRSENCIGFIIQKEKHERGRKFVLCAACSKFTKKINRQKRESDKLMKVKCKIEKLYKNSKNTHQKCKRLLDKV
->UniRef90_A0A257RIT0 Peptide deformylase n=3 Tax=Acetobacteraceae TaxID=433 RepID=A0A257RIT0_9PROT
-MASAADERADLDSAHAQRYTKNPSFANLNASKFSRFRAGPVCETRQLRHLCIMAILKLARMGHPVLLTRADPVADPTAPEIRRLLADMIETLDDAGGVGLAAPQVHVPLRLFIYKVPERRVSTIEGDEPRGLSAVINPQLTLLDGDPIEDWEGCLSIPGMTALIPRAARLILTGTDASGAKFTRQAAGFHARVIQHEADHLDGILYPTRMTDLRMIGFTDEITKFREDILAVHHNPTL
->UniRef90_A0A6A4KJ17 Peptidyl-prolyl cis-trans isomerase (Fragment) n=1 Tax=Rhododendron williamsianum TaxID=262921 RepID=A0A6A4KJ17_9ERIC
-MSSSSDKVRASHILIKHKGSRRKASWKDPDGHVITSTTRESAVAQLKALRDDIVSGKAKFNDSPLVSPIVAPPNAAAISVSLLASAVFSRIRLFRSKIQSPSVRIFYYEAMLSLVLFCKSVPI
->UniRef90_A0A329J1P4 Phage infection protein n=1 Tax=Pseudomonas sp. RIT 412 TaxID=2202161 RepID=A0A329J1P4_9PSED
-MNTQKLILGLAFSVLATGAFALPTVHGTSAVAENGSSHTHIERVAADGADRVGANRVAENGSDRTALGRIAADGADRVGANRVAENGSDRTALGRIAADGADRVGANRLS
->UniRef90_A0A6A3LY11 Reverse transcriptase domain-containing protein n=2 Tax=Phytophthora rubi TaxID=129364 RepID=A0A6A3LY11_9STRA
-MSPSSTRSRARRRRRMRRRASAASSTPDEVSSVLSGEAPHDCGEQLYTLVNGVTGDVDSDIGLDPLPSLNALLELEEMPVADFGEALKAGDLAEVVMIRPEDELNSSSLLDEAVLEDTKQALNARSGSAILKDPSDPLYSLVVEFGDVVSKVPPMGLPPDRGVRHEIDLVPGTKYCVMRQWPLPKEQCDVIDAFFRAKHAAGLVRESKSPHSTPTFCVRKSNGKWRIVHAFNKLNAATIPAQTPIPRKDVLQNNMVGCMLYSALDLVDGYYQLLMRASDIPLTAVSTPSGMLWEWLAMPQGLSNAPATFNRLVTQLFRPHRAYAQTYFDDIFVHSRAEHGKSDMENHIDHLRAVLECMRANKLYANADKCIFGAEEIPFLECFIGKRGLRADPAKVKAIVDWPVPANQKDLRKWLGLANYLHKYSENYAELARPLPTLLKKDAEWCWDTGQQEAFEAIKESLLQAPILALPDPDRPFSVVCDASDFAIGCALLQADGEGHERVIAFESRQLKAAEKNYPVHDKELLAMKYVLVKFRVHLLGSKPFVIYTDHASLRTATQSPHLSQRMARWLSFFAEYNFEVKYKPGRQNVLADALSRRPDYELAHVTSVTSSISEMIREAYARDDVCVALLRALGSEEFQNSDIKLSARLRARLHRYSLEGQMLYYSTGSDDTPRAVVPHDEDLKNRILYEAHDVPASGHLGREKTYSSVSRHYWWPKLYQWVKTYVSTCETCQRVKP
->UniRef90_A0A850EYH4 Ribosomal RNA small subunit methyltransferase D n=2 Tax=Enterobacteriaceae TaxID=543 RepID=A0A850EYH4_9ENTR
-MKRPHSAGGGQIRIIGGQWRSRKLPVPDSPGLRPTTDRVRETLFNWLAPWVTRARCLDCFAGSGALGLEALSRYAASATLLEKDRIVAQQLRKNLETLKAPQGEVVNTDTLSFLAHPGTPFDLVFVDPPFRKGLLNETLHLLEHNGWLADEALIYVESEVENGPPNVPHTWSLHREKVAGQVAWRLYHREVTTGE
->UniRef90_A0A2M7RS75 Methicillin resistance protein n=2 Tax=Candidatus Gottesmanbacteria TaxID=1752720 RepID=A0A2M7RS75_9BACT
-MIVKEITDKKIWEAYITQYSPNSLFQSWNWGEVAKKLDDRTNNTKLWRLGFYLNNKLFGIAQVVKVKAKRGIYIQVRHGPILSEWSKKNILMVTDYLKKIGCKENAYFIRMNPLISSSEDNKQIFKEIGFIDAPIHAMDGELVWVLDLNKKKEEIFSGMRKTTRYLIRKGEKLGVKIFKSQNKEDIDNFLILYKKTATRHHFIPHKGIKEEFVTFLKDKQIILFRGYYNNRLLSAALILFYNKQAIYHHSASIEQKVPVSYVLQWEVIKEVMNRGISIYNFWGIAPEDNLHHPWVGLSMFKKGFGGRKVEYLHTKDFILSPKYYFTYLFEYGRKIIKRY
->UniRef90_A0A3D0LW13 DUF4870 domain-containing protein n=1 Tax=Betaproteobacteria bacterium TaxID=1891241 RepID=A0A3D0LW13_9PROT
-MSPSADDPPFPECPDPPGQTLAVIAEVLYLMNLLLLPGFAFLILLGLYFKEGGAPQLARCHLRQTVAASLWAVALLGAANGLILLLGGYAMPATWVVVILYFTVCHSTLVLLGVLGLAKAMAGRTFIYPVVGRRCDG
->UniRef90_A0A5C9DQB6 CopG family transcriptional regulator n=1 Tax=Spirochaetes bacterium TaxID=2202144 RepID=A0A5C9DQB6_9SPIR
-MKNITLSMDEKVLRAGREYARRHNISFNVLVRRLVEQAVLSTKDSWLDDTFSLMDTLHASTENVMWTREELYRV
->UniRef90_A0A438CFM9 Beta-xylosidase/alpha-L-arabinofuranosidase 2 n=1 Tax=Vitis vinifera TaxID=29760 RepID=A0A438CFM9_VITVI
-MSGGGFDISFAKNDDKIASILWVGYPGEAGGAAIADVIFGFYNPSGRLPMTWYPQSYIDKVPMTNMNMRPDPASGYPGRTYRFTLGKPFTHLEMD
->UniRef90_G1PVF8 Synaptotagmin like 5 n=10 Tax=Vespertilionidae TaxID=9431 RepID=G1PVF8_MYOLU
-MSKNSEFINLSFLLDHEKEMILGVLKRDEYLKKVEEKRIRKLKNELLEAKHRSGKIQQETSRVCVYCQRNLGLIFDRGNPCQACSLRVCSECRVSDLDGSWKCTVCAKVAQLRIITGEWFFEEKAKRFKQVNVLGTDVVRQSILRRNPGGAKEIQSQEKNHQDAEKSNTSPSTGQKASHDESKEKGFLLSKFRSAARGEIIITPNTESGWSYSMDLDSRNFRHLKSAPSSDRRNTGSSDLNDKEVGPGTLKSSQSSGMTPVTHRSPAPSPCNITPVISREHGFENSLDLAAIEGTSEDFTKNHCTNTSGTPSIAVSRASLSSDQSQSELDLSGSFKEDLKDTVNLRSKYVPGALDKDLDSSEETEESIDDVVSSRFSANTHSLASGLSRNSQAGSDKKWTYLNVPDIDSDTASLNSMLSVYSETGDYGNVKVSGEILLHISYCYKTGGLHIFVKNCKNLAIGDEKKQRTDAYVKSYLLPDKSRNNKRKTKIRTGINPEFNETLKYTISHTQLETRTLQLSVWHYDRFGHNSFLGEVEIPFDSWNFENPSDEWFVLQPKMELSTDIGLQYKGELTVVLRYIPPDEYLMFPPGQLQAHTGKKTFKRGTKKPPVLSGGILEVLIKEAKNLTVVKSGGTSDSFVKGYLLPDDKKVTKHKTLVIKRSVNPQWNHTFMFCGLHPQDIKNVCLELTIWDKEAFSSNIFLGGVRLNSGSGVSHGKTVDWMDSQGEEQHLWQKMADNPGTPVEGILMLRSSMGKRQL
->UniRef90_A0A1G4YLJ9 Acetyltransferase n=2 Tax=unclassified Nitrosospira TaxID=2609267 RepID=A0A1G4YLJ9_9PROT
-MNYDVFNGDADGLCALHQLRLAYPVKAELVTGVKRDIKLLDRVQAGAGDWVTVFDISLDSNRSRLMQLLEAAVHVEYFDHHYAGEIPRHINLVSHIDVSADVCTSILVDRSLEGRFRLWAVVAAFGDNLGQSTRSLVGSMGLAESQIEQLAGLGKYLNYNGYGDSVDDLHFHPAKLYEEMKPYPDPFDFIARSTAFNLLAAGFRDDMAMAGSLLPLSEEPCHAAYLLPDAPWARRVVGVFANRLATDHPSRAHAVITPTRHGDYAVSVRAPIAKPEGADMLCMKFETGGGRKAAAGINRLPMDELDRFLAIFAEQFD
->UniRef90_A0A104MTA2 DUF2384 domain-containing protein n=17 Tax=Burkholderia TaxID=32008 RepID=A0A104MTA2_BURPY
-MTRHAHAIKGTVAILDVETEAALRSAVGAATMLGPDRARALLRLSDEQLGHLFKIGIAQAIDLAATVTFGIAAAATRDKKKSADPARHVKPAARTDGVPADFERGALSERQTLVAEGRLLPAIEVRVGLGITRQALSKAVAAGRIFTLDVGAGQYYPAFYLAGDIDRKTLGKVAQRLGSLPGWSKWQFFTAPKASLGNITPLEALSRGKVEQVERAAAAFAER
->UniRef90_UPI0021C2958F uncharacterized protein LOC126978868 n=1 Tax=Leptidea sinapis TaxID=189913 RepID=UPI0021C2958F
-MSFLLIYPAVAALTLFIIVVIMVMLRFGATCCKLRHTAFANQEDWLEEEAYEQKVSYA
->UniRef90_M0NT14 DUF3194 domain-containing protein n=1 Tax=Halorubrum kocurii JCM 14978 TaxID=1230456 RepID=M0NT14_9EURY
-MPSESTDEPTDEEVVRTAAEAAEGVVFAHYDQSAVTDLDVTVTFEEGVLDVDVYLNAPDDPDPDVVAREAAETAGEAVDELFAA
->UniRef90_A0A8C6TNC3 THAP-type domain-containing protein n=1 Tax=Neogobius melanostomus TaxID=47308 RepID=A0A8C6TNC3_9GOBI
-MPSACYAMGCTNALSQKKGLAFYKFPKDPVRRQKWITRDEPTHANVRKRQSFVYYLPFL
->UniRef90_UPI000522A661 ubiquitin carboxyl-terminal hydrolase 15-like n=3 Tax=Amniota TaxID=32524 RepID=UPI000522A661
-YLVDSRWFKQWKKYVGFDSWDKYQMGDQNVYPGPIDNSGLLKDGDSQSLKEHLIDELDYILLPTEGWNRLVSWYTLMEGQEPIARKVVEQGMFVKHCKVEVYLTELKLCENGNMNNVVTRRFSKADTIDTIEKEIRKIFNIPGEKETRLWNKYMSNTFEPLNKPDSTIQDAGLYQGQVLVIEQKNEDGTWPRGPSTPKSPGASNFSTLPKISPSLSNNYNNMNNRNVKNSNYCLPSYTAYKNYDYSETGRHNEQPGLCGLSNLGNTCFMNSAIQ
->UniRef90_UPI000401F0EE valine--tRNA ligase n=1 Tax=Desulfuromonas sp. TF TaxID=1232410 RepID=UPI000401F0EE
-MEPKLPKGYEPREVEEKWYAVWEQAGFFRADENSPKPHYSIVIPPPNVTGVLHMGHALNNTLQDILCRWKRMTGHEVLWMPGTDHAGIATQNVVEKQLAGEGKDRHELGREKFIERVWQWREESGGQIINQLKRLGASCDWERERFTMDEGLSRAVREVFVRLFEEGLIYRDNRLINWCPRCHTALSDLEVEHEEKKGHLWHLRYPVQGTDRFLVVATTRPETMLGDTAVAVNPGDERYADLIGRKVLLPLVDREIPIIADEYVDREFGSGAVKITPAHDFNDFEIGKRHDLEFINILDESGNINENGGPYDGLERYEARRKVVADLEAQGLIEKIDDYANAVGECYRCRTVIEPYMSKQWYVDVKPLAKEAIAAVEEGRTKIVPQQWEKTYYEWMYNIQDWCISRQIWWGHRIPAWFCDACGEITVSRQDPTECAQCGSADIRQETDVLDTWFSSALWPFSTMGWPDQTETLAKFYPTSCLVTGFDILFFWVARMMMMGIKFMGEVPFTEVYIHALVRDAQGQKMSKSKGNVIDPLTVIEEYGTDAFRFTLAAFAAMGRDIKLSTERIAGYRNFANKLWNASRFALMNLEDFNPEKVDLDKLELTLADRWILSRLSETAKEVDTALTGYKFNDAANALYSFTWHSFCDWYIELIKDELYGDDPQAKACAQAVLFTVLEQLLRLLHPFMPFITEEIWQALPGRRPEKSIMHAACPNGEDLPVDAEGAEKMERIMDVVKAIRNIRGEMDVAPSRQIAAVLDCKSESSAAVMREGEGYVKALARVNDLICGVEVERPAQAATQVAGEVEILLPLAGLIDVGEEEKRLEKEIAKVEKDVAMFSKKLSNEKFVSNAPPEVLEKDRGKLAAAEEKLGILQESLKKIQALK
->UniRef90_A0A4S4L702 BAG domain-containing protein n=1 Tax=Phellinidium pouzarii TaxID=167371 RepID=A0A4S4L702_9AGAM
-MAYFCTPSSYASTFYDSPFSRRRPSPPPTTYYSRSNAYDPYVRAIAEEQVARSALQDAIQREQEARRRRTQEEARARARAQETARARSRAARQHAGMFYGLPARYQYADYPECGYGYGYEYGDEGDEDDEIKDTYSPFIHFYSTPEFVSKQGSAPPMSRSSSLRPSQQELRAKETEGQSSSKESTPKVSIPINTPSSQTSQHSDQVRNEAVLKIQTIYRKHVARKAALTEIESIRQRFETQCNAFSFPSVLDFQDDPASPEASAAPEERPRLAYTAHNTPVHVHEDALVKMLQALDSVESHGDATVRDVRRTLVRAVEEELGRVDAAVRRVWEELVVQAKAESHKTTEEPMEVLLDLASESDTTVEAVVDQPALAADQALPTMDVESASIAESIVQPVAEKTESGMEEPEARTFPPAEKTNIESTTSTAAESPFDEIAIDDVPIPSTIDNALGQMAHPISTLAPPPPAADVVFEPIPISEPPLNADSETDSEVETPSQPAVAFPAAQVVSAEDRQDDREEEDDTVLVEETLKTPDGYEKNSETAVVDTEFVLV
->UniRef90_A0A401PBY0 Tripartite motif containing 62 n=7 Tax=Chondrichthyes TaxID=7777 RepID=A0A401PBY0_SCYTO
-MACSLKDELLCSICLSIYQDPVSFGCEHYFCRKCIAEHWSRQDQSSRDCPECRRSFRDPLLSPSLKLSNIVERYSAFPLDAILQAQRNSFPCKDHDKVKLFCLNDKCLVCFFCDEPALHEQHHVTNIEESFEEIQRELKDQYEVLQDSEHGHVKALQLLKRQLSETKSSAKSLRATIAEAFERLHRFLKEKQKSMLEELETDTARTLNDIEQKIQRYSHQLREVQEGMQILQEKLVEADKLLFLEGINITLERLKGKIHETNLTYEDFPTSKYMGPLQYTIWKSLFQDIQPVPAALTLDPITAHQRLILSDDCTIVAYGNLHPQPLQDSPKRFDVEVSVLGSDSFDGGVHYWEVMVSEKTQWMIGVALESVNRKGSIQIQPSRGFYCIVMHDGNQYSACTEPWTRLNVKSKLEKVGVYFDYNKSLLTFYNADDMSWLYTFREKFTGKFFPYFSPGQSHANGKNVQPLRINTVRI
->UniRef90_D5ASH9 Membrane protein, putative n=3 Tax=Rhodobacter TaxID=1060 RepID=D5ASH9_RHOCB
-METLPILVPPVLNLVSAIAVGALIGTERERRKGEGPARSPAGLRTFAIASTAGAVGFSLGGAVLLAVVAASVAGLLAVSYGKRPHQDPGLTTEIVLLLTVLLGGLCIPAPQMAAAIAVTVTVLLHLKAWLHTLVTTLISKDELDDALIFAAATLVILPLVPDRPMGSWLALNPHSLGIVIVLVMAIGAAGYLAVRLFGARFGLPLSGALSGFVSSTATIGAMGARALQSPEMRAACVAGAVLSTVATVLQMALVLAAVSLPTLRQMILPLVFAGVTAVVYGVVLTLAAMRHPAPEAPGPGSAFSLKTALIFGTVLALVLVLAAGLQAHFGGSGVLLAATAAGLVDTHASAISVATLVAAGKVAPEAAAVPILAGLSANTATKILVAAISGGRGFALRVVPGLVLVILAAWAGSLFW
->UniRef90_A0A7S3BTX3 Protein kinase domain-containing protein (Fragment) n=1 Tax=Prasinoderma singulare TaxID=676789 RepID=A0A7S3BTX3_9VIRI
-GAAPSASPPRALPAAGGLGPRRSQQSTVPMARTALRAPTARSTARAAARSSRGSRGNHRRAVAAALVGPEAAGALDALALAQQAAEHGVHHAALPSLAEGIGPQCALYDCGDMTYRSTLDLELRKELGGLTLQGKAIIGGVGLYLLATPGVLWGFIDTYIVRLLQRALSPAYRLRDFELGQRLGKGAFGEVFRATCLREGASEDQVVLKRADDYGAEEVWMNGRVSRLPVSTNFARYLGAFRETGRDGSEQTWLAWRYEGDFTLSTYMRRKDFPECLEVSLLGESLEGESKARRRSAVVRELMRQLFEALDAALG
->UniRef90_A0A812J0M9 Mfhas1 protein n=5 Tax=Symbiodinium TaxID=2949 RepID=A0A812J0M9_9DINO
-MQKLAKHQNALGQYSSLGTEVFFTEFGADWTSYRSARNRRRVDFSGPQWSLETLEGEQENGLMHKQFIREHIEVLNLAKNKLTDIGCLNAMKDTRAFEFRRLQILNASRNMLTFVKLVNPSLTEINLSHNELIKLPDFSSLTQLSKLLLSHNYIDDMLDQFGQLQKLRVLDLSSNRFFWRPTLFKKQLGHLERIHLEELRFWPNPFAEGFKEYQFITASTLTSLTSLDGFQIDSDLRFQLRVQADQLQLNIADFSIFDVRVEDRGKVGEAEEKCSCRGTSRHHARALLGPHSKHFIPAFLGGREQEVAGVVGILETLKLGDRNVPPQQSGGKVPLLTELIEAMRKSLDQPNDLLKHVYDLEQKVVASDFASGTCHMRHCMQLSVLCLALKLQVLQHPSCNRTSSQVSCMWNAHFWDRRRLMLAEDGERKQRSYMKPAEADRAAAEFADKMQQVLGRFESVQDVLVMCLVRMLGCGNRQLSERCGTLLAEWVDANAEELHDRMDSMSEALFNDLRHALVVGIKSVNEKPMACYEASHGAREPEDDSELEQTEASWHILAALRRFGPSRLYDKVVSPWRARVLRPFLPALCRETKEVLGPDQPPDRWSKYQGFDSFSEDVAEVLEVQEKNLVSCEEKCVRQGFGGFVVEATDELGMVKVCFKQQSPQTLASLRRSSAKRTLHVRPLGRPPKRPNKAAEEGGGRNHAWEAWVDGLAVLVTATSDSQNAAYCVSYFDAHLAVTKHESDKQGFTEAALLGSSEANNAFVRLLQLARNLMQAYGDAGLKAARHFLEAKLHTNCWARARRRLQEGGSPLPVSRLSEMNPDDVALISELVGILHTMVKCGDLEISNQAMNDILAENGMDVFEMLLEVAASSADPDPLFLAISYESVYVFVQSDIMRPRVLSKVISRLRETAILLPYIRGPYIKDVPNEKYMQLWCKCELKYGMKNDARERLEKRYTSLDPDEHSQWRELVPEIRELQNTMMHRTLLGIVKIIQLFSDLARRDDSPPSLKMVTDNVCGGFVKSKKALGEIPGDLLNANDRERLLIGPTTGLVTCPDFDVRVESLICIRHVLEATPDQFDLEEMGWLLNYLTSVGMGIGKQGQFLTEVIDLIKMFVRNNSRTGQSFRNKFAKYAIRECFEMLTVNSRRETHGNKEEAKAKADLTAKIIELLKDCSRPLSGGLRKFLRRVDLLQSIREVLQQEERTSSNPATQILDIWTGRDIRQVLLPIVTSPAFDVHGPVVHAALMRLADVLQAYSWTDVPPTDEAGPWPGLTMLYRLLDYRDAIENEDSGYQQEYFMNSRGLDPLLDFAHRFFAANEDLNILLNRVQDKLAQELGEKERSLRAKWEGRQQDVHQSEASVKTKQEEQTMSEVVQDCLTARLRSLNEGAAAHFRCNLNQYDQKKQEFSLSKLAKVYQNYWKDNENRANQEVQERGDAVYELLRIPDKIAIDGQLRDVQDLGRVPRKQRRIRQPHRDFEKLMYQALSAHKIMKQMLCDSSKRDHNEVARWCQYEPDANGPPSVLAIGLLDFLQDNQALAIDAGLRPREELLVQDKYKYFRRHDRRTNLSCIVLEFPDARCLLAALQEFLKRAQRLFLYQVRNRFRLASDLGEYCIALKFQLQLKDSSIHYSELRMCLSGKSKKNNTVQQYRDTMRKVEEILQSSCDVPTSETTLVAQYLSTMLRSRSIHHSDIIFLRCKDVNLEVDGEEVFAQSAELTSCQLFVIEREAGDGVVKTGDRIRLKSKFTQKYLDVHASGHLRCRLADFSEDYDMTFTVEAIGCRDDYALSRCGMKGSLTEFRSLHTETSLRLKVSASNFVTVRQGANFLTSFGEKLSVKSEPNDAAHEAGQVFTIFRDGALLLDFHSTHSGSRAAIRTLALETSDEILQKTMMEAHMRTEISNGDVDVQGSSFRTVPPEFKTMMWSIAGHFRHVGHSKHAASHEASSLHKLWTRASKNLAAILRCLFVMMEFPQCVGGRRYVLDTFATRMTQHSSLPRIIALVSAVQLVRKEKMPDGELDLTCALLPKKFMRFCSALLSNLWVCQKPDEIEAIFTVPREQERHERELATIDRERMHLLSMVGSYTCDMVVKPMLDKLRVAGQRPLSRDEVLVFQDFASLCMALVQSIFDNEMRCLSLSNQASHHHHHHGTTAISDKERAGPQSGQSPSHKDAVAIPQNVDDGEQGDALNTNVLLASNADKRRANTLSQASWTYVTHFRAGISSATLAVMTRQDARAAVVAEIIPPITIKALVHLFLYALHQEAIAFRSATRDTEIPVRVISGIINQCVTALAALMTLTGKSNAEVGPTEDAPDASGSCDYDVCEAISQAMTEGAQLVPRARVAQLQAERGADCLRAHVQKMMEEGSFEFSSHRGPKLNLSTERVSTVGFVWTRLAGDIQACASPCFYDKQLFLNDRPRIVMHQDTRCLLVTTTRFRMILLRVPARASVMPQPADLHVLSEPRNMQDLKRVIFDLRTLNSVLESVKDRQVSKCPQSFVRMRQILCLVWDGEEGLKFQRLVFESSGRRRSFQEVLRKVPRKQQDTGEEDGKKETASIRMRARGILESAVKSTSLESLRETCQVRRGGIPLVSVTFVQSTGGLGLNAQLDMLVLTRCSVTVVSFNSFWSKFWRSDDESHYEREVTQASLDTDSEDDRLPDFSESVVATSNDHADKCEALHGPWDLEDLQGVWFLSEASPKVRLQFGSTLEVTFLSDGERQRFRRHLATILAEGAVPRAGKASQAWAVVPTDKTDIKTIQKETGAVQNGRLALTRGEGDDVARDVLPSVCFRSRCALWSGSPHKASSGKFAEHATFGGEADALNKRVACTGDDSEEDEWVVLLEVVEGLRSARAAFSDAEYQVLYSQVHSAWDPGRRFCNPLQRGAVRFCLEEHHVHAEELLASSRILSVAASTLTTLLLQAPSESLFWSSDEANASRDAERLVEGAVRSTFRNISSSMQHHLHLAQELDSFSLTEGQLKAFVSILEHLVDPRVQDLGLAVAKALDQYFQGGVTGEQDVKLLLLQATQPRIVEIRELWHEVKLGALHGPGLGWGVAVNPANLFVLQSFGQPVTYQPRQQEHSQAFWVAAATFEQARVLLLHLEALLRTFGMTINAHGLLQSLSGSSEPFLSQLLACHSDDAEAAEMGTEHDLSRYRRMACSIKYGSAGIDVIASIGGSHPGLAPAQS
->UniRef90_A0A6A6N897 Receptor-like protein EIX2 n=1 Tax=Hevea brasiliensis TaxID=3981 RepID=A0A6A6N897_HEVBR
-MAWNQLRQWSGIACHNTTGAVLAVDLPNSSGRQPLGGEIRASLAKLKSLKHLDLSGNNFTGKIPHFLSSLENLQYLNLSYAGFSGAIPPNLGNLSSLQFLDVSYWGLTVDNLEWVSGLLSLKYLAMNSVDLSKLGGEWIEPLNKLPLLSELHLEYCGLSGFSYSLPSLNFTSLKVLNLQGSLFKAKLPTWLANISSLVSVDIGNSWLTGRIPLGFGELPNLQSLKLNYNLKLSASCFQLFARSWKKIQILDLSINGLHGVISEAHFHRLGKLEKISLSENSFVLNVSSIWVPPFQVIALEMGSCHLDPLTVKCSNDSNNGGDNYPDGGGKADQTDNGNGFIDKWFYMSIGVGFAAGLLLPYLVFAMKRSWGGVYFAFVDGTAYRLSSEKMKAAARRRNRGAR
->UniRef90_S7SN88 Polysaccharide biosynthesis protein n=4 Tax=Geobacillus TaxID=129337 RepID=S7SN88_9BACI
-MRTVASMVAPVSNALYPVSAKLFKKSNDVAIKYLKKFLFIGSLVFMLAGVGMVVFSNVIVLVMTGEENIEIQYLLLIMAFIPLSIYINNIYGTQIMLNLYLEKVFKYLIITNDISLPVLSYILTLNFNLWGASFSLLITEILLTVSMVVYVEFIKKQGFLGVLKK
->UniRef90_E6QXG0 Secreted protein n=1 Tax=mine drainage metagenome TaxID=410659 RepID=E6QXG0_9ZZZZ
-MWRQVYKWLLIYLLRWMGYWFDEMGSCGSFGTVFRVANDCNGVVCWFGIARGAIVHLVALSFDYGLESFRYLAGALAVWYSLSSVGSGKFTCCTEYCDGQAPIGLGNHCVACVVAADGDGD
->UniRef90_A0A3N7FFK6 NADH-ubiquinone reductase complex 1 MLRQ subunit n=2 Tax=Populus TaxID=3689 RepID=A0A3N7FFK6_POPTR
-MASSRWIRPEVFPLFASVGVAVGICAMQLVRNICTNPEVRVTKENRAAGVLDNFKEGEKYAEHGLRKFVRNKTPQIMPSINGFFSDPDLPTN
->UniRef90_B8A485 PHD finger protein 3 (Fragment) n=1 Tax=Danio rerio TaxID=7955 RepID=B8A485_DANRE
-MASRHHADHEMTGAGVRQSPSDGEHNQSGFLQDRRQAGQMQRRQTASRGRVRGRRLGPARKAAESYNRESTCSEEHDRDNSPDEKREALLSRRF
->UniRef90_UPI001F4BB424 secondary thiamine-phosphate synthase enzyme YjbQ n=2 Tax=Belliella TaxID=232244 RepID=UPI001F4BB424
-MKLFQKEIKLRSYPRGYHLITDVIQSQFPEIKLVHQGVLQIFIKHTSAGLTINENADPTVRKDFETFVNELVPESYPRFIHTYEGSDDMPAHLKSSFLGNSLQIPITGGKLNLGTWQGIYLCEFRDFGGARSLVLTAFGV
->UniRef90_UPI000F8ECADA GntR family transcriptional regulator n=1 Tax=Pararhodobacter zhoushanensis TaxID=2479545 RepID=UPI000F8ECADA
-MNADAPSGPEALVRDVLQGLAEGRFVPGQRLAEPDLMARYGLGRSTVREGLGRLAASGIVVQAPHRGAQIRLLGRRAAQDVLRVTDLLLGLAARQAAEAVAAGADPAPLIAAARDYDAAVPGERARIRARYYRALTTLAGNAELDRLLPLLQVHLIRAQLRLNRPPGRPARTALVAAVAAGRPDAAEDAARSHIRALIAALPNLPDNAFAPD
->UniRef90_A0A7X9B2E4 Leucine-rich repeat protein n=1 Tax=Lentisphaerae bacterium TaxID=1932692 RepID=A0A7X9B2E4_9BACT
-MKKLLQRKRRSASTLLAALMTFFLFVGASARGQGAPDPEKDYAYEPYSYGSASGVIITAYLGNEEVVTTPAHLGGQPVIAIGPGVPRVLIDQDMEPDWGTKGFCNTPVTDLTVSEGVLFIDDAGLGNDALTRISLPASLQELGGNPFFAQYNAPNAELVITVAAGNPNFAIEPNSGALIQNGTHLIFWPTLAARAAAVDGLLTIPDGVTHIGTRILAWNRYYDPDARANVYAFTRIAFPAGVTHIADCAFYACHLESLTLPTSLTSLGLWVSFTALDLPASLAHLGGHPSPHQGHLR
->UniRef90_A0A1H4NAP5 MFS transporter, AAHS family, 4-hydroxybenzoate transporter n=1 Tax=Beijerinckia sp. 28-YEA-48 TaxID=1882748 RepID=A0A1H4NAP5_9HYPH
-METEALNVTSLIDDRPIGGLQIAVIILCALVNMLDGIDTQSIGVAAPFIAEGLGIPVAQFGPIFSAALLGAALGAIGFGAVADRLGRKPLLLVALLLIGVFTLLTAHASSVKWLVVYRFLAGAGLGGATPCFIALTSEYAPARNRAACVTLMWAGFPLGAMLGAFANSFLLPAFGWRAIFYIGGLLPLIVAMILIIWLPESLKFLVNRGAFDAARRILQRMGIKTEPGTKLTTNEHKQEGLPLRQVFSEGRGLLTLLLWVPFFISFGILTVAVLWTPTLLRLNGISPAMTAFVVAFNGLGALFGQGLAGRLVERFGALRTLVPAFILGALATAGLGYGASSVAAASFFIGLNGLFLGLASGGAIALAALLYPTAVRSSGVGLGMAMGRFGQVVSPLIAGGMLGAGFNAGQIMVVIGSGALVGALFVIWFRILAARRHIATVGTEASTG
->UniRef90_A0A848GUV0 Signal peptide protein n=1 Tax=Ramlibacter agri TaxID=2728837 RepID=A0A848GUV0_9BURK
-MKLAVLALSLLACGSAFAQAAATAPEPDYTASVNIGAVTDYRYRGISQSRLQPALQGGADFAHKSGFYIGTWASSIKWVKDAGGNADAEVDLYGGYKFNGGPVAFDVGALRYLYPSSQLAVSPNTTELYVSGTYGPATLKYSHAITNLFGFADSKNSYYVDLNATFDTGYWGLTVTPHIGYQGIKNNSGFSYTDWSVALGKDFGNGFSASLAYVDTNNSNYRSPDGKDLGRATAVLGVKYTYSF
->UniRef90_UPI00214A619A hypothetical protein n=2 Tax=Lachnospiraceae TaxID=186803 RepID=UPI00214A619A
-MIRNIYTKTLDSGPITPVSARKEKEKALSWRNTLMEHQKHLDKTLSQCISEDEYRLTAMELDCLEHVIQLDDFYDFCTDYMCEHGIDTVVDIGCAYGHQSEAFLEENLGYIGIESSGDSPKWNIDKCMYLTEKYPCKIPDGCRFAVSNMCFEYFINDYEALAHDFDTVILSGLGKNTKVFELFDVEEIHYRPLIDSNAIWNLFILTNKHIGD
->UniRef90_A0A0D6A1E3 Transcriptional regulator n=1 Tax=Lactobacillus acetotolerans TaxID=1600 RepID=A0A0D6A1E3_9LACO
-MTDVVRKDVKQRLENGDYSCAKELTLSMFSGKWKIVILFHLGTDGPYRFNQLMRLLPKTSHKVLTNQLREMEEDQLISRTVKSDS
->UniRef90_A0A2H6N9Y6 Cytosolic carboxypeptidase 1 n=1 Tax=Micrurus lemniscatus carvalhoi TaxID=129465 RepID=A0A2H6N9Y6_MICLE
-MWHCTVKVLKYGILLPFLNRTKIAQDIERLIHPNDIIDRVVYDLDNLSCLVPDEGDVLKFNSKFESGNLRKVIQIRKNEYDLILNSDINSNHYHQWFYFEVSGMRTGNAYRFNIINCEKTNSQFNYGMQPLMYSVQEALGGRPSWIRTGTDICYYKNHFSRSSIAAGGQKGKSYYTITFTVTFHHKDDVCYFAYHYPYTYSALMMHLQKLESTNNPQQIYFRQHLLCETLSGNNCPVVTITAMPESNYYEHICQFRNRPYIFLSARVHPGETNSSWVMKGTLEYLMSNTPGAQNLRESYIFKIVPMLNPDGVINGNHRCSLSGEDLNRQWQNPNPDLHPTIYHAKGLLQYLAAIKRLPLVFCDYHGHSRKKNVFMYGCSIKETIWHTNVSAASCDLIEDLGYRTLPKILSQAAPAFCMSSCSFVVEKSKESTARVVVWREIGVQRSYTMESTLCGCDQGKYKGLQIGTHELEEMGAKFCTGLLRLKKLTSPLEYNLPSTLLDIENELIESSCKVTSPTTYVLEEDEPHFLEEVDYSAESNDEPDIDLANNAGDYEPCLHEDGLSDSEITRTHLP
->UniRef90_UPI00197F5B0B hypothetical protein n=1 Tax=Pseudomonas viridiflava TaxID=33069 RepID=UPI00197F5B0B
-ISHKIQFLQWVAGCLIRGGLPAMNDDAVLLTYRVDCIAGKPPPKVKCLPRDSATAKTWWCLPQSEFAAR
->UniRef90_A0A1E5KYP1 Zn-finger containing protein n=1 Tax=Enterococcus rivorum TaxID=762845 RepID=A0A1E5KYP1_9ENTE
-MGQVWMERLMRWNAKLQHFLKGRYARMDQLNKTMLIGSIVLIIANSFLPTSVLRWIGLALIVFIYYRFLSKRIYVRANENTKYLKIHNRIFGKIKKIKLRFQQRKIYKYFTCPSCKQSLRAPKGKGQIKVTCSKCHQQFSKKV
->UniRef90_E3MKT5 Eukaryotic translation initiation factor 3 subunit A n=1 Tax=Caenorhabditis remanei TaxID=31234 RepID=E3MKT5_CAERE
-MAPNYFQKPEAALKRAEELIQVGKESDALDTLHDTIKARRHKQWTQTHEAIMIKHMELCVDLKKQHLAKDALFQYKALTQQINVKSLETVVEHFLKLAESKTEEAQKQSIEKVEEIGDLDQGDVPERLLLAVVSGAAAQDRMDRTVLAPWLRFLWDSYRNCLELLRNNAQVEHLYHQISRHSFSFCLRYQRRTEFRKLCDLLRMHLNQIQKHQYAPNVNSFRVKLTSPESLALMQDTRLVQLDTAIQMELWQEAYKSAEDVHGMMQLSKDKDKRTVKPSSYVNYYDKLALVFWKAGNSLFHAAALLQKFIIYKDMKKSFTQEEAQEQATRVLLATLSIPEGSDSPSDLSRNLDIEEQHVANMRLLSNLLRLPIAPTKNGILKEAARIGVPEASGQIAKDLYKLLESNFSPLKVAKDVQAVLDTITRPDHQQYVESLQAVAAVKALKQVSVIYEAISWERIRKIIPFYSDLALERVVVEASKHRIVKAQIDHRADCVRFGSSDATLAGGVDECDNNEGFTGDDTQLGVEGVRNHLEAMYTRLRVLVEGLDAEKRRKEMVRKIENHVTSYEKNRPTEIDRIHRRKKMLENYKENWERVKAEKTLQAATEQAKREEAARAEEMKRLEEQNKESERKRKQAEAEEIQKKIKQDQLYKMQQNAIYQAIIKEKGLDQFRDMDPEQVLREQRERLDKERAETQRRLQQQEKNFDHHVRALHLEEMNERRAVMHMRMNEAPKLHDQYEEQRITKEM
->UniRef90_UPI001D11B2C3 phosphoribosyltransferase family protein n=1 Tax=Aquihabitans sp. Kera 3 TaxID=2884263 RepID=UPI001D11B2C3
-MTTAEPIEEREALTYELFGTAIRDLAHQVDDSGWEPDWILSIARGGLLIGGALAYALGMKNVATMNVEFYTDVEQRRDVPVVLPPVLELVHLADTKVLVADDVADTGETLQLVRDMVADTVAEVRTLVVYEKSRSVIRPDYVWRRTDRWIDFAWSAQPPVTRRPGVF
->UniRef90_UPI001CFFCFA9 GNAT family N-acetyltransferase n=1 Tax=Arthrobacter sp. ES1 TaxID=1897056 RepID=UPI001CFFCFA9
-MSVSFLQVRPLTDADAAVLGAWAEDELFCRHAGWTSSSPAKVCDFWIRQIKDPPTGLLRLAAESVDRELLGYMDLHGTDPESRELGFLVGPSRRWGHGLGRRIAEAGLTYGFTELSLERIWAEAVAANVASVQILRSLGMRETGRGEAETFLETNSYYLQFEILRDAWELGADR
->UniRef90_A0A1C6SX88 Beta_helix domain-containing protein n=2 Tax=Micromonospora rhizosphaerae TaxID=568872 RepID=A0A1C6SX88_9ACTN
-MTALPSASARTAPSASTPPPRRSTSPSPRSAANPRHSLKAGKNSRAGCALPKYPSPDCTGVPAGTRLATLRLNLDNDSYAVYEAGAVIDRKHIPGNLLIRAPNVTVKDSQIDGTVFNDYNGRLHPFTIVDSTIGPATGCITAPGLAYANYTAKRVRIRGHDDGFRVATPGNVRIEDSYAKLCWNPPELAPPDGSHSGGIQADCRAGECVGIWFNHNTIDNRGPNGNSGITMMSFDGNPVRNVISNDNLVMGGGYSIIYWWTTGPNFELHNNRVVEGTYVYAPADANGTCAHQNWSGNTLVTIDARYNVTSTVGPLPCIQ
->UniRef90_A0A0H4BB36 Uma2 domain-containing protein n=1 Tax=Synechococcus sp. (strain WH8020) TaxID=32052 RepID=A0A0H4BB36_SYNPY
-MWQQQPDYARYKEKLNGEGWLVNRQEGMLLQIKPDTPTQHAQFVLVSYYHLSARIGKPVRQQRMLRHLGIEMWINLQKIGWERCLAPQN
->UniRef90_A0A496XIQ2 Alkaline serine protease n=1 Tax=Gammaproteobacteria bacterium TaxID=1913989 RepID=A0A496XIQ2_9GAMM
-MRHHTRAVGLLVCLLSSAVQSAPAPETETLQVMLQGGSSQELTQLVETQGGTITHDLHIINAVGALLTQAQLDKVLKSPLVTRHIDDLSVSEAPDEPDESTCEVGGALELDYDTRGLRWTLYNKLPAPAILETLELTWPATLGTVEKISLGDTTIDPELYRDTQIGTLKLQFSGPAAPVLTGKADLRVDLKSPSLLHTSDLPLRQRDFTITASFLGDCSTKLIPGYENNHENFYYASVAGADALHLQGITGKGVTVAVLDSGLWEHEALVNDTSGKPRVLARYDAIKNISGNEVFDESGHGTHMTSVIAHSGAVTVDGKPTGSFKGTAPNVNLVAVKAFDVEGQGDLLDIVRAVQWVVDNRETYDIRVLNLSFSARPRWHYWEDPINQTIMRAWASGIIVIAAAGNTGPDPMTIGSPGNLPYVITVGAMTDSWTPDNRDDDYIPDFSSRGPTPTAHIKPDIVAPGGHITGLTRPNSTLMLEHPDYMLSTGEFVMTGSSQASALVSGIAALLLELEPNLSPDDIKCKLLSSAEPAIHRDGFLAYSPFQQGHGQVNATRAVTLGQIGCGNSDMNIRLDISGVKHFQGPAIVESDGNASLPGLSKIVSPEPSERGLSKTRKWGVKAHIERLDPAVTDLESSEISPIDWQKIYRQEKTAMESLIHEPPE
->UniRef90_A0A520FEH4 3-isopropylmalate dehydratase large subunit (Fragment) n=1 Tax=Sphingomonas sp. TaxID=28214 RepID=A0A520FEH4_SPHSX
-MRSRPQTLYEKIWAAHVVERRDDGTCLVYIDRHLVHEVTSPQAFDGLRLAGRKVRRPDLTLAVPDHNLPTTQRVDAAGRELPIADPESAAQLDALRRNTTEFGIDYIDANAVQQGIVHVIGPELGFTLPGTTLVCGDSHTSAHGALGALAFGIGTSEVEHVLATQTLLLSPSKTMEVRVDGTLGFGVSAKDVILSIIGKIGAAGGTGHVIEYTGEVIRALSIEGRLTIANMSIEGGARAGLVAPDDTTFAYLKGRPLAPTGAAW
->UniRef90_A0A842QUU5 Flap endonuclease 1 n=1 Tax=Candidatus Bathyarchaeota archaeon TaxID=2026714 RepID=A0A842QUU5_9ARCH
-MGVDLKSILVKDTIKLDELKGKVITIDASNILHQFLSTIRKPDGTPLTDSQGNVTSHLIGLFYRTLKMMREFSVKPVYVFDGEMPDLKTDVVEKRAERRREAKKKWSKAKQVGKDEKAFKEAVKTGFLDDQMIKDAKLLLNNMGLPIVQAPAEAEAQCAYMTHDEEIYAMNSRDYDSMLFGASKLLRYMTISNKDNIEIIDLDKFLNHHEISWAQLVDMGILIGTDYNEGVFRVGPKTALKLIKRHGSIEKIPEKYQKKLDENYADVRKLFLDPPLIEDYSLEFKEINRNGVMQFLCEERGFPHERVLNNLEK
->UniRef90_A0A4Q3S4G9 Acyltransferase domain-containing protein (Fragment) n=1 Tax=Chitinophagaceae bacterium TaxID=1869212 RepID=A0A4Q3S4G9_9BACT
-MKAYIFPGQGAQFSGMGKELYENEQAKAMFEKANEIIG
->UniRef90_A0A1Z4EIA0 Peptidase M24 n=1 Tax=Mycobacterium shigaense TaxID=722731 RepID=A0A1Z4EIA0_9MYCO
-MVLALTGYVWQQDVGAVFRRDTVLITDGGVDVLTDSPSWG
->UniRef90_A0A672Z142 Cytoplasmic linker associated protein 1a n=1 Tax=Sphaeramia orbicularis TaxID=375764 RepID=A0A672Z142_9TELE
-MDLNMEDLLEQLMHKDLGRRIQVGQEILELIPDQDKFPELEQDQTLLDRMVDTVAGSWVNSSNFKVGVASTCLIKGLCLCLIATLNVSFSHLSMNCLVEIYRHVGERVRMDLGKKGLPQSRLNVIFSRFDEVQRSGNMVLSPLSGETYLLTPQTDGGGAGAVDEQDFIQSFDDVPTLQIYSNREVEETMTKIRDVLSDDKRDWELRVAALKKVRSLLLAGAVEFDGFLQQLRLMEAPFKLSVKDLRSQVVREACITLGHLSSVLGGRFDHAAEAIMPALLNLVPNSAKVMATSGVAAIRLILRHTHYPRLIPIITSNCTSKSVAVRRRCFEFMDLLLQEWQTNALERHGTVLMETIKKGIHDADAEARSVARKCYWGFHGHFSREAEQLFQTLESSYQKALQAHLRSGDSLMSLPASDRSSSSSQEIVFLTPASTSSSGSLHRSRSDVDVNAAATATARTRMPAVPAAMQAPPFSSASALPPGSYASLGETHLTTLSFGGSLWTAGRVLKHFHCFPAGSRSGSPGRLLSSTYGRIPRPTMGTAAATGCISGGTMEKGRPRGHRSQGCSRETSPSRSARSRIPRPSMSQGCSRETSRESSRDTSPARGFSPLDRLSHQARISASVNAMRILNTGTEVEAAVADALLLGDSRSKRRPARRRYESPGMYSDDDANSDASSACSERSFSSRNGGVAPHFLRQTEDVAEVLNHCASANWSERKEGLLGLQNLLKGQRTLSRVELKRLCEIFTRMFADPHSKVFSMFLETLVDFIVLHRDDLQDWLFVLLTQLLKKMGADLLGSVQAKVQKALDVTRESFPFEQQFNILMRFIVDQTQTPNLKVKVAILRYIHALARQMDPADFVNSSETRLAVSRIITWTTEPKSSDVRKAAQVVLIALFELNTPEFTMLLGALPKTFQDGTTKLLHNHLRNLCFLRPQASSGTALGRTPPRPPSSRGSPLTSPTNCSHGGLSPSMLDYGSENLNSEEIYSSLRGVSEAIQNFSFRSQEDLMESPRSDGMSGVAASSESAVEVGGRTALDNKTSLLNTPSPRSFAGPRFRDYNPYNYSDAIGSTDKVATKEALYEDAVDPAEQLELVGDLLKALSQAQGGEPGLDERRRTLLELLKVAREDSLVVWEEHFKTTLLLLLETLGDKDHTIRALAMRVLKEILRNQPARFKNYAELTIMKTLEAHKDSHKEVVRAAEEAASTLAGSIHPDQCIKVLCPIVQTADYPINLAAIKMQTRAIERIAKEPLHQLLPDIIPGLLQGYDNTESSVRKASVFCLVAIYSVIGEELKPYLAQLTGSKVPWESLRLVCTCADVGIQSHVKGMGKESVWLEMFF
->UniRef90_A0A7W5NUZ0 Glycosyltransferase involved in cell wall biosynthesis n=5 Tax=Pseudoxanthomonas TaxID=83618 RepID=A0A7W5NUZ0_9GAMM
-MNTMAARLPAQDADTLVSVIMPVYNAEQTLRRSADSVLAQSFGQLELILIDDGSRDGSAAIVEELARRDERVVAVRQPNGGVAAARNTGLRAARGTHIAFLDSDDWWEPRKLELQLAWMRETGAMVCYASYQRVAEDGRLLSKVSPPLEVDYRRMLGSNHIGNLTGIYDRRLGEASFQKMGHEDYVFWLDRVRRAGSAVRVPGDAPLAYYLVRNGSVSANKLRAAGWQWRIYRQVEGLSAPRAAWYMLQYIRHALWKRKPVTT
->UniRef90_A0A534HYX9 DNA alkylation repair protein n=1 Tax=Euryarchaeota archaeon TaxID=2026739 RepID=A0A534HYX9_9EURY
-MAGPVERMREDLVRQLDAAKRPGKLGAQAYLGSPVPVLGVPVPDLRKIVSGFKKTHKDVDAKTLNPLAASLWDGATFEEKAVAINLLDACLKILDEDSWTLLNRWAGEATGWGLCDWLGMGLIAKIVYRQPRRFQEILGWTKSTNPWRRRIAVYALRNFVFAGELDKPFRLLERLLYDPEVWVQRAVGTWLRECWKKDPRRTEAFLRKHVRGLPKVVITVATERAPAVFRAELRRGREPEAR
->UniRef90_A0A2N2AM00 Precorrin-6Y C5,15-methyltransferase (Decarboxylating) subunit CbiT n=1 Tax=Firmicutes bacterium HGW-Firmicutes-8 TaxID=2013789 RepID=A0A2N2AM00_9FIRM
-MSDKQWIYRTGGIPDELFARDEVPMTKAEVRAVTLAKARLQESHVIWDIGAGTGSISIEAALMAVTGKVFAIEKKPEGVQLIKKNIEIFAVANITVCSGIAPEALQGLPEPDRVFIGGSGGNMAEIIRYVHEKMPIGGRVVVNAIVLESLVTSVETMKKYGFGDIDVTQVSIAKTVDVGRLHMFKSHNPVFIISGEKTTNQLTVKKETTEGLAQRSCNQF
->UniRef90_A0A2G2LVQ5 DNA-binding response regulator n=1 Tax=Robiginitomaculum sp. TaxID=2030823 RepID=A0A2G2LVQ5_9PROT
-MQSTEQEKAHLLVVDDDDRIRDLLRTYLSRHGYRISVASDAKRVRRLLKTLEFDLVVLDVMMPGEDGISLTRFLRQSSAIPIFLLTARGAPEERIEGLRAGADDYLSKPFEPEELLLRIGAILRRKGTTIGSGATLQFGPWRFTPSTGELVGTKGRVSLTDNEARLLAALCKRPGEAFSREALSRDTAAIERSVDVQIARLRRKIEDNSRFPQYLQTVRGAGYRLLAHHVSETSSA
->UniRef90_A0A699XL38 Secreted protein (Fragment) n=1 Tax=Tanacetum cinerariifolium TaxID=118510 RepID=A0A699XL38_TANCI
-MPSAPMMASCLACTPLANVMSPDDVSTSTHCSLVSSWTATLCGDTPDLVVDDKLDRLASTFFLQSAVHEHLVHVLTVEHV
->UniRef90_UPI001FF62731 hypothetical protein n=1 Tax=Amycolatopsis sp. WQ 127309 TaxID=2932773 RepID=UPI001FF62731
-MPPTQTFMVVAVLRDDTDLAEFAALRNDEEKQLELLRSAGRIGAHYISPARRATFVEVIADDEKQVAETLATLPFARFFDADVYPTAPPDAAEIAYRARAATA
->UniRef90_A0A8S5L7T1 Large Terminase n=1 Tax=Myoviridae sp. ctKHS5 TaxID=2823541 RepID=A0A8S5L7T1_9CAUD
-MKSKEFLAELRAYADSLRQKVEAEFDGWDDSLQAIAERRKKVFDPVTGYDYFVSHYFPHYVRSPHRSELHDYLFATLPEVLADPKSVNMATAAPRGEAKSTLVSQLLTVYCLITQQKRYALIVMDSINQAYPMLESIKVELEFNQRLKIDFPEVAGQGRVWQATTILTKANQKVEIAGSGKRLRGLRHGAYRPDLVILDDIENDELVRSAEQRDKLHDWLKKTVLPLGVPGEKMDVVYIGTILHYDSVLNRTLSSKAWKTAKFKALKKMPDDMALWDKWESFYLNEGEAVADAFYYANRAAMDKGAEISWAARPLLALMKIRARDGHATFDSEYQNDPVSSEDAIFANAIRYWTELPSDLIYFGALDPSLGKAGASRDPSAILVGGYQRSTGKLYVVEAQIKKRLPDLIIEDVIRLHKQYHCQRWFVETVQFQEFLKDELVKRSAQRGCPVPATAIKPNTDKMLRIESLQPHMVNGLIMLHGSQATLIAQLRHFPKADHDDGPDALEMLFKNAASCAAPIEWMGLDALDDDEYDDNDLGYSKWKH
->UniRef90_A0A651EH65 DNA-binding response regulator (Fragment) n=1 Tax=Rhodobacteraceae bacterium TaxID=1904441 RepID=A0A651EH65_9RHOB
-MATIALVDDDRNILTSVSLALEAEGFDVRSFTDGVAALAEFGRNAPDLAVLDIKMPRLDGMELLRRLRLKSDLPVIFLTSKDEEIDEVLGLRMGADDYIRKPFSQRLLIERIRAVLRRREAAVEGEREEDDRPLTRGRLTMDPLKHDAFWGGQEVTLTVTEFLILRALAQRPGVVKSRDQLMDVAYDDQVYVDDRTIDSHIKRIRKKFR
->UniRef90_A0A1C9CI92 Acyl carrier protein n=2 Tax=Rhodochaete parvula TaxID=110510 RepID=A0A1C9CI92_9RHOD
-MEKHSISDRVKNIVSEQLGVNLDEVTDQASFVDDLGADTLDTVELVMAFEEEFSFEIPDEDAEKIKTVAQAMEFIQQKVEATAT
->UniRef90_A0A2E7B655 Type IV pilus biogenesis protein PilP n=1 Tax=Hyphomonas sp. TaxID=87 RepID=A0A2E7B655_9PROT
-MLTLPLLAKMSSAAVAAAITASLTYGQYNIASGPNGSGLMPPASVLHPNARPGAMLDPLAEMASAMTSLKQERAKADRNRAMIDWLAGLQTRFTVQRFETGLVYKVRYAAAGXAGTVLQDXVAVPYGPELPXAVSLQAGXGGXVRVEGLSCSGQETLSEMDAGAGEQAVETAAMSRAEAYLXQPXAADPALPADCLMARLKRG
->UniRef90_A0A3N2C5J3 Vegetative cell wall protein gp1-like n=1 Tax=Plantibacter flavus TaxID=150123 RepID=A0A3N2C5J3_9MICO
-MQTPPASRGSSTPPEPEAVPGPPRPPSSPGHRADPCRSPSRPSRSLSRPSRSPSRPLPVTEQPAPVTEPVEVPHTEAPRPTTLPGGPSTSSGNEYPHPGHASQPRSPSNPPRSPSNPHRSLSLSKCHTPKPPAPQRSPGALRHFDKLSAAKLRERTSLPRSPIRPSRSLSLSKCHTPKPPDPRRHPGGPSTLRQAQCGAAQGTDIPPPVTEQTAPGH
->UniRef90_A0A5J4QFG3 Virulence protein (Fragment) n=1 Tax=termite gut metagenome TaxID=433724 RepID=A0A5J4QFG3_9ZZZZ
-MEDIPMKENEDIGGRKSKNEQIESYLQERYDFRFNTVKSKPEFRPKNGNHPFSPVTKFDLNSLKREMDRTMGIATSSDNVRTILESDFSPKIHPVREYFNRLPRLDPDINNYTWQLSQTVRVANSDKWLEYLVKWLVGVVANALHDVGCQNHTCLVLTGEQGRFKTTWLDHLCPPSLQSYLFTGKIDPQNKDVLTLIAEYLFINIDDQLKALNKRDENELKNLITTPAVKYRRPYGVYIEEYSHLASFMASVNGNDFLTDPTGSRRFLPFEVISIDME
->UniRef90_UPI0014789B01 phosphoribosylformylglycinamidine cyclo-ligase n=1 Tax=Leucothrix arctica TaxID=1481894 RepID=UPI0014789B01
-MEENKTSLTYQDAGVSIETGNALIDRIKPHAKRTKRPEVLGGLGGFGALMSIPSRYENPVLVSGTDGVGTKLKLAIDMNRFDTIGVDLVAMCVNDIIVTGAEPLFFLDYYATGKLNNDDAENVIKGIADGCEQAGAALIGGETAEMPGIYREGDFDLAGFSVGVVERDAIIDQSSVANGNVLIGLASSGPHSNGYSLVRKVIEVSGAKLDEKFSDKEETLLGDALLEPTIIYVKPLLKALKQFDIKALAHITGGGLTENLPRVLPSNCKAVIDLTSWDRPEIFNWLQKEGNIEDMEMLKTFNCGIGMVLVVAEDQADEVINSFKLQDIKSFKLGQISAAETEEAYVEYV
->UniRef90_A0A1I7TZE8 G_PROTEIN_RECEP_F1_2 domain-containing protein n=2 Tax=Caenorhabditis tropicalis TaxID=1561998 RepID=A0A1I7TZE8_9PELO
-MDKKYMNCTRCELCATADVIYGTPFMEYSILLRLLTAPLATMGMGLLSATIVKTKGIHINTKVILFVLCISAITCNTGITIDCLYKFFISNVMPDYMQCDFQVFNPQYGLVIRHIEMLGSMCLSTSSIALAVERTVATIFYRNYPSKPTLGSILVVVQIHDYKFYHFITTWQALLNVLAISVFIILWIINYYRMKIIENSHLQVVLARYNLHENMSTTCLMAPIIVVLCLMVFSAELIILLFTPQYDEDTVVTHKVLDEVIEYSFYPELQLTLIPIFFIALILVLITQSKKLRENFLLVSNLSICFPVKVHTTDSRSSSESSSSEGSSSIHWNSKMDGLSITPQVPKF
->UniRef90_A0A3M2HUF5 Spermidine synthase n=2 Tax=Stutzerimonas TaxID=2901164 RepID=A0A3M2HUF5_9GAMM
-MKRFVLIDTAQIPDDGGALCLFEYGEDFVIKIQGGNGNQLMNTRTHGSEDALAEIPCRKIAQRPHPRVLIGGLGMGFTLASALRHLGEDAEVHVAELVPGVIEWNRGPLGEKAGMPINDPRARVLRSDVADILKNEPQGFDAIMLDVDNGPEGLTRKSNSWLYSSAGLEACAKALRPKGLLAVWSASADQAFSQKLARSGFNAEEVQVFAHGNRGTRHTIWIAEKRE
->UniRef90_A0A2T1LZU9 histidine kinase n=1 Tax=Aphanothece hegewaldii CCALA 016 TaxID=2107694 RepID=A0A2T1LZU9_9CHRO
-MKEQDIKRQFLDEAGDYLNVIESALLGCSTKEITSAQFDAVLRAAHSIKGGAAMMGYQTLSDFAHRLEDFFKVLKSHSKPEIDETVESLFLSSVDQLRQISSFYRQGAETIAPEWLSEQVEPIFQGLLDRIGELTPEKSLSLLSEDVGEEMTVLIFETEVESCLQGLESIIAQPQPTNLREEILSISQELGGLGEMLQLPQFSRLCTSIYEHLKSATEGIDAIALSAIQAWRRAQAMVIVGQKEAITSEFLLNHSTVIPTLETETTSPEELKIETVSTEEKTLRVSSSLLTELADLFGEMSIGRNSMDLQLQRLRRLFNLLNQRIQRLESSSQALRSLYDQRIQGYTSSVIPIKTNSVKPHLALFDNLEMDNYSDLHPLSQEVMETIFQIEEVANDLDIYLAETEKTAKDSQQTFELIQSQLTKARMRPLTDLIAHFPRALRDMSLKYGKPVELKIQGETTRIDRTILESLNDPLLHLLRNAFDHGIEDPEKRKEVGKPPQGTITISASTVRNHTIIQIQDDGAGINLDKIRSQAHKMGLDEDIIAKATIDDLLNLIFEPGFSTAENKSELSGRGVGMDIVKTQVQQMQGDIKVSTLAGQGTTFTITVPMTLSLIRVLLIEVEQMLMAVPCNAIEAMILPEPSQIIQFKGQTFLKEESELFPLIYLKDWLNIPTVYTQRDHESLPSIDKPTILKIALGNNYIGLWVERYWGEQEVTIRPVEGNLKLPNGFTGCTILGDGCVVPLIDPALLLQPSFPPSFLSSSFISNSQPTAQKATLLVIDDSINVRRLLALTLEKAGYQVEQAKDGQDALEKLQRGLGVQGIICDIEMPRLDGYGFLANYKTDSIGQNIPVVMLTSRSGEKHRSIAMNLGASAYFSKPFQEKLLLQTLQSLIKN
->UniRef90_A0A0R0EP28 Glutamyl-tRNA(Gln) amidotransferase subunit C, chloroplastic/mitochondrial n=4 Tax=Glycine subgen. Soja TaxID=1462606 RepID=A0A0R0EP28_SOYBN
-MTSKGLLRGASLTANAVWHRSSFFPKVTVSVHPKLVKFQSFSSTTACSSLPPPDLPRLAKTAQISLTPNEVEEIAPKIQQVIEWFGQLQGIDLESVEPSIRAGSL
->UniRef90_UPI0015687092 helix-turn-helix domain-containing protein n=1 Tax=Ensifer adhaerens TaxID=106592 RepID=UPI0015687092
-MVDGIPSFFVYGEPEQPLEPGFFHVETVMARRGLHHGQVKAHKHDQLAQVTYWLRGRGSYFIEDKVLDFSAPAVSFVPSGIVHGFSVEPRESDAIVISIADGLMLSVRAQTALAIDVPVMIAGVSGDSQWQRLSQLMDIIADEYATAAFGTQSMMASLASAILTQIARLASFAPSPSQSPDMMLAMQLRRMIDAHFRENWTVGRYTDALGSTPHLLAKATGAAFGMQVKELINERRLLEAKRLLLFTIRPLEDIAYEIGFRDAAYFSRFFRLRTGVAPSDWRQLKLGQTASSP
->UniRef90_A0A261KVG4 Transposase (Fragment) n=1 Tax=Hydrocoleum sp. CS-953 TaxID=1671698 RepID=A0A261KVG4_9CYAN
-MILYHFEKRILRPDCIILLSALAQVGHNSPDLIAYAFRSGLFRLPGGTSQTLPKEPVNYTLDQVGDSLKRLELATPKLKQSVVDACAYRTPKWIYKI
->UniRef90_A0A2T5BQX3 Heme-degrading monooxygenase HmoA n=1 Tax=Rhodovulum imhoffii TaxID=365340 RepID=A0A2T5BQX3_9RHOB
-MPTISRSNEFQTVITTFEVTPGTCQDLLDALSEAYASFISRQPGFIGAGLHVNDAQTRIANYSQWVRREDFQAMLRSEEMRDRNRRFTELSKSFEPVMYDVFESYD
->UniRef90_A0A1G9W8E7 Neutral/alkaline non-lysosomal ceramidase, N-terminal n=1 Tax=Daejeonella rubra TaxID=990371 RepID=A0A1G9W8E7_9SPHI
-MKKLFSCIIISVQIILLSERPAAQENSHSGWKAGVASVVITPEESLWMAGFAHRTKPSDGKLHELWAKALVIEDASGKQALLITTDLSGIPKSISDSIRNQLEKRFKFSRSQIIFNTSHTHSGPVLVDALWDLYPLDDTQKERITKYTKKFELQIESIVRKALGSMKPVNISSENGITRFAVNRRNNIENKIDAQTDLKGPSDYAVPVIRVSDQKGKILALAFGYACHNTVLHGYEWSGDYAGYAQITLEKAHPGATALFFQGCGGNQNALPRKTVPLATQYGKELALAVDAVLEGEMKILEPKLSTAYSEVKLELEKAPSKDELLTIVSKETGYIKNWALNMIKKADKGETFISSYPYPVQFWQLGNQSIVALGGEPVVDYAINLKKVFGPDLFVMGYSNDVMAYIPTAEILREGGYEGHTSQMAFGMPAKWKESIEPTIMREVMILAEQLGVKAKPKP
->UniRef90_A0A5C5YMF9 Putative electron transport protein YccM n=1 Tax=Posidoniimonas polymericola TaxID=2528002 RepID=A0A5C5YMF9_9BACT
-MTPLSSLAAILRRAASLEIVVLAFAFLFALATGVEGQEAYDRPVSSAPQPDDIGAGYQTPEVQRTSPRSAALQMLDVVLLIGGMAAIAWVSRRGRRRWVVTAVTLASLAYFGFYRQGCVCPIGATQNVAASLSDASLATPMVVLAFFLLPLAASLLAGRVFCGGVCPLGAIQDLVLLRPVQTPQGVDRWLGMFRYVYLGLAVWFAVLPAGQRDFVICRFDPFVGFFRLNGPAWMLGVGVALLLLGTVVGRPYCRYLCPYGGLISVVSRFAIWPVRITPDEELDCGLCVDSCPFGAIKDLRAKPSECLACARCFAHCPRQQLAWGEIELVELDELVSSAKCVAQRSGGNE
->UniRef90_A0A1I0ZIW2 Enediyne biosynthesis thioesterase n=1 Tax=Amycolatopsis marina TaxID=490629 RepID=A0A1I0ZIW2_9PSEU
-MAYYEIRHIVGFEETNLVGNVYYVNYLRWQGRCREMFLKEKAPAVLEEVRADLKLFTLKVDCEFFAEITAFDELSIRMRLEELTQTQIQFTFEYVQLAEGRENLVARGRQRIACMRGPNTATVPARVPEELRTALAPYAEDVKGARTESAAVPATGV
->UniRef90_UPI0013C30B07 phosphatase PAP2 family protein n=1 Tax=Euzebya tangerina TaxID=591198 RepID=UPI0013C30B07
-MVRQAFSRLPGAVALSRATTDLGSMFMVAGAAAMLLAGGRVRRAGEVAAAGALGWTVAHQAKKVFDRPRPYEAEATPRLIAEPTGSSMPSGHAAVAMATATVLAGRAGPGRRWVWLLMPAWVPLTRIHLGVHYPTDTMAGLILGHGLGRLVVAVSDHRSRRQPQDDGRVV
->UniRef90_UPI001C0550E4 protein PRRC2C isoform X12 n=1 Tax=Corvus kubaryi TaxID=68294 RepID=UPI001C0550E4
-MSEKSGQSTKAKDGKTKYATLSLFNTYKGKSLETQKTTVAARHGLQSLGKVAISRRMPPPANLPSLKAENKGNDPNVNIVPKDGTGWASKQEQHEEEKQPDVPQTQPKPAVPAPPEAAPVAKSWANTKPGGQEGPPIPINSYFQQEFPSLPAAGDQEKSGKDKDAPEDGSGPNLRPQNQDPKALGQEDASATPAEQNDGQKAGDKRDVRLPQVPQPKLNGQQQPPISSQYRAMMPPYMFNQYPRMAYPPSMQGPTRFPNSEPGRGPRGRGPPSWCSEPIERPSILSASELKELDKFDNLDAEADEGWAGAQSEVDYTEQLNFSDDDEQGSSQKEKESGDEQTPSKDSQSPDGQKETEEQTNAKSATQVSAAAAKGSYSKSSQLDQDRGPPQPSIHERGGPALPPKSILPPHPPPPDRQMGRQGPFPPKPVPDDDEIWKQRRRQQSEISAAVERARKRREEEERRMEEQRKAACAEKLKRLNEKFGCVTKPSREDPLKEREREREREREREREREREREKEREREREREKEREKEKEKEREREKEKEKEEKEKLEKAKEQEVEKEKEKEVEKEEKENEKEKEEEKPAHDVPEPVEPVATPVVEKQESETKNNKKEKEDQAVFTRQDSGRNEKEVSQVTHENEPDSGSQPRPAVSSGYSKQFQKSLPPRFQRQQEQMKQQQWQQQQQGVLPQSAPSQPSSGPVPPPQHRPLYQPMQPHPQHLASMGFDPRWLMMQSYMDPRMMSGRPAMDMPPIHPGIMPPKPLMRREQLEGSAAGSDSFEHMARSAREHTVPLSEPRMMWGSDPYPHAESQQSSSPPKVLEEPDDLRSEAHLEQERVAVPASAYPVEHNQLDSHPKTEFFRESGEVEVQKFPSRPLEDVQPLQTDTPNTAVNFEAVNEKVTRSSPELVPVGESHSSLKRSISHGSSHSLKSEDQRSETAANIPKLSNRPIEAKETIERLEIKPKKEILITNRTSEGPKPEKTFKPKSETRWGPRPGYGRRDEGGDRPVRRSGPIKKPVLRDMKEEREQREEREQRKEKEGEKTASEKPGKPEKSDKKEAPQVPLPQAEPERSTSSSAPLAKKITQDAAPVPASQESSQPEAAAKAVVQPPAPAVQQQLPAAQPAAAQLPPAIPQAPATQPAVQPPPHAQPPAPASKEEKQAEKVVSKEVVEKPRLETRPVKREPGLPPRTYWKEARDRDWFPDQGYRGRGRGEYYSRGRSYRGSYGGRGRGSRGHNREYPHYRDPKPRSEHVPSGPVRQREESETRSESSDFEVIPKRRRQHGSETDSDSEVHESASDTLLSDKDSIIKGKHPKREERADGKKPPKPLSFKPENNIRVDNRSLEKTYVRDDENKPKPGFLPKGEPSRRGRGGMYRRGGRDPGGRPPRPSTIRRPAYRDNQWNPRQTEIIKPEDGEPPRRNEHYGPIPIDKRPPKFERKFDPNRERPRRQRPARPPRQDKPPRFRRLKEREAASKMSEVVTSSTTSATVSNAVNEPSNPALDVSGSKTPDLSNQNSSDQANEEWETASESSDFNERRERDEKKTADAAAQVAAKAGENAGVPKREIAKRSFSSQRPGIDRQNRRGNNGPAKPGRNFSGPRSERRSGPPPRSGKRGPFEEQAAPVPGVDPANSNALHQEDGGVAAAGQKTTKDASGKKREEPKAGPKKPKEKVDALSQFDLNNYASVVIIDDHPEVTVVEDSQSNLNDDGFTEVVSKKQQKRLQDEERRKKEEQTVQVWTKKGSSEKGRGQNSKLPPRFAKKQQQAAAAAAQQAQAQPPCPAQSPAQPQAPVPTQSQAAGGTASTDYTVSGKVLQNTQAHNGLGAELWDNKVPPTAVLNDISKKLGPISPPQPPSVSAWNKPLTSFGSATSPEGTKPGQEGGVDLGIETIQFGAPASSGSDNEVGPVLSEKSTDKLPEPKEQRQKQPRAGPIKAQKLPDLSPVENKEYKPGPIGKERSLKNRKVKDAQQGEPEGQEKPSPTSVRSPEPVTTKETKAASELSTEIGTMISVSAPEFGTNTKESVTDYTTPSSHPNTVATSSTKMEETLVTNVPLPHTLPLPRRETLQQSSSLTPVSPATVDLTLKMESARKAWENSPNMGEKSSPVTSAASPIAGGSSSSSTGPSSGTYSSFSSASMPPIPVASVTPTTSLSGAGTYTTSSLSTKTASTSDPPNICKVKPQQLQTSSLASASHFSQLSCMPSLIAQQQQSPQVYVSQSAAGTTAQIPAFYMDTSHLFNTQHARLAPPSLAQQQGFQPGLSQPASVQQIPIPIYAPLQGQHQAQLSLGAAPAVSQAQELFNSSLQPYRSQQAFMQSGLSQPSPVVLSGTALHNFPAVQHQELAKAQSSLAFQQTSNTQPIPILYEHQLGQASGLGGSQLIDTHILQARATLTQASNLYSGQVQQPGQSNFYNTAQSPSALQQVTVPLPGSQISLPNFGSTAQPLIALPQSLQPPLQHTPPQAQAQNLSRPAQVTQPFRGLIPAGTQHSMIAATGKISEMDLKAFGGGIDVKPGTPPVTGRSTTPTSSPFRASSTSPNNQSNKMNSIVYQKQFQSAAAAVRMTQPFPAQFAPQILSQPNLLPPLVRAPFTNTFPAPVQRLPVVLHSQMPSQMTTGLMSHPQLPRVARGPCGSVPGARGTQAQAALKAERDMKVSM
->UniRef90_A0A1A2FR64 MPAB_Lcp_cat domain-containing protein n=1 Tax=Mycobacterium sp. 852002-51057_SCH5723018 TaxID=1834094 RepID=A0A1A2FR64_9MYCO
-MKGPATRIADLLNPAAVLLPAANVIMQLSLPGVGYGVLESPVDSGNVYKHPFKRARTTGTYLAVAAIGTESDRALIRGAVDVAHRQVRSTPSSPVSYNAFDPKLQLWVAGCLYRYFVDQHEFLHGPLDDYSAEAVYRDAKRLGTTLQVPERMWPPDRAAFDAYWKRSLDQLRIDPPVREHLHGVASMAFLPWPLRMLAGPFNLFATTGFLAPEFRAMMRLDWSRSQQRRFDWLLVALRLADRLIPHRAWLFSYRLYLWDMRSRARRGRRIA
->UniRef90_A0A7C8PLT4 Uncharacterized protein n=1 Tax=Orbilia oligospora TaxID=2813651 RepID=A0A7C8PLT4_ORBOL
-MPTGRFREQFRRFIASEILAASIASGPPKDLSRLEMPKYPIQTRPPKMPSESTRAASTESATLVRIAEYVFDEKYSNQNKFN
->UniRef90_R5PHK2 Glycosyltransferase group 1 family n=1 Tax=Prevotella sp. CAG:487 TaxID=1262928 RepID=R5PHK2_9BACT
-MAGRLALKTCALGYVSDDKRIAVIYNAADIYVLPSVEDNLPNTIMEAMACGVPCVGFRTGGIPEMIDHGKNGYVADFRKADDLAAGMHRLLCGDDYEAMSRAAVSKVHIHYSQQSVAMRYIEVYNETAAMKKYII
->UniRef90_A0A067SRJ6 HET domain-containing protein n=2 Tax=Galerina marginata (strain CBS 339.88) TaxID=685588 RepID=A0A067SRJ6_GALM3
-MPAIKAAGIDNSRTLYDIVHGCCVTLFACTWLSIHPNICAPSDSDWTSRRRRLKTMLCALIVPELVLVWALRQRTGAKKIAEKQKEKKWTRYHGFFISMGGFNLFCDGKRIPLSPKRLEQLEECGWIAWPGISEREIKDKSKGDFLSKGIAVSQTLWFVVQCIARFEQGLAVTELELVTMAFVVLNVALYWAWWDKPLDVRCPVDVKIKEGITLPQVEDLFYRDDTRSDPPNRLQLPSFRILKLSTEEGIQPTYPDQTFFLRKFMTFIHPKGPHGCLHRMIISLARPFSDMLSSTEIPRGADCVPTFYAPSGDSRSDYSDEYSIALGLGFAILFGLSHCVGIWVNLSFPTEIEQDIWRVTAIAITAAPLAFQLLGGLVLALGSPEPERPWSGVFMYGCLVIWYLILIAYIFSRFVLLVLPLIAMRALPGSAFDDISWAKFLPHI
->UniRef90_A0A8J4Y4H5 Neurofibromin n=1 Tax=Chionoecetes opilio TaxID=41210 RepID=A0A8J4Y4H5_CHIOP
-MCVCVTPSPVPSPVTRHRFCSHPDDKKRAKVAMILDKLITLTIEEVEMYPSIQAKIWGNIGQVSELIDMVLDSFIKRSVTGGLGSGQAEIMADTAVALASANVASVAKKVIGRLCRVIDKTCTSPTQTLEQHLMWDDIAILARYLLMLSFNNCLDVARHLPYLFHIITFLVTTGPVSMRASTHGLVINIIHSLCTCTKPTFLGKFVCFVAVFVCRFFRP
->UniRef90_UPI0021698233 SPOR domain-containing protein n=1 Tax=Mucilaginibacter sp. X4EP1 TaxID=2723092 RepID=UPI0021698233
-MKNTASYLKTKIGWIGYCIFFVLFILPALSHAQTRGKVEVVKDPLIDTLIARRASLGKNVAVGDDATSGYRVQIFFGSNRQDAYSAQARFLGEYPDTRTYILYTEPNFKVQVGDFRTKLEAQKLQNDLRDKFTSLFIIQGKINPPKTDASND
->UniRef90_A0A8T9PFL0 O-antigen ligase family protein n=1 Tax=Leucobacter sp. H25R-14 TaxID=2932245 RepID=A0A8T9PFL0_9MICO
-MAESKTRLGVSAYAICVFIFTLGSNGVRNLVGWPAFLALAVVLTGLGIVLFVRLKPERFRWYRLPAPIYWFLILAALSILWSQYRLESVLGVAAQLATTVLAVVVAFVLSWHEVLRTLGTALRYLIGLSFLFELWVALFVRAPLLPWWMEEPEGETPKLLYWSRDLLFSGGPIQGLVASSVLLGFLGLLGVIIFAIQLRAGLVRPFSGWCWLALSLLTILLTRGATVWVALAAVVVGLVVALWARRLGPERRVPLYVTSGALLAAVIALTLFARDTVFGLLGKSGDMTGRLETWQKVIELAEQRPWFGWGWISYWAPWAEPFASLDRKAGLQVMSAHNAWLDVWLQLGIVGLLAFAPIVVLTMWRTWFRAVDQPRRGHGPALPYATSSLWPFLVIIALLVQSLTESRLLIEGNWVLLILLAVKSRFDFQLPSLDAEPTRLPWRRVPIPQERLVPYKRDPRD
->UniRef90_A0A1Q9V6M8 TetR family transcriptional regulator n=1 Tax=Saccharomonospora sp. CUA-673 TaxID=1904969 RepID=A0A1Q9V6M8_9PSEU
-MPKYVDHEGRRTEIVEATWRLIAERGIEEATMRAISESLDMANGALKYYFPDKNSIIRAAFEHVVAATNARVRERVGEATGLAALRAFCVEMAPLTELTKLEARVVLPFWQRALSDPDLERLHTDSVTLLRAHIVEFLQQARAEGTVRASTPDDVLADQLLAMLIGLQALALLDQDGTGEAAQLRMIDAFLDSLA
->UniRef90_UPI0015550403 DUF3990 domain-containing protein n=1 Tax=Palleniella intestinalis TaxID=2736291 RepID=UPI0015550403
-MLVYHTSDVQLNIPDTVHSRGNLDFGRGFYTTRLKEQAIKYGERFVALGHDAYLHTFDYTPCSNLRIKTFDSYDEEWLRFVCSCRKGGTEYEQFDIIEGGVANDKVYRTVDFFMTGIYTLEQALQQLVYHKPNHQICFITRKAIDLCLRLSDCRKLNI
->UniRef90_A0A2G2GAA8 CSD domain-containing protein n=1 Tax=Arcobacter sp. TaxID=1872629 RepID=A0A2G2GAA8_9PROT
-MKESKGFIMKGKLFNCSNGATSSEHCFVIADGGKHGYFVSSKKADGPLMNGACISFELEDQKKGSIVTDVHILD
->UniRef90_UPI000314C431 metal ABC transporter permease n=1 Tax=Bartonella rattaustraliani TaxID=481139 RepID=UPI000314C431
-MYAFFLAPFIDFHFMQNALIGSILLSISACPVGVFLMLRGMSLTGDAISHAILPGVAAAFLFRGFSLISMTLGGLIAGFIVVLATALISRNSFQKEDASLTVFYLIALAAGVMIVSLKNSATDLLHFLFGSVLALDTQAIFLITTIMVITVCSLYILWRALLVESFDPFFFKSLSPLSKYVHLSLLGLVVLNLVGGFQSLGTLLSVGIMMIPAITARFWLSRLGPICILSILLGIIASICGLLLSFHLSLPSGPAIIIAAGSLYLFSCFISPRGFIVAWFPHLFYNYFLNLKK
->UniRef90_UPI00210245CE peptidoglycan endopeptidase n=1 Tax=Sandaracinobacter sp. RS1-74 TaxID=2913411 RepID=UPI00210245CE
-MGGAFRPQGRGEEGLDCLGLALRALAAGGCRVDMPRLPMRGHSVEQVHGWLCAAGFARLEVEEASPGDLLLSFPATRQAHLAVRTAEGFVEANAQLRRVVERPWGGGGVWDSAWCIGAGAVKGRG
->UniRef90_A0A2E9K2A4 AraC_E_bind domain-containing protein n=1 Tax=Alteromonadaceae bacterium TaxID=1916082 RepID=A0A2E9K2A4_9ALTE
-MVLVSKTTDSTAMNEPEPALVQFEGVKLAQLVHRGSPQTLMASVGAFIQWRKLNGSPPSQSRTFNIFYSDPLNTEPAAFTFGIAAEHSKDIAPNSQGVSEAHIPALHCLSWIETGSDGKLQQRIEQVIGEGGYDWHFEQFPPFIERLHFYPDVPMAEAISRVYLPVQAQ
->UniRef90_A0A8T1N0L7 Fibronectin type-III domain-containing protein (Fragment) n=1 Tax=Clonorchis sinensis TaxID=79923 RepID=A0A8T1N0L7_CLOSI
-MSITLDRLDECSETWMGIFAINFAGDSPVSPLVKLISPSAPTAPNDVRFNVDRRTRKIHITWKDTSVCPTTNYTLSDVQKGWLVTTVNREAYLDFGVPCYHYQIHIKGANTGGQGPASDVIRFFTPHNFDAPTNVRVTTEPSVPDVEVSWLATGVCHSIQYMVTLYVAGVIVKTEVTESLNVILRDLEKCKPSSITVKKYTQWWSGDESGRTEFQIPGVPSAPKLIGATTEQNVPSATVSWTYDGACTSTDFLVTVYATAESVPEPVRASGLSTSIGGLPMCVDLVFGVVGRNQFGSGQETKSSPIRIDAVPSAPKLIEATTEQNVSSATVSWTYDGACTSTDFLVTVYTTAGSVPEPVRASGLSTSIGGLPMCVDLVFGVVGRNQFGSGQETKSSPIRIDAVPSAPKLIGATTEQNVPSATVSWTYDGACTSTDFLVTVYTTAGSVPEPVRASGLSTSIGGLP
->UniRef90_A0A843CS01 PAS domain-containing protein (Fragment) n=1 Tax=Methanomicrobium sp. TaxID=2052684 RepID=A0A843CS01_9EURY
-MTVKEITKVLEEALMGNYSVRVNVDEAEDELKELAETVNTAIEFIIDSKRTCDNVSMMIQQNPYPMMLLDRNFMPIDVNAAYEKLMGYSKDQILTMLASDYKSRRISGDNTETLFTAGHNTETLVEIDFKDGRKLFVEQRGVPLRDSDGNVEMGLFVFKNVTNEVIEKEEITKQLEQIKVLQGRSEVIVQENPMPILLCDKNF
->UniRef90_UPI0004174C5D hypothetical protein n=1 Tax=Mesorhizobium sp. WSM3224 TaxID=1040986 RepID=UPI0004174C5D
-MPFTVIWYGRSGIVDKMSFDAEKAARDYAMSMFQTRKGDDGIVAVEVRKDNGAVVFSHSEN
->UniRef90_A0A1N6TYF1 Putative signal transducing protein n=2 Tax=Marinobacterium stanieri TaxID=49186 RepID=A0A1N6TYF1_9GAMM
-MLVTIARYTYPYEAQIARALLDSEGIDAFIADEQTINMQWLYSDALGGVRLQVAQEDVMRAQRILQDDRETPLVELEGEDRPACPVCGSRDTEYYQIGRRWAFLMFLAIDFPLFRVQDGIRCHSCGAISKQHSDAARH
->UniRef90_A0A7Y4ZJH0 3-keto-5-aminohexanoate cleavage protein n=1 Tax=Polyangiaceae bacterium TaxID=2268199 RepID=A0A7Y4ZJH0_9DELT
-MSSHDAHYAGELVDGARMLALFGDLATELLIRIDGDEGLFRAYESVEFLAPVLAGDYIEASAELLTLGNTSRKMAFVAKKVVSNLRAHGVSPSAAEVLDEPLVVCRAIGTCVTPKSLQRRPKGLYMPGLPPGPEPEASPIVTPVSNDVILTAAIVGAEVTRAQTKYLPITPQEIADEAARCREAGAAVIHLHVRNDDGTSTQSKERYAEVLEAIAKKTDCIVQTTTGGAVGMPIEERAGPLACKPEMATLNCGTINFGDDVFVNSRPDIRKLAKLIREAGSIPELECYEVGHVEEALALFREEHIQAPLHFQFVLGVAGGIGAREENVHYLRSLVPPEATWGVAAVGRHQVPMTELAMRLGGHARVGLEDNIYLSKGVLSEGSAPLVARAAAFAREIGRTPADPTRARQLLGLTK
->UniRef90_A0A0N5BVH2 Calponin-homology (CH) domain-containing protein n=1 Tax=Strongyloides papillosus TaxID=174720 RepID=A0A0N5BVH2_STREA
-MTDNRLTEIPQIIIEKMKLLETLILAKNVIKTLPTCMKGFNSLNYLDLSSNNLTTIPSAIYSLPLQILLLSNNKLDTVSGDIVQMAPTIQELDFSKNRITSITSNISLLKQLRKLNLRSNRLGALPSEMASLDLYSLDISANRLTHIPVEFCSMQSLIHLSILDNPLLSPPIEIVLKGREHIFKYLQSAISSDVDYRGNYTDWSTNRNSFINATIRRPKNAEKVAAKAKRFAALNSSDSGYTSTGDDQRHSYDMEFSRNSLASIDENHKKETIIINKEYNGCLNNDDEGVDLSHTPKDVRKLNLIEECNDVNNSNNNNNNDINMDSSIYTTLASVTVTDSTYIKPNNIVVKDKEPKNEENPDSVLESTSPTTSESHSPLSESMASLSSPDGENNSTLVIESPNVKDNSNILVPISSNESPPKASNNRTLKPPTKKSPPSKVQSKLSVPSQGKSTLLIKKEPTISKLMKPSITTAIPTPRISKLTPPKKSMSISSSRSTTPSTPISPSNDDDVELMKKLLGSKLLAVTKEDEISKQLSSGVLLCNFVNKLKPRTIPVVMASLSPSQPVPLPKAKKNAENYVNAAKKLGLSEVCFTIFIISSF
->UniRef90_A0A1H1DUL9 Lipoprotein n=2 Tax=Pseudovibrio sp. Tun.PSC04-5.I4 TaxID=1798213 RepID=A0A1H1DUL9_9HYPH
-MVGTQVANTLLKNTGRALLLIGIGASLAGCGSIMSSDSDLEASSSEAPATERTFDLSVLQAPAMCPSLQELSGTTILAKYPRGKEKTPENLTFQAVITDWARTCKRVGKDSAMKLGIAGNITPGPAWKGGEIFLPIRVAVTNEVDDVEKTTYSKLFSVPVTLGAGSPSATWAFVEEGIILPNETGQNVVFGFDEN
->UniRef90_UPI00097132DB hypothetical protein n=1 Tax=Herminiimonas arsenitoxidans TaxID=1809410 RepID=UPI00097132DB
-MKQVLNIFIVGSILLSSQPVFAQSTTTVEADSQSYSVSALTERYPANSIQSSTAASSALADVTKARSFIESRFAAGQRACYKEFFTNSCLAKVKEQKRADLAVIKPIEIEANAYTRHAKVAESDRRLAEKAAQSEGRATASTQNKTDAASGKSTEANDLTKDAQRKVRAENYAKKNADYAERQKLLRENEQADAKKRAENVERYEAKVRESEARQKEVAAKKAEKAREQANKQ
->UniRef90_UPI000FD9191E proton-conducting transporter membrane subunit n=1 Tax=Rhodobacterales TaxID=204455 RepID=UPI000FD9191E
-MTTAFSLSFLAPVLLIAAALAAFRTPGRRPGAVPQISEVAALGALGLVALGLIQVIVAGPAVSSLFDGAGVLALRADPVSATLALLVAFIGWIVLRYSRTYLDGEAREGAFHGLMLVTLAAVLIFVMSGSLWLLVAATIATGLGLKRLLLFYADRPEARRAAAKFGLVWHGGDAALIAAALVLTSAHGTGDLSAIAASNGGAGIAGHMAAGLLVLAAILKTACFPLHGWLTEVMEAPTPVSALLHAGIINSGGVILIKTAPLVQTSPGAMAALVMIGGFTALFGAAVMLTQSAVKTSLAWSTVSQMGFMLLQCGLGLWALALLHIVAHSLYKAHAFLSSGGAVAAVAAIRKPGPVAVPDLGAVLKSFGLALLLYAAIAGLFSVAIGPKTAQALALGAILVFGVAYLVAQGLADTAPAELTRRTVAASLAATLAYFSFQAVAQWVWGADLPAAPAPGPLEWALIVLAVLSFGMVALAQSLFPLWAHHPATAGLRVHLANGLYLNALLDRAIGGFRTTKSS
->UniRef90_A0A8J4S172 DNA ligase n=2 Tax=Phytophthora kernoviae TaxID=325452 RepID=A0A8J4S172_9STRA
-MPAEDERAALRLSFGALCRVLEKLERTPKSDAKLRLLFSDALRAQLGGGDLYPLIRLVLPQLDRDRTYNLKEKMIAKIYIDVLGMASASKDAQKLEHFNDPNVIASKYVGDFAAVLYEVLLYRSLARDRQNERTLQDIIGLIDALEQADSSAMRKKVVMRLATEFSASEQKWIVRIVLKDLKVGLRHERVLNFLHPDAMKMYNHTNDLHKVCTDLRNSAVRYVPQLEPFRVFSPMVAKQVTFGECITAINADTFVMEPKLDGERITCHVQGKQVQFISRNGVNYTELYGTSMTPHVLSQLMPGVDCILDGEMMVWDNTEYQFREFGLLKNVANAMRNGDATNRWLCYTVWDVVYLGGSPKAESLIHEVFKGPREVSAVMGLPLHARRKLLLRILSPLDHRITIIEQTAVNAKSPKERHDIVMAEVDRQISNGGEGVIMKDLNAHYMCGESSRRAKKWLKLKPDYAGMTTDLDVLIIGGFYGTGRRRSGNVSAFLLGVLAQSVDENAAAETLKPGASCPMVYTFARVGTGYNLEELEQMRQELDPYWQPWDDNNIPPHLNGWKPQKYYLKPDLWIDPRHSKVLEVYGFELTYTTLYQTGLTIRFPRCKSIRNDKEWYQCINLQDLNAARGSLSIKRAGEIALGQKSTAKRAPKRQVLRARRAGGVLANYSQAALDGLEQECDVFEGKEFCVLPGKYDAPPPNSVSAIPSGILEEHAKHMSKQMVEKLLHSFGGSIVQNPIAESTNYVVAAGDAGFKVVNLKKQGHFNIVHISGSPPITAATGNDYGTSDRVQVEQLQPIVRKLRHQGLQEPPTVTKEWVEQSVEQRTQLPVEKFFVAM
->UniRef90_A0A239J7H2 Amino acid ABC transporter substrate-binding protein, PAAT family n=2 Tax=Streptomyces TaxID=1883 RepID=A0A239J7H2_9ACTN
-MSERSSLSRRGFLSRTAAVGGLAAVPGLLAACSRTQAGTGAPTGDGDLLATLRKQGYVRVGFAGEAPYGYRDGNELAGEAPTLHGEIFTALGVPELRPTLTDFGALIPGLTADRFDVVSAGMAITPDRCRKVIFSEPEFVSPTALMVREGNPKGLSDLLSCAREKATVGVLSAAVEADYADAAGVPLTSVKSLAKQQDGVDALLADRIDAFALTGISLRWLARTNDGAAVEVLDPFLPVVGGRRQYSPGGAVFRPGATGLRDAFNKELGKITADPGRYTSLIGKYGFTKAEVPPATLRTAQLCKA
->UniRef90_UPI001877F83B 2-oxo acid dehydrogenase subunit E2 n=1 Tax=Microbacterium sp. YJN-G TaxID=2763257 RepID=UPI001877F83B
-MIAEFRLPDLGEGLTEAEVVQWLVKPGDTVALNQTLAEVETAKAVVELPSPYEGTVSSLHADAGETVAVGAPLIAFDIGGDTPDSEPDGDEAATGEAADGGSAEKDAAPDAEKAQPNLVGYGAQPASSGRPARRVRRGGAGATATADAAVIEAAPHDALPPSAAEPAVGERPRSTPPVRAHAKRLGIDLVLVAAQVGDRVITRADVDAYAERVGAAAPVGTEQDAEMVPAAPPAPRGERAQTRIPIKGVRKHTAQAMVRSAFTAPHVTTFHTVDVTATMELIEQLRADRSLAEHRIGPLVVVARAVCLALGRNPSLNATWDEDAGEIIQNHFVDLGIAAATERGLIVPIIRDAERMSLPELADALQQLTQTVRAGKTGPADLAGGNFSITNIGVFGIDAGTPILPPGQSGILAVGAVRRQPWEHRGEIALRQVMTLSVSFDHRLVDGAEGARFLKDIADLLEQPGRAMLF
->UniRef90_UPI0004BB0B65 T9SS type A sorting domain-containing protein n=1 Tax=Alkaliflexus imshenetskii TaxID=286730 RepID=UPI0004BB0B65
-MKLRLSLLAFLLVLAVDGMLGQQVWFFSEGTGATFYDQGIVDVANLGGSSFEYTHPPGLPQFNDKVPCSATAWSGSTSLKFNYTSAASGNWKATIYRSDWSVADITGMEFLGFYLYAGSGLPASALPKIGLVANRLGGGGDATSLLYDLSAHNDDVPADQWVEVKIPLSVFIEDGGNALLDFTRVKGVVFSQSEVNGVPRLLFIDDIKAFVSMDVVPPVSQLKAEGFDSHVELRWQQPLDFLSYRIYARYAGSEDYVQIAETDKDYYLHFVPQSARNTEISYKVEAFSQDKESDAVTIQATVRDFTDEELLDMFQRYTFRYFWEGAHQPSGMALERTNGDGRTVASGATGMGLMAMVVAYERAYEERAEIKTRILKILEFLENCERHKGAWAHWYNGDTYQTQPFSSLDDGGDLVETSFVAQALITLRNYFRDEDAQSVQIRQKATLLWEAIDWNWYRNGNQNVLYWHWSPNHGFAMNMKIQGWNESLITYVMAAASPTFGINKETYTQGWARNGSMVNPRTYYEHPISLSPNWGGPLFWIHYSHLGLNPKGLSDQYADYWQEHVNTAKIHHAYAVNNPLGHQNYSENNWGLTASDDPFGYTAHEPMNNDNGTISPTAALASMPFTPMESMKALKYFYRERGADLFGLYGPYDAFNDNMGWVQKSYIGIDQGPIVVMIENHRTGLLWKHFMADAEVQAGLDKLGFSYQATSAAPGLEHSELINLFPNPAVDNVSIELPHHLVGRQIAVAIYATDGSQVYSSVFESSETIYTINCSAVQNGFYLLKMVSGSRVYRAKLIIRK
->UniRef90_A0A6I9VL36 secernin-1 n=6 Tax=Bactrocera TaxID=27456 RepID=A0A6I9VL36_BACDO
-MSATGDCFIVQSPNTAENTIIFGRNALDADALTEAQEVQYYNANVALEGKPDGGADVVKANGEILRMILQKTQTGIWGGDVGANDHNVCIAVSWSAEEPANDSDTLRSTDIVRLTLAIAKTAVDAVERIGNLVANHGSDNAKFSFVVCDTKEVWLVSSGAKLWAAHQVADGFLRLTNKGLSVKTAIDKSTDDLGDALKTLGLWDGEGDLNFASCFDAAETAEAEWSGEAPNGDGSYTLTSMFDTLRSAADSATSRSASVSVLTNGISCHWFTATPNASESVFKPFVFAPNPKISPLTKVPPDNTHTLLHKLHAQRKPNAVEDLKALEAACVEELNAYLAEHPNADEELDELMKDCVEAEVKFYR
->UniRef90_A0A2Z5ZAZ3 Uncharacterized protein n=1 Tax=Nitzschia sp. PL1-4 TaxID=2083272 RepID=A0A2Z5ZAZ3_9STRA
-MIYINFNILLNFFLILYIFFIYTLQVIRPEIVTDTDVMLMSLLVLYNWVLVIQGWKFDPIMLFSQYILILLILTLEWENIRLRGFILILKKIINNK
->UniRef90_UPI001BB17932 GATOR complex protein DEPDC5 isoform X7 n=1 Tax=Microtus oregoni TaxID=111838 RepID=UPI001BB17932
-MRTTKVYKLVIHKKGFGGSDDELVVNPKVFPHIKLGDIVEIAHPNDEYSPLLLQVKSLKEDLQKETISVDQTVTQVFRLRPYQDVYVNVVDPKDVTLDLVELTFKDQYIGRGDMWRLKKSLVSTCAYITQKVEFAGIRAQAGELWVKNEKVMCGYISEETRVVFRSTSAMVYIFIQMSCEMWDFDIYGDLYFEKAVNGFLADLFTKWKEKNCSHEVTVVLFSRTFYDAKSIDEFPEINRASIQQDHKGRFYEDFYKVVAQNERREEWTSLLVTIKKLFIQYPVLVRLEQAGGFPQGDNSTSAQGNYLEAINLSFNVFDKHYINRNFDRTGQMSVVITPGVGVFEVDRLLMILTKQRMIDNGIGVDLVCMGEQPLHAVPLFKLHNRSVPRDSRLGDDYNIPHWINHSFYTSKSQLFCNSFTPRIKLAGKKPTSEKTKNGRDTSLGTPKESENTLPIQVDYDAYDAQVFRLPGPSRAQRLATCRSVREQENHNRKSASSCDVSSSPSLPSRALPTEEVRSQASDDSSLGKSTNILMIPNPHLHQYEVSSSLGYTSTRDVLENMIEPPQRDSSAPGRFHVGSAESMLHVRPGGYTPQRALINPFAPSRMPMKLTSNRRRWMHTFPVGPSGEAIQIHHQTRQNMAELQGSRQRDPTHSSAELLELAYHEAAGRHSTSRHPGDSMSLNFGATEELSASLLSNSGAGLNPRTQNKDSPEDGVSTSPDPMPGFCCTVGVDWKSLTTPACLPLTTDYFPDRQGLQNDYTEGCYDLLPEADMDRRDEEGVQMTAQQVFEEFICQRLMQGYQIIVQPKAQKPSTTVPPPLSSSPLYSRGLVSRNRPEEEGQYWLSMGRTFHKVTLKDKMITVTRYLPKYPYESAQIHYTYSLCPSHSDSEFVSCWVEFCHERLEEYKWNYLDQYICSAGSEDFSLIESLKFWRTRFLLLPACVTATKRITEGEVHCDIYGDRPRADEDEWQLLDGFIRFVEGLNRIRRRHRSDRMIRKGTAMKGLQMTGPISAHSLESTGPPVGKKGTSALSALLEMEASQKCLGEQQATVHGKSSTQAAESSSVAMTPTYVDSPRKDGAFFMEFVRSPRTASSAFYPQASVDQTAALVSDSASLGVSTCQSLDRGSNQTLGNSQNIGEQAFPSANSDCSAQQHAASSLTSSSTLVEILEAMKHPSTGVQLLSEQKGLAPCCFISAEVVHWLMNNVEGVQTQAMAIDIMQKMLEEQLITHASGEAWRTFIYGFYFYKIVMDKEPDRVAMQQPTAPWHTTGVDDFASFQRKWFEVAFVAEELVHSEIPAFLLPWLPSRPASYASRHSSFSRSFGGRSQAAALLAATVPEQRTVTLDVDVNNRTDRLEWCSCYYHGNFSLNAAFEIKLHWMAVTATVLFEMVQGWHRKATSCGFLLVPVLEGPFALPSYLYGDPLRAQLFIPLNLSCLLKDGSEHLFDSFEPETYWDRMHLFQEAIAHRFGFVQDKYSASAFNFPAENKPQYIHVTGTVFLQLPYSKRKFSGQQRRRRNSTSSTNQNMFCEERVGYNWAYNTMLTKTWRSSATGDEKFADRLLKDFTDFCINRDNRLVMFWTNCLEKMHASAP
->UniRef90_A0A317JBS3 DUF2959 domain-containing protein n=1 Tax=Chlamydiae bacterium TaxID=2081524 RepID=A0A317JBS3_9BACT
-MSLKEECKQLSDLFHRAAEGQSIDLQQVFAQSLQFFERLKVELKEEDPQRRQEAMAMLMEIYQHMIKDTKLICETSGMTEEQLVSFAENPTNFSPEQWASIQESREKISHAGQDLAKALEQLSSSQGEKKPHDPTKKSKKSDWMRS
->UniRef90_A0A8J7MXB5 Tripartite tricarboxylate transporter substrate binding protein n=1 Tax=Candidatus Odyssella sp. TaxID=2589116 RepID=A0A8J7MXB5_9PROT
-MAAVAVAASALAVSTVAQAAWPERPVTIIVPAGAGGGTDATARLLAKQLQDELRQPFNVVNQGQASGLVGHTNISQARPDGYTLGIIYPYYQFNLSGQSQLDHSSFTPIALYNMDPSALSVAANSQFRTAQEALAFIRANPGRVRMSCGGSCGGSWDLPLAGLLVRLGIDPRTVVMVPSGGAAPGLQELVSGGVEMIACSLPEAAALISANRVRPLMVLASERAGNFPDVPTAREATGQDHTGGAWRAVAGPPGLPPEVVATMERTLERIWRSDEFQNAMRQRGFGLRWANSRDTAAFLLQHEREWTDGMTALGMVRRAPR
->UniRef90_A0A661CEU1 Ferredoxin (Fragment) n=1 Tax=Gammaproteobacteria bacterium TaxID=1913989 RepID=A0A661CEU1_9GAMM
-TQVTLYNTEQLLASDRQTQGLISQQTQQFAQIAEQRSQSDSGGGFGGFLKGLVSVAANVFLPGSGVIAGALVGVVSDVVQGKDLDEALIGGAKDIVGEHCPPCAPAMDVAEGLVQGKEPGDILLNVAKNQLGNYCPECTPFVDVADGLLTGEDPLTTLEHFAKSQLGDACPECVQVWDTAKGIAQGVPPEQLITDLVGHQIGQQCPDCMPAVQAIQGVVAGQPIETVLQNSIGTQLKTYCPECAPVVDIAQQVVAGESLDHILGQAATQALSQSCPECLPAVAVVRSLANGQSPITVLKQALAEPLQTACPSCGTLFEVAEDLAAGKDITDTLTTAAQNQVATVCPECVPAWQTAEKMLQGDDPKTVISALVTDKITEHCPDCAPTLDMVQQIAQGKNPLELVVETTQRQLAKDCPECGEVLQTIIPIAQQAAFDTKQKVLAHLQSQRYNAGFSKEISETLNVSKELMETLQNFL
->UniRef90_A0A2N0DCP7 TPR_REGION domain-containing protein n=2 Tax=Rhizobium sullae TaxID=50338 RepID=A0A2N0DCP7_RHISU
-MRTRPDQLDENILTLFNRACRQSRWEVAEHLLRALEASSDEGDGCEPPCVRSPLTDAYLSIASLHSKQ
->UniRef90_A0A819ZRA3 G_PROTEIN_RECEP_F1_2 domain-containing protein (Fragment) n=1 Tax=Adineta steineri TaxID=433720 RepID=A0A819ZRA3_9BILA
-MPLNIVQLDLIGRYLNIYLGSFMLIAGLLGSCINLWLFTRHRFRKSSCSRFVIASSLFDILHLIVALFLRVLADGFGKDPASSSVIGCR
->UniRef90_A0A533XQ95 DUF3108 domain-containing protein n=1 Tax=Nitrospirae bacterium TaxID=2026887 RepID=A0A533XQ95_9BACT
-MKRVFSQTPSMIRLVGFILTMLLMVGGFMEASGTAEESDQKADAIPAGDYVLYDQVVTRKFLTSATQLVVIDRMTRLRLSPDQEGPTTIDTFQEQGYFDGELPADLVREFSAVNRQPSRLEGRFHFGVGYRFATGDTIEEPEVSLARPVTVARARPVQAPSVLDRLAFSRVARSLLNDDALLYVEALRPDGTGAGFLVWFRRQGGSLTLFDTEVAWAIQAQVEPEEGPLLAP
->UniRef90_A0A7C1TM52 OmpA family protein n=1 Tax=Gammaproteobacteria bacterium TaxID=1913989 RepID=A0A7C1TM52_9GAMM
-MHARTRFVVLFLGAMLAVSGCATDEYGRPREMTDTEKGAIIGAATGALLGLATRREAKYGVLYGIVGGVAGGAVGAYMDKQKKDFEKQLAPELDRGVIYMEKLPQNRLLVGMTAATAFEVDSTRIKPGFNPVLDKIARILNKYGKTHLTIIGHTDSTGSRAYNQKLSERRAEAVKQALLARNVIPERITTAGAGEDHPRASNATPEGRRKNRRVEIIIEPIVEPEG
->UniRef90_UPI0005283947 DNA polymerase III subunit gamma/tau n=1 Tax=Bordetella bronchiseptica TaxID=518 RepID=UPI0005283947
-MTYLVLARKWRPRSFDTLIGQDHVVRALTHALDTQRLHHAWLFTGTRGVGKTTLSRILAKSLNCENGITSKPCGQCRACTEIDAGRFVDYLELDAASNRGVEEMTQLLEQAVYAPGAGRFKVYMIDEVHMLTGHAFNAMLKTLEEPPPHVKFILATTDPQKIPVTVLSRCLQFNLKQMPPDAIVGHLQAVLGEEQIGFEVPALRLIGQAAGGSMRDALSLTDQAIAYSAGNLSEEAVRGMLGTIDQRHLVRLLDALASGDAAGVLAVADELAVRGLSYAGALADLAVLLSRVAIEQRVRGALPQDDPLTEDITRLAAALHPDAVQLFYSVAVHSRGELTLSPDEYAGFVMACLRMLALNGEAGPATAVQAPRADTTPRAAAPAAAAPAETRPEPTPAPALAPQAAAAPRAVARSESKPQPAPEPEPAPRPAATPVAATPPAVAEPEPVAAPAVQARAAEPEPAPAPVPPWEDLPEAVAAPAPAQPAAAPAPVAADDDGPPAWVDEAIPDEAGGGFVPEHSFTADPDDEFETLAPAAAAMPAPRAPTPRRESGGRGRAARSRLADMSPTGWPELAARLPVTGLAAELARQSEWAGVQGDAVLLRVAVRTLAESESRVRLQTVLCEHFGQGLRLEIEVGVTGDGTAHAVAQIERAARQQAAEDAVAVDPFVQALVADFGGRVVPGSIRHVDNPPAA
->UniRef90_A0A0B1P2W7 Putative rna binding protein n=1 Tax=Uncinula necator TaxID=52586 RepID=A0A0B1P2W7_UNCNE
-MGEKTSSRNHQSRKERKAKKRAVENSIPDIPTPELELEPEPVSLATKSAEEVKQLQLDNSLNANEPQGNKRKRNKDGNGESGDNDEEEIDKKKKSKKRNKNLSNKEAKFCEVLKNSVSEATRENINYKNNGEEQRYSPLVKDEGKKKEKKKDSKTKKSNSIIATNNTEEGSSPLLDQEKSSSQKSSKKERKTAKLNVVALKHDHLQNGKNSDDHSGNENMDISKEGLKDSTSTIVTTTTITPPTTTTTSVDEKISKKKKHKKKNSQDPDQSIPKSTSTIIQNTNLPSKRSIKKTSENLVEKVSSSPPRGKSRFIVFVGNLPYTATKDSIMSHFSKLKPLSVRHLTKKEDSSKSRGIAFVEFENFDTHKTALKIMHHSIFDDGKSEPRMINVELTAGGGGNTEDRKTKIKVKNEKLNEERIRRVEEDKAKLKKEEEKKSGLGKESSLKDDQNSSESHIHPSRRRMITA
->UniRef90_UPI001E8E8CDE uncharacterized protein n=1 Tax=Fusarium flagelliforme TaxID=2675880 RepID=UPI001E8E8CDE
-MDGPSHSTLPLNPVSVFFSKSSQPALFWSEFPSWASLSLPSLLFSPLFCFALHCASILESWSCVASITFVTSSAPTSTLIPQLHQPPSKRLINFCFTSQRKEDQDFTTSASYYTPSRPRHTASRVPLVVQPHLAVATRLIVLHNDETDFSTTPSETLSLPQYRKTVIVRVRTAEHSEAC
->UniRef90_A0A369W8G8 Formate dehydrogenase subunit gamma n=1 Tax=Pelagibacterium lacus TaxID=2282655 RepID=A0A369W8G8_9HYPH
-MALQDPGPDAAAQTRNIIADMTHLEGPLLPMLHAVQAAFGHVPQEALPVIADTLNISNAEIHGVVSFYHDFRRAPAGRHVLKLCRAEACQSMGSEAVAAKLTALLGVRSGETSPDQAVTIEPVYCLGLCSCAPAALLDGEPIGRLDDERIVAIVERVRP
->UniRef90_A0A7I8XJZ7 (pine wood nematode) hypothetical protein n=1 Tax=Bursaphelenchus xylophilus TaxID=6326 RepID=A0A7I8XJZ7_BURXY
-MEDGVEEKAWSVVWYGNMHKGFDLTHFGMGFIHLNLKFAVTVDAPEYDAIPTAHLAFHTSQMSMAGAVAS
->UniRef90_A0A6M4IS34 M42 family metallopeptidase n=1 Tax=Gemmatimonas groenlandica TaxID=2732249 RepID=A0A6M4IS34_9BACT
-MLSESSVAFLKRLLDTPGPSGFEGAPARVWRAEAATFSTVKADVVGNSLATVEGSGGPTILLAGHIDEIGVIVTYIDENGYIYFEPIGGWDPQVLVGQRMRFLGRNGDVFGVIGKKPIHLMKPEEREKASKITDLWVDIGVKNKAEAMEHLEIGDAGVIDARVMEMPNNRIVSRAIDDRIGAFVVLEALRRYAAKPGAARVIAAATAQEEIGYAGGGARVAAQQLDAKMAIAVDVTFATDHPGVEKKELGEHNVGGGPVLTRGSIVHPVVFRLLADTAKKLEIPYSVHAAGRFTSTDADGIHLTRDGVATALLSIPNRYMHSPNELVSLDDLDRAADLIAEACRAVTSETDFTAR
->UniRef90_A0A836I9D3 60S ribosomal protein L22 n=18 Tax=Leishmaniinae TaxID=1286322 RepID=A0A836I9D3_9TRYP
-MVAVRAKVGSRSHIRQKQLAKGKKVFKIDCSIPAADGIFSEDVLGNFEQFFQDNTKLNGRKGKLTEKVRLTMKDNVLIITTTMVYRKKYFKYLTKKFLKKKDLRDWIRILSTGKGTYQLKYFNIQDQEE
->UniRef90_A0A8S9ZRV0 Leo1-like protein n=1 Tax=Meloidogyne graminicola TaxID=189291 RepID=A0A8S9ZRV0_9BILA
-MDMENFENGKIIPSQIRNFTVKDFGNSNEAKIELSKPHEELSIHGGRNLFIGNSSGSSSNKNRSRKRNDDNESNEPENCDELPPRQQRRNDGSSESDN
->UniRef90_Q8GPG3 Dimethylsulfide dehydrogenase subunit beta n=5 Tax=Rhodovulum sulfidophilum TaxID=35806 RepID=DDHB_RHOSU
-MVKRQISMVLDLNKCIGCQTCTSACKLQWTNRNGREYMYWNNVETHPGPGYPRNYEHSGGGFDEEGALKIGITPSAEDYGIPWEYNYEEALMTGTDPWLRPNVKPTWGANWNEDEGRGEYPNSYYFYLPRICNHCANPGCLAACARNAIYKRQEDGIVLVDQERCRGYRYCITACPYKKVYFNEQISKAEKCIFCYPRIEKGLPTACAKQCVGRIRFIGYLDDEAGPVHLLVERYKVAIPLHPEWGTKPSVFYVPPLAPPRIGDDGEPTEETRVPLAYLKELFGEAVVPALETLKTERAKKQSGAESELMDTLIGYRHPEMFKLS
->UniRef90_A0A3N6CGQ7 ABC transmembrane type-1 domain-containing protein n=46 Tax=Paenibacillus TaxID=44249 RepID=A0A3N6CGQ7_9BACL
-MGKSFDLSLVLDFIPELLRYLHITLIVLGGSIVLGLVGGVLLAIPRLYRIPVLSQLATLYVSFMRGTPILIKLFLVYYGLPELLKPIGIDLSRTDPLLFVIVTYALSDAASFAEIFRGAVRSVDKGQTEAAYAAGMTTFQSFRRIVVPQALIVAFPNMANTLIGSLKDTSLAFSIGVMDMVGRGQTLISATSHALEVYISLSVVYYVIVIVLEKGFAFAERRLQRHERKRVVHKPAIRAKRLKEVVQKVRF
->UniRef90_A0A1F8MA83 Ovule protein n=1 Tax=Chloroflexi bacterium RBG_13_51_36 TaxID=1797625 RepID=A0A1F8MA83_9CHLR
-MGNEVGNKAEKNGESSTNQADNKVNQSLGLKYLETDQKRNLGLAGTNLEATQKLPPKHVETNLETDLETNRKLTRKPDPKLTQVDSNPDICGN
->UniRef90_A0A285JE01 Two component transcriptional regulator, LuxR family n=2 Tax=Arsukibacterium TaxID=336830 RepID=A0A285JE01_9GAMM
-MHKVLLVDDQKLIRDGIKSLLGLSGKVVVVGECVDGSGVLTACSQLQPDVILLDLSMPVMNGVQTLASLKQAGVSTPVLILTTFDEHELVLKSISYGARGFLLKDVSLETLVQAIATLADGGSWFAPNITERLLGSIRQTSDAGFSMPAQLEPLSDKELEILQLMAAGYSNKEIAAALYKSEGTVKNQCSAILAKLGVRDRTRAVLLALELGLIN
->UniRef90_UPI0008F89955 permease n=1 Tax=Haloprofundus marisrubri TaxID=1514971 RepID=UPI0008F89955
-MSVVDQLVSAAELVIGMTWETWWALVLGFTLSGAVEAFVSEERMTDLLGDDGWREATLGTAFGAASSSCSYSAVGTARTLFKKGASGVAALAAFMFASTDLVFELGLVMWVLLGWQFVLGEYVGGLVAVVVMVAIFRYVVPQSWFDHARERVRENDDEECAACGMDADGDEAVYADAFPDAVFCCEGCLTAYENRTDAAGETSLRERVFSVAGWKSAASATTKDWEMLWDDIAIGFLIAGVVGAFVPTTWWTALFGADGSLEAVAVNVVIGVVIGILTFMCSVGNVPFALVLWTNGLPFGGILAFIYGDLLIPPLVNLYRKYYGWRLAAALSLSLFVSAVVAGVVVHTLFDGLGLIPTQGTVGGTLSGEYTTVLNLALTPVFLAQVYVTFGRDGVERRLAAGAAKLLRLAEWVVGTVAVLGTATGVVAGVVDAFGDVLHDAGDRARESVRHARVRALRRVRGREMPSPGTADATAEQTESDE
->UniRef90_A0A251SHM8 Ovule protein n=1 Tax=Helianthus annuus TaxID=4232 RepID=A0A251SHM8_HELAN
-MNLRTCNKVDTVLRMHLLMNHITRRSNRIWVMGYTGMKVDTEVTVDTVVMVDTGVKVVTVYTIDLGMKLDTVDTKNMVDMVMSPVTHHFMNHLPRAIHFK
->UniRef90_A0A081IBZ0 THO complex subunit 2 n=10 Tax=Plasmodium (Vinckeia) TaxID=418101 RepID=A0A081IBZ0_PLAVN
-MSLNFSDDDIYENKGDEIPYENNLNEDIENNEVNFNGDPYGDEYADEFERNANIEEEEQKEKKKKKTITFQLKNLFNETALKQINSDINKKRKNEKRNSYNDDYSNMMDQDEFEEQYSDNDELKKYVQDEKNKIKQLVDEKDELWDMYIYLNLKKKKRKIDYTEERYTSAIKKVLDSFCSEYKNMVIENLFKNKIFEKYLIVSDIDIFFKNNNIENVYKNTTTPVINKKNSLLEIKKRLVDIYNKGNCFNYLKEVSVDNRTRLNGVAEDEYGFENDESINEDKNEYMFNDNSKRGELDTNFIIEREKINLKINKLEHKYIKLIQTVKQYKRKHLRTNFNLFMNLINEVTSKLYFSIHNVLLMNDGENNLADIYKTIRRKYNIHDVLNKVQNLTQKKEVYEHYRSYLIYKYKSTYPICNNTFKNHQMEENINIFNFKKTYNTKFTNNFSLLQDENDLGDEHFNKVENSTSANKTDINANNNMNTNNKKVEENIFAQDIYEEDFFNIDTQNKESDIKTDSWEDREKNNETHPNTNSFASTKQDTQNKLNTPNEPTTIEETPLERAKRIAREKKKKLMESQAKIL
->UniRef90_UPI001C2DB369 hypothetical protein n=1 Tax=Catellatospora tritici TaxID=2851566 RepID=UPI001C2DB369
-MSEQNIADAQIVVKSDMGRNHELEFDYDIVVVAGERGRQLAAAQAESILEILEPFGPPAEPSDRPGPEPDETSSRAELM
->UniRef90_A0A1V6QLK6 FAA_hydrolase domain-containing protein n=2 Tax=Penicillium TaxID=5073 RepID=A0A1V6QLK6_9EURO
-MSSINIPWTRLVRYSSSADGPVKYGEPVASPNADLGQLANEGKLQVKQLSGSDPFSLQTTDVTEGVFCLYGPLAPKDVPIIRCIGLNYKTHILETGRPLPTCPTIFTKPGPAVADHDSPVPIPTIAQEQCDYEGELVIVIGRDGKNISEADALDYVAAYTAGNDVSARDWQREAGKAGPVPQWGFSKSFDKYAPLGPCLVRQDQLNEANNLSLRTLVNGEVRQDSHTSDLCFGVRKLVAFCSQGQTLQKGSLIMTGTPGGVGLFMKPPNFLKDGDEVSVEIENIGTLRNIMKFEE
->UniRef90_A0A0C2I283 TPR_REGION domain-containing protein n=1 Tax=Pseudomonas batumici TaxID=226910 RepID=A0A0C2I283_9PSED
-MSTRNWPRHLLCLSLSLPLGSALACGPDFPLRLLEDRAQSLADLPETNFQFEVNRLGEAVAGLKPATEATLTPYWDSDDNTKPYREQRDKVEASELPENLRAEVARLRNLADPQQVETEGASLPAELRLYIAGAVAFQSGDAQRAVDYFRQVLALPADQRKLRSTWAAYSLGRALVALSAQAEAGVDTPADSAAPVVTSPELQAQARLAFQQTRALSAGDFSDPLELGIASLGEEARLARFDNDWNRAIALYASQSRLGSNSGYTSLKQVAGELARLPDDELGALLKEKNVQALLTAYVLSRVGGFFDEQPEADQRLSRMVLASVAGSLDNADRLAALSYQKGDYAGAKAFVGHAGDGGLAWWVRAKLALRDGDKVQAAAAYAKAAKAFPKDEVWGPRRAPDWSFESIQPGCRVQGESAILALDRGDYLQAFDQLYRSQDIYWLDAATVAERVLTLDELKTYVDAHVPAPPAAKPEDKDNYVRRPVAAQLRELLGRRLLREGRYDEAPKYFDSPELQATARDYGRDRQQAVSRWTATGRAESLFAAATLARKSGMEILGYEMAPDYRALDGYYSLGAAELKPGPFLETAEVQRQQASVAKPDRRYHYRWVAADLANQAADQLPHSSQAFAAVLCKAANWVAGSDEEIQYYQRYVEQGPYVSWAANFGRQCQAPDFDQANRRYLTQPLNSVRSALRPYKVALVVGGLALFGGLAALWVRRRKAKL
->UniRef90_UPI001EF2088A response regulator n=1 Tax=Actinoplanes cyaneus TaxID=52696 RepID=UPI001EF2088A
-MAEDDPDIREISLLLMRRAGHRVISAEDGAQGWRAVLFHDPDLVISDVDMPEMDGLELCAKIRGNPATELTPIIFISGVLMPDDDRVITAGATALLHKPFTAAEMLSCVNASLAAGAKAGRDTK
->UniRef90_A0A7Y2JY00 TetR/AcrR family transcriptional regulator n=1 Tax=Massilia aromaticivorans TaxID=2725995 RepID=A0A7Y2JY00_9BURK
-MRQKTEAKRQAILAAAGAVFREHGFETSSVSDIAARVGGSKATIYSYFPSKEALLMEVILSAAETRSVTVFSEVLALGDVVTGLRRIGEAHLSFISTAEAVALARLAITAGERSTLGREFYTRGPLVMIENLAAFLAASIARDELRPGDPRQMAESLKALYEAGIVERHLLGDLKGLEGVDLAVHAAQAVDIFLAYYGKA
->UniRef90_A0A1R3UIW8 Inner membrane protein n=2 Tax=Nocardiopsis TaxID=2013 RepID=A0A1R3UIW8_9ACTN
-MNFNSLSALAFRVVAVFEAFTWVGLLVGMYFKYLGNGSELGVQIFGPLHGGAFVAYGLVALLAAYRFRWGAWPTLVALAASVPPLGTLLADWWLHRTGRLDPERAETVRTPEPVA
->UniRef90_A0A222G883 Uncharacterized protein n=1 Tax=Cognaticolwellia beringensis TaxID=1967665 RepID=A0A222G883_9GAMM
-MEANKLARLSCLFEKAVANNAKLLEKHELDELYNEFINDGRDHIKNTVVAFPKGLRRTAS
->UniRef90_UPI00190B6181 septal ring lytic transglycosylase RlpA family protein n=1 Tax=Paraburkholderia TaxID=1822464 RepID=UPI00190B6181
-MSNGQELVTSAPVTPRLIEGSPPMLVAGAENRLDAETPPLPYNHGHVAHFWQSGLASWYGKVFHGRRTASGEQYDMYALTAAHRTLPLGSYVRVTALRDARSVVVRINDRGPYARGRVIDLSYVAAAALGLSRTGTMRVRIESVGKQDSQRVALDCKCTEVETGG
->UniRef90_A0A148KMI4 Alginate lyase n=2 Tax=Paraglaciecola hydrolytica TaxID=1799789 RepID=A0A148KMI4_9ALTE
-MLLTPCSYSATDTHQNTLPASHSALAEGELLGDFTKLDPSKKPSENFDLEDWSLTLPTDLNKDKKADMIYEKPLSSGFELKPLFYTADDGGMVFACPNVGAKTSNNTKYARTELREMLRRGDTHIKSQGITGNNWVFSSAHGSDRRNAGAVEGSLEATLAVNRVSTTGDEKMLGRVIIGQIHATDDEPIRLYYRKLPNNNKGSVYFAHEINGGDDVWLDLIGSRSHTLADPEDGIELDEKFSYKITVENDILFVTLVRQGKTNITQSLDMSQSGYNKSNQYMYFKAGVYNQNNSGDPKDYVQATFYHLDNQH
->UniRef90_Q90X71 carbonyl reductase (NADPH) n=2 Tax=Anguilla TaxID=7935 RepID=Q90X71_ANGJA
-MSTNKVALVTGSNKGIGFAVVRALCKEFPGDVYLSARDVDRGTAAVENLKTEGLNPFFHQLDITDPASVRHARDFFKEKYGGLDVLVNNAGIAFKVADSTPFGIQAEVTLRTNFLATRDLCNEFLPIIKPGGRVVNVSSGMSSIALKSCSSELQARFRSNDITEEELVMLMEKFVQEAQKGEHTHKGWPNTAYGVSKIGVTVLSRIQARRLREERAGDQILLNACCPGWVRTDMAGPNATKSPDEGAVTPVYLALLPVGATEPQGQFVSEKQVQVW
->UniRef90_A0A5M9QSU3 DUF4134 domain-containing protein n=5 Tax=Lactococcus TaxID=1357 RepID=A0A5M9QSU3_9LACT
-MKKNKIILGISLVGFIASMFLPSFQGIDIKVFDYTKMNYFELVKEKWWIYVLLLIILVLIRTLSIEKSKILSSIFVSGFIFFKLSLLSLENGHLFINGYPVLWGYAVATLFGLLVSFSLLIDTYKDRG
->UniRef90_UPI00146DA424 glycosyltransferase n=1 Tax=Flavobacterium silvaticum TaxID=1852020 RepID=UPI00146DA424
-MKTITVFTPTYNRAHCLTILYDSLLRQTSDDFEWLVIDDGSVDETKQLVQGWIDEGRIPITYKYKENGGMHTGHNTAYAMISTELNVCIDSDDYLPDDGIEKMITLWRRDGSNKYAGMIGLDVTIKGAVIGTQFPEGLKECTYSELAPRYKVVADKKLVYRTEVVKKYEPYPVFPDERFVPLYFPIVIDRDYKVLCYNEVFCIVDYQPDGSTIGIFKSYFRNPKGFAHSRKIEMIYDPFWKRKVKSAMHYVANAIMTKNANFLSESPKKLLTFLSIPGGVALYLYLNRKKNQDRDISKGYKR
->UniRef90_Q9AAQ7 TonB-dependent receptor n=4 Tax=Caulobacter vibrioides TaxID=155892 RepID=Q9AAQ7_CAUVC
-MKKISGLRLCGDNVAALIVRPRVLKKVLEWSASCLQCATSPQSVFAPLSQGGIQKMTNTKTTATAGRRKAFVIALLSGACFAEAALAQSTPAPAADQAAVDEVVVTAFRKSLATALEVKRKDVRVSDGISSEDIGKFPSENIAEAIQRIPGVQISAINGRGSTISIRGLGPQYALTTVNGQAFKSSNFTDGFRYDVIQTELASGIQVYKSPTADMDAGGLAGTVNIDTVHPFDVKGRQIIVAGKLQQQELIGGNPTGKYGLTYVDHFLDGKLGVFLGGGYQELKDRGDYLWMDRWTVSNNVYTPARLRYRRIDRETKRSMINGAVQWKPTEHLQMDLIGTYAEDKTTQNIHQQVFLFTTPSASNVVPITVANGTSTKVQVNNFRLENNQQYENRPQSTSALTTKLHYTGLENWDFNAVAHYSRGNAKHNEEAAVLGINIPSATVDIADPKNVIFTTSTALTNTAQYAPTTLIRNTYPTGAFRTVGSHESAAQFDAKRYLDWGILESVQVGAKTRSEVLKRYVIRKDNQVVPASFSPTMANSGIAVTNFLDGQMTLPNAWVSPNLDAYREALKAQGISVYEGFDPLGSYRVERDLTSVYAMANLRGEVLSKSYRANIGVRNESTDQTIKGYIGSTANPQNTEVRLAAGNYTAKKSYDNLLPSANLSVDLTDNLLLRVAAAKVLVRPIIDSSNQLARTMTSATDTTGRRIFTISSGQGNLNPMTANQLDLTLEWYYGQGNGLSAGYFSKKVKNGVFSQLTCPTSYESVALSRDSSGVCVAANGDNYMITESFNDSRVVDIHGYEVNWQQSLDAWLPIEGFGLIANYTHVTPAKSTTGFRLANLSEHTANGTVYWENQKFSARLSANYRSAYDQTSVESFFAGPLGHTIKARTQLDLNLGYNFNERLSFAFAAMNINNAQEEAYLINASRWQETAVTGPSYFLSFQYKM
->UniRef90_A0A1J5H2U3 DUF3598 domain-containing protein n=1 Tax=Oscillatoriales cyanobacterium CG2_30_44_21 TaxID=1805292 RepID=A0A1J5H2U3_9CYAN
-MRSQWECLLKNLGNWKGSFARLNPQGAILEDIPSETILELKEDRQTMRQTVRRFIDGQPQDLVLEYQNLNKSTTFFENGAFSQGSPQFAPYAEFGTEMGLIDGDRRLRLVLLYDKAAQLDRITLIREHLAHSENSQPPILTLHDLLGKWEGEAITIAADWSEPEVIATKTEWNQNGDRVTMSLQMGTQSLTATAFINPFQPQILTFPQDQVQTLFLPDGASLTCPVAIAPRQSFRLSVSWLLEPNLHQRMIRAYDAKGAWSSLSLVTERKTM
->UniRef90_A0A157SJD7 Acyl-CoA transferase n=8 Tax=Bordetella TaxID=517 RepID=A0A157SJD7_9BORD
-MSQRSAPLTGIRVLDLTRVLAGPWCTQNLADLGAEVTKIERPGAGDDTREWGPPYLKDEHGNDTTEAAYYLSANRNKLSVALDIATPRGAELVRELAAQSDVLVENFKVGGLRKYGLDYDSLSQINPRLIYCSITGFGQTGPYASRPGYDFMIQGMGGLMSITGERDDLPGGGPQKAGVAVADLMTGMYSTVGILAALHERARSGLGQHLDMALLDCQVAMMANQNLNFMTSGKAPRRAGNAHQNLVPYQVFAARDGHLIVAVGNDSQFRNYSRVIGLPELSADPRYATNPQRVQNRDTLVPLLAERMATGERDRWLAELEAAGVPAGPINTLDQVYQDPQVLARNMRLELPHPTAGKVPMAASPLKFSGSPVQYRHAPPMLGQHTRQVLQERLGLSEDDIQALAQPRA
->UniRef90_A0A223S709 Alpha/beta hydrolase n=1 Tax=Nocardiopsis gilva YIM 90087 TaxID=1235441 RepID=A0A223S709_9ACTN
-MGLPVVLVHGLRLSGTMWRPQQELLEAQGRRVVAVDLPGHGTRRGQEFTLPAAIDAVAEAIDAVGGRALLVGLSLGGFVSIAVAAAHPGRVAGLVAAGCTARPAQTLAQVYRIPAVLLDRLPDHGQAVNERFHRLTLPTDGAAAALDGGLAMEAARAVIDEISDMEVLEALGAYEGPVWLINGARDPFRIHERQFLEACVDGRLLNVPRAGHMVSLDQPENFAKLVGDIADVASVRAAEAPPGAARSHGPGV
->UniRef90_A0A8K0DS69 DDE Tnp4 domain-containing protein n=1 Tax=Ignelater luminosus TaxID=2038154 RepID=A0A8K0DS69_9COLE
-MDAILKLKKVEKLSKLVKLKRLHEHKNKRLWSREWLLRRDSKELGACSFVEHELQEEDYNLYKNYLRMDKCVFEKLLRLIEEDIAKQDMQFRKSISPRFRLMITLRFLATGETFTSLSYSTRVGVSTLSTFIPEVLSAIYKNLCKLYLKVPSTTQEWKTISNEFLTQWNVPNTVGAMDGKHVVFRPPKSAGSHYYNYKGTHSIVLLAIVDASCRFLYIDVGTNGQISDGGVFEDCDFAVELNRHSLNIPEDTPLPGMTIPVPHVLLADAAFPAQQHILKPFPMKDMTKHQRIYNYQISRGRRIVENAFGILVNRFRVLLNPISLARDKVVLITQACCVLHNYIKTESHEQIIKAQDSENIKKITIQLYIMLHTPEDVQVSDILSHENNLKNTLIIMVQYLGRITKHNVFIIV
->UniRef90_UPI00177E212B Fe-S biogenesis protein NfuA n=1 Tax=Blochmannia endosymbiont of Colobopsis nipponica TaxID=2681987 RepID=UPI00177E212B
-MIDITNIAQEHLTKLLSQQKPGTQIRIFVIEPGTYNAECGISYCFAENINPSDIKIRFKSFSVYINKTNLPYLKDTEIDLIFNQTESQLTIKAPNARMCQPNDDAPLDKKIEYILQSKINPVLAQHGGSVKLIEITKDMSAIIQFSGGCNGCSMVNLTLKESIEKELLQKFPELKKICDLTEHQHGKHSFY
->UniRef90_UPI001054CDFC AAA family ATPase n=1 Tax=Occultella glacieicola TaxID=2518684 RepID=UPI001054CDFC
-MGRTNYLIEGLSGTGKTTVCDELQRRGHHAIHGDRELAYRGDPETGRPTAGFGHEHHIWDVDKVRALVADREHAATFFCGGSRNFSKFIDLFDGVFVLRVDLATLNRRLDERPDQEWGGGQPTERDRIVHWHRTNTDVPANGIAIDATAPVERVVDEILRRCETDR
->UniRef90_A0A146FHF8 Short-chain dehydrogenase n=1 Tax=Aspergillus kawachii TaxID=1069201 RepID=A0A146FHF8_ASPKA
-MTRTWVVVGASRGIGLEFVRQLASSGERVIAAVRSLSSAEQLFGLLSQYTRNGAPLITVEECDVTKPDSIDDFSHNVEKAVRDGGLRLTNVILNAGINQYPNRATEMYAYRP
->UniRef90_A0A0A0MRI8 Obscurin (Fragment) n=3 Tax=Hominidae TaxID=9604 RepID=A0A0A0MRI8_HUMAN
-AGKTMAIAAQGACRSLTIYRCEFADQGVYVCDAHDAQSSASVKVQGRNIQIVRPLEDVEVMEKDGATFSCEVSHDEVPGQWFWEGSKLRPTDNVRIRQEGRTYTLIYRRVLAEDAGEIQFVAENAESRAQLRVKELPVTLVRPLRDKIAMEKHRGVLECQVSRASAQVRWFKGSQELQPGPKYELVSDGLYRKLIISDVHAEDEDTYTCDAGDVKTSAQFFVEEQSITIVRGLQDVTVMEPAPAWFECETSIPSVRPPKWLLGKTVLQAGGNVGLEQEGTVHRLMLRRTCSTMTGPVHFTVGKSRSSARLVVSDIPVVLTRPLEPKTGRELQSVVLSCDFRPAPKAVQWYKDDTPLSPSEKFKMSLEGQMAELRILRLMPADAGVYRCQAGSAHSSTEVTVEAREVTVTGPLQDAEATEEGWASFSCELSHEDEEVEWSLNGMPLYNDSFHEISHKGRRHTLVLKSIQRADAGIVRASSLKVSTSARLEVRVKPVVFLKALDDLSAEERGTLALQCEVSDPEAHVVWRKDGVQLGPSDKYDFLHTAGTRGLVVHDVSPEDAGLYTCHVGSEETRARVRVHDLHVGITKRLKTMEVLEGESCSFECVLSHESASDPAMWTVGGKTVGSSSRFQATRQGRKYILVVREAAPSDAGEVVFSVRGLTSKASLIVRERPAAIIKPLEDQWVAPGEDVELRCELSRAGTPVHWLKDRKAIRKSQKYDVVCEGTMAMLVIRGASLKDAGEYTCEVEASKSTASLHVEEKANCFTEELTNLQVEEKGTAVFTCKTEHPAATVTWRKGLLELRASGKHQPSQEGLTLRLTISALEKADSDTYTCDIGQAQSRAQLLVQGEAAKCARA
->UniRef90_A0A5A9P3B1 Leucine-rich repeat and calponin-like proteiny domain-containing protein 3 n=1 Tax=Triplophysa tibetana TaxID=1572043 RepID=A0A5A9P3B1_9TELE
-MAASVLHSAESAVPSFTVGHPARATGIHGLSNAPGPGSWNRSLDRALDEAAATGVLNLSGRKLKEFPVIVNFLSKTTHYYLSRNRLPELPVEVCMFVSLENLNLYQNCLRSLPESLINLQSLTYLNISRNQLSTLPAHLCRLPLKVLIACNNKLVSLPEDLGKLRHLTELDVSCNEIQTLPPQIGQLETLRDLNIRRNHLVRLPPEVAELPLVRLDFSCNKVTSIPVCYRNLRQLQSIILDNNPLQSPPAQICIKGKIHIFKYLNMEALVKRKRKNRLLNTPELSCNCLSSVERERKKERDKKKDRGVAEDLGDKRWSGNEASGFQPVEGRSQLASAPILNYACLLITQLMSLCVLTLSSGESRCTHTHSVRESRVQCFYSCRCGCVCKRVAGVTSGSEKQISAERRCYELRQADYLLTSQTFTMGRWHRTHDVCMVFQLCVCEHNKSSPSPTKLSPTDTCYLKSHVSCSISESVPLQTVHSHRRLRPLYGKSQSNRNFIVKRTQSLRLKHTYTGEEADLIEQLRRNIECRLKVSLPSDLGAALTDGVVLCHLANHVRPRSIPSIHVPSPAVPKLTMAKCRRNVENFLEACRRIGVPQKQLCLPLHVLEERGLSQVAGTVQALLDMAPPKQTSSFTL
->UniRef90_A0A1C6D475 Translation initiation factor IF-2 n=4 Tax=Eubacteriales TaxID=186802 RepID=A0A1C6D475_9CLOT
-MAKLRVYELAKELGKESKDVLTVLASKNIEVKSHASSLSDEQVDMVRKSLSPKAQVQSQARPQSQVQRPSAPAGEAAAHAPEARPQQEVPKKKPNIIQVYNPQNSQQASLNRQSGRPQAGRPGQNPRPQGQRPMGSQQGARPAQGQGQPGTRPVQGQGQPGTRPVQGQGQQGTRPVQGQGQPGTRPVQGQGQPGTRPVQGQGQQGTRPVQGQGQPGTRPAQGQGQPGTRPVQGQGQQGTRPMQSQGQQGARPVQSQSQQGTRPAGQAGNQGVRPNGSYQGNQGQRPQGQQGSQNRPAGASQYNRPNGQQGNSSQRPAGNQQSYGSNRPYGQQNNNGNRNTAAGQGQRSGQGQYNRPAQGDRPNGRPNQGSGQYQNQGSGQYQRNSQGQGGQRSGQGQYGNRPYQGQNGRPQGQNNRSQGTRPGGAPSMRDGLTIPKPPQTKATEKQNVTSRAERGDRNDRSRDKDRNGRNDRRGYQDNRPNQRNMGGKGRNNAPAPKPVQQEPKEVTIRTIILPETMTIKELAEKMKVQAAAVVKKLFLQGSVVTVNQEIDFEKAEEIALEFNCIAEAEVKVDVIEELLKEEEEDPATLIPRPPVVCVMGHVDHGKTSLLDAIRNTHVIDKEAGGITQHIGAYTVSIDGQKITFLDTPGHEAFTAMRMRGANSTDIAILVVAADDGVMPQTIEAINHAKAAGIEIIVAINKIDKPSANIERVKQELTEYELIPEDWGGSTIFAPVSAHTHEGIDNLLEMILLTAEVCELKANPKRRARGLVIEAELDKGKGPVATVLVQKGTLHVGDSIAAGSSYGKVRAMMDDKGRRVKEAGPSTPVEILGLSDVPNAGDIFVSPENDKEARNFAQTFISEGRERLLEDTKAKMSLDDLFTQIKAGNVKELGIVVKADVQGSVEAVKQSLLKLSNEEVVVKIIHGGVGAINESDVILASASNAIIIGFNVRPDATAKNTAEREGVDMRLYRVIYDAIADVEAAMKGMLDPVFEEKVLGHAQVRQTFKASGVGTIAGAYILDGIFQRNCTVRLTRDGVVIYEGPLASLKRFKDDVKEVKSGFECGLVLEGFNDIKEEDLVEAYTMVEVPR
->UniRef90_A0A315BXB9 MFS domain-containing protein n=3 Tax=unclassified Limnohabitans TaxID=2626134 RepID=A0A315BXB9_9BURK
-MMFGNVVIGTGVMMAAGTLNDIVDSLSISVATAGQLISSSALLVCFGAPVLAAVVAGWDRRKLLVGSLLWYALWHFLAALSPGFYSLLGFRAMAMLAAAIFTPQAASCIGLLVKEHQRGQAMTFVFLGWSVASVLGMPLGSWIGGHFGWRWSMGLIALLSVIGAYWLWRQMPSKVLPPALSGAAWRQTLTSRTIWVTLSVTMMLAAGQFVLFSYLAPYVKERFGVSPAQFSLMLLAYGSMGFVGNALLSRFIDRIGPSRCILISLSSMCLSVLIAGEVTHATGMALALGFWGLGGFSSNSAQQARLASQAPWLASASISLNTSAMYAGQAIGATVGGWTIVHQGMSALPQRGLIGLLLAIGLSLLATRYARLHPLRSPEKA
->UniRef90_A0A2N7D5J4 Flagellar basal-body rod protein FlgC n=2 Tax=unclassified Vibrio TaxID=2614977 RepID=A0A2N7D5J4_9VIBR
-MSFTDIYSIAGSAMTAQTVRLNTVASNLANADAVSANPDDAYKALKPVFATVYNKSQLSAEQALYPNAEVRIVDVVQSQSQAEQRFEPSNPLANQEGYVYYPGIDVVTEMADMMSATRSFETNVEVLANVKSMQQGLLRLGEGR
->UniRef90_UPI001CF99253 hypothetical protein n=1 Tax=Pseudomonas sp. L5B5 TaxID=2883205 RepID=UPI001CF99253
-MLQTLWVLLNWEAWGESLVIAFIPFLLFVWVGALVTMLVLRFRGRISIFWASQLAGGVAGVAATLAFMMAANFVVDYKAYRESVRQLEAQERLQPKPESPNVETQPVELAGGMAGLESMKIFMALLSYRADSKRLRESDRQLGEKELLQTQKTSQTVEVQSVSSPENVLGEVSDSSGHR
->UniRef90_A0A8K0MZ08 Auxin-responsive protein n=1 Tax=Cocos nucifera TaxID=13894 RepID=A0A8K0MZ08_COCNU
-MATSASIGVAGKELGVISEASSPLKRYNGLRPLLGSKQMASFAAMRKPNGPFPSLPSLKSPRIRAVASPTVAAPKREKDPKKRIVVTGIGLVSVFGSDIDTFYNKLLEGQSGISLIDRFDASSYSVRFGGQIRDFSSKGYIDGKNDRRLDDCWRYCLVAGKRALDDANLGPEVLQSMDRSRIGVLVGTGMGGLTAFSNGVEALIQKGYKKITPFFIPYSITNMGSALLAIETGLMGPNYSISTACATANYCFYAAANHIRRGEADIMVAGGTEAAILPTGVGGFIACRALSQRNDEPQKASRPWDKDRDGFVMGEGSGVLIMESLEHARKRGATIIAEYLGGAITCDAHHMTDPRSDGLGVSSCIVKSLEDAGVSPEEVNYVNAHATSTLAGDLAEVNAIKKSMIGHCLGAAGGLEAIATIKAITTGWLHPTINQNNLEPDVTVDTIPNVKKKHEVNVGLGEQDLTEELWRLCAGPLVEVPRVNERVFYFPQGHMEQLEASTNQELNQKIPRFNLPSKILCRVFNVQLRAEPETDEVYAQITLHPEPDQSEPTSLDPCPPETRRPMVYSFCQPRRHLLTTGWSTFVTSKRLVAGDAFVFLRFTGTVVGVEDVSSQWTDSKWRSLKVQWDEATNILRPDRISPWEIEPFNTTAPTLNAMHPVLVKNKRPRLPMDMVGYTVLEPTSPFWYSGTTHSHELDGLSSVDANSSATQVIWPCMQKENKGNGVKNGPGSCDPMVLDDWLKGLHSPIKSPPASLTDVSLKLFQDMNDETKVASWPVNPGSMMEQQPVLKLGNGVEEWKKPEVRSSSCRLFGIDLMNHSKSTTVSEKAIAAPAFTKSIAPIEGPSKATASVDESDQQQSGLSKASREHKQGLDSSPKEIQSKHHGSTRSRTKVHMQGMAVGRAVDLTNLVGYNELITELEQMFEIKGELRQRNKWEVVFTDDEGDMMLVGDDPWP
->UniRef90_A0A2E7GD31 50S ribosomal protein L18 n=1 Tax=Bdellovibrionaceae bacterium TaxID=2026715 RepID=A0A2E7GD31_9PROT
-MSVKVRKRTDKKKVVRFKRKRKIRSTVEGSSERPRLCIFRSNTNVYAQLIDDQKGHTLASASTKDAELKDQKSTVEGAKQVGALLAKRAQAKKIESVVFDRNGYLYHGRVKALADAAREAGLKF
->UniRef90_UPI0011841962 trans-aconitate 2-methyltransferase n=1 Tax=Catellatospora sichuanensis TaxID=1969805 RepID=UPI0011841962
-MWNPETYLRFADERGRPFHDLLARVDAEQPRQVVDLGCGPGNLTATLTARWPGAQVRGIDSSPEMIEKAVADQGGPGPVSYQVGDVREYLPGPEVDVIVTNAVLQWVPGQEELVGRWARALRPGAWLALQVPGNHDGPAHRALRELCASSRWSALLGEIAEQPRSVPGSQEYARLLRAAGCAADTWETEYVHQLPVTGGPHPVLTWLTGTALRPVRAALAEQPGAWEAFCVALEPALISAYPADGAIVDFPFRRVFAVGRRTAAPS
->UniRef90_A0A0M8PST9 Uncharacterized protein n=1 Tax=Lysinibacillus sp. FJAT-14222 TaxID=1932366 RepID=A0A0M8PST9_9BACI
-MSRLGQHDVGHEGVITRRDAFSLRSSMCSLQGLIFDANPQGVAQSQLQSTNSYSMYPLPIAII
->UniRef90_A0A7Y9F3N0 YtxH domain-containing protein n=1 Tax=Nocardioides marinisabuli TaxID=419476 RepID=A0A7Y9F3N0_9ACTN
-MSRGLWFVAGAGAGVYAMVRGRRAAEALSADGLRDRAGALALGARMFRDEVAQGRAEAEDQLRQRLAAARPREIDSPHPTERTTEQEGTS
->UniRef90_UPI001967ED96 hypothetical protein n=1 Tax=Janthinobacterium lividum TaxID=29581 RepID=UPI001967ED96
-MQQDSGTAKAVPLNYFYRGVTVSKKQKTIVNHRSAVSGRFVTERYVKSHPATTVTEHNRISAPAKPLKRR
->UniRef90_A0A5A8ADR5 GNAT family N-acetyltransferase n=1 Tax=Chryseobacterium sp. SN22 TaxID=2606431 RepID=A0A5A8ADR5_9FLAO
-MEHLTNFTYSDIKSELFRLKSKEMKANFFMTELQFNRLWSENKIQVFKTEKACFLLTDDDGFKRLYFIASDIEEIKYFLNNEIKNSDTDISVETVGNSKYLQDIRDAFLQNGFYEYSSMVRMSKIRNQVEEVDFENIHLLAADNKEEFQELYRKYFDKFVERIPAIEEIEGFIENKNAYYFSDNNEIQGFIVFEYYGITSHLRYWFVHPDYREKRIGSKLIQLFFNLGENIRRELFWVIESNENAIKRYKHFGFVEEDMHNLILINKNKKYEEPNY
->UniRef90_A0A2D7PFG9 NADPH:quinone reductase n=1 Tax=Candidatus Pelagibacter sp. TaxID=2024849 RepID=A0A2D7PFG9_9PROT
-MKKIFIAFGHHNTKNSFNASIRDTFIEEAKKCGHNIDLVNLFDEQEKLPFYNQNINPPPQLVLDYRKRLEKCDVMMLIGSCNNLRLNAILENWIDWVLHPKWFFTYRSLLPGNKYFKNYGYPVAGAMKGKLGVVSITYGGPMISYQSFSFFDNIPYRRLKKSVFQLGGLKTKYLRFYSILPEMEKKEFENHMLKVRKFAKSL
->UniRef90_A0A415FL20 DUF2953 domain-containing protein n=2 Tax=Ruminococcus sp. AF46-10NS TaxID=2292072 RepID=A0A415FL20_9FIRM
-MTAVQSFLGIPSKIFKKIRNLTLTIKKFCGKINWYKEFINHAQTRAALSLVWKDGKKLVRHVLPTRITGKITFGCEDPSITGTVLAVLGMTIPFHKNAIAVTPLFDSENVLEGEVMLKGRIYGIMLLKTAAELYFNKHIKYVIHRWRHKEVNHGERE
->UniRef90_A0A7G8QAU1 SmpA_OmlA domain-containing protein n=1 Tax=Dyella telluris TaxID=2763498 RepID=A0A7G8QAU1_9GAMM
-MSKLSISLSIALLASAGLGTPAVASAESLLVNRVQQEKTMDLPSRGMSMAEVEKKYGAPQRKLSPRGGGSSKQPVINRWDYSNFIVYFEQSHVIHAVLNTPAGNNTNPASAN
->UniRef90_A0A6J4UR21 3-oxoacyl-[acyl-carrier protein] reductase n=1 Tax=uncultured Thermomicrobiales bacterium TaxID=1645740 RepID=A0A6J4UR21_9CHLR
-MSDRARFAGKVALITGGGSGIGAATARLIAAEGGSVAVLGRTAATVKATATAIGGAGGRALAIAADVSREEAIDAAFTRAIEAFGRIDVVVANAAVQLHRRDLPIHEQDFAAWRETQEVNLGGAFLTCRAGVRQMLAQGEGGAIVIVSSVTALAGTAAQNPSYTASKGGLVSLSRALAVKYAPDHIRCNVVCPGALAAPPDVEEIDNAARERRLVGQIPLGRLGDFAEIAPMIAFLASDEASYATGGTFVVDGGLTAT
->UniRef90_A0A8T9LM70 LytTR family DNA-binding domain-containing protein n=2 Tax=unclassified Dyadobacter TaxID=2625061 RepID=A0A8T9LM70_9BACT
-MMNTKQLTAKIVIVDDEFFVRQTLVSMIANIPNAMVVGEAEDVGSGIELILEKEPDLILLDIKMPVRSGFDLLEELTHCQQQYGLIFVSGYPDEALTAVQKAAPYFHSDFVVKPIDPVILQTKFSIFYNKWQAAKEQESELAGLLETGIPQIAYKSDQLVFQNSQLFHCIDIDDILYCESANRQINVYCSQYEHINIPNTTLDAIERMLPADAFIRIGKSHILNKSAIRFIQKGNRPKCILARNGKSYEVQLYASNVEKVEQSYSITRK
->UniRef90_A0A811MPR2 Rep_fac-A_C domain-containing protein n=1 Tax=Miscanthus lutarioriparius TaxID=422564 RepID=A0A811MPR2_9POAL
-MGSSEDDFTPLSELTVGMNKCRVRVRVSRLWESFNPKNDISFGLDCLLIDDQGETMQARVLPDYIDQFEGQLIEGKTVVNEIEGDIDSIPLHSFEFIDFKNLHSMCDDISILRDVLGHIVYVGDLQEVEKKSRTIEICNATIQNLSGRKLGVTLYGDIACGFAEDMLEKGQKASGVAVFAGMRVESSHSVCSTTCSKYYLDLEIPEVQEFCENLSIQQENPVSEKSQAQKLAESWRTIEQLKRLNPKDYDEDTKFLCRVSLIDIDCTSGWCYLGCNTCYKSMYRAPRKYKCSRCGPIKRPINWYKLKTMVQDATGTMNLMIFCEVAEELVGVSAEELVDEIEDDEEWFTLPDEIEDLLGSTHTFQVFDKHLSGSFSVYAIMDDDTVPVPAATTSQCKEESVPEGSVNAAVPSPATTQCKAEPGMAAPAPAMIPCKEEPVLEENFSMVVPAPTTKHECKEEPFLEHSVNMAVLKPTITQCKVEEPVPKGSAGTGEARLKSTRLQKPNKRLLGDDWIN
->UniRef90_A0A5C7TQB5 Conjugative relaxase n=1 Tax=Rheinheimera sp. TaxID=1869214 RepID=A0A5C7TQB5_9GAMM
-MLSIQTLGTMTKDKVAYYTELAATGYYTEAEEPAGQYFGKLASVLNLDQKAVTQEDLLELAKGFDTKGKALVANAGDEHRMGIDLTFSAPKSVSVCFGLAGTELRTAIQKAHESAVKAALTYAEQNFIQVRHGFEDNQQRRMINTGNALFALFEHGSSRSNDPLLHTHAVLLNFSQVKNGEFRCLEAPDLFNYKKALGALYRAELANQLEALGLKTEADEEFFKVTKVPDELCKLFSKRSNEIHDLLQEGGFTRANAKLKQNAALFTRQAKTHQSRETLYKNWAVEAEQISTWKPEQAFTKDRNQNKVDTEKLLESLTEKKSLFTYPDFLEQVFIHFQHAGLSSREAEEFAKATLESKAIRRIQHPQAGICYTTEQQYQLEMSFYKEMTEYLDRWRTAHARCPAFLPAWL
->UniRef90_UPI001A901165 agmatine deiminase n=4 Tax=Halomonadaceae TaxID=28256 RepID=UPI001A901165
-MHPTHCPSSVAPSAATPAAQGYVMPAEFAPHDACWMLWPQRPDTWRLGAKPAQQAFVAVASAIAESETVYVGVNDDQYENARHQLPAHVRVVELSSNDAWMRDVGPTFLVHPDKGLALVDWEFNAWGGLKDGLYFPWDKDRRIRPKIAEMLGIPCFDVEVVLEGGAIHVDGEGTLITTEECLLNPNRNPGMDRATMERRLQDSLGIQKVIWLPRGCYLDETDGHVDNLCCFVGPAEVALTWCDDDTDPEYAICREARAVLEASTDAKGRAITVHPLPQPGPLTIAEDEASGIDRLASSHPRRPGDRMAASYVNFYIGNRVVVMPQLDPRHDATVMDILARLFPDRRVVGVPAREILLGGGNIHCITQQQPRP
->UniRef90_A0A6L8CSU2 VWA domain-containing protein n=1 Tax=Gammaproteobacteria bacterium TaxID=1913989 RepID=A0A6L8CSU2_9GAMM
-MSGPLSPTPPASRMLEFAGYLRRHGYRIGVGELPDLFRLVDRGARDPVLTRRGLRALCCRTHDEWREFDRHFNRFWFPVESEQVAPASVPGGLPDSPGQTLVGLAGTSDREPDSTHGQSDIEGSGAGRQRTLGKADFRFLRDRTAMHEVESLVERLGQQLRRRLGKRREISPRGGHLDMRRSLRRSLATGGLPLKLVWSRPRPVPLHLVVLHDVSHSMTWNNPLLFRFVRGLMQNFRGSVAFAFHTRLFEVTPFFRERSLERMLARLDAGENLWLGGTCIARSLAEFNRHHAGTLLRSDSHVLIISDGFDTDDPEMLRTELSRIRLRCRQILWLNPMLGREGVTLTEASLSARLPEVHRFLPANSLDGLRAAVENLSRTGPRTRPGGTPPVHGQDSRQGDGH
->UniRef90_A0A1G8EYP0 Catechol 2,3-dioxygenase n=3 Tax=Agrococcus TaxID=46352 RepID=A0A1G8EYP0_9MICO
-MPVTGPDFVSLQVRDLAGSQAFYERYLGLERSPAGPPHAVVFTTTPIAFALRDLVEGTDLDASQPGLGVALWLHATDVQQIHDALVADGHAIAVAPFDGPFGRTCTLVDPDGYLVTLHDRA
->UniRef90_A0A1F9IIM5 GlnD_UR_UTase domain-containing protein n=1 Tax=Deltaproteobacteria bacterium RIFCSPLOWO2_02_FULL_50_16 TaxID=1797881 RepID=A0A1F9IIM5_9DELT
-MISWVFNIFGMTVEATRQGMTYLEKKAKPKLIDVAEGTFLAEKAREMHIAMRQLLQNHSVERQCSDVKRRARKRVKENIIKAYDRDDVVDEITVRLTDAAMADSFYKKWFAH
->UniRef90_A0A1F5VQL0 CZB domain-containing protein n=1 Tax=Candidatus Fischerbacteria bacterium RBG_13_37_8 TaxID=1817863 RepID=A0A1F5VQL0_9BACT
-MGIAITGSDMLCKRITEGFVQQQESVQGKVFYSERIETDFDELLQKERINREVPGSWENTQAVRANKVESSVIRGKEECSRLENVMKEFEEMHNRLSEIITYTMNGRQFNAQELLAFQAEMHRITNYIEMVSKIIEQGINGVKHTLQTQV
->UniRef90_A0A2P8AWN7 HTH_17 domain-containing protein n=3 Tax=unclassified Micromonospora TaxID=2617518 RepID=A0A2P8AWN7_9ACTN
-MTTPKRPERGTPRPARHLTIADVCDDLGISRSTFYDWRAKRKGPPARKLPNGEIRIERRDYETWLETLYEEAA
->UniRef90_A0A1M6QX74 Putative addiction module component n=1 Tax=Rubritalea squalenifaciens DSM 18772 TaxID=1123071 RepID=A0A1M6QX74_9BACT
-MATLSELENEVLRLPKDQRVSLIHRILEKSELPENSDVKNLWNAEILERIERLDANSTECHSASDVFQAIDEQFAQ
->UniRef90_A0A1M7QN82 Germination protein, Ger(X)C family n=1 Tax=Gracilibacillus kekensis TaxID=1027249 RepID=A0A1M7QN82_9BACI
-MIRVIVLLIFSILLSGCYDRIELEQQSYVIAIGIDKTEQEGVYSFTYQIANPEIGSAAVQSGPDEPPTEIVTVNGSDILSSTYTANSFVSKKITLDHTKIIVISEELARSEDFIRVIQSASRTPQIRRSVQMLVSKEKAIDFINNNEPIMEKRPHKYYQFMLNRAVQTGIIPKSTLHRFFQITEGDADLFLAIYATTEQSDQKKNTEGFEDKYIAGEIPQIGGSPTQFMGSAVFKEGQMIDILDGEETRVAQMLDKTLEMEDYLATIPDPKMPEYRISYNYYQKKEPIININYYKNKPTEIDVNISFQVEVIAIPSLIMYSQSKKDQQTLQEALTQRLEEKTNALIEKTQNSYKSDAFYWSLYIRKHFKDIKEYEDADWHKNIYPNAKINVTYELEKMEFGKMINDSNLEDVRD
->UniRef90_UPI001E451F19 hypothetical protein n=1 Tax=Methylococcus sp. BF19-07 TaxID=2743472 RepID=UPI001E451F19
-MLWPAWILPEDVFRSIWERVRPVFLASMGQQRIPFTLAEPLARVYLPLAAWVVAHKKDGPFVLGVNGAQGSGKSTLCEFLALILREGYGCKVAGFSLDDIYKTRSERERLAREVHPLLVTRGVPGTHDVGLGLQTLDRLTTAGPEIAVALPAFDKSIDDRCPMSAWPQTSAPVDIVIFEGWCVGCLPQSGEHLVRPINALEAGEDADGSWRTYVNEQLGGPYAELFGRLDRLIMLKVPDMECVYQWRSLQERKLAAAIGNGSSGHRLMDETALRRFIMHYERLTRHMLAEMPARADVTLFLDENHGFARVHINE
->UniRef90_A0A8X7XX04 Uncharacterized protein n=2 Tax=Populus TaxID=3689 RepID=A0A8X7XX04_POPTO
-MNQSSSKTHNQKCPSAALPEQPTKIRRRKKQQHHQPSFRRNALQDLNNGGIDTTSIDNSSNASSLSSIEAPRGCLRFFLSHSSSSSSSAKTPFSSSSSNQRLKKVKPSRTPKSAPSMRPTKEKPISKKVEKGKRNHPPCLYQWQSGKKRASSRNEVGDSKVSSFLDSSGSLVKNKLKSGPGELKKVMIDGVCEGSGANLTPLCKVGSGSGLNLGVGGKVMNDDCYEKSSNGKAESNSTSSNTKTPPVQPSVSPEIQCGSSMKLMTVETITPATCYGAGHVVSGVTDKRKCRPRGILAGGEAKALGSFDSDDDIEQANDVGLIENSDVSMLPLPIDASMHWLLSPCDEKDEGQKDNSRNRSRRFRRLEERAIHNSPASPSSGYGGFSPELCNTSANRSISTVSAGRRSASLLSPSALPVPQFQGFLGTPLCDNFPVSSLEEETENRHCTDGENSPFSIGSLGSGNIIQTPQSDTSCDRRVGASGTQVDGKRKKCNFDSDLNSVAEQLQMTSLSPMSHASVWDPTNSSFRFDSLTMPSNSVDLSKFHKILEERNSWFSNSTIENVSQSQMRISWREGLMSRMFEMDEFDCCRYLSDEEDDGNVCNIDCLKSHKSPQLNVEAATDHISINGIGSTEFVKKEQDTGGKTKDGLPSQPPCSCAESISTDGGGLVRSDDSDWTLWSKDSEVNMGNLIEYIDLAGCGPGGKSQLHYKVDGARGLFADIGFTIFGSLVFEEWLAEVERQSMDKLQEMSQAYLELVANLPCHVRIKGKLSQESVPDLVSSSFVFPLIIREKEEPDRAERGSCVLMEGLIPLVCKAFRKNKTRRQYECLSVGTALSYNISDFYTHEAPKSELHFQPSMENTNSQKKVHRRFWSVHEDFSGGFSSPAVRSTTAASPQTKQLARFRSQRV
->UniRef90_A0A853BRY5 Anti-sigma regulatory factor (Ser/Thr protein kinase) n=1 Tax=Streptomonospora nanhaiensis TaxID=1323731 RepID=A0A853BRY5_9ACTN
-MAQCDGVDDDVGIYTLRACRTFAGAARECREARLWARRHMRPFPDVADAVELVVSEFFGNAVRHTASGQPGGTVFVSLVGLVSGALHLEVHDEGPRRGAPRTTARVLAPDLERPDGRGLFLAAALTKEWGRLPLHGGPGYAERGYTSIFDPDLDHETSDYVGPMITWAEFSTSFRAAPASAAAHHAG
->UniRef90_X0WKB2 GH26 domain-containing protein (Fragment) n=1 Tax=marine sediment metagenome TaxID=412755 RepID=X0WKB2_9ZZZZ
-TGSRPLGEYEPAGTWGSYGINHWLYVAAEDPLYGQAAKDYWGTVNVKGSGNIPLFLDCWFWCGGPENDDTPPAWDGHRILGHTESMNRFCINRHQQGINGVFLDYSARKVWLKELWHVKWARNFNVNYPGPYWETEAPWMAQFKAH
->UniRef90_UPI0012FA07AB hypothetical protein n=1 Tax=Nocardioides alkalitolerans TaxID=281714 RepID=UPI0012FA07AB
-MTTLMLDQARTDDATTAPTDVRDVAGGLEDELFEQAVGEQVAGLTTMPSISTIHCLTSRHDTTLLPRL
->UniRef90_A0A2E0G851 Peptidase n=1 Tax=Candidatus Marinimicrobia bacterium TaxID=2026760 RepID=A0A2E0G851_9BACT
-MIKKNKHIIFIIIFYSLFVESLFSSDTIVYRVPIQGVIDLGLPTYIERIINEAESNQAEAIIFDIDTFGGRVDAATQIKDAILDSDVPTIAFINRRAISAGALISLSCEKIYMTGGATIGAATAVDMSGNKASEKVISYMREEMASTAENRNRNTDIAKCMVDEDLSFTYVIIDNDSIEVTDLEGRKEGKLITLTTEQALKYKMADGLAEDLDELLSLLELSGAEVKTFYENWSENLVRFLTNPVVASLLTTFGFLGILFELQSPGWGIPGTFGAVCLTLSLSASVIVKLATKSDLLIVFFGLSLLMVEAFLIPGFGIAGLAGIGVILWGLYMLLLPDVPVSQEIYDSAMTGLTIGLIGAIIAVILLFRMMTKTKFWIKLTSPGIESSEEGYNTSLGLENLIGETGVATSDLRPSGWVLVNNEKIFVVTEGEFVDKDQEIKILSVDGNRVVVRINN
->UniRef90_UPI0012BBE16F YeaH/YhbH family protein n=1 Tax=Sansalvadorimonas verongulae TaxID=2172824 RepID=UPI0012BBE16F
-MSSIIIDRRRNSKGKSTVNRERFMRRYRRQIQKAVNDAVNSRSITDTDSGEEITISRKSLSEPFFHHGEGGDRDQTHPGNKEFVTGDRFPKPKGGKGKGKGGGGGDASDSGEGLDDFAFQINRDEFLEYLFDDLELPNMVRKELKESSEFAFRRGGFTSAGAPDRLNVIRSLRGAHARRIALSGKDRKEIRALKRELREMEVSPDDTNEARAEEIKLRIKELNEKIKRLPFIDDFDLKFNNLIKVPLPSSSAVMFCVMDVSGSMTRDIKDMAKRFFFLLYMFLQRNYEKVEVVFIRHHAEAKECDEHDFFYARETGGTVVSSALTLARDIIDERYDPKKYNIYVAQASDGDNWEADSPKCSKVISEDMMKNLAYYAYVEITDRHHQNLWHEYKKLEQAHPDHFAMSHIKGPTDIYPVFRELFEKKEAMA
->UniRef90_A0A6A6R4P4 MFS domain-containing protein n=1 Tax=Lophium mytilinum TaxID=390894 RepID=A0A6A6R4P4_9PEZI
-MRLLGESGLISKRRYPCIYTKMVLILLPHFQRLQELCRHRSWNGLLIFHAFWCCSVYHYTVRALFTFLFAMGFSVGSCMSFAIPFNVLDSRCAWLSTSERRAQFVLYNMPGCGVR
->UniRef90_A0A8J4XW43 Uncharacterized protein n=1 Tax=Chionoecetes opilio TaxID=41210 RepID=A0A8J4XW43_CHIOP
-MAIYLFTRQDPSRPHPPAGKKDAVNWDQHAILLEGRKKTPPGVGWSFDSGLTDTSHVRKVAKNAAWKLELHPTRLRTSWTGSGSRHIYKSQVRSLMEYSPLAWSSYPPSYRCLLDRVQARAQRLARLKAPEDAAQIIQPLQQRRDVAGMWGHVQKGHRMQLLQLAELRLNPGPGPPIYPCGPQHRHQGLAIREDGKITSAPSYPAMVDYGTPFGAPDDLTFTPSMHAFKSGVNAWLQEADEALDGDEGWLLPITSHKASRPLHSEPFVPVAWMVD
->UniRef90_UPI001FD5AA06 methyltransferase domain-containing protein n=1 Tax=Nocardioides sp. W7 TaxID=2931390 RepID=UPI001FD5AA06
-MVAQAIPSRIRWAVEFMDVQPSDHVLEIGCGPGAGAEAICSKLETGKLFAIDRSESGVDRTKRRCAKYVASGRLTVRQIDLATLRVPVKRLTKVYAFNVNLFWVRECPDEIALLHERVLPGGAVFLFYEVKFPDQMPTIVEKASAALAGGGFRVSVVEQKTPAVVGVIGRR
->UniRef90_A0A7X8TA91 L-idonate 5-dehydrogenase n=1 Tax=Rhizobium sp. P32RR-XVIII TaxID=2726738 RepID=A0A7X8TA91_9HYPH
-MKAVVIHAAKDLRVEERQEEALEPGQVAIAIEAGGICGSDLHYYNHGGFGAIRIREPMILGHEVAGTIKAVGEGVSRLAAGDRVAISPSRPCGSCEYCLKGQQNHCLNMRFYGSAMPMPHIQGAFRQRLVAEEWQCHKVAEGISINEAALAEPFAVTLHAVARAGSLLGKRVLVSGCGPIGALAIIAARAHGAREIIASDVMDAVLKKALSIGADRAINVADDPQALDAYSTNKGYFDVQFEASGNESAVRSGLGVLKPRSTLVQLGLGGDIAIPQNILVAKEIEMKGTFRFHEEFGLSVDLINARRVDLKPLLTGVFPLDDAVAAFEAAGDRSRNMKVQLAF
->UniRef90_A0A1F6CIC4 SsrA-binding protein n=1 Tax=Candidatus Kaiserbacteria bacterium RIFCSPHIGHO2_01_FULL_53_31 TaxID=1798481 RepID=A0A1F6CIC4_9BACT
-MELIKNKKAHLKYVPLENFSAGIELIGQEVKALKNKLGSLEGARVVVRGGEAFIVGMTIPAYQAANAPKNYDPERPRRLLLAKAEIAELAAAESKKGLTSIPFGVYTAHNFVKAHVAIVRGKGKADRREDLKKRDAEREAGRILKNR
->UniRef90_A0A3M1TVI0 AarF/ABC1/UbiB kinase family protein n=1 Tax=Deltaproteobacteria bacterium TaxID=2026735 RepID=A0A3M1TVI0_9DELT
-MLDAFGRVEVNRKTVEFAGLSATGYVRGGRAAPREEHAPGTPSVSKSSALRTVYANLMATRTAIRDVRRFRQIAGVLARHGFGFLFSRFSRKDPEVAKAVDEALQEAPSAPQVPQALPYAQLARRARAALEDLGPTFIKFGQILSTRPDLLPQAFCDELQNLQDDVPPMSIEEVNAVIRRELGSEPTEIFAEFDETPLAAASIAQVHRARLKSGEEVAVKVQRPGIAAIIEADLDILYFLARQLTVAVPETRLFDPPGIVREFERAIRKELDFSAEARHMKKFARNFREVDYIHIPEVYDRYSTAKVLTMEFIEGVKITDAVEQGLADGEVLAKRLLWALFKQFFQDGFFHGDLHPGNIYVLPGNRVCYLDFGLVGRLTPEMKDRVIDLLFAVGRQDFDALARVLFEMGIREGPVDYDAFVADVYEVAERYFDGTPLAEIDVGGLFRELVEGAMRHHMRMPTTYTMVFKALMTVEGLGKRIAPEMDLVEEAQPFIAELLRERYSPERLWKKASEALYTTSRLLRQVPPAMTRVFEDIDAGRLTFQIDAPRLDDYLEDRRRSDVMWGTGLAYATLMICATLALSWDEYRILGFPALSFIGYLLALPTGLWFFNHWWRR
->UniRef90_UPI00210E2C07 response regulator n=1 Tax=Stutzerimonas stutzeri TaxID=316 RepID=UPI00210E2C07
-MDIPLSQRLSFKQASLTVLLALTLGGAFGLTRAVLDYASERDGINRKAQALLTVTTAAADHALREQDARLADQLVHGLLQAPAVLRAELRAADGTPLAIASRHPTESGWRRRLSDRLFGAELHLTLPLADGRGSQHLLLDTWPHGQRFLRRAGLGLAGGLTSSLLLSLALLGLSHLLLTRPLGSLVAALGSRDAQRSARTPLPCPAGHRHDEIGALVGACNEQLARLDSEIAQRRAAEEHLTRALGELEGRVAERTAELERANRELLASNRELQLAQRTTQEMAQARAHFLASMSHEIRTPLNGLLGMLALALDSPLPPQVRQQLGIAHDSGRGLVELLNGVLDLSKFEAGQLELERIPFDLASLVEDTASLLAQNAAPGVELTCLIAPDLPGEVIGDPLRVRQIVSNLLANALKFTRHGRVDLRLIANPDGILLEVRDTGIGIAREALARIFQPFAQAEAGISRQFGGSGLGLSLTRRLCEAMQGTLEVDSQPGLGSRFSVRLPLATHAAATSLPSLHGRVVALCSRRSGLSELLDAWLPAWGIEYLRLDTDASLAGLEVDLLISDCPECLHGRRPQANAAILLVCSYGDFLPEGEAQALQPLEQLPRPLSRAALYQALQRGLGQPLGAGPAQTDEPRRPRILLVEDNPVNQLVVKGLLGRLGLTVEMARQGEQALKLLAQQNFDLVLMDCNMPILDGYETTRRLRREPRHAHLPVVALTANALPEERERCLQAGMNDYLSKPLRREELEAVLARWLPNCLQPA
->UniRef90_A0A6G6VZM2 Multifunctional oxoglutarate decarboxylase/oxoglutarate dehydrogenase thiamine pyrophosphate-binding subunit/dihydrolipoyllysine-residue succinyltransferase subunit n=1 Tax=Microbacterium sp. 4R-513 TaxID=2567934 RepID=A0A6G6VZM2_9MICO
-MSSQVTGVGVSNEGEFGANEWLVEELYEQFKIDRNSVDKAWWPILENYHPVDEAAPAVPAAPSAPASEAAAPTQAQPGASEPRPVTAPIPVIGAQPVARTTAKPAANQPIPAQAPAAVPSTGEASTEEDQVTVLRGMTKTLAANMDESLTVPTATSVRTVPAKLMIDNRIVINNHMARTRGGKVSFTHLIGWAIIRALKEFPSQNVFYAEIDGKPSVVAPAHVNLGIAIDLPKPDGTRSLLVPSIKRADTLTFGEYLASYEDLISRARGNKLTAGDFQGTTISLTNPGGIGTVHSVPRLMKGQGCIVGAGALEYPAEFQGSSEKTLVELGIGKTITLTSTYDHRVIQGAGSGEFLKKVHELLIGQRNFYEDIFAALRIPYAPIHWASDINVDIAERVDKTARVQELINSFRVRGHLMADIDPLEYVQRTHPDLEIENHGLTFWDLDREFVTGGFGGKRIMKLRDILGVLRDSYCRTIGIEYMHIQDPGQRAWFQEHVEIKYQKPGHDEQLRILSKLNEAEAFETFLQTKYVGQKRFSLEGGESLIPLLDEILQGAAQSGLDGAAIGMAHRGRLNVLTNIAGKTYGQVFREFEGSVAVGSKSGSGDVKYHLGTEGTFVADGGDELPVLLAANPSHLETVDGVLEGITRAKQDRKPIGTFSWLPILVHGDAAFAGQGVVVETLQMSQLRGYRTGGTIHVVVNNQVGFTTVPGDARSSIYATDVAKTIQAPIFHVNGDDPEAVVRVAQLAFAYREQFHRDVVIDLVCYRRRGHNEGDDPSMTQPLMTNLIEAKRSVRRLYTEALVGRGDITEEEYEKAKLDFQNGLEVAFAETHAAQTGTHPVVPDAEASAPVSGAPETTGVPTEIVQLIGDAFVNKPDGFTVHPKLQQLLDKRLDMSRNGGIDWAFGELLAFGSLLIEGTNVRLAGQDARRGTFVQRHAVLHDRANGQEWIPLANLGDSQGRFWVYDSLLSEYAAMGFEYGYSVERADSLVLWEAQFGDFANGAQSVIDEYISAAEQKWGQQSSVVLLLPHGYEGQGPDHSSARIERYLSLCAQDNMTVARPSTPASYFHLLRRQAYARPRRPLIVFTPKAMLRLRGATSKVEDFVNGTFQPVLDDDRGVDKGAVTRVLLHAGKIHWDLRAELEKNPNPEVALVRLEQFYPAPIQELNAVIDSYPNAQLYWVQDEPENQGAWPFIALEVVKHLHGRTIRRISRSAAASPATGSPKVHAVEHAELMKKALTTTSR
->UniRef90_UPI0014206272 serine hydrolase n=1 Tax=Chryseobacterium sp. Tr-659 TaxID=2608340 RepID=UPI0014206272
-MKKLTLAFLISLSFNMFAQSVNDKIKLFESNLNYWDQLKTKKWSLKERMALYNANAVSIAVIKNYKVEWVKAYGFADISENRPATTQTLFQAASISKSINSLGILKLVQEGKLGLNDDINNYLKTWKFPYDDAVSKGKKISIANLLSHTGGLSVGGFGGYEKGEKLPTIIEILNGTAPANSNAVRSIFEPGSKFEYSGGGTVISQLILENTTGEKYEDYMLKNVLVPLGMNSSSFNQPPSKDKEALFAAAYVNGKEVTGKYHIYPEKAPAGLWTNPTDLAQYIIETQLSLLGKSNKVLSKEMSAKRIENNLGVFLNDFKGTKYFGHSGRNEGFTCHYVGSLEDGNGIIVMTNGSNMKLVEEIVSSIASLNQWKNYPLEPMKESIALTIRKECEKNIDKGIALYKKLKNTLPNNYNFSDENELNNLGYEFLRSGNIDSAIKIFNLNVYEFPKSANVYDSRGEAYLNKKEYQLSKEDYSKVLELDPTQQNAREMLLKIKKETGK
->UniRef90_A0A7S1LBN8 Cation_ATPase_C domain-containing protein (Fragment) n=1 Tax=Alexandrium catenella TaxID=2925 RepID=A0A7S1LBN8_ALECA
-PNYVLDVCKTWVGRDGSVEAFSDAAREDAMRTIDILSSQALRVLAIAVRPMAQLPFDPEEDQDSSADEKMGILCQDLTLMGLVASIDPPRAGVRDAVQAAQNGHIRVMMITGDYLKTAAAIAQDVGILEPDVGERGALDCTSLRPSGDYLPDLKIDELTKDARVFARAKPEDKLEIVKSLQRQGLVSAMTGDGVNDAPALNAADIGVAMGIQGTEVAKGASAMILTDDNFVSIVGAVEKGRVIYAGIQKFVAFIMSVHIAEVLQIFICIVSELPVMRTPLQILYLILVTDLAPSIALGLEPGQAGIMNDRPRPKKQPILLWWMWVSTVANAAILTAIIISVYIWGLDTFVNERNVKMISRMVVDEEANGLPGHTKRGLEQAQTVAFISLVWSENIRAYTSRSFDSPVCKELCTNRYMQGAIGVAQAALYTAIFLPGLSDILGLKGADIGLKGWIAALVGAGACLVACEAYKALQWLAG
->UniRef90_A0A7J6FTG0 Calcium-binding protein CML44 n=2 Tax=Cannabis sativa TaxID=3483 RepID=A0A7J6FTG0_CANSA
-MSPLSTYDLKRIFQKLDKNGDDLVSLEELSWLLERINNGSVHHQFSKTELESLVGKSSLNFDEFLFFYESISSKHNDEIDDEVEEIIISDLVKAFKVFDQNDDGFISCEELQSVLIRLGLMEENSTDKDCKTMINAFDANSDGQLDFEEFKTMMLLTITS
->UniRef90_A0A0P7TU97 Main olfactory receptor family H subfamily 129 member 1-like (Fragment) n=2 Tax=Scleropages formosus TaxID=113540 RepID=A0A0P7TU97_SCLFO
-TDLKTDFAVAYRDIVGSGKVGVHEAAHGPGVDQSLSLHFPSALRQTNEYSETNETVLGNTTSNRSLMVIMKICFVSPFFGVFLYCIVVMLHTFILHRQFWDSSRYILFVYMLINDTLQLLSSVLLFLFVMADLHISFACCAPLLFLSTATFQNTPLILATMSLERYVAIFYPLQQPAAWHADHIWVIILSLWLISCIIPTVDFSLGGLRISIDVLLTPVLCKTQALNSSPVQMLFKVILNGLFFTLVAIIILFTYIRILLETRKMRQDRASVSKALHTVLLHGLQLLLCMMSLTHPITEGLIIQHMGWLQDNISFFNYFCFVLLPRFLSPLIYGLRDDMLRKKIRGAIFCCSTKGAQQVTDKHILK
->UniRef90_A0A0Q7EWN4 Carnitine dehydratase n=3 Tax=Massilia group TaxID=2895353 RepID=A0A0Q7EWN4_9BURK
-MTPAEPSLPLSGIRVLDLTRLLPGPAATMQLADLGAEIIKIEDPGPGDYARAMGPVRKEVSQFFVAVNRGKRFLRMDLKDAAQREQLLAMVEQADVLVESFRPGVMDKLGLGWDVLRARNPKLVMCAISGYGQDGPYAMLAGHDINYVGYAGMLDQNAAPDGRPALPNLQVGDLLGGAQAALQGILAALVAVKMGGMGRFVDVSMTDAVFANNIMPLVAVNNGGDAAPGRDLLTGGVPCYNVYRTSDGRYMAVGALELKFWQACCDVLQRPDLKARHWQLGQQVGGPDALAVQAELEAVFAQRTLAQWTEAFAGSDCCVSPILRTSEALVHPLFQARGMAVRAVHESEGEYWAAAGPLKFKA
->UniRef90_A0A7W8G837 VWFA domain-containing protein n=1 Tax=Treponema ruminis TaxID=744515 RepID=A0A7W8G837_9SPIR
-MPKRHLALILIISLFHSSILFSENAENEAGEVLSLKQIDLLIDTTAYNDALRELSRYIAAHPNDFDRAQKRISRVMKLREEYNKGADSLVELIRNGDESKSEKLAKIAELESSELESNENVIEFTNLARRTVTLGEILILYDRIMREGVALVRSEKFSDAAVKFEEGFAIKNEVSDLVFDVENHSFAAEGTPVVYESDITEPVRKSVSNIRSLVAGNLVSASMESRINDCEKAFNEYMRAVSARDVNSISAALKNVNAAFEKYAALRNKIIADAKVLEAADILANERNPLLYGTSYITFHQKFILGDESNPDTGIIGAFDAYFNSRVERMKDKTNEAVLETLNLLITNLPEGKIYSLANKIDAEQKNVAVAKMYSQFARYVHDLYNLEKNLDGSTVGEKFSGYASSMSFVSEYLSDLSLAYKSAQELAWEKANPEKIDKNDFSDPVLAYNLKKLLRYEQIKADSKSYISLVNEEEKKQKEFFDKKSEREKEIEELRRISGGRLRISGAQKRTTAGVQISDNPLDFRKQIGYFLSLNEQNLKEARNHAKGLWGYMASAYSALAKKDYDHYEKLCSDTEKLLTGGLASSSDSDFSSEFIKKYPIEAKDSALKINQEISIKKTELLEKREVLNGGEEYRMSESDYNKGTLALDKIILDFDSLYAKNQTLAEEAIPKIRDYENLIRNADEQYEIALRAFKKEDFENANIAVDSASEKYAEALDIEYSEKIRAMREETLNELAVKIQRAEYEKVLREVFALKDKAAIAYYSSSFDTAETLLVTAQSRWSKVSTEEDSEIEDMLNIVKTIKSIEYGRVLLQSDPHYPELSYSLDMAKQSFEKGVKLKNDGNTVKANEAFNLALTNIRNVQNVYPLNKEARLITLKIQQELDPEGFPRQFENQYNAARLNANKNERLADLEDLYAINPKYPGLAQEIYDIKDSLGMFPKKEVKKEVKRSADSKIAEAKKAFKDAGSDEAKLNKALLLANEAIAIDGTSKAAKELKLQIQLKIGASATAILSQNDEKMYAEAARLFNQRRFADAKGIMDNLLKGAAAKKSRKVIDLNNRLLKRL
->UniRef90_A0A847Q3W9 DUF814 domain-containing protein n=1 Tax=Candidatus Fermentibacteria bacterium TaxID=2044591 RepID=A0A847Q3W9_9BACT
-MDGVYISAVACRLSEELTGRTCSRVTRPFAGGLGLSIGGRMLLLDARPPSPAAWLGDDGADDGDPAPQPWSDGLAGTRLEEVRQEGLDRILVFEFSRVRRYCNPLMRLIFEMTGRNCNLILADSGSRILACTRIVSRSMSRVRTVRPGETYEGPPSSGAGLGSWREDRVLEALGKATSPEEIHPLLEGVGPATAGAILEESRASGRKVPEVVAVLGSALESREFAPWASVHGPMPIRLGEGAPIADVLSPPSGGGPAGACRKAAVEILEARRAFLERKLEKLRSVLDGVPSEDLLRLRGAILLANIPRVPRGAEEVVLPDWDGMEHRIPLRPGRSAVENAQRYFRKARNAAVERSRLESSIRETRAAIGELDAALAGGSGQCRIDRLAGAVGATRGAEARSPAGRAMGGGWTCLVGRSARENDEITFRIAGRDDIWLHARGAAGAHVVLRHESRGQTPPRAVLEAAAALAAASVRNRPDVVPVDYTKVRYVRKFRGAGPGEVVYTGEKTLFVRLCSARRGGARPGEAK
->UniRef90_UPI001FF9ECF4 transglycosylase SLT domain-containing protein n=1 Tax=Bradyrhizobium sp. 1 TaxID=241591 RepID=UPI001FF9ECF4
-MPRDRAHFRFGATWRNVAAAALLLASSCAHAGDGEQYTAGAPDLGAAETATSRAEIRRIVDSETGKANLPADLADAVIFVESGYNSSVVGSVGEVGLMQVRPETAAMLGFRGTAEELAKPDANIHYGVLYLARAWRLSGGDLCRTLMKYRAGHGEETMTPRSQVYCNRARNHLLAMNSPVATGATAAPAPAPVPSTVVATTTTSIARSPKALSRPKEVYARFRQGTAAASRAYWAAHEARISLIKARIETRWKRVASR
->UniRef90_A0A0K2UCG6 Uncharacterized protein n=1 Tax=Lepeophtheirus salmonis TaxID=72036 RepID=A0A0K2UCG6_LEPSM
-MWPTVHSLIQTLVLLLPDLQP
->UniRef90_UPI001E440651 type IV secretion protein Rhs n=1 Tax=Chryseobacterium gleum TaxID=250 RepID=UPI001E440651
-MAEFSVKTLPNDKIMKLYDKKIQLFSSFILSLCSVLGFSQTILYQAESTSRTVQDPQTVVLAPGFRASSTSSNPFVAKIGPATENPGGGPTDSNAGSNNPSGTTAPDGKSFHDTKGNIEVNGAGQLQFTLPIALPPGVKSVAPQVNLVYTSGSSNGIAGYSWNLSGVTTISRVGKNIEKDGEVKGIQLDYSDYYSFNGQRLILKSGEYGKDGAEYITENYSNIKIKSFGSIPGQVWKGPEYWEVTFEDGSQSWYGTIASGNSTARTPLEYNIVKWKDAQGNYITYNYTQNNSNNVAVISSITWGGNETLNKPHFNTIEFTYLPRKIVEISYLKGILFKQDKILDQIKVKANGSPFKSYSIQYSETQNIVNNDSNNKINYDFVEKIVEINSEGKEANPITLSTNPLLTGSNEFDFGDYDNIITTGDYNGDGLIDFIVRQPAQNSRPEGYYLYFNALNNSNPSFVYLGATSVFWPSSSLTTVNIKSADNFIKPRQGLVITKSNVGYNPPSTGNIELAYYSIKSDASVINTYNNPLVFEYSKTIQSNNYLFDSSLYPPETDPEYLGGLNQSGLSVLKEVDIDSDGISELVLPIEDKKCKYVVIVPDPPKGRWQCKTLGYRYIAVDNDNIQNNTISIIPGTTSKNILSKGGIMDFDNDGKQDIMFLEPTDSKVNVTFYTQVINSGSNNSSPVSLTTEAPLNNLKQYELKKVGNNYTINLKNTISVKGLADGLQFGDLNGDRNIEVLLPVGHPYINRLQGWSIYLNTGNGLQEDIQGLMPYFPYTSSNTDNYSYTIPKLMDLDNDGKSEIINSNVSFGPDVIPSNGSYHSSWYIDSYGEASYDPNNSQFKWSFAKKRIFSSVRNEVVVSPIFGDFRVNNSSSKILFLIKGINGNNERKIISYKHYSLNPDKNISLISQGSQNYYIDYKELDPSFNSNIYAPVKKEQYPFVEMDRLSQTFGVSQLRQTDGQTVRKQDFRYRGYIVNLHGNGVTGFRQAARSSWYADGFENTKIWSGTEMDPLNEGVPVKEWSIRTNNENQIFPADISENNTQLLSFKSTNYQIDKLLNGQVVSTVADSDKPKVVTVVAPKISRVKDFLTGTITESTITYGNYYLPSQSVSNVNNGYAITTSTSEYIHNPSGIGSDYYIGRPKSKINVVQAYGDTKSSKEEYIYENSFVKTLKTWNRDNTGYLQETYNYDGFGNVTGKVISNSIDSQTQTTTSSYDPKGRFVVKKTDNLGLETNITYNDWGQILTQTDPLGNVLTNTYDGWGKILTSKTNLAGTITYQYEKDNNSNIIVTQNDPDGNISKKFTNKLGQEYKTSTKAFGQGQYITKTILYDALGRKTSESEFTFSPDGLGGPWNLVAYDDTVFPTKVTATSFNGKQMETSMSGLTTTVKELNGYQRTTSKTTDVLGNIIYSTDKGGTIQFTYNAAGEQIKAQYGENIITTKYDSWGRKSEFNDPSNGIYKYEYDGFGQAKKITSPKGTKEYTYNNLGQLISQKEISTADGGQATNKLISYSYDNKGRLISKSGTSKGQAYSSNISYDLQGRLLSSSESSNGKYFIQKGITYDDKARVISCEKQLYSSGTLTKVQIENVYSIWNGELYQVKDKATGKILWELKETNAKGQVLKSKLGAADINNVYDANGLLANVNHSSQAKPGILQLSYSFDTIKNELKSRITGGDFNITESFDYDDNNRLVNWTNPVTGIKPTTSRNVYDVKGRIILNDQVGTVKFENSTKIYQPTGMTLNAAGEHNYNNDLIQSIIYNENNDPVFIDGMKGDAAFQYGLTSMRQRVTYGGNFSTDGEGKFTKFYSEDGSFEVVKDNTTGKEKHILYIGGTPYESNIVYLKNFSESSGSYKFLHKDYIGSILAISDEAGNKLEQRHFDAWGNFTHLQIGNGSIITDQNTILTLSKDLAIDRGYTSHEHFVEVGIIHMNGRLYDPLLRRFLNADENIQDIFNTQNYNKYGYVLNNPLMFNDPSGEFIWFLGAAWAAAHVFLAGVITAAVIGTAVGLAAYSLGVAISGSKWQLGGALKSMFWGGVSGAVTFGIGSAFTPVAGTVLTLTDKVASAMAQGLVHGFAQGVLSMMQGANFAHGFASGASGSWGASLFGAFAGSFANSAAGTVVSGALLGGVASELTGGNFWEGAVIGGVVAGLNHYLHKIETTNKIRKRIDKYYNDKSVADASVKKGFLQDLTKIFPEIYELTAKNFAIANEENLKQFNESTGADYVLIDKTIVSDGGNGENINGITSMKDGSVLISPHRTRTALGFAATWYHEGIHSLHLVTGMFKAWEIKYGAKEALRITEFYAHSMTDAMSGLSMTSSLAFSRYYPSLYIQSLSSFLRP
->UniRef90_A0A1A9ZG83 RNA_pol_A_bac domain-containing protein n=1 Tax=Glossina pallidipes TaxID=7398 RepID=A0A1A9ZG83_GLOPL
-MTCIPEPRIARIFTQEKDTKSSPHESQRKRHENSNTFDNVCAIDMYGHQISSNNIRIKIYSGQIKWWPKGKQAQIYIESDVGPIDDDILITQMRPGHELDIRLAAVKGIGKDHAKFSPVATAFYRLLPEMKLKKDVVDVELRWKFQTK
->UniRef90_A0A0B6Z514 Protein CASP (Fragment) n=1 Tax=Arion vulgaris TaxID=1028688 RepID=A0A0B6Z514_9EUPU
-PFKMAANVQLMCQYWKNFDLQELQRELDTTATELANRQDESEGSRKRLVEQSREFKKNTPEDIRKVVAPLLKSFQLEVDSLSKRSKATEAAFLSVYKKLIDLPDPVPTLEHAQNLQKKAHKVQDLEIENKQLRETLEEYNHEFAEVKNQEVTIKQLKEKLKEHEERVEATAQNRAKEKERELQRTFAEKERQLQETQLIVARKLGEAEHQIATLHRALETAQSELFEVKAKYDEATSAKSDEMEIVMADLERANERATSAERQVERLKQQLTLAAESLNHQDEEDITQQNLASDQAMDILKRSTLEVELAAKEKEIAQLVEDVQRLQASLNKLRETTSAQVTKLEEELTAKNHAFRILEDRLRTQEDYEEVKRELRVLKSIEFANVSSEESHNEESKSLEMRLLEKNKSLQTENTHLKVVNSGLTDQVRKLQEEYKEAAATVQEQKSLITQLEEDLRNINAFSSMFRGDAEGEPGPPDANSEAMASIVKEVTQLTSGKFSKSAADSLLPIIQSQRERYRLRAQELEAQTLSQQQQVTLLQNEMDKLRSDNVKLYEKIRFLQSYPNKDGTREGAATDDVTSSYSSQYEDRLDPFTYFSRAERQRRYHELKPYDKITLSMGRLIMGNRTARVFAFFYTVILHVLVFLVLYKLAHTESCKRDMAADWHQRYSEHMMKVHGEEGQHVD
->UniRef90_A0A1V5QNZ9 Transcriptional repressor NrdR n=1 Tax=Betaproteobacteria bacterium ADurb.Bin341 TaxID=1852821 RepID=A0A1V5QNZ9_9PROT
-MKCPFCGAEDTAVVDTRINDEGDIVRRRRSCKVCDKRFTTYERAEIRLPQVVKKNGSRTEFNRDKLRASLDLALRKRPVTTEAVDAAITDIEEKLLAMGEREVTSQQVGELVMRELKRLDKVAYIRFASVYRNFEDVSAFSRAIKEVK
->UniRef90_A0A1S8RD89 Acetate CoA-transferase YdiF n=24 Tax=Clostridiaceae TaxID=31979 RepID=A0A1S8RD89_CLOBE
-MVKIINSKEAADLVKDNNVLATSGFALLGVPESLIKRLEERFLEENSPKNLTLMFAAASGDRGSKGLNHLAHEGLTGRVIGGHFGLAPKIGALIRDNKTYAYNLPQGVMCHMFRDKASNRTGTITKVGLNTFVDPRVEGGKANSITKDDIVQVIDILGEENLIYKCPKIDIAFIRGTYADEKGNITMDHEATYSEAACIAQAVKNCGGTVVVQVEKIVKFGTLDPRAVKIPRIYVDYIVEAEDKEDQAQILGYNYDPSLTGEANMVVDGLAPLKLDERKIIGRRAAMELVKGQVVNIGIGMPEAISNVANEEGICDYFTLTVEPGAIGGIPQGGNKFGASINPECMYDQPTQFDFYDGGGLDIAFLGLAEVDKQGNINVSKFGPKVPGCGGFINITQSSKKVVFCGTFTAKGLDIKIEDGKLKIINDGSNKKFVDSVQQITFSGNRATKLKQPVMYITERAVFELKEDGLHLTEIAPGVNLEKDILAAMDFAPIVDKDLKLMDARIFEDKVMGLN
->UniRef90_A0A7S4VIJ8 Gp_dh_C domain-containing protein n=1 Tax=Alexandrium monilatum TaxID=311494 RepID=A0A7S4VIJ8_9DINO
-TACGAFQEDTELVQISTKVLPLLAEEDPTDVQSLQDCAGALPAGDVPPGVTTALLGASVVPWKEPSAGPPAVGHMVDCSAIDAPRSPLSGSPIAVSSLLALIRAVSACDRTMKLTLEGMAS
->UniRef90_A0A7R8ANC3 Zn(2)-C6 fungal-type domain-containing protein n=1 Tax=Aspergillus puulaauensis TaxID=1220207 RepID=A0A7R8ANC3_9EURO
-MSTRKSQSSRKRPLRLPTIAPKDDMTPLRSHDGTPAAIRATVIQPRLRFPPRSRTGCWTCRSRKIKCDEVHPQCNQCARLGHICDYQPRLCFRDDTRRVMERMPDVKTEGNSVWDPTKMSLWRERLGTSDSIPCDLLPDFSKLISDEDREKKAQGSVPGTYHVVAVPESFARLPEYTEDAFETVPGDPYWSPPSESSSHDLMDEVTTSEDPNVVILSQFRDSRKQPYSNRPSHTQSPESELRPTSVSVETIYTSLQNIPEDEISESIDLEAYDMTLLDHFENIVWMQLIPGDYGYLEANIFEQEASNFPPLLHVMMALSALSLVQQGNNHYMDVLQYYDQALPSLQSSLQNCDDVLSDGLFLTHFLLLIYQIAYTTPNNGLNLWSHHLSRLLQLSLLRQSVTEQERYPLIIWLTCHVDLYALLSGASEGAYVRAAIESHLLPETEFLLYPVGLQNSSVMHPDEYDPRSLIMRLYRECFILSARFGLFTAEVKGSKMAYTEPIFRELENMRAAFKHLWNSDEVQFFIESQSNMPKPSQHSFYQLSILFHTSLLFTCTSFGRIESELEKEIQHHTNAILHLAEKMIAQGRHNGPLFLTFPLFLSGAVTSSHTAKMTALKLLAQLGETELGYKAATTSSMLRIVCETQLQHWRSGGSVREIDWSEVAANHGFRLVNYG
->UniRef90_A0A2E4T8P5 AarF/ABC1/UbiB kinase family protein n=4 Tax=unclassified Alcanivorax TaxID=2638842 RepID=A0A2E4T8P5_9GAMM
-MSKDTIVNEMRANLAREREGLALVRNTARGAFRVFETVGVVGRQGLGWLLGDREALPRHLRRTFESLGATYIKLGQFIASSPSLFPEEYVSEFQKCLDRTPPLPFHYIRETVEAELGAPLDTLYEWVDPKPLASASIAQVHAARLKNGADVVIKVQRPGVRQVLLTDFNFLYASARLVESLAPGLSRSALSGVIEELQAGMLEECDFLQEARNLDAFNRFLAETGNVAAVAPRPVASHTTKRVLTMERFHGVPLTDLQVLRRYTDDPAGTLITALNTWFSSLMVCDFFHADVHAGNLMLLEDGRVGFIDFGMVGRIRPEAWQGMMAFFEAIGSGDVPAMARAMAMVGMTSEEVDVDALARDISALQDRLTDVDASALVQADRNDREVNQLLTDLVRIGEGHGIRFPREFALLLKQFLYFDRYVQALAPELDMFSDQRVDLFGTLDQLPGDEPLH
->UniRef90_UPI00156E65B2 VOC family protein n=1 Tax=Flavobacterium sp. 7E TaxID=2735898 RepID=UPI00156E65B2
-MSKNITGIHHVTAIAGGAQKNLEFYAGILGLRLVKKTINFDAPEVYHLYYGDEQGNPGSVLTFFPYQGLKMGRHGKGMLNTTTFSVPLDSIAFWTERLSRFGIAFKPPQERFQNEIVIYFEDYDGMGLELVFNDTDSRVGYYNGAINESNAIRGFHNVEIWQEGYELTAGVLTQQLNHTLIAEKGNRFRFAAQESSGNYVDILCAPDSLKGLAGSGMVHHLAFKTPNKTSQEAIRTIIVDRGLNPTPILDRKYFTSIYFKEPGGVLFEIATEAPGFAIDEDAEHLGEELQLPEWFESRRAELNSKLPNISIDHNKFL
->UniRef90_A0A6B3SK05 ABC transporter ATP-binding protein/permease n=1 Tax=Noviherbaspirillum galbum TaxID=2709383 RepID=A0A6B3SK05_9BURK
-MRRYSASSPEPAANQGTRNDWVTLKTLFPYLWAYKWRMLLALIFLIGAKLANVGVPLVLKKLVDNMSIEPNHPQALLVLPVGLLVAYGALRVSTTMFTELREFVFAKVTQRAVRTIALQVFRHLHALSLRFHLNRQTGGMTRDIERGTRGISSLVSYTLYSILPTLVEIALVTGYLVLHYDIWFAVITFIALGVYIGFTVAVTEWRTNFRRTMNELDSKANTRAIDSLINYETVKYFSNEDFEARRYDQSLENWETAAVKSQTSLSLLNTGQSLIIAIAVTLILWRATQGVIAGTMTLGDLVLVNAFMIQLYVPLNFLGVIYREIKQSMADMERLFQLLEQHREVADAPDAKPLAVRGAEVRFSHVNFSYESKRQILFDVDFSIPAGTTTAVVGHSGSGKSTLSRLLYRFYDIQSGSITIDGQDLRDVTQASLRAAIGIVPQDTVLFNDTIEYNIGYGKPEASKDDIVAAARAAHIHDFIVSLPDGYATMVGERGLKLSGGEKQRVAIARTLLKNPSILIFDEATSALDSKSEQAIQAQLKEVAQDRTTLVIAHRLSTIADAGQILVLDHGRIIERGTHGQLLAADGAYAQMWARQQAHRDEQTASPAAPDLDASAA
->UniRef90_A0A2N3HH73 Sialate O-acetylesterase n=2 Tax=Confluentibacter flavum TaxID=1909700 RepID=A0A2N3HH73_9FLAO
-MTVKCFLFISCISMNTAVYAEIKLPAIFGSNMVLQRNSEVSVWGTAKTKSKVTVSTSWNNRSYETTSDKEGNWKIKVSTPEAGGPYIIKMSDGQELVLDNVLIGEVWLCSGQSNMERTLRGAGNDPILGANEAILKSNNPSIRFFTVERAKSEEPEDNFKGDWKVCNRSTAPDFSATGYFFGNLLQEILDVPVGLISSNWGGTQIQRWLDEGTIKTFAPEHWESSPSTLFNAMINPMLNFNIKGVIWYQGESNRENPEIYDEMMVKLVQNWREKWGIGNFPFYYCQIAPYEYDNKVNSAFLREAQLKASKEIPNSGMVSLLDVGEERNIHPANKRAAGERLAYFALKETYGIEGISARSPEYLDMKIEGSTVELNFSENLTSFGKELKLFEVAGKNQIFYPAKARIKGKGIILVSEEVAEPVAARYGFKNFVDGDLYNIHGIPASSFRTDKW
->UniRef90_A0A672QUX7 Galactose-3-O-sulfotransferase 2 n=3 Tax=Sinocyclocheilus grahami TaxID=75366 RepID=A0A672QUX7_SINGR
-MLPPQRIAGRERRAFRWRTAIPWTTCVRVACCSRLRFMWFALVVLTVLCGALQMLGVVRQARSSKVLKLVSEQLVRMPAEMYRPVKHKDWENLWSVSAAIVEEPLDLQPFIQRKDESENPHSEEGRDQVLEDTRKKLSSSTKAAPPIEAIKLWLDQYFPNQPQRPAFPKRTPEIHKPPPSDDKTDKQTVKSLVDDTAMCHPKNHIVFLKTHKTASSTILNILYRYGESHNLTFALPLNMQSQLFYPAFFAAHFVEGVRTRSVEEFHILCNHMRFSSQEVRKVMPKDTFYFSILRNPVSMMESLFVYYKAIPAFRTVKSLEEFLIQAPENDTELDKRSAEVIAAVERDFPLILISEYFDESLVLLKHALCWSLDDVSSFRLNSRSERSRRPLSAEIAEWVKEWNSLDWRLYQHFNATFWKRIDSTLGRAKLQQEVELLSAKRRKLEKMCLQEGGAVDPAQVQDSSLKPFQYGAAVIQGYNLRLGLSNATRQLCHRLITPELQYTSALYTKQFPHLADVRAVAANKFAASRSTAMHRAVKHYFDLTYQYK
->UniRef90_A0A8E0G9R0 MaoC_dehydrat_N domain-containing protein n=6 Tax=Burkholderia TaxID=32008 RepID=A0A8E0G9R0_BURTH
-MRATPAERRDDALRIVTDLVSPAPAAALAATLDRDAHPRAGDPLPPLWHWLYFWTAARQSSLGGDGHPRTGGFLPDPGLPRRMAAGGRVRFIAPLAIGSSATRTSRVASLERKAGRSGRLAFVTVEHRIESSGALAIHEEQDIVYREPAEPGAPSPPRQAAPDGAHWQREIAPAETLLFRYSALTFNGHRIHYDRAYAQHAEGYPDLVVHGPLIATLLLDLVSRSMPDAVVTDYAYKAVRPAFVGRALTLCGRLAPDGRSAELWAKDHEGSLTMSARASLVR
->UniRef90_A0A3P6UJT8 Mediator of RNA polymerase II transcription subunit 13 (Fragment) n=2 Tax=Gongylonema pulchrum TaxID=637853 RepID=A0A3P6UJT8_9BILA
-MCLSLIRDTGEQENIGWEDVLTARQYMEYIDLSGYATQFKYQKVISSLHSIASALASCCGLGAFQSNTVMIEYPSQAALSGLPDSLLYHYHMHRVCVQHSNLVVVKGTFPLKMQ
->UniRef90_A0A8J6DP79 Uncharacterized protein n=1 Tax=Galemys pyrenaicus TaxID=202257 RepID=A0A8J6DP79_GALPY
-MDGVMRMPGPTDRTERTNRTDSTDEHQRAAAVESSREVEMHMPASQPLAPMPAMYLTTSTNKSMKSHGGLQDSSSLTRLPRTILTLAPVPPFLPLQMIMENRM
->UniRef90_V5RHL7 Single-stranded DNA-binding protein n=1 Tax=Spiroplasma apis B31 TaxID=1276258 RepID=V5RHL7_SPIAP
-MNNVNIIGQIEGTPQLVFNSKNGEKKLFKFILRVPRNYKNKDGIITDDFINVKVWSNVLGDEYEYYDQSFVGIEGRIISFGSTDSVTYGNEIVANKIIHIA
->UniRef90_A0A074WYW5 Ubiquitin carboxyl-terminal hydrolase n=29 Tax=Aureobasidium TaxID=5579 RepID=A0A074WYW5_9PEZI
-MSGGWNTIESDAGVFTYLLENLGVKNVQFEELISLDAQSLGQLSPLGVIFLFKYNNDGRKSDGPLDGQFDFEATYNLDDAGSGGDGKGKVWFAAQTIQNACGTQALLSVLMNKDNADGVELGPHLTDFKDFTAAFPPDIRGEALSNSDLIRDTHNSFARSSPFVSDETRMATQDDDLFHFIAYTSINGKLYELDGLQEAPINHGPCAPTDFAEKVIPVLQRRIERYPSNEIRFNLLAMCQDLRVKAREFGDEDMVYREEEKRRAWQWENALRRHNFVGFVGELMKGVTAAKIADGSYDAWIEDSKQKTKKKLEEGKKKGYNPDEMEM
->UniRef90_A0A413WZM4 Secreted protein n=1 Tax=Bacteroides uniformis TaxID=820 RepID=A0A413WZM4_BACUN
-MFYGINFLWPASGCFLYLVSKARSAGCARNDNSVSFHHAMFAHQCWNSEKYGIKFLEEMLLSNKREYKLLSFI
->UniRef90_A0A8S3J9F7 Glycylpeptide N-tetradecanoyltransferase n=1 Tax=Rotaria magnacalcarata TaxID=392030 RepID=A0A8S3J9F7_9BILA
-MNTYIFNDDIFLATADQILEELADESVVDLRSHWPILPLLQINLYHVPPQPKKVQEWTIVEVDNDDILTPYPYPSDPMIAERFYEEYSSGNKQKSMENEPGKSKTEEKVFKKNNNATEEAMDPSMTLDATMIENNPEIRKMFLDAAVKQESSLVLKYKYGSFFFKNNNNNTVNLLECLM
->UniRef90_UPI00197D08DB FMN-dependent L-lactate dehydrogenase LldD n=1 Tax=Novosphingobium sp. GeG2 TaxID=2726189 RepID=UPI00197D08DB
-MIPLSVFDYRSAAKRRLPKFLFEYIDGGSYAETTLRRNMADLQEISLNQRVLRDVSSIDLTTDLFGQTIDLPLVLAPVGLAGMNARRGEVQAVRAAQEKNIPFTLSTVSACSLPEVARATTRPFWFQLYMLRDRGFMREMLETAQEARCKTLVFTVDMPVPGTRYRDYRSGLAGAPGIVGRARRLFQAAMKPQWAWDVGLRGRPHTLGNVAPLLGRNTGLEDFFAWMRTNFDPSASWSDLEWVRERWPGTLVVKGILDVDDAKEAIHAGADGVIVSNHGGRQLDGVVSSAQALPAIAEALSGQATIMVDGGIRSGLDVVRMIALGADAVMIGRAWAYALAARGELGVSNLIDTIRSEMLVAMALTGETNVHNLCTNNIIR
->UniRef90_A0A358QV57 Na/Pi cotransporter family protein n=1 Tax=Desulfotomaculum sp. TaxID=41211 RepID=A0A358QV57_9FIRM
-MWHVVILGLIGGMGLLLYGMQILSEGLQKIAGAKLRTLMSTLTQNRLSALAVGATITVLFQSSTATTVILVGLTSAGIMSLKQTLGVILGADIGTTVTAQLIALKVTEIALPIVGLGATIIFFTKRERYRRYGQVLMGFGLLFLGLKIMSDVMYPLRENPMFPEMMAKMSDNPLLAMLIAAVFTFLIHSSAASIGIIMVLSMQHLVSLHAAIYLLFGANIGTSFTAILSSLGSSRESQRVATAHLLFKVAGVIVFLPFVGPFIALMEKITDSPGYQVANAHTFFNIALAIAFTPFVSQFANLLMKIVPEKRKIGEVFGPRYLDIKLINTPAIALGLATKEINRTFDYVYEMTRDTLLMLEKNDASIISTVAKKEDRVDILFKEISQYLTNVLRQPHSRGEFVKCMGLINIVNDLEHIGDIIEKNVTYLAQCKIDGHCTFSEEGWDDISIMHKKVCDLMQMTSTAFVTSNHDLADRAYKLQPEITKMERHLRVLHIHRLRISGSTEEEGALYLDLINALLRISEHVRNIAWEVANEGLEFTASGERVATDER
->UniRef90_A7HUX0 Short-chain dehydrogenase/reductase SDR n=1 Tax=Parvibaculum lavamentivorans (strain DS-1 / DSM 13023 / NCIMB 13966) TaxID=402881 RepID=A7HUX0_PARL1
-MASGNTLSGKVAIVTGGASGIGRAIAHAFANEGAKVVIADVEEETGEKTAAEIVEGGGEAIFRYCDVGERLDVRNLVCAAGDAFEKVDILVNNAGVVSKGSDFLTLEEEEFDRVIRINLKGHFLVGQAVAQRMVAQIEEGHAPGTIINMSSINAVVAIPAQAAYSASKGGIKQLTEAMALSLAPYGIRVNAIGPGTIQTAMAGNVNENPGANKMLLSRTPLGRVGQPEEIASIAVFLASDGASYMTGQTVYADGGRLSLNYTALPMAKKKGEEKKE
->UniRef90_A0A3L7A326 GNAT family N-acetyltransferase n=1 Tax=Mycetocola tolaasinivorans TaxID=76635 RepID=A0A3L7A326_9MICO
-MTTESMLPLNQRVTAPTQLPVPTGTEGVTWRPATAADLPAILTLDRAVEAVDDPRHVTTIEALTVDFAASGFDPAADSLLAETTDGTVIAYGTAHAEPEARSVVKVHVPGAVHPEYRGRGLGTALLDWQEARAAQHLAASDLAVPGWISTGAAEHAESPRGFLTTRGYVERRWWMELTRDLSDAIPELPLHADVRLEPLTEELSEATRQAFNDSFRDHWGSQPTNEEDWKKYGSVSTLRGDLSALAVTSDNEVAALVIVSVDPAQWEAAGYRFGYIDLVATRRDWRGKGLAKSLLAQVLRNLKAEGLERAALDVDSESPTGALRLYESVGFAPEARSVSLVREF
->UniRef90_A0A0A8VBS4 Transposase n=1 Tax=Yersinia ruckeri TaxID=29486 RepID=A0A0A8VBS4_YERRU
-MTALIRRHLRPLYLSLDLTSVVQDSPWAEALSWLRMVFSKKQTLLQRPLAECPPETLPERLRPYLLEFGEDGEPTGLNAGRYEFWLYRQIRKRFKSGEFHLNNSLRHRHLSDELVPEGEQAAVLAAMNIPFLQKPVKTQLKALESELHRQWKAFNRELKQGKLKHLEYDQQTQKLTWHKSVVSRHKAQEKSFYEQLPFCDVTDVFRFVNEHCRFLPAMKPLQPRYAKNEVDADSLMAVIVAQAMNHGNHVMARTSDIPFHVLETTYEQYLRLASLLTANDCITDAIEALPIFPLYSFDPGTLYGAVDGQKFGVERPTVKARHSRKYFGRGKGMVAYTLLCNHIPINGYLIGTNDYEGHHVFDICYRNTSEVKPTAITGDMHSINKANFAILHWFGLRFEPHFTDLNRQLQELYCTRDPSAYKKCLIQPAGQIDLNLIIREKSNLDRIVATLGLKEMTQGTLIRKLCTYTTTNPTRQAVFAYDLLVRSIYTLKYLRDPQLERNIRRSQNRVESYHQLRAAVAKVGGKKELTGKNDIETEISNQCGRLICNAIVYYNSAILSRLLERLETEDNTKGIEALPRISPVAWQHILLNGHYIFQSNNEIIDLDALVAGLKLR
->UniRef90_K7W9Y4 Glycosyl transferase group 1 n=17 Tax=Nostocales TaxID=1161 RepID=K7W9Y4_9NOST
-MAGKDIKLSSASASILTLGTGWFPNNPGGLERYIYELIHKLAASQDQVELCGVGLPLDAKNTQIKLTNLACPDSKISSRLWSIRDNFQKTRLGKPDAINLHFALYSFPILDILPKGVPVTFNFHGPWASESQEEVVNKKLSVWLKEKIIEQSTYNRCDRFIVLSKAFGQILHQKYQVPWQKIHIIPGGVDINHFQNNLSRQEARIKLGWPTNRPILFTSRRLVHRMGIDKLLQAIAMIKVGIPDIWLAIAGRGHIQALLQQQARELGLENNVQFLGFVPENDLPVAYQAADLTVMPSQSFEGFGLAILESLACGTPVLCTPVGGMPEILQKFSPDLITEAITVESIADKLAQVMLGKLPLPSREECRNYTIKNYDWTNIAQQVRQVLLA
->UniRef90_S4SV14 Cytochrome c oxidase subunit 3 n=3 Tax=Scarabaeoidea TaxID=75546 RepID=S4SV14_9SCAR
-MSAKNHPYHLVDASPWPILGALSAMISMVGIIKWFHMFNSTLLLLGLSITSLIMYQWWRDISREGTFQGLHTYPVTMGLRWGMILFITSEVFFFISFFWAFFHSSLAPSIELGMNWPPKGVIPFNPIEIPLLNTLILLTSGLTVTWAHHSLMENNFTQATQSLILTVTLGVYFSVLQAYEYMEAPFTIADAAYGSTFFMATGFHGIHVIIGTTFLFTCLMRHLNNHFSSIHHFGFEAAAWYWHFVDVVWLFLYISVYWWGS
->UniRef90_A0A6G1DB44 Epidermal patterning factor-like protein n=1 Tax=Oryza meyeriana var. granulata TaxID=110450 RepID=A0A6G1DB44_9ORYZ
-MGHLLLLLLALLLLASSVHAKSAAFTEEKGVAGITVVIGSRPPSCEGRCRSCGHCEAVQVPISPQELQKKSGQVDSKKKKKLGHGDRAAAAAGGRTMPDSYDDHSNYKPLSWRCKCGGLILNP
->UniRef90_B5HBE5 CsbD family protein n=4 Tax=Streptomyces TaxID=1883 RepID=B5HBE5_STRE2
-MGISDQFKDKAQELADQAKQKAGKGDQSERARRAREEVSERTQQGREQQGARSRESMQERGENAMRERRDRVEDYDA
->UniRef90_UPI001D7ADF37 heterokaryon incompatibility protein-domain-containing protein n=1 Tax=Truncatella angustata TaxID=152316 RepID=UPI001D7ADF37
-MDDDLERQHQEFINRPLRDELPCDRCANLKLSTELFNESFDIGEIELTNILVDHFIFREVNSEYCSSCVDLMRRIDRQEITIRPRRILGFNSESEGDDLLVRSTFQINPDLRPLLCRVDNDSKTFDWGSESKSFGTYTTSDIVGPDHIRHVGDTPNYDAIKVWLGHCLRSHKQCNYSGDLKSALEMIFLIDIEKRQVVTYPKNGEHAPEYFALSYVWGGYKGVSYKPHSTLPYPLPQTIEDAIFVTKRLKLGYLWVDAVCIDQDDDVQKKEQISLMASIYRGAVATIIPLSSNTSDDGFPRVHSGSRRSNQLSLDFGHGKCLQQKLPRLADAIHEAKWNTRCWTFQEKLLSHRRIYFTDHQVHLSCAELVCCEAWHDETHYHNNPEEEDYLIMNPPNREDDLFTQNDHDCDIVSDFENIVNQYLERELEKPEDILHAFSGILEELKQHKFPDGFHQGLPKEDFQHSLLWRAGKVYGVMVDKISGKKYGGLSQATKREFLPQLPSWSWISWRPISGIKFYRLPDQTREPEIYSLKPWVHISDTKQVQLYEGSVAFRRKWEKLVLAHHGWSQNFTSPYITINQDLKQDRAIPAHRSNLHEHARLCVEGIVLQLPFQFMRRNTRVRTTSSYTTRYTRDLELTICDHIISKRLDVEWHFDRRFDRTKKYEEALKSSPLLLLDAYLQTDGGILIPGDFVLNLELLVLSWNGLLARREGTVTVRLKLDRKLKNLKSLVLGHHSITSRDGIDWPSDRVGQVDDTKSDGFASLRIDTERMN
->UniRef90_A0A6A7C4R0 Thioredoxin-like protein (Fragment) n=1 Tax=Piedraia hortae CBS 480.64 TaxID=1314780 RepID=A0A6A7C4R0_9PEZI
-LTLTTTEARCVVHFAKEEFARCRTMDTALEQLAKRHVETRFVRLEATEAPWVVERLKVRVLPCVMGFVGGKSVARITGFEGLGGGREEQSGFSLGKLERKLVEYGVLER
->UniRef90_UPI001FE2688D hypothetical protein n=1 Tax=Winogradskyella ursingii TaxID=2686079 RepID=UPI001FE2688D
-MRQKLRHSSAVFFTILFVALLSAPTIITSFDDSIDISFFYSLSEEEENEKNFKLVFETDSDSEIFFDAKKRKGKGIYKFKKYPKPHLNLVSPPPEFIS
->UniRef90_M5C988 Delta14-sterol reductase n=1 Tax=Thanatephorus cucumeris (strain AG1-IB / isolate 7/3/14) TaxID=1108050 RepID=M5C988_THACB
-MPLGTELRTGGRIKYKINAFSTMLLALGLTLGWIINFGPESFTFIYDHWVGLCTASLINSFIQATWCYYISTKNEETRTLAVGGNSGNVLYDWFIGRELNPTIGSFDIKSFNELRPGLILWLLCNISSACEQLTRRGTLIPTDSMGLVLLFQGLYVADALYNEPAIFTTMDITTDGFGFMLAVGDLAWVPFTYSLQARYLAFNHVELGPFWTCIIFVIHAVGYWIFRGANNEKNDFRNGKNPKNLTSLQTERGTRLLTSGWWGMCQHPNYLGDWIMSVSYSLPTGFNTPITYFYCIYFLILLLHRQTRDDDHCRKKYGKDWDTYTSIVPWRMFPYIY
->UniRef90_UPI001CF80729 YggS family pyridoxal phosphate-dependent enzyme n=2 Tax=Dechloromonas denitrificans TaxID=281362 RepID=UPI001CF80729
-MRKGSDDGETRPVSSSGTPPRQDELGRYPRPSSLEDFRRNLAAVRARIDAACRRVGRDPASVRLLPVSKTVDEGQIRLSYAAGCRLLGENKVQEAHRKWQAMADLIDLRWSVIGHLQTNKAKWVARFAAEFQALDSLRVAEALERRLQIEGRSLDVFVQVNTSGEASKYGLPPADVQAFLQALPGFPALRVRGLMTLALLSGEAERVRQCFIRLRTLRDQLRQSAPVGTCLDELSMGMSGDFEIAIEEGATVVRVGQAIYGARALPNSHFWPSETNTRESP
->UniRef90_UPI001010A2DF DUF58 domain-containing protein n=1 Tax=Cellulomonas endophytica TaxID=2494735 RepID=UPI001010A2DF
-MVLTGRAVLLAAAGVVALALVPSAGTVLVWAVLVALVCVVDALLAASPRRVAVHREVPASVRLSQSATCTLTVTNVGPRRLRGLVRDAWQPSAGAVVDRHRVDLPPGEGRRLRTVLVPTRRGDRRADLVTVRTVGPLGVAGRQASVPVPARLRVLPEFASRRHLPSRLARLRELDGRSAVQVRGAGTEFDSLREYVVGDDVRSIDWRATARRNDVVVRTWRPERDRRVLLVLDTSRTSAARVGDAPRLDAALEAALLLAALASRAGDRVELLAYDRRVRARVVGASGPRLMPALADALAGVEPTLVEADWPGAAAQVRERLSRRALVVLLTALEPAAVEAGLLAVVGPLAQRHQVVLASVADPEAEDLRRGRGDAAAVFDAAAAERAGLERAAVALRLRQRGVEVVDALPDDLAPALADRYLALKAAGRL
->UniRef90_A0A7J2IPL5 (Fe-S)-binding protein n=1 Tax=Candidatus Bathyarchaeota archaeon TaxID=2026714 RepID=A0A7J2IPL5_9ARCH
-MSSKMYELFKKTLEKYLPGKGVTKRITPDQLELKRFEDLEHYKDVLYFCGKCGQCRYVFQEAYWSRVCPSGELKKFEAYYLGGKNLLLWGVLSGKLKWTENLAKILYHCTLCGNCTQQCQIPEIHHYALEWLFAARIESVKRGIAPMPEHRKFGEWTKKEHNPYMELHTDRQKWISSDIRRELPEKADIVYFVGCTSSYREIQVAKAMLDILTSLKLNFTILKDEWCCGSPLFWTGQIDIAKECAKHNIEEIEKSGATIVVTSCAGCYRMIKEIYRNKFGLEYSFEVLHAPEFLLSLVKDGTLPLENEISEKVTYHDPCHIGRHMGLYEPPRELLKNIPGIELIEMTRNRRNAWCCGAGAGVKSAFKDLALFAAHERLKEAQSTEAEILATSCPFCERNLRDAAKAYNVNIKVVDIIELIKYSM
->UniRef90_A0A2E3V0Q5 Response regulatory domain-containing protein n=7 Tax=Chloroflexi TaxID=200795 RepID=A0A2E3V0Q5_9CHLR
-MNNLSEKNRNQKILIVDDEHMSDLMRSVLRRLEVDGFNTIVVKPKGNMGTGDEYEIQTLFALEEHHPDAILLDVRFGEYDTDRFKGLSILKKIVERNNKIPVLMFTQYAQGPYRDTAVTATLSVDANVDFIDKLASPEEVVLRLRRLIGSSPEKVMIGDIFEIDSDNSAVYAIVDGKKEIVKDVQGMKLEILKELAAALYRSEGELVPFSKLERFSFGEDSRASLRVRIRELKISLGKSIGREFSANELIINVRNRGYRLIHPE
->UniRef90_UPI00189E7165 hypothetical protein n=1 Tax=Halomonas sp. KAO TaxID=2783858 RepID=UPI00189E7165
-MASRTSASLSPQAPLSRHLRSSLRLSRWSGQSSPRLPRLIEPAFHLEVEFDAESGELVGMERVRIDAMRRREEAP
->UniRef90_UPI0006E14DC3 hypothetical protein n=1 Tax=Streptomyces neyagawaensis TaxID=42238 RepID=UPI0006E14DC3
-MTHPTAVPLAVASLEPALLFAAAAVLTVLAVPSGVWLIRRRPTRIGRERPTAPAVWVAALAAIGCTAYSADTSWRFAADYLDMAGTTERAAMFAAAELALFATALMARQNLASQGAPGLPGVLVWIITGVQVIPAYAESGPIGGTVRAFVGPVMAAMLWHQAMGIELRLRKPGASSRGVTATLGREARERLLSRLGIAERDRDAAQITRDRATARAVTLATRLAGRTPKQRGNWRGRRITRRLQGALARADVGTDPEQLGVLLDQLAARRHATALATVDLPSPWTRPLLSPPHGRRDQPSLAPHQVAVGDQVTPQCHAVPKAGPETKMDSPRIRDRPEEGHMGPALGTEPAGDGDRPRPVPETGDRGAAGDLAADAAAGHGAKGDQASAVPGTEDAQDGDETSEGDGDKTAAQGSDIPSRTPFPYNGDHLVPRTETGAGTESTGDRPQTVPARRRPKASRTRTRGGQGKPSRRQPQLSVDQLVTQLRPHVPRLLERDGNAEVTRTQLREIMRAHNIGIRNDRLTPVLERLRREAATSTTKKRSAR
->UniRef90_UPI0005A97BD1 hypothetical protein n=1 Tax=Streptacidiphilus anmyonensis TaxID=405782 RepID=UPI0005A97BD1
-MSSAVLATRETSAAPRSGLRPRGVTWLTWRQTRAALLVVTLGYAAALAYLLYQHHQFDVTTVRLRGLHCSTDTRDPVSVITANCNLAALAVMQAASGVHRLATVALAAPGLLGAVLAAQPLAVDLERGRHRLLWSQSVSPRRWFTQRMLLPAAILLVLSAVLSVALRWAVLWTHPALPIEDWSFDNASDALAPVYPLLTLAAFALGAVVGLLLHRVIAALGITLALYGVLLYGMAQVRPYLVPLHRKVVGPGDPWPSGDWVYDSGPVVHGKDFSYSACPVATGCDKEPSWILYHPLSQFGPMLWVETGMLAALTAGLVALAYRRLLALTR
->UniRef90_A0A5B9QW56 Alkaline ceramidase n=1 Tax=Roseimaritima ulvae TaxID=980254 RepID=A0A5B9QW56_9BACT
-MTHPPKSLKPHPGFKGRIGIAREDITPPVGIYSRNWGAAQHDTADSIHRPLTLTALTISASSTDEPLILIDADLGWWRPLDLFQQFQQRLLEELSLESSRLIFALTHTHAAAPLMKPDPALPSSEPLGPWLERVYQATVSAIRRALADADEAILDWHHGRCALAAVRDFPDPDPAANRILCGFNPAAVADDTLLVGRITDASGTVRATLVNYACHPTTLAWANTTISPDYIGAMRETLEAATGATAFFLQGMSGDVAPKHQYVGDVEVADRHGRQLGFAALATLQDMQPAGRQLYFDEVVESGAPLAAWRHRPHALSSELRAVEIAADLQIKDWPTAEELEQQRLACEDRALEERLRRKRDIRRSLGDGSSSPLAVHAWRIGDAVLVGCGGEAYSQLQQELRSRFPELAVICMNLINGSVGYLPPADLYDVDIYPVWQTPFARGCLEHIRETMTSAIEELVR
->UniRef90_UPI000D340775 DUF1566 domain-containing protein n=1 Tax=Muricauda amoyensis TaxID=2169401 RepID=UPI000D340775
-MNKTSKLTHLFILTILLIGFGCSNDDDAGSPISLEDLAVSMDENPSNGQTVGMVETVGGTAMNFSIVSQSPAGAMDIDSSSGELTVANASLFDYETNATITATIDAENAENTATITVTLNNVNEVSAQALEVTMDENPTNGDVVGSLQATGTASGFTITSQTPAGALTIDSATGELTVADATLFDYETNPTLTATVTLEDAQNPVTVTVNLDNVFEVTVQDITLSVDENPTDGQVIGIVQTSGATATNFNIVSQTPNGALNIDAATGELSVVDPNLFDFETNPTITATVIVDDAENPATVTINLNDVDEITVQPGNFTIDENPSNGDSIGTLQATAGSSLTYTITFQNPVGAFSIDQNTGELFVADETLFDFEANPNMFATISVDNGTYSVSANVFVALNNLNEIGEFKYGGVIFWIDPADNGHGLVSAITDQSTSATWGCQGTLISGTGTGIGSGDTNTAAIIAGCATPGIAADIASNTTIDGYSDWFLPSRSELNQMYAQKAIIDATAIANGGTAFPPSVFYWSSTEANSNTAWAVFFDNGNNGGFNKGVSTFYQVRVVREFDLGN
->UniRef90_UPI0013DE5835 hypothetical protein n=2 Tax=Pseudoalteromonas TaxID=53246 RepID=UPI0013DE5835
-MKVTLNKKSIKSLSANPATIIRAQETPQIGGGRVIDESFWVCINTRSNCEGTKRCPFD
->UniRef90_W9ZDG4 DUF4097 domain-containing protein n=1 Tax=Fusarium oxysporum f. sp. melonis 26406 TaxID=1089452 RepID=W9ZDG4_FUSOX
-MDFSSFDLPFTIAEDHTAQPVSTGSAYDFRETIDGTLARRSLANTPDCLISKLAGLKLDSSSAVFRSRIVAVANEDKGVMVKGDGKPIDLLSGSLSIEQVPDKPSFSISSDKVAIQGYYLPGEDDVIIHGHGHDNNELEIAKYSSATGKMASPRVVGTQFRLDDGVWQVSEPSGMQFHLYVFPKTYFLHLTSKPSKRPRLEDGESTPRP
->UniRef90_UPI0010938F88 DUF3108 domain-containing protein n=1 Tax=Mesorhizobium sp. M4B.F.Ca.ET.172.01.1.1 TaxID=2563950 RepID=UPI0010938F88
-SSRYENGVYSIDGSVSAAGLAKRFDDTRGTISSKGTISSQKMVPQAFRADYTSGKKASLVDIRFGNGNVTSTKVVPAPEKRDPKSWVPLGAGDLKSVLDPMAA
->UniRef90_A0A095C0S5 Integral membrane protein n=5 Tax=Cryptococcus gattii species complex TaxID=1884637 RepID=A0A095C0S5_CRYGR
-MKENYAVENALGTIGAVLWMVQILPQIIKSHREKTTKGLSASLMFIWALASFFLGAYIVAQKLSIPLQVQPQAFGVLAAVSWCQCLHYERGYSLKSVWAIFIAFCCVFAGFEAGSVYALWAGQRNGVEWPVLMYGYISAVLLAVALLPQYWEIYKYREVIGISLLFMVVDILGGVFSFLSLFFRNDLDIAAFVSYSLVVVLDGIVVILYFILNPIAERRRARQAGRHSDSEAKIEGSSSVGMSTVPTLVGHGLMIDKEVQDGDRRQDNVRVDSEMEQSRVDDRDKMKAGGAEVEVHGPDAQGHETTGSSGEHSEESVKTIK
->UniRef90_D7WDM9 Glycogen synthase, Corynebacterium family n=7 Tax=Corynebacterium TaxID=1716 RepID=D7WDM9_9CORY
-MMTREYPPEVYGGAGVHVTELTRFMRDIVDVDVHCMGEPREGENIYVHGVDPELTEANGAIKTLSTGLRMAHAADNVDVVHSHTWYTGLGGHLAGLLHGVPHVVTAHSLEPDRPWKREQLGGGYDISSWSEKNAMENADAVIGVSTGMKKAILEAYPNIDEDKVHVVLNGIDTEDWHRVAPSDAESNGVIERLGVDTSKPVVAFVGRITRQKGVPHLVKAAQDFDEDIQIILCAGAPDTPEIADETQALVDKLREGRGGVYWVTDMLPKEEIREIYSAADIFVCPSVYEPLGIVNLEAMACETAVVASDVGGIPEVVVDGETGTLVHYDKDDTETFEKDLAEAVNTLAADADLTKRYAQAGLARVKKEFTWDKIAQETVDIYKSLI
->UniRef90_A0A0K6GGW7 DPBB_1 domain-containing protein n=1 Tax=Rhizoctonia solani TaxID=456999 RepID=A0A0K6GGW7_9AGAM
-MRSTQILAVLAVLATSVSSMSIGHVPNQLTHRRHAAEVHESVIQARGARRAVFAQNTPEMAKRDDAPRRRKRGINQRRCAPKTTTGLPQTASVPSTSSAAPTSSAAPTSSVVPTSSAHTTSAASATTPEPEPTSSQAETTTSAKAKYTKPSAQTPTKTSTSVKPTATDDDSGSSSGSTYTGQATYYGTGLGACGITSSDTDYIAAASQLLFDGFDGYKGSDPNSNPICGKKVKANYQGKSVTITIVDRCVACAKYDLDFSPSAFSQLADQALGRLSGMTWSFIS
->UniRef90_A0A1Y1CLL0 PAS domain S-box protein n=1 Tax=Labilibaculum antarcticum TaxID=1717717 RepID=A0A1Y1CLL0_9BACT
-MVEQKVLRSRILELLFKGESESAILNELVHQAQLIASDSICSILCVDEKGKRLLLGAAPDLPDFYNKVIHGTPIRHGVGSCGTAAFTGERVIVEDISTHPFWKNVKNLAKEADLGSCWSEPIKDPSGKVLGTFAIYHRTPNSPNPKDLELISELSDLTAIVLDRYKIIKRLEESENKYKVLANAGNEAIFILEGDKIVEVNKRAEIITGYSEMELSGMSIYNFLAKEYWITPYSDESRKFRHKIKAVGVNKNGLNVSVIVRIKNSTFKGKVVCLLSVRDVTNYINAKIELSKLSQSIIQSPVSVVITNVDGDIEYVNPKFNKLTGYSLEEVIGENPRLLSSGNNKAELYKSMWQEIKSGNVWRGEFQNKKKSGELFWEFATISPLKDDREQIINFIAVKEDITDRKRQEQIQRIILNISNAVFTQMTLVEFIQFIREELSSIMDTTNFFVALYDDETELFSLPFHDDEHDSFEKFPKGKTISGWVVDHETALLATAEKLDELEAKGEIDLVGEPSKIWLGMPLKGKEKVIGVLVIQSYIDENVVTEEDKNMLELVSQQISISIEQKRTEQELHKALRDATESDRLKSVFLATMSHELRTPLNAVIGFSELINNEIDLETAVEYSKMVNQSGQNLLNIVEDLFDISLIQSGAVKIKQENYSLLNLFYEISAVINVEQKVLNKEHIELKINFPSDYNDFFIKTDPHRFKQVYLNLLKNALKFTDRGSIEYGFTKSDLKSGIVLQFYVKDTGIGIPEEVQESIFGLFRQANEKLSRKYNGVGIGLSISKSLTELLGGKIWFDSIPEEGSTFYFTHPIK
->UniRef90_A0A2N8BAE4 Mandelate racemase n=1 Tax=Pseudomonas sp. FW305-25 TaxID=2070636 RepID=A0A2N8BAE4_9PSED
-MKIISIKVFQFDVPLKEKYSLSGGRLQYASLDTTIVLVTTDSGLVGVGESCPWGATYLPAYAKGVRAGIDELAPHLLGENPLHLDQLNERMDVMLPGHPYVKAAIDLACWDILGKHCQLPVYTLLGGRFQDSVALQSSIPTDDAAQMMAHLERARNQGYRTHSCKVGTGIDDDVAQIKYLLDQRVPGEVITFDVNRAWTVAEAVAVMNSVADPTVCFEQPCESMDQCRAVRELTRNPIILDESIVTFADLVQAQRQNIAQLIGLKIGRVGGLTKARQMRDFCIHHGIRMNIEDVGGTQVSDSAVMHLAASTPRRFHRASWNCCRHHEVQLAEGSFDIRQGRAYLHDSPGLGLTLDPRQFECPIAQYS
->UniRef90_A0A8G2BJ52 Transmembrane transcriptional regulator (Anti-sigma factor RsiW) n=2 Tax=Thalassobaculum TaxID=526215 RepID=A0A8G2BJ52_9PROT
-MSTRNGNGTNGSGSIEDWEVGAYVDDELSPQRRREIAAAAGASPELAARIEVYTRHKSLLAGLASRPVDDEIPEQMRAAATRLSRATTVHGWMRRGRQVMVAQARIAAVLVIGAVVGWTAQEILAPRPGNATDGPLAFIDEATEAHRTLALAPMFATDVGSVDFAKLSEMFSEGIDPAGLRANGLILSKVDMASTDQGPAVQFLFFDREARPVSLLLSVNSASLHSVGVPDGEMVVTSYNDFAVAFGRRDSIAFVVTAALPERRVGEIARQLVASAGF
->UniRef90_UPI001B3A3E04 LPS assembly protein LptD n=1 Tax=Pseudoalteromonas sp. MMG010 TaxID=2822685 RepID=UPI001B3A3E04
-MNKSWGILMLSVVSTSSLADTELTHKLCGVSMLTRTWQPMQGLELGTVDIKADEVEFLGTQSAEFNGNVDINTLDMSLSAQSALLDKERSLLNATGPITYQNSVSTVHSTGLNADLNNSEISLLGANYNLTEQLGKGGAEKLTVNNSGLLLMNASFTACPGEIPVWAIEADEINLSREEGWGETYNAVLRILDTPVLYLPYFTFPLDERRKSGLLTPSFSSSDSYGLETITPYYWNIAPNYDATITPRYMSRIGLQLQTEFRYLTDTSKGLVGIEYLNEDDSEPELDSRYMFHWQQKSYFGENWRASVDITNVSDDNYLTDLTSNYANTTDTQLYRTGALTHLGDTWRTDIKIQSFEVLGDHDESYTALPQINFTQTAPWRINHFDFSISGELSHFINGSTEVEVDEATRLHIEPKVRFGYEQYAWSFLSEVSLLQTNYKQHGDLDGTQYSSSVSRTLPKVRLYSQLNFERDTSFFFEDGIQTLEPQMQYLYTPNKDQTDIALFDTVNLQEDFFGLFRDTRFSGVDRIAGANQLTIGATTRLFSSKSEEVFNFSAGQIFYLSDSAKPTEQGITEETNYNALFAAQTMVHWHRRWYLSGGIQYDTDGKQMIQSNVTLDYKGDNNQLVQLNHRYANDVSGNTIEQVGMFTSVPISDEWQFIASYHKDIENKRSIEVLTGLQYESCCWAVQITGQRQIKTDLNQAIDQDQATFDSSIRLNFVLKGLGSKSSYDAQKLLQQSIFGYRRPYFLNN
->UniRef90_UPI0016098D3D hypothetical protein n=3 Tax=Rhizobium TaxID=379 RepID=UPI0016098D3D
-MQNALLDYADLISLLTAVGTFVAIVAGVVELIKARREHVRAKEQEFNSSYLTISDAYHQLLELSVEYPHLGIFPWQEEPADLSPDDLVRRDIFYEMMISIFERAYLERHKTPEIAEHFWPGWETFLRRQIEKPSFRKYWGIFDGEGAFGAYDKRFEAFAKRLDGGLPGQDGV
->UniRef90_A0A3N5IFY8 Peroxiredoxin (Fragment) n=1 Tax=Planctomycetaceae bacterium TaxID=2026779 RepID=A0A3N5IFY8_9PLAN
-MSDWLEPGTPMPSFTLADHTGAKVKSSQWKGKPLAIYFYPKDDTPGCTKEACAFRDASQPLEK
->UniRef90_A0A2Y9K040 AP-3 complex subunit sigma-2 isoform X3 n=13 Tax=Boreoeutheria TaxID=1437010 RepID=A0A2Y9K040_ENHLU
-MIQAILVFNNHGKPRLVRFYQRFPEEIQQQIVRETFHLVLKRDDNICNFLEGGSLIGGSDYKLIYRHYATLYFVFCVDSSESELGILDLIQVFVETLDKCFENVCELDLIFHMDKGGLSAAPARAVSAVKNINLPEIPRNINIGDLNIKVPNLSQFV
->UniRef90_A0A379GMX6 Inner membrane ABC transporter permease protein ydcV n=7 Tax=Morganellaceae TaxID=1903414 RepID=A0A379GMX6_PROST
-MNTIKTNNGQKVVKISLIFFIFINVVWLGLPFTMAILWSLVDPQHPWSYPDLFPQKLSLARWKIVWEQTSLATALFNSYTIAPAVAILSLLLATPTAYAFGRMTFKGKAVAEMLTLIPLVMPGMIIGIFFSSMLISLNISNTFMSIVIGHTVLTLPYSIRIMSAGFKSIPQDIIDASRDMGASFWGTFCNAFLPMLKPSLLASLIFCLVRSLEEFSISFVLGSPDFITVPTILYSFLGYSFVRPDAAVVSMILVIPNVILMIIIERLLKGNYLSQSTGKA
->UniRef90_A0A382A9E5 Swi3 domain-containing protein (Fragment) n=1 Tax=marine metagenome TaxID=408172 RepID=A0A382A9E5_9ZZZZ
-LRPTPGRKDKEHDDGGLNENNDDEEDLEESLKISIKMPKASLFESAGFNVKQQKKVASIFESAIKSTTRQVGKQIHEHYSKVHKKRLAEHQQLIENRLNTYLDVVVEEWVETNRPAVRSSLRTELSENFLNGLQKLFTEHYIDVPESKTDVVKSLTQHVETLKRQVNEQYTEKLKLHRLAETANKKRIVATFARDMSESQAGKLEKLAEDTQYVNANDFREKLSMLKESYFEKQPSRATRLPEENVQEVTETGVAKGEADMVADAITRQAKSSDW
->UniRef90_F8A565 histidine kinase n=2 Tax=Cellulomonas gilvus TaxID=11 RepID=F8A565_CELGA
-MSPAPGTRWGLAARLLAALVVVLAVAAFTAWLVASAVGPGLFHEHMVRAGLQDHDSAVLHAERAFRDASAVSLALALGAAAITSAAVSVVLAGRIGRSLATVSKAAARLGAGEYESRVPAAGLGAEFDDLADSFNTMAARLRDADRLRARLLADVAHEVRTPVATIAGYLEAVQDGAQPMDEATMTVLADQAARLTRLAQDLAAVTRAEAGDLVLNVEPVPTRDLLEQTAAAWRDRAAAAGVHLALDPDAGSGAGPVAVDRHRIAQVMDNLVANALRHTAAGGTITLRARAVDDPSRVALAVRDTGKGIAPEHLPHVFERFYRADTARDRASGGSGIGLAICKALTEAHGGTITAASAGVGAGATFVVTLPAINSGP
->UniRef90_A0A651I330 T9SS C-terminal target domain-containing protein n=1 Tax=Saprospirales bacterium TaxID=2026790 RepID=A0A651I330_9BACT
-MKSSFFLLPLLFFGTLNMCFSQVPFIEVLNPNEVSLDSTEAVRYDSIVGFGENYQKYLIRINPIQNYVSLDTITISIPLAEIGEIQFVTTAIEYRNDSSFSLTGYNLSGGFLNFTLLESEIGANMFIPESQSLYQFNSISESYAVMLRYPNWTGFESIGCITTGEDGDQEDYYPDEFSGPDSLNYAQERSICDHNRIRVLVLFTTQGRNESFLRGSNMNRDAQRLIDELNLSIANTGISRSRISFALADTRLLGSFVEDDEDEDIQGDVELLSNNQEAQEMRDEVLADIVVLITGNVYGNIFGVARDIRASESRAYAISTYEFTFNGNLTGTHEIGHLIGTRHQRCRRCPSACDPKWSKYKGYKVGSDMRTIMHVQGCGRTRVNVWSSSGAKFMGQSTGNTNNRNSGILKNRASKVACFREGVPPIPPPPPLSIYYIEGPLFLCPDNAFPQYEVHYNQNVFQNPIFNWDISENGLFNWTTIIGKIKNGNPVTLTQPNNLPDVFWLRATVSDPSGTTASTTIQVRKRDEPYSCNTFLRILREANEQDGTNSEYILYPNPTNNDIFVSGIVGKVWYKIFSSAGELIKIGTDNLSKDQELNISLTYFPAGLYFMELIMENNESHVMKLVKK
->UniRef90_A0A4S8PU73 DUF4240 domain-containing protein n=1 Tax=Glycomyces buryatensis TaxID=2570927 RepID=A0A4S8PU73_9ACTN
-MDTTKALKKGRNLIPDEVFAKLVTRIEAEHHFDADMAARCVDQAAAYLAACASSTAPLSPSMAADIGWHMFILHTRDYADFCEQVAGRFIHHVPHDEPAEQSTEDVQAILDRSSAAIRKAGYQVDTELWRADGGAGKCNGCHSGCHDDPAPVPPFHEG
->UniRef90_UPI0018E12798 fasciclin domain-containing protein n=1 Tax=Aquamicrobium zhengzhouense TaxID=2781738 RepID=UPI0018E12798
-MRMTFALAAGLIAIAIPAHAQDKDIVDTAVAAGEFTTLAAALDAAGLVQTLKGEGPFTVFAPTDAAFAKLPAGTVEELLRPENKEKLAAILTYHLVPGKVMAADVVSLDEAKTVNGETIEIQVDGNSVRVNDASVTATDVAASNGVIHVIDQVILPPEG
->UniRef90_UPI0010459B45 aminoglycoside 6-adenylyltransferase n=1 Tax=Streptococcus downii TaxID=1968889 RepID=UPI0010459B45
-MRTEPEMFDVILQIAKSLKVEAVAMSGSRTDTKAPKDEFQDYDVVYVVDDLDNLTSDLSWLDQFGTRIIEQHNVLGNRRLYLMLFEDGNRIDLTLCPTEYIQEWVDSEAGFTVLEDPKGLFAPYSPSPQRYWISLASQTDFEKACNEFWWVSAYVVKGICRKQVIYATDHLYGICQQELLKVVAWQVAADNGTVDVGKNYKYLFQYLPAEKEKEFSALLDFSSVEKLIQSLFATMQLFHQEAQFLANKMGFDYDKEVAEKMIQYAKERLN
->UniRef90_UPI000E3E49EC hypothetical protein n=1 Tax=Paraliobacillus sp. X-1268 TaxID=2213193 RepID=UPI000E3E49EC
-MRNVRGAKELSKYLESIGAPISESTIFSLLREGKIPHQRPSPRILIFNLNAIDEWLNLK
->UniRef90_A0A286TUH0 Signal transduction histidine kinase (Fragment) n=1 Tax=Candidatus Scalindua japonica TaxID=1284222 RepID=A0A286TUH0_9BACT
-CELGKEGAFIWVNQTAAEMFGYKSPEEMIGTKVNEIYVNIDDGRTQLEMLEKHGVLSNTVYLCKNKSGDCFYAECTSHLVKDKKGKQCRIEGIIRVITERKKSEYRLIAQHAVTKILSESETIKIAFQGILKVICEALDWDFGSLWLEHDNVLRCVYLWHVPGLQFSEFKKKTKEISFLPGIGLPGRVLSKGKAAWIKDVVVESNFPRATAASKVGLHGAFAFPIIANTEILGVIEFFSQKPEEPDKELLNMMEAIGSQVGQFIKRKQADEQVSKLSRAVEQSPVSVVITDTKNNIEYVNRKYTEVTGYSLEEVKGKNPIVLKTVEENVEEHKELWKTITSGKEWQGEFCNFNKNGEIYWESESISPIKNCDGIITGFIQLKEDITERKLVQSHLKTQLEVAKVLAESNTIREASTRIIEVVCIALGWDLGEVWIYDKQQYILRNTEIWHLPSLNFSEFKDITCRTTFSPQKGLPGLVWQTAKPLWIEDVARDSNFLRASVADKEGLHGAFGFPIAIDNVVLGTICFFSREIRRPDDKLLNMMSSIGNHIALFIERKQADEQISKLSRAVEQSPASVVITDTKGNIEYVNRKFTEVTGYSFEEVKGKNPRVLKSDERNSVDYKELWDTISSGKEWRGEFKNKNSDGKAYWEFASISPIKNNQGVTTGYIAIKEDITVHKNLEQQLMHAQKMESIGHLAAGIAHEINTPTQYIMDNTRFLQDSFNDINKLLEKYSHLLETCKSGSVESELIEEIEVAVRELDEDFLVDEIPNAITQSLEGLDRVKNIVYAMKNFSHPDNENKKPIDINKAINNTITVARNEWKYVAEVKTDFDSSLTSVPCFPGEFNQVILNLIVNAAHAIGEEPGNGNEGKGIIVISTLCDGEWAEIRVSDTGTGISGDIRKKIFDPFFTTKEVGKGTGQGLSLVHSTVVGRHNGTITLDTELGKGTTFIIRLPLCTSSSEIVKV
->UniRef90_A0A2N9EE18 Myb_DNA-bind_3 domain-containing protein n=1 Tax=Fagus sylvatica TaxID=28930 RepID=A0A2N9EE18_FAGSY
-MGTGIYAREDAKLWPARLEKLFIDIMVEEMHKGNMPMGIFKLKTWCKILEELNLRSKQSFKLKQVKAKYNRLKQKYRVFSQLLQQNGFVWHGETNSVTASDEVWESYLYANPDAERFREKGCEHYKLLGILFNKLIAMGFMAFASTQDAPDTDEERELDEAYRNGAFIDVDSDSQDDHEKKVSQKRTKRSGKCPMRSEAKGRKRSRKADEFSELNDAIRAFAEQTKLMLEAKVARMKEKEKRKQQRDEFSIPNCVNALESLGDLDMNTYTLAIKKFSTAEWREAFMSLSSNARKKAWLDCLK
->UniRef90_L7LLZ8 Phosphoribosylformylglycinamidine synthase subunit PurS n=9 Tax=Gordoniaceae TaxID=85026 RepID=L7LLZ8_9ACTN
-MARVVVDVMPKAEILDPQGQAIVGALGRLGFAGVADVRQGKRFELEVDGTVDDAALERIAEELLTNTVIENFNVTRVAE
->UniRef90_Q1IWN5 Nitrogen regulatory protein P-II n=7 Tax=Deinococcus TaxID=1298 RepID=Q1IWN5_DEIGD
-MKLITAVVRPERVQQVKAALFEAGISGLTLSRVSGHGGEQEIVEHYRGTRVMVEFRDKVEFRMAVSEPFVEVAIRAICESARTGEVGDGKIFVQPLERVVRIRTGEEDNAALTPVTETRLTPGLPVRHAR
->UniRef90_A0A534D3W2 Lipoprotein (Fragment) n=1 Tax=Gammaproteobacteria bacterium TaxID=1913989 RepID=A0A534D3W2_9GAMM
-MFREKRFVSLVLGVSLLAPGCGESTESVSPLQTLPASRGQLLNNPPTKLGSFSVSDLLSRLSGSQMGRELIKLAFSPTCSVDT
->UniRef90_A0A2G2QLC1 C4-dicarboxylate ABC transporter n=1 Tax=Cycloclasticus sp. TaxID=2024830 RepID=A0A2G2QLC1_9GAMM
-MVSENKLPLAVVFLFLMLGVIWWPSFSNLGDLFGYAAKAEYKGVSLLNFFRAELVVLVTVWAVLISYKEQNDMVDGNAYVTRFLILVMFVIGQVFMGFFAGGFLVHQDASWYQVIHEANEVMPSQAVILLVCYPLYLFFGGSAFIYAKTRLPKFLKGKEFSFMVLTFAPLAFLPYYDSSFMQAKKDLFEIAYLSVYWLLSVGWVVIGVLYIILKASQGIFKGLSDPYGEM
->UniRef90_A0A562TCA1 Toprim domain-containing protein n=1 Tax=Chitinophaga japonensis TaxID=104662 RepID=A0A562TCA1_CHIJA
-MKKLMCAEAKQIDLVDYLASLGHRPQKVRNQDYWYLSPLREEKTPSFKVNRQLNVWYDHGTGKGGDLIDFGTLYFGCSVSDLLDRLSHHQPAPSLSLHPPTHASRQHSGPASFAGERKDASGSRIVILDARPLAEPSLLEYLQKRCIPLEIATRFCKEVDFLLYGEKRTVIGFRNNAGGYELRSGNFKGSSSPKDVTFIDNHAGEITVFEGFFSFLSFQTINNNQQDTVSNCLILNSLSFFEKSRPLMEQHGKVHLVLDRDAAGIHHTQKTLQWDRDKYQDRSDFYHGHKDLNEWLVHHHHSQKEPQRLRRRP
->UniRef90_UPI0017892BBC TlpA family protein disulfide reductase n=1 Tax=Plantactinospora soyae TaxID=1544732 RepID=UPI0017892BBC
-MRRPRRARLGALLAVAAALALALVGCSGEDDWKDDCTTKGGVIECAPEHRPQAPKVTGELLSGGNYDLAQDRGQVAVINFWGSWCAPCRAEADDLEATYQATRERGVRFIGINIQDGRDKARAFEEAFKVTYPSLFDPPSRLALAFDIPPNSIPATVVLDREGRIAVVIRTAVTRETLEPILTRVAAEQAAPGGGPN
->UniRef90_A0A3M8TKU5 Tail assembly chaperone n=2 Tax=Pseudomonas putida group TaxID=136845 RepID=A0A3M8TKU5_PSEPU
-MKQPERITLVLRASEAAPLSSILPFTKLGDLVSAGRGLAVIAGFSEGDLQARLAECEAQLQEADVLLREAIAYVNDELVNVEYRDILIARIDRLLDRDQAQQAEKPREQEP
->UniRef90_A0A357MHW4 SseB domain-containing protein (Fragment) n=1 Tax=Rhodobacteraceae bacterium TaxID=1904441 RepID=A0A357MHW4_9RHOB
-MTEAPKTPETPETALDAAHAAMQAAPADDAARLRFFERVADSELFLLLKREASGDQVDPESFELADGTFVLAFDREERLAAFTGRASPYLALSGRVLARMLAGQGIGLGLNLEVA
->UniRef90_UPI0004CC520E alpha-L-rhamnosidase N-terminal domain-containing protein n=1 Tax=Streptomyces cellulosae TaxID=1968 RepID=UPI0004CC520E
-MTYTDGSATSLVTDKDWLTADGPTTFDQVYSGEKDDARRADELEEWRSAGHRAARAGQLLRTVPRVPRHACRGDYPRRPSAAHSGLVQDRVDDLSHLVPALMTADRAVLSLPGRDDRPDQLPRLQVALAPAPRTARTVAAADHAG
diff --git a/src/alphafold3/test_data/model_config.json b/src/alphafold3/test_data/model_config.json
deleted file mode 100644
index 867032a1387e83e6e1e528d6fd7f30a48a66117e..0000000000000000000000000000000000000000
--- a/src/alphafold3/test_data/model_config.json
+++ /dev/null
@@ -1,230 +0,0 @@
-{
-  "evoformer": {
-    "max_relative_chain": 2,
-    "max_relative_idx": 32,
-    "msa_channel": 64,
-    "msa_stack": {
-      "msa_attention": {
-        "num_head": 8
-      },
-      "msa_transition": {
-        "num_intermediate_factor": 4,
-        "use_glu_kernel": true
-      },
-      "num_layer": 4,
-      "outer_product_mean": {
-        "chunk_size": 128,
-        "num_outer_channel": 32
-      },
-      "pair_attention": {
-        "num_head": 4
-      },
-      "pair_transition": {
-        "num_intermediate_factor": 4,
-        "use_glu_kernel": true
-      },
-      "shard_transition_blocks": true,
-      "triangle_multiplication_incoming": {
-        "equation": "kjc,kic->ijc",
-        "use_glu_kernel": true
-      },
-      "triangle_multiplication_outgoing": {
-        "equation": "ikc,jkc->ijc",
-        "use_glu_kernel": true
-      }
-    },
-    "num_msa": 1024,
-    "pair_channel": 128,
-    "pairformer": {
-      "block_remat": false,
-      "num_layer": 48,
-      "pair_attention": {
-        "num_head": 4
-      },
-      "pair_transition": {
-        "num_intermediate_factor": 4,
-        "use_glu_kernel": true
-      },
-      "remat_block_size": 8,
-      "shard_transition_blocks": true,
-      "single_attention": {
-        "key_dim": null,
-        "num_head": 16,
-        "value_dim": null
-      },
-      "single_transition": {
-        "num_intermediate_factor": 4,
-        "use_glu_kernel": true
-      },
-      "triangle_multiplication_incoming": {
-        "equation": "kjc,kic->ijc",
-        "use_glu_kernel": true
-      },
-      "triangle_multiplication_outgoing": {
-        "equation": "ikc,jkc->ijc",
-        "use_glu_kernel": true
-      }
-    },
-    "per_atom_conditioning": {
-      "atom_transformer": {
-        "attention": {
-          "key_dim": 128,
-          "num_head": 4,
-          "value_dim": 128
-        },
-        "num_blocks": 3,
-        "num_intermediate_factor": 2
-      },
-      "per_atom_channels": 128,
-      "per_atom_pair_channels": 16,
-      "per_token_channels": 384
-    },
-    "seq_channel": 384,
-    "template": {
-      "dgram_features": {
-        "max_bin": 50.75,
-        "min_bin": 3.25,
-        "num_bins": 39
-      },
-      "num_channels": 64,
-      "template_stack": {
-        "num_layer": 2,
-        "pair_attention": {
-          "num_head": 4
-        },
-        "pair_transition": {
-          "num_intermediate_factor": 2,
-          "use_glu_kernel": true
-        },
-        "shard_transition_blocks": true,
-        "single_attention": null,
-        "single_transition": null,
-        "triangle_multiplication_incoming": {
-          "equation": "kjc,kic->ijc",
-          "use_glu_kernel": true
-        },
-        "triangle_multiplication_outgoing": {
-          "equation": "ikc,jkc->ijc",
-          "use_glu_kernel": true
-        }
-      }
-    }
-  },
-  "global_config": {
-    "bfloat16": "all",
-    "final_init": "zeros",
-    "flash_attention_implementation": "triton",
-    "pair_attention_chunk_size": [
-      [
-        1536,
-        128
-      ],
-      [
-        null,
-        32
-      ]
-    ],
-    "pair_transition_shard_spec": [
-      [
-        2048,
-        null
-      ],
-      [
-        null,
-        1024
-      ]
-    ]
-  },
-  "heads": {
-    "confidence": {
-      "dgram_features": {
-        "max_bin": 50.75,
-        "min_bin": 3.25,
-        "num_bins": 39
-      },
-      "max_error_bin": 31.0,
-      "no_embedding_prob": 0.2,
-      "num_bins": 64,
-      "num_plddt_bins": 50,
-      "pae": {
-        "max_error_bin": 31.0,
-        "num_bins": 64
-      },
-      "pairformer": {
-        "num_layer": 4,
-        "pair_attention": {
-          "num_head": 4
-        },
-        "pair_transition": {
-          "num_intermediate_factor": 4,
-          "use_glu_kernel": true
-        },
-        "shard_transition_blocks": true,
-        "single_attention": {
-          "key_dim": null,
-          "num_head": 16,
-          "value_dim": null
-        },
-        "single_transition": {
-          "num_intermediate_factor": 4,
-          "use_glu_kernel": true
-        },
-        "triangle_multiplication_incoming": {
-          "equation": "kjc,kic->ijc",
-          "use_glu_kernel": true
-        },
-        "triangle_multiplication_outgoing": {
-          "equation": "ikc,jkc->ijc",
-          "use_glu_kernel": true
-        }
-      }
-    },
-    "diffusion": {
-      "atom_transformer": {
-        "attention": {
-          "key_dim": 128,
-          "num_head": 4,
-          "value_dim": 128
-        },
-        "num_blocks": 3,
-        "num_intermediate_factor": 2
-      },
-      "conditioning": {
-        "pair_channel": 128,
-        "prob": 0.8,
-        "seq_channel": 384
-      },
-      "eval": {
-        "gamma_0": 0.8,
-        "gamma_min": 1.0,
-        "noise_scale": 1.003,
-        "num_samples": 5,
-        "step_scale": 1.5,
-        "steps": 200
-      },
-      "eval_batch_dim_shard_size": 5,
-      "eval_batch_size": 5,
-      "per_atom_channels": 128,
-      "per_atom_pair_channels": 16,
-      "per_token_channels": 768,
-      "transformer": {
-        "attention": {
-          "key_dim": null,
-          "num_head": 16,
-          "value_dim": null
-        },
-        "block_remat": false,
-        "num_blocks": 24,
-        "num_intermediate_factor": 2,
-        "super_block_size": 4
-      }
-    },
-    "distogram": {
-      "first_break": 2.3125,
-      "last_break": 21.6875,
-      "num_bins": 64
-    }
-  },
-  "num_recycles": 10,
-  "return_embeddings": false
-}
\ No newline at end of file
diff --git a/src/alphafold3/version.py b/src/alphafold3/version.py
deleted file mode 100644
index ff4c5f02286847675b762b4259731ec72fb29286..0000000000000000000000000000000000000000
--- a/src/alphafold3/version.py
+++ /dev/null
@@ -1,13 +0,0 @@
-# Copyright 2024 DeepMind Technologies Limited
-#
-# AlphaFold 3 source code is licensed under CC BY-NC-SA 4.0. To view a copy of
-# this license, visit https://creativecommons.org/licenses/by-nc-sa/4.0/
-#
-# To request access to the AlphaFold 3 model parameters, follow the process set
-# out at https://github.com/google-deepmind/alphafold3. You may only use these
-# if received directly from Google. Use is subject to terms of use available at
-# https://github.com/google-deepmind/alphafold3/blob/main/WEIGHTS_TERMS_OF_USE.md
-
-"""Single source of truth for the AlphaFold version."""
-
-__version__ = '3.0.1'
diff --git a/template-build-tags.yml b/template-build-tags.yml
new file mode 100644
index 0000000000000000000000000000000000000000..7e0b930da88fe6cb5f6736154bd73275300c9d61
--- /dev/null
+++ b/template-build-tags.yml
@@ -0,0 +1,30 @@
+stages:
+  - build
+
+variables:
+  GITHUB_URL: "github.com/google-deepmind/alphafold3.git"
+  REGISTRY_URL: "${CI_REGISTRY_IMAGE}"
+  IMAGE_NAME: "alphafold3"
+  REPO_URL: "https://gitlab.rc.uab.edu/api/v4/projects/${CI_PROJECT_ID}/registry/repositories/"
+  DOCKER_TLS_CERTDIR: "/certs"
+
+build_tags:
+  image: docker:latest
+  stage: build
+  services:
+    - docker:dind
+  parallel:
+    matrix:
+      - TAG: [ REPLACE_HERE ]
+  before_script:
+    - unset DOCKER_HOST
+    - echo "${CI_REGISTRY_PASSWORD}" | docker login -u "${CI_REGISTRY_USER}" --password-stdin ${CI_REGISTRY}
+  script:
+    - apk update && apk add git curl bash
+    - git clone https://${CI_GITHUB_USER}:${CI_GITHUB_TOKEN}@${GITHUB_URL}
+    - |
+      cd alphafold3
+      echo "Building tag {$TAG}"
+      git checkout tags/v$TAG
+      docker build -t $REGISTRY_URL/$IMAGE_NAME:$TAG -f docker/Dockerfile .
+      docker push $REGISTRY_URL/$IMAGE_NAME:$TAG 
\ No newline at end of file