comparison repex_full_clustering.xml @ 0:15b422443267 draft

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0:15b422443267

<tool id="repeatexplorer2" name="RepeatExplorer2 clustering: " version="2.3.7" >
    <stdio>
      <regex match="lastdb: can't open file: NEAR" source="stderr" level="fatal" description="Version of last is too old, use ver 956 or higher\n" />
      <regex match="Traceback" source="stderr" level="fatal" description="Unknown error" />
      <regex match="error" source="stderr" level="fatal" description="Unknown error" />
      <regex match="Warning" source="stderr" level="warning" description="Unknown error" />
      <exit_code range="1:" level="fatal" description="Error" />
    </stdio>
    <description>Improved version or repeat discovery and characterization using graph based sequence clustering</description>
   <requirements>
     <requirement type="package">last</requirement>
     <requirement type="package">imagemagick</requirement>
     <requirement type="package">mafft</requirement>
     <requirement type="package">blast</requirement>
     <requirement type="package">diamond</requirement>
     <requirement type="package">blast-legacy</requirement>
     <requirement type="package">r-igraph</requirement>
     <requirement type="package">r-data.tree</requirement>
     <requirement type="package">r-stringr</requirement>
     <requirement type="package">r-r2html</requirement>
     <requirement type="package">r-hwriter</requirement>
     <requirement type="package">r-dt</requirement>
     <requirement type="package">r-scales</requirement>
     <requirement type="package">r-plotrix</requirement>
     <requirement type="package">r-png</requirement>
     <requirement type="package">r-plyr</requirement>
     <requirement type="package">r-dplyr</requirement>
     <requirement type="package">r-optparse</requirement>
     <requirement type="package">r-dbi</requirement>
     <requirement type="package">r-rsqlite</requirement>
     <requirement type="package">r-rserve</requirement>
     <requirement type="package">bioconductor-biostrings</requirement>
     <requirement type="package" version="2.3.7">repex_tarean</requirement>
     <requirement type="set_environment">REPEX</requirement>
     <requirement type="set_environment">REPEX_VERSION</requirement>
     <requirement type="package" version="0.9.1" >pyrserve</requirement>
   </requirements>
    <command >
      export PYTHONHASHSEED=0;
      \${REPEX}/seqclust --sample ${sample} --output_dir=tarean_output --logfile=${log} --cleanup $paired --taxon $taxon

      #if $advanced_options.advanced:
      --mincl $advanced_options.size_threshold $advanced_options.keep_names $advanced_options.automatic_filtering  -D $advanced_options.blastx.options_blastx
      --assembly_min $advanced_options.assembly_min_cluster_size

        #if $advanced_options.comparative.options_comparative:
          --prefix_length $advanced_options.comparative.prefix_length
        #end if
      
        #if $advanced_options.custom_library.options_custom_library:
       	  -d $advanced_options.custom_library.library extra_database
        #end if
        
        #if $advanced_options.options.options:
         -opt $advanced_options.options.options
        #end if 
      #end if
      ${FastaFile}  >stdout.log 2> stderr.log ;
      echo "STDOUT CONTENT:" >> ${log} ;
      cat stdout.log >> ${log} ;
      echo "STDERR CONTENT:" >> ${log};
      cat stderr.log >> ${log} &amp;&amp;
      \${REPEX}/stderr_filter.py stderr.log &amp;&amp;
      cd tarean_output &amp;&amp;
      zip -r  ${ReportArchive}.zip * &amp;&amp;
      mv ${ReportArchive}.zip ${ReportArchive} &amp;&amp;
      cp index.html ${ReportFile} &amp;&amp;
      mkdir ${ReportFile.files_path} &amp;&amp;
      cp -r --parents libdir ${ReportFile.files_path} &amp;&amp;
      cp -r --parents seqclust/clustering/superclusters ${ReportFile.files_path} &amp;&amp;
      cp -r --parents seqclust/clustering/clusters ${ReportFile.files_path} &amp;&amp;
      cp seqclust/clustering/hitsort.cls ${ReportFile.files_path}/seqclust/clustering/hitsort.cls &amp;&amp;
      cp *.png ${ReportFile.files_path}/ &amp;&amp;
      cp *.csv ${ReportFile.files_path}/ &amp;&amp;
      cp *.html ${ReportFile.files_path}/  &amp;&amp;
      cp *.css ${ReportFile.files_path}/  &amp;&amp;
      cp *.fasta ${ReportFile.files_path}/ 2>>$log  &amp;&amp; rm -r ../tarean_output || :

    </command>
 <inputs>
	<param name="FastaFile" label="NGS reads" type="data" format="fasta"
	       help="Input file must contain fasta-formatted NGS reads. If paired end reads are used, reads must be interlaced  and all pairs must be complete. Example of input data format is provided in the help below. "/>
  <param name="paired" type="boolean" truevalue="--paired" falsevalue="" checked="True" label="Paired-end reads" help="Check if you are using pair reads and input sequences contain both read mates and left mates alternate with their right mates" />
 
	<param name="sample" label="Sample size" type="integer" value="500000" min="10000"/>
  <param name="taxon" label="Select taxon and protein domain database version (REXdb)" type="select" help="Reference database of transposable element protein domains - REXdb - is used for annotation of repeats">
    <option value="VIRIDIPLANTAE3.0" selected="true">Viridiplantae version 3.0 </option>
    <option value="VIRIDIPLANTAE2.2" selected="true">Viridiplantae version 2.2</option>
    <option value="METAZOA3.0" >Metazoa version 3.0</option>
    <option value="METAZOA2.0" >Metazoa version 2.0</option>
    <!-- Modify setting in config.py accordingly -->
  </param>

  <conditional name="advanced_options">
    <param name="advanced" type="boolean" truevalue="true" falsevalue="false" checked="False" label="Advanced options" />
    <when value="false">
      <!-- pass -->
    </when>
    <when value="true">
      <conditional name="comparative">
        <param name="options_comparative" type="boolean" truevalue="true" falsevalue="false" checked="False" label="Perform comparative analysis" help="Use this options when you want to compare sequences multiple groups"/>
	      <when value="false">
          <!-- do nothing here -->
        </when>
        <when value="true">
   		    <param name="prefix_length" label="Group code length" type="integer" value="3" min="1" max="10" help="For comparative analysis, sequences are from individial groups distinguished by sample code which must be used as prefix for sequence name. See example below."/>
        </when>
      </conditional>

      <conditional name="blastx">
        <param name="options_blastx" type="select" label="Select parameters for protein domain search">
          <option value="BLASTX_W2" selected="false">blastx with word size 2 (the most sensitive, slowest)</option>
          <option value="BLASTX_W3" selected="true">blastx with word size 3 (default)</option>
          <option value="DIAMOND" selected="false">diamond program (the least sensitive, fastest)</option>
        </param>
      </conditional>

      <conditional name="options">
        <param name="options" type="select" label="Similarity search options" help="Different similarity search parameters are used depending on the used input data to adjust search to differences in length and error rate">
          <option value="ILLUMINA" selected="true">Illumina reads, read length 100nt or more </option>
          <option value="ILLUMINA_SHORT" selected="false">Illumina reads, shorter than 100nt (Do not use reads shorter than 50nt!) </option>
          <option value="ILLUMINA_DUST_OFF" selected="false">Illumina reads, no masking of low complexity repeats  </option>
          <option value="OXFORD_NANOPORE" selected="false">
            Pseudo short reads simulated from Oxford Nanopore data (experimental feature)
          </option>
        </param>
      </conditional>
      
      <conditional name="custom_library">
	      <param name="options_custom_library" type="boolean" truevalue="true" falsevalue="false" checked="False" label="Use custom repeat database"/>
	      <when value="false">
          <!-- do nothing here -->
        </when>
        <when value="true">
   		    <param name="library" format="fasta" type="data" label="Custom library of repeats" help="Library of repeats as DNA sequences in fasta format. The required format for IDs in a custom library is : '>reapeatname#class/subclass'"/>
        </when>
      </conditional>
	    <param name="size_threshold" label="Cluster size threshold  for detailed analysis" type="float" value="0.01" min="0.0001" max="100" help ="Minimal size (as percentage of input reads) of the smallest cluster which is analyzed, cluster with less than 20 reads are not considered at all."/>
      <param name="automatic_filtering" label="Perform automatic filtering of abundant satellite repeats" help="Automatic filtering tries to identify the most abundant tandem repeats and remove such sequences partially from analysis. Removal of abundant tandem repeat can enable to analyze higher proportion of other less abundant repeats." type="boolean" truevalue="--automatic_filtering" falsevalue="" checked="false"/>
      <param name="keep_names" label="Keep original sequences names" type="boolean" truevalue="--keep_names" falsevalue="" checked="false" help="By default sequence are relabeled using  integers. If you want to keep original names, use this option."/>
      <param name="assembly_min_cluster_size" type="integer" label="min cluster size for assembly" value="5" min="2" max="100"/>
    </when>
  </conditional>

  

 </inputs>
    <outputs>
	<data name="log" format="txt" label="RepeatExplorer2 - log file"/> 
	<data name="ReportArchive" format="zip" label="RepeatExplorer2 - Archive with HTML report from data ${FastaFile.hid}"/> 
	<data name="ReportFile" format="html" label="RepeatExplorer2 - HTML report from data ${FastaFile.hid}"/> 
    </outputs>

    <help>
      **HELP**
      
      RepeatExplorer2 clustering is a computational pipeline for unsupervised
      identification of repeats from unassembled sequence reads. The
      pipeline uses low-pass whole genome sequence reads and performs graph-based
      clustering. Resulting clusters, representing all types of repeats, are then
      examined to identify and classify into repeats groups. 

      **Input data**
      
      The analysis requires either **single** or **paired-end reads** generated
      by whole genome shotgun sequencing provided as a single fasta-formatted file.
      Generally, paired-end reads provide significantly better results than single
      reads. Reads should be of uniform length (optimal size range is 100-200 nt) and
      the number of analyzed reads should represent less than 1x genome equivalent
      (genome coverage of 0.01 - 0.50 x is recommended). Reads should be
      quality-filtered (recommended filtering : quality score >=10 over 95% of bases
      and no Ns allowed) and only **complete read pairs** should be submitted for
      analysis. When paired reads are used, input data must be **interlaced** format
      as fasta file:

      example of interlaced input format::
      
        >0001_f
        CGTAATATACATACTTGCTAGCTAGTTGGATGCATCCAACTTGCAAGCTAGTTTGATG
        >0001_r
        GATTTGACGGACACACTAACTAGCTAGTTGCATCTAAGCGGGCACACTAACTAACTAT
        >0002_f
        ACTCATTTGGACTTAACTTTGATAATAAAAACTTAAAAAGGTTTCTGCACATGAATCG
        >0002_r
        TATGTTGAAAAATTGAATTTCGGGACGAAACAGCGTCTATCGTCACGACATAGTGCTC
        >0003_f
        TGACATTTGTGAACGTTAATGTTCAACAAATCTTTCCAATGTCTTTTTATCTTATCAT
        >0003_r
        TATTGAAATACTGGACACAAATTGGAAATGAAACCTTGTGAGTTATTCAATTTATGTT
        ...


      **Comparative analysis**

      For comparative analysis sequence names must contain code (prefix) for each group.
      Prefix in sequences names  must be of fixed length.

      Example of labeling two groups with where **group code length** is 2 and is used to distinguish groups - AA and BB ::

        >AA0001_f
        CGTAATATACATACTTGCTAGCTAGTTGGATGCATCCAACTTGCAAGCTAGTTTGATG
        >AA0001_r
        GATTTGACGGACACACTAACTAGCTAGTTGCATCTAAGCGGGCACACTAACTAACTAT
        >AA0002_f
        ACTCATTTGGACTTAACTTTGATAATAAAAACTTAAAAAGGTTTCTGCACATGAATCG
        >AA0002_r
        TATGTTGAAAAATTGAATTTCGGGACGAAACAGCGTCTATCGTCACGACATAGTGCTC
        >BB0001_f
        TGACATTTGTGAACGTTAATGTTCAACAAATCTTTCCAATGTCTTTTTATCTTATCAT
        >BB0001_r
        TATTGAAATACTGGACACAAATTGGAAATGAAACCTTGTGAGTTATTCAATTTATGTT
        >BB0002_f
        TGACATTTGTGAACGTTAATGTTCAACAAATCTTTCCAATGTCTTTTTATCTTATCAT
        >BB0002_r
        TATTGAAATACTGGACACAAATTGGAAATGAAACCTTGTGAGTTATTCAATTTATGTT
        

      To prepare quality filtered and interlaced input fasta file from fastq
      files, use `Preprocessing of paired-reads`__  tool.

      .. __: tool_runner?tool_id=paired_fastq_filtering


      **Additional parameters**

      **Sample size** defines how many reads should be used in calculation.
      Default setting with 500,000 reads will enable detection of high copy
      repeats within several hours of computation time. For higher
      sensitivity the sample size can be set higher. Since sample size affects
      the memory usage, this parameter may be automatically adjusted to lower
      value during the run. Maximum sample size which can be processed depends on
      the repetitiveness of analyzed genome.

      
      **Select taxon and protein domain database version (REXdb)**. Classification
      of transposable elements is based on the similarity to our reference database
      of transposable element protein domains (**REXdb**). Standalone database for Viridiplantae species
      can be obtained on `repeatexplorer.org`__. Classification
      system used in REXdb is described in article `Systematic survey of plant
      LTR-retrotransposons elucidates phylogenetic relationships of their
      polyprotein domains and provides a reference for element classification`__
      Database for Metazoa species is still under development so use it with caution.

      .. __: http://repeatexplorer.org
      .. __: https://doi.org/10.1186/s13100-018-0144-1

      **Select parameters for protein domain search** REXdb is compared with s
      equence clusters either using blastx or diamond aligner. Diamond program
      is about three time faster than blastx with word size 3.

      **Similarity search options** By default sequence reads are compared using
      mgblast program. Default threshold is explicitly set to 90% sequence
      similarity spanning at least 55% of the read length (in the case of reads
      differing in length it applies to the longer one). Additionally, sequence
      overlap must be at least 55 nt. If you select option for shorter reads
      than 100 nt,  minimum overlap 55 nt is not required.

      By default,
      mgblast search use DUST program to filter out
      low-complexity sequences. If you want
      to increase sensitivity of detection of satellites with shorter monomer
      use option with '*no masking of low complexity repeats*'. Note that omitting
      DUST filtering will significantly increase running times
     

      **Automatic filtering of abundant satellite repeats** perform clustering on
      smaller dataset of sequence reads to detect abundant high confidence
      satellite repeats. If such satellites are detected, sequence reads derived
      from these satellites are depleted from input dataset. This step enable more
      sensitive detection of less abundant repeats as more reads can be used
      in clustering step.

      **Use custom repeat database**. This option allows users to perform similarity
      comparison of identified repeats to their custom databases. The repeat class must
      be encoded in FASTA headers of database entries in order to allow correct 
      parsing of similarity hits. Required format for custom database sequence name is: ::

        >reapeatname#class/subclass


      **Output**

      List of clusters identified as putative satellite repeats, their genomic
      abundance and various cluster characteristics. 

      Output includes a **HTML summary** with table listing of all analyzed
      clusters. More detailed information about clusters is provided in
      additional files and directories. All results are also provided as
      downloadable **zip archive**. Additionally a **log file** reporting
      the progress of the computational pipeline is provided.
      
    </help>

</tool>