Mercurial > repos > rnateam > vienna_rna
view rna2dfold.xml @ 1:ec0fdb8c4ebb draft
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author | rnateam |
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date | Wed, 04 Feb 2015 12:45:16 -0500 |
parents | 78d673470d45 |
children | 5e58cbf27a05 |
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<tool id="rna2dfold" name="RNA2Dfold" version="2.1.6.0"> <description>explore structure space between two reference structures</description> <expand macro="requirements" /> <expand macro="version_command" /> <expand macro="stdio" /> <macros> <token name="@EXECUTABLE@">RNA2Dfold</token> <import>macros.xml</import> </macros> <command> <![CDATA[ RNA2Dfold -T $temperature -d $dangling --stochBT=$nrbt #if int($nk) > -1 and int($nl) > -1 --neighborhood=$nk:$nl #end if #if $varExists('$pfselect.pfscaling') --partfunc --pfScale=$pfselect.pfscaling #end if #if $varExists('$advancedOptions.noconversion') #if $advancedOptions.noconversion --noconv #end if #if $advancedOptions.nogu --noGU #end if #if $advancedOptions.noclosinggu --noClosingGU #end if #if $advancedOptions.notetra --noTetra #end if --maxDist1=$maxK --maxDist2=$maxL #end if < $custom_input > $out_file ]]> </command> <inputs> <param format="txt" name="custom_input" type="data" label="Custom File"/> <param name="temperature" size="6" type="float" value="37.0" label="Temperature [°C]" help="-T"/> <param name="nrbt" type="integer" value="1" label="number of backtrack of Boltzmann samples" help="--stochBT=INT"/> <param name="nk" type="integer" value="-1" label="k distance to first reference structure of neighborhood in which to backtrack" help="--neighborhood=k:l"/> <param name="nl" type="integer" value="-1" label="l distance to second reference structure of neighborhood in which to backtrack" help="--neighborhood=k:l"/> <param name="dangling" type="select" label="how to treat dangling end energies" help="-d"> <option value="2" selected="true">unpaired bases participate in all dangling ends (2)</option> <option value="0">ignore dangling ends (0)</option> <option value="1">unpaired bases participate in one dangling end only (1)</option> <option value="3">allow coaxial stacking (3)</option> </param> <param name="circular" type="boolean" checked="false" label="assume circular RNA structure" help="--circ"/> <conditional name="pfselect"> <param name="pf" type="select" label="calculate partition function" help="--partfunc"> <option value="no">no</option> <option value="yes">yes</option> </param> <when value="yes"> <param name="pfscaling" size="6" type="float" value="1.0" label="scaling factor for the partition function"/> </when> </conditional> <conditional name="advancedOptions"> <param name="advancedSelector" type="select" label="advanced options"> <option value="basic">basic Options</option> <option value="advanced">advanced Options</option> </param> <when value="advanced"> <param name="maxK" type="integer" value="50" label="Maximum distance to first reference structure" help="--maxDist1=INT"/> <param name="maxL" type="integer" value="50" label="Maximum distance to second reference structure" help="--maxDist2=INT"/> <param name="noconversion" type="boolean" checked="false" label="no conversion" help="--noconv do not convert thymine to uracile (T -> U)."/> <param name="gquad" type="boolean" checked="false" label="G Quadruplex formation" help="-g take into account G Quadruplex formation"/> <param name="nogu" type="boolean" checked="false" label="No GU pairing" help="--noGU don't allow pairing of G and U."/> <param name="noclosinggu" type="boolean" checked="false" label="No GU pairing at the ends" help="--noClosingGU don't allow pairing of G and U at the ends of helices."/> <param name="notetra" type="boolean" checked="false" label="No stabilization for loops, hairpins etc." help="--noTetra"/> </when> </conditional> </inputs> <outputs> <data format="txt" name="out_file"/> </outputs> <tests> </tests> <help> <![CDATA[ **RNA2Dfold** The program partitions the secondary structure space into (basepair)distance classes according to two fixed reference structures. It expects a sequence and two secondary structures in dot-bracket notation as its inputs. For each distance class, the MFE representative, Boltzmann probabilities and Gibbs free energy is computed. Additionally, a stochastic backtracking routine allows to produce samples of representative suboptimal secondary structures from each partition. The k-distance corresponds to the distance to the first reference structure, and the l-distance corresponds to the distance to the second reference structure ----- **Input format** RNA2Dfold requires one input file in the following format - 1st line: RNA sequence - 2nd line: first reference structure in dot-bracket format - 3rd line: second reference structure in dot-bracket format ------ **Outputs** - text output with several secondary structures and its energies ]]> </help> <expand macro="requirements" /> </tool>