Mercurial > repos > peterjc > tmhmm_and_signalp
view tools/protein_analysis/tmhmm2.xml @ 10:09ff180d1615 draft
Uploaded v0.1.3 with missing HMM file for RXLR tool included.
author | peterjc |
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date | Wed, 27 Mar 2013 11:21:05 -0400 |
parents | e52220a9ddad |
children | 99b82a2b1272 |
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<tool id="tmhmm2" name="TMHMM 2.0" version="0.0.9"> <description>Find transmembrane domains in protein sequences</description> <!-- If job splitting is enabled, break up the query file into parts --> <!-- Using 2000 chunks meaning 4 threads doing 500 each is ideal --> <parallelism method="basic" split_inputs="fasta_file" split_mode="to_size" split_size="2000" merge_outputs="tabular_file"></parallelism> <command interpreter="python"> tmhmm2.py "\$NSLOTS" $fasta_file $tabular_file ##Set the number of threads in the runner entry in universe_wsgi.ini ##which (on SGE at least) will set the $NSLOTS environment variable. ##If the environment variable isn't set, get "", and defaults to one. </command> <stdio> <!-- Anything other than zero is an error --> <exit_code range="1:" /> <exit_code range=":-1" /> </stdio> <inputs> <param name="fasta_file" type="data" format="fasta" label="FASTA file of protein sequences"/> <!-- <param name="version" type="select" display="radio" label="Model version"> <option value="">Version 1 (old)</option> <option value="" selected="True">Version 2 (default)</option> </param> --> </inputs> <outputs> <data name="tabular_file" format="tabular" label="TMHMM results" /> </outputs> <requirements> <requirement type="binary">tmhmm</requirement> </requirements> <tests> <test> <param name="fasta_file" value="four_human_proteins.fasta" ftype="fasta"/> <output name="tabular_file" file="four_human_proteins.tmhmm2.tabular" ftype="tabular"/> </test> <test> <param name="fasta_file" value="empty.fasta" ftype="fasta"/> <output name="tabular_file" file="empty_tmhmm2.tabular" ftype="tabular"/> </test> </tests> <help> **What it does** This calls the TMHMM v2.0 tool for prediction of transmembrane (TM) helices in proteins using a hidden Markov model (HMM). The input is a FASTA file of protein sequences, and the output is tabular with six columns (one row per protein): 1. Sequence identifier 2. Sequence length 3. Expected number of amino acids in TM helices (ExpAA). If this number is larger than 18 it is very likely to be a transmembrane protein (OR have a signal peptide). 4. Expected number of amino acids in TM helices in the first 60 amino acids of the protein (Exp60). If this number more than a few, be aware that a predicted transmembrane helix in the N-term could be a signal peptide. 5. Number of transmembrane helices predicted by N-best. 6. Topology predicted by N-best (encoded as a strip using o for output and i for inside) Predicted TM segments in the n-terminal region sometimes turn out to be signal peptides. One of the most common mistakes by the program is to reverse the direction of proteins with one TM segment (i.e. mixing up which end of the protein is outside and inside the membrane). Do not use the program to predict whether a non-membrane protein is cytoplasmic or not. **Notes** The short format output from TMHMM v2.0 looks like this (six columns tab separated, shown here as a table): =================================== ======= =========== ============= ========= ============================= gi|2781234|pdb|1JLY|B len=304 ExpAA=0.01 First60=0.00 PredHel=0 Topology=o gi|4959044|gb|AAD34209.1|AF069992_1 len=600 ExpAA=0.00 First60=0.00 PredHel=0 Topology=o gi|671626|emb|CAA85685.1| len=473 ExpAA=0.19 First60=0.00 PredHel=0 Topology=o gi|3298468|dbj|BAA31520.1| len=107 ExpAA=59.37 First60=31.17 PredHel=3 Topology=o23-45i52-74o89-106i =================================== ======= =========== ============= ========= ============================= In order to make it easier to use in Galaxy, the wrapper script simplifies this to remove the redundant tags, and instead adds a comment line at the top with the column names: =================================== === ===== ======= ======= ==================== #ID len ExpAA First60 PredHel Topology gi|2781234|pdb|1JLY|B 304 0.01 0.00 0 o gi|4959044|gb|AAD34209.1|AF069992_1 600 0.00 0.00 0 o gi|671626|emb|CAA85685.1| 473 0.19 0.00 0 o gi|3298468|dbj|BAA31520.1| 107 59.37 31.17 3 o23-45i52-74o89-106i =================================== === ===== ======= ======= ==================== **References** Krogh, Larsson, von Heijne, and Sonnhammer. Predicting Transmembrane Protein Topology with a Hidden Markov Model: Application to Complete Genomes. J. Mol. Biol. 305:567-580, 2001. http://dx.doi.org/10.1006/jmbi.2000.4315 Sonnhammer, von Heijne, and Krogh. A hidden Markov model for predicting transmembrane helices in protein sequences. In J. Glasgow et al., eds.: Proc. Sixth Int. Conf. on Intelligent Systems for Molecular Biology, pages 175-182. AAAI Press, 1998. http://www.ncbi.nlm.nih.gov/pubmed/9783223 http://www.cbs.dtu.dk/services/TMHMM/ </help> </tool>