Genome wide identification of regulatory motifs in Bacillus subtilis

<p>Abstract</p> <p>Background</p> <p>To explain the vastly different phenotypes exhibited by the same organism under different conditions, it is essential that we understand how the organism's genes are coordinately regulated. While there are many excellent tools f...

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Main Authors: Siggia Eric D, Mwangi Michael M
Format: Article
Language:English
Published: BMC 2003-05-01
Series:BMC Bioinformatics
Online Access:http://www.biomedcentral.com/1471-2105/4/18
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spelling doaj-13bf4839e653497dbdb3e9addd84c88c2020-11-25T01:39:17ZengBMCBMC Bioinformatics1471-21052003-05-01411810.1186/1471-2105-4-18Genome wide identification of regulatory motifs in Bacillus subtilisSiggia Eric DMwangi Michael M<p>Abstract</p> <p>Background</p> <p>To explain the vastly different phenotypes exhibited by the same organism under different conditions, it is essential that we understand how the organism's genes are coordinately regulated. While there are many excellent tools for predicting sequences encoding proteins or RNA genes, few algorithms exist to predict regulatory sequences on a genome wide scale with no prior information.</p> <p>Results</p> <p>To identify motifs involved in the control of transcription, an algorithm was developed that searches upstream of operons for improbably frequent dimers. The algorithm was applied to the B. subtilis genome, which is predicted to encode for approximately 200 DNA binding proteins. The dimers found to be over-represented could be clustered into 317 distinct groups, each thought to represent a class of motifs uniquely recognized by some transcription factor. For each cluster of dimers, a representative weight matrix was derived and scored over the regions upstream of the operons to predict the sites recognized by the cluster's factor, and a putative regulon of the operons immediately downstream of the sites was inferred. The distribution in number of operons per predicted regulon is comparable to that for well characterized transcription factors. The most highly over-represented dimers matched σ<sup><it>A</it></sup>, the T-box, and σ<sup><it>W </it></sup>sites. We have evidence to suggest that at least 52 of our clusters of dimers represent actual regulatory motifs, based on the groups' weight matrix matches to experimentally characterized sites, the functional similarity of the component operons of the groups' regulons, and the positional biases of the weight matrix matches. All predictions are assigned a significance value, and thresholds are set to avoid false positives. Where possible, we examine our false negatives, drawing examples from known regulatory motifs and regulons inferred from RNA expression data.</p> <p>Conclusions</p> <p>We have demonstrated that in the case of B. subtilis our algorithm allows for the genome wide identification of regulatory sites. As well as recovering known sites, we predict new sites of yet uncharacterized factors. Results can be viewed at <url>http://www.physics.rockefeller.edu/~mwangi/</url>.</p> http://www.biomedcentral.com/1471-2105/4/18
collection DOAJ
language English
format Article
sources DOAJ
author Siggia Eric D
Mwangi Michael M
spellingShingle Siggia Eric D
Mwangi Michael M
Genome wide identification of regulatory motifs in Bacillus subtilis
BMC Bioinformatics
author_facet Siggia Eric D
Mwangi Michael M
author_sort Siggia Eric D
title Genome wide identification of regulatory motifs in Bacillus subtilis
title_short Genome wide identification of regulatory motifs in Bacillus subtilis
title_full Genome wide identification of regulatory motifs in Bacillus subtilis
title_fullStr Genome wide identification of regulatory motifs in Bacillus subtilis
title_full_unstemmed Genome wide identification of regulatory motifs in Bacillus subtilis
title_sort genome wide identification of regulatory motifs in bacillus subtilis
publisher BMC
series BMC Bioinformatics
issn 1471-2105
publishDate 2003-05-01
description <p>Abstract</p> <p>Background</p> <p>To explain the vastly different phenotypes exhibited by the same organism under different conditions, it is essential that we understand how the organism's genes are coordinately regulated. While there are many excellent tools for predicting sequences encoding proteins or RNA genes, few algorithms exist to predict regulatory sequences on a genome wide scale with no prior information.</p> <p>Results</p> <p>To identify motifs involved in the control of transcription, an algorithm was developed that searches upstream of operons for improbably frequent dimers. The algorithm was applied to the B. subtilis genome, which is predicted to encode for approximately 200 DNA binding proteins. The dimers found to be over-represented could be clustered into 317 distinct groups, each thought to represent a class of motifs uniquely recognized by some transcription factor. For each cluster of dimers, a representative weight matrix was derived and scored over the regions upstream of the operons to predict the sites recognized by the cluster's factor, and a putative regulon of the operons immediately downstream of the sites was inferred. The distribution in number of operons per predicted regulon is comparable to that for well characterized transcription factors. The most highly over-represented dimers matched σ<sup><it>A</it></sup>, the T-box, and σ<sup><it>W </it></sup>sites. We have evidence to suggest that at least 52 of our clusters of dimers represent actual regulatory motifs, based on the groups' weight matrix matches to experimentally characterized sites, the functional similarity of the component operons of the groups' regulons, and the positional biases of the weight matrix matches. All predictions are assigned a significance value, and thresholds are set to avoid false positives. Where possible, we examine our false negatives, drawing examples from known regulatory motifs and regulons inferred from RNA expression data.</p> <p>Conclusions</p> <p>We have demonstrated that in the case of B. subtilis our algorithm allows for the genome wide identification of regulatory sites. As well as recovering known sites, we predict new sites of yet uncharacterized factors. Results can be viewed at <url>http://www.physics.rockefeller.edu/~mwangi/</url>.</p>
url http://www.biomedcentral.com/1471-2105/4/18
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