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PhyloGibbs: A Gibbs Sampling Motif Finder That Incorporates Phylogeny

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  • Rahul Siddharthan
  • Eric D Siggia
  • Erik van Nimwegen

Abstract

A central problem in the bioinformatics of gene regulation is to find the binding sites for regulatory proteins. One of the most promising approaches toward identifying these short and fuzzy sequence patterns is the comparative analysis of orthologous intergenic regions of related species. This analysis is complicated by various factors. First, one needs to take the phylogenetic relationship between the species into account in order to distinguish conservation that is due to the occurrence of functional sites from spurious conservation that is due to evolutionary proximity. Second, one has to deal with the complexities of multiple alignments of orthologous intergenic regions, and one has to consider the possibility that functional sites may occur outside of conserved segments. Here we present a new motif sampling algorithm, PhyloGibbs, that runs on arbitrary collections of multiple local sequence alignments of orthologous sequences. The algorithm searches over all ways in which an arbitrary number of binding sites for an arbitrary number of transcription factors (TFs) can be assigned to the multiple sequence alignments. These binding site configurations are scored by a Bayesian probabilistic model that treats aligned sequences by a model for the evolution of binding sites and “background” intergenic DNA. This model takes the phylogenetic relationship between the species in the alignment explicitly into account. The algorithm uses simulated annealing and Monte Carlo Markov-chain sampling to rigorously assign posterior probabilities to all the binding sites that it reports. In tests on synthetic data and real data from five Saccharomyces species our algorithm performs significantly better than four other motif-finding algorithms, including algorithms that also take phylogeny into account. Our results also show that, in contrast to the other algorithms, PhyloGibbs can make realistic estimates of the reliability of its predictions. Our tests suggest that, running on the five-species multiple alignment of a single gene's upstream region, PhyloGibbs on average recovers over 50% of all binding sites in S. cerevisiae at a specificity of about 50%, and 33% of all binding sites at a specificity of about 85%. We also tested PhyloGibbs on collections of multiple alignments of intergenic regions that were recently annotated, based on ChIP-on-chip data, to contain binding sites for the same TF. We compared PhyloGibbs's results with the previous analysis of these data using six other motif-finding algorithms. For 16 of 21 TFs for which all other motif-finding methods failed to find a significant motif, PhyloGibbs did recover a motif that matches the literature consensus. In 11 cases where there was disagreement in the results we compiled lists of known target genes from the literature, and found that running PhyloGibbs on their regulatory regions yielded a binding motif matching the literature consensus in all but one of the cases. Interestingly, these literature gene lists had little overlap with the targets annotated based on the ChIP-on-chip data. The PhyloGibbs code can be downloaded from http://www.biozentrum.unibas.ch/~nimwegen/cgi-bin/phylogibbs.cgi or http://www.imsc.res.in/~rsidd/phylogibbs. The full set of predicted sites from our tests on yeast are available at http://www.swissregulon.unibas.ch.Synopsis: Computational discovery of regulatory sites in intergenic DNA is one of the central problems in bioinformatics. Up until recently motif finders would typically take one of the following two general approaches. Given a known set of co-regulated genes, one searches their promoter regions for significantly overrepresented sequence motifs. Alternatively, in a “phylogenetic footprinting” approach one searches multiple alignments of orthologous intergenic regions for short segments that are significantly more conserved than expected based on the phylogeny of the species.

Suggested Citation

  • Rahul Siddharthan & Eric D Siggia & Erik van Nimwegen, 2005. "PhyloGibbs: A Gibbs Sampling Motif Finder That Incorporates Phylogeny," PLOS Computational Biology, Public Library of Science, vol. 1(7), pages 1-23, December.
  • Handle: RePEc:plo:pcbi00:0010067
    DOI: 10.1371/journal.pcbi.0010067
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    1. Christopher T. Harbison & D. Benjamin Gordon & Tong Ihn Lee & Nicola J. Rinaldi & Kenzie D. Macisaac & Timothy W. Danford & Nancy M. Hannett & Jean-Bosco Tagne & David B. Reynolds & Jane Yoo & Ezra G., 2004. "Transcriptional regulatory code of a eukaryotic genome," Nature, Nature, vol. 431(7004), pages 99-104, September.
    2. Manolis Kellis & Nick Patterson & Matthew Endrizzi & Bruce Birren & Eric S. Lander, 2003. "Sequencing and comparison of yeast species to identify genes and regulatory elements," Nature, Nature, vol. 423(6937), pages 241-254, May.
    3. Antonis Rokas & Barry L. Williams & Nicole King & Sean B. Carroll, 2003. "Genome-scale approaches to resolving incongruence in molecular phylogenies," Nature, Nature, vol. 425(6960), pages 798-804, October.
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    1. Harri Lähdesmäki & Alistair G Rust & Ilya Shmulevich, 2008. "Probabilistic Inference of Transcription Factor Binding from Multiple Data Sources," PLOS ONE, Public Library of Science, vol. 3(3), pages 1-24, March.
    2. Ivan Dotu & Scott I Adamson & Benjamin Coleman & Cyril Fournier & Emma Ricart-Altimiras & Eduardo Eyras & Jeffrey H Chuang, 2018. "SARNAclust: Semi-automatic detection of RNA protein binding motifs from immunoprecipitation data," PLOS Computational Biology, Public Library of Science, vol. 14(3), pages 1-25, March.
    3. Jia Lu & Xiaoyi Cao & Sheng Zhong, 2018. "A likelihood approach to testing hypotheses on the co-evolution of epigenome and genome," PLOS Computational Biology, Public Library of Science, vol. 14(12), pages 1-28, December.
    4. Saeed Omidi & Mihaela Zavolan & Mikhail Pachkov & Jeremie Breda & Severin Berger & Erik van Nimwegen, 2017. "Automated incorporation of pairwise dependency in transcription factor binding site prediction using dinucleotide weight tensors," PLOS Computational Biology, Public Library of Science, vol. 13(7), pages 1-22, July.
    5. Aqil M Azmi & Abdulrakeeb Al-Ssulami, 2014. "Encoded Expansion: An Efficient Algorithm to Discover Identical String Motifs," PLOS ONE, Public Library of Science, vol. 9(5), pages 1-9, May.
    6. Timothy E Reddy & Charles DeLisi & Boris E Shakhnovich, 2007. "Binding Site Graphs: A New Graph Theoretical Framework for Prediction of Transcription Factor Binding Sites," PLOS Computational Biology, Public Library of Science, vol. 3(5), pages 1-11, May.
    7. Siewert Elizabeth A & Kechris Katerina J, 2009. "Prediction of Motifs Based on a Repeated-Measures Model for Integrating Cross-Species Sequence and Expression Data," Statistical Applications in Genetics and Molecular Biology, De Gruyter, vol. 8(1), pages 1-36, September.
    8. Kenzie D MacIsaac & Ernest Fraenkel, 2006. "Practical Strategies for Discovering Regulatory DNA Sequence Motifs," PLOS Computational Biology, Public Library of Science, vol. 2(4), pages 1-10, April.

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