CREME: a framework for identifying cis-regulatory modules in human-mouse conserved segments

doi:10.1093/bioinformatics/btg1039

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Bioinformatics Vol. 19 Suppl. 1 2003
Pages i283-i291
© 2003 Oxford University Press

CREME: a framework for identifying cis-regulatory modules in human-mouse conserved segments

Roded Sharan ¹^,*^,, Ivan Ovcharenko ²^,, Asa Ben-Hur ³ and Richard M. Karp ¹

¹ International Computer Science Institute, 1947 Center St., Suite 600, Berkeley CA-94704
² Genome Sciences Department, Lawrence Berkeley National Laboratory, Berkeley CA-94720
³ Department of Biochemistry, B400 Beckman Center, Stanford University CA-94305, USA

Received on January 6, 2003 ; accepted on February 20, 2003

Motivation: The binding of transcription factors to specificregulatory sequence elements is a primary mechanism for controllinggene transcription. Recent findings suggest a modular organizationof binding sites for transcription factors that cooperate inthe regulation of genes. In this work we establish a frameworkfor finding recurrent cis-regulatory modules in the promotersof a selected set of genes and scoring their statistical significance.

Results: Proceeding from a database of identified binding sitemotifs and their genomic locations we seek motifs whose frequency in the selected promoters is different than in a backgroundpromoter set. We present several statistical tests designedfor this purpose. We provide a hashing algorithm for detecting combinationsof these motifs that co-occur in clusters within the selected promoters. The significance of such co-occurrences is evaluatedusing novel statistical scores. Our methods are combinedin CREME, a suite of software which includes a browser forviewing the pattern of occurrence of selected cis-regulatory modules. We applied our methodology to find modules within human-mouse conserved promoter segments, focusing on cell cycle regulatedgenes and stress response related genes. To validate the biologicalsignificance of the identified modules we tested whether theassociated genes tended to be co-expressed or share similarfunction. In the cell cycle set five of the seven identifiedsets of genes were coherently expressed. On the stress responsedata four of the six detected sets fell predominantly into well-defined functional sub-categories.

Availability: http://icsi.berkeley.edu/~roded/creme.html

Contact: roded{at}icsi.berkeley.edu.

Keywords: Cis-regulatory module, transcription factor bindingsite, motif cluster, statistical test.

^* To whom correspondence should be addressed.

These authors contributed equally to this work.

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