Evolution of the Vertebrate Gene Regulatory Network Controlled by the Transcriptional Repressor REST

doi:10.1093/molbev/msp058

MBE Advance Access originally published online on March 24, 2009
Molecular Biology and Evolution 2009 26(7):1491-1507; doi:10.1093/molbev/msp058

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© The Author 2009. Published by Oxford University Press on behalf of the Society for Molecular Biology and Evolution. All rights reserved. For permissions, please e-mail: journals.permissions@oxfordjournals.org

Research Articles

Evolution of the Vertebrate Gene Regulatory Network Controlled by the Transcriptional Repressor REST

Rory Johnson^*, John Samuel, Calista Keow Leng Ng, Ralf Jauch, Lawrence W. Stanton^* and Ian C. Wood

^* Stem Cell and Developmental Biology Group, Genome Institute of Singapore, Singapore
Institute of Membrane and Systems Biology, Faculty of Biological Sciences, University of Leeds, Leeds, UK
Laboratory of Structural Biochemistry, Genome Institute of Singapore, Singapore

E-mail: johnsonrb{at}gis.a-star.edu.sg; i.c.wood{at}leeds.ac.uk

Accepted for publication March 19, 2009.

Specific wiring of gene-regulatory networks is likely to underliemuch of the phenotypic difference between species, but the extentof lineage-specific regulatory architecture remains poorly understood.The essential vertebrate transcriptional repressor REST (RE1-SilencingTranscription Factor) targets many neural genes during developmentof the preimplantation embryo and the central nervous system,through its cognate DNA motif, the RE1 (Repressor Element 1).Here we present a comparative genomic analysis of REST recruitmentin multiple species by integrating both sequence and experimentaldata. We use an accurate, experimentally validated Position-SpecificScoring Matrix method to identify REST binding sites in multiplyaligned vertebrate genomes, allowing us to infer the evolutionaryorigin of each of 1,298 human RE1 elements. We validate thesefindings using experimental data of REST binding across thewhole genomes of human and mouse. We show that one-third ofhuman RE1s are unique to primates: These sites recruit RESTin vivo, target neural genes, and are under purifying evolutionaryselection. We observe a consistent and significant trend formore ancient RE1s to have higher affinity for REST than lineage-specificsites and to be more proximal to target genes. Our results leadus to propose a model where new transcription factor bindingsites are constantly generated throughout the genome; thereafter,refinement of their sequence and location consolidates thisremodeling of networks governing neural gene regulation.

Key Words: REST • NRSF • RE1 • evolution • transcription factor binding • motif • gene regulation • neural gene • primate • network • primate-specific • human-specific • lineage-specific

Aoife McLysaght, Associate Editor

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