Genomic analysis of regulatory network dynamics reveals large topological changes

Luscombe, Nicholas M.; Babu, M. Madan; Yu, Haiyuan; Snyder, Michael; Teichmann, Sarah A.; Gerstein, Mark

Genomic analysis of regulatory network dynamics reveals large topological changes

Nicholas M. Luscombe (), M. Madan Babu (), Haiyuan Yu, Michael Snyder, Sarah A. Teichmann () and Mark Gerstein ()
Additional contact information
Nicholas M. Luscombe: Yale University
M. Madan Babu: MRC Laboratory of Molecular Biology
Haiyuan Yu: Yale University
Michael Snyder: Yale University
Sarah A. Teichmann: MRC Laboratory of Molecular Biology
Mark Gerstein: Yale University

Nature, 2004, vol. 431, issue 7006, 308-312

Abstract: Abstract Network analysis has been applied widely, providing a unifying language to describe disparate systems ranging from social interactions to power grids. It has recently been used in molecular biology, but so far the resulting networks have only been analysed statically1,2,3,4,5,6,7,8. Here we present the dynamics of a biological network on a genomic scale, by integrating transcriptional regulatory information9,10,11 and gene-expression data12,13,14,15,16 for multiple conditions in Saccharomyces cerevisiae. We develop an approach for the statistical analysis of network dynamics, called SANDY, combining well-known global topological measures, local motifs and newly derived statistics. We uncover large changes in underlying network architecture that are unexpected given current viewpoints and random simulations. In response to diverse stimuli, transcription factors alter their interactions to varying degrees, thereby rewiring the network. A few transcription factors serve as permanent hubs, but most act transiently only during certain conditions. By studying sub-network structures, we show that environmental responses facilitate fast signal propagation (for example, with short regulatory cascades), whereas the cell cycle and sporulation direct temporal progression through multiple stages (for example, with highly inter-connected transcription factors). Indeed, to drive the latter processes forward, phase-specific transcription factors inter-regulate serially, and ubiquitously active transcription factors layer above them in a two-tiered hierarchy. We anticipate that many of the concepts presented here—particularly the large-scale topological changes and hub transience—will apply to other biological networks, including complex sub-systems in higher eukaryotes.

Date: 2004
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DOI: 10.1038/nature02782

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