The Evolution of Combinatorial Gene Regulation in Fungi

David J Galgoczy,Laurence D Hurst,Hao Li,Alexander D Johnson,Brian B Tuch,Aaron D Hernday

doi:10.1371/journal.pbio.0060038

David J Galgoczy, Laurence D Hurst + Show 4 more

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https://doi.org/10.1371/journal.pbio.0060038

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Journal: PLoS Biology	Publication Date: Feb 1, 2008
Citations: 287	License type: CC BY 4.0

Affiliation: University of California, San Francisco

Abstract

It is widely suspected that gene regulatory networks are highly plastic. The rapid turnover of transcription factor binding sites has been predicted on theoretical grounds and has been experimentally demonstrated in closely related species. We combined experimental approaches with comparative genomics to focus on the role of combinatorial control in the evolution of a large transcriptional circuit in the fungal lineage. Our study centers on Mcm1, a transcriptional regulator that, in combination with five cofactors, binds roughly 4% of the genes in Saccharomyces cerevisiae and regulates processes ranging from the cell-cycle to mating. In Kluyveromyces lactis and Candida albicans, two other hemiascomycetes, we find that the Mcm1 combinatorial circuits are substantially different. This massive rewiring of the Mcm1 circuitry has involved both substantial gain and loss of targets in ancient combinatorial circuits as well as the formation of new combinatorial interactions. We have dissected the gains and losses on the global level into subsets of functionally and temporally related changes. One particularly dramatic change is the acquisition of Mcm1 binding sites in close proximity to Rap1 binding sites at 70 ribosomal protein genes in the K. lactis lineage. Another intriguing and very recent gain occurs in the C. albicans lineage, where Mcm1 is found to bind in combination with the regulator Wor1 at many genes that function in processes associated with adaptation to the human host, including the white-opaque epigenetic switch. The large turnover of Mcm1 binding sites and the evolution of new Mcm1–cofactor interactions illuminate in sharp detail the rapid evolution of combinatorial transcription networks.

Highlights

The recent genome sequencing and annotation of the major model organisms established that organismal complexity does not scale in a simple way with gene count
By using genomewide transcription factor localization experiments in S. cerevisiae, K. lactis, and C. albicans, combined with comparative genomics across many more yeast species, we examined how a large combinatorial transcription circuit evolves over the course of hundreds of millions of years
Our studies focused on one prolific combinatorial regulator, Mcm1, which, in combination with five cofactors, binds and regulates genes functioning in a diverse range of cellular processes in S. cerevisiae

Summary

Introduction

The recent genome sequencing and annotation of the major model organisms established that organismal complexity does not scale in a simple way with gene count. This discordance is consistent with earlier proposals that ‘‘tinkering’’ with gene regulation may be a powerful mode of evolution [1,2,3]. The potential for rapid turnover (gains and losses) of transcription factor binding sites was predicted on theoretical grounds [9,10,11] and was supported by comparisons of cis regulatory sequence both within and between species [12,13,14,15]. Analogous experiments performed on two transcription factors from closely related yeasts led to similar conclusions [17], in this case, it was not clear how the differences in binding related to gains and losses of cis-acting sequences

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