Abstract
Changes in cis-regulatory DNA sequences and transcription factor (TF) repertoires provide major sources of phenotypic diversity that shape the evolution of gene regulation in eukaryotes. The DNA-binding specificities of TFs may be diversified or produce new variants in different eukaryotic species. However, it is currently unclear how various levels of divergence in TF DNA-binding specificities or motifs became introduced into the cis-regulatory DNA regions of the genome over evolutionary time. Here, we first estimated the evolutionary divergence levels of TF binding motifs and quantified their occurrence at DNase I-hypersensitive sites. Results from our in silico motif scan and experimentally derived chromatin immunoprecipitation (TF-ChIP) show that the divergent motifs tend to be introduced in the edges of cis-regulatory regions, which is probably accompanied by the expansion of the accessible core of promoter-associated regulatory elements during evolution. We also find that the genes neighboring the expanded cis-regulatory regions with the most divergent motifs are associated with functions like development and morphogenesis. Accordingly, we propose that the accumulation of divergent motifs in the edges of cis-regulatory regions provides a functional mechanism for the evolution of divergent regulatory circuits.
Highlights
Transcription factors (TFs) are primary regulators of gene expression that function by interacting with DNA in a sequence-specific manner
To address this knowledge gap, we have developed a novel measurement, the motif prevalence index (MPI), for the level of divergence of motifs among eukaryotes, based on the discovery that TF binding motifs are generally conserved among diverse organisms
Based on phylogenetic distance and the existence of a given motif across metazoan species, the MPI represented the evolutionary divergence level of human motifs, with a score from 0 to 1
Summary
Transcription factors (TFs) are primary regulators of gene expression that function by interacting with DNA in a sequence-specific manner. Previous studies have reported that the DNA-binding specificities of TF orthologs between human and Drosophila are mostly conserved (Nitta et al, 2015). TFs do evolve divergent binding specificities in different species through genetic variation, such as gene duplication and the expansion of gene families (Jolma and Taipale, 2011; Weirauch et al, 2014; Nitta et al, 2015). Divergence in TF binding specificities contributes significantly to differential gene regulation, and shapes eukaryotic evolution (Wittkopp and Kalay, 2012; De Mendoza et al, 2013; Schmitz et al, 2016)
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
