Pairs of Adjacent Conserved Noncoding Elements Separated by Conserved Genomic Distances Act as Cis-Regulatory Units.

Lifei Li,Eva Hirth,Leila Taher,Nicolai K H Barth,Naruya Saitou

doi:10.1093/gbe/evy196

Lifei Li, Eva Hirth + Show 3 more

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https://doi.org/10.1093/gbe/evy196

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Abstract

Comparative genomic studies have identified thousands of conserved noncoding elements (CNEs) in the mammalian genome, many of which have been reported to exert cis-regulatory activity. We analyzed ∼5,500 pairs of adjacent CNEs in the human genome and found that despite divergence at the nucleotide sequence level, the inter-CNE distances of the pairs are under strong evolutionary constraint, with inter-CNE sequences featuring significantly lower transposon densities than expected. Further, we show that different degrees of conservation of the inter-CNE distance are associated with distinct cis-regulatory functions at the CNEs. Specifically, the CNEs in pairs with conserved and mildly contracted inter-CNE sequences are the most likely to represent active or poised enhancers. In contrast, CNEs in pairs with extremely contracted or expanded inter-CNE sequences are associated with no cis-regulatory activity. Furthermore, we observed that functional CNEs in a pair have very similar epigenetic profiles, hinting at a functional relationship between them. Taken together, our results support the existence of epistatic interactions between adjacent CNEs that are distance-sensitive and disrupted by transposon insertions and deletions, and contribute to our understanding of the selective forces acting on cis-regulatory elements, which are crucial for elucidating the molecular mechanisms underlying adaptive evolution and human genetic diseases.

Highlights

Over 97% of the human genome does not code for proteins, but instead is mainly involved in gene expression regulation and chromosome structure maintenance (Koop and Hood 1994; Lander et al 2001)
We found that AO conserved noncoding elements (CNEs)–CNE pairs with consistent contraction/expansion trends in the human and mouse were associated with more biological processes, molecular functions, and protein domains than AO CNE–CNE pairs with opposite contraction/expansion trends
Compared with the entire collection of CNE–CNE pairs in the human genome, AO CNE–CNE pairs with consistent contraction/expansion trends had a higher proportion of pairs in cluster iii, with odds ratios ranging between 1.8 and 2.3

Summary

Introduction

Over 97% of the human genome does not code for proteins, but instead is mainly involved in gene expression regulation and chromosome structure maintenance (Koop and Hood 1994; Lander et al 2001). It has been shown that the protein complexes, mediator and cohesin, have especially important roles in bringing into and maintaining the TFs at the enhancers and silencers and the basic transcriptional machinery at promoters in physical proximity (Andersson et al 2015). Despite this progress in our understanding of their mechanisms of action and their well-established roles in organismal development and human disease (Stathopoulos and Levine 2005; Bhatia ß The Author(s) 2018.

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