Abstract
BackgroundThe functional annotation of genomes, including chromatin accessibility and modifications, is important for understanding and effectively utilizing the increased amount of genome sequences reported. However, while such annotation has been well explored in a diverse set of tissues and cell types in human and model organisms, relatively little data are available for livestock genomes, hindering our understanding of complex trait variation, domestication, and adaptive evolution. Here, we present the first complete global landscape of regulatory elements in cattle and explore the dynamics of chromatin states in rumen epithelial cells induced by the rumen developmental regulator—butyrate.ResultsWe established the first global map of regulatory elements (15 chromatin states) and defined their coordinated activities in cattle, through genome-wide profiling for six histone modifications, RNA polymerase II, CTCF-binding sites, DNA accessibility, DNA methylation, and transcriptome in rumen epithelial primary cells (REPC), rumen tissues, and Madin-Darby bovine kidney epithelial cells (MDBK). We demonstrated that each chromatin state exhibited specific enrichment for sequence ontology, transcription, methylation, trait-associated variants, gene expression-associated variants, selection signatures, and evolutionarily conserved elements, implying distinct biological functions. After butyrate treatments, we observed that the weak enhancers and flanking active transcriptional start sites (TSS) were the most dynamic chromatin states, occurred concomitantly with significant alterations in gene expression and DNA methylation, which was significantly associated with heifer conception rate and stature economic traits.ConclusionOur results demonstrate the crucial role of functional genome annotation for understanding genome regulation, complex trait variation, and adaptive evolution in livestock. Using butyrate to induce the dynamics of the epigenomic landscape, we were able to establish the correlation among nutritional elements, chromatin states, gene activities, and phenotypic outcomes.
Highlights
Ruminants evolved from simple-stomached animals by transforming into foregut microbial fermenters that could digest grasses and complex carbohydrates [1]
The second peak might imply the existence of longrange regulatory elements; further researches are required for a better understanding of its functional impacts on the gene activities
We observed that CTCF and ATAC from the rumen epithelial primary cells (REPC) sets were associated with many active histone modifications (e.g., H3K4me1, H3K4me3, RNA poly II, H3K9ac, and H3K27ac) in both REPC and rumen tissues (Additional file 1: Figure S7a), demonstrating that epigenomic modification shared certain similarities between the primary cells and rumen tissues
Summary
Ruminants evolved from simple-stomached animals by transforming into foregut microbial fermenters that could digest grasses and complex carbohydrates [1]. Butyrate-induced biological effects in bovine cells may serve as a paradigm of epigenetic regulation and serve as a model for understanding the full range of butyrate’s potential biological roles and molecular mechanisms in cell growth, proliferation, and energy metabolism [10]. The functional annotation of genomes, including chromatin accessibility and modifications, is important for understanding and effectively utilizing the increased amount of genome sequences reported. While such annotation has been well explored in a diverse set of tissues and cell types in human and model organisms, relatively little data are available for livestock genomes, hindering our understanding of complex trait variation, domestication, and adaptive evolution. We present the first complete global landscape of regulatory elements in cattle and explore the dynamics of chromatin states in rumen epithelial cells induced by the rumen developmental regulator—butyrate
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