Reorganization of chromatin architecture during prenatal development of porcine skeletal muscle.

IF 3.9 2区生物学 Q1 GENETICS & HEREDITY

DNA Research Pub Date : 2021-05-02 DOI:10.1093/dnares/dsab003

Renqiang Yuan, Jiaman Zhang, Yujie Wang, Xingxing Zhu, Silu Hu, Jianhua Zeng, Feng Liang, Qianzi Tang, Yaosheng Chen, Luxi Chen, Wei Zhu, Mingzhou Li, Delin Mo

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引用次数: 7

Abstract

Myofibres (primary and secondary myofibre) are the basic structure of muscle and the determinant of muscle mass. To explore the skeletal muscle developmental processes from primary myofibres to secondary myofibres in pigs, we conducted an integrative three-dimensional structure of genome and transcriptomic characterization of longissimus dorsi muscle of pig from primary myofibre formation stage [embryonic Day 35 (E35)] to secondary myofibre formation stage (E80). In the hierarchical genomic structure, we found that 11.43% of genome switched compartment A/B status, 14.53% of topologically associating domains are changed intradomain interactions (D-scores) and 2,730 genes with differential promoter-enhancer interactions and (or) enhancer activity from E35 to E80. The alterations of genome architecture were found to correlate with expression of genes that play significant roles in neuromuscular junction, embryonic morphogenesis, skeletal muscle development or metabolism, typically, NEFL, MuSK, SLN, Mef2D and GCK. Significantly, Sox6 and MATN2 play important roles in the process of primary to secondary myofibres formation and increase the regulatory potential score and genes expression in it. In brief, we reveal the genomic reorganization from E35 to E80 and construct genome-wide high-resolution interaction maps that provide a resource for studying long-range control of gene expression from E35 to E80.

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猪骨骼肌产前发育过程中染色质结构的重组。

肌纤维(初级和次级肌纤维)是肌肉的基本结构，也是肌肉质量的决定因素。为了探索猪骨骼肌从初级肌纤维到次级肌纤维的发育过程，我们对猪背最长肌从初级肌纤维形成阶段[胚胎第35天(E35)]到次级肌纤维形成阶段(E80)的基因组进行了完整的三维结构和转录组学表征。在分层基因组结构中，我们发现11.43%的基因组改变了室A/B状态，14.53%的拓扑相关结构域改变了域内相互作用(D-scores)， 2730个基因在E35到E80之间具有不同的启动子-增强子相互作用和(或)增强子活性。基因组结构的改变与在神经肌肉连接、胚胎形态发生、骨骼肌发育或代谢中起重要作用的基因的表达相关，典型的是NEFL、MuSK、SLN、Mef2D和GCK。值得注意的是，Sox6和MATN2在原发性到继发性肌纤维形成过程中发挥重要作用，并增加其中的调控电位评分和基因表达。总之，我们揭示了E35 - E80的基因组重组，并构建了全基因组高分辨率相互作用图谱，为研究E35 - E80基因表达的远程调控提供了资源。

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来源期刊

DNA Research 生物-遗传学

CiteScore

6.00

自引率

4.90%

发文量

审稿时长

4.5 months

期刊介绍： DNA Research is an internationally peer-reviewed journal which aims at publishing papers of highest quality in broad aspects of DNA and genome-related research. Emphasis will be made on the following subjects: 1) Sequencing and characterization of genomes/important genomic regions, 2) Comprehensive analysis of the functions of genes, gene families and genomes, 3) Techniques and equipments useful for structural and functional analysis of genes, gene families and genomes, 4) Computer algorithms and/or their applications relevant to structural and functional analysis of genes and genomes. The journal also welcomes novel findings in other scientific disciplines related to genomes.