Transcriptomic and epigenomic landscapes of muscle growth during the postnatal period of broilers.

IF 6.3 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE
Shuang Gu, Qiang Huang, Yuchen Jie, Congjiao Sun, Chaoliang Wen, Ning Yang
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引用次数: 0

Abstract

Background: Broilers stand out as one of the fastest-growing livestock globally, making a substantial contribution to animal meat production. However, the molecular and epigenetic mechanisms underlying the rapid growth and development of broiler chickens are still unclear. This study aims to explore muscle development patterns and regulatory networks during the postnatal rapid growth phase of fast-growing broilers. We measured the growth performance of Cornish (CC) and White Plymouth Rock (RR) over a 42-d period. Pectoral muscle samples from both CC and RR were randomly collected at day 21 after hatching (D21) and D42 for RNA-seq and ATAC-seq library construction.

Results: The consistent increase in body weight and pectoral muscle weight across both breeds was observed as they matured, with CC outpacing RR in terms of weight at each stage of development. Differential expression analysis identified 398 and 1,129 genes in the two dimensions of breeds and ages, respectively. A total of 75,149 ATAC-seq peaks were annotated in promoter, exon, intron and intergenic regions, with a higher number of peaks in the promoter and intronic regions. The age-biased genes and breed-biased genes of RNA-seq were combined with the ATAC-seq data for subsequent analysis. The results spotlighted the upregulation of ACTC1 and FDPS at D21, which were primarily associated with muscle structure development by gene cluster enrichment. Additionally, a noteworthy upregulation of MUSTN1, FOS and TGFB3 was spotted in broiler chickens at D42, which were involved in cell differentiation and muscle regeneration after injury, suggesting a regulatory role of muscle growth and repair.

Conclusions: This work provided a regulatory network of postnatal broiler chickens and revealed ACTC1 and MUSTN1 as the key responsible for muscle development and regeneration. Our findings highlight that rapid growth in broiler chickens triggers ongoing muscle damage and subsequent regeneration. These findings provide a foundation for future research to investigate the functional aspects of muscle development.

肉鸡出生后肌肉生长的转录组和表观基因组图谱
背景:肉鸡是全球增长最快的家畜之一,对动物肉类生产做出了重大贡献。然而,肉鸡快速生长发育的分子和表观遗传学机制仍不清楚。本研究旨在探索快速生长肉鸡出生后快速生长阶段的肌肉发育模式和调控网络。我们测量了康氏鸡(CC)和普利茅斯岩白鸡(RR)42 天的生长性能。我们在孵化后第21天(D21)和第42天随机采集了CC和RR的胸肌样本,用于构建RNA-seq和ATAC-seq文库:结果:随着发育成熟,两个品种的体重和胸肌重量持续增加,CC在每个发育阶段的体重都超过了RR。差异表达分析在品种和年龄两个维度上分别发现了 398 个和 1,129 个基因。在启动子、外显子、内含子和基因间区共注释了75 149个ATAC-seq峰值,其中启动子和内含子区的峰值数量较多。RNA-seq的年龄偏倚基因和品种偏倚基因与ATAC-seq数据相结合进行了后续分析。结果发现,ACTC1和FDPS在D21时上调,通过基因簇富集,这两个基因主要与肌肉结构发育有关。此外,肉鸡在D42时发现了MUSTN1、FOS和TGFB3的显著上调,它们参与了损伤后的细胞分化和肌肉再生,表明它们对肌肉生长和修复起着调控作用:这项研究提供了肉鸡出生后的调控网络,发现 ACTC1 和 MUSTN1 是肌肉发育和再生的关键。我们的研究结果突出表明,肉鸡的快速生长会引发持续的肌肉损伤和随后的再生。这些发现为今后研究肌肉发育的功能方面奠定了基础。
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来源期刊
CiteScore
10.30
自引率
0.00%
发文量
822
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