Comparative analyses of dynamic transcriptome profiles highlight key response genes and dominant isoforms for muscle development and growth in chicken.

IF 3.6 1区 农林科学 Q1 AGRICULTURE, DAIRY & ANIMAL SCIENCE Genetics Selection Evolution Pub Date : 2023-10-23 DOI:10.1186/s12711-023-00849-4
Zhang Wang, Weihua Tian, Dandan Wang, Yulong Guo, Zhimin Cheng, Yanyan Zhang, Xinyan Li, Yihao Zhi, Donghua Li, Zhuanjian Li, Ruirui Jiang, Guoxi Li, Yadong Tian, Xiangtao Kang, Hong Li, Ian C Dunn, Xiaojun Liu
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Abstract

Background: Modern breeding strategies have resulted in significant differences in muscle mass between indigenous chicken and specialized broiler. However, the molecular regulatory mechanisms that underlie these differences remain elusive. The aim of this study was to identify key genes and regulatory mechanisms underlying differences in breast muscle development between indigenous chicken and specialized broiler.

Results: Two time-series RNA-sequencing profiles of breast muscles were generated from commercial Arbor Acres (AA) broiler (fast-growing) and Chinese indigenous Lushi blue-shelled-egg (LS) chicken (slow-growing) at embryonic days 10, 14, and 18, and post-hatching day 1 and weeks 1, 3, and 5. Principal component analysis of the transcriptome profiles showed that the top four principal components accounted for more than 80% of the total variance in each breed. The developmental axes between the AA and LS chicken overlapped at the embryonic stages but gradually separated at the adult stages. Integrative investigation of differentially-expressed transcripts contained in the top four principal components identified 44 genes that formed a molecular network associated with differences in breast muscle mass between the two breeds. In addition, alternative splicing analysis revealed that genes with multiple isoforms always had one dominant transcript that exhibited a significantly higher expression level than the others. Among the 44 genes, the TNFRSF6B gene, a mediator of signal transduction pathways and cell proliferation, harbored two alternative splicing isoforms, TNFRSF6B-X1 and TNFRSF6B-X2. TNFRSF6B-X1 was the dominant isoform in both breeds before the age of one week. A switching event of the dominant isoform occurred at one week of age, resulting in TNFRSF6B-X2 being the dominant isoform in AA broiler, whereas TNFRSF6B-X1 remained the dominant isoform in LS chicken. Gain-of-function assays demonstrated that both isoforms promoted the proliferation of chicken primary myoblasts, but only TNFRSF6B-X2 augmented the differentiation and intracellular protein content of chicken primary myoblasts.

Conclusions: For the first time, we identified several key genes and dominant isoforms that may be responsible for differences in muscle mass between slow-growing indigenous chicken and fast-growing commercial broiler. These findings provide new insights into the regulatory mechanisms underlying breast muscle development in chicken.

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动态转录组图谱的比较分析突出了鸡肌肉发育和生长的关键反应基因和显性亚型。
背景:现代养殖策略导致土鸡和特种肉鸡的肌肉质量存在显著差异。然而,这些差异背后的分子调控机制仍然难以捉摸。本研究的目的是确定本地鸡和专业肉鸡胸肌发育差异的关键基因和调控机制。结果:从商品Arbor Acres(AA)肉鸡(快速生长)和中国本土鲁西蓝壳蛋(LS)鸡(缓慢生长)的胚胎第10、14和18天,以及孵化后第1天和第1、3和5周产生了胸肌的两个时间序列RNA测序图谱。转录组图谱的主成分分析显示,前四个主成分占每个品种总方差的80%以上。AA和LS鸡的发育轴在胚胎期重叠,但在成年期逐渐分离。对前四个主要成分中差异表达转录物的综合研究确定了44个基因,这些基因形成了与两个品种之间胸肌质量差异相关的分子网络。此外,选择性剪接分析显示,具有多种异构体的基因总是有一个显性转录物,其表达水平明显高于其他转录物。在44个基因中,TNFRSF6B基因是信号转导途径和细胞增殖的介质,含有两种可供选择的剪接异构体,TNFRSF6B-X1和TNFRSF6B-X2。TNFRSF6B-X1在一周龄前是两个品种的优势亚型。显性同种型的转换事件发生在一周大时,导致TNFRSF6B-X2是AA肉鸡的显性同种型,而TNFRSF6B-X1仍然是LS鸡的显性同种。功能获得分析表明,这两种亚型都能促进鸡原代成肌细胞的增殖,但只有TNFRSF6B-X2能增强鸡原代成肌细胞的分化和细胞内蛋白质含量。结论:我们首次确定了几个关键基因和优势亚型,这些基因和亚型可能是缓慢生长的本地鸡和快速生长的商品肉鸡肌肉质量差异的原因。这些发现为鸡胸肌发育的调控机制提供了新的见解。
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来源期刊
Genetics Selection Evolution
Genetics Selection Evolution 生物-奶制品与动物科学
CiteScore
6.50
自引率
9.80%
发文量
74
审稿时长
1 months
期刊介绍: Genetics Selection Evolution invites basic, applied and methodological content that will aid the current understanding and the utilization of genetic variability in domestic animal species. Although the focus is on domestic animal species, research on other species is invited if it contributes to the understanding of the use of genetic variability in domestic animals. Genetics Selection Evolution publishes results from all levels of study, from the gene to the quantitative trait, from the individual to the population, the breed or the species. Contributions concerning both the biological approach, from molecular genetics to quantitative genetics, as well as the mathematical approach, from population genetics to statistics, are welcome. Specific areas of interest include but are not limited to: gene and QTL identification, mapping and characterization, analysis of new phenotypes, high-throughput SNP data analysis, functional genomics, cytogenetics, genetic diversity of populations and breeds, genetic evaluation, applied and experimental selection, genomic selection, selection efficiency, and statistical methodology for the genetic analysis of phenotypes with quantitative and mixed inheritance.
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