Combined metabolome and transcriptome analysis revealed that MSTN regulated the process of bovine fatty acid metabolism in gut.

IF 2.6 2区农林科学 Q1 VETERINARY SCIENCES

Frontiers in Veterinary Science Pub Date : 2025-04-28 eCollection Date: 2025-01-01 DOI:10.3389/fvets.2025.1541257

Li Gao, Yong Ma, Lili Wang, Hao Wu, Ruobing Kang, Guangpeng Li, Lei Yang, Tong Wen

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引用次数: 0

Abstract

Introduction: MSTN is a well-studied inhibitor of skeletal muscle development, but its mechanism of affecting gut metabolites and the functions it exerts through this pathway are still unclear. This study aims to reveal how MSTN affects the metabolism process by regulating gut metabolites.

Methods: Combined analysis of jejunal contents metabolome and jejunal tissue transcriptome was used to compare the differences in intestinal metabolites and intestinal tissue gene expression between MSTN mutant and wild-type bovines.

Results: Metabolomic analysis identified that compared to wild-type bovine, the abundance of 304 metabolites were significantly changed in MSTN mutant cattle including 142 upregulated and 162 downregulated. Transcriptome results showed that the expression level of 1541 genes were influenced by MSTN disruption, including 536 upregulated genes and 1005 downregulated genes, which were categorized into 311 KEGG signaling pathways, primarily related to disease and metabolism. Correlation analysis results suggested a notable cross-regulation between the transcript levels of some specific genes in jejunal tissues and the abundance of jejunal metabolites, represented by fatty metabolites and genes associated with fatty acid degradation, synthesis and elongation.

Discussion: Collectively, the result of this study indicated that MSTN gene mutation led to alterations in gut microbial metabolites by increasing the abundance of beneficial monounsaturated fatty acids (MUFAs) such as oleic acid, then to promote fatty acid degradation while inhibiting its synthesis by regulating the expression levels of relevant genes. These results provide a foundation for understanding the effects of MSTN gene mutations on gut metabolites and its certain functions that MSTN regulated via gut metabolites.

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代谢组学和转录组学分析表明，MSTN调控了牛肠道脂肪酸代谢过程。

简介：MSTN是一种被广泛研究的骨骼肌发育抑制剂，但其影响肠道代谢物的机制及其通过该途径发挥的功能尚不清楚。本研究旨在揭示MSTN如何通过调节肠道代谢物影响代谢过程。方法：采用空肠内容物代谢组和空肠组织转录组联合分析的方法，比较MSTN突变体与野生型牛肠道代谢物和肠组织基因表达的差异。结果：代谢组学分析发现，与野生型牛相比，MSTN突变牛的304种代谢物丰度发生了显著变化，其中142种表达上调，162种表达下调。转录组结果显示，1541个基因的表达水平受到MSTN破坏的影响，包括536个上调基因和1005个下调基因，这些基因被分类为311个KEGG信号通路，主要与疾病和代谢相关。相关分析结果表明，空肠组织中某些特定基因的转录水平与空肠代谢产物丰度之间存在显著的交叉调节，以脂肪代谢产物和脂肪酸降解、合成和延伸相关基因为代表。综上所述，本研究结果表明，MSTN基因突变通过增加油酸等有益单不饱和脂肪酸（MUFAs）的丰度，进而通过调节相关基因的表达水平，促进脂肪酸降解，抑制脂肪酸合成，从而导致肠道微生物代谢产物的改变。这些结果为了解MSTN基因突变对肠道代谢物的影响以及MSTN通过肠道代谢物调控的某些功能提供了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Frontiers in Veterinary Science Veterinary-General Veterinary

CiteScore

4.80

自引率

9.40%

发文量

1870

审稿时长

14 weeks

期刊介绍： Frontiers in Veterinary Science is a global, peer-reviewed, Open Access journal that bridges animal and human health, brings a comparative approach to medical and surgical challenges, and advances innovative biotechnology and therapy. Veterinary research today is interdisciplinary, collaborative, and socially relevant, transforming how we understand and investigate animal health and disease. Fundamental research in emerging infectious diseases, predictive genomics, stem cell therapy, and translational modelling is grounded within the integrative social context of public and environmental health, wildlife conservation, novel biomarkers, societal well-being, and cutting-edge clinical practice and specialization. Frontiers in Veterinary Science brings a 21st-century approach—networked, collaborative, and Open Access—to communicate this progress and innovation to both the specialist and to the wider audience of readers in the field. Frontiers in Veterinary Science publishes articles on outstanding discoveries across a wide spectrum of translational, foundational, and clinical research. The journal''s mission is to bring all relevant veterinary sciences together on a single platform with the goal of improving animal and human health.