Lu Xu, Zhe Liu, Mengling Gong, Zhiheng Wei, Yang Gu, Lisha Yu, Jianfeng Yu, Zhiliang Gu
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引用次数: 0
摘要
目的:鉴于肝脏是家禽脂质代谢的关键,而禁食模型在动物营养代谢研究中应用广泛,本研究采用禁食的方法探讨鸡肝脏脂质代谢特征,为家禽脂质代谢研究提供依据。方法:采用RNA-seq和代谢组学相结合的方法,分析禁食72 h对鸡肝脏脂质代谢的影响。鉴定了脂质代谢相关的关键基因和代谢物,并通过RNAi和Oil Red O染色探讨了它们的作用机制。结果:代谢组学鉴定出648种差异代谢物,其中8种(如花生四烯醇胺)的水平比对照组高160倍。转录组学发现849个差异表达基因(DEGs),其中78个参与脂质代谢;PPI分析显示EHHADH等枢纽基因。转录组-代谢组相关分析显示,101个DEGs与99种代谢物相关,EHHADH与54种代谢物相关(最多),并通过KGML与2-methylcrotonoyl-CoA和5条通路相连。禁食上调EHHADH,其过表达/干扰改变Fabp7、Plin2、ACACA、FASN、PPARα mRNA水平以及胆固醇/甘油三酯水平。EHHADH过表达降低了LMH细胞脂质沉积,而干扰使其增加,提示其在降低脂质沉积中的作用。结论:禁食可显著改变鸡肝脏脂质代谢,EHHADH有助于减少肝脏脂质沉积。
Transcriptome and metabolite profiling reveals the mechanism of hepatic lipid metabolism during fasting in chicken.
Objective: : Since the liver is key to poultry lipid metabolism and fasting models are widely used in studying animal nutrition metabolism, this study used fasting to explore chicken liver lipid metabolism characteristics, providing a basis for poultry lipid metabolism research.
Method: : RNA-seq and metabolomics were combined to analyze 72-hour fasting effects on chicken liver lipid metabolism. Key lipid metabolism-related genes and metabolites were identified, with their mechanisms explored via RNAi and Oil Red O staining.
Result: : Metabolomics identified 648 differential metabolites, including 8 (e.g., Arachidonoyl amine) with levels 160-fold higher than controls. Transcriptomics found 849 differentially expressed genes (DEGs), 78 involved in lipid metabolism; PPI analysis revealed hub genes like EHHADH. Transcriptome-metabolome correlation analysis showed 101 DEGs correlated with 99 metabolites, with EHHADH associated with 54 metabolites (the most) and linked to 2-methylcrotonoyl-CoA and 5 pathways via KGML. Fasting upregulated EHHADH, whose overexpression/interference altered mRNA levels of Fabp7, Plin2, ACACA, FASN, PPARα, as well as cholesterol/triglyceride levels. EHHADH overexpression reduced LMH cell lipid deposition, while interference increased it, indicating its role in reducing lipid deposition.
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