Whole-body mass spectrometry imaging reveals the systemic metabolic disorder and catecholamines biosynthesis alteration on heart-gut axis in heart failure rat.

Zhengyu Fang, Qingce Zang, Jiemei Chen, Zeyu Li, Dawei Yang, Chongming Wu, Hongjun Yang, Na Guo
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Abstract

Introduction: Heart failure (HF) is a systemic metabolic disorder disease, across multiorgan investigations advancing knowledge of progression and treatment of HF. Whole-body MSI provides spatiotemporal information of metabolites in multiorgan and is expected to be a potent tool to dig out the complex mechanism of HF.

Objectives: This study aimed at exploring the systemic metabolic disorder in multiorgan and catecholamines biosynthesis alteration on heart-gut axis after HF.

Methods: Whole-body MSI was used to characterize metabolic disorder of the whole rat body after HF. An integrated method by MSI, LC-MS/MS and ELISA was utilized to analyze key metabolites and enzymes on heart, small intestine, cecum and colon tissues of rat. Gut microbiota dysbiosis was investigated by 16S rDNA sequencing and metagenomic sequencing. Validation experiments and in vitro experiments were performed to verify the effect of catecholamines biosynthesis alteration on heart-gut axis after HF.

Results: Whole-body MSI exhibited varieties of metabolites alteration in multiple organs. Remarkably, catecholamine biosynthesis was significantly altered in the serum, heart and intestines of rats. Furthermore, catecholamines and tyrosine hydroxylase were obviously upregulated in heart and colon tissue. Turicibacter_sanguinis was relevant to catecholamines of heart and colon. Validation experiments demonstrated excessive norepinephrine induced cardio-intestinal injury, including significantly elevating the levels of BNP, pro-BNP, LPS, DAO, and increased the abundance of Turicibacter_sanguinis. These alterations could be reversed by metoprolol treatment blocking the effect of norepinephrine. Additionally, in vitro studies demonstrated that norepinephrine promoted the growth of Turicibacter_sanguinis and Turicibacter_sanguinis could import and metabolize norepinephrine. Collectively, excessive norepinephrine exerted bidirectional effects on cardio-intestinal function to participate in the progression of HF.

Conclusion: Our study provides a new approach to elucidate multiorgan metabolic disorder and proposes new insights into heart-gut axis in HF development.

全身质谱成像揭示心衰大鼠全身代谢紊乱和儿茶酚胺在心肠轴上的生物合成改变
简介:心力衰竭(HF)是一种全身性代谢紊乱疾病:心力衰竭(HF)是一种全身性代谢紊乱疾病,跨越多器官的研究可促进对心力衰竭进展和治疗的了解。全身 MSI 可提供多器官代谢物的时空信息,有望成为探究心力衰竭复杂机制的有力工具:本研究旨在探讨高血脂后多器官系统代谢紊乱和儿茶酚胺在心肠轴上的生物合成改变:方法:采用全身 MSI 分析高频后大鼠全身代谢紊乱的特征。采用 MSI、LC-MS/MS 和 ELISA 的综合方法分析大鼠心脏、小肠、盲肠和结肠组织中的关键代谢物和酶。通过 16S rDNA 测序和元基因组测序研究了肠道微生物菌群失调。通过验证实验和体外实验来验证高频后儿茶酚胺生物合成改变对心脏-肠道轴的影响:结果:全身 MSI 显示了多个器官中多种代谢物的改变。值得注意的是,大鼠血清、心脏和肠道中儿茶酚胺的生物合成发生了显著变化。此外,心脏和结肠组织中的儿茶酚胺和酪氨酸羟化酶明显上调。粪绿杆菌与心脏和结肠中的儿茶酚胺有关。验证实验表明,过量去甲肾上腺素会诱发心肠损伤,包括 BNP、pro-BNP、LPS、DAO 水平的显著升高,以及 Turicibacter_sanguinis 数量的增加。美托洛尔治疗可阻断去甲肾上腺素的作用,从而逆转这些改变。此外,体外研究表明,去甲肾上腺素能促进粪绿杆菌的生长,粪绿杆菌能输入和代谢去甲肾上腺素。总之,过多的去甲肾上腺素对心肠功能产生双向影响,从而参与高血脂的进展:我们的研究为阐明多器官代谢紊乱提供了一种新方法,并提出了心-肠轴在高血脂发病中的新见解。
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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