A cobalamin-dependent pathway of choline demethylation from the human gut acetogen Eubacterium limosum.

IF 4 2区生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY

Journal of Biological Chemistry Pub Date : 2025-04-23 DOI:10.1016/j.jbc.2025.108524

Ruisheng Jiang,Duncan J Kountz,Liwen Zhang,Joseph A Krzycki

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Abstract

Elevated serum levels of trimethylamine N-oxide (TMAO) are reported to promote the development of atherosclerosis. TMAO is produced by hepatic oxidation of trimethylamine (TMA) produced by the gut microbiome from dietary quaternary amines such as choline. Net TMA production in the gut depends on microbial enzymes that either produce or consume TMA and its precursors. Here we report the elucidation of a novel microbial pathway consuming choline without TMA production. The human gut acetogen Eubacterium limosum grows by demethylating choline to N-N-dimethylaminoethanol. Quantitative mass spectral analysis of the proteome revealed a multi-protein choline to tetrahydrofolate (THF) methyltransferase system present only in choline-grown cells. The components are encoded in a gene cluster on the genome and include MthB, an MttB superfamily member; MthC, homologous to methylotrophic cobalamin-binding proteins; MthA, homologous to cobalamin:THF methyltransferases; and MthK, a protein related to serine kinases. Together, MthB, MthC, and MthA methylate THF with phosphocholine, but not choline or other quaternary amines. MthB specifically methylates Co(I)-MthC with phosphocholine. MthK acts as a bifunctional choline kinase which can utilize ATP or the MthB demethylation product, N,N-dimethylaminoethanol phosphate, to phosphorylate choline. Together, MthK, MthB, MthC, and MthA are proposed to carry out the methylation of THF with choline. These results outline a THF methylation pathway in which choline is first activated with ATP to phosphocholine prior to demethylation to form N,N-dimethylaminoethanol phosphate. The latter can be recycled by MthK to form more phosphocholine without expending additional ATP, thus minimizing energy utilization during choline-dependent acetogenesis.

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人类肠道醋酸真杆菌胆碱去甲基化的钴胺依赖途径。

据报道，血清三甲胺n -氧化物（TMAO）水平升高可促进动脉粥样硬化的发展。氧化三甲胺是由肠道微生物从膳食中的季胺（如胆碱）中产生的三甲胺（TMA）的肝脏氧化产生的。肠道中TMA的净产量取决于微生物酶，这些酶要么产生TMA，要么消耗TMA及其前体。在这里，我们报告了一种新的微生物途径的阐明消耗胆碱没有TMA生产。人类肠道内的乳酸真杆菌通过将胆碱去甲基化成n - n -二甲氨基乙醇而生长。蛋白质组的定量质谱分析显示，多蛋白胆碱到四氢叶酸（THF）甲基转移酶系统只存在于胆碱生长的细胞中。这些成分在基因组上的一个基因簇中编码，包括MthB， MthB超家族成员；甲基营养钴胺结合蛋白同源；MthA，同源钴胺素：THF甲基转移酶；和MthK，一种与丝氨酸激酶相关的蛋白质。MthB、MthC和MthA一起使THF与磷胆碱甲基化，但不与胆碱或其他季胺甲基化。MthB特异性地用磷酸胆碱甲基化Co(I)-MthC。MthK是一种双功能胆碱激酶，它可以利用ATP或MthB去甲基化产物N，N-二甲氨基乙醇磷酸，使胆碱磷酸化。MthK, MthB， MthC和MthA一起被提出进行THF与胆碱的甲基化。这些结果概述了THF甲基化途径，其中胆碱首先被ATP激活成磷酸胆碱，然后去甲基化形成N，N-二甲氨基乙醇磷酸。后者可以被MthK循环，形成更多的磷酸胆碱，而不消耗额外的ATP，从而最大限度地减少胆碱依赖性丙酮生成过程中的能量利用。

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来源期刊

Journal of Biological Chemistry Biochemistry, Genetics and Molecular Biology-Biochemistry

自引率

4.20%

发文量

1233

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