A widespread hydrogenase supports fermentative growth of gut bacteria in healthy people.

IF 19.4 1区生物学 Q1 MICROBIOLOGY

Nature Microbiology Pub Date : 2025-10-23 DOI:10.1038/s41564-025-02154-w

Caitlin Welsh, Princess R Cabotaje, Vanessa R Marcelino, Thomas D Watts, Duncan J Kountz, Marion Jespersen, Jodee A Gould, Nhu Quynh Doan, James P Lingford, Thilini Koralegedara, Jessica Solari, Gemma L D'Adamo, Ping Huang, Natasha Bong, Emily L Gulliver, Remy B Young, Henrik Land, Kaija Walter, Isaac Cann, Gabriel V Pereira, Eric C Martens, Patricia G Wolf, Jason M Ridlon, H Rex Gaskins, Edward M Giles, Dena Lyras, Rachael Lappan, Gustav Berggren, Samuel C Forster, Chris Greening

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Abstract

Disruption of hydrogen (H₂) cycling in the gut is linked to gastrointestinal disorders, infections and cancers. However, the mechanisms and microorganisms controlling H₂ production in the gut remain unresolved. Here we show that gut H₂ production is primarily driven by the microbial group B [FeFe]-hydrogenase. Metagenomics and metatranscriptomics of stool and tissue biopsy samples show that hydrogenase-encoding genes are widely present and transcribed in gut bacteria. Assessment of 19 taxonomically diverse gut isolates revealed that the group B [FeFe]-hydrogenases produce large amounts of H₂ gas and support fermentative growth of Bacteroidetes and Firmicutes. Further biochemical and spectroscopic characterization of purified enzymes show that they are catalytically active, bind a di-iron active site and reoxidize ferredoxin derived from the pyruvate:ferredoxin oxidoreductase reaction. Group B hydrogenase-encoding genes are significantly depleted in favour of other fermentative hydrogenases in patients with Crohn's disease. Finally, metabolically flexible respiratory bacteria may be the dominant hydrogenotrophs in the gut, rather than acetogens, methanogens and sulfate reducers. These results uncover the enzymes and microorganisms controlling H₂ cycling in the healthy human gut.

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广泛存在的氢化酶支持健康人肠道细菌的发酵生长。

肠道中氢气循环的中断与胃肠道疾病、感染和癌症有关。然而，控制肠道H2产生的机制和微生物仍未得到解决。在这里，我们发现肠道H2的产生主要是由微生物群B [FeFe]-氢化酶驱动的。粪便和组织活检样本的宏基因组学和亚转录组学表明，氢化酶编码基因广泛存在于肠道细菌中并被转录。对19种不同分类的肠道分离株的评估表明，B组[FeFe]-氢化酶产生大量H2气体，并支持拟杆菌门和厚壁菌门的发酵生长。进一步的生化和光谱表征表明，纯化酶具有催化活性，结合二铁活性位点并重新氧化丙酮酸：铁氧还蛋白氧化还原酶反应产生的铁氧还蛋白。在克罗恩病患者中，B组氢化酶编码基因明显减少，有利于其他发酵氢化酶。最后，代谢灵活的呼吸道细菌可能是肠道中主要的氢养菌，而不是产醋菌、产甲烷菌和硫酸盐还原剂。这些结果揭示了控制健康人类肠道中H2循环的酶和微生物。

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

Nature Microbiology Immunology and Microbiology-Microbiology

CiteScore

44.40

自引率

1.10%

发文量

226

期刊介绍： Nature Microbiology aims to cover a comprehensive range of topics related to microorganisms. This includes: Evolution: The journal is interested in exploring the evolutionary aspects of microorganisms. This may include research on their genetic diversity, adaptation, and speciation over time. Physiology and cell biology: Nature Microbiology seeks to understand the functions and characteristics of microorganisms at the cellular and physiological levels. This may involve studying their metabolism, growth patterns, and cellular processes. Interactions: The journal focuses on the interactions microorganisms have with each other, as well as their interactions with hosts or the environment. This encompasses investigations into microbial communities, symbiotic relationships, and microbial responses to different environments. Societal significance: Nature Microbiology recognizes the societal impact of microorganisms and welcomes studies that explore their practical applications. This may include research on microbial diseases, biotechnology, or environmental remediation. In summary, Nature Microbiology is interested in research related to the evolution, physiology and cell biology of microorganisms, their interactions, and their societal relevance.