Decoding the role of the arginine dihydrolase pathway in shaping human gut community assembly and health-relevant metabolites.

Cell systems Pub Date : 2025-05-21 Epub Date: 2025-05-07 DOI:10.1016/j.cels.2025.101292

Yiyi Liu, Yu-Yu Cheng, Jaron Thompson, Zhichao Zhou, Eugenio I Vivas, Matthew F Warren, Julie M DuClos, Karthik Anantharaman, Federico E Rey, Ophelia S Venturelli

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Abstract

The arginine dihydrolase pathway (arc operon) provides a metabolic niche by transforming arginine into metabolic byproducts. We investigate the role of the arc operon in probiotic Escherichia coli Nissle 1917 on human gut community assembly and health-relevant metabolite profiles. By stabilizing environmental pH, the arc operon reduces variability in community composition in response to pH perturbations and frequently enhances butyrate production in synthetic communities. We use a tailored machine learning model for microbiomes to predict community assembly in response to variation in initial media pH and arc operon activity. This model uncovers the pH- and arc operon-dependent interactions shaping community assembly. Human gut species display altered colonization dynamics in response to the arc operon in the murine gut. In sum, our framework to quantify the contribution of a specific pathway to microbial community assembly and metabolite production can reveal new engineering strategies. A record of this paper's transparent peer review process is included in the supplemental information.

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解码精氨酸二水解酶途径在塑造人类肠道群落组装和健康相关代谢物中的作用。

精氨酸二水解酶途径（圆弧操纵子）通过将精氨酸转化为代谢副产物提供了一个代谢生态位。我们研究了益生菌大肠杆菌Nissle 1917中arc操纵子在人类肠道群落组装和健康相关代谢物谱中的作用。通过稳定环境pH值，圆弧操纵子减少了群落组成对pH扰动的响应变异性，并经常提高合成群落中丁酸盐的产量。我们使用定制的微生物组机器学习模型来预测群落组装对初始培养基pH和arc操纵子活性变化的响应。该模型揭示了pH和arc操纵子依赖的相互作用，形成了群落组装。在小鼠肠道中，人类肠道物种显示出改变的定植动态，以响应弧形操纵子。总之，我们的框架量化了特定途径对微生物群落组装和代谢物生产的贡献，可以揭示新的工程策略。本文的透明同行评议过程记录包含在补充信息中。

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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Cell systems

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