Bacterial growth and environmental adaptation via thiamine biosynthesis and thiamine-mediated metabolic interactions.

IF 10.8 1区 环境科学与生态学 Q1 ECOLOGY ISME Journal Pub Date : 2024-01-08 DOI:10.1093/ismejo/wrae157
Xihui Xu, Can Li, Weimiao Cao, Lulu Yan, Lulu Cao, Qi Han, Minling Gao, Yahua Chen, Zhenguo Shen, Jiandong Jiang, Chen Chen
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Abstract

Understanding the ancestral transition from anaerobic to aerobic lifestyles is essential for comprehending life's early evolution. However, the biological adaptations occurring during this crucial transition remain largely unexplored. Thiamine is an important cofactor involved in central carbon metabolism and aerobic respiration. Here, we explored the phylogenetic and global distribution of thiamine-auxotrophic and thiamine-prototrophic bacteria based on the thiamine biosynthetic pathway in 154 838 bacterial genomes. We observed strong coincidences of the origin of thiamine-synthetic bacteria with the "Great Oxygenation Event," indicating that thiamine biosynthesis in bacteria emerged as an adaptation to aerobic respiration. Furthermore, we demonstrated that thiamine-mediated metabolic interactions are fundamental factors influencing the assembly and diversity of bacterial communities by a global survey across 4245 soil samples. Through our newly established stable isotope probing-metabolic modeling method, we uncovered the active utilization of thiamine-mediated metabolic interactions by bacterial communities in response to changing environments, thus revealing an environmental adaptation strategy employed by bacteria at the community level. Our study demonstrates the widespread thiamine-mediated metabolic interactions in bacterial communities and their crucial roles in setting the stage for an evolutionary transition from anaerobic to aerobic lifestyles and subsequent environmental adaptation. These findings provide new insights into early bacterial evolution and their subsequent growth and adaptations to environments.

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通过硫胺素生物合成和硫胺素介导的代谢相互作用实现细菌生长和环境适应。
了解祖先从厌氧生活方式向有氧生活方式的过渡对于理解生命的早期进化至关重要。然而,在这一关键过渡时期发生的生物适应性在很大程度上仍未得到探索。硫胺素是参与中心碳代谢和有氧呼吸的重要辅助因子。在这里,我们根据 154 838 个细菌基因组中的硫胺生物合成途径,探讨了硫胺素-缺养型和硫胺素-脯养型细菌的系统发育和全球分布。我们观察到硫胺素合成细菌的起源与 "大增氧事件"(GOE)高度吻合,表明细菌的硫胺素生物合成是为了适应有氧呼吸而出现的。此外,通过对全球 4245 个土壤样本的调查,我们证明了硫胺素介导的新陈代谢相互作用是影响细菌群落组装和多样性的基本因素。通过新建立的 SIP 代谢模型方法,我们发现了细菌群落在应对环境变化时对硫胺素介导的代谢相互作用的积极利用,从而揭示了细菌在群落水平上所采用的环境适应策略。我们的研究证明了硫胺素介导的代谢相互作用在细菌群落中的广泛存在,以及它们在为从厌氧生活方式向需氧生活方式的进化过渡和随后的环境适应创造条件方面的关键作用。这些发现为早期细菌进化及其随后的生长和环境适应提供了新的视角。
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来源期刊
ISME Journal
ISME Journal 环境科学-生态学
CiteScore
22.10
自引率
2.70%
发文量
171
审稿时长
2.6 months
期刊介绍: The ISME Journal covers the diverse and integrated areas of microbial ecology. We encourage contributions that represent major advances for the study of microbial ecosystems, communities, and interactions of microorganisms in the environment. Articles in The ISME Journal describe pioneering discoveries of wide appeal that enhance our understanding of functional and mechanistic relationships among microorganisms, their communities, and their habitats.
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