CO-driven electron and carbon flux fuels synergistic microbial reductive dechlorination.

IF 13.8 1区 生物学 Q1 MICROBIOLOGY
Jingjing Wang, Xiuying Li, Huijuan Jin, Shujing Yang, Lian Yu, Hongyan Wang, Siqi Huang, Hengyi Liao, Xuhao Wang, Jun Yan, Yi Yang
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引用次数: 0

Abstract

Background: Carbon monoxide (CO), hypothetically linked to prebiotic biosynthesis and possibly the origin of the life, emerges as a substantive growth substrate for numerous microorganisms. In anoxic environments, the coupling of CO oxidation with hydrogen (H2) production is an essential source of electrons, which can subsequently be utilized by hydrogenotrophic bacteria (e.g., organohalide-respring bacteria). While Dehalococcoides strains assume pivotal roles in the natural turnover of halogenated organics and the bioremediation of chlorinated ethenes, relying on external H2 as their electron donor and acetate as their carbon source, the synergistic dynamics within the anaerobic microbiome have received comparatively less scrutiny. This study delves into the intriguing prospect of CO serving as both the exclusive carbon source and electron donor, thereby supporting the reductive dechlorination of trichloroethene (TCE).

Results: The metabolic pathway involved anaerobic CO oxidation, specifically the Wood-Ljungdahl pathway, which produced H2 and acetate as primary metabolic products. In an intricate microbial interplay, these H2 and acetate were subsequently utilized by Dehalococcoides, facilitating the dechlorination of TCE. Notably, Acetobacterium emerged as one of the pivotal collaborators for Dehalococcoides, furnishing not only a crucial carbon source essential for its growth and proliferation but also providing a defense against CO inhibition.

Conclusions: This research expands our understanding of CO's versatility as a microbial energy and carbon source and unveils the intricate syntrophic dynamics underlying reductive dechlorination.

一氧化碳驱动的电子和碳通量促进了协同微生物还原脱氯。
背景:一氧化碳(CO)被假定与前生物的生物合成有关,也可能是生命的起源。在缺氧环境中,一氧化碳氧化与氢(H2)产生的耦合是电子的重要来源,随后可被亲氢细菌(如有机卤化物回春细菌)利用。虽然 Dehalococcoides 菌株在卤代有机物的自然转化和氯化醚的生物修复中发挥着关键作用,依靠外部 H2 作为其电子供体和醋酸盐作为其碳源,但厌氧微生物群内的协同动态却较少受到关注。本研究深入探讨了 CO 同时作为唯一碳源和电子供体,从而支持三氯乙烯(TCE)还原脱氯的有趣前景:代谢途径涉及厌氧 CO 氧化,特别是伍德-荣格达尔途径,该途径产生的主要代谢产物是 H2 和醋酸盐。在错综复杂的微生物相互作用中,这些 H2 和乙酸酯随后被 Dehalococcoides 利用,促进了 TCE 的脱氯。值得注意的是,醋酸菌成为 Dehalococcoides 的关键合作者之一,不仅为其提供了生长和增殖所必需的重要碳源,还提供了抵御 CO 抑制的能力:这项研究拓展了我们对一氧化碳作为微生物能量和碳源的多功能性的认识,并揭示了还原脱氯背后错综复杂的合成营养动力学。
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
Microbiome
Microbiome MICROBIOLOGY-
CiteScore
21.90
自引率
2.60%
发文量
198
审稿时长
4 weeks
期刊介绍: Microbiome is a journal that focuses on studies of microbiomes in humans, animals, plants, and the environment. It covers both natural and manipulated microbiomes, such as those in agriculture. The journal is interested in research that uses meta-omics approaches or novel bioinformatics tools and emphasizes the community/host interaction and structure-function relationship within the microbiome. Studies that go beyond descriptive omics surveys and include experimental or theoretical approaches will be considered for publication. The journal also encourages research that establishes cause and effect relationships and supports proposed microbiome functions. However, studies of individual microbial isolates/species without exploring their impact on the host or the complex microbiome structures and functions will not be considered for publication. Microbiome is indexed in BIOSIS, Current Contents, DOAJ, Embase, MEDLINE, PubMed, PubMed Central, and Science Citations Index Expanded.
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