在营养状态不同的五个温带湖泊中,不依赖氢的二氧化碳还原作用主导了甲烷的生成。

IF 5.1 Q1 ECOLOGY
ISME communications Pub Date : 2024-06-21 eCollection Date: 2024-01-01 DOI:10.1093/ismeco/ycae089
Dimitri Meier, Sigrid van Grinsven, Anja Michel, Philip Eickenbusch, Clemens Glombitza, Xingguo Han, Annika Fiskal, Stefano Bernasconi, Carsten J Schubert, Mark A Lever
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引用次数: 0

摘要

湖泊沉积物中微生物产生的甲烷(CH4)是这种强效温室气体向大气排放的主要来源。据信,CH4 的产生和排放速率受电子受体分布和有机碳含量的影响,而电子受体分布和有机碳含量反过来又受导致富营养化的人为营养物质输入的影响。在此,我们研究了富营养化如何影响五个瑞士湖泊的甲烷生成途径、CH4生成古细菌的丰度和群落结构以及甲烷生成途径的时间分辨沉积记录。尽管富营养化湖泊沉积物中的 CH4 浓度较高,表明其甲烷生成活性较强,但低营养湖泊沉积物中的甲烷菌丰度最高。此外,根据沉积层是在寡营养还是富营养条件下沉积的不同,甲烷菌群落组成在最低分类水平(OTU)上存在显著差异,但与电子受体的原位分布没有明显的相关趋势。值得注意的是,尽管根据碳同位素分馏值、分类学特征和常驻甲烷菌基因组,二氧化碳还原产生甲烷是所有沉积物中的主要途径,但根据测量的反应物和产物浓度,氢(H2)的二氧化碳还原在热力学上是不利的。相反,CO2还原甲烷菌和具有细胞外电子传递潜力的厌氧细菌基因组丰度之间的强相关性表明,湖泊沉积物中甲烷菌的CO2还原主要是由合成细菌的直接电子传递驱动的,而不涉及作为电子穿梭器的H2。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Hydrogen-independent CO2 reduction dominates methanogenesis in five temperate lakes that differ in trophic states.

Emissions of microbially produced methane (CH4) from lake sediments are a major source of this potent greenhouse gas to the atmosphere. The rates of CH4 production and emission are believed to be influenced by electron acceptor distributions and organic carbon contents, which in turn are affected by anthropogenic inputs of nutrients leading to eutrophication. Here, we investigate how eutrophication influences the abundance and community structure of CH4 producing Archaea and methanogenesis pathways across time-resolved sedimentary records of five Swiss lakes with well-characterized trophic histories. Despite higher CH4 concentrations which suggest higher methanogenic activity in sediments of eutrophic lakes, abundances of methanogens were highest in oligotrophic lake sediments. Moreover, while the methanogenic community composition differed significantly at the lowest taxonomic levels (OTU), depending on whether sediment layers had been deposited under oligotrophic or eutrophic conditions, it showed no clear trend in relation to in situ distributions of electron acceptors. Remarkably, even though methanogenesis from CO2-reduction was the dominant pathway in all sediments based on carbon isotope fractionation values, taxonomic identities, and genomes of resident methanogens, CO2-reduction with hydrogen (H2) was thermodynamically unfavorable based on measured reactant and product concentrations. Instead, strong correlations between genomic abundances of CO2-reducing methanogens and anaerobic bacteria with potential for extracellular electron transfer suggest that methanogenic CO2-reduction in lake sediments is largely powered by direct electron transfer from syntrophic bacteria without involvement of H2 as an electron shuttle.

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