在生物废物的高温消化过程中，协同乙酸氧化取代了产乙酸甲烷发酵。

Syntrophic acetate oxidation replaces acetoclastic methanogenesis during thermophilic digestion of biowaste.

机构信息

Faculty of Technology, Microbiology - Biotechnology, University of Applied Sciences Emden/Leer, Emden, Germany.

出版信息

Microbiome. 2020 Jul 3;8(1):105. doi: 10.1186/s40168-020-00862-5.

DOI:10.1186/s40168-020-00862-5

PMID:32620171

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7334858/

Abstract

BACKGROUND

Anaerobic digestion (AD) is a globally important technology for effective waste and wastewater management. In AD, microorganisms interact in a complex food web for the production of biogas. Here, acetoclastic methanogens and syntrophic acetate-oxidizing bacteria (SAOB) compete for acetate, a major intermediate in the mineralization of organic matter. Although evidence is emerging that syntrophic acetate oxidation is an important pathway for methane production, knowledge about the SAOB is still very limited.

RESULTS

A metabolic reconstruction of metagenome-assembled genomes (MAGs) from a thermophilic solid state biowaste digester covered the basic functions of the biogas microbial community. Firmicutes was the most abundant phylum in the metagenome (53%) harboring species that take place in various functions ranging from the hydrolysis of polymers to syntrophic acetate oxidation. The Wood-Ljungdahl pathway for syntrophic acetate oxidation and corresponding genes for energy conservation were identified in a Dethiobacteraceae MAG that is phylogenetically related to known SAOB. 16S rRNA gene amplicon sequencing and enrichment cultivation consistently identified the uncultured Dethiobacteraceae together with Syntrophaceticus, Tepidanaerobacter, and unclassified Clostridia as members of a potential acetate-oxidizing core community in nine full-scare digesters, whereas acetoclastic methanogens were barely detected.

CONCLUSIONS

Results presented here provide new insights into a remarkable anaerobic digestion ecosystem where acetate catabolism is mainly realized by Bacteria. Metagenomics and enrichment cultivation revealed a core community of diverse and novel uncultured acetate-oxidizing bacteria and point to a particular niche for them in dry fermentation of biowaste. Their genomic repertoire suggests metabolic plasticity besides the potential for syntrophic acetate oxidation. Video Abstract.

摘要

背景

厌氧消化（AD）是一种全球范围内重要的废物和废水处理技术。在 AD 中，微生物通过复杂的食物网相互作用，以生产沼气。在这里，乙酰营养型产甲烷菌和互养乙酸氧化菌（SAOB）争夺乙酸，这是有机物矿化的主要中间产物。尽管有证据表明，共养乙酸氧化是产生甲烷的重要途径，但对 SAOB 的了解仍然非常有限。

结果

从嗜热固态生物废物消化器的宏基因组组装基因组（MAG）进行的代谢重建涵盖了沼气微生物群落的基本功能。厚壁菌门（Firmicutes）是宏基因组中最丰富的门（53%），包含参与各种功能的物种，从聚合物的水解到共养乙酸氧化。在与已知 SAOB 具有系统发育关系的脱硫杆菌科 MAG 中，鉴定了共养乙酸氧化的 Wood-Ljungdahl 途径和相应的能量保存基因。16S rRNA 基因扩增子测序和富集培养一致鉴定出未培养的脱硫杆菌科与 Syntrophaceticus、Tepidanaerobacter 和未分类的梭菌一起，作为九个全规模消化器中潜在乙酸氧化核心群落的成员，而乙酰营养型产甲烷菌几乎检测不到。

结论

本文提供的结果为一个显著的厌氧消化生态系统提供了新的见解，其中乙酸代谢主要由细菌实现。宏基因组学和富集培养揭示了一个多样化和新颖的未培养乙酸氧化细菌核心群落，并指出它们在生物废物干式发酵中具有特定的生态位。它们的基因组谱表明除了共养乙酸氧化的潜力外，还具有代谢可塑性。视频摘要。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/11e7/7334858/ecf34254e1a9/40168_2020_862_Fig1_HTML.jpg

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在生物废物的高温消化过程中，协同乙酸氧化取代了产乙酸甲烷发酵。

Syntrophic acetate oxidation replaces acetoclastic methanogenesis during thermophilic digestion of biowaste.

机构信息

Faculty of Technology, Microbiology - Biotechnology, University of Applied Sciences Emden/Leer, Emden, Germany.