产甲烷湖泊沉积物中缺氧条件下需氧养甲烷生物的生存策略。

IF 6.2 2区 环境科学与生态学 Q1 GENETICS & HEREDITY
Almog Gafni, Maxim Rubin-Blum, Colin Murrell, Hanni Vigderovich, Werner Eckert, Nasmille Larke-Mejía, Orit Sivan
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引用次数: 0

摘要

背景:微生物甲烷氧化(即甲烷营养作用)在减少水生系统释放强效温室气体甲烷方面发挥着至关重要的作用。虽然好氧甲烷营养体在富氧环境中是一个成熟的过程,但新出现的证据表明它们在缺氧条件下也有活动。然而,人们对这些甲烷营养体对这种环境的适应性仍然知之甚少。在这里,我们探讨了好氧甲烷营养体在基纳特湖(LK)产甲烷沉积物中对缺氧的遗传适应性。这些位于氧化带和硫化带之下的湖泊甲烷沉积物以前的特点是甲烷氧化与好氧甲烷营养体参与的铁还原作用:为了探索甲烷营养体对缺氧的适应性,我们使用 LK 沉积物作为接种体进行了两项实验:(i) 利用 DNA 稳定同位素探针(DNA-SIP)对环境空气进行好氧 "经典 "甲烷营养体富集;(ii) 反复添加 1% 氧气进行缺氧甲烷营养体富集。对 16S rRNA 基因扩增子的分析表明,富集了甲基球菌属甲烷营养群落,占富集群落的三分之一。在有氧实验中,甲基芽孢杆菌(Methylobacter)、甲基芽孢杆菌(Methylogaea)和甲基单胞菌(Methylomonas)最为突出,而在缺氧条件下,主要富集的是甲基单胞菌。通过对从这些实验中提取的 DNA 进行元基因组学测序,我们整理出了五个甲基球菌元基因组组装基因组(MAGs),并评估了它们在缺氧环境中生存的遗传基础。通过与另外 62 个来自不同环境的甲球藻基因组进行比较分析,我们发现在大多数被研究的甲球藻基因组中都存在几种适应缺氧环境的核心基因,包括高亲和性细胞色素氧化酶、氧结合蛋白、基于发酵的甲烷氧化、运动性和糖原利用。我们还发现,包括 LK 甲基球菌在内的一些甲基球菌可进行反硝化,而金属和腐殖质也可作为氧气以外的电子受体。外膜多血红素细胞色素和核黄素被认为是利用金属和腐殖质的潜在媒介。这些不同的机制表明,甲烷营养体有能力在以前认为不适合其生长的生态位中茁壮成长:我们的研究揭示了产甲烷 LK 沉积物中富集的甲基球菌甲烷营养体在缺氧条件下的生存能力。基因组分析揭示了一系列遗传能力,这些能力可能使这些甲烷营养体发挥作用。所发现的机制,如使用替代电子受体的机制,拓展了我们对甲烷营养体在不同生态环境中的恢复能力的认识。这些发现有助于拓宽微生物甲烷氧化的知识面,并对理解甲烷营养体在各种环境条件下减少甲烷排放的潜在贡献具有影响。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Survival strategies of aerobic methanotrophs under hypoxia in methanogenic lake sediments.

Background: Microbial methane oxidation, methanotrophy, plays a crucial role in mitigating the release of the potent greenhouse gas methane from aquatic systems. While aerobic methanotrophy is a well-established process in oxygen-rich environments, emerging evidence suggests their activity in hypoxic conditions. However, the adaptability of these methanotrophs to such environments has remained poorly understood. Here, we explored the genetic adaptability of aerobic methanotrophs to hypoxia in the methanogenic sediments of Lake Kinneret (LK). These LK methanogenic sediments, situated below the oxidic and sulfidic zones, were previously characterized by methane oxidation coupled with iron reduction via the involvement of aerobic methanotrophs.

Results: In order to explore the adaptation of the methanotrophs to hypoxia, we conducted two experiments using LK sediments as inoculum: (i) an aerobic "classical" methanotrophic enrichment with ambient air employing DNA stable isotope probing (DNA-SIP) and (ii) hypoxic methanotrophic enrichment with repeated spiking of 1% oxygen. Analysis of 16S rRNA gene amplicons revealed the enrichment of Methylococcales methanotrophs, being up to a third of the enriched community. Methylobacter, Methylogaea, and Methylomonas were prominent in the aerobic experiment, while hypoxic conditions enriched primarily Methylomonas. Using metagenomics sequencing of DNA extracted from these experiments, we curated five Methylococcales metagenome-assembled genomes (MAGs) and evaluated the genetic basis for their survival in hypoxic environments. A comparative analysis with an additional 62 Methylococcales genomes from various environments highlighted several core genetic adaptations to hypoxia found in most examined Methylococcales genomes, including high-affinity cytochrome oxidases, oxygen-binding proteins, fermentation-based methane oxidation, motility, and glycogen use. We also found that some Methylococcales, including LK Methylococcales, may denitrify, while metals and humic substances may also serve as electron acceptors alternative to oxygen. Outer membrane multi-heme cytochromes and riboflavin were identified as potential mediators for the utilization of metals and humic material. These diverse mechanisms suggest the ability of methanotrophs to thrive in ecological niches previously thought inhospitable for their growth.

Conclusions: Our study sheds light on the ability of enriched Methylococcales methanotrophs from methanogenic LK sediments to survive under hypoxia. Genomic analysis revealed a spectrum of genetic capabilities, potentially enabling these methanotrophs to function. The identified mechanisms, such as those enabling the use of alternative electron acceptors, expand our understanding of methanotroph resilience in diverse ecological settings. These findings contribute to the broader knowledge of microbial methane oxidation and have implications for understanding and potential contribution methanotrophs may have in mitigating methane emissions in various environmental conditions.

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来源期刊
Environmental Microbiome
Environmental Microbiome Immunology and Microbiology-Microbiology
CiteScore
7.40
自引率
2.50%
发文量
55
审稿时长
13 weeks
期刊介绍: Microorganisms, omnipresent across Earth's diverse environments, play a crucial role in adapting to external changes, influencing Earth's systems and cycles, and contributing significantly to agricultural practices. Through applied microbiology, they offer solutions to various everyday needs. Environmental Microbiome recognizes the universal presence and significance of microorganisms, inviting submissions that explore the diverse facets of environmental and applied microbiological research.
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