Microbial assemblages and associated biogeochemical processes in Lake Bonney, a permanently ice-covered lake in the McMurdo Dry Valleys, Antarctica.

IF 6.2 2区 环境科学与生态学 Q1 GENETICS & HEREDITY
Hanbyul Lee, Kyuin Hwang, Ahnna Cho, Soyeon Kim, Minkyung Kim, Rachael Morgan-Kiss, John C Priscu, Kyung Mo Kim, Ok-Sun Kim
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引用次数: 0

Abstract

Background: Lake Bonney, which is divided into a west lobe (WLB) and an east lobe (ELB), is a perennially ice-covered lake located in the McMurdo Dry Valleys of Antarctica. Despite previous reports on the microbial community dynamics of ice-covered lakes in this region, there is a paucity of information on the relationship between microbial genomic diversity and associated nutrient cycling. Here, we applied gene- and genome-centric approaches to investigate the microbial ecology and reconstruct microbial metabolic potential along the depth gradient in Lake Bonney.

Results: Lake Bonney is strongly chemically stratified with three distinct redox zones, yielding different microbial niches. Our genome enabled approach revealed that in the sunlit and relatively freshwater epilimnion, oxygenic photosynthetic production by the cyanobacterium Pseudanabaena and a diversity of protists and microalgae may provide new organic carbon to the environment. CO-oxidizing bacteria, such as Acidimicrobiales, Nanopelagicales, and Burkholderiaceae were also prominent in the epilimnion and their ability to oxidize carbon monoxide to carbon dioxide may serve as a supplementary energy conservation strategy. In the more saline metalimnion of ELB, an accumulation of inorganic nitrogen and phosphorus supports photosynthesis despite relatively low light levels. Conversely, in WLB the release of organic rich subglacial discharge from Taylor Glacier into WLB would be implicated in the possible high abundance of heterotrophs supported by increased potential for glycolysis, beta-oxidation, and glycoside hydrolase and may contribute to the growth of iron reducers in the dark and extremely saline hypolimnion of WLB. The suboxic and subzero temperature zones beneath the metalimnia in both lobes supported microorganisms capable of utilizing reduced nitrogens and sulfurs as electron donors. Heterotrophs, including nitrate reducing sulfur oxidizing bacteria, such as Acidimicrobiales (MAG72) and Salinisphaeraceae (MAG109), and denitrifying bacteria, such as Gracilimonas (MAG7), Acidimicrobiales (MAG72) and Salinisphaeraceae (MAG109), dominated the hypolimnion of WLB, whereas the environmental harshness of the hypolimnion of ELB was supported by the relatively low in metabolic potential, as well as the abundance of halophile Halomonas and endospore-forming Virgibacillus.

Conclusions: The vertical distribution of microbially driven C, N and S cycling genes/pathways in Lake Bonney reveals the importance of geochemical gradients to microbial diversity and biogeochemical cycles with the vertical water column.

南极洲麦克默多干谷永久冰封湖泊邦尼湖中的微生物群落及相关生物地球化学过程。
背景:邦尼湖(Lake Bonney)分为西湖(WLB)和东湖(ELB),是位于南极洲麦克默多干谷(McMurdo Dry Valleys)的一个常年冰封的湖泊。尽管之前有关于该地区冰封湖泊微生物群落动态的报道,但关于微生物基因组多样性与相关营养循环之间关系的信息却很少。在这里,我们采用了以基因和基因组为中心的方法来研究邦尼湖的微生物生态学,并沿着深度梯度重建微生物的代谢潜力:结果:邦尼湖具有强烈的化学分层,有三个不同的氧化还原区,产生了不同的微生物生态位。我们的基因组学方法发现,在阳光充足和相对淡水的上水层,蓝藻、多种原生动物和微藻类的氧光合作用可为环境提供新的有机碳。一氧化碳氧化细菌,如酸性微生物菌、Nanopelagicales 和 Burkholderiaceae 等,在上水层也很突出,它们将一氧化碳氧化为二氧化碳的能力可能是一种补充性节能策略。在盐度较高的 ELB 金属盐层中,尽管光照水平相对较低,但无机氮和磷的积累仍能支持光合作用。相反,在 WLB 中,泰勒冰川向 WLB 释放的富含有机物的冰川下泄流可能与异养生物的大量存在有关,这些异养生物因糖酵解、β-氧化和糖苷水解酶的潜力增加而得到支持,并可能有助于铁还原剂在 WLB 黑暗和极度盐化的下盐层中生长。两个叶片金属膜下的亚缺氧和亚零度温度区支持能够利用还原型氮和硫作为电子供体的微生物。异养生物,包括硝酸盐还原硫氧化细菌,如酸性微生物菌(MAG72)和 Salinisphaeraceae(MAG109),以及反硝化细菌,如 Gracilimonas(MAG7)、酸性微生物菌(MAG72)和 Salinisphaeraceae(MAG109)、而 ELB 的下盐层环境恶劣,代谢潜力相对较低,嗜卤卤单胞菌和内生孢子形成维吉巴氏菌数量丰富。结论邦尼湖中微生物驱动的 C、N 和 S 循环基因/途径的垂直分布揭示了地球化学梯度对微生物多样性和垂直水柱生物地球化学循环的重要性。
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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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