Metagenome-assembled genomes of deep-sea sediments: changes in microbial functional potential lag behind redox transitions

IF 5.1 Q1 ECOLOGY
Clemens Schauberger, B. Thamdrup, C. Lemonnier, Blandine Trouche, J. Poulain, P. Wincker, Sophie Arnaud-Haond, R. Glud, Loïs Maignien
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Abstract

Hadal sediments are hotspots of microbial activity in the deep-sea and exhibit strong biogeochemical gradients. But while these gradients are widely assumed to exert selective forces on hadal microbial communities, the actual relationship between biogeochemistry, functional traits, and microbial community structure remains poorly understood. We tested whether the biogeochemical conditions in hadal sediments select for microbes based on their genomic capacity for respiration and carbohydrate utilization via a metagenomic analysis of over 153 samples from the Atacama Trench region (max. Depth 8085 m). The obtained 1357 non-redundant microbial genomes were affiliated with about one third of all known microbial phyla, with more than half belonging to unknown genera. This indicated that the capability to withstand extreme hydrostatic pressure is a phylogenetically widespread trait and that hadal sediments are inhabited by diverse microbial lineages. While community composition changed gradually over sediment depth, these changes were not driven by selection for respiratory or carbohydrate degradation capability in the oxic and nitrogenous zones, except in the case of anammox bacteria and nitrifying archaea. However, selection based on respiration and carbohydrate degradation capacity did structure the communities of the ferruginous zone, where aerobic and nitrogen respiring microbes declined exponentially (half-life 125–419 years) and were replaced by subsurface communities. These results highlight a delayed response of microbial community composition to selective pressure imposed by redox zonation and indicated that gradual changes in microbial composition are shaped by the high-resilience and slow growth of microbes in the seafloor.
深海沉积物的元基因组组装基因组:微生物功能潜力的变化滞后于氧化还原转变
Hadal 沉积物是深海微生物活动的热点,表现出强烈的生物地球化学梯度。尽管人们普遍认为这些梯度会对哈达尔微生物群落产生选择性作用,但对生物地球化学、功能特征和微生物群落结构之间的实际关系仍然知之甚少。我们通过对阿塔卡马海沟地区(最大深度 8085 米)超过 153 个样本进行元基因组分析,检验了哈达尔沉积物中的生物地球化学条件是否会根据微生物的呼吸和碳水化合物利用基因组能力对微生物进行选择。获得的 1357 个非冗余微生物基因组隶属于约三分之一的已知微生物门,其中一半以上属于未知属。这表明,承受极端静水压力的能力是一个系统发育中普遍存在的特征,而且哈达尔沉积物中栖息着多种微生物系。虽然群落组成随着沉积深度的增加而逐渐发生变化,但这些变化并不是由氧和氮区的呼吸或碳水化合物降解能力的选择所驱动的,氨氧细菌和硝化古细菌除外。然而,基于呼吸作用和碳水化合物降解能力的选择确实构建了铁锈色带群落的结构,在铁锈色带,需氧和氮呼吸微生物呈指数下降(半衰期为 125-419 年),并被地下群落所取代。这些结果突显了微生物群落组成对氧化还原分带所施加的选择压力的延迟反应,并表明微生物组成的渐变是由海底微生物的高恢复力和缓慢生长所决定的。
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