新的候选类群有助于芬诺斯坎地盾深层地下水的关键代谢过程。

IF 5.1 Q1 ECOLOGY
ISME communications Pub Date : 2024-09-23 eCollection Date: 2024-01-01 DOI:10.1093/ismeco/ycae113
Mark Dopson, Maryam Rezaei Somee, Carolina González-Rosales, Lauren M Lui, Stephanie Turner, Moritz Buck, Emelie Nilsson, George Westmeijer, Kamal Ashoor, Torben N Nielsen, Maliheh Mehrshad, Stefan Bertilsson
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引用次数: 0

摘要

大陆深层生物圈蕴藏着巨大的微生物宝库,但其多样性中仍有很大一部分是未培养和未描述的。在这项研究中,对芬诺斯坎地盾深层地下水中微生物群落的代谢潜力(元基因组)和活性(元转录组)进行了描述,重点是新的类群。DNA 测序产生了 1270 个去复制元基因组组装基因组和单体扩增基因组,包含 7 个新类、34 个目和 72 个科。大多数新类群隶属于棒状杆菌(Patescibacteria),而在新古细菌类群中,热蛋白菌群(Thermoproteota)和纳米古细菌群(Nanoarchaeota)占主导地位。元转录组显示,112 个新类群中的 30 个类、目和科在至少一个调查过的地下水样本中处于活跃状态,这意味着新类群代表了部分活跃但迄今尚未定性的深层生物圈组成部分。新型类群基因组主要通过伍德-荣格达尔途径进行碳固定、氮固定、硫和氢氧化以及发酵途径(包括乙酰生成)的编码。这些代谢过程对整个群落的能力贡献巨大,其中发酵占 9.9%,伍德-荣格达尔途径占 6.4%,硫氧化占 6.8%,氢氧化占 8.6%,通过硝酸盐(4.4%)和硫酸盐(6.0%)还原进行能量守恒。关键的新类群包括 UBA9089 门,其代表在碳固定、硝酸盐和硫酸盐还原以及有机和无机电子供体氧化中发挥着重要作用。这些数据有助于深入了解深生物圈微生物的多样性及其对该生态系统养分和能量循环的贡献。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Novel candidate taxa contribute to key metabolic processes in Fennoscandian Shield deep groundwaters.

The continental deep biosphere contains a vast reservoir of microorganisms, although a large proportion of its diversity remains both uncultured and undescribed. In this study, the metabolic potential (metagenomes) and activity (metatranscriptomes) of the microbial communities in Fennoscandian Shield deep subsurface groundwaters were characterized with a focus on novel taxa. DNA sequencing generated 1270 de-replicated metagenome-assembled genomes and single-amplified genomes, containing 7 novel classes, 34 orders, and 72 families. The majority of novel taxa were affiliated with Patescibacteria, whereas among novel archaea taxa, Thermoproteota and Nanoarchaeota representatives dominated. Metatranscriptomes revealed that 30 of the 112 novel taxa at the class, order, and family levels were active in at least one investigated groundwater sample, implying that novel taxa represent a partially active but hitherto uncharacterized deep biosphere component. The novel taxa genomes coded for carbon fixation predominantly via the Wood-Ljungdahl pathway, nitrogen fixation, sulfur plus hydrogen oxidation, and fermentative pathways, including acetogenesis. These metabolic processes contributed significantly to the total community's capacity, with up to 9.9% of fermentation, 6.4% of the Wood-Ljungdahl pathway, 6.8% of sulfur plus 8.6% of hydrogen oxidation, and energy conservation via nitrate (4.4%) and sulfate (6.0%) reduction. Key novel taxa included the UBA9089 phylum, with representatives having a prominent role in carbon fixation, nitrate and sulfate reduction, and organic and inorganic electron donor oxidation. These data provided insights into deep biosphere microbial diversity and their contribution to nutrient and energy cycling in this ecosystem.

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