大气二氧化碳水平升高影响土壤原生生物功能核心群落组成

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-10-16 DOI:10.1007/s00284-024-03930-3
Alessandra Ö C-Dupont, David Rosado-Porto, Indhu Shanmuga Sundaram, Stefan Ratering, Sylvia Schnell
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引用次数: 0

摘要

被称为微核生物的原生生物是土壤微生物群落的重要组成部分。它们是细菌的重要捕食者,原生生物群落的生长和进化依赖于细菌群落的动态。与此同时,大气中二氧化碳含量的增加也会对根圈土壤中的细菌代谢活动产生重大影响。在这项研究中,我们调查了大气二氧化碳水平升高对代谢活跃的原生生物群落组成和功能的影响,以及它们与细菌的共存情况,这些原生生物群落来自吉森自由空气二氧化碳富集草地实验的块状土壤和根圈土壤。对土壤总 RNA 部分 18S rRNA 的元条码测序数据分析显示,二氧化碳浓度升高只刺激了细菌和其他微核生物的吞噬捕食者的少数 ASV,影响了原生生物群落的组成(P = 0.006,PERMANOVA)。同时,在环境 CO2 条件下,噬食和寄生类群似乎略微有利,微生物特征分析也证实了这一结果。原生生物与细菌共存的交叉比较显示,原核生物与微真核细胞之间大多呈负相关,这表明大气中二氧化碳的持续增加将导致土壤微生物群落及其相互作用发生变化,并有可能级联到土壤系统中更高的营养级。
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Elevated Atmospheric Co2 Levels Impact Soil Protist Functional Core Community Compositions.

Protists, known as microeukaryotes, are a significant portion of soil microbial communities. They are crucial predators of bacteria and depend on bacterial community dynamics for the growth and evolution of protistan communities. In parallel, increased levels of atmospheric CO2 significantly impact bacterial metabolic activity in rhizosphere soils. In this study, we investigated the effect of elevated atmospheric CO2 levels on the metabolically active protist community composition and function and their co-occurrences with bacteria from bulk and rhizosphere soils from the Giessen Free-Air CO2 enrichment grassland experiment. Metabarcoding sequencing data analyses of partial 18S rRNA from total soil RNA showed that elevated CO2 concentrations stimulated only a few ASVs of phagotrophic predators of bacteria and other microeukaryotes, affecting protist community composition (P = 0.006, PERMANOVA). In parallel, phagotrophic and parasitic lineages appeared slightly favoured under ambient CO2 conditions, results that were corroborated by microbial signature analyses. Cross-comparisons of protist-bacteria co-occurrences showed mostly negative relations between prokaryotes and microeukaryotes, indicating that the ongoing increase in atmospheric CO2 will lead to changes in microbial soil communities and their interactions, potentially cascading to higher trophic levels in soil systems.

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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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