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The adjustment of life history strategies drives the ecological adaptations of soil microbiota to aridity

Chaonan LiKey Laboratory of Environmental and Applied Microbiology Chinese Academy of Sciences; Environmental Microbiology Key Laboratory of Sichuan Province Chengdu Institute of Biology Chinese Academy of Sciences Chengdu ChinaHaijun LiaoKey Laboratory of Environmental and Applied Microbiology Chinese Academy of Sciences; Environmental Microbiology Key Laboratory of Sichuan Province Chengdu Institute of Biology Chinese Academy of Sciences Chengdu ChinaLin XuKey Laboratory of Environmental and Applied Microbiology Chinese Academy of Sciences; Environmental Microbiology Key Laboratory of Sichuan Province Chengdu Institute of Biology Chinese Academy of Sciences Chengdu ChinaChangting WangInstitute of Qinghai‐Tibet Plateau Southwest Minzu University Chengdu ChinaNianpeng HeKey Laboratory of Ecosystem Network Observation and Modeling Institute of Geographic Sciences and Natural Resources Research Chinese Academy of Sciences Beijing ChinaJunming WangSection of Climate Science Illinois State Water Survey Prairie Research Institute University of Illinois at Urbana‐Champaign Champaign Illinois USAXiangzhen LiKey Laboratory of Environmental and Applied Microbiology Chinese Academy of Sciences; Environmental Microbiology Key Laboratory of Sichuan Province Chengdu Institute of Biology Chinese Academy of Sciences Chengdu China
2022en
ABI

Аннотация

Soil microbiota increase their fitness to local habitats by adjusting their life history strategies. Yet, how such adjustments drive their ecological adaptations in xeric grasslands remains elusive. In this study, shifts in the traits that potentially represent microbial life history strategies were studied along two aridity gradients with different climates using metagenomic and trait-based approaches. The results indicated that resource acquisition (e.g., higher activities of β-d-glucosidase and N-acetyl-β-d-glucosidase, higher degradation rates of cellulose and chitin, as well as genes involved in cell motility, biodegradation, transportation and competition) and growth yield (e.g., higher biomass and respiration) strategies were depleted at higher aridity. However, maintenance of cellular and high growth potential (e.g., higher metabolic quotients and genes related to DNA replication, transcription, translation, central carbon metabolism and biosynthesis) and stress tolerance (e.g., genes involved in DNA damage repair, cation transportation, sporulation and osmolyte biosynthesis) strategies were enriched at higher aridity. This implied that microbiota have lower growth yields but are probably well primed for rapid responses to pulses of rainfall in more arid soils, whereas those in less arid soils may have stronger resource acquisition and growth yield abilities. By integrating a large amount of evidence from taxonomic, metagenomic, genomic and biochemical investigations, this study demonstrates that the ecological adaptations of soil microbiota to aridity made by adjusting and optimizing their life history strategies are universal in xeric grasslands and provides an underlying mechanistic understanding of soil microbial responses to climate changes.

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