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Fungal-bacterial diversity and microbiome complexity predict ecosystem functioning

2019· article· en· 1,791 citations· W2981774387 on OpenAlex· 10.1038/s41467-019-12798-y

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GPT teacher head0.233
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Abstract

The soil microbiome is highly diverse and comprises up to one quarter of Earth's diversity. Yet, how such a diverse and functionally complex microbiome influences ecosystem functioning remains unclear. Here we manipulated the soil microbiome in experimental grassland ecosystems and observed that microbiome diversity and microbial network complexity positively influenced multiple ecosystem functions related to nutrient cycling (e.g. multifunctionality). Grassland microcosms with poorly developed microbial networks and reduced microbial richness had the lowest multifunctionality due to fewer taxa present that support the same function (redundancy) and lower diversity of taxa that support different functions (reduced functional uniqueness). Moreover, different microbial taxa explained different ecosystem functions pointing to the significance of functional diversity in microbial communities. These findings indicate the importance of microbial interactions within and among fungal and bacterial communities for enhancing ecosystem performance and demonstrate that the extinction of complex ecological associations belowground can impair ecosystem functioning.

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The record

Venue
Nature Communications
Topic
Microbial Community Ecology and Physiology
Field
Environmental Science
Canadian institutions
Agriculture and Agri-Food Canada
Funders
AgroscopeKoninklijke Nederlandse Akademie van WetenschappenSchweizerischer Nationalfonds zur Förderung der Wissenschaftlichen ForschungNederlands Instituut voor EcologieNational Science Foundation
Keywords
EcosystemMicrobiomeMicrocosmEcologyBiologyNutrient cycleSpecies richnessGrasslandBioinformatics
Has abstract in OpenAlex
yes