Functional diversity of microbial decomposers facilitates plant coexistence in a plant–microbe–soil feedback model

Theory and empirical evidence suggest that plant–soil feedback (PSF) determines the structure of a plant community and nutrient cycling in terrestrial ecosystems. The plant community alters the nutrient pool size in soil by affecting litter decomposition processes, which in turn shapes the plant com...

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Veröffentlicht in:	Proceedings of the National Academy of Sciences - PNAS 2010-08, Vol.107 (32), p.14251-14256
Hauptverfasser:	Miki, Takeshi, Ushio, Masayuki, Fukui, Shin, Kondoh, Michio, Levin, Simon A.
Format:	Artikel
Sprache:	eng
Schlagworte:	Biodiversity Biological Sciences Biomass Coexistence Community composition Community ecology Decomposition Ecosystem Feedback Food Food Chain Functional diversity Immobilization Litter Litter size Microbiology Microorganisms Mineralization Models, Biological Models, Theoretical Nutrient cycle Nutrients Plant communities Plant litter Plants Plants - microbiology Soil Soil Microbiology Soil microorganisms Soil nutrients Terrestrial ecosystems
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container_title	Proceedings of the National Academy of Sciences - PNAS
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creator	Miki, Takeshi Ushio, Masayuki Fukui, Shin Kondoh, Michio Levin, Simon A.
description	Theory and empirical evidence suggest that plant–soil feedback (PSF) determines the structure of a plant community and nutrient cycling in terrestrial ecosystems. The plant community alters the nutrient pool size in soil by affecting litter decomposition processes, which in turn shapes the plant community, forming a PSF system. However, the role of microbial decomposers in PSF function is often overlooked, and it remains unclear whether decomposers reinforce or weaken litter-mediated plant control over nutrient cycling. Here, we present a theoretical model incorporating the functional diversity of both plants and microbial decomposers. Two fundamental microbial processes are included that control nutrient mineralization from plant litter: (i) assimilation of mineralized nutrient into the microbial biomass (microbial immobilization), and (ii) release of the microbial nutrients into the inorganic nutrient pool (net mineralization). With this model, we show that microbial diversity may act as a buffer that weakens plant control over the soil nutrient pool, reversing the sign of PSF from positive to negative and facilitating plant coexistence. This is explained by the decoupling of litter decomposability and nutrient pool size arising from a flexible change in the microbial community composition and decomposition processes in response to variations in plant litter decomposability. Our results suggest that the microbial community plays a central role in PSF function and the plant community structure. Furthermore, the results strongly imply that the plant-centered view of nutrient cycling should be changed to a plant–microbe–soil feedback system, by incorporating the community ecology of microbial decomposers and their functional diversity.
doi_str_mv	10.1073/pnas.0914281107
format	Article
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The plant community alters the nutrient pool size in soil by affecting litter decomposition processes, which in turn shapes the plant community, forming a PSF system. However, the role of microbial decomposers in PSF function is often overlooked, and it remains unclear whether decomposers reinforce or weaken litter-mediated plant control over nutrient cycling. Here, we present a theoretical model incorporating the functional diversity of both plants and microbial decomposers. Two fundamental microbial processes are included that control nutrient mineralization from plant litter: (i) assimilation of mineralized nutrient into the microbial biomass (microbial immobilization), and (ii) release of the microbial nutrients into the inorganic nutrient pool (net mineralization). With this model, we show that microbial diversity may act as a buffer that weakens plant control over the soil nutrient pool, reversing the sign of PSF from positive to negative and facilitating plant coexistence. This is explained by the decoupling of litter decomposability and nutrient pool size arising from a flexible change in the microbial community composition and decomposition processes in response to variations in plant litter decomposability. Our results suggest that the microbial community plays a central role in PSF function and the plant community structure. 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This is explained by the decoupling of litter decomposability and nutrient pool size arising from a flexible change in the microbial community composition and decomposition processes in response to variations in plant litter decomposability. Our results suggest that the microbial community plays a central role in PSF function and the plant community structure. 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This is explained by the decoupling of litter decomposability and nutrient pool size arising from a flexible change in the microbial community composition and decomposition processes in response to variations in plant litter decomposability. Our results suggest that the microbial community plays a central role in PSF function and the plant community structure. Furthermore, the results strongly imply that the plant-centered view of nutrient cycling should be changed to a plant–microbe–soil feedback system, by incorporating the community ecology of microbial decomposers and their functional diversity.</abstract><cop>United States</cop><pub>National Academy of Sciences</pub><pmid>20663953</pmid><doi>10.1073/pnas.0914281107</doi><tpages>6</tpages><oa>free_for_read</oa></addata></record>
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subjects	Biodiversity Biological Sciences Biomass Coexistence Community composition Community ecology Decomposition Ecosystem Feedback Food Food Chain Functional diversity Immobilization Litter Litter size Microbiology Microorganisms Mineralization Models, Biological Models, Theoretical Nutrient cycle Nutrients Plant communities Plant litter Plants Plants - microbiology Soil Soil Microbiology Soil microorganisms Soil nutrients Terrestrial ecosystems
title	Functional diversity of microbial decomposers facilitates plant coexistence in a plant–microbe–soil feedback model
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