The application of ecological stoichiometry to plant-microbial-soil organic matter transformations

Elemental stoichiometry constitutes an inherent link between biogeochemistry and the structure and processes within food webs, and thus is at the core of ecosystem functioning. Stoichiometry allows for spanning different levels of biological organization, from cellular metabolism to ecosystem struct...

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Veröffentlicht in:	Ecological monographs 2015-05, Vol.85 (2), p.133-155
Hauptverfasser:	Zechmeister-Boltenstern, Sophie, Keiblinger, Katharina Maria, Mooshammer, Maria, Peñuelas, Josep, Richter, Andreas, Sardans, Jordi, Wanek, Wolfgang
Format:	Artikel
Sprache:	eng
Schlagworte:	Biogeochemistry carbon use efficiency Ecosystems Food chains Forest soils growth rate hypothesis homeostasis litter decomposition Microbial ecology nitrogen turnover nutrient recycling phosphorus deficiency Plant litter Plant nutrition Plants REVIEWS Soil ecology soil enzymes Soil fertility soil microbiology Soil microorganisms Soil nutrients Stoichiometry substrate age hypothesis Terrestrial ecosystems
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container_title	Ecological monographs
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creator	Zechmeister-Boltenstern, Sophie Keiblinger, Katharina Maria Mooshammer, Maria Peñuelas, Josep Richter, Andreas Sardans, Jordi Wanek, Wolfgang
description	Elemental stoichiometry constitutes an inherent link between biogeochemistry and the structure and processes within food webs, and thus is at the core of ecosystem functioning. Stoichiometry allows for spanning different levels of biological organization, from cellular metabolism to ecosystem structure and nutrient cycling, and is therefore particularly useful for establishing links between different ecosystem compartments. We review elemental carbon : nitrogen : phosphorus (C:N:P) ratios in terrestrial ecosystems (from vegetation, leaf litter, woody debris, and dead roots, to soil microbes and organic matter). While the stoichiometry of the plant, litter, and soil compartments of ecosystems is well understood, heterotrophic microbial communities, which dominate the soil food web and drive nutrient cycling, have received increasing interest in recent years. This review highlights the effects of resource stoichiometry on soil microorganisms and decomposition, specifically on the structure and function of heterotrophic microbial communities and suggests several general patterns. First, latitudinal gradients of soil and litter stoichiometry are reflected in microbial community structure and function. Second, resource stoichiometry may cause changes in microbial interactions and community dynamics that lead to feedbacks in nutrient availability. Third, global change alters the C:N, C:P, and N:P ratios of primary producers, with repercussions for microbial decomposer communities and critical ecosystem services such as soil fertility. We argue that ecological stoichiometry provides a framework to analyze and predict such global change effects at various scales.
doi_str_mv	10.1890/14-0777.1
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Stoichiometry allows for spanning different levels of biological organization, from cellular metabolism to ecosystem structure and nutrient cycling, and is therefore particularly useful for establishing links between different ecosystem compartments. We review elemental carbon : nitrogen : phosphorus (C:N:P) ratios in terrestrial ecosystems (from vegetation, leaf litter, woody debris, and dead roots, to soil microbes and organic matter). While the stoichiometry of the plant, litter, and soil compartments of ecosystems is well understood, heterotrophic microbial communities, which dominate the soil food web and drive nutrient cycling, have received increasing interest in recent years. This review highlights the effects of resource stoichiometry on soil microorganisms and decomposition, specifically on the structure and function of heterotrophic microbial communities and suggests several general patterns. First, latitudinal gradients of soil and litter stoichiometry are reflected in microbial community structure and function. Second, resource stoichiometry may cause changes in microbial interactions and community dynamics that lead to feedbacks in nutrient availability. Third, global change alters the C:N, C:P, and N:P ratios of primary producers, with repercussions for microbial decomposer communities and critical ecosystem services such as soil fertility. 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First, latitudinal gradients of soil and litter stoichiometry are reflected in microbial community structure and function. Second, resource stoichiometry may cause changes in microbial interactions and community dynamics that lead to feedbacks in nutrient availability. Third, global change alters the C:N, C:P, and N:P ratios of primary producers, with repercussions for microbial decomposer communities and critical ecosystem services such as soil fertility. 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subjects	Biogeochemistry carbon use efficiency Ecosystems Food chains Forest soils growth rate hypothesis homeostasis litter decomposition Microbial ecology nitrogen turnover nutrient recycling phosphorus deficiency Plant litter Plant nutrition Plants REVIEWS Soil ecology soil enzymes Soil fertility soil microbiology Soil microorganisms Soil nutrients Stoichiometry substrate age hypothesis Terrestrial ecosystems
title	The application of ecological stoichiometry to plant-microbial-soil organic matter transformations
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