Litcius/Paper detail

Environmental and stoichiometric controls on microbial carbon‐use efficiency in soils

Stefano Manzoni, Philip Taylor, Andreas Richter, Amilcare Porporato, Göran I. Ågren

2012New Phytologist1,689 citationsDOIOpen Access PDF

Abstract

Carbon (C) metabolism is at the core of ecosystem function. Decomposers play a critical role in this metabolism as they drive soil C cycle by mineralizing organic matter to CO(2). Their growth depends on the carbon-use efficiency (CUE), defined as the ratio of growth over C uptake. By definition, high CUE promotes growth and possibly C stabilization in soils, while low CUE favors respiration. Despite the importance of this variable, flexibility in CUE for terrestrial decomposers is still poorly characterized and is not represented in most biogeochemical models. Here, we synthesize the theoretical and empirical basis of changes in CUE across aquatic and terrestrial ecosystems, highlighting common patterns and hypothesizing changes in CUE under future climates. Both theoretical considerations and empirical evidence from aquatic organisms indicate that CUE decreases as temperature increases and nutrient availability decreases. More limited evidence shows a similar sensitivity of CUE to temperature and nutrient availability in terrestrial decomposers. Increasing CUE with improved nutrient availability might explain observed declines in respiration from fertilized stands, while decreased CUE with increasing temperature and plant C : N ratios might decrease soil C storage. Current biogeochemical models could be improved by accounting for these CUE responses along environmental and stoichiometric gradients.

Topics & Concepts

DecomposerBiogeochemical cycleEcosystemNutrientCarbon cycleSoil waterTerrestrial ecosystemEcological stoichiometryEcologySoil carbonAquatic ecosystemNutrient cycleEnvironmental chemistryEnvironmental scienceSoil organic matterBiogeochemistryBiologyChemistryMicrobial Community Ecology and PhysiologySoil Carbon and Nitrogen DynamicsSoil and Water Nutrient Dynamics