Microbial temperature sensitivity and biomass change explain soil carbon loss with warming.
Tom W. N. Walker,Tom W. N. Walker,Christina Kaiser,Christina Kaiser,Florian Strasser,Craig W. Herbold,Niki I. W. Leblans,Niki I. W. Leblans,Dagmar Woebken,Ivan A. Janssens,Bjarni D. Sigurdsson,Andreas Richter,Andreas Richter +12 more
TLDR
A framework is provided for interpreting the links between temperature, microbial activity and soil carbon loss on timescales relevant to Earth’s climate system via their control over microbial biomass.Abstract:
Soil microorganisms control carbon losses from soils to the atmosphere1-3, yet their responses to climate warming are often short-lived and unpredictable4-7. Two mechanisms, microbial acclimation and substrate depletion, have been proposed to explain temporary warming effects on soil microbial activity8-10. However, empirical support for either mechanism is unconvincing. Here we used geothermal temperature gradients (> 50 years of field warming)11 and a short-term experiment to show that microbial activity (gross rates of growth, turnover, respiration and carbon uptake) is intrinsically temperature sensitive and does not acclimate to warming (+ 6 oC) over weeks or decades. Permanently accelerated microbial activity caused carbon loss from soil. However, soil carbon loss was temporary because substrate depletion reduced microbial biomass and constrained the influence of microbes over the ecosystem. A microbial biogeochemical model12-14 showed that these observations are reproducible through a modest, but permanent, acceleration in microbial physiology. These findings reveal a mechanism by which intrinsic microbial temperature sensitivity and substrate depletion together dictate warming effects on soil carbon loss via their control over microbial biomass. We thus provide a framework for interpreting the links between temperature, microbial activity and soil carbon loss on timescales relevant to Earth's climate system.read more
Citations
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Journal ArticleDOI
Scientists' Warning to Humanity: Microorganisms and Climate Change
Ricardo Cavicchioli,William J. Ripple,Kenneth N. Timmis,Farooq Azam,Lars R. Bakken,Matthew Baylis,Michael J. Behrenfeld,Antje Boetius,Philip W. Boyd,Aimée T. Classen,Thomas W. Crowther,Roberto Danovaro,Christine M. Foreman,Jef Huisman,David A. Hutchins,Janet K. Jansson,David M. Karl,Britt Koskella,David B. Mark Welch,Jennifer B. H. Martiny,Mary Ann Moran,Victoria J. Orphan,David S. Reay,Justin V. Remais,Virginia I. Rich,Brajesh K. Singh,Lisa Y. Stein,Frank J. Stewart,Matthew B. Sullivan,Madeleine J. H. van Oppen,Madeleine J. H. van Oppen,Scott C. Weaver,Eric A. Webb,Nicole S. Webster,Nicole S. Webster +34 more
TL;DR: This Consensus Statement documents the central role and global importance of microorganisms in climate change biology and puts humanity on notice that the impact of climate change will depend heavily on responses of micro organisms, which are essential for achieving an environmentally sustainable future.
Journal ArticleDOI
Increased microbial growth, biomass, and turnover drive soil organic carbon accumulation at higher plant diversity.
Judith Prommer,Tom W. N. Walker,Tom W. N. Walker,Wolfgang Wanek,Judith Braun,Judith Braun,David Zezula,Yuntao Hu,Yuntao Hu,Florian Hofhansl,Andreas Richter,Andreas Richter +11 more
TL;DR: It is suggested that PSR favors faster rates of microbial growth and turnover, likely due to greater plant productivity, resulting in higher amounts of microbial biomass and necromass that translate into the observed increase in SOC.
Journal ArticleDOI
Above- and belowground linkages shape responses of mountain vegetation to climate change
TL;DR: This work unravels above- and belowground linkages by drawing insights from short-term experimental manipulations and elevation gradient studies to better understand mountain ecosystem dynamics and their feedbacks to climate.
Journal ArticleDOI
Soil carbon loss with warming: New evidence from carbon-degrading enzymes.
Ji Chen,Lars Elsgaard,Kees Jan van Groenigen,Jørgen E. Olesen,Zhi Liang,Yu Jiang,Poul Erik Lærke,Yuefang Zhang,Yiqi Luo,Bruce A. Hungate,Robert L. Sinsabaugh,Uffe Jørgensen +11 more
TL;DR: It is shown, using meta-analysis, that reductions in soil C stocks with warming are associated with increased ratios of ligninase to cellulase activity, and that warming stimulates microbial utilization of recalcitrant C pools, possibly exacerbating long-term climate-C feedbacks.
References
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Journal ArticleDOI
Acclimatization of soil respiration to warming in a tall grass prairie
TL;DR: Observations in a tall grass prairie ecosystem in the US Great Plains indicate that the temperature sensitivity of soil respiration decreases—or acclimatizes—under warming and that the acclim atization is greater at high temperatures, which may weaken the positive feedback between the terrestrial carbon cycle and climate.
Journal ArticleDOI
Soil-carbon response to warming dependent on microbial physiology
TL;DR: In this article, the authors explore the mechanisms using a microbial-enzyme model to simulate the responses of soil carbon to warming by 5'∘C. They find that declines in microbial biomass and degradative enzymes can explain the observed attenuation of soil-carbon emissions in response to warming.
Journal ArticleDOI
Soil Warming and Carbon-Cycle Feedbacks to the Climate System
Jerry M. Melillo,Paul A. Steudler,John D. Aber,K. Newkirk,H. Lux,F. P. Bowles,C. Catricala,A. Magill,Toby Ahrens,S. Morrisseau +9 more
TL;DR: In this paper, a decade-long soil warming experiment in a mid-latitude hardwood forest, documented changes in soil carbon and nitrogen cycling in order to investigate the consequences of these changes for the climate system, and showed that whereas soil warming accelerates soil organic matter decay and carbon dioxide fluxes to the atmosphere, this response is small and short-lived for a midlatitude forest, because of the limited size of the labile soil carbon pool.
Journal ArticleDOI
Environmental and stoichiometric controls on microbial carbon‐use efficiency in soils
TL;DR: Theoretical considerations and empirical evidence indicate that CUE decreases as temperature increases and nutrient availability decreases, and current biogeochemical models could be improved by accounting for these CUE responses along environmental and stoichiometric gradients.
Journal ArticleDOI
Global patterns in belowground communities.
TL;DR: A meta-analysis of published data identifies robust patterns in the structure of belowground microbial and faunal communities at broad scales which may be explained by universal mechanisms that regulate belowground biota across biomes.
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