Litcius/Paper detail

The temperature sensitivity of soil: microbial biodiversity, growth, and carbon mineralization

Chao Wang, Ember M. Morrissey, Rebecca L. Mau, Michaela Hayer, J. Piñeiro, Michelle C. Mack, Jane C. Marks, Sheryl Bell, Samantha Miller, Egbert Schwartz, Paul Dijkstra, Benjamin J. Koch, Bram WG Stone, Alicia M. Purcell, Steven J. Blazewicz, Kirsten Hofmockel, Jennifer Pett‐Ridge, Bruce A. Hungate

2021The ISME Journal243 citationsDOIOpen Access PDF

Abstract

Abstract Microorganisms drive soil carbon mineralization and changes in their activity with increased temperature could feedback to climate change. Variation in microbial biodiversity and the temperature sensitivities (Q10) of individual taxa may explain differences in the Q10 of soil respiration, a possibility not previously examined due to methodological limitations. Here, we show phylogenetic and taxonomic variation in the Q10 of growth (5–35 °C) among soil bacteria from four sites, one from each of Arctic, boreal, temperate, and tropical biomes. Differences in the temperature sensitivities of taxa and the taxonomic composition of communities determined community-assembled bacterial growth Q10, which was strongly predictive of soil respiration Q10 within and across biomes. Our results suggest community-assembled traits of microbial taxa may enable enhanced prediction of carbon cycling feedbacks to climate change in ecosystems across the globe.

Topics & Concepts

BiologyMineralization (soil science)BiodiversityMicrobial ecologySoil microbiologyEcologyCarbon cycleGeomicrobiologyEnvironmental chemistryEnvironmental biotechnologySoil waterEcosystemBacteriaChemistryGeneticsGeology and Paleoclimatology ResearchSoil Carbon and Nitrogen DynamicsIsotope Analysis in Ecology