Microbial Diversity Declines in Warmed Tropical Soil and Respiration Rise Exceed Predictions As Communities Adapt

Overview

Journal Nat Microbiol

Specialties Microbiology
Parasitology

Date 2022 Sep 6

PMID 36065063

Authors

Andrew T Nottingham

Jarrod J Scott

Kristin Saltonstall

Kirk Broders

Maria Montero-Sanchez

Johann Puspok

Erland Baath

Patrick Meir

Affiliations

Soon will be listed here.

Abstract

Perturbation of soil microbial communities by rising temperatures could have important consequences for biodiversity and future climate, particularly in tropical forests where high biological diversity coincides with a vast store of soil carbon. We carried out a 2-year in situ soil warming experiment in a tropical forest in Panama and found large changes in the soil microbial community and its growth sensitivity, which did not fully explain observed large increases in CO emission. Microbial diversity, especially of bacteria, declined markedly with 3 to 8 °C warming, demonstrating a breakdown in the positive temperature-diversity relationship observed elsewhere. The microbial community composition shifted with warming, with many taxa no longer detected and others enriched, including thermophilic taxa. This community shift resulted in community adaptation of growth to warmer temperatures, which we used to predict changes in soil CO emissions. However, the in situ CO emissions exceeded our model predictions threefold, potentially driven by abiotic acceleration of enzymatic activity. Our results suggest that warming of tropical forests will have rapid, detrimental consequences both for soil microbial biodiversity and future climate.

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