Journal Article
mSystems, vol. 4, iss. 4, 2019
Authors
Taniya Roy Chowdhury, Joon-Yong Lee, Eric M. Bottos, Colin J. Brislawn, Richard Allen White, Lisa M. Bramer, Joseph Brown, Jeremy D. Zucker, Young-Mo Kim, Ari Jumpponen, Charles W. Rice, Sarah J. Fansler, Thomas O. Metz, Lee Ann McCue, Stephen J. Callister, Hyun-Seob Song, Janet K. Jansson, Steven J. Hallam
Abstract
Climate change is predicted to result in increased drought extent and intensity in the highly productive, former tallgrass prairie region of the continental United States. These soils store large reserves of carbon. The decrease in soil moisture due to drought has largely unknown consequences on soil carbon cycling and other key biogeochemical cycles carried out by soil microbiomes. In this study, we found that soil drying had a significant impact on the structure and function of soil microbial communities, including shifts in expression of specific metabolic pathways, such as those leading toward production of osmoprotectant compounds. This study demonstrates the application of an untargeted multi-omics approach to decipher details of the soil microbial community’s metaphenotypic response to environmental perturbations and should be applicable to studies of other complex microbial systems as well.
