营养物
生态系统
生物
生态学
营养循环
微生物种群生物学
草原
土壤养分
陆地生态系统
环境科学
磷
植物群落
农学
生态演替
细菌
化学
有机化学
遗传学
作者
Jonathan Leff,Stuart E. Jones,Suzanne M. Prober,Albert Barberán,Elizabeth T. Borer,Jennifer Firn,W. Stanley Harpole,Sarah E. Hobbie,Kirsten Hofmockel,Johannes M. H. Knops,Rebecca L. McCulley,Kimberly La Pierre,Anita C. Risch,Eric W. Seabloom,Martin Schütz,Christopher Steenbock,Carly Stevens,Noah Fierer
标识
DOI:10.1073/pnas.1508382112
摘要
Soil microorganisms are critical to ecosystem functioning and the maintenance of soil fertility. However, despite global increases in the inputs of nitrogen (N) and phosphorus (P) to ecosystems due to human activities, we lack a predictive understanding of how microbial communities respond to elevated nutrient inputs across environmental gradients. Here we used high-throughput sequencing of marker genes to elucidate the responses of soil fungal, archaeal, and bacterial communities using an N and P addition experiment replicated at 25 globally distributed grassland sites. We also sequenced metagenomes from a subset of the sites to determine how the functional attributes of bacterial communities change in response to elevated nutrients. Despite strong compositional differences across sites, microbial communities shifted in a consistent manner with N or P additions, and the magnitude of these shifts was related to the magnitude of plant community responses to nutrient inputs. Mycorrhizal fungi and methanogenic archaea decreased in relative abundance with nutrient additions, as did the relative abundances of oligotrophic bacterial taxa. The metagenomic data provided additional evidence for this shift in bacterial life history strategies because nutrient additions decreased the average genome sizes of the bacterial community members and elicited changes in the relative abundances of representative functional genes. Our results suggest that elevated N and P inputs lead to predictable shifts in the taxonomic and functional traits of soil microbial communities, including increases in the relative abundances of faster-growing, copiotrophic bacterial taxa, with these shifts likely to impact belowground ecosystems worldwide.
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