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Microbial community shifts trigger loss of orthophosphate in wetland soils subjected to experimental warming
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Microbial community shifts trigger loss of orthophosphate in wetland soils subjected to experimental warming
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Microbial community shifts trigger loss of orthophosphate in wetland soils subjected to experimental warming
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Journal Article
Microbial community shifts trigger loss of orthophosphate in wetland soils subjected to experimental warming
2018
Overview
Aims Microbial-driven biogeochemical cycles of phosphorus (P) in wetlands subjected to global climate warming result in a downstream eutrophication risk. However, how warming influences P associated with microbial shifts in wetland soils is largely unknown. Methods A custom-built, novel microcosm that simulated climate warming was established under ambient temperature and elevated wanning conditions (+ 3 °C). 31P nuclear magnetic resonance (31P–NMR) technology was used to characterize different P forms and highthroughput sequencing of 16S rRNA gene was used to identify microbial community and functional potentials in wetland soils varied with nutrition status. Results Soil P forms were dominated by orthophosphate. The dynamic changes of different P forms in response to warming were mainly observed in high nutrition wetlands. The relative abundance of orthophosphate and polyphosphate (inorganic) significantly (p < 0.05) decreased, which was accompanied with increased phosphonate (organic) under warming. Consistently, soil microbial community shifts were also found in high nutrition wetlands, especially in fall with significantly (p < 0.05) increased relative abundance of Alphaproteobacteria and Betaproteobacteria and decreased Clostridia under warming. The microbial functions related to catabolism, the transport, degradation and release of P were enriched under warming. Changed microbial community may have altered the overall functional potentials which were responsible for P dynamics. Conclusions Soil microbial community shifts in response to experimental warming were season-based. Microbial changes and P shifts from high nutrition wetlands were more sensitive to warming. The changed microbial community under warming conditions may trigger the loss of orthophosphate through the altered functional potentials. These findings aid to better understand microbial-driven biogeochemical cycles of P in wetland soils under future climate changes.
Publisher
Springer,Springer International Publishing,Springer Nature B.V
Subject
