| Literature DB >> 33360134 |
Abstract
Microbes simultaneously drive multiple functions (multifunctionality) that support human well-beinpan>g. However, the structure anpan>d functionpan> of microbial communities anpan>d their impact onpan> soil multifunctionpan>ality followinpan>g grasslanpan>d afforestationpan> remainpan>s unknown, thus hinpan>derinpan>g our ability to formulate conpan>servationpan> policies. We compared soil bacterial anpan>d fungal communities, soil abiotic properties, anpan>d soil pan> class="Chemical">nitrogen (N) function and multifunctionality in the afforested sites that were previously grassland, on a subtropical plateau in China. We also explored the degree to which the niche complementarity effect and the selection effect of microbes are linked to soil N function and multifunctionality. We found that afforestation of grassland significantly decreased pH, available N concentration and density, and soil multifunctionality. However, afforestation significantly increased C (carbon) limitation and shifted soil microbes from being limited by N to, instead, being co-limited by N and P (phosphorus). The significant decrease in available N was primarily driven by soil microbes. In shaping soil N availability, the effect of bacterial diversities was stronger than that of fungal diversities, and the effect of fungal functional diversities was stronger than that of bacterial functional diversities. The effect of functional diversities was greater than that of all the significant changes in the functions and, also, the significant changes in the N-related functions. These results further emphasized that functional niche complementarity dominated soil N availability. In addition, bacterial taxonomic diversities showed positive effects of niche complementarity on soil multifunctionality; ultimately, the losses in bacterial taxonomic diversities derived from the increases in C limitation and the shifts in NP limitation combined to impaired soil multifunctionality. Our results suggested that the optimization of soil microbial functional diversities might increase soil N availability, and that minimizing losses of soil microbial taxonomic diversities by optimizing soil abiotic environments might improve soil multifunctionality.Entities:
Keywords: Available nitrogen; Bacteria; Element limitation; Fungi; Niche complementarity; Selection effect
Year: 2020 PMID: 33360134 DOI: 10.1016/j.scitotenv.2020.143663
Source DB: PubMed Journal: Sci Total Environ ISSN: 0048-9697 Impact factor: 7.963